1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
742
743
744
745
746
747
748
749
750
751
752
753
754
755
756
757
758
759
760
761
762
763
764
765
766
767
768
769
770
771
772
773
774
775
776
777
778
779
780
781
782
783
784
785
786
787
788
789
790
791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
806
807
808
809
810
811
812
813
814
815
816
817
818
819
820
821
822
823
824
825
826
827
828
829
830
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
848
849
850
851
852
853
854
855
856
857
858
859
860
861
862
863
864
865
866
867
868
869
870
871
872
873
874
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
905
906
907
908
909
910
911
912
913
914
915
916
917
918
919
920
921
922
923
924
925
926
927
928
929
930
931
932
933
934
935
936
937
938
939
940
941
942
943
944
945
946
947
948
949
950
951
952
953
954
955
956
957
958
959
960
961
962
963
964
965
966
967
968
969
970
971
972
973
974
975
976
977
978
979
980
981
982
983
984
985
986
987
988
989
990
991
992
993
994
995
996
997
998
999
1000
1001
1002
1003
1004
1005
1006
1007
1008
1009
1010
1011
|
// file : libbuild2/b.cli
// license : MIT; see accompanying LICENSE file
include <set>;
include <libbuild2/common.cli>;
"\section=1"
"\name=b"
"\summary=build system driver"
namespace build2
{
{
"<options>
<variables>
<buildspec> <meta-operation> <operation> <target> <parameters>",
"\h|SYNOPSIS|
\c{\b{b --help}\n
\b{b --version}\n
\b{b} [<options>] [<variables>] [<buildspec>]}
\c{<buildspec> = <meta-operation>\b{(}<operation>\b{(}<target>...[\b{,}<parameters>]\b{)}...\b{)}...}
\h|DESCRIPTION|
The \cb{build2} build system driver executes a set of meta-operations on
operations on targets according to the build specification, or
\i{buildspec} for short. This process can be controlled by specifying
driver <options> and build system <variables>.
Note that <options>, <variables>, and <buildspec> fragments can be
specified in any order. To avoid treating an argument that starts with
\cb{'-'} as an option, add the \cb{'--'} separator. To avoid treating an
argument that contains \cb{'='} as a variable, add the second \cb{'--'}
separator."
}
// For usage it's nice to see the list of options on the first page. So
// let's not put this "extended" description into usage.
//
{
"<meta-operation> <operation> <target> <parameters> <src-base>",
"",
"All components in the buildspec can be omitted. If <meta-operation> is
omitted, then it defaults to \cb{perform}. If <operation> is omitted,
then it defaults to the default operation for this meta-operation. For
\cb{perform} it is \cb{update}. Finally, if <target> is omitted, then it
defaults to the current working directory. A meta-operation on operation
is called an \i{action}. Some operations and meta-operations may take
additional <parameters>. For example:
\
$ b # perform(update(./))
$ b foo/ # perform(update(foo/))
$ b foo/ bar/ # perform(update(foo/ bar/))
$ b update # perform(update(./))
$ b 'clean(../)' # perform(clean(../))
$ b perform # perform(update(./))
$ b configure # configure(?(./))
$ b 'configure(../)' # configure(?(../))
$ b clean update # perform(clean(./) update(./))
$ b configure update # configure(?(./)) perform(update(./))
$ b 'create(conf/, cxx)' # create(?(conf/), cxx)
\
Notice the question mark used to show the (imaginary) default operation
for the \cb{configure} meta-operation. For \cb{configure} the default
operation is \"all operations\". That is, it will configure all the
operations for the specified target.
You can also \"generate\" multiple operations for the same set of targets.
Compare:
\
$ b 'clean(foo/ bar/)' 'update(foo/ bar/)'
$ b '{clean update}(foo/ bar/)'
\
Some more useful buildspec examples:
\
$ b '{clean update}(...)' # rebuild
$ b '{clean update clean}(...)' # make sure builds
$ b '{clean test clean}(...)' # make sure passes tests
$ b '{clean disfigure}(...)' # similar to distclean
\
In POSIX shells parenthesis are special characters and must be quoted
when used in a buildspec. Besides being an inconvenience in itself,
quoting also inhibits path auto-completion. To help with this situation a
shortcut syntax is available for executing a single operation or
meta-operation, for example:
\
$ b clean: foo/ bar/ # clean(foo/ bar/)
$ b configure: src/@out/ # configure(src/@out/)
$ b create: conf/, cxx # create(conf/, cxx)
$ b configure: config.cxx=g++ src/ # configure(src/) config.cxx=g++
\
To activate the shortcut syntax the first buildspec argument must start
with an operation or meta-operation name and end with a colon (\cb{:}).
To transform the shortcut syntax to the normal buildspec syntax the colon
is replaced with the opening parenthesis ('\cb{(}'), the rest of the
buildspec arguments are treated as is, and the final closing parenthesis
('\cb{)}') is added.
For each <target> the driver expects to find \cb{buildfile} either in the
target's directory or, if the directory is part of the \cb{out} tree
(\cb{out_base}), in the corresponding \cb{src} directory (\cb{src_base}).
For example, assuming \cb{foo/} is the source directory of a project:
\
$ b foo/ # out_base=src_base=foo/
$ b foo-out/ # out_base=foo-out/ src_base=foo/
$ b foo-out/exe{foo} # out_base=foo-out/ src_base=foo/
\
An exception to this requirement is a directory target in which case,
provided the directory has subdirectories, an \i{implied} \cb{buildfile}
with the following content is assumed:
\
# Implied directory buildfile: build all subdirectories.
#
./: */
\
In the above example, we assumed that the build system driver was able to
determine the association between \cb{out_base} and \cb{src_base}. In
case \cb{src_base} and \cb{out_base} are not the same directory, this is
achieved in one of two ways: the \cb{config} module (which implements the
\cb{configure}, \cb{disfigure}, and \cb{create} meta-operations) saves
this association as part of the configuration process. If, however, the
association hasn't been saved, then we have to specify \cb{src_base}
explicitly using the following extended <target> syntax:
\c{<src-base>/@<target>}
Continuing with the previous example:
\
$ b foo/@foo-out/exe{foo} # out_base=foo-out/ src_base=foo/
\
Normally, you would need to specify \cb{src_base} explicitly only once,
during configuration. For example, a typical usage would be:
\
$ b configure: foo/@foo-out/ # src_base is saved
$ b foo-out/ # no need to specify src_base
$ b clean: foo-out/exe{foo} # no need to specify src_base
\
Besides in and out of source builds, \cb{build2} also supports
configuring a project's source directory as \i{forwarded} to an out of
source build. With such a forwarded configuration in place, if we run the
build system driver from the source directory, it will automatically
build in the output directory and \i{backlink} (using symlinks or another
suitable mechanism) certain \"interesting\" targets (executables,
documentation, etc) to the source directory for easy access. Continuing
with the previous example:
\
$ b configure: foo/@foo-out/,forward # foo/ forwarded to foo-out/
$ cd foo/
$ b # build in foo-out/
$ ./foo # symlink to foo-out/foo
\
The ability to specify \cb{build2} variables as part of the command line
is normally used to pass configuration values, for example:
\
$ b config.cxx=clang++ config.cxx.coptions=-O3
\
Similar to buildspec, POSIX shells often inhibit path auto-completion on
the right hand side of a variable assignment. To help with this situation
the assignment can be broken down into three separate command line
arguments, for example:
\
$ b config.import.libhello = ../libhello/
\
The build system has the following built-in and pre-defined
meta-operations:
\dl|
\li|\cb{perform}
Perform an operation.|
\li|\cb{configure}
Configure all operations supported by a project and save the result
in the project's \cb{build/config.build} file. Implemented by the
\cb{config} module. For example:
\
$ b configure \
config.cxx=clang++ \
config.cxx.coptions=-O3 \
config.install.root=/usr/local \
config.install.root.sudo=sudo
\
Use the \cb{forward} parameter to instead configure a source
directory as forwarded to an out of source build. For example:
\
$ b configure: src/@out/,forward
\
|
\li|\cb{disfigure}
Disfigure all operations supported by a project and remove the
project's \cb{build/config.build} file. Implemented by the
\cb{config} module.
Use the \cb{forward} parameter to instead disfigure forwarding of a
source directory to an out of source build. For example:
\
$ b disfigure: src/,forward
\
|
\li|\cb{create}
Create and configure a \i{configuration} project. Implemented by the
\cb{config} module.
Normally a \cb{build2} project is created manually by writing the
\cb{bootstrap.build} and \cb{config.build} files, adding source
files, and so on. However, a special kind of project, which we call
\i{configuration}, is often useful. Such a project doesn't have any
source files of its own. Instead, it serves as an amalgamation for
building other projects as part of it. Doing it this way has two
major benefits: sub-projects automatically resolve their imports
to other projects in the amalgamation and sub-projects inherits their
configuration from the amalgamation (which means if we want to change
something, we only need to do it in one place).
As an example, let's assume we have two C++ projects: the
\cb{libhello} library in \cb{libhello/} and the \cb{hello} executable
that imports it in \cb{hello/}. And we want to build \cb{hello} with
\cb{clang++}.
One way to do it would be to configure and build each project in its
own directory, for example:
\
$ b configure: libhello/@libhello-clang/ config.cxx=clang++
$ b configure: hello/@hello-clang/ config.cxx=clang++ \
config.import.libhello=libhello-clang/
\
The two drawbacks, as mentioned above, are the need to explicitly
resolve the import and having to make changes in multiple places
should, for example, we want to switch from \cb{clang++} to \cb{g++}.
We can, however, achieve the same end result but without any of the
drawbacks using the configuration project:
\
$ b create: clang/,cxx config.cxx=clang++ # Creates clang/.
$ b configure: libhello/@clang/libhello/
$ b configure: hello/@clang/hello/
\
The targets passed to the \cb{create} meta-operation must be
directories which should either not exist or be empty. For each
such directory \cb{create} first initializes a project as described
below and then configures it by executing the \cb{configure}
meta-operation.
The first optional parameter to \cb{create} is the list of modules to
load in \cb{root.build}. By default, \cb{create} appends \cb{.config}
to the names of these modules so that only their configurations are
loaded. You can override this behavior by specifying the period
(\cb{.}) after the module name. You can also instruct \cb{create} to
use the optional module load by prefixing the module name with the
question mark (\cb{?}).
The second optional parameter is the list of modules to load in
\cb{bootstrap.build}. If not specified, then the \cb{test},
\cb{dist}, and \cb{install} modules are loaded by default. The
\cb{config} module is always loaded first.
Besides creating project's \cb{bootstrap.build} and \cb{root.build},
\cb{create} also writes the root \cb{buildfile} with the following
contents:
\
./: {*/ -build/}
\
If used, this \cb{buildfile} will build all the sub-projects
currently present in the configuration.|
\li|\cb{dist}
Prepare a distribution containing all files necessary to perform all
operations in a project. Implemented by the \cb{dist} module.|
\li|\cb{info}
Print basic information (name, version, source and output
directories, etc) about one or more projects to \cb{stdout},
separating multiple projects with a blank line. Each project is
identified by its root directory target. For example (some output
is omitted):
\
$ b info: libfoo/ libbar/
project: libfoo
version: 1.0.0
src_root: /tmp/libfoo
out_root: /tmp/libfoo
project: libbar
version: 2.0.0
src_root: /tmp/libbar
out_root: /tmp/libbar-out
\
To instead print this information in the JSON format, use the
\cb{json} parameter, for example:
\
$ b info: libfoo/,json
\
In this case the output is a JSON array of objects which are the
serialized representation of the following C++ \cb{struct}
\cb{project_info}:
\
struct subproject
{
string path;
optional<string> name;
};
struct project_info
{
optional<string> project;
optional<string> version;
optional<string> summary;
optional<string> url;
string src_root;
string out_root;
optional<string> amalgamation;
vector<subproject> subprojects;
vector<string> operations;
vector<string> meta_operations;
vector<string> modules;
};
\
For example:
\
[
{
\"project\": \"libfoo\",
\"version\": \"1.0.0\",
\"summary\": \"libfoo C++ library\",
\"src_root\": \"/tmp/libfoo\",
\"out_root\": \"/tmp/gcc-debug/libfoo\",
\"amalgamation\": \"..\",
\"subprojects\": [
{
\"path\": \"tests\"
}
],
\"operations\": [
\"update\",
\"clean\",
\"test\",
\"update-for-test\",
\"install\",
\"uninstall\",
\"update-for-install\"
],
\"meta-operations\": [
\"perform\",
\"configure\",
\"disfigure\",
\"dist\",
\"info\"
],
\"modules\": [
\"version\",
\"config\",
\"test\",
\"install\",
\"dist\"
]
}
]
\
See the JSON OUTPUT section below for details on the overall
properties of this format and the semantics of the \cb{struct}
serialization.
||
The build system has the following built-in and pre-defined operations:
\dl|
\li|\cb{update}
Update a target.|
\li|\cb{clean}
Clean a target.|
\li|\cb{test}
Test a target. Performs \cb{update} as a pre-operation. Implemented by
the \cb{test} module.|
\li|\cb{update-for-test}
Update a target for testing. This operation is equivalent to the
\cb{update} pre-operation as executed by the \cb{test} operation and
can be used to only update what is necessary for testing. Implemented
by the \cb{test} module.|
\li|\cb{install}
Install a target. Performs \cb{update} as a pre-operation. Implemented
by the \cb{install} module.|
\li|\cb{uninstall}
Uninstall a target. Performs \cb{update} as a pre-operation.
Implemented by the \cb{install} module.|
\li|\cb{update-for-install}
Update a target for installation. This operation is equivalent to the
\cb{update} pre-operation as executed by the \cb{install} operation
and can be used to only update what is necessary for
installation. Implemented by the \cb{install} module.||
Note that buildspec and command line variable values are treated as
\cb{buildfile} fragments and so can use quoting and escaping as well as
contain variable expansions and evaluation contexts. However, to be more
usable on various platforms, escaping in these two situations is limited
to the \i{effective sequences} of \cb{\\'}, \cb{\\\"}, \cb{\\\\},
\cb{\\$}, and \cb{\\(} with all other sequences interpreted as is.
Together with double-quoting this is sufficient to represent any value.
For example:
\
$ b config.install.root=c:\projects\install
$ b \"config.install.root='c:\Program Files\test\'\"
$ b 'config.cxx.poptions=-DFOO_STR=\"foo\"'
\
"
}
class b_options
{
"\h#options|OPTIONS|"
uint64_t --build2-metadata; // Leave undocumented/hidden.
bool -v
{
"Print actual commands being executed. This options is equivalent to
\cb{--verbose 2}."
}
bool -V
{
"Print all underlying commands being executed. This options is
equivalent to \cb{--verbose 3}."
}
bool --quiet|-q
{
"Run quietly, only printing error messages in most contexts. In certain
contexts (for example, while updating build system modules) this
verbosity level may be ignored. Use \cb{--silent} to run quietly in all
contexts. This option is equivalent to \cb{--verbose 0}."
}
bool --silent
{
"Run quietly, only printing error messages in all contexts."
}
uint16_t --verbose = 1
{
"<level>",
"Set the diagnostics verbosity to <level> between 0 and 6. Level 0
disables any non-error messages (but see the difference between
\cb{--quiet} and \cb{--silent}) while level 6 produces lots of
information, with level 1 being the default. The following additional
types of diagnostics are produced at each level:
\ol|
\li|High-level information messages.|
\li|Essential underlying commands being executed.|
\li|All underlying commands being executed.|
\li|Information that could be helpful to the user.|
\li|Information that could be helpful to the developer.|
\li|Even more detailed information.||"
}
bool --stat
{
"Display build statistics."
}
bool --progress
{
"Display build progress. If printing to a terminal the progress is
displayed by default for low verbosity levels. Use \cb{--no-progress}
to suppress."
}
bool --no-progress
{
"Don't display build progress."
}
bool --diag-color
{
"Use color in diagnostics. If printing to a terminal the color is used
by default provided the terminal is not dumb. Use \cb{--no-diag-color}
to suppress.
This option affects the diagnostics printed by the build system itself.
Some rules may also choose to propagate its value to tools (such as
compilers) that they invoke."
}
bool --no-diag-color
{
"Don't use color in diagnostics."
}
size_t --jobs|-j
{
"<num>",
"Number of active jobs to perform in parallel. This includes both the
number of active threads inside the build system as well as the number
of external commands (compilers, linkers, etc) started but not yet
finished. If this option is not specified or specified with the \cb{0}
value, then the number of available hardware threads is used."
}
size_t --max-jobs|-J
{
"<num>",
"Maximum number of jobs (threads) to create. The default is 8x the
number of active jobs (\cb{--jobs|j}) on 32-bit architectures and 32x
on 64-bit. See the build system scheduler implementation for details."
}
size_t --queue-depth|-Q = 4
{
"<num>",
"The queue depth as a multiplier over the number of active jobs.
Normally we want a deeper queue if the jobs take long (for example,
compilation) and shorter if they are quick (for example, simple tests).
The default is 4. See the build system scheduler implementation for
details."
}
string --file-cache
{
"<impl>",
"File cache implementation to use for intermediate build results. Valid
values are \cb{noop} (no caching or compression) and \cb{sync-lz4} (no
caching with synchronous LZ4 on-disk compression). If this option is
not specified, then a suitable default implementation is used
(currently \cb{sync-lz4})."
}
size_t --max-stack
{
"<num>",
"The maximum stack size in KBytes to allow for newly created threads.
For \i{pthreads}-based systems the driver queries the stack size of
the main thread and uses the same size for creating additional threads.
This allows adjusting the stack size using familiar mechanisms, such
as \cb{ulimit}. Sometimes, however, the stack size of the main thread
is excessively large. As a result, the driver checks if it is greater
than a predefined limit (64MB on 64-bit systems and 32MB on 32-bit
ones) and caps it to a more sensible value (8MB) if that's the case.
This option allows you to override this check with the special zero
value indicating that the main thread stack size should be used as is."
}
bool --serial-stop|-s
{
"Run serially and stop at the first error. This mode is useful to
investigate build failures that are caused by build system errors
rather than compilation errors. Note that if you don't want to keep
going but still want parallel execution, add \cb{--jobs|-j} (for
example \cb{-j\ 0} for default concurrency). Note also that during
serial execution there is no diagnostics buffering and child
process' \cb{stderr} is a terminal (unless redirected; see
\cb{--no-diag-buffer} for details)."
}
bool --dry-run|-n
{
"Print commands without actually executing them. Note that commands
that are required to create an accurate build state will still be
executed and the extracted auxiliary dependency information saved. In
other words, this is not the \i{\"don't touch the filesystem\"} mode
but rather \i{\"do minimum amount of work to show what needs to be
done\"}. Note also that only the \cb{perform} meta-operation supports
this mode."
}
bool --no-diag-buffer
{
"Do not buffer diagnostics from child processes. By default, unless
running serially, such diagnostics is buffered and printed all at
once after each child exits in order to prevent interleaving.
However, this can have side-effects since the child process'
\cb{stderr} is no longer a terminal. Most notably, the use of
color in diagnostics may be disabled by some programs. On the
other hand, depending on the platform and programs invoked, the
interleaving diagnostics may not break lines and thus could be
tolerable."
}
bool --match-only
{
"Match the rules but do not execute the operation. This mode is primarily
useful for profiling."
}
bool --no-external-modules
{
"Don't load external modules during project bootstrap. Note that this
option can only be used with meta-operations that do not load the
project's \cb{buildfiles}, such as \cb{info}."
}
structured_result_format --structured-result
{
"<fmt>",
"Write the result of execution in a structured form. In this mode,
instead of printing to \cb{stderr} diagnostics messages about the
outcome of executing actions on targets, the driver writes to
\cb{stdout} a machine-readable result description in the specified
format. Valid values for this option are \cb{lines} and \cb{json}.
Note that currently only the \cb{perform} meta-operation supports
the structured result output.
If the output format is \cb{lines}, then the result is written one line
per the buildspec action/target pair. Each line has the following form:
\c{\i{state} \i{meta-operation} \i{operation} \i{target}}
Where \ci{state} can be one of \cb{unchanged}, \cb{changed}, or
\cb{failed}. If the action is a pre or post operation, then the
outer operation is specified in parenthesis. For example:
\
unchanged perform update(test) /tmp/dir{hello/}
changed perform test /tmp/hello/exe{test}
\
If the output format is \cb{json}, then the output is a JSON array of
objects which are the serialized representation of the following C++
\cb{struct} \cb{target_action_result}:
\
struct target_action_result
{
string target;
string quoted_target;
string target_type;
optional<string> target_path;
string meta_operation;
string operation;
optional<string> outer_operation;
string state;
};
\
For example:
\
[
{
\"target\": \"/tmp/dir{hello/}\",
\"quoted_target\": \"/tmp/dir{hello/}\",
\"target_type\": \"dir\",
\"target_path\": \"/tmp/hello\",
\"meta_operation\": \"perform\",
\"operation\": \"update\",
\"outer_operation\": \"test\",
\"state\": \"unchanged\"
},
{
\"target\": \"/tmp/dir{hello/}\",
\"quoted_target\": \"/tmp/dir{hello/}\",
\"target_type\": \"dir\",
\"target_path\": \"/tmp/hello\",
\"meta_operation\": \"perform\",
\"operation\": \"test\",
\"state\": \"changed\"
}
]
\
See the JSON OUTPUT section below for details on the overall
properties of this format and the semantics of the \cb{struct}
serialization.
The \cb{target} member is a \"display\" target name, the same as in the
\cb{lines} format. The \cb{quoted_target} member is a target name that,
if required, is quoted so that it can be passed back to the driver on
the command line. The \cb{target_type} member is the type of target.
The \cb{target_path} member is an absolute path to the target if the
target type is path-based or \cb{dir}.
"
}
bool --mtime-check
{
"Perform file modification time sanity checks. These checks can be
helpful in diagnosing spurious rebuilds and are enabled by default
on Windows (which is known not to guarantee monotonically increasing
mtimes) and for the staged version of the build system on other
platforms. Use \cb{--no-mtime-check} to disable."
}
bool --no-mtime-check
{
"Don't perform file modification time sanity checks. See
\cb{--mtime-check} for details."
}
std::set<string> --dump
{
"<phase>",
"Dump the build system state after the specified phase. Valid <phase>
values are \cb{load} (after loading \cb{buildfiles}) and \cb{match}
(after matching rules to targets). Repeat this option to dump the
state after multiple phases."
}
std::vector<name> --trace-match
{
"<target>",
"Trace rule matching for the specified target. This is primarily useful
during troubleshooting. Repeat this option to trace multiple targets."
}
std::vector<name> --trace-execute
{
"<target>",
"Trace rule execution for the specified target. This is primarily useful
during troubleshooting. Repeat this option to trace multiple targets."
}
bool --no-column
{
"Don't print column numbers in diagnostics."
}
bool --no-line
{
"Don't print line and column numbers in diagnostics."
}
path --buildfile
{
"<path>",
"The alternative file to read build information from. The default is
\cb{buildfile} or \cb{build2file}, depending on the project's build
file/directory naming scheme. If <path> is '\cb{-}', then read from
\cb{stdin}. Note that this option only affects the files read as part
of the buildspec processing. Specifically, it has no effect on the
\cb{source} and \cb{include} directives. As a result, this option is
primarily intended for testing rather than changing the build file
names in real projects."
}
path --config-guess
{
"<path>",
"The path to the \cb{config.guess(1)} script that should be used to
guess the host machine triplet. If this option is not specified, then
\cb{b} will fall back on to using the target it was built for as host."
}
path --config-sub
{
"<path>",
"The path to the \cb{config.sub(1)} script that should be used to
canonicalize machine triplets. If this option is not specified, then
\cb{b} will use its built-in canonicalization support which should
be sufficient for commonly-used platforms."
}
string --pager // String to allow empty value.
{
"<path>",
"The pager program to be used to show long text. Commonly used pager
programs are \cb{less} and \cb{more}. You can also specify additional
options that should be passed to the pager program with
\cb{--pager-option}. If an empty string is specified as the pager
program, then no pager will be used. If the pager program is not
explicitly specified, then \cb{b} will try to use \cb{less}. If it
is not available, then no pager will be used."
}
strings --pager-option
{
"<opt>",
"Additional option to be passed to the pager program. See \cb{--pager}
for more information on the pager program. Repeat this option to
specify multiple pager options."
}
// The following option is "fake" in that it is actually handled by
// argv_file_scanner. We have it here for documentation.
//
string --options-file
{
"<file>",
"Read additional options from <file>. Each option should appear on a
separate line optionally followed by space or equal sign (\cb{=}) and
an option value. Empty lines and lines starting with \cb{#} are
ignored. Option values can be enclosed in double (\cb{\"}) or single
(\cb{'}) quotes to preserve leading and trailing whitespaces as well as
to specify empty values. If the value itself contains trailing or
leading quotes, enclose it with an extra pair of quotes, for example
\cb{'\"x\"'}. Non-leading and non-trailing quotes are interpreted as
being part of the option value.
The semantics of providing options in a file is equivalent to providing
the same set of options in the same order on the command line at the
point where the \cb{--options-file} option is specified except that
the shell escaping and quoting is not required. Repeat this option
to specify more than one options file."
}
dir_path --default-options
{
"<dir>",
"The directory to load additional default options files from."
}
bool --no-default-options
{
"Don't load default options files."
}
bool --help {"Print usage information and exit."}
bool --version {"Print version and exit."}
};
"
\h|DEFAULT OPTIONS FILES|
Instead of having a separate config file format for tool configuration, the
\cb{build2} toolchain uses \i{default options files} which contain the same
options as what can be specified on the command line. The default options
files are like options files that one can specify with \cb{--options-file}
except that they are loaded by default.
The default options files for the build system driver are called
\cb{b.options} and are searched for in the \cb{.build2/} subdirectory of the
home directory and in the system directory (for example, \cb{/etc/build2/})
if configured. Note that besides options these files can also contain global
variable overrides.
Once the search is complete, the files are loaded in the reverse order, that
is, beginning from the system directory (if any), followed by the home
directory, and finishing off with the options specified on the command line.
In other words, the files are loaded from the more generic to the more
specific with the command line options having the ability to override any
values specified in the default options files.
If a default options file contains \cb{--no-default-options}, then the
search is stopped at the directory containing this file and no outer files
are loaded. If this option is specified on the command line, then none of
the default options files are searched for or loaded.
An additional directory containing default options files can be specified
with \cb{--default-options}. Its configuration files are loaded after the
home directory.
The order in which default options files are loaded is traced at the
verbosity level 3 (\cb{-V} option) or higher.
\h|JSON OUTPUT|
Commands that support the JSON output specify their formats as a
serialized representation of a C++ \cb{struct} or an array thereof. For
example:
\
struct package
{
string name;
};
struct configuration
{
uint64_t id;
string path;
optional<string> name;
bool default;
vector<package> packages;
};
\
An example of the serialized JSON representation of \cb{struct}
\cb{configuration}:
\
{
\"id\": 1,
\"path\": \"/tmp/hello-gcc\",
\"name\": \"gcc\",
\"default\": true,
\"packages\": [
{
\"name\": \"hello\"
}
]
}
\
This sections provides details on the overall properties of such formats
and the semantics of the \cb{struct} serialization.
The order of members in a JSON object is fixed as specified in the
corresponding \cb{struct}. While new members may be added in the
future (and should be ignored by older consumers), the semantics of the
existing members (including whether the top-level entry is an object or
array) may not change.
An object member is required unless its type is \cb{optional<>},
\cb{bool}, or \cb{vector<>} (array). For \cb{bool} members absent means
\cb{false}. For \cb{vector<>} members absent means empty. An empty
top-level array is always present.
For example, the following JSON text is a possible serialization of
the above \cb{struct} \cb{configuration}:
\
{
\"id\": 1,
\"path\": \"/tmp/hello-gcc\"
}
\
\h|EXIT STATUS|
Non-zero exit status is returned in case of an error.
"
// NOTE: remember to update --build2-metadata output if adding any relevant
// new environment variables.
//
"
\h|ENVIRONMENT|
The \cb{HOME} environment variable is used to determine the user's home
directory. If it is not set, then \cb{getpwuid(3)} is used instead. This
value is used to shorten paths printed in diagnostics by replacing the home
directory with \cb{~/}. It is also made available to \cb{buildfile}'s as the
\cb{build.home} variable.
The \cb{BUILD2_VAR_OVR} environment variable is used to propagate global
variable overrides to nested build system driver invocations. Its value is a
list of global variable assignments separated with newlines.
The \cb{BUILD2_DEF_OPT} environment variable is used to suppress loading of
default options files in nested build system driver invocations. Its values
are \cb{false} or \cb{0} to suppress and \cb{true} or \cb{1} to load.
"
}
|