/** * @file * * Southbridge Init during POWER-ON * * Prepare Southbridge environment during power on stage. * * @xrefitem bom "File Content Label" "Release Content" * @e project: CIMx-SB * @e sub-project: * @e \$Revision:$ @e \$Date:$ * */ /*;******************************************************************************** ; ; Copyright (c) 2011, 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 "SbPlatform.h" #include "cbtypes.h" #include "AmdSbLib.h" #include "Hudson-2.h" /** * sbPorInitPciTable - PCI device registers initial during the power on stage. * * * * */ REG8MASK sbPorInitPciTable[] = { // SATA device {0x00, SATA_BUS_DEV_FUN, 0}, {SB_SATA_REG84 + 3, ~BIT2, 0}, {SB_SATA_REGA0, ~(BIT2 + BIT3 + BIT4 + BIT5 + BIT6), BIT2 + BIT3 + BIT4 + BIT5}, {0xFF, 0xFF, 0xFF}, // LPC Device (Bus 0, Dev 20, Func 3) {0x00, LPC_BUS_DEV_FUN, 0}, {SB_LPC_REG44, 0xFF, BIT6 + BIT7}, //Enable COM1 and COM2 {SB_LPC_REG47, 0xFF, BIT5}, {SB_LPC_REG48, 0x00, BIT0 + BIT1 + BIT2}, {SB_LPC_REG7C, 0x00, BIT0 + BIT2}, {SB_LPC_REG78, 0xF0, BIT2 + BIT3}, // Enable LDRQ pin {SB_LPC_REGBB, 0xFF, BIT3 + BIT4 + BIT5}, // A12 set 0xBB [5:3] = 111 to improve SPI timing margin. // A12 Set 0xBA [6:5] = 11 improve SPI timing margin. (SPI Prefetch enhancement) {SB_LPC_REGBB, 0xBE, BIT0 + BIT3 + BIT4 + BIT5}, {SB_LPC_REGBA, 0x9F, BIT5 + BIT6}, {SB_LPC_REGA4, ~ BIT0, BIT0}, //[BUG Fix] Force EC_PortActive to 1 to fix possible IR non function issue when NO_EC_SUPPORT is defined {0xFF, 0xFF, 0xFF}, // P2P Bridge (Bus 0, Dev 20, Func 4) {0x00, PCIB_BUS_DEV_FUN, 0}, {SB_PCIB_REG4B, 0xFF, BIT6 + BIT7 + BIT4}, // ENH230012: Disable P2P bridge decoder for IO address 0x1000-0x1FFF in SBPOR // ENH260809: Add PCI port 80 support in Hudson-2/3 #ifdef SB_PCIB_PORT_80_SUPPORT {SB_PCIB_REG1C, 0x00, 0xF0}, {SB_PCIB_REG1D, 0x00, 0x00}, {SB_PCIB_REG04, 0x00, 0x21}, #endif {SB_PCIB_REG40, 0xDF, 0x20}, {SB_PCIB_REG50, 0x02, 0x01}, {0xFF, 0xFF, 0xFF}, }; /** * sbPmioPorInitTable - Southbridge ACPI MMIO initial during the power on stage. * * * * */ AcpiRegWrite sbPmioPorInitTable[] = { {00, 00, 0xB0, 0xAC}, // Signature {MISC_BASE >> 8, SB_MISC_REG41, 0x1F, 0x40}, //keep Auxiliary_14Mclk_Sel [12] //RPR 8.9 USB 3.0 Reference Clock MISC_REG 0x40 [4] = 0 Enable spread-spectrum reference clock. {MISC_BASE >> 8, SB_MISC_REG40, 0xEF, 0x00}, // {MISC_BASE >> 8, 0x24 + 2, 0xFF, 0x20}, Testing CPU clk strength {PMIO_BASE >> 8, SB_PMIOA_REG5D, 0x00, BIT0}, {PMIO_BASE >> 8, SB_PMIOA_REGD2, 0xCF, BIT4 + BIT5}, {SMBUS_BASE >> 8, SB_SMBUS_REG12, 0x00, BIT0}, {PMIO_BASE >> 8, SB_PMIOA_REG28, 0xFF, BIT0 + BIT2}, {PMIO_BASE >> 8, SB_PMIOA_REG44 + 3, 0x67, BIT7 + BIT3}, // 2.5 Enable Boot Timer {PMIO_BASE >> 8, SB_PMIOA_REG48, 0xFF, BIT0}, {PMIO_BASE >> 8, SB_PMIOA_REG00, 0xFF, 0x0E}, {PMIO_BASE >> 8, SB_PMIOA_REG00 + 2, 0xFF, 0x40}, {PMIO_BASE >> 8, SB_PMIOA_REG00 + 3, 0xFF, 0x08}, {PMIO_BASE >> 8, SB_PMIOA_REG34, 0xEF, BIT0 + BIT1}, {PMIO_BASE >> 8, SB_PMIOA_REGEC, 0xFD, BIT1}, //{PMIO_BASE >> 8, SB_PMIOA_REG5B, 0xF9, BIT1 + BIT2}, {PMIO_BASE >> 8, SB_PMIOA_REG08, 0xFE, BIT2 + BIT4}, {PMIO_BASE >> 8, SB_PMIOA_REG08 + 1, 0xFF, BIT0}, {PMIO_BASE >> 8, SB_PMIOA_REG54, 0x00, BIT4 + BIT6 + BIT7}, {PMIO_BASE >> 8, SB_PMIOA_REG04 + 3, 0xFD, BIT1}, {PMIO_BASE >> 8, SB_PMIOA_REG74, 0xF6, BIT0 + BIT3}, {PMIO_BASE >> 8, SB_PMIOA_REGF0, ~BIT2, 0x00}, // RPR GEC I/O Termination Setting // PM_Reg 0xF6 = Power-on default setting // PM_Reg 0xF7 = Power-on default setting // PM_Reg 0xF8 = 0x6C // PM_Reg 0xF9 = 0x21 // PM_Reg 0xFA = 0x00 Hudson-2 A12 GEC I/O Pad settings for 3.3V CMOS {PMIO_BASE >> 8, SB_PMIOA_REGF8, 0x00, 0x6C}, {PMIO_BASE >> 8, SB_PMIOA_REGF8 + 1, 0x00, 0x07}, {PMIO_BASE >> 8, SB_PMIOA_REGF8 + 2, 0x00, 0x00}, // PRP GEC -end {PMIO_BASE >> 8, SB_PMIOA_REGC4, 0xee, 0x04}, // Release NB_PCIE_RST {PMIO_BASE >> 8, SB_PMIOA_REGC0 + 2, 0xBF, 0x40}, {PMIO_BASE >> 8, SB_PMIOA_REGBE, 0xDF, BIT5}, //OBS200280 //{PMIO_BASE >> 8, SB_PMIOA_REGBE, 0xFF, BIT1}, {0xFF, 0xFF, 0xFF, 0xFF}, }; /** * sbPowerOnInit - Config Southbridge during power on stage. * * * * @param[in] pConfig Southbridge configuration structure pointer. * */ VOID sbPowerOnInit ( IN AMDSBCFG* pConfig ) { UINT8 dbPortStatus; //UINT8 dbSysConfig; UINT32 abValue; UINT32 abValue2; UINT8 dbValue; UINT8 dbEfuse; UINT32 dbSpiMode; UINT16 dwAsfPort; UINT16 smbusBase; UINT8 cimSataMode; // UINT8 cimSpiFastReadEnable; // UINT8 cimSpiFastReadSpeed; UINT8 cimSataInternal100Spread; UINT8 indexValue; UINT32 ddValue; UINT8 SataPortNum; UINT8 XhciEfuse; XhciEfuse = XHCI_EFUSE_LOCATION; cimSataMode = pConfig->SATAMODE.SataModeReg; // if (pConfig->BuildParameters.SpiFastReadEnable != NULL ) { // cimSpiFastReadEnable = (UINT8) pConfig->BuildParameters.SpiFastReadEnable; // } else { // cimSpiFastReadEnable = cimSpiFastReadEnableDefault; // } // cimSpiFastReadSpeed = (UINT8) pConfig->BuildParameters.SpiFastReadSpeed; cimSataInternal100Spread = ( UINT8 ) pConfig->SataInternal100Spread; #if SB_CIMx_PARAMETER == 0 cimSataMode = (UINT8) ((cimSataMode & 0xFB) | cimSataSetMaxGen2Default); cimSataMode = (UINT8) ((cimSataMode & 0x0F) | cimSataClkModeDefault); cimSpiFastReadEnable = cimSpiFastReadEnableDefault; cimSpiFastReadSpeed = cimSpiFastReadSpeedDefault; cimSataInternal100Spread = SataInternal100SpreadDefault; #endif TRACE ((DMSG_SB_TRACE, "CIMx - Entering sbPowerOnInit \n")); // Hudson-2 Only Enabled (Mmio_mem_enablr) // Default value is correct RWPMIO (SB_PMIOA_REG24, AccWidthUint8, 0xFF, BIT0); RWPMIO (0xD3, AccWidthUint8, ~BIT4, 0); RWPMIO (0xD3, AccWidthUint8, ~BIT4, BIT4); if ( pConfig->Cg2Pll == 1 ) { TurnOffCG2 (); pConfig->SATAMODE.SataMode.SataClkMode = 0x0a; } //enable CF9 RWPMIO (0xD2, AccWidthUint8, ~BIT6, 0); // Set A-Link bridge access address. This address is set at device 14h, function 0, // register 0f0h. This is an I/O address. The I/O address must be on 16-byte boundary. RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGE0, AccWidthUint32, 00, ALINK_ACCESS_INDEX); writeAlink (0x80000004, 0x04); // RPR 4.2 Enable Hudson-2 to issue memory read/write requests in the upstream direction abValue = readAlink (SB_ABCFG_REG9C | (UINT32) (ABCFG << 29)); // RPR 4.5 Disable the credit variable in the downstream arbitration equation abValue = abValue | BIT0; writeAlink (SB_ABCFG_REG9C | (UINT32) (ABCFG << 29), abValue); writeAlink (0x30, 0x10); // AXINDC 0x10[9]=1, Enabling Non-Posted memory write for K8 platform. writeAlink (0x34, readAlink (0x34) | BIT9); rwAlink (SB_ABCFG_REG10050 | (UINT32) (ABCFG << 29), ~BIT2, 0x00); // Enable external Stickybit register reset feature //writeAlink (SB_AX_INDXC_REG30 | (UINT32) (AXINDC << 29), 0x30); //abValue = readAlink (SB_AX_DATAC_REG34 | (UINT32) (AXINDC << 29)); //abValue |= BIT6 + BIT5; //writeAlink (SB_AX_DATAC_REG34 | (UINT32) (AXINDC << 29), abValue); // Configure UMI target link speed dbEfuse = PCIE_FORCE_GEN1_EFUSE_LOCATION; getEfuseStatus (&dbEfuse); if ( dbEfuse & BIT0 ) { pConfig->NbSbGen2 = 0; } dbEfuse = FCH_Variant_EFUSE_LOCATION; getEfuseStatus (&dbEfuse); if ((dbEfuse == 0x07) || (dbEfuse == 0x08)) { pConfig->NbSbGen2 = 0; } if (pConfig->NbSbGen2) { abValue = 2; abValue2 = BIT0; } else { abValue = 1; abValue2 = 0; } rwAlink (SB_AX_INDXP_REGA4, 0xFFFFFFFE, abValue2); rwAlink ((UINT32)SB_AX_CFG_REG88, 0xFFFFFFF0, abValue); if (pConfig->sdbEnable) { rwAlink (SB_ABCFG_REGC0 | (UINT32) (ABCFG << 29), ~BIT12, 0x00); RWMEM (ACPI_MMIO_BASE + SERIAL_DEBUG_BASE + 0, AccWidthUint8, 0, pConfig->Debug_Reg00); RWMEM (ACPI_MMIO_BASE + SERIAL_DEBUG_BASE + 2, AccWidthUint8, 0, pConfig->Debug_Reg02); RWMEM (ACPI_MMIO_BASE + SERIAL_DEBUG_BASE + 4, AccWidthUint8, 0, pConfig->Debug_Reg04); RWMEM (ACPI_MMIO_BASE + SERIAL_DEBUG_BASE + 1, AccWidthUint8, 0, pConfig->Debug_Reg01); RWMEM (ACPI_MMIO_BASE + SERIAL_DEBUG_BASE + 3, AccWidthUint8, 0, pConfig->Debug_Reg03); RWMEM (ACPI_MMIO_BASE + SERIAL_DEBUG_BASE + 5, AccWidthUint8, 0, pConfig->Debug_Reg05); } // Set Build option into SB WritePCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REG64, AccWidthUint16 | S3_SAVE, &(pConfig->BuildParameters.SioPmeBaseAddress)); RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGA0, AccWidthUint32 | S3_SAVE, 0x001F, (pConfig->BuildParameters.SpiRomBaseAddress)); RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REG9C, AccWidthUint32 | S3_SAVE, 0, (pConfig->BuildParameters.GecShadowRomBase + 1)); // Enabled SMBUS0/SMBUS1 (ASF) Base Address RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG2C, AccWidthUint16, 06, (pConfig->BuildParameters.Smbus0BaseAddress) + BIT0); //protect BIT[2:1] RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG28, AccWidthUint16, 06, (pConfig->BuildParameters.Smbus1BaseAddress) + BIT0); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG60, AccWidthUint16, 00, (pConfig->BuildParameters.AcpiPm1EvtBlkAddr)); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG62, AccWidthUint16, 00, (pConfig->BuildParameters.AcpiPm1CntBlkAddr)); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG64, AccWidthUint16, 00, (pConfig->BuildParameters.AcpiPmTmrBlkAddr)); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG66, AccWidthUint16, 00, (pConfig->BuildParameters.CpuControlBlkAddr)); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG68, AccWidthUint16, 00, (pConfig->BuildParameters.AcpiGpe0BlkAddr)); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG6A, AccWidthUint16, 00, (pConfig->BuildParameters.SmiCmdPortAddr)); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG6C, AccWidthUint16, 00, (pConfig->BuildParameters.AcpiPmaCntBlkAddr)); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG6E, AccWidthUint16, 00, (pConfig->BuildParameters.SmiCmdPortAddr) + 8); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG48, AccWidthUint32, 00, (pConfig->BuildParameters.WatchDogTimerBase)); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REG2E, AccWidthUint8, ~(BIT1 + BIT2), 0); //clear BIT[2:1] smbusBase = (UINT16) (pConfig->BuildParameters.Smbus0BaseAddress); dbValue = 0x00; WriteIO (smbusBase + 0x14, AccWidthUint8, &dbValue); dbEfuse = SATA_FIS_BASE_EFUSE_LOC; getEfuseStatus (&dbEfuse); programSbAcpiMmioTbl ((AcpiRegWrite*) FIXUP_PTR (&sbPmioPorInitTable[0])); //RPR 3.4 Enabling ClkRun Function RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGBB, AccWidthUint8, ~ BIT2, BIT2); //BUG265683: Mismatch clkrun enable register setting between RPR and CIMX code RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGD0, AccWidthUint8, ~ BIT2, 0); SataPortNum = 0; for ( SataPortNum = 0; SataPortNum < 0x06; SataPortNum++ ) { RWPCI (((SATA_BUS_DEV_FUN << 16) + SB_SATA_REG40 + 2), AccWidthUint8, 0xFF, 1 << SataPortNum); SbStall (2); RWPCI (((SATA_BUS_DEV_FUN << 16) + SB_SATA_REG40 + 2), AccWidthUint8, (0xFF ^ (1 << SataPortNum)) , 0x00); SbStall (2); } dbValue = 0x0A; WriteIO (SB_IOMAP_REG70, AccWidthUint8, &dbValue); ReadIO (SB_IOMAP_REG71, AccWidthUint8, &dbValue); dbValue &= 0xEF; WriteIO (SB_IOMAP_REG71, AccWidthUint8, &dbValue); RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG00, AccWidthUint32 | S3_SAVE, 0xFFFFFFFF, (BIT19 + BIT24 + BIT25 + BIT26)); RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG0C, AccWidthUint32 | S3_SAVE, 0xFFC0FFFF, 0 ); if (pConfig->BuildParameters.SpiSpeed) { RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG0C, AccWidthUint32 | S3_SAVE, ~(BIT13 + BIT12), ((pConfig->BuildParameters.SpiSpeed - 1 ) << 12)); } if (pConfig->BuildParameters.SpiFastSpeed) { RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG0C, AccWidthUint32 | S3_SAVE, ~(BIT15 + BIT14), ((pConfig->BuildParameters.SpiFastSpeed - 1 ) << 14)); } //if (pConfig->BuildParameters.SpiBurstWrite) { RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG1C, AccWidthUint32 | S3_SAVE, ~(BIT10), ((pConfig->BuildParameters.SpiBurstWrite) << 10)); //} dbSpiMode = pConfig->BuildParameters.SpiMode; if (pConfig->BuildParameters.SpiMode) { if ((dbSpiMode == SB_SPI_MODE_QUAL_114) || (dbSpiMode == SB_SPI_MODE_QUAL_112) || (dbSpiMode == SB_SPI_MODE_QUAL_144) || (dbSpiMode == SB_SPI_MODE_QUAL_122)) { // RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG00, AccWidthUint32 | S3_SAVE, 0xFFFF0000, 0x013e); // RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG0C, AccWidthUint32 | S3_SAVE, 0xFFFFFF00, 0x80 ); // RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG00, AccWidthUint32 | S3_SAVE, 0xFFFEFFFF, 0x10000); // SbStall (1000); } RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG00, AccWidthUint32 | S3_SAVE, ~( BIT18 + BIT29 + BIT30), ((pConfig->BuildParameters.SpiMode & 1) << 18) + ((pConfig->BuildParameters.SpiMode & 6) << 28)); } // if ( cimSpiFastReadSpeed ) { // RWMEM ((pConfig->BuildParameters.SpiRomBaseAddress) + SB_SPI_MMIO_REG0C, AccWidthUint16 | S3_SAVE, ~(BIT15 + BIT14), ( cimSpiFastReadSpeed << 14)); // } //Program power on pci init table programPciByteTable ( (REG8MASK*) FIXUP_PTR (&sbPorInitPciTable[0]), sizeof (sbPorInitPciTable) / sizeof (REG8MASK) ); programSbAcpiMmioTbl ((AcpiRegWrite *) (pConfig->OEMPROGTBL.OemProgrammingTablePtr_Ptr)); RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REG6C, AccWidthUint32 | S3_SAVE, 0xFFFFFF00, 0); if (pConfig->SATAMODE.SataModeReg == 0) { pConfig->SATAMODE.SataModeReg = (pConfig->SATAMODE.SataMode.SataController << 0) \ + (pConfig->SATAMODE.SataMode.SataIdeCombMdPriSecOpt << 1) \ + (pConfig->SATAMODE.SataMode.SataSetMaxGen2 << 2) \ + (pConfig->SATAMODE.SataMode.SataIdeCombinedMode << 3) \ + (pConfig->SATAMODE.SataMode.SataClkMode << 4); } RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGDA, AccWidthUint8, 0x00, pConfig->SATAMODE.SataModeReg); if (dbEfuse & BIT0) { RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGDA, AccWidthUint8, 0xFB, 0x04); } ReadMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGDA, AccWidthUint8, &dbPortStatus); if ( ((dbPortStatus & 0xF0) == 0x10) ) { RWMEM (ACPI_MMIO_BASE + MISC_BASE + SB_PMIOA_REG08, AccWidthUint8, 0, BIT5); } if ( pConfig->BuildParameters.LegacyFree ) { RWPCI (((LPC_BUS_DEV_FUN << 16) + SB_LPC_REG44), AccWidthUint32 | S3_SAVE, 00, 0x0003C000); } else { RWPCI (((LPC_BUS_DEV_FUN << 16) + SB_LPC_REG44), AccWidthUint32 | S3_SAVE, 00, 0xFF03FFD5); } if ( cimSataInternal100Spread ) { RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x1E, AccWidthUint8, 0xFF, BIT4); RWPCI (((SATA_BUS_DEV_FUN << 16) + SB_SATA_REG84), AccWidthUint32, 0xFFFFFFFB, 0x00); } else { RWMEM (ACPI_MMIO_BASE + MISC_BASE + 0x1E, AccWidthUint8, ~BIT4, 0x00); } // Toggle GEVENT4 to reset all GPP devices sbGppTogglePcieReset (pConfig); if ( cimSataInternal100Spread ) { RWPCI (((SATA_BUS_DEV_FUN << 16) + SB_SATA_REG84), AccWidthUint32, 0xFFFFFFFF, 0x04); } dbValue = 0x08; WriteIO (SB_IOMAP_REGC00, AccWidthUint8, &dbValue); ReadIO (SB_IOMAP_REGC01, AccWidthUint8, &dbValue); if ( !pConfig->BuildParameters.EcKbd ) { // Route SIO IRQ1/IRQ12 to USB IRQ1/IRQ12 input dbValue = dbValue | 0x0A; } WriteIO (SB_IOMAP_REGC01, AccWidthUint8, &dbValue); dbValue = 0x09; WriteIO (SB_IOMAP_REGC00, AccWidthUint8, &dbValue); ReadIO (SB_IOMAP_REGC01, AccWidthUint8, &dbValue); if ( !pConfig->BuildParameters.EcKbd ) { // Route SIO IRQ1/IRQ12 to USB IRQ1/IRQ12 input dbValue = dbValue & 0xF9; } if ( pConfig->BuildParameters.LegacyFree ) { // Disable IRQ1/IRQ12 filter enable for Legacy free with USB KBC emulation. dbValue = dbValue & 0x9F; } // Enabled IRQ input dbValue = dbValue | BIT4; WriteIO (SB_IOMAP_REGC01, AccWidthUint8, &dbValue); dwAsfPort = ((UINT16) pConfig->BuildParameters.Smbus1BaseAddress & 0xFFF0); if ( dwAsfPort != 0 ) { RWIO (dwAsfPort + 0x0E, AccWidthUint8, 0x0, 0x70); // 0x70 will change to EQU ( Remote control address) } #ifndef NO_EC_SUPPORT getChipSysMode (&dbPortStatus); if ( ((dbPortStatus & ChipSysEcEnable) == 0x00) ) { // EC is disabled by jumper setting or board config RWPCI (((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGA4), AccWidthUint16 | S3_SAVE, 0xFFFE, BIT0); } else { RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGC4, AccWidthUint8, 0xF7, 0x08); ecPowerOnInit ( pConfig); imcSleep ( pConfig); } #endif ReadPCI ((USB_XHCI_BUS_DEV_FUN << 16) + 0x00, AccWidthUint32, &ddValue); ReadPCI ((USB_XHCI_BUS_DEV_FUN << 16) + 0x00, AccWidthUint32, &ddValue); if ( ddValue == 0x78121022 ) { // // First Xhci controller. // ReadPCI ((USB_XHCI_BUS_DEV_FUN << 16) + 0x00, AccWidthUint32, &ddValue); ddValue = 0; indexValue = XHCI_REGISTER_BAR03; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); ddValue = (UINT32) dbValue; indexValue = XHCI_REGISTER_BAR02; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); ddValue <<= 8; ddValue |= (UINT32) dbValue; indexValue = XHCI_REGISTER_BAR01; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); ddValue <<= 8; ddValue |= (UINT32) dbValue; indexValue = XHCI_REGISTER_BAR00; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); ddValue <<= 8; ddValue |= (UINT32) dbValue; WritePCI ((USB_XHCI_BUS_DEV_FUN << 16) + 0x10, AccWidthUint32, &ddValue); indexValue = XHCI_REGISTER_04H; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); WritePCI ((USB_XHCI_BUS_DEV_FUN << 16) + 0x04, AccWidthUint8, &dbValue); indexValue = XHCI_REGISTER_0CH; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); WritePCI ((USB_XHCI_BUS_DEV_FUN << 16) + 0x0C, AccWidthUint8, &dbValue); indexValue = XHCI_REGISTER_3CH; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); WritePCI ((USB_XHCI_BUS_DEV_FUN << 16) + 0x3C, AccWidthUint8, &dbValue); // // Second Xhci controller. // ReadPCI ((USB_XHCI1_BUS_DEV_FUN << 16) + 0x00, AccWidthUint32, &ddValue); ddValue = 0; indexValue = XHCI1_REGISTER_BAR03; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); ddValue = (UINT32) dbValue; indexValue = XHCI1_REGISTER_BAR02; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); ddValue <<= 8; ddValue |= (UINT32) dbValue; indexValue = XHCI1_REGISTER_BAR01; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); ddValue <<= 8; ddValue |= (UINT32) dbValue; indexValue = XHCI1_REGISTER_BAR00; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); ddValue <<= 8; ddValue |= (UINT32) dbValue; WritePCI ((USB_XHCI1_BUS_DEV_FUN << 16) + 0x10, AccWidthUint32, &ddValue); indexValue = XHCI1_REGISTER_04H; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); WritePCI ((USB_XHCI1_BUS_DEV_FUN << 16) + 0x04, AccWidthUint8, &dbValue); indexValue = XHCI1_REGISTER_0CH; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); WritePCI ((USB_XHCI1_BUS_DEV_FUN << 16) + 0x0C, AccWidthUint8, &dbValue); indexValue = XHCI1_REGISTER_3CH; WriteIO (SB_IOMAP_REGCD4, AccWidthUint8, &indexValue); ReadIO (SB_IOMAP_REGCD5, AccWidthUint8, &dbValue); WritePCI ((USB_XHCI1_BUS_DEV_FUN << 16) + 0x3C, AccWidthUint8, &dbValue); } // RPR 3.2 Enabling SPI ROM Prefetch // Set LPC cfg 0xBA bit 8 RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGBA, AccWidthUint16 | S3_SAVE, 0xFFFF, BIT8); if (IsSbA12Plus ()) { // Enable SPI Prefetch for USB, set LPC cfg 0xBA bit 7 to 1 for A12 and above RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGBA, AccWidthUint16 | S3_SAVE, 0xFFFF, BIT7); } #ifdef XHCI_SUPPORT #ifdef XHCI_INIT_IN_ROM_SUPPORT if ( pConfig->XhciSwitch == 1 ) { if ( pConfig->S3Resume == 0 ) { XhciEarlyInit (); } else { XhciInitIndirectReg (); } } else { // for power saving. // add Efuse checking for Xhci enable/disable getEfuseStatus (&XhciEfuse); if ((XhciEfuse & (BIT0 + BIT1)) != (BIT0 + BIT1)) { RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, 0xF0FFFBFF, 0x0); } } #endif #endif } #ifdef XHCI_SUPPORT VOID XhciInitIndirectReg ( ) { UINT32 ddDrivingStrength; UINT32 port; ddDrivingStrength = 0; port = 0; #ifdef SB_USB_BATTERY_CHARGE_SUPPORT RWXhciIndReg ( 0x40000018, 0xFFFFFFFF, 0x00000030); #endif // // RPR SuperSpeed PHY Configuration (adaptation mode setting) // RWXhciIndReg ( SB_XHCI_IND_REG94, 0xFFFFFC00, 0x00000021); RWXhciIndReg ( SB_XHCI_IND_REGD4, 0xFFFFFC00, 0x00000021); // // RPR SuperSpeed PHY Configuration (CR phase and frequency filter settings) // RWXhciIndReg ( SB_XHCI_IND_REG98, 0xFFFFFFC0, 0x0000000A); RWXhciIndReg ( SB_XHCI_IND_REGD8, 0xFFFFFFC0, 0x0000000A); // // RPR BLM Meaasge // RWXhciIndReg ( SB_XHCI_IND_REG00, 0xF8FFFFFF, 0x07000000); // // RPR 8.13 xHCI USB 2.0 PHY Settings // Step 1 is done by hardware default // Step 2 #ifdef USB3_EHCI_DRIVING_STRENGTH for (port = 0; port < 4; port ++) { ddDrivingStrength = (USB3_EHCI_DRIVING_STRENGTH >> (port * 4)) & 0xF; if (ddDrivingStrength & BIT3) { ddDrivingStrength &= 0x07; if (port < 2) { RWXhci0IndReg ( SB_XHCI_IND60_REG00, 0xFFFE0FF8, (port << 13) + ddDrivingStrength); RWXhci0IndReg ( SB_XHCI_IND60_REG00, 0xFFFFEFFF, 0x00001000); } else { RWXhci1IndReg ( SB_XHCI_IND60_REG00, 0xFFFE0FF8, (port << 13) + ddDrivingStrength); RWXhci1IndReg ( SB_XHCI_IND60_REG00, 0xFFFFEFFF, 0x00001000); } } } #endif // Step 3 if (IsSbA11 ()) { RWXhciIndReg ( SB_XHCI_IND60_REG0C, ~ ((UINT32) (0x0f << 8)), ((UINT32) (0x00 << 8))); RWXhciIndReg ( SB_XHCI_IND60_REG08, ~ ((UINT32) (0xff << 8)), ((UINT32) (0x15 << 8))); } else { RWXhciIndReg ( SB_XHCI_IND60_REG0C, ~ ((UINT32) (0x0f << 8)), ((UINT32) (0x02 << 8))); RWXhciIndReg ( SB_XHCI_IND60_REG08, ~ ((UINT32) (0xff << 8)), ((UINT32) (0x0f << 8))); } } VOID XhciEarlyInit ( ) { UINT16 BcdAddress; UINT16 BcdSize; UINT16 AcdAddress; UINT16 AcdSize; UINT16 FwAddress; UINT16 FwSize; UINTN XhciFwStarting; UINT32 SpiValidBase; UINT32 RegData; UINT16 i; RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, 0x00000000, 0x00400700); SbStall (20); // // Get ROM SIG starting address for USB firmware starting address (offset 0x0C to SIG address) // GetRomSigPtr (&XhciFwStarting); if (XhciFwStarting == 0) { return; } XhciFwStarting = ACPIMMIO32 (XhciFwStarting + FW_TO_SIGADDR_OFFSET); if (IsLpcRom ()) { //XHCI firmware re-load RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGCC, AccWidthUint32 | S3_SAVE, ~BIT2, (BIT2 + BIT1 + BIT0)); RWPCI ((LPC_BUS_DEV_FUN << 16) + SB_LPC_REGCC, AccWidthUint32 | S3_SAVE, 0x00000FFF, (UINT32) (XhciFwStarting)); } // // RPR Enable SuperSpeed receive special error case logic. 0x20 bit8 // RPR Enable USB2.0 RX_Valid Synchronization. 0x20 bit9 // Enable USB2.0 DIN/SE0 Synchronization. 0x20 bit10 // RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG20, AccWidthUint32, 0xFFFFF8FF, 0x00000700); // // RPR SuperSpeed PHY Configuration (adaptation timer setting) // RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG90, AccWidthUint32, 0xFFF00000, 0x000AAAAA); //RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG90 + 0x40, AccWidthUint32, 0xFFF00000, 0x000AAAAA); // // Step 1. to enable Xhci IO and Firmware load mode // #ifdef XHCI_SUPPORT_ONE_CONTROLLER RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, 0xF0FFFFFC, 0x00000001); #else RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, 0xF0FFFFFC, 0x00000003); #endif RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, 0xEFFFFFFF, 0x10000000); // // Step 2. to read a portion of the USB3_APPLICATION_CODE from BIOS ROM area and program certain registers. // RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGA0, AccWidthUint32, 0x00000000, (SPI_HEAD_LENGTH << 16)); BcdAddress = ACPIMMIO16 (XhciFwStarting + BCD_ADDR_OFFSET); BcdSize = ACPIMMIO16 (XhciFwStarting + BCD_SIZE_OFFSET); RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGA4, AccWidthUint16, 0x0000, BcdAddress); RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGA4 + 2, AccWidthUint16, 0x0000, BcdSize); AcdAddress = ACPIMMIO16 (XhciFwStarting + ACD_ADDR_OFFSET); AcdSize = ACPIMMIO16 (XhciFwStarting + ACD_SIZE_OFFSET); RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGA8, AccWidthUint16, 0x0000, AcdAddress); RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGA8 + 2, AccWidthUint16, 0x0000, AcdSize); SpiValidBase = SPI_BASE2 (XhciFwStarting + 4) | SPI_BAR0_VLD | SPI_BASE0 | SPI_BAR1_VLD | SPI_BASE1 | SPI_BAR2_VLD; RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGB0, AccWidthUint32, 0x00000000, SpiValidBase); // // Copy Type0/1/2 data block from ROM image to MMIO starting from 0xC0 // for (i = 0; i < SPI_HEAD_LENGTH; i++) { RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGC0 + i, AccWidthUint8, 0, ACPIMMIO8 (XhciFwStarting + i)); } for (i = 0; i < BcdSize; i++) { RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGC0 + SPI_HEAD_LENGTH + i, AccWidthUint8, 0, ACPIMMIO8 (XhciFwStarting + BcdAddress + i)); } for (i = 0; i < AcdSize; i++) { RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGC0 + SPI_HEAD_LENGTH + BcdSize + i, AccWidthUint8, 0, ACPIMMIO8 (XhciFwStarting + AcdAddress + i)); } // // Step 3. to enable the instruction RAM preload functionality. // FwAddress = ACPIMMIO16 (XhciFwStarting + FW_ADDR_OFFSET); RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGB4, AccWidthUint16, 0x0000, ACPIMMIO16 (XhciFwStarting + FwAddress)); FwAddress += 2; RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG04, AccWidthUint16, 0x0000, FwAddress); FwSize = ACPIMMIO16 (XhciFwStarting + FW_SIZE_OFFSET); RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG04 + 2, AccWidthUint16, 0x0000, FwSize); // // Set the starting address offset for Instruction RAM preload. // RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG08, AccWidthUint16, 0x0000, 0); RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, ~BIT29, BIT29); for (;;) { ReadMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00 , AccWidthUint32, &RegData); if (RegData & BIT30) break; } RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, ~BIT29, 0); // // Step 4. to release resets in XHCI_ACPI_MMIO_AMD_REG00. wait for USPLL to lock by polling USPLL lock. // RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, ~U3PLL_RESET, 0); //Release U3PLLreset for (;;) { ReadMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00 , AccWidthUint32, &RegData); if (RegData & U3PLL_LOCK) break; } RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, ~U3PHY_RESET, 0); //Release U3PHY RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, ~U3CORE_RESET, 0); //Release core reset // RPR 8.8 SuperSpeed PHY Configuration, it is only for A11. if (IsSbA11 ()) { RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG90, AccWidthUint32, 0xFFF00000, 0x000AAAAA); // RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REGD0, AccWidthUint32, 0xFFF00000, 0x000AAAAA); // } XhciInitIndirectReg (); RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGEF, AccWidthUint8, ~(BIT4 + BIT5), 0); // Disable Device 22 RWMEM (ACPI_MMIO_BASE + PMIO_BASE + SB_PMIOA_REGEF, AccWidthUint8, ~(BIT7), BIT7); // Enable 2.0 devices //if (!(pConfig->S4Resume)) { RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, ~(BIT21), BIT21); //SMI //} // // Step 5. // RWMEM (ACPI_MMIO_BASE + XHCI_BASE + XHCI_ACPI_MMIO_AMD_REG00, AccWidthUint32, ~(BIT17 + BIT18 + BIT19), BIT17 + BIT18); } #endif