/* -----------------------------------------------------------------------------
- * $Id: RetainerProfile.c,v 1.2 2001/11/26 16:54:21 simonmar Exp $
*
* (c) The GHC Team, 2001
* Author: Sungwoo Park
#ifdef PROFILING
+// Turn off inlining when debugging - it obfuscates things
+#ifdef DEBUG
+#define INLINE
+#else
+#define INLINE inline
+#endif
+
#include "Rts.h"
#include "RtsUtils.h"
#include "RetainerProfile.h"
#include "Schedule.h"
#include "Printer.h"
#include "Storage.h"
-#include "StoragePriv.h"
#include "RtsFlags.h"
#include "Weak.h"
#include "Sanity.h"
#include "Profiling.h"
#include "Stats.h"
#include "BlockAlloc.h"
-#include "Itimer.h"
-#include "Proftimer.h"
#include "ProfHeap.h"
+#include "Apply.h"
/*
Note: what to change in order to plug-in a new retainer profiling scheme?
#define setRetainerSetToNull(c) \
(c)->header.prof.hp.rs = (RetainerSet *)((StgWord)NULL | flip)
-static void retainStack(StgClosure *, StgClosure *, StgClosure *, StgPtr, StgPtr);
-static void retainClosure(StgClosure *, StgClosure *, StgClosure *);
+static void retainStack(StgClosure *, retainer, StgPtr, StgPtr);
+static void retainClosure(StgClosure *, StgClosure *, retainer);
#ifdef DEBUG_RETAINER
static void belongToHeap(StgPtr p);
#endif
posTypeStep,
posTypePtrs,
posTypeSRT,
+ posTypeLargeSRT,
} nextPosType;
typedef union {
// SRT
struct {
StgClosure **srt;
- StgClosure **srt_end;
+ StgWord srt_bitmap;
} srt;
+
+ // Large SRT
+ struct {
+ StgLargeSRT *srt;
+ StgWord offset;
+ } large_srt;
+
} nextPos;
typedef struct {
typedef struct {
StgClosure *c;
- StgClosure *c_child_r;
+ retainer c_child_r;
stackPos info;
} stackElement;
the topmost element on the previous block group so as to satisfy
the invariants described above.
*/
-bdescr *firstStack = NULL;
+static bdescr *firstStack = NULL;
static bdescr *currentStack;
static stackElement *stackBottom, *stackTop, *stackLimit;
* Invariants:
* currentStack->link == s.
* -------------------------------------------------------------------------- */
-static inline void
+static INLINE void
newStackBlock( bdescr *bd )
{
currentStack = bd;
* Invariants:
* s->link == currentStack.
* -------------------------------------------------------------------------- */
-static inline void
+static INLINE void
returnToOldStack( bdescr *bd )
{
currentStack = bd;
/* -----------------------------------------------------------------------------
* Returns rtsTrue if the whole stack is empty.
* -------------------------------------------------------------------------- */
-static inline rtsBool
+static INLINE rtsBool
isEmptyRetainerStack( void )
{
return (firstStack == currentStack) && stackTop == stackLimit;
}
/* -----------------------------------------------------------------------------
+ * Returns size of stack
+ * -------------------------------------------------------------------------- */
+#ifdef DEBUG
+lnat
+retainerStackBlocks( void )
+{
+ bdescr* bd;
+ lnat res = 0;
+
+ for (bd = firstStack; bd != NULL; bd = bd->link)
+ res += bd->blocks;
+
+ return res;
+}
+#endif
+
+/* -----------------------------------------------------------------------------
* Returns rtsTrue if stackTop is at the stack boundary of the current stack,
* i.e., if the current stack chunk is empty.
* -------------------------------------------------------------------------- */
-static inline rtsBool
+static INLINE rtsBool
isOnBoundary( void )
{
return stackTop == currentStackBoundary;
* Invariants:
* payload[] begins with ptrs pointers followed by non-pointers.
* -------------------------------------------------------------------------- */
-static inline void
+static INLINE void
init_ptrs( stackPos *info, nat ptrs, StgPtr payload )
{
info->type = posTypePtrs;
/* -----------------------------------------------------------------------------
* Find the next object from *info.
* -------------------------------------------------------------------------- */
-static inline StgClosure *
+static INLINE StgClosure *
find_ptrs( stackPos *info )
{
if (info->next.ptrs.pos < info->next.ptrs.ptrs) {
/* -----------------------------------------------------------------------------
* Initializes *info from SRT information stored in *infoTable.
* -------------------------------------------------------------------------- */
-static inline void
-init_srt( stackPos *info, StgInfoTable *infoTable )
+static INLINE void
+init_srt_fun( stackPos *info, StgFunInfoTable *infoTable )
+{
+ if (infoTable->i.srt_bitmap == (StgHalfWord)(-1)) {
+ info->type = posTypeLargeSRT;
+ info->next.large_srt.srt = (StgLargeSRT *)GET_FUN_SRT(infoTable);
+ info->next.large_srt.offset = 0;
+ } else {
+ info->type = posTypeSRT;
+ info->next.srt.srt = (StgClosure **)GET_FUN_SRT(infoTable);
+ info->next.srt.srt_bitmap = infoTable->i.srt_bitmap;
+ }
+}
+
+static INLINE void
+init_srt_thunk( stackPos *info, StgThunkInfoTable *infoTable )
{
- info->type = posTypeSRT;
- info->next.srt.srt = (StgClosure **)(infoTable->srt);
- info->next.srt.srt_end = info->next.srt.srt + infoTable->srt_len;
+ if (infoTable->i.srt_bitmap == (StgHalfWord)(-1)) {
+ info->type = posTypeLargeSRT;
+ info->next.large_srt.srt = (StgLargeSRT *)GET_SRT(infoTable);
+ info->next.large_srt.offset = 0;
+ } else {
+ info->type = posTypeSRT;
+ info->next.srt.srt = (StgClosure **)GET_SRT(infoTable);
+ info->next.srt.srt_bitmap = infoTable->i.srt_bitmap;
+ }
}
/* -----------------------------------------------------------------------------
* Find the next object from *info.
* -------------------------------------------------------------------------- */
-static inline StgClosure *
+static INLINE StgClosure *
find_srt( stackPos *info )
{
StgClosure *c;
+ StgWord bitmap;
- if (info->next.srt.srt < info->next.srt.srt_end) {
- // See scavenge_srt() in GC.c for details.
+ if (info->type == posTypeSRT) {
+ // Small SRT bitmap
+ bitmap = info->next.srt.srt_bitmap;
+ while (bitmap != 0) {
+ if ((bitmap & 1) != 0) {
#ifdef ENABLE_WIN32_DLL_SUPPORT
- if ((unsigned long)(*(info->next.srt.srt)) & 0x1)
- c = (* (StgClosure **)((unsigned long)*(info->next.srt.srt)) & ~0x1);
- else
- c = *(info->next.srt.srt);
+
+ if ((unsigned long)(*(info->next.srt.srt)) & 0x1)
+ c = (* (StgClosure **)((unsigned long)*(info->next.srt.srt)) & ~0x1);
+ else
+ c = *(info->next.srt.srt);
#else
- c = *(info->next.srt.srt);
+ c = *(info->next.srt.srt);
#endif
- info->next.srt.srt++;
- return c;
- } else {
+ bitmap = bitmap >> 1;
+ info->next.srt.srt++;
+ info->next.srt.srt_bitmap = bitmap;
+ return c;
+ }
+ bitmap = bitmap >> 1;
+ info->next.srt.srt++;
+ }
+ // bitmap is now zero...
+ return NULL;
+ }
+ else {
+ // Large SRT bitmap
+ nat i = info->next.large_srt.offset;
+ StgWord bitmap;
+
+ // Follow the pattern from GC.c:scavenge_large_srt_bitmap().
+ bitmap = info->next.large_srt.srt->l.bitmap[i / BITS_IN(W_)];
+ bitmap = bitmap >> (i % BITS_IN(StgWord));
+ while (i < info->next.large_srt.srt->l.size) {
+ if ((bitmap & 1) != 0) {
+ c = ((StgClosure **)info->next.large_srt.srt->srt)[i];
+ i++;
+ info->next.large_srt.offset = i;
+ return c;
+ }
+ i++;
+ if (i % BITS_IN(W_) == 0) {
+ bitmap = info->next.large_srt.srt->l.bitmap[i / BITS_IN(W_)];
+ } else {
+ bitmap = bitmap >> 1;
+ }
+ }
+ // reached the end of this bitmap.
+ info->next.large_srt.offset = i;
return NULL;
}
}
* Invariants:
* *c_child_r is the most recent retainer of *c's children.
- * *c is not any of TSO, PAP, or AP_UPD, which means that
+ * *c is not any of TSO, AP, PAP, AP_STACK, which means that
* there cannot be any stack objects.
* Note: SRTs are considered to be children as well.
* -------------------------------------------------------------------------- */
-static inline void
-push( StgClosure *c, StgClosure *c_child_r, StgClosure **first_child )
+static INLINE void
+push( StgClosure *c, retainer c_child_r, StgClosure **first_child )
{
stackElement se;
bdescr *nbd; // Next Block Descriptor
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "push(): stackTop = 0x%x, currentStackBoundary = 0x%x\n", stackTop, currentStackBoundary);
+ // debugBelch("push(): stackTop = 0x%x, currentStackBoundary = 0x%x\n", stackTop, currentStackBoundary);
#endif
ASSERT(get_itbl(c)->type != TSO);
- ASSERT(get_itbl(c)->type != PAP);
- ASSERT(get_itbl(c)->type != AP_UPD);
+ ASSERT(get_itbl(c)->type != AP_STACK);
//
// fill in se
// one child (fixed), no SRT
case MUT_VAR:
- case MUT_CONS:
*first_child = ((StgMutVar *)c)->var;
return;
case BLACKHOLE_BQ:
case IND_PERM:
case IND_OLDGEN_PERM:
case IND_OLDGEN:
- *first_child = ((StgIndOldGen *)c)->indirectee;
+ *first_child = ((StgInd *)c)->indirectee;
return;
case CONSTR_1_0:
case CONSTR_1_1:
// layout.payload.ptrs, SRT
case FUN: // *c is a heap object.
case FUN_2_0:
+ init_ptrs(&se.info, get_itbl(c)->layout.payload.ptrs, (StgPtr)c->payload);
+ *first_child = find_ptrs(&se.info);
+ if (*first_child == NULL)
+ // no child from ptrs, so check SRT
+ goto fun_srt_only;
+ break;
+
case THUNK:
case THUNK_2_0:
init_ptrs(&se.info, get_itbl(c)->layout.payload.ptrs, (StgPtr)c->payload);
*first_child = find_ptrs(&se.info);
if (*first_child == NULL)
// no child from ptrs, so check SRT
- goto srt_only;
+ goto thunk_srt_only;
break;
// 1 fixed child, SRT
case FUN_1_0:
case FUN_1_1:
+ *first_child = c->payload[0];
+ ASSERT(*first_child != NULL);
+ init_srt_fun(&se.info, get_fun_itbl(c));
+ break;
+
case THUNK_1_0:
case THUNK_1_1:
*first_child = c->payload[0];
ASSERT(*first_child != NULL);
- init_srt(&se.info, get_itbl(c));
+ init_srt_thunk(&se.info, get_thunk_itbl(c));
break;
- // SRT only
- case THUNK_STATIC:
case FUN_STATIC: // *c is a heap object.
- ASSERT(get_itbl(c)->srt_len != 0);
+ ASSERT(get_itbl(c)->srt_bitmap != 0);
case FUN_0_1:
case FUN_0_2:
+ fun_srt_only:
+ init_srt_fun(&se.info, get_fun_itbl(c));
+ *first_child = find_srt(&se.info);
+ if (*first_child == NULL)
+ return; // no child
+ break;
+
+ // SRT only
+ case THUNK_STATIC:
+ ASSERT(get_itbl(c)->srt_bitmap != 0);
case THUNK_0_1:
case THUNK_0_2:
- srt_only:
- init_srt(&se.info, get_itbl(c));
+ thunk_srt_only:
+ init_srt_thunk(&se.info, get_thunk_itbl(c));
*first_child = find_srt(&se.info);
if (*first_child == NULL)
return; // no child
// cannot appear
case PAP:
- case AP_UPD:
+ case AP:
+ case AP_STACK:
case TSO:
case IND_STATIC:
case CONSTR_INTLIKE:
case UPDATE_FRAME:
case CATCH_FRAME:
case STOP_FRAME:
- case SEQ_FRAME:
case RET_DYN:
case RET_BCO:
case RET_SMALL:
if (stackTop - 1 < stackBottom) {
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "push() to the next stack.\n");
+ // debugBelch("push() to the next stack.\n");
#endif
// currentStack->free is updated when the active stack is switched
// to the next stack.
stackSize++;
if (stackSize > maxStackSize) maxStackSize = stackSize;
// ASSERT(stackSize >= 0);
- // fprintf(stderr, "stackSize = %d\n", stackSize);
+ // debugBelch("stackSize = %d\n", stackSize);
#endif
}
* executed at the end of popOff() in necessary. Since popOff() is
* likely to be executed quite often while popOffReal() is not, we
* separate popOffReal() from popOff(), which is declared as an
- * inline function (for the sake of execution speed). popOffReal()
+ * INLINE function (for the sake of execution speed). popOffReal()
* is called only within popOff() and nowhere else.
* -------------------------------------------------------------------------- */
static void
bdescr *pbd; // Previous Block Descriptor
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "pop() to the previous stack.\n");
+ // debugBelch("pop() to the previous stack.\n");
#endif
ASSERT(stackTop + 1 == stackLimit);
if (stackSize > maxStackSize) maxStackSize = stackSize;
/*
ASSERT(stackSize >= 0);
- fprintf(stderr, "stackSize = %d\n", stackSize);
+ debugBelch("stackSize = %d\n", stackSize);
*/
#endif
return;
if (stackSize > maxStackSize) maxStackSize = stackSize;
/*
ASSERT(stackSize >= 0);
- fprintf(stderr, "stackSize = %d\n", stackSize);
+ debugBelch("stackSize = %d\n", stackSize);
*/
#endif
}
-static inline void
+static INLINE void
popOff(void) {
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "\tpopOff(): stackTop = 0x%x, currentStackBoundary = 0x%x\n", stackTop, currentStackBoundary);
+ // debugBelch("\tpopOff(): stackTop = 0x%x, currentStackBoundary = 0x%x\n", stackTop, currentStackBoundary);
#endif
ASSERT(stackTop != stackLimit);
if (stackSize > maxStackSize) maxStackSize = stackSize;
/*
ASSERT(stackSize >= 0);
- fprintf(stderr, "stackSize = %d\n", stackSize);
+ debugBelch("stackSize = %d\n", stackSize);
*/
#endif
return;
* It is okay to call this function even when the current stack chunk
* is empty.
* -------------------------------------------------------------------------- */
-static inline void
-pop( StgClosure **c, StgClosure **cp, StgClosure **r )
+static INLINE void
+pop( StgClosure **c, StgClosure **cp, retainer *r )
{
stackElement *se;
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "pop(): stackTop = 0x%x, currentStackBoundary = 0x%x\n", stackTop, currentStackBoundary);
+ // debugBelch("pop(): stackTop = 0x%x, currentStackBoundary = 0x%x\n", stackTop, currentStackBoundary);
#endif
do {
// layout.payload.ptrs, SRT
case FUN: // always a heap object
case FUN_2_0:
+ if (se->info.type == posTypePtrs) {
+ *c = find_ptrs(&se->info);
+ if (*c != NULL) {
+ *cp = se->c;
+ *r = se->c_child_r;
+ return;
+ }
+ init_srt_fun(&se->info, get_fun_itbl(se->c));
+ }
+ goto do_srt;
+
case THUNK:
case THUNK_2_0:
if (se->info.type == posTypePtrs) {
*r = se->c_child_r;
return;
}
- init_srt(&se->info, get_itbl(se->c));
+ init_srt_thunk(&se->info, get_thunk_itbl(se->c));
}
- // fall through
+ goto do_srt;
// SRT
+ do_srt:
case THUNK_STATIC:
case FUN_STATIC:
case FUN_0_1:
case ARR_WORDS:
// one child (fixed), no SRT
case MUT_VAR:
- case MUT_CONS:
case BLACKHOLE_BQ:
case THUNK_SELECTOR:
case IND_PERM:
case CONSTR_1_1:
// cannot appear
case PAP:
- case AP_UPD:
+ case AP:
+ case AP_STACK:
case TSO:
case IND_STATIC:
case CONSTR_INTLIKE:
case UPDATE_FRAME:
case CATCH_FRAME:
case STOP_FRAME:
- case SEQ_FRAME:
case RET_BCO:
case RET_SMALL:
case RET_VEC_SMALL:
* We have to perform an XOR (^) operation each time a closure is examined.
* The reason is that we do not know when a closure is visited last.
* -------------------------------------------------------------------------- */
-static inline void
+static INLINE void
maybeInitRetainerSet( StgClosure *c )
{
if (!isRetainerSetFieldValid(c)) {
/* -----------------------------------------------------------------------------
* Returns rtsTrue if *c is a retainer.
* -------------------------------------------------------------------------- */
-static inline rtsBool
+static INLINE rtsBool
isRetainer( StgClosure *c )
{
- if (get_itbl(c)->prof.closure_desc != NULL && !strcmp(get_itbl(c)->prof.closure_desc,"PCS")) { return rtsTrue; }
-
switch (get_itbl(c)->type) {
//
// True case
// mutable objects
case MVAR:
case MUT_VAR:
- case MUT_CONS:
case MUT_ARR_PTRS:
case MUT_ARR_PTRS_FROZEN:
case THUNK_1_1:
case THUNK_0_2:
case THUNK_SELECTOR:
- case AP_UPD:
+ case AP:
+ case AP_STACK:
// Static thunks, or CAFS, are obviously retainers.
case THUNK_STATIC:
case UPDATE_FRAME:
case CATCH_FRAME:
case STOP_FRAME:
- case SEQ_FRAME:
case RET_DYN:
case RET_BCO:
case RET_SMALL:
* re-initialize the hash table.
* See refreshAllRetainerSet() in RetainerSet.c.
* -------------------------------------------------------------------------- */
-static inline retainer
+static INLINE retainer
getRetainerFrom( StgClosure *c )
{
ASSERT(isRetainer(c));
* c != NULL
* s != NULL
* -------------------------------------------------------------------------- */
-static inline void
+static INLINE void
associate( StgClosure *c, RetainerSet *s )
{
// StgWord has the same size as pointers, so the following type
}
/* -----------------------------------------------------------------------------
+ Call retainClosure for each of the closures covered by a large bitmap.
+ -------------------------------------------------------------------------- */
+
+static void
+retain_large_bitmap (StgPtr p, StgLargeBitmap *large_bitmap, nat size,
+ StgClosure *c, retainer c_child_r)
+{
+ nat i, b;
+ StgWord bitmap;
+
+ b = 0;
+ bitmap = large_bitmap->bitmap[b];
+ for (i = 0; i < size; ) {
+ if ((bitmap & 1) == 0) {
+ retainClosure((StgClosure *)*p, c, c_child_r);
+ }
+ i++;
+ p++;
+ if (i % BITS_IN(W_) == 0) {
+ b++;
+ bitmap = large_bitmap->bitmap[b];
+ } else {
+ bitmap = bitmap >> 1;
+ }
+ }
+}
+
+static INLINE StgPtr
+retain_small_bitmap (StgPtr p, nat size, StgWord bitmap,
+ StgClosure *c, retainer c_child_r)
+{
+ while (size > 0) {
+ if ((bitmap & 1) == 0) {
+ retainClosure((StgClosure *)*p, c, c_child_r);
+ }
+ p++;
+ bitmap = bitmap >> 1;
+ size--;
+ }
+ return p;
+}
+
+/* -----------------------------------------------------------------------------
+ * Call retainClosure for each of the closures in an SRT.
+ * ------------------------------------------------------------------------- */
+
+static void
+retain_large_srt_bitmap (StgLargeSRT *srt, StgClosure *c, retainer c_child_r)
+{
+ nat i, b, size;
+ StgWord bitmap;
+ StgClosure **p;
+
+ b = 0;
+ p = (StgClosure **)srt->srt;
+ size = srt->l.size;
+ bitmap = srt->l.bitmap[b];
+ for (i = 0; i < size; ) {
+ if ((bitmap & 1) != 0) {
+ retainClosure((StgClosure *)*p, c, c_child_r);
+ }
+ i++;
+ p++;
+ if (i % BITS_IN(W_) == 0) {
+ b++;
+ bitmap = srt->l.bitmap[b];
+ } else {
+ bitmap = bitmap >> 1;
+ }
+ }
+}
+
+static INLINE void
+retainSRT (StgClosure **srt, nat srt_bitmap, StgClosure *c, retainer c_child_r)
+{
+ nat bitmap;
+ StgClosure **p;
+
+ bitmap = srt_bitmap;
+ p = srt;
+
+ if (bitmap == (StgHalfWord)(-1)) {
+ retain_large_srt_bitmap( (StgLargeSRT *)srt, c, c_child_r );
+ return;
+ }
+
+ while (bitmap != 0) {
+ if ((bitmap & 1) != 0) {
+#ifdef ENABLE_WIN32_DLL_SUPPORT
+ if ( (unsigned long)(*srt) & 0x1 ) {
+ retainClosure(*stgCast(StgClosure**,(stgCast(unsigned long, *srt) & ~0x1)),
+ c, c_child_r);
+ } else {
+ retainClosure(*srt,c,c_child_r);
+ }
+#else
+ retainClosure(*srt,c,c_child_r);
+#endif
+ }
+ p++;
+ bitmap = bitmap >> 1;
+ }
+}
+
+/* -----------------------------------------------------------------------------
* Process all the objects in the stack chunk from stackStart to stackEnd
* with *c and *c_child_r being their parent and their most recent retainer,
* respectively. Treat stackOptionalFun as another child of *c if it is
* not NULL.
* Invariants:
- * *c is one of the following: TSO, PAP, and AP_UPD.
- * If *c is AP_UPD or PAP, stackOptionalFun is not NULL. Otherwise,
- * it is NULL.
+ * *c is one of the following: TSO, AP_STACK.
* If *c is TSO, c == c_child_r.
* stackStart < stackEnd.
* RSET(c) and RSET(c_child_r) are valid, i.e., their
* retainClosure() is invoked instead of evacuate().
* -------------------------------------------------------------------------- */
static void
-retainStack( StgClosure *c, StgClosure *c_child_r,
- StgClosure *stackOptionalFun, StgPtr stackStart,
- StgPtr stackEnd )
+retainStack( StgClosure *c, retainer c_child_r,
+ StgPtr stackStart, StgPtr stackEnd )
{
stackElement *oldStackBoundary;
- StgPtr p, q;
- StgInfoTable *info;
+ StgPtr p;
+ StgRetInfoTable *info;
StgWord32 bitmap;
+ nat size;
#ifdef DEBUG_RETAINER
cStackSize++;
currentStackBoundary = stackTop;
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "retainStack() called: oldStackBoundary = 0x%x, currentStackBoundary = 0x%x\n", oldStackBoundary, currentStackBoundary);
+ // debugBelch("retainStack() called: oldStackBoundary = 0x%x, currentStackBoundary = 0x%x\n", oldStackBoundary, currentStackBoundary);
#endif
- if (stackOptionalFun != NULL) {
- ASSERT(get_itbl(c)->type == AP_UPD || get_itbl(c)->type == PAP);
- retainClosure(stackOptionalFun, c, c_child_r);
- } else {
- ASSERT(get_itbl(c)->type == TSO);
- ASSERT(((StgTSO *)c)->what_next != ThreadRelocated &&
- ((StgTSO *)c)->what_next != ThreadComplete &&
- ((StgTSO *)c)->what_next != ThreadKilled);
- }
-
+ ASSERT(get_itbl(c)->type != TSO ||
+ (((StgTSO *)c)->what_next != ThreadRelocated &&
+ ((StgTSO *)c)->what_next != ThreadComplete &&
+ ((StgTSO *)c)->what_next != ThreadKilled));
+
p = stackStart;
while (p < stackEnd) {
- q = *(StgPtr *)p;
-
- //
- // Note & Todo:
- // The correctness of retainer profiling is subject to the
- // correctness of the two macros IS_ARG_TAG() and
- // LOOKS_LIKE_GHC_INFO(). Since LOOKS_LIKE_GHC_INFO() is a bit
- // precarious macro, so I believe that the current
- // implementation may not be quite safe. Also, scavenge_stack()
- // in GC.c also exploits this macro in order to identify shallow
- // pointers. I am not sure whether scavenge_stack() takes
- // further measurements to discern real shallow pointers.
- //
- // I think this can be a serious problem if a stack chunk
- // contains some word which looks like a pointer but is
- // actually, say, a word constituting a floating number.
- //
-
- // skip tagged words
- if (IS_ARG_TAG((StgWord)q)) {
- p += 1 + ARG_SIZE(q);
- continue;
- }
-
- // check if *p is a shallow closure pointer
- if (!LOOKS_LIKE_GHC_INFO(q)) {
- retainClosure((StgClosure *)q, c, c_child_r);
- p++;
- continue;
- }
-
- // regular stack objects
- info = get_itbl((StgClosure *)p);
- switch(info->type) {
- case RET_DYN:
- bitmap = ((StgRetDyn *)p)->liveness;
- p = ((StgRetDyn *)p)->payload;
- goto small_bitmap;
+ info = get_ret_itbl((StgClosure *)p);
- // FUN and FUN_STATIC keep only their info pointer.
- case FUN:
- case FUN_STATIC:
- p++;
- goto follow_srt;
+ switch(info->i.type) {
case UPDATE_FRAME:
retainClosure(((StgUpdateFrame *)p)->updatee, c, c_child_r);
case STOP_FRAME:
case CATCH_FRAME:
- case SEQ_FRAME:
- case RET_BCO:
case RET_SMALL:
case RET_VEC_SMALL:
- bitmap = info->layout.bitmap;
+ bitmap = BITMAP_BITS(info->i.layout.bitmap);
+ size = BITMAP_SIZE(info->i.layout.bitmap);
p++;
- small_bitmap:
- while (bitmap != 0) {
- if ((bitmap & 1) == 0)
- retainClosure((StgClosure *)*p, c, c_child_r);
- p++;
- bitmap = bitmap >> 1;
- }
+ p = retain_small_bitmap(p, size, bitmap, c, c_child_r);
+
follow_srt:
- {
- StgClosure **srt, **srt_end;
+ retainSRT((StgClosure **)GET_SRT(info), info->i.srt_bitmap, c, c_child_r);
+ continue;
- srt = (StgClosure **)(info->srt);
- srt_end = srt + info->srt_len;
- for (; srt < srt_end; srt++) {
- // See scavenge_srt() in GC.c for details.
-#ifdef ENABLE_WIN32_DLL_SUPPORT
- if ((unsigned long)(*srt) & 0x1)
- retainClosure(*(StgClosure **)(((unsigned long)*srt & ~0x1)), c, c_child_r);
- else
- retainClosure(*srt, c, c_child_r);
-#else
- retainClosure(*srt, c, c_child_r);
-#endif
- }
- }
+ case RET_BCO: {
+ StgBCO *bco;
+
+ p++;
+ retainClosure((StgClosure *)*p, c, c_child_r);
+ bco = (StgBCO *)*p;
+ p++;
+ size = BCO_BITMAP_SIZE(bco);
+ retain_large_bitmap(p, BCO_BITMAP(bco), size, c, c_child_r);
+ p += size;
continue;
+ }
+ // large bitmap (> 32 entries, or > 64 on a 64-bit machine)
case RET_BIG:
case RET_VEC_BIG:
- {
- StgPtr q;
- StgLargeBitmap *large_bitmap;
- nat i;
-
- large_bitmap = info->layout.large_bitmap;
+ size = GET_LARGE_BITMAP(&info->i)->size;
p++;
+ retain_large_bitmap(p, GET_LARGE_BITMAP(&info->i),
+ size, c, c_child_r);
+ p += size;
+ // and don't forget to follow the SRT
+ goto follow_srt;
- for (i = 0; i < large_bitmap->size; i++) {
- bitmap = large_bitmap->bitmap[i];
- q = p + sizeofW(StgWord) * 8;
- while (bitmap != 0) {
- if ((bitmap & 1) == 0)
- retainClosure((StgClosure *)*p, c, c_child_r);
- p++;
- bitmap = bitmap >> 1;
- }
- if (i + 1 < large_bitmap->size) {
- while (p < q) {
- retainClosure((StgClosure *)*p, c, c_child_r);
- p++;
- }
- }
+ // Dynamic bitmap: the mask is stored on the stack
+ case RET_DYN: {
+ StgWord dyn;
+ dyn = ((StgRetDyn *)p)->liveness;
+
+ // traverse the bitmap first
+ bitmap = RET_DYN_LIVENESS(dyn);
+ p = (P_)&((StgRetDyn *)p)->payload[0];
+ size = RET_DYN_BITMAP_SIZE;
+ p = retain_small_bitmap(p, size, bitmap, c, c_child_r);
+
+ // skip over the non-ptr words
+ p += RET_DYN_NONPTRS(dyn) + RET_DYN_NONPTR_REGS_SIZE;
+
+ // follow the ptr words
+ for (size = RET_DYN_PTRS(dyn); size > 0; size--) {
+ retainClosure((StgClosure *)*p, c, c_child_r);
+ p++;
}
+ continue;
}
- goto follow_srt;
+
+ case RET_FUN: {
+ StgRetFun *ret_fun = (StgRetFun *)p;
+ StgFunInfoTable *fun_info;
+
+ retainClosure(ret_fun->fun, c, c_child_r);
+ fun_info = get_fun_itbl(ret_fun->fun);
+
+ p = (P_)&ret_fun->payload;
+ switch (fun_info->f.fun_type) {
+ case ARG_GEN:
+ bitmap = BITMAP_BITS(fun_info->f.bitmap);
+ size = BITMAP_SIZE(fun_info->f.bitmap);
+ p = retain_small_bitmap(p, size, bitmap, c, c_child_r);
+ break;
+ case ARG_GEN_BIG:
+ size = GET_FUN_LARGE_BITMAP(fun_info)->size;
+ retain_large_bitmap(p, GET_FUN_LARGE_BITMAP(fun_info),
+ size, c, c_child_r);
+ p += size;
+ break;
+ default:
+ bitmap = BITMAP_BITS(stg_arg_bitmaps[fun_info->f.fun_type]);
+ size = BITMAP_SIZE(stg_arg_bitmaps[fun_info->f.fun_type]);
+ p = retain_small_bitmap(p, size, bitmap, c, c_child_r);
+ break;
+ }
+ goto follow_srt;
+ }
+
default:
barf("Invalid object found in retainStack(): %d",
- (int)(info->type));
+ (int)(info->i.type));
}
}
// restore currentStackBoundary
currentStackBoundary = oldStackBoundary;
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "retainStack() finished: currentStackBoundary = 0x%x\n", currentStackBoundary);
+ // debugBelch("retainStack() finished: currentStackBoundary = 0x%x\n", currentStackBoundary);
#endif
#ifdef DEBUG_RETAINER
#endif
}
+/* ----------------------------------------------------------------------------
+ * Call retainClosure for each of the children of a PAP/AP
+ * ------------------------------------------------------------------------- */
+
+static INLINE StgPtr
+retain_PAP (StgPAP *pap, retainer c_child_r)
+{
+ StgPtr p;
+ StgWord bitmap, size;
+ StgFunInfoTable *fun_info;
+
+ retainClosure(pap->fun, (StgClosure *)pap, c_child_r);
+ fun_info = get_fun_itbl(pap->fun);
+ ASSERT(fun_info->i.type != PAP);
+
+ p = (StgPtr)pap->payload;
+ size = pap->n_args;
+
+ switch (fun_info->f.fun_type) {
+ case ARG_GEN:
+ bitmap = BITMAP_BITS(fun_info->f.bitmap);
+ p = retain_small_bitmap(p, pap->n_args, bitmap,
+ (StgClosure *)pap, c_child_r);
+ break;
+ case ARG_GEN_BIG:
+ retain_large_bitmap(p, GET_FUN_LARGE_BITMAP(fun_info),
+ size, (StgClosure *)pap, c_child_r);
+ p += size;
+ break;
+ case ARG_BCO:
+ retain_large_bitmap((StgPtr)pap->payload, BCO_BITMAP(pap->fun),
+ size, (StgClosure *)pap, c_child_r);
+ p += size;
+ break;
+ default:
+ bitmap = BITMAP_BITS(stg_arg_bitmaps[fun_info->f.fun_type]);
+ p = retain_small_bitmap(p, pap->n_args, bitmap,
+ (StgClosure *)pap, c_child_r);
+ break;
+ }
+ return p;
+}
+
/* -----------------------------------------------------------------------------
* Compute the retainer set of *c0 and all its desecents by traversing.
* *cp0 is the parent of *c0, and *r0 is the most recent retainer of *c0.
* its descendants.
* Note:
* stackTop must be the same at the beginning and the exit of this function.
- * *c0 can be TSO (as well as PAP and AP_UPD).
+ * *c0 can be TSO (as well as AP_STACK).
* -------------------------------------------------------------------------- */
static void
-retainClosure( StgClosure *c0, StgClosure *cp0, StgClosure *r0 )
+retainClosure( StgClosure *c0, StgClosure *cp0, retainer r0 )
{
// c = Current closure
// cp = Current closure's Parent
// r = current closures' most recent Retainer
// c_child_r = current closure's children's most recent retainer
// first_child = first child of c
- StgClosure *c, *cp, *r, *c_child_r, *first_child;
+ StgClosure *c, *cp, *first_child;
RetainerSet *s, *retainerSetOfc;
- retainer R_r;
+ retainer r, c_child_r;
StgWord typeOfc;
#ifdef DEBUG_RETAINER
#ifdef DEBUG_RETAINER
// oldStackTop = stackTop;
- // fprintf(stderr, "retainClosure() called: c0 = 0x%x, cp0 = 0x%x, r0 = 0x%x\n", c0, cp0, r0);
+ // debugBelch("retainClosure() called: c0 = 0x%x, cp0 = 0x%x, r0 = 0x%x\n", c0, cp0, r0);
#endif
// (c, cp, r) = (c0, cp0, r0)
goto inner_loop;
loop:
- //fprintf(stderr, "loop");
+ //debugBelch("loop");
// pop to (c, cp, r);
pop(&c, &cp, &r);
if (c == NULL) {
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "retainClosure() ends: oldStackTop = 0x%x, stackTop = 0x%x\n", oldStackTop, stackTop);
+ // debugBelch("retainClosure() ends: oldStackTop = 0x%x, stackTop = 0x%x\n", oldStackTop, stackTop);
#endif
return;
}
- //fprintf(stderr, "inner_loop");
+ //debugBelch("inner_loop");
inner_loop:
// c = current closure under consideration,
if (((StgTSO *)c)->what_next == ThreadComplete ||
((StgTSO *)c)->what_next == ThreadKilled) {
#ifdef DEBUG_RETAINER
- fprintf(stderr, "ThreadComplete or ThreadKilled encountered in retainClosure()\n");
+ debugBelch("ThreadComplete or ThreadKilled encountered in retainClosure()\n");
#endif
goto loop;
}
if (((StgTSO *)c)->what_next == ThreadRelocated) {
#ifdef DEBUG_RETAINER
- fprintf(stderr, "ThreadRelocated encountered in retainClosure()\n");
+ debugBelch("ThreadRelocated encountered in retainClosure()\n");
#endif
c = (StgClosure *)((StgTSO *)c)->link;
goto inner_loop;
goto loop;
case THUNK_STATIC:
case FUN_STATIC:
- if (get_itbl(c)->srt_len == 0) {
+ if (get_itbl(c)->srt_bitmap == 0) {
// No need to compute the retainer set; no dynamic objects
// are reachable from *c.
//
s = retainerSetOf(cp);
// (c, cp, r, s) is available.
- R_r = getRetainerFrom(r);
// (c, cp, r, s, R_r) is available, so compute the retainer set for *c.
if (retainerSetOfc == NULL) {
numObjectVisited++;
if (s == NULL)
- associate(c, singleton(R_r));
+ associate(c, singleton(r));
else
// s is actually the retainer set of *c!
associate(c, s);
// compute c_child_r
- c_child_r = isRetainer(c) ? c : r;
+ c_child_r = isRetainer(c) ? getRetainerFrom(c) : r;
} else {
// This is not the first visit to *c.
- if (isMember(R_r, retainerSetOfc))
+ if (isMember(r, retainerSetOfc))
goto loop; // no need to process child
if (s == NULL)
- associate(c, addElement(R_r, retainerSetOfc));
+ associate(c, addElement(r, retainerSetOfc));
else {
// s is not NULL and cp is not a retainer. This means that
// each time *cp is visited, so is *c. Thus, if s has
}
// Otherwise, just add R_r to the current retainer set of *c.
else {
- associate(c, addElement(R_r, retainerSetOfc));
+ associate(c, addElement(r, retainerSetOfc));
}
}
// process child
- if (typeOfc == TSO) {
+ // Special case closures: we process these all in one go rather
+ // than attempting to save the current position, because doing so
+ // would be hard.
+ switch (typeOfc) {
+ case TSO:
retainStack(c, c_child_r,
- NULL,
((StgTSO *)c)->sp,
((StgTSO *)c)->stack + ((StgTSO *)c)->stack_size);
- // no more children
goto loop;
- } else if (typeOfc == PAP) {
- retainStack(c, c_child_r,
- ((StgPAP *)c)->fun,
- (StgPtr)((StgPAP *)c)->payload,
- (StgPtr)((StgPAP *)c)->payload + ((StgPAP *)c)->n_args);
- // no more children
+
+ case PAP:
+ case AP:
+ retain_PAP((StgPAP *)c, c_child_r);
goto loop;
- } else if (typeOfc == AP_UPD) {
+
+ case AP_STACK:
+ retainClosure(((StgAP_STACK *)c)->fun, c, c_child_r);
retainStack(c, c_child_r,
- ((StgAP_UPD *)c)->fun,
- (StgPtr)((StgAP_UPD *)c)->payload,
- (StgPtr)((StgAP_UPD *)c)->payload +
- ((StgAP_UPD *)c)->n_args);
- // no more children
+ (StgPtr)((StgAP_STACK *)c)->payload,
+ (StgPtr)((StgAP_STACK *)c)->payload +
+ ((StgAP_STACK *)c)->size);
goto loop;
}
ASSERT(isEmptyRetainerStack());
currentStackBoundary = stackTop;
- retainClosure(*tl, *tl, *tl);
+ if (isRetainer(*tl)) {
+ retainClosure(*tl, *tl, getRetainerFrom(*tl));
+ } else {
+ retainClosure(*tl, *tl, CCS_SYSTEM);
+ }
// NOT TRUE: ASSERT(isMember(getRetainerFrom(*tl), retainerSetOf(*tl)));
// *tl might be a TSO which is ThreadComplete, in which
StgWeak *weak;
RetainerSet *rtl;
nat g;
- StgMutClosure *ml;
+ StgPtr ml;
+ bdescr *bd;
#ifdef DEBUG_RETAINER
RetainerSet tmpRetainerSet;
#endif
// retainRoot((StgClosure *)weak);
retainRoot((StgClosure **)&weak);
+ // Consider roots from the stable ptr table.
+ markStablePtrTable(retainRoot);
+
// The following code resets the rs field of each unvisited mutable
// object (computing sumOfNewCostExtra and updating costArray[] when
// debugging retainer profiler).
for (g = 0; g < RtsFlags.GcFlags.generations; g++) {
- ASSERT(g != 0 ||
- (generations[g].mut_list == END_MUT_LIST &&
- generations[g].mut_once_list == END_MUT_LIST));
-
- // Todo:
- // I think traversing through mut_list is unnecessary.
- // Think about removing this part.
- for (ml = generations[g].mut_list; ml != END_MUT_LIST;
- ml = ml->mut_link) {
-
- maybeInitRetainerSet((StgClosure *)ml);
- rtl = retainerSetOf((StgClosure *)ml);
+ ASSERT(g != 0 || (generations[g].mut_list == NULL));
-#ifdef DEBUG_RETAINER
- if (rtl == NULL) {
- // first visit to *ml
- // This is a violation of the interface rule!
- RSET(ml) = (RetainerSet *)((StgWord)(&tmpRetainerSet) | flip);
-
- switch (get_itbl((StgClosure *)ml)->type) {
- case IND_STATIC:
- // no cost involved
- break;
- case CONSTR_INTLIKE:
- case CONSTR_CHARLIKE:
- case CONSTR_NOCAF_STATIC:
- case CONSTR_STATIC:
- case THUNK_STATIC:
- case FUN_STATIC:
- barf("Invalid object in computeRetainerSet(): %d", get_itbl((StgClosure*)ml)->type);
- break;
- default:
- // dynamic objects
- costArray[get_itbl((StgClosure *)ml)->type] += cost((StgClosure *)ml);
- sumOfNewCostExtra += cost((StgClosure *)ml);
- break;
- }
- }
-#endif
- }
-
- // Traversing through mut_once_list is, in contrast, necessary
+ // Traversing through mut_list is necessary
// because we can find MUT_VAR objects which have not been
// visited during retainer profiling.
- for (ml = generations[g].mut_once_list; ml != END_MUT_LIST;
- ml = ml->mut_link) {
+ for (bd = generations[g].mut_list; bd != NULL; bd = bd->link) {
+ for (ml = bd->start; ml < bd->free; ml++) {
+
+ maybeInitRetainerSet((StgClosure *)ml);
+ rtl = retainerSetOf((StgClosure *)ml);
- maybeInitRetainerSet((StgClosure *)ml);
- rtl = retainerSetOf((StgClosure *)ml);
#ifdef DEBUG_RETAINER
- if (rtl == NULL) {
- // first visit to *ml
- // This is a violation of the interface rule!
- RSET(ml) = (RetainerSet *)((StgWord)(&tmpRetainerSet) | flip);
-
- switch (get_itbl((StgClosure *)ml)->type) {
- case IND_STATIC:
- // no cost involved
- break;
- case CONSTR_INTLIKE:
- case CONSTR_CHARLIKE:
- case CONSTR_NOCAF_STATIC:
- case CONSTR_STATIC:
- case THUNK_STATIC:
- case FUN_STATIC:
- barf("Invalid object in computeRetainerSet(): %d", get_itbl((StgClosure*)ml)->type);
- break;
- default:
- // dynamic objects
- costArray[get_itbl((StgClosure *)ml)->type] += cost((StgClosure *)ml);
- sumOfNewCostExtra += cost((StgClosure *)ml);
- break;
+ if (rtl == NULL) {
+ // first visit to *ml
+ // This is a violation of the interface rule!
+ RSET(ml) = (RetainerSet *)((StgWord)(&tmpRetainerSet) | flip);
+
+ switch (get_itbl((StgClosure *)ml)->type) {
+ case IND_STATIC:
+ // no cost involved
+ break;
+ case CONSTR_INTLIKE:
+ case CONSTR_CHARLIKE:
+ case CONSTR_NOCAF_STATIC:
+ case CONSTR_STATIC:
+ case THUNK_STATIC:
+ case FUN_STATIC:
+ barf("Invalid object in computeRetainerSet(): %d", get_itbl((StgClosure*)ml)->type);
+ break;
+ default:
+ // dynamic objects
+ costArray[get_itbl((StgClosure *)ml)->type] += cost((StgClosure *)ml);
+ sumOfNewCostExtra += cost((StgClosure *)ml);
+ break;
+ }
}
- }
#endif
+ }
}
}
}
}
}
#ifdef DEBUG_RETAINER
- // fprintf(stderr, "count in scavenged_static_objects = %d\n", count);
+ // debugBelch("count in scavenged_static_objects = %d\n", count);
#endif
}
#endif
#ifdef DEBUG_RETAINER
- fprintf(stderr, " < retainerProfile() invoked : %d>\n", retainerGeneration);
+ debugBelch(" < retainerProfile() invoked : %d>\n", retainerGeneration);
#endif
stat_startRP();
// We haven't flipped the bit yet.
#ifdef DEBUG_RETAINER
- fprintf(stderr, "Before traversing:\n");
+ debugBelch("Before traversing:\n");
sumOfCostLinear = 0;
for (i = 0;i < N_CLOSURE_TYPES; i++)
costArrayLinear[i] = 0;
totalHeapSize = checkHeapSanityForRetainerProfiling();
- fprintf(stderr, "\tsumOfCostLinear = %d, totalHeapSize = %d\n", sumOfCostLinear, totalHeapSize);
+ debugBelch("\tsumOfCostLinear = %d, totalHeapSize = %d\n", sumOfCostLinear, totalHeapSize);
/*
- fprintf(stderr, "costArrayLinear[] = ");
+ debugBelch("costArrayLinear[] = ");
for (i = 0;i < N_CLOSURE_TYPES; i++)
- fprintf(stderr, "[%u:%u] ", i, costArrayLinear[i]);
- fprintf(stderr, "\n");
+ debugBelch("[%u:%u] ", i, costArrayLinear[i]);
+ debugBelch("\n");
*/
ASSERT(sumOfCostLinear == totalHeapSize);
/*
#define pcostArrayLinear(index) \
if (costArrayLinear[index] > 0) \
- fprintf(stderr, "costArrayLinear[" #index "] = %u\n", costArrayLinear[index])
+ debugBelch("costArrayLinear[" #index "] = %u\n", costArrayLinear[index])
pcostArrayLinear(THUNK_STATIC);
pcostArrayLinear(FUN_STATIC);
pcostArrayLinear(CONSTR_STATIC);
timesAnyObjectVisited = 0;
#ifdef DEBUG_RETAINER
- fprintf(stderr, "During traversing:\n");
+ debugBelch("During traversing:\n");
sumOfNewCost = 0;
sumOfNewCostExtra = 0;
for (i = 0;i < N_CLOSURE_TYPES; i++)
computeRetainerSet();
#ifdef DEBUG_RETAINER
- fprintf(stderr, "After traversing:\n");
+ debugBelch("After traversing:\n");
sumOfCostLinear = 0;
for (i = 0;i < N_CLOSURE_TYPES; i++)
costArrayLinear[i] = 0;
totalHeapSize = checkHeapSanityForRetainerProfiling();
- fprintf(stderr, "\tsumOfCostLinear = %d, totalHeapSize = %d\n", sumOfCostLinear, totalHeapSize);
+ debugBelch("\tsumOfCostLinear = %d, totalHeapSize = %d\n", sumOfCostLinear, totalHeapSize);
ASSERT(sumOfCostLinear == totalHeapSize);
// now, compare the two results
1) Dead weak pointers, whose type is CONSTR. These objects are not
reachable from any roots.
*/
- fprintf(stderr, "Comparison:\n");
- fprintf(stderr, "\tcostArrayLinear[] (must be empty) = ");
+ debugBelch("Comparison:\n");
+ debugBelch("\tcostArrayLinear[] (must be empty) = ");
for (i = 0;i < N_CLOSURE_TYPES; i++)
if (costArray[i] != costArrayLinear[i])
// nothing should be printed except MUT_VAR after major GCs
- fprintf(stderr, "[%u:%u] ", i, costArrayLinear[i]);
- fprintf(stderr, "\n");
+ debugBelch("[%u:%u] ", i, costArrayLinear[i]);
+ debugBelch("\n");
- fprintf(stderr, "\tsumOfNewCost = %u\n", sumOfNewCost);
- fprintf(stderr, "\tsumOfNewCostExtra = %u\n", sumOfNewCostExtra);
- fprintf(stderr, "\tcostArray[] (must be empty) = ");
+ debugBelch("\tsumOfNewCost = %u\n", sumOfNewCost);
+ debugBelch("\tsumOfNewCostExtra = %u\n", sumOfNewCostExtra);
+ debugBelch("\tcostArray[] (must be empty) = ");
for (i = 0;i < N_CLOSURE_TYPES; i++)
if (costArray[i] != costArrayLinear[i])
// nothing should be printed except MUT_VAR after major GCs
- fprintf(stderr, "[%u:%u] ", i, costArray[i]);
- fprintf(stderr, "\n");
+ debugBelch("[%u:%u] ", i, costArray[i]);
+ debugBelch("\n");
// only for major garbage collection
ASSERT(sumOfNewCost + sumOfNewCostExtra == sumOfCostLinear);
if (get_itbl(c)->type == CONSTR &&
!strcmp(get_itbl(c)->prof.closure_type, "DEAD_WEAK") &&
!strcmp(get_itbl(c)->prof.closure_desc, "DEAD_WEAK")) {
- fprintf(stderr, "\tUnvisited dead weak pointer object found: c = %p\n", c);
+ debugBelch("\tUnvisited dead weak pointer object found: c = %p\n", c);
costArray[get_itbl(c)->type] += cost(c);
sumOfNewCost += cost(c);
} else
- fprintf(stderr,
+ debugBelch(
"Unvisited object: flip = %d, c = %p(%d, %s, %s), rs = %p\n",
flip, c, get_itbl(c)->type,
get_itbl(c)->prof.closure_type, get_itbl(c)->prof.closure_desc,
RSET(c));
} else {
- // fprintf(stderr, "sanityCheckHeapClosure) S: flip = %d, c = %p(%d), rs = %p\n", flip, c, get_itbl(c)->type, RSET(c));
+ // debugBelch("sanityCheckHeapClosure) S: flip = %d, c = %p(%d), rs = %p\n", flip, c, get_itbl(c)->type, RSET(c));
}
info = get_itbl(c);
case MUT_ARR_PTRS_FROZEN:
return mut_arr_ptrs_sizeW((StgMutArrPtrs *)c);
- case AP_UPD:
+ case AP:
case PAP:
return pap_sizeW((StgPAP *)c);
+ case AP:
+ return ap_stack_sizeW((StgAP_STACK *)c);
+
case ARR_WORDS:
return arr_words_sizeW((StgArrWords *)c);
case FUN_0_2:
case WEAK:
case MUT_VAR:
- case MUT_CONS:
case CAF_BLACKHOLE:
case BLACKHOLE:
case SE_BLACKHOLE:
case UPDATE_FRAME:
case CATCH_FRAME:
case STOP_FRAME:
- case SEQ_FRAME:
case RET_DYN:
case RET_BCO:
case RET_SMALL:
nat costSum, g, s;
costSum = 0;
- fprintf(stderr, "START: sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
+ debugBelch("START: sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
if (RtsFlags.GcFlags.generations == 1) {
costSum += heapCheck(g0s0->to_blocks);
- fprintf(stderr, "heapCheck: sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
+ debugBelch("heapCheck: sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
costSum += chainCheck(g0s0->large_objects);
- fprintf(stderr, "chainCheck: sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
+ debugBelch("chainCheck: sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
} else {
for (g = 0; g < RtsFlags.GcFlags.generations; g++)
for (s = 0; s < generations[g].n_steps; s++) {
*/
if (g == 0 && s == 0) {
costSum += smallObjectPoolCheck();
- fprintf(stderr, "smallObjectPoolCheck(): sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
+ debugBelch("smallObjectPoolCheck(): sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
costSum += chainCheck(generations[g].steps[s].large_objects);
- fprintf(stderr, "chainCheck(): sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
+ debugBelch("chainCheck(): sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
} else {
costSum += heapCheck(generations[g].steps[s].blocks);
- fprintf(stderr, "heapCheck(): sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
+ debugBelch("heapCheck(): sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
costSum += chainCheck(generations[g].steps[s].large_objects);
- fprintf(stderr, "chainCheck(): sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
+ debugBelch("chainCheck(): sumOfCostLinear = %d, costSum = %d\n", sumOfCostLinear, costSum);
}
}
}
if (*q == (StgWord)p) {
r = q;
while (!LOOKS_LIKE_GHC_INFO(*r)) r--;
- fprintf(stderr, "Found in gen[%d], step[%d]: q = %p, r = %p\n", g, s, q, r);
+ debugBelch("Found in gen[%d], step[%d]: q = %p, r = %p\n", g, s, q, r);
// return;
}
}
if (*q == (StgWord)p) {
r = q;
while (*r == 0 || !LOOKS_LIKE_GHC_INFO(*r)) r--;
- fprintf(stderr, "Found in gen[%d], large_objects: %p\n", g, r);
+ debugBelch("Found in gen[%d], large_objects: %p\n", g, r);
// return;
}
}
bd = generations[g].steps[s].blocks;
for (; bd; bd = bd->link) {
if (bd->start <= p && p < bd->free) {
- fprintf(stderr, "Belongs to gen[%d], step[%d]", g, s);
+ debugBelch("Belongs to gen[%d], step[%d]", g, s);
return;
}
}
bd = generations[g].steps[s].large_objects;
for (; bd; bd = bd->link) {
if (bd->start <= p && p < bd->start + getHeapClosureSize((StgClosure *)bd->start)) {
- fprintf(stderr, "Found in gen[%d], large_objects: %p\n", g, bd->start);
+ debugBelch("Found in gen[%d], large_objects: %p\n", g, bd->start);
return;
}
}