/** The scan bus callback function to register PCI device. @param[in] Context The context of the callback. @param[in] Segment The segment of the source. @param[in] Bus The bus of the source. @param[in] Device The device of the source. @param[in] Function The function of the source. @retval EFI_SUCCESS The PCI device is registered. **/ EFI_STATUS EFIAPI ScanBusCallbackRegisterPciDevice ( IN VOID *Context, IN UINT16 Segment, IN UINT8 Bus, IN UINT8 Device, IN UINT8 Function ) { VTD_SOURCE_ID SourceId; UINTN VtdIndex; UINT8 BaseClass; UINT8 SubClass; UINT8 DeviceType; EFI_STATUS Status; VtdIndex = (UINTN)Context; SourceId.Bits.Bus = Bus; SourceId.Bits.Device = Device; SourceId.Bits.Function = Function; DeviceType = EFI_ACPI_DEVICE_SCOPE_ENTRY_TYPE_PCI_ENDPOINT; BaseClass = PciSegmentRead8 (PCI_SEGMENT_LIB_ADDRESS(Segment, Bus, Device, Function, PCI_CLASSCODE_OFFSET + 2)); if (BaseClass == PCI_CLASS_BRIDGE) { SubClass = PciSegmentRead8 (PCI_SEGMENT_LIB_ADDRESS(Segment, Bus, Device, Function, PCI_CLASSCODE_OFFSET + 1)); if (SubClass == PCI_CLASS_BRIDGE_P2P) { DeviceType = EFI_ACPI_DEVICE_SCOPE_ENTRY_TYPE_PCI_BRIDGE; } } Status = RegisterPciDevice (VtdIndex, Segment, SourceId, DeviceType, FALSE); return Status; }
/** Scan PCI bus and invoke callback function for each PCI devices under the bus. @param[in] Context The context of the callback function. @param[in] Segment The segment of the source. @param[in] Bus The bus of the source. @param[in] Callback The callback function in PCI scan. @retval EFI_SUCCESS The PCI devices under the bus are scaned. **/ EFI_STATUS ScanPciBus ( IN VOID *Context, IN UINT16 Segment, IN UINT8 Bus, IN SCAN_BUS_FUNC_CALLBACK_FUNC Callback ) { UINT8 Device; UINT8 Function; UINT8 SecondaryBusNumber; UINT8 HeaderType; UINT8 BaseClass; UINT8 SubClass; UINT32 MaxFunction; UINT16 VendorID; UINT16 DeviceID; EFI_STATUS Status; // Scan the PCI bus for devices for (Device = 0; Device < PCI_MAX_DEVICE + 1; Device++) { HeaderType = PciSegmentRead8 (PCI_SEGMENT_LIB_ADDRESS(Segment, Bus, Device, 0, PCI_HEADER_TYPE_OFFSET)); MaxFunction = PCI_MAX_FUNC + 1; if ((HeaderType & HEADER_TYPE_MULTI_FUNCTION) == 0x00) { MaxFunction = 1; } for (Function = 0; Function < MaxFunction; Function++) { VendorID = PciSegmentRead16 (PCI_SEGMENT_LIB_ADDRESS(Segment, Bus, Device, Function, PCI_VENDOR_ID_OFFSET)); DeviceID = PciSegmentRead16 (PCI_SEGMENT_LIB_ADDRESS(Segment, Bus, Device, Function, PCI_DEVICE_ID_OFFSET)); if (VendorID == 0xFFFF && DeviceID == 0xFFFF) { continue; } Status = Callback (Context, Segment, Bus, Device, Function); if (EFI_ERROR (Status)) { return Status; } BaseClass = PciSegmentRead8 (PCI_SEGMENT_LIB_ADDRESS(Segment, Bus, Device, Function, PCI_CLASSCODE_OFFSET + 2)); if (BaseClass == PCI_CLASS_BRIDGE) { SubClass = PciSegmentRead8 (PCI_SEGMENT_LIB_ADDRESS(Segment, Bus, Device, Function, PCI_CLASSCODE_OFFSET + 1)); if (SubClass == PCI_CLASS_BRIDGE_P2P) { SecondaryBusNumber = PciSegmentRead8 (PCI_SEGMENT_LIB_ADDRESS(Segment, Bus, Device, Function, PCI_BRIDGE_SECONDARY_BUS_REGISTER_OFFSET)); DEBUG ((DEBUG_INFO," ScanPciBus: PCI bridge S%04x B%02x D%02x F%02x (SecondBus:%02x)\n", Segment, Bus, Device, Function, SecondaryBusNumber)); if (SecondaryBusNumber != 0) { Status = ScanPciBus (Context, Segment, SecondaryBusNumber, Callback); if (EFI_ERROR (Status)) { return Status; } } } } } } return EFI_SUCCESS; }
/** Always enable the VTd page attribute for the device in the DeviceScope. @param[in] DeviceScope the input device scope data structure @retval EFI_SUCCESS The VTd entry is updated to always enable all DMA access for the specific device in the device scope. **/ EFI_STATUS AlwaysEnablePageAttributeDeviceScope ( IN EDKII_PLATFORM_VTD_DEVICE_SCOPE *DeviceScope ) { UINT8 Bus; UINT8 Device; UINT8 Function; VTD_SOURCE_ID SourceId; UINT8 SecondaryBusNumber; EFI_STATUS Status; Status = GetPciBusDeviceFunction (DeviceScope->SegmentNumber, &DeviceScope->DeviceScope, &Bus, &Device, &Function); if (DeviceScope->DeviceScope.Type == EFI_ACPI_DEVICE_SCOPE_ENTRY_TYPE_PCI_BRIDGE) { // // Need scan the bridge and add all devices. // SecondaryBusNumber = PciSegmentRead8 (PCI_SEGMENT_LIB_ADDRESS(DeviceScope->SegmentNumber, Bus, Device, Function, PCI_BRIDGE_SECONDARY_BUS_REGISTER_OFFSET)); Status = ScanPciBus (NULL, DeviceScope->SegmentNumber, SecondaryBusNumber, ScanBusCallbackAlwaysEnablePageAttribute); return Status; } else { SourceId.Bits.Bus = Bus; SourceId.Bits.Device = Device; SourceId.Bits.Function = Function; Status = AlwaysEnablePageAttribute (DeviceScope->SegmentNumber, SourceId); return Status; } }
/** Reads an 8-bit PCI configuration register, and saves the value in the S3 script to be replayed on S3 resume. Reads and returns the 8-bit PCI configuration register specified by Address. This function must guarantee that all PCI read and write operations are serialized. If any reserved bits in Address are set, then ASSERT(). @param Address Address that encodes the PCI Segment, Bus, Device, Function, and Register. @return The 8-bit PCI configuration register specified by Address. **/ UINT8 EFIAPI S3PciSegmentRead8 ( IN UINT64 Address ) { return InternalSavePciSegmentWrite8ValueToBootScript (Address, PciSegmentRead8 (Address)); }
/** Performs a bitwise AND of an 8-bit PCI configuration register with an 8-bit value. Reads the 8-bit PCI configuration register specified by Address, performs a bitwise AND between the read result and the value specified by AndData, and writes the result to the 8-bit PCI configuration register specified by Address. The value written to the PCI configuration register is returned. This function must guarantee that all PCI read and write operations are serialized. If any reserved bits in Address are set, then ASSERT(). @param Address Address that encodes the PCI Segment, Bus, Device, Function and Register. @param AndData The value to AND with the PCI configuration register. @return The value written back to the PCI configuration register. **/ UINT8 EFIAPI PciSegmentAnd8 ( IN UINT64 Address, IN UINT8 AndData ) { return PciSegmentWrite8 (Address, (UINT8) (PciSegmentRead8 (Address) & AndData)); }
/** Performs a bitwise OR of an 8-bit PCI configuration register with an 8-bit value. Reads the 8-bit PCI configuration register specified by Address, performs a bitwise OR between the read result and the value specified by OrData, and writes the result to the 8-bit PCI configuration register specified by Address. The value written to the PCI configuration register is returned. This function must guarantee that all PCI read and write operations are serialized. If any reserved bits in Address are set, then ASSERT(). @param Address Address that encodes the PCI Segment, Bus, Device, Function and Register. @param OrData The value to OR with the PCI configuration register. @return The value written back to the PCI configuration register. **/ UINT8 EFIAPI PciSegmentOr8 ( IN UINT64 Address, IN UINT8 OrData ) { return PciSegmentWrite8 (Address, (UINT8) (PciSegmentRead8 (Address) | OrData)); }
/** Performs a bitwise OR of an 8-bit PCI configuration register with an 8-bit value. Reads the 8-bit PCI configuration register specified by Address, performs a bitwise OR between the read result and the value specified by OrData, and writes the result to the 8-bit PCI configuration register specified by Address. The value written to the PCI configuration register is returned. This function must guarantee that all PCI read and write operations are serialized. If any reserved bits in Address are set, then ASSERT(). @param Address Address that encodes the PCI Segment, Bus, Device, Function, and Register. @param OrData The value to OR with the PCI configuration register. @return The value written to the PCI configuration register. **/ UINT8 EFIAPI PciSegmentOr8 ( IN UINT64 Address, IN UINT8 OrData ) { return PciWrite8 (PCI_SEGMENT_TO_PCI_ADDRESS (Address), (UINT8) (PciSegmentRead8 (Address) | OrData)); }
/** Reads a bit field of a PCI configuration register. Reads the bit field in an 8-bit PCI configuration register. The bit field is specified by the StartBit and the EndBit. The value of the bit field is returned. If any reserved bits in Address are set, then ASSERT(). If StartBit is greater than 7, then ASSERT(). If EndBit is greater than 7, then ASSERT(). If EndBit is less than StartBit, then ASSERT(). @param Address PCI configuration register to read. @param StartBit The ordinal of the least significant bit in the bit field. Range 0..7. @param EndBit The ordinal of the most significant bit in the bit field. Range 0..7. @return The value of the bit field read from the PCI configuration register. **/ UINT8 EFIAPI PciSegmentBitFieldRead8 ( IN UINT64 Address, IN UINTN StartBit, IN UINTN EndBit ) { return BitFieldRead8 (PciSegmentRead8 (Address), StartBit, EndBit); }
/** Performs a bitwise AND of an 8-bit PCI configuration register with an 8-bit value, followed a bitwise OR with another 8-bit value. Reads the 8-bit PCI configuration register specified by Address, performs a bitwise AND between the read result and the value specified by AndData, performs a bitwise OR between the result of the AND operation and the value specified by OrData, and writes the result to the 8-bit PCI configuration register specified by Address. The value written to the PCI configuration register is returned. This function must guarantee that all PCI read and write operations are serialized. If any reserved bits in Address are set, then ASSERT(). @param Address Address that encodes the PCI Segment, Bus, Device, Function and Register. @param AndData The value to AND with the PCI configuration register. @param OrData The value to OR with the result of the AND operation. @return The value written back to the PCI configuration register. **/ UINT8 EFIAPI PciSegmentAndThenOr8 ( IN UINT64 Address, IN UINT8 AndData, IN UINT8 OrData ) { return PciSegmentWrite8 (Address, (UINT8) ((PciSegmentRead8 (Address) & AndData) | OrData)); }
/** Reads a bit field in an 8-bit PCI configuration register, performs a bitwise AND, and writes the result back to the bit field in the 8-bit register. Reads the 8-bit PCI configuration register specified by Address, performs a bitwise AND between the read result and the value specified by AndData, and writes the result to the 8-bit PCI configuration register specified by Address. The value written to the PCI configuration register is returned. This function must guarantee that all PCI read and write operations are serialized. Extra left bits in AndData are stripped. If any reserved bits in Address are set, then ASSERT(). If StartBit is greater than 7, then ASSERT(). If EndBit is greater than 7, then ASSERT(). If EndBit is less than StartBit, then ASSERT(). @param Address PCI configuration register to write. @param StartBit The ordinal of the least significant bit in the bit field. Range 0..7. @param EndBit The ordinal of the most significant bit in the bit field. Range 0..7. @param AndData The value to AND with the PCI configuration register. @return The value written back to the PCI configuration register. **/ UINT8 EFIAPI PciSegmentBitFieldAnd8 ( IN UINT64 Address, IN UINTN StartBit, IN UINTN EndBit, IN UINT8 AndData ) { return PciSegmentWrite8 ( Address, BitFieldAnd8 (PciSegmentRead8 (Address), StartBit, EndBit, AndData) ); }
/** Writes a bit field to a PCI configuration register. Writes Value to the bit field of the PCI configuration register. The bit field is specified by the StartBit and the EndBit. All other bits in the destination PCI configuration register are preserved. The new value of the 8-bit register is returned. If any reserved bits in Address are set, then ASSERT(). If StartBit is greater than 7, then ASSERT(). If EndBit is greater than 7, then ASSERT(). If EndBit is less than StartBit, then ASSERT(). @param Address PCI configuration register to write. @param StartBit The ordinal of the least significant bit in the bit field. Range 0..7. @param EndBit The ordinal of the most significant bit in the bit field. Range 0..7. @param Value New value of the bit field. @return The value written back to the PCI configuration register. **/ UINT8 EFIAPI PciSegmentBitFieldWrite8 ( IN UINT64 Address, IN UINTN StartBit, IN UINTN EndBit, IN UINT8 Value ) { return PciSegmentWrite8 ( Address, BitFieldWrite8 (PciSegmentRead8 (Address), StartBit, EndBit, Value) ); }
/** Reads a range of PCI configuration registers into a caller supplied buffer. Reads the range of PCI configuration registers specified by StartAddress and Size into the buffer specified by Buffer. This function only allows the PCI configuration registers from a single PCI function to be read. Size is returned. When possible 32-bit PCI configuration read cycles are used to read from StartAdress to StartAddress + Size. Due to alignment restrictions, 8-bit and 16-bit PCI configuration read cycles may be used at the beginning and the end of the range. If StartAddress > 0x0FFFFFFF, then ASSERT(). If ((StartAddress & 0xFFF) + Size) > 0x1000, then ASSERT(). If Size > 0 and Buffer is NULL, then ASSERT(). @param StartAddress Starting Address that encodes the PCI Segment, Bus, Device, Function and Register. @param Size Size in bytes of the transfer. @param Buffer Pointer to a buffer receiving the data read. @return Size **/ UINTN EFIAPI PciSegmentReadBuffer ( IN UINT64 StartAddress, IN UINTN Size, OUT VOID *Buffer ) { UINTN ReturnValue; ASSERT_INVALID_PCI_SEGMENT_ADDRESS (StartAddress, 0); ASSERT (((StartAddress & 0xFFF) + Size) <= 0x1000); if (Size == 0) { return Size; } ASSERT (Buffer != NULL); // // Save Size for return // ReturnValue = Size; if ((StartAddress & 1) != 0) { // // Read a byte if StartAddress is byte aligned // *(volatile UINT8 *)Buffer = PciSegmentRead8 (StartAddress); StartAddress += sizeof (UINT8); Size -= sizeof (UINT8); Buffer = (UINT8*)Buffer + 1; } if (Size >= sizeof (UINT16) && (StartAddress & 2) != 0) { // // Read a word if StartAddress is word aligned // *(volatile UINT16 *)Buffer = PciSegmentRead16 (StartAddress); StartAddress += sizeof (UINT16); Size -= sizeof (UINT16); Buffer = (UINT16*)Buffer + 1; } while (Size >= sizeof (UINT32)) { // // Read as many double words as possible // *(volatile UINT32 *)Buffer = PciSegmentRead32 (StartAddress); StartAddress += sizeof (UINT32); Size -= sizeof (UINT32); Buffer = (UINT32*)Buffer + 1; } if (Size >= sizeof (UINT16)) { // // Read the last remaining word if exist // *(volatile UINT16 *)Buffer = PciSegmentRead16 (StartAddress); StartAddress += sizeof (UINT16); Size -= sizeof (UINT16); Buffer = (UINT16*)Buffer + 1; } if (Size >= sizeof (UINT8)) { // // Read the last remaining byte if exist // *(volatile UINT8 *)Buffer = PciSegmentRead8 (StartAddress); } return ReturnValue; }
/** Register PCI device to VTd engine. @param[in] VtdIndex The index of VTd engine. @param[in] Segment The segment of the source. @param[in] SourceId The SourceId of the source. @param[in] DeviceType The DMAR device scope type. @param[in] CheckExist TRUE: ERROR will be returned if the PCI device is already registered. FALSE: SUCCESS will be returned if the PCI device is registered. @retval EFI_SUCCESS The PCI device is registered. @retval EFI_OUT_OF_RESOURCES No enough resource to register a new PCI device. @retval EFI_ALREADY_STARTED The device is already registered. **/ EFI_STATUS RegisterPciDevice ( IN UINTN VtdIndex, IN UINT16 Segment, IN VTD_SOURCE_ID SourceId, IN UINT8 DeviceType, IN BOOLEAN CheckExist ) { PCI_DEVICE_INFORMATION *PciDeviceInfo; VTD_SOURCE_ID *PciSourceId; UINTN PciDataIndex; UINTN Index; PCI_DEVICE_DATA *NewPciDeviceData; EDKII_PLATFORM_VTD_PCI_DEVICE_ID *PciDeviceId; PciDeviceInfo = &mVtdUnitInformation[VtdIndex].PciDeviceInfo; if (PciDeviceInfo->IncludeAllFlag) { // // Do not register device in other VTD Unit // for (Index = 0; Index < VtdIndex; Index++) { PciDataIndex = GetPciDataIndex (Index, Segment, SourceId); if (PciDataIndex != (UINTN)-1) { DEBUG ((DEBUG_INFO, " RegisterPciDevice: PCI S%04x B%02x D%02x F%02x already registered by Other Vtd(%d)\n", Segment, SourceId.Bits.Bus, SourceId.Bits.Device, SourceId.Bits.Function, Index)); return EFI_SUCCESS; } } } PciDataIndex = GetPciDataIndex (VtdIndex, Segment, SourceId); if (PciDataIndex == (UINTN)-1) { // // Register new // if (PciDeviceInfo->PciDeviceDataNumber >= PciDeviceInfo->PciDeviceDataMaxNumber) { // // Reallocate // NewPciDeviceData = AllocateZeroPool (sizeof(*NewPciDeviceData) * (PciDeviceInfo->PciDeviceDataMaxNumber + MAX_VTD_PCI_DATA_NUMBER)); if (NewPciDeviceData == NULL) { return EFI_OUT_OF_RESOURCES; } PciDeviceInfo->PciDeviceDataMaxNumber += MAX_VTD_PCI_DATA_NUMBER; if (PciDeviceInfo->PciDeviceData != NULL) { CopyMem (NewPciDeviceData, PciDeviceInfo->PciDeviceData, sizeof(*NewPciDeviceData) * PciDeviceInfo->PciDeviceDataNumber); FreePool (PciDeviceInfo->PciDeviceData); } PciDeviceInfo->PciDeviceData = NewPciDeviceData; } ASSERT (PciDeviceInfo->PciDeviceDataNumber < PciDeviceInfo->PciDeviceDataMaxNumber); PciSourceId = &PciDeviceInfo->PciDeviceData[PciDeviceInfo->PciDeviceDataNumber].PciSourceId; PciSourceId->Bits.Bus = SourceId.Bits.Bus; PciSourceId->Bits.Device = SourceId.Bits.Device; PciSourceId->Bits.Function = SourceId.Bits.Function; DEBUG ((DEBUG_INFO, " RegisterPciDevice: PCI S%04x B%02x D%02x F%02x", Segment, SourceId.Bits.Bus, SourceId.Bits.Device, SourceId.Bits.Function)); PciDeviceId = &PciDeviceInfo->PciDeviceData[PciDeviceInfo->PciDeviceDataNumber].PciDeviceId; if ((DeviceType == EFI_ACPI_DEVICE_SCOPE_ENTRY_TYPE_PCI_ENDPOINT) || (DeviceType == EFI_ACPI_DEVICE_SCOPE_ENTRY_TYPE_PCI_BRIDGE)) { PciDeviceId->VendorId = PciSegmentRead16 (PCI_SEGMENT_LIB_ADDRESS(Segment, SourceId.Bits.Bus, SourceId.Bits.Device, SourceId.Bits.Function, PCI_VENDOR_ID_OFFSET)); PciDeviceId->DeviceId = PciSegmentRead16 (PCI_SEGMENT_LIB_ADDRESS(Segment, SourceId.Bits.Bus, SourceId.Bits.Device, SourceId.Bits.Function, PCI_DEVICE_ID_OFFSET)); PciDeviceId->RevisionId = PciSegmentRead8 (PCI_SEGMENT_LIB_ADDRESS(Segment, SourceId.Bits.Bus, SourceId.Bits.Device, SourceId.Bits.Function, PCI_REVISION_ID_OFFSET)); DEBUG ((DEBUG_INFO, " (%04x:%04x:%02x", PciDeviceId->VendorId, PciDeviceId->DeviceId, PciDeviceId->RevisionId)); if (DeviceType == EFI_ACPI_DEVICE_SCOPE_ENTRY_TYPE_PCI_ENDPOINT) { PciDeviceId->SubsystemVendorId = PciSegmentRead16 (PCI_SEGMENT_LIB_ADDRESS(Segment, SourceId.Bits.Bus, SourceId.Bits.Device, SourceId.Bits.Function, PCI_SUBSYSTEM_VENDOR_ID_OFFSET)); PciDeviceId->SubsystemDeviceId = PciSegmentRead16 (PCI_SEGMENT_LIB_ADDRESS(Segment, SourceId.Bits.Bus, SourceId.Bits.Device, SourceId.Bits.Function, PCI_SUBSYSTEM_ID_OFFSET)); DEBUG ((DEBUG_INFO, ":%04x:%04x", PciDeviceId->SubsystemVendorId, PciDeviceId->SubsystemDeviceId)); } DEBUG ((DEBUG_INFO, ")")); } PciDeviceInfo->PciDeviceData[PciDeviceInfo->PciDeviceDataNumber].DeviceType = DeviceType; if ((DeviceType != EFI_ACPI_DEVICE_SCOPE_ENTRY_TYPE_PCI_ENDPOINT) && (DeviceType != EFI_ACPI_DEVICE_SCOPE_ENTRY_TYPE_PCI_BRIDGE)) { DEBUG ((DEBUG_INFO, " (*)")); } DEBUG ((DEBUG_INFO, "\n")); PciDeviceInfo->PciDeviceDataNumber++; } else { if (CheckExist) { DEBUG ((DEBUG_INFO, " RegisterPciDevice: PCI S%04x B%02x D%02x F%02x already registered\n", Segment, SourceId.Bits.Bus, SourceId.Bits.Device, SourceId.Bits.Function)); return EFI_ALREADY_STARTED; } } return EFI_SUCCESS; }