/* $NoKeywords:$ */ /** * @file * * Config Fch Gpp controller * * Init Gpp Controller features. * * @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" #include "Ids.h" #include "Filecode.h" #define FILECODE PROC_FCH_PCIE_GPPLATE_FILECODE // // Declaration of local functions // /** * FchGppSetAspm - Set GPP ASPM * * * @param[in] PciAddress PCI Address. * @param[in] LxState Lane State. * @param[in] StdHeader * */ STATIC VOID FchGppSetAspm ( IN UINT32 PciAddress, IN UINT8 LxState, IN AMD_CONFIG_PARAMS *StdHeader ) { UINT8 PcieCapOffset; UINT8 DeviceType; PcieCapOffset = FchFindPciCap (PciAddress, PCIE_CAP_ID, StdHeader); if (PcieCapOffset) { // // Read link capabilities register (0x0C[11:10] - ASPM support) // ReadPci (PciAddress + PcieCapOffset + 0x0D, AccessWidth8, &DeviceType, StdHeader); if (DeviceType & BIT2) { DeviceType = (DeviceType >> 2) & (BIT1 + BIT0); // // Set ASPM state in link control register // RwPci (PciAddress + PcieCapOffset + 0x10, AccessWidth8, 0xffffffff, LxState & DeviceType, StdHeader); } } } /** * FchGppSetEpAspm - Set EP ASPM * * * @param[in] PciAddress PCI Address. * @param[in] LxState Lane State. * @param[in] StdHeader * */ STATIC VOID FchGppSetEpAspm ( IN UINT32 PciAddress, IN UINT8 LxState, IN AMD_CONFIG_PARAMS *StdHeader ) { UINT8 DeviceType; UINT8 MaxFuncs; UINT32 DevBDF; MaxFuncs = 1; ReadPci (PciAddress + 0x0E, AccessWidth8, &DeviceType, StdHeader); if (DeviceType & BIT7) { MaxFuncs = 8; /// multi-function device } while (MaxFuncs != 0) { DevBDF = PciAddress + (UINT32) ((MaxFuncs - 1) << 16); FchGppSetAspm (DevBDF, LxState, StdHeader); MaxFuncs--; } } /** * FchGppValidateAspm - Validate EndPoint support for GPP ASPM * * * @param[in] PciAddress PCI Address. * @param[in] LxState Lane State. * @param[in] StdHeader * */ STATIC VOID FchGppValidateAspm ( IN UINT32 PciAddress, IN UINT8 *LxState, IN AMD_CONFIG_PARAMS *StdHeader ) { UINT8 PcieCapOffset; UINT8 DeviceType; UINT8 MaxFuncs; UINT32 DevBDF; MaxFuncs = 1; ReadPci (PciAddress + 0x0E, AccessWidth8, &DeviceType, StdHeader); if (DeviceType & BIT7) { MaxFuncs = 8; /// multi-function device } while (MaxFuncs != 0) { DevBDF = PciAddress + (UINT32) ((MaxFuncs - 1) << 16); PcieCapOffset = FchFindPciCap (DevBDF, PCIE_CAP_ID, StdHeader); if (PcieCapOffset) { // // Read link capabilities register (0x0C[11:10] - ASPM support) // ReadPci (DevBDF + PcieCapOffset + 0x0D, AccessWidth8, &DeviceType, StdHeader); if (DeviceType & BIT2) { DeviceType = (DeviceType >> 2) & (BIT1 + BIT0); // // Update ASPM state as what endpoint support // *LxState &= DeviceType; } } MaxFuncs--; } } /** * FchInitLateGpp - Prepare Gpp controller to boot to OS. * * PcieGppLateInit * * @param[in] FchDataPtr Fch configuration structure pointer. * */ VOID FchInitLateGpp ( IN VOID *FchDataPtr ) { UINT8 PortId; UINT8 BusNum; UINT8 PortAspmValue; UINT8 AllowStrapControlByAB; UINT8 GppS3Data; FCH_GPP_PORT_CONFIG *PortCfg; UINT32 PciAspmValue; UINT32 AbValue; FCH_DATA_BLOCK *LocalCfgPtr; AMD_CONFIG_PARAMS *StdHeader; LocalCfgPtr = (FCH_DATA_BLOCK *) FchDataPtr; StdHeader = LocalCfgPtr->StdHeader; // // Disable hidden register decode and serial number capability // AbValue = ReadAlink (FCH_ABCFG_REG330 | (UINT32) (ABCFG << 29), StdHeader); WriteAlink (FCH_ABCFG_REG330 | (UINT32) (ABCFG << 29), AbValue & ~(BIT26 + BIT10), StdHeader); // // Configure ASPM & Save GPP port status into CMOS // AllowStrapControlByAB = 0x01; GppS3Data = 0x00; for ( PortId = 0; PortId < MAX_GPP_PORTS; PortId++ ) { // // write pci_reg3d with 0x01 to fix yellow mark for GPP bridge under some OS // when native PCIE is enabled but MSI is not available // BIF/GPP allowing strap STRAP_BIF_INTERRUPT_PIN_SB controlled by AB reg // PortCfg = &LocalCfgPtr->Gpp.PortCfg[PortId]; if (PortCfg->PortDetected) { GppS3Data |= 1 << (PortId + 4); if (PortCfg->PortIsGen2 == FALSE) { GppS3Data |= 1 << (PortId); } } if (PortCfg->PortHotPlug) { RwPci (PCI_ADDRESS (0, 21, PortId, 0x04), AccessWidth8, 0xFE, 0x00, StdHeader); ///clear IO enable to fix possible hotplug hang } WritePci (PCI_ADDRESS (0, 21, PortId, 0x3d), AccessWidth8, &AllowStrapControlByAB, StdHeader); ReadPci (PCI_ADDRESS (0, 21, PortId, 0x19), AccessWidth8, &BusNum, StdHeader); if (BusNum != 0xFF) { ReadPci (PCI_ADDRESS (BusNum, 0, 0, 0x00), AccessWidth32, &PciAspmValue, StdHeader); if (PciAspmValue != 0xffffffff) { PortAspmValue = LocalCfgPtr->Gpp.GppPortAspm; // // Validate ASPM support on EP side // FchGppValidateAspm (PCI_ADDRESS (BusNum, 0, 0, 0), &PortAspmValue, StdHeader); // // Set ASPM on EP side // FchGppSetEpAspm (PCI_ADDRESS (BusNum, 0, 0, 0), PortAspmValue, StdHeader); // // Set ASPM on port side // FchGppSetAspm (PCI_ADDRESS (0, 21, PortId, 0), PortAspmValue, StdHeader); } } RwAlink ((FCH_RCINDXP_REG02 | (UINT32) (PortId << 24)), (UINT32)~BIT15, BIT15, StdHeader); } RwAlink (FCH_RCINDXC_REG02, (UINT32)~BIT0, BIT0, StdHeader); if ( LocalCfgPtr->Gpp.GppPhyPllPowerDown == TRUE ) { // // Power Saving Feature for GPP Lanes // // Set PCIE_P_CNTL in Alink PCIEIND space // AbValue = ReadAlink (FCH_RCINDXC_REG40, StdHeader); AbValue |= BIT12 + BIT0; AbValue &= ~(BIT9 + BIT4); WriteAlink (FCH_RCINDXC_REG40, AbValue, StdHeader); RwAlink (FCH_RCINDXC_REG02, (UINT32)~(BIT8 + BIT3), BIT8 + BIT3, StdHeader); GppGen2Workaround (&LocalCfgPtr->Gpp, StdHeader); } // // Configure Lock HWInit registers // AbValue = ReadAlink (FCH_ABCFG_REGC0 | (UINT32) (ABCFG << 29), StdHeader); if (AbValue & 0xF0) { AbValue = ReadAlink (FCH_RCINDXC_REG10, StdHeader); WriteAlink (FCH_RCINDXC_REG10, AbValue | BIT0, StdHeader); /// Set HWINIT_WR_LOCK } // // Restore strap0 via override // if (LocalCfgPtr->Gpp.PcieAer) { RwAlink (0x310 | (UINT32) (ABCFG << 29), 0xFFFFFFFF, BIT7, StdHeader); RwAlink (FCH_RCINDXC_REGC0, 0xFFFFFFFF, BIT9, StdHeader); } if (ReadFchSleepType (StdHeader) != ACPI_SLPTYP_S3) { RwMem (ACPI_MMIO_BASE + CMOS_RAM_BASE + 0x0D, AccessWidth8, 0, GppS3Data); } }