NetBSD/sys/dev/pci/azalia.c

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/* $NetBSD: azalia.c,v 1.5 2005/06/20 11:48:47 kent Exp $ */
/*-
* Copyright (c) 2005 The NetBSD Foundation, Inc.
* All rights reserved.
*
* This code is derived from software contributed to The NetBSD Foundation
* by TAMURA Kent
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the NetBSD
* Foundation, Inc. and its contributors.
* 4. Neither the name of The NetBSD Foundation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/*
* TO DO:
* - recording support
* - Volume Knob widget
* - power hook
* - detach
*/
#include <sys/cdefs.h>
__KERNEL_RCSID(0, "$NetBSD: azalia.c,v 1.5 2005/06/20 11:48:47 kent Exp $");
#include <sys/param.h>
#include <sys/device.h>
#include <sys/malloc.h>
#include <sys/systm.h>
#include <sys/audioio.h>
#include <dev/audio_if.h>
#include <dev/auconv.h>
#include <dev/pci/pcidevs.h>
#include <dev/pci/pcivar.h>
/* ----------------------------------------------------------------
* High Definition Audio constant values
* ---------------------------------------------------------------- */
/* High Definition Audio registers */
#define HDA_GCAP 0x000 /* 2 */
#define HDA_GCAP_OSS(x) ((x & 0xf000) >> 12)
#define HDA_GCAP_ISS(x) ((x & 0x0f00) >> 8)
#define HDA_GCAP_BSS(x) ((x & 0x00f8) >> 3)
#define HDA_GCAP_NSDO_MASK 0x0006
#define HDA_GCAP_NSDO_1 0x0000
#define HDA_GCAP_NSDO_2 0x0002
#define HDA_GCAP_NSDO_4 0x0004
#define HDA_GCAP_NSDO_RESERVED 0x0006
#define HDA_GCAP_64OK 0x0001
#define HDA_VMIN 0x002 /* 1 */
#define HDA_VMAJ 0x003 /* 1 */
#define HDA_OUTPAY 0x004 /* 2 */
#define HDA_INPAY 0x006 /* 2 */
#define HDA_GCTL 0x008 /* 4 */
#define HDA_GCTL_UNSOL 0x00000080
#define HDA_GCTL_FCNTRL 0x00000002
#define HDA_GCTL_CRST 0x00000001
#define HDA_WAKEEN 0x00c /* 2 */
#define HDA_WAKEEN_SDIWEN 0x7fff
#define HDA_STATESTS 0x00e /* 2 */
#define HDA_STATESTS_SDIWAKE 0x7fff
#define HDA_GSTS 0x010 /* 2 */
#define HDA_GSTS_FSTS 0x0002
#define HDA_OUTSTRMPAY 0x018 /* 2 */
#define HDA_INSTRMPAY 0x01a /* 2 */
#define HDA_INTCTL 0x020 /* 4 */
#define HDA_INTCTL_GIE 0x80000000
#define HDA_INTCTL_CIE 0x40000000
#define HDA_INTCTL_SIE 0x3fffffff
#define HDA_INTSTS 0x024 /* 4 */
#define HDA_INTSTS_GIS 0x80000000
#define HDA_INTSTS_CIS 0x40000000
#define HDA_INTSTS_SIS 0x3fffffff
#define HDA_WALCLK 0x030 /* 4 */
#define HDA_SSYNC 0x034 /* 4 */
#define HDA_SSYNC_SSYNC 0x3fffffff
#define HDA_CORBLBASE 0x040 /* 4 */
#define HDA_CORBUBASE 0x044 /* 4 */
#define HDA_CORBWP 0x048 /* 2 */
#define HDA_CORBWP_CORBWP 0x00ff
#define HDA_CORBRP 0x04a /* 2 */
#define HDA_CORBRP_CORBRPRST 0x8000
#define HDA_CORBRP_CORBRP 0x00ff
#define HDA_CORBCTL 0x04c /* 1 */
#define HDA_CORBCTL_CORBRUN 0x02
#define HDA_CORBCTL_CMEIE 0x01
#define HDA_CORBSTS 0x04d /* 1 */
#define HDA_CORBSTS_CMEI 0x01
#define HDA_CORBSIZE 0x04e /* 1 */
#define HDA_CORBSIZE_CORBSZCAP_MASK 0xf0
#define HDA_CORBSIZE_CORBSZCAP_2 0x10
#define HDA_CORBSIZE_CORBSZCAP_16 0x20
#define HDA_CORBSIZE_CORBSZCAP_256 0x40
#define HDA_CORBSIZE_CORBSIZE_MASK 0x03
#define HDA_CORBSIZE_CORBSIZE_2 0x00
#define HDA_CORBSIZE_CORBSIZE_16 0x01
#define HDA_CORBSIZE_CORBSIZE_256 0x02
#define HDA_RIRBLBASE 0x050 /* 4 */
#define HDA_RIRBUBASE 0x054 /* 4 */
#define HDA_RIRBWP 0x058 /* 2 */
#define HDA_RIRBWP_RIRBWPRST 0x8000
#define HDA_RIRBWP_RIRBWP 0x00ff
#define HDA_RINTCNT 0x05a /* 2 */
#define HDA_RINTCNT_RINTCNT 0x00ff
#define HDA_RIRBCTL 0x05c /* 1 */
#define HDA_RIRBCTL_RIRBOIC 0x04
#define HDA_RIRBCTL_RIRBDMAEN 0x02
#define HDA_RIRBCTL_RINTCTL 0x01
#define HDA_RIRBSTS 0x05d /* 1 */
#define HDA_RIRBSTS_RIRBOIS 0x04
#define HDA_RIRBSTS_RINTFL 0x01
#define HDA_RIRBSIZE 0x05e /* 1 */
#define HDA_RIRBSIZE_RIRBSZCAP_MASK 0xf0
#define HDA_RIRBSIZE_RIRBSZCAP_2 0x10
#define HDA_RIRBSIZE_RIRBSZCAP_16 0x20
#define HDA_RIRBSIZE_RIRBSZCAP_256 0x40
#define HDA_RIRBSIZE_RIRBSIZE_MASK 0x03
#define HDA_RIRBSIZE_RIRBSIZE_2 0x00
#define HDA_RIRBSIZE_RIRBSIZE_16 0x01
#define HDA_RIRBSIZE_RIRBSIZE_256 0x02
#define HDA_IC 0x060 /* 4 */
#define HDA_IR 0x064 /* 4 */
#define HDA_IRS 0x068 /* 2 */
#define HDA_IRS_IRRADD 0x00f0
#define HDA_IRS_IRRUNSOL 0x0008
#define HDA_IRS_IRV 0x0002
#define HDA_IRS_ICB 0x0001
#define HDA_DPLBASE 0x070 /* 4 */
#define HDA_DPLBASE_DPLBASE 0xffffff80
#define HDA_DPLBASE_ENABLE 0x00000001
#define HDA_DPUBASE 0x074
#define HDA_SD_BASE 0x080
#define HDA_SD_CTL 0x00 /* 2 */
#define HDA_SD_CTL_DEIE 0x0010
#define HDA_SD_CTL_FEIE 0x0008
#define HDA_SD_CTL_IOCE 0x0004
#define HDA_SD_CTL_RUN 0x0002
#define HDA_SD_CTL_SRST 0x0001
#define HDA_SD_CTL2 0x02 /* 1 */
#define HDA_SD_CTL2_STRM 0xf0
#define HDA_SD_CTL2_STRM_SHIFT 4
#define HDA_SD_CTL2_DIR 0x08
#define HDA_SD_CTL2_TP 0x04
#define HDA_SD_CTL2_STRIPE 0x03
#define HDA_SD_STS 0x03 /* 1 */
#define HDA_SD_STS_FIFORDY 0x20
#define HDA_SD_STS_DESE 0x10
#define HDA_SD_STS_FIFOE 0x08
#define HDA_SD_STS_BCIS 0x04
#define HDA_SD_LPIB 0x04 /* 4 */
#define HDA_SD_CBL 0x08 /* 4 */
#define HDA_SD_LVI 0x0c /* 2 */
#define HDA_SD_LVI_LVI 0x00ff
#define HDA_SD_FIFOW 0x0e /* 2 */
#define HDA_SD_FIFOS 0x10 /* 2 */
#define HDA_SD_FMT 0x12 /* 2 */
#define HDA_SD_FMT_BASE 0x4000
#define HDA_SD_FMT_BASE_48 0x0000
#define HDA_SD_FMT_BASE_44 0x4000
#define HDA_SD_FMT_MULT 0x3800
#define HDA_SD_FMT_MULT_X1 0x0000
#define HDA_SD_FMT_MULT_X2 0x0800
#define HDA_SD_FMT_MULT_X3 0x1000
#define HDA_SD_FMT_MULT_X4 0x1800
#define HDA_SD_FMT_DIV 0x0700
#define HDA_SD_FMT_DIV_BY1 0x0000
#define HDA_SD_FMT_DIV_BY2 0x0100
#define HDA_SD_FMT_DIV_BY3 0x0200
#define HDA_SD_FMT_DIV_BY4 0x0300
#define HDA_SD_FMT_DIV_BY5 0x0400
#define HDA_SD_FMT_DIV_BY6 0x0500
#define HDA_SD_FMT_DIV_BY7 0x0600
#define HDA_SD_FMT_DIV_BY8 0x0700
#define HDA_SD_FMT_BITS 0x0070
#define HDA_SD_FMT_BITS_8_16 0x0000
#define HDA_SD_FMT_BITS_16_16 0x0010
#define HDA_SD_FMT_BITS_20_32 0x0020
#define HDA_SD_FMT_BITS_24_32 0x0030
#define HDA_SD_FMT_BITS_32_32 0x0040
#define HDA_SD_FMT_CHAN 0x000f
#define HDA_SD_BDPL 0x18 /* 4 */
#define HDA_SD_BDPU 0x1c /* 4 */
#define HDA_SD_SIZE 0x20
/* CORB commands */
#define CORB_GET_PARAMETER 0xf00
#define COP_VENDOR_ID 0x00
#define COP_VID_VENDOR(x) (x >> 16)
#define COP_VID_DEVICE(x) (x & 0xffff)
#define COP_REVISION_ID 0x02
#define COP_RID_MAJ(x) ((x >> 20) & 0x0f)
#define COP_RID_MIN(x) ((x >> 16) & 0x0f)
#define COP_RID_REVISION(x) ((x >> 8) & 0xff)
#define COP_RID_STEPPING(x) (x & 0xff)
#define COP_SUBORDINATE_NODE_COUNT 0x04
#define COP_START_NID(x) ((x & 0x00ff0000) >> 16)
#define COP_NSUBNODES(x) (x & 0x000000ff)
#define COP_FUNCTION_GROUP_TYPE 0x05
#define COP_FTYPE(x) (x & 0x000000ff)
#define COP_FTYPE_RESERVED 0x01
#define COP_FTYPE_AUDIO 0x01
#define COP_FTYPE_MODEM 0x02
#define COP_AUDIO_FUNCTION_GROUP_CAPABILITY 0x08
#define COP_AUDIO_WIDGET_CAP 0x09
#define COP_AWCAP_TYPE(x) ((x >> 20) & 0xf)
#define COP_AWTYPE_AUDIO_OUTPUT 0x0
#define COP_AWTYPE_AUDIO_INPUT 0x1
#define COP_AWTYPE_AUDIO_MIXER 0x2
#define COP_AWTYPE_AUDIO_SELECTOR 0x3
#define COP_AWTYPE_PIN_COMPLEX 0x4
#define COP_AWTYPE_POWER 0x5
#define COP_AWTYPE_VOLUME_KNOB 0x6
#define COP_AWTYPE_BEEP_GENERATOR 0x7
#define COP_AWTYPE_VENDOR_DEFINED 0xf
#define COP_AWCAP_STEREO 0x001
#define COP_AWCAP_INAMP 0x002
#define COP_AWCAP_OUTAMP 0x004
#define COP_AWCAP_AMPOV 0x008
#define COP_AWCAP_FORMATOV 0x010
#define COP_AWCAP_STRIPE 0x020
#define COP_AWCAP_PROC 0x040
#define COP_AWCAP_UNSOL 0x080
#define COP_AWCAP_CONNLIST 0x100
#define COP_AWCAP_DIGITAL 0x200
#define COP_AWCAP_POWER 0x400
#define COP_AWCAP_LRSWAP 0x800
#define COP_AWCAP_DELAY(x) ((x >> 16) & 0xf)
#define COP_PCM 0x0a
#define COP_PCM_B32 0x00100000
#define COP_PCM_B24 0x00080000
#define COP_PCM_B20 0x00040000
#define COP_PCM_B16 0x00020000
#define COP_PCM_B8 0x00010000
#define COP_PCM_R3840 0x00000800
#define COP_PCM_R1920 0x00000400
#define COP_PCM_R1764 0x00000200
#define COP_PCM_R960 0x00000100
#define COP_PCM_R882 0x00000080
#define COP_PCM_R480 0x00000040
#define COP_PCM_R441 0x00000020
#define COP_PCM_R320 0x00000010
#define COP_PCM_R220 0x00000008
#define COP_PCM_R160 0x00000004
#define COP_PCM_R110 0x00000002
#define COP_PCM_R80 0x00000001
#define COP_STREAM_FORMATS 0x0b
#define COP_STREAM_FORMAT_PCM 0x00000001
#define COP_STREAM_FORMAT_FLOAT32 0x00000002
#define COP_STREAM_FORMAT_AC3 0x00000003
#define COP_PINCAP 0x0c
#define COP_PINCAP_IMPEDANCE 0x00000001
#define COP_PINCAP_TRIGGER 0x00000002
#define COP_PINCAP_PRESENCE 0x00000004
#define COP_PINCAP_HEADPHONE 0x00000008
#define COP_PINCAP_OUTPUT 0x00000010
#define COP_PINCAP_INPUT 0x00000020
#define COP_PINCAP_BALANCE 0x00000040
#define COP_PINCAP_VREF(x) ((x >> 8) & 0xff)
#define COP_PINCAP_EAPD 0x00010000
#define COP_INPUT_AMPCAP 0x0d
#define COP_AMPCAP_OFFSET(x) (x & 0x0000007f)
#define COP_AMPCAP_NUMSTEPS(x) ((x >> 8) & 0x7f)
#define COP_AMPCAP_STEPSIZE(x) ((x >> 16) & 0x7f)
#define COP_AMPCAP_MUTE 0x80000000
#define COP_CONNECTION_LIST_LENGTH 0x0e
#define COP_CLL_LONG 0x00000080
#define COP_CLL_LENGTH(x) (x & 0x0000007f)
#define COP_SUPPORTED_POWER_STATES 0x0f
#define COP_PROCESSING_CAPABILITIES 0x10
#define COP_GPIO_COUNT 0x11
#define COP_OUTPUT_AMPCAP 0x12
#define COP_VOLUME_KNOB_CAPABILITIES 0x13
#define CORB_GET_CONNECTION_SELECT_CONTROL 0xf01
#define CORB_CSC_INDEX(x) (x & 0xff)
#define CORB_SET_CONNECTION_SELECT_CONTROL 0x701
#define CORB_GET_CONNECTION_LIST_ENTRY 0xf02
#define CORB_CLE_LONG_0(x) (x & 0x0000ffff)
#define CORB_CLE_LONG_1(x) ((x & 0xffff0000) >> 16)
#define CORB_CLE_SHORT_0(x) (x & 0xff)
#define CORB_CLE_SHORT_1(x) ((x >> 8) & 0xff)
#define CORB_CLE_SHORT_2(x) ((x >> 16) & 0xff)
#define CORB_CLE_SHORT_3(x) ((x >> 24) & 0xff)
#define CORB_GET_PROCESSING_STATE 0xf03
#define CORB_SET_PROCESSING_STATE 0x703
#define CORB_GET_COEFFICIENT_INDEX 0xd00
#define CORB_SET_COEFFICIENT_INDEX 0x500
#define CORB_GET_PROCESSING_COEFFICIENT 0xc00
#define CORB_SET_PROCESSING_COEFFICIENT 0x400
#define CORB_GET_AMPLIFIER_GAIN_MUTE 0xb00
#define CORB_GAGM_INPUT 0x0000
#define CORB_GAGM_OUTPUT 0x8000
#define CORB_GAGM_RIGHT 0x0000
#define CORB_GAGM_LEFT 0x2000
#define CORB_GAGM_MUTE 0x00000080
#define CORB_GAGM_GAIN(x) (x & 0x0000007f)
#define CORB_SET_AMPLIFIER_GAIN_MUTE 0x300
#define CORB_AGM_GAIN_MASK 0x007f
#define CORB_AGM_MUTE 0x0080
#define CORB_AGM_INDEX_SHIFT 8
#define CORB_AGM_RIGHT 0x1000
#define CORB_AGM_LEFT 0x2000
#define CORB_AGM_INPUT 0x4000
#define CORB_AGM_OUTPUT 0x8000
#define CORB_GET_CONVERTER_FORMAT 0xa00
#define CORB_SET_CONVERTER_FORMAT 0x200
#define CORB_GET_DIGITAL_CONVERTER_CONTROL 0xf0d
#define CORB_SET_DIGITAL_CONVERTER_CONTROL_L 0x70d
#define CORB_SET_DIGITAL_CONVERTER_CONTROL_H 0x70e
#define CORB_GET_POWER_STATE 0xf05
#define CORB_SET_POWER_STATE 0x705
#define CORB_GET_CONVERTER_STREAM_CHANNEL 0xf06
#define CORB_SET_CONVERTER_STREAM_CHANNEL 0x706
#define CORB_GET_INPUT_CONVERTER_SDI_SELECT 0xf04
#define CORB_SET_INPUT_CONVERTER_SDI_SELECT 0x704
#define CORB_GET_PIN_WIDGET_CONTROL 0xf07
#define CORB_SET_PIN_WIDGET_CONTROL 0x707
#define CORB_PWC_HEADPHONE 0x80
#define CORB_PWC_OUTPUT 0x40
#define CORB_PWC_INPUT 0x20
#define CORB_PWC_VREF_HIZ 0x00
#define CORB_PWC_VREF_50 0x01
#define CORB_PWC_VREF_GND 0x02
#define CORB_PWC_VREF_80 0x04
#define CORB_PWC_VREF_100 0x05
#define CORB_GET_UNSOLICITED_RESPONSE 0xf08
#define CORB_SET_UNSOLICITED_RESPONSE 0x708
#define CORB_GET_PIN_SENSE 0xf09
#define CORB_EXECUTE_PIN_SENSE 0x709
#define CORB_GET_EAPD_BTL_ENABLE 0xf0c
#define CORB_SET_EAPD_BTL_ENABLE 0x70c
#define CORB_GET_GPI_DATA 0xf10
#define CORB_SET_GPI_DATA 0x710
#define CORB_GET_GPI_WAKE_ENABLE_MASK 0xf11
#define CORB_SET_GPI_WAKE_ENABLE_MASK 0x711
#define CORB_GET_GPI_UNSOLICITED_ENABLE_MASK 0xf12
#define CORB_SET_GPI_UNSOLICITED_ENABLE_MASK 0x712
#define CORB_GET_GPI_STICKY_MASK 0xf13
#define CORB_SET_GPI_STICKY_MASK 0x713
#define CORB_GET_GPO_DATA 0xf14
#define CORB_SET_GPO_DATA 0x714
#define CORB_GET_GPIO_DATA 0xf15
#define CORB_SET_GPIO_DATA 0x715
#define CORB_GET_GPIO_ENABLE_MASK 0xf16
#define CORB_SET_GPIO_ENABLE_MASK 0x716
#define CORB_GET_GPIO_DIRECTION 0xf17
#define CORB_SET_GPIO_DIRECTION 0x717
#define CORB_GET_GPIO_WAKE_ENABLE_MASK 0xf18
#define CORB_SET_GPIO_WAKE_ENABLE_MASK 0x718
#define CORB_GET_GPIO_UNSOLICITED_ENABLE_MASK 0xf19
#define CORB_SET_GPIO_UNSOLICITED_ENABLE_MASK 0x719
#define CORB_GET_GPIO_STICKY_MASK 0xf1a
#define CORB_SET_GPIO_STICKY_MASK 0x71a
#define CORB_GET_BEEP_GENERATION 0xf0a
#define CORB_SET_BEEP_GENERATION 0x70a
#define CORB_GET_VOLUME_KNOB 0xf0f
#define CORB_SET_VOLUME_KNOB 0x70f
#define CORB_GET_SUBSYSTEM_ID 0xf20
#define CORB_SET_SUBSYSTEM_ID_1 0x720
#define CORB_SET_SUBSYSTEM_ID_2 0x721
#define CORB_SET_SUBSYSTEM_ID_3 0x722
#define CORB_SET_SUBSYSTEM_ID_4 0x723
#define CORB_GET_CONFIGURATION_DEFAULT 0xf1c
#define CORB_SET_CONFIGURATION_DEFAULT_1 0x71c
#define CORB_SET_CONFIGURATION_DEFAULT_2 0x71d
#define CORB_SET_CONFIGURATION_DEFAULT_3 0x71e
#define CORB_SET_CONFIGURATION_DEFAULT_4 0x71f
#define CORB_CD_SEQUENCE(x) (x & 0x0000000f)
#define CORB_CD_SEQUENCE_MAX 0x0f
#define CORB_CD_ASSOCIATION(x) ((x >> 4) & 0xf)
#define CORB_CD_ASSOCIATION_MAX 0x0f
#define CORB_CD_MISC_MASK 0x00000f00
#define CORB_CD_COLOR(x) ((x >> 12) & 0xf)
#define CORB_CD_COLOR_UNKNOWN 0x0
#define CORB_CD_BLACK 0x1
#define CORB_CD_GRAY 0x2
#define CORB_CD_BLUE 0x3
#define CORB_CD_GREEN 0x4
#define CORB_CD_RED 0x5
#define CORB_CD_ORANGE 0x6
#define CORB_CD_YELLOW 0x7
#define CORB_CD_PURPLE 0x8
#define CORB_CD_PINK 0x9
#define CORB_CD_WHITE 0xe
#define CORB_CD_COLOR_OTHER 0xf
#define CORB_CD_CONNECTION_MASK 0x000f0000
#define CORB_CD_DEVICE(x) ((x >> 20) & 0xf)
#define CORB_CD_LINEOUT 0x0
#define CORB_CD_SPEAKER 0x1
#define CORB_CD_HEADPHONE 0x2
#define CORB_CD_CD 0x3
#define CORB_CD_SPDIFOUT 0x4
#define CORB_CD_DIGITALOUT 0x5
#define CORB_CD_MODEMLINE 0x6
#define CORB_CD_MODEMHANDSET 0x7
#define CORB_CD_LINEIN 0x8
#define CORB_CD_AUX 0x9
#define CORB_CD_MICIN 0xa
#define CORB_CD_TELEPHONY 0xb
#define CORB_CD_SPDIFIN 0xc
#define CORB_CD_DIGITALIN 0xd
#define CORB_CD_DEVICE_OTHER 0xf
#define CORB_CD_LOCATION_MASK 0x3f000000
#define CORB_CD_PORT_MASK 0xc0000000
#define CORB_GET_STRIPE_CONTROL 0xf24
#define CORB_SET_STRIPE_CONTROL 0x720 /* XXX typo in the spec? */
#define CORB_EXECUTE_FUNCTION_RESET 0x7ff
#define CORB_NID_ROOT 0
#define HDA_MAX_CHANNELS 16
#define PCI_SUBCLASS_HDAUDIO 0x03
/* memory-mapped types */
typedef struct {
uint32_t low;
uint32_t high;
uint32_t length;
uint32_t flags;
#define BDLIST_ENTRY_IOC 0x00000001
} __packed bdlist_entry_t;
#define HDA_BDL_MAX 256
typedef struct {
uint32_t position;
uint32_t reserved;
} __packed dmaposition_t;
typedef uint32_t corb_entry_t;
typedef struct {
uint32_t resp;
uint32_t resp_ex;
} __packed rirb_entry_t;
/* ----------------------------------------------------------------
* ICH6/ICH7 constant values
* ---------------------------------------------------------------- */
/* PCI registers */
#define ICH_PCI_HDBARL 0x10
#define ICH_PCI_HDBARU 0x14
#define ICH_PCI_HDCTL 0x40
#define ICH_PCI_HDCTL_CLKDETCLR 0x08
#define ICH_PCI_HDCTL_CLKDETEN 0x04
#define ICH_PCI_HDCTL_CLKDETINV 0x02
#define ICH_PCI_HDCTL_SIGNALMODE 0x01
/* #define AZALIA_DEBUG */
#ifdef AZALIA_DEBUG
# define DPRINTF(x) do { printf x; } while (0/*CONSTCOND*/)
#else
# define DPRINTF(x) do {} while (0/*CONSTCOND*/)
#endif
#define PTR_UPPER32(x) ((uint64_t)(uintptr_t)x >> 32)
#define FLAGBUFLEN 256
#define MAX_VOLUME_255 1
/* internal types */
typedef struct {
bus_dmamap_t map;
caddr_t addr; /* kernel virtual address */
bus_dma_segment_t segments[1];
size_t size;
} azalia_dma_t;
#define AZALIA_DMA_DMAADDR(p) ((p)->map->dm_segs[0].ds_addr)
typedef struct {
int regbase;
int number;
uint32_t intr_bit;
azalia_dma_t bdlist;
azalia_dma_t buffer;
void (*intr)(void*);
void *intr_arg;
bus_addr_t dmaend, dmanext; /* XXX needed? */
} stream_t;
#define STR_READ_1(z, s, r) \
bus_space_read_1((z)->iot, (z)->ioh, (s)->regbase + HDA_SD_##r)
#define STR_READ_2(z, s, r) \
bus_space_read_2((z)->iot, (z)->ioh, (s)->regbase + HDA_SD_##r)
#define STR_READ_4(z, s, r) \
bus_space_read_4((z)->iot, (z)->ioh, (s)->regbase + HDA_SD_##r)
#define STR_WRITE_1(z, s, r, v) \
bus_space_write_1((z)->iot, (z)->ioh, (s)->regbase + HDA_SD_##r, v)
#define STR_WRITE_2(z, s, r, v) \
bus_space_write_2((z)->iot, (z)->ioh, (s)->regbase + HDA_SD_##r, v)
#define STR_WRITE_4(z, s, r, v) \
bus_space_write_4((z)->iot, (z)->ioh, (s)->regbase + HDA_SD_##r, v)
typedef int nid_t;
typedef struct {
nid_t nid;
uint32_t widgetcap;
int type; /* = bit20-24 of widgetcap */
int nconnections;
nid_t *connections;
int selected;
uint32_t inamp_cap;
uint32_t outamp_cap;
char name[MAX_AUDIO_DEV_LEN];
union {
struct { /* for AUDIO_INPUT/OUTPUT */
uint32_t encodings;
uint32_t bits_rates;
} audio;
struct { /* for PIN */
uint32_t cap;
uint32_t config;
int sequence;
int association;
int color;
int device;
} pin;
struct { /* for VOLUME_KNOB */
uint32_t cap;
} volume;
} d;
} widget_t;
typedef struct {
mixer_devinfo_t devinfo;
nid_t nid; /* target NID; 0 is invalid. */
int target; /* 0-15: inamp index, 0x100: outamp */
#define IS_MI_TARGET_INAMP(x) ((x) <= 15)
#define MI_TARGET_INAMP(x) (x)
#define MI_TARGET_OUTAMP 0x100
#define MI_TARGET_CONNLIST 0x101
#define MI_TARGET_PINDIR 0x102 /* for bidirectional pin */
#define MI_TARGET_PINBOOST 0x103 /* for headphone pin */
#define MI_TARGET_DAC 0x104
#define MI_TARGET_ADC 0x105
} mixer_item_t;
typedef struct {
int nconv;
nid_t conv[HDA_MAX_CHANNELS];
} convgroup_t;
typedef struct codec_t {
int (*comresp)(const struct codec_t *, nid_t, uint32_t, uint32_t, uint32_t *);
struct azalia_t *az;
int address;
int nfunctions;
nid_t audiofunc; /* NID of an audio function node */
nid_t wstart; /* start NID of audio widgets */
nid_t wend; /* the last NID of audio widgets + 1 */
widget_t *w; /* widgets in the audio function.
* w[0] to w[wstart-1] are unused. */
#define FOR_EACH_WIDGET(this, i) for (i = (this)->wstart; i < (this)->wend; i++)
int ndacgroups;
convgroup_t dacgroups[32];
int cur_dac; /* currently selected DAC group index */
int nadcs;
nid_t adcs[32];
int cur_adc; /* currently selected ADC index */
int nmixers, maxmixers;
mixer_item_t *mixers;
struct audio_format* formats;
int nformats;
struct audio_encoding_set *encodings;
} codec_t;
typedef struct azalia_t {
struct device dev;
struct device *audiodev;
void *ih;
bus_space_tag_t iot;
bus_space_handle_t ioh;
bus_dma_tag_t dmat;
codec_t codecs[15];
int ncodecs;
azalia_dma_t corb_dma;
int corb_size;
azalia_dma_t rirb_dma;
int rirb_size;
int rirb_rp;
int nistreams, nostreams, nbstreams;
stream_t pstream;
stream_t rstream;
int running;
} azalia_t;
#define XNAME(sc) ((sc)->dev.dv_xname)
#define AZ_READ_1(z, r) bus_space_read_1((z)->iot, (z)->ioh, HDA_##r)
#define AZ_READ_2(z, r) bus_space_read_2((z)->iot, (z)->ioh, HDA_##r)
#define AZ_READ_4(z, r) bus_space_read_4((z)->iot, (z)->ioh, HDA_##r)
#define AZ_WRITE_1(z, r, v) bus_space_write_1((z)->iot, (z)->ioh, HDA_##r, v)
#define AZ_WRITE_2(z, r, v) bus_space_write_2((z)->iot, (z)->ioh, HDA_##r, v)
#define AZ_WRITE_4(z, r, v) bus_space_write_4((z)->iot, (z)->ioh, HDA_##r, v)
/* prototypes */
static int azalia_pci_match(struct device *, struct cfdata *, void *);
static void azalia_pci_attach(struct device *, struct device *, void *);
static int azalia_pci_detach(struct device *, int);
static int azalia_intr(void *);
static int azalia_attach(azalia_t *);
static void azalia_attach_intr(struct device *);
static int azalia_init_corb(azalia_t *);
static int azalia_init_rirb(azalia_t *);
static int azalia_set_command(const azalia_t *, nid_t, int, uint32_t,
uint32_t);
static int azalia_get_response(azalia_t *, uint32_t *);
static int azalia_alloc_dmamem(azalia_t *, size_t, size_t, azalia_dma_t *);
static int azalia_free_dmamem(const azalia_t *, azalia_dma_t*);
static int azalia_codec_init(codec_t *);
static int azalia_codec_construct_format(codec_t *);
static void azalia_codec_add_format(codec_t *, int, int, int, uint32_t,
int32_t);
static int azalia_codec_find_pin(const codec_t *, int, int, uint32_t);
static int azalia_codec_find_dac(const codec_t *, int, int);
static int azalia_codec_comresp(const codec_t *, nid_t, uint32_t,
uint32_t, uint32_t *);
static int azalia_codec_connect_stream(codec_t *, int, uint16_t, int);
static int azalia_mixer_init(codec_t *);
static int azalia_mixer_get(const codec_t *, mixer_ctrl_t *);
static int azalia_mixer_set(codec_t *, const mixer_ctrl_t *);
static int azalia_mixer_ensure_capacity(codec_t *, size_t);
static u_char azalia_mixer_from_device_value(const codec_t *,
const mixer_item_t *, uint32_t );
static uint32_t azalia_mixer_to_device_value(const codec_t *,
const mixer_item_t *, u_char);
static boolean_t azalia_mixer_validate_value(const codec_t *,
const mixer_item_t *, u_char);
static int azalia_widget_init(widget_t *, const codec_t *, int);
static int azalia_widget_init_audio(widget_t *, const codec_t *);
static int azalia_widget_print_audio(const widget_t *, const char *);
static int azalia_widget_init_pin(widget_t *, const codec_t *);
static int azalia_widget_print_pin(const widget_t *);
static int azalia_widget_init_connection(widget_t *, const codec_t *);
static int azalia_open(void *, int);
static void azalia_close(void *);
static int azalia_query_encoding(void *, audio_encoding_t *);
static int azalia_set_params(void *, int, int, audio_params_t *,
audio_params_t *, stream_filter_list_t *, stream_filter_list_t *);
static int azalia_round_blocksize(void *, int, int, const audio_params_t *);
static int azalia_halt_output(void *);
static int azalia_halt_input(void *);
static int azalia_getdev(void *, struct audio_device *);
static int azalia_set_port(void *, mixer_ctrl_t *);
static int azalia_get_port(void *, mixer_ctrl_t *);
static int azalia_query_devinfo(void *, mixer_devinfo_t *);
static void *azalia_allocm(void *, int, size_t, struct malloc_type *, int);
static void azalia_freem(void *, void *, struct malloc_type *);
static size_t azalia_round_buffersize(void *, int, size_t);
static int azalia_get_props(void *);
static int azalia_trigger_output(void *, void *, void *, int,
void (*)(void *), void *, const audio_params_t *);
static int azalia_trigger_input(void *, void *, void *, int,
void (*)(void *), void *, const audio_params_t *);
static int azalia_params2fmt(const audio_params_t *, uint16_t *);
/* variables */
CFATTACH_DECL(azalia, sizeof(azalia_t),
azalia_pci_match, azalia_pci_attach, azalia_pci_detach, NULL);
static const struct audio_hw_if azalia_hw_if = {
azalia_open,
azalia_close,
NULL, /* drain */
azalia_query_encoding,
azalia_set_params,
azalia_round_blocksize,
NULL, /* commit_settings */
NULL, /* init_output */
NULL, /* init_input */
NULL, /* start_output */
NULL, /* satart_inpu */
azalia_halt_output,
azalia_halt_input,
NULL, /* speaker_ctl */
azalia_getdev,
NULL, /* setfd */
azalia_set_port,
azalia_get_port,
azalia_query_devinfo,
azalia_allocm,
azalia_freem,
azalia_round_buffersize,
NULL, /* mappage */
azalia_get_props,
azalia_trigger_output,
azalia_trigger_input,
NULL, /* dev_ioctl */
};
static const char *pin_colors[16] = {
"unknown", "black", "gray", "blue",
"green", "red", "orange", "yellow",
"purple", "pink", "col0a", "col0b",
"col0c", "col0d", "white", "other"};
#ifdef AZALIA_DEBUG
static const char *pin_devices[16] = {
"line-out", AudioNspeaker, AudioNheadphone, AudioNcd,
"SPDIF-out", "digital-out", "modem-line", "modem-handset",
"line-in", AudioNaux, AudioNmicrophone, "telephony",
"SPDIF-in", "digital-in", "dev0e", "other"};
#endif
/* ================================================================
* PCI functions
* ================================================================ */
static int
azalia_pci_match(struct device *parent, struct cfdata *match, void *aux)
{
struct pci_attach_args *pa;
pa = aux;
if (PCI_CLASS(pa->pa_class) == PCI_CLASS_MULTIMEDIA
&& PCI_SUBCLASS(pa->pa_class) == PCI_SUBCLASS_HDAUDIO)
return 1;
return 0;
}
static void
azalia_pci_attach(struct device *parent, struct device *self, void *aux)
{
azalia_t *sc;
struct pci_attach_args *pa;
bus_size_t regsize;
pcireg_t v;
pci_intr_handle_t ih;
const char *intrrupt_str;
const char *name;
sc = (azalia_t*)self;
pa = aux;
sc->dmat = pa->pa_dmat;
aprint_normal(": Generic High Definition Audio Controller\n");
if (pci_mapreg_map(pa, ICH_PCI_HDBARL, PCI_MAPREG_MEM_TYPE_64BIT, 0,
&sc->iot, &sc->ioh, NULL, &regsize)) {
aprint_error("%s: can't map device i/o space\n", XNAME(sc));
return;
}
/* enable bus mastering */
v = pci_conf_read(pa->pa_pc, pa->pa_tag, PCI_COMMAND_STATUS_REG);
pci_conf_write(pa->pa_pc, pa->pa_tag, PCI_COMMAND_STATUS_REG,
v | PCI_COMMAND_MASTER_ENABLE | PCI_COMMAND_BACKTOBACK_ENABLE);
/* interrupt */
if (pci_intr_map(pa, &ih)) {
aprint_error("%s: can't map interrupt\n", XNAME(sc));
return;
}
intrrupt_str = pci_intr_string(pa->pa_pc, ih);
sc->ih = pci_intr_establish(pa->pa_pc, ih, IPL_AUDIO, azalia_intr, sc);
if (sc->ih == NULL) {
aprint_error("%s: can't establish interrupt", XNAME(sc));
if (intrrupt_str != NULL)
aprint_error(" at %s", intrrupt_str);
aprint_error("\n");
return;
}
aprint_normal("%s: interrupting at %s\n", XNAME(sc), intrrupt_str);
name = pci_findproduct(pa->pa_id);
if (name != NULL) {
aprint_normal("%s: host: %s (rev. %d)\n",
XNAME(sc), name, PCI_REVISION(pa->pa_class));
} else {
aprint_normal("%s: host: 0x%4.4x/0x%4.4x (rev. %d)\n",
XNAME(sc), PCI_VENDOR(pa->pa_id), PCI_PRODUCT(pa->pa_id),
PCI_REVISION(pa->pa_class));
}
if (azalia_attach(sc)) {
aprint_error("%s: initialization failure\n", XNAME(sc));
return;
}
config_interrupts(self, azalia_attach_intr);
}
static int
azalia_pci_detach(struct device *self, int flags)
{
azalia_t *az;
az = (azalia_t*)self;
azalia_free_dmamem(az, &az->corb_dma);
return 0;
}
static int
azalia_intr(void *v)
{
azalia_t *az;
stream_t *str;
int ret;
uint32_t intsts;
uint8_t rirbsts;
az = v;
ret = 0;
//printf("[i]");
intsts = AZ_READ_4(az, INTSTS);
if (intsts == 0)
return ret;
str = &az->pstream;
if (intsts & str->intr_bit) {
STR_WRITE_1(az, str, STS,
HDA_SD_STS_DESE | HDA_SD_STS_FIFOE | HDA_SD_STS_BCIS);
//printf("[p]");
str->intr(str->intr_arg);
ret++;
}
rirbsts = AZ_READ_1(az, RIRBSTS);
if (rirbsts & (HDA_RIRBSTS_RIRBOIS | HDA_RIRBSTS_RINTFL)) {
if (rirbsts & HDA_RIRBSTS_RINTFL) {
//printf("[R]");
} else {
//printf("[O]");
}
AZ_WRITE_1(az, RIRBSTS,
rirbsts | HDA_RIRBSTS_RIRBOIS | HDA_RIRBSTS_RINTFL);
ret++;
}
return 0;
}
/* ================================================================
* HDA controller functions
* ================================================================ */
static int
azalia_attach(azalia_t *az)
{
int i, n;
uint32_t gctl;
uint16_t gcap;
uint16_t statests;
aprint_normal("%s: host: High Definition Audio rev. %d.%d\n",
XNAME(az), AZ_READ_1(az, VMAJ), AZ_READ_1(az, VMIN));
gcap = AZ_READ_2(az, GCAP);
az->nistreams = HDA_GCAP_ISS(gcap);
az->nostreams = HDA_GCAP_OSS(gcap);
az->nbstreams = HDA_GCAP_BSS(gcap);
DPRINTF(("%s: host: %d output, %d input, and %d bidi streams\n",
XNAME(az), az->nostreams, az->nistreams, az->nbstreams));
/* 4.2.2 Starting the High Definition Audio Controller */
DPRINTF(("%s: resetting\n", __func__));
gctl = AZ_READ_4(az, GCTL);
AZ_WRITE_4(az, GCTL, gctl & ~HDA_GCTL_CRST);
for (i = 5000; i >= 0; i--) {
DELAY(10);
if ((AZ_READ_4(az, GCTL) & HDA_GCTL_CRST) == 0)
break;
}
DPRINTF(("%s: reset counter = %d\n", __func__, i));
if (i <= 0) {
aprint_error("%s: reset failure\n", XNAME(az));
return ETIMEDOUT;
}
DELAY(1000);
gctl = AZ_READ_4(az, GCTL);
AZ_WRITE_4(az, GCTL, gctl | HDA_GCTL_CRST);
for (i = 5000; i >= 0; i--) {
DELAY(10);
if (AZ_READ_4(az, GCTL) & HDA_GCTL_CRST)
break;
}
DPRINTF(("%s: reset counter = %d\n", __func__, i));
if (i <= 0) {
aprint_error("%s: reset-exit failure\n", XNAME(az));
return ETIMEDOUT;
}
/* 4.3 Codec discovery */
DELAY(1000);
statests = AZ_READ_2(az, STATESTS);
for (i = 0, n = 0; i < 15; i++) {
if ((statests >> i) & 1) {
DPRINTF(("%s: found a codec at #%d\n", XNAME(az), i));
az->codecs[n].address = i;
az->codecs[n++].az = az;
}
}
az->ncodecs = n;
if (az->ncodecs < 1) {
aprint_error("%s: No HD-Audio codecs\n", XNAME(az));
return -1;
}
return 0;
}
static void
azalia_attach_intr(struct device *self)
{
azalia_t *az;
int err, i;
az = (azalia_t*)self;
AZ_WRITE_2(az, STATESTS, HDA_STATESTS_SDIWAKE);
AZ_WRITE_1(az, RIRBSTS, HDA_RIRBSTS_RINTFL | HDA_RIRBSTS_RIRBOIS);
AZ_WRITE_4(az, INTSTS, HDA_INTSTS_CIS | HDA_INTSTS_GIS);
AZ_WRITE_4(az, DPLBASE, 0);
AZ_WRITE_4(az, DPUBASE, 0);
/* 4.4.1 Command Outbound Ring Buffer */
azalia_init_corb(az);
/* 4.4.2 Response Inbound Ring Buffer */
azalia_init_rirb(az);
AZ_WRITE_4(az, INTCTL,
AZ_READ_4(az, INTCTL) | HDA_INTCTL_CIE | HDA_INTCTL_GIE);
for (i = 0; i < az->ncodecs; i++) {
err = azalia_codec_init(&az->codecs[i]);
if (err)
return;
}
az->pstream.regbase = HDA_SD_BASE + (az->nistreams + 0) * HDA_SD_SIZE;
az->pstream.intr_bit = 1 << ((az->pstream.regbase - HDA_SD_BASE) / HDA_SD_SIZE);
az->pstream.number = 1;
az->rstream.regbase = HDA_SD_BASE + 0 * HDA_SD_SIZE;
az->rstream.intr_bit = 1 << ((az->rstream.regbase - HDA_SD_BASE) / HDA_SD_SIZE);
az->rstream.number = 2;
/* setup BDL buffers */
err = azalia_alloc_dmamem(az, sizeof(bdlist_entry_t) * HDA_BDL_MAX,
128, &az->pstream.bdlist);
if (err) {
aprint_error("%s: can't allocate a BDL buffer\n", XNAME(az));
return;
}
err = azalia_alloc_dmamem(az, sizeof(bdlist_entry_t) * HDA_BDL_MAX,
128, &az->rstream.bdlist);
if (err) {
aprint_error("%s: can't allocate a BDL buffer\n", XNAME(az));
return;
}
az->audiodev = audio_attach_mi(&azalia_hw_if, az, &az->dev);
return;
/* XXX deallocation on errors */
}
static int
azalia_init_corb(azalia_t *az)
{
int entries, err, i;
uint16_t corbrp, corbwp;
uint8_t corbsize, cap, corbctl;
/* stop the CORB */
corbctl = AZ_READ_1(az, CORBCTL);
if (corbctl & HDA_CORBCTL_CORBRUN) { /* running? */
AZ_WRITE_1(az, CORBCTL, corbctl & ~HDA_CORBCTL_CORBRUN);
for (i = 5000; i >= 0; i--) {
DELAY(10);
corbctl = AZ_READ_1(az, CORBCTL);
if ((corbctl & HDA_CORBCTL_CORBRUN) == 0)
break;
}
if (i <= 0) {
aprint_error("%s: CORB is running\n", XNAME(az));
return EBUSY;
}
}
/* determine CORB size */
corbsize = AZ_READ_1(az, CORBSIZE);
cap = corbsize & HDA_CORBSIZE_CORBSZCAP_MASK;
corbsize &= ~HDA_CORBSIZE_CORBSIZE_MASK;
if (cap & HDA_CORBSIZE_CORBSZCAP_256) {
entries = 256;
corbsize |= HDA_CORBSIZE_CORBSIZE_256;
} else if (cap & HDA_CORBSIZE_CORBSZCAP_16) {
entries = 16;
corbsize |= HDA_CORBSIZE_CORBSIZE_16;
} else if (cap & HDA_CORBSIZE_CORBSZCAP_2) {
entries = 2;
corbsize |= HDA_CORBSIZE_CORBSIZE_2;
} else {
aprint_error("%s: Invalid CORBSZCAP: 0x%2x\n", XNAME(az), cap);
return -1;
}
err = azalia_alloc_dmamem(az, entries * sizeof(corb_entry_t),
128, &az->corb_dma);
if (err) {
aprint_error("%s: can't allocate CORB buffer\n", XNAME(az));
return err;
}
AZ_WRITE_4(az, CORBLBASE, (uint32_t)AZALIA_DMA_DMAADDR(&az->corb_dma));
AZ_WRITE_4(az, CORBUBASE, PTR_UPPER32(AZALIA_DMA_DMAADDR(&az->corb_dma)));
AZ_WRITE_1(az, CORBSIZE, corbsize);
az->corb_size = entries;
DPRINTF(("%s: CORB allocation succeeded.\n", __func__));
/* reset CORBRP */
corbrp = AZ_READ_2(az, CORBRP);
AZ_WRITE_2(az, CORBRP, corbrp | HDA_CORBRP_CORBRPRST);
for (i = 5000; i >= 0; i--) {
DELAY(10);
corbrp = AZ_READ_2(az, CORBRP);
if (corbrp & HDA_CORBRP_CORBRPRST)
break;
}
if (i <= 0) {
aprint_error("%s: CORBRP reset failure\n", XNAME(az));
return -1;
}
AZ_WRITE_2(az, CORBRP, corbrp & ~HDA_CORBRP_CORBRPRST);
for (i = 5000; i >= 0; i--) {
DELAY(10);
corbrp = AZ_READ_2(az, CORBRP);
if ((corbrp & HDA_CORBRP_CORBRPRST) == 0)
break;
}
if (i <= 0) {
aprint_error("%s: CORBRP reset failure 2\n", XNAME(az));
return -1;
}
DPRINTF(("%s: CORBWP=%d; size=%d\n", __func__,
AZ_READ_2(az, CORBRP) & HDA_CORBRP_CORBRP, az->corb_size));
/* clear CORBWP */
corbwp = AZ_READ_2(az, CORBWP);
AZ_WRITE_2(az, CORBWP, corbwp & ~HDA_CORBWP_CORBWP);
/* Run! */
corbctl = AZ_READ_1(az, CORBCTL);
AZ_WRITE_1(az, CORBCTL, corbctl | HDA_CORBCTL_CORBRUN);
return 0;
}
static int
azalia_init_rirb(azalia_t *az)
{
int entries, err, i;
uint16_t rirbwp;
uint8_t rirbsize, cap, rirbctl;
/* stop the RIRB */
rirbctl = AZ_READ_1(az, RIRBCTL);
if (rirbctl & HDA_RIRBCTL_RIRBDMAEN) { /* running? */
AZ_WRITE_1(az, RIRBCTL, rirbctl & ~HDA_RIRBCTL_RIRBDMAEN);
for (i = 5000; i >= 0; i--) {
DELAY(10);
rirbctl = AZ_READ_1(az, RIRBCTL);
if ((rirbctl & HDA_RIRBCTL_RIRBDMAEN) == 0)
break;
}
if (i <= 0) {
aprint_error("%s: RIRB is running\n", XNAME(az));
return EBUSY;
}
}
/* determine RIRB size */
rirbsize = AZ_READ_1(az, RIRBSIZE);
cap = rirbsize & HDA_RIRBSIZE_RIRBSZCAP_MASK;
rirbsize &= ~HDA_RIRBSIZE_RIRBSIZE_MASK;
if (cap & HDA_RIRBSIZE_RIRBSZCAP_256) {
entries = 256;
rirbsize |= HDA_RIRBSIZE_RIRBSIZE_256;
} else if (cap & HDA_RIRBSIZE_RIRBSZCAP_16) {
entries = 16;
rirbsize |= HDA_RIRBSIZE_RIRBSIZE_16;
} else if (cap & HDA_RIRBSIZE_RIRBSZCAP_2) {
entries = 2;
rirbsize |= HDA_RIRBSIZE_RIRBSIZE_2;
} else {
aprint_error("%s: Invalid RIRBSZCAP: 0x%2x\n", XNAME(az), cap);
return -1;
}
err = azalia_alloc_dmamem(az, entries * sizeof(rirb_entry_t),
128, &az->rirb_dma);
if (err) {
aprint_error("%s: can't allocate RIRB buffer\n", XNAME(az));
return err;
}
AZ_WRITE_4(az, RIRBLBASE, (uint32_t)AZALIA_DMA_DMAADDR(&az->rirb_dma));
AZ_WRITE_4(az, RIRBUBASE, PTR_UPPER32(AZALIA_DMA_DMAADDR(&az->rirb_dma)));
AZ_WRITE_1(az, RIRBSIZE, rirbsize);
az->rirb_size = entries;
DPRINTF(("%s: RIRB allocation succeeded.\n", __func__));
//rirbctl = AZ_READ_1(az, RIRBCTL);
//AZ_WRITE_1(az, RIRBCTL, rirbctl & ~HDA_RIRBCTL_RINTCTL);
/* reset the write pointer */
rirbwp = AZ_READ_2(az, RIRBWP);
AZ_WRITE_2(az, RIRBWP, rirbwp | HDA_RIRBWP_RIRBWPRST);
/* clear the read pointer */
az->rirb_rp = AZ_READ_2(az, RIRBWP) & HDA_RIRBWP_RIRBWP;
DPRINTF(("%s: RIRBRP=%d, size=%d\n", __func__, az->rirb_rp, az->rirb_size));
AZ_WRITE_2(az, RINTCNT, 1);
/* Run! */
rirbctl = AZ_READ_1(az, RIRBCTL);
AZ_WRITE_1(az, RIRBCTL, rirbctl | HDA_RIRBCTL_RIRBDMAEN | HDA_RIRBCTL_RINTCTL);
return 0;
}
static int
azalia_set_command(const azalia_t *az, int caddr, nid_t nid, uint32_t control,
uint32_t param)
{
corb_entry_t *corb;
int wp;
uint32_t verb;
uint16_t corbwp;
#ifdef DIAGNOSTIC
if ((AZ_READ_1(az, CORBCTL) & HDA_CORBCTL_CORBRUN) == 0) {
aprint_error("%s: CORB is not running.\n", XNAME(az));
return -1;
}
#endif
verb = (caddr << 28) | (nid << 20) | (control << 8) | param;
corbwp = AZ_READ_2(az, CORBWP);
wp = corbwp & HDA_CORBWP_CORBWP;
corb = (corb_entry_t*)az->corb_dma.addr;
if (++wp >= az->corb_size)
wp = 0;
corb[wp] = verb;
AZ_WRITE_2(az, CORBWP, (corbwp & ~HDA_CORBWP_CORBWP) | wp);
#if 0
DPRINTF(("%s: caddr=%d nid=%d control=0x%x param=0x%x verb=0x%8.8x wp=%d\n",
__func__, caddr, nid, control, param, verb, wp));
#endif
return 0;
}
static int
azalia_get_response(azalia_t *az, uint32_t *result)
{
const rirb_entry_t *rirb;
int i;
uint16_t wp;
#ifdef DIAGNOSTIC
if ((AZ_READ_1(az, RIRBCTL) & HDA_RIRBCTL_RIRBDMAEN) == 0) {
aprint_error("%s: RIRB is not running.\n", XNAME(az));
return -1;
}
#endif
for (i = 5000; i >= 0; i--) {
wp = AZ_READ_2(az, RIRBWP) & HDA_RIRBWP_RIRBWP;
if (az->rirb_rp != wp)
break;
DELAY(10);
}
if (i <= 0) {
aprint_error("%s: RIRB time out\n", XNAME(az));
return ETIMEDOUT;
}
rirb = (rirb_entry_t*)az->rirb_dma.addr;
if (++az->rirb_rp >= az->rirb_size)
az->rirb_rp = 0;
if (result != NULL)
*result = rirb[az->rirb_rp].resp;
#if 0
DPRINTF(("%s: rirbwp=%d rp=%d resp1=0x%8.8x resp2=0x%8.8x\n",
__func__, wp, az->rirb_rp, rirb[az->rirb_rp].resp,
rirb[az->rirb_rp].resp_ex));
#endif
#if 0
for (i = 0; i < 16 /*az->rirb_size*/; i++) {
DPRINTF(("rirb[%d] 0x%8.8x:0x%8.8x ", i, rirb[i].resp, rirb[i].resp_ex));
if ((i % 2) == 1)
DPRINTF(("\n"));
}
#endif
return 0;
}
static int
azalia_alloc_dmamem(azalia_t *az, size_t size, size_t align, azalia_dma_t *d)
{
int err;
int nsegs;
d->size = size;
err = bus_dmamem_alloc(az->dmat, size, align, 0, d->segments, 1,
&nsegs, BUS_DMA_NOWAIT);
if (err)
return err;
if (nsegs != 1)
goto free;
err = bus_dmamem_map(az->dmat, d->segments, 1, size,
&d->addr, BUS_DMA_NOWAIT | BUS_DMA_COHERENT | BUS_DMA_NOCACHE);
if (err)
goto free;
err = bus_dmamap_create(az->dmat, size, 1, size, 0,
BUS_DMA_NOWAIT, &d->map);
if (err)
goto unmap;
err = bus_dmamap_load(az->dmat, d->map, d->addr, size,
NULL, BUS_DMA_NOWAIT);
if (err)
goto destroy;
return 0;
destroy:
bus_dmamap_destroy(az->dmat, d->map);
unmap:
bus_dmamem_unmap(az->dmat, d->addr, size);
free:
bus_dmamem_free(az->dmat, d->segments, 1);
return err;
}
static int
azalia_free_dmamem(const azalia_t *az, azalia_dma_t* d)
{
bus_dmamap_unload(az->dmat, d->map);
bus_dmamap_destroy(az->dmat, d->map);
bus_dmamem_unmap(az->dmat, d->addr, d->size);
bus_dmamem_free(az->dmat, d->segments, 1);
return 0;
}
/* ================================================================
* HDA coodec functions
* ================================================================ */
static int
azalia_codec_init(codec_t *this)
{
uint32_t rev, result, digital;
int err, addr, n, i, j;
int assoc, dac, seq, group;
this->comresp = azalia_codec_comresp;
addr = this->address;
DPRINTF(("%s: information of codec[%d] follows:\n",
XNAME(this->az), addr));
/* codec vendor/device/revision */
err = this->comresp(this, CORB_NID_ROOT, CORB_GET_PARAMETER,
COP_REVISION_ID, &rev);
if (err)
return err;
err = this->comresp(this, CORB_NID_ROOT, CORB_GET_PARAMETER,
COP_VENDOR_ID, &result);
if (err)
return err;
aprint_normal("%s: codec: 0x%4.4x/0x%4.4x (rev. %u.%u)\n",
XNAME(this->az), result >> 16, result & 0xffff,
COP_RID_REVISION(rev), COP_RID_STEPPING(rev));
aprint_normal("%s: codec: High Definition Audio rev. %u.%u\n",
XNAME(this->az), COP_RID_MAJ(rev), COP_RID_MIN(rev));
/* identify function nodes */
err = this->comresp(this, CORB_NID_ROOT, CORB_GET_PARAMETER,
COP_SUBORDINATE_NODE_COUNT, &result);
if (err)
return err;
this->nfunctions = COP_NSUBNODES(result);
if (COP_NSUBNODES(result) <= 0) {
aprint_error("%s: No function groups\n", XNAME(this->az));
return -1;
}
/* iterate function nodes and find an audio function */
n = COP_START_NID(result);
DPRINTF(("%s: nidstart=%d #functions=%d\n",
__func__, n, this->nfunctions));
this->audiofunc = -1;
for (i = 0; i < this->nfunctions; i++) {
err = this->comresp(this, n + i, CORB_GET_PARAMETER,
COP_FUNCTION_GROUP_TYPE, &result);
if (err)
continue;
DPRINTF(("%s: FTYPE result = 0x%8.8x\n", __func__, result));
if (COP_FTYPE(result) == COP_FTYPE_AUDIO) {
this->audiofunc = n + i;
break; /* XXX multiple audio functions? */
}
}
if (this->audiofunc < 0) {
aprint_error("%s: codec[%d]: No audio functions\n",
XNAME(this->az), addr);
return -1;
}
/* check widgets in the audio function */
err = this->comresp(this, this->audiofunc,
CORB_GET_PARAMETER, COP_SUBORDINATE_NODE_COUNT, &result);
if (err)
return err;
DPRINTF(("%s: There are %d widgets in the audio function.\n",
__func__, COP_NSUBNODES(result)));
this->wstart = COP_START_NID(result);
if (this->wstart < 2) {
aprint_error("%s: invalid node structure\n", XNAME(this->az));
return -1;
}
this->wend = this->wstart + COP_NSUBNODES(result);
this->w = malloc(sizeof(widget_t) * this->wend, M_DEVBUF,
M_ZERO | M_NOWAIT);
if (this->w == NULL) {
aprint_error("%s: out of memory\n", XNAME(this->az));
return ENOMEM;
}
FOR_EACH_WIDGET(this, i) {
err = azalia_widget_init(&this->w[i], this, i);
if (err)
return err;
}
/*
* grouping DACs
* [0] the lowest assoc DACs
* [1] the lowest assoc digital outputs
* [2] the 2nd assoc DACs
* :
*/
group = 0;
for (assoc = 0; assoc < CORB_CD_ASSOCIATION_MAX; assoc++) {
for (digital = 0; digital <= COP_AWCAP_DIGITAL; digital += COP_AWCAP_DIGITAL) {
n = 0;
for (seq = 0 ; seq < CORB_CD_SEQUENCE_MAX; seq++) {
i = azalia_codec_find_pin(this, assoc, seq, digital);
if (i < 0)
continue;
dac = azalia_codec_find_dac(this, i, 0);
if (dac < 0)
continue;
/* duplication check */
for (j = 0; j < n; j++) {
if (this->dacgroups[group].conv[j] == dac)
break;
}
if (j < n)
continue;
this->dacgroups[group].conv[n++] = dac;
DPRINTF(("%s: assoc=%d seq=%d ==> g=%d n=%d\n",
__func__, assoc, seq, group, n-1));
}
if (n > 0) {
this->dacgroups[group].nconv = n;
/* check if the same combination is already
* registered */
for (i = 0; i < group; i++) {
if (n != this->dacgroups[i].nconv)
continue;
for (j = 0; j < n; j++) {
if (this->dacgroups[group].conv[j] != this->dacgroups[i].conv[j])
break;
}
if (j >= n) /* matched */
break;
}
if (i >= group) /* not found */
group++;
}
}
}
this->ndacgroups = group;
/* find DACs which do not connect with any pins by default */
DPRINTF(("%s: find non-connected DACs\n", __func__));
FOR_EACH_WIDGET(this, i) {
boolean_t found;
if (this->w[i].type != COP_AWTYPE_AUDIO_OUTPUT)
continue;
found = FALSE;
for (group = 0; group < this->ndacgroups; group++) {
for (j = 0; j < this->dacgroups[group].nconv; j++) {
if (i == this->dacgroups[group].conv[j]) {
found = TRUE;
group = this->ndacgroups;
break;
}
}
}
if (found)
continue;
if (this->ndacgroups >= 32)
break;
this->dacgroups[this->ndacgroups].nconv = 1;
this->dacgroups[this->ndacgroups].conv[0] = i;
this->ndacgroups++;
}
#ifdef AZALIA_DEBUG
for (group = 0; group < this->ndacgroups; group++) {
DPRINTF(("%s: dacgroup[%d]:", __func__, group));
for (j = 0; j < this->dacgroups[group].nconv; j++) {
DPRINTF((" %2.2x", this->dacgroups[group].conv[j]));
}
DPRINTF(("\n"));
}
#endif
this->cur_dac = 0;
#if 0
/* search pins for the lowest association */
assoc = INT_MAX;
FOR_EACH_WIDGET(this, i) {
if (this->w[i].type != COP_AWTYPE_PIN_COMPLEX)
continue;
if ((this->w[i].d.pin.cap & COP_PINCAP_OUTPUT) == 0)
continue;
if (this->w[i].d.pin.association < assoc)
assoc = this->w[i].d.pin.association;
}
if (assoc == INT_MAX) {
aprint_error("%s: no pins\n", XNAME(this->az));
return -1;
}
/* collect pins in the lowest association */
/* XXX digital and non-digital pins are stored */
for (seq = 0, npin = 0;
npin < HDA_MAX_CHANNELS && seq <= CORB_CD_SEQUENCE_MAX; seq++) {
i = azalia_codec_find_pin(this, COP_PINCAP_OUTPUT, assoc, seq);
if (i < 0)
continue;
pindexes[npin] = i;
this->dacindexes[npin] = azalia_codec_find_dac(this, i, 0);
if (this->dacindexes[npin] < 0) {
aprint_error("%s: a pin 0x%x does not connect to any DAC.",
XNAME(this->az), this->w[i].nid);
return -1;
}
npin++;
}
this->ndacindexes = npin;
DPRINTF(("%s: DACs:", __func__));
for (i = 0; i < npin; i++) {
DPRINTF((" 0x%x", this->dacindexes[i]));
}
DPRINTF(("\n"));
#endif
/* enumerate ADCs */
this->nadcs = 0;
FOR_EACH_WIDGET(this, i) {
if (this->w[i].type != COP_AWTYPE_AUDIO_INPUT)
continue;
this->adcs[this->nadcs++] = i;
if (this->nadcs >= 32)
break;
}
this->cur_adc = 0;
err = azalia_codec_construct_format(this);
if (err)
return err;
azalia_mixer_init(this);
return 0;
}
static int
azalia_codec_construct_format(codec_t *this)
{
char flagbuf[FLAGBUFLEN];
const convgroup_t *group;
uint32_t bits_rates;
int pvariation, rvariation;
int nbits, dac, chan, i, err;
group = &this->dacgroups[this->cur_dac];
snprintf(flagbuf, FLAGBUFLEN, "%s: playback", XNAME(this->az));
azalia_widget_print_audio(&this->w[group->conv[0]], flagbuf);
snprintf(flagbuf, FLAGBUFLEN, "%s: record", XNAME(this->az));
azalia_widget_print_audio(&this->w[this->adcs[this->cur_adc]], flagbuf);
bits_rates = this->w[group->conv[0]].d.audio.bits_rates;
nbits = 0;
if (bits_rates & COP_PCM_B8)
nbits++;
if (bits_rates & COP_PCM_B16)
nbits++;
if (bits_rates & COP_PCM_B20)
nbits++;
if (bits_rates & COP_PCM_B24)
nbits++;
if (bits_rates & COP_PCM_B32)
nbits++;
if (nbits == 0) {
aprint_error("%s: invalid PCM format: 0x%8.8x\n",
XNAME(this->az), bits_rates);
return -1;
}
pvariation = group->nconv * nbits;
bits_rates = this->w[this->adcs[this->cur_adc]].d.audio.bits_rates;
nbits = 0;
if (bits_rates & COP_PCM_B8)
nbits++;
if (bits_rates & COP_PCM_B16)
nbits++;
if (bits_rates & COP_PCM_B20)
nbits++;
if (bits_rates & COP_PCM_B24)
nbits++;
if (bits_rates & COP_PCM_B32)
nbits++;
if (nbits == 0) {
aprint_error("%s: invalid PCM format: 0x%8.8x\n",
XNAME(this->az), bits_rates);
return -1;
}
rvariation = nbits;
if (this->formats != NULL)
free(this->formats, M_DEVBUF);
this->nformats = 0;
this->formats = malloc(sizeof(struct audio_format) *
(pvariation + rvariation), M_DEVBUF, M_ZERO | M_NOWAIT);
if (this->formats == NULL) {
aprint_error("%s: out of memory in %s\n",
XNAME(this->az), __func__);
return ENOMEM;
}
bits_rates = this->w[group->conv[0]].d.audio.bits_rates;
for (dac = 0; dac < group->nconv; dac++) {
for (chan = 0, i = 0; i <= dac; i++)
chan += this->w[group->conv[dac]].widgetcap
& COP_AWCAP_STEREO ? 2 : 1;
if (bits_rates & COP_PCM_B8)
azalia_codec_add_format(this, chan, 8, 16, bits_rates, AUMODE_PLAY);
if (bits_rates & COP_PCM_B16)
azalia_codec_add_format(this, chan, 16, 16, bits_rates, AUMODE_PLAY);
if (bits_rates & COP_PCM_B20)
azalia_codec_add_format(this, chan, 20, 32, bits_rates, AUMODE_PLAY);
if (bits_rates & COP_PCM_B24)
azalia_codec_add_format(this, chan, 24, 32, bits_rates, AUMODE_PLAY);
if (bits_rates & COP_PCM_B32)
azalia_codec_add_format(this, chan, 32, 32, bits_rates, AUMODE_PLAY);
}
chan = this->w[this->adcs[this->cur_adc]].widgetcap & COP_AWCAP_STEREO ? 2 : 1;
bits_rates = this->w[this->adcs[this->cur_adc]].d.audio.bits_rates;
if (bits_rates & COP_PCM_B8)
azalia_codec_add_format(this, chan, 8, 16, bits_rates, AUMODE_RECORD);
if (bits_rates & COP_PCM_B16)
azalia_codec_add_format(this, chan, 16, 16, bits_rates, AUMODE_RECORD);
if (bits_rates & COP_PCM_B20)
azalia_codec_add_format(this, chan, 20, 32, bits_rates, AUMODE_RECORD);
if (bits_rates & COP_PCM_B24)
azalia_codec_add_format(this, chan, 24, 32, bits_rates, AUMODE_RECORD);
if (bits_rates & COP_PCM_B32)
azalia_codec_add_format(this, chan, 32, 32, bits_rates, AUMODE_RECORD);
err = auconv_create_encodings(this->formats, this->nformats,
&this->encodings);
if (err)
return err;
return 0;
}
static void
azalia_codec_add_format(codec_t *this, int chan, int valid, int prec,
uint32_t rates, int32_t mode)
{
struct audio_format *f;
f = &this->formats[this->nformats++];
f->mode = mode;
f->encoding = AUDIO_ENCODING_SLINEAR_LE;
if (valid == 8 && prec == 8)
f->encoding = AUDIO_ENCODING_ULINEAR_LE;
f->validbits = valid;
f->precision = prec;
f->channels = chan;
switch (chan) {
case 1:
f->channel_mask = AUFMT_MONAURAL;
break;
case 2:
f->channel_mask = AUFMT_STEREO;
break;
case 4:
f->channel_mask = AUFMT_SURROUND4;
break;
case 6:
f->channel_mask = AUFMT_DOLBY_5_1;
break;
case 8:
f->channel_mask = AUFMT_DOLBY_5_1
| AUFMT_SIDE_LEFT | AUFMT_SIDE_RIGHT;
break;
default:
f->channel_mask = 0;
}
if (rates & COP_PCM_R80)
f->frequency[f->frequency_type++] = 8000;
if (rates & COP_PCM_R110)
f->frequency[f->frequency_type++] = 11025;
if (rates & COP_PCM_R160)
f->frequency[f->frequency_type++] = 16000;
if (rates & COP_PCM_R220)
f->frequency[f->frequency_type++] = 22050;
if (rates & COP_PCM_R320)
f->frequency[f->frequency_type++] = 32000;
if (rates & COP_PCM_R441)
f->frequency[f->frequency_type++] = 44100;
if (rates & COP_PCM_R480)
f->frequency[f->frequency_type++] = 48000;
if (rates & COP_PCM_R882)
f->frequency[f->frequency_type++] = 88200;
if (rates & COP_PCM_R960)
f->frequency[f->frequency_type++] = 96000;
if (rates & COP_PCM_R1764)
f->frequency[f->frequency_type++] = 176400;
if (rates & COP_PCM_R1920)
f->frequency[f->frequency_type++] = 192000;
if (rates & COP_PCM_R3840)
f->frequency[f->frequency_type++] = 384000;
}
static int
azalia_codec_find_pin(const codec_t *this, int assoc, int seq, uint32_t digital)
{
int i;
FOR_EACH_WIDGET(this, i) {
if (this->w[i].type != COP_AWTYPE_PIN_COMPLEX)
continue;
if ((this->w[i].d.pin.cap & COP_PINCAP_OUTPUT) == 0)
continue;
if ((this->w[i].widgetcap & COP_AWCAP_DIGITAL) != digital)
continue;
if (this->w[i].d.pin.association != assoc)
continue;
if (this->w[i].d.pin.sequence == seq) {
return i;
}
}
return -1;
}
static int
azalia_codec_find_dac(const codec_t *this, int index, int depth)
{
const widget_t *w;
int i, j, ret;
w = &this->w[index];
if (w->type == COP_AWTYPE_AUDIO_OUTPUT) {
DPRINTF(("%s: DAC: nid=0x%x index=%d\n",
__func__, w->nid, index));
return index;
}
if (++depth > 50) {
return -1;
}
if (w->selected >= 0) {
j = w->connections[w->selected];
ret = azalia_codec_find_dac(this, j, depth);
if (ret >= 0) {
DPRINTF(("%s: DAC path: nid=0x%x index=%d\n",
__func__, w->nid, index));
return ret;
}
}
for (i = 0; i < w->nconnections; i++) {
j = w->connections[i];
ret = azalia_codec_find_dac(this, j, depth);
if (ret >= 0) {
DPRINTF(("%s: DAC path: nid=0x%x index=%d\n",
__func__, w->nid, index));
return ret;
}
}
return -1;
}
static int
azalia_codec_comresp(const codec_t *codec, nid_t nid, uint32_t control,
uint32_t param, uint32_t* result)
{
int err;
err = azalia_set_command(codec->az, codec->address, nid, control, param);
if (err)
return err;
return azalia_get_response(codec->az, result);
}
static int
azalia_codec_connect_stream(codec_t *this, int dir, uint16_t fmt, int number)
{
const convgroup_t *group;
int i, err, startchan, nchan;
nid_t nid;
boolean_t flag222;
/* XXX */
DPRINTF(("%s: fmt=0x%4.4x number=%d\n", __func__, fmt, number));
err = 0;
if (dir == AUMODE_RECORD) {
printf("%s: not implemented for AUMODE_RECORD\n", __func__);
return -1;
}
group = &this->dacgroups[this->cur_dac];
flag222 = group->nconv >= 3 &&
(this->w[group->conv[0]].widgetcap & COP_AWCAP_STEREO) &&
(this->w[group->conv[1]].widgetcap & COP_AWCAP_STEREO) &&
(this->w[group->conv[2]].widgetcap & COP_AWCAP_STEREO);
nchan = (fmt & HDA_SD_FMT_CHAN) + 1;
startchan = 0;
for (i = 0; i < group->nconv; i++) {
nid = group->conv[i];
/* surround and c/lfe handling */
if (nchan >= 6 && flag222 && i == 1) {
nid = group->conv[2];
} else if (nchan >= 6 && flag222 && i == 2) {
nid = group->conv[1];
}
err = this->comresp(this, nid, CORB_SET_CONVERTER_FORMAT, fmt, NULL);
if (err)
goto exit;
err = this->comresp(this, nid, CORB_SET_CONVERTER_STREAM_CHANNEL,
(number << 4) | startchan, NULL);
if (err)
goto exit;
startchan += this->w[nid].widgetcap & COP_AWCAP_STEREO ? 2 : 1;
}
exit:
DPRINTF(("%s: leave with %d\n", __func__, err));
return err;
}
/* ================================================================
* HDA mixer functions
* ================================================================ */
static int
azalia_mixer_init(codec_t *this)
{
/*
* pin "<color>%2.2x"
* audio output "dac%2.2x"
* audio input "adc%2.2x"
* mixer "mixer%2.2x"
* selector "sel%2.2x"
*/
mixer_item_t *m;
int nadcs;
int err, i, j;
nadcs = 0;
this->maxmixers = 10;
this->nmixers = 0;
this->mixers = malloc(sizeof(mixer_item_t) * this->maxmixers,
M_DEVBUF, M_ZERO | M_NOWAIT);
if (this->mixers == NULL) {
aprint_error("%s: out of memory in %s\n", XNAME(this->az), __func__);
return ENOMEM;
}
/* register classes */
#define AZ_CLASS_INPUT 0
#define AZ_CLASS_OUTPUT 1
#define AZ_CLASS_RECORD 2
m = &this->mixers[AZ_CLASS_INPUT];
m->devinfo.index = AZ_CLASS_INPUT;
strlcpy(m->devinfo.label.name, AudioCinputs, sizeof(m->devinfo.label.name));
m->devinfo.type = AUDIO_MIXER_CLASS;
m->devinfo.mixer_class = AZ_CLASS_INPUT;
m->devinfo.next = AUDIO_MIXER_LAST;
m->devinfo.prev = AUDIO_MIXER_LAST;
m->nid = 0;
m = &this->mixers[AZ_CLASS_OUTPUT];
m->devinfo.index = AZ_CLASS_OUTPUT;
strlcpy(m->devinfo.label.name, AudioCoutputs, sizeof(m->devinfo.label.name));
m->devinfo.type = AUDIO_MIXER_CLASS;
m->devinfo.mixer_class = AZ_CLASS_OUTPUT;
m->devinfo.next = AUDIO_MIXER_LAST;
m->devinfo.prev = AUDIO_MIXER_LAST;
m->nid = 0;
m = &this->mixers[AZ_CLASS_RECORD];
m->devinfo.index = AZ_CLASS_RECORD;
strlcpy(m->devinfo.label.name, AudioCrecord, sizeof(m->devinfo.label.name));
m->devinfo.type = AUDIO_MIXER_CLASS;
m->devinfo.mixer_class = AZ_CLASS_RECORD;
m->devinfo.next = AUDIO_MIXER_LAST;
m->devinfo.prev = AUDIO_MIXER_LAST;
m->nid = 0;
this->nmixers = AZ_CLASS_RECORD + 1;
#define MIXER_REG_PROLOG \
mixer_devinfo_t *d; \
err = azalia_mixer_ensure_capacity(this, this->nmixers + 1); \
if (err) \
return err; \
m = &this->mixers[this->nmixers]; \
d = &m->devinfo; \
d->index = this->nmixers; \
m->nid = i
FOR_EACH_WIDGET(this, i) {
const widget_t *w;
w = &this->w[i];
if (w->type == COP_AWTYPE_AUDIO_INPUT)
nadcs++;
/* selector */
if (w->type != COP_AWTYPE_AUDIO_MIXER && w->nconnections >= 2) {
MIXER_REG_PROLOG;
snprintf(d->label.name, sizeof(d->label.name),
"%s.source", w->name);
d->type = AUDIO_MIXER_ENUM;
if (w->type == COP_AWTYPE_AUDIO_MIXER)
d->mixer_class = AZ_CLASS_RECORD;
else if (w->type == COP_AWTYPE_AUDIO_SELECTOR)
d->mixer_class = AZ_CLASS_INPUT;
else
d->mixer_class = AZ_CLASS_OUTPUT;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = MI_TARGET_CONNLIST;
for (j = 0; j < w->nconnections && j < 32; j++) {
d->un.e.member[j].ord = j;
strlcpy(d->un.e.member[j].label.name,
this->w[w->connections[j]].name, MAX_AUDIO_DEV_LEN);
}
d->un.e.num_mem = j;
this->nmixers++;
}
/* output mute */
if (w->widgetcap & COP_AWCAP_OUTAMP && w->outamp_cap & COP_AMPCAP_MUTE) {
MIXER_REG_PROLOG;
snprintf(d->label.name, sizeof(d->label.name),
"%s.mute", w->name);
d->type = AUDIO_MIXER_ENUM;
if (w->type == COP_AWTYPE_AUDIO_MIXER)
d->mixer_class = AZ_CLASS_OUTPUT;
else if (w->type == COP_AWTYPE_AUDIO_SELECTOR)
d->mixer_class = AZ_CLASS_OUTPUT;
else if (w->type == COP_AWTYPE_PIN_COMPLEX)
d->mixer_class = AZ_CLASS_OUTPUT;
else
d->mixer_class = AZ_CLASS_INPUT;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = MI_TARGET_OUTAMP;
d->un.e.num_mem = 2;
d->un.e.member[0].ord = 0;
strlcpy(d->un.e.member[0].label.name, AudioNoff, MAX_AUDIO_DEV_LEN);
d->un.e.member[1].ord = 1;
strlcpy(d->un.e.member[1].label.name, AudioNon, MAX_AUDIO_DEV_LEN);
this->nmixers++;
}
/* output gain */
if (w->widgetcap & COP_AWCAP_OUTAMP && COP_AMPCAP_NUMSTEPS(w->outamp_cap)) {
MIXER_REG_PROLOG;
snprintf(d->label.name, sizeof(d->label.name),
"%s", w->name);
d->type = AUDIO_MIXER_VALUE;
if (w->type == COP_AWTYPE_AUDIO_MIXER)
d->mixer_class = AZ_CLASS_OUTPUT;
else if (w->type == COP_AWTYPE_AUDIO_SELECTOR)
d->mixer_class = AZ_CLASS_OUTPUT;
else if (w->type == COP_AWTYPE_PIN_COMPLEX)
d->mixer_class = AZ_CLASS_OUTPUT;
else
d->mixer_class = AZ_CLASS_INPUT;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = MI_TARGET_OUTAMP;
d->un.v.num_channels = w->widgetcap & COP_AWCAP_STEREO ? 2 : 1;
#ifdef MAX_VOLUME_255
d->un.v.units.name[0] = 0;
d->un.v.delta = AUDIO_MAX_GAIN /
COP_AMPCAP_NUMSTEPS(w->outamp_cap);
#else
snprintf(d->un.v.units.name, sizeof(d->un.v.units.name),
"0.25x%ddB", COP_AMPCAP_STEPSIZE(w->outamp_cap)+1);
d->un.v.delta = 1;
#endif
this->nmixers++;
}
/* input mute */
if (w->widgetcap & COP_AWCAP_INAMP && w->inamp_cap & COP_AMPCAP_MUTE) {
for (j = 0; j < w->nconnections; j++) {
MIXER_REG_PROLOG;
snprintf(d->label.name, sizeof(d->label.name),
"%s.%s.mute", w->name,
this->w[w->connections[j]].name);
d->type = AUDIO_MIXER_ENUM;
if (w->type == COP_AWTYPE_PIN_COMPLEX)
d->mixer_class = AZ_CLASS_OUTPUT;
else if (w->type == COP_AWTYPE_AUDIO_INPUT)
d->mixer_class = AZ_CLASS_RECORD;
else
d->mixer_class = AZ_CLASS_INPUT;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = j;
d->un.e.num_mem = 2;
d->un.e.member[0].ord = 0;
strlcpy(d->un.e.member[0].label.name,
AudioNoff, MAX_AUDIO_DEV_LEN);
d->un.e.member[1].ord = 1;
strlcpy(d->un.e.member[1].label.name,
AudioNon, MAX_AUDIO_DEV_LEN);
this->nmixers++;
}
}
/* input gain */
if (w->widgetcap & COP_AWCAP_INAMP && COP_AMPCAP_NUMSTEPS(w->inamp_cap)) {
for (j = 0; j < w->nconnections; j++) {
MIXER_REG_PROLOG;
snprintf(d->label.name, sizeof(d->label.name),
"%s.%s", w->name,
this->w[w->connections[j]].name);
d->type = AUDIO_MIXER_VALUE;
if (w->type == COP_AWTYPE_PIN_COMPLEX)
d->mixer_class = AZ_CLASS_OUTPUT;
else if (w->type == COP_AWTYPE_AUDIO_INPUT)
d->mixer_class = AZ_CLASS_RECORD;
else
d->mixer_class = AZ_CLASS_INPUT;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = j;
d->un.v.num_channels = w->widgetcap & COP_AWCAP_STEREO ? 2 : 1;
#ifdef MAX_VOLUME_255
d->un.v.units.name[0] = 0;
d->un.v.delta = AUDIO_MAX_GAIN /
COP_AMPCAP_NUMSTEPS(w->inamp_cap);
#else
snprintf(d->un.v.units.name, sizeof(d->un.v.units.name),
"0.25x%ddB", COP_AMPCAP_STEPSIZE(w->inamp_cap)+1);
d->un.v.delta = 1;
#endif
this->nmixers++;
}
}
/* pin direction */
if (w->type == COP_AWTYPE_PIN_COMPLEX &&
w->d.pin.cap & COP_PINCAP_OUTPUT &&
w->d.pin.cap & COP_PINCAP_INPUT) {
MIXER_REG_PROLOG;
snprintf(d->label.name, sizeof(d->label.name),
"%s.dir", w->name);
d->type = AUDIO_MIXER_ENUM;
d->mixer_class = AZ_CLASS_OUTPUT;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = MI_TARGET_PINDIR;
d->un.e.num_mem = 2;
d->un.e.member[0].ord = 0;
strlcpy(d->un.e.member[0].label.name, AudioNinput,
MAX_AUDIO_DEV_LEN);
d->un.e.member[1].ord = 1;
strlcpy(d->un.e.member[1].label.name, AudioNoutput,
MAX_AUDIO_DEV_LEN);
this->nmixers++;
}
/* pin headphone-boost */
if (w->type == COP_AWTYPE_PIN_COMPLEX &&
w->d.pin.cap & COP_PINCAP_HEADPHONE) {
MIXER_REG_PROLOG;
snprintf(d->label.name, sizeof(d->label.name),
"%s.boost", w->name);
d->type = AUDIO_MIXER_ENUM;
d->mixer_class = AZ_CLASS_OUTPUT;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = MI_TARGET_PINBOOST;
d->un.e.num_mem = 2;
d->un.e.member[0].ord = 0;
strlcpy(d->un.e.member[0].label.name, AudioNoff,
MAX_AUDIO_DEV_LEN);
d->un.e.member[1].ord = 1;
strlcpy(d->un.e.member[1].label.name, AudioNon,
MAX_AUDIO_DEV_LEN);
this->nmixers++;
}
}
/* if the codec has multiple DAC groups, create "inputs.usingdac" */
if (this->ndacgroups > 1) {
MIXER_REG_PROLOG;
strlcpy(d->label.name, "usingdac", sizeof(d->label.name));
d->type = AUDIO_MIXER_ENUM;
d->mixer_class = AZ_CLASS_INPUT;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = MI_TARGET_DAC;
for (i = 0; i < this->ndacgroups && i < 32; i++) {
d->un.e.member[i].ord = i;
for (j = 0; j < this->dacgroups[i].nconv; j++) {
if (j * 2 >= MAX_AUDIO_DEV_LEN)
break;
snprintf(d->un.e.member[i].label.name + j*2,
MAX_AUDIO_DEV_LEN - j*2, "%2.2x",
this->dacgroups[i].conv[j]);
}
}
d->un.e.num_mem = i;
this->nmixers++;
}
/* if the codec has multiple ADCs, create "record.usingadc" */
if (this->nadcs > 1) {
MIXER_REG_PROLOG;
strlcpy(d->label.name, "usingadc", sizeof(d->label.name));
d->type = AUDIO_MIXER_ENUM;
d->mixer_class = AZ_CLASS_RECORD;
d->next = AUDIO_MIXER_LAST;
d->prev = AUDIO_MIXER_LAST;
m->target = MI_TARGET_ADC;
for (i = 0; i < this->nadcs && i < 32; i++) {
d->un.e.member[i].ord = i;
strlcpy(d->un.e.member[i].label.name,
this->w[this->adcs[i]].name, MAX_AUDIO_DEV_LEN);
}
d->un.e.num_mem = i;
this->nmixers++;
}
/* unmute all */
for (i = 0; i < this->nmixers; i++) {
mixer_ctrl_t mc;
if (!IS_MI_TARGET_INAMP(this->mixers[i].target) &&
this->mixers[i].target != MI_TARGET_OUTAMP)
continue;
if (this->mixers[i].devinfo.type != AUDIO_MIXER_ENUM)
continue;
mc.dev = i;
mc.type = AUDIO_MIXER_ENUM;
mc.un.ord = 0;
azalia_mixer_set(this, &mc);
}
/*
* for bidirectional pins,
* green=front, orange=surround, gray=c/lfe, black=size --> output
* blue=line-in, pink=mic-in --> input
*/
for (i = 0; i < this->nmixers; i++) {
mixer_ctrl_t mc;
if (this->mixers[i].target != MI_TARGET_PINDIR)
continue;
mc.dev = i;
mc.type = AUDIO_MIXER_ENUM;
switch (this->w[this->mixers[i].nid].d.pin.color) {
case CORB_CD_GREEN:
case CORB_CD_ORANGE:
case CORB_CD_GRAY:
case CORB_CD_BLACK:
mc.un.ord = 1;
break;
default:
mc.un.ord = 0;
}
azalia_mixer_set(this, &mc);
}
return 0;
}
static int
azalia_mixer_get(const codec_t *this, mixer_ctrl_t *mc)
{
const mixer_item_t *m;
uint32_t result;
int err;
if (mc->dev >= this->nmixers)
return ENXIO;
m = &this->mixers[mc->dev];
mc->type = m->devinfo.type;
if (mc->type == AUDIO_MIXER_CLASS)
return 0; /* nothing to do */
/* inamp mute */
if (IS_MI_TARGET_INAMP(m->target) && m->devinfo.type == AUDIO_MIXER_ENUM) {
err = this->comresp(this, m->nid, CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_INPUT | CORB_GAGM_LEFT | MI_TARGET_INAMP(m->target), &result);
if (err)
return err;
mc->un.ord = result & CORB_GAGM_MUTE ? 1 : 0;
}
/* inamp gain */
else if (IS_MI_TARGET_INAMP(m->target) && m->devinfo.type == AUDIO_MIXER_VALUE) {
err = this->comresp(this, m->nid, CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_INPUT | CORB_GAGM_LEFT | MI_TARGET_INAMP(m->target), &result);
if (err)
return err;
mc->un.value.level[0] = azalia_mixer_from_device_value(this, m,
CORB_GAGM_GAIN(result));
if (this->w[m->nid].widgetcap & COP_AWCAP_STEREO) {
err = this->comresp(this, m->nid,
CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT |
CORB_GAGM_RIGHT | MI_TARGET_INAMP(m->target), &result);
if (err)
return err;
mc->un.value.level[1] = azalia_mixer_from_device_value
(this, m, CORB_GAGM_GAIN(result));
mc->un.value.num_channels = 2;
} else {
mc->un.value.num_channels = 1;
}
}
/* outamp mute */
else if (m->target == MI_TARGET_OUTAMP && m->devinfo.type == AUDIO_MIXER_ENUM) {
err = this->comresp(this, m->nid, CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_OUTPUT | CORB_GAGM_LEFT | 0, &result);
if (err)
return err;
mc->un.ord = result & CORB_GAGM_MUTE ? 1 : 0;
}
/* outamp gain */
else if (m->target == MI_TARGET_OUTAMP && m->devinfo.type == AUDIO_MIXER_VALUE) {
err = this->comresp(this, m->nid, CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_OUTPUT | CORB_GAGM_LEFT | 0, &result);
if (err)
return err;
mc->un.value.level[0] = azalia_mixer_from_device_value(this, m,
CORB_GAGM_GAIN(result));
if (this->w[m->nid].widgetcap & COP_AWCAP_STEREO) {
err = this->comresp(this, m->nid,
CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_OUTPUT | CORB_GAGM_RIGHT | 0, &result);
if (err)
return err;
mc->un.value.level[1] = azalia_mixer_from_device_value
(this, m, CORB_GAGM_GAIN(result));
mc->un.value.num_channels = 2;
} else {
mc->un.value.num_channels = 1;
}
}
/* selection */
else if (m->target == MI_TARGET_CONNLIST) {
err = this->comresp(this, m->nid,
CORB_GET_CONNECTION_SELECT_CONTROL, 0, &result);
if (err)
return err;
mc->un.ord = CORB_CSC_INDEX(result);
}
/* pin I/O */
else if (m->target == MI_TARGET_PINDIR) {
err = this->comresp(this, m->nid,
CORB_GET_PIN_WIDGET_CONTROL, 0, &result);
if (err)
return err;
mc->un.ord = result & CORB_PWC_OUTPUT ? 1 : 0;
}
/* pin headphone-boost */
else if (m->target == MI_TARGET_PINBOOST) {
err = this->comresp(this, m->nid,
CORB_GET_PIN_WIDGET_CONTROL, 0, &result);
if (err)
return err;
mc->un.ord = result & CORB_PWC_HEADPHONE ? 1 : 0;
}
/* DAC group selection */
else if (m->target == MI_TARGET_DAC) {
mc->un.ord = this->cur_dac;
}
/* ADC selection */
else if (m->target == MI_TARGET_ADC) {
mc->un.ord = this->cur_adc;
}
else {
aprint_error("%s: internal error in %s: %x\n", XNAME(this->az),
__func__, m->target);
return -1;
}
return 0;
}
static int
azalia_mixer_set(codec_t *this, const mixer_ctrl_t *mc)
{
const mixer_item_t *m;
uint32_t result, value;
int err;
if (mc->dev >= this->nmixers)
return ENXIO;
m = &this->mixers[mc->dev];
if (mc->type != m->devinfo.type)
return EINVAL;
if (mc->type == AUDIO_MIXER_CLASS)
return 0; /* nothing to do */
/* inamp mute */
if (IS_MI_TARGET_INAMP(m->target) && m->devinfo.type == AUDIO_MIXER_ENUM) {
/* We have to set stereo mute separately to keep each gain value. */
err = this->comresp(this, m->nid, CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_INPUT | CORB_GAGM_LEFT |
MI_TARGET_INAMP(m->target), &result);
if (err)
return err;
value = CORB_AGM_INPUT | CORB_AGM_LEFT |
(m->target << CORB_AGM_INDEX_SHIFT) | CORB_GAGM_GAIN(result);
if (mc->un.ord)
value |= CORB_AGM_MUTE;
err = this->comresp(this, m->nid, CORB_SET_AMPLIFIER_GAIN_MUTE,
value, &result);
if (err)
return err;
if (this->w[m->nid].widgetcap & COP_AWCAP_STEREO) {
err = this->comresp(this, m->nid,
CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT |
CORB_GAGM_RIGHT | MI_TARGET_INAMP(m->target), &result);
if (err)
return err;
value = CORB_AGM_INPUT | CORB_AGM_RIGHT |
(m->target << CORB_AGM_INDEX_SHIFT) |
CORB_GAGM_GAIN(result);
if (mc->un.ord)
value |= CORB_AGM_MUTE;
err = this->comresp(this, m->nid,
CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result);
if (err)
return err;
}
}
/* inamp gain */
else if (IS_MI_TARGET_INAMP(m->target) && m->devinfo.type == AUDIO_MIXER_VALUE) {
if (mc->un.value.num_channels < 1)
return EINVAL;
if (!azalia_mixer_validate_value(this, m, mc->un.value.level[0]))
return EINVAL;
err = this->comresp(this, m->nid, CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_INPUT | CORB_GAGM_LEFT |
MI_TARGET_INAMP(m->target), &result);
if (err)
return err;
value = azalia_mixer_to_device_value(this, m, mc->un.value.level[0]);
value = CORB_AGM_INPUT | CORB_AGM_LEFT |
(m->target << CORB_AGM_INDEX_SHIFT) |
(result & CORB_GAGM_MUTE ? CORB_AGM_MUTE : 0) |
(value & CORB_AGM_GAIN_MASK);
err = this->comresp(this, m->nid, CORB_SET_AMPLIFIER_GAIN_MUTE,
value, &result);
if (err)
return err;
if (mc->un.value.num_channels >= 2 &&
this->w[m->nid].widgetcap & COP_AWCAP_STEREO) {
if (!azalia_mixer_validate_value(this, m,
mc->un.value.level[1]))
return EINVAL;
err = this->comresp(this, m->nid,
CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_INPUT |
CORB_GAGM_RIGHT | MI_TARGET_INAMP(m->target), &result);
if (err)
return err;
value = azalia_mixer_to_device_value(this, m,
mc->un.value.level[1]);
value = CORB_AGM_INPUT | CORB_AGM_RIGHT |
(m->target << CORB_AGM_INDEX_SHIFT) |
(result & CORB_GAGM_MUTE ? CORB_AGM_MUTE : 0) |
(value & CORB_AGM_GAIN_MASK);
err = this->comresp(this, m->nid,
CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result);
if (err)
return err;
}
}
/* outamp mute */
else if (m->target == MI_TARGET_OUTAMP && m->devinfo.type == AUDIO_MIXER_ENUM) {
err = this->comresp(this, m->nid, CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_OUTPUT | CORB_GAGM_LEFT, &result);
if (err)
return err;
value = CORB_AGM_OUTPUT | CORB_AGM_LEFT | CORB_GAGM_GAIN(result);
if (mc->un.ord)
value |= CORB_AGM_MUTE;
err = this->comresp(this, m->nid, CORB_SET_AMPLIFIER_GAIN_MUTE,
value, &result);
if (err)
return err;
if (this->w[m->nid].widgetcap & COP_AWCAP_STEREO) {
err = this->comresp(this, m->nid,
CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_OUTPUT | CORB_GAGM_RIGHT, &result);
if (err)
return err;
value = CORB_AGM_OUTPUT | CORB_AGM_RIGHT |
CORB_GAGM_GAIN(result);
if (mc->un.ord)
value |= CORB_AGM_MUTE;
err = this->comresp(this, m->nid,
CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result);
if (err)
return err;
}
}
/* outamp gain */
else if (m->target == MI_TARGET_OUTAMP && m->devinfo.type == AUDIO_MIXER_VALUE) {
if (mc->un.value.num_channels < 1)
return EINVAL;
if (!azalia_mixer_validate_value(this, m, mc->un.value.level[0]))
return EINVAL;
err = this->comresp(this, m->nid, CORB_GET_AMPLIFIER_GAIN_MUTE,
CORB_GAGM_OUTPUT | CORB_GAGM_LEFT, &result);
if (err)
return err;
value = azalia_mixer_to_device_value(this, m,
mc->un.value.level[0]);
value = CORB_AGM_OUTPUT | CORB_AGM_LEFT |
(result & CORB_GAGM_MUTE ? CORB_AGM_MUTE : 0) |
(value & CORB_AGM_GAIN_MASK);
err = this->comresp(this, m->nid, CORB_SET_AMPLIFIER_GAIN_MUTE,
value, &result);
if (err)
return err;
if (mc->un.value.num_channels >= 2 &&
this->w[m->nid].widgetcap & COP_AWCAP_STEREO) {
if (!azalia_mixer_validate_value(this, m,
mc->un.value.level[1]))
return EINVAL;
err = this->comresp(this, m->nid,
CORB_GET_AMPLIFIER_GAIN_MUTE, CORB_GAGM_OUTPUT |
CORB_GAGM_RIGHT, &result);
if (err)
return err;
value = azalia_mixer_to_device_value(this, m,
mc->un.value.level[1]);
value = CORB_AGM_OUTPUT | CORB_AGM_RIGHT |
(result & CORB_GAGM_MUTE ? CORB_AGM_MUTE : 0) |
(value & CORB_AGM_GAIN_MASK);
err = this->comresp(this, m->nid,
CORB_SET_AMPLIFIER_GAIN_MUTE, value, &result);
if (err)
return err;
}
}
/* selection */
else if (m->target == MI_TARGET_CONNLIST) {
if (mc->un.ord >= this->w[m->nid].nconnections)
return EINVAL;
err = this->comresp(this, m->nid,
CORB_SET_CONNECTION_SELECT_CONTROL, mc->un.ord, &result);
if (err)
return err;
}
/* pin I/O */
else if (m->target == MI_TARGET_PINDIR) {
if (mc->un.ord >= 2)
return EINVAL;
err = this->comresp(this, m->nid,
CORB_GET_PIN_WIDGET_CONTROL, 0, &result);
if (err)
return err;
if (mc->un.ord == 0) {
result &= ~CORB_PWC_OUTPUT;
result |= CORB_PWC_INPUT;
} else {
result &= ~CORB_PWC_INPUT;
result |= CORB_PWC_OUTPUT;
}
err = this->comresp(this, m->nid,
CORB_SET_PIN_WIDGET_CONTROL, result, &result);
if (err)
return err;
}
/* pin headphone-boost */
else if (m->target == MI_TARGET_PINBOOST) {
if (mc->un.ord >= 2)
return EINVAL;
err = this->comresp(this, m->nid,
CORB_GET_PIN_WIDGET_CONTROL, 0, &result);
if (err)
return err;
if (mc->un.ord == 0) {
result &= ~CORB_PWC_HEADPHONE;
} else {
result |= CORB_PWC_HEADPHONE;
}
err = this->comresp(this, m->nid,
CORB_SET_PIN_WIDGET_CONTROL, result, &result);
if (err)
return err;
}
/* DAC group selection */
else if (m->target == MI_TARGET_DAC) {
if (this->az->running)
return EBUSY;
if (mc->un.ord >= this->ndacgroups)
return EINVAL;
this->cur_dac = mc->un.ord;
return azalia_codec_construct_format(this);
}
/* ADC selection */
else if (m->target == MI_TARGET_ADC) {
if (this->az->running)
return EBUSY;
if (mc->un.ord >= this->nadcs)
return EINVAL;
this->cur_adc = mc->un.ord;
/* use this->adcs[this->cur_adc] */
return azalia_codec_construct_format(this);
}
else {
aprint_error("%s: internal error in %s: %x\n", XNAME(this->az),
__func__, m->target);
return -1;
}
return 0;
}
static int
azalia_mixer_ensure_capacity(codec_t *this, size_t newsize)
{
size_t newmax;
void *newbuf;
if (this->maxmixers >= newsize)
return 0;
newmax = this->maxmixers + 10;
if (newmax < newsize)
newmax = newsize;
newbuf = realloc(this->mixers, sizeof(mixer_item_t) * newmax, M_DEVBUF,
M_ZERO | M_NOWAIT);
if (newbuf == NULL) {
aprint_error("%s: out of memory in %s\n", XNAME(this->az), __func__);
return ENOMEM;
}
this->mixers = newbuf;
this->maxmixers = newmax;
return 0;
}
static u_char
azalia_mixer_from_device_value(const codec_t *this, const mixer_item_t *m, uint32_t dv)
{
#ifdef MAX_VOLUME_255
uint32_t dmax;
dmax = IS_MI_TARGET_INAMP(m->target)
? COP_AMPCAP_NUMSTEPS(this->w[m->nid].inamp_cap)
: COP_AMPCAP_NUMSTEPS(this->w[m->nid].outamp_cap);
return dv * AUDIO_MAX_GAIN / dmax;
#else
return dv;
#endif
}
static uint32_t
azalia_mixer_to_device_value(const codec_t *this, const mixer_item_t *m, u_char uv)
{
#ifdef MAX_VOLUME_255
uint32_t dmax;
dmax = IS_MI_TARGET_INAMP(m->target)
? COP_AMPCAP_NUMSTEPS(this->w[m->nid].inamp_cap)
: COP_AMPCAP_NUMSTEPS(this->w[m->nid].outamp_cap);
return uv * dmax / AUDIO_MAX_GAIN;
#else
return uv;
#endif
}
static boolean_t
azalia_mixer_validate_value(const codec_t *this, const mixer_item_t *m, u_char uv)
{
#ifdef MAX_VOLUME_255
return TRUE;
#else
uint32_t dmax;
dmax = IS_MI_TARGET_INAMP(m->target)
? COP_AMPCAP_NUMSTEPS(this->w[m->nid].inamp_cap)
: COP_AMPCAP_NUMSTEPS(this->w[m->nid].outamp_cap);
return uv <= dmax;
#endif
}
/* ================================================================
* HDA widget functions
* ================================================================ */
static int
azalia_widget_init(widget_t *this, const codec_t *codec, nid_t nid)
{
char flagbuf[FLAGBUFLEN];
uint32_t result;
int err;
err = codec->comresp(codec, nid, CORB_GET_PARAMETER,
COP_AUDIO_WIDGET_CAP, &result);
if (err)
return err;
this->nid = nid;
this->widgetcap = result;
this->type = COP_AWCAP_TYPE(result);
bitmask_snprintf(this->widgetcap, "\20\014LRSWAP\013POWER\012DIGITAL"
"\011CONNLIST\010UNSOL\07PROC\06STRIPE\05FORMATOV\04AMPOV\03OUTAMP"
"\02INAMP\01STEREO", flagbuf, FLAGBUFLEN);
DPRINTF(("%s: ", XNAME(codec->az)));
switch (this->type) {
case COP_AWTYPE_AUDIO_OUTPUT:
snprintf(this->name, sizeof(this->name), "dac%2.2x", nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
azalia_widget_init_audio(this, codec);
break;
case COP_AWTYPE_AUDIO_INPUT:
snprintf(this->name, sizeof(this->name), "adc%2.2x", nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
azalia_widget_init_audio(this, codec);
break;
case COP_AWTYPE_AUDIO_MIXER:
snprintf(this->name, sizeof(this->name), "mix%2.2x", nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
break;
case COP_AWTYPE_AUDIO_SELECTOR:
snprintf(this->name, sizeof(this->name), "sel%2.2x", nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
break;
case COP_AWTYPE_PIN_COMPLEX:
azalia_widget_init_pin(this, codec);
snprintf(this->name, sizeof(this->name), "%s%2.2x",
pin_colors[this->d.pin.color], nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
azalia_widget_print_pin(this);
break;
case COP_AWTYPE_POWER:
snprintf(this->name, sizeof(this->name), "pow%2.2x", nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
break;
case COP_AWTYPE_VOLUME_KNOB:
snprintf(this->name, sizeof(this->name), "knob%2.2x", nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
break;
case COP_AWTYPE_BEEP_GENERATOR:
snprintf(this->name, sizeof(this->name), "beep%2.2x", nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
break;
default:
snprintf(this->name, sizeof(this->name), "o%2.2x", nid);
DPRINTF(("%s wcap=%s\n", this->name, flagbuf));
break;
}
azalia_widget_init_connection(this, codec);
/* amplifier information */
if (this->widgetcap & COP_AWCAP_INAMP) {
codec->comresp(codec, nid, CORB_GET_PARAMETER,
COP_INPUT_AMPCAP, &this->inamp_cap);
DPRINTF(("\tinamp: mute=%u size=%u steps=%u offset=%u\n",
(this->inamp_cap & COP_AMPCAP_MUTE) != 0,
COP_AMPCAP_STEPSIZE(this->inamp_cap),
COP_AMPCAP_NUMSTEPS(this->inamp_cap),
COP_AMPCAP_OFFSET(this->inamp_cap)));
}
if (this->widgetcap & COP_AWCAP_OUTAMP) {
codec->comresp(codec, nid, CORB_GET_PARAMETER,
COP_OUTPUT_AMPCAP, &this->outamp_cap);
DPRINTF(("\toutamp: mute=%u size=%u steps=%u offset=%u\n",
(this->outamp_cap & COP_AMPCAP_MUTE) != 0,
COP_AMPCAP_STEPSIZE(this->outamp_cap),
COP_AMPCAP_NUMSTEPS(this->outamp_cap),
COP_AMPCAP_OFFSET(this->outamp_cap)));
}
return 0;
}
static int
azalia_widget_init_audio(widget_t *this, const codec_t *codec)
{
uint32_t result;
int err;
/* check audio format */
err = codec->comresp(codec, this->nid,
CORB_GET_PARAMETER, COP_STREAM_FORMATS, &result);
if (err)
return err;
this->d.audio.encodings = result;
if ((result & COP_STREAM_FORMAT_PCM) == 0) {
aprint_error("%s: No PCM support\n", XNAME(codec->az));
return -1;
}
err = codec->comresp(codec, this->nid, CORB_GET_PARAMETER, COP_PCM, &result);
if (err)
return err;
this->d.audio.bits_rates = result;
#ifdef AZALIA_DEBUG
azalia_widget_print_audio(this, "\t");
#endif
return 0;
}
static int
azalia_widget_print_audio(const widget_t *this, const char *lead)
{
char flagbuf[FLAGBUFLEN];
bitmask_snprintf(this->d.audio.encodings, "\20\3AC3\2FLOAT32\1PCM",
flagbuf, FLAGBUFLEN);
aprint_normal("%s: encodings=%s\n", lead, flagbuf);
bitmask_snprintf(this->d.audio.bits_rates, "\20\x15""32bit\x14""24bit\x13""20bit"
"\x12""16bit\x11""8bit""\x0c""384kHz\x0b""192kHz\x0a""176.4kHz"
"\x09""96kHz\x08""88.2kHz\x07""48kHz\x06""44.1kHz\x05""32kHz\x04"
"22.05kHz\x03""16kHz\x02""11.025kHz\x01""8kHz",
flagbuf, FLAGBUFLEN);
aprint_normal("%s: PCM formats=%s\n", lead, flagbuf);
return 0;
}
static int
azalia_widget_init_pin(widget_t *this, const codec_t *codec)
{
uint32_t result;
int err;
err = codec->comresp(codec, this->nid, CORB_GET_CONFIGURATION_DEFAULT,
0, &result);
if (err)
return err;
this->d.pin.config = result;
this->d.pin.sequence = CORB_CD_SEQUENCE(result);
this->d.pin.association = CORB_CD_ASSOCIATION(result);
this->d.pin.color = CORB_CD_COLOR(result);
this->d.pin.device = CORB_CD_DEVICE(result);
err = codec->comresp(codec, this->nid, CORB_GET_PARAMETER,
COP_PINCAP, &result);
if (err)
return err;
this->d.pin.cap = result;
return 0;
}
static int
azalia_widget_print_pin(const widget_t *this)
{
char flagbuf[FLAGBUFLEN];
DPRINTF(("\tpin config; device=%s "
"color=%s assoc=%d seq=%d",
pin_devices[this->d.pin.device],
pin_colors[this->d.pin.color],
this->d.pin.association, this->d.pin.sequence));
bitmask_snprintf(this->d.pin.cap, "\20\021EAPD\07BALANCE\06INPUT\05OUTPUT"
"\04HEADPHONE\03PRESENCE\02TRIGGER\01IMPEDANCE", flagbuf, FLAGBUFLEN);
DPRINTF((" cap=%s\n", flagbuf));
return 0;
}
static int
azalia_widget_init_connection(widget_t *this, const codec_t *codec)
{
uint32_t result;
int err;
boolean_t longform;
int length, i;
this->selected = -1;
if ((this->widgetcap & COP_AWCAP_CONNLIST) == 0)
return 0;
err = codec->comresp(codec, this->nid, CORB_GET_PARAMETER,
COP_CONNECTION_LIST_LENGTH, &result);
if (err)
return err;
longform = (result & COP_CLL_LONG) != 0;
length = COP_CLL_LENGTH(result);
if (length == 0)
return 0;
this->nconnections = length;
this->connections = malloc(sizeof(nid_t) * length, M_DEVBUF, M_NOWAIT);
if (this->connections == NULL) {
aprint_error("%s: out of memory\n", XNAME(codec->az));
return ENOMEM;
}
if (longform) {
for (i = 0; i < length; i += 2) {
err = codec->comresp(codec, this->nid,
CORB_GET_CONNECTION_LIST_ENTRY, i, &result);
if (err)
return err;
this->connections[i] = CORB_CLE_LONG_0(result);
this->connections[i+1] = CORB_CLE_LONG_1(result);
}
} else {
for (i = 0; i < length; i += 4) {
err = codec->comresp(codec, this->nid,
CORB_GET_CONNECTION_LIST_ENTRY, i, &result);
if (err)
return err;
this->connections[i] = CORB_CLE_SHORT_0(result);
this->connections[i+1] = CORB_CLE_SHORT_1(result);
this->connections[i+2] = CORB_CLE_SHORT_2(result);
this->connections[i+3] = CORB_CLE_SHORT_3(result);
}
}
if (length > 0) {
DPRINTF(("\tconnections=0x%x", this->connections[0]));
for (i = 1; i < length; i++) {
DPRINTF((",0x%x", this->connections[i]));
}
err = codec->comresp(codec, this->nid,
CORB_GET_CONNECTION_SELECT_CONTROL, 0, &result);
if (err)
return err;
this->selected = CORB_CSC_INDEX(result);
DPRINTF(("; selected=0x%x\n", this->connections[result]));
}
return 0;
}
/* ================================================================
* MI audio entries
* ================================================================ */
static int
azalia_open(void *v, int flags)
{
azalia_t *az;
DPRINTF(("%s: flags=0x%x\n", __func__, flags));
az = v;
az->running++;
return 0;
}
static void
azalia_close(void *v)
{
azalia_t *az;
DPRINTF(("%s\n", __func__));
az = v;
az->running--;
}
static int
azalia_query_encoding(void *v, audio_encoding_t *enc)
{
azalia_t *az;
codec_t *codec;
az = v;
codec = &az->codecs[0];
return auconv_query_encoding(codec->encodings, enc);
}
static int
azalia_set_params(void *v, int smode, int umode, audio_params_t *p,
audio_params_t *r, stream_filter_list_t *pfil, stream_filter_list_t *rfil)
{
azalia_t *az;
codec_t *codec;
int index;
az = v;
codec = &az->codecs[0];
if (smode & AUMODE_RECORD && r != NULL) {
index = auconv_set_converter(codec->formats, codec->nformats,
AUMODE_RECORD, r, TRUE, rfil);
if (index < 0)
return 0/* XXX EINVAL */;
}
if (smode & AUMODE_PLAY && p != NULL) {
index = auconv_set_converter(codec->formats, codec->nformats,
AUMODE_PLAY, p, TRUE, pfil);
if (index < 0)
return EINVAL;
}
return 0;
}
static int
azalia_round_blocksize(void *v, int blk, int mode, const audio_params_t *param)
{
azalia_t *az;
size_t size;
blk &= ~0x7f; /* must be multiple of 128 */
if (blk <= 0)
blk = 128;
/* number of blocks must be <= HDA_BDL_MAX */
az = v;
size = mode == AUMODE_PLAY ? az->pstream.buffer.size : az->rstream.buffer.size;
#ifdef DIAGNOSTIC
if (size <= 0) {
aprint_error("%s: size is 0", __func__);
return 256;
}
#endif
if (size > HDA_BDL_MAX * blk) {
blk = size / HDA_BDL_MAX;
if (blk & 0x7f)
blk = (blk + 0x7f) & ~0x7f;
}
DPRINTF(("%s: resultant block size = %d\n", __func__, blk));
return blk;
}
static int
azalia_halt_output(void *v)
{
azalia_t *az;
stream_t *str;
uint16_t ctl;
DPRINTF(("%s\n", __func__));
az = v;
str = &az->pstream;
ctl = STR_READ_2(az, str, CTL);
ctl &= ~(HDA_SD_CTL_DEIE | HDA_SD_CTL_FEIE | HDA_SD_CTL_IOCE | HDA_SD_CTL_RUN);
STR_WRITE_2(az, str, CTL, ctl);
AZ_WRITE_1(az, INTCTL, AZ_READ_1(az, INTCTL) & ~str->intr_bit);
return 0;
}
static int
azalia_halt_input(void *v)
{
azalia_t *az;
stream_t *str;
uint16_t ctl;
DPRINTF(("%s\n", __func__));
az = v;
str = &az->rstream;
ctl = STR_READ_2(az, str, CTL);
ctl &= ~(HDA_SD_CTL_DEIE | HDA_SD_CTL_FEIE | HDA_SD_CTL_IOCE | HDA_SD_CTL_RUN);
STR_WRITE_2(az, str, CTL, ctl);
AZ_WRITE_1(az, INTCTL, AZ_READ_1(az, INTCTL) & ~str->intr_bit);
return 0;
}
static int
azalia_getdev(void *v, struct audio_device *dev)
{
azalia_t *az;
az = v;
strlcpy(dev->name, "HD-Audio", MAX_AUDIO_DEV_LEN);
snprintf(dev->version, MAX_AUDIO_DEV_LEN,
"%d.%d", AZ_READ_1(az, VMAJ), AZ_READ_1(az, VMIN));
strlcpy(dev->config, XNAME(az), MAX_AUDIO_DEV_LEN);
return 0;
}
static int
azalia_set_port(void *v, mixer_ctrl_t *mc)
{
azalia_t *az;
codec_t *co;
az = v;
co = &az->codecs[0];
return azalia_mixer_set(co, mc);
}
static int
azalia_get_port(void *v, mixer_ctrl_t *mc)
{
azalia_t *az;
codec_t *co;
az = v;
co = &az->codecs[0];
return azalia_mixer_get(co, mc);
}
static int
azalia_query_devinfo(void *v, mixer_devinfo_t *mdev)
{
azalia_t *az;
codec_t *co;
az = v;
co = &az->codecs[0];
if (mdev->index >= co->nmixers)
return ENXIO;
*mdev = co->mixers[mdev->index].devinfo;
return 0;
}
static void *
azalia_allocm(void *v, int dir, size_t size, struct malloc_type *pool, int flags)
{
azalia_t *az;
stream_t *stream;
int err;
az = v;
stream = dir == AUMODE_PLAY ? &az->pstream : &az->rstream;
err = azalia_alloc_dmamem(az, size, 128, &stream->buffer);
if (err)
return NULL;
return stream->buffer.addr;
}
static void
azalia_freem(void *v, void *addr, struct malloc_type *pool)
{
azalia_t *az;
stream_t *stream;
az = v;
if (addr == az->pstream.buffer.addr) {
stream = &az->pstream;
} else if (addr == az->rstream.buffer.addr) {
stream = &az->rstream;
} else {
return;
}
azalia_free_dmamem(az, &stream->buffer);
}
static size_t
azalia_round_buffersize(void *v, int dir, size_t size)
{
size &= ~0x7f; /* must be multiple of 128 */
if (size <= 0)
size = 128;
return size;
}
static int
azalia_get_props(void *v)
{
return AUDIO_PROP_INDEPENDENT | AUDIO_PROP_FULLDUPLEX;
}
static int
azalia_trigger_output(void *v, void *start, void *end, int blk,
void (*intr)(void *), void *arg, const audio_params_t *param)
{
azalia_t *az;
stream_t *str;
bdlist_entry_t *bdlist;
bus_addr_t dmaaddr;
int err, index, i;
uint16_t fmt, ctl;
uint8_t ctl2, intctl;
DPRINTF(("%s: this=%p start=%p end=%p blk=%d {enc=%u %uch %u/%ubit %uHz}\n",
__func__, v, start, end, blk, param->encoding, param->channels,
param->validbits, param->precision, param->sample_rate));
az = v;
str = &az->pstream;
str->intr = intr;
str->intr_arg = arg;
/* reset the stream */
ctl = STR_READ_2(az, str, CTL);
STR_WRITE_2(az, str, CTL, ctl | HDA_SD_CTL_SRST);
for (i = 5000; i >= 0; i--) {
DELAY(10);
ctl = STR_READ_2(az, str, CTL);
if (ctl & HDA_SD_CTL_SRST)
break;
}
if (i <= 0) {
aprint_error("%s: stream reset failure 1\n", XNAME(az));
return -1;
}
STR_WRITE_2(az, str, CTL, ctl & ~HDA_SD_CTL_SRST);
for (i = 5000; i >= 0; i--) {
DELAY(10);
ctl = STR_READ_2(az, str, CTL);
if ((ctl & HDA_SD_CTL_SRST) == 0)
break;
}
if (i <= 0) {
aprint_error("%s: stream reset failure 2\n", XNAME(az));
return -1;
}
/* setup BDL */
dmaaddr = AZALIA_DMA_DMAADDR(&str->buffer);
str->dmaend = dmaaddr + ((caddr_t)end - (caddr_t)start);
bdlist = (bdlist_entry_t*)str->bdlist.addr;
for (index = 0; index < HDA_BDL_MAX; index++) {
bdlist[index].low = dmaaddr;
bdlist[index].high = PTR_UPPER32(dmaaddr);
bdlist[index].length = blk;
bdlist[index].flags = BDLIST_ENTRY_IOC;
dmaaddr += blk;
if (dmaaddr >= str->dmaend) {
index++;
break;
}
}
/* The BDL covers the whole of the buffer. */
str->dmanext = AZALIA_DMA_DMAADDR(&str->buffer);
dmaaddr = AZALIA_DMA_DMAADDR(&str->bdlist);
STR_WRITE_4(az, str, BDPL, dmaaddr);
STR_WRITE_4(az, str, BDPU, PTR_UPPER32(dmaaddr));
STR_WRITE_2(az, str, LVI, (index - 1) & HDA_SD_LVI_LVI);
ctl2 = STR_READ_1(az, str, CTL2);
STR_WRITE_1(az, str, CTL2,
(ctl2 & ~HDA_SD_CTL2_STRM) | (str->number << HDA_SD_CTL2_STRM_SHIFT));
STR_WRITE_4(az, str, CBL, ((caddr_t)end - (caddr_t)start));
err = azalia_params2fmt(param, &fmt);
if (err)
return EINVAL;
STR_WRITE_2(az, str, FMT, fmt);
err = azalia_codec_connect_stream(&az->codecs[0], AUMODE_PLAY,
fmt, str->number);
if (err)
return EINVAL;
intctl = AZ_READ_1(az, INTCTL);
intctl |= str->intr_bit;
AZ_WRITE_1(az, INTCTL, intctl);
ctl = STR_READ_2(az, str, CTL);
ctl |= ctl | HDA_SD_CTL_DEIE | HDA_SD_CTL_FEIE | HDA_SD_CTL_IOCE | HDA_SD_CTL_RUN;
STR_WRITE_2(az, str, CTL, ctl);
return 0;
}
static int
azalia_trigger_input(void *v, void *start, void *end, int blk,
void (*intr)(void *), void *arg, const audio_params_t *param)
{
DPRINTF(("%s: this=%p start=%p end=%p blk=%d {enc=%u %uch %u/%ubit %uHz}\n",
__func__, v, start, end, blk, param->encoding, param->channels,
param->validbits, param->precision, param->sample_rate));
aprint_error("%s: NOT IMPLEMENTED\n", __func__); /* XXX */
return ENXIO;
}
/* --------------------------------
* helpers for MI audio functions
* -------------------------------- */
static int
azalia_params2fmt(const audio_params_t *param, uint16_t *fmt)
{
uint16_t ret;
ret = 0;
#ifdef DIAGNOSTIC
if (param->channels > HDA_MAX_CHANNELS) {
aprint_error("%s: too many channels: %u\n", __func__, param->channels);
return EINVAL;
}
#endif
ret |= param->channels - 1;
switch (param->validbits) {
case 8:
ret |= HDA_SD_FMT_BITS_8_16;
break;
case 16:
ret |= HDA_SD_FMT_BITS_16_16;
break;
case 20:
ret |= HDA_SD_FMT_BITS_20_32;
break;
case 24:
ret |= HDA_SD_FMT_BITS_24_32;
break;
case 32:
ret |= HDA_SD_FMT_BITS_32_32;
break;
default:
aprint_error("%s: invalid validbits: %u\n", __func__, param->validbits);
}
if (param->sample_rate == 384000) {
aprint_error("%s: invalid sample_rate: %u\n", __func__, param->sample_rate);
return EINVAL;
} else if (param->sample_rate == 192000) {
ret |= HDA_SD_FMT_BASE_48 | HDA_SD_FMT_MULT_X4 | HDA_SD_FMT_DIV_BY1;
} else if (param->sample_rate == 176400) {
ret |= HDA_SD_FMT_BASE_44 | HDA_SD_FMT_MULT_X4 | HDA_SD_FMT_DIV_BY1;
} else if (param->sample_rate == 96000) {
ret |= HDA_SD_FMT_BASE_48 | HDA_SD_FMT_MULT_X2 | HDA_SD_FMT_DIV_BY1;
} else if (param->sample_rate == 88200) {
ret |= HDA_SD_FMT_BASE_44 | HDA_SD_FMT_MULT_X2 | HDA_SD_FMT_DIV_BY1;
} else if (param->sample_rate == 48000) {
ret |= HDA_SD_FMT_BASE_48 | HDA_SD_FMT_MULT_X1 | HDA_SD_FMT_DIV_BY1;
} else if (param->sample_rate == 44100) {
ret |= HDA_SD_FMT_BASE_44 | HDA_SD_FMT_MULT_X1 | HDA_SD_FMT_DIV_BY1;
} else if (param->sample_rate == 32000) {
ret |= HDA_SD_FMT_BASE_48 | HDA_SD_FMT_MULT_X2 | HDA_SD_FMT_DIV_BY3;
} else if (param->sample_rate == 22050) {
ret |= HDA_SD_FMT_BASE_44 | HDA_SD_FMT_MULT_X1 | HDA_SD_FMT_DIV_BY2;
} else if (param->sample_rate == 16000) {
ret |= HDA_SD_FMT_BASE_48 | HDA_SD_FMT_MULT_X1 | HDA_SD_FMT_DIV_BY3;
} else if (param->sample_rate == 11025) {
ret |= HDA_SD_FMT_BASE_44 | HDA_SD_FMT_MULT_X1 | HDA_SD_FMT_DIV_BY4;
} else if (param->sample_rate == 8000) {
ret |= HDA_SD_FMT_BASE_48 | HDA_SD_FMT_MULT_X1 | HDA_SD_FMT_DIV_BY6;
} else {
aprint_error("%s: invalid sample_rate: %u\n", __func__, param->sample_rate);
return EINVAL;
}
*fmt = ret;
return 0;
}