/* * 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 * Example for the CoAP REST Engine * \author * Matthias Kovatsch */ #include #include #include #include "contiki.h" #include "contiki-net.h" /* Define which resources to include to meet memory constraints. */ #define REST_RES_HELLO 1 #define REST_RES_MIRROR 0 /* causes largest code size */ #define REST_RES_CHUNKS 1 #define REST_RES_SEPARATE 1 #define REST_RES_PUSHING 1 #define REST_RES_EVENT 1 #define REST_RES_LEDS 1 #define REST_RES_TOGGLE 1 #define REST_RES_LIGHT 0 #define REST_RES_BATTERY 1 #if !UIP_CONF_IPV6_RPL && !defined (CONTIKI_TARGET_MINIMAL_NET) #warning "Compiling with static routing!" #include "static-routing.h" #endif #include "erbium.h" #if defined (PLATFORM_HAS_BUTTON) #include "dev/button-sensor.h" #endif #if defined (PLATFORM_HAS_LEDS) #include "dev/leds.h" #endif #if defined (PLATFORM_HAS_LIGHT) #include "dev/light-sensor.h" #endif #if defined (PLATFORM_HAS_BATTERY) #include "dev/battery-sensor.h" #endif #if defined (PLATFORM_HAS_SHT11) #include "dev/sht11-sensor.h" #endif /* For CoAP-specific example: not required for normal RESTful Web service. */ #if WITH_COAP == 3 #include "er-coap-03.h" #elif WITH_COAP == 7 #include "er-coap-07.h" #else #warning "REST example without CoAP" #endif /* CoAP-specific example */ #define DEBUG 0 #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 #if REST_RES_HELLO /* * Resources are defined by the RESOURCE macro. * Signature: resource name, the RESTful methods it handles, and its URI path (omitting the leading slash). */ RESOURCE(helloworld, METHOD_GET, "hello", "title=\"Hello world: ?len=0..\";rt=\"Text\""); /* * 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 helloworld_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { const char *len = NULL; /* Some data that has the length up to REST_MAX_CHUNK_SIZE. For more, see the chunk resource. */ char const * const message = "Hello World! ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxy"; int length = 12; /* |<-------->| */ /* The query string can be retrieved by rest_get_query() or parsed for its key-value pairs. */ if (REST.get_query_variable(request, "len", &len)) { length = atoi(len); if (length<0) length = 0; if (length>REST_MAX_CHUNK_SIZE) length = REST_MAX_CHUNK_SIZE; memcpy(buffer, message, length); } else { memcpy(buffer, message, length); } REST.set_header_content_type(response, REST.type.TEXT_PLAIN); /* text/plain is the default, hence this option could be omitted. */ REST.set_header_etag(response, (uint8_t *) &length, 1); REST.set_response_payload(response, buffer, length); } #endif #if REST_RES_MIRROR /* This resource mirrors the incoming request. It shows how to access the options and how to set them for the response. */ RESOURCE(mirror, METHOD_GET | METHOD_POST | METHOD_PUT | METHOD_DELETE, "debug/mirror", "title=\"Returns your decoded message\";rt=\"Debug\""); void mirror_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { /* The ETag and Token is copied to the header. */ uint8_t opaque[] = {0x0A, 0xBC, 0xDE}; /* Strings are not copied, so use static string buffers or strings in .text memory (char *str = "string in .text";). */ static char location[] = {'/','f','/','a','?','k','&','e', 0}; /* Getter for the header option Content-Type. If the option is not set, text/plain is returned by default. */ unsigned int content_type = REST.get_header_content_type(request); /* The other getters copy the value (or string/array pointer) to the given pointers and return 1 for success or the length of strings/arrays. */ uint32_t max_age = 0; const char *str = NULL; uint32_t observe = 0; const uint8_t *bytes = NULL; uint32_t block_num = 0; uint8_t block_more = 0; uint16_t block_size = 0; const char *query = ""; int len = 0; /* Mirror the received header options in the response payload. Unsupported getters (e.g., rest_get_header_observe() with HTTP) will return 0. */ int strpos = 0; /* snprintf() counts the terminating '\0' to the size parameter. * The additional byte is taken care of by allocating REST_MAX_CHUNK_SIZE+1 bytes in the REST framework. * Add +1 to fill the complete buffer. */ strpos += snprintf((char *)buffer, REST_MAX_CHUNK_SIZE+1, "CT %u\n", content_type); /* Some getters such as for ETag or Location are omitted, as these options should not appear in a request. * Max-Age might appear in HTTP requests or used for special purposes in CoAP. */ if (strpos<=REST_MAX_CHUNK_SIZE && REST.get_header_max_age(request, &max_age)) { strpos += snprintf((char *)buffer+strpos, REST_MAX_CHUNK_SIZE-strpos+1, "MA %lu\n", max_age); } if (strpos<=REST_MAX_CHUNK_SIZE && (len = REST.get_header_host(request, &str))) { strpos += snprintf((char *)buffer+strpos, REST_MAX_CHUNK_SIZE-strpos+1, "UH %.*s\n", len, str); } /* CoAP-specific example: actions not required for normal RESTful Web service. */ #if WITH_COAP > 1 if (strpos<=REST_MAX_CHUNK_SIZE && coap_get_header_observe(request, &observe)) { strpos += snprintf((char *)buffer+strpos, REST_MAX_CHUNK_SIZE-strpos+1, "Ob %lu\n", observe); } if (strpos<=REST_MAX_CHUNK_SIZE && (len = coap_get_header_token(request, &bytes))) { strpos += snprintf((char *)buffer+strpos, REST_MAX_CHUNK_SIZE-strpos+1, "To 0x"); int index = 0; for (index = 0; index 03 */ #endif /* CoAP-specific example */ if (strpos<=REST_MAX_CHUNK_SIZE && (len = REST.get_query(request, &query))) { strpos += snprintf((char *)buffer+strpos, REST_MAX_CHUNK_SIZE-strpos+1, "Qu %.*s\n", len, query); } if (strpos<=REST_MAX_CHUNK_SIZE && (len = REST.get_request_payload(request, &bytes))) { strpos += snprintf((char *)buffer+strpos, REST_MAX_CHUNK_SIZE-strpos+1, "%.*s", len, bytes); } if (strpos >= REST_MAX_CHUNK_SIZE) { buffer[REST_MAX_CHUNK_SIZE-1] = 0xBB; /* 'ยป' to indicate truncation */ } REST.set_response_payload(response, buffer, strpos); PRINTF("/mirror options received: %s\n", buffer); /* Set dummy header options for response. Like getters, some setters are not implemented for HTTP and have no effect. */ REST.set_header_content_type(response, REST.type.TEXT_PLAIN); REST.set_header_max_age(response, 10); /* For HTTP, browsers will not re-request the page for 10 seconds. CoAP action depends on the client. */ REST.set_header_etag(response, opaque, 2); REST.set_header_location(response, location); /* Initial slash is omitted by framework */ /* CoAP-specific example: actions not required for normal RESTful Web service. */ #if WITH_COAP > 1 coap_set_header_uri_host(response, "tiki"); coap_set_header_observe(response, 10); #if WITH_COAP == 3 coap_set_header_block(response, 42, 0, 64); /* The block option might be overwritten by the framework when blockwise transfer is requested. */ #else coap_set_header_proxy_uri(response, "ftp://x"); coap_set_header_block2(response, 42, 0, 64); /* The block option might be overwritten by the framework when blockwise transfer is requested. */ coap_set_header_block1(response, 23, 0, 16); coap_set_header_accept(response, TEXT_PLAIN); coap_set_header_if_none_match(response); #endif /* CoAP > 03 */ #endif /* CoAP-specific example */ } #endif /* REST_RES_MIRROR */ #if REST_RES_CHUNKS /* * For data larger than REST_MAX_CHUNK_SIZE (e.g., stored in flash) resources must be aware of the buffer limitation * and split their responses by themselves. To transfer the complete resource through a TCP stream or CoAP's blockwise transfer, * the byte offset where to continue is provided to the handler as int32_t pointer. * These chunk-wise resources must set the offset value to its new position or -1 of the end is reached. * (The offset for CoAP's blockwise transfer can go up to 2'147'481'600 = ~2047 M for block size 2048 (reduced to 1024 in observe-03.) */ RESOURCE(chunks, METHOD_GET, "debug/chunks", "title=\"Blockwise demo\";rt=\"Data\""); #define CHUNKS_TOTAL 2050 void chunks_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { int32_t strpos = 0; /* Check the offset for boundaries of the resource data. */ if (*offset>=CHUNKS_TOTAL) { REST.set_response_status(response, REST.status.BAD_OPTION); /* A block error message should not exceed the minimum block size (16). */ const char *error_msg = "BlockOutOfScope"; REST.set_response_payload(response, error_msg, strlen(error_msg)); return; } /* Generate data until reaching CHUNKS_TOTAL. */ while (strpos preferred_size) { strpos = preferred_size; } /* Truncate if above CHUNKS_TOTAL bytes. */ if (*offset+(int32_t)strpos > CHUNKS_TOTAL) { strpos = CHUNKS_TOTAL - *offset; } REST.set_response_payload(response, buffer, strpos); /* IMPORTANT for chunk-wise resources: Signal chunk awareness to REST engine. */ *offset += strpos; /* Signal end of resource representation. */ if (*offset>=CHUNKS_TOTAL) { *offset = -1; } } #endif #if REST_RES_SEPARATE && WITH_COAP > 3 /* Required to manually (=not by the engine) handle the response transaction. */ #include "er-coap-07-separate.h" #include "er-coap-07-transactions.h" /* * CoAP-specific example for separate responses. * Note the call "rest_set_pre_handler(&resource_separate, coap_separate_handler);" in the main process. * The pre-handler takes care of the empty ACK and updates the MID and message type for CON requests. * The resource handler must store all information that required to finalize the response later. */ RESOURCE(separate, METHOD_GET, "debug/separate", "title=\"Separate demo\""); /* A structure to store the required information */ typedef struct application_separate_store { /* Provided by Erbium to store generic request information such as remote address and token. */ coap_separate_t request_metadata; /* Add fields for addition information to be stored for finalizing, e.g.: */ char buffer[16]; } application_separate_store_t; static uint8_t separate_active = 0; static application_separate_store_t separate_store[1]; void separate_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { /* * Example allows only one open separate response. * For multiple, the application must manage the list of stores. */ if (separate_active) { REST.set_response_status(response, REST.status.SERVICE_UNAVAILABLE); const char *msg = "AlreadyInUse"; REST.set_response_payload(response, msg, strlen(msg)); } else { separate_active = 1; /* Take over and skip response by engine. */ coap_separate_response(request, &separate_store->request_metadata); /* * At the moment, only the minimal information is stored in the store (client address, port, token, MID, type, and Block2). * Extend the store, if the application requires additional information from this handler. * buffer is an example field for custom information. */ snprintf(separate_store->buffer, sizeof(separate_store->buffer), "StoredInfo"); } } void separate_finalize_handler() { if (separate_active) { coap_transaction_t *transaction = NULL; if ( (transaction = coap_new_transaction(separate_store->request_metadata.mid, &separate_store->request_metadata.addr, separate_store->request_metadata.port)) ) { coap_packet_t response[1]; /* This way the packet can be treated as pointer as usual. */ coap_init_message(response, separate_store->request_metadata.type, CONTENT_2_05, separate_store->request_metadata.mid); coap_set_payload(response, separate_store->buffer, strlen(separate_store->buffer)); /* Warning: No check for serialization error. */ transaction->packet_len = coap_serialize_message(response, transaction->packet); coap_send_transaction(transaction); /* The engine will clear the transaction (right after send for NON, after acked for CON). */ separate_active = 0; } else { /* * Set timer for retry, send error message, ... * The example simply waits for another button press. */ } } /* if (separate_active) */ } #endif #if REST_RES_PUSHING /* * Example for a periodic resource. * It takes an additional period parameter, which defines the interval to call [name]_periodic_handler(). * A default post_handler takes care of subscriptions by managing a list of subscribers to notify. */ PERIODIC_RESOURCE(pushing, METHOD_GET, "debug/push", "title=\"Periodic demo\";rt=\"Observable\"", 5*CLOCK_SECOND); void pushing_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { REST.set_header_content_type(response, REST.type.TEXT_PLAIN); /* Usually, a CoAP server would response with the resource representation matching the periodic_handler. */ const char *msg = "It's periodic!"; REST.set_response_payload(response, msg, strlen(msg)); /* A post_handler that handles subscriptions will be called for periodic resources by the REST framework. */ } /* * Additionally, a handler function named [resource name]_handler must be implemented for each PERIODIC_RESOURCE. * It will be called by the REST manager process with the defined period. */ int pushing_periodic_handler(resource_t *r) { static uint32_t periodic_i = 0; static char content[16]; PRINTF("TICK /%s\n", r->url); periodic_i = periodic_i + 1; /* Notify the registered observers with the given message type, observe option, and payload. */ REST.notify_subscribers(r->url, 1, periodic_i, (uint8_t *)content, snprintf(content, sizeof(content), "TICK %lu", periodic_i)); /* |-> implementation-specific, e.g. CoAP: 1=CON and 0=NON notification */ return 1; } #endif #if defined (PLATFORM_HAS_BUTTON) && REST_RES_EVENT /* * Example for an event resource. * Additionally takes a period parameter that defines the interval to call [name]_periodic_handler(). * A default post_handler takes care of subscriptions and manages a list of subscribers to notify. */ EVENT_RESOURCE(event, METHOD_GET, "sensors/button", "title=\"Event demo\";rt=\"Observable\""); void event_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { REST.set_header_content_type(response, REST.type.TEXT_PLAIN); /* Usually, a CoAP server would response with the current resource representation. */ const char *msg = "It's eventful!"; REST.set_response_payload(response, (uint8_t *)msg, strlen(msg)); /* A post_handler that handles subscriptions/observing will be called for periodic resources by the framework. */ } /* Additionally, a handler function named [resource name]_event_handler must be implemented for each PERIODIC_RESOURCE defined. * It will be called by the REST manager process with the defined period. */ int event_event_handler(resource_t *r) { static uint32_t event_i = 0; static char content[10]; PRINTF("EVENT /%s\n", r->url); ++event_i; /* Notify registered observers with the given message type, observe option, and payload. * The token will be set automatically. */ // FIXME provide a rest_notify_subscribers call; how to manage specific options such as COAP_TYPE? REST.notify_subscribers(r->url, 0, event_i, content, snprintf(content, sizeof(content), "EVENT %lu", event_i)); return 1; } #endif /* PLATFORM_HAS_BUTTON */ #if defined (PLATFORM_HAS_LEDS) #if REST_RES_LEDS /*A simple actuator example, depending on the color query parameter and post variable mode, corresponding led is activated or deactivated*/ RESOURCE(leds, METHOD_POST | METHOD_PUT , "actuators/leds", "title=\"LEDs: ?color=r|g|b, POST/PUT mode=on|off\";rt=\"Control\""); void leds_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { size_t len = 0; const char *color = NULL; const char *mode = NULL; uint8_t led = 0; int success = 1; if ((len=REST.get_query_variable(request, "color", &color))) { PRINTF("color %.*s\n", len, color); if (strncmp(color, "r", len)==0) { led = LEDS_RED; } else if(strncmp(color,"g", len)==0) { led = LEDS_GREEN; } else if (strncmp(color,"b", len)==0) { led = LEDS_BLUE; } else { success = 0; } } else { success = 0; } 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); } } #endif #if REST_RES_TOGGLE /* A simple actuator example. Toggles the red led */ RESOURCE(toggle, METHOD_GET | METHOD_PUT | METHOD_POST, "actuators/toggle", "title=\"Red LED\";rt=\"Control\""); void toggle_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { leds_toggle(LEDS_RED); } #endif #endif /* PLATFORM_HAS_LEDS */ #if defined (PLATFORM_HAS_LIGHT) && REST_RES_LIGHT /* A simple getter example. Returns the reading from light sensor with a simple etag */ RESOURCE(light, METHOD_GET, "sensors/light", "title=\"Photosynthetic and solar light (supports JSON)\";rt=\"LightSensor\""); void light_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { uint16_t light_photosynthetic = light_sensor.value(LIGHT_SENSOR_PHOTOSYNTHETIC); uint16_t light_solar = light_sensor.value(LIGHT_SENSOR_TOTAL_SOLAR); const uint16_t *accept = NULL; int num = REST.get_header_accept(request, &accept); if ((num==0) || (num && accept[0]==REST.type.TEXT_PLAIN)) { REST.set_header_content_type(response, REST.type.TEXT_PLAIN); snprintf(buffer, REST_MAX_CHUNK_SIZE, "%u;%u", light_photosynthetic, light_solar); REST.set_response_payload(response, (uint8_t *)buffer, strlen(buffer)); } else if (num && (accept[0]==REST.type.APPLICATION_XML)) { REST.set_header_content_type(response, REST.type.APPLICATION_XML); snprintf(buffer, REST_MAX_CHUNK_SIZE, "", light_photosynthetic, light_solar); REST.set_response_payload(response, buffer, strlen(buffer)); } else if (num && (accept[0]==REST.type.APPLICATION_JSON)) { REST.set_header_content_type(response, REST.type.APPLICATION_JSON); snprintf(buffer, REST_MAX_CHUNK_SIZE, "{'light':{'photosynthetic':%u,'solar':%u}}", light_photosynthetic, light_solar); REST.set_response_payload(response, buffer, strlen(buffer)); } else { REST.set_response_status(response, REST.status.UNSUPPORTED_MADIA_TYPE); const char *msg = "Supporting content-types text/plain, application/xml, and application/json"; REST.set_response_payload(response, msg, strlen(msg)); } } #endif /* PLATFORM_HAS_LIGHT */ #if defined (PLATFORM_HAS_BATTERY) && REST_RES_BATTERY /* A simple getter example. Returns the reading from light sensor with a simple etag */ RESOURCE(battery, METHOD_GET, "sensors/battery", "title=\"Battery status\";rt=\"Battery\""); void battery_handler(void* request, void* response, uint8_t *buffer, uint16_t preferred_size, int32_t *offset) { int battery = battery_sensor.value(0); const uint16_t *accept = NULL; int num = REST.get_header_accept(request, &accept); if ((num==0) || (num && accept[0]==REST.type.TEXT_PLAIN)) { REST.set_header_content_type(response, REST.type.TEXT_PLAIN); snprintf(buffer, REST_MAX_CHUNK_SIZE, "%d", battery); REST.set_response_payload(response, (uint8_t *)buffer, strlen(buffer)); } else if (num && (accept[0]==REST.type.APPLICATION_JSON)) { REST.set_header_content_type(response, REST.type.APPLICATION_JSON); snprintf(buffer, REST_MAX_CHUNK_SIZE, "{'battery':%d}", battery); REST.set_response_payload(response, buffer, strlen(buffer)); } else { REST.set_response_status(response, REST.status.UNSUPPORTED_MADIA_TYPE); const char *msg = "Supporting content-types text/plain and application/json"; REST.set_response_payload(response, msg, strlen(msg)); } } #endif /* PLATFORM_HAS_BATTERY */ PROCESS(rest_server_example, "Rest Server Example"); AUTOSTART_PROCESSES(&rest_server_example); PROCESS_THREAD(rest_server_example, ev, data) { PROCESS_BEGIN(); PRINTF("Rest Example\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) set_global_address(); configure_routing(); #endif /* Initialize the REST engine. */ rest_init_engine(); /* Activate the application-specific resources. */ #if REST_RES_HELLO rest_activate_resource(&resource_helloworld); #endif #if REST_RES_MIRROR rest_activate_resource(&resource_mirror); #endif #if REST_RES_CHUNKS rest_activate_resource(&resource_chunks); #endif #if REST_RES_PUSHING rest_activate_periodic_resource(&periodic_resource_pushing); #endif #if REST_RES_SEPARATE && WITH_COAP > 3 rest_set_pre_handler(&resource_separate, coap_separate_handler); rest_activate_resource(&resource_separate); #endif #if defined (PLATFORM_HAS_BUTTON) && REST_RES_EVENT SENSORS_ACTIVATE(button_sensor); rest_activate_event_resource(&resource_event); #endif #if defined (PLATFORM_HAS_LEDS) #if REST_RES_LEDS rest_activate_resource(&resource_leds); #endif #if REST_RES_TOGGLE rest_activate_resource(&resource_toggle); #endif #endif /* PLATFORM_HAS_LEDS */ #if defined (PLATFORM_HAS_LIGHT) && REST_RES_LIGHT SENSORS_ACTIVATE(light_sensor); rest_activate_resource(&resource_light); #endif #if defined (PLATFORM_HAS_BATTERY) && REST_RES_BATTERY SENSORS_ACTIVATE(battery_sensor); rest_activate_resource(&resource_battery); #endif /* Define application-specific events here. */ while(1) { PROCESS_WAIT_EVENT(); #if defined (PLATFORM_HAS_BUTTON) if (ev == sensors_event && data == &button_sensor) { PRINTF("BUTTON\n"); #if REST_RES_EVENT /* Call the event_handler for this application-specific event. */ event_event_handler(&resource_event); #endif #if REST_RES_SEPARATE && WITH_COAP>3 /* Also call the separate response example handler. */ separate_finalize_handler(); #endif } #endif /* PLATFORM_HAS_BUTTON */ } /* while (1) */ PROCESS_END(); }