/** @file NorFlashDxe.c Copyright (c) 2011 - 2014, ARM Ltd. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent **/ #include #include #include #include #include #include "NorFlashDxe.h" STATIC EFI_EVENT mNorFlashVirtualAddrChangeEvent; // // Global variable declarations // NOR_FLASH_INSTANCE **mNorFlashInstances; UINT32 mNorFlashDeviceCount; NOR_FLASH_INSTANCE mNorFlashInstanceTemplate = { NOR_FLASH_SIGNATURE, // Signature NULL, // Handle ... NEED TO BE FILLED 0, // DeviceBaseAddress ... NEED TO BE FILLED 0, // RegionBaseAddress ... NEED TO BE FILLED 0, // Size ... NEED TO BE FILLED 0, // StartLba { EFI_BLOCK_IO_PROTOCOL_REVISION2, // Revision NULL, // Media ... NEED TO BE FILLED NorFlashBlockIoReset, // Reset; NorFlashBlockIoReadBlocks, // ReadBlocks NorFlashBlockIoWriteBlocks, // WriteBlocks NorFlashBlockIoFlushBlocks // FlushBlocks }, // BlockIoProtocol { 0, // MediaId ... NEED TO BE FILLED FALSE, // RemovableMedia TRUE, // MediaPresent FALSE, // LogicalPartition FALSE, // ReadOnly FALSE, // WriteCaching; 0, // BlockSize ... NEED TO BE FILLED 4, // IoAlign 0, // LastBlock ... NEED TO BE FILLED 0, // LowestAlignedLba 1, // LogicalBlocksPerPhysicalBlock }, //Media; { EFI_DISK_IO_PROTOCOL_REVISION, // Revision NorFlashDiskIoReadDisk, // ReadDisk NorFlashDiskIoWriteDisk // WriteDisk }, { FvbGetAttributes, // GetAttributes FvbSetAttributes, // SetAttributes FvbGetPhysicalAddress, // GetPhysicalAddress FvbGetBlockSize, // GetBlockSize FvbRead, // Read FvbWrite, // Write FvbEraseBlocks, // EraseBlocks NULL, //ParentHandle }, // FvbProtoccol; NULL, // ShadowBuffer { { { HARDWARE_DEVICE_PATH, HW_VENDOR_DP, { (UINT8)(OFFSET_OF (NOR_FLASH_DEVICE_PATH, End)), (UINT8)(OFFSET_OF (NOR_FLASH_DEVICE_PATH, End) >> 8) } }, { 0x0, 0x0, 0x0, { 0x0, 0x0, 0x0, 0x0, 0x0, 0x0, 0x0, 0x0 } }, // GUID ... NEED TO BE FILLED }, 0, // Index { END_DEVICE_PATH_TYPE, END_ENTIRE_DEVICE_PATH_SUBTYPE, { sizeof (EFI_DEVICE_PATH_PROTOCOL), 0 } } } // DevicePath }; EFI_STATUS NorFlashCreateInstance ( IN UINTN NorFlashDeviceBase, IN UINTN NorFlashRegionBase, IN UINTN NorFlashSize, IN UINT32 Index, IN UINT32 BlockSize, IN BOOLEAN SupportFvb, 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 = Index; Instance->Media.BlockSize = BlockSize; Instance->Media.LastBlock = (NorFlashSize / BlockSize)-1; CopyGuid (&Instance->DevicePath.Vendor.Guid, &gEfiCallerIdGuid); Instance->DevicePath.Index = (UINT8)Index; Instance->ShadowBuffer = AllocateRuntimePool (BlockSize);; if (Instance->ShadowBuffer == NULL) { return EFI_OUT_OF_RESOURCES; } if (SupportFvb) { NorFlashFvbInitialize (Instance); Status = gBS->InstallMultipleProtocolInterfaces ( &Instance->Handle, &gEfiDevicePathProtocolGuid, &Instance->DevicePath, &gEfiBlockIoProtocolGuid, &Instance->BlockIoProtocol, &gEfiFirmwareVolumeBlockProtocolGuid, &Instance->FvbProtocol, NULL ); if (EFI_ERROR(Status)) { FreePool (Instance); return Status; } } else { 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; } UINT32 NorFlashReadStatusRegister ( IN NOR_FLASH_INSTANCE *Instance, IN UINTN SR_Address ) { // Prepare to read the status register SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_READ_STATUS_REGISTER); return MmioRead32 (Instance->DeviceBaseAddress); } STATIC BOOLEAN NorFlashBlockIsLocked ( IN NOR_FLASH_INSTANCE *Instance, IN UINTN BlockAddress ) { UINT32 LockStatus; // Send command for reading device id SEND_NOR_COMMAND (BlockAddress, 2, P30_CMD_READ_DEVICE_ID); // Read block lock status LockStatus = MmioRead32 (CREATE_NOR_ADDRESS(BlockAddress, 2)); // Decode block lock status LockStatus = FOLD_32BIT_INTO_16BIT(LockStatus); if ((LockStatus & 0x2) != 0) { DEBUG((EFI_D_ERROR, "NorFlashBlockIsLocked: WARNING: Block LOCKED DOWN\n")); } return ((LockStatus & 0x1) != 0); } STATIC EFI_STATUS NorFlashUnlockSingleBlock ( IN NOR_FLASH_INSTANCE *Instance, IN UINTN BlockAddress ) { UINT32 LockStatus; // Raise the Task Priority Level to TPL_NOTIFY to serialise all its operations // and to protect shared data structures. if (FeaturePcdGet (PcdNorFlashCheckBlockLocked) == TRUE) { do { // Request a lock setup SEND_NOR_COMMAND (BlockAddress, 0, P30_CMD_LOCK_BLOCK_SETUP); // Request an unlock SEND_NOR_COMMAND (BlockAddress, 0, P30_CMD_UNLOCK_BLOCK); // Send command for reading device id SEND_NOR_COMMAND (BlockAddress, 2, P30_CMD_READ_DEVICE_ID); // Read block lock status LockStatus = MmioRead32 (CREATE_NOR_ADDRESS(BlockAddress, 2)); // Decode block lock status LockStatus = FOLD_32BIT_INTO_16BIT(LockStatus); } while ((LockStatus & 0x1) == 1); } else { // Request a lock setup SEND_NOR_COMMAND (BlockAddress, 0, P30_CMD_LOCK_BLOCK_SETUP); // Request an unlock SEND_NOR_COMMAND (BlockAddress, 0, P30_CMD_UNLOCK_BLOCK); // Wait until the status register gives us the all clear do { LockStatus = NorFlashReadStatusRegister (Instance, BlockAddress); } while ((LockStatus & P30_SR_BIT_WRITE) != P30_SR_BIT_WRITE); } // Put device back into Read Array mode SEND_NOR_COMMAND (BlockAddress, 0, P30_CMD_READ_ARRAY); DEBUG((DEBUG_BLKIO, "UnlockSingleBlock: BlockAddress=0x%08x\n", BlockAddress)); return EFI_SUCCESS; } STATIC EFI_STATUS NorFlashUnlockSingleBlockIfNecessary ( IN NOR_FLASH_INSTANCE *Instance, IN UINTN BlockAddress ) { EFI_STATUS Status; Status = EFI_SUCCESS; if (NorFlashBlockIsLocked (Instance, BlockAddress) == TRUE) { Status = NorFlashUnlockSingleBlock (Instance, BlockAddress); } return Status; } /** * The following function presumes that the block has already been unlocked. **/ STATIC EFI_STATUS NorFlashEraseSingleBlock ( IN NOR_FLASH_INSTANCE *Instance, IN UINTN BlockAddress ) { EFI_STATUS Status; UINT32 StatusRegister; Status = EFI_SUCCESS; // Request a block erase and then confirm it SEND_NOR_COMMAND(BlockAddress, 0, P30_CMD_BLOCK_ERASE_SETUP); SEND_NOR_COMMAND(BlockAddress, 0, P30_CMD_BLOCK_ERASE_CONFIRM); // Wait until the status register gives us the all clear do { StatusRegister = NorFlashReadStatusRegister (Instance, BlockAddress); } while ((StatusRegister & P30_SR_BIT_WRITE) != P30_SR_BIT_WRITE); if (StatusRegister & P30_SR_BIT_VPP) { DEBUG((EFI_D_ERROR,"EraseSingleBlock(BlockAddress=0x%08x: VPP Range Error\n", BlockAddress)); Status = EFI_DEVICE_ERROR; } if ((StatusRegister & (P30_SR_BIT_ERASE | P30_SR_BIT_PROGRAM)) == (P30_SR_BIT_ERASE | P30_SR_BIT_PROGRAM)) { DEBUG((EFI_D_ERROR,"EraseSingleBlock(BlockAddress=0x%08x: Command Sequence Error\n", BlockAddress)); Status = EFI_DEVICE_ERROR; } if (StatusRegister & P30_SR_BIT_ERASE) { DEBUG((EFI_D_ERROR,"EraseSingleBlock(BlockAddress=0x%08x: Block Erase Error StatusRegister:0x%X\n", BlockAddress, StatusRegister)); Status = EFI_DEVICE_ERROR; } if (StatusRegister & P30_SR_BIT_BLOCK_LOCKED) { // The debug level message has been reduced because a device lock might happen. In this case we just retry it ... DEBUG((EFI_D_INFO,"EraseSingleBlock(BlockAddress=0x%08x: Block Locked Error\n", BlockAddress)); Status = EFI_WRITE_PROTECTED; } if (EFI_ERROR(Status)) { // Clear the Status Register SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_CLEAR_STATUS_REGISTER); } // Put device back into Read Array mode SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_READ_ARRAY); return Status; } /** * This function unlock and erase an entire NOR Flash block. **/ EFI_STATUS NorFlashUnlockAndEraseSingleBlock ( IN NOR_FLASH_INSTANCE *Instance, IN UINTN BlockAddress ) { EFI_STATUS Status; UINTN Index; EFI_TPL OriginalTPL; if (!EfiAtRuntime ()) { // Raise TPL to TPL_HIGH to stop anyone from interrupting us. OriginalTPL = gBS->RaiseTPL (TPL_HIGH_LEVEL); } else { // This initialization is only to prevent the compiler to complain about the // use of uninitialized variables OriginalTPL = TPL_HIGH_LEVEL; } Index = 0; // The block erase might fail a first time (SW bug ?). Retry it ... do { // Unlock the block if we have to Status = NorFlashUnlockSingleBlockIfNecessary (Instance, BlockAddress); if (EFI_ERROR (Status)) { break; } Status = NorFlashEraseSingleBlock (Instance, BlockAddress); Index++; } while ((Index < NOR_FLASH_ERASE_RETRY) && (Status == EFI_WRITE_PROTECTED)); if (Index == NOR_FLASH_ERASE_RETRY) { DEBUG((EFI_D_ERROR,"EraseSingleBlock(BlockAddress=0x%08x: Block Locked Error (try to erase %d times)\n", BlockAddress,Index)); } if (!EfiAtRuntime ()) { // Interruptions can resume. gBS->RestoreTPL (OriginalTPL); } return Status; } STATIC EFI_STATUS NorFlashWriteSingleWord ( IN NOR_FLASH_INSTANCE *Instance, IN UINTN WordAddress, IN UINT32 WriteData ) { EFI_STATUS Status; UINT32 StatusRegister; Status = EFI_SUCCESS; // Request a write single word command SEND_NOR_COMMAND(WordAddress, 0, P30_CMD_WORD_PROGRAM_SETUP); // Store the word into NOR Flash; MmioWrite32 (WordAddress, WriteData); // Wait for the write to complete and then check for any errors; i.e. check the Status Register do { // Prepare to read the status register StatusRegister = NorFlashReadStatusRegister (Instance, WordAddress); // The chip is busy while the WRITE bit is not asserted } while ((StatusRegister & P30_SR_BIT_WRITE) != P30_SR_BIT_WRITE); // Perform a full status check: // Mask the relevant bits of Status Register. // Everything should be zero, if not, we have a problem if (StatusRegister & P30_SR_BIT_VPP) { DEBUG((EFI_D_ERROR,"NorFlashWriteSingleWord(WordAddress:0x%X): VPP Range Error\n",WordAddress)); Status = EFI_DEVICE_ERROR; } if (StatusRegister & P30_SR_BIT_PROGRAM) { DEBUG((EFI_D_ERROR,"NorFlashWriteSingleWord(WordAddress:0x%X): Program Error\n",WordAddress)); Status = EFI_DEVICE_ERROR; } if (StatusRegister & P30_SR_BIT_BLOCK_LOCKED) { DEBUG((EFI_D_ERROR,"NorFlashWriteSingleWord(WordAddress:0x%X): Device Protect Error\n",WordAddress)); Status = EFI_DEVICE_ERROR; } if (!EFI_ERROR(Status)) { // Clear the Status Register SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_CLEAR_STATUS_REGISTER); } // Put device back into Read Array mode SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_READ_ARRAY); return Status; } /* * Writes data to the NOR Flash using the Buffered Programming method. * * The maximum size of the on-chip buffer is 32-words, because of hardware restrictions. * Therefore this function will only handle buffers up to 32 words or 128 bytes. * To deal with larger buffers, call this function again. * * This function presumes that both the TargetAddress and the TargetAddress+BufferSize * exist entirely within the NOR Flash. Therefore these conditions will not be checked here. * * In buffered programming, if the target address not at the beginning of a 32-bit word boundary, * then programming time is doubled and power consumption is increased. * Therefore, it is a requirement to align buffer writes to 32-bit word boundaries. * i.e. the last 4 bits of the target start address must be zero: 0x......00 */ EFI_STATUS NorFlashWriteBuffer ( IN NOR_FLASH_INSTANCE *Instance, IN UINTN TargetAddress, IN UINTN BufferSizeInBytes, IN UINT32 *Buffer ) { EFI_STATUS Status; UINTN BufferSizeInWords; UINTN Count; volatile UINT32 *Data; UINTN WaitForBuffer; BOOLEAN BufferAvailable; UINT32 StatusRegister; WaitForBuffer = MAX_BUFFERED_PROG_ITERATIONS; BufferAvailable = FALSE; // Check that the target address does not cross a 32-word boundary. if ((TargetAddress & BOUNDARY_OF_32_WORDS) != 0) { return EFI_INVALID_PARAMETER; } // Check there are some data to program if (BufferSizeInBytes == 0) { return EFI_BUFFER_TOO_SMALL; } // Check that the buffer size does not exceed the maximum hardware buffer size on chip. if (BufferSizeInBytes > P30_MAX_BUFFER_SIZE_IN_BYTES) { return EFI_BAD_BUFFER_SIZE; } // Check that the buffer size is a multiple of 32-bit words if ((BufferSizeInBytes % 4) != 0) { return EFI_BAD_BUFFER_SIZE; } // Pre-programming conditions checked, now start the algorithm. // Prepare the data destination address Data = (UINT32 *)TargetAddress; // Check the availability of the buffer do { // Issue the Buffered Program Setup command SEND_NOR_COMMAND(TargetAddress, 0, P30_CMD_BUFFERED_PROGRAM_SETUP); // Read back the status register bit#7 from the same address if (((*Data) & P30_SR_BIT_WRITE) == P30_SR_BIT_WRITE) { BufferAvailable = TRUE; } // Update the loop counter WaitForBuffer--; } while ((WaitForBuffer > 0) && (BufferAvailable == FALSE)); // The buffer was not available for writing if (WaitForBuffer == 0) { Status = EFI_DEVICE_ERROR; goto EXIT; } // From now on we work in 32-bit words BufferSizeInWords = BufferSizeInBytes / (UINTN)4; // Write the word count, which is (buffer_size_in_words - 1), // because word count 0 means one word. SEND_NOR_COMMAND(TargetAddress, 0, (BufferSizeInWords - 1)); // Write the data to the NOR Flash, advancing each address by 4 bytes for(Count=0; Count < BufferSizeInWords; Count++, Data++, Buffer++) { MmioWrite32 ((UINTN)Data, *Buffer); } // Issue the Buffered Program Confirm command, to start the programming operation SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_BUFFERED_PROGRAM_CONFIRM); // Wait for the write to complete and then check for any errors; i.e. check the Status Register do { StatusRegister = NorFlashReadStatusRegister (Instance, TargetAddress); // The chip is busy while the WRITE bit is not asserted } while ((StatusRegister & P30_SR_BIT_WRITE) != P30_SR_BIT_WRITE); // Perform a full status check: // Mask the relevant bits of Status Register. // Everything should be zero, if not, we have a problem Status = EFI_SUCCESS; if (StatusRegister & P30_SR_BIT_VPP) { DEBUG((EFI_D_ERROR,"NorFlashWriteBuffer(TargetAddress:0x%X): VPP Range Error\n", TargetAddress)); Status = EFI_DEVICE_ERROR; } if (StatusRegister & P30_SR_BIT_PROGRAM) { DEBUG((EFI_D_ERROR,"NorFlashWriteBuffer(TargetAddress:0x%X): Program Error\n", TargetAddress)); Status = EFI_DEVICE_ERROR; } if (StatusRegister & P30_SR_BIT_BLOCK_LOCKED) { DEBUG((EFI_D_ERROR,"NorFlashWriteBuffer(TargetAddress:0x%X): Device Protect Error\n",TargetAddress)); Status = EFI_DEVICE_ERROR; } if (!EFI_ERROR(Status)) { // Clear the Status Register SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_CLEAR_STATUS_REGISTER); } EXIT: // Put device back into Read Array mode SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_READ_ARRAY); return Status; } STATIC EFI_STATUS NorFlashWriteFullBlock ( IN NOR_FLASH_INSTANCE *Instance, IN EFI_LBA Lba, IN UINT32 *DataBuffer, IN UINT32 BlockSizeInWords ) { EFI_STATUS Status; UINTN WordAddress; UINT32 WordIndex; UINTN BufferIndex; UINTN BlockAddress; UINTN BuffersInBlock; UINTN RemainingWords; EFI_TPL OriginalTPL; UINTN Cnt; Status = EFI_SUCCESS; // Get the physical address of the block BlockAddress = GET_NOR_BLOCK_ADDRESS (Instance->RegionBaseAddress, Lba, BlockSizeInWords * 4); // Start writing from the first address at the start of the block WordAddress = BlockAddress; if (!EfiAtRuntime ()) { // Raise TPL to TPL_HIGH to stop anyone from interrupting us. OriginalTPL = gBS->RaiseTPL (TPL_HIGH_LEVEL); } else { // This initialization is only to prevent the compiler to complain about the // use of uninitialized variables OriginalTPL = TPL_HIGH_LEVEL; } Status = NorFlashUnlockAndEraseSingleBlock (Instance, BlockAddress); if (EFI_ERROR(Status)) { DEBUG((EFI_D_ERROR, "WriteSingleBlock: ERROR - Failed to Unlock and Erase the single block at 0x%X\n", BlockAddress)); goto EXIT; } // To speed up the programming operation, NOR Flash is programmed using the Buffered Programming method. // Check that the address starts at a 32-word boundary, i.e. last 7 bits must be zero if ((WordAddress & BOUNDARY_OF_32_WORDS) == 0x00) { // First, break the entire block into buffer-sized chunks. BuffersInBlock = (UINTN)(BlockSizeInWords * 4) / P30_MAX_BUFFER_SIZE_IN_BYTES; // Then feed each buffer chunk to the NOR Flash // If a buffer does not contain any data, don't write it. for(BufferIndex=0; BufferIndex < BuffersInBlock; BufferIndex++, WordAddress += P30_MAX_BUFFER_SIZE_IN_BYTES, DataBuffer += P30_MAX_BUFFER_SIZE_IN_WORDS ) { // Check the buffer to see if it contains any data (not set all 1s). for (Cnt = 0; Cnt < P30_MAX_BUFFER_SIZE_IN_WORDS; Cnt++) { if (~DataBuffer[Cnt] != 0 ) { // Some data found, write the buffer. Status = NorFlashWriteBuffer (Instance, WordAddress, P30_MAX_BUFFER_SIZE_IN_BYTES, DataBuffer); if (EFI_ERROR(Status)) { goto EXIT; } break; } } } // Finally, finish off any remaining words that are less than the maximum size of the buffer RemainingWords = BlockSizeInWords % P30_MAX_BUFFER_SIZE_IN_WORDS; if(RemainingWords != 0) { Status = NorFlashWriteBuffer (Instance, WordAddress, (RemainingWords * 4), DataBuffer); if (EFI_ERROR(Status)) { goto EXIT; } } } else { // For now, use the single word programming algorithm // It is unlikely that the NOR Flash will exist in an address which falls within a 32 word boundary range, // i.e. which ends in the range 0x......01 - 0x......7F. for(WordIndex=0; WordIndexRestoreTPL (OriginalTPL); } if (EFI_ERROR(Status)) { DEBUG((EFI_D_ERROR, "NOR FLASH Programming [WriteSingleBlock] failed at address 0x%08x. Exit Status = \"%r\".\n", WordAddress, Status)); } return Status; } EFI_STATUS NorFlashWriteBlocks ( IN NOR_FLASH_INSTANCE *Instance, IN EFI_LBA Lba, IN UINTN BufferSizeInBytes, IN VOID *Buffer ) { UINT32 *pWriteBuffer; EFI_STATUS Status = EFI_SUCCESS; EFI_LBA CurrentBlock; UINT32 BlockSizeInWords; UINT32 NumBlocks; UINT32 BlockCount; // The buffer must be valid if (Buffer == NULL) { return EFI_INVALID_PARAMETER; } if(Instance->Media.ReadOnly == TRUE) { return EFI_WRITE_PROTECTED; } // We must have some bytes to read DEBUG((DEBUG_BLKIO, "NorFlashWriteBlocks: BufferSizeInBytes=0x%x\n", BufferSizeInBytes)); if(BufferSizeInBytes == 0) { return EFI_BAD_BUFFER_SIZE; } // The size of the buffer must be a multiple of the block size DEBUG((DEBUG_BLKIO, "NorFlashWriteBlocks: BlockSize in bytes =0x%x\n", Instance->Media.BlockSize)); if ((BufferSizeInBytes % Instance->Media.BlockSize) != 0) { return EFI_BAD_BUFFER_SIZE; } // All blocks must be within the device NumBlocks = ((UINT32)BufferSizeInBytes) / Instance->Media.BlockSize ; DEBUG((DEBUG_BLKIO, "NorFlashWriteBlocks: NumBlocks=%d, LastBlock=%ld, Lba=%ld.\n", NumBlocks, Instance->Media.LastBlock, Lba)); if ((Lba + NumBlocks) > (Instance->Media.LastBlock + 1)) { DEBUG((EFI_D_ERROR, "NorFlashWriteBlocks: ERROR - Write will exceed last block.\n")); return EFI_INVALID_PARAMETER; } BlockSizeInWords = Instance->Media.BlockSize / 4; // Because the target *Buffer is a pointer to VOID, we must put all the data into a pointer // to a proper data type, so use *ReadBuffer pWriteBuffer = (UINT32 *)Buffer; CurrentBlock = Lba; for (BlockCount=0; BlockCount < NumBlocks; BlockCount++, CurrentBlock++, pWriteBuffer = pWriteBuffer + BlockSizeInWords) { DEBUG((DEBUG_BLKIO, "NorFlashWriteBlocks: Writing block #%d\n", (UINTN)CurrentBlock)); Status = NorFlashWriteFullBlock (Instance, CurrentBlock, pWriteBuffer, BlockSizeInWords); if (EFI_ERROR(Status)) { break; } } DEBUG((DEBUG_BLKIO, "NorFlashWriteBlocks: Exit Status = \"%r\".\n", Status)); return Status; } #define BOTH_ALIGNED(a, b, align) ((((UINTN)(a) | (UINTN)(b)) & ((align) - 1)) == 0) /** Copy Length bytes from Source to Destination, using aligned accesses only. Note that this implementation uses memcpy() semantics rather then memmove() semantics, i.e., SourceBuffer and DestinationBuffer should not overlap. @param DestinationBuffer The target of the copy request. @param SourceBuffer The place to copy from. @param Length The number of bytes to copy. @return Destination **/ STATIC VOID * AlignedCopyMem ( OUT VOID *DestinationBuffer, IN CONST VOID *SourceBuffer, IN UINTN Length ) { UINT8 *Destination8; CONST UINT8 *Source8; UINT32 *Destination32; CONST UINT32 *Source32; UINT64 *Destination64; CONST UINT64 *Source64; if (BOTH_ALIGNED(DestinationBuffer, SourceBuffer, 8) && Length >= 8) { Destination64 = DestinationBuffer; Source64 = SourceBuffer; while (Length >= 8) { *Destination64++ = *Source64++; Length -= 8; } Destination8 = (UINT8 *)Destination64; Source8 = (CONST UINT8 *)Source64; } else if (BOTH_ALIGNED(DestinationBuffer, SourceBuffer, 4) && Length >= 4) { Destination32 = DestinationBuffer; Source32 = SourceBuffer; while (Length >= 4) { *Destination32++ = *Source32++; Length -= 4; } Destination8 = (UINT8 *)Destination32; Source8 = (CONST UINT8 *)Source32; } else { Destination8 = DestinationBuffer; Source8 = SourceBuffer; } while (Length-- != 0) { *Destination8++ = *Source8++; } return DestinationBuffer; } EFI_STATUS NorFlashReadBlocks ( IN NOR_FLASH_INSTANCE *Instance, IN EFI_LBA Lba, IN UINTN BufferSizeInBytes, OUT VOID *Buffer ) { UINT32 NumBlocks; UINTN StartAddress; DEBUG((DEBUG_BLKIO, "NorFlashReadBlocks: BufferSize=0x%xB BlockSize=0x%xB LastBlock=%ld, Lba=%ld.\n", BufferSizeInBytes, Instance->Media.BlockSize, Instance->Media.LastBlock, Lba)); // The buffer must be valid if (Buffer == NULL) { return EFI_INVALID_PARAMETER; } // Return if we have not any byte to read if (BufferSizeInBytes == 0) { return EFI_SUCCESS; } // The size of the buffer must be a multiple of the block size if ((BufferSizeInBytes % Instance->Media.BlockSize) != 0) { return EFI_BAD_BUFFER_SIZE; } // All blocks must be within the device NumBlocks = ((UINT32)BufferSizeInBytes) / Instance->Media.BlockSize ; if ((Lba + NumBlocks) > (Instance->Media.LastBlock + 1)) { DEBUG((EFI_D_ERROR, "NorFlashReadBlocks: ERROR - Read will exceed last block\n")); return EFI_INVALID_PARAMETER; } // Get the address to start reading from StartAddress = GET_NOR_BLOCK_ADDRESS (Instance->RegionBaseAddress, Lba, Instance->Media.BlockSize ); // Put the device into Read Array mode SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_READ_ARRAY); // Readout the data AlignedCopyMem (Buffer, (VOID *)StartAddress, BufferSizeInBytes); return EFI_SUCCESS; } EFI_STATUS NorFlashRead ( IN NOR_FLASH_INSTANCE *Instance, IN EFI_LBA Lba, IN UINTN Offset, IN UINTN BufferSizeInBytes, OUT VOID *Buffer ) { UINTN StartAddress; // The buffer must be valid if (Buffer == NULL) { return EFI_INVALID_PARAMETER; } // Return if we have not any byte to read if (BufferSizeInBytes == 0) { return EFI_SUCCESS; } if (((Lba * Instance->Media.BlockSize) + Offset + BufferSizeInBytes) > Instance->Size) { DEBUG ((EFI_D_ERROR, "NorFlashRead: ERROR - Read will exceed device size.\n")); return EFI_INVALID_PARAMETER; } // Get the address to start reading from StartAddress = GET_NOR_BLOCK_ADDRESS (Instance->RegionBaseAddress, Lba, Instance->Media.BlockSize ); // Put the device into Read Array mode SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_READ_ARRAY); // Readout the data AlignedCopyMem (Buffer, (VOID *)(StartAddress + Offset), BufferSizeInBytes); return EFI_SUCCESS; } /* Write a full or portion of a block. It must not span block boundaries; that is, Offset + *NumBytes <= Instance->Media.BlockSize. */ EFI_STATUS NorFlashWriteSingleBlock ( IN NOR_FLASH_INSTANCE *Instance, IN EFI_LBA Lba, IN UINTN Offset, IN OUT UINTN *NumBytes, IN UINT8 *Buffer ) { EFI_STATUS TempStatus; UINT32 Tmp; UINT32 TmpBuf; UINT32 WordToWrite; UINT32 Mask; BOOLEAN DoErase; UINTN BytesToWrite; UINTN CurOffset; UINTN WordAddr; UINTN BlockSize; UINTN BlockAddress; UINTN PrevBlockAddress; PrevBlockAddress = 0; DEBUG ((DEBUG_BLKIO, "NorFlashWriteSingleBlock(Parameters: Lba=%ld, Offset=0x%x, *NumBytes=0x%x, Buffer @ 0x%08x)\n", Lba, Offset, *NumBytes, Buffer)); // Detect WriteDisabled state if (Instance->Media.ReadOnly == TRUE) { DEBUG ((EFI_D_ERROR, "NorFlashWriteSingleBlock: ERROR - Can not write: Device is in WriteDisabled state.\n")); // It is in WriteDisabled state, return an error right away return EFI_ACCESS_DENIED; } // Cache the block size to avoid de-referencing pointers all the time BlockSize = Instance->Media.BlockSize; // The write must not span block boundaries. // We need to check each variable individually because adding two large values together overflows. if ( ( Offset >= BlockSize ) || ( *NumBytes > BlockSize ) || ( (Offset + *NumBytes) > BlockSize ) ) { DEBUG ((EFI_D_ERROR, "NorFlashWriteSingleBlock: ERROR - EFI_BAD_BUFFER_SIZE: (Offset=0x%x + NumBytes=0x%x) > BlockSize=0x%x\n", Offset, *NumBytes, BlockSize )); return EFI_BAD_BUFFER_SIZE; } // We must have some bytes to write if (*NumBytes == 0) { DEBUG ((EFI_D_ERROR, "NorFlashWriteSingleBlock: ERROR - EFI_BAD_BUFFER_SIZE: (Offset=0x%x + NumBytes=0x%x) > BlockSize=0x%x\n", Offset, *NumBytes, BlockSize )); return EFI_BAD_BUFFER_SIZE; } // Pick 128bytes as a good start for word operations as opposed to erasing the // block and writing the data regardless if an erase is really needed. // It looks like most individual NV variable writes are smaller than 128bytes. if (*NumBytes <= 128) { // Check to see if we need to erase before programming the data into NOR. // If the destination bits are only changing from 1s to 0s we can just write. // After a block is erased all bits in the block is set to 1. // If any byte requires us to erase we just give up and rewrite all of it. DoErase = FALSE; BytesToWrite = *NumBytes; CurOffset = Offset; while (BytesToWrite > 0) { // Read full word from NOR, splice as required. A word is the smallest // unit we can write. TempStatus = NorFlashRead (Instance, Lba, CurOffset & ~(0x3), sizeof(Tmp), &Tmp); if (EFI_ERROR (TempStatus)) { return EFI_DEVICE_ERROR; } // Physical address of word in NOR to write. WordAddr = (CurOffset & ~(0x3)) + GET_NOR_BLOCK_ADDRESS (Instance->RegionBaseAddress, Lba, BlockSize); // The word of data that is to be written. TmpBuf = *((UINT32*)(Buffer + (*NumBytes - BytesToWrite))); // First do word aligned chunks. if ((CurOffset & 0x3) == 0) { if (BytesToWrite >= 4) { // Is the destination still in 'erased' state? if (~Tmp != 0) { // Check to see if we are only changing bits to zero. if ((Tmp ^ TmpBuf) & TmpBuf) { DoErase = TRUE; break; } } // Write this word to NOR WordToWrite = TmpBuf; CurOffset += sizeof(TmpBuf); BytesToWrite -= sizeof(TmpBuf); } else { // BytesToWrite < 4. Do small writes and left-overs Mask = ~((~0) << (BytesToWrite * 8)); // Mask out the bytes we want. TmpBuf &= Mask; // Is the destination still in 'erased' state? if ((Tmp & Mask) != Mask) { // Check to see if we are only changing bits to zero. if ((Tmp ^ TmpBuf) & TmpBuf) { DoErase = TRUE; break; } } // Merge old and new data. Write merged word to NOR WordToWrite = (Tmp & ~Mask) | TmpBuf; CurOffset += BytesToWrite; BytesToWrite = 0; } } else { // Do multiple words, but starting unaligned. if (BytesToWrite > (4 - (CurOffset & 0x3))) { Mask = ((~0) << ((CurOffset & 0x3) * 8)); // Mask out the bytes we want. TmpBuf &= Mask; // Is the destination still in 'erased' state? if ((Tmp & Mask) != Mask) { // Check to see if we are only changing bits to zero. if ((Tmp ^ TmpBuf) & TmpBuf) { DoErase = TRUE; break; } } // Merge old and new data. Write merged word to NOR WordToWrite = (Tmp & ~Mask) | TmpBuf; BytesToWrite -= (4 - (CurOffset & 0x3)); CurOffset += (4 - (CurOffset & 0x3)); } else { // Unaligned and fits in one word. Mask = (~((~0) << (BytesToWrite * 8))) << ((CurOffset & 0x3) * 8); // Mask out the bytes we want. TmpBuf = (TmpBuf << ((CurOffset & 0x3) * 8)) & Mask; // Is the destination still in 'erased' state? if ((Tmp & Mask) != Mask) { // Check to see if we are only changing bits to zero. if ((Tmp ^ TmpBuf) & TmpBuf) { DoErase = TRUE; break; } } // Merge old and new data. Write merged word to NOR WordToWrite = (Tmp & ~Mask) | TmpBuf; CurOffset += BytesToWrite; BytesToWrite = 0; } } // // Write the word to NOR. // BlockAddress = GET_NOR_BLOCK_ADDRESS (Instance->RegionBaseAddress, Lba, BlockSize); if (BlockAddress != PrevBlockAddress) { TempStatus = NorFlashUnlockSingleBlockIfNecessary (Instance, BlockAddress); if (EFI_ERROR (TempStatus)) { return EFI_DEVICE_ERROR; } PrevBlockAddress = BlockAddress; } TempStatus = NorFlashWriteSingleWord (Instance, WordAddr, WordToWrite); if (EFI_ERROR (TempStatus)) { return EFI_DEVICE_ERROR; } } // Exit if we got here and could write all the data. Otherwise do the // Erase-Write cycle. if (!DoErase) { return EFI_SUCCESS; } } // Check we did get some memory. Buffer is BlockSize. if (Instance->ShadowBuffer == NULL) { DEBUG ((EFI_D_ERROR, "FvbWrite: ERROR - Buffer not ready\n")); return EFI_DEVICE_ERROR; } // Read NOR Flash data into shadow buffer TempStatus = NorFlashReadBlocks (Instance, Lba, BlockSize, Instance->ShadowBuffer); if (EFI_ERROR (TempStatus)) { // Return one of the pre-approved error statuses return EFI_DEVICE_ERROR; } // Put the data at the appropriate location inside the buffer area CopyMem ((VOID*)((UINTN)Instance->ShadowBuffer + Offset), Buffer, *NumBytes); // Write the modified buffer back to the NorFlash TempStatus = NorFlashWriteBlocks (Instance, Lba, BlockSize, Instance->ShadowBuffer); if (EFI_ERROR (TempStatus)) { // Return one of the pre-approved error statuses return EFI_DEVICE_ERROR; } return EFI_SUCCESS; } /* Although DiskIoDxe will automatically install the DiskIO protocol whenever we install the BlockIO protocol, its implementation is sub-optimal as it reads and writes entire blocks using the BlockIO protocol. In fact we can access NOR flash with a finer granularity than that, so we can improve performance by directly producing the DiskIO protocol. */ /** Read BufferSize bytes from Offset into Buffer. @param This Protocol instance pointer. @param MediaId Id of the media, changes every time the media is replaced. @param Offset The starting byte offset to read from @param BufferSize Size of Buffer @param Buffer Buffer containing read data @retval EFI_SUCCESS The data was read correctly from the device. @retval EFI_DEVICE_ERROR The device reported an error while performing the read. @retval EFI_NO_MEDIA There is no media in the device. @retval EFI_MEDIA_CHANGED The MediaId does not match the current device. @retval EFI_INVALID_PARAMETER The read request contains device addresses that are not valid for the device. **/ EFI_STATUS EFIAPI NorFlashDiskIoReadDisk ( IN EFI_DISK_IO_PROTOCOL *This, IN UINT32 MediaId, IN UINT64 DiskOffset, IN UINTN BufferSize, OUT VOID *Buffer ) { NOR_FLASH_INSTANCE *Instance; UINT32 BlockSize; UINT32 BlockOffset; EFI_LBA Lba; Instance = INSTANCE_FROM_DISKIO_THIS(This); if (MediaId != Instance->Media.MediaId) { return EFI_MEDIA_CHANGED; } BlockSize = Instance->Media.BlockSize; Lba = (EFI_LBA) DivU64x32Remainder (DiskOffset, BlockSize, &BlockOffset); return NorFlashRead (Instance, Lba, BlockOffset, BufferSize, Buffer); } /** Writes a specified number of bytes to a device. @param This Indicates a pointer to the calling context. @param MediaId ID of the medium to be written. @param Offset The starting byte offset on the logical block I/O device to write. @param BufferSize The size in bytes of Buffer. The number of bytes to write to the device. @param Buffer A pointer to the buffer containing the data to be written. @retval EFI_SUCCESS The data was written correctly to the device. @retval EFI_WRITE_PROTECTED The device can not be written to. @retval EFI_DEVICE_ERROR The device reported an error while performing the write. @retval EFI_NO_MEDIA There is no media in the device. @retval EFI_MEDIA_CHANGED The MediaId does not match the current device. @retval EFI_INVALID_PARAMETER The write request contains device addresses that are not valid for the device. **/ EFI_STATUS EFIAPI NorFlashDiskIoWriteDisk ( IN EFI_DISK_IO_PROTOCOL *This, IN UINT32 MediaId, IN UINT64 DiskOffset, IN UINTN BufferSize, IN VOID *Buffer ) { NOR_FLASH_INSTANCE *Instance; UINT32 BlockSize; UINT32 BlockOffset; EFI_LBA Lba; UINTN RemainingBytes; UINTN WriteSize; EFI_STATUS Status; Instance = INSTANCE_FROM_DISKIO_THIS(This); if (MediaId != Instance->Media.MediaId) { return EFI_MEDIA_CHANGED; } BlockSize = Instance->Media.BlockSize; Lba = (EFI_LBA) DivU64x32Remainder (DiskOffset, BlockSize, &BlockOffset); RemainingBytes = BufferSize; // Write either all the remaining bytes, or the number of bytes that bring // us up to a block boundary, whichever is less. // (DiskOffset | (BlockSize - 1)) + 1) rounds DiskOffset up to the next // block boundary (even if it is already on one). WriteSize = MIN (RemainingBytes, ((DiskOffset | (BlockSize - 1)) + 1) - DiskOffset); do { if (WriteSize == BlockSize) { // Write a full block Status = NorFlashWriteFullBlock (Instance, Lba, Buffer, BlockSize / sizeof (UINT32)); } else { // Write a partial block Status = NorFlashWriteSingleBlock (Instance, Lba, BlockOffset, &WriteSize, Buffer); } if (EFI_ERROR (Status)) { return Status; } // Now continue writing either all the remaining bytes or single blocks. RemainingBytes -= WriteSize; Buffer = (UINT8 *) Buffer + WriteSize; Lba++; BlockOffset = 0; WriteSize = MIN (RemainingBytes, BlockSize); } while (RemainingBytes); return Status; } EFI_STATUS NorFlashReset ( IN NOR_FLASH_INSTANCE *Instance ) { // As there is no specific RESET to perform, ensure that the devices is in the default Read Array mode SEND_NOR_COMMAND (Instance->DeviceBaseAddress, 0, P30_CMD_READ_ARRAY); return EFI_SUCCESS; } /** Fixup internal data so that EFI can be call in virtual mode. Call the passed in Child Notify event and convert any pointers in lib to virtual mode. @param[in] Event The Event that is being processed @param[in] Context Event Context **/ VOID EFIAPI NorFlashVirtualNotifyEvent ( IN EFI_EVENT Event, IN VOID *Context ) { UINTN Index; for (Index = 0; Index < mNorFlashDeviceCount; Index++) { EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->DeviceBaseAddress); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->RegionBaseAddress); // Convert BlockIo protocol EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->BlockIoProtocol.FlushBlocks); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->BlockIoProtocol.ReadBlocks); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->BlockIoProtocol.Reset); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->BlockIoProtocol.WriteBlocks); // Convert Fvb EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->FvbProtocol.EraseBlocks); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->FvbProtocol.GetAttributes); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->FvbProtocol.GetBlockSize); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->FvbProtocol.GetPhysicalAddress); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->FvbProtocol.Read); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->FvbProtocol.SetAttributes); EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->FvbProtocol.Write); if (mNorFlashInstances[Index]->ShadowBuffer != NULL) { EfiConvertPointer (0x0, (VOID**)&mNorFlashInstances[Index]->ShadowBuffer); } } return; } EFI_STATUS EFIAPI NorFlashInitialise ( IN EFI_HANDLE ImageHandle, IN EFI_SYSTEM_TABLE *SystemTable ) { EFI_STATUS Status; UINT32 Index; NOR_FLASH_DESCRIPTION* NorFlashDevices; BOOLEAN ContainVariableStorage; Status = NorFlashPlatformInitialization (); if (EFI_ERROR(Status)) { DEBUG((EFI_D_ERROR,"NorFlashInitialise: Fail to initialize Nor Flash devices\n")); return Status; } Status = NorFlashPlatformGetDevices (&NorFlashDevices, &mNorFlashDeviceCount); if (EFI_ERROR(Status)) { DEBUG((EFI_D_ERROR,"NorFlashInitialise: Fail to get Nor Flash devices\n")); return Status; } mNorFlashInstances = AllocateRuntimePool (sizeof(NOR_FLASH_INSTANCE*) * mNorFlashDeviceCount); for (Index = 0; Index < mNorFlashDeviceCount; Index++) { // Check if this NOR Flash device contain the variable storage region ContainVariableStorage = (NorFlashDevices[Index].RegionBaseAddress <= PcdGet32 (PcdFlashNvStorageVariableBase)) && (PcdGet32 (PcdFlashNvStorageVariableBase) + PcdGet32 (PcdFlashNvStorageVariableSize) <= NorFlashDevices[Index].RegionBaseAddress + NorFlashDevices[Index].Size); Status = NorFlashCreateInstance ( NorFlashDevices[Index].DeviceBaseAddress, NorFlashDevices[Index].RegionBaseAddress, NorFlashDevices[Index].Size, Index, NorFlashDevices[Index].BlockSize, ContainVariableStorage, &mNorFlashInstances[Index] ); if (EFI_ERROR(Status)) { DEBUG((EFI_D_ERROR,"NorFlashInitialise: Fail to create instance for NorFlash[%d]\n",Index)); } } // // Register for the virtual address change event // Status = gBS->CreateEventEx ( EVT_NOTIFY_SIGNAL, TPL_NOTIFY, NorFlashVirtualNotifyEvent, NULL, &gEfiEventVirtualAddressChangeGuid, &mNorFlashVirtualAddrChangeEvent ); ASSERT_EFI_ERROR (Status); return Status; }