main.c
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/*
* 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 <hauke.petersen@fu-berlin.de>
*
* @}
*/
#include <stdbool.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <inttypes.h>
#include <arpa/inet.h>
#include "periph/gpio.h"
#include "board.h"
#include "periph_conf.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 "thread.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"
#include "net/gnrc/rpl.h"
#include "net/gnrc/rpl/structs.h"
#include "net/gnrc/rpl/dodag.h"
#include "utlist.h"
#include "trickle.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 PWM_FREQ 1000
#define PWM_RES 1000
#define DEADLINE 30000
static msg_t _main_msg_queue[MAIN_QUEUE_SIZE];
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;
int ordre = 0;
int64_t offset = 0;
int timer_run = 0;
int tourne = 0;
int arret = 0;
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;
typedef struct tableau {
uint32_t heure_actuelle;
char donnees[2];
}Data;
/***************** RPL functions *****************/
int crea_rpl_dodag_root(uint8_t instance_id, ipv6_addr_t dodag_id)
{
gnrc_rpl_instance_t *inst = NULL;
inst = gnrc_rpl_root_init(instance_id, &dodag_id, false, false);
if (inst == NULL) {
char addr_str[IPV6_ADDR_MAX_STR_LEN];
printf("error: could not add DODAG (%s) to instance (%d)\n",
ipv6_addr_to_str(addr_str, &dodag_id, sizeof(addr_str)), instance_id);
return 1;
}
printf("successfully added a new RPL DODAG\n");
return 0;
}
/***************** /RPL functions ****************/
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;
}
void *sock_server_thread(void *arg)
{
(void) arg;
Data buf;
int compteur = 5;
int deadline;
local.port = 1234;
int interruption_msg = 0;
int sync = 0;
sock_udp_ep_t server = { .port = NTP_PORT, .family = AF_INET6 };
ipv6_addr_from_str((ipv6_addr_t *)&server.addr, "dead:beef::3402");
if (sock_udp_create(&sock, &local, 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, &buf, sizeof(buf), 5 * SEC_IN_USEC ,&remote)) >= 0) {
deadline = xtimer_now_usec() + offset - buf.heure_actuelle;
printf("tps de transmission : %i\n",deadline);
if(buf.donnees[0] == 'g' && buf.donnees[1] == 'o') {
if(sync == 0)
{
while(sntp_sync(&server, 5000000) < 0) {
puts("Erreur dans la synchronisation - Nouvelle tentative :");
}
offset = sntp_get_offset();
sync = 1;
printf("offset : %i\n",(int)offset);
}
if(interruption_msg == 1) {
puts("reprise de la communication - tentative de synchronisation :");
while(sntp_sync(&server, 5000000) < 0) {
puts("Erreur dans la synchronisation - Nouvelle tentative :");
}
offset = sntp_get_offset();
printf("offset : %i\n",(int)offset);
interruption_msg = 0;
}
if(deadline >= DEADLINE && compteur >=5) {
compteur = 0;
if(arret == 0) {
if (sock_udp_send(&sock, "d", sizeof("d"), &remote) < 0) {
puts("Error sending reply");
}
}
if(tourne == 1)
{
pwm_set(PWM_DEV(0),1,987);
pwm_set(PWM_DEV(1),1,960);
}
if(timer_run == 0) {
puts("Degradation");
gpio_clear(LED1_PIN);
gpio_clear(LED2_PIN);
gpio_set(LED0_PIN);
timer_set(TIMER_DEV(1),0,25200);
timer_run = 1;
}
}
if(deadline >= DEADLINE && compteur < 5) {
compteur = 0;
if (sock_udp_send(&sock, "d", sizeof("d"), &remote) < 0) {
puts("Error sending reply");
}
}
if(deadline<=DEADLINE && compteur >=5) {
pwm_set(PWM_DEV(0),1,992);
pwm_set(PWM_DEV(1),1,658);
tourne = 1;
timer_run=0;
timer_clear(TIMER_DEV(1),0);
if (sock_udp_send(&sock, "n", sizeof("n"), &remote) < 0) {
puts("Error sending reply");
}
arret = 0;
gpio_clear(LED2_PIN);
gpio_clear(LED0_PIN);
gpio_set(LED1_PIN);
}
if(deadline<=DEADLINE && compteur <5) {
compteur++;
}
printf("compteur : %d\n",compteur);
memset(&buf,0,sizeof(buf));
if(arret == 1) {
if (sock_udp_send(&sock, "a", sizeof("a"), &remote) < 0) {
puts("Error sending reply");
}
}
}
}
else {
puts("msg non recu");
if(timer_run == 0 && interruption_msg == 0) {
timer_run = 1;
timer_set(TIMER_DEV(1),0,25200);
}
interruption_msg = 1;
if(tourne == 1)
{
pwm_set(PWM_DEV(0),1,987);
pwm_set(PWM_DEV(1),1,960);
gpio_clear(LED1_PIN);
gpio_clear(LED2_PIN);
gpio_set(LED0_PIN);
}
}
}
return NULL;
}
void *sock_client_thread(void *arg)
{
(void) arg;
Data data;
int vitesse=2;
uint8_t buf[3];
ssize_t res;
data.donnees[0] = 'g';
data.donnees[1] = 'o';
sock_udp_ep_t remote = { .family = AF_INET6 };
remote.port = 1234;
remote.addr.ipv6[0] = 0xde;
remote.addr.ipv6[1] = 0xad;
remote.addr.ipv6[2] = 0xbe;
remote.addr.ipv6[3] = 0xef;
remote.addr.ipv6[14] = 0x34;
remote.addr.ipv6[15] = 0x1e;
while (1) {
data.heure_actuelle = xtimer_now_usec();
if (sock_udp_send(&sock, &data, sizeof(data), &remote) < 0) {
puts("Error sending message");
}
if ((res = sock_udp_recv(&sock, buf, sizeof(buf), 0.05 * SEC_IN_USEC,NULL)) < 0) {
if (res == -ETIMEDOUT) {
vitesse = 1;
}
else {
puts("Error receiving message");
}
}
else {
if(buf[0] == 'n')
vitesse = 2;
else if(buf[0] == 'a') {
vitesse = 1;
gpio_set(LED2_PIN);
}
else vitesse = 1;
}
if(vitesse==2) {
gpio_clear(LED0_PIN);
gpio_clear(LED2_PIN);
gpio_toggle(LED1_PIN);
}
else {
gpio_clear(LED1_PIN);
gpio_toggle(LED0_PIN);
}
xtimer_sleep(vitesse);
}
return NULL;
}
static void arret_urgence(void *arg,int channel)
{
pwm_set(PWM_DEV(0),1,0);
pwm_set(PWM_DEV(1),1,0);
tourne = 0;
timer_run = 0;
arret = 1;
gpio_clear(LED0_PIN);
gpio_clear(LED1_PIN);
gpio_set(LED2_PIN);
puts("Arret d'urgence");
}
static void _init_timer(void)
{
timer_init(TIMER_DEV(1), CLOCK_CORECLOCK/2 ,&arret_urgence,NULL);
timer_irq_enable(TIMER_DEV(1));
}
static void _init_pwm(void)
{
pwm_init(PWM_DEV(0), PWM_LEFT, PWM_FREQ, PWM_RES);
pwm_set(PWM_DEV(0),1,0);
pwm_init(PWM_DEV(1), PWM_LEFT, PWM_FREQ, PWM_RES);
pwm_set(PWM_DEV(1),1,0);
}
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] = 0xde;
addr.u8[1] = 0xad;
addr.u8[2] = 0xbe;
addr.u8[3] = 0xef;
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: dead:beef::Hwaddr */
if((addr.u8[14]==0x34)&&(addr.u8[15]==0x02)){
crea_rpl_dodag_root(1, addr);
client=thread_create(sock_client_stack,sizeof(sock_client_stack),8,THREAD_CREATE_STACKTEST | THREAD_CREATE_WOUT_YIELD,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]==0x37)&&(addr.u8[15]==0x62)){
}else if((addr.u8[14]==0x34)&&(addr.u8[15]==0x12)){
}else if((addr.u8[14]==0x34)&&(addr.u8[15]==0x0a)){
}else if((addr.u8[14]==0x34)&&(addr.u8[15]==0x1e)){
_init_timer();
_init_pwm();
xtimer_sleep(2);
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 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;
}