kc3-lang/ftgl/test/mmgr.cpp

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  Date : 2015-02-18T15:28:10
  

  windows: use the proper preprocessor define

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• test/mmgr.cpp

• // ---------------------------------------------------------------------------------------------------------------------------------
  //
  //
  //  _ __ ___  _ __ ___   __ _ _ __      ___ _ __  _ __
  // | '_ ` _ \| '_ ` _ \ / _` | '__|    / __| '_ \| '_ \
  // | | | | | | | | | | | (_| | |    _ | (__| |_) | |_) |
  // |_| |_| |_|_| |_| |_|\__, |_|   (_) \___| .__/| .__/
  //                       __/ |             | |   | |
  //                      |___/              |_|   |_|
  //
  // Memory manager & tracking software
  //
  // Best viewed with 8-character tabs and (at least) 132 columns
  //
  // ---------------------------------------------------------------------------------------------------------------------------------
  //
  // Restrictions & freedoms pertaining to usage and redistribution of this software:
  //
  //  * This software is 100% free
  //  * If you use this software (in part or in whole) you must credit the author.
  //  * This software may not be re-distributed (in part or in whole) in a modified
  //    form without clear documentation on how to obtain a copy of the original work.
  //  * You may not use this software to directly or indirectly cause harm to others.
  //  * This software is provided as-is and without warrantee. Use at your own risk.
  //
  // For more information, visit HTTP://www.FluidStudios.com
  //
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Originally created on 12/22/2000 by Paul Nettle
  //
  // Copyright 2000, Fluid Studios, Inc., all rights reserved.
  // ---------------------------------------------------------------------------------------------------------------------------------
  //
  // !!IMPORTANT!!
  //
  // This software is self-documented with periodic comments. Before you start using this software, perform a search for the string
  // "-DOC-" to locate pertinent information about how to use this software.
  //
  // You are also encouraged to read the comment blocks throughout this source file. They will help you understand how this memory
  // tracking software works, so you can better utilize it within your applications.
  //
  // NOTES:
  //
  // 1. This code purposely uses no external routines that allocate RAM (other than the raw allocation routines, such as malloc). We
  //    do this because we want this to be as self-contained as possible. As an example, we don't use assert, because when running
  //    under WIN32, the assert brings up a dialog box, which allocates RAM. Doing this in the middle of an allocation would be bad.
  //
  // 2. When trying to override new/delete under MFC (which has its own version of global new/delete) the linker will complain. In
  //    order to fix this error, use the compiler option: /FORCE, which will force it to build an executable even with linker errors.
  //    Be sure to check those errors each time you compile, otherwise, you may miss a valid linker error.
  //
  // 3. If you see something that looks odd to you or seems like a strange way of going about doing something, then consider that this
  //    code was carefully thought out. If something looks odd, then just assume I've got a good reason for doing it that way (an
  //    example is the use of the class MemStaticTimeTracker.)
  //
  // 4. With MFC applications, you will need to comment out any occurance of "#define new DEBUG_NEW" from all source files.
  //
  // 5. Include file dependencies are _very_important_ for getting the MMGR to integrate nicely into your application. Be careful if
  //    you're including standard includes from within your own project inclues; that will break this very specific dependency order.
  //    It should look like this:
  //
  //		#include <stdio.h>   // Standard includes MUST come first
  //		#include <stdlib.h>  //
  //		#include <streamio>  //
  //
  //		#include "mmgr.h"    // mmgr.h MUST come next
  //
  //		#include "myfile1.h" // Project includes MUST come last
  //		#include "myfile2.h" //
  //		#include "myfile3.h" //
  //
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  //#include "stdafx.h"
  #include <iostream>
  #include <stdio.h>
  #include <stdlib.h>
  #include <assert.h>
  #include <string.h>
  #include <time.h>
  #include <stdarg.h>
  #include <new>
  
  #ifndef	_WIN32
  #include <unistd.h>
  #endif
  
  #include "mmgr.h"
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- If you're like me, it's hard to gain trust in foreign code. This memory manager will try to INDUCE your code to crash (for
  // very good reasons... like making bugs obvious as early as possible.) Some people may be inclined to remove this memory tracking
  // software if it causes crashes that didn't exist previously. In reality, these new crashes are the BEST reason for using this
  // software!
  //
  // Whether this software causes your application to crash, or if it reports errors, you need to be able to TRUST this software. To
  // this end, you are given some very simple debugging tools.
  //
  // The quickest way to locate problems is to enable the STRESS_TEST macro (below.) This should catch 95% of the crashes before they
  // occur by validating every allocation each time this memory manager performs an allocation function. If that doesn't work, keep
  // reading...
  //
  // If you enable the TEST_MEMORY_MANAGER #define (below), this memory manager will log an entry in the memory.log file each time it
  // enters and exits one of its primary allocation handling routines. Each call that succeeds should place an "ENTER" and an "EXIT"
  // into the log. If the program crashes within the memory manager, it will log an "ENTER", but not an "EXIT". The log will also
  // report the name of the routine.
  //
  // Just because this memory manager crashes does not mean that there is a bug here! First, an application could inadvertantly damage
  // the heap, causing malloc(), realloc() or free() to crash. Also, an application could inadvertantly damage some of the memory used
  // by this memory tracking software, causing it to crash in much the same way that a damaged heap would affect the standard
  // allocation routines.
  //
  // In the event of a crash within this code, the first thing you'll want to do is to locate the actual line of code that is
  // crashing. You can do this by adding log() entries throughout the routine that crashes, repeating this process until you narrow
  // in on the offending line of code. If the crash happens in a standard C allocation routine (i.e. malloc, realloc or free) don't
  // bother contacting me, your application has damaged the heap. You can help find the culprit in your code by enabling the
  // STRESS_TEST macro (below.)
  //
  // If you truely suspect a bug in this memory manager (and you had better be sure about it! :) you can contact me at
  // midnight@FluidStudios.com. Before you do, however, check for a newer version at:
  //
  //	http://www.FluidStudios.com/publications.html
  //
  // When using this debugging aid, make sure that you are NOT setting the alwaysLogAll variable on, otherwise the log could be
  // cluttered and hard to read.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  //#define	TEST_MEMORY_MANAGER
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- Enable this sucker if you really want to stress-test your app's memory usage, or to help find hard-to-find bugs
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  #define	STRESS_TEST
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- Enable this sucker if you want to stress-test your app's error-handling. Set RANDOM_FAIL to the percentage of failures you
  //       want to test with (0 = none, >100 = all failures).
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  //#define	RANDOM_FAILURE 10.0
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- Locals -- modify these flags to suit your needs
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  #ifdef	STRESS_TEST
  	static	const	unsigned int	hashBits           		= 12;
  	static			bool			randomWipe          	= true;
  	static			bool			alwaysValidateAll   	= true;
  	static			bool			alwaysLogAll        	= true;
  	static			bool			alwaysWipeAll       	= true;
  	static			bool			cleanupLogOnFirstRun	= true;
  	static	const	unsigned int	paddingSize         	= 1024; // An extra 8K per allocation!
  #else
  	static	const	unsigned int	hashBits               = 12;
  	static			bool			randomWipe             = false;
  	static			bool			alwaysValidateAll      = false;
  	static			bool			alwaysLogAll           = false;
  	static			bool			alwaysWipeAll          = true;
  	static			bool			cleanupLogOnFirstRun   = true;
  	static	const	unsigned int	paddingSize            = 4;
  #endif
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // We define our own assert, because we don't want to bring up an assertion dialog, since that allocates RAM. Our new assert
  // simply declares a forced breakpoint.
  //
  // The BEOS assert added by Arvid Norberg <arvid@iname.com>.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  #ifdef	_WIN32
  	#ifdef	_DEBUG
  	#define	m_assert(x) if ((x) == false) __asm { int 3 }
  	#else
  	#define	m_assert(x) {}
  	#endif
  #elif defined(__BEOS__)
  	#ifdef DEBUG
  		extern void debugger(const char *message);
  		#define	m_assert(x) if ((x) == false) debugger("mmgr: assert failed")
  	#else
  		#define m_assert(x) {}
  	#endif
  #else	// Linux uses assert, which we can use safely, since it doesn't bring up a dialog within the program.
  	#define	m_assert(cond) assert(cond)
  #endif
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Here, we turn off our macros because any place in this source file where the word 'new' or the word 'delete' (etc.)
  // appear will be expanded by the macro. So to avoid problems using them within this source file, we'll just #undef them.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  #undef	new
  #undef	delete
  #undef	malloc
  #undef	calloc
  #undef	realloc
  #undef	free
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Defaults for the constants & statics in the MemoryManager class
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  const		unsigned int	m_alloc_unknown        = 0;
  const		unsigned int	m_alloc_new            = 1;
  const		unsigned int	m_alloc_new_array      = 2;
  const		unsigned int	m_alloc_malloc         = 3;
  const		unsigned int	m_alloc_calloc         = 4;
  const		unsigned int	m_alloc_realloc        = 5;
  const		unsigned int	m_alloc_delete         = 6;
  const		unsigned int	m_alloc_delete_array   = 7;
  const		unsigned int	m_alloc_free           = 8;
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- Get to know these values. They represent the values that will be used to fill unused and deallocated RAM.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static		unsigned int	prefixPattern          = 0xbaadf00d; // Fill pattern for bytes preceeding allocated blocks
  static		unsigned int	postfixPattern         = 0xdeadc0de; // Fill pattern for bytes following allocated blocks
  static		unsigned int	unusedPattern          = 0xfeedface; // Fill pattern for freshly allocated blocks
  static		unsigned int	releasedPattern        = 0xdeadbeef; // Fill pattern for deallocated blocks
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Other locals
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	const	unsigned int	hashSize               = 1 << hashBits;
  static	const	char		*allocationTypes[]     = {"Unknown",
  							  "new",     "new[]",  "malloc",   "calloc",
  							  "realloc", "delete", "delete[]", "free"};
  static		sAllocUnit	*hashTable[hashSize];
  static		sAllocUnit	*reservoir;
  static		unsigned int	currentAllocationCount = 0;
  static		unsigned int	breakOnAllocationCount = 0;
  static		sMStats		stats;
  static	const	char		*sourceFile            = "??";
  static	const	char		*sourceFunc            = "??";
  static		unsigned int	sourceLine             = 0;
  static		bool		staticDeinitTime       = false;
  static		sAllocUnit	**reservoirBuffer      = NULL;
  static		unsigned int	reservoirBufferSize    = 0;
  static const	char		*memoryLogFile         = "memory.log";
  static const	char		*memoryLeakLogFile     = "memleaks.log";
  static		void		doCleanupLogOnFirstRun();
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Local functions only
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	void	log(const char *format, ...)
  {
  	// Build the buffer
  
  	static char buffer[2048];
  	va_list	ap;
  	va_start(ap, format);
  	vsprintf(buffer, format, ap);
  	va_end(ap);
  
  	// Cleanup the log?
  
  	if (cleanupLogOnFirstRun) doCleanupLogOnFirstRun();
  
  	// Open the log file
  
  	FILE	*fp = fopen(memoryLogFile, "ab");
  
  	// If you hit this assert, then the memory logger is unable to log information to a file (can't open the file for some
  	// reason.) You can interrogate the variable 'buffer' to see what was supposed to be logged (but won't be.)
  	m_assert(fp);
  
  	if (!fp) return;
  
  	// Spit out the data to the log
  
  	fprintf(fp, "%s\r\n", buffer);
  	fclose(fp);
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	void	doCleanupLogOnFirstRun()
  {
  	if (cleanupLogOnFirstRun)
  	{
  		unlink(memoryLogFile);
  		cleanupLogOnFirstRun = false;
  
  		// Print a header for the log
  
  		time_t	t = time(NULL);
  		log("--------------------------------------------------------------------------------");
  		log("");
  		log("      %s - Memory logging file created on %s", memoryLogFile, asctime(localtime(&t)));
  		log("--------------------------------------------------------------------------------");
  		log("");
  		log("This file contains a log of all memory operations performed during the last run.");
  		log("");
  		log("Interrogate this file to track errors or to help track down memory-related");
  		log("issues. You can do this by tracing the allocations performed by a specific owner");
  		log("or by tracking a specific address through a series of allocations and");
  		log("reallocations.");
  		log("");
  		log("There is a lot of useful information here which, when used creatively, can be");
  		log("extremely helpful.");
  		log("");
  		log("Note that the following guides are used throughout this file:");
  		log("");
  		log("   [!] - Error");
  		log("   [+] - Allocation");
  		log("   [~] - Reallocation");
  		log("   [-] - Deallocation");
  		log("   [I] - Generic information");
  		log("   [F] - Failure induced for the purpose of stress-testing your application");
  		log("   [D] - Information used for debugging this memory manager");
  		log("");
  		log("...so, to find all errors in the file, search for \"[!]\"");
  		log("");
  		log("--------------------------------------------------------------------------------");
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	const char	*sourceFileStripper(const char *sourceFile)
  {
  	char	*ptr = strrchr(sourceFile, '\\');
  	if (ptr) return ptr + 1;
  	ptr = strrchr(sourceFile, '/');
  	if (ptr) return ptr + 1;
  	return sourceFile;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	const char	*ownerString(const char *sourceFile, const unsigned int sourceLine, const char *sourceFunc)
  {
  	static	char	str[90];
  	memset(str, 0, sizeof(str));
  	sprintf(str, "%s(%05d)::%s", sourceFileStripper(sourceFile), sourceLine, sourceFunc);
  	return str;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	const char	*insertCommas(unsigned int value)
  {
  	static	char	str[30];
  	memset(str, 0, sizeof(str));
  
  	sprintf(str, "%u", value);
  	if (strlen(str) > 3)
  	{
  		memmove(&str[strlen(str)-3], &str[strlen(str)-4], 4);
  		str[strlen(str) - 4] = ',';
  	}
  	if (strlen(str) > 7)
  	{
  		memmove(&str[strlen(str)-7], &str[strlen(str)-8], 8);
  		str[strlen(str) - 8] = ',';
  	}
  	if (strlen(str) > 11)
  	{
  		memmove(&str[strlen(str)-11], &str[strlen(str)-12], 12);
  		str[strlen(str) - 12] = ',';
  	}
  
  	return str;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	const char	*memorySizeString(unsigned long size)
  {
  	static	char	str[90];
  	     if (size > (1024*1024))	sprintf(str, "%10s (%7.2fM)", insertCommas(size), (float) size / (1024.0f * 1024.0f));
  	else if (size > 1024)		sprintf(str, "%10s (%7.2fK)", insertCommas(size), (float) size / 1024.0f);
  	else				sprintf(str, "%10s bytes     ", insertCommas(size));
  	return str;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	sAllocUnit	*findAllocUnit(const void *reportedAddress)
  {
  	// Just in case...
  	m_assert(reportedAddress != NULL);
  
  	// Use the address to locate the hash index. Note that we shift off the lower four bits. This is because most allocated
  	// addresses will be on four-, eight- or even sixteen-byte boundaries. If we didn't do this, the hash index would not have
  	// very good coverage.
  
  	unsigned int	hashIndex = ((unsigned int) reportedAddress >> 4) & (hashSize - 1);
  	sAllocUnit	*ptr = hashTable[hashIndex];
  	while(ptr)
  	{
  		if (ptr->reportedAddress == reportedAddress) return ptr;
  		ptr = ptr->next;
  	}
  
  	return NULL;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	size_t	calculateActualSize(const size_t reportedSize)
  {
  	// We use DWORDS as our padding, and a long is guaranteed to be 4 bytes, but an int is not (ANSI defines an int as
  	// being the standard word size for a processor; on a 32-bit machine, that's 4 bytes, but on a 64-bit machine, it's
  	// 8 bytes, which means an int can actually be larger than a long.)
  
  	return reportedSize + paddingSize * sizeof(long) * 2;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	size_t	calculateReportedSize(const size_t actualSize)
  {
  	// We use DWORDS as our padding, and a long is guaranteed to be 4 bytes, but an int is not (ANSI defines an int as
  	// being the standard word size for a processor; on a 32-bit machine, that's 4 bytes, but on a 64-bit machine, it's
  	// 8 bytes, which means an int can actually be larger than a long.)
  
  	return actualSize - paddingSize * sizeof(long) * 2;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	void	*calculateReportedAddress(const void *actualAddress)
  {
  	// We allow this...
  
  	if (!actualAddress) return NULL;
  
  	// JUst account for the padding
  
  	return (void *) ((char *) actualAddress + sizeof(long) * paddingSize);
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	void	wipeWithPattern(sAllocUnit *allocUnit, unsigned long pattern, const unsigned int originalReportedSize = 0)
  {
  	// For a serious test run, we use wipes of random a random value. However, if this causes a crash, we don't want it to
  	// crash in a differnt place each time, so we specifically DO NOT call srand. If, by chance your program calls srand(),
  	// you may wish to disable that when running with a random wipe test. This will make any crashes more consistent so they
  	// can be tracked down easier.
  
  	if (randomWipe)
  	{
  		pattern = ((rand() & 0xff) << 24) | ((rand() & 0xff) << 16) | ((rand() & 0xff) << 8) | (rand() & 0xff);
  	}
  
  	// -DOC- We should wipe with 0's if we're not in debug mode, so we can help hide bugs if possible when we release the
  	// product. So uncomment the following line for releases.
  	//
  	// Note that the "alwaysWipeAll" should be turned on for this to have effect, otherwise it won't do much good. But we'll
  	// leave it this way (as an option) because this does slow things down.
  //	pattern = 0;
  
  	// This part of the operation is optional
  
  	if (alwaysWipeAll && allocUnit->reportedSize > originalReportedSize)
  	{
  		// Fill the bulk
  
  		long	*lptr = (long *) ((char *)allocUnit->reportedAddress + originalReportedSize);
  		int	length = allocUnit->reportedSize - originalReportedSize;
  		int	i;
  		for (i = 0; i < (length >> 2); i++, lptr++)
  		{
  			*lptr = pattern;
  		}
  
  		// Fill the remainder
  
  		unsigned int	shiftCount = 0;
  		char		*cptr = (char *) lptr;
  		for (i = 0; i < (length & 0x3); i++, cptr++, shiftCount += 8)
  		{
  			*cptr = (pattern & (0xff << shiftCount)) >> shiftCount;
  		}
  	}
  
  	// Write in the prefix/postfix bytes
  
  	long		*pre = (long *) allocUnit->actualAddress;
  	long		*post = (long *) ((char *)allocUnit->actualAddress + allocUnit->actualSize - paddingSize * sizeof(long));
  	for (unsigned int i = 0; i < paddingSize; i++, pre++, post++)
  	{
  		*pre = prefixPattern;
  		*post = postfixPattern;
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	void	dumpAllocations(FILE *fp)
  {
  	fprintf(fp, "Alloc.   Addr       Size       Addr       Size                        BreakOn BreakOn              \r\n");
  	fprintf(fp, "Number Reported   Reported    Actual     Actual     Unused    Method  Dealloc Realloc Allocated by \r\n");
  	fprintf(fp, "------ ---------- ---------- ---------- ---------- ---------- -------- ------- ------- --------------------------------------------------- \r\n");
  
  
  	for (unsigned int i = 0; i < hashSize; i++)
  	{
  		sAllocUnit *ptr = hashTable[i];
  		while(ptr)
  		{
  			fprintf(fp, "%06d 0x%08X 0x%08X 0x%08X 0x%08X 0x%08X %-8s    %c       %c    %s\r\n",
  				ptr->allocationNumber,
  				(unsigned int) ptr->reportedAddress, ptr->reportedSize,
  				(unsigned int) ptr->actualAddress, ptr->actualSize,
  				m_calcUnused(ptr),
  				allocationTypes[ptr->allocationType],
  				ptr->breakOnDealloc ? 'Y':'N',
  				ptr->breakOnRealloc ? 'Y':'N',
  				ownerString(ptr->sourceFile, ptr->sourceLine, ptr->sourceFunc));
  			ptr = ptr->next;
  		}
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	void	dumpLeakReport()
  {
  	// Open the report file
  
  	FILE	*fp = fopen(memoryLeakLogFile, "w+b");
  
  	// If you hit this assert, then the memory report generator is unable to log information to a file (can't open the file for
  	// some reason.)
  	m_assert(fp);
  	if (!fp) return;
  
  	// Any leaks?
  
  	// Header
  
  	static  char    timeString[25];
  	memset(timeString, 0, sizeof(timeString));
  	time_t  t = time(NULL);
  	struct  tm *tme = localtime(&t);
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "|                                          Memory leak report for:  %02d/%02d/%04d %02d:%02d:%02d                                            |\r\n", tme->tm_mon + 1, tme->tm_mday, tme->tm_year + 1900, tme->tm_hour, tme->tm_min, tme->tm_sec);
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "\r\n");
  	fprintf(fp, "\r\n");
  	if (stats.totalAllocUnitCount)
  	{
  		fprintf(fp, "%d memory leak%s found:\r\n", stats.totalAllocUnitCount, stats.totalAllocUnitCount == 1 ? "":"s");
  	}
  	else
  	{
  		fprintf(fp, "Congratulations! No memory leaks found!\r\n");
  
  		// We can finally free up our own memory allocations
  
  		if (reservoirBuffer)
  		{
  			for (unsigned int i = 0; i < reservoirBufferSize; i++)
  			{
  				free(reservoirBuffer[i]);
  			}
  			free(reservoirBuffer);
  			reservoirBuffer = 0;
  			reservoirBufferSize = 0;
  			reservoir = NULL;
  		}
  	}
  	fprintf(fp, "\r\n");
  
  	if (stats.totalAllocUnitCount)
  	{
  		dumpAllocations(fp);
  	}
  
  	fclose(fp);
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // We use a static class to let us know when we're in the midst of static deinitialization
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  class	MemStaticTimeTracker
  {
  public:
  	MemStaticTimeTracker() {doCleanupLogOnFirstRun();}
  	~MemStaticTimeTracker() {staticDeinitTime = true; dumpLeakReport();}
  };
  static	MemStaticTimeTracker	mstt;
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- Flags & options -- Call these routines to enable/disable the following options
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	&m_alwaysValidateAll()
  {
  	// Force a validation of all allocation units each time we enter this software
  	return alwaysValidateAll;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	&m_alwaysLogAll()
  {
  	// Force a log of every allocation & deallocation into memory.log
  	return alwaysLogAll;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	&m_alwaysWipeAll()
  {
  	// Force this software to always wipe memory with a pattern when it is being allocated/dallocated
  	return alwaysWipeAll;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	&m_randomeWipe()
  {
  	// Force this software to use a random pattern when wiping memory -- good for stress testing
  	return randomWipe;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- Simply call this routine with the address of an allocated block of RAM, to cause it to force a breakpoint when it is
  // reallocated.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	&m_breakOnRealloc(void *reportedAddress)
  {
  	// Locate the existing allocation unit
  
  	sAllocUnit	*au = findAllocUnit(reportedAddress);
  
  	// If you hit this assert, you tried to set a breakpoint on reallocation for an address that doesn't exist. Interrogate the
  	// stack frame or the variable 'au' to see which allocation this is.
  	m_assert(au != NULL);
  
  	// If you hit this assert, you tried to set a breakpoint on reallocation for an address that wasn't allocated in a way that
  	// is compatible with reallocation.
  	m_assert(au->allocationType == m_alloc_malloc ||
  		 au->allocationType == m_alloc_calloc ||
  		 au->allocationType == m_alloc_realloc);
  
  	return au->breakOnRealloc;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- Simply call this routine with the address of an allocated block of RAM, to cause it to force a breakpoint when it is
  // deallocated.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	&m_breakOnDealloc(void *reportedAddress)
  {
  	// Locate the existing allocation unit
  
  	sAllocUnit	*au = findAllocUnit(reportedAddress);
  
  	// If you hit this assert, you tried to set a breakpoint on deallocation for an address that doesn't exist. Interrogate the
  	// stack frame or the variable 'au' to see which allocation this is.
  	m_assert(au != NULL);
  
  	return au->breakOnDealloc;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- When tracking down a difficult bug, use this routine to force a breakpoint on a specific allocation count
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	m_breakOnAllocation(unsigned int count)
  {
  	breakOnAllocationCount = count;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Used by the macros
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	m_setOwner(const char *file, const unsigned int line, const char *func)
  {
  	// You're probably wondering about this...
  	//
  	// It's important for this memory manager to primarily work with global new/delete in their original forms (i.e. with
  	// no extra parameters.) In order to do this, we use macros that call this function prior to operators new & delete. This
  	// is fine... usually. Here's what actually happens when you use this macro to delete an object:
  	//
  	// m_setOwner(__FILE__, __LINE__, __FUNCTION__) --> object::~object() --> delete
  	//
  	// Note that the compiler inserts a call to the object's destructor just prior to calling our overridden operator delete.
  	// But what happens when we delete an object whose destructor deletes another object, whose desctuctor deletes another
  	// object? Here's a diagram (indentation follows stack depth):
  	//
  	// m_setOwner(...) -> ~obj1()                          // original call to delete obj1
  	//     m_setOwner(...) -> ~obj2()                      // obj1's destructor deletes obj2
  	//         m_setOwner(...) -> ~obj3()                  // obj2's destructor deletes obj3
  	//             ...                                     // obj3's destructor just does some stuff
  	//         delete                                      // back in obj2's destructor, we call delete
  	//     delete                                          // back in obj1's destructor, we call delete
  	// delete                                              // back to our original call, we call delete
  	//
  	// Because m_setOwner() just sets up some static variables (below) it's important that each call to m_setOwner() and
  	// successive calls to new/delete alternate. However, in this case, three calls to m_setOwner() happen in succession
  	// followed by three calls to delete in succession (with a few calls to destructors mixed in for fun.) This means that
  	// only the final call to delete (in this chain of events) will have the proper reporting, and the first two in the chain
  	// will not have ANY owner-reporting information. The deletes will still work fine, we just won't know who called us.
  	//
  	// "Then build a stack, my friend!" you might think... but it's a very common thing that people will be working with third-
  	// party libraries (including MFC under Windows) which is not compiled with this memory manager's macros. In those cases,
  	// m_setOwner() is never called, and rightfully should not have the proper trace-back information. So if one of the
  	// destructors in the chain ends up being a call to a delete from a non-mmgr-compiled library, the stack will get confused.
  	//
  	// I've been unable to find a solution to this problem, but at least we can detect it and report the data before we
  	// lose it. That's what this is all about. It makes it somewhat confusing to read in the logs, but at least ALL the
  	// information is present...
  	//
  	// There's a caveat here... The compiler is not required to call operator delete if the value being deleted is NULL.
  	// In this case, any call to delete with a NULL will sill call m_setOwner(), which will make m_setOwner() think that
  	// there is a destructor chain becuase we setup the variables, but nothing gets called to clear them. Because of this
  	// we report a "Possible destructor chain".
  	//
  	// Thanks to J. Woznack (from Kodiak Interactive Software Studios -- www.kodiakgames.com) for pointing this out.
  
  	if (sourceLine && alwaysLogAll)
  	{
  		log("[I] NOTE! Possible destructor chain: previous owner is %s", ownerString(sourceFile, sourceLine, sourceFunc));
  	}
  
  	// Okay... save this stuff off so we can keep track of the caller
  
  	sourceFile = file;
  	sourceLine = line;
  	sourceFunc = func;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  static	void	resetGlobals()
  {
  	sourceFile = "??";
  	sourceLine = 0;
  	sourceFunc = "??";
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Global new/new[]
  //
  // These are the standard new/new[] operators. They are merely interface functions that operate like normal new/new[], but use our
  // memory tracking routines.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	*operator new(size_t reportedSize)
  {
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] ENTER: new");
  	#endif
  
  	// Save these off...
  
  	const	char		*file = sourceFile;
  	const	unsigned int	line = sourceLine;
  	const	char		*func = sourceFunc;
  
  	// ANSI says: allocation requests of 0 bytes will still return a valid value
  
  	if (reportedSize == 0) reportedSize = 1;
  
  	// ANSI says: loop continuously because the error handler could possibly free up some memory
  
  	for(;;)
  	{
  		// Try the allocation
  
  		void	*ptr = m_allocator(file, line, func, m_alloc_new, reportedSize);
  		if (ptr)
  		{
  			#ifdef TEST_MEMORY_MANAGER
  			log("[D] EXIT : new");
  			#endif
  			return ptr;
  		}
  
  		// There isn't a way to determine the new handler, except through setting it. So we'll just set it to NULL, then
  		// set it back again.
  
  		std::new_handler	nh = std::set_new_handler(0);
  		std::set_new_handler(nh);
  
  		// If there is an error handler, call it
  
  		if (nh)
  		{
  			(*nh)();
  		}
  
  		// Otherwise, throw the exception
  
  		else
  		{
  			#ifdef TEST_MEMORY_MANAGER
  			log("[D] EXIT : new");
  			#endif
  			throw std::bad_alloc();
  		}
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	*operator new[](size_t reportedSize)
  {
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] ENTER: new[]");
  	#endif
  
  	// Save these off...
  
  	const	char		*file = sourceFile;
  	const	unsigned int	line = sourceLine;
  	const	char		*func = sourceFunc;
  
  	// The ANSI standard says that allocation requests of 0 bytes will still return a valid value
  
  	if (reportedSize == 0) reportedSize = 1;
  
  	// ANSI says: loop continuously because the error handler could possibly free up some memory
  
  	for(;;)
  	{
  		// Try the allocation
  
  		void	*ptr = m_allocator(file, line, func, m_alloc_new_array, reportedSize);
  		if (ptr)
  		{
  			#ifdef TEST_MEMORY_MANAGER
  			log("[D] EXIT : new[]");
  			#endif
  			return ptr;
  		}
  
  		// There isn't a way to determine the new handler, except through setting it. So we'll just set it to NULL, then
  		// set it back again.
  
  		std::new_handler	nh = std::set_new_handler(0);
  		std::set_new_handler(nh);
  
  		// If there is an error handler, call it
  
  		if (nh)
  		{
  			(*nh)();
  		}
  
  		// Otherwise, throw the exception
  
  		else
  		{
  			#ifdef TEST_MEMORY_MANAGER
  			log("[D] EXIT : new[]");
  			#endif
  			throw std::bad_alloc();
  		}
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Other global new/new[]
  //
  // These are the standard new/new[] operators as used by Microsoft's memory tracker. We don't want them interfering with our memory
  // tracking efforts. Like the previous versions, these are merely interface functions that operate like normal new/new[], but use
  // our memory tracking routines.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	*operator new(size_t reportedSize, const char *sourceFile, int sourceLine)
  {
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] ENTER: new");
  	#endif
  
  	// The ANSI standard says that allocation requests of 0 bytes will still return a valid value
  
  	if (reportedSize == 0) reportedSize = 1;
  
  	// ANSI says: loop continuously because the error handler could possibly free up some memory
  
  	for(;;)
  	{
  		// Try the allocation
  
  		void	*ptr = m_allocator(sourceFile, sourceLine, "??", m_alloc_new, reportedSize);
  		if (ptr)
  		{
  			#ifdef TEST_MEMORY_MANAGER
  			log("[D] EXIT : new");
  			#endif
  			return ptr;
  		}
  
  		// There isn't a way to determine the new handler, except through setting it. So we'll just set it to NULL, then
  		// set it back again.
  
  		std::new_handler	nh = std::set_new_handler(0);
  		std::set_new_handler(nh);
  
  		// If there is an error handler, call it
  
  		if (nh)
  		{
  			(*nh)();
  		}
  
  		// Otherwise, throw the exception
  
  		else
  		{
  			#ifdef TEST_MEMORY_MANAGER
  			log("[D] EXIT : new");
  			#endif
  			throw std::bad_alloc();
  		}
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	*operator new[](size_t reportedSize, const char *sourceFile, int sourceLine)
  {
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] ENTER: new[]");
  	#endif
  
  	// The ANSI standard says that allocation requests of 0 bytes will still return a valid value
  
  	if (reportedSize == 0) reportedSize = 1;
  
  	// ANSI says: loop continuously because the error handler could possibly free up some memory
  
  	for(;;)
  	{
  		// Try the allocation
  
  		void	*ptr = m_allocator(sourceFile, sourceLine, "??", m_alloc_new_array, reportedSize);
  		if (ptr)
  		{
  			#ifdef TEST_MEMORY_MANAGER
  			log("[D] EXIT : new[]");
  			#endif
  			return ptr;
  		}
  
  		// There isn't a way to determine the new handler, except through setting it. So we'll just set it to NULL, then
  		// set it back again.
  
  		std::new_handler	nh = std::set_new_handler(0);
  		std::set_new_handler(nh);
  
  		// If there is an error handler, call it
  
  		if (nh)
  		{
  			(*nh)();
  		}
  
  		// Otherwise, throw the exception
  
  		else
  		{
  			#ifdef TEST_MEMORY_MANAGER
  			log("[D] EXIT : new[]");
  			#endif
  			throw std::bad_alloc();
  		}
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Global delete/delete[]
  //
  // These are the standard delete/delete[] operators. They are merely interface functions that operate like normal delete/delete[],
  // but use our memory tracking routines.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	operator delete(void *reportedAddress)
  {
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] ENTER: delete");
  	#endif
  
  	// ANSI says: delete & delete[] allow NULL pointers (they do nothing)
  
  	if (reportedAddress) m_deallocator(sourceFile, sourceLine, sourceFunc, m_alloc_delete, reportedAddress);
  	else if (alwaysLogAll) log("[-] ----- %8s of NULL                      by %s", allocationTypes[m_alloc_delete], ownerString(sourceFile, sourceLine, sourceFunc));
  
  	// Resetting the globals insures that if at some later time, somebody calls our memory manager from an unknown
  	// source (i.e. they didn't include our H file) then we won't think it was the last allocation.
  
  	resetGlobals();
  
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] EXIT : delete");
  	#endif
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	operator delete[](void *reportedAddress)
  {
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] ENTER: delete[]");
  	#endif
  
  	// ANSI says: delete & delete[] allow NULL pointers (they do nothing)
  
  	if (reportedAddress) m_deallocator(sourceFile, sourceLine, sourceFunc, m_alloc_delete_array, reportedAddress);
  	else if (alwaysLogAll)
  		log("[-] ----- %8s of NULL                      by %s", allocationTypes[m_alloc_delete_array], ownerString(sourceFile, sourceLine, sourceFunc));
  
  	// Resetting the globals insures that if at some later time, somebody calls our memory manager from an unknown
  	// source (i.e. they didn't include our H file) then we won't think it was the last allocation.
  
  	resetGlobals();
  
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] EXIT : delete[]");
  	#endif
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Allocate memory and track it
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	*m_allocator(const char *sourceFile, const unsigned int sourceLine, const char *sourceFunc, const unsigned int allocationType, const size_t reportedSize)
  {
  	try
  	{
  		#ifdef TEST_MEMORY_MANAGER
  		log("[D] ENTER: m_allocator()");
  		#endif
  
  		// Increase our allocation count
  
  		currentAllocationCount++;
  
  		// Log the request
  
  		if (alwaysLogAll) log("[+] %05d %8s of size 0x%08X(%08d) by %s", currentAllocationCount, allocationTypes[allocationType], reportedSize, reportedSize, ownerString(sourceFile, sourceLine, sourceFunc));
  
  		// If you hit this assert, you requested a breakpoint on a specific allocation count
  		m_assert(currentAllocationCount != breakOnAllocationCount);
  
  		// If necessary, grow the reservoir of unused allocation units
  
  		if (!reservoir)
  		{
  			// Allocate 256 reservoir elements
  
  			reservoir = (sAllocUnit *) malloc(sizeof(sAllocUnit) * 256);
  
  			// If you hit this assert, then the memory manager failed to allocate internal memory for tracking the
  			// allocations
  			m_assert(reservoir != NULL);
  
  			// Danger Will Robinson!
  
  			if (reservoir == NULL) throw "Unable to allocate RAM for internal memory tracking data";
  
  			// Build a linked-list of the elements in our reservoir
  
  			memset(reservoir, 0, sizeof(sAllocUnit) * 256);
  			for (unsigned int i = 0; i < 256 - 1; i++)
  			{
  				reservoir[i].next = &reservoir[i+1];
  			}
  
  			// Add this address to our reservoirBuffer so we can free it later
  
  			sAllocUnit	**temp = (sAllocUnit **) realloc(reservoirBuffer, (reservoirBufferSize + 1) * sizeof(sAllocUnit *));
  			m_assert(temp);
  			if (temp)
  			{
  				reservoirBuffer = temp;
  				reservoirBuffer[reservoirBufferSize++] = reservoir;
  			}
  		}
  
  		// Logical flow says this should never happen...
  		m_assert(reservoir != NULL);
  
  		// Grab a new allocaton unit from the front of the reservoir
  
  		sAllocUnit	*au = reservoir;
  		reservoir = au->next;
  
  		// Populate it with some real data
  
  		memset(au, 0, sizeof(sAllocUnit));
  		au->actualSize        = calculateActualSize(reportedSize);
  		#ifdef RANDOM_FAILURE
  		double	a = rand();
  		double	b = RAND_MAX / 100.0 * RANDOM_FAILURE;
  		if (a > b)
  		{
  			au->actualAddress = malloc(au->actualSize);
  		}
  		else
  		{
  			log("[F] Random faiure");
  			au->actualAddress = NULL;
  		}
  		#else
  		au->actualAddress     = malloc(au->actualSize);
  		#endif
  		au->reportedSize      = reportedSize;
  		au->reportedAddress   = calculateReportedAddress(au->actualAddress);
  		au->allocationType    = allocationType;
  		au->sourceLine        = sourceLine;
  		au->allocationNumber  = currentAllocationCount;
  		if (sourceFile) strncpy(au->sourceFile, sourceFileStripper(sourceFile), sizeof(au->sourceFile) - 1);
  		else		strcpy (au->sourceFile, "??");
  		if (sourceFunc) strncpy(au->sourceFunc, sourceFunc, sizeof(au->sourceFunc) - 1);
  		else		strcpy (au->sourceFunc, "??");
  
  		// We don't want to assert with random failures, because we want the application to deal with them.
  
  		#ifndef RANDOM_FAILURE
  		// If you hit this assert, then the requested allocation simply failed (you're out of memory.) Interrogate the
  		// variable 'au' or the stack frame to see what you were trying to do.
  		m_assert(au->actualAddress != NULL);
  		#endif
  
  		if (au->actualAddress == NULL)
  		{
  			throw "Request for allocation failed. Out of memory.";
  		}
  
  		// If you hit this assert, then this allocation was made from a source that isn't setup to use this memory tracking
  		// software, use the stack frame to locate the source and include our H file.
  		m_assert(allocationType != m_alloc_unknown);
  
  		// Insert the new allocation into the hash table
  
  		unsigned int	hashIndex = ((unsigned int) au->reportedAddress >> 4) & (hashSize - 1);
  		if (hashTable[hashIndex]) hashTable[hashIndex]->prev = au;
  		au->next = hashTable[hashIndex];
  		au->prev = NULL;
  		hashTable[hashIndex] = au;
  
  		// Account for the new allocatin unit in our stats
  
  		stats.totalReportedMemory += au->reportedSize;
  		stats.totalActualMemory   += au->actualSize;
  		stats.totalAllocUnitCount++;
  		if (stats.totalReportedMemory > stats.peakReportedMemory) stats.peakReportedMemory = stats.totalReportedMemory;
  		if (stats.totalActualMemory   > stats.peakActualMemory)   stats.peakActualMemory   = stats.totalActualMemory;
  		if (stats.totalAllocUnitCount > stats.peakAllocUnitCount) stats.peakAllocUnitCount = stats.totalAllocUnitCount;
  		stats.accumulatedReportedMemory += au->reportedSize;
  		stats.accumulatedActualMemory += au->actualSize;
  		stats.accumulatedAllocUnitCount++;
  
  		// Prepare the allocation unit for use (wipe it with recognizable garbage)
  
  		wipeWithPattern(au, unusedPattern);
  
  		// calloc() expects the reported memory address range to be filled with 0's
  
  		if (allocationType == m_alloc_calloc)
  		{
  			memset(au->reportedAddress, 0, au->reportedSize);
  		}
  
  		// Validate every single allocated unit in memory
  
  		if (alwaysValidateAll) m_validateAllAllocUnits();
  
  		// Log the result
  
  		if (alwaysLogAll) log("[+] ---->             addr 0x%08X", (unsigned int) au->reportedAddress);
  
  		// Resetting the globals insures that if at some later time, somebody calls our memory manager from an unknown
  		// source (i.e. they didn't include our H file) then we won't think it was the last allocation.
  
  		resetGlobals();
  
  		// Return the (reported) address of the new allocation unit
  
  		#ifdef TEST_MEMORY_MANAGER
  		log("[D] EXIT : m_allocator()");
  		#endif
  
  		return au->reportedAddress;
  	}
  	catch(const char *err)
  	{
  		// Deal with the errors
  
  		log("[!] %s", err);
  		resetGlobals();
  
  		#ifdef TEST_MEMORY_MANAGER
  		log("[D] EXIT : m_allocator()");
  		#endif
  
  		return NULL;
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Reallocate memory and track it
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	*m_reallocator(const char *sourceFile, const unsigned int sourceLine, const char *sourceFunc, const unsigned int reallocationType, const size_t reportedSize, void *reportedAddress)
  {
  	try
  	{
  		#ifdef TEST_MEMORY_MANAGER
  		log("[D] ENTER: m_reallocator()");
  		#endif
  
  		// Calling realloc with a NULL should force same operations as a malloc
  
  		if (!reportedAddress)
  		{
  			return m_allocator(sourceFile, sourceLine, sourceFunc, reallocationType, reportedSize);
  		}
  
  		// Increase our allocation count
  
  		currentAllocationCount++;
  
  		// If you hit this assert, you requested a breakpoint on a specific allocation count
  		m_assert(currentAllocationCount != breakOnAllocationCount);
  
  		// Log the request
  
  		if (alwaysLogAll) log("[~] %05d %8s of size 0x%08X(%08d) by %s", currentAllocationCount, allocationTypes[reallocationType], reportedSize, reportedSize, ownerString(sourceFile, sourceLine, sourceFunc));
  
  		// Locate the existing allocation unit
  
  		sAllocUnit	*au = findAllocUnit(reportedAddress);
  
  		// If you hit this assert, you tried to reallocate RAM that wasn't allocated by this memory manager.
  		m_assert(au != NULL);
  		if (au == NULL) throw "Request to reallocate RAM that was never allocated";
  
  		// If you hit this assert, then the allocation unit that is about to be reallocated is damaged. But you probably
  		// already know that from a previous assert you should have seen in validateAllocUnit() :)
  		m_assert(m_validateAllocUnit(au));
  
  		// If you hit this assert, then this reallocation was made from a source that isn't setup to use this memory
  		// tracking software, use the stack frame to locate the source and include our H file.
  		m_assert(reallocationType != m_alloc_unknown);
  
  		// If you hit this assert, you were trying to reallocate RAM that was not allocated in a way that is compatible with
  		// realloc. In other words, you have a allocation/reallocation mismatch.
  		m_assert(au->allocationType == m_alloc_malloc ||
  			 au->allocationType == m_alloc_calloc ||
  			 au->allocationType == m_alloc_realloc);
  
  		// If you hit this assert, then the "break on realloc" flag for this allocation unit is set (and will continue to be
  		// set until you specifically shut it off. Interrogate the 'au' variable to determine information about this
  		// allocation unit.
  		m_assert(au->breakOnRealloc == false);
  
  		// Keep track of the original size
  
  		unsigned int	originalReportedSize = au->reportedSize;
  
  		if (alwaysLogAll) log("[~] ---->             from 0x%08X(%08d)", originalReportedSize, originalReportedSize);
  
  		// Do the reallocation
  
  		void	*oldReportedAddress = reportedAddress;
  		size_t	newActualSize = calculateActualSize(reportedSize);
  		void	*newActualAddress = NULL;
  		#ifdef RANDOM_FAILURE
  		double	a = rand();
  		double	b = RAND_MAX / 100.0 * RANDOM_FAILURE;
  		if (a > b)
  		{
  			newActualAddress = realloc(au->actualAddress, newActualSize);
  		}
  		else
  		{
  			log("[F] Random faiure");
  		}
  		#else
  		newActualAddress = realloc(au->actualAddress, newActualSize);
  		#endif
  
  		// We don't want to assert with random failures, because we want the application to deal with them.
  
  		#ifndef RANDOM_FAILURE
  		// If you hit this assert, then the requested allocation simply failed (you're out of memory) Interrogate the
  		// variable 'au' to see the original allocation. You can also query 'newActualSize' to see the amount of memory
  		// trying to be allocated. Finally, you can query 'reportedSize' to see how much memory was requested by the caller.
  		m_assert(newActualAddress);
  		#endif
  
  		if (!newActualAddress) throw "Request for reallocation failed. Out of memory.";
  
  		// Remove this allocation from our stats (we'll add the new reallocation again later)
  
  		stats.totalReportedMemory -= au->reportedSize;
  		stats.totalActualMemory   -= au->actualSize;
  
  		// Update the allocation with the new information
  
  		au->actualSize        = newActualSize;
  		au->actualAddress     = newActualAddress;
  		au->reportedSize      = calculateReportedSize(newActualSize);
  		au->reportedAddress   = calculateReportedAddress(newActualAddress);
  		au->allocationType    = reallocationType;
  		au->sourceLine        = sourceLine;
  		au->allocationNumber  = currentAllocationCount;
  		if (sourceFile) strncpy(au->sourceFile, sourceFileStripper(sourceFile), sizeof(au->sourceFile) - 1);
  		else		strcpy (au->sourceFile, "??");
  		if (sourceFunc) strncpy(au->sourceFunc, sourceFunc, sizeof(au->sourceFunc) - 1);
  		else		strcpy (au->sourceFunc, "??");
  
  		// The reallocation may cause the address to change, so we should relocate our allocation unit within the hash table
  
  		unsigned int	hashIndex = (unsigned int) -1;
  		if (oldReportedAddress != au->reportedAddress)
  		{
  			// Remove this allocation unit from the hash table
  
  			{
  				unsigned int	hashIndex = ((unsigned int) oldReportedAddress >> 4) & (hashSize - 1);
  				if (hashTable[hashIndex] == au)
  				{
  					hashTable[hashIndex] = hashTable[hashIndex]->next;
  				}
  				else
  				{
  					if (au->prev)	au->prev->next = au->next;
  					if (au->next)	au->next->prev = au->prev;
  				}
  			}
  
  			// Re-insert it back into the hash table
  
  			hashIndex = ((unsigned int) au->reportedAddress >> 4) & (hashSize - 1);
  			if (hashTable[hashIndex]) hashTable[hashIndex]->prev = au;
  			au->next = hashTable[hashIndex];
  			au->prev = NULL;
  			hashTable[hashIndex] = au;
  		}
  
  		// Account for the new allocatin unit in our stats
  
  		stats.totalReportedMemory += au->reportedSize;
  		stats.totalActualMemory   += au->actualSize;
  		if (stats.totalReportedMemory > stats.peakReportedMemory) stats.peakReportedMemory = stats.totalReportedMemory;
  		if (stats.totalActualMemory   > stats.peakActualMemory)   stats.peakActualMemory   = stats.totalActualMemory;
  		int	deltaReportedSize = reportedSize - originalReportedSize;
  		if (deltaReportedSize > 0)
  		{
  			stats.accumulatedReportedMemory += deltaReportedSize;
  			stats.accumulatedActualMemory += deltaReportedSize;
  		}
  
  		// Prepare the allocation unit for use (wipe it with recognizable garbage)
  
  		wipeWithPattern(au, unusedPattern, originalReportedSize);
  
  		// If you hit this assert, then something went wrong, because the allocation unit was properly validated PRIOR to
  		// the reallocation. This should not happen.
  		m_assert(m_validateAllocUnit(au));
  
  		// Validate every single allocated unit in memory
  
  		if (alwaysValidateAll) m_validateAllAllocUnits();
  
  		// Log the result
  
  		if (alwaysLogAll) log("[~] ---->             addr 0x%08X", (unsigned int) au->reportedAddress);
  
  		// Resetting the globals insures that if at some later time, somebody calls our memory manager from an unknown
  		// source (i.e. they didn't include our H file) then we won't think it was the last allocation.
  
  		resetGlobals();
  
  		// Return the (reported) address of the new allocation unit
  
  		#ifdef TEST_MEMORY_MANAGER
  		log("[D] EXIT : m_reallocator()");
  		#endif
  
  		return au->reportedAddress;
  	}
  	catch(const char *err)
  	{
  		// Deal with the errors
  
  		log("[!] %s", err);
  		resetGlobals();
  
  		#ifdef TEST_MEMORY_MANAGER
  		log("[D] EXIT : m_reallocator()");
  		#endif
  
  		return NULL;
  	}
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // Deallocate memory and track it
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	m_deallocator(const char *sourceFile, const unsigned int sourceLine, const char *sourceFunc, const unsigned int deallocationType, const void *reportedAddress)
  {
  	try
  	{
  		#ifdef TEST_MEMORY_MANAGER
  		log("[D] ENTER: m_deallocator()");
  		#endif
  
  		// Log the request
  
  		if (alwaysLogAll) log("[-] ----- %8s of addr 0x%08X           by %s", allocationTypes[deallocationType], (unsigned int) reportedAddress, ownerString(sourceFile, sourceLine, sourceFunc));
  
  		// Go get the allocation unit
  
  		sAllocUnit	*au = findAllocUnit(reportedAddress);
  
  		// If you hit this assert, you tried to deallocate RAM that wasn't allocated by this memory manager.
  		m_assert(au != NULL);
  		if (au == NULL) throw "Request to deallocate RAM that was never allocated";
  
  		// If you hit this assert, then the allocation unit that is about to be deallocated is damaged. But you probably
  		// already know that from a previous assert you should have seen in validateAllocUnit() :)
  		m_assert(m_validateAllocUnit(au));
  
  		// If you hit this assert, then this deallocation was made from a source that isn't setup to use this memory
  		// tracking software, use the stack frame to locate the source and include our H file.
  		m_assert(deallocationType != m_alloc_unknown);
  
  		// If you hit this assert, you were trying to deallocate RAM that was not allocated in a way that is compatible with
  		// the deallocation method requested. In other words, you have a allocation/deallocation mismatch.
  		m_assert((deallocationType == m_alloc_delete       && au->allocationType == m_alloc_new      ) ||
  			 (deallocationType == m_alloc_delete_array && au->allocationType == m_alloc_new_array) ||
  			 (deallocationType == m_alloc_free         && au->allocationType == m_alloc_malloc   ) ||
  			 (deallocationType == m_alloc_free         && au->allocationType == m_alloc_calloc   ) ||
  			 (deallocationType == m_alloc_free         && au->allocationType == m_alloc_realloc  ) ||
  			 (deallocationType == m_alloc_unknown                                                ) );
  
  		// If you hit this assert, then the "break on dealloc" flag for this allocation unit is set. Interrogate the 'au'
  		// variable to determine information about this allocation unit.
  		m_assert(au->breakOnDealloc == false);
  
  		// Wipe the deallocated RAM with a new pattern. This doen't actually do us much good in debug mode under WIN32,
  		// because Microsoft's memory debugging & tracking utilities will wipe it right after we do. Oh well.
  
  		wipeWithPattern(au, releasedPattern);
  
  		// Do the deallocation
  
  		free(au->actualAddress);
  
  		// Remove this allocation unit from the hash table
  
  		unsigned int	hashIndex = ((unsigned int) au->reportedAddress >> 4) & (hashSize - 1);
  		if (hashTable[hashIndex] == au)
  		{
  			hashTable[hashIndex] = au->next;
  		}
  		else
  		{
  			if (au->prev)	au->prev->next = au->next;
  			if (au->next)	au->next->prev = au->prev;
  		}
  
  		// Remove this allocation from our stats
  
  		stats.totalReportedMemory -= au->reportedSize;
  		stats.totalActualMemory   -= au->actualSize;
  		stats.totalAllocUnitCount--;
  
  		// Add this allocation unit to the front of our reservoir of unused allocation units
  
  		memset(au, 0, sizeof(sAllocUnit));
  		au->next = reservoir;
  		reservoir = au;
  
  		// Resetting the globals insures that if at some later time, somebody calls our memory manager from an unknown
  		// source (i.e. they didn't include our H file) then we won't think it was the last allocation.
  
  		resetGlobals();
  
  		// Validate every single allocated unit in memory
  
  		if (alwaysValidateAll) m_validateAllAllocUnits();
  
  		// If we're in the midst of static deinitialization time, track any pending memory leaks
  
  		if (staticDeinitTime) dumpLeakReport();
  	}
  	catch(const char *err)
  	{
  		// Deal with errors
  
  		log("[!] %s", err);
  		resetGlobals();
  	}
  
  	#ifdef TEST_MEMORY_MANAGER
  	log("[D] EXIT : m_deallocator()");
  	#endif
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- The following utilitarian allow you to become proactive in tracking your own memory, or help you narrow in on those tough
  // bugs.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	m_validateAddress(const void *reportedAddress)
  {
  	// Just see if the address exists in our allocation routines
  
  	return findAllocUnit(reportedAddress) != NULL;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	m_validateAllocUnit(const sAllocUnit *allocUnit)
  {
  	// Make sure the padding is untouched
  
  	long	*pre = (long *) allocUnit->actualAddress;
  	long	*post = (long *) ((char *)allocUnit->actualAddress + allocUnit->actualSize - paddingSize * sizeof(long));
  	bool	errorFlag = false;
  	for (unsigned int i = 0; i < paddingSize; i++, pre++, post++)
  	{
  		if (*pre != (long) prefixPattern)
  		{
  			log("[!] A memory allocation unit was corrupt because of an underrun:");
  			m_dumpAllocUnit(allocUnit, "  ");
  			errorFlag = true;
  		}
  
  		// If you hit this assert, then you should know that this allocation unit has been damaged. Something (possibly the
  		// owner?) has underrun the allocation unit (modified a few bytes prior to the start). You can interrogate the
  		// variable 'allocUnit' to see statistics and information about this damaged allocation unit.
  		m_assert(*pre == (long) prefixPattern);
  
  		if (*post != (long) postfixPattern)
  		{
  			log("[!] A memory allocation unit was corrupt because of an overrun:");
  			m_dumpAllocUnit(allocUnit, "  ");
  			errorFlag = true;
  		}
  
  		// If you hit this assert, then you should know that this allocation unit has been damaged. Something (possibly the
  		// owner?) has overrun the allocation unit (modified a few bytes after the end). You can interrogate the variable
  		// 'allocUnit' to see statistics and information about this damaged allocation unit.
  		m_assert(*post == (long) postfixPattern);
  	}
  
  	// Return the error status (we invert it, because a return of 'false' means error)
  
  	return !errorFlag;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  bool	m_validateAllAllocUnits()
  {
  	// Just go through each allocation unit in the hash table and count the ones that have errors
  
  	unsigned int	errors = 0;
  	unsigned int	allocCount = 0;
  	for (unsigned int i = 0; i < hashSize; i++)
  	{
  		sAllocUnit	*ptr = hashTable[i];
  		while(ptr)
  		{
  			allocCount++;
  			if (!m_validateAllocUnit(ptr)) errors++;
  			ptr = ptr->next;
  		}
  	}
  
  	// Test for hash-table correctness
  
  	if (allocCount != stats.totalAllocUnitCount)
  	{
  		log("[!] Memory tracking hash table corrupt!");
  		errors++;
  	}
  
  	// If you hit this assert, then the internal memory (hash table) used by this memory tracking software is damaged! The
  	// best way to track this down is to use the alwaysLogAll flag in conjunction with STRESS_TEST macro to narrow in on the
  	// offending code. After running the application with these settings (and hitting this assert again), interrogate the
  	// memory.log file to find the previous successful operation. The corruption will have occurred between that point and this
  	// assertion.
  	m_assert(allocCount == stats.totalAllocUnitCount);
  
  	// If you hit this assert, then you've probably already been notified that there was a problem with a allocation unit in a
  	// prior call to validateAllocUnit(), but this assert is here just to make sure you know about it. :)
  	m_assert(errors == 0);
  
  	// Log any errors
  
  	if (errors) log("[!] While validting all allocation units, %d allocation unit(s) were found to have problems", errors);
  
  	// Return the error status
  
  	return errors != 0;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- Unused RAM calculation routines. Use these to determine how much of your RAM is unused (in bytes)
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  unsigned int	m_calcUnused(const sAllocUnit *allocUnit)
  {
  	const unsigned long	*ptr = (const unsigned long *) allocUnit->reportedAddress;
  	unsigned int		count = 0;
  
  	for (unsigned int i = 0; i < allocUnit->reportedSize; i += sizeof(long), ptr++)
  	{
  		if (*ptr == unusedPattern) count += sizeof(long);
  	}
  
  	return count;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  unsigned int	m_calcAllUnused()
  {
  	// Just go through each allocation unit in the hash table and count the unused RAM
  
  	unsigned int	total = 0;
  	for (unsigned int i = 0; i < hashSize; i++)
  	{
  		sAllocUnit	*ptr = hashTable[i];
  		while(ptr)
  		{
  			total += m_calcUnused(ptr);
  			ptr = ptr->next;
  		}
  	}
  
  	return total;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // -DOC- The following functions are for logging and statistics reporting.
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	m_dumpAllocUnit(const sAllocUnit *allocUnit, const char *prefix)
  {
  	log("[I] %sAddress (reported): %010p",       prefix, allocUnit->reportedAddress);
  	log("[I] %sAddress (actual)  : %010p",       prefix, allocUnit->actualAddress);
  	log("[I] %sSize (reported)   : 0x%08X (%s)", prefix, allocUnit->reportedSize, memorySizeString(allocUnit->reportedSize));
  	log("[I] %sSize (actual)     : 0x%08X (%s)", prefix, allocUnit->actualSize, memorySizeString(allocUnit->actualSize));
  	log("[I] %sOwner             : %s(%d)::%s",  prefix, allocUnit->sourceFile, allocUnit->sourceLine, allocUnit->sourceFunc);
  	log("[I] %sAllocation type   : %s",          prefix, allocationTypes[allocUnit->allocationType]);
  	log("[I] %sAllocation number : %d",          prefix, allocUnit->allocationNumber);
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  void	m_dumpMemoryReport(const char *filename, const bool overwrite)
  {
  	// Open the report file
  
  	FILE	*fp = NULL;
  
  	if (overwrite)	fp = fopen(filename, "w+b");
  	else		fp = fopen(filename, "ab");
  
  	// If you hit this assert, then the memory report generator is unable to log information to a file (can't open the file for
  	// some reason.)
  	m_assert(fp);
  	if (!fp) return;
  
          // Header
  
          static  char    timeString[25];
          memset(timeString, 0, sizeof(timeString));
          time_t  t = time(NULL);
          struct  tm *tme = localtime(&t);
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
          fprintf(fp, "|                                             Memory report for: %02d/%02d/%04d %02d:%02d:%02d                                               |\r\n", tme->tm_mon + 1, tme->tm_mday, tme->tm_year + 1900, tme->tm_hour, tme->tm_min, tme->tm_sec);
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "\r\n");
  	fprintf(fp, "\r\n");
  
  	// Report summary
  
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "|                                                           T O T A L S                                                            |\r\n");
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "              Allocation unit count: %10s\r\n", insertCommas(stats.totalAllocUnitCount));
  	fprintf(fp, "            Reported to application: %s\r\n", memorySizeString(stats.totalReportedMemory));
  	fprintf(fp, "         Actual total memory in use: %s\r\n", memorySizeString(stats.totalActualMemory));
  	fprintf(fp, "           Memory tracking overhead: %s\r\n", memorySizeString(stats.totalActualMemory - stats.totalReportedMemory));
  	fprintf(fp, "\r\n");
  
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "|                                                            P E A K S                                                             |\r\n");
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "              Allocation unit count: %10s\r\n", insertCommas(stats.peakAllocUnitCount));
  	fprintf(fp, "            Reported to application: %s\r\n", memorySizeString(stats.peakReportedMemory));
  	fprintf(fp, "                             Actual: %s\r\n", memorySizeString(stats.peakActualMemory));
  	fprintf(fp, "           Memory tracking overhead: %s\r\n", memorySizeString(stats.peakActualMemory - stats.peakReportedMemory));
  	fprintf(fp, "\r\n");
  
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "|                                                      A C C U M U L A T E D                                                       |\r\n");
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "              Allocation unit count: %s\r\n", memorySizeString(stats.accumulatedAllocUnitCount));
  	fprintf(fp, "            Reported to application: %s\r\n", memorySizeString(stats.accumulatedReportedMemory));
  	fprintf(fp, "                             Actual: %s\r\n", memorySizeString(stats.accumulatedActualMemory));
  	fprintf(fp, "\r\n");
  
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "|                                                           U N U S E D                                                            |\r\n");
  	fprintf(fp, " ---------------------------------------------------------------------------------------------------------------------------------- \r\n");
  	fprintf(fp, "    Memory allocated but not in use: %s\r\n", memorySizeString(m_calcAllUnused()));
  	fprintf(fp, "\r\n");
  
  	dumpAllocations(fp);
  
  	fclose(fp);
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  
  sMStats	m_getMemoryStatistics()
  {
  	return stats;
  }
  
  // ---------------------------------------------------------------------------------------------------------------------------------
  // mmgr.cpp - End of file
  // ---------------------------------------------------------------------------------------------------------------------------------
  

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