/* * header.c * * Read, write, or print a WIM header. */ /* * Copyright 2012-2023 Eric Biggers * * This file is free software; you can redistribute it and/or modify it under * the terms of the GNU Lesser General Public License as published by the Free * Software Foundation; either version 3 of the License, or (at your option) any * later version. * * This file is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS * FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more * details. * * You should have received a copy of the GNU Lesser General Public License * along with this file; if not, see https://www.gnu.org/licenses/. */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include #include #include #include #include "wimlib.h" #include "wimlib/alloca.h" #include "wimlib/assert.h" #include "wimlib/endianness.h" #include "wimlib/error.h" #include "wimlib/file_io.h" #include "wimlib/header.h" #include "wimlib/util.h" #include "wimlib/wim.h" /* * Reads the header from a WIM file. * * @wim * WIM to read the header from. @wim->in_fd must be positioned at the * beginning of the file. * * @hdr * Structure to read the header into. * * Return values: * WIMLIB_ERR_SUCCESS (0) * WIMLIB_ERR_IMAGE_COUNT * WIMLIB_ERR_INVALID_PART_NUMBER * WIMLIB_ERR_NOT_A_WIM_FILE * WIMLIB_ERR_READ * WIMLIB_ERR_UNEXPECTED_END_OF_FILE * WIMLIB_ERR_UNKNOWN_VERSION */ int read_wim_header(WIMStruct *wim, struct wim_header *hdr) { struct wim_header_disk disk_hdr __attribute__((aligned(8))); struct filedes *in_fd = &wim->in_fd; const tchar *filename = wim->filename; int ret; tchar *pipe_str; wimlib_assert(in_fd->offset == 0); if (filename == NULL) { pipe_str = alloca(40); tsprintf(pipe_str, T("[fd %d]"), in_fd->fd); filename = pipe_str; } STATIC_ASSERT(sizeof(struct wim_header_disk) == WIM_HEADER_DISK_SIZE); ret = full_read(in_fd, &disk_hdr, sizeof(disk_hdr)); if (ret) goto read_error; hdr->magic = le64_to_cpu(disk_hdr.magic); if (hdr->magic != WIM_MAGIC) { if (hdr->magic == PWM_MAGIC) { /* Pipable WIM: Use header at end instead, unless * actually reading from a pipe. */ if (!in_fd->is_pipe) { ret = WIMLIB_ERR_READ; if (-1 == lseek(in_fd->fd, -WIM_HEADER_DISK_SIZE, SEEK_END)) goto read_error; ret = full_read(in_fd, &disk_hdr, sizeof(disk_hdr)); if (ret) goto read_error; } } else { ERROR("\"%"TS"\": Invalid magic characters in header", filename); return WIMLIB_ERR_NOT_A_WIM_FILE; } } if (le32_to_cpu(disk_hdr.hdr_size) != sizeof(struct wim_header_disk)) { ERROR("\"%"TS"\": Header size is invalid (%u bytes)", filename, le32_to_cpu(disk_hdr.hdr_size)); return WIMLIB_ERR_INVALID_HEADER; } hdr->wim_version = le32_to_cpu(disk_hdr.wim_version); if (hdr->wim_version != WIM_VERSION_DEFAULT && hdr->wim_version != WIM_VERSION_SOLID) { ERROR("\"%"TS"\": Unknown WIM version: %u", filename, hdr->wim_version); return WIMLIB_ERR_UNKNOWN_VERSION; } hdr->flags = le32_to_cpu(disk_hdr.wim_flags); hdr->chunk_size = le32_to_cpu(disk_hdr.chunk_size); copy_guid(hdr->guid, disk_hdr.guid); hdr->part_number = le16_to_cpu(disk_hdr.part_number); hdr->total_parts = le16_to_cpu(disk_hdr.total_parts); if (hdr->total_parts == 0 || hdr->part_number == 0 || hdr->part_number > hdr->total_parts) { ERROR("\"%"TS"\": Invalid WIM part number: %hu of %hu", filename, hdr->part_number, hdr->total_parts); return WIMLIB_ERR_INVALID_PART_NUMBER; } hdr->image_count = le32_to_cpu(disk_hdr.image_count); if (unlikely(hdr->image_count > MAX_IMAGES)) { ERROR("\"%"TS"\": Invalid image count (%u)", filename, hdr->image_count); return WIMLIB_ERR_IMAGE_COUNT; } get_wim_reshdr(&disk_hdr.blob_table_reshdr, &hdr->blob_table_reshdr); get_wim_reshdr(&disk_hdr.xml_data_reshdr, &hdr->xml_data_reshdr); get_wim_reshdr(&disk_hdr.boot_metadata_reshdr, &hdr->boot_metadata_reshdr); hdr->boot_idx = le32_to_cpu(disk_hdr.boot_idx); get_wim_reshdr(&disk_hdr.integrity_table_reshdr, &hdr->integrity_table_reshdr); /* * Prevent huge memory allocations when processing fuzzed files. The * blob table, XML data, and integrity table are all uncompressed, so * they should never be larger than the WIM file itself. */ if (wim->file_size > 0 && (hdr->blob_table_reshdr.uncompressed_size > wim->file_size || hdr->xml_data_reshdr.uncompressed_size > wim->file_size || hdr->integrity_table_reshdr.uncompressed_size > wim->file_size)) return WIMLIB_ERR_INVALID_HEADER; return 0; read_error: ERROR_WITH_ERRNO("\"%"TS"\": Error reading header", filename); return ret; } /* Writes the header for a WIM file at the specified offset. If the offset * specified is the current one, the position is advanced by the size of the * header. */ int write_wim_header(const struct wim_header *hdr, struct filedes *out_fd, off_t offset) { struct wim_header_disk disk_hdr __attribute__((aligned(8))); int ret; disk_hdr.magic = cpu_to_le64(hdr->magic); disk_hdr.hdr_size = cpu_to_le32(sizeof(struct wim_header_disk)); disk_hdr.wim_version = cpu_to_le32(hdr->wim_version); disk_hdr.wim_flags = cpu_to_le32(hdr->flags); disk_hdr.chunk_size = cpu_to_le32(hdr->chunk_size); copy_guid(disk_hdr.guid, hdr->guid); disk_hdr.part_number = cpu_to_le16(hdr->part_number); disk_hdr.total_parts = cpu_to_le16(hdr->total_parts); disk_hdr.image_count = cpu_to_le32(hdr->image_count); put_wim_reshdr(&hdr->blob_table_reshdr, &disk_hdr.blob_table_reshdr); put_wim_reshdr(&hdr->xml_data_reshdr, &disk_hdr.xml_data_reshdr); put_wim_reshdr(&hdr->boot_metadata_reshdr, &disk_hdr.boot_metadata_reshdr); disk_hdr.boot_idx = cpu_to_le32(hdr->boot_idx); put_wim_reshdr(&hdr->integrity_table_reshdr, &disk_hdr.integrity_table_reshdr); memset(disk_hdr.unused, 0, sizeof(disk_hdr.unused)); if (offset == out_fd->offset) ret = full_write(out_fd, &disk_hdr, sizeof(disk_hdr)); else ret = full_pwrite(out_fd, &disk_hdr, sizeof(disk_hdr), offset); if (ret) ERROR_WITH_ERRNO("Failed to write WIM header"); return ret; } /* Update just the wim_flags field. */ int write_wim_header_flags(u32 hdr_flags, struct filedes *out_fd) { le32 flags = cpu_to_le32(hdr_flags); return full_pwrite(out_fd, &flags, sizeof(flags), offsetof(struct wim_header_disk, wim_flags)); } static const struct { u32 flag; const char *name; } hdr_flags[] = { {WIM_HDR_FLAG_RESERVED, "RESERVED"}, {WIM_HDR_FLAG_COMPRESSION, "COMPRESSION"}, {WIM_HDR_FLAG_READONLY, "READONLY"}, {WIM_HDR_FLAG_SPANNED, "SPANNED"}, {WIM_HDR_FLAG_RESOURCE_ONLY, "RESOURCE_ONLY"}, {WIM_HDR_FLAG_METADATA_ONLY, "METADATA_ONLY"}, {WIM_HDR_FLAG_WRITE_IN_PROGRESS,"WRITE_IN_PROGRESS"}, {WIM_HDR_FLAG_RP_FIX, "RP_FIX"}, {WIM_HDR_FLAG_COMPRESS_RESERVED,"COMPRESS_RESERVED"}, {WIM_HDR_FLAG_COMPRESS_LZX, "COMPRESS_LZX"}, {WIM_HDR_FLAG_COMPRESS_XPRESS, "COMPRESS_XPRESS"}, {WIM_HDR_FLAG_COMPRESS_LZMS, "COMPRESS_LZMS"}, {WIM_HDR_FLAG_COMPRESS_XPRESS_2,"COMPRESS_XPRESS_2"}, }; /* API function documented in wimlib.h */ WIMLIBAPI void wimlib_print_header(const WIMStruct *wim) { const struct wim_header *hdr = &wim->hdr; tprintf(T("Magic Characters = ")); for (int i = 0; i < sizeof(hdr->magic); i++) { tchar c = (u8)(hdr->magic >> ((8 * i))); if (istalpha(c)) tputchar(c); else tprintf(T("\\%o"), c); } tputchar(T('\n')); tprintf(T("Header Size = %u\n"), WIM_HEADER_DISK_SIZE); tprintf(T("Version = 0x%x\n"), hdr->wim_version); tprintf(T("Flags = 0x%x\n"), hdr->flags); for (size_t i = 0; i < ARRAY_LEN(hdr_flags); i++) if (hdr_flags[i].flag & hdr->flags) tprintf(T(" WIM_HDR_FLAG_%s is set\n"), hdr_flags[i].name); tprintf(T("Chunk Size = %u\n"), hdr->chunk_size); tfputs (T("GUID = "), stdout); print_byte_field(hdr->guid, GUID_SIZE, stdout); tputchar(T('\n')); tprintf(T("Part Number = %hu\n"), hdr->part_number); tprintf(T("Total Parts = %hu\n"), hdr->total_parts); tprintf(T("Image Count = %u\n"), hdr->image_count); tprintf(T("Blob Table Size = %"PRIu64"\n"), (u64)hdr->blob_table_reshdr.size_in_wim); tprintf(T("Blob Table Flags = 0x%hhx\n"), (u8)hdr->blob_table_reshdr.flags); tprintf(T("Blob Table Offset = %"PRIu64"\n"), hdr->blob_table_reshdr.offset_in_wim); tprintf(T("Blob Table Original_size = %"PRIu64"\n"), hdr->blob_table_reshdr.uncompressed_size); tprintf(T("XML Data Size = %"PRIu64"\n"), (u64)hdr->xml_data_reshdr.size_in_wim); tprintf(T("XML Data Flags = 0x%hhx\n"), (u8)hdr->xml_data_reshdr.flags); tprintf(T("XML Data Offset = %"PRIu64"\n"), hdr->xml_data_reshdr.offset_in_wim); tprintf(T("XML Data Original Size = %"PRIu64"\n"), hdr->xml_data_reshdr.uncompressed_size); tprintf(T("Boot Metadata Size = %"PRIu64"\n"), (u64)hdr->boot_metadata_reshdr.size_in_wim); tprintf(T("Boot Metadata Flags = 0x%hhx\n"), (u8)hdr->boot_metadata_reshdr.flags); tprintf(T("Boot Metadata Offset = %"PRIu64"\n"), hdr->boot_metadata_reshdr.offset_in_wim); tprintf(T("Boot Metadata Original Size = %"PRIu64"\n"), hdr->boot_metadata_reshdr.uncompressed_size); tprintf(T("Boot Index = %u\n"), hdr->boot_idx); tprintf(T("Integrity Size = %"PRIu64"\n"), (u64)hdr->integrity_table_reshdr.size_in_wim); tprintf(T("Integrity Flags = 0x%hhx\n"), (u8)hdr->integrity_table_reshdr.flags); tprintf(T("Integrity Offset = %"PRIu64"\n"), hdr->integrity_table_reshdr.offset_in_wim); tprintf(T("Integrity Original_size = %"PRIu64"\n"), hdr->integrity_table_reshdr.uncompressed_size); }