Jeon byungchul
/
aws-iot-example
this is fork and i will modify for STM32
Fork of AWS-test by
aws-iot/src/aws_iot_mqtt_client_yield.cpp
- Committer:
- peyo
- Date:
- 2017-04-12
- Revision:
- 0:cd5404401c2f
- Child:
- 2:db59f45ad3d3
File content as of revision 0:cd5404401c2f:
/* * Copyright 2015-2016 Amazon.com, Inc. or its affiliates. All Rights Reserved. * * Licensed under the Apache License, Version 2.0 (the "License"). * You may not use this file except in compliance with the License. * A copy of the License is located at * * http://aws.amazon.com/apache2.0 * * or in the "license" file accompanying this file. This file is distributed * on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either * express or implied. See the License for the specific language governing * permissions and limitations under the License. */ // Based on Eclipse Paho. /******************************************************************************* * Copyright (c) 2014 IBM Corp. * * All rights reserved. This program and the accompanying materials * are made available under the terms of the Eclipse Public License v1.0 * and Eclipse Distribution License v1.0 which accompany this distribution. * * The Eclipse Public License is available at * http://www.eclipse.org/legal/epl-v10.html * and the Eclipse Distribution License is available at * http://www.eclipse.org/org/documents/edl-v10.php. * * Contributors: * Allan Stockdill-Mander/Ian Craggs - initial API and implementation and/or initial documentation *******************************************************************************/ /** * @file aws_iot_mqtt_client_yield.c * @brief MQTT client yield API definitions */ #ifdef __cplusplus extern "C" { #endif #include "aws_iot_mqtt_client_common_internal.h" /** * This is for the case when the aws_iot_mqtt_internal_send_packet Fails. */ static void _aws_iot_mqtt_force_client_disconnect(AWS_IoT_Client *pClient) { pClient->clientStatus.clientState = CLIENT_STATE_DISCONNECTED_ERROR; pClient->networkStack.disconnect(&(pClient->networkStack)); pClient->networkStack.destroy(&(pClient->networkStack)); } static IoT_Error_t _aws_iot_mqtt_handle_disconnect(AWS_IoT_Client *pClient) { IoT_Error_t rc; FUNC_ENTRY; rc = aws_iot_mqtt_disconnect(pClient); if(rc != SUCCESS) { // If the aws_iot_mqtt_internal_send_packet prevents us from sending a disconnect packet then we have to clean the stack _aws_iot_mqtt_force_client_disconnect(pClient); } if(NULL != pClient->clientData.disconnectHandler) { pClient->clientData.disconnectHandler(pClient, pClient->clientData.disconnectHandlerData); } /* Reset to 0 since this was not a manual disconnect */ pClient->clientStatus.clientState = CLIENT_STATE_DISCONNECTED_ERROR; FUNC_EXIT_RC(NETWORK_DISCONNECTED_ERROR); } static IoT_Error_t _aws_iot_mqtt_handle_reconnect(AWS_IoT_Client *pClient) { IoT_Error_t rc; FUNC_ENTRY; if(!has_timer_expired(&(pClient->reconnectDelayTimer))) { /* Timer has not expired. Not time to attempt reconnect yet. * Return attempting reconnect */ FUNC_EXIT_RC(NETWORK_ATTEMPTING_RECONNECT); } rc = NETWORK_PHYSICAL_LAYER_DISCONNECTED; if(NULL != pClient->networkStack.isConnected) { rc = pClient->networkStack.isConnected(&(pClient->networkStack)); } if(NETWORK_PHYSICAL_LAYER_CONNECTED == rc) { rc = aws_iot_mqtt_attempt_reconnect(pClient); if(NETWORK_RECONNECTED == rc) { rc = aws_iot_mqtt_set_client_state(pClient, CLIENT_STATE_CONNECTED_IDLE, CLIENT_STATE_CONNECTED_YIELD_IN_PROGRESS); if(SUCCESS != rc) { FUNC_EXIT_RC(rc); } FUNC_EXIT_RC(NETWORK_RECONNECTED); } } pClient->clientData.currentReconnectWaitInterval *= 2; if(AWS_IOT_MQTT_MAX_RECONNECT_WAIT_INTERVAL < pClient->clientData.currentReconnectWaitInterval) { FUNC_EXIT_RC(NETWORK_RECONNECT_TIMED_OUT_ERROR); } countdown_ms(&(pClient->reconnectDelayTimer), pClient->clientData.currentReconnectWaitInterval); FUNC_EXIT_RC(rc); } static IoT_Error_t _aws_iot_mqtt_keep_alive(AWS_IoT_Client *pClient) { IoT_Error_t rc = SUCCESS; TimerAWS timer; size_t serialized_len; FUNC_ENTRY; if(NULL == pClient) { FUNC_EXIT_RC(NULL_VALUE_ERROR); } if(0 == pClient->clientData.keepAliveInterval) { FUNC_EXIT_RC(SUCCESS); } if(!has_timer_expired(&pClient->pingTimer)) { FUNC_EXIT_RC(SUCCESS); } if(pClient->clientStatus.isPingOutstanding) { rc = _aws_iot_mqtt_handle_disconnect(pClient); FUNC_EXIT_RC(rc); } /* there is no ping outstanding - send one */ init_timer(&timer); countdown_ms(&timer, pClient->clientData.commandTimeoutMs); serialized_len = 0; rc = aws_iot_mqtt_internal_serialize_zero(pClient->clientData.writeBuf, pClient->clientData.writeBufSize, PINGREQ, &serialized_len); if(SUCCESS != rc) { FUNC_EXIT_RC(rc); } /* send the ping packet */ rc = aws_iot_mqtt_internal_send_packet(pClient, serialized_len, &timer); if(SUCCESS != rc) { //If sending a PING fails we can no longer determine if we are connected. In this case we decide we are disconnected and begin reconnection attempts rc = _aws_iot_mqtt_handle_disconnect(pClient); FUNC_EXIT_RC(rc); } pClient->clientStatus.isPingOutstanding = true; /* start a timer to wait for PINGRESP from server */ countdown_sec(&pClient->pingTimer, pClient->clientData.keepAliveInterval); FUNC_EXIT_RC(SUCCESS); } /** * @brief Yield to the MQTT client * * Called to yield the current thread to the underlying MQTT client. This time is used by * the MQTT client to manage PING requests to monitor the health of the TCP connection as * well as periodically check the socket receive buffer for subscribe messages. Yield() * must be called at a rate faster than the keepalive interval. It must also be called * at a rate faster than the incoming message rate as this is the only way the client receives * processing time to manage incoming messages. * This is the internal function which is called by the yield API to perform the operation. * Not meant to be called directly as it doesn't do validations or client state changes * * @param pClient Reference to the IoT Client * @param timeout_ms Maximum number of milliseconds to pass thread execution to the client. * * @return An IoT Error Type defining successful/failed client processing. * If this call results in an error it is likely the MQTT connection has dropped. * iot_is_mqtt_connected can be called to confirm. */ static IoT_Error_t _aws_iot_mqtt_internal_yield(AWS_IoT_Client *pClient, uint32_t timeout_ms) { IoT_Error_t yieldRc = SUCCESS; uint8_t packet_type; ClientState clientState; TimerAWS timer; init_timer(&timer); countdown_ms(&timer, timeout_ms); FUNC_ENTRY; // evaluate timeout at the end of the loop to make sure the actual yield runs at least once do { clientState = aws_iot_mqtt_get_client_state(pClient); if(CLIENT_STATE_PENDING_RECONNECT == clientState) { if(AWS_IOT_MQTT_MAX_RECONNECT_WAIT_INTERVAL < pClient->clientData.currentReconnectWaitInterval) { yieldRc = NETWORK_RECONNECT_TIMED_OUT_ERROR; break; } yieldRc = _aws_iot_mqtt_handle_reconnect(pClient); /* Network reconnect attempted, check if yield timer expired before * doing anything else */ continue; } yieldRc = aws_iot_mqtt_internal_cycle_read(pClient, &timer, &packet_type); if(SUCCESS == yieldRc) { yieldRc = _aws_iot_mqtt_keep_alive(pClient); } else { // SSL read and write errors are terminal, connection must be closed and retried if(NETWORK_SSL_READ_ERROR == yieldRc || NETWORK_SSL_READ_TIMEOUT_ERROR == yieldRc || NETWORK_SSL_WRITE_ERROR == yieldRc || NETWORK_SSL_WRITE_TIMEOUT_ERROR == yieldRc) { yieldRc = _aws_iot_mqtt_handle_disconnect(pClient); } } if(NETWORK_DISCONNECTED_ERROR == yieldRc) { pClient->clientData.counterNetworkDisconnected++; if(1 == pClient->clientStatus.isAutoReconnectEnabled) { yieldRc = aws_iot_mqtt_set_client_state(pClient, CLIENT_STATE_DISCONNECTED_ERROR, CLIENT_STATE_PENDING_RECONNECT); if(SUCCESS != yieldRc) { FUNC_EXIT_RC(yieldRc); } pClient->clientData.currentReconnectWaitInterval = AWS_IOT_MQTT_MIN_RECONNECT_WAIT_INTERVAL; countdown_ms(&(pClient->reconnectDelayTimer), pClient->clientData.currentReconnectWaitInterval); /* Depending on timer values, it is possible that yield timer has expired * Set to rc to attempting reconnect to inform client that autoreconnect * attempt has started */ yieldRc = NETWORK_ATTEMPTING_RECONNECT; } else { break; } } else if(SUCCESS != yieldRc) { break; } } while(!has_timer_expired(&timer)); FUNC_EXIT_RC(yieldRc); } /** * @brief Yield to the MQTT client * * Called to yield the current thread to the underlying MQTT client. This time is used by * the MQTT client to manage PING requests to monitor the health of the TCP connection as * well as periodically check the socket receive buffer for subscribe messages. Yield() * must be called at a rate faster than the keepalive interval. It must also be called * at a rate faster than the incoming message rate as this is the only way the client receives * processing time to manage incoming messages. * This is the outer function which does the validations and calls the internal yield above * to perform the actual operation. It is also responsible for client state changes * * @param pClient Reference to the IoT Client * @param timeout_ms Maximum number of milliseconds to pass thread execution to the client. * * @return An IoT Error Type defining successful/failed client processing. * If this call results in an error it is likely the MQTT connection has dropped. * iot_is_mqtt_connected can be called to confirm. */ IoT_Error_t aws_iot_mqtt_yield(AWS_IoT_Client *pClient, uint32_t timeout_ms) { IoT_Error_t rc, yieldRc; ClientState clientState; if(NULL == pClient || 0 == timeout_ms) { FUNC_EXIT_RC(NULL_VALUE_ERROR); } clientState = aws_iot_mqtt_get_client_state(pClient); /* Check if network was manually disconnected */ if(CLIENT_STATE_DISCONNECTED_MANUALLY == clientState) { FUNC_EXIT_RC(NETWORK_MANUALLY_DISCONNECTED); } /* If we are in the pending reconnect state, skip other checks. * Pending reconnect state is only set when auto-reconnect is enabled */ if(CLIENT_STATE_PENDING_RECONNECT != clientState) { /* Check if network is disconnected and auto-reconnect is not enabled */ if(!aws_iot_mqtt_is_client_connected(pClient)) { FUNC_EXIT_RC(NETWORK_DISCONNECTED_ERROR); } /* Check if client is idle, if not another operation is in progress and we should return */ if(CLIENT_STATE_CONNECTED_IDLE != clientState) { FUNC_EXIT_RC(MQTT_CLIENT_NOT_IDLE_ERROR); } rc = aws_iot_mqtt_set_client_state(pClient, CLIENT_STATE_CONNECTED_IDLE, CLIENT_STATE_CONNECTED_YIELD_IN_PROGRESS); if(SUCCESS != rc) { FUNC_EXIT_RC(rc); } } yieldRc = _aws_iot_mqtt_internal_yield(pClient, timeout_ms); if(NETWORK_DISCONNECTED_ERROR != yieldRc && NETWORK_ATTEMPTING_RECONNECT != yieldRc) { rc = aws_iot_mqtt_set_client_state(pClient, CLIENT_STATE_CONNECTED_YIELD_IN_PROGRESS, CLIENT_STATE_CONNECTED_IDLE); if(SUCCESS == yieldRc && SUCCESS != rc) { yieldRc = rc; } } FUNC_EXIT_RC(yieldRc); } #ifdef __cplusplus } #endif