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osd-contiki/examples/osd/pingtheplug/er-example-server.c
Ralf Schlatterbeck 04bbba6c12 Multi-platform support, osd-merkur-{128,256} 
Rename guhRF platform to osd-merkur-256, previous osd-merkur platform is
now osd-merkur-128. Also check that everything is consistent.
Add both platforms to the regression tests.
Move redundant files in platform dev directory of both platforms to
cpu/avr/dev. Note that this probably needs some rework. Already
discovered some inconsistency in io definitions of both devices in the
avr/io.h includes. Added a workaround in the obvious cases.
The platform makefiles now set correct parameters for bootloader and for
reading mac-address from flash memory.
Factor the flash programming into cpu/avr and platform/osd-merkur* and
rework *all* osd example makefiles to use the new settings. Also update
all the flash.sh and run.sh to use the new settings.
The suli ledstrip modules (and osd example) have also been removed.
2016-04-22 17:59:40 +02:00

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/*
* Copyright (c) 2011, Matthias Kovatsch and other contributors.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the Institute nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE INSTITUTE AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE INSTITUTE OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* This file is part of the Contiki operating system.
*/
/**
* \file
* Erbium (Er) PIR REST Engine example (with CoAP-specific code)
* \author
* Matthias Kovatsch <kovatsch@inf.ethz.ch>
* Harald Pichler <harald@the-develop.net>
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "contiki.h"
#include "contiki-net.h"
#include <avr/eeprom.h>
#include "rest-engine.h"
#define PLATFORM_HAS_LED 1
//#define PLATFORM_HAS_BUTTON 1
#define PLATFORM_HAS_OPTRIAC 1
#define PLATFORM_HAS_TEMPERATURE 1
#define PLATFORM_HAS_BATTERY 1
/* Define which resources to include to meet memory constraints. */
#define REST_RES_MODEL 1
#define REST_RES_NAME 1
#define REST_RES_SW 1
#define REST_RES_RESET 1
#define REST_RES_TIMER 1
#define REST_RES_OPTRIAC 1
#define REST_RES_TEMPERATURE 1
#define REST_RES_LED 1
#define REST_RES_BATTERY 1
#include "pcintkey.h"
#include "statusled.h"
#if defined (PLATFORM_HAS_BUTTON)
#include "dev/button-sensor.h"
#endif
#if defined (PLATFORM_HAS_LED)
#include "dev/leds.h"
#endif
#if defined (PLATFORM_HAS_OPTRIAC)
#include "dev/optriac-sensor.h"
#endif
#if defined (PLATFORM_HAS_TEMPERATURE)
#include "dev/temperature-sensor.h"
#endif
#if defined (PLATFORM_HAS_BATTERY)
#include "dev/battery-sensor.h"
#endif
#define DEBUG 1
#if DEBUG
#define PRINTF(...) printf(__VA_ARGS__)
#define PRINT6ADDR(addr) PRINTF("[%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x]", ((uint8_t *)addr)[0], ((uint8_t *)addr)[1], ((uint8_t *)addr)[2], ((uint8_t *)addr)[3], ((uint8_t *)addr)[4], ((uint8_t *)addr)[5], ((uint8_t *)addr)[6], ((uint8_t *)addr)[7], ((uint8_t *)addr)[8], ((uint8_t *)addr)[9], ((uint8_t *)addr)[10], ((uint8_t *)addr)[11], ((uint8_t *)addr)[12], ((uint8_t *)addr)[13], ((uint8_t *)addr)[14], ((uint8_t *)addr)[15])
#define PRINTLLADDR(lladdr) PRINTF("[%02x:%02x:%02x:%02x:%02x:%02x]",(lladdr)->addr[0], (lladdr)->addr[1], (lladdr)->addr[2], (lladdr)->addr[3],(lladdr)->addr[4], (lladdr)->addr[5])
#else
#define PRINTF(...)
#define PRINT6ADDR(addr)
#define PRINTLLADDR(addr)
#endif
/******************************************************************************/
uint8_t g_triac_a = 0;
uint8_t g_triac_b = 0;
/******************************************************************************/
#if REST_RES_MODEL
/*
* Resources are defined by the RESOURCE macro.
* Signature: resource name, the RESTful methods it handles, and its URI path (omitting the leading slash).
*/
/*
* A handler function named [resource name]_handler must be implemented for each RESOURCE.
* A buffer for the response payload is provided through the buffer pointer. Simple resources can ignore
* preferred_size and offset, but must respect the REST_MAX_CHUNK_SIZE limit for the buffer.
* If a smaller block size is requested for CoAP, the REST framework automatically splits the data.
*/
void
model_get_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
char message[100];
int index = 0;
int length = 0; /* |<-------->| */
/* Some data that has the length up to REST_MAX_CHUNK_SIZE. For more, see the chunk resource. */
// jSON Format
index += sprintf(message + index,"{\n \"model\" : \"PingThePlug\"\n");
index += sprintf(message + index,"}\n");
length = strlen(message);
memcpy(buffer, message,length );
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
REST.set_response_payload(response, buffer, length);
}
RESOURCE(res_model, "title=\"model\";rt=\"simple.dev.md\"", model_get_handler, NULL, NULL, NULL);
#endif
/******************************************************************************/
#if REST_RES_SW
/*
* Resources are defined by the RESOURCE macro.
* Signature: resource name, the RESTful methods it handles, and its URI path (omitting the leading slash).
*/
/*
* A handler function named [resource name]_handler must be implemented for each RESOURCE.
* A buffer for the response payload is provided through the buffer pointer. Simple resources can ignore
* preferred_size and offset, but must respect the REST_MAX_CHUNK_SIZE limit for the buffer.
* If a smaller block size is requested for CoAP, the REST framework automatically splits the data.
*/
void
sw_get_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
char message[100];
int index = 0;
int length = 0; /* |<-------->| */
/* Some data that has the length up to REST_MAX_CHUNK_SIZE. For more, see the chunk resource. */
// jSON Format
index += sprintf(message + index,"{\n \"sw\" : \"V1.0\"\n");
index += sprintf(message + index,"}\n");
length = strlen(message);
memcpy(buffer, message,length );
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
REST.set_response_payload(response, buffer, length);
}
RESOURCE(res_sw, "title=\"Software Version\";rt=\"simple.dev.sv\"", sw_get_handler, NULL, NULL, NULL);
#endif
/******************************************************************************/
#if REST_RES_NAME
/*
* Resources are defined by the RESOURCE macro.
* Signature: resource name, the RESTful methods it handles, and its URI path (omitting the leading slash).
*/
/* eeprom space */
#define P_NAME "Testboard"
#define P_NAME_MAX 17
uint8_t eemem_p_name[P_NAME_MAX] EEMEM = P_NAME;
/*
* A handler function named [resource name]_handler must be implemented for each RESOURCE.
* A buffer for the response payload is provided through the buffer pointer. Simple resources can ignore
* preferred_size and offset, but must respect the REST_MAX_CHUNK_SIZE limit for the buffer.
* If a smaller block size is requested for CoAP, the REST framework automatically splits the data.
*/
void
name_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
uint8_t eebuffer[32];
char message[100];
int index = 0;
int length = 0; /* |<-------->| */
const char *name = NULL;
int success = 1;
switch(REST.get_method_type(request)){
case METHOD_GET:
cli();
eeprom_read_block (eebuffer, &eemem_p_name, sizeof(eemem_p_name));
sei();
/* Some data that has the length up to REST_MAX_CHUNK_SIZE. For more, see the chunk resource. */
// jSON Format
index += sprintf(message + index,"{\n \"name\" : \"%s\"\n",eebuffer);
index += sprintf(message + index,"}\n");
length = strlen(message);
memcpy(buffer, message,length );
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
REST.set_response_payload(response, buffer, length);
break;
case METHOD_POST:
if (success && (length=REST.get_post_variable(request, "name", &name))) {
PRINTF("name %s\n", name);
if (length < P_NAME_MAX) {
memcpy(&eebuffer, name,length);
eebuffer[length]=0;
cli();
eeprom_write_block(&eebuffer, &eemem_p_name, sizeof(eemem_p_name));
sei();
} else {
success = 0;
}
} else {
success = 0;
}
break;
default:
success = 0;
}
if (!success) {
REST.set_response_status(response, REST.status.BAD_REQUEST);
}
}
RESOURCE(res_name, "title=\"name\";rt=\"simple.dev.n\"", name_handler, NULL, name_handler, NULL );
#endif
/******************************************************************************/
#if REST_RES_TIMER
/*A simple actuator example*/
/* eeprom space */
#define P_TIMER "60"
#define P_TIMER_MAX 10
uint8_t eemem_p_timer[P_TIMER_MAX] EEMEM = P_TIMER;
int gtimer_read(){
uint8_t eebuffer[32];
cli();
eeprom_read_block (eebuffer, &eemem_p_timer, sizeof(eemem_p_timer));
sei();
return atoi((const char *)eebuffer);
}
void
timer_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
uint8_t eebuffer[32];
const char *timer = NULL;
char message[100];
int length = 0; /* |<-------->| */
int index = 0;
int success = 1;
switch(REST.get_method_type(request)){
case METHOD_GET:
cli();
eeprom_read_block (eebuffer, &eemem_p_timer, sizeof(eemem_p_timer));
sei();
/* Some data that has the length up to REST_MAX_CHUNK_SIZE. For more, see the chunk resource. */
// jSON Format
index += sprintf(message + index,"{\n \"timer\" : \"%s\"\n",eebuffer);
index += sprintf(message + index,"}\n");
length = strlen(message);
memcpy(buffer, message,length );
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
REST.set_response_payload(response, buffer, length);
break;
case METHOD_POST:
if (success && (length=REST.get_post_variable(request, "timer", &timer))) {
PRINTF("name %s\n", timer);
if (length < P_TIMER_MAX) {
memcpy(&eebuffer, timer,length);
eebuffer[length]=0;
cli();
eeprom_write_block(&eebuffer, &eemem_p_timer, sizeof(eemem_p_timer));
sei();
} else {
success = 0;
}
} else {
success = 0;
}
break;
default:
success = 0;
}
if (!success) {
REST.set_response_status(response, REST.status.BAD_REQUEST);
}
}
RESOURCE(res_timer, "title=\"timer\";rt=\"timer\"", timer_handler, NULL, timer_handler, NULL );
#endif
/******************************************************************************/
#if REST_RES_RESET
/*A simple actuator example*/
/* eeprom space */
#define P_RESET "0"
#define P_RESET_MAX 10
uint8_t eemem_p_reset[P_RESET_MAX] EEMEM = P_RESET;
void
reset_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
uint8_t eebuffer[32];
const char *mode = NULL;
char message[100];
int length = 0; /* |<-------->| */
int index = 0;
int reset = 0;
size_t len = 0;
int success = 1;
switch(REST.get_method_type(request)){
case METHOD_GET:
cli();
eeprom_read_block (eebuffer, &eemem_p_reset, sizeof(eemem_p_reset));
sei();
/* Some data that has the length up to REST_MAX_CHUNK_SIZE. For more, see the chunk resource. */
// jSON Format
index += sprintf(message + index,"{\n \"reset\" : \"%s\"\n",eebuffer);
index += sprintf(message + index,"}\n");
length = strlen(message);
memcpy(buffer, message,length );
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
REST.set_response_payload(response, buffer, length);
break;
case METHOD_POST:
if (success && (len=REST.get_post_variable(request, "mode", &mode))) {
PRINTF("mode %s\n", mode);
if (strncmp(mode, "on", len)==0) {
length=strlen(P_NAME);
memcpy(&eebuffer, P_NAME,length);
eebuffer[length]=0;
cli();
eeprom_write_block(&eebuffer, &eemem_p_name, sizeof(eemem_p_name));
sei();
length=strlen(P_TIMER);
memcpy(&eebuffer, P_TIMER,length);
eebuffer[length]=0;
cli();
eeprom_write_block(&eebuffer, &eemem_p_timer, sizeof(eemem_p_timer));
eeprom_read_block (eebuffer, &eemem_p_reset, sizeof(eemem_p_reset));
sei();
reset= atoi((char*)eebuffer) + 1;
length=sprintf((char*)eebuffer,"%d",reset);
cli();
eeprom_write_block(&eebuffer, &eemem_p_reset, sizeof(eemem_p_reset));
sei();
} else {
success = 0;
}
} else {
success = 0;
}
break;
default:
success = 0;
}
if (!success) {
REST.set_response_status(response, REST.status.BAD_REQUEST);
}
}
RESOURCE(res_reset, "title=\"reset\";rt=\"reset\"", reset_handler, NULL, reset_handler, NULL );
#endif
/******************************************************************************/
// pcintkey_ext
/*A simple actuator example. read the key button status*/
void
extbutton_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
static char bname1[17]="button1";
static char bname2[17]="button2";
static char bname3[17]="button3";
int success = 1;
char temp[100];
int index = 0;
int length = 0; /* |<-------->| */
const char *name = NULL;
size_t len = 0;
switch(REST.get_method_type(request)){
case METHOD_GET:
// jSON Format
index += sprintf(temp + index,"{\n \"%s\" : ",bname1);
if(is_button_ext4())
index += sprintf(temp + index,"\"on\",\n");
else
index += sprintf(temp + index,"\"off\",\n");
index += sprintf(temp + index,"{\n \"%s\" : ",bname2);
if(is_button_ext5())
index += sprintf(temp + index,"\"on\",\n");
else
index += sprintf(temp + index,"\"off\",\n");
index += sprintf(temp + index," \"%s\" : ",bname3);
if(is_button_ext6())
index += sprintf(temp + index,"\"on\"\n");
else
index += sprintf(temp + index,"\"off\"\n");
index += sprintf(temp + index,"}\n");
length = strlen(temp);
memcpy(buffer, temp,length );
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
REST.set_response_payload(response, buffer, length);
break;
case METHOD_POST:
if (success && (len=REST.get_post_variable(request, "name", &name))) {
PRINTF("name %s\n", name);
memcpy(bname1, name,len);
bname1[len]=0;
} else {
success = 0;
}
break;
default:
success = 0;
}
if (!success) {
REST.set_response_status(response, REST.status.BAD_REQUEST);
}
}
RESOURCE(res_extbutton, "title=\"button\";rt=\"button\"", extbutton_handler, NULL, extbutton_handler, NULL );
/******************************************************************************/
#if REST_RES_LED
/*A simple actuator example, depending on the color query parameter and post variable mode, corresponding led is activated or deactivated*/
void
led1_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
size_t len = 0;
const char *mode = NULL;
uint8_t led = 0;
int success = 1;
led = LEDS_RED;
if (success && (len=REST.get_post_variable(request, "mode", &mode))) {
PRINTF("mode %s\n", mode);
if (strncmp(mode, "on", len)==0) {
leds_on(led);
} else if (strncmp(mode, "off", len)==0) {
leds_off(led);
} else {
success = 0;
}
} else {
success = 0;
}
if (!success) {
REST.set_response_status(response, REST.status.BAD_REQUEST);
}
}
RESOURCE(res_led1, "title=\"LED: PUT mode=on|off\";rt=\"simple.act.led\"", led1_handler, NULL, led1_handler, NULL );
/*A simple actuator example, depending on the color query parameter and post variable mode, corresponding led is activated or deactivated*/
void
led2_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
size_t len = 0;
const char *mode = NULL;
int success = 1;
if (success && (len=REST.get_post_variable(request, "mode", &mode))) {
PRINTF("mode %s\n", mode);
if (strncmp(mode, "on", len)==0) {
statusled_on();
} else if (strncmp(mode, "off", len)==0) {
statusled_off();
} else {
success = 0;
}
} else {
success = 0;
}
if (!success) {
REST.set_response_status(response, REST.status.BAD_REQUEST);
}
}
RESOURCE(res_led2, "title=\"LED: PUT mode=on|off\";rt=\"simple.act.led\"", led2_handler, NULL, led2_handler, NULL );
#endif
#if REST_RES_OPTRIAC
/*A simple actuator example*/
void
optriac_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
const char *mode = NULL;
static char namea[17]="Triac-a";
static char nameb[17]="Triac-b";
char temp[100];
int index = 0;
size_t len = 0;
int success = 1;
switch(REST.get_method_type(request)){
case METHOD_GET:
// jSON Format
index += sprintf(temp + index,"{\n \"%s\" : ",namea);
if(optriac_sensor.value(OPTRIAC_SENSOR_1) == 0)
index += sprintf(temp + index,"\"off\",\n");
if(optriac_sensor.value(OPTRIAC_SENSOR_1) == 1)
index += sprintf(temp + index,"\"on\",\n");
index += sprintf(temp + index," \"%s\" : ",nameb);
if(optriac_sensor.value(OPTRIAC_SENSOR_2) == 0)
index += sprintf(temp + index,"\"off\"\n");
if(optriac_sensor.value(OPTRIAC_SENSOR_2) == 1)
index += sprintf(temp + index,"\"on\"\n");
index += sprintf(temp + index,"}\n");
len = strlen(temp);
memcpy(buffer, temp,len );
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
REST.set_response_payload(response, buffer, len);
break;
case METHOD_PUT:
if (success && (len=REST.get_post_variable(request, "mode", &mode))) {
PRINTF("mode %s\n", mode);
if (strncmp(mode, "on", len)==0) {
optriac_sensor.configure(OPTRIAC_SENSOR_1,1);
optriac_sensor.configure(OPTRIAC_SENSOR_2,1);
statusled_on();
} else if (strncmp(mode, "off", len)==0) {
optriac_sensor.configure(OPTRIAC_SENSOR_1,0);
optriac_sensor.configure(OPTRIAC_SENSOR_2,0);
statusled_off();
} else {
success = 0;
}
} else {
success = 0;
}
break;
default:
success = 0;
}
if (!success) {
REST.set_response_status(response, REST.status.BAD_REQUEST);
}
}
RESOURCE(res_optriac, "title=\"TRIAC, PUT mode=on|off\";rt=\"simple.act.triac\"", optriac_handler, NULL, optriac_handler, NULL );
#endif /* PLATFORM_HAS_OPTRIAC */
/******************************************************************************/
#if REST_RES_TEMPERATURE && defined (PLATFORM_HAS_TEMPERATURE)
/* A simple getter example. Returns the reading from light sensor with a simple etag */
void
temperature_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
int temperature = temperature_sensor.value(0);
unsigned int accept = -1;
REST.get_header_accept(request, &accept);
if(accept == -1 || accept == REST.type.TEXT_PLAIN)
{
REST.set_header_content_type(response, REST.type.TEXT_PLAIN);
snprintf((char *)buffer, REST_MAX_CHUNK_SIZE, "%d.%02d", temperature/100, temperature % 100);
REST.set_response_payload(response, (uint8_t *)buffer, strlen((char *)buffer));
}
else if (accept == REST.type.APPLICATION_JSON)
{
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
snprintf((char *)buffer, REST_MAX_CHUNK_SIZE, "{'temperature':%d.%02d}", temperature/100, temperature % 100);
REST.set_response_payload(response, buffer, strlen((char *)buffer));
}
else
{
REST.set_response_status(response, REST.status.NOT_ACCEPTABLE);
const char *msg = "Supporting content-types text/plain and application/json";
REST.set_response_payload(response, msg, strlen(msg));
}
}
RESOURCE(res_temperature, "title=\"Temperature status\";rt=\"temperature-c\"", temperature_handler, NULL, NULL, NULL );
#endif /* PLATFORM_HAS_TEMPERATURE */
/******************************************************************************/
#if REST_RES_BATTERY && defined (PLATFORM_HAS_BATTERY)
/* A simple getter example. Returns the reading from light sensor with a simple etag */
void
battery_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset)
{
int battery = battery_sensor.value(0);
unsigned int accept = -1;
REST.get_header_accept(request, &accept);
if(accept == -1 || accept == REST.type.TEXT_PLAIN)
{
REST.set_header_content_type(response, REST.type.TEXT_PLAIN);
snprintf((char *)buffer, REST_MAX_CHUNK_SIZE, "%d.%02d", battery/1000, battery % 1000);
REST.set_response_payload(response, (uint8_t *)buffer, strlen((char *)buffer));
}
else if (accept == REST.type.APPLICATION_JSON)
{
REST.set_header_content_type(response, REST.type.APPLICATION_JSON);
snprintf((char *)buffer, REST_MAX_CHUNK_SIZE, "{\"battery\":%d.%02d}", battery/1000, battery % 1000);
REST.set_response_payload(response, buffer, strlen((char *)buffer));
}
else
{
REST.set_response_status(response, REST.status.NOT_ACCEPTABLE);
const char *msg = "Supporting content-types text/plain and application/json";
REST.set_response_payload(response, msg, strlen(msg));
}
}
RESOURCE(res_battery, "title=\"Battery status\";rt=\"battery-mV\"", battery_handler, NULL, NULL, NULL );
#endif /* PLATFORM_HAS_BATTERY */
/******************************************************************************/
void
hw_init()
{
leds_off(LEDS_RED);
statusledinit();
key_init();
}
#define MESURE_INTERVAL (CLOCK_SECOND/2)
PROCESS(rest_server_example, "Erbium Example Server");
AUTOSTART_PROCESSES(&rest_server_example, &sensors_process);
PROCESS_THREAD(rest_server_example, ev, data)
{
static struct etimer ds_periodic_timer;
// static int ext4=0;
static int ext5=0;
static int ext6=0;
// ext4 = is_button_ext4();
// ext5 = is_button_ext5();
// ext6 = is_button_ext6();
PROCESS_BEGIN();
PRINTF("Starting Erbium Example Server\n");
#ifdef RF_CHANNEL
PRINTF("RF channel: %u\n", RF_CHANNEL);
#endif
#ifdef IEEE802154_PANID
PRINTF("PAN ID: 0x%04X\n", IEEE802154_PANID);
#endif
PRINTF("uIP buffer: %u\n", UIP_BUFSIZE);
PRINTF("LL header: %u\n", UIP_LLH_LEN);
PRINTF("IP+UDP header: %u\n", UIP_IPUDPH_LEN);
PRINTF("REST max chunk: %u\n", REST_MAX_CHUNK_SIZE);
/* if static routes are used rather than RPL */
#if !UIP_CONF_IPV6_RPL && !defined (CONTIKI_TARGET_MINIMAL_NET) && !defined (CONTIKI_TARGET_NATIVE)
set_global_address();
configure_routing();
#endif
/* Initialize the OSD Hardware. */
hw_init();
/* Initialize the REST engine. */
rest_init_engine();
/* Activate the application-specific resources. */
#if REST_RES_MODEL
rest_activate_resource(&res_model,"p/model");
#endif
#if REST_RES_SW
rest_activate_resource(&res_sw,"p/sw");
#endif
#if REST_RES_NAME
rest_activate_resource(&res_name,"p/name");
#endif
#if REST_RES_RESET
rest_activate_resource(&res_reset,"p/reset");
#endif
#if REST_RES_TIMER
rest_activate_resource(&res_timer,"a/timer");
#endif
rest_activate_resource(&res_extbutton,"s/extbutton");
/* Activate the application-specific resources. */
#if REST_RES_OPTRIAC
SENSORS_ACTIVATE(optriac_sensor);
rest_activate_resource(&res_optriac,"a/optriac");
#endif
#if defined (PLATFORM_HAS_LED)
#if REST_RES_LED
rest_activate_resource(&res_led1,"a/led1");
rest_activate_resource(&res_led2,"a/led2");
#endif
#endif /* PLATFORM_HAS_LED */
#if defined (PLATFORM_HAS_TEMPERATURE) && REST_RES_TEMPERATURE
SENSORS_ACTIVATE(temperature_sensor);
rest_activate_resource(&res_temperature,"s/cputemp");
#endif
#if defined (PLATFORM_HAS_BATTERY) && REST_RES_BATTERY
SENSORS_ACTIVATE(battery_sensor);
rest_activate_resource(&res_battery,"s/battery");
#endif
etimer_set(&ds_periodic_timer, MESURE_INTERVAL);
/* Define application-specific events here. */
while(1) {
PROCESS_WAIT_EVENT();
/* Button Tric Logic */
if(etimer_expired(&ds_periodic_timer)) {
PRINTF("Periodic %d %d\n",ext5,ext6);
}
} /* while (1) */
PROCESS_END();
}
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