/*
* MessagePack for Ruby unpacking routine
*
* Copyright (C) 2008-2010 FURUHASHI Sadayuki
*
* 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.
*/
#include "ruby.h"
#include "compat.h"
#include "msgpack/unpack_define.h"
static ID s_sysread;
static ID s_readpartial;
struct unpack_buffer {
size_t used;
size_t free;
char* ptr;
};
typedef struct {
int finished;
VALUE source;
size_t offset;
struct unpack_buffer buffer;
VALUE stream;
VALUE streambuf;
ID stream_append_method;
size_t buffer_free_size;
} unpack_user;
#define msgpack_unpack_struct(name) \
struct template ## name
#define msgpack_unpack_func(ret, name) \
ret template ## name
#define msgpack_unpack_callback(name) \
template_callback ## name
#define msgpack_unpack_object VALUE
#define msgpack_unpack_user unpack_user
struct template_context;
typedef struct template_context msgpack_unpack_t;
static void template_init(msgpack_unpack_t* u);
static VALUE template_data(msgpack_unpack_t* u);
static int template_execute(msgpack_unpack_t* u,
const char* data, size_t len, size_t* off);
static inline VALUE template_callback_root(unpack_user* u)
{ return Qnil; }
static inline int template_callback_uint8(unpack_user* u, uint8_t d, VALUE* o)
{ *o = INT2FIX(d); return 0; }
static inline int template_callback_uint16(unpack_user* u, uint16_t d, VALUE* o)
{ *o = INT2FIX(d); return 0; }
static inline int template_callback_uint32(unpack_user* u, uint32_t d, VALUE* o)
{ *o = UINT2NUM(d); return 0; }
static inline int template_callback_uint64(unpack_user* u, uint64_t d, VALUE* o)
{ *o = rb_ull2inum(d); return 0; }
static inline int template_callback_int8(unpack_user* u, int8_t d, VALUE* o)
{ *o = INT2FIX((long)d); return 0; }
static inline int template_callback_int16(unpack_user* u, int16_t d, VALUE* o)
{ *o = INT2FIX((long)d); return 0; }
static inline int template_callback_int32(unpack_user* u, int32_t d, VALUE* o)
{ *o = INT2NUM((long)d); return 0; }
static inline int template_callback_int64(unpack_user* u, int64_t d, VALUE* o)
{ *o = rb_ll2inum(d); return 0; }
static inline int template_callback_float(unpack_user* u, float d, VALUE* o)
{ *o = rb_float_new(d); return 0; }
static inline int template_callback_double(unpack_user* u, double d, VALUE* o)
{ *o = rb_float_new(d); return 0; }
static inline int template_callback_nil(unpack_user* u, VALUE* o)
{ *o = Qnil; return 0; }
static inline int template_callback_true(unpack_user* u, VALUE* o)
{ *o = Qtrue; return 0; }
static inline int template_callback_false(unpack_user* u, VALUE* o)
{ *o = Qfalse; return 0;}
static inline int template_callback_array(unpack_user* u, unsigned int n, VALUE* o)
{ *o = rb_ary_new2(n); return 0; }
static inline int template_callback_array_item(unpack_user* u, VALUE* c, VALUE o)
{ rb_ary_push(*c, o); return 0; } // FIXME set value directry RARRAY_PTR(obj)[RARRAY_LEN(obj)++]
static inline int template_callback_map(unpack_user* u, unsigned int n, VALUE* o)
{ *o = rb_hash_new(); return 0; }
static inline int template_callback_map_item(unpack_user* u, VALUE* c, VALUE k, VALUE v)
{ rb_hash_aset(*c, k, v); return 0; }
#ifdef RSTRING_EMBED_LEN_MAX
#define COW_MIN_SIZE RSTRING_EMBED_LEN_MAX
#else
#define COW_MIN_SIZE ((sizeof(VALUE)*3)/sizeof(char)-1)
#endif
static inline int template_callback_raw(unpack_user* u, const char* b, const char* p, unsigned int l, VALUE* o)
{
if(u->source == Qnil || l <= COW_MIN_SIZE) {
*o = rb_str_new(p, l);
} else {
*o = rb_str_substr(u->source, p - b, l);
}
#ifdef COMPAT_HAVE_ENCODING
ENCODING_SET(*o, s_enc_utf8);
#endif
return 0;
}
#include "msgpack/unpack_template.h"
#define UNPACKER(from, name) \
msgpack_unpack_t *name = NULL; \
Data_Get_Struct(from, msgpack_unpack_t, name); \
if(name == NULL) { \
rb_raise(rb_eArgError, "NULL found for " # name " when shouldn't be."); \
}
#define CHECK_STRING_TYPE(value) \
value = rb_check_string_type(value); \
if( NIL_P(value) ) { \
rb_raise(rb_eTypeError, "instance of String needed"); \
}
static VALUE template_execute_rescue(VALUE nouse)
{
rb_gc_enable();
COMPAT_RERAISE;
}
static VALUE template_execute_do(VALUE argv)
{
VALUE* args = (VALUE*)argv;
msgpack_unpack_t* mp = (msgpack_unpack_t*)args[0];
char* dptr = (char*)args[1];
size_t dlen = (size_t)args[2];
size_t* from = (size_t*)args[3];
int ret = template_execute(mp, dptr, dlen, from);
return (VALUE)ret;
}
static int template_execute_wrap(msgpack_unpack_t* mp,
VALUE str, size_t dlen, size_t* from)
{
VALUE args[4] = {
(VALUE)mp,
(VALUE)RSTRING_PTR(str),
(VALUE)dlen,
(VALUE)from,
};
// FIXME execute実行中はmp->topが更新されないのでGC markが機能しない
rb_gc_disable();
mp->user.source = str;
int ret = (int)rb_rescue(template_execute_do, (VALUE)args,
template_execute_rescue, Qnil);
rb_gc_enable();
return ret;
}
static int template_execute_wrap_each(msgpack_unpack_t* mp,
const char* ptr, size_t dlen, size_t* from)
{
VALUE args[4] = {
(VALUE)mp,
(VALUE)ptr,
(VALUE)dlen,
(VALUE)from,
};
// FIXME execute実行中はmp->topが更新されないのでGC markが機能しない
rb_gc_disable();
mp->user.source = Qnil;
int ret = (int)rb_rescue(template_execute_do, (VALUE)args,
template_execute_rescue, Qnil);
rb_gc_enable();
return ret;
}
static VALUE cUnpacker;
/**
* Document-module: MessagePack::UnpackerError
*
*/
static VALUE eUnpackError;
#ifndef MSGPACK_UNPACKER_BUFFER_INIT_SIZE
#define MSGPACK_UNPACKER_BUFFER_INIT_SIZE (32*1024)
#endif
#ifndef MSGPACK_UNPACKER_BUFFER_RESERVE_SIZE
#define MSGPACK_UNPACKER_BUFFER_RESERVE_SIZE (8*1024)
#endif
/*
#ifndef MSGPACK_BUFFER_FREE_SIZE
#define MSGPACK_BUFFER_FREE_SIZE (1024*1024)
#endif
*/
#define MSGPACK_BUFFER_FREE_SIZE 0
static void MessagePack_Unpacker_free(void* data)
{
if(data) {
msgpack_unpack_t* mp = (msgpack_unpack_t*)data;
free(mp->user.buffer.ptr);
free(mp);
}
}
static void MessagePack_Unpacker_mark(msgpack_unpack_t *mp)
{
unsigned int i;
rb_gc_mark(mp->user.stream);
rb_gc_mark(mp->user.streambuf);
rb_gc_mark_maybe(template_data(mp));
for(i=0; i < mp->top; ++i) {
rb_gc_mark(mp->stack[i].obj);
rb_gc_mark_maybe(mp->stack[i].map_key);
}
}
static VALUE MessagePack_Unpacker_alloc(VALUE klass)
{
VALUE obj;
msgpack_unpack_t* mp = ALLOC_N(msgpack_unpack_t, 1);
// rb_gc_mark (not _maybe) is used for following member objects.
mp->user.stream = Qnil;
mp->user.streambuf = Qnil;
mp->user.finished = 0;
mp->user.offset = 0;
mp->user.buffer.used = 0;
mp->user.buffer.free = 0;
mp->user.buffer.ptr = NULL;
obj = Data_Wrap_Struct(klass, MessagePack_Unpacker_mark,
MessagePack_Unpacker_free, mp);
return obj;
}
static ID append_method_of(VALUE stream)
{
if(rb_respond_to(stream, s_sysread)) {
return s_sysread;
} else {
return s_readpartial;
}
}
/**
* Document-method: MessagePack::Unpacker#initialize
*
* call-seq:
* MessagePack::Unpacker.new(stream = nil)
*
* Creates instance of MessagePack::Unpacker.
*
* You can specify a _stream_ for input stream.
* It is required to implement *sysread* or *readpartial* method.
*
* With the input stream, buffers will be feeded into the deserializer automatically.
*
* Without the input stream, use *feed* method manually. Or you can manage the buffer manually
* with *execute*, *finished?*, *data* and *reset* methods.
*/
static VALUE MessagePack_Unpacker_initialize(int argc, VALUE *argv, VALUE self)
{
VALUE stream;
switch(argc) {
case 0:
stream = Qnil;
break;
case 1:
stream = argv[0];
break;
default:
rb_raise(rb_eArgError, "wrong number of arguments (%d for 0)", argc);
}
UNPACKER(self, mp);
template_init(mp);
mp->user.stream = stream;
mp->user.streambuf = rb_str_buf_new(MSGPACK_UNPACKER_BUFFER_RESERVE_SIZE);
mp->user.stream_append_method = append_method_of(stream);
mp->user.buffer_free_size = MSGPACK_BUFFER_FREE_SIZE;
return self;
}
/**
* Document-method: MessagePack::Unpacker#stream
*
* call-seq:
* unpacker.stream
*
* Gets the input stream.
*/
static VALUE MessagePack_Unpacker_stream_get(VALUE self)
{
UNPACKER(self, mp);
return mp->user.stream;
}
/**
* Document-method: MessagePack::Unpacker#stream=
*
* call-seq:
* unpacker.stream = stream
*
* Resets the input stream. You can set nil not to use input stream.
*/
static VALUE MessagePack_Unpacker_stream_set(VALUE self, VALUE val)
{
UNPACKER(self, mp);
mp->user.stream = val;
mp->user.stream_append_method = append_method_of(val);
return val;
}
static void reserve_buffer(msgpack_unpack_t* mp, size_t require)
{
struct unpack_buffer* buffer = &mp->user.buffer;
if(buffer->used == 0) {
if(require <= buffer->free) {
/* enough free space */
return;
}
/* no used buffer: realloc only */
size_t nsize = buffer->free == 0 ?
MSGPACK_UNPACKER_BUFFER_INIT_SIZE : buffer->free*2;
while(nsize < require) {
nsize *= 2;
}
char* tmp = REALLOC_N(buffer->ptr, char, nsize);
buffer->free = nsize;
buffer->ptr = tmp;
return;
}
if(buffer->used <= mp->user.offset) {
/* clear buffer and rewind offset */
buffer->free += buffer->used;
buffer->used = 0;
mp->user.offset = 0;
}
if(require <= buffer->free) {
/* enough free space */
return;
}
size_t nsize = (buffer->used + buffer->free) * 2;
if(mp->user.offset <= buffer->used / 2) {
/* parsed less than half: realloc only */
while(nsize < buffer->used + require) {
nsize *= 2;
}
char* tmp = REALLOC_N(buffer->ptr, char, nsize);
buffer->free = nsize - buffer->used;
buffer->ptr = tmp;
} else {
/* parsed more than half: realloc and move */
size_t not_parsed = buffer->used - mp->user.offset;
while(nsize < not_parsed + require) {
nsize *= 2;
}
char* tmp = REALLOC_N(buffer->ptr, char, nsize);
memcpy(tmp, tmp + mp->user.offset, not_parsed);
buffer->free = nsize - not_parsed;
buffer->used = not_parsed;
buffer->ptr = tmp;
mp->user.offset = 0;
}
}
static inline void try_free_buffer(msgpack_unpack_t* mp, size_t require)
{
if(mp->user.buffer_free_size == 0) {
return;
}
struct unpack_buffer* buffer = &mp->user.buffer;
size_t csize = buffer->used + buffer->free;
if(csize <= mp->user.buffer_free_size) {
return;
}
if(mp->user.offset <= buffer->used / 2) {
/* parsed less than half: do nothing */
} else if(mp->user.offset < buffer->used) {
/* parsed more than half but not all: realloc and move */
size_t nsize = MSGPACK_UNPACKER_BUFFER_INIT_SIZE;
size_t not_parsed = buffer->used - mp->user.offset;
while(nsize < not_parsed + require) {
nsize *= 2;
}
if(nsize >= csize) {
return;
}
char* tmp;
if(mp->user.offset == 0) {
tmp = ALLOC_N(char, nsize);
memcpy(tmp, buffer->ptr + mp->user.offset, not_parsed);
free(buffer->ptr);
} else {
tmp = REALLOC_N(buffer->ptr, char, nsize);
}
buffer->free = nsize - not_parsed;
buffer->used = not_parsed;
buffer->ptr = tmp;
mp->user.offset = 0;
} else {
/* all parsed: free all */
free(buffer->ptr);
buffer->free = 0;
buffer->used = 0;
buffer->ptr = NULL;
mp->user.offset = 0;
}
}
static void feed_buffer(msgpack_unpack_t* mp, const char* ptr, size_t len)
{
struct unpack_buffer* buffer = &mp->user.buffer;
reserve_buffer(mp, len);
memcpy(buffer->ptr + buffer->used, ptr, len);
buffer->used += len;
buffer->free -= len;
}
/**
* Document-method: MessagePack::Unpacker#feed
*
* call-seq:
* unpacker.feed(data)
*
* Fills the internal buffer with the specified buffer.
*/
static VALUE MessagePack_Unpacker_feed(VALUE self, VALUE data)
{
UNPACKER(self, mp);
StringValue(data);
feed_buffer(mp, RSTRING_PTR(data), RSTRING_LEN(data));
return Qnil;
}
/**
* Document-method: MessagePack::Unpacker#fill
*
* call-seq:
* unpacker.fill -> length of read data
*
* Fills the internal buffer using the input stream.
*
* If the input stream is not specified, it returns nil.
* You can set it on *initialize* or *stream=* methods.
*
* This methods raises exceptions that _stream.sysread_ or
* _stream.readpartial_ method raises.
*/
static VALUE MessagePack_Unpacker_fill(VALUE self)
{
UNPACKER(self, mp);
if(mp->user.stream == Qnil) {
return Qnil;
}
rb_funcall(mp->user.stream, mp->user.stream_append_method, 2,
LONG2FIX(MSGPACK_UNPACKER_BUFFER_RESERVE_SIZE),
mp->user.streambuf);
size_t len = RSTRING_LEN(mp->user.streambuf);
feed_buffer(mp, RSTRING_PTR(mp->user.streambuf), len);
return LONG2FIX(len);
}
/**
* Document-method: MessagePack::Unpacker#each
*
* call-seq:
* unpacker.each {|object| }
*
* Deserializes objects repeatedly. This calls *fill* method automatically.
*
* UnpackError is throw when parse error is occured.
* This method raises exceptions that *fill* method raises.
*/
static VALUE MessagePack_Unpacker_each(VALUE self)
{
UNPACKER(self, mp);
int ret;
#ifdef RETURN_ENUMERATOR
RETURN_ENUMERATOR(self, 0, 0);
#endif
while(1) {
if(mp->user.buffer.used <= mp->user.offset) {
do_fill:
{
VALUE len = MessagePack_Unpacker_fill(self);
if(len == Qnil || FIX2LONG(len) == 0) {
break;
}
}
}
ret = template_execute_wrap_each(mp,
mp->user.buffer.ptr, mp->user.buffer.used,
&mp->user.offset);
if(ret < 0) {
rb_raise(eUnpackError, "parse error.");
} else if(ret > 0) {
VALUE data = template_data(mp);
template_init(mp);
rb_yield(data);
} else {
goto do_fill;
}
}
try_free_buffer(mp, 0);
return Qnil;
}
static VALUE feed_each_impl(VALUE args)
{
VALUE self = ((VALUE*)args)[0];
VALUE data = ((VALUE*)args)[1];
size_t* pconsumed = (size_t*)((VALUE*)args)[2];
UNPACKER(self, mp);
int ret;
const char* ptr = RSTRING_PTR(data);
size_t len = RSTRING_LEN(data);
if(mp->user.buffer.used > 0) {
while(1) {
ret = template_execute_wrap_each(mp,
mp->user.buffer.ptr, mp->user.buffer.used,
&mp->user.offset);
if(ret < 0) {
rb_raise(eUnpackError, "parse error.");
} else if(ret > 0) {
VALUE data = template_data(mp);
template_init(mp);
rb_yield(data);
} else {
break;
}
}
}
if(len <= 0) {
return Qnil;
}
if(mp->user.buffer.used <= mp->user.offset) {
// wrap & execute & feed
while(1) {
ret = template_execute_wrap_each(mp,
ptr, len, pconsumed);
if(ret < 0) {
rb_raise(eUnpackError, "parse error.");
} else if(ret > 0) {
VALUE data = template_data(mp);
template_init(mp);
rb_yield(data);
} else {
break;
}
}
} else {
// feed & execute
feed_buffer(mp, ptr, len);
*pconsumed = len;
while(1) {
ret = template_execute_wrap_each(mp,
mp->user.buffer.ptr, mp->user.buffer.used,
&mp->user.offset);
if(ret < 0) {
rb_raise(eUnpackError, "parse error.");
} else if(ret > 0) {
VALUE data = template_data(mp);
template_init(mp);
rb_yield(data);
} else {
break;
}
}
}
return Qnil;
}
static VALUE feed_each_ensure(VALUE args) {
VALUE self = ((VALUE*)args)[0];
VALUE data = ((VALUE*)args)[1];
size_t* pconsumed = (size_t*)((VALUE*)args)[2];
const char* dptr = RSTRING_PTR(data) + *pconsumed;
size_t dlen = RSTRING_LEN(data) - *pconsumed;
if(dlen > 0) {
UNPACKER(self, mp);
try_free_buffer(mp, dlen);
feed_buffer(mp, dptr, dlen);
}
return Qnil;
}
/**
* Document-method: MessagePack::Unpacker#feed_each
*
* call-seq:
* unpacker.feed_each(data) {|object| }
*
* Same as feed(data) + each {|object| }, but tries to avoid copying of the buffer.
*/
static VALUE MessagePack_Unpacker_feed_each(VALUE self, VALUE data)
{
size_t consumed = 0;
StringValue(data);
VALUE args[3];
args[0] = self;
args[1] = data;
args[2] = (VALUE)&consumed;
return rb_ensure(feed_each_impl, (VALUE)args,
feed_each_ensure, (VALUE)args);
}
static inline VALUE MessagePack_unpack_impl(VALUE self, VALUE data, unsigned long dlen)
{
msgpack_unpack_t mp;
template_init(&mp);
mp.user.finished = 0;
size_t from = 0;
int ret = template_execute_wrap(&mp, data, dlen, &from);
if(ret < 0) {
rb_raise(eUnpackError, "parse error.");
} else if(ret == 0) {
rb_raise(eUnpackError, "insufficient bytes.");
} else {
if(from < dlen) {
rb_raise(eUnpackError, "extra bytes.");
}
return template_data(&mp);
}
}
/**
* Document-method: MessagePack::Unpacker.unpack_limit
*
* call-seq:
* MessagePack::Unpacker.unpack_limit(data, limit) -> object
*
* Deserializes one object over the specified buffer upto _limit_ bytes.
*
* UnpackError is throw when parse error is occured, the buffer is insufficient
* to deserialize one object or there are extra bytes.
*/
static VALUE MessagePack_unpack_limit(VALUE self, VALUE data, VALUE limit)
{
CHECK_STRING_TYPE(data);
return MessagePack_unpack_impl(self, data, NUM2ULONG(limit));
}
/**
* Document-method: MessagePack::Unpacker.unpack
*
* call-seq:
* MessagePack::Unpacker.unpack(data) -> object
*
* Deserializes one object over the specified buffer.
*
* UnpackError is throw when parse error is occured, the buffer is insufficient
* to deserialize one object or there are extra bytes.
*/
static VALUE MessagePack_unpack(VALUE self, VALUE data)
{
CHECK_STRING_TYPE(data);
return MessagePack_unpack_impl(self, data, RSTRING_LEN(data));
}
static VALUE MessagePack_Unpacker_execute_impl(VALUE self, VALUE data,
size_t from, size_t limit)
{
UNPACKER(self, mp);
if(from >= limit) {
rb_raise(eUnpackError, "offset is bigger than data buffer size.");
}
int ret = template_execute_wrap(mp, data, limit, &from);
if(ret < 0) {
rb_raise(eUnpackError, "parse error.");
} else if(ret > 0) {
mp->user.finished = 1;
return ULONG2NUM(from);
} else {
mp->user.finished = 0;
return ULONG2NUM(from);
}
}
/**
* Document-method: MessagePack::Unpacker#execute_limit
*
* call-seq:
* unpacker.execute_limit(data, offset, limit) -> next offset
*
* Deserializes one object over the specified buffer from _offset_ bytes upto _limit_ bytes.
*
* This method doesn't use the internal buffer.
*
* Call *reset* method before calling this method again.
*
* UnpackError is throw when parse error is occured.
*/
static VALUE MessagePack_Unpacker_execute_limit(VALUE self, VALUE data,
VALUE off, VALUE limit)
{
CHECK_STRING_TYPE(data);
return MessagePack_Unpacker_execute_impl(self, data,
(size_t)NUM2ULONG(off), (size_t)NUM2ULONG(limit));
}
/**
* Document-method: MessagePack::Unpacker#execute
*
* call-seq:
* unpacker.execute(data, offset) -> next offset
*
* Deserializes one object over the specified buffer from _offset_ bytes.
*
* This method doesn't use the internal buffer.
*
* Call *reset* method before calling this method again.
*
* This returns offset that was parsed to.
* Use *finished?* method to check an object is deserialized and call *data*
* method if it returns true.
*
* UnpackError is throw when parse error is occured.
*/
static VALUE MessagePack_Unpacker_execute(VALUE self, VALUE data, VALUE off)
{
CHECK_STRING_TYPE(data);
return MessagePack_Unpacker_execute_impl(self, data,
(size_t)NUM2ULONG(off), (size_t)RSTRING_LEN(data));
}
/**
* Document-method: MessagePack::Unpacker#finished?
*
* call-seq:
* unpacker.finished?
*
* Returns true if an object is ready to get with data method.
*
* Use this method with execute method.
*/
static VALUE MessagePack_Unpacker_finished_p(VALUE self)
{
UNPACKER(self, mp);
if(mp->user.finished) {
return Qtrue;
}
return Qfalse;
}
/**
* Document-method: MessagePack::Unpacker#data
*
* call-seq:
* unpacker.data
*
* Gets the object deserialized by execute method.
*
* Use this method with execute method.
*/
static VALUE MessagePack_Unpacker_data(VALUE self)
{
UNPACKER(self, mp);
return template_data(mp);
}
/**
* Document-method: MessagePack::Unpacker#reset
*
* call-seq:
* unpacker.reset
*
* Resets the internal state of the unpacker.
*/
static VALUE MessagePack_Unpacker_reset(VALUE self)
{
UNPACKER(self, mp);
template_init(mp);
mp->user.finished = 0;
try_free_buffer(mp, 0);
return self;
}
void Init_msgpack_unpack(VALUE mMessagePack)
{
s_sysread = rb_intern("sysread");
s_readpartial = rb_intern("readpartial");
eUnpackError = rb_define_class_under(mMessagePack, "UnpackError", rb_eStandardError);
cUnpacker = rb_define_class_under(mMessagePack, "Unpacker", rb_cObject);
rb_define_alloc_func(cUnpacker, MessagePack_Unpacker_alloc);
rb_define_method(cUnpacker, "initialize", MessagePack_Unpacker_initialize, -1);
/* Buffered API */
rb_define_method(cUnpacker, "feed", MessagePack_Unpacker_feed, 1);
rb_define_method(cUnpacker, "fill", MessagePack_Unpacker_fill, 0);
rb_define_method(cUnpacker, "each", MessagePack_Unpacker_each, 0);
rb_define_method(cUnpacker, "stream", MessagePack_Unpacker_stream_get, 0);
rb_define_method(cUnpacker, "stream=", MessagePack_Unpacker_stream_set, 1);
rb_define_method(cUnpacker, "feed_each", MessagePack_Unpacker_feed_each, 1);
/* Unbuffered API */
rb_define_method(cUnpacker, "execute", MessagePack_Unpacker_execute, 2);
rb_define_method(cUnpacker, "execute_limit", MessagePack_Unpacker_execute_limit, 3);
rb_define_method(cUnpacker, "finished?", MessagePack_Unpacker_finished_p, 0);
rb_define_method(cUnpacker, "data", MessagePack_Unpacker_data, 0);
rb_define_method(cUnpacker, "reset", MessagePack_Unpacker_reset, 0);
/**
* MessagePack module is defined in rbinit.c file.
* mMessagePack = rb_define_module("MessagePack");
*/
rb_define_module_function(mMessagePack, "unpack", MessagePack_unpack, 1);
rb_define_module_function(mMessagePack, "unpack_limit", MessagePack_unpack_limit, 2);
}
/**
* Document-module: MessagePack::Unpacker
*
* Deserializer class that includes Buffered API and Unbuffered API.
*
*
* Buffered API uses the internal buffer of the Unpacker.
* Following code uses Buffered API with an input stream:
*
* # create an unpacker with input stream.
* pac = MessagePack::Unpacker.new(STDIN)
*
* # deserialize object one after another.
* pac.each {|obj|
* # ...
* }
*
*
* Following code doesn't use the input stream and feeds buffer
* manually. This is useful to use special stream or with
* event-driven I/O library.
*
* # create an unpacker without input stream.
* pac = MessagePack::Unpacker.new()
*
* # feed buffer to the internal buffer.
* pac.feed(input_bytes)
*
* # deserialize object one after another.
* pac.each {|obj|
* # ...
* }
*
*
* You can manage the buffer manually with the combination of
* *execute*, *finished?*, *data* and *reset* method.
*
* # create an unpacker.
* pac = MessagePack::Unpacker.new()
*
* # manage buffer and offset manually.
* offset = 0
* buffer = ''
*
* # read some data into the buffer.
* buffer << [1,2,3].to_msgpack
* buffer << [4,5,6].to_msgpack
*
* while true
* offset = pac.execute(buffer, offset)
*
* if pac.finished?
* obj = pac.data
*
* buffer.slice!(0, offset)
* offset = 0
* pac.reset
*
* # do something with the object
* # ...
*
* # repeat execution if there are more data.
* next unless buffer.empty?
* end
*
* break
* end
*/