#ifndef lint char nettest_sctp[]="\ @(#)nettest_sctp.c (c) Copyright 2005-2007 Hewlett-Packard Co. Version 2.4.3"; #else #define DIRTY #define WANT_HISTOGRAM #define WANT_INTERVALS #endif /* lint */ /****************************************************************/ /* */ /* nettest_sctp.c */ /* */ /* */ /* scan_sctp_args() get the sctp command line args */ /* */ /* the actual test routines... */ /* */ /* send_sctp_stream() perform a sctp stream test */ /* recv_sctp_stream() */ /* send_sctp_rr() perform a sctp request/response */ /* recv_sctp_rr() */ /* send_sctp_stream_udp() perform a sctp request/response */ /* recv_sctp_stream_upd() using UDP style API */ /* send_sctp_rr_udp() perform a sctp request/response */ /* recv_sctp_rr_upd() using UDP style API */ /* */ /* relies on create_data_socket in nettest_bsd.c */ /****************************************************************/ #if HAVE_CONFIG_H # include <config.h> #endif #if defined(WANT_SCTP) #include <sys/types.h> #include <fcntl.h> #include <errno.h> #include <signal.h> #include <stdio.h> #include <string.h> #include <time.h> #ifdef NOSTDLIBH #include <malloc.h> #else /* NOSTDLIBH */ #include <stdlib.h> #endif /* NOSTDLIBH */ #if !defined(__VMS) #include <sys/ipc.h> #endif /* !defined(__VMS) */ #include <unistd.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <netinet/tcp.h> #include <netinet/sctp.h> #include <arpa/inet.h> #include <netdb.h> /* would seem that not all sctp.h files define a MSG_EOF, but that MSG_EOF can be the same as MSG_FIN so lets work with that assumption. initial find by Jon Pedersen. raj 2006-02-01 */ #ifndef MSG_EOF #ifdef MSG_FIN #define MSG_EOF MSG_FIN #else #error Must have either MSG_EOF or MSG_FIN defined #endif #endif #include "netlib.h" #include "netsh.h" /* get some of the functions from nettest_bsd.c */ #include "nettest_bsd.h" #include "nettest_sctp.h" #ifdef WANT_HISTOGRAM #ifdef __sgi #include <sys/time.h> #endif /* __sgi */ #include "hist.h" #endif /* WANT_HISTOGRAM */ #ifdef WANT_FIRST_BURST extern int first_burst_size; #endif /* WANT_FIRST_BURST */ /* these variables are specific to SCTP tests. declare */ /* them static to make them global only to this file. */ static int msg_count = 0, /* number of messages to transmit on association */ non_block = 0, /* default to blocking sockets */ num_associations = 1; /* number of associations on the endpoint */ static int confidence_iteration; static char local_cpu_method; static char remote_cpu_method; #ifdef WANT_HISTOGRAM static struct timeval time_one; static struct timeval time_two; static HIST time_hist; #endif /* WANT_HISTOGRAM */ char sctp_usage[] = "\n\ Usage: netperf [global options] -- [test options] \n\ \n\ SCTP Sockets Test Options:\n\ -b number Send number requests at the start of _RR tests\n\ -D [L][,R] Set SCTP_NODELAY locally and/or remotely\n\ -h Display this text\n\ -H name,fam Use name (or IP) and family as target of data connection\n\ -L name,fam Use name (or IP) and family as source of data connextion\n\ -m bytes Set the size of each sent message\n\ -M bytes Set the size of each received messages\n\ -P local[,remote] Set the local/remote port for the data socket\n\ -r req,[rsp] Set request/response sizes (_RR tests)\n\ -s send[,recv] Set local socket send/recv buffer sizes\n\ -S send[,recv] Set remote socket send/recv buffer sizes\n\ -V Enable copy avoidance if supported\n\ -N number Specifies the number of messages to send (_STREAM tests)\n\ -B run the test in non-blocking mode\n\ -T number Number of associations to create (_MANY tests)\n\ -4 Use AF_INET (eg IPv4) on both ends of the data conn\n\ -6 Use AF_INET6 (eg IPv6) on both ends of the data conn\n\ \n\ For those options taking two parms, at least one must be specified;\n\ specifying one value without a comma will set both parms to that\n\ value, specifying a value with a leading comma will set just the second\n\ parm, a value with a trailing comma will set just the first. To set\n\ each parm to unique values, specify both and separate them with a\n\ comma.\n"; /* This routine is intended to retrieve interesting aspects of tcp */ /* for the data connection. at first, it attempts to retrieve the */ /* maximum segment size. later, it might be modified to retrieve */ /* other information, but it must be information that can be */ /* retrieved quickly as it is called during the timing of the test. */ /* for that reason, a second routine may be created that can be */ /* called outside of the timing loop */ static void get_sctp_info(socket, mss) int socket; int *mss; { int sock_opt_len; if (sctp_opt_info(socket, 0, SCTP_MAXSEG, mss, &sock_opt_len) < 0) { lss_size = -1; } } static void sctp_enable_events(socket, ev_mask) int socket; int ev_mask; { struct sctp_event_subscribe ev; bzero(&ev, sizeof(ev)); if (ev_mask & SCTP_SNDRCV_INFO_EV) ev.sctp_data_io_event = 1; if (ev_mask & SCTP_ASSOC_CHANGE_EV) ev.sctp_association_event = 1; if (ev_mask & SCTP_PEERADDR_CHANGE_EV) ev.sctp_address_event = 1; if (ev_mask & SCTP_SND_FAILED_EV) ev.sctp_send_failure_event = 1; if (ev_mask & SCTP_REMOTE_ERROR_EV) ev.sctp_peer_error_event = 1; if (ev_mask & SCTP_SHUTDOWN_EV) ev.sctp_shutdown_event = 1; if (ev_mask & SCTP_PD_EV) ev.sctp_partial_delivery_event = 1; if (ev_mask & SCTP_ADAPT_EV) #ifdef HAVE_SCTP_ADAPTATION_LAYER_EVENT ev.sctp_adaptation_layer_event = 1; #else ev.sctp_adaption_layer_event = 1; #endif if (setsockopt(socket, IPPROTO_SCTP, #ifdef SCTP_EVENTS SCTP_EVENTS, #else SCTP_SET_EVENTS, #endif (const char*)&ev, sizeof(ev)) != 0 ) { fprintf(where, "sctp_enable_event: could not set sctp events errno %d\n", errno); fflush(where); exit(1); } } static sctp_disposition_t sctp_process_event(socket, buf) int socket; void *buf; { struct sctp_assoc_change *sac; struct sctp_send_failed *ssf; struct sctp_paddr_change *spc; struct sctp_remote_error *sre; union sctp_notification *snp; snp = buf; switch (snp->sn_header.sn_type) { case SCTP_ASSOC_CHANGE: if (debug) { fprintf(where, "\tSCTP_ASSOC_CHANGE event, type:"); fflush(where); } sac = &snp->sn_assoc_change; switch (sac->sac_type) { case SCTP_COMM_UP: if (debug) { fprintf(where, " SCTP_COMM_UP\n"); fflush(where); } break; case SCTP_RESTART: if (debug) { fprintf(where, " SCTP_RESTART\n"); fflush(where); } break; case SCTP_CANT_STR_ASSOC: if (debug) { fprintf(where, " SCTP_CANT_STR_ASSOC\n"); fflush(where); } break; /* FIXME ignore above status changes */ case SCTP_COMM_LOST: if (debug) { fprintf(where, " SCTP_COMM_LOST\n"); fflush(where); } return SCTP_CLOSE; case SCTP_SHUTDOWN_COMP: if (debug) { fprintf(where, " SCTP_SHUTDOWN_COMPLETE\n"); fflush(where); } return SCTP_CLOSE; break; } case SCTP_SEND_FAILED: if (debug) { fprintf(where, "\tSCTP_SEND_FAILED event\n"); fflush(where); } ssf = &snp->sn_send_failed; break; /* FIXME ??? ignore this for now */ case SCTP_PEER_ADDR_CHANGE: if (debug) { fprintf(where, "\tSCTP_PEER_ADDR_CHANGE event\n"); fflush(where); } spc = &snp->sn_paddr_change; break; /* FIXME ??? ignore this for now */ case SCTP_REMOTE_ERROR: if (debug) { fprintf(where, "\tSCTP_REMOTE_ERROR event\n"); fflush(where); } sre = &snp->sn_remote_error; break; /* FIXME ??? ignore this for now */ case SCTP_SHUTDOWN_EVENT: if (debug) { fprintf(where, "\tSCTP_SHUTDOWN event\n"); fflush(where); } return SCTP_CLOSE; default: fprintf(where, "unknown type: %hu\n", snp->sn_header.sn_type); fflush(where); break; } return SCTP_OK; } /* This routine implements the SCTP unidirectional data transfer test */ /* (a.k.a. stream) for the sockets interface. It receives its */ /* parameters via global variables from the shell and writes its */ /* output to the standard output. */ void send_sctp_stream(remote_host) char remote_host[]; { char *tput_title = "\ Recv Send Send \n\ Socket Socket Message Elapsed \n\ Size Size Size Time Throughput \n\ bytes bytes bytes secs. %s/sec \n\n"; char *tput_fmt_0 = "%7.2f\n"; char *tput_fmt_1 = "%6d %6d %6d %-6.2f %7.2f \n"; char *cpu_title = "\ Recv Send Send Utilization Service Demand\n\ Socket Socket Message Elapsed Send Recv Send Recv\n\ Size Size Size Time Throughput local remote local remote\n\ bytes bytes bytes secs. %-8.8s/s %% %c %% %c us/KB us/KB\n\n"; char *cpu_fmt_0 = "%6.3f %c\n"; char *cpu_fmt_1 = "%6d %6d %6d %-6.2f %7.2f %-6.2f %-6.2f %-6.3f %-6.3f\n"; char *ksink_fmt = "\n\ Alignment Offset %-8.8s %-8.8s Sends %-8.8s Recvs\n\ Local Remote Local Remote Xfered Per Per\n\ Send Recv Send Recv Send (avg) Recv (avg)\n\ %5d %5d %5d %5d %6.4g %6.2f %6d %6.2f %6d\n"; char *ksink_fmt2 = "\n\ Maximum\n\ Segment\n\ Size (bytes)\n\ %6d\n"; float elapsed_time; #ifdef WANT_INTERVALS int interval_count; sigset_t signal_set; #endif /* what we want is to have a buffer space that is at least one */ /* send-size greater than our send window. this will insure that we */ /* are never trying to re-use a buffer that may still be in the hands */ /* of the transport. This buffer will be malloc'd after we have found */ /* the size of the local senc socket buffer. We will want to deal */ /* with alignment and offset concerns as well. */ #ifdef DIRTY int *message_int_ptr; #endif struct ring_elt *send_ring; int len; unsigned int nummessages = 0; int send_socket; int bytes_remaining; int sctp_mss; int timed_out; /* with links like fddi, one can send > 32 bits worth of bytes */ /* during a test... ;-) at some point, this should probably become a */ /* 64bit integral type, but those are not entirely common yet */ double bytes_sent = 0.0; #ifdef DIRTY int i; #endif /* DIRTY */ float local_cpu_utilization; float local_service_demand; float remote_cpu_utilization; float remote_service_demand; double thruput; struct addrinfo *remote_res; struct addrinfo *local_res; struct addrinfo *local_remote_res; struct addrinfo *local_local_res; struct sctp_stream_request_struct *sctp_stream_request; struct sctp_stream_response_struct *sctp_stream_response; struct sctp_stream_results_struct *sctp_stream_result; sctp_stream_request = (struct sctp_stream_request_struct *)netperf_request.content.test_specific_data; sctp_stream_response = (struct sctp_stream_response_struct *)netperf_response.content.test_specific_data; sctp_stream_result = (struct sctp_stream_results_struct *)netperf_response.content.test_specific_data; #ifdef WANT_HISTOGRAM time_hist = HIST_new(); #endif /* WANT_HISTOGRAM */ /* since we are now disconnected from the code that established the */ /* control socket, and since we want to be able to use different */ /* protocols and such, we are passed the name of the remote host and */ /* must turn that into the test specific addressing information. */ /* complete_addrinfos will either succede or exit the process */ complete_addrinfos(&remote_res, &local_res, remote_host, SOCK_STREAM, IPPROTO_SCTP, 0); if ( print_headers ) { print_top_test_header("SCTP STREAM TEST", local_res, remote_res); } send_ring = NULL; confidence_iteration = 1; init_stat(); /* we have a great-big while loop which controls the number of times */ /* we run a particular test. this is for the calculation of a */ /* confidence interval (I really should have stayed awake during */ /* probstats :). If the user did not request confidence measurement */ /* (no confidence is the default) then we will only go though the */ /* loop once. the confidence stuff originates from the folks at IBM */ while (((confidence < 0) && (confidence_iteration < iteration_max)) || (confidence_iteration <= iteration_min)) { /* initialize a few counters. we have to remember that we might be */ /* going through the loop more than once. */ nummessages = 0; bytes_sent = 0.0; times_up = 0; timed_out = 0; /*set up the data socket */ send_socket = create_data_socket(local_res); if (send_socket == INVALID_SOCKET){ perror("netperf: send_sctp_stream: sctp stream data socket"); exit(1); } if (debug) { fprintf(where,"send_sctp_stream: send_socket obtained...\n"); } /* at this point, we have either retrieved the socket buffer sizes, */ /* or have tried to set them, so now, we may want to set the send */ /* size based on that (because the user either did not use a -m */ /* option, or used one with an argument of 0). If the socket buffer */ /* size is not available, we will set the send size to 4KB - no */ /* particular reason, just arbitrary... */ if (send_size == 0) { if (lss_size > 0) { send_size = lss_size; } else { send_size = 4096; } } /* set-up the data buffer ring with the requested alignment and offset. */ /* note also that we have allocated a quantity */ /* of memory that is at least one send-size greater than our socket */ /* buffer size. We want to be sure that there are at least two */ /* buffers allocated - this can be a bit of a problem when the */ /* send_size is bigger than the socket size, so we must check... the */ /* user may have wanted to explicitly set the "width" of our send */ /* buffers, we should respect that wish... */ if (send_width == 0) { send_width = (lss_size/send_size) + 1; if (send_width == 1) send_width++; } if (send_ring == NULL) { /* only allocate the send ring once. this is a networking test, */ /* not a memory allocation test. this way, we do not need a */ /* deallocate_buffer_ring() routine, and I don't feel like */ /* writing one anyway :) raj 11/94 */ send_ring = allocate_buffer_ring(send_width, send_size, local_send_align, local_send_offset); } /* If the user has requested cpu utilization measurements, we must */ /* calibrate the cpu(s). We will perform this task within the tests */ /* themselves. If the user has specified the cpu rate, then */ /* calibrate_local_cpu will return rather quickly as it will have */ /* nothing to do. If local_cpu_rate is zero, then we will go through */ /* all the "normal" calibration stuff and return the rate back. */ if (local_cpu_usage) { local_cpu_rate = calibrate_local_cpu(local_cpu_rate); } /* Tell the remote end to do a listen. The server alters the socket */ /* paramters on the other side at this point, hence the reason for */ /* all the values being passed in the setup message. If the user did */ /* not specify any of the parameters, they will be passed as 0, which */ /* will indicate to the remote that no changes beyond the system's */ /* default should be used. Alignment is the exception, it will */ /* default to 1, which will be no alignment alterations. */ netperf_request.content.request_type = DO_SCTP_STREAM; sctp_stream_request->send_buf_size = rss_size_req; sctp_stream_request->recv_buf_size = rsr_size_req; sctp_stream_request->receive_size = recv_size; sctp_stream_request->no_delay = rem_nodelay; sctp_stream_request->recv_alignment = remote_recv_align; sctp_stream_request->recv_offset = remote_recv_offset; sctp_stream_request->measure_cpu = remote_cpu_usage; sctp_stream_request->cpu_rate = remote_cpu_rate; if (test_time) { sctp_stream_request->test_length = test_time; } else { if (msg_count) test_bytes = send_size * msg_count; sctp_stream_request->test_length = test_bytes; } sctp_stream_request->so_rcvavoid = rem_rcvavoid; sctp_stream_request->so_sndavoid = rem_sndavoid; #ifdef DIRTY sctp_stream_request->dirty_count = rem_dirty_count; sctp_stream_request->clean_count = rem_clean_count; #endif /* DIRTY */ sctp_stream_request->port = htonl(atoi(remote_data_port)); sctp_stream_request->ipfamily = af_to_nf(remote_res->ai_family); sctp_stream_request->non_blocking = non_block; if (debug > 1) { fprintf(where, "netperf: send_sctp_stream: requesting sctp stream test\n"); } send_request(); /* The response from the remote will contain all of the relevant */ /* socket parameters for this test type. We will put them back into */ /* the variables here so they can be displayed if desired. The */ /* remote will have calibrated CPU if necessary, and will have done */ /* all the needed set-up we will have calibrated the cpu locally */ /* before sending the request, and will grab the counter value right*/ /* after the connect returns. The remote will grab the counter right*/ /* after the accept call. This saves the hassle of extra messages */ /* being sent for the sctp tests. */ recv_response(); if (!netperf_response.content.serv_errno) { if (debug) fprintf(where,"remote listen done.\n"); rsr_size = sctp_stream_response->recv_buf_size; rss_size = sctp_stream_response->send_buf_size; rem_nodelay = sctp_stream_response->no_delay; remote_cpu_usage= sctp_stream_response->measure_cpu; remote_cpu_rate = sctp_stream_response->cpu_rate; /* we have to make sure that the server port number is in */ /* network order */ set_port_number(remote_res, (short)sctp_stream_response->data_port_number); rem_rcvavoid = sctp_stream_response->so_rcvavoid; rem_sndavoid = sctp_stream_response->so_sndavoid; } else { Set_errno(netperf_response.content.serv_errno); fprintf(where, "netperf: remote error %d", netperf_response.content.serv_errno); perror(""); fflush(where); exit(1); } /*Connect up to the remote port on the data socket */ if (connect(send_socket, remote_res->ai_addr, remote_res->ai_addrlen) == INVALID_SOCKET) { perror("netperf: send_sctp_stream: data socket connect failed"); exit(1); } sctp_enable_events(send_socket, SCTP_ASSOC_CHANGE_EV); if (non_block) { /* now that we are connected, mark the socket as non-blocking */ if (!set_nonblock(send_socket)) { perror("netperf: fcntl"); exit(1); } } /* Data Socket set-up is finished. If there were problems, either */ /* the connect would have failed, or the previous response would */ /* have indicated a problem. I failed to see the value of the */ /* extra message after the accept on the remote. If it failed, */ /* we'll see it here. If it didn't, we might as well start pumping */ /* data. */ /* Set-up the test end conditions. For a stream test, they can be */ /* either time or byte-count based. */ if (test_time) { /* The user wanted to end the test after a period of time. */ times_up = 0; bytes_remaining = 0; /* in previous revisions, we had the same code repeated throught */ /* all the test suites. this was unnecessary, and meant more */ /* work for me when I wanted to switch to POSIX signals, so I */ /* have abstracted this out into a routine in netlib.c. if you */ /* are experiencing signal problems, you might want to look */ /* there. raj 11/94 */ start_timer(test_time); } else { /* The tester wanted to send a number of bytes. */ bytes_remaining = test_bytes; times_up = 1; } /* The cpu_start routine will grab the current time and possibly */ /* value of the idle counter for later use in measuring cpu */ /* utilization and/or service demand and thruput. */ cpu_start(local_cpu_usage); #ifdef WANT_INTERVALS if ((interval_burst) || (demo_mode)) { /* zero means that we never pause, so we never should need the */ /* interval timer, unless we are in demo_mode */ start_itimer(interval_wate); } interval_count = interval_burst; /* get the signal set for the call to sigsuspend */ if (sigprocmask(SIG_BLOCK, (sigset_t *)NULL, &signal_set) != 0) { fprintf(where, "send_sctp_stream: unable to get sigmask errno %d\n", errno); fflush(where); exit(1); } #endif /* WANT_INTERVALS */ #ifdef DIRTY /* initialize the random number generator for putting dirty stuff */ /* into the send buffer. raj */ srand((int) getpid()); #endif /* before we start, initialize a few variables */ /* We use an "OR" to control test execution. When the test is */ /* controlled by time, the byte count check will always return false. */ /* When the test is controlled by byte count, the time test will */ /* always return false. When the test is finished, the whole */ /* expression will go false and we will stop sending data. */ while ((!times_up) || (bytes_remaining > 0)) { #ifdef DIRTY /* we want to dirty some number of consecutive integers in the buffer */ /* we are about to send. we may also want to bring some number of */ /* them cleanly into the cache. The clean ones will follow any dirty */ /* ones into the cache. at some point, we might want to replace */ /* the rand() call with something from a table to reduce our call */ /* overhead during the test, but it is not a high priority item. */ message_int_ptr = (int *)(send_ring->buffer_ptr); for (i = 0; i < loc_dirty_count; i++) { *message_int_ptr = rand(); message_int_ptr++; } for (i = 0; i < loc_clean_count; i++) { loc_dirty_count = *message_int_ptr; message_int_ptr++; } #endif /* DIRTY */ #ifdef WANT_HISTOGRAM /* timestamp just before we go into send and then again just after */ /* we come out raj 8/94 */ HIST_timestamp(&time_one); #endif /* WANT_HISTOGRAM */ while ((len=sctp_sendmsg(send_socket, send_ring->buffer_ptr, send_size, NULL, 0, 0, 0, 0, 0, 0)) != send_size) { if (non_block && errno == EAGAIN) continue; else if ((len >=0) || SOCKET_EINTR(len)) { /* the test was interrupted, must be the end of test */ timed_out = 1; break; } perror("netperf: data send error"); printf("len was %d\n",len); exit(1); } if (timed_out) break; /* we timed out durint sendmsg, done with test */ #ifdef WANT_HISTOGRAM /* timestamp the exit from the send call and update the histogram */ HIST_timestamp(&time_two); HIST_add(time_hist,delta_micro(&time_one,&time_two)); #endif /* WANT_HISTOGRAM */ #ifdef WANT_INTERVALS if (demo_mode) { units_this_tick += send_size; } /* in this case, the interval count is the count-down couter */ /* to decide to sleep for a little bit */ if ((interval_burst) && (--interval_count == 0)) { /* call sigsuspend and wait for the interval timer to get us */ /* out */ if (debug > 1) { fprintf(where,"about to suspend\n"); fflush(where); } if (sigsuspend(&signal_set) == EFAULT) { fprintf(where, "send_sctp_stream: fault with sigsuspend.\n"); fflush(where); exit(1); } interval_count = interval_burst; } #endif /* WANT_INTERVALS */ /* now we want to move our pointer to the next position in the */ /* data buffer...we may also want to wrap back to the "beginning" */ /* of the bufferspace, so we will mod the number of messages sent */ /* by the send width, and use that to calculate the offset to add */ /* to the base pointer. */ nummessages++; send_ring = send_ring->next; if (bytes_remaining) { bytes_remaining -= send_size; } } /* The test is over. Flush the buffers to the remote end. We do a */ /* graceful release to insure that all data has been taken by the */ /* remote. */ /* but first, if the verbosity is greater than 1, find-out what */ /* the sctp maximum segment_size was (if possible) */ if (verbosity > 1) { sctp_mss = -1; get_sctp_info(send_socket, &sctp_mss); } shutdown(send_socket, SHUT_WR); /* The test server will signal to us when it wants to shutdown. * In blocking mode, we can call recvmsg. In non-blocking * mode, we need to select on the socket for reading. * We'll assume that all returns are succefull */ if (non_block) { fd_set readfds; FD_ZERO(&readfds); FD_SET(send_socket, &readfds); select(send_socket+1, &readfds, NULL, NULL, NULL); } else { sctp_recvmsg(send_socket, send_ring->buffer_ptr, send_size, NULL, 0, NULL, 0); } /* this call will always give us the elapsed time for the test, and */ /* will also store-away the necessaries for cpu utilization */ cpu_stop(local_cpu_usage,&elapsed_time); /* was cpu being */ /* measured and how */ /* long did we really */ /* run? */ /* we are finished with the socket, so close it to prevent hitting */ /* the limit on maximum open files. */ close(send_socket); /* Get the statistics from the remote end. The remote will have */ /* calculated service demand and all those interesting things. If it */ /* wasn't supposed to care, it will return obvious values. */ recv_response(); if (!netperf_response.content.serv_errno) { if (debug) fprintf(where,"remote results obtained\n"); } else { Set_errno(netperf_response.content.serv_errno); fprintf(where, "netperf: remote error %d", netperf_response.content.serv_errno); perror(""); fflush(where); exit(1); } /* We now calculate what our thruput was for the test. In the future, */ /* we may want to include a calculation of the thruput measured by */ /* the remote, but it should be the case that for a sctp stream test, */ /* that the two numbers should be *very* close... We calculate */ /* bytes_sent regardless of the way the test length was controlled. */ /* If it was time, we needed to, and if it was by bytes, the user may */ /* have specified a number of bytes that wasn't a multiple of the */ /* send_size, so we really didn't send what he asked for ;-) */ bytes_sent = ntohd(sctp_stream_result->bytes_received); thruput = (double) calc_thruput(bytes_sent); if (local_cpu_usage || remote_cpu_usage) { /* We must now do a little math for service demand and cpu */ /* utilization for the system(s) */ /* Of course, some of the information might be bogus because */ /* there was no idle counter in the kernel(s). We need to make */ /* a note of this for the user's benefit...*/ if (local_cpu_usage) { local_cpu_utilization = calc_cpu_util(0.0); local_service_demand = calc_service_demand(bytes_sent, 0.0, 0.0, 0); } else { local_cpu_utilization = (float) -1.0; local_service_demand = (float) -1.0; } if (remote_cpu_usage) { remote_cpu_utilization = sctp_stream_result->cpu_util; remote_service_demand = calc_service_demand(bytes_sent, 0.0, remote_cpu_utilization, sctp_stream_result->num_cpus); } else { remote_cpu_utilization = (float) -1.0; remote_service_demand = (float) -1.0; } } else { /* we were not measuring cpu, for the confidence stuff, we */ /* should make it -1.0 */ local_cpu_utilization = (float) -1.0; local_service_demand = (float) -1.0; remote_cpu_utilization = (float) -1.0; remote_service_demand = (float) -1.0; } /* at this point, we want to calculate the confidence information. */ /* if debugging is on, calculate_confidence will print-out the */ /* parameters we pass it */ calculate_confidence(confidence_iteration, elapsed_time, thruput, local_cpu_utilization, remote_cpu_utilization, local_service_demand, remote_service_demand); confidence_iteration++; } /* at this point, we have finished making all the runs that we */ /* will be making. so, we should extract what the calcuated values */ /* are for all the confidence stuff. we could make the values */ /* global, but that seemed a little messy, and it did not seem worth */ /* all the mucking with header files. so, we create a routine much */ /* like calcualte_confidence, which just returns the mean values. */ /* raj 11/94 */ retrieve_confident_values(&elapsed_time, &thruput, &local_cpu_utilization, &remote_cpu_utilization, &local_service_demand, &remote_service_demand); /* We are now ready to print all the information. If the user */ /* has specified zero-level verbosity, we will just print the */ /* local service demand, or the remote service demand. If the */ /* user has requested verbosity level 1, he will get the basic */ /* "streamperf" numbers. If the user has specified a verbosity */ /* of greater than 1, we will display a veritable plethora of */ /* background information from outside of this block as it it */ /* not cpu_measurement specific... */ if (confidence < 0) { /* we did not hit confidence, but were we asked to look for it? */ if (iteration_max > 1) { display_confidence(); } } if (local_cpu_usage || remote_cpu_usage) { local_cpu_method = format_cpu_method(cpu_method); remote_cpu_method = format_cpu_method(sctp_stream_result->cpu_method); switch (verbosity) { case 0: if (local_cpu_usage) { fprintf(where, cpu_fmt_0, local_service_demand, local_cpu_method); } else { fprintf(where, cpu_fmt_0, remote_service_demand, remote_cpu_method); } break; case 1: case 2: if (print_headers) { fprintf(where, cpu_title, format_units(), local_cpu_method, remote_cpu_method); } fprintf(where, cpu_fmt_1, /* the format string */ rsr_size, /* remote recvbuf size */ lss_size, /* local sendbuf size */ send_size, /* how large were the sends */ elapsed_time, /* how long was the test */ thruput, /* what was the xfer rate */ local_cpu_utilization, /* local cpu */ remote_cpu_utilization, /* remote cpu */ local_service_demand, /* local service demand */ remote_service_demand); /* remote service demand */ break; } } else { /* The tester did not wish to measure service demand. */ switch (verbosity) { case 0: fprintf(where, tput_fmt_0, thruput); break; case 1: case 2: if (print_headers) { fprintf(where,tput_title,format_units()); } fprintf(where, tput_fmt_1, /* the format string */ rsr_size, /* remote recvbuf size */ lss_size, /* local sendbuf size */ send_size, /* how large were the sends */ elapsed_time, /* how long did it take */ thruput);/* how fast did it go */ break; } } /* it would be a good thing to include information about some of the */ /* other parameters that may have been set for this test, but at the */ /* moment, I do not wish to figure-out all the formatting, so I will */ /* just put this comment here to help remind me that it is something */ /* that should be done at a later time. */ if (verbosity > 1) { /* The user wanted to know it all, so we will give it to him. */ /* This information will include as much as we can find about */ /* sctp statistics, the alignments of the sends and receives */ /* and all that sort of rot... */ /* this stuff needs to be worked-out in the presence of confidence */ /* intervals and multiple iterations of the test... raj 11/94 */ fprintf(where, ksink_fmt, "Bytes", "Bytes", "Bytes", local_send_align, remote_recv_align, local_send_offset, remote_recv_offset, bytes_sent, bytes_sent / (double)nummessages, nummessages, bytes_sent / (double)sctp_stream_result->recv_calls, sctp_stream_result->recv_calls); fprintf(where, ksink_fmt2, sctp_mss); fflush(where); #ifdef WANT_HISTOGRAM fprintf(where,"\n\nHistogram of time spent in send() call.\n"); fflush(where); HIST_report(time_hist); #endif /* WANT_HISTOGRAM */ } } /* This is the server-side routine for the sctp stream test. It is */ /* implemented as one routine. I could break things-out somewhat, but */ /* didn't feel it was necessary. */ void recv_sctp_stream() { struct sockaddr_in myaddr_in; /* needed to get port number */ struct sockaddr_storage peeraddr; /* used in accept */ int s_listen,s_data; int addrlen; int len; unsigned int receive_calls; float elapsed_time; double bytes_received; struct ring_elt *recv_ring; struct addrinfo *local_res; char local_name[BUFSIZ]; char port_buffer[PORTBUFSIZE]; int msg_flags = 0; #ifdef DIRTY int *message_int_ptr; int dirty_count; int clean_count; int i; #endif #ifdef DO_SELECT fd_set readfds; struct timeval timeout; #endif /* DO_SELECT */ struct sctp_stream_request_struct *sctp_stream_request; struct sctp_stream_response_struct *sctp_stream_response; struct sctp_stream_results_struct *sctp_stream_results; #ifdef DO_SELECT FD_ZERO(&readfds); timeout.tv_sec = 1; timeout.tv_usec = 0; #endif /* DO_SELECT */ sctp_stream_request = (struct sctp_stream_request_struct *)netperf_request.content.test_specific_data; sctp_stream_response = (struct sctp_stream_response_struct *)netperf_response.content.test_specific_data; sctp_stream_results = (struct sctp_stream_results_struct *)netperf_response.content.test_specific_data; if (debug) { fprintf(where,"netserver: recv_sctp_stream: entered...\n"); fflush(where); } /* We want to set-up the listen socket with all the desired */ /* parameters and then let the initiator know that all is ready. If */ /* socket size defaults are to be used, then the initiator will have */ /* sent us 0's. If the socket sizes cannot be changed, then we will */ /* send-back what they are. If that information cannot be determined, */ /* then we send-back -1's for the sizes. If things go wrong for any */ /* reason, we will drop back ten yards and punt. */ /* If anything goes wrong, we want the remote to know about it. It */ /* would be best if the error that the remote reports to the user is */ /* the actual error we encountered, rather than some bogus unexpected */ /* response type message. */ if (debug) { fprintf(where,"recv_sctp_stream: setting the response type...\n"); fflush(where); } netperf_response.content.response_type = SCTP_STREAM_RESPONSE; if (debug) { fprintf(where,"recv_sctp_stream: the response type is set...\n"); fflush(where); } /* We now alter the message_ptr variable to be at the desired */ /* alignment with the desired offset. */ if (debug) { fprintf(where,"recv_sctp_stream: requested alignment of %d\n", sctp_stream_request->recv_alignment); fflush(where); } /* create_data_socket expects to find some things in the global */ /* variables, so set the globals based on the values in the request. */ /* once the socket has been created, we will set the response values */ /* based on the updated value of those globals. raj 7/94 */ lss_size_req = sctp_stream_request->send_buf_size; lsr_size_req = sctp_stream_request->recv_buf_size; loc_nodelay = sctp_stream_request->no_delay; loc_rcvavoid = sctp_stream_request->so_rcvavoid; loc_sndavoid = sctp_stream_request->so_sndavoid; non_block = sctp_stream_request->non_blocking; set_hostname_and_port(local_name, port_buffer, nf_to_af(sctp_stream_request->ipfamily), sctp_stream_request->port); local_res = complete_addrinfo(local_name, local_name, port_buffer, nf_to_af(sctp_stream_request->ipfamily), SOCK_STREAM, IPPROTO_SCTP, 0); s_listen = create_data_socket(local_res); if (s_listen < 0) { netperf_response.content.serv_errno = errno; send_response(); exit(1); } /* what sort of sizes did we end-up with? */ if (sctp_stream_request->receive_size == 0) { if (lsr_size > 0) { recv_size = lsr_size; } else { recv_size = 4096; } } else { recv_size = sctp_stream_request->receive_size; } /* we want to set-up our recv_ring in a manner analagous to what we */ /* do on the sending side. this is more for the sake of symmetry */ /* than for the needs of say copy avoidance, but it might also be */ /* more realistic - this way one could conceivably go with a */ /* double-buffering scheme when taking the data an putting it into */ /* the filesystem or something like that. raj 7/94 */ if (recv_width == 0) { recv_width = (lsr_size/recv_size) + 1; if (recv_width == 1) recv_width++; } recv_ring = allocate_buffer_ring(recv_width, recv_size, sctp_stream_request->recv_alignment, sctp_stream_request->recv_offset); if (debug) { fprintf(where,"recv_sctp_stream: set recv_size = %d, align = %d, offset = %d.\n", recv_size, sctp_stream_request->recv_alignment, sctp_stream_request->recv_offset); fflush(where); } /* now get the port number assigned by the system */ addrlen = sizeof(myaddr_in); if (getsockname(s_listen, (struct sockaddr *)&myaddr_in, &addrlen) == -1){ netperf_response.content.serv_errno = errno; close(s_listen); send_response(); exit(1); } /* Now myaddr_in contains the port and the internet address this is */ /* returned to the sender also implicitly telling the sender that the */ /* socket buffer sizing has been done. */ sctp_stream_response->data_port_number = (int) ntohs(myaddr_in.sin_port); netperf_response.content.serv_errno = 0; /* But wait, there's more. If the initiator wanted cpu measurements, */ /* then we must call the calibrate routine, which will return the max */ /* rate back to the initiator. If the CPU was not to be measured, or */ /* something went wrong with the calibration, we will return a -1 to */ /* the initiator. */ sctp_stream_response->cpu_rate = (float)0.0; /* assume no cpu */ if (sctp_stream_request->measure_cpu) { sctp_stream_response->measure_cpu = 1; sctp_stream_response->cpu_rate = calibrate_local_cpu(sctp_stream_request->cpu_rate); } else { sctp_stream_response->measure_cpu = 0; } /* before we send the response back to the initiator, pull some of */ /* the socket parms from the globals */ sctp_stream_response->send_buf_size = lss_size; sctp_stream_response->recv_buf_size = lsr_size; sctp_stream_response->no_delay = loc_nodelay; sctp_stream_response->so_rcvavoid = loc_rcvavoid; sctp_stream_response->so_sndavoid = loc_sndavoid; sctp_stream_response->receive_size = recv_size; /* Now, let's set-up the socket to listen for connections */ if (listen(s_listen, 5) == -1) { netperf_response.content.serv_errno = errno; close(s_listen); send_response(); exit(1); } send_response(); addrlen = sizeof(peeraddr); if ((s_data = accept(s_listen, (struct sockaddr *)&peeraddr, &addrlen)) == INVALID_SOCKET) { /* Let's just punt. The remote will be given some information */ close(s_listen); exit(1); } sctp_enable_events(s_data, SCTP_ASSOC_CHANGE_EV | SCTP_SHUTDOWN_EV); /* now that we are connected, mark the socket as non-blocking */ if (non_block) { fprintf(where, "setting socket as nonblocking\n"); fflush(where); if (!set_nonblock(s_data)) { close(s_data); exit(1); } } #ifdef KLUDGE_SOCKET_OPTIONS /* this is for those systems which *INCORRECTLY* fail to pass */ /* attributes across an accept() call. Including this goes against */ /* my better judgement :( raj 11/95 */ kludge_socket_options(s_data); #endif /* KLUDGE_SOCKET_OPTIONS */ /* Now it's time to start receiving data on the connection. We will */ /* first grab the apropriate counters and then start grabbing. */ cpu_start(sctp_stream_request->measure_cpu); /* The loop will exit when the sender does a shutdown, which will */ /* return a length of zero */ #ifdef DIRTY /* we want to dirty some number of consecutive integers in the buffer */ /* we are about to recv. we may also want to bring some number of */ /* them cleanly into the cache. The clean ones will follow any dirty */ /* ones into the cache. */ dirty_count = sctp_stream_request->dirty_count; clean_count = sctp_stream_request->clean_count; message_int_ptr = (int *)recv_ring->buffer_ptr; for (i = 0; i < dirty_count; i++) { *message_int_ptr = rand(); message_int_ptr++; } for (i = 0; i < clean_count; i++) { dirty_count = *message_int_ptr; message_int_ptr++; } #endif /* DIRTY */ bytes_received = 0; receive_calls = 0; while ((len = sctp_recvmsg(s_data, recv_ring->buffer_ptr, recv_size, NULL, 0, NULL, &msg_flags)) != 0) { if (len == SOCKET_ERROR) { if (non_block && errno == EAGAIN) { if (debug){ fprintf(where, "recv_sctp_stream: sctp_recvmsg timed out, trying again\n"); fflush(where); } Set_errno(0); continue; } if (debug) { fprintf(where, "recv_sctp_stream: sctp_recvmsg error %d, exiting", errno); fflush(where); } netperf_response.content.serv_errno = errno; send_response(); close(s_data); exit(1); } if (msg_flags & MSG_NOTIFICATION) { msg_flags = 0; if (debug) { fprintf(where, "recv_sctp_stream: Got notification... processing\n"); fflush(where); } if (sctp_process_event(s_data, recv_ring->buffer_ptr) == SCTP_CLOSE) break; /* break out of the recvmsg loop */ continue; } bytes_received += len; receive_calls++; /* more to the next buffer in the recv_ring */ recv_ring = recv_ring->next; #ifdef PAUSE sleep(1); #endif /* PAUSE */ #ifdef DIRTY message_int_ptr = (int *)(recv_ring->buffer_ptr); for (i = 0; i < dirty_count; i++) { *message_int_ptr = rand(); message_int_ptr++; } for (i = 0; i < clean_count; i++) { dirty_count = *message_int_ptr; message_int_ptr++; } #endif /* DIRTY */ #ifdef DO_SELECT FD_SET(s_data,&readfds); select(s_data+1,&readfds,NULL,NULL,&timeout); #endif /* DO_SELECT */ } /* perform a shutdown to signal the sender that */ /* we have received all the data sent. raj 4/93 */ if (close(s_data) == -1) { netperf_response.content.serv_errno = errno; send_response(); exit(1); } cpu_stop(sctp_stream_request->measure_cpu,&elapsed_time); /* send the results to the sender */ if (debug) { fprintf(where, "recv_sctp_stream: got %g bytes\n", bytes_received); fprintf(where, "recv_sctp_stream: got %d recvs\n", receive_calls); fflush(where); } sctp_stream_results->bytes_received = htond(bytes_received); sctp_stream_results->elapsed_time = elapsed_time; sctp_stream_results->recv_calls = receive_calls; if (sctp_stream_request->measure_cpu) { sctp_stream_results->cpu_util = calc_cpu_util(0.0); }; if (debug) { fprintf(where, "recv_sctp_stream: test complete, sending results.\n"); fprintf(where, " bytes_received %g receive_calls %d\n", bytes_received, receive_calls); fprintf(where, " len %d\n", len); fflush(where); } sctp_stream_results->cpu_method = cpu_method; sctp_stream_results->num_cpus = lib_num_loc_cpus; send_response(); /* we are now done with the sockets */ close(s_listen); } /* This routine implements the SCTP unidirectional data transfer test */ /* (a.k.a. stream) for the sockets interface. It receives its */ /* parameters via global variables from the shell and writes its */ /* output to the standard output. */ void send_sctp_stream_1toMany(remote_host) char remote_host[]; { char *tput_title = "\ Recv Send Send \n\ Socket Socket Message Elapsed \n\ Size Size Size Time Throughput \n\ bytes bytes bytes secs. %s/sec \n\n"; char *tput_fmt_0 = "%7.2f\n"; char *tput_fmt_1 = "%6d %6d %6d %-6.2f %7.2f \n"; char *cpu_title = "\ Recv Send Send Utilization Service Demand\n\ Socket Socket Message Elapsed Send Recv Send Recv\n\ Size Size Size Time Throughput local remote local remote\n\ bytes bytes bytes secs. %-8.8s/s %% %c %% %c us/KB us/KB\n\n"; char *cpu_fmt_0 = "%6.3f %c\n"; char *cpu_fmt_1 = "%6d %6d %6d %-6.2f %7.2f %-6.2f %-6.2f %-6.3f %-6.3f\n"; char *ksink_fmt = "\n\ Alignment Offset %-8.8s %-8.8s Sends %-8.8s Recvs\n\ Local Remote Local Remote Xfered Per Per\n\ Send Recv Send Recv Send (avg) Recv (avg)\n\ %5d %5d %5d %5d %6.4g %6.2f %6d %6.2f %6d\n"; char *ksink_fmt2 = "\n\ Maximum\n\ Segment\n\ Size (bytes)\n\ %6d\n"; float elapsed_time; #ifdef WANT_INTERVALS int interval_count; sigset_t signal_set; #endif /* what we want is to have a buffer space that is at least one */ /* send-size greater than our send window. this will insure that we */ /* are never trying to re-use a buffer that may still be in the hands */ /* of the transport. This buffer will be malloc'd after we have found */ /* the size of the local senc socket buffer. We will want to deal */ /* with alignment and offset concerns as well. */ #ifdef DIRTY int *message_int_ptr; #endif struct ring_elt *send_ring; int len; unsigned int nummessages = 0; int *send_socket; int bytes_remaining; int sctp_mss; /* with links like fddi, one can send > 32 bits worth of bytes */ /* during a test... ;-) at some point, this should probably become a */ /* 64bit integral type, but those are not entirely common yet */ double bytes_sent = 0.0; #ifdef DIRTY int i; #endif /* DIRTY */ int j; float local_cpu_utilization; float local_service_demand; float remote_cpu_utilization; float remote_service_demand; double thruput; struct addrinfo *remote_res; struct addrinfo *local_res; struct addrinfo *last_remote_res; struct addrinfo *last_local_res; struct sctp_stream_request_struct *sctp_stream_request; struct sctp_stream_response_struct *sctp_stream_response; struct sctp_stream_results_struct *sctp_stream_result; sctp_stream_request = (struct sctp_stream_request_struct *)netperf_request.content.test_specific_data; sctp_stream_response = (struct sctp_stream_response_struct *)netperf_response.content.test_specific_data; sctp_stream_result = (struct sctp_stream_results_struct *)netperf_response.content.test_specific_data; #ifdef WANT_HISTOGRAM time_hist = HIST_new(); #endif /* WANT_HISTOGRAM */ complete_addrinfos(&remote_res, &local_res, remote_host, SOCK_SEQPACKET, IPPROTO_SCTP, 0); if ( print_headers ) { print_top_test_header("SCTP 1-TO-MANY STREAM TEST",local_res,remote_res); } send_ring = NULL; confidence_iteration = 1; init_stat(); send_socket = malloc(sizeof (int) * num_associations); if (send_socket == NULL) { fprintf(where, "send_sctp_stream_1toMany: failed to allocation sockets!\n"); exit(1); } /* we have a great-big while loop which controls the number of times */ /* we run a particular test. this is for the calculation of a */ /* confidence interval (I really should have stayed awake during */ /* probstats :). If the user did not request confidence measurement */ /* (no confidence is the default) then we will only go though the */ /* loop once. the confidence stuff originates from the folks at IBM */ while (((confidence < 0) && (confidence_iteration < iteration_max)) || (confidence_iteration <= iteration_min)) { int j=0; int timed_out = 0; /* initialize a few counters. we have to remember that we might be */ /* going through the loop more than once. */ nummessages = 0; bytes_sent = 0.0; times_up = 0; /* at this point, we have either retrieved the socket buffer sizes, */ /* or have tried to set them, so now, we may want to set the send */ /* size based on that (because the user either did not use a -m */ /* option, or used one with an argument of 0). If the socket buffer */ /* size is not available, we will set the send size to 4KB - no */ /* particular reason, just arbitrary... */ if (send_size == 0) { if (lss_size > 0) { send_size = lss_size; } else { send_size = 4096; } } /* set-up the data buffer ring with the requested alignment and offset. */ /* note also that we have allocated a quantity */ /* of memory that is at least one send-size greater than our socket */ /* buffer size. We want to be sure that there are at least two */ /* buffers allocated - this can be a bit of a problem when the */ /* send_size is bigger than the socket size, so we must check... the */ /* user may have wanted to explicitly set the "width" of our send */ /* buffers, we should respect that wish... */ if (send_width == 0) { send_width = (lss_size/send_size) + 1; if (send_width == 1) send_width++; } if (send_ring == NULL) { /* only allocate the send ring once. this is a networking test, */ /* not a memory allocation test. this way, we do not need a */ /* deallocate_buffer_ring() routine, and I don't feel like */ /* writing one anyway :) raj 11/94 */ send_ring = allocate_buffer_ring(send_width, send_size, local_send_align, local_send_offset); } /* If the user has requested cpu utilization measurements, we must */ /* calibrate the cpu(s). We will perform this task within the tests */ /* themselves. If the user has specified the cpu rate, then */ /* calibrate_local_cpu will return rather quickly as it will have */ /* nothing to do. If local_cpu_rate is zero, then we will go through */ /* all the "normal" calibration stuff and return the rate back. */ if (local_cpu_usage) { local_cpu_rate = calibrate_local_cpu(local_cpu_rate); } /* Tell the remote end to do a listen. The server alters the socket */ /* paramters on the other side at this point, hence the reason for */ /* all the values being passed in the setup message. If the user did */ /* not specify any of the parameters, they will be passed as 0, which */ /* will indicate to the remote that no changes beyond the system's */ /* default should be used. Alignment is the exception, it will */ /* default to 1, which will be no alignment alterations. */ netperf_request.content.request_type = DO_SCTP_STREAM_MANY; sctp_stream_request->send_buf_size = rss_size_req; sctp_stream_request->recv_buf_size = rsr_size_req; sctp_stream_request->receive_size = recv_size; sctp_stream_request->no_delay = rem_nodelay; sctp_stream_request->recv_alignment = remote_recv_align; sctp_stream_request->recv_offset = remote_recv_offset; sctp_stream_request->measure_cpu = remote_cpu_usage; sctp_stream_request->cpu_rate = remote_cpu_rate; if (test_time) { sctp_stream_request->test_length = test_time; } else { if (msg_count) test_bytes = send_size * msg_count; sctp_stream_request->test_length = test_bytes*num_associations; } sctp_stream_request->so_rcvavoid = rem_rcvavoid; sctp_stream_request->so_sndavoid = rem_sndavoid; #ifdef DIRTY sctp_stream_request->dirty_count = rem_dirty_count; sctp_stream_request->clean_count = rem_clean_count; #endif /* DIRTY */ sctp_stream_request->port = (atoi(remote_data_port)); sctp_stream_request->ipfamily = af_to_nf(remote_res->ai_family); sctp_stream_request->non_blocking = non_block; if (debug > 1) { fprintf(where, "netperf: send_sctp_stream_1toMany: requesting sctp stream test\n"); } send_request(); /* The response from the remote will contain all of the relevant */ /* socket parameters for this test type. We will put them back into */ /* the variables here so they can be displayed if desired. The */ /* remote will have calibrated CPU if necessary, and will have done */ /* all the needed set-up we will have calibrated the cpu locally */ /* before sending the request, and will grab the counter value right*/ /* after the connect returns. The remote will grab the counter right*/ /* after the accept call. This saves the hassle of extra messages */ /* being sent for the sctp tests. */ recv_response(); if (!netperf_response.content.serv_errno) { if (debug) fprintf(where,"remote listen done.\n"); rsr_size = sctp_stream_response->recv_buf_size; rss_size = sctp_stream_response->send_buf_size; rem_nodelay = sctp_stream_response->no_delay; remote_cpu_usage= sctp_stream_response->measure_cpu; remote_cpu_rate = sctp_stream_response->cpu_rate; /* we have to make sure that the server port number is in */ /* network order */ set_port_number(remote_res, (unsigned short)sctp_stream_response->data_port_number); rem_rcvavoid = sctp_stream_response->so_rcvavoid; rem_sndavoid = sctp_stream_response->so_sndavoid; } else { Set_errno(netperf_response.content.serv_errno); fprintf(where, "netperf: remote error %d", netperf_response.content.serv_errno); perror(""); fflush(where); exit(1); } /*set up the the array of data sockets and connect them to the server */ for (j = 0; j < num_associations; j++) { send_socket[j] = create_data_socket(local_res); if (send_socket[j] < 0){ perror("netperf: send_sctp_stream_1toMany: sctp stream data socket"); exit(1); } if (debug) { fprintf(where,"send_sctp_stream_1toMany: send_socket obtained...\n"); } /*Connect up to the remote port on the data socket */ if (connect(send_socket[j], remote_res->ai_addr, remote_res->ai_addrlen) == INVALID_SOCKET){ perror("netperf: send_sctp_stream_1toMany: data socket connect failed"); exit(1); } /* Do it after connect is successfull, so that we don't see COMM_UP */ sctp_enable_events(send_socket[j], SCTP_ASSOC_CHANGE_EV); if (non_block) { /* now that we are connected, mark the socket as non-blocking */ if (!set_nonblock(send_socket[j])) { perror("netperf: fcntl"); exit(1); } } } /* Data Socket set-up is finished. If there were problems, either */ /* the connect would have failed, or the previous response would */ /* have indicated a problem. I failed to see the value of the */ /* extra message after the accept on the remote. If it failed, */ /* we'll see it here. If it didn't, we might as well start pumping */ /* data. */ /* Set-up the test end conditions. For a stream test, they can be */ /* either time or byte-count based. */ if (test_time) { /* The user wanted to end the test after a period of time. */ times_up = 0; bytes_remaining = 0; /* in previous revisions, we had the same code repeated throught */ /* all the test suites. this was unnecessary, and meant more */ /* work for me when I wanted to switch to POSIX signals, so I */ /* have abstracted this out into a routine in netlib.c. if you */ /* are experiencing signal problems, you might want to look */ /* there. raj 11/94 */ start_timer(test_time); } else { /* The tester wanted to send a number of bytes. */ bytes_remaining = test_bytes * num_associations; times_up = 1; } /* The cpu_start routine will grab the current time and possibly */ /* value of the idle counter for later use in measuring cpu */ /* utilization and/or service demand and thruput. */ cpu_start(local_cpu_usage); #ifdef WANT_INTERVALS if ((interval_burst) || (demo_mode)) { /* zero means that we never pause, so we never should need the */ /* interval timer, unless we are in demo_mode */ start_itimer(interval_wate); } interval_count = interval_burst; /* get the signal set for the call to sigsuspend */ if (sigprocmask(SIG_BLOCK, (sigset_t *)NULL, &signal_set) != 0) { fprintf(where, "send_sctp_stream_1toMany: unable to get sigmask errno %d\n", errno); fflush(where); exit(1); } #endif /* WANT_INTERVALS */ #ifdef DIRTY /* initialize the random number generator for putting dirty stuff */ /* into the send buffer. raj */ srand((int) getpid()); #endif /* before we start, initialize a few variables */ /* We use an "OR" to control test execution. When the test is */ /* controlled by time, the byte count check will always return false. */ /* When the test is controlled by byte count, the time test will */ /* always return false. When the test is finished, the whole */ /* expression will go false and we will stop sending data. */ while ((!times_up) || (bytes_remaining > 0)) { #ifdef DIRTY /* we want to dirty some number of consecutive integers in the buffer */ /* we are about to send. we may also want to bring some number of */ /* them cleanly into the cache. The clean ones will follow any dirty */ /* ones into the cache. at some point, we might want to replace */ /* the rand() call with something from a table to reduce our call */ /* overhead during the test, but it is not a high priority item. */ message_int_ptr = (int *)(send_ring->buffer_ptr); for (i = 0; i < loc_dirty_count; i++) { *message_int_ptr = rand(); message_int_ptr++; } for (i = 0; i < loc_clean_count; i++) { loc_dirty_count = *message_int_ptr; message_int_ptr++; } #endif /* DIRTY */ #ifdef WANT_HISTOGRAM /* timestamp just before we go into send and then again just after */ /* we come out raj 8/94 */ gettimeofday(&time_one,NULL); #endif /* WANT_HISTOGRAM */ for (j = 0; j < num_associations; j++) { if((len=sctp_sendmsg(send_socket[j], send_ring->buffer_ptr, send_size, (struct sockaddr *)remote_res->ai_addr, remote_res->ai_addrlen, 0, 0, 0, 0, 0)) != send_size) { if ((len >=0) || SOCKET_EINTR(len)) { /* the test was interrupted, must be the end of test */ timed_out = 1; break; } else if (non_block && errno == EAGAIN) { j--; /* send again on the same socket */ Set_errno(0); continue; } perror("netperf: data send error"); printf("len was %d\n",len); exit(1); } } if (timed_out) break; /* test is over, try next iteration */ #ifdef WANT_HISTOGRAM /* timestamp the exit from the send call and update the histogram */ gettimeofday(&time_two,NULL); HIST_add(time_hist,delta_micro(&time_one,&time_two)); #endif /* WANT_HISTOGRAM */ #ifdef WANT_INTERVALS if (demo_mode) { units_this_tick += send_size; } /* in this case, the interval count is the count-down couter */ /* to decide to sleep for a little bit */ if ((interval_burst) && (--interval_count == 0)) { /* call sigsuspend and wait for the interval timer to get us */ /* out */ if (debug > 1) { fprintf(where,"about to suspend\n"); fflush(where); } if (sigsuspend(&signal_set) == EFAULT) { fprintf(where, "send_sctp_stream_1toMany: fault with sigsuspend.\n"); fflush(where); exit(1); } interval_count = interval_burst; } #endif /* WANT_INTERVALS */ /* now we want to move our pointer to the next position in the */ /* data buffer...we may also want to wrap back to the "beginning" */ /* of the bufferspace, so we will mod the number of messages sent */ /* by the send width, and use that to calculate the offset to add */ /* to the base pointer. */ nummessages++; send_ring = send_ring->next; if (bytes_remaining) { bytes_remaining -= send_size; } } /* The test is over. Flush the buffers to the remote end. We do a */ /* graceful release to insure that all data has been taken by the */ /* remote. */ /* but first, if the verbosity is greater than 1, find-out what */ /* the sctp maximum segment_size was (if possible) */ if (verbosity > 1) { sctp_mss = -1; get_sctp_info(send_socket[0], &sctp_mss); } /* signal the server that we are all done writing, this will * initiate a shutdonw of one of the associations on the * server and trigger an event telling the server it's all done */ sctp_sendmsg(send_socket[0], NULL, 0, remote_res->ai_addr, remote_res->ai_addrlen, 0, MSG_EOF, 0, 0, 0); /* The test server will initiate closure of all associations * when it's done reading. We want a basic mechanism to catch this * and are using SCTP events for this. * In blocking mode, we can call recvmsg with the last socket we created. * In non-blocking mode, we need to select on the socket for reading. * We'll assume that all returns are succefull and signify * closure. * It is sufficient to do this on a single socket in the client. * We choose to do it on a socket other then the one that send MSG_EOF. * This means that anything comming in on that socket will be a shutdown. */ if (non_block) { fd_set readfds; FD_ZERO(&readfds); FD_SET(send_socket[num_associations-1], &readfds); select(send_socket[num_associations-1]+1, &readfds, NULL, NULL, NULL); } else { sctp_recvmsg(send_socket[num_associations], send_ring->buffer_ptr, send_size, NULL, 0, NULL, 0); } /* this call will always give us the elapsed time for the test, and */ /* will also store-away the necessaries for cpu utilization */ cpu_stop(local_cpu_usage,&elapsed_time); /* was cpu being */ /* measured and how */ /* long did we really */ /* run? */ /* we are finished with our sockets, so close them to prevent hitting */ /* the limit on maximum open files. */ for (j = 0; j < num_associations; j++) close(send_socket[j]); /* Get the statistics from the remote end. The remote will have */ /* calculated service demand and all those interesting things. If it */ /* wasn't supposed to care, it will return obvious values. */ recv_response(); if (!netperf_response.content.serv_errno) { if (debug) fprintf(where,"remote results obtained\n"); } else { Set_errno(netperf_response.content.serv_errno); fprintf(where, "netperf: remote error %d", netperf_response.content.serv_errno); perror(""); fflush(where); exit(1); } /* We now calculate what our thruput was for the test. In the future, */ /* we may want to include a calculation of the thruput measured by */ /* the remote, but it should be the case that for a sctp stream test, */ /* that the two numbers should be *very* close... We calculate */ /* bytes_sent regardless of the way the test length was controlled. */ /* If it was time, we needed to, and if it was by bytes, the user may */ /* have specified a number of bytes that wasn't a multiple of the */ /* send_size, so we really didn't send what he asked for ;-) */ bytes_sent = ntohd(sctp_stream_result->bytes_received); thruput = (double) calc_thruput(bytes_sent); if (local_cpu_usage || remote_cpu_usage) { /* We must now do a little math for service demand and cpu */ /* utilization for the system(s) */ /* Of course, some of the information might be bogus because */ /* there was no idle counter in the kernel(s). We need to make */ /* a note of this for the user's benefit...*/ if (local_cpu_usage) { local_cpu_utilization = calc_cpu_util(0.0); local_service_demand = calc_service_demand(bytes_sent, 0.0, 0.0, 0); } else { local_cpu_utilization = (float) -1.0; local_service_demand = (float) -1.0; } if (remote_cpu_usage) { remote_cpu_utilization = sctp_stream_result->cpu_util; remote_service_demand = calc_service_demand(bytes_sent, 0.0, remote_cpu_utilization, sctp_stream_result->num_cpus); } else { remote_cpu_utilization = (float) -1.0; remote_service_demand = (float) -1.0; } } else { /* we were not measuring cpu, for the confidence stuff, we */ /* should make it -1.0 */ local_cpu_utilization = (float) -1.0; local_service_demand = (float) -1.0; remote_cpu_utilization = (float) -1.0; remote_service_demand = (float) -1.0; } /* at this point, we want to calculate the confidence information. */ /* if debugging is on, calculate_confidence will print-out the */ /* parameters we pass it */ calculate_confidence(confidence_iteration, elapsed_time, thruput, local_cpu_utilization, remote_cpu_utilization, local_service_demand, remote_service_demand); confidence_iteration++; } /* at this point, we have finished making all the runs that we */ /* will be making. so, we should extract what the calcuated values */ /* are for all the confidence stuff. we could make the values */ /* global, but that seemed a little messy, and it did not seem worth */ /* all the mucking with header files. so, we create a routine much */ /* like calcualte_confidence, which just returns the mean values. */ /* raj 11/94 */ retrieve_confident_values(&elapsed_time, &thruput, &local_cpu_utilization, &remote_cpu_utilization, &local_service_demand, &remote_service_demand); /* We are now ready to print all the information. If the user */ /* has specified zero-level verbosity, we will just print the */ /* local service demand, or the remote service demand. If the */ /* user has requested verbosity level 1, he will get the basic */ /* "streamperf" numbers. If the user has specified a verbosity */ /* of greater than 1, we will display a veritable plethora of */ /* background information from outside of this block as it it */ /* not cpu_measurement specific... */ if (confidence < 0) { /* we did not hit confidence, but were we asked to look for it? */ if (iteration_max > 1) { display_confidence(); } } if (local_cpu_usage || remote_cpu_usage) { local_cpu_method = format_cpu_method(cpu_method); remote_cpu_method = format_cpu_method(sctp_stream_result->cpu_method); switch (verbosity) { case 0: if (local_cpu_usage) { fprintf(where, cpu_fmt_0, local_service_demand, local_cpu_method); } else { fprintf(where, cpu_fmt_0, remote_service_demand, remote_cpu_method); } break; case 1: case 2: if (print_headers) { fprintf(where, cpu_title, format_units(), local_cpu_method, remote_cpu_method); } fprintf(where, cpu_fmt_1, /* the format string */ rsr_size, /* remote recvbuf size */ lss_size, /* local sendbuf size */ send_size, /* how large were the sends */ elapsed_time, /* how long was the test */ thruput, /* what was the xfer rate */ local_cpu_utilization, /* local cpu */ remote_cpu_utilization, /* remote cpu */ local_service_demand, /* local service demand */ remote_service_demand); /* remote service demand */ break; } } else { /* The tester did not wish to measure service demand. */ switch (verbosity) { case 0: fprintf(where, tput_fmt_0, thruput); break; case 1: case 2: if (print_headers) { fprintf(where,tput_title,format_units()); } fprintf(where, tput_fmt_1, /* the format string */ rsr_size, /* remote recvbuf size */ lss_size, /* local sendbuf size */ send_size, /* how large were the sends */ elapsed_time, /* how long did it take */ thruput);/* how fast did it go */ break; } } /* it would be a good thing to include information about some of the */ /* other parameters that may have been set for this test, but at the */ /* moment, I do not wish to figure-out all the formatting, so I will */ /* just put this comment here to help remind me that it is something */ /* that should be done at a later time. */ if (verbosity > 1) { /* The user wanted to know it all, so we will give it to him. */ /* This information will include as much as we can find about */ /* sctp statistics, the alignments of the sends and receives */ /* and all that sort of rot... */ /* this stuff needs to be worked-out in the presence of confidence */ /* intervals and multiple iterations of the test... raj 11/94 */ fprintf(where, ksink_fmt, "Bytes", "Bytes", "Bytes", local_send_align, remote_recv_align, local_send_offset, remote_recv_offset, bytes_sent, bytes_sent / (double)nummessages, nummessages, bytes_sent / (double)sctp_stream_result->recv_calls, sctp_stream_result->recv_calls); fprintf(where, ksink_fmt2, sctp_mss); fflush(where); #ifdef WANT_HISTOGRAM fprintf(where,"\n\nHistogram of time spent in send() call.\n"); fflush(where); HIST_report(time_hist); #endif /* WANT_HISTOGRAM */ } } /* This is the server-side routine for the sctp stream test. It is */ /* implemented as one routine. I could break things-out somewhat, but */ /* didn't feel it was necessary. */ void recv_sctp_stream_1toMany() { struct sockaddr_in myaddr_in; int s_recv; int addrlen; int len; unsigned int receive_calls; float elapsed_time; double bytes_received; int msg_flags = 0; struct ring_elt *recv_ring; struct addrinfo *local_res; char local_name[BUFSIZ]; char port_buffer[PORTBUFSIZE]; #ifdef DIRTY int *message_int_ptr; int dirty_count; int clean_count; int i; #endif #ifdef DO_SELECT fd_set readfds; struct timeval timeout; #endif struct sctp_stream_request_struct *sctp_stream_request; struct sctp_stream_response_struct *sctp_stream_response; struct sctp_stream_results_struct *sctp_stream_results; #ifdef DO_SELECT FD_ZERO(&readfds); timeout.tv_sec = 1; timeout.tv_usec = 0; #endif sctp_stream_request = (struct sctp_stream_request_struct *)netperf_request.content.test_specific_data; sctp_stream_response = (struct sctp_stream_response_struct *)netperf_response.content.test_specific_data; sctp_stream_results = (struct sctp_stream_results_struct *)netperf_response.content.test_specific_data; if (debug) { fprintf(where,"netserver: recv_sctp_stream: entered...\n"); fflush(where); } /* We want to set-up the listen socket with all the desired */ /* parameters and then let the initiator know that all is ready. If */ /* socket size defaults are to be used, then the initiator will have */ /* sent us 0's. If the socket sizes cannot be changed, then we will */ /* send-back what they are. If that information cannot be determined, */ /* then we send-back -1's for the sizes. If things go wrong for any */ /* reason, we will drop back ten yards and punt. */ /* If anything goes wrong, we want the remote to know about it. It */ /* would be best if the error that the remote reports to the user is */ /* the actual error we encountered, rather than some bogus unexpected */ /* response type message. */ if (debug) { fprintf(where,"recv_sctp_stream_1toMany: setting the response type...\n"); fflush(where); } netperf_response.content.response_type = SCTP_STREAM_MANY_RESPONSE; if (debug) { fprintf(where,"recv_sctp_stream_1toMany: the response type is set...\n"); fflush(where); } /* We now alter the message_ptr variable to be at the desired */ /* alignment with the desired offset. */ if (debug) { fprintf(where,"recv_sctp_stream_1toMany: requested alignment of %d\n", sctp_stream_request->recv_alignment); fflush(where); } /* create_data_socket expects to find some things in the global */ /* variables, so set the globals based on the values in the request. */ /* once the socket has been created, we will set the response values */ /* based on the updated value of those globals. raj 7/94 */ lss_size_req = sctp_stream_request->send_buf_size; lsr_size_req = sctp_stream_request->recv_buf_size; loc_nodelay = sctp_stream_request->no_delay; loc_rcvavoid = sctp_stream_request->so_rcvavoid; loc_sndavoid = sctp_stream_request->so_sndavoid; non_block = sctp_stream_request->non_blocking; set_hostname_and_port(local_name, port_buffer, nf_to_af(sctp_stream_request->ipfamily), sctp_stream_request->port); local_res = complete_addrinfo(local_name, local_name, port_buffer, nf_to_af(sctp_stream_request->ipfamily), SOCK_SEQPACKET, IPPROTO_SCTP, 0); s_recv = create_data_socket(local_res); if (s_recv < 0) { netperf_response.content.serv_errno = errno; send_response(); exit(1); } /* what sort of sizes did we end-up with? */ if (sctp_stream_request->receive_size == 0) { if (lsr_size > 0) { recv_size = lsr_size; } else { recv_size = 4096; } } else { recv_size = sctp_stream_request->receive_size; } /* we want to set-up our recv_ring in a manner analagous to what we */ /* do on the sending side. this is more for the sake of symmetry */ /* than for the needs of say copy avoidance, but it might also be */ /* more realistic - this way one could conceivably go with a */ /* double-buffering scheme when taking the data an putting it into */ /* the filesystem or something like that. raj 7/94 */ if (recv_width == 0) { recv_width = (lsr_size/recv_size) + 1; if (recv_width == 1) recv_width++; } recv_ring = allocate_buffer_ring(recv_width, recv_size, sctp_stream_request->recv_alignment, sctp_stream_request->recv_offset); if (debug) { fprintf(where,"recv_sctp_stream: receive alignment and offset set...\n"); fflush(where); } /* Now, let's set-up the socket to listen for connections */ if (listen(s_recv, 5) == -1) { netperf_response.content.serv_errno = errno; close(s_recv); send_response(); exit(1); } /* now get the port number assigned by the system */ addrlen = sizeof(myaddr_in); if (getsockname(s_recv, (struct sockaddr *)&myaddr_in, &addrlen) == -1){ netperf_response.content.serv_errno = errno; close(s_recv); send_response(); exit(1); } /* Now myaddr_in contains the port and the internet address this is */ /* returned to the sender also implicitly telling the sender that the */ /* socket buffer sizing has been done. */ sctp_stream_response->data_port_number = (int) ntohs(myaddr_in.sin_port); netperf_response.content.serv_errno = 0; /* But wait, there's more. If the initiator wanted cpu measurements, */ /* then we must call the calibrate routine, which will return the max */ /* rate back to the initiator. If the CPU was not to be measured, or */ /* something went wrong with the calibration, we will return a -1 to */ /* the initiator. */ sctp_stream_response->cpu_rate = (float)0.0; /* assume no cpu */ if (sctp_stream_request->measure_cpu) { sctp_stream_response->measure_cpu = 1; sctp_stream_response->cpu_rate = calibrate_local_cpu(sctp_stream_request->cpu_rate); } else { sctp_stream_response->measure_cpu = 0; } /* before we send the response back to the initiator, pull some of */ /* the socket parms from the globals */ sctp_stream_response->send_buf_size = lss_size; sctp_stream_response->recv_buf_size = lsr_size; sctp_stream_response->no_delay = loc_nodelay; sctp_stream_response->so_rcvavoid = loc_rcvavoid; sctp_stream_response->so_sndavoid = loc_sndavoid; sctp_stream_response->receive_size = recv_size; send_response(); sctp_enable_events(s_recv, SCTP_ASSOC_CHANGE_EV | SCTP_SHUTDOWN_EV); /* now that we are connected, mark the socket as non-blocking */ if (non_block) { if (!set_nonblock(s_recv)) { close(s_recv); exit(1); } } /* Now it's time to start receiving data on the connection. We will */ /* first grab the apropriate counters and then start grabbing. */ cpu_start(sctp_stream_request->measure_cpu); /* The loop will exit when the sender does a shutdown, which will */ /* return a length of zero */ #ifdef DIRTY /* we want to dirty some number of consecutive integers in the buffer */ /* we are about to recv. we may also want to bring some number of */ /* them cleanly into the cache. The clean ones will follow any dirty */ /* ones into the cache. */ dirty_count = sctp_stream_request->dirty_count; clean_count = sctp_stream_request->clean_count; message_int_ptr = (int *)recv_ring->buffer_ptr; for (i = 0; i < dirty_count; i++) { *message_int_ptr = rand(); message_int_ptr++; } for (i = 0; i < clean_count; i++) { dirty_count = *message_int_ptr; message_int_ptr++; } #endif /* DIRTY */ bytes_received = 0; receive_calls = 0; while ((len = sctp_recvmsg(s_recv, recv_ring->buffer_ptr, recv_size, NULL, 0, /* we don't care who it's from */ NULL, &msg_flags)) != 0) { if (len < 0) { if (non_block && errno == EAGAIN) { Set_errno(0); continue; } netperf_response.content.serv_errno = errno; send_response(); close(s_recv); exit(1); } if (msg_flags & MSG_NOTIFICATION) { if (sctp_process_event(s_recv, recv_ring->buffer_ptr) == SCTP_CLOSE) break; continue; } bytes_received += len; receive_calls++; /* more to the next buffer in the recv_ring */ recv_ring = recv_ring->next; #ifdef PAUSE sleep(1); #endif /* PAUSE */ #ifdef DIRTY message_int_ptr = (int *)(recv_ring->buffer_ptr); for (i = 0; i < dirty_count; i++) { *message_int_ptr = rand(); message_int_ptr++; } for (i = 0; i < clean_count; i++) { dirty_count = *message_int_ptr; message_int_ptr++; } #endif /* DIRTY */ #ifdef DO_SELECT FD_SET(s_recv,&readfds); select(s_recv+1,&readfds,NULL,NULL,&timeout); #endif /* DO_SELECT */ } /* perform a shutdown to signal the sender. in this case, sctp * will close all associations on this socket */ if (close(s_recv) == -1) { netperf_response.content.serv_errno = errno; send_response(); exit(1); } cpu_stop(sctp_stream_request->measure_cpu,&elapsed_time); /* send the results to the sender */ if (debug) { fprintf(where, "recv_sctp_stream: got %g bytes\n", bytes_received); fprintf(where, "recv_sctp_stream: got %d recvs\n", receive_calls); fflush(where); } sctp_stream_results->bytes_received = htond(bytes_received); sctp_stream_results->elapsed_time = elapsed_time; sctp_stream_results->recv_calls = receive_calls; if (sctp_stream_request->measure_cpu) { sctp_stream_results->cpu_util = calc_cpu_util(0.0); }; if (debug) { fprintf(where, "recv_sctp_stream: test complete, sending results.\n"); fprintf(where, " bytes_received %g receive_calls %d\n", bytes_received, receive_calls); fprintf(where, " len %d\n", len); fflush(where); } sctp_stream_results->cpu_method = cpu_method; sctp_stream_results->num_cpus = lib_num_loc_cpus; send_response(); } /* this routine implements the sending (netperf) side of the SCTP_RR */ /* test. */ void send_sctp_rr(remote_host) char remote_host[]; { char *tput_title = "\ Local /Remote\n\ Socket Size Request Resp. Elapsed Trans.\n\ Send Recv Size Size Time Rate \n\ bytes Bytes bytes bytes secs. per sec \n\n"; char *tput_fmt_0 = "%7.2f\n"; char *tput_fmt_1_line_1 = "\ %-6d %-6d %-6d %-6d %-6.2f %7.2f \n"; char *tput_fmt_1_line_2 = "\ %-6d %-6d\n"; char *cpu_title = "\ Local /Remote\n\ Socket Size Request Resp. Elapsed Trans. CPU CPU S.dem S.dem\n\ Send Recv Size Size Time Rate local remote local remote\n\ bytes bytes bytes bytes secs. per sec %% %c %% %c us/Tr us/Tr\n\n"; char *cpu_fmt_0 = "%6.3f %c\n"; char *cpu_fmt_1_line_1 = "\ %-6d %-6d %-6d %-6d %-6.2f %-6.2f %-6.2f %-6.2f %-6.3f %-6.3f\n"; char *cpu_fmt_1_line_2 = "\ %-6d %-6d\n"; char *ksink_fmt = "\ Alignment Offset\n\ Local Remote Local Remote\n\ Send Recv Send Recv\n\ %5d %5d %5d %5d\n"; int timed_out = 0; float elapsed_time; int len; char *temp_message_ptr; int nummessages; int send_socket; int trans_remaining; int msg_flags = 0; double bytes_xferd; struct ring_elt *send_ring; struct ring_elt *recv_ring; int rsp_bytes_left; int rsp_bytes_recvd; float local_cpu_utilization; float local_service_demand; float remote_cpu_utilization; float remote_service_demand; double thruput; struct sockaddr_storage peer; struct addrinfo *remote_res; struct addrinfo *local_res; struct sctp_rr_request_struct *sctp_rr_request; struct sctp_rr_response_struct *sctp_rr_response; struct sctp_rr_results_struct *sctp_rr_result; #ifdef WANT_INTERVALS int interval_count; sigset_t signal_set; #endif /* WANT_INTERVALS */ sctp_rr_request = (struct sctp_rr_request_struct *)netperf_request.content.test_specific_data; sctp_rr_response = (struct sctp_rr_response_struct *)netperf_response.content.test_specific_data; sctp_rr_result = (struct sctp_rr_results_struct *)netperf_response.content.test_specific_data; #ifdef WANT_HISTOGRAM time_hist = HIST_new(); #endif /* WANT_HISTOGRAM */ /* since we are now disconnected from the code that established the */ /* control socket, and since we want to be able to use different */ /* protocols and such, we are passed the name of the remote host and */ /* must turn that into the test specific addressing information. */ /* complete_addrinfos will either succede or exit the process */ complete_addrinfos(&remote_res, &local_res, remote_host, SOCK_STREAM, IPPROTO_SCTP, 0); if ( print_headers ) { print_top_test_header("SCTP REQUEST/RESPONSE TEST", local_res, remote_res); } /* initialize a few counters */ send_ring = NULL; recv_ring = NULL; confidence_iteration = 1; init_stat(); /* we have a great-big while loop which controls the number of times */ /* we run a particular test. this is for the calculation of a */ /* confidence interval (I really should have stayed awake during */ /* probstats :). If the user did not request confidence measurement */ /* (no confidence is the default) then we will only go though the */ /* loop once. the confidence stuff originates from the folks at IBM */ while (((confidence < 0) && (confidence_iteration < iteration_max)) || (confidence_iteration <= iteration_min)) { /* initialize a few counters. we have to remember that we might be */ /* going through the loop more than once. */ nummessages = 0; bytes_xferd = 0.0; times_up = 0; timed_out = 0; trans_remaining = 0; /* set-up the data buffers with the requested alignment and offset. */ /* since this is a request/response test, default the send_width and */ /* recv_width to 1 and not two raj 7/94 */ if (send_width == 0) send_width = 1; if (recv_width == 0) recv_width = 1; if (send_ring == NULL) { send_ring = allocate_buffer_ring(send_width, req_size, local_send_align, local_send_offset); } if (recv_ring == NULL) { recv_ring = allocate_buffer_ring(recv_width, rsp_size, local_recv_align, local_recv_offset); } /*set up the data socket */ send_socket = create_data_socket(local_res); if (send_socket < 0){ perror("netperf: send_sctp_rr: sctp stream data socket"); exit(1); } if (debug) { fprintf(where,"send_sctp_rr: send_socket obtained...\n"); } /* If the user has requested cpu utilization measurements, we must */ /* calibrate the cpu(s). We will perform this task within the tests */ /* themselves. If the user has specified the cpu rate, then */ /* calibrate_local_cpu will return rather quickly as it will have */ /* nothing to do. If local_cpu_rate is zero, then we will go through */ /* all the "normal" calibration stuff and return the rate back.*/ if (local_cpu_usage) { local_cpu_rate = calibrate_local_cpu(local_cpu_rate); } /* Tell the remote end to do a listen. The server alters the socket */ /* paramters on the other side at this point, hence the reason for */ /* all the values being passed in the setup message. If the user did */ /* not specify any of the parameters, they will be passed as 0, which */ /* will indicate to the remote that no changes beyond the system's */ /* default should be used. Alignment is the exception, it will */ /* default to 8, which will be no alignment alterations. */ netperf_request.content.request_type = DO_SCTP_RR; sctp_rr_request->recv_buf_size = rsr_size_req; sctp_rr_request->send_buf_size = rss_size_req; sctp_rr_request->recv_alignment = remote_recv_align; sctp_rr_request->recv_offset = remote_recv_offset; sctp_rr_request->send_alignment = remote_send_align; sctp_rr_request->send_offset = remote_send_offset; sctp_rr_request->request_size = req_size; sctp_rr_request->response_size = rsp_size; sctp_rr_request->no_delay = rem_nodelay; sctp_rr_request->measure_cpu = remote_cpu_usage; sctp_rr_request->cpu_rate = remote_cpu_rate; sctp_rr_request->so_rcvavoid = rem_rcvavoid; sctp_rr_request->so_sndavoid = rem_sndavoid; if (test_time) { sctp_rr_request->test_length = test_time; } else { sctp_rr_request->test_length = test_trans * -1; } sctp_rr_request->non_blocking = non_block; sctp_rr_request->ipfamily = af_to_nf(remote_res->ai_family); if (debug > 1) { fprintf(where,"netperf: send_sctp_rr: requesting SCTP rr test\n"); } send_request(); /* The response from the remote will contain all of the relevant */ /* socket parameters for this test type. We will put them back into */ /* the variables here so they can be displayed if desired. The */ /* remote will have calibrated CPU if necessary, and will have done */ /* all the needed set-up we will have calibrated the cpu locally */ /* before sending the request, and will grab the counter value right*/ /* after the connect returns. The remote will grab the counter right*/ /* after the accept call. This saves the hassle of extra messages */ /* being sent for the sctp tests. */ recv_response(); if (!netperf_response.content.serv_errno) { if (debug) fprintf(where,"remote listen done.\n"); rsr_size = sctp_rr_response->recv_buf_size; rss_size = sctp_rr_response->send_buf_size; rem_nodelay = sctp_rr_response->no_delay; remote_cpu_usage = sctp_rr_response->measure_cpu; remote_cpu_rate = sctp_rr_response->cpu_rate; /* make sure that port numbers are in network order */ set_port_number(remote_res, (unsigned short)sctp_rr_response->data_port_number); } else { Set_errno(netperf_response.content.serv_errno); fprintf(where, "netperf: remote error %d", netperf_response.content.serv_errno); perror(""); fflush(where); exit(1); } /*Connect up to the remote port on the data socket */ if (connect(send_socket, remote_res->ai_addr, remote_res->ai_addrlen) <0){ perror("netperf: send_sctp_rr data socket connect failed"); exit(1); } /* don't need events for 1-to-1 API with request-response tests */ sctp_enable_events(send_socket, 0); /* set non-blocking if needed */ if (non_block) { if (!set_nonblock(send_socket)) { close(send_socket); exit(1); } } /* Data Socket set-up is finished. If there were problems, either the */ /* connect would have failed, or the previous response would have */ /* indicated a problem. I failed to see the value of the extra */ /* message after the accept on the remote. If it failed, we'll see it */ /* here. If it didn't, we might as well start pumping data. */ /* Set-up the test end conditions. For a request/response test, they */ /* can be either time or transaction based. */ if (test_time) { /* The user wanted to end the test after a period of time. */ times_up = 0; trans_remaining = 0; start_timer(test_time); } else { /* The tester wanted to send a number of bytes. */ trans_remaining = test_bytes; times_up = 1; } /* The cpu_start routine will grab the current time and possibly */ /* value of the idle counter for later use in measuring cpu */ /* utilization and/or service demand and thruput. */ cpu_start(local_cpu_usage); #ifdef WANT_INTERVALS if ((interval_burst) || (demo_mode)) { /* zero means that we never pause, so we never should need the */ /* interval timer, unless we are in demo_mode */ start_itimer(interval_wate); } interval_count = interval_burst; /* get the signal set for the call to sigsuspend */ if (sigprocmask(SIG_BLOCK, (sigset_t *)NULL, &signal_set) != 0) { fprintf(where, "send_sctp_rr: unable to get sigmask errno %d\n", errno); fflush(where); exit(1); } #endif /* WANT_INTERVALS */ /* We use an "OR" to control test execution. When the test is */ /* controlled by time, the byte count check will always return false. */ /* When the test is controlled by byte count, the time test will */ /* always return false. When the test is finished, the whole */ /* expression will go false and we will stop sending data. I think I */ /* just arbitrarily decrement trans_remaining for the timed test, but */ /* will not do that just yet... One other question is whether or not */ /* the send buffer and the receive buffer should be the same buffer. */ #ifdef WANT_FIRST_BURST { int i; for (i = 0; i < first_burst_size; i++) { if((len=sctp_sendmsg(send_socket, send_ring->buffer_ptr, req_size, NULL, 0, /* don't need addrs with 1-to-1 */ 0, 0, 0, 0, 0)) != req_size) { /* we should never hit the end of the test in the first burst */ perror("send_sctp_rr: initial burst data send error"); exit(1); } } } #endif /* WANT_FIRST_BURST */ while ((!times_up) || (trans_remaining > 0)) { /* send the request. we assume that if we use a blocking socket, */ /* the request will be sent at one shot. */ #ifdef WANT_HISTOGRAM /* timestamp just before our call to send, and then again just */ /* after the receive raj 8/94 */ HIST_timestamp(&time_one); #endif /* WANT_HISTOGRAM */ while ((len=sctp_sendmsg(send_socket, send_ring->buffer_ptr, req_size, NULL, 0, /* don't need addrs with 1-to-1 */ 0, 0, 0, 0, 0)) != req_size) { if (non_block && errno == EAGAIN) { /* try sending again */ continue; } else if (SOCKET_EINTR(len) || (errno == 0)) { /* we hit the end of a */ /* timed test. */ timed_out = 1; break; } perror("send_sctp_rr: data send error"); exit(1); } if (timed_out) { /* we timed out while sending. break out another level */ break; } send_ring = send_ring->next; /* receive the response */ rsp_bytes_left = rsp_size; temp_message_ptr = recv_ring->buffer_ptr; do { msg_flags = 0; if ((rsp_bytes_recvd=sctp_recvmsg(send_socket, temp_message_ptr, rsp_bytes_left, NULL, 0, NULL, &msg_flags)) < 0) { if (errno == EINTR) { /* We hit the end of a timed test. */ timed_out = 1; break; } else if (non_block && errno == EAGAIN) { continue; } perror("send_sctp_rr: data recv error"); exit(1); } rsp_bytes_left -= rsp_bytes_recvd; temp_message_ptr += rsp_bytes_recvd; } while (!(msg_flags & MSG_EOR)); recv_ring = recv_ring->next; if (timed_out) { /* we may have been in a nested while loop - we need */ /* another call to break. */ break; } #ifdef WANT_HISTOGRAM HIST_timestamp(&time_two); HIST_add(time_hist,delta_micro(&time_one,&time_two)); #endif /* WANT_HISTOGRAM */ #ifdef WANT_INTERVALS if (demo_mode) { units_this_tick += 1; } /* in this case, the interval count is the count-down couter */ /* to decide to sleep for a little bit */ if ((interval_burst) && (--interval_count == 0)) { /* call sigsuspend and wait for the interval timer to get us */ /* out */ if (debug > 1) { fprintf(where,"about to suspend\n"); fflush(where); } if (sigsuspend(&signal_set) == EFAULT) { fprintf(where, "send_sctp_rr: fault with signal set!\n"); fflush(where); exit(1); } interval_count = interval_burst; } #endif /* WANT_INTERVALS */ nummessages++; if (trans_remaining) { trans_remaining--; } if (debug > 3) { if ((nummessages % 100) == 0) { fprintf(where, "Transaction %d completed\n", nummessages); fflush(where); } } } /* At this point we used to call shutdown on the data socket to be */ /* sure all the data was delivered, but this was not germane in a */ /* request/response test, and it was causing the tests to "hang" when */ /* they were being controlled by time. So, I have replaced this */ /* shutdown call with a call to close that can be found later in the */ /* procedure. */ /* this call will always give us the elapsed time for the test, and */ /* will also store-away the necessaries for cpu utilization */ cpu_stop(local_cpu_usage,&elapsed_time); /* was cpu being */ /* measured? how long */ /* did we really run? */ /* Get the statistics from the remote end. The remote will have */ /* calculated CPU utilization. If it wasn't supposed to care, it */ /* will return obvious values. */ recv_response(); if (!netperf_response.content.serv_errno) { if (debug) fprintf(where,"remote results obtained\n"); } else { Set_errno(netperf_response.content.serv_errno); fprintf(where,"netperf: remote error %d", netperf_response.content.serv_errno); perror(""); fflush(where); exit(1); } /* We now calculate what our throughput was for the test. */ bytes_xferd = (req_size * nummessages) + (rsp_size * nummessages); thruput = nummessages/elapsed_time; if (local_cpu_usage || remote_cpu_usage) { /* We must now do a little math for service demand and cpu */ /* utilization for the system(s) */ /* Of course, some of the information might be bogus because */ /* there was no idle counter in the kernel(s). We need to make */ /* a note of this for the user's benefit...*/ if (local_cpu_usage) { local_cpu_utilization = calc_cpu_util(0.0); /* since calc_service demand is doing ms/Kunit we will */ /* multiply the number of transaction by 1024 to get */ /* "good" numbers */ local_service_demand = calc_service_demand((double) nummessages*1024, 0.0, 0.0, 0); } else { local_cpu_utilization = (float) -1.0; local_service_demand = (float) -1.0; } if (remote_cpu_usage) { remote_cpu_utilization = sctp_rr_result->cpu_util; /* since calc_service demand is doing ms/Kunit we will */ /* multiply the number of transaction by 1024 to get */ /* "good" numbers */ remote_service_demand = calc_service_demand((double) nummessages*1024, 0.0, remote_cpu_utilization, sctp_rr_result->num_cpus); } else { remote_cpu_utilization = (float) -1.0; remote_service_demand = (float) -1.0; } } else { /* we were not measuring cpu, for the confidence stuff, we */ /* should make it -1.0 */ local_cpu_utilization = (float) -1.0; local_service_demand = (float) -1.0; remote_cpu_utilization = (float) -1.0; remote_service_demand = (float) -1.0; } /* at this point, we want to calculate the confidence information. */ /* if debugging is on, calculate_confidence will print-out the */ /* parameters we pass it */ calculate_confidence(confidence_iteration, elapsed_time, thruput, local_cpu_utilization, remote_cpu_utilization, local_service_demand, remote_service_demand); confidence_iteration++; /* we are now done with the socket, so close it */ close(send_socket); } retrieve_confident_values(&elapsed_time, &thruput, &local_cpu_utilization, &remote_cpu_utilization, &local_service_demand, &remote_service_demand); /* We are now ready to print all the information. If the user */ /* has specified zero-level verbosity, we will just print the */ /* local service demand, or the remote service demand. If the */ /* user has requested verbosity level 1, he will get the basic */ /* "streamperf" numbers. If the user has specified a verbosity */ /* of greater than 1, we will display a veritable plethora of */ /* background information from outside of this block as it it */ /* not cpu_measurement specific... */ if (confidence < 0) { /* we did not hit confidence, but were we asked to look for it? */ if (iteration_max > 1) { display_confidence(); } } if (local_cpu_usage || remote_cpu_usage) { local_cpu_method = format_cpu_method(cpu_method); remote_cpu_method = format_cpu_method(sctp_rr_result->cpu_method); switch (verbosity) { case 0: if (local_cpu_usage) { fprintf(where, cpu_fmt_0, local_service_demand, local_cpu_method); } else { fprintf(where, cpu_fmt_0, remote_service_demand, remote_cpu_method); } break; case 1: case 2: if (print_headers) { fprintf(where, cpu_title, local_cpu_method, remote_cpu_method); } fprintf(where, cpu_fmt_1_line_1, /* the format string */ lss_size, /* local sendbuf size */ lsr_size, req_size, /* how large were the requests */ rsp_size, /* guess */ elapsed_time, /* how long was the test */ thruput, local_cpu_utilization, /* local cpu */ remote_cpu_utilization, /* remote cpu */ local_service_demand, /* local service demand */ remote_service_demand); /* remote service demand */ fprintf(where, cpu_fmt_1_line_2, rss_size, rsr_size); break; } } else { /* The tester did not wish to measure service demand. */ switch (verbosity) { case 0: fprintf(where, tput_fmt_0, thruput); break; case 1: case 2: if (print_headers) { fprintf(where,tput_title,format_units()); } fprintf(where, tput_fmt_1_line_1, /* the format string */ lss_size, lsr_size, req_size, /* how large were the requests */ rsp_size, /* how large were the responses */ elapsed_time, /* how long did it take */ thruput); fprintf(where, tput_fmt_1_line_2, rss_size, /* remote recvbuf size */ rsr_size); break; } } /* it would be a good thing to include information about some of the */ /* other parameters that may have been set for this test, but at the */ /* moment, I do not wish to figure-out all the formatting, so I will */ /* just put this comment here to help remind me that it is something */ /* that should be done at a later time. */ /* how to handle the verbose information in the presence of */ /* confidence intervals is yet to be determined... raj 11/94 */ if (verbosity > 1) { /* The user wanted to know it all, so we will give it to him. */ /* This information will include as much as we can find about */ /* TCP statistics, the alignments of the sends and receives */ /* and all that sort of rot... */ fprintf(where, ksink_fmt, local_send_align, remote_recv_offset, local_send_offset, remote_recv_offset); #ifdef WANT_HISTOGRAM fprintf(where,"\nHistogram of request/response times\n"); fflush(where); HIST_report(time_hist); #endif /* WANT_HISTOGRAM */ } } /* this routine implements the receive (netserver) side of a TCP_RR */ /* test */ void recv_sctp_rr() { struct ring_elt *send_ring; struct ring_elt *recv_ring; struct addrinfo *local_res; char local_name[BUFSIZ]; char port_buffer[PORTBUFSIZE]; struct sockaddr_in myaddr_in, peeraddr_in; int s_listen, s_data; int addrlen; char *temp_message_ptr; int trans_received; int trans_remaining; int bytes_sent; int request_bytes_recvd; int request_bytes_remaining; int timed_out = 0; float elapsed_time; struct sctp_rr_request_struct *sctp_rr_request; struct sctp_rr_response_struct *sctp_rr_response; struct sctp_rr_results_struct *sctp_rr_results; sctp_rr_request = (struct sctp_rr_request_struct *)netperf_request.content.test_specific_data; sctp_rr_response = (struct sctp_rr_response_struct *)netperf_response.content.test_specific_data; sctp_rr_results = (struct sctp_rr_results_struct *)netperf_response.content.test_specific_data; if (debug) { fprintf(where,"netserver: recv_sctp_rr: entered...\n"); fflush(where); } /* We want to set-up the listen socket with all the desired */ /* parameters and then let the initiator know that all is ready. If */ /* socket size defaults are to be used, then the initiator will have */ /* sent us 0's. If the socket sizes cannot be changed, then we will */ /* send-back what they are. If that information cannot be determined, */ /* then we send-back -1's for the sizes. If things go wrong for any */ /* reason, we will drop back ten yards and punt. */ /* If anything goes wrong, we want the remote to know about it. It */ /* would be best if the error that the remote reports to the user is */ /* the actual error we encountered, rather than some bogus unexpected */ /* response type message. */ if (debug) { fprintf(where,"recv_sctp_rr: setting the response type...\n"); fflush(where); } netperf_response.content.response_type = SCTP_RR_RESPONSE; if (debug) { fprintf(where,"recv_sctp_rr: the response type is set...\n"); fflush(where); } /* allocate the recv and send rings with the requested alignments */ /* and offsets. raj 7/94 */ if (debug) { fprintf(where,"recv_sctp_rr: requested recv alignment of %d offset %d\n", sctp_rr_request->recv_alignment, sctp_rr_request->recv_offset); fprintf(where,"recv_sctp_rr: requested send alignment of %d offset %d\n", sctp_rr_request->send_alignment, sctp_rr_request->send_offset); fflush(where); } /* at some point, these need to come to us from the remote system */ if (send_width == 0) send_width = 1; if (recv_width == 0) recv_width = 1; send_ring = allocate_buffer_ring(send_width, sctp_rr_request->response_size, sctp_rr_request->send_alignment, sctp_rr_request->send_offset); recv_ring = allocate_buffer_ring(recv_width, sctp_rr_request->request_size, sctp_rr_request->recv_alignment, sctp_rr_request->recv_offset); /* Grab a socket to listen on, and then listen on it. */ if (debug) { fprintf(where,"recv_sctp_rr: grabbing a socket...\n"); fflush(where); } /* create_data_socket expects to find some things in the global */ /* variables, so set the globals based on the values in the request. */ /* once the socket has been created, we will set the response values */ /* based on the updated value of those globals. raj 7/94 */ lss_size_req = sctp_rr_request->send_buf_size; lsr_size_req = sctp_rr_request->recv_buf_size; loc_nodelay = sctp_rr_request->no_delay; loc_rcvavoid = sctp_rr_request->so_rcvavoid; loc_sndavoid = sctp_rr_request->so_sndavoid; non_block = sctp_rr_request->non_blocking; set_hostname_and_port(local_name, port_buffer, nf_to_af(sctp_rr_request->ipfamily), sctp_rr_request->port); local_res = complete_addrinfo(local_name, local_name, port_buffer, nf_to_af(sctp_rr_request->ipfamily), SOCK_STREAM, IPPROTO_SCTP, 0); s_listen = create_data_socket(local_res); if (s_listen < 0) { netperf_response.content.serv_errno = errno; send_response(); exit(1); } /* Now, let's set-up the socket to listen for connections */ if (listen(s_listen, 5) == -1) { netperf_response.content.serv_errno = errno; close(s_listen); send_response(); exit(1); } /* now get the port number assigned by the system */ addrlen = sizeof(myaddr_in); if (getsockname(s_listen, (struct sockaddr *)&myaddr_in, &addrlen) == -1){ netperf_response.content.serv_errno = errno; close(s_listen); send_response(); exit(1); } /* Now myaddr_in contains the port and the internet address this is */ /* returned to the sender also implicitly telling the sender that the */ /* socket buffer sizing has been done. */ sctp_rr_response->data_port_number = (int) ntohs(myaddr_in.sin_port); netperf_response.content.serv_errno = 0; /* But wait, there's more. If the initiator wanted cpu measurements, */ /* then we must call the calibrate routine, which will return the max */ /* rate back to the initiator. If the CPU was not to be measured, or */ /* something went wrong with the calibration, we will return a 0.0 to */ /* the initiator. */ sctp_rr_response->cpu_rate = (float)0.0; /* assume no cpu */ sctp_rr_response->measure_cpu = 0; if (sctp_rr_request->measure_cpu) { sctp_rr_response->measure_cpu = 1; sctp_rr_response->cpu_rate = calibrate_local_cpu(sctp_rr_request->cpu_rate); } /* before we send the response back to the initiator, pull some of */ /* the socket parms from the globals */ sctp_rr_response->send_buf_size = lss_size; sctp_rr_response->recv_buf_size = lsr_size; sctp_rr_response->no_delay = loc_nodelay; sctp_rr_response->so_rcvavoid = loc_rcvavoid; sctp_rr_response->so_sndavoid = loc_sndavoid; sctp_rr_response->test_length = sctp_rr_request->test_length; send_response(); addrlen = sizeof(peeraddr_in); if ((s_data = accept(s_listen, (struct sockaddr *)&peeraddr_in, &addrlen)) == -1) { /* Let's just punt. The remote will be given some information */ close(s_listen); exit(1); } /* we do not need events on a 1-to-1 RR test. The test will finish * once all transactions are done. */ /* now that we are connected, mark the socket as non-blocking */ if (non_block) { if (!set_nonblock(s_data)) { perror("netperf: set_nonblock"); exit(1); } } #ifdef KLUDGE_SOCKET_OPTIONS /* this is for those systems which *INCORRECTLY* fail to pass */ /* attributes across an accept() call. Including this goes against */ /* my better judgement :( raj 11/95 */ kludge_socket_options(s_data); #endif /* KLUDGE_SOCKET_OPTIONS */ if (debug) { fprintf(where,"recv_sctp_rr: accept completes on the data connection.\n"); fflush(where); } /* Now it's time to start receiving data on the connection. We will */ /* first grab the apropriate counters and then start grabbing. */ cpu_start(sctp_rr_request->measure_cpu); /* The loop will exit when we hit the end of the test time, or when */ /* we have exchanged the requested number of transactions. */ if (sctp_rr_request->test_length > 0) { times_up = 0; trans_remaining = 0; start_timer(sctp_rr_request->test_length + PAD_TIME); } else { times_up = 1; trans_remaining = sctp_rr_request->test_length * -1; } trans_received = 0; while ((!times_up) || (trans_remaining > 0)) { int msg_flags = 0; temp_message_ptr = recv_ring->buffer_ptr; request_bytes_remaining = sctp_rr_request->request_size; while(!(msg_flags & MSG_EOR)) { if((request_bytes_recvd=sctp_recvmsg(s_data, temp_message_ptr, request_bytes_remaining, NULL, 0, NULL, &msg_flags)) < 0) { if (errno == EINTR) { /* the timer popped */ timed_out = 1; break; } else if (non_block && errno == EAGAIN) { continue; /* while request_bytes_remaining */ } netperf_response.content.serv_errno = errno; send_response(); exit(1); } request_bytes_remaining -= request_bytes_recvd; temp_message_ptr += request_bytes_recvd; } recv_ring = recv_ring->next; if (timed_out) { /* we hit the end of the test based on time - lets */ /* bail out of here now... */ if (debug) { fprintf(where,"yo55\n"); fflush(where); } break; } /* Now, send the response to the remote * In 1-to-1 API destination addr is not needed. */ while ((bytes_sent=sctp_sendmsg(s_data, send_ring->buffer_ptr, sctp_rr_request->response_size, NULL, 0, 0, 0, 0, 0, 0)) == -1) { if (errno == EINTR) { /* the test timer has popped */ timed_out = 1; break; } else if (non_block && errno == EAGAIN) { continue; } netperf_response.content.serv_errno = 982; send_response(); exit(1); } if (timed_out) { /* we hit the end of the test based on time - lets */ /* bail out of here now... */ if (debug) { fprintf(where,"yo6\n"); fflush(where); } break; } send_ring = send_ring->next; trans_received++; if (trans_remaining) { trans_remaining--; } } /* The loop now exits due to timeout or transaction count being */ /* reached */ cpu_stop(sctp_rr_request->measure_cpu,&elapsed_time); stop_timer(); if (timed_out) { /* we ended the test by time, which was at least 2 seconds */ /* longer than we wanted to run. so, we want to subtract */ /* PAD_TIME from the elapsed_time. */ elapsed_time -= PAD_TIME; } /* send the results to the sender */ if (debug) { fprintf(where, "recv_sctp_rr: got %d transactions\n", trans_received); fflush(where); } sctp_rr_results->bytes_received = (trans_received * (sctp_rr_request->request_size + sctp_rr_request->response_size)); sctp_rr_results->trans_received = trans_received; sctp_rr_results->elapsed_time = elapsed_time; sctp_rr_results->cpu_method = cpu_method; sctp_rr_results->num_cpus = lib_num_loc_cpus; if (sctp_rr_request->measure_cpu) { sctp_rr_results->cpu_util = calc_cpu_util(elapsed_time); } if (debug) { fprintf(where, "recv_sctp_rr: test complete, sending results.\n"); fflush(where); } /* we are now done with the sockets */ send_response(); close(s_data); close(s_listen); } /* this routine implements the sending (netperf) side of the SCTP_RR_1TOMANY test */ void send_sctp_rr_1toMany(remote_host) char remote_host[]; { char *tput_title = "\ Local /Remote\n\ Socket Size Request Resp. Elapsed Trans.\n\ Send Recv Size Size Time Rate \n\ bytes Bytes bytes bytes secs. per sec \n\n"; char *tput_fmt_0 = "%7.2f\n"; char *tput_fmt_1_line_1 = "\ %-6d %-6d %-6d %-6d %-6.2f %7.2f \n"; char *tput_fmt_1_line_2 = "\ %-6d %-6d\n"; char *cpu_title = "\ Local /Remote\n\ Socket Size Request Resp. Elapsed Trans. CPU CPU S.dem S.dem\n\ Send Recv Size Size Time Rate local remote local remote\n\ bytes bytes bytes bytes secs. per sec %% %c %% %c us/Tr us/Tr\n\n"; char *cpu_fmt_0 = "%6.3f %c\n"; char *cpu_fmt_1_line_1 = "\ %-6d %-6d %-6d %-6d %-6.2f %-6.2f %-6.2f %-6.2f %-6.3f %-6.3f\n"; char *cpu_fmt_1_line_2 = "\ %-6d %-6d\n"; char *ksink_fmt = "\ Alignment Offset\n\ Local Remote Local Remote\n\ Send Recv Send Recv\n\ %5d %5d %5d %5d\n"; int timed_out = 0; float elapsed_time; int len, j = 0; char *temp_message_ptr; int nummessages; int *send_socket; int trans_remaining; double bytes_xferd; int msg_flags = 0; struct ring_elt *send_ring; struct ring_elt *recv_ring; int rsp_bytes_left; int rsp_bytes_recvd; float local_cpu_utilization; float local_service_demand; float remote_cpu_utilization; float remote_service_demand; double thruput; struct sockaddr_storage peer; struct addrinfo *local_res; struct addrinfo *remote_res; struct sctp_rr_request_struct *sctp_rr_request; struct sctp_rr_response_struct *sctp_rr_response; struct sctp_rr_results_struct *sctp_rr_result; #ifdef WANT_INTERVALS int interval_count; sigset_t signal_set; #endif /* WANT_INTERVALS */ sctp_rr_request = (struct sctp_rr_request_struct *)netperf_request.content.test_specific_data; sctp_rr_response = (struct sctp_rr_response_struct *)netperf_response.content.test_specific_data; sctp_rr_result = (struct sctp_rr_results_struct *)netperf_response.content.test_specific_data; #ifdef WANT_HISTOGRAM time_hist = HIST_new(); #endif /* WANT_HISTOGRAM */ /* since we are now disconnected from the code that established the */ /* control socket, and since we want to be able to use different */ /* protocols and such, we are passed the name of the remote host and */ /* must turn that into the test specific addressing information. */ complete_addrinfos(&remote_res, &local_res, remote_host, SOCK_SEQPACKET, IPPROTO_SCTP, 0); if ( print_headers ) { print_top_test_header("SCTP 1-TO-MANY REQUEST/RESPONSE TEST",local_res,remote_res); } /* initialize a few counters */ send_ring = NULL; recv_ring = NULL; confidence_iteration = 1; init_stat(); send_socket = malloc(sizeof(int) * num_associations); if (send_socket == NULL) { fprintf(where, "Could not create the socket array for %d associations", num_associations); fflush(where); exit(1); } /* we have a great-big while loop which controls the number of times */ /* we run a particular test. this is for the calculation of a */ /* confidence interval (I really should have stayed awake during */ /* probstats :). If the user did not request confidence measurement */ /* (no confidence is the default) then we will only go though the */ /* loop once. the confidence stuff originates from the folks at IBM */ while (((confidence < 0) && (confidence_iteration < iteration_max)) || (confidence_iteration <= iteration_min)) { /* initialize a few counters. we have to remember that we might be */ /* going through the loop more than once. */ nummessages = 0; bytes_xferd = 0.0; times_up = 0; timed_out = 0; trans_remaining = 0; /* set-up the data buffers with the requested alignment and offset. */ /* since this is a request/response test, default the send_width and */ /* recv_width to 1 and not two raj 7/94 */ if (send_width == 0) send_width = 1; if (recv_width == 0) recv_width = 1; if (send_ring == NULL) { send_ring = allocate_buffer_ring(send_width, req_size, local_send_align, local_send_offset); } if (recv_ring == NULL) { recv_ring = allocate_buffer_ring(recv_width, rsp_size, local_recv_align, local_recv_offset); } /* If the user has requested cpu utilization measurements, we must */ /* calibrate the cpu(s). We will perform this task within the tests */ /* themselves. If the user has specified the cpu rate, then */ /* calibrate_local_cpu will return rather quickly as it will have */ /* nothing to do. If local_cpu_rate is zero, then we will go through */ /* all the "normal" calibration stuff and return the rate back.*/ if (local_cpu_usage) { local_cpu_rate = calibrate_local_cpu(local_cpu_rate); } /* Tell the remote end to do a listen. The server alters the socket */ /* paramters on the other side at this point, hence the reason for */ /* all the values being passed in the setup message. If the user did */ /* not specify any of the parameters, they will be passed as 0, which */ /* will indicate to the remote that no changes beyond the system's */ /* default should be used. Alignment is the exception, it will */ /* default to 8, which will be no alignment alterations. */ netperf_request.content.request_type = DO_SCTP_RR_MANY; sctp_rr_request->recv_buf_size = rsr_size_req; sctp_rr_request->send_buf_size = rss_size_req; sctp_rr_request->recv_alignment = remote_recv_align; sctp_rr_request->recv_offset = remote_recv_offset; sctp_rr_request->send_alignment = remote_send_align; sctp_rr_request->send_offset = remote_send_offset; sctp_rr_request->request_size = req_size; sctp_rr_request->response_size = rsp_size; sctp_rr_request->no_delay = rem_nodelay; sctp_rr_request->measure_cpu = remote_cpu_usage; sctp_rr_request->cpu_rate = remote_cpu_rate; sctp_rr_request->so_rcvavoid = rem_rcvavoid; sctp_rr_request->so_sndavoid = rem_sndavoid; if (test_time) { sctp_rr_request->test_length = test_time; } else { sctp_rr_request->test_length = test_trans * num_associations * -1; } sctp_rr_request->non_blocking = non_block; sctp_rr_request->port = atoi(remote_data_port); sctp_rr_request->ipfamily = af_to_nf(remote_res->ai_family); if (debug > 1) { fprintf(where,"netperf: send_sctp_rr_1toMany: requesting SCTP rr test\n"); } send_request(); /* The response from the remote will contain all of the relevant */ /* socket parameters for this test type. We will put them back into */ /* the variables here so they can be displayed if desired. The */ /* remote will have calibrated CPU if necessary, and will have done */ /* all the needed set-up we will have calibrated the cpu locally */ /* before sending the request, and will grab the counter value right*/ /* after the connect returns. The remote will grab the counter right*/ /* after the accept call. This saves the hassle of extra messages */ /* being sent for the sctp tests. */ recv_response(); if (!netperf_response.content.serv_errno) { rsr_size = sctp_rr_response->recv_buf_size; rss_size = sctp_rr_response->send_buf_size; rem_nodelay = sctp_rr_response->no_delay; remote_cpu_usage = sctp_rr_response->measure_cpu; remote_cpu_rate = sctp_rr_response->cpu_rate; /* make sure that port numbers are in network order */ set_port_number(remote_res, (unsigned short)sctp_rr_response->data_port_number); } else { Set_errno(netperf_response.content.serv_errno); fprintf(where, "netperf: remote error %d", netperf_response.content.serv_errno); perror(""); fflush(where); exit(1); } /*set up the data socket list */ for (j = 0; j < num_associations; j++) { send_socket[j] = create_data_socket(local_res); if (send_socket < 0){ perror("netperf: send_sctp_rr_1toMany: sctp stream data socket"); exit(1); } /*Connect up to the remote port on the data socket */ if (connect(send_socket[j], remote_res->ai_addr, remote_res->ai_addrlen) < 0){ perror("netperf: data socket connect failed"); exit(1); } /* The client end of the 1-to-Many test uses 1-to-1 sockets. * it doesn't need events. */ sctp_enable_events(send_socket[j], 0); if (non_block) { if (!set_nonblock(send_socket[j])) { close(send_socket[j]); exit(1); } } } /* Data Socket set-up is finished. If there were problems, either the */ /* connect would have failed, or the previous response would have */ /* indicated a problem. I failed to see the value of the extra */ /* message after the accept on the remote. If it failed, we'll see it */ /* here. If it didn't, we might as well start pumping data. */ /* Set-up the test end conditions. For a request/response test, they */ /* can be either time or transaction based. */ if (test_time) { /* The user wanted to end the test after a period of time. */ times_up = 0; trans_remaining = 0; start_timer(test_time); } else { /* The tester wanted to send a number of bytes. */ trans_remaining = test_bytes * num_associations; times_up = 1; } /* The cpu_start routine will grab the current time and possibly */ /* value of the idle counter for later use in measuring cpu */ /* utilization and/or service demand and thruput. */ cpu_start(local_cpu_usage); #ifdef WANT_INTERVALS if ((interval_burst) || (demo_mode)) { /* zero means that we never pause, so we never should need the */ /* interval timer, unless we are in demo_mode */ start_itimer(interval_wate); } interval_count = interval_burst; /* get the signal set for the call to sigsuspend */ if (sigprocmask(SIG_BLOCK, (sigset_t *)NULL, &signal_set) != 0) { fprintf(where, "send_sctp_rr_1toMany: unable to get sigmask errno %d\n", errno); fflush(where); exit(1); } #endif /* WANT_INTERVALS */ /* We use an "OR" to control test execution. When the test is */ /* controlled by time, the byte count check will always return false. */ /* When the test is controlled by byte count, the time test will */ /* always return false. When the test is finished, the whole */ /* expression will go false and we will stop sending data. I think I */ /* just arbitrarily decrement trans_remaining for the timed test, but */ /* will not do that just yet... One other question is whether or not */ /* the send buffer and the receive buffer should be the same buffer. */ #ifdef WANT_FIRST_BURST { int i; for (j = 0; j < num_associations; j++) { for (i = 0; i < first_burst_size; i++) { if((len=sctp_sendmsg(send_socket[j], send_ring->buffer_ptr, send_size, remote_res->ai_addr, remote_res->ai_addrlen, 0, 0, 0, 0, 0)) != req_size) { /* we should never hit the end of the test in the first burst */ perror("send_sctp_rr_1toMany: initial burst data send error"); exit(1); } } } } #endif /* WANT_FIRST_BURST */ while ((!times_up) || (trans_remaining > 0)) { /* send the request. we assume that if we use a blocking socket, */ /* the request will be sent at one shot. */ /* this is a fairly poor way of testing 1toMany connections. * For each association we measure round trip time to account for * any delay in lookups and delivery. To stress the server a bit * more we would need a distributed client test, or at least multiple * processes. I want to force as much paralellism as possible, but * this will do for the fist take. vlad */ for (j = 0; j < num_associations; j++) { #ifdef WANT_HISTOGRAM /* timestamp just before our call to send, and then again just */ /* after the receive raj 8/94 */ gettimeofday(&time_one,NULL); #endif /* WANT_HISTOGRAM */ while ((len=sctp_sendmsg(send_socket[j], send_ring->buffer_ptr, send_size, remote_res->ai_addr, remote_res->ai_addrlen, 0, 0, 0, 0, 0)) != req_size) { if (non_block && errno == EAGAIN) { /* try sending again */ continue; } else if ((errno == EINTR) || (errno == 0)) { /* we hit the end of a */ /* timed test. */ timed_out = 1; break; } perror("send_sctp_rr_1toMany: data send error"); exit(1); } if (timed_out) { /* we may have been in a nested while loop - we need */ /* another call to break. */ break; } /* setup for the next time */ send_ring = send_ring->next; rsp_bytes_left = rsp_size; temp_message_ptr = recv_ring->buffer_ptr; while (!(msg_flags & MSG_EOR)) { if((rsp_bytes_recvd = sctp_recvmsg(send_socket[j], temp_message_ptr, rsp_bytes_left, NULL, 0, NULL, &msg_flags)) < 0) { if (errno == EINTR) { /* We hit the end of a timed test. */ timed_out = 1; break; } else if (non_block && errno == EAGAIN) { continue; } perror("send_sctp_rr_1toMany: data recv error"); exit(1); } rsp_bytes_left -= rsp_bytes_recvd; temp_message_ptr += rsp_bytes_recvd; } recv_ring = recv_ring->next; if (timed_out) { /* we may have been in a nested while loop - we need */ /* another call to break. */ break; } #ifdef WANT_HISTOGRAM gettimeofday(&time_two,NULL); HIST_add(time_hist,delta_micro(&time_one,&time_two)); #endif /* WANT_HISTOGRAM */ nummessages++; if (trans_remaining) { trans_remaining--; } if (debug > 3) { if ((nummessages % 100) == 0) { fprintf(where, "Transaction %d completed\n", nummessages); fflush(where); } } } } /* At this point we used to call shutdown on the data socket to be */ /* sure all the data was delivered, but this was not germane in a */ /* request/response test, and it was causing the tests to "hang" when */ /* they were being controlled by time. So, I have replaced this */ /* shutdown call with a call to close that can be found later in the */ /* procedure. */ /* this call will always give us the elapsed time for the test, and */ /* will also store-away the necessaries for cpu utilization */ cpu_stop(local_cpu_usage,&elapsed_time); /* was cpu being */ /* measured? how long */ /* did we really run? */ /* Get the statistics from the remote end. The remote will have */ /* calculated CPU utilization. If it wasn't supposed to care, it */ /* will return obvious values. */ recv_response(); if (!netperf_response.content.serv_errno) { if (debug) fprintf(where,"remote results obtained\n"); } else { Set_errno(netperf_response.content.serv_errno); fprintf(where,"netperf: remote error %d", netperf_response.content.serv_errno); perror(""); fflush(where); exit(1); } /* We now calculate what our throughput was for the test. */ bytes_xferd = (req_size * nummessages) + (rsp_size * nummessages); thruput = nummessages/elapsed_time; if (local_cpu_usage || remote_cpu_usage) { /* We must now do a little math for service demand and cpu */ /* utilization for the system(s) */ /* Of course, some of the information might be bogus because */ /* there was no idle counter in the kernel(s). We need to make */ /* a note of this for the user's benefit...*/ if (local_cpu_usage) { local_cpu_utilization = calc_cpu_util(0.0); /* since calc_service demand is doing ms/Kunit we will */ /* multiply the number of transaction by 1024 to get */ /* "good" numbers */ local_service_demand = calc_service_demand((double) nummessages*1024, 0.0, 0.0, 0); } else { local_cpu_utilization = (float) -1.0; local_service_demand = (float) -1.0; } if (remote_cpu_usage) { remote_cpu_utilization = sctp_rr_result->cpu_util; /* since calc_service demand is doing ms/Kunit we will */ /* multiply the number of transaction by 1024 to get */ /* "good" numbers */ remote_service_demand = calc_service_demand((double) nummessages*1024, 0.0, remote_cpu_utilization, sctp_rr_result->num_cpus); } else { remote_cpu_utilization = (float) -1.0; remote_service_demand = (float) -1.0; } } else { /* we were not measuring cpu, for the confidence stuff, we */ /* should make it -1.0 */ local_cpu_utilization = (float) -1.0; local_service_demand = (float) -1.0; remote_cpu_utilization = (float) -1.0; remote_service_demand = (float) -1.0; } /* at this point, we want to calculate the confidence information. */ /* if debugging is on, calculate_confidence will print-out the */ /* parameters we pass it */ calculate_confidence(confidence_iteration, elapsed_time, thruput, local_cpu_utilization, remote_cpu_utilization, local_service_demand, remote_service_demand); confidence_iteration++; /* we are now done with the socket, so close it */ for (j = 0; j < num_associations; j++) close(send_socket[j]); } retrieve_confident_values(&elapsed_time, &thruput, &local_cpu_utilization, &remote_cpu_utilization, &local_service_demand, &remote_service_demand); /* We are now ready to print all the information. If the user */ /* has specified zero-level verbosity, we will just print the */ /* local service demand, or the remote service demand. If the */ /* user has requested verbosity level 1, he will get the basic */ /* "streamperf" numbers. If the user has specified a verbosity */ /* of greater than 1, we will display a veritable plethora of */ /* background information from outside of this block as it it */ /* not cpu_measurement specific... */ if (confidence < 0) { /* we did not hit confidence, but were we asked to look for it? */ if (iteration_max > 1) { display_confidence(); } } if (local_cpu_usage || remote_cpu_usage) { local_cpu_method = format_cpu_method(cpu_method); remote_cpu_method = format_cpu_method(sctp_rr_result->cpu_method); switch (verbosity) { case 0: if (local_cpu_usage) { fprintf(where, cpu_fmt_0, local_service_demand, local_cpu_method); } else { fprintf(where, cpu_fmt_0, remote_service_demand, remote_cpu_method); } break; case 1: case 2: if (print_headers) { fprintf(where, cpu_title, local_cpu_method, remote_cpu_method); } fprintf(where, cpu_fmt_1_line_1, /* the format string */ lss_size, /* local sendbuf size */ lsr_size, req_size, /* how large were the requests */ rsp_size, /* guess */ elapsed_time, /* how long was the test */ thruput, local_cpu_utilization, /* local cpu */ remote_cpu_utilization, /* remote cpu */ local_service_demand, /* local service demand */ remote_service_demand); /* remote service demand */ fprintf(where, cpu_fmt_1_line_2, rss_size, rsr_size); break; } } else { /* The tester did not wish to measure service demand. */ switch (verbosity) { case 0: fprintf(where, tput_fmt_0, thruput); break; case 1: case 2: if (print_headers) { fprintf(where,tput_title,format_units()); } fprintf(where, tput_fmt_1_line_1, /* the format string */ lss_size, lsr_size, req_size, /* how large were the requests */ rsp_size, /* how large were the responses */ elapsed_time, /* how long did it take */ thruput); fprintf(where, tput_fmt_1_line_2, rss_size, /* remote recvbuf size */ rsr_size); break; } } /* it would be a good thing to include information about some of the */ /* other parameters that may have been set for this test, but at the */ /* moment, I do not wish to figure-out all the formatting, so I will */ /* just put this comment here to help remind me that it is something */ /* that should be done at a later time. */ /* how to handle the verbose information in the presence of */ /* confidence intervals is yet to be determined... raj 11/94 */ if (verbosity > 1) { /* The user wanted to know it all, so we will give it to him. */ /* This information will include as much as we can find about */ /* TCP statistics, the alignments of the sends and receives */ /* and all that sort of rot... */ fprintf(where, ksink_fmt, local_send_align, remote_recv_offset, local_send_offset, remote_recv_offset); #ifdef WANT_HISTOGRAM fprintf(where,"\nHistogram of request/response times\n"); fflush(where); HIST_report(time_hist); #endif /* WANT_HISTOGRAM */ } } /* this routine implements the receive (netserver) side of a TCP_RR */ /* test */ void recv_sctp_rr_1toMany() { struct ring_elt *send_ring; struct ring_elt *recv_ring; struct sockaddr_in myaddr_in; /* needed to get the port number */ struct sockaddr_storage peeraddr; /* to communicate with peer */ struct addrinfo *local_res; char local_name[BUFSIZ]; char port_buffer[PORTBUFSIZE]; int msg_flags; int s_rcv; int addrlen; char *temp_message_ptr; int trans_received; int trans_remaining; int bytes_sent; int bytes_recvd; int recv_buf_size; int timed_out = 0; float elapsed_time; struct sctp_rr_request_struct *sctp_rr_request; struct sctp_rr_response_struct *sctp_rr_response; struct sctp_rr_results_struct *sctp_rr_results; sctp_rr_request = (struct sctp_rr_request_struct *)netperf_request.content.test_specific_data; sctp_rr_response = (struct sctp_rr_response_struct *)netperf_response.content.test_specific_data; sctp_rr_results = (struct sctp_rr_results_struct *)netperf_response.content.test_specific_data; if (debug) { fprintf(where,"netserver: recv_sctp_rr_1toMany: entered...\n"); fflush(where); } /* We want to set-up the listen socket with all the desired */ /* parameters and then let the initiator know that all is ready. If */ /* socket size defaults are to be used, then the initiator will have */ /* sent us 0's. If the socket sizes cannot be changed, then we will */ /* send-back what they are. If that information cannot be determined, */ /* then we send-back -1's for the sizes. If things go wrong for any */ /* reason, we will drop back ten yards and punt. */ /* If anything goes wrong, we want the remote to know about it. It */ /* would be best if the error that the remote reports to the user is */ /* the actual error we encountered, rather than some bogus unexpected */ /* response type message. */ if (debug) { fprintf(where,"recv_sctp_rr_1toMany: setting the response type...\n"); fflush(where); } netperf_response.content.response_type = SCTP_RR_MANY_RESPONSE; if (debug) { fprintf(where,"recv_sctp_rr_1toMany: the response type is set...\n"); fflush(where); } /* allocate the recv and send rings with the requested alignments */ /* and offsets. raj 7/94 */ if (debug) { fprintf(where,"recv_sctp_rr_1toMany: requested recv alignment of %d offset %d\n", sctp_rr_request->recv_alignment, sctp_rr_request->recv_offset); fprintf(where,"recv_sctp_rr_1toMany: requested send alignment of %d offset %d\n", sctp_rr_request->send_alignment, sctp_rr_request->send_offset); fflush(where); } /* at some point, these need to come to us from the remote system */ if (send_width == 0) send_width = 1; if (recv_width == 0) recv_width = 1; send_ring = allocate_buffer_ring(send_width, sctp_rr_request->response_size, sctp_rr_request->send_alignment, sctp_rr_request->send_offset); recv_ring = allocate_buffer_ring(recv_width, sctp_rr_request->request_size, sctp_rr_request->recv_alignment, sctp_rr_request->recv_offset); /* create_data_socket expects to find some things in the global */ /* variables, so set the globals based on the values in the request. */ /* once the socket has been created, we will set the response values */ /* based on the updated value of those globals. raj 7/94 */ lss_size_req = sctp_rr_request->send_buf_size; lsr_size_req = sctp_rr_request->recv_buf_size; loc_nodelay = sctp_rr_request->no_delay; loc_rcvavoid = sctp_rr_request->so_rcvavoid; loc_sndavoid = sctp_rr_request->so_sndavoid; non_block = sctp_rr_request->non_blocking; set_hostname_and_port(local_name, port_buffer, nf_to_af(sctp_rr_request->ipfamily), sctp_rr_request->port); local_res = complete_addrinfo(local_name, local_name, port_buffer, nf_to_af(sctp_rr_request->ipfamily), SOCK_SEQPACKET, IPPROTO_SCTP, 0); /* Grab a socket to listen on, and then listen on it. */ if (debug) { fprintf(where,"recv_sctp_rr_1toMany: grabbing a socket...\n"); fflush(where); } s_rcv = create_data_socket(local_res); if (s_rcv < 0) { netperf_response.content.serv_errno = errno; send_response(); exit(1); } /* Now, let's set-up the socket to listen for connections */ if (listen(s_rcv, 5) == -1) { netperf_response.content.serv_errno = errno; close(s_rcv); send_response(); exit(1); } /* now get the port number assigned by the system */ addrlen = sizeof(myaddr_in); if (getsockname(s_rcv, (struct sockaddr *)&myaddr_in, &addrlen) == -1){ netperf_response.content.serv_errno = errno; close(s_rcv); send_response(); exit(1); } /* Now myaddr_in contains the port and the internet address this is */ /* returned to the sender also implicitly telling the sender that the */ /* socket buffer sizing has been done. */ sctp_rr_response->data_port_number = (int) ntohs(myaddr_in.sin_port); netperf_response.content.serv_errno = 0; /* But wait, there's more. If the initiator wanted cpu measurements, */ /* then we must call the calibrate routine, which will return the max */ /* rate back to the initiator. If the CPU was not to be measured, or */ /* something went wrong with the calibration, we will return a 0.0 to */ /* the initiator. */ sctp_rr_response->cpu_rate = (float)0.0; /* assume no cpu */ sctp_rr_response->measure_cpu = 0; if (sctp_rr_request->measure_cpu) { sctp_rr_response->measure_cpu = 1; sctp_rr_response->cpu_rate = calibrate_local_cpu(sctp_rr_request->cpu_rate); } /* before we send the response back to the initiator, pull some of */ /* the socket parms from the globals */ sctp_rr_response->send_buf_size = lss_size; sctp_rr_response->recv_buf_size = lsr_size; sctp_rr_response->no_delay = loc_nodelay; sctp_rr_response->so_rcvavoid = loc_rcvavoid; sctp_rr_response->so_sndavoid = loc_sndavoid; sctp_rr_response->test_length = sctp_rr_request->test_length; send_response(); /* Don't need events */ sctp_enable_events(s_rcv, 0); /* now that we are connected, mark the socket as non-blocking */ if (non_block) { if (!set_nonblock(s_rcv)) { perror("netperf: set_nonblock"); exit(1); } } /* FIXME: The way 1-to-Many test operates right now, we are including * association setup time into our measurements. The reason for this * is that the client creates multiple endpoints and connects each * endpoint to us using the connect call. On this end we simply call * recvmsg() to get data becuase there is no equivalen of accept() for * 1-to-Many API. * I think this is OK, but if it were to be fixed, the server side * would need to know how many associations are being setup and * have a recvmsg() loop with SCTP_ASSOC_CHANGE events waiting for * all the associations to be be established. * I am punting on this for now. */ addrlen = sizeof(peeraddr); /* Now it's time to start receiving data on the connection. We will */ /* first grab the apropriate counters and then start grabbing. */ cpu_start(sctp_rr_request->measure_cpu); /* The loop will exit when we hit the end of the test time, or when */ /* we have exchanged the requested number of transactions. */ if (sctp_rr_request->test_length > 0) { times_up = 0; trans_remaining = 0; start_timer(sctp_rr_request->test_length + PAD_TIME); } else { times_up = 1; trans_remaining = sctp_rr_request->test_length * -1; } trans_received = 0; while ((!times_up) || (trans_remaining > 0)) { recv_buf_size = sctp_rr_request->request_size; /* Receive the data. We don't particularly care which association * the data came in on. We'll simply be doing a receive untill * we get and MSG_EOR flag (meaning that a single transmission was * received) and a send to the same address, so the RR would be for * the same associations. * We can get away with this because the client will establish all * the associations before transmitting any data. Any partial data * will not have EOR thus will we will not send a response untill * we get everything. */ do { msg_flags = 0; if((bytes_recvd = sctp_recvmsg(s_rcv, recv_ring->buffer_ptr, recv_buf_size, (struct sockaddr *)&peeraddr, &addrlen, 0, &msg_flags)) == SOCKET_ERROR) { if (SOCKET_EINTR(bytes_recvd)) { /* the timer popped */ timed_out = 1; break; } else if (non_block & errno == EAGAIN) { /* do recvmsg again */ continue; } netperf_response.content.serv_errno = errno; send_response(); exit(1); } } while(!(msg_flags & MSG_EOR)); recv_ring = recv_ring->next; if (timed_out) { /* we hit the end of the test based on time - lets */ /* bail out of here now... */ if (debug) { fprintf(where,"yo5\n"); fflush(where); } break; } /* Now, send the response to the remote */ while ((bytes_sent=sctp_sendmsg(s_rcv, send_ring->buffer_ptr, sctp_rr_request->response_size, (struct sockaddr *)&peeraddr, addrlen, 0, 0, 0, 0, 0)) == SOCKET_ERROR) { if (SOCKET_EINTR(bytes_sent)) { /* the test timer has popped */ timed_out = 1; break; } else if (non_block && errno == EAGAIN) { continue; } netperf_response.content.serv_errno = 992; send_response(); exit(1); } if (timed_out) { if (debug) { fprintf(where,"yo6\n"); fflush(where); } /* we hit the end of the test based on time - lets */ /* bail out of here now... */ break; } send_ring = send_ring->next; trans_received++; if (trans_remaining) { trans_remaining--; } } /* The loop now exits due to timeout or transaction count being */ /* reached */ cpu_stop(sctp_rr_request->measure_cpu,&elapsed_time); stop_timer(); if (timed_out) { /* we ended the test by time, which was at least 2 seconds */ /* longer than we wanted to run. so, we want to subtract */ /* PAD_TIME from the elapsed_time. */ elapsed_time -= PAD_TIME; } /* send the results to the sender */ if (debug) { fprintf(where, "recv_sctp_rr: got %d transactions\n", trans_received); fflush(where); } sctp_rr_results->bytes_received = (trans_received * (sctp_rr_request->request_size + sctp_rr_request->response_size)); sctp_rr_results->trans_received = trans_received; sctp_rr_results->elapsed_time = elapsed_time; sctp_rr_results->cpu_method = cpu_method; sctp_rr_results->num_cpus = lib_num_loc_cpus; if (sctp_rr_request->measure_cpu) { sctp_rr_results->cpu_util = calc_cpu_util(elapsed_time); } if (debug) { fprintf(where, "recv_sctp_rr: test complete, sending results.\n"); fflush(where); } /* we are now done with the sockets */ close(s_rcv); send_response(); } void print_sctp_usage() { printf("%s",sctp_usage); exit(1); } void scan_sctp_args(argc, argv) int argc; char *argv[]; { #define SOCKETS_ARGS "BDhH:I:L:m:M:P:r:s:S:VN:T:46" extern char *optarg; /* pointer to option string */ int c; char arg1[BUFSIZ], /* argument holders */ arg2[BUFSIZ]; if (no_control) { fprintf(where, "The SCTP tests do not know how to deal with no control tests\n"); exit(-1); } strncpy(local_data_port,"0",sizeof(local_data_port)); strncpy(remote_data_port,"0",sizeof(remote_data_port)); /* Go through all the command line arguments and break them */ /* out. For those options that take two parms, specifying only */ /* the first will set both to that value. Specifying only the */ /* second will leave the first untouched. To change only the */ /* first, use the form "first," (see the routine break_args.. */ while ((c= getopt(argc, argv, SOCKETS_ARGS)) != EOF) { switch (c) { case '?': case '4': remote_data_family = AF_INET; local_data_family = AF_INET; break; case '6': #if defined(AF_INET6) remote_data_family = AF_INET6; local_data_family = AF_INET6; #else fprintf(stderr, "This netperf was not compiled on an IPv6 capable host!\n"); fflush(stderr); exit(-1); #endif break; case 'h': print_sctp_usage(); exit(1); case 'b': #ifdef WANT_FIRST_BURST first_burst_size = atoi(optarg); #else /* WANT_FIRST_BURST */ printf("Initial request burst functionality not compiled-in!\n"); #endif /* WANT_FIRST_BURST */ break; case 'D': /* set the nodelay flag */ loc_nodelay = 1; rem_nodelay = 1; break; case 'H': break_args_explicit(optarg,arg1,arg2); if (arg1[0]) { /* make sure we leave room for the NULL termination boys and girls. raj 2005-02-82 */ remote_data_address = malloc(strlen(arg1)+1); strncpy(remote_data_address,arg1,strlen(arg1)); } if (arg2[0]) remote_data_family = parse_address_family(arg2); break; case 'L': break_args_explicit(optarg,arg1,arg2); if (arg1[0]) { /* make sure we leave room for the NULL termination boys and girls. raj 2005-02-82 */ local_data_address = malloc(strlen(arg1)+1); strncpy(local_data_address,arg1,strlen(arg1)); } if (arg2[0]) local_data_family = parse_address_family(arg2); break; case 'P': /* set the local and remote data port numbers for the tests to allow them to run through those blankety blank end-to-end breaking firewalls. raj 2004-06-15 */ break_args(optarg,arg1,arg2); if (arg1[0]) strncpy(local_data_port,arg1,sizeof(local_data_port)); if (arg2[0]) strncpy(remote_data_port,arg2,sizeof(remote_data_port)); break; case 's': /* set local socket sizes */ break_args(optarg,arg1,arg2); if (arg1[0]) lss_size_req = convert(arg1); if (arg2[0]) lsr_size_req = convert(arg2); break; case 'S': /* set remote socket sizes */ break_args(optarg,arg1,arg2); if (arg1[0]) rss_size_req = convert(arg1); if (arg2[0]) rsr_size_req = convert(arg2); break; case 'r': /* set the request/response sizes */ break_args(optarg,arg1,arg2); if (arg1[0]) req_size = convert(arg1); if (arg2[0]) rsp_size = convert(arg2); break; case 'm': /* set size of the buffer for each sent message */ send_size = convert(optarg); break; case 'M': /* set the size of the buffer for each received message */ recv_size = convert(optarg); break; case 't': /* set the test name */ strcpy(test_name,optarg); break; case 'W': /* set the "width" of the user space data */ /* buffer. This will be the number of */ /* send_size buffers malloc'd in the */ /* *_STREAM test. It may be enhanced to set */ /* both send and receive "widths" but for now */ /* it is just the sending *_STREAM. */ send_width = convert(optarg); break; case 'V': /* we want to do copy avoidance and will set */ /* it for everything, everywhere, if we really */ /* can. of course, we don't know anything */ /* about the remote... */ #ifdef SO_SND_COPYAVOID loc_sndavoid = 1; #else loc_sndavoid = 0; printf("Local send copy avoidance not available.\n"); #endif #ifdef SO_RCV_COPYAVOID loc_rcvavoid = 1; #else loc_rcvavoid = 0; printf("Local recv copy avoidance not available.\n"); #endif rem_sndavoid = 1; rem_rcvavoid = 1; break; case 'N': /* this opton allows the user to set the number of * messages to send. This in effect modifies the test * time. If we know the message size, then the we can * express the test time as message_size * number_messages */ msg_count = convert (optarg); if (msg_count > 0) test_time = 0; break; case 'B': non_block = 1; break; case 'T': num_associations = atoi(optarg); if (num_associations <= 1) { printf("Number of SCTP associations must be >= 1\n"); exit(1); } break; }; } } #endif /* WANT_SCTP */