JSD
/
TinyGSM_Senseright

/**
 * @file       TinyGsmClientSIM800.h * @author     Volodymyr Shymanskyy * @license    LGPL-3.0 * @copyright  Copyright (c) 2016 Volodymyr Shymanskyy * @date       Nov 2016 */
#ifndef TinyGsmClientSIM800_h
#define TinyGsmClientSIM800_h
//#pragma message("TinyGSM:  TinyGsmClientSIM800")

//#define TINY_GSM_DEBUG Serial
//#define TINY_GSM_USE_HEX

#if !defined(TINY_GSM_RX_BUFFER)
  #define TINY_GSM_RX_BUFFER 64
#endif

#define TINY_GSM_MUX_COUNT 5

#include <TinyGsmCommon.h>

#define GSM_NL "\r\n"
static const char GSM_OK[] TINY_GSM_PROGMEM = "OK" GSM_NL;static const char GSM_ERROR[] TINY_GSM_PROGMEM = "ERROR" GSM_NL;
enum SimStatus {  SIM_ERROR = 0,  SIM_READY = 1,  SIM_LOCKED = 2,};
enum RegStatus {  REG_UNREGISTERED = 0,  REG_SEARCHING    = 2,  REG_DENIED       = 3,  REG_OK_HOME      = 1,  REG_OK_ROAMING   = 5,  REG_UNKNOWN      = 4,};
enum TinyGSMDateTimeFormat {  DATE_FULL = 0,  DATE_TIME = 1,  DATE_DATE = 2};
class TinyGsmSim800{
public:
class GsmClient : public Client{  friend class TinyGsmSim800;  typedef TinyGsmFifo<uint8_t, TINY_GSM_RX_BUFFER> RxFifo;
public:  GsmClient() {}
  GsmClient(TinyGsmSim800& modem, uint8_t mux = 1) {    init(&modem, mux);  }
  bool init(TinyGsmSim800* modem, uint8_t mux = 1) {    this->at = modem;    this->mux = mux;    sock_available = 0;    prev_check = 0;    sock_connected = false;    got_data = false;
    at->sockets[mux] = this;
    return true;  }
public:  virtual int connect(const char *host, uint16_t port, int timeout_s) {    stop();    TINY_GSM_YIELD();    rx.clear();    sock_connected = at->modemConnect(host, port, mux, false, timeout_s);    return sock_connected;  }
TINY_GSM_CLIENT_CONNECT_OVERLOADS()
  virtual void stop(uint32_t maxWaitMs) {    TINY_GSM_CLIENT_DUMP_MODEM_BUFFER()    at->sendAT(GF("+CIPCLOSE="), mux, GF(",1"));  // Quick close
    sock_connected = false;    at->waitResponse();  }
  virtual void stop() { stop(15000L); }
TINY_GSM_CLIENT_WRITE()
TINY_GSM_CLIENT_AVAILABLE_WITH_BUFFER_CHECK()
TINY_GSM_CLIENT_READ_WITH_BUFFER_CHECK()
TINY_GSM_CLIENT_PEEK_FLUSH_CONNECTED()
  /*
   * Extended API   */
  String remoteIP() TINY_GSM_ATTR_NOT_IMPLEMENTED;
private:  TinyGsmSim800*  at;  uint8_t         mux;  uint16_t        sock_available;  uint32_t        prev_check;  bool            sock_connected;  bool            got_data;  RxFifo          rx;};

class GsmClientSecure : public GsmClient{public:  GsmClientSecure() {}
  GsmClientSecure(TinyGsmSim800& modem, uint8_t mux = 1)    : GsmClient(modem, mux)  {}
public:  virtual int connect(const char *host, uint16_t port, int timeout_s) {    stop();    TINY_GSM_YIELD();    rx.clear();    sock_connected = at->modemConnect(host, port, mux, true, timeout_s);    return sock_connected;  }};

public:
  TinyGsmSim800(Stream& stream)    : stream(stream)  {    memset(sockets, 0, sizeof(sockets));  }
  /*
   * Basic functions   */
  bool begin(const char* pin = NULL) {    return init(pin);  }
  bool init(const char* pin = NULL) {    DBG(GF("### TinyGSM Version:"), TINYGSM_VERSION);    if (!testAT()) {      return false;    }    sendAT(GF("&FZ"));  // Factory + Reset
    waitResponse();    sendAT(GF("E0"));   // Echo Off
    if (waitResponse() != 1) {      return false;    }    DBG(GF("### Modem:"), getModemName());    getSimStatus();    return true;  }
  String getModemName() {    String name = "";    #if defined(TINY_GSM_MODEM_SIM800)
      name = "SIMCom SIM800";    #elif defined(TINY_GSM_MODEM_SIM808)
      name = "SIMCom SIM808";    #elif defined(TINY_GSM_MODEM_SIM868)
      name = "SIMCom SIM868";    #elif defined(TINY_GSM_MODEM_SIM900)
      name = "SIMCom SIM900";    #endif

    sendAT(GF("+GMM"));    String res2;    if (waitResponse(1000L, res2) != 1) {      return name;    }    res2.replace(GSM_NL "OK" GSM_NL, "");    res2.replace("_", " ");    res2.trim();
    name = res2;    DBG("### Modem:", name);    return name;  }
TINY_GSM_MODEM_SET_BAUD_IPR()
TINY_GSM_MODEM_TEST_AT()
TINY_GSM_MODEM_MAINTAIN_CHECK_SOCKS()
  bool factoryDefault() {    sendAT(GF("&FZE0&W"));  // Factory + Reset + Echo Off + Write
    waitResponse();    sendAT(GF("+IPR=0"));   // Auto-baud
    waitResponse();    sendAT(GF("+IFC=0,0")); // No Flow Control
    waitResponse();    sendAT(GF("+ICF=3,3")); // 8 data 0 parity 1 stop
    waitResponse();    sendAT(GF("+CSCLK=0")); // Disable Slow Clock
    waitResponse();    sendAT(GF("&W"));       // Write configuration
    return waitResponse() == 1;  }
TINY_GSM_MODEM_GET_INFO_ATI()
  bool hasSSL() {#if defined(TINY_GSM_MODEM_SIM900)
    return false;#else
    sendAT(GF("+CIPSSL=?"));    if (waitResponse(GF(GSM_NL "+CIPSSL:")) != 1) {      return false;    }    return waitResponse() == 1;#endif
  }
  bool hasWifi() {    return false;  }
  bool hasGPRS() {    return true;  }
  /*
   * Power functions   */
  bool restart() {    if (!testAT()) {      return false;    }    //Enable Local Time Stamp for getting network time
    // TODO: Find a better place for this
    sendAT(GF("+CLTS=1"));    if (waitResponse(10000L) != 1) {      return false;    }    sendAT(GF("&W"));    waitResponse();    sendAT(GF("+CFUN=0"));    if (waitResponse(10000L) != 1) {      return false;    }    sendAT(GF("+CFUN=1,1"));    if (waitResponse(10000L) != 1) {      return false;    }    delay(3000);    return init();  }
  bool poweroff() {    sendAT(GF("+CPOWD=1"));    return waitResponse(10000L, GF("NORMAL POWER DOWN")) == 1;  }
  bool radioOff() {    sendAT(GF("+CFUN=0"));    if (waitResponse(10000L) != 1) {      return false;    }    delay(3000);    return true;  }
  /*
    During sleep, the SIM800 module has its serial communication disabled. In order to reestablish communication    pull the DRT-pin of the SIM800 module LOW for at least 50ms. Then use this function to disable sleep mode.    The DTR-pin can then be released again.  */  bool sleepEnable(bool enable = true) {    sendAT(GF("+CSCLK="), enable);    return waitResponse() == 1;  }
  /*
   * SIM card functions   */
TINY_GSM_MODEM_SIM_UNLOCK_CPIN()
TINY_GSM_MODEM_GET_SIMCCID_CCID()
TINY_GSM_MODEM_GET_IMEI_GSN()
  SimStatus getSimStatus(unsigned long timeout_ms = 10000L) {    for (unsigned long start = millis(); millis() - start < timeout_ms; ) {      sendAT(GF("+CPIN?"));      if (waitResponse(GF(GSM_NL "+CPIN:")) != 1) {        delay(1000);        continue;      }      int status = waitResponse(GF("READY"), GF("SIM PIN"), GF("SIM PUK"), GF("NOT INSERTED"), GF("NOT READY"));      waitResponse();      switch (status) {        case 2:        case 3:  return SIM_LOCKED;        case 1:  return SIM_READY;        default: return SIM_ERROR;      }    }    return SIM_ERROR;  }
TINY_GSM_MODEM_GET_REGISTRATION_XREG(CREG)
TINY_GSM_MODEM_GET_OPERATOR_COPS()
  /*
   * Generic network functions   */
TINY_GSM_MODEM_GET_CSQ()
  bool isNetworkConnected() {    RegStatus s = getRegistrationStatus();    return (s == REG_OK_HOME || s == REG_OK_ROAMING);  }
TINY_GSM_MODEM_WAIT_FOR_NETWORK()
  /*
   * GPRS functions   */
  bool gprsConnect(const char* apn, const char* user = NULL, const char* pwd = NULL) {    gprsDisconnect();
    // Set the Bearer for the IP
    sendAT(GF("+SAPBR=3,1,\"Contype\",\"GPRS\""));  // Set the connection type to GPRS
    waitResponse();
    sendAT(GF("+SAPBR=3,1,\"APN\",\""), apn, '"');  // Set the APN
    waitResponse();
    if (user && strlen(user) > 0) {      sendAT(GF("+SAPBR=3,1,\"USER\",\""), user, '"');  // Set the user name
      waitResponse();    }    if (pwd && strlen(pwd) > 0) {      sendAT(GF("+SAPBR=3,1,\"PWD\",\""), pwd, '"');  // Set the password
      waitResponse();    }
    // Define the PDP context
    sendAT(GF("+CGDCONT=1,\"IP\",\""), apn, '"');    waitResponse();
    // Activate the PDP context
    sendAT(GF("+CGACT=1,1"));    waitResponse(60000L);
    // Open the definied GPRS bearer context
    sendAT(GF("+SAPBR=1,1"));    waitResponse(85000L);    // Query the GPRS bearer context status
    sendAT(GF("+SAPBR=2,1"));    if (waitResponse(30000L) != 1)      return false;
    // Attach to GPRS
    sendAT(GF("+CGATT=1"));    if (waitResponse(60000L) != 1)      return false;
    // TODO: wait AT+CGATT?

    // Set to multi-IP
    sendAT(GF("+CIPMUX=1"));    if (waitResponse() != 1) {      return false;    }
    // Put in "quick send" mode (thus no extra "Send OK")
    sendAT(GF("+CIPQSEND=1"));    if (waitResponse() != 1) {      return false;    }
    // Set to get data manually
    sendAT(GF("+CIPRXGET=1"));    if (waitResponse() != 1) {      return false;    }
    // Start Task and Set APN, USER NAME, PASSWORD
    sendAT(GF("+CSTT=\""), apn, GF("\",\""), user, GF("\",\""), pwd, GF("\""));    if (waitResponse(60000L) != 1) {      return false;    }
    // Bring Up Wireless Connection with GPRS or CSD
    sendAT(GF("+CIICR"));    if (waitResponse(60000L) != 1) {      return false;    }
    // Get Local IP Address, only assigned after connection
    sendAT(GF("+CIFSR;E0"));    if (waitResponse(10000L) != 1) {      return false;    }
    // Configure Domain Name Server (DNS)
    sendAT(GF("+CDNSCFG=\"8.8.8.8\",\"8.8.4.4\""));    if (waitResponse() != 1) {      return false;    }
    return true;  }
  bool gprsDisconnect() {    // Shut the TCP/IP connection
    // CIPSHUT will close *all* open connections
    sendAT(GF("+CIPSHUT"));    if (waitResponse(60000L) != 1)      return false;
    sendAT(GF("+CGATT=0"));  // Deactivate the bearer context
    if (waitResponse(60000L) != 1)      return false;
    return true;  }
  bool isGprsConnected() {    sendAT(GF("+CGATT?"));    if (waitResponse(GF(GSM_NL "+CGATT:")) != 1) {      return false;    }    int res = stream.readStringUntil('\n').toInt();    waitResponse();    if (res != 1)      return false;
    sendAT(GF("+CIFSR;E0")); // Another option is to use AT+CGPADDR=1
    if (waitResponse() != 1)      return false;
    return true;  }
  /*
   * IP Address functions   */
  String getLocalIP() {    sendAT(GF("+CIFSR;E0"));    String res;    if (waitResponse(10000L, res) != 1) {      return "";    }    res.replace(GSM_NL "OK" GSM_NL, "");    res.replace(GSM_NL, "");    res.trim();    return res;  }
  IPAddress localIP() {    return TinyGsmIpFromString(getLocalIP());  }
  /*
   * Phone Call functions   */
  bool setGsmBusy(bool busy = true) {    sendAT(GF("+GSMBUSY="), busy ? 1 : 0);    return waitResponse() == 1;  }
  bool callAnswer() {    sendAT(GF("A"));    return waitResponse() == 1;  }
  // Returns true on pick-up, false on error/busy
  bool callNumber(const String& number) {    if (number == GF("last")) {      sendAT(GF("DL"));    } else {      sendAT(GF("D"), number, ";");    }    int status = waitResponse(60000L,                              GFP(GSM_OK),                              GF("BUSY" GSM_NL),                              GF("NO ANSWER" GSM_NL),                              GF("NO CARRIER" GSM_NL));    switch (status) {    case 1:  return true;    case 2:    case 3:  return false;    default: return false;    }  }
  bool callHangup() {    sendAT(GF("H"));    return waitResponse() == 1;  }
  // 0-9,*,#,A,B,C,D
  bool dtmfSend(char cmd, int duration_ms = 100) {    duration_ms = constrain(duration_ms, 100, 1000);
    sendAT(GF("+VTD="), duration_ms / 100); // VTD accepts in 1/10 of a second
    waitResponse();
    sendAT(GF("+VTS="), cmd);    return waitResponse(10000L) == 1;  }
  /*
   * Messaging functions   */
  String sendUSSD(const String& code) {    sendAT(GF("+CMGF=1"));    waitResponse();    sendAT(GF("+CSCS=\"HEX\""));    waitResponse();    sendAT(GF("+CUSD=1,\""), code, GF("\""));    if (waitResponse() != 1) {      return "";    }    if (waitResponse(10000L, GF(GSM_NL "+CUSD:")) != 1) {      return "";    }    stream.readStringUntil('"');    String hex = stream.readStringUntil('"');    stream.readStringUntil(',');    int dcs = stream.readStringUntil('\n').toInt();
    if (dcs == 15) {      return TinyGsmDecodeHex8bit(hex);    } else if (dcs == 72) {      return TinyGsmDecodeHex16bit(hex);    } else {      return hex;    }  }
  bool sendSMS(const String& number, const String& text) {    sendAT(GF("+CMGF=1"));    waitResponse();    //Set GSM 7 bit default alphabet (3GPP TS 23.038)
    sendAT(GF("+CSCS=\"GSM\""));    waitResponse();    sendAT(GF("+CMGS=\""), number, GF("\""));    if (waitResponse(GF(">")) != 1) {      return false;    }    stream.print(text);    stream.write((char)0x1A);    stream.flush();    return waitResponse(60000L) == 1;  }
  bool sendSMS_UTF16(const String& number, const void* text, size_t len) {    sendAT(GF("+CMGF=1"));    waitResponse();    sendAT(GF("+CSCS=\"HEX\""));    waitResponse();    sendAT(GF("+CSMP=17,167,0,8"));    waitResponse();
    sendAT(GF("+CMGS=\""), number, GF("\""));    if (waitResponse(GF(">")) != 1) {      return false;    }
    uint16_t* t = (uint16_t*)text;    for (size_t i=0; i<len; i++) {      uint8_t c = t[i] >> 8;      if (c < 0x10) { stream.print('0'); }      stream.print(c, HEX);      c = t[i] & 0xFF;      if (c < 0x10) { stream.print('0'); }      stream.print(c, HEX);    }    stream.write((char)0x1A);    stream.flush();    return waitResponse(60000L) == 1;  }

  /*
   * Location functions   */
  String getGsmLocation() {    sendAT(GF("+CIPGSMLOC=1,1"));    if (waitResponse(10000L, GF(GSM_NL "+CIPGSMLOC:")) != 1) {      return "";    }    String res = stream.readStringUntil('\n');    waitResponse();    res.trim();    return res;  }
  /*
   * Time functions   */
  String getGSMDateTime(TinyGSMDateTimeFormat format) {    sendAT(GF("+CCLK?"));    if (waitResponse(2000L, GF(GSM_NL "+CCLK: \"")) != 1) {      return "";    }
    String res;
    switch(format) {      case DATE_FULL:        res = stream.readStringUntil('"');      break;      case DATE_TIME:        streamSkipUntil(',');        res = stream.readStringUntil('"');      break;      case DATE_DATE:        res = stream.readStringUntil(',');      break;    }    return res;  }
  /*
   * Battery & temperature functions   */
  // Use: float vBatt = modem.getBattVoltage() / 1000.0;
  uint16_t getBattVoltage() {    sendAT(GF("+CBC"));    if (waitResponse(GF(GSM_NL "+CBC:")) != 1) {      return 0;    }    streamSkipUntil(','); // Skip battery charge status
    streamSkipUntil(','); // Skip battery charge level
    // return voltage in mV
    uint16_t res = stream.readStringUntil(',').toInt();    // Wait for final OK
    waitResponse();    return res;  }
  int8_t getBattPercent() {    sendAT(GF("+CBC"));    if (waitResponse(GF(GSM_NL "+CBC:")) != 1) {      return false;    }    streamSkipUntil(','); // Skip battery charge status
    // Read battery charge level
    int res = stream.readStringUntil(',').toInt();    // Wait for final OK
    waitResponse();    return res;  }
  uint8_t getBattChargeState() {    sendAT(GF("+CBC?"));    if (waitResponse(GF(GSM_NL "+CBC:")) != 1) {      return false;    }    // Read battery charge status
    int res = stream.readStringUntil(',').toInt();    // Wait for final OK
    waitResponse();    return res;  }
  bool getBattStats(uint8_t &chargeState, int8_t &percent, uint16_t &milliVolts) {    sendAT(GF("+CBC?"));    if (waitResponse(GF(GSM_NL "+CBC:")) != 1) {      return false;    }    chargeState = stream.readStringUntil(',').toInt();    percent = stream.readStringUntil(',').toInt();    milliVolts = stream.readStringUntil('\n').toInt();    // Wait for final OK
    waitResponse();    return true;  }
  /*
   * NTP server functions   */  boolean isValidNumber(String str) {    boolean isNum = false;    if(!(str.charAt(0) == '+' || str.charAt(0) == '-' || isDigit(str.charAt(0)))) return false;
    for(byte i=1;i < str.length(); i++) {      if(!(isDigit(str.charAt(i)) || str.charAt(i) == '.')) return false;    }    return true;  }
  String ShowNTPError(byte error) {    switch (error) {      case 1:        return "Network time synchronization is successful";      case 61:        return "Network error";      case 62:        return "DNS resolution error";      case 63:        return "Connection error";      case 64:        return "Service response error";      case 65:        return "Service response timeout";      default:        return "Unknown error: " + String(error);    }  }
  byte NTPServerSync(String server = "pool.ntp.org", byte TimeZone = 3) {    //Serial.println("Sync time with NTP server.");
    sendAT(GF("+CNTPCID=1"));    if (waitResponse(10000L) != 1) {        return -1;    }
    sendAT(GF("+CNTP="), server, ',', String(TimeZone));    if (waitResponse(10000L) != 1) {        return -1;    }
    sendAT(GF("+CNTP"));    if (waitResponse(10000L, GF(GSM_NL "+CNTP:"))) {        String result = stream.readStringUntil('\n');        result.trim();        if (isValidNumber(result))        {          return result.toInt();        }    }    else {      return -1;    }    return -1;  }
  float getTemperature() TINY_GSM_ATTR_NOT_AVAILABLE;
  /*
   * Client related functions   */
protected:
  bool modemConnect(const char* host, uint16_t port, uint8_t mux,                    bool ssl = false, int timeout_s = 75) {    int rsp;    uint32_t timeout_ms = ((uint32_t)timeout_s)*1000;#if !defined(TINY_GSM_MODEM_SIM900)
    sendAT(GF("+CIPSSL="), ssl);    rsp = waitResponse();    if (ssl && rsp != 1) {      return false;    }#endif
    sendAT(GF("+CIPSTART="), mux, ',', GF("\"TCP"), GF("\",\""), host, GF("\","), port);    rsp = waitResponse(timeout_ms,                       GF("CONNECT OK" GSM_NL),                       GF("CONNECT FAIL" GSM_NL),                       GF("ALREADY CONNECT" GSM_NL),                       GF("ERROR" GSM_NL),                       GF("CLOSE OK" GSM_NL)   // Happens when HTTPS handshake fails
                      );    return (1 == rsp);  }
  int16_t modemSend(const void* buff, size_t len, uint8_t mux) {    sendAT(GF("+CIPSEND="), mux, ',', len);    if (waitResponse(GF(">")) != 1) {      return 0;    }    stream.write((uint8_t*)buff, len);    stream.flush();    if (waitResponse(GF(GSM_NL "DATA ACCEPT:")) != 1) {      return 0;    }    streamSkipUntil(','); // Skip mux
    return stream.readStringUntil('\n').toInt();  }
  size_t modemRead(size_t size, uint8_t mux) {#ifdef TINY_GSM_USE_HEX
    sendAT(GF("+CIPRXGET=3,"), mux, ',', size);    if (waitResponse(GF("+CIPRXGET:")) != 1) {      return 0;    }#else
    sendAT(GF("+CIPRXGET=2,"), mux, ',', size);    if (waitResponse(GF("+CIPRXGET:")) != 1) {      return 0;    }#endif
    streamSkipUntil(','); // Skip Rx mode 2/normal or 3/HEX
    streamSkipUntil(','); // Skip mux
    size_t len_requested = stream.readStringUntil(',').toInt();    //  ^^ Requested number of data bytes (1-1460 bytes)to be read
    size_t len_confirmed = stream.readStringUntil('\n').toInt();    // ^^ Confirmed number of data bytes to be read, which may be less than requested.
    // 0 indicates that no data can be read.
    // This is actually be the number of bytes that will be remaining after the read
    for (size_t i=0; i<len_requested; i++) {      uint32_t startMillis = millis();#ifdef TINY_GSM_USE_HEX
      while (stream.available() < 2 && (millis() - startMillis < sockets[mux]->_timeout)) { TINY_GSM_YIELD(); }      char buf[4] = { 0, };      buf[0] = stream.read();      buf[1] = stream.read();      char c = strtol(buf, NULL, 16);#else
      while (!stream.available() && (millis() - startMillis < sockets[mux]->_timeout)) { TINY_GSM_YIELD(); }      char c = stream.read();#endif
      sockets[mux]->rx.put(c);    }    DBG("### READ:", len_requested, "from", mux);    // sockets[mux]->sock_available = modemGetAvailable(mux);
    sockets[mux]->sock_available = len_confirmed;    waitResponse();    return len_requested;  }
  size_t modemGetAvailable(uint8_t mux) {    sendAT(GF("+CIPRXGET=4,"), mux);    size_t result = 0;    if (waitResponse(GF("+CIPRXGET:")) == 1) {      streamSkipUntil(','); // Skip mode 4
      streamSkipUntil(','); // Skip mux
      result = stream.readStringUntil('\n').toInt();      waitResponse();    }    DBG("### Available:", result, "on", mux);    if (!result) {      sockets[mux]->sock_connected = modemGetConnected(mux);    }    return result;  }
  bool modemGetConnected(uint8_t mux) {    sendAT(GF("+CIPSTATUS="), mux);    waitResponse(GF("+CIPSTATUS"));    int res = waitResponse(GF(",\"CONNECTED\""), GF(",\"CLOSED\""), GF(",\"CLOSING\""),                           GF(",\"REMOTE CLOSING\""), GF(",\"INITIAL\""));    waitResponse();    return 1 == res;  }
public:
  /*
   Utilities   */
TINY_GSM_MODEM_STREAM_UTILITIES()
  // TODO: Optimize this!
  uint8_t waitResponse(uint32_t timeout_ms, String& data,                       GsmConstStr r1=GFP(GSM_OK), GsmConstStr r2=GFP(GSM_ERROR),                       GsmConstStr r3=NULL, GsmConstStr r4=NULL, GsmConstStr r5=NULL)  {    /*String r1s(r1); r1s.trim();
    String r2s(r2); r2s.trim();    String r3s(r3); r3s.trim();    String r4s(r4); r4s.trim();    String r5s(r5); r5s.trim();    DBG("### ..:", r1s, ",", r2s, ",", r3s, ",", r4s, ",", r5s);*/    data.reserve(64);    int index = 0;    unsigned long startMillis = millis();    do {      TINY_GSM_YIELD();      while (stream.available() > 0) {        int a = stream.read();        if (a <= 0) continue; // Skip 0x00 bytes, just in case
        data += (char)a;        if (r1 && data.endsWith(r1)) {          index = 1;          goto finish;        } else if (r2 && data.endsWith(r2)) {          index = 2;          goto finish;        } else if (r3 && data.endsWith(r3)) {          index = 3;          goto finish;        } else if (r4 && data.endsWith(r4)) {          index = 4;          goto finish;        } else if (r5 && data.endsWith(r5)) {          index = 5;          goto finish;        } else if (data.endsWith(GF(GSM_NL "+CIPRXGET:"))) {          String mode = stream.readStringUntil(',');          if (mode.toInt() == 1) {            int mux = stream.readStringUntil('\n').toInt();            if (mux >= 0 && mux < TINY_GSM_MUX_COUNT && sockets[mux]) {              sockets[mux]->got_data = true;            }            data = "";            DBG("### Got Data:", mux);          } else {            data += mode;          }        } else if (data.endsWith(GF(GSM_NL "+RECEIVE:"))) {          int mux = stream.readStringUntil(',').toInt();          int len = stream.readStringUntil('\n').toInt();          if (mux >= 0 && mux < TINY_GSM_MUX_COUNT && sockets[mux]) {            sockets[mux]->got_data = true;            sockets[mux]->sock_available = len;          }          data = "";          DBG("### Got Data:", len, "on", mux);        } else if (data.endsWith(GF("CLOSED" GSM_NL))) {          int nl = data.lastIndexOf(GSM_NL, data.length()-8);          int coma = data.indexOf(',', nl+2);          int mux = data.substring(nl+2, coma).toInt();          if (mux >= 0 && mux < TINY_GSM_MUX_COUNT && sockets[mux]) {            sockets[mux]->sock_connected = false;          }          data = "";          DBG("### Closed: ", mux);        }      }    } while (millis() - startMillis < timeout_ms);finish:    if (!index) {      data.trim();      if (data.length()) {        DBG("### Unhandled:", data);      }      data = "";    }    //data.replace(GSM_NL, "/");
    //DBG('<', index, '>', data);
    return index;  }
  uint8_t waitResponse(uint32_t timeout_ms,                       GsmConstStr r1=GFP(GSM_OK), GsmConstStr r2=GFP(GSM_ERROR),                       GsmConstStr r3=NULL, GsmConstStr r4=NULL, GsmConstStr r5=NULL)  {    String data;    return waitResponse(timeout_ms, data, r1, r2, r3, r4, r5);  }
  uint8_t waitResponse(GsmConstStr r1=GFP(GSM_OK), GsmConstStr r2=GFP(GSM_ERROR),                       GsmConstStr r3=NULL, GsmConstStr r4=NULL, GsmConstStr r5=NULL)  {    return waitResponse(1000, r1, r2, r3, r4, r5);  }
public:  Stream&       stream;
protected:  GsmClient*    sockets[TINY_GSM_MUX_COUNT];};
#endif