Exemplo n.º 1
0
/**
  Writes memory-mapped registers.

  @param[in]  PeiServices  An indirect pointer to the PEI Services Table
                           published by the PEI Foundation.
  @param[in]  This         Pointer to local data for the interface.
  @param[in]  Width        The width of the access. Enumerated in bytes.
  @param[in]  Address      The physical address of the access.
  @param[in]  Count        The number of accesses to perform.
  @param[in]  Buffer       A pointer to the buffer of data.

  @retval EFI_SUCCESS            The function completed successfully.
  @retval EFI_INVALID_PARAMETER  Width is invalid for this EFI system.
  @retval EFI_INVALID_PARAMETER  Buffer is NULL.
  @retval EFI_UNSUPPORTED        The address range specified by Address, Width, 
                                 and Count is not valid for this EFI system.

**/
EFI_STATUS
EFIAPI
CpuMemoryServiceWrite (
  IN CONST EFI_PEI_SERVICES    **PeiServices,
  IN CONST EFI_PEI_CPU_IO_PPI  *This,
  IN EFI_PEI_CPU_IO_PPI_WIDTH  Width,
  IN UINT64                    Address,
  IN UINTN                     Count,
  IN VOID                      *Buffer
  )
{
  EFI_STATUS                Status;
  UINT8                     InStride;
  UINT8                     OutStride;
  EFI_PEI_CPU_IO_PPI_WIDTH  OperationWidth;
  BOOLEAN                   Aligned;
  UINT8                     *Uint8Buffer;

  Status = CpuIoCheckParameter (TRUE, Width, Address, Count, Buffer);
  if (EFI_ERROR (Status)) {
    return Status;
  }

  //
  // Select loop based on the width of the transfer
  //
  InStride = mInStride[Width];
  OutStride = mOutStride[Width];
  OperationWidth = (EFI_PEI_CPU_IO_PPI_WIDTH) (Width & 0x03);
  Aligned = (BOOLEAN)(((UINTN)Buffer & (mInStride[OperationWidth] - 1)) == 0x00);
  for (Uint8Buffer = Buffer; Count > 0; Address += InStride, Uint8Buffer += OutStride, Count--) {
    if (OperationWidth == EfiPeiCpuIoWidthUint8) {
      MmioWrite8 ((UINTN)Address, *Uint8Buffer);
    } else if (OperationWidth == EfiPeiCpuIoWidthUint16) {
      if (Aligned) {
        MmioWrite16 ((UINTN)Address, *((UINT16 *)Uint8Buffer));
      } else {
        MmioWrite16 ((UINTN)Address, ReadUnaligned16 ((UINT16 *)Uint8Buffer));
      }
    } else if (OperationWidth == EfiPeiCpuIoWidthUint32) {
      if (Aligned) {
        MmioWrite32 ((UINTN)Address, *((UINT32 *)Uint8Buffer));
      } else {
        MmioWrite32 ((UINTN)Address, ReadUnaligned32 ((UINT32 *)Uint8Buffer));
      }
    } else if (OperationWidth == EfiPeiCpuIoWidthUint64) {
      if (Aligned) {
        MmioWrite64 ((UINTN)Address, *((UINT64 *)Uint8Buffer));
      } else {
        MmioWrite64 ((UINTN)Address, ReadUnaligned64 ((UINT64 *)Uint8Buffer));
      }
    }
  }
  return EFI_SUCCESS;
}
Exemplo n.º 2
0
/**
  Check whether the device path node is ISA Serial Node.

  @param Acpi           Device path node to be checked

  @retval TRUE          It's ISA Serial Node.
  @retval FALSE         It's NOT ISA Serial Node.

**/
BOOLEAN
IsIsaSerialNode (
  IN ACPI_HID_DEVICE_PATH *Acpi
  )
{
  return (BOOLEAN) (
      (DevicePathType (Acpi) == ACPI_DEVICE_PATH) &&
      (DevicePathSubType (Acpi) == ACPI_DP) &&
      (ReadUnaligned32 (&Acpi->HID) == EISA_PNP_ID (0x0501))
      );
}
Exemplo n.º 3
0
/**
  Check to see if this driver supports the given controller

  @param  This                 A pointer to the EFI_DRIVER_BINDING_PROTOCOL instance.
  @param  Controller           The handle of the controller to test.
  @param  RemainingDevicePath  A pointer to the remaining portion of a device path.

  @return EFI_SUCCESS          This driver can support the given controller

**/
EFI_STATUS
EFIAPI
SerialControllerDriverSupported (
  IN EFI_DRIVER_BINDING_PROTOCOL    *This,
  IN EFI_HANDLE                     Controller,
  IN EFI_DEVICE_PATH_PROTOCOL       *RemainingDevicePath
  )

{
  EFI_STATUS                                Status;
  UART_DEVICE_PATH                          *Uart;
  UART_FLOW_CONTROL_DEVICE_PATH             *FlowControl;

  //
  // Test RemainingDevicePath
  //
  if ((RemainingDevicePath != NULL) && !IsDevicePathEnd (RemainingDevicePath)) {
    Status = EFI_UNSUPPORTED;

    Uart = SkipControllerDevicePathNode (RemainingDevicePath, NULL, NULL);
    if (DevicePathType (Uart) != MESSAGING_DEVICE_PATH ||
        DevicePathSubType (Uart) != MSG_UART_DP ||
        DevicePathNodeLength (Uart) != sizeof (UART_DEVICE_PATH)
        ) {
      return EFI_UNSUPPORTED;
    }

    //
    // Do a rough check because Clock Rate is unknown until DriverBindingStart()
    //
    if (!VerifyUartParameters (0, Uart->BaudRate, Uart->DataBits, Uart->Parity, Uart->StopBits, NULL, NULL)) {
      return EFI_UNSUPPORTED;
    }

    FlowControl = (UART_FLOW_CONTROL_DEVICE_PATH *) NextDevicePathNode (Uart);
    if (IsUartFlowControlDevicePathNode (FlowControl)) {
      //
      // If the second node is Flow Control Node,
      //   return error when it request other than hardware flow control.
      //
      if ((ReadUnaligned32 (&FlowControl->FlowControlMap) & ~UART_FLOW_CONTROL_HARDWARE) != 0) {
        return EFI_UNSUPPORTED;
      }
    }
  }

  Status = IsSioSerialController (Controller);
  if (EFI_ERROR (Status)) {
    Status = IsPciSerialController (Controller);
  }
  return Status;
}
/**
  Returns the size of a given image execution info table in bytes.

  This function returns the size, in bytes, of the image execution info table specified by
  ImageExeInfoTable. If ImageExeInfoTable is NULL, then 0 is returned.

  @param  ImageExeInfoTable          A pointer to a image execution info table structure.

  @retval 0       If ImageExeInfoTable is NULL.
  @retval Others  The size of a image execution info table in bytes.

**/
UINTN
GetImageExeInfoTableSize (
  EFI_IMAGE_EXECUTION_INFO_TABLE        *ImageExeInfoTable
  )
{
  UINTN                     Index;
  EFI_IMAGE_EXECUTION_INFO  *ImageExeInfoItem;
  UINTN                     TotalSize;

  if (ImageExeInfoTable == NULL) {
    return 0;
  }

  ImageExeInfoItem  = (EFI_IMAGE_EXECUTION_INFO *) ((UINT8 *) ImageExeInfoTable + sizeof (EFI_IMAGE_EXECUTION_INFO_TABLE));
  TotalSize         = sizeof (EFI_IMAGE_EXECUTION_INFO_TABLE);
  for (Index = 0; Index < ImageExeInfoTable->NumberOfImages; Index++) {
    TotalSize += ReadUnaligned32 ((UINT32 *) &ImageExeInfoItem->InfoSize);
    ImageExeInfoItem = (EFI_IMAGE_EXECUTION_INFO *) ((UINT8 *) ImageExeInfoItem + ReadUnaligned32 ((UINT32 *) &ImageExeInfoItem->InfoSize));
  }

  return TotalSize;
}
Exemplo n.º 5
0
VOID
ArmPlatformGetGlobalVariable (
  IN  UINTN     VariableOffset,
  IN  UINTN     VariableSize,
  OUT VOID*     Variable
  )
{
  UINTN  GlobalVariableBase;

  // Ensure the Global Variable Size have been initialized
  ASSERT (VariableOffset < PcdGet32 (PcdSecGlobalVariableSize));

  GlobalVariableBase = PcdGet32 (PcdCPUCoresSecStackBase) + PcdGet32 (PcdCPUCoreSecPrimaryStackSize) - PcdGet32 (PcdSecGlobalVariableSize);
  
  if (VariableSize == 4) {
    *(UINT32*)Variable = ReadUnaligned32 ((CONST UINT32*)(GlobalVariableBase + VariableOffset));
  } else if (VariableSize == 8) {
    *(UINT64*)Variable = ReadUnaligned64 ((CONST UINT64*)(GlobalVariableBase + VariableOffset));
  } else {
    CopyMem (Variable, (VOID*)(GlobalVariableBase + VariableOffset), VariableSize);
  }
}
Exemplo n.º 6
0
/**
  Worker function that displays the list of boot options that is passed in.

  The function loops over the entries of the list of boot options that is passed
  in. For each entry, the boot option description is displayed on a single line
  along with the position of the option in the list. In debug mode, the UEFI
  device path and the arguments of the boot option are displayed as well in
  subsequent lines.

  @param[in]  BootOptionsList  List of the boot options

**/
STATIC
VOID
DisplayBootOptions (
  IN  LIST_ENTRY*   BootOptionsList
  )
{
  EFI_STATUS        Status;
  UINTN             BootOptionCount;
  LIST_ENTRY       *Entry;
  BDS_LOAD_OPTION  *BdsLoadOption;
  BOOLEAN           IsUnicode;

  BootOptionCount = 0 ;
  for (Entry = GetFirstNode (BootOptionsList);
       !IsNull (BootOptionsList, Entry);
       Entry = GetNextNode (BootOptionsList, Entry)
      ) {

    BdsLoadOption = LOAD_OPTION_FROM_LINK (Entry);
    Print (L"[%d] %s\n", ++BootOptionCount, BdsLoadOption->Description);

    DEBUG_CODE_BEGIN ();
      CHAR16*                           DevicePathTxt;
      EFI_DEVICE_PATH_TO_TEXT_PROTOCOL* DevicePathToTextProtocol;
      ARM_BDS_LOADER_TYPE               LoaderType;
      ARM_BDS_LOADER_OPTIONAL_DATA*     OptionalData;

      Status = gBS->LocateProtocol (
                     &gEfiDevicePathToTextProtocolGuid,
                     NULL,
                     (VOID **)&DevicePathToTextProtocol
                     );
      ASSERT_EFI_ERROR (Status);
      DevicePathTxt = DevicePathToTextProtocol->ConvertDevicePathToText (
                                                  BdsLoadOption->FilePathList,
                                                  TRUE,
                                                  TRUE
                                                  );
      Print (L"\t- %s\n", DevicePathTxt);

      OptionalData = BdsLoadOption->OptionalData;
      if (IS_ARM_BDS_BOOTENTRY (BdsLoadOption)) {
        LoaderType = (ARM_BDS_LOADER_TYPE)ReadUnaligned32 ((CONST UINT32*)&OptionalData->Header.LoaderType);
        if ((LoaderType == BDS_LOADER_KERNEL_LINUX_ATAG) ||
            (LoaderType == BDS_LOADER_KERNEL_LINUX_FDT )   ) {
          Print (L"\t- Arguments: %a\n", &OptionalData->Arguments.LinuxArguments + 1);
        }
      } else if (OptionalData != NULL) {
        if (IsPrintableString (OptionalData, &IsUnicode)) {
          if (IsUnicode) {
            Print (L"\t- Arguments: %s\n", OptionalData);
          } else {
            AsciiPrint ("\t- Arguments: %a\n", OptionalData);
          }
        }
      }

      FreePool (DevicePathTxt);
    DEBUG_CODE_END ();
  }
}
Exemplo n.º 7
0
/**
  Sends an NVM Express Command Packet to an NVM Express controller or namespace. This function only
  supports blocking execution of the command.

  @param[in] Private        The pointer to the NVME_CONTEXT Data structure.
  @param[in] NamespaceId    Is a 32 bit Namespace ID to which the Express HCI command packet will
                            be sent.
                            A Value of 0 denotes the NVM Express controller, a Value of all 0FFh in
                            the namespace ID specifies that the command packet should be sent to all
                            valid namespaces.
  @param[in,out] Packet     A pointer to the EDKII PEI NVM Express PassThru Command Packet to send
                            to the NVMe namespace specified by NamespaceId.

  @retval EFI_SUCCESS              The EDKII PEI NVM Express Command Packet was sent by the host.
                                   TransferLength bytes were transferred to, or from DataBuffer.
  @retval EFI_NOT_READY            The EDKII PEI NVM Express Command Packet could not be sent because
                                   the controller is not ready. The caller may retry again later.
  @retval EFI_DEVICE_ERROR         A device error occurred while attempting to send the EDKII PEI NVM
                                   Express Command Packet.
  @retval EFI_INVALID_PARAMETER    Namespace, or the contents of EDKII_PEI_NVM_EXPRESS_PASS_THRU_COMMAND_PACKET
                                   are invalid.
                                   The EDKII PEI NVM Express Command Packet was not sent, so no
                                   additional status information is available.
  @retval EFI_UNSUPPORTED          The command described by the EDKII PEI NVM Express Command Packet
                                   is not supported by the host adapter.
                                   The EDKII PEI NVM Express Command Packet was not sent, so no
                                   additional status information is available.
  @retval EFI_TIMEOUT              A timeout occurred while waiting for the EDKII PEI NVM Express Command
                                   Packet to execute.

**/
EFI_STATUS
NvmePassThru (
  IN     PEI_NVME_CONTROLLER_PRIVATE_DATA                  *Private,
  IN     UINT32                                            NamespaceId,
  IN OUT EDKII_PEI_NVM_EXPRESS_PASS_THRU_COMMAND_PACKET    *Packet
  )
{
  EFI_STATUS               Status;
  NVME_SQ                  *Sq;
  NVME_CQ                  *Cq;
  UINT8                    QueueId;
  UINTN                    SqSize;
  UINTN                    CqSize;
  EDKII_IOMMU_OPERATION    MapOp;
  UINTN                    MapLength;
  EFI_PHYSICAL_ADDRESS     PhyAddr;
  VOID                     *MapData;
  VOID                     *MapMeta;
  UINT32                   Bytes;
  UINT32                   Offset;
  UINT32                   Data32;
  UINT64                   Timer;

  //
  // Check the data fields in Packet parameter
  //
  if (Packet == NULL) {
    DEBUG ((
      DEBUG_ERROR,
      "%a, Invalid parameter: Packet(%lx)\n",
      __FUNCTION__,
      (UINTN)Packet
      ));
    return EFI_INVALID_PARAMETER;
  }

  if ((Packet->NvmeCmd == NULL) || (Packet->NvmeCompletion == NULL)) {
    DEBUG ((
      DEBUG_ERROR,
      "%a, Invalid parameter: NvmeCmd (%lx)/NvmeCompletion(%lx)\n",
      __FUNCTION__,
      (UINTN)Packet->NvmeCmd,
      (UINTN)Packet->NvmeCompletion
      ));
    return EFI_INVALID_PARAMETER;
  }

  if (Packet->QueueType != NVME_ADMIN_QUEUE && Packet->QueueType != NVME_IO_QUEUE) {
    DEBUG ((
      DEBUG_ERROR,
      "%a, Invalid parameter: QueueId(%lx)\n",
      __FUNCTION__,
      (UINTN)Packet->QueueType
      ));
    return EFI_INVALID_PARAMETER;
  }

  QueueId = Packet->QueueType;
  Sq      = Private->SqBuffer[QueueId] + Private->SqTdbl[QueueId].Sqt;
  Cq      = Private->CqBuffer[QueueId] + Private->CqHdbl[QueueId].Cqh;
  if (QueueId == NVME_ADMIN_QUEUE) {
    SqSize = NVME_ASQ_SIZE + 1;
    CqSize = NVME_ACQ_SIZE + 1;
  } else {
    SqSize = NVME_CSQ_SIZE + 1;
    CqSize = NVME_CCQ_SIZE + 1;
  }

  if (Packet->NvmeCmd->Nsid != NamespaceId) {
    DEBUG ((
      DEBUG_ERROR,
      "%a: Nsid mismatch (%x, %x)\n",
      __FUNCTION__,
      Packet->NvmeCmd->Nsid,
      NamespaceId
      ));
    return EFI_INVALID_PARAMETER;
  }

  ZeroMem (Sq, sizeof (NVME_SQ));
  Sq->Opc  = Packet->NvmeCmd->Cdw0.Opcode;
  Sq->Fuse = Packet->NvmeCmd->Cdw0.FusedOperation;
  Sq->Cid  = Packet->NvmeCmd->Cdw0.Cid;
  Sq->Nsid = Packet->NvmeCmd->Nsid;

  //
  // Currently we only support PRP for data transfer, SGL is NOT supported
  //
  ASSERT (Sq->Psdt == 0);
  if (Sq->Psdt != 0) {
    DEBUG ((DEBUG_ERROR, "%a: Does not support SGL mechanism.\n", __FUNCTION__));
    return EFI_UNSUPPORTED;
  }

  Sq->Prp[0] = (UINT64)(UINTN)Packet->TransferBuffer;
  Sq->Prp[1] = 0;
  MapData    = NULL;
  MapMeta    = NULL;
  Status     = EFI_SUCCESS;
  //
  // If the NVMe cmd has data in or out, then mapping the user buffer to the PCI controller
  // specific addresses.
  //
  if ((Sq->Opc & (BIT0 | BIT1)) != 0) {
    if (((Packet->TransferLength != 0) && (Packet->TransferBuffer == NULL)) ||
        ((Packet->TransferLength == 0) && (Packet->TransferBuffer != NULL))) {
      return EFI_INVALID_PARAMETER;
    }

    //
    // Currently, we only support creating IO submission/completion queues that are
    // allocated internally by the driver.
    //
    if ((Packet->QueueType == NVME_ADMIN_QUEUE) &&
        ((Sq->Opc == NVME_ADMIN_CRIOCQ_CMD) || (Sq->Opc == NVME_ADMIN_CRIOSQ_CMD))) {
      if ((Packet->TransferBuffer != Private->SqBuffer[NVME_IO_QUEUE]) &&
          (Packet->TransferBuffer != Private->CqBuffer[NVME_IO_QUEUE])) {
        DEBUG ((
          DEBUG_ERROR,
          "%a: Does not support external IO queues creation request.\n",
          __FUNCTION__
          ));
        return EFI_UNSUPPORTED;
      }
    } else {
      if ((Sq->Opc & BIT0) != 0) {
        MapOp = EdkiiIoMmuOperationBusMasterRead;
      } else {
        MapOp = EdkiiIoMmuOperationBusMasterWrite;
      }

      if ((Packet->TransferLength != 0) && (Packet->TransferBuffer != NULL)) {
        MapLength = Packet->TransferLength;
        Status = IoMmuMap (
                   MapOp,
                   Packet->TransferBuffer,
                   &MapLength,
                   &PhyAddr,
                   &MapData
                   );
        if (EFI_ERROR (Status) || (MapLength != Packet->TransferLength)) {
          Status = EFI_OUT_OF_RESOURCES;
          DEBUG ((DEBUG_ERROR, "%a: Fail to map data buffer.\n", __FUNCTION__));
          goto Exit;
        }

        Sq->Prp[0] = PhyAddr;
      }

      if((Packet->MetadataLength != 0) && (Packet->MetadataBuffer != NULL)) {
        MapLength = Packet->MetadataLength;
        Status = IoMmuMap (
                   MapOp,
                   Packet->MetadataBuffer,
                   &MapLength,
                   &PhyAddr,
                   &MapMeta
                   );
        if (EFI_ERROR (Status) || (MapLength != Packet->MetadataLength)) {
          Status = EFI_OUT_OF_RESOURCES;
          DEBUG ((DEBUG_ERROR, "%a: Fail to map meta data buffer.\n", __FUNCTION__));
          goto Exit;
        }
        Sq->Mptr = PhyAddr;
      }
    }
  }

  //
  // If the Buffer Size spans more than two memory pages (page Size as defined in CC.Mps),
  // then build a PRP list in the second PRP submission queue entry.
  //
  Offset = ((UINT32)Sq->Prp[0]) & (EFI_PAGE_SIZE - 1);
  Bytes  = Packet->TransferLength;

  if ((Offset + Bytes) > (EFI_PAGE_SIZE * 2)) {
    //
    // Create PrpList for remaining Data Buffer.
    //
    PhyAddr = (Sq->Prp[0] + EFI_PAGE_SIZE) & ~(EFI_PAGE_SIZE - 1);
    Sq->Prp[1] = NvmeCreatePrpList (
                   Private,
                   PhyAddr,
                   EFI_SIZE_TO_PAGES(Offset + Bytes) - 1
                   );
    if (Sq->Prp[1] == 0) {
      Status = EFI_OUT_OF_RESOURCES;
      DEBUG ((DEBUG_ERROR, "%a: Create PRP list fail, Status - %r\n", __FUNCTION__, Status));
      goto Exit;
    }

  } else if ((Offset + Bytes) > EFI_PAGE_SIZE) {
    Sq->Prp[1] = (Sq->Prp[0] + EFI_PAGE_SIZE) & ~(EFI_PAGE_SIZE - 1);
  }

  if (Packet->NvmeCmd->Flags & CDW10_VALID) {
    Sq->Payload.Raw.Cdw10 = Packet->NvmeCmd->Cdw10;
  }
  if (Packet->NvmeCmd->Flags & CDW11_VALID) {
    Sq->Payload.Raw.Cdw11 = Packet->NvmeCmd->Cdw11;
  }
  if (Packet->NvmeCmd->Flags & CDW12_VALID) {
    Sq->Payload.Raw.Cdw12 = Packet->NvmeCmd->Cdw12;
  }
  if (Packet->NvmeCmd->Flags & CDW13_VALID) {
    Sq->Payload.Raw.Cdw13 = Packet->NvmeCmd->Cdw13;
  }
  if (Packet->NvmeCmd->Flags & CDW14_VALID) {
    Sq->Payload.Raw.Cdw14 = Packet->NvmeCmd->Cdw14;
  }
  if (Packet->NvmeCmd->Flags & CDW15_VALID) {
    Sq->Payload.Raw.Cdw15 = Packet->NvmeCmd->Cdw15;
  }

  //
  // Ring the submission queue doorbell.
  //
  Private->SqTdbl[QueueId].Sqt++;
  if (Private->SqTdbl[QueueId].Sqt == SqSize) {
    Private->SqTdbl[QueueId].Sqt = 0;
  }
  Data32 = ReadUnaligned32 ((UINT32 *)&Private->SqTdbl[QueueId]);
  Status = NVME_SET_SQTDBL (Private, QueueId, &Data32);
  if (EFI_ERROR (Status)) {
    DEBUG ((DEBUG_ERROR, "%a: NVME_SET_SQTDBL fail, Status - %r\n", __FUNCTION__, Status));
    goto Exit;
  }

  //
  // Wait for completion queue to get filled in.
  //
  Status = EFI_TIMEOUT;
  Timer  = 0;
  while (Timer < Packet->CommandTimeout) {
    if (Cq->Pt != Private->Pt[QueueId]) {
      Status = EFI_SUCCESS;
      break;
    }

    MicroSecondDelay (NVME_POLL_INTERVAL);
    Timer += NVME_POLL_INTERVAL;
  }

  if (Status == EFI_TIMEOUT) {
    //
    // Timeout occurs for an NVMe command, reset the controller to abort the outstanding command
    //
    DEBUG ((DEBUG_ERROR, "%a: Timeout occurs for the PassThru command.\n", __FUNCTION__));
    Status = NvmeControllerInit (Private);
    if (EFI_ERROR (Status)) {
      Status = EFI_DEVICE_ERROR;
    } else {
      //
      // Return EFI_TIMEOUT to indicate a timeout occurs for PassThru command
      //
      Status = EFI_TIMEOUT;
    }
    goto Exit;
  }

  //
  // Move forward the Completion Queue head
  //
  Private->CqHdbl[QueueId].Cqh++;
  if (Private->CqHdbl[QueueId].Cqh == CqSize) {
    Private->CqHdbl[QueueId].Cqh = 0;
    Private->Pt[QueueId] ^= 1;
  }

  //
  // Copy the Respose Queue entry for this command to the callers response buffer
  //
  CopyMem (Packet->NvmeCompletion, Cq, sizeof (EDKII_PEI_NVM_EXPRESS_COMPLETION));

  //
  // Check the NVMe cmd execution result
  //
  Status = NvmeCheckCqStatus (Cq);
  NVME_SET_CQHDBL (Private, QueueId, &Private->CqHdbl[QueueId]);

Exit:
  if (MapMeta != NULL) {
    IoMmuUnmap (MapMeta);
  }

  if (MapData != NULL) {
    IoMmuUnmap (MapData);
  }

  return Status;
}
Exemplo n.º 8
0
/**
  Sends an NVM Express Command Packet to an NVM Express controller or namespace. This function supports
  both blocking I/O and non-blocking I/O. The blocking I/O functionality is required, and the non-blocking
  I/O functionality is optional.


  @param[in]     This                A pointer to the EFI_NVM_EXPRESS_PASS_THRU_PROTOCOL instance.
  @param[in]     NamespaceId         A 32 bit namespace ID as defined in the NVMe specification to which the NVM Express Command
                                     Packet will be sent.  A value of 0 denotes the NVM Express controller, a value of all 0xFF's
                                     (all bytes are 0xFF) in the namespace ID specifies that the command packet should be sent to
                                     all valid namespaces.
  @param[in,out] Packet              A pointer to the NVM Express Command Packet.
  @param[in]     Event               If non-blocking I/O is not supported then Event is ignored, and blocking I/O is performed.
                                     If Event is NULL, then blocking I/O is performed. If Event is not NULL and non-blocking I/O
                                     is supported, then non-blocking I/O is performed, and Event will be signaled when the NVM
                                     Express Command Packet completes.

  @retval EFI_SUCCESS                The NVM Express Command Packet was sent by the host. TransferLength bytes were transferred
                                     to, or from DataBuffer.
  @retval EFI_BAD_BUFFER_SIZE        The NVM Express Command Packet was not executed. The number of bytes that could be transferred
                                     is returned in TransferLength.
  @retval EFI_NOT_READY              The NVM Express Command Packet could not be sent because the controller is not ready. The caller
                                     may retry again later.
  @retval EFI_DEVICE_ERROR           A device error occurred while attempting to send the NVM Express Command Packet.
  @retval EFI_INVALID_PARAMETER      NamespaceId or the contents of EFI_NVM_EXPRESS_PASS_THRU_COMMAND_PACKET are invalid. The NVM
                                     Express Command Packet was not sent, so no additional status information is available.
  @retval EFI_UNSUPPORTED            The command described by the NVM Express Command Packet is not supported by the NVM Express
                                     controller. The NVM Express Command Packet was not sent so no additional status information
                                     is available.
  @retval EFI_TIMEOUT                A timeout occurred while waiting for the NVM Express Command Packet to execute.

**/
EFI_STATUS
EFIAPI
NvmExpressPassThru (
  IN     EFI_NVM_EXPRESS_PASS_THRU_PROTOCOL          *This,
  IN     UINT32                                      NamespaceId,
  IN OUT EFI_NVM_EXPRESS_PASS_THRU_COMMAND_PACKET    *Packet,
  IN     EFI_EVENT                                   Event OPTIONAL
  )
{
  NVME_CONTROLLER_PRIVATE_DATA   *Private;
  EFI_STATUS                     Status;
  EFI_PCI_IO_PROTOCOL            *PciIo;
  NVME_SQ                        *Sq;
  NVME_CQ                        *Cq;
  UINT16                         QueueId;
  UINT32                         Bytes;
  UINT16                         Offset;
  EFI_EVENT                      TimerEvent;
  EFI_PCI_IO_PROTOCOL_OPERATION  Flag;
  EFI_PHYSICAL_ADDRESS           PhyAddr;
  VOID                           *MapData;
  VOID                           *MapMeta;
  VOID                           *MapPrpList;
  UINTN                          MapLength;
  UINT64                         *Prp;
  VOID                           *PrpListHost;
  UINTN                          PrpListNo;
  UINT32                         Attributes;
  UINT32                         IoAlign;
  UINT32                         MaxTransLen;
  UINT32                         Data;
  NVME_PASS_THRU_ASYNC_REQ       *AsyncRequest;
  EFI_TPL                        OldTpl;

  //
  // check the data fields in Packet parameter.
  //
  if ((This == NULL) || (Packet == NULL)) {
    return EFI_INVALID_PARAMETER;
  }

  if ((Packet->NvmeCmd == NULL) || (Packet->NvmeCompletion == NULL)) {
    return EFI_INVALID_PARAMETER;
  }

  if (Packet->QueueType != NVME_ADMIN_QUEUE && Packet->QueueType != NVME_IO_QUEUE) {
    return EFI_INVALID_PARAMETER;
  }

  //
  // 'Attributes' with neither EFI_NVM_EXPRESS_PASS_THRU_ATTRIBUTES_LOGICAL nor
  // EFI_NVM_EXPRESS_PASS_THRU_ATTRIBUTES_PHYSICAL set is an illegal
  // configuration.
  //
  Attributes  = This->Mode->Attributes;
  if ((Attributes & (EFI_NVM_EXPRESS_PASS_THRU_ATTRIBUTES_PHYSICAL |
    EFI_NVM_EXPRESS_PASS_THRU_ATTRIBUTES_LOGICAL)) == 0) {
    return EFI_INVALID_PARAMETER;
  }

  //
  // Buffer alignment check for TransferBuffer & MetadataBuffer.
  //
  IoAlign     = This->Mode->IoAlign;
  if (IoAlign > 0 && (((UINTN) Packet->TransferBuffer & (IoAlign - 1)) != 0)) {
    return EFI_INVALID_PARAMETER;
  }

  if (IoAlign > 0 && (((UINTN) Packet->MetadataBuffer & (IoAlign - 1)) != 0)) {
    return EFI_INVALID_PARAMETER;
  }

  Private     = NVME_CONTROLLER_PRIVATE_DATA_FROM_PASS_THRU (This);

  //
  // Check NamespaceId is valid or not.
  //
  if ((NamespaceId > Private->ControllerData->Nn) &&
      (NamespaceId != (UINT32) -1)) {
    return EFI_INVALID_PARAMETER;
  }

  //
  // Check whether TransferLength exceeds the maximum data transfer size.
  //
  if (Private->ControllerData->Mdts != 0) {
    MaxTransLen = (1 << (Private->ControllerData->Mdts)) *
                  (1 << (Private->Cap.Mpsmin + 12));
    if (Packet->TransferLength > MaxTransLen) {
      Packet->TransferLength = MaxTransLen;
      return EFI_BAD_BUFFER_SIZE;
    }
  }

  PciIo       = Private->PciIo;
  MapData     = NULL;
  MapMeta     = NULL;
  MapPrpList  = NULL;
  PrpListHost = NULL;
  PrpListNo   = 0;
  Prp         = NULL;
  TimerEvent  = NULL;
  Status      = EFI_SUCCESS;

  if (Packet->QueueType == NVME_ADMIN_QUEUE) {
    QueueId = 0;
  } else {
    if (Event == NULL) {
      QueueId = 1;
    } else {
      QueueId = 2;

      //
      // Submission queue full check.
      //
      if ((Private->SqTdbl[QueueId].Sqt + 1) % (NVME_ASYNC_CSQ_SIZE + 1) ==
          Private->AsyncSqHead) {
        return EFI_NOT_READY;
      }
    }
  }
  Sq  = Private->SqBuffer[QueueId] + Private->SqTdbl[QueueId].Sqt;
  Cq  = Private->CqBuffer[QueueId] + Private->CqHdbl[QueueId].Cqh;

  if (Packet->NvmeCmd->Nsid != NamespaceId) {
    return EFI_INVALID_PARAMETER;
  }

  ZeroMem (Sq, sizeof (NVME_SQ));
  Sq->Opc  = (UINT8)Packet->NvmeCmd->Cdw0.Opcode;
  Sq->Fuse = (UINT8)Packet->NvmeCmd->Cdw0.FusedOperation;
  Sq->Cid  = Private->Cid[QueueId]++;
  Sq->Nsid = Packet->NvmeCmd->Nsid;

  //
  // Currently we only support PRP for data transfer, SGL is NOT supported.
  //
  ASSERT (Sq->Psdt == 0);
  if (Sq->Psdt != 0) {
    DEBUG ((EFI_D_ERROR, "NvmExpressPassThru: doesn't support SGL mechanism\n"));
    return EFI_UNSUPPORTED;
  }

  Sq->Prp[0] = (UINT64)(UINTN)Packet->TransferBuffer;
  //
  // If the NVMe cmd has data in or out, then mapping the user buffer to the PCI controller specific addresses.
  // Note here we don't handle data buffer for CreateIOSubmitionQueue and CreateIOCompletionQueue cmds because
  // these two cmds are special which requires their data buffer must support simultaneous access by both the
  // processor and a PCI Bus Master. It's caller's responsbility to ensure this.
  //
  if (((Sq->Opc & (BIT0 | BIT1)) != 0) && (Sq->Opc != NVME_ADMIN_CRIOCQ_CMD) && (Sq->Opc != NVME_ADMIN_CRIOSQ_CMD)) {
    if ((Packet->TransferLength == 0) || (Packet->TransferBuffer == NULL)) {
      return EFI_INVALID_PARAMETER;
    }

    if ((Sq->Opc & BIT0) != 0) {
      Flag = EfiPciIoOperationBusMasterRead;
    } else {
      Flag = EfiPciIoOperationBusMasterWrite;
    }

    MapLength = Packet->TransferLength;
    Status = PciIo->Map (
                      PciIo,
                      Flag,
                      Packet->TransferBuffer,
                      &MapLength,
                      &PhyAddr,
                      &MapData
                      );
    if (EFI_ERROR (Status) || (Packet->TransferLength != MapLength)) {
      return EFI_OUT_OF_RESOURCES;
    }

    Sq->Prp[0] = PhyAddr;
    Sq->Prp[1] = 0;

    if((Packet->MetadataLength != 0) && (Packet->MetadataBuffer != NULL)) {
      MapLength = Packet->MetadataLength;
      Status = PciIo->Map (
                        PciIo,
                        Flag,
                        Packet->MetadataBuffer,
                        &MapLength,
                        &PhyAddr,
                        &MapMeta
                        );
      if (EFI_ERROR (Status) || (Packet->MetadataLength != MapLength)) {
        PciIo->Unmap (
                 PciIo,
                 MapData
                 );

        return EFI_OUT_OF_RESOURCES;
      }
      Sq->Mptr = PhyAddr;
    }
  }
  //
  // If the buffer size spans more than two memory pages (page size as defined in CC.Mps),
  // then build a PRP list in the second PRP submission queue entry.
  //
  Offset = ((UINT16)Sq->Prp[0]) & (EFI_PAGE_SIZE - 1);
  Bytes  = Packet->TransferLength;

  if ((Offset + Bytes) > (EFI_PAGE_SIZE * 2)) {
    //
    // Create PrpList for remaining data buffer.
    //
    PhyAddr = (Sq->Prp[0] + EFI_PAGE_SIZE) & ~(EFI_PAGE_SIZE - 1);
    Prp = NvmeCreatePrpList (PciIo, PhyAddr, EFI_SIZE_TO_PAGES(Offset + Bytes) - 1, &PrpListHost, &PrpListNo, &MapPrpList);
    if (Prp == NULL) {
      goto EXIT;
    }

    Sq->Prp[1] = (UINT64)(UINTN)Prp;
  } else if ((Offset + Bytes) > EFI_PAGE_SIZE) {
    Sq->Prp[1] = (Sq->Prp[0] + EFI_PAGE_SIZE) & ~(EFI_PAGE_SIZE - 1);
  }

  if(Packet->NvmeCmd->Flags & CDW2_VALID) {
    Sq->Rsvd2 = (UINT64)Packet->NvmeCmd->Cdw2;
  }
  if(Packet->NvmeCmd->Flags & CDW3_VALID) {
    Sq->Rsvd2 |= LShiftU64 ((UINT64)Packet->NvmeCmd->Cdw3, 32);
  }
  if(Packet->NvmeCmd->Flags & CDW10_VALID) {
    Sq->Payload.Raw.Cdw10 = Packet->NvmeCmd->Cdw10;
  }
  if(Packet->NvmeCmd->Flags & CDW11_VALID) {
    Sq->Payload.Raw.Cdw11 = Packet->NvmeCmd->Cdw11;
  }
  if(Packet->NvmeCmd->Flags & CDW12_VALID) {
    Sq->Payload.Raw.Cdw12 = Packet->NvmeCmd->Cdw12;
  }
  if(Packet->NvmeCmd->Flags & CDW13_VALID) {
    Sq->Payload.Raw.Cdw13 = Packet->NvmeCmd->Cdw13;
  }
  if(Packet->NvmeCmd->Flags & CDW14_VALID) {
    Sq->Payload.Raw.Cdw14 = Packet->NvmeCmd->Cdw14;
  }
  if(Packet->NvmeCmd->Flags & CDW15_VALID) {
    Sq->Payload.Raw.Cdw15 = Packet->NvmeCmd->Cdw15;
  }

  //
  // Ring the submission queue doorbell.
  //
  if ((Event != NULL) && (QueueId != 0)) {
    Private->SqTdbl[QueueId].Sqt =
      (Private->SqTdbl[QueueId].Sqt + 1) % (NVME_ASYNC_CSQ_SIZE + 1);
  } else {
    Private->SqTdbl[QueueId].Sqt ^= 1;
  }
  Data = ReadUnaligned32 ((UINT32*)&Private->SqTdbl[QueueId]);
  Status = PciIo->Mem.Write (
               PciIo,
               EfiPciIoWidthUint32,
               NVME_BAR,
               NVME_SQTDBL_OFFSET(QueueId, Private->Cap.Dstrd),
               1,
               &Data
               );

  if (EFI_ERROR (Status)) {
    goto EXIT;
  }

  //
  // For non-blocking requests, return directly if the command is placed
  // in the submission queue.
  //
  if ((Event != NULL) && (QueueId != 0)) {
    AsyncRequest = AllocateZeroPool (sizeof (NVME_PASS_THRU_ASYNC_REQ));
    if (AsyncRequest == NULL) {
      Status = EFI_DEVICE_ERROR;
      goto EXIT;
    }

    AsyncRequest->Signature     = NVME_PASS_THRU_ASYNC_REQ_SIG;
    AsyncRequest->Packet        = Packet;
    AsyncRequest->CommandId     = Sq->Cid;
    AsyncRequest->CallerEvent   = Event;
    AsyncRequest->MapData       = MapData;
    AsyncRequest->MapMeta       = MapMeta;
    AsyncRequest->MapPrpList    = MapPrpList;
    AsyncRequest->PrpListNo     = PrpListNo;
    AsyncRequest->PrpListHost   = PrpListHost;

    OldTpl = gBS->RaiseTPL (TPL_NOTIFY);
    InsertTailList (&Private->AsyncPassThruQueue, &AsyncRequest->Link);
    gBS->RestoreTPL (OldTpl);

    return EFI_SUCCESS;
  }

  Status = gBS->CreateEvent (
                  EVT_TIMER,
                  TPL_CALLBACK,
                  NULL,
                  NULL,
                  &TimerEvent
                  );
  if (EFI_ERROR (Status)) {
    goto EXIT;
  }

  Status = gBS->SetTimer(TimerEvent, TimerRelative, Packet->CommandTimeout);

  if (EFI_ERROR(Status)) {
    goto EXIT;
  }

  //
  // Wait for completion queue to get filled in.
  //
  Status = EFI_TIMEOUT;
  while (EFI_ERROR (gBS->CheckEvent (TimerEvent))) {
    if (Cq->Pt != Private->Pt[QueueId]) {
      Status = EFI_SUCCESS;
      break;
    }
  }

  //
  // Check the NVMe cmd execution result
  //
  if (Status != EFI_TIMEOUT) {
    if ((Cq->Sct == 0) && (Cq->Sc == 0)) {
      Status = EFI_SUCCESS;
    } else {
      Status = EFI_DEVICE_ERROR;
      //
      // Copy the Respose Queue entry for this command to the callers response buffer
      //
      CopyMem(Packet->NvmeCompletion, Cq, sizeof(EFI_NVM_EXPRESS_COMPLETION));
    
      //
      // Dump every completion entry status for debugging.
      //
      DEBUG_CODE_BEGIN();
        NvmeDumpStatus(Cq);
      DEBUG_CODE_END();
    }
  } else {
    //
    // Timeout occurs for an NVMe command. Reset the controller to abort the
    // outstanding commands.
    //
    DEBUG ((DEBUG_ERROR, "NvmExpressPassThru: Timeout occurs for an NVMe command.\n"));

    //
    // Disable the timer to trigger the process of async transfers temporarily.
    //
    Status = gBS->SetTimer (Private->TimerEvent, TimerCancel, 0);
    if (EFI_ERROR (Status)) {
      goto EXIT;
    }

    //
    // Reset the NVMe controller.
    //
    Status = NvmeControllerInit (Private);
    if (!EFI_ERROR (Status)) {
      Status = AbortAsyncPassThruTasks (Private);
      if (!EFI_ERROR (Status)) {
        //
        // Re-enable the timer to trigger the process of async transfers.
        //
        Status = gBS->SetTimer (Private->TimerEvent, TimerPeriodic, NVME_HC_ASYNC_TIMER);
        if (!EFI_ERROR (Status)) {
          //
          // Return EFI_TIMEOUT to indicate a timeout occurs for NVMe PassThru command.
          //
          Status = EFI_TIMEOUT;
        }
      }
    } else {
      Status = EFI_DEVICE_ERROR;
    }

    goto EXIT;
  }

  if ((Private->CqHdbl[QueueId].Cqh ^= 1) == 0) {
    Private->Pt[QueueId] ^= 1;
  }

  Data = ReadUnaligned32 ((UINT32*)&Private->CqHdbl[QueueId]);
  Status = PciIo->Mem.Write (
               PciIo,
               EfiPciIoWidthUint32,
               NVME_BAR,
               NVME_CQHDBL_OFFSET(QueueId, Private->Cap.Dstrd),
               1,
               &Data
               );

  //
  // For now, the code does not support the non-blocking feature for admin queue.
  // If Event is not NULL for admin queue, signal the caller's event here.
  //
  if (Event != NULL) {
    ASSERT (QueueId == 0);
    gBS->SignalEvent (Event);
  }

EXIT:
  if (MapData != NULL) {
    PciIo->Unmap (
             PciIo,
             MapData
             );
  }

  if (MapMeta != NULL) {
    PciIo->Unmap (
             PciIo,
             MapMeta
             );
  }

  if (MapPrpList != NULL) {
    PciIo->Unmap (
             PciIo,
             MapPrpList
             );
  }

  if (Prp != NULL) {
    PciIo->FreeBuffer (PciIo, PrpListNo, PrpListHost);
  }

  if (TimerEvent != NULL) {
    gBS->CloseEvent (TimerEvent);
  }
  return Status;
}
Exemplo n.º 9
0
/**
  This command defines the attributes of an NV Index and causes the TPM to
  reserve space to hold the data associated with the index.
  If a definition already exists at the index, the TPM will return TPM_RC_NV_DEFINED.

  @param[in]  AuthHandle         TPM_RH_OWNER or TPM_RH_PLATFORM+{PP}.
  @param[in]  AuthSession        Auth Session context
  @param[in]  Auth               The authorization data.
  @param[in]  NvPublic           The public area of the index.
  
  @retval EFI_SUCCESS            Operation completed successfully.
  @retval EFI_DEVICE_ERROR       The command was unsuccessful.
  @retval EFI_ALREADY_STARTED    The command was returned successfully, but NvIndex is already defined.
**/
EFI_STATUS
EFIAPI
Tpm2NvDefineSpace (
  IN      TPMI_RH_PROVISION         AuthHandle,
  IN      TPMS_AUTH_COMMAND         *AuthSession, OPTIONAL
  IN      TPM2B_AUTH                *Auth,
  IN      TPM2B_NV_PUBLIC           *NvPublic
  )
{
  EFI_STATUS                        Status;
  TPM2_NV_DEFINESPACE_COMMAND       SendBuffer;
  TPM2_NV_DEFINESPACE_RESPONSE      RecvBuffer;
  UINT32                            SendBufferSize;
  UINT32                            RecvBufferSize;
  UINT16                            NvPublicSize;
  UINT8                             *Buffer;
  UINT32                            SessionInfoSize;
  TPM_RC                            ResponseCode;

  //
  // Construct command
  //
  SendBuffer.Header.tag = SwapBytes16(TPM_ST_SESSIONS);
  SendBuffer.Header.commandCode = SwapBytes32(TPM_CC_NV_DefineSpace);
  SendBuffer.AuthHandle = SwapBytes32 (AuthHandle);

  //
  // Add in Auth session
  //
  Buffer = (UINT8 *)&SendBuffer.AuthSession;

  // sessionInfoSize
  SessionInfoSize = CopyAuthSessionCommand (AuthSession, Buffer);
  Buffer += SessionInfoSize;
  SendBuffer.AuthSessionSize = SwapBytes32(SessionInfoSize);

  //
  // IndexAuth
  //
  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16(Auth->size));
  Buffer += sizeof(UINT16);
  CopyMem(Buffer, Auth->buffer, Auth->size);
  Buffer += Auth->size;

  //
  // NvPublic
  //
  NvPublicSize = NvPublic->size;

  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16 (NvPublicSize));
  Buffer += sizeof(UINT16);
  WriteUnaligned32 ((UINT32 *)Buffer, SwapBytes32 (NvPublic->nvPublic.nvIndex));
  Buffer += sizeof(UINT32);
  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16 (NvPublic->nvPublic.nameAlg));
  Buffer += sizeof(UINT16);
  WriteUnaligned32 ((UINT32 *)Buffer, SwapBytes32 (ReadUnaligned32 ((UINT32 *)&NvPublic->nvPublic.attributes)));
  Buffer += sizeof(UINT32);
  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16 (NvPublic->nvPublic.authPolicy.size));
  Buffer += sizeof(UINT16);
  CopyMem (Buffer, NvPublic->nvPublic.authPolicy.buffer, NvPublic->nvPublic.authPolicy.size);
  Buffer += NvPublic->nvPublic.authPolicy.size;
  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16 (NvPublic->nvPublic.dataSize));
  Buffer += sizeof(UINT16);

  SendBufferSize = (UINT32)(Buffer - (UINT8 *)&SendBuffer);
  SendBuffer.Header.paramSize = SwapBytes32 (SendBufferSize);

  //
  // send Tpm command
  //
  RecvBufferSize = sizeof (RecvBuffer);
  Status = Tpm2SubmitCommand (SendBufferSize, (UINT8 *)&SendBuffer, &RecvBufferSize, (UINT8 *)&RecvBuffer);
  if (EFI_ERROR (Status)) {
    goto Done;
  }

  if (RecvBufferSize < sizeof (TPM2_RESPONSE_HEADER)) {
    DEBUG ((EFI_D_ERROR, "Tpm2NvDefineSpace - RecvBufferSize Error - %x\n", RecvBufferSize));
    Status = EFI_DEVICE_ERROR;
    goto Done;
  }

  ResponseCode = SwapBytes32(RecvBuffer.Header.responseCode);
  if (ResponseCode != TPM_RC_SUCCESS) {
    DEBUG ((EFI_D_ERROR, "Tpm2NvDefineSpace - responseCode - %x\n", SwapBytes32(RecvBuffer.Header.responseCode)));
  }
  switch (ResponseCode) {
  case TPM_RC_SUCCESS:
    // return data
    break;
  case TPM_RC_SIZE + RC_NV_DefineSpace_publicInfo:
  case TPM_RC_SIZE + RC_NV_DefineSpace_auth:
    Status = EFI_BAD_BUFFER_SIZE;
    break;
  case TPM_RC_ATTRIBUTES:
  case TPM_RC_ATTRIBUTES + RC_NV_DefineSpace_publicInfo:
    Status = EFI_UNSUPPORTED;
    break;
  case TPM_RC_ATTRIBUTES + RC_NV_DefineSpace_authHandle:
    Status = EFI_INVALID_PARAMETER;
    break;
  case TPM_RC_NV_DEFINED:
    Status = EFI_ALREADY_STARTED;
    break;
  case TPM_RC_VALUE + RC_NV_DefineSpace_publicInfo:
  case TPM_RC_VALUE + RC_NV_DefineSpace_authHandle:
    Status = EFI_INVALID_PARAMETER;
    break;
  case TPM_RC_NV_SPACE:
    Status = EFI_OUT_OF_RESOURCES;
    break;
  default:
    Status = EFI_DEVICE_ERROR;
    break;
  }

Done:
  //
  // Clear AuthSession Content
  //
  ZeroMem (&SendBuffer, sizeof(SendBuffer));
  ZeroMem (&RecvBuffer, sizeof(RecvBuffer));
  return Status;
}
Exemplo n.º 10
0
/**

  This function is RDMSR handler for SMM.

  @param Index CPU index

**/
VOID
SmmReadMsrHandler (
  IN UINT32 Index
  )
{
  UINT64            Data64;
  UINT32            MsrIndex;
  X86_REGISTER      *Reg;
  STM_RSC_MSR_DESC  *MsrDesc;
  STM_RSC_MSR_DESC  LocalMsrDesc;

  Reg = &mGuestContextCommonSmm.GuestContextPerCpu[Index].Register;
  MsrIndex = ReadUnaligned32 ((UINT32 *)&Reg->Rcx);

  MsrDesc = GetStmResourceMsr (mHostContextCommon.MleProtectedResource.Base, MsrIndex);
  if ((MsrDesc != NULL) && (MsrDesc->ReadMask != 0)) {
    DEBUG ((EFI_D_ERROR, "RDMSR (%x) violation!\n", MsrIndex));
    AddEventLogForResource (EvtHandledProtectionException, (STM_RSC *)MsrDesc);
    SmmExceptionHandler (Index);
    CpuDeadLoop ();
  }

  MsrDesc = GetStmResourceMsr ((STM_RSC *)(UINTN)mGuestContextCommonSmm.BiosHwResourceRequirementsPtr, MsrIndex);
  if ((MsrDesc == NULL) || (MsrDesc->ReadMask == 0) || (MsrDesc->KernelModeProcessing == 0)) {
    ZeroMem (&LocalMsrDesc, sizeof(LocalMsrDesc));
    LocalMsrDesc.Hdr.RscType = MACHINE_SPECIFIC_REG;
    LocalMsrDesc.Hdr.Length = sizeof(LocalMsrDesc);
    LocalMsrDesc.MsrIndex = MsrIndex;
    LocalMsrDesc.ReadMask = (UINT64)-1;
    LocalMsrDesc.WriteMask = 0;
    AddEventLogForResource (EvtBiosAccessToUnclaimedResource, (STM_RSC *)&LocalMsrDesc);
  }

//  DEBUG ((EFI_D_INFO, "!!!ReadMsrHandler!!!\n"));

  switch (MsrIndex) {
  case IA32_EFER_MSR_INDEX:
    Data64 = mGuestContextCommonSmm.GuestContextPerCpu[Index].Efer;
    break;

  case IA32_SYSENTER_CS_MSR_INDEX:
    Data64 = (UINT64)VmRead32 (VMCS_32_GUEST_IA32_SYSENTER_CS_INDEX);
    break;
  case IA32_SYSENTER_ESP_MSR_INDEX:
    Data64 = (UINT64)VmReadN (VMCS_N_GUEST_IA32_SYSENTER_ESP_INDEX);
    break;
  case IA32_SYSENTER_EIP_MSR_INDEX:
    Data64 = (UINT64)VmReadN (VMCS_N_GUEST_IA32_SYSENTER_EIP_INDEX);
    break;

  case IA32_FS_BASE_MSR_INDEX:
    Data64 = (UINT64)VmReadN (VMCS_N_GUEST_FS_BASE_INDEX);
    break;
  case IA32_GS_BASE_MSR_INDEX:
    Data64 = (UINT64)VmReadN (VMCS_N_GUEST_GS_BASE_INDEX);
    break;

  default:
    //
    // For rest one, we need pass back to BIOS
    //

    Data64 = AsmReadMsr64 (MsrIndex);
    //
    // Need mask read item
    //
    MsrDesc = GetStmResourceMsr (mHostContextCommon.MleProtectedResource.Base, MsrIndex);
    if (MsrDesc != NULL) {
      Data64 &= MsrDesc->ReadMask;
    }

    break;
  }

  Reg->Rax = (UINTN)(UINT32)Data64; // HIGH bits are cleared
  Reg->Rdx = (UINTN)(UINT32)RShiftU64 (Data64, 32); // HIGH bits are cleared

  VmWriteN (VMCS_N_GUEST_RIP_INDEX, VmReadN(VMCS_N_GUEST_RIP_INDEX) + VmRead32(VMCS_32_RO_VMEXIT_INSTRUCTION_LENGTH_INDEX));
  return ;
}
Exemplo n.º 11
0
/**
  Build the Boot#### or Driver#### option from the VariableName.

  @param  VariableName          Variable name of the load option
  @param  VendorGuid            Variable GUID of the load option
  @param  Option                Return the load option.

  @retval EFI_SUCCESS     Get the option just been created
  @retval EFI_NOT_FOUND   Failed to get the new option

**/
EFI_STATUS
EFIAPI
EfiBootManagerVariableToLoadOptionEx (
  IN CHAR16                           *VariableName,
  IN EFI_GUID                         *VendorGuid,
  IN OUT EFI_BOOT_MANAGER_LOAD_OPTION *Option  
  )
{
  EFI_STATUS                         Status;
  UINT32                             Attribute;
  UINT16                             FilePathSize;
  UINT8                              *Variable;
  UINT8                              *VariablePtr;
  UINTN                              VariableSize;
  EFI_DEVICE_PATH_PROTOCOL           *FilePath;
  UINT8                              *OptionalData;
  UINT32                             OptionalDataSize;
  CHAR16                             *Description;
  EFI_BOOT_MANAGER_LOAD_OPTION_TYPE  OptionType;
  UINT16                             OptionNumber;

  if ((VariableName == NULL) || (Option == NULL)) {
    return EFI_INVALID_PARAMETER;
  }

  if (!BmIsValidLoadOptionVariableName (VariableName, &OptionType, &OptionNumber)) {
    return EFI_INVALID_PARAMETER;
  }

  //
  // Read the variable
  //
  GetVariable2 (VariableName, VendorGuid, (VOID **) &Variable, &VariableSize);
  if (Variable == NULL) {
    return EFI_NOT_FOUND;
  }

  //
  // Validate *#### variable data.
  //
  if (!BmValidateOption(Variable, VariableSize)) {
    FreePool (Variable);
    return EFI_INVALID_PARAMETER;
  }

  //
  // Get the option attribute
  //
  VariablePtr = Variable;
  Attribute = ReadUnaligned32 ((UINT32 *) VariablePtr);
  VariablePtr += sizeof (UINT32);

  //
  // Get the option's device path size
  //
  FilePathSize = ReadUnaligned16 ((UINT16 *) VariablePtr);
  VariablePtr += sizeof (UINT16);

  //
  // Get the option's description string
  //
  Description = (CHAR16 *) VariablePtr;

  //
  // Get the option's description string size
  //
  VariablePtr += StrSize ((CHAR16 *) VariablePtr);

  //
  // Get the option's device path
  //
  FilePath = (EFI_DEVICE_PATH_PROTOCOL *) VariablePtr;
  VariablePtr += FilePathSize;

  OptionalDataSize = (UINT32) (VariableSize - (UINTN) (VariablePtr - Variable));
  if (OptionalDataSize == 0) {
    OptionalData = NULL;
  } else {
    OptionalData = VariablePtr;
  }

  Status = EfiBootManagerInitializeLoadOption (
             Option,
             OptionNumber,
             OptionType,
             Attribute,
             Description,
             FilePath,
             OptionalData,
             OptionalDataSize
             );
  ASSERT_EFI_ERROR (Status);

  CopyGuid (&Option->VendorGuid, VendorGuid);

  FreePool (Variable);
  return Status;
}
Exemplo n.º 12
0
/**
  Look for the formset GUID which has the gEfiHiiDriverHealthFormsetGuid class GUID in the specified HII package list.

  @param Handle         Handle to the HII package list.
  @param FormsetGuid    Return the formset GUID.

  @retval EFI_SUCCESS   The formset is found successfully.
  @retval EFI_NOT_FOUND The formset cannot be found.
**/
EFI_STATUS
DriverHealthManagerGetFormsetId (
  IN  EFI_HII_HANDLE   Handle,
  OUT EFI_GUID         *FormsetGuid
  )
{
  EFI_STATUS                   Status;
  EFI_HII_PACKAGE_LIST_HEADER  *HiiPackageList;
  UINTN                        BufferSize;
  UINT8                        *Package;
  UINT8                        *OpCodeData;
  UINT32                       Offset;
  UINT32                       Offset2;
  EFI_HII_PACKAGE_HEADER       PackageHeader;
  UINT8                        Index;
  UINT8                        NumberOfClassGuid;
  EFI_GUID                     *ClassGuid;

  //
  // Get HII PackageList
  //
  BufferSize     = 0;
  HiiPackageList = NULL;
  Status = mDriverHealthManagerDatabase->ExportPackageLists (mDriverHealthManagerDatabase, Handle, &BufferSize, HiiPackageList);
  if (Status == EFI_BUFFER_TOO_SMALL) {
    HiiPackageList = AllocatePool (BufferSize);
    ASSERT (HiiPackageList != NULL);

    Status = mDriverHealthManagerDatabase->ExportPackageLists (mDriverHealthManagerDatabase, Handle, &BufferSize, HiiPackageList);
  }
  if (EFI_ERROR (Status)) {
    return Status;
  }
  ASSERT (HiiPackageList != NULL);

  //
  // Get Form package from this HII package List
  //
  for (Offset = sizeof (EFI_HII_PACKAGE_LIST_HEADER); Offset < ReadUnaligned32 (&HiiPackageList->PackageLength); Offset += PackageHeader.Length) {
    Package = ((UINT8 *) HiiPackageList) + Offset;
    CopyMem (&PackageHeader, Package, sizeof (EFI_HII_PACKAGE_HEADER));

    if (PackageHeader.Type == EFI_HII_PACKAGE_FORMS) {
      //
      // Search FormSet in this Form Package
      //
      
      for (Offset2 = sizeof (EFI_HII_PACKAGE_HEADER); Offset2 < PackageHeader.Length; Offset2 += ((EFI_IFR_OP_HEADER *) OpCodeData)->Length) {
        OpCodeData = Package + Offset2;

        if ((((EFI_IFR_OP_HEADER *) OpCodeData)->OpCode == EFI_IFR_FORM_SET_OP) &&
            (((EFI_IFR_OP_HEADER *) OpCodeData)->Length > OFFSET_OF (EFI_IFR_FORM_SET, Flags))) {
          //
          // Try to compare against formset class GUID
          //
          NumberOfClassGuid = (UINT8) (((EFI_IFR_FORM_SET *) OpCodeData)->Flags & 0x3);
          ClassGuid         = (EFI_GUID *) (OpCodeData + sizeof (EFI_IFR_FORM_SET));
          for (Index = 0; Index < NumberOfClassGuid; Index++) {
            if (CompareGuid (&gEfiHiiDriverHealthFormsetGuid, &ClassGuid[Index])) {
              CopyMem (FormsetGuid, &((EFI_IFR_FORM_SET *) OpCodeData)->Guid, sizeof (EFI_GUID));
              FreePool (HiiPackageList);
              return EFI_SUCCESS;
            }
          }
        }
      }
    }
  }

  //
  // Form package not found in this Package List
  //
  FreePool (HiiPackageList);
  return EFI_NOT_FOUND;
}
Exemplo n.º 13
0
/**
  This function performs a read-modify-write operation on the contents from a given
  location in the PCI configuration space.

  @param  PeiServices     An indirect pointer to the PEI Services Table
                          published by the PEI Foundation.
  @param  This            Pointer to local data for the interface.
  @param  Width           The width of the access. Enumerated in bytes. Type
                          EFI_PEI_PCI_CFG_PPI_WIDTH is defined in Read().
  @param  Address         The physical address of the access.
  @param  SetBits         Points to value to bitwise-OR with the read configuration value.
                          The size of the value is determined by Width.
  @param  ClearBits       Points to the value to negate and bitwise-AND with the read configuration value.
                          The size of the value is determined by Width.

  @retval EFI_SUCCESS           The function completed successfully.
  @retval EFI_INVALID_PARAMETER The invalid access width.

**/
EFI_STATUS
EFIAPI
PciCfg2Modify (
  IN CONST  EFI_PEI_SERVICES          **PeiServices,
  IN CONST  EFI_PEI_PCI_CFG2_PPI      *This,
  IN        EFI_PEI_PCI_CFG_PPI_WIDTH Width,
  IN        UINT64                    Address,
  IN        VOID                      *SetBits,
  IN        VOID                      *ClearBits
  )
{
  UINTN   PciLibAddress;
  UINT16  ClearValue16;
  UINT16  SetValue16;
  UINT32  ClearValue32;
  UINT32  SetValue32;

  PciLibAddress = PciCfgAddressConvert ((EFI_PEI_PCI_CFG_PPI_PCI_ADDRESS *) &Address);

  if (Width == EfiPeiPciCfgWidthUint8) {
    PciAndThenOr8 (PciLibAddress, (UINT8) (~(*(UINT8 *) ClearBits)), *((UINT8 *) SetBits));
  } else if (Width == EfiPeiPciCfgWidthUint16) {
    if ((PciLibAddress & 0x01) == 0) {
      //
      // Aligned Pci address access
      //
      ClearValue16  = (UINT16) (~ReadUnaligned16 ((UINT16 *) ClearBits));
      SetValue16    = ReadUnaligned16 ((UINT16 *) SetBits);
      PciAndThenOr16 (PciLibAddress, ClearValue16, SetValue16);
    } else {
      //
      // Unaligned Pci address access, break up the request into byte by byte.
      //
      PciAndThenOr8 (PciLibAddress, (UINT8) (~(*(UINT8 *) ClearBits)), *((UINT8 *) SetBits));
      PciAndThenOr8 (PciLibAddress + 1, (UINT8) (~(*((UINT8 *) ClearBits + 1))), *((UINT8 *) SetBits + 1));
    }
  } else if (Width == EfiPeiPciCfgWidthUint32) {
    if ((PciLibAddress & 0x03) == 0) {
      //
      // Aligned Pci address access
      //
      ClearValue32  = (UINT32) (~ReadUnaligned32 ((UINT32 *) ClearBits));
      SetValue32    = ReadUnaligned32 ((UINT32 *) SetBits);
      PciAndThenOr32 (PciLibAddress, ClearValue32, SetValue32);
    } else if ((PciLibAddress & 0x01) == 0) {
      //
      // Unaligned Pci address access, break up the request into word by word.
      //
      ClearValue16  = (UINT16) (~ReadUnaligned16 ((UINT16 *) ClearBits));
      SetValue16    = ReadUnaligned16 ((UINT16 *) SetBits);
      PciAndThenOr16 (PciLibAddress, ClearValue16, SetValue16);

      ClearValue16  = (UINT16) (~ReadUnaligned16 ((UINT16 *) ClearBits + 1));
      SetValue16    = ReadUnaligned16 ((UINT16 *) SetBits + 1);
      PciAndThenOr16 (PciLibAddress + 2, ClearValue16, SetValue16);
    } else {
      //
      // Unaligned Pci address access, break up the request into byte by byte.
      //
      PciAndThenOr8 (PciLibAddress, (UINT8) (~(*(UINT8 *) ClearBits)), *((UINT8 *) SetBits));
      PciAndThenOr8 (PciLibAddress + 1, (UINT8) (~(*((UINT8 *) ClearBits + 1))), *((UINT8 *) SetBits + 1));
      PciAndThenOr8 (PciLibAddress + 2, (UINT8) (~(*((UINT8 *) ClearBits + 2))), *((UINT8 *) SetBits + 2));
      PciAndThenOr8 (PciLibAddress + 3, (UINT8) (~(*((UINT8 *) ClearBits + 3))), *((UINT8 *) SetBits + 3));
    }
  } else {
    return EFI_INVALID_PARAMETER;
  }

  return EFI_SUCCESS;
}
/**
  Call back function when the timer event is signaled.

  @param[in]  Event     The Event this notify function registered to.
  @param[in]  Context   Pointer to the context data registered to the
                        Event.

**/
VOID
EFIAPI
ProcessAsyncTaskList (
  IN EFI_EVENT                    Event,
  IN VOID*                        Context
  )
{
  NVME_CONTROLLER_PRIVATE_DATA         *Private;
  EFI_PCI_IO_PROTOCOL                  *PciIo;
  NVME_CQ                              *Cq;
  UINT16                               QueueId;
  UINT32                               Data;
  LIST_ENTRY                           *Link;
  LIST_ENTRY                           *NextLink;
  NVME_PASS_THRU_ASYNC_REQ             *AsyncRequest;
  NVME_BLKIO2_SUBTASK                  *Subtask;
  NVME_BLKIO2_REQUEST                  *BlkIo2Request;
  EFI_BLOCK_IO2_TOKEN                  *Token;
  BOOLEAN                              HasNewItem;
  EFI_STATUS                           Status;

  Private    = (NVME_CONTROLLER_PRIVATE_DATA*)Context;
  QueueId    = 2;
  Cq         = Private->CqBuffer[QueueId] + Private->CqHdbl[QueueId].Cqh;
  HasNewItem = FALSE;
  PciIo      = Private->PciIo;

  //
  // Submit asynchronous subtasks to the NVMe Submission Queue
  //
  for (Link = GetFirstNode (&Private->UnsubmittedSubtasks);
       !IsNull (&Private->UnsubmittedSubtasks, Link);
       Link = NextLink) {
    NextLink      = GetNextNode (&Private->UnsubmittedSubtasks, Link);
    Subtask       = NVME_BLKIO2_SUBTASK_FROM_LINK (Link);
    BlkIo2Request = Subtask->BlockIo2Request;
    Token         = BlkIo2Request->Token;
    RemoveEntryList (Link);
    BlkIo2Request->UnsubmittedSubtaskNum--;

    //
    // If any previous subtask fails, do not process subsequent ones.
    //
    if (Token->TransactionStatus != EFI_SUCCESS) {
      if (IsListEmpty (&BlkIo2Request->SubtasksQueue) &&
          BlkIo2Request->LastSubtaskSubmitted &&
          (BlkIo2Request->UnsubmittedSubtaskNum == 0)) {
        //
        // Remove the BlockIo2 request from the device asynchronous queue.
        //
        RemoveEntryList (&BlkIo2Request->Link);
        FreePool (BlkIo2Request);
        gBS->SignalEvent (Token->Event);
      }

      FreePool (Subtask->CommandPacket->NvmeCmd);
      FreePool (Subtask->CommandPacket->NvmeCompletion);
      FreePool (Subtask->CommandPacket);
      FreePool (Subtask);

      continue;
    }

    Status = Private->Passthru.PassThru (
                                 &Private->Passthru,
                                 Subtask->NamespaceId,
                                 Subtask->CommandPacket,
                                 Subtask->Event
                                 );
    if (Status == EFI_NOT_READY) {
      InsertHeadList (&Private->UnsubmittedSubtasks, Link);
      BlkIo2Request->UnsubmittedSubtaskNum++;
      break;
    } else if (EFI_ERROR (Status)) {
      Token->TransactionStatus = EFI_DEVICE_ERROR;

      if (IsListEmpty (&BlkIo2Request->SubtasksQueue) &&
          Subtask->IsLast) {
        //
        // Remove the BlockIo2 request from the device asynchronous queue.
        //
        RemoveEntryList (&BlkIo2Request->Link);
        FreePool (BlkIo2Request);
        gBS->SignalEvent (Token->Event);
      }

      FreePool (Subtask->CommandPacket->NvmeCmd);
      FreePool (Subtask->CommandPacket->NvmeCompletion);
      FreePool (Subtask->CommandPacket);
      FreePool (Subtask);
    } else {
      InsertTailList (&BlkIo2Request->SubtasksQueue, Link);
      if (Subtask->IsLast) {
        BlkIo2Request->LastSubtaskSubmitted = TRUE;
      }
    }
  }

  while (Cq->Pt != Private->Pt[QueueId]) {
    ASSERT (Cq->Sqid == QueueId);

    HasNewItem = TRUE;

    //
    // Find the command with given Command Id.
    //
    for (Link = GetFirstNode (&Private->AsyncPassThruQueue);
         !IsNull (&Private->AsyncPassThruQueue, Link);
         Link = NextLink) {
      NextLink = GetNextNode (&Private->AsyncPassThruQueue, Link);
      AsyncRequest = NVME_PASS_THRU_ASYNC_REQ_FROM_THIS (Link);
      if (AsyncRequest->CommandId == Cq->Cid) {
        //
        // Copy the Respose Queue entry for this command to the callers
        // response buffer.
        //
        CopyMem (
          AsyncRequest->Packet->NvmeCompletion,
          Cq,
          sizeof(EFI_NVM_EXPRESS_COMPLETION)
          );

        //
        // Free the resources allocated before cmd submission
        //
        if (AsyncRequest->MapData != NULL) {
          PciIo->Unmap (PciIo, AsyncRequest->MapData);
        }
        if (AsyncRequest->MapMeta != NULL) {
          PciIo->Unmap (PciIo, AsyncRequest->MapMeta);
        }
        if (AsyncRequest->MapPrpList != NULL) {
          PciIo->Unmap (PciIo, AsyncRequest->MapPrpList);
        }
        if (AsyncRequest->PrpListHost != NULL) {
          PciIo->FreeBuffer (
                   PciIo,
                   AsyncRequest->PrpListNo,
                   AsyncRequest->PrpListHost
                   );
        }

        RemoveEntryList (Link);
        gBS->SignalEvent (AsyncRequest->CallerEvent);
        FreePool (AsyncRequest);

        //
        // Update submission queue head.
        //
        Private->AsyncSqHead = Cq->Sqhd;
        break;
      }
    }

    Private->CqHdbl[QueueId].Cqh++;
    if (Private->CqHdbl[QueueId].Cqh > NVME_ASYNC_CCQ_SIZE) {
      Private->CqHdbl[QueueId].Cqh = 0;
      Private->Pt[QueueId] ^= 1;
    }

    Cq = Private->CqBuffer[QueueId] + Private->CqHdbl[QueueId].Cqh;
  }

  if (HasNewItem) {
    Data  = ReadUnaligned32 ((UINT32*)&Private->CqHdbl[QueueId]);
    PciIo->Mem.Write (
                 PciIo,
                 EfiPciIoWidthUint32,
                 NVME_BAR,
                 NVME_CQHDBL_OFFSET(QueueId, Private->Cap.Dstrd),
                 1,
                 &Data
                 );
  }
}
Exemplo n.º 15
0
/**
  Check whether the PKCS7 signedData is revoked by verifying with the revoked
  certificates database, and if the signedData is timestamped, the embedded timestamp
  couterSignature will be checked with the supplied timestamp database.

  @param[in]  SignedData      Pointer to buffer containing ASN.1 DER-encoded PKCS7
                              signature.
  @param[in]  SignedDataSize  The size of SignedData buffer in bytes.
  @param[in]  InData          Pointer to the buffer containing the raw message data
                              previously signed and to be verified.
  @param[in]  InDataSize      The size of InData buffer in bytes.
  @param[in]  RevokedDb       Pointer to a list of pointers to EFI_SIGNATURE_LIST
                              structure which contains list of X.509 certificates
                              of revoked signers and revoked content hashes.
  @param[in]  TimeStampDb     Pointer to a list of pointers to EFI_SIGNATURE_LIST
                              structures which is used to pass a list of X.509
                              certificates of trusted timestamp signers.

  @retval  EFI_SUCCESS             The PKCS7 signedData is revoked.
  @retval  EFI_SECURITY_VIOLATION  Fail to verify the signature in PKCS7 signedData.
  @retval  EFI_INVALID_PARAMETER   SignedData is NULL or SignedDataSize is zero.
                                   AllowedDb is NULL.
                                   Content is not NULL and ContentSize is NULL.
  @retval  EFI_NOT_FOUND           Content not found because InData is NULL and no
                                   content embedded in PKCS7 signedData.
  @retval  EFI_UNSUPPORTED         The PKCS7 signedData was not correctly formatted.

**/
EFI_STATUS
P7CheckRevocation (
  IN UINT8                *SignedData,
  IN UINTN                SignedDataSize,
  IN UINT8                *InData,
  IN UINTN                InDataSize,
  IN EFI_SIGNATURE_LIST   **RevokedDb,
  IN EFI_SIGNATURE_LIST   **TimeStampDb
  )
{
  EFI_STATUS          Status;
  EFI_SIGNATURE_LIST  *SigList;
  EFI_SIGNATURE_DATA  *SigData;
  UINT8               *RevokedCert;
  UINTN               RevokedCertSize;
  UINTN               Index;
  UINT8               *CertBuffer;
  UINTN               BufferLength;
  UINT8               *TrustedCert;
  UINTN               TrustedCertLength;
  UINT8               CertNumber;
  UINT8               *CertPtr;
  UINT8               *Cert;
  UINTN               CertSize;
  EFI_TIME            RevocationTime;

  Status          = EFI_UNSUPPORTED;
  SigData         = NULL;
  RevokedCert     = NULL;
  RevokedCertSize = 0;
  CertBuffer      = NULL;
  TrustedCert     = NULL;

  //
  // The signedData is revoked if the hash of content existed in RevokedDb
  //
  if (IsContentHashRevoked (InData, InDataSize, RevokedDb)) {
    Status = EFI_SUCCESS;
    goto _Exit;
  }

  //
  // Check if the signer's certificate can be found in Revoked database
  //
  for (Index = 0; ; Index++) {
    SigList = (EFI_SIGNATURE_LIST *)(RevokedDb[Index]);

    //
    // The list is terminated by a NULL pointer.
    //
    if (SigList == NULL) {
      break;
    }

    //
    // Ignore any non-X509-format entry in the list.
    //
    if (!CompareGuid (&SigList->SignatureType, &gEfiCertX509Guid)) {
      continue;
    }

    SigData = (EFI_SIGNATURE_DATA *) ((UINT8 *) SigList + sizeof (EFI_SIGNATURE_LIST) +
                                      SigList->SignatureHeaderSize);

    RevokedCert     = SigData->SignatureData;
    RevokedCertSize = SigList->SignatureSize - sizeof (EFI_GUID);

    //
    // Verifying the PKCS#7 SignedData with the revoked certificate in RevokedDb
    //
    if (Pkcs7Verify (SignedData, SignedDataSize, RevokedCert, RevokedCertSize, InData, InDataSize)) {
      //
      // The signedData was verified by one entry in Revoked Database
      //
      Status = EFI_SUCCESS;
      break;
    }
  }

  if (!EFI_ERROR (Status)) {
    //
    // The signedData was revoked, since it was hit by RevokedDb
    //
    goto _Exit;
  }

  //
  // Now we will continue to check the X.509 Certificate Hash & Possible Timestamp
  //
  if ((TimeStampDb == NULL) || (*TimeStampDb == NULL)) {
    goto _Exit;
  }

  Pkcs7GetSigners (SignedData, SignedDataSize, &CertBuffer, &BufferLength, &TrustedCert, &TrustedCertLength);
  if ((BufferLength == 0) || (CertBuffer == NULL)) {
    Status = EFI_SUCCESS;
    goto _Exit;
  }

  //
  // Check if any hash of certificates embedded in P7 data is in the revoked database.
  //
  CertNumber = (UINT8) (*CertBuffer);
  CertPtr    = CertBuffer + 1;
  for (Index = 0; Index < CertNumber; Index++) {
    //
    // Retrieve the Certificate data
    //
    CertSize = (UINTN) ReadUnaligned32 ((UINT32 *) CertPtr);
    Cert     = (UINT8 *)CertPtr + sizeof (UINT32);

    if (IsCertHashRevoked (Cert, CertSize, RevokedDb, &RevocationTime)) {
      //
      // Check the timestamp signature and signing time to determine if p7 data can be trusted.
      //
      Status = EFI_SUCCESS;
      if (IsValidTimestamp (SignedData, SignedDataSize, TimeStampDb, &RevocationTime)) {
        //
        // Use EFI_NOT_READY to identify the P7Data is not reovked, because the timestamping
        // occured prior to the time of certificate revocation.
        //
        Status = EFI_NOT_READY;
      }

      goto _Exit;
    }

    CertPtr = CertPtr + sizeof (UINT32) + CertSize;
  }

_Exit:
  Pkcs7FreeSigners (CertBuffer);
  Pkcs7FreeSigners (TrustedCert);

  return Status;
}
Exemplo n.º 16
0
EFI_STATUS
BootOptionStart (
  IN BDS_LOAD_OPTION *BootOption
  )
{
  EFI_STATUS                            Status;
  EFI_DEVICE_PATH_FROM_TEXT_PROTOCOL*   EfiDevicePathFromTextProtocol;
  UINT32                                LoaderType;
  ARM_BDS_LOADER_OPTIONAL_DATA*         OptionalData;
  ARM_BDS_LINUX_ARGUMENTS*              LinuxArguments;
  EFI_DEVICE_PATH_PROTOCOL*             FdtDevicePath;
  EFI_DEVICE_PATH_PROTOCOL*             DefaultFdtDevicePath;
  UINTN                                 FdtDevicePathSize;
  UINTN                                 CmdLineSize;
  UINTN                                 InitrdSize;
  EFI_DEVICE_PATH*                      Initrd;
  UINT16                                LoadOptionIndexSize;

  if (IS_ARM_BDS_BOOTENTRY (BootOption)) {
    Status = EFI_UNSUPPORTED;
    OptionalData = BootOption->OptionalData;
    LoaderType = ReadUnaligned32 ((CONST UINT32*)&OptionalData->Header.LoaderType);

    if (LoaderType == BDS_LOADER_EFI_APPLICATION) {
      if ((BootOption->Attributes & LOAD_OPTION_CATEGORY) == LOAD_OPTION_CATEGORY_APP) {
        // Need to connect every drivers to ensure no dependencies are missing for the application
        BdsConnectAllDrivers ();
      }

      Status = BdsStartEfiApplication (gImageHandle, BootOption->FilePathList, 0, NULL);
    } else if (LoaderType == BDS_LOADER_KERNEL_LINUX_ATAG) {
      LinuxArguments = &(OptionalData->Arguments.LinuxArguments);
      CmdLineSize = ReadUnaligned16 ((CONST UINT16*)&LinuxArguments->CmdLineSize);
      InitrdSize = ReadUnaligned16 ((CONST UINT16*)&LinuxArguments->InitrdSize);

      if (InitrdSize > 0) {
        Initrd = GetAlignedDevicePath ((EFI_DEVICE_PATH*)((UINTN)(LinuxArguments + 1) + CmdLineSize));
      } else {
        Initrd = NULL;
      }

      Status = BdsBootLinuxAtag (BootOption->FilePathList,
                                 Initrd, // Initrd
                                 (CHAR8*)(LinuxArguments + 1)); // CmdLine
    } else if (LoaderType == BDS_LOADER_KERNEL_LINUX_FDT) {
      LinuxArguments = &(OptionalData->Arguments.LinuxArguments);
      CmdLineSize = ReadUnaligned16 ((CONST UINT16*)&LinuxArguments->CmdLineSize);
      InitrdSize = ReadUnaligned16 ((CONST UINT16*)&LinuxArguments->InitrdSize);

      if (InitrdSize > 0) {
        Initrd = GetAlignedDevicePath ((EFI_DEVICE_PATH*)((UINTN)(LinuxArguments + 1) + CmdLineSize));
      } else {
        Initrd = NULL;
      }

      // Get the default FDT device path
      Status = gBS->LocateProtocol (&gEfiDevicePathFromTextProtocolGuid, NULL, (VOID **)&EfiDevicePathFromTextProtocol);
      ASSERT_EFI_ERROR(Status);
      DefaultFdtDevicePath = EfiDevicePathFromTextProtocol->ConvertTextToDevicePath ((CHAR16*)PcdGetPtr(PcdFdtDevicePath));

      // Get the FDT device path
      FdtDevicePathSize = GetDevicePathSize (DefaultFdtDevicePath);
      Status = GetEnvironmentVariable ((CHAR16 *)L"Fdt", &gArmGlobalVariableGuid,
                 DefaultFdtDevicePath, &FdtDevicePathSize, (VOID **)&FdtDevicePath);
      ASSERT_EFI_ERROR(Status);

      Status = BdsBootLinuxFdt (BootOption->FilePathList,
                                Initrd, // Initrd
                                (CHAR8*)(LinuxArguments + 1),
                                FdtDevicePath);

      FreePool (DefaultFdtDevicePath);
      FreePool (FdtDevicePath);
    }
  } else {
    // Connect all the drivers if the EFI Application is not a EFI OS Loader
    if ((BootOption->Attributes & LOAD_OPTION_CATEGORY) == LOAD_OPTION_CATEGORY_APP) {
      BdsConnectAllDrivers ();
    }

    // Set BootCurrent variable
    LoadOptionIndexSize = sizeof(UINT16);
    gRT->SetVariable (L"BootCurrent", &gEfiGlobalVariableGuid,
              EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS,
              LoadOptionIndexSize, &(BootOption->LoadOptionIndex));

    Status = BdsStartEfiApplication (gImageHandle, BootOption->FilePathList, BootOption->OptionalDataSize, BootOption->OptionalData);

    // Clear BootCurrent variable
    LoadOptionIndexSize = sizeof(UINT16);
    gRT->SetVariable (L"BootCurrent", &gEfiGlobalVariableGuid,
              EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS,
              0, NULL);
  }

  return Status;
}
Exemplo n.º 17
0
/**
  This command is used to cause an update to the indicated PCR.
  The data in eventData is hashed using the hash algorithm associated with each bank in which the
  indicated PCR has been allocated. After the data is hashed, the digests list is returned. If the pcrHandle
  references an implemented PCR and not TPM_ALG_NULL, digests list is processed as in
  TPM2_PCR_Extend().
  A TPM shall support an Event.size of zero through 1,024 inclusive.

  @param[in]  PcrHandle   Handle of the PCR
  @param[in]  EventData   Event data in sized buffer
  @param[out] Digests     List of digest

  @retval EFI_SUCCESS      Operation completed successfully.
  @retval EFI_DEVICE_ERROR Unexpected device behavior.
**/
EFI_STATUS
EFIAPI
Tpm2PcrEvent (
  IN      TPMI_DH_PCR               PcrHandle,
  IN      TPM2B_EVENT               *EventData,
     OUT  TPML_DIGEST_VALUES        *Digests
  )
{
  EFI_STATUS                        Status;
  TPM2_PCR_EVENT_COMMAND            Cmd;
  TPM2_PCR_EVENT_RESPONSE           Res;
  UINT32                            CmdSize;
  UINT32                            RespSize;
  UINT32                            ResultBufSize;
  UINT8                             *Buffer;
  UINTN                             Index;
  UINT32                            SessionInfoSize;
  UINT16                            DigestSize;

  Cmd.Header.tag         = SwapBytes16(TPM_ST_SESSIONS);
  Cmd.Header.commandCode = SwapBytes32(TPM_CC_PCR_Event);
  Cmd.PcrHandle          = SwapBytes32(PcrHandle);

  //
  // Add in Auth session
  //
  Buffer = (UINT8 *)&Cmd.AuthSessionPcr;

  // sessionInfoSize
  SessionInfoSize = CopyAuthSessionCommand (NULL, Buffer);
  Buffer += SessionInfoSize;
  Cmd.AuthorizationSize = SwapBytes32(SessionInfoSize);

  // Event
  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16(EventData->size));
  Buffer += sizeof(UINT16);

  CopyMem (Buffer, EventData->buffer, EventData->size);
  Buffer += EventData->size;
  
  CmdSize              = (UINT32)((UINTN)Buffer - (UINTN)&Cmd);
  Cmd.Header.paramSize = SwapBytes32(CmdSize);

  ResultBufSize = sizeof(Res);
  Status = Tpm2SubmitCommand (CmdSize, (UINT8 *)&Cmd, &ResultBufSize, (UINT8 *)&Res);
  if (EFI_ERROR(Status)) {
    return Status;
  }

  if (ResultBufSize > sizeof(Res)) {
    DEBUG ((EFI_D_ERROR, "Tpm2PcrEvent: Failed ExecuteCommand: Buffer Too Small\r\n"));
    return EFI_BUFFER_TOO_SMALL;
  }

  //
  // Validate response headers
  //
  RespSize = SwapBytes32(Res.Header.paramSize);
  if (RespSize > sizeof(Res)) {
    DEBUG ((EFI_D_ERROR, "Tpm2PcrEvent: Response size too large! %d\r\n", RespSize));
    return EFI_BUFFER_TOO_SMALL;
  }

  //
  // Fail if command failed
  //
  if (SwapBytes32(Res.Header.responseCode) != TPM_RC_SUCCESS) {
    DEBUG ((EFI_D_ERROR, "Tpm2PcrEvent: Response Code error! 0x%08x\r\n", SwapBytes32(Res.Header.responseCode)));
    return EFI_DEVICE_ERROR;
  }

  //
  // Unmarshal the response
  //
  Buffer = (UINT8 *)&Res.Digests;

  Digests->count = SwapBytes32 (ReadUnaligned32 ((UINT32 *)Buffer));
  Buffer += sizeof(UINT32);
  for (Index = 0; Index < Digests->count; Index++) {
    Digests->digests[Index].hashAlg = SwapBytes16 (ReadUnaligned16 ((UINT16 *)Buffer));
    Buffer += sizeof(UINT16);
    DigestSize = GetHashSizeFromAlgo (Digests->digests[Index].hashAlg);
    if (DigestSize == 0) {
      DEBUG ((EFI_D_ERROR, "Unknown hash algorithm %d\r\n", Digests->digests[Index].hashAlg));
      return EFI_DEVICE_ERROR;
    }
    CopyMem(
      &Digests->digests[Index].digest,
      Buffer,
      DigestSize
      );
    Buffer += DigestSize;
  }

  return EFI_SUCCESS;
}
Exemplo n.º 18
0
/**
  This service enables the sending of commands to the TPM12.

  @param[in]     InputParameterBlockSize   Size of the TPM12 input parameter block.
  @param[in]     InputParameterBlock       Pointer to the TPM12 input parameter block.
  @param[in,out] OutputParameterBlockSize  Size of the TPM12 output parameter block.
  @param[in]     OutputParameterBlock      Pointer to the TPM12 output parameter block.

  @retval EFI_SUCCESS           The command byte stream was successfully sent to
                                the device and a response was successfully received.
  @retval EFI_DEVICE_ERROR      The command was not successfully sent to the
                                device or a response was not successfully received
                                from the device.
  @retval EFI_BUFFER_TOO_SMALL  The output parameter block is too small.
**/
EFI_STATUS
EFIAPI
Tpm12SubmitCommand (
  IN UINT32      InputParameterBlockSize,
  IN UINT8       *InputParameterBlock,
  IN OUT UINT32  *OutputParameterBlockSize,
  IN UINT8       *OutputParameterBlock
  )
{
  EFI_STATUS           Status;
  UINT32               TpmOutSize;
  TPM_RSP_COMMAND_HDR  *ResponseHeader;
  UINT64               Current;
  UINT64               Previous;
  UINT64               Total;
  UINT64               Start;
  UINT64               End;
  UINT64               Timeout;
  INT64                Cycle;
  INT64                Delta;

  //
  // Make sure response buffer is big enough to hold a response header
  //
  if (*OutputParameterBlockSize < sizeof (TPM_RSP_COMMAND_HDR)) {
    Status = EFI_BUFFER_TOO_SMALL;
    goto Done;
  }

  //
  // Get the current timer value
  //
  Current = GetPerformanceCounter();

  //
  // Initialize local variables
  //
  Start = 0;
  End   = 0;
  Total = 0;

  //
  // Retrieve the performance counter properties and compute the number of
  // performance counter ticks required to reach the maximum TIS timeout of
  // TIS_TIMEOUT_A.  TIS_TIMEOUT_A is in microseconds.
  //
  Timeout = DivU64x32 (
              MultU64x32 (
                GetPerformanceCounterProperties (&Start, &End),
                TIS_TIMEOUT_A
                ),
              1000000
              );
  Cycle = End - Start;
  if (Cycle < 0) {
    Cycle = -Cycle;
  }
  Cycle++;

  //
  // Send command
  //
  do {
    Status = WriteTpmBufferMultiple (InputParameterBlock, InputParameterBlockSize);

    Previous = Current;
    Current  = GetPerformanceCounter();
    Delta = (INT64) (Current - Previous);
    if (Start > End) {
      Delta = -Delta;
    }
    if (Delta < 0) {
      Delta += Cycle;
    }
    Total += Delta;
    if (Total >= Timeout) {
      Status = EFI_TIMEOUT;
      goto Done;
    }
  } while (EFI_ERROR (Status));

  //
  // Receive response header
  //
  do {
    Status = ReadTpmBufferMultiple (OutputParameterBlock, sizeof (TPM_RSP_COMMAND_HDR));

    Previous = Current;
    Current  = GetPerformanceCounter();
    Delta = (INT64) (Current - Previous);
    if (Start > End) {
      Delta = -Delta;
    }
    if (Delta < 0) {
      Delta += Cycle;
    }
    Total += Delta;
    if (Total >= Timeout) {
      Status = EFI_TIMEOUT;
      goto Done;
    }
  } while (EFI_ERROR (Status));

  //
  // Check the response data header (tag, parasize and returncode)
  //
  ResponseHeader = (TPM_RSP_COMMAND_HDR *)OutputParameterBlock;
  if (SwapBytes16 (ReadUnaligned16 (&ResponseHeader->tag)) != TPM_TAG_RSP_COMMAND) {
    Status = EFI_DEVICE_ERROR;
    goto Done;
  }

  TpmOutSize = SwapBytes32 (ReadUnaligned32 (&ResponseHeader->paramSize));
  if (TpmOutSize == sizeof (TPM_RSP_COMMAND_HDR)) {
    Status = EFI_SUCCESS;
    goto Done;
  }
  if (TpmOutSize < sizeof (TPM_RSP_COMMAND_HDR)) {
    Status = EFI_DEVICE_ERROR;
    goto Done;
  }
  if (*OutputParameterBlockSize < TpmOutSize) {
    Status = EFI_BUFFER_TOO_SMALL;
    goto Done;
  }
  *OutputParameterBlockSize = TpmOutSize;

  //
  // Receive the remaining data in the response header
  //
  do {
    Status = ReadTpmBufferMultiple (
               OutputParameterBlock + sizeof (TPM_RSP_COMMAND_HDR),
               TpmOutSize - sizeof (TPM_RSP_COMMAND_HDR)
               );

    Previous = Current;
    Current  = GetPerformanceCounter();
    Delta = (INT64) (Current - Previous);
    if (Start > End) {
      Delta = -Delta;
    }
    if (Delta < 0) {
      Delta += Cycle;
    }
    Total += Delta;
    if (Total >= Timeout) {
      Status = EFI_TIMEOUT;
      goto Done;
    }
  } while (EFI_ERROR (Status));

Done:
  DEBUG ((
    EFI_D_VERBOSE,
    "Tpm12SubmitCommand() Status = %r  Time = %ld ms\n",
    Status,
    DivU64x64Remainder (
      MultU64x32 (Total, 1000),
      GetPerformanceCounterProperties (NULL, NULL),
      NULL
      )
    ));

  return Status;
}
Exemplo n.º 19
0
/**
  Copies the data in a caller supplied buffer to a specified range of PCI
  configuration space.

  Writes the range of PCI configuration registers specified by StartAddress and
  Size from the buffer specified by Buffer. This function only allows the PCI
  configuration registers from a single PCI function to be written. Size is
  returned. When possible 32-bit PCI configuration write cycles are used to
  write from StartAdress to StartAddress + Size. Due to alignment restrictions,
  8-bit and 16-bit PCI configuration write 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  The starting address that encodes the PCI Bus, Device,
                        Function and Register.
  @param  Size          The size in bytes of the transfer.
  @param  Buffer        The pointer to a buffer containing the data to write.

  @return Size written to StartAddress.

**/
UINTN
EFIAPI
PciWriteBuffer (
  IN      UINTN                     StartAddress,
  IN      UINTN                     Size,
  IN      VOID                      *Buffer
  )
{
  UINTN                             ReturnValue;

  ASSERT_INVALID_PCI_ADDRESS (StartAddress, 0);
  ASSERT (((StartAddress & 0xFFF) + Size) <= 0x1000);

  if (Size == 0) {
    return 0;
  }

  ASSERT (Buffer != NULL);

  //
  // Save Size for return
  //
  ReturnValue = Size;

  if ((StartAddress & BIT0) != 0) {
    //
    // Write a byte if StartAddress is byte aligned
    //
    PciWrite8 (StartAddress, *(UINT8*)Buffer);
    StartAddress += sizeof (UINT8);
    Size -= sizeof (UINT8);
    Buffer = (UINT8*)Buffer + 1;
  }

  if (Size >= sizeof (UINT16) && (StartAddress & BIT1) != 0) {
    //
    // Write a word if StartAddress is word aligned
    //
    PciWrite16 (StartAddress, ReadUnaligned16 (Buffer));
    StartAddress += sizeof (UINT16);
    Size -= sizeof (UINT16);
    Buffer = (UINT16*)Buffer + 1;
  }

  while (Size >= sizeof (UINT32)) {
    //
    // Write as many double words as possible
    //
    PciWrite32 (StartAddress, ReadUnaligned32 (Buffer));
    StartAddress += sizeof (UINT32);
    Size -= sizeof (UINT32);
    Buffer = (UINT32*)Buffer + 1;
  }

  if (Size >= sizeof (UINT16)) {
    //
    // Write the last remaining word if exist
    //
    PciWrite16 (StartAddress, ReadUnaligned16 (Buffer));
    StartAddress += sizeof (UINT16);
    Size -= sizeof (UINT16);
    Buffer = (UINT16*)Buffer + 1;
  }

  if (Size >= sizeof (UINT8)) {
    //
    // Write the last remaining byte if exist
    //
    PciWrite8 (StartAddress, *(UINT8*)Buffer);
  }

  return ReturnValue;
}
Exemplo n.º 20
0
EFI_STATUS
BootMenuUpdateBootOption (
  IN LIST_ENTRY *BootOptionsList
  )
{
  EFI_STATUS                    Status;
  BDS_LOAD_OPTION_ENTRY         *BootOptionEntry;
  BDS_LOAD_OPTION               *BootOption;
  BDS_LOAD_OPTION_SUPPORT*      DeviceSupport;
  ARM_BDS_LOADER_ARGUMENTS*     BootArguments;
  CHAR16                        BootDescription[BOOT_DEVICE_DESCRIPTION_MAX];
  CHAR8                         CmdLine[BOOT_DEVICE_OPTION_MAX];
  CHAR16                        UnicodeCmdLine[BOOT_DEVICE_OPTION_MAX];
  EFI_DEVICE_PATH               *DevicePath;
  EFI_DEVICE_PATH               *TempInitrdPath;
  ARM_BDS_LOADER_TYPE           BootType;
  ARM_BDS_LOADER_OPTIONAL_DATA* LoaderOptionalData;
  ARM_BDS_LINUX_ARGUMENTS*      LinuxArguments;
  EFI_DEVICE_PATH               *InitrdPathNodes;
  EFI_DEVICE_PATH               *InitrdPath;
  UINTN                         InitrdSize;
  UINTN                         CmdLineSize;
  BOOLEAN                       InitrdSupport;
  UINT8*                        OptionalData;
  UINTN                         OptionalDataSize;
  BOOLEAN                       IsPrintable;
  BOOLEAN                       IsUnicode;

  DisplayBootOptions (BootOptionsList);
  Status = SelectBootOption (BootOptionsList, UPDATE_BOOT_ENTRY, &BootOptionEntry);
  if (EFI_ERROR (Status)) {
    return Status;
  }
  BootOption = BootOptionEntry->BdsLoadOption;

  // Get the device support for this Boot Option
  Status = BootDeviceGetDeviceSupport (BootOption->FilePathList, &DeviceSupport);
  if (EFI_ERROR(Status)) {
    Print(L"Not possible to retrieve the supported device for the update\n");
    return EFI_UNSUPPORTED;
  }

  Status = DeviceSupport->UpdateDevicePathNode (BootOption->FilePathList, L"EFI Application or the kernel", &DevicePath);
  if (EFI_ERROR(Status)) {
    Status = EFI_ABORTED;
    goto EXIT;
  }

  if (DeviceSupport->RequestBootType) {
    Status = BootDeviceGetType (DevicePath, &BootType, &BootOption->Attributes);
    if (EFI_ERROR(Status)) {
      Status = EFI_ABORTED;
      goto EXIT;
    }
  }

  LoaderOptionalData = BootOption->OptionalData;
  if (LoaderOptionalData != NULL) {
    BootType = (ARM_BDS_LOADER_TYPE)ReadUnaligned32 ((UINT32 *)(&LoaderOptionalData->Header.LoaderType));
  } else {
    BootType = BDS_LOADER_EFI_APPLICATION;
  }

  if ((BootType == BDS_LOADER_KERNEL_LINUX_ATAG) || (BootType == BDS_LOADER_KERNEL_LINUX_FDT)) {
    LinuxArguments = &LoaderOptionalData->Arguments.LinuxArguments;

    CmdLineSize = ReadUnaligned16 ((CONST UINT16*)&LinuxArguments->CmdLineSize);

    InitrdSize = ReadUnaligned16 ((CONST UINT16*)&LinuxArguments->InitrdSize);
    if (InitrdSize > 0) {
      Print(L"Keep the initrd: ");
    } else {
      Print(L"Add an initrd: ");
    }
    Status = GetHIInputBoolean (&InitrdSupport);
    if (EFI_ERROR(Status)) {
      Status = EFI_ABORTED;
      goto EXIT;
    }

    if (InitrdSupport) {
      if (InitrdSize > 0) {
        // Case we update the initrd device path
        Status = DeviceSupport->UpdateDevicePathNode ((EFI_DEVICE_PATH*)((UINTN)(LinuxArguments + 1) + CmdLineSize), L"initrd", &InitrdPath);
        if (EFI_ERROR(Status) && Status != EFI_NOT_FOUND) {// EFI_NOT_FOUND is returned on empty input string, but we can boot without an initrd
          Status = EFI_ABORTED;
          goto EXIT;
        }
        InitrdSize = GetDevicePathSize (InitrdPath);
      } else {
        // Case we create the initrd device path

        Status = DeviceSupport->CreateDevicePathNode (L"initrd", &InitrdPathNodes);
        if (EFI_ERROR(Status) && Status != EFI_NOT_FOUND) { // EFI_NOT_FOUND is returned on empty input string, but we can boot without an initrd
          Status = EFI_ABORTED;
          goto EXIT;
        }

        if (InitrdPathNodes != NULL) {
          // Duplicate Linux kernel Device Path
          TempInitrdPath = DuplicateDevicePath (BootOption->FilePathList);
          // Replace Linux kernel Node by EndNode
          SetDevicePathEndNode (GetLastDevicePathNode (TempInitrdPath));
          // Append the Device Path to the selected device path
          InitrdPath = AppendDevicePath (TempInitrdPath, (CONST EFI_DEVICE_PATH_PROTOCOL *)InitrdPathNodes);
          FreePool (TempInitrdPath);
          // Free the InitrdPathNodes created by Support->CreateDevicePathNode()
          FreePool (InitrdPathNodes);
          if (InitrdPath == NULL) {
            Status = EFI_OUT_OF_RESOURCES;
            goto EXIT;
          }
          InitrdSize = GetDevicePathSize (InitrdPath);
        } else {
          InitrdPath = NULL;
        }
      }
    } else {
      InitrdSize = 0;
    }

    Print(L"Arguments to pass to the binary: ");
    if (CmdLineSize > 0) {
      AsciiStrnCpy (CmdLine, (CONST CHAR8*)(LinuxArguments + 1), sizeof (CmdLine));
      CmdLine[sizeof (CmdLine) - 1] = '\0';
    } else {
      CmdLine[0] = '\0';
    }
    Status = EditHIInputAscii (CmdLine, BOOT_DEVICE_OPTION_MAX);
    if (EFI_ERROR(Status)) {
      Status = EFI_ABORTED;
      goto FREE_DEVICE_PATH;
    }

    CmdLineSize = AsciiStrSize (CmdLine);

    OptionalDataSize = sizeof(ARM_BDS_LOADER_ARGUMENTS) + CmdLineSize + InitrdSize;
    BootArguments = (ARM_BDS_LOADER_ARGUMENTS*)AllocatePool (OptionalDataSize);
    BootArguments->LinuxArguments.CmdLineSize = CmdLineSize;
    BootArguments->LinuxArguments.InitrdSize = InitrdSize;
    CopyMem (&BootArguments->LinuxArguments + 1, CmdLine, CmdLineSize);
    CopyMem ((VOID*)((UINTN)(&BootArguments->LinuxArguments + 1) + CmdLineSize), InitrdPath, InitrdSize);

    OptionalData = (UINT8*)BootArguments;
  } else {
    Print (L"Arguments to pass to the EFI Application: ");

    if (BootOption->OptionalDataSize > 0) {
      IsPrintable = IsPrintableString (BootOption->OptionalData, &IsUnicode);
      if (IsPrintable) {
          //
          // The size in bytes of the string, final zero included, should
          // be equal to or at least lower than "BootOption->OptionalDataSize"
          // and the "IsPrintableString()" has already tested that the length
          // in number of characters is smaller than BOOT_DEVICE_OPTION_MAX,
          // final '\0' included. We can thus copy the string for editing
          // using "CopyMem()". Furthermore, note that in the case of an Unicode
          // string "StrnCpy()" and "StrCpy()" can not be used to copy the
          // string because the data pointed to by "BootOption->OptionalData"
          // is not necessarily 2-byte aligned.
          //
        if (IsUnicode) {
          CopyMem (
            UnicodeCmdLine, BootOption->OptionalData,
            MIN (sizeof (UnicodeCmdLine),
                 BootOption->OptionalDataSize)
            );
        } else {
          CopyMem (
            CmdLine, BootOption->OptionalData,
            MIN (sizeof (CmdLine),
                 BootOption->OptionalDataSize)
            );
        }
      }
    } else {
      UnicodeCmdLine[0] = L'\0';
      IsPrintable = TRUE;
      IsUnicode = TRUE;
    }

    // We do not request arguments for OptionalData that cannot be printed
    if (IsPrintable) {
      if (IsUnicode) {
        Status = EditHIInputStr (UnicodeCmdLine, BOOT_DEVICE_OPTION_MAX);
        if (EFI_ERROR (Status)) {
          Status = EFI_ABORTED;
          goto FREE_DEVICE_PATH;
        }

        OptionalData = (UINT8*)UnicodeCmdLine;
        OptionalDataSize = StrSize (UnicodeCmdLine);
      } else {
        Status = EditHIInputAscii (CmdLine, BOOT_DEVICE_OPTION_MAX);
        if (EFI_ERROR (Status)) {
          Status = EFI_ABORTED;
          goto FREE_DEVICE_PATH;
        }

        OptionalData = (UINT8*)CmdLine;
        OptionalDataSize = AsciiStrSize (CmdLine);
      }
    } else {
      // We keep the former OptionalData
      OptionalData = BootOption->OptionalData;
      OptionalDataSize = BootOption->OptionalDataSize;
    }
  }

  Print(L"Description for this new Entry: ");
  StrnCpy (BootDescription, BootOption->Description, BOOT_DEVICE_DESCRIPTION_MAX);
  Status = EditHIInputStr (BootDescription, BOOT_DEVICE_DESCRIPTION_MAX);
  if (EFI_ERROR(Status)) {
    Status = EFI_ABORTED;
    goto FREE_DEVICE_PATH;
  }

  // Update the entry
  Status = BootOptionUpdate (BootOption, BootOption->Attributes, BootDescription, DevicePath, BootType, OptionalData, OptionalDataSize);

FREE_DEVICE_PATH:
  FreePool (DevicePath);

EXIT:
  if (Status == EFI_ABORTED) {
    Print(L"\n");
  }
  return Status;
}
Exemplo n.º 21
0
/**

  This function is WRMSR handler for SMM.

  @param Index CPU index

**/
VOID
SmmWriteMsrHandler (
  IN UINT32 Index
  )
{
  UINT64            Data64;
  UINT32            MsrIndex;
  VM_ENTRY_CONTROLS VmEntryControls;
  X86_REGISTER      *Reg;
  STM_RSC_MSR_DESC  *MsrDesc;
  STM_RSC_MSR_DESC  LocalMsrDesc;

  Reg = &mGuestContextCommonSmm.GuestContextPerCpu[Index].Register;
  MsrIndex = ReadUnaligned32 ((UINT32 *)&Reg->Rcx);

  MsrDesc = GetStmResourceMsr (mHostContextCommon.MleProtectedResource.Base, MsrIndex);
  if ((MsrDesc != NULL) && (MsrDesc->WriteMask != 0)) {
    DEBUG ((EFI_D_ERROR, "WRMSR (%x) violation!\n", MsrIndex));
    AddEventLogForResource (EvtHandledProtectionException, (STM_RSC *)MsrDesc);
    SmmExceptionHandler (Index);
    CpuDeadLoop ();
  }

  MsrDesc = GetStmResourceMsr ((STM_RSC *)(UINTN)mGuestContextCommonSmm.BiosHwResourceRequirementsPtr, MsrIndex);
  if ((MsrDesc == NULL) || (MsrDesc->WriteMask == 0) || (MsrDesc->KernelModeProcessing == 0)) {
    ZeroMem (&LocalMsrDesc, sizeof(LocalMsrDesc));
    LocalMsrDesc.Hdr.RscType = MACHINE_SPECIFIC_REG;
    LocalMsrDesc.Hdr.Length = sizeof(LocalMsrDesc);
    LocalMsrDesc.MsrIndex = MsrIndex;
    LocalMsrDesc.ReadMask = 0;
    LocalMsrDesc.WriteMask = (UINT64)-1;
    AddEventLogForResource (EvtBiosAccessToUnclaimedResource, (STM_RSC *)&LocalMsrDesc);
  }

//  DEBUG ((EFI_D_INFO, "!!!WriteMsrHandler!!!\n"));
  Data64 = LShiftU64 ((UINT64)ReadUnaligned32 ((UINT32 *)&Reg->Rdx), 32) | (UINT64)ReadUnaligned32 ((UINT32 *)&Reg->Rax);

  switch (MsrIndex) {
  case IA32_EFER_MSR_INDEX:
#if 0
  AcquireSpinLock (&mHostContextCommon.DebugLock);
    if ((Data64 & IA32_EFER_MSR_SCE) != 0) {
      DEBUG ((EFI_D_INFO, "!!!WriteMsrHandler - SCE!!!\n"));
    }
    if ((Data64 & IA32_EFER_MSR_XDE) != 0) {
      DEBUG ((EFI_D_INFO, "!!!WriteMsrHandler - XDE!!!\n"));
    }
  ReleaseSpinLock (&mHostContextCommon.DebugLock);
#endif
    mGuestContextCommonSmm.GuestContextPerCpu[Index].Efer = Data64;
    //
    // Check IA32e mode switch
    //
    VmEntryControls.Uint32 = VmRead32 (VMCS_32_CONTROL_VMENTRY_CONTROLS_INDEX);
    if ((Data64 & IA32_EFER_MSR_MLE) != 0) {
      mGuestContextCommonSmm.GuestContextPerCpu[Index].Efer |= IA32_EFER_MSR_MLE;
    } else {
      mGuestContextCommonSmm.GuestContextPerCpu[Index].Efer &= ~IA32_EFER_MSR_MLE;
    }
    if (((mGuestContextCommonSmm.GuestContextPerCpu[Index].Efer & IA32_EFER_MSR_MLE) != 0) && 
        ((VmReadN (VMCS_N_GUEST_CR0_INDEX) & CR0_PG) != 0)) {
      mGuestContextCommonSmm.GuestContextPerCpu[Index].Efer |= IA32_EFER_MSR_MLA;
      VmEntryControls.Bits.Ia32eGuest = 1;
    } else {
      mGuestContextCommonSmm.GuestContextPerCpu[Index].Efer &= ~IA32_EFER_MSR_MLA;
      VmEntryControls.Bits.Ia32eGuest = 0;
    }
    VmWrite32 (VMCS_32_CONTROL_VMENTRY_CONTROLS_INDEX, VmEntryControls.Uint32);
    VmWrite64 (VMCS_64_GUEST_IA32_EFER_INDEX,          mGuestContextCommonSmm.GuestContextPerCpu[Index].Efer);

    break;

  case IA32_SYSENTER_CS_MSR_INDEX:
    VmWrite32 (VMCS_32_GUEST_IA32_SYSENTER_CS_INDEX, (UINT32)Data64);
    break;
  case IA32_SYSENTER_ESP_MSR_INDEX:
    VmWriteN (VMCS_N_GUEST_IA32_SYSENTER_ESP_INDEX, (UINTN)Data64);
    break;
  case IA32_SYSENTER_EIP_MSR_INDEX:
    VmWriteN (VMCS_N_GUEST_IA32_SYSENTER_EIP_INDEX, (UINTN)Data64);
    break;

  case IA32_FS_BASE_MSR_INDEX:
    VmWriteN (VMCS_N_GUEST_FS_BASE_INDEX, (UINTN)Data64);
    AsmWriteMsr64 (MsrIndex, Data64); // VMM does not use FS
    break;
  case IA32_GS_BASE_MSR_INDEX:
    VmWriteN (VMCS_N_GUEST_GS_BASE_INDEX, (UINTN)Data64);
    AsmWriteMsr64 (MsrIndex, Data64); // VMM does not use GS
    break;
#if 0
  case IA32_KERNAL_GS_BASE_MSR_INDEX:
    AsmWriteMsr64 (MsrIndex, Data64); // VMM does not use this
    break;
  case IA32_STAR_MSR_INDEX:
    AsmWriteMsr64 (MsrIndex, Data64); // VMM does not use this
    break;
  case IA32_LSTAR_MSR_INDEX:
    AsmWriteMsr64 (MsrIndex, Data64); // VMM does not use this
    break;
  case IA32_FMASK_MSR_INDEX:
    AsmWriteMsr64 (MsrIndex, Data64); // VMM does not use this
    break;
#endif

  case IA32_SMM_MONITOR_CTL_MSR_INDEX:
    break;

  case EFI_MSR_NEHALEM_SMRR_PHYS_BASE:
  case EFI_MSR_NEHALEM_SMRR_PHYS_MASK:
    // Ignore the write
    break;
    
  case IA32_BIOS_UPDT_TRIG_MSR_INDEX:
    // Only write it when BIOS request MicrocodeUpdate
    MsrDesc = GetStmResourceMsr ((STM_RSC *)(UINTN)mGuestContextCommonSmm.BiosHwResourceRequirementsPtr, IA32_BIOS_UPDT_TRIG_MSR_INDEX);
    if (MsrDesc != NULL) {
      AsmWriteMsr64 (MsrIndex, Data64);
    }
    break;

  default:
    //
    // For rest one, we need pass back to BIOS
    //

    //
    // Need mask write item
    //
    if (MsrDesc != NULL) {
      Data64 |= MsrDesc->WriteMask;
    }

    AsmWriteMsr64 (MsrIndex, Data64);
    break;
  }

  VmWriteN (VMCS_N_GUEST_RIP_INDEX, VmReadN(VMCS_N_GUEST_RIP_INDEX) + VmRead32(VMCS_32_RO_VMEXIT_INSTRUCTION_LENGTH_INDEX));
  return ;
}
Exemplo n.º 22
0
EFI_STATUS
BootMenuMain (
  VOID
  )
{
  LIST_ENTRY                    BootOptionsList;
  UINTN                         OptionCount;
  UINTN                         BootOptionCount;
  EFI_STATUS                    Status;
  LIST_ENTRY*                   Entry;
  BDS_LOAD_OPTION*              BootOption;
  UINTN                         BootOptionSelected;
  UINTN                         Index;
  UINTN                         BootMainEntryCount;
  BOOLEAN                       IsUnicode;

  BootOption         = NULL;
  BootMainEntryCount = sizeof(BootMainEntries) / sizeof(struct BOOT_MAIN_ENTRY);

  while (TRUE) {
    // Get Boot#### list
    BootOptionList (&BootOptionsList);

    OptionCount = 1;

    // Display the Boot options
    for (Entry = GetFirstNode (&BootOptionsList);
         !IsNull (&BootOptionsList,Entry);
         Entry = GetNextNode (&BootOptionsList,Entry)
         )
    {
      BootOption = LOAD_OPTION_FROM_LINK(Entry);

      Print(L"[%d] %s\n", OptionCount, BootOption->Description);

      DEBUG_CODE_BEGIN();
        CHAR16*                           DevicePathTxt;
        EFI_DEVICE_PATH_TO_TEXT_PROTOCOL* DevicePathToTextProtocol;
        ARM_BDS_LOADER_OPTIONAL_DATA*     OptionalData;
        UINTN                             CmdLineSize;
        ARM_BDS_LOADER_TYPE               LoaderType;

        Status = gBS->LocateProtocol (&gEfiDevicePathToTextProtocolGuid, NULL, (VOID **)&DevicePathToTextProtocol);
        if (EFI_ERROR(Status)) {
          // You must provide an implementation of DevicePathToTextProtocol in your firmware (eg: DevicePathDxe)
          DEBUG((EFI_D_ERROR,"Error: Bds requires DevicePathToTextProtocol\n"));
          return Status;
        }
        DevicePathTxt = DevicePathToTextProtocol->ConvertDevicePathToText (BootOption->FilePathList, TRUE, TRUE);

        Print(L"\t- %s\n",DevicePathTxt);

        // If it is a supported BootEntry then print its details
        if (IS_ARM_BDS_BOOTENTRY (BootOption)) {
          OptionalData = BootOption->OptionalData;
          LoaderType = (ARM_BDS_LOADER_TYPE)ReadUnaligned32 ((CONST UINT32*)&OptionalData->Header.LoaderType);
          if ((LoaderType == BDS_LOADER_KERNEL_LINUX_ATAG) || (LoaderType == BDS_LOADER_KERNEL_LINUX_FDT)) {
            if (ReadUnaligned16 (&OptionalData->Arguments.LinuxArguments.InitrdSize) > 0) {
              CmdLineSize = ReadUnaligned16 (&OptionalData->Arguments.LinuxArguments.CmdLineSize);
              DevicePathTxt = DevicePathToTextProtocol->ConvertDevicePathToText (
                  GetAlignedDevicePath ((EFI_DEVICE_PATH*)((UINTN)(&OptionalData->Arguments.LinuxArguments + 1) + CmdLineSize)), TRUE, TRUE);
              Print(L"\t- Initrd: %s\n", DevicePathTxt);
            }
            if (ReadUnaligned16 (&OptionalData->Arguments.LinuxArguments.CmdLineSize) > 0) {
              Print(L"\t- Arguments: %a\n", (&OptionalData->Arguments.LinuxArguments + 1));
            }
          }

          switch (LoaderType) {
            case BDS_LOADER_EFI_APPLICATION:
              Print(L"\t- LoaderType: EFI Application\n");
              break;

            case BDS_LOADER_KERNEL_LINUX_ATAG:
              Print(L"\t- LoaderType: Linux kernel with ATAG support\n");
              break;

            case BDS_LOADER_KERNEL_LINUX_FDT:
              Print(L"\t- LoaderType: Linux kernel with FDT support\n");
              break;

            default:
              Print(L"\t- LoaderType: Not recognized (%d)\n", LoaderType);
          }
        } else if (BootOption->OptionalData != NULL) {
          if (IsPrintableString (BootOption->OptionalData, &IsUnicode)) {
            if (IsUnicode) {
              Print (L"\t- Arguments: %s\n", BootOption->OptionalData);
            } else {
              AsciiPrint ("\t- Arguments: %a\n", BootOption->OptionalData);
            }
          }
        }
        FreePool(DevicePathTxt);
      DEBUG_CODE_END();

      OptionCount++;
    }
    BootOptionCount = OptionCount-1;

    // Display the hardcoded Boot entries
    for (Index = 0; Index < BootMainEntryCount; Index++) {
      Print(L"[%d] %s\n",OptionCount,BootMainEntries[Index]);
      OptionCount++;
    }

    // Request the boot entry from the user
    BootOptionSelected = 0;
    while (BootOptionSelected == 0) {
      Print(L"Start: ");
      Status = GetHIInputInteger (&BootOptionSelected);
      if (EFI_ERROR(Status) || (BootOptionSelected == 0) || (BootOptionSelected > OptionCount)) {
        Print(L"Invalid input (max %d)\n",(OptionCount-1));
        BootOptionSelected = 0;
      }
    }

    // Start the selected entry
    if (BootOptionSelected > BootOptionCount) {
      // Start the hardcoded entry
      Status = BootMainEntries[BootOptionSelected - BootOptionCount - 1].Callback (&BootOptionsList);
    } else {
      // Find the selected entry from the Boot#### list
      Index = 1;
      for (Entry = GetFirstNode (&BootOptionsList);
           !IsNull (&BootOptionsList,Entry);
           Entry = GetNextNode (&BootOptionsList,Entry)
           )
      {
        if (Index == BootOptionSelected) {
          BootOption = LOAD_OPTION_FROM_LINK(Entry);
          break;
        }
        Index++;
      }

      Status = BootOptionStart (BootOption);
    }
  }
  // Should never go here
}
Exemplo n.º 23
0
/**
  This command includes a secret-based authorization to a policy.
  The caller proves knowledge of the secret value using an authorization
  session using the authValue associated with authHandle.

  @param[in]  AuthHandle         Handle for an entity providing the authorization
  @param[in]  PolicySession      Handle for the policy session being extended.
  @param[in]  AuthSession        Auth Session context
  @param[in]  NonceTPM           The policy nonce for the session.
  @param[in]  CpHashA            Digest of the command parameters to which this authorization is limited.
  @param[in]  PolicyRef          A reference to a policy relating to the authorization.
  @param[in]  Expiration         Time when authorization will expire, measured in seconds from the time that nonceTPM was generated.
  @param[out] Timeout            Time value used to indicate to the TPM when the ticket expires.
  @param[out] PolicyTicket       A ticket that includes a value indicating when the authorization expires.

  @retval EFI_SUCCESS            Operation completed successfully.
  @retval EFI_DEVICE_ERROR       The command was unsuccessful.
**/
EFI_STATUS
EFIAPI
Tpm2PolicySecret (
  IN      TPMI_DH_ENTITY            AuthHandle,
  IN      TPMI_SH_POLICY            PolicySession,
  IN      TPMS_AUTH_COMMAND         *AuthSession, OPTIONAL
  IN      TPM2B_NONCE               *NonceTPM,
  IN      TPM2B_DIGEST              *CpHashA,
  IN      TPM2B_NONCE               *PolicyRef,
  IN      INT32                     Expiration,
  OUT     TPM2B_TIMEOUT             *Timeout,
  OUT     TPMT_TK_AUTH              *PolicyTicket
  )
{
  EFI_STATUS                        Status;
  TPM2_POLICY_SECRET_COMMAND        SendBuffer;
  TPM2_POLICY_SECRET_RESPONSE       RecvBuffer;
  UINT32                            SendBufferSize;
  UINT32                            RecvBufferSize;
  UINT8                             *Buffer;
  UINT32                            SessionInfoSize;

  //
  // Construct command
  //
  SendBuffer.Header.tag = SwapBytes16(TPM_ST_SESSIONS);
  SendBuffer.Header.commandCode = SwapBytes32(TPM_CC_PolicySecret);
  SendBuffer.AuthHandle = SwapBytes32 (AuthHandle);
  SendBuffer.PolicySession = SwapBytes32 (PolicySession);

  //
  // Add in Auth session
  //
  Buffer = (UINT8 *)&SendBuffer.AuthSession;

  // sessionInfoSize
  SessionInfoSize = CopyAuthSessionCommand (AuthSession, Buffer);
  Buffer += SessionInfoSize;
  SendBuffer.AuthSessionSize = SwapBytes32(SessionInfoSize);

  //
  // Real data
  //
  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16(NonceTPM->size));
  Buffer += sizeof(UINT16);
  CopyMem (Buffer, NonceTPM->buffer, NonceTPM->size);
  Buffer += NonceTPM->size;

  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16(CpHashA->size));
  Buffer += sizeof(UINT16);
  CopyMem (Buffer, CpHashA->buffer, CpHashA->size);
  Buffer += CpHashA->size;

  WriteUnaligned16 ((UINT16 *)Buffer, SwapBytes16(PolicyRef->size));
  Buffer += sizeof(UINT16);
  CopyMem (Buffer, PolicyRef->buffer, PolicyRef->size);
  Buffer += PolicyRef->size;

  WriteUnaligned32 ((UINT32 *)Buffer, SwapBytes32((UINT32)Expiration));
  Buffer += sizeof(UINT32);

  SendBufferSize = (UINT32)((UINTN)Buffer - (UINTN)&SendBuffer);
  SendBuffer.Header.paramSize = SwapBytes32 (SendBufferSize);

  //
  // send Tpm command
  //
  RecvBufferSize = sizeof (RecvBuffer);
  Status = Tpm2SubmitCommand (SendBufferSize, (UINT8 *)&SendBuffer, &RecvBufferSize, (UINT8 *)&RecvBuffer);
  if (EFI_ERROR (Status)) {
    goto Done;
  }

  if (RecvBufferSize < sizeof (TPM2_RESPONSE_HEADER)) {
    DEBUG ((EFI_D_ERROR, "Tpm2PolicySecret - RecvBufferSize Error - %x\n", RecvBufferSize));
    Status = EFI_DEVICE_ERROR;
    goto Done;
  }
  if (SwapBytes32(RecvBuffer.Header.responseCode) != TPM_RC_SUCCESS) {
    DEBUG ((EFI_D_ERROR, "Tpm2PolicySecret - responseCode - %x\n", SwapBytes32(RecvBuffer.Header.responseCode)));
    Status = EFI_DEVICE_ERROR;
    goto Done;
  }

  //
  // Return the response
  //
  Buffer = (UINT8 *)&RecvBuffer.Timeout;
  Timeout->size = SwapBytes16(ReadUnaligned16 ((UINT16 *)Buffer));
  if (Timeout->size > sizeof(UINT64)) {
    DEBUG ((DEBUG_ERROR, "Tpm2PolicySecret - Timeout->size error %x\n", Timeout->size));
    Status = EFI_DEVICE_ERROR;
    goto Done;
  }

  Buffer += sizeof(UINT16);
  CopyMem (Timeout->buffer, Buffer, Timeout->size);

  PolicyTicket->tag = SwapBytes16(ReadUnaligned16 ((UINT16 *)Buffer));
  Buffer += sizeof(UINT16);
  PolicyTicket->hierarchy = SwapBytes32(ReadUnaligned32 ((UINT32 *)Buffer));
  Buffer += sizeof(UINT32);
  PolicyTicket->digest.size = SwapBytes16(ReadUnaligned16 ((UINT16 *)Buffer));
  Buffer += sizeof(UINT16);
  if (PolicyTicket->digest.size > sizeof(TPMU_HA)) {
    DEBUG ((DEBUG_ERROR, "Tpm2PolicySecret - digest.size error %x\n", PolicyTicket->digest.size));
    Status = EFI_DEVICE_ERROR;
    goto Done;
  }

  CopyMem (PolicyTicket->digest.buffer, Buffer, PolicyTicket->digest.size);

Done:
  //
  // Clear AuthSession Content
  //
  ZeroMem (&SendBuffer, sizeof(SendBuffer));
  ZeroMem (&RecvBuffer, sizeof(RecvBuffer));
  return Status;
}
Exemplo n.º 24
0
/**
  This command returns Returns a list of TPMS_ALG_PROPERTIES. Each entry is an
  algorithm ID and a set of properties of the algorithm.

  This function parse the value got from TPM2_GetCapability and return the list.

  @param[out] AlgList      List of algorithm.

  @retval EFI_SUCCESS            Operation completed successfully.
  @retval EFI_DEVICE_ERROR       The command was unsuccessful.
**/
EFI_STATUS
EFIAPI
Tpm2GetCapabilitySupportedAlg (
  OUT TPML_ALG_PROPERTY      *AlgList
  )
{
  TPMS_CAPABILITY_DATA    TpmCap;
  TPMI_YES_NO             MoreData;
  UINTN                   Index;
  EFI_STATUS              Status;

  Status = Tpm2GetCapability (
             TPM_CAP_ALGS,
             1,
             MAX_CAP_ALGS,
             &MoreData,
             &TpmCap
             );
  if (EFI_ERROR (Status)) {
    return Status;
  }

  CopyMem (AlgList, &TpmCap.data.algorithms, sizeof (TPML_ALG_PROPERTY));

  AlgList->count = SwapBytes32 (AlgList->count);
  for (Index = 0; Index < AlgList->count; Index++) {
    AlgList->algProperties[Index].alg = SwapBytes16 (AlgList->algProperties[Index].alg);
    WriteUnaligned32 ((UINT32 *)&AlgList->algProperties[Index].algProperties, SwapBytes32 (ReadUnaligned32 ((UINT32 *)&AlgList->algProperties[Index].algProperties)));
  }

  return EFI_SUCCESS;
}
Exemplo n.º 25
0
/**
  Execute READ CAPACITY 16 bytes command to request information regarding
  the capacity of the installed medium of the device.

  This function executes READ CAPACITY 16 bytes command to get the capacity
  of the USB mass storage media, including the presence, block size,
  and last block number.

  @param  UsbMass                The device to retireve disk gemotric.

  @retval EFI_SUCCESS            The disk geometry is successfully retrieved.
  @retval EFI_NOT_READY          The returned block size is zero.
  @retval Other                  READ CAPACITY 16 bytes command execution failed.

**/
EFI_STATUS
UsbBootReadCapacity16 (
  IN USB_MASS_DEVICE            *UsbMass
  )
{
  UINT8                         CapacityCmd[16];
  EFI_SCSI_DISK_CAPACITY_DATA16 CapacityData;
  EFI_BLOCK_IO_MEDIA            *Media;
  EFI_STATUS                    Status;
  UINT32                        BlockSize;

  Media   = &UsbMass->BlockIoMedia;

  Media->MediaPresent = FALSE;
  Media->LastBlock    = 0;
  Media->BlockSize    = 0;

  ZeroMem (CapacityCmd, sizeof (CapacityCmd));
  ZeroMem (&CapacityData, sizeof (CapacityData));

  CapacityCmd[0]  = EFI_SCSI_OP_READ_CAPACITY16;
  CapacityCmd[1]  = 0x10;
  //
  // Partial medium indicator, set the bytes 2 ~ 9 of the Cdb as ZERO.
  //
  ZeroMem ((CapacityCmd + 2), 8);

  CapacityCmd[13] = sizeof (CapacityData);

  Status = UsbBootExecCmdWithRetry (
             UsbMass,
             CapacityCmd,
             (UINT8) sizeof (CapacityCmd),
             EfiUsbDataIn,
             &CapacityData,
             sizeof (CapacityData),
             USB_BOOT_GENERAL_CMD_TIMEOUT
             );
  if (EFI_ERROR (Status)) {
    return Status;
  }

  //
  // Get the information on media presence, block size, and last block number
  // from READ CAPACITY data.
  //
  Media->MediaPresent = TRUE;
  Media->LastBlock    = SwapBytes64 (ReadUnaligned64 ((CONST UINT64 *) &(CapacityData.LastLba7)));

  BlockSize           = SwapBytes32 (ReadUnaligned32 ((CONST UINT32 *) &(CapacityData.BlockSize3)));

  Media->LowestAlignedLba = (CapacityData.LowestAlignLogic2 << 8) |
                             CapacityData.LowestAlignLogic1;
  Media->LogicalBlocksPerPhysicalBlock  = (1 << CapacityData.LogicPerPhysical);
  if (BlockSize == 0) {
    //
    //  Get sense data
    //
    return UsbBootRequestSense (UsbMass);
  } else {
    Media->BlockSize = BlockSize;
  }

  return Status;
}
Exemplo n.º 26
0
/**
  Extract the displayed formset for given HII handle and class guid.

  @param Handle          The HII handle.
  @param SetupClassGuid  The class guid specifies which form set will be displayed.
  @param SkipCount       Skip some formsets which has processed before.
  @param FormSetTitle    Formset title string.
  @param FormSetHelp     Formset help string.
  @param FormSetGuid     Formset Guid.

  @retval  TRUE          The formset for given HII handle will be displayed.
  @return  FALSE         The formset for given HII handle will not be displayed.

**/
BOOLEAN
ExtractDisplayedHiiFormFromHiiHandle (
  IN      EFI_HII_HANDLE      Handle,
  IN      EFI_GUID            *SetupClassGuid,
  IN      UINTN               SkipCount,
  OUT     EFI_STRING_ID       *FormSetTitle,
  OUT     EFI_STRING_ID       *FormSetHelp,
  OUT     EFI_GUID            *FormSetGuid
  )
{
  EFI_STATUS                   Status;
  UINTN                        BufferSize;
  EFI_HII_PACKAGE_LIST_HEADER  *HiiPackageList;
  UINT8                        *Package;
  UINT8                        *OpCodeData;
  UINT32                       Offset;
  UINT32                       Offset2;
  UINT32                       PackageListLength;
  EFI_HII_PACKAGE_HEADER       PackageHeader;
  EFI_GUID                     *ClassGuid;
  UINT8                        ClassGuidNum;
  BOOLEAN                      FoundAndSkip;

  ASSERT (Handle != NULL);
  ASSERT (SetupClassGuid != NULL && FormSetTitle != NULL && FormSetHelp != NULL && FormSetGuid != NULL);

  *FormSetTitle = 0;
  *FormSetHelp  = 0;
  ClassGuidNum  = 0;
  ClassGuid     = NULL;
  FoundAndSkip  = FALSE;

  //
  // Get HII PackageList
  //
  BufferSize = 0;
  HiiPackageList = NULL;
  Status = gHiiDatabase->ExportPackageLists (gHiiDatabase, Handle, &BufferSize, HiiPackageList);
  //
  // Handle is a invalid handle. Check if Handle is corrupted.
  //
  ASSERT (Status != EFI_NOT_FOUND);
  //
  // The return status should always be EFI_BUFFER_TOO_SMALL as input buffer's size is 0.
  //
  ASSERT (Status == EFI_BUFFER_TOO_SMALL);
  
  HiiPackageList = AllocatePool (BufferSize);
  ASSERT (HiiPackageList != NULL);

  Status = gHiiDatabase->ExportPackageLists (gHiiDatabase, Handle, &BufferSize, HiiPackageList);
  if (EFI_ERROR (Status)) {
    return FALSE;
  }

  //
  // Get Form package from this HII package List
  //
  Offset = sizeof (EFI_HII_PACKAGE_LIST_HEADER);
  PackageListLength = ReadUnaligned32 (&HiiPackageList->PackageLength);

  while (Offset < PackageListLength) {
    Package = ((UINT8 *) HiiPackageList) + Offset;
    CopyMem (&PackageHeader, Package, sizeof (EFI_HII_PACKAGE_HEADER));
    Offset += PackageHeader.Length;

    if (PackageHeader.Type == EFI_HII_PACKAGE_FORMS) {
      //
      // Search FormSet Opcode in this Form Package
      //
      Offset2 = sizeof (EFI_HII_PACKAGE_HEADER);
      while (Offset2 < PackageHeader.Length) {
        OpCodeData = Package + Offset2;
        Offset2 += ((EFI_IFR_OP_HEADER *) OpCodeData)->Length;

        if (((EFI_IFR_OP_HEADER *) OpCodeData)->OpCode == EFI_IFR_FORM_SET_OP) {
          if (((EFI_IFR_OP_HEADER *) OpCodeData)->Length > OFFSET_OF (EFI_IFR_FORM_SET, Flags)) {
            //
            // Find FormSet OpCode
            //
            ClassGuidNum = (UINT8) (((EFI_IFR_FORM_SET *) OpCodeData)->Flags & 0x3);
            ClassGuid = (EFI_GUID *) (VOID *)(OpCodeData + sizeof (EFI_IFR_FORM_SET));
            while (ClassGuidNum-- > 0) {
              if (CompareGuid (SetupClassGuid, ClassGuid)) {
                //
                // Check whether need to skip the formset.
                //
                if (SkipCount != 0) {
                  SkipCount--;
                  FoundAndSkip = TRUE;
                  break;
                }
                CopyMem (FormSetTitle, &((EFI_IFR_FORM_SET *) OpCodeData)->FormSetTitle, sizeof (EFI_STRING_ID));
                CopyMem (FormSetHelp, &((EFI_IFR_FORM_SET *) OpCodeData)->Help, sizeof (EFI_STRING_ID));
                CopyGuid (FormSetGuid, (CONST EFI_GUID *)(&((EFI_IFR_FORM_SET *) OpCodeData)->Guid));
                FreePool (HiiPackageList);
                return TRUE;
              }
              ClassGuid ++;
            }
            if (FoundAndSkip) {
              break;
            }
           } else if (CompareGuid (SetupClassGuid, &gEfiHiiPlatformSetupFormsetGuid)) {
             //
             //  Check whether need to skip the formset.
             //
             if (SkipCount != 0) {
               SkipCount--;
               break;
             }
             CopyMem (FormSetTitle, &((EFI_IFR_FORM_SET *) OpCodeData)->FormSetTitle, sizeof (EFI_STRING_ID));
             CopyMem (FormSetHelp, &((EFI_IFR_FORM_SET *) OpCodeData)->Help, sizeof (EFI_STRING_ID));
             CopyGuid (FormSetGuid, (CONST EFI_GUID *)(&((EFI_IFR_FORM_SET *) OpCodeData)->Guid));
             FreePool (HiiPackageList);
             return TRUE;
          }
        }
      }
    }
  }

  FreePool (HiiPackageList);

  return FALSE;
}
Exemplo n.º 27
0
/**
  This command is used to read the public area and Name of an NV Index.

  @param[in]  NvIndex            The NV Index.
  @param[out] NvPublic           The public area of the index.
  @param[out] NvName             The Name of the nvIndex.
  
  @retval EFI_SUCCESS            Operation completed successfully.
  @retval EFI_DEVICE_ERROR       The command was unsuccessful.
  @retval EFI_NOT_FOUND          The command was returned successfully, but NvIndex is not found.
**/
EFI_STATUS
EFIAPI
Tpm2NvReadPublic (
  IN      TPMI_RH_NV_INDEX          NvIndex,
  OUT     TPM2B_NV_PUBLIC           *NvPublic,
  OUT     TPM2B_NAME                *NvName
  )
{
  EFI_STATUS                        Status;
  TPM2_NV_READPUBLIC_COMMAND        SendBuffer;
  TPM2_NV_READPUBLIC_RESPONSE       RecvBuffer;
  UINT32                            SendBufferSize;
  UINT32                            RecvBufferSize;
  UINT16                            NvPublicSize;
  UINT16                            NvNameSize;
  UINT8                             *Buffer;
  TPM_RC                            ResponseCode;

  //
  // Construct command
  //
  SendBuffer.Header.tag = SwapBytes16(TPM_ST_NO_SESSIONS);
  SendBuffer.Header.commandCode = SwapBytes32(TPM_CC_NV_ReadPublic);

  SendBuffer.NvIndex = SwapBytes32 (NvIndex);
 
  SendBufferSize = (UINT32) sizeof (SendBuffer);
  SendBuffer.Header.paramSize = SwapBytes32 (SendBufferSize);

  //
  // send Tpm command
  //
  RecvBufferSize = sizeof (RecvBuffer);
  Status = Tpm2SubmitCommand (SendBufferSize, (UINT8 *)&SendBuffer, &RecvBufferSize, (UINT8 *)&RecvBuffer);
  if (EFI_ERROR (Status)) {
    return Status;
  }

  if (RecvBufferSize < sizeof (TPM2_RESPONSE_HEADER)) {
    DEBUG ((EFI_D_ERROR, "Tpm2NvReadPublic - RecvBufferSize Error - %x\n", RecvBufferSize));
    return EFI_DEVICE_ERROR;
  }
  ResponseCode = SwapBytes32(RecvBuffer.Header.responseCode);
  if (ResponseCode != TPM_RC_SUCCESS) {
    DEBUG ((EFI_D_ERROR, "Tpm2NvReadPublic - responseCode - %x\n", SwapBytes32(RecvBuffer.Header.responseCode)));
  }
  switch (ResponseCode) {
  case TPM_RC_SUCCESS:
    // return data
    break;
  case TPM_RC_HANDLE + RC_NV_ReadPublic_nvIndex: // TPM_RC_NV_DEFINED:
    return EFI_NOT_FOUND;
  case TPM_RC_VALUE + RC_NV_ReadPublic_nvIndex:
    return EFI_INVALID_PARAMETER;
  default:
    return EFI_DEVICE_ERROR;
  }

  if (RecvBufferSize <= sizeof (TPM2_RESPONSE_HEADER) + sizeof (UINT16) + sizeof(UINT16)) {
    DEBUG ((EFI_D_ERROR, "Tpm2NvReadPublic - RecvBufferSize Error - %x\n", RecvBufferSize));
    return EFI_NOT_FOUND;
  }

  //
  // Basic check
  //
  NvPublicSize = SwapBytes16 (RecvBuffer.NvPublic.size);
  if (NvPublicSize > sizeof(TPMS_NV_PUBLIC)) {
    DEBUG ((DEBUG_ERROR, "Tpm2NvReadPublic - NvPublic.size error %x\n", NvPublicSize));
    return EFI_DEVICE_ERROR;
  }

  NvNameSize = SwapBytes16 (ReadUnaligned16 ((UINT16 *)((UINT8 *)&RecvBuffer + sizeof(TPM2_RESPONSE_HEADER) + sizeof(UINT16) + NvPublicSize)));
  if (NvNameSize > sizeof(TPMU_NAME)){
    DEBUG ((DEBUG_ERROR, "Tpm2NvReadPublic - NvNameSize error %x\n", NvNameSize));
    return EFI_DEVICE_ERROR;
  }

  if (RecvBufferSize != sizeof(TPM2_RESPONSE_HEADER) + sizeof(UINT16) + NvPublicSize + sizeof(UINT16) + NvNameSize) {
    DEBUG ((EFI_D_ERROR, "Tpm2NvReadPublic - RecvBufferSize Error - NvPublicSize %x\n", RecvBufferSize));
    return EFI_NOT_FOUND;
  }

  //
  // Return the response
  //
  CopyMem (NvPublic, &RecvBuffer.NvPublic, sizeof(UINT16) + NvPublicSize);
  NvPublic->size = NvPublicSize;
  NvPublic->nvPublic.nvIndex = SwapBytes32 (NvPublic->nvPublic.nvIndex);
  NvPublic->nvPublic.nameAlg = SwapBytes16 (NvPublic->nvPublic.nameAlg);
  WriteUnaligned32 ((UINT32 *)&NvPublic->nvPublic.attributes, SwapBytes32 (ReadUnaligned32 ((UINT32 *)&NvPublic->nvPublic.attributes)));
  NvPublic->nvPublic.authPolicy.size = SwapBytes16 (NvPublic->nvPublic.authPolicy.size);
  Buffer = (UINT8 *)&RecvBuffer.NvPublic.nvPublic.authPolicy;
  Buffer += sizeof(UINT16) + NvPublic->nvPublic.authPolicy.size;
  NvPublic->nvPublic.dataSize = SwapBytes16 (ReadUnaligned16 ((UINT16 *)Buffer));

  CopyMem (NvName->name, (UINT8 *)&RecvBuffer + sizeof(TPM2_RESPONSE_HEADER) + sizeof(UINT16) + NvPublicSize + sizeof(UINT16), NvNameSize);
  NvName->size = NvNameSize;
  
  return EFI_SUCCESS;
}
Exemplo n.º 28
0
/**
  Update Com Ports attributes from DevicePath

  @param DevicePath      DevicePath that contains Com ports

  @retval EFI_SUCCESS   The update is successful.
  @retval EFI_NOT_FOUND Can not find specific menu entry
**/
EFI_STATUS
UpdateComAttributeFromVariable (
  EFI_DEVICE_PATH_PROTOCOL  *DevicePath
  )
{
  EFI_DEVICE_PATH_PROTOCOL  *Node;
  EFI_DEVICE_PATH_PROTOCOL  *SerialNode;
  ACPI_HID_DEVICE_PATH      *Acpi;
  UART_DEVICE_PATH          *Uart;
  UART_DEVICE_PATH          *Uart1;
  UINTN                     TerminalNumber;
  BM_MENU_ENTRY             *NewMenuEntry;
  BM_TERMINAL_CONTEXT       *NewTerminalContext;
  UINTN                     Index;
  UART_FLOW_CONTROL_DEVICE_PATH *FlowControlNode;
  BOOLEAN                   HasFlowControlNode;

  HasFlowControlNode = FALSE;
  Node            = DevicePath;
  Node            = NextDevicePathNode (Node);
  TerminalNumber  = 0;
  for (Index = 0; Index < TerminalMenu.MenuNumber; Index++) {
    while (!IsDevicePathEnd (Node)) {
      Acpi = (ACPI_HID_DEVICE_PATH *) Node;
      if (IsIsaSerialNode (Acpi)) {
        CopyMem (&TerminalNumber, &Acpi->UID, sizeof (UINT32));
      }

      if ((DevicePathType (Node) == MESSAGING_DEVICE_PATH) && (DevicePathSubType (Node) == MSG_UART_DP)) {
        Uart          = (UART_DEVICE_PATH *) Node;
        NewMenuEntry  = BOpt_GetMenuEntry (&TerminalMenu, TerminalNumber);
        if (NULL == NewMenuEntry) {
          return EFI_NOT_FOUND;
        }

        NewTerminalContext = (BM_TERMINAL_CONTEXT *) NewMenuEntry->VariableContext;
        CopyMem (
          &NewTerminalContext->BaudRate,
          &Uart->BaudRate,
          sizeof (UINT64)
          );

        CopyMem (
          &NewTerminalContext->DataBits,
          &Uart->DataBits,
          sizeof (UINT8)
          );

        CopyMem (
          &NewTerminalContext->Parity,
          &Uart->Parity,
          sizeof (UINT8)
          );

        CopyMem (
          &NewTerminalContext->StopBits,
          &Uart->StopBits,
          sizeof (UINT8)
          );

        FlowControlNode = (UART_FLOW_CONTROL_DEVICE_PATH *) NextDevicePathNode (Node);
        if (IsUartFlowControlNode (FlowControlNode)) {
          HasFlowControlNode = TRUE;
          NewTerminalContext->FlowControl = (UINT8) ReadUnaligned32 (&FlowControlNode->FlowControlMap);
        } else if (NewTerminalContext->FlowControl != 0) {
          //
          // No Flow Control device path node, assumption no Flow control
          //
          NewTerminalContext->FlowControl = 0;
        }

        SerialNode  = NewTerminalContext->DevicePath;
        SerialNode  = NextDevicePathNode (SerialNode);
        while (!IsDevicePathEnd (SerialNode)) {
          if ((DevicePathType (SerialNode) == MESSAGING_DEVICE_PATH) && (DevicePathSubType (SerialNode) == MSG_UART_DP)) {
            //
            // Update following device paths according to
            // previous acquired uart attributes
            //
            Uart1 = (UART_DEVICE_PATH *) SerialNode;
            CopyMem (
              &Uart1->BaudRate,
              &NewTerminalContext->BaudRate,
              sizeof (UINT64)
              );

            CopyMem (
              &Uart1->DataBits,
              &NewTerminalContext->DataBits,
              sizeof (UINT8)
              );
            CopyMem (
              &Uart1->Parity,
              &NewTerminalContext->Parity,
              sizeof (UINT8)
              );
            CopyMem (
              &Uart1->StopBits,
              &NewTerminalContext->StopBits,
              sizeof (UINT8)
              );

            FlowControlNode = (UART_FLOW_CONTROL_DEVICE_PATH *) NextDevicePathNode (SerialNode);
            if (IsUartFlowControlNode (FlowControlNode)) {
              FlowControlNode->FlowControlMap = NewTerminalContext->FlowControl;
            } else {
              if (HasFlowControlNode) {
                mFlowControlDevicePath.FlowControlMap = NewTerminalContext->FlowControl;
                NewTerminalContext->DevicePath = AppendDevicePathNode (
                                             NewTerminalContext->DevicePath,
                                             (EFI_DEVICE_PATH_PROTOCOL *) (&mFlowControlDevicePath)
                                             );
              }
            }
            break;
          }

          SerialNode = NextDevicePathNode (SerialNode);
        }
        //
        // end while
        //
      }

      Node = NextDevicePathNode (Node);
    }
    //
    // end while
    //
  }

  return EFI_SUCCESS;
}
Exemplo n.º 29
0
/**
  Write I/O registers.

  @param[in]  PeiServices  An indirect pointer to the PEI Services Table
                           published by the PEI Foundation.
  @param[in]  This         Pointer to local data for the interface.
  @param[in]  Width        The width of the access. Enumerated in bytes.
  @param[in]  Address      The physical address of the access.
  @param[in]  Count        The number of accesses to perform.
  @param[in]  Buffer       A pointer to the buffer of data.

  @retval EFI_SUCCESS            The function completed successfully.
  @retval EFI_INVALID_PARAMETER  Width is invalid for this EFI system.
  @retval EFI_INVALID_PARAMETER  Buffer is NULL.
  @retval EFI_UNSUPPORTED        The address range specified by Address, Width,
                                 and Count is not valid for this EFI system.

**/
EFI_STATUS
EFIAPI
CpuIoServiceWrite (
  IN CONST EFI_PEI_SERVICES    **PeiServices,
  IN CONST EFI_PEI_CPU_IO_PPI  *This,
  IN EFI_PEI_CPU_IO_PPI_WIDTH  Width,
  IN UINT64                    Address,
  IN UINTN                     Count,
  IN VOID                      *Buffer
  )
{
  EFI_STATUS                Status;
  UINT8                     InStride;
  UINT8                     OutStride;
  EFI_PEI_CPU_IO_PPI_WIDTH  OperationWidth;
  BOOLEAN                   Aligned;
  UINT8                     *Uint8Buffer;

  //
  // Make sure the parameters are valid
  //
  Status = CpuIoCheckParameter (FALSE, Width, Address, Count, Buffer);
  if (EFI_ERROR (Status)) {
    return Status;
  }

  //
  // Select loop based on the width of the transfer
  //
  InStride = mInStride[Width];
  OutStride = mOutStride[Width];
  OperationWidth = (EFI_PEI_CPU_IO_PPI_WIDTH) (Width & 0x03);

  //
  // Fifo operations supported for (mInStride[Width] == 0)
  //
  if (InStride == 0) {
    switch (OperationWidth) {
    case EfiPeiCpuIoWidthUint8:
      IoWriteFifo8 ((UINTN)Address, Count, Buffer);
      return EFI_SUCCESS;
    case EfiPeiCpuIoWidthUint16:
      IoWriteFifo16 ((UINTN)Address, Count, Buffer);
      return EFI_SUCCESS;
    case EfiPeiCpuIoWidthUint32:
      IoWriteFifo32 ((UINTN)Address, Count, Buffer);
      return EFI_SUCCESS;
    default:
      //
      // The CpuIoCheckParameter call above will ensure that this
      // path is not taken.
      //
      ASSERT (FALSE);
      break;
    }
  }

  Aligned = (BOOLEAN)(((UINTN)Buffer & (mInStride[OperationWidth] - 1)) == 0x00);
  for (Uint8Buffer = (UINT8 *)Buffer; Count > 0; Address += InStride, Uint8Buffer += OutStride, Count--) {
    if (OperationWidth == EfiPeiCpuIoWidthUint8) {
      IoWrite8 ((UINTN)Address, *Uint8Buffer);
    } else if (OperationWidth == EfiPeiCpuIoWidthUint16) {
      if (Aligned) {
        IoWrite16 ((UINTN)Address, *((UINT16 *)Uint8Buffer));
      } else {
        IoWrite16 ((UINTN)Address, ReadUnaligned16 ((UINT16 *)Uint8Buffer));
      }
    } else if (OperationWidth == EfiPeiCpuIoWidthUint32) {
      if (Aligned) {
        IoWrite32 ((UINTN)Address, *((UINT32 *)Uint8Buffer));
      } else {
        IoWrite32 ((UINTN)Address, ReadUnaligned32 ((UINT32 *)Uint8Buffer));
      }
    }
  }

  return EFI_SUCCESS;
}
Exemplo n.º 30
0
/**
  Receive response data of last command from TPM.

  @param[out] TpmBuffer  Buffer for response data.
  @param[out] RespSize   Response data length.

  @retval EFI_SUCCESS           Operation completed successfully.
  @retval EFI_TIMEOUT           The register can't run into the expected status in time.
  @retval EFI_DEVICE_ERROR      Unexpected device status.
  @retval EFI_BUFFER_TOO_SMALL  Response data is too long.

**/
EFI_STATUS
TisPcReceive (
    OUT UINT8   *TpmBuffer,
    OUT UINT32  *RespSize
)
{
    EFI_STATUS           Status;
    UINT16               BurstCount;
    UINT32               Index;
    UINT32               ResponseSize;
    TPM_RSP_COMMAND_HDR  *ResponseHeader;

    //
    // Wait for the command completion
    //
    Status = TisPcWaitRegisterBits (
                 INFINEON_TPM_STS_0_ADDRESS_DEFAULT,
                 (UINT8) (TIS_PC_VALID | TIS_PC_STS_DATA),
                 0,
                 TIS_TIMEOUT_B
             );
    if (EFI_ERROR (Status)) {
        Status = EFI_TIMEOUT;
        goto Done;
    }
    //
    // Read the response data header and check it
    //
    Index = 0;
    BurstCount = 0;
    while (Index < sizeof (TPM_RSP_COMMAND_HDR)) {
        Status = TisPcReadBurstCount (&BurstCount);
        if (EFI_ERROR (Status)) {
            Status = EFI_TIMEOUT;
            goto Done;
        }
        for (; BurstCount > 0 ; BurstCount--) {
            *(TpmBuffer + Index) = TpmReadByte (INFINEON_TPM_DATA_FIFO_0_ADDRESS_DEFAULT);
            Index++;
            if (Index == sizeof (TPM_RSP_COMMAND_HDR))
                break;
        }
    }

    //
    // Check the response data header (tag, parasize and returncode)
    //
    ResponseHeader = (TPM_RSP_COMMAND_HDR *)TpmBuffer;
    if (SwapBytes16 (ReadUnaligned16 (&ResponseHeader->tag)) != TPM_TAG_RSP_COMMAND) {
        Status = EFI_DEVICE_ERROR;
        goto Done;
    }

    ResponseSize = SwapBytes32 (ReadUnaligned32 (&ResponseHeader->paramSize));
    if (ResponseSize == sizeof (TPM_RSP_COMMAND_HDR)) {
        Status = EFI_SUCCESS;
        goto Done;
    }
    if (ResponseSize < sizeof (TPM_RSP_COMMAND_HDR)) {
        Status = EFI_DEVICE_ERROR;
        goto Done;
    }
    if (*RespSize < ResponseSize) {
        Status = EFI_BUFFER_TOO_SMALL;
        goto Done;
    }
    *RespSize = ResponseSize;

    //
    // Continue reading the remaining data
    //
    while (Index < ResponseSize) {
        for (; BurstCount > 0 ; BurstCount--) {
            *(TpmBuffer + Index) = TpmReadByte (INFINEON_TPM_DATA_FIFO_0_ADDRESS_DEFAULT);
            Index++;
            if (Index == ResponseSize) {
                Status = EFI_SUCCESS;
                goto Done;
            }
        }
        Status = TisPcReadBurstCount (&BurstCount);
        if (EFI_ERROR (Status) && (Index < ResponseSize)) {
            Status = EFI_DEVICE_ERROR;
            goto Done;
        }
    }

Done:
    //
    // Ensure the TPM state change from "Execution" or "Completion" to "Idle/Ready"
    //
    TpmWriteByte (INFINEON_TPM_STS_0_ADDRESS_DEFAULT, TIS_PC_STS_READY);

    return Status;
}