/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2000-2010. All Rights Reserved.
*
* The contents of this file are subject to the Erlang Public License,
* Version 1.1, (the "License"); you may not use this file except in
* compliance with the License. You should have received a copy of the
* Erlang Public License along with this software. If not, it can be
* retrieved online at http://www.erlang.org/.
*
* Software distributed under the License is distributed on an "AS IS"
* basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
* the License for the specific language governing rights and limitations
* under the License.
*
* %CopyrightEnd%
*/
#ifndef __ERL_BINARY_H
#define __ERL_BINARY_H
#include "erl_threads.h"
/*
* Maximum number of bytes to place in a heap binary.
*/
#define ERL_ONHEAP_BIN_LIMIT 64
/*
* This structure represents a SUB_BINARY.
*
* Note: The last field (orig) is not counted in arityval in the header.
* This simplifies garbage collection.
*/
typedef struct erl_sub_bin {
Eterm thing_word; /* Subtag SUB_BINARY_SUBTAG. */
Uint size; /* Binary size in bytes. */
Uint offs; /* Offset into original binary. */
byte bitsize;
byte bitoffs;
byte is_writable; /* The underlying binary is writable */
Eterm orig; /* Original binary (REFC or HEAP binary). */
} ErlSubBin;
#define ERL_SUB_BIN_SIZE (sizeof(ErlSubBin)/sizeof(Eterm))
#define HEADER_SUB_BIN _make_header(ERL_SUB_BIN_SIZE-2,_TAG_HEADER_SUB_BIN)
/*
* This structure represents a HEAP_BINARY.
*/
typedef struct erl_heap_bin {
Eterm thing_word; /* Subtag HEAP_BINARY_SUBTAG. */
Uint size; /* Binary size in bytes. */
Eterm data[1]; /* The data in the binary. */
} ErlHeapBin;
#define heap_bin_size(num_bytes) \
(sizeof(ErlHeapBin)/sizeof(Eterm) - 1 + \
((num_bytes)+sizeof(Eterm)-1)/sizeof(Eterm))
#define header_heap_bin(num_bytes) \
_make_header(heap_bin_size(num_bytes)-1,_TAG_HEADER_HEAP_BIN)
/*
* Get the size in bytes of any type of binary.
*/
#define binary_size(Bin) (binary_val(Bin)[1])
#define binary_bitsize(Bin) \
((*binary_val(Bin) == HEADER_SUB_BIN) ? \
((ErlSubBin *) binary_val(Bin))->bitsize: \
0)
#define binary_bitoffset(Bin) \
((*binary_val(Bin) == HEADER_SUB_BIN) ? \
((ErlSubBin *) binary_val(Bin))->bitoffs: \
0)
/*
* Get the pointer to the actual data bytes in a binary.
* Works for any type of binary. Always use binary_bytes() if
* you know that the binary cannot be a sub binary.
*
* Bin: input variable (Eterm)
* Bytep: output variable (byte *)
* Bitoffs: output variable (Uint)
* Bitsize: output variable (Uint)
*/
#define ERTS_GET_BINARY_BYTES(Bin,Bytep,Bitoffs,Bitsize) \
do { \
Eterm* _real_bin = binary_val(Bin); \
Uint _offs = 0; \
Bitoffs = Bitsize = 0; \
if (*_real_bin == HEADER_SUB_BIN) { \
ErlSubBin* _sb = (ErlSubBin *) _real_bin; \
_offs = _sb->offs; \
Bitoffs = _sb->bitoffs; \
Bitsize = _sb->bitsize; \
_real_bin = binary_val(_sb->orig); \
} \
if (*_real_bin == HEADER_PROC_BIN) { \
Bytep = ((ProcBin *) _real_bin)->bytes + _offs; \
} else { \
Bytep = (byte *)(&(((ErlHeapBin *) _real_bin)->data)) + _offs; \
} \
} while (0)
/*
* Get the real binary from any binary type, where "real" means
* a REFC or HEAP binary. Also get the byte and bit offset into the
* real binary. Useful if you want to build a SUB binary from
* any binary.
*
* Bin: Input variable (Eterm)
* RealBin: Output variable (Eterm)
* ByteOffset: Output variable (Uint)
* BitOffset: Offset in bits (Uint)
* BitSize: Extra bit size (Uint)
*/
#define ERTS_GET_REAL_BIN(Bin, RealBin, ByteOffset, BitOffset, BitSize) \
do { \
ErlSubBin* _sb = (ErlSubBin *) binary_val(Bin); \
if (_sb->thing_word == HEADER_SUB_BIN) { \
RealBin = _sb->orig; \
ByteOffset = _sb->offs; \
BitOffset = _sb->bitoffs; \
BitSize = _sb->bitsize; \
} else { \
RealBin = Bin; \
ByteOffset = BitOffset = BitSize = 0; \
} \
} while (0)
/*
* Get a pointer to the binary bytes, for a heap or refc binary
* (NOT sub binary).
*/
#define binary_bytes(Bin) \
(*binary_val(Bin) == HEADER_PROC_BIN ? \
((ProcBin *) binary_val(Bin))->bytes : \
(ASSERT_EXPR(thing_subtag(*binary_val(Bin)) == HEAP_BINARY_SUBTAG), \
(byte *)(&(((ErlHeapBin *) binary_val(Bin))->data))))
void erts_init_binary(void);
byte* erts_get_aligned_binary_bytes_extra(Eterm, byte**, unsigned extra);
#if defined(__i386__) || !defined(__GNUC__)
/*
* Doubles aren't required to be 8-byte aligned on intel x86.
* (if not gnuc we don't know if __i386__ is defined on x86;
* therefore, assume intel x86...)
*/
# define ERTS_BIN_ALIGNMENT_MASK ((Uint) 3)
#else
# define ERTS_BIN_ALIGNMENT_MASK ((Uint) 7)
#endif
#define ERTS_CHK_BIN_ALIGNMENT(B) \
do { ASSERT(!(B) || (((Uint) &((Binary *)(B))->orig_bytes[0]) & ERTS_BIN_ALIGNMENT_MASK) == ((Uint) 0)) } while(0)
ERTS_GLB_INLINE byte* erts_get_aligned_binary_bytes(Eterm bin, byte** base_ptr);
ERTS_GLB_INLINE void erts_free_aligned_binary_bytes(byte* buf);
ERTS_GLB_INLINE Binary *erts_bin_drv_alloc_fnf(Uint size);
ERTS_GLB_INLINE Binary *erts_bin_drv_alloc(Uint size);
ERTS_GLB_INLINE Binary *erts_bin_nrml_alloc(Uint size);
ERTS_GLB_INLINE Binary *erts_bin_realloc_fnf(Binary *bp, Uint size);
ERTS_GLB_INLINE Binary *erts_bin_realloc(Binary *bp, Uint size);
ERTS_GLB_INLINE void erts_bin_free(Binary *bp);
ERTS_GLB_INLINE Binary *erts_create_magic_binary(Uint size,
void (*destructor)(Binary *));
#if ERTS_GLB_INLINE_INCL_FUNC_DEF
#include <stddef.h> /* offsetof */
ERTS_GLB_INLINE byte*
erts_get_aligned_binary_bytes(Eterm bin, byte** base_ptr)
{
return erts_get_aligned_binary_bytes_extra(bin, base_ptr, 0);
}
ERTS_GLB_INLINE void
erts_free_aligned_binary_bytes(byte* buf)
{
if (buf) {
erts_free(ERTS_ALC_T_TMP, (void *) buf);
}
}
ERTS_GLB_INLINE Binary *
erts_bin_drv_alloc_fnf(Uint size)
{
Uint bsize = ERTS_SIZEOF_Binary(size);
void *res;
res = erts_alloc_fnf(ERTS_ALC_T_DRV_BINARY, bsize);
ERTS_CHK_BIN_ALIGNMENT(res);
return (Binary *) res;
}
ERTS_GLB_INLINE Binary *
erts_bin_drv_alloc(Uint size)
{
Uint bsize = ERTS_SIZEOF_Binary(size);
void *res;
res = erts_alloc(ERTS_ALC_T_DRV_BINARY, bsize);
ERTS_CHK_BIN_ALIGNMENT(res);
return (Binary *) res;
}
ERTS_GLB_INLINE Binary *
erts_bin_nrml_alloc(Uint size)
{
Uint bsize = ERTS_SIZEOF_Binary(size);
void *res;
res = erts_alloc(ERTS_ALC_T_BINARY, bsize);
ERTS_CHK_BIN_ALIGNMENT(res);
return (Binary *) res;
}
ERTS_GLB_INLINE Binary *
erts_bin_realloc_fnf(Binary *bp, Uint size)
{
Binary *nbp;
Uint bsize = ERTS_SIZEOF_Binary(size);
ASSERT((bp->flags & BIN_FLAG_MAGIC) == 0);
if (bp->flags & BIN_FLAG_DRV)
nbp = erts_realloc_fnf(ERTS_ALC_T_DRV_BINARY, (void *) bp, bsize);
else
nbp = erts_realloc_fnf(ERTS_ALC_T_BINARY, (void *) bp, bsize);
ERTS_CHK_BIN_ALIGNMENT(nbp);
return nbp;
}
ERTS_GLB_INLINE Binary *
erts_bin_realloc(Binary *bp, Uint size)
{
Binary *nbp;
Uint bsize = ERTS_SIZEOF_Binary(size);
ASSERT((bp->flags & BIN_FLAG_MAGIC) == 0);
if (bp->flags & BIN_FLAG_DRV)
nbp = erts_realloc_fnf(ERTS_ALC_T_DRV_BINARY, (void *) bp, bsize);
else
nbp = erts_realloc_fnf(ERTS_ALC_T_BINARY, (void *) bp, bsize);
if (!nbp)
erts_realloc_n_enomem(ERTS_ALC_T2N(bp->flags & BIN_FLAG_DRV
? ERTS_ALC_T_DRV_BINARY
: ERTS_ALC_T_BINARY),
bp,
bsize);
ERTS_CHK_BIN_ALIGNMENT(nbp);
return nbp;
}
ERTS_GLB_INLINE void
erts_bin_free(Binary *bp)
{
if (bp->flags & BIN_FLAG_MAGIC)
ERTS_MAGIC_BIN_DESTRUCTOR(bp)(bp);
if (bp->flags & BIN_FLAG_DRV)
erts_free(ERTS_ALC_T_DRV_BINARY, (void *) bp);
else
erts_free(ERTS_ALC_T_BINARY, (void *) bp);
}
ERTS_GLB_INLINE Binary *
erts_create_magic_binary(Uint size, void (*destructor)(Binary *))
{
Uint bsize = ERTS_MAGIC_BIN_SIZE(size);
Binary* bptr = erts_alloc_fnf(ERTS_ALC_T_BINARY, bsize);
if (!bptr)
erts_alloc_n_enomem(ERTS_ALC_T2N(ERTS_ALC_T_BINARY), bsize);
ERTS_CHK_BIN_ALIGNMENT(bptr);
bptr->flags = BIN_FLAG_MAGIC;
bptr->orig_size = ERTS_MAGIC_BIN_ORIG_SIZE(size);
erts_refc_init(&bptr->refc, 0);
ERTS_MAGIC_BIN_DESTRUCTOR(bptr) = destructor;
return bptr;
}
#endif /* #if ERTS_GLB_INLINE_INCL_FUNC_DEF */
#endif