gcc/libgo/runtime/parfor.c
Ian Lance Taylor b0147ac2e6 re PR go/79037 (gccgo: Binaries crash with parforsetup: pos is not aligned on m68k)
PR go/79037
    compiler, runtime: align gc data for m68k
    
    The current GC requires that the gc data be aligned to at least a 4
    byte boundary, because it uses the lower two bits of the address for
    flags (see LOOP and PRECISE in runtime/mgc0.c).  As the gc data is
    stored as a [...]uintptr, that is normally always true.  However, on
    m68k, that only guarantees 2 byte alignment.  Fix it by forcing the
    alignment.
    
    The parfor code used by the current GC requires that the parfor data
    be aligned to at least an 8 byte boundary.  The code in parfor.c
    verifies this.  This is normally true, as the data uses uint64_t
    values, but, again, this must be enforced explicitly on m68k.
    
    Fixes GCC PR 79037.
    
    Reviewed-on: https://go-review.googlesource.com/35478

From-SVN: r244824
2017-01-23 18:15:22 +00:00

203 lines
4.9 KiB
C

// Copyright 2012 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.
// Parallel for algorithm.
#include "runtime.h"
#include "malloc.h"
#include "arch.h"
struct ParForThread
{
// the thread's iteration space [32lsb, 32msb)
uint64 pos __attribute__((aligned(8)));
// stats
uint64 nsteal;
uint64 nstealcnt;
uint64 nprocyield;
uint64 nosyield;
uint64 nsleep;
byte pad[CacheLineSize];
};
ParFor*
runtime_parforalloc(uint32 nthrmax)
{
ParFor *desc;
// The ParFor object is followed by CacheLineSize padding
// and then nthrmax ParForThread.
desc = (ParFor*)runtime_mallocgc(sizeof(ParFor) + CacheLineSize + nthrmax * sizeof(ParForThread), 0, FlagNoInvokeGC);
desc->thr = (ParForThread*)((byte*)(desc+1) + CacheLineSize);
desc->nthrmax = nthrmax;
return desc;
}
void
runtime_parforsetup(ParFor *desc, uint32 nthr, uint32 n, bool wait, const FuncVal *body)
{
uint32 i, begin, end;
uint64 *pos;
if(desc == nil || nthr == 0 || nthr > desc->nthrmax || body == nil) {
runtime_printf("desc=%p nthr=%d count=%d body=%p\n", desc, nthr, n, body);
runtime_throw("parfor: invalid args");
}
desc->body = body;
desc->done = 0;
desc->nthr = nthr;
desc->thrseq = 0;
desc->cnt = n;
desc->wait = wait;
desc->nsteal = 0;
desc->nstealcnt = 0;
desc->nprocyield = 0;
desc->nosyield = 0;
desc->nsleep = 0;
for(i=0; i<nthr; i++) {
begin = (uint64)n*i / nthr;
end = (uint64)n*(i+1) / nthr;
pos = &desc->thr[i].pos;
if(((uintptr)pos & 7) != 0)
runtime_throw("parforsetup: pos is not aligned");
*pos = (uint64)begin | (((uint64)end)<<32);
}
}
void
runtime_parfordo(ParFor *desc)
{
ParForThread *me;
uint32 tid, begin, end, begin2, try, victim, i;
uint64 *mypos, *victimpos, pos, newpos;
const FuncVal *body;
void (*bodyfn)(ParFor*, uint32);
bool idle;
// Obtain 0-based thread index.
tid = runtime_xadd(&desc->thrseq, 1) - 1;
if(tid >= desc->nthr) {
runtime_printf("tid=%d nthr=%d\n", tid, desc->nthr);
runtime_throw("parfor: invalid tid");
}
body = desc->body;
bodyfn = (void (*)(ParFor*, uint32))(void*)body->fn;
// If single-threaded, just execute the for serially.
if(desc->nthr==1) {
for(i=0; i<desc->cnt; i++)
__builtin_call_with_static_chain (bodyfn(desc, i), body);
return;
}
me = &desc->thr[tid];
mypos = &me->pos;
for(;;) {
for(;;) {
// While there is local work,
// bump low index and execute the iteration.
pos = runtime_xadd64(mypos, 1);
begin = (uint32)pos-1;
end = (uint32)(pos>>32);
if(begin < end) {
__builtin_call_with_static_chain(bodyfn(desc, begin), body);
continue;
}
break;
}
// Out of work, need to steal something.
idle = false;
for(try=0;; try++) {
// If we don't see any work for long enough,
// increment the done counter...
if(try > desc->nthr*4 && !idle) {
idle = true;
runtime_xadd(&desc->done, 1);
}
// ...if all threads have incremented the counter,
// we are done.
if(desc->done + !idle == desc->nthr) {
if(!idle)
runtime_xadd(&desc->done, 1);
goto exit;
}
// Choose a random victim for stealing.
victim = runtime_fastrand() % (desc->nthr-1);
if(victim >= tid)
victim++;
victimpos = &desc->thr[victim].pos;
for(;;) {
// See if it has any work.
pos = runtime_atomicload64(victimpos);
begin = (uint32)pos;
end = (uint32)(pos>>32);
if(begin+1 >= end) {
begin = end = 0;
break;
}
if(idle) {
runtime_xadd(&desc->done, -1);
idle = false;
}
begin2 = begin + (end-begin)/2;
newpos = (uint64)begin | (uint64)begin2<<32;
if(runtime_cas64(victimpos, pos, newpos)) {
begin = begin2;
break;
}
}
if(begin < end) {
// Has successfully stolen some work.
if(idle)
runtime_throw("parfor: should not be idle");
runtime_atomicstore64(mypos, (uint64)begin | (uint64)end<<32);
me->nsteal++;
me->nstealcnt += end-begin;
break;
}
// Backoff.
if(try < desc->nthr) {
// nothing
} else if (try < 4*desc->nthr) {
me->nprocyield++;
runtime_procyield(20);
// If a caller asked not to wait for the others, exit now
// (assume that most work is already done at this point).
} else if (!desc->wait) {
if(!idle)
runtime_xadd(&desc->done, 1);
goto exit;
} else if (try < 6*desc->nthr) {
me->nosyield++;
runtime_osyield();
} else {
me->nsleep++;
runtime_usleep(1);
}
}
}
exit:
runtime_xadd64(&desc->nsteal, me->nsteal);
runtime_xadd64(&desc->nstealcnt, me->nstealcnt);
runtime_xadd64(&desc->nprocyield, me->nprocyield);
runtime_xadd64(&desc->nosyield, me->nosyield);
runtime_xadd64(&desc->nsleep, me->nsleep);
me->nsteal = 0;
me->nstealcnt = 0;
me->nprocyield = 0;
me->nosyield = 0;
me->nsleep = 0;
}
// For testing from Go.
void
runtime_parforiters(ParFor *desc, uintptr tid, uintptr *start, uintptr *end)
{
*start = (uint32)desc->thr[tid].pos;
*end = (uint32)(desc->thr[tid].pos>>32);
}