# Request response in C You can find a more detailed description of the C API in the [iceoryx_binding_c README.md](https://github.com/eclipse-iceoryx/iceoryx/blob/v2.0.0/iceoryx_binding_c/README.md). ## Introduction The behavior and structure is very close to the [request response C++ example](https://github.com/eclipse-iceoryx/iceoryx/tree/v2.0.0/iceoryx_examples/request_response) so that we explain here only the C API differences and not the underlying mechanisms. The rough idea is that the client sends two fibonacci numbers to the server which then sends the sum of those numbers back. ## Expected Output [![asciicast](https://asciinema.org/a/476845.svg)](https://asciinema.org/a/476845) ## Code walkthrough ### Client Basic Like with most iceoryx C applications we start with: * Registering a signal handler * Initialize the runtime ```c signal(SIGINT, sigHandler); signal(SIGTERM, sigHandler); iox_runtime_init(APP_NAME); ``` We continue with initializing our `client` to send requests to the server. First of all, we need some memory in which the client can be stored called `clientStorage`. `iox_client_init` will create an object in this memory location, sets the service description and uses the default client options which is indicated by the `NULL` argument at the end. ```c iox_client_storage_t clientStorage; iox_client_t client = iox_client_init(&clientStorage, "Example", "Request-Response", "Add", NULL); ``` Like in the C++ version of our example we implement a client/server based fibonacci algorithm and store the first two fibonacci numbers in `fibonacciLast` and `fibonacciCurrent`. `requestSequenceId` and `expectedResponseSequenceId` are helping us to keep track of the sequence number which we increase with every sent request and then verify it again in the server's response. ```c uint64_t fibonacciLast = 0U; uint64_t fibonacciCurrent = 1U; int64_t requestSequenceId = 0; int64_t expectedResponseSequenceId = requestSequenceId; ``` We enter our main loop and continue sending requests as long as `keepRunning` is `true`. When the users presses Control+C the term signal is emitted and `keepRunning` is set to `false` via the signal handler callback. We start by loaning memory to send out our `request`. ```c struct AddRequest* request = NULL; enum iox_AllocationResult loanResult = iox_client_loan_request(client, (void**)&request, sizeof(struct AddRequest)); ``` To set the sequence id we have to acquire the request header first from the payload. Additionally, we set `expectedResponseSequenceId` so that we can verify the response later and increment the `requestSequenceId` for the next run. ```c iox_request_header_t requestHeader = iox_request_header_from_payload(request); iox_request_header_set_sequence_id(requestHeader, requestSequenceId); expectedResponseSequenceId = requestSequenceId; requestSequenceId += 1; ``` Before we can send out the `request` we have to set the two fibonacci numbers. ```c request->augend = fibonacciLast; request->addend = fibonacciCurrent; printf("%s Send Request: %lu + %lu\n", APP_NAME, (unsigned long)fibonacciLast, (unsigned long)fibonacciCurrent); enum iox_ClientSendResult sendResult = iox_client_send(client, request); if (sendResult != ClientSendResult_SUCCESS) { printf("Error sending Request! Error code: %d\n", sendResult); } ``` Now we give the server a little time to process the `request`. ```c const uint32_t DELAY_TIME_IN_MS = 150U; sleep_for(DELAY_TIME_IN_MS); ``` We process the `response` by acquiring it first with `iox_client_take_response`. If this is successful we verify the sequence number, adjust our fibonacci numbers and print our response to the console. When the sequence number does not fulfill our expectation we print an error message. ```c const struct AddResponse* response = NULL; while (iox_client_take_response(client, (const void**)&response) == ChunkReceiveResult_SUCCESS) { iox_const_response_header_t responseHeader = iox_response_header_from_payload_const(response); int64_t receivedSequenceId = iox_response_header_get_sequence_id_const(responseHeader); if (receivedSequenceId == expectedResponseSequenceId) { fibonacciLast = fibonacciCurrent; fibonacciCurrent = response->sum; printf("%s Got Response: %lu\n", APP_NAME, (unsigned long)fibonacciCurrent); } else { printf("Got Response with outdated sequence ID! Expected = %lu; Actual = %lu! -> skip\n", (unsigned long)expectedResponseSequenceId, (unsigned long)receivedSequenceId); } iox_client_release_response(client, response); } ``` Please do not forget to call `iox_client_release_response` to release the `response` again. If you forget this you won't be able to receive `response`s anymore after a certain time since you hold to many responses in parallel. As final step we cleanup the used resources and deinitialize the client. ```c iox_client_deinit(client); ``` ### Client WaitSet The server and client or both attachable to either a listener or a waitset. In this example we demonstrate how one can implement the client basic example with a waitset. For deeper insights into the WaitSet take a look at the [WaitSet C++ example](https://github.com/eclipse-iceoryx/iceoryx/tree/v2.0.0/iceoryx_examples/waitset) or when you would like to know more about the listener, see the [Callbacks C++ example](https://github.com/eclipse-iceoryx/iceoryx/tree/v2.0.0/iceoryx_examples/callbacks). The startup phase is identical to the client basic version, we register the signal handlers, initialize the runtime, create a client and initialize our variables. Afterwards we create our waitset and attach the client state `ClientState_HAS_RESPONSE` to it. ```c iox_ws_storage_t waitsetStorage; iox_ws_t waitset = iox_ws_init(&waitsetStorage); if (iox_ws_attach_client_state(waitset, client, ClientState_HAS_RESPONSE, 0U, NULL) != WaitSetResult_SUCCESS) { printf("failed to attach client\n"); _exit(-1); } ``` Again we perform the same task like in the client basic example. We enter our main loop, loan a request and set it up. But after we sent the request to our server we do not sleep for some time, we wait on the waitset until the request was received. We use `iox_ws_timed_wait` to wait for at most 2 seconds. ```c iox_notification_info_t notificationArray[NUMBER_OF_NOTIFICATIONS]; uint64_t missedNotifications = 0U; struct timespec timeout; timeout.tv_sec = 2; timeout.tv_nsec = 0; uint64_t numberOfNotifications = iox_ws_timed_wait(waitset, timeout, notificationArray, NUMBER_OF_NOTIFICATIONS, &missedNotifications); ``` When this blocking call returns we iterate over the `notificationArray` and when one triggered originated from our `client` we acquire all responses in a while loop and print them to the console. ```c for (uint64_t i = 0; i < numberOfNotifications; ++i) { if (iox_notification_info_does_originate_from_client(notificationArray[i], client)) { const struct AddResponse* response = NULL; while (iox_client_take_response(client, (const void**)&response) == ChunkReceiveResult_SUCCESS) { iox_const_response_header_t responseHeader = iox_response_header_from_payload_const(response); int64_t receivedSequenceId = iox_response_header_get_sequence_id_const(responseHeader); if (receivedSequenceId == expectedResponseSequenceId) { fibonacciLast = fibonacciCurrent; fibonacciCurrent = response->sum; printf("%s Got Response: %lu\n", APP_NAME, (unsigned long)fibonacciCurrent); } else { printf("Got Response with outdated sequence ID! Expected = %lu; Actual = %lu! -> skip\n", (unsigned long)expectedResponseSequenceId, (unsigned long)receivedSequenceId); } iox_client_release_response(client, response); } } } ``` The cleanup is done when we exit our mainloop. We detach the client state from the waitset first and then deinitialize the waitset and the client. ```c iox_ws_detach_client_state(waitset, client, ClientState_HAS_RESPONSE); iox_ws_deinit(waitset); iox_client_deinit(client); ``` ### Server Basic We again start with registering the signal handler and the runtime. ```c signal(SIGINT, sigHandler); signal(SIGTERM, sigHandler); iox_runtime_init(APP_NAME); ``` As next step we initialize the `server`. Like the client the `server` requires some memory where it can be stored, the `serverStorage`. The `server` is also initialized with the default options which is indicated via the last `NULL` argument. ```c iox_server_storage_t serverStorage; iox_server_t server = iox_server_init(&serverStorage, "Example", "Request-Response", "Add", NULL); ``` We enter the main loop and start it by taking a `request`. If it was taken successfully, we print an info message to the console and loan a `response`. We require the `request` for the loan so that the `response` can be delivered to the corresponding client. When the `iox_server_loan_response` was successful we calculate the sum of the two received fibonacci numbers and send it. ```c const struct AddRequest* request = NULL; if (iox_server_take_request(server, (const void**)&request) == ServerRequestResult_SUCCESS) { printf("%s Got Request: %lu + %lu\n", APP_NAME, (unsigned long)request->augend, (unsigned long)request->addend); struct AddResponse* response = NULL; enum iox_AllocationResult loanResult = iox_server_loan_response(server, request, (void**)&response, sizeof(struct AddResponse)); if (loanResult == AllocationResult_SUCCESS) { response->sum = request->augend + request->addend; printf("%s Send Response: %lu\n", APP_NAME, (unsigned long)response->sum); enum iox_ServerSendResult sendResult = iox_server_send(server, response); if (sendResult != ServerSendResult_SUCCESS) { printf("Error sending Response! Error code: %d\n", sendResult); } } else { printf("%s Could not allocate Response! Error code: %d\n", APP_NAME, loanResult); } iox_server_release_request(server, request); } ``` Again, it is important that one releases the `request` with `iox_server_release_request` otherwise `iox_server_take_request` will fail since one holds to many requests in parallel. The final step is again the resource cleanup where we deinitialize the server. ```c iox_server_deinit(server); ``` ### Server Listener The server and client or both attachable to either a listener or a waitset. In this example we demonstrate how one can implement the server basic example with a listener. For deeper insights into the WaitSet take a look at the [WaitSet C++ example](https://github.com/eclipse-iceoryx/iceoryx/tree/v2.0.0/iceoryx_examples/waitset) or when you would like to know more about the listener, see the [Callbacks C++ example](https://github.com/eclipse-iceoryx/iceoryx/tree/v2.0.0/iceoryx_examples/callbacks). The listener example starts like the basic example by registering the signal handler, initializing the runtime and creating a server. In the next step we create a listener and attach the server event `ServerEvent_REQUEST_RECEIVED` with `iox_listener_attach_server_event`. One parameter of that call is `onRequestReceived` a pointer to a function which handles the logic whenever we receive a request. ```c iox_server_storage_t serverStorage; iox_server_t server = iox_server_init(&serverStorage, "Example", "Request-Response", "Add", NULL); iox_listener_storage_t listenerStorage; iox_listener_t listener = iox_listener_init(&listenerStorage); if (iox_listener_attach_server_event(listener, server, ServerEvent_REQUEST_RECEIVED, onRequestReceived) != ListenerResult_SUCCESS) { printf("unable to attach server\n"); _exit(-1); } ``` In the next step we run into our main loop which waits until the user terminates the process. ```c while (keepRunning) { const uint32_t SLEEP_TIME_IN_MS = 500U; sleep_for(SLEEP_TIME_IN_MS); } ``` The actual logic behind processing a request is handled in the function `onRequestReceived` which is called in a thread inside the listener whenever our server receives a request. The code again looks identical to the server basic example. We take the request with `iox_server_take_request`, print a message to the console and then loan a response with `iox_server_loan_response` which is populated and send to the client with `iox_server_send`. ```c void onRequestReceived(iox_server_t server) { const struct AddRequest* request = NULL; while (iox_server_take_request(server, (const void**)&request) == ServerRequestResult_SUCCESS) { printf("%s Got Request: %lu + %lu\n", APP_NAME, (unsigned long)request->augend, (unsigned long)request->addend); struct AddResponse* response = NULL; enum iox_AllocationResult loanResult = iox_server_loan_response(server, request, (void**)&response, sizeof(struct AddResponse)); if (loanResult == AllocationResult_SUCCESS) { response->sum = request->augend + request->addend; printf("%s Send Response: %lu\n", APP_NAME, (unsigned long)response->sum); enum iox_ServerSendResult sendResult = iox_server_send(server, response); if (sendResult != ServerSendResult_SUCCESS) { printf("Error sending Response! Error code: %d\n", sendResult); } } else { printf("Could not allocate Response! Error code: %d\n", loanResult); } iox_server_release_request(server, request); } } ``` The resource cleanup is done after our mainloop has ended. We detach the server event from the listener first and then deinitialize the listener and server. ```c iox_listener_detach_server_event(listener, server, ServerEvent_REQUEST_RECEIVED); iox_listener_deinit(listener); iox_server_deinit(server); ```
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