/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id: uda1380.c 21975 2009-07-19 22:45:32Z bertrik $ * * Copyright (C) 2009 by Bob Cousins * * 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 #include "config.h" #include "logf.h" #include "system.h" #include "audio.h" #include "debug.h" #include "audiohw.h" const struct sound_settings_info audiohw_settings[] = { [SOUND_VOLUME] = {"dB", 0, 1, -84, 0, -25}, [SOUND_BASS] = {"dB", 0, 2, 0, 24, 0}, [SOUND_TREBLE] = {"dB", 0, 2, 0, 6, 0}, [SOUND_BALANCE] = {"%", 0, 1,-100, 100, 0}, /* not used */ [SOUND_CHANNELS] = {"", 0, 1, 0, 5, 0}, /* not used */ [SOUND_STEREO_WIDTH] = {"%", 0, 5, 0, 250, 100}, /* not used */ #ifdef HAVE_RECORDING [SOUND_LEFT_GAIN] = {"dB", 1, 1,-128, 96, 0}, [SOUND_RIGHT_GAIN] = {"dB", 1, 1,-128, 96, 0}, [SOUND_MIC_GAIN] = {"dB", 1, 1,-128, 108, 16}, #endif }; /* convert tenth of dB volume (-600..0) to master volume register value */ int tenthdb2master(int db) { if (db < -600) return 63; else /* 1 dB steps */ return -(db / 10) + 1; } static unsigned short uda_regs[NUM_REG_ID]; /****************************************************************************/ /* ------------------------------------------------- */ /* Local functions and variables */ /* ------------------------------------------------- */ /* Generic L3 functions */ #define L3PORT GPBDAT #define L3MODE (1 << 2) #define L3DATA (1 << 3) #define L3CLOCK (1 << 4) static void l3_init (void) { L3PORT |= L3MODE | L3CLOCK; L3PORT &= ~L3DATA; S3C2440_GPIO_CONFIG (GPBCON, 2, GPIO_OUTPUT); /* L3 MODE */ S3C2440_GPIO_CONFIG (GPBCON, 3, GPIO_OUTPUT); /* L3 DATA */ S3C2440_GPIO_CONFIG (GPBCON, 4, GPIO_OUTPUT); /* L3 CLOCK */ S3C2440_GPIO_PULLUP (GPBUP, 2, GPIO_PULLUP_DISABLE); S3C2440_GPIO_PULLUP (GPBUP, 3, GPIO_PULLUP_DISABLE); S3C2440_GPIO_PULLUP (GPBUP, 4, GPIO_PULLUP_DISABLE); } static void bit_delay (void) { volatile int j; for (j=0; j<5; j++) ; } static void l3_write_byte (unsigned char data, bool address_mode) { int bit; L3PORT |= L3CLOCK; if (address_mode) L3PORT &= ~L3MODE; else L3PORT |= L3MODE; bit_delay(); for (bit=0; bit < 8; bit++) { if (data & 1) { L3PORT |= L3DATA; } else { L3PORT &= ~L3DATA; } L3PORT &= ~L3CLOCK; bit_delay(); L3PORT |= L3CLOCK; bit_delay(); data >>= 1; } if (address_mode) L3PORT |= L3MODE; else L3PORT &= ~L3MODE; bit_delay(); } static void l3_write_addr (unsigned char addr) { /* write address byte */ l3_write_byte (addr, true); } static void l3_write_data (unsigned char data) { /* write data byte */ l3_write_byte (data, false); } /****************************************************************************/ /* UDA1341 access functions */ static int udacodec_write(unsigned char reg, unsigned short value) { l3_write_addr (UDA1341_ADDR | reg); l3_write_data (value & 0xff); return 0; } static void udacodec_reset(void) { /* uda reset */ l3_init(); udacodec_write (UDA_REG_STATUS, UDA_STATUS_0 | UDA_RESET | UDA_SYSCLK_256FS | I2S_IFMT_IIS); udacodec_write (UDA_REG_STATUS, UDA_STATUS_0 | UDA_SYSCLK_256FS | I2S_IFMT_IIS); udacodec_write (UDA_REG_STATUS, UDA_STATUS_1 | UDA_POWER_DAC_ON); uda_regs[UDA_REG_ID_CTRL2] = UDA_PEAK_DETECT_POS_AFTER | UDA_DE_EMPHASIS_NONE | UDA_MUTE_OFF | UDA_MODE_SWITCH_FLAT; } /****************************************************************************/ /* Audio API functions */ /* This table must match the table in pcm-xxxx.c if using Master mode */ /* [reserved, master clock rate] */ static const unsigned char uda_freq_parms[HW_NUM_FREQ][2] = { [HW_FREQ_44] = { 0, UDA_SYSCLK_384FS }, [HW_FREQ_22] = { 0, UDA_SYSCLK_256FS }, [HW_FREQ_11] = { 0, UDA_SYSCLK_256FS }, }; void audiohw_init(void) { udacodec_reset(); audiohw_set_bass (0); audiohw_set_treble (0); audiohw_set_master_vol (26, 26); /* -25 dB */ } void audiohw_postinit(void) { } void audiohw_close(void) { /* DAC, ADC off */ udacodec_write (UDA_REG_STATUS, UDA_STATUS_1 | 0); } void audiohw_set_bass(int value) { uda_regs [UDA_REG_ID_CTRL1] &= UDA_BASS_BOOST (UDA_BASS_BOOST_MASK); uda_regs [UDA_REG_ID_CTRL1] |= UDA_BASS_BOOST (value & UDA_BASS_BOOST_MASK); udacodec_write (UDA_REG_DATA0, UDA_DATA_CTRL1 | uda_regs [UDA_REG_ID_CTRL1] ); } void audiohw_set_treble(int value) { uda_regs [UDA_REG_ID_CTRL1] &= UDA_TREBLE (UDA_TREBLE_MASK); uda_regs [UDA_REG_ID_CTRL1] |= UDA_TREBLE (value & UDA_TREBLE_MASK); udacodec_write (UDA_REG_DATA0, UDA_DATA_CTRL1 | uda_regs [UDA_REG_ID_CTRL1] ); } /*static void audiohw_mute(bool mute) { if (mute) uda_regs [UDA_REG_ID_CTRL2] |= UDA_MUTE_ON; else uda_regs [UDA_REG_ID_CTRL2] &= ~UDA_MUTE_ON; udacodec_write (UDA_REG_DATA0, UDA_DATA_CTRL2 | uda_regs [UDA_REG_ID_CTRL2] ); } */ void audiohw_set_prescaler(int val) { (void)val; } /** * Sets left and right master volume (1(max) to 62(muted)) */ void audiohw_set_master_vol(int vol_l, int vol_r) { uda_regs[UDA_REG_ID_CTRL0] = (vol_l + vol_r) / 2; udacodec_write (UDA_REG_DATA0, UDA_DATA_CTRL0 | uda_regs[UDA_REG_ID_CTRL0]); } void audiohw_set_frequency(int fsel) { if ((unsigned)fsel >= HW_NUM_FREQ) fsel = HW_FREQ_DEFAULT; uda_regs[UDA_REG_ID_STATUS_0] = I2S_IFMT_IIS | uda_freq_parms[fsel][1]; udacodec_write (UDA_REG_STATUS, UDA_STATUS_0 | uda_regs[UDA_REG_ID_STATUS_0]); }