gecko-dev/tools/jprof/leaky.cpp

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23 KiB
C++
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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
2012-05-21 15:12:37 +04:00
/* 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 "leaky.h"
#include "intcnt.h"
#include <sys/types.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <string.h>
#ifndef NTO
#include <getopt.h>
#endif
#include <assert.h>
#include <stdlib.h>
#include <stdio.h>
#ifdef NTO
#include <mem.h>
#endif
#ifndef FALSE
#define FALSE 0
#endif
#ifndef TRUE
#define TRUE 1
#endif
static const u_int DefaultBuckets = 10007; // arbitrary, but prime
static const u_int MaxBuckets = 1000003; // arbitrary, but prime
//----------------------------------------------------------------------
int main(int argc, char** argv)
{
leaky* l = new leaky;
l->initialize(argc, argv);
l->outputfd = stdout;
for (int i = 0; i < l->numLogFiles; i++) {
if (l->output_dir || l->numLogFiles > 1) {
char name[2048]; // XXX fix
if (l->output_dir)
snprintf(name,sizeof(name),"%s/%s.html",l->output_dir,argv[l->logFileIndex + i]);
else
snprintf(name,sizeof(name),"%s.html",argv[l->logFileIndex + i]);
fprintf(stderr,"opening %s\n",name);
l->outputfd = fopen(name,"w");
// if an error we won't process the file
}
if (l->outputfd) { // paranoia
l->open(argv[l->logFileIndex + i]);
if (l->outputfd != stderr) {
fclose(l->outputfd);
l->outputfd = nullptr;
}
}
}
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return 0;
}
char *
htmlify(const char *in)
{
const char *p = in;
char *out, *q;
int n = 0;
size_t newlen;
// Count the number of '<' and '>' in the input.
while ((p = strpbrk(p, "<>")))
{
++n;
++p;
}
// Knowing the number of '<' and '>', we can calculate the space
// needed for the output string.
newlen = strlen(in) + n * 3 + 1;
out = new char[newlen];
// Copy the input to the output, with substitutions.
p = in;
q = out;
do
{
if (*p == '<')
{
strcpy(q, "&lt;");
q += 4;
}
else if (*p == '>')
{
strcpy(q, "&gt;");
q += 4;
}
else
{
*q++ = *p;
}
p++;
} while (*p);
*q = '\0';
return out;
}
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leaky::leaky()
{
applicationName = nullptr;
progFile = nullptr;
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quiet = true;
showAddress = false;
showThreads = false;
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stackDepth = 100000;
onlyThread = 0;
cleo = false;
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mappedLogFile = -1;
firstLogEntry = lastLogEntry = 0;
sfd = -1;
externalSymbols = 0;
usefulSymbols = 0;
numExternalSymbols = 0;
lowestSymbolAddr = 0;
highestSymbolAddr = 0;
loadMap = nullptr;
collect_last = false;
collect_start = -1;
collect_end = -1;
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}
leaky::~leaky()
{
}
void leaky::usageError()
{
fprintf(stderr, "Usage: %s [-v] [-t] [-e exclude] [-i include] [-s stackdepth] [--last] [--all] [--start n [--end m]] [--cleo] [--output-dir dir] prog log [log2 ...]\n", (char*) applicationName);
fprintf(stderr,
"\t-v: verbose\n"
"\t-t | --threads: split threads\n"
"\t--only-thread n: only profile thread N\n"
"\t-i include-id: stack must include specified id\n"
"\t-e exclude-id: stack must NOT include specified id\n"
"\t-s stackdepth: Limit depth looked at from captured stack frames\n"
"\t--last: only profile the last capture section\n"
"\t--start n [--end m]: profile n to m (or end) capture sections\n"
"\t--cleo: format output for 'cleopatra' display\n"
"\t--output-dir dir: write output files to dir\n"
"\tIf there's one log, output goes to stdout unless --output-dir is set\n"
"\tIf there are more than one log, output files will be named with .html added\n"
);
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exit(-1);
}
static struct option longopts[] = {
{ "threads", 0, nullptr, 't' },
{ "only-thread", 1, nullptr, 'T' },
{ "last", 0, nullptr, 'l' },
{ "start", 1, nullptr, 'x' },
{ "end", 1, nullptr, 'n' },
{ "cleo",0, nullptr, 'c' },
{ "output-dir", 1, nullptr, 'd' },
{ nullptr, 0, nullptr, 0 },
};
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void leaky::initialize(int argc, char** argv)
{
applicationName = argv[0];
applicationName = strrchr(applicationName, '/');
if (!applicationName) {
applicationName = argv[0];
} else {
applicationName++;
}
int arg;
int errflg = 0;
int longindex = 0;
onlyThread = 0;
output_dir = nullptr;
cleo = false;
// XXX tons of cruft here left over from tracemalloc
// XXX The -- options shouldn't need short versions, or they should be documented
while (((arg = getopt_long(argc, argv, "adEe:gh:i:r:Rs:tT:qvx:ln:",longopts,&longindex)) != -1)) {
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switch (arg) {
case '?':
default:
fprintf(stderr,"error: unknown option %c\n",optopt);
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errflg++;
break;
case 'a':
break;
case 'A': // not implemented
showAddress = true;
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break;
case 'c':
cleo = true;
break;
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case 'd':
output_dir = optarg; // reference to an argv pointer
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break;
case 'R':
break;
case 'e':
exclusions.add(optarg);
break;
case 'g':
break;
case 'r': // not implemented
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roots.add(optarg);
if (!includes.IsEmpty()) {
errflg++;
}
break;
case 'i':
includes.add(optarg);
if (!roots.IsEmpty()) {
errflg++;
}
break;
case 'h':
break;
case 's':
stackDepth = atoi(optarg);
if (stackDepth < 2) {
stackDepth = 2;
}
break;
case 'x':
// --start
collect_start = atoi(optarg);
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break;
case 'n':
// --end
collect_end = atoi(optarg);
break;
case 'l':
// --last
collect_last = true;
break;
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case 'q':
break;
case 'v':
quiet = !quiet;
break;
case 't':
showThreads = true;
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break;
case 'T':
showThreads = true;
onlyThread = atoi(optarg);
break;
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}
}
if (errflg || ((argc - optind) < 2)) {
usageError();
}
progFile = argv[optind++];
logFileIndex = optind;
numLogFiles = argc - optind;
if (!quiet)
fprintf(stderr,"numlogfiles = %d\n",numLogFiles);
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}
static void* mapFile(int fd, u_int flags, off_t* sz)
{
struct stat sb;
if (fstat(fd, &sb) < 0) {
perror("fstat");
exit(-1);
}
void* base = mmap(0, (int)sb.st_size, flags, MAP_PRIVATE, fd, 0);
if (!base) {
perror("mmap");
exit(-1);
}
*sz = sb.st_size;
return base;
}
void leaky::LoadMap()
{
malloc_map_entry mme;
char name[1000];
if (!loadMap) {
// all files use the same map
int fd = ::open(M_MAPFILE, O_RDONLY);
if (fd < 0) {
perror("open: " M_MAPFILE);
exit(-1);
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}
for (;;) {
int nb = read(fd, &mme, sizeof(mme));
if (nb != sizeof(mme)) break;
nb = read(fd, name, mme.nameLen);
if (nb != (int)mme.nameLen) break;
name[mme.nameLen] = 0;
if (!quiet) {
fprintf(stderr,"%s @ %lx\n", name, mme.address);
}
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LoadMapEntry* lme = new LoadMapEntry;
lme->address = mme.address;
lme->name = strdup(name);
lme->next = loadMap;
loadMap = lme;
}
close(fd);
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}
}
void leaky::open(char *logFile)
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{
int threadArray[100]; // should auto-expand
int last_thread = -1;
int numThreads = 0;
int section = -1;
bool collecting = false;
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LoadMap();
setupSymbols(progFile);
// open up the log file
if (mappedLogFile)
::close(mappedLogFile);
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mappedLogFile = ::open(logFile, O_RDONLY);
if (mappedLogFile < 0) {
perror("open");
exit(-1);
}
off_t size;
firstLogEntry = (malloc_log_entry*) mapFile(mappedLogFile, PROT_READ, &size);
lastLogEntry = (malloc_log_entry*)((char*)firstLogEntry + size);
if (!collect_last || collect_start < 0) {
collecting = true;
}
// First, restrict it to the capture sections specified (all, last, start/end)
// This loop walks through all the call stacks we recorded
for (malloc_log_entry* lep=firstLogEntry;
lep < lastLogEntry;
lep = reinterpret_cast<malloc_log_entry*>(&lep->pcs[lep->numpcs])) {
if (lep->flags & JP_FIRST_AFTER_PAUSE) {
section++;
if (collect_last) {
firstLogEntry = lep;
numThreads = 0;
collecting = true;
}
if (collect_start == section) {
collecting = true;
firstLogEntry = lep;
}
if (collect_end == section) {
collecting = false;
lastLogEntry = lep;
}
if (!quiet)
fprintf(stderr,"New section %d: first=%p, last=%p, collecting=%d\n",
section,(void*)firstLogEntry,(void*)lastLogEntry,collecting);
}
// Capture thread info at the same time
// Find all the threads captured
// pthread/linux docs say the signal can be delivered to any thread in
// the process. In practice, it appears in Linux that it's always
// delivered to the thread that called setitimer(), and each thread can
// have a separate itimer. There's a support library for gprof that
// overlays pthread_create() to set timers in any threads you spawn.
if (showThreads && collecting) {
if (lep->thread != last_thread)
{
int i;
for (i=0; i<numThreads; i++)
{
if (lep->thread == threadArray[i])
break;
}
if (i == numThreads &&
i < (int) (sizeof(threadArray)/sizeof(threadArray[0])))
{
threadArray[i] = lep->thread;
numThreads++;
if (!quiet)
fprintf(stderr,"new thread %d\n",lep->thread);
}
}
}
}
if (!quiet)
fprintf(stderr,"Done collecting: sections %d: first=%p, last=%p, numThreads=%d\n",
section,(void*)firstLogEntry,(void*)lastLogEntry,numThreads);
if (!cleo) {
fprintf(outputfd,"<html><head><title>Jprof Profile Report</title></head><body>\n");
fprintf(outputfd,"<h1><center>Jprof Profile Report</center></h1>\n");
}
if (showThreads)
{
fprintf(stderr,"Num threads %d\n",numThreads);
if (!cleo) {
fprintf(outputfd,"<hr>Threads:<p><pre>\n");
for (int i=0; i<numThreads; i++)
{
fprintf(outputfd," <a href=\"#thread_%d\">%d</a> ",
threadArray[i],threadArray[i]);
if ((i+1)%10 == 0)
fprintf(outputfd,"<br>\n");
}
fprintf(outputfd,"</pre>");
}
for (int i=0; i<numThreads; i++)
{
if (!onlyThread || onlyThread == threadArray[i])
analyze(threadArray[i]);
}
}
else
{
analyze(0);
}
if (!cleo)
fprintf(outputfd,"</pre></body></html>\n");
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}
//----------------------------------------------------------------------
static int symbolOrder(void const* a, void const* b)
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{
Symbol const** ap = (Symbol const **)a;
Symbol const** bp = (Symbol const **)b;
return (*ap)->address == (*bp)->address ? 0 :
((*ap)->address > (*bp)->address ? 1 : -1);
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}
void leaky::ReadSharedLibrarySymbols()
{
LoadMapEntry* lme = loadMap;
while (nullptr != lme) {
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ReadSymbols(lme->name, lme->address);
lme = lme->next;
}
}
void leaky::setupSymbols(const char *fileName)
{
if (usefulSymbols == 0) {
// only read once!
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// Read in symbols from the program
ReadSymbols(fileName, 0);
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// Read in symbols from the .so's
ReadSharedLibrarySymbols();
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if (!quiet) {
fprintf(stderr,"A total of %d symbols were loaded\n", usefulSymbols);
}
// Now sort them
qsort(externalSymbols, usefulSymbols, sizeof(Symbol *), symbolOrder);
lowestSymbolAddr = externalSymbols[0]->address;
highestSymbolAddr = externalSymbols[usefulSymbols-1]->address;
}
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}
// Binary search the table, looking for a symbol that covers this
// address.
int leaky::findSymbolIndex(u_long addr)
{
u_int base = 0;
u_int limit = usefulSymbols - 1;
Symbol** end = &externalSymbols[limit];
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while (base <= limit) {
u_int midPoint = (base + limit)>>1;
Symbol** sp = &externalSymbols[midPoint];
if (addr < (*sp)->address) {
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if (midPoint == 0) {
return -1;
}
limit = midPoint - 1;
} else {
if (sp+1 < end) {
if (addr < (*(sp+1))->address) {
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return midPoint;
}
} else {
return midPoint;
}
base = midPoint + 1;
}
}
return -1;
}
Symbol* leaky::findSymbol(u_long addr)
{
int idx = findSymbolIndex(addr);
if(idx<0) {
return nullptr;
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} else {
return externalSymbols[idx];
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}
}
//----------------------------------------------------------------------
bool leaky::excluded(malloc_log_entry* lep)
{
if (exclusions.IsEmpty()) {
return false;
}
char** pcp = &lep->pcs[0];
u_int n = lep->numpcs;
for (u_int i = 0; i < n; i++, pcp++) {
Symbol* sp = findSymbol((u_long) *pcp);
if (sp && exclusions.contains(sp->name)) {
return true;
}
}
return false;
}
bool leaky::included(malloc_log_entry* lep)
{
if (includes.IsEmpty()) {
return true;
}
char** pcp = &lep->pcs[0];
u_int n = lep->numpcs;
for (u_int i = 0; i < n; i++, pcp++) {
Symbol* sp = findSymbol((u_long) *pcp);
if (sp && includes.contains(sp->name)) {
return true;
}
}
return false;
}
//----------------------------------------------------------------------
void leaky::displayStackTrace(FILE* out, malloc_log_entry* lep)
{
char** pcp = &lep->pcs[0];
u_int n = (lep->numpcs < stackDepth) ? lep->numpcs : stackDepth;
for (u_int i = 0; i < n; i++, pcp++) {
u_long addr = (u_long) *pcp;
Symbol* sp = findSymbol(addr);
if (sp) {
fputs(sp->name, out);
if (showAddress) {
fprintf(out, "[%p]", (char*)addr);
}
}
else {
fprintf(out, "<%p>", (char*)addr);
}
fputc(' ', out);
}
fputc('\n', out);
}
void leaky::dumpEntryToLog(malloc_log_entry* lep)
{
printf("%ld\t", lep->delTime);
printf(" --> ");
displayStackTrace(outputfd, lep);
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}
void leaky::generateReportHTML(FILE *fp, int *countArray, int count, int thread)
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{
fprintf(fp,"<center>");
if (showThreads)
{
fprintf(fp,"<hr><A NAME=thread_%d><b>Thread: %d</b></A><p>",
thread,thread);
}
fprintf(fp,"<A href=#flat_%d>flat</A><b> | </b><A href=#hier_%d>hierarchical</A>",
thread,thread);
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fprintf(fp,"</center><P><P><P>\n");
int totalTimerHits = count;
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int *rankingTable = new int[usefulSymbols];
for(int cnt=usefulSymbols; --cnt>=0; rankingTable[cnt]=cnt);
// Drat. I would use ::qsort() but I would need a global variable and my
// intro-pascal professor threatened to flunk anyone who used globals.
// She damaged me for life :-) (That was 1986. See how much influence
// she had. I don't remember her name but I always feel guilty about globals)
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// Shell Sort. 581130733 is the max 31 bit value of h = 3h+1
int mx, i, h;
for(mx=usefulSymbols/9, h=581130733; h>0; h/=3) {
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if(h<mx) {
for(i = h-1; i<usefulSymbols; i++) {
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int j, tmp=rankingTable[i], val = countArray[tmp];
for(j = i; (j>=h) && (countArray[rankingTable[j-h]]<val); j-=h) {
rankingTable[j] = rankingTable[j-h];
}
rankingTable[j] = tmp;
}
}
}
// Ok, We are sorted now. Let's go through the table until we get to
// functions that were never called. Right now we don't do much inside
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// this loop. Later we can get callers and callees into it like gprof
// does
fprintf(fp,
"<h2><A NAME=hier_%d></A><center><a href=\"http://dxr.mozilla.org/mozilla-central/source/tools/jprof/README.html#hier\">Hierarchical Profile</a></center></h2><hr>\n",
thread);
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fprintf(fp, "<pre>\n");
fprintf(fp, "%6s %6s %4s %s\n",
"index", "Count", "Hits", "Function Name");
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for(i=0; i<usefulSymbols && countArray[rankingTable[i]]>0; i++) {
Symbol **sp=&externalSymbols[rankingTable[i]];
(*sp)->cntP.printReport(fp, this, rankingTable[i], totalTimerHits);
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char *symname = htmlify((*sp)->name);
fprintf(fp, "%6d %6d (%3.1f%%)%s <a name=%d>%8d (%3.1f%%)</a>%s <b>%s</b>\n",
rankingTable[i],
(*sp)->timerHit, ((*sp)->timerHit*1000/totalTimerHits)/10.0,
((*sp)->timerHit*1000/totalTimerHits)/10.0 >= 10.0 ? "" : " ",
rankingTable[i], countArray[rankingTable[i]],
(countArray[rankingTable[i]]*1000/totalTimerHits)/10.0,
(countArray[rankingTable[i]]*1000/totalTimerHits)/10.0 >= 10.0 ? "" : " ",
symname);
delete [] symname;
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(*sp)->cntC.printReport(fp, this, rankingTable[i], totalTimerHits);
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fprintf(fp, "<hr>\n");
}
fprintf(fp,"</pre>\n");
// OK, Now we want to print the flat profile. To do this we resort on
// the hit count.
// Cut-N-Paste Shell sort from above. The Ranking Table has already been
// populated, so we do not have to reinitialize it.
for(mx=usefulSymbols/9, h=581130733; h>0; h/=3) {
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if(h<mx) {
for(i = h-1; i<usefulSymbols; i++) {
int j, tmp=rankingTable[i], val = externalSymbols[tmp]->timerHit;
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for(j = i;
(j>=h) && (externalSymbols[rankingTable[j-h]]->timerHit<val); j-=h) {
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rankingTable[j] = rankingTable[j-h];
}
rankingTable[j] = tmp;
}
}
}
// Pre-count up total counter hits, to get a percentage.
// I wanted the total before walking the list, if this
// double-pass over externalSymbols gets slow we can
// do single-pass and print this out after the loop finishes.
totalTimerHits = 0;
for(i=0;
i<usefulSymbols && externalSymbols[rankingTable[i]]->timerHit>0; i++) {
Symbol **sp=&externalSymbols[rankingTable[i]];
totalTimerHits += (*sp)->timerHit;
}
if (totalTimerHits == 0)
totalTimerHits = 1;
if (totalTimerHits != count)
fprintf(stderr,"Hit count mismatch: count=%d; totalTimerHits=%d",
count,totalTimerHits);
fprintf(fp,"<h2><A NAME=flat_%d></A><center><a href=\"http://dxr.mozilla.org/mozilla-central/source/tools/jprof/README.html#flat\">Flat Profile</a></center></h2><br>\n",
thread);
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fprintf(fp, "<pre>\n");
fprintf(fp, "Total hit count: %d\n", totalTimerHits);
fprintf(fp, "Count %%Total Function Name\n");
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// Now loop for as long as we have timer hits
for(i=0;
i<usefulSymbols && externalSymbols[rankingTable[i]]->timerHit>0; i++) {
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Symbol **sp=&externalSymbols[rankingTable[i]];
char *symname = htmlify((*sp)->name);
fprintf(fp, "<a href=\"#%d\">%3d %-2.1f %s</a>\n",
rankingTable[i], (*sp)->timerHit,
((float)(*sp)->timerHit/(float)totalTimerHits)*100.0, symname);
delete [] symname;
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}
}
void leaky::analyze(int thread)
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{
int *countArray = new int[usefulSymbols];
int *flagArray = new int[usefulSymbols];
//Zero our function call counter
memset(countArray, 0, sizeof(countArray[0])*usefulSymbols);
// reset hit counts
for(int i=0; i<usefulSymbols; i++) {
externalSymbols[i]->timerHit = 0;
externalSymbols[i]->regClear();
}
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// The flag array is used to prevent counting symbols multiple times
// if functions are called recursively. In order to keep from having
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// to zero it on each pass through the loop, we mark it with the value
// of stacks on each trip through the loop. This means we can determine
// if we have seen this symbol for this stack trace w/o having to reset
// from the prior stacktrace.
memset(flagArray, -1, sizeof(flagArray[0])*usefulSymbols);
if (cleo)
fprintf(outputfd,"m-Start\n");
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// This loop walks through all the call stacks we recorded
// --last, --start and --end can restrict it, as can excludes/includes
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stacks = 0;
for(malloc_log_entry* lep=firstLogEntry;
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lep < lastLogEntry;
lep = reinterpret_cast<malloc_log_entry*>(&lep->pcs[lep->numpcs])) {
if ((thread != 0 && lep->thread != thread) ||
excluded(lep) || !included(lep))
{
continue;
}
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++stacks; // How many stack frames did we collect
u_int n = (lep->numpcs < stackDepth) ? lep->numpcs : stackDepth;
char** pcp = &lep->pcs[n-1];
int idx=-1, parrentIdx=-1; // Init idx incase n==0
if (cleo) {
// This loop walks through every symbol in the call stack. By walking it
// backwards we know who called the function when we get there.
char type = 's';
for (int i=n-1; i>=0; --i, --pcp) {
idx = findSymbolIndex(reinterpret_cast<u_long>(*pcp));
if(idx>=0) {
// Skip over bogus __restore_rt frames that realtime profiling
// can introduce.
if (i > 0 && !strcmp(externalSymbols[idx]->name, "__restore_rt")) {
--pcp;
--i;
idx = findSymbolIndex(reinterpret_cast<u_long>(*pcp));
if (idx < 0) {
continue;
}
}
Symbol **sp=&externalSymbols[idx];
char *symname = htmlify((*sp)->name);
fprintf(outputfd,"%c-%s\n",type,symname);
delete [] symname;
}
// else can't find symbol - ignore
type = 'c';
}
} else {
// This loop walks through every symbol in the call stack. By walking it
// backwards we know who called the function when we get there.
for (int i=n-1; i>=0; --i, --pcp) {
idx = findSymbolIndex(reinterpret_cast<u_long>(*pcp));
if(idx>=0) {
// Skip over bogus __restore_rt frames that realtime profiling
// can introduce.
if (i > 0 && !strcmp(externalSymbols[idx]->name, "__restore_rt")) {
--pcp;
--i;
idx = findSymbolIndex(reinterpret_cast<u_long>(*pcp));
if (idx < 0) {
continue;
}
}
// If we have not seen this symbol before count it and mark it as seen
if(flagArray[idx]!=stacks && ((flagArray[idx]=stacks) || true)) {
++countArray[idx];
}
// We know who we are and we know who our parrent is. Count this
if(parrentIdx>=0) {
externalSymbols[parrentIdx]->regChild(idx);
externalSymbols[idx]->regParrent(parrentIdx);
}
// inside if() so an unknown in the middle of a stack won't break
// the link!
parrentIdx=idx;
}
}
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// idx should be the function that we were in when we received the signal.
if(idx>=0) {
++externalSymbols[idx]->timerHit;
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}
}
}
if (!cleo)
generateReportHTML(outputfd, countArray, stacks, thread);
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}
void FunctionCount::printReport(FILE *fp, leaky *lk, int parent, int total)
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{
const char *fmt = " <A href=\"#%d\">%8d (%3.1f%%)%s %s</A>%s\n";
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int nmax, tmax=((~0U)>>1);
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do {
nmax=0;
for(int j=getSize(); --j>=0;) {
int cnt = getCount(j);
if(cnt==tmax) {
int idx = getIndex(j);
char *symname = htmlify(lk->indexToName(idx));
fprintf(fp, fmt, idx, getCount(j),
getCount(j)*100.0/total,
getCount(j)*100.0/total >= 10.0 ? "" : " ",
symname,
parent == idx ? " (self)" : "");
delete [] symname;
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} else if(cnt<tmax && cnt>nmax) {
nmax=cnt;
}
}
} while((tmax=nmax)>0);
}