/*++ Copyright (c) 1998 Intel Corporation Module Name: misc.c Abstract: Revision History --*/ #include "lib.h" // // // VOID * AllocatePool ( IN UINTN Size ) { EFI_STATUS Status; VOID *p; Status = uefi_call_wrapper(BS->AllocatePool, 3, PoolAllocationType, Size, &p); if (EFI_ERROR(Status)) { DEBUG((D_ERROR, "AllocatePool: out of pool %x\n", Status)); p = NULL; } return p; } VOID * AllocateZeroPool ( IN UINTN Size ) { VOID *p; p = AllocatePool (Size); if (p) { ZeroMem (p, Size); } return p; } VOID * EFIAPI ReallocatePool_1 ( IN UINTN OldSize, IN UINTN NewSize, IN VOID *OldPool OPTIONAL ) { VOID *NewPool; NewPool = NULL; if (NewSize) { NewPool = AllocatePool (NewSize); } if (OldPool) { if (NewPool) { CopyMem (NewPool, OldPool, OldSize < NewSize ? OldSize : NewSize); } FreePool (OldPool); } return NewPool; } VOID FreePool ( IN VOID *Buffer ) { uefi_call_wrapper(BS->FreePool, 1, Buffer); } VOID ZeroMem ( IN VOID *Buffer, IN UINTN Size ) { RtZeroMem (Buffer, Size); } VOID EFIAPI SetMem ( IN VOID *Buffer, IN UINTN Size, IN UINT8 Value ) { RtSetMem (Buffer, Size, Value); } VOID EFIAPI CopyMem_1 ( IN VOID *Dest, IN VOID *Src, IN UINTN len ) { RtCopyMem (Dest, Src, len); } VOID EFIAPI CopyMemC ( IN VOID *Dest, IN CONST VOID *Src, IN UINTN len ) { RtCopyMemC (Dest, Src, len); } INTN CompareMem ( IN CONST VOID *Dest, IN CONST VOID *Src, IN UINTN len ) { return RtCompareMem (Dest, Src, len); } BOOLEAN GrowBuffer( IN OUT EFI_STATUS *Status, IN OUT VOID **Buffer, IN UINTN BufferSize ) /*++ Routine Description: Helper function called as part of the code needed to allocate the proper sized buffer for various EFI interfaces. Arguments: Status - Current status Buffer - Current allocated buffer, or NULL BufferSize - Current buffer size needed Returns: TRUE - if the buffer was reallocated and the caller should try the API again. --*/ { BOOLEAN TryAgain; // // If this is an initial request, buffer will be null with a new buffer size // if (!*Buffer && BufferSize) { *Status = EFI_BUFFER_TOO_SMALL; } // // If the status code is "buffer too small", resize the buffer // TryAgain = FALSE; if (*Status == EFI_BUFFER_TOO_SMALL) { if (*Buffer) { FreePool (*Buffer); } *Buffer = AllocatePool (BufferSize); if (*Buffer) { TryAgain = TRUE; } else { *Status = EFI_OUT_OF_RESOURCES; } } // // If there's an error, free the buffer // if (!TryAgain && EFI_ERROR(*Status) && *Buffer) { FreePool (*Buffer); *Buffer = NULL; } return TryAgain; } EFI_MEMORY_DESCRIPTOR * LibMemoryMap ( OUT UINTN *NoEntries, OUT UINTN *MapKey, OUT UINTN *DescriptorSize, OUT UINT32 *DescriptorVersion ) { EFI_STATUS Status; EFI_MEMORY_DESCRIPTOR *Buffer; UINTN BufferSize; // // Initialize for GrowBuffer loop // Status = EFI_SUCCESS; Buffer = NULL; BufferSize = sizeof(EFI_MEMORY_DESCRIPTOR); // // Call the real function // while (GrowBuffer (&Status, (VOID **) &Buffer, BufferSize)) { Status = uefi_call_wrapper(BS->GetMemoryMap, 5, &BufferSize, Buffer, MapKey, DescriptorSize, DescriptorVersion); } // // Convert buffer size to NoEntries // if (!EFI_ERROR(Status)) { *NoEntries = BufferSize / *DescriptorSize; } return Buffer; } VOID * LibGetVariableAndSize ( IN CHAR16 *Name, IN EFI_GUID *VendorGuid, OUT UINTN *VarSize ) { EFI_STATUS Status = EFI_SUCCESS; VOID *Buffer; UINTN BufferSize; // // Initialize for GrowBuffer loop // Buffer = NULL; BufferSize = 100; // // Call the real function // while (GrowBuffer (&Status, &Buffer, BufferSize)) { Status = uefi_call_wrapper( RT->GetVariable, 5, Name, VendorGuid, NULL, &BufferSize, Buffer ); } if (Buffer) { *VarSize = BufferSize; } else { *VarSize = 0; } return Buffer; } VOID * LibGetVariable ( IN CHAR16 *Name, IN EFI_GUID *VendorGuid ) { UINTN VarSize; return LibGetVariableAndSize (Name, VendorGuid, &VarSize); } EFI_STATUS LibDeleteVariable ( IN CHAR16 *VarName, IN EFI_GUID *VarGuid ) { VOID *VarBuf; EFI_STATUS Status; VarBuf = LibGetVariable(VarName,VarGuid); Status = EFI_NOT_FOUND; if (VarBuf) { // // Delete variable from Storage // Status = uefi_call_wrapper( RT->SetVariable, 5, VarName, VarGuid, EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_NON_VOLATILE, 0, NULL ); ASSERT (!EFI_ERROR(Status)); FreePool(VarBuf); } return (Status); } EFI_STATUS LibSetNVVariable ( IN CHAR16 *VarName, IN EFI_GUID *VarGuid, IN UINTN DataSize, IN VOID *Data ) { EFI_STATUS Status; Status = uefi_call_wrapper( RT->SetVariable, 5, VarName, VarGuid, EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_NON_VOLATILE, DataSize, Data ); ASSERT (!EFI_ERROR(Status)); return (Status); } EFI_STATUS LibSetVariable ( IN CHAR16 *VarName, IN EFI_GUID *VarGuid, IN UINTN DataSize, IN VOID *Data ) { EFI_STATUS Status; Status = uefi_call_wrapper( RT->SetVariable, 5, VarName, VarGuid, EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS, DataSize, Data ); ASSERT (!EFI_ERROR(Status)); return (Status); } EFI_STATUS LibInsertToTailOfBootOrder ( IN UINT16 BootOption, IN BOOLEAN OnlyInsertIfEmpty ) { UINT16 *BootOptionArray; UINT16 *NewBootOptionArray; UINTN VarSize; UINTN Index; EFI_STATUS Status; BootOptionArray = LibGetVariableAndSize (VarBootOrder, &EfiGlobalVariable, &VarSize); if (VarSize != 0 && OnlyInsertIfEmpty) { if (BootOptionArray) { FreePool (BootOptionArray); } return EFI_UNSUPPORTED; } VarSize += sizeof(UINT16); NewBootOptionArray = AllocatePool (VarSize); if (!NewBootOptionArray) return EFI_OUT_OF_RESOURCES; for (Index = 0; Index < ((VarSize/sizeof(UINT16)) - 1); Index++) { NewBootOptionArray[Index] = BootOptionArray[Index]; } // // Insert in the tail of the array // NewBootOptionArray[Index] = BootOption; Status = uefi_call_wrapper( RT->SetVariable, 5, VarBootOrder, &EfiGlobalVariable, EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_NON_VOLATILE, VarSize, (VOID*) NewBootOptionArray ); FreePool (NewBootOptionArray); if (BootOptionArray) { FreePool (BootOptionArray); } return Status; } BOOLEAN ValidMBR( IN MASTER_BOOT_RECORD *Mbr, IN EFI_BLOCK_IO *BlkIo ) { UINT32 StartingLBA, EndingLBA; UINT32 NewEndingLBA; INTN i, j; BOOLEAN ValidMbr; if (Mbr->Signature != MBR_SIGNATURE) { // // The BPB also has this signature, so it can not be used alone. // return FALSE; } ValidMbr = FALSE; for (i=0; iPartition[i].OSIndicator == 0x00 || EXTRACT_UINT32(Mbr->Partition[i].SizeInLBA) == 0 ) { continue; } ValidMbr = TRUE; StartingLBA = EXTRACT_UINT32(Mbr->Partition[i].StartingLBA); EndingLBA = StartingLBA + EXTRACT_UINT32(Mbr->Partition[i].SizeInLBA) - 1; if (EndingLBA > BlkIo->Media->LastBlock) { // // Compatability Errata: // Some systems try to hide drive space with thier INT 13h driver // This does not hide space from the OS driver. This means the MBR // that gets created from DOS is smaller than the MBR created from // a real OS (NT & Win98). This leads to BlkIo->LastBlock being // wrong on some systems FDISKed by the OS. // // if (BlkIo->Media->LastBlock < MIN_MBR_DEVICE_SIZE) { // // If this is a very small device then trust the BlkIo->LastBlock // return FALSE; } if (EndingLBA > (BlkIo->Media->LastBlock + MBR_ERRATA_PAD)) { return FALSE; } } for (j=i+1; jPartition[j].OSIndicator == 0x00 || EXTRACT_UINT32(Mbr->Partition[j].SizeInLBA) == 0) { continue; } if ( EXTRACT_UINT32(Mbr->Partition[j].StartingLBA) >= StartingLBA && EXTRACT_UINT32(Mbr->Partition[j].StartingLBA) <= EndingLBA ) { // // The Start of this region overlaps with the i'th region // return FALSE; } NewEndingLBA = EXTRACT_UINT32(Mbr->Partition[j].StartingLBA) + EXTRACT_UINT32(Mbr->Partition[j].SizeInLBA) - 1; if ( NewEndingLBA >= StartingLBA && NewEndingLBA <= EndingLBA ) { // // The End of this region overlaps with the i'th region // return FALSE; } } } // // Non of the regions overlapped so MBR is O.K. // return ValidMbr; } UINT8 DecimaltoBCD( IN UINT8 DecValue ) { return RtDecimaltoBCD (DecValue); } UINT8 BCDtoDecimal( IN UINT8 BcdValue ) { return RtBCDtoDecimal (BcdValue); } EFI_STATUS LibGetSystemConfigurationTable( IN EFI_GUID *TableGuid, IN OUT VOID **Table ) { UINTN Index; for(Index=0;IndexNumberOfTableEntries;Index++) { if (CompareGuid(TableGuid,&(ST->ConfigurationTable[Index].VendorGuid))==0) { *Table = ST->ConfigurationTable[Index].VendorTable; return EFI_SUCCESS; } } return EFI_NOT_FOUND; } CHAR16 * LibGetUiString ( IN EFI_HANDLE Handle, IN UI_STRING_TYPE StringType, IN ISO_639_2 *LangCode, IN BOOLEAN ReturnDevicePathStrOnMismatch ) { UI_INTERFACE *Ui; UI_STRING_TYPE Index; UI_STRING_ENTRY *Array; EFI_STATUS Status; Status = uefi_call_wrapper(BS->HandleProtocol, 3, Handle, &UiProtocol, (VOID *)&Ui); if (EFI_ERROR(Status)) { return (ReturnDevicePathStrOnMismatch) ? DevicePathToStr(DevicePathFromHandle(Handle)) : NULL; } // // Skip the first strings // for (Index = UiDeviceString, Array = Ui->Entry; Index < StringType; Index++, Array++) { while (Array->LangCode) { Array++; } } // // Search for the match // while (Array->LangCode) { if (strcmpa (Array->LangCode, LangCode) == 0) { return Array->UiString; } } return (ReturnDevicePathStrOnMismatch) ? DevicePathToStr(DevicePathFromHandle(Handle)) : NULL; }