/* $NoKeywords:$ */ /** * @file * * Config FCH HD Audio Controller * * * * @xrefitem bom "File Content Label" "Release Content" * @e project: AGESA * @e sub-project: FCH * @e \$Revision: 63425 $ @e \$Date: 2011-12-22 11:24:10 -0600 (Thu, 22 Dec 2011) $ * */ /* ***************************************************************************** * * Copyright (c) 2008 - 2012, Advanced Micro Devices, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Advanced Micro Devices, Inc. nor the names of * its contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL ADVANCED MICRO DEVICES, INC. BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. **************************************************************************** */ #include "FchPlatform.h" #define FILECODE (0xB003) // // Declaration of local functions // VOID ConfigureAzaliaPinCmd ( IN FCH_DATA_BLOCK *FchDataPtr, IN UINT32 BAR0, IN UINT8 ChannelNum ); VOID ConfigureAzaliaSetConfigD4Dword ( IN CODEC_ENTRY *TempAzaliaCodecEntryPtr, IN UINT32 ChannelNumDword, IN UINT32 BAR0, IN AMD_CONFIG_PARAMS *StdHeader ); /** * FchInitMidAzalia - Config Azalia controller after PCI * emulation * * * * @param[in] FchDataPtr Fch configuration structure pointer. * */ VOID FchInitMidAzalia ( IN VOID *FchDataPtr ) { UINT8 Index; BOOLEAN EnableAzalia; UINT32 PinRouting; UINT8 ChannelNum; UINT8 AzaliaTempVariableByte; UINT16 AzaliaTempVariableWord; UINT32 BAR0; FCH_DATA_BLOCK *LocalCfgPtr; AMD_CONFIG_PARAMS *StdHeader; LocalCfgPtr = (FCH_DATA_BLOCK *) FchDataPtr; StdHeader = LocalCfgPtr->StdHeader; EnableAzalia = FALSE; ChannelNum = 0; AzaliaTempVariableByte = 0; AzaliaTempVariableWord = 0; BAR0 = 0; if ( LocalCfgPtr->Azalia.AzaliaEnable == AzDisable) { return; } else { RwPci ((((0x14<<3)+2) << 16) + 0x04, AccessWidth8, (UINT32)~BIT1, (UINT32)BIT1, StdHeader); if ( LocalCfgPtr->Azalia.AzaliaSsid != 0 ) { RwPci ((((0x14<<3)+2) << 16) + 0x2C, AccessWidth32, 0x00, LocalCfgPtr->Azalia.AzaliaSsid, StdHeader); } ReadPci ((((0x14<<3)+2) << 16) + 0x10, AccessWidth32, &BAR0, StdHeader); if ( BAR0 != 0 ) { if ( BAR0 != 0xFFFFFFFF ) { BAR0 &= ~(0x03FFF); EnableAzalia = TRUE; } } } if ( EnableAzalia ) { // // Get SDIN Configuration // if ( LocalCfgPtr->Azalia.AzaliaConfig.AzaliaSdin0 == 2 ) { RwMem (ACPI_MMIO_BASE + GPIO_BASE + FCH_GPIO_REG167, AccessWidth8, 0, 0x3E); RwMem (ACPI_MMIO_BASE + IOMUX_BASE + FCH_GPIO_REG167, AccessWidth8, 0, 0x00); } else { RwMem (ACPI_MMIO_BASE + GPIO_BASE + FCH_GPIO_REG167, AccessWidth8, 0, 0x0); RwMem (ACPI_MMIO_BASE + IOMUX_BASE + FCH_GPIO_REG167, AccessWidth8, 0, 0x01); } if ( LocalCfgPtr->Azalia.AzaliaConfig.AzaliaSdin1 == 2 ) { RwMem (ACPI_MMIO_BASE + GPIO_BASE + FCH_GPIO_REG168, AccessWidth8, 0, 0x3E); RwMem (ACPI_MMIO_BASE + IOMUX_BASE + FCH_GPIO_REG168, AccessWidth8, 0, 0x00); } else { RwMem (ACPI_MMIO_BASE + GPIO_BASE + FCH_GPIO_REG168, AccessWidth8, 0, 0x0); RwMem (ACPI_MMIO_BASE + IOMUX_BASE + FCH_GPIO_REG168, AccessWidth8, 0, 0x01); } if ( LocalCfgPtr->Azalia.AzaliaConfig.AzaliaSdin2 == 2 ) { RwMem (ACPI_MMIO_BASE + GPIO_BASE + FCH_GPIO_REG169, AccessWidth8, 0, 0x3E); RwMem (ACPI_MMIO_BASE + IOMUX_BASE + FCH_GPIO_REG169, AccessWidth8, 0, 0x00); } else { RwMem (ACPI_MMIO_BASE + GPIO_BASE + FCH_GPIO_REG169, AccessWidth8, 0, 0x0); RwMem (ACPI_MMIO_BASE + IOMUX_BASE + FCH_GPIO_REG169, AccessWidth8, 0, 0x01); } if ( LocalCfgPtr->Azalia.AzaliaConfig.AzaliaSdin3 == 2 ) { RwMem (ACPI_MMIO_BASE + GPIO_BASE + FCH_GPIO_REG170, AccessWidth8, 0, 0x3E); RwMem (ACPI_MMIO_BASE + IOMUX_BASE + FCH_GPIO_REG170, AccessWidth8, 0, 0x00); } else { RwMem (ACPI_MMIO_BASE + GPIO_BASE + FCH_GPIO_REG170, AccessWidth8, 0, 0x0); RwMem (ACPI_MMIO_BASE + IOMUX_BASE + FCH_GPIO_REG170, AccessWidth8, 0, 0x01); } Index = 11; do { ReadMem ( BAR0 + 0x08, AccessWidth8, &AzaliaTempVariableByte); AzaliaTempVariableByte |= BIT0; WriteMem (BAR0 + 0x08, AccessWidth8, &AzaliaTempVariableByte); FchStall (1000, StdHeader); ReadMem (BAR0 + 0x08, AccessWidth8, &AzaliaTempVariableByte); Index--; } while ((! (AzaliaTempVariableByte & BIT0)) && (Index > 0) ); if ( Index == 0 ) { return; } FchStall (1000, StdHeader); ReadMem ( BAR0 + 0x0E, AccessWidth16, &AzaliaTempVariableWord); if ( AzaliaTempVariableWord & 0x0F ) { // //at least one azalia codec found // //PinRouting = LocalCfgPtr->Azalia.AZALIA_CONFIG.AzaliaSdinPin; //new structure need make up PinRouting //need adjust later!!! // PinRouting = 0; PinRouting = (UINT32 )LocalCfgPtr->Azalia.AzaliaConfig.AzaliaSdin3; PinRouting <<= 8; PinRouting |= (UINT32 )LocalCfgPtr->Azalia.AzaliaConfig.AzaliaSdin2; PinRouting <<= 8; PinRouting |= (UINT32 )LocalCfgPtr->Azalia.AzaliaConfig.AzaliaSdin1; PinRouting <<= 8; PinRouting |= (UINT32 )LocalCfgPtr->Azalia.AzaliaConfig.AzaliaSdin0; do { if ( ( ! (PinRouting & BIT0) ) && (PinRouting & BIT1) ) { ConfigureAzaliaPinCmd (LocalCfgPtr, BAR0, ChannelNum); } PinRouting >>= 8; ChannelNum++; } while ( ChannelNum != 4 ); } else { // //No Azalia codec found // if ( LocalCfgPtr->Azalia.AzaliaEnable != AzEnable ) { EnableAzalia = FALSE; ///set flag to disable Azalia } } } if ( EnableAzalia ) { if ( LocalCfgPtr->Azalia.AzaliaSnoop == 1 ) { RwPci ((((0x14<<3)+2) << 16) + 0x42, AccessWidth8, 0xFF, BIT1 + BIT0, StdHeader); } } else { // //disable Azalia controller // RwPci ((((0x14<<3)+2) << 16) + 0x04, AccessWidth16, 0, 0, StdHeader); RwMem (ACPI_MMIO_BASE + PMIO_BASE + 0xEB , AccessWidth8, (UINT32)~BIT0, 0); RwMem (ACPI_MMIO_BASE + PMIO_BASE + 0xEB , AccessWidth8, (UINT32)~BIT0, 0); } } /** * Pin Config for ALC880, ALC882 and ALC883. * * * */ CODEC_ENTRY AzaliaCodecAlc882Table[] = { {0x14, 0x01014010}, {0x15, 0x01011012}, {0x16, 0x01016011}, {0x17, 0x01012014}, {0x18, 0x01A19030}, {0x19, 0x411111F0}, {0x1a, 0x01813080}, {0x1b, 0x411111F0}, {0x1C, 0x411111F0}, {0x1d, 0x411111F0}, {0x1e, 0x01441150}, {0x1f, 0x01C46160}, {0xff, 0xffffffff} }; /** * Pin Config for ALC0262. * * * */ CODEC_ENTRY AzaliaCodecAlc262Table[] = { {0x14, 0x01014010}, {0x15, 0x411111F0}, {0x16, 0x411111F0}, {0x18, 0x01A19830}, {0x19, 0x02A19C40}, {0x1a, 0x01813031}, {0x1b, 0x02014C20}, {0x1c, 0x411111F0}, {0x1d, 0x411111F0}, {0x1e, 0x0144111E}, {0x1f, 0x01C46150}, {0xff, 0xffffffff} }; /** * Pin Config for ALC0269. * * * */ CODEC_ENTRY AzaliaCodecAlc269Table[] = { {0x12, 0x99A308F0}, {0x14, 0x99130010}, {0x15, 0x0121101F}, {0x16, 0x99036120}, {0x18, 0x01A19850}, {0x19, 0x99A309F0}, {0x1a, 0x01813051}, {0x1b, 0x0181405F}, {0x1d, 0x40134601}, {0x1e, 0x01442130}, {0x11, 0x99430140}, {0x20, 0x0030FFFF}, {0xff, 0xffffffff} }; /** * Pin Config for ALC0861. * * * */ CODEC_ENTRY AzaliaCodecAlc861Table[] = { {0x01, 0x8086C601}, {0x0B, 0x01014110}, {0x0C, 0x01813140}, {0x0D, 0x01A19941}, {0x0E, 0x411111F0}, {0x0F, 0x02214420}, {0x10, 0x02A1994E}, {0x11, 0x99330142}, {0x12, 0x01451130}, {0x1F, 0x411111F0}, {0x20, 0x411111F0}, {0x23, 0x411111F0}, {0xff, 0xffffffff} }; /** * Pin Config for ALC0889. * * * */ CODEC_ENTRY AzaliaCodecAlc889Table[] = { {0x11, 0x411111F0}, {0x14, 0x01014010}, {0x15, 0x01011012}, {0x16, 0x01016011}, {0x17, 0x01013014}, {0x18, 0x01A19030}, {0x19, 0x411111F0}, {0x1a, 0x411111F0}, {0x1b, 0x411111F0}, {0x1C, 0x411111F0}, {0x1d, 0x411111F0}, {0x1e, 0x01442150}, {0x1f, 0x01C42160}, {0xff, 0xffffffff} }; /** * Pin Config for ADI1984. * * * */ CODEC_ENTRY AzaliaCodecAd1984Table[] = { {0x11, 0x0221401F}, {0x12, 0x90170110}, {0x13, 0x511301F0}, {0x14, 0x02A15020}, {0x15, 0x50A301F0}, {0x16, 0x593301F0}, {0x17, 0x55A601F0}, {0x18, 0x55A601F0}, {0x1A, 0x91F311F0}, {0x1B, 0x014511A0}, {0x1C, 0x599301F0}, {0xff, 0xffffffff} }; /** * FrontPanel Config table list * * * */ CODEC_ENTRY FrontPanelAzaliaCodecTableList[] = { {0x19, 0x02A19040}, {0x1b, 0x02214020}, {0xff, 0xffffffff} }; /** * Current HD Audio support codec list * * * */ CODEC_TBL_LIST AzaliaCodecTableList[] = { {0x010ec0880, &AzaliaCodecAlc882Table[0]}, {0x010ec0882, &AzaliaCodecAlc882Table[0]}, {0x010ec0883, &AzaliaCodecAlc882Table[0]}, {0x010ec0885, &AzaliaCodecAlc882Table[0]}, {0x010ec0889, &AzaliaCodecAlc889Table[0]}, {0x010ec0262, &AzaliaCodecAlc262Table[0]}, {0x010ec0269, &AzaliaCodecAlc269Table[0]}, {0x010ec0861, &AzaliaCodecAlc861Table[0]}, {0x011d41984, &AzaliaCodecAd1984Table[0]}, { (UINT32) 0x0FFFFFFFF, (CODEC_ENTRY*) (UINTN)0x0FFFFFFFF} }; /** * ConfigureAzaliaPinCmd - Configuration HD Audio PIN Command * * * @param[in] FchDataPtr Fch configuration structure pointer. * @param[in] BAR0 HD Audio BAR0 base address. * @param[in] ChannelNum Channel Number. * */ VOID ConfigureAzaliaPinCmd ( IN FCH_DATA_BLOCK *FchDataPtr, IN UINT32 BAR0, IN UINT8 ChannelNum ) { UINT32 AzaliaTempVariable; UINT32 ChannelNumDword; CODEC_TBL_LIST *TempAzaliaOemCodecTablePtr; CODEC_ENTRY *TempAzaliaCodecEntryPtr; if ( (FchDataPtr->Azalia.AzaliaPinCfg) != 1 ) { return; } ChannelNumDword = ChannelNum << 28; AzaliaTempVariable = 0xF0000; AzaliaTempVariable |= ChannelNumDword; WriteMem (BAR0 + 0x60, AccessWidth32, &AzaliaTempVariable); FchStall (600, FchDataPtr->StdHeader); ReadMem (BAR0 + 0x64, AccessWidth32, &AzaliaTempVariable); if ( ((FchDataPtr->Azalia.AzaliaOemCodecTablePtr) == NULL) || ((FchDataPtr->Azalia.AzaliaOemCodecTablePtr) == ((CODEC_TBL_LIST*) (UINTN)0xFFFFFFFF))) { TempAzaliaOemCodecTablePtr = (CODEC_TBL_LIST*) (&AzaliaCodecTableList[0]); } else { TempAzaliaOemCodecTablePtr = (CODEC_TBL_LIST*) FchDataPtr->Azalia.AzaliaOemCodecTablePtr; } while ( TempAzaliaOemCodecTablePtr->CodecId != 0xFFFFFFFF ) { if ( TempAzaliaOemCodecTablePtr->CodecId == AzaliaTempVariable ) { break; } else { ++TempAzaliaOemCodecTablePtr; } } if ( TempAzaliaOemCodecTablePtr->CodecId != 0xFFFFFFFF ) { TempAzaliaCodecEntryPtr = (CODEC_ENTRY*) TempAzaliaOemCodecTablePtr->CodecTablePtr; if ( ((FchDataPtr->Azalia.AzaliaOemCodecTablePtr) == NULL) || ((FchDataPtr->Azalia.AzaliaOemCodecTablePtr) == ((CODEC_TBL_LIST*) (UINTN)0xFFFFFFFF)) ) { TempAzaliaCodecEntryPtr = (CODEC_ENTRY*) (TempAzaliaCodecEntryPtr); } ConfigureAzaliaSetConfigD4Dword (TempAzaliaCodecEntryPtr, ChannelNumDword, BAR0, FchDataPtr->StdHeader); if ( FchDataPtr->Azalia.AzaliaFrontPanel != 1 ) { if ( (FchDataPtr->Azalia.AzaliaFrontPanel == 2) || (FchDataPtr->Azalia.FrontPanelDetected == 1) ) { if ( ((FchDataPtr->Azalia.AzaliaOemFpCodecTablePtr) == NULL) || ((FchDataPtr->Azalia.AzaliaOemFpCodecTablePtr) == (VOID*) (UINTN)0xFFFFFFFF) ) { TempAzaliaCodecEntryPtr = (CODEC_ENTRY*) (&FrontPanelAzaliaCodecTableList[0]); } else { TempAzaliaCodecEntryPtr = (CODEC_ENTRY*) FchDataPtr->Azalia.AzaliaOemFpCodecTablePtr; } ConfigureAzaliaSetConfigD4Dword (TempAzaliaCodecEntryPtr, ChannelNumDword, BAR0, FchDataPtr->StdHeader); } } } } /** * ConfigureAzaliaSetConfigD4Dword - Configuration HD Audio Codec table * * * @param[in] TempAzaliaCodecEntryPtr HD Audio Codec table structure pointer. * @param[in] ChannelNumDword HD Audio Channel Number. * @param[in] BAR0 HD Audio BAR0 base address. * @param[in] StdHeader * */ VOID ConfigureAzaliaSetConfigD4Dword ( IN CODEC_ENTRY *TempAzaliaCodecEntryPtr, IN UINT32 ChannelNumDword, IN UINT32 BAR0, IN AMD_CONFIG_PARAMS *StdHeader ) { UINT8 TempByte1; UINT8 TempByte2; UINT8 Index; UINT32 TempDword1; UINT32 TempDword2; TempDword1 = 0; TempDword2 = 0; while ( (TempAzaliaCodecEntryPtr->Nid) != 0xFF ) { TempByte1 = 0x20; if ( (TempAzaliaCodecEntryPtr->Nid) == 0x1 ) { TempByte1 = 0x24; } TempDword1 = TempAzaliaCodecEntryPtr->Nid; TempDword1 &= 0xff; TempDword1 <<= 20; TempDword1 |= ChannelNumDword; TempDword1 |= (0x700 << 8); for ( Index = 4; Index > 0; Index-- ) { do { ReadMem (BAR0 + 0x68, AccessWidth32, &TempDword2); } while ( (TempDword2 & BIT0) != 0 ); TempByte2 = (UINT8) (( (TempAzaliaCodecEntryPtr->Byte40) >> ((4 - Index) * 8 ) ) & 0xff); TempDword1 = (TempDword1 & 0xFFFF0000) + ((TempByte1 - Index) << 8) + TempByte2; WriteMem (BAR0 + 0x60, AccessWidth32, &TempDword1); FchStall (60, StdHeader); } ++TempAzaliaCodecEntryPtr; } }