/* $NetBSD: mem.c,v 1.1.1.1 2018/08/12 12:08:23 christos Exp $ */ /* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * See the COPYRIGHT file distributed with this work for additional * information regarding copyright ownership. */ /*! \file */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define MCTXLOCK(m, l) if (((m)->flags & ISC_MEMFLAG_NOLOCK) == 0) LOCK(l) #define MCTXUNLOCK(m, l) if (((m)->flags & ISC_MEMFLAG_NOLOCK) == 0) UNLOCK(l) #ifndef ISC_MEM_DEBUGGING #define ISC_MEM_DEBUGGING 0 #endif LIBISC_EXTERNAL_DATA unsigned int isc_mem_debugging = ISC_MEM_DEBUGGING; LIBISC_EXTERNAL_DATA unsigned int isc_mem_defaultflags = ISC_MEMFLAG_DEFAULT; /* * Constants. */ #define DEF_MAX_SIZE 1100 #define DEF_MEM_TARGET 4096 #define ALIGNMENT_SIZE 8U /*%< must be a power of 2 */ #define NUM_BASIC_BLOCKS 64 /*%< must be > 1 */ #define TABLE_INCREMENT 1024 #define DEBUG_TABLE_COUNT 512U /* * Types. */ typedef struct isc__mem isc__mem_t; typedef struct isc__mempool isc__mempool_t; #if ISC_MEM_TRACKLINES typedef struct debuglink debuglink_t; struct debuglink { ISC_LINK(debuglink_t) link; const void *ptr; size_t size; const char *file; unsigned int line; }; typedef ISC_LIST(debuglink_t) debuglist_t; #define FLARG_PASS , file, line #define FLARG , const char *file, unsigned int line #else #define FLARG_PASS #define FLARG #endif typedef struct element element; struct element { element * next; }; typedef struct { /*! * This structure must be ALIGNMENT_SIZE bytes. */ union { size_t size; isc__mem_t *ctx; char bytes[ALIGNMENT_SIZE]; } u; } size_info; struct stats { unsigned long gets; unsigned long totalgets; unsigned long blocks; unsigned long freefrags; }; #define MEM_MAGIC ISC_MAGIC('M', 'e', 'm', 'C') #define VALID_CONTEXT(c) ISC_MAGIC_VALID(c, MEM_MAGIC) /* List of all active memory contexts. */ static ISC_LIST(isc__mem_t) contexts; static isc_once_t once = ISC_ONCE_INIT; static isc_mutex_t contextslock; static isc_mutex_t createlock; /*% * Total size of lost memory due to a bug of external library. * Locked by the global lock. */ static isc_uint64_t totallost; struct isc__mem { isc_mem_t common; isc_ondestroy_t ondestroy; unsigned int flags; isc_mutex_t lock; isc_memalloc_t memalloc; isc_memfree_t memfree; void * arg; size_t max_size; isc_boolean_t checkfree; struct stats * stats; unsigned int references; char name[16]; void * tag; size_t quota; size_t total; size_t inuse; size_t maxinuse; size_t malloced; size_t maxmalloced; size_t hi_water; size_t lo_water; isc_boolean_t hi_called; isc_boolean_t is_overmem; isc_mem_water_t water; void * water_arg; ISC_LIST(isc__mempool_t) pools; unsigned int poolcnt; /* ISC_MEMFLAG_INTERNAL */ size_t mem_target; element ** freelists; element * basic_blocks; unsigned char ** basic_table; unsigned int basic_table_count; unsigned int basic_table_size; unsigned char * lowest; unsigned char * highest; #if ISC_MEM_TRACKLINES debuglist_t * debuglist; size_t debuglistcnt; #endif unsigned int memalloc_failures; ISC_LINK(isc__mem_t) link; }; #define MEMPOOL_MAGIC ISC_MAGIC('M', 'E', 'M', 'p') #define VALID_MEMPOOL(c) ISC_MAGIC_VALID(c, MEMPOOL_MAGIC) struct isc__mempool { /* always unlocked */ isc_mempool_t common; /*%< common header of mempool's */ isc_mutex_t *lock; /*%< optional lock */ isc__mem_t *mctx; /*%< our memory context */ /*%< locked via the memory context's lock */ ISC_LINK(isc__mempool_t) link; /*%< next pool in this mem context */ /*%< optionally locked from here down */ element *items; /*%< low water item list */ size_t size; /*%< size of each item on this pool */ unsigned int maxalloc; /*%< max number of items allowed */ unsigned int allocated; /*%< # of items currently given out */ unsigned int freecount; /*%< # of items on reserved list */ unsigned int freemax; /*%< # of items allowed on free list */ unsigned int fillcount; /*%< # of items to fetch on each fill */ /*%< Stats only. */ unsigned int gets; /*%< # of requests to this pool */ /*%< Debugging only. */ #if ISC_MEMPOOL_NAMES char name[16]; /*%< printed name in stats reports */ #endif }; /* * Private Inline-able. */ #if ! ISC_MEM_TRACKLINES #define ADD_TRACE(a, b, c, d, e) #define DELETE_TRACE(a, b, c, d, e) #define ISC_MEMFUNC_SCOPE #else #define TRACE_OR_RECORD (ISC_MEM_DEBUGTRACE|ISC_MEM_DEBUGRECORD) #define ADD_TRACE(a, b, c, d, e) \ do { \ if (ISC_UNLIKELY((isc_mem_debugging & TRACE_OR_RECORD) != 0 && \ b != NULL)) \ add_trace_entry(a, b, c, d, e); \ } while (0) #define DELETE_TRACE(a, b, c, d, e) \ do { \ if (ISC_UNLIKELY((isc_mem_debugging & TRACE_OR_RECORD) != 0 && \ b != NULL)) \ delete_trace_entry(a, b, c, d, e); \ } while(0) static void print_active(isc__mem_t *ctx, FILE *out); #endif /* ISC_MEM_TRACKLINES */ /*% * The following are intended for internal use (indicated by "isc__" * prefix) but are not declared as static, allowing direct access * from unit tests, etc. */ isc_result_t isc__mem_create2(size_t init_max_size, size_t target_size, isc_mem_t **ctxp, unsigned int flags); void isc__mem_attach(isc_mem_t *source, isc_mem_t **targetp); void isc__mem_detach(isc_mem_t **ctxp); void isc___mem_putanddetach(isc_mem_t **ctxp, void *ptr, size_t size FLARG); void isc__mem_destroy(isc_mem_t **ctxp); isc_result_t isc__mem_ondestroy(isc_mem_t *ctx, isc_task_t *task, isc_event_t **event); void * isc___mem_get(isc_mem_t *ctx, size_t size FLARG); void isc___mem_put(isc_mem_t *ctx, void *ptr, size_t size FLARG); void isc__mem_stats(isc_mem_t *ctx, FILE *out); void * isc___mem_allocate(isc_mem_t *ctx, size_t size FLARG); void * isc___mem_reallocate(isc_mem_t *ctx, void *ptr, size_t size FLARG); void isc___mem_free(isc_mem_t *ctx, void *ptr FLARG); char * isc___mem_strdup(isc_mem_t *mctx, const char *s FLARG); void isc__mem_setdestroycheck(isc_mem_t *ctx, isc_boolean_t flag); void isc__mem_setquota(isc_mem_t *ctx, size_t quota); size_t isc__mem_getquota(isc_mem_t *ctx); size_t isc__mem_inuse(isc_mem_t *ctx); size_t isc__mem_maxinuse(isc_mem_t *ctx); size_t isc__mem_total(isc_mem_t *ctx); isc_boolean_t isc__mem_isovermem(isc_mem_t *ctx); void isc__mem_setwater(isc_mem_t *ctx, isc_mem_water_t water, void *water_arg, size_t hiwater, size_t lowater); void isc__mem_waterack(isc_mem_t *ctx0, int flag); void isc__mem_setname(isc_mem_t *ctx, const char *name, void *tag); const char * isc__mem_getname(isc_mem_t *ctx); void * isc__mem_gettag(isc_mem_t *ctx); isc_result_t isc__mempool_create(isc_mem_t *mctx, size_t size, isc_mempool_t **mpctxp); void isc__mempool_setname(isc_mempool_t *mpctx, const char *name); void isc__mempool_destroy(isc_mempool_t **mpctxp); void isc__mempool_associatelock(isc_mempool_t *mpctx, isc_mutex_t *lock); void * isc___mempool_get(isc_mempool_t *mpctx FLARG); void isc___mempool_put(isc_mempool_t *mpctx, void *mem FLARG); void isc__mempool_setfreemax(isc_mempool_t *mpctx, unsigned int limit); unsigned int isc__mempool_getfreemax(isc_mempool_t *mpctx); unsigned int isc__mempool_getfreecount(isc_mempool_t *mpctx); void isc__mempool_setmaxalloc(isc_mempool_t *mpctx, unsigned int limit); unsigned int isc__mempool_getmaxalloc(isc_mempool_t *mpctx); unsigned int isc__mempool_getallocated(isc_mempool_t *mpctx); void isc__mempool_setfillcount(isc_mempool_t *mpctx, unsigned int limit); unsigned int isc__mempool_getfillcount(isc_mempool_t *mpctx); void isc__mem_printactive(isc_mem_t *ctx0, FILE *file); unsigned int isc__mem_references(isc_mem_t *ctx0); static struct isc__memmethods { isc_memmethods_t methods; /*% * The following are defined just for avoiding unused static functions. */ void *createx, *create, *create2, *ondestroy, *stats, *setquota, *getquota, *setname, *getname, *gettag; } memmethods = { { isc__mem_attach, isc__mem_detach, isc__mem_destroy, isc___mem_get, isc___mem_put, isc___mem_putanddetach, isc___mem_allocate, isc___mem_reallocate, isc___mem_strdup, isc___mem_free, isc__mem_setdestroycheck, isc__mem_setwater, isc__mem_waterack, isc__mem_inuse, isc__mem_maxinuse, isc__mem_total, isc__mem_isovermem, isc__mempool_create }, (void *)isc_mem_createx, (void *)isc_mem_create, (void *)isc_mem_create2, (void *)isc_mem_ondestroy, (void *)isc_mem_stats, (void *)isc_mem_setquota, (void *)isc_mem_getquota, (void *)isc_mem_setname, (void *)isc_mem_getname, (void *)isc_mem_gettag }; static struct isc__mempoolmethods { isc_mempoolmethods_t methods; /*% * The following are defined just for avoiding unused static functions. */ void *getfreemax, *getfreecount, *getmaxalloc, *getfillcount; } mempoolmethods = { { isc__mempool_destroy, isc___mempool_get, isc___mempool_put, isc__mempool_getallocated, isc__mempool_setmaxalloc, isc__mempool_setfreemax, isc__mempool_setname, isc__mempool_associatelock, isc__mempool_setfillcount }, (void *)isc_mempool_getfreemax, (void *)isc_mempool_getfreecount, (void *)isc_mempool_getmaxalloc, (void *)isc_mempool_getfillcount }; #if ISC_MEM_TRACKLINES /*! * mctx must be locked. */ static void add_trace_entry(isc__mem_t *mctx, const void *ptr, size_t size FLARG) { debuglink_t *dl; isc_uint32_t hash; isc_uint32_t idx; if ((isc_mem_debugging & ISC_MEM_DEBUGTRACE) != 0) fprintf(stderr, isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_ADDTRACE, "add %p size %u " "file %s line %u mctx %p\n"), ptr, size, file, line, mctx); if (mctx->debuglist == NULL) return; hash = isc_hash_function(&ptr, sizeof(ptr), ISC_TRUE, NULL); idx = hash % DEBUG_TABLE_COUNT; dl = malloc(sizeof(debuglink_t)); INSIST(dl != NULL); mctx->malloced += sizeof(debuglink_t); if (mctx->malloced > mctx->maxmalloced) mctx->maxmalloced = mctx->malloced; ISC_LINK_INIT(dl, link); dl->ptr = ptr; dl->size = size; dl->file = file; dl->line = line; ISC_LIST_PREPEND(mctx->debuglist[idx], dl, link); mctx->debuglistcnt++; } static void delete_trace_entry(isc__mem_t *mctx, const void *ptr, size_t size, const char *file, unsigned int line) { debuglink_t *dl; isc_uint32_t hash; isc_uint32_t idx; if ((isc_mem_debugging & ISC_MEM_DEBUGTRACE) != 0) fprintf(stderr, isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_DELTRACE, "del %p size %u " "file %s line %u mctx %p\n"), ptr, size, file, line, mctx); if (mctx->debuglist == NULL) return; hash = isc_hash_function(&ptr, sizeof(ptr), ISC_TRUE, NULL); idx = hash % DEBUG_TABLE_COUNT; dl = ISC_LIST_HEAD(mctx->debuglist[idx]); while (ISC_LIKELY(dl != NULL)) { if (ISC_UNLIKELY(dl->ptr == ptr)) { ISC_LIST_UNLINK(mctx->debuglist[idx], dl, link); mctx->malloced -= sizeof(*dl); free(dl); return; } dl = ISC_LIST_NEXT(dl, link); } /* * If we get here, we didn't find the item on the list. We're * screwed. */ INSIST(0); } #endif /* ISC_MEM_TRACKLINES */ static inline size_t rmsize(size_t size) { /* * round down to ALIGNMENT_SIZE */ return (size & (~(ALIGNMENT_SIZE - 1))); } static inline size_t quantize(size_t size) { /*! * Round up the result in order to get a size big * enough to satisfy the request and be aligned on ALIGNMENT_SIZE * byte boundaries. */ if (size == 0U) return (ALIGNMENT_SIZE); return ((size + ALIGNMENT_SIZE - 1) & (~(ALIGNMENT_SIZE - 1))); } static inline isc_boolean_t more_basic_blocks(isc__mem_t *ctx) { void *tmp; unsigned char *curr, *next; unsigned char *first, *last; unsigned char **table; unsigned int table_size; size_t increment; int i; /* Require: we hold the context lock. */ /* * Did we hit the quota for this context? */ increment = NUM_BASIC_BLOCKS * ctx->mem_target; if (ctx->quota != 0U && ctx->total + increment > ctx->quota) return (ISC_FALSE); INSIST(ctx->basic_table_count <= ctx->basic_table_size); if (ctx->basic_table_count == ctx->basic_table_size) { table_size = ctx->basic_table_size + TABLE_INCREMENT; table = (ctx->memalloc)(ctx->arg, table_size * sizeof(unsigned char *)); if (table == NULL) { ctx->memalloc_failures++; return (ISC_FALSE); } ctx->malloced += table_size * sizeof(unsigned char *); if (ctx->malloced > ctx->maxmalloced) ctx->maxmalloced = ctx->malloced; if (ctx->basic_table_size != 0) { memmove(table, ctx->basic_table, ctx->basic_table_size * sizeof(unsigned char *)); (ctx->memfree)(ctx->arg, ctx->basic_table); ctx->malloced -= ctx->basic_table_size * sizeof(unsigned char *); } ctx->basic_table = table; ctx->basic_table_size = table_size; } tmp = (ctx->memalloc)(ctx->arg, NUM_BASIC_BLOCKS * ctx->mem_target); if (tmp == NULL) { ctx->memalloc_failures++; return (ISC_FALSE); } ctx->total += increment; ctx->basic_table[ctx->basic_table_count] = tmp; ctx->basic_table_count++; ctx->malloced += NUM_BASIC_BLOCKS * ctx->mem_target; if (ctx->malloced > ctx->maxmalloced) ctx->maxmalloced = ctx->malloced; curr = tmp; next = curr + ctx->mem_target; for (i = 0; i < (NUM_BASIC_BLOCKS - 1); i++) { ((element *)curr)->next = (element *)next; curr = next; next += ctx->mem_target; } /* * curr is now pointing at the last block in the * array. */ ((element *)curr)->next = NULL; first = tmp; last = first + NUM_BASIC_BLOCKS * ctx->mem_target - 1; if (first < ctx->lowest || ctx->lowest == NULL) ctx->lowest = first; if (last > ctx->highest) ctx->highest = last; ctx->basic_blocks = tmp; return (ISC_TRUE); } static inline isc_boolean_t more_frags(isc__mem_t *ctx, size_t new_size) { int i, frags; size_t total_size; void *tmp; unsigned char *curr, *next; /*! * Try to get more fragments by chopping up a basic block. */ if (ctx->basic_blocks == NULL) { if (!more_basic_blocks(ctx)) { /* * We can't get more memory from the OS, or we've * hit the quota for this context. */ /* * XXXRTH "At quota" notification here. */ return (ISC_FALSE); } } total_size = ctx->mem_target; tmp = ctx->basic_blocks; ctx->basic_blocks = ctx->basic_blocks->next; frags = (int)(total_size / new_size); ctx->stats[new_size].blocks++; ctx->stats[new_size].freefrags += frags; /* * Set up a linked-list of blocks of size * "new_size". */ curr = tmp; next = curr + new_size; total_size -= new_size; for (i = 0; i < (frags - 1); i++) { ((element *)curr)->next = (element *)next; curr = next; next += new_size; total_size -= new_size; } /* * Add the remaining fragment of the basic block to a free list. */ total_size = rmsize(total_size); if (total_size > 0U) { ((element *)next)->next = ctx->freelists[total_size]; ctx->freelists[total_size] = (element *)next; ctx->stats[total_size].freefrags++; } /* * curr is now pointing at the last block in the * array. */ ((element *)curr)->next = NULL; ctx->freelists[new_size] = tmp; return (ISC_TRUE); } static inline void * mem_getunlocked(isc__mem_t *ctx, size_t size) { size_t new_size = quantize(size); void *ret; if (new_size >= ctx->max_size) { /* * memget() was called on something beyond our upper limit. */ if (ctx->quota != 0U && ctx->total + size > ctx->quota) { ret = NULL; goto done; } ret = (ctx->memalloc)(ctx->arg, size); if (ret == NULL) { ctx->memalloc_failures++; goto done; } ctx->total += size; ctx->inuse += size; ctx->stats[ctx->max_size].gets++; ctx->stats[ctx->max_size].totalgets++; ctx->malloced += size; if (ctx->malloced > ctx->maxmalloced) ctx->maxmalloced = ctx->malloced; /* * If we don't set new_size to size, then the * ISC_MEMFLAG_FILL code might write over bytes we don't * own. */ new_size = size; goto done; } /* * If there are no blocks in the free list for this size, get a chunk * of memory and then break it up into "new_size"-sized blocks, adding * them to the free list. */ if (ctx->freelists[new_size] == NULL && !more_frags(ctx, new_size)) return (NULL); /* * The free list uses the "rounded-up" size "new_size". */ ret = ctx->freelists[new_size]; ctx->freelists[new_size] = ctx->freelists[new_size]->next; /* * The stats[] uses the _actual_ "size" requested by the * caller, with the caveat (in the code above) that "size" >= the * max. size (max_size) ends up getting recorded as a call to * max_size. */ ctx->stats[size].gets++; ctx->stats[size].totalgets++; ctx->stats[new_size].freefrags--; ctx->inuse += new_size; done: if (ISC_UNLIKELY((ctx->flags & ISC_MEMFLAG_FILL) != 0) && ISC_LIKELY(ret != NULL)) memset(ret, 0xbe, new_size); /* Mnemonic for "beef". */ return (ret); } #if ISC_MEM_CHECKOVERRUN static inline void check_overrun(void *mem, size_t size, size_t new_size) { unsigned char *cp; cp = (unsigned char *)mem; cp += size; while (size < new_size) { INSIST(*cp == 0xbe); cp++; size++; } } #endif /* coverity[+free : arg-1] */ static inline void mem_putunlocked(isc__mem_t *ctx, void *mem, size_t size) { size_t new_size = quantize(size); if (new_size >= ctx->max_size) { /* * memput() called on something beyond our upper limit. */ if (ISC_UNLIKELY((ctx->flags & ISC_MEMFLAG_FILL) != 0)) memset(mem, 0xde, size); /* Mnemonic for "dead". */ (ctx->memfree)(ctx->arg, mem); INSIST(ctx->stats[ctx->max_size].gets != 0U); ctx->stats[ctx->max_size].gets--; INSIST(size <= ctx->inuse); ctx->inuse -= size; ctx->malloced -= size; return; } if (ISC_UNLIKELY((ctx->flags & ISC_MEMFLAG_FILL) != 0)) { #if ISC_MEM_CHECKOVERRUN check_overrun(mem, size, new_size); #endif memset(mem, 0xde, new_size); /* Mnemonic for "dead". */ } /* * The free list uses the "rounded-up" size "new_size". */ ((element *)mem)->next = ctx->freelists[new_size]; ctx->freelists[new_size] = (element *)mem; /* * The stats[] uses the _actual_ "size" requested by the * caller, with the caveat (in the code above) that "size" >= the * max. size (max_size) ends up getting recorded as a call to * max_size. */ INSIST(ctx->stats[size].gets != 0U); ctx->stats[size].gets--; ctx->stats[new_size].freefrags++; ctx->inuse -= new_size; } /*! * Perform a malloc, doing memory filling and overrun detection as necessary. */ static inline void * mem_get(isc__mem_t *ctx, size_t size) { char *ret; #if ISC_MEM_CHECKOVERRUN size += 1; #endif ret = (ctx->memalloc)(ctx->arg, size); if (ret == NULL) ctx->memalloc_failures++; if (ISC_UNLIKELY((ctx->flags & ISC_MEMFLAG_FILL) != 0)) { if (ISC_LIKELY(ret != NULL)) memset(ret, 0xbe, size); /* Mnemonic for "beef". */ } #if ISC_MEM_CHECKOVERRUN else { if (ISC_LIKELY(ret != NULL)) ret[size-1] = 0xbe; } #endif return (ret); } /*! * Perform a free, doing memory filling and overrun detection as necessary. */ /* coverity[+free : arg-1] */ static inline void mem_put(isc__mem_t *ctx, void *mem, size_t size) { #if ISC_MEM_CHECKOVERRUN INSIST(((unsigned char *)mem)[size] == 0xbe); size += 1; #endif if (ISC_UNLIKELY((ctx->flags & ISC_MEMFLAG_FILL) != 0)) memset(mem, 0xde, size); /* Mnemonic for "dead". */ (ctx->memfree)(ctx->arg, mem); } /*! * Update internal counters after a memory get. */ static inline void mem_getstats(isc__mem_t *ctx, size_t size) { ctx->total += size; ctx->inuse += size; if (size > ctx->max_size) { ctx->stats[ctx->max_size].gets++; ctx->stats[ctx->max_size].totalgets++; } else { ctx->stats[size].gets++; ctx->stats[size].totalgets++; } #if ISC_MEM_CHECKOVERRUN size += 1; #endif ctx->malloced += size; if (ctx->malloced > ctx->maxmalloced) ctx->maxmalloced = ctx->malloced; } /*! * Update internal counters after a memory put. */ static inline void mem_putstats(isc__mem_t *ctx, void *ptr, size_t size) { UNUSED(ptr); INSIST(ctx->inuse >= size); ctx->inuse -= size; if (size > ctx->max_size) { INSIST(ctx->stats[ctx->max_size].gets > 0U); ctx->stats[ctx->max_size].gets--; } else { INSIST(ctx->stats[size].gets > 0U); ctx->stats[size].gets--; } #if ISC_MEM_CHECKOVERRUN size += 1; #endif ctx->malloced -= size; } /* * Private. */ static void * default_memalloc(void *arg, size_t size) { UNUSED(arg); if (size == 0U) size = 1; return (malloc(size)); } static void default_memfree(void *arg, void *ptr) { UNUSED(arg); free(ptr); } static void initialize_action(void) { RUNTIME_CHECK(isc_mutex_init(&createlock) == ISC_R_SUCCESS); RUNTIME_CHECK(isc_mutex_init(&contextslock) == ISC_R_SUCCESS); ISC_LIST_INIT(contexts); totallost = 0; } /* * Public. */ isc_result_t isc_mem_createx(size_t init_max_size, size_t target_size, isc_memalloc_t memalloc, isc_memfree_t memfree, void *arg, isc_mem_t **ctxp) { return (isc_mem_createx2(init_max_size, target_size, memalloc, memfree, arg, ctxp, isc_mem_defaultflags)); } isc_result_t isc_mem_createx2(size_t init_max_size, size_t target_size, isc_memalloc_t memalloc, isc_memfree_t memfree, void *arg, isc_mem_t **ctxp, unsigned int flags) { isc__mem_t *ctx; isc_result_t result; REQUIRE(ctxp != NULL && *ctxp == NULL); REQUIRE(memalloc != NULL); REQUIRE(memfree != NULL); INSIST((ALIGNMENT_SIZE & (ALIGNMENT_SIZE - 1)) == 0); RUNTIME_CHECK(isc_once_do(&once, initialize_action) == ISC_R_SUCCESS); ctx = (memalloc)(arg, sizeof(*ctx)); if (ctx == NULL) return (ISC_R_NOMEMORY); if ((flags & ISC_MEMFLAG_NOLOCK) == 0) { result = isc_mutex_init(&ctx->lock); if (result != ISC_R_SUCCESS) { (memfree)(arg, ctx); return (result); } } if (init_max_size == 0U) ctx->max_size = DEF_MAX_SIZE; else ctx->max_size = init_max_size; ctx->flags = flags; ctx->references = 1; memset(ctx->name, 0, sizeof(ctx->name)); ctx->tag = NULL; ctx->quota = 0; ctx->total = 0; ctx->inuse = 0; ctx->maxinuse = 0; ctx->malloced = sizeof(*ctx); ctx->maxmalloced = sizeof(*ctx); ctx->hi_water = 0; ctx->lo_water = 0; ctx->hi_called = ISC_FALSE; ctx->is_overmem = ISC_FALSE; ctx->water = NULL; ctx->water_arg = NULL; ctx->common.impmagic = MEM_MAGIC; ctx->common.magic = ISCAPI_MCTX_MAGIC; ctx->common.methods = (isc_memmethods_t *)&memmethods; isc_ondestroy_init(&ctx->ondestroy); ctx->memalloc = memalloc; ctx->memfree = memfree; ctx->arg = arg; ctx->stats = NULL; ctx->checkfree = ISC_TRUE; #if ISC_MEM_TRACKLINES ctx->debuglist = NULL; ctx->debuglistcnt = 0; #endif ISC_LIST_INIT(ctx->pools); ctx->poolcnt = 0; ctx->freelists = NULL; ctx->basic_blocks = NULL; ctx->basic_table = NULL; ctx->basic_table_count = 0; ctx->basic_table_size = 0; ctx->lowest = NULL; ctx->highest = NULL; ctx->stats = (memalloc)(arg, (ctx->max_size+1) * sizeof(struct stats)); if (ctx->stats == NULL) { result = ISC_R_NOMEMORY; goto error; } memset(ctx->stats, 0, (ctx->max_size + 1) * sizeof(struct stats)); ctx->malloced += (ctx->max_size+1) * sizeof(struct stats); ctx->maxmalloced += (ctx->max_size+1) * sizeof(struct stats); if ((flags & ISC_MEMFLAG_INTERNAL) != 0) { if (target_size == 0U) ctx->mem_target = DEF_MEM_TARGET; else ctx->mem_target = target_size; ctx->freelists = (memalloc)(arg, ctx->max_size * sizeof(element *)); if (ctx->freelists == NULL) { result = ISC_R_NOMEMORY; goto error; } memset(ctx->freelists, 0, ctx->max_size * sizeof(element *)); ctx->malloced += ctx->max_size * sizeof(element *); ctx->maxmalloced += ctx->max_size * sizeof(element *); } #if ISC_MEM_TRACKLINES if (ISC_UNLIKELY((isc_mem_debugging & ISC_MEM_DEBUGRECORD) != 0)) { unsigned int i; ctx->debuglist = (memalloc)(arg, (DEBUG_TABLE_COUNT * sizeof(debuglist_t))); if (ctx->debuglist == NULL) { result = ISC_R_NOMEMORY; goto error; } for (i = 0; i < DEBUG_TABLE_COUNT; i++) ISC_LIST_INIT(ctx->debuglist[i]); ctx->malloced += DEBUG_TABLE_COUNT * sizeof(debuglist_t); ctx->maxmalloced += DEBUG_TABLE_COUNT * sizeof(debuglist_t); } #endif ctx->memalloc_failures = 0; LOCK(&contextslock); ISC_LIST_INITANDAPPEND(contexts, ctx, link); UNLOCK(&contextslock); *ctxp = (isc_mem_t *)ctx; return (ISC_R_SUCCESS); error: if (ctx != NULL) { if (ctx->stats != NULL) (memfree)(arg, ctx->stats); if (ctx->freelists != NULL) (memfree)(arg, ctx->freelists); #if ISC_MEM_TRACKLINES if (ctx->debuglist != NULL) (ctx->memfree)(ctx->arg, ctx->debuglist); #endif /* ISC_MEM_TRACKLINES */ if ((ctx->flags & ISC_MEMFLAG_NOLOCK) == 0) DESTROYLOCK(&ctx->lock); (memfree)(arg, ctx); } return (result); } static void destroy(isc__mem_t *ctx) { unsigned int i; isc_ondestroy_t ondest; LOCK(&contextslock); ISC_LIST_UNLINK(contexts, ctx, link); totallost += ctx->inuse; UNLOCK(&contextslock); ctx->common.impmagic = 0; ctx->common.magic = 0; INSIST(ISC_LIST_EMPTY(ctx->pools)); #if ISC_MEM_TRACKLINES if (ISC_UNLIKELY(ctx->debuglist != NULL)) { debuglink_t *dl; for (i = 0; i < DEBUG_TABLE_COUNT; i++) for (dl = ISC_LIST_HEAD(ctx->debuglist[i]); dl != NULL; dl = ISC_LIST_HEAD(ctx->debuglist[i])) { if (ctx->checkfree && dl->ptr != NULL) print_active(ctx, stderr); INSIST (!ctx->checkfree || dl->ptr == NULL); ISC_LIST_UNLINK(ctx->debuglist[i], dl, link); free(dl); ctx->malloced -= sizeof(*dl); } (ctx->memfree)(ctx->arg, ctx->debuglist); ctx->malloced -= DEBUG_TABLE_COUNT * sizeof(debuglist_t); } #endif INSIST(ctx->references == 0); if (ctx->checkfree) { for (i = 0; i <= ctx->max_size; i++) { if (ctx->stats[i].gets != 0U) { fprintf(stderr, "Failing assertion due to probable " "leaked memory in context %p (\"%s\") " "(stats[%u].gets == %lu).\n", ctx, ctx->name, i, ctx->stats[i].gets); #if ISC_MEM_TRACKLINES print_active(ctx, stderr); #endif INSIST(ctx->stats[i].gets == 0U); } } } (ctx->memfree)(ctx->arg, ctx->stats); ctx->malloced -= (ctx->max_size+1) * sizeof(struct stats); if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { for (i = 0; i < ctx->basic_table_count; i++) { (ctx->memfree)(ctx->arg, ctx->basic_table[i]); ctx->malloced -= NUM_BASIC_BLOCKS * ctx->mem_target; } (ctx->memfree)(ctx->arg, ctx->freelists); ctx->malloced -= ctx->max_size * sizeof(element *); if (ctx->basic_table != NULL) { (ctx->memfree)(ctx->arg, ctx->basic_table); ctx->malloced -= ctx->basic_table_size * sizeof(unsigned char *); } } ondest = ctx->ondestroy; if ((ctx->flags & ISC_MEMFLAG_NOLOCK) == 0) DESTROYLOCK(&ctx->lock); ctx->malloced -= sizeof(*ctx); if (ctx->checkfree) INSIST(ctx->malloced == 0); (ctx->memfree)(ctx->arg, ctx); isc_ondestroy_notify(&ondest, ctx); } void isc__mem_attach(isc_mem_t *source0, isc_mem_t **targetp) { isc__mem_t *source = (isc__mem_t *)source0; REQUIRE(VALID_CONTEXT(source)); REQUIRE(targetp != NULL && *targetp == NULL); MCTXLOCK(source, &source->lock); source->references++; MCTXUNLOCK(source, &source->lock); *targetp = (isc_mem_t *)source; } void isc__mem_detach(isc_mem_t **ctxp) { isc__mem_t *ctx; isc_boolean_t want_destroy = ISC_FALSE; REQUIRE(ctxp != NULL); ctx = (isc__mem_t *)*ctxp; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); INSIST(ctx->references > 0); ctx->references--; if (ctx->references == 0) want_destroy = ISC_TRUE; MCTXUNLOCK(ctx, &ctx->lock); if (want_destroy) destroy(ctx); *ctxp = NULL; } /* * isc_mem_putanddetach() is the equivalent of: * * mctx = NULL; * isc_mem_attach(ptr->mctx, &mctx); * isc_mem_detach(&ptr->mctx); * isc_mem_put(mctx, ptr, sizeof(*ptr); * isc_mem_detach(&mctx); */ void isc___mem_putanddetach(isc_mem_t **ctxp, void *ptr, size_t size FLARG) { isc__mem_t *ctx; isc_boolean_t want_destroy = ISC_FALSE; size_info *si; size_t oldsize; REQUIRE(ctxp != NULL); ctx = (isc__mem_t *)*ctxp; REQUIRE(VALID_CONTEXT(ctx)); REQUIRE(ptr != NULL); /* * Must be before mem_putunlocked() as ctxp is usually within * [ptr..ptr+size). */ *ctxp = NULL; if (ISC_UNLIKELY((isc_mem_debugging & (ISC_MEM_DEBUGSIZE|ISC_MEM_DEBUGCTX)) != 0)) { if ((isc_mem_debugging & ISC_MEM_DEBUGSIZE) != 0) { si = &(((size_info *)ptr)[-1]); oldsize = si->u.size - ALIGNMENT_SIZE; if ((isc_mem_debugging & ISC_MEM_DEBUGCTX) != 0) oldsize -= ALIGNMENT_SIZE; INSIST(oldsize == size); } isc__mem_free((isc_mem_t *)ctx, ptr FLARG_PASS); MCTXLOCK(ctx, &ctx->lock); ctx->references--; if (ctx->references == 0) want_destroy = ISC_TRUE; MCTXUNLOCK(ctx, &ctx->lock); if (want_destroy) destroy(ctx); return; } MCTXLOCK(ctx, &ctx->lock); DELETE_TRACE(ctx, ptr, size, file, line); if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { mem_putunlocked(ctx, ptr, size); } else { mem_putstats(ctx, ptr, size); mem_put(ctx, ptr, size); } INSIST(ctx->references > 0); ctx->references--; if (ctx->references == 0) want_destroy = ISC_TRUE; MCTXUNLOCK(ctx, &ctx->lock); if (want_destroy) destroy(ctx); } void isc__mem_destroy(isc_mem_t **ctxp) { isc__mem_t *ctx; /* * This routine provides legacy support for callers who use mctxs * without attaching/detaching. */ REQUIRE(ctxp != NULL); ctx = (isc__mem_t *)*ctxp; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); #if ISC_MEM_TRACKLINES if (ctx->references != 1) print_active(ctx, stderr); #endif REQUIRE(ctx->references == 1); ctx->references--; MCTXUNLOCK(ctx, &ctx->lock); destroy(ctx); *ctxp = NULL; } isc_result_t isc_mem_ondestroy(isc_mem_t *ctx0, isc_task_t *task, isc_event_t **event) { isc__mem_t *ctx = (isc__mem_t *)ctx0; isc_result_t res; MCTXLOCK(ctx, &ctx->lock); res = isc_ondestroy_register(&ctx->ondestroy, task, event); MCTXUNLOCK(ctx, &ctx->lock); return (res); } void * isc___mem_get(isc_mem_t *ctx0, size_t size FLARG) { isc__mem_t *ctx = (isc__mem_t *)ctx0; void *ptr; isc_boolean_t call_water = ISC_FALSE; REQUIRE(VALID_CONTEXT(ctx)); if (ISC_UNLIKELY((isc_mem_debugging & (ISC_MEM_DEBUGSIZE|ISC_MEM_DEBUGCTX)) != 0)) return (isc__mem_allocate(ctx0, size FLARG_PASS)); if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { MCTXLOCK(ctx, &ctx->lock); ptr = mem_getunlocked(ctx, size); } else { ptr = mem_get(ctx, size); MCTXLOCK(ctx, &ctx->lock); if (ptr != NULL) mem_getstats(ctx, size); } ADD_TRACE(ctx, ptr, size, file, line); if (ctx->hi_water != 0U && ctx->inuse > ctx->hi_water) { ctx->is_overmem = ISC_TRUE; if (!ctx->hi_called) call_water = ISC_TRUE; } if (ctx->inuse > ctx->maxinuse) { ctx->maxinuse = ctx->inuse; if (ctx->hi_water != 0U && ctx->inuse > ctx->hi_water && (isc_mem_debugging & ISC_MEM_DEBUGUSAGE) != 0) fprintf(stderr, "maxinuse = %lu\n", (unsigned long)ctx->inuse); } MCTXUNLOCK(ctx, &ctx->lock); if (call_water && (ctx->water != NULL)) (ctx->water)(ctx->water_arg, ISC_MEM_HIWATER); return (ptr); } void isc___mem_put(isc_mem_t *ctx0, void *ptr, size_t size FLARG) { isc__mem_t *ctx = (isc__mem_t *)ctx0; isc_boolean_t call_water = ISC_FALSE; size_info *si; size_t oldsize; REQUIRE(VALID_CONTEXT(ctx)); REQUIRE(ptr != NULL); if (ISC_UNLIKELY((isc_mem_debugging & (ISC_MEM_DEBUGSIZE|ISC_MEM_DEBUGCTX)) != 0)) { if ((isc_mem_debugging & ISC_MEM_DEBUGSIZE) != 0) { si = &(((size_info *)ptr)[-1]); oldsize = si->u.size - ALIGNMENT_SIZE; if ((isc_mem_debugging & ISC_MEM_DEBUGCTX) != 0) oldsize -= ALIGNMENT_SIZE; INSIST(oldsize == size); } isc__mem_free((isc_mem_t *)ctx, ptr FLARG_PASS); return; } MCTXLOCK(ctx, &ctx->lock); DELETE_TRACE(ctx, ptr, size, file, line); if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { mem_putunlocked(ctx, ptr, size); } else { mem_putstats(ctx, ptr, size); mem_put(ctx, ptr, size); } /* * The check against ctx->lo_water == 0 is for the condition * when the context was pushed over hi_water but then had * isc_mem_setwater() called with 0 for hi_water and lo_water. */ if ((ctx->inuse < ctx->lo_water) || (ctx->lo_water == 0U)) { ctx->is_overmem = ISC_FALSE; if (ctx->hi_called) call_water = ISC_TRUE; } MCTXUNLOCK(ctx, &ctx->lock); if (call_water && (ctx->water != NULL)) (ctx->water)(ctx->water_arg, ISC_MEM_LOWATER); } void isc__mem_waterack(isc_mem_t *ctx0, int flag) { isc__mem_t *ctx = (isc__mem_t *)ctx0; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); if (flag == ISC_MEM_LOWATER) ctx->hi_called = ISC_FALSE; else if (flag == ISC_MEM_HIWATER) ctx->hi_called = ISC_TRUE; MCTXUNLOCK(ctx, &ctx->lock); } #if ISC_MEM_TRACKLINES static void print_active(isc__mem_t *mctx, FILE *out) { if (mctx->debuglist != NULL) { debuglink_t *dl; unsigned int i; const char *format; isc_boolean_t found; fprintf(out, "%s", isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_DUMPALLOC, "Dump of all outstanding " "memory allocations:\n")); found = ISC_FALSE; format = isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_PTRFILELINE, "\tptr %p size %u file %s line %u\n"); for (i = 0; i < DEBUG_TABLE_COUNT; i++) { dl = ISC_LIST_HEAD(mctx->debuglist[i]); if (dl != NULL) found = ISC_TRUE; while (dl != NULL) { if (dl->ptr != NULL) fprintf(out, format, dl->ptr, dl->size, dl->file, dl->line); dl = ISC_LIST_NEXT(dl, link); } } if (!found) fputs(isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_NONE, "\tNone.\n"), out); } } #endif /* * Print the stats[] on the stream "out" with suitable formatting. */ void isc_mem_stats(isc_mem_t *ctx0, FILE *out) { isc__mem_t *ctx = (isc__mem_t *)ctx0; size_t i; const struct stats *s; const isc__mempool_t *pool; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); for (i = 0; i <= ctx->max_size; i++) { s = &ctx->stats[i]; if (s->totalgets == 0U && s->gets == 0U) continue; fprintf(out, "%s%5lu: %11lu gets, %11lu rem", (i == ctx->max_size) ? ">=" : " ", (unsigned long) i, s->totalgets, s->gets); if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0 && (s->blocks != 0U || s->freefrags != 0U)) fprintf(out, " (%lu bl, %lu ff)", s->blocks, s->freefrags); fputc('\n', out); } /* * Note that since a pool can be locked now, these stats might be * somewhat off if the pool is in active use at the time the stats * are dumped. The link fields are protected by the isc_mem_t's * lock, however, so walking this list and extracting integers from * stats fields is always safe. */ pool = ISC_LIST_HEAD(ctx->pools); if (pool != NULL) { fprintf(out, "%s", isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLSTATS, "[Pool statistics]\n")); fprintf(out, "%15s %10s %10s %10s %10s %10s %10s %10s %1s\n", isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLNAME, "name"), isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLSIZE, "size"), isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLMAXALLOC, "maxalloc"), isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLALLOCATED, "allocated"), isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLFREECOUNT, "freecount"), isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLFREEMAX, "freemax"), isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLFILLCOUNT, "fillcount"), isc_msgcat_get(isc_msgcat, ISC_MSGSET_MEM, ISC_MSG_POOLGETS, "gets"), "L"); } while (pool != NULL) { fprintf(out, "%15s %10lu %10u %10u %10u %10u %10u %10u %s\n", #if ISC_MEMPOOL_NAMES pool->name, #else "(not tracked)", #endif (unsigned long) pool->size, pool->maxalloc, pool->allocated, pool->freecount, pool->freemax, pool->fillcount, pool->gets, (pool->lock == NULL ? "N" : "Y")); pool = ISC_LIST_NEXT(pool, link); } #if ISC_MEM_TRACKLINES print_active(ctx, out); #endif MCTXUNLOCK(ctx, &ctx->lock); } /* * Replacements for malloc() and free() -- they implicitly remember the * size of the object allocated (with some additional overhead). */ static void * mem_allocateunlocked(isc_mem_t *ctx0, size_t size) { isc__mem_t *ctx = (isc__mem_t *)ctx0; size_info *si; size += ALIGNMENT_SIZE; if (ISC_UNLIKELY((isc_mem_debugging & ISC_MEM_DEBUGCTX) != 0)) size += ALIGNMENT_SIZE; if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) si = mem_getunlocked(ctx, size); else si = mem_get(ctx, size); if (si == NULL) return (NULL); if (ISC_UNLIKELY((isc_mem_debugging & ISC_MEM_DEBUGCTX) != 0)) { si->u.ctx = ctx; si++; } si->u.size = size; return (&si[1]); } void * isc___mem_allocate(isc_mem_t *ctx0, size_t size FLARG) { isc__mem_t *ctx = (isc__mem_t *)ctx0; size_info *si; isc_boolean_t call_water = ISC_FALSE; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); si = mem_allocateunlocked((isc_mem_t *)ctx, size); if (((ctx->flags & ISC_MEMFLAG_INTERNAL) == 0) && (si != NULL)) mem_getstats(ctx, si[-1].u.size); ADD_TRACE(ctx, si, si[-1].u.size, file, line); if (ctx->hi_water != 0U && ctx->inuse > ctx->hi_water && !ctx->is_overmem) { ctx->is_overmem = ISC_TRUE; } if (ctx->hi_water != 0U && !ctx->hi_called && ctx->inuse > ctx->hi_water) { ctx->hi_called = ISC_TRUE; call_water = ISC_TRUE; } if (ctx->inuse > ctx->maxinuse) { ctx->maxinuse = ctx->inuse; if (ISC_UNLIKELY(ctx->hi_water != 0U && ctx->inuse > ctx->hi_water && (isc_mem_debugging & ISC_MEM_DEBUGUSAGE) != 0)) fprintf(stderr, "maxinuse = %lu\n", (unsigned long)ctx->inuse); } MCTXUNLOCK(ctx, &ctx->lock); if (call_water) (ctx->water)(ctx->water_arg, ISC_MEM_HIWATER); return (si); } void * isc___mem_reallocate(isc_mem_t *ctx0, void *ptr, size_t size FLARG) { isc__mem_t *ctx = (isc__mem_t *)ctx0; void *new_ptr = NULL; size_t oldsize, copysize; REQUIRE(VALID_CONTEXT(ctx)); /* * This function emulates the realloc(3) standard library function: * - if size > 0, allocate new memory; and if ptr is non NULL, copy * as much of the old contents to the new buffer and free the old one. * Note that when allocation fails the original pointer is intact; * the caller must free it. * - if size is 0 and ptr is non NULL, simply free the given ptr. * - this function returns: * pointer to the newly allocated memory, or * NULL if allocation fails or doesn't happen. */ if (size > 0U) { new_ptr = isc__mem_allocate(ctx0, size FLARG_PASS); if (new_ptr != NULL && ptr != NULL) { oldsize = (((size_info *)ptr)[-1]).u.size; INSIST(oldsize >= ALIGNMENT_SIZE); oldsize -= ALIGNMENT_SIZE; if (ISC_UNLIKELY((isc_mem_debugging & ISC_MEM_DEBUGCTX) != 0)) { INSIST(oldsize >= ALIGNMENT_SIZE); oldsize -= ALIGNMENT_SIZE; } copysize = (oldsize > size) ? size : oldsize; memmove(new_ptr, ptr, copysize); isc__mem_free(ctx0, ptr FLARG_PASS); } } else if (ptr != NULL) isc__mem_free(ctx0, ptr FLARG_PASS); return (new_ptr); } void isc___mem_free(isc_mem_t *ctx0, void *ptr FLARG) { isc__mem_t *ctx = (isc__mem_t *)ctx0; size_info *si; size_t size; isc_boolean_t call_water= ISC_FALSE; REQUIRE(VALID_CONTEXT(ctx)); REQUIRE(ptr != NULL); if (ISC_UNLIKELY((isc_mem_debugging & ISC_MEM_DEBUGCTX) != 0)) { si = &(((size_info *)ptr)[-2]); REQUIRE(si->u.ctx == ctx); size = si[1].u.size; } else { si = &(((size_info *)ptr)[-1]); size = si->u.size; } MCTXLOCK(ctx, &ctx->lock); DELETE_TRACE(ctx, ptr, size, file, line); if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { mem_putunlocked(ctx, si, size); } else { mem_putstats(ctx, si, size); mem_put(ctx, si, size); } /* * The check against ctx->lo_water == 0 is for the condition * when the context was pushed over hi_water but then had * isc_mem_setwater() called with 0 for hi_water and lo_water. */ if (ctx->is_overmem && (ctx->inuse < ctx->lo_water || ctx->lo_water == 0U)) { ctx->is_overmem = ISC_FALSE; } if (ctx->hi_called && (ctx->inuse < ctx->lo_water || ctx->lo_water == 0U)) { ctx->hi_called = ISC_FALSE; if (ctx->water != NULL) call_water = ISC_TRUE; } MCTXUNLOCK(ctx, &ctx->lock); if (call_water) (ctx->water)(ctx->water_arg, ISC_MEM_LOWATER); } /* * Other useful things. */ char * isc___mem_strdup(isc_mem_t *mctx0, const char *s FLARG) { isc__mem_t *mctx = (isc__mem_t *)mctx0; size_t len; char *ns; REQUIRE(VALID_CONTEXT(mctx)); REQUIRE(s != NULL); len = strlen(s) + 1; ns = isc__mem_allocate((isc_mem_t *)mctx, len FLARG_PASS); if (ns != NULL) strlcpy(ns, s, len); return (ns); } void isc__mem_setdestroycheck(isc_mem_t *ctx0, isc_boolean_t flag) { isc__mem_t *ctx = (isc__mem_t *)ctx0; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); ctx->checkfree = flag; MCTXUNLOCK(ctx, &ctx->lock); } /* * Quotas */ void isc_mem_setquota(isc_mem_t *ctx0, size_t quota) { isc__mem_t *ctx = (isc__mem_t *)ctx0; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); ctx->quota = quota; MCTXUNLOCK(ctx, &ctx->lock); } size_t isc_mem_getquota(isc_mem_t *ctx0) { isc__mem_t *ctx = (isc__mem_t *)ctx0; size_t quota; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); quota = ctx->quota; MCTXUNLOCK(ctx, &ctx->lock); return (quota); } size_t isc__mem_inuse(isc_mem_t *ctx0) { isc__mem_t *ctx = (isc__mem_t *)ctx0; size_t inuse; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); inuse = ctx->inuse; MCTXUNLOCK(ctx, &ctx->lock); return (inuse); } size_t isc__mem_maxinuse(isc_mem_t *ctx0) { isc__mem_t *ctx = (isc__mem_t *)ctx0; size_t maxinuse; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); maxinuse = ctx->maxinuse; MCTXUNLOCK(ctx, &ctx->lock); return (maxinuse); } size_t isc__mem_total(isc_mem_t *ctx0) { isc__mem_t *ctx = (isc__mem_t *)ctx0; size_t total; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); total = ctx->total; MCTXUNLOCK(ctx, &ctx->lock); return (total); } void isc__mem_setwater(isc_mem_t *ctx0, isc_mem_water_t water, void *water_arg, size_t hiwater, size_t lowater) { isc__mem_t *ctx = (isc__mem_t *)ctx0; isc_boolean_t callwater = ISC_FALSE; isc_mem_water_t oldwater; void *oldwater_arg; REQUIRE(VALID_CONTEXT(ctx)); REQUIRE(hiwater >= lowater); MCTXLOCK(ctx, &ctx->lock); oldwater = ctx->water; oldwater_arg = ctx->water_arg; if (water == NULL) { callwater = ctx->hi_called; ctx->water = NULL; ctx->water_arg = NULL; ctx->hi_water = 0; ctx->lo_water = 0; } else { if (ctx->hi_called && (ctx->water != water || ctx->water_arg != water_arg || ctx->inuse < lowater || lowater == 0U)) callwater = ISC_TRUE; ctx->water = water; ctx->water_arg = water_arg; ctx->hi_water = hiwater; ctx->lo_water = lowater; } MCTXUNLOCK(ctx, &ctx->lock); if (callwater && oldwater != NULL) (oldwater)(oldwater_arg, ISC_MEM_LOWATER); } isc_boolean_t isc__mem_isovermem(isc_mem_t *ctx0) { isc__mem_t *ctx = (isc__mem_t *)ctx0; REQUIRE(VALID_CONTEXT(ctx)); /* * We don't bother to lock the context because 100% accuracy isn't * necessary (and even if we locked the context the returned value * could be different from the actual state when it's used anyway) */ return (ctx->is_overmem); } void isc_mem_setname(isc_mem_t *ctx0, const char *name, void *tag) { isc__mem_t *ctx = (isc__mem_t *)ctx0; REQUIRE(VALID_CONTEXT(ctx)); LOCK(&ctx->lock); strlcpy(ctx->name, name, sizeof(ctx->name)); ctx->tag = tag; UNLOCK(&ctx->lock); } const char * isc_mem_getname(isc_mem_t *ctx0) { isc__mem_t *ctx = (isc__mem_t *)ctx0; REQUIRE(VALID_CONTEXT(ctx)); if (ctx->name[0] == 0) return (""); return (ctx->name); } void * isc_mem_gettag(isc_mem_t *ctx0) { isc__mem_t *ctx = (isc__mem_t *)ctx0; REQUIRE(VALID_CONTEXT(ctx)); return (ctx->tag); } /* * Memory pool stuff */ isc_result_t isc__mempool_create(isc_mem_t *mctx0, size_t size, isc_mempool_t **mpctxp) { isc__mem_t *mctx = (isc__mem_t *)mctx0; isc__mempool_t *mpctx; REQUIRE(VALID_CONTEXT(mctx)); REQUIRE(size > 0U); REQUIRE(mpctxp != NULL && *mpctxp == NULL); /* * Allocate space for this pool, initialize values, and if all works * well, attach to the memory context. */ mpctx = isc_mem_get((isc_mem_t *)mctx, sizeof(isc__mempool_t)); if (mpctx == NULL) return (ISC_R_NOMEMORY); mpctx->common.methods = (isc_mempoolmethods_t *)&mempoolmethods; mpctx->common.impmagic = MEMPOOL_MAGIC; mpctx->common.magic = ISCAPI_MPOOL_MAGIC; mpctx->lock = NULL; mpctx->mctx = mctx; mpctx->size = size; mpctx->maxalloc = UINT_MAX; mpctx->allocated = 0; mpctx->freecount = 0; mpctx->freemax = 1; mpctx->fillcount = 1; mpctx->gets = 0; #if ISC_MEMPOOL_NAMES mpctx->name[0] = 0; #endif mpctx->items = NULL; *mpctxp = (isc_mempool_t *)mpctx; MCTXLOCK(mctx, &mctx->lock); ISC_LIST_INITANDAPPEND(mctx->pools, mpctx, link); mctx->poolcnt++; MCTXUNLOCK(mctx, &mctx->lock); return (ISC_R_SUCCESS); } void isc__mempool_setname(isc_mempool_t *mpctx0, const char *name) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; REQUIRE(name != NULL); REQUIRE(VALID_MEMPOOL(mpctx)); #if ISC_MEMPOOL_NAMES if (mpctx->lock != NULL) LOCK(mpctx->lock); strlcpy(mpctx->name, name, sizeof(mpctx->name)); if (mpctx->lock != NULL) UNLOCK(mpctx->lock); #else UNUSED(mpctx); UNUSED(name); #endif } void isc__mempool_destroy(isc_mempool_t **mpctxp) { isc__mempool_t *mpctx; isc__mem_t *mctx; isc_mutex_t *lock; element *item; REQUIRE(mpctxp != NULL); mpctx = (isc__mempool_t *)*mpctxp; REQUIRE(VALID_MEMPOOL(mpctx)); #if ISC_MEMPOOL_NAMES if (mpctx->allocated > 0) UNEXPECTED_ERROR(__FILE__, __LINE__, "isc__mempool_destroy(): mempool %s " "leaked memory", mpctx->name); #endif REQUIRE(mpctx->allocated == 0); mctx = mpctx->mctx; lock = mpctx->lock; if (lock != NULL) LOCK(lock); /* * Return any items on the free list */ MCTXLOCK(mctx, &mctx->lock); while (mpctx->items != NULL) { INSIST(mpctx->freecount > 0); mpctx->freecount--; item = mpctx->items; mpctx->items = item->next; if ((mctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { mem_putunlocked(mctx, item, mpctx->size); } else { mem_putstats(mctx, item, mpctx->size); mem_put(mctx, item, mpctx->size); } } MCTXUNLOCK(mctx, &mctx->lock); /* * Remove our linked list entry from the memory context. */ MCTXLOCK(mctx, &mctx->lock); ISC_LIST_UNLINK(mctx->pools, mpctx, link); mctx->poolcnt--; MCTXUNLOCK(mctx, &mctx->lock); mpctx->common.impmagic = 0; mpctx->common.magic = 0; isc_mem_put((isc_mem_t *)mpctx->mctx, mpctx, sizeof(isc__mempool_t)); if (lock != NULL) UNLOCK(lock); *mpctxp = NULL; } void isc__mempool_associatelock(isc_mempool_t *mpctx0, isc_mutex_t *lock) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; REQUIRE(VALID_MEMPOOL(mpctx)); REQUIRE(mpctx->lock == NULL); REQUIRE(lock != NULL); mpctx->lock = lock; } void * isc___mempool_get(isc_mempool_t *mpctx0 FLARG) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; element *item; isc__mem_t *mctx; unsigned int i; REQUIRE(VALID_MEMPOOL(mpctx)); mctx = mpctx->mctx; if (mpctx->lock != NULL) LOCK(mpctx->lock); /* * Don't let the caller go over quota */ if (ISC_UNLIKELY(mpctx->allocated >= mpctx->maxalloc)) { item = NULL; goto out; } if (ISC_UNLIKELY(mpctx->items == NULL)) { /* * We need to dip into the well. Lock the memory context * here and fill up our free list. */ MCTXLOCK(mctx, &mctx->lock); for (i = 0; i < mpctx->fillcount; i++) { if ((mctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { item = mem_getunlocked(mctx, mpctx->size); } else { item = mem_get(mctx, mpctx->size); if (item != NULL) mem_getstats(mctx, mpctx->size); } if (ISC_UNLIKELY(item == NULL)) break; item->next = mpctx->items; mpctx->items = item; mpctx->freecount++; } MCTXUNLOCK(mctx, &mctx->lock); } /* * If we didn't get any items, return NULL. */ item = mpctx->items; if (ISC_UNLIKELY(item == NULL)) goto out; mpctx->items = item->next; INSIST(mpctx->freecount > 0); mpctx->freecount--; mpctx->gets++; mpctx->allocated++; out: if (mpctx->lock != NULL) UNLOCK(mpctx->lock); #if ISC_MEM_TRACKLINES if (ISC_UNLIKELY(((isc_mem_debugging & TRACE_OR_RECORD) != 0) && item != NULL)) { MCTXLOCK(mctx, &mctx->lock); ADD_TRACE(mctx, item, mpctx->size, file, line); MCTXUNLOCK(mctx, &mctx->lock); } #endif /* ISC_MEM_TRACKLINES */ return (item); } /* coverity[+free : arg-1] */ void isc___mempool_put(isc_mempool_t *mpctx0, void *mem FLARG) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; isc__mem_t *mctx; element *item; REQUIRE(VALID_MEMPOOL(mpctx)); REQUIRE(mem != NULL); mctx = mpctx->mctx; if (mpctx->lock != NULL) LOCK(mpctx->lock); INSIST(mpctx->allocated > 0); mpctx->allocated--; #if ISC_MEM_TRACKLINES if (ISC_UNLIKELY((isc_mem_debugging & TRACE_OR_RECORD) != 0)) { MCTXLOCK(mctx, &mctx->lock); DELETE_TRACE(mctx, mem, mpctx->size, file, line); MCTXUNLOCK(mctx, &mctx->lock); } #endif /* ISC_MEM_TRACKLINES */ /* * If our free list is full, return this to the mctx directly. */ if (mpctx->freecount >= mpctx->freemax) { MCTXLOCK(mctx, &mctx->lock); if ((mctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { mem_putunlocked(mctx, mem, mpctx->size); } else { mem_putstats(mctx, mem, mpctx->size); mem_put(mctx, mem, mpctx->size); } MCTXUNLOCK(mctx, &mctx->lock); if (mpctx->lock != NULL) UNLOCK(mpctx->lock); return; } /* * Otherwise, attach it to our free list and bump the counter. */ mpctx->freecount++; item = (element *)mem; item->next = mpctx->items; mpctx->items = item; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); } /* * Quotas */ void isc__mempool_setfreemax(isc_mempool_t *mpctx0, unsigned int limit) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; REQUIRE(VALID_MEMPOOL(mpctx)); if (mpctx->lock != NULL) LOCK(mpctx->lock); mpctx->freemax = limit; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); } unsigned int isc_mempool_getfreemax(isc_mempool_t *mpctx0) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; unsigned int freemax; REQUIRE(VALID_MEMPOOL(mpctx)); if (mpctx->lock != NULL) LOCK(mpctx->lock); freemax = mpctx->freemax; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); return (freemax); } unsigned int isc_mempool_getfreecount(isc_mempool_t *mpctx0) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; unsigned int freecount; REQUIRE(VALID_MEMPOOL(mpctx)); if (mpctx->lock != NULL) LOCK(mpctx->lock); freecount = mpctx->freecount; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); return (freecount); } void isc__mempool_setmaxalloc(isc_mempool_t *mpctx0, unsigned int limit) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; REQUIRE(limit > 0); REQUIRE(VALID_MEMPOOL(mpctx)); if (mpctx->lock != NULL) LOCK(mpctx->lock); mpctx->maxalloc = limit; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); } unsigned int isc_mempool_getmaxalloc(isc_mempool_t *mpctx0) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; unsigned int maxalloc; REQUIRE(VALID_MEMPOOL(mpctx)); if (mpctx->lock != NULL) LOCK(mpctx->lock); maxalloc = mpctx->maxalloc; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); return (maxalloc); } unsigned int isc__mempool_getallocated(isc_mempool_t *mpctx0) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; unsigned int allocated; REQUIRE(VALID_MEMPOOL(mpctx)); if (mpctx->lock != NULL) LOCK(mpctx->lock); allocated = mpctx->allocated; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); return (allocated); } void isc__mempool_setfillcount(isc_mempool_t *mpctx0, unsigned int limit) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; REQUIRE(limit > 0); REQUIRE(VALID_MEMPOOL(mpctx)); if (mpctx->lock != NULL) LOCK(mpctx->lock); mpctx->fillcount = limit; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); } unsigned int isc_mempool_getfillcount(isc_mempool_t *mpctx0) { isc__mempool_t *mpctx = (isc__mempool_t *)mpctx0; unsigned int fillcount; REQUIRE(VALID_MEMPOOL(mpctx)); if (mpctx->lock != NULL) LOCK(mpctx->lock); fillcount = mpctx->fillcount; if (mpctx->lock != NULL) UNLOCK(mpctx->lock); return (fillcount); } isc_result_t isc__mem_register(void) { return (isc_mem_register(isc_mem_create2)); } void isc__mem_printactive(isc_mem_t *ctx0, FILE *file) { #if ISC_MEM_TRACKLINES isc__mem_t *ctx = (isc__mem_t *)ctx0; REQUIRE(VALID_CONTEXT(ctx)); REQUIRE(file != NULL); print_active(ctx, file); #else UNUSED(ctx0); UNUSED(file); #endif } /* * Requires contextslock to be held by caller. */ static void print_contexts(FILE *file) { isc__mem_t *ctx; for (ctx = ISC_LIST_HEAD(contexts); ctx != NULL; ctx = ISC_LIST_NEXT(ctx, link)) { fprintf(file, "context: %p (%s): %u references\n", ctx, ctx->name[0] == 0 ? "" : ctx->name, ctx->references); print_active(ctx, file); } fflush(file); } void isc_mem_printallactive(FILE *file) { #if !ISC_MEM_TRACKLINES UNUSED(file); #else RUNTIME_CHECK(isc_once_do(&once, initialize_action) == ISC_R_SUCCESS); LOCK(&contextslock); print_contexts(file); UNLOCK(&contextslock); #endif } void isc_mem_checkdestroyed(FILE *file) { #if !ISC_MEM_TRACKLINES UNUSED(file); #endif RUNTIME_CHECK(isc_once_do(&once, initialize_action) == ISC_R_SUCCESS); LOCK(&contextslock); if (!ISC_LIST_EMPTY(contexts)) { #if ISC_MEM_TRACKLINES if (ISC_UNLIKELY((isc_mem_debugging & TRACE_OR_RECORD) != 0)) { print_contexts(file); } #endif INSIST(0); } UNLOCK(&contextslock); } unsigned int isc_mem_references(isc_mem_t *ctx0) { isc__mem_t *ctx = (isc__mem_t *)ctx0; unsigned int references; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); references = ctx->references; MCTXUNLOCK(ctx, &ctx->lock); return (references); } typedef struct summarystat { isc_uint64_t total; isc_uint64_t inuse; isc_uint64_t malloced; isc_uint64_t blocksize; isc_uint64_t contextsize; } summarystat_t; #ifdef HAVE_LIBXML2 #define TRY0(a) do { xmlrc = (a); if (xmlrc < 0) goto error; } while(0) static int xml_renderctx(isc__mem_t *ctx, summarystat_t *summary, xmlTextWriterPtr writer) { int xmlrc; REQUIRE(VALID_CONTEXT(ctx)); MCTXLOCK(ctx, &ctx->lock); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "context")); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "id")); TRY0(xmlTextWriterWriteFormatString(writer, "%p", ctx)); TRY0(xmlTextWriterEndElement(writer)); /* id */ if (ctx->name[0] != 0) { TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "name")); TRY0(xmlTextWriterWriteFormatString(writer, "%s", ctx->name)); TRY0(xmlTextWriterEndElement(writer)); /* name */ } summary->contextsize += sizeof(*ctx) + (ctx->max_size + 1) * sizeof(struct stats) + ctx->max_size * sizeof(element *) + ctx->basic_table_count * sizeof(char *); #if ISC_MEM_TRACKLINES if (ctx->debuglist != NULL) { summary->contextsize += DEBUG_TABLE_COUNT * sizeof(debuglist_t) + ctx->debuglistcnt * sizeof(debuglink_t); } #endif TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "references")); TRY0(xmlTextWriterWriteFormatString(writer, "%d", ctx->references)); TRY0(xmlTextWriterEndElement(writer)); /* references */ summary->total += ctx->total; TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "total")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", (isc_uint64_t)ctx->total)); TRY0(xmlTextWriterEndElement(writer)); /* total */ summary->inuse += ctx->inuse; TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "inuse")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", (isc_uint64_t)ctx->inuse)); TRY0(xmlTextWriterEndElement(writer)); /* inuse */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "maxinuse")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", (isc_uint64_t)ctx->maxinuse)); TRY0(xmlTextWriterEndElement(writer)); /* maxinuse */ summary->malloced += ctx->malloced; TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "malloced")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", (isc_uint64_t)ctx->malloced)); TRY0(xmlTextWriterEndElement(writer)); /* malloced */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "maxmalloced")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", (isc_uint64_t)ctx->maxmalloced)); TRY0(xmlTextWriterEndElement(writer)); /* maxmalloced */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "blocksize")); if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { summary->blocksize += ctx->basic_table_count * NUM_BASIC_BLOCKS * ctx->mem_target; TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", (isc_uint64_t) ctx->basic_table_count * NUM_BASIC_BLOCKS * ctx->mem_target)); } else TRY0(xmlTextWriterWriteFormatString(writer, "%s", "-")); TRY0(xmlTextWriterEndElement(writer)); /* blocksize */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "pools")); TRY0(xmlTextWriterWriteFormatString(writer, "%u", ctx->poolcnt)); TRY0(xmlTextWriterEndElement(writer)); /* pools */ summary->contextsize += ctx->poolcnt * sizeof(isc_mempool_t); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "hiwater")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", (isc_uint64_t)ctx->hi_water)); TRY0(xmlTextWriterEndElement(writer)); /* hiwater */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "lowater")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", (isc_uint64_t)ctx->lo_water)); TRY0(xmlTextWriterEndElement(writer)); /* lowater */ TRY0(xmlTextWriterEndElement(writer)); /* context */ error: MCTXUNLOCK(ctx, &ctx->lock); return (xmlrc); } int isc_mem_renderxml(xmlTextWriterPtr writer) { isc__mem_t *ctx; summarystat_t summary; isc_uint64_t lost; int xmlrc; memset(&summary, 0, sizeof(summary)); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "contexts")); RUNTIME_CHECK(isc_once_do(&once, initialize_action) == ISC_R_SUCCESS); LOCK(&contextslock); lost = totallost; for (ctx = ISC_LIST_HEAD(contexts); ctx != NULL; ctx = ISC_LIST_NEXT(ctx, link)) { xmlrc = xml_renderctx(ctx, &summary, writer); if (xmlrc < 0) { UNLOCK(&contextslock); goto error; } } UNLOCK(&contextslock); TRY0(xmlTextWriterEndElement(writer)); /* contexts */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "summary")); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "TotalUse")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", summary.total)); TRY0(xmlTextWriterEndElement(writer)); /* TotalUse */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "InUse")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", summary.inuse)); TRY0(xmlTextWriterEndElement(writer)); /* InUse */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "Malloced")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", summary.malloced)); TRY0(xmlTextWriterEndElement(writer)); /* InUse */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "BlockSize")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", summary.blocksize)); TRY0(xmlTextWriterEndElement(writer)); /* BlockSize */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "ContextSize")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", summary.contextsize)); TRY0(xmlTextWriterEndElement(writer)); /* ContextSize */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "Lost")); TRY0(xmlTextWriterWriteFormatString(writer, "%" ISC_PRINT_QUADFORMAT "u", lost)); TRY0(xmlTextWriterEndElement(writer)); /* Lost */ TRY0(xmlTextWriterEndElement(writer)); /* summary */ error: return (xmlrc); } #endif /* HAVE_LIBXML2 */ #ifdef HAVE_JSON #define CHECKMEM(m) do { \ if (m == NULL) { \ result = ISC_R_NOMEMORY;\ goto error;\ } \ } while(0) static isc_result_t json_renderctx(isc__mem_t *ctx, summarystat_t *summary, json_object *array) { isc_result_t result = ISC_R_FAILURE; json_object *ctxobj, *obj; char buf[1024]; REQUIRE(VALID_CONTEXT(ctx)); REQUIRE(summary != NULL); REQUIRE(array != NULL); MCTXLOCK(ctx, &ctx->lock); summary->contextsize += sizeof(*ctx) + (ctx->max_size + 1) * sizeof(struct stats) + ctx->max_size * sizeof(element *) + ctx->basic_table_count * sizeof(char *); summary->total += ctx->total; summary->inuse += ctx->inuse; summary->malloced += ctx->malloced; if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) summary->blocksize += ctx->basic_table_count * NUM_BASIC_BLOCKS * ctx->mem_target; #if ISC_MEM_TRACKLINES if (ctx->debuglist != NULL) { summary->contextsize += DEBUG_TABLE_COUNT * sizeof(debuglist_t) + ctx->debuglistcnt * sizeof(debuglink_t); } #endif ctxobj = json_object_new_object(); CHECKMEM(ctxobj); snprintf(buf, sizeof(buf), "%p", ctx); obj = json_object_new_string(buf); CHECKMEM(obj); json_object_object_add(ctxobj, "id", obj); if (ctx->name[0] != 0) { obj = json_object_new_string(ctx->name); CHECKMEM(obj); json_object_object_add(ctxobj, "name", obj); } obj = json_object_new_int64(ctx->references); CHECKMEM(obj); json_object_object_add(ctxobj, "references", obj); obj = json_object_new_int64(ctx->total); CHECKMEM(obj); json_object_object_add(ctxobj, "total", obj); obj = json_object_new_int64(ctx->inuse); CHECKMEM(obj); json_object_object_add(ctxobj, "inuse", obj); obj = json_object_new_int64(ctx->maxinuse); CHECKMEM(obj); json_object_object_add(ctxobj, "maxinuse", obj); obj = json_object_new_int64(ctx->malloced); CHECKMEM(obj); json_object_object_add(ctxobj, "malloced", obj); obj = json_object_new_int64(ctx->maxmalloced); CHECKMEM(obj); json_object_object_add(ctxobj, "maxmalloced", obj); if ((ctx->flags & ISC_MEMFLAG_INTERNAL) != 0) { isc_uint64_t blocksize; blocksize = ctx->basic_table_count * NUM_BASIC_BLOCKS * ctx->mem_target; obj = json_object_new_int64(blocksize); CHECKMEM(obj); json_object_object_add(ctxobj, "blocksize", obj); } obj = json_object_new_int64(ctx->poolcnt); CHECKMEM(obj); json_object_object_add(ctxobj, "pools", obj); summary->contextsize += ctx->poolcnt * sizeof(isc_mempool_t); obj = json_object_new_int64(ctx->hi_water); CHECKMEM(obj); json_object_object_add(ctxobj, "hiwater", obj); obj = json_object_new_int64(ctx->lo_water); CHECKMEM(obj); json_object_object_add(ctxobj, "lowater", obj); MCTXUNLOCK(ctx, &ctx->lock); json_object_array_add(array, ctxobj); return (ISC_R_SUCCESS); error: MCTXUNLOCK(ctx, &ctx->lock); if (ctxobj != NULL) json_object_put(ctxobj); return (result); } isc_result_t isc_mem_renderjson(json_object *memobj) { isc_result_t result = ISC_R_SUCCESS; isc__mem_t *ctx; summarystat_t summary; isc_uint64_t lost; json_object *ctxarray, *obj; memset(&summary, 0, sizeof(summary)); RUNTIME_CHECK(isc_once_do(&once, initialize_action) == ISC_R_SUCCESS); ctxarray = json_object_new_array(); CHECKMEM(ctxarray); LOCK(&contextslock); lost = totallost; for (ctx = ISC_LIST_HEAD(contexts); ctx != NULL; ctx = ISC_LIST_NEXT(ctx, link)) { result = json_renderctx(ctx, &summary, ctxarray); if (result != ISC_R_SUCCESS) { UNLOCK(&contextslock); goto error; } } UNLOCK(&contextslock); obj = json_object_new_int64(summary.total); CHECKMEM(obj); json_object_object_add(memobj, "TotalUse", obj); obj = json_object_new_int64(summary.inuse); CHECKMEM(obj); json_object_object_add(memobj, "InUse", obj); obj = json_object_new_int64(summary.malloced); CHECKMEM(obj); json_object_object_add(memobj, "Malloced", obj); obj = json_object_new_int64(summary.blocksize); CHECKMEM(obj); json_object_object_add(memobj, "BlockSize", obj); obj = json_object_new_int64(summary.contextsize); CHECKMEM(obj); json_object_object_add(memobj, "ContextSize", obj); obj = json_object_new_int64(lost); CHECKMEM(obj); json_object_object_add(memobj, "Lost", obj); json_object_object_add(memobj, "contexts", ctxarray); return (ISC_R_SUCCESS); error: if (ctxarray != NULL) json_object_put(ctxarray); return (result); } #endif /* HAVE_JSON */ static isc_memcreatefunc_t mem_createfunc = NULL; isc_result_t isc_mem_register(isc_memcreatefunc_t createfunc) { isc_result_t result = ISC_R_SUCCESS; RUNTIME_CHECK(isc_once_do(&once, initialize_action) == ISC_R_SUCCESS); LOCK(&createlock); if (mem_createfunc == NULL) mem_createfunc = createfunc; else result = ISC_R_EXISTS; UNLOCK(&createlock); return (result); } isc_result_t isc__mem_create2(size_t init_max_size, size_t target_size, isc_mem_t **mctxp, unsigned int flags) { isc_result_t result; LOCK(&createlock); REQUIRE(mem_createfunc != NULL); result = (*mem_createfunc)(init_max_size, target_size, mctxp, flags); UNLOCK(&createlock); return (result); } isc_result_t isc_mem_create(size_t init_max_size, size_t target_size, isc_mem_t **mctxp) { isc_result_t result; if (isc_bind9) return (isc_mem_createx2(init_max_size, target_size, default_memalloc, default_memfree, NULL, mctxp, isc_mem_defaultflags)); LOCK(&createlock); REQUIRE(mem_createfunc != NULL); result = (*mem_createfunc)(init_max_size, target_size, mctxp, isc_mem_defaultflags); UNLOCK(&createlock); return (result); } isc_result_t isc_mem_create2(size_t init_max_size, size_t target_size, isc_mem_t **mctxp, unsigned int flags) { if (isc_bind9) return (isc_mem_createx2(init_max_size, target_size, default_memalloc, default_memfree, NULL, mctxp, flags)); return (isc_mem_createx2(init_max_size, target_size, default_memalloc, default_memfree, NULL, mctxp, flags)); } void isc_mem_attach(isc_mem_t *source, isc_mem_t **targetp) { REQUIRE(ISCAPI_MCTX_VALID(source)); REQUIRE(targetp != NULL && *targetp == NULL); if (isc_bind9) isc__mem_attach(source, targetp); else source->methods->attach(source, targetp); ENSURE(*targetp == source); } void isc_mem_detach(isc_mem_t **mctxp) { REQUIRE(mctxp != NULL && ISCAPI_MCTX_VALID(*mctxp)); if (isc_bind9) isc__mem_detach(mctxp); else (*mctxp)->methods->detach(mctxp); ENSURE(*mctxp == NULL); } void isc_mem_destroy(isc_mem_t **mctxp) { REQUIRE(mctxp != NULL && ISCAPI_MCTX_VALID(*mctxp)); if (isc_bind9) isc__mem_destroy(mctxp); else (*mctxp)->methods->destroy(mctxp); ENSURE(*mctxp == NULL); } void isc_mem_setdestroycheck(isc_mem_t *mctx, isc_boolean_t flag) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); mctx->methods->setdestroycheck(mctx, flag); } void isc_mem_setwater(isc_mem_t *ctx, isc_mem_water_t water, void *water_arg, size_t hiwater, size_t lowater) { REQUIRE(ISCAPI_MCTX_VALID(ctx)); if (isc_bind9) isc__mem_setwater(ctx, water, water_arg, hiwater, lowater); else ctx->methods->setwater(ctx, water, water_arg, hiwater, lowater); } void isc_mem_waterack(isc_mem_t *ctx, int flag) { REQUIRE(ISCAPI_MCTX_VALID(ctx)); if (isc_bind9) isc__mem_waterack(ctx, flag); else ctx->methods->waterack(ctx, flag); } size_t isc_mem_inuse(isc_mem_t *mctx) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) return (isc__mem_inuse(mctx)); return (mctx->methods->inuse(mctx)); } size_t isc_mem_maxinuse(isc_mem_t *mctx) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) return (isc__mem_maxinuse(mctx)); return (mctx->methods->maxinuse(mctx)); } size_t isc_mem_total(isc_mem_t *mctx) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) return (isc__mem_total(mctx)); return (mctx->methods->total(mctx)); } isc_boolean_t isc_mem_isovermem(isc_mem_t *mctx) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) return (isc__mem_isovermem(mctx)); return (mctx->methods->isovermem(mctx)); } isc_result_t isc_mempool_create(isc_mem_t *mctx, size_t size, isc_mempool_t **mpctxp) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); return (mctx->methods->mpcreate(mctx, size, mpctxp)); } void isc_mempool_destroy(isc_mempool_t **mpctxp) { REQUIRE(mpctxp != NULL && ISCAPI_MPOOL_VALID(*mpctxp)); if (isc_bind9) isc__mempool_destroy(mpctxp); else (*mpctxp)->methods->destroy(mpctxp); ENSURE(*mpctxp == NULL); } unsigned int isc_mempool_getallocated(isc_mempool_t *mpctx) { REQUIRE(ISCAPI_MPOOL_VALID(mpctx)); if (isc_bind9) return (isc__mempool_getallocated(mpctx)); return (mpctx->methods->getallocated(mpctx)); } void isc_mempool_setmaxalloc(isc_mempool_t *mpctx, unsigned int limit) { REQUIRE(ISCAPI_MPOOL_VALID(mpctx)); if (isc_bind9) isc__mempool_setmaxalloc(mpctx, limit); else mpctx->methods->setmaxalloc(mpctx, limit); } void isc_mempool_setfreemax(isc_mempool_t *mpctx, unsigned int limit) { REQUIRE(ISCAPI_MPOOL_VALID(mpctx)); if (isc_bind9) isc__mempool_setfreemax(mpctx, limit); else mpctx->methods->setfreemax(mpctx, limit); } void isc_mempool_setname(isc_mempool_t *mpctx, const char *name) { REQUIRE(ISCAPI_MPOOL_VALID(mpctx)); if (isc_bind9) isc__mempool_setname(mpctx, name); else mpctx->methods->setname(mpctx, name); } void isc_mempool_associatelock(isc_mempool_t *mpctx, isc_mutex_t *lock) { REQUIRE(ISCAPI_MPOOL_VALID(mpctx)); if (isc_bind9) isc__mempool_associatelock(mpctx, lock); else mpctx->methods->associatelock(mpctx, lock); } void isc_mempool_setfillcount(isc_mempool_t *mpctx, unsigned int limit) { REQUIRE(ISCAPI_MPOOL_VALID(mpctx)); if (isc_bind9) isc__mempool_setfillcount(mpctx, limit); else mpctx->methods->setfillcount(mpctx, limit); } void * isc__mem_get(isc_mem_t *mctx, size_t size FLARG) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) return (isc___mem_get(mctx, size FLARG_PASS)); return (mctx->methods->memget(mctx, size FLARG_PASS)); } void isc__mem_put(isc_mem_t *mctx, void *ptr, size_t size FLARG) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) isc___mem_put(mctx, ptr, size FLARG_PASS); else mctx->methods->memput(mctx, ptr, size FLARG_PASS); } void isc__mem_putanddetach(isc_mem_t **mctxp, void *ptr, size_t size FLARG) { REQUIRE(mctxp != NULL && ISCAPI_MCTX_VALID(*mctxp)); if (isc_bind9) isc___mem_putanddetach(mctxp, ptr, size FLARG_PASS); else (*mctxp)->methods->memputanddetach(mctxp, ptr, size FLARG_PASS); /* * XXX: We cannot always ensure *mctxp == NULL here * (see lib/isc/mem.c). */ } void * isc__mem_allocate(isc_mem_t *mctx, size_t size FLARG) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) return (isc___mem_allocate(mctx, size FLARG_PASS)); return (mctx->methods->memallocate(mctx, size FLARG_PASS)); } void * isc__mem_reallocate(isc_mem_t *mctx, void *ptr, size_t size FLARG) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) return (isc___mem_reallocate(mctx, ptr, size FLARG_PASS)); return (mctx->methods->memreallocate(mctx, ptr, size FLARG_PASS)); } char * isc__mem_strdup(isc_mem_t *mctx, const char *s FLARG) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) return (isc___mem_strdup(mctx, s FLARG_PASS)); return (mctx->methods->memstrdup(mctx, s FLARG_PASS)); } void isc__mem_free(isc_mem_t *mctx, void *ptr FLARG) { REQUIRE(ISCAPI_MCTX_VALID(mctx)); if (isc_bind9) isc___mem_free(mctx, ptr FLARG_PASS); else mctx->methods->memfree(mctx, ptr FLARG_PASS); } void * isc__mempool_get(isc_mempool_t *mpctx FLARG) { REQUIRE(ISCAPI_MPOOL_VALID(mpctx)); if (isc_bind9) return (isc___mempool_get(mpctx FLARG_PASS)); return (mpctx->methods->get(mpctx FLARG_PASS)); } void isc__mempool_put(isc_mempool_t *mpctx, void *mem FLARG) { REQUIRE(ISCAPI_MPOOL_VALID(mpctx)); if (isc_bind9) isc___mempool_put(mpctx, mem FLARG_PASS); else mpctx->methods->put(mpctx, mem FLARG_PASS); }