rockbox/firmware/drivers/audio/wm8978.c
Christian Gmeiner 56fceacfeb fix some problems with missing HAVE_RECORDING checks
git-svn-id: svn://svn.rockbox.org/rockbox/trunk@17544 a1c6a512-1295-4272-9138-f99709370657
2008-05-16 20:40:59 +00:00

369 lines
12 KiB
C

/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2008 by Michael Sevakis
*
* Driver for WM8978 audio codec
*
* All files in this archive are subject to the GNU General Public License.
* See the file COPYING in the source tree root for full license agreement.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include "config.h"
#include "system.h"
#include "audiohw.h"
#include "wmcodec.h"
#include "audio.h"
//#define LOGF_ENABLE
#include "logf.h"
/* #define to help adjust lower volume limit */
#define HW_VOL_MIN 0
#define HW_VOL_MUTE 0
#define HW_VOL_MAX 96
#define HW_VOL_ANA_MIN 0
#define HW_VOL_ANA_MAX 63
#define HW_VOL_DIG_MAX 255
#define HW_VOL_DIG_THRESHOLD (HW_VOL_MAX - HW_VOL_ANA_MAX)
#define HW_VOL_DIG_MIN (HW_VOL_DIG_MAX - 2*HW_VOL_DIG_THRESHOLD)
/* TODO: Define/refine an API for special hardware steps outside the
* main codec driver such as special GPIO handling. */
extern void audiohw_enable_headphone_jack(bool enable);
const struct sound_settings_info audiohw_settings[] =
{
[SOUND_VOLUME] = {"dB", 0, 1, -90, 6, -25},
[SOUND_BASS] = {"dB", 0, 1, -12, 12, 0},
[SOUND_TREBLE] = {"dB", 0, 1, -12, 12, 0},
[SOUND_BALANCE] = {"%", 0, 1,-100, 100, 0},
[SOUND_CHANNELS] = {"", 0, 1, 0, 5, 0},
[SOUND_STEREO_WIDTH] = {"%", 0, 5, 0, 250, 100},
#ifdef HAVE_RECORDING
[SOUND_LEFT_GAIN] = {"dB", 1, 1,-128, 96, 0},
[SOUND_RIGHT_GAIN] = {"dB", 1, 1,-128, 96, 0},
#if 0
[SOUND_MIC_GAIN] = {"dB", 1, 1,-128, 108, 16},
#endif
#endif
#if 0
[SOUND_BASS_CUTOFF] = {"", 0, 1, 1, 4, 1},
[SOUND_TREBLE_CUTOFF] = {"", 0, 1, 1, 4, 1},
#endif
};
static uint16_t wmc_regs[WMC_NUM_REGISTERS] =
{
/* Initialized with post-reset default values - the 2-wire interface
* cannot be read. Or-in additional bits desired for some registers. */
[0 ... WMC_NUM_REGISTERS-1] = 0x8000, /* To ID invalids in gaps */
[WMC_SOFTWARE_RESET] = 0x000,
[WMC_POWER_MANAGEMENT1] = 0x000,
[WMC_POWER_MANAGEMENT2] = 0x000,
[WMC_POWER_MANAGEMENT3] = 0x000,
[WMC_AUDIO_INTERFACE] = 0x050,
[WMC_COMPANDING_CTRL] = 0x000,
[WMC_CLOCK_GEN_CTRL] = 0x140,
[WMC_ADDITIONAL_CTRL] = 0x000,
[WMC_GPIO] = 0x000,
[WMC_JACK_DETECT_CONTROL1] = 0x000,
[WMC_DAC_CONTROL] = 0x000,
[WMC_LEFT_DAC_DIGITAL_VOL] = 0x0ff | WMC_VU,
[WMC_RIGHT_DAC_DIGITAL_VOL] = 0x0ff | WMC_VU,
[WMC_JACK_DETECT_CONTROL2] = 0x000,
[WMC_ADC_CONTROL] = 0x100,
[WMC_LEFT_ADC_DIGITAL_VOL] = 0x0ff | WMC_VU,
[WMC_RIGHT_ADC_DIGITAL_VOL] = 0x0ff | WMC_VU,
[WMC_EQ1_LOW_SHELF] = 0x12c,
[WMC_EQ2_PEAK1] = 0x02c,
[WMC_EQ3_PEAK2] = 0x02c,
[WMC_EQ4_PEAK3] = 0x02c,
[WMC_EQ5_HIGH_SHELF] = 0x02c,
[WMC_DAC_LIMITER1] = 0x032,
[WMC_DAC_LIMITER2] = 0x000,
[WMC_NOTCH_FILTER1] = 0x000,
[WMC_NOTCH_FILTER2] = 0x000,
[WMC_NOTCH_FILTER3] = 0x000,
[WMC_NOTCH_FILTER4] = 0x000,
[WMC_ALC_CONTROL1] = 0x038,
[WMC_ALC_CONTROL2] = 0x00b,
[WMC_ALC_CONTROL3] = 0x032,
[WMC_NOISE_GATE] = 0x000,
[WMC_PLL_N] = 0x008,
[WMC_PLL_K1] = 0x00c,
[WMC_PLL_K2] = 0x093,
[WMC_PLL_K3] = 0x0e9,
[WMC_3D_CONTROL] = 0x000,
[WMC_BEEP_CONTROL] = 0x000,
[WMC_INPUT_CTRL] = 0x033,
[WMC_LEFT_INP_PGA_GAIN_CTRL] = 0x010,
[WMC_RIGHT_INP_PGA_GAIN_CTRL] = 0x010,
[WMC_LEFT_ADC_BOOST_CTRL] = 0x100,
[WMC_RIGHT_ADC_BOOST_CTRL] = 0x100,
[WMC_OUTPUT_CTRL] = 0x002,
[WMC_LEFT_MIXER_CTRL] = 0x001,
[WMC_RIGHT_MIXER_CTRL] = 0x001,
[WMC_LOUT1_HP_VOLUME_CTRL] = 0x039 | WMC_VU | WMC_ZC,
[WMC_ROUT1_HP_VOLUME_CTRL] = 0x039 | WMC_VU | WMC_ZC,
[WMC_LOUT2_SPK_VOLUME_CTRL] = 0x039 | WMC_VU | WMC_ZC,
[WMC_ROUT2_SPK_VOLUME_CTRL] = 0x039 | WMC_VU | WMC_ZC,
[WMC_OUT3_MIXER_CTRL] = 0x001,
[WMC_OUT4_MONO_MIXER_CTRL] = 0x001,
};
struct
{
int vol_l;
int vol_r;
bool ahw_mute;
} wmc_vol =
{
HW_VOL_MUTE, HW_VOL_MUTE, false
};
static void wmc_write(unsigned int reg, unsigned int val)
{
if (reg >= WMC_NUM_REGISTERS || (wmc_regs[reg] & 0x8000))
{
logf("wm8978 invalid register: %d", reg);
return;
}
wmc_regs[reg] = val & ~0x8000;
wmcodec_write(reg, val);
}
static void wmc_set(unsigned int reg, unsigned int bits)
{
wmc_write(reg, wmc_regs[reg] | bits);
}
static void wmc_clear(unsigned int reg, unsigned int bits)
{
wmc_write(reg, wmc_regs[reg] & ~bits);
}
static void wmc_write_masked(unsigned int reg, unsigned int bits,
unsigned int mask)
{
wmc_write(reg, (wmc_regs[reg] & ~mask) | (bits & mask));
}
/* convert tenth of dB volume (-890..60) to master volume register value
* (000000...111111) */
int tenthdb2master(int db)
{
/* -90dB to +6dB 1dB steps (96 levels) 7bits */
/* 1100000 == +6dB (0x60,96) */
/* 1101010 == 0dB (0x5a,90) */
/* 1000001 == -57dB (0x21,33,DAC) */
/* 0000001 == -89dB (0x01,01) */
/* 0000000 == -90dB (0x00,00,Mute) */
if (db <= VOLUME_MIN)
{
return 0x0;
}
else
{
return (db - VOLUME_MIN) / 10;
}
}
void audiohw_preinit(void)
{
/* 1. Turn on external power supplies. Wait for supply voltage to settle. */
/* Step 1 should be completed already. Reset and return all registers to
* defaults */
wmcodec_write(WMC_SOFTWARE_RESET, 0xff);
sleep(HZ/10);
/* 2. Mute all analogue outputs */
wmc_set(WMC_LOUT1_HP_VOLUME_CTRL, WMC_MUTE);
wmc_set(WMC_ROUT1_HP_VOLUME_CTRL, WMC_MUTE);
wmc_set(WMC_LOUT2_SPK_VOLUME_CTRL, WMC_MUTE);
wmc_set(WMC_ROUT2_SPK_VOLUME_CTRL, WMC_MUTE);
wmc_set(WMC_OUT3_MIXER_CTRL, WMC_MUTE);
wmc_set(WMC_OUT4_MONO_MIXER_CTRL, WMC_MUTE);
wmc_set(WMC_INPUT_CTRL, 0x000);
/* 3. Set L/RMIXEN = 1 and DACENL/R = 1 in register R3. */
wmc_write(WMC_POWER_MANAGEMENT3,
WMC_RMIXEN | WMC_LMIXEN | WMC_DACENR | WMC_DACENL);
/* 4. Set BUFIOEN = 1 and VMIDSEL[1:0] to required value in register
* R1. Wait for VMID supply to settle */
wmc_write(WMC_POWER_MANAGEMENT1, WMC_BUFIOEN | WMC_VMIDSEL_300K);
sleep(HZ/10);
/* 5. Set BIASEN = 1 in register R1. */
wmc_set(WMC_POWER_MANAGEMENT1, WMC_BIASEN);
}
void audiohw_postinit(void)
{
sleep(HZ);
/* 6. Set L/ROUTEN = 1 in register R2. */
wmc_write(WMC_POWER_MANAGEMENT2, WMC_LOUT1EN | WMC_ROUT1EN);
/* 7. Enable other mixers as required */
/* 8. Enable other outputs as required */
/* 9. Set remaining registers */
wmc_write(WMC_AUDIO_INTERFACE, WMC_WL_16 | WMC_FMT_I2S
| WMC_DACLRSWAP | WMC_ADCLRSWAP);
wmc_write(WMC_DAC_CONTROL, WMC_DACOSR_128 | WMC_AMUTE);
/* Specific to HW clocking */
wmc_write(WMC_CLOCK_GEN_CTRL, WMC_MCLKDIV_1_5 | WMC_BCLKDIV_8 | WMC_MS);
wmc_write(WMC_ADDITIONAL_CTRL, WMC_SR_48KHZ); /* 44.1 */
/* Initialize to minimum volume */
wmc_write_masked(WMC_LEFT_DAC_DIGITAL_VOL, HW_VOL_DIG_MIN, WMC_DVOL);
wmc_write_masked(WMC_LOUT1_HP_VOLUME_CTRL, HW_VOL_ANA_MIN, WMC_AVOL);
wmc_write_masked(WMC_RIGHT_DAC_DIGITAL_VOL, HW_VOL_DIG_MIN, WMC_DVOL);
wmc_write_masked(WMC_ROUT1_HP_VOLUME_CTRL, HW_VOL_ANA_MIN, WMC_AVOL);
/* ADC silenced */
wmc_write_masked(WMC_LEFT_ADC_DIGITAL_VOL, 0x00, WMC_DVOL);
wmc_write_masked(WMC_RIGHT_ADC_DIGITAL_VOL, 0x00, WMC_DVOL);
audiohw_enable_headphone_jack(true);
}
void audiohw_set_headphone_vol(int vol_l, int vol_r)
{
int prev_l = wmc_vol.vol_l;
int prev_r = wmc_vol.vol_r;
int dac_l, dac_r;
wmc_vol.vol_l = vol_l;
wmc_vol.vol_r = vol_r;
/* When analogue volume falls below -57dB (0x00) start attenuating the
* DAC volume */
if (vol_l >= HW_VOL_DIG_THRESHOLD)
{
if (vol_l > HW_VOL_MAX)
vol_l = HW_VOL_MAX;
dac_l = HW_VOL_DIG_MAX;
vol_l -= HW_VOL_DIG_THRESHOLD;
}
else
{
if (vol_l < HW_VOL_MIN)
vol_l = HW_VOL_MIN;
dac_l = 2*vol_l + HW_VOL_DIG_MIN;
vol_l = HW_VOL_ANA_MIN;
}
if (vol_r >= HW_VOL_DIG_THRESHOLD)
{
if (vol_r > HW_VOL_MAX)
vol_r = HW_VOL_MAX;
dac_r = HW_VOL_DIG_MAX;
vol_r -= HW_VOL_DIG_THRESHOLD;
}
else
{
if (vol_r < HW_VOL_MIN)
vol_r = HW_VOL_MIN;
dac_r = 2*vol_r + HW_VOL_DIG_MIN;
vol_r = HW_VOL_ANA_MIN;
}
/* Have to write both channels always to have the latching work */
wmc_write_masked(WMC_LEFT_DAC_DIGITAL_VOL, dac_l, WMC_DVOL);
wmc_write_masked(WMC_LOUT1_HP_VOLUME_CTRL, vol_l, WMC_AVOL);
wmc_write_masked(WMC_RIGHT_DAC_DIGITAL_VOL, dac_r, WMC_DVOL);
wmc_write_masked(WMC_ROUT1_HP_VOLUME_CTRL, vol_r, WMC_AVOL);
if (wmc_vol.vol_l > HW_VOL_MUTE)
{
/* Not muted and going up from mute level? */
if (prev_l <= HW_VOL_MUTE && !wmc_vol.ahw_mute)
wmc_clear(WMC_LOUT1_HP_VOLUME_CTRL, WMC_MUTE);
}
else
{
/* Going to mute level? */
if (prev_l > HW_VOL_MUTE)
wmc_set(WMC_LOUT1_HP_VOLUME_CTRL, WMC_MUTE);
}
if (wmc_vol.vol_r > HW_VOL_MUTE)
{
/* Not muted and going up from mute level? */
if (prev_r <= HW_VOL_MIN && !wmc_vol.ahw_mute)
wmc_clear(WMC_ROUT1_HP_VOLUME_CTRL, WMC_MUTE);
}
else
{
/* Going to mute level? */
if (prev_r > HW_VOL_MUTE)
wmc_set(WMC_ROUT1_HP_VOLUME_CTRL, WMC_MUTE);
}
}
void audiohw_close(void)
{
/* 1. Mute all analogue outputs */
audiohw_mute(true);
audiohw_enable_headphone_jack(false);
/* 2. Disable power management register 1. R1 = 00 */
wmc_write(WMC_POWER_MANAGEMENT1, 0x000);
/* 3. Disable power management register 2. R2 = 00 */
wmc_write(WMC_POWER_MANAGEMENT2, 0x000);
/* 4. Disable power management register 3. R3 = 00 */
wmc_write(WMC_POWER_MANAGEMENT3, 0x000);
/* 5. Remove external power supplies. */
}
void audiohw_mute(bool mute)
{
wmc_vol.ahw_mute = mute;
/* No DAC mute here, please - take care of each enabled output. */
if (mute)
{
wmc_set(WMC_LOUT1_HP_VOLUME_CTRL, WMC_MUTE);
wmc_set(WMC_ROUT1_HP_VOLUME_CTRL, WMC_MUTE);
}
else
{
/* Unmute outputs not at mute level */
if (wmc_vol.vol_l > HW_VOL_MUTE)
wmc_clear(WMC_LOUT1_HP_VOLUME_CTRL, WMC_MUTE);
if (wmc_vol.vol_r > HW_VOL_MUTE)
wmc_clear(WMC_ROUT1_HP_VOLUME_CTRL, WMC_MUTE);
}
}
#ifdef HAVE_RECORDING
/* TODO */
void audiohw_set_recvol(int left, int right, int type)
{
(void)left; (void)right; (void)type;
}
#endif