// Copyright 2017 The Fuchsia Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef __Fuchsia__ #include #endif #define ZXDEBUG 0 #include using digest::Digest; using digest::MerkleTree; namespace blobfs { // Number of blocks reserved for the Merkle Tree uint64_t MerkleTreeBlocks(const blobfs_inode_t& blobNode) { uint64_t size_merkle = MerkleTree::GetTreeLength(blobNode.blob_size); return fbl::round_up(size_merkle, kBlobfsBlockSize) / kBlobfsBlockSize; } // Sanity check the metadata for the blobfs, given a maximum number of // available blocks. zx_status_t blobfs_check_info(const blobfs_info_t* info, uint64_t max) { if ((info->magic0 != kBlobfsMagic0) || (info->magic1 != kBlobfsMagic1)) { fprintf(stderr, "blobfs: bad magic\n"); return ZX_ERR_INVALID_ARGS; } if (info->version != kBlobfsVersion) { fprintf(stderr, "blobfs: FS Version: %08x. Driver version: %08x\n", info->version, kBlobfsVersion); return ZX_ERR_INVALID_ARGS; } if (info->block_size != kBlobfsBlockSize) { fprintf(stderr, "blobfs: bsz %u unsupported\n", info->block_size); return ZX_ERR_INVALID_ARGS; } if ((info->flags & kBlobFlagFVM) == 0) { if (info->block_count + DataStartBlock(*info) > max) { fprintf(stderr, "blobfs: too large for device\n"); return ZX_ERR_INVALID_ARGS; } } else { const size_t blocks_per_slice = info->slice_size / info->block_size; size_t abm_blocks_needed = BlockMapBlocks(*info); size_t abm_blocks_allocated = info->abm_slices * blocks_per_slice; if (abm_blocks_needed > abm_blocks_allocated) { FS_TRACE_ERROR("blobfs: Not enough slices for block bitmap\n"); return ZX_ERR_INVALID_ARGS; } else if (abm_blocks_allocated + BlockMapStartBlock(*info) >= NodeMapStartBlock(*info)) { FS_TRACE_ERROR("blobfs: Block bitmap collides into node map\n"); return ZX_ERR_INVALID_ARGS; } size_t ino_blocks_needed = NodeMapBlocks(*info); size_t ino_blocks_allocated = info->ino_slices * blocks_per_slice; if (ino_blocks_needed > ino_blocks_allocated) { FS_TRACE_ERROR("blobfs: Not enough slices for node map\n"); return ZX_ERR_INVALID_ARGS; } else if (ino_blocks_allocated + NodeMapStartBlock(*info) >= DataStartBlock(*info)) { FS_TRACE_ERROR("blobfs: Node bitmap collides into data blocks\n"); return ZX_ERR_INVALID_ARGS; } size_t dat_blocks_needed = DataBlocks(*info); size_t dat_blocks_allocated = info->dat_slices * blocks_per_slice; if (dat_blocks_needed < kStartBlockMinimum) { FS_TRACE_ERROR("blobfs: Partition too small; no space left for data blocks\n"); return ZX_ERR_INVALID_ARGS; } else if (dat_blocks_needed > dat_blocks_allocated) { FS_TRACE_ERROR("blobfs: Not enough slices for data blocks\n"); return ZX_ERR_INVALID_ARGS; } else if (dat_blocks_allocated + DataStartBlock(*info) > fbl::numeric_limits::max()) { FS_TRACE_ERROR("blobfs: Data blocks overflow uint32\n"); return ZX_ERR_INVALID_ARGS; } } if (info->blob_header_next != 0) { fprintf(stderr, "blobfs: linked blob headers not yet supported\n"); return ZX_ERR_INVALID_ARGS; } return ZX_OK; } zx_status_t blobfs_get_blockcount(int fd, uint64_t* out) { #ifdef __Fuchsia__ block_info_t info; ssize_t r; if ((r = ioctl_block_get_info(fd, &info)) < 0) { return static_cast(r); } *out = (info.block_size * info.block_count) / kBlobfsBlockSize; #else struct stat s; if (fstat(fd, &s) < 0) { return ZX_ERR_BAD_STATE; } *out = s.st_size / kBlobfsBlockSize; #endif return ZX_OK; } zx_status_t readblk(int fd, uint64_t bno, void* data) { off_t off = bno * kBlobfsBlockSize; if (lseek(fd, off, SEEK_SET) < 0) { fprintf(stderr, "blobfs: cannot seek to block %" PRIu64 "\n", bno); return ZX_ERR_IO; } if (read(fd, data, kBlobfsBlockSize) != kBlobfsBlockSize) { fprintf(stderr, "blobfs: cannot read block %" PRIu64 "\n", bno); return ZX_ERR_IO; } return ZX_OK; } zx_status_t writeblk(int fd, uint64_t bno, const void* data) { off_t off = bno * kBlobfsBlockSize; if (lseek(fd, off, SEEK_SET) < 0) { fprintf(stderr, "blobfs: cannot seek to block %" PRIu64 "\n", bno); return ZX_ERR_IO; } if (write(fd, data, kBlobfsBlockSize) != kBlobfsBlockSize) { fprintf(stderr, "blobfs: cannot write block %" PRIu64 "\n", bno); return ZX_ERR_IO; } return ZX_OK; } int blobfs_mkfs(int fd, uint64_t block_count) { uint64_t inodes = kBlobfsDefaultInodeCount; blobfs_info_t info; memset(&info, 0x00, sizeof(info)); info.magic0 = kBlobfsMagic0; info.magic1 = kBlobfsMagic1; info.version = kBlobfsVersion; info.flags = kBlobFlagClean; info.block_size = kBlobfsBlockSize; // Set block_count to max blocks so we can calculate block map blocks info.block_count = block_count; info.inode_count = inodes; info.alloc_block_count = 0; info.alloc_inode_count = 0; info.blob_header_next = 0; // TODO(smklein): Allow chaining // The result of DataStartBlock(info) is based on the current value of info.block_count. As a // result, the block bitmap may have slightly more space allocated than is necessary. info.block_count -= DataStartBlock(info); // Set block_count to number of data blocks #ifdef __Fuchsia__ fvm_info_t fvm_info; if (ioctl_block_fvm_query(fd, &fvm_info) >= 0) { info.slice_size = fvm_info.slice_size; info.flags |= kBlobFlagFVM; if (info.slice_size % kBlobfsBlockSize) { fprintf(stderr, "blobfs mkfs: Slice size not multiple of blobfs block\n"); return -1; } if (fs::fvm_reset_volume_slices(fd) != ZX_OK) { fprintf(stderr, "blobfs mkfs: Failed to reset slices\n"); return -1; } const size_t kBlocksPerSlice = info.slice_size / kBlobfsBlockSize; extend_request_t request; request.length = 1; request.offset = kFVMBlockMapStart / kBlocksPerSlice; if (ioctl_block_fvm_extend(fd, &request) < 0) { fprintf(stderr, "blobfs mkfs: Failed to allocate block map\n"); return -1; } request.offset = kFVMNodeMapStart / kBlocksPerSlice; if (ioctl_block_fvm_extend(fd, &request) < 0) { fprintf(stderr, "blobfs mkfs: Failed to allocate node map\n"); return -1; } request.offset = kFVMDataStart / kBlocksPerSlice; request.length = fbl::round_up(kMinimumDataBlocks, kBlocksPerSlice) / kBlocksPerSlice; if (ioctl_block_fvm_extend(fd, &request) < 0) { fprintf(stderr, "blobfs mkfs: Failed to allocate data blocks\n"); return -1; } info.abm_slices = 1; info.ino_slices = 1; info.dat_slices = static_cast(request.length); info.vslice_count = info.abm_slices + info.ino_slices + info.dat_slices + 1; info.inode_count = static_cast(info.ino_slices * info.slice_size / kBlobfsInodeSize); info.block_count = static_cast(info.dat_slices * info.slice_size / kBlobfsBlockSize); } #endif xprintf("Blobfs Mkfs\n"); xprintf("Disk size : %" PRIu64 "\n", block_count * kBlobfsBlockSize); xprintf("Block Size : %u\n", kBlobfsBlockSize); xprintf("Block Count: %" PRIu64 "\n", TotalBlocks(info)); xprintf("Inode Count: %" PRIu64 "\n", inodes); xprintf("FVM-aware: %s\n", (info.flags & kBlobFlagFVM) ? "YES" : "NO"); if (info.block_count < kMinimumDataBlocks) { fprintf(stderr, "blobfs mkfs: Not enough space for minimum blobfs size\n"); return -1; } // Determine the number of blocks necessary for the block map and node map. uint64_t bbm_blocks = BlockMapBlocks(info); uint64_t nbm_blocks = NodeMapBlocks(info); RawBitmap abm; if (abm.Reset(bbm_blocks * kBlobfsBlockBits)) { fprintf(stderr, "Couldn't allocate blobfs block map\n"); return -1; } else if (abm.Shrink(info.block_count)) { fprintf(stderr, "Couldn't shrink blobfs block map\n"); return -1; } // Reserve first 2 data blocks abm.Set(0, kStartBlockMinimum); info.alloc_block_count += kStartBlockMinimum; if (info.inode_count * sizeof(blobfs_inode_t) != nbm_blocks * kBlobfsBlockSize) { fprintf(stderr, "For simplicity, inode table block must be entirely filled\n"); return -1; } // All in-memory structures have been created successfully. Dump everything to disk. char block[kBlobfsBlockSize]; zx_status_t status; // write the root block to disk memset(block, 0, sizeof(block)); memcpy(block, &info, sizeof(info)); if ((status = writeblk(fd, 0, block)) != ZX_OK) { fprintf(stderr, "Failed to write root block\n"); return status; } // write allocation bitmap to disk for (uint64_t n = 0; n < bbm_blocks; n++) { void* bmdata = get_raw_bitmap_data(abm, n); if ((status = writeblk(fd, BlockMapStartBlock(info) + n, bmdata)) < 0) { fprintf(stderr, "Failed to write blockmap block %" PRIu64 "\n", n); return status; } } // write node map to disk for (uint64_t n = 0; n < nbm_blocks; n++) { memset(block, 0, sizeof(block)); if (writeblk(fd, NodeMapStartBlock(info) + n, block)) { fprintf(stderr, "blobfs: failed writing inode map\n"); return ZX_ERR_IO; } } xprintf("BLOBFS: mkfs success\n"); return 0; } } // namespace blobfs