/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Driver for WM8758 audio codec - based on datasheet for WM8983 * * Based on code from the ipodlinux project - http://ipodlinux.org/ * Adapted for Rockbox in December 2005 * * Original file: linux/arch/armnommu/mach-ipod/audio.c * * Copyright (c) 2003-2005 Bernard Leach (leachbj@bouncycastle.org) * * 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 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "system.h" #include "kernel.h" #include "string.h" #include "audio.h" #include "wmcodec.h" #include "audiohw.h" #include "sound.h" /* shadow registers */ static unsigned short eq1_reg = EQ1_EQ3DMODE | EQ_GAIN_VALUE(0); static unsigned short eq5_reg = EQ_GAIN_VALUE(0); /* convert tenth of dB volume (-89..6) to master volume register value */ static int vol_tenthdb2hw(int db) { /* att DAC AMP result +6dB 0 +6 96 0dB 0 0 90 -57dB 0 -57 33 -58dB -1 -57 32 -89dB -32 -57 1 -90dB -oo -oo 0 */ if (db <= -900) { return 0; } else { return db / 10 - -90; } } /* helper function that calculates the register setting for amplifier and DAC volume out of the input from tenthdb2master() */ static void get_volume_params(int db, int *dac, int *amp) { /* should never happen, set max volume for amp and dac */ if (db > 96) { *dac = 255; *amp = 63; } /* set dac to max and set volume for amp (better snr) */ else if (db > 32) { *dac = 255; *amp = (db-90)+57; } /* set amp to min and reduce dac output */ else if (db > 0) { *dac = (db-33)*2 + 255; *amp = 0; } /* mute all */ else { *dac = 0x00; *amp = 0x40; } } static void audiohw_mute(bool mute) { if (mute) { wmcodec_write(DACCTRL, DACCTRL_SOFTMUTE); } else { wmcodec_write(DACCTRL, DACCTRL_DACOSR128); } } void audiohw_preinit(void) { /* Set low bias mode */ wmcodec_write(BIASCTRL, BIASCTRL_BIASCUT); /* Enable HPCOM, LINECOM */ wmcodec_write(OUTCTRL, OUTCTRL_HP_COM | OUTCTRL_LINE_COM | OUTCTRL_TSOPCTRL | OUTCTRL_TSDEN | OUTCTRL_VROI); /* Mute all Outputs and set PGAs minimum gain */ wmcodec_write(LOUT1VOL, 0x140); wmcodec_write(ROUT1VOL, 0x140); wmcodec_write(LOUT2VOL, 0x140); wmcodec_write(ROUT2VOL, 0x140); wmcodec_write(OUT3MIX, 0x40); wmcodec_write(OUT4MIX, 0x40); /* Enable L/ROUT1 */ wmcodec_write(PWRMGMT2, PWRMGMT2_ROUT1EN | PWRMGMT2_LOUT1EN); /* Enable VMID independent current bias */ wmcodec_write(OUT4TOADC, OUT4TOADC_POBCTRL); /* Enable required DACs and mixers */ wmcodec_write(PWRMGMT3, PWRMGMT3_RMIXEN | PWRMGMT3_LMIXEN | PWRMGMT3_DACENR | PWRMGMT3_DACENL); /* Enable VMIDSEL, BIASEN, BUFIOEN */ wmcodec_write(PWRMGMT1, PWRMGMT1_PLLEN | PWRMGMT1_BIASEN | PWRMGMT1_BUFIOEN | PWRMGMT1_VMIDSEL_10K); /* Setup digital interface, input amplifiers, PLL, ADCs and DACs */ wmcodec_write(AINTFCE, AINTFCE_IWL_16BIT | AINTFCE_FORMAT_I2S); wmcodec_write(CLKCTRL, CLKCTRL_MS); /* WM8758 is clock master */ audiohw_set_frequency(HW_FREQ_44); wmcodec_write(LOUTMIX, LOUTMIX_DACL2LMIX); wmcodec_write(ROUTMIX, ROUTMIX_DACR2RMIX); /* Disable VMID independent current bias */ wmcodec_write(OUT4TOADC, 0); } void audiohw_postinit(void) { wmcodec_write(PWRMGMT1, PWRMGMT1_PLLEN | PWRMGMT1_BIASEN | PWRMGMT1_BUFIOEN | PWRMGMT1_VMIDSEL_500K); /* lower the VMID power consumption */ wmcodec_write(BIASCTRL, 0); audiohw_mute(false); } void audiohw_set_volume(int vol_l, int vol_r) { int dac_l, amp_l, dac_r, amp_r; vol_l = vol_tenthdb2hw(vol_l); vol_r = vol_tenthdb2hw(vol_r); get_volume_params(vol_l, &dac_l, &_l); get_volume_params(vol_r, &dac_r, &_r); /* set DAC Important: DAC is global and will also affect lineout */ wmcodec_write(LDACVOL, dac_l); wmcodec_write(RDACVOL, dac_r | RDACVOL_DACVU); /* set headphone amp OUT1 */ wmcodec_write(LOUT1VOL, amp_l | LOUT1VOL_LOUT1ZC); wmcodec_write(ROUT1VOL, amp_r | ROUT1VOL_ROUT1ZC | ROUT1VOL_OUT1VU); } void audiohw_set_lineout_volume(int vol_l, int vol_r) { int dac_l, amp_l, dac_r, amp_r; vol_l = vol_tenthdb2hw(vol_l); vol_r = vol_tenthdb2hw(vol_r); get_volume_params(vol_l, &dac_l, &_l); get_volume_params(vol_r, &dac_r, &_r); /* set lineout amp OUT2 */ wmcodec_write(LOUT2VOL, amp_l | LOUT2VOL_LOUT2ZC); wmcodec_write(ROUT2VOL, amp_r | ROUT2VOL_ROUT2ZC | ROUT2VOL_OUT2VU); } void audiohw_enable_lineout(bool enable) { /* Initialize data without lineout enabling. */ int pwrmgmt3_data = PWRMGMT3_RMIXEN | PWRMGMT3_LMIXEN | PWRMGMT3_DACENR | PWRMGMT3_DACENL; /* Set lineout (OUT2), if enabled. */ if (enable) pwrmgmt3_data |= PWRMGMT3_LOUT2EN | PWRMGMT3_ROUT2EN; /* Set register. */ wmcodec_write(PWRMGMT3, pwrmgmt3_data); } void audiohw_set_bass(int value) { eq1_reg = (eq1_reg & ~EQ_GAIN_MASK) | EQ_GAIN_VALUE(value); wmcodec_write(EQ1, eq1_reg); } void audiohw_set_bass_cutoff(int value) { eq1_reg = (eq1_reg & ~EQ_CUTOFF_MASK) | EQ_CUTOFF_VALUE(value); wmcodec_write(EQ1, eq1_reg); } void audiohw_set_treble(int value) { eq5_reg = (eq5_reg & ~EQ_GAIN_MASK) | EQ_GAIN_VALUE(value); wmcodec_write(EQ5, eq5_reg); } void audiohw_set_treble_cutoff(int value) { eq5_reg = (eq5_reg & ~EQ_CUTOFF_MASK) | EQ_CUTOFF_VALUE(value); wmcodec_write(EQ5, eq5_reg); } /* Nice shutdown of WM8758 codec */ void audiohw_close(void) { audiohw_mute(true); /* Disable Thermal shutdown */ wmcodec_write(OUTCTRL, OUTCTRL_HP_COM | OUTCTRL_VROI); /* Enable VMIDTOG */ wmcodec_write(OUT4TOADC, OUT4TOADC_VMIDTOG); /* Disable VMIDSEL and BUFIOEN */ wmcodec_write(PWRMGMT1, PWRMGMT1_PLLEN | PWRMGMT1_BIASEN | PWRMGMT1_VMIDSEL_OFF); /* Wait for VMID to discharge */ sleep(3*HZ/10); /* Power off registers */ wmcodec_write(PWRMGMT2, 0); wmcodec_write(PWRMGMT3, 0); wmcodec_write(PWRMGMT1, 0); } /* Note: Disable output before calling this function */ void audiohw_set_frequency(int fsel) { /* CLKCTRL_MCLKDIV_MASK and ADDCTRL_SR_MASK don't overlap, so they can both fit in one byte. Bit 0 selects PLL configuration via pll_setups. */ static const unsigned char freq_setups[HW_NUM_FREQ] = { [HW_FREQ_48] = CLKCTRL_MCLKDIV_2 | ADDCTRL_SR_48kHz | 1, [HW_FREQ_44] = CLKCTRL_MCLKDIV_2 | ADDCTRL_SR_48kHz, [HW_FREQ_32] = CLKCTRL_MCLKDIV_3 | ADDCTRL_SR_32kHz | 1, [HW_FREQ_24] = CLKCTRL_MCLKDIV_4 | ADDCTRL_SR_24kHz | 1, [HW_FREQ_22] = CLKCTRL_MCLKDIV_4 | ADDCTRL_SR_24kHz, [HW_FREQ_16] = CLKCTRL_MCLKDIV_6 | ADDCTRL_SR_16kHz | 1, [HW_FREQ_12] = CLKCTRL_MCLKDIV_8 | ADDCTRL_SR_12kHz | 1, [HW_FREQ_11] = CLKCTRL_MCLKDIV_8 | ADDCTRL_SR_12kHz, [HW_FREQ_8] = CLKCTRL_MCLKDIV_12 | ADDCTRL_SR_8kHz | 1 }; /* Each PLL configuration is an array consisting of { PLLN, PLLK1, PLLK2, PLLK3 }. The WM8983 datasheet requires 5 < PLLN < 13, and states optimum is PLLN = 8, f2 = 90 MHz */ static const unsigned short pll_setups[2][4] = { /* f1 = 12 MHz, R = 7.5264, f2 = 90.3168 MHz, fPLLOUT = 22.5792 MHz */ { PLLN_PLLPRESCALE | 0x7, 0x21, 0x161, 0x26 }, /* f1 = 12 MHz, R = 8.192, f2 = 98.304 MHz, fPLLOUT = 24.576 MHz */ { PLLN_PLLPRESCALE | 0x8, 0xC, 0x93, 0xE9 } }; int i; /* PLLN, PLLK1, PLLK2, PLLK3 are contiguous (at 0x24 to 0x27) */ for (i = 0; i < 4; i++) wmcodec_write(PLLN + i, pll_setups[freq_setups[fsel] & 1][i]); /* CLKCTRL_MCLKDIV divides fPLLOUT to get SYSCLK (256 * sample rate) */ wmcodec_write(CLKCTRL, CLKCTRL_CLKSEL | (freq_setups[fsel] & CLKCTRL_MCLKDIV_MASK) | CLKCTRL_BCLKDIV_2 | CLKCTRL_MS); /* set ADC and DAC filter characteristics according to sample rate */ wmcodec_write(ADDCTRL, (freq_setups[fsel] & ADDCTRL_SR_MASK) | ADDCTRL_SLOWCLKEN); /* SLOWCLK enabled for zero cross timeout to work */ } void audiohw_enable_recording(bool source_mic) { (void)source_mic; /* We only have a line-in (I think) */ wmcodec_write(PWRMGMT2, PWRMGMT2_ROUT1EN | PWRMGMT2_LOUT1EN | PWRMGMT2_INPGAENR | PWRMGMT2_INPGAENL | PWRMGMT2_ADCENR | PWRMGMT2_ADCENL); wmcodec_write(INCTRL, INCTRL_R2_2INPGA | INCTRL_L2_2INPGA); wmcodec_write(LADCBOOST, LADCBOOST_L2_2BOOST(5)); wmcodec_write(RADCBOOST, RADCBOOST_R2_2BOOST(5)); /* Enable monitoring */ wmcodec_write(LOUTMIX, LOUTMIX_BYP2LMIXVOL(5) | LOUTMIX_BYPL2LMIX | LOUTMIX_DACL2LMIX); wmcodec_write(ROUTMIX, ROUTMIX_BYP2RMIXVOL(5) | ROUTMIX_BYPR2RMIX | ROUTMIX_DACR2RMIX); } void audiohw_disable_recording(void) { wmcodec_write(LOUTMIX, LOUTMIX_DACL2LMIX); wmcodec_write(ROUTMIX, ROUTMIX_DACR2RMIX); wmcodec_write(PWRMGMT2, PWRMGMT2_ROUT1EN | PWRMGMT2_LOUT1EN); } /* volume in 0 .. 63, corresponds to -12dB .. +35.25dB in 0.75dB steps */ void audiohw_set_recvol(int left, int right, int type) { switch (type) { case AUDIO_GAIN_MIC: right = left; /* fall through */ case AUDIO_GAIN_LINEIN: wmcodec_write(LINPGAVOL, LINPGAVOL_INPGAZCL | (left & LINPGAVOL_INPGAVOL_MASK)); wmcodec_write(RINPGAVOL, RINPGAVOL_INPGAVU | RINPGAVOL_INPGAZCR | (right & RINPGAVOL_INPGAVOL_MASK)); break; default: return; } } void audiohw_set_monitor(bool enable) { (void)enable; }