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//
// Copyright 2010-2011 Ettus Research LLC
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
#include "udp_common.hpp"
#include <uhd/transport/buffer_pool.hpp>
#include <uhd/transport/udp_simple.hpp> //mtu
#include <uhd/transport/udp_zero_copy.hpp>
#include <uhd/utils/log.hpp>
#include <boost/format.hpp>
#include <vector>
using namespace uhd;
using namespace uhd::transport;
namespace asio = boost::asio;
// A reasonable number of frames for send/recv and async/sync
constexpr size_t UDP_ZERO_COPY_DEFAULT_NUM_FRAMES = 1;
constexpr size_t UDP_ZERO_COPY_DEFAULT_FRAME_SIZE =
1472; // Based on common 1500 byte MTU for 1GbE.
constexpr size_t UDP_ZERO_COPY_DEFAULT_BUFF_SIZE =
2500000; // 20ms of data for 1GbE link (in bytes)
/***********************************************************************
* Check registry for correct fast-path setting (windows only)
**********************************************************************/
#ifdef HAVE_ATLBASE_H
# define CHECK_REG_SEND_THRESH
# include <atlbase.h> //CRegKey
static void check_registry_for_fast_send_threshold(const size_t mtu)
{
static bool warned = false;
if (warned)
return; // only allow one printed warning per process
CRegKey reg_key;
DWORD threshold = 1024; // system default when threshold is not specified
if (reg_key.Open(HKEY_LOCAL_MACHINE,
"System\\CurrentControlSet\\Services\\AFD\\Parameters",
KEY_READ)
!= ERROR_SUCCESS
or reg_key.QueryDWORDValue("FastSendDatagramThreshold", threshold)
!= ERROR_SUCCESS
or threshold < mtu) {
UHD_LOGGER_WARNING("UDP")
<< boost::format(
"The MTU (%d) is larger than the FastSendDatagramThreshold (%d)!\n"
"This will negatively affect the transmit performance.\n"
"See the transport application notes for more detail.\n")
% mtu % threshold;
warned = true;
}
reg_key.Close();
}
#endif /*HAVE_ATLBASE_H*/
/***********************************************************************
* Static initialization to take care of WSA init and cleanup
**********************************************************************/
struct uhd_wsa_control
{
uhd_wsa_control(void)
{
WSADATA wsaData;
WSAStartup(MAKEWORD(2, 2), &wsaData); /*windows socket startup */
}
~uhd_wsa_control(void)
{
WSACleanup();
}
};
/***********************************************************************
* Reusable managed receiver buffer:
* - Initialize with memory and a release callback.
* - Call get new with a length in bytes to re-use.
**********************************************************************/
class udp_zero_copy_asio_mrb : public managed_recv_buffer
{
public:
udp_zero_copy_asio_mrb(void* mem, int sock_fd, const size_t frame_size)
: _sock_fd(sock_fd), _frame_size(frame_size)
{
_wsa_buff.buf = reinterpret_cast<char*>(mem);
ZeroMemory(&_overlapped, sizeof(_overlapped));
_overlapped.hEvent = WSACreateEvent();
UHD_ASSERT_THROW(_overlapped.hEvent != WSA_INVALID_EVENT);
this->release(); // makes buffer available via get_new
}
~udp_zero_copy_asio_mrb(void)
{
WSACloseEvent(_overlapped.hEvent);
}
void release(void)
{
_wsa_buff.len = _frame_size;
_flags = 0;
WSARecv(_sock_fd, &_wsa_buff, 1, &_wsa_buff.len, &_flags, &_overlapped, NULL);
}
UHD_INLINE sptr get_new(const double timeout, size_t& index)
{
const DWORD result = WSAWaitForMultipleEvents(
1, &_overlapped.hEvent, true, DWORD(timeout * 1000), true);
if (result == WSA_WAIT_TIMEOUT)
return managed_recv_buffer::sptr();
index++; // advances the caller's buffer
WSAGetOverlappedResult(_sock_fd, &_overlapped, &_wsa_buff.len, true, &_flags);
WSAResetEvent(_overlapped.hEvent);
return make(this, _wsa_buff.buf, _wsa_buff.len);
}
private:
int _sock_fd;
const size_t _frame_size;
WSAOVERLAPPED _overlapped;
WSABUF _wsa_buff;
DWORD _flags;
};
/***********************************************************************
* Reusable managed send buffer:
* - committing the buffer calls the asynchronous socket send
* - getting a new buffer performs the blocking wait for completion
**********************************************************************/
class udp_zero_copy_asio_msb : public managed_send_buffer
{
public:
udp_zero_copy_asio_msb(void* mem, int sock_fd, const size_t frame_size)
: _sock_fd(sock_fd), _frame_size(frame_size)
{
_wsa_buff.buf = reinterpret_cast<char*>(mem);
ZeroMemory(&_overlapped, sizeof(_overlapped));
_overlapped.hEvent = WSACreateEvent();
UHD_ASSERT_THROW(_overlapped.hEvent != WSA_INVALID_EVENT);
WSASetEvent(_overlapped.hEvent); // makes buffer available via get_new
}
~udp_zero_copy_asio_msb(void)
{
WSACloseEvent(_overlapped.hEvent);
}
void release(void)
{
_wsa_buff.len = size();
WSASend(_sock_fd, &_wsa_buff, 1, NULL, 0, &_overlapped, NULL);
}
UHD_INLINE sptr get_new(const double timeout, size_t& index)
{
const DWORD result = WSAWaitForMultipleEvents(
1, &_overlapped.hEvent, true, DWORD(timeout * 1000), true);
if (result == WSA_WAIT_TIMEOUT)
return managed_send_buffer::sptr();
index++; // advances the caller's buffer
WSAResetEvent(_overlapped.hEvent);
_wsa_buff.len = _frame_size;
return make(this, _wsa_buff.buf, _wsa_buff.len);
}
private:
int _sock_fd;
const size_t _frame_size;
WSAOVERLAPPED _overlapped;
WSABUF _wsa_buff;
};
/***********************************************************************
* Zero Copy UDP implementation with WSA:
*
* This is not a true zero copy implementation as each
* send and recv requires a copy operation to/from userspace.
*
* For receive, use a blocking recv() call on the socket.
* This has better performance than the overlapped IO.
* For send, use overlapped IO to submit async sends.
**********************************************************************/
class udp_zero_copy_wsa_impl : public udp_zero_copy
{
public:
typedef boost::shared_ptr<udp_zero_copy_wsa_impl> sptr;
udp_zero_copy_wsa_impl(const std::string& addr,
const std::string& port,
zero_copy_xport_params& xport_params,
const device_addr_t& hints)
: _recv_frame_size(xport_params.recv_frame_size)
, _num_recv_frames(xport_params.num_recv_frames)
, _send_frame_size(xport_params.send_frame_size)
, _num_send_frames(xport_params.num_send_frames)
, _recv_buffer_pool(buffer_pool::make(
xport_params.num_recv_frames, xport_params.recv_frame_size))
, _send_buffer_pool(buffer_pool::make(
xport_params.num_send_frames, xport_params.send_frame_size))
, _next_recv_buff_index(0)
, _next_send_buff_index(0)
{
#ifdef CHECK_REG_SEND_THRESH
check_registry_for_fast_send_threshold(this->get_send_frame_size());
#endif /*CHECK_REG_SEND_THRESH*/
UHD_LOGGER_TRACE("UDP")
<< boost::format("Creating WSA UDP transport to %s:%s") % addr % port;
static uhd_wsa_control uhd_wsa; // makes wsa start happen via lazy initialization
UHD_ASSERT_THROW(_num_send_frames <= WSA_MAXIMUM_WAIT_EVENTS);
// resolve the address
asio::io_service io_service;
asio::ip::udp::resolver resolver(io_service);
asio::ip::udp::resolver::query query(asio::ip::udp::v4(), addr, port);
asio::ip::udp::endpoint receiver_endpoint = *resolver.resolve(query);
// create the socket
_sock_fd =
WSASocket(AF_INET, SOCK_DGRAM, IPPROTO_UDP, NULL, 0, WSA_FLAG_OVERLAPPED);
if (_sock_fd == INVALID_SOCKET) {
const DWORD error = WSAGetLastError();
throw uhd::os_error(
str(boost::format("WSASocket() failed with error %d") % error));
}
// set the socket non-blocking for recv
// u_long mode = 1;
// ioctlsocket(_sock_fd, FIONBIO, &mode);
// resize the socket buffers
const int recv_buff_size = xport_params.recv_buff_size;
const int send_buff_size = xport_params.send_buff_size;
if (recv_buff_size > 0)
setsockopt(_sock_fd,
SOL_SOCKET,
SO_RCVBUF,
(const char*)&recv_buff_size,
sizeof(recv_buff_size));
if (send_buff_size > 0)
setsockopt(_sock_fd,
SOL_SOCKET,
SO_SNDBUF,
(const char*)&send_buff_size,
sizeof(send_buff_size));
// connect the socket so we can send/recv
const asio::ip::udp::endpoint::data_type& servaddr = *receiver_endpoint.data();
if (WSAConnect(_sock_fd,
(const struct sockaddr*)&servaddr,
sizeof(servaddr),
NULL,
NULL,
NULL,
NULL)
!= 0) {
const DWORD error = WSAGetLastError();
closesocket(_sock_fd);
throw uhd::os_error(
str(boost::format("WSAConnect() failed with error %d") % error));
}
UHD_LOGGER_TRACE("UDP") << boost::format("Local WSA UDP socket endpoint: %s:%s")
% get_local_addr() % get_local_port();
// allocate re-usable managed receive buffers
for (size_t i = 0; i < get_num_recv_frames(); i++) {
_mrb_pool.push_back(
boost::shared_ptr<udp_zero_copy_asio_mrb>(new udp_zero_copy_asio_mrb(
_recv_buffer_pool->at(i), _sock_fd, 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<udp_zero_copy_asio_msb>(new udp_zero_copy_asio_msb(
_send_buffer_pool->at(i), _sock_fd, get_send_frame_size())));
}
}
~udp_zero_copy_wsa_impl(void)
{
closesocket(_sock_fd);
}
/*******************************************************************
* 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 == _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 _num_recv_frames;
}
size_t get_recv_frame_size(void) const
{
return _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 == _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 _num_send_frames;
}
size_t get_send_frame_size(void) const
{
return _send_frame_size;
}
uint16_t get_local_port(void) const
{
struct sockaddr_in addr_info;
int addr_len = sizeof(addr_info);
uint16_t local_port = 0;
if (getsockname(_sock_fd, (SOCKADDR*)&addr_info, &addr_len) == 0) {
local_port = ntohs(addr_info.sin_port);
}
return local_port;
}
std::string get_local_addr(void) const
{
// Behold the beauty of winsock
struct sockaddr_in addr_info;
int addr_len = sizeof(addr_info);
std::string local_addr;
if (getsockname(_sock_fd, (SOCKADDR*)&addr_info, &addr_len) == 0) {
// inet_ntoa() guarantees either NULL or null-terminated array
char* local_ip = inet_ntoa(addr_info.sin_addr);
if (local_ip) {
local_addr = std::string(local_ip);
}
}
return local_addr;
}
//! Read back the socket's buffer space reserved for receives
size_t get_recv_buff_size(void)
{
int recv_buff_size = 0;
int opt_len = sizeof(recv_buff_size);
getsockopt(
_sock_fd, SOL_SOCKET, SO_RCVBUF, (char*)&recv_buff_size, (int*)&opt_len);
return (size_t)recv_buff_size;
}
//! Read back the socket's buffer space reserved for sends
size_t get_send_buff_size(void)
{
int send_buff_size = 0;
int opt_len = sizeof(send_buff_size);
getsockopt(
_sock_fd, SOL_SOCKET, SO_SNDBUF, (char*)&send_buff_size, (int*)&opt_len);
return (size_t)send_buff_size;
}
private:
// memory management -> buffers and fifos
const size_t _recv_frame_size, _num_recv_frames;
const size_t _send_frame_size, _num_send_frames;
buffer_pool::sptr _recv_buffer_pool, _send_buffer_pool;
std::vector<boost::shared_ptr<udp_zero_copy_asio_msb>> _msb_pool;
std::vector<boost::shared_ptr<udp_zero_copy_asio_mrb>> _mrb_pool;
size_t _next_recv_buff_index, _next_send_buff_index;
// socket guts
SOCKET _sock_fd;
};
/***********************************************************************
* UDP zero copy make function
**********************************************************************/
void check_usr_buff_size(size_t actual_buff_size,
size_t user_buff_size, // Set this to zero for no user-defined preference
const std::string tx_rx)
{
UHD_LOGGER_DEBUG("UDP") << boost::format(
"Target/actual %s sock buff size: %d/%d bytes")
% tx_rx % user_buff_size % actual_buff_size;
if ((user_buff_size != 0.0) and (actual_buff_size < user_buff_size))
UHD_LOGGER_WARNING("UDP")
<< boost::format("The %s buffer could not be resized sufficiently.\n"
"Target sock buff size: %d bytes.\n"
"Actual sock buff size: %d bytes.\n"
"See the transport application notes on buffer resizing.\n")
% tx_rx % user_buff_size % actual_buff_size;
}
udp_zero_copy::sptr udp_zero_copy::make(const std::string& addr,
const std::string& port,
const zero_copy_xport_params& default_buff_args,
udp_zero_copy::buff_params& buff_params_out,
const device_addr_t& hints)
{
// Initialize xport_params
zero_copy_xport_params xport_params = default_buff_args;
xport_params.recv_frame_size =
size_t(hints.cast<double>("recv_frame_size", default_buff_args.recv_frame_size));
xport_params.num_recv_frames =
size_t(hints.cast<double>("num_recv_frames", default_buff_args.num_recv_frames));
xport_params.send_frame_size =
size_t(hints.cast<double>("send_frame_size", default_buff_args.send_frame_size));
xport_params.num_send_frames =
size_t(hints.cast<double>("num_send_frames", default_buff_args.num_send_frames));
xport_params.recv_buff_size =
size_t(hints.cast<double>("recv_buff_size", default_buff_args.recv_buff_size));
xport_params.send_buff_size =
size_t(hints.cast<double>("send_buff_size", default_buff_args.send_buff_size));
if (xport_params.num_recv_frames == 0) {
UHD_LOG_TRACE("UDP",
"Default value for num_recv_frames: " << UDP_ZERO_COPY_DEFAULT_NUM_FRAMES);
xport_params.num_recv_frames = UDP_ZERO_COPY_DEFAULT_NUM_FRAMES;
}
if (xport_params.num_send_frames == 0) {
UHD_LOG_TRACE("UDP",
"Default value for no num_send_frames: " << UDP_ZERO_COPY_DEFAULT_NUM_FRAMES);
xport_params.num_send_frames = UDP_ZERO_COPY_DEFAULT_NUM_FRAMES;
}
if (xport_params.recv_frame_size == 0) {
UHD_LOG_TRACE("UDP",
"Using default value for recv_frame_size: "
<< UDP_ZERO_COPY_DEFAULT_FRAME_SIZE);
xport_params.recv_frame_size = UDP_ZERO_COPY_DEFAULT_FRAME_SIZE;
}
if (xport_params.send_frame_size == 0) {
UHD_LOG_TRACE("UDP",
"Using default value for send_frame_size, "
<< UDP_ZERO_COPY_DEFAULT_FRAME_SIZE);
xport_params.send_frame_size = UDP_ZERO_COPY_DEFAULT_FRAME_SIZE;
}
if (xport_params.recv_buff_size == 0) {
UHD_LOG_TRACE("UDP", "Using default value for recv_buff_size");
xport_params.recv_buff_size = std::max(UDP_ZERO_COPY_DEFAULT_BUFF_SIZE,
xport_params.num_recv_frames * MAX_ETHERNET_MTU);
UHD_LOG_TRACE("UDP",
"Using default value for recv_buff_size" << xport_params.recv_buff_size);
}
if (xport_params.send_buff_size == 0) {
UHD_LOG_TRACE("UDP", "default_buff_args has no send_buff_size");
xport_params.send_buff_size = std::max(UDP_ZERO_COPY_DEFAULT_BUFF_SIZE,
xport_params.num_send_frames * MAX_ETHERNET_MTU);
}
// extract buffer size hints from the device addr and check if they match up
size_t usr_recv_buff_size = size_t(hints.cast<double>("recv_buff_size", 0.0));
size_t usr_send_buff_size = size_t(hints.cast<double>("send_buff_size", 0.0));
if (hints.has_key("recv_buff_size")) {
if (usr_recv_buff_size
< xport_params.recv_frame_size * xport_params.num_recv_frames) {
throw uhd::value_error(
(boost::format(
"recv_buff_size must be equal to or greater than (num_recv_frames * "
"recv_frame_size) where num_recv_frames=%d, recv_frame_size=%d")
% xport_params.num_recv_frames % xport_params.recv_frame_size)
.str());
}
}
if (hints.has_key("send_buff_size")) {
if (usr_send_buff_size
< xport_params.send_frame_size * xport_params.num_send_frames) {
throw uhd::value_error(
(boost::format(
"send_buff_size must be equal to or greater than (num_send_frames * "
"send_frame_size) where num_send_frames=%d, send_frame_size=%d")
% xport_params.num_send_frames % xport_params.send_frame_size)
.str());
}
}
udp_zero_copy_wsa_impl::sptr udp_trans(
new udp_zero_copy_wsa_impl(addr, port, xport_params, hints));
// Read back the actual socket buffer sizes
buff_params_out.recv_buff_size = udp_trans->get_recv_buff_size();
buff_params_out.send_buff_size = udp_trans->get_send_buff_size();
check_usr_buff_size(buff_params_out.recv_buff_size, usr_recv_buff_size, "recv");
check_usr_buff_size(buff_params_out.send_buff_size, usr_send_buff_size, "send");
return udp_trans;
}
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