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|
/* -----------------------------------------------------------------------------
*
* (c) The GHC Team, 1998-2008
*
* Storage manager front end
*
* Documentation on the architecture of the Storage Manager can be
* found in the online commentary:
*
* http://hackage.haskell.org/trac/ghc/wiki/Commentary/Rts/Storage
*
* ---------------------------------------------------------------------------*/
#include "PosixSource.h"
#include "Rts.h"
#include "Storage.h"
#include "GCThread.h"
#include "RtsUtils.h"
#include "Stats.h"
#include "BlockAlloc.h"
#include "Weak.h"
#include "Sanity.h"
#include "Arena.h"
#include "Capability.h"
#include "Schedule.h"
#include "RetainerProfile.h" // for counting memory blocks (memInventory)
#include "OSMem.h"
#include "Trace.h"
#include "GC.h"
#include "Evac.h"
#include <string.h>
#include "ffi.h"
/*
* All these globals require sm_mutex to access in THREADED_RTS mode.
*/
StgClosure *caf_list = NULL;
StgClosure *revertible_caf_list = NULL;
rtsBool keepCAFs;
nat large_alloc_lim; /* GC if n_large_blocks in any nursery
* reaches this. */
bdescr *exec_block;
generation *generations = NULL; /* all the generations */
generation *g0 = NULL; /* generation 0, for convenience */
generation *oldest_gen = NULL; /* oldest generation, for convenience */
nursery *nurseries = NULL; /* array of nurseries, size == n_capabilities */
#ifdef THREADED_RTS
/*
* Storage manager mutex: protects all the above state from
* simultaneous access by two STG threads.
*/
Mutex sm_mutex;
#endif
static void allocNurseries ( void );
static void
initGeneration (generation *gen, int g)
{
gen->no = g;
gen->collections = 0;
gen->par_collections = 0;
gen->failed_promotions = 0;
gen->max_blocks = 0;
gen->blocks = NULL;
gen->n_blocks = 0;
gen->n_words = 0;
gen->live_estimate = 0;
gen->old_blocks = NULL;
gen->n_old_blocks = 0;
gen->large_objects = NULL;
gen->n_large_blocks = 0;
gen->n_new_large_words = 0;
gen->scavenged_large_objects = NULL;
gen->n_scavenged_large_blocks = 0;
gen->mark = 0;
gen->compact = 0;
gen->bitmap = NULL;
#ifdef THREADED_RTS
initSpinLock(&gen->sync);
#endif
gen->threads = END_TSO_QUEUE;
gen->old_threads = END_TSO_QUEUE;
}
void
initStorage( void )
{
nat g, n;
if (generations != NULL) {
// multi-init protection
return;
}
initMBlocks();
/* Sanity check to make sure the LOOKS_LIKE_ macros appear to be
* doing something reasonable.
*/
/* We use the NOT_NULL variant or gcc warns that the test is always true */
ASSERT(LOOKS_LIKE_INFO_PTR_NOT_NULL((StgWord)&stg_BLOCKING_QUEUE_CLEAN_info));
ASSERT(LOOKS_LIKE_CLOSURE_PTR(&stg_dummy_ret_closure));
ASSERT(!HEAP_ALLOCED(&stg_dummy_ret_closure));
if (RtsFlags.GcFlags.maxHeapSize != 0 &&
RtsFlags.GcFlags.heapSizeSuggestion >
RtsFlags.GcFlags.maxHeapSize) {
RtsFlags.GcFlags.maxHeapSize = RtsFlags.GcFlags.heapSizeSuggestion;
}
if (RtsFlags.GcFlags.maxHeapSize != 0 &&
RtsFlags.GcFlags.minAllocAreaSize >
RtsFlags.GcFlags.maxHeapSize) {
errorBelch("maximum heap size (-M) is smaller than minimum alloc area size (-A)");
RtsFlags.GcFlags.minAllocAreaSize = RtsFlags.GcFlags.maxHeapSize;
}
initBlockAllocator();
#if defined(THREADED_RTS)
initMutex(&sm_mutex);
#endif
ACQUIRE_SM_LOCK;
/* allocate generation info array */
generations = (generation *)stgMallocBytes(RtsFlags.GcFlags.generations
* sizeof(struct generation_),
"initStorage: gens");
/* Initialise all generations */
for(g = 0; g < RtsFlags.GcFlags.generations; g++) {
initGeneration(&generations[g], g);
}
/* A couple of convenience pointers */
g0 = &generations[0];
oldest_gen = &generations[RtsFlags.GcFlags.generations-1];
nurseries = stgMallocBytes(n_capabilities * sizeof(struct nursery_),
"initStorage: nurseries");
/* Set up the destination pointers in each younger gen. step */
for (g = 0; g < RtsFlags.GcFlags.generations-1; g++) {
generations[g].to = &generations[g+1];
}
oldest_gen->to = oldest_gen;
/* The oldest generation has one step. */
if (RtsFlags.GcFlags.compact || RtsFlags.GcFlags.sweep) {
if (RtsFlags.GcFlags.generations == 1) {
errorBelch("WARNING: compact/sweep is incompatible with -G1; disabled");
} else {
oldest_gen->mark = 1;
if (RtsFlags.GcFlags.compact)
oldest_gen->compact = 1;
}
}
generations[0].max_blocks = 0;
/* The allocation area. Policy: keep the allocation area
* small to begin with, even if we have a large suggested heap
* size. Reason: we're going to do a major collection first, and we
* don't want it to be a big one. This vague idea is borne out by
* rigorous experimental evidence.
*/
allocNurseries();
weak_ptr_list = NULL;
caf_list = END_OF_STATIC_LIST;
revertible_caf_list = END_OF_STATIC_LIST;
/* initialise the allocate() interface */
large_alloc_lim = RtsFlags.GcFlags.minAllocAreaSize * BLOCK_SIZE_W;
exec_block = NULL;
#ifdef THREADED_RTS
initSpinLock(&gc_alloc_block_sync);
whitehole_spin = 0;
#endif
N = 0;
// allocate a block for each mut list
for (n = 0; n < n_capabilities; n++) {
for (g = 1; g < RtsFlags.GcFlags.generations; g++) {
capabilities[n].mut_lists[g] = allocBlock();
}
}
initGcThreads();
IF_DEBUG(gc, statDescribeGens());
RELEASE_SM_LOCK;
}
void
exitStorage (void)
{
stat_exit(calcAllocated(rtsTrue));
}
void
freeStorage (rtsBool free_heap)
{
stgFree(generations);
if (free_heap) freeAllMBlocks();
#if defined(THREADED_RTS)
closeMutex(&sm_mutex);
#endif
stgFree(nurseries);
freeGcThreads();
}
/* -----------------------------------------------------------------------------
CAF management.
The entry code for every CAF does the following:
- builds a CAF_BLACKHOLE in the heap
- calls newCaf, which atomically updates the CAF with
IND_STATIC pointing to the CAF_BLACKHOLE
- if newCaf returns zero, it re-enters the CAF (see Note [atomic
CAF entry])
- pushes an update frame pointing to the CAF_BLACKHOLE
Why do we build an BLACKHOLE in the heap rather than just updating
the thunk directly? It's so that we only need one kind of update
frame - otherwise we'd need a static version of the update frame
too, and various other parts of the RTS that deal with update
frames would also need special cases for static update frames.
newCaf() does the following:
- it updates the CAF with an IND_STATIC pointing to the
CAF_BLACKHOLE, atomically.
- it puts the CAF on the oldest generation's mutable list.
This is so that we treat the CAF as a root when collecting
younger generations.
------------------
Note [atomic CAF entry]
With THREADED_RTS, newCaf() is required to be atomic (see
#5558). This is because if two threads happened to enter the same
CAF simultaneously, they would create two distinct CAF_BLACKHOLEs,
and so the normal threadPaused() machinery for detecting duplicate
evaluation will not detect this. Hence in lockCAF() below, we
atomically lock the CAF with WHITEHOLE before updating it with
IND_STATIC, and return zero if another thread locked the CAF first.
In the event that we lost the race, CAF entry code will re-enter
the CAF and block on the other thread's CAF_BLACKHOLE.
------------------
Note [GHCi CAFs]
For GHCI, we have additional requirements when dealing with CAFs:
- we must *retain* all dynamically-loaded CAFs ever entered,
just in case we need them again.
- we must be able to *revert* CAFs that have been evaluated, to
their pre-evaluated form.
To do this, we use an additional CAF list. When newCaf() is
called on a dynamically-loaded CAF, we add it to the CAF list
instead of the old-generation mutable list, and save away its
old info pointer (in caf->saved_info) for later reversion.
To revert all the CAFs, we traverse the CAF list and reset the
info pointer to caf->saved_info, then throw away the CAF list.
(see GC.c:revertCAFs()).
-- SDM 29/1/01
-------------------------------------------------------------------------- */
STATIC_INLINE StgWord lockCAF (StgClosure *caf, StgClosure *bh)
{
const StgInfoTable *orig_info;
orig_info = caf->header.info;
#ifdef THREADED_RTS
const StgInfoTable *cur_info;
if (orig_info == &stg_IND_STATIC_info ||
orig_info == &stg_WHITEHOLE_info) {
// already claimed by another thread; re-enter the CAF
return 0;
}
cur_info = (const StgInfoTable *)
cas((StgVolatilePtr)&caf->header.info,
(StgWord)orig_info,
(StgWord)&stg_WHITEHOLE_info);
if (cur_info != orig_info) {
// already claimed by another thread; re-enter the CAF
return 0;
}
// successfully claimed by us; overwrite with IND_STATIC
#endif
// For the benefit of revertCAFs(), save the original info pointer
((StgIndStatic *)caf)->saved_info = orig_info;
((StgIndStatic*)caf)->indirectee = bh;
write_barrier();
SET_INFO(caf,&stg_IND_STATIC_info);
return 1;
}
StgWord
newCAF(StgRegTable *reg, StgClosure *caf, StgClosure *bh)
{
if (lockCAF(caf,bh) == 0) return 0;
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.
ACQUIRE_SM_LOCK; // caf_list is global, locked by sm_mutex
((StgIndStatic *)caf)->static_link = caf_list;
caf_list = caf;
RELEASE_SM_LOCK;
}
else
{
// Put this CAF on the mutable list for the old generation.
((StgIndStatic *)caf)->saved_info = NULL;
if (oldest_gen->no != 0) {
recordMutableCap(caf, regTableToCapability(reg), oldest_gen->no);
}
}
return 1;
}
// External API for setting the keepCAFs flag. see #3900.
void
setKeepCAFs (void)
{
keepCAFs = 1;
}
// An alternate version of newCaf which is used for dynamically loaded
// 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.
StgWord
newDynCAF (StgRegTable *reg STG_UNUSED, StgClosure *caf, StgClosure *bh)
{
if (lockCAF(caf,bh) == 0) return 0;
ACQUIRE_SM_LOCK;
((StgIndStatic *)caf)->static_link = revertible_caf_list;
revertible_caf_list = caf;
RELEASE_SM_LOCK;
return 1;
}
/* -----------------------------------------------------------------------------
Nursery management.
-------------------------------------------------------------------------- */
static bdescr *
allocNursery (bdescr *tail, nat blocks)
{
bdescr *bd = NULL;
nat i, n;
// We allocate the nursery as a single contiguous block and then
// divide it into single blocks manually. This way we guarantee
// that the nursery blocks are adjacent, so that the processor's
// automatic prefetching works across nursery blocks. This is a
// tiny optimisation (~0.5%), but it's free.
while (blocks > 0) {
n = stg_min(blocks, BLOCKS_PER_MBLOCK);
blocks -= n;
bd = allocGroup(n);
for (i = 0; i < n; i++) {
initBdescr(&bd[i], g0, g0);
bd[i].blocks = 1;
bd[i].flags = 0;
if (i > 0) {
bd[i].u.back = &bd[i-1];
} else {
bd[i].u.back = NULL;
}
if (i+1 < n) {
bd[i].link = &bd[i+1];
} else {
bd[i].link = tail;
if (tail != NULL) {
tail->u.back = &bd[i];
}
}
bd[i].free = bd[i].start;
}
tail = &bd[0];
}
return &bd[0];
}
static void
assignNurseriesToCapabilities (void)
{
nat i;
for (i = 0; i < n_capabilities; i++) {
capabilities[i].r.rNursery = &nurseries[i];
capabilities[i].r.rCurrentNursery = nurseries[i].blocks;
capabilities[i].r.rCurrentAlloc = NULL;
}
}
static void
allocNurseries( void )
{
nat i;
for (i = 0; i < n_capabilities; i++) {
nurseries[i].blocks =
allocNursery(NULL, RtsFlags.GcFlags.minAllocAreaSize);
nurseries[i].n_blocks =
RtsFlags.GcFlags.minAllocAreaSize;
}
assignNurseriesToCapabilities();
}
lnat // words allocated
clearNurseries (void)
{
lnat allocated = 0;
nat i;
bdescr *bd;
for (i = 0; i < n_capabilities; i++) {
for (bd = nurseries[i].blocks; bd; bd = bd->link) {
allocated += (lnat)(bd->free - bd->start);
bd->free = bd->start;
ASSERT(bd->gen_no == 0);
ASSERT(bd->gen == g0);
IF_DEBUG(sanity,memset(bd->start, 0xaa, BLOCK_SIZE));
}
}
return allocated;
}
void
resetNurseries (void)
{
assignNurseriesToCapabilities();
}
lnat
countNurseryBlocks (void)
{
nat i;
lnat blocks = 0;
for (i = 0; i < n_capabilities; i++) {
blocks += nurseries[i].n_blocks;
}
return blocks;
}
static void
resizeNursery ( nursery *nursery, nat blocks )
{
bdescr *bd;
nat nursery_blocks;
nursery_blocks = nursery->n_blocks;
if (nursery_blocks == blocks) return;
if (nursery_blocks < blocks) {
debugTrace(DEBUG_gc, "increasing size of nursery to %d blocks",
blocks);
nursery->blocks = allocNursery(nursery->blocks, blocks-nursery_blocks);
}
else {
bdescr *next_bd;
debugTrace(DEBUG_gc, "decreasing size of nursery to %d blocks",
blocks);
bd = nursery->blocks;
while (nursery_blocks > blocks) {
next_bd = bd->link;
next_bd->u.back = NULL;
nursery_blocks -= bd->blocks; // might be a large block
freeGroup(bd);
bd = next_bd;
}
nursery->blocks = bd;
// might have gone just under, by freeing a large block, so make
// up the difference.
if (nursery_blocks < blocks) {
nursery->blocks = allocNursery(nursery->blocks, blocks-nursery_blocks);
}
}
nursery->n_blocks = blocks;
ASSERT(countBlocks(nursery->blocks) == nursery->n_blocks);
}
//
// Resize each of the nurseries to the specified size.
//
void
resizeNurseriesFixed (nat blocks)
{
nat i;
for (i = 0; i < n_capabilities; 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_capabilities);
}
/* -----------------------------------------------------------------------------
move_STACK is called to update the TSO structure after it has been
moved from one place to another.
-------------------------------------------------------------------------- */
void
move_STACK (StgStack *src, StgStack *dest)
{
ptrdiff_t diff;
// relocate the stack pointer...
diff = (StgPtr)dest - (StgPtr)src; // In *words*
dest->sp = (StgPtr)dest->sp + diff;
}
/* -----------------------------------------------------------------------------
allocate()
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
allocate (Capability *cap, lnat n)
{
bdescr *bd;
StgPtr p;
if (n >= LARGE_OBJECT_THRESHOLD/sizeof(W_)) {
lnat req_blocks = (lnat)BLOCK_ROUND_UP(n*sizeof(W_)) / BLOCK_SIZE;
// Attempting to allocate an object larger than maxHeapSize
// should definitely be disallowed. (bug #1791)
if (RtsFlags.GcFlags.maxHeapSize > 0 &&
req_blocks >= RtsFlags.GcFlags.maxHeapSize) {
heapOverflow();
// heapOverflow() doesn't exit (see #2592), but we aren't
// in a position to do a clean shutdown here: we
// either have to allocate the memory or exit now.
// Allocating the memory would be bad, because the user
// has requested that we not exceed maxHeapSize, so we
// just exit.
stg_exit(EXIT_HEAPOVERFLOW);
}
ACQUIRE_SM_LOCK
bd = allocGroup(req_blocks);
dbl_link_onto(bd, &g0->large_objects);
g0->n_large_blocks += bd->blocks; // might be larger than req_blocks
g0->n_new_large_words += n;
RELEASE_SM_LOCK;
initBdescr(bd, g0, g0);
bd->flags = BF_LARGE;
bd->free = bd->start + n;
return bd->start;
}
/* small allocation (<LARGE_OBJECT_THRESHOLD) */
TICK_ALLOC_HEAP_NOCTR(n);
CCS_ALLOC(CCCS,n);
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;
initBdescr(bd, g0, g0);
bd->flags = 0;
// If we had to allocate a new block, then we'll GC
// pretty quickly now, because MAYBE_GC() will
// notice that CurrentNursery->link is NULL.
} 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;
IF_DEBUG(sanity, ASSERT(*((StgWord8*)p) == 0xaa));
return p;
}
/* ---------------------------------------------------------------------------
Allocate a fixed/pinned object.
We allocate small pinned objects into a single block, allocating a
new block when the current one overflows. The block is chained
onto the large_object_list of generation 0.
NOTE: The GC can't in general handle pinned objects. This
interface is only safe to use for ByteArrays, which have no
pointers and don't require scavenging. It works because the
block's descriptor has the BF_LARGE flag set, so the block is
treated as a large object and chained onto various lists, rather
than the individual objects being copied. However, when it comes
to scavenge the block, the GC will only scavenge the first object.
The reason is that the GC can't linearly scan a block of pinned
objects at the moment (doing so would require using the
mostly-copying techniques). But since we're restricting ourselves
to pinned ByteArrays, not scavenging is ok.
This function is called by newPinnedByteArray# which immediately
fills the allocated memory with a MutableByteArray#.
------------------------------------------------------------------------- */
StgPtr
allocatePinned (Capability *cap, lnat n)
{
StgPtr p;
bdescr *bd;
// If the request is for a large object, then allocate()
// will give us a pinned object anyway.
if (n >= LARGE_OBJECT_THRESHOLD/sizeof(W_)) {
p = allocate(cap, n);
Bdescr(p)->flags |= BF_PINNED;
return p;
}
TICK_ALLOC_HEAP_NOCTR(n);
CCS_ALLOC(CCCS,n);
bd = cap->pinned_object_block;
// If we don't have a block of pinned objects yet, or the current
// one isn't large enough to hold the new object, allocate a new one.
if (bd == NULL || (bd->free + n) > (bd->start + BLOCK_SIZE_W)) {
// The pinned_object_block remains attached to the capability
// until it is full, even if a GC occurs. We want this
// behaviour because otherwise the unallocated portion of the
// block would be forever slop, and under certain workloads
// (allocating a few ByteStrings per GC) we accumulate a lot
// of slop.
//
// So, the pinned_object_block is initially marked
// BF_EVACUATED so the GC won't touch it. When it is full,
// we place it on the large_objects list, and at the start of
// the next GC the BF_EVACUATED flag will be cleared, and the
// block will be promoted as usual (if anything in it is
// live).
ACQUIRE_SM_LOCK;
if (bd != NULL) {
dbl_link_onto(bd, &g0->large_objects);
g0->n_large_blocks++;
g0->n_new_large_words += bd->free - bd->start;
}
cap->pinned_object_block = bd = allocBlock();
RELEASE_SM_LOCK;
initBdescr(bd, g0, g0);
bd->flags = BF_PINNED | BF_LARGE | BF_EVACUATED;
bd->free = bd->start;
}
p = bd->free;
bd->free += n;
return p;
}
/* -----------------------------------------------------------------------------
Write Barriers
-------------------------------------------------------------------------- */
/*
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);
if (p->header.info == &stg_MUT_VAR_CLEAN_info) {
p->header.info = &stg_MUT_VAR_DIRTY_info;
recordClosureMutated(cap,p);
}
}
// Setting a TSO's link field with a write barrier.
// It is *not* necessary to call this function when
// * setting the link field to END_TSO_QUEUE
// * putting a TSO on the blackhole_queue
// * setting the link field of the currently running TSO, as it
// will already be dirty.
void
setTSOLink (Capability *cap, StgTSO *tso, StgTSO *target)
{
if (tso->dirty == 0) {
tso->dirty = 1;
recordClosureMutated(cap,(StgClosure*)tso);
}
tso->_link = target;
}
void
setTSOPrev (Capability *cap, StgTSO *tso, StgTSO *target)
{
if (tso->dirty == 0) {
tso->dirty = 1;
recordClosureMutated(cap,(StgClosure*)tso);
}
tso->block_info.prev = target;
}
void
dirty_TSO (Capability *cap, StgTSO *tso)
{
if (tso->dirty == 0) {
tso->dirty = 1;
recordClosureMutated(cap,(StgClosure*)tso);
}
}
void
dirty_STACK (Capability *cap, StgStack *stack)
{
if (stack->dirty == 0) {
stack->dirty = 1;
recordClosureMutated(cap,(StgClosure*)stack);
}
}
/*
This is the write barrier for MVARs. An MVAR_CLEAN objects is not
on the mutable list; a MVAR_DIRTY is. When written to, a
MVAR_CLEAN turns into a MVAR_DIRTY and is put on the mutable list.
The check for MVAR_CLEAN is inlined at the call site for speed,
this really does make a difference on concurrency-heavy benchmarks
such as Chaneneos and cheap-concurrency.
*/
void
dirty_MVAR(StgRegTable *reg, StgClosure *p)
{
recordClosureMutated(regTableToCapability(reg),p);
}
/* -----------------------------------------------------------------------------
* Stats and stuff
* -------------------------------------------------------------------------- */
/* -----------------------------------------------------------------------------
* calcAllocated()
*
* Approximate how much we've allocated: number of blocks in the
* nursery + blocks allocated via allocate() - unused nusery blocks.
* This leaves a little slop at the end of each block.
* -------------------------------------------------------------------------- */
lnat
calcAllocated (rtsBool include_nurseries)
{
nat allocated = 0;
nat i;
// When called from GC.c, we already have the allocation count for
// the nursery from resetNurseries(), so we don't need to walk
// through these block lists again.
if (include_nurseries)
{
for (i = 0; i < n_capabilities; i++) {
allocated += countOccupied(nurseries[i].blocks);
}
}
// add in sizes of new large and pinned objects
allocated += g0->n_new_large_words;
return allocated;
}
lnat countOccupied (bdescr *bd)
{
lnat words;
words = 0;
for (; bd != NULL; bd = bd->link) {
ASSERT(bd->free <= bd->start + bd->blocks * BLOCK_SIZE_W);
words += bd->free - bd->start;
}
return words;
}
lnat genLiveWords (generation *gen)
{
return gen->n_words + countOccupied(gen->large_objects);
}
lnat genLiveBlocks (generation *gen)
{
return gen->n_blocks + gen->n_large_blocks;
}
lnat gcThreadLiveWords (nat i, nat g)
{
lnat words;
words = countOccupied(gc_threads[i]->gens[g].todo_bd);
words += countOccupied(gc_threads[i]->gens[g].part_list);
words += countOccupied(gc_threads[i]->gens[g].scavd_list);
return words;
}
lnat gcThreadLiveBlocks (nat i, nat g)
{
lnat blocks;
blocks = countBlocks(gc_threads[i]->gens[g].todo_bd);
blocks += gc_threads[i]->gens[g].n_part_blocks;
blocks += gc_threads[i]->gens[g].n_scavd_blocks;
return blocks;
}
// Return an accurate count of the live data in the heap, excluding
// generation 0.
lnat calcLiveWords (void)
{
nat g;
lnat live;
live = 0;
for (g = 0; g < RtsFlags.GcFlags.generations; g++) {
live += genLiveWords(&generations[g]);
}
return live;
}
lnat calcLiveBlocks (void)
{
nat g;
lnat live;
live = 0;
for (g = 0; g < RtsFlags.GcFlags.generations; g++) {
live += genLiveBlocks(&generations[g]);
}
return live;
}
/* Approximate the number of blocks that will be needed at the next
* garbage collection.
*
* Assume: all data currently live will remain live. Generationss
* that will be collected next time will therefore need twice as many
* blocks since all the data will be copied.
*/
extern lnat
calcNeeded(void)
{
lnat needed = 0;
nat g;
generation *gen;
for (g = 0; g < RtsFlags.GcFlags.generations; g++) {
gen = &generations[g];
// we need at least this much space
needed += gen->n_blocks + gen->n_large_blocks;
// any additional space needed to collect this gen next time?
if (g == 0 || // always collect gen 0
(gen->n_blocks + gen->n_large_blocks > gen->max_blocks)) {
// we will collect this gen next time
if (gen->mark) {
// bitmap:
needed += gen->n_blocks / BITS_IN(W_);
// mark stack:
needed += gen->n_blocks / 100;
}
if (gen->compact) {
continue; // no additional space needed for compaction
} else {
needed += gen->n_blocks;
}
}
}
return needed;
}
/* ----------------------------------------------------------------------------
Executable memory
Executable memory must be managed separately from non-executable
memory. Most OSs these days require you to jump through hoops to
dynamically allocate executable memory, due to various security
measures.
Here we provide a small memory allocator for executable memory.
Memory is managed with a page granularity; we allocate linearly
in the page, and when the page is emptied (all objects on the page
are free) we free the page again, not forgetting to make it
non-executable.
TODO: The inability to handle objects bigger than BLOCK_SIZE_W means that
the linker cannot use allocateExec for loading object code files
on Windows. Once allocateExec can handle larger objects, the linker
should be modified to use allocateExec instead of VirtualAlloc.
------------------------------------------------------------------------- */
#if defined(linux_HOST_OS)
// On Linux we need to use libffi for allocating executable memory,
// because it knows how to work around the restrictions put in place
// by SELinux.
void *allocateExec (nat bytes, void **exec_ret)
{
void **ret, **exec;
ACQUIRE_SM_LOCK;
ret = ffi_closure_alloc (sizeof(void *) + (size_t)bytes, (void**)&exec);
RELEASE_SM_LOCK;
if (ret == NULL) return ret;
*ret = ret; // save the address of the writable mapping, for freeExec().
*exec_ret = exec + 1;
return (ret + 1);
}
// freeExec gets passed the executable address, not the writable address.
void freeExec (void *addr)
{
void *writable;
writable = *((void**)addr - 1);
ACQUIRE_SM_LOCK;
ffi_closure_free (writable);
RELEASE_SM_LOCK
}
#else
void *allocateExec (nat bytes, void **exec_ret)
{
void *ret;
nat n;
ACQUIRE_SM_LOCK;
// round up to words.
n = (bytes + sizeof(W_) + 1) / sizeof(W_);
if (n+1 > BLOCK_SIZE_W) {
barf("allocateExec: can't handle large objects");
}
if (exec_block == NULL ||
exec_block->free + n + 1 > exec_block->start + BLOCK_SIZE_W) {
bdescr *bd;
lnat pagesize = getPageSize();
bd = allocGroup(stg_max(1, pagesize / BLOCK_SIZE));
debugTrace(DEBUG_gc, "allocate exec block %p", bd->start);
bd->gen_no = 0;
bd->flags = BF_EXEC;
bd->link = exec_block;
if (exec_block != NULL) {
exec_block->u.back = bd;
}
bd->u.back = NULL;
setExecutable(bd->start, bd->blocks * BLOCK_SIZE, rtsTrue);
exec_block = bd;
}
*(exec_block->free) = n; // store the size of this chunk
exec_block->gen_no += n; // gen_no stores the number of words allocated
ret = exec_block->free + 1;
exec_block->free += n + 1;
RELEASE_SM_LOCK
*exec_ret = ret;
return ret;
}
void freeExec (void *addr)
{
StgPtr p = (StgPtr)addr - 1;
bdescr *bd = Bdescr((StgPtr)p);
if ((bd->flags & BF_EXEC) == 0) {
barf("freeExec: not executable");
}
if (*(StgPtr)p == 0) {
barf("freeExec: already free?");
}
ACQUIRE_SM_LOCK;
bd->gen_no -= *(StgPtr)p;
*(StgPtr)p = 0;
if (bd->gen_no == 0) {
// Free the block if it is empty, but not if it is the block at
// the head of the queue.
if (bd != exec_block) {
debugTrace(DEBUG_gc, "free exec block %p", bd->start);
dbl_link_remove(bd, &exec_block);
setExecutable(bd->start, bd->blocks * BLOCK_SIZE, rtsFalse);
freeGroup(bd);
} else {
bd->free = bd->start;
}
}
RELEASE_SM_LOCK
}
#endif /* mingw32_HOST_OS */
#ifdef DEBUG
// handy function for use in gdb, because Bdescr() is inlined.
extern bdescr *_bdescr( StgPtr p );
bdescr *
_bdescr( StgPtr p )
{
return Bdescr(p);
}
#endif
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