/** @file Obsolete library. Copyright (c) 2006, Intel Corporation All rights reserved. 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. **/ //// EFI_STATUS R8_EfiLibInstallDriverBinding ( IN EFI_HANDLE ImageHandle, IN EFI_SYSTEM_TABLE *SystemTable, IN EFI_DRIVER_BINDING_PROTOCOL *DriverBinding, IN EFI_HANDLE DriverBindingHandle ) /*++ Routine Description: Intialize a driver by installing the Driver Binding Protocol onto the driver's DriverBindingHandle. This is typically the same as the driver's ImageHandle, but it can be different if the driver produces multiple DriverBinding Protocols. This function also initializes the EFI Driver Library that initializes the global variables gST, gBS, gRT. Arguments: ImageHandle - The image handle of the driver SystemTable - The EFI System Table that was passed to the driver's entry point DriverBinding - A Driver Binding Protocol instance that this driver is producing DriverBindingHandle - The handle that DriverBinding is to be installe onto. If this parameter is NULL, then a new handle is created. Returns: EFI_SUCCESS is DriverBinding is installed onto DriverBindingHandle Otherwise, then return status from gBS->InstallProtocolInterface() --*/ { //EfiInitializeDriverLib (ImageHandle, SystemTable); DriverBinding->ImageHandle = ImageHandle; DriverBinding->DriverBindingHandle = DriverBindingHandle; return gBS->InstallProtocolInterface ( &DriverBinding->DriverBindingHandle, &gEfiDriverBindingProtocolGuid, EFI_NATIVE_INTERFACE, DriverBinding ); } ////~ //// EFI_STATUS R8_EfiLibInstallAllDriverProtocols ( IN EFI_HANDLE ImageHandle, IN EFI_SYSTEM_TABLE * SystemTable, IN EFI_DRIVER_BINDING_PROTOCOL * DriverBinding, IN EFI_HANDLE DriverBindingHandle, IN EFI_COMPONENT_NAME_PROTOCOL * ComponentName, OPTIONAL IN EFI_DRIVER_CONFIGURATION_PROTOCOL * DriverConfiguration, OPTIONAL IN EFI_DRIVER_DIAGNOSTICS_PROTOCOL * DriverDiagnostics OPTIONAL ) /*++ Routine Description: Intialize a driver by installing the Driver Binding Protocol onto the driver's DriverBindingHandle. This is typically the same as the driver's ImageHandle, but it can be different if the driver produces multiple DriverBinding Protocols. This function also initializes the EFI Driver Library that initializes the global variables gST, gBS, gRT. Arguments: ImageHandle - The image handle of the driver SystemTable - The EFI System Table that was passed to the driver's entry point DriverBinding - A Driver Binding Protocol instance that this driver is producing DriverBindingHandle - The handle that DriverBinding is to be installe onto. If this parameter is NULL, then a new handle is created. ComponentName - A Component Name Protocol instance that this driver is producing DriverConfiguration - A Driver Configuration Protocol instance that this driver is producing DriverDiagnostics - A Driver Diagnostics Protocol instance that this driver is producing Returns: EFI_SUCCESS if all the protocols were installed onto DriverBindingHandle Otherwise, then return status from gBS->InstallProtocolInterface() --*/ { EFI_STATUS Status; Status = R8_EfiLibInstallDriverBinding (ImageHandle, SystemTable, DriverBinding, DriverBindingHandle); if (EFI_ERROR (Status)) { return Status; } if (ComponentName != NULL) { Status = gBS->InstallProtocolInterface ( &DriverBinding->DriverBindingHandle, &gEfiComponentNameProtocolGuid, EFI_NATIVE_INTERFACE, ComponentName ); if (EFI_ERROR (Status)) { return Status; } } if (DriverConfiguration != NULL) { Status = gBS->InstallProtocolInterface ( &DriverBinding->DriverBindingHandle, &gEfiDriverConfigurationProtocolGuid, EFI_NATIVE_INTERFACE, DriverConfiguration ); if (EFI_ERROR (Status)) { return Status; } } if (DriverDiagnostics != NULL) { Status = gBS->InstallProtocolInterface ( &DriverBinding->DriverBindingHandle, &gEfiDriverDiagnosticsProtocolGuid, EFI_NATIVE_INTERFACE, DriverDiagnostics ); if (EFI_ERROR (Status)) { return Status; } } return EFI_SUCCESS; } ////~ //// BOOLEAN R8_EfiLibCompareLanguage ( IN CHAR8 *Language1, IN CHAR8 *Language2 ) /*++ Routine Description: Compare whether two names of languages are identical. Arguments: Language1 - Name of language 1 Language2 - Name of language 2 Returns: TRUE - same FALSE - not same --*/ { UINTN Index; for (Index = 0; Index < 3; Index++) { if (Language1[Index] != Language2[Index]) { return FALSE; } } return TRUE; } ////~ ////#BaseLib EFI_STATUS R8_BufToHexString ( IN OUT CHAR16 *Str, IN OUT UINTN *HexStringBufferLength, IN UINT8 *Buf, IN UINTN Len ) /*++ Routine Description: Converts binary buffer to Unicode string. At a minimum, any blob of data could be represented as a hex string. Arguments: Str - Pointer to the string. HexStringBufferLength - Length in bytes of buffer to hold the hex string. Includes tailing '\0' character. If routine return with EFI_SUCCESS, containing length of hex string buffer. If routine return with EFI_BUFFER_TOO_SMALL, containg length of hex string buffer desired. Buf - Buffer to be converted from. Len - Length in bytes of the buffer to be converted. Returns: EFI_SUCCESS: Routine success. EFI_BUFFER_TOO_SMALL: The hex string buffer is too small. --*/ { UINTN Idx; UINT8 Byte; UINTN StrLen; // // Make sure string is either passed or allocate enough. // It takes 2 Unicode characters (4 bytes) to represent 1 byte of the binary buffer. // Plus the Unicode termination character. // StrLen = Len * 2; if (StrLen > ((*HexStringBufferLength) - 1)) { *HexStringBufferLength = StrLen + 1; return EFI_BUFFER_TOO_SMALL; } *HexStringBufferLength = StrLen + 1; // // Ends the string. // Str[StrLen] = L'\0'; for (Idx = 0; Idx < Len; Idx++) { Byte = Buf[Idx]; Str[StrLen - 1 - Idx * 2] = NibbleToHexChar (Byte); Str[StrLen - 2 - Idx * 2] = NibbleToHexChar ((UINT8)(Byte >> 4)); } return EFI_SUCCESS; } ////~ //// VOID R8_EfiStrTrim ( IN OUT CHAR16 *str, IN CHAR16 CharC ) /*++ Routine Description: Removes (trims) specified leading and trailing characters from a string. Arguments: str - Pointer to the null-terminated string to be trimmed. On return, str will hold the trimmed string. CharC - Character will be trimmed from str. Returns: --*/ { CHAR16 *p1; CHAR16 *p2; if (*str == 0) { return; } // // Trim off the leading and trailing characters c // for (p1 = str; *p1 && *p1 == CharC; p1++) { ; } p2 = str; if (p2 == p1) { while (*p1) { p2++; p1++; } } else { while (*p1) { *p2 = *p1; p1++; p2++; } *p2 = 0; } for (p1 = str + StrLen(str) - 1; p1 >= str && *p1 == CharC; p1--) { ; } if (p1 != str + StrLen(str) - 1) { *(p1 + 1) = 0; } } ////~ ////#PrintLib UINTN R8_EfiValueToHexStr ( IN OUT CHAR16 *Buffer, IN UINT64 Value, IN UINTN Flags, IN UINTN Width ) /*++ Routine Description: VSPrint worker function that prints a Value as a hex number in Buffer Arguments: Buffer - Location to place ascii hex string of Value. Value - Hex value to convert to a string in Buffer. Flags - Flags to use in printing Hex string, see file header for details. Width - Width of hex value. Returns: Number of characters printed. --*/ { CHAR16 TempBuffer[MAXIMUM_VALUE_CHARACTERS]; CHAR16 *TempStr; CHAR16 Prefix; CHAR16 *BufferPtr; UINTN Count; UINTN Index; TempStr = TempBuffer; BufferPtr = Buffer; // // Count starts at one since we will null terminate. Each iteration of the // loop picks off one nibble. Oh yea TempStr ends up backwards // Count = 0; if (Width > MAXIMUM_VALUE_CHARACTERS - 1) { Width = MAXIMUM_VALUE_CHARACTERS - 1; } do { // // If Width == 0, it means no limit. // if ((Width != 0) && (Count >= Width)) { break; } Index = ((UINTN)Value & 0xf); *(TempStr++) = mHexStr[Index]; Value = RShiftU64 (Value, 4); Count++; } while (Value != 0); if (Flags & PREFIX_ZERO) { Prefix = '0'; } else { Prefix = ' '; } Index = Count; if (!(Flags & LEFT_JUSTIFY)) { for (; Index < Width; Index++) { *(TempStr++) = Prefix; } } // // Reverse temp string into Buffer. // while (TempStr != TempBuffer) { *(BufferPtr++) = *(--TempStr); } *BufferPtr = 0; return Index; } ////~ //// EFI_STATUS R8_HexStringToBuf ( IN OUT UINT8 *Buf, IN OUT UINTN *Len, IN CHAR16 *Str, OUT UINTN *ConvertedStrLen OPTIONAL ) /*++ Routine Description: Converts Unicode string to binary buffer. The conversion may be partial. The first character in the string that is not hex digit stops the conversion. At a minimum, any blob of data could be represented as a hex string. Arguments: Buf - Pointer to buffer that receives the data. Len - Length in bytes of the buffer to hold converted data. If routine return with EFI_SUCCESS, containing length of converted data. If routine return with EFI_BUFFER_TOO_SMALL, containg length of buffer desired. Str - String to be converted from. ConvertedStrLen - Length of the Hex String consumed. Returns: EFI_SUCCESS: Routine Success. EFI_BUFFER_TOO_SMALL: The buffer is too small to hold converted data. EFI_ --*/ { UINTN HexCnt; UINTN Idx; UINTN BufferLength; UINT8 Digit; UINT8 Byte; // // Find out how many hex characters the string has. // for (Idx = 0, HexCnt = 0; IsHexDigit (&Digit, Str[Idx]); Idx++, HexCnt++); if (HexCnt == 0) { *Len = 0; return EFI_SUCCESS; } // // Two Unicode characters make up 1 buffer byte. Round up. // BufferLength = (HexCnt + 1) / 2; // // Test if buffer is passed enough. // if (BufferLength > (*Len)) { *Len = BufferLength; return EFI_BUFFER_TOO_SMALL; } *Len = BufferLength; for (Idx = 0; Idx < HexCnt; Idx++) { IsHexDigit (&Digit, Str[HexCnt - 1 - Idx]); // // For odd charaters, write the lower nibble for each buffer byte, // and for even characters, the upper nibble. // if ((Idx & 1) == 0) { Byte = Digit; } else { Byte = Buf[Idx / 2]; Byte &= 0x0F; Byte |= Digit << 4; } Buf[Idx / 2] = Byte; } if (ConvertedStrLen != NULL) { *ConvertedStrLen = HexCnt; } return EFI_SUCCESS; } ////~ //// BOOLEAN R8_IsHexDigit ( OUT UINT8 *Digit, IN CHAR16 Char ) /*++ Routine Description: Determines if a Unicode character is a hexadecimal digit. The test is case insensitive. Arguments: Digit - Pointer to byte that receives the value of the hex character. Char - Unicode character to test. Returns: TRUE - If the character is a hexadecimal digit. FALSE - Otherwise. --*/ { if ((Char >= L'0') && (Char <= L'9')) { *Digit = (UINT8) (Char - L'0'); return TRUE; } if ((Char >= L'A') && (Char <= L'F')) { *Digit = (UINT8) (Char - L'A' + 0x0A); return TRUE; } if ((Char >= L'a') && (Char <= L'f')) { *Digit = (UINT8) (Char - L'a' + 0x0A); return TRUE; } return FALSE; } ////~ //// CHAR16 R8_NibbleToHexChar ( IN UINT8 Nibble ) /*++ Routine Description: Converts the low nibble of a byte to hex unicode character. Arguments: Nibble - lower nibble of a byte. Returns: Hex unicode character. --*/ { Nibble &= 0x0F; if (Nibble <= 0x9) { return (CHAR16)(Nibble + L'0'); } return (CHAR16)(Nibble - 0xA + L'A'); } ////~ ////#HobLib VOID * R8_GetHob ( IN UINT16 Type, IN VOID *HobStart ) /*++ Routine Description: This function returns the first instance of a HOB type in a HOB list. Arguments: Type The HOB type to return. HobStart The first HOB in the HOB list. Returns: HobStart There were no HOBs found with the requested type. else Returns the first HOB with the matching type. --*/ { VOID *Hob; // // Return input if not found // if (HobStart == NULL) { return HobStart; } Hob = GetNextHob (Type, HobStart); if (Hob == NULL) { return HobStart; } return Hob; } ////~ //// UINTN R8_GetHobListSize ( IN VOID *HobStart ) /*++ Routine Description: Get size of hob list. Arguments: HobStart - Start pointer of hob list Returns: Size of hob list. --*/ { EFI_PEI_HOB_POINTERS Hob; UINTN Size; Hob.Raw = HobStart; Size = 0; while (Hob.Header->HobType != EFI_HOB_TYPE_END_OF_HOB_LIST) { Size += Hob.Header->HobLength; Hob.Raw += Hob.Header->HobLength; } Size += Hob.Header->HobLength; return Size; } ////~ //// UINT32 R8_GetHobVersion ( IN VOID *HobStart ) /*++ Routine Description: Get hob version. Arguments: HobStart - Start pointer of hob list Returns: Hob version. --*/ { EFI_PEI_HOB_POINTERS Hob; Hob.Raw = HobStart; return Hob.HandoffInformationTable->Version; } ////~ //// EFI_STATUS R8_GetHobBootMode ( IN VOID *HobStart, OUT EFI_BOOT_MODE *BootMode ) /*++ Routine Description: Get current boot mode. Arguments: HobStart - Start pointer of hob list BootMode - Current boot mode recorded in PHIT hob Returns: EFI_NOT_FOUND - Invalid hob header EFI_SUCCESS - Boot mode found --*/ { EFI_PEI_HOB_POINTERS Hob; Hob.Raw = HobStart; if (Hob.Header->HobType != EFI_HOB_TYPE_HANDOFF) { return EFI_NOT_FOUND; } *BootMode = Hob.HandoffInformationTable->BootMode; return EFI_SUCCESS; } ////~ ////#HobLib EFI_STATUS R8_GetCpuHobInfo ( IN VOID *HobStart, OUT UINT8 *SizeOfMemorySpace, OUT UINT8 *SizeOfIoSpace ) /*++ Routine Description: Get information recorded in CPU hob (Memory space size, Io space size) Arguments: HobStart - Start pointer of hob list SizeOfMemorySpace - Size of memory size SizeOfIoSpace - Size of IO size Returns: EFI_NOT_FOUND - CPU hob not found EFI_SUCCESS - CPU hob found and information got. --*/ { EFI_HOB_CPU *CpuHob; CpuHob = GetHob (EFI_HOB_TYPE_CPU, HobStart); if (CpuHob == NULL) { return EFI_NOT_FOUND; } *SizeOfMemorySpace = CpuHob->SizeOfMemorySpace; *SizeOfIoSpace = CpuHob->SizeOfIoSpace; return EFI_SUCCESS; } ////~ ////#HobLib EFI_STATUS R8_GetDxeCoreHobInfo ( IN VOID *HobStart, OUT EFI_PHYSICAL_ADDRESS *BaseAddress, OUT UINT64 *Length, OUT VOID **EntryPoint, OUT EFI_GUID **FileName ) /*++ Routine Description: Get memory allocation hob created for DXE core and extract its information Arguments: HobStart - Start pointer of the hob list BaseAddress - Start address of memory allocated for DXE core Length - Length of memory allocated for DXE core EntryPoint - DXE core file name FileName - File Name Returns: EFI_NOT_FOUND - DxeCoreHob not found EFI_SUCCESS - DxeCoreHob found and information got --*/ { EFI_PEI_HOB_POINTERS DxeCoreHob; DxeCoreHob.Raw = HobStart; DxeCoreHob.Raw = GetHob (EFI_HOB_TYPE_MEMORY_ALLOCATION, DxeCoreHob.Raw); while (DxeCoreHob.Header->HobType == EFI_HOB_TYPE_MEMORY_ALLOCATION && !EfiCompareGuid (&DxeCoreHob.MemoryAllocationModule->MemoryAllocationHeader.Name, &gEfiHobMemeryAllocModuleGuid)) { DxeCoreHob.Raw = GET_NEXT_HOB (DxeCoreHob); DxeCoreHob.Raw = GetHob (EFI_HOB_TYPE_MEMORY_ALLOCATION, DxeCoreHob.Raw); } if (DxeCoreHob.Header->HobType != EFI_HOB_TYPE_MEMORY_ALLOCATION) { return EFI_NOT_FOUND; } *BaseAddress = DxeCoreHob.MemoryAllocationModule->MemoryAllocationHeader.MemoryBaseAddress; *Length = DxeCoreHob.MemoryAllocationModule->MemoryAllocationHeader.MemoryLength; *EntryPoint = (VOID *) (UINTN) DxeCoreHob.MemoryAllocationModule->EntryPoint; *FileName = &DxeCoreHob.MemoryAllocationModule->ModuleName; return EFI_SUCCESS; } ////~ ////#HobLib EFI_STATUS R8_GetNextFirmwareVolumeHob ( IN OUT VOID **HobStart, OUT EFI_PHYSICAL_ADDRESS *BaseAddress, OUT UINT64 *Length ) /*++ Routine Description: Get next firmware volume hob from HobStart Arguments: HobStart - Start pointer of hob list BaseAddress - Start address of next firmware volume Length - Length of next firmware volume Returns: EFI_NOT_FOUND - Next firmware volume not found EFI_SUCCESS - Next firmware volume found with address information --*/ { EFI_PEI_HOB_POINTERS FirmwareVolumeHob; FirmwareVolumeHob.Raw = GetNextHob (EFI_HOB_TYPE_FV, *HobStart); if (FirmwareVolumeHob.Raw != NULL) { return EFI_NOT_FOUND; } *BaseAddress = FirmwareVolumeHob.FirmwareVolume->BaseAddress; *Length = FirmwareVolumeHob.FirmwareVolume->Length; *HobStart = GET_NEXT_HOB (FirmwareVolumeHob); return EFI_SUCCESS; } ////~ ////#HobLib EFI_STATUS R8_GetNextGuidHob ( IN OUT VOID **HobStart, IN EFI_GUID * Guid, OUT VOID **Buffer, OUT UINTN *BufferSize OPTIONAL ) /*++ Routine Description: Get the next guid hob. Arguments: HobStart A pointer to the start hob. Guid A pointer to a guid. Buffer A pointer to the buffer. BufferSize Buffer size. Returns: Status code. EFI_NOT_FOUND - Next Guid hob not found EFI_SUCCESS - Next Guid hob found and data for this Guid got EFI_INVALID_PARAMETER - invalid parameter --*/ { EFI_PEI_HOB_POINTERS GuidHob; if (Buffer == NULL) { return EFI_INVALID_PARAMETER; } GuidHob.Raw = GetNextGuidHob (Guid, *HobStart); if (GuidHob == NULL) { return EFI_NOT_FOUND; } *Buffer = GET_GUID_HOB_DATA (GuidHob.Guid); if (BufferSize != NULL) { *BufferSize = GET_GUID_HOB_DATA_SIZE (GuidHob.Guid); } *HobStart = GET_NEXT_HOB (GuidHob); return EFI_SUCCESS; } ////~ ////#HobLib EFI_STATUS R8_GetPalEntryHobInfo ( IN VOID *HobStart, OUT EFI_PHYSICAL_ADDRESS *PalEntry ) /*++ Routine Description: Get PAL entry from PalEntryHob Arguments: HobStart - Start pointer of hob list PalEntry - Pointer to PAL entry Returns: Status code. --*/ { EFI_HOB_GUID_TYPE *GuidHob; GuidHob = GetNextGuidHob (&gPalEntryHob, HobStart); if (GuidHob == NULL) { return EFI_NOT_FOUND; } *PalEntry = *((EFI_PHYSICAL_ADDRESS *) GET_GUID_HOB_DATA (GuidHob)); return EFI_SUCCESS; } ////~ ////#HobLib EFI_STATUS R8_GetIoPortSpaceAddressHobInfo ( IN VOID *HobStart, OUT EFI_PHYSICAL_ADDRESS *IoPortSpaceAddress ) /*++ Routine Description: Get IO port space address from IoBaseHob. Arguments: HobStart - Start pointer of hob list IoPortSpaceAddress - IO port space address Returns: Status code --*/ { EFI_HOB_GUID_TYPE *GuidHob; GuidHob = GetNextGuidHob (&gEfiIoBaseHobGuid, HobStart); if (GuidHob == NULL) { return EFI_NOT_FOUND; } *IoPortSpaceAddress = *((EFI_PHYSICAL_ADDRESS *) GET_GUID_HOB_DATA (GuidHob)); return EFI_SUCCESS; } ////~