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PR other/66259 * config-ml.in: Reflects renaming of configure.in to configure.ac * configure: Likewise * configure.ac: Likewise boehm-gc/ PR other/66259 * Makefile.direct: Reflects renaming of configure.in to configure.ac * Makefile.dist: Likewise * version.h: Likewise * doc/README: Likewise config/ PR other/66259 * gettext.m4: Reflects renaming of configure.in to configure.ac * po.m4: Likewise * stdint.m4: Likewise * tcl.m4: Likewise gcc/ PR other/66259 * acinclude.m4: Reflects renaming of configure.in to configure.ac * configure: Likewise * configure.ac: Likewise * doc/install.texi: Likewise * doc/tm.texi: Likewise * doc/tm.texi.in: Likewise gcc/ada/ PR other/66259 * prj-nmsc.adb: Reflects renaming of configure.in to configure.ac * gcc-interface/Makefile.in: Likewise intl/ PR other/66259 * configure: Reflects renaming of configure.in to configure.ac libjava/ PR other/66259 * configure: Reflects renaming of configure.in to configure.ac libjava/classpath PR other/66259 * INSTALL: Reflects renaming of configure.in to configure.ac * ltconfig: Likewise * missing: Likewise * m4/ac_prog_javac.m4: Likewise * m4/ac_prog/javac_works.m4: Likewise * resource/META-INF/mimetypes.default: Likewise libjava/libltdl PR other/66259 * THREADS: Reflects renaming of configure.in to configure.ac liboffloadmic/ PR other/66259 * configure: Reflects renaming of configure.in to configure.ac From-SVN: r226183 |
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Copyright (c) 1988, 1989 Hans-J. Boehm, Alan J. Demers Copyright (c) 1991-1996 by Xerox Corporation. All rights reserved. Copyright (c) 1996-1999 by Silicon Graphics. All rights reserved. Copyright (c) 1999-2004 Hewlett-Packard Development Company, L.P. The file linux_threads.c is also Copyright (c) 1998 by Fergus Henderson. All rights reserved. The files Makefile.am, and configure.ac are Copyright (c) 2001 by Red Hat Inc. All rights reserved. Several files supporting GNU-style builds are copyrighted by the Free Software Foundation, and carry a different license from that given below. THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY EXPRESSED OR IMPLIED. ANY USE IS AT YOUR OWN RISK. Permission is hereby granted to use or copy this program for any purpose, provided the above notices are retained on all copies. Permission to modify the code and to distribute modified code is granted, provided the above notices are retained, and a notice that the code was modified is included with the above copyright notice. A few of the files needed to use the GNU-style build procedure come with slightly different licenses, though they are all similar in spirit. A few are GPL'ed, but with an exception that should cover all uses in the collector. (If you are concerned about such things, I recommend you look at the notice in config.guess or ltmain.sh.) This is version 6.6 of a conservative garbage collector for C and C++. You might find a more recent version of this at http://www.hpl.hp.com/personal/Hans_Boehm/gc OVERVIEW This is intended to be a general purpose, garbage collecting storage allocator. The algorithms used are described in: Boehm, H., and M. Weiser, "Garbage Collection in an Uncooperative Environment", Software Practice & Experience, September 1988, pp. 807-820. Boehm, H., A. Demers, and S. Shenker, "Mostly Parallel Garbage Collection", Proceedings of the ACM SIGPLAN '91 Conference on Programming Language Design and Implementation, SIGPLAN Notices 26, 6 (June 1991), pp. 157-164. Boehm, H., "Space Efficient Conservative Garbage Collection", Proceedings of the ACM SIGPLAN '91 Conference on Programming Language Design and Implementation, SIGPLAN Notices 28, 6 (June 1993), pp. 197-206. Boehm H., "Reducing Garbage Collector Cache Misses", Proceedings of the 2000 International Symposium on Memory Management. Possible interactions between the collector and optimizing compilers are discussed in Boehm, H., and D. Chase, "A Proposal for GC-safe C Compilation", The Journal of C Language Translation 4, 2 (December 1992). and Boehm H., "Simple GC-safe Compilation", Proceedings of the ACM SIGPLAN '96 Conference on Programming Language Design and Implementation. (Some of these are also available from http://www.hpl.hp.com/personal/Hans_Boehm/papers/, among other places.) Unlike the collector described in the second reference, this collector operates either with the mutator stopped during the entire collection (default) or incrementally during allocations. (The latter is supported on only a few machines.) On the most common platforms, it can be built with or without thread support. On a few platforms, it can take advantage of a multiprocessor to speed up garbage collection. Many of the ideas underlying the collector have previously been explored by others. Notably, some of the run-time systems developed at Xerox PARC in the early 1980s conservatively scanned thread stacks to locate possible pointers (cf. Paul Rovner, "On Adding Garbage Collection and Runtime Types to a Strongly-Typed Statically Checked, Concurrent Language" Xerox PARC CSL 84-7). Doug McIlroy wrote a simpler fully conservative collector that was part of version 8 UNIX (tm), but appears to not have received widespread use. Rudimentary tools for use of the collector as a leak detector are included (see http://www.hpl.hp.com/personal/Hans_Boehm/gc/leak.html), as is a fairly sophisticated string package "cord" that makes use of the collector. (See doc/README.cords and H.-J. Boehm, R. Atkinson, and M. Plass, "Ropes: An Alternative to Strings", Software Practice and Experience 25, 12 (December 1995), pp. 1315-1330. This is very similar to the "rope" package in Xerox Cedar, or the "rope" package in the SGI STL or the g++ distribution.) Further collector documantation can be found at http://www.hpl.hp.com/personal/Hans_Boehm/gc GENERAL DESCRIPTION This is a garbage collecting storage allocator that is intended to be used as a plug-in replacement for C's malloc. Since the collector does not require pointers to be tagged, it does not attempt to ensure that all inaccessible storage is reclaimed. However, in our experience, it is typically more successful at reclaiming unused memory than most C programs using explicit deallocation. Unlike manually introduced leaks, the amount of unreclaimed memory typically stays bounded. In the following, an "object" is defined to be a region of memory allocated by the routines described below. Any objects not intended to be collected must be pointed to either from other such accessible objects, or from the registers, stack, data, or statically allocated bss segments. Pointers from the stack or registers may point to anywhere inside an object. The same is true for heap pointers if the collector is compiled with ALL_INTERIOR_POINTERS defined, as is now the default. Compiling without ALL_INTERIOR_POINTERS may reduce accidental retention of garbage objects, by requiring pointers from the heap to to the beginning of an object. But this no longer appears to be a significant issue for most programs. There are a number of routines which modify the pointer recognition algorithm. GC_register_displacement allows certain interior pointers to be recognized even if ALL_INTERIOR_POINTERS is nor defined. GC_malloc_ignore_off_page allows some pointers into the middle of large objects to be disregarded, greatly reducing the probablility of accidental retention of large objects. For most purposes it seems best to compile with ALL_INTERIOR_POINTERS and to use GC_malloc_ignore_off_page if you get collector warnings from allocations of very large objects. See README.debugging for details. WARNING: pointers inside memory allocated by the standard "malloc" are not seen by the garbage collector. Thus objects pointed to only from such a region may be prematurely deallocated. It is thus suggested that the standard "malloc" be used only for memory regions, such as I/O buffers, that are guaranteed not to contain pointers to garbage collectable memory. Pointers in C language automatic, static, or register variables, are correctly recognized. (Note that GC_malloc_uncollectable has semantics similar to standard malloc, but allocates objects that are traced by the collector.) WARNING: the collector does not always know how to find pointers in data areas that are associated with dynamic libraries. This is easy to remedy IF you know how to find those data areas on your operating system (see GC_add_roots). Code for doing this under SunOS, IRIX 5.X and 6.X, HP/UX, Alpha OSF/1, Linux, and win32 is included and used by default. (See README.win32 for win32 details.) On other systems pointers from dynamic library data areas may not be considered by the collector. If you're writing a program that depends on the collector scanning dynamic library data areas, it may be a good idea to include at least one call to GC_is_visible() to ensure that those areas are visible to the collector. Note that the garbage collector does not need to be informed of shared read-only data. However if the shared library mechanism can introduce discontiguous data areas that may contain pointers, then the collector does need to be informed. Signal processing for most signals may be deferred during collection, and during uninterruptible parts of the allocation process. Like standard ANSI C mallocs, by default it is unsafe to invoke malloc (and other GC routines) from a signal handler while another malloc call may be in progress. Removing -DNO_SIGNALS from Makefile attempts to remedy that. But that may not be reliable with a compiler that substantially reorders memory operations inside GC_malloc. The allocator/collector can also be configured for thread-safe operation. (Full signal safety can also be achieved, but only at the cost of two system calls per malloc, which is usually unacceptable.) WARNING: the collector does not guarantee to scan thread-local storage (e.g. of the kind accessed with pthread_getspecific()). The collector does scan thread stacks, though, so generally the best solution is to ensure that any pointers stored in thread-local storage are also stored on the thread's stack for the duration of their lifetime. (This is arguably a longstanding bug, but it hasn't been fixed yet.) INSTALLATION AND PORTABILITY As distributed, the macro SILENT is defined in Makefile. In the event of problems, this can be removed to obtain a moderate amount of descriptive output for each collection. (The given statistics exhibit a few peculiarities. Things don't appear to add up for a variety of reasons, most notably fragmentation losses. These are probably much more significant for the contrived program "test.c" than for your application.) Note that typing "make test" will automatically build the collector and then run setjmp_test and gctest. Setjmp_test will give you information about configuring the collector, which is useful primarily if you have a machine that's not already supported. Gctest is a somewhat superficial test of collector functionality. Failure is indicated by a core dump or a message to the effect that the collector is broken. Gctest takes about 35 seconds to run on a SPARCstation 2. It may use up to 8 MB of memory. (The multi-threaded version will use more. 64-bit versions may use more.) "Make test" will also, as its last step, attempt to build and test the "cord" string library. This will fail without an ANSI C compiler, but the garbage collector itself should still be usable. The Makefile will generate a library gc.a which you should link against. Typing "make cords" will add the cord library to gc.a. Note that this requires an ANSI C compiler. It is suggested that if you need to replace a piece of the collector (e.g. GC_mark_rts.c) you simply list your version ahead of gc.a on the ld command line, rather than replacing the one in gc.a. (This will generate numerous warnings under some versions of AIX, but it still works.) All include files that need to be used by clients will be put in the include subdirectory. (Normally this is just gc.h. "Make cords" adds "cord.h" and "ec.h".) The collector currently is designed to run essentially unmodified on machines that use a flat 32-bit or 64-bit address space. That includes the vast majority of Workstations and X86 (X >= 3) PCs. (The list here was deleted because it was getting too long and constantly out of date.) It does NOT run under plain 16-bit DOS or Windows 3.X. There are however various packages (e.g. win32s, djgpp) that allow flat 32-bit address applications to run under those systemsif the have at least an 80386 processor, and several of those are compatible with the collector. In a few cases (Amiga, OS/2, Win32, MacOS) a separate makefile or equivalent is supplied. Many of these have separate README.system files. Dynamic libraries are completely supported only under SunOS/Solaris, (and even that support is not functional on the last Sun 3 release), Linux, FreeBSD, NetBSD, IRIX 5&6, HP/UX, Win32 (not Win32S) and OSF/1 on DEC AXP machines plus perhaps a few others listed near the top of dyn_load.c. On other machines we recommend that you do one of the following: 1) Add dynamic library support (and send us the code). 2) Use static versions of the libraries. 3) Arrange for dynamic libraries to use the standard malloc. This is still dangerous if the library stores a pointer to a garbage collected object. But nearly all standard interfaces prohibit this, because they deal correctly with pointers to stack allocated objects. (Strtok is an exception. Don't use it.) In all cases we assume that pointer alignment is consistent with that enforced by the standard C compilers. If you use a nonstandard compiler you may have to adjust the alignment parameters defined in gc_priv.h. Note that this may also be an issue with packed records/structs, if those enforce less alignment for pointers. A port to a machine that is not byte addressed, or does not use 32 bit or 64 bit addresses will require a major effort. A port to plain MSDOS or win16 is hard. For machines not already mentioned, or for nonstandard compilers, the following are likely to require change: 1. The parameters in gcconfig.h. The parameters that will usually require adjustment are STACKBOTTOM, ALIGNMENT and DATASTART. Setjmp_test prints its guesses of the first two. DATASTART should be an expression for computing the address of the beginning of the data segment. This can often be &etext. But some memory management units require that there be some unmapped space between the text and the data segment. Thus it may be more complicated. On UNIX systems, this is rarely documented. But the adb "$m" command may be helpful. (Note that DATASTART will usually be a function of &etext. Thus a single experiment is usually insufficient.) STACKBOTTOM is used to initialize GC_stackbottom, which should be a sufficient approximation to the coldest stack address. On some machines, it is difficult to obtain such a value that is valid across a variety of MMUs, OS releases, etc. A number of alternatives exist for using the collector in spite of this. See the discussion in gcconfig.h immediately preceding the various definitions of STACKBOTTOM. 2. mach_dep.c. The most important routine here is one to mark from registers. The distributed file includes a generic hack (based on setjmp) that happens to work on many machines, and may work on yours. Try compiling and running setjmp_t.c to see whether it has a chance of working. (This is not correct C, so don't blame your compiler if it doesn't work. Based on limited experience, register window machines are likely to cause trouble. If your version of setjmp claims that all accessible variables, including registers, have the value they had at the time of the longjmp, it also will not work. Vanilla 4.2 BSD on Vaxen makes such a claim. SunOS does not.) If your compiler does not allow in-line assembly code, or if you prefer not to use such a facility, mach_dep.c may be replaced by a .s file (as we did for the MIPS machine and the PC/RT). At this point enough architectures are supported by mach_dep.c that you will rarely need to do more than adjust for assembler syntax. 3. os_dep.c (and gc_priv.h). Several kinds of operating system dependent routines reside here. Many are optional. Several are invoked only through corresponding macros in gc_priv.h, which may also be redefined as appropriate. The routine GC_register_data_segments is crucial. It registers static data areas that must be traversed by the collector. (User calls to GC_add_roots may sometimes be used for similar effect.) Routines to obtain memory from the OS also reside here. Alternatively this can be done entirely by the macro GET_MEM defined in gc_priv.h. Routines to disable and reenable signals also reside here if they are need by the macros DISABLE_SIGNALS and ENABLE_SIGNALS defined in gc_priv.h. In a multithreaded environment, the macros LOCK and UNLOCK in gc_priv.h will need to be suitably redefined. The incremental collector requires page dirty information, which is acquired through routines defined in os_dep.c. Unless directed otherwise by gcconfig.h, these are implemented as stubs that simply treat all pages as dirty. (This of course makes the incremental collector much less useful.) 4. dyn_load.c This provides a routine that allows the collector to scan data segments associated with dynamic libraries. Often it is not necessary to provide this routine unless user-written dynamic libraries are used. For a different version of UN*X or different machines using the Motorola 68000, Vax, SPARC, 80386, NS 32000, PC/RT, or MIPS architecture, it should frequently suffice to change definitions in gcconfig.h. THE C INTERFACE TO THE ALLOCATOR The following routines are intended to be directly called by the user. Note that usually only GC_malloc is necessary. GC_clear_roots and GC_add_roots calls may be required if the collector has to trace from nonstandard places (e.g. from dynamic library data areas on a machine on which the collector doesn't already understand them.) On some machines, it may be desirable to set GC_stacktop to a good approximation of the stack base. (This enhances code portability on HP PA machines, since there is no good way for the collector to compute this value.) Client code may include "gc.h", which defines all of the following, plus many others. 1) GC_malloc(nbytes) - allocate an object of size nbytes. Unlike malloc, the object is cleared before being returned to the user. Gc_malloc will invoke the garbage collector when it determines this to be appropriate. GC_malloc may return 0 if it is unable to acquire sufficient space from the operating system. This is the most probable consequence of running out of space. Other possible consequences are that a function call will fail due to lack of stack space, or that the collector will fail in other ways because it cannot maintain its internal data structures, or that a crucial system process will fail and take down the machine. Most of these possibilities are independent of the malloc implementation. 2) GC_malloc_atomic(nbytes) - allocate an object of size nbytes that is guaranteed not to contain any pointers. The returned object is not guaranteed to be cleared. (Can always be replaced by GC_malloc, but results in faster collection times. The collector will probably run faster if large character arrays, etc. are allocated with GC_malloc_atomic than if they are statically allocated.) 3) GC_realloc(object, new_size) - change the size of object to be new_size. Returns a pointer to the new object, which may, or may not, be the same as the pointer to the old object. The new object is taken to be atomic iff the old one was. If the new object is composite and larger than the original object, then the newly added bytes are cleared (we hope). This is very likely to allocate a new object, unless MERGE_SIZES is defined in gc_priv.h. Even then, it is likely to recycle the old object only if the object is grown in small additive increments (which, we claim, is generally bad coding practice.) 4) GC_free(object) - explicitly deallocate an object returned by GC_malloc or GC_malloc_atomic. Not necessary, but can be used to minimize collections if performance is critical. Probably a performance loss for very small objects (<= 8 bytes). 5) GC_expand_hp(bytes) - Explicitly increase the heap size. (This is normally done automatically if a garbage collection failed to GC_reclaim enough memory. Explicit calls to GC_expand_hp may prevent unnecessarily frequent collections at program startup.) 6) GC_malloc_ignore_off_page(bytes) - identical to GC_malloc, but the client promises to keep a pointer to the somewhere within the first 256 bytes of the object while it is live. (This pointer should nortmally be declared volatile to prevent interference from compiler optimizations.) This is the recommended way to allocate anything that is likely to be larger than 100Kbytes or so. (GC_malloc may result in failure to reclaim such objects.) 7) GC_set_warn_proc(proc) - Can be used to redirect warnings from the collector. Such warnings should be rare, and should not be ignored during code development. 8) GC_enable_incremental() - Enables generational and incremental collection. Useful for large heaps on machines that provide access to page dirty information. Some dirty bit implementations may interfere with debugging (by catching address faults) and place restrictions on heap arguments to system calls (since write faults inside a system call may not be handled well). 9) Several routines to allow for registration of finalization code. User supplied finalization code may be invoked when an object becomes unreachable. To call (*f)(obj, x) when obj becomes inaccessible, use GC_register_finalizer(obj, f, x, 0, 0); For more sophisticated uses, and for finalization ordering issues, see gc.h. The global variable GC_free_space_divisor may be adjusted up from its default value of 4 to use less space and more collection time, or down for the opposite effect. Setting it to 1 or 0 will effectively disable collections and cause all allocations to simply grow the heap. The variable GC_non_gc_bytes, which is normally 0, may be changed to reflect the amount of memory allocated by the above routines that should not be considered as a candidate for collection. Careless use may, of course, result in excessive memory consumption. Some additional tuning is possible through the parameters defined near the top of gc_priv.h. If only GC_malloc is intended to be used, it might be appropriate to define: #define malloc(n) GC_malloc(n) #define calloc(m,n) GC_malloc((m)*(n)) For small pieces of VERY allocation intensive code, gc_inl.h includes some allocation macros that may be used in place of GC_malloc and friends. All externally visible names in the garbage collector start with "GC_". To avoid name conflicts, client code should avoid this prefix, except when accessing garbage collector routines or variables. There are provisions for allocation with explicit type information. This is rarely necessary. Details can be found in gc_typed.h. THE C++ INTERFACE TO THE ALLOCATOR: The Ellis-Hull C++ interface to the collector is included in the collector distribution. If you intend to use this, type "make c++" after the initial build of the collector is complete. See gc_cpp.h for the definition of the interface. This interface tries to approximate the Ellis-Detlefs C++ garbage collection proposal without compiler changes. Cautions: 1. Arrays allocated without new placement syntax are allocated as uncollectable objects. They are traced by the collector, but will not be reclaimed. 2. Failure to use "make c++" in combination with (1) will result in arrays allocated using the default new operator. This is likely to result in disaster without linker warnings. 3. If your compiler supports an overloaded new[] operator, then gc_cpp.cc and gc_cpp.h should be suitably modified. 4. Many current C++ compilers have deficiencies that break some of the functionality. See the comments in gc_cpp.h for suggested workarounds. USE AS LEAK DETECTOR: The collector may be used to track down leaks in C programs that are intended to run with malloc/free (e.g. code with extreme real-time or portability constraints). To do so define FIND_LEAK in Makefile This will cause the collector to invoke the report_leak routine defined near the top of reclaim.c whenever an inaccessible object is found that has not been explicitly freed. Such objects will also be automatically reclaimed. Productive use of this facility normally involves redefining report_leak to do something more intelligent. This typically requires annotating objects with additional information (e.g. creation time stack trace) that identifies their origin. Such code is typically not very portable, and is not included here, except on SPARC machines. If all objects are allocated with GC_DEBUG_MALLOC (see next section), then the default version of report_leak will report the source file and line number at which the leaked object was allocated. This may sometimes be sufficient. (On SPARC/SUNOS4 machines, it will also report a cryptic stack trace. This can often be turned into a sympolic stack trace by invoking program "foo" with "callprocs foo". Callprocs is a short shell script that invokes adb to expand program counter values to symbolic addresses. It was largely supplied by Scott Schwartz.) Note that the debugging facilities described in the next section can sometimes be slightly LESS effective in leak finding mode, since in leak finding mode, GC_debug_free actually results in reuse of the object. (Otherwise the object is simply marked invalid.) Also note that the test program is not designed to run meaningfully in FIND_LEAK mode. Use "make gc.a" to build the collector. DEBUGGING FACILITIES: The routines GC_debug_malloc, GC_debug_malloc_atomic, GC_debug_realloc, and GC_debug_free provide an alternate interface to the collector, which provides some help with memory overwrite errors, and the like. Objects allocated in this way are annotated with additional information. Some of this information is checked during garbage collections, and detected inconsistencies are reported to stderr. Simple cases of writing past the end of an allocated object should be caught if the object is explicitly deallocated, or if the collector is invoked while the object is live. The first deallocation of an object will clear the debugging info associated with an object, so accidentally repeated calls to GC_debug_free will report the deallocation of an object without debugging information. Out of memory errors will be reported to stderr, in addition to returning NIL. GC_debug_malloc checking during garbage collection is enabled with the first call to GC_debug_malloc. This will result in some slowdown during collections. If frequent heap checks are desired, this can be achieved by explicitly invoking GC_gcollect, e.g. from the debugger. GC_debug_malloc allocated objects should not be passed to GC_realloc or GC_free, and conversely. It is however acceptable to allocate only some objects with GC_debug_malloc, and to use GC_malloc for other objects, provided the two pools are kept distinct. In this case, there is a very low probablility that GC_malloc allocated objects may be misidentified as having been overwritten. This should happen with probability at most one in 2**32. This probability is zero if GC_debug_malloc is never called. GC_debug_malloc, GC_malloc_atomic, and GC_debug_realloc take two additional trailing arguments, a string and an integer. These are not interpreted by the allocator. They are stored in the object (the string is not copied). If an error involving the object is detected, they are printed. The macros GC_MALLOC, GC_MALLOC_ATOMIC, GC_REALLOC, GC_FREE, and GC_REGISTER_FINALIZER are also provided. These require the same arguments as the corresponding (nondebugging) routines. If gc.h is included with GC_DEBUG defined, they call the debugging versions of these functions, passing the current file name and line number as the two extra arguments, where appropriate. If gc.h is included without GC_DEBUG defined, then all these macros will instead be defined to their nondebugging equivalents. (GC_REGISTER_FINALIZER is necessary, since pointers to objects with debugging information are really pointers to a displacement of 16 bytes form the object beginning, and some translation is necessary when finalization routines are invoked. For details, about what's stored in the header, see the definition of the type oh in debug_malloc.c) INCREMENTAL/GENERATIONAL COLLECTION: The collector normally interrupts client code for the duration of a garbage collection mark phase. This may be unacceptable if interactive response is needed for programs with large heaps. The collector can also run in a "generational" mode, in which it usually attempts to collect only objects allocated since the last garbage collection. Furthermore, in this mode, garbage collections run mostly incrementally, with a small amount of work performed in response to each of a large number of GC_malloc requests. This mode is enabled by a call to GC_enable_incremental(). Incremental and generational collection is effective in reducing pause times only if the collector has some way to tell which objects or pages have been recently modified. The collector uses two sources of information: 1. Information provided by the VM system. This may be provided in one of several forms. Under Solaris 2.X (and potentially under other similar systems) information on dirty pages can be read from the /proc file system. Under other systems (currently SunOS4.X) it is possible to write-protect the heap, and catch the resulting faults. On these systems we require that system calls writing to the heap (other than read) be handled specially by client code. See os_dep.c for details. 2. Information supplied by the programmer. We define "stubborn" objects to be objects that are rarely changed. Such an object can be allocated (and enabled for writing) with GC_malloc_stubborn. Once it has been initialized, the collector should be informed with a call to GC_end_stubborn_change. Subsequent writes that store pointers into the object must be preceded by a call to GC_change_stubborn. This mechanism performs best for objects that are written only for initialization, and such that only one stubborn object is writable at once. It is typically not worth using for short-lived objects. Stubborn objects are treated less efficiently than pointerfree (atomic) objects. A rough rule of thumb is that, in the absence of VM information, garbage collection pauses are proportional to the amount of pointerful storage plus the amount of modified "stubborn" storage that is reachable during the collection. Initial allocation of stubborn objects takes longer than allocation of other objects, since other data structures need to be maintained. We recommend against random use of stubborn objects in client code, since bugs caused by inappropriate writes to stubborn objects are likely to be very infrequently observed and hard to trace. However, their use may be appropriate in a few carefully written library routines that do not make the objects themselves available for writing by client code. BUGS: Any memory that does not have a recognizable pointer to it will be reclaimed. Exclusive-or'ing forward and backward links in a list doesn't cut it. Some C optimizers may lose the last undisguised pointer to a memory object as a consequence of clever optimizations. This has almost never been observed in practice. Send mail to boehm@acm.org for suggestions on how to fix your compiler. This is not a real-time collector. In the standard configuration, percentage of time required for collection should be constant across heap sizes. But collection pauses will increase for larger heaps. (On SPARCstation 2s collection times will be on the order of 300 msecs per MB of accessible memory that needs to be scanned. Your mileage may vary.) The incremental/generational collection facility helps, but is portable only if "stubborn" allocation is used. Please address bug reports to boehm@acm.org. If you are contemplating a major addition, you might also send mail to ask whether it's already been done (or whether we tried and discarded it).