/* -----------------------------------------------------------------------------
- * $Id: Storage.c,v 1.83 2004/07/21 10:47:28 simonmar Exp $
*
- * (c) The GHC Team, 1998-1999
+ * (c) The GHC Team, 1998-2004
*
* Storage manager front end
*
#include "Weak.h"
#include "Sanity.h"
#include "Arena.h"
-
+#include "OSThreads.h"
+#include "Capability.h"
#include "Storage.h"
#include "Schedule.h"
-#include "OSThreads.h"
-#include "StoragePriv.h"
-
#include "RetainerProfile.h" // for counting memory blocks (memInventory)
#include <stdlib.h>
#include <string.h>
+/*
+ * All these globals require sm_mutex to access in THREADED_RTS mode.
+ */
StgClosure *caf_list = NULL;
+StgClosure *revertible_caf_list = NULL;
+rtsBool keepCAFs;
bdescr *small_alloc_list; /* allocate()d small objects */
bdescr *pinned_object_block; /* allocate pinned objects into this block */
ullong total_allocated = 0; /* total memory allocated during run */
+nat n_nurseries = 0; /* == RtsFlags.ParFlags.nNodes, convenience */
+step *nurseries = NULL; /* array of nurseries, >1 only if THREADED_RTS */
+
+#ifdef THREADED_RTS
/*
* Storage manager mutex: protects all the above state from
* simultaneous access by two STG threads.
*/
-#ifdef SMP
-Mutex sm_mutex = INIT_MUTEX_VAR;
+Mutex sm_mutex;
+/*
+ * This mutex is used by atomicModifyMutVar# only
+ */
+Mutex atomic_modify_mutvar_mutex;
#endif
+
/*
* Forward references
*/
static void *stgReallocForGMP (void *ptr, size_t old_size, size_t new_size);
static void stgDeallocForGMP (void *ptr, size_t size);
+static void
+initStep (step *stp, int g, int s)
+{
+ stp->no = s;
+ stp->blocks = NULL;
+ stp->n_blocks = 0;
+ stp->old_blocks = NULL;
+ stp->n_old_blocks = 0;
+ stp->gen = &generations[g];
+ stp->gen_no = g;
+ stp->hp = NULL;
+ stp->hpLim = NULL;
+ stp->hp_bd = NULL;
+ stp->scavd_hp = NULL;
+ stp->scavd_hpLim = NULL;
+ stp->scan = NULL;
+ stp->scan_bd = NULL;
+ stp->large_objects = NULL;
+ stp->n_large_blocks = 0;
+ stp->new_large_objects = NULL;
+ stp->scavenged_large_objects = NULL;
+ stp->n_scavenged_large_blocks = 0;
+ stp->is_compacted = 0;
+ stp->bitmap = NULL;
+}
+
void
initStorage( void )
{
nat g, s;
- step *stp;
generation *gen;
if (generations != NULL) {
if (RtsFlags.GcFlags.maxHeapSize != 0 &&
RtsFlags.GcFlags.minAllocAreaSize >
RtsFlags.GcFlags.maxHeapSize) {
- prog_belch("maximum heap size (-M) is smaller than minimum alloc area size (-A)");
+ errorBelch("maximum heap size (-M) is smaller than minimum alloc area size (-A)");
exit(1);
}
initBlockAllocator();
-#if defined(SMP)
+#if defined(THREADED_RTS)
initMutex(&sm_mutex);
+ initMutex(&atomic_modify_mutvar_mutex);
#endif
+ ACQUIRE_SM_LOCK;
+
/* allocate generation info array */
generations = (generation *)stgMallocBytes(RtsFlags.GcFlags.generations
- * sizeof(struct _generation),
+ * sizeof(struct generation_),
"initStorage: gens");
/* Initialise all generations */
for(g = 0; g < RtsFlags.GcFlags.generations; g++) {
gen = &generations[g];
gen->no = g;
- gen->mut_list = END_MUT_LIST;
- gen->mut_once_list = END_MUT_LIST;
+ gen->mut_list = allocBlock();
gen->collections = 0;
gen->failed_promotions = 0;
gen->max_blocks = 0;
/* Oldest generation: one step */
oldest_gen->n_steps = 1;
oldest_gen->steps =
- stgMallocBytes(1 * sizeof(struct _step), "initStorage: last step");
+ stgMallocBytes(1 * sizeof(struct step_), "initStorage: last step");
/* set up all except the oldest generation with 2 steps */
for(g = 0; g < RtsFlags.GcFlags.generations-1; g++) {
generations[g].n_steps = RtsFlags.GcFlags.steps;
generations[g].steps =
- stgMallocBytes (RtsFlags.GcFlags.steps * sizeof(struct _step),
+ stgMallocBytes (RtsFlags.GcFlags.steps * sizeof(struct step_),
"initStorage: steps");
}
} else {
/* single generation, i.e. a two-space collector */
g0->n_steps = 1;
- g0->steps = stgMallocBytes (sizeof(struct _step), "initStorage: steps");
+ g0->steps = stgMallocBytes (sizeof(struct step_), "initStorage: steps");
}
+#ifdef THREADED_RTS
+ n_nurseries = n_capabilities;
+ nurseries = stgMallocBytes (n_nurseries * sizeof(struct step_),
+ "initStorage: nurseries");
+#else
+ n_nurseries = 1;
+ nurseries = g0->steps; // just share nurseries[0] with g0s0
+#endif
+
/* Initialise all steps */
for (g = 0; g < RtsFlags.GcFlags.generations; g++) {
for (s = 0; s < generations[g].n_steps; s++) {
- stp = &generations[g].steps[s];
- stp->no = s;
- stp->blocks = NULL;
- stp->n_to_blocks = 0;
- stp->n_blocks = 0;
- stp->gen = &generations[g];
- stp->gen_no = g;
- stp->hp = NULL;
- stp->hpLim = NULL;
- stp->hp_bd = NULL;
- stp->scan = NULL;
- stp->scan_bd = NULL;
- stp->large_objects = NULL;
- stp->n_large_blocks = 0;
- stp->new_large_objects = NULL;
- stp->scavenged_large_objects = NULL;
- stp->n_scavenged_large_blocks = 0;
- stp->is_compacted = 0;
- stp->bitmap = NULL;
+ initStep(&generations[g].steps[s], g, s);
}
}
+#ifdef THREADED_RTS
+ for (s = 0; s < n_nurseries; s++) {
+ initStep(&nurseries[s], 0, s);
+ }
+#endif
+
/* Set up the destination pointers in each younger gen. step */
for (g = 0; g < RtsFlags.GcFlags.generations-1; g++) {
for (s = 0; s < generations[g].n_steps-1; s++) {
}
generations[g].steps[s].to = &generations[g+1].steps[0];
}
+ oldest_gen->steps[0].to = &oldest_gen->steps[0];
+
+#ifdef THREADED_RTS
+ for (s = 0; s < n_nurseries; s++) {
+ nurseries[s].to = generations[0].steps[0].to;
+ }
+#endif
- /* The oldest generation has one step and it is compacted. */
+ /* The oldest generation has one step. */
if (RtsFlags.GcFlags.compact) {
if (RtsFlags.GcFlags.generations == 1) {
- belch("WARNING: compaction is incompatible with -G1; disabled");
+ errorBelch("WARNING: compaction is incompatible with -G1; disabled");
} else {
oldest_gen->steps[0].is_compacted = 1;
}
}
- oldest_gen->steps[0].to = &oldest_gen->steps[0];
+
+#ifdef THREADED_RTS
+ if (RtsFlags.GcFlags.generations == 1) {
+ errorBelch("-G1 is incompatible with -threaded");
+ stg_exit(EXIT_FAILURE);
+ }
+#endif
/* generation 0 is special: that's the nursery */
generations[0].max_blocks = 0;
weak_ptr_list = NULL;
caf_list = NULL;
+ revertible_caf_list = NULL;
/* initialise the allocate() interface */
small_alloc_list = NULL;
mp_set_memory_functions(stgAllocForGMP, stgReallocForGMP, stgDeallocForGMP);
IF_DEBUG(gc, statDescribeGens());
+
+ RELEASE_SM_LOCK;
}
void
void
newCAF(StgClosure* caf)
{
- /* Put this CAF on the mutable list for the old generation.
- * This is a HACK - the IND_STATIC closure doesn't really have
- * a mut_link field, but we pretend it has - in fact we re-use
- * the STATIC_LINK field for the time being, because when we
- * come to do a major GC we won't need the mut_link field
- * any more and can use it as a STATIC_LINK.
- */
ACQUIRE_SM_LOCK;
- ((StgIndStatic *)caf)->saved_info = NULL;
- ((StgMutClosure *)caf)->mut_link = oldest_gen->mut_once_list;
- oldest_gen->mut_once_list = (StgMutClosure *)caf;
-
+ if(keepCAFs)
+ {
+ // HACK:
+ // If we are in GHCi _and_ we are using dynamic libraries,
+ // then we can't redirect newCAF calls to newDynCAF (see below),
+ // so we make newCAF behave almost like newDynCAF.
+ // The dynamic libraries might be used by both the interpreted
+ // program and GHCi itself, so they must not be reverted.
+ // This also means that in GHCi with dynamic libraries, CAFs are not
+ // garbage collected. If this turns out to be a problem, we could
+ // do another hack here and do an address range test on caf to figure
+ // out whether it is from a dynamic library.
+ ((StgIndStatic *)caf)->saved_info = (StgInfoTable *)caf->header.info;
+ ((StgIndStatic *)caf)->static_link = caf_list;
+ caf_list = caf;
+ }
+ else
+ {
+ /* Put this CAF on the mutable list for the old generation.
+ * This is a HACK - the IND_STATIC closure doesn't really have
+ * a mut_link field, but we pretend it has - in fact we re-use
+ * the STATIC_LINK field for the time being, because when we
+ * come to do a major GC we won't need the mut_link field
+ * any more and can use it as a STATIC_LINK.
+ */
+ ((StgIndStatic *)caf)->saved_info = NULL;
+ recordMutableGen(caf, oldest_gen);
+ }
+
RELEASE_SM_LOCK;
#ifdef PAR
/* If we are PAR or DIST then we never forget a CAF */
{ globalAddr *newGA;
- //belch("<##> Globalising CAF %08x %s",caf,info_type(caf));
+ //debugBelch("<##> Globalising CAF %08x %s",caf,info_type(caf));
newGA=makeGlobal(caf,rtsTrue); /*given full weight*/
ASSERT(newGA);
}
// object code in GHCi. In this case we want to retain *all* CAFs in
// the object code, because they might be demanded at any time from an
// expression evaluated on the command line.
+// Also, GHCi might want to revert CAFs, so we add these to the
+// revertible_caf_list.
//
// The linker hackily arranges that references to newCaf from dynamic
// code end up pointing to newDynCAF.
ACQUIRE_SM_LOCK;
((StgIndStatic *)caf)->saved_info = (StgInfoTable *)caf->header.info;
- ((StgIndStatic *)caf)->static_link = caf_list;
- caf_list = caf;
+ ((StgIndStatic *)caf)->static_link = revertible_caf_list;
+ revertible_caf_list = caf;
RELEASE_SM_LOCK;
}
Nursery management.
-------------------------------------------------------------------------- */
+static bdescr *
+allocNursery (step *stp, bdescr *tail, nat blocks)
+{
+ bdescr *bd;
+ nat i;
+
+ // Allocate a nursery: we allocate fresh blocks one at a time and
+ // cons them on to the front of the list, not forgetting to update
+ // the back pointer on the tail of the list to point to the new block.
+ for (i=0; i < blocks; i++) {
+ // @LDV profiling
+ /*
+ processNursery() in LdvProfile.c assumes that every block group in
+ the nursery contains only a single block. So, if a block group is
+ given multiple blocks, change processNursery() accordingly.
+ */
+ bd = allocBlock();
+ bd->link = tail;
+ // double-link the nursery: we might need to insert blocks
+ if (tail != NULL) {
+ tail->u.back = bd;
+ }
+ bd->step = stp;
+ bd->gen_no = 0;
+ bd->flags = 0;
+ bd->free = bd->start;
+ tail = bd;
+ }
+ tail->u.back = NULL;
+ return tail;
+}
+
+static void
+assignNurseriesToCapabilities (void)
+{
+#ifdef THREADED_RTS
+ nat i;
+
+ for (i = 0; i < n_nurseries; i++) {
+ capabilities[i].r.rNursery = &nurseries[i];
+ capabilities[i].r.rCurrentNursery = nurseries[i].blocks;
+ capabilities[i].r.rCurrentAlloc = NULL;
+ }
+#else /* THREADED_RTS */
+ MainCapability.r.rNursery = &nurseries[0];
+ MainCapability.r.rCurrentNursery = nurseries[0].blocks;
+ MainCapability.r.rCurrentAlloc = NULL;
+#endif
+}
+
void
allocNurseries( void )
{
-#ifdef SMP
- Capability *cap;
- bdescr *bd;
-
- g0s0->blocks = NULL;
- g0s0->n_blocks = 0;
- for (cap = free_capabilities; cap != NULL; cap = cap->link) {
- cap->r.rNursery = allocNursery(NULL, RtsFlags.GcFlags.minAllocAreaSize);
- cap->r.rCurrentNursery = cap->r.rNursery;
- /* Set the back links to be equal to the Capability,
- * so we can do slightly better informed locking.
- */
- for (bd = cap->r.rNursery; bd != NULL; bd = bd->link) {
- bd->u.back = (bdescr *)cap;
+ nat i;
+
+ for (i = 0; i < n_nurseries; i++) {
+ nurseries[i].blocks =
+ allocNursery(&nurseries[i], NULL,
+ RtsFlags.GcFlags.minAllocAreaSize);
+ nurseries[i].n_blocks = RtsFlags.GcFlags.minAllocAreaSize;
+ nurseries[i].old_blocks = NULL;
+ nurseries[i].n_old_blocks = 0;
+ /* hp, hpLim, hp_bd, to_space etc. aren't used in the nursery */
}
- }
-#else /* SMP */
- g0s0->blocks = allocNursery(NULL, RtsFlags.GcFlags.minAllocAreaSize);
- g0s0->n_blocks = RtsFlags.GcFlags.minAllocAreaSize;
- g0s0->to_blocks = NULL;
- g0s0->n_to_blocks = 0;
- MainCapability.r.rNursery = g0s0->blocks;
- MainCapability.r.rCurrentNursery = g0s0->blocks;
- /* hp, hpLim, hp_bd, to_space etc. aren't used in G0S0 */
-#endif
+ assignNurseriesToCapabilities();
}
void
resetNurseries( void )
{
- bdescr *bd;
-#ifdef SMP
- Capability *cap;
-
- /* All tasks must be stopped */
- ASSERT(n_free_capabilities == RtsFlags.ParFlags.nNodes);
-
- for (cap = free_capabilities; cap != NULL; cap = cap->link) {
- for (bd = cap->r.rNursery; bd; bd = bd->link) {
- bd->free = bd->start;
- ASSERT(bd->gen_no == 0);
- ASSERT(bd->step == g0s0);
- IF_DEBUG(sanity,memset(bd->start, 0xaa, BLOCK_SIZE));
+ nat i;
+ bdescr *bd;
+ step *stp;
+
+ for (i = 0; i < n_nurseries; i++) {
+ stp = &nurseries[i];
+ for (bd = stp->blocks; bd; bd = bd->link) {
+ bd->free = bd->start;
+ ASSERT(bd->gen_no == 0);
+ ASSERT(bd->step == stp);
+ IF_DEBUG(sanity,memset(bd->start, 0xaa, BLOCK_SIZE));
+ }
}
- cap->r.rCurrentNursery = cap->r.rNursery;
- }
-#else
- for (bd = g0s0->blocks; bd; bd = bd->link) {
- bd->free = bd->start;
- ASSERT(bd->gen_no == 0);
- ASSERT(bd->step == g0s0);
- IF_DEBUG(sanity,memset(bd->start, 0xaa, BLOCK_SIZE));
- }
- MainCapability.r.rNursery = g0s0->blocks;
- MainCapability.r.rCurrentNursery = g0s0->blocks;
-#endif
+ assignNurseriesToCapabilities();
}
-bdescr *
-allocNursery (bdescr *tail, nat blocks)
+lnat
+countNurseryBlocks (void)
{
- bdescr *bd;
- nat i;
+ nat i;
+ lnat blocks = 0;
- // Allocate a nursery: we allocate fresh blocks one at a time and
- // cons them on to the front of the list, not forgetting to update
- // the back pointer on the tail of the list to point to the new block.
- for (i=0; i < blocks; i++) {
- // @LDV profiling
- /*
- processNursery() in LdvProfile.c assumes that every block group in
- the nursery contains only a single block. So, if a block group is
- given multiple blocks, change processNursery() accordingly.
- */
- bd = allocBlock();
- bd->link = tail;
- // double-link the nursery: we might need to insert blocks
- if (tail != NULL) {
- tail->u.back = bd;
+ for (i = 0; i < n_nurseries; i++) {
+ blocks += nurseries[i].n_blocks;
}
- bd->step = g0s0;
- bd->gen_no = 0;
- bd->flags = 0;
- bd->free = bd->start;
- tail = bd;
- }
- tail->u.back = NULL;
- return tail;
+ return blocks;
}
-void
-resizeNursery ( nat blocks )
+static void
+resizeNursery ( step *stp, nat blocks )
{
bdescr *bd;
nat nursery_blocks;
-#ifdef SMP
- barf("resizeNursery: can't resize in SMP mode");
-#endif
+ nursery_blocks = stp->n_blocks;
+ if (nursery_blocks == blocks) return;
- nursery_blocks = g0s0->n_blocks;
- if (nursery_blocks == blocks) {
- return;
- }
-
- else if (nursery_blocks < blocks) {
- IF_DEBUG(gc, fprintf(stderr, "Increasing size of nursery to %d blocks\n",
+ if (nursery_blocks < blocks) {
+ IF_DEBUG(gc, debugBelch("Increasing size of nursery to %d blocks\n",
blocks));
- g0s0->blocks = allocNursery(g0s0->blocks, blocks-nursery_blocks);
+ stp->blocks = allocNursery(stp, stp->blocks, blocks-nursery_blocks);
}
-
else {
bdescr *next_bd;
- IF_DEBUG(gc, fprintf(stderr, "Decreasing size of nursery to %d blocks\n",
+ IF_DEBUG(gc, debugBelch("Decreasing size of nursery to %d blocks\n",
blocks));
- bd = g0s0->blocks;
+ bd = stp->blocks;
while (nursery_blocks > blocks) {
next_bd = bd->link;
next_bd->u.back = NULL;
freeGroup(bd);
bd = next_bd;
}
- g0s0->blocks = bd;
+ stp->blocks = bd;
// might have gone just under, by freeing a large block, so make
// up the difference.
if (nursery_blocks < blocks) {
- g0s0->blocks = allocNursery(g0s0->blocks, blocks-nursery_blocks);
+ stp->blocks = allocNursery(stp, stp->blocks, blocks-nursery_blocks);
}
}
- g0s0->n_blocks = blocks;
- ASSERT(countBlocks(g0s0->blocks) == g0s0->n_blocks);
+ stp->n_blocks = blocks;
+ ASSERT(countBlocks(stp->blocks) == stp->n_blocks);
+}
+
+//
+// Resize each of the nurseries to the specified size.
+//
+void
+resizeNurseriesFixed (nat blocks)
+{
+ nat i;
+ for (i = 0; i < n_nurseries; i++) {
+ resizeNursery(&nurseries[i], blocks);
+ }
+}
+
+//
+// Resize the nurseries to the total specified size.
+//
+void
+resizeNurseries (nat blocks)
+{
+ // If there are multiple nurseries, then we just divide the number
+ // of available blocks between them.
+ resizeNurseriesFixed(blocks / n_nurseries);
}
/* -----------------------------------------------------------------------------
StgPtr
allocate( nat n )
{
- bdescr *bd;
- StgPtr p;
+ bdescr *bd;
+ StgPtr p;
- ACQUIRE_SM_LOCK;
+ ACQUIRE_SM_LOCK;
- TICK_ALLOC_HEAP_NOCTR(n);
- CCS_ALLOC(CCCS,n);
-
- /* big allocation (>LARGE_OBJECT_THRESHOLD) */
- /* ToDo: allocate directly into generation 1 */
- if (n >= LARGE_OBJECT_THRESHOLD/sizeof(W_)) {
- nat req_blocks = (lnat)BLOCK_ROUND_UP(n*sizeof(W_)) / BLOCK_SIZE;
- bd = allocGroup(req_blocks);
- dbl_link_onto(bd, &g0s0->large_objects);
- g0s0->n_large_blocks += req_blocks;
- bd->gen_no = 0;
- bd->step = g0s0;
- bd->flags = BF_LARGE;
- bd->free = bd->start + n;
- alloc_blocks += req_blocks;
- RELEASE_SM_LOCK;
- return bd->start;
+ TICK_ALLOC_HEAP_NOCTR(n);
+ CCS_ALLOC(CCCS,n);
- /* small allocation (<LARGE_OBJECT_THRESHOLD) */
- } else if (small_alloc_list == NULL || alloc_Hp + n > alloc_HpLim) {
- if (small_alloc_list) {
- small_alloc_list->free = alloc_Hp;
+ /* big allocation (>LARGE_OBJECT_THRESHOLD) */
+ /* ToDo: allocate directly into generation 1 */
+ if (n >= LARGE_OBJECT_THRESHOLD/sizeof(W_)) {
+ nat req_blocks = (lnat)BLOCK_ROUND_UP(n*sizeof(W_)) / BLOCK_SIZE;
+ bd = allocGroup(req_blocks);
+ dbl_link_onto(bd, &g0s0->large_objects);
+ g0s0->n_large_blocks += req_blocks;
+ bd->gen_no = 0;
+ bd->step = g0s0;
+ bd->flags = BF_LARGE;
+ bd->free = bd->start + n;
+ alloc_blocks += req_blocks;
+ RELEASE_SM_LOCK;
+ return bd->start;
+
+ /* small allocation (<LARGE_OBJECT_THRESHOLD) */
+ } else if (small_alloc_list == NULL || alloc_Hp + n > alloc_HpLim) {
+ if (small_alloc_list) {
+ small_alloc_list->free = alloc_Hp;
+ }
+ bd = allocBlock();
+ bd->link = small_alloc_list;
+ small_alloc_list = bd;
+ bd->gen_no = 0;
+ bd->step = g0s0;
+ bd->flags = 0;
+ alloc_Hp = bd->start;
+ alloc_HpLim = bd->start + BLOCK_SIZE_W;
+ alloc_blocks++;
}
- bd = allocBlock();
- bd->link = small_alloc_list;
- small_alloc_list = bd;
- bd->gen_no = 0;
- bd->step = g0s0;
- bd->flags = 0;
- alloc_Hp = bd->start;
- alloc_HpLim = bd->start + BLOCK_SIZE_W;
- alloc_blocks++;
- }
-
- p = alloc_Hp;
- alloc_Hp += n;
- RELEASE_SM_LOCK;
- return p;
+
+ p = alloc_Hp;
+ alloc_Hp += n;
+ RELEASE_SM_LOCK;
+ return p;
}
lnat
}
}
+/* -----------------------------------------------------------------------------
+ allocateLocal()
+
+ This allocates memory in the current thread - it is intended for
+ use primarily from STG-land where we have a Capability. It is
+ better than allocate() because it doesn't require taking the
+ sm_mutex lock in the common case.
+
+ Memory is allocated directly from the nursery if possible (but not
+ from the current nursery block, so as not to interfere with
+ Hp/HpLim).
+ -------------------------------------------------------------------------- */
+
+StgPtr
+allocateLocal (Capability *cap, nat n)
+{
+ bdescr *bd;
+ StgPtr p;
+
+ TICK_ALLOC_HEAP_NOCTR(n);
+ CCS_ALLOC(CCCS,n);
+
+ /* big allocation (>LARGE_OBJECT_THRESHOLD) */
+ /* ToDo: allocate directly into generation 1 */
+ if (n >= LARGE_OBJECT_THRESHOLD/sizeof(W_)) {
+ nat req_blocks = (lnat)BLOCK_ROUND_UP(n*sizeof(W_)) / BLOCK_SIZE;
+ ACQUIRE_SM_LOCK;
+ bd = allocGroup(req_blocks);
+ dbl_link_onto(bd, &g0s0->large_objects);
+ g0s0->n_large_blocks += req_blocks;
+ bd->gen_no = 0;
+ bd->step = g0s0;
+ bd->flags = BF_LARGE;
+ bd->free = bd->start + n;
+ alloc_blocks += req_blocks;
+ RELEASE_SM_LOCK;
+ return bd->start;
+
+ /* small allocation (<LARGE_OBJECT_THRESHOLD) */
+ } else {
+
+ bd = cap->r.rCurrentAlloc;
+ if (bd == NULL || bd->free + n > bd->start + BLOCK_SIZE_W) {
+
+ // The CurrentAlloc block is full, we need to find another
+ // one. First, we try taking the next block from the
+ // nursery:
+ bd = cap->r.rCurrentNursery->link;
+
+ if (bd == NULL || bd->free + n > bd->start + BLOCK_SIZE_W) {
+ // The nursery is empty, or the next block is already
+ // full: allocate a fresh block (we can't fail here).
+ ACQUIRE_SM_LOCK;
+ bd = allocBlock();
+ cap->r.rNursery->n_blocks++;
+ RELEASE_SM_LOCK;
+ bd->gen_no = 0;
+ bd->step = cap->r.rNursery;
+ bd->flags = 0;
+ } else {
+ // we have a block in the nursery: take it and put
+ // it at the *front* of the nursery list, and use it
+ // to allocate() from.
+ cap->r.rCurrentNursery->link = bd->link;
+ if (bd->link != NULL) {
+ bd->link->u.back = cap->r.rCurrentNursery;
+ }
+ }
+ dbl_link_onto(bd, &cap->r.rNursery->blocks);
+ cap->r.rCurrentAlloc = bd;
+ IF_DEBUG(sanity, checkNurserySanity(cap->r.rNursery));
+ }
+ }
+ p = bd->free;
+ bd->free += n;
+ return p;
+}
+
/* ---------------------------------------------------------------------------
Allocate a fixed/pinned object.
}
/* -----------------------------------------------------------------------------
+ This is the write barrier for MUT_VARs, a.k.a. IORefs. A
+ MUT_VAR_CLEAN object is not on the mutable list; a MUT_VAR_DIRTY
+ is. When written to, a MUT_VAR_CLEAN turns into a MUT_VAR_DIRTY
+ and is put on the mutable list.
+ -------------------------------------------------------------------------- */
+
+void
+dirty_MUT_VAR(StgRegTable *reg, StgClosure *p)
+{
+ Capability *cap = regTableToCapability(reg);
+ bdescr *bd;
+ if (p->header.info == &stg_MUT_VAR_CLEAN_info) {
+ p->header.info = &stg_MUT_VAR_DIRTY_info;
+ bd = Bdescr((StgPtr)p);
+ if (bd->gen_no > 0) recordMutableCap(p,cap,bd->gen_no);
+ }
+}
+
+/* -----------------------------------------------------------------------------
Allocation functions for GMP.
These all use the allocate() interface - we can't have any garbage
total_size_in_words = sizeofW(StgArrWords) + data_size_in_words;
/* allocate and fill it in. */
- arr = (StgArrWords *)allocate(total_size_in_words);
+#if defined(THREADED_RTS)
+ arr = (StgArrWords *)allocateLocal(myTask()->cap, total_size_in_words);
+#else
+ arr = (StgArrWords *)allocateLocal(&MainCapability, total_size_in_words);
+#endif
SET_ARR_HDR(arr, &stg_ARR_WORDS_info, CCCS, data_size_in_words);
/* and return a ptr to the goods inside the array */
- return(BYTE_ARR_CTS(arr));
+ return arr->payload;
}
static void *
nat allocated;
bdescr *bd;
-#ifdef SMP
- Capability *cap;
-
- /* All tasks must be stopped. Can't assert that all the
- capabilities are owned by the scheduler, though: one or more
- tasks might have been stopped while they were running (non-main)
- threads. */
- /* ASSERT(n_free_capabilities == RtsFlags.ParFlags.nNodes); */
-
- allocated =
- n_free_capabilities * RtsFlags.GcFlags.minAllocAreaSize * BLOCK_SIZE_W
- + allocated_bytes();
-
- for (cap = free_capabilities; cap != NULL; cap = cap->link) {
- for ( bd = cap->r.rCurrentNursery->link; bd != NULL; bd = bd->link ) {
- allocated -= BLOCK_SIZE_W;
- }
- if (cap->r.rCurrentNursery->free < cap->r.rCurrentNursery->start
- + BLOCK_SIZE_W) {
- allocated -= (cap->r.rCurrentNursery->start + BLOCK_SIZE_W)
- - cap->r.rCurrentNursery->free;
- }
+ allocated = allocated_bytes();
+ allocated += countNurseryBlocks() * BLOCK_SIZE_W;
+
+ {
+#ifdef THREADED_RTS
+ nat i;
+ for (i = 0; i < n_nurseries; i++) {
+ Capability *cap;
+ for ( bd = capabilities[i].r.rCurrentNursery->link;
+ bd != NULL; bd = bd->link ) {
+ allocated -= BLOCK_SIZE_W;
+ }
+ cap = &capabilities[i];
+ if (cap->r.rCurrentNursery->free <
+ cap->r.rCurrentNursery->start + BLOCK_SIZE_W) {
+ allocated -= (cap->r.rCurrentNursery->start + BLOCK_SIZE_W)
+ - cap->r.rCurrentNursery->free;
+ }
}
-
-#else /* !SMP */
+#else
bdescr *current_nursery = MainCapability.r.rCurrentNursery;
- allocated = (g0s0->n_blocks * BLOCK_SIZE_W) + allocated_bytes();
for ( bd = current_nursery->link; bd != NULL; bd = bd->link ) {
- allocated -= BLOCK_SIZE_W;
+ allocated -= BLOCK_SIZE_W;
}
if (current_nursery->free < current_nursery->start + BLOCK_SIZE_W) {
- allocated -= (current_nursery->start + BLOCK_SIZE_W)
- - current_nursery->free;
+ allocated -= (current_nursery->start + BLOCK_SIZE_W)
+ - current_nursery->free;
}
#endif
+ }
total_allocated += allocated;
return allocated;
step *stp;
if (RtsFlags.GcFlags.generations == 1) {
- live = (g0s0->n_to_blocks - 1) * BLOCK_SIZE_W +
+ live = (g0s0->n_blocks - 1) * BLOCK_SIZE_W +
((lnat)g0s0->hp_bd->free - (lnat)g0s0->hp_bd->start) / sizeof(W_);
return live;
}
live += ((lnat)stp->hp_bd->free - (lnat)stp->hp_bd->start)
/ sizeof(W_);
}
+ if (stp->scavd_hp != NULL) {
+ live -= (P_)(BLOCK_ROUND_UP(stp->scavd_hp)) - stp->scavd_hp;
+ }
}
}
return live;
#ifdef DEBUG
+static lnat
+stepBlocks (step *stp)
+{
+ lnat total_blocks;
+ bdescr *bd;
+
+ total_blocks = stp->n_blocks;
+ total_blocks += stp->n_old_blocks;
+ for (bd = stp->large_objects; bd; bd = bd->link) {
+ total_blocks += bd->blocks;
+ /* hack for megablock groups: they have an extra block or two in
+ the second and subsequent megablocks where the block
+ descriptors would normally go.
+ */
+ if (bd->blocks > BLOCKS_PER_MBLOCK) {
+ total_blocks -= (MBLOCK_SIZE / BLOCK_SIZE - BLOCKS_PER_MBLOCK)
+ * (bd->blocks/(MBLOCK_SIZE/BLOCK_SIZE));
+ }
+ }
+ return total_blocks;
+}
+
void
memInventory(void)
{
- nat g, s;
+ nat g, s, i;
step *stp;
bdescr *bd;
lnat total_blocks = 0, free_blocks = 0;
/* count the blocks we current have */
for (g = 0; g < RtsFlags.GcFlags.generations; g++) {
- for (s = 0; s < generations[g].n_steps; s++) {
- stp = &generations[g].steps[s];
- total_blocks += stp->n_blocks;
- if (RtsFlags.GcFlags.generations == 1) {
- /* two-space collector has a to-space too :-) */
- total_blocks += g0s0->n_to_blocks;
+ for (i = 0; i < n_capabilities; i++) {
+ for (bd = capabilities[i].mut_lists[g]; bd != NULL; bd = bd->link) {
+ total_blocks += bd->blocks;
+ }
+ }
+ for (bd = generations[g].mut_list; bd != NULL; bd = bd->link) {
+ total_blocks += bd->blocks;
}
- for (bd = stp->large_objects; bd; bd = bd->link) {
- total_blocks += bd->blocks;
- /* hack for megablock groups: they have an extra block or two in
- the second and subsequent megablocks where the block
- descriptors would normally go.
- */
- if (bd->blocks > BLOCKS_PER_MBLOCK) {
- total_blocks -= (MBLOCK_SIZE / BLOCK_SIZE - BLOCKS_PER_MBLOCK)
- * (bd->blocks/(MBLOCK_SIZE/BLOCK_SIZE));
- }
+ for (s = 0; s < generations[g].n_steps; s++) {
+ if (g==0 && s==0) continue;
+ stp = &generations[g].steps[s];
+ total_blocks += stepBlocks(stp);
}
- }
}
+ for (i = 0; i < n_nurseries; i++) {
+ total_blocks += stepBlocks(&nurseries[i]);
+ }
+#ifdef THREADED_RTS
+ // We put pinned object blocks in g0s0, so better count blocks there too.
+ total_blocks += stepBlocks(g0s0);
+#endif
+
/* any blocks held by allocate() */
for (bd = small_alloc_list; bd; bd = bd->link) {
total_blocks += bd->blocks;
if (total_blocks + free_blocks != mblocks_allocated *
BLOCKS_PER_MBLOCK) {
- fprintf(stderr, "Blocks: %ld live + %ld free = %ld total (%ld around)\n",
+ debugBelch("Blocks: %ld live + %ld free = %ld total (%ld around)\n",
total_blocks, free_blocks, total_blocks + free_blocks,
mblocks_allocated * BLOCKS_PER_MBLOCK);
}
nat g, s;
if (RtsFlags.GcFlags.generations == 1) {
- checkHeap(g0s0->to_blocks);
+ checkHeap(g0s0->blocks);
checkChain(g0s0->large_objects);
} else {
for (g = 0; g < RtsFlags.GcFlags.generations; g++) {
for (s = 0; s < generations[g].n_steps; s++) {
+ if (g == 0 && s == 0) { continue; }
ASSERT(countBlocks(generations[g].steps[s].blocks)
== generations[g].steps[s].n_blocks);
ASSERT(countBlocks(generations[g].steps[s].large_objects)
== generations[g].steps[s].n_large_blocks);
- if (g == 0 && s == 0) { continue; }
checkHeap(generations[g].steps[s].blocks);
checkChain(generations[g].steps[s].large_objects);
if (g > 0) {
checkMutableList(generations[g].mut_list, g);
- checkMutOnceList(generations[g].mut_once_list, g);
}
}
}
+
+ for (s = 0; s < n_nurseries; s++) {
+ ASSERT(countBlocks(nurseries[s].blocks)
+ == nurseries[s].n_blocks);
+ ASSERT(countBlocks(nurseries[s].large_objects)
+ == nurseries[s].n_large_blocks);
+ }
+
checkFreeListSanity();
}
}
+/* Nursery sanity check */
+void
+checkNurserySanity( step *stp )
+{
+ bdescr *bd, *prev;
+ nat blocks = 0;
+
+ prev = NULL;
+ for (bd = stp->blocks; bd != NULL; bd = bd->link) {
+ ASSERT(bd->u.back == prev);
+ prev = bd;
+ blocks += bd->blocks;
+ }
+ ASSERT(blocks == stp->n_blocks);
+}
+
// handy function for use in gdb, because Bdescr() is inlined.
extern bdescr *_bdescr( StgPtr p );