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// Copyright 2011 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.
// Implementation of the race detector API.
// +build race
#include "runtime.h"
#include "arch_GOARCH.h"
#include "malloc.h"
#include "race.h"
void runtime∕race·Initialize(uintptr *racectx);
void runtime∕race·MapShadow(void *addr, uintptr size);
void runtime∕race·Finalize(void);
void runtime∕race·FinalizerGoroutine(uintptr racectx);
void runtime∕race·Read(uintptr racectx, void *addr, void *pc);
void runtime∕race·Write(uintptr racectx, void *addr, void *pc);
void runtime∕race·ReadRange(uintptr racectx, void *addr, uintptr sz, uintptr step, void *pc);
void runtime∕race·WriteRange(uintptr racectx, void *addr, uintptr sz, uintptr step, void *pc);
void runtime∕race·FuncEnter(uintptr racectx, void *pc);
void runtime∕race·FuncExit(uintptr racectx);
void runtime∕race·Malloc(uintptr racectx, void *p, uintptr sz, void *pc);
void runtime∕race·Free(void *p);
void runtime∕race·GoStart(uintptr racectx, uintptr *chracectx, void *pc);
void runtime∕race·GoEnd(uintptr racectx);
void runtime∕race·Acquire(uintptr racectx, void *addr);
void runtime∕race·Release(uintptr racectx, void *addr);
void runtime∕race·ReleaseMerge(uintptr racectx, void *addr);
extern byte noptrdata[];
extern byte enoptrbss[];
static bool onstack(uintptr argp);
uintptr
runtime·raceinit(void)
{
uintptr racectx, start, size;
m->racecall = true;
runtime∕race·Initialize(&racectx);
// Round data segment to page boundaries, because it's used in mmap().
start = (uintptr)noptrdata & ~(PageSize-1);
size = ROUND((uintptr)enoptrbss - start, PageSize);
runtime∕race·MapShadow((void*)start, size);
m->racecall = false;
return racectx;
}
void
runtime·racefini(void)
{
m->racecall = true;
runtime∕race·Finalize();
m->racecall = false;
}
void
runtime·racemapshadow(void *addr, uintptr size)
{
m->racecall = true;
runtime∕race·MapShadow(addr, size);
m->racecall = false;
}
// Called from instrumented code.
// If we split stack, getcallerpc() can return runtime·lessstack().
#pragma textflag 7
void
runtime·racewrite(uintptr addr)
{
if(!onstack(addr)) {
m->racecall = true;
runtime∕race·Write(g->racectx, (void*)addr, runtime·getcallerpc(&addr));
m->racecall = false;
}
}
// Called from instrumented code.
// If we split stack, getcallerpc() can return runtime·lessstack().
#pragma textflag 7
void
runtime·raceread(uintptr addr)
{
if(!onstack(addr)) {
m->racecall = true;
runtime∕race·Read(g->racectx, (void*)addr, runtime·getcallerpc(&addr));
m->racecall = false;
}
}
// Called from runtime·racefuncenter (assembly).
#pragma textflag 7
void
runtime·racefuncenter1(uintptr pc)
{
// If the caller PC is lessstack, use slower runtime·callers
// to walk across the stack split to find the real caller.
if(pc == (uintptr)runtime·lessstack)
runtime·callers(2, &pc, 1);
m->racecall = true;
runtime∕race·FuncEnter(g->racectx, (void*)pc);
m->racecall = false;
}
// Called from instrumented code.
#pragma textflag 7
void
runtime·racefuncexit(void)
{
m->racecall = true;
runtime∕race·FuncExit(g->racectx);
m->racecall = false;
}
void
runtime·racemalloc(void *p, uintptr sz, void *pc)
{
// use m->curg because runtime·stackalloc() is called from g0
if(m->curg == nil)
return;
m->racecall = true;
runtime∕race·Malloc(m->curg->racectx, p, sz, pc);
m->racecall = false;
}
void
runtime·racefree(void *p)
{
m->racecall = true;
runtime∕race·Free(p);
m->racecall = false;
}
uintptr
runtime·racegostart(void *pc)
{
uintptr racectx;
m->racecall = true;
runtime∕race·GoStart(g->racectx, &racectx, pc);
m->racecall = false;
return racectx;
}
void
runtime·racegoend(void)
{
m->racecall = true;
runtime∕race·GoEnd(g->racectx);
m->racecall = false;
}
static void
memoryaccess(void *addr, uintptr callpc, uintptr pc, bool write)
{
uintptr racectx;
if(!onstack((uintptr)addr)) {
m->racecall = true;
racectx = g->racectx;
if(callpc) {
if(callpc == (uintptr)runtime·lessstack)
runtime·callers(3, &callpc, 1);
runtime∕race·FuncEnter(racectx, (void*)callpc);
}
if(write)
runtime∕race·Write(racectx, addr, (void*)pc);
else
runtime∕race·Read(racectx, addr, (void*)pc);
if(callpc)
runtime∕race·FuncExit(racectx);
m->racecall = false;
}
}
void
runtime·racewritepc(void *addr, void *callpc, void *pc)
{
memoryaccess(addr, (uintptr)callpc, (uintptr)pc, true);
}
void
runtime·racereadpc(void *addr, void *callpc, void *pc)
{
memoryaccess(addr, (uintptr)callpc, (uintptr)pc, false);
}
static void
rangeaccess(void *addr, uintptr size, uintptr step, uintptr callpc, uintptr pc, bool write)
{
uintptr racectx;
if(!onstack((uintptr)addr)) {
m->racecall = true;
racectx = g->racectx;
if(callpc) {
if(callpc == (uintptr)runtime·lessstack)
runtime·callers(3, &callpc, 1);
runtime∕race·FuncEnter(racectx, (void*)callpc);
}
if(write)
runtime∕race·WriteRange(racectx, addr, size, step, (void*)pc);
else
runtime∕race·ReadRange(racectx, addr, size, step, (void*)pc);
if(callpc)
runtime∕race·FuncExit(racectx);
m->racecall = false;
}
}
void
runtime·racewriterangepc(void *addr, uintptr sz, uintptr step, void *callpc, void *pc)
{
rangeaccess(addr, sz, step, (uintptr)callpc, (uintptr)pc, true);
}
void
runtime·racereadrangepc(void *addr, uintptr sz, uintptr step, void *callpc, void *pc)
{
rangeaccess(addr, sz, step, (uintptr)callpc, (uintptr)pc, false);
}
void
runtime·raceacquire(void *addr)
{
runtime·raceacquireg(g, addr);
}
void
runtime·raceacquireg(G *gp, void *addr)
{
if(g->raceignore)
return;
m->racecall = true;
runtime∕race·Acquire(gp->racectx, addr);
m->racecall = false;
}
void
runtime·racerelease(void *addr)
{
runtime·racereleaseg(g, addr);
}
void
runtime·racereleaseg(G *gp, void *addr)
{
if(g->raceignore)
return;
m->racecall = true;
runtime∕race·Release(gp->racectx, addr);
m->racecall = false;
}
void
runtime·racereleasemerge(void *addr)
{
runtime·racereleasemergeg(g, addr);
}
void
runtime·racereleasemergeg(G *gp, void *addr)
{
if(g->raceignore)
return;
m->racecall = true;
runtime∕race·ReleaseMerge(gp->racectx, addr);
m->racecall = false;
}
void
runtime·racefingo(void)
{
m->racecall = true;
runtime∕race·FinalizerGoroutine(g->racectx);
m->racecall = false;
}
// func RaceAcquire(addr unsafe.Pointer)
void
runtime·RaceAcquire(void *addr)
{
runtime·raceacquire(addr);
}
// func RaceRelease(addr unsafe.Pointer)
void
runtime·RaceRelease(void *addr)
{
runtime·racerelease(addr);
}
// func RaceReleaseMerge(addr unsafe.Pointer)
void
runtime·RaceReleaseMerge(void *addr)
{
runtime·racereleasemerge(addr);
}
// func RaceSemacquire(s *uint32)
void runtime·RaceSemacquire(uint32 *s)
{
runtime·semacquire(s);
}
// func RaceSemrelease(s *uint32)
void runtime·RaceSemrelease(uint32 *s)
{
runtime·semrelease(s);
}
// func RaceRead(addr unsafe.Pointer)
#pragma textflag 7
void
runtime·RaceRead(void *addr)
{
memoryaccess(addr, 0, (uintptr)runtime·getcallerpc(&addr), false);
}
// func RaceWrite(addr unsafe.Pointer)
#pragma textflag 7
void
runtime·RaceWrite(void *addr)
{
memoryaccess(addr, 0, (uintptr)runtime·getcallerpc(&addr), true);
}
// func RaceDisable()
void runtime·RaceDisable(void)
{
g->raceignore++;
}
// func RaceEnable()
void runtime·RaceEnable(void)
{
g->raceignore--;
}
static bool
onstack(uintptr argp)
{
// noptrdata, data, bss, noptrbss
// the layout is in ../../cmd/ld/data.c
if((byte*)argp >= noptrdata && (byte*)argp < enoptrbss)
return false;
if((byte*)argp >= runtime·mheap->arena_start && (byte*)argp < runtime·mheap->arena_used)
return false;
return true;
}
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