/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * Purpose: Driver for the CMedia 8788 sound card */ /* * * Copyright (C) 4Front Technologies 1996-2011. * * This software is released under CDDL 1.0 source license. * See the COPYING file included in the main directory of this source * distribution for the license terms and conditions. */ #include #include #include #include #include #include #include #include #include #include #include #include "audiocmihd.h" static struct ddi_device_acc_attr dev_attr = { DDI_DEVICE_ATTR_V0, DDI_STRUCTURE_LE_ACC, DDI_STRICTORDER_ACC }; static struct ddi_device_acc_attr buf_attr = { DDI_DEVICE_ATTR_V0, DDI_NEVERSWAP_ACC, DDI_STRICTORDER_ACC }; static ddi_dma_attr_t dma_attr_buf = { DMA_ATTR_V0, /* version number */ 0x0, /* dma_attr_addr_lo */ 0xffffffffU, /* dma_attr_addr_hi */ 0x3ffff, /* dma_attr_count_max */ 0x8, /* dma_attr_align */ 0x7f, /* dma_attr_burstsizes */ 0x1, /* dma_attr_minxfer */ 0x3ffff, /* dma_attr_maxxfer */ 0x3ffff, /* dma_attr_seg */ 0x1, /* dma_attr_sgllen */ 0x1, /* dma_attr_granular */ 0 /* dma_attr_flags */ }; static int cmediahd_attach(dev_info_t *); static int cmediahd_resume(dev_info_t *); static int cmediahd_detach(cmediahd_devc_t *); static int cmediahd_suspend(cmediahd_devc_t *); static int cmediahd_open(void *, int, unsigned *, caddr_t *); static void cmediahd_close(void *); static int cmediahd_start(void *); static void cmediahd_stop(void *); static int cmediahd_format(void *); static int cmediahd_channels(void *); static int cmediahd_rate(void *); static uint64_t cmediahd_count(void *); static void cmediahd_sync(void *, unsigned); static void cmediahd_chinfo(void *, int, unsigned *, unsigned *); static uint16_t cmediahd_read_ac97(void *, uint8_t); static void cmediahd_write_ac97(void *, uint8_t, uint16_t); static int cmediahd_alloc_port(cmediahd_devc_t *, int); static void cmediahd_reset_port(cmediahd_portc_t *); static void cmediahd_destroy(cmediahd_devc_t *); static void cmediahd_hwinit(cmediahd_devc_t *); static void cmediahd_refresh_mixer(cmediahd_devc_t *devc); static uint32_t mix_scale(uint32_t, int8_t); static void cmediahd_ac97_hwinit(cmediahd_devc_t *); static void cmediahd_del_controls(cmediahd_devc_t *); static audio_engine_ops_t cmediahd_engine_ops = { AUDIO_ENGINE_VERSION, cmediahd_open, cmediahd_close, cmediahd_start, cmediahd_stop, cmediahd_count, cmediahd_format, cmediahd_channels, cmediahd_rate, cmediahd_sync, NULL, /* qlen */ cmediahd_chinfo, NULL /* playahead */ }; #define PLAYCTL (AUDIO_CTRL_FLAG_RW | AUDIO_CTRL_FLAG_PLAY) #define RECCTL (AUDIO_CTRL_FLAG_RW | AUDIO_CTRL_FLAG_REC) #define MONCTL (AUDIO_CTRL_FLAG_RW | AUDIO_CTRL_FLAG_MONITOR) #define PCMVOL (PLAYCTL | AUDIO_CTRL_FLAG_PCMVOL) #define MAINVOL (PLAYCTL | AUDIO_CTRL_FLAG_MAINVOL) #define RECVOL (RECCTL | AUDIO_CTRL_FLAG_RECVOL) static const char mix_cvt[101] = { 0, 0, 3, 7, 10, 13, 16, 19, 21, 23, 26, 28, 30, 32, 34, 35, 37, 39, 40, 42, 43, 45, 46, 47, 49, 50, 51, 52, 53, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 65, 66, 67, 68, 69, 70, 70, 71, 72, 73, 73, 74, 75, 75, 76, 77, 77, 78, 79, 79, 80, 81, 81, 82, 82, 83, 84, 84, 85, 85, 86, 86, 87, 87, 88, 88, 89, 89, 90, 90, 91, 91, 92, 92, 93, 93, 94, 94, 95, 95, 96, 96, 96, 97, 97, 98, 98, 98, 99, 99, 100 }; static uint32_t mix_scale(uint32_t vol, int8_t bits) { vol = mix_cvt[vol]; vol = (vol * ((1 << bits) - 1)) / 100; return (vol); } static uint16_t cmediahd_read_ac97(void *arg, uint8_t reg) { cmediahd_devc_t *devc = arg; uint32_t val; uint16_t data; mutex_enter(&devc->low_mutex); val = 0L; val |= reg << 16; val |= 0 << 24; /* codec 0 or codec 1 */ val |= 1 << 23; /* ac97 read the reg address */ OUTL(devc, val, AC97_CMD_DATA); drv_usecwait(100); data = INL(devc, AC97_CMD_DATA) & 0xFFFF; mutex_exit(&devc->low_mutex); return (data); } static void cmediahd_write_ac97(void *arg, uint8_t reg, uint16_t data) { cmediahd_devc_t *devc = arg; uint32_t val; mutex_enter(&devc->low_mutex); val = 0L; val |= reg << 16; val |= data & 0xFFFF; val |= 0 << 24; /* on board codec or frontpanel */ val |= 0 << 23; /* ac97 write operation */ OUTL(devc, val, AC97_CMD_DATA); drv_usecwait(100); mutex_exit(&devc->low_mutex); } #if 0 /* Front Panel AC'97 not supported yet */ static uint16_t cmediahd_read_fp_ac97(void *arg, uint8_t reg) { cmediahd_devc_t *devc = arg; uint32_t val; uint16_t data; mutex_enter(&devc->low_mutex); val = 0L; val |= 1 << 24; /* front panel */ val |= 1 << 23; /* ac97 read the reg address */ val |= reg << 16; OUTL(devc, val, AC97_CMD_DATA); drv_usecwait(100); data = INL(devc, AC97_CMD_DATA) & 0xFFFF; mutex_exit(&devc->low_mutex); return (data); } static void cmediahd_write_fp_ac97(void *arg, uint8_t reg, uint16_t data) { cmediahd_devc_t *devc = arg; uint32_t val; mutex_enter(&devc->low_mutex); val = 0L; val |= 1 << 24; /* frontpanel */ val |= 0 << 23; /* ac97 write operation */ val |= reg << 16; val |= data & 0xFFFF; OUTL(devc, val, AC97_CMD_DATA); drv_usecwait(100); mutex_exit(&devc->low_mutex); } #endif static void spi_write(void *arg, int codec_num, unsigned char reg, int val) { cmediahd_devc_t *devc = arg; unsigned int tmp; int latch, shift, count; mutex_enter(&devc->low_mutex); /* check if SPI is busy */ count = 10; while ((INB(devc, SPI_CONTROL) & 0x1) && count-- > 0) { drv_usecwait(10); } if (devc->model == SUBID_XONAR_DS) { shift = 9; latch = 0; } else { shift = 8; latch = 0x80; } /* 2 byte data/reg info to be written */ tmp = val; tmp |= (reg << shift); /* write 2-byte data values */ OUTB(devc, tmp & 0xff, SPI_DATA + 0); OUTB(devc, (tmp >> 8) & 0xff, SPI_DATA + 1); /* Latch high, clock=160, Len=2byte, mode=write */ tmp = (INB(devc, SPI_CONTROL) & ~0x7E) | latch | 0x1; /* now address which codec you want to send the data to */ tmp |= (codec_num << 4); /* send the command to write the data */ OUTB(devc, tmp, SPI_CONTROL); mutex_exit(&devc->low_mutex); } static void i2c_write(void *arg, unsigned char codec_num, unsigned char reg, unsigned char data) { cmediahd_devc_t *devc = arg; int count = 50; /* Wait for it to stop being busy */ mutex_enter(&devc->low_mutex); while ((INW(devc, TWO_WIRE_CTRL) & 0x1) && (count > 0)) { drv_usecwait(10); count--; } if (count == 0) { audio_dev_warn(devc->adev, "Time out on Two-Wire interface"); mutex_exit(&devc->low_mutex); return; } /* first write the Register Address into the MAP register */ OUTB(devc, reg, TWO_WIRE_MAP); /* now write the data */ OUTB(devc, data, TWO_WIRE_DATA); /* select the codec number to address */ OUTB(devc, codec_num, TWO_WIRE_ADDR); mutex_exit(&devc->low_mutex); } static void cs4398_init(void *arg, int codec) { cmediahd_devc_t *devc = arg; /* Fast Two-Wire. Reduces the wire ready time. */ OUTW(devc, 0x0100, TWO_WIRE_CTRL); /* Power down, enable control mode. */ i2c_write(devc, codec, CS4398_MISC_CTRL, CS4398_CPEN | CS4398_POWER_DOWN); /* * Left justified PCM (DAC and 8788 support I2S, but doesn't work. * Setting it introduces clipping like hell). */ i2c_write(devc, codec, CS4398_MODE_CTRL, 0x00); i2c_write(devc, codec, 3, 0x09); i2c_write(devc, codec, 4, 0x82); /* PCM Automute */ i2c_write(devc, codec, 5, 0x80); /* Vol A+B to -64dB */ i2c_write(devc, codec, 6, 0x80); i2c_write(devc, codec, 7, 0xf0); /* soft ramping on */ /* remove the powerdown flag */ i2c_write(devc, codec, CS4398_MISC_CTRL, CS4398_CPEN); } static void cs4362a_init(void *arg, int codec) { cmediahd_devc_t *devc = arg; OUTW(devc, 0x0100, TWO_WIRE_CTRL); /* Power down and enable control port. */ i2c_write(devc, codec, CS4362A_MODE1_CTRL, CS4362A_CPEN | CS4362A_POWER_DOWN); /* Left-justified PCM */ i2c_write(devc, codec, CS4362A_MODE2_CTRL, CS4362A_DIF_LJUST); /* Ramp & Automute, re-set DAC defaults. */ i2c_write(devc, codec, CS4362A_MODE3_CTRL, 0x84); /* Filter control, DAC defs. */ i2c_write(devc, codec, CS4362A_FILTER_CTRL, 0); /* Invert control, DAC defs. */ i2c_write(devc, codec, CS4362A_INVERT_CTRL, 0); /* Mixing control, DAC defs. */ i2c_write(devc, codec, CS4362A_MIX1_CTRL, 0x24); i2c_write(devc, codec, CS4362A_MIX2_CTRL, 0x24); i2c_write(devc, codec, CS4362A_MIX3_CTRL, 0x24); /* Volume to -64dB. */ i2c_write(devc, codec, CS4362A_VOLA_1, 0x40); i2c_write(devc, codec, CS4362A_VOLB_1, 0x40); i2c_write(devc, codec, CS4362A_VOLA_2, 0x40); i2c_write(devc, codec, CS4362A_VOLB_2, 0x40); i2c_write(devc, codec, CS4362A_VOLA_3, 0x40); i2c_write(devc, codec, CS4362A_VOLB_3, 0x40); /* Power up. */ i2c_write(devc, codec, CS4362A_MODE1_CTRL, CS4362A_CPEN); } static void cmediahd_generic_set_play_volume(cmediahd_devc_t *devc, int codec_id, int left, int right) { spi_write(devc, codec_id, AK4396_LchATTCtl | 0x20, mix_scale(left, 8)); spi_write(devc, codec_id, AK4396_RchATTCtl | 0x20, mix_scale(right, 8)); } static void xonar_d1_set_play_volume(cmediahd_devc_t *devc, int codec_id, int left, int right) { switch (codec_id) { case 0: i2c_write(devc, XONAR_DX_FRONTDAC, CS4398_VOLA, CS4398_VOL(left)); i2c_write(devc, XONAR_DX_FRONTDAC, CS4398_VOLB, CS4398_VOL(right)); break; case 1: i2c_write(devc, XONAR_DX_SURRDAC, CS4362A_VOLA_1, CS4362A_VOL(left)); i2c_write(devc, XONAR_DX_SURRDAC, CS4362A_VOLB_1, CS4362A_VOL(right)); break; case 2: i2c_write(devc, XONAR_DX_SURRDAC, CS4362A_VOLA_2, CS4362A_VOL(left)); i2c_write(devc, XONAR_DX_SURRDAC, CS4362A_VOLB_2, CS4362A_VOL(right)); break; case 3: i2c_write(devc, XONAR_DX_SURRDAC, CS4362A_VOLA_3, CS4362A_VOL(left)); i2c_write(devc, XONAR_DX_SURRDAC, CS4362A_VOLB_3, CS4362A_VOL(right)); break; } } static void xonar_d2_set_play_volume(cmediahd_devc_t *devc, int codec_id, int left, int right) { spi_write(devc, xd2_codec_map[codec_id], 16, mix_scale(left, 8)); spi_write(devc, xd2_codec_map[codec_id], 17, mix_scale(right, 8)); } static void xonar_stx_set_play_volume(cmediahd_devc_t *devc, int codec_id, int left, int right) { if (codec_id == 0) { i2c_write(devc, XONAR_STX_FRONTDAC, 16, mix_scale(left, 8)); i2c_write(devc, XONAR_STX_FRONTDAC, 17, mix_scale(right, 8)); } } static void xonar_ds_set_play_volume(cmediahd_devc_t *devc, int codec_id, int left, int right) { switch (codec_id) { case 0: /* front */ spi_write(devc, XONAR_DS_FRONTDAC, 0, mix_scale(left, 7) | 0x180); spi_write(devc, XONAR_DS_FRONTDAC, 1, mix_scale(right, 7) | 0x180); spi_write(devc, XONAR_DS_FRONTDAC, 3, mix_scale(left, 7) |0x180); spi_write(devc, XONAR_DS_FRONTDAC, 4, mix_scale(right, 7) | 0x180); break; case 1: /* side */ spi_write(devc, XONAR_DS_SURRDAC, 0, mix_scale(left, 7) | 0x180); spi_write(devc, XONAR_DS_SURRDAC, 1, mix_scale(right, 7) | 0x180); break; case 2: /* rear */ spi_write(devc, XONAR_DS_SURRDAC, 4, mix_scale(left, 7) | 0x180); spi_write(devc, XONAR_DS_SURRDAC, 5, mix_scale(right, 7) | 0x180); break; case 3: /* center */ spi_write(devc, XONAR_DS_SURRDAC, 6, mix_scale(left, 7) | 0x180); spi_write(devc, XONAR_DS_SURRDAC, 7, mix_scale(right, 7) | 0x180); break; } } static void cmediahd_set_rec_volume(cmediahd_devc_t *devc, int value) { unsigned char left, right; left = (value >> 8) & 0xff; right = value & 0xff; if (left > 100) left = 100; if (right > 100) right = 100; spi_write(devc, XONAR_DS_FRONTDAC, 0xe, mix_scale(left, 8)); spi_write(devc, XONAR_DS_FRONTDAC, 0xf, mix_scale(right, 8)); } static void cmediahd_set_play_volume(cmediahd_devc_t *devc, int codec_id, int value) { int left, right; left = (value >> 8) & 0xFF; right = (value & 0xFF); if (left > 100) left = 100; if (right > 100) right = 100; switch (devc->model) { case SUBID_XONAR_D1: case SUBID_XONAR_DX: xonar_d1_set_play_volume(devc, codec_id, left, right); break; case SUBID_XONAR_D2: case SUBID_XONAR_D2X: xonar_d2_set_play_volume(devc, codec_id, left, right); break; case SUBID_XONAR_STX: xonar_stx_set_play_volume(devc, codec_id, left, right); break; case SUBID_XONAR_DS: xonar_ds_set_play_volume(devc, codec_id, left, right); break; default: cmediahd_generic_set_play_volume(devc, codec_id, left, right); break; } } /* * Audio routines */ int cmediahd_open(void *arg, int flag, unsigned *nframesp, caddr_t *bufp) { cmediahd_portc_t *portc = arg; _NOTE(ARGUNUSED(flag)); portc->count = 0; *nframesp = portc->nframes; *bufp = portc->kaddr; return (0); } void cmediahd_close(void *arg) { _NOTE(ARGUNUSED(arg)); } int cmediahd_start(void *arg) { cmediahd_portc_t *portc = arg; cmediahd_devc_t *devc = portc->devc; mutex_enter(&devc->mutex); portc->offset = 0; cmediahd_reset_port(portc); switch (portc->direction) { case CMEDIAHD_PLAY: /* enable the dma */ OUTW(devc, INW(devc, DMA_START) | 0x10, DMA_START); break; case CMEDIAHD_REC: /* enable the channel */ OUTW(devc, INW(devc, DMA_START) | (1<rec_eng.chan), DMA_START); break; } mutex_exit(&devc->mutex); return (0); } void cmediahd_stop(void *arg) { cmediahd_portc_t *portc = arg; cmediahd_devc_t *devc = portc->devc; mutex_enter(&devc->mutex); switch (portc->direction) { case CMEDIAHD_PLAY: /* disable dma */ OUTW(devc, INW(devc, DMA_START) & ~0x10, DMA_START); break; case CMEDIAHD_REC: /* disable dma */ OUTW(devc, INW(devc, DMA_START) & ~(1<rec_eng.chan), DMA_START); break; } mutex_exit(&devc->mutex); } int cmediahd_format(void *arg) { _NOTE(ARGUNUSED(arg)); return (AUDIO_FORMAT_S16_LE); } int cmediahd_channels(void *arg) { cmediahd_portc_t *portc = arg; return (portc->chans); } int cmediahd_rate(void *arg) { _NOTE(ARGUNUSED(arg)); return (48000); } void cmediahd_sync(void *arg, unsigned nframes) { cmediahd_portc_t *portc = arg; _NOTE(ARGUNUSED(nframes)); (void) ddi_dma_sync(portc->buf_dmah, 0, 0, portc->syncdir); } static void cmediahd_chinfo(void *arg, int chan, unsigned *offset, unsigned *incr) { cmediahd_portc_t *portc = arg; static const int map8ch[] = { 0, 1, 4, 5, 2, 3, 6, 7 }; static const int map4ch[] = { 0, 1, 2, 3 }; if (portc->chans <= 4) { *offset = map4ch[chan]; } else { *offset = map8ch[chan]; } *incr = portc->chans; } uint64_t cmediahd_count(void *arg) { cmediahd_portc_t *portc = arg; cmediahd_devc_t *devc = portc->devc; uint64_t count; uint32_t offset; mutex_enter(&devc->mutex); if (portc->direction == CMEDIAHD_PLAY) offset = portc->bufsz/4 - INL(devc, MULTICH_SIZE) + 1; else offset = portc->bufsz/4 - INW(devc, devc->rec_eng.size) + 1; /* check for wrap */ if (offset < portc->offset) { count = ((portc->bufsz/4) - portc->offset) + offset; } else { count = offset - portc->offset; } portc->count += count; portc->offset = offset; /* convert from 16-bit stereo */ count = portc->count / (portc->chans/2); mutex_exit(&devc->mutex); return (count); } /* private implementation bits */ void cmediahd_reset_port(cmediahd_portc_t *portc) { cmediahd_devc_t *devc = portc->devc; int channels; if (devc->suspended) return; portc->offset = 0; switch (portc->direction) { case CMEDIAHD_PLAY: /* reset channel */ OUTB(devc, INB(devc, CHAN_RESET)|0x10, CHAN_RESET); drv_usecwait(10); OUTB(devc, INB(devc, CHAN_RESET) & ~0x10, CHAN_RESET); drv_usecwait(10); OUTL(devc, portc->paddr, MULTICH_ADDR); OUTL(devc, (portc->bufsz/4) - 1, MULTICH_SIZE); OUTL(devc, (portc->bufsz/4) - 1, MULTICH_FRAG); switch (portc->chans) { case 2: channels = 0; break; case 4: channels = 1; break; case 6: channels = 2; break; case 8: channels = 3; break; default: channels = 0x0; break; } OUTB(devc, (INB(devc, MULTICH_MODE) & ~0x3) | channels, MULTICH_MODE); /* set the format bits in play format register */ OUTB(devc, (INB(devc, PLAY_FORMAT) & ~0xC) | 0x0, PLAY_FORMAT); break; case CMEDIAHD_REC: OUTB(devc, INB(devc, CHAN_RESET) | (1 << devc->rec_eng.chan), CHAN_RESET); drv_usecwait(10); OUTB(devc, INB(devc, CHAN_RESET) & ~(1 << devc->rec_eng.chan), CHAN_RESET); drv_usecwait(10); OUTL(devc, portc->paddr, devc->rec_eng.addr); OUTW(devc, (portc->bufsz/4) - 1, devc->rec_eng.size); OUTW(devc, (portc->bufsz/4) - 1, devc->rec_eng.frag); switch (portc->chans) { case 2: channels = 0x0; break; case 4: channels = 0x1; break; case 6: channels = 0x2; break; case 8: channels = 0x4; break; default: /* Stereo - boomer only supports stereo */ channels = 0x0; break; } OUTB(devc, (INB(devc, REC_MODE) & ~0x3) | channels, REC_MODE); OUTB(devc, (INB(devc, REC_FORMAT) & ~0x3) | 0x0, REC_FORMAT); } } int cmediahd_alloc_port(cmediahd_devc_t *devc, int num) { cmediahd_portc_t *portc; size_t len; ddi_dma_cookie_t cookie; uint_t count; int dir; unsigned caps; audio_dev_t *adev; adev = devc->adev; portc = kmem_zalloc(sizeof (*portc), KM_SLEEP); devc->portc[num] = portc; portc->devc = devc; portc->direction = num; switch (num) { case CMEDIAHD_REC: portc->syncdir = DDI_DMA_SYNC_FORKERNEL; portc->chans = 2; caps = ENGINE_INPUT_CAP; dir = DDI_DMA_READ; break; case CMEDIAHD_PLAY: portc->syncdir = DDI_DMA_SYNC_FORDEV; portc->chans = 8; caps = ENGINE_OUTPUT_CAP; dir = DDI_DMA_WRITE; break; default: return (DDI_FAILURE); } /* * Calculate buffer size and frames */ portc->nframes = 2048; portc->bufsz = portc->nframes * portc->chans * 2; /* Alloc buffers */ if (ddi_dma_alloc_handle(devc->dip, &dma_attr_buf, DDI_DMA_SLEEP, NULL, &portc->buf_dmah) != DDI_SUCCESS) { audio_dev_warn(adev, "failed to allocate BUF handle"); return (DDI_FAILURE); } if (ddi_dma_mem_alloc(portc->buf_dmah, CMEDIAHD_BUF_LEN, &buf_attr, DDI_DMA_CONSISTENT, DDI_DMA_SLEEP, NULL, &portc->kaddr, &len, &portc->buf_acch) != DDI_SUCCESS) { audio_dev_warn(adev, "failed to allocate BUF memory"); return (DDI_FAILURE); } bzero(portc->kaddr, len); if (ddi_dma_addr_bind_handle(portc->buf_dmah, NULL, portc->kaddr, len, DDI_DMA_CONSISTENT | dir, DDI_DMA_SLEEP, NULL, &cookie, &count) != DDI_SUCCESS) { audio_dev_warn(adev, "failed binding BUF DMA handle"); return (DDI_FAILURE); } portc->paddr = cookie.dmac_address; portc->engine = audio_engine_alloc(&cmediahd_engine_ops, caps); if (portc->engine == NULL) { audio_dev_warn(adev, "audio_engine_alloc failed"); return (DDI_FAILURE); } audio_engine_set_private(portc->engine, portc); audio_dev_add_engine(adev, portc->engine); return (DDI_SUCCESS); } void cmediahd_destroy(cmediahd_devc_t *devc) { mutex_destroy(&devc->mutex); mutex_destroy(&devc->low_mutex); for (int i = 0; i < CMEDIAHD_NUM_PORTC; i++) { cmediahd_portc_t *portc = devc->portc[i]; if (!portc) continue; if (portc->engine) { audio_dev_remove_engine(devc->adev, portc->engine); audio_engine_free(portc->engine); } if (portc->paddr) { (void) ddi_dma_unbind_handle(portc->buf_dmah); } if (portc->buf_acch) { ddi_dma_mem_free(&portc->buf_acch); } if (portc->buf_dmah) { ddi_dma_free_handle(&portc->buf_dmah); } kmem_free(portc, sizeof (*portc)); } if (devc->ac97) { ac97_free(devc->ac97); } cmediahd_del_controls(devc); if (devc->adev != NULL) { audio_dev_free(devc->adev); } if (devc->regsh != NULL) { ddi_regs_map_free(&devc->regsh); } if (devc->pcih != NULL) { pci_config_teardown(&devc->pcih); } kmem_free(devc, sizeof (*devc)); } void cmediahd_ac97_hwinit(cmediahd_devc_t *devc) { /* GPIO #0 programmed as output, set CMI9780 Reg0x70 */ cmediahd_write_ac97(devc, 0x70, 0x100); /* LI2LI,MIC2MIC; let them always on, FOE on, ROE/BKOE/CBOE off */ cmediahd_write_ac97(devc, 0x62, 0x180F); /* unmute Master Volume */ cmediahd_write_ac97(devc, 0x02, 0x0); /* change PCBeep path, set Mix2FR on, option for quality issue */ cmediahd_write_ac97(devc, 0x64, 0x8043); /* mute PCBeep, option for quality issues */ cmediahd_write_ac97(devc, 0x0A, 0x8000); /* Record Select Control Register (Index 1Ah) */ cmediahd_write_ac97(devc, 0x1A, 0x0000); /* set Mic Volume Register 0x0Eh umute and enable micboost */ cmediahd_write_ac97(devc, 0x0E, 0x0848); /* set Line in Volume Register 0x10h mute */ cmediahd_write_ac97(devc, 0x10, 0x8808); /* set CD Volume Register 0x12h mute */ cmediahd_write_ac97(devc, 0x12, 0x8808); /* set AUX Volume Register 0x16h max */ cmediahd_write_ac97(devc, 0x16, 0x0808); /* set record gain Register 0x1Ch to max */ cmediahd_write_ac97(devc, 0x1C, 0x0F0F); /* GPIO status register enable GPO0 */ cmediahd_write_ac97(devc, 0x72, 0x0001); } void cmediahd_hwinit(cmediahd_devc_t *devc) { unsigned short sVal; unsigned short i2s_fmt; unsigned char bVal; int i, count; /* setup the default rec DMA engines to REC_A */ devc->rec_eng.addr = RECA_ADDR; devc->rec_eng.size = RECA_SIZE; devc->rec_eng.frag = RECA_FRAG; devc->rec_eng.i2s = I2S_ADC1; devc->rec_eng.chan = REC_A; /* setup GPIOs to 0 */ devc->gpio_mic = 0; devc->gpio_out = 0; devc->gpio_codec = 0; devc->gpio_alt = 0; /* Init CMI Controller */ sVal = INW(devc, CTRL_VERSION); if (!(sVal & 0x0008)) { bVal = INB(devc, MISC_REG); bVal |= 0x20; OUTB(devc, bVal, MISC_REG); } bVal = INB(devc, FUNCTION); bVal |= 0x02; /* Reset codec */ OUTB(devc, bVal, FUNCTION); /* Cold reset onboard AC97 */ OUTW(devc, 0x1, AC97_CTRL); count = 100; while ((INW(devc, AC97_CTRL) & 0x2) && (count--)) { OUTW(devc, (INW(devc, AC97_CTRL) & ~0x2) | 0x2, AC97_CTRL); drv_usecwait(100); } if (!count) audio_dev_warn(devc->adev, "CMI8788 AC97 not ready"); sVal = INW(devc, AC97_CTRL); /* check if there's an onboard AC97 codec (CODEC 0) */ if (sVal & 0x10) { /* disable CODEC0 OUTPUT */ OUTW(devc, INW(devc, AC97_OUT_CHAN_CONFIG) & ~0xFF00, AC97_OUT_CHAN_CONFIG); /* enable CODEC0 INPUT */ OUTW(devc, INW(devc, AC97_IN_CHAN_CONFIG) | 0x0300, AC97_IN_CHAN_CONFIG); devc->has_ac97 = 1; } /* check if there's an front panel AC97 codec (CODEC1) */ if (sVal & 0x20) { /* enable CODEC1 OUTPUT */ OUTW(devc, INW(devc, AC97_OUT_CHAN_CONFIG) | 0x0033, AC97_OUT_CHAN_CONFIG); /* enable CODEC1 INPUT */ OUTW(devc, INW(devc, AC97_IN_CHAN_CONFIG) | 0x0033, AC97_IN_CHAN_CONFIG); devc->has_fp_ac97 = 1; } /* Disable AC97 interrupts and initialize AC97 */ OUTB(devc, 0x0, AC97_INTR_MASK); OUTW(devc, INW(devc, IRQ_MASK) & ~0x4000, IRQ_MASK); /* I2S to 16bit/48Khz/Master, see below. */ i2s_fmt = 0x011A; /* Setup I2S to use 16bit instead of 24Bit */ OUTW(devc, i2s_fmt, I2S_MULTICH_DAC); OUTW(devc, i2s_fmt, I2S_ADC1); OUTW(devc, i2s_fmt, I2S_ADC2); OUTW(devc, i2s_fmt, I2S_ADC3); /* setup Routing regs (default vals) */ OUTW(devc, 0xE400, PLAY_ROUTING); OUTB(devc, 0x00, REC_ROUTING); /* default routing set to I2S */ OUTB(devc, 0x00, REC_MONITOR); /* monitor through MULTICH_PLAY */ OUTB(devc, 0xE4, MONITOR_ROUTING); /* default monitor routing */ /* Enable Xonar output */ switch (devc->model) { case SUBID_XONAR_D1: case SUBID_XONAR_DX: /* GPIO8 = 0x100 controls mic/line-in */ /* GPIO0 = 0x001controls output */ /* GPIO2/3 = 0x00C codec output control */ devc->rec_eng.addr = RECB_ADDR; devc->rec_eng.size = RECB_SIZE; devc->rec_eng.frag = RECB_FRAG; devc->rec_eng.i2s = I2S_ADC2; devc->rec_eng.chan = REC_B; /* disable AC97 mixer - not used */ devc->has_ac97 = 0; /* setup for 2wire communication mode */ OUTB(devc, INB(devc, FUNCTION) | 0x40, FUNCTION); /* setup GPIO direction */ OUTW(devc, INW(devc, GPIO_CONTROL) | 0x10D, GPIO_CONTROL); /* setup GPIO pins */ OUTW(devc, INW(devc, GPIO_DATA) | 0x101, GPIO_DATA); /* init the front and rear dacs */ cs4398_init(devc, XONAR_DX_FRONTDAC); cs4362a_init(devc, XONAR_DX_SURRDAC); break; case SUBID_XONAR_D2: case SUBID_XONAR_D2X: /* GPIO7 = 0x0080 controls mic/line-in */ /* GPIO8 = 0x0100 controls output */ /* GPIO2/3 = 0x000C codec output control */ devc->rec_eng.addr = RECB_ADDR; devc->rec_eng.size = RECB_SIZE; devc->rec_eng.frag = RECB_FRAG; devc->rec_eng.i2s = I2S_ADC2; devc->rec_eng.chan = REC_B; /* disable the AC97 mixer - it's not useful */ devc->has_ac97 = 0; /* setup for spi communication mode */ OUTB(devc, (INB(devc, FUNCTION) & ~0x40) | 0x80, FUNCTION); /* setup the GPIO direction */ OUTW(devc, INW(devc, GPIO_CONTROL) | 0x18c, GPIO_CONTROL); /* setup GPIO Pins */ OUTW(devc, INW(devc, GPIO_DATA) | 0x100, GPIO_DATA); /* for all 4 codecs: unmute, set to 24Bit SPI */ for (i = 0; i < 4; ++i) { /* left vol */ spi_write(devc, i, 16, mix_scale(75, 8)); /* right vol */ spi_write(devc, i, 17, mix_scale(75, 8)); /* unmute/24LSB/ATLD */ spi_write(devc, i, 18, 0x30 | 0x80); } break; case SUBID_XONAR_STX: devc->rec_eng.addr = RECB_ADDR; devc->rec_eng.size = RECB_SIZE; devc->rec_eng.frag = RECB_FRAG; devc->rec_eng.i2s = I2S_ADC2; devc->rec_eng.chan = REC_B; /* disable the AC97 mixer - it's not useful */ devc->has_ac97 = 0; /* setup for spi communication mode */ OUTB(devc, (INB(devc, FUNCTION) & ~0x40) | 0x80, FUNCTION); /* setup the GPIO direction */ OUTW(devc, INW(devc, GPIO_CONTROL) | 0x18F, GPIO_CONTROL); /* setup GPIO Pins */ OUTW(devc, INW(devc, GPIO_DATA) | 0x111, GPIO_DATA); /* init front DAC */ /* left vol */ i2c_write(devc, XONAR_STX_FRONTDAC, 16, mix_scale(75, 8)); /* right vol */ i2c_write(devc, XONAR_STX_FRONTDAC, 17, mix_scale(75, 8)); /* unmute/24LSB/ATLD */ i2c_write(devc, XONAR_STX_FRONTDAC, 18, 0x30 | 0x80); i2c_write(devc, XONAR_STX_FRONTDAC, 19, 0); /* ATS1/FLT_SHARP */ i2c_write(devc, XONAR_STX_FRONTDAC, 20, 0); /* OS_64 */ i2c_write(devc, XONAR_STX_FRONTDAC, 21, 0); break; case SUBID_XONAR_DS: /* GPIO 8 = 1 output enabled 0 mute */ /* GPIO 7 = 1 lineout enabled 0 mute */ /* GPIO 6 = 1 mic select 0 line-in select */ /* GPIO 4 = 1 FP Headphone plugged in */ /* GPIO 3 = 1 FP Mic plugged in */ devc->rec_eng.addr = RECA_ADDR; devc->rec_eng.size = RECA_SIZE; devc->rec_eng.frag = RECA_FRAG; devc->rec_eng.i2s = I2S_ADC1; devc->rec_eng.chan = REC_A; /* disable the AC97 mixer - it's not useful */ devc->has_ac97 = 0; /* setup for spi communication mode */ OUTB(devc, (INB(devc, FUNCTION) & ~0x40) | 0x80, FUNCTION); /* setup the GPIO direction */ OUTW(devc, INW(devc, GPIO_CONTROL) | 0x1D0, GPIO_CONTROL); /* setup GPIO Pins */ OUTW(devc, INW(devc, GPIO_DATA) | 0x1D0, GPIO_DATA); spi_write(devc, XONAR_DS_FRONTDAC, 0x17, 0x1); /* reset */ spi_write(devc, XONAR_DS_FRONTDAC, 0x7, 0x90); /* dac control */ spi_write(devc, XONAR_DS_FRONTDAC, 0x8, 0); /* unmute */ /* powerdown hp */ spi_write(devc, XONAR_DS_FRONTDAC, 0xC, 0x22); spi_write(devc, XONAR_DS_FRONTDAC, 0xD, 0x8); /* powerdown hp */ spi_write(devc, XONAR_DS_FRONTDAC, 0xA, 0x1); /* LJust/16bit */ spi_write(devc, XONAR_DS_FRONTDAC, 0xB, 0x1); /* LJust/16bit */ spi_write(devc, XONAR_DS_SURRDAC, 0x1f, 1); /* reset */ /* LJust/24bit */ spi_write(devc, XONAR_DS_SURRDAC, 0x3, 0x1|0x20); break; default: /* SPI default for anything else, including the */ OUTB(devc, (INB(devc, FUNCTION) & ~0x40) | 0x80, FUNCTION); OUTB(devc, 0x18, REC_ROUTING); /* default routing set to I2S */ break; } /* only initialize AC97 if not defined */ if (devc->has_ac97) cmediahd_ac97_hwinit(devc); } static int cmediahd_set_control(void *arg, uint64_t val) { cmediahd_ctrl_t *pc = arg; cmediahd_devc_t *devc = pc->devc; mutex_enter(&devc->mutex); pc->val = val; switch (pc->num) { case CTL_VOLUME: case CTL_FRONT: cmediahd_set_play_volume(devc, 0, val); break; case CTL_REAR: cmediahd_set_play_volume(devc, 1, val); break; case CTL_CENTER: val &= 0xff; val |= ((devc->controls[CTL_LFE].val) << 8); cmediahd_set_play_volume(devc, 2, val); break; case CTL_LFE: val &= 0xff; val <<= 8; val |= (devc->controls[CTL_CENTER].val); cmediahd_set_play_volume(devc, 2, val); break; case CTL_SURROUND: cmediahd_set_play_volume(devc, 3, val); break; case CTL_MONITOR: /* enable recording monitor rec 1 and rec2 */ if (val) OUTB(devc, INB(devc, REC_MONITOR) | 0xF, REC_MONITOR); else OUTB(devc, INB(devc, REC_MONITOR) & ~0xF, REC_MONITOR); break; case CTL_RECSRC: switch (val) { case 1: /* Line */ if (devc->model == SUBID_XONAR_DS) OUTW(devc, INW(devc, GPIO_DATA) & ~0x40, GPIO_DATA); if (devc->model == SUBID_XONAR_D1 || devc->model == SUBID_XONAR_DX) OUTW(devc, INW(devc, GPIO_DATA) & ~devc->gpio_mic, GPIO_DATA); cmediahd_write_ac97(devc, 0x72, cmediahd_read_ac97(devc, 0x72) & ~0x1); cmediahd_write_ac97(devc, 0x1A, 0x0404); break; case 2: /* Mic */ if (devc->model == SUBID_XONAR_DS) OUTW(devc, INW(devc, GPIO_DATA) | 0x40, GPIO_DATA); if (devc->model == SUBID_XONAR_D1 || devc->model == SUBID_XONAR_DX) OUTW(devc, INW(devc, GPIO_DATA) | devc->gpio_mic, GPIO_DATA); cmediahd_write_ac97(devc, 0x72, cmediahd_read_ac97(devc, 0x72) | 0x1); /* Unmute Mic */ cmediahd_write_ac97(devc, 0xE, cmediahd_read_ac97(devc, 0xE) & ~0x8000); /* Mute AUX and Video */ cmediahd_write_ac97(devc, 0x12, cmediahd_read_ac97(devc, 0x12) | 0x8000); cmediahd_write_ac97(devc, 0x16, cmediahd_read_ac97(devc, 0x16) | 0x8000); cmediahd_write_ac97(devc, 0x1A, 0x0000); break; case 4: /* AUX */ if (devc->model == SUBID_XONAR_D1 || devc->model == SUBID_XONAR_DX) OUTW(devc, INW(devc, GPIO_DATA) | devc->gpio_mic, GPIO_DATA); cmediahd_write_ac97(devc, 0x72, cmediahd_read_ac97(devc, 0x72) | 0x1); /* Unmute AUX */ cmediahd_write_ac97(devc, 0x16, cmediahd_read_ac97(devc, 0x16) & ~0x8000); /* Mute CD and Mic */ cmediahd_write_ac97(devc, 0x14, cmediahd_read_ac97(devc, 0x14) | 0x8000); cmediahd_write_ac97(devc, 0x0E, cmediahd_read_ac97(devc, 0x0E) | 0x8000); cmediahd_write_ac97(devc, 0x1A, 0x0303); break; case 8: /* Video (CD) */ if (devc->model == SUBID_XONAR_D1 || devc->model == SUBID_XONAR_DX) OUTW(devc, INW(devc, GPIO_DATA) | devc->gpio_mic, GPIO_DATA); cmediahd_write_ac97(devc, 0x72, cmediahd_read_ac97(devc, 0x72) | 0x1); /* Unmute Video (CD) */ cmediahd_write_ac97(devc, 0x14, cmediahd_read_ac97(devc, 0x14) & ~0x8000); /* Mute AUX and Mic */ cmediahd_write_ac97(devc, 0x16, cmediahd_read_ac97(devc, 0x16) | 0x8000); cmediahd_write_ac97(devc, 0x0E, cmediahd_read_ac97(devc, 0x0E) | 0x8000); /* set input to video */ cmediahd_write_ac97(devc, 0x1A, 0x0202); break; } break; case CTL_LOOP: if (val) OUTW(devc, INW(devc, GPIO_DATA) | devc->gpio_alt, GPIO_DATA); else OUTW(devc, (INW(devc, GPIO_DATA) & ~devc->gpio_alt), GPIO_DATA); break; case CTL_SPREAD: if (val) OUTW(devc, INW(devc, PLAY_ROUTING) & 0x00FF, PLAY_ROUTING); else OUTW(devc, (INW(devc, PLAY_ROUTING) & 0x00FF) | 0xE400, PLAY_ROUTING); break; case CTL_RECGAIN: cmediahd_set_rec_volume(devc, val); break; case CTL_MICVOL: if (val) cmediahd_write_ac97(devc, 0x0E, (0x40 | mix_scale(val, -5)) & ~0x8000); else cmediahd_write_ac97(devc, 0x0E, 0x8000); break; case CTL_AUXVOL: if (val) cmediahd_write_ac97(devc, 0x16, mix_scale(val, -5) & ~0x8000); else cmediahd_write_ac97(devc, 0x16, 0x8000); break; case CTL_CDVOL: if (val) cmediahd_write_ac97(devc, 0x14, mix_scale(val, -5) & ~0x8000); else cmediahd_write_ac97(devc, 0x14, 0x8000); break; } mutex_exit(&devc->mutex); return (0); } static int cmediahd_get_control(void *arg, uint64_t *val) { cmediahd_ctrl_t *pc = arg; cmediahd_devc_t *devc = pc->devc; mutex_enter(&devc->mutex); *val = pc->val; mutex_exit(&devc->mutex); return (0); } static void cmediahd_alloc_ctrl(cmediahd_devc_t *devc, uint32_t num, uint64_t val) { audio_ctrl_desc_t desc; cmediahd_ctrl_t *pc; bzero(&desc, sizeof (desc)); pc = &devc->controls[num]; pc->num = num; pc->devc = devc; switch (num) { case CTL_VOLUME: desc.acd_name = AUDIO_CTRL_ID_VOLUME; desc.acd_type = AUDIO_CTRL_TYPE_STEREO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = PCMVOL; break; case CTL_FRONT: desc.acd_name = AUDIO_CTRL_ID_FRONT; desc.acd_type = AUDIO_CTRL_TYPE_STEREO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = PCMVOL; break; case CTL_REAR: desc.acd_name = AUDIO_CTRL_ID_REAR; desc.acd_type = AUDIO_CTRL_TYPE_STEREO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = PCMVOL; break; case CTL_SURROUND: desc.acd_name = AUDIO_CTRL_ID_SURROUND; desc.acd_type = AUDIO_CTRL_TYPE_STEREO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = PCMVOL; break; case CTL_CENTER: desc.acd_name = AUDIO_CTRL_ID_CENTER; desc.acd_type = AUDIO_CTRL_TYPE_MONO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = PCMVOL; break; case CTL_LFE: desc.acd_name = AUDIO_CTRL_ID_LFE; desc.acd_type = AUDIO_CTRL_TYPE_MONO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = PCMVOL; break; case CTL_MONITOR: desc.acd_name = AUDIO_CTRL_ID_MONSRC; desc.acd_type = AUDIO_CTRL_TYPE_BOOLEAN; desc.acd_minvalue = 0; desc.acd_maxvalue = 1; desc.acd_flags = RECCTL; break; case CTL_RECSRC: desc.acd_name = AUDIO_CTRL_ID_RECSRC; desc.acd_type = AUDIO_CTRL_TYPE_ENUM; desc.acd_flags = RECCTL; desc.acd_enum[0] = AUDIO_PORT_LINEIN; desc.acd_enum[1] = AUDIO_PORT_MIC; if (devc->model == SUBID_XONAR_D2 || devc->model == SUBID_XONAR_D2X) { desc.acd_minvalue = 0xF; desc.acd_maxvalue = 0xF; desc.acd_enum[2] = AUDIO_PORT_AUX1IN; desc.acd_enum[3] = AUDIO_PORT_CD; } else { desc.acd_minvalue = 0x3; desc.acd_maxvalue = 0x3; } break; case CTL_LOOP: desc.acd_name = AUDIO_CTRL_ID_LOOPBACK; desc.acd_type = AUDIO_CTRL_TYPE_BOOLEAN; desc.acd_minvalue = 0; desc.acd_maxvalue = 1; desc.acd_flags = RECCTL; break; case CTL_SPREAD: desc.acd_name = AUDIO_CTRL_ID_SPREAD; desc.acd_type = AUDIO_CTRL_TYPE_BOOLEAN; desc.acd_minvalue = 0; desc.acd_maxvalue = 1; desc.acd_flags = PLAYCTL; break; case CTL_RECGAIN: desc.acd_name = AUDIO_CTRL_ID_RECGAIN; desc.acd_type = AUDIO_CTRL_TYPE_STEREO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = RECVOL; break; case CTL_MICVOL: desc.acd_name = AUDIO_CTRL_ID_MIC; desc.acd_type = AUDIO_CTRL_TYPE_STEREO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = RECVOL; break; case CTL_AUXVOL: desc.acd_name = AUDIO_CTRL_ID_AUX1IN; desc.acd_type = AUDIO_CTRL_TYPE_STEREO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = RECVOL; break; case CTL_CDVOL: desc.acd_name = AUDIO_CTRL_ID_CD; desc.acd_type = AUDIO_CTRL_TYPE_STEREO; desc.acd_minvalue = 0; desc.acd_maxvalue = 100; desc.acd_flags = RECVOL; break; } pc->val = val; pc->ctrl = audio_dev_add_control(devc->adev, &desc, cmediahd_get_control, cmediahd_set_control, pc); } static void cmediahd_refresh_mixer(cmediahd_devc_t *devc) { int ctl; for (ctl = 0; ctl < CTL_NUM; ctl++) { if (devc->controls[ctl].ctrl == NULL) continue; (void) cmediahd_set_control(&devc->controls[ctl], devc->controls[ctl].val); } } static void cmediahd_add_controls(cmediahd_devc_t *devc) { cmediahd_alloc_ctrl(devc, CTL_VOLUME, 80 | (80 << 8)); cmediahd_alloc_ctrl(devc, CTL_FRONT, 80 | (80<<8)); cmediahd_alloc_ctrl(devc, CTL_REAR, 80 | (80<<8)); cmediahd_alloc_ctrl(devc, CTL_CENTER, 80); cmediahd_alloc_ctrl(devc, CTL_LFE, 80); cmediahd_alloc_ctrl(devc, CTL_SURROUND, 80 | (80<<8)); cmediahd_alloc_ctrl(devc, CTL_SPREAD, 0); cmediahd_alloc_ctrl(devc, CTL_MONITOR, 0); cmediahd_alloc_ctrl(devc, CTL_LOOP, 0); cmediahd_alloc_ctrl(devc, CTL_RECSRC, 2); switch (devc->model) { case SUBID_XONAR_DS: cmediahd_alloc_ctrl(devc, CTL_RECGAIN, 80|80<<8); break; case SUBID_XONAR_D2: case SUBID_XONAR_D2X: cmediahd_alloc_ctrl(devc, CTL_MICVOL, 80|80<<8); cmediahd_alloc_ctrl(devc, CTL_AUXVOL, 80|80<<8); cmediahd_alloc_ctrl(devc, CTL_CDVOL, 80|80<<8); break; } cmediahd_refresh_mixer(devc); } void cmediahd_del_controls(cmediahd_devc_t *dev) { for (int i = 0; i < CTL_NUM; i++) { if (dev->controls[i].ctrl) { audio_dev_del_control(dev->controls[i].ctrl); dev->controls[i].ctrl = NULL; } } } int cmediahd_attach(dev_info_t *dip) { uint16_t pci_command, vendor, device, subvendor, subdevice; cmediahd_devc_t *devc; ddi_acc_handle_t pcih; devc = kmem_zalloc(sizeof (*devc), KM_SLEEP); devc->dip = dip; ddi_set_driver_private(dip, devc); mutex_init(&devc->mutex, NULL, MUTEX_DRIVER, NULL); mutex_init(&devc->low_mutex, NULL, MUTEX_DRIVER, NULL); if ((devc->adev = audio_dev_alloc(dip, 0)) == NULL) { cmn_err(CE_WARN, "audio_dev_alloc failed"); goto error; } if (pci_config_setup(dip, &pcih) != DDI_SUCCESS) { audio_dev_warn(devc->adev, "pci_config_setup failed"); goto error; } devc->pcih = pcih; vendor = pci_config_get16(pcih, PCI_CONF_VENID); device = pci_config_get16(pcih, PCI_CONF_DEVID); subvendor = pci_config_get16(pcih, PCI_CONF_SUBVENID); subdevice = pci_config_get16(pcih, PCI_CONF_SUBSYSID); if (vendor != PCI_VENDOR_ID_CMEDIA || device != PCI_DEVICE_ID_CMEDIAHD) { audio_dev_warn(devc->adev, "Hardware not recognized " "(vendor=%x, dev=%x)", vendor, device); goto error; } pci_command = pci_config_get16(pcih, PCI_CONF_COMM); pci_command |= PCI_COMM_ME | PCI_COMM_IO; pci_config_put16(pcih, PCI_CONF_COMM, pci_command); if ((ddi_regs_map_setup(dip, 1, &devc->base, 0, 0, &dev_attr, &devc->regsh)) != DDI_SUCCESS) { audio_dev_warn(devc->adev, "failed to map registers"); goto error; } audio_dev_set_description(devc->adev, "CMedia 8788"); /* Detect Xonar device */ if (subvendor == ASUS_VENDOR_ID) { switch (subdevice) { case SUBID_XONAR_D1: audio_dev_set_description(devc->adev, "Asus Xonar D1 (AV100)"); break; case SUBID_XONAR_DX: audio_dev_set_description(devc->adev, "Asus Xonar DX (AV100)"); break; case SUBID_XONAR_D2: audio_dev_set_description(devc->adev, "Asus Xonar D2 (AV200)"); break; case SUBID_XONAR_D2X: audio_dev_set_description(devc->adev, "Asus Xonar D2X (AV200)"); break; case SUBID_XONAR_STX: audio_dev_set_description(devc->adev, "Asus Xonar STX (AV100)"); break; case SUBID_XONAR_DS: audio_dev_set_description(devc->adev, "Asus Xonar DS (AV66)"); break; default: audio_dev_set_description(devc->adev, "Asus Xonar Unknown Model"); subdevice = SUBID_GENERIC; break; } devc->model = subdevice; } cmediahd_hwinit(devc); if (cmediahd_alloc_port(devc, CMEDIAHD_PLAY) != DDI_SUCCESS) goto error; if (cmediahd_alloc_port(devc, CMEDIAHD_REC) != DDI_SUCCESS) goto error; /* Add the AC97 Mixer if there is an onboard AC97 device */ if (devc->has_ac97) { devc->ac97 = ac97_alloc(dip, cmediahd_read_ac97, cmediahd_write_ac97, devc); if (ac97_init(devc->ac97, devc->adev) != DDI_SUCCESS) { audio_dev_warn(devc->adev, "failed to init ac97"); goto error; } } #if 0 /* Add the front panel AC97 device if one exists */ if (devc->has_fp_ac97) { devc->fp_ac97 = ac97_alloc(dip, cmediahd_read_fp_ac97, cmediahd_write_fp_ac97, devc); if (ac97_init(devc->fp_ac97, devc->adev) != DDI_SUCCESS) { audio_dev_warn(devc->adev, "failed to init fp_ac97"); goto error; } } #endif /* Add the standard CMI8788 Mixer panel */ cmediahd_add_controls(devc); if (audio_dev_register(devc->adev) != DDI_SUCCESS) { audio_dev_warn(devc->adev, "unable to register with framework"); goto error; } ddi_report_dev(dip); return (DDI_SUCCESS); error: cmediahd_destroy(devc); return (DDI_FAILURE); } int cmediahd_resume(dev_info_t *dip) { cmediahd_devc_t *devc; devc = ddi_get_driver_private(dip); cmediahd_hwinit(devc); if (devc->ac97) ac97_reset(devc->ac97); cmediahd_refresh_mixer(devc); audio_dev_resume(devc->adev); return (DDI_SUCCESS); } int cmediahd_detach(cmediahd_devc_t *devc) { if (audio_dev_unregister(devc->adev) != DDI_SUCCESS) return (DDI_FAILURE); cmediahd_destroy(devc); return (DDI_SUCCESS); } int cmediahd_suspend(cmediahd_devc_t *devc) { audio_dev_suspend(devc->adev); return (DDI_SUCCESS); } static int cmediahd_ddi_attach(dev_info_t *, ddi_attach_cmd_t); static int cmediahd_ddi_detach(dev_info_t *, ddi_detach_cmd_t); static int cmediahd_ddi_quiesce(dev_info_t *); static struct dev_ops cmediahd_dev_ops = { DEVO_REV, /* rev */ 0, /* refcnt */ NULL, /* getinfo */ nulldev, /* identify */ nulldev, /* probe */ cmediahd_ddi_attach, /* attach */ cmediahd_ddi_detach, /* detach */ nodev, /* reset */ NULL, /* cb_ops */ NULL, /* bus_ops */ NULL, /* power */ cmediahd_ddi_quiesce, /* quiesce */ }; static struct modldrv cmediahd_modldrv = { &mod_driverops, /* drv_modops */ "CMedia 8788", /* linkinfo */ &cmediahd_dev_ops, /* dev_ops */ }; static struct modlinkage modlinkage = { MODREV_1, { &cmediahd_modldrv, NULL } }; int _init(void) { int rv; audio_init_ops(&cmediahd_dev_ops, CMEDIAHD_NAME); if ((rv = mod_install(&modlinkage)) != 0) { audio_fini_ops(&cmediahd_dev_ops); } return (rv); } int _fini(void) { int rv; if ((rv = mod_remove(&modlinkage)) == 0) { audio_fini_ops(&cmediahd_dev_ops); } return (rv); } int _info(struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); } int cmediahd_ddi_attach(dev_info_t *dip, ddi_attach_cmd_t cmd) { switch (cmd) { case DDI_ATTACH: return (cmediahd_attach(dip)); case DDI_RESUME: return (cmediahd_resume(dip)); default: return (DDI_FAILURE); } } int cmediahd_ddi_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { cmediahd_devc_t *devc; devc = ddi_get_driver_private(dip); switch (cmd) { case DDI_DETACH: return (cmediahd_detach(devc)); case DDI_SUSPEND: return (cmediahd_suspend(devc)); default: return (DDI_FAILURE); } } int cmediahd_ddi_quiesce(dev_info_t *dip) { cmediahd_devc_t *devc; devc = ddi_get_driver_private(dip); OUTW(devc, 0x0, DMA_START); /* * Turn off the hardware */ return (DDI_SUCCESS); }