/******************************************************************************* * 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 *******************************************************************************/ #include #include #include "MQTTClient.h" static void new_message_data(mqtt_message_data_t* md, mqtt_string_t* aTopicName, mqtt_message_t* aMessgage) { md->topic = aTopicName; md->message = aMessgage; } static int get_next_packet_id(mqtt_client_t *c) { return c->next_packetid = (c->next_packetid == MQTT_MAX_PACKET_ID) ? 1 : c->next_packetid + 1; } static int send_packet(mqtt_client_t* c, int length, mqtt_timer_t* timer) { int rc = MQTT_FAILURE, sent = 0; while (sent < length && !mqtt_timer_expired(timer)) { rc = c->ipstack->mqttwrite(c->ipstack, &c->buf[sent], length - sent, mqtt_timer_left_ms(timer)); if (rc < 0) // there was an error writing the data break; sent += rc; } if (sent == length) { mqtt_timer_countdown(&(c->ping_timer), c->keepAliveInterval); // record the fact that we have successfully sent the packet rc = MQTT_SUCCESS; } else rc = MQTT_FAILURE; return rc; } static int decode_packet(mqtt_client_t* c, int* value, int timeout) { unsigned char i; int multiplier = 1; int len = 0; const int MAX_NO_OF_REMAINING_LENGTH_BYTES = 4; *value = 0; do { int rc = MQTTPACKET_READ_ERROR; if (++len > MAX_NO_OF_REMAINING_LENGTH_BYTES) { rc = MQTTPACKET_READ_ERROR; /* bad data */ goto exit; } rc = c->ipstack->mqttread(c->ipstack, &i, 1, timeout); if (rc != 1) { goto exit; } *value += (i & 127) * multiplier; multiplier *= 128; } while ((i & 128) != 0); exit: return len; } // Return packet type. If no packet avilable, return FAILURE, or READ_ERROR if timeout static int read_packet(mqtt_client_t* c, mqtt_timer_t* timer) { int rc = MQTT_FAILURE; mqtt_header_t header = {0}; int len = 0; int rem_len = 0; /* 1. read the header byte. This has the packet type in it */ if (c->ipstack->mqttread(c->ipstack, c->readbuf, 1, mqtt_timer_left_ms(timer)) != 1) goto exit; len = 1; /* 2. read the remaining length. This is variable in itself */ len += decode_packet(c, &rem_len, mqtt_timer_left_ms(timer)); if (len <= 1 || len + rem_len > c->readbuf_size) /* if packet is too big to fit in our readbuf, abort */ { rc = MQTT_READ_ERROR; goto exit; } mqtt_packet_encode(c->readbuf + 1, rem_len); /* put the original remaining length back into the buffer */ /* 3. read the rest of the buffer using a callback to supply the rest of the data */ if (rem_len > 0 && (c->ipstack->mqttread(c->ipstack, c->readbuf + len, rem_len, mqtt_timer_left_ms(timer)) != rem_len)) { rc = MQTT_READ_ERROR; goto exit; } header.byte = c->readbuf[0]; rc = header.bits.type; exit: return rc; } // assume topic filter and name is in correct format // # can only be at end // + and # can only be next to separator static char is_topic_matched(char* topicFilter, mqtt_string_t* topicName) { char* curf = topicFilter; char* curn = topicName->lenstring.data; char* curn_end = curn + topicName->lenstring.len; while (*curf && curn < curn_end) { if (*curn == '/' && *curf != '/') break; if (*curf != '+' && *curf != '#' && *curf != *curn) break; if (*curf == '+') { // skip until we meet the next separator, or end of string char* nextpos = curn + 1; while (nextpos < curn_end && *nextpos != '/') nextpos = ++curn + 1; } else if (*curf == '#') curn = curn_end - 1; // skip until end of string curf++; curn++; }; return (curn == curn_end) && (*curf == '\0'); } static int deliver_message(mqtt_client_t* c, mqtt_string_t* topicName, mqtt_message_t* message) { int i; int rc = MQTT_FAILURE; // we have to find the right message handler - indexed by topic for (i = 0; i < MQTT_MAX_MESSAGE_HANDLERS; ++i) { if (c->messageHandlers[i].topicFilter != 0 && (mqtt_packet_equals(topicName, (char*)c->messageHandlers[i].topicFilter) || is_topic_matched((char*)c->messageHandlers[i].topicFilter, topicName))) { if (c->messageHandlers[i].fp != NULL) { mqtt_message_data_t md; new_message_data(&md, topicName, message); c->messageHandlers[i].fp(&md); rc = MQTT_SUCCESS; } } } if (rc == MQTT_FAILURE && c->defaultMessageHandler != NULL) { mqtt_message_data_t md; new_message_data(&md, topicName, message); c->defaultMessageHandler(&md); rc = MQTT_SUCCESS; } return rc; } static int keepalive(mqtt_client_t* c) { int rc = MQTT_SUCCESS; if (c->keepAliveInterval == 0) { rc = MQTT_SUCCESS; goto exit; } if (mqtt_timer_expired(&(c->ping_timer))) { if (c->ping_outstanding) { // if ping failure accumulated above MAX_FAIL_ALLOWED, the connection is broken ++(c->fail_count); if (c->fail_count >= MQTT_MAX_FAIL_ALLOWED) { rc = MQTT_DISCONNECTED; goto exit; } } else { mqtt_timer_t timer; mqtt_timer_init(&timer); mqtt_timer_countdown_ms(&timer, 1000); c->ping_outstanding = 1; int len = mqtt_serialize_pingreq(c->buf, c->buf_size); if (len > 0) send_packet(c, len, &timer); } // re-arm ping counter mqtt_timer_countdown(&(c->ping_timer), c->keepAliveInterval); } exit: return rc; } static int cycle(mqtt_client_t* c, mqtt_timer_t* timer) { // read the socket, see what work is due int packet_type = read_packet(c, timer); int len = 0, rc = MQTT_SUCCESS; switch (packet_type) { case MQTTPACKET_CONNACK: case MQTTPACKET_PUBACK: case MQTTPACKET_SUBACK: break; case MQTTPACKET_PUBLISH: { mqtt_string_t topicName; mqtt_message_t msg; if (mqtt_deserialize_publish((unsigned char*)&msg.dup, (int*)&msg.qos, (unsigned char*)&msg.retained, (unsigned short*)&msg.id, &topicName, (unsigned char**)&msg.payload, (int*)&msg.payloadlen, c->readbuf, c->readbuf_size) != 1) goto exit; deliver_message(c, &topicName, &msg); if (msg.qos != MQTT_QOS0) { if (msg.qos == MQTT_QOS1) len = mqtt_serialize_ack(c->buf, c->buf_size, MQTTPACKET_PUBACK, 0, msg.id); else if (msg.qos == MQTT_QOS2) len = mqtt_serialize_ack(c->buf, c->buf_size, MQTTPACKET_PUBREC, 0, msg.id); if (len <= 0) rc = MQTT_FAILURE; else rc = send_packet(c, len, timer); if (rc == MQTT_FAILURE) goto exit; // there was a problem } break; } case MQTTPACKET_PUBREC: { unsigned short mypacketid; unsigned char dup, type; if (mqtt_deserialize_ack(&type, &dup, &mypacketid, c->readbuf, c->readbuf_size) != 1) rc = MQTT_FAILURE; else if ((len = mqtt_serialize_ack(c->buf, c->buf_size, MQTTPACKET_PUBREL, 0, mypacketid)) <= 0) rc = MQTT_FAILURE; else if ((rc = send_packet(c, len, timer)) != MQTT_SUCCESS) // send the PUBREL packet rc = MQTT_FAILURE; // there was a problem if (rc == MQTT_FAILURE) goto exit; // there was a problem break; } case MQTTPACKET_PUBCOMP: break; case MQTTPACKET_PINGRESP: { c->ping_outstanding = 0; c->fail_count = 0; break; } case MQTT_READ_ERROR: { c->isconnected = 0; // we simulate a disconnect if reading error rc = MQTT_DISCONNECTED; // so that the outer layer will reconnect and recover break; } } if (c->isconnected) rc = keepalive(c); exit: if (rc == MQTT_SUCCESS) rc = packet_type; return rc; } void mqtt_client_new(mqtt_client_t* c, mqtt_network_t* network, unsigned int command_timeout_ms, unsigned char* buf, size_t buf_size, unsigned char* readbuf, size_t readbuf_size) { int i; c->ipstack = network; for (i = 0; i < MQTT_MAX_MESSAGE_HANDLERS; ++i) c->messageHandlers[i].topicFilter = 0; c->command_timeout_ms = command_timeout_ms; c->buf = buf; c->buf_size = buf_size; c->readbuf = readbuf; c->readbuf_size = readbuf_size; c->isconnected = 0; c->ping_outstanding = 0; c->fail_count = 0; c->defaultMessageHandler = NULL; mqtt_timer_init(&(c->ping_timer)); } int mqtt_yield(mqtt_client_t* c, int timeout_ms) { int rc = MQTT_SUCCESS; mqtt_timer_t timer; mqtt_timer_init(&timer); mqtt_timer_countdown_ms(&timer, timeout_ms); while (!mqtt_timer_expired(&timer)) { rc = cycle(c, &timer); // cycle could return 0 or packet_type or 65535 if nothing is read // cycle returns DISCONNECTED only if keepalive() fails. if (rc == MQTT_DISCONNECTED) break; rc = MQTT_SUCCESS; } return rc; } // only used in single-threaded mode where one command at a time is in process static int waitfor(mqtt_client_t* c, int packet_type, mqtt_timer_t* timer) { int rc = MQTT_FAILURE; do { if (mqtt_timer_expired(timer)) break; // we timed out } while ((rc = cycle(c, timer)) != packet_type); return rc; } int mqtt_connect(mqtt_client_t* c, mqtt_packet_connect_data_t* options) { mqtt_timer_t connect_timer; int rc = MQTT_FAILURE; mqtt_packet_connect_data_t default_options = mqtt_packet_connect_data_initializer; int len = 0; mqtt_timer_init(&connect_timer); mqtt_timer_countdown_ms(&connect_timer, c->command_timeout_ms); if (c->isconnected) // don't send connect packet again if we are already connected goto exit; if (options == 0) options = &default_options; // set default options if none were supplied c->keepAliveInterval = options->keepAliveInterval; mqtt_timer_countdown(&(c->ping_timer), c->keepAliveInterval); if ((len = mqtt_serialize_connect(c->buf, c->buf_size, options)) <= 0) goto exit; if ((rc = send_packet(c, len, &connect_timer)) != MQTT_SUCCESS) // send the connect packet goto exit; // there was a problem // this will be a blocking call, wait for the connack if (waitfor(c, MQTTPACKET_CONNACK, &connect_timer) == MQTTPACKET_CONNACK) { unsigned char connack_rc = 255; char sessionPresent = 0; if (mqtt_deserialize_connack((unsigned char*)&sessionPresent, &connack_rc, c->readbuf, c->readbuf_size) == 1) rc = connack_rc; else rc = MQTT_FAILURE; } else rc = MQTT_FAILURE; exit: if (rc == MQTT_SUCCESS) c->isconnected = 1; return rc; } int mqtt_subscribe(mqtt_client_t* c, const char* topic, enum mqtt_qos qos, mqtt_message_handler_t handler) { int rc = MQTT_FAILURE; mqtt_timer_t timer; int len = 0; mqtt_string_t topicStr = mqtt_string_initializer; topicStr.cstring = (char *)topic; mqtt_timer_init(&timer); mqtt_timer_countdown_ms(&timer, c->command_timeout_ms); if (!c->isconnected) goto exit; len = mqtt_serialize_subscribe(c->buf, c->buf_size, 0, get_next_packet_id(c), 1, &topicStr, (int*)&qos); if (len <= 0) goto exit; if ((rc = send_packet(c, len, &timer)) != MQTT_SUCCESS) // send the subscribe packet { goto exit; // there was a problem } if (waitfor(c, MQTTPACKET_SUBACK, &timer) == MQTTPACKET_SUBACK) // wait for suback { int count = 0, grantedQoS = -1; unsigned short mypacketid; if (mqtt_deserialize_suback(&mypacketid, 1, &count, &grantedQoS, c->readbuf, c->readbuf_size) == 1) rc = grantedQoS; // 0, 1, 2 or 0x80 if (rc != 0x80) { int i; for (i = 0; i < MQTT_MAX_MESSAGE_HANDLERS; ++i) { if (c->messageHandlers[i].topicFilter == 0) { c->messageHandlers[i].topicFilter = topic; c->messageHandlers[i].fp = handler; rc = 0; break; } } } } else rc = MQTT_FAILURE; exit: return rc; } int mqtt_unsubscribe(mqtt_client_t* c, const char* topicFilter) { int rc = MQTT_FAILURE; mqtt_timer_t timer; mqtt_string_t topic = mqtt_string_initializer; topic.cstring = (char *)topicFilter; int len = 0; mqtt_timer_init(&timer); mqtt_timer_countdown_ms(&timer, c->command_timeout_ms); if (!c->isconnected) goto exit; if ((len = mqtt_serialize_unsubscribe(c->buf, c->buf_size, 0, get_next_packet_id(c), 1, &topic)) <= 0) goto exit; if ((rc = send_packet(c, len, &timer)) != MQTT_SUCCESS) // send the subscribe packet goto exit; // there was a problem if (waitfor(c, MQTTPACKET_UNSUBACK, &timer) == MQTTPACKET_UNSUBACK) { unsigned short mypacketid; // should be the same as the packetid above if (mqtt_deserialize_unsuback(&mypacketid, c->readbuf, c->readbuf_size) == 1) rc = 0; } else rc = MQTT_FAILURE; exit: return rc; } int mqtt_publish(mqtt_client_t* c, const char* topic, mqtt_message_t* message) { int rc = MQTT_FAILURE; mqtt_timer_t timer; mqtt_string_t topicStr = mqtt_string_initializer; topicStr.cstring = (char *)topic; int len = 0; mqtt_timer_init(&timer); mqtt_timer_countdown_ms(&timer, c->command_timeout_ms); if (!c->isconnected) goto exit; if (message->qos == MQTT_QOS1 || message->qos == MQTT_QOS2) message->id = get_next_packet_id(c); len = mqtt_serialize_publish(c->buf, c->buf_size, 0, message->qos, message->retained, message->id, topicStr, (unsigned char*)message->payload, message->payloadlen); if (len <= 0) goto exit; if ((rc = send_packet(c, len, &timer)) != MQTT_SUCCESS) // send the subscribe packet { goto exit; // there was a problem } if (message->qos == MQTT_QOS1) { if (waitfor(c, MQTTPACKET_PUBACK, &timer) == MQTTPACKET_PUBACK) { // We still can receive from broker, treat as recoverable c->fail_count = 0; unsigned short mypacketid; unsigned char dup, type; if (mqtt_deserialize_ack(&type, &dup, &mypacketid, c->readbuf, c->readbuf_size) != 1) rc = MQTT_FAILURE; else rc = MQTT_SUCCESS; } else { rc = MQTT_FAILURE; } } else if (message->qos == MQTT_QOS2) { if (waitfor(c, MQTTPACKET_PUBCOMP, &timer) == MQTTPACKET_PUBCOMP) { // We still can receive from broker, treat as recoverable c->fail_count = 0; unsigned short mypacketid; unsigned char dup, type; if (mqtt_deserialize_ack(&type, &dup, &mypacketid, c->readbuf, c->readbuf_size) != 1) rc = MQTT_FAILURE; else rc = MQTT_SUCCESS; } else { rc = MQTT_FAILURE; } } exit: return rc; } int mqtt_disconnect(mqtt_client_t* c) { int rc = MQTT_FAILURE; mqtt_timer_t timer; // we might wait for incomplete incoming publishes to complete int len = mqtt_serialize_disconnect(c->buf, c->buf_size); mqtt_timer_init(&timer); mqtt_timer_countdown_ms(&timer, c->command_timeout_ms); if (len > 0) rc = send_packet(c, len, &timer); // send the disconnect packet c->isconnected = 0; return rc; }