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/* -*- Mode: C; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
*
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* This Source Code Form is subject to the terms of the Mozilla Public
* License , v . 2.0 . If a copy of the MPL was not distributed with this
* file , You can obtain one at http : //mozilla.org/MPL/2.0/. */
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# include <stdio.h>
# include <stdlib.h>
# include <string.h>
# include <time.h>
# include <ctype.h>
# include <errno.h>
# include <math.h>
# include "nspr.h"
# include "tmreader.h"
# define ERROR_REPORT(num, val, msg) fprintf(stderr, "error(%d):\t\"%s\"\t%s\n", (num), (val), (msg));
# define CLEANUP(ptr) do { if(NULL != ptr) { free(ptr); ptr = NULL; } } while(0)
# define ticks2msec(reader, ticks) ticks2xsec((reader), (ticks), 1000)
# define ticks2usec(reader, ticks) ticks2xsec((reader), (ticks), 1000000)
# define TICK_RESOLUTION 1000
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# define TICK_PRINTABLE(timeval) ((double)(timeval) / (double)ST_TIMEVAL_RESOLUTION)
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typedef struct __struct_Options
/*
* * Options to control how we perform .
* *
* * mProgramName Used in help text .
* * mInputName Name of the file .
* * mOutput Output file , append .
* * Default is stdout .
* * mOutputName Name of the file .
* * mHelp Whether or not help should be shown .
* * mOverhead How much overhead an allocation will have .
* * mAlignment What boundry will the end of an allocation line up on .
* * mPageSize Controls the page size . A page containing only fragments
* * is not fragmented . A page containing any life memory
* * costs mPageSize in bytes .
*/
{
const char * mProgramName ;
char * mInputName ;
FILE * mOutput ;
char * mOutputName ;
int mHelp ;
unsigned mOverhead ;
unsigned mAlignment ;
unsigned mPageSize ;
}
Options ;
typedef struct __struct_Switch
/*
* * Command line options .
*/
{
const char * mLongName ;
const char * mShortName ;
int mHasValue ;
const char * mValue ;
const char * mDescription ;
}
Switch ;
# define DESC_NEWLINE "\n\t\t"
static Switch gInputSwitch = { " --input " , " -i " , 1 , NULL , " Specify input file. " DESC_NEWLINE " stdin is default. " } ;
static Switch gOutputSwitch = { " --output " , " -o " , 1 , NULL , " Specify output file. " DESC_NEWLINE " Appends if file exists. " DESC_NEWLINE " stdout is default. " } ;
static Switch gHelpSwitch = { " --help " , " -h " , 0 , NULL , " Information on usage. " } ;
static Switch gAlignmentSwitch = { " --alignment " , " -al " , 1 , NULL , " All allocation sizes are made to be a multiple of this number. " DESC_NEWLINE " Closer to actual heap conditions; set to 1 for true sizes. " DESC_NEWLINE " Default value is 16. " } ;
static Switch gOverheadSwitch = { " --overhead " , " -ov " , 1 , NULL , " After alignment, all allocations are made to increase by this number. " DESC_NEWLINE " Closer to actual heap conditions; set to 0 for true sizes. " DESC_NEWLINE " Default value is 8. " } ;
static Switch gPageSizeSwitch = { " --page-size " , " -ps " , 1 , NULL , " Sets the page size which aids the identification of fragmentation. " DESC_NEWLINE " Closer to actual heap conditions; set to 4294967295 for true sizes. " DESC_NEWLINE " Default value is 4096. " } ;
static Switch * gSwitches [ ] = {
& gInputSwitch ,
& gOutputSwitch ,
& gAlignmentSwitch ,
& gOverheadSwitch ,
& gPageSizeSwitch ,
& gHelpSwitch
} ;
typedef struct __struct_AnyArray
/*
* * Variable sized item array .
* *
* * mItems The void pointer items .
* * mItemSize Size of each different item .
* * mCount The number of items in the array .
* * mCapacity How many more items we can hold before reallocing .
* * mGrowBy How many items we allocate when we grow .
*/
{
void * mItems ;
unsigned mItemSize ;
unsigned mCount ;
unsigned mCapacity ;
unsigned mGrowBy ;
}
AnyArray ;
typedef int ( * arrayMatchFunc ) ( void * inContext , AnyArray * inArray , void * inItem , unsigned inItemIndex )
/*
* * Callback function for the arrayIndexFn function .
* * Used to determine an item match by customizable criteria .
* *
* * inContext The criteria and state of the search .
* * User specified / created .
* * inArray The array the item is in .
* * inItem The item to evaluate for match .
* * inItemIndex The index of this particular item in the array .
* *
* * return int 0 to specify a match .
* * ! 0 to continue the search performed by arrayIndexFn .
*/
;
typedef enum __enum_HeapEventType
/*
* * Simple heap events are really one of two things .
*/
{
FREE ,
ALLOC
}
HeapEventType ;
typedef enum __enum_HeapObjectType
/*
* * The various types of heap objects we track .
*/
{
ALLOCATION ,
FRAGMENT
}
HeapObjectType ;
typedef struct __struct_HeapObject HeapObject ;
typedef struct __struct_HeapHistory
/*
* * A marker as to what has happened .
* *
* * mTimestamp When history occurred .
* * mTMRSerial The historical state as known to the tmreader .
* * mObjectIndex Index to the object that was before or after this event .
* * The index as in the index according to all heap objects
* * kept in the TMState structure .
* * We use an index instead of a pointer as the array of
* * objects can change location in the heap .
*/
{
unsigned mTimestamp ;
unsigned mTMRSerial ;
unsigned mObjectIndex ;
}
HeapHistory ;
struct __struct_HeapObject
/*
* * An object in the heap .
* *
* * A special case should be noted here . If either the birth or death
* * history leads to an object of the same type , then this object
* * is the same as that object , but was modified somehow .
* * Also note that multiple objects may have the same birth object ,
* * as well as the same death object .
* *
* * mUniqueID Each object is unique .
* * mType Either allocation or fragment .
* * mHeapOffset Where in the heap the object is .
* * mSize How much of the heap the object takes .
* * mBirth History about the birth event .
* * mDeath History about the death event .
*/
{
unsigned mUniqueID ;
HeapObjectType mType ;
unsigned mHeapOffset ;
unsigned mSize ;
HeapHistory mBirth ;
HeapHistory mDeath ;
} ;
typedef struct __struct_TMState
/*
* * State of our current operation .
* * Stats we are trying to calculate .
* *
* * mOptions Obilgatory options pointer .
* * mTMR The tmreader , used in tmreader API calls .
* * mLoopExitTMR Set to non zero in order to quickly exit from tmreader
* * input loop . This will also result in an error .
* * uMinTicks Start of run , milliseconds .
* * uMaxTicks End of run , milliseconds .
*/
{
Options * mOptions ;
tmreader * mTMR ;
int mLoopExitTMR ;
unsigned uMinTicks ;
unsigned uMaxTicks ;
}
TMState ;
int initOptions ( Options * outOptions , int inArgc , char * * inArgv )
/*
* * returns int 0 if successful .
*/
{
int retval = 0 ;
int loop = 0 ;
int switchLoop = 0 ;
int match = 0 ;
const int switchCount = sizeof ( gSwitches ) / sizeof ( gSwitches [ 0 ] ) ;
Switch * current = NULL ;
/*
* * Set any defaults .
*/
memset ( outOptions , 0 , sizeof ( Options ) ) ;
outOptions - > mProgramName = inArgv [ 0 ] ;
outOptions - > mInputName = strdup ( " - " ) ;
outOptions - > mOutput = stdout ;
outOptions - > mOutputName = strdup ( " stdout " ) ;
outOptions - > mAlignment = 16 ;
outOptions - > mOverhead = 8 ;
if ( NULL = = outOptions - > mOutputName | | NULL = = outOptions - > mInputName )
{
retval = __LINE__ ;
ERROR_REPORT ( retval , " stdin/stdout " , " Unable to strdup. " ) ;
}
/*
* * Go through and attempt to do the right thing .
*/
for ( loop = 1 ; loop < inArgc & & 0 = = retval ; loop + + )
{
match = 0 ;
current = NULL ;
for ( switchLoop = 0 ; switchLoop < switchCount & & 0 = = retval ; switchLoop + + )
{
if ( 0 = = strcmp ( gSwitches [ switchLoop ] - > mLongName , inArgv [ loop ] ) )
{
match = __LINE__ ;
}
else if ( 0 = = strcmp ( gSwitches [ switchLoop ] - > mShortName , inArgv [ loop ] ) )
{
match = __LINE__ ;
}
if ( match )
{
if ( gSwitches [ switchLoop ] - > mHasValue )
{
/*
* * Attempt to absorb next option to fullfill value .
*/
if ( loop + 1 < inArgc )
{
loop + + ;
current = gSwitches [ switchLoop ] ;
current - > mValue = inArgv [ loop ] ;
}
}
else
{
current = gSwitches [ switchLoop ] ;
}
break ;
}
}
if ( 0 = = match )
{
outOptions - > mHelp = __LINE__ ;
retval = __LINE__ ;
ERROR_REPORT ( retval , inArgv [ loop ] , " Unknown command line switch. " ) ;
}
else if ( NULL = = current )
{
outOptions - > mHelp = __LINE__ ;
retval = __LINE__ ;
ERROR_REPORT ( retval , inArgv [ loop ] , " Command line switch requires a value. " ) ;
}
else
{
/*
* * Do something based on address / swtich .
*/
if ( current = = & gInputSwitch )
{
CLEANUP ( outOptions - > mInputName ) ;
outOptions - > mInputName = strdup ( current - > mValue ) ;
if ( NULL = = outOptions - > mInputName )
{
retval = __LINE__ ;
ERROR_REPORT ( retval , current - > mValue , " Unable to strdup. " ) ;
}
}
else if ( current = = & gOutputSwitch )
{
CLEANUP ( outOptions - > mOutputName ) ;
if ( NULL ! = outOptions - > mOutput & & stdout ! = outOptions - > mOutput )
{
fclose ( outOptions - > mOutput ) ;
outOptions - > mOutput = NULL ;
}
outOptions - > mOutput = fopen ( current - > mValue , " a " ) ;
if ( NULL = = outOptions - > mOutput )
{
retval = __LINE__ ;
ERROR_REPORT ( retval , current - > mValue , " Unable to open output file. " ) ;
}
else
{
outOptions - > mOutputName = strdup ( current - > mValue ) ;
if ( NULL = = outOptions - > mOutputName )
{
retval = __LINE__ ;
ERROR_REPORT ( retval , current - > mValue , " Unable to strdup. " ) ;
}
}
}
else if ( current = = & gHelpSwitch )
{
outOptions - > mHelp = __LINE__ ;
}
else if ( current = = & gAlignmentSwitch )
{
unsigned arg = 0 ;
char * endScan = NULL ;
errno = 0 ;
arg = strtoul ( current - > mValue , & endScan , 0 ) ;
if ( 0 = = errno & & endScan ! = current - > mValue )
{
outOptions - > mAlignment = arg ;
}
else
{
retval = __LINE__ ;
ERROR_REPORT ( retval , current - > mValue , " Unable to convert to a number. " ) ;
}
}
else if ( current = = & gOverheadSwitch )
{
unsigned arg = 0 ;
char * endScan = NULL ;
errno = 0 ;
arg = strtoul ( current - > mValue , & endScan , 0 ) ;
if ( 0 = = errno & & endScan ! = current - > mValue )
{
outOptions - > mOverhead = arg ;
}
else
{
retval = __LINE__ ;
ERROR_REPORT ( retval , current - > mValue , " Unable to convert to a number. " ) ;
}
}
else if ( current = = & gPageSizeSwitch )
{
unsigned arg = 0 ;
char * endScan = NULL ;
errno = 0 ;
arg = strtoul ( current - > mValue , & endScan , 0 ) ;
if ( 0 = = errno & & endScan ! = current - > mValue )
{
outOptions - > mPageSize = arg ;
}
else
{
retval = __LINE__ ;
ERROR_REPORT ( retval , current - > mValue , " Unable to convert to a number. " ) ;
}
}
else
{
retval = __LINE__ ;
ERROR_REPORT ( retval , current - > mLongName , " No handler for command line switch. " ) ;
}
}
}
return retval ;
}
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uint32_t ticks2xsec ( tmreader * aReader , uint32_t aTicks , uint32_t aResolution )
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/*
* * Convert platform specific ticks to second units
*/
{
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uint32_t retval = 0 ;
uint64_t bigone ;
uint64_t tmp64 ;
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LL_UI2L ( bigone , aResolution ) ;
LL_UI2L ( tmp64 , aTicks ) ;
LL_MUL ( bigone , bigone , tmp64 ) ;
LL_UI2L ( tmp64 , aReader - > ticksPerSec ) ;
LL_DIV ( bigone , bigone , tmp64 ) ;
LL_L2UI ( retval , bigone ) ;
return retval ;
}
void cleanOptions ( Options * inOptions )
/*
* * Clean up any open handles .
*/
{
unsigned loop = 0 ;
CLEANUP ( inOptions - > mInputName ) ;
CLEANUP ( inOptions - > mOutputName ) ;
if ( NULL ! = inOptions - > mOutput & & stdout ! = inOptions - > mOutput )
{
fclose ( inOptions - > mOutput ) ;
}
memset ( inOptions , 0 , sizeof ( Options ) ) ;
}
void showHelp ( Options * inOptions )
/*
* * Show some simple help text on usage .
*/
{
int loop = 0 ;
const int switchCount = sizeof ( gSwitches ) / sizeof ( gSwitches [ 0 ] ) ;
const char * valueText = NULL ;
printf ( " usage: \t %s [arguments] \n " , inOptions - > mProgramName ) ;
printf ( " \n " ) ;
printf ( " arguments: \n " ) ;
for ( loop = 0 ; loop < switchCount ; loop + + )
{
if ( gSwitches [ loop ] - > mHasValue )
{
valueText = " <value> " ;
}
else
{
valueText = " " ;
}
printf ( " \t %s%s \n " , gSwitches [ loop ] - > mLongName , valueText ) ;
printf ( " \t %s%s " , gSwitches [ loop ] - > mShortName , valueText ) ;
printf ( DESC_NEWLINE " %s \n \n " , gSwitches [ loop ] - > mDescription ) ;
}
printf ( " This tool reports heap fragmentation stats from a trace-malloc log. \n " ) ;
}
AnyArray * arrayCreate ( unsigned inItemSize , unsigned inGrowBy )
/*
* * Create an array container object .
*/
{
AnyArray * retval = NULL ;
if ( 0 ! = inGrowBy & & 0 ! = inItemSize )
{
retval = ( AnyArray * ) calloc ( 1 , sizeof ( AnyArray ) ) ;
retval - > mItemSize = inItemSize ;
retval - > mGrowBy = inGrowBy ;
}
return retval ;
}
void arrayDestroy ( AnyArray * inArray )
/*
* * Release the memory the array contains .
* * This will release the items as well .
*/
{
if ( NULL ! = inArray )
{
if ( NULL ! = inArray - > mItems )
{
free ( inArray - > mItems ) ;
}
free ( inArray ) ;
}
}
unsigned arrayAlloc ( AnyArray * inArray , unsigned inItems )
/*
* * Resize the item array capcity to a specific number of items .
* * This could possibly truncate the array , so handle that as well .
* *
* * returns unsigned < = inArray - > mCapacity on success .
*/
{
unsigned retval = ( unsigned ) - 1 ;
if ( NULL ! = inArray )
{
void * moved = NULL ;
moved = realloc ( inArray - > mItems , inItems * inArray - > mItemSize ) ;
if ( NULL ! = moved )
{
inArray - > mItems = moved ;
inArray - > mCapacity = inItems ;
if ( inArray - > mCount > inItems )
{
inArray - > mCount = inItems ;
}
retval = inItems ;
}
}
return retval ;
}
void * arrayItem ( AnyArray * inArray , unsigned inIndex )
/*
* * Return the array item at said index .
* * Zero based index .
* *
* * returns void * NULL on failure .
*/
{
void * retval = NULL ;
if ( NULL ! = inArray & & inIndex < inArray - > mCount )
{
retval = ( void * ) ( ( char * ) inArray - > mItems + ( inArray - > mItemSize * inIndex ) ) ;
}
return retval ;
}
unsigned arrayIndex ( AnyArray * inArray , void * inItem , unsigned inStartIndex )
/*
* * Go through the array from the index specified looking for an item
* * match based on byte for byte comparison .
* * We allow specifying the start index in order to handle arrays with
* * duplicate items .
* *
* * returns unsigned > = inArray - > mCount on failure .
*/
{
unsigned retval = ( unsigned ) - 1 ;
if ( NULL ! = inArray & & NULL ! = inItem & & inStartIndex < inArray - > mCount )
{
void * curItem = NULL ;
for ( retval = inStartIndex ; retval < inArray - > mCount ; retval + + )
{
curItem = arrayItem ( inArray , retval ) ;
if ( 0 = = memcmp ( inItem , curItem , inArray - > mItemSize ) )
{
break ;
}
}
}
return retval ;
}
unsigned arrayIndexFn ( AnyArray * inArray , arrayMatchFunc inFunc , void * inFuncContext , unsigned inStartIndex )
/*
* * Go through the array from the index specified looking for an item
* * match based upon the return value of inFunc ( 0 , Zero , is a match ) .
* * We allow specifying the start index in order to facilitate looping over
* * the array which could have multiple matches .
* *
* * returns unsigned > = inArray - > mCount on failure .
*/
{
unsigned retval = ( unsigned ) - 1 ;
if ( NULL ! = inArray & & NULL ! = inFunc & & inStartIndex < inArray - > mCount )
{
void * curItem = NULL ;
for ( retval = inStartIndex ; retval < inArray - > mCount ; retval + + )
{
curItem = arrayItem ( inArray , retval ) ;
if ( 0 = = inFunc ( inFuncContext , inArray , curItem , retval ) )
{
break ;
}
}
}
return retval ;
}
unsigned arrayAddItem ( AnyArray * inArray , void * inItem )
/*
* * Add a new item to the array .
* * This is done by copying the item .
* *
* * returns unsigned < inArray - > mCount on success .
*/
{
unsigned retval = ( unsigned ) - 1 ;
if ( NULL ! = inArray & & NULL ! = inItem )
{
int noCopy = 0 ;
/*
* * See if the array should grow .
*/
if ( inArray - > mCount = = inArray - > mCapacity )
{
unsigned allocRes = 0 ;
allocRes = arrayAlloc ( inArray , inArray - > mCapacity + inArray - > mGrowBy ) ;
if ( allocRes > inArray - > mCapacity )
{
noCopy = __LINE__ ;
}
}
if ( 0 = = noCopy )
{
retval = inArray - > mCount ;
inArray - > mCount + + ;
memcpy ( arrayItem ( inArray , retval ) , inItem , inArray - > mItemSize ) ;
}
}
return retval ;
}
HeapObject * initHeapObject ( HeapObject * inObject )
/*
* * Function to init the heap object just right .
* * Sets the unique ID to something unique .
*/
{
HeapObject * retval = inObject ;
if ( NULL ! = inObject )
{
static unsigned uniqueGenerator = 0 ;
memset ( inObject , - 1 , sizeof ( HeapObject ) ) ;
inObject - > mUniqueID = uniqueGenerator ;
uniqueGenerator + + ;
}
return retval ;
}
int simpleHeapEvent ( TMState * inStats , HeapEventType inType , unsigned mTimestamp , unsigned inSerial , unsigned inHeapID , unsigned inSize )
/*
* * A new heap event will cause the creation of a new heap object .
* * The new heap object will displace , or replace , a heap object of a different type .
*/
{
int retval = 0 ;
HeapObject newObject ;
/*
* * Set the most basic object details .
*/
initHeapObject ( & newObject ) ;
newObject . mHeapOffset = inHeapID ;
newObject . mSize = inSize ;
if ( FREE = = inType )
{
newObject . mType = FRAGMENT ;
}
else if ( ALLOC = = inType )
{
newObject . mType = ALLOCATION ;
}
/*
* * Add it to the heap object array .
*/
/*
* * TODO GAB
* *
* * First thing to do is to add the new object to the heap in order to
* * obtain a valid index .
* *
* * Next , find all matches to this range of heap memory that this event
* * refers to , that are alive during this timestamp ( no death yet ) .
* * Fill in the death event of those objects .
* * If the objects contain some portions outside of the range , then
* * new objects for those ranges need to be created that carry on
* * the same object type , have the index of the old object for birth ,
* * and the serial of the old object , new timestamp of course .
* * The old object ' s death points to the new object , which tells why the
* * fragmentation took place .
* * The new object birth points to the old object only if a fragment .
* * An allocation only has a birth object when it is a realloc ( complex )
* * heap event .
* *
* * I believe this give us enough information to look up particular
* * details of the heap at any given time .
*/
return retval ;
}
int complexHeapEvent ( TMState * inStats , unsigned mTimestamp , unsigned inOldSerial , unsigned inOldHeapID , unsigned inOSize , unsigned inNewSerial , unsigned inNewHeapID , unsigned inNewSize )
/*
* * Generally , this event intends to chain one old heap object to a newer heap object .
* * Otherwise , the functionality should recognizable ala simpleHeapEvent .
*/
{
int retval = 0 ;
/*
* * TODO GAB
*/
return retval ;
}
unsigned actualByteSize ( Options * inOptions , unsigned retval )
/*
* * Apply alignment and overhead to size to figure out actual byte size .
* * This by default mimics spacetrace with default options ( msvc crt heap ) .
*/
{
if ( 0 ! = retval )
{
unsigned eval = 0 ;
unsigned over = 0 ;
eval = retval - 1 ;
if ( 0 ! = inOptions - > mAlignment )
{
over = eval % inOptions - > mAlignment ;
}
retval = eval + inOptions - > mOverhead + inOptions - > mAlignment - over ;
}
return retval ;
}
void tmEventHandler ( tmreader * inReader , tmevent * inEvent )
/*
* * Callback from the tmreader_eventloop .
* * Build up our fragmentation information herein .
*/
{
char type = inEvent - > type ;
TMState * stats = ( TMState * ) inReader - > data ;
/*
* * Only intersted in handling events of a particular type .
*/
switch ( type )
{
default :
return ;
case TM_EVENT_MALLOC :
case TM_EVENT_CALLOC :
case TM_EVENT_REALLOC :
case TM_EVENT_FREE :
break ;
}
/*
* * Should we even try to look ?
* * Set mLoopExitTMR to non - zero to abort the read loop faster .
*/
if ( 0 = = stats - > mLoopExitTMR )
{
Options * options = ( Options * ) stats - > mOptions ;
unsigned timestamp = ticks2msec ( stats - > mTMR , inEvent - > u . alloc . interval ) ;
unsigned actualSize = actualByteSize ( options , inEvent - > u . alloc . size ) ;
unsigned heapID = inEvent - > u . alloc . ptr ;
unsigned serial = inEvent - > serial ;
/*
* * Check the timestamp range of our overall state .
*/
if ( stats - > uMinTicks > timestamp )
{
stats - > uMinTicks = timestamp ;
}
if ( stats - > uMaxTicks < timestamp )
{
stats - > uMaxTicks = timestamp ;
}
/*
* * Realloc in general deserves some special attention if dealing
* * with an old allocation ( not new memory ) .
*/
if ( TM_EVENT_REALLOC = = type & & 0 ! = inEvent - > u . alloc . oldserial )
{
unsigned oldActualSize = actualByteSize ( options , inEvent - > u . alloc . oldsize ) ;
unsigned oldHeapID = inEvent - > u . alloc . oldptr ;
unsigned oldSerial = inEvent - > u . alloc . oldserial ;
if ( 0 = = actualSize )
{
/*
* * Reallocs of size zero are to become free events .
*/
stats - > mLoopExitTMR = simpleHeapEvent ( stats , FREE , timestamp , serial , oldHeapID , oldActualSize ) ;
}
else if ( heapID ! = oldHeapID | | actualSize ! = oldActualSize )
{
/*
* * Reallocs which moved generate two events .
* * Reallocs which changed size generate two events .
* *
* * One event to free the old memory area .
* * Another event to allocate the new memory area .
* * They are to be linked to one another , so the history
* * and true origin can be tracked .
*/
stats - > mLoopExitTMR = complexHeapEvent ( stats , timestamp , oldSerial , oldHeapID , oldActualSize , serial , heapID , actualSize ) ;
}
else
{
/*
* * The realloc is not considered an operation and is skipped .
* * It is not an operation , because it did not move or change
* * size ; this can happen if a realloc falls within the
* * alignment of an allocation .
* * Say if you realloc a 1 byte allocation to 2 bytes , it will
* * not really change heap impact unless you have 1 set as
* * the alignment of your allocations .
*/
}
}
else if ( TM_EVENT_FREE = = type )
{
/*
* * Generate a free event to create a fragment .
*/
stats - > mLoopExitTMR = simpleHeapEvent ( stats , FREE , timestamp , serial , heapID , actualSize ) ;
}
else
{
/*
* * Generate an allocation event to clear fragments .
*/
stats - > mLoopExitTMR = simpleHeapEvent ( stats , ALLOC , timestamp , serial , heapID , actualSize ) ;
}
}
}
int tmfrags ( Options * inOptions )
/*
* * Load the input file and report stats .
*/
{
int retval = 0 ;
TMState stats ;
memset ( & stats , 0 , sizeof ( stats ) ) ;
stats . mOptions = inOptions ;
stats . uMinTicks = 0xFFFFFFFFU ;
/*
* * Need a tmreader .
*/
stats . mTMR = tmreader_new ( inOptions - > mProgramName , & stats ) ;
if ( NULL ! = stats . mTMR )
{
int tmResult = 0 ;
tmResult = tmreader_eventloop ( stats . mTMR , inOptions - > mInputName , tmEventHandler ) ;
if ( 0 = = tmResult )
{
retval = __LINE__ ;
ERROR_REPORT ( retval , inOptions - > mInputName , " Problem reading trace-malloc data. " ) ;
}
if ( 0 ! = stats . mLoopExitTMR )
{
retval = stats . mLoopExitTMR ;
ERROR_REPORT ( retval , inOptions - > mInputName , " Aborted trace-malloc input loop. " ) ;
}
tmreader_destroy ( stats . mTMR ) ;
stats . mTMR = NULL ;
}
else
{
retval = __LINE__ ;
ERROR_REPORT ( retval , inOptions - > mProgramName , " Unable to obtain tmreader. " ) ;
}
return retval ;
}
int main ( int inArgc , char * * inArgv )
{
int retval = 0 ;
Options options ;
retval = initOptions ( & options , inArgc , inArgv ) ;
if ( options . mHelp )
{
showHelp ( & options ) ;
}
else if ( 0 = = retval )
{
retval = tmfrags ( & options ) ;
}
cleanOptions ( & options ) ;
return retval ;
}