1 @c Copyright (C) 2002-2018 Free Software Foundation, Inc.
2 @c This is part of the GCC manual.
3 @c For copying conditions, see the file gcc.texi.
6 @chapter Memory Management and Type Information
10 GCC uses some fairly sophisticated memory management techniques, which
11 involve determining information about GCC's data structures from GCC's
12 source code and using this information to perform garbage collection and
13 implement precompiled headers.
15 A full C++ parser would be too complicated for this task, so a limited
16 subset of C++ is interpreted and special markers are used to determine
17 what parts of the source to look at. All @code{struct}, @code{union}
18 and @code{template} structure declarations that define data structures
19 that are allocated under control of the garbage collector must be
20 marked. All global variables that hold pointers to garbage-collected
21 memory must also be marked. Finally, all global variables that need
22 to be saved and restored by a precompiled header must be marked. (The
23 precompiled header mechanism can only save static variables if they're
24 scalar. Complex data structures must be allocated in garbage-collected
25 memory to be saved in a precompiled header.)
27 The full format of a marker is
29 GTY (([@var{option}] [(@var{param})], [@var{option}] [(@var{param})] @dots{}))
32 but in most cases no options are needed. The outer double parentheses
33 are still necessary, though: @code{GTY(())}. Markers can appear:
37 In a structure definition, before the open brace;
39 In a global variable declaration, after the keyword @code{static} or
42 In a structure field definition, before the name of the field.
45 Here are some examples of marking simple data structures and globals.
48 struct GTY(()) @var{tag}
53 typedef struct GTY(()) @var{tag}
58 static GTY(()) struct @var{tag} *@var{list}; /* @r{points to GC memory} */
59 static GTY(()) int @var{counter}; /* @r{save counter in a PCH} */
62 The parser understands simple typedefs such as
63 @code{typedef struct @var{tag} *@var{name};} and
64 @code{typedef int @var{name};}.
65 These don't need to be marked.
67 Since @code{gengtype}'s understanding of C++ is limited, there are
68 several constructs and declarations that are not supported inside
69 classes/structures marked for automatic GC code generation. The
70 following C++ constructs produce a @code{gengtype} error on
71 structures/classes marked for automatic GC code generation:
75 Type definitions inside classes/structures are not supported.
77 Enumerations inside classes/structures are not supported.
80 If you have a class or structure using any of the above constructs,
81 you need to mark that class as @code{GTY ((user))} and provide your
82 own marking routines (see section @ref{User GC} for details).
84 It is always valid to include function definitions inside classes.
85 Those are always ignored by @code{gengtype}, as it only cares about
89 * GTY Options:: What goes inside a @code{GTY(())}.
90 * Inheritance and GTY:: Adding GTY to a class hierarchy.
91 * User GC:: Adding user-provided GC marking routines.
92 * GGC Roots:: Making global variables GGC roots.
93 * Files:: How the generated files work.
94 * Invoking the garbage collector:: How to invoke the garbage collector.
95 * Troubleshooting:: When something does not work as expected.
99 @section The Inside of a @code{GTY(())}
101 Sometimes the C code is not enough to fully describe the type
102 structure. Extra information can be provided with @code{GTY} options
103 and additional markers. Some options take a parameter, which may be
104 either a string or a type name, depending on the parameter. If an
105 option takes no parameter, it is acceptable either to omit the
106 parameter entirely, or to provide an empty string as a parameter. For
107 example, @code{@w{GTY ((skip))}} and @code{@w{GTY ((skip ("")))}} are
110 When the parameter is a string, often it is a fragment of C code. Four
111 special escapes may be used in these strings, to refer to pieces of
112 the data structure being marked:
114 @cindex % in GTY option
117 The current structure.
119 The structure that immediately contains the current structure.
121 The outermost structure that contains the current structure.
123 A partial expression of the form @code{[i1][i2]@dots{}} that indexes
124 the array item currently being marked.
127 For instance, suppose that you have a structure of the form
137 and @code{b} is a variable of type @code{struct B}. When marking
138 @samp{b.foo[11]}, @code{%h} would expand to @samp{b.foo[11]},
139 @code{%0} and @code{%1} would both expand to @samp{b}, and @code{%a}
140 would expand to @samp{[11]}.
142 As in ordinary C, adjacent strings will be concatenated; this is
143 helpful when you have a complicated expression.
146 GTY ((chain_next ("TREE_CODE (&%h.generic) == INTEGER_TYPE"
147 " ? TYPE_NEXT_VARIANT (&%h.generic)"
148 " : TREE_CHAIN (&%h.generic)")))
152 The available options are:
156 @item length ("@var{expression}")
158 There are two places the type machinery will need to be explicitly told
159 the length of an array of non-atomic objects. The first case is when a
160 structure ends in a variable-length array, like this:
162 struct GTY(()) rtvec_def @{
163 int num_elem; /* @r{number of elements} */
164 rtx GTY ((length ("%h.num_elem"))) elem[1];
168 In this case, the @code{length} option is used to override the specified
169 array length (which should usually be @code{1}). The parameter of the
170 option is a fragment of C code that calculates the length.
172 The second case is when a structure or a global variable contains a
173 pointer to an array, like this:
175 struct gimple_omp_for_iter * GTY((length ("%h.collapse"))) iter;
177 In this case, @code{iter} has been allocated by writing something like
179 x->iter = ggc_alloc_cleared_vec_gimple_omp_for_iter (collapse);
181 and the @code{collapse} provides the length of the field.
183 This second use of @code{length} also works on global variables, like:
185 static GTY((length("reg_known_value_size"))) rtx *reg_known_value;
188 Note that the @code{length} option is only meant for use with arrays of
189 non-atomic objects, that is, objects that contain pointers pointing to
190 other GTY-managed objects. For other GC-allocated arrays and strings
191 you should use @code{atomic}.
196 If @code{skip} is applied to a field, the type machinery will ignore it.
197 This is somewhat dangerous; the only safe use is in a union when one
198 field really isn't ever used.
203 Use this to mark types that need to be marked by user gc routines, but are not
204 refered to in a template argument. So if you have some user gc type T1 and a
205 non user gc type T2 you can give T2 the for_user option so that the marking
206 functions for T1 can call non mangled functions to mark T2.
211 @item desc ("@var{expression}")
212 @itemx tag ("@var{constant}")
215 The type machinery needs to be told which field of a @code{union} is
216 currently active. This is done by giving each field a constant
217 @code{tag} value, and then specifying a discriminator using @code{desc}.
218 The value of the expression given by @code{desc} is compared against
219 each @code{tag} value, each of which should be different. If no
220 @code{tag} is matched, the field marked with @code{default} is used if
221 there is one, otherwise no field in the union will be marked.
223 In the @code{desc} option, the ``current structure'' is the union that
224 it discriminates. Use @code{%1} to mean the structure containing it.
225 There are no escapes available to the @code{tag} option, since it is a
230 struct GTY(()) tree_binding
232 struct tree_common common;
233 union tree_binding_u @{
234 tree GTY ((tag ("0"))) scope;
235 struct cp_binding_level * GTY ((tag ("1"))) level;
236 @} GTY ((desc ("BINDING_HAS_LEVEL_P ((tree)&%0)"))) xscope;
241 In this example, the value of BINDING_HAS_LEVEL_P when applied to a
242 @code{struct tree_binding *} is presumed to be 0 or 1. If 1, the type
243 mechanism will treat the field @code{level} as being present and if 0,
244 will treat the field @code{scope} as being present.
246 The @code{desc} and @code{tag} options can also be used for inheritance
247 to denote which subclass an instance is. See @ref{Inheritance and GTY}
248 for more information.
253 When the @code{cache} option is applied to a global variable gt_clear_cache is
254 called on that variable between the mark and sweep phases of garbage
255 collection. The gt_clear_cache function is free to mark blocks as used, or to
256 clear pointers in the variable.
261 @code{deletable}, when applied to a global variable, indicates that when
262 garbage collection runs, there's no need to mark anything pointed to
263 by this variable, it can just be set to @code{NULL} instead. This is used
264 to keep a list of free structures around for re-use.
269 When applied to a field, @code{maybe_undef} indicates that it's OK if
270 the structure that this fields points to is never defined, so long as
271 this field is always @code{NULL}. This is used to avoid requiring
272 backends to define certain optional structures. It doesn't work with
276 @item nested_ptr (@var{type}, "@var{to expression}", "@var{from expression}")
278 The type machinery expects all pointers to point to the start of an
279 object. Sometimes for abstraction purposes it's convenient to have
280 a pointer which points inside an object. So long as it's possible to
281 convert the original object to and from the pointer, such pointers
282 can still be used. @var{type} is the type of the original object,
283 the @var{to expression} returns the pointer given the original object,
284 and the @var{from expression} returns the original object given
285 the pointer. The pointer will be available using the @code{%h}
290 @findex chain_circular
291 @item chain_next ("@var{expression}")
292 @itemx chain_prev ("@var{expression}")
293 @itemx chain_circular ("@var{expression}")
295 It's helpful for the type machinery to know if objects are often
296 chained together in long lists; this lets it generate code that uses
297 less stack space by iterating along the list instead of recursing down
298 it. @code{chain_next} is an expression for the next item in the list,
299 @code{chain_prev} is an expression for the previous item. For singly
300 linked lists, use only @code{chain_next}; for doubly linked lists, use
301 both. The machinery requires that taking the next item of the
302 previous item gives the original item. @code{chain_circular} is similar
303 to @code{chain_next}, but can be used for circular single linked lists.
306 @item reorder ("@var{function name}")
308 Some data structures depend on the relative ordering of pointers. If
309 the precompiled header machinery needs to change that ordering, it
310 will call the function referenced by the @code{reorder} option, before
311 changing the pointers in the object that's pointed to by the field the
312 option applies to. The function must take four arguments, with the
313 signature @samp{@w{void *, void *, gt_pointer_operator, void *}}.
314 The first parameter is a pointer to the structure that contains the
315 object being updated, or the object itself if there is no containing
316 structure. The second parameter is a cookie that should be ignored.
317 The third parameter is a routine that, given a pointer, will update it
318 to its correct new value. The fourth parameter is a cookie that must
319 be passed to the second parameter.
321 PCH cannot handle data structures that depend on the absolute values
322 of pointers. @code{reorder} functions can be expensive. When
323 possible, it is better to depend on properties of the data, like an ID
324 number or the hash of a string instead.
329 The @code{atomic} option can only be used with pointers. It informs
330 the GC machinery that the memory that the pointer points to does not
331 contain any pointers, and hence it should be treated by the GC and PCH
332 machinery as an ``atomic'' block of memory that does not need to be
333 examined when scanning memory for pointers. In particular, the
334 machinery will not scan that memory for pointers to mark them as
335 reachable (when marking pointers for GC) or to relocate them (when
338 The @code{atomic} option differs from the @code{skip} option.
339 @code{atomic} keeps the memory under Garbage Collection, but makes the
340 GC ignore the contents of the memory. @code{skip} is more drastic in
341 that it causes the pointer and the memory to be completely ignored by
342 the Garbage Collector. So, memory marked as @code{atomic} is
343 automatically freed when no longer reachable, while memory marked as
346 The @code{atomic} option must be used with great care, because all
347 sorts of problem can occur if used incorrectly, that is, if the memory
348 the pointer points to does actually contain a pointer.
350 Here is an example of how to use it:
352 struct GTY(()) my_struct @{
353 int number_of_elements;
354 unsigned int * GTY ((atomic)) elements;
357 In this case, @code{elements} is a pointer under GC, and the memory it
358 points to needs to be allocated using the Garbage Collector, and will
359 be freed automatically by the Garbage Collector when it is no longer
360 referenced. But the memory that the pointer points to is an array of
361 @code{unsigned int} elements, and the GC must not try to scan it to
362 find pointers to mark or relocate, which is why it is marked with the
363 @code{atomic} option.
365 Note that, currently, global variables can not be marked with
366 @code{atomic}; only fields of a struct can. This is a known
367 limitation. It would be useful to be able to mark global pointers
368 with @code{atomic} to make the PCH machinery aware of them so that
369 they are saved and restored correctly to PCH files.
372 @item special ("@var{name}")
374 The @code{special} option is used to mark types that have to be dealt
375 with by special case machinery. The parameter is the name of the
376 special case. See @file{gengtype.c} for further details. Avoid
377 adding new special cases unless there is no other alternative.
382 The @code{user} option indicates that the code to mark structure
383 fields is completely handled by user-provided routines. See section
384 @ref{User GC} for details on what functions need to be provided.
387 @node Inheritance and GTY
388 @section Support for inheritance
389 gengtype has some support for simple class hierarchies. You can use
390 this to have gengtype autogenerate marking routines, provided:
394 There must be a concrete base class, with a discriminator expression
395 that can be used to identify which subclass an instance is.
397 Only single inheritance is used.
399 None of the classes within the hierarchy are templates.
402 If your class hierarchy does not fit in this pattern, you must use
403 @ref{User GC} instead.
405 The base class and its discriminator must be identified using the ``desc''
406 option. Each concrete subclass must use the ``tag'' option to identify
407 which value of the discriminator it corresponds to.
409 Every class in the hierarchy must have a @code{GTY(())} marker, as
410 gengtype will only attempt to parse classes that have such a marker
411 @footnote{Classes lacking such a marker will not be identified as being
412 part of the hierarchy, and so the marking routines will not handle them,
413 leading to a assertion failure within the marking routines due to an
414 unknown tag value (assuming that assertions are enabled).}.
417 class GTY((desc("%h.kind"), tag("0"))) example_base
424 class GTY((tag("1"))) some_subclass : public example_base
430 class GTY((tag("2"))) some_other_subclass : public example_base
437 The generated marking routines for the above will contain a ``switch''
438 on ``kind'', visiting all appropriate fields. For example, if kind is
439 2, it will cast to ``some_other_subclass'' and visit fields a, b, and c.
442 @section Support for user-provided GC marking routines
444 The garbage collector supports types for which no automatic marking
445 code is generated. For these types, the user is required to provide
446 three functions: one to act as a marker for garbage collection, and
447 two functions to act as marker and pointer walker for pre-compiled
450 Given a structure @code{struct GTY((user)) my_struct}, the following functions
451 should be defined to mark @code{my_struct}:
454 void gt_ggc_mx (my_struct *p)
456 /* This marks field 'fld'. */
460 void gt_pch_nx (my_struct *p)
462 /* This marks field 'fld'. */
466 void gt_pch_nx (my_struct *p, gt_pointer_operator op, void *cookie)
468 /* For every field 'fld', call the given pointer operator. */
469 op (&(tp->fld), cookie);
473 In general, each marker @code{M} should call @code{M} for every
474 pointer field in the structure. Fields that are not allocated in GC
475 or are not pointers must be ignored.
477 For embedded lists (e.g., structures with a @code{next} or @code{prev}
478 pointer), the marker must follow the chain and mark every element in
481 Note that the rules for the pointer walker @code{gt_pch_nx (my_struct
482 *, gt_pointer_operator, void *)} are slightly different. In this
483 case, the operation @code{op} must be applied to the @emph{address} of
486 @subsection User-provided marking routines for template types
487 When a template type @code{TP} is marked with @code{GTY}, all
488 instances of that type are considered user-provided types. This means
489 that the individual instances of @code{TP} do not need to be marked
490 with @code{GTY}. The user needs to provide template functions to mark
491 all the fields of the type.
493 The following code snippets represent all the functions that need to
494 be provided. Note that type @code{TP} may reference to more than one
495 type. In these snippets, there is only one type @code{T}, but there
500 void gt_ggc_mx (TP<T> *tp)
502 extern void gt_ggc_mx (T&);
504 /* This marks field 'fld' of type 'T'. */
509 void gt_pch_nx (TP<T> *tp)
511 extern void gt_pch_nx (T&);
513 /* This marks field 'fld' of type 'T'. */
518 void gt_pch_nx (TP<T *> *tp, gt_pointer_operator op, void *cookie)
520 /* For every field 'fld' of 'tp' with type 'T *', call the given
522 op (&(tp->fld), cookie);
526 void gt_pch_nx (TP<T> *tp, gt_pointer_operator, void *cookie)
528 extern void gt_pch_nx (T *, gt_pointer_operator, void *);
530 /* For every field 'fld' of 'tp' with type 'T', call the pointer
531 walker for all the fields of T. */
532 gt_pch_nx (&(tp->fld), op, cookie);
536 Support for user-defined types is currently limited. The following
540 @item Type @code{TP} and all the argument types @code{T} must be
541 marked with @code{GTY}.
543 @item Type @code{TP} can only have type names in its argument list.
545 @item The pointer walker functions are different for @code{TP<T>} and
546 @code{TP<T *>}. In the case of @code{TP<T>}, references to
547 @code{T} must be handled by calling @code{gt_pch_nx} (which
548 will, in turn, walk all the pointers inside fields of @code{T}).
549 In the case of @code{TP<T *>}, references to @code{T *} must be
550 handled by calling the @code{op} function on the address of the
551 pointer (see the code snippets above).
555 @section Marking Roots for the Garbage Collector
556 @cindex roots, marking
557 @cindex marking roots
559 In addition to keeping track of types, the type machinery also locates
560 the global variables (@dfn{roots}) that the garbage collector starts
561 at. Roots must be declared using one of the following syntaxes:
565 @code{extern GTY(([@var{options}])) @var{type} @var{name};}
567 @code{static GTY(([@var{options}])) @var{type} @var{name};}
573 @code{GTY(([@var{options}])) @var{type} @var{name};}
576 is @emph{not} accepted. There should be an @code{extern} declaration
577 of such a variable in a header somewhere---mark that, not the
578 definition. Or, if the variable is only used in one file, make it
582 @section Source Files Containing Type Information
583 @cindex generated files
584 @cindex files, generated
586 Whenever you add @code{GTY} markers to a source file that previously
587 had none, or create a new source file containing @code{GTY} markers,
588 there are three things you need to do:
592 You need to add the file to the list of source files the type
593 machinery scans. There are four cases:
597 For a back-end file, this is usually done
598 automatically; if not, you should add it to @code{target_gtfiles} in
599 the appropriate port's entries in @file{config.gcc}.
602 For files shared by all front ends, add the filename to the
603 @code{GTFILES} variable in @file{Makefile.in}.
606 For files that are part of one front end, add the filename to the
607 @code{gtfiles} variable defined in the appropriate
608 @file{config-lang.in}.
609 Headers should appear before non-headers in this list.
612 For files that are part of some but not all front ends, add the
613 filename to the @code{gtfiles} variable of @emph{all} the front ends
618 If the file was a header file, you'll need to check that it's included
619 in the right place to be visible to the generated files. For a back-end
620 header file, this should be done automatically. For a front-end header
621 file, it needs to be included by the same file that includes
622 @file{gtype-@var{lang}.h}. For other header files, it needs to be
623 included in @file{gtype-desc.c}, which is a generated file, so add it to
624 @code{ifiles} in @code{open_base_file} in @file{gengtype.c}.
626 For source files that aren't header files, the machinery will generate a
627 header file that should be included in the source file you just changed.
628 The file will be called @file{gt-@var{path}.h} where @var{path} is the
629 pathname relative to the @file{gcc} directory with slashes replaced by
630 @verb{|-|}, so for example the header file to be included in
631 @file{cp/parser.c} is called @file{gt-cp-parser.c}. The
632 generated header file should be included after everything else in the
633 source file. Don't forget to mention this file as a dependency in the
638 For language frontends, there is another file that needs to be included
639 somewhere. It will be called @file{gtype-@var{lang}.h}, where
640 @var{lang} is the name of the subdirectory the language is contained in.
642 Plugins can add additional root tables. Run the @code{gengtype}
643 utility in plugin mode as @code{gengtype -P pluginout.h @var{source-dir}
644 @var{file-list} @var{plugin*.c}} with your plugin files
645 @var{plugin*.c} using @code{GTY} to generate the @var{pluginout.h} file.
646 The GCC build tree is needed to be present in that mode.
649 @node Invoking the garbage collector
650 @section How to invoke the garbage collector
651 @cindex garbage collector, invocation
654 The GCC garbage collector GGC is only invoked explicitly. In contrast
655 with many other garbage collectors, it is not implicitly invoked by
656 allocation routines when a lot of memory has been consumed. So the
657 only way to have GGC reclaim storage is to call the @code{ggc_collect}
658 function explicitly. This call is an expensive operation, as it may
659 have to scan the entire heap. Beware that local variables (on the GCC
660 call stack) are not followed by such an invocation (as many other
661 garbage collectors do): you should reference all your data from static
662 or external @code{GTY}-ed variables, and it is advised to call
663 @code{ggc_collect} with a shallow call stack. The GGC is an exact mark
664 and sweep garbage collector (so it does not scan the call stack for
665 pointers). In practice GCC passes don't often call @code{ggc_collect}
666 themselves, because it is called by the pass manager between passes.
668 At the time of the @code{ggc_collect} call all pointers in the GC-marked
669 structures must be valid or @code{NULL}. In practice this means that
670 there should not be uninitialized pointer fields in the structures even
671 if your code never reads or writes those fields at a particular
672 instance. One way to ensure this is to use cleared versions of
673 allocators unless all the fields are initialized manually immediately
676 @node Troubleshooting
677 @section Troubleshooting the garbage collector
678 @cindex garbage collector, troubleshooting
680 With the current garbage collector implementation, most issues should
681 show up as GCC compilation errors. Some of the most commonly
682 encountered issues are described below.
685 @item Gengtype does not produce allocators for a @code{GTY}-marked type.
686 Gengtype checks if there is at least one possible path from GC roots to
687 at least one instance of each type before outputting allocators. If
688 there is no such path, the @code{GTY} markers will be ignored and no
689 allocators will be output. Solve this by making sure that there exists
690 at least one such path. If creating it is unfeasible or raises a ``code
691 smell'', consider if you really must use GC for allocating such type.
693 @item Link-time errors about undefined @code{gt_ggc_r_foo_bar} and
694 similarly-named symbols. Check if your @file{foo_bar} source file has
695 @code{#include "gt-foo_bar.h"} as its very last line.