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//
// Copyright 2016 Ettus Research LLC
//
// SPDX-License-Identifier: GPL-3.0
//
#include <uhd/transport/muxed_zero_copy_if.hpp>
#include <uhd/transport/bounded_buffer.hpp>
#include <uhd/exception.hpp>
#include <uhd/utils/safe_call.hpp>
#include <boost/enable_shared_from_this.hpp>
#include <boost/make_shared.hpp>
#include <boost/thread.hpp>
#include <boost/thread/locks.hpp>
#include <map>
using namespace uhd;
using namespace uhd::transport;
class muxed_zero_copy_if_impl : public muxed_zero_copy_if,
public boost::enable_shared_from_this<muxed_zero_copy_if_impl>
{
public:
typedef boost::shared_ptr<muxed_zero_copy_if_impl> sptr;
muxed_zero_copy_if_impl(
zero_copy_if::sptr base_xport,
stream_classifier_fn classify_fn,
size_t max_streams
):
_base_xport(base_xport), _classify(classify_fn),
_max_num_streams(max_streams), _num_dropped_frames(0)
{
//Create the receive thread to poll the underlying transport
//and classify packets into queues
_recv_thread = boost::thread(
boost::bind(&muxed_zero_copy_if_impl::_update_queues, this));
}
virtual ~muxed_zero_copy_if_impl()
{
UHD_SAFE_CALL(
//Interrupt buffer updater loop
_recv_thread.interrupt();
//Wait for loop to finish
//No timeout on join. The recv loop is guaranteed
//to terminate in a reasonable amount of time because
//there are no timed blocks on the underlying.
_recv_thread.join();
//Flush base transport
while (_base_xport->get_recv_buff(0.0001)) /*NOP*/;
//Release child streams
//Note that this will not delete or flush the child streams
//until the owners of the streams have released the respective
//shared pointers. This ensures that packets are not dropped.
_streams.clear();
);
}
virtual zero_copy_if::sptr make_stream(const uint32_t stream_num)
{
boost::lock_guard<boost::mutex> lock(_mutex);
if (_streams.size() >= _max_num_streams) {
throw uhd::runtime_error("muxed_zero_copy_if: stream capacity exceeded. cannot create more streams.");
}
// Only allocate a portion of the base transport's frames to each stream
// to prevent all streams from attempting to use all the frames.
stream_impl::sptr stream = boost::make_shared<stream_impl>(
this->shared_from_this(), stream_num,
_base_xport->get_num_send_frames() / _max_num_streams,
_base_xport->get_num_recv_frames() / _max_num_streams);
_streams[stream_num] = stream;
return stream;
}
virtual size_t get_num_dropped_frames() const
{
return _num_dropped_frames;
}
void remove_stream(const uint32_t stream_num)
{
boost::lock_guard<boost::mutex> lock(_mutex);
_streams.erase(stream_num);
}
private:
/*
* @class stream_mrb is used to copy the data and release the original
* managed receive buffer back to the base transport.
*/
class stream_mrb : public managed_recv_buffer
{
public:
stream_mrb(size_t size) : _buff(new char[size]) {}
~stream_mrb() {
delete[] _buff;
}
void release() {}
UHD_INLINE sptr get_new(char *buff, size_t len)
{
memcpy(_buff, buff, len);
return make(this, _buff, len);
}
private:
char *_buff;
};
class stream_impl : public zero_copy_if
{
public:
typedef boost::shared_ptr<stream_impl> sptr;
typedef boost::weak_ptr<stream_impl> wptr;
stream_impl(
muxed_zero_copy_if_impl::sptr muxed_xport,
const uint32_t stream_num,
const size_t num_send_frames,
const size_t num_recv_frames
) :
_stream_num(stream_num), _muxed_xport(muxed_xport),
_num_send_frames(num_send_frames),
_send_frame_size(_muxed_xport->base_xport()->get_send_frame_size()),
_num_recv_frames(num_recv_frames),
_recv_frame_size(_muxed_xport->base_xport()->get_recv_frame_size()),
_buff_queue(num_recv_frames),
_buffers(num_recv_frames),
_buffer_index(0)
{
for (size_t i = 0; i < num_recv_frames; i++) {
_buffers[i] = boost::make_shared<stream_mrb>(_recv_frame_size);
}
}
~stream_impl(void)
{
//First remove the stream from muxed transport
//so no more frames are pushed in
_muxed_xport->remove_stream(_stream_num);
//Flush the transport
managed_recv_buffer::sptr buff;
while (_buff_queue.pop_with_haste(buff)) {
//NOP
}
}
size_t get_num_recv_frames(void) const {
return _num_recv_frames;
}
size_t get_recv_frame_size(void) const {
return _recv_frame_size;
}
managed_recv_buffer::sptr get_recv_buff(double timeout) {
managed_recv_buffer::sptr buff;
if (_buff_queue.pop_with_timed_wait(buff, timeout)) {
return buff;
} else {
return managed_recv_buffer::sptr();
}
}
void push_recv_buff(managed_recv_buffer::sptr buff) {
_buff_queue.push_with_wait(_buffers.at(_buffer_index++)->get_new(buff->cast<char*>(), buff->size()));
_buffer_index %= _buffers.size();
}
size_t get_num_send_frames(void) const {
return _num_send_frames;
}
size_t get_send_frame_size(void) const {
return _send_frame_size;
}
managed_send_buffer::sptr get_send_buff(double timeout)
{
return _muxed_xport->base_xport()->get_send_buff(timeout);
}
private:
const uint32_t _stream_num;
muxed_zero_copy_if_impl::sptr _muxed_xport;
const size_t _num_send_frames;
const size_t _send_frame_size;
const size_t _num_recv_frames;
const size_t _recv_frame_size;
bounded_buffer<managed_recv_buffer::sptr> _buff_queue;
std::vector< boost::shared_ptr<stream_mrb> > _buffers;
size_t _buffer_index;
};
inline zero_copy_if::sptr& base_xport() { return _base_xport; }
void _update_queues()
{
//Run forever:
// - Pull packets from the base transport
// - Classify them
// - Push them to the appropriate receive queue
while (true) {
{ //Uninterruptable block of code
boost::this_thread::disable_interruption interrupt_disabler;
if (not _process_next_buffer()) {
//Be a good citizen and yield if no packet is processed
static const size_t MIN_DUR = 1;
boost::this_thread::sleep_for(boost::chrono::nanoseconds(MIN_DUR));
//We call sleep(MIN_DUR) above instead of yield() to ensure that we
//relinquish the current scheduler time slot.
//yield() is a hint to the scheduler to end the time
//slice early and schedule in another thread that is ready to run.
//However in most situations, there will be no other thread and
//this thread will continue to run which will rail a CPU core.
//We call sleep(MIN_DUR=1) instead which will sleep for a minimum time.
//Ideally we would like to use boost::chrono::.*seconds::min() but that
//is bound to 0, which causes the sleep_for call to be a no-op and
//thus useless to actually force a sleep.
//****************************************************************
//NOTE: This behavior makes this transport a poor choice for
// low latency communication.
//****************************************************************
}
}
//Check if the master thread has requested a shutdown
if (boost::this_thread::interruption_requested()) break;
}
}
bool _process_next_buffer()
{
managed_recv_buffer::sptr buff = _base_xport->get_recv_buff(0.0);
if (buff) {
stream_impl::sptr stream;
try {
const uint32_t stream_num = _classify(buff->cast<void*>(), _base_xport->get_recv_frame_size());
{
//Hold the stream mutex long enough to pull a bounded buffer
//and lock it (increment its ref count).
boost::lock_guard<boost::mutex> lock(_mutex);
stream_map_t::iterator str_iter = _streams.find(stream_num);
if (str_iter != _streams.end()) {
stream = (*str_iter).second.lock();
}
}
} catch (std::exception&) {
//If _classify throws we simply drop the frame
}
//Once a bounded buffer is acquired, we can rely on its
//thread safety to serialize with the consumer.
if (stream.get()) {
stream->push_recv_buff(buff);
} else {
boost::lock_guard<boost::mutex> lock(_mutex);
_num_dropped_frames++;
}
//We processed a packet, and there could be more coming
//Don't yield in the next iteration.
return true;
} else {
//The base transport is idle. Return false to let the
//thread yield.
return false;
}
}
typedef std::map<uint32_t, stream_impl::wptr> stream_map_t;
zero_copy_if::sptr _base_xport;
stream_classifier_fn _classify;
stream_map_t _streams;
const size_t _max_num_streams;
size_t _num_dropped_frames;
boost::thread _recv_thread;
boost::mutex _mutex;
};
muxed_zero_copy_if::sptr muxed_zero_copy_if::make(
zero_copy_if::sptr base_xport,
muxed_zero_copy_if::stream_classifier_fn classify_fn,
size_t max_streams
) {
return boost::make_shared<muxed_zero_copy_if_impl>(base_xport, classify_fn, max_streams);
}
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