1 /* 2 * iperf, Copyright (c) 2014-2020, The Regents of the University of 3 * California, through Lawrence Berkeley National Laboratory (subject 4 * to receipt of any required approvals from the U.S. Dept. of 5 * Energy). All rights reserved. 6 * 7 * If you have questions about your rights to use or distribute this 8 * software, please contact Berkeley Lab's Technology Transfer 9 * Department at [email protected]. 10 * 11 * NOTICE. This software is owned by the U.S. Department of Energy. 12 * As such, the U.S. Government has been granted for itself and others 13 * acting on its behalf a paid-up, nonexclusive, irrevocable, 14 * worldwide license in the Software to reproduce, prepare derivative 15 * works, and perform publicly and display publicly. Beginning five 16 * (5) years after the date permission to assert copyright is obtained 17 * from the U.S. Department of Energy, and subject to any subsequent 18 * five (5) year renewals, the U.S. Government is granted for itself 19 * and others acting on its behalf a paid-up, nonexclusive, 20 * irrevocable, worldwide license in the Software to reproduce, 21 * prepare derivative works, distribute copies to the public, perform 22 * publicly and display publicly, and to permit others to do so. 23 * 24 * This code is distributed under a BSD style license, see the LICENSE file 25 * for complete information. 26 */ 27 #ifndef _GNU_SOURCE 28 # define _GNU_SOURCE 29 #endif 30 #define __USE_GNU 31 32 #include "iperf_config.h" 33 34 #include <stdio.h> 35 #include <stdlib.h> 36 #include <string.h> 37 #include <time.h> 38 #include <getopt.h> 39 #include <errno.h> 40 #include <signal.h> 41 #include <unistd.h> 42 #include <assert.h> 43 #include <fcntl.h> 44 #include <sys/socket.h> 45 #include <sys/types.h> 46 #include <netinet/in.h> 47 #include <arpa/inet.h> 48 #include <netdb.h> 49 #ifdef HAVE_STDINT_H 50 #include <stdint.h> 51 #endif 52 #include <netinet/tcp.h> 53 #include <sys/time.h> 54 #include <sys/resource.h> 55 #include <sys/mman.h> 56 #include <sys/stat.h> 57 #include <sched.h> 58 #include <setjmp.h> 59 #include <stdarg.h> 60 61 #if defined(HAVE_CPUSET_SETAFFINITY) 62 #include <sys/param.h> 63 #include <sys/cpuset.h> 64 #endif /* HAVE_CPUSET_SETAFFINITY */ 65 66 #if defined(__CYGWIN__) || defined(_WIN32) || defined(_WIN64) || defined(__WINDOWS__) 67 #define CPU_SETSIZE __CPU_SETSIZE 68 #endif /* __CYGWIN__, _WIN32, _WIN64, __WINDOWS__ */ 69 70 #if defined(HAVE_SETPROCESSAFFINITYMASK) 71 #include <Windows.h> 72 #endif /* HAVE_SETPROCESSAFFINITYMASK */ 73 74 #include "net.h" 75 #include "iperf.h" 76 #include "iperf_api.h" 77 #include "iperf_udp.h" 78 #include "iperf_tcp.h" 79 #if defined(HAVE_SCTP) 80 #include "iperf_sctp.h" 81 #endif /* HAVE_SCTP */ 82 #include "timer.h" 83 84 #include "cjson.h" 85 #include "units.h" 86 #include "iperf_util.h" 87 #include "iperf_locale.h" 88 #include "version.h" 89 #if defined(HAVE_SSL) 90 #include <openssl/bio.h> 91 #include "iperf_auth.h" 92 #endif /* HAVE_SSL */ 93 94 /* Forwards. */ 95 static int send_parameters(struct iperf_test *test); 96 static int get_parameters(struct iperf_test *test); 97 static int send_results(struct iperf_test *test); 98 static int get_results(struct iperf_test *test); 99 static int diskfile_send(struct iperf_stream *sp); 100 static int diskfile_recv(struct iperf_stream *sp); 101 static int JSON_write(int fd, cJSON *json); 102 static void print_interval_results(struct iperf_test *test, struct iperf_stream *sp, cJSON *json_interval_streams); 103 static cJSON *JSON_read(int fd); 104 105 106 /*************************** Print usage functions ****************************/ 107 108 void 109 usage() 110 { 111 fputs(usage_shortstr, stderr); 112 } 113 114 115 void 116 usage_long(FILE *f) 117 { 118 fprintf(f, usage_longstr, UDP_RATE / (1024*1024), DURATION, DEFAULT_TCP_BLKSIZE / 1024, DEFAULT_UDP_BLKSIZE); 119 } 120 121 122 void warning(char *str) 123 { 124 fprintf(stderr, "warning: %s\n", str); 125 } 126 127 128 /************** Getter routines for some fields inside iperf_test *************/ 129 130 int 131 iperf_get_verbose(struct iperf_test *ipt) 132 { 133 return ipt->verbose; 134 } 135 136 int 137 iperf_get_control_socket(struct iperf_test *ipt) 138 { 139 return ipt->ctrl_sck; 140 } 141 142 int 143 iperf_get_control_socket_mss(struct iperf_test *ipt) 144 { 145 return ipt->ctrl_sck_mss; 146 } 147 148 int 149 iperf_get_test_omit(struct iperf_test *ipt) 150 { 151 return ipt->omit; 152 } 153 154 int 155 iperf_get_test_duration(struct iperf_test *ipt) 156 { 157 return ipt->duration; 158 } 159 160 uint64_t 161 iperf_get_test_rate(struct iperf_test *ipt) 162 { 163 return ipt->settings->rate; 164 } 165 166 uint64_t 167 iperf_get_test_fqrate(struct iperf_test *ipt) 168 { 169 return ipt->settings->fqrate; 170 } 171 172 int 173 iperf_get_test_pacing_timer(struct iperf_test *ipt) 174 { 175 return ipt->settings->pacing_timer; 176 } 177 178 uint64_t 179 iperf_get_test_bytes(struct iperf_test *ipt) 180 { 181 return (uint64_t) ipt->settings->bytes; 182 } 183 184 uint64_t 185 iperf_get_test_blocks(struct iperf_test *ipt) 186 { 187 return (uint64_t) ipt->settings->blocks; 188 } 189 190 int 191 iperf_get_test_burst(struct iperf_test *ipt) 192 { 193 return ipt->settings->burst; 194 } 195 196 char 197 iperf_get_test_role(struct iperf_test *ipt) 198 { 199 return ipt->role; 200 } 201 202 int 203 iperf_get_test_reverse(struct iperf_test *ipt) 204 { 205 return ipt->reverse; 206 } 207 208 int 209 iperf_get_test_blksize(struct iperf_test *ipt) 210 { 211 return ipt->settings->blksize; 212 } 213 214 FILE * 215 iperf_get_test_outfile (struct iperf_test *ipt) 216 { 217 return ipt->outfile; 218 } 219 220 int 221 iperf_get_test_socket_bufsize(struct iperf_test *ipt) 222 { 223 return ipt->settings->socket_bufsize; 224 } 225 226 double 227 iperf_get_test_reporter_interval(struct iperf_test *ipt) 228 { 229 return ipt->reporter_interval; 230 } 231 232 double 233 iperf_get_test_stats_interval(struct iperf_test *ipt) 234 { 235 return ipt->stats_interval; 236 } 237 238 int 239 iperf_get_test_num_streams(struct iperf_test *ipt) 240 { 241 return ipt->num_streams; 242 } 243 244 int 245 iperf_get_test_repeating_payload(struct iperf_test *ipt) 246 { 247 return ipt->repeating_payload; 248 } 249 250 int 251 iperf_get_test_server_port(struct iperf_test *ipt) 252 { 253 return ipt->server_port; 254 } 255 256 char* 257 iperf_get_test_server_hostname(struct iperf_test *ipt) 258 { 259 return ipt->server_hostname; 260 } 261 262 char* 263 iperf_get_test_template(struct iperf_test *ipt) 264 { 265 return ipt->tmp_template; 266 } 267 268 int 269 iperf_get_test_protocol_id(struct iperf_test *ipt) 270 { 271 return ipt->protocol->id; 272 } 273 274 int 275 iperf_get_test_json_output(struct iperf_test *ipt) 276 { 277 return ipt->json_output; 278 } 279 280 char * 281 iperf_get_test_json_output_string(struct iperf_test *ipt) 282 { 283 return ipt->json_output_string; 284 } 285 286 int 287 iperf_get_test_zerocopy(struct iperf_test *ipt) 288 { 289 return ipt->zerocopy; 290 } 291 292 int 293 iperf_get_test_get_server_output(struct iperf_test *ipt) 294 { 295 return ipt->get_server_output; 296 } 297 298 char 299 iperf_get_test_unit_format(struct iperf_test *ipt) 300 { 301 return ipt->settings->unit_format; 302 } 303 304 char * 305 iperf_get_test_bind_address(struct iperf_test *ipt) 306 { 307 return ipt->bind_address; 308 } 309 310 int 311 iperf_get_test_udp_counters_64bit(struct iperf_test *ipt) 312 { 313 return ipt->udp_counters_64bit; 314 } 315 316 int 317 iperf_get_test_one_off(struct iperf_test *ipt) 318 { 319 return ipt->one_off; 320 } 321 322 int 323 iperf_get_test_tos(struct iperf_test *ipt) 324 { 325 return ipt->settings->tos; 326 } 327 328 char * 329 iperf_get_test_extra_data(struct iperf_test *ipt) 330 { 331 return ipt->extra_data; 332 } 333 334 static const char iperf_version[] = IPERF_VERSION; 335 char * 336 iperf_get_iperf_version(void) 337 { 338 return (char*)iperf_version; 339 } 340 341 int 342 iperf_get_test_no_delay(struct iperf_test *ipt) 343 { 344 return ipt->no_delay; 345 } 346 347 int 348 iperf_get_test_connect_timeout(struct iperf_test *ipt) 349 { 350 return ipt->settings->connect_timeout; 351 } 352 353 /************** Setter routines for some fields inside iperf_test *************/ 354 355 void 356 iperf_set_verbose(struct iperf_test *ipt, int verbose) 357 { 358 ipt->verbose = verbose; 359 } 360 361 void 362 iperf_set_control_socket(struct iperf_test *ipt, int ctrl_sck) 363 { 364 ipt->ctrl_sck = ctrl_sck; 365 } 366 367 void 368 iperf_set_test_omit(struct iperf_test *ipt, int omit) 369 { 370 ipt->omit = omit; 371 } 372 373 void 374 iperf_set_test_duration(struct iperf_test *ipt, int duration) 375 { 376 ipt->duration = duration; 377 } 378 379 void 380 iperf_set_test_reporter_interval(struct iperf_test *ipt, double reporter_interval) 381 { 382 ipt->reporter_interval = reporter_interval; 383 } 384 385 void 386 iperf_set_test_stats_interval(struct iperf_test *ipt, double stats_interval) 387 { 388 ipt->stats_interval = stats_interval; 389 } 390 391 void 392 iperf_set_test_state(struct iperf_test *ipt, signed char state) 393 { 394 ipt->state = state; 395 } 396 397 void 398 iperf_set_test_blksize(struct iperf_test *ipt, int blksize) 399 { 400 ipt->settings->blksize = blksize; 401 } 402 403 void 404 iperf_set_test_logfile(struct iperf_test *ipt, char *logfile) 405 { 406 ipt->logfile = strdup(logfile); 407 } 408 409 void 410 iperf_set_test_rate(struct iperf_test *ipt, uint64_t rate) 411 { 412 ipt->settings->rate = rate; 413 } 414 415 void 416 iperf_set_test_fqrate(struct iperf_test *ipt, uint64_t fqrate) 417 { 418 ipt->settings->fqrate = fqrate; 419 } 420 421 void 422 iperf_set_test_pacing_timer(struct iperf_test *ipt, int pacing_timer) 423 { 424 ipt->settings->pacing_timer = pacing_timer; 425 } 426 427 void 428 iperf_set_test_bytes(struct iperf_test *ipt, uint64_t bytes) 429 { 430 ipt->settings->bytes = (iperf_size_t) bytes; 431 } 432 433 void 434 iperf_set_test_blocks(struct iperf_test *ipt, uint64_t blocks) 435 { 436 ipt->settings->blocks = (iperf_size_t) blocks; 437 } 438 439 void 440 iperf_set_test_burst(struct iperf_test *ipt, int burst) 441 { 442 ipt->settings->burst = burst; 443 } 444 445 void 446 iperf_set_test_server_port(struct iperf_test *ipt, int srv_port) 447 { 448 ipt->server_port = srv_port; 449 } 450 451 void 452 iperf_set_test_socket_bufsize(struct iperf_test *ipt, int socket_bufsize) 453 { 454 ipt->settings->socket_bufsize = socket_bufsize; 455 } 456 457 void 458 iperf_set_test_num_streams(struct iperf_test *ipt, int num_streams) 459 { 460 ipt->num_streams = num_streams; 461 } 462 463 void 464 iperf_set_test_repeating_payload(struct iperf_test *ipt, int repeating_payload) 465 { 466 ipt->repeating_payload = repeating_payload; 467 } 468 469 static void 470 check_sender_has_retransmits(struct iperf_test *ipt) 471 { 472 if (ipt->mode != RECEIVER && ipt->protocol->id == Ptcp && has_tcpinfo_retransmits()) 473 ipt->sender_has_retransmits = 1; 474 else 475 ipt->sender_has_retransmits = 0; 476 } 477 478 void 479 iperf_set_test_role(struct iperf_test *ipt, char role) 480 { 481 ipt->role = role; 482 if (!ipt->reverse) { 483 if (ipt->bidirectional) 484 ipt->mode = BIDIRECTIONAL; 485 else if (role == 'c') 486 ipt->mode = SENDER; 487 else if (role == 's') 488 ipt->mode = RECEIVER; 489 } else { 490 if (role == 'c') 491 ipt->mode = RECEIVER; 492 else if (role == 's') 493 ipt->mode = SENDER; 494 } 495 check_sender_has_retransmits(ipt); 496 } 497 498 void 499 iperf_set_test_server_hostname(struct iperf_test *ipt, char *server_hostname) 500 { 501 ipt->server_hostname = strdup(server_hostname); 502 } 503 504 void 505 iperf_set_test_template(struct iperf_test *ipt, char *tmp_template) 506 { 507 ipt->tmp_template = strdup(tmp_template); 508 } 509 510 void 511 iperf_set_test_reverse(struct iperf_test *ipt, int reverse) 512 { 513 ipt->reverse = reverse; 514 if (!ipt->reverse) { 515 if (ipt->role == 'c') 516 ipt->mode = SENDER; 517 else if (ipt->role == 's') 518 ipt->mode = RECEIVER; 519 } else { 520 if (ipt->role == 'c') 521 ipt->mode = RECEIVER; 522 else if (ipt->role == 's') 523 ipt->mode = SENDER; 524 } 525 check_sender_has_retransmits(ipt); 526 } 527 528 void 529 iperf_set_test_json_output(struct iperf_test *ipt, int json_output) 530 { 531 ipt->json_output = json_output; 532 } 533 534 int 535 iperf_has_zerocopy( void ) 536 { 537 return has_sendfile(); 538 } 539 540 void 541 iperf_set_test_zerocopy(struct iperf_test *ipt, int zerocopy) 542 { 543 ipt->zerocopy = (zerocopy && has_sendfile()); 544 } 545 546 void 547 iperf_set_test_get_server_output(struct iperf_test *ipt, int get_server_output) 548 { 549 ipt->get_server_output = get_server_output; 550 } 551 552 void 553 iperf_set_test_unit_format(struct iperf_test *ipt, char unit_format) 554 { 555 ipt->settings->unit_format = unit_format; 556 } 557 558 #if defined(HAVE_SSL) 559 void 560 iperf_set_test_client_username(struct iperf_test *ipt, char *client_username) 561 { 562 ipt->settings->client_username = strdup(client_username); 563 } 564 565 void 566 iperf_set_test_client_password(struct iperf_test *ipt, char *client_password) 567 { 568 ipt->settings->client_password = strdup(client_password); 569 } 570 571 void 572 iperf_set_test_client_rsa_pubkey(struct iperf_test *ipt, char *client_rsa_pubkey_base64) 573 { 574 ipt->settings->client_rsa_pubkey = load_pubkey_from_base64(client_rsa_pubkey_base64); 575 } 576 577 void 578 iperf_set_test_server_authorized_users(struct iperf_test *ipt, char *server_authorized_users) 579 { 580 ipt->server_authorized_users = strdup(server_authorized_users); 581 } 582 583 void 584 iperf_set_test_server_rsa_privkey(struct iperf_test *ipt, char *server_rsa_privkey_base64) 585 { 586 ipt->server_rsa_private_key = load_privkey_from_base64(server_rsa_privkey_base64); 587 } 588 #endif // HAVE_SSL 589 590 void 591 iperf_set_test_bind_address(struct iperf_test *ipt, char *bnd_address) 592 { 593 ipt->bind_address = strdup(bnd_address); 594 } 595 596 void 597 iperf_set_test_udp_counters_64bit(struct iperf_test *ipt, int udp_counters_64bit) 598 { 599 ipt->udp_counters_64bit = udp_counters_64bit; 600 } 601 602 void 603 iperf_set_test_one_off(struct iperf_test *ipt, int one_off) 604 { 605 ipt->one_off = one_off; 606 } 607 608 void 609 iperf_set_test_tos(struct iperf_test *ipt, int tos) 610 { 611 ipt->settings->tos = tos; 612 } 613 614 void 615 iperf_set_test_extra_data(struct iperf_test *ipt, char *dat) 616 { 617 ipt->extra_data = strdup(dat); 618 } 619 620 void 621 iperf_set_test_bidirectional(struct iperf_test* ipt, int bidirectional) 622 { 623 ipt->bidirectional = bidirectional; 624 if (bidirectional) 625 ipt->mode = BIDIRECTIONAL; 626 else 627 iperf_set_test_reverse(ipt, ipt->reverse); 628 } 629 630 void 631 iperf_set_test_no_delay(struct iperf_test* ipt, int no_delay) 632 { 633 ipt->no_delay = no_delay; 634 } 635 636 void 637 iperf_set_test_connect_timeout(struct iperf_test* ipt, int ct) 638 { 639 ipt->settings->connect_timeout = ct; 640 } 641 642 643 /********************** Get/set test protocol structure ***********************/ 644 645 struct protocol * 646 get_protocol(struct iperf_test *test, int prot_id) 647 { 648 struct protocol *prot; 649 650 SLIST_FOREACH(prot, &test->protocols, protocols) { 651 if (prot->id == prot_id) 652 break; 653 } 654 655 if (prot == NULL) 656 i_errno = IEPROTOCOL; 657 658 return prot; 659 } 660 661 int 662 set_protocol(struct iperf_test *test, int prot_id) 663 { 664 struct protocol *prot = NULL; 665 666 SLIST_FOREACH(prot, &test->protocols, protocols) { 667 if (prot->id == prot_id) { 668 test->protocol = prot; 669 check_sender_has_retransmits(test); 670 return 0; 671 } 672 } 673 674 i_errno = IEPROTOCOL; 675 return -1; 676 } 677 678 679 /************************** Iperf callback functions **************************/ 680 681 void 682 iperf_on_new_stream(struct iperf_stream *sp) 683 { 684 connect_msg(sp); 685 } 686 687 void 688 iperf_on_test_start(struct iperf_test *test) 689 { 690 if (test->json_output) { 691 cJSON_AddItemToObject(test->json_start, "test_start", iperf_json_printf("protocol: %s num_streams: %d blksize: %d omit: %d duration: %d bytes: %d blocks: %d reverse: %d tos: %d", test->protocol->name, (int64_t) test->num_streams, (int64_t) test->settings->blksize, (int64_t) test->omit, (int64_t) test->duration, (int64_t) test->settings->bytes, (int64_t) test->settings->blocks, test->reverse?(int64_t)1:(int64_t)0, (int64_t) test->settings->tos)); 692 } else { 693 if (test->verbose) { 694 if (test->settings->bytes) 695 iperf_printf(test, test_start_bytes, test->protocol->name, test->num_streams, test->settings->blksize, test->omit, test->settings->bytes, test->settings->tos); 696 else if (test->settings->blocks) 697 iperf_printf(test, test_start_blocks, test->protocol->name, test->num_streams, test->settings->blksize, test->omit, test->settings->blocks, test->settings->tos); 698 else 699 iperf_printf(test, test_start_time, test->protocol->name, test->num_streams, test->settings->blksize, test->omit, test->duration, test->settings->tos); 700 } 701 } 702 } 703 704 /* This converts an IPv6 string address from IPv4-mapped format into regular 705 ** old IPv4 format, which is easier on the eyes of network veterans. 706 ** 707 ** If the v6 address is not v4-mapped it is left alone. 708 */ 709 static void 710 mapped_v4_to_regular_v4(char *str) 711 { 712 char *prefix = "::ffff:"; 713 int prefix_len; 714 715 prefix_len = strlen(prefix); 716 if (strncmp(str, prefix, prefix_len) == 0) { 717 int str_len = strlen(str); 718 memmove(str, str + prefix_len, str_len - prefix_len + 1); 719 } 720 } 721 722 void 723 iperf_on_connect(struct iperf_test *test) 724 { 725 time_t now_secs; 726 const char* rfc1123_fmt = "%a, %d %b %Y %H:%M:%S %Z"; 727 char now_str[100]; 728 char ipr[INET6_ADDRSTRLEN]; 729 int port; 730 struct sockaddr_storage sa; 731 struct sockaddr_in *sa_inP; 732 struct sockaddr_in6 *sa_in6P; 733 socklen_t len; 734 735 now_secs = time((time_t*) 0); 736 (void) strftime(now_str, sizeof(now_str), rfc1123_fmt, gmtime(&now_secs)); 737 if (test->json_output) 738 cJSON_AddItemToObject(test->json_start, "timestamp", iperf_json_printf("time: %s timesecs: %d", now_str, (int64_t) now_secs)); 739 else if (test->verbose) 740 iperf_printf(test, report_time, now_str); 741 742 if (test->role == 'c') { 743 if (test->json_output) 744 cJSON_AddItemToObject(test->json_start, "connecting_to", iperf_json_printf("host: %s port: %d", test->server_hostname, (int64_t) test->server_port)); 745 else { 746 iperf_printf(test, report_connecting, test->server_hostname, test->server_port); 747 if (test->reverse) 748 iperf_printf(test, report_reverse, test->server_hostname); 749 } 750 } else { 751 len = sizeof(sa); 752 getpeername(test->ctrl_sck, (struct sockaddr *) &sa, &len); 753 if (getsockdomain(test->ctrl_sck) == AF_INET) { 754 sa_inP = (struct sockaddr_in *) &sa; 755 inet_ntop(AF_INET, &sa_inP->sin_addr, ipr, sizeof(ipr)); 756 port = ntohs(sa_inP->sin_port); 757 } else { 758 sa_in6P = (struct sockaddr_in6 *) &sa; 759 inet_ntop(AF_INET6, &sa_in6P->sin6_addr, ipr, sizeof(ipr)); 760 port = ntohs(sa_in6P->sin6_port); 761 } 762 mapped_v4_to_regular_v4(ipr); 763 if (test->json_output) 764 cJSON_AddItemToObject(test->json_start, "accepted_connection", iperf_json_printf("host: %s port: %d", ipr, (int64_t) port)); 765 else 766 iperf_printf(test, report_accepted, ipr, port); 767 } 768 if (test->json_output) { 769 cJSON_AddStringToObject(test->json_start, "cookie", test->cookie); 770 if (test->protocol->id == SOCK_STREAM) { 771 if (test->settings->mss) 772 cJSON_AddNumberToObject(test->json_start, "tcp_mss", test->settings->mss); 773 else { 774 cJSON_AddNumberToObject(test->json_start, "tcp_mss_default", test->ctrl_sck_mss); 775 } 776 if (test->settings->rate) 777 cJSON_AddNumberToObject(test->json_start, "target_bitrate", test->settings->rate); 778 } 779 } else if (test->verbose) { 780 iperf_printf(test, report_cookie, test->cookie); 781 if (test->protocol->id == SOCK_STREAM) { 782 if (test->settings->mss) 783 iperf_printf(test, " TCP MSS: %d\n", test->settings->mss); 784 else { 785 iperf_printf(test, " TCP MSS: %d (default)\n", test->ctrl_sck_mss); 786 } 787 } 788 if (test->settings->rate) 789 iperf_printf(test, " Target Bitrate: %"PRIu64"\n", test->settings->rate); 790 } 791 } 792 793 void 794 iperf_on_test_finish(struct iperf_test *test) 795 { 796 } 797 798 799 /******************************************************************************/ 800 801 int 802 iperf_parse_arguments(struct iperf_test *test, int argc, char **argv) 803 { 804 static struct option longopts[] = 805 { 806 {"port", required_argument, NULL, 'p'}, 807 {"format", required_argument, NULL, 'f'}, 808 {"interval", required_argument, NULL, 'i'}, 809 {"daemon", no_argument, NULL, 'D'}, 810 {"one-off", no_argument, NULL, '1'}, 811 {"verbose", no_argument, NULL, 'V'}, 812 {"json", no_argument, NULL, 'J'}, 813 {"version", no_argument, NULL, 'v'}, 814 {"server", no_argument, NULL, 's'}, 815 {"client", required_argument, NULL, 'c'}, 816 {"udp", no_argument, NULL, 'u'}, 817 {"bitrate", required_argument, NULL, 'b'}, 818 {"bandwidth", required_argument, NULL, 'b'}, 819 {"time", required_argument, NULL, 't'}, 820 {"bytes", required_argument, NULL, 'n'}, 821 {"blockcount", required_argument, NULL, 'k'}, 822 {"length", required_argument, NULL, 'l'}, 823 {"parallel", required_argument, NULL, 'P'}, 824 {"reverse", no_argument, NULL, 'R'}, 825 {"bidir", no_argument, NULL, OPT_BIDIRECTIONAL}, 826 {"window", required_argument, NULL, 'w'}, 827 {"bind", required_argument, NULL, 'B'}, 828 {"cport", required_argument, NULL, OPT_CLIENT_PORT}, 829 {"set-mss", required_argument, NULL, 'M'}, 830 {"no-delay", no_argument, NULL, 'N'}, 831 {"version4", no_argument, NULL, '4'}, 832 {"version6", no_argument, NULL, '6'}, 833 {"tos", required_argument, NULL, 'S'}, 834 {"dscp", required_argument, NULL, OPT_DSCP}, 835 {"extra-data", required_argument, NULL, OPT_EXTRA_DATA}, 836 #if defined(HAVE_FLOWLABEL) 837 {"flowlabel", required_argument, NULL, 'L'}, 838 #endif /* HAVE_FLOWLABEL */ 839 {"zerocopy", no_argument, NULL, 'Z'}, 840 {"omit", required_argument, NULL, 'O'}, 841 {"file", required_argument, NULL, 'F'}, 842 {"repeating-payload", no_argument, NULL, OPT_REPEATING_PAYLOAD}, 843 #if defined(HAVE_CPU_AFFINITY) 844 {"affinity", required_argument, NULL, 'A'}, 845 #endif /* HAVE_CPU_AFFINITY */ 846 {"title", required_argument, NULL, 'T'}, 847 #if defined(HAVE_TCP_CONGESTION) 848 {"congestion", required_argument, NULL, 'C'}, 849 {"linux-congestion", required_argument, NULL, 'C'}, 850 #endif /* HAVE_TCP_CONGESTION */ 851 #if defined(HAVE_SCTP) 852 {"sctp", no_argument, NULL, OPT_SCTP}, 853 {"nstreams", required_argument, NULL, OPT_NUMSTREAMS}, 854 {"xbind", required_argument, NULL, 'X'}, 855 #endif 856 {"pidfile", required_argument, NULL, 'I'}, 857 {"logfile", required_argument, NULL, OPT_LOGFILE}, 858 {"forceflush", no_argument, NULL, OPT_FORCEFLUSH}, 859 {"get-server-output", no_argument, NULL, OPT_GET_SERVER_OUTPUT}, 860 {"udp-counters-64bit", no_argument, NULL, OPT_UDP_COUNTERS_64BIT}, 861 {"no-fq-socket-pacing", no_argument, NULL, OPT_NO_FQ_SOCKET_PACING}, 862 #if defined(HAVE_SSL) 863 {"username", required_argument, NULL, OPT_CLIENT_USERNAME}, 864 {"rsa-public-key-path", required_argument, NULL, OPT_CLIENT_RSA_PUBLIC_KEY}, 865 {"rsa-private-key-path", required_argument, NULL, OPT_SERVER_RSA_PRIVATE_KEY}, 866 {"authorized-users-path", required_argument, NULL, OPT_SERVER_AUTHORIZED_USERS}, 867 #endif /* HAVE_SSL */ 868 {"fq-rate", required_argument, NULL, OPT_FQ_RATE}, 869 {"pacing-timer", required_argument, NULL, OPT_PACING_TIMER}, 870 {"connect-timeout", required_argument, NULL, OPT_CONNECT_TIMEOUT}, 871 {"debug", no_argument, NULL, 'd'}, 872 {"help", no_argument, NULL, 'h'}, 873 {NULL, 0, NULL, 0} 874 }; 875 int flag; 876 int portno; 877 int blksize; 878 int server_flag, client_flag, rate_flag, duration_flag; 879 char *endptr; 880 #if defined(HAVE_CPU_AFFINITY) 881 char* comma; 882 #endif /* HAVE_CPU_AFFINITY */ 883 char* slash; 884 struct xbind_entry *xbe; 885 double farg; 886 887 blksize = 0; 888 server_flag = client_flag = rate_flag = duration_flag = 0; 889 #if defined(HAVE_SSL) 890 char *client_username = NULL, *client_rsa_public_key = NULL, *server_rsa_private_key = NULL; 891 #endif /* HAVE_SSL */ 892 893 while ((flag = getopt_long(argc, argv, "p:f:i:D1VJvsc:ub:t:n:k:l:P:Rw:B:M:N46S:L:ZO:F:A:T:C:dI:hX:", longopts, NULL)) != -1) { 894 switch (flag) { 895 case 'p': 896 portno = atoi(optarg); 897 if (portno < 1 || portno > 65535) { 898 i_errno = IEBADPORT; 899 return -1; 900 } 901 test->server_port = portno; 902 break; 903 case 'f': 904 if (!optarg) { 905 i_errno = IEBADFORMAT; 906 return -1; 907 } 908 test->settings->unit_format = *optarg; 909 if (test->settings->unit_format == 'k' || 910 test->settings->unit_format == 'K' || 911 test->settings->unit_format == 'm' || 912 test->settings->unit_format == 'M' || 913 test->settings->unit_format == 'g' || 914 test->settings->unit_format == 'G' || 915 test->settings->unit_format == 't' || 916 test->settings->unit_format == 'T') { 917 break; 918 } 919 else { 920 i_errno = IEBADFORMAT; 921 return -1; 922 } 923 break; 924 case 'i': 925 /* XXX: could potentially want separate stat collection and reporting intervals, 926 but just set them to be the same for now */ 927 test->stats_interval = test->reporter_interval = atof(optarg); 928 if ((test->stats_interval < MIN_INTERVAL || test->stats_interval > MAX_INTERVAL) && test->stats_interval != 0) { 929 i_errno = IEINTERVAL; 930 return -1; 931 } 932 break; 933 case 'D': 934 test->daemon = 1; 935 server_flag = 1; 936 break; 937 case '1': 938 test->one_off = 1; 939 server_flag = 1; 940 break; 941 case 'V': 942 test->verbose = 1; 943 break; 944 case 'J': 945 test->json_output = 1; 946 break; 947 case 'v': 948 printf("%s (cJSON %s)\n%s\n%s\n", version, cJSON_Version(), get_system_info(), 949 get_optional_features()); 950 exit(0); 951 case 's': 952 if (test->role == 'c') { 953 i_errno = IESERVCLIENT; 954 return -1; 955 } 956 iperf_set_test_role(test, 's'); 957 break; 958 case 'c': 959 if (test->role == 's') { 960 i_errno = IESERVCLIENT; 961 return -1; 962 } 963 iperf_set_test_role(test, 'c'); 964 iperf_set_test_server_hostname(test, optarg); 965 break; 966 case 'u': 967 set_protocol(test, Pudp); 968 client_flag = 1; 969 break; 970 case OPT_SCTP: 971 #if defined(HAVE_SCTP) 972 set_protocol(test, Psctp); 973 client_flag = 1; 974 break; 975 #else /* HAVE_SCTP */ 976 i_errno = IEUNIMP; 977 return -1; 978 #endif /* HAVE_SCTP */ 979 980 case OPT_NUMSTREAMS: 981 #if defined(linux) || defined(__FreeBSD__) 982 test->settings->num_ostreams = unit_atoi(optarg); 983 client_flag = 1; 984 #else /* linux */ 985 i_errno = IEUNIMP; 986 return -1; 987 #endif /* linux */ 988 case 'b': 989 slash = strchr(optarg, '/'); 990 if (slash) { 991 *slash = '\0'; 992 ++slash; 993 test->settings->burst = atoi(slash); 994 if (test->settings->burst <= 0 || 995 test->settings->burst > MAX_BURST) { 996 i_errno = IEBURST; 997 return -1; 998 } 999 } 1000 test->settings->rate = unit_atof_rate(optarg); 1001 rate_flag = 1; 1002 client_flag = 1; 1003 break; 1004 case 't': 1005 test->duration = atoi(optarg); 1006 if (test->duration > MAX_TIME) { 1007 i_errno = IEDURATION; 1008 return -1; 1009 } 1010 duration_flag = 1; 1011 client_flag = 1; 1012 break; 1013 case 'n': 1014 test->settings->bytes = unit_atoi(optarg); 1015 client_flag = 1; 1016 break; 1017 case 'k': 1018 test->settings->blocks = unit_atoi(optarg); 1019 client_flag = 1; 1020 break; 1021 case 'l': 1022 blksize = unit_atoi(optarg); 1023 client_flag = 1; 1024 break; 1025 case 'P': 1026 test->num_streams = atoi(optarg); 1027 if (test->num_streams > MAX_STREAMS) { 1028 i_errno = IENUMSTREAMS; 1029 return -1; 1030 } 1031 client_flag = 1; 1032 break; 1033 case 'R': 1034 if (test->bidirectional) { 1035 i_errno = IEREVERSEBIDIR; 1036 return -1; 1037 } 1038 iperf_set_test_reverse(test, 1); 1039 client_flag = 1; 1040 break; 1041 case OPT_BIDIRECTIONAL: 1042 if (test->reverse) { 1043 i_errno = IEREVERSEBIDIR; 1044 return -1; 1045 } 1046 iperf_set_test_bidirectional(test, 1); 1047 client_flag = 1; 1048 break; 1049 case 'w': 1050 // XXX: This is a socket buffer, not specific to TCP 1051 // Do sanity checks as double-precision floating point 1052 // to avoid possible integer overflows. 1053 farg = unit_atof(optarg); 1054 if (farg > (double) MAX_TCP_BUFFER) { 1055 i_errno = IEBUFSIZE; 1056 return -1; 1057 } 1058 test->settings->socket_bufsize = (int) farg; 1059 client_flag = 1; 1060 break; 1061 case 'B': 1062 test->bind_address = strdup(optarg); 1063 break; 1064 case OPT_CLIENT_PORT: 1065 portno = atoi(optarg); 1066 if (portno < 1 || portno > 65535) { 1067 i_errno = IEBADPORT; 1068 return -1; 1069 } 1070 test->bind_port = portno; 1071 break; 1072 case 'M': 1073 test->settings->mss = atoi(optarg); 1074 if (test->settings->mss > MAX_MSS) { 1075 i_errno = IEMSS; 1076 return -1; 1077 } 1078 client_flag = 1; 1079 break; 1080 case 'N': 1081 test->no_delay = 1; 1082 client_flag = 1; 1083 break; 1084 case '4': 1085 test->settings->domain = AF_INET; 1086 break; 1087 case '6': 1088 test->settings->domain = AF_INET6; 1089 break; 1090 case 'S': 1091 test->settings->tos = strtol(optarg, &endptr, 0); 1092 if (endptr == optarg || 1093 test->settings->tos < 0 || 1094 test->settings->tos > 255) { 1095 i_errno = IEBADTOS; 1096 return -1; 1097 } 1098 client_flag = 1; 1099 break; 1100 case OPT_DSCP: 1101 test->settings->tos = parse_qos(optarg); 1102 if(test->settings->tos < 0) { 1103 i_errno = IEBADTOS; 1104 return -1; 1105 } 1106 client_flag = 1; 1107 break; 1108 case OPT_EXTRA_DATA: 1109 test->extra_data = strdup(optarg); 1110 client_flag = 1; 1111 break; 1112 case 'L': 1113 #if defined(HAVE_FLOWLABEL) 1114 test->settings->flowlabel = strtol(optarg, &endptr, 0); 1115 if (endptr == optarg || 1116 test->settings->flowlabel < 1 || test->settings->flowlabel > 0xfffff) { 1117 i_errno = IESETFLOW; 1118 return -1; 1119 } 1120 client_flag = 1; 1121 #else /* HAVE_FLOWLABEL */ 1122 i_errno = IEUNIMP; 1123 return -1; 1124 #endif /* HAVE_FLOWLABEL */ 1125 break; 1126 case 'X': 1127 xbe = (struct xbind_entry *)malloc(sizeof(struct xbind_entry)); 1128 if (!xbe) { 1129 i_errno = IESETSCTPBINDX; 1130 return -1; 1131 } 1132 memset(xbe, 0, sizeof(*xbe)); 1133 xbe->name = strdup(optarg); 1134 if (!xbe->name) { 1135 i_errno = IESETSCTPBINDX; 1136 return -1; 1137 } 1138 TAILQ_INSERT_TAIL(&test->xbind_addrs, xbe, link); 1139 break; 1140 case 'Z': 1141 if (!has_sendfile()) { 1142 i_errno = IENOSENDFILE; 1143 return -1; 1144 } 1145 test->zerocopy = 1; 1146 client_flag = 1; 1147 break; 1148 case OPT_REPEATING_PAYLOAD: 1149 test->repeating_payload = 1; 1150 client_flag = 1; 1151 break; 1152 case 'O': 1153 test->omit = atoi(optarg); 1154 if (test->omit < 0 || test->omit > 60) { 1155 i_errno = IEOMIT; 1156 return -1; 1157 } 1158 client_flag = 1; 1159 break; 1160 case 'F': 1161 test->diskfile_name = optarg; 1162 break; 1163 case 'A': 1164 #if defined(HAVE_CPU_AFFINITY) 1165 test->affinity = strtol(optarg, &endptr, 0); 1166 if (endptr == optarg || 1167 test->affinity < 0 || test->affinity > 1024) { 1168 i_errno = IEAFFINITY; 1169 return -1; 1170 } 1171 comma = strchr(optarg, ','); 1172 if (comma != NULL) { 1173 test->server_affinity = atoi(comma+1); 1174 if (test->server_affinity < 0 || test->server_affinity > 1024) { 1175 i_errno = IEAFFINITY; 1176 return -1; 1177 } 1178 client_flag = 1; 1179 } 1180 #else /* HAVE_CPU_AFFINITY */ 1181 i_errno = IEUNIMP; 1182 return -1; 1183 #endif /* HAVE_CPU_AFFINITY */ 1184 break; 1185 case 'T': 1186 test->title = strdup(optarg); 1187 client_flag = 1; 1188 break; 1189 case 'C': 1190 #if defined(HAVE_TCP_CONGESTION) 1191 test->congestion = strdup(optarg); 1192 client_flag = 1; 1193 #else /* HAVE_TCP_CONGESTION */ 1194 i_errno = IEUNIMP; 1195 return -1; 1196 #endif /* HAVE_TCP_CONGESTION */ 1197 break; 1198 case 'd': 1199 test->debug = 1; 1200 break; 1201 case 'I': 1202 test->pidfile = strdup(optarg); 1203 server_flag = 1; 1204 break; 1205 case OPT_LOGFILE: 1206 test->logfile = strdup(optarg); 1207 break; 1208 case OPT_FORCEFLUSH: 1209 test->forceflush = 1; 1210 break; 1211 case OPT_GET_SERVER_OUTPUT: 1212 test->get_server_output = 1; 1213 client_flag = 1; 1214 break; 1215 case OPT_UDP_COUNTERS_64BIT: 1216 test->udp_counters_64bit = 1; 1217 break; 1218 case OPT_NO_FQ_SOCKET_PACING: 1219 #if defined(HAVE_SO_MAX_PACING_RATE) 1220 printf("Warning: --no-fq-socket-pacing is deprecated\n"); 1221 test->settings->fqrate = 0; 1222 client_flag = 1; 1223 #else /* HAVE_SO_MAX_PACING_RATE */ 1224 i_errno = IEUNIMP; 1225 return -1; 1226 #endif 1227 break; 1228 case OPT_FQ_RATE: 1229 #if defined(HAVE_SO_MAX_PACING_RATE) 1230 test->settings->fqrate = unit_atof_rate(optarg); 1231 client_flag = 1; 1232 #else /* HAVE_SO_MAX_PACING_RATE */ 1233 i_errno = IEUNIMP; 1234 return -1; 1235 #endif 1236 break; 1237 #if defined(HAVE_SSL) 1238 case OPT_CLIENT_USERNAME: 1239 client_username = strdup(optarg); 1240 break; 1241 case OPT_CLIENT_RSA_PUBLIC_KEY: 1242 client_rsa_public_key = strdup(optarg); 1243 break; 1244 case OPT_SERVER_RSA_PRIVATE_KEY: 1245 server_rsa_private_key = strdup(optarg); 1246 break; 1247 case OPT_SERVER_AUTHORIZED_USERS: 1248 test->server_authorized_users = strdup(optarg); 1249 break; 1250 #endif /* HAVE_SSL */ 1251 case OPT_PACING_TIMER: 1252 test->settings->pacing_timer = unit_atoi(optarg); 1253 client_flag = 1; 1254 break; 1255 case OPT_CONNECT_TIMEOUT: 1256 test->settings->connect_timeout = unit_atoi(optarg); 1257 client_flag = 1; 1258 break; 1259 case 'h': 1260 usage_long(stdout); 1261 exit(0); 1262 default: 1263 usage_long(stderr); 1264 exit(1); 1265 } 1266 } 1267 1268 /* Check flag / role compatibility. */ 1269 if (test->role == 'c' && server_flag) { 1270 i_errno = IESERVERONLY; 1271 return -1; 1272 } 1273 if (test->role == 's' && client_flag) { 1274 i_errno = IECLIENTONLY; 1275 return -1; 1276 } 1277 1278 #if defined(HAVE_SSL) 1279 1280 if (test->role == 's' && (client_username || client_rsa_public_key)){ 1281 i_errno = IECLIENTONLY; 1282 return -1; 1283 } else if (test->role == 'c' && (client_username || client_rsa_public_key) && 1284 !(client_username && client_rsa_public_key)) { 1285 i_errno = IESETCLIENTAUTH; 1286 return -1; 1287 } else if (test->role == 'c' && (client_username && client_rsa_public_key)){ 1288 1289 char *client_password = NULL; 1290 size_t s; 1291 /* Need to copy env var, so we can do a common free */ 1292 if ((client_password = getenv("IPERF3_PASSWORD")) != NULL) 1293 client_password = strdup(client_password); 1294 else if (iperf_getpass(&client_password, &s, stdin) < 0){ 1295 return -1; 1296 } 1297 if (test_load_pubkey_from_file(client_rsa_public_key) < 0){ 1298 i_errno = IESETCLIENTAUTH; 1299 return -1; 1300 } 1301 1302 test->settings->client_username = client_username; 1303 test->settings->client_password = client_password; 1304 test->settings->client_rsa_pubkey = load_pubkey_from_file(client_rsa_public_key); 1305 free(client_rsa_public_key); 1306 client_rsa_public_key = NULL; 1307 } 1308 1309 if (test->role == 'c' && (server_rsa_private_key || test->server_authorized_users)){ 1310 i_errno = IESERVERONLY; 1311 return -1; 1312 } else if (test->role == 's' && (server_rsa_private_key || test->server_authorized_users) && 1313 !(server_rsa_private_key && test->server_authorized_users)) { 1314 i_errno = IESETSERVERAUTH; 1315 return -1; 1316 } else if (test->role == 's' && server_rsa_private_key) { 1317 test->server_rsa_private_key = load_privkey_from_file(server_rsa_private_key); 1318 if (test->server_rsa_private_key == NULL){ 1319 i_errno = IESETSERVERAUTH; 1320 return -1; 1321 } 1322 free(server_rsa_private_key); 1323 server_rsa_private_key = NULL; 1324 } 1325 1326 #endif //HAVE_SSL 1327 if (blksize == 0) { 1328 if (test->protocol->id == Pudp) 1329 blksize = 0; /* try to dynamically determine from MSS */ 1330 else if (test->protocol->id == Psctp) 1331 blksize = DEFAULT_SCTP_BLKSIZE; 1332 else 1333 blksize = DEFAULT_TCP_BLKSIZE; 1334 } 1335 if ((test->protocol->id != Pudp && blksize <= 0) 1336 || blksize > MAX_BLOCKSIZE) { 1337 i_errno = IEBLOCKSIZE; 1338 return -1; 1339 } 1340 if (test->protocol->id == Pudp && 1341 (blksize > 0 && 1342 (blksize < MIN_UDP_BLOCKSIZE || blksize > MAX_UDP_BLOCKSIZE))) { 1343 i_errno = IEUDPBLOCKSIZE; 1344 return -1; 1345 } 1346 test->settings->blksize = blksize; 1347 1348 if (!rate_flag) 1349 test->settings->rate = test->protocol->id == Pudp ? UDP_RATE : 0; 1350 1351 if ((test->settings->bytes != 0 || test->settings->blocks != 0) && ! duration_flag) 1352 test->duration = 0; 1353 1354 /* Disallow specifying multiple test end conditions. The code actually 1355 ** works just fine without this prohibition. As soon as any one of the 1356 ** three possible end conditions is met, the test ends. So this check 1357 ** could be removed if desired. 1358 */ 1359 if ((duration_flag && test->settings->bytes != 0) || 1360 (duration_flag && test->settings->blocks != 0) || 1361 (test->settings->bytes != 0 && test->settings->blocks != 0)) { 1362 i_errno = IEENDCONDITIONS; 1363 return -1; 1364 } 1365 1366 /* For subsequent calls to getopt */ 1367 #ifdef __APPLE__ 1368 optreset = 1; 1369 #endif 1370 optind = 0; 1371 1372 if ((test->role != 'c') && (test->role != 's')) { 1373 i_errno = IENOROLE; 1374 return -1; 1375 } 1376 1377 /* Show warning if JSON output is used with explicit report format */ 1378 if ((test->json_output) && (test->settings->unit_format != 'a')) { 1379 warning("Report format (-f) flag ignored with JSON output (-J)"); 1380 } 1381 1382 /* Show warning if JSON output is used with verbose or debug flags */ 1383 if (test->json_output && test->verbose) { 1384 warning("Verbose output (-v) may interfere with JSON output (-J)"); 1385 } 1386 if (test->json_output && test->debug) { 1387 warning("Debug output (-d) may interfere with JSON output (-J)"); 1388 } 1389 1390 return 0; 1391 } 1392 1393 /* 1394 * Open the file specified by test->logfile and set test->outfile to its' FD. 1395 */ 1396 int iperf_open_logfile(struct iperf_test *test) 1397 { 1398 test->outfile = fopen(test->logfile, "a+"); 1399 if (test->outfile == NULL) { 1400 i_errno = IELOGFILE; 1401 return -1; 1402 } 1403 1404 return 0; 1405 } 1406 1407 int 1408 iperf_set_send_state(struct iperf_test *test, signed char state) 1409 { 1410 test->state = state; 1411 if (Nwrite(test->ctrl_sck, (char*) &state, sizeof(state), Ptcp) < 0) { 1412 i_errno = IESENDMESSAGE; 1413 return -1; 1414 } 1415 return 0; 1416 } 1417 1418 void 1419 iperf_check_throttle(struct iperf_stream *sp, struct iperf_time *nowP) 1420 { 1421 struct iperf_time temp_time; 1422 double seconds; 1423 uint64_t bits_per_second; 1424 1425 if (sp->test->done || sp->test->settings->rate == 0 || sp->test->settings->burst != 0) 1426 return; 1427 iperf_time_diff(&sp->result->start_time_fixed, nowP, &temp_time); 1428 seconds = iperf_time_in_secs(&temp_time); 1429 bits_per_second = sp->result->bytes_sent * 8 / seconds; 1430 if (bits_per_second < sp->test->settings->rate) { 1431 sp->green_light = 1; 1432 FD_SET(sp->socket, &sp->test->write_set); 1433 } else { 1434 sp->green_light = 0; 1435 FD_CLR(sp->socket, &sp->test->write_set); 1436 } 1437 } 1438 1439 int 1440 iperf_send(struct iperf_test *test, fd_set *write_setP) 1441 { 1442 register int multisend, r, streams_active; 1443 register struct iperf_stream *sp; 1444 struct iperf_time now; 1445 1446 /* Can we do multisend mode? */ 1447 if (test->settings->burst != 0) 1448 multisend = test->settings->burst; 1449 else if (test->settings->rate == 0) 1450 multisend = test->multisend; 1451 else 1452 multisend = 1; /* nope */ 1453 1454 for (; multisend > 0; --multisend) { 1455 if (test->settings->rate != 0 && test->settings->burst == 0) 1456 iperf_time_now(&now); 1457 streams_active = 0; 1458 SLIST_FOREACH(sp, &test->streams, streams) { 1459 if ((sp->green_light && sp->sender && 1460 (write_setP == NULL || FD_ISSET(sp->socket, write_setP)))) { 1461 if ((r = sp->snd(sp)) < 0) { 1462 if (r == NET_SOFTERROR) 1463 break; 1464 i_errno = IESTREAMWRITE; 1465 return r; 1466 } 1467 streams_active = 1; 1468 test->bytes_sent += r; 1469 ++test->blocks_sent; 1470 iperf_check_throttle(sp, &now); 1471 if (multisend > 1 && test->settings->bytes != 0 && test->bytes_sent >= test->settings->bytes) 1472 break; 1473 if (multisend > 1 && test->settings->blocks != 0 && test->blocks_sent >= test->settings->blocks) 1474 break; 1475 } 1476 } 1477 if (!streams_active) 1478 break; 1479 } 1480 if (test->settings->burst != 0) { 1481 iperf_time_now(&now); 1482 SLIST_FOREACH(sp, &test->streams, streams) 1483 iperf_check_throttle(sp, &now); 1484 } 1485 if (write_setP != NULL) 1486 SLIST_FOREACH(sp, &test->streams, streams) 1487 if (FD_ISSET(sp->socket, write_setP)) 1488 FD_CLR(sp->socket, write_setP); 1489 1490 return 0; 1491 } 1492 1493 int 1494 iperf_recv(struct iperf_test *test, fd_set *read_setP) 1495 { 1496 int r; 1497 struct iperf_stream *sp; 1498 1499 SLIST_FOREACH(sp, &test->streams, streams) { 1500 if (FD_ISSET(sp->socket, read_setP) && !sp->sender) { 1501 if ((r = sp->rcv(sp)) < 0) { 1502 i_errno = IESTREAMREAD; 1503 return r; 1504 } 1505 test->bytes_received += r; 1506 ++test->blocks_received; 1507 FD_CLR(sp->socket, read_setP); 1508 } 1509 } 1510 1511 return 0; 1512 } 1513 1514 int 1515 iperf_init_test(struct iperf_test *test) 1516 { 1517 struct iperf_time now; 1518 struct iperf_stream *sp; 1519 1520 if (test->protocol->init) { 1521 if (test->protocol->init(test) < 0) 1522 return -1; 1523 } 1524 1525 /* Init each stream. */ 1526 if (iperf_time_now(&now) < 0) { 1527 i_errno = IEINITTEST; 1528 return -1; 1529 } 1530 SLIST_FOREACH(sp, &test->streams, streams) { 1531 sp->result->start_time = sp->result->start_time_fixed = now; 1532 } 1533 1534 if (test->on_test_start) 1535 test->on_test_start(test); 1536 1537 return 0; 1538 } 1539 1540 static void 1541 send_timer_proc(TimerClientData client_data, struct iperf_time *nowP) 1542 { 1543 struct iperf_stream *sp = client_data.p; 1544 1545 /* All we do here is set or clear the flag saying that this stream may 1546 ** be sent to. The actual sending gets done in the send proc, after 1547 ** checking the flag. 1548 */ 1549 iperf_check_throttle(sp, nowP); 1550 } 1551 1552 int 1553 iperf_create_send_timers(struct iperf_test * test) 1554 { 1555 struct iperf_time now; 1556 struct iperf_stream *sp; 1557 TimerClientData cd; 1558 1559 if (iperf_time_now(&now) < 0) { 1560 i_errno = IEINITTEST; 1561 return -1; 1562 } 1563 SLIST_FOREACH(sp, &test->streams, streams) { 1564 sp->green_light = 1; 1565 if (test->settings->rate != 0) { 1566 cd.p = sp; 1567 sp->send_timer = tmr_create(NULL, send_timer_proc, cd, test->settings->pacing_timer, 1); 1568 if (sp->send_timer == NULL) { 1569 i_errno = IEINITTEST; 1570 return -1; 1571 } 1572 } 1573 } 1574 return 0; 1575 } 1576 1577 #if defined(HAVE_SSL) 1578 int test_is_authorized(struct iperf_test *test){ 1579 if ( !(test->server_rsa_private_key && test->server_authorized_users)) { 1580 return 0; 1581 } 1582 1583 if (test->settings->authtoken){ 1584 char *username = NULL, *password = NULL; 1585 time_t ts; 1586 int rc = decode_auth_setting(test->debug, test->settings->authtoken, test->server_rsa_private_key, &username, &password, &ts); 1587 if (rc) { 1588 return -1; 1589 } 1590 int ret = check_authentication(username, password, ts, test->server_authorized_users); 1591 if (ret == 0){ 1592 iperf_printf(test, report_authentication_succeeded, username, ts); 1593 free(username); 1594 free(password); 1595 return 0; 1596 } else { 1597 iperf_printf(test, report_authentication_failed, username, ts); 1598 free(username); 1599 free(password); 1600 return -1; 1601 } 1602 } 1603 return -1; 1604 } 1605 #endif //HAVE_SSL 1606 1607 /** 1608 * iperf_exchange_parameters - handles the param_Exchange part for client 1609 * 1610 */ 1611 1612 int 1613 iperf_exchange_parameters(struct iperf_test *test) 1614 { 1615 int s; 1616 int32_t err; 1617 1618 if (test->role == 'c') { 1619 1620 if (send_parameters(test) < 0) 1621 return -1; 1622 1623 } else { 1624 1625 if (get_parameters(test) < 0) 1626 return -1; 1627 1628 #if defined(HAVE_SSL) 1629 if (test_is_authorized(test) < 0){ 1630 if (iperf_set_send_state(test, SERVER_ERROR) != 0) 1631 return -1; 1632 i_errno = IEAUTHTEST; 1633 err = htonl(i_errno); 1634 if (Nwrite(test->ctrl_sck, (char*) &err, sizeof(err), Ptcp) < 0) { 1635 i_errno = IECTRLWRITE; 1636 return -1; 1637 } 1638 return -1; 1639 } 1640 #endif //HAVE_SSL 1641 1642 if ((s = test->protocol->listen(test)) < 0) { 1643 if (iperf_set_send_state(test, SERVER_ERROR) != 0) 1644 return -1; 1645 err = htonl(i_errno); 1646 if (Nwrite(test->ctrl_sck, (char*) &err, sizeof(err), Ptcp) < 0) { 1647 i_errno = IECTRLWRITE; 1648 return -1; 1649 } 1650 err = htonl(errno); 1651 if (Nwrite(test->ctrl_sck, (char*) &err, sizeof(err), Ptcp) < 0) { 1652 i_errno = IECTRLWRITE; 1653 return -1; 1654 } 1655 return -1; 1656 } 1657 FD_SET(s, &test->read_set); 1658 test->max_fd = (s > test->max_fd) ? s : test->max_fd; 1659 test->prot_listener = s; 1660 1661 // Send the control message to create streams and start the test 1662 if (iperf_set_send_state(test, CREATE_STREAMS) != 0) 1663 return -1; 1664 1665 } 1666 1667 return 0; 1668 } 1669 1670 /*************************************************************/ 1671 1672 int 1673 iperf_exchange_results(struct iperf_test *test) 1674 { 1675 if (test->role == 'c') { 1676 /* Send results to server. */ 1677 if (send_results(test) < 0) 1678 return -1; 1679 /* Get server results. */ 1680 if (get_results(test) < 0) 1681 return -1; 1682 } else { 1683 /* Get client results. */ 1684 if (get_results(test) < 0) 1685 return -1; 1686 /* Send results to client. */ 1687 if (send_results(test) < 0) 1688 return -1; 1689 } 1690 return 0; 1691 } 1692 1693 /*************************************************************/ 1694 1695 static int 1696 send_parameters(struct iperf_test *test) 1697 { 1698 int r = 0; 1699 cJSON *j; 1700 1701 j = cJSON_CreateObject(); 1702 if (j == NULL) { 1703 i_errno = IESENDPARAMS; 1704 r = -1; 1705 } else { 1706 if (test->protocol->id == Ptcp) 1707 cJSON_AddTrueToObject(j, "tcp"); 1708 else if (test->protocol->id == Pudp) 1709 cJSON_AddTrueToObject(j, "udp"); 1710 else if (test->protocol->id == Psctp) 1711 cJSON_AddTrueToObject(j, "sctp"); 1712 cJSON_AddNumberToObject(j, "omit", test->omit); 1713 if (test->server_affinity != -1) 1714 cJSON_AddNumberToObject(j, "server_affinity", test->server_affinity); 1715 cJSON_AddNumberToObject(j, "time", test->duration); 1716 if (test->settings->bytes) 1717 cJSON_AddNumberToObject(j, "num", test->settings->bytes); 1718 if (test->settings->blocks) 1719 cJSON_AddNumberToObject(j, "blockcount", test->settings->blocks); 1720 if (test->settings->mss) 1721 cJSON_AddNumberToObject(j, "MSS", test->settings->mss); 1722 if (test->no_delay) 1723 cJSON_AddTrueToObject(j, "nodelay"); 1724 cJSON_AddNumberToObject(j, "parallel", test->num_streams); 1725 if (test->reverse) 1726 cJSON_AddTrueToObject(j, "reverse"); 1727 if (test->bidirectional) 1728 cJSON_AddTrueToObject(j, "bidirectional"); 1729 if (test->settings->socket_bufsize) 1730 cJSON_AddNumberToObject(j, "window", test->settings->socket_bufsize); 1731 if (test->settings->blksize) 1732 cJSON_AddNumberToObject(j, "len", test->settings->blksize); 1733 if (test->settings->rate) 1734 cJSON_AddNumberToObject(j, "bandwidth", test->settings->rate); 1735 if (test->settings->fqrate) 1736 cJSON_AddNumberToObject(j, "fqrate", test->settings->fqrate); 1737 if (test->settings->pacing_timer) 1738 cJSON_AddNumberToObject(j, "pacing_timer", test->settings->pacing_timer); 1739 if (test->settings->burst) 1740 cJSON_AddNumberToObject(j, "burst", test->settings->burst); 1741 if (test->settings->tos) 1742 cJSON_AddNumberToObject(j, "TOS", test->settings->tos); 1743 if (test->settings->flowlabel) 1744 cJSON_AddNumberToObject(j, "flowlabel", test->settings->flowlabel); 1745 if (test->title) 1746 cJSON_AddStringToObject(j, "title", test->title); 1747 if (test->extra_data) 1748 cJSON_AddStringToObject(j, "extra_data", test->extra_data); 1749 if (test->congestion) 1750 cJSON_AddStringToObject(j, "congestion", test->congestion); 1751 if (test->congestion_used) 1752 cJSON_AddStringToObject(j, "congestion_used", test->congestion_used); 1753 if (test->get_server_output) 1754 cJSON_AddNumberToObject(j, "get_server_output", iperf_get_test_get_server_output(test)); 1755 if (test->udp_counters_64bit) 1756 cJSON_AddNumberToObject(j, "udp_counters_64bit", iperf_get_test_udp_counters_64bit(test)); 1757 if (test->repeating_payload) 1758 cJSON_AddNumberToObject(j, "repeating_payload", test->repeating_payload); 1759 #if defined(HAVE_SSL) 1760 /* Send authentication parameters */ 1761 if (test->settings->client_username && test->settings->client_password && test->settings->client_rsa_pubkey){ 1762 int rc = encode_auth_setting(test->settings->client_username, test->settings->client_password, test->settings->client_rsa_pubkey, &test->settings->authtoken); 1763 1764 if (rc) { 1765 cJSON_Delete(j); 1766 i_errno = IESENDPARAMS; 1767 return -1; 1768 } 1769 1770 cJSON_AddStringToObject(j, "authtoken", test->settings->authtoken); 1771 } 1772 #endif // HAVE_SSL 1773 cJSON_AddStringToObject(j, "client_version", IPERF_VERSION); 1774 1775 if (test->debug) { 1776 char *str = cJSON_Print(j); 1777 printf("send_parameters:\n%s\n", str); 1778 cJSON_free(str); 1779 } 1780 1781 if (JSON_write(test->ctrl_sck, j) < 0) { 1782 i_errno = IESENDPARAMS; 1783 r = -1; 1784 } 1785 cJSON_Delete(j); 1786 } 1787 return r; 1788 } 1789 1790 /*************************************************************/ 1791 1792 static int 1793 get_parameters(struct iperf_test *test) 1794 { 1795 int r = 0; 1796 cJSON *j; 1797 cJSON *j_p; 1798 1799 j = JSON_read(test->ctrl_sck); 1800 if (j == NULL) { 1801 i_errno = IERECVPARAMS; 1802 r = -1; 1803 } else { 1804 if (test->debug) { 1805 char *str; 1806 str = cJSON_Print(j); 1807 printf("get_parameters:\n%s\n", str ); 1808 cJSON_free(str); 1809 } 1810 1811 if ((j_p = cJSON_GetObjectItem(j, "tcp")) != NULL) 1812 set_protocol(test, Ptcp); 1813 if ((j_p = cJSON_GetObjectItem(j, "udp")) != NULL) 1814 set_protocol(test, Pudp); 1815 if ((j_p = cJSON_GetObjectItem(j, "sctp")) != NULL) 1816 set_protocol(test, Psctp); 1817 if ((j_p = cJSON_GetObjectItem(j, "omit")) != NULL) 1818 test->omit = j_p->valueint; 1819 if ((j_p = cJSON_GetObjectItem(j, "server_affinity")) != NULL) 1820 test->server_affinity = j_p->valueint; 1821 if ((j_p = cJSON_GetObjectItem(j, "time")) != NULL) 1822 test->duration = j_p->valueint; 1823 if ((j_p = cJSON_GetObjectItem(j, "num")) != NULL) 1824 test->settings->bytes = j_p->valueint; 1825 if ((j_p = cJSON_GetObjectItem(j, "blockcount")) != NULL) 1826 test->settings->blocks = j_p->valueint; 1827 if ((j_p = cJSON_GetObjectItem(j, "MSS")) != NULL) 1828 test->settings->mss = j_p->valueint; 1829 if ((j_p = cJSON_GetObjectItem(j, "nodelay")) != NULL) 1830 test->no_delay = 1; 1831 if ((j_p = cJSON_GetObjectItem(j, "parallel")) != NULL) 1832 test->num_streams = j_p->valueint; 1833 if ((j_p = cJSON_GetObjectItem(j, "reverse")) != NULL) 1834 iperf_set_test_reverse(test, 1); 1835 if ((j_p = cJSON_GetObjectItem(j, "bidirectional")) != NULL) 1836 iperf_set_test_bidirectional(test, 1); 1837 if ((j_p = cJSON_GetObjectItem(j, "window")) != NULL) 1838 test->settings->socket_bufsize = j_p->valueint; 1839 if ((j_p = cJSON_GetObjectItem(j, "len")) != NULL) 1840 test->settings->blksize = j_p->valueint; 1841 if ((j_p = cJSON_GetObjectItem(j, "bandwidth")) != NULL) 1842 test->settings->rate = j_p->valueint; 1843 if ((j_p = cJSON_GetObjectItem(j, "fqrate")) != NULL) 1844 test->settings->fqrate = j_p->valueint; 1845 if ((j_p = cJSON_GetObjectItem(j, "pacing_timer")) != NULL) 1846 test->settings->pacing_timer = j_p->valueint; 1847 if ((j_p = cJSON_GetObjectItem(j, "burst")) != NULL) 1848 test->settings->burst = j_p->valueint; 1849 if ((j_p = cJSON_GetObjectItem(j, "TOS")) != NULL) 1850 test->settings->tos = j_p->valueint; 1851 if ((j_p = cJSON_GetObjectItem(j, "flowlabel")) != NULL) 1852 test->settings->flowlabel = j_p->valueint; 1853 if ((j_p = cJSON_GetObjectItem(j, "title")) != NULL) 1854 test->title = strdup(j_p->valuestring); 1855 if ((j_p = cJSON_GetObjectItem(j, "extra_data")) != NULL) 1856 test->extra_data = strdup(j_p->valuestring); 1857 if ((j_p = cJSON_GetObjectItem(j, "congestion")) != NULL) 1858 test->congestion = strdup(j_p->valuestring); 1859 if ((j_p = cJSON_GetObjectItem(j, "congestion_used")) != NULL) 1860 test->congestion_used = strdup(j_p->valuestring); 1861 if ((j_p = cJSON_GetObjectItem(j, "get_server_output")) != NULL) 1862 iperf_set_test_get_server_output(test, 1); 1863 if ((j_p = cJSON_GetObjectItem(j, "udp_counters_64bit")) != NULL) 1864 iperf_set_test_udp_counters_64bit(test, 1); 1865 if ((j_p = cJSON_GetObjectItem(j, "repeating_payload")) != NULL) 1866 test->repeating_payload = 1; 1867 #if defined(HAVE_SSL) 1868 if ((j_p = cJSON_GetObjectItem(j, "authtoken")) != NULL) 1869 test->settings->authtoken = strdup(j_p->valuestring); 1870 #endif //HAVE_SSL 1871 if (test->mode && test->protocol->id == Ptcp && has_tcpinfo_retransmits()) 1872 test->sender_has_retransmits = 1; 1873 if (test->settings->rate) 1874 cJSON_AddNumberToObject(test->json_start, "target_bitrate", test->settings->rate); 1875 cJSON_Delete(j); 1876 } 1877 return r; 1878 } 1879 1880 /*************************************************************/ 1881 1882 static int 1883 send_results(struct iperf_test *test) 1884 { 1885 int r = 0; 1886 cJSON *j; 1887 cJSON *j_streams; 1888 struct iperf_stream *sp; 1889 cJSON *j_stream; 1890 int sender_has_retransmits; 1891 iperf_size_t bytes_transferred; 1892 int retransmits; 1893 struct iperf_time temp_time; 1894 double start_time, end_time; 1895 1896 j = cJSON_CreateObject(); 1897 if (j == NULL) { 1898 i_errno = IEPACKAGERESULTS; 1899 r = -1; 1900 } else { 1901 cJSON_AddNumberToObject(j, "cpu_util_total", test->cpu_util[0]); 1902 cJSON_AddNumberToObject(j, "cpu_util_user", test->cpu_util[1]); 1903 cJSON_AddNumberToObject(j, "cpu_util_system", test->cpu_util[2]); 1904 if ( test->mode == RECEIVER ) 1905 sender_has_retransmits = -1; 1906 else 1907 sender_has_retransmits = test->sender_has_retransmits; 1908 cJSON_AddNumberToObject(j, "sender_has_retransmits", sender_has_retransmits); 1909 if ( test->congestion_used ) { 1910 cJSON_AddStringToObject(j, "congestion_used", test->congestion_used); 1911 } 1912 1913 /* If on the server and sending server output, then do this */ 1914 if (test->role == 's' && test->get_server_output) { 1915 if (test->json_output) { 1916 /* Add JSON output */ 1917 cJSON_AddItemReferenceToObject(j, "server_output_json", test->json_top); 1918 } 1919 else { 1920 /* Add textual output */ 1921 size_t buflen = 0; 1922 1923 /* Figure out how much room we need to hold the complete output string */ 1924 struct iperf_textline *t; 1925 TAILQ_FOREACH(t, &(test->server_output_list), textlineentries) { 1926 buflen += strlen(t->line); 1927 } 1928 1929 /* Allocate and build it up from the component lines */ 1930 char *output = calloc(buflen + 1, 1); 1931 TAILQ_FOREACH(t, &(test->server_output_list), textlineentries) { 1932 strncat(output, t->line, buflen); 1933 buflen -= strlen(t->line); 1934 } 1935 1936 cJSON_AddStringToObject(j, "server_output_text", output); 1937 free(output); 1938 } 1939 } 1940 1941 j_streams = cJSON_CreateArray(); 1942 if (j_streams == NULL) { 1943 i_errno = IEPACKAGERESULTS; 1944 r = -1; 1945 } else { 1946 cJSON_AddItemToObject(j, "streams", j_streams); 1947 SLIST_FOREACH(sp, &test->streams, streams) { 1948 j_stream = cJSON_CreateObject(); 1949 if (j_stream == NULL) { 1950 i_errno = IEPACKAGERESULTS; 1951 r = -1; 1952 } else { 1953 cJSON_AddItemToArray(j_streams, j_stream); 1954 bytes_transferred = sp->sender ? (sp->result->bytes_sent - sp->result->bytes_sent_omit) : sp->result->bytes_received; 1955 retransmits = (sp->sender && test->sender_has_retransmits) ? sp->result->stream_retrans : -1; 1956 cJSON_AddNumberToObject(j_stream, "id", sp->id); 1957 cJSON_AddNumberToObject(j_stream, "bytes", bytes_transferred); 1958 cJSON_AddNumberToObject(j_stream, "retransmits", retransmits); 1959 cJSON_AddNumberToObject(j_stream, "jitter", sp->jitter); 1960 cJSON_AddNumberToObject(j_stream, "errors", sp->cnt_error); 1961 cJSON_AddNumberToObject(j_stream, "packets", sp->packet_count); 1962 1963 iperf_time_diff(&sp->result->start_time, &sp->result->start_time, &temp_time); 1964 start_time = iperf_time_in_secs(&temp_time); 1965 iperf_time_diff(&sp->result->start_time, &sp->result->end_time, &temp_time); 1966 end_time = iperf_time_in_secs(&temp_time); 1967 cJSON_AddNumberToObject(j_stream, "start_time", start_time); 1968 cJSON_AddNumberToObject(j_stream, "end_time", end_time); 1969 1970 } 1971 } 1972 if (r == 0 && test->debug) { 1973 char *str = cJSON_Print(j); 1974 printf("send_results\n%s\n", str); 1975 cJSON_free(str); 1976 } 1977 if (r == 0 && JSON_write(test->ctrl_sck, j) < 0) { 1978 i_errno = IESENDRESULTS; 1979 r = -1; 1980 } 1981 } 1982 cJSON_Delete(j); 1983 } 1984 return r; 1985 } 1986 1987 /*************************************************************/ 1988 1989 static int 1990 get_results(struct iperf_test *test) 1991 { 1992 int r = 0; 1993 cJSON *j; 1994 cJSON *j_cpu_util_total; 1995 cJSON *j_cpu_util_user; 1996 cJSON *j_cpu_util_system; 1997 cJSON *j_remote_congestion_used; 1998 cJSON *j_sender_has_retransmits; 1999 int result_has_retransmits; 2000 cJSON *j_streams; 2001 int n, i; 2002 cJSON *j_stream; 2003 cJSON *j_id; 2004 cJSON *j_bytes; 2005 cJSON *j_retransmits; 2006 cJSON *j_jitter; 2007 cJSON *j_errors; 2008 cJSON *j_packets; 2009 cJSON *j_server_output; 2010 cJSON *j_start_time, *j_end_time; 2011 int sid, cerror, pcount; 2012 double jitter; 2013 iperf_size_t bytes_transferred; 2014 int retransmits; 2015 struct iperf_stream *sp; 2016 2017 j = JSON_read(test->ctrl_sck); 2018 if (j == NULL) { 2019 i_errno = IERECVRESULTS; 2020 r = -1; 2021 } else { 2022 j_cpu_util_total = cJSON_GetObjectItem(j, "cpu_util_total"); 2023 j_cpu_util_user = cJSON_GetObjectItem(j, "cpu_util_user"); 2024 j_cpu_util_system = cJSON_GetObjectItem(j, "cpu_util_system"); 2025 j_sender_has_retransmits = cJSON_GetObjectItem(j, "sender_has_retransmits"); 2026 if (j_cpu_util_total == NULL || j_cpu_util_user == NULL || j_cpu_util_system == NULL || j_sender_has_retransmits == NULL) { 2027 i_errno = IERECVRESULTS; 2028 r = -1; 2029 } else { 2030 if (test->debug) { 2031 char *str = cJSON_Print(j); 2032 printf("get_results\n%s\n", str); 2033 cJSON_free(str); 2034 } 2035 2036 test->remote_cpu_util[0] = j_cpu_util_total->valuedouble; 2037 test->remote_cpu_util[1] = j_cpu_util_user->valuedouble; 2038 test->remote_cpu_util[2] = j_cpu_util_system->valuedouble; 2039 result_has_retransmits = j_sender_has_retransmits->valueint; 2040 if ( test->mode == RECEIVER ) { 2041 test->sender_has_retransmits = result_has_retransmits; 2042 test->other_side_has_retransmits = 0; 2043 } 2044 else if ( test->mode == BIDIRECTIONAL ) 2045 test->other_side_has_retransmits = result_has_retransmits; 2046 2047 j_streams = cJSON_GetObjectItem(j, "streams"); 2048 if (j_streams == NULL) { 2049 i_errno = IERECVRESULTS; 2050 r = -1; 2051 } else { 2052 n = cJSON_GetArraySize(j_streams); 2053 for (i=0; i<n; ++i) { 2054 j_stream = cJSON_GetArrayItem(j_streams, i); 2055 if (j_stream == NULL) { 2056 i_errno = IERECVRESULTS; 2057 r = -1; 2058 } else { 2059 j_id = cJSON_GetObjectItem(j_stream, "id"); 2060 j_bytes = cJSON_GetObjectItem(j_stream, "bytes"); 2061 j_retransmits = cJSON_GetObjectItem(j_stream, "retransmits"); 2062 j_jitter = cJSON_GetObjectItem(j_stream, "jitter"); 2063 j_errors = cJSON_GetObjectItem(j_stream, "errors"); 2064 j_packets = cJSON_GetObjectItem(j_stream, "packets"); 2065 j_start_time = cJSON_GetObjectItem(j_stream, "start_time"); 2066 j_end_time = cJSON_GetObjectItem(j_stream, "end_time"); 2067 if (j_id == NULL || j_bytes == NULL || j_retransmits == NULL || j_jitter == NULL || j_errors == NULL || j_packets == NULL) { 2068 i_errno = IERECVRESULTS; 2069 r = -1; 2070 } else { 2071 sid = j_id->valueint; 2072 bytes_transferred = j_bytes->valueint; 2073 retransmits = j_retransmits->valueint; 2074 jitter = j_jitter->valuedouble; 2075 cerror = j_errors->valueint; 2076 pcount = j_packets->valueint; 2077 SLIST_FOREACH(sp, &test->streams, streams) 2078 if (sp->id == sid) break; 2079 if (sp == NULL) { 2080 i_errno = IESTREAMID; 2081 r = -1; 2082 } else { 2083 if (sp->sender) { 2084 sp->jitter = jitter; 2085 sp->cnt_error = cerror; 2086 sp->peer_packet_count = pcount; 2087 sp->result->bytes_received = bytes_transferred; 2088 /* 2089 * We have to handle the possibilty that 2090 * start_time and end_time might not be 2091 * available; this is the case for older (pre-3.2) 2092 * servers. 2093 * 2094 * We need to have result structure members to hold 2095 * the both sides' start_time and end_time. 2096 */ 2097 if (j_start_time && j_end_time) { 2098 sp->result->receiver_time = j_end_time->valuedouble - j_start_time->valuedouble; 2099 } 2100 else { 2101 sp->result->receiver_time = 0.0; 2102 } 2103 } else { 2104 sp->peer_packet_count = pcount; 2105 sp->result->bytes_sent = bytes_transferred; 2106 sp->result->stream_retrans = retransmits; 2107 if (j_start_time && j_end_time) { 2108 sp->result->sender_time = j_end_time->valuedouble - j_start_time->valuedouble; 2109 } 2110 else { 2111 sp->result->sender_time = 0.0; 2112 } 2113 } 2114 } 2115 } 2116 } 2117 } 2118 /* 2119 * If we're the client and we're supposed to get remote results, 2120 * look them up and process accordingly. 2121 */ 2122 if (test->role == 'c' && iperf_get_test_get_server_output(test)) { 2123 /* Look for JSON. If we find it, grab the object so it doesn't get deleted. */ 2124 j_server_output = cJSON_DetachItemFromObject(j, "server_output_json"); 2125 if (j_server_output != NULL) { 2126 test->json_server_output = j_server_output; 2127 } 2128 else { 2129 /* No JSON, look for textual output. Make a copy of the text for later. */ 2130 j_server_output = cJSON_GetObjectItem(j, "server_output_text"); 2131 if (j_server_output != NULL) { 2132 test->server_output_text = strdup(j_server_output->valuestring); 2133 } 2134 } 2135 } 2136 } 2137 } 2138 2139 j_remote_congestion_used = cJSON_GetObjectItem(j, "congestion_used"); 2140 if (j_remote_congestion_used != NULL) { 2141 test->remote_congestion_used = strdup(j_remote_congestion_used->valuestring); 2142 } 2143 2144 cJSON_Delete(j); 2145 } 2146 return r; 2147 } 2148 2149 /*************************************************************/ 2150 2151 static int 2152 JSON_write(int fd, cJSON *json) 2153 { 2154 uint32_t hsize, nsize; 2155 char *str; 2156 int r = 0; 2157 2158 str = cJSON_PrintUnformatted(json); 2159 if (str == NULL) 2160 r = -1; 2161 else { 2162 hsize = strlen(str); 2163 nsize = htonl(hsize); 2164 if (Nwrite(fd, (char*) &nsize, sizeof(nsize), Ptcp) < 0) 2165 r = -1; 2166 else { 2167 if (Nwrite(fd, str, hsize, Ptcp) < 0) 2168 r = -1; 2169 } 2170 cJSON_free(str); 2171 } 2172 return r; 2173 } 2174 2175 /*************************************************************/ 2176 2177 static cJSON * 2178 JSON_read(int fd) 2179 { 2180 uint32_t hsize, nsize; 2181 char *str; 2182 cJSON *json = NULL; 2183 int rc; 2184 2185 /* 2186 * Read a four-byte integer, which is the length of the JSON to follow. 2187 * Then read the JSON into a buffer and parse it. Return a parsed JSON 2188 * structure, NULL if there was an error. 2189 */ 2190 if (Nread(fd, (char*) &nsize, sizeof(nsize), Ptcp) >= 0) { 2191 hsize = ntohl(nsize); 2192 /* Allocate a buffer to hold the JSON */ 2193 str = (char *) calloc(sizeof(char), hsize+1); /* +1 for trailing null */ 2194 if (str != NULL) { 2195 rc = Nread(fd, str, hsize, Ptcp); 2196 if (rc >= 0) { 2197 /* 2198 * We should be reading in the number of bytes corresponding to the 2199 * length in that 4-byte integer. If we don't the socket might have 2200 * prematurely closed. Only do the JSON parsing if we got the 2201 * correct number of bytes. 2202 */ 2203 if (rc == hsize) { 2204 json = cJSON_Parse(str); 2205 } 2206 else { 2207 printf("WARNING: Size of data read does not correspond to offered length\n"); 2208 } 2209 } 2210 } 2211 free(str); 2212 } 2213 return json; 2214 } 2215 2216 /*************************************************************/ 2217 /** 2218 * add_to_interval_list -- adds new interval to the interval_list 2219 */ 2220 2221 void 2222 add_to_interval_list(struct iperf_stream_result * rp, struct iperf_interval_results * new) 2223 { 2224 struct iperf_interval_results *irp; 2225 2226 irp = (struct iperf_interval_results *) malloc(sizeof(struct iperf_interval_results)); 2227 memcpy(irp, new, sizeof(struct iperf_interval_results)); 2228 TAILQ_INSERT_TAIL(&rp->interval_results, irp, irlistentries); 2229 } 2230 2231 2232 /************************************************************/ 2233 2234 /** 2235 * connect_msg -- displays connection message 2236 * denoting sender/receiver details 2237 * 2238 */ 2239 2240 void 2241 connect_msg(struct iperf_stream *sp) 2242 { 2243 char ipl[INET6_ADDRSTRLEN], ipr[INET6_ADDRSTRLEN]; 2244 int lport, rport; 2245 2246 if (getsockdomain(sp->socket) == AF_INET) { 2247 inet_ntop(AF_INET, (void *) &((struct sockaddr_in *) &sp->local_addr)->sin_addr, ipl, sizeof(ipl)); 2248 mapped_v4_to_regular_v4(ipl); 2249 inet_ntop(AF_INET, (void *) &((struct sockaddr_in *) &sp->remote_addr)->sin_addr, ipr, sizeof(ipr)); 2250 mapped_v4_to_regular_v4(ipr); 2251 lport = ntohs(((struct sockaddr_in *) &sp->local_addr)->sin_port); 2252 rport = ntohs(((struct sockaddr_in *) &sp->remote_addr)->sin_port); 2253 } else { 2254 inet_ntop(AF_INET6, (void *) &((struct sockaddr_in6 *) &sp->local_addr)->sin6_addr, ipl, sizeof(ipl)); 2255 mapped_v4_to_regular_v4(ipl); 2256 inet_ntop(AF_INET6, (void *) &((struct sockaddr_in6 *) &sp->remote_addr)->sin6_addr, ipr, sizeof(ipr)); 2257 mapped_v4_to_regular_v4(ipr); 2258 lport = ntohs(((struct sockaddr_in6 *) &sp->local_addr)->sin6_port); 2259 rport = ntohs(((struct sockaddr_in6 *) &sp->remote_addr)->sin6_port); 2260 } 2261 2262 if (sp->test->json_output) 2263 cJSON_AddItemToArray(sp->test->json_connected, iperf_json_printf("socket: %d local_host: %s local_port: %d remote_host: %s remote_port: %d", (int64_t) sp->socket, ipl, (int64_t) lport, ipr, (int64_t) rport)); 2264 else 2265 iperf_printf(sp->test, report_connected, sp->socket, ipl, lport, ipr, rport); 2266 } 2267 2268 2269 /**************************************************************************/ 2270 2271 struct iperf_test * 2272 iperf_new_test() 2273 { 2274 struct iperf_test *test; 2275 2276 test = (struct iperf_test *) malloc(sizeof(struct iperf_test)); 2277 if (!test) { 2278 i_errno = IENEWTEST; 2279 return NULL; 2280 } 2281 /* initialize everything to zero */ 2282 memset(test, 0, sizeof(struct iperf_test)); 2283 2284 test->settings = (struct iperf_settings *) malloc(sizeof(struct iperf_settings)); 2285 if (!test->settings) { 2286 free(test); 2287 i_errno = IENEWTEST; 2288 return NULL; 2289 } 2290 memset(test->settings, 0, sizeof(struct iperf_settings)); 2291 2292 /* By default all output goes to stdout */ 2293 test->outfile = stdout; 2294 2295 return test; 2296 } 2297 2298 /**************************************************************************/ 2299 2300 struct protocol * 2301 protocol_new(void) 2302 { 2303 struct protocol *proto; 2304 2305 proto = malloc(sizeof(struct protocol)); 2306 if(!proto) { 2307 return NULL; 2308 } 2309 memset(proto, 0, sizeof(struct protocol)); 2310 2311 return proto; 2312 } 2313 2314 void 2315 protocol_free(struct protocol *proto) 2316 { 2317 free(proto); 2318 } 2319 2320 /**************************************************************************/ 2321 int 2322 iperf_defaults(struct iperf_test *testp) 2323 { 2324 struct protocol *tcp, *udp; 2325 #if defined(HAVE_SCTP) 2326 struct protocol *sctp; 2327 #endif /* HAVE_SCTP */ 2328 2329 testp->omit = OMIT; 2330 testp->duration = DURATION; 2331 testp->diskfile_name = (char*) 0; 2332 testp->affinity = -1; 2333 testp->server_affinity = -1; 2334 TAILQ_INIT(&testp->xbind_addrs); 2335 #if defined(HAVE_CPUSET_SETAFFINITY) 2336 CPU_ZERO(&testp->cpumask); 2337 #endif /* HAVE_CPUSET_SETAFFINITY */ 2338 testp->title = NULL; 2339 testp->extra_data = NULL; 2340 testp->congestion = NULL; 2341 testp->congestion_used = NULL; 2342 testp->remote_congestion_used = NULL; 2343 testp->server_port = PORT; 2344 testp->ctrl_sck = -1; 2345 testp->prot_listener = -1; 2346 testp->other_side_has_retransmits = 0; 2347 2348 testp->stats_callback = iperf_stats_callback; 2349 testp->reporter_callback = iperf_reporter_callback; 2350 2351 testp->stats_interval = testp->reporter_interval = 1; 2352 testp->num_streams = 1; 2353 2354 testp->settings->domain = AF_UNSPEC; 2355 testp->settings->unit_format = 'a'; 2356 testp->settings->socket_bufsize = 0; /* use autotuning */ 2357 testp->settings->blksize = DEFAULT_TCP_BLKSIZE; 2358 testp->settings->rate = 0; 2359 testp->settings->fqrate = 0; 2360 testp->settings->pacing_timer = 1000; 2361 testp->settings->burst = 0; 2362 testp->settings->mss = 0; 2363 testp->settings->bytes = 0; 2364 testp->settings->blocks = 0; 2365 testp->settings->connect_timeout = -1; 2366 memset(testp->cookie, 0, COOKIE_SIZE); 2367 2368 testp->multisend = 10; /* arbitrary */ 2369 2370 /* Set up protocol list */ 2371 SLIST_INIT(&testp->streams); 2372 SLIST_INIT(&testp->protocols); 2373 2374 tcp = protocol_new(); 2375 if (!tcp) 2376 return -1; 2377 2378 tcp->id = Ptcp; 2379 tcp->name = "TCP"; 2380 tcp->accept = iperf_tcp_accept; 2381 tcp->listen = iperf_tcp_listen; 2382 tcp->connect = iperf_tcp_connect; 2383 tcp->send = iperf_tcp_send; 2384 tcp->recv = iperf_tcp_recv; 2385 tcp->init = NULL; 2386 SLIST_INSERT_HEAD(&testp->protocols, tcp, protocols); 2387 2388 udp = protocol_new(); 2389 if (!udp) { 2390 protocol_free(tcp); 2391 return -1; 2392 } 2393 2394 udp->id = Pudp; 2395 udp->name = "UDP"; 2396 udp->accept = iperf_udp_accept; 2397 udp->listen = iperf_udp_listen; 2398 udp->connect = iperf_udp_connect; 2399 udp->send = iperf_udp_send; 2400 udp->recv = iperf_udp_recv; 2401 udp->init = iperf_udp_init; 2402 SLIST_INSERT_AFTER(tcp, udp, protocols); 2403 2404 set_protocol(testp, Ptcp); 2405 2406 #if defined(HAVE_SCTP) 2407 sctp = protocol_new(); 2408 if (!sctp) { 2409 protocol_free(tcp); 2410 protocol_free(udp); 2411 return -1; 2412 } 2413 2414 sctp->id = Psctp; 2415 sctp->name = "SCTP"; 2416 sctp->accept = iperf_sctp_accept; 2417 sctp->listen = iperf_sctp_listen; 2418 sctp->connect = iperf_sctp_connect; 2419 sctp->send = iperf_sctp_send; 2420 sctp->recv = iperf_sctp_recv; 2421 sctp->init = iperf_sctp_init; 2422 2423 SLIST_INSERT_AFTER(udp, sctp, protocols); 2424 #endif /* HAVE_SCTP */ 2425 2426 testp->on_new_stream = iperf_on_new_stream; 2427 testp->on_test_start = iperf_on_test_start; 2428 testp->on_connect = iperf_on_connect; 2429 testp->on_test_finish = iperf_on_test_finish; 2430 2431 TAILQ_INIT(&testp->server_output_list); 2432 2433 return 0; 2434 } 2435 2436 2437 /**************************************************************************/ 2438 void 2439 iperf_free_test(struct iperf_test *test) 2440 { 2441 struct protocol *prot; 2442 struct iperf_stream *sp; 2443 2444 /* Free streams */ 2445 while (!SLIST_EMPTY(&test->streams)) { 2446 sp = SLIST_FIRST(&test->streams); 2447 SLIST_REMOVE_HEAD(&test->streams, streams); 2448 iperf_free_stream(sp); 2449 } 2450 if (test->server_hostname) 2451 free(test->server_hostname); 2452 if (test->tmp_template) 2453 free(test->tmp_template); 2454 if (test->bind_address) 2455 free(test->bind_address); 2456 if (!TAILQ_EMPTY(&test->xbind_addrs)) { 2457 struct xbind_entry *xbe; 2458 2459 while (!TAILQ_EMPTY(&test->xbind_addrs)) { 2460 xbe = TAILQ_FIRST(&test->xbind_addrs); 2461 TAILQ_REMOVE(&test->xbind_addrs, xbe, link); 2462 if (xbe->ai) 2463 freeaddrinfo(xbe->ai); 2464 free(xbe->name); 2465 free(xbe); 2466 } 2467 } 2468 #if defined(HAVE_SSL) 2469 2470 if (test->server_rsa_private_key) 2471 EVP_PKEY_free(test->server_rsa_private_key); 2472 test->server_rsa_private_key = NULL; 2473 2474 free(test->settings->authtoken); 2475 test->settings->authtoken = NULL; 2476 2477 free(test->settings->client_username); 2478 test->settings->client_username = NULL; 2479 2480 free(test->settings->client_password); 2481 test->settings->client_password = NULL; 2482 2483 if (test->settings->client_rsa_pubkey) 2484 EVP_PKEY_free(test->settings->client_rsa_pubkey); 2485 test->settings->client_rsa_pubkey = NULL; 2486 #endif /* HAVE_SSL */ 2487 2488 if (test->settings) 2489 free(test->settings); 2490 if (test->title) 2491 free(test->title); 2492 if (test->extra_data) 2493 free(test->extra_data); 2494 if (test->congestion) 2495 free(test->congestion); 2496 if (test->congestion_used) 2497 free(test->congestion_used); 2498 if (test->remote_congestion_used) 2499 free(test->remote_congestion_used); 2500 if (test->omit_timer != NULL) 2501 tmr_cancel(test->omit_timer); 2502 if (test->timer != NULL) 2503 tmr_cancel(test->timer); 2504 if (test->stats_timer != NULL) 2505 tmr_cancel(test->stats_timer); 2506 if (test->reporter_timer != NULL) 2507 tmr_cancel(test->reporter_timer); 2508 2509 /* Free protocol list */ 2510 while (!SLIST_EMPTY(&test->protocols)) { 2511 prot = SLIST_FIRST(&test->protocols); 2512 SLIST_REMOVE_HEAD(&test->protocols, protocols); 2513 free(prot); 2514 } 2515 2516 if (test->server_output_text) { 2517 free(test->server_output_text); 2518 test->server_output_text = NULL; 2519 } 2520 2521 if (test->json_output_string) { 2522 free(test->json_output_string); 2523 test->json_output_string = NULL; 2524 } 2525 2526 /* Free output line buffers, if any (on the server only) */ 2527 struct iperf_textline *t; 2528 while (!TAILQ_EMPTY(&test->server_output_list)) { 2529 t = TAILQ_FIRST(&test->server_output_list); 2530 TAILQ_REMOVE(&test->server_output_list, t, textlineentries); 2531 free(t->line); 2532 free(t); 2533 } 2534 2535 /* sctp_bindx: do not free the arguments, only the resolver results */ 2536 if (!TAILQ_EMPTY(&test->xbind_addrs)) { 2537 struct xbind_entry *xbe; 2538 2539 TAILQ_FOREACH(xbe, &test->xbind_addrs, link) { 2540 if (xbe->ai) { 2541 freeaddrinfo(xbe->ai); 2542 xbe->ai = NULL; 2543 } 2544 } 2545 } 2546 2547 /* XXX: Why are we setting these values to NULL? */ 2548 // test->streams = NULL; 2549 test->stats_callback = NULL; 2550 test->reporter_callback = NULL; 2551 free(test); 2552 } 2553 2554 2555 void 2556 iperf_reset_test(struct iperf_test *test) 2557 { 2558 struct iperf_stream *sp; 2559 2560 /* Free streams */ 2561 while (!SLIST_EMPTY(&test->streams)) { 2562 sp = SLIST_FIRST(&test->streams); 2563 SLIST_REMOVE_HEAD(&test->streams, streams); 2564 iperf_free_stream(sp); 2565 } 2566 if (test->omit_timer != NULL) { 2567 tmr_cancel(test->omit_timer); 2568 test->omit_timer = NULL; 2569 } 2570 if (test->timer != NULL) { 2571 tmr_cancel(test->timer); 2572 test->timer = NULL; 2573 } 2574 if (test->stats_timer != NULL) { 2575 tmr_cancel(test->stats_timer); 2576 test->stats_timer = NULL; 2577 } 2578 if (test->reporter_timer != NULL) { 2579 tmr_cancel(test->reporter_timer); 2580 test->reporter_timer = NULL; 2581 } 2582 test->done = 0; 2583 2584 SLIST_INIT(&test->streams); 2585 2586 if (test->remote_congestion_used) 2587 free(test->remote_congestion_used); 2588 test->remote_congestion_used = NULL; 2589 test->role = 's'; 2590 test->mode = RECEIVER; 2591 test->sender_has_retransmits = 0; 2592 set_protocol(test, Ptcp); 2593 test->omit = OMIT; 2594 test->duration = DURATION; 2595 test->server_affinity = -1; 2596 #if defined(HAVE_CPUSET_SETAFFINITY) 2597 CPU_ZERO(&test->cpumask); 2598 #endif /* HAVE_CPUSET_SETAFFINITY */ 2599 test->state = 0; 2600 2601 test->ctrl_sck = -1; 2602 test->prot_listener = -1; 2603 2604 test->bytes_sent = 0; 2605 test->blocks_sent = 0; 2606 2607 test->bytes_received = 0; 2608 test->blocks_received = 0; 2609 2610 test->other_side_has_retransmits = 0; 2611 2612 test->reverse = 0; 2613 test->bidirectional = 0; 2614 test->no_delay = 0; 2615 2616 FD_ZERO(&test->read_set); 2617 FD_ZERO(&test->write_set); 2618 2619 test->num_streams = 1; 2620 test->settings->socket_bufsize = 0; 2621 test->settings->blksize = DEFAULT_TCP_BLKSIZE; 2622 test->settings->rate = 0; 2623 test->settings->burst = 0; 2624 test->settings->mss = 0; 2625 test->settings->tos = 0; 2626 2627 #if defined(HAVE_SSL) 2628 if (test->settings->authtoken) { 2629 free(test->settings->authtoken); 2630 test->settings->authtoken = NULL; 2631 } 2632 if (test->settings->client_username) { 2633 free(test->settings->client_username); 2634 test->settings->client_username = NULL; 2635 } 2636 if (test->settings->client_password) { 2637 free(test->settings->client_password); 2638 test->settings->client_password = NULL; 2639 } 2640 if (test->settings->client_rsa_pubkey) { 2641 EVP_PKEY_free(test->settings->client_rsa_pubkey); 2642 test->settings->client_rsa_pubkey = NULL; 2643 } 2644 #endif /* HAVE_SSL */ 2645 2646 memset(test->cookie, 0, COOKIE_SIZE); 2647 test->multisend = 10; /* arbitrary */ 2648 test->udp_counters_64bit = 0; 2649 if (test->title) { 2650 free(test->title); 2651 test->title = NULL; 2652 } 2653 if (test->extra_data) { 2654 free(test->extra_data); 2655 test->extra_data = NULL; 2656 } 2657 2658 /* Free output line buffers, if any (on the server only) */ 2659 struct iperf_textline *t; 2660 while (!TAILQ_EMPTY(&test->server_output_list)) { 2661 t = TAILQ_FIRST(&test->server_output_list); 2662 TAILQ_REMOVE(&test->server_output_list, t, textlineentries); 2663 free(t->line); 2664 free(t); 2665 } 2666 } 2667 2668 2669 /* Reset all of a test's stats back to zero. Called when the omitting 2670 ** period is over. 2671 */ 2672 void 2673 iperf_reset_stats(struct iperf_test *test) 2674 { 2675 struct iperf_time now; 2676 struct iperf_stream *sp; 2677 struct iperf_stream_result *rp; 2678 2679 test->bytes_sent = 0; 2680 test->blocks_sent = 0; 2681 iperf_time_now(&now); 2682 SLIST_FOREACH(sp, &test->streams, streams) { 2683 sp->omitted_packet_count = sp->packet_count; 2684 sp->omitted_cnt_error = sp->cnt_error; 2685 sp->omitted_outoforder_packets = sp->outoforder_packets; 2686 sp->jitter = 0; 2687 rp = sp->result; 2688 rp->bytes_sent_omit = rp->bytes_sent; 2689 rp->bytes_received = 0; 2690 rp->bytes_sent_this_interval = rp->bytes_received_this_interval = 0; 2691 if (test->sender_has_retransmits == 1) { 2692 struct iperf_interval_results ir; /* temporary results structure */ 2693 save_tcpinfo(sp, &ir); 2694 rp->stream_prev_total_retrans = get_total_retransmits(&ir); 2695 } 2696 rp->stream_retrans = 0; 2697 rp->start_time = now; 2698 } 2699 } 2700 2701 2702 /**************************************************************************/ 2703 2704 /** 2705 * Gather statistics during a test. 2706 * This function works for both the client and server side. 2707 */ 2708 void 2709 iperf_stats_callback(struct iperf_test *test) 2710 { 2711 struct iperf_stream *sp; 2712 struct iperf_stream_result *rp = NULL; 2713 struct iperf_interval_results *irp, temp; 2714 struct iperf_time temp_time; 2715 2716 temp.omitted = test->omitting; 2717 SLIST_FOREACH(sp, &test->streams, streams) { 2718 rp = sp->result; 2719 temp.bytes_transferred = sp->sender ? rp->bytes_sent_this_interval : rp->bytes_received_this_interval; 2720 2721 irp = TAILQ_LAST(&rp->interval_results, irlisthead); 2722 /* result->end_time contains timestamp of previous interval */ 2723 if ( irp != NULL ) /* not the 1st interval */ 2724 memcpy(&temp.interval_start_time, &rp->end_time, sizeof(struct iperf_time)); 2725 else /* or use timestamp from beginning */ 2726 memcpy(&temp.interval_start_time, &rp->start_time, sizeof(struct iperf_time)); 2727 /* now save time of end of this interval */ 2728 iperf_time_now(&rp->end_time); 2729 memcpy(&temp.interval_end_time, &rp->end_time, sizeof(struct iperf_time)); 2730 iperf_time_diff(&temp.interval_start_time, &temp.interval_end_time, &temp_time); 2731 temp.interval_duration = iperf_time_in_secs(&temp_time); 2732 if (test->protocol->id == Ptcp) { 2733 if ( has_tcpinfo()) { 2734 save_tcpinfo(sp, &temp); 2735 if (test->sender_has_retransmits == 1) { 2736 long total_retrans = get_total_retransmits(&temp); 2737 temp.interval_retrans = total_retrans - rp->stream_prev_total_retrans; 2738 rp->stream_retrans += temp.interval_retrans; 2739 rp->stream_prev_total_retrans = total_retrans; 2740 2741 temp.snd_cwnd = get_snd_cwnd(&temp); 2742 if (temp.snd_cwnd > rp->stream_max_snd_cwnd) { 2743 rp->stream_max_snd_cwnd = temp.snd_cwnd; 2744 } 2745 2746 temp.rtt = get_rtt(&temp); 2747 if (temp.rtt > rp->stream_max_rtt) { 2748 rp->stream_max_rtt = temp.rtt; 2749 } 2750 if (rp->stream_min_rtt == 0 || 2751 temp.rtt < rp->stream_min_rtt) { 2752 rp->stream_min_rtt = temp.rtt; 2753 } 2754 rp->stream_sum_rtt += temp.rtt; 2755 rp->stream_count_rtt++; 2756 2757 temp.rttvar = get_rttvar(&temp); 2758 temp.pmtu = get_pmtu(&temp); 2759 } 2760 } 2761 } else { 2762 if (irp == NULL) { 2763 temp.interval_packet_count = sp->packet_count; 2764 temp.interval_outoforder_packets = sp->outoforder_packets; 2765 temp.interval_cnt_error = sp->cnt_error; 2766 } else { 2767 temp.interval_packet_count = sp->packet_count - irp->packet_count; 2768 temp.interval_outoforder_packets = sp->outoforder_packets - irp->outoforder_packets; 2769 temp.interval_cnt_error = sp->cnt_error - irp->cnt_error; 2770 } 2771 temp.packet_count = sp->packet_count; 2772 temp.jitter = sp->jitter; 2773 temp.outoforder_packets = sp->outoforder_packets; 2774 temp.cnt_error = sp->cnt_error; 2775 } 2776 add_to_interval_list(rp, &temp); 2777 rp->bytes_sent_this_interval = rp->bytes_received_this_interval = 0; 2778 } 2779 } 2780 2781 /** 2782 * Print intermediate results during a test (interval report). 2783 * Uses print_interval_results to print the results for each stream, 2784 * then prints an interval summary for all streams in this 2785 * interval. 2786 */ 2787 static void 2788 iperf_print_intermediate(struct iperf_test *test) 2789 { 2790 struct iperf_stream *sp = NULL; 2791 struct iperf_interval_results *irp; 2792 struct iperf_time temp_time; 2793 cJSON *json_interval; 2794 cJSON *json_interval_streams; 2795 2796 int lower_mode, upper_mode; 2797 int current_mode; 2798 2799 /* 2800 * Due to timing oddities, there can be cases, especially on the 2801 * server side, where at the end of a test there is a fairly short 2802 * interval with no data transferred. This could caused by 2803 * the control and data flows sharing the same path in the network, 2804 * and having the control messages for stopping the test being 2805 * queued behind the data packets. 2806 * 2807 * We'd like to try to omit that last interval when it happens, to 2808 * avoid cluttering data and output with useless stuff. 2809 * So we're going to try to ignore very short intervals (less than 2810 * 10% of the interval time) that have no data. 2811 */ 2812 int interval_ok = 0; 2813 SLIST_FOREACH(sp, &test->streams, streams) { 2814 irp = TAILQ_LAST(&sp->result->interval_results, irlisthead); 2815 if (irp) { 2816 iperf_time_diff(&irp->interval_start_time, &irp->interval_end_time, &temp_time); 2817 double interval_len = iperf_time_in_secs(&temp_time); 2818 if (test->debug) { 2819 printf("interval_len %f bytes_transferred %" PRIu64 "\n", interval_len, irp->bytes_transferred); 2820 } 2821 2822 /* 2823 * If the interval is at least 10% the normal interval 2824 * length, or if there were actual bytes transferrred, 2825 * then we want to keep this interval. 2826 */ 2827 if (interval_len >= test->stats_interval * 0.10 || 2828 irp->bytes_transferred > 0) { 2829 interval_ok = 1; 2830 if (test->debug) { 2831 printf("interval forces keep\n"); 2832 } 2833 } 2834 } 2835 } 2836 if (!interval_ok) { 2837 if (test->debug) { 2838 printf("ignoring short interval with no data\n"); 2839 } 2840 return; 2841 } 2842 2843 if (test->json_output) { 2844 json_interval = cJSON_CreateObject(); 2845 if (json_interval == NULL) 2846 return; 2847 cJSON_AddItemToArray(test->json_intervals, json_interval); 2848 json_interval_streams = cJSON_CreateArray(); 2849 if (json_interval_streams == NULL) 2850 return; 2851 cJSON_AddItemToObject(json_interval, "streams", json_interval_streams); 2852 } else { 2853 json_interval = NULL; 2854 json_interval_streams = NULL; 2855 } 2856 2857 /* 2858 * We must to sum streams separately. 2859 * For bidirectional mode we must to display 2860 * information about sender and receiver streams. 2861 * For client side we must handle sender streams 2862 * firstly and receiver streams for server side. 2863 * The following design allows us to do this. 2864 */ 2865 2866 if (test->mode == BIDIRECTIONAL) { 2867 if (test->role == 'c') { 2868 lower_mode = -1; 2869 upper_mode = 0; 2870 } else { 2871 lower_mode = 0; 2872 upper_mode = 1; 2873 } 2874 } else { 2875 lower_mode = test->mode; 2876 upper_mode = lower_mode; 2877 } 2878 2879 2880 for (current_mode = lower_mode; current_mode <= upper_mode; ++current_mode) { 2881 char ubuf[UNIT_LEN]; 2882 char nbuf[UNIT_LEN]; 2883 char mbuf[UNIT_LEN]; 2884 char zbuf[] = " "; 2885 2886 iperf_size_t bytes = 0; 2887 double bandwidth; 2888 int retransmits = 0; 2889 double start_time, end_time; 2890 2891 int total_packets = 0, lost_packets = 0; 2892 double avg_jitter = 0.0, lost_percent; 2893 int stream_must_be_sender = current_mode * current_mode; 2894 2895 /* Print stream role just for bidirectional mode. */ 2896 2897 if (test->mode == BIDIRECTIONAL) { 2898 sprintf(mbuf, "[%s-%s]", stream_must_be_sender?"TX":"RX", test->role == 'c'?"C":"S"); 2899 } else { 2900 mbuf[0] = '\0'; 2901 zbuf[0] = '\0'; 2902 } 2903 2904 SLIST_FOREACH(sp, &test->streams, streams) { 2905 if (sp->sender == stream_must_be_sender) { 2906 print_interval_results(test, sp, json_interval_streams); 2907 /* sum up all streams */ 2908 irp = TAILQ_LAST(&sp->result->interval_results, irlisthead); 2909 if (irp == NULL) { 2910 iperf_err(test, 2911 "iperf_print_intermediate error: interval_results is NULL"); 2912 return; 2913 } 2914 bytes += irp->bytes_transferred; 2915 if (test->protocol->id == Ptcp) { 2916 if (test->sender_has_retransmits == 1) { 2917 retransmits += irp->interval_retrans; 2918 } 2919 } else { 2920 total_packets += irp->interval_packet_count; 2921 lost_packets += irp->interval_cnt_error; 2922 avg_jitter += irp->jitter; 2923 } 2924 } 2925 } 2926 2927 /* next build string with sum of all streams */ 2928 if (test->num_streams > 1 || test->json_output) { 2929 sp = SLIST_FIRST(&test->streams); /* reset back to 1st stream */ 2930 /* Only do this of course if there was a first stream */ 2931 if (sp) { 2932 irp = TAILQ_LAST(&sp->result->interval_results, irlisthead); /* use 1st stream for timing info */ 2933 2934 unit_snprintf(ubuf, UNIT_LEN, (double) bytes, 'A'); 2935 bandwidth = (double) bytes / (double) irp->interval_duration; 2936 unit_snprintf(nbuf, UNIT_LEN, bandwidth, test->settings->unit_format); 2937 2938 iperf_time_diff(&sp->result->start_time,&irp->interval_start_time, &temp_time); 2939 start_time = iperf_time_in_secs(&temp_time); 2940 iperf_time_diff(&sp->result->start_time,&irp->interval_end_time, &temp_time); 2941 end_time = iperf_time_in_secs(&temp_time); 2942 if (test->protocol->id == Ptcp || test->protocol->id == Psctp) { 2943 if (test->sender_has_retransmits == 1 && stream_must_be_sender) { 2944 /* Interval sum, TCP with retransmits. */ 2945 if (test->json_output) 2946 cJSON_AddItemToObject(json_interval, "sum", iperf_json_printf("start: %f end: %f seconds: %f bytes: %d bits_per_second: %f retransmits: %d omitted: %b sender: %b", (double) start_time, (double) end_time, (double) irp->interval_duration, (int64_t) bytes, bandwidth * 8, (int64_t) retransmits, irp->omitted, stream_must_be_sender)); /* XXX irp->omitted or test->omitting? */ 2947 else 2948 iperf_printf(test, report_sum_bw_retrans_format, mbuf, start_time, end_time, ubuf, nbuf, retransmits, irp->omitted?report_omitted:""); /* XXX irp->omitted or test->omitting? */ 2949 } else { 2950 /* Interval sum, TCP without retransmits. */ 2951 if (test->json_output) 2952 cJSON_AddItemToObject(json_interval, "sum", iperf_json_printf("start: %f end: %f seconds: %f bytes: %d bits_per_second: %f omitted: %b sender: %b", (double) start_time, (double) end_time, (double) irp->interval_duration, (int64_t) bytes, bandwidth * 8, test->omitting, stream_must_be_sender)); 2953 else 2954 iperf_printf(test, report_sum_bw_format, mbuf, start_time, end_time, ubuf, nbuf, test->omitting?report_omitted:""); 2955 } 2956 } else { 2957 /* Interval sum, UDP. */ 2958 if (stream_must_be_sender) { 2959 if (test->json_output) 2960 cJSON_AddItemToObject(json_interval, "sum", iperf_json_printf("start: %f end: %f seconds: %f bytes: %d bits_per_second: %f packets: %d omitted: %b sender: %b", (double) start_time, (double) end_time, (double) irp->interval_duration, (int64_t) bytes, bandwidth * 8, (int64_t) total_packets, test->omitting, stream_must_be_sender)); 2961 else 2962 iperf_printf(test, report_sum_bw_udp_sender_format, mbuf, start_time, end_time, ubuf, nbuf, zbuf, total_packets, test->omitting?report_omitted:""); 2963 } else { 2964 avg_jitter /= test->num_streams; 2965 if (total_packets > 0) { 2966 lost_percent = 100.0 * lost_packets / total_packets; 2967 } 2968 else { 2969 lost_percent = 0.0; 2970 } 2971 if (test->json_output) 2972 cJSON_AddItemToObject(json_interval, "sum", iperf_json_printf("start: %f end: %f seconds: %f bytes: %d bits_per_second: %f jitter_ms: %f lost_packets: %d packets: %d lost_percent: %f omitted: %b sender: %b", (double) start_time, (double) end_time, (double) irp->interval_duration, (int64_t) bytes, bandwidth * 8, (double) avg_jitter * 1000.0, (int64_t) lost_packets, (int64_t) total_packets, (double) lost_percent, test->omitting, stream_must_be_sender)); 2973 else 2974 iperf_printf(test, report_sum_bw_udp_format, mbuf, start_time, end_time, ubuf, nbuf, avg_jitter * 1000.0, lost_packets, total_packets, lost_percent, test->omitting?report_omitted:""); 2975 } 2976 } 2977 } 2978 } 2979 } 2980 } 2981 2982 /** 2983 * Print overall summary statistics at the end of a test. 2984 */ 2985 static void 2986 iperf_print_results(struct iperf_test *test) 2987 { 2988 2989 cJSON *json_summary_streams = NULL; 2990 2991 int lower_mode, upper_mode; 2992 int current_mode; 2993 2994 int tmp_sender_has_retransmits = test->sender_has_retransmits; 2995 2996 /* print final summary for all intervals */ 2997 2998 if (test->json_output) { 2999 json_summary_streams = cJSON_CreateArray(); 3000 if (json_summary_streams == NULL) 3001 return; 3002 cJSON_AddItemToObject(test->json_end, "streams", json_summary_streams); 3003 } else { 3004 iperf_printf(test, "%s", report_bw_separator); 3005 if (test->verbose) 3006 iperf_printf(test, "%s", report_summary); 3007 if (test->protocol->id == Ptcp || test->protocol->id == Psctp) { 3008 if (test->sender_has_retransmits || test->other_side_has_retransmits) { 3009 if (test->bidirectional) 3010 iperf_printf(test, "%s", report_bw_retrans_header_bidir); 3011 else 3012 iperf_printf(test, "%s", report_bw_retrans_header); 3013 } 3014 else { 3015 if (test->bidirectional) 3016 iperf_printf(test, "%s", report_bw_header_bidir); 3017 else 3018 iperf_printf(test, "%s", report_bw_header); 3019 } 3020 } else { 3021 if (test->bidirectional) 3022 iperf_printf(test, "%s", report_bw_udp_header_bidir); 3023 else 3024 iperf_printf(test, "%s", report_bw_udp_header); 3025 } 3026 } 3027 3028 /* 3029 * We must to sum streams separately. 3030 * For bidirectional mode we must to display 3031 * information about sender and receiver streams. 3032 * For client side we must handle sender streams 3033 * firstly and receiver streams for server side. 3034 * The following design allows us to do this. 3035 */ 3036 3037 if (test->mode == BIDIRECTIONAL) { 3038 if (test->role == 'c') { 3039 lower_mode = -1; 3040 upper_mode = 0; 3041 } else { 3042 lower_mode = 0; 3043 upper_mode = 1; 3044 } 3045 } else { 3046 lower_mode = test->mode; 3047 upper_mode = lower_mode; 3048 } 3049 3050 3051 for (current_mode = lower_mode; current_mode <= upper_mode; ++current_mode) { 3052 cJSON *json_summary_stream = NULL; 3053 int total_retransmits = 0; 3054 int total_packets = 0, lost_packets = 0; 3055 int sender_packet_count = 0, receiver_packet_count = 0; /* for this stream, this interval */ 3056 int sender_total_packets = 0, receiver_total_packets = 0; /* running total */ 3057 char ubuf[UNIT_LEN]; 3058 char nbuf[UNIT_LEN]; 3059 struct stat sb; 3060 char sbuf[UNIT_LEN]; 3061 struct iperf_stream *sp = NULL; 3062 iperf_size_t bytes_sent, total_sent = 0; 3063 iperf_size_t bytes_received, total_received = 0; 3064 double start_time, end_time = 0.0, avg_jitter = 0.0, lost_percent = 0.0; 3065 double sender_time = 0.0, receiver_time = 0.0; 3066 struct iperf_time temp_time; 3067 double bandwidth; 3068 3069 char mbuf[UNIT_LEN]; 3070 int stream_must_be_sender = current_mode * current_mode; 3071 3072 3073 /* Print stream role just for bidirectional mode. */ 3074 3075 if (test->mode == BIDIRECTIONAL) { 3076 sprintf(mbuf, "[%s-%s]", stream_must_be_sender?"TX":"RX", test->role == 'c'?"C":"S"); 3077 } else { 3078 mbuf[0] = '\0'; 3079 } 3080 3081 /* Get sender_has_retransmits for each sender side (client and server) */ 3082 if (test->mode == BIDIRECTIONAL && stream_must_be_sender) 3083 test->sender_has_retransmits = tmp_sender_has_retransmits; 3084 else if (test->mode == BIDIRECTIONAL && !stream_must_be_sender) 3085 test->sender_has_retransmits = test->other_side_has_retransmits; 3086 3087 start_time = 0.; 3088 sp = SLIST_FIRST(&test->streams); 3089 3090 /* 3091 * If there is at least one stream, then figure out the length of time 3092 * we were running the tests and print out some statistics about 3093 * the streams. It's possible to not have any streams at all 3094 * if the client got interrupted before it got to do anything. 3095 * 3096 * Also note that we try to keep seperate values for the sender 3097 * and receiver ending times. Earlier iperf (3.1 and earlier) 3098 * servers didn't send that to the clients, so in this case we fall 3099 * back to using the client's ending timestamp. The fallback is 3100 * basically emulating what iperf 3.1 did. 3101 */ 3102 3103 if (sp) { 3104 iperf_time_diff(&sp->result->start_time, &sp->result->end_time, &temp_time); 3105 end_time = iperf_time_in_secs(&temp_time); 3106 if (sp->sender) { 3107 sp->result->sender_time = end_time; 3108 if (sp->result->receiver_time == 0.0) { 3109 sp->result->receiver_time = sp->result->sender_time; 3110 } 3111 } 3112 else { 3113 sp->result->receiver_time = end_time; 3114 if (sp->result->sender_time == 0.0) { 3115 sp->result->sender_time = sp->result->receiver_time; 3116 } 3117 } 3118 sender_time = sp->result->sender_time; 3119 receiver_time = sp->result->receiver_time; 3120 SLIST_FOREACH(sp, &test->streams, streams) { 3121 if (sp->sender == stream_must_be_sender) { 3122 if (test->json_output) { 3123 json_summary_stream = cJSON_CreateObject(); 3124 if (json_summary_stream == NULL) 3125 return; 3126 cJSON_AddItemToArray(json_summary_streams, json_summary_stream); 3127 } 3128 3129 bytes_sent = sp->result->bytes_sent - sp->result->bytes_sent_omit; 3130 bytes_received = sp->result->bytes_received; 3131 total_sent += bytes_sent; 3132 total_received += bytes_received; 3133 3134 if (sp->sender) { 3135 sender_packet_count = sp->packet_count; 3136 receiver_packet_count = sp->peer_packet_count; 3137 } 3138 else { 3139 sender_packet_count = sp->peer_packet_count; 3140 receiver_packet_count = sp->packet_count; 3141 } 3142 3143 if (test->protocol->id == Ptcp || test->protocol->id == Psctp) { 3144 if (test->sender_has_retransmits) { 3145 total_retransmits += sp->result->stream_retrans; 3146 } 3147 } else { 3148 /* 3149 * Running total of the total number of packets. Use the sender packet count if we 3150 * have it, otherwise use the receiver packet count. 3151 */ 3152 int packet_count = sender_packet_count ? sender_packet_count : receiver_packet_count; 3153 total_packets += (packet_count - sp->omitted_packet_count); 3154 sender_total_packets += (sender_packet_count - sp->omitted_packet_count); 3155 receiver_total_packets += (receiver_packet_count - sp->omitted_packet_count); 3156 lost_packets += (sp->cnt_error - sp->omitted_cnt_error); 3157 avg_jitter += sp->jitter; 3158 } 3159 3160 unit_snprintf(ubuf, UNIT_LEN, (double) bytes_sent, 'A'); 3161 if (sender_time > 0.0) { 3162 bandwidth = (double) bytes_sent / (double) sender_time; 3163 } 3164 else { 3165 bandwidth = 0.0; 3166 } 3167 unit_snprintf(nbuf, UNIT_LEN, bandwidth, test->settings->unit_format); 3168 if (test->protocol->id == Ptcp || test->protocol->id == Psctp) { 3169 if (test->sender_has_retransmits) { 3170 /* Sender summary, TCP and SCTP with retransmits. */ 3171 if (test->json_output) 3172 cJSON_AddItemToObject(json_summary_stream, "sender", iperf_json_printf("socket: %d start: %f end: %f seconds: %f bytes: %d bits_per_second: %f retransmits: %d max_snd_cwnd: %d max_rtt: %d min_rtt: %d mean_rtt: %d sender: %b", (int64_t) sp->socket, (double) start_time, (double) sender_time, (double) sender_time, (int64_t) bytes_sent, bandwidth * 8, (int64_t) sp->result->stream_retrans, (int64_t) sp->result->stream_max_snd_cwnd, (int64_t) sp->result->stream_max_rtt, (int64_t) sp->result->stream_min_rtt, (int64_t) ((sp->result->stream_count_rtt == 0) ? 0 : sp->result->stream_sum_rtt / sp->result->stream_count_rtt), stream_must_be_sender)); 3173 else 3174 if (test->role == 's' && !sp->sender) { 3175 if (test->verbose) 3176 iperf_printf(test, report_sender_not_available_format, sp->socket); 3177 } 3178 else { 3179 iperf_printf(test, report_bw_retrans_format, sp->socket, mbuf, start_time, sender_time, ubuf, nbuf, sp->result->stream_retrans, report_sender); 3180 } 3181 } else { 3182 /* Sender summary, TCP and SCTP without retransmits. */ 3183 if (test->json_output) 3184 cJSON_AddItemToObject(json_summary_stream, "sender", iperf_json_printf("socket: %d start: %f end: %f seconds: %f bytes: %d bits_per_second: %f sender: %b", (int64_t) sp->socket, (double) start_time, (double) sender_time, (double) sender_time, (int64_t) bytes_sent, bandwidth * 8, stream_must_be_sender)); 3185 else 3186 if (test->role == 's' && !sp->sender) { 3187 if (test->verbose) 3188 iperf_printf(test, report_sender_not_available_format, sp->socket); 3189 } 3190 else { 3191 iperf_printf(test, report_bw_format, sp->socket, mbuf, start_time, sender_time, ubuf, nbuf, report_sender); 3192 } 3193 } 3194 } else { 3195 /* Sender summary, UDP. */ 3196 if (sender_packet_count - sp->omitted_packet_count > 0) { 3197 lost_percent = 100.0 * (sp->cnt_error - sp->omitted_cnt_error) / (sender_packet_count - sp->omitted_packet_count); 3198 } 3199 else { 3200 lost_percent = 0.0; 3201 } 3202 if (test->json_output) { 3203 /* 3204 * For hysterical raisins, we only emit one JSON 3205 * object for the UDP summary, and it contains 3206 * information for both the sender and receiver 3207 * side. 3208 * 3209 * The JSON format as currently defined only includes one 3210 * value for the number of packets. We usually want that 3211 * to be the sender's value (how many packets were sent 3212 * by the sender). However this value might not be 3213 * available on the receiver in certain circumstances 3214 * specifically on the server side for a normal test or 3215 * the client side for a reverse-mode test. If this 3216 * is the case, then use the receiver's count of packets 3217 * instead. 3218 */ 3219 int packet_count = sender_packet_count ? sender_packet_count : receiver_packet_count; 3220 cJSON_AddItemToObject(json_summary_stream, "udp", iperf_json_printf("socket: %d start: %f end: %f seconds: %f bytes: %d bits_per_second: %f jitter_ms: %f lost_packets: %d packets: %d lost_percent: %f out_of_order: %d sender: %b", (int64_t) sp->socket, (double) start_time, (double) sender_time, (double) sender_time, (int64_t) bytes_sent, bandwidth * 8, (double) sp->jitter * 1000.0, (int64_t) (sp->cnt_error - sp->omitted_cnt_error), (int64_t) (packet_count - sp->omitted_packet_count), (double) lost_percent, (int64_t) (sp->outoforder_packets - sp->omitted_outoforder_packets), stream_must_be_sender)); 3221 } 3222 else { 3223 /* 3224 * Due to ordering of messages on the control channel, 3225 * the server cannot report on client-side summary 3226 * statistics. If we're the server, omit one set of 3227 * summary statistics to avoid giving meaningless 3228 * results. 3229 */ 3230 if (test->role == 's' && !sp->sender) { 3231 if (test->verbose) 3232 iperf_printf(test, report_sender_not_available_format, sp->socket); 3233 } 3234 else { 3235 iperf_printf(test, report_bw_udp_format, sp->socket, mbuf, start_time, sender_time, ubuf, nbuf, 0.0, 0, (sender_packet_count - sp->omitted_packet_count), (double) 0, report_sender); 3236 } 3237 if ((sp->outoforder_packets - sp->omitted_outoforder_packets) > 0) 3238 iperf_printf(test, report_sum_outoforder, mbuf, start_time, sender_time, (sp->outoforder_packets - sp->omitted_outoforder_packets)); 3239 } 3240 } 3241 3242 if (sp->diskfile_fd >= 0) { 3243 if (fstat(sp->diskfile_fd, &sb) == 0) { 3244 /* In the odd case that it's a zero-sized file, say it was all transferred. */ 3245 int percent_sent = 100, percent_received = 100; 3246 if (sb.st_size > 0) { 3247 percent_sent = (int) ( ( (double) bytes_sent / (double) sb.st_size ) * 100.0 ); 3248 percent_received = (int) ( ( (double) bytes_received / (double) sb.st_size ) * 100.0 ); 3249 } 3250 unit_snprintf(sbuf, UNIT_LEN, (double) sb.st_size, 'A'); 3251 if (test->json_output) 3252 cJSON_AddItemToObject(json_summary_stream, "diskfile", iperf_json_printf("sent: %d received: %d size: %d percent_sent: %d percent_received: %d filename: %s", (int64_t) bytes_sent, (int64_t) bytes_received, (int64_t) sb.st_size, (int64_t) percent_sent, (int64_t) percent_received, test->diskfile_name)); 3253 else 3254 if (stream_must_be_sender) { 3255 iperf_printf(test, report_diskfile, ubuf, sbuf, percent_sent, test->diskfile_name); 3256 } 3257 else { 3258 unit_snprintf(ubuf, UNIT_LEN, (double) bytes_received, 'A'); 3259 iperf_printf(test, report_diskfile, ubuf, sbuf, percent_received, test->diskfile_name); 3260 } 3261 } 3262 } 3263 3264 unit_snprintf(ubuf, UNIT_LEN, (double) bytes_received, 'A'); 3265 if (receiver_time > 0) { 3266 bandwidth = (double) bytes_received / (double) receiver_time; 3267 } 3268 else { 3269 bandwidth = 0.0; 3270 } 3271 unit_snprintf(nbuf, UNIT_LEN, bandwidth, test->settings->unit_format); 3272 if (test->protocol->id == Ptcp || test->protocol->id == Psctp) { 3273 /* Receiver summary, TCP and SCTP */ 3274 if (test->json_output) 3275 cJSON_AddItemToObject(json_summary_stream, "receiver", iperf_json_printf("socket: %d start: %f end: %f seconds: %f bytes: %d bits_per_second: %f sender: %b", (int64_t) sp->socket, (double) start_time, (double) receiver_time, (double) end_time, (int64_t) bytes_received, bandwidth * 8, stream_must_be_sender)); 3276 else 3277 if (test->role == 's' && sp->sender) { 3278 if (test->verbose) 3279 iperf_printf(test, report_receiver_not_available_format, sp->socket); 3280 } 3281 else { 3282 iperf_printf(test, report_bw_format, sp->socket, mbuf, start_time, receiver_time, ubuf, nbuf, report_receiver); 3283 } 3284 } 3285 else { 3286 /* 3287 * Receiver summary, UDP. Note that JSON was emitted with 3288 * the sender summary, so we only deal with human-readable 3289 * data here. 3290 */ 3291 if (! test->json_output) { 3292 if (receiver_packet_count - sp->omitted_packet_count > 0) { 3293 lost_percent = 100.0 * (sp->cnt_error - sp->omitted_cnt_error) / (receiver_packet_count - sp->omitted_packet_count); 3294 } 3295 else { 3296 lost_percent = 0.0; 3297 } 3298 3299 if (test->role == 's' && sp->sender) { 3300 if (test->verbose) 3301 iperf_printf(test, report_receiver_not_available_format, sp->socket); 3302 } 3303 else { 3304 iperf_printf(test, report_bw_udp_format, sp->socket, mbuf, start_time, receiver_time, ubuf, nbuf, sp->jitter * 1000.0, (sp->cnt_error - sp->omitted_cnt_error), (receiver_packet_count - sp->omitted_packet_count), lost_percent, report_receiver); 3305 } 3306 } 3307 } 3308 } 3309 } 3310 } 3311 3312 if (test->num_streams > 1 || test->json_output) { 3313 unit_snprintf(ubuf, UNIT_LEN, (double) total_sent, 'A'); 3314 /* If no tests were run, arbitrarily set bandwidth to 0. */ 3315 if (sender_time > 0.0) { 3316 bandwidth = (double) total_sent / (double) sender_time; 3317 } 3318 else { 3319 bandwidth = 0.0; 3320 } 3321 unit_snprintf(nbuf, UNIT_LEN, bandwidth, test->settings->unit_format); 3322 if (test->protocol->id == Ptcp || test->protocol->id == Psctp) { 3323 if (test->sender_has_retransmits) { 3324 /* Summary sum, TCP with retransmits. */ 3325 if (test->json_output) 3326 cJSON_AddItemToObject(test->json_end, "sum_sent", iperf_json_printf("start: %f end: %f seconds: %f bytes: %d bits_per_second: %f retransmits: %d sender: %b", (double) start_time, (double) sender_time, (double) sender_time, (int64_t) total_sent, bandwidth * 8, (int64_t) total_retransmits, stream_must_be_sender)); 3327 else 3328 if (test->role == 's' && !stream_must_be_sender) { 3329 if (test->verbose) 3330 iperf_printf(test, report_sender_not_available_summary_format, "SUM"); 3331 } 3332 else { 3333 iperf_printf(test, report_sum_bw_retrans_format, mbuf, start_time, sender_time, ubuf, nbuf, total_retransmits, report_sender); 3334 } 3335 } else { 3336 /* Summary sum, TCP without retransmits. */ 3337 if (test->json_output) 3338 cJSON_AddItemToObject(test->json_end, "sum_sent", iperf_json_printf("start: %f end: %f seconds: %f bytes: %d bits_per_second: %f sender: %b", (double) start_time, (double) sender_time, (double) sender_time, (int64_t) total_sent, bandwidth * 8, stream_must_be_sender)); 3339 else 3340 if (test->role == 's' && !stream_must_be_sender) { 3341 if (test->verbose) 3342 iperf_printf(test, report_sender_not_available_summary_format, "SUM"); 3343 } 3344 else { 3345 iperf_printf(test, report_sum_bw_format, mbuf, start_time, sender_time, ubuf, nbuf, report_sender); 3346 } 3347 } 3348 unit_snprintf(ubuf, UNIT_LEN, (double) total_received, 'A'); 3349 /* If no tests were run, set received bandwidth to 0 */ 3350 if (receiver_time > 0.0) { 3351 bandwidth = (double) total_received / (double) receiver_time; 3352 } 3353 else { 3354 bandwidth = 0.0; 3355 } 3356 unit_snprintf(nbuf, UNIT_LEN, bandwidth, test->settings->unit_format); 3357 if (test->json_output) 3358 cJSON_AddItemToObject(test->json_end, "sum_received", iperf_json_printf("start: %f end: %f seconds: %f bytes: %d bits_per_second: %f sender: %b", (double) start_time, (double) receiver_time, (double) receiver_time, (int64_t) total_received, bandwidth * 8, stream_must_be_sender)); 3359 else 3360 if (test->role == 's' && stream_must_be_sender) { 3361 if (test->verbose) 3362 iperf_printf(test, report_receiver_not_available_summary_format, "SUM"); 3363 } 3364 else { 3365 iperf_printf(test, report_sum_bw_format, mbuf, start_time, receiver_time, ubuf, nbuf, report_receiver); 3366 } 3367 } else { 3368 /* Summary sum, UDP. */ 3369 avg_jitter /= test->num_streams; 3370 /* If no packets were sent, arbitrarily set loss percentage to 0. */ 3371 if (total_packets > 0) { 3372 lost_percent = 100.0 * lost_packets / total_packets; 3373 } 3374 else { 3375 lost_percent = 0.0; 3376 } 3377 if (test->json_output) 3378 cJSON_AddItemToObject(test->json_end, "sum", iperf_json_printf("start: %f end: %f seconds: %f bytes: %d bits_per_second: %f jitter_ms: %f lost_packets: %d packets: %d lost_percent: %f sender: %b", (double) start_time, (double) receiver_time, (double) receiver_time, (int64_t) total_sent, bandwidth * 8, (double) avg_jitter * 1000.0, (int64_t) lost_packets, (int64_t) total_packets, (double) lost_percent, stream_must_be_sender)); 3379 else { 3380 /* 3381 * On the client we have both sender and receiver overall summary 3382 * stats. On the server we have only the side that was on the 3383 * server. Output whatever we have. 3384 */ 3385 if (! (test->role == 's' && !stream_must_be_sender) ) { 3386 unit_snprintf(ubuf, UNIT_LEN, (double) total_sent, 'A'); 3387 iperf_printf(test, report_sum_bw_udp_format, mbuf, start_time, sender_time, ubuf, nbuf, 0.0, 0, sender_total_packets, 0.0, "sender"); 3388 } 3389 if (! (test->role == 's' && stream_must_be_sender) ) { 3390 3391 unit_snprintf(ubuf, UNIT_LEN, (double) total_received, 'A'); 3392 /* Compute received bandwidth. */ 3393 if (end_time > 0.0) { 3394 bandwidth = (double) total_received / (double) receiver_time; 3395 } 3396 else { 3397 bandwidth = 0.0; 3398 } 3399 unit_snprintf(nbuf, UNIT_LEN, bandwidth, test->settings->unit_format); 3400 iperf_printf(test, report_sum_bw_udp_format, mbuf, start_time, receiver_time, ubuf, nbuf, avg_jitter * 1000.0, lost_packets, receiver_total_packets, lost_percent, "receiver"); 3401 } 3402 } 3403 } 3404 } 3405 3406 if (test->json_output && current_mode == upper_mode) { 3407 cJSON_AddItemToObject(test->json_end, "cpu_utilization_percent", iperf_json_printf("host_total: %f host_user: %f host_system: %f remote_total: %f remote_user: %f remote_system: %f", (double) test->cpu_util[0], (double) test->cpu_util[1], (double) test->cpu_util[2], (double) test->remote_cpu_util[0], (double) test->remote_cpu_util[1], (double) test->remote_cpu_util[2])); 3408 if (test->protocol->id == Ptcp) { 3409 char *snd_congestion = NULL, *rcv_congestion = NULL; 3410 if (stream_must_be_sender) { 3411 snd_congestion = test->congestion_used; 3412 rcv_congestion = test->remote_congestion_used; 3413 } 3414 else { 3415 snd_congestion = test->remote_congestion_used; 3416 rcv_congestion = test->congestion_used; 3417 } 3418 if (snd_congestion) { 3419 cJSON_AddStringToObject(test->json_end, "sender_tcp_congestion", snd_congestion); 3420 } 3421 if (rcv_congestion) { 3422 cJSON_AddStringToObject(test->json_end, "receiver_tcp_congestion", rcv_congestion); 3423 } 3424 } 3425 } 3426 else { 3427 if (test->verbose) { 3428 if (stream_must_be_sender) { 3429 if (test->bidirectional) { 3430 iperf_printf(test, report_cpu, report_local, stream_must_be_sender?report_sender:report_receiver, test->cpu_util[0], test->cpu_util[1], test->cpu_util[2], report_remote, stream_must_be_sender?report_receiver:report_sender, test->remote_cpu_util[0], test->remote_cpu_util[1], test->remote_cpu_util[2]); 3431 iperf_printf(test, report_cpu, report_local, !stream_must_be_sender?report_sender:report_receiver, test->cpu_util[0], test->cpu_util[1], test->cpu_util[2], report_remote, !stream_must_be_sender?report_receiver:report_sender, test->remote_cpu_util[0], test->remote_cpu_util[1], test->remote_cpu_util[2]); 3432 } else 3433 iperf_printf(test, report_cpu, report_local, stream_must_be_sender?report_sender:report_receiver, test->cpu_util[0], test->cpu_util[1], test->cpu_util[2], report_remote, stream_must_be_sender?report_receiver:report_sender, test->remote_cpu_util[0], test->remote_cpu_util[1], test->remote_cpu_util[2]); 3434 } 3435 if (test->protocol->id == Ptcp) { 3436 char *snd_congestion = NULL, *rcv_congestion = NULL; 3437 if (stream_must_be_sender) { 3438 snd_congestion = test->congestion_used; 3439 rcv_congestion = test->remote_congestion_used; 3440 } 3441 else { 3442 snd_congestion = test->remote_congestion_used; 3443 rcv_congestion = test->congestion_used; 3444 } 3445 if (snd_congestion) { 3446 iperf_printf(test, "snd_tcp_congestion %s\n", snd_congestion); 3447 } 3448 if (rcv_congestion) { 3449 iperf_printf(test, "rcv_tcp_congestion %s\n", rcv_congestion); 3450 } 3451 } 3452 } 3453 3454 /* Print server output if we're on the client and it was requested/provided */ 3455 if (test->role == 'c' && iperf_get_test_get_server_output(test) && !test->json_output) { 3456 if (test->json_server_output) { 3457 char *str = cJSON_Print(test->json_server_output); 3458 iperf_printf(test, "\nServer JSON output:\n%s\n", str); 3459 cJSON_free(str); 3460 cJSON_Delete(test->json_server_output); 3461 test->json_server_output = NULL; 3462 } 3463 if (test->server_output_text) { 3464 iperf_printf(test, "\nServer output:\n%s\n", test->server_output_text); 3465 test->server_output_text = NULL; 3466 } 3467 } 3468 } 3469 } 3470 3471 /* Set real sender_has_retransmits for current side */ 3472 if (test->mode == BIDIRECTIONAL) 3473 test->sender_has_retransmits = tmp_sender_has_retransmits; 3474 } 3475 3476 /**************************************************************************/ 3477 3478 /** 3479 * Main report-printing callback. 3480 * Prints results either during a test (interval report only) or 3481 * after the entire test has been run (last interval report plus 3482 * overall summary). 3483 */ 3484 void 3485 iperf_reporter_callback(struct iperf_test *test) 3486 { 3487 switch (test->state) { 3488 case TEST_RUNNING: 3489 case STREAM_RUNNING: 3490 /* print interval results for each stream */ 3491 iperf_print_intermediate(test); 3492 break; 3493 case TEST_END: 3494 case DISPLAY_RESULTS: 3495 iperf_print_intermediate(test); 3496 iperf_print_results(test); 3497 break; 3498 } 3499 3500 } 3501 3502 /** 3503 * Print the interval results for one stream. 3504 * This function needs to know about the overall test so it can determine the 3505 * context for printing headers, separators, etc. 3506 */ 3507 static void 3508 print_interval_results(struct iperf_test *test, struct iperf_stream *sp, cJSON *json_interval_streams) 3509 { 3510 char ubuf[UNIT_LEN]; 3511 char nbuf[UNIT_LEN]; 3512 char cbuf[UNIT_LEN]; 3513 char mbuf[UNIT_LEN]; 3514 char zbuf[] = " "; 3515 double st = 0., et = 0.; 3516 struct iperf_time temp_time; 3517 struct iperf_interval_results *irp = NULL; 3518 double bandwidth, lost_percent; 3519 3520 if (test->mode == BIDIRECTIONAL) { 3521 sprintf(mbuf, "[%s-%s]", sp->sender?"TX":"RX", test->role == 'c'?"C":"S"); 3522 } else { 3523 mbuf[0] = '\0'; 3524 zbuf[0] = '\0'; 3525 } 3526 3527 irp = TAILQ_LAST(&sp->result->interval_results, irlisthead); /* get last entry in linked list */ 3528 if (irp == NULL) { 3529 iperf_err(test, "print_interval_results error: interval_results is NULL"); 3530 return; 3531 } 3532 if (!test->json_output) { 3533 /* First stream? */ 3534 if (sp == SLIST_FIRST(&test->streams)) { 3535 /* It it's the first interval, print the header; 3536 ** else if there's more than one stream, print the separator; 3537 ** else nothing. 3538 */ 3539 if (iperf_time_compare(&sp->result->start_time, &irp->interval_start_time) == 0) { 3540 if (test->protocol->id == Ptcp || test->protocol->id == Psctp) { 3541 if (test->sender_has_retransmits == 1) { 3542 if (test->bidirectional) 3543 iperf_printf(test, "%s", report_bw_retrans_cwnd_header_bidir); 3544 else 3545 iperf_printf(test, "%s", report_bw_retrans_cwnd_header); 3546 } 3547 else { 3548 if (test->bidirectional) 3549 iperf_printf(test, "%s", report_bw_header_bidir); 3550 else 3551 iperf_printf(test, "%s", report_bw_header); 3552 } 3553 } else { 3554 if (test->mode == SENDER) { 3555 iperf_printf(test, "%s", report_bw_udp_sender_header); 3556 } else if (test->mode == RECEIVER){ 3557 iperf_printf(test, "%s", report_bw_udp_header); 3558 } else { 3559 /* BIDIRECTIONAL */ 3560 iperf_printf(test, "%s", report_bw_udp_header_bidir); 3561 } 3562 } 3563 } else if (test->num_streams > 1) 3564 iperf_printf(test, "%s", report_bw_separator); 3565 } 3566 } 3567 3568 unit_snprintf(ubuf, UNIT_LEN, (double) (irp->bytes_transferred), 'A'); 3569 if (irp->interval_duration > 0.0) { 3570 bandwidth = (double) irp->bytes_transferred / (double) irp->interval_duration; 3571 } 3572 else { 3573 bandwidth = 0.0; 3574 } 3575 unit_snprintf(nbuf, UNIT_LEN, bandwidth, test->settings->unit_format); 3576 3577 iperf_time_diff(&sp->result->start_time, &irp->interval_start_time, &temp_time); 3578 st = iperf_time_in_secs(&temp_time); 3579 iperf_time_diff(&sp->result->start_time, &irp->interval_end_time, &temp_time); 3580 et = iperf_time_in_secs(&temp_time); 3581 3582 if (test->protocol->id == Ptcp || test->protocol->id == Psctp) { 3583 if (test->sender_has_retransmits == 1 && sp->sender) { 3584 /* Interval, TCP with retransmits. */ 3585 if (test->json_output) 3586 cJSON_AddItemToArray(json_interval_streams, iperf_json_printf("socket: %d start: %f end: %f seconds: %f bytes: %d bits_per_second: %f retransmits: %d snd_cwnd: %d rtt: %d rttvar: %d pmtu: %d omitted: %b sender: %b", (int64_t) sp->socket, (double) st, (double) et, (double) irp->interval_duration, (int64_t) irp->bytes_transferred, bandwidth * 8, (int64_t) irp->interval_retrans, (int64_t) irp->snd_cwnd, (int64_t) irp->rtt, (int64_t) irp->rttvar, (int64_t) irp->pmtu, irp->omitted, sp->sender)); 3587 else { 3588 unit_snprintf(cbuf, UNIT_LEN, irp->snd_cwnd, 'A'); 3589 iperf_printf(test, report_bw_retrans_cwnd_format, sp->socket, mbuf, st, et, ubuf, nbuf, irp->interval_retrans, cbuf, irp->omitted?report_omitted:""); 3590 } 3591 } else { 3592 /* Interval, TCP without retransmits. */ 3593 if (test->json_output) 3594 cJSON_AddItemToArray(json_interval_streams, iperf_json_printf("socket: %d start: %f end: %f seconds: %f bytes: %d bits_per_second: %f omitted: %b sender: %b", (int64_t) sp->socket, (double) st, (double) et, (double) irp->interval_duration, (int64_t) irp->bytes_transferred, bandwidth * 8, irp->omitted, sp->sender)); 3595 else 3596 iperf_printf(test, report_bw_format, sp->socket, mbuf, st, et, ubuf, nbuf, irp->omitted?report_omitted:""); 3597 } 3598 } else { 3599 /* Interval, UDP. */ 3600 if (sp->sender) { 3601 if (test->json_output) 3602 cJSON_AddItemToArray(json_interval_streams, iperf_json_printf("socket: %d start: %f end: %f seconds: %f bytes: %d bits_per_second: %f packets: %d omitted: %b sender: %b", (int64_t) sp->socket, (double) st, (double) et, (double) irp->interval_duration, (int64_t) irp->bytes_transferred, bandwidth * 8, (int64_t) irp->interval_packet_count, irp->omitted, sp->sender)); 3603 else 3604 iperf_printf(test, report_bw_udp_sender_format, sp->socket, mbuf, st, et, ubuf, nbuf, zbuf, irp->interval_packet_count, irp->omitted?report_omitted:""); 3605 } else { 3606 if (irp->interval_packet_count > 0) { 3607 lost_percent = 100.0 * irp->interval_cnt_error / irp->interval_packet_count; 3608 } 3609 else { 3610 lost_percent = 0.0; 3611 } 3612 if (test->json_output) 3613 cJSON_AddItemToArray(json_interval_streams, iperf_json_printf("socket: %d start: %f end: %f seconds: %f bytes: %d bits_per_second: %f jitter_ms: %f lost_packets: %d packets: %d lost_percent: %f omitted: %b sender: %b", (int64_t) sp->socket, (double) st, (double) et, (double) irp->interval_duration, (int64_t) irp->bytes_transferred, bandwidth * 8, (double) irp->jitter * 1000.0, (int64_t) irp->interval_cnt_error, (int64_t) irp->interval_packet_count, (double) lost_percent, irp->omitted, sp->sender)); 3614 else 3615 iperf_printf(test, report_bw_udp_format, sp->socket, mbuf, st, et, ubuf, nbuf, irp->jitter * 1000.0, irp->interval_cnt_error, irp->interval_packet_count, lost_percent, irp->omitted?report_omitted:""); 3616 } 3617 } 3618 3619 if (test->logfile || test->forceflush) 3620 iflush(test); 3621 } 3622 3623 /**************************************************************************/ 3624 void 3625 iperf_free_stream(struct iperf_stream *sp) 3626 { 3627 struct iperf_interval_results *irp, *nirp; 3628 3629 /* XXX: need to free interval list too! */ 3630 munmap(sp->buffer, sp->test->settings->blksize); 3631 close(sp->buffer_fd); 3632 if (sp->diskfile_fd >= 0) 3633 close(sp->diskfile_fd); 3634 for (irp = TAILQ_FIRST(&sp->result->interval_results); irp != NULL; irp = nirp) { 3635 nirp = TAILQ_NEXT(irp, irlistentries); 3636 free(irp); 3637 } 3638 free(sp->result); 3639 if (sp->send_timer != NULL) 3640 tmr_cancel(sp->send_timer); 3641 free(sp); 3642 } 3643 3644 /**************************************************************************/ 3645 struct iperf_stream * 3646 iperf_new_stream(struct iperf_test *test, int s, int sender) 3647 { 3648 struct iperf_stream *sp; 3649 int ret = 0; 3650 3651 char template[1024]; 3652 if (test->tmp_template) { 3653 snprintf(template, sizeof(template) / sizeof(char), "%s", test->tmp_template); 3654 } else { 3655 //find the system temporary dir *unix, windows, cygwin support 3656 char* tempdir = getenv("TMPDIR"); 3657 if (tempdir == 0){ 3658 tempdir = getenv("TEMP"); 3659 } 3660 if (tempdir == 0){ 3661 tempdir = getenv("TMP"); 3662 } 3663 if (tempdir == 0){ 3664 tempdir = "/tmp"; 3665 } 3666 snprintf(template, sizeof(template) / sizeof(char), "%s/iperf3.XXXXXX", tempdir); 3667 } 3668 3669 sp = (struct iperf_stream *) malloc(sizeof(struct iperf_stream)); 3670 if (!sp) { 3671 i_errno = IECREATESTREAM; 3672 return NULL; 3673 } 3674 3675 memset(sp, 0, sizeof(struct iperf_stream)); 3676 3677 sp->sender = sender; 3678 sp->test = test; 3679 sp->settings = test->settings; 3680 sp->result = (struct iperf_stream_result *) malloc(sizeof(struct iperf_stream_result)); 3681 if (!sp->result) { 3682 free(sp); 3683 i_errno = IECREATESTREAM; 3684 return NULL; 3685 } 3686 3687 memset(sp->result, 0, sizeof(struct iperf_stream_result)); 3688 TAILQ_INIT(&sp->result->interval_results); 3689 3690 /* Create and randomize the buffer */ 3691 sp->buffer_fd = mkstemp(template); 3692 if (sp->buffer_fd == -1) { 3693 i_errno = IECREATESTREAM; 3694 free(sp->result); 3695 free(sp); 3696 return NULL; 3697 } 3698 if (unlink(template) < 0) { 3699 i_errno = IECREATESTREAM; 3700 free(sp->result); 3701 free(sp); 3702 return NULL; 3703 } 3704 if (ftruncate(sp->buffer_fd, test->settings->blksize) < 0) { 3705 i_errno = IECREATESTREAM; 3706 free(sp->result); 3707 free(sp); 3708 return NULL; 3709 } 3710 sp->buffer = (char *) mmap(NULL, test->settings->blksize, PROT_READ|PROT_WRITE, MAP_PRIVATE, sp->buffer_fd, 0); 3711 if (sp->buffer == MAP_FAILED) { 3712 i_errno = IECREATESTREAM; 3713 free(sp->result); 3714 free(sp); 3715 return NULL; 3716 } 3717 3718 /* Set socket */ 3719 sp->socket = s; 3720 3721 sp->snd = test->protocol->send; 3722 sp->rcv = test->protocol->recv; 3723 3724 if (test->diskfile_name != (char*) 0) { 3725 sp->diskfile_fd = open(test->diskfile_name, sender ? O_RDONLY : (O_WRONLY|O_CREAT|O_TRUNC), S_IRUSR|S_IWUSR); 3726 if (sp->diskfile_fd == -1) { 3727 i_errno = IEFILE; 3728 munmap(sp->buffer, sp->test->settings->blksize); 3729 free(sp->result); 3730 free(sp); 3731 return NULL; 3732 } 3733 sp->snd2 = sp->snd; 3734 sp->snd = diskfile_send; 3735 sp->rcv2 = sp->rcv; 3736 sp->rcv = diskfile_recv; 3737 } else 3738 sp->diskfile_fd = -1; 3739 3740 /* Initialize stream */ 3741 if (test->repeating_payload) 3742 fill_with_repeating_pattern(sp->buffer, test->settings->blksize); 3743 else 3744 ret = readentropy(sp->buffer, test->settings->blksize); 3745 3746 if ((ret < 0) || (iperf_init_stream(sp, test) < 0)) { 3747 close(sp->buffer_fd); 3748 munmap(sp->buffer, sp->test->settings->blksize); 3749 free(sp->result); 3750 free(sp); 3751 return NULL; 3752 } 3753 iperf_add_stream(test, sp); 3754 3755 return sp; 3756 } 3757 3758 /**************************************************************************/ 3759 int 3760 iperf_init_stream(struct iperf_stream *sp, struct iperf_test *test) 3761 { 3762 socklen_t len; 3763 int opt; 3764 3765 len = sizeof(struct sockaddr_storage); 3766 if (getsockname(sp->socket, (struct sockaddr *) &sp->local_addr, &len) < 0) { 3767 i_errno = IEINITSTREAM; 3768 return -1; 3769 } 3770 len = sizeof(struct sockaddr_storage); 3771 if (getpeername(sp->socket, (struct sockaddr *) &sp->remote_addr, &len) < 0) { 3772 i_errno = IEINITSTREAM; 3773 return -1; 3774 } 3775 3776 /* Set IP TOS */ 3777 if ((opt = test->settings->tos)) { 3778 if (getsockdomain(sp->socket) == AF_INET6) { 3779 #ifdef IPV6_TCLASS 3780 if (setsockopt(sp->socket, IPPROTO_IPV6, IPV6_TCLASS, &opt, sizeof(opt)) < 0) { 3781 i_errno = IESETCOS; 3782 return -1; 3783 } 3784 #else 3785 i_errno = IESETCOS; 3786 return -1; 3787 #endif 3788 } else { 3789 if (setsockopt(sp->socket, IPPROTO_IP, IP_TOS, &opt, sizeof(opt)) < 0) { 3790 i_errno = IESETTOS; 3791 return -1; 3792 } 3793 } 3794 } 3795 3796 return 0; 3797 } 3798 3799 /**************************************************************************/ 3800 void 3801 iperf_add_stream(struct iperf_test *test, struct iperf_stream *sp) 3802 { 3803 int i; 3804 struct iperf_stream *n, *prev; 3805 3806 if (SLIST_EMPTY(&test->streams)) { 3807 SLIST_INSERT_HEAD(&test->streams, sp, streams); 3808 sp->id = 1; 3809 } else { 3810 // for (n = test->streams, i = 2; n->next; n = n->next, ++i); 3811 i = 2; 3812 SLIST_FOREACH(n, &test->streams, streams) { 3813 prev = n; 3814 ++i; 3815 } 3816 SLIST_INSERT_AFTER(prev, sp, streams); 3817 sp->id = i; 3818 } 3819 } 3820 3821 /* This pair of routines gets inserted into the snd/rcv function pointers 3822 ** when there's a -F flag. They handle the file stuff and call the real 3823 ** snd/rcv functions, which have been saved in snd2/rcv2. 3824 ** 3825 ** The advantage of doing it this way is that in the much more common 3826 ** case of no -F flag, there is zero extra overhead. 3827 */ 3828 3829 static int 3830 diskfile_send(struct iperf_stream *sp) 3831 { 3832 int r; 3833 static int rtot; 3834 3835 /* if needed, read enough data from the disk to fill up the buffer */ 3836 if (sp->diskfile_left < sp->test->settings->blksize && !sp->test->done) { 3837 r = read(sp->diskfile_fd, sp->buffer, sp->test->settings->blksize - 3838 sp->diskfile_left); 3839 rtot += r; 3840 if (sp->test->debug) { 3841 printf("read %d bytes from file, %d total\n", r, rtot); 3842 if (r != sp->test->settings->blksize - sp->diskfile_left) 3843 printf("possible eof\n"); 3844 } 3845 /* If there's no data left in the file or in the buffer, we're done */ 3846 if (r == 0 && sp->diskfile_left == 0) { 3847 sp->test->done = 1; 3848 if (sp->test->debug) 3849 printf("done\n"); 3850 } 3851 } 3852 3853 r = sp->snd2(sp); 3854 if (r < 0) { 3855 return r; 3856 } 3857 /* 3858 * Compute how much data is in the buffer but didn't get sent. 3859 * If there are bytes that got left behind, slide them to the 3860 * front of the buffer so they can hopefully go out on the next 3861 * pass. 3862 */ 3863 sp->diskfile_left = sp->test->settings->blksize - r; 3864 if (sp->diskfile_left && sp->diskfile_left < sp->test->settings->blksize) { 3865 memcpy(sp->buffer, 3866 sp->buffer + (sp->test->settings->blksize - sp->diskfile_left), 3867 sp->diskfile_left); 3868 if (sp->test->debug) 3869 printf("Shifting %d bytes by %d\n", sp->diskfile_left, (sp->test->settings->blksize - sp->diskfile_left)); 3870 } 3871 return r; 3872 } 3873 3874 static int 3875 diskfile_recv(struct iperf_stream *sp) 3876 { 3877 int r; 3878 3879 r = sp->rcv2(sp); 3880 if (r > 0) { 3881 (void) write(sp->diskfile_fd, sp->buffer, r); 3882 (void) fsync(sp->diskfile_fd); 3883 } 3884 return r; 3885 } 3886 3887 3888 void 3889 iperf_catch_sigend(void (*handler)(int)) 3890 { 3891 #ifdef SIGINT 3892 signal(SIGINT, handler); 3893 #endif 3894 #ifdef SIGTERM 3895 signal(SIGTERM, handler); 3896 #endif 3897 #ifdef SIGHUP 3898 signal(SIGHUP, handler); 3899 #endif 3900 } 3901 3902 /** 3903 * Called as a result of getting a signal. 3904 * Depending on the current state of the test (and the role of this 3905 * process) compute and report one more set of ending statistics 3906 * before cleaning up and exiting. 3907 */ 3908 void 3909 iperf_got_sigend(struct iperf_test *test) 3910 { 3911 /* 3912 * If we're the client, or if we're a server and running a test, 3913 * then dump out the accumulated stats so far. 3914 */ 3915 if (test->role == 'c' || 3916 (test->role == 's' && test->state == TEST_RUNNING)) { 3917 3918 test->done = 1; 3919 cpu_util(test->cpu_util); 3920 test->stats_callback(test); 3921 test->state = DISPLAY_RESULTS; /* change local state only */ 3922 if (test->on_test_finish) 3923 test->on_test_finish(test); 3924 test->reporter_callback(test); 3925 } 3926 3927 if (test->ctrl_sck >= 0) { 3928 test->state = (test->role == 'c') ? CLIENT_TERMINATE : SERVER_TERMINATE; 3929 (void) Nwrite(test->ctrl_sck, (char*) &test->state, sizeof(signed char), Ptcp); 3930 } 3931 i_errno = (test->role == 'c') ? IECLIENTTERM : IESERVERTERM; 3932 iperf_errexit(test, "interrupt - %s", iperf_strerror(i_errno)); 3933 } 3934 3935 /* Try to write a PID file if requested, return -1 on an error. */ 3936 int 3937 iperf_create_pidfile(struct iperf_test *test) 3938 { 3939 if (test->pidfile) { 3940 int fd; 3941 char buf[8]; 3942 3943 /* See if the file already exists and we can read it. */ 3944 fd = open(test->pidfile, O_RDONLY, 0); 3945 if (fd >= 0) { 3946 if (read(fd, buf, sizeof(buf) - 1) >= 0) { 3947 3948 /* We read some bytes, see if they correspond to a valid PID */ 3949 pid_t pid; 3950 pid = atoi(buf); 3951 if (pid > 0) { 3952 3953 /* See if the process exists. */ 3954 if (kill(pid, 0) == 0) { 3955 /* 3956 * Make sure not to try to delete existing PID file by 3957 * scribbling over the pathname we'd use to refer to it. 3958 * Then exit with an error. 3959 */ 3960 free(test->pidfile); 3961 test->pidfile = NULL; 3962 iperf_errexit(test, "Another instance of iperf3 appears to be running"); 3963 } 3964 } 3965 } 3966 } 3967 3968 /* 3969 * File didn't exist, we couldn't read it, or it didn't correspond to 3970 * a running process. Try to create it. 3971 */ 3972 fd = open(test->pidfile, O_WRONLY | O_CREAT | O_TRUNC, S_IRUSR|S_IWUSR); 3973 if (fd < 0) { 3974 return -1; 3975 } 3976 snprintf(buf, sizeof(buf), "%d", getpid()); /* no trailing newline */ 3977 if (write(fd, buf, strlen(buf) + 1) < 0) { 3978 return -1; 3979 } 3980 if (close(fd) < 0) { 3981 return -1; 3982 }; 3983 } 3984 return 0; 3985 } 3986 3987 /* Get rid of a PID file, return -1 on error. */ 3988 int 3989 iperf_delete_pidfile(struct iperf_test *test) 3990 { 3991 if (test->pidfile) { 3992 if (unlink(test->pidfile) < 0) { 3993 return -1; 3994 } 3995 } 3996 return 0; 3997 } 3998 3999 int 4000 iperf_json_start(struct iperf_test *test) 4001 { 4002 test->json_top = cJSON_CreateObject(); 4003 if (test->json_top == NULL) 4004 return -1; 4005 test->json_start = cJSON_CreateObject(); 4006 if (test->json_start == NULL) 4007 return -1; 4008 cJSON_AddItemToObject(test->json_top, "start", test->json_start); 4009 test->json_connected = cJSON_CreateArray(); 4010 if (test->json_connected == NULL) 4011 return -1; 4012 cJSON_AddItemToObject(test->json_start, "connected", test->json_connected); 4013 test->json_intervals = cJSON_CreateArray(); 4014 if (test->json_intervals == NULL) 4015 return -1; 4016 cJSON_AddItemToObject(test->json_top, "intervals", test->json_intervals); 4017 test->json_end = cJSON_CreateObject(); 4018 if (test->json_end == NULL) 4019 return -1; 4020 cJSON_AddItemToObject(test->json_top, "end", test->json_end); 4021 return 0; 4022 } 4023 4024 int 4025 iperf_json_finish(struct iperf_test *test) 4026 { 4027 if (test->title) 4028 cJSON_AddStringToObject(test->json_top, "title", test->title); 4029 if (test->extra_data) 4030 cJSON_AddStringToObject(test->json_top, "extra_data", test->extra_data); 4031 /* Include server output */ 4032 if (test->json_server_output) { 4033 cJSON_AddItemToObject(test->json_top, "server_output_json", test->json_server_output); 4034 } 4035 if (test->server_output_text) { 4036 cJSON_AddStringToObject(test->json_top, "server_output_text", test->server_output_text); 4037 } 4038 test->json_output_string = cJSON_Print(test->json_top); 4039 if (test->json_output_string == NULL) 4040 return -1; 4041 fprintf(test->outfile, "%s\n", test->json_output_string); 4042 iflush(test); 4043 cJSON_free(test->json_output_string); 4044 test->json_output_string = NULL; 4045 cJSON_Delete(test->json_top); 4046 test->json_top = test->json_start = test->json_connected = test->json_intervals = test->json_server_output = test->json_end = NULL; 4047 return 0; 4048 } 4049 4050 4051 /* CPU affinity stuff - Linux, FreeBSD, and Windows only. */ 4052 4053 int 4054 iperf_setaffinity(struct iperf_test *test, int affinity) 4055 { 4056 #if defined(HAVE_SCHED_SETAFFINITY) 4057 cpu_set_t cpu_set; 4058 4059 CPU_ZERO(&cpu_set); 4060 CPU_SET(affinity, &cpu_set); 4061 if (sched_setaffinity(0, sizeof(cpu_set_t), &cpu_set) != 0) { 4062 i_errno = IEAFFINITY; 4063 return -1; 4064 } 4065 return 0; 4066 #elif defined(HAVE_CPUSET_SETAFFINITY) 4067 cpuset_t cpumask; 4068 4069 if(cpuset_getaffinity(CPU_LEVEL_WHICH, CPU_WHICH_PID, -1, 4070 sizeof(cpuset_t), &test->cpumask) != 0) { 4071 i_errno = IEAFFINITY; 4072 return -1; 4073 } 4074 4075 CPU_ZERO(&cpumask); 4076 CPU_SET(affinity, &cpumask); 4077 4078 if(cpuset_setaffinity(CPU_LEVEL_WHICH,CPU_WHICH_PID, -1, 4079 sizeof(cpuset_t), &cpumask) != 0) { 4080 i_errno = IEAFFINITY; 4081 return -1; 4082 } 4083 return 0; 4084 #elif defined(HAVE_SETPROCESSAFFINITYMASK) 4085 HANDLE process = GetCurrentProcess(); 4086 DWORD_PTR processAffinityMask = 1 << affinity; 4087 4088 if (SetProcessAffinityMask(process, processAffinityMask) == 0) { 4089 i_errno = IEAFFINITY; 4090 return -1; 4091 } 4092 return 0; 4093 #else /* neither HAVE_SCHED_SETAFFINITY nor HAVE_CPUSET_SETAFFINITY nor HAVE_SETPROCESSAFFINITYMASK */ 4094 i_errno = IEAFFINITY; 4095 return -1; 4096 #endif /* neither HAVE_SCHED_SETAFFINITY nor HAVE_CPUSET_SETAFFINITY nor HAVE_SETPROCESSAFFINITYMASK */ 4097 } 4098 4099 int 4100 iperf_clearaffinity(struct iperf_test *test) 4101 { 4102 #if defined(HAVE_SCHED_SETAFFINITY) 4103 cpu_set_t cpu_set; 4104 int i; 4105 4106 CPU_ZERO(&cpu_set); 4107 for (i = 0; i < CPU_SETSIZE; ++i) 4108 CPU_SET(i, &cpu_set); 4109 if (sched_setaffinity(0, sizeof(cpu_set_t), &cpu_set) != 0) { 4110 i_errno = IEAFFINITY; 4111 return -1; 4112 } 4113 return 0; 4114 #elif defined(HAVE_CPUSET_SETAFFINITY) 4115 if(cpuset_setaffinity(CPU_LEVEL_WHICH,CPU_WHICH_PID, -1, 4116 sizeof(cpuset_t), &test->cpumask) != 0) { 4117 i_errno = IEAFFINITY; 4118 return -1; 4119 } 4120 return 0; 4121 #elif defined(HAVE_SETPROCESSAFFINITYMASK) 4122 HANDLE process = GetCurrentProcess(); 4123 DWORD_PTR processAffinityMask; 4124 DWORD_PTR lpSystemAffinityMask; 4125 4126 if (GetProcessAffinityMask(process, &processAffinityMask, &lpSystemAffinityMask) == 0 4127 || SetProcessAffinityMask(process, lpSystemAffinityMask) == 0) { 4128 i_errno = IEAFFINITY; 4129 return -1; 4130 } 4131 return 0; 4132 #else /* neither HAVE_SCHED_SETAFFINITY nor HAVE_CPUSET_SETAFFINITY nor HAVE_SETPROCESSAFFINITYMASK */ 4133 i_errno = IEAFFINITY; 4134 return -1; 4135 #endif /* neither HAVE_SCHED_SETAFFINITY nor HAVE_CPUSET_SETAFFINITY nor HAVE_SETPROCESSAFFINITYMASK */ 4136 } 4137 4138 int 4139 iperf_printf(struct iperf_test *test, const char* format, ...) 4140 { 4141 va_list argp; 4142 int r = -1; 4143 4144 /* 4145 * There are roughly two use cases here. If we're the client, 4146 * want to print stuff directly to the output stream. 4147 * If we're the sender we might need to buffer up output to send 4148 * to the client. 4149 * 4150 * This doesn't make a whole lot of difference except there are 4151 * some chunks of output on the client (on particular the whole 4152 * of the server output with --get-server-output) that could 4153 * easily exceed the size of the line buffer, but which don't need 4154 * to be buffered up anyway. 4155 */ 4156 if (test->role == 'c') { 4157 if (test->title) 4158 fprintf(test->outfile, "%s: ", test->title); 4159 va_start(argp, format); 4160 r = vfprintf(test->outfile, format, argp); 4161 va_end(argp); 4162 } 4163 else if (test->role == 's') { 4164 char linebuffer[1024]; 4165 va_start(argp, format); 4166 r = vsnprintf(linebuffer, sizeof(linebuffer), format, argp); 4167 va_end(argp); 4168 fprintf(test->outfile, "%s", linebuffer); 4169 4170 if (test->role == 's' && iperf_get_test_get_server_output(test)) { 4171 struct iperf_textline *l = (struct iperf_textline *) malloc(sizeof(struct iperf_textline)); 4172 l->line = strdup(linebuffer); 4173 TAILQ_INSERT_TAIL(&(test->server_output_list), l, textlineentries); 4174 } 4175 } 4176 return r; 4177 } 4178 4179 int 4180 iflush(struct iperf_test *test) 4181 { 4182 return fflush(test->outfile); 4183 } 4184