gcc/libgo/runtime/mgc0.c

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// 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.
// Garbage collector -- step 0.
//
// Stop the world, mark and sweep garbage collector.
// NOT INTENDED FOR PRODUCTION USE.
//
// A mark and sweep collector provides a way to exercise
// and test the memory allocator and the stack walking machinery
// without also needing to get reference counting
// exactly right.
#include "runtime.h"
#include "malloc.h"
enum {
Debug = 0
};
typedef struct BlockList BlockList;
struct BlockList
{
byte *obj;
uintptr size;
};
static bool finstarted;
static pthread_mutex_t finqlock = PTHREAD_MUTEX_INITIALIZER;
static pthread_cond_t finqcond = PTHREAD_COND_INITIALIZER;
static Finalizer *finq;
static int32 fingwait;
static BlockList *bl, *ebl;
static void runfinq(void*);
enum {
PtrSize = sizeof(void*)
};
static void
scanblock(byte *b, int64 n)
{
int32 off;
void *obj;
uintptr size;
uint32 *refp, ref;
void **vp;
int64 i;
BlockList *w;
w = bl;
w->obj = b;
w->size = n;
w++;
while(w > bl) {
w--;
b = w->obj;
n = w->size;
if(Debug > 1)
runtime_printf("scanblock %p %lld\n", b, (long long) n);
off = (uint32)(uintptr)b & (PtrSize-1);
if(off) {
b += PtrSize - off;
n -= PtrSize - off;
}
vp = (void**)b;
n /= PtrSize;
for(i=0; i<n; i++) {
obj = vp[i];
if(obj == nil)
continue;
if(runtime_mheap.closure_min != nil && runtime_mheap.closure_min <= (byte*)obj && (byte*)obj < runtime_mheap.closure_max) {
if((((uintptr)obj) & 63) != 0)
continue;
// Looks like a Native Client closure.
// Actual pointer is pointed at by address in first instruction.
// Embedded pointer starts at byte 2.
// If it is f4f4f4f4 then that space hasn't been
// used for a closure yet (f4 is the HLT instruction).
// See nacl/386/closure.c for more.
void **pp;
pp = *(void***)((byte*)obj+2);
if(pp == (void**)0xf4f4f4f4) // HLT... - not a closure after all
continue;
obj = *pp;
}
if(runtime_mheap.min <= (byte*)obj && (byte*)obj < runtime_mheap.max) {
if(runtime_mlookup(obj, (byte**)&obj, &size, nil, &refp)) {
ref = *refp;
switch(ref & ~RefFlags) {
case RefNone:
if(Debug > 1)
runtime_printf("found at %p: ", &vp[i]);
*refp = RefSome | (ref & RefFlags);
if(!(ref & RefNoPointers)) {
if(w >= ebl)
runtime_throw("scanblock: garbage collection stack overflow");
w->obj = obj;
w->size = size;
w++;
}
break;
}
}
}
}
}
}
static void
markfin(void *v)
{
uintptr size;
uint32 *refp;
size = 0;
refp = nil;
if(!runtime_mlookup(v, (byte**)&v, &size, nil, &refp) || !(*refp & RefHasFinalizer))
runtime_throw("mark - finalizer inconsistency");
// do not mark the finalizer block itself. just mark the things it points at.
scanblock(v, size);
}
struct root_list {
struct root_list *next;
struct root {
void *decl;
size_t size;
} roots[];
};
static struct root_list* roots;
void
__go_register_gc_roots (struct root_list* r)
{
// FIXME: This needs locking if multiple goroutines can call
// dlopen simultaneously.
r->next = roots;
roots = r;
}
static void
mark(void)
{
uintptr blsize, nobj;
struct root_list *pl;
// Figure out how big an object stack we need.
// Get a new one if we need more than we have
// or we need significantly less than we have.
nobj = mstats.heap_objects;
if(nobj > (uintptr)(ebl - bl) || nobj < (uintptr)(ebl-bl)/4) {
if(bl != nil)
runtime_SysFree(bl, (byte*)ebl - (byte*)bl);
// While we're allocated a new object stack,
// add 20% headroom and also round up to
// the nearest page boundary, since mmap
// will anyway.
nobj = nobj * 12/10;
blsize = nobj * sizeof *bl;
blsize = (blsize + 4095) & ~4095;
nobj = blsize / sizeof *bl;
bl = runtime_SysAlloc(blsize);
ebl = bl + nobj;
}
for(pl = roots; pl != nil; pl = pl->next) {
struct root* pr = &pl->roots[0];
while(1) {
void *decl = pr->decl;
if(decl == nil)
break;
scanblock(decl, pr->size);
pr++;
}
}
scanblock((byte*)&m0, sizeof m0);
scanblock((byte*)&finq, sizeof finq);
runtime_MProf_Mark(scanblock);
// mark stacks
__go_scanstacks(scanblock);
// mark things pointed at by objects with finalizers
runtime_walkfintab(markfin, scanblock);
}
// free RefNone, free & queue finalizers for RefNone|RefHasFinalizer, reset RefSome
static void
sweepspan(MSpan *s)
{
int32 n, npages, size;
byte *p;
uint32 ref, *gcrefp, *gcrefep;
MCache *c;
Finalizer *f;
p = (byte*)(s->start << PageShift);
if(s->sizeclass == 0) {
// Large block.
ref = s->gcref0;
switch(ref & ~(RefFlags^RefHasFinalizer)) {
case RefNone:
// Free large object.
mstats.alloc -= s->npages<<PageShift;
runtime_memclr(p, s->npages<<PageShift);
if(ref & RefProfiled)
runtime_MProf_Free(p, s->npages<<PageShift);
s->gcref0 = RefFree;
runtime_MHeap_Free(&runtime_mheap, s, 1);
break;
case RefNone|RefHasFinalizer:
f = runtime_getfinalizer(p, 1);
if(f == nil)
runtime_throw("finalizer inconsistency");
f->arg = p;
f->next = finq;
finq = f;
ref &= ~RefHasFinalizer;
// fall through
case RefSome:
case RefSome|RefHasFinalizer:
s->gcref0 = RefNone | (ref&RefFlags);
break;
}
return;
}
// Chunk full of small blocks.
runtime_MGetSizeClassInfo(s->sizeclass, &size, &npages, &n);
gcrefp = s->gcref;
gcrefep = s->gcref + n;
for(; gcrefp < gcrefep; gcrefp++, p += size) {
ref = *gcrefp;
if(ref < RefNone) // RefFree or RefStack
continue;
switch(ref & ~(RefFlags^RefHasFinalizer)) {
case RefNone:
// Free small object.
if(ref & RefProfiled)
runtime_MProf_Free(p, size);
*gcrefp = RefFree;
c = m->mcache;
if(size > (int32)sizeof(uintptr))
((uintptr*)p)[1] = 1; // mark as "needs to be zeroed"
mstats.alloc -= size;
mstats.by_size[s->sizeclass].nfree++;
runtime_MCache_Free(c, p, s->sizeclass, size);
break;
case RefNone|RefHasFinalizer:
f = runtime_getfinalizer(p, 1);
if(f == nil)
runtime_throw("finalizer inconsistency");
f->arg = p;
f->next = finq;
finq = f;
ref &= ~RefHasFinalizer;
// fall through
case RefSome:
case RefSome|RefHasFinalizer:
*gcrefp = RefNone | (ref&RefFlags);
break;
}
}
}
static void
sweep(void)
{
MSpan *s;
for(s = runtime_mheap.allspans; s != nil; s = s->allnext)
if(s->state == MSpanInUse)
sweepspan(s);
}
static pthread_mutex_t gcsema = PTHREAD_MUTEX_INITIALIZER;
// Initialized from $GOGC. GOGC=off means no gc.
//
// Next gc is after we've allocated an extra amount of
// memory proportional to the amount already in use.
// If gcpercent=100 and we're using 4M, we'll gc again
// when we get to 8M. This keeps the gc cost in linear
// proportion to the allocation cost. Adjusting gcpercent
// just changes the linear constant (and also the amount of
// extra memory used).
static int32 gcpercent = -2;
void
runtime_gc(int32 force __attribute__ ((unused)))
{
int64 t0, t1;
char *p;
Finalizer *fp;
// The gc is turned off (via enablegc) until
// the bootstrap has completed.
// Also, malloc gets called in the guts
// of a number of libraries that might be
// holding locks. To avoid priority inversion
// problems, don't bother trying to run gc
// while holding a lock. The next mallocgc
// without a lock will do the gc instead.
if(!mstats.enablegc || m->locks > 0 /* || runtime_panicking */)
return;
if(gcpercent == -2) { // first time through
p = runtime_getenv("GOGC");
if(p == nil || p[0] == '\0')
gcpercent = 100;
else if(runtime_strcmp(p, "off") == 0)
gcpercent = -1;
else
gcpercent = runtime_atoi(p);
}
if(gcpercent < 0)
return;
pthread_mutex_lock(&finqlock);
pthread_mutex_lock(&gcsema);
m->locks++; // disable gc during the mallocs in newproc
t0 = runtime_nanotime();
runtime_stoptheworld();
if(force || mstats.heap_alloc >= mstats.next_gc) {
__go_cachestats();
mark();
sweep();
__go_stealcache();
mstats.next_gc = mstats.heap_alloc+mstats.heap_alloc*gcpercent/100;
}
t1 = runtime_nanotime();
mstats.numgc++;
mstats.pause_ns += t1 - t0;
if(mstats.debuggc)
runtime_printf("pause %llu\n", (unsigned long long)t1-t0);
pthread_mutex_unlock(&gcsema);
runtime_starttheworld();
// finqlock is still held.
fp = finq;
if(fp != nil) {
// kick off or wake up goroutine to run queued finalizers
if(!finstarted) {
__go_go(runfinq, nil);
finstarted = 1;
}
else if(fingwait) {
fingwait = 0;
pthread_cond_signal(&finqcond);
}
}
m->locks--;
pthread_mutex_unlock(&finqlock);
}
static void
runfinq(void* dummy)
{
Finalizer *f, *next;
USED(dummy);
for(;;) {
pthread_mutex_lock(&finqlock);
f = finq;
finq = nil;
if(f == nil) {
fingwait = 1;
pthread_cond_wait(&finqcond, &finqlock);
pthread_mutex_unlock(&finqlock);
continue;
}
pthread_mutex_unlock(&finqlock);
for(; f; f=next) {
void *params[1];
next = f->next;
params[0] = &f->arg;
reflect_call(f->ft, (void*)f->fn, 0, params, nil);
f->fn = nil;
f->arg = nil;
f->next = nil;
runtime_free(f);
}
runtime_gc(1); // trigger another gc to clean up the finalized objects, if possible
}
}
void
__go_enable_gc()
{
mstats.enablegc = 1;
}