OCRepPayload* constructResponse(OCEntityHandlerRequest *ehRequest)
{
OCRepPayload* payload = OCRepPayloadCreate();
if (!payload)
{
OC_LOG(ERROR, ES_RH_TAG, "Failed to allocate Payload");
return NULL;
}
if (ehRequest->resource == g_prov.handle)
{
OCRepPayloadSetUri(payload, OC_RSRVD_ES_URI_PROV);
OCRepPayloadSetPropInt(payload, OC_RSRVD_ES_PS, g_prov.ps);
OCRepPayloadSetPropInt(payload, OC_RSRVD_ES_TNT, g_prov.tnt);
OCRepPayloadSetPropString(payload, OC_RSRVD_ES_TNN, g_prov.tnn);
OCRepPayloadSetPropString(payload, OC_RSRVD_ES_CD, g_prov.cd);
}
else if (ehRequest->requestHandle == g_net.handle)
{
OCRepPayloadSetUri(payload, OC_RSRVD_ES_URI_NET);
OCRepPayloadSetPropInt(payload, "ant", g_net.ant[0]);
}
return payload;
}
TEST_F(CborByteStringTest, ByteStringArraySetGetTest )
{
OCRepPayloadSetUri(payload_in, "/a/quake_sensor");
OCRepPayloadSetPropInt(payload_in, "scale", 4);
size_t dimensions_in[MAX_REP_ARRAY_DEPTH] = { 3, 0, 0};
uint8_t binval1[] = {0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19};
uint8_t binval2[] = {0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28, 0x29};
uint8_t binval3[] = {0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39};
OCByteString quakedata_in[3] = {{binval1, sizeof(binval1)},
{binval2, sizeof(binval2)},
{binval3, sizeof(binval3)}};
EXPECT_EQ(true, OCRepPayloadSetByteStringArray(payload_in, "quakedata",
quakedata_in, dimensions_in));
OCByteString* quakedata_out = NULL;
size_t dimensions_out[MAX_REP_ARRAY_DEPTH] = {0};
ASSERT_EQ(true, OCRepPayloadGetByteStringArray(payload_in, "quakedata",
&quakedata_out, dimensions_out));
for(size_t i = 0; i < dimensions_in[0]; i++)
{
EXPECT_EQ(quakedata_in[i].len, quakedata_out[i].len);
EXPECT_EQ(0, memcmp(quakedata_in[i].bytes, quakedata_out[i].bytes, quakedata_in[i].len));
}
// Cleanup
for(size_t i = 0; i < dimensions_out[0]; i++)
{
OICFree(quakedata_out[i].bytes);
}
OICFree(quakedata_out);
}
NSResult NSSetMessagePayload(NSMessage *msg, OCRepPayload** msgPayload)
{
NS_LOG(DEBUG, "NSSetMessagePayload - IN");
*msgPayload = msg->extraInfo != NULL ? msg->extraInfo : OCRepPayloadCreate();
if (!*msgPayload)
{
NS_LOG(ERROR, "Failed to allocate payload");
return NS_ERROR;
}
OCRepPayloadSetUri(*msgPayload, NS_COLLECTION_MESSAGE_URI);
OCRepPayloadSetPropInt(*msgPayload, NS_ATTRIBUTE_MESSAGE_ID, msg->messageId);
OCRepPayloadSetPropString(*msgPayload, NS_ATTRIBUTE_PROVIDER_ID, msg->providerId);
NSDuplicateSetPropertyInt(msgPayload, NS_ATTRIBUTE_TYPE, msg->type);
NSDuplicateSetPropertyInt(msgPayload, NS_ATTRIBUTE_TTL, msg->ttl);
NSDuplicateSetPropertyString(msgPayload, NS_ATTRIBUTE_DATETIME, msg->dateTime);
NSDuplicateSetPropertyString(msgPayload, NS_ATTRIBUTE_TITLE, msg->title);
NSDuplicateSetPropertyString(msgPayload, NS_ATTRIBUTE_TEXT, msg->contentText);
NSDuplicateSetPropertyString(msgPayload, NS_ATTRIBUTE_SOURCE, msg->sourceName);
NSDuplicateSetPropertyString(msgPayload, NS_ATTRIBUTE_TOPIC_NAME, msg->topic);
if (msg->mediaContents)
{
NSDuplicateSetPropertyString(msgPayload, NS_ATTRIBUTE_ICON_IMAGE,
msg->mediaContents->iconImage);
}
NS_LOG(DEBUG, "NSSetMessagePayload - OUT");
return NS_OK;
}
OCEntityHandlerResult LcdOCEntityHandlerCb(OCEntityHandlerFlag flag, OCEntityHandlerRequest * entityHandlerRequest,
void *callbackParam)
{
OCEntityHandlerResult ehRet = OC_EH_OK;
OCEntityHandlerResponse response = {0};
OCRepPayload* payload = OCRepPayloadCreate();
if(!payload) {
OC_LOG(ERROR, TAG, ("Failed to allocate Payload"));
return OC_EH_ERROR;
}
if(entityHandlerRequest && (flag & OC_REQUEST_FLAG)) {
OC_LOG (INFO, TAG, ("Flag includes OC_REQUEST_FLAG"));
if(OC_REST_GET == entityHandlerRequest->method) {
OCRepPayloadSetUri(payload, "/grove/lcd");
OCRepPayloadSetPropString(payload, "lcd", (const char *)lcd.str);
} else if(OC_REST_PUT == entityHandlerRequest->method) {
OC_LOG(INFO, TAG, ("PUT request"));
OCRepPayload *rep = (OCRepPayload *)entityHandlerRequest->payload;
OCRepPayloadGetPropString(rep, "lcd", &lcd.str);
OC_LOG_V(INFO, TAG, "LCD string: %s", lcd.str);
lcd_put();
OCRepPayloadSetPropString(payload, "lcd", (const char *)lcd.str);
}
if (ehRet == OC_EH_OK) {
// Format the response. Note this requires some info about the request
response.requestHandle = entityHandlerRequest->requestHandle;
response.resourceHandle = entityHandlerRequest->resource;
response.ehResult = ehRet;
response.payload = (OCPayload*) payload;
response.numSendVendorSpecificHeaderOptions = 0;
memset(response.sendVendorSpecificHeaderOptions, 0, sizeof response.sendVendorSpecificHeaderOptions);
memset(response.resourceUri, 0, sizeof response.resourceUri);
// Indicate that response is NOT in a persistent buffer
response.persistentBufferFlag = 0;
// Send the response
if (OCDoResponse(&response) != OC_STACK_OK) {
OC_LOG(ERROR, TAG, "Error sending response");
ehRet = OC_EH_ERROR;
}
}
}
if (entityHandlerRequest && (flag & OC_OBSERVE_FLAG)) {
if (OC_OBSERVE_REGISTER == entityHandlerRequest->obsInfo.action) {
OC_LOG (INFO, TAG, ("Received OC_OBSERVE_REGISTER from client"));
gLightUnderObservation = 1;
} else if (OC_OBSERVE_DEREGISTER == entityHandlerRequest->obsInfo.action) {
OC_LOG (INFO, TAG, ("Received OC_OBSERVE_DEREGISTER from client"));
gLightUnderObservation = 0;
}
}
OCRepPayloadDestroy(payload);
return ehRet;
}
static int handle_post_req_on_single_rsrc(things_resource_s *single_rsrc)
{
RET_VAL_IF_PARAM_IS_NULL(TAG, single_rsrc, 0);
// Retrieve the request representation. This representation will hold all the input properties of post request.
// Payload in this representation will be used to form the request message which will be given to the application.
struct things_representation_s *req_rep = NULL;
bool rep_exist = single_rsrc->things_get_representation(single_rsrc, &req_rep);
if (!rep_exist || NULL == req_rep || NULL == req_rep->payload) {
THINGS_LOG_E(TAG, "Empty payload in POST request.");
return 0; // TODO: When a post request comes with empty payload, how do we handle?
}
// Setup the response representation. This representation will be handed over to the underlying stack.
// The payload which is passed as a parameter will be updated with the common properties.
things_representation_s *resp_rep = things_create_representation_inst(NULL);
RET_VAL_IF_NULL(TAG, resp_rep, "Failed to create response representation.", 0);
if (!OCRepPayloadSetUri(resp_rep->payload, single_rsrc->uri)) {
THINGS_LOG_E(TAG, "Failed to set the resource uri(%s) in response payload.", single_rsrc->uri);
things_release_representation_inst(resp_rep);
return 0;
}
THINGS_LOG_D(TAG, "Resource uri(%s) is set in the response payload.", single_rsrc->uri);
// Get interface type from query parameter
char *if_type = NULL;
if (NULL != single_rsrc->query && strlen(single_rsrc->query) > 0) {
bool found = false;
bool result = get_query_value_internal(single_rsrc->query, OC_RSRVD_INTERFACE, &if_type, &found);
if (found && !result) { // If query is present but API returns false.
THINGS_LOG_E(TAG, "Failed to get the interface type from query parameter(%s).", single_rsrc->query);
things_release_representation_inst(resp_rep);
return 0;
}
}
// Set the common properties in the payload (Only for baseline interface).
// The payload which is passed as a parameter will be updated with the common properties.
if (NULL == if_type || !strncmp(if_type, OC_RSRVD_INTERFACE_DEFAULT, strlen(OC_RSRVD_INTERFACE_DEFAULT))) {
if (!add_common_props(single_rsrc, false, resp_rep->payload)) {
THINGS_LOG_E(TAG, "Failed to add the common properties in response payload.");
things_release_representation_inst(resp_rep);
things_free(if_type);
return 0;
}
THINGS_LOG_D(TAG, "Added common properties in response payload.");
}
// Give the request properties to application and get the response back.
bool res = handle_post_req_helper(single_rsrc->uri, single_rsrc->query, req_rep->payload, resp_rep->payload);
if (res) {
// Set the response representation in the resource.
single_rsrc->things_set_representation(single_rsrc, resp_rep);
} else {
things_release_representation_inst(resp_rep);
}
things_free(if_type);
return res ? 1 : 0;
}
// This is the entity handler for the registered resource.
// This is invoked by OCStack whenever it recevies a request for this resource.
OCEntityHandlerResult SensorOCEntityHandlerCb(OCEntityHandlerFlag flag, OCEntityHandlerRequest * entityHandlerRequest,
void *callbackParam)
{
OCEntityHandlerResult ehRet = OC_EH_OK;
OCEntityHandlerResponse response = {0};
OCRepPayload* payload = OCRepPayloadCreate();
if(!payload) {
OC_LOG(ERROR, TAG, ("Failed to allocate Payload"));
return OC_EH_ERROR;
}
if(entityHandlerRequest && (flag & OC_REQUEST_FLAG)) {
OC_LOG (INFO, TAG, ("Flag includes OC_REQUEST_FLAG"));
if(OC_REST_GET == entityHandlerRequest->method) {
//sensor_get();
OCRepPayloadSetUri(payload, "/grove/sensor");
OCRepPayloadSetPropDouble(payload, "temperature", sensor.temp);
OCRepPayloadSetPropInt(payload, "light", sensor.light);
OCRepPayloadSetPropInt(payload, "sound", sensor.sound);
} else if(OC_REST_PUT == entityHandlerRequest->method) {
OC_LOG(ERROR, TAG, ("Un-supported request for Sensor: PUT"));
}
if (ehRet == OC_EH_OK) {
// Format the response. Note this requires some info about the request
response.requestHandle = entityHandlerRequest->requestHandle;
response.resourceHandle = entityHandlerRequest->resource;
response.ehResult = ehRet;
response.payload = (OCPayload*) payload;
response.numSendVendorSpecificHeaderOptions = 0;
memset(response.sendVendorSpecificHeaderOptions, 0, sizeof response.sendVendorSpecificHeaderOptions);
memset(response.resourceUri, 0, sizeof response.resourceUri);
// Indicate that response is NOT in a persistent buffer
response.persistentBufferFlag = 0;
// Send the response
if (OCDoResponse(&response) != OC_STACK_OK) {
OC_LOG(ERROR, TAG, "Error sending response");
ehRet = OC_EH_ERROR;
}
}
}
if (entityHandlerRequest && (flag & OC_OBSERVE_FLAG)) {
if (OC_OBSERVE_REGISTER == entityHandlerRequest->obsInfo.action) {
OC_LOG (INFO, TAG, ("Received OC_OBSERVE_REGISTER from client"));
gLightUnderObservation = 1;
} else if (OC_OBSERVE_DEREGISTER == entityHandlerRequest->obsInfo.action) {
OC_LOG (INFO, TAG, ("Received OC_OBSERVE_DEREGISTER from client"));
gLightUnderObservation = 0;
}
}
OCRepPayloadDestroy(payload);
return ehRet;
}
TEST_F(CborByteStringTest, ByteStringArrayConvertParseTest )
{
OCRepPayloadSetUri(payload_in, "/a/quake_sensor");
OCRepPayloadSetPropInt(payload_in, "scale", 4);
size_t dimensions_in[MAX_REP_ARRAY_DEPTH] = { 3, 0, 0};
uint8_t binval1[] = {0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19};
uint8_t binval2[] = {0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28, 0x29};
uint8_t binval3[] = {0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39};
OCByteString quakedata_in[3] = {{binval1, sizeof(binval1)},
{binval2, sizeof(binval2)},
{binval3, sizeof(binval3)}};
EXPECT_EQ(true, OCRepPayloadSetByteStringArray(payload_in, "quakedata",
quakedata_in, dimensions_in));
// Convert OCPayload to CBOR
uint8_t *payload_cbor = NULL;
size_t payload_cbor_size = 0;
EXPECT_EQ(OC_STACK_OK, OCConvertPayload((OCPayload*) payload_in, &payload_cbor, &payload_cbor_size));
#ifdef CBOR_BIN_STRING_DEBUG
FILE *fp = fopen("binstringarr.cbor", "wb+");
if (fp)
{
fwrite(payload_cbor, 1, payload_cbor_size, fp);
fclose(fp);
}
#endif //CBOR_BIN_STRING_DEBUG
// Parse CBOR back to OCPayload
OCPayload* payload_out = NULL;
EXPECT_EQ(OC_STACK_OK, OCParsePayload(&payload_out, PAYLOAD_TYPE_REPRESENTATION,
payload_cbor, payload_cbor_size));
OCByteString* quakedata_out = NULL;
size_t dimensions_out[MAX_REP_ARRAY_DEPTH] = {0};
ASSERT_EQ(true, OCRepPayloadGetByteStringArray((OCRepPayload*)payload_out, "quakedata",
&quakedata_out, dimensions_out));
for(size_t i = 0; i < dimensions_in[0]; i++)
{
EXPECT_EQ(quakedata_in[i].len, quakedata_out[i].len);
EXPECT_EQ(0, memcmp(quakedata_in[i].bytes, quakedata_out[i].bytes, quakedata_in[i].len));
}
// Cleanup
OICFree(payload_cbor);
for(size_t i = 0; i < dimensions_out[0]; i++)
{
OICFree(quakedata_out[i].bytes);
}
OICFree(quakedata_out);
OCPayloadDestroy((OCPayload*)payload_out);
}
//This function takes the request as an input and returns the response
//in JSON format.
OCRepPayload* constructResponse (OCEntityHandlerRequest *ehRequest)
{
LEDResource *currLEDResource = &LED;
OC_LOG(INFO, TAG, "Entering constructResponse");
if (ehRequest->resource == gLedInstance[0].handle)
{
OC_LOG(INFO, TAG, "handle 0");
currLEDResource = &gLedInstance[0];
gResourceUri = const_cast<char *>("a/led/0");
}
else if (ehRequest->resource == gLedInstance[1].handle)
{
OC_LOG(INFO, TAG, "handle 1");
currLEDResource = &gLedInstance[1];
gResourceUri = const_cast<char *>("a/led/1");
}
if(OC_REST_PUT == ehRequest->method)
{
if(ehRequest->payload && ehRequest->payload->type != PAYLOAD_TYPE_REPRESENTATION)
{
OC_LOG(ERROR, TAG, PCF("Incoming payload not a representation"));
return nullptr;
}
OCRepPayload *putPayload = reinterpret_cast<OCRepPayload*> (ehRequest->payload);
int64_t power;
bool state;
if (OCRepPayloadGetPropBool(putPayload, "state", &state))
{
currLEDResource->state = state;
}
if (OCRepPayloadGetPropInt (putPayload, "power", &power))
{
currLEDResource->power = power;
}
}
OCRepPayload *response = OCRepPayloadCreate();
if (!response)
{
OC_LOG_V(ERROR, TAG, "Memory allocation for response payload failed.");
}
OCRepPayloadSetUri (response, gResourceUri);
OCRepPayloadSetPropBool(response, "state", currLEDResource->state);
OCRepPayloadSetPropInt(response, "power", currLEDResource->power);
return response;
}
OCStackResult BuildResponseRepresentation(const OCResource *resourcePtr,
OCRepPayload** payload)
{
OCRepPayload *tempPayload = OCRepPayloadCreate();
if (!resourcePtr)
{
OCRepPayloadDestroy(tempPayload);
return OC_STACK_INVALID_PARAM;
}
if(!tempPayload)
{
return OC_STACK_NO_MEMORY;
}
OCRepPayloadSetUri(tempPayload, resourcePtr->uri);
OCResourceType *resType = resourcePtr->rsrcType;
while(resType)
{
OCRepPayloadAddResourceType(tempPayload, resType->resourcetypename);
resType = resType->next;
}
OCResourceInterface *resInterface = resourcePtr->rsrcInterface;
while(resInterface)
{
OCRepPayloadAddInterface(tempPayload, resInterface->name);
resInterface = resInterface->next;
}
OCAttribute *resAttrib = resourcePtr->rsrcAttributes;
while(resAttrib)
{
OCRepPayloadSetPropString(tempPayload, resAttrib->attrName,
resAttrib->attrValue);
resAttrib = resAttrib->next;
}
if(!*payload)
{
*payload = tempPayload;
}
else
{
OCRepPayloadAppend(*payload, tempPayload);
}
return OC_STACK_OK;
}
static int handle_get_req_on_single_rsrc(things_resource_s *single_rsrc)
{
RET_VAL_IF_PARAM_IS_NULL(TAG, single_rsrc, 0);
// Setup the response representation. This representation will be handed over to the underlying stack.
things_representation_s *resp_rep = things_create_representation_inst(NULL);
RET_VAL_IF_NULL(TAG, resp_rep, "Failed to create response representation.", 0);
bool result = OCRepPayloadSetUri(resp_rep->payload, single_rsrc->uri);
if (!result) {
THINGS_LOG_E(TAG, "Failed to set the resource uri(%s) in response payload.", single_rsrc->uri);
things_release_representation_inst(resp_rep);
return 0;
}
THINGS_LOG_D(TAG, "Resource uri(%s) is set in the response payload.", single_rsrc->uri);
// Set the common properties in the payload (Only for baseline interface).
char *if_type = NULL;
if (NULL != single_rsrc->query && strlen(single_rsrc->query) > 0) {
bool found = false;
bool result = get_query_value_internal(single_rsrc->query, OC_RSRVD_INTERFACE, &if_type, &found);
if (found && !result) { // If query is present but API returns false.
THINGS_LOG_E(TAG, "Failed to get the interface type from query parameter(%s).", single_rsrc->query);
things_release_representation_inst(resp_rep);
return 0;
}
}
if (NULL == if_type || strlen(if_type) < 1 || !strncmp(if_type, OC_RSRVD_INTERFACE_DEFAULT, strlen(OC_RSRVD_INTERFACE_DEFAULT))) {
if (!add_common_props(single_rsrc, false, resp_rep->payload)) {
THINGS_LOG_E(TAG, "Failed to add the common properties in response payload.");
things_release_representation_inst(resp_rep);
things_free(if_type);
return 0;
}
THINGS_LOG_D(TAG, "Added common properties in response payload.");
}
// Get the resource's properties from the application.
result = handle_get_req_helper(single_rsrc->uri, single_rsrc->query, resp_rep->payload);
if (!result) {
things_release_representation_inst(resp_rep);
things_free(if_type);
return 0;
}
// Set the response representation in the resource.
single_rsrc->things_set_representation(single_rsrc, resp_rep);
things_free(if_type);
return 1;
}
OCRepPayload* getPayload(const char* uri, int64_t brightness)
{
OCRepPayload* payload = OCRepPayloadCreate();
if(!payload)
{
OIC_LOG(ERROR, TAG, PCF("Failed to allocate Payload"));
return nullptr;
}
OCRepPayloadSetUri(payload, uri);
OCRepPayloadSetPropInt(payload, "brightness", brightness);
return payload;
}
OCRepPayload* constructResponse(OCEntityHandlerRequest *ehRequest)
{
OCRepPayload* payload = OCRepPayloadCreate();
if (!payload)
{
OIC_LOG(ERROR, ES_RH_TAG, "Failed to allocate Payload");
return NULL;
}
if (ehRequest->resource == gProvResource.handle)
{
OIC_LOG(INFO, ES_RH_TAG, "constructResponse prov res");
OCRepPayloadSetUri(payload, OC_RSRVD_ES_URI_PROV);
OCRepPayloadSetPropInt(payload, OC_RSRVD_ES_PS, gProvResource.ps);
OCRepPayloadSetPropInt(payload, OC_RSRVD_ES_TNT, gProvResource.tnt);
}
else if (ehRequest->requestHandle == gNetResource.handle)
{
OCRepPayloadSetUri(payload, OC_RSRVD_ES_URI_NET);
OCRepPayloadSetPropInt(payload, "ant", gNetResource.ant[0]);
}
return payload;
}
OCRepPayload* getPayload(const char* uri, int64_t power, bool state)
{
OCRepPayload* payload = OCRepPayloadCreate();
if(!payload)
{
OIC_LOG(ERROR, TAG, "Failed to allocate Payload");
return NULL;
}
OCRepPayloadSetUri(payload, uri);
OCRepPayloadSetPropBool(payload, "state", state);
OCRepPayloadSetPropInt(payload, "power", power);
return payload;
}
TEST_F(CborByteStringTest, ByteStringConvertParseTest)
{
OCRepPayloadSetUri(payload_in, "/a/quake_sensor");
OCRepPayloadSetPropInt(payload_in, "scale", 4);
uint8_t binval[] = {0x1, 0x2, 0x3, 0x4, 0x5, 0x6, 0x7, 0x8, 0x9, 0x0, 0xA, 0xB, 0xC,
0xD, 0xE, 0xF};
OCByteString quakedata_in = { binval, sizeof(binval)};
// Set ByteString in Payload
EXPECT_EQ(true, OCRepPayloadSetPropByteString(payload_in, "quakedata", quakedata_in));
// Convert OCPayload to CBOR
uint8_t *payload_cbor = NULL;
size_t payload_cbor_size = 0;
EXPECT_EQ(OC_STACK_OK, OCConvertPayload((OCPayload*) payload_in, &payload_cbor, &payload_cbor_size));
#ifdef CBOR_BIN_STRING_DEBUG
FILE *fp = fopen("binstring.cbor", "wb+");
if (fp)
{
fwrite(payload_cbor, 1, payload_cbor_size, fp);
fclose(fp);
}
#endif //CBOR_BIN_STRING_DEBUG
// Parse CBOR back to OCPayload
OCPayload* payload_out = NULL;
EXPECT_EQ(OC_STACK_OK, OCParsePayload(&payload_out, PAYLOAD_TYPE_REPRESENTATION,
payload_cbor, payload_cbor_size));
OCByteString quakedata_out = {NULL, 0};
ASSERT_EQ(true, OCRepPayloadGetPropByteString((OCRepPayload*)payload_out, "quakedata", &quakedata_out));
// Compare input and output data
EXPECT_EQ(quakedata_in.len, quakedata_out.len);
EXPECT_EQ(0, memcmp(quakedata_in.bytes, quakedata_out.bytes, quakedata_in.len));
// Cleanup
OICFree(payload_cbor);
OICFree(quakedata_out.bytes);
OCPayloadDestroy((OCPayload*)payload_out);
}
TEST_F(CborByteStringTest, ByteStringSetGetTest)
{
OCRepPayloadSetUri(payload_in, "/a/quake_sensor");
OCRepPayloadSetPropInt(payload_in, "scale", 4);
uint8_t binval[] = {0x1, 0x2, 0x3, 0x4, 0x5, 0x6, 0x7, 0x8, 0x9, 0x0, 0xA, 0xB, 0xC,
0xD, 0xE, 0xF};
OCByteString quakedata_in = { binval, sizeof(binval)};
EXPECT_EQ(true, OCRepPayloadSetPropByteString(payload_in, "quakedata", quakedata_in));
OCByteString quakedata_out = { NULL, 0};
ASSERT_EQ(true, OCRepPayloadGetPropByteString(payload_in, "quakedata", &quakedata_out));
EXPECT_EQ(quakedata_in.len, quakedata_out.len);
EXPECT_EQ(0, memcmp(quakedata_in.bytes, quakedata_out.bytes, quakedata_in.len));
// Cleanup
OICFree(quakedata_out.bytes);
}
OCRepPayload* icd_payload_representation_from_gvariant(GVariant *var)
{
int ret;
GVariant *child;
OCRepPayload *repr, *cur;
char *uri_path, *resource_iface, *resource_type;
GVariantIter *resource_types, *resource_ifaces, *repr_gvar, *children;
repr = OCRepPayloadCreate();
g_variant_get(var, "(&sasasa{sv}av)", &uri_path, &resource_ifaces, &resource_types,
&repr_gvar, &children);
if (IC_STR_EQUAL != strcmp(IC_STR_NULL, uri_path))
OCRepPayloadSetUri(repr, uri_path);
while (g_variant_iter_loop(resource_ifaces, "s", &resource_iface))
OCRepPayloadAddInterface(repr, resource_iface);
while (g_variant_iter_loop(resource_types, "s", &resource_type))
OCRepPayloadAddResourceType(repr, resource_type);
ret = _icd_state_value_from_gvariant(repr, repr_gvar);
if (IOTCON_ERROR_NONE != ret) {
ERR("_icd_state_value_from_gvariant() Fail(%d)", ret);
OCRepPayloadDestroy(repr);
return NULL;
}
cur = repr;
while (g_variant_iter_loop(children, "v", &child)) {
cur->next = icd_payload_representation_from_gvariant(child);
if (NULL == cur->next) {
ERR("icd_payload_representation_from_gvariant() Fail");
OCRepPayloadDestroy(repr);
return NULL;
}
cur = cur->next;
}
return repr;
}
NSResult NSSetSyncPayload(NSSyncInfo *sync, OCRepPayload** syncPayload)
{
NS_LOG(DEBUG, "NSSetSyncPayload - IN");
*syncPayload = OCRepPayloadCreate();
if (!*syncPayload)
{
NS_LOG(ERROR, "Failed to allocate payload");
return NS_ERROR;
}
OCRepPayloadSetUri(*syncPayload, NS_COLLECTION_SYNC_URI);
OCRepPayloadSetPropString(*syncPayload, NS_ATTRIBUTE_PROVIDER_ID, sync->providerId);
OCRepPayloadSetPropInt(*syncPayload, NS_ATTRIBUTE_MESSAGE_ID, sync->messageId);
OCRepPayloadSetPropInt(*syncPayload, NS_ATTRIBUTE_STATE, sync->state);
NS_LOG(DEBUG, "NSSetSyncPayload - OUT");
return NS_OK;
}
OCStackResult ProvisionEnrollee(OCQualityOfService qos, const char *query, const char *resUri,
OCDevAddr *destination, int pauseBeforeStart) {
// This sleep is required in case of BLE provisioning due to packet drop issue.
OIC_LOG_V(INFO, TAG, "Sleeping for %d seconds", pauseBeforeStart);
sleep(pauseBeforeStart);
OIC_LOG_V(INFO, TAG, "\n\nExecuting ProvisionEnrollee%s", __func__);
OCRepPayload *payload = OCRepPayloadCreate();
OCRepPayloadSetUri(payload, resUri);
OCRepPayloadSetPropString(payload, OC_RSRVD_ES_TNN, netProvInfo->netAddressInfo.WIFI.ssid);
OCRepPayloadSetPropString(payload, OC_RSRVD_ES_CD, netProvInfo->netAddressInfo.WIFI.pwd);
OIC_LOG_V(DEBUG, TAG, "OCPayload ready for ProvisionEnrollee");
OCStackResult ret = InvokeOCDoResource(query, OC_REST_PUT, destination, OC_HIGH_QOS,
ProvisionEnrolleeResponse, payload, NULL, 0);
return ret;
}
/**
* @brief Create and loads the payload
*
* @return the created payload
*/
OCRepPayload *getPayload(OCEntityHandlerRequest *ehRequest, OCBaseResourceT *resource)
{
OIC_LOG(DEBUG, TAG, "Getting Payload");
if(ehRequest->payload && ehRequest->payload->type != PAYLOAD_TYPE_REPRESENTATION)
{
OIC_LOG(ERROR, TAG, "Incoming payload not a representation");
return NULL;
}
OCRepPayload *payload = OCRepPayloadCreate();
if(!payload)
{
OIC_LOG(ERROR, TAG, "Failed to allocate Payload");
return NULL;
}
OCRepPayloadSetUri(payload, resource->uri);
//OCRepPayloadSetPropString(payload, "name", resource->name);
return payload;
}
void set_uri(struct things_resource_s *res, const char *key)
{
//THINGS_LOG_D(TAG, THINGS_FUNC_ENTRY);
if (key == NULL) {
return;
}
if (res->uri != NULL) {
things_free(res->uri);
res->uri = NULL;
}
res->uri = (char *)things_malloc(sizeof(char) *strlen(key) + 1);
memset(res->uri, 0, strlen(key) + 1);
things_strncpy(res->uri, key, strlen(key) + 1);
if (NULL != res->rep) {
OCRepPayloadSetUri(res->rep->payload, key);
} else {
THINGS_LOG_E(TAG, "Set URI Failed, No Representation Yet");
}
//THINGS_LOG_D(TAG, THINGS_FUNC_EXIT);
}
OCEntityHandlerResult OCEntityHandlerCb(OCEntityHandlerFlag flag, OCEntityHandlerRequest * entityHandlerRequest,
void *callbackParam)
{
OCEntityHandlerResult ehRet = OC_EH_OK;
OCEntityHandlerResponse response = {0};
OCRepPayload* payload = OCRepPayloadCreate();
if(!payload)
{
//OC_LOG(ERROR, TAG, PCF("Failed to allocate Payload"));
return OC_EH_ERROR;
}
if(entityHandlerRequest && (flag & OC_REQUEST_FLAG))
{
//OC_LOG (INFO, TAG, PCF("Flag includes OC_REQUEST_FLAG"));
if(OC_REST_GET == entityHandlerRequest->method)
{
OCRepPayloadSetUri(payload, "/iotar/speaker");
OCRepPayloadSetPropInt(payload, "state", speaker.state);
OCRepPayloadSetPropInt(payload, "volume",speaker.volume);
OCRepPayloadSetPropInt(payload, "time", speaker.time);
OCRepPayloadSetPropInt(payload, "present_song",speaker.present_song);
OCRepPayloadSetPropInt(payload, "next_song", speaker.next_song);
}
else if(OC_REST_PUT == entityHandlerRequest->method)
{
//OC_LOG_V(DEBUG, TAG, "put \n");
//풋 올때 데이터 어떻게 받지??
OCRepPayload* pay = (OCRepPayload*) entityHandlerRequest-> payload;
int64_t order = 0;
int64_t temp = 0;
char in[10];
OCRepPayloadGetPropInt(pay, "order", &order);
if(order == 30){ //재생
OCRepPayloadGetPropInt(pay, "temp", &temp);
makeString('a', temp, (char*)&in);
speaker.present_song = temp;
Serial1.println(in);
millis_prv = millis();
save_time = 0;
speaker.state = 1;
}else if(order == 31){ //볼륨 설정
OCRepPayloadGetPropInt(pay, "temp", &temp);
makeString('v', temp, (char*)&in);
speaker.volume = temp;
Serial1.println(in);
}else if(order == 32){ //다음 노래 설정
OCRepPayloadGetPropInt(pay, "temp", &temp);
makeString('d', temp, (char*)&in);
speaker.next_song = temp;
Serial1.println(in);
}else if(order == 33){ // 현재 아무일 안하고 있으면 0, 재생중 1, 일시정지 2. 로 세팅.
Serial1.println('x');
}else if(order == 34) { //정지.
Serial1.println('s');
}else if(order == 35) { // +1 볼륨.
speaker.volume++;
if(speaker.volume >= 100){
speaker.volume = 100;
}
makeString('v', speaker.volume, (char*)&in);
Serial1.println(in);
}else if(order == 36) { // -1 볼륨.
speaker.volume--;
if(speaker.volume < 1){
speaker.volume = 1;
}
makeString('v', speaker.volume, (char*)&in);
Serial1.println(in);
}else if(order == 37){ // 일시정지, 일시정지 풀기.
Serial1.println('p');
if(speaker.state == 1){
speaker.state = 2;
save_time = speaker.time+2;
}else{
speaker.state = 1;
millis_prv = millis();
}
}else if(order == 38){ //다음노래 재생
speaker.present_song++;
if(speaker.present_song > MAX_SONG){
speaker.present_song = 1;
}
makeString('a', speaker.present_song, (char*)&in);
Serial1.println(in);
millis_prv = millis();
save_time = 0;
speaker.state = 1;
}else if(order == 39){ // 이전 노래 재생
speaker.present_song--;
if(speaker.present_song < 1){
speaker.present_song = MAX_SONG;
}
makeString('a', speaker.present_song, (char*)&in);
Serial1.println(in);
millis_prv = millis();
save_time = 0;
speaker.state = 1;
}
OCRepPayloadSetUri(payload, "/iotar/speaker");
OCRepPayloadSetPropInt(payload, "time", speaker.time);
}
if (ehRet == OC_EH_OK)
{
// Format the response. Note this requires some info about the request
response.requestHandle = entityHandlerRequest->requestHandle;
response.resourceHandle = entityHandlerRequest->resource;
response.ehResult = ehRet;
response.payload = (OCPayload*) payload;
response.numSendVendorSpecificHeaderOptions = 0;
memset(response.sendVendorSpecificHeaderOptions, 0,
sizeof response.sendVendorSpecificHeaderOptions);
memset(response.resourceUri, 0, sizeof response.resourceUri);
// Indicate that response is NOT in a persistent buffer
response.persistentBufferFlag = 0;
// Send the response
if (OCDoResponse(&response) != OC_STACK_OK)
{
// OC_LOG(ERROR, TAG, "Error sending response");
ehRet = OC_EH_ERROR;
}
}
}
if (entityHandlerRequest && (flag & OC_OBSERVE_FLAG))
{
if (OC_OBSERVE_REGISTER == entityHandlerRequest->obsInfo.action)
{
// OC_LOG (INFO, TAG, PCF("Received OC_OBSERVE_REGISTER from client"));
gLightUnderObservation = 1;
}
else if (OC_OBSERVE_DEREGISTER == entityHandlerRequest->obsInfo.action)
{
// OC_LOG (INFO, TAG, PCF("Received OC_OBSERVE_DEREGISTER from client"));
gLightUnderObservation = 0;
}
}
OCRepPayloadDestroy(payload);
return ehRet;
}
OCEntityHandlerResult ProcessPostRequest (OCEntityHandlerRequest *ehRequest,
OCEntityHandlerResponse *response, OCRepPayload** payload)
{
OCEntityHandlerResult ehResult = OC_EH_OK;
OCRepPayload *respPLPost_light = nullptr;
/*
* The entity handler determines how to process a POST request.
* Per the REST paradigm, POST can also be used to update representation of existing
* resource or create a new resource.
* In the sample below, if the POST is for /a/light then a new instance of the Light
* resource is created with default representation (if representation is included in
* POST payload it can be used as initial values) as long as the instance is
* lesser than max new instance count. Once max instance count is reached, POST on
* /a/light updated the representation of /a/light (just like PUT)
*/
if (ehRequest->resource == Light.handle)
{
if (gCurrLightInstance < SAMPLE_MAX_NUM_POST_INSTANCE)
{
// Create new Light instance
char newLightUri[URI_MAXSIZE];
snprintf(newLightUri, URI_MAXSIZE, "/a/light/%d", gCurrLightInstance);
respPLPost_light = OCRepPayloadCreate();
OCRepPayloadSetUri(respPLPost_light, gResourceUri);
OCRepPayloadSetPropString(respPLPost_light, "createduri", newLightUri);
if (0 == createLightResource (newLightUri, &gLightInstance[gCurrLightInstance]))
{
OIC_LOG (INFO, TAG, "Created new Light instance\n");
gLightInstance[gCurrLightInstance].state = 0;
gLightInstance[gCurrLightInstance].power = 0;
gCurrLightInstance++;
strncpy ((char *)response->resourceUri, newLightUri, MAX_URI_LENGTH);
ehResult = OC_EH_RESOURCE_CREATED;
}
}
else
{
// Update repesentation of /a/light
Light.state = true;
Light.power = 11;
respPLPost_light = constructResponse(ehRequest);
}
}
else
{
for (int i = 0; i < SAMPLE_MAX_NUM_POST_INSTANCE; i++)
{
if (ehRequest->resource == gLightInstance[i].handle)
{
gLightInstance[i].state = true;
gLightInstance[i].power = 22;
if (i == 0)
{
respPLPost_light = constructResponse(ehRequest);
break;
}
else if (i == 1)
{
respPLPost_light = constructResponse(ehRequest);
}
}
}
}
if ((respPLPost_light != NULL))
{
*payload = respPLPost_light;
}
else
{
OIC_LOG(INFO, TAG, "Payload was NULL");
ehResult = OC_EH_ERROR;
}
return ehResult;
}
OCEntityHandlerResult ProcessPostRequest (OCEntityHandlerRequest *ehRequest,
OCEntityHandlerResponse *response, OCRepPayload **payload)
{
OCRepPayload *respPLPost_led = NULL;
OCEntityHandlerResult ehResult = OC_EH_OK;
/*
* The entity handler determines how to process a POST request.
* Per the REST paradigm, POST can also be used to update representation of existing
* resource or create a new resource.
* In the sample below, if the POST is for /a/led then a new instance of the LED
* resource is created with default representation (if representation is included in
* POST payload it can be used as initial values) as long as the instance is
* lesser than max new instance count. Once max instance count is reached, POST on
* /a/led updated the representation of /a/led (just like PUT)
*/
if (ehRequest->resource == LED.handle)
{
if (gCurrLedInstance < SAMPLE_MAX_NUM_POST_INSTANCE)
{
// Create new LED instance
char newLedUri[15] = "/a/led/";
int newLedUriLength = strlen(newLedUri);
snprintf (newLedUri + newLedUriLength, sizeof(newLedUri)-newLedUriLength, "%d", gCurrLedInstance);
respPLPost_led = OCRepPayloadCreate();
OCRepPayloadSetUri(respPLPost_led, gResourceUri);
OCRepPayloadSetPropString(respPLPost_led, "createduri", newLedUri);
if (0 == createLEDResource (newLedUri, &gLedInstance[gCurrLedInstance], false, 0))
{
OIC_LOG (INFO, TAG, "Created new LED instance");
gLedInstance[gCurrLedInstance].state = 0;
gLedInstance[gCurrLedInstance].power = 0;
gCurrLedInstance++;
strncpy ((char *)response->resourceUri, newLedUri, MAX_URI_LENGTH);
ehResult = OC_EH_RESOURCE_CREATED;
}
}
else
{
respPLPost_led = constructResponse(ehRequest);
}
}
else
{
for (int i = 0; i < SAMPLE_MAX_NUM_POST_INSTANCE; i++)
{
if (ehRequest->resource == gLedInstance[i].handle)
{
if (i == 0)
{
respPLPost_led = constructResponse(ehRequest);
break;
}
else if (i == 1)
{
respPLPost_led = constructResponse(ehRequest);
}
}
}
}
if (respPLPost_led != NULL)
{
*payload = respPLPost_led;
ehResult = OC_EH_OK;
}
else
{
OIC_LOG_V (INFO, TAG, "Payload was NULL");
ehResult = OC_EH_ERROR;
}
return ehResult;
}
// This is the entity handler for the registered resource.
// This is invoked by OCStack whenever it recevies a request for this resource.
OCEntityHandlerResult OCEntityHandlerCb(OCEntityHandlerFlag flag, OCEntityHandlerRequest * entityHandlerRequest,
void *callbackParam)
{
OCEntityHandlerResult ehRet = OC_EH_OK;
OCEntityHandlerResponse response = {0};
OCRepPayload* payload = OCRepPayloadCreate();
if(!payload)
{
OC_LOG(ERROR, TAG, PCF("Failed to allocate Payload"));
return OC_EH_ERROR;
}
if(entityHandlerRequest && (flag & OC_REQUEST_FLAG))
{
OC_LOG (INFO, TAG, PCF("Flag includes OC_REQUEST_FLAG"));
if(OC_REST_GET == entityHandlerRequest->method)
{
OCRepPayloadSetUri(payload, "/a/light");
OCRepPayloadSetPropBool(payload, "state", true);
OCRepPayloadSetPropInt(payload, "power", 10);
}
else if(OC_REST_PUT == entityHandlerRequest->method)
{
//Do something with the 'put' payload
OCRepPayloadSetUri(payload, "/a/light");
OCRepPayloadSetPropBool(payload, "state", false);
OCRepPayloadSetPropInt(payload, "power", 0);
}
if (ehRet == OC_EH_OK)
{
// Format the response. Note this requires some info about the request
response.requestHandle = entityHandlerRequest->requestHandle;
response.resourceHandle = entityHandlerRequest->resource;
response.ehResult = ehRet;
response.payload = (OCPayload*) payload;
response.numSendVendorSpecificHeaderOptions = 0;
memset(response.sendVendorSpecificHeaderOptions, 0,
sizeof response.sendVendorSpecificHeaderOptions);
memset(response.resourceUri, 0, sizeof response.resourceUri);
// Indicate that response is NOT in a persistent buffer
response.persistentBufferFlag = 0;
// Send the response
if (OCDoResponse(&response) != OC_STACK_OK)
{
OC_LOG(ERROR, TAG, "Error sending response");
ehRet = OC_EH_ERROR;
}
}
}
if (entityHandlerRequest && (flag & OC_OBSERVE_FLAG))
{
if (OC_OBSERVE_REGISTER == entityHandlerRequest->obsInfo.action)
{
OC_LOG (INFO, TAG, PCF("Received OC_OBSERVE_REGISTER from client"));
gLightUnderObservation = 1;
}
else if (OC_OBSERVE_DEREGISTER == entityHandlerRequest->obsInfo.action)
{
OC_LOG (INFO, TAG, PCF("Received OC_OBSERVE_DEREGISTER from client"));
}
}
return ehRet;
}
static OCStackResult
HandleBatchInterface(OCEntityHandlerRequest *ehRequest)
{
if (!ehRequest)
{
return OC_STACK_INVALID_PARAM;
}
OCResource * collResource = (OCResource *) ehRequest->resource;
OCRepPayload* payload = OCRepPayloadCreate();
if (!payload)
{
return OC_STACK_NO_MEMORY;
}
if (collResource)
{
OCRepPayloadSetUri(payload, collResource->uri);
}
OCEntityHandlerResponse response = {0};
response.ehResult = OC_EH_OK;
response.payload = (OCPayload*)payload;
response.persistentBufferFlag = 0;
response.requestHandle = (OCRequestHandle) ehRequest->requestHandle;
response.resourceHandle = (OCResourceHandle) collResource;
OCStackResult stackRet = OCDoResponse(&response);
if (stackRet == OC_STACK_OK)
{
for (uint8_t i = 0; i < MAX_CONTAINED_RESOURCES; i++)
{
OCResource* temp = collResource->rsrcResources[i];
if (temp)
{
// Note that all entity handlers called through a collection
// will get the same pointer to ehRequest, the only difference
// is ehRequest->resource
ehRequest->resource = (OCResourceHandle) temp;
OCEntityHandlerResult ehResult = temp->entityHandler(OC_REQUEST_FLAG, ehRequest,
temp->entityHandlerCallbackParam);
// The default collection handler is returning as OK
if (stackRet != OC_STACK_SLOW_RESOURCE)
{
stackRet = OC_STACK_OK;
}
// if a single resource is slow, then entire response will be treated
// as slow response
if (ehResult == OC_EH_SLOW)
{
OC_LOG(INFO, TAG, "This is a slow resource");
((OCServerRequest *)ehRequest->requestHandle)->slowFlag = 1;
stackRet = EntityHandlerCodeToOCStackCode(ehResult);
}
}
else
{
break;
}
}
ehRequest->resource = (OCResourceHandle) collResource;
}
return stackRet;
}
