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/*
* Copyright (c) 2015-2016, Luca Fulchir<luca@fulchir.it>, All rights reserved.
*
* This file is part of "libRaptorQ".
*
* libRaptorQ is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as
* published by the Free Software Foundation, either version 3
* of the License, or (at your option) any later version.
*
* libRaptorQ 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* and a copy of the GNU Lesser General Public License
* along with libRaptorQ. If not, see <http://www.gnu.org/licenses/>.
*/
#pragma once
#include "RaptorQ/v1/common.hpp"
#include "RaptorQ/v1/block_sizes.hpp"
#ifdef RQ_HEADER_ONLY
#include "RaptorQ/v1/RaptorQ_Iterators.hpp"
#endif
#include "RaptorQ/v1/Encoder.hpp"
#include "RaptorQ/v1/Decoder.hpp"
template <typename Rnd_It, typename Fwd_It = Rnd_It>
class RAPTORQ_LOCAL Encoder;
template <typename In_It, typename Fwd_It = In_It>
class RAPTORQ_LOCAL Decoder;
} // namespace Impl
// expose classes, but only if header-only
#ifdef RQ_HEADER_ONLY
// does this export symbols??
template <typename Rnd_It, typename Fwd_It>
using Encoder = RAPTORQ_API Impl::Encoder<Rnd_It, Fwd_It>;
template <typename Rnd_It, typename Fwd_It>
using Decoder = RAPTORQ_API Impl::Decoder<Rnd_It, Fwd_It>;
#endif
template <typename Rnd_It, typename Fwd_It>
class RAPTORQ_LOCAL Encoder
{
public:
Encoder (const Block_Size symbols, const size_t symbol_size);
uint16_t symbols() const;
size_t symbol_size() const; //FIXME: max smbol size is same as signed size_t
uint32_t max_repair() const;
RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It> begin_source();
RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It> end_source();
RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It> begin_repair();
RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It> end_repair
size_t set_data (const Rnd_It &from, const Rnd_It &to);
void clear_data();
std::future<Error> precompute();
size_t encode (Fwd_It &output, const Fwd_It end, const uint32_t id);
enum class Enc_State : uint8_t {
INIT_ERROR = 1,
NEED_DATA = 2,
FULL = 3
};
Raw_Encoder<Rnd_It, Fwd_It, without_interleaver> encoder;
DenseMtx precomputed;
std::thread waiting;
enum class RAPTORQ_LOCAL Dec_Report : uint8_t {
PARTIAL_FROM_BEGINNING = RQ_COMPUTE_PARTIAL_FROM_BEGINNING,
PARTIAL_ANY = RQ_COMPUTE_PARTIAL_ANY,
COMPLETE = RQ_COMPUTE_COMPLETE
};
template <typename In_It, typename Fwd_It>
class RAPTORQ_LOCAL Decoder
{
public:
Decoder (const Block_Size symbols, const size_t symbol_size,
RaptorQ__v1::It::Decoder::Symbol_Iterator<In_It, Fwd_It> begin();
RaptorQ__v1::It::Decoder::Symbol_Iterator<In_It, Fwd_It> end();
Error add_symbol (In_It &from, const In_It to, const uint32_t esi);
bool can_decode() const;
void stop();
uint16_t needed_symbols() const;
std::pair<Error, uint16_t> poll();
std::pair<Error, uint16_t> wait_sync();
std::future<std::pair<Error, uint16_t>> wait();
Error decode_symbol (Fwd_It &start, const Fwd_It end,const uint16_t esi);
// return number of bytes written
std::pair<size_t, size_t> decode_bytes (Fwd_It &start, const Fwd_It end,
const size_t from_byte, const size_t skip);
std::atomic<uint32_t> last_reported;
const Report _type;
RaptorQ__v1::Work_State work;
Raw_Decoder<In_It> dec;
// 2* symbols. Actually tracks available and reported symbols.
// each symbol gets 2 bool: 1= available, 2=reported
std::deque<std::atomic<bool>> symbols_tracker;
std::mutex _mtx;
std::condition_variable _cond;
std::vector<std::thread> waiting;
static void waiting_thread (Decoder<In_It, Fwd_It> *obj,
std::promise<std::pair<Error, uint16_t>> p);
};
///////////////////
//// Encoder
///////////////////
template <typename Rnd_It, typename Fwd_It>
Encoder<Rnd_It, Fwd_It>::~Encoder()
{
encoder.stop();
if (waiting.joinable())
waiting.join();
}
template <typename Rnd_It, typename Fwd_It>
Encoder<Rnd_It, Fwd_It>::Encoder (const Block_Size symbols,
: _symbol_size (symbol_size), _symbols (static_cast<uint16_t> (symbols)),
encoder (symbols, _symbol_size)
IS_RANDOM(Rnd_It, "RaptorQ__v1::Encoder");
IS_FORWARD(Fwd_It, "RaptorQ__v1::Encoder");
// check for proper initialization
uint16_t idx;
for (idx = 0; idx < (*blocks).size(); ++idx) {
if ((*blocks)[idx] == symbols)
break;
}
// check that the user did not try some cast trickery,
// and maximum size is ssize_t::max. But ssize_t is not standard,
// so we search the maximum ourselves.
if (idx == (*blocks).size() || symbol_size >= std::pow (2,
(sizeof(size_t) == 4 ? 31 : 63))) {
_state = Enc_State::INIT_ERROR;
}
_state = Enc_State::NEED_DATA;
template <typename Rnd_It, typename Fwd_It>
Encoder<Rnd_It, Fwd_It>::operator bool() const
{ return _state != Enc_State::INIT_ERROR; }
template <typename Rnd_It, typename Fwd_It>
uint16_t Encoder<Rnd_It, Fwd_It>::symbols() const
{
if (_state == Enc_State::INIT_ERROR)
return 0;
if (_state == Enc_State::INIT_ERROR)
return 0;
}
template <typename Rnd_It, typename Fwd_It>
uint32_t Encoder<Rnd_It, Fwd_It>::max_repair() const
{
// you can have up to 56403 symbols in a block
// rfc6330 limits you to 992173 repair symbols
// but limits are meant to be broken!
// the limit sould be up to 4294967279 repair symbols 2^32-(_param.S + H)
// but people might misuse the API, and call end_repair(max_repair),
// which would overflow.
// We are sorry for taking away from you that 0.0014% of repair symbols.
if (_state == Enc_State::INIT_ERROR)
return 0;
auto _param = Parameters (_symbols);
return static_cast<uint32_t> (std::numeric_limits<uint32_t>::max() -
_param.L);
RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It>
return RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It> (this, 0);
RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It>
return RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It> (this,
}
template <typename Rnd_It, typename Fwd_It>
RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It>
template <typename Rnd_It, typename Fwd_It>
RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It>
Encoder<Rnd_It, Fwd_It>::end_repair (const uint32_t repair)
return RaptorQ__v1::It::Encoder::Symbol_Iterator<Rnd_It, Fwd_It> (nullptr,
bool Encoder<Rnd_It, Fwd_It>::has_data() const
{
if (_state == Enc_State::INIT_ERROR)
return false;
return _state == Enc_State::FULL;
}
template <typename Rnd_It, typename Fwd_It>
size_t Encoder<Rnd_It, Fwd_It>::set_data (const Rnd_It &from, const Rnd_It &to)
{
if (_state == Enc_State::INIT_ERROR)
return 0;
return static_cast<size_t>(_to - _from) *
sizeof(typename std::iterator_traits<Rnd_It>::value_type);
template <typename Rnd_It, typename Fwd_It>
void Encoder<Rnd_It, Fwd_It>::clear_data()
{
if (_state == Enc_State::INIT_ERROR)
return;
_state = Enc_State::NEED_DATA;
template <typename Rnd_It, typename Fwd_It>
void Encoder<Rnd_It, Fwd_It>::stop()
{ encoder.stop(); }
template <typename Rnd_It, typename Fwd_It>
bool Encoder<Rnd_It, Fwd_It>::precompute_sync()
{
if (_state == Enc_State::INIT_ERROR)
return false;
static RaptorQ__v1::Work_State work = RaptorQ__v1::Work_State::KEEP_WORKING;
if (precomputed.rows() == 0) {
precomputed = encoder.get_precomputed (&work);
if (precomputed.rows() == 0)
return false; // exit was forced.
}
template <typename Rnd_It, typename Fwd_It>
bool Encoder<Rnd_It, Fwd_It>::compute_sync()
{
if (_state == Enc_State::INIT_ERROR)
return false;
static RaptorQ__v1::Work_State work = RaptorQ__v1::Work_State::KEEP_WORKING;
if (encoder.ready())
return true;
return encoder.generate_symbols (&work, &_from, &_to);
} else {
if (precomputed.rows() != 0)
return true;
precomputed = encoder.get_precomputed (&work);
return precomputed.rows() != 0;
}
template <typename Rnd_It, typename Fwd_It>
void Encoder<Rnd_It, Fwd_It>::compute_thread (
Encoder<Rnd_It, Fwd_It> *obj, bool force_precomputation,
std::promise<Error> p)
static RaptorQ__v1::Work_State work = RaptorQ__v1::Work_State::KEEP_WORKING;
if (force_precomputation) {
if (obj->precomputed.rows() == 0)
obj->precomputed = obj->encoder.get_precomputed (&work);
if (obj->precomputed.rows() == 0) {
// encoder always works. only possible reason:
p.set_value (Error::EXITING);
return;
}
// if we finished getting data by the time the computation
// finished, update it all.
if (obj->_state == Enc_State::FULL && !obj->encoder.ready())
obj->encoder.generate_symbols (obj->precomputed,
&obj->_from, &obj->_to);
p.set_value (Error::NONE);
} else {
if (obj->encoder.ready()) {
p.set_value (Error::NONE);
return;
}
if (obj->encoder.generate_symbols (&work, &obj->_from, &obj->_to)) {
p.set_value (Error::NONE);
return;
} else {
// only possible reason:
p.set_value (Error::EXITING);
return;
}
} else {
if (obj->precomputed.rows() == 0) {
obj->precomputed = obj->encoder.get_precomputed (&work);
if (obj->precomputed.rows() == 0) {
// only possible reason:
p.set_value (Error::EXITING);
return;
}
}
// if we finished getting data by the time the computation
// finished, update it all.
obj->encoder.generate_symbols (obj->precomputed,
&obj->_from, &obj->_to);
}
p.set_value (Error::NONE);
return;
}
}
}
template <typename Rnd_It, typename Fwd_It>
std::future<Error> Encoder<Rnd_It, Fwd_It>::precompute()
{
if (_state == Enc_State::INIT_ERROR) {
p.set_value (Error::INITIALIZATION);
return p.get_future();
}
// only one waiting thread for the encoder
if (waiting.joinable()) {
p.set_value (Error::WORKING);
return p.get_future();
}
waiting = std::thread (compute_thread, this, true, std::move(p));
return future;
}
template <typename Rnd_It, typename Fwd_It>
std::future<Error> Encoder<Rnd_It, Fwd_It>::compute()
{
if (_state == Enc_State::INIT_ERROR) {
p.set_value (Error::INITIALIZATION);
return p.get_future();
}
// only one waiting thread for the encoder
if (waiting.joinable()) {
p.set_value (Error::WORKING);
return p.get_future();
}
waiting = std::thread (compute_thread, this, false, std::move(p));
return future;
size_t Encoder<Rnd_It, Fwd_It>::encode (Fwd_It &output, const Fwd_It end,
if (_state == Enc_State::INIT_ERROR)
return 0;
if (!encoder.ready()) {
if (precomputed.rows() == 0)
encoder.generate_symbols (precomputed, &_from, &_to);
}
}
///////////////////
//// Decoder
///////////////////
template <typename In_It, typename Fwd_It>
Decoder<In_It, Fwd_It>::~Decoder ()
{
work = RaptorQ__v1::Work_State::ABORT_COMPUTATION;
_cond.notify_all();
// wait threads to exit
do {
std::unique_lock<std::mutex> lock (_mtx);
if (waiting.size() == 0)
break;
_cond.wait (lock);
lock.unlock();
} while (waiting.size() != 0);
Decoder<In_It, Fwd_It>::Decoder (const Block_Size symbols,
const size_t symbol_size, const Report type)
:_symbols (static_cast<uint16_t> (symbols)), _symbol_size (symbol_size),
_type (type), dec (symbols, symbol_size)
IS_INPUT(In_It, "RaptorQ__v1::Decoder");
IS_FORWARD(Fwd_It, "RaptorQ__v1::Decoder");
// check for proper initialization
uint16_t idx;
for (idx = 0; idx < (*blocks).size(); ++idx) {
if ((*blocks)[idx] == symbols)
break;
}
// check that the user did not try some cast trickery,
// and maximum size is ssize_t::max. But ssize_t is not standard,
// so we search the maximum ourselves.
if (idx == (*blocks).size() || symbol_size >= std::pow (2,
(sizeof(size_t) == 4 ? 31 : 63))) {
return;
}
if (type != Report::PARTIAL_FROM_BEGINNING &&
type != Report::PARTIAL_ANY &&
type != Report::COMPLETE) {
return; // no cast trickey plz
}
last_reported.store (0);
symbols_tracker = std::deque<std::atomic<bool>> (2 * _symbols);
symbols_tracker[idx] = false;
work = RaptorQ__v1::Work_State::KEEP_WORKING;
template <typename Rnd_It, typename Fwd_It>
Decoder<Rnd_It, Fwd_It>::operator bool() const
{ return symbols_tracker.size() > 0; }
template <typename In_It, typename Fwd_It>
uint16_t Decoder<In_It, Fwd_It>::symbols() const
{
RaptorQ__v1::It::Decoder::Symbol_Iterator<In_It, Fwd_It>
return RaptorQ__v1::It::Decoder::Symbol_Iterator<In_It, Fwd_It> (this, 0);
RaptorQ__v1::It::Decoder::Symbol_Iterator<In_It, Fwd_It>
return RaptorQ__v1::It::Decoder::Symbol_Iterator<In_It, Fwd_It> (nullptr,
_symbols);
template <typename In_It, typename Fwd_It>
uint16_t Decoder<In_It, Fwd_It>::needed_symbols() const
{
Error Decoder<In_It, Fwd_It>::add_symbol (In_It &from, const In_It to,
if (symbols_tracker.size() == 0)
return Error::INITIALIZATION;
auto ret = dec.add_symbol (from, to, esi);
if (ret == Error::NONE && esi < _symbols) {
symbols_tracker [2 * esi].store (true);
_cond.notify_all();
}
return ret;
}
template <typename In_It, typename Fwd_It>
if (symbols_tracker.size() == 0)
return {Error::INITIALIZATION, 0};
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uint32_t idx;
uint32_t last;
bool expected = false;
switch (_type) {
case Report::PARTIAL_FROM_BEGINNING:
// report the number of symbols that are known, starting from
// the beginning.
last = last_reported.load();
idx = last;
for (; idx < symbols_tracker.size(); idx += 2) {
if (symbols_tracker[idx].load() == true) {
++idx;
if (symbols_tracker[idx].load() == false)
symbols_tracker[idx].store (true);
--idx;
} else {
break;
}
}
idx /= 2;
if (idx > last) {
while (!last_reported.compare_exchange_weak (last, idx)) {
// expected is now "last_reported.load()"
if (last >= idx) {
// other thread already reported more than us.
// do not report things twice.
if (dec.ready()) {
last_reported.store (_symbols);
return {Error::NONE, _symbols};
}
return {Error::WORKING, 0};
return {Error::NEED_DATA, 0};
}
// else we can report the new stuff
}
return {Error::NONE, idx};
}
// nothing to report
if (dec.ready()) {
last_reported.store (_symbols);
return {Error::NONE, _symbols};
}
return {Error::WORKING, 0};
return {Error::NEED_DATA, 0};
case Report::PARTIAL_ANY:
// report the first available, not yet reported.
// or return {NONE, _symbols} if all have been reported
if (dec.ready())
return {Error::NONE, _symbols};
for (idx = 0; idx < static_cast<uint32_t> (symbols_tracker.size());
idx += 2) {
if (symbols_tracker[idx].load() == true) {
++idx;
if (symbols_tracker[idx].load() == false) {
expected = false;
if (symbols_tracker[idx].
compare_exchange_strong (expected, true)) {
return {Error::NONE, idx / 2};
} // else some other thread raced us, keep trying other
// symbols
}
}
}
if (dec.ready())
return {Error::NONE, _symbols};
return {Error::WORKING, 0};
return {Error::NEED_DATA, 0};
case Report::COMPLETE:
idx = init * 2;
for (; idx < symbols_tracker.size(); idx += 2) {
if (symbols_tracker[idx].load() == false) {
idx /= 2;
while (!last_reported.compare_exchange_weak(init, idx))
idx = std::max(init, idx);
if (dec.threads() > 0)
return {Error::WORKING, 0};
return {Error::NEED_DATA, 0};
}
}
last_reported.store (_symbols);
return {Error::NONE, 0};
}
return {Error::WORKING, 0};
}
template <typename In_It, typename Fwd_It>
void Decoder<In_It, Fwd_It>::waiting_thread (Decoder<In_It, Fwd_It> *obj,
while (obj->work == RaptorQ__v1::Work_State::KEEP_WORKING) {
bool compute = obj->dec.add_concurrent (obj->_max_threads);
if (compute) {
obj->decode_once();
std::unique_lock<std::mutex> lock (obj->_mtx);
obj->dec.drop_concurrent();
lock.unlock();
obj->_cond.notify_all(); // notify other waiting threads
}
std::unique_lock<std::mutex> lock (obj->_mtx);
// poll() does not actually need to be locked, but we use the
// lock-wait mechanism to signal the arrival of new symbols,
// so that we retry only when we get new data.
auto res = obj->poll();
if (res.first == Error::NONE || (obj->dec.end_of_input == true &&
!obj->dec.can_decode() &&
obj->dec.threads() == 0 &&
res.first == Error::NEED_DATA)){
p.set_value (res);
break;
}
obj->_cond.wait (lock);
lock.unlock();
}
if (obj->work != RaptorQ__v1::Work_State::KEEP_WORKING)
p.set_value ({Error::EXITING, 0});
std::unique_lock<std::mutex> lock (obj->_mtx);
RQ_UNUSED (lock);
for (auto th = obj->waiting.begin(); th != obj->waiting.end(); ++th) {
if (std::this_thread::get_id() == th->get_id()) {
th->detach();
obj->waiting.erase (th);
break;
}
}
lock.unlock();
obj->_cond.notify_all(); // notify exit to destructor
}
template <typename In_It, typename Fwd_It>
std::pair<Error, uint16_t> Decoder<In_It, Fwd_It>::wait_sync ()
if (symbols_tracker.size() == 0)
return {Error::INITIALIZATION, 0};
std::promise<std::pair<Error, uint16_t>> p;
auto fut = p.get_future();
waiting_thread (this, std::move(p));
fut.wait();
return fut.get();
}
template <typename In_It, typename Fwd_It>
std::future<std::pair<Error, uint16_t>> Decoder<In_It, Fwd_It>::wait ()
{
if (symbols_tracker.size() == 0) {
p.set_value ({Error::INITIALIZATION, 0});
return p.get_future();
}
auto f = p.get_future();
waiting.emplace_back (waiting_thread, this, std::move(p));
return f;
template <typename In_It, typename Fwd_It>
void Decoder<In_It, Fwd_It>::end_of_input()
{
if (symbols_tracker.size() != 0)
dec.end_of_input = true;
}
template <typename In_It, typename Fwd_It>
bool Decoder<In_It, Fwd_It>::can_decode() const
{
if (symbols_tracker.size() == 0)
return false;
return dec.can_decode();
}
void Decoder<In_It, Fwd_It>::set_max_concurrency (const uint16_t max_threads)
{
if (symbols_tracker.size() != 0)
_max_threads = max_threads;
}
template <typename In_It, typename Fwd_It>
typename Decoder<In_It, Fwd_It>::Decoder_Result
Decoder<In_It, Fwd_It>::decode_once()
{
if (symbols_tracker.size() == 0)
return Decoder<In_It, Fwd_It>::Decoder_Result::STOPPED;
auto res = dec.decode (&work);
if (res == Decoder_Result::DECODED) {
std::unique_lock<std::mutex> lock (_mtx);
RQ_UNUSED (lock);
if (_type != Report::COMPLETE) {
uint32_t id = last_reported.load();
for (; id < symbols_tracker.size(); id += 2)
symbols_tracker[id].store (true);
}
last_reported.store(_symbols);
lock.unlock();
}
return res;
}
template <typename In_It, typename Fwd_It>
void Decoder<In_It, Fwd_It>::stop()
{
work = RaptorQ__v1::Work_State::ABORT_COMPUTATION;
_cond.notify_all();
}
template <typename In_It, typename Fwd_It>
std::pair<size_t, size_t> Decoder<In_It, Fwd_It>::decode_bytes (Fwd_It &start,
const Fwd_It end,
const size_t from_byte,
const size_t skip)
{
using T = typename std::iterator_traits<Fwd_It>::value_type;
if (symbols_tracker.size() == 0 || skip >= sizeof(T) || from_byte >=
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static_cast<size_t> (_symbols * _symbol_size)) {
return {0, 0};
}
auto decoded = dec.get_symbols();
uint16_t esi = static_cast<uint16_t> (from_byte /
static_cast<size_t> (_symbol_size));
uint16_t byte = static_cast<uint16_t> (from_byte %
static_cast<size_t> (_symbol_size));
size_t offset_al = skip;
T element = static_cast<T> (0);
if (skip != 0) {
uint8_t *p = reinterpret_cast<uint8_t *> (&*start);
for (size_t keep = 0; keep < skip; ++keep) {
element += static_cast<T> (*(p++)) << keep * 8;
}
}
size_t written = 0;
while (start != end && esi < _symbols && dec.has_symbol (esi)) {
element += static_cast<T> (static_cast<uint8_t> ((*decoded)(esi, byte)))
<< offset_al * 8;
++offset_al;
if (offset_al == sizeof(T)) {
*start = element;
++start;
written += offset_al;
offset_al = 0;
element = static_cast<T> (0);
}
++byte;
if (byte == decoded->cols()) {
byte = 0;
++esi;
}
}
if (start != end && offset_al != 0) {
// we have more stuff in "element", but not enough to fill
// the iterator. Do not overwrite additional data of the iterator.
uint8_t *out = reinterpret_cast<uint8_t *> (&*start);
uint8_t *in = reinterpret_cast<uint8_t *> (&element);
for (size_t idx = 0; idx < offset_al; ++idx, ++out, ++in)
*out = *in;
written += offset_al;
}
return {written, offset_al};
Error Decoder<In_It, Fwd_It>::decode_symbol (Fwd_It &start, const Fwd_It end,
if (symbols_tracker.size() == 0)
return Error::INITIALIZATION;
auto start_copy = start;
size_t esi_byte = esi * _symbol_size;
auto pair = decode_bytes (start_copy, end, esi_byte, 0);
if (pair.first == _symbol_size) {
start = start_copy;
return Error::NONE;
}
return Error::NEED_DATA;