#include #include #include #include #include "ioexpander.hpp" namespace pimoroni { enum reg { CHIP_ID_L = 0xfa, CHIP_ID_H = 0xfb, VERSION = 0xfc, // Rotary encoder ENC_EN = 0x04, // BIT_ENC_EN_1 = 0 // BIT_ENC_MICROSTEP_1 = 1 // BIT_ENC_EN_2 = 2 // BIT_ENC_MICROSTEP_2 = 3 // BIT_ENC_EN_3 = 4 // BIT_ENC_MICROSTEP_3 = 5 // BIT_ENC_EN_4 = 6 // BIT_ENC_MICROSTEP_4 = 7 ENC_1_CFG = 0x05, ENC_1_COUNT = 0x06, ENC_2_CFG = 0x07, ENC_2_COUNT = 0x08, ENC_3_CFG = 0x09, ENC_3_COUNT = 0x0A, ENC_4_CFG = 0x0B, ENC_4_COUNT = 0x0C, // Cap touch CAPTOUCH_EN = 0x0D, CAPTOUCH_CFG = 0x0E, CAPTOUCH_0 = 0x0F, // First of 8 bytes from 15-22 // Switch counters SWITCH_EN_P0 = 0x17, SWITCH_EN_P1 = 0x18, SWITCH_P00 = 0x19, // First of 8 bytes from 25-40 SWITCH_P10 = 0x21, // First of 8 bytes from 33-49 USER_FLASH = 0xD0, FLASH_PAGE = 0xF0, DEBUG = 0xF8, P0 = 0x40, // protect_bits 2 # Bit addressing SP = 0x41, // Read only DPL = 0x42, // Read only DPH = 0x43, // Read only RCTRIM0 = 0x44, // Read only RCTRIM1 = 0x45, // Read only RWK = 0x46, PCON = 0x47, // Read only TCON = 0x48, TMOD = 0x49, TL0 = 0x4a, TL1 = 0x4b, TH0 = 0x4c, TH1 = 0x4d, CKCON = 0x4e, WKCON = 0x4f, // Read only P1 = 0x50, // protect_bits 3 6 # Bit addressing SFRS = 0x51, // TA protected # Read only CAPCON0 = 0x52, CAPCON1 = 0x53, CAPCON2 = 0x54, CKDIV = 0x55, CKSWT = 0x56, // TA protected # Read only CKEN = 0x57, // TA protected # Read only SCON = 0x58, SBUF = 0x59, SBUF_1 = 0x5a, EIE = 0x5b, // Read only EIE1 = 0x5c, // Read only CHPCON = 0x5f, // TA protected # Read only P2 = 0x60, // Bit addressing AUXR1 = 0x62, BODCON0 = 0x63, // TA protected IAPTRG = 0x64, // TA protected # Read only IAPUEN = 0x65, // TA protected # Read only IAPAL = 0x66, // Read only IAPAH = 0x67, // Read only IE = 0x68, // Read only SADDR = 0x69, WDCON = 0x6a, // TA protected BODCON1 = 0x6b, // TA protected P3M1 = 0x6c, P3S = 0xc0, // Page 1 # Reassigned from 0x6c to avoid collision P3M2 = 0x6d, P3SR = 0xc1, // Page 1 # Reassigned from 0x6d to avoid collision IAPFD = 0x6e, // Read only IAPCN = 0x6f, // Read only P3 = 0x70, // Bit addressing P0M1 = 0x71, // protect_bits 2 P0S = 0xc2, // Page 1 # Reassigned from 0x71 to avoid collision P0M2 = 0x72, // protect_bits 2 P0SR = 0xc3, // Page 1 # Reassigned from 0x72 to avoid collision P1M1 = 0x73, // protect_bits 3 6 P1S = 0xc4, // Page 1 # Reassigned from 0x73 to avoid collision P1M2 = 0x74, // protect_bits 3 6 P1SR = 0xc5, // Page 1 # Reassigned from 0x74 to avoid collision P2S = 0x75, IPH = 0x77, // Read only PWMINTC = 0xc6, // Page 1 # Read only # Reassigned from 0x77 to avoid collision IP = 0x78, // Read only SADEN = 0x79, SADEN_1 = 0x7a, SADDR_1 = 0x7b, I2DAT = 0x7c, // Read only I2STAT = 0x7d, // Read only I2CLK = 0x7e, // Read only I2TOC = 0x7f, // Read only I2CON = 0x80, // Read only I2ADDR = 0x81, // Read only ADCRL = 0x82, ADCRH = 0x83, T3CON = 0x84, PWM4H = 0xc7, // Page 1 # Reassigned from 0x84 to avoid collision RL3 = 0x85, PWM5H = 0xc8, // Page 1 # Reassigned from 0x85 to avoid collision RH3 = 0x86, PIOCON1 = 0xc9, // Page 1 # Reassigned from 0x86 to avoid collision TA = 0x87, // Read only T2CON = 0x88, T2MOD = 0x89, RCMP2L = 0x8a, RCMP2H = 0x8b, TL2 = 0x8c, PWM4L = 0xca, // Page 1 # Reassigned from 0x8c to avoid collision TH2 = 0x8d, PWM5L = 0xcb, // Page 1 # Reassigned from 0x8d to avoid collision ADCMPL = 0x8e, ADCMPH = 0x8f, PSW = 0x90, // Read only PWMPH = 0x91, PWM0H = 0x92, PWM1H = 0x93, PWM2H = 0x94, PWM3H = 0x95, PNP = 0x96, FBD = 0x97, PWMCON0 = 0x98, PWMPL = 0x99, PWM0L = 0x9a, PWM1L = 0x9b, PWM2L = 0x9c, PWM3L = 0x9d, PIOCON0 = 0x9e, PWMCON1 = 0x9f, ACC = 0xa0, // Read only ADCCON1 = 0xa1, ADCCON2 = 0xa2, ADCDLY = 0xa3, C0L = 0xa4, C0H = 0xa5, C1L = 0xa6, C1H = 0xa7, ADCCON0 = 0xa8, PICON = 0xa9, // Read only PINEN = 0xaa, // Read only PIPEN = 0xab, // Read only PIF = 0xac, // Read only C2L = 0xad, C2H = 0xae, EIP = 0xaf, // Read only B = 0xb0, // Read only CAPCON3 = 0xb1, CAPCON4 = 0xb2, SPCR = 0xb3, SPCR2 = 0xcc, // Page 1 # Reassigned from 0xb3 to avoid collision SPSR = 0xb4, SPDR = 0xb5, AINDIDS = 0xb6, EIPH = 0xb7, // Read only SCON_1 = 0xb8, PDTEN = 0xb9, // TA protected PDTCNT = 0xba, // TA protected PMEN = 0xbb, PMD = 0xbc, EIP1 = 0xbe, // Read only EIPH1 = 0xbf, // Read only INT = 0xf9, INT_MASK_P0 = 0x00, INT_MASK_P1 = 0x01, INT_MASK_P3 = 0x03, ADDR = 0xfd, CTRL = 0xfe, // 0 = Sleep, 1 = Reset, 2 = Read Flash, 3 = Write Flash, 4 = Addr Unlock }; enum int_mask { TRIG = 0x1, OUT = 0x2, }; enum int_bit { TRIGD = 0, OUT_EN = 1, PIN_SWAP = 2, // 0 = P1.3, 1 = P0.0 }; enum ctrl_mask { SLEEP = 0x1, RESET = 0x2, FREAD = 0x4, FWRITE = 0x8, ADDRWR = 0x10, }; static const uint8_t NUM_BIT_ADDRESSED_REGISTERS = 4; static const uint8_t BIT_ADDRESSED_REGS[NUM_BIT_ADDRESSED_REGISTERS] = {reg::P0, reg::P1, reg::P2, reg::P3}; static const uint8_t ENC_CFG[4] = {reg::ENC_1_CFG, reg::ENC_2_CFG, reg::ENC_3_CFG, reg::ENC_4_CFG}; static const uint8_t ENC_COUNT[4] = {reg::ENC_1_COUNT, reg::ENC_2_COUNT, reg::ENC_3_COUNT, reg::ENC_4_COUNT}; const uint8_t IOExpander::Pin::PxM1[4] = {reg::P0M1, reg::P1M1, (uint8_t)-1, reg::P3M1}; const uint8_t IOExpander::Pin::PxM2[4] = {reg::P0M2, reg::P1M2, (uint8_t)-1, reg::P3M2}; const uint8_t IOExpander::Pin::Px[4] = {reg::P0, reg::P1, (uint8_t)-1, reg::P3}; const uint8_t IOExpander::Pin::PxS[4] = {reg::P0S, reg::P1S, (uint8_t)-1, reg::P3S}; const uint8_t IOExpander::Pin::MASK_P[4] = {reg::INT_MASK_P0, reg::INT_MASK_P1, (uint8_t)-1, reg::INT_MASK_P3}; const uint8_t IOExpander::Pin::PWML[6] = {reg::PWM0L, reg::PWM1L, reg::PWM2L, reg::PWM3L, reg::PWM4L, reg::PWM5L}; const uint8_t IOExpander::Pin::PWMH[6] = {reg::PWM0H, reg::PWM1H, reg::PWM2H, reg::PWM3H, reg::PWM4H, reg::PWM5H}; static const char* MODE_NAMES[3] = {"IO", "PWM", "ADC"}; static const char* GPIO_NAMES[4] = {"QB", "PP", "IN", "OD"}; static const char* STATE_NAMES[2] = {"LOW", "HIGH"}; IOExpander::Pin::Pin(uint8_t port, uint8_t pin) : type(TYPE_IO), mode(0), port(port), pin(pin), adc_channel(0), pwm_channel(0), reg_m1(PxM1[port]), reg_m2(PxM2[port]), reg_p(Px[port]), reg_ps(PxS[port]), reg_int_mask_p(MASK_P[port]), reg_io_pwm(0), reg_pwml(0), reg_pwmh(0) { } IOExpander::Pin::Pin(uint8_t port, uint8_t pin, uint8_t pwm_channel, uint8_t reg_io_pwm) : type(TYPE_PWM), mode(0), port(port), pin(pin), adc_channel(0), pwm_channel(pwm_channel), reg_m1(PxM1[port]), reg_m2(PxM2[port]), reg_p(Px[port]), reg_ps(PxS[port]), reg_int_mask_p(MASK_P[port]), reg_io_pwm(reg_io_pwm), reg_pwml(PWML[pwm_channel]), reg_pwmh(PWMH[pwm_channel]) { } IOExpander::Pin::Pin(uint8_t port, uint8_t pin, uint8_t adc_channel) : type(TYPE_ADC), mode(0), port(port), pin(pin), adc_channel(adc_channel), pwm_channel(0), reg_m1(PxM1[port]), reg_m2(PxM2[port]), reg_p(Px[port]), reg_ps(PxS[port]), reg_int_mask_p(MASK_P[port]), reg_io_pwm(0), reg_pwml(0), reg_pwmh(0) { } IOExpander::Pin::Pin(uint8_t port, uint8_t pin, uint8_t adc_channel, uint8_t pwm_channel, uint8_t reg_io_pwm) : type(TYPE_ADC_OR_PWM), mode(0), port(port), pin(pin), adc_channel(adc_channel), pwm_channel(pwm_channel), reg_m1(PxM1[port]), reg_m2(PxM2[port]), reg_p(Px[port]), reg_ps(PxS[port]), reg_int_mask_p(MASK_P[port]), reg_io_pwm(reg_io_pwm), reg_pwml(PWML[pwm_channel]), reg_pwmh(PWMH[pwm_channel]) { } IOExpander::Pin IOExpander::Pin::io(uint8_t port, uint8_t pin) { return Pin(port, pin); } IOExpander::Pin IOExpander::Pin::pwm(uint8_t port, uint8_t pin, uint8_t channel, uint8_t reg_iopwm) { return Pin(port, pin, channel, reg_iopwm); } IOExpander::Pin IOExpander::Pin::adc(uint8_t port, uint8_t pin, uint8_t channel) { return Pin(port, pin, channel); } IOExpander::Pin IOExpander::Pin::adc_or_pwm(uint8_t port, uint8_t pin, uint8_t adc_channel, uint8_t pwm_channel, uint8_t reg_iopwm) { return Pin(port, pin, adc_channel, pwm_channel, reg_iopwm); } bool IOExpander::Pin::mode_supported(uint8_t mode) { bool supported = false; if((type & TYPE_PWM) && (mode == PIN_MODE_PWM)) { supported = true; } else if((type & TYPE_ADC) && (mode == PIN_MODE_ADC)) { supported = true; } return supported; } IOExpander::Pin::IOType IOExpander::Pin::get_type() { return type; } uint8_t IOExpander::Pin::get_mode() { return mode; } void IOExpander::Pin::set_mode(uint8_t mode) { this->mode = mode; } IOExpander::IOExpander() : IOExpander(new I2C(DEFAULT_SDA_PIN, DEFAULT_SCL_PIN), DEFAULT_I2C_ADDRESS, DEFAULT_INT_PIN, timeout, debug) {}; IOExpander::IOExpander(uint8_t address, uint32_t timeout, bool debug) : IOExpander(new I2C(DEFAULT_SDA_PIN, DEFAULT_SCL_PIN), address, DEFAULT_INT_PIN, timeout, debug) {}; IOExpander::IOExpander(uint8_t address, uint8_t sda, uint8_t scl, uint8_t interrupt, uint32_t timeout, bool debug) : IOExpander(new I2C(sda, scl), address, interrupt, timeout, debug) {}; IOExpander::IOExpander(i2c_inst_t *i2c, uint8_t address, uint8_t sda, uint8_t scl, uint8_t interrupt, uint32_t timeout, bool debug) : IOExpander(new I2C(sda, scl), address, interrupt, timeout, debug) {}; IOExpander::IOExpander(I2C *i2c, uint8_t address, uint8_t interrupt, uint32_t timeout, bool debug) : i2c(i2c), address(address), interrupt(interrupt), timeout(timeout), debug(debug), vref(3.3f), encoder_offset{0,0,0,0}, encoder_last{0,0,0,0}, pins{ Pin::pwm(1, 5, 5, reg::PIOCON1), Pin::pwm(1, 0, 2, reg::PIOCON0), Pin::pwm(1, 2, 0, reg::PIOCON0), Pin::pwm(1, 4, 1, reg::PIOCON1), Pin::pwm(0, 0, 3, reg::PIOCON0), Pin::pwm(0, 1, 4, reg::PIOCON0), Pin::adc_or_pwm(1, 1, 7, 1, reg::PIOCON0), Pin::adc_or_pwm(0, 3, 6, 5, reg::PIOCON0), Pin::adc_or_pwm(0, 4, 5, 3, reg::PIOCON1), Pin::adc(3, 0, 1), Pin::adc(0, 6, 3), Pin::adc_or_pwm(0, 5, 4, 2, reg::PIOCON1), Pin::adc(0, 7, 2), Pin::adc(1, 7, 0)} {} bool IOExpander::init(bool skipChipIdCheck) { bool succeeded = true; if(interrupt != PIN_UNUSED) { gpio_set_function(interrupt, GPIO_FUNC_SIO); gpio_set_dir(interrupt, GPIO_IN); gpio_pull_up(interrupt); enable_interrupt_out(true); } if(!skipChipIdCheck) { uint16_t chip_id = get_chip_id(); if(chip_id != CHIP_ID) { if(debug) { printf("Chip ID invalid: %04x expected: %04x\n", chip_id, CHIP_ID); } succeeded = false; } } return succeeded; } i2c_inst_t* IOExpander::get_i2c() const { return i2c->get_i2c(); } int IOExpander::get_address() const { return address; } int IOExpander::get_sda() const { return i2c->get_sda(); } int IOExpander::get_scl() const { return i2c->get_scl(); } int IOExpander::get_int() const { return interrupt; } uint16_t IOExpander::get_chip_id() { return ((uint16_t)i2c->reg_read_uint8(address, reg::CHIP_ID_H) << 8) | (uint16_t)i2c->reg_read_uint8(address, reg::CHIP_ID_L); } void IOExpander::set_address(uint8_t address) { set_bit(reg::CTRL, 4); i2c->reg_write_uint8(address, reg::ADDR, address); this->address = address; sleep_ms(250); //TODO Handle addr change IOError better //wait_for_flash() clr_bit(reg::CTRL, 4); } float IOExpander::get_adc_vref() { return vref; } void IOExpander::set_adc_vref(float vref) { this->vref = vref; } void IOExpander::enable_interrupt_out(bool pin_swap) { set_bit(reg::INT, int_bit::OUT_EN); change_bit(reg::INT, int_bit::PIN_SWAP, pin_swap); } void IOExpander::disable_interrupt_out() { clr_bit(reg::INT, int_bit::OUT_EN); } bool IOExpander::get_interrupt_flag() { if(interrupt != PIN_UNUSED) return !gpio_get(interrupt); else return (get_bit(reg::INT, int_bit::TRIGD) != 0); } void IOExpander::clear_interrupt_flag() { clr_bit(reg::INT, int_bit::TRIGD); } bool IOExpander::set_pin_interrupt(uint8_t pin, bool enabled) { bool succeeded = false; if(pin >= 1 && pin <= NUM_PINS) { Pin& io_pin = pins[pin - 1]; change_bit(io_pin.reg_int_mask_p, io_pin.pin, enabled); succeeded = true; } return succeeded; } void IOExpander::pwm_load(bool wait_for_load) { // Load new period and duty registers into buffer uint32_t start_time = millis(); set_bit(reg::PWMCON0, 6); // Set the "LOAD" bit of PWMCON0 if(wait_for_load) { while(pwm_loading()) { sleep_ms(1); // Wait for "LOAD" to complete if(millis() - start_time >= timeout) { if(debug) printf("Timed out waiting for PWM load!"); return; } } } } bool IOExpander::pwm_loading() { return get_bit(reg::PWMCON0, 6); } void IOExpander::pwm_clear(bool wait_for_clear) { uint32_t start_time = millis(); set_bit(reg::PWMCON0, 4); // Set the "CLRPWM" bit of PWMCON0 if(wait_for_clear) { while(pwm_clearing()) { sleep_ms(1); // Wait for "CLRPWM" to complete if(millis() - start_time >= timeout) { if(debug) printf("Timed out waiting for PWM clear!"); return; } } } } bool IOExpander::pwm_clearing() { return get_bit(reg::PWMCON0, 4); } bool IOExpander::set_pwm_control(uint8_t divider) { bool divider_good = true; uint8_t pwmdiv2 = 0; switch(divider) { case 1: pwmdiv2 = 0b000; break; case 2: pwmdiv2 = 0b001; break; case 4: pwmdiv2 = 0b010; break; case 8: pwmdiv2 = 0b011; break; case 16: pwmdiv2 = 0b100; break; case 32: pwmdiv2 = 0b101; break; case 64: pwmdiv2 = 0b110; break; case 128: pwmdiv2 = 0b111; break; default: if(debug) { printf("ValueError: A clock divider of %d\n", divider); } divider_good = false; break; } if(divider_good) { //TODO: This currently sets GP, PWMTYP and FBINEN to 0 // It might be desirable to make these available to the user // GP - Group mode enable (changes first three pairs of pAM to PWM01H and PWM01L) // PWMTYP - PWM type select: 0 edge-aligned, 1 center-aligned // FBINEN - Fault-break input enable i2c->reg_write_uint8(address, reg::PWMCON1, pwmdiv2); } return divider_good; } void IOExpander::set_pwm_period(uint16_t value, bool load) { value &= 0xffff; i2c->reg_write_uint8(address, reg::PWMPL, (uint8_t)(value & 0xff)); i2c->reg_write_uint8(address, reg::PWMPH, (uint8_t)(value >> 8)); if(load) pwm_load(); } uint8_t IOExpander::get_mode(uint8_t pin) { if(pin < 1 || pin > NUM_PINS) { printf("ValueError: Pin should be in range 1-14.\n"); return UINT8_MAX; } return pins[pin - 1].get_mode(); } void IOExpander::set_mode(uint8_t pin, uint8_t mode, bool schmitt_trigger, bool invert) { if(pin < 1 || pin > NUM_PINS) { printf("ValueError: Pin should be in range 1-14.\n"); return; } Pin& io_pin = pins[pin - 1]; uint8_t gpio_mode = mode & 0b11; uint8_t io_type = (mode >> 2) & 0b11; uint8_t initial_state = mode >> 4; if(io_pin.get_mode() == mode) { if(debug) { printf("Mode already is %s\n", MODE_NAMES[io_type]); } return; } if((io_type != Pin::TYPE_IO) && !io_pin.mode_supported(mode)) { if(debug) { printf("Pin %d does not support %s!\n", pin, MODE_NAMES[io_type]); } return; } io_pin.set_mode(mode); if(debug) { printf("Setting pin %d to mode %s %s, state: %s\n", pin, MODE_NAMES[io_type], GPIO_NAMES[gpio_mode], STATE_NAMES[initial_state]); } if(mode == PIN_MODE_PWM) { set_bit(io_pin.reg_io_pwm, io_pin.pwm_channel); change_bit(reg::PNP, io_pin.pwm_channel, invert); set_bit(reg::PWMCON0, 7); // Set PWMRUN bit } else { if(io_pin.get_type() & Pin::TYPE_PWM) clr_bit(io_pin.reg_io_pwm, io_pin.pwm_channel); } uint8_t pm1 = i2c->reg_read_uint8(address, io_pin.reg_m1); uint8_t pm2 = i2c->reg_read_uint8(address, io_pin.reg_m2); // Clear the pm1 and pm2 bits pm1 &= 255 - (1 << io_pin.pin); pm2 &= 255 - (1 << io_pin.pin); // Set the new pm1 and pm2 bits according to our gpio_mode pm1 |= (gpio_mode >> 1) << io_pin.pin; pm2 |= (gpio_mode & 0b1) << io_pin.pin; i2c->reg_write_uint8(address, io_pin.reg_m1, pm1); i2c->reg_write_uint8(address, io_pin.reg_m2, pm2); // Set up Schmitt trigger mode on inputs if(mode == PIN_MODE_PU || mode == PIN_MODE_IN) change_bit(io_pin.reg_ps, io_pin.pin, schmitt_trigger); // 5th bit of mode encodes default output pin state i2c->reg_write_uint8(address, io_pin.reg_p, (initial_state << 3) | io_pin.pin); } int16_t IOExpander::input(uint8_t pin, uint32_t adc_timeout) { if(pin < 1 || pin > NUM_PINS) { if(debug) printf("ValueError: Pin should be in range 1-14.\n"); return -1; } Pin& io_pin = pins[pin - 1]; if(io_pin.get_mode() == PIN_MODE_ADC) { if(debug) { printf("Reading ADC from pin %d\n", pin); } clr_bits(reg::ADCCON0, 0x0f); set_bits(reg::ADCCON0, io_pin.adc_channel); i2c->reg_write_uint8(address, reg::AINDIDS, 0); set_bit(reg::AINDIDS, io_pin.adc_channel); set_bit(reg::ADCCON1, 0); clr_bit(reg::ADCCON0, 7); // ADCF - Clear the conversion complete flag set_bit(reg::ADCCON0, 6); // ADCS - Set the ADC conversion start flag // Wait for the ADCF conversion complete flag to be set unsigned long start_time = millis(); while(!get_bit(reg::ADCCON0, 7)) { sleep_ms(10); if(millis() - start_time >= adc_timeout) { if(debug) printf("Timeout waiting for ADC conversion!"); return -1; } } uint8_t hi = i2c->reg_read_uint8(address, reg::ADCRH); uint8_t lo = i2c->reg_read_uint8(address, reg::ADCRL); return (uint16_t)(hi << 4) | (uint16_t)lo; } else { if(debug) { printf("Reading IO from pin %d\n", pin); } uint8_t pv = get_bit(io_pin.reg_p, io_pin.pin); return (pv) ? 1 : 0; } } float IOExpander::input_as_voltage(uint8_t pin, uint32_t adc_timeout) { if(pin < 1 || pin > NUM_PINS) { if(debug) printf("ValueError: Pin should be in range 1-14.\n"); return -1; } Pin& io_pin = pins[pin - 1]; if(io_pin.get_mode() == PIN_MODE_ADC) { if(debug) { printf("Reading ADC from pin %d\n", pin); } clr_bits(reg::ADCCON0, 0x0f); set_bits(reg::ADCCON0, io_pin.adc_channel); i2c->reg_write_uint8(address, reg::AINDIDS, 0); set_bit(reg::AINDIDS, io_pin.adc_channel); set_bit(reg::ADCCON1, 0); clr_bit(reg::ADCCON0, 7); // ADCF - Clear the conversion complete flag set_bit(reg::ADCCON0, 6); // ADCS - Set the ADC conversion start flag // Wait for the ADCF conversion complete flag to be set unsigned long start_time = millis(); while(!get_bit(reg::ADCCON0, 7)) { sleep_ms(1); if(millis() - start_time >= adc_timeout) { if(debug) printf("Timeout waiting for ADC conversion!\n"); return -1; } } uint8_t hi = i2c->reg_read_uint8(address, reg::ADCRH); uint8_t lo = i2c->reg_read_uint8(address, reg::ADCRL); return ((float)((uint16_t)(hi << 4) | (uint16_t)lo) / 4095.0f) * vref; } else { if(debug) { printf("Reading IO from pin %d\n", pin); } uint8_t pv = get_bit(io_pin.reg_p, io_pin.pin); return (pv) ? vref : 0.0f; } } void IOExpander::output(uint8_t pin, uint16_t value, bool load) { if(pin < 1 || pin > NUM_PINS) { printf("Pin should be in range 1-14."); return; } Pin& io_pin = pins[pin - 1]; if(io_pin.get_mode() == PIN_MODE_PWM) { if(debug) { printf("Outputting PWM to pin: %d\n", pin); } i2c->reg_write_uint8(address, io_pin.reg_pwml, (uint8_t)(value & 0xff)); i2c->reg_write_uint8(address, io_pin.reg_pwmh, (uint8_t)(value >> 8)); if(load) pwm_load(); } else { if(value == LOW) { if(debug) { printf("Outputting LOW to pin: %d\n", pin); } clr_bit(io_pin.reg_p, io_pin.pin); } else if(value == HIGH) { if(debug) { printf("Outputting HIGH to pin: %d\n", pin); } set_bit(io_pin.reg_p, io_pin.pin); } } } void IOExpander::setup_rotary_encoder(uint8_t channel, uint8_t pin_a, uint8_t pin_b, uint8_t pin_c, bool count_microsteps) { channel -= 1; set_mode(pin_a, PIN_MODE_PU, true); set_mode(pin_b, PIN_MODE_PU, true); if(pin_c != 0) { set_mode(pin_c, PIN_MODE_OD); output(pin_c, 0); } i2c->reg_write_uint8(address, ENC_CFG[channel], pin_a | (pin_b << 4)); change_bit(reg::ENC_EN, (channel * 2) + 1, count_microsteps); set_bit(reg::ENC_EN, channel * 2); // Reset internal encoder count to zero uint8_t reg = ENC_COUNT[channel]; i2c->reg_write_uint8(address, reg, 0x00); } int16_t IOExpander::read_rotary_encoder(uint8_t channel) { channel -= 1; int16_t last = encoder_last[channel]; uint8_t reg = ENC_COUNT[channel]; int16_t value = (int16_t)i2c->reg_read_uint8(address, reg); if(value & 0b10000000) value -= 256; if(last > 64 && value < -64) encoder_offset[channel] += 256; if(last < -64 && value > 64) encoder_offset[channel] -= 256; encoder_last[channel] = value; return encoder_offset[channel] + value; } uint8_t IOExpander::get_bit(uint8_t reg, uint8_t bit) { // Returns the specified bit (nth position from right) from a register return i2c->reg_read_uint8(address, reg) & (1 << bit); } void IOExpander::set_bits(uint8_t reg, uint8_t bits) { // Set the specified bits (using a mask) in a register. // Deal with special case registers first bool reg_in_bit_addressed_regs = false; for(uint8_t i = 0; i < NUM_BIT_ADDRESSED_REGISTERS; i++) { if(BIT_ADDRESSED_REGS[i] == reg) { for(uint8_t bit = 0; bit < 8; bit++) { if(bits & (1 << bit)) i2c->reg_write_uint8(address, reg, 0b1000 | (bit & 0b111)); } reg_in_bit_addressed_regs = true; break; } } // Now deal with any other registers if(!reg_in_bit_addressed_regs) { uint8_t value = i2c->reg_read_uint8(address, reg); sleep_us(10); i2c->reg_write_uint8(address, reg, value | bits); } } void IOExpander::set_bit(uint8_t reg, uint8_t bit) { // Set the specified bit (nth position from right) in a register. set_bits(reg, (1 << bit)); } void IOExpander::clr_bits(uint8_t reg, uint8_t bits) { bool reg_in_bit_addressed_regs = false; for(uint8_t i = 0; i < NUM_BIT_ADDRESSED_REGISTERS; i++) { if(BIT_ADDRESSED_REGS[i] == reg) { for(uint8_t bit = 0; bit < 8; bit++) { if(bits & (1 << bit)) i2c->reg_write_uint8(address, reg, 0b0000 | (bit & 0b111)); } reg_in_bit_addressed_regs = true; break; } } // Now deal with any other registers if(!reg_in_bit_addressed_regs) { uint8_t value = i2c->reg_read_uint8(address, reg); sleep_us(10); i2c->reg_write_uint8(address, reg, value & ~bits); } } void IOExpander::clr_bit(uint8_t reg, uint8_t bit) { // Clear the specified bit (nth position from right) in a register. clr_bits(reg, (1 << bit)); } void IOExpander::change_bit(uint8_t reg, uint8_t bit, bool state) { // Toggle one register bit on/off. if(state) set_bit(reg, bit); else clr_bit(reg, bit); } void IOExpander::wait_for_flash(void) { // Wait for the IOE to finish writing non-volatile memory. unsigned long start_time = millis(); while(get_interrupt_flag()) { if(millis() - start_time > timeout) { printf("Timed out waiting for interrupt!\n"); return; } sleep_ms(1); } start_time = millis(); while(!get_interrupt_flag()) { if(millis() - start_time > timeout) { printf("Timed out waiting for interrupt!\n"); return; } sleep_ms(1); } } uint32_t IOExpander::millis() { return to_ms_since_boot(get_absolute_time()); } }