/*
 * Copyright 2009 Ettus Research LLC
 */

#include "db_wbxng_adf4350_regs.h"
#include "db_wbxng_adf4350.h"

//#include "cal_div.h"

/* reg 0 */
/* reg 1 */
const uint16_t adf4350_regs::s_phase = 0;
/* reg 2 */
const uint8_t adf4350_regs::s_low_noise_and_low_spur_modes = 3;
const uint8_t adf4350_regs::s_muxout = 6;
const uint8_t adf4350_regs::s_reference_doubler = 0;
const uint8_t adf4350_regs::s_rdiv2 = 0;
const uint8_t adf4350_regs::s_double_buff = 0;
const uint8_t adf4350_regs::s_charge_pump_setting = 5;
const uint8_t adf4350_regs::s_ldf = 0;
const uint8_t adf4350_regs::s_ldp = 0;
const uint8_t adf4350_regs::s_pd_polarity = 1;
const uint8_t adf4350_regs::s_power_down = 0;
const uint8_t adf4350_regs::s_cp_three_state = 0;
const uint8_t adf4350_regs::s_counter_reset = 0;
/* reg 3 */
const uint8_t adf4350_regs::s_csr = 0;
const uint8_t adf4350_regs::s_clk_div_mode = 0;
const uint16_t adf4350_regs::s_12_bit_clock_divider_value = 0;
/* reg 4 */
const uint8_t adf4350_regs::s_feedback_select = 1;
const uint8_t adf4350_regs::s_vco_power_down = 0;
const uint8_t adf4350_regs::s_mtld = 0;
const uint8_t adf4350_regs::s_aux_output_select = 1;
const uint8_t adf4350_regs::s_aux_output_enable = 0;
const uint8_t adf4350_regs::s_aux_output_power = 0;
const uint8_t adf4350_regs::s_rf_output_enable = 1;
const uint8_t adf4350_regs::s_output_power = 3;
/* reg 5 */
const uint8_t adf4350_regs::s_ld_pin_mode = 1;

adf4350_regs::adf4350_regs(adf4350* _adf4350){
    d_adf4350 = _adf4350;

    /* reg 0 */
    d_int = uint16_t(100);
    d_frac = 0;
    /* reg 1 */
    d_prescaler = uint8_t(0);
    d_mod = uint16_t(0xfff);                      /* max fractional accuracy */
    /* reg 2 */
    d_10_bit_r_counter = uint16_t(2);
    /* reg 3 */
    /* reg 4 */
    d_divider_select = 0;
    d_8_bit_band_select_clock_divider_value = 0;
    /* reg 5 */
}

adf4350_regs::~adf4350_regs(void){
}

uint32_t
adf4350_regs::_reg_shift(uint32_t data, uint32_t shift){
        return data << shift;
    }

void
adf4350_regs::_load_register(uint8_t addr){
	uint32_t data;
	switch (addr){
		case 0: data = (
			_reg_shift(d_int, 15)                           |
			_reg_shift(d_frac, 3)); break;
		case 1: data = (
			_reg_shift(d_prescaler, 27)                     |
			_reg_shift(s_phase, 15)                         |
			_reg_shift(d_mod, 3)); break;
		case 2: data = (
			_reg_shift(s_low_noise_and_low_spur_modes, 29)  |
			_reg_shift(s_muxout, 26)                        |
			_reg_shift(s_reference_doubler, 25)             |
			_reg_shift(s_rdiv2, 24)                         |
			_reg_shift(d_10_bit_r_counter, 14)              |
			_reg_shift(s_double_buff, 13)                   |
			_reg_shift(s_charge_pump_setting, 9)            |
			_reg_shift(s_ldf, 8)                            |
			_reg_shift(s_ldp, 7)                            |
			_reg_shift(s_pd_polarity, 6)                    |
			_reg_shift(s_power_down, 5)                     |
			_reg_shift(s_cp_three_state, 4)                 |
			_reg_shift(s_counter_reset, 3)); break;
		case 3: data = (
			_reg_shift(s_csr, 18)                           |
			_reg_shift(s_clk_div_mode, 15)                  |
			_reg_shift(s_12_bit_clock_divider_value, 3)); break;
		case 4: data = (
			_reg_shift(s_feedback_select, 23)               |
			_reg_shift(d_divider_select, 20)                |
			_reg_shift(d_8_bit_band_select_clock_divider_value, 12) |
			_reg_shift(s_vco_power_down, 11)                |
			_reg_shift(s_mtld, 10)                          |
			_reg_shift(s_aux_output_select, 9)              |
			_reg_shift(s_aux_output_enable, 8)              |
			_reg_shift(s_aux_output_power, 6)               |
			_reg_shift(s_rf_output_enable, 5)               |
			_reg_shift(s_output_power, 3)); break;
		case 5: data = (
			_reg_shift(s_ld_pin_mode, 22)); break;
		default: return;
	}
	/* write the data out to spi */
	d_adf4350->_write(addr, data);
}