/* $Id: cs4231.c,v 1.47 2001/10/08 22:19:50 davem Exp $ * drivers/sbus/audio/cs4231.c * * Copyright 1996, 1997, 1998, 1999 Derrick J Brashear (shadow@andrew.cmu.edu) * The 4231/ebus support was written by David Miller, who didn't bother * crediting himself here, so I will. * * Based on the AMD7930 driver: * Copyright 1996 Thomas K. Dyas (tdyas@noc.rutgers.edu) * * This is the lowlevel driver for the CS4231 audio chip found on some * sun4m and sun4u machines. * * This was culled from the Crystal docs on the 4231a, and the addendum they * faxed me on the 4231. * The APC DMA controller support unfortunately is not documented. Thanks, Sun. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef CONFIG_PCI #define EB4231_SUPPORT #include #include #endif #include #include "cs4231.h" #undef __CS4231_DEBUG #undef __CS4231_TRACE #define __CS4231_ERROR #ifdef __CS4231_ERROR #define eprintk(x) printk x #else #define eprintk(x) #endif #ifdef __CS4231_TRACE #define tprintk(x) printk x #else #define tprintk(x) #endif #ifdef __CS4231_DEBUG #define dprintk(x) printk x #else #define dprintk(x) #endif #define MAX_DRIVERS 1 static struct sparcaudio_driver drivers[MAX_DRIVERS]; static int num_drivers; static int cs4231_record_gain(struct sparcaudio_driver *drv, int value, unsigned char balance); static int cs4231_play_gain(struct sparcaudio_driver *drv, int value, unsigned char balance); static void cs4231_ready(struct sparcaudio_driver *drv); static void cs4231_playintr(struct sparcaudio_driver *drv, int); static int cs4231_recintr(struct sparcaudio_driver *drv); static int cs4231_output_muted(struct sparcaudio_driver *drv, int value); static void cs4231_pollinput(struct sparcaudio_driver *drv); static int cs4231_length_to_samplecount(struct audio_prinfo *thisdir, unsigned int length); static void cs4231_getsamplecount(struct sparcaudio_driver *drv, unsigned int length, unsigned int value); #ifdef EB4231_SUPPORT static void eb4231_pollinput(struct sparcaudio_driver *drv); #endif /* Serveral shorthands save typing... */ #define CHIP_READY() \ do { udelay(100); cs4231_ready(drv); udelay(1000); } while(0) #define WRITE_IAR(__VAL) \ CS4231_WRITE8(cs4231_chip, cs4231_chip->regs + IAR, __VAL) #define WRITE_IDR(__VAL) \ CS4231_WRITE8(cs4231_chip, cs4231_chip->regs + IDR, __VAL) #define READ_IAR() \ CS4231_READ8(cs4231_chip, cs4231_chip->regs + IAR) #define READ_IDR() \ CS4231_READ8(cs4231_chip, cs4231_chip->regs + IDR) /* Enable cs4231 interrupts atomically. */ static void cs4231_enable_interrupts(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; unsigned long flags; tprintk(("enabling interrupts\n")); save_flags(flags); cli(); if ((cs4231_chip->status & CS_STATUS_INTS_ON) == 0) { WRITE_IAR(0xa); WRITE_IDR(INTR_ON); cs4231_chip->status |= CS_STATUS_INTS_ON; } restore_flags(flags); } /* Disable cs4231 interrupts atomically. */ static void cs4231_disable_interrupts(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; unsigned long flags; tprintk(("disabling interrupts\n")); save_flags(flags); cli(); if ((cs4231_chip->status & CS_STATUS_INTS_ON) != 0) { WRITE_IAR(0xa); WRITE_IDR(INTR_OFF); cs4231_chip->status &= ~CS_STATUS_INTS_ON; } restore_flags(flags); } static void cs4231_enable_play(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; unsigned long flags; tprintk(("enabling play\n")); save_flags(flags); cli(); WRITE_IAR(0x9); WRITE_IDR(READ_IDR() | PEN_ENABLE); restore_flags(flags); } static void cs4231_disable_play(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; unsigned long flags; tprintk(("disabling play\n")); save_flags(flags); cli(); WRITE_IAR(0x9); WRITE_IDR(READ_IDR() & PEN_DISABLE); restore_flags(flags); } static void cs4231_enable_rec(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; unsigned long flags; tprintk(("enabling rec\n")); save_flags(flags); cli(); WRITE_IAR(0x9); WRITE_IDR(READ_IDR() | CEN_ENABLE); restore_flags(flags); } static void cs4231_disable_rec(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; unsigned long flags; tprintk(("disabling rec\n")); save_flags(flags); cli(); WRITE_IAR(0x9); WRITE_IDR(READ_IDR() & CEN_DISABLE); restore_flags(flags); } static struct cs4231_rates { int speed, bits; } cs4231_rate_table[] = { { 5512, CS4231_DFR_5512 }, { 6615, CS4231_DFR_6615 }, { 8000, CS4231_DFR_8000 }, { 9600, CS4231_DFR_9600 }, { 11025, CS4231_DFR_11025 }, { 16000, CS4231_DFR_16000 }, { 18900, CS4231_DFR_18900 }, { 22050, CS4231_DFR_22050 }, { 27429, CS4231_DFR_27429 }, { 32000, CS4231_DFR_32000 }, { 33075, CS4231_DFR_33075 }, { 37800, CS4231_DFR_37800 }, { 44100, CS4231_DFR_44100 }, { 48000, CS4231_DFR_48000 } }; #define NUM_RATES (sizeof(cs4231_rate_table) / sizeof(struct cs4231_rates)) static int cs4231_rate_to_bits(struct sparcaudio_driver *drv, int *value) { struct cs4231_rates *p = &cs4231_rate_table[0]; int i, wanted = *value; /* We try to be nice and approximate what the user asks for. */ if (wanted < 5512) wanted = 5512; if (wanted > 48000) wanted = 48000; for (i = 0; i < NUM_RATES; i++, p++) { /* Exact match? */ if (wanted == p->speed) break; /* If we're inbetween two entries, and neither is exact, * pick the closest one. */ if (wanted == p[1].speed) continue; if (wanted > p->speed && wanted < p[1].speed) { int diff1, diff2; diff1 = wanted - p->speed; diff2 = p[1].speed - wanted; if (diff2 < diff1) p++; break; } } *value = p->speed; return p->bits; } static int cs4231_encoding_to_bits(struct sparcaudio_driver *drv, int value) { int set_bits; switch (value) { case AUDIO_ENCODING_ULAW: set_bits = CS4231_DFR_ULAW; break; case AUDIO_ENCODING_ALAW: set_bits = CS4231_DFR_ALAW; break; case AUDIO_ENCODING_DVI: set_bits = CS4231_DFR_ADPCM; break; case AUDIO_ENCODING_LINEARLE: set_bits = CS4231_DFR_LINEARLE; break; case AUDIO_ENCODING_LINEAR: set_bits = CS4231_DFR_LINEARBE; break; case AUDIO_ENCODING_LINEAR8: set_bits = CS4231_DFR_LINEAR8; break; default: set_bits = -EINVAL; break; }; return set_bits; } static int cs4231_set_output_encoding(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int tmp_bits, set_bits; tprintk(("output encoding %d\n", value)); if (value != 0) { set_bits = cs4231_encoding_to_bits(drv, value); if (set_bits >= 0) { READ_IDR(); READ_IDR(); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x8); tmp_bits = READ_IDR(); WRITE_IDR(CHANGE_ENCODING(tmp_bits, set_bits)); READ_IDR(); READ_IDR(); CHIP_READY(); cs4231_chip->perchip_info.play.encoding = value; return 0; } } dprintk(("output enc failed\n")); return -EINVAL; } static int cs4231_get_output_encoding(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.play.encoding; } static int cs4231_set_input_encoding(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int tmp_bits, set_bits; tprintk(("input encoding %d\n", value)); if (value != 0) { set_bits = cs4231_encoding_to_bits(drv, value); if (set_bits >= 0) { READ_IDR(); READ_IDR(); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x1c); tmp_bits = READ_IDR(); WRITE_IDR(CHANGE_ENCODING(tmp_bits, set_bits)); READ_IDR(); READ_IDR(); CHIP_READY(); cs4231_chip->perchip_info.record.encoding = value; return 0; } } dprintk(("input enc failed\n")); return -EINVAL; } static int cs4231_get_input_encoding(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.record.encoding; } static int cs4231_set_output_rate(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int tmp_bits, set_bits; tprintk(("output rate %d\n", value)); if (value != 0) { set_bits = cs4231_rate_to_bits(drv, &value); if (set_bits >= 0) { READ_IDR(); READ_IDR(); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x8); tmp_bits = READ_IDR(); WRITE_IDR(CHANGE_DFR(tmp_bits, set_bits)); READ_IDR(); READ_IDR(); CHIP_READY(); cs4231_chip->perchip_info.play.sample_rate = value; tprintk(("tmp_bits[%02x] set_bits[%02x] CHANGE_DFR[%02x]\n", tmp_bits, set_bits, CHANGE_DFR(tmp_bits, set_bits))); return 0; } } dprintk(("output rate failed\n")); return -EINVAL; } static int cs4231_get_output_rate(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.play.sample_rate; } static int cs4231_set_input_rate(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int tmp_bits, set_bits; tprintk(("input rate %d\n", value)); if (value != 0) { set_bits = cs4231_rate_to_bits(drv, &value); if (set_bits >= 0) { READ_IDR(); READ_IDR(); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x1c); tmp_bits = READ_IDR(); WRITE_IDR(CHANGE_DFR(tmp_bits, set_bits)); READ_IDR(); READ_IDR(); CHIP_READY(); cs4231_chip->perchip_info.record.sample_rate = value; return 0; } } dprintk(("input rate failed\n")); return -EINVAL; } static int cs4231_get_input_rate(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.record.sample_rate; } /* Generically we support 4 channels. This hardware does 2 */ static int cs4231_set_input_channels(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int tmp_bits; tprintk(("input channels %d\n", value)); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x1c); tmp_bits = READ_IDR(); switch (value) { case 1: WRITE_IDR(CS4231_MONO_ON(tmp_bits)); break; case 2: WRITE_IDR(CS4231_STEREO_ON(tmp_bits)); break; default: dprintk(("input chan failed\n")); return -EINVAL; }; CHIP_READY(); cs4231_chip->perchip_info.record.channels = value; return 0; } static int cs4231_get_input_channels(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.record.channels; } /* Generically we support 4 channels. This hardware does 2 */ static int cs4231_set_output_channels(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int tmp_bits; tprintk(("output channels %d\n", value)); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x8); tmp_bits = READ_IDR(); switch (value) { case 1: WRITE_IDR(CS4231_MONO_ON(tmp_bits)); break; case 2: WRITE_IDR(CS4231_STEREO_ON(tmp_bits)); break; default: dprintk(("output chan failed\n")); return -EINVAL; }; CHIP_READY(); cs4231_chip->perchip_info.play.channels = value; return 0; } static int cs4231_get_output_channels(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.play.channels; } static int cs4231_get_input_precision(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.record.precision; } static int cs4231_get_output_precision(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.play.precision; } static int cs4231_set_input_precision(struct sparcaudio_driver *drv, int val) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_chip->perchip_info.record.precision = val; return cs4231_chip->perchip_info.record.precision; } static int cs4231_set_output_precision(struct sparcaudio_driver *drv, int val) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_chip->perchip_info.play.precision = val; return cs4231_chip->perchip_info.play.precision; } /* Wait until the auto calibration process has finished */ static void cs4231_ready(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; unsigned int x; WRITE_IAR(IAR_AUTOCAL_END); x = 0; do { if (READ_IDR() != IAR_NOT_READY) break; x++; } while (x <= CS_TIMEOUT); WRITE_IAR(0x0b); x = 0; do { if (READ_IDR() != AUTOCAL_IN_PROGRESS) break; x++; } while (x <= CS_TIMEOUT); } /* Set output mute */ static int cs4231_output_muted(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; tprintk(("in cs4231_output_muted: %d\n", value)); if (!value) { WRITE_IAR(0x7); WRITE_IDR(READ_IDR() & OUTCR_UNMUTE); WRITE_IAR(0x6); WRITE_IDR(READ_IDR() & OUTCR_UNMUTE); cs4231_chip->perchip_info.output_muted = 0; } else { WRITE_IAR(0x7); WRITE_IDR(READ_IDR() | OUTCR_MUTE); WRITE_IAR(0x6); WRITE_IDR(READ_IDR() | OUTCR_MUTE); cs4231_chip->perchip_info.output_muted = 1; } return 0; } static int cs4231_get_output_muted(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.output_muted; } static int cs4231_get_formats(struct sparcaudio_driver *drv) { return (AFMT_MU_LAW | AFMT_A_LAW | AFMT_U8 | AFMT_IMA_ADPCM | AFMT_S16_LE | AFMT_S16_BE); } static int cs4231_get_output_ports(struct sparcaudio_driver *drv) { return (AUDIO_LINE_OUT | AUDIO_SPEAKER | AUDIO_HEADPHONE); } static int cs4231_get_input_ports(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; /* This apparently applies only to APC ultras, not ebus ultras */ if (cs4231_chip->status & CS_STATUS_IS_ULTRA) return (AUDIO_LINE_IN | AUDIO_MICROPHONE | AUDIO_ANALOG_LOOPBACK); else return (AUDIO_INTERNAL_CD_IN | AUDIO_LINE_IN | AUDIO_MICROPHONE | AUDIO_ANALOG_LOOPBACK); } /* Set chip "output" port */ static int cs4231_set_output_port(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int retval = 0; tprintk(("output port: %d\n", value)); /* Aaaaaah! It's all coming so fast! Turn it all off, then selectively * enable things. */ WRITE_IAR(0x1a); WRITE_IDR(READ_IDR() | MONO_IOCR_MUTE); WRITE_IAR(0x0a); WRITE_IDR(READ_IDR() | PINCR_LINE_MUTE); WRITE_IDR(READ_IDR() | PINCR_HDPH_MUTE); if (value & AUDIO_SPEAKER) { WRITE_IAR(0x1a); WRITE_IDR(READ_IDR() & ~MONO_IOCR_MUTE); retval |= AUDIO_SPEAKER; } if (value & AUDIO_HEADPHONE) { WRITE_IAR(0x0a); WRITE_IDR(READ_IDR() & ~PINCR_HDPH_MUTE); retval |= AUDIO_HEADPHONE; } if (value & AUDIO_LINE_OUT) { WRITE_IAR(0x0a); WRITE_IDR(READ_IDR() & ~PINCR_LINE_MUTE); retval |= AUDIO_LINE_OUT; } cs4231_chip->perchip_info.play.port = retval; return (retval); } static int cs4231_get_output_port(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.play.port; } /* Set chip "input" port */ static int cs4231_set_input_port(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int retval = 0; tprintk(("input port: %d\n", value)); /* You can have one and only one. This is probably wrong, but * appears to be how SunOS is doing it. Should be able to mix. * More work to be done. CD input mixable, analog loopback may be. */ /* Ultra systems do not support AUDIO_INTERNAL_CD_IN */ /* This apparently applies only to APC ultras, not ebus ultras */ if (!(cs4231_chip->status & CS_STATUS_IS_ULTRA)) { if (value & AUDIO_INTERNAL_CD_IN) { WRITE_IAR(0x1); WRITE_IDR(CDROM_ENABLE(READ_IDR())); WRITE_IAR(0x0); WRITE_IDR(CDROM_ENABLE(READ_IDR())); retval = AUDIO_INTERNAL_CD_IN; } } if ((value & AUDIO_LINE_IN)) { WRITE_IAR(0x1); WRITE_IDR(LINE_ENABLE(READ_IDR())); WRITE_IAR(0x0); WRITE_IDR(LINE_ENABLE(READ_IDR())); retval = AUDIO_LINE_IN; } else if (value & AUDIO_MICROPHONE) { WRITE_IAR(0x1); WRITE_IDR(MIC_ENABLE(READ_IDR())); WRITE_IAR(0x0); WRITE_IDR(MIC_ENABLE(READ_IDR())); retval = AUDIO_MICROPHONE; } else if (value & AUDIO_ANALOG_LOOPBACK) { WRITE_IAR(0x1); WRITE_IDR(OUTPUTLOOP_ENABLE(READ_IDR())); WRITE_IAR(0x0); WRITE_IDR(OUTPUTLOOP_ENABLE(READ_IDR())); retval = AUDIO_ANALOG_LOOPBACK; } cs4231_chip->perchip_info.record.port = retval; return retval; } static int cs4231_get_input_port(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.record.port; } /* Set chip "monitor" gain */ static int cs4231_set_monitor_volume(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int a = 0; tprintk(("monitor gain: %d\n", value)); /* This interpolation really sucks. The question is, be compatible * with ScumOS/Sloaris or not? */ a = CS4231_MON_MAX_ATEN - (value * (CS4231_MON_MAX_ATEN + 1) / (AUDIO_MAX_GAIN + 1)); WRITE_IAR(0x0d); if (a >= CS4231_MON_MAX_ATEN) WRITE_IDR(LOOPB_OFF); else WRITE_IDR((a << 2) | LOOPB_ON); if (value == AUDIO_MAX_GAIN) cs4231_chip->perchip_info.monitor_gain = AUDIO_MAX_GAIN; else cs4231_chip->perchip_info.monitor_gain = ((CS4231_MAX_DEV_ATEN - a) * (AUDIO_MAX_GAIN + 1) / (CS4231_MAX_DEV_ATEN + 1)); return 0; } static int cs4231_get_monitor_volume(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return (int) cs4231_chip->perchip_info.monitor_gain; } static int cs4231_get_output_error(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return (int) cs4231_chip->perchip_info.play.error; } static int cs4231_get_input_error(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return (int) cs4231_chip->perchip_info.record.error; } #ifdef EB4231_SUPPORT static int eb4231_get_output_samples(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dbcr = readl(cs4231_chip->eb2p + EBDMA_COUNT); int count = cs4231_length_to_samplecount(&cs4231_chip->perchip_info.play, dbcr); return (cs4231_chip->perchip_info.play.samples - ((count > cs4231_chip->perchip_info.play.samples) ? 0 : count)); } static int eb4231_get_input_samples(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dbcr = readl(cs4231_chip->eb2c + EBDMA_COUNT); int count = cs4231_length_to_samplecount(&cs4231_chip->perchip_info.record, dbcr); return (cs4231_chip->perchip_info.record.samples - ((count > cs4231_chip->perchip_info.record.samples) ? 0 : count)); } #endif static int cs4231_get_output_samples(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dmapc = sbus_readl(cs4231_chip->regs + APCPC); int count = cs4231_length_to_samplecount(&cs4231_chip->perchip_info.play, dmapc); return (cs4231_chip->perchip_info.play.samples - ((count > cs4231_chip->perchip_info.play.samples) ? 0 : count)); } static int cs4231_get_input_samples(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dmacc = sbus_readl(cs4231_chip->regs + APCCC); int count = cs4231_length_to_samplecount(&cs4231_chip->perchip_info.record, dmacc); return (cs4231_chip->perchip_info.record.samples - ((count > cs4231_chip->perchip_info.record.samples) ? 0 : count)); } static int cs4231_get_output_pause(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return (int) cs4231_chip->perchip_info.play.pause; } static int cs4231_get_input_pause(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return (int) cs4231_chip->perchip_info.record.pause; } /* But for play/record we have these cheesy jacket routines because of * how this crap gets set. */ static int cs4231_set_input_volume(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_record_gain(drv, value, cs4231_chip->perchip_info.record.balance); return 0; } static int cs4231_get_input_volume(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return (int) cs4231_chip->perchip_info.record.gain; } static int cs4231_set_output_volume(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_play_gain(drv, value, cs4231_chip->perchip_info.play.balance); return 0; } static int cs4231_get_output_volume(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return cs4231_chip->perchip_info.play.gain; } /* Likewise for balance */ static int cs4231_set_input_balance(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_chip->perchip_info.record.balance = value; cs4231_record_gain(drv, cs4231_chip->perchip_info.record.gain, cs4231_chip->perchip_info.record.balance); return 0; } static int cs4231_get_input_balance(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return (int) cs4231_chip->perchip_info.record.balance; } static int cs4231_set_output_balance(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_chip->perchip_info.play.balance = value; cs4231_play_gain(drv, cs4231_chip->perchip_info.play.gain, cs4231_chip->perchip_info.play.balance); return 0; } static int cs4231_get_output_balance(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; return (int) cs4231_chip->perchip_info.play.balance; } /* Set chip record gain */ static int cs4231_record_gain(struct sparcaudio_driver *drv, int value, unsigned char balance) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int tmp = 0, r, l, r_adj, l_adj; unsigned char old_gain; r = l = value; if (balance < AUDIO_MID_BALANCE) { r = (int) (value - ((AUDIO_MID_BALANCE - balance) << AUDIO_BALANCE_SHIFT)); if (r < 0) r = 0; } else if (balance > AUDIO_MID_BALANCE) { l = (int) (value - ((balance - AUDIO_MID_BALANCE) << AUDIO_BALANCE_SHIFT)); if (l < 0) l = 0; } l_adj = l * (CS4231_MAX_GAIN + 1) / (AUDIO_MAX_GAIN + 1); r_adj = r * (CS4231_MAX_GAIN + 1) / (AUDIO_MAX_GAIN + 1); WRITE_IAR(0x0); old_gain = READ_IDR(); WRITE_IDR(RECGAIN_SET(old_gain, l_adj)); WRITE_IAR(0x1); old_gain = READ_IDR(); WRITE_IDR(RECGAIN_SET(old_gain, r_adj)); if (l == value) { (l == 0) ? (tmp = 0) : (tmp = ((l_adj + 1) * AUDIO_MAX_GAIN) / (CS4231_MAX_GAIN + 1)); } else if (r == value) { (r == 0) ? (tmp = 0) : (tmp = ((r_adj + 1) * AUDIO_MAX_GAIN) / (CS4231_MAX_GAIN + 1)); } cs4231_chip->perchip_info.record.gain = tmp; return 0; } /* Set chip play gain */ static int cs4231_play_gain(struct sparcaudio_driver *drv, int value, unsigned char balance) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int tmp = 0, r, l, r_adj, l_adj; unsigned char old_gain; tprintk(("in play_gain: %d %c\n", value, balance)); r = l = value; if (balance < AUDIO_MID_BALANCE) { r = (int) (value - ((AUDIO_MID_BALANCE - balance) << AUDIO_BALANCE_SHIFT)); if (r < 0) r = 0; } else if (balance > AUDIO_MID_BALANCE) { l = (int) (value - ((balance - AUDIO_MID_BALANCE) << AUDIO_BALANCE_SHIFT)); if (l < 0) l = 0; } (l == 0) ? (l_adj = CS4231_MAX_DEV_ATEN) : (l_adj = CS4231_MAX_ATEN - (l * (CS4231_MAX_ATEN + 1) / (AUDIO_MAX_GAIN + 1))); (r == 0) ? (r_adj = CS4231_MAX_DEV_ATEN) : (r_adj = CS4231_MAX_ATEN - (r * (CS4231_MAX_ATEN + 1) / (AUDIO_MAX_GAIN + 1))); WRITE_IAR(0x6); old_gain = READ_IDR(); WRITE_IDR(GAIN_SET(old_gain, l_adj)); WRITE_IAR(0x7); old_gain = READ_IDR(); WRITE_IDR(GAIN_SET(old_gain, r_adj)); if ((value == 0) || (value == AUDIO_MAX_GAIN)) { tmp = value; } else { if (value == l) { tmp = ((CS4231_MAX_ATEN - l_adj) * (AUDIO_MAX_GAIN + 1) / (CS4231_MAX_ATEN + 1)); } else if (value == r) { tmp = ((CS4231_MAX_ATEN - r_adj) * (AUDIO_MAX_GAIN + 1) / (CS4231_MAX_ATEN + 1)); } } cs4231_chip->perchip_info.play.gain = tmp; return 0; } /* Reset the audio chip to a sane state. */ static void cs4231_chip_reset(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; unsigned char vers; tprintk(("in cs4231_chip_reset\n")); if (cs4231_chip->status & CS_STATUS_IS_EBUS) { #ifdef EB4231_SUPPORT writel(EBUS_DCSR_RESET, cs4231_chip->eb2p + EBDMA_CSR); writel(EBUS_DCSR_RESET, cs4231_chip->eb2c + EBDMA_CSR); writel(EBUS_DCSR_BURST_SZ_16, cs4231_chip->eb2p + EBDMA_CSR); writel(EBUS_DCSR_BURST_SZ_16, cs4231_chip->eb2c + EBDMA_CSR); #endif } else { u32 tmp; sbus_writel(APC_CHIP_RESET, cs4231_chip->regs + APCCSR); sbus_writel(0x00, cs4231_chip->regs + APCCSR); tmp = sbus_readl(cs4231_chip->regs + APCCSR); tmp |= APC_CDC_RESET; sbus_writel(tmp, cs4231_chip->regs + APCCSR); udelay(20); tmp = sbus_readl(cs4231_chip->regs + APCCSR); tmp &= ~(APC_CDC_RESET); sbus_writel(tmp, cs4231_chip->regs + APCCSR); } WRITE_IAR(READ_IAR() | IAR_AUTOCAL_BEGIN); CHIP_READY(); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x0c); WRITE_IDR(MISC_IR_MODE2); /* This is the equivalent of DEFAULT_DATA_FMAT */ cs4231_set_input_encoding(drv, AUDIO_ENCODING_ULAW); cs4231_set_input_rate(drv, CS4231_RATE); cs4231_set_input_channels(drv, CS4231_CHANNELS); cs4231_set_input_precision(drv, CS4231_PRECISION); cs4231_set_output_encoding(drv, AUDIO_ENCODING_ULAW); cs4231_set_output_rate(drv, CS4231_RATE); cs4231_set_output_channels(drv, CS4231_CHANNELS); cs4231_set_output_precision(drv, CS4231_PRECISION); WRITE_IAR(0x19); /* see what we can turn on */ vers = READ_IDR(); if (vers & CS4231A) { tprintk(("This is a CS4231A\n")); cs4231_chip->status |= CS_STATUS_REV_A; } else { cs4231_chip->status &= ~CS_STATUS_REV_A; } WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x10); WRITE_IDR(OLB_ENABLE); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x11); if (cs4231_chip->status & CS_STATUS_REV_A) WRITE_IDR(HPF_ON | XTALE_ON); else WRITE_IDR(HPF_ON); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x1a); WRITE_IDR(0x00); /* Now set things up for defaults */ cs4231_set_input_balance(drv, AUDIO_MID_BALANCE); cs4231_set_output_balance(drv, AUDIO_MID_BALANCE); cs4231_set_input_volume(drv, CS4231_DEFAULT_RECGAIN); cs4231_set_output_volume(drv, CS4231_DEFAULT_PLAYGAIN); cs4231_set_input_port(drv, AUDIO_MICROPHONE); cs4231_set_output_port(drv, AUDIO_SPEAKER); cs4231_set_monitor_volume(drv, LOOPB_OFF); WRITE_IAR(IAR_AUTOCAL_END); cs4231_ready(drv); WRITE_IAR(IAR_AUTOCAL_BEGIN | 0x09); WRITE_IDR(READ_IDR() & ACAL_DISABLE); WRITE_IAR(IAR_AUTOCAL_END); cs4231_ready(drv); cs4231_output_muted(drv, 0); cs4231_chip->recording_count = 0; cs4231_chip->input_next_dma_handle = 0; cs4231_chip->input_dma_handle = 0; cs4231_chip->input_next_dma_size = 0; cs4231_chip->input_dma_size = 0; cs4231_chip->playing_count = 0; cs4231_chip->output_next_dma_handle = 0; cs4231_chip->output_dma_handle = 0; cs4231_chip->output_next_dma_size = 0; cs4231_chip->output_dma_size = 0; } static int cs4231_length_to_samplecount(struct audio_prinfo *thisdir, unsigned int length) { unsigned int count; if (thisdir->channels == 2) count = (length / 2); else count = length; if (thisdir->encoding == AUDIO_ENCODING_LINEAR) count = (count / 2); else if (thisdir->encoding == AUDIO_ENCODING_DVI) count = (count / 4); return count; } #ifdef EB4231_SUPPORT static void eb4231_getsamplecount(struct sparcaudio_driver *drv, unsigned int length, unsigned int direction) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; struct audio_prinfo *thisdir; unsigned int count, curcount, nextcount, dbcr; if(direction == 1) { thisdir = &cs4231_chip->perchip_info.record; dbcr = readl(cs4231_chip->eb2c + EBDMA_COUNT); nextcount = cs4231_chip->input_next_dma_size; } else { thisdir = &cs4231_chip->perchip_info.play; dbcr = readl(cs4231_chip->eb2p + EBDMA_COUNT); nextcount = cs4231_chip->output_next_dma_size; } curcount = cs4231_length_to_samplecount(thisdir, dbcr); count = thisdir->samples; length = cs4231_length_to_samplecount(thisdir, length); /* normalize for where we are. */ thisdir->samples = ((count - nextcount) + (length - curcount)); } #endif static void cs4231_getsamplecount(struct sparcaudio_driver *drv, unsigned int length, unsigned int direction) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; struct audio_prinfo *thisdir; unsigned int count, nextcount, curcount; u32 tmp; if (direction == 1) { /* record */ thisdir = &cs4231_chip->perchip_info.record; tmp = sbus_readl(cs4231_chip->regs + APCCC); curcount = cs4231_length_to_samplecount(thisdir, tmp); tmp = sbus_readl(cs4231_chip->regs + APCCNC); nextcount = cs4231_length_to_samplecount(thisdir, tmp); } else { /* play */ thisdir = &cs4231_chip->perchip_info.play; tmp = sbus_readl(cs4231_chip->regs + APCPC); curcount = cs4231_length_to_samplecount(thisdir, tmp); tmp = sbus_readl(cs4231_chip->regs + APCPNC); nextcount = cs4231_length_to_samplecount(thisdir, tmp); } count = thisdir->samples; length = cs4231_length_to_samplecount(thisdir, length); /* normalize for where we are. */ thisdir->samples = ((count - nextcount) + (length - curcount)); } static int cs4231_open(struct inode * inode, struct file * file, struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; /* Set the default audio parameters if not already in use. */ if (file->f_mode & FMODE_WRITE) { if (!(drv->flags & SDF_OPEN_WRITE) && (cs4231_chip->perchip_info.play.active == 0)) { cs4231_chip->perchip_info.play.open = 1; cs4231_chip->perchip_info.play.samples = cs4231_chip->perchip_info.play.error = 0; } } if (file->f_mode & FMODE_READ) { if (!(drv->flags & SDF_OPEN_READ) && (cs4231_chip->perchip_info.record.active == 0)) { cs4231_chip->perchip_info.record.open = 1; cs4231_chip->perchip_info.record.samples = cs4231_chip->perchip_info.record.error = 0; } } cs4231_ready(drv); CHIP_READY(); MOD_INC_USE_COUNT; return 0; } static void cs4231_release(struct inode * inode, struct file * file, struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *)drv->private; void (*dma_unmap_single)(struct sbus_dev *, dma_addr_t, size_t, int) = sbus_unmap_single; #ifdef EB4231_SUPPORT if (cs4231_chip->status & CS_STATUS_IS_EBUS) dma_unmap_single = (void (*)(struct sbus_dev *, dma_addr_t, size_t, int)) pci_unmap_single; #endif /* zero out any info about what data we have as well */ if (file->f_mode & FMODE_READ) { /* stop capture here or midlevel? */ cs4231_chip->perchip_info.record.open = 0; if (cs4231_chip->input_dma_handle) { dma_unmap_single(drv->dev, cs4231_chip->input_dma_handle, cs4231_chip->input_dma_size, SBUS_DMA_FROMDEVICE); cs4231_chip->input_dma_handle = 0; cs4231_chip->input_dma_size = 0; } if (cs4231_chip->input_next_dma_handle) { dma_unmap_single(drv->dev, cs4231_chip->input_next_dma_handle, cs4231_chip->input_next_dma_size, SBUS_DMA_FROMDEVICE); cs4231_chip->input_next_dma_handle = 0; cs4231_chip->input_next_dma_size = 0; } } if (file->f_mode & FMODE_WRITE) { cs4231_chip->perchip_info.play.active = cs4231_chip->perchip_info.play.open = 0; if (cs4231_chip->output_dma_handle) { dma_unmap_single(drv->dev, cs4231_chip->output_dma_handle, cs4231_chip->output_dma_size, SBUS_DMA_TODEVICE); cs4231_chip->output_dma_handle = 0; cs4231_chip->output_dma_size = 0; } if (cs4231_chip->output_next_dma_handle) { dma_unmap_single(drv->dev, cs4231_chip->output_next_dma_handle, cs4231_chip->output_next_dma_size, SBUS_DMA_TODEVICE); cs4231_chip->output_next_dma_handle = 0; cs4231_chip->output_next_dma_size = 0; } } if (!cs4231_chip->perchip_info.play.open && !cs4231_chip->perchip_info.record.open && (cs4231_chip->status & CS_STATUS_INIT_ON_CLOSE)) { cs4231_chip_reset(drv); cs4231_chip->status &= ~CS_STATUS_INIT_ON_CLOSE; } MOD_DEC_USE_COUNT; } static void cs4231_playintr(struct sparcaudio_driver *drv, int push) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int status = 0; if (!push) { if (!cs4231_chip->perchip_info.play.active) { sbus_writel(cs4231_chip->output_next_dma_handle, cs4231_chip->regs + APCPNVA); sbus_writel(cs4231_chip->output_next_dma_size, cs4231_chip->regs + APCPNC); } sparcaudio_output_done(drv, 0); return; } if (cs4231_chip->playlen == 0 && cs4231_chip->output_size > 0) cs4231_chip->playlen = cs4231_chip->output_size; if (cs4231_chip->output_dma_handle) { sbus_unmap_single(drv->dev, cs4231_chip->output_dma_handle, cs4231_chip->output_dma_size, SBUS_DMA_TODEVICE); cs4231_chip->output_dma_handle = 0; cs4231_chip->output_dma_size = 0; cs4231_chip->playing_count--; status++; } if (cs4231_chip->output_next_dma_handle) { cs4231_chip->output_dma_handle = cs4231_chip->output_next_dma_handle; cs4231_chip->output_dma_size = cs4231_chip->output_next_dma_size; cs4231_chip->output_next_dma_size = 0; cs4231_chip->output_next_dma_handle = 0; } if ((cs4231_chip->output_ptr && cs4231_chip->output_size > 0) && !(cs4231_chip->perchip_info.play.pause)) { cs4231_chip->output_next_dma_handle = sbus_map_single(drv->dev, (char *)cs4231_chip->output_ptr, cs4231_chip->output_size, SBUS_DMA_TODEVICE); cs4231_chip->output_next_dma_size = cs4231_chip->output_size; sbus_writel(cs4231_chip->output_next_dma_handle, cs4231_chip->regs + APCPNVA); sbus_writel(cs4231_chip->output_next_dma_size, cs4231_chip->regs + APCPNC); cs4231_chip->output_size = 0; cs4231_chip->output_ptr = NULL; cs4231_chip->playing_count++; status += 2; } else { sbus_writel(0, cs4231_chip->regs + APCPNVA); sbus_writel(0, cs4231_chip->regs + APCPNC); } sparcaudio_output_done(drv, status); } #ifdef EB4231_SUPPORT static void eb4231_playintr(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int status = 0; if (cs4231_chip->playlen == 0 && cs4231_chip->output_size > 0) cs4231_chip->playlen = cs4231_chip->output_size; if (cs4231_chip->output_dma_handle) { pci_unmap_single((struct pci_dev *)drv->dev, cs4231_chip->output_dma_handle, cs4231_chip->output_dma_size, PCI_DMA_TODEVICE); cs4231_chip->output_dma_handle = 0; cs4231_chip->output_dma_size = 0; cs4231_chip->playing_count--; status++; } if(cs4231_chip->output_next_dma_handle) { cs4231_chip->output_dma_handle = cs4231_chip->output_next_dma_handle; cs4231_chip->output_dma_size = cs4231_chip->output_next_dma_size; cs4231_chip->output_next_dma_handle = 0; cs4231_chip->output_next_dma_size = 0; } if ((cs4231_chip->output_ptr && cs4231_chip->output_size > 0) && !(cs4231_chip->perchip_info.play.pause)) { cs4231_chip->output_next_dma_handle = pci_map_single((struct pci_dev *)drv->dev, (char *)cs4231_chip->output_ptr, cs4231_chip->output_size, PCI_DMA_TODEVICE); cs4231_chip->output_next_dma_size = cs4231_chip->output_size; writel(cs4231_chip->output_next_dma_size, cs4231_chip->eb2p + EBDMA_COUNT); writel(cs4231_chip->output_next_dma_handle, cs4231_chip->eb2p + EBDMA_ADDR); cs4231_chip->output_size = 0; cs4231_chip->output_ptr = NULL; cs4231_chip->playing_count++; status += 2; } sparcaudio_output_done(drv, status); } #endif static void cs4231_recclear(int fmt, char *dmabuf, int length) { switch (fmt) { case AUDIO_ENCODING_LINEAR: memset(dmabuf, 0x00, length); break; case AUDIO_ENCODING_ALAW: memset(dmabuf, 0xd5, length); break; case AUDIO_ENCODING_ULAW: memset(dmabuf, 0xff, length); break; } } static int cs4231_recintr(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int status = 0; if (cs4231_chip->perchip_info.record.active == 0) { dprintk(("going inactive\n")); cs4231_pollinput(drv); cs4231_disable_rec(drv); } if (cs4231_chip->input_dma_handle) { sbus_unmap_single(drv->dev, cs4231_chip->input_dma_handle, cs4231_chip->input_dma_size, SBUS_DMA_FROMDEVICE); cs4231_chip->input_dma_handle = 0; cs4231_chip->input_dma_size = 0; cs4231_chip->recording_count--; status++; } if (cs4231_chip->input_next_dma_handle) { cs4231_chip->input_dma_handle = cs4231_chip->input_next_dma_handle; cs4231_chip->input_dma_size = cs4231_chip->input_next_dma_size; cs4231_chip->input_next_dma_size = 0; cs4231_chip->input_next_dma_handle = 0; } if ((cs4231_chip->input_ptr && cs4231_chip->input_size > 0) && !(cs4231_chip->perchip_info.record.pause)) { cs4231_recclear(cs4231_chip->perchip_info.record.encoding, (char *)cs4231_chip->input_ptr, cs4231_chip->input_size); cs4231_chip->input_next_dma_handle = sbus_map_single(drv->dev, (char *)cs4231_chip->input_ptr, cs4231_chip->input_size, SBUS_DMA_FROMDEVICE); cs4231_chip->input_next_dma_size = cs4231_chip->input_size; sbus_writel(cs4231_chip->input_next_dma_handle, cs4231_chip->regs + APCCNVA); sbus_writel(cs4231_chip->input_next_dma_size, cs4231_chip->regs + APCCNC); cs4231_chip->input_size = 0; cs4231_chip->input_ptr = NULL; cs4231_chip->recording_count++; status += 2; } else { sbus_writel(0, cs4231_chip->regs + APCCNVA); sbus_writel(0, cs4231_chip->regs + APCCNC); } sparcaudio_input_done(drv, status); return 1; } #ifdef EB4231_SUPPORT static int eb4231_recintr(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int status = 0; if (cs4231_chip->perchip_info.record.active == 0) { dprintk(("going inactive\n")); eb4231_pollinput(drv); cs4231_disable_rec(drv); } if (cs4231_chip->input_dma_handle) { pci_unmap_single((struct pci_dev *)drv->dev, cs4231_chip->input_dma_handle, cs4231_chip->input_dma_size, PCI_DMA_FROMDEVICE); cs4231_chip->input_dma_handle = 0; cs4231_chip->input_dma_size = 0; cs4231_chip->recording_count--; status++; } if (cs4231_chip->input_next_dma_handle) { cs4231_chip->input_dma_handle = cs4231_chip->input_next_dma_handle; cs4231_chip->input_dma_size = cs4231_chip->input_next_dma_size; cs4231_chip->input_next_dma_size = 0; cs4231_chip->input_next_dma_handle = 0; } if ((cs4231_chip->input_ptr && cs4231_chip->input_size > 0) && !(cs4231_chip->perchip_info.record.pause)) { cs4231_recclear(cs4231_chip->perchip_info.record.encoding, (char *)cs4231_chip->input_ptr, cs4231_chip->input_size); cs4231_chip->input_next_dma_handle = pci_map_single((struct pci_dev *)drv->dev, (char *)cs4231_chip->input_ptr, cs4231_chip->input_size, PCI_DMA_FROMDEVICE); cs4231_chip->input_next_dma_size = cs4231_chip->input_size; writel(cs4231_chip->input_next_dma_size, cs4231_chip->eb2c + EBDMA_COUNT); writel(cs4231_chip->input_next_dma_handle, cs4231_chip->eb2c + EBDMA_ADDR); cs4231_chip->input_size = 0; cs4231_chip->input_ptr = NULL; cs4231_chip->recording_count++; status += 2; } sparcaudio_input_done(drv, status); return 1; } #endif #ifdef EB4231_SUPPORT static void eb4231_start_output(struct sparcaudio_driver *drv, __u8 * buffer, unsigned long count) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dcsr; cs4231_chip->output_ptr = buffer; cs4231_chip->output_size = count; if (cs4231_chip->perchip_info.play.active || (cs4231_chip->perchip_info.play.pause)) return; cs4231_ready(drv); cs4231_chip->perchip_info.play.active = 1; cs4231_chip->playing_count = 0; dcsr = readl(cs4231_chip->eb2p + EBDMA_CSR); if (!(dcsr & EBUS_DCSR_EN_DMA)) { writel(EBUS_DCSR_RESET, cs4231_chip->eb2p + EBDMA_CSR); writel(EBUS_DCSR_BURST_SZ_16, cs4231_chip->eb2p + EBDMA_CSR); eb4231_playintr(drv); writel(EBUS_DCSR_BURST_SZ_16 | (EBUS_DCSR_EN_DMA | EBUS_DCSR_INT_EN | EBUS_DCSR_EN_CNT | EBUS_DCSR_EN_NEXT), cs4231_chip->eb2p + EBDMA_CSR); cs4231_enable_play(drv); cs4231_ready(drv); } else { eb4231_playintr(drv); } } #endif static void cs4231_start_output(struct sparcaudio_driver *drv, __u8 * buffer, unsigned long count) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 csr; tprintk(("in 4231 start output\n")); cs4231_chip->output_ptr = buffer; cs4231_chip->output_size = count; if (cs4231_chip->perchip_info.play.active || (cs4231_chip->perchip_info.play.pause)) return; cs4231_ready(drv); cs4231_chip->perchip_info.play.active = 1; cs4231_chip->playing_count = 0; csr = sbus_readl(cs4231_chip->regs + APCCSR); if ((csr & APC_PPAUSE) || !(csr & APC_PDMA_READY)) { u32 pnva; csr &= ~APC_XINT_PLAY; sbus_writel(csr, cs4231_chip->regs + APCCSR); csr &= ~APC_PPAUSE; sbus_writel(csr, cs4231_chip->regs + APCCSR); pnva = sbus_readl(cs4231_chip->regs + APCPNVA); cs4231_playintr(drv, (pnva == 0) ? 1 : 0); csr |= APC_PLAY_SETUP; sbus_writel(csr, cs4231_chip->regs + APCCSR); cs4231_enable_play(drv); cs4231_ready(drv); } } #ifdef EB4231_SUPPORT static void eb4231_stop_output(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dcsr; dprintk(("eb4231_stop_output: dcsr 0x%x dacr 0x%x dbcr %d\n", readl(cs4231_chip->eb2p + EBDMA_CSR), readl(cs4231_chip->eb2p + EBDMA_ADDR), readl(cs4231_chip->eb2p + EBDMA_COUNT))); cs4231_chip->output_ptr = NULL; cs4231_chip->output_size = 0; if (cs4231_chip->output_dma_handle) { pci_unmap_single((struct pci_dev *)drv->dev, cs4231_chip->output_dma_handle, cs4231_chip->output_dma_size, PCI_DMA_TODEVICE); cs4231_chip->output_dma_handle = 0; cs4231_chip->output_dma_size = 0; } if (cs4231_chip->output_next_dma_handle) { pci_unmap_single((struct pci_dev *)drv->dev, cs4231_chip->output_next_dma_handle, cs4231_chip->output_next_dma_size, PCI_DMA_TODEVICE); cs4231_chip->output_next_dma_handle = 0; cs4231_chip->output_next_dma_size = 0; } dcsr = readl(cs4231_chip->eb2p + EBDMA_CSR); if(dcsr & EBUS_DCSR_EN_DMA) writel(dcsr & ~EBUS_DCSR_EN_DMA, cs4231_chip->eb2p + EBDMA_CSR); /* Else subsequent speed setting changes are ignored by the chip. */ cs4231_disable_play(drv); } #endif static void cs4231_stop_output(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; tprintk(("in cs4231_stop_output\n")); cs4231_chip->output_ptr = NULL; cs4231_chip->output_size = 0; if (cs4231_chip->output_dma_handle) { sbus_unmap_single(drv->dev, cs4231_chip->output_dma_handle, cs4231_chip->output_dma_size, SBUS_DMA_TODEVICE); cs4231_chip->output_dma_handle = 0; cs4231_chip->output_dma_size = 0; } if (cs4231_chip->output_next_dma_handle) { sbus_unmap_single(drv->dev, cs4231_chip->output_next_dma_handle, cs4231_chip->output_next_dma_size, SBUS_DMA_TODEVICE); cs4231_chip->output_next_dma_handle = 0; cs4231_chip->output_next_dma_size = 0; } #if 0 /* Not safe without shutting off the DMA controller as well. -DaveM */ /* Else subsequent speed setting changes are ignored by the chip. */ cs4231_disable_play(drv); #endif } #ifdef EB4231_SUPPORT static void eb4231_pollinput(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int x; u32 dcsr; x = 0; do { dcsr = readl(cs4231_chip->eb2c + EBDMA_CSR); if (dcsr & EBUS_DCSR_TC) break; x++; } while (x <= CS_TIMEOUT); writel(dcsr | EBUS_DCSR_TC, cs4231_chip->eb2c + EBDMA_CSR); } #endif static void cs4231_pollinput(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int x; u32 csr; x = 0; do { csr = sbus_readl(cs4231_chip->regs + APCCSR); if (csr & APC_XINT_COVF) break; x++; } while (x <= CS_TIMEOUT); sbus_writel(csr | APC_XINT_CEMP, cs4231_chip->regs + APCCSR); } static void cs4231_start_input(struct sparcaudio_driver *drv, __u8 * buffer, unsigned long count) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 csr; cs4231_chip->input_ptr = buffer; cs4231_chip->input_size = count; if (cs4231_chip->perchip_info.record.active || (cs4231_chip->perchip_info.record.pause)) return; cs4231_ready(drv); cs4231_chip->perchip_info.record.active = 1; cs4231_chip->recording_count = 0; csr = sbus_readl(cs4231_chip->regs + APCCSR); if ((csr & APC_CPAUSE) || !(csr & APC_CDMA_READY)) { csr &= ~APC_XINT_CAPT; sbus_writel(csr, cs4231_chip->regs + APCCSR); csr &= ~APC_CPAUSE; sbus_writel(csr, cs4231_chip->regs + APCCSR); cs4231_recintr(drv); csr |= APC_CAPT_SETUP; sbus_writel(csr, cs4231_chip->regs + APCCSR); cs4231_enable_rec(drv); cs4231_ready(drv); } else { cs4231_recintr(drv); } } static void cs4231_stop_input(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 csr; cs4231_chip->perchip_info.record.active = 0; csr = sbus_readl(cs4231_chip->regs + APCCSR); csr |= APC_CPAUSE; sbus_writel(csr, cs4231_chip->regs + APCCSR); cs4231_chip->input_ptr = NULL; cs4231_chip->input_size = 0; if (cs4231_chip->input_dma_handle) { sbus_unmap_single(drv->dev, cs4231_chip->input_dma_handle, cs4231_chip->input_dma_size, SBUS_DMA_FROMDEVICE); cs4231_chip->input_dma_handle = 0; cs4231_chip->input_dma_size = 0; } if (cs4231_chip->input_next_dma_handle) { sbus_unmap_single(drv->dev, cs4231_chip->input_next_dma_handle, cs4231_chip->input_next_dma_size, SBUS_DMA_FROMDEVICE); cs4231_chip->input_next_dma_handle = 0; cs4231_chip->input_next_dma_size = 0; } cs4231_pollinput(drv); } #ifdef EB4231_SUPPORT static void eb4231_start_input(struct sparcaudio_driver *drv, __u8 * buffer, unsigned long count) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dcsr; cs4231_chip->input_ptr = buffer; cs4231_chip->input_size = count; if (cs4231_chip->perchip_info.record.active || (cs4231_chip->perchip_info.record.pause)) return; cs4231_ready(drv); cs4231_chip->perchip_info.record.active = 1; cs4231_chip->recording_count = 0; dcsr = readl(cs4231_chip->eb2c + EBDMA_CSR); if (!(dcsr & EBUS_DCSR_EN_DMA)) { writel(EBUS_DCSR_RESET, cs4231_chip->eb2c + EBDMA_CSR); writel(EBUS_DCSR_BURST_SZ_16, cs4231_chip->eb2c + EBDMA_CSR); eb4231_recintr(drv); writel(EBUS_DCSR_BURST_SZ_16 | (EBUS_DCSR_EN_DMA | EBUS_DCSR_INT_EN | EBUS_DCSR_EN_CNT | EBUS_DCSR_EN_NEXT), cs4231_chip->eb2c + EBDMA_CSR); cs4231_enable_rec(drv); cs4231_ready(drv); } else { eb4231_recintr(drv); } } static void eb4231_stop_input(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dcsr; cs4231_chip->perchip_info.record.active = 0; cs4231_chip->input_ptr = NULL; cs4231_chip->input_size = 0; if (cs4231_chip->input_dma_handle) { pci_unmap_single((struct pci_dev *)drv->dev, cs4231_chip->input_dma_handle, cs4231_chip->input_dma_size, PCI_DMA_FROMDEVICE); cs4231_chip->input_dma_handle = 0; cs4231_chip->input_dma_size = 0; } if (cs4231_chip->input_next_dma_handle) { pci_unmap_single((struct pci_dev *)drv->dev, cs4231_chip->input_next_dma_handle, cs4231_chip->input_next_dma_size, PCI_DMA_FROMDEVICE); cs4231_chip->input_next_dma_handle = 0; cs4231_chip->input_next_dma_size = 0; } dcsr = readl(cs4231_chip->eb2c + EBDMA_CSR); if (dcsr & EBUS_DCSR_EN_DMA) writel(dcsr & ~EBUS_DCSR_EN_DMA, cs4231_chip->eb2c + EBDMA_CSR); cs4231_disable_rec(drv); } #endif static int cs4231_set_output_pause(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_chip->perchip_info.play.pause = value; if (!value) sparcaudio_output_done(drv, 0); return value; } static int cs4231_set_output_error(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int i; i = cs4231_chip->perchip_info.play.error; cs4231_chip->perchip_info.play.error = value; return i; } static int cs4231_set_input_error(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int i; i = cs4231_chip->perchip_info.record.error; cs4231_chip->perchip_info.record.error = value; return i; } static int cs4231_set_output_samples(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *)drv->private; int i; i = cs4231_chip->perchip_info.play.samples; cs4231_chip->perchip_info.play.samples = value; return i; } static int cs4231_set_input_samples(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int i; i = cs4231_chip->perchip_info.record.samples; cs4231_chip->perchip_info.record.samples = value; return i; } static int cs4231_set_input_pause(struct sparcaudio_driver *drv, int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_chip->perchip_info.record.pause = value; if (value) cs4231_stop_input(drv); return value; } static void cs4231_audio_getdev(struct sparcaudio_driver *drv, audio_device_t * audinfo) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; strncpy(audinfo->name, "SUNW,CS4231", sizeof(audinfo->name) - 1); /* versions */ /* a: SPARCstation 4/5 b: Ultra 1/2 (electron) */ /* c: Ultra 1/2 PCI? (positron) d: ppc */ /* e: x86 f: Ultra Enterprise? (tazmo) */ /* g: Ultra 30? (quark) h: Ultra 5/10? (darwin) */ /* apparently Ultra 1, Ultra 2 don't have internal CD input */ if (cs4231_chip->status & CS_STATUS_IS_ULTRA) strncpy(audinfo->version, "b", sizeof(audinfo->version) - 1); else strncpy(audinfo->version, "a", sizeof(audinfo->version) - 1); strncpy(audinfo->config, "onboard1", sizeof(audinfo->config) - 1); } static int cs4231_audio_getdev_sunos(struct sparcaudio_driver *drv) { return AUDIO_DEV_CS4231; } static void cs4231_loopback(struct sparcaudio_driver *drv, unsigned int value) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; WRITE_IAR(0x0d); WRITE_IDR(value ? LOOPB_ON : 0); } static int cs4231_ioctl(struct inode * inode, struct file * file, unsigned int cmd, unsigned long arg, struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; int retval = 0; switch (cmd) { case AUDIO_DIAG_LOOPBACK: cs4231_chip->status |= CS_STATUS_INIT_ON_CLOSE; cs4231_loopback(drv, (unsigned int)arg); break; default: retval = -EINVAL; }; return retval; } #ifdef EB4231_SUPPORT /* ebus audio capture interrupt handler. */ void eb4231_cinterrupt(int irq, void *dev_id, struct pt_regs *regs) { struct sparcaudio_driver *drv = (struct sparcaudio_driver *) dev_id; struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dummy; /* Clear the interrupt. */ dummy = readl(cs4231_chip->eb2c + EBDMA_CSR); writel(dummy, cs4231_chip->eb2c + EBDMA_CSR); if ((dummy & EBUS_DCSR_TC) != 0 /*&& (dummy & EBUS_DCSR_A_LOADED) != 0*/) { cs4231_chip->perchip_info.record.samples += cs4231_length_to_samplecount(&(cs4231_chip->perchip_info.record), cs4231_chip->reclen); eb4231_recintr(drv); } if ((dummy & EBUS_DCSR_A_LOADED) == 0) { cs4231_chip->perchip_info.record.active = 0; eb4231_recintr(drv); eb4231_getsamplecount(drv, cs4231_chip->reclen, 1); } } /* ebus audio play interrupt handler. */ void eb4231_pinterrupt(int irq, void *dev_id, struct pt_regs *regs) { struct sparcaudio_driver *drv = (struct sparcaudio_driver *) dev_id; struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; u32 dummy; /* Clear the interrupt. Bleh, when not using the next-address * feature, TC can only be cleared by a reset. */ dummy = readl(cs4231_chip->eb2p + EBDMA_CSR); writel(dummy, cs4231_chip->eb2p + EBDMA_CSR); /* If we get a terminal count and address loaded condition, * this means the DNAR was copied into DACR. */ if((dummy & EBUS_DCSR_TC) != 0 /*&& (dummy & EBUS_DCSR_A_LOADED) != 0*/) { cs4231_chip->perchip_info.play.samples += cs4231_length_to_samplecount(&(cs4231_chip->perchip_info.play), cs4231_chip->playlen); eb4231_playintr(drv); } if((dummy & EBUS_DCSR_A_LOADED) == 0) { cs4231_chip->perchip_info.play.active = 0; eb4231_playintr(drv); eb4231_getsamplecount(drv, cs4231_chip->playlen, 0); } } #endif /* Audio interrupt handler. */ void cs4231_interrupt(int irq, void *dev_id, struct pt_regs *regs) { struct sparcaudio_driver *drv = (struct sparcaudio_driver *) dev_id; struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; __u32 dummy; dprintk(("in cs4231_interrupt\n")); /* Clear the interrupt. */ dummy = sbus_readl(cs4231_chip->regs + APCCSR); sbus_writel(dummy, cs4231_chip->regs + APCCSR); /* now go through and figure out what gets to claim the interrupt * if anything since we may be doing shared interrupts */ if (dummy & APC_PLAY_INT) { if (dummy & APC_XINT_PNVA) { cs4231_chip->perchip_info.play.samples += cs4231_length_to_samplecount(&(cs4231_chip->perchip_info.play), cs4231_chip->playlen); if (!(dummy & APC_XINT_EMPT)) cs4231_playintr(drv, 1); } /* Any other conditions we need worry about? */ } if (dummy & APC_CAPT_INT) { if (dummy & APC_XINT_CNVA) { cs4231_chip->perchip_info.record.samples += cs4231_length_to_samplecount(&(cs4231_chip->perchip_info.record), cs4231_chip->reclen); cs4231_recintr(drv); } /* Any other conditions we need worry about? */ } if (dummy & APC_XINT_CEMP) { if (cs4231_chip->perchip_info.record.active == 0) { /* Fix me */ cs4231_chip->perchip_info.record.active = 0; cs4231_chip->perchip_info.record.error = 1; cs4231_recintr(drv); } } if (dummy & APC_XINT_EMPT) { if (!cs4231_chip->output_next_dma_handle) { u32 csr = sbus_readl(cs4231_chip->regs + APCCSR); csr |= APC_PPAUSE; sbus_writel(csr, cs4231_chip->regs + APCCSR); cs4231_disable_play(drv); cs4231_chip->perchip_info.play.error = 1; } cs4231_chip->perchip_info.play.active = 0; cs4231_playintr(drv, 0); cs4231_getsamplecount(drv, cs4231_chip->playlen, 0); } if (dummy & APC_GENL_INT) { /* If we get here we must be sharing an interrupt, but I haven't code * to handle this right now. */ } } static struct sparcaudio_operations cs4231_ops = { cs4231_open, cs4231_release, cs4231_ioctl, cs4231_start_output, cs4231_stop_output, cs4231_start_input, cs4231_stop_input, cs4231_audio_getdev, cs4231_set_output_volume, cs4231_get_output_volume, cs4231_set_input_volume, cs4231_get_input_volume, cs4231_set_monitor_volume, cs4231_get_monitor_volume, cs4231_set_output_balance, cs4231_get_output_balance, cs4231_set_input_balance, cs4231_get_input_balance, cs4231_set_output_channels, cs4231_get_output_channels, cs4231_set_input_channels, cs4231_get_input_channels, cs4231_set_output_precision, cs4231_get_output_precision, cs4231_set_input_precision, cs4231_get_input_precision, cs4231_set_output_port, cs4231_get_output_port, cs4231_set_input_port, cs4231_get_input_port, cs4231_set_output_encoding, cs4231_get_output_encoding, cs4231_set_input_encoding, cs4231_get_input_encoding, cs4231_set_output_rate, cs4231_get_output_rate, cs4231_set_input_rate, cs4231_get_input_rate, cs4231_audio_getdev_sunos, cs4231_get_output_ports, cs4231_get_input_ports, cs4231_output_muted, cs4231_get_output_muted, cs4231_set_output_pause, cs4231_get_output_pause, cs4231_set_input_pause, cs4231_get_input_pause, cs4231_set_output_samples, cs4231_get_output_samples, cs4231_set_input_samples, cs4231_get_input_samples, cs4231_set_output_error, cs4231_get_output_error, cs4231_set_input_error, cs4231_get_input_error, cs4231_get_formats, }; #ifdef EB4231_SUPPORT static struct sparcaudio_operations eb4231_ops = { cs4231_open, cs4231_release, cs4231_ioctl, eb4231_start_output, eb4231_stop_output, eb4231_start_input, eb4231_stop_input, cs4231_audio_getdev, cs4231_set_output_volume, cs4231_get_output_volume, cs4231_set_input_volume, cs4231_get_input_volume, cs4231_set_monitor_volume, cs4231_get_monitor_volume, cs4231_set_output_balance, cs4231_get_output_balance, cs4231_set_input_balance, cs4231_get_input_balance, cs4231_set_output_channels, cs4231_get_output_channels, cs4231_set_input_channels, cs4231_get_input_channels, cs4231_set_output_precision, cs4231_get_output_precision, cs4231_set_input_precision, cs4231_get_input_precision, cs4231_set_output_port, cs4231_get_output_port, cs4231_set_input_port, cs4231_get_input_port, cs4231_set_output_encoding, cs4231_get_output_encoding, cs4231_set_input_encoding, cs4231_get_input_encoding, cs4231_set_output_rate, cs4231_get_output_rate, cs4231_set_input_rate, cs4231_get_input_rate, cs4231_audio_getdev_sunos, cs4231_get_output_ports, cs4231_get_input_ports, cs4231_output_muted, cs4231_get_output_muted, cs4231_set_output_pause, cs4231_get_output_pause, cs4231_set_input_pause, cs4231_get_input_pause, cs4231_set_output_samples, eb4231_get_output_samples, cs4231_set_input_samples, eb4231_get_input_samples, cs4231_set_output_error, cs4231_get_output_error, cs4231_set_input_error, cs4231_get_input_error, cs4231_get_formats, }; #endif /* Attach to an cs4231 chip given its PROM node. */ static int cs4231_attach(struct sparcaudio_driver *drv, struct sbus_dev *sdev) { struct cs4231_chip *cs4231_chip; int err; /* Allocate our private information structure. */ drv->private = kmalloc(sizeof(struct cs4231_chip), GFP_KERNEL); if (drv->private == NULL) return -ENOMEM; /* Point at the information structure and initialize it. */ drv->ops = &cs4231_ops; cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_chip->input_ptr = cs4231_chip->output_ptr = NULL; cs4231_chip->input_size = cs4231_chip->output_size = 0; cs4231_chip->status = 0; drv->dev = sdev; /* Map the registers into memory. */ cs4231_chip->regs_size = sdev->reg_addrs[0].reg_size; cs4231_chip->regs = sbus_ioremap(&sdev->resource[0], 0, sdev->reg_addrs[0].reg_size, "cs4231"); if (!cs4231_chip->regs) { printk(KERN_ERR "cs4231: could not remap registers\n"); kfree(drv->private); return -EIO; } /* Attach the interrupt handler to the audio interrupt. */ cs4231_chip->irq = sdev->irqs[0]; request_irq(cs4231_chip->irq, cs4231_interrupt, SA_SHIRQ, "cs4231", drv); enable_irq(cs4231_chip->irq); cs4231_chip->nirqs = 1; cs4231_enable_interrupts(drv); /* Reset the audio chip. */ cs4231_chip_reset(drv); /* Register ourselves with the midlevel audio driver. */ err = register_sparcaudio_driver(drv, 1); if (err < 0) { printk(KERN_ERR "cs4231: unable to register\n"); cs4231_disable_interrupts(drv); disable_irq(cs4231_chip->irq); free_irq(cs4231_chip->irq, drv); sbus_iounmap(cs4231_chip->regs, cs4231_chip->regs_size); kfree(drv->private); return -EIO; } cs4231_chip->perchip_info.play.active = cs4231_chip->perchip_info.play.pause = 0; cs4231_chip->perchip_info.record.active = cs4231_chip->perchip_info.record.pause = 0; cs4231_chip->perchip_info.play.avail_ports = (AUDIO_HEADPHONE | AUDIO_SPEAKER | AUDIO_LINE_OUT); cs4231_chip->perchip_info.record.avail_ports = (AUDIO_INTERNAL_CD_IN | AUDIO_LINE_IN | AUDIO_MICROPHONE | AUDIO_ANALOG_LOOPBACK); /* Announce the hardware to the user. */ printk(KERN_INFO "audio%d: cs4231%c at %lx irq %s\n", drv->index, (cs4231_chip->status & CS_STATUS_REV_A) ? 'a' : ' ', cs4231_chip->regs, __irq_itoa(cs4231_chip->irq)); /* Success! */ return 0; } #ifdef EB4231_SUPPORT /* Attach to an cs4231 chip given its PROM node. */ static int eb4231_attach(struct sparcaudio_driver *drv, struct linux_ebus_device *edev) { struct cs4231_chip *cs4231_chip; int len, err, nregs; struct linux_prom_registers regs[4]; /* Allocate our private information structure. */ drv->private = kmalloc(sizeof(struct cs4231_chip), GFP_KERNEL); if (drv->private == NULL) return -ENOMEM; /* Point at the information structure and initialize it. */ drv->ops = &eb4231_ops; cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_chip->input_ptr = cs4231_chip->output_ptr = NULL; cs4231_chip->input_size = cs4231_chip->output_size = 0; cs4231_chip->status = 0; drv->dev = (struct sbus_dev *)edev->bus->self; len = prom_getproperty(edev->prom_node, "reg", (void *)regs, sizeof(regs)); if ((len % sizeof(regs[0])) != 0) { printk("eb4231: Strange reg property size %d\n", len); return -ENODEV; } nregs = len / sizeof(regs[0]); cs4231_chip->regs = (unsigned long)ioremap(edev->resource[0].start, 0x10); cs4231_chip->eb2p = (unsigned long)ioremap(edev->resource[1].start, 0x10); cs4231_chip->eb2c = (unsigned long)ioremap(edev->resource[2].start, 0x10); cs4231_chip->status |= CS_STATUS_IS_EBUS; /* Attach the interrupt handler to the audio interrupt. */ cs4231_chip->irq = edev->irqs[0]; cs4231_chip->irq2 = edev->irqs[1]; if(request_irq(cs4231_chip->irq, eb4231_cinterrupt, SA_SHIRQ, "cs4231", drv) || request_irq(cs4231_chip->irq2, eb4231_pinterrupt, SA_SHIRQ, "cs4231", drv)) goto bail; cs4231_chip->nirqs = 2; cs4231_enable_interrupts(drv); /* Reset the audio chip. */ cs4231_chip_reset(drv); /* Register ourselves with the midlevel audio driver. */ err = register_sparcaudio_driver(drv, 1); if (err < 0) { bail: printk(KERN_ERR "cs4231: unable to register\n"); cs4231_disable_interrupts(drv); disable_irq(cs4231_chip->irq); free_irq(cs4231_chip->irq, drv); disable_irq(cs4231_chip->irq2); free_irq(cs4231_chip->irq2, drv); kfree(drv->private); return -EIO; } cs4231_chip->perchip_info.play.active = cs4231_chip->perchip_info.play.pause = 0; cs4231_chip->perchip_info.record.active = cs4231_chip->perchip_info.record.pause = 0; cs4231_chip->perchip_info.play.avail_ports = (AUDIO_HEADPHONE | AUDIO_SPEAKER | AUDIO_LINE_OUT); cs4231_chip->perchip_info.record.avail_ports = (AUDIO_INTERNAL_CD_IN | AUDIO_LINE_IN | AUDIO_MICROPHONE | AUDIO_ANALOG_LOOPBACK); /* Announce the hardware to the user. */ printk(KERN_INFO "audio%d: cs4231%c(eb2) at %lx irq %s\n", drv->index, (cs4231_chip->status & CS_STATUS_REV_A) ? 'a' : ' ', cs4231_chip->regs, __irq_itoa(cs4231_chip->irq)); /* Success! */ return 0; } #endif #ifdef EB4231_SUPPORT static int __init ebus_cs4231_p(struct linux_ebus_device *edev) { if (!strcmp(edev->prom_name, "SUNW,CS4231")) return 1; if (!strcmp(edev->prom_name, "audio")) { char compat[16]; prom_getstring(edev->prom_node, "compatible", compat, sizeof(compat)); compat[15] = '\0'; if (!strcmp(compat, "SUNW,CS4231")) return 1; } return 0; } #endif /* Detach from an cs4231 chip given the device structure. */ static void __exit cs4231_detach(struct sparcaudio_driver *drv) { struct cs4231_chip *cs4231_chip = (struct cs4231_chip *) drv->private; cs4231_disable_interrupts(drv); unregister_sparcaudio_driver(drv, 1); disable_irq(cs4231_chip->irq); free_irq(cs4231_chip->irq, drv); if (!(cs4231_chip->status & CS_STATUS_IS_EBUS)) { sbus_iounmap(cs4231_chip->regs, cs4231_chip->regs_size); } else { #ifdef EB4231_SUPPORT iounmap(cs4231_chip->regs); iounmap(cs4231_chip->eb2p); iounmap(cs4231_chip->eb2c); disable_irq(cs4231_chip->irq2); free_irq(cs4231_chip->irq2, drv); #endif } kfree(drv->private); } /* Probe for the cs4231 chip and then attach the driver. */ static int __init cs4231_init(void) { struct sbus_bus *sbus; struct sbus_dev *sdev; #ifdef EB4231_SUPPORT struct linux_ebus *ebus; struct linux_ebus_device *edev; #endif num_drivers = 0; /* Probe each SBUS for cs4231 chips. */ for_all_sbusdev(sdev, sbus) { if (!strcmp(sdev->prom_name, "SUNW,CS4231")) { /* Don't go over the max number of drivers. */ if (num_drivers >= MAX_DRIVERS) continue; if (cs4231_attach(&drivers[num_drivers], sdev) == 0) num_drivers++; } } #ifdef EB4231_SUPPORT for_each_ebus(ebus) { for_each_ebusdev(edev, ebus) { if (ebus_cs4231_p(edev)) { /* Don't go over the max number of drivers. */ if (num_drivers >= MAX_DRIVERS) continue; if (eb4231_attach(&drivers[num_drivers], edev) == 0) num_drivers++; } } } #endif /* Only return success if we found some cs4231 chips. */ return (num_drivers > 0) ? 0 : -EIO; } static void __exit cs4231_exit(void) { register int i; for (i = 0; i < num_drivers; i++) { cs4231_detach(&drivers[i]); num_drivers--; } } module_init(cs4231_init); module_exit(cs4231_exit); MODULE_LICENSE("GPL"); /* * Overrides for Emacs so that we follow Linus's tabbing style. * Emacs will notice this stuff at the end of the file and automatically * adjust the settings for this buffer only. This must remain at the end * of the file. * --------------------------------------------------------------------------- * Local variables: * c-indent-level: 4 * c-brace-imaginary-offset: 0 * c-brace-offset: -4 * c-argdecl-indent: 4 * c-label-offset: -4 * c-continued-statement-offset: 4 * c-continued-brace-offset: 0 * indent-tabs-mode: nil * tab-width: 8 * End: */