Beispiel #1
0
EFI_STATUS
LibUpdateCapsule (
  IN UEFI_CAPSULE_HEADER     **CapsuleHeaderArray,
  IN UINTN                   CapsuleCount,
  IN EFI_PHYSICAL_ADDRESS    ScatterGatherList OPTIONAL
  )
/*++

Routine Description:

  This code finds if the capsule needs reset to update, if no, update immediately.

Arguments:

  CapsuleHeaderArray             A array of pointers to capsule headers passed in
  CapsuleCount                   The number of capsule
  ScatterGatherList              Physical address of datablock list points to capsule

Returns:

  EFI STATUS
  EFI_SUCCESS                    Valid capsule was passed.If CAPSULE_FLAG_PERSIT_ACROSS_RESET is
                                 not set, the capsule has been successfully processed by the firmware.
                                 If it set, the ScattlerGatherList is successfully to be set.
  EFI_INVALID_PARAMETER          CapsuleCount is less than 1,CapsuleGuid is not supported.
  EFI_DEVICE_ERROR               Failed to SetVariable or AllocatePool or ProcessFirmwareVolume.

--*/
{
  UINTN                     CapsuleSize;
  UINTN                     ArrayNumber;
  VOID                      *BufferPtr;
  EFI_STATUS                Status;
  EFI_HANDLE                FvHandle;
  UEFI_CAPSULE_HEADER       *CapsuleHeader;

  if ((CapsuleCount < 1) || (CapsuleCount > MAX_SUPPORT_CAPSULE_NUM)){
    return EFI_INVALID_PARAMETER;
  }

  BufferPtr       = NULL;
  CapsuleHeader   = NULL;

  //
  //Compare GUIDs with EFI_CAPSULE_GUID, if capsule header contains CAPSULE_FLAGS_PERSIST_ACROSS_RESET
  //and CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE flags,whatever the GUID is ,the service supports.
  //
  for (ArrayNumber = 0; ArrayNumber < CapsuleCount; ArrayNumber++) {
    CapsuleHeader = CapsuleHeaderArray[ArrayNumber];
    if ((CapsuleHeader->Flags & (CAPSULE_FLAGS_PERSIST_ACROSS_RESET | CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE)) == CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE) {
      return EFI_INVALID_PARAMETER;
    }
    if (!CompareGuid (&CapsuleHeader->CapsuleGuid, &gEfiCapsuleGuid)) {
      if ((CapsuleHeader->Flags & CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE) == 0) {
        return EFI_UNSUPPORTED;
      }
    }
  }

  //
  //Assume that capsules have the same flags on reseting or not.
  //
  CapsuleHeader = CapsuleHeaderArray[0];

  if ((CapsuleHeader->Flags & CAPSULE_FLAGS_PERSIST_ACROSS_RESET) != 0) {
    //
    //Check if the platform supports update capsule across a system reset
    //
    if (!SupportUpdateCapsuleRest()) {
      return EFI_UNSUPPORTED;
    }

    if (ScatterGatherList == 0) {
      return EFI_INVALID_PARAMETER;
    } else {
      Status = EfiSetVariable (
                 EFI_CAPSULE_VARIABLE_NAME,
                 &gEfiCapsuleVendorGuid,
                 EFI_VARIABLE_NON_VOLATILE | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_BOOTSERVICE_ACCESS,
                 sizeof (UINTN),
                 (VOID *) &ScatterGatherList
                 );
      if (Status != EFI_SUCCESS) {
        return EFI_DEVICE_ERROR;
      }
    }
    return EFI_SUCCESS;
  }

  //
  //The rest occurs in the condition of non-reset mode
  //
  if (EfiAtRuntime ()) {
    return EFI_INVALID_PARAMETER;
  }

  //
  //Here should be in the boot-time
  //
  for (ArrayNumber = 0; ArrayNumber < CapsuleCount ; ArrayNumber++) {
    CapsuleHeader = CapsuleHeaderArray[ArrayNumber];
    CapsuleSize = CapsuleHeader->CapsuleImageSize - CapsuleHeader->HeaderSize;
    Status = gBS->AllocatePool (EfiBootServicesData, CapsuleSize, &BufferPtr);
    if (Status != EFI_SUCCESS) {
      goto Done;
    }
    gBS->CopyMem (BufferPtr, (UINT8*)CapsuleHeader+ CapsuleHeader->HeaderSize, CapsuleSize);

    //
    //Call DXE service ProcessFirmwareVolume to process immediatelly
    //
    Status = gDS->ProcessFirmwareVolume (BufferPtr, CapsuleSize, &FvHandle);
    if (Status != EFI_SUCCESS) {
      gBS->FreePool (BufferPtr);
      return EFI_DEVICE_ERROR;
    }
    gDS->Dispatch ();
    gBS->FreePool (BufferPtr);
  }
  return EFI_SUCCESS;

Done:
  if (BufferPtr != NULL) {
    gBS->FreePool (BufferPtr);
  }
  return EFI_DEVICE_ERROR;
}
Beispiel #2
0
/**
  Test whether DevicePath is a valid Terminal


  @param DevicePath      DevicePath to be checked
  @param Termi           If DevicePath is valid Terminal, terminal type is returned.
  @param Com             If DevicePath is valid Terminal, Com Port type is returned.

  @retval  TRUE         If DevicePath point to a Terminal.
  @retval  FALSE        If DevicePath does not point to a Terminal.

**/
BOOLEAN
IsTerminalDevicePath (
  IN  EFI_DEVICE_PATH_PROTOCOL *DevicePath,
  OUT TYPE_OF_TERMINAL         *Termi,
  OUT UINTN                    *Com
  )
{
  BOOLEAN                   IsTerminal;
  EFI_DEVICE_PATH_PROTOCOL  *Node;
  VENDOR_DEVICE_PATH        *Vendor;
  UART_DEVICE_PATH          *Uart;
  ACPI_HID_DEVICE_PATH      *Acpi;

  IsTerminal = FALSE;

  Uart   = NULL;
  Vendor = NULL;
  Acpi   = NULL;
  for (Node = DevicePath; !IsDevicePathEnd (Node); Node = NextDevicePathNode (Node)) {
    //
    // Vendor points to the node before the End node
    //
    Vendor = (VENDOR_DEVICE_PATH *) Node;

    if ((DevicePathType (Node) == MESSAGING_DEVICE_PATH) && (DevicePathSubType (Node) == MSG_UART_DP)) {
      Uart = (UART_DEVICE_PATH *) Node;
    }

    if (Uart == NULL) {
      //
      // Acpi points to the node before the UART node
      //
      Acpi = (ACPI_HID_DEVICE_PATH *) Node;
    }
  }

  if (Vendor == NULL ||
      DevicePathType (Vendor) != MESSAGING_DEVICE_PATH ||
      DevicePathSubType (Vendor) != MSG_VENDOR_DP ||
      Uart == NULL) {
    return FALSE;
  }

  //
  // There are four kinds of Terminal types
  // check to see whether this devicepath
  // is one of that type
  //
  if (CompareGuid (&Vendor->Guid, &TerminalTypeGuid[0])) {
    *Termi      = TerminalTypePcAnsi;
    IsTerminal  = TRUE;
  } else {
    if (CompareGuid (&Vendor->Guid, &TerminalTypeGuid[1])) {
      *Termi      = TerminalTypeVt100;
      IsTerminal  = TRUE;
    } else {
      if (CompareGuid (&Vendor->Guid, &TerminalTypeGuid[2])) {
        *Termi      = TerminalTypeVt100Plus;
        IsTerminal  = TRUE;
      } else {
        if (CompareGuid (&Vendor->Guid, &TerminalTypeGuid[3])) {
          *Termi      = TerminalTypeVtUtf8;
          IsTerminal  = TRUE;
        } else {
          IsTerminal = FALSE;
        }
      }
    }
  }

  if (!IsTerminal) {
    return FALSE;
  }

  if ((Acpi != NULL) && IsIsaSerialNode (Acpi)) {
    CopyMem (Com, &Acpi->UID, sizeof (UINT32));
  } else {
    return FALSE;
  }

  return TRUE;
}
Beispiel #3
0
EFI_STATUS
QueryCapsuleCapabilities (
  IN  UEFI_CAPSULE_HEADER  **CapsuleHeaderArray,
  IN  UINTN                CapsuleCount,
  OUT UINT64               *MaxiumCapsuleSize,
  OUT EFI_RESET_TYPE       *ResetType
  )
/*++

Routine Description:

  This code is query about capsule capability.

Arguments:

  CapsuleHeaderArray              A array of pointers to capsule headers passed in
  CapsuleCount                    The number of capsule
  MaxiumCapsuleSize               Max capsule size is supported
  ResetType                       Reset type the capsule indicates, if reset is not needed,return EfiResetCold.
                                  If reset is needed, return EfiResetWarm.

Returns:

  EFI STATUS
  EFI_SUCCESS                     Valid answer returned
  EFI_INVALID_PARAMETER           MaxiumCapsuleSize is NULL,ResetType is NULL.CapsuleCount is less than 1,CapsuleGuid is not supported.
  EFI_UNSUPPORTED                 The capsule type is not supported.

--*/
{
  UINTN                     ArrayNumber;
  UEFI_CAPSULE_HEADER       *CapsuleHeader;
  UINT32                    MaxSizePopulate;
  UINT32                    MaxSizeNonPopulate;


  if ((CapsuleCount < 1) || (CapsuleCount > MAX_SUPPORT_CAPSULE_NUM)){
    return EFI_INVALID_PARAMETER;
  }

  if ((MaxiumCapsuleSize == NULL) ||(ResetType == NULL)) {
    return EFI_INVALID_PARAMETER;
  }

  CapsuleHeader = NULL;

  //
  //Compare GUIDs with EFI_CAPSULE_GUID, if capsule header contains CAPSULE_FLAGS_PERSIST_ACROSS_RESET
  //and CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE flags,whatever the GUID is ,the service supports.
  //
  for (ArrayNumber = 0; ArrayNumber < CapsuleCount; ArrayNumber++) {
    CapsuleHeader = CapsuleHeaderArray[ArrayNumber];
    if ((CapsuleHeader->Flags & (CAPSULE_FLAGS_PERSIST_ACROSS_RESET | CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE)) == CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE) {
      return EFI_INVALID_PARAMETER;
    }
    if (!CompareGuid (&CapsuleHeader->CapsuleGuid, &gEfiCapsuleGuid)) {
      if ((CapsuleHeader->Flags & CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE) == 0) {
        return EFI_UNSUPPORTED;
      }
    }
  }

  SupportCapsuleSize(&MaxSizePopulate,&MaxSizeNonPopulate);
  //
  //Assume that capsules have the same flags on reseting or not.
  //
  CapsuleHeader = CapsuleHeaderArray[0];
  if ((CapsuleHeader->Flags & CAPSULE_FLAGS_PERSIST_ACROSS_RESET) != 0) {
    //
    //Check if the platform supports update capsule across a system reset
    //
    if (!SupportUpdateCapsuleRest()) {
      return EFI_UNSUPPORTED;
    }
    *ResetType = EfiResetWarm;
    *MaxiumCapsuleSize = MaxSizePopulate;
  } else {
    *ResetType = EfiResetCold;
    *MaxiumCapsuleSize = MaxSizeNonPopulate;
  }
  return EFI_SUCCESS;
}
Beispiel #4
0
/**
  Update System Firmware image.

  @param[in]  SystemFirmwareImage     Points to the System Firmware image.
  @param[in]  SystemFirmwareImageSize The length of the System Firmware image in bytes.
  @param[in]  ConfigImage             Points to the config file image.
  @param[in]  ConfigImageSize         The length of the config file image in bytes.
  @param[out] LastAttemptVersion      The last attempt version, which will be recorded in ESRT and FMP EFI_FIRMWARE_IMAGE_DESCRIPTOR.
  @param[out] LastAttemptStatus       The last attempt status, which will be recorded in ESRT and FMP EFI_FIRMWARE_IMAGE_DESCRIPTOR.

  @retval EFI_SUCCESS             The System Firmware image is updated.
  @retval EFI_WRITE_PROTECTED     The flash device is read only.
**/
EFI_STATUS
UpdateImage (
  IN VOID                         *SystemFirmwareImage,
  IN UINTN                        SystemFirmwareImageSize,
  IN VOID                         *ConfigImage,
  IN UINTN                        ConfigImageSize,
  OUT UINT32                      *LastAttemptVersion,
  OUT UINT32                      *LastAttemptStatus
  )
{
  EFI_STATUS                            Status;
  UPDATE_CONFIG_DATA                    *ConfigData;
  UPDATE_CONFIG_DATA                    *UpdateConfigData;
  CONFIG_HEADER                         ConfigHeader;
  UINTN                                 Index;

  if (ConfigImage == NULL) {
    DEBUG((DEBUG_INFO, "PlatformUpdate (NoConfig):"));
    DEBUG((DEBUG_INFO, "  BaseAddress - 0x%x,", 0));
    DEBUG((DEBUG_INFO, "  Length - 0x%x\n", SystemFirmwareImageSize));
    // ASSUME the whole System Firmware include NVRAM region.
    Status = PerformFlashWrite (
               PlatformFirmwareTypeNvRam,
               0,
               FlashAddressTypeRelativeAddress,
               SystemFirmwareImage,
               SystemFirmwareImageSize
               );
    if (!EFI_ERROR(Status)) {
      *LastAttemptStatus = LAST_ATTEMPT_STATUS_SUCCESS;
      mNvRamUpdated = TRUE;
    } else {
      *LastAttemptStatus = LAST_ATTEMPT_STATUS_ERROR_UNSUCCESSFUL;
    }
    return Status;
  }

  DEBUG((DEBUG_INFO, "PlatformUpdate (With Config):\n"));
  ConfigData        = NULL;
  ZeroMem (&ConfigHeader, sizeof(ConfigHeader));
  Status            = ParseUpdateDataFile (
                        ConfigImage,
                        ConfigImageSize,
                        &ConfigHeader,
                        &ConfigData
                        );
  DEBUG((DEBUG_INFO, "ParseUpdateDataFile - %r\n", Status));
  if (EFI_ERROR(Status)) {
    *LastAttemptStatus = LAST_ATTEMPT_STATUS_ERROR_UNSUCCESSFUL;
    return EFI_INVALID_PARAMETER;
  }
  DEBUG((DEBUG_INFO, "ConfigHeader.NumOfUpdates - 0x%x\n", ConfigHeader.NumOfUpdates));
  DEBUG((DEBUG_INFO, "PcdEdkiiSystemFirmwareFileGuid - %g\n", PcdGetPtr(PcdEdkiiSystemFirmwareFileGuid)));

  Index = 0;
  UpdateConfigData = ConfigData;
  while (Index < ConfigHeader.NumOfUpdates) {
    if (CompareGuid(&UpdateConfigData->FileGuid, PcdGetPtr(PcdEdkiiSystemFirmwareFileGuid))) {
      DEBUG((DEBUG_INFO, "FileGuid - %g (processing)\n", &UpdateConfigData->FileGuid));
      Status = PerformUpdate (
                 SystemFirmwareImage,
                 SystemFirmwareImageSize,
                 UpdateConfigData,
                 LastAttemptVersion,
                 LastAttemptStatus
                 );
      //
      // Shall updates be serialized so that if an update is not successfully completed,
      // the remaining updates won't be performed.
      //
      if (EFI_ERROR (Status)) {
        break;
      }
    } else {
      DEBUG((DEBUG_INFO, "FileGuid - %g (ignored)\n", &UpdateConfigData->FileGuid));
    }

    Index++;
    UpdateConfigData++;
  }

  return Status;
}
/**

  Extraction handler tries to extract raw data from the input guided section.
  It also does authentication check for RSA 2048 SHA 256 signature in the input guided section.
  It first checks whether the input guid section is supported.
  If not, EFI_INVALID_PARAMETER will return.

  @param InputSection    Buffer containing the input GUIDed section to be processed.
  @param OutputBuffer    Buffer to contain the output raw data allocated by the caller.
  @param ScratchBuffer   A pointer to a caller-allocated buffer for function internal use.
  @param AuthenticationStatus A pointer to a caller-allocated UINT32 that indicates the
                              authentication status of the output buffer.

  @retval EFI_SUCCESS            Section Data and Auth Status is extracted successfully.
  @retval EFI_INVALID_PARAMETER  The GUID in InputSection does not match this instance guid.

**/
EFI_STATUS
EFIAPI
Rsa2048Sha256GuidedSectionHandler (
  IN CONST  VOID    *InputSection,
  OUT       VOID    **OutputBuffer,
  IN        VOID    *ScratchBuffer,        OPTIONAL
  OUT       UINT32  *AuthenticationStatus
  )
{
  EFI_STATUS                      Status;
  UINT32                          OutputBufferSize;
  EFI_CERT_BLOCK_RSA_2048_SHA256  *CertBlockRsa2048Sha256;
  BOOLEAN                         CryptoStatus;
  UINT8                           Digest[SHA256_DIGEST_SIZE];
  UINT8                           *PublicKey;
  UINTN                           PublicKeyBufferSize;
  VOID                            *HashContext;
  VOID                            *Rsa;

  HashContext = NULL;
  Rsa         = NULL;

  if (IS_SECTION2 (InputSection)) {
    //
    // Check whether the input guid section is recognized.
    //
    if (!CompareGuid (
        &gEfiCertTypeRsa2048Sha256Guid,
        &(((EFI_GUID_DEFINED_SECTION2 *)InputSection)->SectionDefinitionGuid))) {
      return EFI_INVALID_PARAMETER;
    }

    //
    // Get the RSA 2048 SHA 256 information.
    //
    CertBlockRsa2048Sha256 = &((RSA_2048_SHA_256_SECTION2_HEADER *) InputSection)->CertBlockRsa2048Sha256;
    OutputBufferSize       = SECTION2_SIZE (InputSection) - sizeof (RSA_2048_SHA_256_SECTION2_HEADER);
    if ((((EFI_GUID_DEFINED_SECTION *)InputSection)->Attributes & EFI_GUIDED_SECTION_PROCESSING_REQUIRED) != 0) {
      PERF_START (NULL, "RsaCopy", "PEI", 0);
      CopyMem (*OutputBuffer, (UINT8 *)InputSection + sizeof (RSA_2048_SHA_256_SECTION2_HEADER), OutputBufferSize);
      PERF_END (NULL, "RsaCopy", "PEI", 0);
    } else {
      *OutputBuffer = (UINT8 *)InputSection + sizeof (RSA_2048_SHA_256_SECTION2_HEADER);
    }

    //
    // Implicitly RSA 2048 SHA 256 GUIDed section should have STATUS_VALID bit set
    //
    ASSERT ((((EFI_GUID_DEFINED_SECTION2 *)InputSection)->Attributes & EFI_GUIDED_SECTION_AUTH_STATUS_VALID) != 0);
    *AuthenticationStatus = EFI_AUTH_STATUS_IMAGE_SIGNED;
  } else {
    //
    // Check whether the input guid section is recognized.
    //
    if (!CompareGuid (
        &gEfiCertTypeRsa2048Sha256Guid,
        &(((EFI_GUID_DEFINED_SECTION *)InputSection)->SectionDefinitionGuid))) {
      return EFI_INVALID_PARAMETER;
    }

    //
    // Get the RSA 2048 SHA 256 information.
    //
    CertBlockRsa2048Sha256 = &((RSA_2048_SHA_256_SECTION_HEADER *)InputSection)->CertBlockRsa2048Sha256;
    OutputBufferSize       = SECTION_SIZE (InputSection) - sizeof (RSA_2048_SHA_256_SECTION_HEADER);
    if ((((EFI_GUID_DEFINED_SECTION *)InputSection)->Attributes & EFI_GUIDED_SECTION_PROCESSING_REQUIRED) != 0) {
      PERF_START (NULL, "RsaCopy", "PEI", 0);
      CopyMem (*OutputBuffer, (UINT8 *)InputSection + sizeof (RSA_2048_SHA_256_SECTION_HEADER), OutputBufferSize);
      PERF_END (NULL, "RsaCopy", "PEI", 0);
    } else {
      *OutputBuffer = (UINT8 *)InputSection + sizeof (RSA_2048_SHA_256_SECTION_HEADER);
    }

    //
    // Implicitly RSA 2048 SHA 256 GUIDed section should have STATUS_VALID bit set
    //
    ASSERT ((((EFI_GUID_DEFINED_SECTION *) InputSection)->Attributes & EFI_GUIDED_SECTION_AUTH_STATUS_VALID) != 0);
    *AuthenticationStatus = EFI_AUTH_STATUS_IMAGE_SIGNED;
  }

  //
  // All paths from here return EFI_SUCESS and result is returned in AuthenticationStatus
  //
  Status = EFI_SUCCESS;

  //
  // Fail if the HashType is not SHA 256
  //
  if (!CompareGuid (&gEfiHashAlgorithmSha256Guid, &CertBlockRsa2048Sha256->HashType)) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: HASH type of section is not supported\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }

  //
  // Allocate hash context buffer required for SHA 256
  //
  HashContext = AllocatePool (Sha256GetContextSize ());
  if (HashContext == NULL) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: Can not allocate hash context\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }

  //
  // Hash public key from data payload with SHA256.
  //
  ZeroMem (Digest, SHA256_DIGEST_SIZE);
  CryptoStatus = Sha256Init (HashContext);
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: Sha256Init() failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }
  CryptoStatus = Sha256Update (HashContext, &CertBlockRsa2048Sha256->PublicKey, sizeof(CertBlockRsa2048Sha256->PublicKey));
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: Sha256Update() failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }
  CryptoStatus  = Sha256Final (HashContext, Digest);
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: Sha256Final() failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }

  //
  // Fail if the PublicKey is not one of the public keys in PcdRsa2048Sha256PublicKeyBuffer
  //
  PublicKey = (UINT8 *)PcdGetPtr (PcdRsa2048Sha256PublicKeyBuffer);
  DEBUG ((DEBUG_VERBOSE, "PeiPcdRsa2048Sha256: PublicKeyBuffer = %p\n", PublicKey));
  ASSERT (PublicKey != NULL);
  DEBUG ((DEBUG_VERBOSE, "PeiPcdRsa2048Sha256: PublicKeyBuffer Token = %08x\n", PcdToken (PcdRsa2048Sha256PublicKeyBuffer)));
  PublicKeyBufferSize = LibPcdGetExSize (&gEfiSecurityPkgTokenSpaceGuid, PcdToken (PcdRsa2048Sha256PublicKeyBuffer));
  DEBUG ((DEBUG_VERBOSE, "PeiPcdRsa2048Sha256: PublicKeyBuffer Size = %08x\n", PublicKeyBufferSize));
  ASSERT ((PublicKeyBufferSize % SHA256_DIGEST_SIZE) == 0);
  CryptoStatus = FALSE;
  while (PublicKeyBufferSize != 0) {
    if (CompareMem (Digest, PublicKey, SHA256_DIGEST_SIZE) == 0) {
      CryptoStatus = TRUE;
      break;
    }
    PublicKey = PublicKey + SHA256_DIGEST_SIZE;
    PublicKeyBufferSize = PublicKeyBufferSize - SHA256_DIGEST_SIZE;
  }
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: Public key in section is not supported\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }

  //
  // Generate & Initialize RSA Context.
  //
  Rsa = RsaNew ();
  if (Rsa == NULL) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: RsaNew() failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }

  //
  // Set RSA Key Components.
  // NOTE: Only N and E are needed to be set as RSA public key for signature verification.
  //
  CryptoStatus = RsaSetKey (Rsa, RsaKeyN, CertBlockRsa2048Sha256->PublicKey, sizeof(CertBlockRsa2048Sha256->PublicKey));
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: RsaSetKey(RsaKeyN) failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }
  CryptoStatus = RsaSetKey (Rsa, RsaKeyE, mRsaE, sizeof (mRsaE));
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: RsaSetKey(RsaKeyE) failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }

  //
  // Hash data payload with SHA256.
  //
  ZeroMem (Digest, SHA256_DIGEST_SIZE);
  CryptoStatus = Sha256Init (HashContext);
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: Sha256Init() failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }
  PERF_START (NULL, "RsaShaData", "PEI", 0);
  CryptoStatus = Sha256Update (HashContext, *OutputBuffer, OutputBufferSize);
  PERF_END (NULL, "RsaShaData", "PEI", 0);
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: Sha256Update() failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }
  CryptoStatus  = Sha256Final (HashContext, Digest);
  if (!CryptoStatus) {
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: Sha256Final() failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
    goto Done;
  }

  //
  // Verify the RSA 2048 SHA 256 signature.
  //
  PERF_START (NULL, "RsaVerify", "PEI", 0);
  CryptoStatus = RsaPkcs1Verify (
                   Rsa,
                   Digest,
                   SHA256_DIGEST_SIZE,
                   CertBlockRsa2048Sha256->Signature,
                   sizeof (CertBlockRsa2048Sha256->Signature)
                   );
  PERF_END (NULL, "RsaVerify", "PEI", 0);
  if (!CryptoStatus) {
    //
    // If RSA 2048 SHA 256 signature verification fails, AUTH tested failed bit is set.
    //
    DEBUG ((DEBUG_ERROR, "PeiRsa2048Sha256: RsaPkcs1Verify() failed\n"));
    *AuthenticationStatus |= EFI_AUTH_STATUS_TEST_FAILED;
  }

Done:
  //
  // Free allocated resources used to perform RSA 2048 SHA 256 signature verification
  //
  if (Rsa != NULL) {
    RsaFree (Rsa);
  }
  if (HashContext != NULL) {
    FreePool (HashContext);
  }

  //
  // Temp solution until PeiCore checks AUTH Status.
  //
  if ((*AuthenticationStatus & (EFI_AUTH_STATUS_TEST_FAILED | EFI_AUTH_STATUS_NOT_TESTED)) != 0) {
    Status = EFI_ACCESS_DENIED;
  }
  DEBUG ((DEBUG_VERBOSE, "PeiRsa2048Sha256: Status = %r  AuthenticationStatus = %08x\n", Status, *AuthenticationStatus));

  return Status;
}
Beispiel #6
0
/**
  Event notification that is fired every time a DxeSmmReadyToLock protocol is added
  or if gEfiEventReadyToBootGuid is signaled.

  @param  Event                 The Event that is being processed, not used.
  @param  Context               Event Context, not used.

**/
VOID
EFIAPI
SmmIplReadyToLockEventNotify (
  IN EFI_EVENT  Event,
  IN VOID       *Context
  )
{
  EFI_STATUS  Status;
  VOID        *Interface;
  UINTN       Index;

  //
  // See if we are already locked
  //
  if (mSmmLocked) {
    return;
  }
  
  //
  // Make sure this notification is for this handler
  //
  if (CompareGuid ((EFI_GUID *)Context, &gEfiDxeSmmReadyToLockProtocolGuid)) {
    Status = gBS->LocateProtocol (&gEfiDxeSmmReadyToLockProtocolGuid, NULL, &Interface);
    if (EFI_ERROR (Status)) {
      return;
    }
  } else {
    //
    // If SMM is not locked yet and we got here from gEfiEventReadyToBootGuid being 
    // signaled, then gEfiDxeSmmReadyToLockProtocolGuid was not installed as expected.
    // Print a warning on debug builds.
    //
    DEBUG ((DEBUG_WARN, "SMM IPL!  DXE SMM Ready To Lock Protocol not installed before Ready To Boot signal\n"));
  }

  //
  // Lock the SMRAM (Note: Locking SMRAM may not be supported on all platforms)
  //
  mSmmAccess->Lock (mSmmAccess);
  
  //
  // Close protocol and event notification events that do not apply after the 
  // DXE SMM Ready To Lock Protocol has been installed or the Ready To Boot 
  // event has been signalled.
  //
  for (Index = 0; mSmmIplEvents[Index].NotifyFunction != NULL; Index++) {
    if (mSmmIplEvents[Index].CloseOnLock) {
      gBS->CloseEvent (mSmmIplEvents[Index].Event);
    }
  }

  //
  // Inform SMM Core that the DxeSmmReadyToLock protocol was installed
  //
  SmmIplGuidedEventNotify (Event, (VOID *)&gEfiDxeSmmReadyToLockProtocolGuid);

  //
  // Print debug message that the SMRAM window is now locked.
  //
  DEBUG ((DEBUG_INFO, "SMM IPL locked SMRAM window\n"));
  
  //
  // Set flag so this operation will not be performed again
  //
  mSmmLocked = TRUE;
}
Beispiel #7
0
void
parse_db(UINT8 *data, UINTN len, EFI_HANDLE image, CHAR16 *name, int save_file)
{
	EFI_SIGNATURE_LIST  *CertList = (EFI_SIGNATURE_LIST *)data;
	EFI_SIGNATURE_DATA  *Cert;
	UINTN count = 0, DataSize = len;
	EFI_FILE *file;
	CHAR16 *buf = AllocatePool(StrSize(name) + 4 + 2 + 4 + 8 +100);
	CHAR16 *ext;
	EFI_STATUS status;
	int size;

	certlist_for_each_certentry(CertList, data, size, DataSize) {
		int Index = 0;
		count++;

		if (CompareGuid(&CertList->SignatureType, &X509_GUID) == 0) {
			ext = L"X509";
		} else if (CompareGuid(&CertList->SignatureType, &RSA2048_GUID) == 0) {
			ext = L"RSA2048";
		} else if (CompareGuid(&CertList->SignatureType, &PKCS7_GUID) == 0) {
			ext = L"PKCS7";
		} else if (CompareGuid(&CertList->SignatureType, &EFI_CERT_SHA256_GUID) == 0) {
			ext = L"SHA256";
		} else {
			ext = L"Unknown";
		}

		Print(L"%s: List %d, type %s\n", name, count, ext);

		certentry_for_each_cert(Cert, CertList) {
			Print(L"    Signature %d, size %d, owner %g\n",
			      Index++, CertList->SignatureSize,
			      &Cert->SignatureOwner);

			if (StrCmp(ext, L"X509") == 0) {
				CHAR16 buf1[4096];

				x509_to_str(Cert->SignatureData,
					    CertList->SignatureSize,
					    X509_OBJ_SUBJECT, buf1,
					    sizeof(buf1));
				Print(L"        Subject: %s\n", buf1);

				x509_to_str(Cert->SignatureData,
					    CertList->SignatureSize,
					    X509_OBJ_ISSUER, buf1,
					    sizeof(buf1));
				Print(L"        Issuer: %s\n", buf1);
				
			} else if (StrCmp(ext, L"SHA256") == 0) {
				CHAR16 buf1[256];

				StrCpy(buf1, L"Hash: ");
				sha256_StrCat_hash(buf1, Cert->SignatureData);
				Print(L"        %s\n", buf1);
			}

			if (save_file) {
				SPrint(buf, 0, L"%s-%d-%d-%s-%g", name, count, Index, ext, &Cert->SignatureOwner);
				Print(L"Writing to file %s\n", buf);
				status = simple_file_open(image, buf, &file, EFI_FILE_MODE_READ | EFI_FILE_MODE_WRITE | EFI_FILE_MODE_CREATE);
				if (status != EFI_SUCCESS) {
					Print(L"Failed to open file %s: %d\n", buf, status);
					continue;
				}
				status = simple_file_write_all(file, CertList->SignatureSize-sizeof(EFI_GUID), Cert->SignatureData);
				simple_file_close(file);
				if (status != EFI_SUCCESS) {
					Print(L"Failed to write signature to file %s: %d\n", buf, status);
					continue;
				}
			}

		}
Beispiel #8
0
/**
  Install child handles if the Handle supports GPT partition structure.

  @param[in]  This       Calling context.
  @param[in]  Handle     Parent Handle.
  @param[in]  DiskIo     Parent DiskIo interface.
  @param[in]  BlockIo    Parent BlockIo interface.
  @param[in]  BlockIo2   Parent BlockIo2 interface.
  @param[in]  DevicePath Parent Device Path.

  @retval EFI_SUCCESS           Valid GPT disk.
  @retval EFI_MEDIA_CHANGED     Media changed Detected.
  @retval other                 Not a valid GPT disk.

**/
EFI_STATUS
PartitionInstallGptChildHandles (
  IN  EFI_DRIVER_BINDING_PROTOCOL  *This,
  IN  EFI_HANDLE                   Handle,
  IN  EFI_DISK_IO_PROTOCOL         *DiskIo,
  IN  EFI_BLOCK_IO_PROTOCOL        *BlockIo,
  IN  EFI_BLOCK_IO2_PROTOCOL       *BlockIo2,
  IN  EFI_DEVICE_PATH_PROTOCOL     *DevicePath
  )
{
  EFI_STATUS                  Status;
  UINT32                      BlockSize;
  EFI_LBA                     LastBlock;
  MASTER_BOOT_RECORD          *ProtectiveMbr;
  EFI_PARTITION_TABLE_HEADER  *PrimaryHeader;
  EFI_PARTITION_TABLE_HEADER  *BackupHeader;
  EFI_PARTITION_ENTRY         *PartEntry;
  EFI_PARTITION_ENTRY_STATUS  *PEntryStatus;
  UINTN                       Index;
  EFI_STATUS                  GptValidStatus;
  HARDDRIVE_DEVICE_PATH       HdDev;
  UINT32                      MediaId;

  ProtectiveMbr = NULL;
  PrimaryHeader = NULL;
  BackupHeader  = NULL;
  PartEntry     = NULL;
  PEntryStatus  = NULL;

  BlockSize     = BlockIo->Media->BlockSize;
  LastBlock     = BlockIo->Media->LastBlock;
  MediaId       = BlockIo->Media->MediaId;

  DEBUG ((EFI_D_INFO, " BlockSize : %d \n", BlockSize));
  DEBUG ((EFI_D_INFO, " LastBlock : %lx \n", LastBlock));

  GptValidStatus = EFI_NOT_FOUND;

  //
  // Allocate a buffer for the Protective MBR
  //
  ProtectiveMbr = AllocatePool (BlockSize);
  if (ProtectiveMbr == NULL) {
    return EFI_NOT_FOUND;
  }

  //
  // Read the Protective MBR from LBA #0
  //
  Status = DiskIo->ReadDisk (
                     DiskIo,
                     MediaId,
                     0,
                     BlockSize,
                     ProtectiveMbr
                     );
  if (EFI_ERROR (Status)) {
    GptValidStatus = Status;
    goto Done;
  }

  //
  // Verify that the Protective MBR is valid
  //
  for (Index = 0; Index < MAX_MBR_PARTITIONS; Index++) {
    if (ProtectiveMbr->Partition[Index].BootIndicator == 0x00 &&
        ProtectiveMbr->Partition[Index].OSIndicator == PMBR_GPT_PARTITION &&
        UNPACK_UINT32 (ProtectiveMbr->Partition[Index].StartingLBA) == 1
        ) {
      break;
    }
  }
  if (Index == MAX_MBR_PARTITIONS) {
    goto Done;
  }

  //
  // Allocate the GPT structures
  //
  PrimaryHeader = AllocateZeroPool (sizeof (EFI_PARTITION_TABLE_HEADER));
  if (PrimaryHeader == NULL) {
    goto Done;
  }

  BackupHeader = AllocateZeroPool (sizeof (EFI_PARTITION_TABLE_HEADER));
  if (BackupHeader == NULL) {
    goto Done;
  }

  //
  // Check primary and backup partition tables
  //
  if (!PartitionValidGptTable (BlockIo, DiskIo, PRIMARY_PART_HEADER_LBA, PrimaryHeader)) {
    DEBUG ((EFI_D_INFO, " Not Valid primary partition table\n"));

    if (!PartitionValidGptTable (BlockIo, DiskIo, LastBlock, BackupHeader)) {
      DEBUG ((EFI_D_INFO, " Not Valid backup partition table\n"));
      goto Done;
    } else {
      DEBUG ((EFI_D_INFO, " Valid backup partition table\n"));
      DEBUG ((EFI_D_INFO, " Restore primary partition table by the backup\n"));
      if (!PartitionRestoreGptTable (BlockIo, DiskIo, BackupHeader)) {
        DEBUG ((EFI_D_INFO, " Restore primary partition table error\n"));
      }

      if (PartitionValidGptTable (BlockIo, DiskIo, BackupHeader->AlternateLBA, PrimaryHeader)) {
        DEBUG ((EFI_D_INFO, " Restore backup partition table success\n"));
      }
    }
  } else if (!PartitionValidGptTable (BlockIo, DiskIo, PrimaryHeader->AlternateLBA, BackupHeader)) {
    DEBUG ((EFI_D_INFO, " Valid primary and !Valid backup partition table\n"));
    DEBUG ((EFI_D_INFO, " Restore backup partition table by the primary\n"));
    if (!PartitionRestoreGptTable (BlockIo, DiskIo, PrimaryHeader)) {
      DEBUG ((EFI_D_INFO, " Restore  backup partition table error\n"));
    }

    if (PartitionValidGptTable (BlockIo, DiskIo, PrimaryHeader->AlternateLBA, BackupHeader)) {
      DEBUG ((EFI_D_INFO, " Restore backup partition table success\n"));
    }

  }

  DEBUG ((EFI_D_INFO, " Valid primary and Valid backup partition table\n"));

  //
  // Read the EFI Partition Entries
  //
  PartEntry = AllocatePool (PrimaryHeader->NumberOfPartitionEntries * sizeof (EFI_PARTITION_ENTRY));
  if (PartEntry == NULL) {
    DEBUG ((EFI_D_ERROR, "Allocate pool error\n"));
    goto Done;
  }

  Status = DiskIo->ReadDisk (
                     DiskIo,
                     MediaId,
                     MultU64x32(PrimaryHeader->PartitionEntryLBA, BlockSize),
                     PrimaryHeader->NumberOfPartitionEntries * (PrimaryHeader->SizeOfPartitionEntry),
                     PartEntry
                     );
  if (EFI_ERROR (Status)) {
    GptValidStatus = Status;
    DEBUG ((EFI_D_ERROR, " Partition Entry ReadDisk error\n"));
    goto Done;
  }

  DEBUG ((EFI_D_INFO, " Partition entries read block success\n"));

  DEBUG ((EFI_D_INFO, " Number of partition entries: %d\n", PrimaryHeader->NumberOfPartitionEntries));

  PEntryStatus = AllocateZeroPool (PrimaryHeader->NumberOfPartitionEntries * sizeof (EFI_PARTITION_ENTRY_STATUS));
  if (PEntryStatus == NULL) {
    DEBUG ((EFI_D_ERROR, "Allocate pool error\n"));
    goto Done;
  }

  //
  // Check the integrity of partition entries
  //
  PartitionCheckGptEntry (PrimaryHeader, PartEntry, PEntryStatus);

  //
  // If we got this far the GPT layout of the disk is valid and we should return true
  //
  GptValidStatus = EFI_SUCCESS;

  //
  // Create child device handles
  //
  for (Index = 0; Index < PrimaryHeader->NumberOfPartitionEntries; Index++) {
    if (CompareGuid (&PartEntry[Index].PartitionTypeGUID, &gEfiPartTypeUnusedGuid) ||
        PEntryStatus[Index].OutOfRange ||
        PEntryStatus[Index].Overlap ||
        PEntryStatus[Index].OsSpecific
        ) {
      //
      // Don't use null EFI Partition Entries, Invalid Partition Entries or OS specific
      // partition Entries
      //
      continue;
    }

    ZeroMem (&HdDev, sizeof (HdDev));
    HdDev.Header.Type     = MEDIA_DEVICE_PATH;
    HdDev.Header.SubType  = MEDIA_HARDDRIVE_DP;
    SetDevicePathNodeLength (&HdDev.Header, sizeof (HdDev));

    HdDev.PartitionNumber = (UINT32) Index + 1;
    HdDev.MBRType         = MBR_TYPE_EFI_PARTITION_TABLE_HEADER;
    HdDev.SignatureType   = SIGNATURE_TYPE_GUID;
    HdDev.PartitionStart  = PartEntry[Index].StartingLBA;
    HdDev.PartitionSize   = PartEntry[Index].EndingLBA - PartEntry[Index].StartingLBA + 1;
    CopyMem (HdDev.Signature, &PartEntry[Index].UniquePartitionGUID, sizeof (EFI_GUID));

    DEBUG ((EFI_D_INFO, " Index : %d\n", (UINT32) Index));
    DEBUG ((EFI_D_INFO, " Start LBA : %lx\n", (UINT64) HdDev.PartitionStart));
    DEBUG ((EFI_D_INFO, " End LBA : %lx\n", (UINT64) PartEntry[Index].EndingLBA));
    DEBUG ((EFI_D_INFO, " Partition size: %lx\n", (UINT64) HdDev.PartitionSize));
    DEBUG ((EFI_D_INFO, " Start : %lx", MultU64x32 (PartEntry[Index].StartingLBA, BlockSize)));
    DEBUG ((EFI_D_INFO, " End : %lx\n", MultU64x32 (PartEntry[Index].EndingLBA, BlockSize)));

    Status = PartitionInstallChildHandle (
               This,
               Handle,
               DiskIo,
               BlockIo,
               BlockIo2,
               DevicePath,
               (EFI_DEVICE_PATH_PROTOCOL *) &HdDev,
               PartEntry[Index].StartingLBA,
               PartEntry[Index].EndingLBA,
               BlockSize,
               CompareGuid(&PartEntry[Index].PartitionTypeGUID, &gEfiPartTypeSystemPartGuid)
               );
  }

  DEBUG ((EFI_D_INFO, "Prepare to Free Pool\n"));

Done:
  if (ProtectiveMbr != NULL) {
    FreePool (ProtectiveMbr);
  }
  if (PrimaryHeader != NULL) {
    FreePool (PrimaryHeader);
  }
  if (BackupHeader != NULL) {
    FreePool (BackupHeader);
  }
  if (PartEntry != NULL) {
    FreePool (PartEntry);
  }
  if (PEntryStatus != NULL) {
    FreePool (PEntryStatus);
  }

  return GptValidStatus;
}
Beispiel #9
0
EFI_STATUS
StandaloneMmCpuInitialize (
  IN EFI_HANDLE         ImageHandle,  // not actual imagehandle
  IN EFI_MM_SYSTEM_TABLE   *SystemTable  // not actual systemtable
  )
{
  ARM_TF_CPU_DRIVER_EP_DESCRIPTOR *CpuDriverEntryPointDesc;
  EFI_CONFIGURATION_TABLE         *ConfigurationTable;
  MP_INFORMATION_HOB_DATA         *MpInformationHobData;
  EFI_MMRAM_DESCRIPTOR            *NsCommBufMmramRange;
  EFI_STATUS                       Status;
  EFI_HANDLE                       DispatchHandle;
  UINT32                           MpInfoSize;
  UINTN                            Index;
  UINTN                            ArraySize;
  VOID                            *HobStart;

  ASSERT (SystemTable != NULL);
  mMmst = SystemTable;

  // publish the MM config protocol so the MM core can register its entry point
  Status = mMmst->MmInstallProtocolInterface (
                    &mMmCpuHandle,
                    &gEfiMmConfigurationProtocolGuid,
                    EFI_NATIVE_INTERFACE,
                    &mMmConfig
                    );
  if (EFI_ERROR (Status)) {
    return Status;
  }

  // register the root MMI handler
  Status = mMmst->MmiHandlerRegister (
                    PiMmCpuTpFwRootMmiHandler,
                    NULL,
                    &DispatchHandle
                    );
  if (EFI_ERROR (Status)) {
    return Status;
  }

  // Retrieve the Hoblist from the MMST to extract the details of the NS
  // communication buffer that has been reserved by S-EL1/EL3
  ConfigurationTable = mMmst->MmConfigurationTable;
  for (Index = 0; Index < mMmst->NumberOfTableEntries; Index++) {
    if (CompareGuid (&gEfiHobListGuid, &(ConfigurationTable[Index].VendorGuid))) {
      break;
    }
  }

  // Bail out if the Hoblist could not be found
  if (Index >= mMmst->NumberOfTableEntries) {
    DEBUG ((DEBUG_INFO, "Hoblist not found - 0x%x\n", Index));
    return EFI_OUT_OF_RESOURCES;
  }

  HobStart = ConfigurationTable[Index].VendorTable;

  //
  // Locate the HOB with the buffer to populate the entry point of this driver
  //
  Status = GetGuidedHobData (
             HobStart,
             &gEfiArmTfCpuDriverEpDescriptorGuid,
             (VOID **) &CpuDriverEntryPointDesc
             );
  if (EFI_ERROR (Status)) {
    DEBUG ((DEBUG_INFO, "ArmTfCpuDriverEpDesc HOB data extraction failed - 0x%x\n", Status));
    return Status;
  }

  // Share the entry point of the CPU driver
  DEBUG ((DEBUG_INFO, "Sharing Cpu Driver EP *0x%lx = 0x%lx\n",
          (UINT64) CpuDriverEntryPointDesc->ArmTfCpuDriverEpPtr,
          (UINT64) PiMmStandaloneArmTfCpuDriverEntry));
  *(CpuDriverEntryPointDesc->ArmTfCpuDriverEpPtr) = PiMmStandaloneArmTfCpuDriverEntry;

  // Find the descriptor that contains the whereabouts of the buffer for
  // communication with the Normal world.
  Status = GetGuidedHobData (
             HobStart,
             &gEfiStandaloneMmNonSecureBufferGuid,
             (VOID **) &NsCommBufMmramRange
             );
  if (EFI_ERROR (Status)) {
    DEBUG ((DEBUG_INFO, "NsCommBufMmramRange HOB data extraction failed - 0x%x\n", Status));
    return Status;
  }

  DEBUG ((DEBUG_INFO, "mNsCommBuffer.PhysicalStart - 0x%lx\n", (UINT64) NsCommBufMmramRange->PhysicalStart));
  DEBUG ((DEBUG_INFO, "mNsCommBuffer.PhysicalSize - 0x%lx\n", (UINT64) NsCommBufMmramRange->PhysicalSize));

  CopyMem (&mNsCommBuffer, NsCommBufMmramRange, sizeof(EFI_MMRAM_DESCRIPTOR));
  DEBUG ((DEBUG_INFO, "mNsCommBuffer: 0x%016lx - 0x%lx\n", mNsCommBuffer.CpuStart, mNsCommBuffer.PhysicalSize));

  //
  // Extract the MP information from the Hoblist
  //
  Status = GetGuidedHobData (
             HobStart,
             &gMpInformationHobGuid,
             (VOID **) &MpInformationHobData
             );
  if (EFI_ERROR (Status)) {
    DEBUG ((DEBUG_INFO, "MpInformationHob extraction failed - 0x%x\n", Status));
    return Status;
  }

  //
  // Allocate memory for the MP information and copy over the MP information
  // passed by Trusted Firmware. Use the number of processors passed in the HOB
  // to copy the processor information
  //
  MpInfoSize = sizeof (MP_INFORMATION_HOB_DATA) +
               (sizeof (EFI_PROCESSOR_INFORMATION) *
               MpInformationHobData->NumberOfProcessors);
  Status = mMmst->MmAllocatePool (
                    EfiRuntimeServicesData,
                    MpInfoSize,
                    (VOID **) &mMpInformationHobData
                    );
  if (EFI_ERROR (Status)) {
    DEBUG ((DEBUG_INFO, "mMpInformationHobData mem alloc failed - 0x%x\n", Status));
    return Status;
  }

  CopyMem (mMpInformationHobData, MpInformationHobData, MpInfoSize);

  // Print MP information
  DEBUG ((DEBUG_INFO, "mMpInformationHobData: 0x%016lx - 0x%lx\n",
          mMpInformationHobData->NumberOfProcessors,
          mMpInformationHobData->NumberOfEnabledProcessors));
  for (Index = 0; Index < mMpInformationHobData->NumberOfProcessors; Index++) {
    DEBUG ((DEBUG_INFO, "mMpInformationHobData[0x%lx]: %d, %d, %d\n",
            mMpInformationHobData->ProcessorInfoBuffer[Index].ProcessorId,
            mMpInformationHobData->ProcessorInfoBuffer[Index].Location.Package,
            mMpInformationHobData->ProcessorInfoBuffer[Index].Location.Core,
            mMpInformationHobData->ProcessorInfoBuffer[Index].Location.Thread));
  }

  //
  // Allocate memory for a table to hold pointers to a
  // EFI_MM_COMMUNICATE_HEADER for each CPU
  //
  ArraySize = sizeof (EFI_MM_COMMUNICATE_HEADER *) *
              mMpInformationHobData->NumberOfEnabledProcessors;
  Status = mMmst->MmAllocatePool (
                    EfiRuntimeServicesData,
                    ArraySize,
                    (VOID **) &PerCpuGuidedEventContext
                    );
  if (EFI_ERROR (Status)) {
    DEBUG ((DEBUG_INFO, "PerCpuGuidedEventContext mem alloc failed - 0x%x\n", Status));
    return Status;
  }
  return Status;
}
/**
  BIOS process FspBobList for Memory Resource Descriptor.

  @param[in] FspHobList  Pointer to the HOB data structure produced by FSP.

  @return If platform process the FSP hob list successfully.
**/
EFI_STATUS
EFIAPI
FspHobProcessForMemoryResource (
  IN VOID                 *FspHobList
  )
{
  EFI_PEI_HOB_POINTERS Hob;
  UINT64               LowMemorySize;
  UINT64               FspMemorySize;
  EFI_PHYSICAL_ADDRESS FspMemoryBase;
  UINT64               PeiMemSize;
  EFI_PHYSICAL_ADDRESS PeiMemBase;
  UINT64               S3PeiMemSize;
  EFI_PHYSICAL_ADDRESS S3PeiMemBase;
  BOOLEAN              FoundFspMemHob;
  EFI_STATUS           Status;
  EFI_BOOT_MODE        BootMode;
  EFI_PEI_CAPSULE_PPI  *Capsule;
  VOID                 *CapsuleBuffer;
  UINTN                CapsuleBufferLength;
  UINT64               RequiredMemSize;
  EFI_PEI_SERVICES     **PeiServices;

  PeiServices = (EFI_PEI_SERVICES **)GetPeiServicesTablePointer ();

  PeiServicesGetBootMode (&BootMode);

  PeiMemBase = 0;
  LowMemorySize = 0;
  FspMemorySize = 0;
  FspMemoryBase = 0;
  FoundFspMemHob = FALSE;

  //
  // Parse the hob list from fsp
  // Report all the resource hob except the memory between 1M and 4G
  //
  Hob.Raw = (UINT8 *)(UINTN)FspHobList;
  DEBUG((DEBUG_INFO, "FspHobList - 0x%x\n", FspHobList));

  while ((Hob.Raw = GetNextHob (EFI_HOB_TYPE_RESOURCE_DESCRIPTOR, Hob.Raw)) != NULL) {
    DEBUG((DEBUG_INFO, "\nResourceType: 0x%x\n", Hob.ResourceDescriptor->ResourceType));
    if ((Hob.ResourceDescriptor->ResourceType == EFI_RESOURCE_SYSTEM_MEMORY) ||
        (Hob.ResourceDescriptor->ResourceType == EFI_RESOURCE_MEMORY_RESERVED)) {
      DEBUG((DEBUG_INFO, "ResourceAttribute: 0x%x\n", Hob.ResourceDescriptor->ResourceAttribute));
      DEBUG((DEBUG_INFO, "PhysicalStart: 0x%x\n", Hob.ResourceDescriptor->PhysicalStart));
      DEBUG((DEBUG_INFO, "ResourceLength: 0x%x\n", Hob.ResourceDescriptor->ResourceLength));
      DEBUG((DEBUG_INFO, "Owner: %g\n\n", &Hob.ResourceDescriptor->Owner));
    }

    if ((Hob.ResourceDescriptor->ResourceType == EFI_RESOURCE_SYSTEM_MEMORY)  // Found the low memory length below 4G
        && (Hob.ResourceDescriptor->PhysicalStart >= BASE_1MB)
        && (Hob.ResourceDescriptor->PhysicalStart + Hob.ResourceDescriptor->ResourceLength <= BASE_4GB)) {
        LowMemorySize += Hob.ResourceDescriptor->ResourceLength;
      Hob.Raw = GET_NEXT_HOB (Hob);
      continue;
    }

    if ((Hob.ResourceDescriptor->ResourceType == EFI_RESOURCE_MEMORY_RESERVED)  // Found the low memory length below 4G
        && (Hob.ResourceDescriptor->PhysicalStart >= BASE_1MB)
        && (Hob.ResourceDescriptor->PhysicalStart + Hob.ResourceDescriptor->ResourceLength <= BASE_4GB)
        && (CompareGuid (&Hob.ResourceDescriptor->Owner, &gFspReservedMemoryResourceHobGuid))) {
      FoundFspMemHob = TRUE;
      FspMemoryBase = Hob.ResourceDescriptor->PhysicalStart;
      FspMemorySize = Hob.ResourceDescriptor->ResourceLength;
      DEBUG((DEBUG_INFO, "Find fsp mem hob, base 0x%x, len 0x%x\n", FspMemoryBase, FspMemorySize));
    }

    //
    // Report the resource hob
    //
    BuildResourceDescriptorHob (
      Hob.ResourceDescriptor->ResourceType,
      Hob.ResourceDescriptor->ResourceAttribute,
      Hob.ResourceDescriptor->PhysicalStart,
      Hob.ResourceDescriptor->ResourceLength
      );

    Hob.Raw = GET_NEXT_HOB (Hob);
  }

  if (!FoundFspMemHob) {
    DEBUG((DEBUG_INFO, "Didn't find the fsp used memory information.\n"));
    //ASSERT(FALSE);
  }

  DEBUG((DEBUG_INFO, "LowMemorySize: 0x%x.\n", LowMemorySize));
  DEBUG((DEBUG_INFO, "FspMemoryBase: 0x%x.\n", FspMemoryBase));
  DEBUG((DEBUG_INFO, "FspMemorySize: 0x%x.\n", FspMemorySize));

  if (BootMode == BOOT_ON_S3_RESUME) {
    BuildResourceDescriptorHob (
      EFI_RESOURCE_SYSTEM_MEMORY,
      (
         EFI_RESOURCE_ATTRIBUTE_PRESENT |
         EFI_RESOURCE_ATTRIBUTE_INITIALIZED |
         // EFI_RESOURCE_ATTRIBUTE_TESTED |
         EFI_RESOURCE_ATTRIBUTE_UNCACHEABLE |
         EFI_RESOURCE_ATTRIBUTE_WRITE_COMBINEABLE |
         EFI_RESOURCE_ATTRIBUTE_WRITE_THROUGH_CACHEABLE |
         EFI_RESOURCE_ATTRIBUTE_WRITE_BACK_CACHEABLE
      ),
      BASE_1MB,
      LowMemorySize
      );

    S3PeiMemBase = 0;
    S3PeiMemSize = 0;
    Status = GetS3MemoryInfo (&S3PeiMemSize, &S3PeiMemBase);
    ASSERT_EFI_ERROR (Status);
    DEBUG((DEBUG_INFO, "S3 memory %Xh - %Xh bytes\n", S3PeiMemBase, S3PeiMemSize));

    //
    // Make sure Stack and PeiMemory are not overlap
    //

    Status = PeiServicesInstallPeiMemory (
               S3PeiMemBase,
               S3PeiMemSize
               );
    ASSERT_EFI_ERROR (Status);
  } else {
    PeiMemSize = GetPeiMemSize (PeiServices, BootMode);
    DEBUG((DEBUG_INFO, "PEI memory size = %Xh bytes\n", PeiMemSize));

    //
    // Capsule mode
    //
    Capsule = NULL;
    CapsuleBuffer = NULL;
    CapsuleBufferLength = 0;
    if (BootMode == BOOT_ON_FLASH_UPDATE) {
      Status = PeiServicesLocatePpi (
                 &gEfiPeiCapsulePpiGuid,
                 0,
                 NULL,
                 (VOID **) &Capsule
                 );
      ASSERT_EFI_ERROR (Status);

      if (Status == EFI_SUCCESS) {
        //
        // Make sure Stack and CapsuleBuffer are not overlap
        //
        CapsuleBuffer = (VOID *)(UINTN)BASE_1MB;
        CapsuleBufferLength = (UINTN)(LowMemorySize - PeiMemSize);
        //
        // Call the Capsule PPI Coalesce function to coalesce the capsule data.
        //
        Status = Capsule->Coalesce (PeiServices, &CapsuleBuffer, &CapsuleBufferLength);
      }
    }

    RequiredMemSize = RetrieveRequiredMemorySize (PeiServices);
    DEBUG((DEBUG_INFO, "Required memory size = %Xh bytes\n", RequiredMemSize));

    //
    // Report the main memory
    //
    BuildResourceDescriptorHob (
      EFI_RESOURCE_SYSTEM_MEMORY,
      (
         EFI_RESOURCE_ATTRIBUTE_PRESENT |
         EFI_RESOURCE_ATTRIBUTE_INITIALIZED |
         EFI_RESOURCE_ATTRIBUTE_TESTED |
         EFI_RESOURCE_ATTRIBUTE_UNCACHEABLE |
         EFI_RESOURCE_ATTRIBUTE_WRITE_COMBINEABLE |
         EFI_RESOURCE_ATTRIBUTE_WRITE_THROUGH_CACHEABLE |
         EFI_RESOURCE_ATTRIBUTE_WRITE_BACK_CACHEABLE
      ),
      BASE_1MB,
      LowMemorySize
      );

    //
    // Make sure Stack and CapsuleBuffer are not overlap
    //

    //
    // Install efi memory
    //
    PeiMemBase = BASE_1MB + LowMemorySize - PeiMemSize;
    Status = PeiServicesInstallPeiMemory (
               PeiMemBase,
               PeiMemSize - RequiredMemSize
               );
    ASSERT_EFI_ERROR (Status);

    if (Capsule != NULL) {
      Status = Capsule->CreateState (PeiServices, CapsuleBuffer, CapsuleBufferLength);
    }
  }

  return EFI_SUCCESS;
}
Beispiel #11
0
/**

  This routine is called to see if there are any capsules we need to process.
  If the boot mode is not UPDATE, then we do nothing. Otherwise find the
  capsule HOBS and produce firmware volumes for them via the DXE service.
  Then call the dispatcher to dispatch drivers from them. Finally, check
  the status of the updates.

  This function should be called by BDS in case we need to do some
  sort of processing even if there is no capsule to process. We
  need to do this if an earlier update went away and we need to
  clear the capsule variable so on the next reset PEI does not see it and
  think there is a capsule available.

  @param BootMode                 the current boot mode

  @retval EFI_INVALID_PARAMETER   boot mode is not correct for an update
  @retval EFI_SUCCESS             There is no error when processing capsule

**/
EFI_STATUS
EFIAPI
BdsProcessCapsules (
  EFI_BOOT_MODE BootMode
  )
{
  EFI_STATUS                  Status;
  EFI_PEI_HOB_POINTERS        HobPointer;
  EFI_CAPSULE_HEADER          *CapsuleHeader;
  UINT32                      Size;
  UINT32                      CapsuleNumber;
  UINT32                      CapsuleTotalNumber;
  EFI_CAPSULE_TABLE           *CapsuleTable;
  UINT32                      Index;
  UINT32                      CacheIndex;
  UINT32                      CacheNumber;
  VOID                        **CapsulePtr;
  VOID                        **CapsulePtrCache;
  EFI_GUID                    *CapsuleGuidCache; 
  BOOLEAN                     NeedReset;

  CapsuleNumber = 0;
  CapsuleTotalNumber = 0;
  CacheIndex   = 0;
  CacheNumber  = 0;
  CapsulePtr        = NULL;
  CapsulePtrCache   = NULL;
  CapsuleGuidCache  = NULL;
  NeedReset          = FALSE;

  //
  // We don't do anything else if the boot mode is not flash-update
  //
  if (BootMode != BOOT_ON_FLASH_UPDATE) {
    return EFI_INVALID_PARAMETER;
  }
  
  Status = EFI_SUCCESS;
  //
  // Find all capsule images from hob
  //
  HobPointer.Raw = GetHobList ();
  while ((HobPointer.Raw = GetNextHob (EFI_HOB_TYPE_UEFI_CAPSULE, HobPointer.Raw)) != NULL) {
    CapsuleTotalNumber ++;
    HobPointer.Raw = GET_NEXT_HOB (HobPointer);
  }
  
  if (CapsuleTotalNumber == 0) {
    //
    // We didn't find a hob, so had no errors.
    //
    PlatformBdsLockNonUpdatableFlash ();
    return EFI_SUCCESS;
  }
  
  //
  // Init temp Capsule Data table.
  //
  CapsulePtr       = (VOID **) AllocateZeroPool (sizeof (VOID *) * CapsuleTotalNumber);
//  ASSERT (CapsulePtr != NULL);
  CapsulePtrCache  = (VOID **) AllocateZeroPool (sizeof (VOID *) * CapsuleTotalNumber);
//  ASSERT (CapsulePtrCache != NULL);
  CapsuleGuidCache = (EFI_GUID *) AllocateZeroPool (sizeof (EFI_GUID) * CapsuleTotalNumber);
//  ASSERT (CapsuleGuidCache != NULL);
  
  //
  // Find all capsule images from hob
  //
  HobPointer.Raw = GetHobList ();
  while ((HobPointer.Raw = GetNextHob (EFI_HOB_TYPE_UEFI_CAPSULE, HobPointer.Raw)) != NULL) {
    CapsulePtr [CapsuleNumber++] = (VOID *) (UINTN) HobPointer.Capsule->BaseAddress;
    HobPointer.Raw = GET_NEXT_HOB (HobPointer);
  }

  //
  //Check the capsule flags,if contains CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE, install
  //capsuleTable to configure table with EFI_CAPSULE_GUID
  //

  //
  // Capsules who have CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE always are used for operating
  // System to have information persist across a system reset. EFI System Table must 
  // point to an array of capsules that contains the same CapsuleGuid value. And agents
  // searching for this type capsule will look in EFI System Table and search for the 
  // capsule's Guid and associated pointer to retrieve the data. Two steps below describes
  // how to sorting the capsules by the unique guid and install the array to EFI System Table. 
  // Firstly, Loop for all coalesced capsules, record unique CapsuleGuids and cache them in an 
  // array for later sorting capsules by CapsuleGuid.
  //
  for (Index = 0; Index < CapsuleTotalNumber; Index++) {
    CapsuleHeader = (EFI_CAPSULE_HEADER*) CapsulePtr [Index];
    if ((CapsuleHeader->Flags & CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE) != 0) {
      //
      // For each capsule, we compare it with known CapsuleGuid in the CacheArray.
      // If already has the Guid, skip it. Whereas, record it in the CacheArray as 
      // an additional one.
      //
      CacheIndex = 0;
      while (CacheIndex < CacheNumber) {
        if (CompareGuid(&CapsuleGuidCache[CacheIndex],&CapsuleHeader->CapsuleGuid)) {
          break;
        }
        CacheIndex++;
      }
      if (CacheIndex == CacheNumber) {
        CopyMem(&CapsuleGuidCache[CacheNumber++],&CapsuleHeader->CapsuleGuid,sizeof(EFI_GUID));
      }
    }
  }

  //
  // Secondly, for each unique CapsuleGuid in CacheArray, gather all coalesced capsules
  // whose guid is the same as it, and malloc memory for an array which preceding
  // with UINT32. The array fills with entry point of capsules that have the same
  // CapsuleGuid, and UINT32 represents the size of the array of capsules. Then install
  // this array into EFI System Table, so that agents searching for this type capsule
  // will look in EFI System Table and search for the capsule's Guid and associated
  // pointer to retrieve the data.
  //
  CacheIndex = 0;
  while (CacheIndex < CacheNumber) {
    CapsuleNumber = 0;  
    for (Index = 0; Index < CapsuleTotalNumber; Index++) {
      CapsuleHeader = (EFI_CAPSULE_HEADER*) CapsulePtr [Index];
      if ((CapsuleHeader->Flags & CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE) != 0) {
        if (CompareGuid (&CapsuleGuidCache[CacheIndex], &CapsuleHeader->CapsuleGuid)) {
          //
          // Cache Caspuleheader to the array, this array is uniqued with certain CapsuleGuid.
          //
          CapsulePtrCache[CapsuleNumber++] = (VOID*)CapsuleHeader;
        }
      }
    }
    if (CapsuleNumber != 0) {
      Size = sizeof(EFI_CAPSULE_TABLE) + (CapsuleNumber - 1) * sizeof(VOID*);  
      CapsuleTable = AllocateRuntimePool (Size);
//      ASSERT (CapsuleTable != NULL);
      CapsuleTable->CapsuleArrayNumber =  CapsuleNumber;
      CopyMem(&CapsuleTable->CapsulePtr[0], CapsulePtrCache, CapsuleNumber * sizeof(VOID*));
      Status = gBS->InstallConfigurationTable (&CapsuleGuidCache[CacheIndex], (VOID*)CapsuleTable);
//      ASSERT_EFI_ERROR (Status);
    }
    CacheIndex++;
  }

  //
  // Besides ones with CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE flag, all capsules left are
  // recognized by platform with CapsuleGuid. For general platform driver, UpdateFlash 
  // type is commonly supported, so here only deal with encapsuled FVs capsule. Additional
  // type capsule transaction could be extended. It depends on platform policy.
  //
  for (Index = 0; Index < CapsuleTotalNumber; Index++) {
    CapsuleHeader = (EFI_CAPSULE_HEADER*) CapsulePtr [Index];
    if ((CapsuleHeader->Flags & CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE) == 0) {
      //
      // Always reset system after all capsule processed if FMP capsule exist
      //
      if (CompareGuid (&gEfiFmpCapsuleGuid, &CapsuleHeader->CapsuleGuid)){
        NeedReset = TRUE;
      }

      //
      // Call capsule library to process capsule image.
      //
      ProcessCapsuleImage (CapsuleHeader);
    }
  }

  if (NeedReset) {
    Print(L"Capsule Request Cold Reboot.\n");

    for (Index = 5; Index > 0; Index--) {
      Print(L"\rResetting system in %d seconds ...", Index);
      gBS->Stall (1000000);
    }

    gRT->ResetSystem (EfiResetCold, EFI_SUCCESS, 0, NULL);

    CpuDeadLoop ();
  }

  PlatformBdsLockNonUpdatableFlash ();
  
  //
  // Free the allocated temp memory space.
  //
  FreePool (CapsuleGuidCache);
  FreePool (CapsulePtrCache);
  FreePool (CapsulePtr);

  return Status;
}
Beispiel #12
0
EFI_STATUS fsw_efi_dnode_getinfo(IN FSW_FILE_DATA *File,
                                 IN EFI_GUID *InformationType,
                                 IN OUT UINTN *BufferSize,
                                 OUT VOID *Buffer)
{
    EFI_STATUS          Status;
    FSW_VOLUME_DATA     *Volume = (FSW_VOLUME_DATA *)File->shand.dnode->vol->host_data;
    EFI_FILE_SYSTEM_INFO *FSInfo;
    UINTN               RequiredSize;
    struct fsw_volume_stat vsb;

    if (CompareGuid(InformationType, &GUID_NAME(FileInfo))) {
#if DEBUG_LEVEL
        Print(L"fsw_efi_dnode_getinfo: FILE_INFO\n");
#endif

        Status = fsw_efi_dnode_fill_FileInfo(Volume, File->shand.dnode, BufferSize, Buffer);

    } else if (CompareGuid(InformationType, &GUID_NAME(FileSystemInfo))) {
#if DEBUG_LEVEL
        Print(L"fsw_efi_dnode_getinfo: FILE_SYSTEM_INFO\n");
#endif

        // check buffer size
        RequiredSize = SIZE_OF_EFI_FILE_SYSTEM_INFO + fsw_efi_strsize(&Volume->vol->label);
        if (*BufferSize < RequiredSize) {
            *BufferSize = RequiredSize;
            return EFI_BUFFER_TOO_SMALL;
        }

        // fill structure
        FSInfo = (EFI_FILE_SYSTEM_INFO *)Buffer;
        FSInfo->Size        = RequiredSize;
        FSInfo->ReadOnly    = TRUE;
        FSInfo->BlockSize   = Volume->vol->log_blocksize;
        fsw_efi_strcpy(FSInfo->VolumeLabel, &Volume->vol->label);

        // get the missing info from the fs driver
        ZeroMem(&vsb, sizeof(struct fsw_volume_stat));
        Status = fsw_efi_map_status(fsw_volume_stat(Volume->vol, &vsb), Volume);
        if (EFI_ERROR(Status))
            return Status;
        FSInfo->VolumeSize  = vsb.total_bytes;
        FSInfo->FreeSpace   = vsb.free_bytes;

        // prepare for return
        *BufferSize = RequiredSize;
        Status = EFI_SUCCESS;

    } else if (CompareGuid(InformationType, &GUID_NAME(FileSystemVolumeLabelInfoId))) {
#if DEBUG_LEVEL
        Print(L"fsw_efi_dnode_getinfo: FILE_SYSTEM_VOLUME_LABEL\n");
#endif

        // check buffer size
        RequiredSize = SIZE_OF_EFI_FILE_SYSTEM_VOLUME_LABEL_INFO + fsw_efi_strsize(&Volume->vol->label);
        if (*BufferSize < RequiredSize) {
            *BufferSize = RequiredSize;
            return EFI_BUFFER_TOO_SMALL;
        }

        // copy volume label
        fsw_efi_strcpy(((EFI_FILE_SYSTEM_VOLUME_LABEL_INFO *)Buffer)->VolumeLabel, &Volume->vol->label);

        // prepare for return
        *BufferSize = RequiredSize;
        Status = EFI_SUCCESS;

    } else {
        Status = EFI_UNSUPPORTED;
    }

    return Status;
}
Beispiel #13
0
/**
  Measure GPT table data into TPM log.

  Caution: This function may receive untrusted input.
  The GPT partition table is external input, so this function should parse partition data carefully.

  @param TreeProtocol            Pointer to the located TREE protocol instance.
  @param GptHandle               Handle that GPT partition was installed.

  @retval EFI_SUCCESS            Successfully measure GPT table.
  @retval EFI_UNSUPPORTED        Not support GPT table on the given handle.
  @retval EFI_DEVICE_ERROR       Can't get GPT table because device error.
  @retval EFI_OUT_OF_RESOURCES   No enough resource to measure GPT table.
  @retval other error value
**/
EFI_STATUS
EFIAPI
TrEEMeasureGptTable (
  IN  EFI_TREE_PROTOCOL  *TreeProtocol,
  IN  EFI_HANDLE         GptHandle
  )
{
  EFI_STATUS                        Status;
  EFI_BLOCK_IO_PROTOCOL             *BlockIo;
  EFI_DISK_IO_PROTOCOL              *DiskIo;
  EFI_PARTITION_TABLE_HEADER        *PrimaryHeader;
  EFI_PARTITION_ENTRY               *PartitionEntry;
  UINT8                             *EntryPtr;
  UINTN                             NumberOfPartition;
  UINT32                            Index;
  TrEE_EVENT                        *TreeEvent;
  EFI_GPT_DATA                      *GptData;
  UINT32                            EventSize;

  if (mTrEEMeasureGptCount > 0) {
    return EFI_SUCCESS;
  }

  Status = gBS->HandleProtocol (GptHandle, &gEfiBlockIoProtocolGuid, (VOID**)&BlockIo);
  if (EFI_ERROR (Status)) {
    return EFI_UNSUPPORTED;
  }
  Status = gBS->HandleProtocol (GptHandle, &gEfiDiskIoProtocolGuid, (VOID**)&DiskIo);
  if (EFI_ERROR (Status)) {
    return EFI_UNSUPPORTED;
  }
  //
  // Read the EFI Partition Table Header
  //  
  PrimaryHeader = (EFI_PARTITION_TABLE_HEADER *) AllocatePool (BlockIo->Media->BlockSize);
  if (PrimaryHeader == NULL) {
    return EFI_OUT_OF_RESOURCES;
  }  
  Status = DiskIo->ReadDisk (
                     DiskIo,
                     BlockIo->Media->MediaId,
                     1 * BlockIo->Media->BlockSize,
                     BlockIo->Media->BlockSize,
                     (UINT8 *)PrimaryHeader
                     );
  if (EFI_ERROR (Status)) {
    DEBUG ((EFI_D_ERROR, "Failed to Read Partition Table Header!\n"));
    FreePool (PrimaryHeader);
    return EFI_DEVICE_ERROR;
  }  
  //
  // Read the partition entry.
  //
  EntryPtr = (UINT8 *)AllocatePool (PrimaryHeader->NumberOfPartitionEntries * PrimaryHeader->SizeOfPartitionEntry);
  if (EntryPtr == NULL) {
    FreePool (PrimaryHeader);
    return EFI_OUT_OF_RESOURCES;
  }
  Status = DiskIo->ReadDisk (
                     DiskIo,
                     BlockIo->Media->MediaId,
                     MultU64x32(PrimaryHeader->PartitionEntryLBA, BlockIo->Media->BlockSize),
                     PrimaryHeader->NumberOfPartitionEntries * PrimaryHeader->SizeOfPartitionEntry,
                     EntryPtr
                     );
  if (EFI_ERROR (Status)) {
    FreePool (PrimaryHeader);
    FreePool (EntryPtr);
    return EFI_DEVICE_ERROR;
  }
  
  //
  // Count the valid partition
  //
  PartitionEntry    = (EFI_PARTITION_ENTRY *)EntryPtr;
  NumberOfPartition = 0;
  for (Index = 0; Index < PrimaryHeader->NumberOfPartitionEntries; Index++) {
    if (!CompareGuid (&PartitionEntry->PartitionTypeGUID, &mTrEEZeroGuid)) {
      NumberOfPartition++;  
    }
    PartitionEntry = (EFI_PARTITION_ENTRY *)((UINT8 *)PartitionEntry + PrimaryHeader->SizeOfPartitionEntry);
  }

  //
  // Prepare Data for Measurement
  // 
  EventSize = (UINT32)(sizeof (EFI_GPT_DATA) - sizeof (GptData->Partitions) 
                        + NumberOfPartition * PrimaryHeader->SizeOfPartitionEntry);
  TreeEvent = (TrEE_EVENT *) AllocateZeroPool (EventSize + sizeof (TrEE_EVENT) - sizeof(TreeEvent->Event));
  if (TreeEvent == NULL) {
    FreePool (PrimaryHeader);
    FreePool (EntryPtr);
    return EFI_OUT_OF_RESOURCES;
  }

  TreeEvent->Size = EventSize + sizeof (TrEE_EVENT) - sizeof(TreeEvent->Event);
  TreeEvent->Header.HeaderSize    = sizeof(TrEE_EVENT_HEADER);
  TreeEvent->Header.HeaderVersion = TREE_EVENT_HEADER_VERSION;
  TreeEvent->Header.PCRIndex      = 5;
  TreeEvent->Header.EventType     = EV_EFI_GPT_EVENT;
  GptData = (EFI_GPT_DATA *) TreeEvent->Event;  

  //
  // Copy the EFI_PARTITION_TABLE_HEADER and NumberOfPartition
  //  
  CopyMem ((UINT8 *)GptData, (UINT8*)PrimaryHeader, sizeof (EFI_PARTITION_TABLE_HEADER));
  GptData->NumberOfPartitions = NumberOfPartition;
  //
  // Copy the valid partition entry
  //
  PartitionEntry    = (EFI_PARTITION_ENTRY*)EntryPtr;
  NumberOfPartition = 0;
  for (Index = 0; Index < PrimaryHeader->NumberOfPartitionEntries; Index++) {
    if (!CompareGuid (&PartitionEntry->PartitionTypeGUID, &mTrEEZeroGuid)) {
      CopyMem (
        (UINT8 *)&GptData->Partitions + NumberOfPartition * PrimaryHeader->SizeOfPartitionEntry,
        (UINT8 *)PartitionEntry,
        PrimaryHeader->SizeOfPartitionEntry
        );
      NumberOfPartition++;
    }
    PartitionEntry =(EFI_PARTITION_ENTRY *)((UINT8 *)PartitionEntry + PrimaryHeader->SizeOfPartitionEntry);
  }

  //
  // Measure the GPT data
  //
  Status = TreeProtocol->HashLogExtendEvent (
             TreeProtocol,
             0,
             (EFI_PHYSICAL_ADDRESS) (UINTN) (VOID *) GptData,
             (UINT64) EventSize,
             TreeEvent
             );
  if (!EFI_ERROR (Status)) {
    mTrEEMeasureGptCount++;
  }

  FreePool (PrimaryHeader);
  FreePool (EntryPtr);
  FreePool (TreeEvent);

  return Status;
}
Beispiel #14
0
/**
  Notification event handler registered by CoreNotifyOnArchProtocolInstallation ().
  This notify function is registered for every architectural protocol. This handler
  updates mArchProtocol[] array entry with protocol instance data and sets it's
  present flag to TRUE. If any constructor is required it is executed. The EFI
  System Table headers are updated.

  @param  Event          The Event that is being processed, not used.
  @param  Context        Event Context, not used.

**/
VOID
EFIAPI
GenericProtocolNotify (
  IN  EFI_EVENT  Event,
  IN  VOID       *Context
  )
{
  EFI_STATUS                      Status;
  EFI_CORE_PROTOCOL_NOTIFY_ENTRY  *Entry;
  VOID                            *Protocol;
  LIST_ENTRY                      *Link;
  LIST_ENTRY                      TempLinkNode;

  Protocol = NULL;

  //
  // Get Entry from Context
  //
  Entry = (EFI_CORE_PROTOCOL_NOTIFY_ENTRY *)Context;

  //
  // See if the expected protocol is present in the handle database
  //
  Status = CoreLocateProtocol (Entry->ProtocolGuid, Entry->Registration, &Protocol);
  if (EFI_ERROR (Status)) {
    return;
  }

  //
  // Mark the protocol as present
  //
  Entry->Present = TRUE;

  //
  // Update protocol global variable if one exists. Entry->Protocol points to a global variable
  // if one exists in the DXE core for this Architectural Protocol
  //
  if (Entry->Protocol != NULL) {
    *(Entry->Protocol) = Protocol;
  }

  //
  // Do special operations for Architectural Protocols
  //

  if (CompareGuid (Entry->ProtocolGuid, &gEfiTimerArchProtocolGuid)) {
    //
    // Register the Core timer tick handler with the Timer AP
    //
    gTimer->RegisterHandler (gTimer, CoreTimerTick);
  }

  if (CompareGuid (Entry->ProtocolGuid, &gEfiRuntimeArchProtocolGuid)) {
    //
    // When runtime architectural protocol is available, updates CRC32 in the Debug Table
    //
    CoreUpdateDebugTableCrc32 ();

    //
    // Update the Runtime Architectural protocol with the template that the core was
    // using so there would not need to be a dependency on the Runtime AP
    //

    //
    // Copy all the registered Image to new gRuntime protocol
    //
    for (Link = gRuntimeTemplate.ImageHead.ForwardLink; Link != &gRuntimeTemplate.ImageHead; Link = TempLinkNode.ForwardLink) {
      CopyMem (&TempLinkNode, Link, sizeof(LIST_ENTRY));
      InsertTailList (&gRuntime->ImageHead, Link);
    }
    //
    // Copy all the registered Event to new gRuntime protocol
    //
    for (Link = gRuntimeTemplate.EventHead.ForwardLink; Link != &gRuntimeTemplate.EventHead; Link = TempLinkNode.ForwardLink) {
      CopyMem (&TempLinkNode, Link, sizeof(LIST_ENTRY));
      InsertTailList (&gRuntime->EventHead, Link);
    }

    //
    // Clean up gRuntimeTemplate
    //
    gRuntimeTemplate.ImageHead.ForwardLink = &gRuntimeTemplate.ImageHead;
    gRuntimeTemplate.ImageHead.BackLink    = &gRuntimeTemplate.ImageHead;
    gRuntimeTemplate.EventHead.ForwardLink = &gRuntimeTemplate.EventHead;
    gRuntimeTemplate.EventHead.BackLink    = &gRuntimeTemplate.EventHead;
  }

  //
  // It's over kill to do them all every time, but it saves a lot of code.
  //
  CalculateEfiHdrCrc (&gDxeCoreRT->Hdr);
  CalculateEfiHdrCrc (&gBS->Hdr);
  CalculateEfiHdrCrc (&gDxeCoreST->Hdr);
  CalculateEfiHdrCrc (&gDxeCoreDS->Hdr);
}