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/* -----------------------------------------------------------------------------
*
* (c) The GHC Team, 1998-1999
*
* Block structure for the storage manager
*
* ---------------------------------------------------------------------------*/
#pragma once
#include "ghcconfig.h"
/* The actual block and megablock-size constants are defined in
* includes/Constants.h, all constants here are derived from these.
*/
/* Block related constants (BLOCK_SHIFT is defined in Constants.h) */
#if SIZEOF_LONG == SIZEOF_VOID_P
#define UNIT 1UL
#elif SIZEOF_LONG_LONG == SIZEOF_VOID_P
#define UNIT 1ULL
#else
#error "Size of pointer is suspicious."
#endif
#if defined(CMINUSMINUS)
#define BLOCK_SIZE (1<<BLOCK_SHIFT)
#else
#define BLOCK_SIZE (UNIT<<BLOCK_SHIFT)
// Note [integer overflow]
#endif
#define BLOCK_SIZE_W (BLOCK_SIZE/sizeof(W_))
#define BLOCK_MASK (BLOCK_SIZE-1)
#define BLOCK_ROUND_UP(p) (((W_)(p)+BLOCK_SIZE-1) & ~BLOCK_MASK)
#define BLOCK_ROUND_DOWN(p) ((void *) ((W_)(p) & ~BLOCK_MASK))
/* Megablock related constants (MBLOCK_SHIFT is defined in Constants.h) */
#if defined(CMINUSMINUS)
#define MBLOCK_SIZE (1<<MBLOCK_SHIFT)
#else
#define MBLOCK_SIZE (UNIT<<MBLOCK_SHIFT)
// Note [integer overflow]
#endif
#define MBLOCK_SIZE_W (MBLOCK_SIZE/sizeof(W_))
#define MBLOCK_MASK (MBLOCK_SIZE-1)
#define MBLOCK_ROUND_UP(p) ((void *)(((W_)(p)+MBLOCK_SIZE-1) & ~MBLOCK_MASK))
#define MBLOCK_ROUND_DOWN(p) ((void *)((W_)(p) & ~MBLOCK_MASK ))
/* The largest size an object can be before we give it a block of its
* own and treat it as an immovable object during GC, expressed as a
* fraction of BLOCK_SIZE.
*/
#define LARGE_OBJECT_THRESHOLD ((uint32_t)(BLOCK_SIZE * 8 / 10))
/*
* Note [integer overflow]
*
* The UL suffix in BLOCK_SIZE and MBLOCK_SIZE promotes the expression
* to an unsigned long, which means that expressions involving these
* will be promoted to unsigned long, which makes integer overflow
* less likely. Historically, integer overflow in expressions like
* (n * BLOCK_SIZE)
* where n is int or unsigned int, have caused obscure segfaults in
* programs that use large amounts of memory (e.g. #7762, #5086).
*/
/* -----------------------------------------------------------------------------
* Block descriptor. This structure *must* be the right length, so we
* can do pointer arithmetic on pointers to it.
*/
/* The block descriptor is 64 bytes on a 64-bit machine, and 32-bytes
* on a 32-bit machine.
*/
// Note: fields marked with [READ ONLY] must not be modified by the
// client of the block allocator API. All other fields can be
// freely modified.
#if !defined(CMINUSMINUS)
struct NonmovingSegmentInfo {
StgWord8 log_block_size;
StgWord16 next_free_snap;
};
typedef struct bdescr_ {
StgPtr start; // [READ ONLY] start addr of memory
union {
StgPtr free; // First free byte of memory.
// allocGroup() sets this to the value of start.
// NB. during use this value should lie
// between start and start + blocks *
// BLOCK_SIZE. Values outside this
// range are reserved for use by the
// block allocator. In particular, the
// value (StgPtr)(-1) is used to
// indicate that a block is unallocated.
//
// Unused by the non-moving allocator.
struct NonmovingSegmentInfo nonmoving_segment;
};
struct bdescr_ *link; // used for chaining blocks together
union {
struct bdescr_ *back; // used (occasionally) for doubly-linked lists
StgWord *bitmap; // bitmap for marking GC
StgPtr scan; // scan pointer for copying GC
} u;
struct generation_ *gen; // generation
StgWord16 gen_no; // gen->no, cached
StgWord16 dest_no; // number of destination generation
StgWord16 node; // which memory node does this block live on?
StgWord16 flags; // block flags, see below
StgWord32 blocks; // [READ ONLY] no. of blocks in a group
// (if group head, 0 otherwise)
#if SIZEOF_VOID_P == 8
StgWord32 _padding[3];
#else
StgWord32 _padding[0];
#endif
} bdescr;
#endif
#if SIZEOF_VOID_P == 8
#define BDESCR_SIZE 0x40
#define BDESCR_MASK 0x3f
#define BDESCR_SHIFT 6
#else
#define BDESCR_SIZE 0x20
#define BDESCR_MASK 0x1f
#define BDESCR_SHIFT 5
#endif
/* Block contains objects evacuated during this GC */
#define BF_EVACUATED 1
/* Block is a large object */
#define BF_LARGE 2
/* Block is pinned */
#define BF_PINNED 4
/* Block is to be marked, not copied. Also used for marked large objects in
* non-moving heap. */
#define BF_MARKED 8
/* Block is executable */
#define BF_EXEC 32
/* Block contains only a small amount of live data */
#define BF_FRAGMENTED 64
/* we know about this block (for finding leaks) */
#define BF_KNOWN 128
/* Block was swept in the last generation */
#define BF_SWEPT 256
/* Block is part of a Compact */
#define BF_COMPACT 512
/* A non-moving allocator segment (see NonMoving.c) */
#define BF_NONMOVING 1024
/* A large object which has been moved to off of oldest_gen->large_objects and
* onto nonmoving_large_objects. The mark phase ignores objects which aren't
* so-flagged */
#define BF_NONMOVING_SWEEPING 2048
/* Maximum flag value (do not define anything higher than this!) */
#define BF_FLAG_MAX (1 << 15)
/* Finding the block descriptor for a given block -------------------------- */
#if defined(CMINUSMINUS)
#define Bdescr(p) \
((((p) & MBLOCK_MASK & ~BLOCK_MASK) >> (BLOCK_SHIFT-BDESCR_SHIFT)) \
| ((p) & ~MBLOCK_MASK))
#else
EXTERN_INLINE bdescr *Bdescr(StgPtr p);
EXTERN_INLINE bdescr *Bdescr(StgPtr p)
{
return (bdescr *)
((((W_)p & MBLOCK_MASK & ~BLOCK_MASK) >> (BLOCK_SHIFT-BDESCR_SHIFT))
| ((W_)p & ~MBLOCK_MASK)
);
}
#endif
/* Useful Macros ------------------------------------------------------------ */
/* Offset of first real data block in a megablock */
#define FIRST_BLOCK_OFF \
((W_)BLOCK_ROUND_UP(BDESCR_SIZE * (MBLOCK_SIZE / BLOCK_SIZE)))
/* First data block in a given megablock */
#define FIRST_BLOCK(m) ((void *)(FIRST_BLOCK_OFF + (W_)(m)))
/* Last data block in a given megablock */
#define LAST_BLOCK(m) ((void *)(MBLOCK_SIZE-BLOCK_SIZE + (W_)(m)))
/* First real block descriptor in a megablock */
#define FIRST_BDESCR(m) \
((bdescr *)((FIRST_BLOCK_OFF>>(BLOCK_SHIFT-BDESCR_SHIFT)) + (W_)(m)))
/* Last real block descriptor in a megablock */
#define LAST_BDESCR(m) \
((bdescr *)(((MBLOCK_SIZE-BLOCK_SIZE)>>(BLOCK_SHIFT-BDESCR_SHIFT)) + (W_)(m)))
/* Number of usable blocks in a megablock */
#if !defined(CMINUSMINUS) // already defined in DerivedConstants.h
#define BLOCKS_PER_MBLOCK ((MBLOCK_SIZE - FIRST_BLOCK_OFF) / BLOCK_SIZE)
#endif
/* How many blocks in this megablock group */
#define MBLOCK_GROUP_BLOCKS(n) \
(BLOCKS_PER_MBLOCK + (n-1) * (MBLOCK_SIZE / BLOCK_SIZE))
/* Compute the required size of a megablock group */
#define BLOCKS_TO_MBLOCKS(n) \
(1 + (W_)MBLOCK_ROUND_UP((n-BLOCKS_PER_MBLOCK) * BLOCK_SIZE) / MBLOCK_SIZE)
#if !defined(CMINUSMINUS)
/* to the end... */
/* Double-linked block lists: --------------------------------------------- */
INLINE_HEADER void
dbl_link_onto(bdescr *bd, bdescr **list)
{
bd->link = *list;
bd->u.back = NULL;
if (*list) {
(*list)->u.back = bd; /* double-link the list */
}
*list = bd;
}
INLINE_HEADER void
dbl_link_remove(bdescr *bd, bdescr **list)
{
if (bd->u.back) {
bd->u.back->link = bd->link;
} else {
*list = bd->link;
}
if (bd->link) {
bd->link->u.back = bd->u.back;
}
}
INLINE_HEADER void
dbl_link_insert_after(bdescr *bd, bdescr *after)
{
bd->link = after->link;
bd->u.back = after;
if (after->link) {
after->link->u.back = bd;
}
after->link = bd;
}
INLINE_HEADER void
dbl_link_replace(bdescr *new_, bdescr *old, bdescr **list)
{
new_->link = old->link;
new_->u.back = old->u.back;
if (old->link) {
old->link->u.back = new_;
}
if (old->u.back) {
old->u.back->link = new_;
} else {
*list = new_;
}
}
/* Initialisation ---------------------------------------------------------- */
extern void initBlockAllocator(void);
/* Allocation -------------------------------------------------------------- */
bdescr *allocGroup(W_ n);
EXTERN_INLINE bdescr* allocBlock(void);
EXTERN_INLINE bdescr* allocBlock(void)
{
return allocGroup(1);
}
bdescr *allocGroupOnNode(uint32_t node, W_ n);
// Allocate n blocks, aligned at n-block boundary. The returned bdescr will
// have this invariant
//
// bdescr->start % BLOCK_SIZE*n == 0
//
bdescr *allocAlignedGroupOnNode(uint32_t node, W_ n);
EXTERN_INLINE bdescr* allocBlockOnNode(uint32_t node);
EXTERN_INLINE bdescr* allocBlockOnNode(uint32_t node)
{
return allocGroupOnNode(node,1);
}
// versions that take the storage manager lock for you:
bdescr *allocGroup_lock(W_ n);
bdescr *allocBlock_lock(void);
bdescr *allocGroupOnNode_lock(uint32_t node, W_ n);
bdescr *allocBlockOnNode_lock(uint32_t node);
/* De-Allocation ----------------------------------------------------------- */
void freeGroup(bdescr *p);
void freeChain(bdescr *p);
// versions that take the storage manager lock for you:
void freeGroup_lock(bdescr *p);
void freeChain_lock(bdescr *p);
bdescr * splitBlockGroup (bdescr *bd, uint32_t blocks);
/* Round a value to megablocks --------------------------------------------- */
// We want to allocate an object around a given size, round it up or
// down to the nearest size that will fit in an mblock group.
INLINE_HEADER StgWord
round_to_mblocks(StgWord words)
{
if (words > BLOCKS_PER_MBLOCK * BLOCK_SIZE_W) {
// first, ignore the gap at the beginning of the first mblock by
// adding it to the total words. Then we can pretend we're
// dealing in a uniform unit of megablocks.
words += FIRST_BLOCK_OFF/sizeof(W_);
if ((words % MBLOCK_SIZE_W) < (MBLOCK_SIZE_W / 2)) {
words = (words / MBLOCK_SIZE_W) * MBLOCK_SIZE_W;
} else {
words = ((words / MBLOCK_SIZE_W) + 1) * MBLOCK_SIZE_W;
}
words -= FIRST_BLOCK_OFF/sizeof(W_);
}
return words;
}
#endif /* !CMINUSMINUS */
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