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/*
* MessagePack for C zero-copy buffer implementation
*
* Copyright (C) 2008-2009 FURUHASHI Sadayuki
*
* Distributed under the Boost Software License, Version 1.0.
* (See accompanying file LICENSE_1_0.txt or copy at
* http://www.boost.org/LICENSE_1_0.txt)
*/
#include "msgpack/vrefbuffer.h"
#include <stdlib.h>
#include <string.h>
#define MSGPACK_PACKER_MAX_BUFFER_SIZE 9
struct msgpack_vrefbuffer_chunk {
struct msgpack_vrefbuffer_chunk* next;
/* data ... */
};
bool msgpack_vrefbuffer_init(msgpack_vrefbuffer* vbuf,
size_t ref_size, size_t chunk_size)
{
size_t nfirst;
msgpack_iovec* array;
msgpack_vrefbuffer_chunk* chunk;
if (ref_size == 0) {
ref_size = MSGPACK_VREFBUFFER_REF_SIZE;
}
if(chunk_size == 0) {
chunk_size = MSGPACK_VREFBUFFER_CHUNK_SIZE;
}
vbuf->chunk_size = chunk_size;
vbuf->ref_size =
ref_size > MSGPACK_PACKER_MAX_BUFFER_SIZE + 1 ?
ref_size : MSGPACK_PACKER_MAX_BUFFER_SIZE + 1 ;
if((sizeof(msgpack_vrefbuffer_chunk) + chunk_size) < chunk_size) {
return false;
}
nfirst = (sizeof(msgpack_iovec) < 72/2) ?
72 / sizeof(msgpack_iovec) : 8;
array = (msgpack_iovec*)malloc(
sizeof(msgpack_iovec) * nfirst);
if(array == NULL) {
return false;
}
vbuf->tail = array;
vbuf->end = array + nfirst;
vbuf->array = array;
chunk = (msgpack_vrefbuffer_chunk*)malloc(
sizeof(msgpack_vrefbuffer_chunk) + chunk_size);
if(chunk == NULL) {
free(array);
return false;
}
else {
msgpack_vrefbuffer_inner_buffer* const ib = &vbuf->inner_buffer;
ib->free = chunk_size;
ib->ptr = ((char*)chunk) + sizeof(msgpack_vrefbuffer_chunk);
ib->head = chunk;
chunk->next = NULL;
return true;
}
}
void msgpack_vrefbuffer_destroy(msgpack_vrefbuffer* vbuf)
{
msgpack_vrefbuffer_chunk* c = vbuf->inner_buffer.head;
while(true) {
msgpack_vrefbuffer_chunk* n = c->next;
free(c);
if(n != NULL) {
c = n;
} else {
break;
}
}
free(vbuf->array);
}
void msgpack_vrefbuffer_clear(msgpack_vrefbuffer* vbuf)
{
msgpack_vrefbuffer_chunk* c = vbuf->inner_buffer.head->next;
msgpack_vrefbuffer_chunk* n;
while(c != NULL) {
n = c->next;
free(c);
c = n;
}
{
msgpack_vrefbuffer_inner_buffer* const ib = &vbuf->inner_buffer;
msgpack_vrefbuffer_chunk* chunk = ib->head;
chunk->next = NULL;
ib->free = vbuf->chunk_size;
ib->ptr = ((char*)chunk) + sizeof(msgpack_vrefbuffer_chunk);
vbuf->tail = vbuf->array;
}
}
int msgpack_vrefbuffer_append_ref(msgpack_vrefbuffer* vbuf,
const char* buf, size_t len)
{
if(vbuf->tail == vbuf->end) {
const size_t nused = (size_t)(vbuf->tail - vbuf->array);
const size_t nnext = nused * 2;
msgpack_iovec* nvec = (msgpack_iovec*)realloc(
vbuf->array, sizeof(msgpack_iovec)*nnext);
if(nvec == NULL) {
return -1;
}
vbuf->array = nvec;
vbuf->end = nvec + nnext;
vbuf->tail = nvec + nused;
}
vbuf->tail->iov_base = (char*)buf;
vbuf->tail->iov_len = len;
++vbuf->tail;
return 0;
}
int msgpack_vrefbuffer_append_copy(msgpack_vrefbuffer* vbuf,
const char* buf, size_t len)
{
msgpack_vrefbuffer_inner_buffer* const ib = &vbuf->inner_buffer;
char* m;
if(ib->free < len) {
msgpack_vrefbuffer_chunk* chunk;
size_t sz = vbuf->chunk_size;
if(sz < len) {
sz = len;
}
if((sizeof(msgpack_vrefbuffer_chunk) + sz) < sz){
return -1;
}
chunk = (msgpack_vrefbuffer_chunk*)malloc(
sizeof(msgpack_vrefbuffer_chunk) + sz);
if(chunk == NULL) {
return -1;
}
chunk->next = ib->head;
ib->head = chunk;
ib->free = sz;
ib->ptr = ((char*)chunk) + sizeof(msgpack_vrefbuffer_chunk);
}
m = ib->ptr;
memcpy(m, buf, len);
ib->free -= len;
ib->ptr += len;
if(vbuf->tail != vbuf->array && m ==
(const char*)((vbuf->tail-1)->iov_base) + (vbuf->tail-1)->iov_len) {
(vbuf->tail-1)->iov_len += len;
return 0;
} else {
return msgpack_vrefbuffer_append_ref(vbuf, m, len);
}
}
int msgpack_vrefbuffer_migrate(msgpack_vrefbuffer* vbuf, msgpack_vrefbuffer* to)
{
size_t sz = vbuf->chunk_size;
msgpack_vrefbuffer_chunk* empty;
if((sizeof(msgpack_vrefbuffer_chunk) + sz) < sz){
return -1;
}
empty = (msgpack_vrefbuffer_chunk*)malloc(
sizeof(msgpack_vrefbuffer_chunk) + sz);
if(empty == NULL) {
return -1;
}
empty->next = NULL;
{
const size_t nused = (size_t)(vbuf->tail - vbuf->array);
if(to->tail + nused < vbuf->end) {
msgpack_iovec* nvec;
const size_t tosize = (size_t)(to->tail - to->array);
const size_t reqsize = nused + tosize;
size_t nnext = (size_t)(to->end - to->array) * 2;
while(nnext < reqsize) {
size_t tmp_nnext = nnext * 2;
if (tmp_nnext <= nnext) {
nnext = reqsize;
break;
}
nnext = tmp_nnext;
}
nvec = (msgpack_iovec*)realloc(
to->array, sizeof(msgpack_iovec)*nnext);
if(nvec == NULL) {
free(empty);
return -1;
}
to->array = nvec;
to->end = nvec + nnext;
to->tail = nvec + tosize;
}
memcpy(to->tail, vbuf->array, sizeof(msgpack_iovec)*nused);
to->tail += nused;
vbuf->tail = vbuf->array;
{
msgpack_vrefbuffer_inner_buffer* const ib = &vbuf->inner_buffer;
msgpack_vrefbuffer_inner_buffer* const toib = &to->inner_buffer;
msgpack_vrefbuffer_chunk* last = ib->head;
while(last->next != NULL) {
last = last->next;
}
last->next = toib->head;
toib->head = ib->head;
if(toib->free < ib->free) {
toib->free = ib->free;
toib->ptr = ib->ptr;
}
ib->head = empty;
ib->free = sz;
ib->ptr = ((char*)empty) + sizeof(msgpack_vrefbuffer_chunk);
}
}
return 0;
}
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