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//========================================================================== // // tests/nc_test_slave.c // // Network characterizations test (slave portion) // //========================================================================== // ####BSDALTCOPYRIGHTBEGIN#### // ------------------------------------------- // Portions of this software may have been derived from FreeBSD, OpenBSD, // or other sources, and if so are covered by the appropriate copyright // and license included herein. // ------------------------------------------- // ####BSDALTCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): gthomas // Contributors: gthomas // Date: 2000-01-10 // Purpose: // Description: // // //####DESCRIPTIONEND#### // //========================================================================== // Network characterization test code - slave portion #include "nc_test_framework.h" #include <math.h> #ifdef __ECOS #ifndef CYGPKG_LIBC_STDIO #define perror(s) diag_printf(#s ": %s\n", strerror(errno)) #endif #define STACK_SIZE (CYGNUM_HAL_STACK_SIZE_TYPICAL + 0x1000) #define MAX_LOAD_THREAD_LEVEL 20 #define MIN_LOAD_THREAD_LEVEL 0 #define NUM_LOAD_THREADS 10 #define IDLE_THREAD_PRIORITY CYGPKG_NET_THREAD_PRIORITY+3 #define LOAD_THREAD_PRIORITY CYGPKG_NET_THREAD_PRIORITY-1 #define MAIN_THREAD_PRIORITY CYGPKG_NET_THREAD_PRIORITY-2 #define DESIRED_BACKGROUND_LOAD 20 static char main_thread_stack[CYGHWR_NET_DRIVERS][STACK_SIZE]; static cyg_thread main_thread_data[CYGHWR_NET_DRIVERS]; static cyg_handle_t main_thread_handle[CYGHWR_NET_DRIVERS]; static char idle_thread_stack[STACK_SIZE]; static cyg_thread idle_thread_data; static cyg_handle_t idle_thread_handle; static cyg_sem_t idle_thread_sem; volatile static long long idle_thread_count; static cyg_tick_count_t idle_thread_start_time; static cyg_tick_count_t idle_thread_stop_time; static char load_thread_stack[NUM_LOAD_THREADS][STACK_SIZE]; static cyg_thread load_thread_data[NUM_LOAD_THREADS]; static cyg_handle_t load_thread_handle[NUM_LOAD_THREADS]; static cyg_sem_t load_thread_sem[NUM_LOAD_THREADS]; static long load_thread_level; static void calibrate_load(int load); static void start_load(int load); static void do_some_random_computation(int p); #define abs(n) ((n) < 0 ? -(n) : (n)) #endif #ifdef __ECOS #define test_param_t cyg_addrword_t #ifdef CYGDBG_NET_TIMING_STATS extern void show_net_times(void); #endif #else #define test_param_t int #endif #define MAX_BUF 8192 static unsigned char in_buf[MAX_BUF], out_buf[MAX_BUF]; #ifdef __ECOS extern void cyg_test_exit(void); #else void cyg_test_exit(void) { test_printf("... Done\n"); exit(1); } static void show_net_times(void) { } #endif #ifdef __ECOS static void test_delay(int ticks) { cyg_thread_delay(ticks); } #else static void test_delay(int ticks) { usleep(ticks * 10000); } #endif void pexit(char *s) { perror(s); #ifdef CYGDBG_NET_TIMING_STATS show_net_times(); #endif cyg_test_exit(); } // // Generic UDP test // static void do_udp_test(int s1, struct nc_request *req, struct sockaddr_in *master) { int i, s, td_len, seq, seq_errors, lost; struct sockaddr_in test_chan_slave, test_chan_master; fd_set fds; struct timeval timeout; struct nc_test_results results; struct nc_test_data *tdp; int nsent, nrecvd; int need_recv, need_send; need_recv = true; need_send = true; switch (ntohl(req->type)) { case NC_REQUEST_UDP_SEND: need_recv = false; need_send = true; break; case NC_REQUEST_UDP_RECV: need_recv = true; need_send = false; break; case NC_REQUEST_UDP_ECHO: break; } s = socket(AF_INET, SOCK_DGRAM, 0); if (s < 0) { pexit("datagram socket"); } memset((char *) &test_chan_slave, 0, sizeof(test_chan_slave)); test_chan_slave.sin_family = AF_INET; #ifdef __ECOS test_chan_slave.sin_len = sizeof(test_chan_slave); #endif test_chan_slave.sin_addr.s_addr = htonl(INADDR_ANY); test_chan_slave.sin_port = htons(ntohl(req->slave_port)); if (bind(s, (struct sockaddr *) &test_chan_slave, sizeof(test_chan_slave)) < 0) { perror("bind"); close(s); } memcpy(&test_chan_master, master, sizeof(*master)); test_chan_master.sin_port = htons(ntohl(req->master_port)); nsent = 0; nrecvd = 0; seq = 0; seq_errors = 0; lost = 0; for (i = 0; i < ntohl(req->nbufs); i++) { if (need_recv) { FD_ZERO(&fds); FD_SET(s, &fds); timeout.tv_sec = NC_TEST_TIMEOUT; timeout.tv_usec = 0; if (select(s+1, &fds, 0, 0, &timeout) <= 0) { test_printf("recvfrom timeout, expecting seq #%d\n", seq); if (++lost > MAX_ERRORS) { test_printf("... giving up\n"); break; } } else { nrecvd++; tdp = (struct nc_test_data *)in_buf; td_len = ntohl(req->buflen) + sizeof(struct nc_test_data); if (recvfrom(s, tdp, td_len, 0, 0, 0) < 0) { perror("recvfrom"); close(s); return; } if ((ntohl(tdp->key1) == NC_TEST_DATA_KEY1) && (ntohl(tdp->key2) == NC_TEST_DATA_KEY2)) { if (ntohl(tdp->seq) != seq) { test_printf("Packets out of sequence - recvd: %d, expected: %d\n", ntohl(tdp->seq), seq); seq = ntohl(tdp->seq); seq_errors++; } } else { test_printf("Bad data packet - key: %x/%x, seq: %d\n", ntohl(tdp->key1), ntohl(tdp->key2), ntohl(tdp->seq)); } } } if (need_send) { int retries = 10; int sent = false; int res; tdp = (struct nc_test_data *)out_buf; tdp->key1 = htonl(NC_TEST_DATA_KEY1); tdp->key2 = htonl(NC_TEST_DATA_KEY2); tdp->seq = htonl(seq); td_len = ntohl(req->buflen) + sizeof(struct nc_test_data); tdp->len = htonl(td_len); while (!sent && (--retries >= 0)) { res = sendto(s, tdp, td_len, 0, (struct sockaddr *)&test_chan_master, sizeof(test_chan_master)); if (res > 0) { sent = true; break; } if (errno == ENOBUFS) { // Saturated the system test_delay(1); // Time for 200 500 byte 10-baseT packets } else { // What else to do? close(s); return; } } if (sent) { nsent++; } else { perror("sendto"); } } seq++; } results.key1 = htonl(NC_TEST_RESULT_KEY1); results.key2 = htonl(NC_TEST_RESULT_KEY2); results.seq = req->seq; results.nsent = htonl(nsent); results.nrecvd = htonl(nrecvd); if (sendto(s, &results, sizeof(results), 0, (struct sockaddr *)&test_chan_master, sizeof(test_chan_master)) < 0) { perror("sendto results"); } close(s); } // // Read data from a stream, accounting for the fact that packet 'boundaries' // are not preserved. This can also timeout (which would probably wreck the // data boundaries). // int do_read(int fd, void *buf, int buflen) { char *p = (char *)buf; int len = buflen; int res; while (len) { res = read(fd, p, len); if (res < 0) { perror("read"); } else { len -= res; p += res; if (res == 0) { break; } } } return (buflen - len); } // // Generic TCP test // static void do_tcp_test(int s1, struct nc_request *req, struct sockaddr_in *master) { int i, s, td_len, seq, seq_errors, lost, test_chan, res; socklen_t len; struct sockaddr_in test_chan_slave, test_chan_master; struct nc_test_results results; struct nc_test_data *tdp; int nsent, nrecvd; int need_recv, need_send; int one = 1; static int slave_tcp_port = -1; need_recv = true; need_send = true; switch (ntohl(req->type)) { case NC_REQUEST_TCP_SEND: need_recv = false; need_send = true; break; case NC_REQUEST_TCP_RECV: need_recv = true; need_send = false; break; case NC_REQUEST_TCP_ECHO: break; } if (slave_tcp_port < 0) { s = socket(AF_INET, SOCK_STREAM, 0); if (s < 0) { pexit("datagram socket"); } if (setsockopt(s, SOL_SOCKET, SO_REUSEADDR, &one, sizeof(one))) { perror("setsockopt SO_REUSEADDR"); return; } #ifdef SO_REUSEPORT if (setsockopt(s, SOL_SOCKET, SO_REUSEPORT, &one, sizeof(one))) { perror("setsockopt SO_REUSEPORT"); return; } #endif memset((char *) &test_chan_slave, 0, sizeof(test_chan_slave)); test_chan_slave.sin_family = AF_INET; #ifdef __ECOS test_chan_slave.sin_len = sizeof(test_chan_slave); #endif test_chan_slave.sin_addr.s_addr = htonl(INADDR_ANY); test_chan_slave.sin_port = htons(ntohl(req->slave_port)); if (bind(s, (struct sockaddr *) &test_chan_slave, sizeof(test_chan_slave)) < 0) { perror("bind"); close(s); } listen(s, SOMAXCONN); slave_tcp_port = s; } s = slave_tcp_port; len = sizeof(test_chan_master); if ((test_chan = accept(s, (struct sockaddr *)&test_chan_master, &len)) < 0) { pexit("accept"); } len = sizeof(test_chan_master); getpeername(test_chan, (struct sockaddr *)&test_chan_master, &len); test_printf("connection from %s.%d\n", inet_ntoa(test_chan_master.sin_addr), ntohs(test_chan_master.sin_port)); nsent = 0; nrecvd = 0; seq = 0; seq_errors = 0; lost = 0; for (i = 0; i < ntohl(req->nbufs); i++) { if (need_recv) { tdp = (struct nc_test_data *)in_buf; td_len = ntohl(req->buflen) + sizeof(struct nc_test_data); res = do_read(test_chan, tdp, td_len); if (res != td_len) { test_printf("recvfrom timeout, expecting seq #%d\n", seq); if (++lost > MAX_ERRORS) { test_printf("... giving up\n"); break; } } else { nrecvd++; if ((ntohl(tdp->key1) == NC_TEST_DATA_KEY1) && (ntohl(tdp->key2) == NC_TEST_DATA_KEY2)) { if (ntohl(tdp->seq) != seq) { test_printf("Packets out of sequence - recvd: %d, expected: %d\n", ntohl(tdp->seq), seq); seq = ntohl(tdp->seq); seq_errors++; } } else { test_printf("Bad data packet - key: %x/%x, seq: %d\n", ntohl(tdp->key1), ntohl(tdp->key2), ntohl(tdp->seq)); } } } if (need_send) { tdp = (struct nc_test_data *)out_buf; tdp->key1 = htonl(NC_TEST_DATA_KEY1); tdp->key2 = htonl(NC_TEST_DATA_KEY2); tdp->seq = htonl(seq); td_len = ntohl(req->buflen) + sizeof(struct nc_test_data); tdp->len = htonl(td_len); if (write(test_chan, tdp, td_len) != td_len) { perror("write"); if (errno == ENOBUFS) { // Saturated the system test_delay(25); } else { // What else to do? close(test_chan); return; } } else { nsent++; } } seq++; } results.key1 = htonl(NC_TEST_RESULT_KEY1); results.key2 = htonl(NC_TEST_RESULT_KEY2); results.seq = req->seq; results.nsent = htonl(nsent); results.nrecvd = htonl(nrecvd); if (write(test_chan, &results, sizeof(results)) != sizeof(results)) { perror("write"); } close(test_chan); } // // Protocol driver for testing slave. // // This function is the main routine running here, handling requests sent from // the master and providing various responses. // static void nc_slave(test_param_t param) { int s; socklen_t masterlen; struct sockaddr_in my_addr, master; struct nc_request req; struct nc_reply reply; int done = false; test_printf("Start test for eth%d\n", param); s = socket(AF_INET, SOCK_DGRAM, 0); if (s < 0) { pexit("datagram socket"); } memset((char *) &my_addr, 0, sizeof(my_addr)); my_addr.sin_family = AF_INET; #ifdef __ECOS my_addr.sin_len = sizeof(my_addr); #endif my_addr.sin_addr.s_addr = htonl(INADDR_ANY); my_addr.sin_port = htons(NC_SLAVE_PORT); if (bind(s, (struct sockaddr *) &my_addr, sizeof(my_addr)) < 0) { pexit("bind"); } while (!done) { masterlen = sizeof(master); if (recvfrom(s, &req, sizeof(req), 0, (struct sockaddr *)&master, &masterlen) < 0) { pexit("recvfrom"); } #if 0 test_printf("Request %d from %s:%d\n", ntohl(req.type), inet_ntoa(master.sin_addr), ntohs(master.sin_port)); #endif reply.response = htonl(NC_REPLY_ACK); reply.seq = req.seq; switch (ntohl(req.type)) { case NC_REQUEST_DISCONNECT: done = true; break; case NC_REQUEST_UDP_SEND: test_printf("UDP send - %d buffers, %d bytes\n", ntohl(req.nbufs), ntohl(req.buflen)); break; case NC_REQUEST_UDP_RECV: test_printf("UDP recv - %d buffers, %d bytes\n", ntohl(req.nbufs), ntohl(req.buflen)); break; case NC_REQUEST_UDP_ECHO: test_printf("UDP echo - %d buffers, %d bytes\n", ntohl(req.nbufs), ntohl(req.buflen)); break; case NC_REQUEST_TCP_SEND: test_printf("TCP send - %d buffers, %d bytes\n", ntohl(req.nbufs), ntohl(req.buflen)); break; case NC_REQUEST_TCP_RECV: test_printf("TCP recv - %d buffers, %d bytes\n", ntohl(req.nbufs), ntohl(req.buflen)); break; case NC_REQUEST_TCP_ECHO: test_printf("TCP echo - %d buffers, %d bytes\n", ntohl(req.nbufs), ntohl(req.buflen)); break; #ifdef __ECOS case NC_REQUEST_SET_LOAD: start_load(ntohl(req.nbufs)); break; case NC_REQUEST_START_IDLE: test_printf("Start IDLE thread\n"); idle_thread_count = 0; idle_thread_start_time = cyg_current_time(); cyg_semaphore_post(&idle_thread_sem); break; case NC_REQUEST_STOP_IDLE: cyg_semaphore_wait(&idle_thread_sem); idle_thread_stop_time = cyg_current_time(); test_printf("Stop IDLE thread\n"); reply.misc.idle_results.elapsed_time = htonl(idle_thread_stop_time - idle_thread_start_time); reply.misc.idle_results.count[0] = htonl(idle_thread_count >> 32); reply.misc.idle_results.count[1] = htonl((long)idle_thread_count); break; #endif default: test_printf("Unrecognized request: %d\n", ntohl(req.type)); reply.response = htonl(NC_REPLY_NAK); reply.reason = htonl(NC_REPLY_NAK_UNKNOWN_REQUEST); break; } if (sendto(s, &reply, sizeof(reply), 0, (struct sockaddr *)&master, masterlen) < 0) { pexit("sendto"); } if (reply.response == ntohl(NC_REPLY_NAK)) { continue; } switch (ntohl(req.type)) { case NC_REQUEST_UDP_SEND: case NC_REQUEST_UDP_RECV: case NC_REQUEST_UDP_ECHO: do_udp_test(s, &req, &master); break; case NC_REQUEST_TCP_SEND: case NC_REQUEST_TCP_RECV: case NC_REQUEST_TCP_ECHO: do_tcp_test(s, &req, &master); break; case NC_REQUEST_START_IDLE: case NC_REQUEST_STOP_IDLE: case NC_REQUEST_SET_LOAD: default: break; } } close(s); } void net_test(test_param_t param) { // int i; if (param == 0) { test_printf("Start Network Characterization - SLAVE\n"); #ifdef __ECOS init_all_network_interfaces(); calibrate_load(DESIRED_BACKGROUND_LOAD); #if 0 // I can see what this is trying to do, but I get "bind: Address already in // use" errors from the 2nd interface - and the parameter is not used // anyway, so one thread does quite well enough (but only tests one i/f at // once). // Comment in the 'int i' above too. for (i = 1; i < CYGHWR_NET_DRIVERS; i++) { cyg_thread_resume(main_thread_handle[i]); // Start other threads } #endif #endif } nc_slave(param); #ifdef CYGDBG_NET_TIMING_STATS show_net_times(); #endif cyg_test_exit(); } #ifdef __ECOS // // This function is called to calibrate the "background load" which can be // applied during testing. It will be called before any commands from the // host are managed. // static void calibrate_load(int desired_load) { long long no_load_idle, load_idle; int percent_load; int high, low; // Set limits high = MAX_LOAD_THREAD_LEVEL; low = MIN_LOAD_THREAD_LEVEL; // Compute the "no load" idle value idle_thread_count = 0; cyg_semaphore_post(&idle_thread_sem); // Start idle thread cyg_thread_delay(1*100); // Pause for one second cyg_semaphore_wait(&idle_thread_sem); // Stop idle thread no_load_idle = idle_thread_count; diag_printf("No load = %d\n", (int)idle_thread_count); // First ensure that the HIGH level is indeed higher while (true) { load_thread_level = high; start_load(desired_load); // Start up a given load idle_thread_count = 0; cyg_semaphore_post(&idle_thread_sem); // Start idle thread cyg_thread_delay(1*100); // Pause for one second cyg_semaphore_wait(&idle_thread_sem); // Stop idle thread load_idle = idle_thread_count; start_load(0); // Shut down background load percent_load = 100 - ((load_idle * 100) / no_load_idle); diag_printf("High Load[%ld] = %d => %d%%\n", load_thread_level, (int)idle_thread_count, percent_load); if ( percent_load > desired_load ) break; // HIGH level is indeed higher low = load_thread_level; // known to be lower high *= 2; // else double it and try again } // Now chop down to the level required while (true) { load_thread_level = (high + low) / 2; start_load(desired_load); // Start up a given load idle_thread_count = 0; cyg_semaphore_post(&idle_thread_sem); // Start idle thread cyg_thread_delay(1*100); // Pause for one second cyg_semaphore_wait(&idle_thread_sem); // Stop idle thread load_idle = idle_thread_count; start_load(0); // Shut down background load percent_load = 100 - ((load_idle * 100) / no_load_idle); diag_printf("Load[%ld] = %d => %d%%\n", load_thread_level, (int)idle_thread_count, percent_load); if (((high-low) <= 1) || (abs(desired_load-percent_load) <= 2)) break; if (percent_load < desired_load) { low = load_thread_level; } else { high = load_thread_level; } } // Now we are within a few percent of the target; scale the load // factor to get a better fit, and test it, print the answer. load_thread_level *= desired_load; load_thread_level /= percent_load; start_load(desired_load); // Start up a given load idle_thread_count = 0; cyg_semaphore_post(&idle_thread_sem); // Start idle thread cyg_thread_delay(1*100); // Pause for one second cyg_semaphore_wait(&idle_thread_sem); // Stop idle thread load_idle = idle_thread_count; start_load(0); // Shut down background load percent_load = 100 - ((load_idle * 100) / no_load_idle); diag_printf("Final load[%ld] = %d => %d%%\n", load_thread_level, (int)idle_thread_count, percent_load); // no_load_idle_count_1_second = no_load_idle; } // // This function is called to set up a load level of 'load' percent (given // as a whole number, e.g. start_load(20) would mean initiate a background // load of 20%, leaving the cpu 80% idle). // static void start_load(int load) { static int prev_load = 0; int i; test_printf("Set background load = %d%%\n", load); if (load == 0) { if (prev_load == 0) return; // Nothing out there to stop for (i = 0; i < prev_load/10; i++) { cyg_semaphore_wait(&load_thread_sem[i]); } prev_load = 0; } else { for (i = 0; i < load/10; i++) { cyg_semaphore_post(&load_thread_sem[i]); } prev_load = load; } } // // These thread(s) do some amount of "background" computing. This is used // to simulate a given load level. They need to be run at a higher priority // than the network code itself. // // Like the "idle" thread, they run as long as their "switch" (aka semaphore) // is enabled. // void net_load(cyg_addrword_t who) { int i; while (true) { cyg_semaphore_wait(&load_thread_sem[who]); for (i = 0; i < load_thread_level; i++) { do_some_random_computation(i); } cyg_thread_delay(1); // Wait until the next 'tick' cyg_semaphore_post(&load_thread_sem[who]); } } // // Some arbitrary computation, designed to use up the CPU and cause associated // cache "thrash" behaviour - part of background load modelling. // static void do_some_random_computation(int p) { // Just something that might be "hard" volatile double x; x = ((p * 10) * 3.14159) / 180.0; // radians } // // This thread does nothing but count. It will be allowed to count // as long as the semaphore is "free". // void net_idle(cyg_addrword_t param) { while (true) { cyg_semaphore_wait(&idle_thread_sem); idle_thread_count++; cyg_semaphore_post(&idle_thread_sem); } } void cyg_start(void) { int i; // Create processing threads for (i = 0; i < CYGHWR_NET_DRIVERS; i++) { cyg_thread_create(MAIN_THREAD_PRIORITY, // Priority net_test, // entry i, // entry parameter "Network test", // Name &main_thread_stack[i][0], // Stack STACK_SIZE, // Size &main_thread_handle[i], // Handle &main_thread_data[i] // Thread data structure ); } cyg_thread_resume(main_thread_handle[0]); // Start first one // Create the idle thread environment cyg_semaphore_init(&idle_thread_sem, 0); cyg_thread_create(IDLE_THREAD_PRIORITY, // Priority net_idle, // entry 0, // entry parameter "Network idle", // Name &idle_thread_stack[0], // Stack STACK_SIZE, // Size &idle_thread_handle, // Handle &idle_thread_data // Thread data structure ); cyg_thread_resume(idle_thread_handle); // Start it // Create the load threads and their environment(s) for (i = 0; i < NUM_LOAD_THREADS; i++) { cyg_semaphore_init(&load_thread_sem[i], 0); cyg_thread_create(LOAD_THREAD_PRIORITY, // Priority net_load, // entry i, // entry parameter "Background load", // Name &load_thread_stack[i][0], // Stack STACK_SIZE, // Size &load_thread_handle[i], // Handle &load_thread_data[i] // Thread data structure ); cyg_thread_resume(load_thread_handle[i]); // Start it } cyg_scheduler_start(); } #else int main(int argc, char *argv[]) { net_test(0); } #endif
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