//
// Copyright 2010-2012,2015,2016 Ettus Research LLC
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//

#include "codec_ctrl.hpp"
#include "usrp1_iface.hpp"
#include "usrp1_impl.hpp"
#include <uhd/types/dict.hpp>
#include <uhd/usrp/dboard_iface.hpp>
#include <uhd/utils/assert_has.hpp>
#include <boost/assign/list_of.hpp>
#include <iostream>

#define FR_OE_0 5
#define FR_OE_1 6
#define FR_OE_2 7
#define FR_OE_3 8

#define FR_ATR_MASK_0 20
#define FR_ATR_TXVAL_0 21
#define FR_ATR_RXVAL_0 22

#define FR_ATR_MASK_1 23
#define FR_ATR_TXVAL_1 24
#define FR_ATR_RXVAL_1 25

#define FR_ATR_MASK_2 26
#define FR_ATR_TXVAL_2 27
#define FR_ATR_RXVAL_2 28

#define FR_ATR_MASK_3 29
#define FR_ATR_TXVAL_3 30
#define FR_ATR_RXVAL_3 31

#define FR_RX_A_REFCLK 41
#define FR_RX_B_REFCLK 43

// i/o registers for pins that go to daughterboards.
// top 16 is a mask, low 16 is value

#define FR_IO_0 9 // slot 0
#define FR_IO_1 10
#define FR_IO_2 11
#define FR_IO_3 12
#define SPI_ENABLE_TX_A 0x10 // select d'board TX A
#define SPI_ENABLE_RX_A 0x20 // select d'board RX A
#define SPI_ENABLE_TX_B 0x40 // select d'board TX B
#define SPI_ENABLE_RX_B 0x80 // select d'board RX B


using namespace uhd;
using namespace uhd::usrp;
using namespace uhd::usrp::gpio_atr;
using namespace boost::assign;

static const dboard_id_t tvrx_id(0x0040);

class usrp1_dboard_iface : public dboard_iface
{
public:
    usrp1_dboard_iface(usrp1_iface::sptr iface,
        usrp1_codec_ctrl::sptr codec,
        usrp1_impl::dboard_slot_t dboard_slot,
        const double& master_clock_rate,
        const dboard_id_t& rx_dboard_id)
        : _dboard_slot(dboard_slot)
        , _master_clock_rate(master_clock_rate)
        , _rx_dboard_id(rx_dboard_id)
    {
        _iface = iface;
        _codec = codec;

        _dbsrx_classic_div = 1;

        // yes this is evil but it's necessary for TVRX to work on USRP1
        if (_rx_dboard_id == tvrx_id)
            _codec->bypass_adc_buffers(false);
        // else _codec->bypass_adc_buffers(false); //don't think this is necessary
    }

    ~usrp1_dboard_iface()
    {
        /* NOP */
    }

    special_props_t get_special_props()
    {
        special_props_t props;
        props.soft_clock_divider = true;
        props.mangle_i2c_addrs   = (_dboard_slot == usrp1_impl::DBOARD_SLOT_B);
        return props;
    }

    void write_aux_dac(unit_t, aux_dac_t, double);
    double read_aux_adc(unit_t, aux_adc_t);

    void set_pin_ctrl(unit_t unit, uint32_t value, uint32_t mask = 0xffffffff);
    uint32_t get_pin_ctrl(unit_t unit);
    void set_atr_reg(
        unit_t unit, atr_reg_t reg, uint32_t value, uint32_t mask = 0xffffffff);
    uint32_t get_atr_reg(unit_t unit, atr_reg_t reg);
    void set_gpio_ddr(unit_t unit, uint32_t value, uint32_t mask = 0xffffffff);
    uint32_t get_gpio_ddr(unit_t unit);
    void set_gpio_out(unit_t unit, uint32_t value, uint32_t mask = 0xffffffff);
    uint32_t get_gpio_out(unit_t unit);
    uint32_t read_gpio(unit_t unit);

    void _set_pin_ctrl(unit_t, uint16_t);
    void _set_atr_reg(unit_t, atr_reg_t, uint16_t);
    void _set_gpio_ddr(unit_t, uint16_t);
    void _set_gpio_out(unit_t, uint16_t);

    void set_command_time(const uhd::time_spec_t& t);
    uhd::time_spec_t get_command_time(void);

    void write_i2c(uint16_t, const byte_vector_t&);
    byte_vector_t read_i2c(uint16_t, size_t);

    void write_spi(
        unit_t unit, const spi_config_t& config, uint32_t data, size_t num_bits);

    uint32_t read_write_spi(
        unit_t unit, const spi_config_t& config, uint32_t data, size_t num_bits);

    void set_clock_rate(unit_t, double);
    std::vector<double> get_clock_rates(unit_t);
    double get_clock_rate(unit_t);
    void set_clock_enabled(unit_t, bool);
    double get_codec_rate(unit_t);
    void set_fe_connection(
        unit_t unit, const std::string&, const fe_connection_t& fe_conn);

private:
    usrp1_iface::sptr _iface;
    usrp1_codec_ctrl::sptr _codec;
    unsigned _dbsrx_classic_div;
    const usrp1_impl::dboard_slot_t _dboard_slot;
    const double& _master_clock_rate;
    const dboard_id_t _rx_dboard_id;
    uhd::dict<unit_t, uint16_t> _pin_ctrl, _gpio_out, _gpio_ddr;
    uhd::dict<unit_t, uhd::dict<atr_reg_t, uint16_t>> _atr_regs;
};

/***********************************************************************
 * Make Function
 **********************************************************************/
dboard_iface::sptr usrp1_impl::make_dboard_iface(usrp1_iface::sptr iface,
    usrp1_codec_ctrl::sptr codec,
    usrp1_impl::dboard_slot_t dboard_slot,
    const double& master_clock_rate,
    const dboard_id_t& rx_dboard_id)
{
    return dboard_iface::sptr(new usrp1_dboard_iface(
        iface, codec, dboard_slot, master_clock_rate, rx_dboard_id));
}

/***********************************************************************
 * Clock Rates
 **********************************************************************/
static const dboard_id_t dbsrx_classic_id(0x0002);

/*
 * Daughterboard reference clock register
 *
 * Bit  7    - 1 turns on refclk, 0 allows IO use
 * Bits 6:0  - Divider value
 */
void usrp1_dboard_iface::set_clock_rate(unit_t unit, double rate)
{
    assert_has(this->get_clock_rates(unit), rate, "dboard clock rate");

    if (unit == UNIT_RX && _rx_dboard_id == dbsrx_classic_id) {
        _dbsrx_classic_div = size_t(_master_clock_rate / rate);
        switch (_dboard_slot) {
            case usrp1_impl::DBOARD_SLOT_A:
                _iface->poke32(FR_RX_A_REFCLK, (_dbsrx_classic_div & 0x7f) | 0x80);
                break;

            case usrp1_impl::DBOARD_SLOT_B:
                _iface->poke32(FR_RX_B_REFCLK, (_dbsrx_classic_div & 0x7f) | 0x80);
                break;
        }
    }
}

std::vector<double> usrp1_dboard_iface::get_clock_rates(unit_t unit)
{
    std::vector<double> rates;
    if (unit == UNIT_RX && _rx_dboard_id == dbsrx_classic_id) {
        for (size_t div = 1; div <= 127; div++)
            rates.push_back(_master_clock_rate / div);
    } else {
        rates.push_back(_master_clock_rate);
    }
    return rates;
}

double usrp1_dboard_iface::get_clock_rate(unit_t unit)
{
    if (unit == UNIT_RX && _rx_dboard_id == dbsrx_classic_id) {
        return _master_clock_rate / _dbsrx_classic_div;
    }
    return _master_clock_rate;
}

void usrp1_dboard_iface::set_clock_enabled(unit_t, bool)
{
    // TODO we can only enable for special case anyway...
}

double usrp1_dboard_iface::get_codec_rate(unit_t)
{
    return _master_clock_rate;
}

/***********************************************************************
 * GPIO
 **********************************************************************/
template <typename T>
static T shadow_it(T& shadow, const T& value, const T& mask)
{
    shadow = (shadow & ~mask) | (value & mask);
    return shadow;
}

void usrp1_dboard_iface::set_pin_ctrl(unit_t unit, uint32_t value, uint32_t mask)
{
    _set_pin_ctrl(unit,
        shadow_it(
            _pin_ctrl[unit], static_cast<uint16_t>(value), static_cast<uint16_t>(mask)));
}

uint32_t usrp1_dboard_iface::get_pin_ctrl(unit_t unit)
{
    return _pin_ctrl[unit];
}

void usrp1_dboard_iface::set_atr_reg(
    unit_t unit, atr_reg_t reg, uint32_t value, uint32_t mask)
{
    _set_atr_reg(unit,
        reg,
        shadow_it(_atr_regs[unit][reg],
            static_cast<uint16_t>(value),
            static_cast<uint16_t>(mask)));
}

uint32_t usrp1_dboard_iface::get_atr_reg(unit_t unit, atr_reg_t reg)
{
    return _atr_regs[unit][reg];
}

void usrp1_dboard_iface::set_gpio_ddr(unit_t unit, uint32_t value, uint32_t mask)
{
    _set_gpio_ddr(unit,
        shadow_it(
            _gpio_ddr[unit], static_cast<uint16_t>(value), static_cast<uint16_t>(mask)));
}

uint32_t usrp1_dboard_iface::get_gpio_ddr(unit_t unit)
{
    return _gpio_ddr[unit];
}

void usrp1_dboard_iface::set_gpio_out(unit_t unit, uint32_t value, uint32_t mask)
{
    _set_gpio_out(unit,
        shadow_it(
            _gpio_out[unit], static_cast<uint16_t>(value), static_cast<uint16_t>(mask)));
}

uint32_t usrp1_dboard_iface::get_gpio_out(unit_t unit)
{
    return _gpio_out[unit];
}

uint32_t usrp1_dboard_iface::read_gpio(unit_t unit)
{
    uint32_t out_value;

    if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
        out_value = _iface->peek32(1);
    else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
        out_value = _iface->peek32(2);
    else
        UHD_THROW_INVALID_CODE_PATH();

    switch (unit) {
        case UNIT_RX:
            return (uint32_t)((out_value >> 16) & 0x0000ffff);
        case UNIT_TX:
            return (uint32_t)((out_value >> 0) & 0x0000ffff);
        default:
            UHD_THROW_INVALID_CODE_PATH();
    }
    UHD_ASSERT_THROW(false);
}

void usrp1_dboard_iface::_set_pin_ctrl(unit_t unit, uint16_t value)
{
    switch (unit) {
        case UNIT_RX:
            if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                _iface->poke32(FR_ATR_MASK_1, value);
            else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                _iface->poke32(FR_ATR_MASK_3, value);
            break;
        case UNIT_TX:
            if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                _iface->poke32(FR_ATR_MASK_0, value);
            else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                _iface->poke32(FR_ATR_MASK_2, value);
            break;
        default:
            UHD_THROW_INVALID_CODE_PATH();
    }
}

void usrp1_dboard_iface::_set_gpio_ddr(unit_t unit, uint16_t value)
{
    switch (unit) {
        case UNIT_RX:
            if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                _iface->poke32(FR_OE_1, 0xffff0000 | value);
            else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                _iface->poke32(FR_OE_3, 0xffff0000 | value);
            break;
        case UNIT_TX:
            if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                _iface->poke32(FR_OE_0, 0xffff0000 | value);
            else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                _iface->poke32(FR_OE_2, 0xffff0000 | value);
            break;
        default:
            UHD_THROW_INVALID_CODE_PATH();
    }
}

void usrp1_dboard_iface::_set_gpio_out(unit_t unit, uint16_t value)
{
    switch (unit) {
        case UNIT_RX:
            if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                _iface->poke32(FR_IO_1, 0xffff0000 | value);
            else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                _iface->poke32(FR_IO_3, 0xffff0000 | value);
            break;
        case UNIT_TX:
            if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                _iface->poke32(FR_IO_0, 0xffff0000 | value);
            else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                _iface->poke32(FR_IO_2, 0xffff0000 | value);
            break;
        default:
            UHD_THROW_INVALID_CODE_PATH();
    }
}

void usrp1_dboard_iface::_set_atr_reg(unit_t unit, atr_reg_t atr, uint16_t value)
{
    // Ignore unsupported states
    if ((atr == ATR_REG_IDLE) || (atr == ATR_REG_TX_ONLY))
        return;
    if (atr == ATR_REG_RX_ONLY) {
        switch (unit) {
            case UNIT_RX:
                if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                    _iface->poke32(FR_ATR_RXVAL_1, value);
                else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                    _iface->poke32(FR_ATR_RXVAL_3, value);
                break;
            case UNIT_TX:
                if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                    _iface->poke32(FR_ATR_RXVAL_0, value);
                else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                    _iface->poke32(FR_ATR_RXVAL_2, value);
                break;
            default:
                UHD_THROW_INVALID_CODE_PATH();
        }
    } else if (atr == ATR_REG_FULL_DUPLEX) {
        switch (unit) {
            case UNIT_RX:
                if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                    _iface->poke32(FR_ATR_TXVAL_1, value);
                else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                    _iface->poke32(FR_ATR_TXVAL_3, value);
                break;
            case UNIT_TX:
                if (_dboard_slot == usrp1_impl::DBOARD_SLOT_A)
                    _iface->poke32(FR_ATR_TXVAL_0, value);
                else if (_dboard_slot == usrp1_impl::DBOARD_SLOT_B)
                    _iface->poke32(FR_ATR_TXVAL_2, value);
                break;
            default:
                UHD_THROW_INVALID_CODE_PATH();
        }
    }
}
/***********************************************************************
 * SPI
 **********************************************************************/
/*!
 * Static function to convert a unit type to a spi slave device number.
 * \param unit the dboard interface unit type enum
 * \param slot the side (A or B) the dboard is attached
 * \return the slave device number
 */
static uint32_t unit_to_otw_spi_dev(
    dboard_iface::unit_t unit, usrp1_impl::dboard_slot_t slot)
{
    switch (unit) {
        case dboard_iface::UNIT_TX:
            if (slot == usrp1_impl::DBOARD_SLOT_A)
                return SPI_ENABLE_TX_A;
            else if (slot == usrp1_impl::DBOARD_SLOT_B)
                return SPI_ENABLE_TX_B;
            else
                break;
        case dboard_iface::UNIT_RX:
            if (slot == usrp1_impl::DBOARD_SLOT_A)
                return SPI_ENABLE_RX_A;
            else if (slot == usrp1_impl::DBOARD_SLOT_B)
                return SPI_ENABLE_RX_B;
            else
                break;
        default:
            break;
    }
    UHD_THROW_INVALID_CODE_PATH();
}

void usrp1_dboard_iface::write_spi(
    unit_t unit, const spi_config_t& config, uint32_t data, size_t num_bits)
{
    _iface->write_spi(unit_to_otw_spi_dev(unit, _dboard_slot), config, data, num_bits);
}

uint32_t usrp1_dboard_iface::read_write_spi(
    unit_t unit, const spi_config_t& config, uint32_t data, size_t num_bits)
{
    return _iface->read_spi(
        unit_to_otw_spi_dev(unit, _dboard_slot), config, data, num_bits);
}

/***********************************************************************
 * I2C
 **********************************************************************/
void usrp1_dboard_iface::write_i2c(uint16_t addr, const byte_vector_t& bytes)
{
    return _iface->write_i2c(addr, bytes);
}

byte_vector_t usrp1_dboard_iface::read_i2c(uint16_t addr, size_t num_bytes)
{
    return _iface->read_i2c(addr, num_bytes);
}

/***********************************************************************
 * Aux DAX/ADC
 **********************************************************************/
void usrp1_dboard_iface::write_aux_dac(
    dboard_iface::unit_t, aux_dac_t which, double value)
{
    // same aux dacs for each unit
    static const uhd::dict<aux_dac_t, usrp1_codec_ctrl::aux_dac_t> which_to_aux_dac =
        map_list_of(AUX_DAC_A, usrp1_codec_ctrl::AUX_DAC_A)(AUX_DAC_B,
            usrp1_codec_ctrl::AUX_DAC_B)(AUX_DAC_C, usrp1_codec_ctrl::AUX_DAC_C)(
            AUX_DAC_D, usrp1_codec_ctrl::AUX_DAC_D);

    _codec->write_aux_dac(which_to_aux_dac[which], value);
}

double usrp1_dboard_iface::read_aux_adc(dboard_iface::unit_t unit, aux_adc_t which)
{
    static const uhd::dict<unit_t, uhd::dict<aux_adc_t, usrp1_codec_ctrl::aux_adc_t>>
        unit_to_which_to_aux_adc = map_list_of(UNIT_RX,
            map_list_of(AUX_ADC_A, usrp1_codec_ctrl::AUX_ADC_A1)(
                AUX_ADC_B, usrp1_codec_ctrl::AUX_ADC_B1))(UNIT_TX,
            map_list_of(AUX_ADC_A, usrp1_codec_ctrl::AUX_ADC_A2)(
                AUX_ADC_B, usrp1_codec_ctrl::AUX_ADC_B2));

    return _codec->read_aux_adc(unit_to_which_to_aux_adc[unit][which]);
}

/***********************************************************************
 * Unsupported
 **********************************************************************/

void usrp1_dboard_iface::set_command_time(const uhd::time_spec_t&)
{
    throw uhd::not_implemented_error("timed command support not implemented");
}

uhd::time_spec_t usrp1_dboard_iface::get_command_time()
{
    throw uhd::not_implemented_error("timed command support not implemented");
}

void usrp1_dboard_iface::set_fe_connection(
    unit_t, const std::string&, const fe_connection_t&)
{
    throw uhd::not_implemented_error(
        "fe connection configuration support not implemented");
}