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// Copyright Joyent, Inc. and other Node contributors.
//
// Permission is hereby granted, free of charge, to any person obtaining a
// copy of this software and associated documentation files (the
// "Software"), to deal in the Software without restriction, including
// without limitation the rights to use, copy, modify, merge, publish,
// distribute, sublicense, and/or sell copies of the Software, and to permit
// persons to whom the Software is furnished to do so, subject to the
// following conditions:
//
// The above copyright notice and this permission notice shall be included
// in all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
// OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN
// NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
// DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
// OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE
// USE OR OTHER DEALINGS IN THE SOFTWARE.
#include "v8.h"
#include <errno.h>
#include <string.h>
#include <stdlib.h>
#include <sys/types.h>
#include "zlib.h"
#include "node.h"
#include "node_buffer.h"
namespace node {
using namespace v8;
static Persistent<String> callback_sym;
static Persistent<String> onerror_sym;
enum node_zlib_mode {
DEFLATE = 1,
INFLATE,
GZIP,
GUNZIP,
DEFLATERAW,
INFLATERAW,
UNZIP
};
void InitZlib(v8::Handle<v8::Object> target);
/**
* Deflate/Inflate
*/
class ZCtx : public ObjectWrap {
public:
ZCtx(node_zlib_mode mode) : ObjectWrap(), dictionary_(NULL), mode_(mode) {}
~ZCtx() {
if (mode_ == DEFLATE || mode_ == GZIP || mode_ == DEFLATERAW) {
(void)deflateEnd(&strm_);
} else if (mode_ == INFLATE || mode_ == GUNZIP || mode_ == INFLATERAW ||
mode_ == UNZIP) {
(void)inflateEnd(&strm_);
}
if (dictionary_ != NULL) delete[] dictionary_;
}
// write(flush, in, in_off, in_len, out, out_off, out_len)
static Handle<Value> Write(const Arguments& args) {
HandleScope scope;
assert(args.Length() == 7);
ZCtx *ctx = ObjectWrap::Unwrap<ZCtx>(args.This());
assert(ctx->init_done_ && "write before init");
assert(!ctx->write_in_progress_ && "write already in progress");
ctx->write_in_progress_ = true;
unsigned int flush = args[0]->Uint32Value();
Bytef *in;
Bytef *out;
size_t in_off, in_len, out_off, out_len;
if (args[1]->IsNull()) {
// just a flush
Bytef nada[1] = { 0 };
in = nada;
in_len = 0;
in_off = 0;
} else {
assert(Buffer::HasInstance(args[1]));
Local<Object> in_buf;
in_buf = args[1]->ToObject();
in_off = args[2]->Uint32Value();
in_len = args[3]->Uint32Value();
assert(in_off + in_len <= Buffer::Length(in_buf));
in = reinterpret_cast<Bytef *>(Buffer::Data(in_buf) + in_off);
}
assert(Buffer::HasInstance(args[4]));
Local<Object> out_buf = args[4]->ToObject();
out_off = args[5]->Uint32Value();
out_len = args[6]->Uint32Value();
assert(out_off + out_len <= Buffer::Length(out_buf));
out = reinterpret_cast<Bytef *>(Buffer::Data(out_buf) + out_off);
// build up the work request
uv_work_t* work_req = &(ctx->work_req_);
ctx->strm_.avail_in = in_len;
ctx->strm_.next_in = in;
ctx->strm_.avail_out = out_len;
ctx->strm_.next_out = out;
ctx->flush_ = flush;
// set this so that later on, I can easily tell how much was written.
ctx->chunk_size_ = out_len;
uv_queue_work(uv_default_loop(),
work_req,
ZCtx::Process,
ZCtx::After);
ctx->Ref();
return ctx->handle_;
}
// thread pool!
// This function may be called multiple times on the uv_work pool
// for a single write() call, until all of the input bytes have
// been consumed.
static void Process(uv_work_t* work_req) {
ZCtx *ctx = container_of(work_req, ZCtx, work_req_);
// If the avail_out is left at 0, then it means that it ran out
// of room. If there was avail_out left over, then it means
// that all of the input was consumed.
switch (ctx->mode_) {
case DEFLATE:
case GZIP:
case DEFLATERAW:
ctx->err_ = deflate(&ctx->strm_, ctx->flush_);
break;
case UNZIP:
case INFLATE:
case GUNZIP:
case INFLATERAW:
ctx->err_ = inflate(&ctx->strm_, ctx->flush_);
// If data was encoded with dictionary
if (ctx->err_ == Z_NEED_DICT) {
assert(ctx->dictionary_ != NULL && "Stream has no dictionary");
if (ctx->dictionary_ != NULL) {
// Load it
ctx->err_ = inflateSetDictionary(&ctx->strm_,
ctx->dictionary_,
ctx->dictionary_len_);
assert(ctx->err_ == Z_OK && "Failed to set dictionary");
if (ctx->err_ == Z_OK) {
// And try to decode again
ctx->err_ = inflate(&ctx->strm_, ctx->flush_);
}
}
}
break;
default:
assert(0 && "wtf?");
}
// pass any errors back to the main thread to deal with.
// now After will emit the output, and
// either schedule another call to Process,
// or shift the queue and call Process.
}
// v8 land!
static void After(uv_work_t* work_req) {
HandleScope scope;
ZCtx *ctx = container_of(work_req, ZCtx, work_req_);
// Acceptable error states depend on the type of zlib stream.
switch (ctx->err_) {
case Z_OK:
case Z_STREAM_END:
case Z_BUF_ERROR:
// normal statuses, not fatal
break;
default:
// something else.
ZCtx::Error(ctx, "Zlib error");
return;
}
Local<Integer> avail_out = Integer::New(ctx->strm_.avail_out);
Local<Integer> avail_in = Integer::New(ctx->strm_.avail_in);
ctx->write_in_progress_ = false;
// call the write() cb
assert(ctx->handle_->Get(callback_sym)->IsFunction() &&
"Invalid callback");
Local<Value> args[2] = { avail_in, avail_out };
MakeCallback(ctx->handle_, callback_sym, ARRAY_SIZE(args), args);
ctx->Unref();
}
static void Error(ZCtx *ctx, const char *msg_) {
const char *msg;
if (ctx->strm_.msg != NULL) {
msg = ctx->strm_.msg;
} else {
msg = msg_;
}
assert(ctx->handle_->Get(onerror_sym)->IsFunction() &&
"Invalid error handler");
HandleScope scope;
Local<Value> args[2] = { String::New(msg),
Local<Value>::New(Number::New(ctx->err_)) };
MakeCallback(ctx->handle_, onerror_sym, ARRAY_SIZE(args), args);
// no hope of rescue.
ctx->Unref();
}
static Handle<Value> New(const Arguments& args) {
HandleScope scope;
if (args.Length() < 1 || !args[0]->IsInt32()) {
return ThrowException(Exception::TypeError(String::New("Bad argument")));
}
node_zlib_mode mode = (node_zlib_mode) args[0]->Int32Value();
if (mode < DEFLATE || mode > UNZIP) {
return ThrowException(Exception::TypeError(String::New("Bad argument")));
}
ZCtx *ctx = new ZCtx(mode);
ctx->Wrap(args.This());
return args.This();
}
// just pull the ints out of the args and call the other Init
static Handle<Value> Init(const Arguments& args) {
HandleScope scope;
assert((args.Length() == 4 || args.Length() == 5) &&
"init(windowBits, level, memLevel, strategy, [dictionary])");
ZCtx *ctx = ObjectWrap::Unwrap<ZCtx>(args.This());
int windowBits = args[0]->Uint32Value();
assert((windowBits >= 8 && windowBits <= 15) && "invalid windowBits");
int level = args[1]->Uint32Value();
assert((level >= -1 && level <= 9) && "invalid compression level");
int memLevel = args[2]->Uint32Value();
assert((memLevel >= 1 && memLevel <= 9) && "invalid memlevel");
int strategy = args[3]->Uint32Value();
assert((strategy == Z_FILTERED ||
strategy == Z_HUFFMAN_ONLY ||
strategy == Z_RLE ||
strategy == Z_FIXED ||
strategy == Z_DEFAULT_STRATEGY) && "invalid strategy");
char* dictionary = NULL;
size_t dictionary_len = 0;
if (args.Length() >= 5 && Buffer::HasInstance(args[4])) {
Local<Object> dictionary_ = args[4]->ToObject();
dictionary_len = Buffer::Length(dictionary_);
dictionary = new char[dictionary_len];
memcpy(dictionary, Buffer::Data(dictionary_), dictionary_len);
}
Init(ctx, level, windowBits, memLevel, strategy,
dictionary, dictionary_len);
SetDictionary(ctx);
return Undefined();
}
static Handle<Value> Reset(const Arguments &args) {
HandleScope scope;
ZCtx *ctx = ObjectWrap::Unwrap<ZCtx>(args.This());
Reset(ctx);
SetDictionary(ctx);
return Undefined();
}
static void Init(ZCtx *ctx, int level, int windowBits, int memLevel,
int strategy, char* dictionary, size_t dictionary_len) {
ctx->level_ = level;
ctx->windowBits_ = windowBits;
ctx->memLevel_ = memLevel;
ctx->strategy_ = strategy;
ctx->strm_.zalloc = Z_NULL;
ctx->strm_.zfree = Z_NULL;
ctx->strm_.opaque = Z_NULL;
ctx->flush_ = Z_NO_FLUSH;
ctx->err_ = Z_OK;
if (ctx->mode_ == GZIP || ctx->mode_ == GUNZIP) {
ctx->windowBits_ += 16;
}
if (ctx->mode_ == UNZIP) {
ctx->windowBits_ += 32;
}
if (ctx->mode_ == DEFLATERAW || ctx->mode_ == INFLATERAW) {
ctx->windowBits_ *= -1;
}
switch (ctx->mode_) {
case DEFLATE:
case GZIP:
case DEFLATERAW:
ctx->err_ = deflateInit2(&ctx->strm_,
ctx->level_,
Z_DEFLATED,
ctx->windowBits_,
ctx->memLevel_,
ctx->strategy_);
break;
case INFLATE:
case GUNZIP:
case INFLATERAW:
case UNZIP:
ctx->err_ = inflateInit2(&ctx->strm_, ctx->windowBits_);
break;
default:
assert(0 && "wtf?");
}
if (ctx->err_ != Z_OK) {
ZCtx::Error(ctx, "Init error");
}
ctx->dictionary_ = reinterpret_cast<Bytef *>(dictionary);
ctx->dictionary_len_ = dictionary_len;
ctx->write_in_progress_ = false;
ctx->init_done_ = true;
}
static void SetDictionary(ZCtx* ctx) {
if (ctx->dictionary_ == NULL) return;
ctx->err_ = Z_OK;
switch (ctx->mode_) {
case DEFLATE:
case DEFLATERAW:
ctx->err_ = deflateSetDictionary(&ctx->strm_,
ctx->dictionary_,
ctx->dictionary_len_);
break;
default:
break;
}
if (ctx->err_ != Z_OK) {
ZCtx::Error(ctx, "Failed to set dictionary");
}
}
static void Reset(ZCtx* ctx) {
ctx->err_ = Z_OK;
switch (ctx->mode_) {
case DEFLATE:
case DEFLATERAW:
ctx->err_ = deflateReset(&ctx->strm_);
break;
case INFLATE:
case INFLATERAW:
ctx->err_ = inflateReset(&ctx->strm_);
break;
default:
break;
}
if (ctx->err_ != Z_OK) {
ZCtx::Error(ctx, "Failed to reset stream");
}
}
private:
bool init_done_;
z_stream strm_;
int level_;
int windowBits_;
int memLevel_;
int strategy_;
int err_;
Bytef* dictionary_;
size_t dictionary_len_;
int flush_;
int chunk_size_;
bool write_in_progress_;
uv_work_t work_req_;
node_zlib_mode mode_;
};
void InitZlib(Handle<Object> target) {
HandleScope scope;
Local<FunctionTemplate> z = FunctionTemplate::New(ZCtx::New);
z->InstanceTemplate()->SetInternalFieldCount(1);
NODE_SET_PROTOTYPE_METHOD(z, "write", ZCtx::Write);
NODE_SET_PROTOTYPE_METHOD(z, "init", ZCtx::Init);
NODE_SET_PROTOTYPE_METHOD(z, "reset", ZCtx::Reset);
z->SetClassName(String::NewSymbol("Zlib"));
target->Set(String::NewSymbol("Zlib"), z->GetFunction());
callback_sym = NODE_PSYMBOL("callback");
onerror_sym = NODE_PSYMBOL("onerror");
NODE_DEFINE_CONSTANT(target, Z_NO_FLUSH);
NODE_DEFINE_CONSTANT(target, Z_PARTIAL_FLUSH);
NODE_DEFINE_CONSTANT(target, Z_SYNC_FLUSH);
NODE_DEFINE_CONSTANT(target, Z_FULL_FLUSH);
NODE_DEFINE_CONSTANT(target, Z_FINISH);
NODE_DEFINE_CONSTANT(target, Z_BLOCK);
// return/error codes
NODE_DEFINE_CONSTANT(target, Z_OK);
NODE_DEFINE_CONSTANT(target, Z_STREAM_END);
NODE_DEFINE_CONSTANT(target, Z_NEED_DICT);
NODE_DEFINE_CONSTANT(target, Z_ERRNO);
NODE_DEFINE_CONSTANT(target, Z_STREAM_ERROR);
NODE_DEFINE_CONSTANT(target, Z_DATA_ERROR);
NODE_DEFINE_CONSTANT(target, Z_MEM_ERROR);
NODE_DEFINE_CONSTANT(target, Z_BUF_ERROR);
NODE_DEFINE_CONSTANT(target, Z_VERSION_ERROR);
NODE_DEFINE_CONSTANT(target, Z_NO_COMPRESSION);
NODE_DEFINE_CONSTANT(target, Z_BEST_SPEED);
NODE_DEFINE_CONSTANT(target, Z_BEST_COMPRESSION);
NODE_DEFINE_CONSTANT(target, Z_DEFAULT_COMPRESSION);
NODE_DEFINE_CONSTANT(target, Z_FILTERED);
NODE_DEFINE_CONSTANT(target, Z_HUFFMAN_ONLY);
NODE_DEFINE_CONSTANT(target, Z_RLE);
NODE_DEFINE_CONSTANT(target, Z_FIXED);
NODE_DEFINE_CONSTANT(target, Z_DEFAULT_STRATEGY);
NODE_DEFINE_CONSTANT(target, ZLIB_VERNUM);
NODE_DEFINE_CONSTANT(target, DEFLATE);
NODE_DEFINE_CONSTANT(target, INFLATE);
NODE_DEFINE_CONSTANT(target, GZIP);
NODE_DEFINE_CONSTANT(target, GUNZIP);
NODE_DEFINE_CONSTANT(target, DEFLATERAW);
NODE_DEFINE_CONSTANT(target, INFLATERAW);
NODE_DEFINE_CONSTANT(target, UNZIP);
target->Set(String::NewSymbol("ZLIB_VERSION"), String::New(ZLIB_VERSION));
}
} // namespace node
NODE_MODULE(node_zlib, node::InitZlib)
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