/* $Id: DevIchHdaCodec.cpp 61413 2016-06-02 13:24:16Z vboxsync $ */ /** @file * DevIchHdaCodec - VBox ICH Intel HD Audio Codec. * * Implemented against "Intel I/O Controller Hub 6 (ICH6) High Definition * Audio / AC '97 - Programmer's Reference Manual (PRM)", document number * 302349-003. */ /* * Copyright (C) 2006-2016 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #define LOG_GROUP LOG_GROUP_DEV_HDA_CODEC #include #include #include #include #include #include #include #include #include "VBoxDD.h" #include "DevIchHdaCodec.h" /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ /* PRM 5.3.1 */ /** Codec address mask. */ #define CODEC_CAD_MASK 0xF0000000 /** Codec address shift. */ #define CODEC_CAD_SHIFT 28 #define CODEC_DIRECT_MASK RT_BIT(27) /** Node ID mask. */ #define CODEC_NID_MASK 0x07F00000 /** Node ID shift. */ #define CODEC_NID_SHIFT 20 #define CODEC_VERBDATA_MASK 0x000FFFFF #define CODEC_VERB_4BIT_CMD 0x000FFFF0 #define CODEC_VERB_4BIT_DATA 0x0000000F #define CODEC_VERB_8BIT_CMD 0x000FFF00 #define CODEC_VERB_8BIT_DATA 0x000000FF #define CODEC_VERB_16BIT_CMD 0x000F0000 #define CODEC_VERB_16BIT_DATA 0x0000FFFF #define CODEC_CAD(cmd) (((cmd) & CODEC_CAD_MASK) >> CODEC_CAD_SHIFT) #define CODEC_DIRECT(cmd) ((cmd) & CODEC_DIRECT_MASK) #define CODEC_NID(cmd) ((((cmd) & CODEC_NID_MASK)) >> CODEC_NID_SHIFT) #define CODEC_VERBDATA(cmd) ((cmd) & CODEC_VERBDATA_MASK) #define CODEC_VERB_CMD(cmd, mask, x) (((cmd) & (mask)) >> (x)) #define CODEC_VERB_CMD4(cmd) (CODEC_VERB_CMD((cmd), CODEC_VERB_4BIT_CMD, 4)) #define CODEC_VERB_CMD8(cmd) (CODEC_VERB_CMD((cmd), CODEC_VERB_8BIT_CMD, 8)) #define CODEC_VERB_CMD16(cmd) (CODEC_VERB_CMD((cmd), CODEC_VERB_16BIT_CMD, 16)) #define CODEC_VERB_PAYLOAD4(cmd) ((cmd) & CODEC_VERB_4BIT_DATA) #define CODEC_VERB_PAYLOAD8(cmd) ((cmd) & CODEC_VERB_8BIT_DATA) #define CODEC_VERB_PAYLOAD16(cmd) ((cmd) & CODEC_VERB_16BIT_DATA) #define CODEC_VERB_GET_AMP_DIRECTION RT_BIT(15) #define CODEC_VERB_GET_AMP_SIDE RT_BIT(13) #define CODEC_VERB_GET_AMP_INDEX 0x7 /* HDA spec 7.3.3.7 NoteA */ #define CODEC_GET_AMP_DIRECTION(cmd) (((cmd) & CODEC_VERB_GET_AMP_DIRECTION) >> 15) #define CODEC_GET_AMP_SIDE(cmd) (((cmd) & CODEC_VERB_GET_AMP_SIDE) >> 13) #define CODEC_GET_AMP_INDEX(cmd) (CODEC_GET_AMP_DIRECTION(cmd) ? 0 : ((cmd) & CODEC_VERB_GET_AMP_INDEX)) /* HDA spec 7.3.3.7 NoteC */ #define CODEC_VERB_SET_AMP_OUT_DIRECTION RT_BIT(15) #define CODEC_VERB_SET_AMP_IN_DIRECTION RT_BIT(14) #define CODEC_VERB_SET_AMP_LEFT_SIDE RT_BIT(13) #define CODEC_VERB_SET_AMP_RIGHT_SIDE RT_BIT(12) #define CODEC_VERB_SET_AMP_INDEX (0x7 << 8) #define CODEC_VERB_SET_AMP_MUTE RT_BIT(7) /** Note: 7-bit value [6:0]. */ #define CODEC_VERB_SET_AMP_GAIN 0x7F #define CODEC_SET_AMP_IS_OUT_DIRECTION(cmd) (((cmd) & CODEC_VERB_SET_AMP_OUT_DIRECTION) != 0) #define CODEC_SET_AMP_IS_IN_DIRECTION(cmd) (((cmd) & CODEC_VERB_SET_AMP_IN_DIRECTION) != 0) #define CODEC_SET_AMP_IS_LEFT_SIDE(cmd) (((cmd) & CODEC_VERB_SET_AMP_LEFT_SIDE) != 0) #define CODEC_SET_AMP_IS_RIGHT_SIDE(cmd) (((cmd) & CODEC_VERB_SET_AMP_RIGHT_SIDE) != 0) #define CODEC_SET_AMP_INDEX(cmd) (((cmd) & CODEC_VERB_SET_AMP_INDEX) >> 7) #define CODEC_SET_AMP_MUTE(cmd) ((cmd) & CODEC_VERB_SET_AMP_MUTE) #define CODEC_SET_AMP_GAIN(cmd) ((cmd) & CODEC_VERB_SET_AMP_GAIN) /* HDA spec 7.3.3.1 defines layout of configuration registers/verbs (0xF00) */ /* VendorID (7.3.4.1) */ #define CODEC_MAKE_F00_00(vendorID, deviceID) (((vendorID) << 16) | (deviceID)) #define CODEC_F00_00_VENDORID(f00_00) (((f00_00) >> 16) & 0xFFFF) #define CODEC_F00_00_DEVICEID(f00_00) ((f00_00) & 0xFFFF) /* RevisionID (7.3.4.2)*/ #define CODEC_MAKE_F00_02(MajRev, MinRev, RevisionID, SteppingID) (((MajRev) << 20)|((MinRev) << 16)|((RevisionID) << 8)|(SteppingID)) /* Subordinate node count (7.3.4.3)*/ #define CODEC_MAKE_F00_04(startNodeNumber, totalNodeNumber) ((((startNodeNumber) & 0xFF) << 16)|((totalNodeNumber) & 0xFF)) #define CODEC_F00_04_TO_START_NODE_NUMBER(f00_04) (((f00_04) >> 16) & 0xFF) #define CODEC_F00_04_TO_NODE_COUNT(f00_04) ((f00_04) & 0xFF) /* * Function Group Type (7.3.4.4) * 0 & [0x3-0x7f] are reserved types * [0x80 - 0xff] are vendor defined function groups */ #define CODEC_MAKE_F00_05(UnSol, NodeType) (((UnSol) << 8)|(NodeType)) #define CODEC_F00_05_UNSOL RT_BIT(8) #define CODEC_F00_05_AFG (0x1) #define CODEC_F00_05_MFG (0x2) #define CODEC_F00_05_IS_UNSOL(f00_05) RT_BOOL((f00_05) & RT_BIT(8)) #define CODEC_F00_05_GROUP(f00_05) ((f00_05) & 0xff) /* Audio Function Group capabilities (7.3.4.5) */ #define CODEC_MAKE_F00_08(BeepGen, InputDelay, OutputDelay) ((((BeepGen) & 0x1) << 16)| (((InputDelay) & 0xF) << 8) | ((OutputDelay) & 0xF)) #define CODEC_F00_08_BEEP_GEN(f00_08) ((f00_08) & RT_BIT(16) /* Widget Capabilities (7.3.4.6) */ #define CODEC_MAKE_F00_09(type, delay, chanel_count) \ ( (((type) & 0xF) << 20) \ | (((delay) & 0xF) << 16) \ | (((chanel_count) & 0xF) << 13)) /* note: types 0x8-0xe are reserved */ #define CODEC_F00_09_TYPE_AUDIO_OUTPUT (0x0) #define CODEC_F00_09_TYPE_AUDIO_INPUT (0x1) #define CODEC_F00_09_TYPE_AUDIO_MIXER (0x2) #define CODEC_F00_09_TYPE_AUDIO_SELECTOR (0x3) #define CODEC_F00_09_TYPE_PIN_COMPLEX (0x4) #define CODEC_F00_09_TYPE_POWER_WIDGET (0x5) #define CODEC_F00_09_TYPE_VOLUME_KNOB (0x6) #define CODEC_F00_09_TYPE_BEEP_GEN (0x7) #define CODEC_F00_09_TYPE_VENDOR_DEFINED (0xF) #define CODEC_F00_09_CAP_CP RT_BIT(12) #define CODEC_F00_09_CAP_L_R_SWAP RT_BIT(11) #define CODEC_F00_09_CAP_POWER_CTRL RT_BIT(10) #define CODEC_F00_09_CAP_DIGITAL RT_BIT(9) #define CODEC_F00_09_CAP_CONNECTION_LIST RT_BIT(8) #define CODEC_F00_09_CAP_UNSOL RT_BIT(7) #define CODEC_F00_09_CAP_PROC_WIDGET RT_BIT(6) #define CODEC_F00_09_CAP_STRIPE RT_BIT(5) #define CODEC_F00_09_CAP_FMT_OVERRIDE RT_BIT(4) #define CODEC_F00_09_CAP_AMP_FMT_OVERRIDE RT_BIT(3) #define CODEC_F00_09_CAP_OUT_AMP_PRESENT RT_BIT(2) #define CODEC_F00_09_CAP_IN_AMP_PRESENT RT_BIT(1) #define CODEC_F00_09_CAP_LSB RT_BIT(0) #define CODEC_F00_09_TYPE(f00_09) (((f00_09) >> 20) & 0xF) #define CODEC_F00_09_IS_CAP_CP(f00_09) RT_BOOL((f00_09) & RT_BIT(12)) #define CODEC_F00_09_IS_CAP_L_R_SWAP(f00_09) RT_BOOL((f00_09) & RT_BIT(11)) #define CODEC_F00_09_IS_CAP_POWER_CTRL(f00_09) RT_BOOL((f00_09) & RT_BIT(10)) #define CODEC_F00_09_IS_CAP_DIGITAL(f00_09) RT_BOOL((f00_09) & RT_BIT(9)) #define CODEC_F00_09_IS_CAP_CONNECTION_LIST(f00_09) RT_BOOL((f00_09) & RT_BIT(8)) #define CODEC_F00_09_IS_CAP_UNSOL(f00_09) RT_BOOL((f00_09) & RT_BIT(7)) #define CODEC_F00_09_IS_CAP_PROC_WIDGET(f00_09) RT_BOOL((f00_09) & RT_BIT(6)) #define CODEC_F00_09_IS_CAP_STRIPE(f00_09) RT_BOOL((f00_09) & RT_BIT(5)) #define CODEC_F00_09_IS_CAP_FMT_OVERRIDE(f00_09) RT_BOOL((f00_09) & RT_BIT(4)) #define CODEC_F00_09_IS_CAP_AMP_OVERRIDE(f00_09) RT_BOOL((f00_09) & RT_BIT(3)) #define CODEC_F00_09_IS_CAP_OUT_AMP_PRESENT(f00_09) RT_BOOL((f00_09) & RT_BIT(2)) #define CODEC_F00_09_IS_CAP_IN_AMP_PRESENT(f00_09) RT_BOOL((f00_09) & RT_BIT(1)) #define CODEC_F00_09_IS_CAP_LSB(f00_09) RT_BOOL((f00_09) & RT_BIT(0)) /* Supported PCM size, rates (7.3.4.7) */ #define CODEC_F00_0A_32_BIT RT_BIT(19) #define CODEC_F00_0A_24_BIT RT_BIT(18) #define CODEC_F00_0A_16_BIT RT_BIT(17) #define CODEC_F00_0A_8_BIT RT_BIT(16) #define CODEC_F00_0A_48KHZ_MULT_8X RT_BIT(11) #define CODEC_F00_0A_48KHZ_MULT_4X RT_BIT(10) #define CODEC_F00_0A_44_1KHZ_MULT_4X RT_BIT(9) #define CODEC_F00_0A_48KHZ_MULT_2X RT_BIT(8) #define CODEC_F00_0A_44_1KHZ_MULT_2X RT_BIT(7) #define CODEC_F00_0A_48KHZ RT_BIT(6) #define CODEC_F00_0A_44_1KHZ RT_BIT(5) /* 2/3 * 48kHz */ #define CODEC_F00_0A_48KHZ_2_3X RT_BIT(4) /* 1/2 * 44.1kHz */ #define CODEC_F00_0A_44_1KHZ_1_2X RT_BIT(3) /* 1/3 * 48kHz */ #define CODEC_F00_0A_48KHZ_1_3X RT_BIT(2) /* 1/4 * 44.1kHz */ #define CODEC_F00_0A_44_1KHZ_1_4X RT_BIT(1) /* 1/6 * 48kHz */ #define CODEC_F00_0A_48KHZ_1_6X RT_BIT(0) /* Supported streams formats (7.3.4.8) */ #define CODEC_F00_0B_AC3 RT_BIT(2) #define CODEC_F00_0B_FLOAT32 RT_BIT(1) #define CODEC_F00_0B_PCM RT_BIT(0) /* Pin Capabilities (7.3.4.9)*/ #define CODEC_MAKE_F00_0C(vref_ctrl) (((vref_ctrl) & 0xFF) << 8) #define CODEC_F00_0C_CAP_HBR RT_BIT(27) #define CODEC_F00_0C_CAP_DP RT_BIT(24) #define CODEC_F00_0C_CAP_EAPD RT_BIT(16) #define CODEC_F00_0C_CAP_HDMI RT_BIT(7) #define CODEC_F00_0C_CAP_BALANCED_IO RT_BIT(6) #define CODEC_F00_0C_CAP_INPUT RT_BIT(5) #define CODEC_F00_0C_CAP_OUTPUT RT_BIT(4) #define CODEC_F00_0C_CAP_HP RT_BIT(3) #define CODEC_F00_0C_CAP_PRESENSE_DETECT RT_BIT(2) #define CODEC_F00_0C_CAP_TRIGGER_REQUIRED RT_BIT(1) #define CODEC_F00_0C_CAP_IMPENDANCE_SENSE RT_BIT(0) #define CODEC_F00_0C_IS_CAP_HBR(f00_0c) ((f00_0c) & RT_BIT(27)) #define CODEC_F00_0C_IS_CAP_DP(f00_0c) ((f00_0c) & RT_BIT(24)) #define CODEC_F00_0C_IS_CAP_EAPD(f00_0c) ((f00_0c) & RT_BIT(16)) #define CODEC_F00_0C_IS_CAP_HDMI(f00_0c) ((f00_0c) & RT_BIT(7)) #define CODEC_F00_0C_IS_CAP_BALANCED_IO(f00_0c) ((f00_0c) & RT_BIT(6)) #define CODEC_F00_0C_IS_CAP_INPUT(f00_0c) ((f00_0c) & RT_BIT(5)) #define CODEC_F00_0C_IS_CAP_OUTPUT(f00_0c) ((f00_0c) & RT_BIT(4)) #define CODEC_F00_0C_IS_CAP_HP(f00_0c) ((f00_0c) & RT_BIT(3)) #define CODEC_F00_0C_IS_CAP_PRESENSE_DETECT(f00_0c) ((f00_0c) & RT_BIT(2)) #define CODEC_F00_0C_IS_CAP_TRIGGER_REQUIRED(f00_0c) ((f00_0c) & RT_BIT(1)) #define CODEC_F00_0C_IS_CAP_IMPENDANCE_SENSE(f00_0c) ((f00_0c) & RT_BIT(0)) /* Input Amplifier capabilities (7.3.4.10) */ #define CODEC_MAKE_F00_0D(mute_cap, step_size, num_steps, offset) \ ( (((mute_cap) & 0x1) << 31) \ | (((step_size) & 0xFF) << 16) \ | (((num_steps) & 0xFF) << 8) \ | ((offset) & 0xFF)) #define CODEC_F00_0D_CAP_MUTE RT_BIT(7) #define CODEC_F00_0D_IS_CAP_MUTE(f00_0d) ( ( f00_0d) & RT_BIT(31)) #define CODEC_F00_0D_STEP_SIZE(f00_0d) ((( f00_0d) & (0x7F << 16)) >> 16) #define CODEC_F00_0D_NUM_STEPS(f00_0d) ((((f00_0d) & (0x7F << 8)) >> 8) + 1) #define CODEC_F00_0D_OFFSET(f00_0d) ( (f00_0d) & 0x7F) /* Output Amplifier capabilities (7.3.4.10) */ #define CODEC_MAKE_F00_12 CODEC_MAKE_F00_0D #define CODEC_F00_12_IS_CAP_MUTE(f00_12) CODEC_F00_0D_IS_CAP_MUTE(f00_12) #define CODEC_F00_12_STEP_SIZE(f00_12) CODEC_F00_0D_STEP_SIZE(f00_12) #define CODEC_F00_12_NUM_STEPS(f00_12) CODEC_F00_0D_NUM_STEPS(f00_12) #define CODEC_F00_12_OFFSET(f00_12) CODEC_F00_0D_OFFSET(f00_12) /* Connection list lenght (7.3.4.11) */ #define CODEC_MAKE_F00_0E(long_form, length) \ ( (((long_form) & 0x1) << 7) \ | ((length) & 0x7F)) /* Indicates short-form NIDs. */ #define CODEC_F00_0E_LIST_NID_SHORT 0 /* Indicates long-form NIDs. */ #define CODEC_F00_0E_LIST_NID_LONG 1 #define CODEC_F00_0E_IS_LONG(f00_0e) RT_BOOL((f00_0e) & RT_BIT(7)) #define CODEC_F00_0E_COUNT(f00_0e) ((f00_0e) & 0x7F) /* Supported Power States (7.3.4.12) */ #define CODEC_F00_0F_EPSS RT_BIT(31) #define CODEC_F00_0F_CLKSTOP RT_BIT(30) #define CODEC_F00_0F_S3D3 RT_BIT(29) #define CODEC_F00_0F_D3COLD RT_BIT(4) #define CODEC_F00_0F_D3 RT_BIT(3) #define CODEC_F00_0F_D2 RT_BIT(2) #define CODEC_F00_0F_D1 RT_BIT(1) #define CODEC_F00_0F_D0 RT_BIT(0) /* Processing capabilities 7.3.4.13 */ #define CODEC_MAKE_F00_10(num, benign) ((((num) & 0xFF) << 8) | ((benign) & 0x1)) #define CODEC_F00_10_NUM(f00_10) (((f00_10) & (0xFF << 8)) >> 8) #define CODEC_F00_10_BENING(f00_10) ((f00_10) & 0x1) /* CP/IO Count (7.3.4.14) */ #define CODEC_MAKE_F00_11(wake, unsol, numgpi, numgpo, numgpio) \ ( (((wake) & 0x1) << 31) \ | (((unsol) & 0x1) << 30) \ | (((numgpi) & 0xFF) << 16) \ | (((numgpo) & 0xFF) << 8) \ | ((numgpio) & 0xFF)) /* Processing States (7.3.3.4) */ #define CODEC_F03_OFF (0) #define CODEC_F03_ON RT_BIT(0) #define CODEC_F03_BENING RT_BIT(1) /* Power States (7.3.3.10) */ #define CODEC_MAKE_F05(reset, stopok, error, act, set) \ ( (((reset) & 0x1) << 10) \ | (((stopok) & 0x1) << 9) \ | (((error) & 0x1) << 8) \ | (((act) & 0x7) << 4) \ | ((set) & 0x7)) #define CODEC_F05_D3COLD (4) #define CODEC_F05_D3 (3) #define CODEC_F05_D2 (2) #define CODEC_F05_D1 (1) #define CODEC_F05_D0 (0) #define CODEC_F05_IS_RESET(value) (((value) & RT_BIT(10)) != 0) #define CODEC_F05_IS_STOPOK(value) (((value) & RT_BIT(9)) != 0) #define CODEC_F05_IS_ERROR(value) (((value) & RT_BIT(8)) != 0) #define CODEC_F05_ACT(value) (((value) & 0x7) >> 4) #define CODEC_F05_SET(value) (((value) & 0x7)) #define CODEC_F05_GE(p0, p1) ((p0) <= (p1)) #define CODEC_F05_LE(p0, p1) ((p0) >= (p1)) /* Pin Widged Control (7.3.3.13) */ #define CODEC_F07_VREF_HIZ (0) #define CODEC_F07_VREF_50 (0x1) #define CODEC_F07_VREF_GROUND (0x2) #define CODEC_F07_VREF_80 (0x4) #define CODEC_F07_VREF_100 (0x5) #define CODEC_F07_IN_ENABLE RT_BIT(5) #define CODEC_F07_OUT_ENABLE RT_BIT(6) #define CODEC_F07_OUT_H_ENABLE RT_BIT(7) /* Unsolicited enabled (7.3.3.14) */ #define CODEC_MAKE_F08(enable, tag) ((((enable) & 1) << 7) | ((tag) & 0x3F)) /* Converter formats (7.3.3.8) and (3.7.1) */ #define CODEC_MAKE_A(fNonPCM, f44_1BaseRate, mult, div, bits, chan) \ ( (((fNonPCM) & 0x1) << 15) \ | (((f44_1BaseRate) & 0x1) << 14) \ | (((mult) & 0x7) << 11) \ | (((div) & 0x7) << 8) \ | (((bits) & 0x7) << 4) \ | ((chan) & 0xF)) #define CODEC_A_TYPE RT_BIT(15) #define CODEC_A_TYPE_PCM (0) #define CODEC_A_TYPE_NON_PCM (1) #define CODEC_A_BASE RT_BIT(14) #define CODEC_A_BASE_48KHZ (0) #define CODEC_A_BASE_44KHZ (1) #define CODEC_A_MULT_1X (0) #define CODEC_A_MULT_2X (1) #define CODEC_A_MULT_3X (2) #define CODEC_A_MULT_4X (3) #define CODEC_A_DIV_1X (0) #define CODEC_A_DIV_2X (1) #define CODEC_A_DIV_3X (2) #define CODEC_A_DIV_4X (3) #define CODEC_A_DIV_5X (4) #define CODEC_A_DIV_6X (5) #define CODEC_A_DIV_7X (6) #define CODEC_A_DIV_8X (7) #define CODEC_A_8_BIT (0) #define CODEC_A_16_BIT (1) #define CODEC_A_20_BIT (2) #define CODEC_A_24_BIT (3) #define CODEC_A_32_BIT (4) #define CODEC_A_CHAN_MONO (0) #define CODEC_A_CHAN_STEREO (1) /* Pin Sense (7.3.3.15) */ #define CODEC_MAKE_F09_ANALOG(fPresent, impedance) \ ( (((fPresent) & 0x1) << 31) \ | (((impedance) & 0x7FFFFFFF))) #define CODEC_F09_ANALOG_NA 0x7FFFFFFF #define CODEC_MAKE_F09_DIGITAL(fPresent, fELDValid) \ ( (((fPresent) & 0x1) << 31) \ | (((fELDValid) & 0x1) << 30)) #define CODEC_MAKE_F0C(lrswap, eapd, btl) ((((lrswap) & 1) << 2) | (((eapd) & 1) << 1) | ((btl) & 1)) #define CODEC_FOC_IS_LRSWAP(f0c) RT_BOOL((f0c) & RT_BIT(2)) #define CODEC_FOC_IS_EAPD(f0c) RT_BOOL((f0c) & RT_BIT(1)) #define CODEC_FOC_IS_BTL(f0c) RT_BOOL((f0c) & RT_BIT(0)) /* HDA spec 7.3.3.31 defines layout of configuration registers/verbs (0xF1C) */ /* Configuration's port connection */ #define CODEC_F1C_PORT_MASK (0x3) #define CODEC_F1C_PORT_SHIFT (30) #define CODEC_F1C_PORT_COMPLEX (0x0) #define CODEC_F1C_PORT_NO_PHYS (0x1) #define CODEC_F1C_PORT_FIXED (0x2) #define CODEC_F1C_BOTH (0x3) /* Configuration default: connection */ #define CODEC_F1C_PORT_MASK (0x3) #define CODEC_F1C_PORT_SHIFT (30) /* Connected to a jack (1/8", ATAPI, ...). */ #define CODEC_F1C_PORT_COMPLEX (0x0) /* No physical connection. */ #define CODEC_F1C_PORT_NO_PHYS (0x1) /* Fixed function device (integrated speaker, integrated mic, ...). */ #define CODEC_F1C_PORT_FIXED (0x2) /* Both, a jack and an internal device are attached. */ #define CODEC_F1C_BOTH (0x3) /* Configuration default: Location */ #define CODEC_F1C_LOCATION_MASK (0x3F) #define CODEC_F1C_LOCATION_SHIFT (24) /* [4:5] bits of location region means chassis attachment */ #define CODEC_F1C_LOCATION_PRIMARY_CHASSIS (0) #define CODEC_F1C_LOCATION_INTERNAL RT_BIT(4) #define CODEC_F1C_LOCATION_SECONDRARY_CHASSIS RT_BIT(5) #define CODEC_F1C_LOCATION_OTHER RT_BIT(5) /* [0:3] bits of location region means geometry location attachment */ #define CODEC_F1C_LOCATION_NA (0) #define CODEC_F1C_LOCATION_REAR (0x1) #define CODEC_F1C_LOCATION_FRONT (0x2) #define CODEC_F1C_LOCATION_LEFT (0x3) #define CODEC_F1C_LOCATION_RIGTH (0x4) #define CODEC_F1C_LOCATION_TOP (0x5) #define CODEC_F1C_LOCATION_BOTTOM (0x6) #define CODEC_F1C_LOCATION_SPECIAL_0 (0x7) #define CODEC_F1C_LOCATION_SPECIAL_1 (0x8) #define CODEC_F1C_LOCATION_SPECIAL_2 (0x9) /* Configuration default: Device type */ #define CODEC_F1C_DEVICE_MASK (0xF) #define CODEC_F1C_DEVICE_SHIFT (20) #define CODEC_F1C_DEVICE_LINE_OUT (0) #define CODEC_F1C_DEVICE_SPEAKER (0x1) #define CODEC_F1C_DEVICE_HP (0x2) #define CODEC_F1C_DEVICE_CD (0x3) #define CODEC_F1C_DEVICE_SPDIF_OUT (0x4) #define CODEC_F1C_DEVICE_DIGITAL_OTHER_OUT (0x5) #define CODEC_F1C_DEVICE_MODEM_LINE_SIDE (0x6) #define CODEC_F1C_DEVICE_MODEM_HANDSET_SIDE (0x7) #define CODEC_F1C_DEVICE_LINE_IN (0x8) #define CODEC_F1C_DEVICE_AUX (0x9) #define CODEC_F1C_DEVICE_MIC (0xA) #define CODEC_F1C_DEVICE_PHONE (0xB) #define CODEC_F1C_DEVICE_SPDIF_IN (0xC) #define CODEC_F1C_DEVICE_RESERVED (0xE) #define CODEC_F1C_DEVICE_OTHER (0xF) /* Configuration default: Connection type */ #define CODEC_F1C_CONNECTION_TYPE_MASK (0xF) #define CODEC_F1C_CONNECTION_TYPE_SHIFT (16) #define CODEC_F1C_CONNECTION_TYPE_UNKNOWN (0) #define CODEC_F1C_CONNECTION_TYPE_1_8INCHES (0x1) #define CODEC_F1C_CONNECTION_TYPE_1_4INCHES (0x2) #define CODEC_F1C_CONNECTION_TYPE_ATAPI (0x3) #define CODEC_F1C_CONNECTION_TYPE_RCA (0x4) #define CODEC_F1C_CONNECTION_TYPE_OPTICAL (0x5) #define CODEC_F1C_CONNECTION_TYPE_OTHER_DIGITAL (0x6) #define CODEC_F1C_CONNECTION_TYPE_ANALOG (0x7) #define CODEC_F1C_CONNECTION_TYPE_DIN (0x8) #define CODEC_F1C_CONNECTION_TYPE_XLR (0x9) #define CODEC_F1C_CONNECTION_TYPE_RJ_11 (0xA) #define CODEC_F1C_CONNECTION_TYPE_COMBO (0xB) #define CODEC_F1C_CONNECTION_TYPE_OTHER (0xF) /* Configuration's color */ #define CODEC_F1C_COLOR_MASK (0xF) #define CODEC_F1C_COLOR_SHIFT (12) #define CODEC_F1C_COLOR_UNKNOWN (0) #define CODEC_F1C_COLOR_BLACK (0x1) #define CODEC_F1C_COLOR_GREY (0x2) #define CODEC_F1C_COLOR_BLUE (0x3) #define CODEC_F1C_COLOR_GREEN (0x4) #define CODEC_F1C_COLOR_RED (0x5) #define CODEC_F1C_COLOR_ORANGE (0x6) #define CODEC_F1C_COLOR_YELLOW (0x7) #define CODEC_F1C_COLOR_PURPLE (0x8) #define CODEC_F1C_COLOR_PINK (0x9) #define CODEC_F1C_COLOR_RESERVED_0 (0xA) #define CODEC_F1C_COLOR_RESERVED_1 (0xB) #define CODEC_F1C_COLOR_RESERVED_2 (0xC) #define CODEC_F1C_COLOR_RESERVED_3 (0xD) #define CODEC_F1C_COLOR_WHITE (0xE) #define CODEC_F1C_COLOR_OTHER (0xF) /* Configuration's misc */ #define CODEC_F1C_MISC_MASK (0xF) #define CODEC_F1C_MISC_SHIFT (8) #define CODEC_F1C_MISC_JACK_DETECT (0) #define CODEC_F1C_MISC_RESERVED_0 (1) #define CODEC_F1C_MISC_RESERVED_1 (2) #define CODEC_F1C_MISC_RESERVED_2 (3) /* Configuration default: Association */ #define CODEC_F1C_ASSOCIATION_MASK (0xF) #define CODEC_F1C_ASSOCIATION_SHIFT (4) /* Reserved; don't use. */ #define CODEC_F1C_ASSOCIATION_INVALID 0x0 #define CODEC_F1C_ASSOCIATION_GROUP_0 0x1 #define CODEC_F1C_ASSOCIATION_GROUP_1 0x2 #define CODEC_F1C_ASSOCIATION_GROUP_2 0x3 #define CODEC_F1C_ASSOCIATION_GROUP_3 0x4 #define CODEC_F1C_ASSOCIATION_GROUP_4 0x5 #define CODEC_F1C_ASSOCIATION_GROUP_5 0x6 #define CODEC_F1C_ASSOCIATION_GROUP_6 0x7 #define CODEC_F1C_ASSOCIATION_GROUP_7 0x8 #define CODEC_F1C_ASSOCIATION_GROUP_15 0xF /* Configuration default: Association Sequence */ #define CODEC_F1C_SEQ_MASK (0xF) #define CODEC_F1C_SEQ_SHIFT (0) /* Implementation identification (7.3.3.30) */ #define CODEC_MAKE_F20(bmid, bsku, aid) \ ( (((bmid) & 0xFFFF) << 16) \ | (((bsku) & 0xFF) << 8) \ | (((aid) & 0xFF)) \ ) /* macro definition helping in filling the configuration registers. */ #define CODEC_MAKE_F1C(port_connectivity, location, device, connection_type, color, misc, association, sequence) \ ( ((port_connectivity) << CODEC_F1C_PORT_SHIFT) \ | ((location) << CODEC_F1C_LOCATION_SHIFT) \ | ((device) << CODEC_F1C_DEVICE_SHIFT) \ | ((connection_type) << CODEC_F1C_CONNECTION_TYPE_SHIFT) \ | ((color) << CODEC_F1C_COLOR_SHIFT) \ | ((misc) << CODEC_F1C_MISC_SHIFT) \ | ((association) << CODEC_F1C_ASSOCIATION_SHIFT) \ | ((sequence))) /********************************************************************************************************************************* * Structures and Typedefs * *********************************************************************************************************************************/ /** The F00 parameter length (in dwords). */ #define CODECNODE_F00_PARAM_LENGTH 20 /** The F02 parameter length (in dwords). */ #define CODECNODE_F02_PARAM_LENGTH 16 /** * Common (or core) codec node structure. */ typedef struct CODECCOMMONNODE { /** Node id - 7 bit format */ uint8_t id; /** The node name. */ char const *pszName; /* PRM 5.3.6 */ uint32_t au32F00_param[CODECNODE_F00_PARAM_LENGTH]; uint32_t au32F02_param[CODECNODE_F02_PARAM_LENGTH]; } CODECCOMMONNODE; typedef CODECCOMMONNODE *PCODECCOMMONNODE; AssertCompile(CODECNODE_F00_PARAM_LENGTH == 20); /* saved state */ AssertCompile(CODECNODE_F02_PARAM_LENGTH == 16); /* saved state */ /** * Compile time assertion on the expected node size. */ #define AssertNodeSize(a_Node, a_cParams) \ AssertCompile((a_cParams) <= (60 + 6)); /* the max size - saved state */ \ AssertCompile( sizeof(a_Node) - sizeof(CODECCOMMONNODE) \ == (((a_cParams) * sizeof(uint32_t) + sizeof(void *) - 1) & ~(sizeof(void *) - 1)) ) typedef struct ROOTCODECNODE { CODECCOMMONNODE node; } ROOTCODECNODE, *PROOTCODECNODE; AssertNodeSize(ROOTCODECNODE, 0); #define AMPLIFIER_SIZE 60 typedef uint32_t AMPLIFIER[AMPLIFIER_SIZE]; #define AMPLIFIER_IN 0 #define AMPLIFIER_OUT 1 #define AMPLIFIER_LEFT 1 #define AMPLIFIER_RIGHT 0 #define AMPLIFIER_REGISTER(amp, inout, side, index) ((amp)[30*(inout) + 15*(side) + (index)]) typedef struct DACNODE { CODECCOMMONNODE node; uint32_t u32F0d_param; uint32_t u32F04_param; uint32_t u32F05_param; uint32_t u32F06_param; uint32_t u32F0c_param; uint32_t u32A_param; AMPLIFIER B_params; } DACNODE, *PDACNODE; AssertNodeSize(DACNODE, 6 + 60); typedef struct ADCNODE { CODECCOMMONNODE node; uint32_t u32F03_param; uint32_t u32F05_param; uint32_t u32F06_param; uint32_t u32F09_param; uint32_t u32A_param; uint32_t u32F01_param; AMPLIFIER B_params; } ADCNODE, *PADCNODE; AssertNodeSize(DACNODE, 6 + 60); typedef struct SPDIFOUTNODE { CODECCOMMONNODE node; uint32_t u32F05_param; uint32_t u32F06_param; uint32_t u32F09_param; uint32_t u32F0d_param; uint32_t u32A_param; AMPLIFIER B_params; } SPDIFOUTNODE, *PSPDIFOUTNODE; AssertNodeSize(SPDIFOUTNODE, 5 + 60); typedef struct SPDIFINNODE { CODECCOMMONNODE node; uint32_t u32F05_param; uint32_t u32F06_param; uint32_t u32F09_param; uint32_t u32F0d_param; uint32_t u32A_param; AMPLIFIER B_params; } SPDIFINNODE, *PSPDIFINNODE; AssertNodeSize(SPDIFINNODE, 5 + 60); typedef struct AFGCODECNODE { CODECCOMMONNODE node; uint32_t u32F05_param; uint32_t u32F08_param; uint32_t u32F20_param; uint32_t u32F17_param; } AFGCODECNODE, *PAFGCODECNODE; AssertNodeSize(AFGCODECNODE, 4); typedef struct PORTNODE { CODECCOMMONNODE node; uint32_t u32F07_param; uint32_t u32F08_param; uint32_t u32F09_param; uint32_t u32F01_param; uint32_t u32F1c_param; AMPLIFIER B_params; } PORTNODE, *PPORTNODE; AssertNodeSize(PORTNODE, 5 + 60); typedef struct DIGOUTNODE { CODECCOMMONNODE node; uint32_t u32F01_param; uint32_t u32F08_param; uint32_t u32F07_param; uint32_t u32F09_param; uint32_t u32F1c_param; } DIGOUTNODE, *PDIGOUTNODE; AssertNodeSize(DIGOUTNODE, 5); typedef struct DIGINNODE { CODECCOMMONNODE node; uint32_t u32F05_param; uint32_t u32F07_param; uint32_t u32F08_param; uint32_t u32F09_param; uint32_t u32F0c_param; uint32_t u32F1c_param; uint32_t u32F1e_param; } DIGINNODE, *PDIGINNODE; AssertNodeSize(DIGINNODE, 7); typedef struct ADCMUXNODE { CODECCOMMONNODE node; uint32_t u32F01_param; uint32_t u32A_param; AMPLIFIER B_params; } ADCMUXNODE, *PADCMUXNODE; AssertNodeSize(ADCMUXNODE, 2 + 60); typedef struct PCBEEPNODE { CODECCOMMONNODE node; uint32_t u32F07_param; uint32_t u32F0a_param; uint32_t u32A_param; AMPLIFIER B_params; uint32_t u32F1c_param; } PCBEEPNODE, *PPCBEEPNODE; AssertNodeSize(PCBEEPNODE, 3 + 60 + 1); typedef struct CDNODE { CODECCOMMONNODE node; uint32_t u32F07_param; uint32_t u32F1c_param; } CDNODE, *PCDNODE; AssertNodeSize(CDNODE, 2); typedef struct VOLUMEKNOBNODE { CODECCOMMONNODE node; uint32_t u32F08_param; uint32_t u32F0f_param; } VOLUMEKNOBNODE, *PVOLUMEKNOBNODE; AssertNodeSize(VOLUMEKNOBNODE, 2); typedef struct ADCVOLNODE { CODECCOMMONNODE node; uint32_t u32F0c_param; uint32_t u32F01_param; uint32_t u32A_params; AMPLIFIER B_params; } ADCVOLNODE, *PADCVOLNODE; AssertNodeSize(ADCVOLNODE, 3 + 60); typedef struct RESNODE { CODECCOMMONNODE node; uint32_t u32F05_param; uint32_t u32F06_param; uint32_t u32F07_param; uint32_t u32F1c_param; } RESNODE, *PRESNODE; AssertNodeSize(RESNODE, 4); /** * Used for the saved state. */ typedef struct CODECSAVEDSTATENODE { CODECCOMMONNODE Core; uint32_t au32Params[60 + 6]; } CODECSAVEDSTATENODE; AssertNodeSize(CODECSAVEDSTATENODE, 60 + 6); typedef union CODECNODE { CODECCOMMONNODE node; ROOTCODECNODE root; AFGCODECNODE afg; DACNODE dac; ADCNODE adc; SPDIFOUTNODE spdifout; SPDIFINNODE spdifin; PORTNODE port; DIGOUTNODE digout; DIGINNODE digin; ADCMUXNODE adcmux; PCBEEPNODE pcbeep; CDNODE cdnode; VOLUMEKNOBNODE volumeKnob; ADCVOLNODE adcvol; RESNODE reserved; CODECSAVEDSTATENODE SavedState; } CODECNODE, *PCODECNODE; AssertNodeSize(CODECNODE, 60 + 6); /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /* STAC9220 - Nodes IDs / names. */ #define STAC9220_NID_ROOT 0x0 /* Root node */ #define STAC9220_NID_AFG 0x1 /* Audio Configuration Group */ #define STAC9220_NID_DAC0 0x2 /* Out */ #define STAC9220_NID_DAC1 0x3 /* Out */ #define STAC9220_NID_DAC2 0x4 /* Out */ #define STAC9220_NID_DAC3 0x5 /* Out */ #define STAC9220_NID_ADC0 0x6 /* In */ #define STAC9220_NID_ADC1 0x7 /* In */ #define STAC9220_NID_SPDIF_OUT 0x8 /* Out */ #define STAC9220_NID_SPDIF_IN 0x9 /* In */ #define STAC9220_NID_PIN_HEADPHONE0 0xA /* In, Out */ #define STAC9220_NID_PIN_B 0xB /* In, Out */ #define STAC9220_NID_PIN_C 0xC /* In, Out */ #define STAC9220_NID_PIN_HEADPHONE1 0xD /* In, Out */ #define STAC9220_NID_PIN_E 0xE /* In */ #define STAC9220_NID_PIN_F 0xF /* In, Out */ #define STAC9220_NID_PIN_SPDIF_OUT 0x10 /* Out */ #define STAC9220_NID_PIN_SPDIF_IN 0x11 /* In */ #define STAC9220_NID_ADC0_MUX 0x12 /* In */ #define STAC9220_NID_ADC1_MUX 0x13 /* In */ #define STAC9220_NID_PCBEEP 0x14 /* Out */ #define STAC9220_NID_PIN_CD 0x15 /* In */ #define STAC9220_NID_VOL_KNOB 0x16 #define STAC9220_NID_AMP_ADC0 0x17 /* In */ #define STAC9220_NID_AMP_ADC1 0x18 /* In */ /* STAC9221. */ #define STAC9221_NID_ADAT_OUT 0x19 /* Out */ #define STAC9221_NID_I2S_OUT 0x1A /* Out */ #define STAC9221_NID_PIN_I2S_OUT 0x1B /* Out */ #if 1 /* STAC9220 - Referenced thru STAC9220WIDGET in the constructor below. */ static uint8_t const g_abStac9220Ports[] = { 0x0A, 0xB, 0xC, 0xD, 0xE, 0xF, 0}; static uint8_t const g_abStac9220Dacs[] = { 0x02, 0x3, 0x4, 0x5, 0}; static uint8_t const g_abStac9220Adcs[] = { 0x06, 0x7, 0}; static uint8_t const g_abStac9220SpdifOuts[] = { 0x08, 0 }; static uint8_t const g_abStac9220SpdifIns[] = { 0x09, 0 }; static uint8_t const g_abStac9220DigOutPins[] = { 0x10, 0 }; static uint8_t const g_abStac9220DigInPins[] = { 0x11, 0 }; static uint8_t const g_abStac9220AdcVols[] = { 0x17, 0x18, 0}; static uint8_t const g_abStac9220AdcMuxs[] = { 0x12, 0x13, 0}; static uint8_t const g_abStac9220Pcbeeps[] = { 0x14, 0 }; static uint8_t const g_abStac9220Cds[] = { 0x15, 0 }; static uint8_t const g_abStac9220VolKnobs[] = { 0x16, 0 }; static uint8_t const g_abStac9220Reserveds[] = { 0x09, 0x19, 0x1a, 0x1b, 0 }; #else /** @todo Enable this after 5.0 -- needs more testing first. */ static uint8_t const g_abStac9220Ports[] = { STAC9220_NID_PIN_HEADPHONE0, STAC9220_NID_PIN_B, STAC9220_NID_PIN_C, STAC9220_NID_PIN_HEADPHONE1, STAC9220_NID_PIN_E, STAC9220_NID_PIN_F, 0}; static uint8_t const g_abStac9220Dacs[] = { STAC9220_NID_DAC0, STAC9220_NID_DAC1, STAC9220_NID_DAC2, STAC9220_NID_DAC3, 0}; static uint8_t const g_abStac9220Adcs[] = { STAC9220_NID_ADC0, STAC9220_NID_ADC1, 0}; static uint8_t const g_abStac9220SpdifOuts[] = { STAC9220_NID_SPDIF_OUT, 0 }; static uint8_t const g_abStac9220SpdifIns[] = { STAC9220_NID_SPDIF_IN, 0 }; static uint8_t const g_abStac9220DigOutPins[] = { STAC9220_NID_PIN_SPDIF_OUT, 0 }; static uint8_t const g_abStac9220DigInPins[] = { STAC9220_NID_PIN_SPDIF_IN, 0 }; static uint8_t const g_abStac9220AdcVols[] = { STAC9220_NID_AMP_ADC0, STAC9220_NID_AMP_ADC1, 0}; static uint8_t const g_abStac9220AdcMuxs[] = { STAC9220_NID_ADC0_MUX, STAC9220_NID_ADC1_MUX, 0}; static uint8_t const g_abStac9220Pcbeeps[] = { STAC9220_NID_PCBEEP, 0 }; static uint8_t const g_abStac9220Cds[] = { STAC9220_NID_PIN_CD, 0 }; static uint8_t const g_abStac9220VolKnobs[] = { STAC9220_NID_VOL_KNOB, 0 }; /* STAC 9221. */ /** @todo Is STAC9220_NID_SPDIF_IN really correct for reserved nodes? */ static uint8_t const g_abStac9220Reserveds[] = { STAC9220_NID_SPDIF_IN, STAC9221_NID_ADAT_OUT, STAC9221_NID_I2S_OUT, STAC9221_NID_PIN_I2S_OUT, 0 }; #endif /** SSM description of a CODECNODE. */ static SSMFIELD const g_aCodecNodeFields[] = { SSMFIELD_ENTRY( CODECSAVEDSTATENODE, Core.id), SSMFIELD_ENTRY_PAD_HC_AUTO(3, 3), SSMFIELD_ENTRY( CODECSAVEDSTATENODE, Core.au32F00_param), SSMFIELD_ENTRY( CODECSAVEDSTATENODE, Core.au32F02_param), SSMFIELD_ENTRY( CODECSAVEDSTATENODE, au32Params), SSMFIELD_ENTRY_TERM() }; /** Backward compatibility with v1 of the CODECNODE. */ static SSMFIELD const g_aCodecNodeFieldsV1[] = { SSMFIELD_ENTRY( CODECSAVEDSTATENODE, Core.id), SSMFIELD_ENTRY_PAD_HC_AUTO(3, 7), SSMFIELD_ENTRY_OLD_HCPTR(Core.name), SSMFIELD_ENTRY( CODECSAVEDSTATENODE, Core.au32F00_param), SSMFIELD_ENTRY( CODECSAVEDSTATENODE, Core.au32F02_param), SSMFIELD_ENTRY( CODECSAVEDSTATENODE, au32Params), SSMFIELD_ENTRY_TERM() }; static DECLCALLBACK(void) stac9220DbgNodes(PHDACODEC pThis, PCDBGFINFOHLP pHlp, const char *pszArgs) { for (int i = 1; i < 12; i++) { PCODECNODE pNode = &pThis->paNodes[i]; AMPLIFIER *pAmp = &pNode->dac.B_params; uint8_t lVol = AMPLIFIER_REGISTER(*pAmp, AMPLIFIER_OUT, AMPLIFIER_LEFT, 0) & 0x7f; uint8_t rVol = AMPLIFIER_REGISTER(*pAmp, AMPLIFIER_OUT, AMPLIFIER_RIGHT, 0) & 0x7f; pHlp->pfnPrintf(pHlp, "0x%x: lVol=%RU8, rVol=%RU8\n", i, lVol, rVol); } } static DECLCALLBACK(int) stac9220ResetNode(PHDACODEC pThis, uint8_t nodenum, PCODECNODE pNode) { pNode->node.id = nodenum; pNode->node.au32F00_param[0xF] = 0; /* Power statest Supported: are the same as AFG reports */ switch (nodenum) { /* Root Node*/ case 0: pNode->node.au32F00_param[0x02] = CODEC_MAKE_F00_02(0x1, 0x0, 0x34, 0x1); /* rev id */ break; case 1: pNode->node.au32F00_param[0x08] = CODEC_MAKE_F00_08(1, 0xd, 0xd); pNode->node.au32F00_param[0x0C] = CODEC_MAKE_F00_0C(0x17) | CODEC_F00_0C_CAP_BALANCED_IO | CODEC_F00_0C_CAP_INPUT | CODEC_F00_0C_CAP_PRESENSE_DETECT | CODEC_F00_0C_CAP_TRIGGER_REQUIRED | CODEC_F00_0C_CAP_IMPENDANCE_SENSE;//(17 << 8)|RT_BIT(6)|RT_BIT(5)|RT_BIT(2)|RT_BIT(1)|RT_BIT(0); pNode->node.au32F00_param[0x0B] = CODEC_F00_0B_PCM; pNode->node.au32F00_param[0x0D] = CODEC_MAKE_F00_0D(1, 0x5, 0xE, 0);//RT_BIT(31)|(0x5 << 16)|(0xE)<<8; pNode->node.au32F00_param[0x12] = RT_BIT(31)|(0x2 << 16)|(0x7f << 8)|0x7f; pNode->node.au32F00_param[0x11] = CODEC_MAKE_F00_11(1, 1, 0, 0, 4);//0xc0000004; pNode->node.au32F00_param[0x0F] = CODEC_F00_0F_D3|CODEC_F00_0F_D2|CODEC_F00_0F_D1|CODEC_F00_0F_D0; pNode->afg.u32F05_param = CODEC_MAKE_F05(0, 0, 0, CODEC_F05_D2, CODEC_F05_D2);//0x2 << 4| 0x2; /* PS-Act: D3, PS->Set D3 */ pNode->afg.u32F08_param = 0; pNode->afg.u32F17_param = 0; break; case 2: case 3: case 4: case 5: memset(pNode->dac.B_params, 0, AMPLIFIER_SIZE); pNode->dac.u32A_param = CODEC_MAKE_A(0, 1, CODEC_A_MULT_1X, CODEC_A_DIV_1X, CODEC_A_16_BIT, 1);//RT_BIT(14)|(0x1 << 4)|0x1; /* 44100Hz/16bit/2ch */ AMPLIFIER_REGISTER(pNode->dac.B_params, AMPLIFIER_OUT, AMPLIFIER_LEFT, 0) = 0x7F | RT_BIT(7); AMPLIFIER_REGISTER(pNode->dac.B_params, AMPLIFIER_OUT, AMPLIFIER_RIGHT, 0) = 0x7F | RT_BIT(7); pNode->dac.node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_AUDIO_OUTPUT, 0xD, 0) | CODEC_F00_09_CAP_L_R_SWAP | CODEC_F00_09_CAP_POWER_CTRL | CODEC_F00_09_CAP_OUT_AMP_PRESENT | CODEC_F00_09_CAP_LSB;//(0xD << 16) | RT_BIT(11) | RT_BIT(10) | RT_BIT(2) | RT_BIT(0); pNode->dac.u32F0c_param = 0; pNode->dac.u32F05_param = CODEC_MAKE_F05(0, 0, 0, CODEC_F05_D3, CODEC_F05_D3);//0x3 << 4 | 0x3; /* PS-Act: D3, Set: D3 */ break; case 6: pNode->node.au32F02_param[0] = 0x17; goto adc_init; case 7: pNode->node.au32F02_param[0] = 0x18; adc_init: pNode->adc.u32A_param = CODEC_MAKE_A(0, 1, CODEC_A_MULT_1X, CODEC_A_DIV_1X, CODEC_A_16_BIT, 1);//RT_BIT(14)|(0x1 << 3)|0x1; /* 44100Hz/16bit/2ch */ pNode->adc.node.au32F00_param[0xE] = CODEC_MAKE_F00_0E(0, 1);//RT_BIT(0); pNode->adc.u32F03_param = RT_BIT(0); pNode->adc.u32F05_param = CODEC_MAKE_F05(0, 0, 0, CODEC_F05_D3, CODEC_F05_D3);//0x3 << 4 | 0x3; /* PS-Act: D3 Set: D3 */ pNode->adc.u32F06_param = 0; pNode->adc.node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_AUDIO_INPUT, 0xD, 0) | CODEC_F00_09_CAP_POWER_CTRL | CODEC_F00_09_CAP_CONNECTION_LIST | CODEC_F00_09_CAP_PROC_WIDGET | CODEC_F00_09_CAP_LSB;//RT_BIT(20)| (0xd << 16) | RT_BIT(10) | RT_BIT(8) | RT_BIT(6)| RT_BIT(0); break; case 8: pNode->spdifout.u32A_param = CODEC_MAKE_A(0, 1, CODEC_A_MULT_1X, CODEC_A_DIV_1X, CODEC_A_16_BIT, 1);//(1<<14)|(0x1<<4) | 0x1; pNode->spdifout.node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_AUDIO_OUTPUT, 0x4, 0) | CODEC_F00_09_CAP_DIGITAL | CODEC_F00_09_CAP_FMT_OVERRIDE | CODEC_F00_09_CAP_LSB;//(4 << 16) | RT_BIT(9)|RT_BIT(4)|0x1; pNode->node.au32F00_param[0xa] = pThis->paNodes[1].node.au32F00_param[0xA]; pNode->spdifout.node.au32F00_param[0xB] = CODEC_F00_0B_PCM; pNode->spdifout.u32F06_param = 0; pNode->spdifout.u32F0d_param = 0; break; case 9: pNode->spdifin.u32A_param = CODEC_MAKE_A(0, 1, CODEC_A_MULT_1X, CODEC_A_DIV_1X, CODEC_A_16_BIT, 1);//(0x1<<4) | 0x1; pNode->spdifin.node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_AUDIO_INPUT, 0x4, 0) | CODEC_F00_09_CAP_DIGITAL | CODEC_F00_09_CAP_CONNECTION_LIST | CODEC_F00_09_CAP_FMT_OVERRIDE | CODEC_F00_09_CAP_LSB;//(0x1 << 20)|(4 << 16) | RT_BIT(9)| RT_BIT(8)|RT_BIT(4)|0x1; pNode->node.au32F00_param[0xA] = pThis->paNodes[1].node.au32F00_param[0xA]; pNode->node.au32F00_param[0xE] = CODEC_MAKE_F00_0E(0, 1);//RT_BIT(0); pNode->node.au32F02_param[0] = 0x11; pNode->spdifin.node.au32F00_param[0xB] = CODEC_F00_0B_PCM; pNode->spdifin.u32F06_param = 0; pNode->spdifin.u32F0d_param = 0; break; case 0xA: pNode->node.au32F00_param[0xC] = CODEC_MAKE_F00_0C(0x17) | CODEC_F00_0C_CAP_INPUT | CODEC_F00_0C_CAP_OUTPUT | CODEC_F00_0C_CAP_HP | CODEC_F00_0C_CAP_PRESENSE_DETECT | CODEC_F00_0C_CAP_TRIGGER_REQUIRED | CODEC_F00_0C_CAP_IMPENDANCE_SENSE;//0x173f; pNode->node.au32F02_param[0] = 0x2; pNode->port.u32F07_param = CODEC_F07_IN_ENABLE | CODEC_F07_OUT_ENABLE; pNode->port.u32F08_param = 0; if (!pThis->fInReset) pNode->port.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_COMPLEX, CODEC_F1C_LOCATION_FRONT, CODEC_F1C_DEVICE_HP, CODEC_F1C_CONNECTION_TYPE_1_8INCHES, CODEC_F1C_COLOR_GREEN, CODEC_F1C_MISC_JACK_DETECT, 0x2, 0);//RT_MAKE_U32_FROM_U8(0x20, 0x40, 0x21, 0x02); pNode->port.u32F09_param = CODEC_MAKE_F09_ANALOG(0, CODEC_F09_ANALOG_NA);//0x7fffffff; goto port_init; case 0xB: pNode->node.au32F00_param[0xC] = CODEC_MAKE_F00_0C(0x17) | CODEC_F00_0C_CAP_INPUT | CODEC_F00_0C_CAP_OUTPUT | CODEC_F00_0C_CAP_PRESENSE_DETECT | CODEC_F00_0C_CAP_TRIGGER_REQUIRED | CODEC_F00_0C_CAP_IMPENDANCE_SENSE;//0x1737; pNode->node.au32F02_param[0] = 0x4; pNode->port.u32F07_param = CODEC_F07_IN_ENABLE; if (!pThis->fInReset) pNode->port.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_COMPLEX, CODEC_F1C_LOCATION_INTERNAL|CODEC_F1C_LOCATION_REAR, CODEC_F1C_DEVICE_SPEAKER, CODEC_F1C_CONNECTION_TYPE_1_8INCHES, CODEC_F1C_COLOR_BLACK, CODEC_F1C_MISC_JACK_DETECT, 0x1, 0x1);//RT_MAKE_U32_FROM_U8(0x11, 0x60, 0x11, 0x01); pNode->port.u32F09_param = CODEC_MAKE_F09_ANALOG(1, CODEC_F09_ANALOG_NA);//RT_BIT(31)|0x7fffffff; goto port_init; case 0xC: pNode->node.au32F02_param[0] = 0x3; pNode->node.au32F00_param[0xC] = CODEC_MAKE_F00_0C(0x17) | CODEC_F00_0C_CAP_INPUT | CODEC_F00_0C_CAP_OUTPUT | CODEC_F00_0C_CAP_PRESENSE_DETECT | CODEC_F00_0C_CAP_TRIGGER_REQUIRED | CODEC_F00_0C_CAP_IMPENDANCE_SENSE;//0x1737; pNode->port.u32F07_param = CODEC_F07_IN_ENABLE; if (!pThis->fInReset) pNode->port.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_COMPLEX, CODEC_F1C_LOCATION_REAR, CODEC_F1C_DEVICE_SPEAKER, CODEC_F1C_CONNECTION_TYPE_1_8INCHES, CODEC_F1C_COLOR_GREEN, 0x0, 0x1, 0x0);//RT_MAKE_U32_FROM_U8(0x10, 0x40, 0x11, 0x01); pNode->port.u32F09_param = CODEC_MAKE_F09_ANALOG(1, CODEC_F09_ANALOG_NA);//RT_BIT(31)|0x7fffffff; goto port_init; case 0xD: pNode->node.au32F00_param[0xC] = CODEC_MAKE_F00_0C(0x17) | CODEC_F00_0C_CAP_INPUT | CODEC_F00_0C_CAP_OUTPUT | CODEC_F00_0C_CAP_PRESENSE_DETECT | CODEC_F00_0C_CAP_TRIGGER_REQUIRED | CODEC_F00_0C_CAP_IMPENDANCE_SENSE;//0x1737; pNode->port.u32F07_param = CODEC_F07_IN_ENABLE; pNode->node.au32F02_param[0] = 0x2; if (!pThis->fInReset) pNode->port.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_COMPLEX, CODEC_F1C_LOCATION_FRONT, CODEC_F1C_DEVICE_MIC, CODEC_F1C_CONNECTION_TYPE_1_8INCHES, CODEC_F1C_COLOR_PINK, 0x0, 0x5, 0x0);//RT_MAKE_U32_FROM_U8(0x50, 0x90, 0xA1, 0x02); /* Microphone */ pNode->port.u32F09_param = CODEC_MAKE_F09_ANALOG(1, CODEC_F09_ANALOG_NA);//RT_BIT(31)|0x7fffffff; port_init: pNode->port.u32F08_param = 0; pNode->node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_PIN_COMPLEX, 0x0, 0) | CODEC_F00_09_CAP_CONNECTION_LIST | CODEC_F00_09_CAP_UNSOL | CODEC_F00_09_CAP_LSB;//(4 << 20)|RT_BIT(8)|RT_BIT(7)|RT_BIT(0); pNode->node.au32F00_param[0xE] = CODEC_MAKE_F00_0E(0, 1);//0x1; break; case 0xE: pNode->node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_PIN_COMPLEX, 0x0, 0) | CODEC_F00_09_CAP_UNSOL | CODEC_F00_09_CAP_LSB;//(4 << 20)|RT_BIT(7)|RT_BIT(0); pNode->port.u32F08_param = 0; pNode->node.au32F00_param[0xC] = CODEC_F00_0C_CAP_INPUT | CODEC_F00_0C_CAP_OUTPUT | CODEC_F00_0C_CAP_PRESENSE_DETECT;//0x34; pNode->port.u32F07_param = CODEC_F07_IN_ENABLE; pNode->port.u32F09_param = CODEC_MAKE_F09_ANALOG(0, CODEC_F09_ANALOG_NA);//0x7fffffff; if (!pThis->fInReset) pNode->port.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_COMPLEX, CODEC_F1C_LOCATION_REAR, CODEC_F1C_DEVICE_LINE_OUT, CODEC_F1C_CONNECTION_TYPE_1_8INCHES, CODEC_F1C_COLOR_BLUE, 0x0, 0x4, 0x0);//0x01013040; /* Line Out */ break; case 0xF: pNode->node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_PIN_COMPLEX, 0x0, 0x0) | CODEC_F00_09_CAP_CONNECTION_LIST | CODEC_F00_09_CAP_UNSOL | CODEC_F00_09_CAP_OUT_AMP_PRESENT | CODEC_F00_09_CAP_LSB;//(4 << 20)|RT_BIT(8)|RT_BIT(7)|RT_BIT(2)|RT_BIT(0); pNode->node.au32F00_param[0xC] = CODEC_F00_0C_CAP_INPUT | CODEC_F00_0C_CAP_OUTPUT | CODEC_F00_0C_CAP_PRESENSE_DETECT /* | CODEC_F00_0C_CAP_TRIGGER_REQUIRED | CODEC_F00_0C_CAP_IMPENDANCE_SENSE */;//0x37; pNode->node.au32F00_param[0xE] = CODEC_MAKE_F00_0E(0, 1);//0x1; pNode->port.u32F08_param = 0; pNode->port.u32F07_param = CODEC_F07_OUT_ENABLE | CODEC_F07_IN_ENABLE; if (!pThis->fInReset) pNode->port.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_COMPLEX, CODEC_F1C_LOCATION_INTERNAL, CODEC_F1C_DEVICE_SPEAKER, CODEC_F1C_CONNECTION_TYPE_1_8INCHES, CODEC_F1C_COLOR_ORANGE, 0x0, 0x1, 0x2);//RT_MAKE_U32_FROM_U8(0x12, 0x60, 0x11, 0x01); pNode->node.au32F02_param[0] = 0x5; pNode->port.u32F09_param = CODEC_MAKE_F09_ANALOG(0, CODEC_F09_ANALOG_NA);//0x7fffffff; break; case 0x10: pNode->node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_PIN_COMPLEX, 0x0, 0x0) | CODEC_F00_09_CAP_DIGITAL | CODEC_F00_09_CAP_CONNECTION_LIST | CODEC_F00_09_CAP_LSB;//(4<<20)|RT_BIT(9)|RT_BIT(8)|RT_BIT(0); pNode->node.au32F00_param[0xC] = CODEC_F00_0C_CAP_OUTPUT;//RT_BIT(4); pNode->node.au32F00_param[0xE] = CODEC_MAKE_F00_0E(0, 0x3); pNode->node.au32F02_param[0] = RT_MAKE_U32_FROM_U8(0x08, 0x17, 0x19, 0); if (!pThis->fInReset) pNode->digout.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_COMPLEX, CODEC_F1C_LOCATION_REAR, CODEC_F1C_DEVICE_SPDIF_OUT, CODEC_F1C_CONNECTION_TYPE_DIN, CODEC_F1C_COLOR_BLACK, 0x0, 0x3, 0x0);//RT_MAKE_U32_FROM_U8(0x30, 0x10, 0x45, 0x01); break; case 0x11: pNode->node.au32F00_param[9] = (4 << 20) | (3 << 16) | RT_BIT(10) | RT_BIT(9) | RT_BIT(7) | RT_BIT(0); pNode->node.au32F00_param[0xC] = CODEC_F00_0C_CAP_EAPD | CODEC_F00_0C_CAP_INPUT | CODEC_F00_0C_CAP_PRESENSE_DETECT;//RT_BIT(16)| RT_BIT(5)|RT_BIT(2); pNode->digin.u32F05_param = CODEC_MAKE_F05(0, 0, 0, CODEC_F05_D3, CODEC_F05_D3);//0x3 << 4 | 0x3; /* PS-Act: D3 -> D3 */ pNode->digin.u32F07_param = 0; pNode->digin.u32F08_param = 0; pNode->digin.u32F09_param = CODEC_MAKE_F09_DIGITAL(0, 0); pNode->digin.u32F0c_param = 0; if (!pThis->fInReset) pNode->digin.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_COMPLEX, CODEC_F1C_LOCATION_REAR, CODEC_F1C_DEVICE_SPDIF_IN, CODEC_F1C_CONNECTION_TYPE_OTHER_DIGITAL, CODEC_F1C_COLOR_BLACK, 0x0, 0x6, 0x0);//(0x1 << 24) | (0xc5 << 16) | (0x10 << 8) | 0x60; break; case 0x12: pNode->adcmux.u32F01_param = 0; goto adcmux_init; case 0x13: pNode->adcmux.u32F01_param = 1; adcmux_init: pNode->node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_AUDIO_SELECTOR, 0x0, 0) | CODEC_F00_09_CAP_CONNECTION_LIST | CODEC_F00_09_CAP_AMP_FMT_OVERRIDE | CODEC_F00_09_CAP_OUT_AMP_PRESENT | CODEC_F00_09_CAP_LSB;//(3<<20)|RT_BIT(8)|RT_BIT(3)|RT_BIT(2)|RT_BIT(0); pNode->node.au32F00_param[0xe] = CODEC_MAKE_F00_0E(0, 0x7); pNode->node.au32F00_param[0x12] = (0x27 << 16)|(0x4 << 8); /* STAC 9220 v10 6.21-22.{4,5} both(left and right) out amplefiers inited with 0*/ memset(pNode->adcmux.B_params, 0, AMPLIFIER_SIZE); pNode->node.au32F02_param[0] = RT_MAKE_U32_FROM_U8(0xe, 0x15, 0xf, 0xb); pNode->node.au32F02_param[4] = RT_MAKE_U32_FROM_U8(0xc, 0xd, 0xa, 0x0); break; case 0x14: pNode->node.au32F00_param[9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_BEEP_GEN, 0, 0) | CODEC_F00_09_CAP_AMP_FMT_OVERRIDE | CODEC_F00_09_CAP_OUT_AMP_PRESENT;//(7 << 20) | RT_BIT(3) | RT_BIT(2); pNode->node.au32F00_param[0x12] = (0x17 << 16)|(0x3 << 8)| 0x3; pNode->pcbeep.u32F0a_param = 0; memset(pNode->pcbeep.B_params, 0, AMPLIFIER_SIZE); break; case 0x15: pNode->node.au32F00_param[0x9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_PIN_COMPLEX, 0, 0) | CODEC_F00_09_CAP_LSB;//(4 << 20)|RT_BIT(0); pNode->node.au32F00_param[0xc] = CODEC_F00_0C_CAP_INPUT;//RT_BIT(5); if (!pThis->fInReset) pNode->cdnode.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_FIXED, CODEC_F1C_LOCATION_INTERNAL, CODEC_F1C_DEVICE_CD, CODEC_F1C_CONNECTION_TYPE_ATAPI, CODEC_F1C_COLOR_UNKNOWN, 0x0, 0x7, 0x0);//RT_MAKE_U32_FROM_U8(0x70, 0x0, 0x33, 0x90); break; case 0x16: pNode->node.au32F00_param[0x9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_VOLUME_KNOB, 0x0, 0x0);//(0x6 << 20); pNode->node.au32F00_param[0x13] = RT_BIT(7)| 0x7F; pNode->node.au32F00_param[0xe] = CODEC_MAKE_F00_0E(0, 0x4); pNode->node.au32F02_param[0] = RT_MAKE_U32_FROM_U8(0x2, 0x3, 0x4, 0x5); pNode->volumeKnob.u32F08_param = 0; pNode->volumeKnob.u32F0f_param = 0x7f; break; case 0x17: pNode->node.au32F02_param[0] = 0x12; goto adcvol_init; case 0x18: pNode->node.au32F02_param[0] = 0x13; adcvol_init: memset(pNode->adcvol.B_params, 0, AMPLIFIER_SIZE); pNode->node.au32F00_param[0x9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_AUDIO_SELECTOR, 0, 0) | CODEC_F00_09_CAP_L_R_SWAP | CODEC_F00_09_CAP_CONNECTION_LIST | CODEC_F00_09_CAP_IN_AMP_PRESENT | CODEC_F00_09_CAP_LSB;//(0x3 << 20)|RT_BIT(11)|RT_BIT(8)|RT_BIT(1)|RT_BIT(0); pNode->node.au32F00_param[0xe] = CODEC_MAKE_F00_0E(0, 0x1); AMPLIFIER_REGISTER(pNode->adcvol.B_params, AMPLIFIER_IN, AMPLIFIER_LEFT, 0) = RT_BIT(7); AMPLIFIER_REGISTER(pNode->adcvol.B_params, AMPLIFIER_IN, AMPLIFIER_RIGHT, 0) = RT_BIT(7); pNode->adcvol.u32F0c_param = 0; break; case 0x19: pNode->node.au32F00_param[0x9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_VENDOR_DEFINED, 0x3, 0) | CODEC_F00_09_CAP_DIGITAL | CODEC_F00_09_CAP_LSB;//(0xF << 20)|(0x3 << 16)|RT_BIT(9)|RT_BIT(0); break; case 0x1A: pNode->node.au32F00_param[0x9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_AUDIO_OUTPUT, 0x3, 0) | CODEC_F00_09_CAP_DIGITAL | CODEC_F00_09_CAP_LSB;//(0x3 << 16)|RT_BIT(9)|RT_BIT(0); break; case 0x1B: pNode->node.au32F00_param[0x9] = CODEC_MAKE_F00_09(CODEC_F00_09_TYPE_PIN_COMPLEX, 0, 0) | CODEC_F00_09_CAP_DIGITAL | CODEC_F00_09_CAP_CONNECTION_LIST | CODEC_F00_09_CAP_LSB;//(0x4 << 20)|RT_BIT(9)|RT_BIT(8)|RT_BIT(0); pNode->node.au32F00_param[0xE] = CODEC_MAKE_F00_0E(0, 0x1); pNode->node.au32F00_param[0xC] = CODEC_F00_0C_CAP_OUTPUT;//0x10; pNode->node.au32F02_param[0] = 0x1a; pNode->reserved.u32F1c_param = CODEC_MAKE_F1C(CODEC_F1C_PORT_NO_PHYS, CODEC_F1C_LOCATION_NA, CODEC_F1C_DEVICE_LINE_OUT, CODEC_F1C_CONNECTION_TYPE_UNKNOWN, CODEC_F1C_COLOR_UNKNOWN, 0x0, 0x0, 0xf);//0x4000000f; break; default: break; } return VINF_SUCCESS; } static int stac9220Construct(PHDACODEC pThis) { unconst(pThis->cTotalNodes) = 0x1C; pThis->pfnCodecNodeReset = stac9220ResetNode; pThis->pfnDbgListNodes = stac9220DbgNodes; pThis->u16VendorId = 0x8384; pThis->u16DeviceId = 0x7680; pThis->u8BSKU = 0x76; pThis->u8AssemblyId = 0x80; pThis->paNodes = (PCODECNODE)RTMemAllocZ(sizeof(CODECNODE) * pThis->cTotalNodes); if (!pThis->paNodes) return VERR_NO_MEMORY; pThis->fInReset = false; #define STAC9220WIDGET(type) pThis->au8##type##s = g_abStac9220##type##s STAC9220WIDGET(Port); STAC9220WIDGET(Dac); STAC9220WIDGET(Adc); STAC9220WIDGET(AdcVol); STAC9220WIDGET(AdcMux); STAC9220WIDGET(Pcbeep); STAC9220WIDGET(SpdifIn); STAC9220WIDGET(SpdifOut); STAC9220WIDGET(DigInPin); STAC9220WIDGET(DigOutPin); STAC9220WIDGET(Cd); STAC9220WIDGET(VolKnob); STAC9220WIDGET(Reserved); #undef STAC9220WIDGET unconst(pThis->u8AdcVolsLineIn) = 0x17; unconst(pThis->u8DacLineOut) = 0x3; return VINF_SUCCESS; } /* * Some generic predicate functions. */ #define DECLISNODEOFTYPE(type) \ DECLINLINE(int) hdaCodecIs##type##Node(PHDACODEC pThis, uint8_t cNode) \ { \ Assert(pThis->au8##type##s); \ for (int i = 0; pThis->au8##type##s[i] != 0; ++i) \ if (pThis->au8##type##s[i] == cNode) \ return 1; \ return 0; \ } /* hdaCodecIsPortNode */ DECLISNODEOFTYPE(Port) /* hdaCodecIsDacNode */ DECLISNODEOFTYPE(Dac) /* hdaCodecIsAdcVolNode */ DECLISNODEOFTYPE(AdcVol) /* hdaCodecIsAdcNode */ DECLISNODEOFTYPE(Adc) /* hdaCodecIsAdcMuxNode */ DECLISNODEOFTYPE(AdcMux) /* hdaCodecIsPcbeepNode */ DECLISNODEOFTYPE(Pcbeep) /* hdaCodecIsSpdifOutNode */ DECLISNODEOFTYPE(SpdifOut) /* hdaCodecIsSpdifInNode */ DECLISNODEOFTYPE(SpdifIn) /* hdaCodecIsDigInPinNode */ DECLISNODEOFTYPE(DigInPin) /* hdaCodecIsDigOutPinNode */ DECLISNODEOFTYPE(DigOutPin) /* hdaCodecIsCdNode */ DECLISNODEOFTYPE(Cd) /* hdaCodecIsVolKnobNode */ DECLISNODEOFTYPE(VolKnob) /* hdaCodecIsReservedNode */ DECLISNODEOFTYPE(Reserved) /* * Misc helpers. */ static int hdaCodecToAudVolume(PHDACODEC pThis, AMPLIFIER *pAmp, PDMAUDIOMIXERCTL mt) { uint32_t dir = AMPLIFIER_OUT; ENMSOUNDSOURCE enmSrc; switch (mt) { case PDMAUDIOMIXERCTL_PCM: enmSrc = PO_INDEX; dir = AMPLIFIER_OUT; break; case PDMAUDIOMIXERCTL_LINE_IN: enmSrc = PI_INDEX; dir = AMPLIFIER_IN; break; default: AssertMsgFailedReturn(("Invalid mixer control %ld\n", mt), VERR_INVALID_PARAMETER); break; } int mute = AMPLIFIER_REGISTER(*pAmp, dir, AMPLIFIER_LEFT, 0) & RT_BIT(7); mute |= AMPLIFIER_REGISTER(*pAmp, dir, AMPLIFIER_RIGHT, 0) & RT_BIT(7); mute >>=7; mute &= 0x1; uint8_t lVol = AMPLIFIER_REGISTER(*pAmp, dir, AMPLIFIER_LEFT, 0) & 0x7f; uint8_t rVol = AMPLIFIER_REGISTER(*pAmp, dir, AMPLIFIER_RIGHT, 0) & 0x7f; /* The STAC9220 volume controls have 0 to -96dB attenuation range in 128 steps. * We have 0 to -96dB range in 256 steps. HDA volume setting of 127 must map * to 255 internally (0dB), while HDA volume setting of 0 (-96dB) should map * to 1 (rather than zero) internally. */ lVol = (lVol + 1) * (2 * 255) / 256; rVol = (rVol + 1) * (2 * 255) / 256; return pThis->pfnSetVolume(pThis->pHDAState, enmSrc, RT_BOOL(mute), lVol, rVol); } DECLINLINE(void) hdaCodecSetRegister(uint32_t *pu32Reg, uint32_t u32Cmd, uint8_t u8Offset, uint32_t mask) { Assert((pu32Reg && u8Offset < 32)); *pu32Reg &= ~(mask << u8Offset); *pu32Reg |= (u32Cmd & mask) << u8Offset; } DECLINLINE(void) hdaCodecSetRegisterU8(uint32_t *pu32Reg, uint32_t u32Cmd, uint8_t u8Offset) { hdaCodecSetRegister(pu32Reg, u32Cmd, u8Offset, CODEC_VERB_8BIT_DATA); } DECLINLINE(void) hdaCodecSetRegisterU16(uint32_t *pu32Reg, uint32_t u32Cmd, uint8_t u8Offset) { hdaCodecSetRegister(pu32Reg, u32Cmd, u8Offset, CODEC_VERB_16BIT_DATA); } /* * Verb processor functions. */ static DECLCALLBACK(int) vrbProcUnimplemented(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { LogFlowFunc(("cmd(raw:%x: cad:%x, d:%c, nid:%x, verb:%x)\n", cmd, CODEC_CAD(cmd), CODEC_DIRECT(cmd) ? 'N' : 'Y', CODEC_NID(cmd), CODEC_VERBDATA(cmd))); *pResp = 0; return VINF_SUCCESS; } static DECLCALLBACK(int) vrbProcBreak(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { int rc; rc = vrbProcUnimplemented(pThis, cmd, pResp); *pResp |= CODEC_RESPONSE_UNSOLICITED; return rc; } /* B-- */ static DECLCALLBACK(int) vrbProcGetAmplifier(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; /* HDA spec 7.3.3.7 Note A */ /** @todo: if index out of range response should be 0 */ uint8_t u8Index = CODEC_GET_AMP_DIRECTION(cmd) == AMPLIFIER_OUT? 0 : CODEC_GET_AMP_INDEX(cmd); PCODECNODE pNode = &pThis->paNodes[CODEC_NID(cmd)]; if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) *pResp = AMPLIFIER_REGISTER(pNode->dac.B_params, CODEC_GET_AMP_DIRECTION(cmd), CODEC_GET_AMP_SIDE(cmd), u8Index); else if (hdaCodecIsAdcVolNode(pThis, CODEC_NID(cmd))) *pResp = AMPLIFIER_REGISTER(pNode->adcvol.B_params, CODEC_GET_AMP_DIRECTION(cmd), CODEC_GET_AMP_SIDE(cmd), u8Index); else if (hdaCodecIsAdcMuxNode(pThis, CODEC_NID(cmd))) *pResp = AMPLIFIER_REGISTER(pNode->adcmux.B_params, CODEC_GET_AMP_DIRECTION(cmd), CODEC_GET_AMP_SIDE(cmd), u8Index); else if (hdaCodecIsPcbeepNode(pThis, CODEC_NID(cmd))) *pResp = AMPLIFIER_REGISTER(pNode->pcbeep.B_params, CODEC_GET_AMP_DIRECTION(cmd), CODEC_GET_AMP_SIDE(cmd), u8Index); else if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) *pResp = AMPLIFIER_REGISTER(pNode->port.B_params, CODEC_GET_AMP_DIRECTION(cmd), CODEC_GET_AMP_SIDE(cmd), u8Index); else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) *pResp = AMPLIFIER_REGISTER(pNode->adc.B_params, CODEC_GET_AMP_DIRECTION(cmd), CODEC_GET_AMP_SIDE(cmd), u8Index); else AssertMsgFailedReturn(("access to fields of %x need to be implemented\n", CODEC_NID(cmd)), VINF_SUCCESS); return VINF_SUCCESS; } /* 3-- */ static DECLCALLBACK(int) vrbProcSetAmplifier(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { bool fIsLeft = false; bool fIsRight = false; bool fIsOut = false; bool fIsIn = false; uint8_t u8Index = 0; Assert(CODEC_CAD(cmd) == pThis->id); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; PCODECNODE pNode = &pThis->paNodes[CODEC_NID(cmd)]; AMPLIFIER *pAmplifier; if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) pAmplifier = &pNode->dac.B_params; else if (hdaCodecIsAdcVolNode(pThis, CODEC_NID(cmd))) pAmplifier = &pNode->adcvol.B_params; else if (hdaCodecIsAdcMuxNode(pThis, CODEC_NID(cmd))) pAmplifier = &pNode->adcmux.B_params; else if (hdaCodecIsPcbeepNode(pThis, CODEC_NID(cmd))) pAmplifier = &pNode->pcbeep.B_params; else if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) pAmplifier = &pNode->port.B_params; else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) pAmplifier = &pNode->adc.B_params; else AssertFailedReturn(VINF_SUCCESS); fIsOut = CODEC_SET_AMP_IS_OUT_DIRECTION(cmd); fIsIn = CODEC_SET_AMP_IS_IN_DIRECTION(cmd); fIsRight = CODEC_SET_AMP_IS_RIGHT_SIDE(cmd); fIsLeft = CODEC_SET_AMP_IS_LEFT_SIDE(cmd); u8Index = CODEC_SET_AMP_INDEX(cmd); if ( (!fIsLeft && !fIsRight) || (!fIsOut && !fIsIn)) return VINF_SUCCESS; if (fIsIn) { if (fIsLeft) hdaCodecSetRegisterU8(&LIFIER_REGISTER(*pAmplifier, AMPLIFIER_IN, AMPLIFIER_LEFT, u8Index), cmd, 0); if (fIsRight) hdaCodecSetRegisterU8(&LIFIER_REGISTER(*pAmplifier, AMPLIFIER_IN, AMPLIFIER_RIGHT, u8Index), cmd, 0); /** @todo Fix ID of u8AdcVolsLineIn! */ hdaCodecToAudVolume(pThis, pAmplifier, PDMAUDIOMIXERCTL_LINE_IN); } if (fIsOut) { if (fIsLeft) hdaCodecSetRegisterU8(&LIFIER_REGISTER(*pAmplifier, AMPLIFIER_OUT, AMPLIFIER_LEFT, u8Index), cmd, 0); if (fIsRight) hdaCodecSetRegisterU8(&LIFIER_REGISTER(*pAmplifier, AMPLIFIER_OUT, AMPLIFIER_RIGHT, u8Index), cmd, 0); if (CODEC_NID(cmd) == pThis->u8DacLineOut) hdaCodecToAudVolume(pThis, pAmplifier, PDMAUDIOMIXERCTL_PCM); } return VINF_SUCCESS; } static DECLCALLBACK(int) vrbProcGetParameter(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } Assert((cmd & CODEC_VERB_8BIT_DATA) < CODECNODE_F00_PARAM_LENGTH); if ((cmd & CODEC_VERB_8BIT_DATA) >= CODECNODE_F00_PARAM_LENGTH) { LogFlowFunc(("invalid F00 parameter %d\n", (cmd & CODEC_VERB_8BIT_DATA))); return VINF_SUCCESS; } *pResp = pThis->paNodes[CODEC_NID(cmd)].node.au32F00_param[cmd & CODEC_VERB_8BIT_DATA]; return VINF_SUCCESS; } /* F01 */ static DECLCALLBACK(int) vrbProcGetConSelectCtrl(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsAdcMuxNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].adcmux.u32F01_param; else if (hdaCodecIsDigOutPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digout.u32F01_param; else if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].port.u32F01_param; else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].adc.u32F01_param; else if (hdaCodecIsAdcVolNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].adcvol.u32F01_param; return VINF_SUCCESS; } /* 701 */ static DECLCALLBACK(int) vrbProcSetConSelectCtrl(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; uint32_t *pu32Reg; if (hdaCodecIsAdcMuxNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].adcmux.u32F01_param; else if (hdaCodecIsDigOutPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digout.u32F01_param; else if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].port.u32F01_param; else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].adc.u32F01_param; else if (hdaCodecIsAdcVolNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].adcvol.u32F01_param; else AssertFailedReturn(VINF_SUCCESS); hdaCodecSetRegisterU8(pu32Reg, cmd, 0); return VINF_SUCCESS; } /* F07 */ static DECLCALLBACK(int) vrbProcGetPinCtrl(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].port.u32F07_param; else if (hdaCodecIsDigOutPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digout.u32F07_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digin.u32F07_param; else if (hdaCodecIsCdNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].cdnode.u32F07_param; else if (hdaCodecIsPcbeepNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].pcbeep.u32F07_param; else if (hdaCodecIsReservedNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].reserved.u32F07_param; else AssertMsgFailed(("Unsupported")); return VINF_SUCCESS; } /* 707 */ static DECLCALLBACK(int) vrbProcSetPinCtrl(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; uint32_t *pu32Reg; if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].port.u32F07_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digin.u32F07_param; else if (hdaCodecIsDigOutPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digout.u32F07_param; else if (hdaCodecIsCdNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].cdnode.u32F07_param; else if (hdaCodecIsPcbeepNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].pcbeep.u32F07_param; else if ( hdaCodecIsReservedNode(pThis, CODEC_NID(cmd)) && CODEC_NID(cmd) == 0x1b) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].reserved.u32F07_param; else AssertFailedReturn(VINF_SUCCESS); hdaCodecSetRegisterU8(pu32Reg, cmd, 0); return VINF_SUCCESS; } /* F08 */ static DECLCALLBACK(int) vrbProcGetUnsolicitedEnabled(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].port.u32F08_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digin.u32F08_param; else if ((cmd) == 1 /* AFG */) *pResp = pThis->paNodes[CODEC_NID(cmd)].afg.u32F08_param; else if (hdaCodecIsVolKnobNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].volumeKnob.u32F08_param; else if (hdaCodecIsDigOutPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digout.u32F08_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digin.u32F08_param; else AssertMsgFailed(("unsupported operation %x on node: %x\n", CODEC_VERB_CMD8(cmd), CODEC_NID(cmd))); return VINF_SUCCESS; } /* 708 */ static DECLCALLBACK(int) vrbProcSetUnsolicitedEnabled(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; uint32_t *pu32Reg; if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].port.u32F08_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digin.u32F08_param; else if (CODEC_NID(cmd) == 1 /* AFG */) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].afg.u32F08_param; else if (hdaCodecIsVolKnobNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].volumeKnob.u32F08_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digin.u32F08_param; else if (hdaCodecIsDigOutPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digout.u32F08_param; else AssertMsgFailedReturn(("unsupported operation %x on node: %x\n", CODEC_VERB_CMD8(cmd), CODEC_NID(cmd)), VINF_SUCCESS); hdaCodecSetRegisterU8(pu32Reg, cmd, 0); return VINF_SUCCESS; } /* F09 */ static DECLCALLBACK(int) vrbProcGetPinSense(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].port.u32F09_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digin.u32F09_param; else AssertMsgFailed(("unsupported operation %x on node: %x\n", CODEC_VERB_CMD8(cmd), CODEC_NID(cmd))); return VINF_SUCCESS; } /* 709 */ static DECLCALLBACK(int) vrbProcSetPinSense(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; uint32_t *pu32Reg; if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].port.u32F09_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digin.u32F09_param; else AssertFailedReturn(VINF_SUCCESS); hdaCodecSetRegisterU8(pu32Reg, cmd, 0); return VINF_SUCCESS; } static DECLCALLBACK(int) vrbProcGetConnectionListEntry(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); *pResp = 0; if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } Assert((cmd & CODEC_VERB_8BIT_DATA) < CODECNODE_F02_PARAM_LENGTH); if ((cmd & CODEC_VERB_8BIT_DATA) >= CODECNODE_F02_PARAM_LENGTH) { LogFlowFunc(("access to invalid F02 index %d\n", (cmd & CODEC_VERB_8BIT_DATA))); return VINF_SUCCESS; } *pResp = pThis->paNodes[CODEC_NID(cmd)].node.au32F02_param[cmd & CODEC_VERB_8BIT_DATA]; return VINF_SUCCESS; } /* F03 */ static DECLCALLBACK(int) vrbProcGetProcessingState(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].adc.u32F03_param; return VINF_SUCCESS; } /* 703 */ static DECLCALLBACK(int) vrbProcSetProcessingState(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) hdaCodecSetRegisterU8(&pThis->paNodes[CODEC_NID(cmd)].adc.u32F03_param, cmd, 0); return VINF_SUCCESS; } /* F0D */ static DECLCALLBACK(int) vrbProcGetDigitalConverter(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsSpdifOutNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].spdifout.u32F0d_param; else if (hdaCodecIsSpdifInNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].spdifin.u32F0d_param; return VINF_SUCCESS; } static int codecSetDigitalConverter(PHDACODEC pThis, uint32_t cmd, uint8_t u8Offset, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsSpdifOutNode(pThis, CODEC_NID(cmd))) hdaCodecSetRegisterU8(&pThis->paNodes[CODEC_NID(cmd)].spdifout.u32F0d_param, cmd, u8Offset); else if (hdaCodecIsSpdifInNode(pThis, CODEC_NID(cmd))) hdaCodecSetRegisterU8(&pThis->paNodes[CODEC_NID(cmd)].spdifin.u32F0d_param, cmd, u8Offset); return VINF_SUCCESS; } /* 70D */ static DECLCALLBACK(int) vrbProcSetDigitalConverter1(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { return codecSetDigitalConverter(pThis, cmd, 0, pResp); } /* 70E */ static DECLCALLBACK(int) vrbProcSetDigitalConverter2(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { return codecSetDigitalConverter(pThis, cmd, 8, pResp); } /* F20 */ static DECLCALLBACK(int) vrbProcGetSubId(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } if (CODEC_NID(cmd) == 1 /* AFG */) *pResp = pThis->paNodes[CODEC_NID(cmd)].afg.u32F20_param; else *pResp = 0; return VINF_SUCCESS; } static int codecSetSubIdX(PHDACODEC pThis, uint32_t cmd, uint8_t u8Offset) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } uint32_t *pu32Reg; if (CODEC_NID(cmd) == 0x1 /* AFG */) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].afg.u32F20_param; else AssertFailedReturn(VINF_SUCCESS); hdaCodecSetRegisterU8(pu32Reg, cmd, u8Offset); return VINF_SUCCESS; } /* 720 */ static DECLCALLBACK(int) vrbProcSetSubId0(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { *pResp = 0; return codecSetSubIdX(pThis, cmd, 0); } /* 721 */ static DECLCALLBACK(int) vrbProcSetSubId1(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { *pResp = 0; return codecSetSubIdX(pThis, cmd, 8); } /* 722 */ static DECLCALLBACK(int) vrbProcSetSubId2(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { *pResp = 0; return codecSetSubIdX(pThis, cmd, 16); } /* 723 */ static DECLCALLBACK(int) vrbProcSetSubId3(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { *pResp = 0; return codecSetSubIdX(pThis, cmd, 24); } static DECLCALLBACK(int) vrbProcReset(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) == 1 /* AFG */); if ( CODEC_NID(cmd) == 1 /* AFG */ && pThis->pfnCodecNodeReset) { uint8_t i; LogFlowFunc(("enters reset\n")); Assert(pThis->pfnCodecNodeReset); for (i = 0; i < pThis->cTotalNodes; ++i) { pThis->pfnCodecNodeReset(pThis, i, &pThis->paNodes[i]); } pThis->fInReset = false; LogFlowFunc(("exits reset\n")); } *pResp = 0; return VINF_SUCCESS; } /* F05 */ static DECLCALLBACK(int) vrbProcGetPowerState(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (CODEC_NID(cmd) == 1 /* AFG */) *pResp = pThis->paNodes[CODEC_NID(cmd)].afg.u32F05_param; else if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].dac.u32F05_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digin.u32F05_param; else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].adc.u32F05_param; else if (hdaCodecIsSpdifOutNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].spdifout.u32F05_param; else if (hdaCodecIsSpdifInNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].spdifin.u32F05_param; else if (hdaCodecIsReservedNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].reserved.u32F05_param; return VINF_SUCCESS; } /* 705 */ DECLINLINE(void) codecPropogatePowerState(uint32_t *pu32F05_param) { Assert(pu32F05_param); if (!pu32F05_param) return; bool fReset = CODEC_F05_IS_RESET(*pu32F05_param); bool fStopOk = CODEC_F05_IS_STOPOK(*pu32F05_param); uint8_t u8SetPowerState = CODEC_F05_SET(*pu32F05_param); *pu32F05_param = CODEC_MAKE_F05(fReset, fStopOk, 0, u8SetPowerState, u8SetPowerState); } static DECLCALLBACK(int) vrbProcSetPowerState(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; uint32_t *pu32Reg; if (CODEC_NID(cmd) == 1 /* AFG */) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].afg.u32F05_param; else if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].dac.u32F05_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digin.u32F05_param; else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].adc.u32F05_param; else if (hdaCodecIsSpdifOutNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].spdifout.u32F05_param; else if (hdaCodecIsSpdifInNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].spdifin.u32F05_param; else if (hdaCodecIsReservedNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].reserved.u32F05_param; else AssertFailedReturn(VINF_SUCCESS); bool fReset = CODEC_F05_IS_RESET(*pu32Reg); bool fStopOk = CODEC_F05_IS_STOPOK(*pu32Reg); if (CODEC_NID(cmd) != 1 /* AFG */) { /* * We shouldn't propogate actual power state, which actual for AFG */ *pu32Reg = CODEC_MAKE_F05(fReset, fStopOk, 0, CODEC_F05_ACT(pThis->paNodes[1].afg.u32F05_param), CODEC_F05_SET(cmd)); } /* Propagate next power state only if AFG is on or verb modifies AFG power state */ if ( CODEC_NID(cmd) == 1 /* AFG */ || !CODEC_F05_ACT(pThis->paNodes[1].afg.u32F05_param)) { *pu32Reg = CODEC_MAKE_F05(fReset, fStopOk, 0, CODEC_F05_SET(cmd), CODEC_F05_SET(cmd)); if ( CODEC_NID(cmd) == 1 /* AFG */ && (CODEC_F05_SET(cmd)) == CODEC_F05_D0) { /* now we're powered on AFG and may propogate power states on nodes */ const uint8_t *pu8NodeIndex = &pThis->au8Dacs[0]; while (*(++pu8NodeIndex)) codecPropogatePowerState(&pThis->paNodes[*pu8NodeIndex].dac.u32F05_param); pu8NodeIndex = &pThis->au8Adcs[0]; while (*(++pu8NodeIndex)) codecPropogatePowerState(&pThis->paNodes[*pu8NodeIndex].adc.u32F05_param); pu8NodeIndex = &pThis->au8DigInPins[0]; while (*(++pu8NodeIndex)) codecPropogatePowerState(&pThis->paNodes[*pu8NodeIndex].digin.u32F05_param); } } return VINF_SUCCESS; } static DECLCALLBACK(int) vrbProcGetStreamId(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].dac.u32F06_param; else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].adc.u32F06_param; else if (hdaCodecIsSpdifInNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].spdifin.u32F06_param; else if (hdaCodecIsSpdifOutNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].spdifout.u32F06_param; else if (CODEC_NID(cmd) == 0x1A) *pResp = pThis->paNodes[CODEC_NID(cmd)].reserved.u32F06_param; return VINF_SUCCESS; } static DECLCALLBACK(int) vrbProcSetStreamId(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; uint32_t *pu32addr; if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) pu32addr = &pThis->paNodes[CODEC_NID(cmd)].dac.u32F06_param; else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) pu32addr = &pThis->paNodes[CODEC_NID(cmd)].adc.u32F06_param; else if (hdaCodecIsSpdifOutNode(pThis, CODEC_NID(cmd))) pu32addr = &pThis->paNodes[CODEC_NID(cmd)].spdifout.u32F06_param; else if (hdaCodecIsSpdifInNode(pThis, CODEC_NID(cmd))) pu32addr = &pThis->paNodes[CODEC_NID(cmd)].spdifin.u32F06_param; else if (hdaCodecIsReservedNode(pThis, CODEC_NID(cmd))) pu32addr = &pThis->paNodes[CODEC_NID(cmd)].reserved.u32F06_param; else AssertFailedReturn(VINF_SUCCESS); hdaCodecSetRegisterU8(pu32addr, cmd, 0); return VINF_SUCCESS; } static DECLCALLBACK(int) vrbProcGetConverterFormat(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].dac.u32A_param; else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].adc.u32A_param; else if (hdaCodecIsSpdifOutNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].spdifout.u32A_param; else if (hdaCodecIsSpdifInNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].spdifin.u32A_param; return VINF_SUCCESS; } static DECLCALLBACK(int) vrbProcSetConverterFormat(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) hdaCodecSetRegisterU16(&pThis->paNodes[CODEC_NID(cmd)].dac.u32A_param, cmd, 0); else if (hdaCodecIsAdcNode(pThis, CODEC_NID(cmd))) hdaCodecSetRegisterU16(&pThis->paNodes[CODEC_NID(cmd)].adc.u32A_param, cmd, 0); else if (hdaCodecIsSpdifOutNode(pThis, CODEC_NID(cmd))) hdaCodecSetRegisterU16(&pThis->paNodes[CODEC_NID(cmd)].spdifout.u32A_param, cmd, 0); else if (hdaCodecIsSpdifInNode(pThis, CODEC_NID(cmd))) hdaCodecSetRegisterU16(&pThis->paNodes[CODEC_NID(cmd)].spdifin.u32A_param, cmd, 0); return VINF_SUCCESS; } /* F0C */ static DECLCALLBACK(int) vrbProcGetEAPD_BTLEnabled(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsAdcVolNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].adcvol.u32F0c_param; else if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].dac.u32F0c_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digin.u32F0c_param; return VINF_SUCCESS; } /* 70C */ static DECLCALLBACK(int) vrbProcSetEAPD_BTLEnabled(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; uint32_t *pu32Reg; if (hdaCodecIsAdcVolNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].adcvol.u32F0c_param; else if (hdaCodecIsDacNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].dac.u32F0c_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digin.u32F0c_param; else AssertFailedReturn(VINF_SUCCESS); hdaCodecSetRegisterU8(pu32Reg, cmd, 0); return VINF_SUCCESS; } /* F0F */ static DECLCALLBACK(int) vrbProcGetVolumeKnobCtrl(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsVolKnobNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].volumeKnob.u32F0f_param; return VINF_SUCCESS; } /* 70F */ static DECLCALLBACK(int) vrbProcSetVolumeKnobCtrl(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } uint32_t *pu32Reg = NULL; *pResp = 0; if (hdaCodecIsVolKnobNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].volumeKnob.u32F0f_param; Assert(pu32Reg); if (pu32Reg) hdaCodecSetRegisterU8(pu32Reg, cmd, 0); return VINF_SUCCESS; } /* F17 */ static DECLCALLBACK(int) vrbProcGetGPIOUnsolisted(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; /* note: this is true for ALC885 */ if (CODEC_NID(cmd) == 0x1 /* AFG */) *pResp = pThis->paNodes[1].afg.u32F17_param; return VINF_SUCCESS; } /* 717 */ static DECLCALLBACK(int) vrbProcSetGPIOUnsolisted(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } uint32_t *pu32Reg = NULL; *pResp = 0; if (CODEC_NID(cmd) == 1 /* AFG */) pu32Reg = &pThis->paNodes[1].afg.u32F17_param; Assert(pu32Reg); if (pu32Reg) hdaCodecSetRegisterU8(pu32Reg, cmd, 0); return VINF_SUCCESS; } /* F1C */ static DECLCALLBACK(int) vrbProcGetConfig(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } *pResp = 0; if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].port.u32F1c_param; else if (hdaCodecIsDigOutPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digout.u32F1c_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].digin.u32F1c_param; else if (hdaCodecIsPcbeepNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].pcbeep.u32F1c_param; else if (hdaCodecIsCdNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].cdnode.u32F1c_param; else if (hdaCodecIsReservedNode(pThis, CODEC_NID(cmd))) *pResp = pThis->paNodes[CODEC_NID(cmd)].reserved.u32F1c_param; return VINF_SUCCESS; } static int codecSetConfigX(PHDACODEC pThis, uint32_t cmd, uint8_t u8Offset) { Assert(CODEC_CAD(cmd) == pThis->id); Assert(CODEC_NID(cmd) < pThis->cTotalNodes); if (CODEC_NID(cmd) >= pThis->cTotalNodes) { LogFlowFunc(("invalid node address %d\n", CODEC_NID(cmd))); return VINF_SUCCESS; } uint32_t *pu32Reg = NULL; if (hdaCodecIsPortNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].port.u32F1c_param; else if (hdaCodecIsDigInPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digin.u32F1c_param; else if (hdaCodecIsDigOutPinNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].digout.u32F1c_param; else if (hdaCodecIsCdNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].cdnode.u32F1c_param; else if (hdaCodecIsPcbeepNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].pcbeep.u32F1c_param; else if (hdaCodecIsReservedNode(pThis, CODEC_NID(cmd))) pu32Reg = &pThis->paNodes[CODEC_NID(cmd)].reserved.u32F1c_param; Assert(pu32Reg); if (pu32Reg) hdaCodecSetRegisterU8(pu32Reg, cmd, u8Offset); return VINF_SUCCESS; } /* 71C */ static DECLCALLBACK(int) vrbProcSetConfig0(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { *pResp = 0; return codecSetConfigX(pThis, cmd, 0); } /* 71D */ static DECLCALLBACK(int) vrbProcSetConfig1(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { *pResp = 0; return codecSetConfigX(pThis, cmd, 8); } /* 71E */ static DECLCALLBACK(int) vrbProcSetConfig2(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { *pResp = 0; return codecSetConfigX(pThis, cmd, 16); } /* 71E */ static DECLCALLBACK(int) vrbProcSetConfig3(PHDACODEC pThis, uint32_t cmd, uint64_t *pResp) { *pResp = 0; return codecSetConfigX(pThis, cmd, 24); } /** * HDA codec verb map. * @todo Any reason not to use binary search here? */ static const CODECVERB g_aCodecVerbs[] = { /* verb | verb mask | callback */ /* ----------- -------------------- ----------------------- */ { 0x000F0000, CODEC_VERB_8BIT_CMD , vrbProcGetParameter }, { 0x000F0100, CODEC_VERB_8BIT_CMD , vrbProcGetConSelectCtrl }, { 0x00070100, CODEC_VERB_8BIT_CMD , vrbProcSetConSelectCtrl }, { 0x000F0600, CODEC_VERB_8BIT_CMD , vrbProcGetStreamId }, { 0x00070600, CODEC_VERB_8BIT_CMD , vrbProcSetStreamId }, { 0x000F0700, CODEC_VERB_8BIT_CMD , vrbProcGetPinCtrl }, { 0x00070700, CODEC_VERB_8BIT_CMD , vrbProcSetPinCtrl }, { 0x000F0800, CODEC_VERB_8BIT_CMD , vrbProcGetUnsolicitedEnabled }, { 0x00070800, CODEC_VERB_8BIT_CMD , vrbProcSetUnsolicitedEnabled }, { 0x000F0900, CODEC_VERB_8BIT_CMD , vrbProcGetPinSense }, { 0x00070900, CODEC_VERB_8BIT_CMD , vrbProcSetPinSense }, { 0x000F0200, CODEC_VERB_8BIT_CMD , vrbProcGetConnectionListEntry }, { 0x000F0300, CODEC_VERB_8BIT_CMD , vrbProcGetProcessingState }, { 0x00070300, CODEC_VERB_8BIT_CMD , vrbProcSetProcessingState }, { 0x000F0D00, CODEC_VERB_8BIT_CMD , vrbProcGetDigitalConverter }, { 0x00070D00, CODEC_VERB_8BIT_CMD , vrbProcSetDigitalConverter1 }, { 0x00070E00, CODEC_VERB_8BIT_CMD , vrbProcSetDigitalConverter2 }, { 0x000F2000, CODEC_VERB_8BIT_CMD , vrbProcGetSubId }, { 0x00072000, CODEC_VERB_8BIT_CMD , vrbProcSetSubId0 }, { 0x00072100, CODEC_VERB_8BIT_CMD , vrbProcSetSubId1 }, { 0x00072200, CODEC_VERB_8BIT_CMD , vrbProcSetSubId2 }, { 0x00072300, CODEC_VERB_8BIT_CMD , vrbProcSetSubId3 }, { 0x0007FF00, CODEC_VERB_8BIT_CMD , vrbProcReset }, { 0x000F0500, CODEC_VERB_8BIT_CMD , vrbProcGetPowerState }, { 0x00070500, CODEC_VERB_8BIT_CMD , vrbProcSetPowerState }, { 0x000F0C00, CODEC_VERB_8BIT_CMD , vrbProcGetEAPD_BTLEnabled }, { 0x00070C00, CODEC_VERB_8BIT_CMD , vrbProcSetEAPD_BTLEnabled }, { 0x000F0F00, CODEC_VERB_8BIT_CMD , vrbProcGetVolumeKnobCtrl }, { 0x00070F00, CODEC_VERB_8BIT_CMD , vrbProcSetVolumeKnobCtrl }, { 0x000F1700, CODEC_VERB_8BIT_CMD , vrbProcGetGPIOUnsolisted }, { 0x00071700, CODEC_VERB_8BIT_CMD , vrbProcSetGPIOUnsolisted }, { 0x000F1C00, CODEC_VERB_8BIT_CMD , vrbProcGetConfig }, { 0x00071C00, CODEC_VERB_8BIT_CMD , vrbProcSetConfig0 }, { 0x00071D00, CODEC_VERB_8BIT_CMD , vrbProcSetConfig1 }, { 0x00071E00, CODEC_VERB_8BIT_CMD , vrbProcSetConfig2 }, { 0x00071F00, CODEC_VERB_8BIT_CMD , vrbProcSetConfig3 }, { 0x000A0000, CODEC_VERB_16BIT_CMD, vrbProcGetConverterFormat }, { 0x00020000, CODEC_VERB_16BIT_CMD, vrbProcSetConverterFormat }, { 0x000B0000, CODEC_VERB_16BIT_CMD, vrbProcGetAmplifier }, { 0x00030000, CODEC_VERB_16BIT_CMD, vrbProcSetAmplifier }, }; #ifdef DEBUG typedef struct CODECDBGINFO { /** DBGF info helpers. */ PCDBGFINFOHLP pHlp; /** Current recursion level. */ uint8_t uLevel; /** Pointer to codec state. */ PHDACODEC pThis; } CODECDBGINFO, *PCODECDBGINFO; #define CODECDBG_INDENT pInfo->uLevel++; #define CODECDBG_UNINDENT if (pInfo->uLevel) pInfo->uLevel--; #define CODECDBG_PRINT(...) pInfo->pHlp->pfnPrintf(pInfo->pHlp, __VA_ARGS__) #define CODECDBG_PRINTI(...) codecDbgPrintf(pInfo, __VA_ARGS__) static void codecDbgPrintfIndentV(PCODECDBGINFO pInfo, uint16_t uIndent, const char *pszFormat, va_list va) { char *pszValueFormat; if (RTStrAPrintfV(&pszValueFormat, pszFormat, va)) { pInfo->pHlp->pfnPrintf(pInfo->pHlp, "%*s%s", uIndent, "", pszValueFormat); RTStrFree(pszValueFormat); } } static void codecDbgPrintf(PCODECDBGINFO pInfo, const char *pszFormat, ...) { va_list va; va_start(va, pszFormat); codecDbgPrintfIndentV(pInfo, pInfo->uLevel * 4, pszFormat, va); va_end(va); } /* Power state */ static void codecDbgPrintNodeRegF05(PCODECDBGINFO pInfo, uint32_t u32Reg) { codecDbgPrintf(pInfo, "Power (F05): fReset=%RTbool, fStopOk=%RTbool, Set=%RU8, Act=%RU8\n", CODEC_F05_IS_RESET(u32Reg), CODEC_F05_IS_STOPOK(u32Reg), CODEC_F05_SET(u32Reg), CODEC_F05_ACT(u32Reg)); } static void codecDbgPrintNodeRegA(PCODECDBGINFO pInfo, uint32_t u32Reg) { codecDbgPrintf(pInfo, "RegA: %x\n", u32Reg); } static void codecDbgPrintNodeRegF00(PCODECDBGINFO pInfo, uint32_t *paReg00) { codecDbgPrintf(pInfo, "Parameters (F00):\n"); CODECDBG_INDENT codecDbgPrintf(pInfo, "Amplifier Caps:\n"); uint32_t uReg = paReg00[0xD]; CODECDBG_INDENT codecDbgPrintf(pInfo, "Input Steps=%02RU8, StepSize=%02RU8, StepOff=%02RU8, fCanMute=%RTbool\n", CODEC_F00_0D_NUM_STEPS(uReg), CODEC_F00_0D_STEP_SIZE(uReg), CODEC_F00_0D_OFFSET(uReg), RT_BOOL(CODEC_F00_0D_IS_CAP_MUTE(uReg))); uReg = paReg00[0x12]; codecDbgPrintf(pInfo, "Output Steps=%02RU8, StepSize=%02RU8, StepOff=%02RU8, fCanMute=%RTbool\n", CODEC_F00_12_NUM_STEPS(uReg), CODEC_F00_12_STEP_SIZE(uReg), CODEC_F00_12_OFFSET(uReg), RT_BOOL(CODEC_F00_0D_IS_CAP_MUTE(uReg))); CODECDBG_UNINDENT CODECDBG_UNINDENT } static void codecDbgPrintNodeAmp(PCODECDBGINFO pInfo, uint32_t *paReg, uint8_t uIdx, uint8_t uDir) { #define CODECDBG_AMP(reg, chan) \ codecDbgPrintf(pInfo, "Amp %RU8 %s %s: In=%RTbool, Out=%RTbool, Left=%RTbool, Right=%RTbool, Idx=%RU8, fMute=%RTbool, uGain=%RU8\n", \ uIdx, chan, uDir == AMPLIFIER_IN ? "In" : "Out", \ RT_BOOL(CODEC_SET_AMP_IS_IN_DIRECTION(reg)), RT_BOOL(CODEC_SET_AMP_IS_OUT_DIRECTION(reg)), \ RT_BOOL(CODEC_SET_AMP_IS_LEFT_SIDE(reg)), RT_BOOL(CODEC_SET_AMP_IS_RIGHT_SIDE(reg)), \ CODEC_SET_AMP_INDEX(reg), RT_BOOL(CODEC_SET_AMP_MUTE(reg)), CODEC_SET_AMP_GAIN(reg)); uint32_t regAmp = AMPLIFIER_REGISTER(paReg, uDir, AMPLIFIER_LEFT, uIdx); CODECDBG_AMP(regAmp, "Left"); regAmp = AMPLIFIER_REGISTER(paReg, uDir, AMPLIFIER_RIGHT, uIdx); CODECDBG_AMP(regAmp, "Right"); #undef CODECDBG_AMP } static void codecDbgPrintNodeConnections(PCODECDBGINFO pInfo, PCODECNODE pNode) { if (pNode->node.au32F00_param[0xE] == 0) /* Directly connected to HDA link. */ { codecDbgPrintf(pInfo, "[HDA LINK]\n"); return; } } static void codecDbgPrintNode(PCODECDBGINFO pInfo, PCODECNODE pNode) { codecDbgPrintf(pInfo, "Node 0x%02x (%02RU8): ", pNode->node.id, pNode->node.id); if (pNode->node.id == STAC9220_NID_ROOT) { CODECDBG_PRINT("ROOT\n"); } else if (pNode->node.id == STAC9220_NID_AFG) { CODECDBG_PRINT("AFG\n"); CODECDBG_INDENT codecDbgPrintNodeRegF00(pInfo, pNode->node.au32F00_param); codecDbgPrintNodeRegF05(pInfo, pNode->afg.u32F05_param); CODECDBG_UNINDENT } else if (hdaCodecIsPortNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("PORT\n"); } else if (hdaCodecIsDacNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("DAC\n"); CODECDBG_INDENT codecDbgPrintNodeRegF00(pInfo, pNode->node.au32F00_param); codecDbgPrintNodeRegF05(pInfo, pNode->dac.u32F05_param); codecDbgPrintNodeRegA (pInfo, pNode->dac.u32A_param); codecDbgPrintNodeAmp (pInfo, pNode->dac.B_params, 0, AMPLIFIER_OUT); CODECDBG_UNINDENT } else if (hdaCodecIsAdcVolNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("ADC VOLUME\n"); CODECDBG_INDENT codecDbgPrintNodeRegF00(pInfo, pNode->node.au32F00_param); codecDbgPrintNodeRegA (pInfo, pNode->adcvol.u32A_params); codecDbgPrintNodeAmp (pInfo, pNode->adcvol.B_params, 0, AMPLIFIER_IN); CODECDBG_UNINDENT } else if (hdaCodecIsAdcNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("ADC\n"); CODECDBG_INDENT codecDbgPrintNodeRegF00(pInfo, pNode->node.au32F00_param); codecDbgPrintNodeRegF05(pInfo, pNode->adc.u32F05_param); codecDbgPrintNodeRegA (pInfo, pNode->adc.u32A_param); codecDbgPrintNodeAmp (pInfo, pNode->adc.B_params, 0, AMPLIFIER_IN); CODECDBG_UNINDENT } else if (hdaCodecIsAdcMuxNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("ADC MUX\n"); CODECDBG_INDENT codecDbgPrintNodeRegF00(pInfo, pNode->node.au32F00_param); codecDbgPrintNodeRegA (pInfo, pNode->adcmux.u32A_param); codecDbgPrintNodeAmp (pInfo, pNode->adcmux.B_params, 0, AMPLIFIER_IN); CODECDBG_UNINDENT } else if (hdaCodecIsPcbeepNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("PC BEEP\n"); } else if (hdaCodecIsSpdifOutNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("SPDIF OUT\n"); } else if (hdaCodecIsSpdifInNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("SPDIF IN\n"); } else if (hdaCodecIsDigInPinNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("DIGITAL IN PIN\n"); } else if (hdaCodecIsDigOutPinNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("DIGITAL OUT PIN\n"); } else if (hdaCodecIsCdNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("CD\n"); } else if (hdaCodecIsVolKnobNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("VOLUME KNOB\n"); } else if (hdaCodecIsReservedNode(pInfo->pThis, pNode->node.id)) { CODECDBG_PRINT("RESERVED\n"); } else CODECDBG_PRINT("UNKNOWN TYPE 0x%x\n", pNode->node.id); } static DECLCALLBACK(void) codecDbgListNodes(PHDACODEC pThis, PCDBGFINFOHLP pHlp, const char *pszArgs) { pHlp->pfnPrintf(pHlp, "HDA LINK\n"); CODECDBGINFO dbgInfo; dbgInfo.pHlp = pHlp; dbgInfo.pThis = pThis; dbgInfo.uLevel = 0; PCODECDBGINFO pInfo = &dbgInfo; CODECDBG_INDENT for (uint8_t i = 0; i < pThis->cTotalNodes; i++) { PCODECNODE pNode = &pThis->paNodes[i]; if (pNode->node.au32F00_param[0xE] == 0) /* Start with all nodes connected directly to the HDA (Azalia) link. */ codecDbgPrintNode(&dbgInfo, pNode); } CODECDBG_UNINDENT } static DECLCALLBACK(void) codecDbgSelector(PHDACODEC pThis, PCDBGFINFOHLP pHlp, const char *pszArgs) { } #endif static DECLCALLBACK(int) codecLookup(PHDACODEC pThis, uint32_t cmd, PPFNHDACODECVERBPROCESSOR pfn) { Assert(CODEC_CAD(cmd) == pThis->id); if (hdaCodecIsReservedNode(pThis, CODEC_NID(cmd))) LogFlowFunc(("cmd %x was addressed to reserved node\n", cmd)); if ( CODEC_VERBDATA(cmd) == 0 || CODEC_NID(cmd) >= pThis->cTotalNodes) { *pfn = vrbProcUnimplemented; /// @todo r=michaln: There needs to be a counter to avoid log flooding (see e.g. DevRTC.cpp) LogFlowFunc(("cmd %x was ignored\n", cmd)); return VINF_SUCCESS; } for (int i = 0; i < pThis->cVerbs; ++i) { if ((CODEC_VERBDATA(cmd) & pThis->paVerbs[i].mask) == pThis->paVerbs[i].verb) { *pfn = pThis->paVerbs[i].pfn; return VINF_SUCCESS; } } *pfn = vrbProcUnimplemented; LogFlowFunc(("callback for %x wasn't found\n", CODEC_VERBDATA(cmd))); return VINF_SUCCESS; } /* * APIs exposed to DevHDA. */ /** * * routines open one of the voices (IN, OUT) with corresponding parameters. * this routine could be called from HDA on setting/resseting sound format. * * @todo Probably passed settings should be verified (if AFG's declared proposed * format) before enabling. */ int hdaCodecOpenStream(PHDACODEC pThis, ENMSOUNDSOURCE enmSoundSource, PPDMAUDIOSTREAMCFG pCfg) { AssertPtrReturn(pThis, VERR_INVALID_POINTER); int rc; switch (enmSoundSource) { case PI_INDEX: rc = pThis->pfnOpenIn(pThis->pHDAState, "hda.in", PDMAUDIORECSOURCE_LINE_IN, pCfg); break; #ifdef VBOX_WITH_HDA_MIC_IN case MC_INDEX: rc = pThis->pfnOpenIn(pThis->pHDAState, "hda.mc", PDMAUDIORECSOURCE_MIC, pCfg); break; #endif case PO_INDEX: rc = pThis->pfnOpenOut(pThis->pHDAState, "hda.out", pCfg); break; default: AssertMsgFailed(("Index %ld not implemented\n", enmSoundSource)); rc = VERR_NOT_IMPLEMENTED; } LogFlowFuncLeaveRC(rc); return rc; } int hdaCodecSaveState(PHDACODEC pThis, PSSMHANDLE pSSM) { AssertLogRelMsgReturn(pThis->cTotalNodes == 0x1c, ("cTotalNodes=%#x, should be 0x1c", pThis->cTotalNodes), VERR_INTERNAL_ERROR); SSMR3PutU32(pSSM, pThis->cTotalNodes); for (unsigned idxNode = 0; idxNode < pThis->cTotalNodes; ++idxNode) SSMR3PutStructEx(pSSM, &pThis->paNodes[idxNode].SavedState, sizeof(pThis->paNodes[idxNode].SavedState), 0 /*fFlags*/, g_aCodecNodeFields, NULL /*pvUser*/); return VINF_SUCCESS; } int hdaCodecLoadState(PHDACODEC pThis, PSSMHANDLE pSSM, uint32_t uVersion) { PCSSMFIELD pFields; uint32_t fFlags; switch (uVersion) { case HDA_SSM_VERSION_1: AssertReturn(pThis->cTotalNodes == 0x1c, VERR_INTERNAL_ERROR); pFields = g_aCodecNodeFieldsV1; fFlags = SSMSTRUCT_FLAGS_MEM_BAND_AID_RELAXED; break; case HDA_SSM_VERSION_2: case HDA_SSM_VERSION_3: AssertReturn(pThis->cTotalNodes == 0x1c, VERR_INTERNAL_ERROR); pFields = g_aCodecNodeFields; fFlags = SSMSTRUCT_FLAGS_MEM_BAND_AID_RELAXED; break; /* Since version 4 a flexible node count is supported. */ case HDA_SSM_VERSION_4: case HDA_SSM_VERSION_5: case HDA_SSM_VERSION: { uint32_t cNodes; int rc2 = SSMR3GetU32(pSSM, &cNodes); AssertRCReturn(rc2, rc2); if (cNodes != 0x1c) return VERR_SSM_DATA_UNIT_FORMAT_CHANGED; AssertReturn(pThis->cTotalNodes == 0x1c, VERR_INTERNAL_ERROR); pFields = g_aCodecNodeFields; fFlags = 0; break; } default: return VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION; } for (unsigned idxNode = 0; idxNode < pThis->cTotalNodes; ++idxNode) { uint8_t idOld = pThis->paNodes[idxNode].SavedState.Core.id; int rc = SSMR3GetStructEx(pSSM, &pThis->paNodes[idxNode].SavedState, sizeof(pThis->paNodes[idxNode].SavedState), fFlags, pFields, NULL); if (RT_FAILURE(rc)) return rc; AssertLogRelMsgReturn(idOld == pThis->paNodes[idxNode].SavedState.Core.id, ("loaded %#x, expected %#x\n", pThis->paNodes[idxNode].SavedState.Core.id, idOld), VERR_SSM_DATA_UNIT_FORMAT_CHANGED); } /* * Update stuff after changing the state. */ if (hdaCodecIsDacNode(pThis, pThis->u8DacLineOut)) hdaCodecToAudVolume(pThis, &pThis->paNodes[pThis->u8DacLineOut].dac.B_params, PDMAUDIOMIXERCTL_PCM); else if (hdaCodecIsSpdifOutNode(pThis, pThis->u8DacLineOut)) hdaCodecToAudVolume(pThis, &pThis->paNodes[pThis->u8DacLineOut].spdifout.B_params, PDMAUDIOMIXERCTL_PCM); hdaCodecToAudVolume(pThis, &pThis->paNodes[pThis->u8AdcVolsLineIn].adcvol.B_params, PDMAUDIOMIXERCTL_LINE_IN); return VINF_SUCCESS; } int hdaCodecDestruct(PHDACODEC pThis) { AssertPtrReturn(pThis, VERR_INVALID_POINTER); if (pThis->paNodes) { RTMemFree(pThis->paNodes); pThis->paNodes = NULL; } return VINF_SUCCESS; } int hdaCodecConstruct(PPDMDEVINS pDevIns, PHDACODEC pThis, uint16_t uLUN, PCFGMNODE pCfg) { AssertPtrReturn(pDevIns, VERR_INVALID_POINTER); AssertPtrReturn(pThis, VERR_INVALID_POINTER); AssertPtrReturn(pCfg, VERR_INVALID_POINTER); pThis->id = uLUN; pThis->paVerbs = &g_aCodecVerbs[0]; pThis->cVerbs = RT_ELEMENTS(g_aCodecVerbs); pThis->pfnLookup = codecLookup; #ifdef DEBUG pThis->pfnDbgSelector = codecDbgSelector; pThis->pfnDbgListNodes = codecDbgListNodes; #endif int rc = stac9220Construct(pThis); AssertRC(rc); /* common root node initializers */ pThis->paNodes[0].node.au32F00_param[0] = CODEC_MAKE_F00_00(pThis->u16VendorId, pThis->u16DeviceId); pThis->paNodes[0].node.au32F00_param[4] = CODEC_MAKE_F00_04(0x1, 0x1); /* common AFG node initializers */ pThis->paNodes[1].node.au32F00_param[4] = CODEC_MAKE_F00_04(0x2, pThis->cTotalNodes - 2); pThis->paNodes[1].node.au32F00_param[5] = CODEC_MAKE_F00_05(1, CODEC_F00_05_AFG); pThis->paNodes[1].afg.u32F20_param = CODEC_MAKE_F20(pThis->u16VendorId, pThis->u8BSKU, pThis->u8AssemblyId); /* This codec uses a fixed setting (44.1 kHz, 16-bit signed, 2 channels). */ pThis->strmCfg.uHz = 44100; pThis->strmCfg.cChannels = 2; pThis->strmCfg.enmFormat = AUD_FMT_S16; pThis->strmCfg.enmEndianness = PDMAUDIOHOSTENDIANNESS; hdaCodecOpenStream(pThis, PI_INDEX, &pThis->strmCfg); #ifdef VBOX_WITH_HDA_MIC_IN hdaCodecOpenStream(pThis, MC_INDEX, &pThis->strmCfg); #endif hdaCodecOpenStream(pThis, PO_INDEX, &pThis->strmCfg); /* Initialize the AFG node with the fixed setting. */ pThis->paNodes[1].node.au32F00_param[0xA] = CODEC_F00_0A_44_1KHZ | CODEC_F00_0A_16_BIT; AssertPtr(pThis->paNodes); AssertPtr(pThis->pfnCodecNodeReset); for (uint8_t i = 0; i < pThis->cTotalNodes; i++) pThis->pfnCodecNodeReset(pThis, i, &pThis->paNodes[i]); hdaCodecToAudVolume(pThis, &pThis->paNodes[pThis->u8DacLineOut].dac.B_params, PDMAUDIOMIXERCTL_PCM); hdaCodecToAudVolume(pThis, &pThis->paNodes[pThis->u8AdcVolsLineIn].adcvol.B_params, PDMAUDIOMIXERCTL_LINE_IN); return VINF_SUCCESS; }