//
// Copyright 2011-2013 Ettus Research LLC
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program 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
// along with this program. If not, see .
//
#ifndef INCLUDED_LIBUHD_TRANSPORT_SUPER_SEND_PACKET_HANDLER_HPP
#define INCLUDED_LIBUHD_TRANSPORT_SUPER_SEND_PACKET_HANDLER_HPP
#include
#include
#include
#include
#include
#include
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#include
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#include
namespace uhd{ namespace transport{ namespace sph{
/***********************************************************************
* Super send packet handler
*
* A send packet handler represents a group of channels.
* The channel group shares a common sample rate.
* All channels are sent in unison in send().
**********************************************************************/
class send_packet_handler{
public:
typedef boost::function get_buff_type;
typedef boost::function async_receiver_type;
typedef void(*vrt_packer_type)(boost::uint32_t *, vrt::if_packet_info_t &);
//typedef boost::function vrt_packer_type;
/*!
* Make a new packet handler for send
* \param size the number of transport channels
*/
send_packet_handler(const size_t size = 1):
_next_packet_seq(0)
{
this->set_enable_trailer(true);
this->resize(size);
}
~send_packet_handler(void){
_task_barrier.interrupt();
_task_handlers.clear();
}
//! Resize the number of transport channels
void resize(const size_t size){
if (this->size() == size) return;
_task_handlers.clear();
_props.resize(size);
static const boost::uint64_t zero = 0;
_zero_buffs.resize(size, &zero);
_task_barrier.resize(size);
_task_handlers.resize(size);
for (size_t i = 1/*skip 0*/; i < size; i++){
_task_handlers[i] = task::make(boost::bind(&send_packet_handler::converter_thread_task, this, i));
};
}
//! Get the channel width of this handler
size_t size(void) const{
return _props.size();
}
//! Setup the vrt packer function and offset
void set_vrt_packer(const vrt_packer_type &vrt_packer, const size_t header_offset_words32 = 0){
_vrt_packer = vrt_packer;
_header_offset_words32 = header_offset_words32;
}
//! Set the stream ID for a specific channel (or no SID)
void set_xport_chan_sid(const size_t xport_chan, const bool has_sid, const boost::uint32_t sid = 0){
_props.at(xport_chan).has_sid = has_sid;
_props.at(xport_chan).sid = sid;
}
void set_enable_trailer(const bool enable)
{
_has_tlr = enable;
}
//! Set the rate of ticks per second
void set_tick_rate(const double rate){
_tick_rate = rate;
}
//! Set the rate of samples per second
void set_samp_rate(const double rate){
_samp_rate = rate;
}
/*!
* Set the function to get a managed buffer.
* \param xport_chan which transport channel
* \param get_buff the getter function
*/
void set_xport_chan_get_buff(const size_t xport_chan, const get_buff_type &get_buff){
_props.at(xport_chan).get_buff = get_buff;
}
//! Set the conversion routine for all channels
void set_converter(const uhd::convert::id_type &id){
_num_inputs = id.num_inputs;
_converter = uhd::convert::get_converter(id)();
this->set_scale_factor(32767.); //update after setting converter
_bytes_per_otw_item = uhd::convert::get_bytes_per_item(id.output_format);
_bytes_per_cpu_item = uhd::convert::get_bytes_per_item(id.input_format);
}
/*!
* Set the maximum number of samples per host packet.
* Ex: A USRP1 in dual channel mode would be half.
* \param num_samps the maximum samples in a packet
*/
void set_max_samples_per_packet(const size_t num_samps){
_max_samples_per_packet = num_samps;
}
//! Set the scale factor used in float conversion
void set_scale_factor(const double scale_factor){
_converter->set_scalar(scale_factor);
}
//! Set the callback to get async messages
void set_async_receiver(const async_receiver_type &async_receiver)
{
_async_receiver = async_receiver;
}
//! Overload call to get async metadata
bool recv_async_msg(
uhd::async_metadata_t &async_metadata, double timeout = 0.1
){
if (_async_receiver) return _async_receiver(async_metadata, timeout);
boost::this_thread::sleep(boost::posix_time::microseconds(long(timeout*1e6)));
return false;
}
/*******************************************************************
* Send:
* The entry point for the fast-path send calls.
* Dispatch into combinations of single packet send calls.
******************************************************************/
UHD_INLINE size_t send(
const uhd::tx_streamer::buffs_type &buffs,
const size_t nsamps_per_buff,
const uhd::tx_metadata_t &metadata,
const double timeout
){
//translate the metadata to vrt if packet info
vrt::if_packet_info_t if_packet_info;
if_packet_info.packet_type = vrt::if_packet_info_t::PACKET_TYPE_DATA;
//if_packet_info.has_sid = false; //set per channel
if_packet_info.has_cid = false;
if_packet_info.has_tlr = _has_tlr;
if_packet_info.has_tsi = false;
if_packet_info.has_tsf = metadata.has_time_spec;
if_packet_info.tsf = metadata.time_spec.to_ticks(_tick_rate);
if_packet_info.sob = metadata.start_of_burst;
if_packet_info.eob = metadata.end_of_burst;
if (nsamps_per_buff <= _max_samples_per_packet){
//TODO remove this code when sample counts of zero are supported by hardware
#ifndef SSPH_DONT_PAD_TO_ONE
static const boost::uint64_t zero = 0;
_zero_buffs.resize(buffs.size(), &zero);
if (nsamps_per_buff == 0) return send_one_packet(
_zero_buffs, 1, if_packet_info, timeout
) & 0x0;
#endif
return send_one_packet(buffs, nsamps_per_buff, if_packet_info, timeout);
}
size_t total_num_samps_sent = 0;
//false until final fragment
if_packet_info.eob = false;
const size_t num_fragments = (nsamps_per_buff-1)/_max_samples_per_packet;
const size_t final_length = ((nsamps_per_buff-1)%_max_samples_per_packet)+1;
//loop through the following fragment indexes
for (size_t i = 0; i < num_fragments; i++){
//send a fragment with the helper function
const size_t num_samps_sent = send_one_packet(
buffs, _max_samples_per_packet,
if_packet_info, timeout,
total_num_samps_sent*_bytes_per_cpu_item
);
total_num_samps_sent += num_samps_sent;
if (num_samps_sent == 0) return total_num_samps_sent;
//setup metadata for the next fragment
const time_spec_t time_spec = metadata.time_spec + time_spec_t::from_ticks(total_num_samps_sent, _samp_rate);
if_packet_info.tsf = time_spec.to_ticks(_tick_rate);
if_packet_info.sob = false;
}
//send the final fragment with the helper function
if_packet_info.eob = metadata.end_of_burst;
return total_num_samps_sent + send_one_packet(
buffs, final_length,
if_packet_info, timeout,
total_num_samps_sent*_bytes_per_cpu_item
);
}
private:
vrt_packer_type _vrt_packer;
size_t _header_offset_words32;
double _tick_rate, _samp_rate;
struct xport_chan_props_type{
xport_chan_props_type(void):has_sid(false){}
get_buff_type get_buff;
bool has_sid;
boost::uint32_t sid;
managed_send_buffer::sptr buff;
};
std::vector _props;
size_t _num_inputs;
size_t _bytes_per_otw_item; //used in conversion
size_t _bytes_per_cpu_item; //used in conversion
uhd::convert::converter::sptr _converter; //used in conversion
size_t _max_samples_per_packet;
std::vector _zero_buffs;
size_t _next_packet_seq;
bool _has_tlr;
async_receiver_type _async_receiver;
/*******************************************************************
* Send a single packet:
******************************************************************/
UHD_INLINE size_t send_one_packet(
const uhd::tx_streamer::buffs_type &buffs,
const size_t nsamps_per_buff,
vrt::if_packet_info_t &if_packet_info,
const double timeout,
const size_t buffer_offset_bytes = 0
){
//load the rest of the if_packet_info in here
if_packet_info.num_payload_bytes = nsamps_per_buff*_num_inputs*_bytes_per_otw_item;
if_packet_info.num_payload_words32 = (if_packet_info.num_payload_bytes + 3/*round up*/)/sizeof(boost::uint32_t);
if_packet_info.packet_count = _next_packet_seq;
//get a buffer for each channel or timeout
BOOST_FOREACH(xport_chan_props_type &props, _props){
if (not props.buff) props.buff = props.get_buff(timeout);
if (not props.buff) return 0; //timeout
}
//setup the data to share with converter threads
_convert_nsamps = nsamps_per_buff;
_convert_buffs = &buffs;
_convert_buffer_offset_bytes = buffer_offset_bytes;
_convert_if_packet_info = &if_packet_info;
//perform N channels of conversion
converter_thread_task(0);
_next_packet_seq++; //increment sequence after commits
return nsamps_per_buff;
}
/*******************************************************************
* Perform one thread's work of the conversion task.
* The entry and exit use a dual synchronization barrier,
* to wait for data to become ready and block until completion.
******************************************************************/
UHD_INLINE void converter_thread_task(const size_t index)
{
_task_barrier.wait();
//shortcut references to local data structures
managed_send_buffer::sptr &buff = _props[index].buff;
vrt::if_packet_info_t if_packet_info = *_convert_if_packet_info;
const tx_streamer::buffs_type &buffs = *_convert_buffs;
//fill IO buffs with pointers into the output buffer
const void *io_buffs[4/*max interleave*/];
for (size_t i = 0; i < _num_inputs; i++){
const char *b = reinterpret_cast(buffs[index*_num_inputs + i]);
io_buffs[i] = b + _convert_buffer_offset_bytes;
}
const ref_vector in_buffs(io_buffs, _num_inputs);
//pack metadata into a vrt header
boost::uint32_t *otw_mem = buff->cast() + _header_offset_words32;
if_packet_info.has_sid = _props[index].has_sid;
if_packet_info.sid = _props[index].sid;
_vrt_packer(otw_mem, if_packet_info);
otw_mem += if_packet_info.num_header_words32;
//perform the conversion operation
_converter->conv(in_buffs, otw_mem, _convert_nsamps);
//commit the samples to the zero-copy interface
const size_t num_vita_words32 = _header_offset_words32+if_packet_info.num_packet_words32;
buff->commit(num_vita_words32*sizeof(boost::uint32_t));
buff.reset(); //effectively a release
if (index == 0) _task_barrier.wait_others();
}
//! Shared variables for the worker threads
reusable_barrier _task_barrier;
std::vector _task_handlers;
size_t _convert_nsamps;
const tx_streamer::buffs_type *_convert_buffs;
size_t _convert_buffer_offset_bytes;
vrt::if_packet_info_t *_convert_if_packet_info;
};
class send_packet_streamer : public send_packet_handler, public tx_streamer{
public:
send_packet_streamer(const size_t max_num_samps){
_max_num_samps = max_num_samps;
this->set_max_samples_per_packet(_max_num_samps);
}
size_t get_num_channels(void) const{
return this->size();
}
size_t get_max_num_samps(void) const{
return _max_num_samps;
}
size_t send(
const tx_streamer::buffs_type &buffs,
const size_t nsamps_per_buff,
const uhd::tx_metadata_t &metadata,
const double timeout
){
return send_packet_handler::send(buffs, nsamps_per_buff, metadata, timeout);
}
bool recv_async_msg(
uhd::async_metadata_t &async_metadata, double timeout = 0.1
){
return send_packet_handler::recv_async_msg(async_metadata, timeout);
}
private:
size_t _max_num_samps;
};
}}} //namespace
#endif /* INCLUDED_LIBUHD_TRANSPORT_SUPER_SEND_PACKET_HANDLER_HPP */