#include "SX1276.h"
#if !defined(RADIOLIB_EXCLUDE_SX127X)

SX1276::SX1276(Module* mod) : SX1278(mod) {

}

int16_t SX1276::begin(float freq, float bw, uint8_t sf, uint8_t cr, uint8_t syncWord, int8_t power, uint8_t currentLimit, uint16_t preambleLength, uint8_t gain) {
  // execute common part
  int16_t state = SX127x::begin(SX1278_CHIP_VERSION, syncWord, currentLimit, preambleLength);
  RADIOLIB_ASSERT(state);

  // configure settings not accessible by API
  state = config();
  RADIOLIB_ASSERT(state);

  // configure publicly accessible settings
  state = setFrequency(freq);
  RADIOLIB_ASSERT(state);

  state = setBandwidth(bw);
  RADIOLIB_ASSERT(state);

  state = setSpreadingFactor(sf);
  RADIOLIB_ASSERT(state);

  state = setCodingRate(cr);
  RADIOLIB_ASSERT(state);

  state = setOutputPower(power);
  RADIOLIB_ASSERT(state);

  state = setGain(gain);

  return(state);
}

int16_t SX1276::setFrequency(float freq) {
  RADIOLIB_CHECK_RANGE(freq, 137.0, 1020.0, ERR_INVALID_FREQUENCY);

  // SX1276/77/78 Errata fixes
  if(getActiveModem() == SX127X_LORA) {
    // sensitivity optimization for 500kHz bandwidth
    // see SX1276/77/78 Errata, section 2.1 for details
    if(abs(_bw - 500.0) <= 0.001) {
      if((freq >= 862.0) && (freq <= 1020.0)) {
        _mod->SPIwriteRegister(0x36, 0x02);
        _mod->SPIwriteRegister(0x3a, 0x64);
      } else if((freq >= 410.0) && (freq <= 525.0)) {
        _mod->SPIwriteRegister(0x36, 0x02);
        _mod->SPIwriteRegister(0x3a, 0x7F);
      }
    }

    // mitigation of receiver spurious response
    // see SX1276/77/78 Errata, section 2.3 for details
    if(abs(_bw - 7.8) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x48);
      _mod->SPIsetRegValue(0x30, 0x00);
      freq += 7.8;
    } else if(abs(_bw - 10.4) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x44);
      _mod->SPIsetRegValue(0x30, 0x00);
      freq += 10.4;
    } else if(abs(_bw - 15.6) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x44);
      _mod->SPIsetRegValue(0x30, 0x00);
      freq += 15.6;
    } else if(abs(_bw - 20.8) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x44);
      _mod->SPIsetRegValue(0x30, 0x00);
      freq += 20.8;
    } else if(abs(_bw - 31.25) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x44);
      _mod->SPIsetRegValue(0x30, 0x00);
      freq += 31.25;
    } else if(abs(_bw - 41.7) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x44);
      _mod->SPIsetRegValue(0x30, 0x00);
      freq += 41.7;
    } else if(abs(_bw - 62.5) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x40);
      _mod->SPIsetRegValue(0x30, 0x00);
    } else if(abs(_bw - 125.0) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x40);
      _mod->SPIsetRegValue(0x30, 0x00);
    } else if(abs(_bw - 250.0) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b0000000, 7, 7);
      _mod->SPIsetRegValue(0x2F, 0x40);
      _mod->SPIsetRegValue(0x30, 0x00);
    } else if(abs(_bw - 500.0) <= 0.001) {
      _mod->SPIsetRegValue(0x31, 0b1000000, 7, 7);
    }
  }

  // set frequency
  return(SX127x::setFrequencyRaw(freq));
}

#endif