boinc/client/win/HeapCheck/HeapCheck.c

957 lines
24 KiB
C
Executable File

/***************************************************************************
* HeapCheck - a heap debugging library
* Copyright (C) 2001 Thanassis Tsiodras (ttsiod@softlab.ntua.gr)
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
**************************************************************************
*
* HeapCheck 1.2
* =============
*
* A simple debugging allocator, designed to help heap bug-hunting.
* Like most debugging heap allocators, it helps you find memory leaks.
* It also helps you where others can't: in catching invalid accesses.
* It uses the paging system to create inaccessible pages by the side
* of your normal allocations. This way, accesses outside the heap-
* allocated space cause an exception (even READ accesses). This is much
* better than heap debugging done with:
*
* 1. Visual C++ 6.0 Runtime Heap Debugging:
* This only checks for heap corruption (i.e. only WRITINGS outside
* the allocations) and even then, it only catches writings in the
* NO_MANS_LAND_SIZE (default:4 bytes) on either side of the blocks.
* The detection of these errors is done whenever the user (or the system)
* calls _CrtCheckMemory(). HeapCheck catches READ accesses as well,
* at the EXACT place they are made, and in a much larger
* block (a page in i386 systems is 4096 bytes).
*
* 2. BoundsChecker:
* This is a very good debugging tool, capable of catching almost
* every bug. However, in order to perform all these checks, a lot
* of CPU cycles are used, especially in instrumentation mode and
* maximum memory checking (some programs won't work correctly when
* they run so slowly, e.g. protocol stacks). HeapCheck catches only
* heap-related errors, but it uses the paging hardware to do the
* checking. The net result is that the HeapCheck debug versions of
* programs run at almost the same speed as normal debug versions.
*
* I hope (but can't guarantee) that it will help you in your heap
* bug hunting. It has definitely helped me with my projects.
* Many thanks for the original idea go to the creator of UNIX's
* Electric Fence, Bruce Perens. Oh, and make sure you use the
* correct (Win2000) versions of the debugging libraries. I used:
*
* dbghelp.dll : 5.0.2195.1
* imagehlp.dll : 5.0.2195.1
*
* Maybe SymGetLineFromAddr works with other combinations, but I used
* these successfully under both NT 4.0sp6 and Win2000.
*
* Happy coding!
* Thanassis Tsiodras
* ttsiod@softlab.ntua.gr
*
**************************************************************************
*/
/*
* Remember, all of this code gets called only in _DEBUG builds!
* Check swaps.h to see why...
*/
#ifdef _DEBUG
#include <windows.h>
#include <crtdbg.h>
#include <imagehlp.h>
/* Include prototypes for HeapCheck functions */
#include "HeapCheckPrototypes.h"
/*
* It is possible to write code that bypasses the allocation mechanisms of
* the library, and allocates from the standard VC-heap. An example inside
* the runtime library is the use of an enhanced 'new' operator in
* iostrini.cpp (line 21) and cerrinit.cpp (line 21) where _new_crt is used.
* _new_crt maps through a #define to a 'new' operator that takes extra
* parameters. HeapCheck can't catch this call, so when the time comes for
* the deletion of these blocks, the library's delete operator doesn't find
* them in it's tables. It is capable though to understand that these are
* VC-heap blocks, through the use of _CrtIsValidHeapPointer.
*
* If you #define NO_VC_HEAP_ERRS, the library won't complain for such
* situations. This is the default, but if you use inside your code direct
* calls to _malloc_dbg, _calloc_dbg, etc, you should disable this.
*/
#define NO_VC_HEAP_ERRS
/*
* Modify this for Alpha, PowerPC, etc. It is the page size used by
* the virtual memory hardware. For Intel architectures, this is 4096
* bytes. For others, place a breakpoint in the call to HeapCheckStartup's
* GetSystemInfo, and read the 'dwPageSize' field of the 'si' variable.
*/
#define PAGE_SIZE 4096
/*
* Total concurrent allocations possible. If your program needs more,
* you'll get an assertion telling you to increase this.
*/
#define MAX_ALLOCATIONS 16384
/*
* Total heap available to the application. If your program needs more,
* you'll get an assertion telling you to increase this.
*/
#define MAX_ALLOCATABLE_BLOCK 8*1048576
/*
* Max depth of call stack looked up when our functions are called
*/
#define MAX_STACK_DEPTH 30
/*
* Define PRINT_NUMERIC_EIP to get stack traces that boldly go
* where no imagehlp.dll has gone before... Hope you have SoftIce...
*/
//#define PRINT_NUMERIC_EIP
/*
* Variables
*/
static DWORD dwAllocationGranularity = 0;
static PCHAR pMemoryBase;
static DWORD dwTotalPages;
static DWORD dwFreePages;
static struct tag_allocations {
DWORD isFree;
PCHAR pData;
DWORD dwPages;
DWORD dwLength;
DWORD EIPs[MAX_STACK_DEPTH];
} allocations[MAX_ALLOCATIONS];
static BYTE pagesState[MAX_ALLOCATABLE_BLOCK/PAGE_SIZE];
static DWORD dwTotalPeakMemory = 0, dwTotalAllocated = 0;
static CRITICAL_SECTION section;
/*
* Function prototypes.
*/
/*
* Weird hack, in order to support 5 and 6 argument passing to _CrtDbgReport.
* Unforunately, with VC 5.0/6.0, RPT macros go up until _RPT4!
*/
#ifndef _RPT5
#define _RPT5(rptno, msg, arg1, arg2, arg3, arg4, arg5) \
do { if ((1 == _CrtDbgReport(rptno, NULL, 0, NULL, msg, arg1, arg2, arg3, arg4, arg5))) \
_CrtDbgBreak(); } while (0)
#endif
#ifndef _RPT6
#define _RPT6(rptno, msg, arg1, arg2, arg3, arg4, arg5, arg6) \
do { if ((1 == _CrtDbgReport(rptno, NULL, 0, NULL, msg, arg1, arg2, arg3, arg4, arg5, arg6))) \
_CrtDbgBreak(); } while (0)
#endif
static void HeapCheckStartup(void);
static void HeapCheckShutDown(void);
/*
* Simple allocator of pages that never frees.
*/
static void *
FindConsecutiveFreePagesSimple(DWORD dwPages)
{
return pMemoryBase + PAGE_SIZE*(dwTotalPages - dwFreePages);
}
/*
* Page allocator that searches for free pages.
* Can be improved with better algorithms, but it's good enough for
* most projects...
*/
static void *
FindConsecutiveFreePages(DWORD dwPages)
{
DWORD i;
PVOID pv;
for(i=0; i<sizeof(pagesState); i++) {
if (!pagesState[i]) {
// Found a free page. Make sure there's enough free pages after it...
PVOID test;
// If you land here after an assertion, stop debugging
// and increase MAX_ALLOCATABLE_BLOCK
_ASSERTE ((i + dwPages - 1) < sizeof(pagesState));
// Search for used-up page in our searching range...
test = memchr(&pagesState[i], 1, dwPages);
if (!test) // We found enough pages.
break;
}
}
// If you land here after an assertion 'Retry', stop debugging
// and increase MAX_ALLOCATABLE_BLOCK
_ASSERTE(i<sizeof(pagesState));
// Set 1 to these pages's slots to reflect NON-FREE state
FillMemory(&pagesState[i], dwPages, 1);
pv = pMemoryBase + i*PAGE_SIZE;
return pv;
}
/*
* Utility function for VC-heap blocks.
* Should be using binary search, but hey...I'm lazy.
*
* NOT TESTED YET - Who cares about VC-blocks?
*/
static DWORD
GetSize(PVOID pData)
{
// Search for block length....
DWORD dwTest;
for(dwTest=0; dwTest<MAX_ALLOCATABLE_BLOCK; dwTest++)
if (_CrtIsMemoryBlock(pData, dwTest, NULL, NULL, NULL))
break;
if (dwTest == MAX_ALLOCATABLE_BLOCK)
return -1;
else
return dwTest;
}
static void FillCallStack(
DWORD EIPs[])
{
DWORD LevelOneFrame;
DWORD dwFrame = 0;
__asm {
push eax
push ebx
mov eax, [ebp] // return to the frame of the caller
mov LevelOneFrame, eax
pop ebx
pop eax
}
while(1) {
DWORD _eip;
if (IsBadReadPtr((VOID*)LevelOneFrame, 8))
break;
if (LevelOneFrame & 3)
break;
_eip = ((PULONG) LevelOneFrame)[1];
if (!_eip)
break;
// If you end up in this assertion, stop debugging and re-compile
// with an increased value for the MAX_STACK_DEPTH constant.
_ASSERTE(dwFrame < MAX_STACK_DEPTH);
EIPs[dwFrame++] = _eip;
LevelOneFrame = ((PULONG) LevelOneFrame)[0];
}
EIPs[dwFrame] = 0;
}
static void PrintCaller()
{
DWORD LevelOneFrame;
IMAGEHLP_LINE dbgLine;
DWORD dwTemp;
HANDLE hProcess = GetCurrentProcess();
__asm {
push eax
push ebx
mov eax, [ebp] // return to the frame of the caller
mov LevelOneFrame, eax
pop ebx
pop eax
}
while(1) {
DWORD _eip;
if (IsBadReadPtr((VOID*)LevelOneFrame, 8))
break;
if (LevelOneFrame & 3)
break;
_eip = ((PULONG) LevelOneFrame)[1];
if (!_eip)
break;
ZeroMemory(&dbgLine, sizeof(IMAGEHLP_LINE));
dbgLine.SizeOfStruct = sizeof(IMAGEHLP_LINE);
if(!SymGetLineFromAddr(hProcess, _eip, &dwTemp, &dbgLine)) {
//_RPT1(_CRT_WARN, "Called from EIP = %x\n", _eip);
break;
} else {
_RPT3(
_CRT_WARN,
"\tCalled from line %d(+%d bytes) of %s\n",
dbgLine.LineNumber,
dwTemp,
dbgLine.FileName);
}
LevelOneFrame = ((PULONG) LevelOneFrame)[0];
}
}
/*
* Post-allocation fence versions of malloc, calloc, realloc and free
*/
void *
HeapCheckPostFenceMalloc(
size_t blockSize)
{
DWORD dwSlot;
DWORD dwPages;
DWORD dwOldProtection;
PCHAR data = NULL;
BOOL bResult = FALSE;
LPVOID lpvResult = NULL;
static DWORD dwFirstTime = 1;
if (dwFirstTime) {
dwFirstTime = 0;
HeapCheckStartup();
}
if (!blockSize)
return NULL;
EnterCriticalSection(&section);
for(dwSlot = 0; dwSlot<MAX_ALLOCATIONS; dwSlot++)
if (allocations[dwSlot].isFree) {
allocations[dwSlot].isFree = 0;
break;
}
// If you end up in this assertion, stop debugging and re-compile
// with an increased value for the MAX_ALLOCATIONS constant.
_ASSERTE(dwSlot != MAX_ALLOCATIONS);
// Calculate number of requires pages
dwPages = ((blockSize - 1) / PAGE_SIZE) + 2;
//_RPT2(_CRT_WARN, "Requested %7d bytes, granted %2d pages\n", blockSize, dwPages);
// Make sure we have enough room
if (dwFreePages < dwPages) {
_RPT1(
_CRT_WARN,
"Your application requires more free memory...\n"
"Increase MAX_ALLOCATABLE_BLOCK in %s.", __FILE__);
_ASSERTE(dwFreePages >= dwPages);
}
data = (char*)FindConsecutiveFreePages(dwPages);
// OK, now make data-pages available...
lpvResult = VirtualAlloc(
(LPVOID) data,
(dwPages-1)*PAGE_SIZE,
MEM_COMMIT,
PAGE_READWRITE);
_ASSERTE(lpvResult != NULL );
VirtualProtect(
(LPVOID) data,
(dwPages-1)*PAGE_SIZE,
PAGE_READWRITE,
&dwOldProtection);
// and fence-page untouchable!
bResult = VirtualFree(
(LPVOID) (data + (dwPages-1)*PAGE_SIZE),
PAGE_SIZE,
MEM_DECOMMIT);
_ASSERTE(bResult == TRUE);
data += (PAGE_SIZE - (blockSize % PAGE_SIZE)) % PAGE_SIZE;
dwFreePages -= dwPages;
allocations[dwSlot].pData = data;
allocations[dwSlot].dwPages = dwPages;
allocations[dwSlot].dwLength = blockSize;
FillCallStack(allocations[dwSlot].EIPs);
// Cause problems to users who think malloc zeroes block memory...
FillMemory(data, blockSize, 0xCD);
dwTotalAllocated += blockSize;
if (dwTotalPeakMemory<dwTotalAllocated)
dwTotalPeakMemory = dwTotalAllocated;
LeaveCriticalSection(&section);
return (void *)data;
}
void *
HeapCheckPostFenceCalloc(
size_t blockSize)
{
PVOID *data = (PVOID*) HeapCheckPostFenceMalloc(blockSize);
if (data)
FillMemory(data, blockSize, 0);
return data;
}
void *
HeapCheckPostFenceRealloc(
void *ptr,
size_t size)
{
void *tmpData;
DWORD dw;
EnterCriticalSection(&section);
for(dw=0; dw<MAX_ALLOCATIONS; dw++)
if(!allocations[dw].isFree)
if(allocations[dw].pData == ptr)
break;
if(dw == MAX_ALLOCATIONS) {
_RPT0(
_CRT_WARN,
"### ERROR ### Attempt to realloc unallocated block!...\n");
PrintCaller();
_ASSERTE(dw != MAX_ALLOCATIONS);
}
LeaveCriticalSection(&section);
tmpData = HeapCheckPostFenceMalloc(size);
if (!tmpData)
return NULL;
if (size < allocations[dw].dwLength)
CopyMemory(tmpData, allocations[dw].pData, size);
else
CopyMemory(tmpData, allocations[dw].pData, allocations[dw].dwLength);
HeapCheckPostFenceFree(ptr);
return tmpData;
}
void
HeapCheckPostFenceFree(
void *pData)
{
PCHAR pTmp = (PCHAR) pData;
DWORD dw;
EnterCriticalSection(&section);
for(dw=0; dw<MAX_ALLOCATIONS; dw++)
if(!allocations[dw].isFree)
if(allocations[dw].pData == pData)
break;
if(dw == MAX_ALLOCATIONS) {
// This is a block not allocated from us...
// Check first to see if it was allocated from
// the normal VC heap through any direct calls
// (brain-dead coding, that is)
if (_CrtIsValidHeapPointer(pData)) {
#ifndef NO_VC_HEAP_ERRS
char *origFileName;
DWORD origLineNo, origBlockSize;
if (_CrtIsMemoryBlock(
pData,
origBlockSize = GetSize(pData),
NULL,
&origFileName,
&origLineNo))
{
_RPT6(
_CRT_WARN,
"Freeing VC-heap allocated block (%d bytes from line %d of %s)\n",
origBlockSize, origLineNo, origFileName);
PrintCaller();
}
else {
_RPT0(
_CRT_WARN,
"Freeing unknown VC-heap allocated block\n");
PrintCaller();
_CrtDbgBreak();
}
#endif
}
else {
_RPT0(
_CRT_WARN,
"### ERROR ### Attempt to free unallocated block!... \n");
PrintCaller();
_CrtDbgBreak();
}
LeaveCriticalSection(&section);
return;
}
// Make data pages inaccessible, since they are freed!
pTmp -= (((DWORD)pTmp) % PAGE_SIZE);
VirtualFree(
pTmp,
(allocations[dw].dwPages - 1)*PAGE_SIZE,
MEM_DECOMMIT);
// Set these pages to 'available' again.
ZeroMemory(
&pagesState[ (pTmp - pMemoryBase)/PAGE_SIZE ],
allocations[dw].dwPages);
dwFreePages += allocations[dw].dwPages;
dwTotalAllocated -= allocations[dw].dwLength;
allocations[dw].isFree = 1;
allocations[dw].pData = NULL;
allocations[dw].dwPages = 0;
allocations[dw].dwLength = 0;
allocations[dw].EIPs[0] = 0;
LeaveCriticalSection(&section);
}
/*
* Pre-allocation fence versions of malloc, calloc, realloc and free
*
*/
void *
HeapCheckPreFenceMalloc(
size_t blockSize)
{
DWORD dwSlot;
DWORD dwPages, dwOldProtection;
PCHAR data = NULL;
BOOL bResult = FALSE;
LPVOID lpvResult = NULL;
static DWORD dwFirstTime = 1;
if (dwFirstTime) {
dwFirstTime = 0;
HeapCheckStartup();
}
if (!blockSize)
return NULL;
EnterCriticalSection(&section);
for(dwSlot = 0; dwSlot<MAX_ALLOCATIONS; dwSlot++)
if (allocations[dwSlot].isFree) {
allocations[dwSlot].isFree = 0;
break;
}
// If you end up in this assertion, stop debugging and re-compile
// with an increased value for the MAX_ALLOCATIONS constant.
_ASSERTE(dwSlot != MAX_ALLOCATIONS);
// Calculate number of requires pages
dwPages = ((blockSize - 1) / PAGE_SIZE) + 2;
//_RPT2(_CRT_WARN, "Requested %7d bytes, granted %2d pages\n", blockSize, dwPages);
// Make sure we have enough room
if (dwFreePages < dwPages) {
_RPT1(
_CRT_WARN,
"Your application requires more free memory...\n"
"Change MAX_ALLOCATABLE_BLOCK in %s.", __FILE__);
_ASSERTE(dwFreePages >= dwPages);
}
data = (char*) FindConsecutiveFreePages(dwPages);
// OK, now make fence-page untouchable...
bResult = VirtualFree(
(LPVOID) data,
PAGE_SIZE,
MEM_DECOMMIT);
_ASSERTE(bResult == TRUE);
// and data-pages available!
lpvResult = VirtualAlloc(
(LPVOID) (data+PAGE_SIZE),
(dwPages-1)*PAGE_SIZE,
MEM_COMMIT,
PAGE_READWRITE);
_ASSERTE(lpvResult != NULL );
VirtualProtect(
(LPVOID) (data+PAGE_SIZE),
(dwPages-1)*PAGE_SIZE,
PAGE_READWRITE,
&dwOldProtection);
data += PAGE_SIZE;
dwFreePages -= dwPages;
allocations[dwSlot].pData = data;
allocations[dwSlot].dwPages = dwPages;
allocations[dwSlot].dwLength = blockSize;
FillCallStack(allocations[dwSlot].EIPs);
// Cause problems to users who think malloc zeroes block memory...
FillMemory(data, blockSize, 0xCD);
dwTotalAllocated += blockSize;
if (dwTotalPeakMemory<dwTotalAllocated)
dwTotalPeakMemory = dwTotalAllocated;
LeaveCriticalSection(&section);
return (void *)data;
}
void *
HeapCheckPreFenceCalloc(
size_t blockSize)
{
PVOID *data = (PVOID*) HeapCheckPreFenceMalloc(blockSize);
if (data)
FillMemory(data, blockSize, 0);
return data;
}
void *
HeapCheckPreFenceRealloc(
void *ptr,
size_t size)
{
void *tmpData;
DWORD dw;
EnterCriticalSection(&section);
for(dw=0; dw<MAX_ALLOCATIONS; dw++)
if(!allocations[dw].isFree)
if(allocations[dw].pData == ptr)
break;
if(dw == MAX_ALLOCATIONS) {
_RPT0(
_CRT_WARN,
"### ERROR ### Attempt to realloc unallocated block!...\n");
PrintCaller();
_ASSERTE(dw != MAX_ALLOCATIONS);
}
LeaveCriticalSection(&section);
tmpData = HeapCheckPreFenceMalloc(size);
if (!tmpData)
return NULL;
if (size < allocations[dw].dwLength)
CopyMemory(tmpData, allocations[dw].pData, size);
else
CopyMemory(tmpData, allocations[dw].pData, allocations[dw].dwLength);
HeapCheckPreFenceFree(ptr);
return tmpData;
}
void
HeapCheckPreFenceFree(
void *pData)
{
PCHAR pTmp;
DWORD dw;
EnterCriticalSection(&section);
for(dw=0; dw<MAX_ALLOCATIONS; dw++)
if(!allocations[dw].isFree)
if(allocations[dw].pData == pData)
break;
if(dw == MAX_ALLOCATIONS) {
// This is a block not allocated from us...
// Check first to see if it was allocated from
// the normal VC heap through any direct calls
// (brain-dead coding, that is)
if (_CrtIsValidHeapPointer(pData)) {
#ifndef NO_VC_HEAP_ERRS
char *origFileName;
DWORD origLineNo, origBlockSize;
if (_CrtIsMemoryBlock(
pData,
origBlockSize = GetSize(pData),
NULL,
&origFileName,
&origLineNo))
{
_RPT6(
_CRT_WARN,
"Freeing VC-heap allocated block (%d bytes from line %d of %s)\n",
origBlockSize, origLineNo, origFileName);
PrintCaller();
}
else {
_RPT0(
_CRT_WARN,
"Freeing unknown VC-heap allocated block\n");
PrintCaller();
_CrtDbgBreak();
}
#endif
}
else {
_RPT0(
_CRT_WARN,
"### ERROR ### Attempt to free unallocated block!... \n");
PrintCaller();
_CrtDbgBreak();
}
LeaveCriticalSection(&section);
return;
}
// Make data pages inaccessible, since they are freed!
VirtualFree(
pData,
(allocations[dw].dwPages - 1)*PAGE_SIZE,
MEM_DECOMMIT);
// Set these pages to 'available' again.
pTmp = (PCHAR) pData;
pTmp -= PAGE_SIZE;
ZeroMemory(
&pagesState[ (pTmp - pMemoryBase)/PAGE_SIZE ],
allocations[dw].dwPages);
dwFreePages += allocations[dw].dwPages;
dwTotalAllocated -= allocations[dw].dwLength;
allocations[dw].isFree = 1;
allocations[dw].pData = NULL;
allocations[dw].dwPages = 0;
allocations[dw].dwLength = 0;
allocations[dw].EIPs[0] = 0;
LeaveCriticalSection(&section);
}
/*
* Startup and shutdown functions
*/
static void
HeapCheckStartup()
{
SYSTEM_INFO si;
DWORD dw;
CHAR dbgPath[MAX_PATH], *pEnd;
SymSetOptions(SymGetOptions() | SYMOPT_LOAD_LINES );
// Try to read the symbols from the path of the .exe file
if (!GetModuleFileName(
NULL,
dbgPath,
sizeof(dbgPath))) {
// if we failed, do your best
if(!SymInitialize(GetCurrentProcess(), NULL, TRUE)) {
_RPT0(
_CRT_WARN,
"HEAPCHECK: Won't be able to read file/line information...:(\n");
}
} else {
pEnd = strrchr(dbgPath, '\\');
if (!pEnd) {
// if we failed, do your best
if(!SymInitialize(GetCurrentProcess(), NULL, TRUE)) {
_RPT0(
_CRT_WARN,
"HEAPCHECK: Won't be able to read file/line information...:(\n");
}
} else {
// 99% probability of success with file/line info...!
*pEnd = 0;
if(!SymInitialize(GetCurrentProcess(), dbgPath, TRUE)) {
_RPT0(
_CRT_WARN,
"HEAPCHECK: Won't be able to read file/line information...:(\n");
}
}
}
InitializeCriticalSection(&section);
GetSystemInfo(&si);
_ASSERTE(si.dwPageSize == PAGE_SIZE);
dwAllocationGranularity = si.dwAllocationGranularity;
_ASSERTE(dwAllocationGranularity <= MAX_ALLOCATABLE_BLOCK);
pMemoryBase = (PCHAR) VirtualAlloc(
NULL, // Place memory base wherever
MAX_ALLOCATABLE_BLOCK, // Total heap memory available
MEM_RESERVE, // For now, just reserve it
PAGE_NOACCESS); // and make it no-touch.
_ASSERTE(pMemoryBase != NULL);
dwTotalPages = MAX_ALLOCATABLE_BLOCK / PAGE_SIZE;
dwFreePages = dwTotalPages;
if(atexit(HeapCheckShutDown)) {
_RPT0(_CRT_WARN, "### WARNING ### Can't check for memory leaks automatically!\n");
_RPT0(_CRT_WARN, "### WARNING ### Call HeapCheckShutDown at the end of your app,\n");
}
for(dw=0; dw<MAX_ALLOCATIONS; dw++)
allocations[dw].isFree = 1;
ZeroMemory(pagesState, sizeof(pagesState));
}
static void
HeapCheckShutDown()
{
BOOL bSuccess;
DWORD dw;
HANDLE hProcess = GetCurrentProcess();
EnterCriticalSection(&section);
_RPT0(_CRT_WARN, "\n##################################\n");
_RPT0(_CRT_WARN, "####### HeapCheck report ######\n");
_RPT0(_CRT_WARN, "##################################\n\n");
for(dw=0; dw<MAX_ALLOCATIONS; dw++) {
if (!allocations[dw].isFree) {
// We have to use IMAGEHLP.DLL. God help us...
IMAGEHLP_LINE dbgLine;
DWORD dwTemp, dwCodePlaces = 0;
_RPT1(
_CRT_WARN,
"### WARNING ### Memory leak (%d bytes) found... Allocated:\n",
allocations[dw].dwLength);
while(allocations[dw].EIPs[dwCodePlaces]) {
ZeroMemory(&dbgLine, sizeof(IMAGEHLP_LINE));
dbgLine.SizeOfStruct = sizeof(IMAGEHLP_LINE);
if(!SymGetLineFromAddr(
hProcess,
allocations[dw].EIPs[dwCodePlaces],
&dwTemp,
&dbgLine))
{
#ifdef PRINT_NUMERIC_EIP
_RPT1(
_CRT_WARN,
"\tfrom EIP = %x\n",
allocations[dw].EIPs[dwCodePlaces]);
#endif
} else {
_RPT3(
_CRT_WARN,
"\tfrom line %d(+%d bytes) of %s\n",
dbgLine.LineNumber,
dwTemp,
dbgLine.FileName);
}
dwCodePlaces++;
// If you land here after an assertion, stop debugging
// and increase MAX_STACK_DEPTH
_ASSERTE(dwCodePlaces < MAX_STACK_DEPTH);
}
}
}
/* Decommit the entire block. */
bSuccess = VirtualFree(
pMemoryBase, /* base address of block */
MAX_ALLOCATABLE_BLOCK, /* bytes of committed pages */
MEM_DECOMMIT); /* decommit the pages */
_ASSERTE(bSuccess);
/* Release the entire block. */
if (bSuccess)
bSuccess = VirtualFree(
pMemoryBase, /* base address of block */
0, /* releases the entire block */
MEM_RELEASE); /* releases the pages */
_ASSERTE(bSuccess);
_RPT1(_CRT_WARN, "HeapCheck Statistics:\n\tMaximum memory allocated = %d\n\n", dwTotalPeakMemory);
SymCleanup(hProcess);
LeaveCriticalSection(&section);
DeleteCriticalSection(&section);
}
#endif
const char *BOINC_RCSID_972eaf72ca = "$Id$";