/*
Copyright (c) 2007-2016 Contributors as noted in the AUTHORS file
This file is part of libzmq, the ZeroMQ core engine in C++.
libzmq is free software; you can redistribute it and/or modify it under
the terms of the GNU Lesser General Public License (LGPL) as published
by the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
As a special exception, the Contributors give you permission to link
this library with independent modules to produce an executable,
regardless of the license terms of these independent modules, and to
copy and distribute the resulting executable under terms of your choice,
provided that you also meet, for each linked independent module, the
terms and conditions of the license of that module. An independent
module is a module which is not derived from or based on this library.
If you modify this library, you must extend this exception to your
version of the library.
libzmq is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
License for more details.
You should have received a copy of the GNU Lesser General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef __ZMQ_DECODER_HPP_INCLUDED__
#define __ZMQ_DECODER_HPP_INCLUDED__
#include <algorithm>
#include <cstddef>
#include <cstring>
#include "decoder_allocators.hpp"
#include "err.hpp"
#include "i_decoder.hpp"
#include "msg.hpp"
#include "stdint.hpp"
namespace zmq
{
// Helper base class for decoders that know the amount of data to read
// in advance at any moment. Knowing the amount in advance is a property
// of the protocol used. 0MQ framing protocol is based size-prefixed
// paradigm, which qualifies it to be parsed by this class.
// On the other hand, XML-based transports (like XMPP or SOAP) don't allow
// for knowing the size of data to read in advance and should use different
// decoding algorithms.
//
// This class implements the state machine that parses the incoming buffer.
// Derived class should implement individual state machine actions.
//
// Buffer management is done by an allocator policy.
template <typename T, typename A = c_single_allocator>
class decoder_base_t : public i_decoder
{
public:
explicit decoder_base_t (A *allocator_) :
next (NULL),
read_pos (NULL),
to_read (0),
allocator(allocator_)
{
buf = allocator->allocate ();
}
// The destructor doesn't have to be virtual. It is made virtual
// just to keep ICC and code checking tools from complaining.
virtual ~decoder_base_t ()
{
allocator->deallocate ();
}
// Returns a buffer to be filled with binary data.
void get_buffer (unsigned char **data_, std::size_t *size_)
{
buf = allocator->allocate ();
// If we are expected to read large message, we'll opt for zero-
// copy, i.e. we'll ask caller to fill the data directly to the
// message. Note that subsequent read(s) are non-blocking, thus
// each single read reads at most SO_RCVBUF bytes at once not
// depending on how large is the chunk returned from here.
// As a consequence, large messages being received won't block
// other engines running in the same I/O thread for excessive
// amounts of time.
if (to_read >= allocator->size ()) {
*data_ = read_pos;
*size_ = to_read;
return;
}
*data_ = buf;
*size_ = allocator->size ();
}
// Processes the data in the buffer previously allocated using
// get_buffer function. size_ argument specifies number of bytes
// actually filled into the buffer. Function returns 1 when the
// whole message was decoded or 0 when more data is required.
// On error, -1 is returned and errno set accordingly.
// Number of bytes processed is returned in bytes_used_.
int decode (const unsigned char *data_, std::size_t size_,
std::size_t &bytes_used_)
{
bytes_used_ = 0;
// In case of zero-copy simply adjust the pointers, no copying
// is required. Also, run the state machine in case all the data
// were processed.
if (data_ == read_pos) {
zmq_assert (size_ <= to_read);
read_pos += size_;
to_read -= size_;
bytes_used_ = size_;
while (!to_read) {
const int rc =
(static_cast <T *> (this)->*next) (data_ + bytes_used_);
if (rc != 0)
return rc;
}
return 0;
}
while (bytes_used_ < size_) {
// Copy the data from buffer to the message.
const size_t to_copy = std::min (to_read, size_ - bytes_used_);
// Only copy when destination address is different from the
// current address in the buffer.
if (read_pos != data_ + bytes_used_) {
memcpy (read_pos, data_ + bytes_used_, to_copy);
}
read_pos += to_copy;
to_read -= to_copy;
bytes_used_ += to_copy;
// Try to get more space in the message to fill in.
// If none is available, return.
while (to_read == 0) {
// pass current address in the buffer
const int rc =
(static_cast <T *> (this)->*next) (data_ + bytes_used_);
if (rc != 0)
return rc;
}
}
return 0;
}
virtual void resize_buffer (std::size_t new_size)
{
allocator->resize (new_size);
}
protected:
// Prototype of state machine action. Action should return false if
// it is unable to push the data to the system.
typedef int (T:: *step_t) (unsigned char const *);
// This function should be called from derived class to read data
// from the buffer and schedule next state machine action.
void next_step (void *read_pos_, std::size_t to_read_, step_t next_)
{
read_pos = static_cast <unsigned char*> (read_pos_);
to_read = to_read_;
next = next_;
}
private:
// Next step. If set to NULL, it means that associated data stream
// is dead. Note that there can be still data in the process in such
// case.
step_t next;
// Where to store the read data.
unsigned char *read_pos;
// How much data to read before taking next step.
std::size_t to_read;
// The duffer for data to decode.
A *allocator;
unsigned char *buf;
decoder_base_t (const decoder_base_t &);
const decoder_base_t &operator = (const decoder_base_t &);
};
}
#endif