/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2000-2016. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* %CopyrightEnd%
*/
#ifndef ERL_BINARY_H__TYPES__
#define ERL_BINARY_H__TYPES__
/*
** Just like the driver binary but with initial flags
** Note that the two structures Binary and ErlDrvBinary HAVE to
** be equal except for extra fields in the beginning of the struct.
** ErlDrvBinary is defined in erl_driver.h.
** When driver_alloc_binary is called, a Binary is allocated, but
** the pointer returned is to the address of the first element that
** also occurs in the ErlDrvBinary struct (driver.*binary takes care if this).
** The driver need never know about additions to the internal Binary of the
** emulator. One should however NEVER be sloppy when mixing ErlDrvBinary
** and Binary, the macros below can convert one type to the other, as they both
** in reality are equal.
*/
#ifdef ARCH_32
/* *DO NOT USE* only for alignment. */
#define ERTS_BINARY_STRUCT_ALIGNMENT Uint32 align__;
#else
#define ERTS_BINARY_STRUCT_ALIGNMENT
#endif
/* Add fields in binary_internals, otherwise the drivers crash */
struct binary_internals {
UWord flags;
erts_refc_t refc;
ERTS_BINARY_STRUCT_ALIGNMENT
};
typedef struct binary {
struct binary_internals intern;
SWord orig_size;
char orig_bytes[1]; /* to be continued */
} Binary;
#define ERTS_SIZEOF_Binary(Sz) \
(offsetof(Binary,orig_bytes) + (Sz))
#if ERTS_REF_NUMBERS != 3
#error "Update ErtsMagicBinary"
#endif
typedef struct magic_binary ErtsMagicBinary;
struct magic_binary {
struct binary_internals intern;
SWord orig_size;
int (*destructor)(Binary *);
Uint32 refn[ERTS_REF_NUMBERS];
ErtsAlcType_t alloc_type;
union {
struct {
ERTS_BINARY_STRUCT_ALIGNMENT
char data[1];
} aligned;
struct {
char data[1];
} unaligned;
} u;
};
#define ERTS_MAGIC_BIN_BYTES_TO_ALIGN \
(offsetof(ErtsMagicBinary,u.aligned.data) - \
offsetof(ErtsMagicBinary,u.unaligned.data))
typedef union {
Binary binary;
ErtsMagicBinary magic_binary;
struct {
struct binary_internals intern;
ErlDrvBinary binary;
} driver;
} ErtsBinary;
/*
* 'Binary' alignment:
* Address of orig_bytes[0] of a Binary should always be 8-byte aligned.
* It is assumed that the flags, refc, and orig_size fields are 4 bytes on
* 32-bits architectures and 8 bytes on 64-bits architectures.
*/
#define ERTS_MAGIC_BIN_REFN(BP) \
((ErtsBinary *) (BP))->magic_binary.refn
#define ERTS_MAGIC_BIN_ATYPE(BP) \
((ErtsBinary *) (BP))->magic_binary.alloc_type
#define ERTS_MAGIC_DATA_OFFSET \
(offsetof(ErtsMagicBinary,u.aligned.data) - offsetof(Binary,orig_bytes))
#define ERTS_MAGIC_BIN_DESTRUCTOR(BP) \
((ErtsBinary *) (BP))->magic_binary.destructor
#define ERTS_MAGIC_BIN_DATA(BP) \
((void *) ((ErtsBinary *) (BP))->magic_binary.u.aligned.data)
#define ERTS_MAGIC_BIN_DATA_SIZE(BP) \
((BP)->orig_size - ERTS_MAGIC_DATA_OFFSET)
#define ERTS_MAGIC_DATA_OFFSET \
(offsetof(ErtsMagicBinary,u.aligned.data) - offsetof(Binary,orig_bytes))
#define ERTS_MAGIC_BIN_ORIG_SIZE(Sz) \
(ERTS_MAGIC_DATA_OFFSET + (Sz))
#define ERTS_MAGIC_BIN_SIZE(Sz) \
(offsetof(ErtsMagicBinary,u.aligned.data) + (Sz))
#define ERTS_MAGIC_BIN_FROM_DATA(DATA) \
((ErtsBinary*)((char*)(DATA) - offsetof(ErtsMagicBinary,u.aligned.data)))
/* On 32-bit arch these macro variants will save memory
by not forcing 8-byte alignment for the magic payload.
*/
#define ERTS_MAGIC_BIN_UNALIGNED_DATA(BP) \
((void *) ((ErtsBinary *) (BP))->magic_binary.u.unaligned.data)
#define ERTS_MAGIC_UNALIGNED_DATA_OFFSET \
(offsetof(ErtsMagicBinary,u.unaligned.data) - offsetof(Binary,orig_bytes))
#define ERTS_MAGIC_BIN_UNALIGNED_DATA_SIZE(BP) \
((BP)->orig_size - ERTS_MAGIC_UNALIGNED_DATA_OFFSET)
#define ERTS_MAGIC_BIN_UNALIGNED_ORIG_SIZE(Sz) \
(ERTS_MAGIC_UNALIGNED_DATA_OFFSET + (Sz))
#define ERTS_MAGIC_BIN_UNALIGNED_SIZE(Sz) \
(offsetof(ErtsMagicBinary,u.unaligned.data) + (Sz))
#define ERTS_MAGIC_BIN_FROM_UNALIGNED_DATA(DATA) \
((ErtsBinary*)((char*)(DATA) - offsetof(ErtsMagicBinary,u.unaligned.data)))
#define Binary2ErlDrvBinary(B) (&((ErtsBinary *) (B))->driver.binary)
#define ErlDrvBinary2Binary(D) ((Binary *) \
(((char *) (D)) \
- offsetof(ErtsBinary, driver.binary)))
/* A "magic" binary flag */
#define BIN_FLAG_MAGIC 1
#define BIN_FLAG_USR1 2 /* Reserved for use by different modules too mark */
#define BIN_FLAG_USR2 4 /* certain binaries as special (used by ets) */
#define BIN_FLAG_DRV 8
#endif /* ERL_BINARY_H__TYPES__ */
#if !defined(ERL_BINARY_H__) && !defined(ERTS_BINARY_TYPES_ONLY__)
#define ERL_BINARY_H__
#include "erl_threads.h"
#include "bif.h"
#include "erl_bif_unique.h"
#include "erl_bits.h"
/*
* Maximum number of bytes to place in a heap binary.
*/
#define ERL_ONHEAP_BIN_LIMIT 64
#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(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**, ErtsAlcType_t, unsigned extra);
/* Used by unicode module */
Eterm erts_bin_bytes_to_list(Eterm previous, Eterm* hp, byte* bytes, Uint size, Uint bitoffs);
/*
* Common implementation for erlang:list_to_binary/1 and binary:list_to_bin/1
*/
BIF_RETTYPE erts_list_to_binary_bif(Process *p, Eterm arg, Export *bif);
BIF_RETTYPE erts_gc_binary_part(Process *p, Eterm *reg, Eterm live, int range_is_tuple);
BIF_RETTYPE erts_binary_part(Process *p, Eterm binary, Eterm epos, Eterm elen);
typedef union {
/*
* These two are almost always of
* the same size, but when fallback
* atomics are used they might
* differ in size.
*/
erts_smp_atomic_t smp_atomic_word;
erts_atomic_t atomic_word;
} ErtsMagicIndirectionWord;
#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) || (((UWord) &((Binary *)(B))->orig_bytes[0]) & ERTS_BIN_ALIGNMENT_MASK) == ((UWord) 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 void erts_free_aligned_binary_bytes_extra(byte* buf, ErtsAlcType_t);
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 void erts_bin_release(Binary *bp);
ERTS_GLB_INLINE Binary *erts_create_magic_binary_x(Uint size,
int (*destructor)(Binary *),
ErtsAlcType_t alloc_type,
int unaligned);
ERTS_GLB_INLINE Binary *erts_create_magic_binary(Uint size,
int (*destructor)(Binary *));
ERTS_GLB_INLINE Binary *erts_create_magic_indirection(int (*destructor)(Binary *));
ERTS_GLB_INLINE erts_smp_atomic_t *erts_smp_binary_to_magic_indirection(Binary *bp);
ERTS_GLB_INLINE erts_atomic_t *erts_binary_to_magic_indirection(Binary *bp);
#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, ERTS_ALC_T_TMP, 0);
}
ERTS_GLB_INLINE void
erts_free_aligned_binary_bytes_extra(byte* buf, ErtsAlcType_t allocator)
{
if (buf) {
erts_free(allocator, (void *) buf);
}
}
ERTS_GLB_INLINE void
erts_free_aligned_binary_bytes(byte* buf)
{
erts_free_aligned_binary_bytes_extra(buf,ERTS_ALC_T_TMP);
}
/* Explicit extra bytes allocated to counter buggy drivers.
** These extra bytes where earlier (< R13B04) added by an alignment-bug
** in this code. Do we dare remove this in some major release (R14?) maybe?
*/
#if defined(DEBUG) || defined(VALGRIND)
# define CHICKEN_PAD 0
#else
# define CHICKEN_PAD (sizeof(void*) - 1)
#endif
/* Caller must initialize 'refc'
*/
ERTS_GLB_INLINE Binary *
erts_bin_drv_alloc_fnf(Uint size)
{
Uint bsize = ERTS_SIZEOF_Binary(size) + CHICKEN_PAD;
Binary *res;
if (bsize < size) /* overflow */
return NULL;
res = erts_alloc_fnf(ERTS_ALC_T_DRV_BINARY, bsize);
ERTS_CHK_BIN_ALIGNMENT(res);
if (res) {
res->orig_size = size;
res->intern.flags = BIN_FLAG_DRV;
erts_refc_init(&res->intern.refc, 1);
}
return res;
}
/* Caller must initialize 'refc'
*/
ERTS_GLB_INLINE Binary *
erts_bin_drv_alloc(Uint size)
{
Uint bsize = ERTS_SIZEOF_Binary(size) + CHICKEN_PAD;
Binary *res;
if (bsize < size) /* overflow */
erts_alloc_enomem(ERTS_ALC_T_DRV_BINARY, size);
res = erts_alloc(ERTS_ALC_T_DRV_BINARY, bsize);
ERTS_CHK_BIN_ALIGNMENT(res);
res->orig_size = size;
res->intern.flags = BIN_FLAG_DRV;
erts_refc_init(&res->intern.refc, 1);
return res;
}
/* Caller must initialize 'refc'
*/
ERTS_GLB_INLINE Binary *
erts_bin_nrml_alloc(Uint size)
{
Uint bsize = ERTS_SIZEOF_Binary(size) + CHICKEN_PAD;
Binary *res;
if (bsize < size) /* overflow */
erts_alloc_enomem(ERTS_ALC_T_BINARY, size);
res = erts_alloc(ERTS_ALC_T_BINARY, bsize);
ERTS_CHK_BIN_ALIGNMENT(res);
res->orig_size = size;
res->intern.flags = 0;
erts_refc_init(&res->intern.refc, 1);
return res;
}
ERTS_GLB_INLINE Binary *
erts_bin_realloc_fnf(Binary *bp, Uint size)
{
Binary *nbp;
Uint bsize = ERTS_SIZEOF_Binary(size) + CHICKEN_PAD;
ErtsAlcType_t type = (bp->intern.flags & BIN_FLAG_DRV) ? ERTS_ALC_T_DRV_BINARY
: ERTS_ALC_T_BINARY;
ASSERT((bp->intern.flags & BIN_FLAG_MAGIC) == 0);
if (bsize < size) /* overflow */
return NULL;
nbp = erts_realloc_fnf(type, (void *) bp, bsize);
ERTS_CHK_BIN_ALIGNMENT(nbp);
if (nbp)
nbp->orig_size = size;
return nbp;
}
ERTS_GLB_INLINE Binary *
erts_bin_realloc(Binary *bp, Uint size)
{
Binary *nbp;
Uint bsize = ERTS_SIZEOF_Binary(size) + CHICKEN_PAD;
ErtsAlcType_t type = (bp->intern.flags & BIN_FLAG_DRV) ? ERTS_ALC_T_DRV_BINARY
: ERTS_ALC_T_BINARY;
ASSERT((bp->intern.flags & BIN_FLAG_MAGIC) == 0);
if (bsize < size) /* overflow */
erts_realloc_enomem(type, bp, size);
nbp = erts_realloc_fnf(type, (void *) bp, bsize);
if (!nbp)
erts_realloc_enomem(type, bp, bsize);
ERTS_CHK_BIN_ALIGNMENT(nbp);
nbp->orig_size = size;
return nbp;
}
ERTS_GLB_INLINE void
erts_bin_free(Binary *bp)
{
if (bp->intern.flags & BIN_FLAG_MAGIC) {
if (!ERTS_MAGIC_BIN_DESTRUCTOR(bp)(bp)) {
/* Destructor took control of the deallocation */
return;
}
erts_magic_ref_remove_bin(ERTS_MAGIC_BIN_REFN(bp));
erts_free(ERTS_MAGIC_BIN_ATYPE(bp), (void *) bp);
}
else if (bp->intern.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 void
erts_bin_release(Binary *bp)
{
if (erts_refc_dectest(&bp->intern.refc, 0) == 0) {
erts_bin_free(bp);
}
}
ERTS_GLB_INLINE Binary *
erts_create_magic_binary_x(Uint size, int (*destructor)(Binary *),
ErtsAlcType_t alloc_type,
int unaligned)
{
Uint bsize = unaligned ? ERTS_MAGIC_BIN_UNALIGNED_SIZE(size)
: ERTS_MAGIC_BIN_SIZE(size);
Binary* bptr = erts_alloc_fnf(alloc_type, bsize);
ASSERT(bsize > size);
if (!bptr)
erts_alloc_n_enomem(ERTS_ALC_T2N(alloc_type), bsize);
ERTS_CHK_BIN_ALIGNMENT(bptr);
bptr->intern.flags = BIN_FLAG_MAGIC;
bptr->orig_size = unaligned ? ERTS_MAGIC_BIN_UNALIGNED_ORIG_SIZE(size)
: ERTS_MAGIC_BIN_ORIG_SIZE(size);
erts_refc_init(&bptr->intern.refc, 0);
ERTS_MAGIC_BIN_DESTRUCTOR(bptr) = destructor;
ERTS_MAGIC_BIN_ATYPE(bptr) = alloc_type;
erts_make_magic_ref_in_array(ERTS_MAGIC_BIN_REFN(bptr));
return bptr;
}
ERTS_GLB_INLINE Binary *
erts_create_magic_binary(Uint size, int (*destructor)(Binary *))
{
return erts_create_magic_binary_x(size, destructor,
ERTS_ALC_T_BINARY, 0);
}
ERTS_GLB_INLINE Binary *
erts_create_magic_indirection(int (*destructor)(Binary *))
{
return erts_create_magic_binary_x(sizeof(ErtsMagicIndirectionWord),
destructor,
ERTS_ALC_T_MINDIRECTION,
1); /* Not 64-bit aligned,
but word aligned */
}
ERTS_GLB_INLINE erts_smp_atomic_t *
erts_smp_binary_to_magic_indirection(Binary *bp)
{
ErtsMagicIndirectionWord *mip;
ASSERT(bp->intern.flags & BIN_FLAG_MAGIC);
ASSERT(ERTS_MAGIC_BIN_ATYPE(bp) == ERTS_ALC_T_MINDIRECTION);
mip = ERTS_MAGIC_BIN_UNALIGNED_DATA(bp);
return &mip->smp_atomic_word;
}
ERTS_GLB_INLINE erts_atomic_t *
erts_binary_to_magic_indirection(Binary *bp)
{
ErtsMagicIndirectionWord *mip;
ASSERT(bp->intern.flags & BIN_FLAG_MAGIC);
ASSERT(ERTS_MAGIC_BIN_ATYPE(bp) == ERTS_ALC_T_MINDIRECTION);
mip = ERTS_MAGIC_BIN_UNALIGNED_DATA(bp);
return &mip->atomic_word;
}
#endif /* #if ERTS_GLB_INLINE_INCL_FUNC_DEF */
#endif /* !ERL_BINARY_H__ */