/*++ Copyright (c) 2005 - 2009, Intel Corporation. All rights reserved.
This program and the accompanying materials are licensed and made available under the terms and conditions of the BSD License which accompanies this distribution. The full text of the license may be found at http://opensource.org/licenses/bsd-license.php THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. Module Name: PcatPciRootBridge.c Abstract: EFI PC-AT PCI Root Bridge Controller --*/ #include "PcatPciRootBridge.h" #include "DeviceIo.h" EFI_CPU_IO2_PROTOCOL *gCpuIo; typedef struct { PCI_DEVICE_INDEPENDENT_REGION Hdr; union { PCI_CARDBUS_CONTROL_REGISTER CardBridge; PCI_BRIDGE_CONTROL_REGISTER P2PBridge; } Bridge; } PCI_TYPE02; EFI_STATUS EFIAPI InitializePcatPciRootBridge ( IN EFI_HANDLE ImageHandle, IN EFI_SYSTEM_TABLE *SystemTable ) /*++ Routine Description: Initializes the PCI Root Bridge Controller Arguments: ImageHandle - SystemTable - Returns: None --*/ { EFI_STATUS Status; PCAT_PCI_ROOT_BRIDGE_INSTANCE *PrivateData; UINTN PciSegmentIndex; UINTN PciRootBridgeIndex; UINTN PrimaryBusIndex; UINTN NumberOfPciRootBridges; UINTN NumberOfPciDevices; UINTN Device; UINTN Function; UINT16 VendorId; PCI_TYPE02 PciConfigurationHeader; UINT64 Address; UINT64 Value; UINT64 Base; UINT64 Limit; // // Initialize gCpuIo now since the chipset init code requires it. // Status = gBS->LocateProtocol (&gEfiCpuIo2ProtocolGuid, NULL, (VOID **)&gCpuIo); ASSERT_EFI_ERROR(Status); // // Initialize variables required to search all PCI segments for PCI devices // PciSegmentIndex = 0; PciRootBridgeIndex = 0; NumberOfPciRootBridges = 0; PrimaryBusIndex = 0; while (PciSegmentIndex <= PCI_MAX_SEGMENT) { PrivateData = NULL; Status = gBS->AllocatePool( EfiBootServicesData, sizeof (PCAT_PCI_ROOT_BRIDGE_INSTANCE), (VOID **)&PrivateData ); if (EFI_ERROR(Status)) { goto Done; } ZeroMem (PrivateData, sizeof (PCAT_PCI_ROOT_BRIDGE_INSTANCE)); // // Initialize the signature of the private data structure // PrivateData->Signature = PCAT_PCI_ROOT_BRIDGE_SIGNATURE; PrivateData->Handle = NULL; PrivateData->DevicePath = NULL; InitializeListHead (&PrivateData->MapInfo); // // Initialize the PCI root bridge number and the bus range for that root bridge // PrivateData->RootBridgeNumber = (UINT32)PciRootBridgeIndex; PrivateData->PrimaryBus = (UINT32)PrimaryBusIndex; PrivateData->SubordinateBus = (UINT32)PrimaryBusIndex; PrivateData->IoBase = 0xffffffff; PrivateData->MemBase = 0xffffffff; PrivateData->Mem32Base = 0xffffffffffffffffULL; PrivateData->Pmem32Base = 0xffffffffffffffffULL; PrivateData->Mem64Base = 0xffffffffffffffffULL; PrivateData->Pmem64Base = 0xffffffffffffffffULL; // // The default mechanism for performing PCI Configuration cycles is to // use the I/O ports at 0xCF8 and 0xCFC. This is only used for IA-32. // IPF uses SAL calls to perform PCI COnfiguration cycles // PrivateData->PciAddress = 0xCF8; PrivateData->PciData = 0xCFC; // // Get the physical I/O base for performing PCI I/O cycles // For IA-32, this is always 0, because IA-32 has IN and OUT instructions // For IPF, a SAL call is made to retrieve the base address for PCI I/O cycles // Status = PcatRootBridgeIoGetIoPortMapping ( &PrivateData->PhysicalIoBase, &PrivateData->PhysicalMemoryBase ); if (EFI_ERROR(Status)) { goto Done; } // // Get PCI Express Base Address // PrivateData->PciExpressBaseAddress = GetPciExpressBaseAddressForRootBridge (PciSegmentIndex, PciRootBridgeIndex); /* if (PrivateData->PciExpressBaseAddress != 0) { DEBUG ((EFI_D_ERROR, "PCIE Base - 0x%lx\n", PrivateData->PciExpressBaseAddress)); } */ // // Create a lock for performing PCI Configuration cycles // EfiInitializeLock (&PrivateData->PciLock, TPL_HIGH_LEVEL); // // Initialize the attributes for this PCI root bridge // PrivateData->Attributes = 0; // // Build the EFI Device Path Protocol instance for this PCI Root Bridge // Status = PcatRootBridgeDevicePathConstructor (&PrivateData->DevicePath, PciRootBridgeIndex, (BOOLEAN)((PrivateData->PciExpressBaseAddress != 0) ? TRUE : FALSE)); if (EFI_ERROR(Status)) { goto Done; } // // Build the PCI Root Bridge I/O Protocol instance for this PCI Root Bridge // Status = PcatRootBridgeIoConstructor (&PrivateData->Io, PciSegmentIndex); if (EFI_ERROR(Status)) { goto Done; } // // Scan all the PCI devices on the primary bus of the PCI root bridge // for (Device = 0, NumberOfPciDevices = 0; Device <= PCI_MAX_DEVICE; Device++) { for (Function = 0; Function <= PCI_MAX_FUNC; Function++) { // // Compute the PCI configuration address of the PCI device to probe // Address = EFI_PCI_ADDRESS (PrimaryBusIndex, Device, Function, 0); // // Read the Vendor ID from the PCI Configuration Header // Status = PrivateData->Io.Pci.Read ( &PrivateData->Io, EfiPciWidthUint16, Address, sizeof (VendorId) / sizeof (UINT16), &VendorId ); if ((EFI_ERROR(Status)) || ((VendorId == 0xffff) && (Function == 0))) { // // If the PCI Configuration Read fails, or a PCI device does not exist, then // skip this entire PCI device // break; } if (VendorId == 0xffff) { // // If PCI function != 0, VendorId == 0xFFFF, we continue to search PCI function. // continue; } // // Read the entire PCI Configuration Header // Status = PrivateData->Io.Pci.Read ( &PrivateData->Io, EfiPciWidthUint16, Address, sizeof (PciConfigurationHeader) / sizeof (UINT16), &PciConfigurationHeader ); if (EFI_ERROR(Status)) { // // If the entire PCI Configuration Header can not be read, then skip this entire PCI device // break; } // // Increment the number of PCI device found on the primary bus of the PCI root bridge // NumberOfPciDevices++; // // Look for devices with the VGA Palette Snoop enabled in the COMMAND register of the PCI Config Header // if (PciConfigurationHeader.Hdr.Command & 0x20) { PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_PALETTE_IO; } // // If the device is a PCI-PCI Bridge, then look at the Subordinate Bus Number // if (IS_PCI_BRIDGE(&PciConfigurationHeader)) { // // Get the Bus range that the PPB is decoding // if (PciConfigurationHeader.Bridge.P2PBridge.SubordinateBus > PrivateData->SubordinateBus) { // // If the suborinate bus number of the PCI-PCI bridge is greater than the PCI root bridge's // current subordinate bus number, then update the PCI root bridge's subordinate bus number // PrivateData->SubordinateBus = PciConfigurationHeader.Bridge.P2PBridge.SubordinateBus; } // // Get the I/O range that the PPB is decoding // Value = PciConfigurationHeader.Bridge.P2PBridge.IoBase & 0x0f; Base = ((UINT32)PciConfigurationHeader.Bridge.P2PBridge.IoBase & 0xf0) << 8; Limit = (((UINT32)PciConfigurationHeader.Bridge.P2PBridge.IoLimit & 0xf0) << 8) | 0x0fff; if (Value == 0x01) { Base |= ((UINT32)PciConfigurationHeader.Bridge.P2PBridge.IoBaseUpper16 << 16); Limit |= ((UINT32)PciConfigurationHeader.Bridge.P2PBridge.IoLimitUpper16 << 16); } if (Base < Limit) { if (PrivateData->IoBase > Base) { PrivateData->IoBase = Base; } if (PrivateData->IoLimit < Limit) { PrivateData->IoLimit = Limit; } } // // Get the Memory range that the PPB is decoding // Base = ((UINT32)PciConfigurationHeader.Bridge.P2PBridge.MemoryBase & 0xfff0) << 16; Limit = (((UINT32)PciConfigurationHeader.Bridge.P2PBridge.MemoryLimit & 0xfff0) << 16) | 0xfffff; if (Base < Limit) { if (PrivateData->MemBase > Base) { PrivateData->MemBase = Base; } if (PrivateData->MemLimit < Limit) { PrivateData->MemLimit = Limit; } if (PrivateData->Mem32Base > Base) { PrivateData->Mem32Base = Base; } if (PrivateData->Mem32Limit < Limit) { PrivateData->Mem32Limit = Limit; } } // // Get the Prefetchable Memory range that the PPB is decoding // Value = PciConfigurationHeader.Bridge.P2PBridge.PrefetchableMemoryBase & 0x0f; Base = ((UINT32)PciConfigurationHeader.Bridge.P2PBridge.PrefetchableMemoryBase & 0xfff0) << 16; Limit = (((UINT32)PciConfigurationHeader.Bridge.P2PBridge.PrefetchableMemoryLimit & 0xfff0) << 16) | 0xffffff; if (Value == 0x01) { Base |= LShiftU64((UINT64)PciConfigurationHeader.Bridge.P2PBridge.PrefetchableBaseUpper32,32); Limit |= LShiftU64((UINT64)PciConfigurationHeader.Bridge.P2PBridge.PrefetchableLimitUpper32,32); } if (Base < Limit) { if (PrivateData->MemBase > Base) { PrivateData->MemBase = Base; } if (PrivateData->MemLimit < Limit) { PrivateData->MemLimit = Limit; } if (Value == 0x00) { if (PrivateData->Pmem32Base > Base) { PrivateData->Pmem32Base = Base; } if (PrivateData->Pmem32Limit < Limit) { PrivateData->Pmem32Limit = Limit; } } if (Value == 0x01) { if (PrivateData->Pmem64Base > Base) { PrivateData->Pmem64Base = Base; } if (PrivateData->Pmem64Limit < Limit) { PrivateData->Pmem64Limit = Limit; } } } // // Look at the PPB Configuration for legacy decoding attributes // if (PciConfigurationHeader.Bridge.P2PBridge.BridgeControl & 0x04) { PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_ISA_IO; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_ISA_MOTHERBOARD_IO; } if (PciConfigurationHeader.Bridge.P2PBridge.BridgeControl & 0x08) { // PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_PALETTE_IO; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_MEMORY; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_IO; } } else if (IS_CARDBUS_BRIDGE(&PciConfigurationHeader)) { // // Get the Bus range that the PPB is decoding // if (PciConfigurationHeader.Bridge.CardBridge.SubordinateBusNumber > PrivateData->SubordinateBus) { // // If the suborinate bus number of the PCI-PCI bridge is greater than the PCI root bridge's // current subordinate bus number, then update the PCI root bridge's subordinate bus number // PrivateData->SubordinateBus = PciConfigurationHeader.Bridge.CardBridge.SubordinateBusNumber; } // // Get the I/O range that the PPB is decoding // Base = PciConfigurationHeader.Bridge.CardBridge.IoBase0; Limit = PciConfigurationHeader.Bridge.CardBridge.IoLimit0; if (Base < Limit) { if (PrivateData->IoBase > Base) { PrivateData->IoBase = Base; } if (PrivateData->IoLimit < Limit) { PrivateData->IoLimit = Limit; } } // // Get the Memory range that the PPB is decoding // Base = PciConfigurationHeader.Bridge.CardBridge.MemoryBase0; Limit = PciConfigurationHeader.Bridge.CardBridge.MemoryLimit0; if (Base < Limit) { if (PrivateData->MemBase > Base) { PrivateData->MemBase = Base; } if (PrivateData->MemLimit < Limit) { PrivateData->MemLimit = Limit; } if (PrivateData->Mem32Base > Base) { PrivateData->Mem32Base = Base; } if (PrivateData->Mem32Limit < Limit) { PrivateData->Mem32Limit = Limit; } } } else { // // Parse the BARs of the PCI device to determine what I/O Ranges, // Memory Ranges, and Prefetchable Memory Ranges the device is decoding // if ((PciConfigurationHeader.Hdr.HeaderType & HEADER_LAYOUT_CODE) == HEADER_TYPE_DEVICE) { Status = PcatPciRootBridgeParseBars ( PrivateData, PciConfigurationHeader.Hdr.Command, PrimaryBusIndex, Device, Function ); } // // See if the PCI device is an IDE controller // if (PciConfigurationHeader.Hdr.ClassCode[2] == 0x01 && PciConfigurationHeader.Hdr.ClassCode[1] == 0x01 ) { if (PciConfigurationHeader.Hdr.ClassCode[0] & 0x80) { PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_IDE_PRIMARY_IO; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_IDE_SECONDARY_IO; } if (PciConfigurationHeader.Hdr.ClassCode[0] & 0x01) { PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_IDE_PRIMARY_IO; } if (PciConfigurationHeader.Hdr.ClassCode[0] & 0x04) { PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_IDE_SECONDARY_IO; } } // // See if the PCI device is a legacy VGA controller // if (PciConfigurationHeader.Hdr.ClassCode[2] == 0x00 && PciConfigurationHeader.Hdr.ClassCode[1] == 0x01 ) { PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_PALETTE_IO; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_MEMORY; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_IO; } // // See if the PCI device is a standard VGA controller // if (PciConfigurationHeader.Hdr.ClassCode[2] == 0x03 && PciConfigurationHeader.Hdr.ClassCode[1] == 0x00 ) { PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_PALETTE_IO; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_MEMORY; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_VGA_IO; } // // See if the PCI Device is a PCI - ISA or PCI - EISA // or ISA_POSITIVIE_DECODE Bridge device // if (PciConfigurationHeader.Hdr.ClassCode[2] == 0x06) { if (PciConfigurationHeader.Hdr.ClassCode[1] == 0x01 || PciConfigurationHeader.Hdr.ClassCode[1] == 0x02 || PciConfigurationHeader.Hdr.ClassCode[1] == 0x80 ) { PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_ISA_IO; PrivateData->Attributes |= EFI_PCI_ATTRIBUTE_ISA_MOTHERBOARD_IO; if (PrivateData->MemBase > 0xa0000) { PrivateData->MemBase = 0xa0000; } if (PrivateData->MemLimit < 0xbffff) { PrivateData->MemLimit = 0xbffff; } } } } // // If this device is not a multi function device, then skip the rest of this PCI device // if (Function == 0 && !(PciConfigurationHeader.Hdr.HeaderType & HEADER_TYPE_MULTI_FUNCTION)) { break; } } } // // After scanning all the PCI devices on the PCI root bridge's primary bus, update the // Primary Bus Number for the next PCI root bridge to be this PCI root bridge's subordinate // bus number + 1. // PrimaryBusIndex = PrivateData->SubordinateBus + 1; // // If at least one PCI device was found on the primary bus of this PCI root bridge, then the PCI root bridge // exists. // if (NumberOfPciDevices > 0) { // // Adjust the I/O range used for bounds checking for the legacy decoding attributed // if (PrivateData->Attributes & 0x7f) { PrivateData->IoBase = 0; if (PrivateData->IoLimit < 0xffff) { PrivateData->IoLimit = 0xffff; } } // // Adjust the Memory range used for bounds checking for the legacy decoding attributed // if (PrivateData->Attributes & EFI_PCI_ATTRIBUTE_VGA_MEMORY) { if (PrivateData->MemBase > 0xa0000) { PrivateData->MemBase = 0xa0000; } if (PrivateData->MemLimit < 0xbffff) { PrivateData->MemLimit = 0xbffff; } } // // Build ACPI descriptors for the resources on the PCI Root Bridge // Status = ConstructConfiguration(PrivateData); ASSERT_EFI_ERROR(Status); // // Create the handle for this PCI Root Bridge // Status = gBS->InstallMultipleProtocolInterfaces ( &PrivateData->Handle, &gEfiDevicePathProtocolGuid, PrivateData->DevicePath, &gEfiPciRootBridgeIoProtocolGuid, &PrivateData->Io, NULL ); ASSERT_EFI_ERROR(Status); // // Contruct DeviceIoProtocol // Status = DeviceIoConstructor ( PrivateData->Handle, &PrivateData->Io, PrivateData->DevicePath, (UINT16)PrivateData->PrimaryBus, (UINT16)PrivateData->SubordinateBus ); ASSERT_EFI_ERROR(Status); #if 0 //patch by nms42 // // Scan this PCI Root Bridge for PCI Option ROMs and add them to the PCI Option ROM Table // Status = ScanPciRootBridgeForRoms(&PrivateData->Io); #endif // // Increment the index for the next PCI Root Bridge // PciRootBridgeIndex++; } else { // // If no PCI Root Bridges were found on the current PCI segment, then exit // if (NumberOfPciRootBridges == 0) { Status = EFI_SUCCESS; goto Done; } } // // If the PrimaryBusIndex is greater than the maximum allowable PCI bus number, then // the PCI Segment Number is incremented, and the next segment is searched starting at Bus #0 // Otherwise, the search is continued on the next PCI Root Bridge // if (PrimaryBusIndex > PCI_MAX_BUS) { PciSegmentIndex++; NumberOfPciRootBridges = 0; PrimaryBusIndex = 0; } else { NumberOfPciRootBridges++; } } return EFI_SUCCESS; Done: // // Clean up memory allocated for the PCI Root Bridge that was searched but not created. // if (PrivateData) { if (PrivateData->DevicePath) { gBS->FreePool(PrivateData->DevicePath); } gBS->FreePool(PrivateData); } // // If no PCI Root Bridges were discovered, then return the error condition from scanning the // first PCI Root Bridge // if (PciRootBridgeIndex == 0) { return Status; } return EFI_SUCCESS; } EFI_STATUS ConstructConfiguration( IN OUT PCAT_PCI_ROOT_BRIDGE_INSTANCE *PrivateData ) /*++ Routine Description: Arguments: Returns: None --*/ { EFI_STATUS Status; UINT8 NumConfig; EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *Configuration; EFI_ACPI_END_TAG_DESCRIPTOR *ConfigurationEnd; NumConfig = 0; PrivateData->Configuration = NULL; if (PrivateData->SubordinateBus >= PrivateData->PrimaryBus) { NumConfig++; } if (PrivateData->IoLimit >= PrivateData->IoBase) { NumConfig++; } if (PrivateData->Mem32Limit >= PrivateData->Mem32Base) { NumConfig++; } if (PrivateData->Pmem32Limit >= PrivateData->Pmem32Base) { NumConfig++; } if (PrivateData->Mem64Limit >= PrivateData->Mem64Base) { NumConfig++; } if (PrivateData->Pmem64Limit >= PrivateData->Pmem64Base) { NumConfig++; } if ( NumConfig == 0 ) { // // If there is no resource request // Status = gBS->AllocatePool ( EfiBootServicesData, sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) + sizeof (EFI_ACPI_END_TAG_DESCRIPTOR), (VOID **)&PrivateData->Configuration ); if (EFI_ERROR(Status )) { return Status; } Configuration = PrivateData->Configuration; ZeroMem ( Configuration, sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) + sizeof (EFI_ACPI_END_TAG_DESCRIPTOR) ); Configuration->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; Configuration->Len = sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); Configuration++; ConfigurationEnd = (EFI_ACPI_END_TAG_DESCRIPTOR *)(Configuration); ConfigurationEnd->Desc = ACPI_END_TAG_DESCRIPTOR; ConfigurationEnd->Checksum = 0; } // // If there is at least one type of resource request, // allocate a acpi resource node // Status = gBS->AllocatePool ( EfiBootServicesData, sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) * NumConfig + sizeof (EFI_ACPI_END_TAG_DESCRIPTOR), (VOID **)&PrivateData->Configuration ); if (EFI_ERROR(Status )) { return Status; } Configuration = PrivateData->Configuration; ZeroMem ( Configuration, sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) * NumConfig + sizeof (EFI_ACPI_END_TAG_DESCRIPTOR) ); if (PrivateData->SubordinateBus >= PrivateData->PrimaryBus) { Configuration->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; Configuration->Len = sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); Configuration->ResType = ACPI_ADDRESS_SPACE_TYPE_BUS; Configuration->SpecificFlag = 0; Configuration->AddrRangeMin = PrivateData->PrimaryBus; Configuration->AddrRangeMax = PrivateData->SubordinateBus; Configuration->AddrLen = Configuration->AddrRangeMax - Configuration->AddrRangeMin + 1; Configuration++; } // // Deal with io aperture // if (PrivateData->IoLimit >= PrivateData->IoBase) { Configuration->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; Configuration->Len = sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); Configuration->ResType = ACPI_ADDRESS_SPACE_TYPE_IO; Configuration->SpecificFlag = 1; //non ISA range Configuration->AddrRangeMin = PrivateData->IoBase; Configuration->AddrRangeMax = PrivateData->IoLimit; Configuration->AddrLen = Configuration->AddrRangeMax - Configuration->AddrRangeMin + 1; Configuration++; } // // Deal with mem32 aperture // if (PrivateData->Mem32Limit >= PrivateData->Mem32Base) { Configuration->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; Configuration->Len = sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); Configuration->ResType = ACPI_ADDRESS_SPACE_TYPE_MEM; Configuration->SpecificFlag = 0; //Nonprefechable Configuration->AddrSpaceGranularity = 32; //32 bit Configuration->AddrRangeMin = PrivateData->Mem32Base; Configuration->AddrRangeMax = PrivateData->Mem32Limit; Configuration->AddrLen = Configuration->AddrRangeMax - Configuration->AddrRangeMin + 1; Configuration++; } // // Deal with Pmem32 aperture // if (PrivateData->Pmem32Limit >= PrivateData->Pmem32Base) { Configuration->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; Configuration->Len = sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); Configuration->ResType = ACPI_ADDRESS_SPACE_TYPE_MEM; Configuration->SpecificFlag = 0x6; //prefechable Configuration->AddrSpaceGranularity = 32; //32 bit Configuration->AddrRangeMin = PrivateData->Pmem32Base; Configuration->AddrRangeMax = PrivateData->Pmem32Limit; Configuration->AddrLen = Configuration->AddrRangeMax - Configuration->AddrRangeMin + 1; Configuration++; } // // Deal with mem64 aperture // if (PrivateData->Mem64Limit >= PrivateData->Mem64Base) { Configuration->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; Configuration->Len = sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); Configuration->ResType = ACPI_ADDRESS_SPACE_TYPE_MEM; Configuration->SpecificFlag = 0; //nonprefechable Configuration->AddrSpaceGranularity = 64; //32 bit Configuration->AddrRangeMin = PrivateData->Mem64Base; Configuration->AddrRangeMax = PrivateData->Mem64Limit; Configuration->AddrLen = Configuration->AddrRangeMax - Configuration->AddrRangeMin + 1; Configuration++; } // // Deal with Pmem64 aperture // if (PrivateData->Pmem64Limit >= PrivateData->Pmem64Base) { Configuration->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; Configuration->Len = sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); Configuration->ResType = ACPI_ADDRESS_SPACE_TYPE_MEM; Configuration->SpecificFlag = 0x06; //prefechable Configuration->AddrSpaceGranularity = 64; //32 bit Configuration->AddrRangeMin = PrivateData->Pmem64Base; Configuration->AddrRangeMax = PrivateData->Pmem64Limit; Configuration->AddrLen = Configuration->AddrRangeMax - Configuration->AddrRangeMin + 1; Configuration++; } // // put the checksum // ConfigurationEnd = (EFI_ACPI_END_TAG_DESCRIPTOR *)(Configuration); ConfigurationEnd->Desc = ACPI_END_TAG_DESCRIPTOR; ConfigurationEnd->Checksum = 0; return EFI_SUCCESS; } EFI_STATUS PcatPciRootBridgeBarExisted ( IN PCAT_PCI_ROOT_BRIDGE_INSTANCE *PrivateData, IN UINT64 Address, OUT UINT32 *OriginalValue, OUT UINT32 *Value ) /*++ Routine Description: Arguments: Returns: None --*/ { EFI_STATUS Status; UINT32 AllOnes; EFI_TPL OldTpl; // // Preserve the original value // /*Status = */PrivateData->Io.Pci.Read ( &PrivateData->Io, EfiPciWidthUint32, Address, 1, OriginalValue ); // // Raise TPL to high level to disable timer interrupt while the BAR is probed // OldTpl = gBS->RaiseTPL (TPL_HIGH_LEVEL); AllOnes = 0xffffffff; /*Status = */PrivateData->Io.Pci.Write ( &PrivateData->Io, EfiPciWidthUint32, Address, 1, &AllOnes ); Status = PrivateData->Io.Pci.Read ( &PrivateData->Io, EfiPciWidthUint32, Address, 1, Value ); // //Write back the original value // if (!EFI_ERROR(Status)) { /*Status = */PrivateData->Io.Pci.Write ( &PrivateData->Io, EfiPciWidthUint32, Address, 1, OriginalValue ); } // // Restore TPL to its original level // gBS->RestoreTPL (OldTpl); if ( *Value == 0 ) { return EFI_DEVICE_ERROR; } return Status; } EFI_STATUS PcatPciRootBridgeParseBars ( IN PCAT_PCI_ROOT_BRIDGE_INSTANCE *PrivateData, IN UINT16 Command, IN UINTN Bus, IN UINTN Device, IN UINTN Function ) /*++ Routine Description: Arguments: Returns: None --*/ { EFI_STATUS Status; UINT64 Address; UINT32 OriginalValue; UINT32 Value; UINT32 OriginalUpperValue; UINT32 UpperValue; UINT64 Mask; UINTN Offset; UINT64 Base; UINT64 Length; UINT64 Limit; for (Offset = 0x10; Offset < 0x28; Offset += 4) { Address = EFI_PCI_ADDRESS (Bus, Device, Function, Offset); Status = PcatPciRootBridgeBarExisted ( PrivateData, Address, &OriginalValue, &Value ); if (!EFI_ERROR(Status )) { if ( Value & 0x01 ) { if (Command & 0x0001) { // //Device I/Os // Mask = 0xfffffffc; Base = OriginalValue & Mask; Length = ((~(Value & Mask)) & Mask) + 0x04; if (!(Value & 0xFFFF0000)){ Length &= 0x0000FFFF; } Limit = Base + Length - 1; if (Base < Limit) { if (PrivateData->IoBase > Base) { PrivateData->IoBase = (UINT32)Base; } if (PrivateData->IoLimit < Limit) { PrivateData->IoLimit = (UINT32)Limit; } } } } else { if (Command & 0x0002) { Mask = 0xfffffff0; Base = OriginalValue & Mask; Length = Value & Mask; if ((Value & 0x07) != 0x04) { Length = ((~Length) + 1) & 0xffffffff; } else { Offset += 4; Address = EFI_PCI_ADDRESS (Bus, Device, Function, Offset); Status = PcatPciRootBridgeBarExisted ( PrivateData, Address, &OriginalUpperValue, &UpperValue ); Base = Base | LShiftU64((UINT64)OriginalUpperValue,32); Length = Length | LShiftU64((UINT64)UpperValue,32); Length = (~Length) + 1; } Limit = Base + Length - 1; if (Base < Limit) { if (PrivateData->MemBase > Base) { PrivateData->MemBase = Base; } if (PrivateData->MemLimit < Limit) { PrivateData->MemLimit = Limit; } switch (Value &0x07) { case 0x00: ////memory space; anywhere in 32 bit address space if (Value & 0x08) { if (PrivateData->Pmem32Base > Base) { PrivateData->Pmem32Base = Base; } if (PrivateData->Pmem32Limit < Limit) { PrivateData->Pmem32Limit = Limit; } } else { if (PrivateData->Mem32Base > Base) { PrivateData->Mem32Base = Base; } if (PrivateData->Mem32Limit < Limit) { PrivateData->Mem32Limit = Limit; } } break; case 0x04: //memory space; anywhere in 64 bit address space if (Value & 0x08) { if (PrivateData->Pmem64Base > Base) { PrivateData->Pmem64Base = Base; } if (PrivateData->Pmem64Limit < Limit) { PrivateData->Pmem64Limit = Limit; } } else { if (PrivateData->Mem64Base > Base) { PrivateData->Mem64Base = Base; } if (PrivateData->Mem64Limit < Limit) { PrivateData->Mem64Limit = Limit; } } break; } } } } } } return EFI_SUCCESS; } UINT64 GetPciExpressBaseAddressForRootBridge ( IN UINTN HostBridgeNumber, IN UINTN RootBridgeNumber ) /*++ Routine Description: This routine is to get PciExpress Base Address for this RootBridge Arguments: HostBridgeNumber - The number of HostBridge RootBridgeNumber - The number of RootBridge Returns: UINT64 - PciExpressBaseAddress for this HostBridge and RootBridge --*/ { EFI_PCI_EXPRESS_BASE_ADDRESS_INFORMATION *PciExpressBaseAddressInfo; UINTN BufferSize; UINT32 Index; UINT32 Number; EFI_PEI_HOB_POINTERS GuidHob; // // Get PciExpressAddressInfo Hob // PciExpressBaseAddressInfo = NULL; BufferSize = 0; GuidHob.Raw = GetFirstGuidHob (&gEfiPciExpressBaseAddressGuid); if (GuidHob.Raw != NULL) { PciExpressBaseAddressInfo = GET_GUID_HOB_DATA (GuidHob.Guid); BufferSize = GET_GUID_HOB_DATA_SIZE (GuidHob.Guid); } else { return 0; } // // Search the PciExpress Base Address in the Hob for current RootBridge // Number = (UINT32)(BufferSize / sizeof(EFI_PCI_EXPRESS_BASE_ADDRESS_INFORMATION)); for (Index = 0; Index < Number; Index++) { if ((PciExpressBaseAddressInfo[Index].HostBridgeNumber == HostBridgeNumber) && (PciExpressBaseAddressInfo[Index].RootBridgeNumber == RootBridgeNumber)) { return PciExpressBaseAddressInfo[Index].PciExpressBaseAddress; } } // // Do not find the PciExpress Base Address in the Hob // return 0; }