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//
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
/**
* Benchmark program to check performance of 2 simultaneous links
*/
#include "../transport/dpdk_zero_copy.hpp"
#include <uhdlib/transport/uhd-dpdk.h>
#include <arpa/inet.h>
#include <errno.h>
#include <sched.h>
#include <sys/syscall.h>
#include <sys/time.h>
#include <unistd.h>
#include <boost/program_options.hpp>
#include <boost/regex.hpp>
#include <cstdbool>
#include <cstdio>
#include <cstring>
#include <iostream>
static const boost::regex colons(":");
namespace po = boost::program_options;
namespace {
constexpr unsigned int NUM_MBUFS = 8192; /* Total number of mbufs in pool */
constexpr unsigned int MBUF_CACHE_SIZE = 384; /* Size of cpu-local mbuf cache */
constexpr unsigned int BURST_SIZE = 64; /* Maximum burst size for RX */
constexpr unsigned int NUM_PORTS = 2; /* Number of NIC ports */
constexpr unsigned int TX_CREDITS = 28; /* Number of TX credits */
constexpr unsigned int RX_CREDITS = 64; /* Number of RX credits */
constexpr unsigned int BENCH_SPP = 700; /* "Samples" per packet */
} // namespace
struct dpdk_test_args
{
unsigned int portid;
std::string dst_ip;
pthread_cond_t *cond;
pthread_mutex_t mutex;
bool started;
int cpu;
};
struct dpdk_test_stats
{
uint32_t last_seqno;
uint32_t dropped_packets;
uint32_t lasts[16];
uint32_t drops[16];
uint32_t last_ackno;
uint32_t tx_seqno;
uint64_t tx_xfer;
};
static void process_udp(int id, uint32_t *udp_data, struct dpdk_test_stats *stats)
{
if (udp_data[0] != stats[id].last_seqno + 1) {
stats[id].lasts[stats[id].dropped_packets & 0xf] = stats[id].last_seqno;
stats[id].drops[stats[id].dropped_packets & 0xf] = udp_data[0];
stats[id].dropped_packets++;
}
stats[id].last_seqno = udp_data[0];
stats[id].last_ackno = udp_data[1];
}
static void send_udp(uhd::transport::dpdk_zero_copy::sptr& stream,
int id,
bool fc_only,
struct dpdk_test_stats *stats)
{
uhd::transport::managed_send_buffer::sptr mbuf = stream->get_send_buff(0);
if (mbuf.get() == nullptr) {
printf("Could not get TX buffer!\n");
return;
}
auto *tx_data = mbuf->cast<uint32_t *>();
tx_data[0] = fc_only ? stats[id].tx_seqno - 1 : stats[id].tx_seqno;
tx_data[1] = stats[id].last_seqno;
if (!fc_only) {
memset(&tx_data[2], stats[id].last_seqno, 8*BENCH_SPP);
stats[id].tx_xfer += 8*BENCH_SPP;
}
size_t num_bytes = 8 + (fc_only ? 0 : 8*BENCH_SPP);
mbuf->commit(num_bytes);
mbuf.reset();
if (!fc_only) {
stats[id].tx_seqno++;
}
}
static void bench(
uhd::transport::dpdk_zero_copy::sptr *stream, uint32_t nb_ports, double timeout)
{
uint64_t total_xfer[NUM_PORTS];
uint32_t id;
struct dpdk_test_stats *stats = (struct dpdk_test_stats *) malloc(sizeof(*stats)*nb_ports);
for (id = 0; id < nb_ports; id++) {
stats[id].tx_seqno = 1;
stats[id].tx_xfer = 0;
stats[id].last_ackno = 0;
stats[id].last_seqno = 0;
stats[id].dropped_packets = 0;
total_xfer[id] = 0;
}
sleep(1);
struct timeval bench_start, bench_end;
gettimeofday(&bench_start, NULL);
/*
* The test...
*/
uint64_t total_received = 0;
uint32_t consec_no_rx = 0;
while ((total_received / nb_ports) < 10000000) { //&& consec_no_rx < 10000) {
for (id = 0; id < nb_ports; id++) {
unsigned int nb_rx = 0;
uhd::transport::managed_recv_buffer::sptr bufs[BURST_SIZE];
for (; nb_rx < BURST_SIZE; nb_rx++) {
bufs[nb_rx] = stream[id]->get_recv_buff(timeout);
if (bufs[nb_rx].get() == nullptr) {
bufs[nb_rx].reset();
break;
}
}
if (nb_rx <= 0) {
if (timeout > 0.0) {
send_udp(stream[id], id, true, stats);
}
consec_no_rx++;
if (consec_no_rx >= 100000) {
// uint32_t skt_drops = stream[id]->get_drop_count();
// printf("TX seq %d, TX ack %d, RX seq %d, %d drops!\n",
// stats[id].tx_seqno, stats[id].last_ackno, stats[id].last_seqno,
// skt_drops);
consec_no_rx = 0;
break;
}
continue;
} else {
consec_no_rx = 0;
}
for (unsigned int buf = 0; buf < nb_rx; buf++) {
total_xfer[id] += bufs[buf]->size();
auto data = bufs[buf]->cast<uint32_t *>();
process_udp(id, data, stats);
}
total_received += nb_rx;
}
for (id = 0; id < nb_ports; id++) {
/* TX portion */
uint32_t window_end = stats[id].last_ackno + TX_CREDITS;
// uint32_t window_end = last_seqno[port] + TX_CREDITS;
if (window_end <= stats[id].tx_seqno) {
if (consec_no_rx == 9999) {
send_udp(stream[id], id, true, stats);
}
// send_udp(tx[id], id, true);
;
} else {
for (unsigned int pktno = 0;
(pktno < BURST_SIZE) && (stats[id].tx_seqno < window_end);
pktno++) {
send_udp(stream[id], id, false, stats);
}
}
}
}
gettimeofday(&bench_end, NULL);
printf("Benchmark complete\n\n");
for (id = 0; id < nb_ports; id++) {
printf("\n");
printf("Bytes received = %ld\n", total_xfer[id]);
printf("Bytes sent = %ld\n", stats[id].tx_xfer);
printf("Time taken = %ld us\n",
(bench_end.tv_sec - bench_start.tv_sec)*1000000
+ (bench_end.tv_usec - bench_start.tv_usec));
double elapsed_time = (bench_end.tv_sec - bench_start.tv_sec)*1000000
+ (bench_end.tv_usec - bench_start.tv_usec);
elapsed_time *= 1.0e-6;
double elapsed_bytes = total_xfer[id];
printf("RX Performance = %e Gbps\n", elapsed_bytes*8.0/1.0e9/elapsed_time);
elapsed_bytes = stats[id].tx_xfer;
printf("TX Performance = %e Gbps\n", elapsed_bytes*8.0/1.0e9/elapsed_time);
uint32_t skt_drops = stream[id]->get_drop_count();
printf("Dropped %d packets\n", stats[id].dropped_packets);
printf("Socket reports dropped %d packets\n", skt_drops);
for (unsigned int i = 0; i < 16; i++) {
if (i >= stats[id].dropped_packets)
break;
printf("Last(%u), Recv(%u)\n", stats[id].lasts[i], stats[id].drops[i]);
}
// printf("%d missed/dropped packets\n", errors);
printf("\n");
}
free(stats);
}
static inline void set_cpu(pthread_t t, int cpu)
{
cpu_set_t cpuset;
CPU_ZERO(&cpuset);
CPU_SET(cpu, &cpuset);
int status = pthread_setaffinity_np(t, sizeof(cpu_set_t), &cpuset);
if (status) {
perror("Could not set affinity");
} else {
printf("Set CPU to %d\n", cpu);
}
}
std::string get_ipv4_addr(unsigned int port_id)
{
struct in_addr ipv4_addr;
int status = uhd_dpdk_get_ipv4_addr(port_id, &ipv4_addr.s_addr, NULL);
UHD_ASSERT_THROW(status == 0);
char addr_str[INET_ADDRSTRLEN];
inet_ntop(AF_INET, &ipv4_addr, addr_str, sizeof(addr_str));
return std::string(addr_str);
}
void *prepare_and_bench_blocking(void *arg)
{
struct dpdk_test_args *args = (struct dpdk_test_args *) arg;
pthread_mutex_lock(&args->mutex);
pthread_t t = pthread_self();
set_cpu(t, args->cpu);
args->started = true;
pthread_cond_wait(args->cond, &args->mutex);
auto& ctx = uhd::transport::uhd_dpdk_ctx::get();
uhd::transport::dpdk_zero_copy::sptr eth_data[1];
uhd::transport::zero_copy_xport_params buff_args;
buff_args.recv_frame_size = 8000;
buff_args.send_frame_size = 8000;
buff_args.num_send_frames = 8;
buff_args.num_recv_frames = 8;
auto dev_addr = uhd::device_addr_t();
eth_data[0] = uhd::transport::dpdk_zero_copy::make(
ctx,
args->portid,
args->dst_ip,
"48888",
"48888",
buff_args,
dev_addr
);
bench(eth_data, 1, 0.1);
return 0;
}
void prepare_and_bench_polling(void)
{
auto& ctx = uhd::transport::uhd_dpdk_ctx::get();
uhd::transport::dpdk_zero_copy::sptr eth_data[NUM_PORTS];
uhd::transport::zero_copy_xport_params buff_args;
buff_args.recv_frame_size = 8000;
buff_args.send_frame_size = 8000;
buff_args.num_send_frames = 8;
buff_args.num_recv_frames = 8;
auto dev_addr = uhd::device_addr_t();
eth_data[0] = uhd::transport::dpdk_zero_copy::make(
ctx,
0,
get_ipv4_addr(1),
"48888",
"48888",
buff_args,
dev_addr
);
eth_data[1] = uhd::transport::dpdk_zero_copy::make(
ctx,
1,
get_ipv4_addr(0),
"48888",
"48888",
buff_args,
dev_addr
);
bench(eth_data, NUM_PORTS, 0.0);
}
int main(int argc, char **argv)
{
int retval, user0_cpu = 0, user1_cpu = 2;
int status = 0;
std::string args;
std::string cpusets;
po::options_description desc("Allowed options");
desc.add_options()
("help", "help message")
("args", po::value<std::string>(&args)->default_value(""), "UHD-DPDK args")
("polling-mode", "Use polling mode (single thread on own core)")
("cpusets", po::value<std::string>(&cpusets)->default_value(""), "which core(s) to use for a given thread in blocking mode (specify something like \"user0=0,user1=2\")")
;
po::variables_map vm;
po::store(po::parse_command_line(argc, argv, desc), vm);
po::notify(vm);
if (vm.count("help")) {
std::cout << desc << std::endl;
return 0;
}
auto dpdk_args = uhd::device_addr_t(args);
auto cpuset_map = uhd::device_addr_t(cpusets);
for (std::string& key : cpuset_map.keys()) {
if (key == "user0") {
user0_cpu = std::stoi(cpuset_map[key], NULL, 0);
} else if (key == "user1") {
user1_cpu = std::stoi(cpuset_map[key], NULL, 0);
}
}
auto& ctx = uhd::transport::uhd_dpdk_ctx::get();
ctx.init(args);
if (vm.count("polling-mode")) {
prepare_and_bench_polling();
} else {
pthread_cond_t cond;
pthread_cond_init(&cond, NULL);
struct dpdk_test_args bench_args[2];
pthread_mutex_init(&bench_args[0].mutex, NULL);
pthread_mutex_init(&bench_args[1].mutex, NULL);
bench_args[0].cpu = user0_cpu;
bench_args[0].cond = &cond;
bench_args[0].dst_ip = get_ipv4_addr(1);
bench_args[0].started = false;
bench_args[0].portid = 0;
bench_args[1].cpu = user1_cpu;
bench_args[1].cond = &cond;
bench_args[1].dst_ip = get_ipv4_addr(0);
bench_args[1].started = false;
bench_args[1].portid = 1;
pthread_t threads[2];
pthread_create(&threads[0], NULL, prepare_and_bench_blocking, &bench_args[0]);
pthread_create(&threads[1], NULL, prepare_and_bench_blocking, &bench_args[1]);
do {
pthread_mutex_lock(&bench_args[0].mutex);
if (bench_args[0].started)
break;
pthread_mutex_unlock(&bench_args[0].mutex);
} while (true);
pthread_mutex_unlock(&bench_args[0].mutex);
do {
pthread_mutex_lock(&bench_args[1].mutex);
if (bench_args[1].started)
break;
pthread_mutex_unlock(&bench_args[1].mutex);
} while (true);
pthread_mutex_unlock(&bench_args[1].mutex);
pthread_cond_broadcast(&cond);
status = pthread_join(threads[0], (void **) &retval);
if (status) {
perror("Error while joining thread");
return status;
}
status = pthread_join(threads[1], (void **) &retval);
if (status) {
perror("Error while joining thread");
return status;
}
}
return status;
}
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