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/* -----------------------------------------------------------------------------
*
* (c) The GHC Team 1998-2008
*
* Generational garbage collector: utilities
*
* Documentation on the architecture of the Garbage Collector can be
* found in the online commentary:
*
* http://hackage.haskell.org/trac/ghc/wiki/Commentary/Rts/Storage/GC
*
* ---------------------------------------------------------------------------*/
#include "Rts.h"
#include "RtsFlags.h"
#include "Storage.h"
#include "GC.h"
#include "GCThread.h"
#include "GCUtils.h"
#include "Printer.h"
#include "Trace.h"
#ifdef THREADED_RTS
#include "WSDeque.h"
#endif
#ifdef THREADED_RTS
SpinLock gc_alloc_block_sync;
#endif
bdescr *
allocBlock_sync(void)
{
bdescr *bd;
ACQUIRE_SPIN_LOCK(&gc_alloc_block_sync);
bd = allocBlock();
RELEASE_SPIN_LOCK(&gc_alloc_block_sync);
return bd;
}
#if 0
static void
allocBlocks_sync(nat n, bdescr **hd, bdescr **tl,
nat gen_no, step *stp,
StgWord32 flags)
{
bdescr *bd;
nat i;
ACQUIRE_SPIN_LOCK(&gc_alloc_block_sync);
bd = allocGroup(n);
for (i = 0; i < n; i++) {
bd[i].blocks = 1;
bd[i].gen_no = gen_no;
bd[i].step = stp;
bd[i].flags = flags;
bd[i].link = &bd[i+1];
bd[i].u.scan = bd[i].free = bd[i].start;
}
*hd = bd;
*tl = &bd[n-1];
RELEASE_SPIN_LOCK(&gc_alloc_block_sync);
}
#endif
void
freeChain_sync(bdescr *bd)
{
ACQUIRE_SPIN_LOCK(&gc_alloc_block_sync);
freeChain(bd);
RELEASE_SPIN_LOCK(&gc_alloc_block_sync);
}
/* -----------------------------------------------------------------------------
Workspace utilities
-------------------------------------------------------------------------- */
bdescr *
grab_local_todo_block (step_workspace *ws)
{
bdescr *bd;
step *stp;
stp = ws->step;
bd = ws->todo_overflow;
if (bd != NULL)
{
ws->todo_overflow = bd->link;
bd->link = NULL;
ws->n_todo_overflow--;
return bd;
}
bd = popWSDeque(ws->todo_q);
if (bd != NULL)
{
ASSERT(bd->link == NULL);
return bd;
}
return NULL;
}
bdescr *
steal_todo_block (nat s)
{
nat n;
bdescr *bd;
// look for work to steal
for (n = 0; n < n_gc_threads; n++) {
if (n == gct->thread_index) continue;
bd = stealWSDeque(gc_threads[n]->steps[s].todo_q);
if (bd) {
return bd;
}
}
return NULL;
}
void
push_scanned_block (bdescr *bd, step_workspace *ws)
{
ASSERT(bd != NULL);
ASSERT(bd->link == NULL);
ASSERT(bd->step == ws->step);
ASSERT(bd->u.scan == bd->free);
if (bd->start + BLOCK_SIZE_W - bd->free > WORK_UNIT_WORDS)
{
// a partially full block: put it on the part_list list.
bd->link = ws->part_list;
ws->part_list = bd;
ws->n_part_blocks++;
IF_DEBUG(sanity,
ASSERT(countBlocks(ws->part_list) == ws->n_part_blocks));
}
else
{
// put the scan block on the ws->scavd_list.
bd->link = ws->scavd_list;
ws->scavd_list = bd;
ws->n_scavd_blocks ++;
IF_DEBUG(sanity,
ASSERT(countBlocks(ws->scavd_list) == ws->n_scavd_blocks));
}
}
StgPtr
todo_block_full (nat size, step_workspace *ws)
{
bdescr *bd;
bd = ws->todo_bd;
ASSERT(bd != NULL);
ASSERT(bd->link == NULL);
ASSERT(bd->step == ws->step);
// If the global list is not empty, or there's not much work in
// this block to push, and there's enough room in
// this block to evacuate the current object, then just increase
// the limit.
if (!looksEmptyWSDeque(ws->todo_q) ||
(ws->todo_free - bd->u.scan < WORK_UNIT_WORDS / 2)) {
if (ws->todo_free + size < bd->start + BLOCK_SIZE_W) {
ws->todo_lim = stg_min(bd->start + BLOCK_SIZE_W,
ws->todo_lim + stg_max(WORK_UNIT_WORDS,size));
debugTrace(DEBUG_gc, "increasing limit for %p to %p", bd->start, ws->todo_lim);
return ws->todo_free;
}
}
gct->copied += ws->todo_free - bd->free;
bd->free = ws->todo_free;
ASSERT(bd->u.scan >= bd->start && bd->u.scan <= bd->free);
// If this block is not the scan block, we want to push it out and
// make room for a new todo block.
if (bd != gct->scan_bd)
{
// If this block does not have enough space to allocate the
// current object, but it also doesn't have any work to push, then
// push it on to the scanned list. It cannot be empty, because
// then there would be enough room to copy the current object.
if (bd->u.scan == bd->free)
{
ASSERT(bd->free != bd->start);
push_scanned_block(bd, ws);
}
// Otherwise, push this block out to the global list.
else
{
step *stp;
stp = ws->step;
trace(TRACE_gc|DEBUG_gc, "push todo block %p (%ld words), step %d, todo_q: %ld",
bd->start, (unsigned long)(bd->free - bd->u.scan),
stp->abs_no, dequeElements(ws->todo_q));
if (!pushWSDeque(ws->todo_q, bd)) {
bd->link = ws->todo_overflow;
ws->todo_overflow = bd;
ws->n_todo_overflow++;
}
}
}
ws->todo_bd = NULL;
ws->todo_free = NULL;
ws->todo_lim = NULL;
alloc_todo_block(ws, size);
return ws->todo_free;
}
StgPtr
alloc_todo_block (step_workspace *ws, nat size)
{
bdescr *bd/*, *hd, *tl */;
// Grab a part block if we have one, and it has enough room
if (ws->part_list != NULL &&
ws->part_list->start + BLOCK_SIZE_W - ws->part_list->free > (int)size)
{
bd = ws->part_list;
ws->part_list = bd->link;
ws->n_part_blocks--;
}
else
{
// blocks in to-space get the BF_EVACUATED flag.
// allocBlocks_sync(16, &hd, &tl,
// ws->step->gen_no, ws->step, BF_EVACUATED);
//
// tl->link = ws->part_list;
// ws->part_list = hd->link;
// ws->n_part_blocks += 15;
//
// bd = hd;
bd = allocBlock_sync();
bd->step = ws->step;
bd->gen_no = ws->step->gen_no;
bd->flags = BF_EVACUATED;
bd->u.scan = bd->free = bd->start;
}
bd->link = NULL;
ws->todo_bd = bd;
ws->todo_free = bd->free;
ws->todo_lim = stg_min(bd->start + BLOCK_SIZE_W,
bd->free + stg_max(WORK_UNIT_WORDS,size));
debugTrace(DEBUG_gc, "alloc new todo block %p for step %d",
bd->free, ws->step->abs_no);
return ws->todo_free;
}
/* -----------------------------------------------------------------------------
* Debugging
* -------------------------------------------------------------------------- */
#if DEBUG
void
printMutableList(generation *gen)
{
bdescr *bd;
StgPtr p;
debugBelch("mutable list %p: ", gen->mut_list);
for (bd = gen->mut_list; bd != NULL; bd = bd->link) {
for (p = bd->start; p < bd->free; p++) {
debugBelch("%p (%s), ", (void *)*p, info_type((StgClosure *)*p));
}
}
debugBelch("\n");
}
#endif /* DEBUG */
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