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@set gprconfig GPRconfig
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@c ------ projects.texi
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@c Copyright (C) 2002-2012, Free Software Foundation, Inc.
5
@c This file is shared between the GNAT user's guide and gprbuild. It is not
6
@c compilable on its own, you should instead compile the other two manuals.
7
@c For that reason, there is no toplevel @menu
8
 
9
@c ---------------------------------------------
10
@node GNAT Project Manager
11
@chapter GNAT Project Manager
12
@c ---------------------------------------------
13
 
14
@noindent
15
@menu
16
* Introduction::
17
* Building With Projects::
18
* Organizing Projects into Subsystems::
19
* Scenarios in Projects::
20
* Library Projects::
21
* Project Extension::
22
* Aggregate Projects::
23
* Aggregate Library Projects::
24
* Project File Reference::
25
@end menu
26
 
27
@c ---------------------------------------------
28
@node Introduction
29
@section Introduction
30
@c ---------------------------------------------
31
 
32
@noindent
33
This chapter describes GNAT's @emph{Project Manager}, a facility that allows
34
you to manage complex builds involving a number of source files, directories,
35
and options for different system configurations. In particular,
36
project files allow you to specify:
37
 
38
@itemize @bullet
39
@item The directory or set of directories containing the source files, and/or the
40
  names of the specific source files themselves
41
@item The directory in which the compiler's output
42
  (@file{ALI} files, object files, tree files, etc.) is to be placed
43
@item The directory in which the executable programs are to be placed
44
@item Switch settings for any of the project-enabled tools;
45
  you can apply these settings either globally or to individual compilation units.
46
@item The source files containing the main subprogram(s) to be built
47
@item The source programming language(s)
48
@item Source file naming conventions; you can specify these either globally or for
49
  individual compilation units (@pxref{Naming Schemes}).
50
@item Change any of the above settings depending on external values, thus enabling
51
  the reuse of the projects in various @b{scenarios} (@pxref{Scenarios
52
  in Projects}).
53
@item Automatically build libraries as part of the build process
54
  (@pxref{Library Projects}).
55
 
56
@end itemize
57
 
58
@noindent
59
Project files are written in a syntax close to that of Ada, using familiar
60
notions such as packages, context clauses, declarations, default values,
61
assignments, and inheritance (@pxref{Project File Reference}).
62
 
63
Project files can be built hierarchically from other project files, simplifying
64
complex system integration and project reuse (@pxref{Organizing Projects into
65
Subsystems}).
66
 
67
@itemize @bullet
68
@item One project can import other projects containing needed source files.
69
  More generally, the Project Manager lets you structure large development
70
  efforts into hierarchical subsystems, where build decisions are delegated
71
  to the subsystem level, and thus different compilation environments
72
  (switch settings) used for different subsystems.
73
@item You can organize GNAT projects in a hierarchy: a child project
74
  can extend a parent project, inheriting the parent's source files and
75
  optionally overriding any of them with alternative versions
76
  (@pxref{Project Extension}).
77
 
78
@end itemize
79
 
80
@noindent
81
Several tools support project files, generally in addition to specifying
82
the information on the command line itself). They share common switches
83
to control the loading of the project (in particular
84
@option{^-P^/PROJECT_FILE=^@emph{projectfile}} and
85
@option{^-X^/EXTERNAL_REFERENCE=^@emph{vbl}=@emph{value}}).
86
@xref{Switches Related to Project Files}.
87
 
88
The Project Manager supports a wide range of development strategies,
89
for systems of all sizes.  Here are some typical practices that are
90
easily handled:
91
 
92
@itemize @bullet
93
@item Using a common set of source files and generating object files in different
94
  directories via different switch settings. It can be used for instance, for
95
  generating separate sets of object files for debugging and for production.
96
@item Using a mostly-shared set of source files with different versions of
97
  some units or subunits. It can be used for instance, for grouping and hiding
98
@end itemize
99
 
100
@noindent
101
all OS dependencies in a small number of implementation units.
102
 
103
Project files can be used to achieve some of the effects of a source
104
versioning system (for example, defining separate projects for
105
the different sets of sources that comprise different releases) but the
106
Project Manager is independent of any source configuration management tool
107
that might be used by the developers.
108
 
109
The various sections below introduce the different concepts related to
110
projects. Each section starts with examples and use cases, and then goes into
111
the details of related project file capabilities.
112
 
113
@c ---------------------------------------------
114
@node Building With Projects
115
@section Building With Projects
116
@c ---------------------------------------------
117
 
118
@noindent
119
In its simplest form, a unique project is used to build a single executable.
120
This section concentrates on such a simple setup. Later sections will extend
121
this basic model to more complex setups.
122
 
123
The following concepts are the foundation of project files, and will be further
124
detailed later in this documentation. They are summarized here as a reference.
125
 
126
@table @asis
127
@item @b{Project file}:
128
  A text file using an Ada-like syntax, generally using the @file{.gpr}
129
  extension. It defines build-related characteristics of an application.
130
  The characteristics include the list of sources, the location of those
131
  sources, the location for the generated object files, the name of
132
  the main program, and the options for the various tools involved in the
133
  build process.
134
 
135
@item @b{Project attribute}:
136
  A specific project characteristic is defined by an attribute clause. Its
137
  value is a string or a sequence of strings. All settings in a project
138
  are defined through a list of predefined attributes with precise
139
  semantics. @xref{Attributes}.
140
 
141
@item @b{Package in a project}:
142
  Global attributes are defined at the top level of a project.
143
  Attributes affecting specific tools are grouped in a
144
  package whose name is related to tool's function. The most common
145
  packages are @code{Builder}, @code{Compiler}, @code{Binder},
146
  and @code{Linker}. @xref{Packages}.
147
 
148
@item @b{Project variables}:
149
  In addition to attributes, a project can use variables to store intermediate
150
  values and avoid duplication in complex expressions. It can be initialized
151
  with a value coming from the environment.
152
  A frequent use of variables is to define scenarios.
153
  @xref{External Values}, @xref{Scenarios in Projects}, and @xref{Variables}.
154
 
155
@item @b{Source files} and @b{source directories}:
156
  A source file is associated with a language through a naming convention. For
157
  instance, @code{foo.c} is typically the name of a C source file;
158
  @code{bar.ads} or @code{bar.1.ada} are two common naming conventions for a
159
  file containing an Ada spec. A compilation unit is often composed of a main
160
  source file and potentially several auxiliary ones, such as header files in C.
161
  The naming conventions can be user defined @xref{Naming Schemes}, and will
162
  drive the builder to call the appropriate compiler for the given source file.
163
  Source files are searched for in the source directories associated with the
164
  project through the @b{Source_Dirs} attribute. By default, all the files (in
165
  these source directories) following the naming conventions associated with the
166
  declared languages are considered to be part of the project. It is also
167
  possible to limit the list of source files using the @b{Source_Files} or
168
  @b{Source_List_File} attributes. Note that those last two attributes only
169
  accept basenames with no directory information.
170
 
171
@item @b{Object files} and @b{object directory}:
172
  An object file is an intermediate file produced by the compiler from a
173
  compilation unit. It is used by post-compilation tools to produce
174
  final executables or libraries. Object files produced in the context of
175
  a given project are stored in a single directory that can be specified by the
176
  @b{Object_Dir} attribute. In order to store objects in
177
  two or more object directories, the system must be split into
178
  distinct subsystems with their own project file.
179
 
180
@end table
181
 
182
The following subsections introduce gradually all the attributes of interest
183
for simple build needs. Here is the simple setup that will be used in the
184
following examples.
185
 
186
The Ada source files @file{pack.ads}, @file{pack.adb}, and @file{proc.adb} are in
187
the @file{common/} directory. The file @file{proc.adb} contains an Ada main
188
subprogram @code{Proc} that @code{with}s package @code{Pack}. We want to compile
189
these source files with the switch @option{-O2}, and put the resulting files in
190
the directory @file{obj/}.
191
 
192
@smallexample
193
@group
194
^common/^[COMMON]^
195
  pack.ads
196
  pack.adb
197
  proc.adb
198
@end group
199
@group
200
^common/release/^[COMMON.RELEASE]^
201
  proc.ali, proc.o pack.ali, pack.o
202
@end group
203
@end smallexample
204
 
205
@noindent
206
Our project is to be called @emph{Build}. The name of the
207
file is the name of the project (case-insensitive) with the
208
@file{.gpr} extension, therefore the project file name is @file{build.gpr}. This
209
is not mandatory, but a warning is issued when this convention is not followed.
210
 
211
This is a very simple example, and as stated above, a single project
212
file is enough for it. We will thus create a new file, that for now
213
should contain the following code:
214
 
215
@smallexample
216
@b{project} Build @b{is}
217
@b{end} Build;
218
@end smallexample
219
 
220
@menu
221
* Source Files and Directories::
222
* Object and Exec Directory::
223
* Main Subprograms::
224
* Tools Options in Project Files::
225
* Compiling with Project Files::
226
* Executable File Names::
227
* Avoid Duplication With Variables::
228
* Naming Schemes::
229
@end menu
230
 
231
@c ---------------------------------------------
232
@node Source Files and Directories
233
@subsection Source Files and Directories
234
@c ---------------------------------------------
235
 
236
@noindent
237
When you create a new project, the first thing to describe is how to find the
238
corresponding source files. This is the only settings that are needed by all
239
the tools that will use this project (builder, compiler, binder and linker for
240
the compilation, IDEs to edit the source files,@dots{}).
241
 
242
@cindex Source directories
243
First step is to declare the source directories, which are the directories
244
to be searched to find source files. In the case of the example,
245
the @file{common} directory is the only source directory.
246
 
247
@cindex @code{Source_Dirs}
248
There are several ways of defining source directories:
249
 
250
@itemize @bullet
251
@item When the attribute @b{Source_Dirs} is not used, a project contains a
252
  single source directory which is the one where the project file itself
253
  resides. In our example, if @file{build.gpr} is placed in the @file{common}
254
  directory, the project has the needed implicit source directory.
255
 
256
@item The attribute @b{Source_Dirs} can be set to a list of path names, one
257
  for each of the source directories. Such paths can either be absolute
258
  names (for instance @file{"/usr/local/common/"} on UNIX), or relative to the
259
  directory in which the project file resides (for instance "." if
260
  @file{build.gpr} is inside @file{common/}, or "common" if it is one level up).
261
  Each of the source directories must exist and be readable.
262
 
263
@cindex portability
264
  The syntax for directories is platform specific. For portability, however,
265
  the project manager will always properly translate UNIX-like path names to
266
  the native format of specific platform. For instance, when the same project
267
  file is to be used both on Unix and Windows, "/" should be used as the
268
  directory separator rather than "\".
269
 
270
@item The attribute @b{Source_Dirs} can automatically include subdirectories
271
  using a special syntax inspired by some UNIX shells. If any of the path in
272
  the list ends with @emph{"**"}, then that path and all its subdirectories
273
  (recursively) are included in the list of source directories. For instance,
274
  @file{**} and @file{./**} represent the complete directory tree rooted at ".".
275
@cindex Source directories, recursive
276
 
277
@cindex @code{Excluded_Source_Dirs}
278
  When using that construct, it can sometimes be convenient to also use the
279
  attribute @b{Excluded_Source_Dirs}, which is also a list of paths. Each entry
280
  specifies a directory whose immediate content, not including subdirs, is to
281
  be excluded. It is also possible to exclude a complete directory subtree
282
  using the "**" notation.
283
 
284
@cindex @code{Ignore_Source_Sub_Dirs}
285
  It is often desirable to remove, from the source directories, directory
286
  subtrees rooted at some subdirectories. An example is the subdirectories
287
  created by a Version Control System such as Subversion that creates directory
288
  subtrees .svn/**. To do that, attribute  @b{Ignore_Source_Sub_Dirs} can be
289
  used. It specifies the list of simple file names for the root of these
290
  undesirable directory subtrees.
291
 
292
@end itemize
293
 
294
@noindent
295
When applied to the simple example, and because we generally prefer to have
296
the project file at the toplevel directory rather than mixed with the sources,
297
we will create the following file
298
 
299
@smallexample
300
   build.gpr
301
   @b{project} Build @b{is}
302
      @b{for} Source_Dirs @b{use} ("common");  --  <<<<
303
   @b{end} Build;
304
@end smallexample
305
 
306
@noindent
307
Once source directories have been specified, one may need to indicate
308
source files of interest. By default, all source files present in the source
309
directories are considered by the project manager. When this is not desired,
310
it is possible to specify the list of sources to consider explicitly.
311
In such a case, only source file base names are indicated and not
312
their absolute or relative path names. The project manager is in charge of
313
locating the specified source files in the specified source directories.
314
 
315
@itemize @bullet
316
@item By default, the project manager  search for all source files of all
317
  specified languages in all the source directories.
318
 
319
  Since the project manager was initially developed for Ada environments, the
320
  default language is usually Ada and the above project file is complete: it
321
  defines without ambiguity the sources composing the project: that is to say,
322
  all the sources in subdirectory "common" for the default language (Ada) using
323
  the default naming convention.
324
 
325
@cindex @code{Languages}
326
  However, when compiling a multi-language application, or a pure C
327
  application, the project manager must be told which languages are of
328
  interest, which is done by setting the @b{Languages} attribute to a list of
329
  strings, each of which is the name of a language. Tools like
330
  @command{gnatmake} only know about Ada, while other tools like
331
  @command{gprbuild} know about many more languages such as C, C++, Fortran,
332
  assembly and others can be added dynamically.
333
 
334
@cindex Naming scheme
335
  Even when using only Ada, the default naming might not be suitable. Indeed,
336
  how does the project manager recognizes an "Ada file" from any other
337
  file? Project files can describe the naming scheme used for source files,
338
  and override the default (@pxref{Naming Schemes}). The default is the
339
  standard GNAT extension (@file{.adb} for bodies and @file{.ads} for
340
  specs), which is what is used in our example, explaining why no naming scheme
341
  is explicitly specified.
342
  @xref{Naming Schemes}.
343
 
344
@item @code{Source Files}
345
  @cindex @code{Source_Files}
346
  In some cases, source directories might contain files that should not be
347
  included in a project. One can specify the explicit list of file names to
348
  be considered through the @b{Source_Files} attribute.
349
  When this attribute is defined, instead of looking at every file in the
350
  source directories, the project manager takes only those names into
351
  consideration  reports  errors if they cannot be found in the source
352
  directories or does not correspond to the naming scheme.
353
 
354
@item For various reasons, it is sometimes useful to have a project with no
355
  sources (most of the time because the attributes defined in the project
356
  file will be reused in other projects, as explained in @pxref{Organizing
357
  Projects into Subsystems}. To do this, the attribute
358
  @emph{Source_Files} is set to the empty list, i.e. @code{()}. Alternatively,
359
  @emph{Source_Dirs} can be set to the empty list, with the same
360
  result.
361
 
362
@item @code{Source_List_File}
363
@cindex @code{Source_List_File}
364
  If there is a great number of files, it might be more convenient to use
365
  the attribute @b{Source_List_File}, which specifies the full path of a file.
366
  This file must contain a list of source file names (one per line, no
367
  directory information) that are searched as if they had been defined
368
  through @emph{Source_Files}. Such a file can easily be created through
369
  external tools.
370
 
371
  A warning is issued if both attributes @code{Source_Files} and
372
  @code{Source_List_File} are given explicit values. In this case, the
373
  attribute @code{Source_Files} prevails.
374
 
375
@item @code{Excluded_Source_Files}
376
@cindex @code{Excluded_Source_Files}
377
@cindex @code{Locally_Removed_Files}
378
@cindex @code{Excluded_Source_List_File}
379
  Specifying an explicit list of files is not always convenient.It might be
380
  more convenient to use the default search rules with specific exceptions.
381
  This can be done thanks to the attribute @b{Excluded_Source_Files}
382
  (or its synonym @b{Locally_Removed_Files}).
383
  Its value is the list of file names that should not be taken into account.
384
  This attribute is often used when extending a project, @xref{Project
385
  Extension}. A similar attribute @b{Excluded_Source_List_File} plays the same
386
  role but takes the name of file containing file names similarly to
387
  @code{Source_List_File}.
388
 
389
@end itemize
390
 
391
@noindent
392
In most simple cases, such as the above example, the default source file search
393
behavior provides the expected result, and we do not need to add anything after
394
setting @code{Source_Dirs}. The project manager automatically finds
395
@file{pack.ads}, @file{pack.adb} and @file{proc.adb} as source files of the
396
project.
397
 
398
Note that it is considered an error for a project file to have no sources
399
attached to it unless explicitly declared as mentioned above.
400
 
401
If the order of the source directories is known statically, that is if
402
@code{"**"} is not used in the string list @code{Source_Dirs}, then there may
403
be several files with the same source file name sitting in different
404
directories of the project. In this case, only the file in the first directory
405
is considered as a source of the project and the others are hidden. If
406
@code{"**"} is used in the string list @code{Source_Dirs}, it is an error
407
to have several files with the same source file name in the same directory
408
@code{"**"} subtree, since there would be an ambiguity as to which one should
409
be used. However, two files with the same source file name may exist in two
410
single directories or directory subtrees. In this case, the one in the first
411
directory or directory subtree is a source of the project.
412
 
413
@c ---------------------------------------------
414
@node Object and Exec Directory
415
@subsection Object and Exec Directory
416
@c ---------------------------------------------
417
 
418
@noindent
419
The next step when writing a project is to indicate where the compiler should
420
put the object files. In fact, the compiler and other tools might create
421
several different kind of files (for GNAT, there is the object file and the ALI
422
file for instance). One of the important concepts in projects is that most
423
tools may consider source directories as read-only and do not attempt to create
424
new or temporary files there. Instead, all files are created in the object
425
directory. It is of course not true for project-aware IDEs, whose purpose it is
426
to create the source files.
427
 
428
@cindex @code{Object_Dir}
429
The object directory is specified through the @b{Object_Dir} attribute.
430
Its value is the path to the object directory, either absolute or
431
relative to the directory containing the project file. This
432
directory must already exist and be readable and writable, although
433
some tools have a switch to create the directory if needed (See
434
the switch @code{-p} for @command{gnatmake} and @command{gprbuild}).
435
 
436
If the attribute @code{Object_Dir} is not specified, it defaults to
437
the project directory, that is the directory containing the project file.
438
 
439
For our example, we can specify the object dir in this way:
440
 
441
@smallexample
442
   @b{project} Build @b{is}
443
      @b{for} Source_Dirs @b{use} ("common");
444
      @b{for} Object_Dir @b{use} "obj";   --  <<<<
445
   @b{end} Build;
446
@end smallexample
447
 
448
@noindent
449
As mentioned earlier, there is a single object directory per project. As a
450
result, if you have an existing system where the object files are spread in
451
several directories, you can either move all of them into the same directory if
452
you want to build it with a single project file, or study the section on
453
subsystems (@pxref{Organizing Projects into Subsystems}) to see how each
454
separate object directory can be associated with one of the subsystem
455
constituting the application.
456
 
457
When the @command{linker} is called, it usually creates an executable. By
458
default, this executable is placed in the object directory of the project. It
459
might be convenient to store it in its own directory.
460
 
461
@cindex @code{Exec_Dir}
462
This can be done through the @code{Exec_Dir} attribute, which, like
463
@emph{Object_Dir} contains a single absolute or relative path and must point to
464
an existing and writable directory, unless you ask the tool to create it on
465
your behalf. When not specified, It defaults to the object directory and
466
therefore to the project file's directory if neither @emph{Object_Dir} nor
467
@emph{Exec_Dir} was specified.
468
 
469
In the case of the example, let's place the executable in the root
470
of the hierarchy, ie the same directory as @file{build.gpr}. Hence
471
the project file is now
472
 
473
@smallexample
474
   @b{project} Build @b{is}
475
      @b{for} Source_Dirs @b{use} ("common");
476
      @b{for} Object_Dir @b{use} "obj";
477
      @b{for} Exec_Dir @b{use} ".";  --   <<<<
478
   @b{end} Build;
479
@end smallexample
480
 
481
@c ---------------------------------------------
482
@node Main Subprograms
483
@subsection Main Subprograms
484
@c ---------------------------------------------
485
 
486
@noindent
487
In the previous section, executables were mentioned. The project manager needs
488
to be taught what they are. In a project file, an executable is indicated by
489
pointing to source file of the main subprogram. In C this is the file that
490
contains the @code{main} function, and in Ada the file that contains the main
491
unit.
492
 
493
There can be any number of such main files within a given project, and thus
494
several executables can be built in the context of a single project file. Of
495
course, one given executable might not (and in fact will not) need all the
496
source files referenced by the project. As opposed to other build environments
497
such as @command{makefile}, one does not need to specify the list of
498
dependencies of each executable, the project-aware builders knows enough of the
499
semantics of the languages to build ands link only the necessary elements.
500
 
501
@cindex @code{Main}
502
The list of main files is specified via the @b{Main} attribute. It contains
503
a list of file names (no directories). If a project defines this
504
attribute, it is not necessary to identify  main files on the
505
command line when invoking a builder, and editors like
506
@command{GPS} will be able to create extra menus to spawn or debug the
507
corresponding executables.
508
 
509
@smallexample
510
   @b{project} Build @b{is}
511
      @b{for} Source_Dirs @b{use} ("common");
512
      @b{for} Object_Dir @b{use} "obj";
513
      @b{for} Exec_Dir @b{use} ".";
514
      @b{for} Main @b{use} ("proc.adb");  --   <<<<
515
   @b{end} Build;
516
@end smallexample
517
 
518
@noindent
519
If this attribute is defined in the project, then spawning the builder
520
with a command such as
521
 
522
@smallexample
523
   gnatmake ^-Pbuild^/PROJECT_FILE=build^
524
@end smallexample
525
 
526
@noindent
527
automatically builds all the executables corresponding to the files
528
listed in the @emph{Main} attribute. It is possible to specify one
529
or more executables on the command line to build a subset of them.
530
 
531
@c ---------------------------------------------
532
@node Tools Options in Project Files
533
@subsection Tools Options in Project Files
534
@c ---------------------------------------------
535
 
536
@noindent
537
We now have a project file that fully describes our environment, and can be
538
used to build the application with a simple @command{gnatmake} command as seen
539
in the previous section. In fact, the empty project we showed immediately at
540
the beginning (with no attribute at all) could already fulfill that need if it
541
was put in the @file{common} directory.
542
 
543
Of course, we always want more control. This section will show you how to
544
specify the compilation switches that the various tools involved in the
545
building of the executable should use.
546
 
547
@cindex command line length
548
Since source names and locations are described into the project file, it is not
549
necessary to use switches on the command line for this purpose (switches such
550
as -I for gcc). This removes a major source of command line length overflow.
551
Clearly, the builders will have to communicate this information one way or
552
another to the underlying compilers and tools they call but they usually use
553
response files for this and thus should not be subject to command line
554
overflows.
555
 
556
Several tools are participating to the creation of an executable: the compiler
557
produces object files from the source files; the binder (in the Ada case)
558
creates an source file that takes care, among other things, of elaboration
559
issues and global variables initialization; and the linker gathers everything
560
into a single executable that users can execute. All these tools are known by
561
the project manager and will be called with user defined switches from the
562
project files. However, we need to introduce a new project file concept to
563
express which switches to be used for any of the tools involved in the build.
564
 
565
@cindex project file packages
566
A project file is subdivided into zero or more @b{packages}, each of which
567
contains the attributes specific to one tool (or one set of tools). Project
568
files use an Ada-like syntax for packages. Package names permitted in project
569
files are restricted to a predefined set (@pxref{Packages}), and the contents
570
of packages are limited to a small set of constructs and attributes
571
(@pxref{Attributes}).
572
 
573
Our example project file can be extended with the following empty packages. At
574
this stage, they could all be omitted since they are empty, but they show which
575
packages would be involved in the build process.
576
 
577
@smallexample
578
   @b{project} Build @b{is}
579
      @b{for} Source_Dirs @b{use} ("common");
580
      @b{for} Object_Dir @b{use} "obj";
581
      @b{for} Exec_Dir @b{use} ".";
582
      @b{for} Main @b{use} ("proc.adb");
583
 
584
      @b{package} Builder @b{is}  --<<<  for gnatmake and gprbuild
585
      @b{end} Builder;
586
 
587
      @b{package} Compiler @b{is} --<<<  for the compiler
588
      @b{end} Compiler;
589
 
590
      @b{package} Binder @b{is}   --<<<  for the binder
591
      @b{end} Binder;
592
 
593
      @b{package} Linker @b{is}   --<<<  for the linker
594
      @b{end} Linker;
595
   @b{end} Build;
596
@end smallexample
597
 
598
@noindent
599
Let's first examine the compiler switches. As stated in the initial description
600
of the example, we want to compile all files with @option{-O2}. This is a
601
compiler switch, although it is usual, on the command line, to pass it to the
602
builder which then passes it to the compiler. It is recommended to use directly
603
the right package, which will make the setup easier to understand for other
604
people.
605
 
606
Several attributes can be used to specify the switches:
607
 
608
@table @asis
609
@item @b{Default_Switches}:
610
@cindex @code{Default_Switches}
611
  This is the first mention in this manual of an @b{indexed attribute}. When
612
  this attribute is defined, one must supply an @emph{index} in the form of a
613
  literal string.
614
  In the case of @emph{Default_Switches}, the index is the name of the
615
  language to which the switches apply (since a different compiler will
616
  likely be used for each language, and each compiler has its own set of
617
  switches). The value of the attribute is a list of switches.
618
 
619
  In this example, we want to compile all Ada source files with the
620
  @option{-O2} switch, and the resulting project file is as follows
621
  (only the @code{Compiler} package is shown):
622
 
623
  @smallexample
624
  @b{package} Compiler @b{is}
625
    @b{for} Default_Switches ("Ada") @b{use} ("-O2");
626
  @b{end} Compiler;
627
  @end smallexample
628
 
629
@item @b{Switches}:
630
@cindex @code{Switches}
631
  in some cases, we might want to use specific switches
632
  for one or more files. For instance, compiling @file{proc.adb} might not be
633
  possible at high level of optimization because of a compiler issue.
634
  In such a case, the @emph{Switches}
635
  attribute (indexed on the file name) can be used and will override the
636
  switches defined by @emph{Default_Switches}. Our project file would
637
  become:
638
 
639
  @smallexample
640
  @b{package} Compiler @b{is}
641
    @b{for} Default_Switches ("Ada") @b{use} ("-O2");
642
    @b{for} Switches ("proc.adb") @b{use} ("-O0");
643
  @b{end} Compiler;
644
  @end smallexample
645
 
646
  @noindent
647
  @code{Switches} may take a pattern as an index, such as in:
648
 
649
  @smallexample
650
  @b{package} Compiler @b{is}
651
    @b{for} Default_Switches ("Ada") @b{use} ("-O2");
652
    @b{for} Switches ("pkg*") @b{use} ("-O0");
653
  @b{end} Compiler;
654
  @end smallexample
655
 
656
  @noindent
657
  Sources @file{pkg.adb} and @file{pkg-child.adb} would be compiled with -O0,
658
  not -O2.
659
 
660
  @noindent
661
  @code{Switches} can also be given a language name as index instead of a file
662
  name in which case it has the same semantics as @emph{Default_Switches}.
663
  However, indexes with wild cards are never valid for language name.
664
 
665
@item @b{Local_Configuration_Pragmas}:
666
@cindex @code{Local_Configuration_Pragmas}
667
  this attribute may specify the path
668
  of a file containing configuration pragmas for use by the Ada compiler,
669
  such as @code{pragma Restrictions (No_Tasking)}. These pragmas will be
670
  used for all the sources of the project.
671
 
672
@end table
673
 
674
The switches for the other tools are defined in a similar manner through the
675
@b{Default_Switches} and @b{Switches} attributes, respectively in the
676
@emph{Builder} package (for @command{gnatmake} and @command{gprbuild}),
677
the @emph{Binder} package (binding Ada executables) and the @emph{Linker}
678
package (for linking executables).
679
 
680
@c ---------------------------------------------
681
@node Compiling with Project Files
682
@subsection Compiling with Project Files
683
@c ---------------------------------------------
684
 
685
@noindent
686
Now that our project files are written, let's build our executable.
687
Here is the command we would use from the command line:
688
 
689
@smallexample
690
   gnatmake ^-Pbuild^/PROJECT_FILE=build^
691
@end smallexample
692
 
693
@noindent
694
This will automatically build the executables specified through the
695
@emph{Main} attribute: for each, it will compile or recompile the
696
sources for which the object file does not exist or is not up-to-date; it
697
will then run the binder; and finally run the linker to create the
698
executable itself.
699
 
700
@command{gnatmake} only knows how to handle Ada files. By using
701
@command{gprbuild} as a builder, you could automatically manage C files the
702
same way: create the file @file{utils.c} in the @file{common} directory,
703
set the attribute @emph{Languages} to @code{"(Ada, C)"}, and run
704
 
705
@smallexample
706
   gprbuild ^-Pbuild^/PROJECT_FILE=build^
707
@end smallexample
708
 
709
@noindent
710
Gprbuild knows how to recompile the C files and will
711
recompile them only if one of their dependencies has changed. No direct
712
indication on how to build the various elements is given in the
713
project file, which describes the project properties rather than a
714
set of actions to be executed. Here is the invocation of
715
@command{gprbuild} when building a multi-language program:
716
 
717
@smallexample
718
$ gprbuild -Pbuild
719
gcc -c proc.adb
720
gcc -c pack.adb
721
gcc -c utils.c
722
gprbind proc
723
...
724
gcc proc.o -o proc
725
@end smallexample
726
 
727
@noindent
728
Notice the three steps described earlier:
729
 
730
@itemize @bullet
731
@item The first three gcc commands correspond to the compilation phase.
732
@item The gprbind command corresponds to the post-compilation phase.
733
@item The last gcc command corresponds to the final link.
734
 
735
@end itemize
736
 
737
@noindent
738
@cindex @option{-v} option (for GPRbuild)
739
The default output of GPRbuild's execution is kept reasonably simple and easy
740
to understand. In particular, some of the less frequently used commands are not
741
shown, and some parameters are abbreviated. So it is not possible to rerun the
742
effect of the @command{gprbuild} command by cut-and-pasting its output.
743
GPRbuild's option @code{-v} provides a much more verbose output which includes,
744
among other information, more complete compilation, post-compilation and link
745
commands.
746
 
747
@c ---------------------------------------------
748
@node Executable File Names
749
@subsection Executable File Names
750
@c ---------------------------------------------
751
 
752
@noindent
753
@cindex @code{Executable}
754
By default, the executable name corresponding to a main file is
755
computed from the main source file name. Through the attribute
756
@b{Builder.Executable}, it is possible to change this default.
757
 
758
For instance, instead of building @command{proc} (or @command{proc.exe}
759
on Windows), we could configure our project file to build "proc1"
760
(resp proc1.exe) with the following addition:
761
 
762
@smallexample @c projectfile
763
   project Build is
764
      ...  --  same as before
765
      package Builder is
766
         for Executable ("proc.adb") use "proc1";
767
      end Builder
768
   end Build;
769
@end smallexample
770
 
771
@noindent
772
@cindex @code{Executable_Suffix}
773
Attribute @b{Executable_Suffix}, when specified, may change the suffix
774
of the executable files, when no attribute @code{Executable} applies:
775
its value replace the platform-specific executable suffix.
776
The default executable suffix is empty on UNIX and ".exe" on Windows.
777
 
778
It is also possible to change the name of the produced executable by using the
779
command line switch @option{-o}. When several mains are defined in the project,
780
it is not possible to use the @option{-o} switch and the only way to change the
781
names of the executable is provided by Attributes @code{Executable} and
782
@code{Executable_Suffix}.
783
 
784
@c ---------------------------------------------
785
@node Avoid Duplication With Variables
786
@subsection Avoid Duplication With Variables
787
@c ---------------------------------------------
788
 
789
@noindent
790
To illustrate some other project capabilities, here is a slightly more complex
791
project using similar sources and a main program in C:
792
 
793
@smallexample @c projectfile
794
project C_Main is
795
   for Languages    use ("Ada", "C");
796
   for Source_Dirs  use ("common");
797
   for Object_Dir   use  "obj";
798
   for Main         use ("main.c");
799
   package Compiler is
800
      C_Switches := ("-pedantic");
801
      for Default_Switches ("C")   use C_Switches;
802
      for Default_Switches ("Ada") use ("-gnaty");
803
      for Switches ("main.c") use C_Switches & ("-g");
804
   end Compiler;
805
end C_Main;
806
@end smallexample
807
 
808
@noindent
809
This project has many similarities with the previous one.
810
As expected, its @code{Main} attribute now refers to a C source.
811
The attribute @emph{Exec_Dir} is now omitted, thus the resulting
812
executable will be put in the directory @file{obj}.
813
 
814
The most noticeable difference is the use of a variable in the
815
@emph{Compiler} package to store settings used in several attributes.
816
This avoids text duplication, and eases maintenance (a single place to
817
modify if we want to add new switches for C files). We will revisit
818
the use of variables in the context of scenarios (@pxref{Scenarios in
819
Projects}).
820
 
821
In this example, we see how the file @file{main.c} can be compiled with
822
the switches used for all the other C files, plus @option{-g}.
823
In this specific situation the use of a variable could have been
824
replaced by a reference to the @code{Default_Switches} attribute:
825
 
826
@smallexample @c projectfile
827
   for Switches ("c_main.c") use Compiler'Default_Switches ("C") & ("-g");
828
@end smallexample
829
 
830
@noindent
831
Note the tick (@emph{'}) used to refer to attributes defined in a package.
832
 
833
Here is the output of the GPRbuild command using this project:
834
 
835
@smallexample
836
$gprbuild -Pc_main
837
gcc -c -pedantic -g main.c
838
gcc -c -gnaty proc.adb
839
gcc -c -gnaty pack.adb
840
gcc -c -pedantic utils.c
841
gprbind main.bexch
842
...
843
gcc main.o -o main
844
@end smallexample
845
 
846
@noindent
847
The default switches for Ada sources,
848
the default switches for C sources (in the compilation of @file{lib.c}),
849
and the specific switches for @file{main.c} have all been taken into
850
account.
851
 
852
@c ---------------------------------------------
853
@node Naming Schemes
854
@subsection Naming Schemes
855
@c ---------------------------------------------
856
 
857
@noindent
858
Sometimes an Ada software system is ported from one compilation environment to
859
another (say GNAT), and the file are not named using the default GNAT
860
conventions. Instead of changing all the file names, which for a variety of
861
reasons might not be possible, you can define the relevant file naming scheme
862
in the @b{Naming} package of your project file.
863
 
864
The naming scheme has two distinct goals for the project manager: it
865
allows finding of source files when searching in the source
866
directories, and given a source file name it makes it possible to guess
867
the associated language, and thus the compiler to use.
868
 
869
Note that the use by the Ada compiler of pragmas Source_File_Name is not
870
supported when using project files. You must use the features described in this
871
paragraph. You can however specify other configuration pragmas
872
(@pxref{Specifying Configuration Pragmas}).
873
 
874
The following attributes can be defined in package @code{Naming}:
875
 
876
@table @asis
877
@item @b{Casing}:
878
@cindex @code{Casing}
879
  Its value must be one of @code{"lowercase"} (the default if
880
  unspecified), @code{"uppercase"} or @code{"mixedcase"}. It describes the
881
  casing of file names with regards to the Ada unit name. Given an Ada unit
882
  My_Unit, the file name will respectively be @file{my_unit.adb} (lowercase),
883
  @file{MY_UNIT.ADB} (uppercase) or @file{My_Unit.adb} (mixedcase).
884
  On Windows, file names are case insensitive, so this attribute is
885
  irrelevant.
886
 
887
@item @b{Dot_Replacement}:
888
@cindex @code{Dot_Replacement}
889
  This attribute specifies the string that should replace the "." in unit
890
  names. Its default value is @code{"-"} so that a unit
891
  @code{Parent.Child} is expected to be found in the file
892
  @file{parent-child.adb}. The replacement string must satisfy the following
893
  requirements to avoid ambiguities in the naming scheme:
894
 
895
  @itemize -
896
  @item It must not be empty
897
  @item It cannot start or end with an alphanumeric character
898
  @item It cannot be a single underscore
899
  @item It cannot start with an underscore followed by an alphanumeric
900
  @item It cannot contain a dot @code{'.'} except if the entire string
901
     is @code{"."}
902
 
903
  @end itemize
904
 
905
@item @b{Spec_Suffix} and @b{Specification_Suffix}:
906
@cindex @code{Spec_Suffix}
907
@cindex @code{Specification_Suffix}
908
  For Ada, these attributes give the suffix used in file names that contain
909
  specifications. For other languages, they give the extension for files
910
  that contain declaration (header files in C for instance). The attribute
911
  is indexed on the language.
912
  The two attributes are equivalent, but the latter is obsolescent.
913
  If @code{Spec_Suffix ("Ada")} is not specified, then the default is
914
  @code{"^.ads^.ADS^"}.
915
  The value must satisfy the following requirements:
916
 
917
  @itemize -
918
  @item It must not be empty
919
  @item It cannot start with an alphanumeric character
920
  @item It cannot start with an underscore followed by an alphanumeric character
921
  @item It must include at least one dot
922
 
923
  @end itemize
924
 
925
@item @b{Body_Suffix} and @b{Implementation_Suffix}:
926
@cindex @code{Body_Suffix}
927
@cindex @code{Implementation_Suffix}
928
  These attributes give the extension used for file names that contain
929
  code (bodies in Ada). They are indexed on the language. The second
930
  version is obsolescent and fully replaced by the first attribute.
931
 
932
  These attributes must satisfy the same requirements as @code{Spec_Suffix}.
933
  In addition, they must be different from any of the values in
934
  @code{Spec_Suffix}.
935
  If @code{Body_Suffix ("Ada")} is not specified, then the default is
936
  @code{"^.adb^.ADB^"}.
937
 
938
  If @code{Body_Suffix ("Ada")} and @code{Spec_Suffix ("Ada")} end with the
939
  same string, then a file name that ends with the longest of these two
940
  suffixes will be a body if the longest suffix is @code{Body_Suffix ("Ada")}
941
  or a spec if the longest suffix is @code{Spec_Suffix ("Ada")}.
942
 
943
  If the suffix does not start with a '.', a file with a name exactly equal
944
  to the suffix will also be part of the project (for instance if you define
945
  the suffix as @code{Makefile}, a file called @file{Makefile} will be part
946
  of the project. This capability is usually not interesting  when building.
947
  However, it might become useful when a project is also used to
948
  find the list of source files in an editor, like the GNAT Programming System
949
  (GPS).
950
 
951
@item @b{Separate_Suffix}:
952
@cindex @code{Separate_Suffix}
953
  This attribute is specific to Ada. It denotes the suffix used in file names
954
  that contain separate bodies. If it is not specified, then it defaults to
955
  same value as @code{Body_Suffix ("Ada")}. The same rules apply as for the
956
  @code{Body_Suffix} attribute. The only accepted index is "Ada".
957
 
958
@item @b{Spec} or @b{Specification}:
959
@cindex @code{Spec}
960
@cindex @code{Specification}
961
  This attribute @code{Spec} can be used to define the source file name for a
962
  given Ada compilation unit's spec. The index is the literal name of the Ada
963
  unit (case insensitive). The value is the literal base name of the file that
964
  contains this unit's spec (case sensitive or insensitive depending on the
965
  operating system). This attribute allows the definition of exceptions to the
966
  general naming scheme, in case some files do not follow the usual
967
  convention.
968
 
969
  When a source file contains several units, the relative position of the unit
970
  can be indicated. The first unit in the file is at position 1
971
 
972
  @smallexample @c projectfile
973
   for Spec ("MyPack.MyChild") use "mypack.mychild.spec";
974
   for Spec ("top") use "foo.a" at 1;
975
   for Spec ("foo") use "foo.a" at 2;
976
  @end smallexample
977
 
978
@item @b{Body} or @b{Implementation}:
979
@cindex @code{Body}
980
@cindex @code{Implementation}
981
  These attribute play the same role as @emph{Spec} for Ada bodies.
982
 
983
@item @b{Specification_Exceptions} and @b{Implementation_Exceptions}:
984
@cindex @code{Specification_Exceptions}
985
@cindex @code{Implementation_Exceptions}
986
  These attributes define exceptions to the naming scheme for languages
987
  other than Ada. They are indexed on the language name, and contain
988
  a list of file names respectively for headers and source code.
989
 
990
@end table
991
 
992
@ifclear vms
993
For example, the following package models the Apex file naming rules:
994
 
995
@smallexample @c projectfile
996
@group
997
  package Naming is
998
    for Casing               use "lowercase";
999
    for Dot_Replacement      use ".";
1000
    for Spec_Suffix ("Ada")  use ".1.ada";
1001
    for Body_Suffix ("Ada")  use ".2.ada";
1002
  end Naming;
1003
@end group
1004
@end smallexample
1005
@end ifclear
1006
 
1007
@ifset vms
1008
For example, the following package models the DEC Ada file naming rules:
1009
 
1010
@smallexample @c projectfile
1011
@group
1012
  package Naming is
1013
    for Casing               use "lowercase";
1014
    for Dot_Replacement      use "__";
1015
    for Spec_Suffix ("Ada")  use "_.ada";
1016
    for Body_Suffix ("Ada")  use ".ada";
1017
  end Naming;
1018
@end group
1019
@end smallexample
1020
 
1021
@noindent
1022
(Note that @code{Casing} is @code{"lowercase"} because GNAT gets the file
1023
names in lower case)
1024
@end ifset
1025
 
1026
@c ---------------------------------------------
1027
@node Organizing Projects into Subsystems
1028
@section Organizing Projects into Subsystems
1029
@c ---------------------------------------------
1030
 
1031
@noindent
1032
A @b{subsystem} is a coherent part of the complete system to be built. It is
1033
represented by a set of sources and one single object directory. A system can
1034
be composed of a single subsystem when it is simple as we have seen in the
1035
first section. Complex systems are usually composed of several interdependent
1036
subsystems. A subsystem is dependent on another subsystem if knowledge of the
1037
other one is required to build it, and in particular if visibility on some of
1038
the sources of this other subsystem is required. Each subsystem is usually
1039
represented by its own project file.
1040
 
1041
In this section, the previous example is being extended. Let's assume some
1042
sources of our @code{Build} project depend on other sources.
1043
For instance, when building a graphical interface, it is usual to depend upon
1044
a graphical library toolkit such as GtkAda. Furthermore, we also need
1045
sources from a logging module we had previously written.
1046
 
1047
@menu
1048
* Project Dependencies::
1049
* Cyclic Project Dependencies::
1050
* Sharing Between Projects::
1051
* Global Attributes::
1052
@end menu
1053
 
1054
@c ---------------------------------------------
1055
@node Project Dependencies
1056
@subsection Project Dependencies
1057
@c ---------------------------------------------
1058
 
1059
@noindent
1060
GtkAda comes with its own project file (appropriately called
1061
@file{gtkada.gpr}), and we will assume we have already built a project
1062
called @file{logging.gpr} for the logging module. With the information provided
1063
so far in @file{build.gpr}, building the application would fail with an error
1064
indicating that the gtkada and logging units that are relied upon by the sources
1065
of this project cannot be found.
1066
 
1067
This is easily solved by adding the following @b{with} clauses at the beginning
1068
of our project:
1069
 
1070
@smallexample @c projectfile
1071
  with "gtkada.gpr";
1072
  with "a/b/logging.gpr";
1073
  project Build is
1074
     ...  --  as before
1075
  end Build;
1076
@end smallexample
1077
 
1078
@noindent
1079
@cindex @code{Externally_Built}
1080
When such a project is compiled, @command{gnatmake} will automatically
1081
check the other projects and recompile their sources when needed. It will also
1082
recompile the sources from @code{Build} when needed, and finally create the
1083
executable. In some cases, the implementation units needed to recompile a
1084
project are not available, or come from some third-party and you do not want to
1085
recompile it yourself. In this case, the attribute @b{Externally_Built} to
1086
"true" can be set, indicating to the builder that this project can be assumed
1087
to be up-to-date, and should not be considered for recompilation. In Ada, if
1088
the sources of this externally built project were compiled with another version
1089
of the compiler or with incompatible options, the binder will issue an error.
1090
 
1091
The project's @code{with} clause has several effects. It provides source
1092
visibility between projects during the compilation process. It also guarantees
1093
that the necessary object files from @code{Logging} and @code{GtkAda} are
1094
available when linking @code{Build}.
1095
 
1096
As can be seen in this example, the syntax for importing projects is similar
1097
to the syntax for importing compilation units in Ada. However, project files
1098
use literal strings instead of names, and the @code{with} clause identifies
1099
project files rather than packages.
1100
 
1101
Each literal string after @code{with} is the path
1102
(absolute or relative) to a project file. The @code{.gpr} extension is
1103
optional, although we recommend adding it. If no extension is specified,
1104
and no project file with the @file{^.gpr^.GPR^} extension is found, then
1105
the file is searched for exactly as written in the @code{with} clause,
1106
that is with no extension.
1107
 
1108
As mentioned above, the path after a @code{with} has to be a literal
1109
string, and you cannot use concatenation, or lookup the value of external
1110
variables to change the directories from which a project is loaded.
1111
A solution if you need something like this is to use aggregate projects
1112
(@pxref{Aggregate Projects}).
1113
 
1114
@cindex project path
1115
When a relative path or a base name is used, the
1116
project files are searched relative to each of the directories in the
1117
@b{project path}. This path includes all the directories found with the
1118
following algorithm, in that order, as soon as a matching file is found,
1119
the search stops:
1120
 
1121
@itemize @bullet
1122
@item First, the file is searched relative to the directory that contains the
1123
  current project file.
1124
 
1125
@item
1126
@cindex @code{ADA_PROJECT_PATH}
1127
@cindex @code{GPR_PROJECT_PATH}
1128
  Then it is searched relative to all the directories specified in the
1129
  ^environment variables^logical names^ @b{GPR_PROJECT_PATH} and
1130
  @b{ADA_PROJECT_PATH} (in that order) if they exist. The former is
1131
  recommended, the latter is kept for backward compatibility.
1132
 
1133
@item Finally, it is searched relative to the default project directories.
1134
  Such directories depends on the tool used. The different locations searched
1135
  in the specified order are:
1136
 
1137
  @itemize @bullet
1138
  @item @file{<prefix>/<target>/lib/gnat}
1139
  (for @command{gnatmake} in all cases, and for @command{gprbuild} if option
1140
  @option{--target} is specified)
1141
  @item @file{<prefix>/share/gpr/}
1142
  (for @command{gnatmake} and @command{gprbuild})
1143
  @item @file{<prefix>/lib/gnat/}
1144
  (for @command{gnatmake} and @command{gprbuild})
1145
  @end itemize
1146
 
1147
  In our example, @file{gtkada.gpr} is found in the predefined directory if
1148
  it was installed at the same root as GNAT.
1149
@end itemize
1150
 
1151
@noindent
1152
Some tools also support extending the project path from the command line,
1153
generally through the @option{-aP}. You can see the value of the project
1154
path by using the @command{gnatls -v} command.
1155
 
1156
Any symbolic link will be fully resolved in the directory of the
1157
importing project file before the imported project file is examined.
1158
 
1159
Any source file in the imported project can be used by the sources of the
1160
importing project, transitively.
1161
Thus if @code{A} imports @code{B}, which imports @code{C}, the sources of
1162
@code{A} may depend on the sources of @code{C}, even if @code{A} does not
1163
import @code{C} explicitly. However, this is not recommended, because if
1164
and when @code{B} ceases to import @code{C}, some sources in @code{A} will
1165
no longer compile. @command{gprbuild} has a switch @option{--no-indirect-imports}
1166
that will report such indirect dependencies.
1167
 
1168
One very important aspect of a project hierarchy is that
1169
@b{a given source can only belong to one project} (otherwise the project manager
1170
would not know which settings apply to it and when to recompile it). It means
1171
that different project files do not usually share source directories or
1172
when they do, they need to specify precisely which project owns which sources
1173
using attribute @code{Source_Files} or equivalent. By contrast, 2 projects
1174
can each own a source with the same base file name as long as they live in
1175
different directories. The latter is not true for Ada Sources because of the
1176
correlation between source files and Ada units.
1177
 
1178
@c ---------------------------------------------
1179
@node Cyclic Project Dependencies
1180
@subsection Cyclic Project Dependencies
1181
@c ---------------------------------------------
1182
 
1183
@noindent
1184
Cyclic dependencies are mostly forbidden:
1185
if @code{A} imports @code{B} (directly or indirectly) then @code{B}
1186
is not allowed to import @code{A}. However, there are cases when cyclic
1187
dependencies would be beneficial. For these cases, another form of import
1188
between projects exists: the @b{limited with}.  A project @code{A} that
1189
imports a project @code{B} with a straight @code{with} may also be imported,
1190
directly or indirectly, by @code{B} through a @code{limited with}.
1191
 
1192
The difference between straight @code{with} and @code{limited with} is that
1193
the name of a project imported with a @code{limited with} cannot be used in the
1194
project importing it. In particular, its packages cannot be renamed and
1195
its variables cannot be referred to.
1196
 
1197
@smallexample @c 0projectfile
1198
with "b.gpr";
1199
with "c.gpr";
1200
project A is
1201
    For Exec_Dir use B'Exec_Dir; -- ok
1202
end A;
1203
 
1204
limited with "a.gpr";   --  Cyclic dependency: A -> B -> A
1205
project B is
1206
   For Exec_Dir use A'Exec_Dir; -- not ok
1207
end B;
1208
 
1209
with "d.gpr";
1210
project C is
1211
end C;
1212
 
1213
limited with "a.gpr";  --  Cyclic dependency: A -> C -> D -> A
1214
project D is
1215
   For Exec_Dir use A'Exec_Dir; -- not ok
1216
end D;
1217
@end smallexample
1218
 
1219
@c ---------------------------------------------
1220
@node Sharing Between Projects
1221
@subsection Sharing Between Projects
1222
@c ---------------------------------------------
1223
 
1224
@noindent
1225
When building an application, it is common to have similar needs in several of
1226
the projects corresponding to the subsystems under construction. For instance,
1227
they will all have the same compilation switches.
1228
 
1229
As seen before (@pxref{Tools Options in Project Files}), setting compilation
1230
switches for all sources of a subsystem is simple: it is just a matter of
1231
adding a @code{Compiler.Default_Switches} attribute to each project files with
1232
the same value. Of course, that means duplication of data, and both places need
1233
to be changed in order to recompile the whole application with different
1234
switches. It can become a real problem if there are many subsystems and thus
1235
many project files to edit.
1236
 
1237
There are two main approaches to avoiding this duplication:
1238
 
1239
@itemize @bullet
1240
@item Since @file{build.gpr} imports @file{logging.gpr}, we could change it
1241
  to reference the attribute in Logging, either through a package renaming,
1242
  or by referencing the attribute. The following example shows both cases:
1243
 
1244
  @smallexample @c projectfile
1245
  project Logging is
1246
     package Compiler is
1247
        for Switches ("Ada") use ("-O2");
1248
     end Compiler;
1249
     package Binder is
1250
        for Switches ("Ada") use ("-E");
1251
     end Binder;
1252
  end Logging;
1253
 
1254
  with "logging.gpr";
1255
  project Build is
1256
     package Compiler renames Logging.Compiler;
1257
     package Binder is
1258
        for Switches ("Ada") use Logging.Binder'Switches ("Ada");
1259
     end Binder;
1260
  end Build;
1261
  @end smallexample
1262
 
1263
  @noindent
1264
  The solution used for @code{Compiler} gets the same value for all
1265
  attributes of the package, but you cannot modify anything from the
1266
  package (adding extra switches or some exceptions). The second
1267
  version is more flexible, but more verbose.
1268
 
1269
  If you need to refer to the value of a variable in an imported
1270
  project, rather than an attribute, the syntax is similar but uses
1271
  a "." rather than an apostrophe. For instance:
1272
 
1273
  @smallexample @c projectfile
1274
  with "imported";
1275
  project Main is
1276
     Var1 := Imported.Var;
1277
  end Main;
1278
  @end smallexample
1279
 
1280
@item The second approach is to define the switches in a third project.
1281
  That project is setup without any sources (so that, as opposed to
1282
  the first example, none of the project plays a special role), and
1283
  will only be used to define the attributes. Such a project is
1284
  typically called @file{shared.gpr}.
1285
 
1286
  @smallexample @c projectfile
1287
  abstract project Shared is
1288
     for Source_Files use ();   --  no project
1289
     package Compiler is
1290
        for Switches ("Ada") use ("-O2");
1291
     end Compiler;
1292
  end Shared;
1293
 
1294
  with "shared.gpr";
1295
  project Logging is
1296
     package Compiler renames Shared.Compiler;
1297
  end Logging;
1298
 
1299
  with "shared.gpr";
1300
  project Build is
1301
     package Compiler renames Shared.Compiler;
1302
  end Build;
1303
  @end smallexample
1304
 
1305
  @noindent
1306
  As for the first example, we could have chosen to set the attributes
1307
  one by one rather than to rename a package. The reason we explicitly
1308
  indicate that @code{Shared} has no sources is so that it can be created
1309
  in any directory and we are sure it shares no sources with @code{Build}
1310
  or @code{Logging}, which of course would be invalid.
1311
 
1312
@cindex project qualifier
1313
  Note the additional use of the @b{abstract} qualifier in @file{shared.gpr}.
1314
  This qualifier is optional, but helps convey the message that we do not
1315
  intend this project to have sources (@pxref{Qualified Projects} for
1316
  more qualifiers).
1317
@end itemize
1318
 
1319
@c ---------------------------------------------
1320
@node Global Attributes
1321
@subsection Global Attributes
1322
@c ---------------------------------------------
1323
 
1324
@noindent
1325
We have already seen many examples of attributes used to specify a special
1326
option of one of the tools involved in the build process. Most of those
1327
attributes are project specific. That it to say, they only affect the invocation
1328
of tools on the sources of the project where they are defined.
1329
 
1330
There are a few additional attributes that apply to all projects in a
1331
hierarchy as long as they are defined on the "main" project.
1332
The main project is the project explicitly mentioned on the command-line.
1333
The project hierarchy is the "with"-closure of the main project.
1334
 
1335
Here is a list of commonly used global attributes:
1336
 
1337
@table @asis
1338
@item @b{Builder.Global_Configuration_Pragmas}:
1339
@cindex @code{Global_Configuration_Pragmas}
1340
  This attribute points to a file that contains configuration pragmas
1341
  to use when building executables. These pragmas apply for all
1342
  executables build from this project hierarchy. As we have seen before,
1343
  additional pragmas can be specified on a per-project basis by setting the
1344
  @code{Compiler.Local_Configuration_Pragmas} attribute.
1345
 
1346
@item @b{Builder.Global_Compilation_Switches}:
1347
@cindex @code{Global_Compilation_Switches}
1348
  This attribute is a list of compiler switches to use when compiling any
1349
  source file in the project hierarchy. These switches are used in addition
1350
  to the ones defined in the @code{Compiler} package, which only apply to
1351
  the sources of the corresponding project. This attribute is indexed on
1352
  the name of the language.
1353
 
1354
@end table
1355
 
1356
Using such global capabilities is convenient. It can also lead to unexpected
1357
behavior. Especially when several subsystems are shared among different main
1358
projects and the different global attributes are not
1359
compatible. Note that using aggregate projects can be a safer and more powerful
1360
replacement to global attributes.
1361
 
1362
@c ---------------------------------------------
1363
@node Scenarios in Projects
1364
@section Scenarios in Projects
1365
@c ---------------------------------------------
1366
 
1367
@noindent
1368
Various aspects of the projects can be modified based on @b{scenarios}. These
1369
are user-defined modes that change the behavior of a project. Typical
1370
examples are the setup of platform-specific compiler options, or the use of
1371
a debug and a release mode (the former would activate the generation of debug
1372
information, when the second will focus on improving code optimization).
1373
 
1374
Let's enhance our example to support a debug and a release modes.The issue is to
1375
let the user choose what kind of system he is building:
1376
use @option{-g} as compiler switches in debug mode and @option{-O2}
1377
in release mode. We will also setup the projects so that we do not share the
1378
same object directory in both modes, otherwise switching from one to the other
1379
might trigger more recompilations than needed or mix objects from the 2 modes.
1380
 
1381
One naive approach is to create two different project files, say
1382
@file{build_debug.gpr} and @file{build_release.gpr}, that set the appropriate
1383
attributes as explained in previous sections. This solution does not scale well,
1384
because in presence of multiple projects depending on each other,
1385
you will also have to duplicate the complete hierarchy and adapt the project
1386
files to point to the right copies.
1387
 
1388
@cindex scenarios
1389
Instead, project files support the notion of scenarios controlled
1390
by external values. Such values can come from several sources (in decreasing
1391
order of priority):
1392
 
1393
@table @asis
1394
@item @b{Command line}:
1395
@cindex @option{-X}
1396
  When launching @command{gnatmake} or @command{gprbuild}, the user can pass
1397
  extra @option{-X} switches to define the external value. In
1398
  our case, the command line might look like
1399
 
1400
  @smallexample
1401
       gnatmake -Pbuild.gpr -Xmode=debug
1402
   or  gnatmake -Pbuild.gpr -Xmode=release
1403
  @end smallexample
1404
 
1405
@item @b{^Environment variables^Logical names^}:
1406
  When the external value does not come from the command line, it can come from
1407
  the value of ^environment variables^logical names^ of the appropriate name.
1408
  In our case, if ^an environment variable^a logical name^ called "mode"
1409
  exist, its value will be taken into account.
1410
 
1411
@item @b{External function second parameter}
1412
 
1413
@end table
1414
 
1415
@cindex @code{external}
1416
We now need to get that value in the project. The general form is to use
1417
the predefined function @b{external} which returns the current value of
1418
the external. For instance, we could setup the object directory to point to
1419
either @file{obj/debug} or @file{obj/release} by changing our project to
1420
 
1421
@smallexample @c projectfile
1422
   project Build is
1423
       for Object_Dir use "obj/" & external ("mode", "debug");
1424
       ... --  as before
1425
   end Build;
1426
@end smallexample
1427
 
1428
@noindent
1429
The second parameter to @code{external} is optional, and is the default
1430
value to use if "mode" is not set from the command line or the environment.
1431
 
1432
In order to set the switches according to the different scenarios, other
1433
constructs have to be introduced such as typed variables and case statements.
1434
 
1435
@cindex typed variable
1436
@cindex case statement
1437
A @b{typed variable} is a variable that
1438
can take only a limited number of values, similar to an enumeration in Ada.
1439
Such a variable can then be used in a @b{case statement} and create conditional
1440
sections in the project. The following example shows how this can be done:
1441
 
1442
@smallexample @c projectfile
1443
   project Build is
1444
      type Mode_Type is ("debug", "release");  --  all possible values
1445
      Mode : Mode_Type := external ("mode", "debug"); -- a typed variable
1446
 
1447
      package Compiler is
1448
         case Mode is
1449
            when "debug" =>
1450
               for Switches ("Ada") use ("-g");
1451
            when "release" =>
1452
               for Switches ("Ada") use ("-O2");
1453
         end case;
1454
      end Compiler;
1455
   end Build;
1456
@end smallexample
1457
 
1458
@noindent
1459
The project has suddenly grown in size, but has become much more flexible.
1460
@code{Mode_Type} defines the only valid values for the @code{mode} variable. If
1461
any other value is read from the environment, an error is reported and the
1462
project is considered as invalid.
1463
 
1464
The @code{Mode} variable is initialized with an external value
1465
defaulting to @code{"debug"}. This default could be omitted and that would
1466
force the user to define the value. Finally, we can use a case statement to set the
1467
switches depending on the scenario the user has chosen.
1468
 
1469
Most aspects of the projects can depend on scenarios. The notable exception
1470
are project dependencies (@code{with} clauses), which may not depend on a scenario.
1471
 
1472
Scenarios work the same way with @b{project hierarchies}: you can either
1473
duplicate a variable similar to @code{Mode} in each of the project (as long
1474
as the first argument to @code{external} is always the same and the type is
1475
the same), or simply set the variable in the @file{shared.gpr} project
1476
(@pxref{Sharing Between Projects}).
1477
 
1478
@c ---------------------------------------------
1479
@node Library Projects
1480
@section Library Projects
1481
@c ---------------------------------------------
1482
 
1483
@noindent
1484
So far, we have seen examples of projects that create executables. However,
1485
it is also possible to create libraries instead. A @b{library} is a specific
1486
type of subsystem where, for convenience, objects are grouped together
1487
using system-specific means such as archives or windows DLLs.
1488
 
1489
Library projects provide a system- and language-independent way of building both @b{static}
1490
and @b{dynamic} libraries. They also support the concept of @b{standalone
1491
libraries} (SAL) which offers two significant properties: the elaboration
1492
(e.g. initialization) of the library is either automatic or very simple;
1493
a change in the
1494
implementation part of the library implies minimal post-compilation actions on
1495
the complete system and potentially no action at all for the rest of the
1496
system in the case of dynamic SALs.
1497
 
1498
The GNAT Project Manager takes complete care of the library build, rebuild and
1499
installation tasks, including recompilation of the source files for which
1500
objects do not exist or are not up to date, assembly of the library archive, and
1501
installation of the library (i.e., copying associated source, object and
1502
@file{ALI} files to the specified location).
1503
 
1504
@menu
1505
* Building Libraries::
1506
* Using Library Projects::
1507
* Stand-alone Library Projects::
1508
* Installing a library with project files::
1509
@end menu
1510
 
1511
@c ---------------------------------------------
1512
@node Building Libraries
1513
@subsection Building Libraries
1514
@c ---------------------------------------------
1515
 
1516
@noindent
1517
Let's enhance our example and transform the @code{logging} subsystem into a
1518
library.  In order to do so, a few changes need to be made to @file{logging.gpr}.
1519
A number of specific attributes needs to be defined: at least @code{Library_Name}
1520
and @code{Library_Dir}; in addition, a number of other attributes can be used
1521
to specify specific aspects of the library. For readability, it is also
1522
recommended (although not mandatory), to use the qualifier @code{library} in
1523
front of the @code{project} keyword.
1524
 
1525
@table @asis
1526
@item @b{Library_Name}:
1527
@cindex @code{Library_Name}
1528
  This attribute is the name of the library to be built. There is no
1529
  restriction on the name of a library imposed by the project manager, except
1530
  for stand-alone libraries whose names must follow the syntax of Ada
1531
  identifiers; however, there may be system specific restrictions on the name.
1532
  In general, it is recommended to stick to alphanumeric characters (and
1533
  possibly single underscores) to help portability.
1534
 
1535
@item @b{Library_Dir}:
1536
@cindex @code{Library_Dir}
1537
  This attribute  is the path (absolute or relative) of the directory where
1538
  the library is to be installed. In the process of building a library,
1539
  the sources are compiled, the object files end up  in the explicit or
1540
  implicit @code{Object_Dir} directory. When all sources of a library
1541
  are compiled, some of the compilation artifacts, including the library itself,
1542
  are copied to the library_dir directory. This directory must exists and be
1543
  writable. It must also be different from the object directory so that cleanup
1544
  activities in the Library_Dir do not affect recompilation needs.
1545
 
1546
@end table
1547
 
1548
Here is the new version of @file{logging.gpr} that makes it a library:
1549
 
1550
@smallexample @c projectfile
1551
library project Logging is          --  "library" is optional
1552
   for Library_Name use "logging";  --  will create "liblogging.a" on Unix
1553
   for Object_Dir   use "obj";
1554
   for Library_Dir  use "lib";      --  different from object_dir
1555
end Logging;
1556
@end smallexample
1557
 
1558
@noindent
1559
Once the above two attributes are defined, the library project is valid and
1560
is enough for building a library with default characteristics.
1561
Other library-related attributes can be used to change the defaults:
1562
 
1563
@table @asis
1564
@item @b{Library_Kind}:
1565
@cindex @code{Library_Kind}
1566
  The value of this attribute must be either @code{"static"}, @code{"dynamic"} or
1567
  @code{"relocatable"} (the latter is a synonym for dynamic). It indicates
1568
  which kind of library should be build (the default is to build a
1569
  static library, that is an archive of object files that can potentially
1570
  be linked into a static executable). When the library is set to be dynamic,
1571
  a separate image is created that will be loaded independently, usually
1572
  at the start of the main program execution. Support for dynamic libraries is
1573
  very platform specific, for instance on Windows it takes the form of a DLL
1574
  while on GNU/Linux, it is a dynamic elf image whose suffix is usually
1575
  @file{.so}. Library project files, on the other hand, can be written in
1576
  a platform independent way so that the same project file can be used to build
1577
  a library on different operating systems.
1578
 
1579
  If you need to build both a static and a dynamic library, it is recommended
1580
  use two different object directories, since in some cases some extra code
1581
  needs to be generated for the latter. For such cases, one can
1582
  either define two different project files, or a single one which uses scenarios
1583
  to indicate at the various kinds of library to be build and their
1584
  corresponding object_dir.
1585
 
1586
@cindex @code{Library_ALI_Dir}
1587
@item @b{Library_ALI_Dir}:
1588
  This attribute may be specified to indicate the directory where the ALI
1589
  files of the library are installed. By default, they are copied into the
1590
  @code{Library_Dir} directory, but as for the executables where we have a
1591
  separate @code{Exec_Dir} attribute, you might want to put them in a separate
1592
  directory since there can be hundreds of them. The same restrictions as for
1593
  the @code{Library_Dir} attribute apply.
1594
 
1595
@cindex @code{Library_Version}
1596
@item @b{Library_Version}:
1597
  This attribute is platform dependent, and has no effect on VMS and Windows.
1598
  On Unix, it is used only for dynamic libraries as the internal
1599
  name of the library (the @code{"soname"}). If the library file name (built
1600
  from the @code{Library_Name}) is different from the @code{Library_Version},
1601
  then the library file will be a symbolic link to the actual file whose name
1602
  will be @code{Library_Version}. This follows the usual installation schemes
1603
  for dynamic libraries on many Unix systems.
1604
 
1605
@smallexample @c projectfile
1606
@group
1607
  project Logging is
1608
     Version := "1";
1609
     for Library_Dir use "lib";
1610
     for Library_Name use "logging";
1611
     for Library_Kind use "dynamic";
1612
     for Library_Version use "liblogging.so." & Version;
1613
  end Logging;
1614
@end group
1615
@end smallexample
1616
 
1617
  @noindent
1618
  After the compilation, the directory @file{lib} will contain both a
1619
  @file{libdummy.so.1} library and a symbolic link to it called
1620
  @file{libdummy.so}.
1621
 
1622
@cindex @code{Library_GCC}
1623
@item @b{Library_GCC}:
1624
  This attribute is the name of the tool to use instead of "gcc" to link shared
1625
  libraries. A common use of this attribute is to define a wrapper script that
1626
  accomplishes specific actions before calling gcc (which itself is calling the
1627
  linker to build the library image).
1628
 
1629
@item @b{Library_Options}:
1630
@cindex @code{Library_Options}
1631
  This attribute may be used to specify additional switches (last switches)
1632
  when linking a shared library.
1633
 
1634
@item @b{Leading_Library_Options}:
1635
@cindex @code{Leading_Library_Options}
1636
  This attribute, that is taken into account only by @command{gprbuild}, may be
1637
  used to specified leading options (first switches) when linking a shared
1638
  library.
1639
 
1640
@cindex @code{Linker_Options}
1641
@item @b{Linker.Linker_Options}:
1642
  This attribute specifies additional switches to be given to the linker when
1643
  linking an executable. It is ignored when defined in the main project and
1644
  taken into account in all other projects that are imported directly or
1645
  indirectly. These switches complement the @code{Linker.Switches}
1646
  defined in the main project. This is useful when a particular subsystem
1647
  depends on an external library: adding this dependency as a
1648
  @code{Linker_Options} in the project of the subsystem is more convenient than
1649
  adding it to all the @code{Linker.Switches} of the main projects that depend
1650
  upon this subsystem.
1651
@end table
1652
 
1653
@c ---------------------------------------------
1654
@node Using Library Projects
1655
@subsection Using Library Projects
1656
@c ---------------------------------------------
1657
 
1658
@noindent
1659
When the builder detects that a project file is a library project file, it
1660
recompiles all sources of the project that need recompilation and rebuild the
1661
library if any of the sources have been recompiled. It then groups all object
1662
files into a single file, which is a shared or a static library. This library
1663
can later on be linked with multiple executables. Note that the use
1664
of shard libraries reduces the size of the final executable and can also reduce
1665
the memory footprint at execution time when the library is shared among several
1666
executables.
1667
 
1668
It is also possible to build @b{multi-language libraries}. When using
1669
@command{gprbuild} as a builder, multi-language library projects allow naturally
1670
the creation of multi-language libraries . @command{gnatmake}, does not try to
1671
compile non Ada sources. However, when the project is multi-language, it will
1672
automatically link all object files found in the object directory, whether or
1673
not they were compiled from an Ada source file. This specific behavior does not
1674
apply to Ada-only projects which only take into account the objects
1675
corresponding to the sources of the project.
1676
 
1677
A non-library project can import a library project. When the builder is invoked
1678
on the former, the library of the latter is only rebuilt when absolutely
1679
necessary. For instance, if a unit of the
1680
library is not up-to-date but non of the executables need this unit, then the
1681
unit is not recompiled and the library is not reassembled.
1682
For instance, let's assume in our example that logging has the following
1683
sources: @file{log1.ads}, @file{log1.adb}, @file{log2.ads} and
1684
@file{log2.adb}. If @file{log1.adb} has been modified, then the library
1685
@file{liblogging} will be rebuilt when compiling all the sources of
1686
@code{Build} only if @file{proc.ads}, @file{pack.ads} or @file{pack.adb}
1687
include a @code{"with Log1"}.
1688
 
1689
To ensure that all the sources in the @code{Logging} library are
1690
up to date, and that all the sources of @code{Build} are also up to date,
1691
the following two commands needs to be used:
1692
 
1693
@smallexample
1694
gnatmake -Plogging.gpr
1695
gnatmake -Pbuild.gpr
1696
@end smallexample
1697
 
1698
@noindent
1699
All @file{ALI} files will also be copied from the object directory to the
1700
library directory. To build executables, @command{gnatmake} will use the
1701
library rather than the individual object files.
1702
 
1703
@ifclear vms
1704
Library projects can also be useful to describe a library that need to be used
1705
but, for some reason, cannot be rebuilt. For instance, it is the case when some
1706
of the library sources are not available. Such library projects need simply to
1707
use the @code{Externally_Built} attribute as in the example below:
1708
 
1709
@smallexample @c projectfile
1710
library project Extern_Lib is
1711
   for Languages    use ("Ada", "C");
1712
   for Source_Dirs  use ("lib_src");
1713
   for Library_Dir  use "lib2";
1714
   for Library_Kind use "dynamic";
1715
   for Library_Name use "l2";
1716
   for Externally_Built use "true";  --  <<<<
1717
end Extern_Lib;
1718
@end smallexample
1719
 
1720
@noindent
1721
In the case of externally built libraries, the @code{Object_Dir}
1722
attribute does not need to be specified because it will never be
1723
used.
1724
 
1725
The main effect of using such an externally built library project is mostly to
1726
affect the linker command in order to reference the desired library. It can
1727
also be achieved by using @code{Linker.Linker_Options} or @code{Linker.Switches}
1728
in the project corresponding to the subsystem needing this external library.
1729
This latter method is more straightforward in simple cases but when several
1730
subsystems depend upon the same external library, finding the proper place
1731
for the @code{Linker.Linker_Options} might not be easy and if it is
1732
not placed properly, the final link command is likely to present ordering issues.
1733
In such a situation, it is better to use the externally built library project
1734
so that all other subsystems depending on it can declare this dependency thanks
1735
to a project @code{with} clause, which in turn will trigger the builder to find
1736
the proper order of libraries in the final link command.
1737
@end ifclear
1738
 
1739
@c ---------------------------------------------
1740
@node Stand-alone Library Projects
1741
@subsection Stand-alone Library Projects
1742
@c ---------------------------------------------
1743
 
1744
@noindent
1745
@cindex standalone libraries
1746
A @b{stand-alone library} is a library that contains the necessary code to
1747
elaborate the Ada units that are included in the library. A stand-alone
1748
library is a convenient way to add an Ada subsystem to a more global system
1749
whose main is not in Ada since it makes the elaboration of the Ada part mostly
1750
transparent. However, stand-alone libraries are also useful when the main is in
1751
Ada: they provide a means for minimizing relinking & redeployment of complex
1752
systems when localized changes are made.
1753
 
1754
The name of a stand-alone library, specified with attribute
1755
@code{Library_Name}, must have the syntax of an Ada identifier.
1756
 
1757
The most prominent characteristic of a stand-alone library is that it offers a
1758
distinction between interface units and implementation units. Only the former
1759
are visible to units outside the library. A stand-alone library project is thus
1760
characterised by a third attribute, usually @b{Library_Interface}, in addition
1761
to the two attributes that make a project a Library Project
1762
(@code{Library_Name} and @code{Library_Dir}). This third attribute may also be
1763
@b{Interfaces}. @b{Library_Interface} only works when the interface is in Ada
1764
and takes a list of units as parameter. @b{Interfaces} works for any supported
1765
language and takes a list of sources as parameter.
1766
 
1767
@table @asis
1768
@item @b{Library_Interface}:
1769
@cindex @code{Library_Interface}
1770
  This attribute defines an explicit subset of the units of the project. Units
1771
  from projects importing this library project may only "with" units whose
1772
  sources are listed in the @code{Library_Interface}. Other sources are
1773
  considered implementation units.
1774
 
1775
@smallexample @c projectfile
1776
@group
1777
     for Library_Dir use "lib";
1778
     for Library_Name use "loggin";
1779
     for Library_Interface use ("lib1", "lib2");  --  unit names
1780
@end group
1781
@end smallexample
1782
 
1783
@item @b{Interfaces}
1784
  This attribute defines an explicit subset of the source files of a project.
1785
  Sources from projects importing this project, can only depend on sources from
1786
  this subset. This attribute can be used on non library projects. It can also
1787
  be used as a replacement for attribute @code{Library_Interface}, in which
1788
  case, units have to be replaced by source files. For multi-language library
1789
  projects, it is the only way to make the project a Stand-Alone Library project
1790
  whose interface is not purely Ada.
1791
 
1792
@item @b{Library_Standalone}:
1793
@cindex @code{Library_Standalone}
1794
  This attribute defines the kind of standalone library to
1795
  build. Values are either @code{standard} (the default), @code{no} or
1796
  @code{encapsulated}. When @code{standard} is used the code to elaborate and
1797
  finalize the library is embedded, when @code{encapsulated} is used the
1798
  library can furthermore only depends on static libraries (including
1799
  the GNAT runtime). This attribute can be set to @code{no} to make it clear
1800
  that the library should not be standalone in which case the
1801
  @code{Library_Interface} should not defined.
1802
 
1803
@smallexample @c projectfile
1804
@group
1805
     for Library_Dir use "lib";
1806
     for Library_Name use "loggin";
1807
     for Library_Interface use ("lib1", "lib2");  --  unit names
1808
     for Library_Standalone use "encapsulated";
1809
@end group
1810
@end smallexample
1811
 
1812
@end table
1813
 
1814
In order to include the elaboration code in the stand-alone library, the binder
1815
is invoked on the closure of the library units creating a package whose name
1816
depends on the library name (^b~logging.ads/b^B$LOGGING.ADS/B^ in the example).
1817
This binder-generated package includes @b{initialization} and @b{finalization}
1818
procedures whose names depend on the library name (@code{logginginit} and
1819
@code{loggingfinal} in the example). The object corresponding to this package is
1820
included in the library.
1821
 
1822
@table @asis
1823
@item @b{Library_Auto_Init}:
1824
@cindex @code{Library_Auto_Init}
1825
  A dynamic stand-alone Library is automatically initialized
1826
  if automatic initialization of Stand-alone Libraries is supported on the
1827
  platform and if attribute @b{Library_Auto_Init} is not specified or
1828
  is specified with the value "true". A static Stand-alone Library is never
1829
  automatically initialized. Specifying "false" for this attribute
1830
  prevent automatic initialization.
1831
 
1832
  When a non-automatically initialized stand-alone library is used in an
1833
  executable, its initialization procedure must be called before any service of
1834
  the library is used. When the main subprogram is in Ada, it may mean that the
1835
  initialization procedure has to be called during elaboration of another
1836
  package.
1837
 
1838
@item @b{Library_Dir}:
1839
@cindex @code{Library_Dir}
1840
  For a stand-alone library, only the @file{ALI} files of the interface units
1841
  (those that are listed in attribute @code{Library_Interface}) are copied to
1842
  the library directory. As a consequence, only the interface units may be
1843
  imported from Ada units outside of the library. If other units are imported,
1844
  the binding phase will fail.
1845
 
1846
@item @b{Binder.Default_Switches}:
1847
  When a stand-alone library is bound, the switches that are specified in
1848
  the attribute @b{Binder.Default_Switches ("Ada")} are
1849
  used in the call to @command{gnatbind}.
1850
 
1851
@item @b{Library_Src_Dir}:
1852
@cindex @code{Library_Src_Dir}
1853
  This attribute defines the location (absolute or relative to the project
1854
  directory) where the sources of the interface units are copied at
1855
  installation time.
1856
  These sources includes the specs of the interface units along with the closure
1857
  of sources necessary to compile them successfully. That may include bodies and
1858
  subunits, when pragmas @code{Inline} are used, or when there is a generic
1859
  units in the spec. This directory cannot point to the object directory or
1860
  one of the source directories, but it can point to the library directory,
1861
  which is the default value for this attribute.
1862
 
1863
@item @b{Library_Symbol_Policy}:
1864
@cindex @code{Library_Symbol_Policy}
1865
  This attribute controls the export of symbols and, on some platforms (like
1866
  VMS) that have the notions of major and minor IDs built in the library
1867
  files, it controls the setting of these IDs. It is not supported on all
1868
  platforms (where it will just have no effect). It may have one of the
1869
  following values:
1870
 
1871
  @itemize -
1872
  @item @code{"autonomous"} or @code{"default"}: exported symbols are not controlled
1873
  @item @code{"compliant"}: if attribute @b{Library_Reference_Symbol_File}
1874
     is not defined, then it is equivalent to policy "autonomous". If there
1875
     are exported symbols in the reference symbol file that are not in the
1876
     object files of the interfaces, the major ID of the library is increased.
1877
     If there are symbols in the object files of the interfaces that are not
1878
     in the reference symbol file, these symbols are put at the end of the list
1879
     in the newly created symbol file and the minor ID is increased.
1880
  @item @code{"controlled"}: the attribute @b{Library_Reference_Symbol_File} must be
1881
     defined. The library will fail to build if the exported symbols in the
1882
     object files of the interfaces do not match exactly the symbol in the
1883
     symbol file.
1884
  @item @code{"restricted"}: The attribute @b{Library_Symbol_File} must be defined.
1885
     The library will fail to build if there are symbols in the symbol file that
1886
     are not in the exported symbols of the object files of the interfaces.
1887
     Additional symbols in the object files are not added to the symbol file.
1888
  @item @code{"direct"}: The attribute @b{Library_Symbol_File} must be defined and
1889
     must designate an existing file in the object directory. This symbol file
1890
     is passed directly to the underlying linker without any symbol processing.
1891
 
1892
  @end itemize
1893
 
1894
@item @b{Library_Reference_Symbol_File}
1895
@cindex @code{Library_Reference_Symbol_File}
1896
  This attribute may define the path name of a reference symbol file that is
1897
  read when the symbol policy is either "compliant" or "controlled", on
1898
  platforms that support symbol control, such as VMS, when building a
1899
  stand-alone library. The path may be an absolute path or a path relative
1900
  to the project directory.
1901
 
1902
@item @b{Library_Symbol_File}
1903
@cindex @code{Library_Symbol_File}
1904
  This attribute may define the name of the symbol file to be created when
1905
  building a stand-alone library when the symbol policy is either "compliant",
1906
  "controlled" or "restricted", on platforms that support symbol control,
1907
  such as VMS. When symbol policy is "direct", then a file with this name
1908
  must exist in the object directory.
1909
@end table
1910
 
1911
@c ---------------------------------------------
1912
@node Installing a library with project files
1913
@subsection Installing a library with project files
1914
@c ---------------------------------------------
1915
 
1916
@noindent
1917
When using project files, library installation is part of the library build
1918
process. Thus no further action is needed in order to make use of the
1919
libraries that are built as part of the general application build. A usable
1920
version of the library is installed in the directory specified by the
1921
@code{Library_Dir} attribute of the library project file.
1922
 
1923
You may want to install a library in a context different from where the library
1924
is built. This situation arises with third party suppliers, who may want
1925
to distribute a library in binary form where the user is not expected to be
1926
able to recompile the library. The simplest option in this case is to provide
1927
a project file slightly different from the one used to build the library, by
1928
using the @code{externally_built} attribute. @ref{Using Library Projects}
1929
 
1930
@c ---------------------------------------------
1931
@node Project Extension
1932
@section Project Extension
1933
@c ---------------------------------------------
1934
 
1935
@noindent
1936
During development of a large system, it is sometimes necessary to use
1937
modified versions of some of the source files, without changing the original
1938
sources. This can be achieved through the @b{project extension} facility.
1939
 
1940
Suppose for instance that our example @code{Build} project is build every night
1941
for the whole team, in some shared directory. A developer usually need to work
1942
on a small part of the system, and might not want to have a copy of all the
1943
sources and all the object files (mostly because that would require too much
1944
disk space, time to recompile everything). He prefers to be able to override
1945
some of the source files in his directory, while taking advantage of all the
1946
object files generated at night.
1947
 
1948
Another example can be taken from large software systems, where it is common to have
1949
multiple implementations of a common interface; in Ada terms, multiple
1950
versions of a package body for the same spec.  For example, one implementation
1951
might be safe for use in tasking programs, while another might only be used
1952
in sequential applications.  This can be modeled in GNAT using the concept
1953
of @emph{project extension}.  If one project (the ``child'') @emph{extends}
1954
another project (the ``parent'') then by default all source files of the
1955
parent project are inherited by the child, but the child project can
1956
override any of the parent's source files with new versions, and can also
1957
add new files or remove unnecessary ones.
1958
This facility is the project analog of a type extension in
1959
object-oriented programming.  Project hierarchies are permitted (an extending
1960
project may itself be extended), and a project that
1961
extends a project can also import other projects.
1962
 
1963
A third example is that of using project extensions to provide different
1964
versions of the same system. For instance, assume that a @code{Common}
1965
project is used by two development branches. One of the branches has now
1966
been frozen, and no further change can be done to it or to @code{Common}.
1967
However, the other development branch still needs evolution of @code{Common}.
1968
Project extensions provide a flexible solution to create a new version
1969
of a subsystem while sharing and reusing as much as possible from the original
1970
one.
1971
 
1972
A project extension inherits implicitly all the sources and objects from the
1973
project it extends. It is possible to create a new version of some of the
1974
sources in one of the additional source dirs of the extending project. Those new
1975
versions hide the original versions. Adding new sources or removing existing
1976
ones is also possible. Here is an example on how to extend the project
1977
@code{Build} from previous examples:
1978
 
1979
@smallexample @c projectfile
1980
   project Work extends "../bld/build.gpr" is
1981
   end Work;
1982
@end smallexample
1983
 
1984
@noindent
1985
The project after @b{extends} is the one being extended. As usual, it can be
1986
specified using an absolute path, or a path relative to any of the directories
1987
in the project path (@pxref{Project Dependencies}). This project does not
1988
specify source or object directories, so the default value for these attribute
1989
will be used that is to say the current directory (where project @code{Work} is
1990
placed). We can already compile that project with
1991
 
1992
@smallexample
1993
   gnatmake -Pwork
1994
@end smallexample
1995
 
1996
@noindent
1997
If no sources have been placed in the current directory, this command
1998
won't do anything, since this project does not change the
1999
sources it inherited from @code{Build}, therefore all the object files
2000
in @code{Build} and its dependencies are still valid and are reused
2001
automatically.
2002
 
2003
Suppose we now want to supply an alternate version of @file{pack.adb}
2004
but use the existing versions of @file{pack.ads} and @file{proc.adb}.
2005
We can create the new file Work's current directory  (likely
2006
by copying the one from the @code{Build} project and making changes to
2007
it. If new packages are needed at the same time, we simply create
2008
new files in the source directory of the extending project.
2009
 
2010
When we recompile, @command{gnatmake} will now automatically recompile
2011
this file (thus creating @file{pack.o} in the current directory) and
2012
any file that depends on it (thus creating @file{proc.o}). Finally, the
2013
executable is also linked locally.
2014
 
2015
Note that we could have obtained the desired behavior using project import
2016
rather than project inheritance. A @code{base} project would contain the
2017
sources for @file{pack.ads} and @file{proc.adb}, and @code{Work} would
2018
import @code{base} and add @file{pack.adb}. In this scenario,  @code{base}
2019
cannot contain the original version of @file{pack.adb} otherwise there would be
2020
2 versions of the same unit in the closure of the project and this is not
2021
allowed. Generally speaking, it is not recommended to put the spec and the
2022
body of a unit in different projects since this affects their autonomy and
2023
reusability.
2024
 
2025
In a project file that extends another project, it is possible to
2026
indicate that an inherited source is @b{not part} of the sources of the
2027
extending project. This is necessary sometimes when a package spec has
2028
been overridden and no longer requires a body: in this case, it is
2029
necessary to indicate that the inherited body is not part of the sources
2030
of the project, otherwise there will be a compilation error
2031
when compiling the spec.
2032
 
2033
@cindex @code{Excluded_Source_Files}
2034
@cindex @code{Excluded_Source_List_File}
2035
For that purpose, the attribute @b{Excluded_Source_Files} is used.
2036
Its value is a list of file names.
2037
It is also possible to use attribute @code{Excluded_Source_List_File}.
2038
Its value is the path of a text file containing one file name per
2039
line.
2040
 
2041
@smallexample @c @projectfile
2042
project Work extends "../bld/build.gpr" is
2043
   for Source_Files use ("pack.ads");
2044
   --  New spec of Pkg does not need a completion
2045
   for Excluded_Source_Files use ("pack.adb");
2046
end Work;
2047
@end smallexample
2048
 
2049
@noindent
2050
All packages that are not declared in the extending project are inherited from
2051
the project being extended, with their attributes, with the exception of
2052
@code{Linker'Linker_Options} which is never inherited. In particular, an
2053
extending project retains all the switches specified in the project being
2054
extended.
2055
 
2056
At the project level, if they are not declared in the extending project, some
2057
attributes are inherited from the project being extended. They are:
2058
@code{Languages}, @code{Main} (for a root non library project) and
2059
@code{Library_Name} (for a project extending a library project)
2060
 
2061
@menu
2062
* Project Hierarchy Extension::
2063
@end menu
2064
 
2065
@c ---------------------------------------------
2066
@node Project Hierarchy Extension
2067
@subsection Project Hierarchy Extension
2068
@c ---------------------------------------------
2069
 
2070
@noindent
2071
One of the fundamental restrictions in project extension is the following:
2072
@b{A project is not allowed to import directly or indirectly at the same time an
2073
extending project and one of its ancestors}.
2074
 
2075
By means of example, consider the following hierarchy of projects.
2076
 
2077
@smallexample
2078
   a.gpr  contains package A1
2079
   b.gpr, imports a.gpr and contains B1, which depends on A1
2080
   c.gpr, imports b.gpr and contains C1, which depends on B1
2081
@end smallexample
2082
 
2083
@noindent
2084
If we want to locally extend the packages @code{A1} and @code{C1}, we need to
2085
create several extending projects:
2086
 
2087
@smallexample
2088
   a_ext.gpr which extends a.gpr, and overrides A1
2089
   b_ext.gpr which extends b.gpr and imports a_ext.gpr
2090
   c_ext.gpr which extends c.gpr, imports b_ext.gpr and overrides C1
2091
@end smallexample
2092
 
2093
@noindent
2094
@smallexample @c projectfile
2095
   project A_Ext extends "a.gpr" is
2096
      for Source_Files use ("a1.adb", "a1.ads");
2097
   end A_Ext;
2098
 
2099
   with "a_ext.gpr";
2100
   project B_Ext extends "b.gpr" is
2101
   end B_Ext;
2102
 
2103
   with "b_ext.gpr";
2104
   project C_Ext extends "c.gpr" is
2105
      for Source_Files use ("c1.adb");
2106
   end C_Ext;
2107
@end smallexample
2108
 
2109
@noindent
2110
The extension @file{b_ext.gpr} is required, even though we are not overriding
2111
any of the sources of @file{b.gpr} because otherwise @file{c_expr.gpr} would
2112
import @file{b.gpr} which itself knows nothing about @file{a_ext.gpr}.
2113
 
2114
@cindex extends all
2115
When extending a large system spanning multiple projects, it is often
2116
inconvenient to extend every project in the hierarchy that is impacted by a
2117
small change introduced in a low layer. In such cases, it is possible to create
2118
an @b{implicit extension} of entire hierarchy using @b{extends all}
2119
relationship.
2120
 
2121
When the project is extended using @code{extends all} inheritance, all projects
2122
that are imported by it, both directly and indirectly, are considered virtually
2123
extended. That is, the project manager creates implicit projects
2124
that extend every project in the hierarchy; all these implicit projects do not
2125
control sources on their own and use the object directory of
2126
the "extending all" project.
2127
 
2128
It is possible to explicitly extend one or more projects in the hierarchy
2129
in order to modify the sources. These extending projects must be imported by
2130
the "extending all" project, which will replace the corresponding virtual
2131
projects with the explicit ones.
2132
 
2133
When building such a project hierarchy extension, the project manager will
2134
ensure that both modified sources and sources in implicit extending projects
2135
that depend on them, are recompiled.
2136
 
2137
Thus, in our example we could create the following projects instead:
2138
 
2139
@smallexample
2140
   a_ext.gpr, extends a.gpr and overrides A1
2141
   c_ext.gpr, "extends all" c.gpr, imports a_ext.gpr and overrides C1
2142
 
2143
@end smallexample
2144
 
2145
@noindent
2146
@smallexample @c projectfile
2147
   project A_Ext extends "a.gpr" is
2148
      for Source_Files use ("a1.adb", "a1.ads");
2149
   end A_Ext;
2150
 
2151
   with "a_ext.gpr";
2152
   project C_Ext extends all "c.gpr" is
2153
     for Source_Files use ("c1.adb");
2154
   end C_Ext;
2155
@end smallexample
2156
 
2157
@noindent
2158
When building project @file{c_ext.gpr}, the entire modified project space is
2159
considered for recompilation, including the sources of @file{b.gpr} that are
2160
impacted by the changes in @code{A1} and @code{C1}.
2161
 
2162
@c ---------------------------------------------
2163
@node Aggregate Projects
2164
@section Aggregate Projects
2165
@c ---------------------------------------------
2166
 
2167
@noindent
2168
 
2169
Aggregate projects are an extension of the project paradigm, and are
2170
meant to solve a few specific use cases that cannot be solved directly
2171
using standard projects. This section will go over a few of these use
2172
cases to try and explain what you can use aggregate projects for.
2173
 
2174
@menu
2175
* Building all main programs from a single project tree::
2176
* Building a set of projects with a single command::
2177
* Define a build environment::
2178
* Performance improvements in builder::
2179
* Syntax of aggregate projects::
2180
* package Builder in aggregate projects::
2181
@end menu
2182
 
2183
@c -----------------------------------------------------------
2184
@node Building all main programs from a single project tree
2185
@subsection Building all main programs from a single project tree
2186
@c -----------------------------------------------------------
2187
 
2188
Most often, an application is organized into modules and submodules,
2189
which are very conveniently represented as a project tree or graph
2190
(the root project A @code{with}s the projects for each modules (say B and C),
2191
which in turn @code{with} projects for submodules.
2192
 
2193
Very often, modules will build their own executables (for testing
2194
purposes for instance), or libraries (for easier reuse in various
2195
contexts).
2196
 
2197
However, if you build your project through gnatmake or gprbuild, using
2198
a syntax similar to
2199
 
2200
@smallexample
2201
   gprbuild -PA.gpr
2202
@end smallexample
2203
 
2204
this will only rebuild the main programs of project A, not those of the
2205
imported projects B and C. Therefore you have to spawn several
2206
gnatmake commands, one per project, to build all executables.
2207
This is a little inconvenient, but more importantly is inefficient
2208
(since gnatmake needs to do duplicate work to ensure that sources are
2209
up-to-date, and cannot easily compile things in parallel when using
2210
the -j switch).
2211
 
2212
Also libraries are always rebuild when building a project.
2213
 
2214
You could therefore define an aggregate project Agg that groups A, B
2215
and C. Then, when you build with
2216
 
2217
@smallexample
2218
    gprbuild -PAgg.gpr
2219
@end smallexample
2220
 
2221
this will build all mains from A, B and C.
2222
 
2223
@smallexample @c projectfile
2224
   aggregate project Agg is
2225
      for Project_Files use ("a.gpr", "b.gpr", "c.gpr");
2226
   end Agg;
2227
@end smallexample
2228
 
2229
If B or C do not define any main program (through their Main
2230
attribute), all their sources are build. When you do not group them
2231
in the aggregate project, only those sources that are needed by A
2232
will be build.
2233
 
2234
If you add a main to a project P not already explicitly referenced in the
2235
aggregate project, you will need to add "p.gpr" in the list of project
2236
files for the aggregate project, or the main will not be built when
2237
building the aggregate project.
2238
 
2239
@c ---------------------------------------------------------
2240
@node Building a set of projects with a single command
2241
@subsection Building a set of projects with a single command
2242
@c ---------------------------------------------------------
2243
 
2244
One other case is when you have multiple applications and libraries
2245
that are build independently from each other (but they can be build in
2246
parallel). For instance, you have a project tree rooted at A, and
2247
another one (which might share some subprojects) rooted at B.
2248
 
2249
Using only gprbuild, you could do
2250
 
2251
@smallexample
2252
  gprbuild -PA.gpr
2253
  gprbuild -PB.gpr
2254
@end smallexample
2255
 
2256
to build both. But again, gprbuild has to do some duplicate work for
2257
those files that are shared between the two, and cannot truly build
2258
things in parallel efficiently.
2259
 
2260
If the two projects are really independent, share no sources other
2261
than through a common subproject, and have no source files with a
2262
common basename, you could create a project C that imports A and
2263
B. But these restrictions are often too strong, and one has to build
2264
them independently. An aggregate project does not have these
2265
limitations, and can aggregate two project trees that have common
2266
sources.
2267
 
2268
@smallexample
2269
Aggregate projects can group projects with duplicate file names
2270
@end smallexample
2271
 
2272
This scenario is particularly useful in environment like VxWork 653
2273
where the applications running in the multiple partitions can be build
2274
in parallel through a single gprbuild command. This also works nicely
2275
with Annex E.
2276
 
2277
@smallexample
2278
   Aggregate projects can be used to build multiple partitions
2279
@end smallexample
2280
 
2281
@c ---------------------------------------------
2282
@node Define a build environment
2283
@subsection Define a build environment
2284
@c ---------------------------------------------
2285
 
2286
The environment variables at the time you launch gprbuild or gprbuild
2287
will influence the view these tools have of the project (PATH to find
2288
the compiler, ADA_PROJECT_PATH or GPR_PROJECT_PATH to find the
2289
projects, environment variables that are referenced in project files
2290
through the "external" statement,...). Several command line switches
2291
can be used to override those (-X or -aP), but on some systems and
2292
with some projects, this might make the command line too long, and on
2293
all systems often make it hard to read.
2294
 
2295
An aggregate project can be used to set the environment for all
2296
projects build through that aggregate. One of the nice aspects is that
2297
you can put the aggregate project under configuration management, and
2298
make sure all your user have a consistent environment when
2299
building. The syntax looks like
2300
 
2301
@smallexample @c projectfile
2302
   aggregate project Agg is
2303
      for Project_Files use ("A.gpr", "B.gpr");
2304
      for Project_Path use ("../dir1", "../dir1/dir2");
2305
      for External ("BUILD") use "PRODUCTION";
2306
 
2307
      package Builder is
2308
         for Switches ("Ada") use ("-q");
2309
      end Builder;
2310
   end Agg;
2311
@end smallexample
2312
 
2313
One of the often requested features in projects is to be able to
2314
reference external variables in @code{with} statements, as in
2315
 
2316
@smallexample @c projectfile
2317
  with external("SETUP") & "path/prj.gpr";   --  ILLEGAL
2318
  project MyProject is
2319
     ...
2320
  end MyProject;
2321
@end smallexample
2322
 
2323
For various reasons, this isn't authorized. But using aggregate
2324
projects provide an elegant solution. For instance, you could
2325
use a project file like:
2326
 
2327
@smallexample @c projectfile
2328
aggregate project Agg is
2329
    for Project_Path use (external("SETUP") % "path");
2330
    for Project_Files use ("myproject.gpr");
2331
end Agg;
2332
 
2333
with "prj.gpr";  --  searched on Agg'Project_Path
2334
project MyProject is
2335
   ...
2336
end MyProject;
2337
@end smallexample
2338
 
2339
@c --------------------------------------------
2340
@node Performance improvements in builder
2341
@subsection Performance improvements in builder
2342
@c --------------------------------------------
2343
 
2344
The loading of aggregate projects is optimized in gprbuild and
2345
gnatmake, so that all files are searched for only once on the disk
2346
(thus reducing the number of system calls and contributing to faster
2347
compilation times especially on systems with sources on remote
2348
servers). As part of the loading, gprbuild and gnatmake compute how
2349
and where a source file should be compiled, and even if it is found
2350
several times in the aggregated projects it will be compiled only
2351
once.
2352
 
2353
Since there is no ambiguity as to which switches should be used, files
2354
can be compiled in parallel (through the usual -j switch) and this can
2355
be done while maximizing the use of CPUs (compared to launching
2356
multiple gprbuild and gnatmake commands in parallel).
2357
 
2358
@c -------------------------------------
2359
@node Syntax of aggregate projects
2360
@subsection Syntax of aggregate projects
2361
@c -------------------------------------
2362
 
2363
An aggregate project follows the general syntax of project files. The
2364
recommended extension is still @file{.gpr}. However, a special
2365
@code{aggregate} qualifier must be put before the keyword
2366
@code{project}.
2367
 
2368
An aggregate project cannot @code{with} any other project (standard or
2369
aggregate), except an abstract project which can be used to share
2370
attribute values. Building other aggregate projects from an aggregate
2371
project is done through the Project_Files attribute (see below).
2372
 
2373
An aggregate project does not have any source files directly (only
2374
through other standard projects). Therefore a number of the standard
2375
attributes and packages are forbidden in an aggregate project. Here is the
2376
(non exhaustive) list:
2377
 
2378
@itemize @bullet
2379
@item Languages
2380
@item Source_Files, Source_List_File and other attributes dealing with
2381
  list of sources.
2382
@item Source_Dirs, Exec_Dir and Object_Dir
2383
@item Library_Dir, Library_Name and other library-related attributes
2384
@item Main
2385
@item Roots
2386
@item Externally_Built
2387
@item Inherit_Source_Path
2388
@item Excluded_Source_Dirs
2389
@item Locally_Removed_Files
2390
@item Excluded_Source_Files
2391
@item Excluded_Source_List_File
2392
@item Interfaces
2393
@end itemize
2394
 
2395
The only package that is authorized (albeit optional) is
2396
Builder. Other packages (in particular Compiler, Binder and Linker)
2397
are forbidden. It is an error to have any of these
2398
(and such an error prevents the proper loading of the aggregate
2399
project).
2400
 
2401
Three new attributes have been created, which can only be used in the
2402
context of aggregate projects:
2403
 
2404
@table @asis
2405
@item @b{Project_Files}:
2406
@cindex @code{Project_Files}
2407
 
2408
This attribute is compulsory (or else we are not aggregating any project,
2409
and thus not doing anything). It specifies a list of @file{.gpr} files
2410
that are grouped in the aggregate. The list may be empty. The project
2411
files can be either other aggregate projects, or standard projects. When
2412
grouping standard projects, you can have both the root of a project tree
2413
(and you do not need to specify all its imported projects), and any project
2414
within the tree.
2415
 
2416
Basically, the idea is to specify all those projects that have
2417
main programs you want to build and link, or libraries you want to
2418
build. You can even specify projects that do not use the Main
2419
attribute nor the @code{Library_*} attributes, and the result will be to
2420
build all their source files (not just the ones needed by other
2421
projects).
2422
 
2423
The file can include paths (absolute or relative). Paths are
2424
relative to the location of the aggregate project file itself (if
2425
you use a base name, we expect to find the .gpr file in the same
2426
directory as the aggregate project file). The extension @file{.gpr} is
2427
mandatory, since this attribute contains file names, not project names.
2428
 
2429
Paths can also include the @code{"*"} and @code{"**"} globbing patterns. The
2430
latter indicates that any subdirectory (recursively) will be
2431
searched for matching files. The latter (@code{"**"}) can only occur at the
2432
last position in the directory part (ie @code{"a/**/*.gpr"} is supported, but
2433
not @code{"**/a/*.gpr"}). Starting the pattern with @code{"**"} is equivalent
2434
to starting with @code{"./**"}.
2435
 
2436
For now, the pattern @code{"*"} is only allowed in the filename part, not
2437
in the directory part. This is mostly for efficiency reasons to limit the
2438
number of system calls that are needed.
2439
 
2440
Here are a few valid examples:
2441
 
2442
@smallexample @c projectfile
2443
    for Project_Files use ("a.gpr", "subdir/b.gpr");
2444
    --  two specific projects relative to the directory of agg.gpr
2445
 
2446
    for Project_Files use ("**/*.gpr");
2447
    --  all projects recursively
2448
@end smallexample
2449
 
2450
@item @b{Project_Path}:
2451
@cindex @code{Project_Path}
2452
 
2453
This attribute can be used to specify a list of directories in
2454
which to look for project files in @code{with} statements.
2455
 
2456
When you specify a project in Project_Files
2457
say @code{"x/y/a.gpr"}), and this projects imports a project "b.gpr", only
2458
b.gpr is searched in the project path. a.gpr must be exactly at
2459
<dir of the aggregate>/x/y/a.gpr.
2460
 
2461
This attribute, however, does not affect the search for the aggregated
2462
project files specified with @code{Project_Files}.
2463
 
2464
Each aggregate project has its own (that is if agg1.gpr includes
2465
agg2.gpr, they can potentially both have a different project path).
2466
This project path is defined as the concatenation, in that order, of
2467
the current directory, followed by the command line -aP switches,
2468
then the directories from the Project_Path attribute, then the
2469
directories from the GPR_PROJECT_PATH and ADA_PROJECT_PATH env.
2470
variables, and finally the predefined directories.
2471
 
2472
In the example above, agg2.gpr's project path is not influenced by
2473
the attribute agg1'Project_Path, nor is agg1 influenced by
2474
agg2'Project_Path.
2475
 
2476
This can potentially lead to errors. In the following example:
2477
 
2478
@smallexample
2479
     +---------------+                  +----------------+
2480
     | Agg1.gpr      |-=--includes--=-->| Agg2.gpr       |
2481
     |  'project_path|                  |  'project_path |
2482
     |               |                  |                |
2483
     +---------------+                  +----------------+
2484
           :                                   :
2485
           includes                        includes
2486
           :                                   :
2487
           v                                   v
2488
       +-------+                          +---------+
2489
       | P.gpr |<---------- withs --------|  Q.gpr  |
2490
       +-------+---------\                +---------+
2491
           |             |
2492
           withs         |
2493
           |             |
2494
           v             v
2495
       +-------+      +---------+
2496
       | R.gpr |      | R'.gpr  |
2497
       +-------+      +---------+
2498
@end smallexample
2499
 
2500
When looking for p.gpr, both aggregates find the same physical file on
2501
the disk. However, it might happen that with their different project
2502
paths, both aggregate projects would in fact find a different r.gpr.
2503
Since we have a common project (p.gpr) "with"ing two different r.gpr,
2504
this will be reported as an error by the builder.
2505
 
2506
Directories are relative to the location of the aggregate project file.
2507
 
2508
Here are a few valid examples:
2509
 
2510
@smallexample @c projectfile
2511
   for Project_Path use ("/usr/local/gpr", "gpr/");
2512
@end smallexample
2513
 
2514
@item @b{External}:
2515
@cindex @code{External}
2516
 
2517
This attribute can be used to set the value of environment
2518
variables as retrieved through the @code{external} statement
2519
in projects. It does not affect the environment variables
2520
themselves (so for instance you cannot use it to change the value
2521
of your PATH as seen from the spawned compiler).
2522
 
2523
This attribute affects the external values as seen in the rest of
2524
the aggreate projects, and in the aggregated projects.
2525
 
2526
The exact value of external a variable comes from one of three
2527
sources (each level overrides the previous levels):
2528
 
2529
@itemize @bullet
2530
@item An External attribute in aggregate project, for instance
2531
    @code{for External ("BUILD_MODE") use "DEBUG"};
2532
 
2533
@item Environment variables
2534
 
2535
These override the value given by the attribute, so that
2536
users can override the value set in the (presumably shared
2537
with others in his team) aggregate project.
2538
 
2539
@item The -X command line switch to gprbuild and gnatmake
2540
 
2541
This always takes precedence.
2542
 
2543
@end itemize
2544
 
2545
This attribute is only taken into account in the main aggregate
2546
project (i.e. the one specified on the command line to gprbuild or
2547
natmake), and ignored in other aggregate projects. It is invalid
2548
in standard projects.
2549
The goal is to have a consistent value in all
2550
projects that are build through the aggregate, which would not
2551
be the case in the diamond case: A groups the aggregate
2552
projects B and C, which both (either directly or indirectly)
2553
build the project P. If B and C could set different values for
2554
the environment variables, we would have two different views of
2555
P, which in particular might impact the list of source files in P.
2556
 
2557
@end table
2558
 
2559
@c ----------------------------------------------
2560
@node package Builder in aggregate projects
2561
@subsection package Builder in aggregate projects
2562
@c ----------------------------------------------
2563
 
2564
As we mentioned before, only the package Builder can be specified in
2565
an aggregate project. In this package, only the following attributes
2566
are valid:
2567
 
2568
@table @asis
2569
@item @b{Switches}:
2570
@cindex @code{Switches}
2571
This attribute gives the list of switches to use for the builder
2572
(gprbuild or gnatmake), depending on the language of the main file.
2573
For instance,
2574
 
2575
@smallexample @c projectfile
2576
for Switches ("Ada") use ("-d", "-p");
2577
for Switches ("C")   use ("-p");
2578
@end smallexample
2579
 
2580
These switches are only read from the main aggregate project (the
2581
one passed on the command line), and ignored in all other aggregate
2582
projects or projects.
2583
 
2584
It can only contain builder switches, not compiler switches.
2585
 
2586
@item @b{Global_Compilation_Switches}
2587
@cindex @code{Global_Compilation_Switches}
2588
 
2589
This attribute gives the list of compiler switches for the various
2590
languages. For instance,
2591
 
2592
@smallexample @c projectfile
2593
for Global_Compilation_Switches ("Ada") use ("-O1", "-g");
2594
for Global_Compilation_Switches ("C")   use ("-O2");
2595
@end smallexample
2596
 
2597
This attribute is only taken into account in the aggregate project
2598
specified on the command line, not in other aggregate projects.
2599
 
2600
In the projects grouped by that aggregate, the attribute
2601
Builder.Global_Compilation_Switches is also ignored. However, the
2602
attribute Compiler.Default_Switches will be taken into account (but
2603
that of the aggregate have higher priority). The attribute
2604
Compiler.Switches is also taken into account and can be used to
2605
override the switches for a specific file. As a result, it always
2606
has priority.
2607
 
2608
The rules are meant to avoid ambiguities when compiling. For
2609
instance, aggregate project Agg groups the projects A and B, that
2610
both depend on C. Here is an extra for all of these projects:
2611
 
2612
@smallexample @c projectfile
2613
      aggregate project Agg is
2614
          for Project_Files use ("a.gpr", "b.gpr");
2615
          package Builder is
2616
             for Global_Compilation_Switches ("Ada") use ("-O2");
2617
          end Builder;
2618
      end Agg;
2619
 
2620
      with "c.gpr";
2621
      project A is
2622
          package Builder is
2623
             for Global_Compilation_Switches ("Ada") use ("-O1");
2624
             --  ignored
2625
          end Builder;
2626
 
2627
          package Compiler is
2628
             for Default_Switches ("Ada") use ("-O1", "-g");
2629
             for Switches ("a_file1.adb") use ("-O0");
2630
          end Compiler;
2631
      end A;
2632
 
2633
      with "c.gpr";
2634
      project B is
2635
          package Compiler is
2636
             for Default_Switches ("Ada") use ("-O0");
2637
          end Compiler;
2638
      end B;
2639
 
2640
      project C is
2641
          package Compiler is
2642
             for Default_Switches ("Ada") use ("-O3", "-gnatn");
2643
             for Switches ("c_file1.adb") use ("-O0", "-g");
2644
          end Compiler;
2645
      end C;
2646
@end smallexample
2647
 
2648
then the following switches are used:
2649
 
2650
@itemize @bullet
2651
@item all files from project A except a_file1.adb are compiled
2652
      with "-O2 -g", since the aggregate project has priority.
2653
@item the file a_file1.adb is compiled with
2654
      "-O0", since the Compiler.Switches has priority
2655
@item all files from project B are compiled with
2656
      "-O2", since the aggregate project has priority
2657
@item all files from C are compiled with "-O2 -gnatn", except for
2658
      c_file1.adb which is compiled with "-O0 -g"
2659
@end itemize
2660
 
2661
Even though C is seen through two paths (through A and through
2662
B), the switches used by the compiler are unambiguous.
2663
 
2664
@item @b{Global_Configuration_Pragmas}
2665
@cindex @code{Global_Configuration_Pragmas}
2666
 
2667
This attribute can be used to specify a file containing
2668
configuration pragmas, to be passed to the compiler.  Since we
2669
ignore the package Builder in other aggregate projects and projects,
2670
only those pragmas defined in the main aggregate project will be
2671
taken into account.
2672
 
2673
Projects can locally add to those by using the
2674
@code{Compiler.Local_Configuration_Pragmas} attribute if they need.
2675
 
2676
@end table
2677
 
2678
For projects that are build through the aggregate, the package Builder
2679
is ignored, except for the Executable attribute which specifies the
2680
name of the executables resulting from the link of the main programs, and
2681
for the Executable_Suffix.
2682
 
2683
@c ---------------------------------------------
2684
@node Aggregate Library Projects
2685
@section Aggregate Library Projects
2686
@c ---------------------------------------------
2687
 
2688
@noindent
2689
 
2690
Aggregate library projects make it possible to build a single library
2691
using object files built using other standard or library
2692
projects. This gives the flexibility to describe an application as
2693
having multiple modules (a GUI, database access, ...) using different
2694
project files (so possibly built with different compiler options) and
2695
yet create a single library (static or relocatable) out of the
2696
corresponding object files.
2697
 
2698
@menu
2699
* Building aggregate library projects::
2700
* Syntax of aggregate library projects::
2701
@end menu
2702
 
2703
@c ---------------------------------------------
2704
@node Building aggregate library projects
2705
@subsection Building aggregate library projects
2706
@c ---------------------------------------------
2707
 
2708
For example, we can define an aggregate project Agg that groups A, B
2709
and C:
2710
 
2711
@smallexample @c projectfile
2712
   aggregate library project Agg is
2713
      for Project_Files use ("a.gpr", "b.gpr", "c.gpr");
2714
      for Library_Name use ("agg");
2715
      for Library_Dir use ("lagg");
2716
   end Agg;
2717
@end smallexample
2718
 
2719
Then, when you build with:
2720
 
2721
@smallexample
2722
    gprbuild agg.gpr
2723
@end smallexample
2724
 
2725
This will build all units from projects A, B and C and will create a
2726
static library named @file{libagg.a} into the @file{lagg}
2727
directory. An aggregate library project has the same set of
2728
restriction as a standard library project.
2729
 
2730
Note that a shared aggregate library project cannot aggregates a
2731
static library project. In platforms where a compiler option is
2732
required to create relocatable object files, a Builder package in the
2733
aggregate library project may be used:
2734
 
2735
@smallexample @c projectfile
2736
   aggregate library project Agg is
2737
      for Project_Files use ("a.gpr", "b.gpr", "c.gpr");
2738
      for Library_Name use ("agg");
2739
      for Library_Dir use ("lagg");
2740
      for Library_Kind use "relocatable";
2741
 
2742
      package Builder is
2743
         for Global_Compilation_Switches ("Ada") use ("-fPIC");
2744
      end Builder;
2745
   end Agg;
2746
@end smallexample
2747
 
2748
With the above aggregate library Builder package, the @code{-fPIC}
2749
option will be passed to the compiler when building any source code
2750
from projects @file{a.gpr}, @file{b.gpr} and @file{c.gpr}.
2751
 
2752
@c ---------------------------------------------
2753
@node Syntax of aggregate library projects
2754
@subsection Syntax of aggregate library projects
2755
@c ---------------------------------------------
2756
 
2757
An aggregate library project follows the general syntax of project
2758
files. The recommended extension is still @file{.gpr}. However, a special
2759
@code{aggregate library} qualifier must be put before the keyword
2760
@code{project}.
2761
 
2762
An aggregate library project cannot @code{with} any other project
2763
(standard or aggregate), except an abstract project which can be used
2764
to share attribute values.
2765
 
2766
An aggregate library project does not have any source files directly (only
2767
through other standard projects). Therefore a number of the standard
2768
attributes and packages are forbidden in an aggregate library
2769
project. Here is the (non exhaustive) list:
2770
 
2771
@itemize @bullet
2772
@item Languages
2773
@item Source_Files, Source_List_File and other attributes dealing with
2774
  list of sources.
2775
@item Source_Dirs, Exec_Dir and Object_Dir
2776
@item Main
2777
@item Roots
2778
@item Externally_Built
2779
@item Inherit_Source_Path
2780
@item Excluded_Source_Dirs
2781
@item Locally_Removed_Files
2782
@item Excluded_Source_Files
2783
@item Excluded_Source_List_File
2784
@item Interfaces
2785
@end itemize
2786
 
2787
The only package that is authorized (albeit optional) is Builder.
2788
 
2789
The Project_Files attribute (See @pxref{Aggregate Projects}) is used to
2790
described the aggregated projects whose object files have to be
2791
included into the aggregate library.
2792
 
2793
@c ---------------------------------------------
2794
@node Project File Reference
2795
@section Project File Reference
2796
@c ---------------------------------------------
2797
 
2798
@noindent
2799
This section describes the syntactic structure of project files, the various
2800
constructs that can be used. Finally, it ends with a summary of all available
2801
attributes.
2802
 
2803
@menu
2804
* Project Declaration::
2805
* Qualified Projects::
2806
* Declarations::
2807
* Packages::
2808
* Expressions::
2809
* External Values::
2810
* Typed String Declaration::
2811
* Variables::
2812
* Attributes::
2813
* Case Statements::
2814
@end menu
2815
 
2816
@c ---------------------------------------------
2817
@node Project Declaration
2818
@subsection Project Declaration
2819
@c ---------------------------------------------
2820
 
2821
@noindent
2822
Project files have an Ada-like syntax. The minimal project file is:
2823
 
2824
@smallexample @c projectfile
2825
@group
2826
project Empty is
2827
end Empty;
2828
@end group
2829
@end smallexample
2830
 
2831
@noindent
2832
The identifier @code{Empty} is the name of the project.
2833
This project name must be present after the reserved
2834
word @code{end} at the end of the project file, followed by a semi-colon.
2835
 
2836
@b{Identifiers} (i.e.@: the user-defined names such as project or variable names)
2837
have the same syntax as Ada identifiers: they must start with a letter,
2838
and be followed by zero or more letters, digits or underscore characters;
2839
it is also illegal to have two underscores next to each other. Identifiers
2840
are always case-insensitive ("Name" is the same as "name").
2841
 
2842
@smallexample
2843
simple_name ::= identifier
2844
name        ::= simple_name @{ . simple_name @}
2845
@end smallexample
2846
 
2847
@noindent
2848
@b{Strings} are used for values of attributes or as indexes for these
2849
attributes. They are in general case sensitive, except when noted
2850
otherwise (in particular, strings representing file names will be case
2851
insensitive on some systems, so that "file.adb" and "File.adb" both
2852
represent the same file).
2853
 
2854
@b{Reserved words} are the same as for standard Ada 95, and cannot
2855
be used for identifiers. In particular, the following words are currently
2856
used in project files, but others could be added later on. In bold are the
2857
extra reserved words in project files: @code{all, at, case, end, for, is,
2858
limited, null, others, package, renames, type, use, when, with, @b{extends},
2859
@b{external}, @b{project}}.
2860
 
2861
@b{Comments} in project files have the same syntax as in Ada, two consecutive
2862
hyphens through the end of the line.
2863
 
2864
A project may be an @b{independent project}, entirely defined by a single
2865
project file. Any source file in an independent project depends only
2866
on the predefined library and other source files in the same project.
2867
But a project may also depend on other projects, either by importing them
2868
through @b{with clauses}, or by @b{extending} at most one other project. Both
2869
types of dependency can be used in the same project.
2870
 
2871
A path name denotes a project file. It can be absolute or relative.
2872
An absolute path name includes a sequence of directories, in the syntax of
2873
the host operating system, that identifies uniquely the project file in the
2874
file system. A relative path name identifies the project file, relative
2875
to the directory that contains the current project, or relative to a
2876
directory listed in the environment variables ADA_PROJECT_PATH and
2877
GPR_PROJECT_PATH. Path names are case sensitive if file names in the host
2878
operating system are case sensitive. As a special case, the directory
2879
separator can always be "/" even on Windows systems, so that project files
2880
can be made portable across architectures.
2881
The syntax of the environment variable ADA_PROJECT_PATH and
2882
GPR_PROJECT_PATH is a list of directory names separated by colons on UNIX and
2883
semicolons on Windows.
2884
 
2885
A given project name can appear only once in a context clause.
2886
 
2887
It is illegal for a project imported by a context clause to refer, directly
2888
or indirectly, to the project in which this context clause appears (the
2889
dependency graph cannot contain cycles), except when one of the with clause
2890
in the cycle is a @b{limited with}.
2891
@c ??? Need more details here
2892
 
2893
@smallexample @c projectfile
2894
with "other_project.gpr";
2895
project My_Project extends "extended.gpr" is
2896
end My_Project;
2897
@end smallexample
2898
 
2899
@noindent
2900
These dependencies form a @b{directed graph}, potentially cyclic when using
2901
@b{limited with}. The subprogram reflecting the @b{extends} relations is a
2902
tree.
2903
 
2904
A project's @b{immediate sources} are the source files directly defined by
2905
that project, either implicitly by residing in the project source directories,
2906
or explicitly through any of the source-related attributes.
2907
More generally, a project sources are the immediate sources of the project
2908
together with the immediate sources (unless overridden) of any
2909
project on which it depends directly or indirectly.
2910
 
2911
A @b{project hierarchy} can be created, where projects are children of
2912
other projects. The name of such a child project must be @code{Parent.Child},
2913
where @code{Parent} is the name of the parent project. In particular, this
2914
makes all @code{with} clauses of the parent project automatically visible
2915
in the child project.
2916
 
2917
@smallexample
2918
project        ::= context_clause project_declaration
2919
 
2920
context_clause ::= @{with_clause@}
2921
with_clause    ::= @i{with} path_name @{ , path_name @} ;
2922
path_name      ::= string_literal
2923
 
2924
project_declaration ::= simple_project_declaration | project_extension
2925
simple_project_declaration ::=
2926
  @i{project} @i{<project_>}name @i{is}
2927
    @{declarative_item@}
2928
  @i{end} <project_>simple_name;
2929
@end smallexample
2930
 
2931
@c ---------------------------------------------
2932
@node Qualified Projects
2933
@subsection Qualified Projects
2934
@c ---------------------------------------------
2935
 
2936
@noindent
2937
Before the reserved @code{project}, there may be one or two @b{qualifiers}, that
2938
is identifiers or reserved words, to qualify the project.
2939
The current list of qualifiers is:
2940
 
2941
@table @asis
2942
@item @b{abstract}: qualifies a project with no sources. Such a
2943
  project must either have no declaration of attributes @code{Source_Dirs},
2944
  @code{Source_Files}, @code{Languages} or @code{Source_List_File}, or one of
2945
  @code{Source_Dirs}, @code{Source_Files}, or @code{Languages} must be declared
2946
  as empty. If it extends another project, the project it extends must also be a
2947
  qualified abstract project.
2948
@item @b{standard}: a standard project is a non library project with sources.
2949
  This is the default (implicit) qualifier.
2950
@item @b{aggregate}: a project whose sources are aggregated from other
2951
project files.
2952
@item @b{aggregate library}: a library whose sources are aggregated
2953
from other project or library project files.
2954
@item @b{library}: a library project must declare both attributes
2955
  @code{Library_Name} and @code{Library_Dir}.
2956
@item @b{configuration}: a configuration project cannot be in a project tree.
2957
  It describes compilers and other tools to @code{gprbuild}.
2958
@end table
2959
 
2960
@c ---------------------------------------------
2961
@node Declarations
2962
@subsection Declarations
2963
@c ---------------------------------------------
2964
 
2965
@noindent
2966
Declarations introduce new entities that denote types, variables, attributes,
2967
and packages. Some declarations can only appear immediately within a project
2968
declaration. Others can appear within a project or within a package.
2969
 
2970
@smallexample
2971
declarative_item ::= simple_declarative_item
2972
  | typed_string_declaration
2973
  | package_declaration
2974
 
2975
simple_declarative_item ::= variable_declaration
2976
  | typed_variable_declaration
2977
  | attribute_declaration
2978
  | case_construction
2979
  | empty_declaration
2980
 
2981
empty_declaration ::= @i{null} ;
2982
@end smallexample
2983
 
2984
@noindent
2985
An empty declaration is allowed anywhere a declaration is allowed. It has
2986
no effect.
2987
 
2988
@c ---------------------------------------------
2989
@node Packages
2990
@subsection Packages
2991
@c ---------------------------------------------
2992
 
2993
@noindent
2994
A project file may contain @b{packages}, that group attributes (typically
2995
all the attributes that are used by one of the GNAT tools).
2996
 
2997
A package with a given name may only appear once in a project file.
2998
The following packages are currently supported in project files
2999
(See @pxref{Attributes} for the list of attributes that each can contain).
3000
 
3001
@table @code
3002
@item Binder
3003
  This package specifies characteristics useful when invoking the binder either
3004
  directly via the @command{gnat} driver or when using a builder such as
3005
  @command{gnatmake} or @command{gprbuild}. @xref{Main Subprograms}.
3006
@item Builder
3007
  This package specifies the compilation options used when building an
3008
  executable or a library for a project. Most of the options should be
3009
  set in one of @code{Compiler}, @code{Binder} or @code{Linker} packages,
3010
  but there are some general options that should be defined in this
3011
  package. @xref{Main Subprograms}, and @pxref{Executable File Names} in
3012
  particular.
3013
@item Check
3014
  This package specifies the options used when calling the checking tool
3015
  @command{gnatcheck} via the @command{gnat} driver. Its attribute
3016
  @b{Default_Switches} has the same semantics as for the package
3017
  @code{Builder}. The first string should always be @code{-rules} to specify
3018
  that all the other options belong to the @code{-rules} section of the
3019
  parameters to @command{gnatcheck}.
3020
@item Compiler
3021
  This package specifies the compilation options used by the compiler for
3022
  each languages. @xref{Tools Options in Project Files}.
3023
@item Cross_Reference
3024
  This package specifies the options used when calling the library tool
3025
  @command{gnatxref} via the @command{gnat} driver. Its attributes
3026
  @b{Default_Switches} and @b{Switches} have the same semantics as for the
3027
  package @code{Builder}.
3028
@item Eliminate
3029
  This package specifies the options used when calling the tool
3030
  @command{gnatelim} via the @command{gnat} driver. Its attributes
3031
  @b{Default_Switches} and @b{Switches} have the same semantics as for the
3032
  package @code{Builder}.
3033
@item Finder
3034
  This package specifies the options used when calling the search tool
3035
  @command{gnatfind} via the @command{gnat} driver. Its attributes
3036
  @b{Default_Switches} and @b{Switches} have the same semantics as for the
3037
  package @code{Builder}.
3038
@item Gnatls
3039
  This package the options to use when invoking @command{gnatls} via the
3040
  @command{gnat} driver.
3041
@item Gnatstub
3042
  This package specifies the options used when calling the tool
3043
  @command{gnatstub} via the @command{gnat} driver. Its attributes
3044
  @b{Default_Switches} and @b{Switches} have the same semantics as for the
3045
  package @code{Builder}.
3046
@item IDE
3047
  This package specifies the options used when starting an integrated
3048
  development environment, for instance @command{GPS} or @command{Gnatbench}.
3049
  @xref{The Development Environments}.
3050
@item Linker
3051
  This package specifies the options used by the linker.
3052
  @xref{Main Subprograms}.
3053
@item Makefile
3054
@cindex Makefile package in projects
3055
  This package is used by the GPS plugin Makefile.py. See the documentation
3056
  in that plugin (from GPS: /Tools/Plug-ins).
3057
@item Metrics
3058
  This package specifies the options used when calling the tool
3059
  @command{gnatmetric} via the @command{gnat} driver. Its attributes
3060
  @b{Default_Switches} and @b{Switches} have the same semantics as for the
3061
  package @code{Builder}.
3062
@item Naming
3063
  This package specifies the naming conventions that apply
3064
  to the source files in a project. In particular, these conventions are
3065
  used to automatically find all source files in the source directories,
3066
  or given a file name to find out its language for proper processing.
3067
  @xref{Naming Schemes}.
3068
@item Pretty_Printer
3069
  This package specifies the options used when calling the formatting tool
3070
  @command{gnatpp} via the @command{gnat} driver. Its attributes
3071
  @b{Default_Switches} and @b{Switches} have the same semantics as for the
3072
  package @code{Builder}.
3073
@item Stack
3074
  This package specifies the options used when calling the tool
3075
  @command{gnatstack} via the @command{gnat} driver. Its attributes
3076
  @b{Default_Switches} and @b{Switches} have the same semantics as for the
3077
  package @code{Builder}.
3078
@item Synchronize
3079
  This package specifies the options used when calling the tool
3080
  @command{gnatsync} via the @command{gnat} driver.
3081
 
3082
@end table
3083
 
3084
In its simplest form, a package may be empty:
3085
 
3086
@smallexample @c projectfile
3087
@group
3088
project Simple is
3089
  package Builder is
3090
  end Builder;
3091
end Simple;
3092
@end group
3093
@end smallexample
3094
 
3095
@noindent
3096
A package may contain @b{attribute declarations},
3097
@b{variable declarations} and @b{case constructions}, as will be
3098
described below.
3099
 
3100
When there is ambiguity between a project name and a package name,
3101
the name always designates the project. To avoid possible confusion, it is
3102
always a good idea to avoid naming a project with one of the
3103
names allowed for packages or any name that starts with @code{gnat}.
3104
 
3105
A package can also be defined by a @b{renaming declaration}. The new package
3106
renames a package declared in a different project file, and has the same
3107
attributes as the package it renames. The name of the renamed package
3108
must be the same as the name of the renaming package. The project must
3109
contain a package declaration with this name, and the project
3110
must appear in the context clause of the current project, or be its parent
3111
project. It is not possible to add or override attributes to the renaming
3112
project. If you need to do so, you should use an @b{extending declaration}
3113
(see below).
3114
 
3115
Packages that are renamed in other project files often come from project files
3116
that have no sources: they are just used as templates. Any modification in the
3117
template will be reflected automatically in all the project files that rename
3118
a package from the template. This is a very common way to share settings
3119
between projects.
3120
 
3121
Finally, a package can also be defined by an @b{extending declaration}. This is
3122
similar to a @b{renaming declaration}, except that it is possible to add or
3123
override attributes.
3124
 
3125
@smallexample
3126
package_declaration ::= package_spec | package_renaming | package_extension
3127
package_spec ::=
3128
  @i{package} @i{<package_>}simple_name @i{is}
3129
    @{simple_declarative_item@}
3130
  @i{end} package_identifier ;
3131
package_renaming ::==
3132
  @i{package} @i{<package_>}simple_name @i{renames} @i{<project_>}simple_name.package_identifier ;
3133
package_extension ::==
3134
  @i{package} @i{<package_>}simple_name @i{extends} @i{<project_>}simple_name.package_identifier @i{is}
3135
    @{simple_declarative_item@}
3136
  @i{end} package_identifier ;
3137
@end smallexample
3138
 
3139
@c ---------------------------------------------
3140
@node Expressions
3141
@subsection Expressions
3142
@c ---------------------------------------------
3143
 
3144
@noindent
3145
An expression is any value that can be assigned to an attribute or a
3146
variable. It is either a literal value, or a construct requiring runtime
3147
computation by the project manager. In a project file, the computed value of
3148
an expression is either a string or a list of strings.
3149
 
3150
A string value is one of:
3151
@itemize @bullet
3152
@item A literal string, for instance @code{"comm/my_proj.gpr"}
3153
@item The name of a variable that evaluates to a string (@pxref{Variables})
3154
@item The name of an attribute that evaluates to a string (@pxref{Attributes})
3155
@item An external reference (@pxref{External Values})
3156
@item A concatenation of the above, as in @code{"prefix_" & Var}.
3157
 
3158
@end itemize
3159
 
3160
@noindent
3161
A list of strings is one of the following:
3162
 
3163
@itemize @bullet
3164
@item A parenthesized comma-separated list of zero or more string expressions, for
3165
  instance @code{(File_Name, "gnat.adc", File_Name & ".orig")} or @code{()}.
3166
@item The name of a variable that evaluates to a list of strings
3167
@item The name of an attribute that evaluates to a list of strings
3168
@item A concatenation of a list of strings and a string (as defined above), for
3169
  instance @code{("A", "B") & "C"}
3170
@item A concatenation of two lists of strings
3171
 
3172
@end itemize
3173
 
3174
@noindent
3175
The following is the grammar for expressions
3176
 
3177
@smallexample
3178
string_literal ::= "@{string_element@}"  --  Same as Ada
3179
string_expression ::= string_literal
3180
    | @i{variable_}name
3181
    | external_value
3182
    | attribute_reference
3183
    | ( string_expression @{ & string_expression @} )
3184
string_list  ::= ( string_expression @{ , string_expression @} )
3185
   | @i{string_variable}_name
3186
   | @i{string_}attribute_reference
3187
term ::= string_expression | string_list
3188
expression ::= term @{ & term @}     --  Concatenation
3189
@end smallexample
3190
 
3191
@noindent
3192
Concatenation involves strings and list of strings. As soon as a list of
3193
strings is involved, the result of the concatenation is a list of strings. The
3194
following Ada declarations show the existing operators:
3195
 
3196
@smallexample @c ada
3197
  function "&" (X : String;      Y : String)      return String;
3198
  function "&" (X : String_List; Y : String)      return String_List;
3199
  function "&" (X : String_List; Y : String_List) return String_List;
3200
@end smallexample
3201
 
3202
@noindent
3203
Here are some specific examples:
3204
 
3205
@smallexample @c projectfile
3206
@group
3207
   List := () & File_Name; --  One string in this list
3208
   List2 := List & (File_Name & ".orig"); -- Two strings
3209
   Big_List := List & Lists2;  --  Three strings
3210
   Illegal := "gnat.adc" & List2;  --  Illegal, must start with list
3211
@end group
3212
@end smallexample
3213
 
3214
@c ---------------------------------------------
3215
@node External Values
3216
@subsection External Values
3217
@c ---------------------------------------------
3218
 
3219
@noindent
3220
An external value is an expression whose value is obtained from the command
3221
that invoked the processing of the current project file (typically a
3222
gnatmake or gprbuild command).
3223
 
3224
There are two kinds of external values, one that returns a single string, and
3225
one that returns a string list.
3226
 
3227
The syntax of a single string external value is:
3228
 
3229
@smallexample
3230
external_value ::= @i{external} ( string_literal [, string_literal] )
3231
@end smallexample
3232
 
3233
@noindent
3234
The first string_literal is the string to be used on the command line or
3235
in the environment to specify the external value. The second string_literal,
3236
if present, is the default to use if there is no specification for this
3237
external value either on the command line or in the environment.
3238
 
3239
Typically, the external value will either exist in the
3240
^environment variables^logical name^
3241
or be specified on the command line through the
3242
@option{^-X^/EXTERNAL_REFERENCE=^@emph{vbl}=@emph{value}} switch. If both
3243
are specified, then the command line value is used, so that a user can more
3244
easily override the value.
3245
 
3246
The function @code{external} always returns a string. It is an error if the
3247
value was not found in the environment and no default was specified in the
3248
call to @code{external}.
3249
 
3250
An external reference may be part of a string expression or of a string
3251
list expression, and can therefore appear in a variable declaration or
3252
an attribute declaration.
3253
 
3254
Most of the time, this construct is used to initialize typed variables, which
3255
are then used in @b{case} statements to control the value assigned to
3256
attributes in various scenarios. Thus such variables are often called
3257
@b{scenario variables}.
3258
 
3259
The syntax for a string list external value is:
3260
 
3261
@smallexample
3262
external_value ::= @i{external_as_list} ( string_literal , string_literal )
3263
@end smallexample
3264
 
3265
@noindent
3266
The first string_literal is the string to be used on the command line or
3267
in the environment to specify the external value. The second string_literal is
3268
the separator between each component of the string list.
3269
 
3270
If the external value does not exist in the environment or on the command line,
3271
the result is an empty list. This is also the case, if the separator is an
3272
empty string or if the external value is only one separator.
3273
 
3274
Any separator at the beginning or at the end of the external value is
3275
discarded. Then, if there is no separator in the external value, the result is
3276
a string list with only one string. Otherwise, any string between the beginning
3277
and the first separator, between two consecutive separators and between the
3278
last separator and the end are components of the string list.
3279
 
3280
@smallexample
3281
   @i{external_as_list} ("SWITCHES", ",")
3282
@end smallexample
3283
 
3284
@noindent
3285
If the external value is "-O2,-g", the result is ("-O2", "-g").
3286
 
3287
If the external value is ",-O2,-g,", the result is also ("-O2", "-g").
3288
 
3289
if the external value is "-gnav", the result is ("-gnatv").
3290
 
3291
If the external value is ",,", the result is ("").
3292
 
3293
If the external value is ",", the result is (), the empty string list.
3294
 
3295
@c ---------------------------------------------
3296
@node Typed String Declaration
3297
@subsection Typed String Declaration
3298
@c ---------------------------------------------
3299
 
3300
@noindent
3301
A @b{type declaration} introduces a discrete set of string literals.
3302
If a string variable is declared to have this type, its value
3303
is restricted to the given set of literals. These are the only named
3304
types in project files. A string type may only be declared at the project
3305
level, not inside a package.
3306
 
3307
@smallexample
3308
typed_string_declaration ::=
3309
  @i{type} @i{<typed_string_>}_simple_name @i{is} ( string_literal @{, string_literal@} );
3310
@end smallexample
3311
 
3312
@noindent
3313
The string literals in the list are case sensitive and must all be different.
3314
They may include any graphic characters allowed in Ada, including spaces.
3315
Here is an example of a string type declaration:
3316
 
3317
@smallexample @c projectfile
3318
   type OS is ("NT", "nt", "Unix", "GNU/Linux", "other OS");
3319
@end smallexample
3320
 
3321
@noindent
3322
Variables of a string type are called @b{typed variables}; all other
3323
variables are called @b{untyped variables}. Typed variables are
3324
particularly useful in @code{case} constructions, to support conditional
3325
attribute declarations. (@pxref{Case Statements}).
3326
 
3327
A string type may be referenced by its name if it has been declared in the same
3328
project file, or by an expanded name whose prefix is the name of the project
3329
in which it is declared.
3330
 
3331
@c ---------------------------------------------
3332
@node Variables
3333
@subsection Variables
3334
@c ---------------------------------------------
3335
 
3336
@noindent
3337
@b{Variables} store values (strings or list of strings) and can appear
3338
as part of an expression. The declaration of a variable creates the
3339
variable and assigns the value of the expression to it. The name of the
3340
variable is available immediately after the assignment symbol, if you
3341
need to reuse its old value to compute the new value. Before the completion
3342
of its first declaration, the value of a variable defaults to the empty
3343
string ("").
3344
 
3345
A @b{typed} variable can be used as part of a @b{case} expression to
3346
compute the value, but it can only be declared once in the project file,
3347
so that all case statements see the same value for the variable. This
3348
provides more consistency and makes the project easier to understand.
3349
The syntax for its declaration is identical to the Ada syntax for an
3350
object declaration. In effect, a typed variable acts as a constant.
3351
 
3352
An @b{untyped} variable can be declared and overridden multiple times
3353
within the same project. It is declared implicitly through an Ada
3354
assignment. The first declaration establishes the kind of the variable
3355
(string or list of strings) and successive declarations must respect
3356
the initial kind. Assignments are executed in the order in which they
3357
appear, so the new value replaces the old one and any subsequent reference
3358
to the variable uses the new value.
3359
 
3360
A variable may be declared at the project file level, or within a package.
3361
 
3362
@smallexample
3363
typed_variable_declaration ::=
3364
  @i{<typed_variable_>}simple_name : @i{<typed_string_>}name := string_expression;
3365
variable_declaration ::= @i{<variable_>}simple_name := expression;
3366
@end smallexample
3367
 
3368
@noindent
3369
Here are some examples of variable declarations:
3370
 
3371
@smallexample @c projectfile
3372
@group
3373
   This_OS : OS := external ("OS"); --  a typed variable declaration
3374
   That_OS := "GNU/Linux";          --  an untyped variable declaration
3375
 
3376
   Name      := "readme.txt";
3377
   Save_Name := Name & ".saved";
3378
 
3379
   Empty_List := ();
3380
   List_With_One_Element := ("-gnaty");
3381
   List_With_Two_Elements := List_With_One_Element & "-gnatg";
3382
   Long_List := ("main.ada", "pack1_.ada", "pack1.ada", "pack2_.ada");
3383
@end group
3384
@end smallexample
3385
 
3386
@noindent
3387
A @b{variable reference} may take several forms:
3388
 
3389
@itemize @bullet
3390
@item The simple variable name, for a variable in the current package (if any)
3391
  or in the current project
3392
@item An expanded name, whose prefix is a context name.
3393
 
3394
@end itemize
3395
 
3396
@noindent
3397
A @b{context} may be one of the following:
3398
 
3399
@itemize @bullet
3400
@item The name of an existing package in the current project
3401
@item The name of an imported project of the current project
3402
@item The name of an ancestor project (i.e., a project extended by the current
3403
  project, either directly or indirectly)
3404
@item An expanded name whose prefix is an imported/parent project name, and
3405
  whose selector is a package name in that project.
3406
@end itemize
3407
 
3408
@c ---------------------------------------------
3409
@node Attributes
3410
@subsection Attributes
3411
@c ---------------------------------------------
3412
 
3413
@noindent
3414
A project (and its packages) may have @b{attributes} that define
3415
the project's properties.  Some attributes have values that are strings;
3416
others have values that are string lists.
3417
 
3418
@smallexample
3419
attribute_declaration ::=
3420
   simple_attribute_declaration | indexed_attribute_declaration
3421
simple_attribute_declaration ::= @i{for} attribute_designator @i{use} expression ;
3422
indexed_attribute_declaration ::=
3423
  @i{for} @i{<indexed_attribute_>}simple_name ( string_literal) @i{use} expression ;
3424
attribute_designator ::=
3425
  @i{<simple_attribute_>}simple_name
3426
  | @i{<indexed_attribute_>}simple_name ( string_literal )
3427
@end smallexample
3428
 
3429
@noindent
3430
There are two categories of attributes: @b{simple attributes}
3431
and @b{indexed attributes}.
3432
Each simple attribute has a default value: the empty string (for string
3433
attributes) and the empty list (for string list attributes).
3434
An attribute declaration defines a new value for an attribute, and overrides
3435
the previous value. The syntax of a simple attribute declaration is similar to
3436
that of an attribute definition clause in Ada.
3437
 
3438
Some attributes are indexed. These attributes are mappings whose
3439
domain is a set of strings. They are declared one association
3440
at a time, by specifying a point in the domain and the corresponding image
3441
of the attribute.
3442
Like untyped variables and simple attributes, indexed attributes
3443
may be declared several times. Each declaration supplies a new value for the
3444
attribute, and replaces the previous setting.
3445
 
3446
Here are some examples of attribute declarations:
3447
 
3448
@smallexample @c projectfile
3449
   --  simple attributes
3450
   for Object_Dir use "objects";
3451
   for Source_Dirs use ("units", "test/drivers");
3452
 
3453
   --  indexed attributes
3454
   for Body ("main") use "Main.ada";
3455
   for Switches ("main.ada") use ("-v", "-gnatv");
3456
   for Switches ("main.ada") use Builder'Switches ("main.ada") & "-g";
3457
 
3458
   --  indexed attributes copy (from package Builder in project Default)
3459
   --  The package name must always be specified, even if it is the current
3460
   --  package.
3461
   for Default_Switches use Default.Builder'Default_Switches;
3462
@end smallexample
3463
 
3464
@noindent
3465
Attributes references may be appear anywhere in expressions, and are used
3466
to retrieve the value previously assigned to the attribute. If an attribute
3467
has not been set in a given package or project, its value defaults to the
3468
empty string or the empty list.
3469
 
3470
@smallexample
3471
attribute_reference ::= attribute_prefix ' @i{<simple_attribute>_}simple_name [ (string_literal) ]
3472
attribute_prefix ::= @i{project}
3473
  | @i{<project_>}simple_name
3474
  | package_identifier
3475
  | @i{<project_>}simple_name . package_identifier
3476
@end smallexample
3477
 
3478
@noindent
3479
Examples are:
3480
 
3481
@smallexample @c projectfile
3482
  project'Object_Dir
3483
  Naming'Dot_Replacement
3484
  Imported_Project'Source_Dirs
3485
  Imported_Project.Naming'Casing
3486
  Builder'Default_Switches ("Ada")
3487
@end smallexample
3488
 
3489
@noindent
3490
The prefix of an attribute may be:
3491
 
3492
@itemize @bullet
3493
@item @code{project} for an attribute of the current project
3494
@item The name of an existing package of the current project
3495
@item The name of an imported project
3496
@item The name of a parent project that is extended by the current project
3497
@item An expanded name whose prefix is imported/parent project name,
3498
  and whose selector is a package name
3499
 
3500
@end itemize
3501
 
3502
@noindent
3503
Legal attribute names are listed below, including the package in
3504
which they must be declared. These names are case-insensitive. The
3505
semantics for the attributes is explained in great details in other sections.
3506
 
3507
The column @emph{index} indicates whether the attribute is an indexed attribute,
3508
and when it is whether its index is case sensitive (sensitive) or not (insensitive), or if case sensitivity depends is the same as file names sensitivity on the
3509
system (file). The text is between brackets ([]) if the index is optional.
3510
 
3511
@multitable @columnfractions .3 .1 .2 .4
3512
@headitem Attribute Name @tab Value @tab Package @tab Index
3513
@headitem General attributes @tab @tab @tab @pxref{Building With Projects}
3514
@item Name @tab string @tab - @tab (Read-only, name of project)
3515
@item Project_Dir @tab string @tab - @tab (Read-only, directory of project)
3516
@item Source_Files @tab list @tab - @tab -
3517
@item Source_Dirs  @tab list @tab - @tab -
3518
@item Source_List_File @tab string @tab - @tab -
3519
@item Locally_Removed_Files @tab list @tab - @tab -
3520
@item Excluded_Source_Files @tab list @tab - @tab -
3521
@item Object_Dir   @tab string @tab - @tab -
3522
@item Exec_Dir     @tab string @tab - @tab -
3523
@item Excluded_Source_Dirs @tab list @tab - @tab -
3524
@item Excluded_Source_Files @tab list @tab - @tab -
3525
@item Excluded_Source_List_File @tab list @tab - @tab -
3526
@item Inherit_Source_Path  @tab list @tab - @tab insensitive
3527
@item Languages @tab list @tab - @tab -
3528
@item Main      @tab list @tab - @tab -
3529
@item Main_Language @tab string @tab - @tab -
3530
@item Externally_Built      @tab string @tab - @tab -
3531
@item Roots      @tab list @tab - @tab file
3532
@headitem
3533
   Library-related attributes @tab @tab @tab @pxref{Library Projects}
3534
@item Library_Dir @tab string @tab - @tab -
3535
@item Library_Name @tab string @tab - @tab -
3536
@item Library_Kind @tab string @tab - @tab -
3537
@item Library_Version @tab string @tab - @tab -
3538
@item Library_Interface @tab string @tab - @tab -
3539
@item Library_Auto_Init @tab string @tab - @tab -
3540
@item Library_Options @tab list @tab - @tab -
3541
@item Leading_Library_Options @tab list @tab - @tab -
3542
@item Library_Src_Dir @tab string @tab - @tab -
3543
@item Library_ALI_Dir @tab string @tab - @tab -
3544
@item Library_GCC @tab string @tab - @tab -
3545
@item Library_Symbol_File @tab string @tab - @tab -
3546
@item Library_Symbol_Policy @tab string @tab - @tab -
3547
@item Library_Reference_Symbol_File @tab string @tab - @tab -
3548
@item Interfaces @tab list @tab - @tab -
3549
@headitem
3550
   Naming @tab @tab @tab @pxref{Naming Schemes}
3551
@item Spec_Suffix @tab string @tab Naming @tab insensitive (language)
3552
@item Body_Suffix @tab string @tab Naming @tab insensitive (language)
3553
@item Separate_Suffix @tab string @tab Naming @tab -
3554
@item Casing @tab string @tab Naming @tab -
3555
@item Dot_Replacement @tab string @tab Naming @tab -
3556
@item Spec @tab string @tab Naming @tab insensitive (Ada unit)
3557
@item Body @tab string @tab Naming @tab insensitive (Ada unit)
3558
@item Specification_Exceptions @tab list @tab Naming @tab insensitive (language)
3559
@item Implementation_Exceptions @tab list @tab Naming @tab insensitive (language)
3560
@headitem
3561
   Building @tab @tab @tab @pxref{Switches and Project Files}
3562
@item Default_Switches @tab list @tab Builder, Compiler, Binder, Linker, Cross_Reference, Finder, Pretty_Printer, gnatstub, Check, Synchronize, Eliminate, Metrics, IDE @tab insensitive (language name)
3563
@item Switches @tab list @tab Builder, Compiler, Binder, Linker, Cross_Reference, Finder, gnatls, Pretty_Printer, gnatstub, Check, Synchronize, Eliminate, Metrics, Stack @tab [file] (file name)
3564
@item Local_Configuration_Pragmas @tab string @tab Compiler @tab -
3565
@item Local_Config_File @tab string @tab insensitive @tab -
3566
@item Global_Configuration_Pragmas @tab list @tab Builder @tab -
3567
@item Global_Compilation_Switches @tab list @tab Builder @tab language
3568
@item Executable @tab string @tab Builder @tab [file]
3569
@item Executable_Suffix @tab string @tab Builder @tab -
3570
@item Global_Config_File @tab string @tab Builder @tab insensitive (language)
3571
@headitem
3572
   IDE (used and created by GPS) @tab @tab @tab
3573
@item Remote_Host @tab string @tab IDE @tab -
3574
@item Program_Host @tab string @tab IDE @tab -
3575
@item Communication_Protocol @tab string @tab IDE @tab -
3576
@item Compiler_Command @tab string @tab IDE @tab insensitive (language)
3577
@item Debugger_Command @tab string @tab IDE @tab -
3578
@item Gnatlist @tab string @tab IDE @tab -
3579
@item Gnat @tab string @tab IDE @tab -
3580
@item VCS_Kind @tab string @tab IDE @tab -
3581
@item VCS_File_Check @tab string @tab IDE @tab -
3582
@item VCS_Log_Check @tab string @tab IDE @tab -
3583
@item Documentation_Dir @tab string @tab IDE @tab -
3584
@headitem
3585
   Configuration files @tab @tab @tab See gprbuild manual
3586
@item Default_Language @tab string @tab - @tab -
3587
@item Run_Path_Option @tab list @tab - @tab -
3588
@item Run_Path_Origin @tab string @tab - @tab -
3589
@item Separate_Run_Path_Options @tab string @tab - @tab -
3590
@item Toolchain_Version @tab string @tab - @tab insensitive
3591
@item Toolchain_Description @tab string @tab - @tab insensitive
3592
@item Object_Generated @tab string @tab - @tab insensitive
3593
@item Objects_Linked @tab string @tab - @tab insensitive
3594
@item Target @tab string @tab - @tab -
3595
@item Library_Builder @tab string @tab - @tab -
3596
@item Library_Support @tab string @tab - @tab -
3597
@item Archive_Builder @tab list @tab - @tab -
3598
@item Archive_Builder_Append_Option @tab list @tab - @tab -
3599
@item Archive_Indexer @tab list @tab - @tab -
3600
@item Archive_Suffix @tab string @tab - @tab -
3601
@item Library_Partial_Linker @tab list @tab - @tab -
3602
@item Shared_Library_Prefix @tab string @tab - @tab -
3603
@item Shared_Library_Suffix @tab string @tab - @tab -
3604
@item Symbolic_Link_Supported @tab string @tab - @tab -
3605
@item Library_Major_Minor_Id_Supported @tab string @tab - @tab -
3606
@item Library_Auto_Init_Supported @tab string @tab - @tab -
3607
@item Shared_Library_Minimum_Switches @tab list @tab - @tab -
3608
@item Library_Version_Switches @tab list @tab - @tab -
3609
@item Library_Install_Name_Option @tab string @tab - @tab -
3610
@item Runtime_Library_Dir @tab string @tab - @tab insensitive
3611
@item Runtime_Source_Dir @tab string @tab - @tab insensitive
3612
@item Driver @tab string @tab Compiler,Binder,Linker @tab insensitive (language)
3613
@item Required_Switches @tab list @tab Compiler,Binder,Linker @tab insensitive (language)
3614
@item Leading_Required_Switches @tab list @tab Compiler @tab insensitive (language)
3615
@item Trailing_Required_Switches @tab list @tab Compiler @tab insensitive (language)
3616
@item Pic_Options @tab list @tab Compiler @tab insensitive (language)
3617
@item Path_Syntax @tab string @tab Compiler @tab insensitive (language)
3618
@item Object_File_Suffix @tab string @tab Compiler @tab insensitive (language)
3619
@item Object_File_Switches @tab list @tab Compiler @tab insensitive (language)
3620
@item Multi_Unit_Switches @tab list @tab Compiler @tab insensitive (language)
3621
@item Multi_Unit_Object_Separator @tab string @tab Compiler @tab insensitive (language)
3622
@item Mapping_File_Switches @tab list @tab Compiler @tab insensitive (language)
3623
@item Mapping_Spec_Suffix @tab string @tab Compiler @tab insensitive (language)
3624
@item Mapping_body_Suffix @tab string @tab Compiler @tab insensitive (language)
3625
@item Config_File_Switches @tab list @tab Compiler @tab insensitive (language)
3626
@item Config_Body_File_Name @tab string @tab Compiler @tab insensitive (language)
3627
@item Config_Body_File_Name_Index @tab string @tab Compiler @tab insensitive (language)
3628
@item Config_Body_File_Name_Pattern @tab string @tab Compiler @tab insensitive (language)
3629
@item Config_Spec_File_Name @tab string @tab Compiler @tab insensitive (language)
3630
@item Config_Spec_File_Name_Index @tab string @tab Compiler @tab insensitive (language)
3631
@item Config_Spec_File_Name_Pattern @tab string @tab Compiler @tab insensitive (language)
3632
@item Config_File_Unique @tab string @tab Compiler @tab insensitive (language)
3633
@item Dependency_Switches @tab list @tab Compiler @tab insensitive (language)
3634
@item Dependency_Driver @tab list @tab Compiler @tab insensitive (language)
3635
@item Include_Switches @tab list @tab Compiler @tab insensitive (language)
3636
@item Include_Path @tab string @tab Compiler @tab insensitive (language)
3637
@item Include_Path_File @tab string @tab Compiler @tab insensitive (language)
3638
@item Prefix @tab string @tab Binder @tab insensitive (language)
3639
@item Objects_Path @tab string @tab Binder @tab insensitive (language)
3640
@item Objects_Path_File @tab string @tab Binder @tab insensitive (language)
3641
@item Linker_Options @tab list @tab Linker @tab -
3642
@item Leading_Switches @tab list @tab Linker @tab -
3643
@item Map_File_Options @tab string @tab Linker @tab -
3644
@item Executable_Switches @tab list @tab Linker @tab -
3645
@item Lib_Dir_Switch @tab string @tab Linker @tab -
3646
@item Lib_Name_Switch @tab string @tab Linker @tab -
3647
@item Max_Command_Line_Length @tab string @tab Linker @tab -
3648
@item Response_File_Format @tab string @tab Linker @tab -
3649
@item Response_File_Switches @tab list @tab Linker @tab -
3650
@end multitable
3651
 
3652
@c ---------------------------------------------
3653
@node Case Statements
3654
@subsection Case Statements
3655
@c ---------------------------------------------
3656
 
3657
@noindent
3658
A @b{case} statement is used in a project file to effect conditional
3659
behavior. Through this statement, you can set the value of attributes
3660
and variables depending on the value previously assigned to a typed
3661
variable.
3662
 
3663
All choices in a choice list must be distinct. Unlike Ada, the choice
3664
lists of all alternatives do not need to include all values of the type.
3665
An @code{others} choice must appear last in the list of alternatives.
3666
 
3667
The syntax of a @code{case} construction is based on the Ada case statement
3668
(although the @code{null} statement for empty alternatives is optional).
3669
 
3670
The case expression must be a typed string variable, whose value is often
3671
given by an external reference (@pxref{External Values}).
3672
 
3673
Each alternative starts with the reserved word @code{when}, either a list of
3674
literal strings separated by the @code{"|"} character or the reserved word
3675
@code{others}, and the @code{"=>"} token.
3676
Each literal string must belong to the string type that is the type of the
3677
case variable.
3678
After each @code{=>}, there are zero or more statements.  The only
3679
statements allowed in a case construction are other case statements,
3680
attribute declarations and variable declarations. String type declarations and
3681
package declarations are not allowed. Variable declarations are restricted to
3682
variables that have already been declared before the case construction.
3683
 
3684
@smallexample
3685
case_statement ::=
3686
  @i{case} @i{<typed_variable_>}name @i{is} @{case_item@} @i{end case} ;
3687
 
3688
case_item ::=
3689
  @i{when} discrete_choice_list =>
3690
    @{case_statement
3691
      | attribute_declaration
3692
      | variable_declaration
3693
      | empty_declaration@}
3694
 
3695
discrete_choice_list ::= string_literal @{| string_literal@} | @i{others}
3696
@end smallexample
3697
 
3698
@noindent
3699
Here is a typical example:
3700
 
3701
@smallexample @c projectfile
3702
@group
3703
project MyProj is
3704
   type OS_Type is ("GNU/Linux", "Unix", "NT", "VMS");
3705
   OS : OS_Type := external ("OS", "GNU/Linux");
3706
 
3707
   package Compiler is
3708
     case OS is
3709
       when "GNU/Linux" | "Unix" =>
3710
         for Switches ("Ada") use ("-gnath");
3711
       when "NT" =>
3712
         for Switches ("Ada") use ("-gnatP");
3713
       when others =>
3714
         null;
3715
     end case;
3716
   end Compiler;
3717
end MyProj;
3718
@end group
3719
@end smallexample
3720
 
3721
@c ---------------------------------------------
3722
@node Tools Supporting Project Files
3723
@chapter Tools Supporting Project Files
3724
@c ---------------------------------------------
3725
 
3726
@noindent
3727
 
3728
@menu
3729
* gnatmake and Project Files::
3730
* The GNAT Driver and Project Files::
3731
* The Development Environments::
3732
@end menu
3733
 
3734
@c ---------------------------------------------
3735
@node gnatmake and Project Files
3736
@section gnatmake and Project Files
3737
@c ---------------------------------------------
3738
 
3739
@noindent
3740
This section covers several topics related to @command{gnatmake} and
3741
project files: defining ^switches^switches^ for @command{gnatmake}
3742
and for the tools that it invokes; specifying configuration pragmas;
3743
the use of the @code{Main} attribute; building and rebuilding library project
3744
files.
3745
 
3746
@menu
3747
* Switches Related to Project Files::
3748
* Switches and Project Files::
3749
* Specifying Configuration Pragmas::
3750
* Project Files and Main Subprograms::
3751
* Library Project Files::
3752
@end menu
3753
 
3754
@c ---------------------------------------------
3755
@node Switches Related to Project Files
3756
@subsection Switches Related to Project Files
3757
@c ---------------------------------------------
3758
 
3759
@noindent
3760
The following switches are used by GNAT tools that support project files:
3761
 
3762
@table @option
3763
 
3764
@item ^-P^/PROJECT_FILE=^@var{project}
3765
@cindex @option{^-P^/PROJECT_FILE^} (any project-aware tool)
3766
Indicates the name of a project file. This project file will be parsed with
3767
the verbosity indicated by @option{^-vP^MESSAGE_PROJECT_FILES=^@emph{x}},
3768
if any, and using the external references indicated
3769
by @option{^-X^/EXTERNAL_REFERENCE^} switches, if any.
3770
@ifclear vms
3771
There may zero, one or more spaces between @option{-P} and @var{project}.
3772
@end ifclear
3773
 
3774
There must be only one @option{^-P^/PROJECT_FILE^} switch on the command line.
3775
 
3776
Since the Project Manager parses the project file only after all the switches
3777
on the command line are checked, the order of the switches
3778
@option{^-P^/PROJECT_FILE^},
3779
@option{^-vP^/MESSAGES_PROJECT_FILE=^@emph{x}}
3780
or @option{^-X^/EXTERNAL_REFERENCE^} is not significant.
3781
 
3782
@item ^-X^/EXTERNAL_REFERENCE=^@var{name=value}
3783
@cindex @option{^-X^/EXTERNAL_REFERENCE^} (any project-aware tool)
3784
Indicates that external variable @var{name} has the value @var{value}.
3785
The Project Manager will use this value for occurrences of
3786
@code{external(name)} when parsing the project file.
3787
 
3788
@ifclear vms
3789
If @var{name} or @var{value} includes a space, then @var{name=value} should be
3790
put between quotes.
3791
@smallexample
3792
  -XOS=NT
3793
  -X"user=John Doe"
3794
@end smallexample
3795
@end ifclear
3796
 
3797
Several @option{^-X^/EXTERNAL_REFERENCE^} switches can be used simultaneously.
3798
If several @option{^-X^/EXTERNAL_REFERENCE^} switches specify the same
3799
@var{name}, only the last one is used.
3800
 
3801
An external variable specified with a @option{^-X^/EXTERNAL_REFERENCE^} switch
3802
takes precedence over the value of the same name in the environment.
3803
 
3804
@item ^-vP^/MESSAGES_PROJECT_FILE=^@emph{x}
3805
@cindex @option{^-vP^/MESSAGES_PROJECT_FILE^} (any project-aware tool)
3806
Indicates the verbosity of the parsing of GNAT project files.
3807
 
3808
@ifclear vms
3809
@option{-vP0} means Default;
3810
@option{-vP1} means Medium;
3811
@option{-vP2} means High.
3812
@end ifclear
3813
 
3814
@ifset vms
3815
There are three possible options for this qualifier: DEFAULT, MEDIUM and
3816
HIGH.
3817
@end ifset
3818
 
3819
The default is ^Default^DEFAULT^: no output for syntactically correct
3820
project files.
3821
If several @option{^-vP^/MESSAGES_PROJECT_FILE=^@emph{x}} switches are present,
3822
only the last one is used.
3823
 
3824
@item ^-aP^/ADD_PROJECT_SEARCH_DIR=^<dir>
3825
@cindex @option{^-aP^/ADD_PROJECT_SEARCH_DIR=^} (any project-aware tool)
3826
Add directory <dir> at the beginning of the project search path, in order,
3827
after the current working directory.
3828
 
3829
@ifclear vms
3830
@item -eL
3831
@cindex @option{-eL} (any project-aware tool)
3832
Follow all symbolic links when processing project files.
3833
@end ifclear
3834
 
3835
@item ^--subdirs^/SUBDIRS^=<subdir>
3836
@cindex @option{^--subdirs^/SUBDIRS^=} (gnatmake and gnatclean)
3837
This switch is recognized by gnatmake and gnatclean. It indicate that the real
3838
directories (except the source directories) are the subdirectories <subdir>
3839
of the directories specified in the project files. This applies in particular
3840
to object directories, library directories and exec directories. If the
3841
subdirectories do not exist, they are created automatically.
3842
 
3843
@end table
3844
 
3845
@c ---------------------------------------------
3846
@node Switches and Project Files
3847
@subsection Switches and Project Files
3848
@c ---------------------------------------------
3849
 
3850
@noindent
3851
@ifset vms
3852
It is not currently possible to specify VMS style qualifiers in the project
3853
files; only Unix style ^switches^switches^ may be specified.
3854
@end ifset
3855
 
3856
For each of the packages @code{Builder}, @code{Compiler}, @code{Binder}, and
3857
@code{Linker}, you can specify a @code{^Default_Switches^Default_Switches^}
3858
attribute, a @code{Switches} attribute, or both;
3859
as their names imply, these ^switch^switch^-related
3860
attributes affect the ^switches^switches^ that are used for each of these GNAT
3861
components when
3862
@command{gnatmake} is invoked.  As will be explained below, these
3863
component-specific ^switches^switches^ precede
3864
the ^switches^switches^ provided on the @command{gnatmake} command line.
3865
 
3866
The @code{^Default_Switches^Default_Switches^} attribute is an attribute
3867
indexed by language name (case insensitive) whose value is a string list.
3868
For example:
3869
 
3870
@smallexample @c projectfile
3871
@group
3872
package Compiler is
3873
  for ^Default_Switches^Default_Switches^ ("Ada")
3874
      use ("^-gnaty^-gnaty^",
3875
           "^-v^-v^");
3876
end Compiler;
3877
@end group
3878
@end smallexample
3879
 
3880
@noindent
3881
The @code{Switches} attribute is indexed on a file name (which may or may
3882
not be case sensitive, depending
3883
on the operating system) whose value is a string list.  For example:
3884
 
3885
@smallexample @c projectfile
3886
@group
3887
package Builder is
3888
   for Switches ("main1.adb")
3889
       use ("^-O2^-O2^");
3890
   for Switches ("main2.adb")
3891
       use ("^-g^-g^");
3892
end Builder;
3893
@end group
3894
@end smallexample
3895
 
3896
@noindent
3897
For the @code{Builder} package, the file names must designate source files
3898
for main subprograms.  For the @code{Binder} and @code{Linker} packages, the
3899
file names must designate @file{ALI} or source files for main subprograms.
3900
In each case just the file name without an explicit extension is acceptable.
3901
 
3902
For each tool used in a program build (@command{gnatmake}, the compiler, the
3903
binder, and the linker), the corresponding package @dfn{contributes} a set of
3904
^switches^switches^ for each file on which the tool is invoked, based on the
3905
^switch^switch^-related attributes defined in the package.
3906
In particular, the ^switches^switches^
3907
that each of these packages contributes for a given file @var{f} comprise:
3908
 
3909
@itemize @bullet
3910
@item the value of attribute @code{Switches (@var{f})},
3911
  if it is specified in the package for the given file,
3912
@item otherwise, the value of @code{^Default_Switches^Default_Switches^ ("Ada")},
3913
  if it is specified in the package.
3914
 
3915
@end itemize
3916
 
3917
@noindent
3918
If neither of these attributes is defined in the package, then the package does
3919
not contribute any ^switches^switches^ for the given file.
3920
 
3921
When @command{gnatmake} is invoked on a file, the ^switches^switches^ comprise
3922
two sets, in the following order: those contributed for the file
3923
by the @code{Builder} package;
3924
and the switches passed on the command line.
3925
 
3926
When @command{gnatmake} invokes a tool (compiler, binder, linker) on a file,
3927
the ^switches^switches^ passed to the tool comprise three sets,
3928
in the following order:
3929
 
3930
@enumerate
3931
@item
3932
the applicable ^switches^switches^ contributed for the file
3933
by the @code{Builder} package in the project file supplied on the command line;
3934
 
3935
@item
3936
those contributed for the file by the package (in the relevant project file --
3937
see below) corresponding to the tool; and
3938
 
3939
@item
3940
the applicable switches passed on the command line.
3941
@end enumerate
3942
 
3943
The term @emph{applicable ^switches^switches^} reflects the fact that
3944
@command{gnatmake} ^switches^switches^ may or may not be passed to individual
3945
tools, depending on the individual ^switch^switch^.
3946
 
3947
@command{gnatmake} may invoke the compiler on source files from different
3948
projects. The Project Manager will use the appropriate project file to
3949
determine the @code{Compiler} package for each source file being compiled.
3950
Likewise for the @code{Binder} and @code{Linker} packages.
3951
 
3952
As an example, consider the following package in a project file:
3953
 
3954
@smallexample @c projectfile
3955
@group
3956
project Proj1 is
3957
   package Compiler is
3958
      for ^Default_Switches^Default_Switches^ ("Ada")
3959
          use ("^-g^-g^");
3960
      for Switches ("a.adb")
3961
          use ("^-O1^-O1^");
3962
      for Switches ("b.adb")
3963
          use ("^-O2^-O2^",
3964
               "^-gnaty^-gnaty^");
3965
   end Compiler;
3966
end Proj1;
3967
@end group
3968
@end smallexample
3969
 
3970
@noindent
3971
If @command{gnatmake} is invoked with this project file, and it needs to
3972
compile, say, the files @file{a.adb}, @file{b.adb}, and @file{c.adb}, then
3973
@file{a.adb} will be compiled with the ^switch^switch^
3974
@option{^-O1^-O1^},
3975
@file{b.adb} with ^switches^switches^
3976
@option{^-O2^-O2^}
3977
and @option{^-gnaty^-gnaty^},
3978
and @file{c.adb} with @option{^-g^-g^}.
3979
 
3980
The following example illustrates the ordering of the ^switches^switches^
3981
contributed by different packages:
3982
 
3983
@smallexample @c projectfile
3984
@group
3985
project Proj2 is
3986
   package Builder is
3987
      for Switches ("main.adb")
3988
          use ("^-g^-g^",
3989
               "^-O1^-)1^",
3990
               "^-f^-f^");
3991
   end Builder;
3992
@end group
3993
 
3994
@group
3995
   package Compiler is
3996
      for Switches ("main.adb")
3997
          use ("^-O2^-O2^");
3998
   end Compiler;
3999
end Proj2;
4000
@end group
4001
@end smallexample
4002
 
4003
@noindent
4004
If you issue the command:
4005
 
4006
@smallexample
4007
    gnatmake ^-Pproj2^/PROJECT_FILE=PROJ2^ -O0 main
4008
@end smallexample
4009
 
4010
@noindent
4011
then the compiler will be invoked on @file{main.adb} with the following
4012
sequence of ^switches^switches^
4013
 
4014
@smallexample
4015
   ^-g -O1 -O2 -O0^-g -O1 -O2 -O0^
4016
@end smallexample
4017
 
4018
@noindent
4019
with the last @option{^-O^-O^}
4020
^switch^switch^ having precedence over the earlier ones;
4021
several other ^switches^switches^
4022
(such as @option{^-c^-c^}) are added implicitly.
4023
 
4024
The ^switches^switches^
4025
@option{^-g^-g^}
4026
and @option{^-O1^-O1^} are contributed by package
4027
@code{Builder},  @option{^-O2^-O2^} is contributed
4028
by the package @code{Compiler}
4029
and @option{^-O0^-O0^} comes from the command line.
4030
 
4031
The @option{^-g^-g^}
4032
^switch^switch^ will also be passed in the invocation of
4033
@command{Gnatlink.}
4034
 
4035
A final example illustrates switch contributions from packages in different
4036
project files:
4037
 
4038
@smallexample @c projectfile
4039
@group
4040
project Proj3 is
4041
   for Source_Files use ("pack.ads", "pack.adb");
4042
   package Compiler is
4043
      for ^Default_Switches^Default_Switches^ ("Ada")
4044
          use ("^-gnata^-gnata^");
4045
   end Compiler;
4046
end Proj3;
4047
@end group
4048
 
4049
@group
4050
with "Proj3";
4051
project Proj4 is
4052
   for Source_Files use ("foo_main.adb", "bar_main.adb");
4053
   package Builder is
4054
      for Switches ("foo_main.adb")
4055
          use ("^-s^-s^",
4056
               "^-g^-g^");
4057
   end Builder;
4058
end Proj4;
4059
@end group
4060
 
4061
@group
4062
-- Ada source file:
4063
with Pack;
4064
procedure Foo_Main is
4065
   @dots{}
4066
end Foo_Main;
4067
@end group
4068
@end smallexample
4069
 
4070
@noindent
4071
If the command is
4072
@smallexample
4073
gnatmake ^-PProj4^/PROJECT_FILE=PROJ4^ foo_main.adb -cargs -gnato
4074
@end smallexample
4075
 
4076
@noindent
4077
then the ^switches^switches^ passed to the compiler for @file{foo_main.adb} are
4078
@option{^-g^-g^} (contributed by the package @code{Proj4.Builder}) and
4079
@option{^-gnato^-gnato^} (passed on the command line).
4080
When the imported package @code{Pack} is compiled, the ^switches^switches^ used
4081
are @option{^-g^-g^} from @code{Proj4.Builder},
4082
@option{^-gnata^-gnata^} (contributed from package @code{Proj3.Compiler},
4083
and @option{^-gnato^-gnato^} from the command line.
4084
 
4085
When using @command{gnatmake} with project files, some ^switches^switches^ or
4086
arguments may be expressed as relative paths. As the working directory where
4087
compilation occurs may change, these relative paths are converted to absolute
4088
paths. For the ^switches^switches^ found in a project file, the relative paths
4089
are relative to the project file directory, for the switches on the command
4090
line, they are relative to the directory where @command{gnatmake} is invoked.
4091
The ^switches^switches^ for which this occurs are:
4092
^-I^-I^,
4093
^-A^-A^,
4094
^-L^-L^,
4095
^-aO^-aO^,
4096
^-aL^-aL^,
4097
^-aI^-aI^, as well as all arguments that are not switches (arguments to
4098
^switch^switch^
4099
^-o^-o^, object files specified in package @code{Linker} or after
4100
-largs on the command line). The exception to this rule is the ^switch^switch^
4101
^--RTS=^--RTS=^ for which a relative path argument is never converted.
4102
 
4103
@c ---------------------------------------------
4104
@node Specifying Configuration Pragmas
4105
@subsection Specifying Configuration Pragmas
4106
@c ---------------------------------------------
4107
 
4108
@noindent
4109
When using @command{gnatmake} with project files, if there exists a file
4110
@file{gnat.adc} that contains configuration pragmas, this file will be
4111
ignored.
4112
 
4113
Configuration pragmas can be defined by means of the following attributes in
4114
project files: @code{Global_Configuration_Pragmas} in package @code{Builder}
4115
and @code{Local_Configuration_Pragmas} in package @code{Compiler}.
4116
 
4117
Both these attributes are single string attributes. Their values is the path
4118
name of a file containing configuration pragmas. If a path name is relative,
4119
then it is relative to the project directory of the project file where the
4120
attribute is defined.
4121
 
4122
When compiling a source, the configuration pragmas used are, in order,
4123
those listed in the file designated by attribute
4124
@code{Global_Configuration_Pragmas} in package @code{Builder} of the main
4125
project file, if it is specified, and those listed in the file designated by
4126
attribute @code{Local_Configuration_Pragmas} in package @code{Compiler} of
4127
the project file of the source, if it exists.
4128
 
4129
@c ---------------------------------------------
4130
@node Project Files and Main Subprograms
4131
@subsection Project Files and Main Subprograms
4132
@c ---------------------------------------------
4133
 
4134
@noindent
4135
When using a project file, you can invoke @command{gnatmake}
4136
with one or several main subprograms, by specifying their source files on the
4137
command line.
4138
 
4139
@smallexample
4140
    gnatmake ^-P^/PROJECT_FILE=^prj main1.adb main2.adb main3.adb
4141
@end smallexample
4142
 
4143
@noindent
4144
Each of these needs to be a source file of the same project, except
4145
when the switch ^-u^/UNIQUE^ is used.
4146
 
4147
When ^-u^/UNIQUE^ is not used, all the mains need to be sources of the
4148
same project, one of the project in the tree rooted at the project specified
4149
on the command line. The package @code{Builder} of this common project, the
4150
"main project" is the one that is considered by @command{gnatmake}.
4151
 
4152
When ^-u^/UNIQUE^ is used, the specified source files may be in projects
4153
imported directly or indirectly by the project specified on the command line.
4154
Note that if such a source file is not part of the project specified on the
4155
command line, the ^switches^switches^ found in package @code{Builder} of the
4156
project specified on the command line, if any, that are transmitted
4157
to the compiler will still be used, not those found in the project file of
4158
the source file.
4159
 
4160
When using a project file, you can also invoke @command{gnatmake} without
4161
explicitly specifying any main, and the effect depends on whether you have
4162
defined the @code{Main} attribute.  This attribute has a string list value,
4163
where each element in the list is the name of a source file (the file
4164
extension is optional) that contains a unit that can be a main subprogram.
4165
 
4166
If the @code{Main} attribute is defined in a project file as a non-empty
4167
string list and the switch @option{^-u^/UNIQUE^} is not used on the command
4168
line, then invoking @command{gnatmake} with this project file but without any
4169
main on the command line is equivalent to invoking @command{gnatmake} with all
4170
the file names in the @code{Main} attribute on the command line.
4171
 
4172
Example:
4173
@smallexample @c projectfile
4174
@group
4175
   project Prj is
4176
      for Main use ("main1.adb", "main2.adb", "main3.adb");
4177
   end Prj;
4178
@end group
4179
@end smallexample
4180
 
4181
@noindent
4182
With this project file, @code{"gnatmake ^-Pprj^/PROJECT_FILE=PRJ^"}
4183
is equivalent to
4184
@code{"gnatmake ^-Pprj^/PROJECT_FILE=PRJ^ main1.adb main2.adb main3.adb"}.
4185
 
4186
When the project attribute @code{Main} is not specified, or is specified
4187
as an empty string list, or when the switch @option{-u} is used on the command
4188
line, then invoking @command{gnatmake} with no main on the command line will
4189
result in all immediate sources of the project file being checked, and
4190
potentially recompiled. Depending on the presence of the switch @option{-u},
4191
sources from other project files on which the immediate sources of the main
4192
project file depend are also checked and potentially recompiled. In other
4193
words, the @option{-u} switch is applied to all of the immediate sources of the
4194
main project file.
4195
 
4196
When no main is specified on the command line and attribute @code{Main} exists
4197
and includes several mains, or when several mains are specified on the
4198
command line, the default ^switches^switches^ in package @code{Builder} will
4199
be used for all mains, even if there are specific ^switches^switches^
4200
specified for one or several mains.
4201
 
4202
But the ^switches^switches^ from package @code{Binder} or @code{Linker} will be
4203
the specific ^switches^switches^ for each main, if they are specified.
4204
 
4205
@c ---------------------------------------------
4206
@node Library Project Files
4207
@subsection Library Project Files
4208
@c ---------------------------------------------
4209
 
4210
@noindent
4211
When @command{gnatmake} is invoked with a main project file that is a library
4212
project file, it is not allowed to specify one or more mains on the command
4213
line.
4214
 
4215
When a library project file is specified, switches ^-b^/ACTION=BIND^ and
4216
^-l^/ACTION=LINK^ have special meanings.
4217
 
4218
@itemize @bullet
4219
@item ^-b^/ACTION=BIND^ is only allowed for stand-alone libraries. It indicates
4220
  to @command{gnatmake} that @command{gnatbind} should be invoked for the
4221
  library.
4222
 
4223
@item ^-l^/ACTION=LINK^ may be used for all library projects. It indicates
4224
  to @command{gnatmake} that the binder generated file should be compiled
4225
  (in the case of a stand-alone library) and that the library should be built.
4226
@end itemize
4227
 
4228
@c ---------------------------------------------
4229
@node The GNAT Driver and Project Files
4230
@section The GNAT Driver and Project Files
4231
@c ---------------------------------------------
4232
 
4233
@noindent
4234
A number of GNAT tools, other than @command{^gnatmake^gnatmake^}
4235
can benefit from project files:
4236
(@command{^gnatbind^gnatbind^},
4237
@command{^gnatcheck^gnatcheck^},
4238
@command{^gnatclean^gnatclean^},
4239
@command{^gnatelim^gnatelim^},
4240
@command{^gnatfind^gnatfind^},
4241
@command{^gnatlink^gnatlink^},
4242
@command{^gnatls^gnatls^},
4243
@command{^gnatmetric^gnatmetric^},
4244
@command{^gnatpp^gnatpp^},
4245
@command{^gnatstub^gnatstub^},
4246
and @command{^gnatxref^gnatxref^}). However, none of these tools can be invoked
4247
directly with a project file switch (@option{^-P^/PROJECT_FILE=^}).
4248
They must be invoked through the @command{gnat} driver.
4249
 
4250
The @command{gnat} driver is a wrapper that accepts a number of commands and
4251
calls the corresponding tool. It was designed initially for VMS platforms (to
4252
convert VMS qualifiers to Unix-style switches), but it is now available on all
4253
GNAT platforms.
4254
 
4255
On non-VMS platforms, the @command{gnat} driver accepts the following commands
4256
(case insensitive):
4257
 
4258
@itemize @bullet
4259
@item BIND to invoke @command{^gnatbind^gnatbind^}
4260
@item CHOP to invoke @command{^gnatchop^gnatchop^}
4261
@item CLEAN to invoke @command{^gnatclean^gnatclean^}
4262
@item COMP or COMPILE to invoke the compiler
4263
@item ELIM to invoke @command{^gnatelim^gnatelim^}
4264
@item FIND to invoke @command{^gnatfind^gnatfind^}
4265
@item KR or KRUNCH to invoke @command{^gnatkr^gnatkr^}
4266
@item LINK to invoke @command{^gnatlink^gnatlink^}
4267
@item LS or LIST to invoke @command{^gnatls^gnatls^}
4268
@item MAKE to invoke @command{^gnatmake^gnatmake^}
4269
@item NAME to invoke @command{^gnatname^gnatname^}
4270
@item PREP or PREPROCESS to invoke @command{^gnatprep^gnatprep^}
4271
@item PP or PRETTY to invoke @command{^gnatpp^gnatpp^}
4272
@item METRIC to invoke @command{^gnatmetric^gnatmetric^}
4273
@item STUB to invoke @command{^gnatstub^gnatstub^}
4274
@item XREF to invoke @command{^gnatxref^gnatxref^}
4275
 
4276
@end itemize
4277
 
4278
@noindent
4279
(note that the compiler is invoked using the command
4280
@command{^gnatmake -f -u -c^gnatmake -f -u -c^}).
4281
 
4282
On non-VMS platforms, between @command{gnat} and the command, two
4283
special switches may be used:
4284
 
4285
@itemize @bullet
4286
@item @command{-v} to display the invocation of the tool.
4287
@item @command{-dn} to prevent the @command{gnat} driver from removing
4288
  the temporary files it has created. These temporary files are
4289
  configuration files and temporary file list files.
4290
 
4291
@end itemize
4292
 
4293
@noindent
4294
The command may be followed by switches and arguments for the invoked
4295
tool.
4296
 
4297
@smallexample
4298
  gnat bind -C main.ali
4299
  gnat ls -a main
4300
  gnat chop foo.txt
4301
@end smallexample
4302
 
4303
@noindent
4304
Switches may also be put in text files, one switch per line, and the text
4305
files may be specified with their path name preceded by '@@'.
4306
 
4307
@smallexample
4308
   gnat bind @@args.txt main.ali
4309
@end smallexample
4310
 
4311
@noindent
4312
In addition, for commands BIND, COMP or COMPILE, FIND, ELIM, LS or LIST, LINK,
4313
METRIC, PP or PRETTY, STUB and XREF, the project file related switches
4314
(@option{^-P^/PROJECT_FILE^},
4315
@option{^-X^/EXTERNAL_REFERENCE^} and
4316
@option{^-vP^/MESSAGES_PROJECT_FILE=^x}) may be used in addition to
4317
the switches of the invoking tool.
4318
 
4319
When GNAT PP or GNAT PRETTY is used with a project file, but with no source
4320
specified on the command line, it invokes @command{^gnatpp^gnatpp^} with all
4321
the immediate sources of the specified project file.
4322
 
4323
When GNAT METRIC is used with a project file, but with no source
4324
specified on the command line, it invokes @command{^gnatmetric^gnatmetric^}
4325
with all the immediate sources of the specified project file and with
4326
@option{^-d^/DIRECTORY^} with the parameter pointing to the object directory
4327
of the project.
4328
 
4329
In addition, when GNAT PP, GNAT PRETTY or GNAT METRIC is used with
4330
a project file, no source is specified on the command line and
4331
switch ^-U^/ALL_PROJECTS^ is specified on the command line, then
4332
the underlying tool (^gnatpp^gnatpp^ or
4333
^gnatmetric^gnatmetric^) is invoked for all sources of all projects,
4334
not only for the immediate sources of the main project.
4335
@ifclear vms
4336
(-U stands for Universal or Union of the project files of the project tree)
4337
@end ifclear
4338
 
4339
For each of the following commands, there is optionally a corresponding
4340
package in the main project.
4341
 
4342
@itemize @bullet
4343
@item package @code{Binder} for command BIND (invoking @code{^gnatbind^gnatbind^})
4344
 
4345
@item package @code{Check} for command CHECK (invoking
4346
  @code{^gnatcheck^gnatcheck^})
4347
 
4348
@item package @code{Compiler} for command COMP or COMPILE (invoking the compiler)
4349
 
4350
@item package @code{Cross_Reference} for command XREF (invoking
4351
  @code{^gnatxref^gnatxref^})
4352
 
4353
@item package @code{Eliminate} for command ELIM (invoking
4354
  @code{^gnatelim^gnatelim^})
4355
 
4356
@item package @code{Finder} for command FIND (invoking @code{^gnatfind^gnatfind^})
4357
 
4358
@item package @code{Gnatls} for command LS or LIST (invoking @code{^gnatls^gnatls^})
4359
 
4360
@item package @code{Gnatstub} for command STUB
4361
  (invoking @code{^gnatstub^gnatstub^})
4362
 
4363
@item package @code{Linker} for command LINK (invoking @code{^gnatlink^gnatlink^})
4364
 
4365
@item package @code{Check} for command CHECK
4366
  (invoking @code{^gnatcheck^gnatcheck^})
4367
 
4368
@item package @code{Metrics} for command METRIC
4369
  (invoking @code{^gnatmetric^gnatmetric^})
4370
 
4371
@item package @code{Pretty_Printer} for command PP or PRETTY
4372
  (invoking @code{^gnatpp^gnatpp^})
4373
 
4374
@end itemize
4375
 
4376
@noindent
4377
Package @code{Gnatls} has a unique attribute @code{Switches},
4378
a simple variable with a string list value. It contains ^switches^switches^
4379
for the invocation of @code{^gnatls^gnatls^}.
4380
 
4381
@smallexample @c projectfile
4382
@group
4383
project Proj1 is
4384
   package gnatls is
4385
      for Switches
4386
          use ("^-a^-a^",
4387
               "^-v^-v^");
4388
   end gnatls;
4389
end Proj1;
4390
@end group
4391
@end smallexample
4392
 
4393
@noindent
4394
All other packages have two attribute @code{Switches} and
4395
@code{^Default_Switches^Default_Switches^}.
4396
 
4397
@code{Switches} is an indexed attribute, indexed by the
4398
source file name, that has a string list value: the ^switches^switches^ to be
4399
used when the tool corresponding to the package is invoked for the specific
4400
source file.
4401
 
4402
@code{^Default_Switches^Default_Switches^} is an attribute,
4403
indexed by  the programming language that has a string list value.
4404
@code{^Default_Switches^Default_Switches^ ("Ada")} contains the
4405
^switches^switches^ for the invocation of the tool corresponding
4406
to the package, except if a specific @code{Switches} attribute
4407
is specified for the source file.
4408
 
4409
@smallexample @c projectfile
4410
@group
4411
project Proj is
4412
 
4413
   for Source_Dirs use ("**");
4414
 
4415
   package gnatls is
4416
      for Switches use
4417
          ("^-a^-a^",
4418
           "^-v^-v^");
4419
   end gnatls;
4420
@end group
4421
@group
4422
 
4423
   package Compiler is
4424
      for ^Default_Switches^Default_Switches^ ("Ada")
4425
          use ("^-gnatv^-gnatv^",
4426
               "^-gnatwa^-gnatwa^");
4427
   end Binder;
4428
@end group
4429
@group
4430
 
4431
   package Binder is
4432
      for ^Default_Switches^Default_Switches^ ("Ada")
4433
          use ("^-C^-C^",
4434
               "^-e^-e^");
4435
   end Binder;
4436
@end group
4437
@group
4438
 
4439
   package Linker is
4440
      for ^Default_Switches^Default_Switches^ ("Ada")
4441
          use ("^-C^-C^");
4442
      for Switches ("main.adb")
4443
          use ("^-C^-C^",
4444
               "^-v^-v^",
4445
               "^-v^-v^");
4446
   end Linker;
4447
@end group
4448
@group
4449
 
4450
   package Finder is
4451
      for ^Default_Switches^Default_Switches^ ("Ada")
4452
           use ("^-a^-a^",
4453
                "^-f^-f^");
4454
   end Finder;
4455
@end group
4456
@group
4457
 
4458
   package Cross_Reference is
4459
      for ^Default_Switches^Default_Switches^ ("Ada")
4460
          use ("^-a^-a^",
4461
               "^-f^-f^",
4462
               "^-d^-d^",
4463
               "^-u^-u^");
4464
   end Cross_Reference;
4465
end Proj;
4466
@end group
4467
@end smallexample
4468
 
4469
@noindent
4470
With the above project file, commands such as
4471
 
4472
@smallexample
4473
   ^gnat comp -Pproj main^GNAT COMP /PROJECT_FILE=PROJ MAIN^
4474
   ^gnat ls -Pproj main^GNAT LIST /PROJECT_FILE=PROJ MAIN^
4475
   ^gnat xref -Pproj main^GNAT XREF /PROJECT_FILE=PROJ MAIN^
4476
   ^gnat bind -Pproj main.ali^GNAT BIND /PROJECT_FILE=PROJ MAIN.ALI^
4477
   ^gnat link -Pproj main.ali^GNAT LINK /PROJECT_FILE=PROJ MAIN.ALI^
4478
@end smallexample
4479
 
4480
@noindent
4481
will set up the environment properly and invoke the tool with the switches
4482
found in the package corresponding to the tool:
4483
@code{^Default_Switches^Default_Switches^ ("Ada")} for all tools,
4484
except @code{Switches ("main.adb")}
4485
for @code{^gnatlink^gnatlink^}.
4486
It is also possible to invoke some of the tools,
4487
(@code{^gnatcheck^gnatcheck^},
4488
@code{^gnatmetric^gnatmetric^},
4489
and @code{^gnatpp^gnatpp^})
4490
on a set of project units thanks to the combination of the switches
4491
@option{-P}, @option{-U} and possibly the main unit when one is interested
4492
in its closure. For instance,
4493
@smallexample
4494
gnat metric -Pproj
4495
@end smallexample
4496
 
4497
@noindent
4498
will compute the metrics for all the immediate units of project
4499
@code{proj}.
4500
@smallexample
4501
gnat metric -Pproj -U
4502
@end smallexample
4503
 
4504
@noindent
4505
will compute the metrics for all the units of the closure of projects
4506
rooted at @code{proj}.
4507
@smallexample
4508
gnat metric -Pproj -U main_unit
4509
@end smallexample
4510
 
4511
@noindent
4512
will compute the metrics for the closure of units rooted at
4513
@code{main_unit}. This last possibility relies implicitly
4514
on @command{gnatbind}'s option @option{-R}. But if the argument files for the
4515
tool invoked by the @command{gnat} driver are explicitly  specified
4516
either directly or through the tool @option{-files} option, then the tool
4517
is called only for these explicitly specified files.
4518
 
4519
@c ---------------------------------------------
4520
@node The Development Environments
4521
@section The Development Environments
4522
@c ---------------------------------------------
4523
 
4524
@noindent
4525
See the appropriate manuals for more details. These environments will
4526
store a number of settings in the project itself, when they are meant
4527
to be shared by the whole team working on the project. Here are the
4528
attributes defined in the package @b{IDE} in projects.
4529
 
4530
@table @code
4531
@item Remote_Host
4532
This is a simple attribute. Its value is a string that designates the remote
4533
host in a cross-compilation environment, to be used for remote compilation and
4534
debugging. This field should not be specified when running on the local
4535
machine.
4536
 
4537
@item Program_Host
4538
This is a simple attribute. Its value is a string that specifies the
4539
name of IP address of the embedded target in a cross-compilation environment,
4540
on which the program should execute.
4541
 
4542
@item Communication_Protocol
4543
This is a simple string attribute. Its value is the name of the protocol
4544
to use to communicate with the target in a cross-compilation environment,
4545
e.g.@: @code{"wtx"} or @code{"vxworks"}.
4546
 
4547
@item Compiler_Command
4548
This is an associative array attribute, whose domain is a language name. Its
4549
value is  string that denotes the command to be used to invoke the compiler.
4550
The value of @code{Compiler_Command ("Ada")} is expected to be compatible with
4551
gnatmake, in particular in the handling of switches.
4552
 
4553
@item Debugger_Command
4554
This is simple attribute, Its value is a string that specifies the name of
4555
the debugger to be used, such as gdb, powerpc-wrs-vxworks-gdb or gdb-4.
4556
 
4557
@item Default_Switches
4558
This is an associative array attribute. Its indexes are the name of the
4559
external tools that the GNAT Programming System (GPS) is supporting. Its
4560
value is a list of switches to use when invoking that tool.
4561
 
4562
@item  Gnatlist
4563
This is a simple attribute.  Its value is a string that specifies the name
4564
of the @command{gnatls} utility to be used to retrieve information about the
4565
predefined path; e.g., @code{"gnatls"}, @code{"powerpc-wrs-vxworks-gnatls"}.
4566
 
4567
@item VCS_Kind
4568
This is a simple attribute. Its value is a string used to specify the
4569
Version Control System (VCS) to be used for this project, e.g.@: CVS, RCS
4570
ClearCase or Perforce.
4571
 
4572
@item Gnat
4573
This is a simple attribute. Its value is a string that specifies the name
4574
of the @command{gnat} utility to be used when executing various tools from
4575
GPS, in particular @code{"gnat pp"}, @code{"gnat stub"},@dots{}
4576
 
4577
@item VCS_File_Check
4578
This is a simple attribute. Its value is a string that specifies the
4579
command used by the VCS to check the validity of a file, either
4580
when the user explicitly asks for a check, or as a sanity check before
4581
doing the check-in.
4582
 
4583
@item VCS_Log_Check
4584
This is a simple attribute. Its value is a string that specifies
4585
the command used by the VCS to check the validity of a log file.
4586
 
4587
@item VCS_Repository_Root
4588
The VCS repository root path. This is used to create tags or branches
4589
of the repository. For subversion the value should be the @code{URL}
4590
as specified to check-out the working copy of the repository.
4591
 
4592
@item VCS_Patch_Root
4593
The local root directory to use for building patch file. All patch chunks
4594
will be relative to this path. The root project directory is used if
4595
this value is not defined.
4596
 
4597
@end table

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