/** @file It updates TPM2 items in ACPI table and registers SMI2 callback functions for Tcg2 physical presence, ClearMemory, and sample for dTPM StartMethod. Caution: This module requires additional review when modified. This driver will have external input - variable and ACPINvs data in SMM mode. This external input must be validated carefully to avoid security issue. PhysicalPresenceCallback() and MemoryClearCallback() will receive untrusted input and do some check. Copyright (c) 2015 - 2018, Intel Corporation. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent **/ #include "Tcg2Smm.h" #pragma pack(1) typedef struct { EFI_ACPI_DESCRIPTION_HEADER Header; // Flags field is replaced in version 4 and above // BIT0~15: PlatformClass This field is only valid for version 4 and above // BIT16~31: Reserved UINT32 Flags; UINT64 AddressOfControlArea; UINT32 StartMethod; UINT8 PlatformSpecificParameters[12]; // size up to 12 UINT32 Laml; // Optional UINT64 Lasa; // Optional } EFI_TPM2_ACPI_TABLE_V4; #pragma pack() EFI_TPM2_ACPI_TABLE_V4 mTpm2AcpiTemplate = { { EFI_ACPI_5_0_TRUSTED_COMPUTING_PLATFORM_2_TABLE_SIGNATURE, sizeof (mTpm2AcpiTemplate), EFI_TPM2_ACPI_TABLE_REVISION, // // Compiler initializes the remaining bytes to 0 // These fields should be filled in in production // }, 0, // BIT0~15: PlatformClass // BIT16~31: Reserved 0, // Control Area EFI_TPM2_ACPI_TABLE_START_METHOD_TIS, // StartMethod }; EFI_SMM_VARIABLE_PROTOCOL *mSmmVariable; TCG_NVS *mTcgNvs; /** Software SMI callback for TPM physical presence which is called from ACPI method. Caution: This function may receive untrusted input. Variable and ACPINvs are external input, so this function will validate its data structure to be valid value. @param[in] DispatchHandle The unique handle assigned to this handler by SmiHandlerRegister(). @param[in] Context Points to an optional handler context which was specified when the handler was registered. @param[in, out] CommBuffer A pointer to a collection of data in memory that will be conveyed from a non-SMM environment into an SMM environment. @param[in, out] CommBufferSize The size of the CommBuffer. @retval EFI_SUCCESS The interrupt was handled successfully. **/ EFI_STATUS EFIAPI PhysicalPresenceCallback ( IN EFI_HANDLE DispatchHandle, IN CONST VOID *Context, IN OUT VOID *CommBuffer, IN OUT UINTN *CommBufferSize ) { UINT32 MostRecentRequest; UINT32 Response; UINT32 OperationRequest; UINT32 RequestParameter; if (mTcgNvs->PhysicalPresence.Parameter == TCG_ACPI_FUNCTION_RETURN_REQUEST_RESPONSE_TO_OS) { mTcgNvs->PhysicalPresence.ReturnCode = Tcg2PhysicalPresenceLibReturnOperationResponseToOsFunction ( &MostRecentRequest, &Response ); mTcgNvs->PhysicalPresence.LastRequest = MostRecentRequest; mTcgNvs->PhysicalPresence.Response = Response; return EFI_SUCCESS; } else if ((mTcgNvs->PhysicalPresence.Parameter == TCG_ACPI_FUNCTION_SUBMIT_REQUEST_TO_BIOS) || (mTcgNvs->PhysicalPresence.Parameter == TCG_ACPI_FUNCTION_SUBMIT_REQUEST_TO_BIOS_2)) { OperationRequest = mTcgNvs->PhysicalPresence.Request; RequestParameter = mTcgNvs->PhysicalPresence.RequestParameter; mTcgNvs->PhysicalPresence.ReturnCode = Tcg2PhysicalPresenceLibSubmitRequestToPreOSFunctionEx ( &OperationRequest, &RequestParameter ); mTcgNvs->PhysicalPresence.Request = OperationRequest; mTcgNvs->PhysicalPresence.RequestParameter = RequestParameter; } else if (mTcgNvs->PhysicalPresence.Parameter == TCG_ACPI_FUNCTION_GET_USER_CONFIRMATION_STATUS_FOR_REQUEST) { mTcgNvs->PhysicalPresence.ReturnCode = Tcg2PhysicalPresenceLibGetUserConfirmationStatusFunction (mTcgNvs->PPRequestUserConfirm); } return EFI_SUCCESS; } /** Software SMI callback for MemoryClear which is called from ACPI method. Caution: This function may receive untrusted input. Variable and ACPINvs are external input, so this function will validate its data structure to be valid value. @param[in] DispatchHandle The unique handle assigned to this handler by SmiHandlerRegister(). @param[in] Context Points to an optional handler context which was specified when the handler was registered. @param[in, out] CommBuffer A pointer to a collection of data in memory that will be conveyed from a non-SMM environment into an SMM environment. @param[in, out] CommBufferSize The size of the CommBuffer. @retval EFI_SUCCESS The interrupt was handled successfully. **/ EFI_STATUS EFIAPI MemoryClearCallback ( IN EFI_HANDLE DispatchHandle, IN CONST VOID *Context, IN OUT VOID *CommBuffer, IN OUT UINTN *CommBufferSize ) { EFI_STATUS Status; UINTN DataSize; UINT8 MorControl; mTcgNvs->MemoryClear.ReturnCode = MOR_REQUEST_SUCCESS; if (mTcgNvs->MemoryClear.Parameter == ACPI_FUNCTION_DSM_MEMORY_CLEAR_INTERFACE) { MorControl = (UINT8) mTcgNvs->MemoryClear.Request; } else if (mTcgNvs->MemoryClear.Parameter == ACPI_FUNCTION_PTS_CLEAR_MOR_BIT) { DataSize = sizeof (UINT8); Status = mSmmVariable->SmmGetVariable ( MEMORY_OVERWRITE_REQUEST_VARIABLE_NAME, &gEfiMemoryOverwriteControlDataGuid, NULL, &DataSize, &MorControl ); if (EFI_ERROR (Status)) { mTcgNvs->MemoryClear.ReturnCode = MOR_REQUEST_GENERAL_FAILURE; DEBUG ((EFI_D_ERROR, "[TPM] Get MOR variable failure! Status = %r\n", Status)); return EFI_SUCCESS; } if (MOR_CLEAR_MEMORY_VALUE (MorControl) == 0x0) { return EFI_SUCCESS; } MorControl &= ~MOR_CLEAR_MEMORY_BIT_MASK; } else { mTcgNvs->MemoryClear.ReturnCode = MOR_REQUEST_GENERAL_FAILURE; DEBUG ((EFI_D_ERROR, "[TPM] MOR Parameter error! Parameter = %x\n", mTcgNvs->MemoryClear.Parameter)); return EFI_SUCCESS; } DataSize = sizeof (UINT8); Status = mSmmVariable->SmmSetVariable ( MEMORY_OVERWRITE_REQUEST_VARIABLE_NAME, &gEfiMemoryOverwriteControlDataGuid, EFI_VARIABLE_NON_VOLATILE | EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS, DataSize, &MorControl ); if (EFI_ERROR (Status)) { mTcgNvs->MemoryClear.ReturnCode = MOR_REQUEST_GENERAL_FAILURE; DEBUG ((EFI_D_ERROR, "[TPM] Set MOR variable failure! Status = %r\n", Status)); } return EFI_SUCCESS; } /** Find the operation region in TCG ACPI table by given Name and Size, and initialize it if the region is found. @param[in, out] Table The TPM item in ACPI table. @param[in] Name The name string to find in TPM table. @param[in] Size The size of the region to find. @return The allocated address for the found region. **/ VOID * AssignOpRegion ( EFI_ACPI_DESCRIPTION_HEADER *Table, UINT32 Name, UINT16 Size ) { EFI_STATUS Status; AML_OP_REGION_32_8 *OpRegion; EFI_PHYSICAL_ADDRESS MemoryAddress; MemoryAddress = SIZE_4GB - 1; // // Patch some pointers for the ASL code before loading the SSDT. // for (OpRegion = (AML_OP_REGION_32_8 *) (Table + 1); OpRegion <= (AML_OP_REGION_32_8 *) ((UINT8 *) Table + Table->Length); OpRegion = (AML_OP_REGION_32_8 *) ((UINT8 *) OpRegion + 1)) { if ((OpRegion->OpRegionOp == AML_EXT_REGION_OP) && (OpRegion->NameString == Name) && (OpRegion->DWordPrefix == AML_DWORD_PREFIX) && (OpRegion->BytePrefix == AML_BYTE_PREFIX)) { Status = gBS->AllocatePages(AllocateMaxAddress, EfiACPIMemoryNVS, EFI_SIZE_TO_PAGES (Size), &MemoryAddress); ASSERT_EFI_ERROR (Status); ZeroMem ((VOID *)(UINTN)MemoryAddress, Size); OpRegion->RegionOffset = (UINT32) (UINTN) MemoryAddress; OpRegion->RegionLen = (UINT8) Size; break; } } return (VOID *) (UINTN) MemoryAddress; } /** Patch version string of Physical Presence interface supported by platform. The initial string tag in TPM ACPI table is "$PV". @param[in, out] Table The TPM item in ACPI table. @param[in] PPVer Version string of Physical Presence interface supported by platform. @return The allocated address for the found region. **/ EFI_STATUS UpdatePPVersion ( EFI_ACPI_DESCRIPTION_HEADER *Table, CHAR8 *PPVer ) { EFI_STATUS Status; UINT8 *DataPtr; // // Patch some pointers for the ASL code before loading the SSDT. // for (DataPtr = (UINT8 *)(Table + 1); DataPtr <= (UINT8 *) ((UINT8 *) Table + Table->Length - PHYSICAL_PRESENCE_VERSION_SIZE); DataPtr += 1) { if (AsciiStrCmp((CHAR8 *)DataPtr, PHYSICAL_PRESENCE_VERSION_TAG) == 0) { Status = AsciiStrCpyS((CHAR8 *)DataPtr, PHYSICAL_PRESENCE_VERSION_SIZE, PPVer); DEBUG((EFI_D_INFO, "TPM2 Physical Presence Interface Version update status 0x%x\n", Status)); return Status; } } return EFI_NOT_FOUND; } /** Patch interrupt resources returned by TPM _PRS. ResourceTemplate to patch is determined by input interrupt buffer size. BufferSize, PkgLength and interrupt descriptor in ByteList need to be patched @param[in, out] Table The TPM item in ACPI table. @param[in] IrqBuffer Input new IRQ buffer. @param[in] IrqBuffserSize Input new IRQ buffer size. @param[out] IsShortFormPkgLength If _PRS returns Short length Package(ACPI spec 20.2.4). @return patch status. **/ EFI_STATUS UpdatePossibleResource ( IN OUT EFI_ACPI_DESCRIPTION_HEADER *Table, IN UINT32 *IrqBuffer, IN UINT32 IrqBuffserSize, OUT BOOLEAN *IsShortFormPkgLength ) { UINT8 *DataPtr; UINT8 *DataEndPtr; UINT32 NewPkgLength; UINT32 OrignalPkgLength; NewPkgLength = 0; OrignalPkgLength = 0; DataEndPtr = NULL; // // Follow ACPI spec // 6.4.3 Extend Interrupt Descriptor. // 19.3.3 ASL Resource Template // 20 AML specification // to patch TPM ACPI object _PRS returned ResourceTemplate() containing 2 resource descriptors and an auto appended End Tag // // AML data is organized by following rule. // Code need to patch BufferSize and PkgLength and interrupt descriptor in ByteList // // ============= Buffer ==================== // DefBuffer := BufferOp PkgLength BufferSize ByteList // BufferOp := 0x11 // // ==============PkgLength================== // PkgLength := PkgLeadByte | // | // | // // // PkgLeadByte := // // // //==============BufferSize================== // BufferSize := Integer // Integer := ByteConst|WordConst|DwordConst.... // // ByteConst := BytePrefix ByteData // //==============ByteList=================== // ByteList := ByteData ByteList // //========================================= // // 1. Check TPM_PRS_RESS with PkgLength <=63 can hold the input interrupt number buffer for patching // for (DataPtr = (UINT8 *)(Table + 1); DataPtr < (UINT8 *) ((UINT8 *) Table + Table->Length - (TPM_PRS_RES_NAME_SIZE + TPM_POS_RES_TEMPLATE_MIN_SIZE)); DataPtr += 1) { if (CompareMem(DataPtr, TPM_PRS_RESS, TPM_PRS_RES_NAME_SIZE) == 0) { // // Jump over object name & BufferOp // DataPtr += TPM_PRS_RES_NAME_SIZE + 1; if ((*DataPtr & (BIT7|BIT6)) == 0) { OrignalPkgLength = (UINT32)*DataPtr; DataEndPtr = DataPtr + OrignalPkgLength; // // Jump over PkgLength = PkgLeadByte only // NewPkgLength++; // // Jump over BufferSize // if (*(DataPtr + 1) == AML_BYTE_PREFIX) { NewPkgLength += 2; } else if (*(DataPtr + 1) == AML_WORD_PREFIX) { NewPkgLength += 3; } else if (*(DataPtr + 1) == AML_DWORD_PREFIX) { NewPkgLength += 5; } else { ASSERT(FALSE); return EFI_UNSUPPORTED; } } else { ASSERT(FALSE); return EFI_UNSUPPORTED; } // // Include Memory32Fixed Descriptor (12 Bytes) + Interrupt Descriptor header(5 Bytes) + End Tag(2 Bytes) // NewPkgLength += 19 + IrqBuffserSize; if (NewPkgLength > 63) { break; } if (NewPkgLength > OrignalPkgLength) { ASSERT(FALSE); return EFI_INVALID_PARAMETER; } // // 1.1 Patch PkgLength // *DataPtr = (UINT8)NewPkgLength; // // 1.2 Patch BufferSize = sizeof(Memory32Fixed Descriptor + Interrupt Descriptor + End Tag). // It is Little endian. So only patch lowest byte of BufferSize due to current interrupt number limit. // *(DataPtr + 2) = (UINT8)(IrqBuffserSize + 19); // // Notify _PRS to report short formed ResourceTemplate // *IsShortFormPkgLength = TRUE; break; } } // // 2. Use TPM_PRS_RESL with PkgLength > 63 to hold longer input interrupt number buffer for patching // if (NewPkgLength > 63) { NewPkgLength = 0; OrignalPkgLength = 0; for (DataPtr = (UINT8 *)(Table + 1); DataPtr < (UINT8 *) ((UINT8 *) Table + Table->Length - (TPM_PRS_RES_NAME_SIZE + TPM_POS_RES_TEMPLATE_MIN_SIZE)); DataPtr += 1) { if (CompareMem(DataPtr, TPM_PRS_RESL, TPM_PRS_RES_NAME_SIZE) == 0) { // // Jump over object name & BufferOp // DataPtr += TPM_PRS_RES_NAME_SIZE + 1; if ((*DataPtr & (BIT7|BIT6)) != 0) { OrignalPkgLength = (UINT32)(*(DataPtr + 1) << 4) + (*DataPtr & 0x0F); DataEndPtr = DataPtr + OrignalPkgLength; // // Jump over PkgLength = PkgLeadByte + ByteData length // NewPkgLength += 1 + ((*DataPtr & (BIT7|BIT6)) >> 6); // // Jump over BufferSize // if (*(DataPtr + NewPkgLength) == AML_BYTE_PREFIX) { NewPkgLength += 2; } else if (*(DataPtr + NewPkgLength) == AML_WORD_PREFIX) { NewPkgLength += 3; } else if (*(DataPtr + NewPkgLength) == AML_DWORD_PREFIX) { NewPkgLength += 5; } else { ASSERT(FALSE); return EFI_UNSUPPORTED; } } else { ASSERT(FALSE); return EFI_UNSUPPORTED; } // // Include Memory32Fixed Descriptor (12 Bytes) + Interrupt Descriptor header(5 Bytes) + End Tag(2 Bytes) // NewPkgLength += 19 + IrqBuffserSize; if (NewPkgLength > OrignalPkgLength) { ASSERT(FALSE); return EFI_INVALID_PARAMETER; } // // 2.1 Patch PkgLength. Only patch PkgLeadByte and first ByteData // *DataPtr = (UINT8)((*DataPtr) & 0xF0) | (NewPkgLength & 0x0F); *(DataPtr + 1) = (UINT8)((NewPkgLength & 0xFF0) >> 4); // // 2.2 Patch BufferSize = sizeof(Memory32Fixed Descriptor + Interrupt Descriptor + End Tag). // It is Little endian. Only patch lowest byte of BufferSize due to current interrupt number limit. // *(DataPtr + 2 + ((*DataPtr & (BIT7|BIT6)) >> 6)) = (UINT8)(IrqBuffserSize + 19); // // Notify _PRS to report long formed ResourceTemplate // *IsShortFormPkgLength = FALSE; break; } } } if (DataPtr >= (UINT8 *) ((UINT8 *) Table + Table->Length - (TPM_PRS_RES_NAME_SIZE + TPM_POS_RES_TEMPLATE_MIN_SIZE))) { return EFI_NOT_FOUND; } // // 3. Move DataPtr to Interrupt descriptor header and patch interrupt descriptor. // 5 bytes for interrupt descriptor header, 2 bytes for End Tag // DataPtr += NewPkgLength - (5 + IrqBuffserSize + 2); // // 3.1 Patch Length bit[7:0] of Interrupt descriptor patch interrupt descriptor // *(DataPtr + 1) = (UINT8)(2 + IrqBuffserSize); // // 3.2 Patch Interrupt Table Length // *(DataPtr + 4) = (UINT8)(IrqBuffserSize / sizeof(UINT32)); // // 3.3 Copy patched InterruptNumBuffer // CopyMem(DataPtr + 5, IrqBuffer, IrqBuffserSize); // // 4. Jump over Interrupt descriptor and Patch END Tag, set Checksum field to 0 // DataPtr += 5 + IrqBuffserSize; *DataPtr = ACPI_END_TAG_DESCRIPTOR; *(DataPtr + 1) = 0; // // 5. Jump over new ResourceTemplate. Stuff rest bytes to NOOP // DataPtr += 2; if (DataPtr < DataEndPtr) { SetMem(DataPtr, (UINTN)DataEndPtr - (UINTN)DataPtr, AML_NOOP_OP); } return EFI_SUCCESS; } /** Patch TPM2 device HID string. The initial string tag in TPM2 ACPI table is "NNN0000". @param[in, out] Table The TPM2 SSDT ACPI table. @return HID Update status. **/ EFI_STATUS UpdateHID ( EFI_ACPI_DESCRIPTION_HEADER *Table ) { EFI_STATUS Status; UINT8 *DataPtr; CHAR8 Hid[TPM_HID_ACPI_SIZE]; UINT32 ManufacturerID; UINT32 FirmwareVersion1; UINT32 FirmwareVersion2; BOOLEAN PnpHID; PnpHID = TRUE; // // Initialize HID with Default PNP string // ZeroMem(Hid, TPM_HID_ACPI_SIZE); // // Get Manufacturer ID // Status = Tpm2GetCapabilityManufactureID(&ManufacturerID); if (!EFI_ERROR(Status)) { DEBUG((EFI_D_INFO, "TPM_PT_MANUFACTURER 0x%08x\n", ManufacturerID)); // // ManufacturerID defined in TCG Vendor ID Registry // may tailed with 0x00 or 0x20 // if ((ManufacturerID >> 24) == 0x00 || ((ManufacturerID >> 24) == 0x20)) { // // HID containing PNP ID "NNN####" // NNN is uppercase letter for Vendor ID specified by manufacturer // CopyMem(Hid, &ManufacturerID, 3); } else { // // HID containing ACP ID "NNNN####" // NNNN is uppercase letter for Vendor ID specified by manufacturer // CopyMem(Hid, &ManufacturerID, 4); PnpHID = FALSE; } } else { DEBUG ((EFI_D_ERROR, "Get TPM_PT_MANUFACTURER failed %x!\n", Status)); ASSERT(FALSE); return Status; } Status = Tpm2GetCapabilityFirmwareVersion(&FirmwareVersion1, &FirmwareVersion2); if (!EFI_ERROR(Status)) { DEBUG((EFI_D_INFO, "TPM_PT_FIRMWARE_VERSION_1 0x%x\n", FirmwareVersion1)); DEBUG((EFI_D_INFO, "TPM_PT_FIRMWARE_VERSION_2 0x%x\n", FirmwareVersion2)); // // #### is Firmware Version 1 // if (PnpHID) { AsciiSPrint(Hid + 3, TPM_HID_PNP_SIZE - 3, "%02d%02d", ((FirmwareVersion1 & 0xFFFF0000) >> 16), (FirmwareVersion1 & 0x0000FFFF)); } else { AsciiSPrint(Hid + 4, TPM_HID_ACPI_SIZE - 4, "%02d%02d", ((FirmwareVersion1 & 0xFFFF0000) >> 16), (FirmwareVersion1 & 0x0000FFFF)); } } else { DEBUG ((EFI_D_ERROR, "Get TPM_PT_FIRMWARE_VERSION_X failed %x!\n", Status)); ASSERT(FALSE); return Status; } // // Patch HID in ASL code before loading the SSDT. // for (DataPtr = (UINT8 *)(Table + 1); DataPtr <= (UINT8 *) ((UINT8 *) Table + Table->Length - TPM_HID_PNP_SIZE); DataPtr += 1) { if (AsciiStrCmp((CHAR8 *)DataPtr, TPM_HID_TAG) == 0) { if (PnpHID) { CopyMem(DataPtr, Hid, TPM_HID_PNP_SIZE); // // if HID is PNP ID, patch the last byte in HID TAG to Noop // *(DataPtr + TPM_HID_PNP_SIZE) = AML_NOOP_OP; } else { CopyMem(DataPtr, Hid, TPM_HID_ACPI_SIZE); } DEBUG((DEBUG_INFO, "TPM2 ACPI _HID is patched to %a\n", DataPtr)); return Status; } } DEBUG((EFI_D_ERROR, "TPM2 ACPI HID TAG for patch not found!\n")); return EFI_NOT_FOUND; } /** Initialize and publish TPM items in ACPI table. @retval EFI_SUCCESS The TCG ACPI table is published successfully. @retval Others The TCG ACPI table is not published. **/ EFI_STATUS PublishAcpiTable ( VOID ) { EFI_STATUS Status; EFI_ACPI_TABLE_PROTOCOL *AcpiTable; UINTN TableKey; EFI_ACPI_DESCRIPTION_HEADER *Table; UINTN TableSize; UINT32 *PossibleIrqNumBuf; UINT32 PossibleIrqNumBufSize; BOOLEAN IsShortFormPkgLength; IsShortFormPkgLength = FALSE; Status = GetSectionFromFv ( &gEfiCallerIdGuid, EFI_SECTION_RAW, 0, (VOID **) &Table, &TableSize ); ASSERT_EFI_ERROR (Status); // // Measure to PCR[0] with event EV_POST_CODE ACPI DATA. // The measurement has to be done before any update. // Otherwise, the PCR record would be different after TPM FW update // or the PCD configuration change. // TpmMeasureAndLogData( 0, EV_POST_CODE, EV_POSTCODE_INFO_ACPI_DATA, ACPI_DATA_LEN, Table, TableSize ); // // Update Table version before measuring it to PCR // Status = UpdatePPVersion(Table, (CHAR8 *)PcdGetPtr(PcdTcgPhysicalPresenceInterfaceVer)); ASSERT_EFI_ERROR (Status); DEBUG (( DEBUG_INFO, "Current physical presence interface version - %a\n", (CHAR8 *) PcdGetPtr(PcdTcgPhysicalPresenceInterfaceVer) )); // // Update TPM2 HID after measuring it to PCR // Status = UpdateHID(Table); if (EFI_ERROR(Status)) { return Status; } if (PcdGet32(PcdTpm2CurrentIrqNum) != 0) { // // Patch _PRS interrupt resource only when TPM interrupt is supported // PossibleIrqNumBuf = (UINT32 *)PcdGetPtr(PcdTpm2PossibleIrqNumBuf); PossibleIrqNumBufSize = (UINT32)PcdGetSize(PcdTpm2PossibleIrqNumBuf); if (PossibleIrqNumBufSize <= MAX_PRS_INT_BUF_SIZE && (PossibleIrqNumBufSize % sizeof(UINT32)) == 0) { Status = UpdatePossibleResource(Table, PossibleIrqNumBuf, PossibleIrqNumBufSize, &IsShortFormPkgLength); DEBUG (( DEBUG_INFO, "UpdatePossibleResource status - %x. TPM2 service may not ready in OS.\n", Status )); } else { DEBUG (( DEBUG_INFO, "PcdTpm2PossibleIrqNumBuf size %x is not correct. TPM2 service may not ready in OS.\n", PossibleIrqNumBufSize )); } } ASSERT (Table->OemTableId == SIGNATURE_64 ('T', 'p', 'm', '2', 'T', 'a', 'b', 'l')); CopyMem (Table->OemId, PcdGetPtr (PcdAcpiDefaultOemId), sizeof (Table->OemId) ); mTcgNvs = AssignOpRegion (Table, SIGNATURE_32 ('T', 'N', 'V', 'S'), (UINT16) sizeof (TCG_NVS)); ASSERT (mTcgNvs != NULL); mTcgNvs->TpmIrqNum = PcdGet32(PcdTpm2CurrentIrqNum); mTcgNvs->IsShortFormPkgLength = IsShortFormPkgLength; // // Publish the TPM ACPI table. Table is re-checksummed. // Status = gBS->LocateProtocol (&gEfiAcpiTableProtocolGuid, NULL, (VOID **) &AcpiTable); ASSERT_EFI_ERROR (Status); TableKey = 0; Status = AcpiTable->InstallAcpiTable ( AcpiTable, Table, TableSize, &TableKey ); ASSERT_EFI_ERROR (Status); return Status; } /** Publish TPM2 ACPI table @retval EFI_SUCCESS The TPM2 ACPI table is published successfully. @retval Others The TPM2 ACPI table is not published. **/ EFI_STATUS PublishTpm2 ( VOID ) { EFI_STATUS Status; EFI_ACPI_TABLE_PROTOCOL *AcpiTable; UINTN TableKey; UINT64 OemTableId; EFI_TPM2_ACPI_CONTROL_AREA *ControlArea; TPM2_PTP_INTERFACE_TYPE InterfaceType; // // Measure to PCR[0] with event EV_POST_CODE ACPI DATA. // The measurement has to be done before any update. // Otherwise, the PCR record would be different after event log update // or the PCD configuration change. // TpmMeasureAndLogData( 0, EV_POST_CODE, EV_POSTCODE_INFO_ACPI_DATA, ACPI_DATA_LEN, &mTpm2AcpiTemplate, mTpm2AcpiTemplate.Header.Length ); mTpm2AcpiTemplate.Header.Revision = PcdGet8(PcdTpm2AcpiTableRev); DEBUG((DEBUG_INFO, "Tpm2 ACPI table revision is %d\n", mTpm2AcpiTemplate.Header.Revision)); // // PlatformClass is only valid for version 4 and above // BIT0~15: PlatformClass // BIT16~31: Reserved // if (mTpm2AcpiTemplate.Header.Revision >= EFI_TPM2_ACPI_TABLE_REVISION_4) { mTpm2AcpiTemplate.Flags = (mTpm2AcpiTemplate.Flags & 0xFFFF0000) | PcdGet8(PcdTpmPlatformClass); DEBUG((DEBUG_INFO, "Tpm2 ACPI table PlatformClass is %d\n", (mTpm2AcpiTemplate.Flags & 0x0000FFFF))); } mTpm2AcpiTemplate.Laml = PcdGet32(PcdTpm2AcpiTableLaml); mTpm2AcpiTemplate.Lasa = PcdGet64(PcdTpm2AcpiTableLasa); if ((mTpm2AcpiTemplate.Header.Revision < EFI_TPM2_ACPI_TABLE_REVISION_4) || (mTpm2AcpiTemplate.Laml == 0) || (mTpm2AcpiTemplate.Lasa == 0)) { // // If version is smaller than 4 or Laml/Lasa is not valid, rollback to original Length. // mTpm2AcpiTemplate.Header.Length = sizeof(EFI_TPM2_ACPI_TABLE); } InterfaceType = PcdGet8(PcdActiveTpmInterfaceType); switch (InterfaceType) { case Tpm2PtpInterfaceCrb: mTpm2AcpiTemplate.StartMethod = EFI_TPM2_ACPI_TABLE_START_METHOD_COMMAND_RESPONSE_BUFFER_INTERFACE; mTpm2AcpiTemplate.AddressOfControlArea = PcdGet64 (PcdTpmBaseAddress) + 0x40; ControlArea = (EFI_TPM2_ACPI_CONTROL_AREA *)(UINTN)mTpm2AcpiTemplate.AddressOfControlArea; ControlArea->CommandSize = 0xF80; ControlArea->ResponseSize = 0xF80; ControlArea->Command = PcdGet64 (PcdTpmBaseAddress) + 0x80; ControlArea->Response = PcdGet64 (PcdTpmBaseAddress) + 0x80; break; case Tpm2PtpInterfaceFifo: case Tpm2PtpInterfaceTis: break; default: DEBUG((EFI_D_ERROR, "TPM2 InterfaceType get error! %d\n", InterfaceType)); break; } CopyMem (mTpm2AcpiTemplate.Header.OemId, PcdGetPtr (PcdAcpiDefaultOemId), sizeof (mTpm2AcpiTemplate.Header.OemId)); OemTableId = PcdGet64 (PcdAcpiDefaultOemTableId); CopyMem (&mTpm2AcpiTemplate.Header.OemTableId, &OemTableId, sizeof (UINT64)); mTpm2AcpiTemplate.Header.OemRevision = PcdGet32 (PcdAcpiDefaultOemRevision); mTpm2AcpiTemplate.Header.CreatorId = PcdGet32 (PcdAcpiDefaultCreatorId); mTpm2AcpiTemplate.Header.CreatorRevision = PcdGet32 (PcdAcpiDefaultCreatorRevision); // // Construct ACPI table // Status = gBS->LocateProtocol (&gEfiAcpiTableProtocolGuid, NULL, (VOID **) &AcpiTable); ASSERT_EFI_ERROR (Status); Status = AcpiTable->InstallAcpiTable ( AcpiTable, &mTpm2AcpiTemplate, mTpm2AcpiTemplate.Header.Length, &TableKey ); ASSERT_EFI_ERROR (Status); return Status; } /** The driver's entry point. It install callbacks for TPM physical presence and MemoryClear, and locate SMM variable to be used in the callback function. @param[in] ImageHandle The firmware allocated handle for the EFI image. @param[in] SystemTable A pointer to the EFI System Table. @retval EFI_SUCCESS The entry point is executed successfully. @retval Others Some error occurs when executing this entry point. **/ EFI_STATUS EFIAPI InitializeTcgSmm ( IN EFI_HANDLE ImageHandle, IN EFI_SYSTEM_TABLE *SystemTable ) { EFI_STATUS Status; EFI_SMM_SW_DISPATCH2_PROTOCOL *SwDispatch; EFI_SMM_SW_REGISTER_CONTEXT SwContext; EFI_HANDLE SwHandle; if (!CompareGuid (PcdGetPtr(PcdTpmInstanceGuid), &gEfiTpmDeviceInstanceTpm20DtpmGuid)){ DEBUG ((EFI_D_ERROR, "No TPM2 DTPM instance required!\n")); return EFI_UNSUPPORTED; } Status = PublishAcpiTable (); ASSERT_EFI_ERROR (Status); // // Get the Sw dispatch protocol and register SMI callback functions. // Status = gSmst->SmmLocateProtocol (&gEfiSmmSwDispatch2ProtocolGuid, NULL, (VOID**)&SwDispatch); ASSERT_EFI_ERROR (Status); SwContext.SwSmiInputValue = (UINTN) -1; Status = SwDispatch->Register (SwDispatch, PhysicalPresenceCallback, &SwContext, &SwHandle); ASSERT_EFI_ERROR (Status); if (EFI_ERROR (Status)) { return Status; } mTcgNvs->PhysicalPresence.SoftwareSmi = (UINT8) SwContext.SwSmiInputValue; SwContext.SwSmiInputValue = (UINTN) -1; Status = SwDispatch->Register (SwDispatch, MemoryClearCallback, &SwContext, &SwHandle); ASSERT_EFI_ERROR (Status); if (EFI_ERROR (Status)) { return Status; } mTcgNvs->MemoryClear.SoftwareSmi = (UINT8) SwContext.SwSmiInputValue; // // Locate SmmVariableProtocol. // Status = gSmst->SmmLocateProtocol (&gEfiSmmVariableProtocolGuid, NULL, (VOID**)&mSmmVariable); ASSERT_EFI_ERROR (Status); // // Set TPM2 ACPI table // Status = PublishTpm2 (); ASSERT_EFI_ERROR (Status); return EFI_SUCCESS; }