mh
/
mhsw-espurna
forked from mh/espurna-mirror

/*

RFM69 MODULE
Copyright (C) 2016-2017 by Xose Pérez <xose dot perez at gmail dot com>
*/
#include "rfm69.h"

#if RFM69_SUPPORT

#define RFM69_PACKET_SEPARATOR ':'

#include <RFM69.h>
#include <RFM69_ATC.h>
#include <SPI.h>

#include "mqtt.h"
#include "ws.h"

// -----------------------------------------------------------------------------
// Locals
// -----------------------------------------------------------------------------

struct packet_t {    unsigned long messageID;    unsigned char packetID;    unsigned char senderID;    unsigned char targetID;    char * key;    char * value;    int16_t rssi;};
struct _node_t {    unsigned long count = 0;    unsigned long missing = 0;    unsigned long duplicates = 0;    unsigned char lastPacketID = 0;};
_node_t _rfm69_node_info[RFM69_MAX_NODES];unsigned char _rfm69_node_count;unsigned long _rfm69_packet_count;
void _rfm69Clear() {    for(unsigned int i=0; i<RFM69_MAX_NODES; i++) {        _rfm69_node_info[i].duplicates = 0;        _rfm69_node_info[i].missing = 0;        _rfm69_node_info[i].count = 0;    }    _rfm69_node_count = 0;    _rfm69_packet_count = 0;}
// -----------------------------------------------------------------------------

class RFM69Wrap: public RFM69_ATC {
    public:
        RFM69Wrap(uint8_t slaveSelectPin=RF69_SPI_CS, uint8_t interruptPin=RF69_IRQ_PIN, bool isRFM69HW=false):            RFM69_ATC(slaveSelectPin, interruptPin, isRFM69HW) {};
    protected:
        // overriding SPI_CLOCK for ESP8266
        void select() {
            noInterrupts();
            #if defined (SPCR) && defined (SPSR)
                // save current SPI settings
                _SPCR = SPCR;                _SPSR = SPSR;            #endif

            // set RFM69 SPI settings
            SPI.setDataMode(SPI_MODE0);            SPI.setBitOrder(MSBFIRST);
            #if defined(__arm__)
            	SPI.setClockDivider(SPI_CLOCK_DIV16);            #elif defined(ARDUINO_ARCH_ESP8266)
                SPI.setClockDivider(SPI_CLOCK_DIV2); // speeding it up for the ESP8266
            #else
                SPI.setClockDivider(SPI_CLOCK_DIV4);            #endif

            digitalWrite(_slaveSelectPin, LOW);
        }
};
RFM69Wrap * _rfm69_radio;
// -----------------------------------------------------------------------------
// WEB
// -----------------------------------------------------------------------------

#if WEB_SUPPORT

void _rfm69WebSocketOnConnected(JsonObject& root) {
    root["rfm69Visible"] = 1;    root["rfm69Topic"] = getSetting("rfm69Topic", RFM69_DEFAULT_TOPIC);    root["packetCount"] = _rfm69_packet_count;    root["nodeCount"] = _rfm69_node_count;    JsonArray& mappings = root.createNestedArray("mapping");    for (unsigned char i=0; i<RFM69_MAX_TOPICS; i++) {        auto node = getSetting({"node", i}, 0);        if (0 == node) break;        JsonObject& mapping = mappings.createNestedObject();        mapping["node"] = node;        mapping["key"] = getSetting({"key", i});        mapping["topic"] = getSetting({"topic", i});    }
}
bool _rfm69WebSocketOnKeyCheck(const char * key, JsonVariant& value) {    if (strncmp(key, "rfm69", 5) == 0) return true;    if (strncmp(key, "node", 4) == 0) return true;    if (strncmp(key, "key", 3) == 0) return true;    if (strncmp(key, "topic", 5) == 0) return true;    return false;}
void _rfm69WebSocketOnAction(uint32_t client_id, const char * action, JsonObject& data) {    if (strcmp(action, "clear-counts") == 0) _rfm69Clear();}

#endif // WEB_SUPPORT

void _rfm69CleanNodes(unsigned char num) {
    // Look for the last defined node
    unsigned char id = 0;    while (id < num) {        if (0 == getSetting({"node", id}, 0)) break;        if (!getSetting({"key", id}).length()) break;        if (!getSetting({"topic", id}).length()) break;        ++id;    }
    // Delete all other settings
    while (id < SETTINGS_MAX_LIST_COUNT) {        delSetting({"node", id});        delSetting({"key", id});        delSetting({"topic", id});        ++id;    }
}
void _rfm69Configure() {    _rfm69CleanNodes(RFM69_MAX_TOPICS);}
// -----------------------------------------------------------------------------
// Radio
// -----------------------------------------------------------------------------

void _rfm69Debug(const char * level, packet_t * data) {
    DEBUG_MSG_P(        PSTR("[RFM69] %s: messageID:%05d senderID:%03d targetID:%03d packetID:%03d rssi:%-04d key:%s value:%s\n"),        level,        data->messageID,        data->senderID,        data->targetID,        data->packetID,        data->rssi,        data->key,        data->value    );
}
void _rfm69Process(packet_t * data) {
    // Is node beyond RFM69_MAX_NODES?
    if (data->senderID >= RFM69_MAX_NODES) return;
    // Count seen nodes
    if (_rfm69_node_info[data->senderID].count == 0) ++_rfm69_node_count;
    // Detect duplicates and missing packets
    // packetID==0 means device is not sending packetID info
    if (data->packetID > 0) {        if (_rfm69_node_info[data->senderID].count > 0) {
            unsigned char gap = data->packetID - _rfm69_node_info[data->senderID].lastPacketID;
            if (gap == 0) {                _rfm69_node_info[data->senderID].duplicates = _rfm69_node_info[data->senderID].duplicates + 1;                //_rfm69Debug("DUP", data);
                return;            }
            if ((gap > 1) && (data->packetID > 1)) {                _rfm69_node_info[data->senderID].missing = _rfm69_node_info[data->senderID].missing + gap - 1;                DEBUG_MSG_P(PSTR("[RFM69] %u missing packets detected\n"), gap - 1);            }        }
    }
    _rfm69Debug("OK ", data);
    _rfm69_node_info[data->senderID].lastPacketID = data->packetID;    _rfm69_node_info[data->senderID].count = _rfm69_node_info[data->senderID].count + 1;
    // Send info to websocket clients
    {        char buffer[200];        snprintf_P(            buffer,            sizeof(buffer) - 1,            PSTR("{\"nodeCount\": %d, \"packetCount\": %lu, \"packet\": {\"senderID\": %u, \"targetID\": %u, \"packetID\": %u, \"key\": \"%s\", \"value\": \"%s\", \"rssi\": %d, \"duplicates\": %d, \"missing\": %d}}"),            _rfm69_node_count, _rfm69_packet_count,            data->senderID, data->targetID, data->packetID, data->key, data->value, data->rssi,            _rfm69_node_info[data->senderID].duplicates , _rfm69_node_info[data->senderID].missing);        wsSend(buffer);    }
    // If we are the target of the message, forward it via MQTT, otherwise quit
    if (!RFM69_PROMISCUOUS_SENDS && (RFM69_GATEWAY_ID != data->targetID)) return;
    // Try to find a matching mapping
    for (unsigned char i=0; i<RFM69_MAX_TOPICS; i++) {        auto node = getSetting({"node", i}, 0);        if (0 == node) break;        if ((node == data->senderID) && (getSetting({"key", i}).equals(data->key))) {            mqttSendRaw((char *) getSetting({"topic", i}).c_str(), (char *) String(data->value).c_str());            return;        }    }
    // Mapping not found, use default topic
    String topic = getSetting("rfm69Topic", RFM69_DEFAULT_TOPIC);    if (topic.length() > 0) {        topic.replace("{node}", String(data->senderID));        topic.replace("{key}", String(data->key));        mqttSendRaw((char *) topic.c_str(), (char *) String(data->value).c_str());    }
}
void _rfm69Loop() {
    if (_rfm69_radio->receiveDone()) {
        uint8_t senderID = _rfm69_radio->SENDERID;        uint8_t targetID = _rfm69_radio->TARGETID;        int16_t rssi = _rfm69_radio->RSSI;        uint8_t length = _rfm69_radio->DATALEN;        char buffer[length + 1];        strncpy(buffer, (const char *) _rfm69_radio->DATA, length);        buffer[length] = 0;
        // Do not send ACKs in promiscuous mode,
        // we want to listen without being heard
        if (!RFM69_PROMISCUOUS) {            if (_rfm69_radio->ACKRequested()) _rfm69_radio->sendACK();        }
        uint8_t parts = 1;        for (uint8_t i=0; i<length; i++) {            if (buffer[i] == RFM69_PACKET_SEPARATOR) ++parts;        }
        if (parts > 1) {
            char sep[2] = {RFM69_PACKET_SEPARATOR, 0};
            uint8_t packetID = 0;            char * key = strtok(buffer, sep);            char * value = strtok(NULL, sep);            if (parts > 2) {                char * packet = strtok(NULL, sep);                packetID = atoi(packet);            }
            packet_t message;
            message.messageID = ++_rfm69_packet_count;            message.packetID = packetID;            message.senderID = senderID;            message.targetID = targetID;            message.key = key;            message.value = value;            message.rssi = rssi;
            _rfm69Process(&message);
        }
    }
}
// -----------------------------------------------------------------------------
// RFM69
// -----------------------------------------------------------------------------

void rfm69Setup() {
    delay(10);
    _rfm69Configure();
    _rfm69_radio = new RFM69Wrap(RFM69_CS_PIN, RFM69_IRQ_PIN, RFM69_IS_RFM69HW);    _rfm69_radio->initialize(RFM69_FREQUENCY, RFM69_NODE_ID, RFM69_NETWORK_ID);    _rfm69_radio->encrypt(RFM69_ENCRYPTKEY);    _rfm69_radio->spyMode(1 == RFM69_PROMISCUOUS);    _rfm69_radio->enableAutoPower(0);    if (RFM69_IS_RFM69HW) _rfm69_radio->setHighPower();
    DEBUG_MSG_P(PSTR("[RFM69] Working at %u MHz\n"), RFM69_FREQUENCY == RF69_433MHZ ? 433 : RFM69_FREQUENCY == RF69_868MHZ ? 868 : 915);    DEBUG_MSG_P(PSTR("[RFM69] Node %u\n"), RFM69_NODE_ID);    DEBUG_MSG_P(PSTR("[RFM69] Network %u\n"), RFM69_NETWORK_ID);    DEBUG_MSG_P(PSTR("[RFM69] Promiscuous mode %s\n"), RFM69_PROMISCUOUS ? "ON" : "OFF");
    #if WEB_SUPPORT
        wsRegister()            .onConnected(_rfm69WebSocketOnConnected)            .onAction(_rfm69WebSocketOnAction)            .onKeyCheck(_rfm69WebSocketOnKeyCheck);    #endif

    // Main callbacks
    espurnaRegisterLoop(_rfm69Loop);    espurnaRegisterReload(_rfm69Configure);
}
#endif // RFM69_SUPPORT