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#include "ZHandle.h"
#include "Task.h"
#include "Async.h"
#include "TaskMan.h"
Balau::ZStream::ZStream(const IO<Handle> & h, int level, header_t header) : m_h(h) {
m_zin.zalloc = m_zout.zalloc = NULL;
m_zin.zfree = m_zout.zfree = NULL;
m_zin.opaque = m_zout.opaque = NULL;
m_zin.next_in = NULL;
m_zin.avail_in = 0;
int window = 0;
switch (header) {
case ZLIB: window = 15; break;
case GZIP: window = 31; break;
case RAW: window = -15; break;
}
int r;
r = inflateInit2(&m_zin, window);
EAssert(r == Z_OK, "inflateInit2 returned %i", r);
r = deflateInit2(&m_zout, level, Z_DEFLATED, window, 9, Z_DEFAULT_STRATEGY);
EAssert(r == Z_OK, "deflateInit2 returned %i", r);
m_name.set("ZStream(%s)", m_h->getName());
}
void Balau::ZStream::close() throw (GeneralException) {
switch (m_phase) {
case IDLE:
case WRITING_FINISH:
case COMPRESSING_FINISH:
case COMPRESSING_FINISH_IDLE:
if (m_h->canWrite())
finish();
inflateEnd(&m_zin);
deflateEnd(&m_zout);
if (m_buf) {
free(m_buf);
m_buf = NULL;
}
m_closed = true;
m_phase = CLOSING;
case CLOSING:
if (!m_detached)
m_h->close();
m_phase = IDLE;
return;
default:
AAssert(false, "Wrong phase");
}
}
bool Balau::ZStream::isClosed() {
return m_closed;
}
bool Balau::ZStream::isEOF() {
if (m_closed || m_eof)
return true;
return m_h->isEOF();
}
bool Balau::ZStream::canRead() {
return m_h->canRead();
}
bool Balau::ZStream::canWrite() {
return m_h->canWrite();
}
const char * Balau::ZStream::getName() {
return m_name.to_charp();
}
namespace {
class AsyncOpZlib : public Balau::AsyncOperation {
public:
AsyncOpZlib(z_stream * z, bool deflate, int flush) : m_z(z), m_deflate(deflate), m_flush(flush) { }
virtual bool needsMainQueue() { return false; }
virtual bool needsFinishWorker() { return true; }
virtual void run() {
if (m_deflate)
m_r = deflate(m_z, m_flush);
else
m_r = inflate(m_z, Z_SYNC_FLUSH);
}
virtual void done() { m_evt.doSignal(); }
bool gotSignal() { return m_evt.gotSignal(); }
int getR() { return m_r; }
void yield() { Balau::Task::operationYield(&m_evt, Balau::Task::INTERRUPTIBLE); }
private:
z_stream * m_z;
int m_r, m_flush;
bool m_deflate;
Balau::Events::Custom m_evt;
};
};
bool Balau::ZStream::isPendingComplete() {
AsyncOpZlib * async = dynamic_cast<AsyncOpZlib *>(m_op);
switch (m_phase) {
case READING:
case WRITING:
case WRITING_FINISH:
case CLOSING:
return m_h->isPendingComplete();
case COMPRESSING:
case DECOMPRESSING:
case COMPRESSING_FINISH:
IAssert(async, "Shouldn't not have a cbResults here...");
return async->gotSignal();
default:
return true;
}
}
static const int BLOCK_SIZE = 1024;
ssize_t Balau::ZStream::read(void * buf, size_t count) throw (GeneralException) {
if (m_closed || m_eof)
return 0;
AAssert(m_h->canRead(), "Can't call ZStream::read on a non-readable handle.");
const int block_size = BLOCK_SIZE * (m_useAsyncOp ? 16 : 1);
AsyncOpZlib * async = dynamic_cast<AsyncOpZlib *>(m_op);
switch (m_phase) {
case IDLE:
m_total = 0;
m_count = count;
m_zin.next_out = (Bytef *) buf;
m_zin.avail_out = count;
if (!m_buf) {
m_zin.next_in = m_buf = (uint8_t *) malloc(block_size);
m_zin.avail_in = 0;
}
while ((m_count != 0) && !m_h->isClosed() && !m_h->isEOF()) {
if (m_zin.avail_in == 0) {
m_zin.next_in = m_buf;
m_phase = READING;
case READING:
m_status = m_h->read(m_buf, block_size);
if (m_status <= 0)
return m_total;
m_zin.avail_in = m_status;
}
if (m_useAsyncOp) {
m_phase = COMPRESSING;
createAsyncOp(m_op = async = new AsyncOpZlib(&m_zin, false, 0));
async->yield();
case COMPRESSING:
m_status = async->getR();
delete async;
m_op = async = NULL;
} else {
m_status = inflate(&m_zin, Z_SYNC_FLUSH);
m_phase = COMPRESSING_IDLE;
Task::operationYield(NULL, Task::INTERRUPTIBLE);
}
case COMPRESSING_IDLE:
EAssert(m_status == Z_OK || m_status == Z_STREAM_END, "inflate() didn't return Z_OK or Z_STREAM_END but %zi", m_status);
ssize_t didRead = m_count - m_zin.avail_out;
m_total += didRead;
m_count -= didRead;
if (m_status == Z_STREAM_END) {
m_eof = true;
m_phase = IDLE;
return m_total;
}
}
break;
default:
AAssert(false, "Don't call an operation without finishing another.");
}
m_phase = IDLE;
return m_total;
}
ssize_t Balau::ZStream::write(const void * buf, size_t count) throw (GeneralException) {
if (m_closed || m_eof)
return 0;
AAssert(m_h->canWrite(), "Can't call ZStream::write on a non-writable handle.");
const int block_size = BLOCK_SIZE * (m_useAsyncOp ? 16 : 1);
ssize_t w;
AsyncOpZlib * async = dynamic_cast<AsyncOpZlib *>(m_op);
switch (m_phase) {
case IDLE:
m_total = 0;
m_count = count;
m_zout.next_in = (Bytef *) const_cast<void *>(buf);
m_zout.avail_in = count;
if (!m_buf)
m_buf = (uint8_t *) malloc(block_size);
while ((m_count != 0) && !m_h->isClosed()) {
m_zout.next_out = (Bytef *) m_buf;
m_zout.avail_out = block_size;
if (m_useAsyncOp) {
m_phase = DECOMPRESSING;
createAsyncOp(m_op = async = new AsyncOpZlib(&m_zout, true, Z_NO_FLUSH));
async->yield();
case DECOMPRESSING:
m_status = async->getR();
delete async;
m_op = async = NULL;
} else {
m_status = deflate(&m_zout, Z_NO_FLUSH);
m_phase = DECOMPRESSING_IDLE;
Task::operationYield(NULL, Task::INTERRUPTIBLE);
}
case DECOMPRESSING_IDLE:
EAssert(m_status == Z_OK, "deflate() didn't return Z_OK but %zi", m_status);
m_compressed = block_size - m_zout.avail_out;
m_phase = WRITING;
m_wptr = m_buf;
while (m_compressed) {
case WRITING:
w = m_h->write(m_wptr, m_compressed);
if (w <= 0) {
m_phase = IDLE;
return m_total;
}
m_compressed -= w;
m_wptr += w;
}
size_t didWrite = m_count - m_zout.avail_in;
m_total += didWrite;
m_count -= didWrite;
}
break;
default:
AAssert(false, "Don't call an operation without finishing another.");
}
m_phase = IDLE;
return m_total;
}
void Balau::ZStream::doFlush(bool finish) {
AAssert(m_h->canWrite(), "Can't call ZStream::doFlush on a non-writable handle.");
const int block_size = BLOCK_SIZE * (m_useAsyncOp ? 16 : 1);
void * buf = m_useAsyncOp ? malloc(block_size) : alloca(block_size);
AsyncOpZlib * async = dynamic_cast<AsyncOpZlib *>(m_op);
ssize_t w = 0;
switch (m_phase) {
case IDLE:
m_zout.next_in = NULL;
m_zout.avail_in = 0;
do {
m_zout.next_out = (Bytef *) m_buf;
m_zout.avail_out = block_size;
if (m_useAsyncOp) {
m_phase = COMPRESSING_FINISH;
createAsyncOp(m_op = async = new AsyncOpZlib(&m_zout, true, finish ? Z_FINISH : Z_SYNC_FLUSH));
async->yield();
case COMPRESSING_FINISH:
m_status = async->getR();
delete async;
m_op = async = NULL;
} else {
m_status = deflate(&m_zout, finish ? Z_FINISH : Z_SYNC_FLUSH);
m_phase = COMPRESSING_FINISH_IDLE;
Task::operationYield(NULL, Task::INTERRUPTIBLE);
}
case COMPRESSING_FINISH_IDLE:
EAssert((m_status == Z_OK) || ((m_status == Z_STREAM_END) && finish), "deflate() didn't return Z_OK or Z_STREAM_END, but %zi (finish = %s)", m_status, finish ? "true" : "false");
m_compressed = block_size - m_zout.avail_out;
m_phase = WRITING_FINISH;
m_wptr = m_buf;
while (m_compressed) {
case WRITING_FINISH:
w = m_h->write(m_wptr, m_compressed);
if (w <= 0) {
m_phase = IDLE;
return;
}
m_compressed -= w;
m_wptr += w;
}
} while (m_status == Z_OK && finish);
break;
default:
AAssert(false, "Don't call an operation without finishing another.");
}
m_phase = IDLE;
}
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