mayhem-firmware/firmware/common/ak4951.cpp
2017-05-31 11:45:54 -07:00

313 lines
9.3 KiB
C++

/*
* Copyright (C) 2017 Jared Boone, ShareBrained Technology, Inc.
*
* This file is part of PortaPack.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#include "ak4951.hpp"
#include "portapack_io.hpp"
using namespace portapack;
#include <ch.h>
namespace asahi_kasei {
namespace ak4951 {
void AK4951::configure_digital_interface() {
// Configure for external slave mode.
map.r.mode_control_1.DIF = 0b11; // I2S compatible
map.r.mode_control_1.BCKO = 0; // BICK = 32fs
update(Register::ModeControl1);
map.r.mode_control_2.CM = 0b00; // MCKI = 256fs
map.r.mode_control_2.FS = 0b1011; // fs = 48kHz
update(Register::ModeControl2);
// map.r.mode_control_3.DVOLC = 1; // Control L/R channels with DVL (LchDigitalVolumeControl)
// update(Register::ModeControl3);
map.r.power_management_2.MS = 0; // Slave mode
map.r.power_management_2.PMPLL = 0; // EXT mode
update(Register::PowerManagement2);
}
void AK4951::init() {
reset();
// Write dummy address to "release" the reset.
write(0x00, 0x00);
configure_digital_interface();
map.r.power_management_1.PMVCM = 1;
update(Register::PowerManagement1);
// Headphone output is hi-Z when not active, reduces crosstalk from speaker output.
map.r.beep_control.HPZ = 1;
update(Register::BeepControl);
// Pause for VCOM and REGFIL pins to stabilize.
chThdSleepMilliseconds(2);
headphone_mute();
// SPK-Amp gain setting: SPKG1-0 bits = “00” → “01”
map.r.signal_select_2.SPKG = 0b01;
update(Register::SignalSelect2);
map.r.signal_select_3.MONO = 0b00;
update(Register::SignalSelect3);
map.r.digital_filter_mode.PFSDO = 0; // ADC bypass digital filter block.
map.r.digital_filter_mode.ADCPF = 1; // ADC output
map.r.digital_filter_mode.PFDAC = 0b00; // SDTI
update(Register::DigitalFilterMode);
// Set up FRN, FRATT and ADRST1-0 bits (Addr = 09H)
// map.r.timer_select.FRN = 0;
// map.r.timer_select.FRATT = 0;
// map.r.timer_select.ADRST = 0b00;
// update(Register::TimerSelect);
// Set up ALC mode (Addr = 0AH, 0BH)
// map.r.alc_timer_select. = ;
// update(Register::ALCTimerSelect);
// map.r.alc_mode_control_1. = ;
// update(Register::ALCModeControl1);
// Set up REF value of ALC (Addr = 0CH)
// map.r.alc_mode_control_2. = ;
// update(Register::ALCModeControl2);
// Set up IVOL value of ALC operation start (Addr = 0DH)
// map.r.l_ch_input_volume_control. = ;
// update(Register::LchInputVolumeControl);
// map.r.r_ch_input_volume_control. = ;
// update(Register::RchInputVolumeControl);
// Set up the output digital volume. (Addr = 13H)
// set_headphone_volume(...);
// Set up Programmable Filter Path: PFDAC1-0 bits=“01”, PFSDO=ADCPF bits=“0” (Addr = 1DH)
// map.r.digital_filter_mode.PFDAC = 0b01;
// update(Register::DigitalFilterMode);
}
bool AK4951::reset() {
io.audio_reset_state(true);
// PDN# pulse must be >200ns
chThdSleepMicroseconds(10);
io.audio_reset_state(false);
return true;
}
void AK4951::set_digtal_volume_control(const reg_t value) {
map.r.l_ch_digital_volume_control.DV = value;
update(Register::LchDigitalVolumeControl);
}
void AK4951::set_headphone_volume(const volume_t volume) {
const auto normalized = headphone_gain_range().normalize(volume);
auto n = normalized.centibel() / 5;
set_digtal_volume_control(0xcb - n);
}
void AK4951::headphone_mute() {
set_digtal_volume_control(0xff);
}
void AK4951::set_dac_power(const bool enable) {
map.r.power_management_1.PMDAC = enable;
update(Register::PowerManagement1);
}
void AK4951::set_headphone_power(const bool enable) {
map.r.power_management_2.PMHPL = map.r.power_management_2.PMHPR = enable;
update(Register::PowerManagement2);
}
void AK4951::set_speaker_power(const bool enable) {
map.r.power_management_2.PMSL = enable;
update(Register::PowerManagement2);
}
void AK4951::select_line_out(const LineOutSelect value) {
map.r.power_management_2.LOSEL = (value == LineOutSelect::Line) ? 1 : 0;
update(Register::PowerManagement2);
}
void AK4951::headphone_enable() {
set_dac_power(true);
set_headphone_power(true);
// Wait for headphone amplifier charge pump power-up.
chThdSleepMilliseconds(35);
}
void AK4951::headphone_disable() {
set_headphone_power(false);
set_dac_power(false);
}
void AK4951::speaker_enable() {
// Set up the path of DAC → SPK-Amp: DACS bit = “0” → “1”
map.r.signal_select_1.DACS = 1;
update(Register::SignalSelect1);
// Enter Speaker-Amp Output Mode: LOSEL bit = “0”
select_line_out(LineOutSelect::Speaker);
// Power up DAC, Programmable Filter and Speaker-Amp: PMDAC=PMPFIL=PMSL bits=“0”→“1”
set_dac_power(true);
// map.r.power_management_1.PMPFIL = 1;
// update(Register::PowerManagement1);
set_speaker_power(true);
// Time from PMSL=1 to SLPSN=1.
chThdSleepMilliseconds(1);
// Exit the power-save mode of Speaker-Amp: SLPSN bit = “0” → “1”
map.r.signal_select_1.SLPSN = 1;
update(Register::SignalSelect1);
}
void AK4951::speaker_disable() {
// Enter Speaker-Amp Power Save Mode: SLPSN bit = “1” → “0”
map.r.signal_select_1.SLPSN = 0;
update(Register::SignalSelect1);
// Disable the path of DAC → SPK-Amp: DACS bit = “1” → “0”
map.r.signal_select_1.DACS = 0;
update(Register::SignalSelect1);
// Power down DAC, Programmable Filter and speaker: PMDAC=PMPFIL=PMSL bits= “1”→“0”
set_dac_power(false);
// map.r.power_management_1.PMPFIL = 0;
// update(Register::PowerManagement1);
set_speaker_power(false);
}
void AK4951::microphone_enable() {
// map.r.digital_mic.DMIC = 0;
// update(Register::DigitalMic);
map.r.signal_select_1.MGAIN20 = 0b110;
map.r.signal_select_1.PMMP = 1;
map.r.signal_select_1.MPSEL = 1; // MPWR2 pin
map.r.signal_select_1.MGAIN3 = 0b0;
update(Register::SignalSelect1);
map.r.signal_select_2.INL = 0b01; // Lch input signal = LIN2
map.r.signal_select_2.INR = 0b01; // Rch input signal = RIN2
map.r.signal_select_2.MICL = 0; // MPWR = 2.4V
update(Register::SignalSelect2);
// map.r.r_ch_mic_gain_setting.MGR = 0x80; // Microphone sensitivity correction = 0dB.
// update(Register::RchMicGainSetting);
/*
map.r.timer_select.FRN = ?;
map.r.timer_select.FRATT = ?;
map.r.timer_select.ADRST = 0b??;
update(Register::TimerSelect);
map.r.alc_timer_select. = ?;
update(Register::ALCTimerSelect);
map.r.alc_mode_control_1. = ?;
map.r.alc_mode_control_1.ALC = 1;
update(Register::ALCModeControl1);
map.r.alc_mode_control_2.REF = ?;
update(Register::ALCModeControl2);
*/
// map.r.l_ch_input_volume_control.IV = 0xe1;
// update(Register::LchInputVolumeControl);
// map.r.r_ch_input_volume_control.IV = 0xe1;
// update(Register::RchInputVolumeControl);
/*
map.r.auto_hpf_control.STG = 0b00;
map.r.auto_hpf_control.SENC = 0b011;
map.r.auto_hpf_control.AHPF = 0;
update(Register::AutoHPFControl);
*/
map.r.digital_filter_select_1.HPFAD = 1; // HPF1 (after ADC) = on
map.r.digital_filter_select_1.HPFC = 0b11; // 2336.8 Hz @ fs=48k
update(Register::DigitalFilterSelect1);
/*
map.r.digital_filter_select_2.HPF = 0;
map.r.digital_filter_select_2.LPF = 0;
map.r.digital_filter_select_2.FIL3 = 0;
map.r.digital_filter_select_2.EQ0 = 0;
map.r.digital_filter_select_2.GN = 0b00;
update(Register::DigitalFilterSelect2);
map.r.digital_filter_select_3.EQ1 = 0;
map.r.digital_filter_select_3.EQ2 = 0;
map.r.digital_filter_select_3.EQ3 = 0;
map.r.digital_filter_select_3.EQ4 = 0;
map.r.digital_filter_select_3.EQ5 = 0;
update(Register::DigitalFilterSelect3);
*/
map.r.digital_filter_mode.PFSDO = 0; // ADC (+ 1st order HPF) Output
map.r.digital_filter_mode.ADCPF = 1; // ADC Output (default)
update(Register::DigitalFilterMode);
// ... Set coefficients ...
map.r.power_management_1.PMADL = 1; // ADC Lch = Lch input signal
map.r.power_management_1.PMADR = 1; // ADC Rch = Rch input signal
map.r.power_management_1.PMPFIL = 0; // Programmable filter unused, routed around.
update(Register::PowerManagement1);
// 1059/fs, 22ms @ 48kHz
chThdSleepMilliseconds(22);
}
void AK4951::microphone_disable() {
map.r.power_management_1.PMADL = 0;
map.r.power_management_1.PMADR = 0;
map.r.power_management_1.PMPFIL = 0;
update(Register::PowerManagement1);
map.r.alc_mode_control_1.ALC = 0;
update(Register::ALCModeControl1);
}
reg_t AK4951::read(const address_t reg_address) {
const std::array<uint8_t, 1> tx { reg_address };
std::array<uint8_t, 1> rx { 0x00 };
bus.transmit(bus_address, tx.data(), tx.size());
bus.receive(bus_address, rx.data(), rx.size());
return rx[0];
}
void AK4951::update(const Register reg) {
write(toUType(reg), map.w[toUType(reg)]);
}
void AK4951::write(const address_t reg_address, const reg_t value) {
const std::array<uint8_t, 2> tx { reg_address, value };
bus.transmit(bus_address, tx.data(), tx.size());
}
} /* namespace ak4951 */
} /* namespace asahi_kasei */