tinc/src/sptps_speed.c

/*
    sptps_speed.c -- SPTPS benchmark
    Copyright (C) 2013 Guus Sliepen <guus@tinc-vpn.org>,

    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 2 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, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/

#include "system.h"

#include <poll.h>

#include "crypto.h"
#include "ecdh.h"
#include "ecdsa.h"
#include "ecdsagen.h"
#include "sptps.h"

// Symbols necessary to link with logger.o
bool send_request(void *c, const char *msg, ...) { return false; }
struct list_t *connection_list = NULL;
bool send_meta(void *c, const char *msg , int len) { return false; }
char *logfilename = NULL;
struct timeval now;

static bool send_data(void *handle, uint8_t type, const char *data, size_t len) {
	int fd = *(int *)handle;
	send(fd, data, len, 0);
	return true;
}

static bool receive_record(void *handle, uint8_t type, const char *data, uint16_t len) {
	return true;
}

static void receive_data(sptps_t *sptps) {
	char buf[4096];
	int fd = *(int *)sptps->handle;
	size_t len = recv(fd, buf, sizeof buf, 0);
	if(!sptps_receive_data(sptps, buf, len))
		abort();
}

struct timespec start;
struct timespec end;
double elapsed;
double rate;
unsigned int count;

static void clock_start() {
	count = 0;
	clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &start);
}

static bool clock_countto(double seconds) {
	clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &end);
	elapsed = end.tv_sec + end.tv_nsec * 1e-9 - start.tv_sec - start.tv_nsec * 1e-9;
	if(elapsed < seconds)
		return ++count;

	rate = count / elapsed;
	return false;
}

int main(int argc, char *argv[]) {
	ecdsa_t *key1, *key2;
	ecdh_t *ecdh1, *ecdh2;
	sptps_t sptps1, sptps2;
	char buf1[4096], buf2[4096], buf3[4096];
	double duration = argc > 1 ? atof(argv[1]) : 10;

	crypto_init();

	randomize(buf1, sizeof buf1);
	randomize(buf2, sizeof buf2);
	randomize(buf3, sizeof buf3);

	// Key generation

	fprintf(stderr, "Generating keys for %lg seconds: ", duration);
	for(clock_start(); clock_countto(duration);)
		ecdsa_free(ecdsa_generate());
	fprintf(stderr, "%17.2lf op/s\n", rate);

	key1 = ecdsa_generate();
	key2 = ecdsa_generate();

	// ECDSA signatures

	fprintf(stderr, "ECDSA sign for %lg seconds: ", duration);
	for(clock_start(); clock_countto(duration);)
		ecdsa_sign(key1, buf1, 256, buf2);
	fprintf(stderr, "%22.2lf op/s\n", rate);

	fprintf(stderr, "ECDSA verify for %lg seconds: ", duration);
	for(clock_start(); clock_countto(duration);)
		ecdsa_verify(key1, buf1, 256, buf2);
	fprintf(stderr, "%20.2lf op/s\n", rate);

	ecdh1 = ecdh_generate_public(buf1);
	fprintf(stderr, "ECDH for %lg seconds: ", duration);
	for(clock_start(); clock_countto(duration);) {
		ecdh2 = ecdh_generate_public(buf2);
		ecdh_compute_shared(ecdh2, buf1, buf3);
	}
	fprintf(stderr, "%28.2lf op/s\n", rate);
	ecdh_free(ecdh1);

	// SPTPS authentication phase

	int fd[2];
	if(socketpair(AF_UNIX, SOCK_STREAM, 0, fd)) {
		fprintf(stderr, "Could not create a UNIX socket pair: %s\n", strerror(errno));
		return 1;
	}

	struct pollfd pfd[2] = {{fd[0], POLLIN}, {fd[1], POLLIN}};

	fprintf(stderr, "SPTPS/TCP authenticate for %lg seconds: ", duration);
	for(clock_start(); clock_countto(duration);) {
		sptps_start(&sptps1, fd + 0, true, false, key1, key2, "sptps_speed", 11, send_data, receive_record);
		sptps_start(&sptps2, fd + 1, false, false, key2, key1, "sptps_speed", 11, send_data, receive_record);
		while(poll(pfd, 2, 0)) {
			if(pfd[0].revents)
				receive_data(&sptps1);
			if(pfd[1].revents)
				receive_data(&sptps2);
		}
		sptps_stop(&sptps1);
		sptps_stop(&sptps2);
	}
	fprintf(stderr, "%10.2lf op/s\n", rate * 2);

	// SPTPS data

	sptps_start(&sptps1, fd + 0, true, false, key1, key2, "sptps_speed", 11, send_data, receive_record);
	sptps_start(&sptps2, fd + 1, false, false, key2, key1, "sptps_speed", 11, send_data, receive_record);
	while(poll(pfd, 2, 0)) {
		if(pfd[0].revents)
			receive_data(&sptps1);
		if(pfd[1].revents)
			receive_data(&sptps2);
	}
	fprintf(stderr, "SPTPS/TCP transmit for %lg seconds: ", duration);
	for(clock_start(); clock_countto(duration);) {
		if(!sptps_send_record(&sptps1, 0, buf1, 1451))
			abort();
		receive_data(&sptps2);
	}
	rate *= 2 * 1451 * 8;
	if(rate > 1e9)
		fprintf(stderr, "%14.2lf Gbit/s\n", rate / 1e9);
	else if(rate > 1e6)
		fprintf(stderr, "%14.2lf Mbit/s\n", rate / 1e6);
	else if(rate > 1e3)
		fprintf(stderr, "%14.2lf kbit/s\n", rate / 1e3);
	sptps_stop(&sptps1);
	sptps_stop(&sptps2);

	// SPTPS datagram authentication phase

	close(fd[0]);
	close(fd[1]);

	if(socketpair(AF_UNIX, SOCK_DGRAM, 0, fd)) {
		fprintf(stderr, "Could not create a UNIX socket pair: %s\n", strerror(errno));
		return 1;
	}

	fprintf(stderr, "SPTPS/UDP authenticate for %lg seconds: ", duration);
	for(clock_start(); clock_countto(duration);) {
		sptps_start(&sptps1, fd + 0, true, true, key1, key2, "sptps_speed", 11, send_data, receive_record);
		sptps_start(&sptps2, fd + 1, false, true, key2, key1, "sptps_speed", 11, send_data, receive_record);
		while(poll(pfd, 2, 0)) {
			if(pfd[0].revents)
				receive_data(&sptps1);
			if(pfd[1].revents)
				receive_data(&sptps2);
		}
		sptps_stop(&sptps1);
		sptps_stop(&sptps2);
	}
	fprintf(stderr, "%10.2lf op/s\n", rate * 2);

	// SPTPS datagram data

	sptps_start(&sptps1, fd + 0, true, true, key1, key2, "sptps_speed", 11, send_data, receive_record);
	sptps_start(&sptps2, fd + 1, false, true, key2, key1, "sptps_speed", 11, send_data, receive_record);
	while(poll(pfd, 2, 0)) {
		if(pfd[0].revents)
			receive_data(&sptps1);
		if(pfd[1].revents)
			receive_data(&sptps2);
	}
	fprintf(stderr, "SPTPS/UDP transmit for %lg seconds: ", duration);
	for(clock_start(); clock_countto(duration);) {
		if(!sptps_send_record(&sptps1, 0, buf1, 1451))
			abort();
		receive_data(&sptps2);
	}
	rate *= 2 * 1451 * 8;
	if(rate > 1e9)
		fprintf(stderr, "%14.2lf Gbit/s\n", rate / 1e9);
	else if(rate > 1e6)
		fprintf(stderr, "%14.2lf Mbit/s\n", rate / 1e6);
	else if(rate > 1e3)
		fprintf(stderr, "%14.2lf kbit/s\n", rate / 1e3);
	sptps_stop(&sptps1);
	sptps_stop(&sptps2);

	// Clean up

	close(fd[0]);
	close(fd[1]);
	ecdsa_free(key1);
	ecdsa_free(key2);
	crypto_exit();

	return 0;
}
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`/*`
			`sptps_speed.c -- SPTPS benchmark`
			`Copyright (C) 2013 Guus Sliepen <guus@tinc-vpn.org>,`

			`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 2 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, write to the Free Software Foundation, Inc.,`
			`51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.`
			`*/`

			`#include "system.h"`

			`#include <poll.h>`

			`#include "crypto.h"`
			`#include "ecdh.h"`
			`#include "ecdsa.h"`
			`#include "ecdsagen.h"`
			`#include "sptps.h"`

			`// Symbols necessary to link with logger.o`
			`bool send_request(void c, const char msg, ...) { return false; }`
			`struct list_t *connection_list = NULL;`
			`bool send_meta(void c, const char msg , int len) { return false; }`
			`char *logfilename = NULL;`
			`struct timeval now;`

			`static bool send_data(void handle, uint8_t type, const char data, size_t len) {`
			`int fd = (int )handle;`
			`send(fd, data, len, 0);`
			`return true;`
			`}`

			`static bool receive_record(void handle, uint8_t type, const char data, uint16_t len) {`
			`return true;`
			`}`

			`static void receive_data(sptps_t *sptps) {`
			`char buf[4096];`
			`int fd = (int )sptps->handle;`
			`size_t len = recv(fd, buf, sizeof buf, 0);`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`if(!sptps_receive_data(sptps, buf, len))`
			`abort();`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`}`

			`struct timespec start;`
			`struct timespec end;`
			`double elapsed;`
			`double rate;`
			`unsigned int count;`

			`static void clock_start() {`
			`count = 0;`
			`clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &start);`
			`}`

Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`static bool clock_countto(double seconds) {`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &end);`
			`elapsed = end.tv_sec + end.tv_nsec * 1e-9 - start.tv_sec - start.tv_nsec * 1e-9;`
			`if(elapsed < seconds)`
			`return ++count;`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`rate = count / elapsed;`
			`return false;`
			`}`

			`int main(int argc, char *argv[]) {`
			`ecdsa_t key1, key2;`
			`ecdh_t ecdh1, ecdh2;`
			`sptps_t sptps1, sptps2;`
			`char buf1[4096], buf2[4096], buf3[4096];`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`double duration = argc > 1 ? atof(argv[1]) : 10;`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00
			`crypto_init();`

Properly initialize buffers. Valgrind complained about use of uninitialized data. 2014-04-13 10:09:48 +00:00			`randomize(buf1, sizeof buf1);`
			`randomize(buf2, sizeof buf2);`
			`randomize(buf3, sizeof buf3);`

Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`// Key generation`

Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "Generating keys for %lg seconds: ", duration);`
			`for(clock_start(); clock_countto(duration);)`
Don't leak memory during the key generation speed test. 2013-09-15 20:02:33 +00:00			`ecdsa_free(ecdsa_generate());`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "%17.2lf op/s\n", rate);`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00
Don't leak memory during the key generation speed test. 2013-09-15 20:02:33 +00:00			`key1 = ecdsa_generate();`
			`key2 = ecdsa_generate();`

Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`// ECDSA signatures`

Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "ECDSA sign for %lg seconds: ", duration);`
			`for(clock_start(); clock_countto(duration);)`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`ecdsa_sign(key1, buf1, 256, buf2);`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "%22.2lf op/s\n", rate);`

			`fprintf(stderr, "ECDSA verify for %lg seconds: ", duration);`
			`for(clock_start(); clock_countto(duration);)`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`ecdsa_verify(key1, buf1, 256, buf2);`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "%20.2lf op/s\n", rate);`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00
			`ecdh1 = ecdh_generate_public(buf1);`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "ECDH for %lg seconds: ", duration);`
			`for(clock_start(); clock_countto(duration);) {`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`ecdh2 = ecdh_generate_public(buf2);`
			`ecdh_compute_shared(ecdh2, buf1, buf3);`
			`}`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "%28.2lf op/s\n", rate);`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`ecdh_free(ecdh1);`

			`// SPTPS authentication phase`

			`int fd[2];`
			`if(socketpair(AF_UNIX, SOCK_STREAM, 0, fd)) {`
			`fprintf(stderr, "Could not create a UNIX socket pair: %s\n", strerror(errno));`
			`return 1;`
			`}`

			`struct pollfd pfd[2] = {{fd[0], POLLIN}, {fd[1], POLLIN}};`

Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "SPTPS/TCP authenticate for %lg seconds: ", duration);`
			`for(clock_start(); clock_countto(duration);) {`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`sptps_start(&sptps1, fd + 0, true, false, key1, key2, "sptps_speed", 11, send_data, receive_record);`
			`sptps_start(&sptps2, fd + 1, false, false, key2, key1, "sptps_speed", 11, send_data, receive_record);`
			`while(poll(pfd, 2, 0)) {`
			`if(pfd[0].revents)`
			`receive_data(&sptps1);`
			`if(pfd[1].revents)`
			`receive_data(&sptps2);`
			`}`
			`sptps_stop(&sptps1);`
			`sptps_stop(&sptps2);`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`}`
			`fprintf(stderr, "%10.2lf op/s\n", rate * 2);`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00
			`// SPTPS data`

			`sptps_start(&sptps1, fd + 0, true, false, key1, key2, "sptps_speed", 11, send_data, receive_record);`
			`sptps_start(&sptps2, fd + 1, false, false, key2, key1, "sptps_speed", 11, send_data, receive_record);`
			`while(poll(pfd, 2, 0)) {`
			`if(pfd[0].revents)`
			`receive_data(&sptps1);`
			`if(pfd[1].revents)`
			`receive_data(&sptps2);`
			`}`
Use AES-256-GCM for the SPTPS protocol. It is faster than AES-256-CTR + HMAC-SHA256, especially on Intel chips with AES and PCLMULQDQ instructions. 2013-10-12 23:02:52 +00:00			`fprintf(stderr, "SPTPS/TCP transmit for %lg seconds: ", duration);`
			`for(clock_start(); clock_countto(duration);) {`
			`if(!sptps_send_record(&sptps1, 0, buf1, 1451))`
			`abort();`
			`receive_data(&sptps2);`
			`}`
			`rate = 2 1451 * 8;`
			`if(rate > 1e9)`
			`fprintf(stderr, "%14.2lf Gbit/s\n", rate / 1e9);`
			`else if(rate > 1e6)`
			`fprintf(stderr, "%14.2lf Mbit/s\n", rate / 1e6);`
			`else if(rate > 1e3)`
			`fprintf(stderr, "%14.2lf kbit/s\n", rate / 1e3);`
			`sptps_stop(&sptps1);`
			`sptps_stop(&sptps2);`

			`// SPTPS datagram authentication phase`

			`close(fd[0]);`
			`close(fd[1]);`

			`if(socketpair(AF_UNIX, SOCK_DGRAM, 0, fd)) {`
			`fprintf(stderr, "Could not create a UNIX socket pair: %s\n", strerror(errno));`
			`return 1;`
			`}`

			`fprintf(stderr, "SPTPS/UDP authenticate for %lg seconds: ", duration);`
			`for(clock_start(); clock_countto(duration);) {`
			`sptps_start(&sptps1, fd + 0, true, true, key1, key2, "sptps_speed", 11, send_data, receive_record);`
			`sptps_start(&sptps2, fd + 1, false, true, key2, key1, "sptps_speed", 11, send_data, receive_record);`
			`while(poll(pfd, 2, 0)) {`
			`if(pfd[0].revents)`
			`receive_data(&sptps1);`
			`if(pfd[1].revents)`
			`receive_data(&sptps2);`
			`}`
			`sptps_stop(&sptps1);`
			`sptps_stop(&sptps2);`
			`}`
			`fprintf(stderr, "%10.2lf op/s\n", rate * 2);`

			`// SPTPS datagram data`

			`sptps_start(&sptps1, fd + 0, true, true, key1, key2, "sptps_speed", 11, send_data, receive_record);`
			`sptps_start(&sptps2, fd + 1, false, true, key2, key1, "sptps_speed", 11, send_data, receive_record);`
			`while(poll(pfd, 2, 0)) {`
			`if(pfd[0].revents)`
			`receive_data(&sptps1);`
			`if(pfd[1].revents)`
			`receive_data(&sptps2);`
			`}`
			`fprintf(stderr, "SPTPS/UDP transmit for %lg seconds: ", duration);`
			`for(clock_start(); clock_countto(duration);) {`
			`if(!sptps_send_record(&sptps1, 0, buf1, 1451))`
			`abort();`
Add a benchmark for the SPTPS protocol. 2013-09-15 15:35:55 +00:00			`receive_data(&sptps2);`
			`}`
			`rate = 2 1451 * 8;`
			`if(rate > 1e9)`
			`fprintf(stderr, "%14.2lf Gbit/s\n", rate / 1e9);`
			`else if(rate > 1e6)`
			`fprintf(stderr, "%14.2lf Mbit/s\n", rate / 1e6);`
			`else if(rate > 1e3)`
			`fprintf(stderr, "%14.2lf kbit/s\n", rate / 1e3);`
			`sptps_stop(&sptps1);`
			`sptps_stop(&sptps2);`

			`// Clean up`

			`close(fd[0]);`
			`close(fd[1]);`
			`ecdsa_free(key1);`
			`ecdsa_free(key2);`
			`crypto_exit();`

			`return 0;`
			`}`