// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
#include <u.h>
#include <time.h>
#include <libc.h>
#include <bio.h>
#include <ctype.h>
#include <ureg_amd64.h>
#include <mach.h>
char* file = "6.out";
static Fhdr fhdr;
int have_syms;
int fd;
Map *symmap;
struct Ureg ureg;
int total_sec = 0;
int delta_msec = 100;
int nsample;
int nsamplethread;
// output formats
int functions; // print functions
int histograms; // print histograms
int linenums; // print file and line numbers rather than function names
int registers; // print registers
int stacks; // print stack traces
int pid; // main process pid
int nthread; // number of threads
int thread[32]; // thread pids
Map *map[32]; // thread maps
void
Usage(void)
{
fprint(2, "Usage: prof -p pid [-t total_secs] [-d delta_msec] [6.out args ...]\n");
fprint(2, "\tformats (default -h):\n");
fprint(2, "\t\t-h: histograms\n");
fprint(2, "\t\t-f: dynamic functions\n");
fprint(2, "\t\t-l: dynamic file and line numbers\n");
fprint(2, "\t\t-r: dynamic registers\n");
fprint(2, "\t\t-s: dynamic function stack traces\n");
fprint(2, "\t\t-hs: include stack info in histograms\n");
exit(2);
}
typedef struct PC PC;
struct PC {
uvlong pc;
uvlong callerpc;
unsigned int count;
PC* next;
};
enum {
Ncounters = 256
};
PC *counters[Ncounters];
void
regprint(void)
{
fprint(2, "ax\t0x%llux\n", ureg.ax);
fprint(2, "bx\t0x%llux\n", ureg.bx);
fprint(2, "cx\t0x%llux\n", ureg.cx);
fprint(2, "dx\t0x%llux\n", ureg.dx);
fprint(2, "si\t0x%llux\n", ureg.si);
fprint(2, "di\t0x%llux\n", ureg.di);
fprint(2, "bp\t0x%llux\n", ureg.bp);
fprint(2, "r8\t0x%llux\n", ureg.r8);
fprint(2, "r9\t0x%llux\n", ureg.r9);
fprint(2, "r10\t0x%llux\n", ureg.r10);
fprint(2, "r11\t0x%llux\n", ureg.r11);
fprint(2, "r12\t0x%llux\n", ureg.r12);
fprint(2, "r13\t0x%llux\n", ureg.r13);
fprint(2, "r14\t0x%llux\n", ureg.r14);
fprint(2, "r15\t0x%llux\n", ureg.r15);
fprint(2, "ds\t0x%llux\n", ureg.ds);
fprint(2, "es\t0x%llux\n", ureg.es);
fprint(2, "fs\t0x%llux\n", ureg.fs);
fprint(2, "gs\t0x%llux\n", ureg.gs);
fprint(2, "type\t0x%llux\n", ureg.type);
fprint(2, "error\t0x%llux\n", ureg.error);
fprint(2, "pc\t0x%llux\n", ureg.ip);
fprint(2, "cs\t0x%llux\n", ureg.cs);
fprint(2, "flags\t0x%llux\n", ureg.flags);
fprint(2, "sp\t0x%llux\n", ureg.sp);
fprint(2, "ss\t0x%llux\n", ureg.ss);
}
int
getthreads(void)
{
int i, j, curn, found;
Map *curmap[nelem(map)];
int curthread[nelem(map)];
static int complained = 0;
curn = procthreadpids(pid, curthread, nelem(curthread));
if(curn <= 0)
return curn;
if(curn > nelem(map)) {
if(complained == 0) {
fprint(2, "prof: too many threads; limiting to %d\n", nthread, nelem(map));
complained = 1;
}
curn = nelem(map);
}
if(curn == nthread && memcmp(thread, curthread, curn*sizeof(*thread)) == 0)
return curn; // no changes
// Number of threads has changed (might be the init case).
// A bit expensive but rare enough not to bother being clever.
for(i = 0; i < curn; i++) {
found = 0;
for(j = 0; j < nthread; j++) {
if(curthread[i] == thread[j]) {
found = 1;
curmap[i] = map[j];
map[j] = nil;
break;
}
}
if(found)
continue;
// map new thread
curmap[i] = attachproc(curthread[i], &fhdr);
if(curmap[i] == nil) {
fprint(2, "prof: can't attach to %d: %r\n", curthread[i]);
return -1;
}
}
for(j = 0; j < nthread; j++)
if(map[j] != nil)
detachproc(map[j]);
nthread = curn;
memmove(thread, curthread, nthread*sizeof thread[0]);
memmove(map, curmap, sizeof map);
return nthread;
}
int
sample(Map *map)
{
int i;
static int n;
n++;
if(registers) {
for(i = 0; i < sizeof ureg; i+=8) {
if(get8(map, (uvlong)i, &((uvlong*)&ureg)[i/8]) < 0)
goto bad;
}
} else {
// we need only two registers
if(get8(map, offsetof(struct Ureg, ip), (uvlong*)&ureg.ip) < 0)
goto bad;
if(get8(map, offsetof(struct Ureg, sp), (uvlong*)&ureg.sp) < 0)
goto bad;
}
return 1;
bad:
if(n == 1)
fprint(2, "prof: can't read registers: %r\n");
return 0;
}
void
addtohistogram(uvlong pc, uvlong callerpc, uvlong sp)
{
int h;
PC *x;
h = (pc + callerpc*101) % Ncounters;
for(x = counters[h]; x != NULL; x = x->next) {
if(x->pc == pc && x->callerpc == callerpc) {
x->count++;
return;
}
}
x = malloc(sizeof(PC));
x->pc = pc;
x->callerpc = callerpc;
x->count = 1;
x->next = counters[h];
counters[h] = x;
}
uvlong nextpc;
void
xptrace(Map *map, uvlong pc, uvlong sp, Symbol *sym)
{
char buf[1024];
if(sym == nil){
fprint(2, "syms\n");
return;
}
if(histograms)
addtohistogram(nextpc, pc, sp);
if(!histograms || stacks > 1) {
if(nextpc == 0)
nextpc = sym->value;
fprint(2, "%s(", sym->name);
fprint(2, ")");
if(nextpc != sym->value)
fprint(2, "+%#llux ", nextpc - sym->value);
if(have_syms && linenums && fileline(buf, sizeof buf, pc)) {
fprint(2, " %s", buf);
}
fprint(2, "\n");
}
nextpc = pc;
}
void
stacktracepcsp(Map *map, uvlong pc, uvlong sp)
{
nextpc = pc;
if(machdata->ctrace==nil)
fprint(2, "no machdata->ctrace\n");
else if(machdata->ctrace(map, pc, sp, 0, xptrace) <= 0)
fprint(2, "no stack frame: pc=%#p sp=%#p\n", pc, sp);
else {
addtohistogram(nextpc, 0, sp);
if(!histograms || stacks > 1)
fprint(2, "\n");
}
}
void
printpc(Map *map, uvlong pc, uvlong sp)
{
char buf[1024];
if(registers)
regprint();
if(have_syms > 0 && linenums && fileline(buf, sizeof buf, pc))
fprint(2, "%s\n", buf);
if(have_syms > 0 && functions) {
symoff(buf, sizeof(buf), pc, CANY);
fprint(2, "%s\n", buf);
}
if(stacks){
stacktracepcsp(map, pc, sp);
}
else if(histograms){
addtohistogram(pc, 0, sp);
}
}
void
samples(void)
{
int i, pid, msec;
struct timespec req;
req.tv_sec = delta_msec/1000;
req.tv_nsec = 1000000*(delta_msec % 1000);
for(msec = 0; total_sec <= 0 || msec < 1000*total_sec; msec += delta_msec) {
nsample++;
nsamplethread += nthread;
for(i = 0; i < nthread; i++) {
pid = thread[i];
if(ctlproc(pid, "stop") < 0)
return;
if(!sample(map[i])) {
ctlproc(pid, "start");
return;
}
printpc(map[i], ureg.ip, ureg.sp);
ctlproc(pid, "start");
}
nanosleep(&req, NULL);
getthreads();
if(nthread == 0)
break;
}
}
typedef struct Func Func;
struct Func
{
Func *next;
Symbol s;
uint onstack;
uint leaf;
};
Func *func[257];
int nfunc;
Func*
findfunc(uvlong pc)
{
Func *f;
uint h;
Symbol s;
if(pc == 0)
return nil;
if(!findsym(pc, CTEXT, &s))
return nil;
h = s.value % nelem(func);
for(f = func[h]; f != NULL; f = f->next)
if(f->s.value == s.value)
return f;
f = malloc(sizeof *f);
memset(f, 0, sizeof *f);
f->s = s;
f->next = func[h];
func[h] = f;
nfunc++;
return f;
}
int
compareleaf(const void *va, const void *vb)
{
Func *a, *b;
a = *(Func**)va;
b = *(Func**)vb;
if(a->leaf != b->leaf)
return b->leaf - a->leaf;
if(a->onstack != b->onstack)
return b->onstack - a->onstack;
return strcmp(a->s.name, b->s.name);
}
void
dumphistogram()
{
int i, h, n;
PC *x;
Func *f, **ff;
if(!histograms)
return;
// assign counts to functions.
for(h = 0; h < Ncounters; h++) {
for(x = counters[h]; x != NULL; x = x->next) {
f = findfunc(x->pc);
if(f) {
f->onstack += x->count;
f->leaf += x->count;
}
f = findfunc(x->callerpc);
if(f)
f->leaf -= x->count;
}
}
// build array
ff = malloc(nfunc*sizeof ff[0]);
n = 0;
for(h = 0; h < nelem(func); h++)
for(f = func[h]; f != NULL; f = f->next)
ff[n++] = f;
// sort by leaf counts
qsort(ff, nfunc, sizeof ff[0], compareleaf);
// print.
fprint(2, "%d samples (avg %.1g threads)\n", nsample, (double)nsamplethread/nsample);
for(i = 0; i < nfunc; i++) {
f = ff[i];
fprint(2, "%6.2f%%\t", 100.0*(double)f->leaf/nsample);
if(stacks)
fprint(2, "%6.2f%%\t", 100.0*(double)f->onstack/nsample);
fprint(2, "%s\n", f->s.name);
}
}
int
startprocess(char **argv)
{
int pid;
if((pid = fork()) == 0) {
pid = getpid();
if(ctlproc(pid, "hang") < 0){
fprint(2, "prof: child process could not hang\n");
exits(0);
}
execv(argv[0], argv);
fprint(2, "prof: could not exec %s: %r\n", argv[0]);
exits(0);
}
if(pid == -1) {
fprint(2, "prof: could not fork\n");
exit(1);
}
if(ctlproc(pid, "attached") < 0 || ctlproc(pid, "waitstop") < 0) {
fprint(2, "prof: could not attach to child process: %r\n");
exit(1);
}
return pid;
}
void
detach(void)
{
int i;
for(i = 0; i < nthread; i++)
detachproc(map[i]);
}
int
main(int argc, char *argv[])
{
int i;
ARGBEGIN{
case 'd':
delta_msec = atoi(EARGF(Usage()));
break;
case 't':
total_sec = atoi(EARGF(Usage()));
break;
case 'p':
pid = atoi(EARGF(Usage()));
break;
case 'f':
functions = 1;
break;
case 'h':
histograms = 1;
break;
case 'l':
linenums = 1;
break;
case 'r':
registers = 1;
break;
case 's':
stacks++;
break;
}ARGEND
if(pid <= 0 && argc == 0)
Usage();
if(functions+linenums+registers+stacks == 0)
histograms = 1;
if(!machbyname("amd64")) {
fprint(2, "prof: no amd64 support\n", pid);
exit(1);
}
if(argc > 0)
file = argv[0];
else if(pid) {
file = proctextfile(pid);
if (file == NULL) {
fprint(2, "prof: can't find file for pid %d: %r\n", pid);
fprint(2, "prof: on Darwin, need to provide file name explicitly\n");
exit(1);
}
}
fd = open(file, 0);
if(fd < 0) {
fprint(2, "prof: can't open %s: %r\n", file);
exit(1);
}
if(crackhdr(fd, &fhdr)) {
have_syms = syminit(fd, &fhdr);
if(!have_syms) {
fprint(2, "prof: no symbols for %s: %r\n", file);
}
} else {
fprint(2, "prof: crack header for %s: %r\n", file);
exit(1);
}
if(pid <= 0)
pid = startprocess(argv);
attachproc(pid, &fhdr); // initializes thread list
if(getthreads() <= 0) {
detach();
fprint(2, "prof: can't find threads for pid %d\n", pid);
exit(1);
}
for(i = 0; i < nthread; i++)
ctlproc(thread[i], "start");
samples();
detach();
dumphistogram();
exit(0);
}
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