audk/SecurityPkg/Library/DxeImageVerificationLib/DxeImageVerificationLib.c

1430 lines
48 KiB
C

/** @file
Implement image verification services for secure boot service in UEFI2.3.1.
Caution: This file requires additional review when modified.
This library will have external input - PE/COFF image.
This external input must be validated carefully to avoid security issue like
buffer overflow, integer overflow.
DxeImageVerificationLibImageRead() function will make sure the PE/COFF image content
read is within the image buffer.
DxeImageVerificationHandler(), HashPeImageByType(), HashPeImage() function will accept
untrusted PE/COFF image and validate its data structure within this image buffer before use.
Copyright (c) 2009 - 2013, Intel Corporation. All rights reserved.<BR>
This program and the accompanying materials
are licensed and made available under the terms and conditions of the BSD License
which accompanies this distribution. The full text of the license may be found at
http://opensource.org/licenses/bsd-license.php
THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
**/
#include "DxeImageVerificationLib.h"
//
// Caution: This is used by a function which may receive untrusted input.
// These global variables hold PE/COFF image data, and they should be validated before use.
//
EFI_IMAGE_OPTIONAL_HEADER_PTR_UNION mNtHeader;
UINT32 mPeCoffHeaderOffset;
EFI_GUID mCertType;
//
// Information on current PE/COFF image
//
UINTN mImageSize;
UINT8 *mImageBase = NULL;
UINT8 mImageDigest[MAX_DIGEST_SIZE];
UINTN mImageDigestSize;
//
// Notify string for authorization UI.
//
CHAR16 mNotifyString1[MAX_NOTIFY_STRING_LEN] = L"Image verification pass but not found in authorized database!";
CHAR16 mNotifyString2[MAX_NOTIFY_STRING_LEN] = L"Launch this image anyway? (Yes/Defer/No)";
//
// Public Exponent of RSA Key.
//
CONST UINT8 mRsaE[] = { 0x01, 0x00, 0x01 };
//
// OID ASN.1 Value for Hash Algorithms
//
UINT8 mHashOidValue[] = {
0x2B, 0x0E, 0x03, 0x02, 0x1A, // OBJ_sha1
0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x04, // OBJ_sha224
0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x01, // OBJ_sha256
0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x02, // OBJ_sha384
0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x03, // OBJ_sha512
};
HASH_TABLE mHash[] = {
{ L"SHA1", 20, &mHashOidValue[0], 5, Sha1GetContextSize, Sha1Init, Sha1Update, Sha1Final },
{ L"SHA224", 28, &mHashOidValue[5], 9, NULL, NULL, NULL, NULL },
{ L"SHA256", 32, &mHashOidValue[14], 9, Sha256GetContextSize,Sha256Init, Sha256Update, Sha256Final},
{ L"SHA384", 48, &mHashOidValue[23], 9, NULL, NULL, NULL, NULL },
{ L"SHA512", 64, &mHashOidValue[32], 9, NULL, NULL, NULL, NULL }
};
/**
Reads contents of a PE/COFF image in memory buffer.
Caution: This function may receive untrusted input.
PE/COFF image is external input, so this function will make sure the PE/COFF image content
read is within the image buffer.
@param FileHandle Pointer to the file handle to read the PE/COFF image.
@param FileOffset Offset into the PE/COFF image to begin the read operation.
@param ReadSize On input, the size in bytes of the requested read operation.
On output, the number of bytes actually read.
@param Buffer Output buffer that contains the data read from the PE/COFF image.
@retval EFI_SUCCESS The specified portion of the PE/COFF image was read and the size
**/
EFI_STATUS
EFIAPI
DxeImageVerificationLibImageRead (
IN VOID *FileHandle,
IN UINTN FileOffset,
IN OUT UINTN *ReadSize,
OUT VOID *Buffer
)
{
UINTN EndPosition;
if (FileHandle == NULL || ReadSize == NULL || Buffer == NULL) {
return EFI_INVALID_PARAMETER;
}
if (MAX_ADDRESS - FileOffset < *ReadSize) {
return EFI_INVALID_PARAMETER;
}
EndPosition = FileOffset + *ReadSize;
if (EndPosition > mImageSize) {
*ReadSize = (UINT32)(mImageSize - FileOffset);
}
if (FileOffset >= mImageSize) {
*ReadSize = 0;
}
CopyMem (Buffer, (UINT8 *)((UINTN) FileHandle + FileOffset), *ReadSize);
return EFI_SUCCESS;
}
/**
Get the image type.
@param[in] File This is a pointer to the device path of the file that is
being dispatched.
@return UINT32 Image Type
**/
UINT32
GetImageType (
IN CONST EFI_DEVICE_PATH_PROTOCOL *File
)
{
EFI_STATUS Status;
EFI_HANDLE DeviceHandle;
EFI_DEVICE_PATH_PROTOCOL *TempDevicePath;
EFI_BLOCK_IO_PROTOCOL *BlockIo;
if (File == NULL) {
return IMAGE_UNKNOWN;
}
//
// First check to see if File is from a Firmware Volume
//
DeviceHandle = NULL;
TempDevicePath = (EFI_DEVICE_PATH_PROTOCOL *) File;
Status = gBS->LocateDevicePath (
&gEfiFirmwareVolume2ProtocolGuid,
&TempDevicePath,
&DeviceHandle
);
if (!EFI_ERROR (Status)) {
Status = gBS->OpenProtocol (
DeviceHandle,
&gEfiFirmwareVolume2ProtocolGuid,
NULL,
NULL,
NULL,
EFI_OPEN_PROTOCOL_TEST_PROTOCOL
);
if (!EFI_ERROR (Status)) {
return IMAGE_FROM_FV;
}
}
//
// Next check to see if File is from a Block I/O device
//
DeviceHandle = NULL;
TempDevicePath = (EFI_DEVICE_PATH_PROTOCOL *) File;
Status = gBS->LocateDevicePath (
&gEfiBlockIoProtocolGuid,
&TempDevicePath,
&DeviceHandle
);
if (!EFI_ERROR (Status)) {
BlockIo = NULL;
Status = gBS->OpenProtocol (
DeviceHandle,
&gEfiBlockIoProtocolGuid,
(VOID **) &BlockIo,
NULL,
NULL,
EFI_OPEN_PROTOCOL_GET_PROTOCOL
);
if (!EFI_ERROR (Status) && BlockIo != NULL) {
if (BlockIo->Media != NULL) {
if (BlockIo->Media->RemovableMedia) {
//
// Block I/O is present and specifies the media is removable
//
return IMAGE_FROM_REMOVABLE_MEDIA;
} else {
//
// Block I/O is present and specifies the media is not removable
//
return IMAGE_FROM_FIXED_MEDIA;
}
}
}
}
//
// File is not in a Firmware Volume or on a Block I/O device, so check to see if
// the device path supports the Simple File System Protocol.
//
DeviceHandle = NULL;
TempDevicePath = (EFI_DEVICE_PATH_PROTOCOL *) File;
Status = gBS->LocateDevicePath (
&gEfiSimpleFileSystemProtocolGuid,
&TempDevicePath,
&DeviceHandle
);
if (!EFI_ERROR (Status)) {
//
// Simple File System is present without Block I/O, so assume media is fixed.
//
return IMAGE_FROM_FIXED_MEDIA;
}
//
// File is not from an FV, Block I/O or Simple File System, so the only options
// left are a PCI Option ROM and a Load File Protocol such as a PXE Boot from a NIC.
//
TempDevicePath = (EFI_DEVICE_PATH_PROTOCOL *) File;
while (!IsDevicePathEndType (TempDevicePath)) {
switch (DevicePathType (TempDevicePath)) {
case MEDIA_DEVICE_PATH:
if (DevicePathSubType (TempDevicePath) == MEDIA_RELATIVE_OFFSET_RANGE_DP) {
return IMAGE_FROM_OPTION_ROM;
}
break;
case MESSAGING_DEVICE_PATH:
if (DevicePathSubType(TempDevicePath) == MSG_MAC_ADDR_DP) {
return IMAGE_FROM_REMOVABLE_MEDIA;
}
break;
default:
break;
}
TempDevicePath = NextDevicePathNode (TempDevicePath);
}
return IMAGE_UNKNOWN;
}
/**
Caculate hash of Pe/Coff image based on the authenticode image hashing in
PE/COFF Specification 8.0 Appendix A
Caution: This function may receive untrusted input.
PE/COFF image is external input, so this function will validate its data structure
within this image buffer before use.
@param[in] HashAlg Hash algorithm type.
@retval TRUE Successfully hash image.
@retval FALSE Fail in hash image.
**/
BOOLEAN
HashPeImage (
IN UINT32 HashAlg
)
{
BOOLEAN Status;
UINT16 Magic;
EFI_IMAGE_SECTION_HEADER *Section;
VOID *HashCtx;
UINTN CtxSize;
UINT8 *HashBase;
UINTN HashSize;
UINTN SumOfBytesHashed;
EFI_IMAGE_SECTION_HEADER *SectionHeader;
UINTN Index;
UINTN Pos;
UINT32 CertSize;
UINT32 NumberOfRvaAndSizes;
HashCtx = NULL;
SectionHeader = NULL;
Status = FALSE;
if ((HashAlg != HASHALG_SHA1) && (HashAlg != HASHALG_SHA256)) {
return FALSE;
}
//
// Initialize context of hash.
//
ZeroMem (mImageDigest, MAX_DIGEST_SIZE);
if (HashAlg == HASHALG_SHA1) {
mImageDigestSize = SHA1_DIGEST_SIZE;
mCertType = gEfiCertSha1Guid;
} else if (HashAlg == HASHALG_SHA256) {
mImageDigestSize = SHA256_DIGEST_SIZE;
mCertType = gEfiCertSha256Guid;
} else {
return FALSE;
}
CtxSize = mHash[HashAlg].GetContextSize();
HashCtx = AllocatePool (CtxSize);
if (HashCtx == NULL) {
return FALSE;
}
// 1. Load the image header into memory.
// 2. Initialize a SHA hash context.
Status = mHash[HashAlg].HashInit(HashCtx);
if (!Status) {
goto Done;
}
//
// Measuring PE/COFF Image Header;
// But CheckSum field and SECURITY data directory (certificate) are excluded
//
if (mNtHeader.Pe32->FileHeader.Machine == IMAGE_FILE_MACHINE_IA64 && mNtHeader.Pe32->OptionalHeader.Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// NOTE: Some versions of Linux ELILO for Itanium have an incorrect magic value
// in the PE/COFF Header. If the MachineType is Itanium(IA64) and the
// Magic value in the OptionalHeader is EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC
// then override the magic value to EFI_IMAGE_NT_OPTIONAL_HDR64_MAGIC
//
Magic = EFI_IMAGE_NT_OPTIONAL_HDR64_MAGIC;
} else {
//
// Get the magic value from the PE/COFF Optional Header
//
Magic = mNtHeader.Pe32->OptionalHeader.Magic;
}
//
// 3. Calculate the distance from the base of the image header to the image checksum address.
// 4. Hash the image header from its base to beginning of the image checksum.
//
HashBase = mImageBase;
if (Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// Use PE32 offset.
//
HashSize = (UINTN) ((UINT8 *) (&mNtHeader.Pe32->OptionalHeader.CheckSum) - HashBase);
NumberOfRvaAndSizes = mNtHeader.Pe32->OptionalHeader.NumberOfRvaAndSizes;
} else if (Magic == EFI_IMAGE_NT_OPTIONAL_HDR64_MAGIC) {
//
// Use PE32+ offset.
//
HashSize = (UINTN) ((UINT8 *) (&mNtHeader.Pe32Plus->OptionalHeader.CheckSum) - HashBase);
NumberOfRvaAndSizes = mNtHeader.Pe32Plus->OptionalHeader.NumberOfRvaAndSizes;
} else {
//
// Invalid header magic number.
//
Status = FALSE;
goto Done;
}
Status = mHash[HashAlg].HashUpdate(HashCtx, HashBase, HashSize);
if (!Status) {
goto Done;
}
//
// 5. Skip over the image checksum (it occupies a single ULONG).
//
if (NumberOfRvaAndSizes <= EFI_IMAGE_DIRECTORY_ENTRY_SECURITY) {
//
// 6. Since there is no Cert Directory in optional header, hash everything
// from the end of the checksum to the end of image header.
//
if (Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// Use PE32 offset.
//
HashBase = (UINT8 *) &mNtHeader.Pe32->OptionalHeader.CheckSum + sizeof (UINT32);
HashSize = mNtHeader.Pe32->OptionalHeader.SizeOfHeaders - (UINTN) (HashBase - mImageBase);
} else {
//
// Use PE32+ offset.
//
HashBase = (UINT8 *) &mNtHeader.Pe32Plus->OptionalHeader.CheckSum + sizeof (UINT32);
HashSize = mNtHeader.Pe32Plus->OptionalHeader.SizeOfHeaders - (UINTN) (HashBase - mImageBase);
}
if (HashSize != 0) {
Status = mHash[HashAlg].HashUpdate(HashCtx, HashBase, HashSize);
if (!Status) {
goto Done;
}
}
} else {
//
// 7. Hash everything from the end of the checksum to the start of the Cert Directory.
//
if (Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// Use PE32 offset.
//
HashBase = (UINT8 *) &mNtHeader.Pe32->OptionalHeader.CheckSum + sizeof (UINT32);
HashSize = (UINTN) ((UINT8 *) (&mNtHeader.Pe32->OptionalHeader.DataDirectory[EFI_IMAGE_DIRECTORY_ENTRY_SECURITY]) - HashBase);
} else {
//
// Use PE32+ offset.
//
HashBase = (UINT8 *) &mNtHeader.Pe32Plus->OptionalHeader.CheckSum + sizeof (UINT32);
HashSize = (UINTN) ((UINT8 *) (&mNtHeader.Pe32Plus->OptionalHeader.DataDirectory[EFI_IMAGE_DIRECTORY_ENTRY_SECURITY]) - HashBase);
}
if (HashSize != 0) {
Status = mHash[HashAlg].HashUpdate(HashCtx, HashBase, HashSize);
if (!Status) {
goto Done;
}
}
//
// 8. Skip over the Cert Directory. (It is sizeof(IMAGE_DATA_DIRECTORY) bytes.)
// 9. Hash everything from the end of the Cert Directory to the end of image header.
//
if (Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// Use PE32 offset
//
HashBase = (UINT8 *) &mNtHeader.Pe32->OptionalHeader.DataDirectory[EFI_IMAGE_DIRECTORY_ENTRY_SECURITY + 1];
HashSize = mNtHeader.Pe32->OptionalHeader.SizeOfHeaders - (UINTN) (HashBase - mImageBase);
} else {
//
// Use PE32+ offset.
//
HashBase = (UINT8 *) &mNtHeader.Pe32Plus->OptionalHeader.DataDirectory[EFI_IMAGE_DIRECTORY_ENTRY_SECURITY + 1];
HashSize = mNtHeader.Pe32Plus->OptionalHeader.SizeOfHeaders - (UINTN) (HashBase - mImageBase);
}
if (HashSize != 0) {
Status = mHash[HashAlg].HashUpdate(HashCtx, HashBase, HashSize);
if (!Status) {
goto Done;
}
}
}
//
// 10. Set the SUM_OF_BYTES_HASHED to the size of the header.
//
if (Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// Use PE32 offset.
//
SumOfBytesHashed = mNtHeader.Pe32->OptionalHeader.SizeOfHeaders;
} else {
//
// Use PE32+ offset
//
SumOfBytesHashed = mNtHeader.Pe32Plus->OptionalHeader.SizeOfHeaders;
}
Section = (EFI_IMAGE_SECTION_HEADER *) (
mImageBase +
mPeCoffHeaderOffset +
sizeof (UINT32) +
sizeof (EFI_IMAGE_FILE_HEADER) +
mNtHeader.Pe32->FileHeader.SizeOfOptionalHeader
);
//
// 11. Build a temporary table of pointers to all the IMAGE_SECTION_HEADER
// structures in the image. The 'NumberOfSections' field of the image
// header indicates how big the table should be. Do not include any
// IMAGE_SECTION_HEADERs in the table whose 'SizeOfRawData' field is zero.
//
SectionHeader = (EFI_IMAGE_SECTION_HEADER *) AllocateZeroPool (sizeof (EFI_IMAGE_SECTION_HEADER) * mNtHeader.Pe32->FileHeader.NumberOfSections);
if (SectionHeader == NULL) {
Status = FALSE;
goto Done;
}
//
// 12. Using the 'PointerToRawData' in the referenced section headers as
// a key, arrange the elements in the table in ascending order. In other
// words, sort the section headers according to the disk-file offset of
// the section.
//
for (Index = 0; Index < mNtHeader.Pe32->FileHeader.NumberOfSections; Index++) {
Pos = Index;
while ((Pos > 0) && (Section->PointerToRawData < SectionHeader[Pos - 1].PointerToRawData)) {
CopyMem (&SectionHeader[Pos], &SectionHeader[Pos - 1], sizeof (EFI_IMAGE_SECTION_HEADER));
Pos--;
}
CopyMem (&SectionHeader[Pos], Section, sizeof (EFI_IMAGE_SECTION_HEADER));
Section += 1;
}
//
// 13. Walk through the sorted table, bring the corresponding section
// into memory, and hash the entire section (using the 'SizeOfRawData'
// field in the section header to determine the amount of data to hash).
// 14. Add the section's 'SizeOfRawData' to SUM_OF_BYTES_HASHED .
// 15. Repeat steps 13 and 14 for all the sections in the sorted table.
//
for (Index = 0; Index < mNtHeader.Pe32->FileHeader.NumberOfSections; Index++) {
Section = &SectionHeader[Index];
if (Section->SizeOfRawData == 0) {
continue;
}
HashBase = mImageBase + Section->PointerToRawData;
HashSize = (UINTN) Section->SizeOfRawData;
Status = mHash[HashAlg].HashUpdate(HashCtx, HashBase, HashSize);
if (!Status) {
goto Done;
}
SumOfBytesHashed += HashSize;
}
//
// 16. If the file size is greater than SUM_OF_BYTES_HASHED, there is extra
// data in the file that needs to be added to the hash. This data begins
// at file offset SUM_OF_BYTES_HASHED and its length is:
// FileSize - (CertDirectory->Size)
//
if (mImageSize > SumOfBytesHashed) {
HashBase = mImageBase + SumOfBytesHashed;
if (NumberOfRvaAndSizes <= EFI_IMAGE_DIRECTORY_ENTRY_SECURITY) {
CertSize = 0;
} else {
if (Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// Use PE32 offset.
//
CertSize = mNtHeader.Pe32->OptionalHeader.DataDirectory[EFI_IMAGE_DIRECTORY_ENTRY_SECURITY].Size;
} else {
//
// Use PE32+ offset.
//
CertSize = mNtHeader.Pe32Plus->OptionalHeader.DataDirectory[EFI_IMAGE_DIRECTORY_ENTRY_SECURITY].Size;
}
}
if (mImageSize > CertSize + SumOfBytesHashed) {
HashSize = (UINTN) (mImageSize - CertSize - SumOfBytesHashed);
Status = mHash[HashAlg].HashUpdate(HashCtx, HashBase, HashSize);
if (!Status) {
goto Done;
}
} else if (mImageSize < CertSize + SumOfBytesHashed) {
Status = FALSE;
goto Done;
}
}
Status = mHash[HashAlg].HashFinal(HashCtx, mImageDigest);
Done:
if (HashCtx != NULL) {
FreePool (HashCtx);
}
if (SectionHeader != NULL) {
FreePool (SectionHeader);
}
return Status;
}
/**
Recognize the Hash algorithm in PE/COFF Authenticode and caculate hash of
Pe/Coff image based on the authenticode image hashing in PE/COFF Specification
8.0 Appendix A
Caution: This function may receive untrusted input.
PE/COFF image is external input, so this function will validate its data structure
within this image buffer before use.
@param[in] AuthData Pointer to the Authenticode Signature retrieved from signed image.
@param[in] AuthDataSize Size of the Authenticode Signature in bytes.
@retval EFI_UNSUPPORTED Hash algorithm is not supported.
@retval EFI_SUCCESS Hash successfully.
**/
EFI_STATUS
HashPeImageByType (
IN UINT8 *AuthData,
IN UINTN AuthDataSize
)
{
UINT8 Index;
for (Index = 0; Index < HASHALG_MAX; Index++) {
//
// Check the Hash algorithm in PE/COFF Authenticode.
// According to PKCS#7 Definition:
// SignedData ::= SEQUENCE {
// version Version,
// digestAlgorithms DigestAlgorithmIdentifiers,
// contentInfo ContentInfo,
// .... }
// The DigestAlgorithmIdentifiers can be used to determine the hash algorithm in PE/COFF hashing
// This field has the fixed offset (+32) in final Authenticode ASN.1 data.
// Fixed offset (+32) is calculated based on two bytes of length encoding.
//
if ((*(AuthData + 1) & TWO_BYTE_ENCODE) != TWO_BYTE_ENCODE) {
//
// Only support two bytes of Long Form of Length Encoding.
//
continue;
}
if (AuthDataSize < 32 + mHash[Index].OidLength) {
return EFI_UNSUPPORTED;
}
if (CompareMem (AuthData + 32, mHash[Index].OidValue, mHash[Index].OidLength) == 0) {
break;
}
}
if (Index == HASHALG_MAX) {
return EFI_UNSUPPORTED;
}
//
// HASH PE Image based on Hash algorithm in PE/COFF Authenticode.
//
if (!HashPeImage(Index)) {
return EFI_UNSUPPORTED;
}
return EFI_SUCCESS;
}
/**
Returns the size of a given image execution info table in bytes.
This function returns the size, in bytes, of the image execution info table specified by
ImageExeInfoTable. If ImageExeInfoTable is NULL, then 0 is returned.
@param ImageExeInfoTable A pointer to a image execution info table structure.
@retval 0 If ImageExeInfoTable is NULL.
@retval Others The size of a image execution info table in bytes.
**/
UINTN
GetImageExeInfoTableSize (
EFI_IMAGE_EXECUTION_INFO_TABLE *ImageExeInfoTable
)
{
UINTN Index;
EFI_IMAGE_EXECUTION_INFO *ImageExeInfoItem;
UINTN TotalSize;
if (ImageExeInfoTable == NULL) {
return 0;
}
ImageExeInfoItem = (EFI_IMAGE_EXECUTION_INFO *) ((UINT8 *) ImageExeInfoTable + sizeof (EFI_IMAGE_EXECUTION_INFO_TABLE));
TotalSize = sizeof (EFI_IMAGE_EXECUTION_INFO_TABLE);
for (Index = 0; Index < ImageExeInfoTable->NumberOfImages; Index++) {
TotalSize += ReadUnaligned32 ((UINT32 *) &ImageExeInfoItem->InfoSize);
ImageExeInfoItem = (EFI_IMAGE_EXECUTION_INFO *) ((UINT8 *) ImageExeInfoItem + ReadUnaligned32 ((UINT32 *) &ImageExeInfoItem->InfoSize));
}
return TotalSize;
}
/**
Create an Image Execution Information Table entry and add it to system configuration table.
@param[in] Action Describes the action taken by the firmware regarding this image.
@param[in] Name Input a null-terminated, user-friendly name.
@param[in] DevicePath Input device path pointer.
@param[in] Signature Input signature info in EFI_SIGNATURE_LIST data structure.
@param[in] SignatureSize Size of signature.
**/
VOID
AddImageExeInfo (
IN EFI_IMAGE_EXECUTION_ACTION Action,
IN CHAR16 *Name OPTIONAL,
IN CONST EFI_DEVICE_PATH_PROTOCOL *DevicePath,
IN EFI_SIGNATURE_LIST *Signature OPTIONAL,
IN UINTN SignatureSize
)
{
EFI_IMAGE_EXECUTION_INFO_TABLE *ImageExeInfoTable;
EFI_IMAGE_EXECUTION_INFO_TABLE *NewImageExeInfoTable;
EFI_IMAGE_EXECUTION_INFO *ImageExeInfoEntry;
UINTN ImageExeInfoTableSize;
UINTN NewImageExeInfoEntrySize;
UINTN NameStringLen;
UINTN DevicePathSize;
ImageExeInfoTable = NULL;
NewImageExeInfoTable = NULL;
ImageExeInfoEntry = NULL;
NameStringLen = 0;
if (DevicePath == NULL) {
return ;
}
if (Name != NULL) {
NameStringLen = StrSize (Name);
} else {
NameStringLen = sizeof (CHAR16);
}
EfiGetSystemConfigurationTable (&gEfiImageSecurityDatabaseGuid, (VOID **) &ImageExeInfoTable);
if (ImageExeInfoTable != NULL) {
//
// The table has been found!
// We must enlarge the table to accomodate the new exe info entry.
//
ImageExeInfoTableSize = GetImageExeInfoTableSize (ImageExeInfoTable);
} else {
//
// Not Found!
// We should create a new table to append to the configuration table.
//
ImageExeInfoTableSize = sizeof (EFI_IMAGE_EXECUTION_INFO_TABLE);
}
DevicePathSize = GetDevicePathSize (DevicePath);
NewImageExeInfoEntrySize = sizeof (EFI_IMAGE_EXECUTION_INFO) + NameStringLen + DevicePathSize + SignatureSize;
NewImageExeInfoTable = (EFI_IMAGE_EXECUTION_INFO_TABLE *) AllocateRuntimePool (ImageExeInfoTableSize + NewImageExeInfoEntrySize);
if (NewImageExeInfoTable == NULL) {
return ;
}
if (ImageExeInfoTable != NULL) {
CopyMem (NewImageExeInfoTable, ImageExeInfoTable, ImageExeInfoTableSize);
} else {
NewImageExeInfoTable->NumberOfImages = 0;
}
NewImageExeInfoTable->NumberOfImages++;
ImageExeInfoEntry = (EFI_IMAGE_EXECUTION_INFO *) ((UINT8 *) NewImageExeInfoTable + ImageExeInfoTableSize);
//
// Update new item's infomation.
//
WriteUnaligned32 ((UINT32 *) &ImageExeInfoEntry->Action, Action);
WriteUnaligned32 ((UINT32 *) &ImageExeInfoEntry->InfoSize, (UINT32) NewImageExeInfoEntrySize);
if (Name != NULL) {
CopyMem ((UINT8 *) &ImageExeInfoEntry->InfoSize + sizeof (UINT32), Name, NameStringLen);
} else {
ZeroMem ((UINT8 *) &ImageExeInfoEntry->InfoSize + sizeof (UINT32), sizeof (CHAR16));
}
CopyMem (
(UINT8 *) &ImageExeInfoEntry->InfoSize + sizeof (UINT32) + NameStringLen,
DevicePath,
DevicePathSize
);
if (Signature != NULL) {
CopyMem (
(UINT8 *) &ImageExeInfoEntry->InfoSize + sizeof (UINT32) + NameStringLen + DevicePathSize,
Signature,
SignatureSize
);
}
//
// Update/replace the image execution table.
//
gBS->InstallConfigurationTable (&gEfiImageSecurityDatabaseGuid, (VOID *) NewImageExeInfoTable);
//
// Free Old table data!
//
if (ImageExeInfoTable != NULL) {
FreePool (ImageExeInfoTable);
}
}
/**
Check whether signature is in specified database.
@param[in] VariableName Name of database variable that is searched in.
@param[in] Signature Pointer to signature that is searched for.
@param[in] CertType Pointer to hash algrithom.
@param[in] SignatureSize Size of Signature.
@return TRUE Found the signature in the variable database.
@return FALSE Not found the signature in the variable database.
**/
BOOLEAN
IsSignatureFoundInDatabase (
IN CHAR16 *VariableName,
IN UINT8 *Signature,
IN EFI_GUID *CertType,
IN UINTN SignatureSize
)
{
EFI_STATUS Status;
EFI_SIGNATURE_LIST *CertList;
EFI_SIGNATURE_DATA *Cert;
UINTN DataSize;
UINT8 *Data;
UINTN Index;
UINTN CertCount;
BOOLEAN IsFound;
//
// Read signature database variable.
//
IsFound = FALSE;
Data = NULL;
DataSize = 0;
Status = gRT->GetVariable (VariableName, &gEfiImageSecurityDatabaseGuid, NULL, &DataSize, NULL);
if (Status != EFI_BUFFER_TOO_SMALL) {
return FALSE;
}
Data = (UINT8 *) AllocateZeroPool (DataSize);
if (Data == NULL) {
return FALSE;
}
Status = gRT->GetVariable (VariableName, &gEfiImageSecurityDatabaseGuid, NULL, &DataSize, Data);
if (EFI_ERROR (Status)) {
goto Done;
}
//
// Enumerate all signature data in SigDB to check if executable's signature exists.
//
CertList = (EFI_SIGNATURE_LIST *) Data;
while ((DataSize > 0) && (DataSize >= CertList->SignatureListSize)) {
CertCount = (CertList->SignatureListSize - CertList->SignatureHeaderSize) / CertList->SignatureSize;
Cert = (EFI_SIGNATURE_DATA *) ((UINT8 *) CertList + sizeof (EFI_SIGNATURE_LIST) + CertList->SignatureHeaderSize);
if ((CertList->SignatureSize == sizeof(EFI_SIGNATURE_DATA) - 1 + SignatureSize) && (CompareGuid(&CertList->SignatureType, CertType))) {
for (Index = 0; Index < CertCount; Index++) {
if (CompareMem (Cert->SignatureData, Signature, SignatureSize) == 0) {
//
// Find the signature in database.
//
IsFound = TRUE;
break;
}
Cert = (EFI_SIGNATURE_DATA *) ((UINT8 *) Cert + CertList->SignatureSize);
}
if (IsFound) {
break;
}
}
DataSize -= CertList->SignatureListSize;
CertList = (EFI_SIGNATURE_LIST *) ((UINT8 *) CertList + CertList->SignatureListSize);
}
Done:
if (Data != NULL) {
FreePool (Data);
}
return IsFound;
}
/**
Verify PKCS#7 SignedData using certificate found in Variable which formatted
as EFI_SIGNATURE_LIST. The Variable may be PK, KEK, DB or DBX.
@param[in] AuthData Pointer to the Authenticode Signature retrieved from signed image.
@param[in] AuthDataSize Size of the Authenticode Signature in bytes.
@param[in] VariableName Name of Variable to search for Certificate.
@param[in] VendorGuid Variable vendor GUID.
@retval TRUE Image pass verification.
@retval FALSE Image fail verification.
**/
BOOLEAN
IsPkcsSignedDataVerifiedBySignatureList (
IN UINT8 *AuthData,
IN UINTN AuthDataSize,
IN CHAR16 *VariableName,
IN EFI_GUID *VendorGuid
)
{
EFI_STATUS Status;
BOOLEAN VerifyStatus;
EFI_SIGNATURE_LIST *CertList;
EFI_SIGNATURE_DATA *Cert;
UINTN DataSize;
UINT8 *Data;
UINT8 *RootCert;
UINTN RootCertSize;
UINTN Index;
UINTN CertCount;
Data = NULL;
CertList = NULL;
Cert = NULL;
RootCert = NULL;
RootCertSize = 0;
VerifyStatus = FALSE;
DataSize = 0;
Status = gRT->GetVariable (VariableName, VendorGuid, NULL, &DataSize, NULL);
if (Status == EFI_BUFFER_TOO_SMALL) {
Data = (UINT8 *) AllocateZeroPool (DataSize);
if (Data == NULL) {
return VerifyStatus;
}
Status = gRT->GetVariable (VariableName, VendorGuid, NULL, &DataSize, (VOID *) Data);
if (EFI_ERROR (Status)) {
goto Done;
}
//
// Find X509 certificate in Signature List to verify the signature in pkcs7 signed data.
//
CertList = (EFI_SIGNATURE_LIST *) Data;
while ((DataSize > 0) && (DataSize >= CertList->SignatureListSize)) {
if (CompareGuid (&CertList->SignatureType, &gEfiCertX509Guid)) {
Cert = (EFI_SIGNATURE_DATA *) ((UINT8 *) CertList + sizeof (EFI_SIGNATURE_LIST) + CertList->SignatureHeaderSize);
CertCount = (CertList->SignatureListSize - sizeof (EFI_SIGNATURE_LIST) - CertList->SignatureHeaderSize) / CertList->SignatureSize;
for (Index = 0; Index < CertCount; Index++) {
//
// Iterate each Signature Data Node within this CertList for verify.
//
RootCert = Cert->SignatureData;
RootCertSize = CertList->SignatureSize - sizeof (EFI_GUID);
//
// Call AuthenticodeVerify library to Verify Authenticode struct.
//
VerifyStatus = AuthenticodeVerify (
AuthData,
AuthDataSize,
RootCert,
RootCertSize,
mImageDigest,
mImageDigestSize
);
if (VerifyStatus) {
goto Done;
}
Cert = (EFI_SIGNATURE_DATA *) ((UINT8 *) Cert + CertList->SignatureSize);
}
}
DataSize -= CertList->SignatureListSize;
CertList = (EFI_SIGNATURE_LIST *) ((UINT8 *) CertList + CertList->SignatureListSize);
}
}
Done:
if (Data != NULL) {
FreePool (Data);
}
return VerifyStatus;
}
/**
Provide verification service for signed images, which include both signature validation
and platform policy control. For signature types, both UEFI WIN_CERTIFICATE_UEFI_GUID and
MSFT Authenticode type signatures are supported.
In this implementation, only verify external executables when in USER MODE.
Executables from FV is bypass, so pass in AuthenticationStatus is ignored.
The image verification policy is:
If the image is signed,
At least one valid signature or at least one hash value of the image must match a record
in the security database "db", and no valid signature nor any hash value of the image may
be reflected in the security database "dbx".
Otherwise, the image is not signed,
The SHA256 hash value of the image must match a record in the security database "db", and
not be reflected in the security data base "dbx".
Caution: This function may receive untrusted input.
PE/COFF image is external input, so this function will validate its data structure
within this image buffer before use.
@param[in] AuthenticationStatus
This is the authentication status returned from the security
measurement services for the input file.
@param[in] File This is a pointer to the device path of the file that is
being dispatched. This will optionally be used for logging.
@param[in] FileBuffer File buffer matches the input file device path.
@param[in] FileSize Size of File buffer matches the input file device path.
@param[in] BootPolicy A boot policy that was used to call LoadImage() UEFI service.
@retval EFI_SUCCESS The file specified by DevicePath and non-NULL
FileBuffer did authenticate, and the platform policy dictates
that the DXE Foundation may use the file.
@retval EFI_SUCCESS The device path specified by NULL device path DevicePath
and non-NULL FileBuffer did authenticate, and the platform
policy dictates that the DXE Foundation may execute the image in
FileBuffer.
@retval EFI_OUT_RESOURCE Fail to allocate memory.
@retval EFI_SECURITY_VIOLATION The file specified by File did not authenticate, and
the platform policy dictates that File should be placed
in the untrusted state. The image has been added to the file
execution table.
@retval EFI_ACCESS_DENIED The file specified by File and FileBuffer did not
authenticate, and the platform policy dictates that the DXE
Foundation many not use File.
**/
EFI_STATUS
EFIAPI
DxeImageVerificationHandler (
IN UINT32 AuthenticationStatus,
IN CONST EFI_DEVICE_PATH_PROTOCOL *File,
IN VOID *FileBuffer,
IN UINTN FileSize,
IN BOOLEAN BootPolicy
)
{
EFI_STATUS Status;
UINT16 Magic;
EFI_IMAGE_DOS_HEADER *DosHdr;
EFI_STATUS VerifyStatus;
EFI_SIGNATURE_LIST *SignatureList;
UINTN SignatureListSize;
EFI_SIGNATURE_DATA *Signature;
EFI_IMAGE_EXECUTION_ACTION Action;
WIN_CERTIFICATE *WinCertificate;
UINT32 Policy;
UINT8 *SecureBoot;
PE_COFF_LOADER_IMAGE_CONTEXT ImageContext;
UINT32 NumberOfRvaAndSizes;
WIN_CERTIFICATE_EFI_PKCS *PkcsCertData;
WIN_CERTIFICATE_UEFI_GUID *WinCertUefiGuid;
UINT8 *AuthData;
UINTN AuthDataSize;
EFI_IMAGE_DATA_DIRECTORY *SecDataDir;
UINT32 OffSet;
SignatureList = NULL;
SignatureListSize = 0;
WinCertificate = NULL;
SecDataDir = NULL;
PkcsCertData = NULL;
Action = EFI_IMAGE_EXECUTION_AUTH_UNTESTED;
Status = EFI_ACCESS_DENIED;
VerifyStatus = EFI_ACCESS_DENIED;
//
// Check the image type and get policy setting.
//
switch (GetImageType (File)) {
case IMAGE_FROM_FV:
Policy = ALWAYS_EXECUTE;
break;
case IMAGE_FROM_OPTION_ROM:
Policy = PcdGet32 (PcdOptionRomImageVerificationPolicy);
break;
case IMAGE_FROM_REMOVABLE_MEDIA:
Policy = PcdGet32 (PcdRemovableMediaImageVerificationPolicy);
break;
case IMAGE_FROM_FIXED_MEDIA:
Policy = PcdGet32 (PcdFixedMediaImageVerificationPolicy);
break;
default:
Policy = DENY_EXECUTE_ON_SECURITY_VIOLATION;
break;
}
//
// If policy is always/never execute, return directly.
//
if (Policy == ALWAYS_EXECUTE) {
return EFI_SUCCESS;
} else if (Policy == NEVER_EXECUTE) {
return EFI_ACCESS_DENIED;
}
GetEfiGlobalVariable2 (EFI_SECURE_BOOT_MODE_NAME, (VOID**)&SecureBoot, NULL);
//
// Skip verification if SecureBoot variable doesn't exist.
//
if (SecureBoot == NULL) {
return EFI_SUCCESS;
}
//
// Skip verification if SecureBoot is disabled.
//
if (*SecureBoot == SECURE_BOOT_MODE_DISABLE) {
FreePool (SecureBoot);
return EFI_SUCCESS;
}
FreePool (SecureBoot);
//
// Read the Dos header.
//
if (FileBuffer == NULL) {
return EFI_INVALID_PARAMETER;
}
mImageBase = (UINT8 *) FileBuffer;
mImageSize = FileSize;
ZeroMem (&ImageContext, sizeof (ImageContext));
ImageContext.Handle = (VOID *) FileBuffer;
ImageContext.ImageRead = (PE_COFF_LOADER_READ_FILE) DxeImageVerificationLibImageRead;
//
// Get information about the image being loaded
//
Status = PeCoffLoaderGetImageInfo (&ImageContext);
if (EFI_ERROR (Status)) {
//
// The information can't be got from the invalid PeImage
//
goto Done;
}
Status = EFI_ACCESS_DENIED;
DosHdr = (EFI_IMAGE_DOS_HEADER *) mImageBase;
if (DosHdr->e_magic == EFI_IMAGE_DOS_SIGNATURE) {
//
// DOS image header is present,
// so read the PE header after the DOS image header.
//
mPeCoffHeaderOffset = DosHdr->e_lfanew;
} else {
mPeCoffHeaderOffset = 0;
}
//
// Check PE/COFF image.
//
mNtHeader.Pe32 = (EFI_IMAGE_NT_HEADERS32 *) (mImageBase + mPeCoffHeaderOffset);
if (mNtHeader.Pe32->Signature != EFI_IMAGE_NT_SIGNATURE) {
//
// It is not a valid Pe/Coff file.
//
goto Done;
}
if (mNtHeader.Pe32->FileHeader.Machine == IMAGE_FILE_MACHINE_IA64 && mNtHeader.Pe32->OptionalHeader.Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// NOTE: Some versions of Linux ELILO for Itanium have an incorrect magic value
// in the PE/COFF Header. If the MachineType is Itanium(IA64) and the
// Magic value in the OptionalHeader is EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC
// then override the magic value to EFI_IMAGE_NT_OPTIONAL_HDR64_MAGIC
//
Magic = EFI_IMAGE_NT_OPTIONAL_HDR64_MAGIC;
} else {
//
// Get the magic value from the PE/COFF Optional Header
//
Magic = mNtHeader.Pe32->OptionalHeader.Magic;
}
if (Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
//
// Use PE32 offset.
//
NumberOfRvaAndSizes = mNtHeader.Pe32->OptionalHeader.NumberOfRvaAndSizes;
if (NumberOfRvaAndSizes > EFI_IMAGE_DIRECTORY_ENTRY_SECURITY) {
SecDataDir = (EFI_IMAGE_DATA_DIRECTORY *) &mNtHeader.Pe32->OptionalHeader.DataDirectory[EFI_IMAGE_DIRECTORY_ENTRY_SECURITY];
}
} else {
//
// Use PE32+ offset.
//
NumberOfRvaAndSizes = mNtHeader.Pe32Plus->OptionalHeader.NumberOfRvaAndSizes;
if (NumberOfRvaAndSizes > EFI_IMAGE_DIRECTORY_ENTRY_SECURITY) {
SecDataDir = (EFI_IMAGE_DATA_DIRECTORY *) &mNtHeader.Pe32Plus->OptionalHeader.DataDirectory[EFI_IMAGE_DIRECTORY_ENTRY_SECURITY];
}
}
//
// Start Image Validation.
//
if (SecDataDir == NULL || SecDataDir->Size == 0) {
//
// This image is not signed. The SHA256 hash value of the image must match a record in the security database "db",
// and not be reflected in the security data base "dbx".
//
if (!HashPeImage (HASHALG_SHA256)) {
goto Done;
}
if (IsSignatureFoundInDatabase (EFI_IMAGE_SECURITY_DATABASE1, mImageDigest, &mCertType, mImageDigestSize)) {
//
// Image Hash is in forbidden database (DBX).
//
goto Done;
}
if (IsSignatureFoundInDatabase (EFI_IMAGE_SECURITY_DATABASE, mImageDigest, &mCertType, mImageDigestSize)) {
//
// Image Hash is in allowed database (DB).
//
return EFI_SUCCESS;
}
//
// Image Hash is not found in both forbidden and allowed database.
//
goto Done;
}
//
// Verify the signature of the image, multiple signatures are allowed as per PE/COFF Section 4.7
// "Attribute Certificate Table".
// The first certificate starts at offset (SecDataDir->VirtualAddress) from the start of the file.
//
for (OffSet = SecDataDir->VirtualAddress;
OffSet < (SecDataDir->VirtualAddress + SecDataDir->Size);
OffSet += WinCertificate->dwLength, OffSet += ALIGN_SIZE (OffSet)) {
WinCertificate = (WIN_CERTIFICATE *) (mImageBase + OffSet);
if ((SecDataDir->VirtualAddress + SecDataDir->Size - OffSet) <= sizeof (WIN_CERTIFICATE) ||
(SecDataDir->VirtualAddress + SecDataDir->Size - OffSet) < WinCertificate->dwLength) {
break;
}
//
// Verify the image's Authenticode signature, only DER-encoded PKCS#7 signed data is supported.
//
if (WinCertificate->wCertificateType == WIN_CERT_TYPE_PKCS_SIGNED_DATA) {
//
// The certificate is formatted as WIN_CERTIFICATE_EFI_PKCS which is described in the
// Authenticode specification.
//
PkcsCertData = (WIN_CERTIFICATE_EFI_PKCS *) WinCertificate;
if (PkcsCertData->Hdr.dwLength <= sizeof (PkcsCertData->Hdr)) {
break;
}
AuthData = PkcsCertData->CertData;
AuthDataSize = PkcsCertData->Hdr.dwLength - sizeof(PkcsCertData->Hdr);
} else if (WinCertificate->wCertificateType == WIN_CERT_TYPE_EFI_GUID) {
//
// The certificate is formatted as WIN_CERTIFICATE_UEFI_GUID which is described in UEFI Spec.
//
WinCertUefiGuid = (WIN_CERTIFICATE_UEFI_GUID *) WinCertificate;
if (WinCertUefiGuid->Hdr.dwLength <= OFFSET_OF(WIN_CERTIFICATE_UEFI_GUID, CertData)) {
break;
}
if (!CompareGuid (&WinCertUefiGuid->CertType, &gEfiCertPkcs7Guid)) {
continue;
}
AuthData = WinCertUefiGuid->CertData;
AuthDataSize = WinCertUefiGuid->Hdr.dwLength - OFFSET_OF(WIN_CERTIFICATE_UEFI_GUID, CertData);
} else {
if (WinCertificate->dwLength < sizeof (WIN_CERTIFICATE)) {
break;
}
continue;
}
Status = HashPeImageByType (AuthData, AuthDataSize);
if (EFI_ERROR (Status)) {
continue;
}
//
// Check the digital signature against the revoked certificate in forbidden database (dbx).
//
if (IsPkcsSignedDataVerifiedBySignatureList (AuthData, AuthDataSize, EFI_IMAGE_SECURITY_DATABASE1, &gEfiImageSecurityDatabaseGuid)) {
Action = EFI_IMAGE_EXECUTION_AUTH_SIG_FAILED;
VerifyStatus = EFI_ACCESS_DENIED;
break;
}
//
// Check the digital signature against the valid certificate in allowed database (db).
//
if (EFI_ERROR (VerifyStatus)) {
if (IsPkcsSignedDataVerifiedBySignatureList (AuthData, AuthDataSize, EFI_IMAGE_SECURITY_DATABASE, &gEfiImageSecurityDatabaseGuid)) {
VerifyStatus = EFI_SUCCESS;
}
}
//
// Check the image's hash value.
//
if (IsSignatureFoundInDatabase (EFI_IMAGE_SECURITY_DATABASE1, mImageDigest, &mCertType, mImageDigestSize)) {
Action = EFI_IMAGE_EXECUTION_AUTH_SIG_FOUND;
VerifyStatus = EFI_ACCESS_DENIED;
break;
} else if (EFI_ERROR (VerifyStatus)) {
if (IsSignatureFoundInDatabase (EFI_IMAGE_SECURITY_DATABASE, mImageDigest, &mCertType, mImageDigestSize)) {
VerifyStatus = EFI_SUCCESS;
}
}
}
if (OffSet != (SecDataDir->VirtualAddress + SecDataDir->Size)) {
//
// The Size in Certificate Table or the attribute certicate table is corrupted.
//
VerifyStatus = EFI_ACCESS_DENIED;
}
if (!EFI_ERROR (VerifyStatus)) {
return EFI_SUCCESS;
} else {
Status = EFI_ACCESS_DENIED;
if (Action == EFI_IMAGE_EXECUTION_AUTH_SIG_FAILED || Action == EFI_IMAGE_EXECUTION_AUTH_SIG_FOUND) {
//
// Get image hash value as executable's signature.
//
SignatureListSize = sizeof (EFI_SIGNATURE_LIST) + sizeof (EFI_SIGNATURE_DATA) - 1 + mImageDigestSize;
SignatureList = (EFI_SIGNATURE_LIST *) AllocateZeroPool (SignatureListSize);
if (SignatureList == NULL) {
Status = EFI_OUT_OF_RESOURCES;
goto Done;
}
SignatureList->SignatureHeaderSize = 0;
SignatureList->SignatureListSize = (UINT32) SignatureListSize;
SignatureList->SignatureSize = (UINT32) mImageDigestSize;
CopyMem (&SignatureList->SignatureType, &mCertType, sizeof (EFI_GUID));
Signature = (EFI_SIGNATURE_DATA *) ((UINT8 *) SignatureList + sizeof (EFI_SIGNATURE_LIST));
CopyMem (Signature->SignatureData, mImageDigest, mImageDigestSize);
}
}
Done:
if (Status != EFI_SUCCESS) {
//
// Policy decides to defer or reject the image; add its information in image executable information table.
//
AddImageExeInfo (Action, NULL, File, SignatureList, SignatureListSize);
Status = EFI_SECURITY_VIOLATION;
}
if (SignatureList != NULL) {
FreePool (SignatureList);
}
return Status;
}
/**
When VariableWriteArchProtocol install, create "SecureBoot" variable.
@param[in] Event Event whose notification function is being invoked.
@param[in] Context Pointer to the notification function's context.
**/
VOID
EFIAPI
VariableWriteCallBack (
IN EFI_EVENT Event,
IN VOID *Context
)
{
UINT8 SecureBootMode;
UINT8 *SecureBootModePtr;
EFI_STATUS Status;
VOID *ProtocolPointer;
Status = gBS->LocateProtocol (&gEfiVariableWriteArchProtocolGuid, NULL, &ProtocolPointer);
if (EFI_ERROR (Status)) {
return;
}
//
// Check whether "SecureBoot" variable exists.
// If this library is built-in, it means firmware has capability to perform
// driver signing verification.
//
GetEfiGlobalVariable2 (EFI_SECURE_BOOT_MODE_NAME, (VOID**)&SecureBootModePtr, NULL);
if (SecureBootModePtr == NULL) {
SecureBootMode = SECURE_BOOT_MODE_DISABLE;
//
// Authenticated variable driver will update "SecureBoot" depending on SetupMode variable.
//
gRT->SetVariable (
EFI_SECURE_BOOT_MODE_NAME,
&gEfiGlobalVariableGuid,
EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_NON_VOLATILE,
sizeof (UINT8),
&SecureBootMode
);
} else {
FreePool (SecureBootModePtr);
}
}
/**
Register security measurement handler.
@param ImageHandle ImageHandle of the loaded driver.
@param SystemTable Pointer to the EFI System Table.
@retval EFI_SUCCESS The handlers were registered successfully.
**/
EFI_STATUS
EFIAPI
DxeImageVerificationLibConstructor (
IN EFI_HANDLE ImageHandle,
IN EFI_SYSTEM_TABLE *SystemTable
)
{
VOID *Registration;
//
// Register callback function upon VariableWriteArchProtocol.
//
EfiCreateProtocolNotifyEvent (
&gEfiVariableWriteArchProtocolGuid,
TPL_CALLBACK,
VariableWriteCallBack,
NULL,
&Registration
);
return RegisterSecurity2Handler (
DxeImageVerificationHandler,
EFI_AUTH_OPERATION_VERIFY_IMAGE | EFI_AUTH_OPERATION_IMAGE_REQUIRED
);
}