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//
// Copyright 2013-2015 Ettus Research LLC
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
#include <uhd/transport/nirio/nirio_fifo.h>
#include <uhd/transport/nirio_zero_copy.hpp>
#include <uhd/utils/log.hpp>
#include <uhdlib/utils/atomic.hpp>
#include <stdio.h>
#include <boost/date_time/posix_time/posix_time.hpp>
#include <boost/format.hpp>
#include <boost/interprocess/mapped_region.hpp> //get_page_size()
#include <boost/make_shared.hpp>
#include <algorithm> // std::max
#include <chrono>
#include <thread>
#include <vector>
//@TODO: Move the register defs required by the class to a common location
#include "../usrp/x300/x300_regs.hpp"
#if defined(_WIN32) || defined(__WIN32__) || defined(WIN32)
# include <windows.h>
static UHD_INLINE size_t get_page_size()
{
SYSTEM_INFO si;
GetSystemInfo(&si);
return si.dwPageSize;
}
#else
# include <unistd.h>
static UHD_INLINE size_t get_page_size()
{
return size_t(sysconf(_SC_PAGESIZE));
}
#endif
static const size_t page_size = get_page_size();
using namespace uhd;
using namespace uhd::transport;
using namespace uhd::niusrprio;
typedef uint64_t fifo_data_t;
class nirio_zero_copy_mrb : public managed_recv_buffer
{
public:
nirio_zero_copy_mrb(nirio_fifo<fifo_data_t>& fifo, const size_t frame_size)
: _fifo(fifo), _frame_size(frame_size)
{
}
void release(void)
{
_fifo.release(_frame_size / sizeof(fifo_data_t));
}
UHD_INLINE sptr get_new(const double timeout, size_t& index)
{
nirio_status status = 0;
size_t elems_acquired = 0;
size_t elems_remaining = 0;
nirio_status_chain(_fifo.acquire(_typed_buffer,
_frame_size / sizeof(fifo_data_t),
static_cast<uint32_t>(timeout * 1000),
elems_acquired,
elems_remaining),
status);
_length = elems_acquired * sizeof(fifo_data_t);
_buffer = static_cast<void*>(_typed_buffer);
if (nirio_status_not_fatal(status)) {
index++; // Advances the caller's buffer
return make(this, _buffer, _length);
} else if (status == NiRio_Status_CommunicationTimeout) {
nirio_status_to_exception(status, "NI-RIO PCIe data transfer failed.");
return sptr();
} else {
return sptr(); // NULL for timeout or error.
}
}
private:
nirio_fifo<fifo_data_t>& _fifo;
fifo_data_t* _typed_buffer;
const size_t _frame_size;
};
class nirio_zero_copy_msb : public managed_send_buffer
{
public:
nirio_zero_copy_msb(nirio_fifo<fifo_data_t>& fifo, const size_t frame_size)
: _fifo(fifo), _frame_size(frame_size)
{
}
void release(void)
{
_fifo.release(_frame_size / sizeof(fifo_data_t));
}
UHD_INLINE sptr get_new(const double timeout, size_t& index)
{
nirio_status status = 0;
size_t elems_acquired = 0;
size_t elems_remaining = 0;
nirio_status_chain(_fifo.acquire(_typed_buffer,
_frame_size / sizeof(fifo_data_t),
static_cast<uint32_t>(timeout * 1000),
elems_acquired,
elems_remaining),
status);
_length = elems_acquired * sizeof(fifo_data_t);
_buffer = static_cast<void*>(_typed_buffer);
if (nirio_status_not_fatal(status)) {
index++; // Advances the caller's buffer
return make(this, _buffer, _length);
} else if (status == NiRio_Status_CommunicationTimeout) {
nirio_status_to_exception(status, "NI-RIO PCIe data transfer failed.");
return sptr();
} else {
return sptr(); // NULL for timeout or error.
}
}
private:
nirio_fifo<fifo_data_t>& _fifo;
fifo_data_t* _typed_buffer;
const size_t _frame_size;
};
class nirio_zero_copy_impl : public nirio_zero_copy
{
public:
typedef boost::shared_ptr<nirio_zero_copy_impl> sptr;
nirio_zero_copy_impl(uhd::niusrprio::niusrprio_session::sptr fpga_session,
uint32_t instance,
const zero_copy_xport_params& xport_params)
: _fpga_session(fpga_session)
, _fifo_instance(instance)
, _xport_params(xport_params)
, _next_recv_buff_index(0)
, _next_send_buff_index(0)
{
UHD_LOGGER_TRACE("NIRIO")
<< boost::format("Creating PCIe transport for channel %d") % instance;
UHD_LOGGER_TRACE("NIRIO")
<< boost::format("nirio zero-copy RX transport configured with frame size = "
"%u, #frames = %u, buffer size = %u\n")
% _xport_params.recv_frame_size % _xport_params.num_recv_frames
% (_xport_params.recv_frame_size * _xport_params.num_recv_frames);
UHD_LOGGER_TRACE("NIRIO")
<< boost::format("nirio zero-copy TX transport configured with frame size = "
"%u, #frames = %u, buffer size = %u\n")
% _xport_params.send_frame_size % _xport_params.num_send_frames
% (_xport_params.send_frame_size * _xport_params.num_send_frames);
nirio_status status = 0;
size_t actual_depth = 0, actual_size = 0;
// Disable DMA streams in case last shutdown was unclean (cleanup, so don't status
// chain)
_proxy()->poke(
PCIE_TX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance), DMA_CTRL_DISABLED);
_proxy()->poke(
PCIE_RX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance), DMA_CTRL_DISABLED);
_wait_until_stream_ready();
// Configure frame width
nirio_status_chain(
_proxy()->poke(PCIE_TX_DMA_REG(DMA_FRAME_SIZE_REG, _fifo_instance),
static_cast<uint32_t>(
_xport_params.send_frame_size / sizeof(fifo_data_t))),
status);
nirio_status_chain(
_proxy()->poke(PCIE_RX_DMA_REG(DMA_FRAME_SIZE_REG, _fifo_instance),
static_cast<uint32_t>(
_xport_params.recv_frame_size / sizeof(fifo_data_t))),
status);
// Config 32-bit word flipping and enable DMA streams
nirio_status_chain(
_proxy()->poke(PCIE_TX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance),
DMA_CTRL_SW_BUF_U32 | DMA_CTRL_ENABLED),
status);
nirio_status_chain(
_proxy()->poke(PCIE_RX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance),
DMA_CTRL_SW_BUF_U32 | DMA_CTRL_ENABLED),
status);
// Create FIFOs
nirio_status_chain(
_fpga_session->create_rx_fifo(_fifo_instance, _recv_fifo), status);
nirio_status_chain(
_fpga_session->create_tx_fifo(_fifo_instance, _send_fifo), status);
if ((_recv_fifo.get() != NULL) && (_send_fifo.get() != NULL)) {
// Initialize FIFOs
nirio_status_chain(_recv_fifo->initialize((_xport_params.recv_frame_size
* _xport_params.num_recv_frames)
/ sizeof(fifo_data_t),
_xport_params.recv_frame_size / sizeof(fifo_data_t),
actual_depth,
actual_size),
status);
nirio_status_chain(_send_fifo->initialize((_xport_params.send_frame_size
* _xport_params.num_send_frames)
/ sizeof(fifo_data_t),
_xport_params.send_frame_size / sizeof(fifo_data_t),
actual_depth,
actual_size),
status);
_proxy()->get_rio_quirks().add_tx_fifo(_fifo_instance);
nirio_status_chain(_recv_fifo->start(), status);
nirio_status_chain(_send_fifo->start(), status);
if (nirio_status_not_fatal(status)) {
// allocate re-usable managed receive buffers
for (size_t i = 0; i < get_num_recv_frames(); i++) {
_mrb_pool.push_back(boost::shared_ptr<nirio_zero_copy_mrb>(
new nirio_zero_copy_mrb(*_recv_fifo, get_recv_frame_size())));
}
// allocate re-usable managed send buffers
for (size_t i = 0; i < get_num_send_frames(); i++) {
_msb_pool.push_back(boost::shared_ptr<nirio_zero_copy_msb>(
new nirio_zero_copy_msb(*_send_fifo, get_send_frame_size())));
}
}
} else {
nirio_status_chain(NiRio_Status_ResourceNotInitialized, status);
}
nirio_status_to_exception(status, "Could not create nirio_zero_copy transport.");
}
virtual ~nirio_zero_copy_impl()
{
_proxy()->get_rio_quirks().remove_tx_fifo(_fifo_instance);
// Disable DMA streams (cleanup, so don't status chain)
_proxy()->poke(
PCIE_TX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance), DMA_CTRL_DISABLED);
_proxy()->poke(
PCIE_RX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance), DMA_CTRL_DISABLED);
_flush_rx_buff();
// Stop DMA channels. Stop is called in the fifo dtor but
// it doesn't hurt to do it here.
_send_fifo->stop();
_recv_fifo->stop();
}
/*******************************************************************
* Receive implementation:
* Block on the managed buffer's get call and advance the index.
******************************************************************/
managed_recv_buffer::sptr get_recv_buff(double timeout)
{
if (_next_recv_buff_index == _xport_params.num_recv_frames)
_next_recv_buff_index = 0;
return _mrb_pool[_next_recv_buff_index]->get_new(timeout, _next_recv_buff_index);
}
size_t get_num_recv_frames(void) const
{
return _xport_params.num_recv_frames;
}
size_t get_recv_frame_size(void) const
{
return _xport_params.recv_frame_size;
}
/*******************************************************************
* Send implementation:
* Block on the managed buffer's get call and advance the index.
******************************************************************/
managed_send_buffer::sptr get_send_buff(double timeout)
{
if (_next_send_buff_index == _xport_params.num_send_frames)
_next_send_buff_index = 0;
return _msb_pool[_next_send_buff_index]->get_new(timeout, _next_send_buff_index);
}
size_t get_num_send_frames(void) const
{
return _xport_params.num_send_frames;
}
size_t get_send_frame_size(void) const
{
return _xport_params.send_frame_size;
}
private:
UHD_INLINE niriok_proxy::sptr _proxy()
{
return _fpga_session->get_kernel_proxy();
}
UHD_INLINE void _flush_rx_buff()
{
// acquire is called with 0 elements requested first to
// get the number of elements in the buffer and then
// repeatedly with the number of remaining elements
// until the buffer is empty
for (size_t num_elems_requested = 0,
num_elems_acquired = 0,
num_elems_remaining = 1;
num_elems_remaining;
num_elems_requested = num_elems_remaining) {
fifo_data_t* elems_buffer = NULL;
nirio_status status = _recv_fifo->acquire(elems_buffer,
num_elems_requested,
0, // timeout
num_elems_acquired,
num_elems_remaining);
// throw excetption if status is fatal
nirio_status_to_exception(
status, "NI-RIO PCIe data transfer failed during flush.");
_recv_fifo->release(num_elems_acquired);
}
}
UHD_INLINE void _wait_until_stream_ready()
{
static const uint32_t TIMEOUT_IN_MS = 100;
uint32_t reg_data = 0xffffffff;
bool tx_busy = true, rx_busy = true;
boost::posix_time::ptime start_time;
boost::posix_time::time_duration elapsed;
nirio_status status = NiRio_Status_Success;
nirio_status_chain(
_proxy()->peek(
PCIE_TX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance), reg_data),
status);
tx_busy = (reg_data & DMA_STATUS_BUSY) > 0;
nirio_status_chain(
_proxy()->peek(
PCIE_RX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance), reg_data),
status);
rx_busy = (reg_data & DMA_STATUS_BUSY) > 0;
if (nirio_status_not_fatal(status) && (tx_busy || rx_busy)) {
start_time = boost::posix_time::microsec_clock::local_time();
do {
std::this_thread::sleep_for(
std::chrono::microseconds(50)); // Avoid flooding the bus
elapsed = boost::posix_time::microsec_clock::local_time() - start_time;
nirio_status_chain(
_proxy()->peek(
PCIE_TX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance), reg_data),
status);
tx_busy = (reg_data & DMA_STATUS_BUSY) > 0;
nirio_status_chain(
_proxy()->peek(
PCIE_RX_DMA_REG(DMA_CTRL_STATUS_REG, _fifo_instance), reg_data),
status);
rx_busy = (reg_data & DMA_STATUS_BUSY) > 0;
} while (nirio_status_not_fatal(status) && (tx_busy || rx_busy)
&& elapsed.total_milliseconds() < TIMEOUT_IN_MS);
if (tx_busy || rx_busy) {
nirio_status_chain(NiRio_Status_FpgaBusy, status);
}
nirio_status_to_exception(
status, "Could not create nirio_zero_copy transport.");
}
}
// memory management -> buffers and fifos
niusrprio::niusrprio_session::sptr _fpga_session;
uint32_t _fifo_instance;
nirio_fifo<fifo_data_t>::sptr _recv_fifo, _send_fifo;
const zero_copy_xport_params _xport_params;
std::vector<boost::shared_ptr<nirio_zero_copy_msb>> _msb_pool;
std::vector<boost::shared_ptr<nirio_zero_copy_mrb>> _mrb_pool;
size_t _next_recv_buff_index, _next_send_buff_index;
};
nirio_zero_copy::sptr nirio_zero_copy::make(
uhd::niusrprio::niusrprio_session::sptr fpga_session,
const uint32_t instance,
const zero_copy_xport_params& default_buff_args,
const device_addr_t& hints)
{
// Initialize xport_params
zero_copy_xport_params xport_params = default_buff_args;
// The kernel buffer for this transport must be (num_frames * frame_size) big. Unlike
// ethernet, where the kernel buffer size is independent of the circular buffer size
// for the transport, it is possible for users to over constrain the system when they
// set the num_frames and the buff_size So we give buff_size priority over num_frames
// and throw an error if they conflict.
// RX
xport_params.recv_frame_size =
size_t(hints.cast<double>("recv_frame_size", default_buff_args.recv_frame_size));
size_t usr_num_recv_frames = static_cast<size_t>(
hints.cast<double>("num_recv_frames", default_buff_args.num_recv_frames));
size_t usr_recv_buff_size = static_cast<size_t>(
hints.cast<double>("recv_buff_size", default_buff_args.recv_buff_size));
if (hints.has_key("recv_buff_size")) {
if (usr_recv_buff_size % page_size != 0) {
throw uhd::value_error(
(boost::format("recv_buff_size must be multiple of %d") % page_size)
.str());
}
}
if (hints.has_key("recv_frame_size") and hints.has_key("num_recv_frames")) {
if (usr_num_recv_frames * xport_params.recv_frame_size % page_size != 0) {
throw uhd::value_error(
(boost::format(
"num_recv_frames * recv_frame_size must be an even multiple of %d")
% page_size)
.str());
}
}
if (hints.has_key("num_recv_frames") and hints.has_key("recv_buff_size")) {
if (usr_recv_buff_size < xport_params.recv_frame_size)
throw uhd::value_error("recv_buff_size must be equal to or greater than "
"(num_recv_frames * recv_frame_size)");
if ((usr_recv_buff_size / xport_params.recv_frame_size) != usr_num_recv_frames)
throw uhd::value_error(
"Conflicting values for recv_buff_size and num_recv_frames");
}
if (hints.has_key("recv_buff_size")) {
xport_params.num_recv_frames = std::max<size_t>(
1, usr_recv_buff_size / xport_params.recv_frame_size); // Round down
} else if (hints.has_key("num_recv_frames")) {
xport_params.num_recv_frames = usr_num_recv_frames;
}
if (xport_params.num_recv_frames * xport_params.recv_frame_size % page_size != 0) {
throw uhd::value_error(
(boost::format(
"num_recv_frames * recv_frame_size must be an even multiple of %d")
% page_size)
.str());
}
// TX
xport_params.send_frame_size =
size_t(hints.cast<double>("send_frame_size", default_buff_args.send_frame_size));
size_t usr_num_send_frames = static_cast<size_t>(
hints.cast<double>("num_send_frames", default_buff_args.num_send_frames));
size_t usr_send_buff_size = static_cast<size_t>(
hints.cast<double>("send_buff_size", default_buff_args.num_send_frames));
if (hints.has_key("send_buff_size")) {
if (usr_send_buff_size % page_size != 0) {
throw uhd::value_error(
(boost::format("send_buff_size must be multiple of %d") % page_size)
.str());
}
}
if (hints.has_key("send_frame_size") and hints.has_key("num_send_frames")) {
if (usr_num_send_frames * xport_params.send_frame_size % page_size != 0) {
throw uhd::value_error(
(boost::format(
"num_send_frames * send_frame_size must be an even multiple of %d")
% page_size)
.str());
}
}
if (hints.has_key("num_send_frames") and hints.has_key("send_buff_size")) {
if (usr_send_buff_size < xport_params.send_frame_size)
throw uhd::value_error("send_buff_size must be equal to or greater than "
"(num_send_frames * send_frame_size)");
if ((usr_send_buff_size / xport_params.send_frame_size) != usr_num_send_frames)
throw uhd::value_error(
"Conflicting values for send_buff_size and num_send_frames");
}
if (hints.has_key("send_buff_size")) {
xport_params.num_send_frames = std::max<size_t>(
1, usr_send_buff_size / xport_params.send_frame_size); // Round down
} else if (hints.has_key("num_send_frames")) {
xport_params.num_send_frames = usr_num_send_frames;
}
if (xport_params.num_send_frames * xport_params.send_frame_size % page_size != 0) {
throw uhd::value_error(
(boost::format(
"num_send_frames * send_frame_size must be an even multiple of %d")
% page_size)
.str());
}
return nirio_zero_copy::sptr(
new nirio_zero_copy_impl(fpga_session, instance, xport_params));
}
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