/* * Copyright 1988, 1989 Hans-J. Boehm, Alan J. Demers * Copyright (c) 1991-1995 by Xerox Corporation. All rights reserved. * Copyright (c) 1997 by Silicon Graphics. All rights reserved. * Copyright (c) 1999-2004 Hewlett-Packard Development Company, L.P. * Copyright (C) 2007 Free Software Foundation, Inc * * 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. */ #include "private/dbg_mlc.h" #ifndef MSWINCE # include #endif #include #ifndef SHORT_DBG_HDRS /* Check whether object with base pointer p has debugging info. */ /* p is assumed to point to a legitimate object in our part */ /* of the heap. */ /* This excludes the check as to whether the back pointer is */ /* odd, which is added by the GC_HAS_DEBUG_INFO macro. */ /* Note that if DBG_HDRS_ALL is set, uncollectible objects */ /* on free lists may not have debug information set. Thus it's */ /* not always safe to return TRUE (1), even if the client does */ /* its part. Return -1 if the object with debug info has been */ /* marked as deallocated. */ GC_INNER int GC_has_other_debug_info(ptr_t p) { ptr_t body = (ptr_t)((oh *)p + 1); word sz = GC_size(p); if (HBLKPTR(p) != HBLKPTR((ptr_t)body) || sz < DEBUG_BYTES + EXTRA_BYTES) { return 0; } if (((oh *)p) -> oh_sf != (START_FLAG ^ (word)body) && ((word *)p)[BYTES_TO_WORDS(sz)-1] != (END_FLAG ^ (word)body)) { return 0; } if (((oh *)p)->oh_sz == sz) { /* Object may have had debug info, but has been deallocated */ return -1; } return 1; } #endif /* !SHORT_DBG_HDRS */ #ifdef LINT2 long GC_random(void) { static unsigned seed = 1; /* not thread-safe */ /* Linear congruential pseudo-random numbers generator. */ seed = (seed * 1103515245U + 12345) & GC_RAND_MAX; /* overflow is ok */ return (long)seed; } #endif #ifdef KEEP_BACK_PTRS #ifdef LINT2 # define RANDOM() GC_random() #else # include # define GC_RAND_MAX RAND_MAX # if defined(__GLIBC__) || defined(SOLARIS) \ || defined(HPUX) || defined(IRIX5) || defined(OSF1) # define RANDOM() random() # else # define RANDOM() (long)rand() # endif #endif /* !LINT2 */ /* Store back pointer to source in dest, if that appears to be possible. */ /* This is not completely safe, since we may mistakenly conclude that */ /* dest has a debugging wrapper. But the error probability is very */ /* small, and this shouldn't be used in production code. */ /* We assume that dest is the real base pointer. Source will usually */ /* be a pointer to the interior of an object. */ GC_INNER void GC_store_back_pointer(ptr_t source, ptr_t dest) { if (GC_HAS_DEBUG_INFO(dest)) { ((oh *)dest) -> oh_back_ptr = HIDE_BACK_PTR(source); } } GC_INNER void GC_marked_for_finalization(ptr_t dest) { GC_store_back_pointer(MARKED_FOR_FINALIZATION, dest); } /* Store information about the object referencing dest in *base_p */ /* and *offset_p. */ /* source is root ==> *base_p = address, *offset_p = 0 */ /* source is heap object ==> *base_p != 0, *offset_p = offset */ /* Returns 1 on success, 0 if source couldn't be determined. */ /* Dest can be any address within a heap object. */ GC_API GC_ref_kind GC_CALL GC_get_back_ptr_info(void *dest, void **base_p, size_t *offset_p) { oh * hdr = (oh *)GC_base(dest); ptr_t bp; ptr_t bp_base; # ifdef LINT2 /* Explicitly instruct the code analysis tool that */ /* GC_get_back_ptr_info is not expected to be called with an */ /* incorrect "dest" value. */ if (!hdr) ABORT("Invalid GC_get_back_ptr_info argument"); # endif if (!GC_HAS_DEBUG_INFO((ptr_t) hdr)) return GC_NO_SPACE; bp = GC_REVEAL_POINTER(hdr -> oh_back_ptr); if (MARKED_FOR_FINALIZATION == bp) return GC_FINALIZER_REFD; if (MARKED_FROM_REGISTER == bp) return GC_REFD_FROM_REG; if (NOT_MARKED == bp) return GC_UNREFERENCED; # if ALIGNMENT == 1 /* Heuristically try to fix off by 1 errors we introduced by */ /* insisting on even addresses. */ { ptr_t alternate_ptr = bp + 1; ptr_t target = *(ptr_t *)bp; ptr_t alternate_target = *(ptr_t *)alternate_ptr; if ((word)alternate_target >= (word)GC_least_plausible_heap_addr && (word)alternate_target <= (word)GC_greatest_plausible_heap_addr && ((word)target < (word)GC_least_plausible_heap_addr || (word)target > (word)GC_greatest_plausible_heap_addr)) { bp = alternate_ptr; } } # endif bp_base = GC_base(bp); if (0 == bp_base) { *base_p = bp; *offset_p = 0; return GC_REFD_FROM_ROOT; } else { if (GC_HAS_DEBUG_INFO(bp_base)) bp_base += sizeof(oh); *base_p = bp_base; *offset_p = bp - bp_base; return GC_REFD_FROM_HEAP; } } /* Generate a random heap address. */ /* The resulting address is in the heap, but */ /* not necessarily inside a valid object. */ GC_API void * GC_CALL GC_generate_random_heap_address(void) { size_t i; word heap_offset = RANDOM(); if (GC_heapsize > GC_RAND_MAX) { heap_offset *= GC_RAND_MAX; heap_offset += RANDOM(); } heap_offset %= GC_heapsize; /* This doesn't yield a uniform distribution, especially if */ /* e.g. RAND_MAX = 1.5* GC_heapsize. But for typical cases, */ /* it's not too bad. */ for (i = 0;; ++i) { size_t size; if (i >= GC_n_heap_sects) ABORT("GC_generate_random_heap_address: size inconsistency"); size = GC_heap_sects[i].hs_bytes; if (heap_offset < size) { break; } else { heap_offset -= size; } } return GC_heap_sects[i].hs_start + heap_offset; } /* Generate a random address inside a valid marked heap object. */ GC_API void * GC_CALL GC_generate_random_valid_address(void) { ptr_t result; ptr_t base; do { result = GC_generate_random_heap_address(); base = GC_base(result); } while (base == 0 || !GC_is_marked(base)); return result; } /* Print back trace for p */ GC_API void GC_CALL GC_print_backtrace(void *p) { void *current = p; int i; GC_ref_kind source; size_t offset; void *base; GC_print_heap_obj(GC_base(current)); for (i = 0; ; ++i) { source = GC_get_back_ptr_info(current, &base, &offset); if (GC_UNREFERENCED == source) { GC_err_printf("Reference could not be found\n"); goto out; } if (GC_NO_SPACE == source) { GC_err_printf("No debug info in object: Can't find reference\n"); goto out; } GC_err_printf("Reachable via %d levels of pointers from ", i); switch(source) { case GC_REFD_FROM_ROOT: GC_err_printf("root at %p\n\n", base); goto out; case GC_REFD_FROM_REG: GC_err_printf("root in register\n\n"); goto out; case GC_FINALIZER_REFD: GC_err_printf("list of finalizable objects\n\n"); goto out; case GC_REFD_FROM_HEAP: GC_err_printf("offset %ld in object:\n", (long)offset); /* Take GC_base(base) to get real base, i.e. header. */ GC_print_heap_obj(GC_base(base)); break; default: GC_err_printf("INTERNAL ERROR: UNEXPECTED SOURCE!!!!\n"); goto out; } current = base; } out:; } /* Force a garbage collection and generate/print a backtrace */ /* from a random heap address. */ GC_INNER void GC_generate_random_backtrace_no_gc(void) { void * current; current = GC_generate_random_valid_address(); GC_printf("\n****Chosen address %p in object\n", current); GC_print_backtrace(current); } GC_API void GC_CALL GC_generate_random_backtrace(void) { if (GC_try_to_collect(GC_never_stop_func) == 0) { GC_err_printf("Cannot generate a backtrace: " "garbage collection is disabled!\n"); return; } GC_generate_random_backtrace_no_gc(); } #endif /* KEEP_BACK_PTRS */ # define CROSSES_HBLK(p, sz) \ (((word)((p) + sizeof(oh) + (sz) - 1) ^ (word)(p)) >= HBLKSIZE) /* Store debugging info into p. Return displaced pointer. */ /* This version assumes we do hold the allocation lock. */ STATIC ptr_t GC_store_debug_info_inner(ptr_t p, word sz GC_ATTR_UNUSED, const char *string, int linenum) { word * result = (word *)((oh *)p + 1); GC_ASSERT(GC_size(p) >= sizeof(oh) + sz); GC_ASSERT(!(SMALL_OBJ(sz) && CROSSES_HBLK(p, sz))); # ifdef KEEP_BACK_PTRS ((oh *)p) -> oh_back_ptr = HIDE_BACK_PTR(NOT_MARKED); # endif # ifdef MAKE_BACK_GRAPH ((oh *)p) -> oh_bg_ptr = HIDE_BACK_PTR((ptr_t)0); # endif ((oh *)p) -> oh_string = string; ((oh *)p) -> oh_int = (word)linenum; # ifndef SHORT_DBG_HDRS ((oh *)p) -> oh_sz = sz; ((oh *)p) -> oh_sf = START_FLAG ^ (word)result; ((word *)p)[BYTES_TO_WORDS(GC_size(p))-1] = result[SIMPLE_ROUNDED_UP_WORDS(sz)] = END_FLAG ^ (word)result; # endif return((ptr_t)result); } GC_INNER ptr_t GC_store_debug_info(ptr_t p, word sz, const char *string, int linenum) { ptr_t result; DCL_LOCK_STATE; LOCK(); result = GC_store_debug_info_inner(p, sz, string, linenum); UNLOCK(); return result; } #ifndef SHORT_DBG_HDRS /* Check the object with debugging info at ohdr. */ /* Return NULL if it's OK. Else return clobbered */ /* address. */ STATIC ptr_t GC_check_annotated_obj(oh *ohdr) { ptr_t body = (ptr_t)(ohdr + 1); word gc_sz = GC_size((ptr_t)ohdr); if (ohdr -> oh_sz + DEBUG_BYTES > gc_sz) { return((ptr_t)(&(ohdr -> oh_sz))); } if (ohdr -> oh_sf != (START_FLAG ^ (word)body)) { return((ptr_t)(&(ohdr -> oh_sf))); } if (((word *)ohdr)[BYTES_TO_WORDS(gc_sz)-1] != (END_FLAG ^ (word)body)) { return((ptr_t)((word *)ohdr + BYTES_TO_WORDS(gc_sz)-1)); } if (((word *)body)[SIMPLE_ROUNDED_UP_WORDS(ohdr -> oh_sz)] != (END_FLAG ^ (word)body)) { return((ptr_t)((word *)body + SIMPLE_ROUNDED_UP_WORDS(ohdr->oh_sz))); } return(0); } #endif /* !SHORT_DBG_HDRS */ STATIC GC_describe_type_fn GC_describe_type_fns[MAXOBJKINDS] = {0}; GC_API void GC_CALL GC_register_describe_type_fn(int kind, GC_describe_type_fn fn) { GC_describe_type_fns[kind] = fn; } #define GET_OH_LINENUM(ohdr) ((int)(ohdr)->oh_int) #ifndef SHORT_DBG_HDRS # define IF_NOT_SHORTDBG_HDRS(x) x # define COMMA_IFNOT_SHORTDBG_HDRS(x) /* comma */, x #else # define IF_NOT_SHORTDBG_HDRS(x) /* empty */ # define COMMA_IFNOT_SHORTDBG_HDRS(x) /* empty */ #endif /* Print a human-readable description of the object to stderr. */ /* p points to somewhere inside an object with the debugging info. */ STATIC void GC_print_obj(ptr_t p) { oh * ohdr = (oh *)GC_base(p); ptr_t q; hdr * hhdr; int kind; char *kind_str; char buffer[GC_TYPE_DESCR_LEN + 1]; GC_ASSERT(I_DONT_HOLD_LOCK()); # ifdef LINT2 if (!ohdr) ABORT("Invalid GC_print_obj argument"); # endif q = (ptr_t)(ohdr + 1); /* Print a type description for the object whose client-visible */ /* address is q. */ hhdr = GC_find_header(q); kind = hhdr -> hb_obj_kind; if (0 != GC_describe_type_fns[kind] && GC_is_marked(ohdr)) { /* This should preclude free list objects except with */ /* thread-local allocation. */ buffer[GC_TYPE_DESCR_LEN] = 0; (GC_describe_type_fns[kind])(q, buffer); GC_ASSERT(buffer[GC_TYPE_DESCR_LEN] == 0); kind_str = buffer; } else { switch(kind) { case PTRFREE: kind_str = "PTRFREE"; break; case NORMAL: kind_str = "NORMAL"; break; case UNCOLLECTABLE: kind_str = "UNCOLLECTABLE"; break; # ifdef GC_ATOMIC_UNCOLLECTABLE case AUNCOLLECTABLE: kind_str = "ATOMIC_UNCOLLECTABLE"; break; # endif case STUBBORN: kind_str = "STUBBORN"; break; default: kind_str = NULL; /* The alternative is to use snprintf(buffer) but it is */ /* not quite portable (see vsnprintf in misc.c). */ } } if (NULL != kind_str) { GC_err_printf("%p (%s:%d," IF_NOT_SHORTDBG_HDRS(" sz=%lu,") " %s)\n", (void *)((ptr_t)ohdr + sizeof(oh)), ohdr->oh_string, GET_OH_LINENUM(ohdr) /*, */ COMMA_IFNOT_SHORTDBG_HDRS((unsigned long)ohdr->oh_sz), kind_str); } else { GC_err_printf("%p (%s:%d," IF_NOT_SHORTDBG_HDRS(" sz=%lu,") " kind=%d descr=0x%lx)\n", (void *)((ptr_t)ohdr + sizeof(oh)), ohdr->oh_string, GET_OH_LINENUM(ohdr) /*, */ COMMA_IFNOT_SHORTDBG_HDRS((unsigned long)ohdr->oh_sz), kind, (unsigned long)hhdr->hb_descr); } PRINT_CALL_CHAIN(ohdr); } STATIC void GC_debug_print_heap_obj_proc(ptr_t p) { GC_ASSERT(I_DONT_HOLD_LOCK()); if (GC_HAS_DEBUG_INFO(p)) { GC_print_obj(p); } else { GC_default_print_heap_obj_proc(p); } } #ifndef SHORT_DBG_HDRS /* Use GC_err_printf and friends to print a description of the object */ /* whose client-visible address is p, and which was smashed at */ /* clobbered_addr. */ STATIC void GC_print_smashed_obj(const char *msg, ptr_t p, ptr_t clobbered_addr) { oh * ohdr = (oh *)GC_base(p); GC_ASSERT(I_DONT_HOLD_LOCK()); # ifdef LINT2 if (!ohdr) ABORT("Invalid GC_print_smashed_obj argument"); # endif if ((word)clobbered_addr <= (word)(&ohdr->oh_sz) || ohdr -> oh_string == 0) { GC_err_printf( "%s %p in or near object at %p(, appr. sz = %lu)\n", msg, (void *)clobbered_addr, (void *)p, (unsigned long)(GC_size((ptr_t)ohdr) - DEBUG_BYTES)); } else { GC_err_printf("%s %p in or near object at %p (%s:%d, sz=%lu)\n", msg, (void *)clobbered_addr, (void *)p, (word)(ohdr -> oh_string) < HBLKSIZE ? "(smashed string)" : ohdr -> oh_string[0] == '\0' ? "EMPTY(smashed?)" : ohdr -> oh_string, GET_OH_LINENUM(ohdr), (unsigned long)(ohdr -> oh_sz)); PRINT_CALL_CHAIN(ohdr); } } STATIC void GC_check_heap_proc (void); STATIC void GC_print_all_smashed_proc (void); #else STATIC void GC_do_nothing(void) {} #endif GC_INNER void GC_start_debugging_inner(void) { GC_ASSERT(I_HOLD_LOCK()); # ifndef SHORT_DBG_HDRS GC_check_heap = GC_check_heap_proc; GC_print_all_smashed = GC_print_all_smashed_proc; # else GC_check_heap = GC_do_nothing; GC_print_all_smashed = GC_do_nothing; # endif GC_print_heap_obj = GC_debug_print_heap_obj_proc; GC_debugging_started = TRUE; GC_register_displacement_inner((word)sizeof(oh)); } #ifdef THREADS STATIC void GC_start_debugging(void) { DCL_LOCK_STATE; LOCK(); if (!GC_debugging_started) GC_start_debugging_inner(); UNLOCK(); } #else # define GC_start_debugging GC_start_debugging_inner #endif /* !THREADS */ size_t GC_debug_header_size = sizeof(oh); GC_API void GC_CALL GC_debug_register_displacement(size_t offset) { DCL_LOCK_STATE; LOCK(); GC_register_displacement_inner(offset); GC_register_displacement_inner((word)sizeof(oh) + offset); UNLOCK(); } #ifdef GC_ADD_CALLER # if defined(HAVE_DLADDR) && defined(GC_HAVE_RETURN_ADDR_PARENT) # include STATIC void GC_caller_func_offset(word ad, const char **symp, int *offp) { Dl_info caller; if (ad && dladdr((void *)ad, &caller) && caller.dli_sname != NULL) { *symp = caller.dli_sname; *offp = (int)((char *)ad - (char *)caller.dli_saddr); } if (NULL == *symp) { *symp = "unknown"; } } # else # define GC_caller_func_offset(ad, symp, offp) (void)(*(symp) = "unknown") # endif #endif /* GC_ADD_CALLER */ GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc(size_t lb, GC_EXTRA_PARAMS) { void * result; /* Note that according to malloc() specification, if size is 0 then */ /* malloc() returns either NULL, or a unique pointer value that can */ /* later be successfully passed to free(). We always do the latter. */ result = GC_malloc(SIZET_SAT_ADD(lb, DEBUG_BYTES)); # ifdef GC_ADD_CALLER if (s == NULL) { GC_caller_func_offset(ra, &s, &i); } # endif if (result == 0) { GC_err_printf("GC_debug_malloc(%lu) returning NULL (%s:%d)\n", (unsigned long)lb, s, i); return(0); } if (!GC_debugging_started) { GC_start_debugging(); } ADD_CALL_CHAIN(result, ra); return (GC_store_debug_info(result, (word)lb, s, i)); } GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc_ignore_off_page(size_t lb, GC_EXTRA_PARAMS) { void * result = GC_malloc_ignore_off_page(SIZET_SAT_ADD(lb, DEBUG_BYTES)); if (result == 0) { GC_err_printf("GC_debug_malloc_ignore_off_page(%lu)" " returning NULL (%s:%d)\n", (unsigned long)lb, s, i); return(0); } if (!GC_debugging_started) { GC_start_debugging(); } ADD_CALL_CHAIN(result, ra); return (GC_store_debug_info(result, (word)lb, s, i)); } GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc_atomic_ignore_off_page(size_t lb, GC_EXTRA_PARAMS) { void * result = GC_malloc_atomic_ignore_off_page( SIZET_SAT_ADD(lb, DEBUG_BYTES)); if (result == 0) { GC_err_printf("GC_debug_malloc_atomic_ignore_off_page(%lu)" " returning NULL (%s:%d)\n", (unsigned long)lb, s, i); return(0); } if (!GC_debugging_started) { GC_start_debugging(); } ADD_CALL_CHAIN(result, ra); return (GC_store_debug_info(result, (word)lb, s, i)); } STATIC void * GC_debug_generic_malloc(size_t lb, int knd, GC_EXTRA_PARAMS) { void * result = GC_generic_malloc(SIZET_SAT_ADD(lb, DEBUG_BYTES), knd); if (NULL == result) { GC_err_printf( "GC_debug_generic_malloc(%lu, %d) returning NULL (%s:%d)\n", (unsigned long)lb, knd, s, i); return NULL; } if (!GC_debugging_started) { GC_start_debugging(); } ADD_CALL_CHAIN(result, ra); return GC_store_debug_info(result, (word)lb, s, i); } #ifdef DBG_HDRS_ALL /* An allocation function for internal use. Normally internally */ /* allocated objects do not have debug information. But in this */ /* case, we need to make sure that all objects have debug headers. */ /* We assume debugging was started in collector initialization, and */ /* we already hold the GC lock. */ GC_INNER void * GC_debug_generic_malloc_inner(size_t lb, int k) { void * result = GC_generic_malloc_inner( SIZET_SAT_ADD(lb, DEBUG_BYTES), k); if (result == 0) { GC_err_printf("GC internal allocation (%lu bytes) returning NULL\n", (unsigned long) lb); return(0); } if (!GC_debugging_started) { GC_start_debugging_inner(); } ADD_CALL_CHAIN(result, GC_RETURN_ADDR); return (GC_store_debug_info_inner(result, (word)lb, "INTERNAL", 0)); } GC_INNER void * GC_debug_generic_malloc_inner_ignore_off_page(size_t lb, int k) { void * result = GC_generic_malloc_inner_ignore_off_page( SIZET_SAT_ADD(lb, DEBUG_BYTES), k); if (result == 0) { GC_err_printf("GC internal allocation (%lu bytes) returning NULL\n", (unsigned long) lb); return(0); } if (!GC_debugging_started) { GC_start_debugging_inner(); } ADD_CALL_CHAIN(result, GC_RETURN_ADDR); return (GC_store_debug_info_inner(result, (word)lb, "INTERNAL", 0)); } #endif /* DBG_HDRS_ALL */ #ifdef STUBBORN_ALLOC GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc_stubborn(size_t lb, GC_EXTRA_PARAMS) { void * result = GC_malloc_stubborn(SIZET_SAT_ADD(lb, DEBUG_BYTES)); if (result == 0) { GC_err_printf("GC_debug_malloc_stubborn(%lu)" " returning NULL (%s:%d)\n", (unsigned long)lb, s, i); return(0); } if (!GC_debugging_started) { GC_start_debugging(); } ADD_CALL_CHAIN(result, ra); return (GC_store_debug_info(result, (word)lb, s, i)); } GC_API void GC_CALL GC_debug_change_stubborn(const void *p) { const void * q = GC_base_C(p); hdr * hhdr; if (q == 0) { ABORT_ARG1("GC_debug_change_stubborn: bad arg", ": %p", p); } hhdr = HDR(q); if (hhdr -> hb_obj_kind != STUBBORN) { ABORT_ARG1("GC_debug_change_stubborn: arg not stubborn", ": %p", p); } GC_change_stubborn(q); } GC_API void GC_CALL GC_debug_end_stubborn_change(const void *p) { const void * q = GC_base_C(p); hdr * hhdr; if (q == 0) { ABORT_ARG1("GC_debug_end_stubborn_change: bad arg", ": %p", p); } hhdr = HDR(q); if (hhdr -> hb_obj_kind != STUBBORN) { ABORT_ARG1("GC_debug_end_stubborn_change: arg not stubborn", ": %p", p); } GC_end_stubborn_change(q); } #else /* !STUBBORN_ALLOC */ GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc_stubborn(size_t lb, GC_EXTRA_PARAMS) { return GC_debug_malloc(lb, OPT_RA s, i); } GC_API void GC_CALL GC_debug_change_stubborn( const void * p GC_ATTR_UNUSED) {} GC_API void GC_CALL GC_debug_end_stubborn_change( const void * p GC_ATTR_UNUSED) {} #endif /* !STUBBORN_ALLOC */ GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc_atomic(size_t lb, GC_EXTRA_PARAMS) { void * result = GC_malloc_atomic(SIZET_SAT_ADD(lb, DEBUG_BYTES)); if (result == 0) { GC_err_printf("GC_debug_malloc_atomic(%lu) returning NULL (%s:%d)\n", (unsigned long)lb, s, i); return(0); } if (!GC_debugging_started) { GC_start_debugging(); } ADD_CALL_CHAIN(result, ra); return (GC_store_debug_info(result, (word)lb, s, i)); } GC_API GC_ATTR_MALLOC char * GC_CALL GC_debug_strdup(const char *str, GC_EXTRA_PARAMS) { char *copy; size_t lb; if (str == NULL) { if (GC_find_leak) GC_err_printf("strdup(NULL) behavior is undefined\n"); return NULL; } lb = strlen(str) + 1; copy = GC_debug_malloc_atomic(lb, OPT_RA s, i); if (copy == NULL) { # ifndef MSWINCE errno = ENOMEM; # endif return NULL; } BCOPY(str, copy, lb); return copy; } GC_API GC_ATTR_MALLOC char * GC_CALL GC_debug_strndup(const char *str, size_t size, GC_EXTRA_PARAMS) { char *copy; size_t len = strlen(str); /* str is expected to be non-NULL */ if (len > size) len = size; copy = GC_debug_malloc_atomic(len + 1, OPT_RA s, i); if (copy == NULL) { # ifndef MSWINCE errno = ENOMEM; # endif return NULL; } if (len > 0) BCOPY(str, copy, len); copy[len] = '\0'; return copy; } #ifdef GC_REQUIRE_WCSDUP # include /* for wcslen() */ GC_API GC_ATTR_MALLOC wchar_t * GC_CALL GC_debug_wcsdup(const wchar_t *str, GC_EXTRA_PARAMS) { size_t lb = (wcslen(str) + 1) * sizeof(wchar_t); wchar_t *copy = GC_debug_malloc_atomic(lb, OPT_RA s, i); if (copy == NULL) { # ifndef MSWINCE errno = ENOMEM; # endif return NULL; } BCOPY(str, copy, lb); return copy; } #endif /* GC_REQUIRE_WCSDUP */ GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc_uncollectable(size_t lb, GC_EXTRA_PARAMS) { void * result = GC_malloc_uncollectable( SIZET_SAT_ADD(lb, UNCOLLECTABLE_DEBUG_BYTES)); if (result == 0) { GC_err_printf("GC_debug_malloc_uncollectable(%lu)" " returning NULL (%s:%d)\n", (unsigned long)lb, s, i); return(0); } if (!GC_debugging_started) { GC_start_debugging(); } ADD_CALL_CHAIN(result, ra); return (GC_store_debug_info(result, (word)lb, s, i)); } #ifdef GC_ATOMIC_UNCOLLECTABLE GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc_atomic_uncollectable(size_t lb, GC_EXTRA_PARAMS) { void * result = GC_malloc_atomic_uncollectable( SIZET_SAT_ADD(lb, UNCOLLECTABLE_DEBUG_BYTES)); if (result == 0) { GC_err_printf("GC_debug_malloc_atomic_uncollectable(%lu)" " returning NULL (%s:%d)\n", (unsigned long)lb, s, i); return(0); } if (!GC_debugging_started) { GC_start_debugging(); } ADD_CALL_CHAIN(result, ra); return (GC_store_debug_info(result, (word)lb, s, i)); } #endif /* GC_ATOMIC_UNCOLLECTABLE */ #ifndef GC_FREED_MEM_MARKER # if CPP_WORDSZ == 32 # define GC_FREED_MEM_MARKER 0xdeadbeef # else # define GC_FREED_MEM_MARKER GC_WORD_C(0xEFBEADDEdeadbeef) # endif #endif GC_API void GC_CALL GC_debug_free(void * p) { ptr_t base; if (0 == p) return; base = GC_base(p); if (base == 0) { # if defined(REDIRECT_MALLOC) \ && ((defined(NEED_CALLINFO) && defined(GC_HAVE_BUILTIN_BACKTRACE)) \ || defined(GC_LINUX_THREADS) || defined(GC_SOLARIS_THREADS) \ || defined(MSWIN32)) /* In some cases, we should ignore objects that do not belong */ /* to the GC heap. See the comment in GC_free. */ if (!GC_is_heap_ptr(p)) return; # endif ABORT_ARG1("Invalid pointer passed to free()", ": %p", p); } if ((ptr_t)p - (ptr_t)base != sizeof(oh)) { # if defined(REDIRECT_FREE) && defined(USE_PROC_FOR_LIBRARIES) /* TODO: Suppress the warning if free() caller is in libpthread */ /* or libdl. */ # endif GC_err_printf( "GC_debug_free called on pointer %p w/o debugging info\n", p); } else { # ifndef SHORT_DBG_HDRS ptr_t clobbered = GC_check_annotated_obj((oh *)base); word sz = GC_size(base); if (clobbered != 0) { GC_have_errors = TRUE; if (((oh *)base) -> oh_sz == sz) { GC_print_smashed_obj( "GC_debug_free: found previously deallocated (?) object at", p, clobbered); return; /* ignore double free */ } else { GC_print_smashed_obj("GC_debug_free: found smashed location at", p, clobbered); } } /* Invalidate size (mark the object as deallocated) */ ((oh *)base) -> oh_sz = sz; # endif /* SHORT_DBG_HDRS */ } if (GC_find_leak # ifndef SHORT_DBG_HDRS && ((ptr_t)p - (ptr_t)base != sizeof(oh) || !GC_findleak_delay_free) # endif ) { GC_free(base); } else { hdr * hhdr = HDR(p); if (hhdr -> hb_obj_kind == UNCOLLECTABLE # ifdef GC_ATOMIC_UNCOLLECTABLE || hhdr -> hb_obj_kind == AUNCOLLECTABLE # endif ) { GC_free(base); } else { size_t i; size_t obj_sz = BYTES_TO_WORDS(hhdr -> hb_sz - sizeof(oh)); for (i = 0; i < obj_sz; ++i) ((word *)p)[i] = GC_FREED_MEM_MARKER; GC_ASSERT((word *)p + i == (word *)(base + hhdr -> hb_sz)); } } /* !GC_find_leak */ } #if defined(THREADS) && defined(DBG_HDRS_ALL) /* Used internally; we assume it's called correctly. */ GC_INNER void GC_debug_free_inner(void * p) { ptr_t base = GC_base(p); GC_ASSERT((ptr_t)p - (ptr_t)base == sizeof(oh)); # ifdef LINT2 if (!base) ABORT("Invalid GC_debug_free_inner argument"); # endif # ifndef SHORT_DBG_HDRS /* Invalidate size */ ((oh *)base) -> oh_sz = GC_size(base); # endif GC_free_inner(base); } #endif GC_API void * GC_CALL GC_debug_realloc(void * p, size_t lb, GC_EXTRA_PARAMS) { void * base; void * result; hdr * hhdr; if (p == 0) { return GC_debug_malloc(lb, OPT_RA s, i); } if (0 == lb) /* and p != NULL */ { GC_debug_free(p); return NULL; } # ifdef GC_ADD_CALLER if (s == NULL) { GC_caller_func_offset(ra, &s, &i); } # endif base = GC_base(p); if (base == 0) { ABORT_ARG1("Invalid pointer passed to realloc()", ": %p", p); } if ((ptr_t)p - (ptr_t)base != sizeof(oh)) { GC_err_printf( "GC_debug_realloc called on pointer %p w/o debugging info\n", p); return(GC_realloc(p, lb)); } hhdr = HDR(base); switch (hhdr -> hb_obj_kind) { # ifdef STUBBORN_ALLOC case STUBBORN: result = GC_debug_malloc_stubborn(lb, OPT_RA s, i); break; # endif case NORMAL: result = GC_debug_malloc(lb, OPT_RA s, i); break; case PTRFREE: result = GC_debug_malloc_atomic(lb, OPT_RA s, i); break; case UNCOLLECTABLE: result = GC_debug_malloc_uncollectable(lb, OPT_RA s, i); break; # ifdef GC_ATOMIC_UNCOLLECTABLE case AUNCOLLECTABLE: result = GC_debug_malloc_atomic_uncollectable(lb, OPT_RA s, i); break; # endif default: result = NULL; /* initialized to prevent warning. */ ABORT_RET("GC_debug_realloc: encountered bad kind"); } if (result != NULL) { size_t old_sz; # ifdef SHORT_DBG_HDRS old_sz = GC_size(base) - sizeof(oh); # else old_sz = ((oh *)base) -> oh_sz; # endif if (old_sz > 0) BCOPY(p, result, old_sz < lb ? old_sz : lb); GC_debug_free(p); } return(result); } GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_generic_or_special_malloc(size_t lb, int knd, GC_EXTRA_PARAMS) { switch (knd) { # ifdef STUBBORN_ALLOC case STUBBORN: return GC_debug_malloc_stubborn(lb, OPT_RA s, i); # endif case PTRFREE: return GC_debug_malloc_atomic(lb, OPT_RA s, i); case NORMAL: return GC_debug_malloc(lb, OPT_RA s, i); case UNCOLLECTABLE: return GC_debug_malloc_uncollectable(lb, OPT_RA s, i); # ifdef GC_ATOMIC_UNCOLLECTABLE case AUNCOLLECTABLE: return GC_debug_malloc_atomic_uncollectable(lb, OPT_RA s, i); # endif default: return GC_debug_generic_malloc(lb, knd, OPT_RA s, i); } } #ifndef SHORT_DBG_HDRS /* List of smashed (clobbered) locations. We defer printing these, */ /* since we can't always print them nicely with the allocation lock */ /* held. We put them here instead of in GC_arrays, since it may be */ /* useful to be able to look at them with the debugger. */ #ifndef MAX_SMASHED # define MAX_SMASHED 20 #endif STATIC ptr_t GC_smashed[MAX_SMASHED] = {0}; STATIC unsigned GC_n_smashed = 0; STATIC void GC_add_smashed(ptr_t smashed) { GC_ASSERT(GC_is_marked(GC_base(smashed))); /* FIXME: Prevent adding an object while printing smashed list. */ GC_smashed[GC_n_smashed] = smashed; if (GC_n_smashed < MAX_SMASHED - 1) ++GC_n_smashed; /* In case of overflow, we keep the first MAX_SMASHED-1 */ /* entries plus the last one. */ GC_have_errors = TRUE; } /* Print all objects on the list. Clear the list. */ STATIC void GC_print_all_smashed_proc(void) { unsigned i; GC_ASSERT(I_DONT_HOLD_LOCK()); if (GC_n_smashed == 0) return; GC_err_printf("GC_check_heap_block: found %u smashed heap objects:\n", GC_n_smashed); for (i = 0; i < GC_n_smashed; ++i) { ptr_t base = (ptr_t)GC_base(GC_smashed[i]); # ifdef LINT2 if (!base) ABORT("Invalid GC_smashed element"); # endif GC_print_smashed_obj("", base + sizeof(oh), GC_smashed[i]); GC_smashed[i] = 0; } GC_n_smashed = 0; } /* Check all marked objects in the given block for validity */ /* Avoid GC_apply_to_each_object for performance reasons. */ STATIC void GC_check_heap_block(struct hblk *hbp, word dummy GC_ATTR_UNUSED) { struct hblkhdr * hhdr = HDR(hbp); size_t sz = hhdr -> hb_sz; size_t bit_no; char *p, *plim; p = hbp->hb_body; if (sz > MAXOBJBYTES) { plim = p; } else { plim = hbp->hb_body + HBLKSIZE - sz; } /* go through all words in block */ for (bit_no = 0; (word)p <= (word)plim; bit_no += MARK_BIT_OFFSET(sz), p += sz) { if (mark_bit_from_hdr(hhdr, bit_no) && GC_HAS_DEBUG_INFO((ptr_t)p)) { ptr_t clobbered = GC_check_annotated_obj((oh *)p); if (clobbered != 0) GC_add_smashed(clobbered); } } } /* This assumes that all accessible objects are marked, and that */ /* I hold the allocation lock. Normally called by collector. */ STATIC void GC_check_heap_proc(void) { GC_STATIC_ASSERT((sizeof(oh) & (GRANULE_BYTES - 1)) == 0); /* FIXME: Should we check for twice that alignment? */ GC_apply_to_all_blocks(GC_check_heap_block, 0); } GC_INNER GC_bool GC_check_leaked(ptr_t base) { size_t i; size_t obj_sz; word *p; if ( # if defined(KEEP_BACK_PTRS) || defined(MAKE_BACK_GRAPH) (*(word *)base & 1) != 0 && # endif GC_has_other_debug_info(base) >= 0) return TRUE; /* object has leaked */ /* Validate freed object's content. */ p = (word *)(base + sizeof(oh)); obj_sz = BYTES_TO_WORDS(HDR(base)->hb_sz - sizeof(oh)); for (i = 0; i < obj_sz; ++i) if (p[i] != GC_FREED_MEM_MARKER) { GC_set_mark_bit(base); /* do not reclaim it in this cycle */ GC_add_smashed((ptr_t)(&p[i])); /* alter-after-free detected */ break; /* don't report any other smashed locations in the object */ } return FALSE; /* GC_debug_free() has been called */ } #endif /* !SHORT_DBG_HDRS */ #ifndef GC_NO_FINALIZATION struct closure { GC_finalization_proc cl_fn; void * cl_data; }; STATIC void * GC_make_closure(GC_finalization_proc fn, void * data) { struct closure * result = # ifdef DBG_HDRS_ALL (struct closure *) GC_debug_malloc(sizeof (struct closure), GC_EXTRAS); # else (struct closure *) GC_malloc(sizeof (struct closure)); # endif if (result != 0) { result -> cl_fn = fn; result -> cl_data = data; } return((void *)result); } /* An auxiliary fns to make finalization work correctly with displaced */ /* pointers introduced by the debugging allocators. */ STATIC void GC_CALLBACK GC_debug_invoke_finalizer(void * obj, void * data) { struct closure * cl = (struct closure *) data; (*(cl -> cl_fn))((void *)((char *)obj + sizeof(oh)), cl -> cl_data); } /* Special finalizer_proc value to detect GC_register_finalizer() failure. */ #define OFN_UNSET ((GC_finalization_proc)~(signed_word)0) /* Set ofn and ocd to reflect the values we got back. */ static void store_old(void *obj, GC_finalization_proc my_old_fn, struct closure *my_old_cd, GC_finalization_proc *ofn, void **ocd) { if (0 != my_old_fn) { if (my_old_fn == OFN_UNSET) { /* register_finalizer() failed; (*ofn) and (*ocd) are unchanged. */ return; } if (my_old_fn != GC_debug_invoke_finalizer) { GC_err_printf("Debuggable object at %p had a non-debug finalizer\n", obj); /* This should probably be fatal. */ } else { if (ofn) *ofn = my_old_cd -> cl_fn; if (ocd) *ocd = my_old_cd -> cl_data; } } else { if (ofn) *ofn = 0; if (ocd) *ocd = 0; } } GC_API void GC_CALL GC_debug_register_finalizer(void * obj, GC_finalization_proc fn, void * cd, GC_finalization_proc *ofn, void * *ocd) { GC_finalization_proc my_old_fn = OFN_UNSET; void * my_old_cd; ptr_t base = GC_base(obj); if (0 == base) { /* We won't collect it, hence finalizer wouldn't be run. */ if (ocd) *ocd = 0; if (ofn) *ofn = 0; return; } if ((ptr_t)obj - base != sizeof(oh)) { GC_err_printf("GC_debug_register_finalizer called with" " non-base-pointer %p\n", obj); } if (0 == fn) { GC_register_finalizer(base, 0, 0, &my_old_fn, &my_old_cd); } else { cd = GC_make_closure(fn, cd); if (cd == 0) return; /* out of memory */ GC_register_finalizer(base, GC_debug_invoke_finalizer, cd, &my_old_fn, &my_old_cd); } store_old(obj, my_old_fn, (struct closure *)my_old_cd, ofn, ocd); } GC_API void GC_CALL GC_debug_register_finalizer_no_order (void * obj, GC_finalization_proc fn, void * cd, GC_finalization_proc *ofn, void * *ocd) { GC_finalization_proc my_old_fn = OFN_UNSET; void * my_old_cd; ptr_t base = GC_base(obj); if (0 == base) { /* We won't collect it, hence finalizer wouldn't be run. */ if (ocd) *ocd = 0; if (ofn) *ofn = 0; return; } if ((ptr_t)obj - base != sizeof(oh)) { GC_err_printf("GC_debug_register_finalizer_no_order called with" " non-base-pointer %p\n", obj); } if (0 == fn) { GC_register_finalizer_no_order(base, 0, 0, &my_old_fn, &my_old_cd); } else { cd = GC_make_closure(fn, cd); if (cd == 0) return; /* out of memory */ GC_register_finalizer_no_order(base, GC_debug_invoke_finalizer, cd, &my_old_fn, &my_old_cd); } store_old(obj, my_old_fn, (struct closure *)my_old_cd, ofn, ocd); } GC_API void GC_CALL GC_debug_register_finalizer_unreachable (void * obj, GC_finalization_proc fn, void * cd, GC_finalization_proc *ofn, void * *ocd) { GC_finalization_proc my_old_fn = OFN_UNSET; void * my_old_cd; ptr_t base = GC_base(obj); if (0 == base) { /* We won't collect it, hence finalizer wouldn't be run. */ if (ocd) *ocd = 0; if (ofn) *ofn = 0; return; } if ((ptr_t)obj - base != sizeof(oh)) { GC_err_printf("GC_debug_register_finalizer_unreachable called with" " non-base-pointer %p\n", obj); } if (0 == fn) { GC_register_finalizer_unreachable(base, 0, 0, &my_old_fn, &my_old_cd); } else { cd = GC_make_closure(fn, cd); if (cd == 0) return; /* out of memory */ GC_register_finalizer_unreachable(base, GC_debug_invoke_finalizer, cd, &my_old_fn, &my_old_cd); } store_old(obj, my_old_fn, (struct closure *)my_old_cd, ofn, ocd); } GC_API void GC_CALL GC_debug_register_finalizer_ignore_self (void * obj, GC_finalization_proc fn, void * cd, GC_finalization_proc *ofn, void * *ocd) { GC_finalization_proc my_old_fn = OFN_UNSET; void * my_old_cd; ptr_t base = GC_base(obj); if (0 == base) { /* We won't collect it, hence finalizer wouldn't be run. */ if (ocd) *ocd = 0; if (ofn) *ofn = 0; return; } if ((ptr_t)obj - base != sizeof(oh)) { GC_err_printf("GC_debug_register_finalizer_ignore_self called with" " non-base-pointer %p\n", obj); } if (0 == fn) { GC_register_finalizer_ignore_self(base, 0, 0, &my_old_fn, &my_old_cd); } else { cd = GC_make_closure(fn, cd); if (cd == 0) return; /* out of memory */ GC_register_finalizer_ignore_self(base, GC_debug_invoke_finalizer, cd, &my_old_fn, &my_old_cd); } store_old(obj, my_old_fn, (struct closure *)my_old_cd, ofn, ocd); } #endif /* !GC_NO_FINALIZATION */ GC_API GC_ATTR_MALLOC void * GC_CALL GC_debug_malloc_replacement(size_t lb) { return GC_debug_malloc(lb, GC_DBG_EXTRAS); } GC_API void * GC_CALL GC_debug_realloc_replacement(void *p, size_t lb) { return GC_debug_realloc(p, lb, GC_DBG_EXTRAS); }