blob: 4c35e849f2504a73584bf0385f28cbc0daa9a966 [file] [log] [blame]
#include <stdio.h>
#include <assert.h>
#include <string.h>
#define ArraySize(x) ((int)(sizeof(x) / sizeof((x)[0])))
#define MIN(x,y) ((x)<(y) ? (x) : (y))
typedef unsigned int u32;
typedef unsigned char u8;
typedef long long int i64;
typedef unsigned long long int u64;
#if defined(__GLIBC__) && defined(LSM_DEBUG_MEM)
extern int backtrace(void**,int);
extern void backtrace_symbols_fd(void*const*,int,int);
# define TM_BACKTRACE 12
#else
# define backtrace(A,B) 1
# define backtrace_symbols_fd(A,B,C)
#endif
typedef struct TmBlockHdr TmBlockHdr;
typedef struct TmAgg TmAgg;
typedef struct TmGlobal TmGlobal;
struct TmGlobal {
/* Linked list of all currently outstanding allocations. And a table of
** all allocations, past and present, indexed by backtrace() info. */
TmBlockHdr *pFirst;
#ifdef TM_BACKTRACE
TmAgg *aHash[10000];
#endif
/* Underlying malloc/realloc/free functions */
void *(*xMalloc)(int); /* underlying malloc(3) function */
void *(*xRealloc)(void *, int); /* underlying realloc(3) function */
void (*xFree)(void *); /* underlying free(3) function */
/* Mutex to protect pFirst and aHash */
void (*xEnterMutex)(TmGlobal*); /* Call this to enter the mutex */
void (*xLeaveMutex)(TmGlobal*); /* Call this to leave mutex */
void (*xDelMutex)(TmGlobal*); /* Call this to delete mutex */
void *pMutex; /* Mutex handle */
void *(*xSaveMalloc)(void *, size_t);
void *(*xSaveRealloc)(void *, void *, size_t);
void (*xSaveFree)(void *, void *);
/* OOM injection scheduling. If nCountdown is greater than zero when a
** malloc attempt is made, it is decremented. If this means nCountdown
** transitions from 1 to 0, then the allocation fails. If bPersist is true
** when this happens, nCountdown is then incremented back to 1 (so that the
** next attempt fails too).
*/
int nCountdown;
int bPersist;
int bEnable;
void (*xHook)(void *);
void *pHookCtx;
};
struct TmBlockHdr {
TmBlockHdr *pNext;
TmBlockHdr *pPrev;
int nByte;
#ifdef TM_BACKTRACE
TmAgg *pAgg;
#endif
u32 iForeGuard;
};
#ifdef TM_BACKTRACE
struct TmAgg {
int nAlloc; /* Number of allocations at this path */
int nByte; /* Total number of bytes allocated */
int nOutAlloc; /* Number of outstanding allocations */
int nOutByte; /* Number of outstanding bytes */
void *aFrame[TM_BACKTRACE]; /* backtrace() output */
TmAgg *pNext; /* Next object in hash-table collision */
};
#endif
#define FOREGUARD 0x80F5E153
#define REARGUARD 0xE4676B53
static const u32 rearguard = REARGUARD;
#define ROUND8(x) (((x)+7)&~7)
#define BLOCK_HDR_SIZE (ROUND8( sizeof(TmBlockHdr) ))
static void lsmtest_oom_error(void){
static int nErr = 0;
nErr++;
}
static void tmEnterMutex(TmGlobal *pTm){
pTm->xEnterMutex(pTm);
}
static void tmLeaveMutex(TmGlobal *pTm){
pTm->xLeaveMutex(pTm);
}
static void *tmMalloc(TmGlobal *pTm, int nByte){
TmBlockHdr *pNew; /* New allocation header block */
u8 *pUser; /* Return value */
int nReq; /* Total number of bytes requested */
assert( sizeof(rearguard)==4 );
nReq = BLOCK_HDR_SIZE + nByte + 4;
pNew = (TmBlockHdr *)pTm->xMalloc(nReq);
memset(pNew, 0, sizeof(TmBlockHdr));
tmEnterMutex(pTm);
assert( pTm->nCountdown>=0 );
assert( pTm->bPersist==0 || pTm->bPersist==1 );
if( pTm->bEnable && pTm->nCountdown==1 ){
/* Simulate an OOM error. */
lsmtest_oom_error();
pTm->xFree(pNew);
pTm->nCountdown = pTm->bPersist;
if( pTm->xHook ) pTm->xHook(pTm->pHookCtx);
pUser = 0;
}else{
if( pTm->bEnable && pTm->nCountdown ) pTm->nCountdown--;
pNew->iForeGuard = FOREGUARD;
pNew->nByte = nByte;
pNew->pNext = pTm->pFirst;
if( pTm->pFirst ){
pTm->pFirst->pPrev = pNew;
}
pTm->pFirst = pNew;
pUser = &((u8 *)pNew)[BLOCK_HDR_SIZE];
memset(pUser, 0x56, nByte);
memcpy(&pUser[nByte], &rearguard, 4);
#ifdef TM_BACKTRACE
{
TmAgg *pAgg;
int i;
u32 iHash = 0;
void *aFrame[TM_BACKTRACE];
memset(aFrame, 0, sizeof(aFrame));
backtrace(aFrame, TM_BACKTRACE);
for(i=0; i<ArraySize(aFrame); i++){
iHash += (u64)(aFrame[i]) + (iHash<<3);
}
iHash = iHash % ArraySize(pTm->aHash);
for(pAgg=pTm->aHash[iHash]; pAgg; pAgg=pAgg->pNext){
if( memcmp(pAgg->aFrame, aFrame, sizeof(aFrame))==0 ) break;
}
if( !pAgg ){
pAgg = (TmAgg *)pTm->xMalloc(sizeof(TmAgg));
memset(pAgg, 0, sizeof(TmAgg));
memcpy(pAgg->aFrame, aFrame, sizeof(aFrame));
pAgg->pNext = pTm->aHash[iHash];
pTm->aHash[iHash] = pAgg;
}
pAgg->nAlloc++;
pAgg->nByte += nByte;
pAgg->nOutAlloc++;
pAgg->nOutByte += nByte;
pNew->pAgg = pAgg;
}
#endif
}
tmLeaveMutex(pTm);
return pUser;
}
static void tmFree(TmGlobal *pTm, void *p){
if( p ){
TmBlockHdr *pHdr;
u8 *pUser = (u8 *)p;
tmEnterMutex(pTm);
pHdr = (TmBlockHdr *)(pUser - BLOCK_HDR_SIZE);
assert( pHdr->iForeGuard==FOREGUARD );
assert( 0==memcmp(&pUser[pHdr->nByte], &rearguard, 4) );
if( pHdr->pPrev ){
assert( pHdr->pPrev->pNext==pHdr );
pHdr->pPrev->pNext = pHdr->pNext;
}else{
assert( pHdr==pTm->pFirst );
pTm->pFirst = pHdr->pNext;
}
if( pHdr->pNext ){
assert( pHdr->pNext->pPrev==pHdr );
pHdr->pNext->pPrev = pHdr->pPrev;
}
#ifdef TM_BACKTRACE
pHdr->pAgg->nOutAlloc--;
pHdr->pAgg->nOutByte -= pHdr->nByte;
#endif
tmLeaveMutex(pTm);
memset(pUser, 0x58, pHdr->nByte);
memset(pHdr, 0x57, sizeof(TmBlockHdr));
pTm->xFree(pHdr);
}
}
static void *tmRealloc(TmGlobal *pTm, void *p, int nByte){
void *pNew;
pNew = tmMalloc(pTm, nByte);
if( pNew && p ){
TmBlockHdr *pHdr;
u8 *pUser = (u8 *)p;
pHdr = (TmBlockHdr *)(pUser - BLOCK_HDR_SIZE);
memcpy(pNew, p, MIN(nByte, pHdr->nByte));
tmFree(pTm, p);
}
return pNew;
}
static void tmMallocOom(
TmGlobal *pTm,
int nCountdown,
int bPersist,
void (*xHook)(void *),
void *pHookCtx
){
assert( nCountdown>=0 );
assert( bPersist==0 || bPersist==1 );
pTm->nCountdown = nCountdown;
pTm->bPersist = bPersist;
pTm->xHook = xHook;
pTm->pHookCtx = pHookCtx;
pTm->bEnable = 1;
}
static void tmMallocOomEnable(
TmGlobal *pTm,
int bEnable
){
pTm->bEnable = bEnable;
}
static void tmMallocCheck(
TmGlobal *pTm,
int *pnLeakAlloc,
int *pnLeakByte,
FILE *pFile
){
TmBlockHdr *pHdr;
int nLeak = 0;
int nByte = 0;
if( pTm==0 ) return;
for(pHdr=pTm->pFirst; pHdr; pHdr=pHdr->pNext){
nLeak++;
nByte += pHdr->nByte;
}
if( pnLeakAlloc ) *pnLeakAlloc = nLeak;
if( pnLeakByte ) *pnLeakByte = nByte;
#ifdef TM_BACKTRACE
if( pFile ){
int i;
fprintf(pFile, "LEAKS\n");
for(i=0; i<ArraySize(pTm->aHash); i++){
TmAgg *pAgg;
for(pAgg=pTm->aHash[i]; pAgg; pAgg=pAgg->pNext){
if( pAgg->nOutAlloc ){
int j;
fprintf(pFile, "%d %d ", pAgg->nOutByte, pAgg->nOutAlloc);
for(j=0; j<TM_BACKTRACE; j++){
fprintf(pFile, "%p ", pAgg->aFrame[j]);
}
fprintf(pFile, "\n");
}
}
}
fprintf(pFile, "\nALLOCATIONS\n");
for(i=0; i<ArraySize(pTm->aHash); i++){
TmAgg *pAgg;
for(pAgg=pTm->aHash[i]; pAgg; pAgg=pAgg->pNext){
int j;
fprintf(pFile, "%d %d ", pAgg->nByte, pAgg->nAlloc);
for(j=0; j<TM_BACKTRACE; j++) fprintf(pFile, "%p ", pAgg->aFrame[j]);
fprintf(pFile, "\n");
}
}
}
#else
(void)pFile;
#endif
}
#include "lsm.h"
#include "stdlib.h"
typedef struct LsmMutex LsmMutex;
struct LsmMutex {
lsm_env *pEnv;
lsm_mutex *pMutex;
};
static void tmLsmMutexEnter(TmGlobal *pTm){
LsmMutex *p = (LsmMutex *)pTm->pMutex;
p->pEnv->xMutexEnter(p->pMutex);
}
static void tmLsmMutexLeave(TmGlobal *pTm){
LsmMutex *p = (LsmMutex *)(pTm->pMutex);
p->pEnv->xMutexLeave(p->pMutex);
}
static void tmLsmMutexDel(TmGlobal *pTm){
LsmMutex *p = (LsmMutex *)pTm->pMutex;
pTm->xFree(p);
}
static void *tmLsmMalloc(int n){ return malloc(n); }
static void tmLsmFree(void *ptr){ free(ptr); }
static void *tmLsmRealloc(void *ptr, int n){ return realloc(ptr, n); }
static void *tmLsmEnvMalloc(lsm_env *p, size_t n){
return tmMalloc((TmGlobal *)(p->pMemCtx), n);
}
static void tmLsmEnvFree(lsm_env *p, void *ptr){
tmFree((TmGlobal *)(p->pMemCtx), ptr);
}
static void *tmLsmEnvRealloc(lsm_env *p, void *ptr, size_t n){
return tmRealloc((TmGlobal *)(p->pMemCtx), ptr, n);
}
void testMallocInstall(lsm_env *pEnv){
TmGlobal *pGlobal;
LsmMutex *pMutex;
assert( pEnv->pMemCtx==0 );
/* Allocate and populate a TmGlobal structure. */
pGlobal = (TmGlobal *)tmLsmMalloc(sizeof(TmGlobal));
memset(pGlobal, 0, sizeof(TmGlobal));
pGlobal->xMalloc = tmLsmMalloc;
pGlobal->xRealloc = tmLsmRealloc;
pGlobal->xFree = tmLsmFree;
pMutex = (LsmMutex *)pGlobal->xMalloc(sizeof(LsmMutex));
pMutex->pEnv = pEnv;
pEnv->xMutexStatic(pEnv, LSM_MUTEX_HEAP, &pMutex->pMutex);
pGlobal->xEnterMutex = tmLsmMutexEnter;
pGlobal->xLeaveMutex = tmLsmMutexLeave;
pGlobal->xDelMutex = tmLsmMutexDel;
pGlobal->pMutex = (void *)pMutex;
pGlobal->xSaveMalloc = pEnv->xMalloc;
pGlobal->xSaveRealloc = pEnv->xRealloc;
pGlobal->xSaveFree = pEnv->xFree;
/* Set up pEnv to the use the new TmGlobal */
pEnv->pMemCtx = (void *)pGlobal;
pEnv->xMalloc = tmLsmEnvMalloc;
pEnv->xRealloc = tmLsmEnvRealloc;
pEnv->xFree = tmLsmEnvFree;
}
void testMallocUninstall(lsm_env *pEnv){
TmGlobal *p = (TmGlobal *)pEnv->pMemCtx;
pEnv->pMemCtx = 0;
if( p ){
pEnv->xMalloc = p->xSaveMalloc;
pEnv->xRealloc = p->xSaveRealloc;
pEnv->xFree = p->xSaveFree;
p->xDelMutex(p);
tmLsmFree(p);
}
}
void testMallocCheck(
lsm_env *pEnv,
int *pnLeakAlloc,
int *pnLeakByte,
FILE *pFile
){
if( pEnv->pMemCtx==0 ){
*pnLeakAlloc = 0;
*pnLeakByte = 0;
}else{
tmMallocCheck((TmGlobal *)(pEnv->pMemCtx), pnLeakAlloc, pnLeakByte, pFile);
}
}
void testMallocOom(
lsm_env *pEnv,
int nCountdown,
int bPersist,
void (*xHook)(void *),
void *pHookCtx
){
TmGlobal *pTm = (TmGlobal *)(pEnv->pMemCtx);
tmMallocOom(pTm, nCountdown, bPersist, xHook, pHookCtx);
}
void testMallocOomEnable(lsm_env *pEnv, int bEnable){
TmGlobal *pTm = (TmGlobal *)(pEnv->pMemCtx);
tmMallocOomEnable(pTm, bEnable);
}