GNAT User's Guide ***************** GNAT User's Guide for Unix Platforms GNAT, The GNU Ada 95 Compiler GNAT Version 3.15p Date: 2002/05/22 04:20:30 Ada Core Technologies, Inc. Copyright (C) 1995-2001, Free Software Foundation Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.1 or any later version published by the Free Software Foundation; with the Invariant Sections being GNU Free Documentation License", with the Front-Cover Texts being GNAT User's Guide for Unix Platforms", and with no Back-Cover Texts. A copy of the license is included in the section entitled GNU Free Documentation License". About This Guide **************** This guide describes the use of GNAT, a compiler and software development toolset for the full Ada 95 programming language. It describes the features of the compiler and tools, and details how to use them to build Ada 95 applications. What This Guide Contains ======================== This guide contains the following chapters: * *Note Getting Started with GNAT::, describes how to get started compiling and running Ada programs with the GNAT Ada programming environment. * *Note The GNAT Compilation Model::, describes the compilation model used by GNAT. * *Note Compiling Using gcc::, describes how to compile Ada programs with `gcc', the Ada compiler. * *Note Binding Using gnatbind::, describes how to perform binding of Ada programs with `gnatbind', the GNAT binding utility. * *Note Linking Using gnatlink::, describes `gnatlink', a program that provides for linking using the GNAT run-time library to construct a program. `gnatlink' can also incorporate foreign language object units into the executable. * *Note The GNAT Make Program gnatmake::, describes `gnatmake', a utility that automatically determines the set of sources needed by an Ada compilation unit, and executes the necessary compilations binding and link. * *Note Renaming Files Using gnatchop::, describes `gnatchop', a utility that allows you to preprocess a file that contains Ada source code, and split it into one or more new files, one for each compilation unit. * *Note Configuration Pragmas::, describes the configuration pragmas handled by GNAT. * *Note Handling Arbitrary File Naming Conventions Using gnatname::, shows how to override the default GNAT file naming conventions, either for an individual unit or globally. * *Note GNAT Project Manager::, describes how to use project files to organize large projects. * *Note Elaboration Order Handling in GNAT::, describes how GNAT helps you deal with elaboration order issues. * *Note The Cross-Referencing Tools gnatxref and gnatfind::, discusses `gnatxref' and `gnatfind', two tools that provide an easy way to navigate through sources. * *Note File Name Krunching Using gnatkr::, describes the `gnatkr' file name krunching utility, used to handle shortened file names on operating systems with a limit on the length of names. * *Note Preprocessing Using gnatprep::, describes `gnatprep', a preprocessor utility that allows a single source file to be used to generate multiple or parameterized source files, by means of macro substitution. * *Note The GNAT Library Browser gnatls::, describes `gnatls', a utility that displays information about compiled units, including dependences on the corresponding sources files, and consistency of compilations. * *Note GNAT and Libraries::, describes the process of creating and using Libraries with GNAT. It also describes how to recompile the GNAT run-time library. * *Note Using the GNU make Utility::, describes some techniques for using the GNAT toolset in Makefiles. * *Note Finding Memory Problems with gnatmem::, describes `gnatmem', a utility that monitors dynamic allocation and deallocation activity in a program, and displays information about incorrect deallocations and sources of possible memory leaks. * *Note Finding Memory Problems with GNAT Debug Pool::, describes how to use the GNAT-specific Debug Pool in order to detect as early as possible the use of incorrect memory references. * *Note Creating Sample Bodies Using gnatstub::, discusses `gnatstub', a utility that generates empty but compilable bodies for library units. * *Note Reducing the Size of Ada Executables with gnatelim::, describes `gnatelim', a tool which detects unused subprograms and helps the compiler to create a smaller executable for the program. * *Note Other Utility Programs::, discusses several other GNAT utilities, including `gnatpsta'. * *Note Running and Debugging Ada Programs::, describes how to run and debug Ada programs. * *Note Inline Assembler::, shows how to use the inline assembly facility in an Ada program. * *Note Performance Considerations::, reviews the trade offs between using defaults or options in program development. What You Should Know before Reading This Guide ============================================== This user's guide assumes that you are familiar with Ada 95 language, as described in the International Standard ANSI/ISO/IEC-8652:1995, Jan 1995. Related Information =================== For further information about related tools, refer to the following documents: * `GNAT Reference Manual', which contains all reference material for the GNAT implementation of Ada 95. * `Ada 95 Language Reference Manual', which contains all reference material for the Ada 95 programming language. * `Debugging with GDB' contains all details on the use of the GNU source-level debugger. * `GNU Emacs Manual' contains full information on the extensible editor and programming environment Emacs. Conventions =========== Following are examples of the typographical and graphic conventions used in this guide: * `Functions', `utility program names', `standard names', and `classes'. * `Option flags' * `File Names', `button names', and `field names'. * VARIABLES. * _Emphasis_. * [optional information or parameters] * Examples are described by text and then shown this way. Commands that are entered by the user are preceded in this manual by the characters "`$ '" (dollar sign followed by space). If your system uses this sequence as a prompt, then the commands will appear exactly as you see them in the manual. If your system uses some other prompt, then the command will appear with the `$' replaced by whatever prompt character you are using. Getting Started with GNAT ************************* This chapter describes some simple ways of using GNAT to build executable Ada programs. Running GNAT ============ Three steps are needed to create an executable file from an Ada source file: 1. The source file(s) must be compiled. 2. The file(s) must be bound using the GNAT binder. 3. All appropriate object files must be linked to produce an executable. All three steps are most commonly handled by using the `gnatmake' utility program that, given the name of the main program, automatically performs the necessary compilation, binding and linking steps. Running a Simple Ada Program ============================ Any text editor may be used to prepare an Ada program. If `Glide' is used, the optional Ada mode may be helpful in laying out the program. The program text is a normal text file. We will suppose in our initial example that you have used your editor to prepare the following standard format text file: with Ada.Text_IO; use Ada.Text_IO; procedure Hello is begin Put_Line ("Hello WORLD!"); end Hello; This file should be named `hello.adb'. With the normal default file naming conventions, GNAT requires that each file contain a single compilation unit whose file name is the unit name, with periods replaced by hyphens; the extension is `ads' for a spec and `adb' for a body. You can override this default file naming convention by use of the special pragma `Source_File_Name' (*note Using Other File Names::). Alternatively, if you want to rename your files according to this default convention, which is probably more convenient if you will be using GNAT for all your compilations, then the `gnatchop' utility can be used to generate correctly-named source files (*note Renaming Files Using gnatchop::). You can compile the program using the following command (`$' is used as the command prompt in the examples in this document): $ gcc -c hello.adb `gcc' is the command used to run the compiler. This compiler is capable of compiling programs in several languages, including Ada 95 and C. It assumes that you have given it an Ada program if the file extension is either `.ads' or `.adb', and it will then call the GNAT compiler to compile the specified file. The `-c' switch is required. It tells `gcc' to only do a compilation. (For C programs, `gcc' can also do linking, but this capability is not used directly for Ada programs, so the `-c' switch must always be present.) This compile command generates a file `hello.o', which is the object file corresponding to your Ada program. It also generates an "Ada Library Information" file `hello.ali', which contains additional information used to check that an Ada program is consistent. To build an executable file, use `gnatbind' to bind the program and `gnatlink' to link it. The argument to both `gnatbind' and `gnatlink' is the name of the `ali' file, but the default extension of `.ali' can be omitted. This means that in the most common case, the argument is simply the name of the main program: $ gnatbind hello $ gnatlink hello A simpler method of carrying out these steps is to use `gnatmake', a master program that invokes all the required compilation, binding and linking tools in the correct order. In particular, `gnatmake' automatically recompiles any sources that have been modified since they were last compiled, or sources that depend on such modified sources, so that "version skew" is avoided. $ gnatmake hello.adb The result is an executable program called `hello', which can be run by entering: $ hello assuming that the current directory is on the search path for executable programs. and, if all has gone well, you will see Hello WORLD! appear in response to this command. Running a Program with Multiple Units ===================================== Consider a slightly more complicated example that has three files: a main program, and the spec and body of a package: package Greetings is procedure Hello; procedure Goodbye; end Greetings; with Ada.Text_IO; use Ada.Text_IO; package body Greetings is procedure Hello is begin Put_Line ("Hello WORLD!"); end Hello; procedure Goodbye is begin Put_Line ("Goodbye WORLD!"); end Goodbye; end Greetings; with Greetings; procedure Gmain is begin Greetings.Hello; Greetings.Goodbye; end Gmain; Following the one-unit-per-file rule, place this program in the following three separate files: `greetings.ads' spec of package `Greetings' `greetings.adb' body of package `Greetings' `gmain.adb' body of main program To build an executable version of this program, we could use four separate steps to compile, bind, and link the program, as follows: $ gcc -c gmain.adb $ gcc -c greetings.adb $ gnatbind gmain $ gnatlink gmain Note that there is no required order of compilation when using GNAT. In particular it is perfectly fine to compile the main program first. Also, it is not necessary to compile package specs in the case where there is an accompanying body; you only need to compile the body. If you want to submit these files to the compiler for semantic checking and not code generation, then use the `-gnatc' switch: $ gcc -c greetings.ads -gnatc Although the compilation can be done in separate steps as in the above example, in practice it is almost always more convenient to use the `gnatmake' tool. All you need to know in this case is the name of the main program's source file. The effect of the above four commands can be achieved with a single one: $ gnatmake gmain.adb In the next section we discuss the advantages of using `gnatmake' in more detail. Using the `gnatmake' Utility ============================ If you work on a program by compiling single components at a time using `gcc', you typically keep track of the units you modify. In order to build a consistent system, you compile not only these units, but also any units that depend on the units you have modified. For example, in the preceding case, if you edit `gmain.adb', you only need to recompile that file. But if you edit `greetings.ads', you must recompile both `greetings.adb' and `gmain.adb', because both files contain units that depend on `greetings.ads'. `gnatbind' will warn you if you forget one of these compilation steps, so that it is impossible to generate an inconsistent program as a result of forgetting to do a compilation. Nevertheless it is tedious and error-prone to keep track of dependencies among units. One approach to handle the dependency-bookkeeping is to use a makefile. However, makefiles present maintenance problems of their own: if the dependencies change as you change the program, you must make sure that the makefile is kept up-to-date manually, which is also an error-prone process. The `gnatmake' utility takes care of these details automatically. Invoke it using either one of the following forms: $ gnatmake gmain.adb $ gnatmake gmain The argument is the name of the file containing the main program; you may omit the extension. `gnatmake' examines the environment, automatically recompiles any files that need recompiling, and binds and links the resulting set of object files, generating the executable file, `gmain'. In a large program, it can be extremely helpful to use `gnatmake', because working out by hand what needs to be recompiled can be difficult. Note that `gnatmake' takes into account all the Ada 95 rules that establish dependencies among units. These include dependencies that result from inlining subprogram bodies, and from generic instantiation. Unlike some other Ada make tools, `gnatmake' does not rely on the dependencies that were found by the compiler on a previous compilation, which may possibly be wrong when sources change. `gnatmake' determines the exact set of dependencies from scratch each time it is run. Introduction to Glide and GVD ============================= Although it is possible to develop programs using only the command line interface (`gnatmake', etc.) a graphical Interactive Development Environment can make it easier for you to compose, navigate, and debug programs. This section describes the main features of Glide, the GNAT graphical IDE, and also shows how to use the basic commands in GVD, the GNU Visual Debugger. Additional information may be found in the on-line help for these tools. Building a New Program with Glide --------------------------------- The simplest way to invoke Glide is to enter `glide' at the command prompt. It will generally be useful to issue this as a background command, thus allowing you to continue using your command window for other purposes while Glide is running: $ glide& Glide will start up with an initial screen displaying the top-level menu items as well as some other information. The menu selections are as follows * `Buffers' * `Files' * `Tools' * `Edit' * `Search' * `Mule' * `Glide' * `Help' For this introductory example, you will need to create a new Ada source file. First, select the `Files' menu. This will pop open a menu with around a dozen or so items. To create a file, select the `Open file...' choice. Depending on the platform, you may see a pop-up window where you can browse to an appropriate directory and then enter the file name, or else simply see a line at the bottom of the Glide window where you can likewise enter the file name. Note that in Glide, when you attempt to open a non-existent file, the effect is to create a file with that name. For this example enter `hello.adb' as the name of the file. A new buffer will now appear, occupying the entire Glide window, with the file name at the top. The menu selections are slightly different from the ones you saw on the opening screen; there is an `Entities' item, and in place of `Glide' there is now an `Ada' item. Glide uses the file extension to identify the source language, so `adb' indicates an Ada source file. You will enter some of the source program lines explicitly, and use the syntax-oriented template mechanism to enter other lines. First, type the following text: with Ada.Text_IO; use Ada.Text_IO; procedure Hello is begin Observe that Glide uses different colors to distinguish reserved words from identifiers. Also, after the `procedure Hello is' line, the cursor is automatically indented in anticipation of declarations. When you enter `begin', Glide recognizes that there are no declarations and thus places `begin' flush left. But after the `begin' line the cursor is again indented, where the statement(s) will be placed. The main part of the program will be a `for' loop. Instead of entering the text explicitly, however, use a statement template. Select the `Ada' item on the top menu bar, move the mouse to the `Statements' item, and you will see a large selection of alternatives. Choose `for loop'. You will be prompted (at the bottom of the buffer) for a loop name; simply press the key since a loop name is not needed. You should see the beginning of a `for' loop appear in the source program window. You will now be prompted for the name of the loop variable; enter a line with the identifier `ind' (lower case). Note that, by default, Glide capitalizes the name (you can override such behavior if you wish, although this is outside the scope of this introduction). Next, Glide prompts you for the loop range; enter a line containing `1..5' and you will see this also appear in the source program, together with the remaining elements of the `for' loop syntax. Next enter the statement (with an intentional error, a missing semicolon) that will form the body of the loop: Put_Line("Hello, World" & Integer'Image(I)) Finally, type `end Hello;' as the last line in the program. Now save the file: choose the `File' menu item, and then the `Save buffer' selection. You will see a message at the bottom of the buffer confirming that the file has been saved. You are now ready to attempt to build the program. Select the `Ada' item from the top menu bar. Although we could choose simply to compile the file, we will instead attempt to do a build (which invokes `gnatmake') since, if the compile is successful, we want to build an executable. Thus select `Ada build'. This will fail because of the compilation error, and you will notice that the Glide window has been split: the top window contains the source file, and the bottom window contains the output from the GNAT tools. Glide allows you to navigate from a compilation error to the source file position corresponding to the error: click the middle mouse button (or simultaneously press the left and right buttons, on a two-button mouse) on the diagnostic line in the tool window. The focus will shift to the source window, and the cursor will be positioned on the character at which the error was detected. Correct the error: type in a semicolon to terminate the statement. Although you can again save the file explicitly, you can also simply invoke `Ada' => `Build' and you will be prompted to save the file. This time the build will succeed; the tool output window shows you the options that are supplied by default. The GNAT tools' output (e.g., object and ALI files, executable) will go in the directory from which Glide was launched. To execute the program, choose `Ada' and then `Run'. You should see the program's output displayed in the bottom window: Hello, world 1 Hello, world 2 Hello, world 3 Hello, world 4 Hello, world 5 Simple Debugging with GVD ------------------------- This section describes how to set breakpoints, examine/modify variables, and step through execution. In order to enable debugging, you need to pass the `-g' switch to both the compiler and to `gnatlink'. If you are using the command line, passing `-g' to `gnatmake' will have this effect. You can then launch GVD, e.g. on the `hello' program, by issuing the command: $ gvd hello If you are using Glide, then `-g' is passed to the relevant tools by default when you do a build. Start the debugger by selecting the `Ada' menu item, and then `Debug'. GVD comes up in a multi-part window. One pane shows the names of files comprising your executable; another pane shows the source code of the current unit (initially your main subprogram), another pane shows the debugger output and user interactions, and the fourth pane (the data canvas at the top of the window) displays data objects that you have selected. To the left of the source file pane, you will notice green dots adjacent to some lines. These are lines for which object code exists and where breakpoints can thus be set. You set/reset a breakpoint by clicking the green dot. When a breakpoint is set, the dot is replaced by an `X' in a red circle. Clicking the circle toggles the breakpoint off, and the red circle is replaced by the green dot. For this example, set a breakpoint at the statement where `Put_Line' is invoked. Start program execution by selecting the `Run' button on the top menu bar. (The `Start' button will also start your program, but it will cause program execution to break at the entry to your main subprogram.) Evidence of reaching the breakpoint will appear: the source file line will be highlighted, and the debugger interactions pane will display a relevant message. You can examine the values of variables in several ways. Move the mouse over an occurrence of `Ind' in the `for' loop, and you will see the value (now `1') displayed. Alternatively, right-click on `Ind' and select `Display Ind'; a box showing the variable's name and value will appear in the data canvas. Although a loop index is a constant with respect to Ada semantics, you can change its value in the debugger. Right-click in the box for `Ind', and select the `Set Value of Ind' item. Enter `2' as the new value, and press `OK'. The box for `Ind' shows the update. Press the `Step' button on the top menu bar; this will step through one line of program text (the invocation of `Put_Line'), and you can observe the effect of having modified `Ind' since the value displayed is `2'. Remove the breakpoint, and resume execution by selecting the `Cont' button. You will see the remaining output lines displayed in the debugger interaction window, along with a message confirming normal program termination. Other Glide Features -------------------- You may have observed that some of the menu selections contain abbreviations; e.g., `(C-x C-f)' for `Open file...' in the `Files' menu. These are _shortcut keys_ that you can use instead of selecting menu items. The stands for ; thus `(C-x C-f)' means followed by , and this sequence can be used instead of selecting `Files' and then `Open file...'. To abort a Glide command, type . If you want Glide to start with an existing source file, you can either launch Glide as above and then open the file via `Files' => `Open file...', or else simply pass the name of the source file on the command line: $ glide hello.adb& While you are using Glide, a number of _buffers_ exist. You create some explicitly; e.g., when you open/create a file. Others arise as an effect of the commands that you issue; e.g., the buffer containing the output of the tools invoked during a build. If a buffer is hidden, you can bring it into a visible window by first opening the `Buffers' menu and then selecting the desired entry. If a buffer occupies only part of the Glide screen and you want to expand it to fill the entire screen, then click in the buffer and then select `Files' => `One Window'. If a window is occupied by one buffer and you want to split the window to bring up a second buffer, perform the following steps: * Select `Files' => `Split Window'; this will produce two windows each of which holds the original buffer (these are not copies, but rather different views of the same buffer contents) * With the focus in one of the windows, select the desired buffer from the `Buffers' menu To exit from Glide, choose `Files' => `Exit'. The GNAT Compilation Model ************************** This chapter describes the compilation model used by GNAT. Although similar to that used by other languages, such as C and C++, this model is substantially different from the traditional Ada compilation models, which are based on a library. The model is initially described without reference to the library-based model. If you have not previously used an Ada compiler, you need only read the first part of this chapter. The last section describes and discusses the differences between the GNAT model and the traditional Ada compiler models. If you have used other Ada compilers, this section will help you to understand those differences, and the advantages of the GNAT model. Source Representation ===================== Ada source programs are represented in standard text files, using Latin-1 coding. Latin-1 is an 8-bit code that includes the familiar 7-bit ASCII set, plus additional characters used for representing foreign languages (*note Foreign Language Representation:: for support of non-USA character sets). The format effector characters are represented using their standard ASCII encodings, as follows: `VT' Vertical tab, `16#0B#' `HT' Horizontal tab, `16#09#' `CR' Carriage return, `16#0D#' `LF' Line feed, `16#0A#' `FF' Form feed, `16#0C#' Source files are in standard text file format. In addition, GNAT will recognize a wide variety of stream formats, in which the end of physical physical lines is marked by any of the following sequences: `LF', `CR', `CR-LF', or `LF-CR'. This is useful in accommodating files that are imported from other operating systems. The end of a source file is normally represented by the physical end of file. However, the control character `16#1A#' (`SUB') is also recognized as signalling the end of the source file. Again, this is provided for compatibility with other operating systems where this code is used to represent the end of file. Each file contains a single Ada compilation unit, including any pragmas associated with the unit. For example, this means you must place a package declaration (a package "spec") and the corresponding body in separate files. An Ada "compilation" (which is a sequence of compilation units) is represented using a sequence of files. Similarly, you will place each subunit or child unit in a separate file. Foreign Language Representation =============================== GNAT supports the standard character sets defined in Ada 95 as well as several other non-standard character sets for use in localized versions of the compiler (*note Character Set Control::). Latin-1 ------- The basic character set is Latin-1. This character set is defined by ISO standard 8859, part 1. The lower half (character codes `16#00#' ... `16#7F#)' is identical to standard ASCII coding, but the upper half is used to represent additional characters. These include extended letters used by European languages, such as French accents, the vowels with umlauts used in German, and the extra letter A-ring used in Swedish. For a complete list of Latin-1 codes and their encodings, see the source file of library unit `Ada.Characters.Latin_1' in file `a-chlat1.ads'. You may use any of these extended characters freely in character or string literals. In addition, the extended characters that represent letters can be used in identifiers. Other 8-Bit Codes ----------------- GNAT also supports several other 8-bit coding schemes: Latin-2 Latin-2 letters allowed in identifiers, with uppercase and lowercase equivalence. Latin-3 Latin-3 letters allowed in identifiers, with uppercase and lowercase equivalence. Latin-4 Latin-4 letters allowed in identifiers, with uppercase and lowercase equivalence. Latin-5 Latin-4 letters (Cyrillic) allowed in identifiers, with uppercase and lowercase equivalence. IBM PC (code page 437) This code page is the normal default for PCs in the U.S. It corresponds to the original IBM PC character set. This set has some, but not all, of the extended Latin-1 letters, but these letters do not have the same encoding as Latin-1. In this mode, these letters are allowed in identifiers with uppercase and lowercase equivalence. IBM PC (code page 850) This code page is a modification of 437 extended to include all the Latin-1 letters, but still not with the usual Latin-1 encoding. In this mode, all these letters are allowed in identifiers with uppercase and lowercase equivalence. Full Upper 8-bit Any character in the range 80-FF allowed in identifiers, and all are considered distinct. In other words, there are no uppercase and lowercase equivalences in this range. This is useful in conjunction with certain encoding schemes used for some foreign character sets (e.g. the typical method of representing Chinese characters on the PC). No Upper-Half No upper-half characters in the range 80-FF are allowed in identifiers. This gives Ada 83 compatibility for identifier names. For precise data on the encodings permitted, and the uppercase and lowercase equivalences that are recognized, see the file `csets.adb' in the GNAT compiler sources. You will need to obtain a full source release of GNAT to obtain this file. Wide Character Encodings ------------------------ GNAT allows wide character codes to appear in character and string literals, and also optionally in identifiers, by means of the following possible encoding schemes: Hex Coding In this encoding, a wide character is represented by the following five character sequence: ESC a b c d Where `a', `b', `c', `d' are the four hexadecimal characters (using uppercase letters) of the wide character code. For example, ESC A345 is used to represent the wide character with code `16#A345#'. This scheme is compatible with use of the full Wide_Character set. Upper-Half Coding The wide character with encoding `16#abcd#' where the upper bit is on (in other words, "a" is in the range 8-F) is represented as two bytes, `16#ab#' and `16#cd#'. The second byte cannot be a format control character, but is not required to be in the upper half. This method can be also used for shift-JIS or EUC, where the internal coding matches the external coding. Shift JIS Coding A wide character is represented by a two-character sequence, `16#ab#' and `16#cd#', with the restrictions described for upper-half encoding as described above. The internal character code is the corresponding JIS character according to the standard algorithm for Shift-JIS conversion. Only characters defined in the JIS code set table can be used with this encoding method. EUC Coding A wide character is represented by a two-character sequence `16#ab#' and `16#cd#', with both characters being in the upper half. The internal character code is the corresponding JIS character according to the EUC encoding algorithm. Only characters defined in the JIS code set table can be used with this encoding method. UTF-8 Coding A wide character is represented using UCS Transformation Format 8 (UTF-8) as defined in Annex R of ISO 10646-1/Am.2. Depending on the character value, the representation is a one, two, or three byte sequence: 16#0000#-16#007f#: 2#0xxxxxxx# 16#0080#-16#07ff#: 2#110xxxxx# 2#10xxxxxx# 16#0800#-16#ffff#: 2#1110xxxx# 2#10xxxxxx# 2#10xxxxxx# where the xxx bits correspond to the left-padded bits of the 16-bit character value. Note that all lower half ASCII characters are represented as ASCII bytes and all upper half characters and other wide characters are represented as sequences of upper-half (The full UTF-8 scheme allows for encoding 31-bit characters as 6-byte sequences, but in this implementation, all UTF-8 sequences of four or more bytes length will be treated as illegal). Brackets Coding In this encoding, a wide character is represented by the following eight character sequence: [ " a b c d " ] Where `a', `b', `c', `d' are the four hexadecimal characters (using uppercase letters) of the wide character code. For example, ["A345"] is used to represent the wide character with code `16#A345#'. It is also possible (though not required) to use the Brackets coding for upper half characters. For example, the code `16#A3#' can be represented as `["A3"]'. This scheme is compatible with use of the full Wide_Character set, and is also the method used for wide character encoding in the standard ACVC (Ada Compiler Validation Capability) test suite distributions. Note: Some of these coding schemes do not permit the full use of the Ada 95 character set. For example, neither Shift JIS, nor EUC allow the use of the upper half of the Latin-1 set. File Naming Rules ================= The default file name is determined by the name of the unit that the file contains. The name is formed by taking the full expanded name of the unit and replacing the separating dots with hyphens and using lowercase for all letters. An exception arises if the file name generated by the above rules starts with one of the characters a,g,i, or s, and the second character is a minus. In this case, the character tilde is used in place of the minus. The reason for this special rule is to avoid clashes with the standard names for child units of the packages System, Ada, Interfaces, and GNAT, which use the prefixes s- a- i- and g- respectively. The file extension is `.ads' for a spec and `.adb' for a body. The following list shows some examples of these rules. `main.ads' Main (spec) `main.adb' Main (body) `arith_functions.ads' Arith_Functions (package spec) `arith_functions.adb' Arith_Functions (package body) `func-spec.ads' Func.Spec (child package spec) `func-spec.adb' Func.Spec (child package body) `main-sub.adb' Sub (subunit of Main) `a~bad.adb' A.Bad (child package body) Following these rules can result in excessively long file names if corresponding unit names are long (for example, if child units or subunits are heavily nested). An option is available to shorten such long file names (called file name "krunching"). This may be particularly useful when programs being developed with GNAT are to be used on operating systems with limited file name lengths. *Note Using gnatkr::. Of course, no file shortening algorithm can guarantee uniqueness over all possible unit names; if file name krunching is used, it is your responsibility to ensure no name clashes occur. Alternatively you can specify the exact file names that you want used, as described in the next section. Finally, if your Ada programs are migrating from a compiler with a different naming convention, you can use the gnatchop utility to produce source files that follow the GNAT naming conventions. (For details *note Renaming Files Using gnatchop::.) Using Other File Names ====================== In the previous section, we have described the default rules used by GNAT to determine the file name in which a given unit resides. It is often convenient to follow these default rules, and if you follow them, the compiler knows without being explicitly told where to find all the files it needs. However, in some cases, particularly when a program is imported from another Ada compiler environment, it may be more convenient for the programmer to specify which file names contain which units. GNAT allows arbitrary file names to be used by means of the Source_File_Name pragma. The form of this pragma is as shown in the following examples: pragma Source_File_Name (My_Utilities.Stacks, Spec_File_Name => "myutilst_a.ada"); pragma Source_File_name (My_Utilities.Stacks, Body_File_Name => "myutilst.ada"); As shown in this example, the first argument for the pragma is the unit name (in this example a child unit). The second argument has the form of a named association. The identifier indicates whether the file name is for a spec or a body; the file name itself is given by a string literal. The source file name pragma is a configuration pragma, which means that normally it will be placed in the `gnat.adc' file used to hold configuration pragmas that apply to a complete compilation environment. For more details on how the `gnat.adc' file is created and used *note Handling of Configuration Pragmas:: GNAT allows completely arbitrary file names to be specified using the source file name pragma. However, if the file name specified has an extension other than `.ads' or `.adb' it is necessary to use a special syntax when compiling the file. The name in this case must be preceded by the special sequence `-x' followed by a space and the name of the language, here `ada', as in: $ gcc -c -x ada peculiar_file_name.sim `gnatmake' handles non-standard file names in the usual manner (the non-standard file name for the main program is simply used as the argument to gnatmake). Note that if the extension is also non-standard, then it must be included in the gnatmake command, it may not be omitted. Alternative File Naming Schemes =============================== In the previous section, we described the use of the `Source_File_Name' pragma to allow arbitrary names to be assigned to individual source files. However, this approach requires one pragma for each file, and especially in large systems can result in very long `gnat.adc' files, and also create a maintenance problem. GNAT also provides a facility for specifying systematic file naming schemes other than the standard default naming scheme previously described. An alternative scheme for naming is specified by the use of `Source_File_Name' pragmas having the following format: pragma Source_File_Name ( Spec_File_Name => FILE_NAME_PATTERN [,Casing => CASING_SPEC] [,Dot_Replacement => STRING_LITERAL]); pragma Source_File_Name ( Body_File_Name => FILE_NAME_PATTERN [,Casing => CASING_SPEC] [,Dot_Replacement => STRING_LITERAL]); pragma Source_File_Name ( Subunit_File_Name => FILE_NAME_PATTERN [,Casing => CASING_SPEC] [,Dot_Replacement => STRING_LITERAL]); FILE_NAME_PATTERN ::= STRING_LITERAL CASING_SPEC ::= Lowercase | Uppercase | Mixedcase The `FILE_NAME_PATTERN' string shows how the file name is constructed. It contains a single asterisk character, and the unit name is substituted systematically for this asterisk. The optional parameter `Casing' indicates whether the unit name is to be all upper-case letters, all lower-case letters, or mixed-case. If no `Casing' parameter is used, then the default is all lower-case. The optional `Dot_Replacement' string is used to replace any periods that occur in subunit or child unit names. If no `Dot_Replacement' argument is used then separating dots appear unchanged in the resulting file name. Although the above syntax indicates that the `Casing' argument must appear before the `Dot_Replacement' argument, but it is also permissible to write these arguments in the opposite order. As indicated, it is possible to specify different naming schemes for bodies, specs, and subunits. Quite often the rule for subunits is the same as the rule for bodies, in which case, there is no need to give a separate `Subunit_File_Name' rule, and in this case the `Body_File_name' rule is used for subunits as well. The separate rule for subunits can also be used to implement the rather unusual case of a compilation environment (e.g. a single directory) which contains a subunit and a child unit with the same unit name. Although both units cannot appear in the same partition, the Ada Reference Manual allows (but does not require) the possibility of the two units coexisting in the same environment. The file name translation works in the following steps: * If there is a specific `Source_File_Name' pragma for the given unit, then this is always used, and any general pattern rules are ignored. * If there is a pattern type `Source_File_Name' pragma that applies to the unit, then the resulting file name will be used if the file exists. If more than one pattern matches, the latest one will be tried first, and the first attempt resulting in a reference to a file that exists will be used. * If no pattern type `Source_File_Name' pragma that applies to the unit for which the corresponding file exists, then the standard GNAT default naming rules are used. As an example of the use of this mechanism, consider a commonly used scheme in which file names are all lower case, with separating periods copied unchanged to the resulting file name, and specs end with ".1.ada", and bodies end with ".2.ada". GNAT will follow this scheme if the following two pragmas appear: pragma Source_File_Name (Spec_File_Name => "*.1.ada"); pragma Source_File_Name (Body_File_Name => "*.2.ada"); The default GNAT scheme is actually implemented by providing the following default pragmas internally: pragma Source_File_Name (Spec_File_Name => "*.ads", Dot_Replacement => "-"); pragma Source_File_Name (Body_File_Name => "*.adb", Dot_Replacement => "-"); Our final example implements a scheme typically used with one of the Ada 83 compilers, where the separator character for subunits was "__" (two underscores), specs were identified by adding `_.ADA', bodies by adding `.ADA', and subunits by adding `.SEP'. All file names were upper case. Child units were not present of course since this was an Ada 83 compiler, but it seems reasonable to extend this scheme to use the same double underscore separator for child units. pragma Source_File_Name (Spec_File_Name => "*_.ADA", Dot_Replacement => "__", Casing = Uppercase); pragma Source_File_Name (Body_File_Name => "*.ADA", Dot_Replacement => "__", Casing = Uppercase); pragma Source_File_Name (Subunit_File_Name => "*.SEP", Dot_Replacement => "__", Casing = Uppercase); Generating Object Files ======================= An Ada program consists of a set of source files, and the first step in compiling the program is to generate the corresponding object files. These are generated by compiling a subset of these source files. The files you need to compile are the following: * If a package spec has no body, compile the package spec to produce the object file for the package. * If a package has both a spec and a body, compile the body to produce the object file for the package. The source file for the package spec need not be compiled in this case because there is only one object file, which contains the code for both the spec and body of the package. * For a subprogram, compile the subprogram body to produce the object file for the subprogram. The spec, if one is present, is as usual in a separate file, and need not be compiled. * In the case of subunits, only compile the parent unit. A single object file is generated for the entire subunit tree, which includes all the subunits. * Compile child units independently of their parent units (though, of course, the spec of all the ancestor unit must be present in order to compile a child unit). * Compile generic units in the same manner as any other units. The object files in this case are small dummy files that contain at most the flag used for elaboration checking. This is because GNAT always handles generic instantiation by means of macro expansion. However, it is still necessary to compile generic units, for dependency checking and elaboration purposes. The preceding rules describe the set of files that must be compiled to generate the object files for a program. Each object file has the same name as the corresponding source file, except that the extension is `.o' as usual. You may wish to compile other files for the purpose of checking their syntactic and semantic correctness. For example, in the case where a package has a separate spec and body, you would not normally compile the spec. However, it is convenient in practice to compile the spec to make sure it is error-free before compiling clients of this spec, because such compilations will fail if there is an error in the spec. GNAT provides an option for compiling such files purely for the purposes of checking correctness; such compilations are not required as part of the process of building a program. To compile a file in this checking mode, use the `-gnatc' switch. Source Dependencies =================== A given object file clearly depends on the source file which is compiled to produce it. Here we are using "depends" in the sense of a typical `make' utility; in other words, an object file depends on a source file if changes to the source file require the object file to be recompiled. In addition to this basic dependency, a given object may depend on additional source files as follows: * If a file being compiled `with''s a unit X, the object file depends on the file containing the spec of unit X. This includes files that are `with''ed implicitly either because they are parents of `with''ed child units or they are run-time units required by the language constructs used in a particular unit. * If a file being compiled instantiates a library level generic unit, the object file depends on both the spec and body files for this generic unit. * If a file being compiled instantiates a generic unit defined within a package, the object file depends on the body file for the package as well as the spec file. * If a file being compiled contains a call to a subprogram for which pragma `Inline' applies and inlining is activated with the `-gnatn' switch, the object file depends on the file containing the body of this subprogram as well as on the file containing the spec. Note that for inlining to actually occur as a result of the use of this switch, it is necessary to compile in optimizing mode. The use of `-gnatN' activates a more extensive inlining optimization that is performed by the front end of the compiler. This inlining does not require that the code generation be optimized. Like `-gnatn', the use of this switch generates additional dependencies. * If an object file O depends on the proper body of a subunit through inlining or instantiation, it depends on the parent unit of the subunit. This means that any modification of the parent unit or one of its subunits affects the compilation of O. * The object file for a parent unit depends on all its subunit body files. * The previous two rules meant that for purposes of computing dependencies and recompilation, a body and all its subunits are treated as an indivisible whole. These rules are applied transitively: if unit `A' `with''s unit `B', whose elaboration calls an inlined procedure in package `C', the object file for unit `A' will depend on the body of `C', in file `c.adb'. The set of dependent files described by these rules includes all the files on which the unit is semantically dependent, as described in the Ada 95 Language Reference Manual. However, it is a superset of what the ARM describes, because it includes generic, inline, and subunit dependencies. An object file must be recreated by recompiling the corresponding source file if any of the source files on which it depends are modified. For example, if the `make' utility is used to control compilation, the rule for an Ada object file must mention all the source files on which the object file depends, according to the above definition. The determination of the necessary recompilations is done automatically when one uses `gnatmake'. The Ada Library Information Files ================================= Each compilation actually generates two output files. The first of these is the normal object file that has a `.o' extension. The second is a text file containing full dependency information. It has the same name as the source file, but an `.ali' extension. This file is known as the Ada Library Information (`ali') file. The following information is contained in the `ali' file. * Version information (indicates which version of GNAT was used to compile the unit(s) in question) * Main program information (including priority and time slice settings, as well as the wide character encoding used during compilation). * List of arguments used in the `gcc' command for the compilation * Attributes of the unit, including configuration pragmas used, an indication of whether the compilation was successful, exception model used etc. * A list of relevant restrictions applying to the unit (used for consistency) checking. * Categorization information (e.g. use of pragma `Pure'). * Information on all `with''ed units, including presence of `Elaborate' or `Elaborate_All' pragmas. * Information from any `Linker_Options' pragmas used in the unit * Information on the use of `Body_Version' or `Version' attributes in the unit. * Dependency information. This is a list of files, together with time stamp and checksum information. These are files on which the unit depends in the sense that recompilation is required if any of these units are modified. * Cross-reference data. Contains information on all entities referenced in the unit. Used by tools like `gnatxref' and `gnatfind' to provide cross-reference information. For a full detailed description of the format of the `ali' file, see the source of the body of unit `Lib.Writ', contained in file `lib-writ.adb' in the GNAT compiler sources. Binding an Ada Program ====================== When using languages such as C and C++, once the source files have been compiled the only remaining step in building an executable program is linking the object modules together. This means that it is possible to link an inconsistent version of a program, in which two units have included different versions of the same header. The rules of Ada do not permit such an inconsistent program to be built. For example, if two clients have different versions of the same package, it is illegal to build a program containing these two clients. These rules are enforced by the GNAT binder, which also determines an elaboration order consistent with the Ada rules. The GNAT binder is run after all the object files for a program have been created. It is given the name of the main program unit, and from this it determines the set of units required by the program, by reading the corresponding ALI files. It generates error messages if the program is inconsistent or if no valid order of elaboration exists. If no errors are detected, the binder produces a main program, in Ada by default, that contains calls to the elaboration procedures of those compilation unit that require them, followed by a call to the main program. This Ada program is compiled to generate the object file for the main program. The name of the Ada file is `b~XXX.adb' (with the corresponding spec `b~XXX.ads') where XXX is the name of the main program unit. Finally, the linker is used to build the resulting executable program, using the object from the main program from the bind step as well as the object files for the Ada units of the program. Mixed Language Programming ========================== Interfacing to C ---------------- There are two ways to build a program that contains some Ada files and some other language files depending on whether the main program is in Ada or not. If the main program is in Ada, you should proceed as follows: 1. Compile the other language files to generate object files. For instance: gcc -c file1.c gcc -c file2.c 2. Compile the Ada units to produce a set of object files and ALI files. For instance: gnatmake -c my_main.adb 3. Run the Ada binder on the Ada main program. For instance: gnatbind my_main.ali 4. Link the Ada main program, the Ada objects and the other language objects. For instance: gnatlink my_main.ali file1.o file2.o The three last steps can be grouped in a single command: gnatmake my_main.adb -largs file1.o file2.o If the main program is in some language other than Ada, Then you may have more than one entry point in the Ada subsystem. You must use a special option of the binder to generate callable routines to initialize and finalize the Ada units (*note Binding with Non-Ada Main Programs::). Calls to the initialization and finalization routines must be inserted in the main program, or some other appropriate point in the code. The call to initialize the Ada units must occur before the first Ada subprogram is called, and the call to finalize the Ada units must occur after the last Ada subprogram returns. You use the same procedure for building the program as described previously. In this case, however, the binder only places the initialization and finalization subprograms into file `b~XXX.adb' instead of the main program. So, if the main program is not in Ada, you should proceed as follows: 1. Compile the other language files to generate object files. For instance: gcc -c file1.c gcc -c file2.c 2. Compile the Ada units to produce a set of object files and ALI files. For instance: gnatmake -c entry_point1.adb gnatmake -c entry_point2.adb 3. Run the Ada binder on the Ada main program. For instance: gnatbind -n entry_point1.ali entry_point2.ali 4. Link the Ada main program, the Ada objects and the other language objects. You only need to give the last entry point here. For instance: gnatlink entry_point2.ali file1.o file2.o Calling Conventions ------------------- GNAT follows standard calling sequence conventions and will thus interface to any other language that also follows these conventions. The following Convention identifiers are recognized by GNAT: * Ada. This indicates that the standard Ada calling sequence will be used and all Ada data items may be passed without any limitations in the case where GNAT is used to generate both the caller and callee. It is also possible to mix GNAT generated code and code generated by another Ada compiler. In this case, the data types should be restricted to simple cases, including primitive types. Whether complex data types can be passed depends on the situation. Probably it is safe to pass simple arrays, such as arrays of integers or floats. Records may or may not work, depending on whether both compilers lay them out identically. Complex structures involving variant records, access parameters, tasks, or protected types, are unlikely to be able to be passed. Note that in the case of GNAT running on a platform that supports DEC Ada 83, a higher degree of compatibility can be guaranteed, and in particular records are layed out in an identical manner in the two compilers. Note also that if output from two different compilers is mixed, the program is responsible for dealing with elaboration issues. Probably the safest approach is to write the main program in the version of Ada other than GNAT, so that it takes care of its own elaboration requirements, and then call the GNAT-generated adainit procedure to ensure elaboration of the GNAT components. Consult the documentation of the other Ada compiler for further details on elaboration. However, it is not possible to mix the tasking run time of GNAT and DEC Ada 83, All the tasking operations must either be entirely within GNAT compiled sections of the program, or entirely within DEC Ada 83 compiled sections of the program. * Asm. Equivalent to Ada. * Assembler. Equivalent to Ada. * COBOL. Data will be passed according to the conventions described in section B.4 of the Ada 95 Reference Manual. * C. Data will be passed according to the conventions described in section B.3 of the Ada 95 Reference Manual. * CPP. This stands for C++. For most purposes this is identical to C. See the separate description of the specialized GNAT pragmas relating to C++ interfacing for further details. * Fortran. Data will be passed according to the conventions described in section B.5 of the Ada 95 Reference Manual. * Intrinsic. This applies to an intrinsic operation, as defined in the Ada 95 Reference Manual. If a a pragma Import (Intrinsic) applies to a subprogram, this means that the body of the subprogram is provided by the compiler itself, usually by means of an efficient code sequence, and that the user does not supply an explicit body for it. In an application program, the pragma can only be applied to the following two sets of names, which the GNAT compiler recognizes. * Rotate_Left, Rotate_Right, Shift_Left, Shift_Right, Shift_Right_- Arithmetic. The corresponding subprogram declaration must have two formal parameters. The first one must be a signed integer type or a modular type with a binary modulus, and the second parameter must be of type Natural. The return type must be the same as the type of the first argument. The size of this type can only be 8, 16, 32, or 64. * binary arithmetic operators: "+", "-", "*", "/" The corresponding operator declaration must have parameters and result type that have the same root numeric type (for example, all three are long_float types). This simplifies the definition of operations that use type checking to perform dimensional checks: type Distance is new Long_Float; type Time is new Long_Float; type Velocity is new Long_Float; function "/" (D : Distance; T : Time) return Velocity; pragma Import (Intrinsic, "/"); This common idiom is often programmed with a generic definition and an explicit body. The pragma makes it simpler to introduce such declarations. It incurs no overhead in compilation time or code size, because it is implemented as a single machine instruction. * Stdcall. This is relevant only to NT/Win95 implementations of GNAT, and specifies that the Stdcall calling sequence will be used, as defined by the NT API. * Stubbed. This is a special convention that indicates that the compiler should provide a stub body that raises `Program_Error'. Building Mixed Ada & C++ Programs ================================= Building a mixed application containing both Ada and C++ code may be a challenge for the unaware programmer. As a matter of fact, this interfacing has not been standardized in the Ada 95 reference manual due to the immaturity and lack of standard of C++ at the time. This section gives a few hints that should make this task easier. In particular the first section addresses the differences with interfacing with C. The second section looks into the delicate problem of linking the complete application from its Ada and C++ parts. The last section give some hints on how the GNAT run time can be adapted in order to allow inter-language dispatching with a new C++ compiler. Interfacing to C++ ------------------ GNAT supports interfacing with C++ compilers generating code that is compatible with the standard Application Binary Interface of the given platform. Interfacing can be done at 3 levels: simple data, subprograms and classes. In the first 2 cases, GNAT offer a specific CONVENTION CPP that behaves exactly like CONVENTION C. Usually C++ mangle names of subprograms and currently GNAT does not provide any help to solve the demangling problem. This problem can be addressed in 2 ways: * by modifying the C++ code in order to force a C convention using the EXTERN "C" syntax. * by figuring out the mangled name and use it as the Link_Name argument of the pragma import. Interfacing at the class level can be achieved by using the GNAT specific pragmas such as `CPP_Class' and ` CPP_Virtual'. See the GNAT Reference Manual for additional information. Linking a Mixed C++ & Ada Program --------------------------------- Usually the linker of the C++ development system must be used to link mixed applications because most C++ systems will resolve elaboration issues (such as calling constructors on global class instances) transparently during the link phase. GNAT has been adapted to ease the use of a foreign linker for the last phase. Three cases can be considered: 1. Using GNAT and G++ (GNU C++ compiler) from the same GCC installation. The c++ linker can simply be called by using the c++ specific driver called `c++'. Note that this setup is not very common because it may request recompiling the whole GCC tree from sources and it does not allow to upgrade easily to a new version of one compiler for one of the two languages without taking the risk of destabilizing the other. $ c++ -c file1.C $ c++ -c file2.C $ gnatmake ada_unit -largs file1.o file2.o --LINK=c++ 2. Using GNAT and G++ from 2 different GCC installations. If both compilers are on the PATH, the same method can be used. It is important to be aware that environment variables such as C_INCLUDE_PATH, GCC_EXEC_PREFIX, BINUTILS_ROOT or GCC_ROOT will affect both compilers at the same time and thus may make one of the 2 compilers operate improperly if they are set for the other. In particular it is important that the link command has access to the proper gcc library `libgcc.a', that is to say the one that is part of the C++ compiler installation. The implicit link command as suggested in the gnatmake command from the former example can be replaced by an explicit link command with full verbosity in order to verify which library is used: $ gnatbind ada_unit $ gnatlink -v -v ada_unit file1.o file2.o --LINK=c++ If there is a problem due to interfering environment variables, it can be workaround by using an intermediate script. The following example shows the proper script to use when GNAT has not been installed at its default location and g++ has been installed at its default location: $ gnatlink -v -v ada_unit file1.o file2.o --LINK=./my_script $ cat ./my_script #!/bin/sh unset BINUTILS_ROOT unset GCC_ROOT c++ $* 3. Using a non GNU C++ compiler. The same set of command as previously described can be used to insure that the c++ linker is used. Nonetheless, you need to add the path to libgcc explicitely, since some libraries needed by GNAT are located in this directory: $ gnatlink ada_unit file1.o file2.o --LINK=./my_script $ cat ./my_script #!/bin/sh CC $* gcc -print-libgcc-file-name Where CC is the name of the non GNU C++ compiler. A Simple Example ---------------- The following example, provided as part of the GNAT examples, show how to achieve procedural interfacing between Ada and C++ in both directions. The C++ class A has 2 methods. The first method is exported to Ada by the means of an extern C wrapper function. The second method calls an Ada subprogram. On the Ada side, The C++ calls is modelized by a limited record with a layout comparable to the C++ class. The Ada subprogram, in turn, calls the c++ method. So from the C++ main program the code goes back and forth between the 2 languages. Here are the compilation commands for native configurations: $ gnatmake -c simple_cpp_interface $ c++ -c cpp_main.C $ c++ -c ex7.C $ gnatbind -n simple_cpp_interface $ gnatlink simple_cpp_interface -o cpp_main --LINK=$(CPLUSPLUS) -lstdc++ ex7.o cpp_main.o Here are the corresponding sources: //cpp_main.C #include "ex7.h" extern "C" { void adainit (void); void adafinal (void); void method1 (A *t); } void method1 (A *t) { t->method1 (); } int main () { A obj; adainit (); obj.method2 (3030); adafinal (); } //ex7.h class Origin { public: int o_value; }; class A : public Origin { public: void method1 (void); virtual void method2 (int v); A(); int a_value; }; //ex7.C #include "ex7.h" #include extern "C" { void ada_method2 (A *t, int v);} void A::method1 (void) { a_value = 2020; printf ("in A::method1, a_value = %d \n",a_value); } void A::method2 (int v) { ada_method2 (this, v); printf ("in A::method2, a_value = %d \n",a_value); } A::A(void) { a_value = 1010; printf ("in A::A, a_value = %d \n",a_value); } -- Ada sources package body Simple_Cpp_Interface is procedure Ada_Method2 (This : in out A; V : Integer) is begin Method1 (This); This.A_Value := V; end Ada_Method2; end Simple_Cpp_Interface; package Simple_Cpp_Interface is type A is limited record O_Value : Integer; A_Value : Integer; end record; pragma Convention (C, A); procedure Method1 (This : in out A); pragma Import (C, Method1); procedure Ada_Method2 (This : in out A; V : Integer); pragma Export (C, Ada_Method2); end Simple_Cpp_Interface; Adapting the Run Time to a New C++ Compiler ------------------------------------------- GNAT offers the capability to derive Ada 95 tagged types directly from preexisting C++ classes and . See "Interfacing with C++" in the GNAT reference manual. The mechanism used by GNAT for achieving such a goal has been made user configurable through a GNAT library unit `Interfaces.CPP'. The default version of this file is adapted to the GNU c++ compiler. Internal knowledge of the virtual table layout used by the new C++ compiler is needed to configure properly this unit. The Interface of this unit is known by the compiler and cannot be changed except for the value of the constants defining the characteristics of the virtual table: CPP_DT_Prologue_Size, CPP_DT_Entry_Size, CPP_TSD_Prologue_Size, CPP_TSD_Entry_Size. Read comments in the source of this unit for more details. Comparison between GNAT and C/C++ Compilation Models ==================================================== The GNAT model of compilation is close to the C and C++ models. You can think of Ada specs as corresponding to header files in C. As in C, you don't need to compile specs; they are compiled when they are used. The Ada `with' is similar in effect to the `#include' of a C header. One notable difference is that, in Ada, you may compile specs separately to check them for semantic and syntactic accuracy. This is not always possible with C headers because they are fragments of programs that have less specific syntactic or semantic rules. The other major difference is the requirement for running the binder, which performs two important functions. First, it checks for consistency. In C or C++, the only defense against assembling inconsistent programs lies outside the compiler, in a makefile, for example. The binder satisfies the Ada requirement that it be impossible to construct an inconsistent program when the compiler is used in normal mode. The other important function of the binder is to deal with elaboration issues. There are also elaboration issues in C++ that are handled automatically. This automatic handling has the advantage of being simpler to use, but the C++ programmer has no control over elaboration. Where `gnatbind' might complain there was no valid order of elaboration, a C++ compiler would simply construct a program that malfunctioned at run time. Comparison between GNAT and Conventional Ada Library Models =========================================================== This section is intended to be useful to Ada programmers who have previously used an Ada compiler implementing the traditional Ada library model, as described in the Ada 95 Language Reference Manual. If you have not used such a system, please go on to the next section. In GNAT, there is no "library" in the normal sense. Instead, the set of source files themselves acts as the library. Compiling Ada programs does not generate any centralized information, but rather an object file and a ALI file, which are of interest only to the binder and linker. In a traditional system, the compiler reads information not only from the source file being compiled, but also from the centralized library. This means that the effect of a compilation depends on what has been previously compiled. In particular: * When a unit is `with''ed, the unit seen by the compiler corresponds to the version of the unit most recently compiled into the library. * Inlining is effective only if the necessary body has already been compiled into the library. * Compiling a unit may obsolete other units in the library. In GNAT, compiling one unit never affects the compilation of any other units because the compiler reads only source files. Only changes to source files can affect the results of a compilation. In particular: * When a unit is `with''ed, the unit seen by the compiler corresponds to the source version of the unit that is currently accessible to the compiler. * Inlining requires the appropriate source files for the package or subprogram bodies to be available to the compiler. Inlining is always effective, independent of the order in which units are complied. * Compiling a unit never affects any other compilations. The editing of sources may cause previous compilations to be out of date if they depended on the source file being modified. The most important result of these differences is that order of compilation is never significant in GNAT. There is no situation in which one is required to do one compilation before another. What shows up as order of compilation requirements in the traditional Ada library becomes, in GNAT, simple source dependencies; in other words, there is only a set of rules saying what source files must be present when a file is compiled. Compiling Using `gcc' ********************* This chapter discusses how to compile Ada programs using the `gcc' command. It also describes the set of switches that can be used to control the behavior of the compiler. Compiling Programs ================== The first step in creating an executable program is to compile the units of the program using the `gcc' command. You must compile the following files: * the body file (`.adb') for a library level subprogram or generic subprogram * the spec file (`.ads') for a library level package or generic package that has no body * the body file (`.adb') for a library level package or generic package that has a body You need _not_ compile the following files * the spec of a library unit which has a body * subunits because they are compiled as part of compiling related units. GNAT package specs when the corresponding body is compiled, and subunits when the parent is compiled. If you attempt to compile any of these files, you will get one of the following error messages (where fff is the name of the file you compiled): No code generated for file FFF (PACKAGE SPEC) No code generated for file FFF (SUBUNIT) The basic command for compiling a file containing an Ada unit is $ gcc -c [SWITCHES] `file name' where FILE NAME is the name of the Ada file (usually having an extension `.ads' for a spec or `.adb' for a body). You specify the `-c' switch to tell `gcc' to compile, but not link, the file. The result of a successful compilation is an object file, which has the same name as the source file but an extension of `.o' and an Ada Library Information (ALI) file, which also has the same name as the source file, but with `.ali' as the extension. GNAT creates these two output files in the current directory, but you may specify a source file in any directory using an absolute or relative path specification containing the directory information. `gcc' is actually a driver program that looks at the extensions of the file arguments and loads the appropriate compiler. For example, the GNU C compiler is `cc1', and the Ada compiler is `gnat1'. These programs are in directories known to the driver program (in some configurations via environment variables you set), but need not be in your path. The `gcc' driver also calls the assembler and any other utilities needed to complete the generation of the required object files. It is possible to supply several file names on the same `gcc' command. This causes `gcc' to call the appropriate compiler for each file. For example, the following command lists three separate files to be compiled: $ gcc -c x.adb y.adb z.c calls `gnat1' (the Ada compiler) twice to compile `x.adb' and `y.adb', and `cc1' (the C compiler) once to compile `z.c'. The compiler generates three object files `x.o', `y.o' and `z.o' and the two ALI files `x.ali' and `y.ali' from the Ada compilations. Any switches apply to all the files listed, except for `-gnatX' switches, which apply only to Ada compilations. Switches for `gcc' ================== The `gcc' command accepts switches that control the compilation process. These switches are fully described in this section. First we briefly list all the switches, in alphabetical order, then we describe the switches in more detail in functionally grouped sections. `-b TARGET' Compile your program to run on TARGET, which is the name of a system configuration. You must have a GNAT cross-compiler built if TARGET is not the same as your host system. `-BDIR' Load compiler executables (for example, `gnat1', the Ada compiler) from DIR instead of the default location. Only use this switch when multiple versions of the GNAT compiler are available. See the `gcc' manual page for further details. You would normally use the `-b' or `-V' switch instead. `-c' Compile. Always use this switch when compiling Ada programs. Note: for some other languages when using `gcc', notably in the case of C and C++, it is possible to use use `gcc' without a `-c' switch to compile and link in one step. In the case of GNAT, you cannot use this approach, because the binder must be run and `gcc' cannot be used to run the GNAT binder. `-g' Generate debugging information. This information is stored in the object file and copied from there to the final executable file by the linker, where it can be read by the debugger. You must use the `-g' switch if you plan on using the debugger. `-IDIR' Direct GNAT to search the DIR directory for source files needed by the current compilation (*note Search Paths and the Run-Time Library (RTL)::). `-I-' Except for the source file named in the command line, do not look for source files in the directory containing the source file named in the command line (*note Search Paths and the Run-Time Library (RTL)::). `-o FILE' This switch is used in `gcc' to redirect the generated object file and its associated ALI file. Beware of this switch with GNAT, because it may cause the object file and ALI file to have different names which in turn may confuse the binder and the linker. `-O[N]' N controls the optimization level. n = 0 No optimization, the default setting if no `-O' appears n = 1 Normal optimization, the default if you specify `-O' without an operand. n = 2 Extensive optimization n = 3 Extensive optimization with automatic inlining. This applies only to inlining within a unit. For details on control of inter-unit inlining see *Note Subprogram Inlining Control::. `--RTS=RTS-PATH' Specifies the default location of the runtime library. Same meaning as the equivalent `gnatmake' flag (see *Note Switches for gnatmake::). `-S' Used in place of `-c' to cause the assembler source file to be generated, using `.s' as the extension, instead of the object file. This may be useful if you need to examine the generated assembly code. `-v' Show commands generated by the `gcc' driver. Normally used only for debugging purposes or if you need to be sure what version of the compiler you are executing. `-V VER' Execute VER version of the compiler. This is the `gcc' version, not the GNAT version. `-gnata' Assertions enabled. `Pragma Assert' and `pragma Debug' to be activated. `-gnatA' Avoid processing `gnat.adc'. If a gnat.adc file is present, it will be ignored. `-gnatb' Generate brief messages to `stderr' even if verbose mode set. `-gnatc' Check syntax and semantics only (no code generation attempted). `-gnatC' Compress debug information and external symbol name table entries. `-gnatD' Output expanded source files for source level debugging. This switch also suppress generation of cross-reference information (see -gnatx). `-gnatecPATH' Specify a configuration pragma file. (see *Note The Configuration Pragmas Files::) `-gnatemPATH' Specify a mapping file. (see *Note Units to Sources Mapping Files::) `-gnatE' Full dynamic elaboration checks. `-gnatf' Full errors. Multiple errors per line, all undefined references. `-gnatF' Externals names are folded to all uppercase. `-gnatg' Internal GNAT implementation mode. This should not be used for applications programs, it is intended only for use by the compiler and its run-time library. For documentation, see the GNAT sources. `-gnatG' List generated expanded code in source form. `-gnatiC' Identifier character set (C=1/2/3/4/8/9/p/f/n/w). `-gnath' Output usage information. The output is written to `stdout'. `-gnatkN' Limit file names to N (1-999) characters (`k' = krunch). `-gnatl' Output full source listing with embedded error messages. `-gnatmN' Limit number of detected errors to N (1-999). `-gnatn' Activate inlining across unit boundaries for subprograms for which pragma `inline' is specified. `-gnatN' Activate front end inlining. `-fno-inline' Suppresses all inlining, even if other optimization or inlining switches are set. `-fstack-check' Activates stack checking. See separate section on stack checking for details of the use of this option. `-gnato' Enable numeric overflow checking (which is not normally enabled by default). Not that division by zero is a separate check that is not controlled by this switch (division by zero checking is on by default). `-gnatp' Suppress all checks. `-gnatq' Don't quit; try semantics, even if parse errors. `-gnatQ' Don't quit; generate `ali' and tree files even if illegalities. `-gnatP' Enable polling. This is required on some systems (notably Windows NT) to obtain asynchronous abort and asynchronous transfer of control capability. See the description of pragma Polling in the GNAT Reference Manual for full details. `-gnatR[0/1/2/3][s]' Output representation information for declared types and objects. `-gnats' Syntax check only. `-gnatt' Tree output file to be generated. `-gnatT nnn' Set time slice to specified number of microseconds `-gnatu' List units for this compilation. `-gnatU' Tag all error messages with the unique string "error:" `-gnatv' Verbose mode. Full error output with source lines to `stdout'. `-gnatV' Control level of validity checking. See separate section describing this feature. `-gnatwxxxXXX' Warning mode where XXX is a string of options describing the exact warnings that are enabled or disabled. See separate section on warning control. `-gnatWE' Wide character encoding method (E=n/h/u/s/e/8). `-gnatx' Suppress generation of cross-reference information. `-gnaty' Enable built-in style checks. See separate section describing this feature. `-gnatzM' Distribution stub generation and compilation (M=r/c for receiver/caller stubs). `-gnat83' Enforce Ada 83 restrictions. `-pass-exit-codes' Catch exit codes from the compiler and use the most meaningful as exit status. You may combine a sequence of GNAT switches into a single switch. For example, the combined switch -gnatofi3 is equivalent to specifying the following sequence of switches: -gnato -gnatf -gnati3 The following restrictions apply to the combination of switches in this manner: * The switch `-gnatc' if combined with other switches must come first in the string. * The switch `-gnats' if combined with other switches must come first in the string. * Once a "y" appears in the string (that is a use of the `-gnaty' switch), then all further characters in the switch are interpreted as style modifiers (see description of `-gnaty'). * Once a "d" appears in the string (that is a use of the `-gnatd' switch), then all further characters in the switch are interpreted as debug flags (see description of `-gnatd'). * Once a "w" appears in the string (that is a use of the `-gnatw' switch), then all further characters in the switch are interpreted as warning mode modifiers (see description of `-gnatw'). * Once a "V" appears in the string (that is a use of the `-gnatV' switch), then all further characters in the switch are interpreted as validity checking options (see description of `-gnatV'). Output and Error Message Control -------------------------------- The standard default format for error messages is called "brief format." Brief format messages are written to `stderr' (the standard error file) and have the following form: e.adb:3:04: Incorrect spelling of keyword "function" e.adb:4:20: ";" should be "is" The first integer after the file name is the line number in the file, and the second integer is the column number within the line. `glide' can parse the error messages and point to the referenced character. The following switches provide control over the error message format: `-gnatv' The v stands for verbose. The effect of this setting is to write long-format error messages to `stdout' (the standard output file. The same program compiled with the `-gnatv' switch would generate: 3. funcion X (Q : Integer) | >>> Incorrect spelling of keyword "function" 4. return Integer; | >>> ";" should be "is" The vertical bar indicates the location of the error, and the `>>>' prefix can be used to search for error messages. When this switch is used the only source lines output are those with errors. `-gnatl' The `l' stands for list. This switch causes a full listing of the file to be generated. The output might look as follows: 1. procedure E is 2. V : Integer; 3. funcion X (Q : Integer) | >>> Incorrect spelling of keyword "function" 4. return Integer; | >>> ";" should be "is" 5. begin 6. return Q + Q; 7. end; 8. begin 9. V := X + X; 10.end E; When you specify the `-gnatv' or `-gnatl' switches and standard output is redirected, a brief summary is written to `stderr' (standard error) giving the number of error messages and warning messages generated. `-gnatU' This switch forces all error messages to be preceded by the unique string "error:". This means that error messages take a few more characters in space, but allows easy searching for and identification of error messages. `-gnatb' The `b' stands for brief. This switch causes GNAT to generate the brief format error messages to `stderr' (the standard error file) as well as the verbose format message or full listing (which as usual is written to `stdout' (the standard output file). `-gnatmN' The `m' stands for maximum. N is a decimal integer in the range of 1 to 999 and limits the number of error messages to be generated. For example, using `-gnatm2' might yield e.adb:3:04: Incorrect spelling of keyword "function" e.adb:5:35: missing ".." fatal error: maximum errors reached compilation abandoned `-gnatf' The `f' stands for full. Normally, the compiler suppresses error messages that are likely to be redundant. This switch causes all error messages to be generated. In particular, in the case of references to undefined variables. If a given variable is referenced several times, the normal format of messages is e.adb:7:07: "V" is undefined (more references follow) where the parenthetical comment warns that there are additional references to the variable `V'. Compiling the same program with the `-gnatf' switch yields e.adb:7:07: "V" is undefined e.adb:8:07: "V" is undefined e.adb:8:12: "V" is undefined e.adb:8:16: "V" is undefined e.adb:9:07: "V" is undefined e.adb:9:12: "V" is undefined `-gnatq' The `q' stands for quit (really "don't quit"). In normal operation mode, the compiler first parses the program and determines if there are any syntax errors. If there are, appropriate error messages are generated and compilation is immediately terminated. This switch tells GNAT to continue with semantic analysis even if syntax errors have been found. This may enable the detection of more errors in a single run. On the other hand, the semantic analyzer is more likely to encounter some internal fatal error when given a syntactically invalid tree. `-gnatQ' In normal operation mode, the `ali' file is not generated if any illegalities are detected in the program. The use of `-gnatQ' forces generation of the `ali' file. This file is marked as being in error, so it cannot be used for binding purposes, but it does contain reasonably complete cross-reference information, and thus may be useful for use by tools (e.g. semantic browsing tools or integrated development environments) that are driven from the `ali' file. In addition, if `-gnatt' is also specified, then the tree file is generated even if there are illegalities. It may be useful in this case to also specify `-gnatq' to ensure that full semantic processing occurs. The resulting tree file can be processed by ASIS, for the purpose of providing partial information about illegal units, but if the error causes the tree to be badly malformed, then ASIS may crash during the analysis. In addition to error messages, which correspond to illegalities as defined in the Ada 95 Reference Manual, the compiler detects two kinds of warning situations. First, the compiler considers some constructs suspicious and generates a warning message to alert you to a possible error. Second, if the compiler detects a situation that is sure to raise an exception at run time, it generates a warning message. The following shows an example of warning messages: e.adb:4:24: warning: creation of object may raise Storage_Error e.adb:10:17: warning: static value out of range e.adb:10:17: warning: "Constraint_Error" will be raised at run time GNAT considers a large number of situations as appropriate for the generation of warning messages. As always, warnings are not definite indications of errors. For example, if you do an out-of-range assignment with the deliberate intention of raising a `Constraint_Error' exception, then the warning that may be issued does not indicate an error. Some of the situations for which GNAT issues warnings (at least some of the time) are given in the following list, which is not necessarily complete. * Possible infinitely recursive calls * Out-of-range values being assigned * Possible order of elaboration problems * Unreachable code * Fixed-point type declarations with a null range * Variables that are never assigned a value * Variables that are referenced before being initialized * Task entries with no corresponding accept statement * Duplicate accepts for the same task entry in a select * Objects that take too much storage * Unchecked conversion between types of differing sizes * Missing return statements along some execution paths in a function * Incorrect (unrecognized) pragmas * Incorrect external names * Allocation from empty storage pool * Potentially blocking operations in protected types * Suspicious parenthesization of expressions * Mismatching bounds in an aggregate * Attempt to return local value by reference * Unrecognized pragmas * Premature instantiation of a generic body * Attempt to pack aliased components * Out of bounds array subscripts * Wrong length on string assignment * Violations of style rules if style checking is enabled * Unused with clauses * Bit_Order usage that does not have any effect * Compile time biased rounding of floating-point constant * Standard.Duration used to resolve universal fixed expression * Dereference of possibly null value * Declaration that is likely to cause storage error * Internal GNAT unit with'ed by application unit * Values known to be out of range at compile time * Unreferenced labels and variables * Address overlays that could clobber memory * Unexpected initialization when address clause present * Bad alignment for address clause * Useless type conversions * Redundant assignment statements * Accidental hiding of name by child unit * Unreachable code * Access before elaboration detected at compile time * A range in a `for' loop that is known to be null or might be null The following switches are available to control the handling of warning messages: `-gnatwa (activate all optional errors)' This switch activates most optional warning messages, see remaining list in this section for details on optional warning messages that can be individually controlled. `-gnatwA (suppress all optional errors)' This switch suppresses all optional warning messages, see remaining list in this section for details on optional warning messages that can be individually controlled. `-gnatwb (activate warnings on biased rounding)' If a static floating-point expression has a value that is exactly half way between two adjacent machine numbers, then the rules of Ada (Ada Reference Manual, section 4.9(38)) require that this rounding be done away from zero, even if the normal unbiased rounding rules at run time would require rounding towards zero. This warning message alerts you to such instances where compile-time rounding and run-time rounding are not equivalent. If it is important to get proper run-time rounding, then you can force this by making one of the operands into a variable. The default is that such warnings are not generated. Note that `-gnatwa' does not affect the setting of this warning option. `-gnatwB (suppress warnings on biased rounding)' This switch disables warnings on biased rounding. `-gnatwc (activate warnings on conditionals)' This switch activates warnings for conditional expressions used in tests that are known to be True or False at compile time. The default is that such warnings are not generated. This warning can also be turned on using `-gnatwa'. `-gnatwC (suppress warnings on conditionals)' This switch suppresses warnings for conditional expressions used in tests that are known to be True or False at compile time. `-gnatwe (treat warnings as errors)' This switch causes warning messages to be treated as errors. The warning string still appears, but the warning messages are counted as errors, and prevent the generation of an object file. `-gnatwf (activate warnings on unreferenced formals)' This switch causes a warning to be generated if a formal parameter is not referenced in the body of the subprogram. This warning can also be turned on using `-gnatwa' or `-gnatwu'. `-gnatwF (suppress warnings on unreferenced formals)' This switch suppresses warnings for unreferenced formal parameters. Note that the combination `-gnatwu' followed by `-gnatwF' has the effect of warning on unreferenced entities other than subprogram formals. `-gnatwh (activate warnings on hiding)' This switch activates warnings on hiding declarations. A declaration is considered hiding if it is for a non-overloadable entity, and it declares an entity with the same name as some other entity that is directly or use-visible. The default is that such warnings are not generated. Note that `-gnatwa' does not affect the setting of this warning option. `-gnatwH (suppress warnings on hiding)' This switch suppresses warnings on hiding declarations. `-gnatwi (activate warnings on implementation units).' This switch activates warnings for a `with' of an internal GNAT implementation unit, defined as any unit from the `Ada', `Interfaces', `GNAT', or `System' hierarchies that is not documented in either the Ada Reference Manual or the GNAT Programmer's Reference Manual. Such units are intended only for internal implementation purposes and should not be `with''ed by user programs. The default is that such warnings are generated This warning can also be turned on using `-gnatwa'. `-gnatwI (disable warnings on implementation units).' This switch disables warnings for a `with' of an internal GNAT implementation unit. `-gnatwl (activate warnings on elaboration pragmas)' This switch activates warnings on missing pragma Elaborate_All statements. See the section in this guide on elaboration checking for details on when such pragma should be used. The default is that such warnings are not generated. This warning can also be turned on using `-gnatwa'. `-gnatwL (suppress warnings on elaboration pragmas)' This switch suppresses warnings on missing pragma Elaborate_All statements. See the section in this guide on elaboration checking for details on when such pragma should be used. `-gnatwo (activate warnings on address clause overlays)' This switch activates warnings for possibly unintended initialization effects of defining address clauses that cause one variable to overlap another. The default is that such warnings are generated. This warning can also be turned on using `-gnatwa'. `-gnatwO (suppress warnings on address clause overlays)' This switch suppresses warnings on possibly unintended initialization effects of defining address clauses that cause one variable to overlap another. `-gnatwp (activate warnings on ineffective pragma Inlines)' This switch activates warnings for failure of front end inlining (activated by `-gnatN') to inline a particular call. There are many reasons for not being able to inline a call, including most commonly that the call is too complex to inline. This warning can also be turned on using `-gnatwa'. `-gnatwP (suppress warnings on ineffective pragma Inlines)' This switch suppresses warnings on ineffective pragma Inlines. If the inlining mechanism cannot inline a call, it will simply ignore the request silently. `-gnatwr (activate warnings on redundant constructs)' This switch activates warnings for redundant constructs. The following is the current list of constructs regarded as redundant: This warning can also be turned on using `-gnatwa'. * Assignment of an item to itself. * Type conversion that converts an expression to its own type. * Use of the attribute `Base' where `typ'Base' is the same as `typ'. * Use of pragma `Pack' when all components are placed by a record representation clause. `-gnatwR (suppress warnings on redundant constructs)' This switch suppresses warnings for redundant constructs. `-gnatws (suppress all warnings)' This switch completely suppresses the output of all warning messages from the GNAT front end. Note that it does not suppress warnings from the `gcc' back end. To suppress these back end warnings as well, use the switch `-w' in addition to `-gnatws'. `-gnatwu (activate warnings on unused entities)' This switch activates warnings to be generated for entities that are defined but not referenced, and for units that are `with''ed and not referenced. In the case of packages, a warning is also generated if no entities in the package are referenced. This means that if the package is referenced but the only references are in `use' clauses or `renames' declarations, a warning is still generated. A warning is also generated for a generic package that is `with''ed but never instantiated. In the case where a package or subprogram body is compiled, and there is a `with' on the corresponding spec that is only referenced in the body, a warning is also generated, noting that the `with' can be moved to the body. The default is that such warnings are not generated. This switch also activates warnings on unreferenced formals (it is includes the effect of `-gnatwf'). This warning can also be turned on using `-gnatwa'. `-gnatwU (suppress warnings on unused entities)' This switch suppresses warnings for unused entities and packages. It also turns off warnings on unreferenced formals (and thus includes the effect of `-gnatwF'). A string of warning parameters can be used in the same parameter. For example: -gnatwaLe Would turn on all optional warnings except for elaboration pragma warnings, and also specify that warnings should be treated as errors. `-w' This switch suppresses warnings from the `gcc' backend. It may be used in conjunction with `-gnatws' to ensure that all warnings are suppressed during the entire compilation process. Debugging and Assertion Control ------------------------------- `-gnata' The pragmas `Assert' and `Debug' normally have no effect and are ignored. This switch, where `a' stands for assert, causes `Assert' and `Debug' pragmas to be activated. The pragmas have the form: pragma Assert (BOOLEAN-EXPRESSION [, STATIC-STRING-EXPRESSION]) pragma Debug (PROCEDURE CALL) The `Assert' pragma causes BOOLEAN-EXPRESSION to be tested. If the result is `True', the pragma has no effect (other than possible side effects from evaluating the expression). If the result is `False', the exception `Assert_Failure' declared in the package `System.Assertions' is raised (passing STATIC-STRING-EXPRESSION, if present, as the message associated with the exception). If no string expression is given the default is a string giving the file name and line number of the pragma. The `Debug' pragma causes PROCEDURE to be called. Note that `pragma Debug' may appear within a declaration sequence, allowing debugging procedures to be called between declarations. Validity Checking ----------------- The Ada 95 Reference Manual has specific requirements for checking for invalid values. In particular, RM 13.9.1 requires that the evaluation of invalid values (for example from unchecked conversions), not result in erroneous execution. In GNAT, the result of such an evaluation in normal default mode is to either use the value unmodified, or to raise Constraint_Error in those cases where use of the unmodified value would cause erroneous execution. The cases where unmodified values might lead to erroneous execution are case statements (where a wild jump might result from an invalid value), and subscripts on the left hand side (where memory corruption could occur as a result of an invalid value). The `-gnatVx' switch allows more control over the validity checking mode. The `x' argument here is a string of letters which control which validity checks are performed in addition to the default checks described above. * `-gnatVc' Validity checks for copies The right hand side of assignments, and the initializing values of object declarations are validity checked. * `-gnatVd' Default (RM) validity checks Some validity checks are done by default following normal Ada semantics (RM 13.9.1 (9-11)). A check is done in case statements that the expression is within the range of the subtype. If it is not, Constraint_Error is raised. For assignments to array components, a check is done that the expression used as index is within the range. If it is not, Constraint_Error is raised. Both these validity checks may be turned off using switch `-gnatVD'. They are turned on by default. If `-gnatVD' is specified, a subsequent switch `-gnatVd' will leave the checks turned on. Switch `-gnatVD' should be used only if you are sure that all such expressions have valid values. If you use this switch and invalid values are present, then the program is erroneous, and wild jumps or memory overwriting may occur. * `-gnatVi' Validity checks for `in' mode parameters Arguments for parameters of mode `in' are validity checked in function and procedure calls at the point of call. * `-gnatVm' Validity checks for `in out' mode parameters Arguments for parameters of mode `in out' are validity checked in procedure calls at the point of call. The `'m'' here stands for modify, since this concerns parameters that can be modified by the call. Note that there is no specific option to test `out' parameters, but any reference within the subprogram will be tested in the usual manner, and if an invalid value is copied back, any reference to it will be subject to validity checking. * `-gnatVo' Validity checks for operator and attribute operands Arguments for predefined operators and attributes are validity checked. This includes all operators in package `Standard', the shift operators defined as intrinsic in package `Interfaces' and operands for attributes such as `Pos'. * `-gnatVr' Validity checks for function returns The expression in `return' statements in functions is validity checked. * `-gnatVs' Validity checks for subscripts All subscripts expressions are checked for validity, whether they appear on the right side or left side (in default mode only left side subscripts are validity checked). * `-gnatVt' Validity checks for tests Expressions used as conditions in `if', `while' or `exit' statements are checked, as well as guard expressions in entry calls. * `-gnatVf' Validity checks for floating-point values In the absence of this switch, validity checking occurs only for discrete values. If `-gnatVf' is specified, then validity checking also applies for floating-point values, and NaN's and infinities are considered invalid, as well as out of range values for constrained types. Note that this means that standard `IEEE' infinity mode is not allowed. The exact contexts in which floating-point values are checked depends on the setting of other options. For example `-gnatVif' or `-gnatVfi' (the order does not matter) specifies that floating-point parameters of mode `in' should be validity checked. * `-gnatVa' All validity checks All the above validity checks are turned on. That is `-gnatVa' is equivalent to `gnatVcdfimorst'. * `-gnatVn' No validity checks This switch turns off all validity checking, including the default checking for case statements and left hand side subscripts. The `-gnatV' switch may be followed by a string of letters to turn on a series of validity checking options. For example, `-gnatVcr' specifies that in addition to the default validity checking, copies and function return expressions be validity checked. In order to make it easier to specify a set of options, the upper case letters `CDFIMORST' may be used to turn off the corresponding lower case option, so for example `-gnatVaM' turns on all validity checking options except for checking of `in out' procedure arguments. The specification of additional validity checking generates extra code (and in the case of `-gnatva' the code expansion can be substantial. However, these additional checks can be very useful in smoking out cases of uninitialized variables, incorrect use of unchecked conversion, and other errors leading to invalid values. The use of pragma `Initialize_Scalars' is useful in conjunction with the extra validity checking, since this ensures that wherever possible uninitialized variables have invalid values. See also the pragma `Validity_Checks' which allows modification of the validity checking mode at the program source level, and also allows for temporary disabling of validity checks. Style Checking -------------- The -gnatyX switch causes the compiler to enforce specified style rules. A limited set of style rules has been used in writing the GNAT sources themselves. This switch allows user programs to activate all or some of these checks. If the source program fails a specified style check, an appropriate warning message is given, preceded by the character sequence "(style)". The string X is a sequence of letters or digits indicating the particular style checks to be performed. The following checks are defined: `1-9 (specify indentation level)' If a digit from 1-9 appears in the string after `-gnaty' then proper indentation is checked, with the digit indicating the indentation level required. The general style of required indentation is as specified by the examples in the Ada Reference Manual. Full line comments must be aligned with the `--' starting on a column that is a multiple of the alignment level. `a (check attribute casing)' If the letter a appears in the string after `-gnaty' then attribute names, including the case of keywords such as `digits' used as attributes names, must be written in mixed case, that is, the initial letter and any letter following an underscore must be uppercase. All other letters must be lowercase. `b (blanks not allowed at statement end)' If the letter b appears in the string after `-gnaty' then trailing blanks are not allowed at the end of statements. The purpose of this rule, together with h (no horizontal tabs), is to enforce a canonical format for the use of blanks to separate source tokens. `c (check comments)' If the letter c appears in the string after `-gnaty' then comments must meet the following set of rules: * The "-" that starts the column must either start in column one, or else at least one blank must precede this sequence. * Comments that follow other tokens on a line must have at least one blank following the "-" at the start of the comment. * Full line comments must have two blanks following the "-" that starts the comment, with the following exceptions. * A line consisting only of the "-" characters, possibly preceded by blanks is permitted. * A comment starting with "-x" where x is a special character is permitted. This alows proper processing of the output generated by specialized tools including `gnatprep' (where -! is used) and the SPARK annnotation language (where -# is used). For the purposes of this rule, a special character is defined as being in one of the ASCII ranges 16#21#..16#2F# or 16#3A#..16#3F#. * A line consisting entirely of minus signs, possibly preceded by blanks, is permitted. This allows the construction of box comments where lines of minus signs are used to form the top and bottom of the box. * If a comment starts and ends with "-" is permitted as long as at least one blank follows the initial "-". Together with the preceding rule, this allows the construction of box comments, as shown in the following example: --------------------------- -- This is a box comment -- -- with two text lines. -- --------------------------- `e (check end/exit labels)' If the letter e appears in the string after `-gnaty' then optional labels on `end' statements ending subprograms and on `exit' statements exiting named loops, are required to be present. `f (no form feeds or vertical tabs)' If the letter f appears in the string after `-gnaty' then neither form feeds nor vertical tab characters are not permitted in the source text. `h (no horizontal tabs)' If the letter h appears in the string after `-gnaty' then horizontal tab characters are not permitted in the source text. Together with the b (no blanks at end of line) check, this enforces a canonical form for the use of blanks to separate source tokens. `i (check if-then layout)' If the letter i appears in the string after `-gnaty', then the keyword `then' must appear either on the same line as corresponding `if', or on a line on its own, lined up under the `if' with at least one non-blank line in between containing all or part of the condition to be tested. `k (check keyword casing)' If the letter k appears in the string after `-gnaty' then all keywords must be in lower case (with the exception of keywords such as `digits' used as attribute names to which this check does not apply). `l (check layout)' If the letter l appears in the string after `-gnaty' then layout of statement and declaration constructs must follow the recommendations in the Ada Reference Manual, as indicated by the form of the syntax rules. For example an `else' keyword must be lined up with the corresponding `if' keyword. There are two respects in which the style rule enforced by this check option are more liberal than those in the Ada Reference Manual. First in the case of record declarations, it is permissible to put the `record' keyword on the same line as the `type' keyword, and then the `end' in `end record' must line up under `type'. For example, either of the following two layouts is acceptable: type q is record a : integer; b : integer; end record; type q is record a : integer; b : integer; end record; Second, in the case of a block statement, a permitted alternative is to put the block label on the same line as the `declare' or `begin' keyword, and then line the `end' keyword up under the block label. For example both the following are permitted: Block : declare A : Integer := 3; begin Proc (A, A); end Block; Block : declare A : Integer := 3; begin Proc (A, A); end Block; The same alternative format is allowed for loops. For example, both of the following are permitted: Clear : while J < 10 loop A (J) := 0; end loop Clear; Clear : while J < 10 loop A (J) := 0; end loop Clear; `m (check maximum line length)' If the letter m appears in the string after `-gnaty' then the length of source lines must not exceed 79 characters, including any trailing blanks. The value of 79 allows convenient display on an 80 character wide device or window, allowing for possible special treatment of 80 character lines. `Mnnn (set maximum line length)' If the sequence Mnnn, where nnn is a decimal number, appears in the string after `-gnaty' then the length of lines must not exceed the given value. `n (check casing of entities in Standard)' If the letter n appears in the string after `-gnaty' then any identifier from Standard must be cased to match the presentation in the Ada Reference Manual (for example, `Integer' and `ASCII.NUL'). `o (check order of subprogram bodies)' If the letter o appears in the string after `-gnaty' then all subprogram bodies in a given scope (e.g. a package body) must be in alphabetical order. The ordering rule uses normal Ada rules for comparing strings, ignoring casing of letters, except that if there is a trailing numeric suffix, then the value of this suffix is used in the ordering (e.g. Junk2 comes before Junk10). `p (check pragma casing)' If the letter p appears in the string after `-gnaty' then pragma names must be written in mixed case, that is, the initial letter and any letter following an underscore must be uppercase. All other letters must be lowercase. `r (check references)' If the letter r appears in the string after `-gnaty' then all identifier references must be cased in the same way as the corresponding declaration. No specific casing style is imposed on identifiers. The only requirement is for consistency of references with declarations. `s (check separate specs)' If the letter s appears in the string after `-gnaty' then separate declarations ("specs") are required for subprograms (a body is not allowed to serve as its own declaration). The only exception is that parameterless library level procedures are not required to have a separate declaration. This exception covers the most frequent form of main program procedures. `t (check token spacing)' If the letter t appears in the string after `-gnaty' then the following token spacing rules are enforced: * The keywords `abs' and `not' must be followed by a space. * The token `=>' must be surrounded by spaces. * The token `<>' must be preceded by a space or a left parenthesis. * Binary operators other than `**' must be surrounded by spaces. There is no restriction on the layout of the `**' binary operator. * Colon must be surrounded by spaces. * Colon-equal (assignment) must be surrounded by spaces. * Comma must be the first non-blank character on the line, or be immediately preceded by a non-blank character, and must be followed by a space. * If the token preceding a left paren ends with a letter or digit, then a space must separate the two tokens. * A right parenthesis must either be the first non-blank character on a line, or it must be preceded by a non-blank character. * A semicolon must not be preceded by a space, and must not be followed by a non-blank character. * A unary plus or minus may not be followed by a space. * A vertical bar must be surrounded by spaces. In the above rules, appearing in column one is always permitted, that is, counts as meeting either a requirement for a required preceding space, or as meeting a requirement for no preceding space. Appearing at the end of a line is also always permitted, that is, counts as meeting either a requirement for a following space, or as meeting a requirement for no following space. If any of these style rules is violated, a message is generated giving details on the violation. The initial characters of such messages are always "(style)". Note that these messages are treated as warning messages, so they normally do not prevent the generation of an object file. The `-gnatwe' switch can be used to treat warning messages, including style messages, as fatal errors. The switch `-gnaty' on its own (that is not followed by any letters or digits), is equivalent to `gnaty3abcefhiklmprst', that is all checking options are enabled with the exception of -gnatyo, with an indentation level of 3. This is the standard checking option that is used for the GNAT sources. Run-Time Checks --------------- If you compile with the default options, GNAT will insert many run-time checks into the compiled code, including code that performs range checking against constraints, but not arithmetic overflow checking for integer operations (including division by zero) or checks for access before elaboration on subprogram calls. All other run-time checks, as required by the Ada 95 Reference Manual, are generated by default. The following `gcc' switches refine this default behavior: `-gnatp' Suppress all run-time checks as though `pragma Suppress (all_checks') had been present in the source. Use this switch to improve the performance of the code at the expense of safety in the presence of invalid data or program bugs. `-gnato' Enables overflow checking for integer operations. This causes GNAT to generate slower and larger executable programs by adding code to check for overflow (resulting in raising `Constraint_Error' as required by standard Ada semantics). These overflow checks correspond to situations in which the true value of the result of an operation may be outside the base range of the result type. The following example shows the distinction: X1 : Integer := Integer'Last; X2 : Integer range 1 .. 5 := 5; ... X1 := X1 + 1; -- `-gnato' required to catch the Constraint_Error X2 := X2 + 1; -- range check, `-gnato' has no effect here Here the first addition results in a value that is outside the base range of Integer, and hence requires an overflow check for detection of the constraint error. The second increment operation results in a violation of the explicit range constraint, and such range checks are always performed. Basically the compiler can assume that in the absence of the `-gnato' switch that any value of type `xxx' is in range of the base type of `xxx'. Note that the `-gnato' switch does not affect the code generated for any floating-point operations; it applies only to integer semantics). For floating-point, GNAT has the `Machine_Overflows' attribute set to `False' and the normal mode of operation is to generate IEEE NaN and infinite values on overflow or invalid operations (such as dividing 0.0 by 0.0). The reason that we distinguish overflow checking from other kinds of range constraint checking is that a failure of an overflow check can generate an incorrect value, but cannot cause erroneous behavior. This is unlike the situation with a constraint check on an array subscript, where failure to perform the check can result in random memory description, or the range check on a case statement, where failure to perform the check can cause a wild jump. Note again that `-gnato' is off by default, so overflow checking is not performed in default mode. This means that out of the box, with the default settings, GNAT does not do all the checks expected from the language description in the Ada Reference Manual. If you want all constraint checks to be performed, as described in this Manual, then you must explicitly use the -gnato switch either on the `gnatmake' or `gcc' command. `-gnatE' Enables dynamic checks for access-before-elaboration on subprogram calls and generic instantiations. For full details of the effect and use of this switch, *Note Compiling Using gcc::. The setting of these switches only controls the default setting of the checks. You may modify them using either `Suppress' (to remove checks) or `Unsuppress' (to add back suppressed checks) pragmas in the program source. Stack Overflow Checking ----------------------- For most operating systems, `gcc' does not perform stack overflow checking by default. This means that if the main environment task or some other task exceeds the available stack space, then unpredictable behavior will occur. To activate stack checking, compile all units with the gcc option `-fstack-check'. For example: gcc -c -fstack-check package1.adb Units compiled with this option will generate extra instructions to check that any use of the stack (for procedure calls or for declaring local variables in declare blocks) do not exceed the available stack space. If the space is exceeded, then a `Storage_Error' exception is raised. For declared tasks, the stack size is always controlled by the size given in an applicable `Storage_Size' pragma (or is set to the default size if no pragma is used. For the environment task, the stack size depends on system defaults and is unknown to the compiler. The stack may even dynamically grow on some systems, precluding the normal Ada semantics for stack overflow. In the worst case, unbounded stack usage, causes unbounded stack expansion resulting in the system running out of virtual memory. The stack checking may still work correctly if a fixed size stack is allocated, but this cannot be guaranteed. To ensure that a clean exception is signalled for stack overflow, set the environment variable `GNAT_STACK_LIMIT' to indicate the maximum stack area that can be used, as in: SET GNAT_STACK_LIMIT 1600 The limit is given in kilobytes, so the above declaration would set the stack limit of the environment task to 1.6 megabytes. Note that the only purpose of this usage is to limit the amount of stack used by the environment task. If it is necessary to increase the amount of stack for the environment task, then this is an operating systems issue, and must be addressed with the appropriate operating systems commands. Run-Time Control ---------------- `-gnatT nnn' The `gnatT' switch can be used to specify the time-slicing value to be used for task switching between equal priority tasks. The value `nnn' is given in microseconds as a decimal integer. Setting the time-slicing value is only effective if the underlying thread control system can accommodate time slicing. Check the documentation of your operating system for details. Note that the time-slicing value can also be set by use of pragma `Time_Slice' or by use of the `t' switch in the gnatbind step. The pragma overrides a command line argument if both are present, and the `t' switch for gnatbind overrides both the pragma and the `gcc' command line switch. Using `gcc' for Syntax Checking ------------------------------- `-gnats' The `s' stands for syntax. Run GNAT in syntax checking only mode. For example, the command $ gcc -c -gnats x.adb compiles file `x.adb' in syntax-check-only mode. You can check a series of files in a single command , and can use wild cards to specify such a group of files. Note that you must specify the `-c' (compile only) flag in addition to the `-gnats' flag. . You may use other switches in conjunction with `-gnats'. In particular, `-gnatl' and `-gnatv' are useful to control the format of any generated error messages. The output is simply the error messages, if any. No object file or ALI file is generated by a syntax-only compilation. Also, no units other than the one specified are accessed. For example, if a unit `X' `with''s a unit `Y', compiling unit `X' in syntax check only mode does not access the source file containing unit `Y'. Normally, GNAT allows only a single unit in a source file. However, this restriction does not apply in syntax-check-only mode, and it is possible to check a file containing multiple compilation units concatenated together. This is primarily used by the `gnatchop' utility (*note Renaming Files Using gnatchop::). Using `gcc' for Semantic Checking --------------------------------- `-gnatc' The `c' stands for check. Causes the compiler to operate in semantic check mode, with full checking for all illegalities specified in the Ada 95 Reference Manual, but without generation of any object code (no object file is generated). Because dependent files must be accessed, you must follow the GNAT semantic restrictions on file structuring to operate in this mode: * The needed source files must be accessible (*note Search Paths and the Run-Time Library (RTL)::). * Each file must contain only one compilation unit. * The file name and unit name must match (*note File Naming Rules::). The output consists of error messages as appropriate. No object file is generated. An `ALI' file is generated for use in the context of cross-reference tools, but this file is marked as not being suitable for binding (since no object file is generated). The checking corresponds exactly to the notion of legality in the Ada 95 Reference Manual. Any unit can be compiled in semantics-checking-only mode, including units that would not normally be compiled (subunits, and specifications where a separate body is present). Compiling Ada 83 Programs ------------------------- `-gnat83' Although GNAT is primarily an Ada 95 compiler, it accepts this switch to specify that an Ada 83 program is to be compiled in Ada83 mode. If you specify this switch, GNAT rejects most Ada 95 extensions and applies Ada 83 semantics where this can be done easily. It is not possible to guarantee this switch does a perfect job; for example, some subtle tests, such as are found in earlier ACVC tests (that have been removed from the ACVC suite for Ada 95), may not compile correctly. However, for most purposes, using this switch should help to ensure that programs that compile correctly under the `-gnat83' switch can be ported easily to an Ada 83 compiler. This is the main use of the switch. With few exceptions (most notably the need to use `<>' on unconstrained generic formal parameters, the use of the new Ada 95 keywords, and the use of packages with optional bodies), it is not necessary to use the `-gnat83' switch when compiling Ada 83 programs, because, with rare exceptions, Ada 95 is upwardly compatible with Ada 83. This means that a correct Ada 83 program is usually also a correct Ada 95 program. Character Set Control --------------------- `-gnatiC' Normally GNAT recognizes the Latin-1 character set in source program identifiers, as described in the Ada 95 Reference Manual. This switch causes GNAT to recognize alternate character sets in identifiers. C is a single character indicating the character set, as follows: `1' Latin-1 identifiers `2' Latin-2 letters allowed in identifiers `3' Latin-3 letters allowed in identifiers `4' Latin-4 letters allowed in identifiers `5' Latin-5 (Cyrillic) letters allowed in identifiers `9' Latin-9 letters allowed in identifiers `p' IBM PC letters (code page 437) allowed in identifiers `8' IBM PC letters (code page 850) allowed in identifiers `f' Full upper-half codes allowed in identifiers `n' No upper-half codes allowed in identifiers `w' Wide-character codes (that is, codes greater than 255) allowed in identifiers *Note Foreign Language Representation::, for full details on the implementation of these character sets. `-gnatWE' Specify the method of encoding for wide characters. E is one of the following: `h' Hex encoding (brackets coding also recognized) `u' Upper half encoding (brackets encoding also recognized) `s' Shift/JIS encoding (brackets encoding also recognized) `e' EUC encoding (brackets encoding also recognized) `8' UTF-8 encoding (brackets encoding also recognized) `b' Brackets encoding only (default value) For full details on the these encoding methods see *Note Wide Character Encodings::. Note that brackets coding is always accepted, even if one of the other options is specified, so for example `-gnatW8' specifies that both brackets and `UTF-8' encodings will be recognized. The units that are with'ed directly or indirectly will be scanned using the specified representation scheme, and so if one of the non-brackets scheme is used, it must be used consistently throughout the program. However, since brackets encoding is always recognized, it may be conveniently used in standard libraries, allowing these libraries to be used with any of the available coding schemes. scheme. If no `-gnatW?' parameter is present, then the default representation is Brackets encoding only. Note that the wide character representation that is specified (explicitly or by default) for the main program also acts as the default encoding used for Wide_Text_IO files if not specifically overridden by a WCEM form parameter. File Naming Control ------------------- `-gnatkN' Activates file name "krunching". N, a decimal integer in the range 1-999, indicates the maximum allowable length of a file name (not including the `.ads' or `.adb' extension). The default is not to enable file name krunching. For the source file naming rules, *Note File Naming Rules::. Subprogram Inlining Control --------------------------- `-gnatn' The `n' here is intended to suggest the first syllable of the word "inline". GNAT recognizes and processes `Inline' pragmas. However, for the inlining to actually occur, optimization must be enabled. To enable inlining across unit boundaries, this is, inlining a call in one unit of a subprogram declared in a `with''ed unit, you must also specify this switch. In the absence of this switch, GNAT does not attempt inlining across units and does not need to access the bodies of subprograms for which `pragma Inline' is specified if they are not in the current unit. If you specify this switch the compiler will access these bodies, creating an extra source dependency for the resulting object file, and where possible, the call will be inlined. For further details on when inlining is possible see *Note Inlining of Subprograms::. `-gnatN' The front end inlining activated by this switch is generally more extensive, and quite often more effective than the standard `-gnatn' inlining mode. It will also generate additional dependencies. Auxiliary Output Control ------------------------ `-gnatt' Causes GNAT to write the internal tree for a unit to a file (with the extension `.adt'. This not normally required, but is used by separate analysis tools. Typically these tools do the necessary compilations automatically, so you should not have to specify this switch in normal operation. `-gnatu' Print a list of units required by this compilation on `stdout'. The listing includes all units on which the unit being compiled depends either directly or indirectly. `-pass-exit-codes' If this switch is not used, the exit code returned by `gcc' when compiling multiple files indicates whether all source files have been successfully used to generate object files or not. When `-pass-exit-codes' is used, `gcc' exits with an extended exit status and allows an integrated development environment to better react to a compilation failure. Those exit status are: 5 There was an error in at least one source file. 3 At least one source file did not generate an object file. 2 The compiler died unexpectedly (internal error for example). 0 An object file has been generated for every source file. Debugging Control ----------------- `-gnatdX' Activate internal debugging switches. X is a letter or digit, or string of letters or digits, which specifies the type of debugging outputs desired. Normally these are used only for internal development or system debugging purposes. You can find full documentation for these switches in the body of the `Debug' unit in the compiler source file `debug.adb'. `-gnatG' This switch causes the compiler to generate auxiliary output containing a pseudo-source listing of the generated expanded code. Like most Ada compilers, GNAT works by first transforming the high level Ada code into lower level constructs. For example, tasking operations are transformed into calls to the tasking run-time routines. A unique capability of GNAT is to list this expanded code in a form very close to normal Ada source. This is very useful in understanding the implications of various Ada usage on the efficiency of the generated code. There are many cases in Ada (e.g. the use of controlled types), where simple Ada statements can generate a lot of run-time code. By using `-gnatG' you can identify these cases, and consider whether it may be desirable to modify the coding approach to improve efficiency. The format of the output is very similar to standard Ada source, and is easily understood by an Ada programmer. The following special syntactic additions correspond to low level features used in the generated code that do not have any exact analogies in pure Ada source form. The following is a partial list of these special constructions. See the specification of package `Sprint' in file `sprint.ads' for a full list. `new XXX [storage_pool = YYY]' Shows the storage pool being used for an allocator. `at end PROCEDURE-NAME;' Shows the finalization (cleanup) procedure for a scope. `(if EXPR then EXPR else EXPR)' Conditional expression equivalent to the `x?y:z' construction in C. `TARGET^(SOURCE)' A conversion with floating-point truncation instead of rounding. `TARGET?(SOURCE)' A conversion that bypasses normal Ada semantic checking. In particular enumeration types and fixed-point types are treated simply as integers. `TARGET?^(SOURCE)' Combines the above two cases. `X #/ Y' `X #mod Y' `X #* Y' `X #rem Y' A division or multiplication of fixed-point values which are treated as integers without any kind of scaling. `free EXPR [storage_pool = XXX]' Shows the storage pool associated with a `free' statement. `freeze TYPENAME [ACTIONS]' Shows the point at which TYPENAME is frozen, with possible associated actions to be performed at the freeze point. `reference ITYPE' Reference (and hence definition) to internal type ITYPE. `FUNCTION-NAME! (ARG, ARG, ARG)' Intrinsic function call. `LABELNAME : label' Declaration of label LABELNAME. `EXPR && EXPR && EXPR ... && EXPR' A multiple concatenation (same effect as EXPR & EXPR & EXPR, but handled more efficiently). `[constraint_error]' Raise the `Constraint_Error' exception. `EXPRESSION'reference' A pointer to the result of evaluating EXPRESSION. `TARGET-TYPE!(SOURCE-EXPRESSION)' An unchecked conversion of SOURCE-EXPRESSION to TARGET-TYPE. `[NUMERATOR/DENOMINATOR]' Used to represent internal real literals (that) have no exact representation in base 2-16 (for example, the result of compile time evaluation of the expression 1.0/27.0). `-gnatD' This switch is used in conjunction with `-gnatG' to cause the expanded source, as described above to be written to files with names `xxx.dg', where `xxx' is the normal file name, for example, if the source file name is `hello.adb', then a file `hello.adb.dg' will be written. The debugging information generated by the `gcc' `-g' switch will refer to the generated `xxx.dg' file. This allows you to do source level debugging using the generated code which is sometimes useful for complex code, for example to find out exactly which part of a complex construction raised an exception. This switch also suppress generation of cross-reference information (see -gnatx). `-gnatC' In the generated debugging information, and also in the case of long external names, the compiler uses a compression mechanism if the name is very long. This compression method uses a checksum, and avoids trouble on some operating systems which have difficulty with very long names. The `-gnatC' switch forces this compression approach to be used on all external names and names in the debugging information tables. This reduces the size of the generated executable, at the expense of making the naming scheme more complex. The compression only affects the qualification of the name. Thus a name in the source: Very_Long_Package.Very_Long_Inner_Package.Var would normally appear in these tables as: very_long_package__very_long_inner_package__var but if the `-gnatC' switch is used, then the name appears as XCb7e0c705__var Here b7e0c705 is a compressed encoding of the qualification prefix. The GNAT Ada aware version of GDB understands these encoded prefixes, so if this debugger is used, the encoding is largely hidden from the user of the compiler. `-gnatR[0|1|2|3][s]' This switch controls output from the compiler of a listing showing representation information for declared types and objects. For `-gnatR0', no information is output (equivalent to omitting the `-gnatR' switch). For `-gnatR1' (which is the default, so `-gnatR' with no parameter has the same effect), size and alignment information is listed for declared array and record types. For `-gnatR2', size and alignment information is listed for all expression information for values that are computed at run time for variant records. These symbolic expressions have a mostly obvious format with #n being used to represent the value of the n'th discriminant. See source files `repinfo.ads/adb' in the `GNAT' sources for full detalis on the format of `-gnatR3' output. If the switch is followed by an s (e.g. `-gnatR2s'), then the output is to a file with the name `file.rep' where file is the name of the corresponding source file. `-gnatx' Normally the compiler generates full cross-referencing information in the `ALI' file. This information is used by a number of tools, including `gnatfind' and `gnatxref'. The -gnatx switch suppresses this information. This saves some space and may slightly speed up compilation, but means that these tools cannot be used. Units to Sources Mapping Files ------------------------------ `-gnatemPATH' A mapping file is a way to communicate to the compiler two mappings: from unit names to file names (without any directory information) and from file names to path names (with full directory information). These mappings are used by the compiler to short-circuit the path search. A mapping file is a sequence of sets of three lines. In each set, the first line is the unit name, in lower case, with "%s" appended for specifications and "%b" appended for bodies; the second line is the file name; and the third line is the path name. Example: main%b main.2.ada /gnat/project1/sources/main.2.ada When the switch `-gnatem' is specified, the compiler will create in memory the two mappings from the specified file. If there is any problem (non existent file, truncated file or duplicate entries), no mapping will be created. Several `-gnatem' switches may be specified; however, only the last one on the command line will be taken into account. When using a project file, `gnatmake' create a temporary mapping file and communicates it to the compiler using this switch. Search Paths and the Run-Time Library (RTL) =========================================== With the GNAT source-based library system, the compiler must be able to find source files for units that are needed by the unit being compiled. Search paths are used to guide this process. The compiler compiles one source file whose name must be given explicitly on the command line. In other words, no searching is done for this file. To find all other source files that are needed (the most common being the specs of units), the compiler examines the following directories, in the following order: 1. The directory containing the source file of the main unit being compiled (the file name on the command line). 2. Each directory named by an `-I' switch given on the `gcc' command line, in the order given. 3. Each of the directories listed in the value of the `ADA_INCLUDE_PATH' environment variable. Construct this value exactly as the `PATH' environment variable: a list of directory names separated by colons (semicolons when working with the NT version). 4. The content of the "ada_source_path" file which is part of the GNAT installation tree and is used to store standard libraries such as the GNAT Run Time Library (RTL) source files. *Note Installing an Ada Library:: Specifying the switch `-I-' inhibits the use of the directory containing the source file named in the command line. You can still have this directory on your search path, but in this case it must be explicitly requested with a `-I' switch. Specifying the switch `-nostdinc' inhibits the search of the default location for the GNAT Run Time Library (RTL) source files. The compiler outputs its object files and ALI files in the current working directory. Caution: The object file can be redirected with the `-o' switch; however, `gcc' and `gnat1' have not been coordinated on this so the ALI file will not go to the right place. Therefore, you should avoid using the `-o' switch. The packages `Ada', `System', and `Interfaces' and their children make up the GNAT RTL, together with the simple `System.IO' package used in the "Hello World" example. The sources for these units are needed by the compiler and are kept together in one directory. Not all of the bodies are needed, but all of the sources are kept together anyway. In a normal installation, you need not specify these directory names when compiling or binding. Either the environment variables or the built-in defaults cause these files to be found. In addition to the language-defined hierarchies (System, Ada and Interfaces), the GNAT distribution provides a fourth hierarchy, consisting of child units of GNAT. This is a collection of generally useful routines. See the GNAT Reference Manual for further details. Besides simplifying access to the RTL, a major use of search paths is in compiling sources from multiple directories. This can make development environments much more flexible. Order of Compilation Issues =========================== If, in our earlier example, there was a spec for the `hello' procedure, it would be contained in the file `hello.ads'; yet this file would not have to be explicitly compiled. This is the result of the model we chose to implement library management. Some of the consequences of this model are as follows: * There is no point in compiling specs (except for package specs with no bodies) because these are compiled as needed by clients. If you attempt a useless compilation, you will receive an error message. It is also useless to compile subunits because they are compiled as needed by the parent. * There are no order of compilation requirements: performing a compilation never obsoletes anything. The only way you can obsolete something and require recompilations is to modify one of the source files on which it depends. * There is no library as such, apart from the ALI files (*note The Ada Library Information Files::, for information on the format of these files). For now we find it convenient to create separate ALI files, but eventually the information therein may be incorporated into the object file directly. * When you compile a unit, the source files for the specs of all units that it `with''s, all its subunits, and the bodies of any generics it instantiates must be available (reachable by the search-paths mechanism described above), or you will receive a fatal error message. Examples ======== The following are some typical Ada compilation command line examples: `$ gcc -c xyz.adb' Compile body in file `xyz.adb' with all default options. `$ gcc -c -O2 -gnata xyz-def.adb' Compile the child unit package in file `xyz-def.adb' with extensive optimizations, and pragma `Assert'/`Debug' statements enabled. `$ gcc -c -gnatc abc-def.adb' Compile the subunit in file `abc-def.adb' in semantic-checking-only mode. Binding Using `gnatbind' ************************ This chapter describes the GNAT binder, `gnatbind', which is used to bind compiled GNAT objects. The `gnatbind' program performs four separate functions: 1. Checks that a program is consistent, in accordance with the rules in Chapter 10 of the Ada 95 Reference Manual. In particular, error messages are generated if a program uses inconsistent versions of a given unit. 2. Checks that an acceptable order of elaboration exists for the program and issues an error message if it cannot find an order of elaboration that satisfies the rules in Chapter 10 of the Ada 95 Language Manual. 3. Generates a main program incorporating the given elaboration order. This program is a small Ada package (body and spec) that must be subsequently compiled using the GNAT compiler. The necessary compilation step is usually performed automatically by `gnatlink'. The two most important functions of this program are to call the elaboration routines of units in an appropriate order and to call the main program. 4. Determines the set of object files required by the given main program. This information is output in the forms of comments in the generated program, to be read by the `gnatlink' utility used to link the Ada application. Running `gnatbind' ================== The form of the `gnatbind' command is $ gnatbind [SWITCHES] MAINPROG[.ali] [SWITCHES] where MAINPROG.adb is the Ada file containing the main program unit body. If no switches are specified, `gnatbind' constructs an Ada package in two files which names are `b~ADA_MAIN.ads', and `b~ADA_MAIN.adb'. For example, if given the parameter `hello.ali', for a main program contained in file `hello.adb', the binder output files would be `b~hello.ads' and `b~hello.adb'. When doing consistency checking, the binder takes into consideration any source files it can locate. For example, if the binder determines that the given main program requires the package `Pack', whose `.ali' file is `pack.ali' and whose corresponding source spec file is `pack.ads', it attempts to locate the source file `pack.ads' (using the same search path conventions as previously described for the `gcc' command). If it can locate this source file, it checks that the time stamps or source checksums of the source and its references to in `ali' files match. In other words, any `ali' files that mentions this spec must have resulted from compiling this version of the source file (or in the case where the source checksums match, a version close enough that the difference does not matter). The effect of this consistency checking, which includes source files, is that the binder ensures that the program is consistent with the latest version of the source files that can be located at bind time. Editing a source file without compiling files that depend on the source file cause error messages to be generated by the binder. For example, suppose you have a main program `hello.adb' and a package `P', from file `p.ads' and you perform the following steps: 1. Enter `gcc -c hello.adb' to compile the main program. 2. Enter `gcc -c p.ads' to compile package `P'. 3. Edit file `p.ads'. 4. Enter `gnatbind hello'. At this point, the file `p.ali' contains an out-of-date time stamp because the file `p.ads' has been edited. The attempt at binding fails, and the binder generates the following error messages: error: "hello.adb" must be recompiled ("p.ads" has been modified) error: "p.ads" has been modified and must be recompiled Now both files must be recompiled as indicated, and then the bind can succeed, generating a main program. You need not normally be concerned with the contents of this file, but it is similar to the following which is the binder file generated for a simple "hello world" program. -- The package is called Ada_Main unless this name is actually used -- as a unit name in the partition, in which case some other unique -- name is used. with System; package ada_main is Elab_Final_Code : Integer; pragma Import (C, Elab_Final_Code, "__gnat_inside_elab_final_code"); -- The main program saves the parameters (argument count, -- argument values, environment pointer) in global variables -- for later access by other units including -- Ada.Command_Line. gnat_argc : Integer; gnat_argv : System.Address; gnat_envp : System.Address; -- The actual variables are stored in a library routine. This -- is useful for some shared library situations, where there -- are problems if variables are not in the library. pragma Import (C, gnat_argc); pragma Import (C, gnat_argv); pragma Import (C, gnat_envp); -- The exit status is similarly an external location gnat_exit_status : Integer; pragma Import (C, gnat_exit_status); GNAT_Version : constant String := "GNAT Version: 3.15w (20010315)"; pragma Export (C, GNAT_Version, "__gnat_version"); -- This is the generated adafinal routine that performs -- finalization at the end of execution. In the case where -- Ada is the main program, this main program makes a call -- to adafinal at program termination. procedure adafinal; pragma Export (C, adafinal, "adafinal"); -- This is the generated adainit routine that performs -- initialization at the start of execution. In the case -- where Ada is the main program, this main program makes -- a call to adainit at program startup. procedure adainit; pragma Export (C, adainit, "adainit"); -- This routine is called at the start of execution. It is -- a dummy routine that is used by the debugger to breakpoint -- at the start of execution. procedure Break_Start; pragma Import (C, Break_Start, "__gnat_break_start"); -- This is the actual generated main program (it would be -- suppressed if the no main program switch were used). As -- required by standard system conventions, this program has -- the external name main. function main (argc : Integer; argv : System.Address; envp : System.Address) return Integer; pragma Export (C, main, "main"); -- The following set of constants give the version -- identification values for every unit in the bound -- partition. This identification is computed from all -- dependent semantic units, and corresponds to the -- string that would be returned by use of the -- Body_Version or Version attributes. type Version_32 is mod 2 ** 32; u00001 : constant Version_32 := 16#7880BEB3#; u00002 : constant Version_32 := 16#0D24CBD0#; u00003 : constant Version_32 := 16#3283DBEB#; u00004 : constant Version_32 := 16#2359F9ED#; u00005 : constant Version_32 := 16#664FB847#; u00006 : constant Version_32 := 16#68E803DF#; u00007 : constant Version_32 := 16#5572E604#; u00008 : constant Version_32 := 16#46B173D8#; u00009 : constant Version_32 := 16#156A40CF#; u00010 : constant Version_32 := 16#033DABE0#; u00011 : constant Version_32 := 16#6AB38FEA#; u00012 : constant Version_32 := 16#22B6217D#; u00013 : constant Version_32 := 16#68A22947#; u00014 : constant Version_32 := 16#18CC4A56#; u00015 : constant Version_32 := 16#08258E1B#; u00016 : constant Version_32 := 16#367D5222#; u00017 : constant Version_32 := 16#20C9ECA4#; u00018 : constant Version_32 := 16#50D32CB6#; u00019 : constant Version_32 := 16#39A8BB77#; u00020 : constant Version_32 := 16#5CF8FA2B#; u00021 : constant Version_32 := 16#2F1EB794#; u00022 : constant Version_32 := 16#31AB6444#; u00023 : constant Version_32 := 16#1574B6E9#; u00024 : constant Version_32 := 16#5109C189#; u00025 : constant Version_32 := 16#56D770CD#; u00026 : constant Version_32 := 16#02F9DE3D#; u00027 : constant Version_32 := 16#08AB6B2C#; u00028 : constant Version_32 := 16#3FA37670#; u00029 : constant Version_32 := 16#476457A0#; u00030 : constant Version_32 := 16#731E1B6E#; u00031 : constant Version_32 := 16#23C2E789#; u00032 : constant Version_32 := 16#0F1BD6A1#; u00033 : constant Version_32 := 16#7C25DE96#; u00034 : constant Version_32 := 16#39ADFFA2#; u00035 : constant Version_32 := 16#571DE3E7#; u00036 : constant Version_32 := 16#5EB646AB#; u00037 : constant Version_32 := 16#4249379B#; u00038 : constant Version_32 := 16#0357E00A#; u00039 : constant Version_32 := 16#3784FB72#; u00040 : constant Version_32 := 16#2E723019#; u00041 : constant Version_32 := 16#623358EA#; u00042 : constant Version_32 := 16#107F9465#; u00043 : constant Version_32 := 16#6843F68A#; u00044 : constant Version_32 := 16#63305874#; u00045 : constant Version_32 := 16#31E56CE1#; u00046 : constant Version_32 := 16#02917970#; u00047 : constant Version_32 := 16#6CCBA70E#; u00048 : constant Version_32 := 16#41CD4204#; u00049 : constant Version_32 := 16#572E3F58#; u00050 : constant Version_32 := 16#20729FF5#; u00051 : constant Version_32 := 16#1D4F93E8#; u00052 : constant Version_32 := 16#30B2EC3D#; u00053 : constant Version_32 := 16#34054F96#; u00054 : constant Version_32 := 16#5A199860#; u00055 : constant Version_32 := 16#0E7F912B#; u00056 : constant Version_32 := 16#5760634A#; u00057 : constant Version_32 := 16#5D851835#; -- The following Export pragmas export the version numbers -- with symbolic names ending in B (for body) or S -- (for spec) so that they can be located in a link. The -- information provided here is sufficient to track down -- the exact versions of units used in a given build. pragma Export (C, u00001, "helloB"); pragma Export (C, u00002, "system__standard_libraryB"); pragma Export (C, u00003, "system__standard_libraryS"); pragma Export (C, u00004, "adaS"); pragma Export (C, u00005, "ada__text_ioB"); pragma Export (C, u00006, "ada__text_ioS"); pragma Export (C, u00007, "ada__exceptionsB"); pragma Export (C, u00008, "ada__exceptionsS"); pragma Export (C, u00009, "gnatS"); pragma Export (C, u00010, "gnat__heap_sort_aB"); pragma Export (C, u00011, "gnat__heap_sort_aS"); pragma Export (C, u00012, "systemS"); pragma Export (C, u00013, "system__exception_tableB"); pragma Export (C, u00014, "system__exception_tableS"); pragma Export (C, u00015, "gnat__htableB"); pragma Export (C, u00016, "gnat__htableS"); pragma Export (C, u00017, "system__exceptionsS"); pragma Export (C, u00018, "system__machine_state_operationsB"); pragma Export (C, u00019, "system__machine_state_operationsS"); pragma Export (C, u00020, "system__machine_codeS"); pragma Export (C, u00021, "system__storage_elementsB"); pragma Export (C, u00022, "system__storage_elementsS"); pragma Export (C, u00023, "system__secondary_stackB"); pragma Export (C, u00024, "system__secondary_stackS"); pragma Export (C, u00025, "system__parametersB"); pragma Export (C, u00026, "system__parametersS"); pragma Export (C, u00027, "system__soft_linksB"); pragma Export (C, u00028, "system__soft_linksS"); pragma Export (C, u00029, "system__stack_checkingB"); pragma Export (C, u00030, "system__stack_checkingS"); pragma Export (C, u00031, "system__tracebackB"); pragma Export (C, u00032, "system__tracebackS"); pragma Export (C, u00033, "ada__streamsS"); pragma Export (C, u00034, "ada__tagsB"); pragma Export (C, u00035, "ada__tagsS"); pragma Export (C, u00036, "system__string_opsB"); pragma Export (C, u00037, "system__string_opsS"); pragma Export (C, u00038, "interfacesS"); pragma Export (C, u00039, "interfaces__c_streamsB"); pragma Export (C, u00040, "interfaces__c_streamsS"); pragma Export (C, u00041, "system__file_ioB"); pragma Export (C, u00042, "system__file_ioS"); pragma Export (C, u00043, "ada__finalizationB"); pragma Export (C, u00044, "ada__finalizationS"); pragma Export (C, u00045, "system__finalization_rootB"); pragma Export (C, u00046, "system__finalization_rootS"); pragma Export (C, u00047, "system__finalization_implementationB"); pragma Export (C, u00048, "system__finalization_implementationS"); pragma Export (C, u00049, "system__string_ops_concat_3B"); pragma Export (C, u00050, "system__string_ops_concat_3S"); pragma Export (C, u00051, "system__stream_attributesB"); pragma Export (C, u00052, "system__stream_attributesS"); pragma Export (C, u00053, "ada__io_exceptionsS"); pragma Export (C, u00054, "system__unsigned_typesS"); pragma Export (C, u00055, "system__file_control_blockS"); pragma Export (C, u00056, "ada__finalization__list_controllerB"); pragma Export (C, u00057, "ada__finalization__list_controllerS"); -- BEGIN ELABORATION ORDER -- ada (spec) -- gnat (spec) -- gnat.heap_sort_a (spec) -- gnat.heap_sort_a (body) -- gnat.htable (spec) -- gnat.htable (body) -- interfaces (spec) -- system (spec) -- system.machine_code (spec) -- system.parameters (spec) -- system.parameters (body) -- interfaces.c_streams (spec) -- interfaces.c_streams (body) -- system.standard_library (spec) -- ada.exceptions (spec) -- system.exception_table (spec) -- system.exception_table (body) -- ada.io_exceptions (spec) -- system.exceptions (spec) -- system.storage_elements (spec) -- system.storage_elements (body) -- system.machine_state_operations (spec) -- system.machine_state_operations (body) -- system.secondary_stack (spec) -- system.stack_checking (spec) -- system.soft_links (spec) -- system.soft_links (body) -- system.stack_checking (body) -- system.secondary_stack (body) -- system.standard_library (body) -- system.string_ops (spec) -- system.string_ops (body) -- ada.tags (spec) -- ada.tags (body) -- ada.streams (spec) -- system.finalization_root (spec) -- system.finalization_root (body) -- system.string_ops_concat_3 (spec) -- system.string_ops_concat_3 (body) -- system.traceback (spec) -- system.traceback (body) -- ada.exceptions (body) -- system.unsigned_types (spec) -- system.stream_attributes (spec) -- system.stream_attributes (body) -- system.finalization_implementation (spec) -- system.finalization_implementation (body) -- ada.finalization (spec) -- ada.finalization (body) -- ada.finalization.list_controller (spec) -- ada.finalization.list_controller (body) -- system.file_control_block (spec) -- system.file_io (spec) -- system.file_io (body) -- ada.text_io (spec) -- ada.text_io (body) -- hello (body) -- END ELABORATION ORDER end ada_main; -- The following source file name pragmas allow the generated file -- names to be unique for different main programs. They are needed -- since the package name will always be Ada_Main. pragma Source_File_Name (ada_main, Spec_File_Name => "b~hello.ads"); pragma Source_File_Name (ada_main, Body_File_Name => "b~hello.adb"); -- Generated package body for Ada_Main starts here package body ada_main is -- The actual finalization is performed by calling the -- library routine in System.Standard_Library.Adafinal procedure Do_Finalize; pragma Import (C, Do_Finalize, "system__standard_library__adafinal"); ------------- -- adainit -- ------------- procedure adainit is -- These booleans are set to True once the associated unit has -- been elaborated. It is also used to avoid elaborating the -- same unit twice. E040 : Boolean; pragma Import (Ada, E040, "interfaces__c_streams_E"); E008 : Boolean; pragma Import (Ada, E008, "ada__exceptions_E"); E014 : Boolean; pragma Import (Ada, E014, "system__exception_table_E"); E053 : Boolean; pragma Import (Ada, E053, "ada__io_exceptions_E"); E017 : Boolean; pragma Import (Ada, E017, "system__exceptions_E"); E024 : Boolean; pragma Import (Ada, E024, "system__secondary_stack_E"); E030 : Boolean; pragma Import (Ada, E030, "system__stack_checking_E"); E028 : Boolean; pragma Import (Ada, E028, "system__soft_links_E"); E035 : Boolean; pragma Import (Ada, E035, "ada__tags_E"); E033 : Boolean; pragma Import (Ada, E033, "ada__streams_E"); E046 : Boolean; pragma Import (Ada, E046, "system__finalization_root_E"); E048 : Boolean; pragma Import (Ada, E048, "system__finalization_implementation_E"); E044 : Boolean; pragma Import (Ada, E044, "ada__finalization_E"); E057 : Boolean; pragma Import (Ada, E057, "ada__finalization__list_controller_E"); E055 : Boolean; pragma Import (Ada, E055, "system__file_control_block_E"); E042 : Boolean; pragma Import (Ada, E042, "system__file_io_E"); E006 : Boolean; pragma Import (Ada, E006, "ada__text_io_E"); -- Set_Globals is a library routine that stores away the -- value of the indicated set of global values in global -- variables within the library. procedure Set_Globals (Main_Priority : Integer; Time_Slice_Value : Integer; WC_Encoding : Character; Locking_Policy : Character; Queuing_Policy : Character; Task_Dispatching_Policy : Character; Adafinal : System.Address; Unreserve_All_Interrupts : Integer; Exception_Tracebacks : Integer); pragma Import (C, Set_Globals, "__gnat_set_globals"); -- SDP_Table_Build is a library routine used to build the -- exception tables. See unit Ada.Exceptions in files -- a-except.ads/adb for full details of how zero cost -- exception handling works. This procedure, the call to -- it, and the two following tables are all omitted if the -- build is in longjmp/setjump exception mode. procedure SDP_Table_Build (SDP_Addresses : System.Address; SDP_Count : Natural; Elab_Addresses : System.Address; Elab_Addr_Count : Natural); pragma Import (C, SDP_Table_Build, "__gnat_SDP_Table_Build"); -- Table of Unit_Exception_Table addresses. Used for zero -- cost exception handling to build the top level table. ST : aliased constant array (1 .. 23) of System.Address := ( Hello'UET_Address, Ada.Text_Io'UET_Address, Ada.Exceptions'UET_Address, Gnat.Heap_Sort_A'UET_Address, System.Exception_Table'UET_Address, System.Machine_State_Operations'UET_Address, System.Secondary_Stack'UET_Address, System.Parameters'UET_Address, System.Soft_Links'UET_Address, System.Stack_Checking'UET_Address, System.Traceback'UET_Address, Ada.Streams'UET_Address, Ada.Tags'UET_Address, System.String_Ops'UET_Address, Interfaces.C_Streams'UET_Address, System.File_Io'UET_Address, Ada.Finalization'UET_Address, System.Finalization_Root'UET_Address, System.Finalization_Implementation'UET_Address, System.String_Ops_Concat_3'UET_Address, System.Stream_Attributes'UET_Address, System.File_Control_Block'UET_Address, Ada.Finalization.List_Controller'UET_Address); -- Table of addresses of elaboration routines. Used for -- zero cost exception handling to make sure these -- addresses are included in the top level procedure -- address table. EA : aliased constant array (1 .. 23) of System.Address := ( adainit'Code_Address, Do_Finalize'Code_Address, Ada.Exceptions'Elab_Spec'Address, System.Exceptions'Elab_Spec'Address, Interfaces.C_Streams'Elab_Spec'Address, System.Exception_Table'Elab_Body'Address, Ada.Io_Exceptions'Elab_Spec'Address, System.Stack_Checking'Elab_Spec'Address, System.Soft_Links'Elab_Body'Address, System.Secondary_Stack'Elab_Body'Address, Ada.Tags'Elab_Spec'Address, Ada.Tags'Elab_Body'Address, Ada.Streams'Elab_Spec'Address, System.Finalization_Root'Elab_Spec'Address, Ada.Exceptions'Elab_Body'Address, System.Finalization_Implementation'Elab_Spec'Address, System.Finalization_Implementation'Elab_Body'Address, Ada.Finalization'Elab_Spec'Address, Ada.Finalization.List_Controller'Elab_Spec'Address, System.File_Control_Block'Elab_Spec'Address, System.File_Io'Elab_Body'Address, Ada.Text_Io'Elab_Spec'Address, Ada.Text_Io'Elab_Body'Address); -- Start of processing for adainit begin -- Call SDP_Table_Build to build the top level procedure -- table for zero cost exception handling (omitted in -- longjmp/setjump mode). SDP_Table_Build (ST'Address, 23, EA'Address, 23); -- Call Set_Globals to record various information for -- this partition. The values are derived by the binder -- from information stored in the ali files by the compiler. Set_Globals (Main_Priority => -1, -- Priority of main program, -1 if no pragma Priority used Time_Slice_Value => -1, -- Time slice from Time_Slice pragma, -1 if none used WC_Encoding => 'b', -- Wide_Character encoding used, default is brackets Locking_Policy => ' ', -- Locking_Policy used, default of space means not -- specified, otherwise it is the first character of -- the policy name. Queuing_Policy => ' ', -- Queuing_Policy used, default of space means not -- specified, otherwise it is the first character of -- the policy name. Task_Dispatching_Policy => ' ', -- Task_Dispatching_Policy used, default of space means -- not specified, otherwise first character of the -- policy name. Adafinal => System.Null_Address, -- Address of Adafinal routine, not used anymore Unreserve_All_Interrupts => 0, -- Set true if pragma Unreserve_All_Interrupts was used Exception_Tracebacks => 0); -- Indicates if exception tracebacks are enabled Elab_Final_Code := 1; -- Now we have the elaboration calls for all units in the partition. -- The Elab_Spec and Elab_Body attributes generate references to the -- implicit elaboration procedures generated by the compiler for -- each unit that requires elaboration. if not E040 then Interfaces.C_Streams'Elab_Spec; end if; E040 := True; if not E008 then Ada.Exceptions'Elab_Spec; end if; if not E014 then System.Exception_Table'Elab_Body; E014 := True; end if; if not E053 then Ada.Io_Exceptions'Elab_Spec; E053 := True; end if; if not E017 then System.Exceptions'Elab_Spec; E017 := True; end if; if not E030 then System.Stack_Checking'Elab_Spec; end if; if not E028 then System.Soft_Links'Elab_Body; E028 := True; end if; E030 := True; if not E024 then System.Secondary_Stack'Elab_Body; E024 := True; end if; if not E035 then Ada.Tags'Elab_Spec; end if; if not E035 then Ada.Tags'Elab_Body; E035 := True; end if; if not E033 then Ada.Streams'Elab_Spec; E033 := True; end if; if not E046 then System.Finalization_Root'Elab_Spec; end if; E046 := True; if not E008 then Ada.Exceptions'Elab_Body; E008 := True; end if; if not E048 then System.Finalization_Implementation'Elab_Spec; end if; if not E048 then System.Finalization_Implementation'Elab_Body; E048 := True; end if; if not E044 then Ada.Finalization'Elab_Spec; end if; E044 := True; if not E057 then Ada.Finalization.List_Controller'Elab_Spec; end if; E057 := True; if not E055 then System.File_Control_Block'Elab_Spec; E055 := True; end if; if not E042 then System.File_Io'Elab_Body; E042 := True; end if; if not E006 then Ada.Text_Io'Elab_Spec; end if; if not E006 then Ada.Text_Io'Elab_Body; E006 := True; end if; Elab_Final_Code := 0; end adainit; -------------- -- adafinal -- -------------- procedure adafinal is begin Do_Finalize; end adafinal; ---------- -- main -- ---------- -- main is actually a function, as in the ANSI C standard, -- defined to return the exit status. The three parameters -- are the argument count, argument values and environment -- pointer. function main (argc : Integer; argv : System.Address; envp : System.Address) return Integer is -- The initialize routine performs low level system -- initialization using a standard library routine which -- sets up signal handling and performs any other -- required setup. The routine can be found in file -- a-init.c. procedure initialize; pragma Import (C, initialize, "__gnat_initialize"); -- The finalize routine performs low level system -- finalization using a standard library routine. The -- routine is found in file a-final.c and in the standard -- distribution is a dummy routine that does nothing, so -- really this is a hook for special user finalization. procedure finalize; pragma Import (C, finalize, "__gnat_finalize"); -- We get to the main program of the partition by using -- pragma Import because if we try to with the unit and -- call it Ada style, then not only do we waste time -- recompiling it, but also, we don't really know the right -- switches (e.g. identifier character set) to be used -- to compile it. procedure Ada_Main_Program; pragma Import (Ada, Ada_Main_Program, "_ada_hello"); -- Start of processing for main begin -- Save global variables gnat_argc := argc; gnat_argv := argv; gnat_envp := envp; -- Call low level system initialization Initialize; -- Call our generated Ada initialization routine adainit; -- This is the point at which we want the debugger to get -- control Break_Start; -- Now we call the main program of the partition Ada_Main_Program; -- Perform Ada finalization adafinal; -- Perform low level system finalization Finalize; -- Return the proper exit status return (gnat_exit_status); end; -- This section is entirely comments, so it has no effect on the -- compilation of the Ada_Main package. It provides the list of -- object files and linker options, as well as some standard -- libraries needed for the link. The gnatlink utility parses -- this b~hello.adb file to read these comment lines to generate -- the appropriate command line arguments for the call to the -- system linker. The BEGIN/END lines are used for sentinels for -- this parsing operation. -- The exact file names will of course depend on the environment, -- host/target and location of files on the host system. -- BEGIN Object file/option list -- ./hello.o -- -L./ -- -L/usr/local/gnat/lib/gcc-lib/i686-pc-linux-gnu/2.8.1/adalib/ -- /usr/local/gnat/lib/gcc-lib/i686-pc-linux-gnu/2.8.1/adalib/libgnat.a -- END Object file/option list end ada_main; The Ada code in the above example is exactly what is generated by the binder. We have added comments to more clearly indicate the function of each part of the generated `Ada_Main' package. The code is standard Ada in all respects, and can be processed by any tools that handle Ada. In particular, it is possible to use the debugger in Ada mode to debug the generated Ada_Main package. For example, suppose that for reasons that you do not understand, your program is blowing up during elaboration of the body of `Ada.Text_IO'. To chase this bug down, you can place a breakpoint on the call: Ada.Text_Io'Elab_Body; and trace the elaboration routine for this package to find out where the problem might be (more usually of course you would be debugging elaboration code in your own application). Generating the Binder Program in C ================================== In most normal usage, the default mode of `gnatbind' which is to generate the main package in Ada, as described in the previous section. In particular, this means that any Ada programmer can read and understand the generated main program. It can also be debugged just like any other Ada code provided the `-g' switch is used for `gnatbind' and `gnatlink'. However for some purposes it may be convenient to generate the main program in C rather than Ada. This may for example be helpful when you are generating a mixed language program with the main program in C. The GNAT compiler itself is an example. The use of the `-C' switch for both `gnatbind' and `gnatlink' will cause the program to be generated in C (and compiled using the gnu C compiler). The following shows the C code generated for the same "Hello World" program: #ifdef __STDC__ #define PARAMS(paramlist) paramlist #else #define PARAMS(paramlist) () #endif extern void __gnat_set_globals PARAMS ((int, int, int, int, int, int, void (*) PARAMS ((void)), int, int)); extern void adafinal PARAMS ((void)); extern void adainit PARAMS ((void)); extern void system__standard_library__adafinal PARAMS ((void)); extern int main PARAMS ((int, char **, char **)); extern void exit PARAMS ((int)); extern void __gnat_break_start PARAMS ((void)); extern void _ada_hello PARAMS ((void)); extern void __gnat_initialize PARAMS ((void)); extern void __gnat_finalize PARAMS ((void)); extern void ada__exceptions___elabs PARAMS ((void)); extern void system__exceptions___elabs PARAMS ((void)); extern void interfaces__c_streams___elabs PARAMS ((void)); extern void system__exception_table___elabb PARAMS ((void)); extern void ada__io_exceptions___elabs PARAMS ((void)); extern void system__stack_checking___elabs PARAMS ((void)); extern void system__soft_links___elabb PARAMS ((void)); extern void system__secondary_stack___elabb PARAMS ((void)); extern void ada__tags___elabs PARAMS ((void)); extern void ada__tags___elabb PARAMS ((void)); extern void ada__streams___elabs PARAMS ((void)); extern void system__finalization_root___elabs PARAMS ((void)); extern void ada__exceptions___elabb PARAMS ((void)); extern void system__finalization_implementation___elabs PARAMS ((void)); extern void system__finalization_implementation___elabb PARAMS ((void)); extern void ada__finalization___elabs PARAMS ((void)); extern void ada__finalization__list_controller___elabs PARAMS ((void)); extern void system__file_control_block___elabs PARAMS ((void)); extern void system__file_io___elabb PARAMS ((void)); extern void ada__text_io___elabs PARAMS ((void)); extern void ada__text_io___elabb PARAMS ((void)); extern int __gnat_inside_elab_final_code; extern int gnat_argc; extern char **gnat_argv; extern char **gnat_envp; extern int gnat_exit_status; char __gnat_version[] = "GNAT Version: 3.15w (20010315)"; void adafinal () { system__standard_library__adafinal (); } void adainit () { extern char ada__exceptions_E; extern char system__exceptions_E; extern char interfaces__c_streams_E; extern char system__exception_table_E; extern char ada__io_exceptions_E; extern char system__secondary_stack_E; extern char system__stack_checking_E; extern char system__soft_links_E; extern char ada__tags_E; extern char ada__streams_E; extern char system__finalization_root_E; extern char system__finalization_implementation_E; extern char ada__finalization_E; extern char ada__finalization__list_controller_E; extern char system__file_control_block_E; extern char system__file_io_E; extern char ada__text_io_E; extern void *__gnat_hello__SDP; extern void *__gnat_ada__text_io__SDP; extern void *__gnat_ada__exceptions__SDP; extern void *__gnat_gnat__heap_sort_a__SDP; extern void *__gnat_system__exception_table__SDP; extern void *__gnat_system__machine_state_operations__SDP; extern void *__gnat_system__secondary_stack__SDP; extern void *__gnat_system__parameters__SDP; extern void *__gnat_system__soft_links__SDP; extern void *__gnat_system__stack_checking__SDP; extern void *__gnat_system__traceback__SDP; extern void *__gnat_ada__streams__SDP; extern void *__gnat_ada__tags__SDP; extern void *__gnat_system__string_ops__SDP; extern void *__gnat_interfaces__c_streams__SDP; extern void *__gnat_system__file_io__SDP; extern void *__gnat_ada__finalization__SDP; extern void *__gnat_system__finalization_root__SDP; extern void *__gnat_system__finalization_implementation__SDP; extern void *__gnat_system__string_ops_concat_3__SDP; extern void *__gnat_system__stream_attributes__SDP; extern void *__gnat_system__file_control_block__SDP; extern void *__gnat_ada__finalization__list_controller__SDP; void **st[23] = { &__gnat_hello__SDP, &__gnat_ada__text_io__SDP, &__gnat_ada__exceptions__SDP, &__gnat_gnat__heap_sort_a__SDP, &__gnat_system__exception_table__SDP, &__gnat_system__machine_state_operations__SDP, &__gnat_system__secondary_stack__SDP, &__gnat_system__parameters__SDP, &__gnat_system__soft_links__SDP, &__gnat_system__stack_checking__SDP, &__gnat_system__traceback__SDP, &__gnat_ada__streams__SDP, &__gnat_ada__tags__SDP, &__gnat_system__string_ops__SDP, &__gnat_interfaces__c_streams__SDP, &__gnat_system__file_io__SDP, &__gnat_ada__finalization__SDP, &__gnat_system__finalization_root__SDP, &__gnat_system__finalization_implementation__SDP, &__gnat_system__string_ops_concat_3__SDP, &__gnat_system__stream_attributes__SDP, &__gnat_system__file_control_block__SDP, &__gnat_ada__finalization__list_controller__SDP}; extern void ada__exceptions___elabs (); extern void system__exceptions___elabs (); extern void interfaces__c_streams___elabs (); extern void system__exception_table___elabb (); extern void ada__io_exceptions___elabs (); extern void system__stack_checking___elabs (); extern void system__soft_links___elabb (); extern void system__secondary_stack___elabb (); extern void ada__tags___elabs (); extern void ada__tags___elabb (); extern void ada__streams___elabs (); extern void system__finalization_root___elabs (); extern void ada__exceptions___elabb (); extern void system__finalization_implementation___elabs (); extern void system__finalization_implementation___elabb (); extern void ada__finalization___elabs (); extern void ada__finalization__list_controller___elabs (); extern void system__file_control_block___elabs (); extern void system__file_io___elabb (); extern void ada__text_io___elabs (); extern void ada__text_io___elabb (); void (*ea[23]) () = { adainit, system__standard_library__adafinal, ada__exceptions___elabs, system__exceptions___elabs, interfaces__c_streams___elabs, system__exception_table___elabb, ada__io_exceptions___elabs, system__stack_checking___elabs, system__soft_links___elabb, system__secondary_stack___elabb, ada__tags___elabs, ada__tags___elabb, ada__streams___elabs, system__finalization_root___elabs, ada__exceptions___elabb, system__finalization_implementation___elabs, system__finalization_implementation___elabb, ada__finalization___elabs, ada__finalization__list_controller___elabs, system__file_control_block___elabs, system__file_io___elabb, ada__text_io___elabs, ada__text_io___elabb}; __gnat_SDP_Table_Build (&st, 23, ea, 23); __gnat_set_globals ( -1, /* Main_Priority */ -1, /* Time_Slice_Value */ 'b', /* WC_Encoding */ ' ', /* Locking_Policy */ ' ', /* Queuing_Policy */ ' ', /* Tasking_Dispatching_Policy */ 0, /* Finalization routine address, not used anymore */ 0, /* Unreserve_All_Interrupts */ 0); /* Exception_Tracebacks */ __gnat_inside_elab_final_code = 1; if (ada__exceptions_E == 0) { ada__exceptions___elabs (); } if (system__exceptions_E == 0) { system__exceptions___elabs (); system__exceptions_E++; } if (interfaces__c_streams_E == 0) { interfaces__c_streams___elabs (); } interfaces__c_streams_E = 1; if (system__exception_table_E == 0) { system__exception_table___elabb (); system__exception_table_E++; } if (ada__io_exceptions_E == 0) { ada__io_exceptions___elabs (); ada__io_exceptions_E++; } if (system__stack_checking_E == 0) { system__stack_checking___elabs (); } if (system__soft_links_E == 0) { system__soft_links___elabb (); system__soft_links_E++; } system__stack_checking_E = 1; if (system__secondary_stack_E == 0) { system__secondary_stack___elabb (); system__secondary_stack_E++; } if (ada__tags_E == 0) { ada__tags___elabs (); } if (ada__tags_E == 0) { ada__tags___elabb (); ada__tags_E++; } if (ada__streams_E == 0) { ada__streams___elabs (); ada__streams_E++; } if (system__finalization_root_E == 0) { system__finalization_root___elabs (); } system__finalization_root_E = 1; if (ada__exceptions_E == 0) { ada__exceptions___elabb (); ada__exceptions_E++; } if (system__finalization_implementation_E == 0) { system__finalization_implementation___elabs (); } if (system__finalization_implementation_E == 0) { system__finalization_implementation___elabb (); system__finalization_implementation_E++; } if (ada__finalization_E == 0) { ada__finalization___elabs (); } ada__finalization_E = 1; if (ada__finalization__list_controller_E == 0) { ada__finalization__list_controller___elabs (); } ada__finalization__list_controller_E = 1; if (system__file_control_block_E == 0) { system__file_control_block___elabs (); system__file_control_block_E++; } if (system__file_io_E == 0) { system__file_io___elabb (); system__file_io_E++; } if (ada__text_io_E == 0) { ada__text_io___elabs (); } if (ada__text_io_E == 0) { ada__text_io___elabb (); ada__text_io_E++; } __gnat_inside_elab_final_code = 0; } int main (argc, argv, envp) int argc; char **argv; char **envp; { gnat_argc = argc; gnat_argv = argv; gnat_envp = envp; __gnat_initialize (); adainit (); __gnat_break_start (); _ada_hello (); system__standard_library__adafinal (); __gnat_finalize (); exit (gnat_exit_status); } unsigned helloB = 0x7880BEB3; unsigned system__standard_libraryB = 0x0D24CBD0; unsigned system__standard_libraryS = 0x3283DBEB; unsigned adaS = 0x2359F9ED; unsigned ada__text_ioB = 0x47C85FC4; unsigned ada__text_ioS = 0x496FE45C; unsigned ada__exceptionsB = 0x74F50187; unsigned ada__exceptionsS = 0x6736945B; unsigned gnatS = 0x156A40CF; unsigned gnat__heap_sort_aB = 0x033DABE0; unsigned gnat__heap_sort_aS = 0x6AB38FEA; unsigned systemS = 0x0331C6FE; unsigned system__exceptionsS = 0x20C9ECA4; unsigned system__exception_tableB = 0x68A22947; unsigned system__exception_tableS = 0x394BADD5; unsigned gnat__htableB = 0x08258E1B; unsigned gnat__htableS = 0x367D5222; unsigned system__machine_state_operationsB = 0x4F3B7492; unsigned system__machine_state_operationsS = 0x182F5CF4; unsigned system__storage_elementsB = 0x2F1EB794; unsigned system__storage_elementsS = 0x102C83C7; unsigned system__secondary_stackB = 0x1574B6E9; unsigned system__secondary_stackS = 0x708E260A; unsigned system__parametersB = 0x56D770CD; unsigned system__parametersS = 0x237E39BE; unsigned system__soft_linksB = 0x08AB6B2C; unsigned system__soft_linksS = 0x1E2491F3; unsigned system__stack_checkingB = 0x476457A0; unsigned system__stack_checkingS = 0x5299FCED; unsigned system__tracebackB = 0x2971EBDE; unsigned system__tracebackS = 0x2E9C3122; unsigned ada__streamsS = 0x7C25DE96; unsigned ada__tagsB = 0x39ADFFA2; unsigned ada__tagsS = 0x769A0464; unsigned system__string_opsB = 0x5EB646AB; unsigned system__string_opsS = 0x63CED018; unsigned interfacesS = 0x0357E00A; unsigned interfaces__c_streamsB = 0x3784FB72; unsigned interfaces__c_streamsS = 0x2E723019; unsigned system__file_ioB = 0x623358EA; unsigned system__file_ioS = 0x31F873E6; unsigned ada__finalizationB = 0x6843F68A; unsigned ada__finalizationS = 0x63305874; unsigned system__finalization_rootB = 0x31E56CE1; unsigned system__finalization_rootS = 0x23169EF3; unsigned system__finalization_implementationB = 0x6CCBA70E; unsigned system__finalization_implementationS = 0x604AA587; unsigned system__string_ops_concat_3B = 0x572E3F58; unsigned system__string_ops_concat_3S = 0x01F57876; unsigned system__stream_attributesB = 0x1D4F93E8; unsigned system__stream_attributesS = 0x30B2EC3D; unsigned ada__io_exceptionsS = 0x34054F96; unsigned system__unsigned_typesS = 0x7B9E7FE3; unsigned system__file_control_blockS = 0x2FF876A8; unsigned ada__finalization__list_controllerB = 0x5760634A; unsigned ada__finalization__list_controllerS = 0x5D851835; /* BEGIN ELABORATION ORDER ada (spec) gnat (spec) gnat.heap_sort_a (spec) gnat.htable (spec) gnat.htable (body) interfaces (spec) system (spec) system.parameters (spec) system.standard_library (spec) ada.exceptions (spec) system.exceptions (spec) system.parameters (body) gnat.heap_sort_a (body) interfaces.c_streams (spec) interfaces.c_streams (body) system.exception_table (spec) system.exception_table (body) ada.io_exceptions (spec) system.storage_elements (spec) system.storage_elements (body) system.machine_state_operations (spec) system.machine_state_operations (body) system.secondary_stack (spec) system.stack_checking (spec) system.soft_links (spec) system.soft_links (body) system.stack_checking (body) system.secondary_stack (body) system.standard_library (body) system.string_ops (spec) system.string_ops (body) ada.tags (spec) ada.tags (body) ada.streams (spec) system.finalization_root (spec) system.finalization_root (body) system.string_ops_concat_3 (spec) system.string_ops_concat_3 (body) system.traceback (spec) system.traceback (body) ada.exceptions (body) system.unsigned_types (spec) system.stream_attributes (spec) system.stream_attributes (body) system.finalization_implementation (spec) system.finalization_implementation (body) ada.finalization (spec) ada.finalization (body) ada.finalization.list_controller (spec) ada.finalization.list_controller (body) system.file_control_block (spec) system.file_io (spec) system.file_io (body) ada.text_io (spec) ada.text_io (body) hello (body) END ELABORATION ORDER */ /* BEGIN Object file/option list ./hello.o -L./ -L/usr/local/gnat/lib/gcc-lib/alpha-dec-osf5.1/2.8.1/adalib/ /usr/local/gnat/lib/gcc-lib/alpha-dec-osf5.1/2.8.1/adalib/libgnat.a -lexc END Object file/option list */ Here again, the C code is exactly what is generated by the binder. The functions of the various parts of this code correspond in an obvious manner with the commented Ada code shown in the example in the previous section. Consistency-Checking Modes ========================== As described in the previous section, by default `gnatbind' checks that object files are consistent with one another and are consistent with any source files it can locate. The following switches control binder access to sources. `-s' Require source files to be present. In this mode, the binder must be able to locate all source files that are referenced, in order to check their consistency. In normal mode, if a source file cannot be located it is simply ignored. If you specify this switch, a missing source file is an error. `-x' Exclude source files. In this mode, the binder only checks that ALI files are consistent with one another. Source files are not accessed. The binder runs faster in this mode, and there is still a guarantee that the resulting program is self-consistent. If a source file has been edited since it was last compiled, and you specify this switch, the binder will not detect that the object file is out of date with respect to the source file. Note that this is the mode that is automatically used by `gnatmake' because in this case the checking against sources has already been performed by `gnatmake' in the course of compilation (i.e. before binding). Binder Error Message Control ============================ The following switches provide control over the generation of error messages from the binder: `-v' Verbose mode. In the normal mode, brief error messages are generated to `stderr'. If this switch is present, a header is written to `stdout' and any error messages are directed to `stdout'. All that is written to `stderr' is a brief summary message. `-b' Generate brief error messages to `stderr' even if verbose mode is specified. This is relevant only when used with the `-v' switch. `-mN' Limits the number of error messages to N, a decimal integer in the range 1-999. The binder terminates immediately if this limit is reached. `-MXXX' Renames the generated main program from `main' to `xxx'. This is useful in the case of some cross-building environments, where the actual main program is separate from the one generated by `gnatbind'. `-ws' Suppress all warning messages. `-we' Treat any warning messages as fatal errors. `-t' The binder performs a number of consistency checks including: * Check that time stamps of a given source unit are consistent * Check that checksums of a given source unit are consistent * Check that consistent versions of `GNAT' were used for compilation * Check consistency of configuration pragmas as required Normally failure of such checks, in accordance with the consistency requirements of the Ada Reference Manual, causes error messages to be generated which abort the binder and prevent the output of a binder file and subsequent link to obtain an executable. The `-t' switch converts these error messages into warnings, so that binding and linking can continue to completion even in the presence of such errors. The result may be a failed link (due to missing symbols), or a non-functional executable which has undefined semantics. _This means that `-t' should be used only in unusual situations, with extreme care._ Elaboration Control =================== The following switches provide additional control over the elaboration order. For full details see *Note Elaboration Order Handling in GNAT::. `-p' Normally the binder attempts to choose an elaboration order that is likely to minimize the likelihood of an elaboration order error resulting in raising a `Program_Error' exception. This switch reverses the action of the binder, and requests that it deliberately choose an order that is likely to maximize the likelihood of an elaboration error. This is useful in ensuring portability and avoiding dependence on accidental fortuitous elaboration ordering. Normally it only makes sense to use the `-p' switch if dynamic elaboration checking is used (`-gnatE' switch used for compilation). This is because in the default static elaboration mode, all necessary `Elaborate_All' pragmas are implicitly inserted. These implicit pragmas are still respected by the binder in `-p' mode, so a safe elaboration order is assured. Output Control ============== The following switches allow additional control over the output generated by the binder. `-A' Generate binder program in Ada (default). The binder program is named `b~MAINPROG.adb' by default. This can be changed with `-o' `gnatbind' option. `-c' Check only. Do not generate the binder output file. In this mode the binder performs all error checks but does not generate an output file. `-C' Generate binder program in C. The binder program is named `b_MAINPROG.c'. This can be changed with `-o' `gnatbind' option. `-e' Output complete list of elaboration-order dependencies, showing the reason for each dependency. This output can be rather extensive but may be useful in diagnosing problems with elaboration order. The output is written to `stdout'. `-h' Output usage information. The output is written to `stdout'. `-K' Output linker options to `stdout'. Includes library search paths, contents of pragmas Ident and Linker_Options, and libraries added by `gnatbind'. `-l' Output chosen elaboration order. The output is written to `stdout'. `-O' Output full names of all the object files that must be linked to provide the Ada component of the program. The output is written to `stdout'. This list includes the files explicitly supplied and referenced by the user as well as implicitly referenced run-time unit files. The latter are omitted if the corresponding units reside in shared libraries. The directory names for the run-time units depend on the system configuration. `-o FILE' Set name of output file to FILE instead of the normal `b~MAINPROG.adb' default. Note that FILE denote the Ada binder generated body filename. In C mode you would normally give FILE an extension of `.c' because it will be a C source program. Note that if this option is used, then linking must be done manually. It is not possible to use gnatlink in this case, since it cannot locate the binder file. `-r' Generate list of `pragma Rerstrictions' that could be applied to the current unit. This is useful for code audit purposes, and also may be used to improve code generation in some cases. Binding with Non-Ada Main Programs ================================== In our description so far we have assumed that the main program is in Ada, and that the task of the binder is to generate a corresponding function `main' that invokes this Ada main program. GNAT also supports the building of executable programs where the main program is not in Ada, but some of the called routines are written in Ada and compiled using GNAT (*note Mixed Language Programming::). The following switch is used in this situation: `-n' No main program. The main program is not in Ada. In this case, most of the functions of the binder are still required, but instead of generating a main program, the binder generates a file containing the following callable routines: `adainit' You must call this routine to initialize the Ada part of the program by calling the necessary elaboration routines. A call to `adainit' is required before the first call to an Ada subprogram. Note that it is assumed that the basic execution environment must be setup to be appropriate for Ada execution at the point where the first Ada subprogram is called. In particular, if the Ada code will do any floating-point operations, then the FPU must be setup in an appropriate manner. For the case of the x86, for example, full precision mode is required. The procedure GNAT.Float_Control.Reset may be used to ensure that the FPU is in the right state. `adafinal' You must call this routine to perform any library-level finalization required by the Ada subprograms. A call to `adafinal' is required after the last call to an Ada subprogram, and before the program terminates. If the `-n' switch is given, more than one ALI file may appear on the command line for `gnatbind'. The normal "closure" calculation is performed for each of the specified units. Calculating the closure means finding out the set of units involved by tracing `with' references. The reason it is necessary to be able to specify more than one ALI file is that a given program may invoke two or more quite separate groups of Ada units. The binder takes the name of its output file from the last specified ALI file, unless overridden by the use of the `\-o file\/OUTPUT=file\'. The output is an Ada unit in source form that can be compiled with GNAT unless the -C switch is used in which case the output is a C source file, which must be compiled using the C compiler. This compilation occurs automatically as part of the `gnatlink' processing. Currently the GNAT run time requires a FPU using 80 bits mode precision. Under targets where this is not the default it is required to call GNAT.Float_Control.Reset before using floating point numbers (this include float computation, float input and output) in the Ada code. A side effect is that this could be the wrong mode for the foreign code where floating point computation could be broken after this call. Binding Programs with No Main Subprogram ======================================== It is possible to have an Ada program which does not have a main subprogram. This program will call the elaboration routines of all the packages, then the finalization routines. The following switch is used to bind programs organized in this manner: `-z' Normally the binder checks that the unit name given on the command line corresponds to a suitable main subprogram. When this switch is used, a list of ALI files can be given, and the execution of the program consists of elaboration of these units in an appropriate order. Summary of Binder Switches ========================== The following are the switches available with `gnatbind': `-aO' Specify directory to be searched for ALI files. `-aI' Specify directory to be searched for source file. `-A' Generate binder program in Ada (default) `-b' Generate brief messages to `stderr' even if verbose mode set. `-c' Check only, no generation of binder output file. `-C' Generate binder program in C `-e' Output complete list of elaboration-order dependencies. `-E' Store tracebacks in exception occurrences when the target supports it. This is the default with the zero cost exception mechanism. This option is currently supported on the following targets: all x86 ports, Solaris, Windows, HP-UX, AIX, PowerPC VxWorks and Alpha VxWorks. See also the packages `GNAT.Traceback' and `GNAT.Traceback.Symbolic' for more information. Note that on x86 ports, you must not use `-fomit-frame-pointer' `gcc' option. `-h' Output usage (help) information `-I' Specify directory to be searched for source and ALI files. `-I-' Do not look for sources in the current directory where `gnatbind' was invoked, and do not look for ALI files in the directory containing the ALI file named in the `gnatbind' command line. `-l' Output chosen elaboration order. `-Lxxx' Binds the units for library building. In this case the adainit and adafinal procedures (See *note Binding with Non-Ada Main Programs::) are renamed to xxxinit and xxxfinal. Implies -n. See *note GNAT and Libraries:: for more details. `-Mxyz' Rename generated main program from main to xyz `-mN' Limit number of detected errors to N (1-999). `-n' No main program. `-nostdinc' Do not look for sources in the system default directory. `-nostdlib' Do not look for library files in the system default directory. `--RTS=RTS-PATH' Specifies the default location of the runtime library. Same meaning as the equivalent `gnatmake' flag (see *Note Switches for gnatmake::). `-o FILE' Name the output file FILE (default is `b~XXX.adb'). Note that if this option is used, then linking must be done manually, gnatlink cannot be used. `-O' Output object list. `-p' Pessimistic (worst-case) elaboration order `-s' Require all source files to be present. `-static' Link against a static GNAT run time. `-shared' Link against a shared GNAT run time when available. `-t' Tolerate time stamp and other consistency errors `-TN' Set the time slice value to n microseconds. A value of zero means no time slicing and also indicates to the tasking run time to match as close as possible to the annex D requirements of the RM. `-v' Verbose mode. Write error messages, header, summary output to `stdout'. `-wX' Warning mode (X=s/e for suppress/treat as error) `-x' Exclude source files (check object consistency only). `-z' No main subprogram. You may obtain this listing by running the program `gnatbind' with no arguments. Command-Line Access =================== The package `Ada.Command_Line' provides access to the command-line arguments and program name. In order for this interface to operate correctly, the two variables int gnat_argc; char **gnat_argv; are declared in one of the GNAT library routines. These variables must be set from the actual `argc' and `argv' values passed to the main program. With no `n' present, `gnatbind' generates the C main program to automatically set these variables. If the `n' switch is used, there is no automatic way to set these variables. If they are not set, the procedures in `Ada.Command_Line' will not be available, and any attempt to use them will raise `Constraint_Error'. If command line access is required, your main program must set `gnat_argc' and `gnat_argv' from the `argc' and `argv' values passed to it. Search Paths for `gnatbind' =========================== The binder takes the name of an ALI file as its argument and needs to locate source files as well as other ALI files to verify object consistency. For source files, it follows exactly the same search rules as `gcc' (*note Search Paths and the Run-Time Library (RTL)::). For ALI files the directories searched are: 1. The directory containing the ALI file named in the command line, unless the switch `-I-' is specified. 2. All directories specified by `-I' switches on the `gnatbind' command line, in the order given. 3. Each of the directories listed in the value of the `ADA_OBJECTS_PATH' environment variable. Construct this value exactly as the `PATH' environment variable: a list of directory names separated by colons (semicolons when working with the NT version of GNAT). 4. The content of the "ada_object_path" file which is part of the GNAT installation tree and is used to store standard libraries such as the GNAT Run Time Library (RTL) unless the switch `-nostdlib' is specified. *Note Installing an Ada Library:: In the binder the switch `-I' is used to specify both source and library file paths. Use `-aI' instead if you want to specify source paths only, and `-aO' if you want to specify library paths only. This means that for the binder `-I'DIR is equivalent to `-aI'DIR `-aO'DIR. The binder generates the bind file (a C language source file) in the current working directory. The packages `Ada', `System', and `Interfaces' and their children make up the GNAT Run-Time Library, together with the package GNAT and its children, which contain a set of useful additional library functions provided by GNAT. The sources for these units are needed by the compiler and are kept together in one directory. The ALI files and object files generated by compiling the RTL are needed by the binder and the linker and are kept together in one directory, typically different from the directory containing the sources. In a normal installation, you need not specify these directory names when compiling or binding. Either the environment variables or the built-in defaults cause these files to be found. Besides simplifying access to the RTL, a major use of search paths is in compiling sources from multiple directories. This can make development environments much more flexible. Examples of `gnatbind' Usage ============================ This section contains a number of examples of using the GNAT binding utility `gnatbind'. `gnatbind hello' The main program `Hello' (source program in `hello.adb') is bound using the standard switch settings. The generated main program is `b~hello.adb'. This is the normal, default use of the binder. `gnatbind hello -o mainprog.adb' The main program `Hello' (source program in `hello.adb') is bound using the standard switch settings. The generated main program is `mainprog.adb' with the associated spec in `mainprog.ads'. Note that you must specify the body here not the spec, in the case where the output is in Ada. Note that if this option is used, then linking must be done manually, since gnatlink will not be able to find the generated file. `gnatbind main -C -o mainprog.c -x' The main program `Main' (source program in `main.adb') is bound, excluding source files from the consistency checking, generating the file `mainprog.c'. `gnatbind -x main_program -C -o mainprog.c' This command is exactly the same as the previous example. Switches may appear anywhere in the command line, and single letter switches may be combined into a single switch. `gnatbind -n math dbase -C -o ada-control.c' The main program is in a language other than Ada, but calls to subprograms in packages `Math' and `Dbase' appear. This call to `gnatbind' generates the file `ada-control.c' containing the `adainit' and `adafinal' routines to be called before and after accessing the Ada units. Linking Using `gnatlink' ************************ This chapter discusses `gnatlink', a utility program used to link Ada programs and build an executable file. This is a simple program that invokes the Unix linker (via the `gcc' command) with a correct list of object files and library references. `gnatlink' automatically determines the list of files and references for the Ada part of a program. It uses the binder file generated by the binder to determine this list. Running `gnatlink' ================== The form of the `gnatlink' command is $ gnatlink [SWITCHES] MAINPROG[.ali] [NON-ADA OBJECTS] [LINKER OPTIONS] `MAINPROG.ali' references the ALI file of the main program. The `.ali' extension of this file can be omitted. From this reference, `gnatlink' locates the corresponding binder file `b~MAINPROG.adb' and, using the information in this file along with the list of non-Ada objects and linker options, constructs a Unix linker command file to create the executable. The arguments following `MAINPROG.ali' are passed to the linker uninterpreted. They typically include the names of object files for units written in other languages than Ada and any library references required to resolve references in any of these foreign language units, or in `pragma Import' statements in any Ada units. LINKER OPTIONS is an optional list of linker specific switches. The default linker called by gnatlink is GCC which in turn calls the appropriate system linker usually called LD. Standard options for the linker such as `-lmy_lib' or `-Ldir' can be added as is. For options that are not recognized by GCC as linker options, the GCC switches `-Xlinker' or `-Wl,' shall be used. Refer to the GCC documentation for details. Here is an example showing how to generate a linker map assuming that the underlying linker is GNU ld: $ gnatlink my_prog -Wl,-Map,MAPFILE Using LINKER OPTIONS it is possible to set the program stack and heap size. See *note Setting Stack Size from gnatlink:: and *note Setting Heap Size from gnatlink::. `gnatlink' determines the list of objects required by the Ada program and prepends them to the list of objects passed to the linker. `gnatlink' also gathers any arguments set by the use of `pragma Linker_Options' and adds them to the list of arguments presented to the linker. Switches for `gnatlink' ======================= The following switches are available with the `gnatlink' utility: `-A' The binder has generated code in Ada. This is the default. `-C' If instead of generating a file in Ada, the binder has generated one in C, then the linker needs to know about it. Use this switch to signal to `gnatlink' that the binder has generated C code rather than Ada code. `-f' On some targets, the command line length is limited, and `gnatlink' will generate a separate file for the linker if the list of object files is too long. The `-f' flag forces this file to be generated even if the limit is not exceeded. This is useful in some cases to deal with special situations where the command line length is exceeded. `-g' The option to include debugging information causes the Ada bind file (in other words, `b~MAINPROG.adb') to be compiled with `-g'. In addition, the binder does not delete the `b~MAINPROG.adb', `b~MAINPROG.o' and `b~MAINPROG.ali' files. Without `-g', the binder removes these files by default. The same procedure apply if a C bind file was generated using `-C' `gnatbind' option, in this case the filenames are `b_MAINPROG.c' and `b_MAINPROG.o'. `-n' Do not compile the file generated by the binder. This may be used when a link is rerun with different options, but there is no need to recompile the binder file. `-v' Causes additional information to be output, including a full list of the included object files. This switch option is most useful when you want to see what set of object files are being used in the link step. `-v -v' Very verbose mode. Requests that the compiler operate in verbose mode when it compiles the binder file, and that the system linker run in verbose mode. `-o EXEC-NAME' EXEC-NAME specifies an alternate name for the generated executable program. If this switch is omitted, the executable has the same name as the main unit. For example, `gnatlink try.ali' creates an executable called `try'. `-b TARGET' Compile your program to run on TARGET, which is the name of a system configuration. You must have a GNAT cross-compiler built if TARGET is not the same as your host system. `-BDIR' Load compiler executables (for example, `gnat1', the Ada compiler) from DIR instead of the default location. Only use this switch when multiple versions of the GNAT compiler are available. See the `gcc' manual page for further details. You would normally use the `-b' or `-V' switch instead. `--GCC=COMPILER_NAME' Program used for compiling the binder file. The default is `gcc''. You need to use quotes around COMPILER_NAME if `compiler_name' contains spaces or other separator characters. As an example `--GCC="foo -x -y"' will instruct `gnatlink' to use `foo -x -y' as your compiler. Note that switch `-c' is always inserted after your command name. Thus in the above example the compiler command that will be used by `gnatlink' will be `foo -c -x -y'. If several `--GCC=compiler_name' are used, only the last COMPILER_NAME is taken into account. However, all the additional switches are also taken into account. Thus, `--GCC="foo -x -y" --GCC="bar -z -t"' is equivalent to `--GCC="bar -x -y -z -t"'. `--LINK=NAME' NAME is the name of the linker to be invoked. This is especially useful in mixed language programs since languages such as c++ require their own linker to be used. When this switch is omitted, the default name for the linker is (`gcc'). When this switch is used, the specified linker is called instead of (`gcc') with exactly the same parameters that would have been passed to (`gcc') so if the desired linker requires different parameters it is necessary to use a wrapper script that massages the parameters before invoking the real linker. It may be useful to control the exact invocation by using the verbose switch. Setting Stack Size from `gnatlink' ================================== It is possible to specify the program stack size from `gnatlink'. Assuming that the underlying linker is GNU ld there is two ways to do so: * using `-Xlinker' linker option $ gnatlink hello -Xlinker --stack=0x10000,0x1000 This set the stack reserve size to 0x10000 bytes and the stack commit size to 0x1000 bytes. * using `-Wl' linker option $ gnatlink hello -Wl,--stack=0x1000000 This set the stack reserve size to 0x1000000 bytes. Note that with `-Wl' option it is not possible to set the stack commit size because the coma is a separator for this option. Setting Heap Size from `gnatlink' ================================= It is possible to specify the program heap size from `gnatlink'. Assuming that the underlying linker is GNU ld there is two ways to do so: * using `-Xlinker' linker option $ gnatlink hello -Xlinker --heap=0x10000,0x1000 This set the heap reserve size to 0x10000 bytes and the heap commit size to 0x1000 bytes. * using `-Wl' linker option $ gnatlink hello -Wl,--heap=0x1000000 This set the heap reserve size to 0x1000000 bytes. Note that with `-Wl' option it is not possible to set the heap commit size because the coma is a separator for this option. The GNAT Make Program `gnatmake' ******************************** A typical development cycle when working on an Ada program consists of the following steps: 1. Edit some sources to fix bugs. 2. Add enhancements. 3. Compile all sources affected. 4. Rebind and relink. 5. Test. The third step can be tricky, because not only do the modified files have to be compiled, but any files depending on these files must also be recompiled. The dependency rules in Ada can be quite complex, especially in the presence of overloading, `use' clauses, generics and inlined subprograms. `gnatmake' automatically takes care of the third and fourth steps of this process. It determines which sources need to be compiled, compiles them, and binds and links the resulting object files. Unlike some other Ada make programs, the dependencies are always accurately recomputed from the new sources. The source based approach of the GNAT compilation model makes this possible. This means that if changes to the source program cause corresponding changes in dependencies, they will always be tracked exactly correctly by `gnatmake'. Running `gnatmake' ================== The usual form of the `gnatmake' command is $ gnatmake [SWITCHES] FILE_NAME [FILE_NAMES] [MODE_SWITCHES] The only required argument is one FILE_NAME, which specifies a compilation unit that is a main program. Several FILE_NAMES can be specified: this will result in several executables being built. If `switches' are present, they can be placed before the first FILE_NAME, between FILE_NAMES or after the last FILE_NAME. If MODE_SWITCHES are present, they must always be placed after the last FILE_NAME and all `switches'. If you are using standard file extensions (.adb and .ads), then the extension may be omitted from the FILE_NAME arguments. However, if you are using non-standard extensions, then it is required that the extension be given. A relative or absolute directory path can be specified in a FILE_NAME, in which case, the input source file will be searched for in the specified directory only. Otherwise, the input source file will first be searched in the directory where `gnatmake' was invoked and if it is not found, it will be search on the source path of the compiler as described in *Note Search Paths and the Run-Time Library (RTL)::. When several FILE_NAMES are specified, if an executable needs to be rebuilt and relinked, all subsequent executables will be rebuilt and relinked, even if this would not be absolutely necessary. All `gnatmake' output (except when you specify `-M') is to `stderr'. The output produced by the `-M' switch is send to `stdout'. Switches for `gnatmake' ======================= You may specify any of the following switches to `gnatmake': `--GCC=COMPILER_NAME' Program used for compiling. The default is `gcc''. You need to use quotes around COMPILER_NAME if `compiler_name' contains spaces or other separator characters. As an example `--GCC="foo -x -y"' will instruct `gnatmake' to use `foo -x -y' as your compiler. Note that switch `-c' is always inserted after your command name. Thus in the above example the compiler command that will be used by `gnatmake' will be `foo -c -x -y'. If several `--GCC=compiler_name' are used, only the last COMPILER_NAME is taken into account. However, all the additional switches are also taken into account. Thus, `--GCC="foo -x -y" --GCC="bar -z -t"' is equivalent to `--GCC="bar -x -y -z -t"'. `--GNATBIND=BINDER_NAME' Program used for binding. The default is `gnatbind''. You need to use quotes around BINDER_NAME if BINDER_NAME contains spaces or other separator characters. As an example `--GNATBIND="bar -x -y"' will instruct `gnatmake' to use `bar -x -y' as your binder. Binder switches that are normally appended by `gnatmake' to `gnatbind'' are now appended to the end of `bar -x -y'. `--GNATLINK=LINKER_NAME' Program used for linking. The default is `gnatlink''. You need to use quotes around LINKER_NAME if LINKER_NAME contains spaces or other separator characters. As an example `--GNATLINK="lan -x -y"' will instruct `gnatmake' to use `lan -x -y' as your linker. Linker switches that are normally appended by `gnatmake' to `gnatlink'' are now appended to the end of `lan -x -y'. `-a' Consider all files in the make process, even the GNAT internal system files (for example, the predefined Ada library files), as well as any locked files. Locked files are files whose ALI file is write-protected. By default, `gnatmake' does not check these files, because the assumption is that the GNAT internal files are properly up to date, and also that any write protected ALI files have been properly installed. Note that if there is an installation problem, such that one of these files is not up to date, it will be properly caught by the binder. You may have to specify this switch if you are working on GNAT itself. `-a' is also useful in conjunction with `-f' if you need to recompile an entire application, including run-time files, using special configuration pragma settings, such as a non-standard `Float_Representation' pragma. By default `gnatmake -a' compiles all GNAT internal files with `gcc -c -gnatpg' rather than `gcc -c'. `-b' Bind only. Can be combined with `-c' to do compilation and binding, but no link. Can be combined with `-l' to do binding and linking. When not combined with `-c' all the units in the closure of the main program must have been previously compiled and must be up to date. The root unit specified by FILE_NAME may be given without extension, with the source extension or, if no GNAT Project File is specified, with the ALI file extension. `-c' Compile only. Do not perform binding, except when `-b' is also specified. Do not perform linking, except if both `-b' and `-l' are also specified. If the root unit specified by FILE_NAME is not a main unit, this is the default. Otherwise `gnatmake' will attempt binding and linking unless all objects are up to date and the executable is more recent than the objects. `-C' Use a mapping file. A mapping file is a way to communicate to the compiler two mappings: from unit names to file names (without any directory information) and from file names to path names (with full directory information). These mappings are used by the compiler to short-circuit the path search. When `gnatmake' is invoked with this switch, it will create a mapping file, initially populated by the project manager, if `-P' is used, otherwise initially empty. Each invocation of the compiler will add the newly accessed sources to the mapping file. This will improve the source search during the next invocation of the compiler. `-f' Force recompilations. Recompile all sources, even though some object files may be up to date, but don't recompile predefined or GNAT internal files or locked files (files with a write-protected ALI file), unless the `-a' switch is also specified. `' `-i' In normal mode, `gnatmake' compiles all object files and ALI files into the current directory. If the `-i' switch is used, then instead object files and ALI files that already exist are overwritten in place. This means that once a large project is organized into separate directories in the desired manner, then `gnatmake' will automatically maintain and update this organization. If no ALI files are found on the Ada object path (*Note Search Paths and the Run-Time Library (RTL)::), the new object and ALI files are created in the directory containing the source being compiled. If another organization is desired, where objects and sources are kept in different directories, a useful technique is to create dummy ALI files in the desired directories. When detecting such a dummy file, `gnatmake' will be forced to recompile the corresponding source file, and it will be put the resulting object and ALI files in the directory where it found the dummy file. `-jN' Use N processes to carry out the (re)compilations. On a multiprocessor machine compilations will occur in parallel. In the event of compilation errors, messages from various compilations might get interspersed (but `gnatmake' will give you the full ordered list of failing compiles at the end). If this is problematic, rerun the make process with n set to 1 to get a clean list of messages. `-k' Keep going. Continue as much as possible after a compilation error. To ease the programmer's task in case of compilation errors, the list of sources for which the compile fails is given when `gnatmake' terminates. If `gnatmake' is invoked with several `file_names' and with this switch, if there are compilation errors when building an executable, `gnatmake' will not attempt to build the following executables. `-l' Link only. Can be combined with `-b' to binding and linking. Linking will not be performed if combined with `-c' but not with `-b'. When not combined with `-b' all the units in the closure of the main program must have been previously compiled and must be up to date, and the main program need to have been bound. The root unit specified by FILE_NAME may be given without extension, with the source extension or, if no GNAT Project File is specified, with the ALI file extension. `-m' Specifies that the minimum necessary amount of recompilations be performed. In this mode `gnatmake' ignores time stamp differences when the only modifications to a source file consist in adding/removing comments, empty lines, spaces or tabs. This means that if you have changed the comments in a source file or have simply reformatted it, using this switch will tell gnatmake not to recompile files that depend on it (provided other sources on which these files depend have undergone no semantic modifications). `-M' Check if all objects are up to date. If they are, output the object dependences to `stdout' in a form that can be directly exploited in a `Makefile'. By default, each source file is prefixed with its (relative or absolute) directory name. This name is whatever you specified in the various `-aI' and `-I' switches. If you use `gnatmake -M' `-q' (see below), only the source file names, without relative paths, are output. If you just specify the `-M' switch, dependencies of the GNAT internal system files are omitted. This is typically what you want. If you also specify the `-a' switch, dependencies of the GNAT internal files are also listed. Note that dependencies of the objects in external Ada libraries (see switch `-aL'DIR in the following list) are never reported. `-n' Don't compile, bind, or link. Checks if all objects are up to date. If they are not, the full name of the first file that needs to be recompiled is printed. Repeated use of this option, followed by compiling the indicated source file, will eventually result in recompiling all required units. `-o EXEC_NAME' Output executable name. The name of the final executable program will be EXEC_NAME. If the `-o' switch is omitted the default name for the executable will be the name of the input file in appropriate form for an executable file on the host system. This switch cannot be used when invoking `gnatmake' with several `file_names'. `-q' Quiet. When this flag is not set, the commands carried out by `gnatmake' are displayed. `\-s\/SWITCH_CHECK/' Recompile if compiler switches have changed since last compilation. All compiler switches but -I and -o are taken into account in the following way: orders between different first letter" switches are ignored, but orders between same switches are taken into account. For example, `-O -O2' is different than `-O2 -O', but `-g -O' is equivalent to `-O -g'. `-u' Unique. Recompile at most the main file. It implies -c. Combined with -f, it is equivalent to calling the compiler directly. `-v' Verbose. Displays the reason for all recompilations `gnatmake' decides are necessary. `-z' No main subprogram. Bind and link the program even if the unit name given on the command line is a package name. The resulting executable will execute the elaboration routines of the package and its closure, then the finalization routines. ``gcc' switches' The switch `-g' or any uppercase switch (other than `-A', `-L' or `-S') or any switch that is more than one character is passed to `gcc' (e.g. `-O', `-gnato,' etc.) Source and library search path switches: `-aIDIR' When looking for source files also look in directory DIR. The order in which source files search is undertaken is described in *Note Search Paths and the Run-Time Library (RTL)::. `-aLDIR' Consider DIR as being an externally provided Ada library. Instructs `gnatmake' to skip compilation units whose `.ali' files have been located in directory DIR. This allows you to have missing bodies for the units in DIR and to ignore out of date bodies for the same units. You still need to specify the location of the specs for these units by using the switches `-aIDIR' or `-IDIR'. Note: this switch is provided for compatibility with previous versions of `gnatmake'. The easier method of causing standard libraries to be excluded from consideration is to write-protect the corresponding ALI files. `-aODIR' When searching for library and object files, look in directory DIR. The order in which library files are searched is described in *Note Search Paths for gnatbind::. `-ADIR' Equivalent to `-aLDIR -aIDIR'. `-IDIR' Equivalent to `-aODIR -aIDIR'. `-I-' Do not look for source files in the directory containing the source file named in the command line. Do not look for ALI or object files in the directory where `gnatmake' was invoked. `-LDIR' Add directory DIR to the list of directories in which the linker will search for libraries. This is equivalent to `-largs -L'DIR. `-nostdinc' Do not look for source files in the system default directory. `-nostdlib' Do not look for library files in the system default directory. `--RTS=RTS-PATH' Specifies the default location of the runtime library. We look for the runtime in the following directories, and stop as soon as a valid runtime is found ("adainclude" or "ada_source_path", and "adalib" or "ada_object_path" present): * /$rts_path * /$rts_path * /rts-$rts_path The selected path is handled like a normal RTS path. Mode Switches for `gnatmake' ============================ The mode switches (referred to as `mode_switches') allow the inclusion of switches that are to be passed to the compiler itself, the binder or the linker. The effect of a mode switch is to cause all subsequent switches up to the end of the switch list, or up to the next mode switch, to be interpreted as switches to be passed on to the designated component of GNAT. `-cargs SWITCHES' Compiler switches. Here SWITCHES is a list of switches that are valid switches for `gcc'. They will be passed on to all compile steps performed by `gnatmake'. `-bargs SWITCHES' Binder switches. Here SWITCHES is a list of switches that are valid switches for `gcc'. They will be passed on to all bind steps performed by `gnatmake'. `-largs SWITCHES' Linker switches. Here SWITCHES is a list of switches that are valid switches for `gcc'. They will be passed on to all link steps performed by `gnatmake'. Notes on the Command Line ========================= This section contains some additional useful notes on the operation of the `gnatmake' command. * If `gnatmake' finds no ALI files, it recompiles the main program and all other units required by the main program. This means that `gnatmake' can be used for the initial compile, as well as during subsequent steps of the development cycle. * If you enter `gnatmake FILE.adb', where `FILE.adb' is a subunit or body of a generic unit, `gnatmake' recompiles `FILE.adb' (because it finds no ALI) and stops, issuing a warning. * In `gnatmake' the switch `-I' is used to specify both source and library file paths. Use `-aI' instead if you just want to specify source paths only and `-aO' if you want to specify library paths only. * `gnatmake' examines both an ALI file and its corresponding object file for consistency. If an ALI is more recent than its corresponding object, or if the object file is missing, the corresponding source will be recompiled. Note that `gnatmake' expects an ALI and the corresponding object file to be in the same directory. * `gnatmake' will ignore any files whose ALI file is write-protected. This may conveniently be used to exclude standard libraries from consideration and in particular it means that the use of the `-f' switch will not recompile these files unless `-a' is also specified. * `gnatmake' has been designed to make the use of Ada libraries particularly convenient. Assume you have an Ada library organized as follows: OBJ-DIR contains the objects and ALI files for of your Ada compilation units, whereas INCLUDE-DIR contains the specs of these units, but no bodies. Then to compile a unit stored in `main.adb', which uses this Ada library you would just type $ gnatmake -aIINCLUDE-DIR -aLOBJ-DIR main * Using `gnatmake' along with the `-m (minimal recompilation)' switch provides an extremely powerful tool: you can freely update the comments/format of your source files without having to recompile everything. Note, however, that adding or deleting lines in a source files may render its debugging info obsolete. If the file in question is a spec, the impact is rather limited, as that debugging info will only be useful during the elaboration phase of your program. For bodies the impact can be more significant. In all events, your debugger will warn you if a source file is more recent than the corresponding object, and therefore obsolescence of debugging information will go unnoticed. How `gnatmake' Works ==================== Generally `gnatmake' automatically performs all necessary recompilations and you don't need to worry about how it works. However, it may be useful to have some basic understanding of the `gnatmake' approach and in particular to understand how it uses the results of previous compilations without incorrectly depending on them. First a definition: an object file is considered "up to date" if the corresponding ALI file exists and its time stamp predates that of the object file and if all the source files listed in the dependency section of this ALI file have time stamps matching those in the ALI file. This means that neither the source file itself nor any files that it depends on have been modified, and hence there is no need to recompile this file. `gnatmake' works by first checking if the specified main unit is up to date. If so, no compilations are required for the main unit. If not, `gnatmake' compiles the main program to build a new ALI file that reflects the latest sources. Then the ALI file of the main unit is examined to find all the source files on which the main program depends, and `gnatmake' recursively applies the above procedure on all these files. This process ensures that `gnatmake' only trusts the dependencies in an existing ALI file if they are known to be correct. Otherwise it always recompiles to determine a new, guaranteed accurate set of dependencies. As a result the program is compiled "upside down" from what may be more familiar as the required order of compilation in some other Ada systems. In particular, clients are compiled before the units on which they depend. The ability of GNAT to compile in any order is critical in allowing an order of compilation to be chosen that guarantees that `gnatmake' will recompute a correct set of new dependencies if necessary. When invoking `gnatmake' with several FILE_NAMES, if a unit is imported by several of the executables, it will be recompiled at most once. Examples of `gnatmake' Usage ============================ `gnatmake hello.adb' Compile all files necessary to bind and link the main program `hello.adb' (containing unit `Hello') and bind and link the resulting object files to generate an executable file `hello'. `gnatmake main1 main2 main3' Compile all files necessary to bind and link the main programs `main1.adb' (containing unit `Main1'), `main2.adb' (containing unit `Main2') and `main3.adb' (containing unit `Main3') and bind and link the resulting object files to generate three executable files `main1', `main2' and `main3'. `gnatmake -q Main_Unit -cargs -O2 -bargs -l' Compile all files necessary to bind and link the main program unit `Main_Unit' (from file `main_unit.adb'). All compilations will be done with optimization level 2 and the order of elaboration will be listed by the binder. `gnatmake' will operate in quiet mode, not displaying commands it is executing. Renaming Files Using `gnatchop' ******************************* This chapter discusses how to handle files with multiple units by using the `gnatchop' utility. This utility is also useful in renaming files to meet the standard GNAT default file naming conventions. Handling Files with Multiple Units ================================== The basic compilation model of GNAT requires that a file submitted to the compiler have only one unit and there be a strict correspondence between the file name and the unit name. The `gnatchop' utility allows both of these rules to be relaxed, allowing GNAT to process files which contain multiple compilation units and files with arbitrary file names. `gnatchop' reads the specified file and generates one or more output files, containing one unit per file. The unit and the file name correspond, as required by GNAT. If you want to permanently restructure a set of "foreign" files so that they match the GNAT rules, and do the remaining development using the GNAT structure, you can simply use `gnatchop' once, generate the new set of files and work with them from that point on. Alternatively, if you want to keep your files in the "foreign" format, perhaps to maintain compatibility with some other Ada compilation system, you can set up a procedure where you use `gnatchop' each time you compile, regarding the source files that it writes as temporary files that you throw away. Operating gnatchop in Compilation Mode ====================================== The basic function of `gnatchop' is to take a file with multiple units and split it into separate files. The boundary between files is reasonably clear, except for the issue of comments and pragmas. In default mode, the rule is that any pragmas between units belong to the previous unit, except that configuration pragmas always belong to the following unit. Any comments belong to the following unit. These rules almost always result in the right choice of the split point without needing to mark it explicitly and most users will find this default to be what they want. In this default mode it is incorrect to submit a file containing only configuration pragmas, or one that ends in configuration pragmas, to `gnatchop'. However, using a special option to activate "compilation mode", `gnatchop' can perform another function, which is to provide exactly the semantics required by the RM for handling of configuration pragmas in a compilation. In the absence of configuration pragmas (at the main file level), this option has no effect, but it causes such configuration pragmas to be handled in a quite different manner. First, in compilation mode, if `gnatchop' is given a file that consists of only configuration pragmas, then this file is appended to the `gnat.adc' file in the current directory. This behavior provides the required behavior described in the RM for the actions to be taken on submitting such a file to the compiler, namely that these pragmas should apply to all subsequent compilations in the same compilation environment. Using GNAT, the current directory, possibly containing a `gnat.adc' file is the representation of a compilation environment. For more information on the `gnat.adc' file, see the section on handling of configuration pragmas *note Handling of Configuration Pragmas::. Second, in compilation mode, if `gnatchop' is given a file that starts with configuration pragmas, and contains one or more units, then these configuration pragmas are prepended to each of the chopped files. This behavior provides the required behavior described in the RM for the actions to be taken on compiling such a file, namely that the pragmas apply to all units in the compilation, but not to subsequently compiled units. Finally, if configuration pragmas appear between units, they are appended to the previous unit. This results in the previous unit being illegal, since the compiler does not accept configuration pragmas that follow a unit. This provides the required RM behavior that forbids configuration pragmas other than those preceding the first compilation unit of a compilation. For most purposes, `gnatchop' will be used in default mode. The compilation mode described above is used only if you need exactly accurate behavior with respect to compilations, and you have files that contain multiple units and configuration pragmas. In this circumstance the use of `gnatchop' with the compilation mode switch provides the required behavior, and is for example the mode in which GNAT processes the ACVC tests. Command Line for `gnatchop' =========================== The `gnatchop' command has the form: $ gnatchop switches FILE NAME [FILE NAME FILE NAME ...] [DIRECTORY] The only required argument is the file name of the file to be chopped. There are no restrictions on the form of this file name. The file itself contains one or more Ada units, in normal GNAT format, concatenated together. As shown, more than one file may be presented to be chopped. When run in default mode, `gnatchop' generates one output file in the current directory for each unit in each of the files. DIRECTORY, if specified, gives the name of the directory to which the output files will be written. If it is not specified, all files are written to the current directory. For example, given a file called `hellofiles' containing procedure hello; with Text_IO; use Text_IO; procedure hello is begin Put_Line ("Hello"); end hello; the command $ gnatchop hellofiles generates two files in the current directory, one called `hello.ads' containing the single line that is the procedure spec, and the other called `hello.adb' containing the remaining text. The original file is not affected. The generated files can be compiled in the normal manner. Switches for `gnatchop' ======================= `gnatchop' recognizes the following switches: `-c' Causes `gnatchop' to operate in compilation mode, in which configuration pragmas are handled according to strict RM rules. See previous section for a full description of this mode. `-gnatxxx' This passes the given `-gnatxxx' switch to `gnat' which is used to parse the given file. Not all `xxx' options make sense, but for example, the use of `-gnati2' allows `gnatchop' to process a source file that uses Latin-2 coding for identifiers. `-h' Causes `gnatchop' to generate a brief help summary to the standard output file showing usage information. `-kMM' Limit generated file names to the specified number `mm' of characters. This is useful if the resulting set of files is required to be interoperable with systems which limit the length of file names. No space is allowed between the `-k' and the numeric value. The numeric value may be omitted in which case a default of `-k8', suitable for use with DOS-like file systems, is used. If no `-k' switch is present then there is no limit on the length of file names. `-p' Causes the file modification time stamp of the input file to be preserved and used for the time stamp of the output file(s). This may be useful for preserving coherency of time stamps in an enviroment where `gnatchop' is used as part of a standard build process. `-q' Causes output of informational messages indicating the set of generated files to be suppressed. Warnings and error messages are unaffected. `-r' Generate `Source_Reference' pragmas. Use this switch if the output files are regarded as temporary and development is to be done in terms of the original unchopped file. This switch causes `Source_Reference' pragmas to be inserted into each of the generated files to refers back to the original file name and line number. The result is that all error messages refer back to the original unchopped file. In addition, the debugging information placed into the object file (when the `-g' switch of `gcc' or `gnatmake' is specified) also refers back to this original file so that tools like profilers and debuggers will give information in terms of the original unchopped file. If the original file to be chopped itself contains a `Source_Reference' pragma referencing a third file, then gnatchop respects this pragma, and the generated `Source_Reference' pragmas in the chopped file refer to the original file, with appropriate line numbers. This is particularly useful when `gnatchop' is used in conjunction with `gnatprep' to compile files that contain preprocessing statements and multiple units. `-v' Causes `gnatchop' to operate in verbose mode. The version number and copyright notice are output, as well as exact copies of the gnat1 commands spawned to obtain the chop control information. `-w' Overwrite existing file names. Normally `gnatchop' regards it as a fatal error if there is already a file with the same name as a file it would otherwise output, in other words if the files to be chopped contain duplicated units. This switch bypasses this check, and causes all but the last instance of such duplicated units to be skipped. `--GCC=xxxx' Specify the path of the GNAT parser to be used. When this switch is used, no attempt is made to add the prefix to the GNAT parser executable. Examples of `gnatchop' Usage ============================ `gnatchop -w hello_s.ada ichbiah/files' Chops the source file `hello_s.ada'. The output files will be placed in the directory `ichbiah/files', overwriting any files with matching names in that directory (no files in the current directory are modified). `gnatchop archive' Chops the source file `archive' into the current directory. One useful application of `gnatchop' is in sending sets of sources around, for example in email messages. The required sources are simply concatenated (for example, using a Unix `cat' command), and then `gnatchop' is used at the other end to reconstitute the original file names. `gnatchop file1 file2 file3 direc' Chops all units in files `file1', `file2', `file3', placing the resulting files in the directory `direc'. Note that if any units occur more than once anywhere within this set of files, an error message is generated, and no files are written. To override this check, use the `-w' switch, in which case the last occurrence in the last file will be the one that is output, and earlier duplicate occurrences for a given unit will be skipped. Configuration Pragmas ********************* In Ada 95, configuration pragmas include those pragmas described as such in the Ada 95 Reference Manual, as well as implementation-dependent pragmas that are configuration pragmas. See the individual descriptions of pragmas in the GNAT Reference Manual for details on these additional GNAT-specific configuration pragmas. Most notably, the pragma `Source_File_Name', which allows specifying non-default names for source files, is a configuration pragma. The following is a complete list of configuration pragmas recognized by `GNAT': Ada_83 Ada_95 C_Pass_By_Copy Component_Alignment Discard_Names Elaboration_Checks Eliminate Extend_System Extensions_Allowed External_Name_Casing Float_Representation Initialize_Scalars License Locking_Policy Long_Float No_Run_Time Normalize_Scalars Polling Propagate_Exceptions Queuing_Policy Ravenscar Restricted_Run_Time Restrictions Reviewable Source_File_Name Style_Checks Suppress Task_Dispatching_Policy Unsuppress Use_VADS_Size Warnings Validity_Checks Handling of Configuration Pragmas ================================= Configuration pragmas may either appear at the start of a compilation unit, in which case they apply only to that unit, or they may apply to all compilations performed in a given compilation environment. GNAT also provides the `gnatchop' utility to provide an automatic way to handle configuration pragmas following the semantics for compilations (that is, files with multiple units), described in the RM. See section *note Operating gnatchop in Compilation Mode:: for details. However, for most purposes, it will be more convenient to edit the `gnat.adc' file that contains configuration pragmas directly, as described in the following section. The Configuration Pragmas Files =============================== In GNAT a compilation environment is defined by the current directory at the time that a compile command is given. This current directory is searched for a file whose name is `gnat.adc'. If this file is present, it is expected to contain one or more configuration pragmas that will be applied to the current compilation. However, if the switch `-gnatA' is used, `gnat.adc' is not considered. Configuration pragmas may be entered into the `gnat.adc' file either by running `gnatchop' on a source file that consists only of configuration pragmas, or more conveniently by direct editing of the `gnat.adc' file, which is a standard format source file. In addition to `gnat.adc', one additional file containing configuration pragmas may be applied to the current compilation using the switch `-gnatec'PATH. PATH must designate an existing file that contains only configuration pragmas. These configuration pragmas are in addition to those found in `gnat.adc' (provided `gnat.adc' is present and switch `-gnatA' is not used). It is allowed to specify several switches `-gnatec', however only the last one on the command line will be taken into account. Handling Arbitrary File Naming Conventions Using `gnatname' *********************************************************** Arbitrary File Naming Conventions ================================= The GNAT compiler must be able to know the source file name of a compilation unit. When using the standard GNAT default file naming conventions (`.ads' for specs, `.adb' for bodies), the GNAT compiler does not need additional information. When the source file names do not follow the standard GNAT default file naming conventions, the GNAT compiler must be given additional information through a configuration pragmas file (see *Note Configuration Pragmas::) or a project file. When the non standard file naming conventions are well-defined, a small number of pragmas `Source_File_Name' specifying a naming pattern (see *Note Alternative File Naming Schemes::) may be sufficient. However, if the file naming conventions are irregular or arbitrary, a number of pragma `Source_File_Name' for individual compilation units must be defined. To help maintain the correspondence between compilation unit names and source file names within the compiler, GNAT provides a tool `gnatname' to generate the required pragmas for a set of files. Running `gnatname' ================== The usual form of the `gnatname' command is $ gnatname [SWITCHES] [NAMING_PATTERNS] All of the arguments are optional. When used with no arguments, `gnatname' will create a file `gnat.adc' in the current working directory, that contains configuration pragmas for all compilation units in the current directory. To find all compilation units, `gnatname' will use the GNAT compiler in syntax-check-only mode on all regular files. For those files that contain an Ada compilation unit, a pragma `Source_File_Name' will be generated. One or several Naming Patterns may be given as arguments to `gnatname'. Each Naming Pattern is enclosed between double quotes. A Naming Pattern is a regular expression similar to the wildcard patterns used in file names by the Unix shells or the DOS prompt. Examples of Naming Patterns are "*.[12].ada" "*.ad[sb]*" "body_*" "spec_*" For a more complete description of the syntax of Naming Patterns, see the second kind of regular expressions described in `g-regexp.ads' (the "Glob" regular expressions). Specifying no Naming Pattern is equivalent to specifying the single Naming Pattern `"*"'. Switches for `gnatname' ======================= Switches for `gnatname' must precede any specified Naming Pattern. You may specify any of the following switches to `gnatname': `-c`file'' Create a configuration pragmas file `file' (instead of the default `gnat.adc'). There may be zero, one or more space between `-c' and `file'. `file' may include directory information. `file' must be writeable. There may be only one switch `-c'. When a switch `-c' is specified, no switch `-P' may be specified (see below). `-d`dir'' Look for source files in directory `dir'. There may be zero, one or more spaces between `-d' and `dir'. When a switch `-d' is specified, the current working directory will not be searched for source files, unless it is explictly specified with a `-d' or `-D' switch. Several switches `-d' may be specified. If `dir' is a relative path, it is relative to the directory of the configuration pragmas file specified with switch `-c', or to the directory of the project file specified with switch `-P' or, if neither switch `-c' nor switch `-P' are specified, it is relative to the current working directory. The directory specified with switch `-c' must exist and be readable. `-D`file'' Look for source files in all directories listed in text file `file'. There may be zero, one or more spaces between `-d' and `dir'. `file' must be an existing, readable text file. Each non empty line in `file' must be a directory. Specifying switch `-D' is equivalent to specifying as many switches `-d' as there are non empty lines in `file'. `-h' Output usage (help) information. The output is written to `stdout'. `-P`proj'' Create or update project file `proj'. There may be zero, one or more space between `-P' and `proj'. `proj' may include directory information. `proj' must be writeable. There may be only one switch `-P'. When a switch `-P' is specified, no switch `-c' may be specified. `-v' Verbose mode. Output detailed explanation of behavior to `stdout'. This includes name of the file written, the name of the directories to search and, for each file in those directories whose name matches at least one of the Naming Patterns, an indication of whether the file contains a unit, and if so the name of the unit. `-v -v' Very Verbose mode. In addition to the output produced in verbose mode, for each file in the searched directories whose name matches none of the Naming Patterns, an indication is given that there is no match. Examples of `gnatname' Usage ============================ $ gnatname equivalent to $ gnatname -d. "*" $ gnatname -c /home/me/names.adc -d sources "[a-z]*.ada*" In this example, the directory `/home/me' must already exist and be writeable. In addition, the directory `/home/me/sources' (specified by `-d sources') must exist and be readable. Note the optional spaces after `-c' and `-d'. $ gnatname -P/home/me/proj -dsources -dsources/plus -Dcommon_dirs.txt "body_*" "spec_*" Note that several switches `-d' may be used, even in conjunction with one or several switches `-D'. Several Naming Patterns are used in this example. GNAT Project Manager ******************** Introduction ============ This chapter describes GNAT's _Project Manager_, a facility that lets you configure various properties for a collection of source files. In particular, you can specify: * The directory or set of directories containing the source files, and/or the names of the specific source files themselves * The directory in which the compiler's output (`ALI' files, object files, tree files) will be placed * The directory in which the executable programs will be placed * Switch settings for any of the project-enabled tools (`gnatmake', compiler, binder, linker, `gnatls', `gnatxref', `gnatfind'); you can apply these settings either globally or to individual units * The source files containing the main subprogram(s) to be built * The source programming language(s) (currently Ada and/or C) * Source file naming conventions; you can specify these either globally or for individual units Project Files ------------- A "project" is a specific set of values for these properties. You can define a project's settings in a "project file", a text file with an Ada-like syntax; a property value is either a string or a list of strings. Properties that are not explicitly set receive default values. A project file may interrogate the values of "external variables" (user-defined command-line switches or environment variables), and it may specify property settings conditionally, based on the value of such variables. In simple cases, a project's source files depend only on other source files in the same project, or on the predefined libraries. ("Dependence" is in the technical sense; for example, one Ada unit "with"ing another.) However, the Project Manager also allows much more sophisticated arrangements, with the source files in one project depending on source files in other projects: * One project can _import_ other projects containing needed source files. * You can organize GNAT projects in a hierarchy: a _child_ project can extend a _parent_ project, inheriting the parent's source files and optionally overriding any of them with alternative versions More generally, the Project Manager lets you structure large development efforts into hierarchical subsystems, with build decisions deferred to the subsystem level and thus different compilation environments (switch settings) used for different subsystems. The Project Manager is invoked through the `-P_projectfile_' switch to `gnatmake' or to the `gnat' front driver. If you want to define (on the command line) an external variable that is queried by the project file, additionally use the `-X_vbl_=_value_' switch. The Project Manager parses and interprets the project file, and drives the invoked tool based on the project settings. The Project Manager supports a wide range of development strategies, for systems of all sizes. Some typical practices that are easily handled: * Using a common set of source files, but generating object files in different directories via different switch settings * Using a mostly-shared set of source files, but with different versions of some unit or units The destination of an executable can be controlled inside a project file using the `-o' switch. In the absence of such a switch either inside the project file or on the command line, any executable files generated by `gnatmake' will be placed in the directory `Exec_Dir' specified in the project file. If no `Exec_Dir' is specified, they will be placed in the object directory of the project. You can use project files to achieve some of the effects of a source versioning system (for example, defining separate projects for the different sets of sources that comprise different releases) but the Project Manager is independent of any source configuration management tools that might be used by the developers. The next section introduces the main features of GNAT's project facility through a sequence of examples; subsequent sections will present the syntax and semantics in more detail. Examples of Project Files ========================= This section illustrates some of the typical uses of project files and explains their basic structure and behavior. Common Sources with Different Switches and Different Output Directories ----------------------------------------------------------------------- Assume that the Ada source files `pack.ads', `pack.adb', and `proc.adb' are in the `/common' directory. The file `proc.adb' contains an Ada main subprogram `Proc' that "with"s package `Pack'. We want to compile these source files under two sets of switches: * When debugging, we want to pass the `-g' switch to `gnatmake', and the `-gnata', `-gnato', and `-gnatE' switches to the compiler; the compiler's output is to appear in `/common/debug' * When preparing a release version, we want to pass the `-O2' switch to the compiler; the compiler's output is to appear in `/common/release' The GNAT project files shown below, respectively `debug.gpr' and `release.gpr' in the `/common' directory, achieve these effects. Diagrammatically: /common debug.gpr release.gpr pack.ads pack.adb proc.adb /common/debug {-g, -gnata, -gnato, -gnatE} proc.ali, proc.o pack.ali, pack.o /common/release {-O2} proc.ali, proc.o pack.ali, pack.o Here are the project files: project Debug is for Object_Dir use "debug"; for Main use ("proc"); package Builder is for Default_Switches ("Ada") use ("-g"); end Builder; package Compiler is for Default_Switches ("Ada") use ("-fstack-check", "-gnata", "-gnato", "-gnatE"); end Compiler; end Debug; project Release is for Object_Dir use "release"; for Exec_Dir use "."; for Main use ("proc"); package Compiler is for Default_Switches ("Ada") use ("-O2"); end Compiler; end Release; The name of the project defined by `debug.gpr' is `"Debug"' (case insensitive), and analogously the project defined by `release.gpr' is `"Release"'. For consistency the file should have the same name as the project, and the project file's extension should be `"gpr"'. These conventions are not required, but a warning is issued if they are not followed. If the current directory is `/temp', then the command gnatmake -P/common/debug.gpr generates object and ALI files in `/common/debug', and the `proc' executable also in `/common/debug', using the switch settings defined in the project file. Likewise, the command gnatmake -P/common/release.gpr generates object and ALI files in `/common/release', and the `proc' executable in `/common', using the switch settings from the project file. Source Files ............ If a project file does not explicitly specify a set of source directories or a set of source files, then by default the project's source files are the Ada source files in the project file directory. Thus `pack.ads', `pack.adb', and `proc.adb' are the source files for both projects. Specifying the Object Directory ............................... Several project properties are modeled by Ada-style _attributes_; you define the property by supplying the equivalent of an Ada attribute definition clause in the project file. A project's object directory is such a property; the corresponding attribute is `Object_Dir', and its value is a string expression. A directory may be specified either as absolute or as relative; in the latter case, it is relative to the project file directory. Thus the compiler's output is directed to `/common/debug' (for the `Debug' project) and to `/common/release' (for the `Release' project). If `Object_Dir' is not specified, then the default is the project file directory. Specifying the Exec Directory ............................. A project's exec directory is another property; the corresponding attribute is `Exec_Dir', and its value is also a string expression, either specified as relative or absolute. If `Exec_Dir' is not specified, then the default is the object directory (which may also be the project file directory if attribute `Object_Dir' is not specified). Thus the executable is placed in `/common/debug' for the `Debug' project (attribute `Exec_Dir' not specified) and in `/common' for the `Release' project. Project File Packages ..................... A GNAT tool integrated with the Project Manager is modeled by a corresponding package in the project file. The `Debug' project defines the packages `Builder' (for `gnatmake') and `Compiler'; the `Release' project defines only the `Compiler' package. The Ada package syntax is not to be taken literally. Although packages in project files bear a surface resemblance to packages in Ada source code, the notation is simply a way to convey a grouping of properties for a named entity. Indeed, the package names permitted in project files are restricted to a predefined set, corresponding to the project-aware tools, and the contents of packages are limited to a small set of constructs. The packages in the example above contain attribute definitions. Specifying Switch Settings .......................... Switch settings for a project-aware tool can be specified through attributes in the package corresponding to the tool. The example above illustrates one of the relevant attributes, `Default_Switches', defined in the packages in both project files. Unlike simple attributes like `Source_Dirs', `Default_Switches' is known as an _associative array_. When you define this attribute, you must supply an "index" (a literal string), and the effect of the attribute definition is to set the value of the "array" at the specified "index". For the `Default_Switches' attribute, the index is a programming language (in our case, Ada) , and the value specified (after `use') must be a list of string expressions. The attributes permitted in project files are restricted to a predefined set. Some may appear at project level, others in packages. For any attribute that is an associate array, the index must always be a literal string, but the restrictions on this string (e.g., a file name or a language name) depend on the individual attribute. Also depending on the attribute, its specified value will need to be either a string or a string list. In the `Debug' project, we set the switches for two tools, `gnatmake' and the compiler, and thus we include corresponding packages, with each package defining the `Default_Switches' attribute with index `"Ada"'. Note that the package corresponding to `gnatmake' is named `Builder'. The `Release' project is similar, but with just the `Compiler' package. In project `Debug' above the switches starting with `-gnat' that are specified in package `Compiler' could have been placed in package `Builder', since `gnatmake' transmits all such switches to the compiler. Main Subprograms ................ One of the properties of a project is its list of main subprograms (actually a list of names of source files containing main subprograms, with the file extension optional. This property is captured in the `Main' attribute, whose value is a list of strings. If a project defines the `Main' attribute, then you do not need to identify the main subprogram(s) when invoking `gnatmake' (see *Note gnatmake and Project Files::). Source File Naming Conventions .............................. Since the project files do not specify any source file naming conventions, the GNAT defaults are used. The mechanism for defining source file naming conventions - a package named `Naming' - will be described below (*note Naming Schemes::). Source Language(s) .................. Since the project files do not specify a `Languages' attribute, by default the GNAT tools assume that the language of the project file is Ada. More generally, a project can comprise source files in Ada, C, and/or other languages. Using External Variables ------------------------ Instead of supplying different project files for debug and release, we can define a single project file that queries an external variable (set either on the command line or via an environment variable) in order to conditionally define the appropriate settings. Again, assume that the source files `pack.ads', `pack.adb', and `proc.adb' are located in directory `/common'. The following project file, `build.gpr', queries the external variable named `STYLE' and defines an object directory and switch settings based on whether the value is `"deb"' (debug) or `"rel"' (release), where the default is `"deb"'. project Build is for Main use ("proc"); type Style_Type is ("deb", "rel"); Style : Style_Type := external ("STYLE", "deb"); case Style is when "deb" => for Object_Dir use "debug"; when "rel" => for Object_Dir use "release"; for Exec_Dir use "."; end case; package Builder is case Style is when "deb" => for Default_Switches ("Ada") use ("-g"); end case; end Builder; package Compiler is case Style is when "deb" => for Default_Switches ("Ada") use ("-gnata", "-gnato", "-gnatE"); when "rel" => for Default_Switches ("Ada") use ("-O2"); end case; end Compiler; end Build; `Style_Type' is an example of a _string type_, which is the project file analog of an Ada enumeration type but containing string literals rather than identifiers. `Style' is declared as a variable of this type. The form `external("STYLE", "deb")' is known as an _external reference_; its first argument is the name of an _external variable_, and the second argument is a default value to be used if the external variable doesn't exist. You can define an external variable on the command line via the `-X' switch, or you can use an environment variable as an external variable. Each `case' construct is expanded by the Project Manager based on the value of `Style'. Thus the command gnatmake -P/common/build.gpr -XSTYLE=deb is equivalent to the `gnatmake' invocation using the project file `debug.gpr' in the earlier example. So is the command gnatmake -P/common/build.gpr since `"deb"' is the default for `STYLE'. Analogously, gnatmake -P/common/build.gpr -XSTYLE=rel is equivalent to the `gnatmake' invocation using the project file `release.gpr' in the earlier example. Importing Other Projects ------------------------ A compilation unit in a source file in one project may depend on compilation units in source files in other projects. To obtain this behavior, the dependent project must _import_ the projects containing the needed source files. This effect is embodied in syntax similar to an Ada `with' clause, but the "with"ed entities are strings denoting project files. As an example, suppose that the two projects `GUI_Proj' and `Comm_Proj' are defined in the project files `gui_proj.gpr' and `comm_proj.gpr' in directories `/gui' and `/comm', respectively. Assume that the source files for `GUI_Proj' are `gui.ads' and `gui.adb', and that the source files for `Comm_Proj' are `comm.ads' and `comm.adb', with each set of files located in its respective project file directory. Diagrammatically: /gui gui_proj.gpr gui.ads gui.adb /comm comm_proj.gpr comm.ads comm.adb We want to develop an application in directory `/app' that "with"s the packages `GUI' and `Comm', using the properties of the corresponding project files (e.g. the switch settings and object directory). Skeletal code for a main procedure might be something like the following: with GUI, Comm; procedure App_Main is ... begin ... end App_Main; Here is a project file, `app_proj.gpr', that achieves the desired effect: with "/gui/gui_proj", "/comm/comm_proj"; project App_Proj is for Main use ("app_main"); end App_Proj; Building an executable is achieved through the command: gnatmake -P/app/app_proj which will generate the `app_main' executable in the directory where `app_proj.gpr' resides. If an imported project file uses the standard extension (`gpr') then (as illustrated above) the `with' clause can omit the extension. Our example specified an absolute path for each imported project file. Alternatively, you can omit the directory if either * The imported project file is in the same directory as the importing project file, or * You have defined an environment variable `ADA_PROJECT_PATH' that includes the directory containing the needed project file. Thus, if we define `ADA_PROJECT_PATH' to include `/gui' and `/comm', then our project file `app_proj.gpr' could be written as follows: with "gui_proj", "comm_proj"; project App_Proj is for Main use ("app_main"); end App_Proj; Importing other projects raises the possibility of ambiguities. For example, the same unit might be present in different imported projects, or it might be present in both the importing project and an imported project. Both of these conditions are errors. Note that in the current version of the Project Manager, it is illegal to have an ambiguous unit even if the unit is never referenced by the importing project. This restriction may be relaxed in a future release. Extending a Project ------------------- A common situation in large software systems is to have multiple implementations for a common interface; in Ada terms, multiple versions of a package body for the same specification. For example, one implementation might be safe for use in tasking programs, while another might only be used in sequential applications. This can be modeled in GNAT using the concept of _project extension_. If one project (the "child") _extends_ another project (the "parent") then by default all source files of the parent project are inherited by the child, but the child project can override any of the parent's source files with new versions, and can also add new files. This facility is the project analog of extension in Object-Oriented Programming. Project hierarchies are permitted (a child project may be the parent of yet another project), and a project that inherits one project can also import other projects. As an example, suppose that directory `/seq' contains the project file `seq_proj.gpr' and the source files `pack.ads', `pack.adb', and `proc.adb': /seq pack.ads pack.adb proc.adb seq_proj.gpr Note that the project file can simply be empty (that is, no attribute or package is defined): project Seq_Proj is end Seq_Proj; implying that its source files are all the Ada source files in the project directory. Suppose we want to supply an alternate version of `pack.adb', in directory `/tasking', but use the existing versions of `pack.ads' and `proc.adb'. We can define a project `Tasking_Proj' that inherits `Seq_Proj': /tasking pack.adb tasking_proj.gpr project Tasking_Proj extends "/seq/seq_proj" is end Tasking_Proj; The version of `pack.adb' used in a build depends on which project file is specified. Note that we could have designed this using project import rather than project inheritance; a `base' project would contain the sources for `pack.ads' and `proc.adb', a sequential project would import `base' and add `pack.adb', and likewise a tasking project would import `base' and add a different version of `pack.adb'. The choice depends on whether other sources in the original project need to be overridden. If they do, then project extension is necessary, otherwise, importing is sufficient. Project File Syntax =================== This section describes the structure of project files. A project may be an _independent project_, entirely defined by a single project file. Any Ada source file in an independent project depends only on the predefined library and other Ada source files in the same project. A project may also "depend on" other projects, in either or both of the following ways: * It may import any number of projects * It may extend at most one other project The dependence relation is a directed acyclic graph (the subgraph reflecting the "extends" relation is a tree). A project's "immediate sources" are the source files directly defined by that project, either implicitly by residing in the project file's directory, or explicitly through any of the source-related attributes described below. More generally, a project PROJ's "sources" are the immediate sources of PROJ together with the immediate sources (unless overridden) of any project on which PROJ depends (either directly or indirectly). Basic Syntax ------------ As seen in the earlier examples, project files have an Ada-like syntax. The minimal project file is: project Empty is end Empty; The identifier `Empty' is the name of the project. This project name must be present after the reserved word `end' at the end of the project file, followed by a semi-colon. Any name in a project file, such as the project name or a variable name, has the same syntax as an Ada identifier. The reserved words of project files are the Ada reserved words plus `extends', `external', and `project'. Note that the only Ada reserved words currently used in project file syntax are: * `case' * `end' * `for' * `is' * `others' * `package' * `renames' * `type' * `use' * `when' * `with' Comments in project files have the same syntax as in Ada, two consecutives hyphens through the end of the line. Packages -------- A project file may contain _packages_. The name of a package must be one of the identifiers (case insensitive) from a predefined list, and a package with a given name may only appear once in a project file. The predefined list includes the following packages: * `Naming' * `Builder' * `Compiler' * `Binder' * `Linker' * `Finder' * `Cross_Reference' * `gnatls' (The complete list of the package names and their attributes can be found in file `prj-attr.adb'). In its simplest form, a package may be empty: project Simple is package Builder is end Builder; end Simple; A package may contain _attribute declarations_, _variable declarations_ and _case constructions_, as will be described below. When there is ambiguity between a project name and a package name, the name always designates the project. To avoid possible confusion, it is always a good idea to avoid naming a project with one of the names allowed for packages or any name that starts with `gnat'. Expressions ----------- An _expression_ is either a _string expression_ or a _string list expression_. A _string expression_ is either a _simple string expression_ or a _compound string expression_. A _simple string expression_ is one of the following: * A literal string; e.g.`"comm/my_proj.gpr"' * A string-valued variable reference (see *Note Variables::) * A string-valued attribute reference (see *Note Attributes::) * An external reference (see *Note External References in Project Files::) A _compound string expression_ is a concatenation of string expressions, using `"&"' Path & "/" & File_Name & ".ads" A _string list expression_ is either a _simple string list expression_ or a _compound string list expression_. A _simple string list expression_ is one of the following: * A parenthesized list of zero or more string expressions, separated by commas File_Names := (File_Name, "gnat.adc", File_Name & ".orig"); Empty_List := (); * A string list-valued variable reference * A string list-valued attribute reference A _compound string list expression_ is the concatenation (using `"&"') of a simple string list expression and an expression. Note that each term in a compound string list expression, except the first, may be either a string expression or a string list expression. File_Name_List := () & File_Name; -- One string in this list Extended_File_Name_List := File_Name_List & (File_Name & ".orig"); -- Two strings Big_List := File_Name_List & Extended_File_Name_List; -- Concatenation of two string lists: three strings Illegal_List := "gnat.adc" & Extended_File_Name_List; -- Illegal: must start with a string list String Types ------------ The value of a variable may be restricted to a list of string literals. The restricted list of string literals is given in a _string type declaration_. Here is an example of a string type declaration: type OS is ("NT, "nt", "Unix", "Linux", "other OS"); Variables of a string type are called _typed variables_; all other variables are called _untyped variables_. Typed variables are particularly useful in `case' constructions (see *Note case Constructions::). A string type declaration starts with the reserved word `type', followed by the name of the string type (case-insensitive), followed by the reserved word `is', followed by a parenthesized list of one or more string literals separated by commas, followed by a semicolon. The string literals in the list are case sensitive and must all be different. They may include any graphic characters allowed in Ada, including spaces. A string type may only be declared at the project level, not inside a package. A string type may be referenced by its name if it has been declared in the same project file, or by its project name, followed by a dot, followed by the string type name. Variables --------- A variable may be declared at the project file level, or in a package. Here are some examples of variable declarations: This_OS : OS := external ("OS"); -- a typed variable declaration That_OS := "Linux"; -- an untyped variable declaration A _typed variable declaration_ includes the variable name, followed by a colon, followed by the name of a string type, followed by `:=', followed by a simple string expression. An _untyped variable declaration_ includes the variable name, followed by `:=', followed by an expression. Note that, despite the terminology, this form of "declaration" resembles more an assignment than a declaration in Ada. It is a declaration in several senses: * The variable name does not need to be defined previously * The declaration establishes the _kind_ (string versus string list) of the variable, and later declarations of the same variable need to be consistent with this A string variable declaration (typed or untyped) declares a variable whose value is a string. This variable may be used as a string expression. File_Name := "readme.txt"; Saved_File_Name := File_Name & ".saved"; A string list variable declaration declares a variable whose value is a list of strings. The list may contain any number (zero or more) of strings. Empty_List := (); List_With_One_Element := ("-gnaty"); List_With_Two_Elements := List_With_One_Element & "-gnatg"; Long_List := ("main.ada", "pack1_.ada", "pack1.ada", "pack2_.ada" "pack2.ada", "util_.ada", "util.ada"); The same typed variable may not be declared more than once at project level, and it may not be declared more than once in any package; it is in effect a constant or a readonly variable. The same untyped variable may be declared several times. In this case, the new value replaces the old one, and any subsequent reference to the variable uses the new value. However, as noted above, if a variable has been declared as a string, all subsequent declarations must give it a string value. Similarly, if a variable has been declared as a string list, all subsequent declarations must give it a string list value. A _variable reference_ may take several forms: * The simple variable name, for a variable in the current package (if any) or in the current project * A context name, followed by a dot, followed by the variable name. A _context_ may be one of the following: * The name of an existing package in the current project * The name of an imported project of the current project * The name of an ancestor project (i.e., a project extended by the current project, either directly or indirectly) * An imported/parent project name, followed by a dot, followed by a package name A variable reference may be used in an expression. Attributes ---------- A project (and its packages) may have _attributes_ that define the project's properties. Some attributes have values that are strings; others have values that are string lists. There are two categories of attributes: _simple attributes_ and _associative arrays_ (see *Note Associative Array Attributes::). The names of the attributes are restricted; there is a list of project attributes, and a list of package attributes for each package. The names are not case sensitive. The project attributes are as follows (all are simple attributes): _Attribute Name_ _Value_ `Source_Files' string list `Source_Dirs' string list `Source_List_File' string `Object_Dir' string `Exec_Dir' string `Main' string list `Languages' string list `Library_Dir' string `Library_Name' string `Library_Kind' string `Library_Elaboration' string `Library_Version' string The attributes for package `Naming' are as follows (see *Note Naming Schemes::): Attribute Name Category Index Value `Specification_Suffix' associative language name string array `Implementation_Suffix' associative language name string array `Separate_Suffix' simple n/a string attribute `Casing' simple n/a string attribute `Dot_Replacement' simple n/a string attribute `Specification' associative Ada unit name string array `Implementation' associative Ada unit name string array `Specification_Exceptions' associative language name string list array `Implementation_Exceptions' associative language name string list array The attributes for package `Builder', `Compiler', `Binder', `Linker', `Cross_Reference', and `Finder' are as follows (see *Note Switches and Project Files::). Attribute Name Category Index Value `Default_Switches' associative language name string list array `Switches' associative file name string list array In addition, package `Builder' has a single string attribute `Local_Configuration_Pragmas' and package `Builder' has a single string attribute `Global_Configuration_Pragmas'. The attribute for package `Glide' are not documented: they are for internal use only. Each simple attribute has a default value: the empty string (for string-valued attributes) and the empty list (for string list-valued attributes). Similar to variable declarations, an attribute declaration defines a new value for an attribute. Examples of simple attribute declarations: for Object_Dir use "objects"; for Source_Dirs use ("units", "test/drivers"); A "simple attribute declaration" starts with the reserved word `for', followed by the name of the attribute, followed by the reserved word `use', followed by an expression (whose kind depends on the attribute), followed by a semicolon. Attributes may be referenced in expressions. The general form for such a reference is `'': the entity for which the attribute is defined, followed by an apostrophe, followed by the name of the attribute. For associative array attributes, a litteral string between parentheses need to be supplied as index. Examples are: project'Object_Dir Naming'Dot_Replacement Imported_Project'Source_Dirs Imported_Project.Naming'Casing Builder'Default_Switches("Ada") The entity may be: * `project' for an attribute of the current project * The name of an existing package of the current project * The name of an imported project * The name of a parent project (extended by the current project) * An imported/parent project name, followed by a dot, followed by a package name Example: project Prj is for Source_Dirs use project'Source_Dirs & "units"; for Source_Dirs use project'Source_Dirs & "test/drivers" end Prj; In the first attribute declaration, initially the attribute `Source_Dirs' has the default value: an empty string list. After this declaration, `Source_Dirs' is a string list of one element: "units". After the second attribute declaration `Source_Dirs' is a string list of two elements: "units" and "test/drivers". Note: this example is for illustration only. In practice, the project file would contain only one attribute declaration: for Source_Dirs use ("units", "test/drivers"); Associative Array Attributes ---------------------------- Some attributes are defined as _associative arrays_. An associative array may be regarded as a function that takes a string as a parameter and delivers a string or string list value as its result. Here are some examples of associative array attribute declarations: for Implementation ("main") use "Main.ada"; for Switches ("main.ada") use ("-v", "-gnatv"); for Switches ("main.ada") use Builder'Switches ("main.ada") & "-g"; Like untyped variables and simple attributes, associative array attributes may be declared several times. Each declaration supplies a new value for the attribute, replacing the previous setting. `case' Constructions -------------------- A `case' construction is used in a project file to effect conditional behavior. Here is a typical example: project MyProj is type OS_Type is ("Linux", "Unix", "NT", "VMS"); OS : OS_Type := external ("OS", "Linux"); package Compiler is case OS is when "Linux" | "Unix" => for Default_Switches ("Ada") use ("-gnath"); when "NT" => for Default_Switches ("Ada") use ("-gnatP"); when others => end case; end Compiler; end MyProj; The syntax of a `case' construction is based on the Ada case statement (although there is no `null' construction for empty alternatives). Following the reserved word `case' there is the case variable (a typed string variable), the reserved word `is', and then a sequence of one or more alternatives. Each alternative comprises the reserved word `when', either a list of literal strings separated by the `"|"' character or the reserved word `others', and the `"=>"' token. Each literal string must belong to the string type that is the type of the case variable. An `others' alternative, if present, must occur last. The `end case;' sequence terminates the case construction. After each `=>', there are zero or more constructions. The only constructions allowed in a case construction are other case constructions and attribute declarations. String type declarations, variable declarations and package declarations are not allowed. The value of the case variable is often given by an external reference (see *Note External References in Project Files::). Objects and Sources in Project Files ==================================== Each project has exactly one object directory and one or more source directories. The source directories must contain at least one source file, unless the project file explicitly specifies that no source files are present (see *Note Source File Names::). Object Directory ---------------- The object directory for a project is the directory containing the compiler's output (such as `ALI' files and object files) for the project's immediate sources. Note that for inherited sources (when extending a parent project) the parent project's object directory is used. The object directory is given by the value of the attribute `Object_Dir' in the project file. for Object_Dir use "objects"; The attribute OBJECT_DIR has a string value, the path name of the object directory. The path name may be absolute or relative to the directory of the project file. This directory must already exist, and be readable and writable. By default, when the attribute `Object_Dir' is not given an explicit value or when its value is the empty string, the object directory is the same as the directory containing the project file. Exec Directory -------------- The exec directory for a project is the directory containing the executables for the project's main subprograms. The exec directory is given by the value of the attribute `Exec_Dir' in the project file. for Exec_Dir use "executables"; The attribute EXEC_DIR has a string value, the path name of the exec directory. The path name may be absolute or relative to the directory of the project file. This directory must already exist, and be writable. By default, when the attribute `Exec_Dir' is not given an explicit value or when its value is the empty string, the exec directory is the same as the object directory of the project file. Source Directories ------------------ The source directories of a project are specified by the project file attribute `Source_Dirs'. This attribute's value is a string list. If the attribute is not given an explicit value, then there is only one source directory, the one where the project file resides. A `Source_Dirs' attribute that is explicitly defined to be the empty list, as in for Source_Dirs use (); indicates that the project contains no source files. Otherwise, each string in the string list designates one or more source directories. for Source_Dirs use ("sources", "test/drivers"); If a string in the list ends with `"/**"', then the directory whose path name precedes the two asterisks, as well as all its subdirectories (recursively), are source directories. for Source_Dirs use ("/system/sources/**"); Here the directory `/system/sources' and all of its subdirectories (recursively) are source directories. To specify that the source directories are the directory of the project file and all of its subdirectories, you can declare `Source_Dirs' as follows: for Source_Dirs use ("./**"); Each of the source directories must exist and be readable. Source File Names ----------------- In a project that contains source files, their names may be specified by the attributes `Source_Files' (a string list) or `Source_List_File' (a string). Source file names never include any directory information. If the attribute `Source_Files' is given an explicit value, then each element of the list is a source file name. for Source_Files use ("main.adb"); for Source_Files use ("main.adb", "pack1.ads", "pack2.adb"); If the attribute `Source_Files' is not given an explicit value, but the attribute `Source_List_File' is given a string value, then the source file names are contained in the text file whose path name (absolute or relative to the directory of the project file) is the value of the attribute `Source_List_File'. Each line in the file that is not empty or is not a comment contains a source file name. A comment line starts with two hyphens. for Source_List_File use "source_list.txt"; By default, if neither the attribute `Source_Files' nor the attribute `Source_List_File' is given an explicit value, then each file in the source directories that conforms to the project's naming scheme (see *Note Naming Schemes::) is an immediate source of the project. A warning is issued if both attributes `Source_Files' and `Source_List_File' are given explicit values. In this case, the attribute `Source_Files' prevails. Each source file name must be the name of one and only one existing source file in one of the source directories. A `Source_Files' attribute defined with an empty list as its value indicates that there are no source files in the project. Except for projects that are clearly specified as containing no Ada source files (`Source_Dirs' or `Source_Files' specified as an empty list, or `Languages' specified without `"Ada"' in the list) for Source_Dirs use (); for Source_Files use (); for Languages use ("C", "C++"); a project must contain at least one immediate source. Projects with no source files are useful as template packages (see *Note Packages in Project Files::) for other projects; in particular to define a package `Naming' (see *Note Naming Schemes::). Importing Projects ================== An immediate source of a project P may depend on source files that are neither immediate sources of P nor in the predefined library. To get this effect, P must _import_ the projects that contain the needed source files. with "project1", "utilities.gpr"; with "/namings/apex.gpr"; project Main is ... As can be seen in this example, the syntax for importing projects is similar to the syntax for importing compilation units in Ada. However, project files use literal strings instead of names, and the `with' clause identifies project files rather than packages. Each literal string is the file name or path name (absolute or relative) of a project file. If a string is simply a file name, with no path, then its location is determined by the _project path_: * If the environment variable `ADA_PROJECT_PATH' exists, then the project path includes all the directories in this environment variable, plus the directory of the project file. * If the environment variable `ADA_PROJECT_PATH' does not exist, then the project path contains only one directory, namely the one where the project file is located. If a relative pathname is used as in with "tests/proj"; then the path is relative to the directory where the importing project file is located. Any symbolic link will be fully resolved in the directory of the importing project file before the imported project file is looked up. When the `with''ed project file name does not have an extension, the default is `.gpr'. If a file with this extension is not found, then the file name as specified in the `with' clause (no extension) will be used. In the above example, if a file `project1.gpr' is found, then it will be used; otherwise, if a file `project1' exists then it will be used; if neither file exists, this is an error. A warning is issued if the name of the project file does not match the name of the project; this check is case insensitive. Any source file that is an immediate source of the imported project can be used by the immediate sources of the importing project, and recursively. Thus if `A' imports `B', and `B' imports `C', the immediate sources of `A' may depend on the immediate sources of `C', even if `A' does not import `C' explicitly. However, this is not recommended, because if and when `B' ceases to import `C', some sources in `A' will no longer compile. A side effect of this capability is that cyclic dependences are not permitted: if `A' imports `B' (directly or indirectly) then `B' is not allowed to import `A'. Project Extension ================= During development of a large system, it is sometimes necessary to use modified versions of some of the source files without changing the original sources. This can be achieved through a facility known as _project extension_. project Modified_Utilities extends "/baseline/utilities.gpr" is ... The project file for the project being extended (the _parent_) is identified by the literal string that follows the reserved word `extends', which itself follows the name of the extending project (the _child_). By default, a child project inherits all the sources of its parent. However, inherited sources can be overridden: a unit with the same name as one in the parent will hide the original unit. Inherited sources are considered to be sources (but not immediate sources) of the child project; see *Note Project File Syntax::. An inherited source file retains any switches specified in the parent project. For example if the project `Utilities' contains the specification and the body of an Ada package `Util_IO', then the project `Modified_Utilities' can contain a new body for package `Util_IO'. The original body of `Util_IO' will not be considered in program builds. However, the package specification will still be found in the project `Utilities'. A child project can have only one parent but it may import any number of other projects. A project is not allowed to import directly or indirectly at the same time a child project and any of its ancestors. External References in Project Files ==================================== A project file may contain references to external variables; such references are called _external references_. An external variable is either defined as part of the environment (an environment variable in Unix, for example) or else specified on the command line via the `-X_vbl_=_value_' switch. If both, then the command line value is used. An external reference is denoted by the built-in function `external', which returns a string value. This function has two forms: * `external (external_variable_name)' * `external (external_variable_name, default_value)' Each parameter must be a string literal. For example: external ("USER") external ("OS", "Linux") In the form with one parameter, the function returns the value of the external variable given as parameter. If this name is not present in the environment, then the returned value is an empty string. In the form with two string parameters, the second parameter is the value returned when the variable given as the first parameter is not present in the environment. In the example above, if `"OS"' is not the name of an environment variable and is not passed on the command line, then the returned value will be `"Linux"'. An external reference may be part of a string expression or of a string list expression, to define variables or attributes. type Mode_Type is ("Debug", "Release"); Mode : Mode_Type := external ("MODE"); case Mode is when "Debug" => ... Packages in Project Files ========================= The _package_ is the project file feature that defines the settings for project-aware tools. For each such tool you can declare a corresponding package; the names for these packages are preset (see *Note Packages::) but are not case sensitive. A package may contain variable declarations, attribute declarations, and case constructions. project Proj is package Builder is -- used by gnatmake for Default_Switches ("Ada") use ("-v", "-g"); end Builder; end Proj; A package declaration starts with the reserved word `package', followed by the package name (case insensitive), followed by the reserved word `is'. It ends with the reserved word `end', followed by the package name, finally followed by a semi-colon. Most of the packages have an attribute `Default_Switches'. This attribute is an associative array, and its value is a string list. The index of the associative array is the name of a programming language (case insensitive). This attribute indicates the switch or switches to be used with the corresponding tool. Some packages also have another attribute, `Switches', an associative array whose value is a string list. The index is the name of a source file. This attribute indicates the switch or switches to be used by the corresponding tool when dealing with this specific file. Further information on these switch-related attributes is found in *Note Switches and Project Files::. A package may be declared as a _renaming_ of another package; e.g., from the project file for an imported project. with "/global/apex.gpr"; project Example is package Naming renames Apex.Naming; ... end Example; Packages that are renamed in other project files often come from project files that have no sources: they are just used as templates. Any modification in the template will be reflected automatically in all the project files that rename a package from the template. In addition to the tool-oriented packages, you can also declare a package named `Naming' to establish specialized source file naming conventions (see *Note Naming Schemes::). Variables from Imported Projects ================================ An attribute or variable defined in an imported or parent project can be used in expressions in the importing / extending project. Such an attribute or variable is prefixed with the name of the project and (if relevant) the name of package where it is defined. with "imported"; project Main extends "base" is Var1 := Imported.Var; Var2 := Base.Var & ".new"; package Builder is for Default_Switches ("Ada") use Imported.Builder.Ada_Switches & "-gnatg" & "-v"; end Builder; package Compiler is for Default_Switches ("Ada") use Base.Compiler.Ada_Switches; end Compiler; end Main; In this example: * `Var1' is a copy of the variable `Var' defined in the project file `"imported.gpr"' * the value of `Var2' is a copy of the value of variable `Var' defined in the project file `base.gpr', concatenated with `".new"' * attribute `Default_Switches ("Ada")' in package `Builder' is a string list that includes in its value a copy of variable `Ada_Switches' defined in the `Builder' package in project file `imported.gpr' plus two new elements: `"-gnatg"' and `"-v"'; * attribute `Default_Switches ("Ada")' in package `Compiler' is a copy of the variable `Ada_Switches' defined in the `Compiler' package in project file `base.gpr', the project being extended. Naming Schemes ============== Sometimes an Ada software system is ported from a foreign compilation environment to GNAT, with file names that do not use the default GNAT conventions. Instead of changing all the file names (which for a variety of reasons might not be possible), you can define the relevant file naming scheme in the `Naming' package in your project file. For example, the following package models the Apex file naming rules: package Naming is for Casing use "lowercase"; for Dot_Replacement use "."; for Specification_Suffix ("Ada") use ".1.ada"; for Implementation_Suffix ("Ada") use ".2.ada"; end Naming; You can define the following attributes in package `Naming': `CASING' This must be a string with one of the three values `"lowercase"', `"uppercase"' or `"mixedcase"'; these strings are case insensitive. If CASING is not specified, then the default is `"lowercase"'. `DOT_REPLACEMENT' This must be a string whose value satisfies the following conditions: * It must not be empty * It cannot start or end with an alphanumeric character * It cannot be a single underscore * It cannot start with an underscore followed by an alphanumeric * It cannot contain a dot `'.'' except if it the entire string is `"."' If `Dot_Replacement' is not specified, then the default is `"-"'. `SPECIFICATION_SUFFIX' This is an associative array (indexed by the programming language name, case insensitive) whose value is a string that must satisfy the following conditions: * It must not be empty * It cannot start with an alphanumeric character * It cannot start with an underscore followed by an alphanumeric character If `Specification_Suffix ("Ada")' is not specified, then the default is `".ads"'. `IMPLEMENTATION_SUFFIX' This is an associative array (indexed by the programming language name, case insensitive) whose value is a string that must satisfy the following conditions: * It must not be empty * It cannot start with an alphanumeric character * It cannot start with an underscore followed by an alphanumeric character * It cannot be a suffix of `Specification_Suffix' If `Implementation_Suffix ("Ada")' is not specified, then the default is `".adb"'. `SEPARATE_SUFFIX' This must be a string whose value satisfies the same conditions as `Implementation_Suffix'. If `Separate_Suffix ("Ada")' is not specified, then it defaults to same value as `Implementation_Suffix ("Ada")'. `SPECIFICATION' You can use the `Specification' attribute, an associative array, to define the source file name for an individual Ada compilation unit's spec. The array index must be a string literal that identifies the Ada unit (case insensitive). The value of this attribute must be a string that identifies the file that contains this unit's spec (case sensitive or insensitive depending on the operating system). for Specification ("MyPack.MyChild") use "mypack.mychild.spec"; `IMPLEMENTATION' You can use the `Implementation' attribute, an associative array, to define the source file name for an individual Ada compilation unit's body (possibly a subunit). The array index must be a string literal that identifies the Ada unit (case insensitive). The value of this attribute must be a string that identifies the file that contains this unit's body or subunit (case sensitive or insensitive depending on the operating system). for Implementation ("MyPack.MyChild") use "mypack.mychild.body"; Library Projects ================ _Library projects_ are projects whose object code is placed in a library. (Note that this facility is not yet supported on all platforms) To create a library project, you need to define in its project file two project-level attributes: `Library_Name' and `Library_Dir'. Additionally, you may define the library-related attributes `Library_Kind', `Library_Version' and `Library_Elaboration'. The `Library_Name' attribute has a string value that must start with a letter and include only letters and digits. The `Library_Dir' attribute has a string value that designates the path (absolute or relative) of the directory where the library will reside. It must designate an existing directory, and this directory needs to be different from the project's object directory. It also needs to be writable. If both `Library_Name' and `Library_Dir' are specified and are legal, then the project file defines a library project. The optional library-related attributes are checked only for such project files. The `Library_Kind' attribute has a string value that must be one of the following (case insensitive): `"static"', `"dynamic"' or `"relocatable"'. If this attribute is not specified, the library is a static library. Otherwise, the library may be dynamic or relocatable. Depending on the operating system, there may or may not be a distinction between dynamic and relocatable libraries. For example, on Unix there is no such distinction. The `Library_Version' attribute has a string value whose interpretation is platform dependent. On Unix, it is used only for dynamic/relocatable libraries as the internal name of the library (the `"soname"'). If the library file name (built from the `Library_Name') is different from the `Library_Version', then the library file will be a symbolic link to the actual file whose name will be `Library_Version'. Example (on Unix): project Plib is Version := "1"; for Library_Dir use "lib_dir"; for Library_Name use "dummy"; for Library_Kind use "relocatable"; for Library_Version use "libdummy.so." & Version; end Plib; Directory `lib_dir' will contain the internal library file whose name will be `libdummy.so.1', and `libdummy.so' will be a symbolic link to `libdummy.so.1'. When `gnatmake' detects that a project file (not the main project file) is a library project file, it will check all immediate sources of the project and rebuild the library if any of the sources have been recompiled. All `ALI' files will also be copied from the object directory to the library directory. To build executables, `gnatmake' will use the library rather than the individual object files. Switches Related to Project Files ================================= The following switches are used by GNAT tools that support project files: ``-PPROJECT'' Indicates the name of a project file. This project file will be parsed with the verbosity indicated by `-vP_x_', if any, and using the external references indicated by `-X' switches, if any. There must be only one `-P' switch on the command line. Since the Project Manager parses the project file only after all the switches on the command line are checked, the order of the switches `-P', `-Vp_x_' or `-X' is not significant. ``-XNAME=VALUE'' Indicates that external variable NAME has the value VALUE. The Project Manager will use this value for occurrences of `external(name)' when parsing the project file. If NAME or VALUE includes a space, then NAME=VALUE should be put between quotes. -XOS=NT -X"user=John Doe" Several `-X' switches can be used simultaneously. If several `-X' switches specify the same NAME, only the last one is used. An external variable specified with a `-X' switch takes precedence over the value of the same name in the environment. ``-vP_x_'' Indicates the verbosity of the parsing of GNAT project files. `-vP0' means Default (no output for syntactically correct project files); `-vP1' means Medium; `-vP2' means High. The default is Default. If several `-vP_x_' switches are present, only the last one is used. Tools Supporting Project Files ============================== gnatmake and Project Files -------------------------- This section covers two topics related to `gnatmake' and project files: defining switches for `gnatmake' and for the tools that it invokes; and the use of the `Main' attribute. Switches and Project Files .......................... For each of the packages `Builder', `Compiler', `Binder', and `Linker', you can specify a `Default_Switches' attribute, a `Switches' attribute, or both; as their names imply, these switch-related attributes affect which switches are used for which files when `gnatmake' is invoked. As will be explained below, these package-contributed switches precede the switches passed on the `gnatmake' command line. The `Default_Switches' attribute is an associative array indexed by language name (case insensitive) and returning a string list. For example: package Compiler is for Default_Switches ("Ada") use ("-gnaty", "-v"); end Compiler; The `Switches' attribute is also an associative array, indexed by a file name (which may or may not be case sensitive, depending on the operating system) and returning a string list. For example: package Builder is for Switches ("main1.adb") use ("-O2"); for Switches ("main2.adb") use ("-g"); end Builder; For the `Builder' package, the file names should designate source files for main subprograms. For the `Binder' and `Linker' packages, the file names should designate `ALI' or source files for main subprograms. In each case just the file name (without explicit extension) is acceptable. For each tool used in a program build (`gnatmake', the compiler, the binder, and the linker), its corresponding package "contributes" a set of switches for each file on which the tool is invoked, based on the switch-related attributes defined in the package. In particular, the switches that each of these packages contributes for a given file F comprise: * the value of attribute `Switches (F)', if it is specified in the package for the given file, * otherwise, the value of `Default_Switches ("Ada")', if it is specified in the package. If neither of these attributes is defined in the package, then the package does not contribute any switches for the given file. When `gnatmake' is invoked on a file, the switches comprise two sets, in the following order: those contributed for the file by the `Builder' package; and the switches passed on the command line. When `gnatmake' invokes a tool (compiler, binder, linker) on a file, the switches passed to the tool comprise three sets, in the following order: 1. the applicable switches contributed for the file by the `Builder' package in the project file supplied on the command line; 2. those contributed for the file by the package (in the relevant project file - see below) corresponding to the tool; and 3. the applicable switches passed on the command line. The term _applicable switches_ reflects the fact that `gnatmake' switches may or may not be passed to individual tools, depending on the individual switch. `gnatmake' may invoke the compiler on source files from different projects. The Project Manager will use the appropriate project file to determine the `Compiler' package for each source file being compiled. Likewise for the `Binder' and `Linker' packages. As an example, consider the following package in a project file: project Proj1 is package Compiler is for Default_Switches ("Ada") use ("-g"); for Switches ("a.adb") use ("-O1"); for Switches ("b.adb") use ("-O2", "-gnaty"); end Compiler; end Proj1; If `gnatmake' is invoked with this project file, and it needs to compile, say, the files `a.adb', `b.adb', and `c.adb', then `a.adb' will be compiled with the switch `-O1', `b.adb' with switches `-O2' and `-gnaty', and `c.adb' with `-g'. Another example illustrates the ordering of the switches contributed by different packages: project Proj2 is package Builder is for Switches ("main.adb") use ("-g", "-O1", "-f"); end Builder; package Compiler is for Switches ("main.adb") use ("-O2"); end Compiler; end Proj2; If you issue the command: gnatmake -PProj2 -O0 main then the compiler will be invoked on `main.adb' with the following sequence of switches -g -O1 -O2 -O0 with the last `-O' switch having precedence over the earlier ones; several other switches (such as `-c') are added implicitly. The switches `-g' and `-O1' are contributed by package `Builder', `-O2' is contributed by the package `Compiler' and `-O0' comes from the command line. The `-g' switch will also be passed in the invocation of `gnatlink.' A final example illustrates switch contributions from packages in different project files: project Proj3 is for Source_Files use ("pack.ads", "pack.adb"); package Compiler is for Default_Switches ("Ada") use ("-gnata"); end Compiler; end Proj3; with "Proj3"; project Proj4 is for Source_Files use ("foo_main.adb", "bar_main.adb"); package Builder is for Switches ("foo_main.adb") use ("-s", "-g"); end Builder; end Proj4; -- Ada source file: with Pack; procedure Foo_Main is ... end Foo_Main; If the command is gnatmake -PProj4 foo_main.adb -cargs -gnato then the switches passed to the compiler for `foo_main.adb' are `-g' (contributed by the package `Proj4.Builder') and `-gnato' (passed on the command line). When the imported package `Pack' is compiled, the switches used are `-g' from `Proj4.Builder', `-gnata' (contributed from package `Proj3.Compiler', and `-gnato' from the command line. Project Files and Main Subprograms .................................. When using a project file, you can invoke `gnatmake' with several main subprograms, by specifying their source files on the command line. Each of these needs to be an immediate source file of the project. gnatmake -Pprj main1 main2 main3 When using a project file, you can also invoke `gnatmake' without explicitly specifying any main, and the effect depends on whether you have defined the `Main' attribute. This attribute has a string list value, where each element in the list is the name of a source file (the file extension is optional) containing a main subprogram. If the `Main' attribute is defined in a project file as a non-empty string list and the switch `-u' is not used on the command line, then invoking `gnatmake' with this project file but without any main on the command line is equivalent to invoking `gnatmake' with all the file names in the `Main' attribute on the command line. Example: project Prj is for Main use ("main1", "main2", "main3"); end Prj; With this project file, `"gnatmake -Pprj"' is equivalent to `"gnatmake -Pprj main1 main2 main3"'. When the project attribute `Main' is not specified, or is specified as an empty string list, or when the switch `-u' is used on the command line, then invoking `gnatmake' with no main on the command line will result in all immediate sources of the project file being checked, and potentially recompiled. Depending on the presence of the switch `-u', sources from other project files on which the immediate sources of the main project file depend are also checked and potentially recompiled. In other words, the `-u' switch is applied to all of the immediate sources of themain project file. The GNAT Driver and Project Files --------------------------------- A number of GNAT tools, other than `gnatmake' are project-aware: `gnatbind', `gnatfind', `gnatlink', `gnatls' and `gnatxref'. However, none of these tools can be invoked directly with a project file switch (`-P'). They need to be invoke through the `gnat' driver. The `gnat' driver is a front-end that accepts a number of commands and call the corresponding tool. It has been designed initially for VMS to convert VMS style qualifiers to Unix style switches, but it is now available to all the GNAT supported platforms. On non VMS platforms, the `gnat' driver accepts the following commands (case insensitive): * BIND to invoke `gnatbind' * CHOP to invoke `gnatchop' * COMP or COMPILE to invoke the compiler * ELIM to invoke `gnatelim' * FIND to invoke `gnatfind' * KR or KRUNCH to invoke `gnatkr' * LINK to invoke `gnatlink' * LS or LIST to invoke `gnatls' * MAKE to invoke `gnatmake' * NAME to invoke `gnatname' * PREP or PREPROCESS to invoke `gnatprep' * PSTA or STANDARD to invoke `gnatpsta' * STUB to invoke `gnatstub' * XREF to invoke `gnatxref' Note that the compiler is invoked using the command `gnatmake -f -u'. Following the command, you may put switches and arguments for the invoked tool. gnat bind -C main.ali gnat ls -a main gnat chop foo.txt In addition, for command BIND, FIND, LS or LIST, LINK and XREF, the project file related switches (`-P', `-X' and `-vPx') may be used in addition to the switches of the invoking tool. For each of these command, there is possibly a package in the main project that corresponds to the invoked tool. * package `Binder' for command BIND (invoking `gnatbind') * package `Finder' for command FIND (invoking `gnatfind') * package `Gnatls' for command LS or LIST (invoking `gnatls') * package `Linker' for command LINK (invoking `gnatlink') * package `Cross_Reference' for command XREF (invoking `gnatlink') Package `Gnatls' has a unique attribute `Switches', a simple variable with a string list value. It contains switches for the invocation of `gnatls'. project Proj1 is package gnatls is for Switches use ("-a", "-v"); end gnatls; end Proj1; All other packages contains a switch `Default_Switches', an associative array, indexed by the programming language (case insensitive) and having a string list value. `Default_Switches ("Ada")' contains the switches for the invocation of the tool corresponding to the package. project Proj is for Source_Dirs use ("./**"); package gnatls is for Switches use ("-a", "-v"); end gnatls; package Binder is for Default_Switches ("Ada") use ("-C", "-e"); end Binder; package Linker is for Default_Switches ("Ada") use ("-C"); end Linker; package Finder is for Default_Switches ("Ada") use ("-a", "-f"); end Finder; package Cross_Reference is for Default_Switches ("Ada") use ("-a", "-f", "-d", "-u"); end Cross_Reference; end Proj; With the above project file, commands such as gnat ls -Pproj main gnat xref -Pproj main gnat bind -Pproj main.ali will set up the environment properly and invoke the tool with the switches found in the package corresponding to the tool. Glide and Project Files ----------------------- Glide will automatically recognize the `.gpr' extension for project files, and will convert them to its own internal format automatically. However, it doesn't provide a syntax-oriented editor for modifying these files. The project file will be loaded as text when you select the menu item `Ada' => `Project' => `Edit'. You can edit this text and save the `gpr' file; when you next select this project file in Glide it will be automatically reloaded. An Extended Example =================== Suppose that we have two programs, PROG1 and PROG2, with the sources in the respective directories. We would like to build them with a single `gnatmake' command, and we would like to place their object files into `.build' subdirectories of the source directories. Furthermore, we would like to have to have two separate subdirectories in `.build' - `release' and `debug' - which will contain the object files compiled with different set of compilation flags. In other words, we have the following structure: main |- prog1 | |- .build | | debug | | release |- prog2 |- .build | debug | release Here are the project files that we need to create in a directory `main' to maintain this structure: 1. We create a `Common' project with a package `Compiler' that specifies the compilation switches: File "common.gpr": project Common is for Source_Dirs use (); -- No source files type Build_Type is ("release", "debug"); Build : Build_Type := External ("BUILD", "debug"); package Compiler is case Build is when "release" => for Default_Switches ("Ada") use ("-O2"); when "debug" => for Default_Switches ("Ada") use ("-g"); end case; end Compiler; end Common; 2. We create separate projects for the two programs: File "prog1.gpr": with "common"; project Prog1 is for Source_Dirs use ("prog1"); for Object_Dir use "prog1/.build/" & Common.Build; package Compiler renames Common.Compiler; end Prog1; File "prog2.gpr": with "common"; project Prog2 is for Source_Dirs use ("prog2"); for Object_Dir use "prog2/.build/" & Common.Build; package Compiler renames Common.Compiler; end Prog2; 3. We create a wrapping project MAIN: File "main.gpr": with "common"; with "prog1"; with "prog2"; project Main is package Compiler renames Common.Compiler; end Main; 4. Finally we need to create a dummy procedure that `with's (either explicitly or implicitly) all the sources of our two programs. Now we can build the programs using the command gnatmake -Pmain dummy for the Debug mode, or gnatmake -Pmain -XBUILD=release for the Release mode. Project File Complete Syntax ============================ project ::= context_clause project_declaration context_clause ::= {with_clause} with_clause ::= with literal_string { , literal_string } ; project_declaration ::= project simple_name [ extends literal_string ] is {declarative_item} end simple_name; declarative_item ::= package_declaration | typed_string_declaration | other_declarative_item package_declaration ::= package simple_name package_completion package_completion ::= package_body | package_renaming package body ::= is {other_declarative_item} end simple_name ; package_renaming ::== renames simple_name.simple_name ; typed_string_declaration ::= type _simple_name is ( literal_string {, literal_string} ); other_declarative_item ::= attribute_declaration | typed_variable_declaration | variable_declaration | case_construction attribute_declaration ::= for attribute use expression ; attribute ::= simple_name | simple_name ( literal_string ) typed_variable_declaration ::= simple_name : name := string_expression ; variable_declaration ::= simple_name := expression; expression ::= term {& term} term ::= literal_string | string_list | name | external_value | attribute_reference literal_string ::= (same as Ada) string_list ::= ( expression { , expression } ) external_value ::= external ( literal_string [, literal_string] ) attribute_reference ::= attribute_parent ' simple_name [ ( literal_string ) ] attribute_parent ::= project | simple_name | simple_name . simple_name case_construction ::= case name is {case_item} end case ; case_item ::= when discrete_choice_list => {case_construction | attribute_declaration} discrete_choice_list ::= literal_string {| literal_string} name ::= simple_name {. simple_name} simple_name ::= identifier (same as Ada) Elaboration Order Handling in GNAT ********************************** This chapter describes the handling of elaboration code in Ada 95 and in GNAT, and discusses how the order of elaboration of program units can be controlled in GNAT, either automatically or with explicit programming features. Elaboration Code in Ada 95 ========================== Ada 95 provides rather general mechanisms for executing code at elaboration time, that is to say before the main program starts executing. Such code arises in three contexts: Initializers for variables. Variables declared at the library level, in package specs or bodies, can require initialization that is performed at elaboration time, as in: Sqrt_Half : Float := Sqrt (0.5); Package initialization code Code in a `BEGIN-END' section at the outer level of a package body is executed as part of the package body elaboration code. Library level task allocators Tasks that are declared using task allocators at the library level start executing immediately and hence can execute at elaboration time. Subprogram calls are possible in any of these contexts, which means that any arbitrary part of the program may be executed as part of the elaboration code. It is even possible to write a program which does all its work at elaboration time, with a null main program, although stylistically this would usually be considered an inappropriate way to structure a program. An important concern arises in the context of elaboration code: we have to be sure that it is executed in an appropriate order. What we have is a series of elaboration code sections, potentially one section for each unit in the program. It is important that these execute in the correct order. Correctness here means that, taking the above example of the declaration of `Sqrt_Half', if some other piece of elaboration code references `Sqrt_Half', then it must run after the section of elaboration code that contains the declaration of `Sqrt_Half'. There would never be any order of elaboration problem if we made a rule that whenever you `with' a unit, you must elaborate both the spec and body of that unit before elaborating the unit doing the `with''ing: with Unit_1; package Unit_2 is ... would require that both the body and spec of `Unit_1' be elaborated before the spec of `Unit_2'. However, a rule like that would be far too restrictive. In particular, it would make it impossible to have routines in separate packages that were mutually recursive. You might think that a clever enough compiler could look at the actual elaboration code and determine an appropriate correct order of elaboration, but in the general case, this is not possible. Consider the following example. In the body of `Unit_1', we have a procedure `Func_1' that references the variable `Sqrt_1', which is declared in the elaboration code of the body of `Unit_1': Sqrt_1 : Float := Sqrt (0.1); The elaboration code of the body of `Unit_1' also contains: if expression_1 = 1 then Q := Unit_2.Func_2; end if; `Unit_2' is exactly parallel, it has a procedure `Func_2' that references the variable `Sqrt_2', which is declared in the elaboration code of the body `Unit_2': Sqrt_2 : Float := Sqrt (0.1); The elaboration code of the body of `Unit_2' also contains: if expression_2 = 2 then Q := Unit_1.Func_1; end if; Now the question is, which of the following orders of elaboration is acceptable: Spec of Unit_1 Spec of Unit_2 Body of Unit_1 Body of Unit_2 or Spec of Unit_2 Spec of Unit_1 Body of Unit_2 Body of Unit_1 If you carefully analyze the flow here, you will see that you cannot tell at compile time the answer to this question. If `expression_1' is not equal to 1, and `expression_2' is not equal to 2, then either order is acceptable, because neither of the function calls is executed. If both tests evaluate to true, then neither order is acceptable and in fact there is no correct order. If one of the two expressions is true, and the other is false, then one of the above orders is correct, and the other is incorrect. For example, if `expression_1' = 1 and `expression_2' /= 2, then the call to `Func_2' will occur, but not the call to `Func_1.' This means that it is essential to elaborate the body of `Unit_1' before the body of `Unit_2', so the first order of elaboration is correct and the second is wrong. By making `expression_1' and `expression_2' depend on input data, or perhaps the time of day, we can make it impossible for the compiler or binder to figure out which of these expressions will be true, and hence it is impossible to guarantee a safe order of elaboration at run time. Checking the Elaboration Order in Ada 95 ======================================== In some languages that involve the same kind of elaboration problems, e.g. Java and C++, the programmer is expected to worry about these ordering problems himself, and it is common to write a program in which an incorrect elaboration order gives surprising results, because it references variables before they are initialized. Ada 95 is designed to be a safe language, and a programmer-beware approach is clearly not sufficient. Consequently, the language provides three lines of defense: Standard rules Some standard rules restrict the possible choice of elaboration order. In particular, if you `with' a unit, then its spec is always elaborated before the unit doing the `with'. Similarly, a parent spec is always elaborated before the child spec, and finally a spec is always elaborated before its corresponding body. Dynamic elaboration checks Dynamic checks are made at run time, so that if some entity is accessed before it is elaborated (typically by means of a subprogram call) then the exception (`Program_Error') is raised. Elaboration control Facilities are provided for the programmer to specify the desired order of elaboration. Let's look at these facilities in more detail. First, the rules for dynamic checking. One possible rule would be simply to say that the exception is raised if you access a variable which has not yet been elaborated. The trouble with this approach is that it could require expensive checks on every variable reference. Instead Ada 95 has two rules which are a little more restrictive, but easier to check, and easier to state: Restrictions on calls A subprogram can only be called at elaboration time if its body has been elaborated. The rules for elaboration given above guarantee that the spec of the subprogram has been elaborated before the call, but not the body. If this rule is violated, then the exception `Program_Error' is raised. Restrictions on instantiations A generic unit can only be instantiated if the body of the generic unit has been elaborated. Again, the rules for elaboration given above guarantee that the spec of the generic unit has been elaborated before the instantiation, but not the body. If this rule is violated, then the exception `Program_Error' is raised. The idea is that if the body has been elaborated, then any variables it references must have been elaborated; by checking for the body being elaborated we guarantee that none of its references causes any trouble. As we noted above, this is a little too restrictive, because a subprogram that has no non-local references in its body may in fact be safe to call. However, it really would be unsafe to rely on this, because it would mean that the caller was aware of details of the implementation in the body. This goes against the basic tenets of Ada. A plausible implementation can be described as follows. A Boolean variable is associated with each subprogram and each generic unit. This variable is initialized to False, and is set to True at the point body is elaborated. Every call or instantiation checks the variable, and raises `Program_Error' if the variable is False. Note that one might think that it would be good enough to have one Boolean variable for each package, but that would not deal with cases of trying to call a body in the same package as the call that has not been elaborated yet. Of course a compiler may be able to do enough analysis to optimize away some of the Boolean variables as unnecessary, and `GNAT' indeed does such optimizations, but still the easiest conceptual model is to think of there being one variable per subprogram. Controlling the Elaboration Order in Ada 95 =========================================== In the previous section we discussed the rules in Ada 95 which ensure that `Program_Error' is raised if an incorrect elaboration order is chosen. This prevents erroneous executions, but we need mechanisms to specify a correct execution and avoid the exception altogether. To achieve this, Ada 95 provides a number of features for controlling the order of elaboration. We discuss these features in this section. First, there are several ways of indicating to the compiler that a given unit has no elaboration problems: packages that do not require a body In Ada 95, a library package that does not require a body does not permit a body. This means that if we have a such a package, as in: package Definitions is generic type m is new integer; package Subp is type a is array (1 .. 10) of m; type b is array (1 .. 20) of m; end Subp; end Definitions; A package that `with''s `Definitions' may safely instantiate `Definitions.Subp' because the compiler can determine that there definitely is no package body to worry about in this case pragma Pure Places sufficient restrictions on a unit to guarantee that no call to any subprogram in the unit can result in an elaboration problem. This means that the compiler does not need to worry about the point of elaboration of such units, and in particular, does not need to check any calls to any subprograms in this unit. pragma Preelaborate This pragma places slightly less stringent restrictions on a unit than does pragma Pure, but these restrictions are still sufficient to ensure that there are no elaboration problems with any calls to the unit. pragma Elaborate_Body This pragma requires that the body of a unit be elaborated immediately after its spec. Suppose a unit `A' has such a pragma, and unit `B' does a `with' of unit `A'. Recall that the standard rules require the spec of unit `A' to be elaborated before the `with''ing unit; given the pragma in `A', we also know that the body of `A' will be elaborated before `B', so that calls to `A' are safe and do not need a check. Note that, unlike pragma `Pure' and pragma `Preelaborate', the use of `Elaborate_Body' does not guarantee that the program is free of elaboration problems, because it may not be possible to satisfy the requested elaboration order. Let's go back to the example with `Unit_1' and `Unit_2'. If a programmer marks `Unit_1' as `Elaborate_Body', and not `Unit_2,' then the order of elaboration will be: Spec of Unit_2 Spec of Unit_1 Body of Unit_1 Body of Unit_2 Now that means that the call to `Func_1' in `Unit_2' need not be checked, it must be safe. But the call to `Func_2' in `Unit_1' may still fail if `Expression_1' is equal to 1, and the programmer must still take responsibility for this not being the case. If all units carry a pragma `Elaborate_Body', then all problems are eliminated, except for calls entirely within a body, which are in any case fully under programmer control. However, using the pragma everywhere is not always possible. In particular, for our `Unit_1'/`Unit_2' example, if we marked both of them as having pragma `Elaborate_Body', then clearly there would be no possible elaboration order. The above pragmas allow a server to guarantee safe use by clients, and clearly this is the preferable approach. Consequently a good rule in Ada 95 is to mark units as `Pure' or `Preelaborate' if possible, and if this is not possible, mark them as `Elaborate_Body' if possible. As we have seen, there are situations where neither of these three pragmas can be used. So we also provide methods for clients to control the order of elaboration of the servers on which they depend: pragma Elaborate (unit) This pragma is placed in the context clause, after a `with' clause, and it requires that the body of the named unit be elaborated before the unit in which the pragma occurs. The idea is to use this pragma if the current unit calls at elaboration time, directly or indirectly, some subprogram in the named unit. pragma Elaborate_All (unit) This is a stronger version of the Elaborate pragma. Consider the following example: Unit A `with''s unit B and calls B.Func in elab code Unit B `with''s unit C, and B.Func calls C.Func Now if we put a pragma `Elaborate (B)' in unit `A', this ensures that the body of `B' is elaborated before the call, but not the body of `C', so the call to `C.Func' could still cause `Program_Error' to be raised. The effect of a pragma `Elaborate_All' is stronger, it requires not only that the body of the named unit be elaborated before the unit doing the `with', but also the bodies of all units that the named unit uses, following `with' links transitively. For example, if we put a pragma `Elaborate_All (B)' in unit `A', then it requires not only that the body of `B' be elaborated before `A', but also the body of `C', because `B' `with''s `C'. We are now in a position to give a usage rule in Ada 95 for avoiding elaboration problems, at least if dynamic dispatching and access to subprogram values are not used. We will handle these cases separately later. The rule is simple. If a unit has elaboration code that can directly or indirectly make a call to a subprogram in a `with''ed unit, or instantiate a generic unit in a `with''ed unit, then if the `with''ed unit does not have pragma `Pure' or `Preelaborate', then the client should have a pragma `Elaborate_All' for the `with''ed unit. By following this rule a client is assured that calls can be made without risk of an exception. If this rule is not followed, then a program may be in one of four states: No order exists No order of elaboration exists which follows the rules, taking into account any `Elaborate', `Elaborate_All', or `Elaborate_Body' pragmas. In this case, an Ada 95 compiler must diagnose the situation at bind time, and refuse to build an executable program. One or more orders exist, all incorrect One or more acceptable elaboration orders exists, and all of them generate an elaboration order problem. In this case, the binder can build an executable program, but `Program_Error' will be raised when the program is run. Several orders exist, some right, some incorrect One or more acceptable elaboration orders exists, and some of them work, and some do not. The programmer has not controlled the order of elaboration, so the binder may or may not pick one of the correct orders, and the program may or may not raise an exception when it is run. This is the worst case, because it means that the program may fail when moved to another compiler, or even another version of the same compiler. One or more orders exists, all correct One ore more acceptable elaboration orders exist, and all of them work. In this case the program runs successfully. This state of affairs can be guaranteed by following the rule we gave above, but may be true even if the rule is not followed. Note that one additional advantage of following our Elaborate_All rule is that the program continues to stay in the ideal (all orders OK) state even if maintenance changes some bodies of some subprograms. Conversely, if a program that does not follow this rule happens to be safe at some point, this state of affairs may deteriorate silently as a result of maintenance changes. You may have noticed that the above discussion did not mention the use of `Elaborate_Body'. This was a deliberate omission. If you `with' an `Elaborate_Body' unit, it still may be the case that code in the body makes calls to some other unit, so it is still necessary to use `Elaborate_All' on such units. Controlling Elaboration in GNAT - Internal Calls ================================================ In the case of internal calls, i.e. calls within a single package, the programmer has full control over the order of elaboration, and it is up to the programmer to elaborate declarations in an appropriate order. For example writing: function One return Float; Q : Float := One; function One return Float is begin return 1.0; end One; will obviously raise `Program_Error' at run time, because function One will be called before its body is elaborated. In this case GNAT will generate a warning that the call will raise `Program_Error': 1. procedure y is 2. function One return Float; 3. 4. Q : Float := One; | >>> warning: cannot call "One" before body is elaborated >>> warning: Program_Error will be raised at run time 5. 6. function One return Float is 7. begin 8. return 1.0; 9. end One; 10. 11. begin 12. null; 13. end; Note that in this particular case, it is likely that the call is safe, because the function `One' does not access any global variables. Nevertheless in Ada 95, we do not want the validity of the check to depend on the contents of the body (think about the separate compilation case), so this is still wrong, as we discussed in the previous sections. The error is easily corrected by rearranging the declarations so that the body of One appears before the declaration containing the call (note that in Ada 95, declarations can appear in any order, so there is no restriction that would prevent this reordering, and if we write: function One return Float; function One return Float is begin return 1.0; end One; Q : Float := One; then all is well, no warning is generated, and no `Program_Error' exception will be raised. Things are more complicated when a chain of subprograms is executed: function A return Integer; function B return Integer; function C return Integer; function B return Integer is begin return A; end; function C return Integer is begin return B; end; X : Integer := C; function A return Integer is begin return 1; end; Now the call to `C' at elaboration time in the declaration of `X' is correct, because the body of `C' is already elaborated, and the call to `B' within the body of `C' is correct, but the call to `A' within the body of `B' is incorrect, because the body of `A' has not been elaborated, so `Program_Error' will be raised on the call to `A'. In this case GNAT will generate a warning that `Program_Error' may be raised at the point of the call. Let's look at the warning: 1. procedure x is 2. function A return Integer; 3. function B return Integer; 4. function C return Integer; 5. 6. function B return Integer is begin return A; end; | >>> warning: call to "A" before body is elaborated may raise Program_Error >>> warning: "B" called at line 7 >>> warning: "C" called at line 9 7. function C return Integer is begin return B; end; 8. 9. X : Integer := C; 10. 11. function A return Integer is begin return 1; end; 12. 13. begin 14. null; 15. end; Note that the message here says "may raise", instead of the direct case, where the message says "will be raised". That's because whether `A' is actually called depends in general on run-time flow of control. For example, if the body of `B' said function B return Integer is begin if some-condition-depending-on-input-data then return A; else return 1; end if; end B; then we could not know until run time whether the incorrect call to A would actually occur, so `Program_Error' might or might not be raised. It is possible for a compiler to do a better job of analyzing bodies, to determine whether or not `Program_Error' might be raised, but it certainly couldn't do a perfect job (that would require solving the halting problem and is provably impossible), and because this is a warning anyway, it does not seem worth the effort to do the analysis. Cases in which it would be relevant are rare. In practice, warnings of either of the forms given above will usually correspond to real errors, and should be examined carefully and eliminated. In the rare case where a warning is bogus, it can be suppressed by any of the following methods: * Compile with the `-gnatws' switch set * Suppress `Elaboration_Checks' for the called subprogram * Use pragma `Warnings_Off' to turn warnings off for the call For the internal elaboration check case, GNAT by default generates the necessary run-time checks to ensure that `Program_Error' is raised if any call fails an elaboration check. Of course this can only happen if a warning has been issued as described above. The use of pragma `Suppress (Elaboration_Checks)' may (but is not guaranteed to) suppress some of these checks, meaning that it may be possible (but is not guaranteed) for a program to be able to call a subprogram whose body is not yet elaborated, without raising a `Program_Error' exception. Controlling Elaboration in GNAT - External Calls ================================================ The previous section discussed the case in which the execution of a particular thread of elaboration code occurred entirely within a single unit. This is the easy case to handle, because a programmer has direct and total control over the order of elaboration, and furthermore, checks need only be generated in cases which are rare and which the compiler can easily detect. The situation is more complex when separate compilation is taken into account. Consider the following: package Math is function Sqrt (Arg : Float) return Float; end Math; package body Math is function Sqrt (Arg : Float) return Float is begin ... end Sqrt; end Math; with Math; package Stuff is X : Float := Math.Sqrt (0.5); end Stuff; with Stuff; procedure Main is begin ... end Main; where `Main' is the main program. When this program is executed, the elaboration code must first be executed, and one of the jobs of the binder is to determine the order in which the units of a program are to be elaborated. In this case we have four units: the spec and body of `Math', the spec of `Stuff' and the body of `Main'). In what order should the four separate sections of elaboration code be executed? There are some restrictions in the order of elaboration that the binder can choose. In particular, if unit U has a `with' for a package `X', then you are assured that the spec of `X' is elaborated before U , but you are not assured that the body of `X' is elaborated before U. This means that in the above case, the binder is allowed to choose the order: spec of Math spec of Stuff body of Math body of Main but that's not good, because now the call to `Math.Sqrt' that happens during the elaboration of the `Stuff' spec happens before the body of `Math.Sqrt' is elaborated, and hence causes `Program_Error' exception to be raised. At first glance, one might say that the binder is misbehaving, because obviously you want to elaborate the body of something you `with' first, but that is not a general rule that can be followed in all cases. Consider package X is ... package Y is ... with X; package body Y is ... with Y; package body X is ... This is a common arrangement, and, apart from the order of elaboration problems that might arise in connection with elaboration code, this works fine. A rule that says that you must first elaborate the body of anything you `with' cannot work in this case: the body of `X' `with''s `Y', which means you would have to elaborate the body of `Y' first, but that `with''s `X', which means you have to elaborate the body of `X' first, but ... and we have a loop that cannot be broken. It is true that the binder can in many cases guess an order of elaboration that is unlikely to cause a `Program_Error' exception to be raised, and it tries to do so (in the above example of `Math/Stuff/Spec', the GNAT binder will by default elaborate the body of `Math' right after its spec, so all will be well). However, a program that blindly relies on the binder to be helpful can get into trouble, as we discussed in the previous sections, so GNAT provides a number of facilities for assisting the programmer in developing programs that are robust with respect to elaboration order. Default Behavior in GNAT - Ensuring Safety ========================================== The default behavior in GNAT ensures elaboration safety. In its default mode GNAT implements the rule we previously described as the right approach. Let's restate it: * _If a unit has elaboration code that can directly or indirectly make a call to a subprogram in a `with''ed unit, or instantiate a generic unit in a `with''ed unit, then if the `with''ed unit does not have pragma `Pure' or `Preelaborate', then the client should have an `Elaborate_All' for the `with''ed unit._ By following this rule a client is assured that calls and instantiations can be made without risk of an exception. In this mode GNAT traces all calls that are potentially made from elaboration code, and puts in any missing implicit `Elaborate_All' pragmas. The advantage of this approach is that no elaboration problems are possible if the binder can find an elaboration order that is consistent with these implicit `Elaborate_All' pragmas. The disadvantage of this approach is that no such order may exist. If the binder does not generate any diagnostics, then it means that it has found an elaboration order that is guaranteed to be safe. However, the binder may still be relying on implicitly generated `Elaborate_All' pragmas so portability to other compilers than GNAT is not guaranteed. If it is important to guarantee portability, then the compilations should use the `-gnatwl' (warn on elaboration problems) switch. This will cause warning messages to be generated indicating the missing `Elaborate_All' pragmas. Consider the following source program: with k; package j is m : integer := k.r; end; where it is clear that there should be a pragma `Elaborate_All' for unit `k'. An implicit pragma will be generated, and it is likely that the binder will be able to honor it. However, it is safer to include the pragma explicitly in the source. If this unit is compiled with the `-gnatwl' switch, then the compiler outputs a warning: 1. with k; 2. package j is 3. m : integer := k.r; | >>> warning: call to "r" may raise Program_Error >>> warning: missing pragma Elaborate_All for "k" 4. end; and these warnings can be used as a guide for supplying manually the missing pragmas. This default mode is more restrictive than the Ada Reference Manual, and it is possible to construct programs which will compile using the dynamic model described there, but will run into a circularity using the safer static model we have described. Of course any Ada compiler must be able to operate in a mode consistent with the requirements of the Ada Reference Manual, and in particular must have the capability of implementing the standard dynamic model of elaboration with run-time checks. In GNAT, this standard mode can be achieved either by the use of the `-gnatE' switch on the compiler (`gcc' or `gnatmake') command, or by the use of the configuration pragma: pragma Elaboration_Checks (RM); Either approach will cause the unit affected to be compiled using the standard dynamic run-time elaboration checks described in the Ada Reference Manual. The static model is generally preferable, since it is clearly safer to rely on compile and link time checks rather than run-time checks. However, in the case of legacy code, it may be difficult to meet the requirements of the static model. This issue is further discussed in *Note What to Do If the Default Elaboration Behavior Fails::. Note that the static model provides a strict subset of the allowed behavior and programs of the Ada Reference Manual, so if you do adhere to the static model and no circularities exist, then you are assured that your program will work using the dynamic model. Elaboration Issues for Library Tasks ==================================== In this section we examine special elaboration issues that arise for programs that declare library level tasks. Generally the model of execution of an Ada program is that all units are elaborated, and then execution of the program starts. However, the declaration of library tasks definitely does not fit this model. The reason for this is that library tasks start as soon as they are declared (more precisely, as soon as the statement part of the enclosing package body is reached), that is to say before elaboration of the program is complete. This means that if such a task calls a subprogram, or an entry in another task, the callee may or may not be elaborated yet, and in the standard Reference Manual model of dynamic elaboration checks, you can even get timing dependent Program_Error exceptions, since there can be a race between the elaboration code and the task code. The static model of elaboration in GNAT seeks to avoid all such dynamic behavior, by being conservative, and the conservative approach in this particular case is to assume that all the code in a task body is potentially executed at elaboration time if a task is declared at the library level. This can definitely result in unexpected circularities. Consider the following example package Decls is task Lib_Task is entry Start; end Lib_Task; type My_Int is new Integer; function Ident (M : My_Int) return My_Int; end Decls; with Utils; package body Decls is task body Lib_Task is begin accept Start; Utils.Put_Val (2); end Lib_Task; function Ident (M : My_Int) return My_Int is begin return M; end Ident; end Decls; with Decls; package Utils is procedure Put_Val (Arg : Decls.My_Int); end Utils; with Text_IO; package body Utils is procedure Put_Val (Arg : Decls.My_Int) is begin Text_IO.Put_Line (Decls.My_Int'Image (Decls.Ident (Arg))); end Put_Val; end Utils; with Decls; procedure Main is begin Decls.Lib_Task.Start; end; If the above example is compiled in the default static elaboration mode, then a circularity occurs. The circularity comes from the call `Utils.Put_Val' in the task body of `Decls.Lib_Task'. Since this call occurs in elaboration code, we need an implicit pragma `Elaborate_All' for `Utils'. This means that not only must the spec and body of `Utils' be elaborated before the body of `Decls', but also the spec and body of any unit that is `with'ed' by the body of `Utils' must also be elaborated before the body of `Decls'. This is the transitive implication of pragma `Elaborate_All' and it makes sense, because in general the body of `Put_Val' might have a call to something in a `with'ed' unit. In this case, the body of Utils (actually its spec) `with's' `Decls'. Unfortunately this means that the body of `Decls' must be elaborated before itself, in case there is a call from the body of `Utils'. Here is the exact chain of events we are worrying about: 1. In the body of `Decls' a call is made from within the body of a library task to a subprogram in the package `Utils'. Since this call may occur at elaboration time (given that the task is activated at elaboration time), we have to assume the worst, i.e. that the call does happen at elaboration time. 2. This means that the body and spec of `Util' must be elaborated before the body of `Decls' so that this call does not cause an access before elaboration. 3. Within the body of `Util', specifically within the body of `Util.Put_Val' there may be calls to any unit `with''ed by this package. 4. One such `with''ed package is package `Decls', so there might be a call to a subprogram in `Decls' in `Put_Val'. In fact there is such a call in this example, but we would have to assume that there was such a call even if it were not there, since we are not supposed to write the body of `Decls' knowing what is in the body of `Utils'; certainly in the case of the static elaboration model, the compiler does not know what is in other bodies and must assume the worst. 5. This means that the spec and body of `Decls' must also be elaborated before we elaborate the unit containing the call, but that unit is `Decls'! This means that the body of `Decls' must be elaborated before itself, and that's a circularity. Indeed, if you add an explicit pragma Elaborate_All for `Utils' in the body of `Decls' you will get a true Ada Reference Manual circularity that makes the program illegal. In practice, we have found that problems with the static model of elaboration in existing code often arise from library tasks, so we must address this particular situation. Note that if we compile and run the program above, using the dynamic model of elaboration (that is to say use the `-gnatE' switch), then it compiles, binds, links, and runs, printing the expected result of 2. Therefore in some sense the circularity here is only apparent, and we need to capture the properties of this program that distinguish it from other library-level tasks that have real elaboration problems. We have four possible answers to this question: * Use the dynamic model of elaboration. If we use the `-gnatE' switch, then as noted above, the program works. Why is this? If we examine the task body, it is apparent that the task cannot proceed past the `accept' statement until after elaboration has been completed, because the corresponding entry call comes from the main program, not earlier. This is why the dynamic model works here. But that's really giving up on a precise analysis, and we prefer to take this approach only if we cannot solve the problem in any other manner. So let us examine two ways to reorganize the program to avoid the potential elaboration problem. * Split library tasks into separate packages. Write separate packages, so that library tasks are isolated from other declarations as much as possible. Let us look at a variation on the above program. package Decls1 is task Lib_Task is entry Start; end Lib_Task; end Decls1; with Utils; package body Decls1 is task body Lib_Task is begin accept Start; Utils.Put_Val (2); end Lib_Task; end Decls1; package Decls2 is type My_Int is new Integer; function Ident (M : My_Int) return My_Int; end Decls2; with Utils; package body Decls2 is function Ident (M : My_Int) return My_Int is begin return M; end Ident; end Decls2; with Decls2; package Utils is procedure Put_Val (Arg : Decls2.My_Int); end Utils; with Text_IO; package body Utils is procedure Put_Val (Arg : Decls2.My_Int) is begin Text_IO.Put_Line (Decls2.My_Int'Image (Decls2.Ident (Arg))); end Put_Val; end Utils; with Decls1; procedure Main is begin Decls1.Lib_Task.Start; end; All we have done is to split `Decls' into two packages, one containing the library task, and one containing everything else. Now there is no cycle, and the program compiles, binds, links and executes using the default static model of elaboration. * Declare separate task types. A significant part of the problem arises because of the use of the single task declaration form. This means that the elaboration of the task type, and the elaboration of the task itself (i.e. the creation of the task) happen at the same time. A good rule of style in Ada 95 is to always create explicit task types. By following the additional step of placing task objects in separate packages from the task type declaration, many elaboration problems are avoided. Here is another modified example of the example program: package Decls is task type Lib_Task_Type is entry Start; end Lib_Task_Type; type My_Int is new Integer; function Ident (M : My_Int) return My_Int; end Decls; with Utils; package body Decls is task body Lib_Task_Type is begin accept Start; Utils.Put_Val (2); end Lib_Task_Type; function Ident (M : My_Int) return My_Int is begin return M; end Ident; end Decls; with Decls; package Utils is procedure Put_Val (Arg : Decls.My_Int); end Utils; with Text_IO; package body Utils is procedure Put_Val (Arg : Decls.My_Int) is begin Text_IO.Put_Line (Decls.My_Int'Image (Decls.Ident (Arg))); end Put_Val; end Utils; with Decls; package Declst is Lib_Task : Decls.Lib_Task_Type; end Declst; with Declst; procedure Main is begin Declst.Lib_Task.Start; end; What we have done here is to replace the `task' declaration in package `Decls' with a `task type' declaration. Then we introduce a separate package `Declst' to contain the actual task object. This separates the elaboration issues for the `task type' declaration, which causes no trouble, from the elaboration issues of the task object, which is also unproblematic, since it is now independent of the elaboration of `Utils'. This separation of concerns also corresponds to a generally sound engineering principle of separating declarations from instances. This version of the program also compiles, binds, links, and executes, generating the expected output. * Use No_Entry_Calls_In_Elaboration_Code restriction. The previous two approaches described how a program can be restructured to avoid the special problems caused by library task bodies. in practice, however, such restructuring may be difficult to apply to existing legacy code, so we must consider solutions that do not require massive rewriting. Let us consider more carefully why our original sample program works under the dynamic model of elaboration. The reason is that the code in the task body blocks immediately on the `accept' statement. Now of course there is nothing to prohibit elaboration code from making entry calls (for example from another library level task), so we cannot tell in isolation that the task will not execute the accept statement during elaboration. However, in practice it is very unusual to see elaboration code make any entry calls, and the pattern of tasks starting at elaboration time and then immediately blocking on `accept' or `select' statements is very common. What this means is that the compiler is being too pessimistic when it analyzes the whole package body as though it might be executed at elaboration time. If we know that the elaboration code contains no entry calls, (a very safe assumption most of the time, that could almost be made the default behavior), then we can compile all units of the program under control of the following configuration pragma: pragma Restrictions (No_Entry_Calls_In_Elaboration_Code); This pragma can be placed in the `gnat.adc' file in the usual manner. If we take our original unmodified program and compile it in the presence of a `gnat.adc' containing the above pragma, then once again, we can compile, bind, link, and execute, obtaining the expected result. In the presence of this pragma, the compiler does not trace calls in a task body, that appear after the first `accept' or `select' statement, and therefore does not report a potential circularity in the original program. The compiler will check to the extent it can that the above restriction is not violated, but it is not always possible to do a complete check at compile time, so it is important to use this pragma only if the stated restriction is in fact met, that is to say no task receives an entry call before elaboration of all units is completed. Mixing Elaboration Models ========================= So far, we have assumed that the entire program is either compiled using the dynamic model or static model, ensuring consistency. It is possible to mix the two models, but rules have to be followed if this mixing is done to ensure that elaboration checks are not omitted. The basic rule is that _a unit compiled with the static model cannot be `with'ed' by a unit compiled with the dynamic model_. The reason for this is that in the static model, a unit assumes that its clients guarantee to use (the equivalent of) pragma `Elaborate_All' so that no elaboration checks are required in inner subprograms, and this assumption is violated if the client is compiled with dynamic checks. The precise rule is as follows. A unit that is compiled with dynamic checks can only `with' a unit that meets at least one of the following criteria: * The `with'ed' unit is itself compiled with dynamic elaboration checks (that is with the `-gnatE' switch. * The `with'ed' unit is an internal GNAT implementation unit from the System, Interfaces, Ada, or GNAT hierarchies. * The `with'ed' unit has pragma Preelaborate or pragma Pure. * The `with'ing' unit (that is the client) has an explicit pragma `Elaborate_All' for the `with'ed' unit. If this rule is violated, that is if a unit with dynamic elaboration checks `with's' a unit that does not meet one of the above four criteria, then the binder (`gnatbind') will issue a warning similar to that in the following example: warning: "x.ads" has dynamic elaboration checks and with's warning: "y.ads" which has static elaboration checks These warnings indicate that the rule has been violated, and that as a result elaboration checks may be missed in the resulting executable file. This warning may be suppressed using the `-ws' binder switch in the usual manner. One useful application of this mixing rule is in the case of a subsystem which does not itself `with' units from the remainder of the application. In this case, the entire subsystem can be compiled with dynamic checks to resolve a circularity in the subsystem, while allowing the main application that uses this subsystem to be compiled using the more reliable default static model. What to Do If the Default Elaboration Behavior Fails ==================================================== If the binder cannot find an acceptable order, it outputs detailed diagnostics. For example: error: elaboration circularity detected info: "proc (body)" must be elaborated before "pack (body)" info: reason: Elaborate_All probably needed in unit "pack (body)" info: recompile "pack (body)" with -gnatwl info: for full details info: "proc (body)" info: is needed by its spec: info: "proc (spec)" info: which is withed by: info: "pack (body)" info: "pack (body)" must be elaborated before "proc (body)" info: reason: pragma Elaborate in unit "proc (body)" In this case we have a cycle that the binder cannot break. On the one hand, there is an explicit pragma Elaborate in `proc' for `pack'. This means that the body of `pack' must be elaborated before the body of `proc'. On the other hand, there is elaboration code in `pack' that calls a subprogram in `proc'. This means that for maximum safety, there should really be a pragma Elaborate_All in `pack' for `proc' which would require that the body of `proc' be elaborated before the body of `pack'. Clearly both requirements cannot be satisfied. Faced with a circularity of this kind, you have three different options. Fix the program The most desirable option from the point of view of long-term maintenance is to rearrange the program so that the elaboration problems are avoided. One useful technique is to place the elaboration code into separate child packages. Another is to move some of the initialization code to explicitly called subprograms, where the program controls the order of initialization explicitly. Although this is the most desirable option, it may be impractical and involve too much modification, especially in the case of complex legacy code. Perform dynamic checks If the compilations are done using the `-gnatE' (dynamic elaboration check) switch, then GNAT behaves in a quite different manner. Dynamic checks are generated for all calls that could possibly result in raising an exception. With this switch, the compiler does not generate implicit `Elaborate_All' pragmas. The behavior then is exactly as specified in the Ada 95 Reference Manual. The binder will generate an executable program that may or may not raise `Program_Error', and then it is the programmer's job to ensure that it does not raise an exception. Note that it is important to compile all units with the switch, it cannot be used selectively. Suppress checks The drawback of dynamic checks is that they generate a significant overhead at run time, both in space and time. If you are absolutely sure that your program cannot raise any elaboration exceptions, and you still want to use the dynamic elaboration model, then you can use the configuration pragma `Suppress (Elaboration_Checks)' to suppress all such checks. For example this pragma could be placed in the `gnat.adc' file. Suppress checks selectively When you know that certain calls in elaboration code cannot possibly lead to an elaboration error, and the binder nevertheless generates warnings on those calls and inserts Elaborate_All pragmas that lead to elaboration circularities, it is possible to remove those warnings locally and obtain a program that will bind. Clearly this can be unsafe, and it is the responsibility of the programmer to make sure that the resulting program has no elaboration anomalies. The pragma `Suppress (Elaboration_Check)' can be used with different granularity to suppress warnings and break elaboration circularities: * Place the pragma that names the called subprogram in the declarative part that contains the call. * Place the pragma in the declarative part, without naming an entity. This disables warnings on all calls in the corresponding declarative region. * Place the pragma in the package spec that declares the called subprogram, and name the subprogram. This disables warnings on all elaboration calls to that subprogram. * Place the pragma in the package spec that declares the called subprogram, without naming any entity. This disables warnings on all elaboration calls to all subprograms declared in this spec. These four cases are listed in order of decreasing safety, and therefore require increasing programmer care in their application. Consider the following program: package Pack1 is function F1 return Integer; X1 : Integer; end Pack1; package Pack2 is function F2 return Integer; function Pure (x : integer) return integer; -- pragma Suppress (Elaboration_Check, On => Pure); -- (3) -- pragma Suppress (Elaboration_Check); -- (4) end Pack2; with Pack2; package body Pack1 is function F1 return Integer is begin return 100; end F1; Val : integer := Pack2.Pure (11); -- Elab. call (1) begin declare -- pragma Suppress(Elaboration_Check, Pack2.F2); -- (1) -- pragma Suppress(Elaboration_Check); -- (2) begin X1 := Pack2.F2 + 1; -- Elab. call (2) end; end Pack1; with Pack1; package body Pack2 is function F2 return Integer is begin return Pack1.F1; end F2; function Pure (x : integer) return integer is begin return x ** 3 - 3 * x; end; end Pack2; with Pack1, Ada.Text_IO; procedure Proc3 is begin Ada.Text_IO.Put_Line(Pack1.X1'Img); -- 101 end Proc3; In the absence of any pragmas, an attempt to bind this program produces the following diagnostics: error: elaboration circularity detected info: "pack1 (body)" must be elaborated before "pack1 (body)" info: reason: Elaborate_All probably needed in unit "pack1 (body)" info: recompile "pack1 (body)" with -gnatwl for full details info: "pack1 (body)" info: must be elaborated along with its spec: info: "pack1 (spec)" info: which is withed by: info: "pack2 (body)" info: which must be elaborated along with its spec: info: "pack2 (spec)" info: which is withed by: info: "pack1 (body)" The sources of the circularity are the two calls to `Pack2.Pure' and `Pack2.F2' in the body of `Pack1'. We can see that the call to F2 is safe, even though F2 calls F1, because the call appears after the elaboration of the body of F1. Therefore the pragma (1) is safe, and will remove the warning on the call. It is also possible to use pragma (2) because there are no other potentially unsafe calls in the block. The call to `Pure' is safe because this function does not depend on the state of `Pack2'. Therefore any call to this function is safe, and it is correct to place pragma (3) in the corresponding package spec. Finally, we could place pragma (4) in the spec of `Pack2' to disable warnings on all calls to functions declared therein. Note that this is not necessarily safe, and requires more detailed examination of the subprogram bodies involved. In particular, a call to `F2' requires that `F1' be already elaborated. It is hard to generalize on which of these four approaches should be taken. Obviously if it is possible to fix the program so that the default treatment works, this is preferable, but this may not always be practical. It is certainly simple enough to use `-gnatE' but the danger in this case is that, even if the GNAT binder finds a correct elaboration order, it may not always do so, and certainly a binder from another Ada compiler might not. A combination of testing and analysis (for which the warnings generated with the `-gnatwl' switch can be useful) must be used to ensure that the program is free of errors. One switch that is useful in this testing is the `-p (pessimistic elaboration order)' switch for `gnatbind'. Normally the binder tries to find an order that has the best chance of of avoiding elaboration problems. With this switch, the binder plays a devil's advocate role, and tries to choose the order that has the best chance of failing. If your program works even with this switch, then it has a better chance of being error free, but this is still not a guarantee. For an example of this approach in action, consider the C-tests (executable tests) from the ACVC suite. If these are compiled and run with the default treatment, then all but one of them succeed without generating any error diagnostics from the binder. However, there is one test that fails, and this is not surprising, because the whole point of this test is to ensure that the compiler can handle cases where it is impossible to determine a correct order statically, and it checks that an exception is indeed raised at run time. This one test must be compiled and run using the `-gnatE' switch, and then it passes. Alternatively, the entire suite can be run using this switch. It is never wrong to run with the dynamic elaboration switch if your code is correct, and we assume that the C-tests are indeed correct (it is less efficient, but efficiency is not a factor in running the ACVC tests.) Elaboration for Access-to-Subprogram Values =========================================== The introduction of access-to-subprogram types in Ada 95 complicates the handling of elaboration. The trouble is that it becomes impossible to tell at compile time which procedure is being called. This means that it is not possible for the binder to analyze the elaboration requirements in this case. If at the point at which the access value is created (i.e., the evaluation of `P'Access' for a subprogram `P'), the body of the subprogram is known to have been elaborated, then the access value is safe, and its use does not require a check. This may be achieved by appropriate arrangement of the order of declarations if the subprogram is in the current unit, or, if the subprogram is in another unit, by using pragma `Pure', `Preelaborate', or `Elaborate_Body' on the referenced unit. If the referenced body is not known to have been elaborated at the point the access value is created, then any use of the access value must do a dynamic check, and this dynamic check will fail and raise a `Program_Error' exception if the body has not been elaborated yet. GNAT will generate the necessary checks, and in addition, if the `-gnatwl' switch is set, will generate warnings that such checks are required. The use of dynamic dispatching for tagged types similarly generates a requirement for dynamic checks, and premature calls to any primitive operation of a tagged type before the body of the operation has been elaborated, will result in the raising of `Program_Error'. Summary of Procedures for Elaboration Control ============================================= First, compile your program with the default options, using none of the special elaboration control switches. If the binder successfully binds your program, then you can be confident that, apart from issues raised by the use of access-to-subprogram types and dynamic dispatching, the program is free of elaboration errors. If it is important that the program be portable, then use the `-gnatwl' switch to generate warnings about missing `Elaborate_All' pragmas, and supply the missing pragmas. If the program fails to bind using the default static elaboration handling, then you can fix the program to eliminate the binder message, or recompile the entire program with the `-gnatE' switch to generate dynamic elaboration checks, and, if you are sure there really are no elaboration problems, use a global pragma `Suppress (Elaboration_Checks)'. Other Elaboration Order Considerations ====================================== This section has been entirely concerned with the issue of finding a valid elaboration order, as defined by the Ada Reference Manual. In a case where several elaboration orders are valid, the task is to find one of the possible valid elaboration orders (and the static model in GNAT will ensure that this is achieved). The purpose of the elaboration rules in the Ada Reference Manual is to make sure that no entity is accessed before it has been elaborated. For a subprogram, this means that the spec and body must have been elaborated before the subprogram is called. For an object, this means that the object must have been elaborated before its value is read or written. A violation of either of these two requirements is an access before elaboration order, and this section has been all about avoiding such errors. In the case where more than one order of elaboration is possible, in the sense that access before elaboration errors are avoided, then any one of the orders is "correct" in the sense that it meets the requirements of the Ada Reference Manual, and no such error occurs. However, it may be the case for a given program, that there are constraints on the order of elaboration that come not from consideration of avoiding elaboration errors, but rather from extra-lingual logic requirements. Consider this example: with Init_Constants; package Constants is X : Integer := 0; Y : Integer := 0; end Constants; package Init_Constants is procedure Calc; end Init_Constants; with Constants; package body Init_Constants is procedure Calc is begin null; end; begin Constants.X := 3; Constants.Y := 4; end Init_Constants; with Constants; package Calc is Z : Integer := Constants.X + Constants.Y; end Calc; with Calc; with Text_IO; use Text_IO; procedure Main is begin Put_Line (Calc.Z'Img); end Main; In this example, there is more than one valid order of elaboration. For example both the following are correct orders: Init_Constants spec Constants spec Calc spec Main body Init_Constants body and Init_Constants spec Init_Constants body Constants spec Calc spec Main body There is no language rule to prefer one or the other, both are correct from an order of elaboration point of view. But the programmatic effects of the two orders are very different. In the first, the elaboration routine of `Calc' initializes `Z' to zero, and then the main program runs with this value of zero. But in the second order, the elaboration routine of `Calc' runs after the body of Init_Constants has set `X' and `Y' and thus `Z' is set to 7 before `Main' runs. One could perhaps by applying pretty clever non-artificial intelligence to the situation guess that it is more likely that the second order of elaboration is the one desired, but there is no formal linguistic reason to prefer one over the other. In fact in this particular case, GNAT will prefer the second order, because of the rule that bodies are elaborated as soon as possible, but it's just luck that this is what was wanted (if indeed the second order was preferred). If the program cares about the order of elaboration routines in a case like this, it is important to specify the order required. In this particular case, that could have been achieved by adding to the spec of Calc: pragma Elaborate_All (Constants); which requires that the body (if any) and spec of `Constants', as well as the body and spec of any unit `with''ed by `Constants' be elaborated before `Calc' is elaborated. Clearly no automatic method can always guess which alternative you require, and if you are working with legacy code that had constraints of this kind which were not properly specified by adding `Elaborate' or `Elaborate_All' pragmas, then indeed it is possible that two different compilers can choose different orders. The `gnatbind' `-p' switch may be useful in smoking out problems. This switch causes bodies to be elaborated as late as possible instead of as early as possible. In the example above, it would have forced the choice of the first elaboration order. If you get different results when using this switch, and particularly if one set of results is right, and one is wrong as far as you are concerned, it shows that you have some missing `Elaborate' pragmas. For the example above, we have the following output: gnatmake -f -q main main 7 gnatmake -f -q main -bargs -p main 0 It is of course quite unlikely that both these results are correct, so it is up to you in a case like this to investigate the source of the difference, by looking at the two elaboration orders that are chosen, and figuring out which is correct, and then adding the necessary `Elaborate_All' pragmas to ensure the desired order. The Cross-Referencing Tools `gnatxref' and `gnatfind' ***************************************************** The compiler generates cross-referencing information (unless you set the `-gnatx' switch), which are saved in the `.ali' files. This information indicates where in the source each entity is declared and referenced. Note that entities in package Standard are not included, but entities in all other predefined units are included in the output. Before using any of these two tools, you need to compile successfully your application, so that GNAT gets a chance to generate the cross-referencing information. The two tools `gnatxref' and `gnatfind' take advantage of this information to provide the user with the capability to easily locate the declaration and references to an entity. These tools are quite similar, the difference being that `gnatfind' is intended for locating definitions and/or references to a specified entity or entities, whereas `gnatxref' is oriented to generating a full report of all cross-references. To use these tools, you must not compile your application using the `-gnatx' switch on the `gnatmake' command line (*note (gnat_ug)The GNAT Make Program gnatmake::). Otherwise, cross-referencing information will not be generated. `gnatxref' Switches =================== The command lines for `gnatxref' is: $ gnatxref [switches] sourcefile1 [sourcefile2 ...] where `sourcefile1, sourcefile2' identifies the source files for which a report is to be generated. The 'with'ed units will be processed too. You must provide at least one file. These file names are considered to be regular expressions, so for instance specifying 'source*.adb' is the same as giving every file in the current directory whose name starts with 'source' and whose extension is 'adb'. The switches can be : `-a' If this switch is present, `gnatfind' and `gnatxref' will parse the read-only files found in the library search path. Otherwise, these files will be ignored. This option can be used to protect Gnat sources or your own libraries from being parsed, thus making `gnatfind' and `gnatxref' much faster, and their output much smaller. `-aIDIR' When looking for source files also look in directory DIR. The order in which source file search is undertaken is the same as for `gnatmake'. `-aODIR' When searching for library and object files, look in directory DIR. The order in which library files are searched is the same as for `gnatmake'. `-nostdinc' Do not look for sources in the system default directory. `-nostdlib' Do not look for library files in the system default directory. `--RTS=RTS-PATH' Specifies the default location of the runtime library. Same meaning as the equivalent `gnatmake' flag (see *Note Switches for gnatmake::). `-d' If this switch is set `gnatxref' will output the parent type reference for each matching derived types. `-f' If this switch is set, the output file names will be preceded by their directory (if the file was found in the search path). If this switch is not set, the directory will not be printed. `-g' If this switch is set, information is output only for library-level entities, ignoring local entities. The use of this switch may accelerate `gnatfind' and `gnatxref'. `-IDIR' Equivalent to `-aODIR -aIDIR'. `-pFILE' Specify a project file to use *Note Project Files::. By default, `gnatxref' and `gnatfind' will try to locate a project file in the current directory. If a project file is either specified or found by the tools, then the content of the source directory and object directory lines are added as if they had been specified respectively by `-aI' and `-aO'. `-u' Output only unused symbols. This may be really useful if you give your main compilation unit on the command line, as `gnatxref' will then display every unused entity and 'with'ed package. `-v' Instead of producing the default output, `gnatxref' will generate a `tags' file that can be used by vi. For examples how to use this feature, see *Note Examples of gnatxref Usage::. The tags file is output to the standard output, thus you will have to redirect it to a file. All these switches may be in any order on the command line, and may even appear after the file names. They need not be separated by spaces, thus you can say `gnatxref -ag' instead of `gnatxref -a -g'. `gnatfind' Switches =================== The command line for `gnatfind' is: $ gnatfind [switches] pattern[:sourcefile[:line[:column]]] [file1 file2 ...] where `pattern' An entity will be output only if it matches the regular expression found in `pattern', see *Note Regular Expressions in gnatfind and gnatxref::. Omitting the pattern is equivalent to specifying `*', which will match any entity. Note that if you do not provide a pattern, you have to provide both a sourcefile and a line. Entity names are given in Latin-1, with uppercase/lowercase equivalence for matching purposes. At the current time there is no support for 8-bit codes other than Latin-1, or for wide characters in identifiers. `sourcefile' `gnatfind' will look for references, bodies or declarations of symbols referenced in `sourcefile', at line `line' and column `column'. See *note Examples of gnatfind Usage:: for syntax examples. `line' is a decimal integer identifying the line number containing the reference to the entity (or entities) to be located. `column' is a decimal integer identifying the exact location on the line of the first character of the identifier for the entity reference. Columns are numbered from 1. `file1 file2 ...' The search will be restricted to these files. If none are given, then the search will be done for every library file in the search path. These file must appear only after the pattern or sourcefile. These file names are considered to be regular expressions, so for instance specifying 'source*.adb' is the same as giving every file in the current directory whose name starts with 'source' and whose extension is 'adb'. Not that if you specify at least one file in this part, `gnatfind' may sometimes not be able to find the body of the subprograms... At least one of 'sourcefile' or 'pattern' has to be present on the command line. The following switches are available: `-a' If this switch is present, `gnatfind' and `gnatxref' will parse the read-only files found in the library search path. Otherwise, these files will be ignored. This option can be used to protect Gnat sources or your own libraries from being parsed, thus making `gnatfind' and `gnatxref' much faster, and their output much smaller. `-aIDIR' When looking for source files also look in directory DIR. The order in which source file search is undertaken is the same as for `gnatmake'. `-aODIR' When searching for library and object files, look in directory DIR. The order in which library files are searched is the same as for `gnatmake'. `-nostdinc' Do not look for sources in the system default directory. `-nostdlib' Do not look for library files in the system default directory. `--RTS=RTS-PATH' Specifies the default location of the runtime library. Same meaning as the equivalent `gnatmake' flag (see *Note Switches for gnatmake::). `-d' If this switch is set, then `gnatfind' will output the parent type reference for each matching derived types. `-e' By default, `gnatfind' accept the simple regular expression set for `pattern'. If this switch is set, then the pattern will be considered as full Unix-style regular expression. `-f' If this switch is set, the output file names will be preceded by their directory (if the file was found in the search path). If this switch is not set, the directory will not be printed. `-g' If this switch is set, information is output only for library-level entities, ignoring local entities. The use of this switch may accelerate `gnatfind' and `gnatxref'. `-IDIR' Equivalent to `-aODIR -aIDIR'. `-pFILE' Specify a project file (*note Project Files::) to use. By default, `gnatxref' and `gnatfind' will try to locate a project file in the current directory. If a project file is either specified or found by the tools, then the content of the source directory and object directory lines are added as if they had been specified respectively by `-aI' and `-aO'. `-r' By default, `gnatfind' will output only the information about the declaration, body or type completion of the entities. If this switch is set, the `gnatfind' will locate every reference to the entities in the files specified on the command line (or in every file in the search path if no file is given on the command line). `-s' If this switch is set, then `gnatfind' will output the content of the Ada source file lines were the entity was found. `-t' If this switch is set, then `gnatfind' will output the type hierarchy for the specified type. It act like -d option but recursively from parent type to parent type. When this switch is set it is not possible to specify more than one file. All these switches may be in any order on the command line, and may even appear after the file names. They need not be separated by spaces, thus you can say `gnatxref -ag' instead of `gnatxref -a -g'. As stated previously, gnatfind will search in every directory in the search path. You can force it to look only in the current directory if you specify `*' at the end of the command line. Project Files for `gnatxref' and `gnatfind' =========================================== Project files allow a programmer to specify how to compile its application, where to find sources,... These files are used primarily by the Glide Ada mode, but they can also be used by the two tools `gnatxref' and `gnatfind'. A project file name must end with `.adp'. If a single one is present in the current directory, then `gnatxref' and `gnatfind' will extract the information from it. If multiple project files are found, none of them is read, and you have to use the `-p' switch to specify the one you want to use. The following lines can be included, even though most of them have default values which can be used in most cases. The lines can be entered in any order in the file. Except for `src_dir' and `obj_dir', you can only have one instance of each line. If you have multiple instances, only the last one is taken into account. `src_dir=DIR [default: "./"]' specifies a directory where to look for source files. Multiple src_dir lines can be specified and they will be searched in the order they are specified. `obj_dir=DIR [default: "./"]' specifies a directory where to look for object and library files. Multiple obj_dir lines can be specified and they will be searched in the order they are specified `comp_opt=SWITCHES [default: ""]' creates a variable which can be referred to subsequently by using the `${comp_opt}' notation. This is intended to store the default switches given to `gnatmake' and `gcc'. `bind_opt=SWITCHES [default: ""]' creates a variable which can be referred to subsequently by using the `${bind_opt}' notation. This is intended to store the default switches given to `gnatbind'. `link_opt=SWITCHES [default: ""]' creates a variable which can be referred to subsequently by using the `${link_opt}' notation. This is intended to store the default switches given to `gnatlink'. `main=EXECUTABLE [default: ""]' specifies the name of the executable for the application. This variable can be referred to in the following lines by using the `${main}' notation. `comp_cmd=COMMAND [default: "gcc -c -I${src_dir} -g -gnatq"]' specifies the command used to compile a single file in the application. `make_cmd=COMMAND [default: "gnatmake ${main} -aI${src_dir} -aO${obj_dir} -g -gnatq -cargs ${comp_opt} -bargs ${bind_opt} -largs ${link_opt}"]' specifies the command used to recompile the whole application. `run_cmd=COMMAND [default: "${main}"]' specifies the command used to run the application. `debug_cmd=COMMAND [default: "gdb ${main}"]' specifies the command used to debug the application `gnatxref' and `gnatfind' only take into account the `src_dir' and `obj_dir' lines, and ignore the others. Regular Expressions in `gnatfind' and `gnatxref' ================================================ As specified in the section about `gnatfind', the pattern can be a regular expression. Actually, there are to set of regular expressions which are recognized by the program : `globbing patterns' These are the most usual regular expression. They are the same that you generally used in a Unix shell command line, or in a DOS session. Here is a more formal grammar : regexp ::= term term ::= elmt -- matches elmt term ::= elmt elmt -- concatenation (elmt then elmt) term ::= * -- any string of 0 or more characters term ::= ? -- matches any character term ::= [char {char}] -- matches any character listed term ::= [char - char] -- matches any character in range `full regular expression' The second set of regular expressions is much more powerful. This is the type of regular expressions recognized by utilities such a `grep'. The following is the form of a regular expression, expressed in Ada reference manual style BNF is as follows regexp ::= term {| term} -- alternation (term or term ...) term ::= item {item} -- concatenation (item then item) item ::= elmt -- match elmt item ::= elmt * -- zero or more elmt's item ::= elmt + -- one or more elmt's item ::= elmt ? -- matches elmt or nothing elmt ::= nschar -- matches given character elmt ::= [nschar {nschar}] -- matches any character listed elmt ::= [^ nschar {nschar}] -- matches any character not listed elmt ::= [char - char] -- matches chars in given range elmt ::= \ char -- matches given character elmt ::= . -- matches any single character elmt ::= ( regexp ) -- parens used for grouping char ::= any character, including special characters nschar ::= any character except ()[].*+?^ Following are a few examples : `abcde|fghi' will match any of the two strings 'abcde' and 'fghi'. `abc*d' will match any string like 'abd', 'abcd', 'abccd', 'abcccd', and so on `[a-z]+' will match any string which has only lowercase characters in it (and at least one character Examples of `gnatxref' Usage ============================ General Usage ------------- For the following examples, we will consider the following units : main.ads: 1: with Bar; 2: package Main is 3: procedure Foo (B : in Integer); 4: C : Integer; 5: private 6: D : Integer; 7: end Main; main.adb: 1: package body Main is 2: procedure Foo (B : in Integer) is 3: begin 4: C := B; 5: D := B; 6: Bar.Print (B); 7: Bar.Print (C); 8: end Foo; 9: end Main; bar.ads: 1: package Bar is 2: procedure Print (B : Integer); 3: end bar; The first thing to do is to recompile your application (for instance, in that case just by doing a `gnatmake main', so that GNAT generates the cross-referencing information. You can then issue any of the following commands: `gnatxref main.adb' `gnatxref' generates cross-reference information for main.adb and every unit 'with'ed by main.adb. The output would be: B Type: Integer Decl: bar.ads 2:22 B Type: Integer Decl: main.ads 3:20 Body: main.adb 2:20 Ref: main.adb 4:13 5:13 6:19 Bar Type: Unit Decl: bar.ads 1:9 Ref: main.adb 6:8 7:8 main.ads 1:6 C Type: Integer Decl: main.ads 4:5 Modi: main.adb 4:8 Ref: main.adb 7:19 D Type: Integer Decl: main.ads 6:5 Modi: main.adb 5:8 Foo Type: Unit Decl: main.ads 3:15 Body: main.adb 2:15 Main Type: Unit Decl: main.ads 2:9 Body: main.adb 1:14 Print Type: Unit Decl: bar.ads 2:15 Ref: main.adb 6:12 7:12 that is the entity `Main' is declared in main.ads, line 2, column 9, its body is in main.adb, line 1, column 14 and is not referenced any where. The entity `Print' is declared in bar.ads, line 2, column 15 and it it referenced in main.adb, line 6 column 12 and line 7 column 12. `gnatxref package1.adb package2.ads' `gnatxref' will generates cross-reference information for package1.adb, package2.ads and any other package 'with'ed by any of these. Using gnatxref with vi ---------------------- `gnatxref' can generate a tags file output, which can be used directly from `vi'. Note that the standard version of `vi' will not work properly with overloaded symbols. Consider using another free implementation of `vi', such as `vim'. $ gnatxref -v gnatfind.adb > tags will generate the tags file for `gnatfind' itself (if the sources are in the search path!). From `vi', you can then use the command `:tag entity' (replacing entity by whatever you are looking for), and vi will display a new file with the corresponding declaration of entity. Examples of `gnatfind' Usage ============================ `gnatfind -f xyz:main.adb' Find declarations for all entities xyz referenced at least once in main.adb. The references are search in every library file in the search path. The directories will be printed as well (as the `-f' switch is set) The output will look like: directory/main.ads:106:14: xyz <= declaration directory/main.adb:24:10: xyz <= body directory/foo.ads:45:23: xyz <= declaration that is to say, one of the entities xyz found in main.adb is declared at line 12 of main.ads (and its body is in main.adb), and another one is declared at line 45 of foo.ads `gnatfind -fs xyz:main.adb' This is the same command as the previous one, instead `gnatfind' will display the content of the Ada source file lines. The output will look like: directory/main.ads:106:14: xyz <= declaration procedure xyz; directory/main.adb:24:10: xyz <= body procedure xyz is directory/foo.ads:45:23: xyz <= declaration xyz : Integer; This can make it easier to find exactly the location your are looking for. `gnatfind -r "*x*":main.ads:123 foo.adb' Find references to all entities containing an x that are referenced on line 123 of main.ads. The references will be searched only in main.adb and foo.adb. `gnatfind main.ads:123' Find declarations and bodies for all entities that are referenced on line 123 of main.ads. This is the same as `gnatfind "*":main.adb:123'. `gnatfind mydir/main.adb:123:45' Find the declaration for the entity referenced at column 45 in line 123 of file main.adb in directory mydir. Note that it is usual to omit the identifier name when the column is given, since the column position identifies a unique reference. The column has to be the beginning of the identifier, and should not point to any character in the middle of the identifier. File Name Krunching Using `gnatkr' ********************************** This chapter discusses the method used by the compiler to shorten the default file names chosen for Ada units so that they do not exceed the maximum length permitted. It also describes the `gnatkr' utility that can be used to determine the result of applying this shortening. About `gnatkr' ============== The default file naming rule in GNAT is that the file name must be derived from the unit name. The exact default rule is as follows: * Take the unit name and replace all dots by hyphens. * If such a replacement occurs in the second character position of a name, and the first character is a, g, s, or i then replace the dot by the character ~ (tilde) instead of a minus. The reason for this exception is to avoid clashes with the standard names for children of System, Ada, Interfaces, and GNAT, which use the prefixes s- a- i- and g- respectively. The `-gnatkNN' switch of the compiler activates a "krunching" circuit that limits file names to nn characters (where nn is a decimal integer). For example, using OpenVMS, where the maximum file name length is 39, the value of nn is usually set to 39, but if you want to generate a set of files that would be usable if ported to a system with some different maximum file length, then a different value can be specified. The default value of 39 for OpenVMS need not be specified. The `gnatkr' utility can be used to determine the krunched name for a given file, when krunched to a specified maximum length. Using `gnatkr' ============== The `gnatkr' command has the form $ gnatkr NAME [LENGTH] NAME can be an Ada name with dots or the GNAT name of the unit, where the dots representing child units or subunit are replaced by hyphens. The only confusion arises if a name ends in `.ads' or `.adb'. `gnatkr' takes this to be an extension if there are no other dots in the name and the whole name is in lowercase. LENGTH represents the length of the krunched name. The default when no argument is given is 8 characters. A length of zero stands for unlimited, in other words do not chop except for system files which are always 8. The output is the krunched name. The output has an extension only if the original argument was a file name with an extension. Krunching Method ================ The initial file name is determined by the name of the unit that the file contains. The name is formed by taking the full expanded name of the unit and replacing the separating dots with hyphens and using lowercase for all letters, except that a hyphen in the second character position is replaced by a tilde if the first character is a, i, g, or s. The extension is `.ads' for a specification and `.adb' for a body. Krunching does not affect the extension, but the file name is shortened to the specified length by following these rules: * The name is divided into segments separated by hyphens, tildes or underscores and all hyphens, tildes, and underscores are eliminated. If this leaves the name short enough, we are done. * If the name is too long, the longest segment is located (left-most if there are two of equal length), and shortened by dropping its last character. This is repeated until the name is short enough. As an example, consider the krunching of `our-strings-wide_fixed.adb' to fit the name into 8 characters as required by some operating systems. our-strings-wide_fixed 22 our strings wide fixed 19 our string wide fixed 18 our strin wide fixed 17 our stri wide fixed 16 our stri wide fixe 15 our str wide fixe 14 our str wid fixe 13 our str wid fix 12 ou str wid fix 11 ou st wid fix 10 ou st wi fix 9 ou st wi fi 8 Final file name: oustwifi.adb * The file names for all predefined units are always krunched to eight characters. The krunching of these predefined units uses the following special prefix replacements: `ada-' replaced by `a-' `gnat-' replaced by `g-' `interfaces-' replaced by `i-' `system-' replaced by `s-' These system files have a hyphen in the second character position. That is why normal user files replace such a character with a tilde, to avoid confusion with system file names. As an example of this special rule, consider `ada-strings-wide_fixed.adb', which gets krunched as follows: ada-strings-wide_fixed 22 a- strings wide fixed 18 a- string wide fixed 17 a- strin wide fixed 16 a- stri wide fixed 15 a- stri wide fixe 14 a- str wide fixe 13 a- str wid fixe 12 a- str wid fix 11 a- st wid fix 10 a- st wi fix 9 a- st wi fi 8 Final file name: a-stwifi.adb Of course no file shortening algorithm can guarantee uniqueness over all possible unit names, and if file name krunching is used then it is your responsibility to ensure that no name clashes occur. The utility program `gnatkr' is supplied for conveniently determining the krunched name of a file. Examples of `gnatkr' Usage ========================== $ gnatkr very_long_unit_name.ads --> velounna.ads $ gnatkr grandparent-parent-child.ads --> grparchi.ads $ gnatkr Grandparent.Parent.Child --> grparchi $ gnatkr very_long_unit_name.ads/count=6 --> vlunna.ads $ gnatkr very_long_unit_name.ads/count=0 --> very_long_unit_name.ads Preprocessing Using `gnatprep' ****************************** The `gnatprep' utility provides a simple preprocessing capability for Ada programs. It is designed for use with GNAT, but is not dependent on any special features of GNAT. Using `gnatprep' ================ To call `gnatprep' use $ gnatprep [-bcrsu] [-Dsymbol=value] infile outfile [deffile] where `infile' is the full name of the input file, which is an Ada source file containing preprocessor directives. `outfile' is the full name of the output file, which is an Ada source in standard Ada form. When used with GNAT, this file name will normally have an ads or adb suffix. `deffile' is the full name of a text file containing definitions of symbols to be referenced by the preprocessor. This argument is optional, and can be replaced by the use of the `-D' switch. `switches' is an optional sequence of switches as described in the next section. Switches for `gnatprep' ======================= `-b' Causes both preprocessor lines and the lines deleted by preprocessing to be replaced by blank lines in the output source file, preserving line numbers in the output file. `-c' Causes both preprocessor lines and the lines deleted by preprocessing to be retained in the output source as comments marked with the special string "-! ". This option will result in line numbers being preserved in the output file. `-Dsymbol=value' Defines a new symbol, associated with value. If no value is given on the command line, then symbol is considered to be `True'. This switch can be used in place of a definition file. `-r' Causes a `Source_Reference' pragma to be generated that references the original input file, so that error messages will use the file name of this original file. The use of this switch implies that preprocessor lines are not to be removed from the file, so its use will force `-b' mode if `-c' has not been specified explicitly. Note that if the file to be preprocessed contains multiple units, then it will be necessary to `gnatchop' the output file from `gnatprep'. If a `Source_Reference' pragma is present in the preprocessed file, it will be respected by `gnatchop -r' so that the final chopped files will correctly refer to the original input source file for `gnatprep'. `-s' Causes a sorted list of symbol names and values to be listed on the standard output file. `-u' Causes undefined symbols to be treated as having the value FALSE in the context of a preprocessor test. In the absence of this option, an undefined symbol in a `#if' or `#elsif' test will be treated as an error. Note: if neither `-b' nor `-c' is present, then preprocessor lines and deleted lines are completely removed from the output, unless -r is specified, in which case -b is assumed. Form of Definitions File ======================== The definitions file contains lines of the form symbol := value where symbol is an identifier, following normal Ada (case-insensitive) rules for its syntax, and value is one of the following: * Empty, corresponding to a null substitution * A string literal using normal Ada syntax * Any sequence of characters from the set (letters, digits, period, underline). Comment lines may also appear in the definitions file, starting with the usual `--', and comments may be added to the definitions lines. Form of Input Text for `gnatprep' ================================= The input text may contain preprocessor conditional inclusion lines, as well as general symbol substitution sequences. The preprocessor conditional inclusion commands have the form #if expression [then] lines #elsif expression [then] lines #elsif expression [then] lines ... #else lines #end if; In this example, expression is defined by the following grammar: expression ::= expression ::= = "" expression ::= = expression ::= 'Defined expression ::= not expression expression ::= expression and expression expression ::= expression or expression expression ::= expression and then expression expression ::= expression or else expression expression ::= ( expression ) For the first test (expression ::= ) the symbol must have either the value true or false, that is to say the right-hand of the symbol definition must be one of the (case-insensitive) literals `True' or `False'. If the value is true, then the corresponding lines are included, and if the value is false, they are excluded. The test (expression ::= `'Defined') is true only if the symbol has been defined in the definition file or by a `-D' switch on the command line. Otherwise, the test is false. The equality tests are case insensitive, as are all the preprocessor lines. If the symbol referenced is not defined in the symbol definitions file, then the effect depends on whether or not switch `-u' is specified. If so, then the symbol is treated as if it had the value false and the test fails. If this switch is not specified, then it is an error to reference an undefined symbol. It is also an error to reference a symbol that is defined with a value other than `True' or `False'. The use of the `not' operator inverts the sense of this logical test, so that the lines are included only if the symbol is not defined. The `then' keyword is optional as shown The `#' must be the first non-blank character on a line, but otherwise the format is free form. Spaces or tabs may appear between the `#' and the keyword. The keywords and the symbols are case insensitive as in normal Ada code. Comments may be used on a preprocessor line, but other than that, no other tokens may appear on a preprocessor line. Any number of `elsif' clauses can be present, including none at all. The `else' is optional, as in Ada. The `#' marking the start of a preprocessor line must be the first non-blank character on the line, i.e. it must be preceded only by spaces or horizontal tabs. Symbol substitution outside of preprocessor lines is obtained by using the sequence $symbol anywhere within a source line, except in a comment or within a string literal. The identifier following the `$' must match one of the symbols defined in the symbol definition file, and the result is to substitute the value of the symbol in place of `$symbol' in the output file. Note that although the substitution of strings within a string literal is not possible, it is possible to have a symbol whose defined value is a string literal. So instead of setting XYZ to `hello' and writing: Header : String := "$XYZ"; you should set XYZ to `"hello"' and write: Header : String := $XYZ; and then the substitution will occur as desired. The GNAT Library Browser `gnatls' ********************************* `gnatls' is a tool that outputs information about compiled units. It gives the relationship between objects, unit names and source files. It can also be used to check the source dependencies of a unit as well as various characteristics. Running `gnatls' ================ The `gnatls' command has the form $ gnatls switches OBJECT_OR_ALI_FILE The main argument is the list of object or `ali' files (*note The Ada Library Information Files::) for which information is requested. In normal mode, without additional option, `gnatls' produces a four-column listing. Each line represents information for a specific object. The first column gives the full path of the object, the second column gives the name of the principal unit in this object, the third column gives the status of the source and the fourth column gives the full path of the source representing this unit. Here is a simple example of use: $ gnatls *.o ./demo1.o demo1 DIF demo1.adb ./demo2.o demo2 OK demo2.adb ./hello.o h1 OK hello.adb ./instr-child.o instr.child MOK instr-child.adb ./instr.o instr OK instr.adb ./tef.o tef DIF tef.adb ./text_io_example.o text_io_example OK text_io_example.adb ./tgef.o tgef DIF tgef.adb The first line can be interpreted as follows: the main unit which is contained in object file `demo1.o' is demo1, whose main source is in `demo1.adb'. Furthermore, the version of the source used for the compilation of demo1 has been modified (DIF). Each source file has a status qualifier which can be: `OK (unchanged)' The version of the source file used for the compilation of the specified unit corresponds exactly to the actual source file. `MOK (slightly modified)' The version of the source file used for the compilation of the specified unit differs from the actual source file but not enough to require recompilation. If you use gnatmake with the qualifier `-m (minimal recompilation)', a file marked MOK will not be recompiled. `DIF (modified)' No version of the source found on the path corresponds to the source used to build this object. `??? (file not found)' No source file was found for this unit. `HID (hidden, unchanged version not first on PATH)' The version of the source that corresponds exactly to the source used for compilation has been found on the path but it is hidden by another version of the same source that has been modified. Switches for `gnatls' ===================== `gnatls' recognizes the following switches: `-a' Consider all units, including those of the predefined Ada library. Especially useful with `-d'. `-d' List sources from which specified units depend on. `-h' Output the list of options. `-o' Only output information about object files. `-s' Only output information about source files. `-u' Only output information about compilation units. `-aODIR' `-aIDIR' `-IDIR' `-I-' `-nostdinc' Source path manipulation. Same meaning as the equivalent `gnatmake' flags (see *Note Switches for gnatmake::). `--RTS=RTS-PATH' Specifies the default location of the runtime library. Same meaning as the equivalent `gnatmake' flag (see *Note Switches for gnatmake::). `-v' Verbose mode. Output the complete source and object paths. Do not use the default column layout but instead use long format giving as much as information possible on each requested units, including special characteristics such as: `Preelaborable' The unit is preelaborable in the Ada 95 sense. `No_Elab_Code' No elaboration code has been produced by the compiler for this unit. `Pure' The unit is pure in the Ada 95 sense. `Elaborate_Body' The unit contains a pragma Elaborate_Body. `Remote_Types' The unit contains a pragma Remote_Types. `Shared_Passive' The unit contains a pragma Shared_Passive. `Predefined' This unit is part of the predefined environment and cannot be modified by the user. `Remote_Call_Interface' The unit contains a pragma Remote_Call_Interface. Example of `gnatls' Usage ========================= Example of using the verbose switch. Note how the source and object paths are affected by the -I switch. $ gnatls -v -I.. demo1.o GNATLS 3.10w (970212) Copyright 1999 Free Software Foundation, Inc. Source Search Path: ../ /home/comar/local/adainclude/ Object Search Path: ../ /home/comar/local/lib/gcc-lib/mips-sni-sysv4/2.7.2/adalib/ ./demo1.o Unit => Name => demo1 Kind => subprogram body Flags => No_Elab_Code Source => demo1.adb modified The following is an example of use of the dependency list. Note the use of the -s switch which gives a straight list of source files. This can be useful for building specialized scripts. $ gnatls -d demo2.o ./demo2.o demo2 OK demo2.adb OK gen_list.ads OK gen_list.adb OK instr.ads OK instr-child.ads $ gnatls -d -s -a demo1.o demo1.adb /home/comar/local/adainclude/ada.ads /home/comar/local/adainclude/a-finali.ads /home/comar/local/adainclude/a-filico.ads /home/comar/local/adainclude/a-stream.ads /home/comar/local/adainclude/a-tags.ads gen_list.ads gen_list.adb /home/comar/local/adainclude/gnat.ads /home/comar/local/adainclude/g-io.ads instr.ads /home/comar/local/adainclude/system.ads /home/comar/local/adainclude/s-exctab.ads /home/comar/local/adainclude/s-finimp.ads /home/comar/local/adainclude/s-finroo.ads /home/comar/local/adainclude/s-secsta.ads /home/comar/local/adainclude/s-stalib.ads /home/comar/local/adainclude/s-stoele.ads /home/comar/local/adainclude/s-stratt.ads /home/comar/local/adainclude/s-tasoli.ads /home/comar/local/adainclude/s-unstyp.ads /home/comar/local/adainclude/unchconv.ads GNAT and Libraries ****************** This chapter addresses some of the issues related to building and using a library with GNAT. It also shows how the GNAT run-time library can be recompiled. Creating an Ada Library ======================= In the GNAT environment, a library has two components: * Source files. * Compiled code and Ali files. See *Note The Ada Library Information Files::. In order to use other packages *Note The GNAT Compilation Model:: requires a certain number of sources to be available to the compiler. The minimal set of sources required includes the specs of all the packages that make up the visible part of the library as well as all the sources upon which they depend. The bodies of all visible generic units must also be provided. Although it is not strictly mandatory, it is recommended that all sources needed to recompile the library be provided, so that the user can make full use of inter-unit inlining and source-level debugging. This can also make the situation easier for users that need to upgrade their compilation toolchain and thus need to recompile the library from sources. The compiled code can be provided in different ways. The simplest way is to provide directly the set of objects produced by the compiler during the compilation of the library. It is also possible to group the objects into an archive using whatever commands are provided by the operating system. Finally, it is also possible to create a shared library (see option -shared in the GCC manual). There are various possibilities for compiling the units that make up the library: for example with a Makefile *Note Using the GNU make Utility::, or with a conventional script. For simple libraries, it is also possible to create a dummy main program which depends upon all the packages that comprise the interface of the library. This dummy main program can then be given to gnatmake, in order to build all the necessary objects. Here is an example of such a dummy program and the generic commands used to build an archive or a shared library. with My_Lib.Service1; with My_Lib.Service2; with My_Lib.Service3; procedure My_Lib_Dummy is begin null; end; # compiling the library $ gnatmake -c my_lib_dummy.adb # we don't need the dummy object itself $ rm my_lib_dummy.o my_lib_dummy.ali # create an archive with the remaining objects $ ar rc libmy_lib.a *.o # some systems may require "ranlib" to be run as well # or create a shared library $ gcc -shared -o libmy_lib.so *.o # some systems may require the code to have been compiled with -fPIC When the objects are grouped in an archive or a shared library, the user needs to specify the desired library at link time, unless a pragma linker_options has been used in one of the sources: pragma Linker_Options ("-lmy_lib"); Installing an Ada Library ========================= In the GNAT model, installing a library consists in copying into a specific location the files that make up this library. It is possible to install the sources in a different directory from the other files (ALI, objects, archives) since the source path and the object path can easily be specified separately. For general purpose libraries, it is possible for the system administrator to put those libraries in the default compiler paths. To achieve this, he must specify their location in the configuration files "ada_source_path" and "ada_object_path" that must be located in the GNAT installation tree at the same place as the gcc spec file. The location of the gcc spec file can be determined as follows: $ gcc -v The configuration files mentioned above have simple format: each line in them must contain one unique directory name. Those names are added to the corresponding path in their order of appearance in the file. The names can be either absolute or relative, in the latter case, they are relative to where theses files are located. "ada_source_path" and "ada_object_path" might actually not be present in a GNAT installation, in which case, GNAT will look for its run-time library in the directories "adainclude" for the sources and "adalib" for the objects and ALI files. When the files exist, the compiler does not look in "adainclude" and "adalib" at all, and thus the "ada_source_path" file must contain the location for the GNAT run-time sources (which can simply be "adainclude"). In the same way, the "ada_object_path" file must contain the location for the GNAT run-time objects (which can simply be "adalib"). You can also specify a new default path to the runtime library at compilation time with the switch "-RTS=RTS-PATH". You can easily choose and change the runtime you want your program to be compiled with. This switch is recognized by gcc, gnatmake, gnatbind, gnatls, gnatfind and gnatxref. It is possible to install a library before or after the standard GNAT library, by reordering the lines in the configuration files. In general, a library must be installed before the GNAT library if it redefines any part of it. Using an Ada Library ==================== In order to use a Ada library, you need to make sure that this library is on both your source and object path *Note Search Paths and the Run-Time Library (RTL):: and *Note Search Paths for gnatbind::. For instance, you can use the library "mylib" installed in "/dir/my_lib_src" and "/dir/my_lib_obj" with the following commands: $ gnatmake -aI/dir/my_lib_src -aO/dir/my_lib_obj my_appl \ -largs -lmy_lib This can be simplified down to the following: $ gnatmake my_appl when the following conditions are met: * "/dir/my_lib_src" has been added by the user to the environment variable "ADA_INCLUDE_PATH", or by the administrator to the file "ada_source_path" * "/dir/my_lib_obj" has been added by the user to the environment variable "ADA_OBJECTS_PATH", or by the administrator to the file "ada_object_path" * a pragma linker_options, as mentioned in *Note Creating an Ada Library:: as been added to the sources. Creating an Ada Library to be Used in a Non-Ada Context ======================================================= The previous sections detailed how to create and install a library that was usable from an Ada main program. Using this library in a non-Ada context is not possible, because the elaboration of the library is automatically done as part of the main program elaboration. GNAT also provides the ability to build libraries that can be used both in an Ada and non-Ada context. This section describes how to build such a library, and then how to use it from a C program. The method for interfacing with the library from other languages such as Fortran for instance remains the same. Creating the Library -------------------- * Identify the units representing the interface of the library. Here is an example of simple library interface: package Interface is procedure Do_Something; procedure Do_Something_Else; end Interface; * Use `pragma Export' or `pragma Convention' for the exported entities. Our package `Interface' is then updated as follow: package Interface is procedure Do_Something; pragma Export (C, Do_Something, "do_something"); procedure Do_Something_Else; pragma Export (C, Do_Something_Else, "do_something_else"); end Interface; * Compile all the units composing the library. * Bind the library objects. This step is performed by invoking gnatbind with the `-L' switch. `gnatbind' will then generate the library elaboration procedure (named `init') and the run-time finalization procedure (named `final'). # generate the binder file in Ada $ gnatbind -Lmylib interface # generate the binder file in C $ gnatbind -C -Lmylib interface * Compile the files generated by the binder $ gcc -c b~interface.adb * Create the library; The procedure is identical to the procedure explained in *Note Creating an Ada Library::, except that `b~interface.o' needs to be added to the list of objects. # create an archive file $ ar cr libmylib.a b~interface.o # create a shared library $ gcc -shared -o libmylib.so b~interface.o * Provide a "foreign" view of the library interface; The example below shows the content of `mylib_interface.h' (note that there is no rule for the naming of this file, any name can be used) /* the library elaboration procedure */ extern void mylibinit (void); /* the library finalization procedure */ extern void mylibfinal (void); /* the interface exported by the library */ extern void do_something (void); extern void do_something_else (void); Using the Library ----------------- Libraries built as explained above can be used from any program, provided that the elaboration procedures (named `mylibinit' in the previous example) are called before the library services are used. Any number of libraries can be used simultaneously, as long as the elaboration procedure of each library is called. Below is an example of C program that uses our `mylib' library. #include "mylib_interface.h" int main (void) { /* First, elaborate the library before using it */ mylibinit (); /* Main program, using the library exported entities */ do_something (); do_something_else (); /* Library finalization at the end of the program */ mylibfinal (); return 0; } Note that this same library can be used from an equivalent Ada main program. In addition, if the libraries are installed as detailed in *Note Installing an Ada Library::, it is not necessary to invoke the library elaboration and finalization routines. The binder will ensure that this is done as part of the main program elaboration and finalization phases. The Finalization Phase ---------------------- Invoking any library finalization procedure generated by `gnatbind' shuts down the Ada run time permanently. Consequently, the finalization of all Ada libraries must be performed at the end of the program. No call to these libraries nor the Ada run time should be made past the finalization phase. Restrictions in Libraries ------------------------- The pragmas listed below should be used with caution inside libraries, as they can create incompatibilities with other Ada libraries: * pragma `Locking_Policy' * pragma `Queuing_Policy' * pragma `Task_Dispatching_Policy' * pragma `Unreserve_All_Interrupts' When using a library that contains such pragmas, the user must make sure that all libraries use the same pragmas with the same values. Otherwise, a `Program_Error' will be raised during the elaboration of the conflicting libraries. The usage of these pragmas and its consequences for the user should therefore be well documented. Similarly, the traceback in exception occurrences mechanism should be enabled or disabled in a consistent manner across all libraries. Otherwise, a Program_Error will be raised during the elaboration of the conflicting libraries. If the `'Version' and `'Body_Version' attributes are used inside a library, then it is necessary to perform a `gnatbind' step that mentions all ali files in all libraries, so that version identifiers can be properly computed. In practice these attributes are rarely used, so this is unlikely to be a consideration. Rebuilding the GNAT Run-Time Library ==================================== It may be useful to recompile the GNAT library in various contexts, the most important one being the use of partition-wide configuration pragmas such as Normalize_Scalar. A special Makefile called `Makefile.adalib' is provided to that effect and can be found in the directory containing the GNAT library. The location of this directory depends on the way the GNAT environment has been installed and can be determined by means of the command: $ gnatls -v The last entry in the object search path usually contains the gnat library. This Makefile contains its own documentation and in particular the set of instructions needed to rebuild a new library and to use it. Using the GNU `make' Utility **************************** This chapter offers some examples of makefiles that solve specific problems. It does not explain how to write a makefile (see the GNU make documentation), nor does it try to replace the `gnatmake' utility (*note The GNAT Make Program gnatmake::). All the examples in this section are specific to the GNU version of make. Although `make' is a standard utility, and the basic language is the same, these examples use some advanced features found only in `GNU make'. Using gnatmake in a Makefile ============================ Complex project organizations can be handled in a very powerful way by using GNU make combined with gnatmake. For instance, here is a Makefile which allows you to build each subsystem of a big project into a separate shared library. Such a makefile allows you to significantly reduce the link time of very big applications while maintaining full coherence at each step of the build process. The list of dependencies are handled automatically by `gnatmake'. The Makefile is simply used to call gnatmake in each of the appropriate directories. Note that you should also read the example on how to automatically create the list of directories (*note Automatically Creating a List of Directories::) which might help you in case your project has a lot of subdirectories. ## This Makefile is intended to be used with the following directory ## configuration: ## - The sources are split into a series of csc (computer software components) ## Each of these csc is put in its own directory. ## Their name are referenced by the directory names. ## They will be compiled into shared library (although this would also work ## with static libraries ## - The main program (and possibly other packages that do not belong to any ## csc is put in the top level directory (where the Makefile is). ## toplevel_dir __ first_csc (sources) __ lib (will contain the library) ## \_ second_csc (sources) __ lib (will contain the library) ## \_ ... ## Although this Makefile is build for shared library, it is easy to modify ## to build partial link objects instead (modify the lines with -shared and ## gnatlink below) ## ## With this makefile, you can change any file in the system or add any new ## file, and everything will be recompiled correctly (only the relevant shared ## objects will be recompiled, and the main program will be re-linked). # The list of computer software component for your project. This might be # generated automatically. CSC_LIST=aa bb cc # Name of the main program (no extension) MAIN=main # If we need to build objects with -fPIC, uncomment the following line #NEED_FPIC=-fPIC # The following variable should give the directory containing libgnat.so # You can get this directory through 'gnatls -v'. This is usually the last # directory in the Object_Path. GLIB=... # The directories for the libraries # (This macro expands the list of CSC to the list of shared libraries, you # could simply use the expanded form : # LIB_DIR=aa/lib/libaa.so bb/lib/libbb.so cc/lib/libcc.so LIB_DIR=${foreach dir,${CSC_LIST},${dir}/lib/lib${dir}.so} ${MAIN}: objects ${LIB_DIR} gnatbind ${MAIN} ${CSC_LIST:%=-aO%/lib} -shared gnatlink ${MAIN} ${CSC_LIST:%=-l%} objects:: # recompile the sources gnatmake -c -i ${MAIN}.adb ${NEED_FPIC} ${CSC_LIST:%=-I%} # Note: In a future version of GNAT, the following commands will be simplified # by a new tool, gnatmlib ${LIB_DIR}: mkdir -p ${dir $@ } cd ${dir $@ }; gcc -shared -o ${notdir $@ } ../*.o -L${GLIB} -lgnat cd ${dir $@ }; cp -f ../*.ali . # The dependencies for the modules # Note that we have to force the expansion of *.o, since in some cases make won't # be able to do it itself. aa/lib/libaa.so: ${wildcard aa/*.o} bb/lib/libbb.so: ${wildcard bb/*.o} cc/lib/libcc.so: ${wildcard cc/*.o} # Make sure all of the shared libraries are in the path before starting the # program run:: LD_LIBRARY_PATH=pwd/aa/lib:pwd/bb/lib:pwd/cc/lib ./${MAIN} clean:: ${RM} -rf ${CSC_LIST:%=%/lib} ${RM} ${CSC_LIST:%=%/*.ali} ${RM} ${CSC_LIST:%=%/*.o} ${RM} *.o *.ali ${MAIN} Automatically Creating a List of Directories ============================================ In most makefiles, you will have to specify a list of directories, and store it in a variable. For small projects, it is often easier to specify each of them by hand, since you then have full control over what is the proper order for these directories, which ones should be included... However, in larger projects, which might involve hundreds of subdirectories, it might be more convenient to generate this list automatically. The example below presents two methods. The first one, although less general, gives you more control over the list. It involves wildcard characters, that are automatically expanded by `make'. Its shortcoming is that you need to explicitly specify some of the organization of your project, such as for instance the directory tree depth, whether some directories are found in a separate tree,... The second method is the most general one. It requires an external program, called `find', which is standard on all Unix systems. All the directories found under a given root directory will be added to the list. # The examples below are based on the following directory hierarchy: # All the directories can contain any number of files # ROOT_DIRECTORY -> a -> aa -> aaa # -> ab # -> ac # -> b -> ba -> baa # -> bb # -> bc # This Makefile creates a variable called DIRS, that can be reused any time # you need this list (see the other examples in this section) # The root of your project's directory hierarchy ROOT_DIRECTORY=. #### # First method: specify explicitly the list of directories # This allows you to specify any subset of all the directories you need. #### DIRS := a/aa/ a/ab/ b/ba/ #### # Second method: use wildcards # Note that the argument(s) to wildcard below should end with a '/'. # Since wildcards also return file names, we have to filter them out # to avoid duplicate directory names. # We thus use make's `dir' and `sort' functions. # It sets DIRs to the following value (note that the directories aaa and baa # are not given, unless you change the arguments to wildcard). # DIRS= ./a/a/ ./b/ ./a/aa/ ./a/ab/ ./a/ac/ ./b/ba/ ./b/bb/ ./b/bc/ #### DIRS := ${sort ${dir ${wildcard ${ROOT_DIRECTORY}/*/ ${ROOT_DIRECTORY}/*/*/}}} #### # Third method: use an external program # This command is much faster if run on local disks, avoiding NFS slowdowns. # This is the most complete command: it sets DIRs to the following value: # DIRS= ./a ./a/aa ./a/aa/aaa ./a/ab ./a/ac ./b ./b/ba ./b/ba/baa ./b/bb ./b/bc #### DIRS := ${shell find ${ROOT_DIRECTORY} -type d -print} Generating the Command Line Switches ==================================== Once you have created the list of directories as explained in the previous section (*note Automatically Creating a List of Directories::), you can easily generate the command line arguments to pass to gnatmake. For the sake of completeness, this example assumes that the source path is not the same as the object path, and that you have two separate lists of directories. # see "Automatically creating a list of directories" to create # these variables SOURCE_DIRS= OBJECT_DIRS= GNATMAKE_SWITCHES := ${patsubst %,-aI%,${SOURCE_DIRS}} GNATMAKE_SWITCHES += ${patsubst %,-aO%,${OBJECT_DIRS}} all: gnatmake ${GNATMAKE_SWITCHES} main_unit Overcoming Command Line Length Limits ===================================== One problem that might be encountered on big projects is that many operating systems limit the length of the command line. It is thus hard to give gnatmake the list of source and object directories. This example shows how you can set up environment variables, which will make `gnatmake' behave exactly as if the directories had been specified on the command line, but have a much higher length limit (or even none on most systems). It assumes that you have created a list of directories in your Makefile, using one of the methods presented in *Note Automatically Creating a List of Directories::. For the sake of completeness, we assume that the object path (where the ALI files are found) is different from the sources patch. Note a small trick in the Makefile below: for efficiency reasons, we create two temporary variables (SOURCE_LIST and OBJECT_LIST), that are expanded immediately by `make'. This way we overcome the standard make behavior which is to expand the variables only when they are actually used. # In this example, we create both ADA_INCLUDE_PATH and ADA_OBJECT_PATH. # This is the same thing as putting the -I arguments on the command line. # (the equivalent of using -aI on the command line would be to define # only ADA_INCLUDE_PATH, the equivalent of -aO is ADA_OBJECT_PATH). # You can of course have different values for these variables. # # Note also that we need to keep the previous values of these variables, since # they might have been set before running 'make' to specify where the GNAT # library is installed. # see "Automatically creating a list of directories" to create these # variables SOURCE_DIRS= OBJECT_DIRS= empty:= space:=${empty} ${empty} SOURCE_LIST := ${subst ${space},:,${SOURCE_DIRS}} OBJECT_LIST := ${subst ${space},:,${OBJECT_DIRS}} ADA_INCLUDE_PATH += ${SOURCE_LIST} ADA_OBJECT_PATH += ${OBJECT_LIST} export ADA_INCLUDE_PATH export ADA_OBJECT_PATH all: gnatmake main_unit Finding Memory Problems with `gnatmem' ************************************** `gnatmem', is a tool that monitors dynamic allocation and deallocation activity in a program, and displays information about incorrect deallocations and possible sources of memory leaks. Gnatmem provides three type of information: * General information concerning memory management, such as the total number of allocations and deallocations, the amount of allocated memory and the high water mark, i.e. the largest amount of allocated memory in the course of program execution. * Backtraces for all incorrect deallocations, that is to say deallocations which do not correspond to a valid allocation. * Information on each allocation that is potentially the origin of a memory leak. The `gnatmem' command has two modes. It can be used with `gdb' or with instrumented allocation and deallocation routines. The later mode is called the `GMEM' mode. Both modes produce the very same output. Running `gnatmem' (GDB Mode) ============================ The `gnatmem' command has the form $ gnatmem [-q] [n] [-o file] user_program [program_arg]* or $ gnatmem [-q] [n] -i file Gnatmem must be supplied with the executable to examine, followed by its run-time inputs. For example, if a program is executed with the command: $ my_program arg1 arg2 then it can be run under `gnatmem' control using the command: $ gnatmem my_program arg1 arg2 The program is transparently executed under the control of the debugger *Note The GNAT Debugger GDB::. This does not affect the behavior of the program, except for sensitive real-time programs. When the program has completed execution, `gnatmem' outputs a report containing general allocation/deallocation information and potential memory leak. For better results, the user program should be compiled with debugging options *Note Switches for gcc::. Here is a simple example of use: *************** debut cc $ gnatmem test_gm Global information ------------------ Total number of allocations : 45 Total number of deallocations : 6 Final Water Mark (non freed mem) : 11.29 Kilobytes High Water Mark : 11.40 Kilobytes . . . Allocation Root # 2 ------------------- Number of non freed allocations : 11 Final Water Mark (non freed mem) : 1.16 Kilobytes High Water Mark : 1.27 Kilobytes Backtrace : test_gm.adb:23 test_gm.alloc . . . The first block of output give general information. In this case, the Ada construct "new" was executed 45 times, and only 6 calls to an unchecked deallocation routine occurred. Subsequent paragraphs display information on all allocation roots. An allocation root is a specific point in the execution of the program that generates some dynamic allocation, such as a "new" construct. This root is represented by an execution backtrace (or subprogram call stack). By default the backtrace depth for allocations roots is 1, so that a root corresponds exactly to a source location. The backtrace can be made deeper, to make the root more specific. Running `gnatmem' (GMEM Mode) ============================= The `gnatmem' command has the form $ gnatmem [-q] [n] -i gmem.out user_program [program_arg]* The program must have been linked with the instrumented version of the allocation and deallocation routines. This is done with linking with the `libgmem.a' library. For better results, the user program should be compiled with debugging options *Note Switches for gcc::. For example to build `my_program': $ gnatmake -g my_program -largs -lgmem When running `my_program' the file `gmem.out' is produced. This file contains information about all allocations and deallocations done by the program. It is produced by the instrumented allocations and deallocations routines and will be used by `gnatmem'. Gnatmem must be supplied with the `gmem.out' file and the executable to examine followed by its run-time inputs. For example, if a program is executed with the command: $ my_program arg1 arg2 then `gmem.out' can be analysed by `gnatmem' using the command: $ gnatmem -i gmem.out my_program arg1 arg2 Switches for `gnatmem' ====================== `gnatmem' recognizes the following switches: ``-q'' Quiet. Gives the minimum output needed to identify the origin of the memory leaks. Omit statistical information. ``n'' N is an integer literal (usually between 1 and 10) which controls the depth of the backtraces defining allocation root. The default value for N is 1. The deeper the backtrace, the more precise the localization of the root. Note that the total number of roots can depend on this parameter. ``-o file'' Direct the gdb output to the specified file. The `gdb' script used to generate this output is also saved in the file `gnatmem.tmp'. ``-i file'' Do the `gnatmem' processing starting from `file' which has been generated by a previous call to `gnatmem' with the -o switch or `gmem.out' produced by `GMEM' mode. This is useful for post mortem processing. Example of `gnatmem' Usage ========================== This section is based on the `GDB' mode of `gnatmem'. The same results can be achieved using `GMEM' mode. See section *Note Running gnatmem (GMEM Mode)::. The first example shows the use of `gnatmem' on a simple leaking program. Suppose that we have the following Ada program: with Unchecked_Deallocation; procedure Test_Gm is type T is array (1..1000) of Integer; type Ptr is access T; procedure Free is new Unchecked_Deallocation (T, Ptr); A : Ptr; procedure My_Alloc is begin A := new T; end My_Alloc; procedure My_DeAlloc is B : Ptr := A; begin Free (B); end My_DeAlloc; begin My_Alloc; for I in 1 .. 5 loop for J in I .. 5 loop My_Alloc; end loop; My_Dealloc; end loop; end; The program needs to be compiled with debugging option: $ gnatmake -g test_gm `gnatmem' is invoked simply with $ gnatmem test_gm which produces the following output: Global information ------------------ Total number of allocations : 18 Total number of deallocations : 5 Final Water Mark (non freed mem) : 53.00 Kilobytes High Water Mark : 56.90 Kilobytes Allocation Root # 1 ------------------- Number of non freed allocations : 11 Final Water Mark (non freed mem) : 42.97 Kilobytes High Water Mark : 46.88 Kilobytes Backtrace : test_gm.adb:11 test_gm.my_alloc Allocation Root # 2 ------------------- Number of non freed allocations : 1 Final Water Mark (non freed mem) : 10.02 Kilobytes High Water Mark : 10.02 Kilobytes Backtrace : s-secsta.adb:81 system.secondary_stack.ss_init Allocation Root # 3 ------------------- Number of non freed allocations : 1 Final Water Mark (non freed mem) : 12 Bytes High Water Mark : 12 Bytes Backtrace : s-secsta.adb:181 system.secondary_stack.ss_init Note that the GNAT run time contains itself a certain number of allocations that have no corresponding deallocation, as shown here for root #2 and root #1. This is a normal behavior when the number of non freed allocations is one, it locates dynamic data structures that the run time needs for the complete lifetime of the program. Note also that there is only one allocation root in the user program with a single line back trace: test_gm.adb:11 test_gm.my_alloc, whereas a careful analysis of the program shows that 'My_Alloc' is called at 2 different points in the source (line 21 and line 24). If those two allocation roots need to be distinguished, the backtrace depth parameter can be used: $ gnatmem 3 test_gm which will give the following output: Global information ------------------ Total number of allocations : 18 Total number of deallocations : 5 Final Water Mark (non freed mem) : 53.00 Kilobytes High Water Mark : 56.90 Kilobytes Allocation Root # 1 ------------------- Number of non freed allocations : 10 Final Water Mark (non freed mem) : 39.06 Kilobytes High Water Mark : 42.97 Kilobytes Backtrace : test_gm.adb:11 test_gm.my_alloc test_gm.adb:24 test_gm b_test_gm.c:52 main Allocation Root # 2 ------------------- Number of non freed allocations : 1 Final Water Mark (non freed mem) : 10.02 Kilobytes High Water Mark : 10.02 Kilobytes Backtrace : s-secsta.adb:81 system.secondary_stack.ss_init s-secsta.adb:283 b_test_gm.c:33 adainit Allocation Root # 3 ------------------- Number of non freed allocations : 1 Final Water Mark (non freed mem) : 3.91 Kilobytes High Water Mark : 3.91 Kilobytes Backtrace : test_gm.adb:11 test_gm.my_alloc test_gm.adb:21 test_gm b_test_gm.c:52 main Allocation Root # 4 ------------------- Number of non freed allocations : 1 Final Water Mark (non freed mem) : 12 Bytes High Water Mark : 12 Bytes Backtrace : s-secsta.adb:181 system.secondary_stack.ss_init s-secsta.adb:283 b_test_gm.c:33 adainit The allocation root #1 of the first example has been split in 2 roots #1 and #3 thanks to the more precise associated backtrace. GDB and GMEM Modes ================== The main advantage of the `GMEM' mode is that it is a lot faster than the `GDB' mode where the application must be monitored by a `GDB' script. But the `GMEM' mode is available only for DEC Unix, Linux x86, Solaris (sparc and x86) and Windows 95/98/NT/2000 (x86). The main advantage of the `GDB' mode is that it is available on all supported platforms. But it can be very slow if the application does a lot of allocations and deallocations. Implementation Note =================== `gnatmem' Using `GDB' Mode -------------------------- `gnatmem' executes the user program under the control of `GDB' using a script that sets breakpoints and gathers information on each dynamic allocation and deallocation. The output of the script is then analyzed by `gnatmem' in order to locate memory leaks and their origin in the program. Gnatmem works by recording each address returned by the allocation procedure (`__gnat_malloc') along with the backtrace at the allocation point. On each deallocation, the deallocated address is matched with the corresponding allocation. At the end of the processing, the unmatched allocations are considered potential leaks. All the allocations associated with the same backtrace are grouped together and form an allocation root. The allocation roots are then sorted so that those with the biggest number of unmatched allocation are printed first. A delicate aspect of this technique is to distinguish between the data produced by the user program and the data produced by the gdb script. Currently, on systems that allow probing the terminal, the gdb command "tty" is used to force the program output to be redirected to the current terminal while the `gdb' output is directed to a file or to a pipe in order to be processed subsequently by `gnatmem'. `gnatmem' Using `GMEM' Mode --------------------------- This mode use the same algorithm to detect memory leak as the `GDB' mode of `gnatmem', the only difference is in the way data are gathered. In `GMEM' mode the program is linked with instrumented version of `__gnat_malloc' and `__gnat_free' routines. Information needed to find memory leak are recorded by these routines in file `gmem.out'. This mode also require that the stack traceback be available, this is only implemented on some platforms *Note GDB and GMEM Modes::. Finding Memory Problems with GNAT Debug Pool ******************************************** The use of unchecked deallocation and unchecked conversion can easily lead to incorrect memory references. The problems generated by such references are usually difficult to tackle because the symptoms can be very remote from the origin of the problem. In such cases, it is very helpful to detect the problem as early as possible. This is the purpose of the Storage Pool provided by `GNAT.Debug_Pools'. In order to use the GNAT specific debugging pool, the user must associate a debug pool object with each of the access types that may be related to suspected memory problems. See Ada Reference Manual 13.11. type Ptr is access Some_Type; Pool : GNAT.Debug_Pools.Debug_Pool; for Ptr'Storage_Pool use Pool; `GNAT.Debug_Pools' is derived from of a GNAT-specific kind of pool: the Checked_Pool. Such pools, like standard Ada storage pools, allow the user to redefine allocation and deallocation strategies. They also provide a checkpoint for each dereference, through the use of the primitive operation `Dereference' which is implicitly called at each dereference of an access value. Once an access type has been associated with a debug pool, operations on values of the type may raise four distinct exceptions, which correspond to four potential kinds of memory corruption: * `GNAT.Debug_Pools.Accessing_Not_Allocated_Storage' * `GNAT.Debug_Pools.Accessing_Deallocated_Storage' * `GNAT.Debug_Pools.Freeing_Not_Allocated_Storage' * `GNAT.Debug_Pools.Freeing_Deallocated_Storage ' For types associated with a Debug_Pool, dynamic allocation is performed using the standard GNAT allocation routine. References to all allocated chunks of memory are kept in an internal dictionary. The deallocation strategy consists in not releasing the memory to the underlying system but rather to fill it with a memory pattern easily recognizable during debugging sessions: The memory pattern is the old IBM hexadecimal convention: 16#DEADBEEF#. Upon each dereference, a check is made that the access value denotes a properly allocated memory location. Here is a complete example of use of `Debug_Pools', that includes typical instances of memory corruption: with Gnat.Io; use Gnat.Io; with Unchecked_Deallocation; with Unchecked_Conversion; with GNAT.Debug_Pools; with System.Storage_Elements; with Ada.Exceptions; use Ada.Exceptions; procedure Debug_Pool_Test is type T is access Integer; type U is access all T; P : GNAT.Debug_Pools.Debug_Pool; for T'Storage_Pool use P; procedure Free is new Unchecked_Deallocation (Integer, T); function UC is new Unchecked_Conversion (U, T); A, B : aliased T; procedure Info is new GNAT.Debug_Pools.Print_Info(Put_Line); begin Info (P); A := new Integer; B := new Integer; B := A; Info (P); Free (A); begin Put_Line (Integer'Image(B.all)); exception when E : others => Put_Line ("raised: " & Exception_Name (E)); end; begin Free (B); exception when E : others => Put_Line ("raised: " & Exception_Name (E)); end; B := UC(A'Access); begin Put_Line (Integer'Image(B.all)); exception when E : others => Put_Line ("raised: " & Exception_Name (E)); end; begin Free (B); exception when E : others => Put_Line ("raised: " & Exception_Name (E)); end; Info (P); end Debug_Pool_Test; The debug pool mechanism provides the following precise diagnostics on the execution of this erroneous program: Debug Pool info: Total allocated bytes : 0 Total deallocated bytes : 0 Current Water Mark: 0 High Water Mark: 0 Debug Pool info: Total allocated bytes : 8 Total deallocated bytes : 0 Current Water Mark: 8 High Water Mark: 8 raised: GNAT.DEBUG_POOLS.ACCESSING_DEALLOCATED_STORAGE raised: GNAT.DEBUG_POOLS.FREEING_DEALLOCATED_STORAGE raised: GNAT.DEBUG_POOLS.ACCESSING_NOT_ALLOCATED_STORAGE raised: GNAT.DEBUG_POOLS.FREEING_NOT_ALLOCATED_STORAGE Debug Pool info: Total allocated bytes : 8 Total deallocated bytes : 4 Current Water Mark: 4 High Water Mark: 8 Creating Sample Bodies Using `gnatstub' *************************************** `gnatstub' creates body stubs, that is, empty but compilable bodies for library unit declarations. To create a body stub, `gnatstub' has to compile the library unit declaration. Therefore, bodies can be created only for legal library units. Moreover, if a library unit depends semantically upon units located outside the current directory, you have to provide the source search path when calling `gnatstub', see the description of `gnatstub' switches below. Running `gnatstub' ================== `gnatstub' has the command-line interface of the form $ gnatstub [switches] filename [directory] where `filename' is the name of the source file that contains a library unit declaration for which a body must be created. This name should follow the GNAT file name conventions. No crunching is allowed for this file name. The file name may contain the path information. `directory' indicates the directory to place a body stub (default is the current directory) `switches' is an optional sequence of switches as described in the next section Switches for `gnatstub' ======================= `-f' If the destination directory already contains a file with a name of the body file for the argument spec file, replace it with the generated body stub. `-hs' Put the comment header (i.e. all the comments preceding the compilation unit) from the source of the library unit declaration into the body stub. `-hg' Put a sample comment header into the body stub. `-IDIR' `-I-' These switches have the same meaning as in calls to gcc. They define the source search path in the call to gcc issued by `gnatstub' to compile an argument source file. `-iN' (N is a decimal natural number). Set the indentation level in the generated body sample to n, '-i0' means "no indentation", the default indentation is 3. `-k' Do not remove the tree file (i.e. the snapshot of the compiler internal structures used by `gnatstub') after creating the body stub. `-lN' (N is a decimal positive number) Set the maximum line length in the body stub to n, the default is 78. `-q' Quiet mode: do not generate a confirmation when a body is successfully created or a message when a body is not required for an argument unit. `-r' Reuse the tree file (if it exists) instead of creating it: instead of creating the tree file for the library unit declaration, gnatstub tries to find it in the current directory and use it for creating a body. If the tree file is not found, no body is created. `-r' also implies `-k', whether or not `-k' is set explicitly. `-t' Overwrite the existing tree file: if the current directory already contains the file which, according to the GNAT file name rules should be considered as a tree file for the argument source file, gnatstub will refuse to create the tree file needed to create a body sampler, unless `-t' option is set `-v' Verbose mode: generate version information. Reducing the Size of Ada Executables with `gnatelim' **************************************************** About `gnatelim' ================ When a program shares a set of Ada packages with other programs, it may happen that this program uses only a fraction of the subprograms defined in these packages. The code created for these unused subprograms increases the size of the executable. `gnatelim' tracks unused subprograms in an Ada program and outputs a list of GNAT-specific `Eliminate' pragmas (see next section) marking all the subprograms that are declared but never called. By placing the list of `Eliminate' pragmas in the GNAT configuration file `gnat.adc' and recompiling your program, you may decrease the size of its executable, because the compiler will not generate the code for 'eliminated' subprograms. `gnatelim' needs as its input data a set of tree files (see *Note Tree Files::) representing all the components of a program to process and a bind file for a main subprogram (see *Note Preparing Tree and Bind Files for gnatelim::). `Eliminate' Pragma ================== The simplified syntax of the Eliminate pragma used by `gnatelim' is: pragma Eliminate (Library_Unit_Name, Subprogram_Name); where `Library_Unit_Name' full expanded Ada name of a library unit `Subprogram_Name' a simple or expanded name of a subprogram declared within this compilation unit The effect of an `Eliminate' pragma placed in the GNAT configuration file `gnat.adc' is: * If the subprogram `Subprogram_Name' is declared within the library unit `Library_Unit_Name', the compiler will not generate code for this subprogram. This applies to all overloaded subprograms denoted by `Subprogram_Name'. * If a subprogram marked by the pragma `Eliminate' is used (called) in a program, the compiler will produce an error message in the place where it is called. Tree Files ========== A tree file stores a snapshot of the compiler internal data structures at the very end of a successful compilation. It contains all the syntactic and semantic information for the compiled unit and all the units upon which it depends semantically. To use tools that make use of tree files, you need to first produce the right set of tree files. GNAT produces correct tree files when -gnatt -gnatc options are set in a gcc call. The tree files have an .adt extension. Therefore, to produce a tree file for the compilation unit contained in a file named `foo.adb', you must use the command $ gcc -c -gnatc -gnatt foo.adb and you will get the tree file `foo.adt'. compilation. Preparing Tree and Bind Files for `gnatelim' ============================================ A set of tree files covering the program to be analyzed with `gnatelim' and the bind file for the main subprogram does not have to be in the current directory. '-T' gnatelim option may be used to provide the search path for tree files, and '-b' option may be used to point to the bind file to process (see *Note Running gnatelim::) If you do not have the appropriate set of tree files and the right bind file, you may create them in the current directory using the following procedure. Let `Main_Prog' be the name of a main subprogram, and suppose this subprogram is in a file named `main_prog.adb'. To create a bind file for `gnatelim', run `gnatbind' for the main subprogram. `gnatelim' can work with both Ada and C bind files; when both are present, it uses the Ada bind file. The following commands will build the program and create the bind file: $ gnatmake -c Main_Prog $ gnatbind main_prog To create a minimal set of tree files covering the whole program, call `gnatmake' for this program as follows: $ gnatmake -f -c -gnatc -gnatt Main_Prog The `-c' gnatmake option turns off the bind and link steps, that are useless anyway because the sources are compiled with `-gnatc' option which turns off code generation. The `-f' gnatmake option forces recompilation of all the needed sources. This sequence of actions will create all the data needed by `gnatelim' from scratch and therefore guarantee its consistency. If you would like to use some existing set of files as `gnatelim' output, you must make sure that the set of files is complete and consistent. You can use the `-m' switch to check if there are missed tree files Note, that `gnatelim' needs neither object nor ALI files. Running `gnatelim' ================== `gnatelim' has the following command-line interface: $ gnatelim [options] name `name' should be a full expanded Ada name of a main subprogram of a program (partition). `gnatelim' options: `-q' Quiet mode: by default `gnatelim' generates to the standard error stream a trace of the source file names of the compilation units being processed. This option turns this trace off. `-v' Verbose mode: `gnatelim' version information is printed as Ada comments to the standard output stream. `-a' Also look for subprograms from the GNAT run time that can be eliminated. `-m' Check if any tree files are missing for an accurate result. `\-T\DIR' When looking for tree files also look in directory DIR `\-b\BIND_FILE' Specifies BIND_FILE as the bind file to process. If not set, the name of the bind file is computed from the full expanded Ada name of a main subprogram. `-dX' Activate internal debugging switches. X is a letter or digit, or string of letters or digits, which specifies the type of debugging mode desired. Normally these are used only for internal development or system debugging purposes. You can find full documentation for these switches in the body of the `Gnatelim.Options' unit in the compiler source file `gnatelim-options.adb'. `gnatelim' sends its output to the standard output stream, and all the tracing and debug information is sent to the standard error stream. In order to produce a proper GNAT configuration file `gnat.adc', redirection must be used: $ gnatelim Main_Prog > gnat.adc or $ gnatelim Main_Prog >> gnat.adc In order to append the `gnatelim' output to the existing contents of `gnat.adc'. Correcting the List of Eliminate Pragmas ======================================== In some rare cases it may happen that `gnatelim' will try to eliminate subprograms which are actually called in the program. In this case, the compiler will generate an error message of the form: file.adb:106:07: cannot call eliminated subprogram "My_Prog" You will need to manually remove the wrong `Eliminate' pragmas from the `gnat.adc' file. It is advised that you recompile your program from scratch after that because you need a consistent `gnat.adc' file during the entire compilation. Making Your Executables Smaller =============================== In order to get a smaller executable for your program you now have to recompile the program completely with the new `gnat.adc' file created by `gnatelim' in your current directory: $ gnatmake -f Main_Prog (you will need `-f' option for gnatmake to recompile everything with the set of pragmas `Eliminate' you have obtained with `gnatelim'). Be aware that the set of `Eliminate' pragmas is specific to each program. It is not recommended to merge sets of `Eliminate' pragmas created for different programs in one `gnat.adc' file. Summary of the gnatelim Usage Cycle =================================== Here is a quick summary of the steps to be taken in order to reduce the size of your executables with `gnatelim'. You may use other GNAT options to control the optimization level, to produce the debugging information, to set search path, etc. 1. Produce a bind file and a set of tree files $ gnatmake -c Main_Prog $ gnatbind main_prog $ gnatmake -f -c -gnatc -gnatt Main_Prog 2. Generate a list of `Eliminate' pragmas $ gnatelim Main_Prog >[>] gnat.adc 3. Recompile the application $ gnatmake -f Main_Prog Other Utility Programs ********************** This chapter discusses some other utility programs available in the Ada environment. Using Other Utility Programs with GNAT ====================================== The object files generated by GNAT are in standard system format and in particular the debugging information uses this format. This means programs generated by GNAT can be used with existing utilities that depend on these formats. In general, any utility program that works with C will also often work with Ada programs generated by GNAT. This includes software utilities such as gprof (a profiling program), `gdb' (the FSF debugger), and utilities such as Purify. The `gnatpsta' Utility Program ============================== Many of the definitions in package Standard are implementation-dependent. However, the source of this package does not exist as an Ada source file, so these values cannot be determined by inspecting the source. They can be determined by examining in detail the coding of `cstand.adb' which creates the image of Standard in the compiler, but this is awkward and requires a great deal of internal knowledge about the system. The `gnatpsta' utility is designed to deal with this situation. It is an Ada program that dynamically determines the values of all the relevant parameters in Standard, and prints them out in the form of an Ada source listing for Standard, displaying all the values of interest. This output is generated to `stdout'. To determine the value of any parameter in package Standard, simply run `gnatpsta' with no qualifiers or arguments, and examine the output. This is preferable to consulting documentation, because you know that the values you are getting are the actual ones provided by the executing system. The External Symbol Naming Scheme of GNAT ========================================= In order to interpret the output from GNAT, when using tools that are originally intended for use with other languages, it is useful to understand the conventions used to generate link names from the Ada entity names. All link names are in all lowercase letters. With the exception of library procedure names, the mechanism used is simply to use the full expanded Ada name with dots replaced by double underscores. For example, suppose we have the following package spec: package QRS is MN : Integer; end QRS; The variable `MN' has a full expanded Ada name of `QRS.MN', so the corresponding link name is `qrs__mn'. Of course if a `pragma Export' is used this may be overridden: package Exports is Var1 : Integer; pragma Export (Var1, C, External_Name => "var1_name"); Var2 : Integer; pragma Export (Var2, C, Link_Name => "var2_link_name"); end Exports; In this case, the link name for VAR1 is whatever link name the C compiler would assign for the C function VAR1_NAME. This typically would be either VAR1_NAME or _VAR1_NAME, depending on operating system conventions, but other possibilities exist. The link name for VAR2 is VAR2_LINK_NAME, and this is not operating system dependent. One exception occurs for library level procedures. A potential ambiguity arises between the required name `_main' for the C main program, and the name we would otherwise assign to an Ada library level procedure called `Main' (which might well not be the main program). To avoid this ambiguity, we attach the prefix `_ada_' to such names. So if we have a library level procedure such as procedure Hello (S : String); the external name of this procedure will be _ADA_HELLO. Ada Mode for `Glide' ==================== The Glide mode for programming in Ada (both, Ada83 and Ada95) helps the user in understanding existing code and facilitates writing new code. It furthermore provides some utility functions for easier integration of standard Emacs features when programming in Ada. General Features: ----------------- * Full Integrated Development Environment : * support of 'project files' for the configuration (directories, compilation options,...) * compiling and stepping through error messages. * running and debugging your applications within Glide. * easy to use for beginners by pull-down menus, * user configurable by many user-option variables. Ada Mode Features That Help Understanding Code: ----------------------------------------------- * functions for easy and quick stepping through Ada code, * getting cross reference information for identifiers (e.g. find the defining place by a keystroke), * displaying an index menu of types and subprograms and move point to the chosen one, * automatic color highlighting of the various entities in Ada code. Glide Support for Writing Ada Code: ----------------------------------- * switching between spec and body files with possible autogeneration of body files, * automatic formating of subprograms parameter lists. * automatic smart indentation according to Ada syntax, * automatic completion of identifiers, * automatic casing of identifiers, keywords, and attributes, * insertion of statement templates, * filling comment paragraphs like filling normal text, For more information, please refer to the online Glide documentation available in the Glide -> Help Menu. Converting Ada Files to html with `gnathtml' ============================================ This `Perl' script allows Ada source files to be browsed using standard Web browsers. For installation procedure, see the section *Note Installing gnathtml::. Ada reserved keywords are highlighted in a bold font and Ada comments in a blue font. Unless your program was compiled with the gcc `-gnatx' switch to suppress the generation of cross-referencing information, user defined variables and types will appear in a different color; you will be able to click on any identifier and go to its declaration. The command line is as follow: $ perl gnathtml.pl [switches] ada-files You can pass it as many Ada files as you want. `gnathtml' will generate an html file for every ada file, and a global file called `index.htm'. This file is an index of every identifier defined in the files. The available switches are the following ones : `-83' Only the subset on the Ada 83 keywords will be highlighted, not the full Ada 95 keywords set. `-cc COLOR' This option allows you to change the color used for comments. The default value is green. The color argument can be any name accepted by html. `-d' If the ada files depend on some other files (using for instance the `with' command, the latter will also be converted to html. Only the files in the user project will be converted to html, not the files in the run-time library itself. `-D' This command is the same as -d above, but `gnathtml' will also look for files in the run-time library, and generate html files for them. `-f' By default, gnathtml will generate html links only for global entities ('with'ed units, global variables and types,...). If you specify the `-f' on the command line, then links will be generated for local entities too. `-l NUMBER' If this switch is provided and NUMBER is not 0, then `gnathtml' will number the html files every NUMBER line. `-I DIR' Specify a directory to search for library files (`.ali' files) and source files. You can provide several -I switches on the command line, and the directories will be parsed in the order of the command line. `-o DIR' Specify the output directory for html files. By default, gnathtml will saved the generated html files in a subdirectory named `html/'. `-p FILE' If you are using Emacs and the most recent Emacs Ada mode, which provides a full Integrated Development Environment for compiling, checking, running and debugging applications, you may be using `.adp' files to give the directories where Emacs can find sources and object files. Using this switch, you can tell gnathtml to use these files. This allows you to get an html version of your application, even if it is spread over multiple directories. `-sc COLOR' This option allows you to change the color used for symbol definitions. The default value is red. The color argument can be any name accepted by html. `-t FILE' This switch provides the name of a file. This file contains a list of file names to be converted, and the effect is exactly as though they had appeared explicitly on the command line. This is the recommended way to work around the command line length limit on some systems. Installing `gnathtml' ===================== `Perl' needs to be installed on your machine to run this script. `Perl' is freely available for almost every architecture and Operating System via the Internet. On Unix systems, you may want to modify the first line of the script `gnathtml', to explicitly tell the Operating system where Perl is. The syntax of this line is : #!full_path_name_to_perl Alternatively, you may run the script using the following command line: $ perl gnathtml.pl [switches] files Running and Debugging Ada Programs ********************************** This chapter discusses how to debug Ada programs. An incorrect Ada program may be handled in three ways by the GNAT compiler: 1. The illegality may be a violation of the static semantics of Ada. In that case GNAT diagnoses the constructs in the program that are illegal. It is then a straightforward matter for the user to modify those parts of the program. 2. The illegality may be a violation of the dynamic semantics of Ada. In that case the program compiles and executes, but may generate incorrect results, or may terminate abnormally with some exception. 3. When presented with a program that contains convoluted errors, GNAT itself may terminate abnormally without providing full diagnostics on the incorrect user program. The GNAT Debugger GDB ===================== `GDB' is a general purpose, platform-independent debugger that can be used to debug mixed-language programs compiled with `GCC', and in particular is capable of debugging Ada programs compiled with GNAT. The latest versions of `GDB' are Ada-aware and can handle complex Ada data structures. The manual `Debugging with GDB' contains full details on the usage of `GDB', including a section on its usage on programs. This manual should be consulted for full details. The section that follows is a brief introduction to the philosophy and use of `GDB'. When GNAT programs are compiled, the compiler optionally writes debugging information into the generated object file, including information on line numbers, and on declared types and variables. This information is separate from the generated code. It makes the object files considerably larger, but it does not add to the size of the actual executable that will be loaded into memory, and has no impact on run-time performance. The generation of debug information is triggered by the use of the -g switch in the gcc or gnatmake command used to carry out the compilations. It is important to emphasize that the use of these options does not change the generated code. The debugging information is written in standard system formats that are used by many tools, including debuggers and profilers. The format of the information is typically designed to describe C types and semantics, but GNAT implements a translation scheme which allows full details about Ada types and variables to be encoded into these standard C formats. Details of this encoding scheme may be found in the file exp_dbug.ads in the GNAT source distribution. However, the details of this encoding are, in general, of no interest to a user, since `GDB' automatically performs the necessary decoding. When a program is bound and linked, the debugging information is collected from the object files, and stored in the executable image of the program. Again, this process significantly increases the size of the generated executable file, but it does not increase the size of the executable program itself. Furthermore, if this program is run in the normal manner, it runs exactly as if the debug information were not present, and takes no more actual memory. However, if the program is run under control of `GDB', the debugger is activated. The image of the program is loaded, at which point it is ready to run. If a run command is given, then the program will run exactly as it would have if `GDB' were not present. This is a crucial part of the `GDB' design philosophy. `GDB' is entirely non-intrusive until a breakpoint is encountered. If no breakpoint is ever hit, the program will run exactly as it would if no debugger were present. When a breakpoint is hit, `GDB' accesses the debugging information and can respond to user commands to inspect variables, and more generally to report on the state of execution. Running GDB =========== The debugger can be launched directly and simply from `glide' or through its graphical interface: `gvd'. It can also be used directly in text mode. Here is described the basic use of `GDB' in text mode. All the commands described below can be used in the `gvd' console window eventhough there is usually other more graphical ways to achieve the same goals. The command to run de graphical interface of the debugger is $ gvd program The command to run `GDB' in text mode is $ gdb program where `program' is the name of the executable file. This activates the debugger and results in a prompt for debugger commands. The simplest command is simply `run', which causes the program to run exactly as if the debugger were not present. The following section describes some of the additional commands that can be given to `GDB'. Introduction to GDB Commands ============================ `GDB' contains a large repertoire of commands. The manual `Debugging with GDB' includes extensive documentation on the use of these commands, together with examples of their use. Furthermore, the command HELP invoked from within `GDB' activates a simple help facility which summarizes the available commands and their options. In this section we summarize a few of the most commonly used commands to give an idea of what `GDB' is about. You should create a simple program with debugging information and experiment with the use of these `GDB' commands on the program as you read through the following section. `set args ARGUMENTS' The ARGUMENTS list above is a list of arguments to be passed to the program on a subsequent run command, just as though the arguments had been entered on a normal invocation of the program. The `set args' command is not needed if the program does not require arguments. `run' The `run' command causes execution of the program to start from the beginning. If the program is already running, that is to say if you are currently positioned at a breakpoint, then a prompt will ask for confirmation that you want to abandon the current execution and restart. `breakpoint LOCATION' The breakpoint command sets a breakpoint, that is to say a point at which execution will halt and `GDB' will await further commands. LOCATION is either a line number within a file, given in the format `file:linenumber', or it is the name of a subprogram. If you request that a breakpoint be set on a subprogram that is overloaded, a prompt will ask you to specify on which of those subprograms you want to breakpoint. You can also specify that all of them should be breakpointed. If the program is run and execution encounters the breakpoint, then the program stops and `GDB' signals that the breakpoint was encountered by printing the line of code before which the program is halted. `breakpoint exception NAME' A special form of the breakpoint command which breakpoints whenever exception NAME is raised. If NAME is omitted, then a breakpoint will occur when any exception is raised. `print EXPRESSION' This will print the value of the given expression. Most simple Ada expression formats are properly handled by `GDB', so the expression can contain function calls, variables, operators, and attribute references. `continue' Continues execution following a breakpoint, until the next breakpoint or the termination of the program. `step' Executes a single line after a breakpoint. If the next statement is a subprogram call, execution continues into (the first statement of) the called subprogram. `next' Executes a single line. If this line is a subprogram call, executes and returns from the call. `list' Lists a few lines around the current source location. In practice, it is usually more convenient to have a separate edit window open with the relevant source file displayed. Successive applications of this command print subsequent lines. The command can be given an argument which is a line number, in which case it displays a few lines around the specified one. `backtrace' Displays a backtrace of the call chain. This command is typically used after a breakpoint has occurred, to examine the sequence of calls that leads to the current breakpoint. The display includes one line for each activation record (frame) corresponding to an active subprogram. `up' At a breakpoint, `GDB' can display the values of variables local to the current frame. The command `up' can be used to examine the contents of other active frames, by moving the focus up the stack, that is to say from callee to caller, one frame at a time. `down' Moves the focus of `GDB' down from the frame currently being examined to the frame of its callee (the reverse of the previous command), `frame N' Inspect the frame with the given number. The value 0 denotes the frame of the current breakpoint, that is to say the top of the call stack. The above list is a very short introduction to the commands that `GDB' provides. Important additional capabilities, including conditional breakpoints, the ability to execute command sequences on a breakpoint, the ability to debug at the machine instruction level and many other features are described in detail in `Debugging with GDB'. Note that most commands can be abbreviated (for example, c for continue, bt for backtrace). Using Ada Expressions ===================== `GDB' supports a fairly large subset of Ada expression syntax, with some extensions. The philosophy behind the design of this subset is * That `GDB' should provide basic literals and access to operations for arithmetic, dereferencing, field selection, indexing, and subprogram calls, leaving more sophisticated computations to subprograms written into the program (which therefore may be called from `GDB'). * That type safety and strict adherence to Ada language restrictions are not particularly important to the `GDB' user. * That brevity is important to the `GDB' user. Thus, for brevity, the debugger acts as if there were implicit `with' and `use' clauses in effect for all user-written packages, thus making it unnecessary to fully qualify most names with their packages, regardless of context. Where this causes ambiguity, `GDB' asks the user's intent. For details on the supported Ada syntax, see `Debugging with GDB'. Calling User-Defined Subprograms ================================ An important capability of `GDB' is the ability to call user-defined subprograms while debugging. This is achieved simply by entering a subprogram call statement in the form: call subprogram-name (parameters) The keyword `call' can be omitted in the normal case where the `subprogram-name' does not coincide with any of the predefined `GDB' commands. The effect is to invoke the given subprogram, passing it the list of parameters that is supplied. The parameters can be expressions and can include variables from the program being debugged. The subprogram must be defined at the library level within your program, and `GDB' will call the subprogram within the environment of your program execution (which means that the subprogram is free to access or even modify variables within your program). The most important use of this facility is in allowing the inclusion of debugging routines that are tailored to particular data structures in your program. Such debugging routines can be written to provide a suitably high-level description of an abstract type, rather than a low-level dump of its physical layout. After all, the standard `GDB print' command only knows the physical layout of your types, not their abstract meaning. Debugging routines can provide information at the desired semantic level and are thus enormously useful. For example, when debugging GNAT itself, it is crucial to have access to the contents of the tree nodes used to represent the program internally. But tree nodes are represented simply by an integer value (which in turn is an index into a table of nodes). Using the `print' command on a tree node would simply print this integer value, which is not very useful. But the PN routine (defined in file treepr.adb in the GNAT sources) takes a tree node as input, and displays a useful high level representation of the tree node, which includes the syntactic category of the node, its position in the source, the integers that denote descendant nodes and parent node, as well as varied semantic information. To study this example in more detail, you might want to look at the body of the PN procedure in the stated file. Using the Next Command in a Function ==================================== When you use the `next' command in a function, the current source location will advance to the next statement as usual. A special case arises in the case of a `return' statement. Part of the code for a return statement is the "epilog" of the function. This is the code that returns to the caller. There is only one copy of this epilog code, and it is typically associated with the last return statement in the function if there is more than one return. In some implementations, this epilog is associated with the first statement of the function. The result is that if you use the `next' command from a return statement that is not the last return statement of the function you may see a strange apparent jump to the last return statement or to the start of the function. You should simply ignore this odd jump. The value returned is always that from the first return statement that was stepped through. Breaking on Ada Exceptions ========================== You can set breakpoints that trip when your program raises selected exceptions. `break exception' Set a breakpoint that trips whenever (any task in the) program raises any exception. `break exception NAME' Set a breakpoint that trips whenever (any task in the) program raises the exception NAME. `break exception unhandled' Set a breakpoint that trips whenever (any task in the) program raises an exception for which there is no handler. `info exceptions' `info exceptions REGEXP' The `info exceptions' command permits the user to examine all defined exceptions within Ada programs. With a regular expression, REGEXP, as argument, prints out only those exceptions whose name matches REGEXP. Ada Tasks ========= `GDB' allows the following task-related commands: `info tasks' This command shows a list of current Ada tasks, as in the following example: (gdb) info tasks ID TID P-ID Thread Pri State Name 1 8088000 0 807e000 15 Child Activation Wait main_task 2 80a4000 1 80ae000 15 Accept/Select Wait b 3 809a800 1 80a4800 15 Child Activation Wait a * 4 80ae800 3 80b8000 15 Running c In this listing, the asterisk before the first task indicates it to be the currently running task. The first column lists the task ID that is used to refer to tasks in the following commands. `break LINESPEC task TASKID' `break LINESPEC task TASKID if ...' These commands are like the `break ... thread ...'. LINESPEC specifies source lines. Use the qualifier `task TASKID' with a breakpoint command to specify that you only want `GDB' to stop the program when a particular Ada task reaches this breakpoint. TASKID is one of the numeric task identifiers assigned by `GDB', shown in the first column of the `info tasks' display. If you do not specify `task TASKID' when you set a breakpoint, the breakpoint applies to _all_ tasks of your program. You can use the `task' qualifier on conditional breakpoints as well; in this case, place `task TASKID' before the breakpoint condition (before the `if'). `task TASKNO' This command allows to switch to the task referred by TASKNO. In particular, This allows to browse the backtrace of the specified task. It is advised to switch back to the original task before continuing execution otherwise the scheduling of the program may be perturbated. For more detailed information on the tasking support, see `Debugging with GDB'. Debugging Generic Units ======================= GNAT always uses code expansion for generic instantiation. This means that each time an instantiation occurs, a complete copy of the original code is made, with appropriate substitutions of formals by actuals. It is not possible to refer to the original generic entities in `GDB', but it is always possible to debug a particular instance of a generic, by using the appropriate expanded names. For example, if we have procedure g is generic package k is procedure kp (v1 : in out integer); end k; package body k is procedure kp (v1 : in out integer) is begin v1 := v1 + 1; end kp; end k; package k1 is new k; package k2 is new k; var : integer := 1; begin k1.kp (var); k2.kp (var); k1.kp (var); k2.kp (var); end; Then to break on a call to procedure kp in the k2 instance, simply use the command: (gdb) break g.k2.kp When the breakpoint occurs, you can step through the code of the instance in the normal manner and examine the values of local variables, as for other units. GNAT Abnormal Termination or Failure to Terminate ================================================= When presented with programs that contain serious errors in syntax or semantics, GNAT may on rare occasions experience problems in operation, such as aborting with a segmentation fault or illegal memory access, raising an internal exception, terminating abnormally, or failing to terminate at all. In such cases, you can activate various features of GNAT that can help you pinpoint the construct in your program that is the likely source of the problem. The following strategies are presented in increasing order of difficulty, corresponding to your experience in using GNAT and your familiarity with compiler internals. 1. Run `gcc' with the `-gnatf'. This first switch causes all errors on a given line to be reported. In its absence, only the first error on a line is displayed. The `-gnatdO' switch causes errors to be displayed as soon as they are encountered, rather than after compilation is terminated. If GNAT terminates prematurely or goes into an infinite loop, the last error message displayed may help to pinpoint the culprit. 2. Run `gcc' with the `-v (verbose)' switch. In this mode, `gcc' produces ongoing information about the progress of the compilation and provides the name of each procedure as code is generated. This switch allows you to find which Ada procedure was being compiled when it encountered a code generation problem. 3. Run `gcc' with the `-gnatdc' switch. This is a GNAT specific switch that does for the front-end what `-v' does for the back end. The system prints the name of each unit, either a compilation unit or nested unit, as it is being analyzed. 4. Finally, you can start `gdb' directly on the `gnat1' executable. `gnat1' is the front-end of GNAT, and can be run independently (normally it is just called from `gcc'). You can use `gdb' on `gnat1' as you would on a C program (but *note The GNAT Debugger GDB:: for caveats). The `where' command is the first line of attack; the variable `lineno' (seen by `print lineno'), used by the second phase of `gnat1' and by the `gcc' backend, indicates the source line at which the execution stopped, and `input_file name' indicates the name of the source file. Naming Conventions for GNAT Source Files ======================================== In order to examine the workings of the GNAT system, the following brief description of its organization may be helpful: * Files with prefix `sc' contain the lexical scanner. * All files prefixed with `par' are components of the parser. The numbers correspond to chapters of the Ada 95 Reference Manual. For example, parsing of select statements can be found in `par-ch9.adb'. * All files prefixed with `sem' perform semantic analysis. The numbers correspond to chapters of the Ada standard. For example, all issues involving context clauses can be found in `sem_ch10.adb'. In addition, some features of the language require sufficient special processing to justify their own semantic files: sem_aggr for aggregates, sem_disp for dynamic dispatching, etc. * All files prefixed with `exp' perform normalization and expansion of the intermediate representation (abstract syntax tree, or AST). these files use the same numbering scheme as the parser and semantics files. For example, the construction of record initialization procedures is done in `exp_ch3.adb'. * The files prefixed with `bind' implement the binder, which verifies the consistency of the compilation, determines an order of elaboration, and generates the bind file. * The files `atree.ads' and `atree.adb' detail the low-level data structures used by the front-end. * The files `sinfo.ads' and `sinfo.adb' detail the structure of the abstract syntax tree as produced by the parser. * The files `einfo.ads' and `einfo.adb' detail the attributes of all entities, computed during semantic analysis. * Library management issues are dealt with in files with prefix `lib'. * Ada files with the prefix `a-' are children of `Ada', as defined in Annex A. * Files with prefix `i-' are children of `Interfaces', as defined in Annex B. * Files with prefix `s-' are children of `System'. This includes both language-defined children and GNAT run-time routines. * Files with prefix `g-' are children of `GNAT'. These are useful general-purpose packages, fully documented in their specifications. All the other `.c' files are modifications of common `gcc' files. Getting Internal Debugging Information ====================================== Most compilers have internal debugging switches and modes. GNAT does also, except GNAT internal debugging switches and modes are not secret. A summary and full description of all the compiler and binder debug flags are in the file `debug.adb'. You must obtain the sources of the compiler to see the full detailed effects of these flags. The switches that print the source of the program (reconstructed from the internal tree) are of general interest for user programs, as are the options to print the full internal tree, and the entity table (the symbol table information). The reconstructed source provides a readable version of the program after the front-end has completed analysis and expansion, and is useful when studying the performance of specific constructs. For example, constraint checks are indicated, complex aggregates are replaced with loops and assignments, and tasking primitives are replaced with run-time calls. Stack Traceback =============== Traceback is a mechanism to display the sequence of subprogram calls that leads to a specified execution point in a program. Often (but not always) the execution point is an instruction at which an exception has been raised. This mechanism is also known as stack unwinding because it obtains its information by scanning the run-time stack and recovering the activation records of all active subprograms. Stack unwinding is one of the most important tools for program debugging. The first entry stored in traceback corresponds to the deepest calling level, that is to say the subprogram currently executing the instruction from which we want to obtain the traceback. Note that there is no runtime performance penalty when stack traceback is enabled and no exception are raised during program execution. Non-Symbolic Traceback ---------------------- Note: this feature is not supported on all platforms. See `GNAT.Traceback spec in g-traceb.ads' for a complete list of supported platforms. Tracebacks From an Unhandled Exception ...................................... A runtime non-symbolic traceback is a list of addresses of call instructions. To enable this feature you must use the `-E' `gnatbind''s option. With this option a stack traceback is stored as part of exception information. It is possible to retrieve this information using the standard `Ada.Exception.Exception_Information' routine. Let's have a look at a simple example: procedure STB is procedure P1 is begin raise Constraint_Error; end P1; procedure P2 is begin P1; end P2; begin P2; end STB; $ gnatmake stb -bargs -E $ stb Execution terminated by unhandled exception Exception name: CONSTRAINT_ERROR Message: stb.adb:5 Call stack traceback locations: 0x401373 0x40138b 0x40139c 0x401335 0x4011c4 0x4011f1 0x77e892a4 As we see the traceback lists a sequence of addresses for the unhandled exception `CONSTAINT_ERROR' raised in procedure P1. It is easy to guess that this exception come from procedure P1. To translate these addresses into the source lines where the calls appear, the `addr2line' tool, described below, is invaluable. The use of this tool requires the program to be compiled with debug information. $ gnatmake -g stb -bargs -E $ stb Execution terminated by unhandled exception Exception name: CONSTRAINT_ERROR Message: stb.adb:5 Call stack traceback locations: 0x401373 0x40138b 0x40139c 0x401335 0x4011c4 0x4011f1 0x77e892a4 $ addr2line --exe=stb 0x401373 0x40138b 0x40139c 0x401335 0x4011c4 0x4011f1 0x77e892a4 00401373 at d:/stb/stb.adb:5 0040138B at d:/stb/stb.adb:10 0040139C at d:/stb/stb.adb:14 00401335 at d:/stb/b~stb.adb:104 004011C4 at /build/.../crt1.c:200 004011F1 at /build/.../crt1.c:222 77E892A4 in ?? at ??:0 `addr2line' has a number of other useful options: `--functions' to get the function name corresponding to any location `--demangle=gnat' to use the gnat decoding mode for the function names. Note that for binutils version 2.9.x the option is simply `--demangle'. $ addr2line --exe=stb --functions --demangle=gnat 0x401373 0x40138b 0x40139c 0x401335 0x4011c4 0x4011f1 00401373 in stb.p1 at d:/stb/stb.adb:5 0040138B in stb.p2 at d:/stb/stb.adb:10 0040139C in stb at d:/stb/stb.adb:14 00401335 in main at d:/stb/b~stb.adb:104 004011C4 in <__mingw_CRTStartup> at /build/.../crt1.c:200 004011F1 in at /build/.../crt1.c:222 From this traceback we can see that the exception was raised in `stb.adb' at line 5, which was reached from a procedure call in `stb.adb' at line 10, and so on. The `b~std.adb' is the binder file, which contains the call to the main program. *note Running gnatbind::. The remaining entries are assorted runtime routines, and the output will vary from platform to platform. It is also possible to use `GDB' with these traceback addresses to debug the program. For example, we can break at a given code location, as reported in the stack traceback: $ gdb -nw stb (gdb) break *0x401373 Breakpoint 1 at 0x401373: file stb.adb, line 5. It is important to note that the stack traceback addresses do not change when debug information is included. This is particularly useful because it makes it possible to release software without debug information (to minimize object size), get a field report that includes a stack traceback whenever an internal bug occurs, and then be able to retrieve the sequence of calls with the same program compiled with debug information. Tracebacks From Exception Occurrences ..................................... Non-symbolic tracebacks are obtained by using the `-E' binder argument. The stack traceback is attached to the exception information string, and can be retrieved in an exception handler within the Ada program, by means of the Ada95 facilities defined in `Ada.Exceptions'. Here is a simple example: with Ada.Text_IO; with Ada.Exceptions; procedure STB is use Ada; use Ada.Exceptions; procedure P1 is K : Positive := 1; begin K := K - 1; exception when E : others => Text_IO.Put_Line (Exception_Information (E)); end P1; procedure P2 is begin P1; end P2; begin P2; end STB; This program will output: $ stb Exception name: CONSTRAINT_ERROR Message: stb.adb:12 Call stack traceback locations: 0x4015e4 0x401633 0x401644 0x401461 0x4011c4 0x4011f1 0x77e892a4 Tracebacks From Anywhere in a Program ..................................... It is also possible to retrieve a stack traceback from anywhere in a program. For this you need to use the `GNAT.Traceback' API. This package includes a procedure called `Call_Chain' that computes a complete stack traceback, as well as useful display procedures described below. It is not necessary to use the `-E gnatbind' option in this case, because the stack traceback mechanism is invoked explicitly. In the following example we compute a traceback at a specific location in the program, and we display it using `GNAT.Debug_Utilities.Image' to convert addresses to strings: with Ada.Text_IO; with GNAT.Traceback; with GNAT.Debug_Utilities; procedure STB is use Ada; use GNAT; use GNAT.Traceback; procedure P1 is TB : Tracebacks_Array (1 .. 10); -- We are asking for a maximum of 10 stack frames. Len : Natural; -- Len will receive the actual number of stack frames returned. begin Call_Chain (TB, Len); Text_IO.Put ("In STB.P1 : "); for K in 1 .. Len loop Text_IO.Put (Debug_Utilities.Image (TB (K))); Text_IO.Put (' '); end loop; Text_IO.New_Line; end P1; procedure P2 is begin P1; end P2; begin P2; end STB; $ gnatmake stb $ stb In STB.P1 : 16#0040_F1E4# 16#0040_14F2# 16#0040_170B# 16#0040_171C# 16#0040_1461# 16#0040_11C4# 16#0040_11F1# 16#77E8_92A4# Symbolic Traceback ------------------ A symbolic traceback is a stack traceback in which procedure names are associated with each code location. Note that this feature is not supported on all platforms. See `GNAT.Traceback.Symbolic spec in g-trasym.ads' for a complete list of currently supported platforms. Note that the symbolic traceback requires that the program be compiled with debug information. If it is not compiled with debug information only the non-symbolic information will be valid. Tracebacks From Exception Occurrences ..................................... with Ada.Text_IO; with GNAT.Traceback.Symbolic; procedure STB is procedure P1 is begin raise Constraint_Error; end P1; procedure P2 is begin P1; end P2; procedure P3 is begin P2; end P3; begin P3; exception when E : others => Ada.Text_IO.Put_Line (GNAT.Traceback.Symbolic.Symbolic_Traceback (E)); end STB; $ gnatmake -g stb -bargs -E -largs -lgnat -laddr2line -lintl $ stb 0040149F in stb.p1 at stb.adb:8 004014B7 in stb.p2 at stb.adb:13 004014CF in stb.p3 at stb.adb:18 004015DD in ada.stb at stb.adb:22 00401461 in main at b~stb.adb:168 004011C4 in __mingw_CRTStartup at crt1.c:200 004011F1 in mainCRTStartup at crt1.c:222 77E892A4 in ?? at ??:0 The exact sequence of linker options may vary from platform to platform. The above `-largs' section is for Windows platforms. By contrast, under Unix there is no need for the `-largs' section. Differences across platforms are due to details of linker implementation. Tracebacks From Anywhere in a Program ..................................... It is possible to get a symbolic stack traceback from anywhere in a program, just as for non-symbolic tracebacks. The first step is to obtain a non-symbolic traceback, and then call `Symbolic_Traceback' to compute the symbolic information. Here is an example: with Ada.Text_IO; with GNAT.Traceback; with GNAT.Traceback.Symbolic; procedure STB is use Ada; use GNAT.Traceback; use GNAT.Traceback.Symbolic; procedure P1 is TB : Tracebacks_Array (1 .. 10); -- We are asking for a maximum of 10 stack frames. Len : Natural; -- Len will receive the actual number of stack frames returned. begin Call_Chain (TB, Len); Text_IO.Put_Line (Symbolic_Traceback (TB (1 .. Len))); end P1; procedure P2 is begin P1; end P2; begin P2; end STB; Inline Assembler **************** If you need to write low-level software that interacts directly with the hardware, Ada provides two ways to incorporate assembly language code into your program. First, you can import and invoke external routines written in assembly language, an Ada feature fully supported by GNAT. However, for small sections of code it may be simpler or more efficient to include assembly language statements directly in your Ada source program, using the facilities of the implementation-defined package `System.Machine_Code', which incorporates the gcc Inline Assembler. The Inline Assembler approach offers a number of advantages, including the following: * No need to use non-Ada tools * Consistent interface over different targets * Automatic usage of the proper calling conventions * Access to Ada constants and variables * Definition of intrinsic routines * Possibility of inlining a subprogram comprising assembler code * Code optimizer can take Inline Assembler code into account This chapter presents a series of examples to show you how to use the Inline Assembler. Although it focuses on the Intel x86, the general approach applies also to other processors. It is assumed that you are familiar with Ada and with assembly language programming. Basic Assembler Syntax ====================== The assembler used by GNAT and gcc is based not on the Intel assembly language, but rather on a language that descends from the AT&T Unix assembler _as_ (and which is often referred to as AT&T syntax"). The following table summarizes the main features of _as_ syntax and points out the differences from the Intel conventions. See the gcc _as_ and _gas_ (an _as_ macro pre-processor) documentation for further information. Register names gcc / _as_: Prefix with %"; for example `%eax' Intel: No extra punctuation; for example `eax' Immediate operand gcc / _as_: Prefix with $"; for example `$4' Intel: No extra punctuation; for example `4' Address gcc / _as_: Prefix with $"; for example `$loc' Intel: No extra punctuation; for example `loc' Memory contents gcc / _as_: No extra punctuation; for example `loc' Intel: Square brackets; for example `[loc]' Register contents gcc / _as_: Parentheses; for example `(%eax)' Intel: Square brackets; for example `[eax]' Hexadecimal numbers gcc / _as_: Leading 0x" (C language syntax); for example `0xA0' Intel: Trailing h"; for example `A0h' Operand size gcc / _as_: Explicit in op code; for example `movw' to move a 16-bit word Intel: Implicit, deduced by assembler; for example `mov' Instruction repetition gcc / _as_: Split into two lines; for example `rep' `stosl' Intel: Keep on one line; for example `rep stosl' Order of operands gcc / _as_: Source first; for example `movw $4, %eax' Intel: Destination first; for example `mov eax, 4' A Simple Example of Inline Assembler ==================================== The following example will generate a single assembly language statement, `nop', which does nothing. Despite its lack of run-time effect, the example will be useful in illustrating the basics of the Inline Assembler facility. with System.Machine_Code; use System.Machine_Code; procedure Nothing is begin Asm ("nop"); end Nothing; `Asm' is a procedure declared in package `System.Machine_Code'; here it takes one parameter, a _template string_ that must be a static expression and that will form the generated instruction. `Asm' may be regarded as a compile-time procedure that parses the template string and additional parameters (none here), from which it generates a sequence of assembly language instructions. The examples in this chapter will illustrate several of the forms for invoking `Asm'; a complete specification of the syntax is found in the `GNAT Reference Manual'. Under the standard GNAT conventions, the `Nothing' procedure should be in a file named `nothing.adb'. You can build the executable in the usual way: gnatmake nothing However, the interesting aspect of this example is not its run-time behavior but rather the generated assembly code. To see this output, invoke the compiler as follows: gcc -c -S -fomit-frame-pointer -gnatp `nothing.adb' where the options are: `-c' compile only (no bind or link) `-S' generate assembler listing `-fomit-frame-pointer' do not set up separate stack frames `-gnatp' do not add runtime checks This gives a human-readable assembler version of the code. The resulting file will have the same name as the Ada source file, but with a `.s' extension. In our example, the file `nothing.s' has the following contents: .file "nothing.adb" gcc2_compiled.: ___gnu_compiled_ada: .text .align 4 .globl __ada_nothing __ada_nothing: #APP nop #NO_APP jmp L1 .align 2,0x90 L1: ret The assembly code you included is clearly indicated by the compiler, between the `#APP' and `#NO_APP' delimiters. The character before the 'APP' and 'NOAPP' can differ on different targets. For example, Linux uses '#APP' while on NT you will see '/APP'. If you make a mistake in your assembler code (such as using the wrong size modifier, or using a wrong operand for the instruction) GNAT will report this error in a temporary file, which will be deleted when the compilation is finished. Generating an assembler file will help in such cases, since you can assemble this file separately using the _as_ assembler that comes with gcc. Assembling the file using the command as `nothing.s' will give you error messages whose lines correspond to the assembler input file, so you can easily find and correct any mistakes you made. If there are no errors, _as_ will generate an object file `nothing.out'. Output Variables in Inline Assembler ==================================== The examples in this section, showing how to access the processor flags, illustrate how to specify the destination operands for assembly language statements. with Interfaces; use Interfaces; with Ada.Text_IO; use Ada.Text_IO; with System.Machine_Code; use System.Machine_Code; procedure Get_Flags is Flags : Unsigned_32; use ASCII; begin Asm ("pushfl" & LF & HT & -- push flags on stack "popl %%eax" & LF & HT & -- load eax with flags "movl %%eax, %0", -- store flags in variable Outputs => Unsigned_32'Asm_Output ("=g", Flags)); Put_Line ("Flags register:" & Flags'Img); end Get_Flags; In order to have a nicely aligned assembly listing, we have separated multiple assembler statements in the Asm template string with linefeed (ASCII.LF) and horizontal tab (ASCII.HT) characters. The resulting section of the assembly output file is: #APP pushfl popl %eax movl %eax, -40(%ebp) #NO_APP It would have been legal to write the Asm invocation as: Asm ("pushfl popl %%eax movl %%eax, %0") but in the generated assembler file, this would come out as: #APP pushfl popl %eax movl %eax, -40(%ebp) #NO_APP which is not so convenient for the human reader. We use Ada comments at the end of each line to explain what the assembler instructions actually do. This is a useful convention. When writing Inline Assembler instructions, you need to precede each register and variable name with a percent sign. Since the assembler already requires a percent sign at the beginning of a register name, you need two consecutive percent signs for such names in the Asm template string, thus `%%eax'. In the generated assembly code, one of the percent signs will be stripped off. Names such as `%0', `%1', `%2', etc., denote input or output variables: operands you later define using `Input' or `Output' parameters to `Asm'. An output variable is illustrated in the third statement in the Asm template string: movl %%eax, %0 The intent is to store the contents of the eax register in a variable that can be accessed in Ada. Simply writing `movl %%eax, Flags' would not necessarily work, since the compiler might optimize by using a register to hold Flags, and the expansion of the `movl' instruction would not be aware of this optimization. The solution is not to store the result directly but rather to advise the compiler to choose the correct operand form; that is the purpose of the `%0' output variable. Information about the output variable is supplied in the `Outputs' parameter to `Asm': Outputs => Unsigned_32'Asm_Output ("=g", Flags)); The output is defined by the `Asm_Output' attribute of the target type; the general format is Type'Asm_Output (constraint_string, variable_name) The constraint string directs the compiler how to store/access the associated variable. In the example Unsigned_32'Asm_Output ("=m", Flags); the `"m"' (memory) constraint tells the compiler that the variable `Flags' should be stored in a memory variable, thus preventing the optimizer from keeping it in a register. In contrast, Unsigned_32'Asm_Output ("=r", Flags); uses the `"r"' (register) constraint, telling the compiler to store the variable in a register. If the constraint is preceded by the equal character (*=*), it tells the compiler that the variable will be used to store data into it. In the `Get_Flags' example, we used the "g" (global) constraint, allowing the optimizer to choose whatever it deems best. There are a fairly large number of constraints, but the ones that are most useful (for the Intel x86 processor) are the following: `=' output constraint `g' global (i.e. can be stored anywhere) `m' in memory `I' a constant `a' use eax `b' use ebx `c' use ecx `d' use edx `S' use esi `D' use edi `r' use one of eax, ebx, ecx or edx `q' use one of eax, ebx, ecx, edx, esi or edi The full set of constraints is described in the gcc and _as_ documentation; note that it is possible to combine certain constraints in one constraint string. You specify the association of an output variable with an assembler operand through the `%'_n_ notation, where _n_ is a non-negative integer. Thus in Asm ("pushfl" & LF & HT & -- push flags on stack "popl %%eax" & LF & HT & -- load eax with flags "movl %%eax, %0", -- store flags in variable Outputs => Unsigned_32'Asm_Output ("=g", Flags)); `%0' will be replaced in the expanded code by the appropriate operand, whatever the compiler decided for the `Flags' variable. In general, you may have any number of output variables: * Count the operands starting at 0; thus `%0', `%1', etc. * Specify the `Outputs' parameter as a parenthesized comma-separated list of `Asm_Output' attributes For example: Asm ("movl %%eax, %0" & LF & HT & "movl %%ebx, %1" & LF & HT & "movl %%ecx, %2", Outputs => (Unsigned_32'Asm_Output ("=g", Var_A), -- %0 = Var_A Unsigned_32'Asm_Output ("=g", Var_B), -- %1 = Var_B Unsigned_32'Asm_Output ("=g", Var_C))); -- %2 = Var_C where `Var_A', `Var_B', and `Var_C' are variables in the Ada program. As a variation on the `Get_Flags' example, we can use the constraints string to direct the compiler to store the eax register into the `Flags' variable, instead of including the store instruction explicitly in the `Asm' template string: with Interfaces; use Interfaces; with Ada.Text_IO; use Ada.Text_IO; with System.Machine_Code; use System.Machine_Code; procedure Get_Flags_2 is Flags : Unsigned_32; use ASCII; begin Asm ("pushfl" & LF & HT & -- push flags on stack "popl %%eax", -- save flags in eax Outputs => Unsigned_32'Asm_Output ("=a", Flags)); Put_Line ("Flags register:" & Flags'Img); end Get_Flags_2; The `"a"' constraint tells the compiler that the `Flags' variable will come from the eax register. Here is the resulting code: #APP pushfl popl %eax #NO_APP movl %eax,-40(%ebp) The compiler generated the store of eax into Flags after expanding the assembler code. Actually, there was no need to pop the flags into the eax register; more simply, we could just pop the flags directly into the program variable: with Interfaces; use Interfaces; with Ada.Text_IO; use Ada.Text_IO; with System.Machine_Code; use System.Machine_Code; procedure Get_Flags_3 is Flags : Unsigned_32; use ASCII; begin Asm ("pushfl" & LF & HT & -- push flags on stack "pop %0", -- save flags in Flags Outputs => Unsigned_32'Asm_Output ("=g", Flags)); Put_Line ("Flags register:" & Flags'Img); end Get_Flags_3; Input Variables in Inline Assembler =================================== The example in this section illustrates how to specify the source operands for assembly language statements. The program simply increments its input value by 1: with Interfaces; use Interfaces; with Ada.Text_IO; use Ada.Text_IO; with System.Machine_Code; use System.Machine_Code; procedure Increment is function Incr (Value : Unsigned_32) return Unsigned_32 is Result : Unsigned_32; begin Asm ("incl %0", Inputs => Unsigned_32'Asm_Input ("a", Value), Outputs => Unsigned_32'Asm_Output ("=a", Result)); return Result; end Incr; Value : Unsigned_32; begin Value := 5; Put_Line ("Value before is" & Value'Img); Value := Incr (Value); Put_Line ("Value after is" & Value'Img); end Increment; The `Outputs' parameter to `Asm' specifies that the result will be in the eax register and that it is to be stored in the `Result' variable. The `Inputs' parameter looks much like the `Outputs' parameter, but with an `Asm_Input' attribute. The `"="' constraint, indicating an output value, is not present. You can have multiple input variables, in the same way that you can have more than one output variable. The parameter count (%0, %1) etc, now starts at the first input statement, and continues with the output statements. When both parameters use the same variable, the compiler will treat them as the same %n operand, which is the case here. Just as the `Outputs' parameter causes the register to be stored into the target variable after execution of the assembler statements, so does the `Inputs' parameter cause its variable to be loaded into the register before execution of the assembler statements. Thus the effect of the `Asm' invocation is: 1. load the 32-bit value of `Value' into eax 2. execute the `incl %eax' instruction 3. store the contents of eax into the `Result' variable The resulting assembler file (with `-O2' optimization) contains: _increment__incr.1: subl $4,%esp movl 8(%esp),%eax #APP incl %eax #NO_APP movl %eax,%edx movl %ecx,(%esp) addl $4,%esp ret Inlining Inline Assembler Code ============================== For a short subprogram such as the `Incr' function in the previous section, the overhead of the call and return (creating / deleting the stack frame) can be significant, compared to the amount of code in the subprogram body. A solution is to apply Ada's `Inline' pragma to the subprogram, which directs the compiler to expand invocations of the subprogram at the point(s) of call, instead of setting up a stack frame for out-of-line calls. Here is the resulting program: with Interfaces; use Interfaces; with Ada.Text_IO; use Ada.Text_IO; with System.Machine_Code; use System.Machine_Code; procedure Increment_2 is function Incr (Value : Unsigned_32) return Unsigned_32 is Result : Unsigned_32; begin Asm ("incl %0", Inputs => Unsigned_32'Asm_Input ("a", Value), Outputs => Unsigned_32'Asm_Output ("=a", Result)); return Result; end Incr; pragma Inline (Increment); Value : Unsigned_32; begin Value := 5; Put_Line ("Value before is" & Value'Img); Value := Increment (Value); Put_Line ("Value after is" & Value'Img); end Increment_2; Compile the program with both optimization (`-O2') and inlining enabled (`-gnatpn' instead of `-gnatp'). The `Incr' function is still compiled as usual, but at the point in `Increment' where our function used to be called: pushl %edi call _increment__incr.1 the code for the function body directly appears: movl %esi,%eax #APP incl %eax #NO_APP movl %eax,%edx thus saving the overhead of stack frame setup and an out-of-line call. Other `Asm' Functionality ========================= This section describes two important parameters to the `Asm' procedure: `Clobber', which identifies register usage; and `Volatile', which inhibits unwanted optimizations. The `Clobber' Parameter ----------------------- One of the dangers of intermixing assembly language and a compiled language such as Ada is that the compiler needs to be aware of which registers are being used by the assembly code. In some cases, such as the earlier examples, the constraint string is sufficient to indicate register usage (e.g. "a" for the eax register). But more generally, the compiler needs an explicit identification of the registers that are used by the Inline Assembly statements. Using a register that the compiler doesn't know about could be a side effect of an instruction (like `mull' storing its result in both eax and edx). It can also arise from explicit register usage in your assembly code; for example: Asm ("movl %0, %%ebx" & LF & HT & "movl %%ebx, %1", Inputs => Unsigned_32'Asm_Input ("g", Var_In), Outputs => Unsigned_32'Asm_Output ("=g", Var_Out)); where the compiler (since it does not analyze the `Asm' template string) does not know you are using the ebx register. In such cases you need to supply the `Clobber' parameter to `Asm', to identify the registers that will be used by your assembly code: Asm ("movl %0, %%ebx" & LF & HT & "movl %%ebx, %1", Inputs => Unsigned_32'Asm_Input ("g", Var_In), Outputs => Unsigned_32'Asm_Output ("=g", Var_Out), Clobber => "ebx"); The Clobber parameter is a static string expression specifying the register(s) you are using. Note that register names are _not_ prefixed by a percent sign. Also, if more than one register is used then their names are separated by commas; e.g., `"eax, ebx"' The `Clobber' parameter has several additional uses: 1. Use the "register" name `cc' to indicate that flags might have changed 2. Use the "register" name `memory' if you changed a memory location The `Volatile' Parameter ------------------------ Compiler optimizations in the presence of Inline Assembler may sometimes have unwanted effects. For example, when an `Asm' invocation with an input variable is inside a loop, the compiler might move the loading of the input variable outside the loop, regarding it as a one-time initialization. If this effect is not desired, you can disable such optimizations by setting the `Volatile' parameter to `True'; for example: Asm ("movl %0, %%ebx" & LF & HT & "movl %%ebx, %1", Inputs => Unsigned_32'Asm_Input ("g", Var_In), Outputs => Unsigned_32'Asm_Output ("=g", Var_Out), Clobber => "ebx", Volatile => True); By default, `Volatile' is set to `False' unless there is no `Outputs' parameter. Although setting `Volatile' to `True' prevents unwanted optimizations, it will also disable other optimizations that might be important for efficiency. In general, you should set `Volatile' to `True' only if the compiler's optimizations have created problems. A Complete Example ================== This section contains a complete program illustrating a realistic usage of GNAT's Inline Assembler capabilities. It comprises a main procedure `Check_CPU' and a package `Intel_CPU'. The package declares a collection of functions that detect the properties of the 32-bit x86 processor that is running the program. The main procedure invokes these functions and displays the information. The Intel_CPU package could be enhanced by adding functions to detect the type of x386 co-processor, the processor caching options and special operations such as the SIMD extensions. Although the Intel_CPU package has been written for 32-bit Intel compatible CPUs, it is OS neutral. It has been tested on DOS, Windows/NT and Linux. `Check_CPU' Procedure --------------------- --------------------------------------------------------------------- -- -- -- Uses the Intel_CPU package to identify the CPU the program is -- -- running on, and some of the features it supports. -- -- -- --------------------------------------------------------------------- with Intel_CPU; -- Intel CPU detection functions with Ada.Text_IO; -- Standard text I/O with Ada.Command_Line; -- To set the exit status procedure Check_CPU is Type_Found : Boolean := False; -- Flag to indicate that processor was identified Features : Intel_CPU.Processor_Features; -- The processor features Signature : Intel_CPU.Processor_Signature; -- The processor type signature begin ----------------------------------- -- Display the program banner. -- ----------------------------------- Ada.Text_IO.Put_Line (Ada.Command_Line.Command_Name & ": check Intel CPU version and features, v1.0"); Ada.Text_IO.Put_Line ("distribute freely, but no warranty whatsoever"); Ada.Text_IO.New_Line; ----------------------------------------------------------------------- -- We can safely start with the assumption that we are on at least -- -- a x386 processor. If the CPUID instruction is present, then we -- -- have a later processor type. -- ----------------------------------------------------------------------- if Intel_CPU.Has_CPUID = False then -- No CPUID instruction, so we assume this is indeed a x386 -- processor. We can still check if it has a FP co-processor. if Intel_CPU.Has_FPU then Ada.Text_IO.Put_Line ("x386-type processor with a FP co-processor"); else Ada.Text_IO.Put_Line ("x386-type processor without a FP co-processor"); end if; -- check for FPU -- Program done Ada.Command_Line.Set_Exit_Status (Ada.Command_Line.Success); return; end if; -- check for CPUID ----------------------------------------------------------------------- -- If CPUID is supported, check if this is a true Intel processor, -- -- if it is not, display a warning. -- ----------------------------------------------------------------------- if Intel_CPU.Vendor_ID /= Intel_CPU.Intel_Processor then Ada.Text_IO.Put_Line ("*** This is a Intel compatible processor"); Ada.Text_IO.Put_Line ("*** Some information may be incorrect"); end if; -- check if Intel ---------------------------------------------------------------------- -- With the CPUID instruction present, we can assume at least a -- -- x486 processor. If the CPUID support level is < 1 then we have -- -- to leave it at that. -- ---------------------------------------------------------------------- if Intel_CPU.CPUID_Level < 1 then -- Ok, this is a x486 processor. we still can get the Vendor ID Ada.Text_IO.Put_Line ("x486-type processor"); Ada.Text_IO.Put_Line ("Vendor ID is " & Intel_CPU.Vendor_ID); -- We can also check if there is a FPU present if Intel_CPU.Has_FPU then Ada.Text_IO.Put_Line ("Floating-Point support"); else Ada.Text_IO.Put_Line ("No Floating-Point support"); end if; -- check for FPU -- Program done Ada.Command_Line.Set_Exit_Status (Ada.Command_Line.Success); return; end if; -- check CPUID level --------------------------------------------------------------------- -- With a CPUID level of 1 we can use the processor signature to -- -- determine it's exact type. -- --------------------------------------------------------------------- Signature := Intel_CPU.Signature; ---------------------------------------------------------------------- -- Ok, now we go into a lot of messy comparisons to get the -- -- processor type. For clarity, no attememt to try to optimize the -- -- comparisons has been made. Note that since Intel_CPU does not -- -- support getting cache info, we cannot distinguish between P5 -- -- and Celeron types yet. -- ---------------------------------------------------------------------- -- x486SL if Signature.Processor_Type = 2#00# and Signature.Family = 2#0100# and Signature.Model = 2#0100# then Type_Found := True; Ada.Text_IO.Put_Line ("x486SL processor"); end if; -- x486DX2 Write-Back if Signature.Processor_Type = 2#00# and Signature.Family = 2#0100# and Signature.Model = 2#0111# then Type_Found := True; Ada.Text_IO.Put_Line ("Write-Back Enhanced x486DX2 processor"); end if; -- x486DX4 if Signature.Processor_Type = 2#00# and Signature.Family = 2#0100# and Signature.Model = 2#1000# then Type_Found := True; Ada.Text_IO.Put_Line ("x486DX4 processor"); end if; -- x486DX4 Overdrive if Signature.Processor_Type = 2#01# and Signature.Family = 2#0100# and Signature.Model = 2#1000# then Type_Found := True; Ada.Text_IO.Put_Line ("x486DX4 OverDrive processor"); end if; -- Pentium (60, 66) if Signature.Processor_Type = 2#00# and Signature.Family = 2#0101# and Signature.Model = 2#0001# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium processor (60, 66)"); end if; -- Pentium (75, 90, 100, 120, 133, 150, 166, 200) if Signature.Processor_Type = 2#00# and Signature.Family = 2#0101# and Signature.Model = 2#0010# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium processor (75, 90, 100, 120, 133, 150, 166, 200)"); end if; -- Pentium OverDrive (60, 66) if Signature.Processor_Type = 2#01# and Signature.Family = 2#0101# and Signature.Model = 2#0001# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium OverDrive processor (60, 66)"); end if; -- Pentium OverDrive (75, 90, 100, 120, 133, 150, 166, 200) if Signature.Processor_Type = 2#01# and Signature.Family = 2#0101# and Signature.Model = 2#0010# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium OverDrive cpu (75, 90, 100, 120, 133, 150, 166, 200)"); end if; -- Pentium OverDrive processor for x486 processor-based systems if Signature.Processor_Type = 2#01# and Signature.Family = 2#0101# and Signature.Model = 2#0011# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium OverDrive processor for x486 processor-based systems"); end if; -- Pentium processor with MMX technology (166, 200) if Signature.Processor_Type = 2#00# and Signature.Family = 2#0101# and Signature.Model = 2#0100# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium processor with MMX technology (166, 200)"); end if; -- Pentium OverDrive with MMX for Pentium (75, 90, 100, 120, 133) if Signature.Processor_Type = 2#01# and Signature.Family = 2#0101# and Signature.Model = 2#0100# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium OverDrive processor with MMX " & "technology for Pentium processor (75, 90, 100, 120, 133)"); end if; -- Pentium Pro processor if Signature.Processor_Type = 2#00# and Signature.Family = 2#0110# and Signature.Model = 2#0001# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium Pro processor"); end if; -- Pentium II processor, model 3 if Signature.Processor_Type = 2#00# and Signature.Family = 2#0110# and Signature.Model = 2#0011# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium II processor, model 3"); end if; -- Pentium II processor, model 5 or Celeron processor if Signature.Processor_Type = 2#00# and Signature.Family = 2#0110# and Signature.Model = 2#0101# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium II processor, model 5 or Celeron processor"); end if; -- Pentium Pro OverDrive processor if Signature.Processor_Type = 2#01# and Signature.Family = 2#0110# and Signature.Model = 2#0011# then Type_Found := True; Ada.Text_IO.Put_Line ("Pentium Pro OverDrive processor"); end if; -- If no type recognized, we have an unknown. Display what -- we _do_ know if Type_Found = False then Ada.Text_IO.Put_Line ("Unknown processor"); end if; ----------------------------------------- -- Display processor stepping level. -- ----------------------------------------- Ada.Text_IO.Put_Line ("Stepping level:" & Signature.Stepping'Img); --------------------------------- -- Display vendor ID string. -- --------------------------------- Ada.Text_IO.Put_Line ("Vendor ID: " & Intel_CPU.Vendor_ID); ------------------------------------ -- Get the processors features. -- ------------------------------------ Features := Intel_CPU.Features; ----------------------------- -- Check for a FPU unit. -- ----------------------------- if Features.FPU = True then Ada.Text_IO.Put_Line ("Floating-Point unit available"); else Ada.Text_IO.Put_Line ("no Floating-Point unit"); end if; -- check for FPU -------------------------------- -- List processor features. -- -------------------------------- Ada.Text_IO.Put_Line ("Supported features: "); -- Virtual Mode Extension if Features.VME = True then Ada.Text_IO.Put_Line (" VME - Virtual Mode Extension"); end if; -- Debugging Extension if Features.DE = True then Ada.Text_IO.Put_Line (" DE - Debugging Extension"); end if; -- Page Size Extension if Features.PSE = True then Ada.Text_IO.Put_Line (" PSE - Page Size Extension"); end if; -- Time Stamp Counter if Features.TSC = True then Ada.Text_IO.Put_Line (" TSC - Time Stamp Counter"); end if; -- Model Specific Registers if Features.MSR = True then Ada.Text_IO.Put_Line (" MSR - Model Specific Registers"); end if; -- Physical Address Extension if Features.PAE = True then Ada.Text_IO.Put_Line (" PAE - Physical Address Extension"); end if; -- Machine Check Extension if Features.MCE = True then Ada.Text_IO.Put_Line (" MCE - Machine Check Extension"); end if; -- CMPXCHG8 instruction supported if Features.CX8 = True then Ada.Text_IO.Put_Line (" CX8 - CMPXCHG8 instruction"); end if; -- on-chip APIC hardware support if Features.APIC = True then Ada.Text_IO.Put_Line (" APIC - on-chip APIC hardware support"); end if; -- Fast System Call if Features.SEP = True then Ada.Text_IO.Put_Line (" SEP - Fast System Call"); end if; -- Memory Type Range Registers if Features.MTRR = True then Ada.Text_IO.Put_Line (" MTTR - Memory Type Range Registers"); end if; -- Page Global Enable if Features.PGE = True then Ada.Text_IO.Put_Line (" PGE - Page Global Enable"); end if; -- Machine Check Architecture if Features.MCA = True then Ada.Text_IO.Put_Line (" MCA - Machine Check Architecture"); end if; -- Conditional Move Instruction Supported if Features.CMOV = True then Ada.Text_IO.Put_Line (" CMOV - Conditional Move Instruction Supported"); end if; -- Page Attribute Table if Features.PAT = True then Ada.Text_IO.Put_Line (" PAT - Page Attribute Table"); end if; -- 36-bit Page Size Extension if Features.PSE_36 = True then Ada.Text_IO.Put_Line (" PSE_36 - 36-bit Page Size Extension"); end if; -- MMX technology supported if Features.MMX = True then Ada.Text_IO.Put_Line (" MMX - MMX technology supported"); end if; -- Fast FP Save and Restore if Features.FXSR = True then Ada.Text_IO.Put_Line (" FXSR - Fast FP Save and Restore"); end if; --------------------- -- Program done. -- --------------------- Ada.Command_Line.Set_Exit_Status (Ada.Command_Line.Success); exception when others => Ada.Command_Line.Set_Exit_Status (Ada.Command_Line.Failure); raise; end Check_CPU; `Intel_CPU' Package Specification --------------------------------- ------------------------------------------------------------------------- -- -- -- file: intel_cpu.ads -- -- -- -- ********************************************* -- -- * WARNING: for 32-bit Intel processors only * -- -- ********************************************* -- -- -- -- This package contains a number of subprograms that are useful in -- -- determining the Intel x86 CPU (and the features it supports) on -- -- which the program is running. -- -- -- -- The package is based upon the information given in the Intel -- -- Application Note AP-485: "Intel Processor Identification and the -- -- CPUID Instruction" as of April 1998. This application note can be -- -- found on www.intel.com. -- -- -- -- It currently deals with 32-bit processors only, will not detect -- -- features added after april 1998, and does not guarantee proper -- -- results on Intel-compatible processors. -- -- -- -- Cache info and x386 fpu type detection are not supported. -- -- -- -- This package does not use any privileged instructions, so should -- -- work on any OS running on a 32-bit Intel processor. -- -- -- ------------------------------------------------------------------------- with Interfaces; use Interfaces; -- for using unsigned types with System.Machine_Code; use System.Machine_Code; -- for using inline assembler code with Ada.Characters.Latin_1; use Ada.Characters.Latin_1; -- for inserting control characters package Intel_CPU is ---------------------- -- Processor bits -- ---------------------- subtype Num_Bits is Natural range 0 .. 31; -- the number of processor bits (32) -------------------------- -- Processor register -- -------------------------- -- define a processor register type for easy access to -- the individual bits type Processor_Register is array (Num_Bits) of Boolean; pragma Pack (Processor_Register); for Processor_Register'Size use 32; ------------------------- -- Unsigned register -- ------------------------- -- define a processor register type for easy access to -- the individual bytes type Unsigned_Register is record L1 : Unsigned_8; H1 : Unsigned_8; L2 : Unsigned_8; H2 : Unsigned_8; end record; for Unsigned_Register use record L1 at 0 range 0 .. 7; H1 at 0 range 8 .. 15; L2 at 0 range 16 .. 23; H2 at 0 range 24 .. 31; end record; for Unsigned_Register'Size use 32; --------------------------------- -- Intel processor vendor ID -- --------------------------------- Intel_Processor : constant String (1 .. 12) := "GenuineIntel"; -- indicates an Intel manufactured processor ------------------------------------ -- Processor signature register -- ------------------------------------ -- a register type to hold the processor signature type Processor_Signature is record Stepping : Natural range 0 .. 15; Model : Natural range 0 .. 15; Family : Natural range 0 .. 15; Processor_Type : Natural range 0 .. 3; Reserved : Natural range 0 .. 262143; end record; for Processor_Signature use record Stepping at 0 range 0 .. 3; Model at 0 range 4 .. 7; Family at 0 range 8 .. 11; Processor_Type at 0 range 12 .. 13; Reserved at 0 range 14 .. 31; end record; for Processor_Signature'Size use 32; ----------------------------------- -- Processor features register -- ----------------------------------- -- a processor register to hold the processor feature flags type Processor_Features is record FPU : Boolean; -- floating point unit on chip VME : Boolean; -- virtual mode extension DE : Boolean; -- debugging extension PSE : Boolean; -- page size extension TSC : Boolean; -- time stamp counter MSR : Boolean; -- model specific registers PAE : Boolean; -- physical address extension MCE : Boolean; -- machine check extension CX8 : Boolean; -- cmpxchg8 instruction APIC : Boolean; -- on-chip apic hardware Res_1 : Boolean; -- reserved for extensions SEP : Boolean; -- fast system call MTRR : Boolean; -- memory type range registers PGE : Boolean; -- page global enable MCA : Boolean; -- machine check architecture CMOV : Boolean; -- conditional move supported PAT : Boolean; -- page attribute table PSE_36 : Boolean; -- 36-bit page size extension Res_2 : Natural range 0 .. 31; -- reserved for extensions MMX : Boolean; -- MMX technology supported FXSR : Boolean; -- fast FP save and restore Res_3 : Natural range 0 .. 127; -- reserved for extensions end record; for Processor_Features use record FPU at 0 range 0 .. 0; VME at 0 range 1 .. 1; DE at 0 range 2 .. 2; PSE at 0 range 3 .. 3; TSC at 0 range 4 .. 4; MSR at 0 range 5 .. 5; PAE at 0 range 6 .. 6; MCE at 0 range 7 .. 7; CX8 at 0 range 8 .. 8; APIC at 0 range 9 .. 9; Res_1 at 0 range 10 .. 10; SEP at 0 range 11 .. 11; MTRR at 0 range 12 .. 12; PGE at 0 range 13 .. 13; MCA at 0 range 14 .. 14; CMOV at 0 range 15 .. 15; PAT at 0 range 16 .. 16; PSE_36 at 0 range 17 .. 17; Res_2 at 0 range 18 .. 22; MMX at 0 range 23 .. 23; FXSR at 0 range 24 .. 24; Res_3 at 0 range 25 .. 31; end record; for Processor_Features'Size use 32; ------------------- -- Subprograms -- ------------------- function Has_FPU return Boolean; -- return True if a FPU is found -- use only if CPUID is not supported function Has_CPUID return Boolean; -- return True if the processor supports the CPUID instruction function CPUID_Level return Natural; -- return the CPUID support level (0, 1 or 2) -- can only be called if the CPUID instruction is supported function Vendor_ID return String; -- return the processor vendor identification string -- can only be called if the CPUID instruction is supported function Signature return Processor_Signature; -- return the processor signature -- can only be called if the CPUID instruction is supported function Features return Processor_Features; -- return the processors features -- can only be called if the CPUID instruction is supported private ------------------------ -- EFLAGS bit names -- ------------------------ ID_Flag : constant Num_Bits := 21; -- ID flag bit end Intel_CPU; `Intel_CPU' Package Body ------------------------ package body Intel_CPU is --------------------------- -- Detect FPU presence -- --------------------------- -- There is a FPU present if we can set values to the FPU Status -- and Control Words. function Has_FPU return Boolean is Register : Unsigned_16; -- processor register to store a word begin -- check if we can change the status word Asm ( -- the assembler code "finit" & LF & HT & -- reset status word "movw $0x5A5A, %%ax" & LF & HT & -- set value status word "fnstsw %0" & LF & HT & -- save status word "movw %%ax, %0", -- store status word -- output stored in Register -- register must be a memory location Outputs => Unsigned_16'Asm_output ("=m", Register), -- tell compiler that we used eax Clobber => "eax"); -- if the status word is zero, there is no FPU if Register = 0 then return False; -- no status word end if; -- check status word value -- check if we can get the control word Asm ( -- the assembler code "fnstcw %0", -- save the control word -- output into Register -- register must be a memory location Outputs => Unsigned_16'Asm_output ("=m", Register)); -- check the relevant bits if (Register and 16#103F#) /= 16#003F# then return False; -- no control word end if; -- check control word value -- FPU found return True; end Has_FPU; -------------------------------- -- Detect CPUID instruction -- -------------------------------- -- The processor supports the CPUID instruction if it is possible -- to change the value of ID flag bit in the EFLAGS register. function Has_CPUID return Boolean is Original_Flags, Modified_Flags : Processor_Register; -- EFLAG contents before and after changing the ID flag begin -- try flipping the ID flag in the EFLAGS register Asm ( -- the assembler code "pushfl" & LF & HT & -- push EFLAGS on stack "pop %%eax" & LF & HT & -- pop EFLAGS into eax "movl %%eax, %0" & LF & HT & -- save EFLAGS content "xor $0x200000, %%eax" & LF & HT & -- flip ID flag "push %%eax" & LF & HT & -- push EFLAGS on stack "popfl" & LF & HT & -- load EFLAGS register "pushfl" & LF & HT & -- push EFLAGS on stack "pop %1", -- save EFLAGS content -- output values, may be anything -- Original_Flags is %0 -- Modified_Flags is %1 Outputs => (Processor_Register'Asm_output ("=g", Original_Flags), Processor_Register'Asm_output ("=g", Modified_Flags)), -- tell compiler eax is destroyed Clobber => "eax"); -- check if CPUID is supported if Original_Flags(ID_Flag) /= Modified_Flags(ID_Flag) then return True; -- ID flag was modified else return False; -- ID flag unchanged end if; -- check for CPUID end Has_CPUID; ------------------------------- -- Get CPUID support level -- ------------------------------- function CPUID_Level return Natural is Level : Unsigned_32; -- returned support level begin -- execute CPUID, storing the results in the Level register Asm ( -- the assembler code "cpuid", -- execute CPUID -- zero is stored in eax -- returning the support level in eax Inputs => Unsigned_32'Asm_input ("a", 0), -- eax is stored in Level Outputs => Unsigned_32'Asm_output ("=a", Level), -- tell compiler ebx, ecx and edx registers are destroyed Clobber => "ebx, ecx, edx"); -- return the support level return Natural (Level); end CPUID_Level; -------------------------------- -- Get CPU Vendor ID String -- -------------------------------- -- The vendor ID string is returned in the ebx, ecx and edx register -- after executing the CPUID instruction with eax set to zero. -- In case of a true Intel processor the string returned is -- "GenuineIntel" function Vendor_ID return String is Ebx, Ecx, Edx : Unsigned_Register; -- registers containing the vendor ID string Vendor_ID : String (1 .. 12); -- the vendor ID string begin -- execute CPUID, storing the results in the processor registers Asm ( -- the assembler code "cpuid", -- execute CPUID -- zero stored in eax -- vendor ID string returned in ebx, ecx and edx Inputs => Unsigned_32'Asm_input ("a", 0), -- ebx is stored in Ebx -- ecx is stored in Ecx -- edx is stored in Edx Outputs => (Unsigned_Register'Asm_output ("=b", Ebx), Unsigned_Register'Asm_output ("=c", Ecx), Unsigned_Register'Asm_output ("=d", Edx))); -- now build the vendor ID string Vendor_ID( 1) := Character'Val (Ebx.L1); Vendor_ID( 2) := Character'Val (Ebx.H1); Vendor_ID( 3) := Character'Val (Ebx.L2); Vendor_ID( 4) := Character'Val (Ebx.H2); Vendor_ID( 5) := Character'Val (Edx.L1); Vendor_ID( 6) := Character'Val (Edx.H1); Vendor_ID( 7) := Character'Val (Edx.L2); Vendor_ID( 8) := Character'Val (Edx.H2); Vendor_ID( 9) := Character'Val (Ecx.L1); Vendor_ID(10) := Character'Val (Ecx.H1); Vendor_ID(11) := Character'Val (Ecx.L2); Vendor_ID(12) := Character'Val (Ecx.H2); -- return string return Vendor_ID; end Vendor_ID; ------------------------------- -- Get processor signature -- ------------------------------- function Signature return Processor_Signature is Result : Processor_Signature; -- processor signature returned begin -- execute CPUID, storing the results in the Result variable Asm ( -- the assembler code "cpuid", -- execute CPUID -- one is stored in eax -- processor signature returned in eax Inputs => Unsigned_32'Asm_input ("a", 1), -- eax is stored in Result Outputs => Processor_Signature'Asm_output ("=a", Result), -- tell compiler that ebx, ecx and edx are also destroyed Clobber => "ebx, ecx, edx"); -- return processor signature return Result; end Signature; ------------------------------ -- Get processor features -- ------------------------------ function Features return Processor_Features is Result : Processor_Features; -- processor features returned begin -- execute CPUID, storing the results in the Result variable Asm ( -- the assembler code "cpuid", -- execute CPUID -- one stored in eax -- processor features returned in edx Inputs => Unsigned_32'Asm_input ("a", 1), -- edx is stored in Result Outputs => Processor_Features'Asm_output ("=d", Result), -- tell compiler that ebx and ecx are also destroyed Clobber => "ebx, ecx"); -- return processor signature return Result; end Features; end Intel_CPU; Performance Considerations ************************** The GNAT system provides a number of options that allow a trade-off between * performance of the generated code * speed of compilation * minimization of dependences and recompilation * the degree of run-time checking. The defaults (if no options are selected) aim at improving the speed of compilation and minimizing dependences, at the expense of performance of the generated code: * no optimization * no inlining of subprogram calls * all run-time checks enabled except overflow and elaboration checks These options are suitable for most program development purposes. This chapter describes how you can modify these choices, and also provides some guidelines on debugging optimized code. Controlling Run-Time Checks =========================== By default, GNAT generates all run-time checks, except arithmetic overflow checking for integer operations and checks for access before elaboration on subprogram calls. The latter are not required in default mode, because all necessary checking is done at compile time. Two gnat switches, `-gnatp' and `-gnato' allow this default to be modified. *Note Run-Time Checks::. Our experience is that the default is suitable for most development purposes. We treat integer overflow specially because these are quite expensive and in our experience are not as important as other run-time checks in the development process. Note that division by zero is not considered an overflow check, and divide by zero checks are generated where required by default. Elaboration checks are off by default, and also not needed by default, since GNAT uses a static elaboration analysis approach that avoids the need for run-time checking. This manual contains a full chapter discussing the issue of elaboration checks, and if the default is not satisfactory for your use, you should read this chapter. Note that the setting of the switches controls the default setting of the checks. They may be modified using either `pragma Suppress' (to remove checks) or `pragma Unsuppress' (to add back suppressed checks) in the program source. Optimization Levels =================== The default is optimization off. This results in the fastest compile times, but GNAT makes absolutely no attempt to optimize, and the generated programs are considerably larger and slower than when optimization is enabled. You can use the `-ON' switch, where N is an integer from 0 to 3, on the `gcc' command line to control the optimization level: `-O0' no optimization (the default) `-O1' medium level optimization `-O2' full optimization `-O3' full optimization, and also attempt automatic inlining of small subprograms within a unit (*note Inlining of Subprograms::). Higher optimization levels perform more global transformations on the program and apply more expensive analysis algorithms in order to generate faster and more compact code. The price in compilation time, and the resulting improvement in execution time, both depend on the particular application and the hardware environment. You should experiment to find the best level for your application. Note: Unlike some other compilation systems, `gcc' has been tested extensively at all optimization levels. There are some bugs which appear only with optimization turned on, but there have also been bugs which show up only in _unoptimized_ code. Selecting a lower level of optimization does not improve the reliability of the code generator, which in practice is highly reliable at all optimization levels. Debugging Optimized Code ======================== Since the compiler generates debugging tables for a compilation unit before it performs optimizations, the optimizing transformations may invalidate some of the debugging data. You therefore need to anticipate certain anomalous situations that may arise while debugging optimized code. This section describes the most common cases. 1. The "hopping Program Counter": Repeated 'step' or 'next' commands show the PC bouncing back and forth in the code. This may result from any of the following optimizations: * Common subexpression elimination: using a single instance of code for a quantity that the source computes several times. As a result you may not be able to stop on what looks like a statement. * Invariant code motion: moving an expression that does not change within a loop, to the beginning of the loop. * Instruction scheduling: moving instructions so as to overlap loads and stores (typically) with other code, or in general to move computations of values closer to their uses. Often this causes you to pass an assignment statement without the assignment happening and then later bounce back to the statement when the value is actually needed. Placing a breakpoint on a line of code and then stepping over it may, therefore, not always cause all the expected side-effects. 2. The "big leap": More commonly known as cross-jumping, in which two identical pieces of code are merged and the program counter suddenly jumps to a statement that is not supposed to be executed, simply because it (and the code following) translates to the same thing as the code that _was_ supposed to be executed. This effect is typically seen in sequences that end in a jump, such as a `goto', a `return', or a `break' in a C `switch' statement. 3. The "roving variable": The symptom is an unexpected value in a variable. There are various reasons for this effect: * In a subprogram prologue, a parameter may not yet have been moved to its "home". * A variable may be dead, and its register re-used. This is probably the most common cause. * As mentioned above, the assignment of a value to a variable may have been moved. * A variable may be eliminated entirely by value propagation or other means. In this case, GCC may incorrectly generate debugging information for the variable In general, when an unexpected value appears for a local variable or parameter you should first ascertain if that value was actually computed by your program, as opposed to being incorrectly reported by the debugger. Record fields or array elements in an object designated by an access value are generally less of a problem, once you have ascertained that the access value is sensible. Typically, this means checking variables in the preceding code and in the calling subprogram to verify that the value observed is explainable from other values (one must apply the procedure recursively to those other values); or re-running the code and stopping a little earlier (perhaps before the call) and stepping to better see how the variable obtained the value in question; or continuing to step _from_ the point of the strange value to see if code motion had simply moved the variable's assignments later. Inlining of Subprograms ======================= A call to a subprogram in the current unit is inlined if all the following conditions are met: * The optimization level is at least `-O1'. * The called subprogram is suitable for inlining: It must be small enough and not contain nested subprograms or anything else that `gcc' cannot support in inlined subprograms. * The call occurs after the definition of the body of the subprogram. * Either `pragma Inline' applies to the subprogram or it is small and automatic inlining (optimization level `-O3') is specified. Calls to subprograms in `with''ed units are normally not inlined. To achieve this level of inlining, the following conditions must all be true: * The optimization level is at least `-O1'. * The called subprogram is suitable for inlining: It must be small enough and not contain nested subprograms or anything else `gcc' cannot support in inlined subprograms. * The call appears in a body (not in a package spec). * There is a `pragma Inline' for the subprogram. * The `-gnatn' switch is used in the `gcc' command line Note that specifying the `-gnatn' switch causes additional compilation dependencies. Consider the following: package R is procedure Q; pragma Inline (Q); end R; package body R is ... end R; with R; procedure Main is begin ... R.Q; end Main; With the default behavior (no `-gnatn' switch specified), the compilation of the `Main' procedure depends only on its own source, `main.adb', and the spec of the package in file `r.ads'. This means that editing the body of `R' does not require recompiling `Main'. On the other hand, the call `R.Q' is not inlined under these circumstances. If the `-gnatn' switch is present when `Main' is compiled, the call will be inlined if the body of `Q' is small enough, but now `Main' depends on the body of `R' in `r.adb' as well as on the spec. This means that if this body is edited, the main program must be recompiled. Note that this extra dependency occurs whether or not the call is in fact inlined by `gcc'. The use of front end inlining with `-gnatN' generates similar additional dependencies. Note: The `-fno-inline' switch can be used to prevent all inlining. This switch overrides all other conditions and ensures that no inlining occurs. The extra dependences resulting from `-gnatn' will still be active, even if this switch is used to suppress the resulting inlining actions. GNU Free Documentation License ****************************** Version 1.1, March 2000 Copyright (C) 2000 Free Software Foundation, Inc. 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA Everyone is permitted to copy and distribute verbatim copies of this license document, but changing it is not allowed. 0. PREAMBLE =========== The purpose of this License is to make a manual, textbook, or other written document "free" in the sense of freedom: to assure everyone the effective freedom to copy and redistribute it, with or without modifying it, either commercially or noncommercially. Secondarily, this License preserves for the author and publisher a way to get credit for their work, while not being considered responsible for modifications made by others. This License is a kind of "copyleft", which means that derivative works of the document must themselves be free in the same sense. It complements the GNU General Public License, which is a copyleft license designed for free software. 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Index ***** --GCC= (gnatchop): See ``Switches for `gnatchop'''. --GCC=compiler_name (gnatlink): See ``Switches for `gnatlink'''. --GCC=compiler_name (gnatmake): See ``Switches for `gnatmake'''. --GNATBIND=binder_name (gnatmake): See ``Switches for `gnatmake'''. --GNATLINK=linker_name (gnatmake): See ``Switches for `gnatmake'''. --LINK= (gnatlink): See ``Switches for `gnatlink'''. --RTS (gcc): See ``Switches for `gcc'''. --RTS (gnatbind): See ``Summary of Binder Switches''. --RTS (gnatfind): See ```gnatfind' Switches''. --RTS (gnatls): See ``Switches for `gnatls'''. --RTS (gnatmake): See ``Switches for `gnatmake'''. --RTS (gnatxref): See ```gnatxref' Switches''. -83 (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -A (gnatbind): See ``Output Control''. -A (gnatlink): See ``Switches for `gnatlink'''. -a (gnatls): See ``Switches for `gnatls'''. -a (gnatmake): See ``Switches for `gnatmake'''. -A (gnatmake): See ``Switches for `gnatmake'''. -aI (gnatmake): See ``Switches for `gnatmake'''. -aL (gnatmake): See ``Switches for `gnatmake'''. -aO (gnatmake): See ``Switches for `gnatmake'''. -B (gcc): See ``Switches for `gcc'''. -b (gcc): See ``Switches for `gcc'''. -b (gnatbind): See ``Binder Error Message Control''. -B (gnatlink): See ``Switches for `gnatlink'''. -b (gnatlink): See ``Switches for `gnatlink'''. -b (gnatmake): See ``Switches for `gnatmake'''. -bargs (gnatmake): See ``Mode Switches for `gnatmake'''. -c (gcc): See ``Switches for `gcc'''. -c (gnatbind): See ``Output Control''. -C (gnatbind): See ``Output Control''. -c (gnatchop): See ``Switches for `gnatchop'''. -C (gnatlink): See ``Switches for `gnatlink'''. -C (gnatmake): See ``Switches for `gnatmake'''. -c (gnatmake): See ``Switches for `gnatmake'''. -c (gnatname): See ``Switches for `gnatname'''. -cargs (gnatmake): See ``Mode Switches for `gnatmake'''. -d (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -d (gnatls): See ``Switches for `gnatls'''. -d (gnatname): See ``Switches for `gnatname'''. -D (gnatname): See ``Switches for `gnatname'''. -e (gnatbind): See ``Output Control''. -f (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -f (gnatlink): See ``Switches for `gnatlink'''. -f (gnatmake): See ``Switches for `gnatmake'''. -fno-inline (gcc): See ``Inlining of Subprograms''. -fstack-check: See ``Stack Overflow Checking''. -g (gcc): See ``Switches for `gcc'''. -g (gnatlink): See ``Switches for `gnatlink'''. -gnat83 (gcc): See ``Compiling Ada 83 Programs''. -gnata (gcc): See ``Debugging and Assertion Control''. -gnatb (gcc): See ``Output and Error Message Control''. -gnatc (gcc): See ``Using `gcc' for Semantic Checking''. -gnatD (gcc): See ``Debugging Control''. -gnatdc switch: See ``GNAT Abnormal Termination or Failure to Terminate''. -gnatE (gcc) <1>: See ``Run-Time Checks''. -gnatE (gcc): See ``Debugging Control''. -gnatem (gcc): See ``Units to Sources Mapping Files''. -gnatf (gcc): See ``Output and Error Message Control''. -gnatG (gcc): See ``Debugging Control''. -gnati (gcc): See ``Character Set Control''. -gnatk (gcc): See ``File Naming Control''. -gnatl (gcc): See ``Output and Error Message Control''. -gnatm (gcc): See ``Output and Error Message Control''. -gnatn (gcc): See ``Inlining of Subprograms''. -gnatN (gcc): See ``Subprogram Inlining Control''. -gnatn (gcc): See ``Subprogram Inlining Control''. -gnatN switch: See ``Source Dependencies''. -gnatn switch: See ``Source Dependencies''. -gnato (gcc) <1>: See ``Run-Time Checks''. -gnato (gcc): See ``Controlling Run-Time Checks''. -gnatp (gcc) <1>: See ``Run-Time Checks''. -gnatp (gcc): See ``Controlling Run-Time Checks''. -gnatq (gcc): See ``Output and Error Message Control''. -gnatR (gcc): See ``Debugging Control''. -gnats (gcc): See ``Using `gcc' for Syntax Checking''. -gnatt (gcc): See ``Auxiliary Output Control''. -gnatT (gcc): See ``Run-Time Control''. -gnatu (gcc): See ``Auxiliary Output Control''. -gnatU (gcc): See ``Output and Error Message Control''. -gnatv (gcc): See ``Output and Error Message Control''. -gnatW (gcc): See ``Character Set Control''. -gnatwa (gcc): See ``Output and Error Message Control''. -gnatwA (gcc): See ``Output and Error Message Control''. -gnatwC (gcc): See ``Output and Error Message Control''. -gnatwc (gcc): See ``Output and Error Message Control''. -gnatwe (gcc): See ``Output and Error Message Control''. -gnatwf (gcc): See ``Output and Error Message Control''. -gnatwF (gcc): See ``Output and Error Message Control''. -gnatwh (gcc): See ``Output and Error Message Control''. -gnatwH (gcc): See ``Output and Error Message Control''. -gnatwi (gcc): See ``Output and Error Message Control''. -gnatwI (gcc): See ``Output and Error Message Control''. -gnatwl (gcc): See ``Output and Error Message Control''. -gnatwL (gcc): See ``Output and Error Message Control''. -gnatwo (gcc): See ``Output and Error Message Control''. -gnatwO (gcc): See ``Output and Error Message Control''. -gnatwp (gcc): See ``Output and Error Message Control''. -gnatwP (gcc): See ``Output and Error Message Control''. -gnatwR (gcc): See ``Output and Error Message Control''. -gnatwr (gcc): See ``Output and Error Message Control''. -gnatws (gcc): See ``Output and Error Message Control''. -gnatwu (gcc): See ``Output and Error Message Control''. -gnatwU (gcc): See ``Output and Error Message Control''. -gnatx (gcc): See ``Debugging Control''. -h (gnatbind) <1>: See ``Output Control''. -h (gnatbind): See ``Elaboration Control''. -h (gnatls): See ``Switches for `gnatls'''. -h (gnatname): See ``Switches for `gnatname'''. -I (gcc): See ``Switches for `gcc'''. -I (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -I (gnatmake): See ``Switches for `gnatmake'''. -i (gnatmake): See ``Switches for `gnatmake'''. -i (gnatmem): See ``Switches for `gnatmem'''. -I- (gcc): See ``Switches for `gcc'''. -I- (gnatmake): See ``Switches for `gnatmake'''. -j (gnatmake): See ``Switches for `gnatmake'''. -K (gnatbind): See ``Output Control''. -k (gnatchop): See ``Switches for `gnatchop'''. -k (gnatmake): See ``Switches for `gnatmake'''. -l (gnatbind): See ``Output Control''. -l (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -L (gnatmake): See ``Switches for `gnatmake'''. -l (gnatmake): See ``Switches for `gnatmake'''. -largs (gnatmake): See ``Mode Switches for `gnatmake'''. -M (gnatbind): See ``Binder Error Message Control''. -m (gnatbind): See ``Binder Error Message Control''. -m (gnatmake): See ``Switches for `gnatmake'''. -M (gnatmake): See ``Switches for `gnatmake'''. -n (gnatbind): See ``Binding with Non-Ada Main Programs''. -n (gnatlink): See ``Switches for `gnatlink'''. -n (gnatmake): See ``Switches for `gnatmake'''. -nostdinc (gnatmake): See ``Switches for `gnatmake'''. -nostdlib (gnatmake): See ``Switches for `gnatmake'''. -O (gcc) <1>: See ``Switches for `gcc'''. -O (gcc): See ``Optimization Levels''. -o (gcc): See ``Switches for `gcc'''. -o (gnatbind): See ``Output Control''. -O (gnatbind): See ``Output Control''. -o (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -o (gnatlink): See ``Switches for `gnatlink'''. -o (gnatls): See ``Switches for `gnatls'''. -o (gnatmake): See ``Switches for `gnatmake'''. -o (gnatmem): See ``Switches for `gnatmem'''. -p (gnatchop): See ``Switches for `gnatchop'''. -p (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -P (gnatname): See ``Switches for `gnatname'''. -pass-exit-codes (gcc): See ``Auxiliary Output Control''. -q (gnatchop): See ``Switches for `gnatchop'''. -q (gnatmake): See ``Switches for `gnatmake'''. -q (gnatmem): See ``Switches for `gnatmem'''. -r (gnatbind): See ``Output Control''. -r (gnatchop): See ``Switches for `gnatchop'''. -S (gcc): See ``Switches for `gcc'''. -s (gnatbind): See ``Consistency-Checking Modes''. -s (gnatls): See ``Switches for `gnatls'''. -sc (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -t (gnatbind): See ``Binder Error Message Control''. -t (gnathtml): See ``Converting Ada Files to html with `gnathtml'''. -u (gnatls): See ``Switches for `gnatls'''. -u (gnatmake): See ``Switches for `gnatmake'''. -v (gcc): See ``Switches for `gcc'''. -V (gcc): See ``Switches for `gcc'''. -v (gnatbind): See ``Binder Error Message Control''. -v (gnatchop): See ``Switches for `gnatchop'''. -v (gnatlink): See ``Switches for `gnatlink'''. -v (gnatmake): See ``Switches for `gnatmake'''. -v (gnatname): See ``Switches for `gnatname'''. -v -v (gnatlink): See ``Switches for `gnatlink'''. -w: See ``Output and Error Message Control''. -w (gnatchop): See ``Switches for `gnatchop'''. -we (gnatbind): See ``Binder Error Message Control''. -ws (gnatbind): See ``Binder Error Message Control''. -x (gnatbind): See ``Consistency-Checking Modes''. -z (gnatbind): See ``Binding Programs with No Main Subprogram''. -z (gnatmake): See ``Switches for `gnatmake'''. \-s\/SWITCH_CHECK/ (gnatmake): See ``Switches for `gnatmake'''. __gnat_finalize: See ``Running `gnatbind'''. __gnat_initialize: See ``Running `gnatbind'''. __gnat_set_globals: See ``Running `gnatbind'''. _main: See ``The External Symbol Naming Scheme of GNAT''. Access before elaboration: See ``Run-Time Checks''. Access-to-subprogram: See ``Elaboration for Access-to-Subprogram Values''. ACVC, Ada 83 tests: See ``Compiling Ada 83 Programs''. Ada <1>: See ``Naming Conventions for GNAT Source Files''. Ada: See ``Search Paths for `gnatbind'''. Ada 83 compatibility: See ``Compiling Ada 83 Programs''. Ada 95 Language Reference Manual: See ``What You Should Know before Reading This Guide''. Ada expressions: See ``Using Ada Expressions''. Ada Library Information files: See ``The Ada Library Information Files''. Ada.Characters.Latin_1: See ``Latin-1''. ADA_INCLUDE_PATH: See ``Search Paths and the Run-Time Library (RTL)''. ADA_OBJECTS_PATH: See ``Search Paths for `gnatbind'''. adafinal <1>: See ``Binding with Non-Ada Main Programs''. adafinal: See ``Running `gnatbind'''. adainit <1>: See ``Binding with Non-Ada Main Programs''. adainit: See ``Running `gnatbind'''. ali files: See ``The Ada Library Information Files''. Annex A: See ``Naming Conventions for GNAT Source Files''. Annex B: See ``Naming Conventions for GNAT Source Files''. Arbitrary File Naming Conventions: See ``Handling Arbitrary File Naming Conventions Using `gnatname'''. Asm: See ``Calling Conventions''. Assert: See ``Debugging and Assertion Control''. Assertions: See ``Debugging and Assertion Control''. Binder consistency checks: See ``Binder Error Message Control''. Binder output file: See ``Interfacing to C''. Binder, multiple input files: See ``Binding with Non-Ada Main Programs''. Breakpoints and tasks: See ``Ada Tasks''. C: See ``Calling Conventions''. C++: See ``Calling Conventions''. Calling Conventions: See ``Calling Conventions''. Check, elaboration: See ``Run-Time Checks''. Check, overflow: See ``Run-Time Checks''. Check_CPU procedure: See ```Check_CPU' Procedure''. Checks, access before elaboration: See ``Run-Time Checks''. Checks, division by zero: See ``Run-Time Checks''. Checks, elaboration: See ``Checking the Elaboration Order in Ada 95''. Checks, overflow: See ``Controlling Run-Time Checks''. Checks, suppressing: See ``Run-Time Checks''. COBOL: See ``Calling Conventions''. code page 437: See ``Other 8-Bit Codes''. code page 850: See ``Other 8-Bit Codes''. Combining GNAT switches: See ``Switches for `gcc'''. Command line length: See ``Switches for `gnatlink'''. Compilation model: See ``The GNAT Compilation Model''. Configuration pragmas: See ``Configuration Pragmas''. Consistency checks, in binder: See ``Binder Error Message Control''. Convention Ada: See ``Calling Conventions''. Convention Asm: See ``Calling Conventions''. Convention Assembler: See ``Calling Conventions''. Convention C: See ``Calling Conventions''. Convention C++: See ``Calling Conventions''. Convention COBOL: See ``Calling Conventions''. Convention Fortran: See ``Calling Conventions''. Convention Stdcall: See ``Calling Conventions''. Convention Stubbed: See ``Calling Conventions''. Conventions: See ``Conventions''. CR: See ``Source Representation''. Cyrillic: See ``Other 8-Bit Codes''. Debug: See ``Debugging and Assertion Control''. Debug Pool: See ``Finding Memory Problems with GNAT Debug Pool''. Debugger: See ``Running and Debugging Ada Programs''. Debugging: See ``Running and Debugging Ada Programs''. Debugging Generic Units: See ``Debugging Generic Units''. Debugging information, including: See ``Switches for `gnatlink'''. Debugging options: See ``Debugging Control''. Dependencies, producing list: See ``Switches for `gnatmake'''. Dependency rules: See ``The GNAT Make Program `gnatmake'''. Division by zero: See ``Run-Time Checks''. Elaborate: See ``Controlling the Elaboration Order in Ada 95''. Elaborate_All: See ``Controlling the Elaboration Order in Ada 95''. Elaborate_Body: See ``Controlling the Elaboration Order in Ada 95''. Elaboration checks <1>: See ``Run-Time Checks''. Elaboration checks: See ``Checking the Elaboration Order in Ada 95''. Elaboration control <1>: See ``Summary of Procedures for Elaboration Control''. Elaboration control: See ``Elaboration Order Handling in GNAT''. Elaboration of library tasks: See ``Elaboration Issues for Library Tasks''. Elaboration order control: See ``Comparison between GNAT and C/C++ Compilation Models''. Eliminate: See ```Eliminate' Pragma''. End of source file: See ``Source Representation''. Error messages, suppressing: See ``Output and Error Message Control''. EUC Coding: See ``Wide Character Encodings''. Exceptions: See ``Breaking on Ada Exceptions''. Export: See ``The External Symbol Naming Scheme of GNAT''. FF: See ``Source Representation''. File names <1>: See ``Alternative File Naming Schemes''. File names: See ``Using Other File Names''. File naming schemes, alternative: See ``Alternative File Naming Schemes''. Foreign Languages: See ``Calling Conventions''. Fortran: See ``Calling Conventions''. Free Documentation License, GNU: See ``GNU Free Documentation License''. gdb: See ``Running and Debugging Ada Programs''. Generic formal parameters: See ``Compiling Ada 83 Programs''. Generics <1>: See ``Generating Object Files''. Generics: See ``Debugging Generic Units''. Glide: See ``Introduction to Glide and GVD''. GMEM (gnatmem): See ``Running `gnatmem' (GMEM Mode)''. GNAT <1>: See ``Naming Conventions for GNAT Source Files''. GNAT: See ``Search Paths for `gnatbind'''. GNAT Abnormal Termination or Failure to Terminate: See ``GNAT Abnormal Termination or Failure to Terminate''. GNAT compilation model: See ``The GNAT Compilation Model''. GNAT library: See ``Comparison between GNAT and Conventional Ada Library Models''. gnat.adc <1>: See ``The Configuration Pragmas Files''. gnat.adc: See ``Using Other File Names''. gnat1: See ``Compiling Programs''. gnat_argc: See ``Command-Line Access''. gnat_argv: See ``Command-Line Access''. GNAT_STACK_LIMIT: See ``Stack Overflow Checking''. gnatbind: See ``Binding Using `gnatbind'''. gnatchop: See ``Renaming Files Using `gnatchop'''. gnatelim: See ``Reducing the Size of Ada Executables with `gnatelim'''. gnatfind: See ``The Cross-Referencing Tools `gnatxref' and `gnatfind'''. gnatkr: See ``File Name Krunching Using `gnatkr'''. gnatlink: See ``Linking Using `gnatlink'''. gnatls: See ``The GNAT Library Browser `gnatls'''. gnatmake: See ``The GNAT Make Program `gnatmake'''. gnatmem: See ``Finding Memory Problems with `gnatmem'''. gnatprep: See ``Preprocessing Using `gnatprep'''. gnatstub: See ``Creating Sample Bodies Using `gnatstub'''. gnatxref: See ``The Cross-Referencing Tools `gnatxref' and `gnatfind'''. GNU Free Documentation License::: See ``GNU Free Documentation License''. GNU make: See ``Using gnatmake in a Makefile''. GVD: See ``Introduction to Glide and GVD''. HT: See ``Source Representation''. Inline <1>: See ``Inlining of Subprograms''. Inline: See ``Source Dependencies''. Inlining: See ``Comparison between GNAT and Conventional Ada Library Models''. Intel_CPU package body: See ```Intel_CPU' Package Body''. Intel_CPU package specification: See ```Intel_CPU' Package Specification''. Interfaces <1>: See ``Naming Conventions for GNAT Source Files''. Interfaces: See ``Search Paths for `gnatbind'''. Interfacing to Ada: See ``Calling Conventions''. Interfacing to Assembler: See ``Calling Conventions''. Interfacing to C: See ``Calling Conventions''. Interfacing to C++: See ``Calling Conventions''. Interfacing to COBOL: See ``Calling Conventions''. Interfacing to Fortran: See ``Calling Conventions''. Internal trees, writing to file: See ``Auxiliary Output Control''. Latin-1 <1>: See ``Source Representation''. Latin-1: See ``Latin-1''. Latin-2: See ``Other 8-Bit Codes''. Latin-3: See ``Other 8-Bit Codes''. Latin-4: See ``Other 8-Bit Codes''. Latin-5: See ``Other 8-Bit Codes''. LF: See ``Source Representation''. Library browser: See ``The GNAT Library Browser `gnatls'''. Library tasks, elaboration issues: See ``Elaboration Issues for Library Tasks''. Library, building, installing: See ``GNAT and Libraries''. License, GNU Free Documentation: See ``GNU Free Documentation License''. Linker libraries: See ``Switches for `gnatmake'''. Machine_Overflows: See ``Run-Time Checks''. Main Program: See ``Running `gnatbind'''. make: See ``Using the GNU `make' Utility''. makefile: See ``Using gnatmake in a Makefile''. Mixed Language Programming: See ``Mixed Language Programming''. Multiple units, syntax checking: See ``Using `gcc' for Syntax Checking''. n (gnatmem): See ``Switches for `gnatmem'''. No code generated: See ``Compiling Programs''. No_Entry_Calls_In_Elaboration_Code: See ``Elaboration Issues for Library Tasks''. Object file list: See ``Running `gnatbind'''. Order of elaboration: See ``Elaboration Order Handling in GNAT''. Other Ada compilers: See ``Calling Conventions''. Overflow checks <1>: See ``Controlling Run-Time Checks''. Overflow checks: See ``Run-Time Checks''. Parallel make: See ``Switches for `gnatmake'''. Performance: See ``Performance Considerations''. pragma Elaborate: See ``Controlling the Elaboration Order in Ada 95''. pragma Elaborate_All: See ``Controlling the Elaboration Order in Ada 95''. pragma Elaborate_Body: See ``Controlling the Elaboration Order in Ada 95''. pragma Inline: See ``Inlining of Subprograms''. pragma Preelaborate: See ``Controlling the Elaboration Order in Ada 95''. pragma Pure: See ``Controlling the Elaboration Order in Ada 95''. pragma Suppress: See ``Controlling Run-Time Checks''. pragma Unsuppress: See ``Controlling Run-Time Checks''. Pragmas, configuration: See ``Configuration Pragmas''. Preelaborate: See ``Controlling the Elaboration Order in Ada 95''. Pure: See ``Controlling the Elaboration Order in Ada 95''. Recompilation, by gnatmake: See ``Notes on the Command Line''. RTL: See ``Switches for `gcc'''. SDP_Table_Build: See ``Running `gnatbind'''. Search paths, for gnatmake: See ``Switches for `gnatmake'''. Shift JIS Coding: See ``Wide Character Encodings''. Source file, end: See ``Source Representation''. Source files, suppressing search: See ``Switches for `gnatmake'''. Source files, use by binder: See ``Running `gnatbind'''. Source_File_Name pragma <1>: See ``Using Other File Names''. Source_File_Name pragma: See ``Alternative File Naming Schemes''. Source_Reference: See ``Switches for `gnatchop'''. Stack Overflow Checking: See ``Stack Overflow Checking''. stack traceback: See ``Stack Traceback''. stack unwinding: See ``Stack Traceback''. Stdcall: See ``Calling Conventions''. stderr: See ``Output and Error Message Control''. stdout: See ``Output and Error Message Control''. storage, pool, memory corruption: See ``Finding Memory Problems with GNAT Debug Pool''. Stubbed: See ``Calling Conventions''. Style checking: See ``Style Checking''. SUB: See ``Source Representation''. Subunits: See ``Generating Object Files''. Suppress <1>: See ``Run-Time Checks''. Suppress: See ``Controlling Run-Time Checks''. Suppressing checks: See ``Run-Time Checks''. System <1>: See ``Search Paths for `gnatbind'''. System: See ``Naming Conventions for GNAT Source Files''. System.IO: See ``Search Paths and the Run-Time Library (RTL)''. Task switching: See ``Ada Tasks''. Tasks: See ``Ada Tasks''. Time Slicing: See ``Run-Time Control''. Time stamp checks, in binder: See ``Binder Error Message Control''. traceback: See ``Stack Traceback''. traceback, non-symbolic: See ``Non-Symbolic Traceback''. traceback, symbolic: See ``Symbolic Traceback''. Tree file: See ``Tree Files''. Typographical conventions: See ``Conventions''. Unsuppress <1>: See ``Controlling Run-Time Checks''. Unsuppress: See ``Run-Time Checks''. Upper-Half Coding: See ``Wide Character Encodings''. Validity Checking: See ``Validity Checking''. Version skew (avoided by gnatmake): See ``Running a Simple Ada Program''. Volatile parameter: See ``The `Volatile' Parameter''. VT: See ``Source Representation''. Warning messages: See ``Output and Error Message Control''. Warnings: See ``Binder Error Message Control''. Writing internal trees: See ``Auxiliary Output Control''. Zero Cost Exceptions: See ``Running `gnatbind'''. Table of Contents ***************** GNAT User's Guide About This Guide What This Guide Contains What You Should Know before Reading This Guide Related Information Conventions Getting Started with GNAT Running GNAT Running a Simple Ada Program Running a Program with Multiple Units Using the `gnatmake' Utility Introduction to Glide and GVD Building a New Program with Glide Simple Debugging with GVD Other Glide Features The GNAT Compilation Model Source Representation Foreign Language Representation Latin-1 Other 8-Bit Codes Wide Character Encodings File Naming Rules Using Other File Names Alternative File Naming Schemes Generating Object Files Source Dependencies The Ada Library Information Files Binding an Ada Program Mixed Language Programming Interfacing to C Calling Conventions Building Mixed Ada & C++ Programs Interfacing to C++ Linking a Mixed C++ & Ada Program A Simple Example Adapting the Run Time to a New C++ Compiler Comparison between GNAT and C/C++ Compilation Models Comparison between GNAT and Conventional Ada Library Models Compiling Using `gcc' Compiling Programs Switches for `gcc' Output and Error Message Control Debugging and Assertion Control Validity Checking Style Checking Run-Time Checks Stack Overflow Checking Run-Time Control Using `gcc' for Syntax Checking Using `gcc' for Semantic Checking Compiling Ada 83 Programs Character Set Control File Naming Control Subprogram Inlining Control Auxiliary Output Control Debugging Control Units to Sources Mapping Files Search Paths and the Run-Time Library (RTL) Order of Compilation Issues Examples Binding Using `gnatbind' Running `gnatbind' Generating the Binder Program in C Consistency-Checking Modes Binder Error Message Control Elaboration Control Output Control Binding with Non-Ada Main Programs Binding Programs with No Main Subprogram Summary of Binder Switches Command-Line Access Search Paths for `gnatbind' Examples of `gnatbind' Usage Linking Using `gnatlink' Running `gnatlink' Switches for `gnatlink' Setting Stack Size from `gnatlink' Setting Heap Size from `gnatlink' The GNAT Make Program `gnatmake' Running `gnatmake' Switches for `gnatmake' Mode Switches for `gnatmake' Notes on the Command Line How `gnatmake' Works Examples of `gnatmake' Usage Renaming Files Using `gnatchop' Handling Files with Multiple Units Operating gnatchop in Compilation Mode Command Line for `gnatchop' Switches for `gnatchop' Examples of `gnatchop' Usage Configuration Pragmas Handling of Configuration Pragmas The Configuration Pragmas Files Handling Arbitrary File Naming Conventions Using `gnatname' Arbitrary File Naming Conventions Running `gnatname' Switches for `gnatname' Examples of `gnatname' Usage GNAT Project Manager Introduction Project Files Examples of Project Files Common Sources with Different Switches and Different Output Directories Source Files Specifying the Object Directory Specifying the Exec Directory Project File Packages Specifying Switch Settings Main Subprograms Source File Naming Conventions Source Language(s) Using External Variables Importing Other Projects Extending a Project Project File Syntax Basic Syntax Packages Expressions String Types Variables Attributes Associative Array Attributes `case' Constructions Objects and Sources in Project Files Object Directory Exec Directory Source Directories Source File Names Importing Projects Project Extension External References in Project Files Packages in Project Files Variables from Imported Projects Naming Schemes Library Projects Switches Related to Project Files Tools Supporting Project Files gnatmake and Project Files Switches and Project Files Project Files and Main Subprograms The GNAT Driver and Project Files Glide and Project Files An Extended Example Project File Complete Syntax Elaboration Order Handling in GNAT Elaboration Code in Ada 95 Checking the Elaboration Order in Ada 95 Controlling the Elaboration Order in Ada 95 Controlling Elaboration in GNAT - Internal Calls Controlling Elaboration in GNAT - External Calls Default Behavior in GNAT - Ensuring Safety Elaboration Issues for Library Tasks Mixing Elaboration Models What to Do If the Default Elaboration Behavior Fails Elaboration for Access-to-Subprogram Values Summary of Procedures for Elaboration Control Other Elaboration Order Considerations The Cross-Referencing Tools `gnatxref' and `gnatfind' `gnatxref' Switches `gnatfind' Switches Project Files for `gnatxref' and `gnatfind' Regular Expressions in `gnatfind' and `gnatxref' Examples of `gnatxref' Usage General Usage Using gnatxref with vi Examples of `gnatfind' Usage File Name Krunching Using `gnatkr' About `gnatkr' Using `gnatkr' Krunching Method Examples of `gnatkr' Usage Preprocessing Using `gnatprep' Using `gnatprep' Switches for `gnatprep' Form of Definitions File Form of Input Text for `gnatprep' The GNAT Library Browser `gnatls' Running `gnatls' Switches for `gnatls' Example of `gnatls' Usage GNAT and Libraries Creating an Ada Library Installing an Ada Library Using an Ada Library Creating an Ada Library to be Used in a Non-Ada Context Creating the Library Using the Library The Finalization Phase Restrictions in Libraries Rebuilding the GNAT Run-Time Library Using the GNU `make' Utility Using gnatmake in a Makefile Automatically Creating a List of Directories Generating the Command Line Switches Overcoming Command Line Length Limits Finding Memory Problems with `gnatmem' Running `gnatmem' (GDB Mode) Running `gnatmem' (GMEM Mode) Switches for `gnatmem' Example of `gnatmem' Usage GDB and GMEM Modes Implementation Note `gnatmem' Using `GDB' Mode `gnatmem' Using `GMEM' Mode Finding Memory Problems with GNAT Debug Pool Creating Sample Bodies Using `gnatstub' Running `gnatstub' Switches for `gnatstub' Reducing the Size of Ada Executables with `gnatelim' About `gnatelim' `Eliminate' Pragma Tree Files Preparing Tree and Bind Files for `gnatelim' Running `gnatelim' Correcting the List of Eliminate Pragmas Making Your Executables Smaller Summary of the gnatelim Usage Cycle Other Utility Programs Using Other Utility Programs with GNAT The `gnatpsta' Utility Program The External Symbol Naming Scheme of GNAT Ada Mode for `Glide' General Features: Ada Mode Features That Help Understanding Code: Glide Support for Writing Ada Code: Converting Ada Files to html with `gnathtml' Installing `gnathtml' Running and Debugging Ada Programs The GNAT Debugger GDB Running GDB Introduction to GDB Commands Using Ada Expressions Calling User-Defined Subprograms Using the Next Command in a Function Breaking on Ada Exceptions Ada Tasks Debugging Generic Units GNAT Abnormal Termination or Failure to Terminate Naming Conventions for GNAT Source Files Getting Internal Debugging Information Stack Traceback Non-Symbolic Traceback Tracebacks From an Unhandled Exception Tracebacks From Exception Occurrences Tracebacks From Anywhere in a Program Symbolic Traceback Tracebacks From Exception Occurrences Tracebacks From Anywhere in a Program Inline Assembler Basic Assembler Syntax A Simple Example of Inline Assembler Output Variables in Inline Assembler Input Variables in Inline Assembler Inlining Inline Assembler Code Other `Asm' Functionality The `Clobber' Parameter The `Volatile' Parameter A Complete Example `Check_CPU' Procedure `Intel_CPU' Package Specification `Intel_CPU' Package Body Performance Considerations Controlling Run-Time Checks Optimization Levels Debugging Optimized Code Inlining of Subprograms GNU Free Documentation License Index