EFI_STATUS
NorFlashCreateInstance (
IN UINTN NorFlashDeviceBase,
IN UINTN NorFlashRegionBase,
IN UINTN NorFlashSize,
IN UINT32 MediaId,
IN UINT32 BlockSize,
IN BOOLEAN SupportFvb,
IN CONST GUID *NorFlashGuid,
OUT NOR_FLASH_INSTANCE** NorFlashInstance
)
{
EFI_STATUS Status;
NOR_FLASH_INSTANCE* Instance;
ASSERT(NorFlashInstance != NULL);
Instance = AllocateRuntimeCopyPool (sizeof(NOR_FLASH_INSTANCE),&mNorFlashInstanceTemplate);
if (Instance == NULL) {
return EFI_OUT_OF_RESOURCES;
}
Instance->DeviceBaseAddress = NorFlashDeviceBase;
Instance->RegionBaseAddress = NorFlashRegionBase;
Instance->Size = NorFlashSize;
Instance->BlockIoProtocol.Media = &Instance->Media;
Instance->Media.MediaId = MediaId;
Instance->Media.BlockSize = BlockSize;
Instance->Media.LastBlock = (NorFlashSize / BlockSize)-1;
CopyGuid (&Instance->DevicePath.Vendor.Guid, NorFlashGuid);
Instance->ShadowBuffer = AllocateRuntimePool (BlockSize);;
if (Instance->ShadowBuffer == NULL) {
return EFI_OUT_OF_RESOURCES;
}
if (SupportFvb) {
Instance->SupportFvb = TRUE;
Instance->Initialize = NorFlashFvbInitialize;
Status = gBS->InstallMultipleProtocolInterfaces (
&Instance->Handle,
&gEfiDevicePathProtocolGuid, &Instance->DevicePath,
&gEfiBlockIoProtocolGuid, &Instance->BlockIoProtocol,
&gEfiFirmwareVolumeBlockProtocolGuid, &Instance->FvbProtocol,
NULL
);
if (EFI_ERROR(Status)) {
FreePool (Instance);
return Status;
}
} else {
Instance->Initialized = TRUE;
Status = gBS->InstallMultipleProtocolInterfaces (
&Instance->Handle,
&gEfiDevicePathProtocolGuid, &Instance->DevicePath,
&gEfiBlockIoProtocolGuid, &Instance->BlockIoProtocol,
&gEfiDiskIoProtocolGuid, &Instance->DiskIoProtocol,
NULL
);
if (EFI_ERROR(Status)) {
FreePool (Instance);
return Status;
}
}
*NorFlashInstance = Instance;
return Status;
}
/**
Main entry point to DXE Core.
@param HobStart Pointer to the beginning of the HOB List from PEI.
@return This function should never return.
**/
VOID
EFIAPI
DxeMain (
IN VOID *HobStart
)
{
EFI_STATUS Status;
EFI_PHYSICAL_ADDRESS MemoryBaseAddress;
UINT64 MemoryLength;
PE_COFF_LOADER_IMAGE_CONTEXT ImageContext;
UINTN Index;
EFI_HOB_GUID_TYPE *GuidHob;
EFI_VECTOR_HANDOFF_INFO *VectorInfoList;
EFI_VECTOR_HANDOFF_INFO *VectorInfo;
VOID *EntryPoint;
//
// Setup the default exception handlers
//
VectorInfoList = NULL;
GuidHob = GetNextGuidHob (&gEfiVectorHandoffInfoPpiGuid, HobStart);
if (GuidHob != NULL) {
VectorInfoList = (EFI_VECTOR_HANDOFF_INFO *) (GET_GUID_HOB_DATA(GuidHob));
}
Status = InitializeCpuExceptionHandlers (VectorInfoList);
ASSERT_EFI_ERROR (Status);
//
// Initialize Debug Agent to support source level debug in DXE phase
//
InitializeDebugAgent (DEBUG_AGENT_INIT_DXE_CORE, HobStart, NULL);
//
// Initialize Memory Services
//
CoreInitializeMemoryServices (&HobStart, &MemoryBaseAddress, &MemoryLength);
MemoryProfileInit (HobStart);
//
// Allocate the EFI System Table and EFI Runtime Service Table from EfiRuntimeServicesData
// Use the templates to initialize the contents of the EFI System Table and EFI Runtime Services Table
//
gDxeCoreST = AllocateRuntimeCopyPool (sizeof (EFI_SYSTEM_TABLE), &mEfiSystemTableTemplate);
ASSERT (gDxeCoreST != NULL);
gDxeCoreRT = AllocateRuntimeCopyPool (sizeof (EFI_RUNTIME_SERVICES), &mEfiRuntimeServicesTableTemplate);
ASSERT (gDxeCoreRT != NULL);
gDxeCoreST->RuntimeServices = gDxeCoreRT;
//
// Start the Image Services.
//
Status = CoreInitializeImageServices (HobStart);
ASSERT_EFI_ERROR (Status);
//
// Initialize the Global Coherency Domain Services
//
Status = CoreInitializeGcdServices (&HobStart, MemoryBaseAddress, MemoryLength);
ASSERT_EFI_ERROR (Status);
//
// Call constructor for all libraries
//
ProcessLibraryConstructorList (gDxeCoreImageHandle, gDxeCoreST);
PERF_END (NULL,"PEI", NULL, 0) ;
PERF_START (NULL,"DXE", NULL, 0) ;
//
// Report DXE Core image information to the PE/COFF Extra Action Library
//
ZeroMem (&ImageContext, sizeof (ImageContext));
ImageContext.ImageAddress = (EFI_PHYSICAL_ADDRESS)(UINTN)gDxeCoreLoadedImage->ImageBase;
ImageContext.PdbPointer = PeCoffLoaderGetPdbPointer ((VOID*)(UINTN)ImageContext.ImageAddress);
ImageContext.SizeOfHeaders = PeCoffGetSizeOfHeaders ((VOID*)(UINTN)ImageContext.ImageAddress);
Status = PeCoffLoaderGetEntryPoint ((VOID*)(UINTN)ImageContext.ImageAddress, &EntryPoint);
if (Status == EFI_SUCCESS) {
ImageContext.EntryPoint = (EFI_PHYSICAL_ADDRESS)(UINTN)EntryPoint;
}
ImageContext.Handle = (VOID *)(UINTN)gDxeCoreLoadedImage->ImageBase;
ImageContext.ImageRead = PeCoffLoaderImageReadFromMemory;
PeCoffLoaderRelocateImageExtraAction (&ImageContext);
//
// Install the DXE Services Table into the EFI System Tables's Configuration Table
//
Status = CoreInstallConfigurationTable (&gEfiDxeServicesTableGuid, gDxeCoreDS);
ASSERT_EFI_ERROR (Status);
//
// Install the HOB List into the EFI System Tables's Configuration Table
//
Status = CoreInstallConfigurationTable (&gEfiHobListGuid, HobStart);
ASSERT_EFI_ERROR (Status);
//
// Install Memory Type Information Table into the EFI System Tables's Configuration Table
//
Status = CoreInstallConfigurationTable (&gEfiMemoryTypeInformationGuid, &gMemoryTypeInformation);
ASSERT_EFI_ERROR (Status);
//
// If Loading modules At fixed address feature is enabled, install Load moduels at fixed address
// Configuration Table so that user could easily to retrieve the top address to load Dxe and PEI
// Code and Tseg base to load SMM driver.
//
if (PcdGet64(PcdLoadModuleAtFixAddressEnable) != 0) {
Status = CoreInstallConfigurationTable (&gLoadFixedAddressConfigurationTableGuid, &gLoadModuleAtFixAddressConfigurationTable);
ASSERT_EFI_ERROR (Status);
}
//
// Report Status Code here for DXE_ENTRY_POINT once it is available
//
REPORT_STATUS_CODE (
EFI_PROGRESS_CODE,
(EFI_SOFTWARE_DXE_CORE | EFI_SW_DXE_CORE_PC_ENTRY_POINT)
);
//
// Create the aligned system table pointer structure that is used by external
// debuggers to locate the system table... Also, install debug image info
// configuration table.
//
CoreInitializeDebugImageInfoTable ();
CoreNewDebugImageInfoEntry (
EFI_DEBUG_IMAGE_INFO_TYPE_NORMAL,
gDxeCoreLoadedImage,
gDxeCoreImageHandle
);
DEBUG ((DEBUG_INFO | DEBUG_LOAD, "HOBLIST address in DXE = 0x%p\n", HobStart));
DEBUG_CODE_BEGIN ();
EFI_PEI_HOB_POINTERS Hob;
for (Hob.Raw = HobStart; !END_OF_HOB_LIST(Hob); Hob.Raw = GET_NEXT_HOB(Hob)) {
if (GET_HOB_TYPE (Hob) == EFI_HOB_TYPE_MEMORY_ALLOCATION) {
DEBUG ((DEBUG_INFO | DEBUG_LOAD, "Memory Allocation 0x%08x 0x%0lx - 0x%0lx\n", \
Hob.MemoryAllocation->AllocDescriptor.MemoryType, \
Hob.MemoryAllocation->AllocDescriptor.MemoryBaseAddress, \
Hob.MemoryAllocation->AllocDescriptor.MemoryBaseAddress + Hob.MemoryAllocation->AllocDescriptor.MemoryLength - 1));
}
}
for (Hob.Raw = HobStart; !END_OF_HOB_LIST(Hob); Hob.Raw = GET_NEXT_HOB(Hob)) {
if (GET_HOB_TYPE (Hob) == EFI_HOB_TYPE_FV2) {
DEBUG ((DEBUG_INFO | DEBUG_LOAD, "FV2 Hob 0x%0lx - 0x%0lx\n", Hob.FirmwareVolume2->BaseAddress, Hob.FirmwareVolume2->BaseAddress + Hob.FirmwareVolume2->Length - 1));
} else if (GET_HOB_TYPE (Hob) == EFI_HOB_TYPE_FV) {
DEBUG ((DEBUG_INFO | DEBUG_LOAD, "FV Hob 0x%0lx - 0x%0lx\n", Hob.FirmwareVolume->BaseAddress, Hob.FirmwareVolume->BaseAddress + Hob.FirmwareVolume->Length - 1));
}
}
DEBUG_CODE_END ();
//
// Initialize the Event Services
//
Status = CoreInitializeEventServices ();
ASSERT_EFI_ERROR (Status);
MemoryProfileInstallProtocol ();
CoreInitializePropertiesTable ();
CoreInitializeMemoryAttributesTable ();
//
// Get persisted vector hand-off info from GUIDeed HOB again due to HobStart may be updated,
// and install configuration table
//
GuidHob = GetNextGuidHob (&gEfiVectorHandoffInfoPpiGuid, HobStart);
if (GuidHob != NULL) {
VectorInfoList = (EFI_VECTOR_HANDOFF_INFO *) (GET_GUID_HOB_DATA(GuidHob));
VectorInfo = VectorInfoList;
Index = 1;
while (VectorInfo->Attribute != EFI_VECTOR_HANDOFF_LAST_ENTRY) {
VectorInfo ++;
Index ++;
}
VectorInfo = AllocateCopyPool (sizeof (EFI_VECTOR_HANDOFF_INFO) * Index, (VOID *) VectorInfoList);
ASSERT (VectorInfo != NULL);
Status = CoreInstallConfigurationTable (&gEfiVectorHandoffTableGuid, (VOID *) VectorInfo);
ASSERT_EFI_ERROR (Status);
}
//
// Get the Protocols that were passed in from PEI to DXE through GUIDed HOBs
//
// These Protocols are not architectural. This implementation is sharing code between
// PEI and DXE in order to save FLASH space. These Protocols could also be implemented
// as part of the DXE Core. However, that would also require the DXE Core to be ported
// each time a different CPU is used, a different Decompression algorithm is used, or a
// different Image type is used. By placing these Protocols in PEI, the DXE Core remains
// generic, and only PEI and the Arch Protocols need to be ported from Platform to Platform,
// and from CPU to CPU.
//
//
// Publish the EFI, Tiano, and Custom Decompress protocols for use by other DXE components
//
Status = CoreInstallMultipleProtocolInterfaces (
&mDecompressHandle,
&gEfiDecompressProtocolGuid, &gEfiDecompress,
NULL
);
ASSERT_EFI_ERROR (Status);
//
// Register for the GUIDs of the Architectural Protocols, so the rest of the
// EFI Boot Services and EFI Runtime Services tables can be filled in.
// Also register for the GUIDs of optional protocols.
//
CoreNotifyOnProtocolInstallation ();
//
// Produce Firmware Volume Protocols, one for each FV in the HOB list.
//
Status = FwVolBlockDriverInit (gDxeCoreImageHandle, gDxeCoreST);
ASSERT_EFI_ERROR (Status);
Status = FwVolDriverInit (gDxeCoreImageHandle, gDxeCoreST);
ASSERT_EFI_ERROR (Status);
//
// Produce the Section Extraction Protocol
//
Status = InitializeSectionExtraction (gDxeCoreImageHandle, gDxeCoreST);
ASSERT_EFI_ERROR (Status);
//
// Initialize the DXE Dispatcher
//
PERF_START (NULL,"CoreInitializeDispatcher", "DxeMain", 0) ;
CoreInitializeDispatcher ();
PERF_END (NULL,"CoreInitializeDispatcher", "DxeMain", 0) ;
//
// Invoke the DXE Dispatcher
//
PERF_START (NULL, "CoreDispatcher", "DxeMain", 0);
CoreDispatcher ();
PERF_END (NULL, "CoreDispatcher", "DxeMain", 0);
//
// Display Architectural protocols that were not loaded if this is DEBUG build
//
DEBUG_CODE_BEGIN ();
CoreDisplayMissingArchProtocols ();
DEBUG_CODE_END ();
//
// Display any drivers that were not dispatched because dependency expression
// evaluated to false if this is a debug build
//
DEBUG_CODE_BEGIN ();
CoreDisplayDiscoveredNotDispatched ();
DEBUG_CODE_END ();
//
// Assert if the Architectural Protocols are not present.
//
Status = CoreAllEfiServicesAvailable ();
if (EFI_ERROR(Status)) {
//
// Report Status code that some Architectural Protocols are not present.
//
REPORT_STATUS_CODE (
EFI_ERROR_CODE | EFI_ERROR_MAJOR,
(EFI_SOFTWARE_DXE_CORE | EFI_SW_DXE_CORE_EC_NO_ARCH)
);
}
ASSERT_EFI_ERROR (Status);
//
// Report Status code before transfer control to BDS
//
REPORT_STATUS_CODE (
EFI_PROGRESS_CODE,
(EFI_SOFTWARE_DXE_CORE | EFI_SW_DXE_CORE_PC_HANDOFF_TO_NEXT)
);
//
// Transfer control to the BDS Architectural Protocol
//
gBds->Entry (gBds);
//
// BDS should never return
//
ASSERT (FALSE);
CpuDeadLoop ();
UNREACHABLE ();
}
//
// Insert the performance probe
//
PERF_END (NULL, "DXE", NULL, 0);
PERF_START (NULL, "BDS", NULL, 0);
DEBUG ((EFI_D_INFO, "[Bds] Entry...\n"));
PERF_CODE (
BdsAllocateMemoryForPerformanceData ();
);
//
// Fill in FirmwareVendor and FirmwareRevision from PCDs
//
FirmwareVendor = (CHAR16 *) PcdGetPtr (PcdFirmwareVendor);
gST->FirmwareVendor = AllocateRuntimeCopyPool (StrSize (FirmwareVendor), FirmwareVendor);
ASSERT (gST->FirmwareVendor != NULL);
gST->FirmwareRevision = PcdGet32 (PcdFirmwareRevision);
//
// Fixup Tasble CRC after we updated Firmware Vendor and Revision
//
gST->Hdr.CRC32 = 0;
gBS->CalculateCrc32 ((VOID *) gST, sizeof (EFI_SYSTEM_TABLE), &gST->Hdr.CRC32);
//
// Validate Variable.
//
BdsFormalizeEfiGlobalVariable ();
//
VOID
InstallFvbProtocol (
IN EFI_FW_VOL_INSTANCE *FwhInstance,
IN UINTN InstanceNum
)
{
EFI_FW_VOL_BLOCK_DEVICE *FvbDevice;
EFI_FIRMWARE_VOLUME_HEADER *FwVolHeader;
EFI_STATUS Status;
EFI_HANDLE FwbHandle;
EFI_FIRMWARE_VOLUME_BLOCK_PROTOCOL *OldFwbInterface;
FvbDevice = (EFI_FW_VOL_BLOCK_DEVICE *) AllocateRuntimeCopyPool (
sizeof (EFI_FW_VOL_BLOCK_DEVICE),
&mFvbDeviceTemplate
);
ASSERT (FvbDevice != NULL);
FvbDevice->Instance = InstanceNum;
FwVolHeader = &FwhInstance->VolumeHeader;
//
// Set up the devicepath.
//
DEBUG ((EFI_D_INFO, "FwBlockService.c: Setting up DevicePath for 0x%lx:\n", FwhInstance->FvBase));
if (FwVolHeader->ExtHeaderOffset == 0) {
//
// FV does not contains extension header, then produce MEMMAP_DEVICE_PATH.
//
FvbDevice->DevicePath = (EFI_DEVICE_PATH_PROTOCOL *) AllocateRuntimeCopyPool (sizeof (FV_MEMMAP_DEVICE_PATH), &mFvMemmapDevicePathTemplate);
((FV_MEMMAP_DEVICE_PATH *) FvbDevice->DevicePath)->MemMapDevPath.StartingAddress = FwhInstance->FvBase;
((FV_MEMMAP_DEVICE_PATH *) FvbDevice->DevicePath)->MemMapDevPath.EndingAddress = FwhInstance->FvBase + FwVolHeader->FvLength - 1;
} else {
FvbDevice->DevicePath = (EFI_DEVICE_PATH_PROTOCOL *) AllocateRuntimeCopyPool (sizeof (FV_PIWG_DEVICE_PATH), &mFvPIWGDevicePathTemplate);
CopyGuid (
&((FV_PIWG_DEVICE_PATH *)FvbDevice->DevicePath)->FvDevPath.FvName,
(GUID *)(UINTN)(FwhInstance->FvBase + FwVolHeader->ExtHeaderOffset)
);
}
//
// Find a handle with a matching device path that has supports FW Block protocol.
//
Status = gBS->LocateDevicePath (
&gEfiFirmwareVolumeBlockProtocolGuid,
&FvbDevice->DevicePath,
&FwbHandle
);
if (EFI_ERROR (Status) ) {
//
// LocateDevicePath fails so install a new interface and device path.
//
DEBUG ((EFI_D_INFO, "FwBlockService.c: LocateDevicePath failed, install new interface 0x%lx:\n", FwhInstance->FvBase));
FwbHandle = NULL;
Status = gBS->InstallMultipleProtocolInterfaces (
&FwbHandle,
&gEfiFirmwareVolumeBlockProtocolGuid,
&FvbDevice->FwVolBlockInstance,
&gEfiDevicePathProtocolGuid,
FvbDevice->DevicePath,
NULL
);
ASSERT_EFI_ERROR (Status);
DEBUG ((EFI_D_INFO, "FwBlockService.c: IMPI FirmwareVolBlockProt, DevPath 0x%lx: %r\n", FwhInstance->FvBase, Status));
} else if (IsDevicePathEnd (FvbDevice->DevicePath)) {
//
// Device allready exists, so reinstall the FVB protocol.
//
DEBUG ((EFI_D_ERROR, "FwBlockService.c: LocateDevicePath succeeded, reinstall interface 0x%lx:\n", FwhInstance->FvBase));
Status = gBS->HandleProtocol (
FwbHandle,
&gEfiFirmwareVolumeBlockProtocolGuid,
(VOID **) &OldFwbInterface
);
ASSERT_EFI_ERROR (Status);
Status = gBS->ReinstallProtocolInterface (
FwbHandle,
&gEfiFirmwareVolumeBlockProtocolGuid,
OldFwbInterface,
&FvbDevice->FwVolBlockInstance
);
ASSERT_EFI_ERROR (Status);
} else {
//
// There was a FVB protocol on an End Device Path node.
//
ASSERT (FALSE);
}
}
/**
Service routine for BdsInstance->Entry(). Devices are connected, the
consoles are initialized, and the boot options are tried.
@param This Protocol Instance structure.
**/
VOID
EFIAPI
BdsEntry (
IN EFI_BDS_ARCH_PROTOCOL *This
)
{
LIST_ENTRY DriverOptionList;
LIST_ENTRY BootOptionList;
UINTN BootNextSize;
CHAR16 *FirmwareVendor;
EFI_STATUS Status;
UINT16 BootTimeOut;
UINTN Index;
EDKII_VARIABLE_LOCK_PROTOCOL *VariableLock;
//
// Insert the performance probe
//
PERF_END (NULL, "DXE", NULL, 0);
PERF_START (NULL, "BDS", NULL, 0);
//
// Initialize the global system boot option and driver option
//
InitializeListHead (&DriverOptionList);
InitializeListHead (&BootOptionList);
//
// Initialize hotkey service
//
InitializeHotkeyService ();
//
// Fill in FirmwareVendor and FirmwareRevision from PCDs
//
FirmwareVendor = (CHAR16 *)PcdGetPtr (PcdFirmwareVendor);
gST->FirmwareVendor = AllocateRuntimeCopyPool (StrSize (FirmwareVendor), FirmwareVendor);
ASSERT (gST->FirmwareVendor != NULL);
gST->FirmwareRevision = PcdGet32 (PcdFirmwareRevision);
//
// Fixup Tasble CRC after we updated Firmware Vendor and Revision
//
gST->Hdr.CRC32 = 0;
gBS->CalculateCrc32 ((VOID *)gST, sizeof(EFI_SYSTEM_TABLE), &gST->Hdr.CRC32);
//
// Validate Variable.
//
BdsFormalizeEfiGlobalVariable();
//
// Mark the read-only variables if the Variable Lock protocol exists
//
Status = gBS->LocateProtocol (&gEdkiiVariableLockProtocolGuid, NULL, (VOID **) &VariableLock);
DEBUG ((EFI_D_INFO, "[BdsDxe] Locate Variable Lock protocol - %r\n", Status));
if (!EFI_ERROR (Status)) {
for (Index = 0; Index < ARRAY_SIZE (mReadOnlyVariables); Index++) {
Status = VariableLock->RequestToLock (VariableLock, mReadOnlyVariables[Index], &gEfiGlobalVariableGuid);
ASSERT_EFI_ERROR (Status);
}
}
//
// Report Status Code to indicate connecting drivers will happen
//
REPORT_STATUS_CODE (
EFI_PROGRESS_CODE,
(EFI_SOFTWARE_DXE_BS_DRIVER | EFI_SW_DXE_BS_PC_BEGIN_CONNECTING_DRIVERS)
);
InitializeHwErrRecSupport();
//
// Initialize L"Timeout" EFI global variable.
//
BootTimeOut = PcdGet16 (PcdPlatformBootTimeOut);
if (BootTimeOut != 0xFFFF) {
//
// If time out value equal 0xFFFF, no need set to 0xFFFF to variable area because UEFI specification
// define same behavior between no value or 0xFFFF value for L"Timeout".
//
BdsDxeSetVariableAndReportStatusCodeOnError (
L"Timeout",
&gEfiGlobalVariableGuid,
EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_NON_VOLATILE,
sizeof (UINT16),
&BootTimeOut
);
}
//
// bugbug: platform specific code
// Initialize the platform specific string and language
//
InitializeStringSupport ();
InitializeLanguage (TRUE);
InitializeFrontPage (TRUE);
//
// Do the platform init, can be customized by OEM/IBV
//
PERF_START (NULL, "PlatformBds", "BDS", 0);
PlatformBdsInit ();
//
// Set up the device list based on EFI 1.1 variables
// process Driver#### and Load the driver's in the
// driver option list
//
BdsLibBuildOptionFromVar (&DriverOptionList, L"DriverOrder");
if (!IsListEmpty (&DriverOptionList)) {
BdsLibLoadDrivers (&DriverOptionList);
}
//
// Check if we have the boot next option
//
mBootNext = BdsLibGetVariableAndSize (
L"BootNext",
&gEfiGlobalVariableGuid,
&BootNextSize
);
//
// Setup some platform policy here
//
PlatformBdsPolicyBehavior (&DriverOptionList, &BootOptionList, BdsProcessCapsules, BdsMemoryTest);
PERF_END (NULL, "PlatformBds", "BDS", 0);
//
// BDS select the boot device to load OS
//
BdsBootDeviceSelect ();
//
// Only assert here since this is the right behavior, we should never
// return back to DxeCore.
//
ASSERT (FALSE);
return ;
}
/**
Service routine for BdsInstance->Entry(). Devices are connected, the
consoles are initialized, and the boot options are tried.
@param This Protocol Instance structure.
**/
VOID
EFIAPI
BdsEntry (
IN EFI_BDS_ARCH_PROTOCOL *This
)
{
LIST_ENTRY DriverOptionList;
LIST_ENTRY BootOptionList;
UINTN BootNextSize;
CHAR16 *FirmwareVendor;
//
// Insert the performance probe
//
PERF_END (NULL, "DXE", NULL, 0);
PERF_START (NULL, "BDS", NULL, 0);
//
// Initialize the global system boot option and driver option
//
InitializeListHead (&DriverOptionList);
InitializeListHead (&BootOptionList);
//
// Initialize hotkey service
//
InitializeHotkeyService ();
//
// Fill in FirmwareVendor and FirmwareRevision from PCDs
//
FirmwareVendor = (CHAR16 *)PcdGetPtr (PcdFirmwareVendor);
gST->FirmwareVendor = AllocateRuntimeCopyPool (StrSize (FirmwareVendor), FirmwareVendor);
ASSERT (gST->FirmwareVendor != NULL);
gST->FirmwareRevision = PcdGet32 (PcdFirmwareRevision);
//
// Fixup Tasble CRC after we updated Firmware Vendor and Revision
//
gBS->CalculateCrc32 ((VOID *)gST, sizeof(EFI_SYSTEM_TABLE), &gST->Hdr.CRC32);
//
// Validate Variable.
//
BdsFormalizeEfiGlobalVariable();
//
// Do the platform init, can be customized by OEM/IBV
//
PERF_START (NULL, "PlatformBds", "BDS", 0);
PlatformBdsInit ();
InitializeHwErrRecSupport();
//
// bugbug: platform specific code
// Initialize the platform specific string and language
//
InitializeStringSupport ();
InitializeLanguage (TRUE);
InitializeFrontPage (TRUE);
//
// Set up the device list based on EFI 1.1 variables
// process Driver#### and Load the driver's in the
// driver option list
//
BdsLibBuildOptionFromVar (&DriverOptionList, L"DriverOrder");
if (!IsListEmpty (&DriverOptionList)) {
BdsLibLoadDrivers (&DriverOptionList);
}
//
// Check if we have the boot next option
//
mBootNext = BdsLibGetVariableAndSize (
L"BootNext",
&gEfiGlobalVariableGuid,
&BootNextSize
);
//
// Setup some platform policy here
//
PlatformBdsPolicyBehavior (&DriverOptionList, &BootOptionList, BdsProcessCapsules, BdsMemoryTest);
PERF_END (NULL, "PlatformBds", "BDS", 0);
//
// BDS select the boot device to load OS
//
BdsBootDeviceSelect ();
//
// Only assert here since this is the right behavior, we should never
// return back to DxeCore.
//
ASSERT (FALSE);
return ;
}