/* * Copyright (C) 2015 Freie Universität Berlin * * This file is subject to the terms and conditions of the GNU Lesser * General Public License v2.1. See the file LICENSE in the top level * directory for more details. */ /** * @ingroup examples * @{ * * @file * @brief Example application for demonstrating the RIOT network stack * * @author Hauke Petersen * * @} */ #include #include #include #include #include #include #include #include "board.h" #include "periph_conf.h" #include "periph/gpio.h" #include "net/sock/udp.h" #include "net/gnrc/ipv6.h" #include "net/af.h" #include "net/sixlowpan.h" #include "net/gnrc/pktdump.h" #include "shell.h" #include "shell_commands.h" #include "msg.h" #include "thread.h" #include "sched.h" #include "kernel_types.h" #include "net/netstats.h" #include "net/ipv6/addr.h" #include "periph/timer.h" #include "net/gnrc/ipv6/netif.h" #include "net/gnrc/netif.h" #include "net/gnrc/netapi.h" #include "net/netopt.h" #include "net/gnrc/pkt.h" #include "net/gnrc/pktbuf.h" #include "net/gnrc/netif/hdr.h" #include "net/gnrc/sixlowpan/netif.h" #include "net/fib.h" #include "net/gnrc/udp.h" #include "periph/pwm.h" #include "od.h" #include "net/sntp.h" #include "net/ntp_packet.h" #ifdef MODULE_SCHEDSTATISTICS #include "xtimer.h" #endif #ifdef MODULE_TLSF #include "tlsf.h" #endif #define MAIN_QUEUE_SIZE (8) /** * @brief The maximal expected link layer address length in byte */ #define MAX_ADDR_LEN (8U) /** * @brief The default IPv6 prefix length if not specified. */ #define SC_NETIF_IPV6_DEFAULT_PREFIX_LEN (64) #define _STACKSIZE (THREAD_STACKSIZE_DEFAULT + THREAD_EXTRA_STACKSIZE_PRINTF) #define MSG_TYPE_ISR (0x3456) #define MAXPAC 100 #define MAXLEN 1024 #define ECHOLEN 1 //addr ipv6 link local node 1: fe80::1210:642c:1432:1702 uint8_t node1[16]={0xfe,0x80,0x00,0x00,0x00,0x00,0x00,0x00,0x12,0x10,0x64,0x2c,0x14,0x32,0x17,0x02}; // addr ipv6 link local node 2: fe80::1210:6432:140f:1732 //uint8_t node2[16]={0xfe,0x80,0x00,0x00,0x00,0x00,0x00,0x00,0x12,0x10,0x64,0x32,0x14,0x0f,0x17,0x32}; //addr ipv6 link local node 3: fe80::1210:642d:1439:1736 uint8_t node3[16]={0xfe,0x80,0x00,0x00,0x00,0x00,0x00,0x00,0x12,0x10,0x64,0x2d,0x14,0x39,0x17,0x36}; char sock_server_stack[THREAD_STACKSIZE_MAIN]; char sock_client_stack[THREAD_STACKSIZE_MAIN]; char sock_time_server_stack[THREAD_STACKSIZE_MAIN]; kernel_pid_t server, client,time_server; sock_udp_ep_t local = SOCK_IPV6_EP_ANY; sock_udp_t sock; sock_udp_ep_t local_ntp = SOCK_IPV6_EP_ANY; sock_udp_t sock_ntp; static ntp_packet_t sntp_packet; void *sock_time_server_thread(void *arg) { (void) arg; local_ntp.port = NTP_PORT; if (sock_udp_create(&sock_ntp, &local_ntp, NULL, 0) < 0) { puts("Error creating UDP sock"); return NULL; } while (1) { sock_udp_ep_t remote; ssize_t res; if ((res = sock_udp_recv(&sock_ntp,&sntp_packet, sizeof(sntp_packet), SOCK_NO_TIMEOUT, &remote)) >= 0) { sntp_packet.receive.seconds=byteorder_htonl( xtimer_now_usec()); sntp_packet.origin.seconds=sntp_packet.transmit.seconds; sntp_packet.transmit.seconds=byteorder_htonl( xtimer_now_usec()); if (sock_udp_send(&sock_ntp, &sntp_packet, sizeof(sntp_packet), &remote) < 0) { puts("Error sending reply"); } } } return NULL; } typedef struct list { uint32_t send_time; char packet[MAXLEN]; }Data; // calculate the time diff between start and end (in us) uint32_t delay(uint32_t send_time, uint32_t recv_time) { return(recv_time-send_time); } // calculate the min/max/average value from an array void rttd(float t[], int size, uint32_t time) { float avg; float min = t[0]; float max = 0.0; float sum=0.0; int i; for(i=0; i< size; i++){ sum += t[i]; if(t[i] > max) {max = t[i];} if(t[i] < min) {min = t[i];} } avg = sum/(float)size; if(size!=0)printf("Round-trip delay: min/avg/max = %f/%f/%f ms, time = %f s\n",min*1000,avg*1000,max*1000,(float)time/1000000); } void *sock_server_thread(void *arg) { (void) arg; local.port = 1234; Data buf; int64_t offset = 0; int deadline; sock_udp_ep_t server = { .port = NTP_PORT, .family = AF_INET6 }; ipv6_addr_from_str((ipv6_addr_t *)&server.addr, "baad:a555::1702"); if (sock_udp_create(&sock, &local, NULL, 0) < 0) { puts("Error creating UDP sock"); return NULL; } if (sntp_sync(&server, SOCK_NO_TIMEOUT) < 0) { puts("Error in synchronization"); return NULL; } offset = sntp_get_offset(); printf("offset: %i \n",(int)offset); while (1) { sock_udp_ep_t remote; size_t res; if ((res = sock_udp_recv(&sock,&buf, sizeof(buf),SOCK_NO_TIMEOUT ,&remote)) < 0) { puts("Can't receive datagram\n"); } deadline = xtimer_now_usec() + offset - buf.send_time; printf("tps de transmission : %i\n",deadline); //puts("Got a UDP datagram\n"); //send ack if (sock_udp_send(&sock,&buf,sizeof(buf), &remote) != res) { puts("Error sending reply"); } } return NULL; } void *sock_client_thread(void *arg) { (void) arg; ssize_t res; Data data; Data data2; //int i; //uint32_t timebuf; sock_udp_ep_t remote = { .family = AF_INET6 }; remote.port = 1234; remote.addr.ipv6[0] = 0xba; remote.addr.ipv6[1] = 0xad; remote.addr.ipv6[2] = 0xa5; remote.addr.ipv6[3] = 0x55; remote.addr.ipv6[14] = 0x17; remote.addr.ipv6[15] = 0x36; /* fill up the echo message for (i = 0; i < ECHOLEN; i++) { data.donnees[i] = 'e'; }*/ for (;;) { data.send_time = xtimer_now_usec(); //test=xtimer_now_usec(); printf("Heure server: %" PRIu32 "\n",data.heure_actuelle); if (sock_udp_send(&sock,&data,sizeof(data), &remote) < 0) { puts("Error sending message"); } if ((res = sock_udp_recv(&sock,&data2,sizeof(data2),1 * US_PER_SEC,NULL)) < 0) { if (res == -ETIMEDOUT) { puts("Timedout"); } else { puts("Error receiving message"); } } else{ //end = xtimer_now_usec(); //timebuf = delay(test,end); // printf("latency: %" PRIu32 "\n",timebuf); //printf("heure reception: %" PRIu32 "\n",end); xtimer_sleep(1); } } return NULL; } static void init_interface(void) { kernel_pid_t ifs[GNRC_NETIF_NUMOF]; ipv6_addr_t addr = IPV6_ADDR_UNSPECIFIED; ipv6_addr_t tmp_addr= IPV6_ADDR_UNSPECIFIED; uint8_t hwaddr[MAX_ADDR_LEN]; int res; gnrc_netif_get(ifs); //addresses gobales addr.u8[0] = 0xba; addr.u8[1] = 0xad; addr.u8[2] = 0xa5; addr.u8[3] = 0x55; res = gnrc_netapi_get(ifs[0], NETOPT_ADDRESS, 0, hwaddr, sizeof(hwaddr)); if (res >= 0) { addr.u8[14] = *hwaddr; addr.u8[15] = *(hwaddr+1); } memcpy(tmp_addr.u8,addr.u8,IPV6_ADDR_BIT_LEN); gnrc_ipv6_netif_add_addr(ifs[0], &addr, 64, GNRC_IPV6_NETIF_ADDR_FLAGS_UNICAST); /* model ipv6 addr: baad:a555::Hwaddr */ if((addr.u8[14]==0x17)&&(addr.u8[15]==0x02)) { tmp_addr.u8[14] = 0x17; tmp_addr.u8[15] = 0x36; fib_add_entry(&gnrc_ipv6_fib_table, ifs[0],tmp_addr.u8, IN6ADDRSZ, 0,node3, IN6ADDRSZ, 0, FIB_LIFETIME_NO_EXPIRE); client=thread_create(sock_client_stack,sizeof(sock_client_stack),8,THREAD_CREATE_STACKTEST,sock_client_thread,NULL,"sock_client_thread"); time_server=thread_create(sock_time_server_stack,sizeof(sock_time_server_stack),6,THREAD_CREATE_STACKTEST,sock_time_server_thread,NULL,"sock_time_server_thread"); } else if((addr.u8[14]==0x17)&&(addr.u8[15]==0x36)) { tmp_addr.u8[14] = 0x17; tmp_addr.u8[15] = 0x02; fib_add_entry(&gnrc_ipv6_fib_table, ifs[0],tmp_addr.u8, IN6ADDRSZ, 0,node1, IN6ADDRSZ, 0, FIB_LIFETIME_NO_EXPIRE); server=thread_create(sock_server_stack,sizeof(sock_server_stack),6,THREAD_CREATE_STACKTEST,sock_server_thread,NULL,"sock_server_thread"); } else { puts("new node?"); } } static msg_t _main_msg_queue[MAIN_QUEUE_SIZE]; static const shell_command_t shell_commands[] = { { NULL, NULL, NULL } }; int main(void) { msg_init_queue(_main_msg_queue, MAIN_QUEUE_SIZE); puts("RIOT network stack example application"); init_interface(); /* start shell */ puts("All up, running the shell now"); char line_buf[SHELL_DEFAULT_BUFSIZE]; shell_run(shell_commands, line_buf, SHELL_DEFAULT_BUFSIZE); /* should be never reached */ return 0; }