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/* -----------------------------------------------------------------------------
*
* (c) The GHC Team, 1998-2004
*
* External Storage Manger Interface
*
* ---------------------------------------------------------------------------*/
#pragma once
#include <stddef.h>
#include "rts/OSThreads.h"
/* -----------------------------------------------------------------------------
* Generational GC
*
* We support an arbitrary number of generations. Notes (in no particular
* order):
*
* - Objects "age" in the nursery for one GC cycle before being promoted
* to the next generation. There is no aging in other generations.
*
* - generation 0 is the allocation area. It is given
* a fixed set of blocks during initialisation, and these blocks
* normally stay in G0S0. In parallel execution, each
* Capability has its own nursery.
*
* - during garbage collection, each generation which is an
* evacuation destination (i.e. all generations except G0) is
* allocated a to-space. evacuated objects are allocated into
* the generation's to-space until GC is finished, when the
* original generations's contents may be freed and replaced
* by the to-space.
*
* - the mutable-list is per-generation. G0 doesn't have one
* (since every garbage collection collects at least G0).
*
* - block descriptors contain a pointer to the generation that
* the block belongs to, for convenience.
*
* - static objects are stored in per-generation lists. See GC.c for
* details of how we collect CAFs in the generational scheme.
*
* - large objects are per-generation, and are promoted in the
* same way as small objects.
*
* ------------------------------------------------------------------------- */
// A count of blocks needs to store anything up to the size of memory
// divided by the block size. The safest thing is therefore to use a
// type that can store the full range of memory addresses,
// ie. StgWord. Note that we have had some tricky int overflows in a
// couple of cases caused by using ints rather than longs (e.g. #5086)
typedef StgWord memcount;
typedef struct nursery_ {
bdescr * blocks;
memcount n_blocks;
} nursery;
// Nursery invariants:
//
// - cap->r.rNursery points to the nursery for this capability
//
// - cap->r.rCurrentNursery points to the block in the nursery that we are
// currently allocating into. While in Haskell the current heap pointer is
// in Hp, outside Haskell it is stored in cap->r.rCurrentNursery->free.
//
// - the blocks *after* cap->rCurrentNursery in the chain are empty
// (although their bd->free pointers have not been updated to
// reflect that)
//
// - the blocks *before* cap->rCurrentNursery have been used. Except
// for rCurrentAlloc.
//
// - cap->r.rCurrentAlloc is either NULL, or it points to a block in
// the nursery *before* cap->r.rCurrentNursery.
//
// See also Note [allocation accounting] to understand how total
// memory allocation is tracked.
typedef struct generation_ {
uint32_t no; // generation number
bdescr * blocks; // blocks in this gen
memcount n_blocks; // number of blocks
memcount n_words; // number of used words
bdescr * large_objects; // large objects (doubly linked)
memcount n_large_blocks; // no. of blocks used by large objs
memcount n_large_words; // no. of words used by large objs
memcount n_new_large_words; // words of new large objects
// (for doYouWantToGC())
bdescr * compact_objects; // compact objects chain
// the second block in each compact is
// linked from the closure object, while
// the second compact object in the
// chain is linked from bd->link (like
// large objects)
memcount n_compact_blocks; // no. of blocks used by all compacts
bdescr * compact_blocks_in_import; // compact objects being imported
// (not known to the GC because
// potentially invalid, but we
// need to keep track of them
// to avoid assertions in Sanity)
// this is a list shaped like compact_objects
memcount n_compact_blocks_in_import; // no. of blocks used by compacts
// being imported
// Max blocks to allocate in this generation before collecting it. Collect
// this generation when
//
// n_blocks + n_large_blocks + n_compact_blocks > max_blocks
//
memcount max_blocks;
StgTSO * threads; // threads in this gen
// linked via global_link
StgWeak * weak_ptr_list; // weak pointers in this gen
struct generation_ *to; // destination gen for live objects
// stats information
uint32_t collections;
uint32_t par_collections;
uint32_t failed_promotions; // Currently unused
// ------------------------------------
// Fields below are used during GC only
#if defined(THREADED_RTS)
char pad[128]; // make sure the following is
// on a separate cache line.
SpinLock sync; // lock for large_objects
// and scavenged_large_objects
#endif
int mark; // mark (not copy)? (old gen only)
int compact; // compact (not sweep)? (old gen only)
// During GC, if we are collecting this gen, blocks and n_blocks
// are copied into the following two fields. After GC, these blocks
// are freed.
bdescr * old_blocks; // bdescr of first from-space block
memcount n_old_blocks; // number of blocks in from-space
memcount live_estimate; // for sweeping: estimate of live data
bdescr * scavenged_large_objects; // live large objs after GC (d-link)
memcount n_scavenged_large_blocks; // size (not count) of above
bdescr * live_compact_objects; // live compact objs after GC (d-link)
memcount n_live_compact_blocks; // size (not count) of above
bdescr * bitmap; // bitmap for compacting collection
StgTSO * old_threads;
StgWeak * old_weak_ptr_list;
} generation;
extern generation * generations;
extern generation * g0;
extern generation * oldest_gen;
typedef void(*ListBlocksCb)(void *user, bdescr *);
void listAllBlocks(ListBlocksCb cb, void *user);
/* -----------------------------------------------------------------------------
Generic allocation
StgPtr allocate(Capability *cap, W_ n)
Allocates memory from the nursery in
the current Capability.
StgPtr allocatePinned(Capability *cap, W_ n, W_ alignment, W_ align_off)
Allocates a chunk of contiguous store
n words long, which is at a fixed
address (won't be moved by GC). The
word at the byte offset 'align_off'
will be aligned to 'alignment', which
must be a power of two.
Returns a pointer to the first word.
Always succeeds.
NOTE: the GC can't in general handle
pinned objects, so allocatePinned()
can only be used for ByteArrays at the
moment.
Don't forget to TICK_ALLOC_XXX(...)
after calling allocate or
allocatePinned, for the
benefit of the ticky-ticky profiler.
-------------------------------------------------------------------------- */
StgPtr allocate ( Capability *cap, W_ n );
StgPtr allocateMightFail ( Capability *cap, W_ n );
StgPtr allocatePinned ( Capability *cap, W_ n, W_ alignment, W_ align_off);
/* memory allocator for executable memory */
typedef void* AdjustorWritable;
typedef void* AdjustorExecutable;
AdjustorWritable allocateExec(W_ len, AdjustorExecutable *exec_addr);
void flushExec(W_ len, AdjustorExecutable exec_addr);
#if (defined(arm_HOST_ARCH) || defined(aarch64_HOST_ARCH)) && (defined(ios_HOST_OS) || defined(darwin_HOST_OS))
AdjustorWritable execToWritable(AdjustorExecutable exec);
#endif
void freeExec (AdjustorExecutable p);
// Used by GC checks in external .cmm code:
extern W_ large_alloc_lim;
/* -----------------------------------------------------------------------------
Performing Garbage Collection
-------------------------------------------------------------------------- */
void performGC(void);
void performMajorGC(void);
/* -----------------------------------------------------------------------------
The CAF table - used to let us revert CAFs in GHCi
-------------------------------------------------------------------------- */
StgInd *newCAF (StgRegTable *reg, StgIndStatic *caf);
StgInd *newRetainedCAF (StgRegTable *reg, StgIndStatic *caf);
StgInd *newGCdCAF (StgRegTable *reg, StgIndStatic *caf);
void revertCAFs (void);
// Request that all CAFs are retained indefinitely.
// (preferably use RtsConfig.keep_cafs instead)
void setKeepCAFs (void);
// Let the runtime know that all the CAFs in high mem are not
// to be retained. Useful in conjunction with loadNativeObj
void setHighMemDynamic (void);
/* -----------------------------------------------------------------------------
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, StgMutVar *mv, StgClosure *old);
/* set to disable CAF garbage collection in GHCi. */
/* (needed when dynamic libraries are used). */
extern bool keepCAFs;
#include "rts/Flags.h"
INLINE_HEADER void initBdescr(bdescr *bd, generation *gen, generation *dest)
{
RELAXED_STORE(&bd->gen, gen);
RELAXED_STORE(&bd->gen_no, gen->no);
RELAXED_STORE(&bd->dest_no, dest->no);
#if !IN_STG_CODE
/* See Note [RtsFlags is a pointer in STG code] */
ASSERT(gen->no < RtsFlags.GcFlags.generations);
ASSERT(dest->no < RtsFlags.GcFlags.generations);
#endif
}
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