/* ** Allocate a page cache line. Look in the page cache memory pool first ** and use an element from it first if available. If nothing is available ** in the page cache memory pool, go to the general purpose memory allocator. */ static void *pcacheMalloc(int sz, PCache *pCache){ assert( sqlite3_mutex_held(pcache_g.mutex) ); if( sz<=pcache_g.szSlot && pcache_g.pFree ){ PgFreeslot *p = pcache_g.pFree; pcache_g.pFree = p->pNext; sqlite3StatusSet(SQLITE_STATUS_PAGECACHE_SIZE, sz); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, 1); return (void*)p; }else{ void *p; /* Allocate a new buffer using sqlite3Malloc. Before doing so, exit the ** global pcache mutex and unlock the pager-cache object pCache. This is ** so that if the attempt to allocate a new buffer causes the the ** configured soft-heap-limit to be breached, it will be possible to ** reclaim memory from this pager-cache. */ pcacheExitMutex(); p = sqlite3Malloc(sz); pcacheEnterMutex(); if( p ){ sz = sqlite3MallocSize(p); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, sz); } return p; } }
/* ** Free an allocated buffer obtained from pcache1Alloc(). */ static int pcache1Free(void *p){ int nFreed = 0; if( p==0 ) return 0; if( p>=pcache1.pStart && p<pcache1.pEnd ){ PgFreeslot *pSlot; sqlite3_mutex_enter(pcache1.mutex); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, -1); pSlot = (PgFreeslot*)p; pSlot->pNext = pcache1.pFree; pcache1.pFree = pSlot; pcache1.nFreeSlot++; pcache1.bUnderPressure = pcache1.nFreeSlot<pcache1.nReserve; assert( pcache1.nFreeSlot<=pcache1.nSlot ); sqlite3_mutex_leave(pcache1.mutex); }else{ assert( sqlite3MemdebugHasType(p, MEMTYPE_PCACHE) ); sqlite3MemdebugSetType(p, MEMTYPE_HEAP); nFreed = sqlite3MallocSize(p); #ifndef SQLITE_DISABLE_PAGECACHE_OVERFLOW_STATS sqlite3_mutex_enter(pcache1.mutex); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, -nFreed); sqlite3_mutex_leave(pcache1.mutex); #endif sqlite3_free(p); } return nFreed; }
/* ** Do a memory allocation with statistics and alarms. Assume the ** lock is already held. */ static int mallocWithAlarm(int n, void **pp){ int nFull; void *p; assert( sqlite3_mutex_held(mem0.mutex) ); nFull = sqlite3GlobalConfig.m.xRoundup(n); sqlite3StatusSet(SQLITE_STATUS_MALLOC_SIZE, n); if( mem0.alarmCallback!=0 ){ int nUsed = sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED); if( nUsed >= mem0.alarmThreshold - nFull ){ mem0.nearlyFull = 1; sqlite3MallocAlarm(nFull); }else{ mem0.nearlyFull = 0; } } p = sqlite3GlobalConfig.m.xMalloc(nFull); #ifdef SQLITE_ENABLE_MEMORY_MANAGEMENT if( p==0 && mem0.alarmCallback ){ sqlite3MallocAlarm(nFull); p = sqlite3GlobalConfig.m.xMalloc(nFull); } #endif if( p ){ nFull = sqlite3MallocSize(p); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, nFull); sqlite3StatusAdd(SQLITE_STATUS_MALLOC_COUNT, 1); } *pp = p; return nFull; }
/* ** Malloc function used within this file to allocate space from the buffer ** configured using sqlite3_config(SQLITE_CONFIG_PAGECACHE) option. If no ** such buffer exists or there is no space left in it, this function falls ** back to sqlite3Malloc(). ** ** Multiple threads can run this routine at the same time. Global variables ** in pcache1 need to be protected via mutex. */ static void *pcache1Alloc(int nByte){ void *p = 0; assert( sqlite3_mutex_notheld(pcache1.grp.mutex) ); sqlite3StatusSet(SQLITE_STATUS_PAGECACHE_SIZE, nByte); if( nByte<=pcache1.szSlot ){ sqlite3_mutex_enter(pcache1.mutex); p = (PgHdr1 *)pcache1.pFree; if( p ){ pcache1.pFree = pcache1.pFree->pNext; pcache1.nFreeSlot--; pcache1.bUnderPressure = pcache1.nFreeSlot<pcache1.nReserve; assert( pcache1.nFreeSlot>=0 ); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, 1); } sqlite3_mutex_leave(pcache1.mutex); } if( p==0 ){ /* Memory is not available in the SQLITE_CONFIG_PAGECACHE pool. Get ** it from sqlite3Malloc instead. */ p = sqlite3Malloc(nByte); #ifndef SQLITE_DISABLE_PAGECACHE_OVERFLOW_STATS if( p ){ int sz = sqlite3MallocSize(p); sqlite3_mutex_enter(pcache1.mutex); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, sz); sqlite3_mutex_leave(pcache1.mutex); } #endif sqlite3MemdebugSetType(p, MEMTYPE_PCACHE); } return p; }
/* ** Malloc function used within this file to allocate space from the buffer ** configured using sqlite3_config(SQLITE_CONFIG_PAGECACHE) option. If no ** such buffer exists or there is no space left in it, this function falls ** back to sqlite3Malloc(). */ static void *pcache1Alloc(int nByte){ void *p; assert( sqlite3_mutex_held(pcache1.mutex) ); if( nByte<=pcache1.szSlot && pcache1.pFree ){ assert( pcache1.isInit ); p = (PgHdr1 *)pcache1.pFree; pcache1.pFree = pcache1.pFree->pNext; sqlite3StatusSet(SQLITE_STATUS_PAGECACHE_SIZE, nByte); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, 1); }else{ /* Allocate a new buffer using sqlite3Malloc. Before doing so, exit the ** global pcache mutex and unlock the pager-cache object pCache. This is ** so that if the attempt to allocate a new buffer causes the the ** configured soft-heap-limit to be breached, it will be possible to ** reclaim memory from this pager-cache. */ pcache1LeaveMutex(); p = sqlite3Malloc(nByte); pcache1EnterMutex(); if( p ){ int sz = sqlite3MallocSize(p); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, sz); } } return p; }
void *sqlite3ScratchMalloc(int n){ void *p; assert( n>0 ); sqlite3_mutex_enter(mem0.mutex); if( mem0.nScratchFree && sqlite3GlobalConfig.szScratch>=n ){ p = mem0.pScratchFree; mem0.pScratchFree = mem0.pScratchFree->pNext; mem0.nScratchFree--; sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_USED, 1); sqlite3StatusSet(SQLITE_STATUS_SCRATCH_SIZE, n); sqlite3_mutex_leave(mem0.mutex); }else{ if( sqlite3GlobalConfig.bMemstat ){ sqlite3StatusSet(SQLITE_STATUS_SCRATCH_SIZE, n); n = mallocWithAlarm(n, &p); if( p ) sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_OVERFLOW, n); sqlite3_mutex_leave(mem0.mutex); }else{ sqlite3_mutex_leave(mem0.mutex); p = sqlite3GlobalConfig.m.xMalloc(n); } sqlite3MemdebugSetType(p, MEMTYPE_SCRATCH); } assert( sqlite3_mutex_notheld(mem0.mutex) ); #if SQLITE_THREADSAFE==0 && !defined(NDEBUG) assert( scratchAllocOut<=1 ); if( p ) scratchAllocOut++; #endif return p; }
/* ** Allocate memory that is to be used and released right away. ** This routine is similar to alloca() in that it is not intended ** for situations where the memory might be held long-term. This ** routine is intended to get memory to old large transient data ** structures that would not normally fit on the stack of an ** embedded processor. */ void *sqlite3ScratchMalloc(int n){ void *p; assert( n>0 ); #if SQLITE_THREADSAFE==0 && !defined(NDEBUG) /* Verify that no more than two scratch allocation per thread ** is outstanding at one time. (This is only checked in the ** single-threaded case since checking in the multi-threaded case ** would be much more complicated.) */ assert( scratchAllocOut<=1 ); #endif if( sqlite3GlobalConfig.szScratch<n ){ goto scratch_overflow; }else{ sqlite3_mutex_enter(mem0.mutex); if( mem0.nScratchFree==0 ){ sqlite3_mutex_leave(mem0.mutex); goto scratch_overflow; }else{ int i; i = mem0.aScratchFree[--mem0.nScratchFree]; i *= sqlite3GlobalConfig.szScratch; sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_USED, 1); sqlite3StatusSet(SQLITE_STATUS_SCRATCH_SIZE, n); sqlite3_mutex_leave(mem0.mutex); p = (void*)&((char*)sqlite3GlobalConfig.pScratch)[i]; assert( (((u8*)p - (u8*)0) & 7)==0 ); } } #if SQLITE_THREADSAFE==0 && !defined(NDEBUG) scratchAllocOut = p!=0; #endif return p; scratch_overflow: if( sqlite3GlobalConfig.bMemstat ){ sqlite3_mutex_enter(mem0.mutex); sqlite3StatusSet(SQLITE_STATUS_SCRATCH_SIZE, n); n = mallocWithAlarm(n, &p); if( p ) sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_OVERFLOW, n); sqlite3_mutex_leave(mem0.mutex); }else{ p = sqlite3GlobalConfig.m.xMalloc(n); } sqlite3MemdebugSetType(p, MEMTYPE_SCRATCH); #if SQLITE_THREADSAFE==0 && !defined(NDEBUG) scratchAllocOut = p!=0; #endif return p; }
/* ** Free memory previously obtained from sqlite3Malloc(). */ void sqlite3_free(void *p){ if( p==0 ) return; /* IMP: R-49053-54554 */ assert( sqlite3MemdebugNoType(p, MEMTYPE_DB) ); assert( sqlite3MemdebugHasType(p, MEMTYPE_HEAP) ); if( sqlite3GlobalConfig.bMemstat ){ sqlite3_mutex_enter(mem0.mutex); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, -sqlite3MallocSize(p)); sqlite3StatusAdd(SQLITE_STATUS_MALLOC_COUNT, -1); sqlite3GlobalConfig.m.xFree(p); sqlite3_mutex_leave(mem0.mutex); }else{ sqlite3GlobalConfig.m.xFree(p); } }
/* ** Release a pager memory allocation */ static void pcacheFree(void *p){ assert( sqlite3_mutex_held(pcache_g.mutex) ); if( p==0 ) return; if( p>=pcache_g.pStart && p<pcache_g.pEnd ){ PgFreeslot *pSlot; sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, -1); pSlot = (PgFreeslot*)p; pSlot->pNext = pcache_g.pFree; pcache_g.pFree = pSlot; }else{ int iSize = sqlite3MallocSize(p); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, -iSize); sqlite3_free(p); } }
void sqlite3PageFree(void *p){ if( p ){ if( sqlite3GlobalConfig.pPage==0 || p<sqlite3GlobalConfig.pPage || p>=(void*)mem0.aPageFree ){ /* In this case, the page allocation was obtained from a regular ** call to sqlite3_mem_methods.xMalloc() (a page-cache-memory ** "overflow"). Free the block with sqlite3_mem_methods.xFree(). */ if( sqlite3GlobalConfig.bMemstat ){ int iSize = sqlite3MallocSize(p); sqlite3_mutex_enter(mem0.mutex); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, -iSize); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, -iSize); sqlite3GlobalConfig.m.xFree(p); sqlite3_mutex_leave(mem0.mutex); }else{ sqlite3GlobalConfig.m.xFree(p); } }else{ /* The page allocation was allocated from the sqlite3GlobalConfig.pPage ** buffer. In this case all that is add the index of the page in ** the sqlite3GlobalConfig.pPage array to the set of free indexes stored ** in the mem0.aPageFree[] array. */ int i; i = (u8 *)p - (u8 *)sqlite3GlobalConfig.pPage; i /= sqlite3GlobalConfig.szPage; assert( i>=0 && i<sqlite3GlobalConfig.nPage ); sqlite3_mutex_enter(mem0.mutex); assert( mem0.nPageFree<sqlite3GlobalConfig.nPage ); mem0.aPageFree[mem0.nPageFree++] = i; sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, -1); sqlite3_mutex_leave(mem0.mutex); #if !defined(NDEBUG) && 0 /* Assert that a duplicate was not just inserted into aPageFree[]. */ for(i=0; i<mem0.nPageFree-1; i++){ assert( mem0.aPageFree[i]!=mem0.aPageFree[mem0.nPageFree-1] ); } #endif } } }
void sqlite3ScratchFree(void *p){ if( p ){ #if SQLITE_THREADSAFE==0 && !defined(NDEBUG) /* Verify that no more than two scratch allocation per thread ** is outstanding at one time. (This is only checked in the ** single-threaded case since checking in the multi-threaded case ** would be much more complicated.) */ assert( scratchAllocOut>=1 && scratchAllocOut<=2 ); scratchAllocOut--; #endif if( p>=sqlite3GlobalConfig.pScratch && p<mem0.pScratchEnd ){ /* Release memory from the SQLITE_CONFIG_SCRATCH allocation */ ScratchFreeslot *pSlot; pSlot = (ScratchFreeslot*)p; sqlite3_mutex_enter(mem0.mutex); pSlot->pNext = mem0.pScratchFree; mem0.pScratchFree = pSlot; mem0.nScratchFree++; assert( mem0.nScratchFree <= (u32)sqlite3GlobalConfig.nScratch ); sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_USED, -1); sqlite3_mutex_leave(mem0.mutex); }else{ /* Release memory back to the heap */ assert( sqlite3MemdebugHasType(p, MEMTYPE_SCRATCH) ); assert( sqlite3MemdebugNoType(p, ~MEMTYPE_SCRATCH) ); sqlite3MemdebugSetType(p, MEMTYPE_HEAP); if( sqlite3GlobalConfig.bMemstat ){ int iSize = sqlite3MallocSize(p); sqlite3_mutex_enter(mem0.mutex); sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_OVERFLOW, -iSize); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, -iSize); sqlite3StatusAdd(SQLITE_STATUS_MALLOC_COUNT, -1); sqlite3GlobalConfig.m.xFree(p); sqlite3_mutex_leave(mem0.mutex); }else{ sqlite3GlobalConfig.m.xFree(p); } } } }
/* ** Free memory previously obtained from sqlite3Malloc(). */ void sqlite3_free(void *p){ if( p==0 ) return; if( sqlite3GlobalConfig.bMemstat ){ sqlite3_mutex_enter(mem0.mutex); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, -sqlite3MallocSize(p)); sqlite3GlobalConfig.m.xFree(p); sqlite3_mutex_leave(mem0.mutex); }else{ sqlite3GlobalConfig.m.xFree(p); } }
/* ** Free an allocated buffer obtained from pcache1Alloc(). */ static void pcache1Free(void *p){ assert( sqlite3_mutex_held(pcache1.mutex) ); if( p==0 ) return; if( p>=pcache1.pStart && p<pcache1.pEnd ){ PgFreeslot *pSlot; sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, -1); pSlot = (PgFreeslot*)p; pSlot->pNext = pcache1.pFree; pcache1.pFree = pSlot; pcache1.nFreeSlot++; assert( pcache1.nFreeSlot<=pcache1.nSlot ); }else{ int iSize; assert( sqlite3MemdebugHasType(p, MEMTYPE_PCACHE) ); sqlite3MemdebugSetType(p, MEMTYPE_HEAP); iSize = sqlite3MallocSize(p); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, -iSize); sqlite3_free(p); } }
void sqlite3ScratchFree(void *p){ if( p ){ if( sqlite3GlobalConfig.pScratch==0 || p<sqlite3GlobalConfig.pScratch || p>=(void*)mem0.aScratchFree ){ assert( sqlite3MemdebugHasType(p, MEMTYPE_SCRATCH) ); sqlite3MemdebugSetType(p, MEMTYPE_HEAP); if( sqlite3GlobalConfig.bMemstat ){ int iSize = sqlite3MallocSize(p); sqlite3_mutex_enter(mem0.mutex); sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_OVERFLOW, -iSize); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, -iSize); sqlite3GlobalConfig.m.xFree(p); sqlite3_mutex_leave(mem0.mutex); }else{ sqlite3GlobalConfig.m.xFree(p); } }else{ int i; i = (int)((u8*)p - (u8*)sqlite3GlobalConfig.pScratch); i /= sqlite3GlobalConfig.szScratch; assert( i>=0 && i<sqlite3GlobalConfig.nScratch ); sqlite3_mutex_enter(mem0.mutex); assert( mem0.nScratchFree<(u32)sqlite3GlobalConfig.nScratch ); mem0.aScratchFree[mem0.nScratchFree++] = i; sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_USED, -1); sqlite3_mutex_leave(mem0.mutex); #if SQLITE_THREADSAFE==0 && !defined(NDEBUG) /* Verify that no more than two scratch allocation per thread ** is outstanding at one time. (This is only checked in the ** single-threaded case since checking in the multi-threaded case ** would be much more complicated.) */ assert( scratchAllocOut>=1 && scratchAllocOut<=2 ); scratchAllocOut = 0; #endif } } }
/* ** Allocate memory that is to be used and released right away. ** This routine is similar to alloca() in that it is not intended ** for situations where the memory might be held long-term. This ** routine is intended to get memory to old large transient data ** structures that would not normally fit on the stack of an ** embedded processor. */ void *sqlite3ScratchMalloc(int n){ void *p; assert( n>0 ); sqlite3_mutex_enter(mem0.mutex); if( mem0.nScratchFree && sqlite3GlobalConfig.szScratch>=n ){ p = mem0.pScratchFree; mem0.pScratchFree = mem0.pScratchFree->pNext; mem0.nScratchFree--; sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_USED, 1); sqlite3StatusSet(SQLITE_STATUS_SCRATCH_SIZE, n); sqlite3_mutex_leave(mem0.mutex); }else{ if( sqlite3GlobalConfig.bMemstat ){ sqlite3StatusSet(SQLITE_STATUS_SCRATCH_SIZE, n); n = mallocWithAlarm(n, &p); if( p ) sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_OVERFLOW, n); sqlite3_mutex_leave(mem0.mutex); }else{ sqlite3_mutex_leave(mem0.mutex); p = sqlite3GlobalConfig.m.xMalloc(n); } sqlite3MemdebugSetType(p, MEMTYPE_SCRATCH); } assert( sqlite3_mutex_notheld(mem0.mutex) ); #if SQLITE_THREADSAFE==0 && !defined(NDEBUG) /* Verify that no more than two scratch allocations per thread ** are outstanding at one time. (This is only checked in the ** single-threaded case since checking in the multi-threaded case ** would be much more complicated.) */ assert( scratchAllocOut<=1 ); if( p ) scratchAllocOut++; #endif return p; }
void sqlite3ScratchFree(void *p){ if( p ){ #if SQLITE_THREADSAFE==0 && !defined(NDEBUG) assert( scratchAllocOut>=1 && scratchAllocOut<=2 ); scratchAllocOut--; #endif if( p>=sqlite3GlobalConfig.pScratch && p<mem0.pScratchEnd ){ ScratchFreeslot *pSlot; pSlot = (ScratchFreeslot*)p; sqlite3_mutex_enter(mem0.mutex); pSlot->pNext = mem0.pScratchFree; mem0.pScratchFree = pSlot; mem0.nScratchFree++; assert( mem0.nScratchFree <= (u32)sqlite3GlobalConfig.nScratch ); sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_USED, -1); sqlite3_mutex_leave(mem0.mutex); }else{ assert( sqlite3MemdebugHasType(p, MEMTYPE_SCRATCH) ); assert( sqlite3MemdebugNoType(p, ~MEMTYPE_SCRATCH) ); sqlite3MemdebugSetType(p, MEMTYPE_HEAP); if( sqlite3GlobalConfig.bMemstat ){ int iSize = sqlite3MallocSize(p); sqlite3_mutex_enter(mem0.mutex); sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_OVERFLOW, -iSize); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, -iSize); sqlite3StatusAdd(SQLITE_STATUS_MALLOC_COUNT, -1); sqlite3GlobalConfig.m.xFree(p); sqlite3_mutex_leave(mem0.mutex); }else{ sqlite3GlobalConfig.m.xFree(p); } } } }
void *sqlite3PageMalloc(int n){ void *p; assert( n>0 ); assert( (n & (n-1))==0 ); assert( n>=512 && n<=32768 ); if( sqlite3GlobalConfig.szPage<n ){ goto page_overflow; }else{ sqlite3_mutex_enter(mem0.mutex); if( mem0.nPageFree==0 ){ sqlite3_mutex_leave(mem0.mutex); goto page_overflow; }else{ int i; i = mem0.aPageFree[--mem0.nPageFree]; sqlite3_mutex_leave(mem0.mutex); i *= sqlite3GlobalConfig.szPage; sqlite3StatusSet(SQLITE_STATUS_PAGECACHE_SIZE, n); sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, 1); p = (void*)&((char*)sqlite3GlobalConfig.pPage)[i]; } } return p; page_overflow: if( sqlite3GlobalConfig.bMemstat ){ sqlite3_mutex_enter(mem0.mutex); sqlite3StatusSet(SQLITE_STATUS_PAGECACHE_SIZE, n); n = mallocWithAlarm(n, &p); if( p ) sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, n); sqlite3_mutex_leave(mem0.mutex); }else{ p = sqlite3GlobalConfig.m.xMalloc(n); } return p; }
/* ** Change the size of an existing memory allocation */ void *sqlite3Realloc(void *pOld, int nBytes){ int nOld, nNew, nDiff; void *pNew; if( pOld==0 ){ return sqlite3Malloc(nBytes); /* IMP: R-28354-25769 */ } if( nBytes<=0 ){ sqlite3_free(pOld); /* IMP: R-31593-10574 */ return 0; } if( nBytes>=0x7fffff00 ){ /* The 0x7ffff00 limit term is explained in comments on sqlite3Malloc() */ return 0; } nOld = sqlite3MallocSize(pOld); /* IMPLEMENTATION-OF: R-46199-30249 SQLite guarantees that the second ** argument to xRealloc is always a value returned by a prior call to ** xRoundup. */ nNew = sqlite3GlobalConfig.m.xRoundup(nBytes); if( nOld==nNew ){ pNew = pOld; }else if( sqlite3GlobalConfig.bMemstat ){ sqlite3_mutex_enter(mem0.mutex); sqlite3StatusSet(SQLITE_STATUS_MALLOC_SIZE, nBytes); nDiff = nNew - nOld; if( sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED) >= mem0.alarmThreshold-nDiff ){ sqlite3MallocAlarm(nDiff); } assert( sqlite3MemdebugHasType(pOld, MEMTYPE_HEAP) ); assert( sqlite3MemdebugNoType(pOld, ~MEMTYPE_HEAP) ); pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); if( pNew==0 && mem0.alarmCallback ){ sqlite3MallocAlarm(nBytes); pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); } if( pNew ){ nNew = sqlite3MallocSize(pNew); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, nNew-nOld); } sqlite3_mutex_leave(mem0.mutex); }else{ pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); } assert( EIGHT_BYTE_ALIGNMENT(pNew) ); /* IMP: R-04675-44850 */ return pNew; }
void *sqlite3Realloc(void *pOld, int nBytes){ int nOld, nNew; void *pNew; if( pOld==0 ){ return sqlite3Malloc(nBytes); } if( nBytes<=0 ){ sqlite3_free(pOld); return 0; } if( nBytes>=0x7fffff00 ){ return 0; } nOld = sqlite3MallocSize(pOld); nNew = sqlite3GlobalConfig.m.xRoundup(nBytes); if( nOld==nNew ){ pNew = pOld; }else if( sqlite3GlobalConfig.bMemstat ){ sqlite3_mutex_enter(mem0.mutex); sqlite3StatusSet(SQLITE_STATUS_MALLOC_SIZE, nBytes); if( sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED)+nNew-nOld >= mem0.alarmThreshold ){ sqlite3MallocAlarm(nNew-nOld); } assert( sqlite3MemdebugHasType(pOld, MEMTYPE_HEAP) ); assert( sqlite3MemdebugNoType(pOld, ~MEMTYPE_HEAP) ); pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); if( pNew==0 && mem0.alarmCallback ){ sqlite3MallocAlarm(nBytes); pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); } if( pNew ){ nNew = sqlite3MallocSize(pNew); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, nNew-nOld); } sqlite3_mutex_leave(mem0.mutex); }else{ pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); } assert( EIGHT_BYTE_ALIGNMENT(pNew) ); return pNew; }
/* ** Change the size of an existing memory allocation */ void *sqlite3Realloc(void *pOld, int nBytes){ int nOld, nNew; void *pNew; if( pOld==0 ){ return sqlite3Malloc(nBytes); } if( nBytes<=0 ){ sqlite3_free(pOld); return 0; } if( nBytes>=0x7fffff00 ){ /* The 0x7ffff00 limit term is explained in comments on sqlite3Malloc() */ return 0; } nOld = sqlite3MallocSize(pOld); nNew = sqlite3GlobalConfig.m.xRoundup(nBytes); if( nOld==nNew ){ pNew = pOld; }else if( sqlite3GlobalConfig.bMemstat ){ sqlite3_mutex_enter(mem0.mutex); sqlite3StatusSet(SQLITE_STATUS_MALLOC_SIZE, nBytes); if( sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED)+nNew-nOld >= mem0.alarmThreshold ){ sqlite3MallocAlarm(nNew-nOld); } pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); if( pNew==0 && mem0.alarmCallback ){ sqlite3MallocAlarm(nBytes); pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); } if( pNew ){ nNew = sqlite3MallocSize(pNew); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, nNew-nOld); } sqlite3_mutex_leave(mem0.mutex); }else{ pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew); } return pNew; }
/* ** Do a memory allocation with statistics and alarms. Assume the ** lock is already held. */ static int mallocWithAlarm(int n, void **pp){ int nFull; void *p; assert( sqlite3_mutex_held(mem0.mutex) ); nFull = sqlite3GlobalConfig.m.xRoundup(n); sqlite3StatusSet(SQLITE_STATUS_MALLOC_SIZE, n); if( mem0.alarmCallback!=0 ){ int nUsed = sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED); if( nUsed+nFull >= mem0.alarmThreshold ){ sqlite3MallocAlarm(nFull); } } p = sqlite3GlobalConfig.m.xMalloc(nFull); if( p==0 && mem0.alarmCallback ){ sqlite3MallocAlarm(nFull); p = sqlite3GlobalConfig.m.xMalloc(nFull); } if( p ){ nFull = sqlite3MallocSize(p); sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, nFull); } *pp = p; return nFull; }