Add initial Python bindings documentation
[babeltrace.git] / CONTRIBUTING.adoc
1 // Render with Asciidoctor
2
3 = Babeltrace contributor's guide
4 Jérémie Galarneau, Philippe Proulx
5 v0.2, 19 June 2019
6 :toc:
7 :toclevels: 5
8
9
10 This is a partial contributor's guide for the
11 https://babeltrace.org[Babeltrace] project. If you have any
12 questions that are not answered by this guide, please post them on
13 https://lists.lttng.org/cgi-bin/mailman/listinfo/lttng-dev[Babeltrace's
14 mailing list].
15
16
17 == Babeltrace library
18
19 === Object reference counting and lifetime
20
21 This section covers the rationale behind the design of Babeltrace's
22 object lifetime management. This applies to the Babeltrace library, as
23 well as to the CTF writer library (although the public reference
24 counting functions are not named the same way).
25
26 Starting from Babeltrace 2.0, all publicly exposed objects inherit a
27 common base: `bt_object`. This base provides a number of facilities to
28 all objects, chief amongst which are lifetime management functions.
29
30 The lifetime of some public objects is managed by reference counting. In
31 this case, the API offers the `+bt_*_get_ref()+` and `+bt_*_put_ref()+`
32 functions which respectively increment and decrement an object's
33 reference count.
34
35 As far as lifetime management in concerned, Babeltrace makes a clear
36 distinction between regular objects, which have a single parent, and
37 root objects, which don't.
38
39
40 ==== The problem
41
42 Let us consider a problematic case to illustrate the need for this
43 distinction.
44
45 A user of the Babeltrace library creates a trace class, which _has_ a
46 stream class (the class of a stream) and that stream class, in turn,
47 _has_ an event class (the class of an event).
48
49 Nothing prevents this user from releasing his reference on any one of
50 these objects in any order. However, all objects in the
51 __trace--stream class--event class__ hierarchy can be retrieved
52 from any other.
53
54 For instance, the user could discard his reference on both the event
55 class and the stream class, only keeping a reference on the trace class.
56 From this trace class reference, stream classes can be enumerated,
57 providing the user with a new reference to the stream class he discarded
58 earlier. Event classes can also be enumerated from stream classes,
59 providing the user with references to the individual event classes.
60
61 Conversely, the user could also hold a reference to an event class and
62 retrieve its parent stream class. The trace class, in turn, can then be
63 retrieved from the stream class.
64
65 This example illustrates what could be interpreted as a circular
66 reference dependency existing between these objects. Of course, if the
67 objects in such a scenario were to hold references to each other (in
68 both directions), we would be in presence of a circular ownership
69 resulting in a leak of both objects as their reference counts would
70 never reach zero.
71
72 Nonetheless, the API must offer the guarantee that holding a node to any
73 node of the graph keeps all other reachable nodes alive.
74
75
76 ==== The solution
77
78 The scheme employed in Babeltrace to break this cycle consists in the
79 "children" holding _reverse component references_ to their parents. That
80 is, in the context of the trace IR, that event classes hold a reference
81 to their parent stream class and stream classes hold a reference to
82 their parent trace class.
83
84 On the other hand, parents hold _claiming aggregation references_ to
85 their children. A claiming aggregation reference means that the object
86 being referenced should not be deleted as long as the reference still
87 exists. In this respect, it can be said that parents truly hold the
88 ownership of their children, since they control their lifetime.
89 Conversely, the reference counting mechanism is leveraged by children to
90 notify parents that no other child indirectly exposes the parent.
91
92 When a parented object's reference count reaches zero, it invokes
93 `+bt_*_put_ref()+` on its parent and does _not_ free itself. However,
94 from that point, the object depends on its parent to signal the moment
95 when it can be safely reclaimed.
96
97 The invocation of `+bt_*_put_ref()+` by the last children holding a
98 reference to its parent might trigger a cascade of `+bt_*_put_ref()+`
99 from child to parent. Eventually, a **root** object is reached. At that
100 point, if this orphaned object's reference count reaches zero, the
101 object invokes the destructor method defined by everyone of its children
102 as part of their base `struct bt_object`. The key point here is that the
103 cascade of destructor will necessarily originate from the root and
104 propagate in preorder to the children. These children will propagate the
105 destruction to their own children before reclaiming their own memory.
106 This ensures that a node's pointer to its parent is _always_ valid since
107 the parent has the responsibility of tearing-down their children before
108 cleaning themselves up.
109
110 Assuming a reference to an object is _acquired_ by calling
111 `+bt_*_get_ref()+` while its reference count is zero, the object
112 acquires, in turn, a reference on its parent using `+bt_*_get_ref()+`.
113 At that point, the child can be thought of as having converted its weak
114 reference to its parent into a regular reference. That is why this
115 reference is referred to as a _claiming_ aggregation reference.
116
117
118 ==== Caveats
119
120 This scheme imposes a number of strict rules defining the relation
121 between objects:
122
123 * Objects may only have one parent.
124 * Objects, beside the root, are only retrievable from their direct
125 parent or children.
126
127
128 ==== Example
129
130 The initial situation is rather simple: **User{nbsp}A** is holding a
131 reference to a trace class, **TC1**. As per the rules previously
132 enounced, stream classes **SC1** and **SC2** don't hold a reference to
133 **TC1** since their own reference counts are zero. The same holds true
134 for **EC1**, **EC2** and **EC3** with respect to **SC1** and **SC2**.
135
136 image::doc/contributing-images/bt-ref01.png[]
137
138 In this second step, we can see that **User{nbsp}A** has acquired a
139 reference on **SC2** through the trace class, **TC1**.
140
141 The stream class's reference count transitions from zero to one,
142 triggering the acquisition of a strong reference on **TC1** from
143 **SC2**.
144
145 Hence, at this point, the trace class's ownership is shared by
146 **User{nbsp}A** and **SC2**.
147
148 image::doc/contributing-images/bt-ref02.png[]
149
150 Next, **User{nbsp}A** acquires a reference on the **EC3** event class
151 through its parent stream class, **SC2**. Again, the transition of an
152 object's reference count from 0 to 1 triggers the acquisition of a
153 reference on its parent.
154
155 Note that SC2's reference count was incremented to 2. The trace class's
156 reference count remains unchanged.
157
158 image::doc/contributing-images/bt-ref03.png[]
159
160 **User{nbsp}A** decides to drop its reference on **SC2**. **SC2**'s
161 reference count returns back to 1, everything else remaining unchanged.
162
163 image::doc/contributing-images/bt-ref04.png[]
164
165 **User{nbsp}A** can then decide to drop its reference on the trace
166 class. This results in a reversal of the initial situation:
167 **User{nbsp}A** now owns an event, **EC3**, which is keeping everything
168 else alive and reachable.
169
170 image::doc/contributing-images/bt-ref05.png[]
171
172 If another object, **User{nbsp}B**, enters the picture and acquires a
173 reference on the **SC1** stream class, we see that **SC1**'s reference
174 count transitioned from 0 to 1, triggering the acquisition of a
175 reference on **TC1**.
176
177 image::doc/contributing-images/bt-ref06.png[]
178
179 **User{nbsp}B** hands off a reference to **EC1**, acquired through
180 **SC1**, to another object, **User{nbsp}C**. The acquisition of a
181 reference on **EC1**, which transitions from 0 to 1, triggers the
182 acquisition of a reference on its parent, **SC1**.
183
184 image::doc/contributing-images/bt-ref07.png[]
185
186 At some point, **User{nbsp}A** releases its reference on **EC3**. Since
187 **EC3**'s reference count transitions to zero, it releases its reference
188 on **SC2**. **SC2**'s reference count, in turn, reaches zero and it
189 releases its reference to **TC1**.
190
191 **TC1**'s reference count is now 1 and no further action is taken.
192
193 image::doc/contributing-images/bt-ref08.png[]
194
195 **User{nbsp}B** releases its reference on **SC1**. **User{nbsp}C**
196 becomes the sole owner of the whole hierarchy through his ownership of
197 **EC1**.
198
199 image::doc/contributing-images/bt-ref09.png[]
200
201 Finally, **User{nbsp}C** releases his ownership of **EC1**, triggering
202 the release of the whole hierarchy. Let's walk through the reclamation
203 of the whole graph.
204
205 Mirroring what happened when **User{nbsp}A** released its last reference
206 on **EC3**, the release of **EC1** by **User{nbsp}C** causes its
207 reference count to fall to zero.
208
209 This transition to zero causes **EC1** to release its reference on
210 **SC1**. **SC1**'s reference count reaching zero causes it to release
211 its reference on **TC1**.
212
213 image::doc/contributing-images/bt-ref10.png[]
214
215 Since the reference count of **TC1**, a root object, has reached zero,
216 it invokes the destructor method on its children. This method is
217 recursive and causes the stream classes to call the destructor method on
218 their event classes.
219
220 The event classes are reached and, having no children of their own, are
221 reclaimed.
222
223 image::doc/contributing-images/bt-ref11.png[]
224
225 The stream classes having destroyed their children, are then reclaimed
226 by the trace class.
227
228 image::doc/contributing-images/bt-ref12.png[]
229
230 Finally, the stream classes having been reclaimed, **TC1** is reclaimed.
231
232 image::doc/contributing-images/bt-ref13.png[]
233
234
235 == Logging
236
237 Logging is a great instrument for a developer to be able to collect
238 information about a running software.
239
240 Babeltrace is a complex software with many layers. When a Babeltrace
241 graph fails to run, what caused the failure? It could be caused by any
242 component, any message iterator, and any deeply nested validation of a
243 CTF IR object (within the `ctf` plugin), for example. With the
244 appropriate logging statements manually placed in the source code, we
245 can find the cause of a bug faster.
246
247 While <<choose-a-log-level,care must be taken>> when placing _DEBUG_ to
248 _FATAL_ logging statements, you should liberally instrument your
249 Babeltrace module with _TRACE_ logging statements to help future you
250 and other developers understand what's happening at run time.
251
252
253 === Logging API
254
255 The Babeltrace logging API is internal: it is not exposed to the users
256 of the library; only to their developers. The only thing that a library
257 user can control is the current log level of the library itself with
258 `bt_logging_set_global_level()` and the initial library's log level with
259 the `LIBBABELTRACE2_INIT_LOG_LEVEL` environment variable.
260
261 This API is based on https://github.com/wonder-mice/zf_log[zf_log], a
262 lightweight, yet featureful, MIT-licensed core logging library for C and
263 pass:[C++]. The zf_log source files were modified to have the `BT_` and
264 `bt_` prefixes, and other small changes, like color support and using
265 the project's `BT_DEBUG_MODE` definition instead of the standard
266 `NDEBUG`.
267
268 The logging functions are implemented in the logging convenience
269 library (`src/logging` directory).
270
271
272 [[logging-headers]]
273 ==== Headers
274
275 The logging API headers are:
276
277 `<babeltrace2/logging.h>`::
278 Public header which a library user can use to set and get
279 libbabeltrace2's current log level.
280
281 `"logging/log.h"`::
282 Internal, generic logging API which you can use in any Babeltrace
283 module. This is the translation of `zf_log.h`.
284 +
285 This header offers the <<gen-logging-statements,generic logging
286 statement macros>>.
287
288 `"lib/logging.h"`::
289 Specific internal header to use within the library.
290 +
291 This header defines `BT_LOG_OUTPUT_LEVEL` to a custom, library-wide
292 hidden symbol which is the library's current log level before including
293 `"logging/log.h"`.
294 +
295 This header offers the <<lib-logging-statements,library-specific logging
296 statement macros>>.
297
298 `"logging/comp-logging.h"`::
299 Specific internal header to use within a component class.
300 +
301 This header offers the <<comp-logging-statements,component-specific
302 logging statement macros>>.
303
304
305 [[log-levels]]
306 ==== Log levels
307
308 The internal logging API offers the following log levels, in ascending
309 order of severity:
310
311 [options="header,autowidth",cols="4"]
312 |===
313 |Log level name
314 |Log level short name
315 |Internal API enumerator
316 |Public API enumerator
317
318 |_TRACE_
319 |`T`
320 |`BT_LOG_TRACE`
321 |`BT_LOGGING_LEVEL_TRACE`
322
323 |_DEBUG_
324 |`D`
325 |`BT_LOG_DEBUG`
326 |`BT_LOGGING_LEVEL_DEBUG`
327
328 |_INFO_
329 |`I`
330 |`BT_LOG_INFO`
331 |`BT_LOGGING_LEVEL_INFO`
332
333 |_WARNING_
334 |`W`
335 |`BT_LOG_WARNING`
336 |`BT_LOGGING_LEVEL_WARNING`
337
338 |_ERROR_
339 |`E`
340 |`BT_LOG_ERROR`
341 |`BT_LOGGING_LEVEL_ERROR`
342
343 |_FATAL_
344 |`F`
345 |`BT_LOG_FATAL`
346 |`BT_LOGGING_LEVEL_FATAL`
347
348 |_NONE_
349 |`N`
350 |`BT_LOG_NONE`
351 |`BT_LOGGING_LEVEL_NONE`
352 |===
353
354 The short name is accepted by the log level environment variables and by
355 the CLI's `--log-level` options.
356
357 See <<choose-a-log-level,how to decide which one to use>> below.
358
359 There are two important log level expressions:
360
361 [[build-time-log-level]]Build-time, minimal log level::
362 The minimal log level, or build-time log level, is set at build time
363 and determines the minimal log level of the logging statements which
364 can be executed. This applies to all the modules (CLI, library,
365 plugins, bindings, etc.).
366 +
367 All the logging statements with a level below this level are **not built
368 at all**. All the logging statements with a level equal to or greater
369 than this level _can_ be executed, depending on the
370 <<run-time-log-level,run-time log level>>.
371 +
372 You can set this level at configuration time with the
373 `BABELTRACE_MINIMAL_LOG_LEVEL` environment variable, for example:
374 +
375 --
376 ----
377 $ BABELTRACE_MINIMAL_LOG_LEVEL=INFO ./configure
378 ----
379 --
380 +
381 The default build-time log level is `DEBUG`. For optimal performance,
382 set it to `INFO`, which effectively disables all fast path logging in
383 all the Babeltrace modules. You can't set it to `WARNING`, `ERROR`,
384 `FATAL`, or `NONE` because the impact on performance is minuscule
385 starting from the _INFO_ log level anyway and we want any Babeltrace
386 build to always be able to print _INFO_-level logs.
387 +
388 The library's public API provides `bt_logging_get_minimal_level()` to
389 get the configured minimal log level.
390
391 [[run-time-log-level]]Run-time, dynamic log level::
392 The dynamic log level is set at run time and determines the current,
393 _active_ log level. All the logging statements with a level below
394 this level are not executed, **but they still evaluate the
395 condition**. All the logging statements with a level equal to or
396 greater than this level are executed, provided that their level is
397 also <<build-time-log-level,enabled at build time>>.
398 +
399 `zf_log` has a concept of a global run-time log level which uses the
400 `_bt_log_global_output_lvl` symbol. In practice, we never use this
401 symbol, and always make sure that `BT_LOG_OUTPUT_LEVEL` is defined to a
402 module-wise expression before including `"logging/log.h"`.
403 +
404 In the library, `"lib/logging.h"` defines its own
405 `BT_LOG_OUTPUT_LEVEL` to the library's log level symbol before it
406 includes `"logging/log.h"` itself.
407 +
408 In libbabeltrace2, the user can set the current run-time log level with
409 the `bt_logging_set_global_level()` function, for example:
410 +
411 --
412 [source,c]
413 ----
414 bt_logging_set_global_level(BT_LOGGING_LEVEL_INFO);
415 ----
416 --
417 +
418 The library's initial run-time log level is defined by the
419 `LIBBABELTRACE2_INIT_LOG_LEVEL` environment variable, or set to _NONE_
420 if this environment variable is undefined.
421 +
422 Other modules have their own way of setting their run-time log level.
423 +
424 For example, the CLI uses the `BABELTRACE_CLI_LOG_LEVEL` environment
425 variable, as well as its global `--log-level` option:
426 +
427 ----
428 $ babeltrace2 --log-level=I ...
429 ----
430 +
431 The components use their own log level (as returned by
432 `bt_component_get_logging_level()`). With the CLI, you can set a
433 specific component's log level with its own, position-dependent
434 `--log-level` option:
435 +
436 ----
437 $ babeltrace2 /path/to/trace -c sink.ctf.fs --log-level=D
438 ----
439 +
440 Code which is common to the whole project, for example `src/common`
441 and `src/compat`, use function parameters to get its run-time log
442 level, for example:
443 +
444 [source,c]
445 ----
446 BT_HIDDEN
447 char *bt_common_get_home_plugin_path(int log_level);
448 ----
449 +
450 Typically, when a logging-enabled module calls such a function, it
451 passes its own log level expression directly (`BT_LOG_OUTPUT_LEVEL`):
452 +
453 [source,c]
454 ----
455 path = bt_common_get_home_plugin_path(BT_LOG_OUTPUT_LEVEL);
456 ----
457 +
458 Otherwise, just pass `BT_LOG_NONE`:
459 +
460 ----
461 path = bt_common_get_home_plugin_path(BT_LOG_NONE);
462 ----
463
464
465 [[gen-logging-statements]]
466 ==== Generic logging statement macros
467
468 The Babeltrace logging statement macros work just like `printf()`
469 (except the `+BT_LOG*_STR()+` ones) and contain their <<log-levels,log
470 level>> (short name) in their name.
471
472 Each of the following macros evaluate the
473 <<build-time-log-level,build-time log level>> definition and
474 <<run-time-log-level,run-time log level>> expression (as defined by
475 `BT_LOG_OUTPUT_LEVEL`) to log conditionally.
476
477 See <<logging-instrument-c-file-gen,Instrument a C source file
478 (generic)>> and <<logging-instrument-h-file-gen,Instrument a C header
479 file (generic)>> to learn how to be able to use the following macros.
480
481 `+BT_LOGT("format string", ...)+`::
482 Generic trace logging statement.
483
484 `+BT_LOGD("format string", ...)+`::
485 Generic debug logging statement.
486
487 `+BT_LOGI("format string", ...)+`::
488 Generic info logging statement.
489
490 `+BT_LOGW("format string", ...)+`::
491 Generic warning logging statement.
492
493 `+BT_LOGE("format string", ...)+`::
494 Generic error logging statement.
495
496 `+BT_LOGF("format string", ...)+`::
497 Generic fatal logging statement.
498
499 `+BT_LOGT_STR("preformatted string")+`::
500 Generic preformatted string trace logging statement.
501
502 `+BT_LOGD_STR("preformatted string")+`::
503 Generic preformatted string debug logging statement.
504
505 `+BT_LOGI_STR("preformatted string")+`::
506 Generic preformatted string info logging statement.
507
508 `+BT_LOGW_STR("preformatted string")+`::
509 Generic preformatted string warning logging statement.
510
511 `+BT_LOGE_STR("preformatted string")+`::
512 Generic preformatted string error logging statement.
513
514 `+BT_LOGF_STR("preformatted string")+`::
515 Generic preformatted string fatal logging statement.
516
517 `+BT_LOGT_MEM(data_ptr, data_size, "format string", ...)+`::
518 Generic memory trace logging statement.
519
520 `+BT_LOGD_MEM(data_ptr, data_size, "format string", ...)+`::
521 Generic memory debug logging statement.
522
523 `+BT_LOGI_MEM(data_ptr, data_size, "format string", ...)+`::
524 Generic memory info logging statement.
525
526 `+BT_LOGW_MEM(data_ptr, data_size, "format string", ...)+`::
527 Generic memory warning logging statement.
528
529 `+BT_LOGE_MEM(data_ptr, data_size, "format string", ...)+`::
530 Generic memory error logging statement.
531
532 `+BT_LOGF_MEM(data_ptr, data_size, "format string", ...)+`::
533 Generic memory fatal logging statement.
534
535 `+BT_LOGT_ERRNO("initial message", "format string", ...)+`::
536 Generic `errno` string trace logging statement.
537
538 `+BT_LOGD_ERRNO("initial message", "format string", ...)+`::
539 Generic `errno` string debug logging statement.
540
541 `+BT_LOGI_ERRNO("initial message", "format string", ...)+`::
542 Generic `errno` string info logging statement.
543
544 `+BT_LOGW_ERRNO("initial message", "format string", ...)+`::
545 Generic `errno` string warning logging statement.
546
547 `+BT_LOGE_ERRNO("initial message", "format string", ...)+`::
548 Generic `errno` string error logging statement.
549
550 `+BT_LOGF_ERRNO("initial message", "format string", ...)+`::
551 Generic `errno` string fatal logging statement.
552
553
554 [[lib-logging-statements]]
555 ==== Library-specific logging statement macros
556
557 The Babeltrace library contains an internal logging API based on the
558 generic logging framework. You can use it to log known Babeltrace
559 objects without having to manually log each member.
560
561 See <<logging-instrument-c-file-lib,Instrument a library C source file>>
562 and <<logging-instrument-h-file-lib,Instrument a library C header file>> to
563 learn how to be able to use the following macros.
564
565 The library logging statement macros are named `+BT_LIB_LOG*()+` instead
566 of `+BT_LOG*()+`:
567
568 `+BT_LIB_LOGT("format string", ...)+`::
569 Library trace logging statement.
570
571 `+BT_LIB_LOGD("format string", ...)+`::
572 Library debug logging statement.
573
574 `+BT_LIB_LOGI("format string", ...)+`::
575 Library info logging statement.
576
577 `+BT_LIB_LOGW("format string", ...)+`::
578 Library warning logging statement.
579
580 `+BT_LIB_LOGE("format string", ...)+`::
581 Library error logging statement.
582
583 `+BT_LIB_LOGF("format string", ...)+`::
584 Library fatal logging statement.
585
586 `+BT_LIB_LOGW_APPEND_CAUSE("format string", ...)+`::
587 Library warning logging statement, and unconditional error cause
588 appending.
589
590 `+BT_LIB_LOGE_APPEND_CAUSE("format string", ...)+`::
591 Library error logging statement, and unconditional error cause
592 appending.
593
594 `+BT_LIB_LOGF_APPEND_CAUSE("format string", ...)+`::
595 Library fatal logging statement, and unconditional error cause
596 appending.
597
598 The macros above accept the typical `printf()` conversion specifiers
599 with the following limitations:
600
601 * The `+*+` width specifier is not accepted.
602 * The `+*+` precision specifier is not accepted.
603 * The `j` and `t` length modifiers are not accepted.
604 * The `n` format specifier is not accepted.
605 * The format specifiers defined in `<inttypes.h>` are not accepted,
606 except for `PRId64`, `PRIu64`, `PRIx64`, `PRIX64`, `PRIo64`, and
607 `PRIi64`.
608
609 The Babeltrace library custom conversion specifier is accepted. Its
610 syntax is either `%!u` to format a UUID (`bt_uuid` type), or:
611
612 . Introductory `%!` sequence.
613
614 . **Optional**: `[` followed by a custom prefix for the printed fields
615 of this specifier, followed by `]`. The standard form is to end this
616 prefix with `-` so that, for example, with the prefix `tc-`, the
617 complete field name becomes `tc-addr`.
618
619 . **Optional**: `pass:[+]` to print extended object members. This
620 depends on the provided format specifier.
621
622 . Format specifier (see below).
623
624 The available format specifiers are:
625
626 [options="header,autowidth",cols="3"]
627 |===
628 |Specifier
629 |Object
630 |Expected C type
631
632 |`F`
633 |Trace IR field class
634 |`+const struct bt_field_class *+`
635
636 |`f`
637 |Trace IR field
638 |`+const struct bt_field *+`
639
640 |`P`
641 |Trace IR field path
642 |`+const struct bt_field_path *+`
643
644 |`E`
645 |Trace IR event class
646 |`+const struct bt_event_class *+`
647
648 |`e`
649 |Trace IR event
650 |`+const struct bt_event *+`
651
652 |`S`
653 |Trace IR stream class.
654 |`+const struct bt_stream_class *+`
655
656 |`s`
657 |Trace IR stream
658 |`+const struct bt_stream *+`
659
660 |`a`
661 |Trace IR packet
662 |`+const struct bt_packet *+`
663
664 |`T`
665 |Trace IR trace class
666 |`+const struct bt_trace_class *+`
667
668 |`t`
669 |Trace IR trace
670 |`+const struct bt_trace *+`
671
672 |`K`
673 |Trace IR clock class
674 |`+const struct bt_clock_class *+`
675
676 |`k`
677 |Trace IR clock snapshot
678 |`+const struct bt_clock_snapshot *+`
679
680 |`v`
681 |Value object
682 |`+const struct bt_value *+`
683
684 |`R`
685 |Integer range set
686 |`const struct bt_integer_range_set *`
687
688 |`n`
689 |Message
690 |`+const struct bt_message *+`
691
692 |`I`
693 |Message iterator class
694 |`struct bt_message_iterator_class *`
695
696 |`i`
697 |Message iterator
698 |`struct bt_message_iterator *`
699
700 |`C`
701 |Component class
702 |`struct bt_component_class *`
703
704 |`c`
705 |Component
706 |`+const struct bt_component *+`
707
708 |`p`
709 |Port
710 |`+const struct bt_port *+`
711
712 |`x`
713 |Connection
714 |`+const struct bt_connection *+`
715
716 |`g`
717 |Graph
718 |`+const struct bt_graph *+`
719
720 |`z`
721 |Interrupter
722 |`+struct bt_interrupter *+`
723
724 |`l`
725 |Plugin
726 |`+const struct bt_plugin *+`
727
728 |`r`
729 |Error cause
730 |`+const struct bt_error_cause *+`
731
732 |`o`
733 |Object pool
734 |`+const struct bt_object_pool *+`
735
736 |`O`
737 |Object
738 |`+const struct bt_object *+`
739 |===
740
741 Conversion specifier examples:
742
743 * `%!f`
744 * `%![my-event-]+e`
745 * `%!t`
746 * `%!+F`
747
748 The ``, `` string (comma and space) is printed between individual
749 fields, but **not after the last one**. Therefore, you must put this
750 separator in the format string between two conversion specifiers, for
751 example:
752
753 [source,c]
754 ----
755 BT_LIB_LOGW("Message: count=%u, %!E, %!+K", count, event_class, clock_class);
756 ----
757
758 Example with a custom prefix:
759
760 [source,c]
761 ----
762 BT_LIB_LOGI("Some message: %![ec-a-]e, %![ec-b-]+e", ec_a, ec_b);
763 ----
764
765 It is safe to pass `NULL` as any Babeltrace object parameter: the macros
766 only print its null address.
767
768 WARNING: Build-time `printf()` format checks are disabled for the
769 `+BT_LIB_LOG*()+` macros because there are custom conversion specifiers,
770 so make sure to test your logging statements.
771
772
773 [[comp-logging-statements]]
774 ==== Component-specific logging statement macros
775
776 There are available logging macros for components. They prepend a prefix
777 including the component's name to the logging message.
778
779 See <<logging-instrument-c-file-compcls,Instrument a component class C
780 source file>> and <<logging-instrument-h-file-compcls,Instrument a
781 component class C header file>> to learn how to be able to use the
782 following macros.
783
784 The component logging statement macros are named `+BT_COMP_LOG*()+`
785 instead of `+BT_LOG*()+`:
786
787 `+BT_COMP_LOGT("format string", ...)+`::
788 Component trace logging statement.
789
790 `+BT_COMP_LOGD("format string", ...)+`::
791 Component debug logging statement.
792
793 `+BT_COMP_LOGI("format string", ...)+`::
794 Component info logging statement.
795
796 `+BT_COMP_LOGW("format string", ...)+`::
797 Component warning logging statement.
798
799 `+BT_COMP_LOGE("format string", ...)+`::
800 Component error logging statement.
801
802 `+BT_COMP_LOGF("format string", ...)+`::
803 Component fatal logging statement.
804
805 `+BT_COMP_LOGT_STR("preformatted string")+`::
806 Component preformatted string trace logging statement.
807
808 `+BT_COMP_LOGD_STR("preformatted string")+`::
809 Component preformatted string debug logging statement.
810
811 `+BT_COMP_LOGI_STR("preformatted string")+`::
812 Component preformatted string info logging statement.
813
814 `+BT_COMP_LOGW_STR("preformatted string")+`::
815 Component preformatted string warning logging statement.
816
817 `+BT_COMP_LOGE_STR("preformatted string")+`::
818 Component preformatted string error logging statement.
819
820 `+BT_COMP_LOGF_STR("preformatted string")+`::
821 Component preformatted string fatal logging statement.
822
823 `+BT_COMP_LOGT_ERRNO("initial message", "format string", ...)+`::
824 Component `errno` string trace logging statement.
825
826 `+BT_COMP_LOGD_ERRNO("initial message", "format string", ...)+`::
827 Component `errno` string debug logging statement.
828
829 `+BT_COMP_LOGI_ERRNO("initial message", "format string", ...)+`::
830 Component `errno` string info logging statement.
831
832 `+BT_COMP_LOGW_ERRNO("initial message", "format string", ...)+`::
833 Component `errno` string warning logging statement.
834
835 `+BT_COMP_LOGE_ERRNO("initial message", "format string", ...)+`::
836 Component `errno` string error logging statement.
837
838 `+BT_COMP_LOGF_ERRNO("initial message", "format string", ...)+`::
839 Component `errno` string fatal logging statement.
840
841 `+BT_COMP_LOGT_MEM(data_ptr, data_size, "format string", ...)+`::
842 Component memory trace logging statement.
843
844 `+BT_COMP_LOGD_MEM(data_ptr, data_size, "format string", ...)+`::
845 Component memory debug logging statement.
846
847 `+BT_COMP_LOGI_MEM(data_ptr, data_size, "format string", ...)+`::
848 Component memory info logging statement.
849
850 `+BT_COMP_LOGW_MEM(data_ptr, data_size, "format string", ...)+`::
851 Component memory warning logging statement.
852
853 `+BT_COMP_LOGE_MEM(data_ptr, data_size, "format string", ...)+`::
854 Component memory error logging statement.
855
856 `+BT_COMP_LOGF_MEM(data_ptr, data_size, "format string", ...)+`::
857 Component memory fatal logging statement.
858
859
860 ==== Conditional logging
861
862 `+BT_LOG_IF(cond, statement)+`::
863 Execute `statement` only if `cond` is true.
864 +
865 Example:
866 +
867 --
868 [source,c]
869 ----
870 BT_LOG_IF(i < count / 2, BT_LOGD("Log this: i=%d", i));
871 ----
872 --
873
874 To check the <<build-time-log-level,build-time log level>>:
875
876 [source,c]
877 ----
878 #if BT_LOG_ENABLED_DEBUG
879 ...
880 #endif
881 ----
882
883 This tests if the _DEBUG_ level was enabled at build time. This means
884 that the current, <<run-time-log-level,run-time log level>> _could_ be
885 _DEBUG_, but it could also be higher. The rule of thumb is to use only
886 logging statements at the same level in a `BT_LOG_ENABLED_*` conditional
887 block.
888
889 The available definitions for build-time conditions are:
890
891 * `BT_LOG_ENABLED_TRACE`
892 * `BT_LOG_ENABLED_DEBUG`
893 * `BT_LOG_ENABLED_INFO`
894 * `BT_LOG_ENABLED_WARNING`
895 * `BT_LOG_ENABLED_ERROR`
896 * `BT_LOG_ENABLED_FATAL`
897
898 To check the current, <<run-time-log-level,run-time log level>>:
899
900 [source,c]
901 ----
902 if (BT_LOG_ON_DEBUG) {
903 ...
904 }
905 ----
906
907 This tests if the _DEBUG_ log level is dynamically turned on
908 (implies that it's also enabled at build time). This check could have a
909 noticeable impact on performance.
910
911 The available definitions for run-time conditions are:
912
913 * `BT_LOG_ON_TRACE`
914 * `BT_LOG_ON_DEBUG`
915 * `BT_LOG_ON_INFO`
916 * `BT_LOG_ON_WARNING`
917 * `BT_LOG_ON_ERROR`
918 * `BT_LOG_ON_FATAL`
919
920 Those macros check the module-specific log level symbol (defined by
921 `BT_LOG_OUTPUT_LEVEL`).
922
923 Never, ever write code which would be executed only to compute the
924 fields of a logging statement outside a conditional logging scope,
925 for example:
926
927 [source,c]
928 ----
929 int number = get_number_of_event_classes_with_property_x(...);
930 BT_LOGD("Bla bla: number=%d", number);
931 ----
932
933 Do this instead:
934
935 [source,c]
936 ----
937 if (BT_LOG_ON_DEBUG) {
938 int number = get_number_of_event_classes_with_property_x(...);
939 BT_LOGD("Bla bla: number=%d", number);
940 }
941 ----
942
943 Or even this:
944
945 [source,c]
946 ----
947 BT_LOGD("Bla bla: number=%d", get_number_of_event_classes_with_property_x(...));
948 ----
949
950
951 === Guides
952
953 [[logging-instrument-c-file-gen]]
954 ==== Instrument a C source file (generic)
955
956 To instrument a C source file (`.c`):
957
958 . At the top of the file, before the first `#include` line (if any),
959 define your file's <<choose-a-logging-tag,logging tag>> name:
960 +
961 --
962 [source,c]
963 ----
964 #define BT_LOG_TAG "SUBSYS/MY-MODULE/MY-FILE"
965 ----
966 --
967
968 . Below the line above, define the source file's log level expression,
969 `BT_LOG_OUTPUT_LEVEL`. This expression is evaluated for each
970 <<gen-logging-statements,logging statement>> to know the current
971 <<run-time-log-level,run-time log level>>.
972 +
973 Examples:
974 +
975 [source,c]
976 ----
977 /* Global log level variable */
978 #define BT_LOG_OUTPUT_LEVEL module_global_log_level
979 ----
980 +
981 [source,c]
982 ----
983 /* Local log level variable; must exist where you use BT_LOG*() */
984 #define BT_LOG_OUTPUT_LEVEL log_level
985 ----
986 +
987 [source,c]
988 ----
989 /* Object's log level; `obj` must exist where you use BT_LOG*() */
990 #define BT_LOG_OUTPUT_LEVEL (obj->log_level)
991 ----
992
993 . Include `"logging/log.h"`:
994 +
995 [source,c]
996 ----
997 #include "logging/log.h"
998 ----
999
1000 . In the file, instrument your code with the
1001 <<gen-logging-statements,generic logging statement macros>>.
1002
1003
1004 [[logging-instrument-h-file-gen]]
1005 ==== Instrument a C header file (generic)
1006
1007 To instrument a C header file (`.h`), if you have `static inline`
1008 functions in it:
1009
1010 . Do not include `"logging/log.h"`!
1011
1012 . Do one of:
1013
1014 .. In the file, instrument your code with the
1015 <<gen-logging-statements,generic logging statement macros>>, making
1016 each of them conditional to the existence of the macro you're using:
1017 +
1018 [source,c]
1019 ----
1020 static inline
1021 int some_function(int x)
1022 {
1023 /* ... */
1024
1025 #ifdef BT_LOGT
1026 BT_LOGT(...);
1027 #endif
1028
1029 /* ... */
1030
1031 #ifdef BT_LOGW_STR
1032 BT_LOGW_STR(...);
1033 #endif
1034
1035 /* ... */
1036 }
1037 ----
1038 +
1039 The C source files which include this header file determine if logging
1040 is enabled or not for them, and if so, what is their
1041 <<choose-a-logging-tag,logging tag>> and <<run-time-log-level,run-time
1042 log level>> expression.
1043
1044 .. Require that logging be enabled:
1045 +
1046 [source,c]
1047 ----
1048 /* Protection: this file uses BT_LOG*() macros directly */
1049 #ifndef BT_LOG_SUPPORTED
1050 # error Please include "logging/log.h" before including this file.
1051 #endif
1052 ----
1053 +
1054 Then, in the file, instrument your code with the
1055 <<gen-logging-statements,generic logging statement macros>>.
1056
1057
1058 [[logging-instrument-c-file-lib]]
1059 ==== Instrument a library C source file
1060
1061 To instrument a library C source file (`.c`):
1062
1063 . At the top of the file, before the first `#include` line (if any),
1064 define your file's <<choose-a-logging-tag,logging tag>> name (this
1065 tag must start with `LIB/`):
1066 +
1067 --
1068 [source,c]
1069 ----
1070 #define BT_LOG_TAG "LIB/THE-FILE"
1071 ----
1072 --
1073
1074 . Include `"lib/logging.h"`:
1075 +
1076 [source,c]
1077 ----
1078 #include "lib/logging.h"
1079 ----
1080
1081 . In the file, instrument your code with the
1082 <<lib-logging-statements,library logging statement macros>> or with
1083 the <<gen-logging-statements,generic logging statement macros>>.
1084
1085
1086 [[logging-instrument-h-file-lib]]
1087 ==== Instrument a library C header file
1088
1089 To instrument a library C header file (`.h`), if you have `static
1090 inline` functions in it:
1091
1092 . Do not include `"lib/logging.h"`!
1093
1094 . Require that library logging be enabled:
1095 +
1096 [source,c]
1097 ----
1098 /* Protection: this file uses BT_LIB_LOG*() macros directly */
1099 #ifndef BT_LIB_LOG_SUPPORTED
1100 # error Please include "lib/logging.h" before including this file.
1101 #endif
1102 ----
1103
1104 . In the file, instrument your code with the
1105 <<lib-logging-statements,library logging statement macros>> or with
1106 the <<gen-logging-statements,generic logging statement macros>>.
1107
1108
1109 [[logging-instrument-c-file-compcls]]
1110 ==== Instrument a component class C source file
1111
1112 To instrument a component class C source file (`.c`):
1113
1114 . At the top of the file, before the first `#include` line (if any),
1115 define your file's <<choose-a-logging-tag,logging tag>> name (this tag
1116 must start with `PLUGIN/` followed by the component class identifier):
1117 +
1118 --
1119 [source,c]
1120 ----
1121 #define BT_LOG_TAG "PLUGIN/SRC.MY-PLUGIN.MY-SRC"
1122 ----
1123 --
1124
1125 . Below the line above, define the source file's log level expression,
1126 `BT_LOG_OUTPUT_LEVEL`. This expression is evaluated for each
1127 <<comp-logging-statements,logging statement>> to know the current
1128 <<run-time-log-level,run-time log level>>.
1129 +
1130 For a component class file, it is usually a member of a local component
1131 private structure variable:
1132 +
1133 [source,c]
1134 ----
1135 #define BT_LOG_OUTPUT_LEVEL (my_comp->log_level)
1136 ----
1137
1138 . Below the line above, define `BT_COMP_LOG_SELF_COMP` to an expression
1139 which, evaluated in the context of the
1140 <<comp-logging-statements,logging statements>>, evaluates to the self
1141 component address (`+bt_self_component *+`) of the component.
1142 +
1143 This is usually a member of a local component private structure
1144 variable:
1145 +
1146 [source,c]
1147 ----
1148 #define BT_COMP_LOG_SELF_COMP (my_comp->self_comp)
1149 ----
1150
1151 . Include `"logging/comp-logging.h"`:
1152 +
1153 [source,c]
1154 ----
1155 #include "logging/comp-logging.h"
1156 ----
1157
1158 . In the component initialization method, make sure to set the
1159 component private structure's log level member to the initial
1160 component's log level:
1161 +
1162 [source,c]
1163 ----
1164 struct my_comp {
1165 bt_logging_level log_level;
1166 /* ... */
1167 };
1168
1169 BT_HIDDEN
1170 bt_self_component_status my_comp_init(
1171 bt_self_component_source *self_comp_src,
1172 bt_value *params, void *init_method_data)
1173 {
1174 struct my_comp *my_comp = g_new0(struct my_comp, 1);
1175 bt_self_component *self_comp =
1176 bt_self_component_source_as_self_component(self_comp_src);
1177 const bt_component *comp = bt_self_component_as_component(self_comp);
1178
1179 BT_ASSERT(my_comp);
1180 my_comp->log_level = bt_component_get_logging_level(comp);
1181
1182 /* ... */
1183 }
1184 ----
1185
1186 . In the file, instrument your code with the
1187 <<comp-logging-statements,component logging statement macros>>.
1188
1189
1190 [[logging-instrument-h-file-compcls]]
1191 ==== Instrument a component class C header file
1192
1193 To instrument a component class C header file (`.h`), if you have
1194 `static inline` functions in it:
1195
1196 . Do not include `"logging/comp-logging.h"`!
1197
1198 . Require that component logging be enabled:
1199 +
1200 [source,c]
1201 ----
1202 /* Protection: this file uses BT_COMP_LOG*() macros directly */
1203 #ifndef BT_COMP_LOG_SUPPORTED
1204 # error Please include "logging/comp-logging.h" before including this file.
1205 #endif
1206 ----
1207
1208 . In the file, instrument your code with the
1209 <<comp-logging-statements,component logging statement macros>>.
1210
1211
1212 [[choose-a-logging-tag]]
1213 ==== Choose a logging tag
1214
1215 Each logging-enabled C source file must define `BT_LOG_TAG` to a logging
1216 tag. A logging tag is a namespace to identify the logging messages of
1217 this specific source file.
1218
1219 In general, a logging tag name _must_ be only uppercase letters, digits,
1220 and the `-`, `.`, and `/` characters.
1221
1222 Use `/` to show the subsystem to source file hierarchy.
1223
1224 For the Babeltrace library, start with `LIB/`.
1225
1226 For the CTF writer library, start with `CTF-WRITER/`.
1227
1228 For component classes, use:
1229
1230 [verse]
1231 `PLUGIN/__CCTYPE__.__PNAME__.__CCNAME__[/__FILE__]`
1232
1233 With:
1234
1235 `__CCTYPE__`::
1236 Component class's type (`SRC`, `FLT`, or `SINK`).
1237
1238 `__PNAME__`::
1239 Plugin's name.
1240
1241 `__CCNAME__`::
1242 Component class's name.
1243
1244 `__FILE__`::
1245 Additional information to specify the source file name or module.
1246
1247 For plugins (files common to many component classes), use:
1248
1249 [verse]
1250 `PLUGIN/__PNAME__[/__FILE__]`
1251
1252 With:
1253
1254 `__PNAME__`::
1255 Plugin's name.
1256
1257 `__FILE__`::
1258 Additional information to specify the source file name or module.
1259
1260
1261 [[choose-a-log-level]]
1262 ==== Choose a log level
1263
1264 Choosing the appropriate level for your logging statement is very
1265 important.
1266
1267 [options="header,autowidth",cols="1,2,3a,4"]
1268 |===
1269 |Log level |Description |Use cases |Expected impact on performance
1270
1271 |_FATAL_
1272 |
1273 The program, library, or plugin cannot continue to work in this
1274 condition: it must be terminated immediately.
1275
1276 A _FATAL_-level logging statement should always be followed by
1277 `abort()`.
1278 |
1279 * Unexpected return values from system calls.
1280 * Logic error in internal code, for example an unexpected value in a
1281 `switch` statement.
1282 * Failed assertion (within `BT_ASSERT()`).
1283 * Unsatisfied library precondition (within `BT_ASSERT_PRE()` or
1284 `BT_ASSERT_PRE_DEV()`).
1285 * Unsatisfied library postcondition (within `BT_ASSERT_POST()` or
1286 `BT_ASSERT_POST_DEV()`).
1287 |Almost none: always enabled.
1288
1289 |_ERROR_
1290 |
1291 An important error which is somewhat not fatal, that is, the program,
1292 library, or plugin can continue to work after this, but you judge that
1293 it should be reported to the user.
1294
1295 Usually, the program cannot recover from such an error, but it can at
1296 least exit cleanly.
1297 |
1298 * Memory allocation errors.
1299 * Wrong component initialization parameters.
1300 * Corrupted, unrecoverable trace data.
1301 * Failed to perform an operation which should work considering the
1302 implementation and the satisfied preconditions. For example, the
1303 failure to create an empty object (no parameters): most probably
1304 failed internally because of an allocation error.
1305 * Almost any error in terminal elements: CLI and plugins.
1306 |Almost none: always enabled.
1307
1308 |_WARNING_
1309 |
1310 An error which still allows the execution to continue, but you judge
1311 that it should be reported to the user.
1312
1313 _WARNING_-level logging statements are for any error or weird action
1314 that is directly or indirectly caused by the user, often through some
1315 bad input data. For example, not having enough memory is considered
1316 beyond the user's control, so we always log memory errors with an
1317 _ERROR_ level (not _FATAL_ because we usually don't abort in this
1318 condition).
1319 |
1320 * Missing data within something that is expected to have it, but there's
1321 an alternative.
1322 * Invalid file, but recoverable/fixable.
1323 |Almost none: always enabled.
1324
1325 |_INFO_
1326 |
1327 Any useful information which a non-developer user would possibly
1328 understand.
1329
1330 Anything logged with this level must _not_ happen repetitively on the
1331 fast path, that is, nothing related to each message, for example. This
1332 level is used for sporadic and one-shot events.
1333 |
1334 * CLI or component configuration report.
1335 * Successful plugin, component, or message iterator initialization.
1336 * In the library: anything related to plugins, graphs, component
1337 classes, components, message iterators, connections, and ports which
1338 is not on the fast path.
1339 * Successful connection to or disconnection from another system.
1340 * An _optional_ subsystem cannot be loaded.
1341 * An _optional_ field/datum cannot be found.
1342 |
1343 Very little: always enabled.
1344
1345 |_DEBUG_
1346 |
1347 Something that only Babeltrace developers would be interested into,
1348 which can occur on the fast path, but not more often than once per
1349 message.
1350
1351 The _DEBUG_ level is the default <<build-time-log-level,build-time log
1352 level>> as, since it's not _too_ verbose, the performance is similar to
1353 an _INFO_ build.
1354 |
1355 * Object construction and destruction.
1356 * Object recycling (except fields).
1357 * Object copying (except fields and values).
1358 * Object freezing (whatever the type, as freezing only occurs in
1359 developer mode).
1360 * Object interruption.
1361 * Calling user methods and logging the result.
1362 * Setting object properties (except fields and values).
1363 |
1364 Noticeable, but not as much as the _TRACE_ level: could be executed
1365 in production if you're going to need a thorough log for support
1366 tickets without having to rebuild the project.
1367
1368 |_TRACE_
1369 |
1370 Low-level debugging context information (anything that does not fit the
1371 other log levels). More appropriate for tracing in general.
1372 |
1373 * Reference count change.
1374 * Fast path, low level state machine's state change.
1375 * Get or set an object's property.
1376 * Object comparison's intermediate results.
1377 |Huge: not executed in production.
1378 |===
1379
1380 [IMPORTANT]
1381 --
1382 Make sure not to use a _WARNING_ (or higher) log level when the
1383 condition leading to the logging statement can occur under normal
1384 circumstances.
1385
1386 For example, a public function to get some object or
1387 property from an object by name or key that fails to find the value is
1388 not a warning scenario: the user could legitimately use this function to
1389 check if the name/key exists in the object. In this case, use the
1390 _TRACE_ level (or do not log at all).
1391 --
1392
1393
1394 [[message]]
1395 ==== Write an appropriate message
1396
1397 Follow those rules when you write a logging statement's message:
1398
1399 * Use an English sentence which starts with a capital letter.
1400
1401 * Start the sentence with the appropriate verb tense depending on the
1402 context. For example:
1403 +
1404 --
1405 ** Beginning of operation (present continuous): _Creating ..._,
1406 _Copying ..._, _Serializing ..._, _Freezing ..._, _Destroying ..._
1407 ** End of operation (simple past): _Created ..._, _Successfully created ..._,
1408 _Failed to create ..._, _Set ..._ (simple past of _to set_ which is
1409 also _set_)
1410 --
1411 +
1412 For warning and error messages, you can start the message with _Cannot_
1413 or _Failed to_ followed by a verb if it's appropriate.
1414
1415 * Do not include the log level in the message itself. For example,
1416 do not start the message with _Error while_ or _Warning:_.
1417
1418 * Do not put newlines, tabs, or other special characters in the message,
1419 unless you want to log a string with such characters. Note that
1420 multiline logging messages can be hard to parse, analyze, and filter,
1421 however, so prefer multiple logging statements over a single statement
1422 with newlines.
1423
1424 * **If there are fields that your logging statement must record**,
1425 follow the message with `:` followed by a space, then with the list of
1426 fields (more about this below). If there are no fields, end the
1427 sentence with a period.
1428
1429 The statement's fields _must_ be a comma-separated list of
1430 `__name__=__value__` tokens. Keep `__name__` as simple as possible; use
1431 kebab case if possible. If `__value__` is a non-alphanumeric string, put
1432 it between double quotes (`"%s"` specifier). Always use the `PRId64` and
1433 `PRIu64` specifiers to log an `int64_t` or an `uint64_t` value. Use `%d`
1434 to log a boolean value.
1435
1436 Example:
1437
1438 "Cannot read stream data for indexing: path=\"%s\", name=\"%s\", "
1439 "stream-id=%" PRIu64 ", stream-fd=%d, "
1440 "index=%" PRIu64 ", status=%s, is-mapped=%d"
1441
1442 By following a standard format for the statement fields, it is easier to
1443 use tools like https://www.elastic.co/products/logstash[Logstash] or
1444 even https://www.splunk.com/[Splunk] to split fields and analyze logs.
1445
1446 Prefer the following suffixes in field names:
1447
1448 [options="header,autowidth"]
1449 |===
1450 |Field name suffix |Description |Format specifier
1451
1452 |`-addr` |Memory address |`%p`
1453 |`-fd` |File descriptor |`%d`
1454 |`-fp` |File stream (`+FILE *+`) |`%p`
1455 |`-id` |Object's ID |`%" PRIu64 "`
1456 |`-index` |Index |`%" PRIu64 "`
1457 |`-name` |Object's name |`\"%s\"`
1458 |===
1459
1460
1461 === Output
1462
1463 The log is printed to the standard error stream. A log line contains the
1464 time, the process and thread IDs, the <<log-levels,log level>>, the
1465 <<choose-a-logging-tag,logging tag>>, the source's function name, file
1466 name and line number, and the <<message,message>>.
1467
1468 When Babeltrace supports terminal color codes (depends on the
1469 `BABELTRACE_TERM_COLOR` environment variable's value and what the
1470 standard output and error streams are plugged into), _INFO_-level lines
1471 are blue, _WARNING_-level lines are yellow, and _ERROR_-level and
1472 _FATAL_-level lines are red.
1473
1474 Log line example:
1475
1476 ----
1477 05-11 00:58:03.691 23402 23402 D VALUES bt_value_destroy@values.c:498 Destroying value: addr=0xb9c3eb0
1478 ----
1479
1480 You can easily filter the log with `grep` or `ag`. For example, to keep
1481 only the _DEBUG_-level logging messages that the `FIELD-CLASS` module
1482 generates:
1483
1484 ----
1485 $ babeltrace2 --log-level=D /path/to/trace |& ag 'D FIELD-CLASS'
1486 ----
1487
1488
1489 == Valgrind
1490
1491 To use Valgrind on an application (for example, the CLI or a test) which
1492 loads libbabeltrace2, use:
1493
1494 ----
1495 $ G_SLICE=always-malloc G_DEBUG=gc-friendly PYTHONMALLOC=malloc \
1496 LIBBABELTRACE2_NO_DLCLOSE=1 valgrind --leak-check=full app
1497 ----
1498
1499 `G_SLICE=always-malloc` and `G_DEBUG=gc-friendly` is for GLib and
1500 `PYTHONMALLOC=malloc` is for the Python interpreter, if it is used by
1501 the Python plugin provider (Valgrind will probably show a lot of errors
1502 which originate from the Python interpreter anyway).
1503
1504 `LIBBABELTRACE2_NO_DLCLOSE=1` makes libbabeltrace2 not close the shared
1505 libraries (plugins) which it loads. You need this to see the appropriate
1506 backtrace when Valgrind shows errors.
1507
1508 == Testing
1509
1510 [[test-env]]
1511 === Environment
1512
1513 `tests/utils/utils.sh` sets the environment variables for any Babeltrace
1514 test script.
1515
1516 `utils.sh` only needs to know the path to the `tests` directory within
1517 the source and the build directories. By default, `utils.sh` assumes the
1518 build is in tree, that is, you ran `./configure` from the source's root
1519 directory, and sets the `BT_TESTS_SRCDIR` and `BT_TESTS_BUILDDIR`
1520 environment variables accordingly. You can override those variables, for
1521 example if you build out of tree.
1522
1523 All test scripts eventually do something like this to source `utils.sh`,
1524 according to where they are located relative to the `tests` directory:
1525
1526 [source,bash]
1527 ----
1528 if [ "x${BT_TESTS_SRCDIR:-}" != "x" ]; then
1529 UTILSSH="$BT_TESTS_SRCDIR/utils/utils.sh"
1530 else
1531 UTILSSH="$(dirname "$0")/../utils/utils.sh"
1532 fi
1533 ----
1534
1535 ==== Python
1536
1537 You can use the `tests/utils/run_python_bt2` script to run any command
1538 within an environment making the build's `bt2` Python package available.
1539
1540 `run_python_bt2` uses <<test-env,`utils.sh`>> which needs to know the
1541 build directory, so make sure you set the `BT_TESTS_BUILDDIR`
1542 environment variable correctly _if you build out of tree_, for example:
1543
1544 ----
1545 $ export BT_TESTS_BUILDDIR=/path/to/build/babeltrace/tests
1546 ----
1547
1548 You can run any command which needs the `bt2` Python package through
1549 `run_python_bt2`, for example:
1550
1551 ----
1552 $ ./tests/utils/run_python_bt2 ipython3
1553 ----
1554
1555 === Report format
1556
1557 All test scripts output the test results following the
1558 https://testanything.org/[Test Anything Protocol] (TAP) format.
1559
1560 The TAP format has two mechanisms to print additional information about
1561 a test:
1562
1563 * Print a line starting with `#` to the standard output.
1564 +
1565 This is usually done with the `diag()` C function or the `diag` shell
1566 function.
1567
1568 * Print to the standard error.
1569
1570
1571 === Python bindings
1572
1573 The `bt2` Python package tests are located in
1574 `tests/bindings/python/bt2`.
1575
1576
1577 ==== Python test runner
1578
1579 `tests/utils/python/testrunner.py` is Babeltrace's Python test runner
1580 which loads Python files containing unit tests, finds all the test
1581 cases, and runs the tests, producing a TAP report.
1582
1583 You can see the test runner command's help with:
1584
1585 ----
1586 $ python3 ./tests/utils/python/testrunner.py --help
1587 ----
1588
1589 By default, the test runner reports failing tests (TAP's `not{nbsp}ok`
1590 line), but continues to run other tests. You can use the `--failfast`
1591 option to make the test runner fail as soon as a test fails.
1592
1593
1594 ==== Guides
1595
1596 To run all the `bt2` Python package tests:
1597
1598 * Run:
1599 +
1600 ----
1601 $ ./tests/utils/run_python_bt2 ./tests/bindings/python/bt2/test_python_bt2
1602 ----
1603 +
1604 or:
1605 +
1606 ----
1607 $ ./tests/utils/run_python_bt2 python3 ./tests/utils/python/testrunner.py \
1608 ./tests/bindings/python/bt2/ -p '*.py'
1609 ----
1610
1611 To run **all the tests** in a test module (for example,
1612 `test_value.py`):
1613
1614 * Run:
1615 +
1616 ----
1617 $ ./tests/utils/run_python_bt2 python3 ./tests/utils/python/testrunner.py \
1618 ./tests/bindings/python/bt2 -t test_value
1619 ----
1620
1621 To run a **specific test case** (for example, `RealValueTestCase` within
1622 `test_value.py`):
1623
1624 * Run:
1625 +
1626 ----
1627 $ ./tests/utils/run_python_bt2 python3 ./tests/utils/python/testrunner.py \
1628 ./tests/bindings/python/bt2/ -t test_value.RealValueTestCase
1629 ----
1630
1631 To run a **specific test** (for example,
1632 `RealValueTestCase.test_assign_pos_int` within `test_value.py`):
1633
1634 * Run:
1635 +
1636 ----
1637 $ ./tests/utils/run_python_bt2 python3 ./tests/utils/python/testrunner.py \
1638 ./tests/bindings/python/bt2/ -t test_value.RealValueTestCase.test_assign_pos_int
1639 ----
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