/*
* resource.c
*
- * Read uncompressed and compressed metadata and file resources from a WIM file.
+ * Code for reading blobs and resources, including compressed WIM resources.
*/
/*
- * Copyright (C) 2012, 2013 Eric Biggers
+ * Copyright (C) 2012, 2013, 2015 Eric Biggers
*
- * This file is part of wimlib, a library for working with WIM files.
+ * 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.
*
- * wimlib is free software; you can redistribute it and/or modify it under the
- * terms of the GNU 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.
*
- * wimlib 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 General Public License for more details.
- *
- * You should have received a copy of the GNU General Public License along with
- * wimlib; if not, see http://www.gnu.org/licenses/.
+ * You should have received a copy of the GNU Lesser General Public License
+ * along with this file; if not, see http://www.gnu.org/licenses/.
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
-#include "wimlib.h"
-#include "wimlib/dentry.h"
+#include <errno.h>
+#include <fcntl.h>
+#include <unistd.h>
+
+#include "wimlib/alloca.h"
+#include "wimlib/assert.h"
+#include "wimlib/bitops.h"
+#include "wimlib/blob_table.h"
#include "wimlib/endianness.h"
#include "wimlib/error.h"
#include "wimlib/file_io.h"
-#include "wimlib/lookup_table.h"
#include "wimlib/resource.h"
#include "wimlib/sha1.h"
+#include "wimlib/wim.h"
#ifdef __WIN32__
-/* for read_win32_file_prefix(), read_win32_encrypted_file_prefix() */
+/* for read_winnt_stream_prefix(), read_win32_encrypted_file_prefix() */
# include "wimlib/win32.h"
#endif
#ifdef WITH_NTFS_3G
-/* for read_ntfs_file_prefix() */
+/* for read_ntfs_attribute_prefix() */
# include "wimlib/ntfs_3g.h"
#endif
-#ifdef HAVE_ALLOCA_H
-# include <alloca.h>
-#endif
-#include <errno.h>
-#include <fcntl.h>
-#include <stdarg.h>
-#include <stdlib.h>
-#include <unistd.h>
/*
- * Reads all or part of a compressed WIM resource.
+ * Compressed WIM resources
+ *
+ * A compressed resource in a WIM consists of a number of compressed chunks,
+ * each of which decompresses to a fixed chunk size (given in the WIM header;
+ * usually 32768) except possibly the last, which always decompresses to any
+ * remaining bytes. In addition, immediately before the chunks, a table (the
+ * "chunk table") provides the offset, in bytes relative to the end of the chunk
+ * table, of the start of each compressed chunk, except for the first chunk
+ * which is omitted as it always has an offset of 0. Therefore, a compressed
+ * resource with N chunks will have a chunk table with N - 1 entries.
+ *
+ * Additional information:
+ *
+ * - Entries in the chunk table are 4 bytes each, except if the uncompressed
+ * size of the resource is greater than 4 GiB, in which case the entries in
+ * the chunk table are 8 bytes each. In either case, the entries are unsigned
+ * little-endian integers.
+ *
+ * - The chunk table is included in the compressed size of the resource provided
+ * in the corresponding entry in the WIM's blob table.
+ *
+ * - The compressed size of a chunk is never greater than the uncompressed size.
+ * From the compressor's point of view, chunks that would have compressed to a
+ * size greater than or equal to their original size are in fact stored
+ * uncompressed. From the decompresser's point of view, chunks with
+ * compressed size equal to their uncompressed size are in fact uncompressed.
+ *
+ * Furthermore, wimlib supports its own "pipable" WIM format, and for this the
+ * structure of compressed resources was modified to allow piped reading and
+ * writing. To make sequential writing possible, the chunk table is placed
+ * after the chunks rather than before the chunks, and to make sequential
+ * reading possible, each chunk is prefixed with a 4-byte header giving its
+ * compressed size as a 32-bit, unsigned, little-endian integer. Otherwise the
+ * details are the same.
+ */
+
+
+struct data_range {
+ u64 offset;
+ u64 size;
+};
+
+/*
+ * read_compressed_wim_resource() -
+ *
+ * Read data from a compressed WIM resource.
+ *
+ * @rdesc
+ * Description of the compressed WIM resource to read from.
+ * @ranges
+ * Nonoverlapping, nonempty ranges of the uncompressed resource data to
+ * read, sorted by increasing offset.
+ * @num_ranges
+ * Number of ranges in @ranges; must be at least 1.
+ * @cb
+ * Callback function to feed the data being read. Each call provides the
+ * next chunk of the requested data, uncompressed. Each chunk will be of
+ * nonzero size and will not cross range boundaries, but otherwise will be
+ * of unspecified size.
+ * @cb_ctx
+ * Parameter to pass to @cb_ctx.
*
- * Returns zero on success, nonzero on failure.
+ * Possible return values:
+ *
+ * WIMLIB_ERR_SUCCESS (0)
+ * WIMLIB_ERR_READ (errno set)
+ * WIMLIB_ERR_UNEXPECTED_END_OF_FILE (errno set to 0)
+ * WIMLIB_ERR_NOMEM (errno set to ENOMEM)
+ * WIMLIB_ERR_DECOMPRESSION (errno set to EINVAL)
+ *
+ * or other error code returned by the @cb function.
*/
static int
-read_compressed_resource(int in_fd,
- u64 resource_compressed_size,
- u64 resource_uncompressed_size,
- u64 resource_offset,
- int resource_ctype,
- u64 len,
- u64 offset,
- consume_data_callback_t cb,
- void *ctx_or_buf)
+read_compressed_wim_resource(const struct wim_resource_descriptor * const rdesc,
+ const struct data_range * const ranges,
+ const size_t num_ranges,
+ const consume_data_callback_t cb,
+ void * const cb_ctx)
{
int ret;
+ int errno_save;
+
+ u64 *chunk_offsets = NULL;
+ u8 *ubuf = NULL;
+ void *cbuf = NULL;
+ bool chunk_offsets_malloced = false;
+ bool ubuf_malloced = false;
+ bool cbuf_malloced = false;
+ struct wimlib_decompressor *decompressor = NULL;
+
+ /* Sanity checks */
+ wimlib_assert(rdesc != NULL);
+ wimlib_assert(resource_is_compressed(rdesc));
+ wimlib_assert(cb != NULL);
+ wimlib_assert(num_ranges != 0);
+ for (size_t i = 0; i < num_ranges; i++) {
+ DEBUG("Range %zu/%zu: %"PRIu64"@+%"PRIu64" / %"PRIu64,
+ i + 1, num_ranges, ranges[i].size, ranges[i].offset,
+ rdesc->uncompressed_size);
+ wimlib_assert(ranges[i].size != 0);
+ wimlib_assert(ranges[i].offset + ranges[i].size >= ranges[i].size);
+ wimlib_assert(ranges[i].offset + ranges[i].size <= rdesc->uncompressed_size);
+ }
+ for (size_t i = 0; i < num_ranges - 1; i++)
+ wimlib_assert(ranges[i].offset + ranges[i].size <= ranges[i + 1].offset);
+
+ /* Get the offsets of the first and last bytes of the read. */
+ const u64 first_offset = ranges[0].offset;
+ const u64 last_offset = ranges[num_ranges - 1].offset + ranges[num_ranges - 1].size - 1;
+
+ /* Get the file descriptor for the WIM. */
+ struct filedes * const in_fd = &rdesc->wim->in_fd;
+
+ /* Determine if we're reading a pipable resource from a pipe or not. */
+ const bool is_pipe_read = (rdesc->is_pipable && !filedes_is_seekable(in_fd));
+
+ /* Determine if the chunk table is in an alternate format. */
+ const bool alt_chunk_table = (rdesc->flags & WIM_RESHDR_FLAG_SOLID)
+ && !is_pipe_read;
+
+ /* Get the maximum size of uncompressed chunks in this resource, which
+ * we require be a power of 2. */
+ u64 cur_read_offset = rdesc->offset_in_wim;
+ int ctype = rdesc->compression_type;
+ u32 chunk_size = rdesc->chunk_size;
+ if (alt_chunk_table) {
+ /* Alternate chunk table format. Its header specifies the chunk
+ * size and compression format. Note: it could be read here;
+ * however, the relevant data was already loaded into @rdesc by
+ * read_blob_table(). */
+ cur_read_offset += sizeof(struct alt_chunk_table_header_disk);
+ }
- /* Trivial case */
- if (len == 0)
- return 0;
-
- int (*decompress)(const void *, unsigned, void *, unsigned);
- /* Set the appropriate decompress function. */
- if (resource_ctype == WIMLIB_COMPRESSION_TYPE_LZX)
- decompress = wimlib_lzx_decompress;
- else
- decompress = wimlib_xpress_decompress;
-
- /* The structure of a compressed resource consists of a table of chunk
- * offsets followed by the chunks themselves. Each chunk consists of
- * compressed data, and there is one chunk for each WIM_CHUNK_SIZE =
- * 32768 bytes of the uncompressed file, with the last chunk having any
- * remaining bytes.
- *
- * The chunk offsets are measured relative to the end of the chunk
- * table. The first chunk is omitted from the table in the WIM file
- * because its offset is implicitly given by the fact that it directly
- * follows the chunk table and therefore must have an offset of 0.
- */
+ if (!is_power_of_2(chunk_size)) {
+ ERROR("Invalid compressed resource: "
+ "expected power-of-2 chunk size (got %"PRIu32")",
+ chunk_size);
+ ret = WIMLIB_ERR_INVALID_CHUNK_SIZE;
+ errno = EINVAL;
+ goto out_free_memory;
+ }
- /* Calculate how many chunks the resource consists of in its entirety.
- * */
- u64 num_chunks = DIV_ROUND_UP(resource_uncompressed_size, WIM_CHUNK_SIZE);
-
- /* As mentioned, the first chunk has no entry in the chunk table. */
- u64 num_chunk_entries = num_chunks - 1;
-
-
- /* The index of the chunk that the read starts at. */
- u64 start_chunk = offset / WIM_CHUNK_SIZE;
- /* The byte offset at which the read starts, within the start chunk. */
- u64 start_chunk_offset = offset % WIM_CHUNK_SIZE;
-
- /* The index of the chunk that contains the last byte of the read. */
- u64 end_chunk = (offset + len - 1) / WIM_CHUNK_SIZE;
- /* The byte offset of the last byte of the read, within the end chunk */
- u64 end_chunk_offset = (offset + len - 1) % WIM_CHUNK_SIZE;
-
- /* Number of chunks that are actually needed to read the requested part
- * of the file. */
- u64 num_needed_chunks = end_chunk - start_chunk + 1;
-
- /* If the end chunk is not the last chunk, an extra chunk entry is
- * needed because we need to know the offset of the chunk after the last
- * chunk read to figure out the size of the last read chunk. */
- if (end_chunk != num_chunks - 1)
- num_needed_chunks++;
-
- /* According to M$'s documentation, if the uncompressed size of
- * the file is greater than 4 GB, the chunk entries are 8-byte
- * integers. Otherwise, they are 4-byte integers. */
- u64 chunk_entry_size = (resource_uncompressed_size >
- (u64)1 << 32) ? 8 : 4;
-
- /* Size of the full chunk table in the WIM file. */
- u64 chunk_table_size = chunk_entry_size * num_chunk_entries;
-
- /* Allocate the chunk table. It will only contain offsets for the
- * chunks that are actually needed for this read. */
- u64 *chunk_offsets;
- bool chunk_offsets_malloced;
- if (num_needed_chunks < 1024) {
- chunk_offsets = alloca(num_needed_chunks * sizeof(u64));
- chunk_offsets_malloced = false;
+ /* Get valid decompressor. */
+ if (ctype == rdesc->wim->decompressor_ctype &&
+ chunk_size == rdesc->wim->decompressor_max_block_size)
+ {
+ /* Cached decompressor. */
+ decompressor = rdesc->wim->decompressor;
+ rdesc->wim->decompressor_ctype = WIMLIB_COMPRESSION_TYPE_NONE;
+ rdesc->wim->decompressor = NULL;
} else {
- chunk_offsets = malloc(num_needed_chunks * sizeof(u64));
- if (!chunk_offsets) {
- ERROR("Failed to allocate chunk table "
- "with %"PRIu64" entries", num_needed_chunks);
- return WIMLIB_ERR_NOMEM;
+ ret = wimlib_create_decompressor(ctype, chunk_size,
+ &decompressor);
+ if (ret) {
+ if (ret != WIMLIB_ERR_NOMEM)
+ errno = EINVAL;
+ goto out_free_memory;
}
- chunk_offsets_malloced = true;
}
- /* Set the implicit offset of the first chunk if it is included in the
- * needed chunks.
- *
- * Note: M$'s documentation includes a picture that shows the first
- * chunk starting right after the chunk entry table, labeled as offset
- * 0x10. However, in the actual file format, the offset is measured
- * from the end of the chunk entry table, so the first chunk has an
- * offset of 0. */
- if (start_chunk == 0)
- chunk_offsets[0] = 0;
-
-
- /* Read the needed chunk offsets from the table in the WIM file. */
-
- /* Index, in the WIM file, of the first needed entry in the
- * chunk table. */
- u64 start_table_idx = (start_chunk == 0) ? 0 : start_chunk - 1;
-
- /* Number of entries we need to actually read from the chunk
- * table (excludes the implicit first chunk). */
- u64 num_needed_chunk_entries = (start_chunk == 0) ?
- num_needed_chunks - 1 : num_needed_chunks;
-
- /* Skip over unneeded chunk table entries. */
- u64 file_offset_of_needed_chunk_entries = resource_offset +
- start_table_idx * chunk_entry_size;
-
- /* Allocate a buffer into which to read the raw chunk entries. */
- void *chunk_tab_buf;
- bool chunk_tab_buf_malloced = false;
-
- /* Number of bytes we need to read from the chunk table. */
- size_t size = num_needed_chunk_entries * chunk_entry_size;
- if ((u64)size != num_needed_chunk_entries * chunk_entry_size) {
- ERROR("Compressed read request too large to fit into memory!");
- ret = WIMLIB_ERR_NOMEM;
- goto out;
- }
+ const u32 chunk_order = fls32(chunk_size);
+
+ /* Calculate the total number of chunks the resource is divided into. */
+ const u64 num_chunks = (rdesc->uncompressed_size + chunk_size - 1) >> chunk_order;
+
+ /* Calculate the 0-based indices of the first and last chunks containing
+ * data that needs to be passed to the callback. */
+ const u64 first_needed_chunk = first_offset >> chunk_order;
+ const u64 last_needed_chunk = last_offset >> chunk_order;
+
+ /* Calculate the 0-based index of the first chunk that actually needs to
+ * be read. This is normally first_needed_chunk, but for pipe reads we
+ * must always start from the 0th chunk. */
+ const u64 read_start_chunk = (is_pipe_read ? 0 : first_needed_chunk);
+
+ /* Calculate the number of chunk offsets that are needed for the chunks
+ * being read. */
+ const u64 num_needed_chunk_offsets =
+ last_needed_chunk - read_start_chunk + 1 +
+ (last_needed_chunk < num_chunks - 1);
+
+ /* Calculate the number of entries in the chunk table. Normally, it's
+ * one less than the number of chunks, since the first chunk has no
+ * entry. But in the alternate chunk table format, the chunk entries
+ * contain chunk sizes, not offsets, and there is one per chunk. */
+ const u64 num_chunk_entries = (alt_chunk_table ? num_chunks : num_chunks - 1);
+
+ /* Set the size of each chunk table entry based on the resource's
+ * uncompressed size. */
+ const u64 chunk_entry_size = get_chunk_entry_size(rdesc->uncompressed_size,
+ alt_chunk_table);
+
+ /* Calculate the size of the chunk table in bytes. */
+ const u64 chunk_table_size = num_chunk_entries * chunk_entry_size;
+
+ /* Calculate the size of the chunk table in bytes, including the header
+ * in the case of the alternate chunk table format. */
+ const u64 chunk_table_full_size =
+ (alt_chunk_table) ? chunk_table_size + sizeof(struct alt_chunk_table_header_disk)
+ : chunk_table_size;
+
+ if (!is_pipe_read) {
+ /* Read the needed chunk table entries into memory and use them
+ * to initialize the chunk_offsets array. */
+
+ u64 first_chunk_entry_to_read;
+ u64 last_chunk_entry_to_read;
+
+ if (alt_chunk_table) {
+ /* The alternate chunk table contains chunk sizes, not
+ * offsets, so we always must read all preceding entries
+ * in order to determine offsets. */
+ first_chunk_entry_to_read = 0;
+ last_chunk_entry_to_read = last_needed_chunk;
+ } else {
+ /* Here we must account for the fact that the first
+ * chunk has no explicit chunk table entry. */
- if (size < 4096) {
- chunk_tab_buf = alloca(size);
- } else {
- chunk_tab_buf = malloc(size);
- if (!chunk_tab_buf) {
- ERROR("Failed to allocate chunk table buffer of "
- "size %zu bytes", size);
- ret = WIMLIB_ERR_NOMEM;
- goto out;
+ if (read_start_chunk == 0)
+ first_chunk_entry_to_read = 0;
+ else
+ first_chunk_entry_to_read = read_start_chunk - 1;
+
+ if (last_needed_chunk == 0)
+ last_chunk_entry_to_read = 0;
+ else
+ last_chunk_entry_to_read = last_needed_chunk - 1;
+
+ if (last_needed_chunk < num_chunks - 1)
+ last_chunk_entry_to_read++;
}
- chunk_tab_buf_malloced = true;
- }
- if (full_pread(in_fd, chunk_tab_buf, size,
- file_offset_of_needed_chunk_entries) != size)
- goto read_error;
+ const u64 num_chunk_entries_to_read =
+ last_chunk_entry_to_read - first_chunk_entry_to_read + 1;
- /* Now fill in chunk_offsets from the entries we have read in
- * chunk_tab_buf. */
+ const u64 chunk_offsets_alloc_size =
+ max(num_chunk_entries_to_read,
+ num_needed_chunk_offsets) * sizeof(chunk_offsets[0]);
- u64 *chunk_tab_p = chunk_offsets;
- if (start_chunk == 0)
- chunk_tab_p++;
+ if ((size_t)chunk_offsets_alloc_size != chunk_offsets_alloc_size)
+ goto oom;
- if (chunk_entry_size == 4) {
- le32 *entries = (le32*)chunk_tab_buf;
- while (num_needed_chunk_entries--)
- *chunk_tab_p++ = le32_to_cpu(*entries++);
- } else {
- le64 *entries = (le64*)chunk_tab_buf;
- while (num_needed_chunk_entries--)
- *chunk_tab_p++ = le64_to_cpu(*entries++);
- }
+ if (chunk_offsets_alloc_size <= STACK_MAX) {
+ chunk_offsets = alloca(chunk_offsets_alloc_size);
+ } else {
+ chunk_offsets = MALLOC(chunk_offsets_alloc_size);
+ if (chunk_offsets == NULL)
+ goto oom;
+ chunk_offsets_malloced = true;
+ }
- /* Done reading the chunk table now. Now calculate the file offset for
- * the first byte of compressed data we need to read. */
+ const size_t chunk_table_size_to_read =
+ num_chunk_entries_to_read * chunk_entry_size;
- u64 cur_read_offset = resource_offset + chunk_table_size + chunk_offsets[0];
+ const u64 file_offset_of_needed_chunk_entries =
+ cur_read_offset
+ + (first_chunk_entry_to_read * chunk_entry_size)
+ + (rdesc->is_pipable ? (rdesc->size_in_wim - chunk_table_size) : 0);
- /* Pointer to current position in the output buffer for uncompressed
- * data. Alternatively, if using a callback function, we repeatedly
- * fill a temporary buffer to feed data into the callback function. */
- u8 *out_p;
- if (cb)
- out_p = alloca(WIM_CHUNK_SIZE);
- else
- out_p = ctx_or_buf;
-
- /* Buffer for compressed data. While most compressed chunks will have a
- * size much less than WIM_CHUNK_SIZE, WIM_CHUNK_SIZE - 1 is the maximum
- * size in the worst-case. This assumption is valid only if chunks that
- * happen to compress to more than the uncompressed size (i.e. a
- * sequence of random bytes) are always stored uncompressed. But this seems
- * to be the case in M$'s WIM files, even though it is undocumented. */
- void *compressed_buf = alloca(WIM_CHUNK_SIZE - 1);
-
- /* Decompress all the chunks. */
- for (u64 i = start_chunk; i <= end_chunk; i++) {
-
- /* Calculate the sizes of the compressed chunk and of the
- * uncompressed chunk. */
- unsigned compressed_chunk_size;
- unsigned uncompressed_chunk_size;
- if (i != num_chunks - 1) {
- /* All the chunks except the last one in the resource
- * expand to WIM_CHUNK_SIZE uncompressed, and the amount
- * of compressed data for the chunk is given by the
- * difference of offsets in the chunk offset table. */
- compressed_chunk_size = chunk_offsets[i + 1 - start_chunk] -
- chunk_offsets[i - start_chunk];
- uncompressed_chunk_size = WIM_CHUNK_SIZE;
+ void * const chunk_table_data =
+ (u8*)chunk_offsets +
+ chunk_offsets_alloc_size -
+ chunk_table_size_to_read;
+
+ ret = full_pread(in_fd, chunk_table_data, chunk_table_size_to_read,
+ file_offset_of_needed_chunk_entries);
+ if (ret)
+ goto read_error;
+
+ /* Now fill in chunk_offsets from the entries we have read in
+ * chunk_tab_data. We break aliasing rules here to avoid having
+ * to allocate yet another array. */
+ typedef le64 _may_alias_attribute aliased_le64_t;
+ typedef le32 _may_alias_attribute aliased_le32_t;
+ u64 * chunk_offsets_p = chunk_offsets;
+
+ if (alt_chunk_table) {
+ u64 cur_offset = 0;
+ aliased_le32_t *raw_entries = chunk_table_data;
+
+ for (size_t i = 0; i < num_chunk_entries_to_read; i++) {
+ u32 entry = le32_to_cpu(raw_entries[i]);
+ if (i >= read_start_chunk)
+ *chunk_offsets_p++ = cur_offset;
+ cur_offset += entry;
+ }
+ if (last_needed_chunk < num_chunks - 1)
+ *chunk_offsets_p = cur_offset;
} else {
- /* The last compressed chunk consists of the remaining
- * bytes in the file resource, and the last uncompressed
- * chunk has size equal to however many bytes are left-
- * that is, the remainder of the uncompressed size when
- * divided by WIM_CHUNK_SIZE.
- *
- * Note that the resource_compressed_size includes the
- * chunk table, so the size of it must be subtracted. */
- compressed_chunk_size = resource_compressed_size -
- chunk_table_size -
- chunk_offsets[i - start_chunk];
-
- uncompressed_chunk_size = resource_uncompressed_size %
- WIM_CHUNK_SIZE;
-
- /* If the remainder is 0, the last chunk actually
- * uncompresses to a full WIM_CHUNK_SIZE bytes. */
- if (uncompressed_chunk_size == 0)
- uncompressed_chunk_size = WIM_CHUNK_SIZE;
+ if (read_start_chunk == 0)
+ *chunk_offsets_p++ = 0;
+
+ if (chunk_entry_size == 4) {
+ aliased_le32_t *raw_entries = chunk_table_data;
+ for (size_t i = 0; i < num_chunk_entries_to_read; i++)
+ *chunk_offsets_p++ = le32_to_cpu(raw_entries[i]);
+ } else {
+ aliased_le64_t *raw_entries = chunk_table_data;
+ for (size_t i = 0; i < num_chunk_entries_to_read; i++)
+ *chunk_offsets_p++ = le64_to_cpu(raw_entries[i]);
+ }
}
- /* Figure out how much of this chunk we actually need to read */
- u64 start_offset;
- if (i == start_chunk)
- start_offset = start_chunk_offset;
+ /* Set offset to beginning of first chunk to read. */
+ cur_read_offset += chunk_offsets[0];
+ if (rdesc->is_pipable)
+ cur_read_offset += read_start_chunk * sizeof(struct pwm_chunk_hdr);
else
- start_offset = 0;
- u64 end_offset;
- if (i == end_chunk)
- end_offset = end_chunk_offset;
+ cur_read_offset += chunk_table_size;
+ }
+
+ /* Allocate buffer for holding the uncompressed data of each chunk. */
+ if (chunk_size <= STACK_MAX) {
+ ubuf = alloca(chunk_size);
+ } else {
+ ubuf = MALLOC(chunk_size);
+ if (ubuf == NULL)
+ goto oom;
+ ubuf_malloced = true;
+ }
+
+ /* Allocate a temporary buffer for reading compressed chunks, each of
+ * which can be at most @chunk_size - 1 bytes. This excludes compressed
+ * chunks that are a full @chunk_size bytes, which are actually stored
+ * uncompressed. */
+ if (chunk_size - 1 <= STACK_MAX) {
+ cbuf = alloca(chunk_size - 1);
+ } else {
+ cbuf = MALLOC(chunk_size - 1);
+ if (cbuf == NULL)
+ goto oom;
+ cbuf_malloced = true;
+ }
+
+ /* Set current data range. */
+ const struct data_range *cur_range = ranges;
+ const struct data_range * const end_range = &ranges[num_ranges];
+ u64 cur_range_pos = cur_range->offset;
+ u64 cur_range_end = cur_range->offset + cur_range->size;
+
+ /* Read and process each needed chunk. */
+ for (u64 i = read_start_chunk; i <= last_needed_chunk; i++) {
+
+ /* Calculate uncompressed size of next chunk. */
+ u32 chunk_usize;
+ if ((i == num_chunks - 1) && (rdesc->uncompressed_size & (chunk_size - 1)))
+ chunk_usize = (rdesc->uncompressed_size & (chunk_size - 1));
else
- end_offset = WIM_CHUNK_SIZE - 1;
-
- unsigned partial_chunk_size = end_offset + 1 - start_offset;
- bool is_partial_chunk = (partial_chunk_size != uncompressed_chunk_size);
-
- /* This is undocumented, but chunks can be uncompressed. This
- * appears to always be the case when the compressed chunk size
- * is equal to the uncompressed chunk size. */
- if (compressed_chunk_size == uncompressed_chunk_size) {
- /* Uncompressed chunk */
- if (full_pread(in_fd,
- cb ? out_p + start_offset : out_p,
- partial_chunk_size,
- cur_read_offset + start_offset) != partial_chunk_size)
- {
+ chunk_usize = chunk_size;
+
+ /* Calculate compressed size of next chunk. */
+ u32 chunk_csize;
+ if (is_pipe_read) {
+ struct pwm_chunk_hdr chunk_hdr;
+
+ ret = full_pread(in_fd, &chunk_hdr,
+ sizeof(chunk_hdr), cur_read_offset);
+ if (ret)
goto read_error;
- }
+ chunk_csize = le32_to_cpu(chunk_hdr.compressed_size);
} else {
- /* Compressed chunk */
+ if (i == num_chunks - 1) {
+ chunk_csize = rdesc->size_in_wim -
+ chunk_table_full_size -
+ chunk_offsets[i - read_start_chunk];
+ if (rdesc->is_pipable)
+ chunk_csize -= num_chunks * sizeof(struct pwm_chunk_hdr);
+ } else {
+ chunk_csize = chunk_offsets[i + 1 - read_start_chunk] -
+ chunk_offsets[i - read_start_chunk];
+ }
+ }
+ if (chunk_csize == 0 || chunk_csize > chunk_usize) {
+ ERROR("Invalid chunk size in compressed resource!");
+ errno = EINVAL;
+ ret = WIMLIB_ERR_DECOMPRESSION;
+ goto out_free_memory;
+ }
+ if (rdesc->is_pipable)
+ cur_read_offset += sizeof(struct pwm_chunk_hdr);
- /* Read the compressed data into compressed_buf. */
- if (full_pread(in_fd,
- compressed_buf,
- compressed_chunk_size,
- cur_read_offset) != compressed_chunk_size)
- {
- goto read_error;
+ /* Offsets in the uncompressed resource at which this chunk
+ * starts and ends. */
+ const u64 chunk_start_offset = i << chunk_order;
+ const u64 chunk_end_offset = chunk_start_offset + chunk_usize;
+
+ if (chunk_end_offset <= cur_range_pos) {
+
+ /* The next range does not require data in this chunk,
+ * so skip it. */
+ cur_read_offset += chunk_csize;
+ if (is_pipe_read) {
+ u8 dummy;
+
+ ret = full_pread(in_fd, &dummy, 1, cur_read_offset - 1);
+ if (ret)
+ goto read_error;
}
+ } else {
- /* For partial chunks and when writing directly to a
- * buffer, we must buffer the uncompressed data because
- * we don't need all of it. */
- if (is_partial_chunk && !cb) {
- u8 uncompressed_buf[uncompressed_chunk_size];
+ /* Read the chunk and feed data to the callback
+ * function. */
+ u8 *read_buf;
- ret = decompress(compressed_buf,
- compressed_chunk_size,
- uncompressed_buf,
- uncompressed_chunk_size);
- if (ret) {
- ret = WIMLIB_ERR_DECOMPRESSION;
- goto out;
- }
- memcpy(out_p, uncompressed_buf + start_offset,
- partial_chunk_size);
- } else {
- ret = decompress(compressed_buf,
- compressed_chunk_size,
- out_p,
- uncompressed_chunk_size);
+ if (chunk_csize == chunk_usize)
+ read_buf = ubuf;
+ else
+ read_buf = cbuf;
+
+ ret = full_pread(in_fd,
+ read_buf,
+ chunk_csize,
+ cur_read_offset);
+ if (ret)
+ goto read_error;
+
+ if (read_buf == cbuf) {
+ DEBUG("Decompressing chunk %"PRIu64" "
+ "(csize=%"PRIu32" usize=%"PRIu32")",
+ i, chunk_csize, chunk_usize);
+ ret = wimlib_decompress(cbuf,
+ chunk_csize,
+ ubuf,
+ chunk_usize,
+ decompressor);
if (ret) {
+ ERROR("Failed to decompress data!");
ret = WIMLIB_ERR_DECOMPRESSION;
- goto out;
+ errno = EINVAL;
+ goto out_free_memory;
}
}
+ cur_read_offset += chunk_csize;
+
+ /* At least one range requires data in this chunk. */
+ do {
+ size_t start, end, size;
+
+ /* Calculate how many bytes of data should be
+ * sent to the callback function, taking into
+ * account that data sent to the callback
+ * function must not overlap range boundaries.
+ */
+ start = cur_range_pos - chunk_start_offset;
+ end = min(cur_range_end, chunk_end_offset) - chunk_start_offset;
+ size = end - start;
+
+ ret = (*cb)(&ubuf[start], size, cb_ctx);
+
+ if (ret)
+ goto out_free_memory;
+
+ cur_range_pos += size;
+ if (cur_range_pos == cur_range_end) {
+ /* Advance to next range. */
+ if (++cur_range == end_range) {
+ cur_range_pos = ~0ULL;
+ } else {
+ cur_range_pos = cur_range->offset;
+ cur_range_end = cur_range->offset + cur_range->size;
+ }
+ }
+ } while (cur_range_pos < chunk_end_offset);
}
- if (cb) {
- /* Feed the data to the callback function */
- ret = cb(out_p + start_offset,
- partial_chunk_size, ctx_or_buf);
- if (ret)
- goto out;
- } else {
- /* No callback function provided; we are writing
- * directly to a buffer. Advance the pointer into this
- * buffer by the number of uncompressed bytes that were
- * written. */
- out_p += partial_chunk_size;
- }
- cur_read_offset += compressed_chunk_size;
}
+ if (is_pipe_read &&
+ last_offset == rdesc->uncompressed_size - 1 &&
+ chunk_table_size)
+ {
+ u8 dummy;
+ /* If reading a pipable resource from a pipe and the full data
+ * was requested, skip the chunk table at the end so that the
+ * file descriptor is fully clear of the resource after this
+ * returns. */
+ cur_read_offset += chunk_table_size;
+ ret = full_pread(in_fd, &dummy, 1, cur_read_offset - 1);
+ if (ret)
+ goto read_error;
+ }
ret = 0;
-out:
+
+out_free_memory:
+ errno_save = errno;
+ if (decompressor) {
+ wimlib_free_decompressor(rdesc->wim->decompressor);
+ rdesc->wim->decompressor = decompressor;
+ rdesc->wim->decompressor_ctype = ctype;
+ rdesc->wim->decompressor_max_block_size = chunk_size;
+ }
if (chunk_offsets_malloced)
FREE(chunk_offsets);
- if (chunk_tab_buf_malloced)
- FREE(chunk_tab_buf);
+ if (ubuf_malloced)
+ FREE(ubuf);
+ if (cbuf_malloced)
+ FREE(cbuf);
+ errno = errno_save;
return ret;
+oom:
+ ERROR("Not enough memory available to read size=%"PRIu64" bytes "
+ "from compressed WIM resource!", last_offset - first_offset + 1);
+ errno = ENOMEM;
+ ret = WIMLIB_ERR_NOMEM;
+ goto out_free_memory;
+
read_error:
- ERROR_WITH_ERRNO("Error reading compressed file resource");
- ret = WIMLIB_ERR_READ;
- goto out;
+ ERROR_WITH_ERRNO("Error reading compressed WIM resource!");
+ goto out_free_memory;
}
-/* Translates a WIM resource entry from the on-disk format to an in-memory
- * format. */
-void
-get_resource_entry(const struct resource_entry_disk *disk_entry,
- struct resource_entry *entry)
-{
- /* Note: disk_entry may not be 8 byte aligned--- in that case, the
- * offset and original_size members will be unaligned. (This should be
- * okay since `struct resource_entry_disk' is declared as packed.) */
-
- /* Read the size and flags into a bitfield portably... */
- entry->size = (((u64)disk_entry->size[0] << 0) |
- ((u64)disk_entry->size[1] << 8) |
- ((u64)disk_entry->size[2] << 16) |
- ((u64)disk_entry->size[3] << 24) |
- ((u64)disk_entry->size[4] << 32) |
- ((u64)disk_entry->size[5] << 40) |
- ((u64)disk_entry->size[6] << 48));
- entry->flags = disk_entry->flags;
- entry->offset = le64_to_cpu(disk_entry->offset);
- entry->original_size = le64_to_cpu(disk_entry->original_size);
-
- /* offset and original_size are truncated to 62 bits to avoid possible
- * overflows, when converting to a signed 64-bit integer (off_t) or when
- * adding size or original_size. This is okay since no one would ever
- * actually have a WIM bigger than 4611686018427387903 bytes... */
- if (entry->offset & 0xc000000000000000ULL) {
- WARNING("Truncating offset in resource entry");
- entry->offset &= 0x3fffffffffffffffULL;
+static int
+fill_zeroes(u64 size, consume_data_callback_t cb, void *cb_ctx)
+{
+ if (unlikely(size)) {
+ u8 buf[min(size, BUFFER_SIZE)];
+
+ memset(buf, 0, sizeof(buf));
+
+ do {
+ size_t len;
+ int ret;
+
+ len = min(size, BUFFER_SIZE);
+ ret = cb(buf, len, cb_ctx);
+ if (ret)
+ return ret;
+ size -= len;
+ } while (size);
}
- if (entry->original_size & 0xc000000000000000ULL) {
- WARNING("Truncating original_size in resource entry");
- entry->original_size &= 0x3fffffffffffffffULL;
+ return 0;
+}
+
+/* Read raw data from a file descriptor at the specified offset, feeding the
+ * data it in chunks into the specified callback function. */
+static int
+read_raw_file_data(struct filedes *in_fd, u64 offset, u64 size,
+ consume_data_callback_t cb, void *cb_ctx)
+{
+ u8 buf[BUFFER_SIZE];
+ size_t bytes_to_read;
+ int ret;
+
+ while (size) {
+ bytes_to_read = min(sizeof(buf), size);
+ ret = full_pread(in_fd, buf, bytes_to_read, offset);
+ if (ret) {
+ ERROR_WITH_ERRNO("Read error");
+ return ret;
+ }
+ ret = cb(buf, bytes_to_read, cb_ctx);
+ if (ret)
+ return ret;
+ size -= bytes_to_read;
+ offset += bytes_to_read;
}
+ return 0;
}
-/* Translates a WIM resource entry from an in-memory format into the on-disk
- * format. */
-void
-put_resource_entry(const struct resource_entry *entry,
- struct resource_entry_disk *disk_entry)
-{
- /* Note: disk_entry may not be 8 byte aligned--- in that case, the
- * offset and original_size members will be unaligned. (This should be
- * okay since `struct resource_entry_disk' is declared as packed.) */
- u64 size = entry->size;
-
- disk_entry->size[0] = size >> 0;
- disk_entry->size[1] = size >> 8;
- disk_entry->size[2] = size >> 16;
- disk_entry->size[3] = size >> 24;
- disk_entry->size[4] = size >> 32;
- disk_entry->size[5] = size >> 40;
- disk_entry->size[6] = size >> 48;
- disk_entry->flags = entry->flags;
- disk_entry->offset = cpu_to_le64(entry->offset);
- disk_entry->original_size = cpu_to_le64(entry->original_size);
+/* A consume_data_callback_t implementation that simply concatenates all chunks
+ * into a buffer. */
+static int
+bufferer_cb(const void *chunk, size_t size, void *_ctx)
+{
+ u8 **buf_p = _ctx;
+
+ *buf_p = mempcpy(*buf_p, chunk, size);
+ return 0;
}
+/*
+ * read_partial_wim_resource()-
+ *
+ * Read a range of data from an uncompressed or compressed resource in a WIM
+ * file.
+ *
+ * @rdesc
+ * Description of the WIM resource to read from.
+ * @offset
+ * Offset within the uncompressed resource at which to start reading.
+ * @size
+ * Number of bytes to read.
+ * @cb
+ * Callback function to feed the data being read. Each call provides the
+ * next chunk of the requested data, uncompressed. Each chunk will be of
+ * nonzero size and will not cross range boundaries, but otherwise will be
+ * of unspecified size.
+ * @cb_ctx
+ * Parameter to pass to @cb_ctx.
+ *
+ * Return values:
+ * WIMLIB_ERR_SUCCESS (0)
+ * WIMLIB_ERR_READ (errno set)
+ * WIMLIB_ERR_UNEXPECTED_END_OF_FILE (errno set to 0)
+ * WIMLIB_ERR_NOMEM (errno set to ENOMEM)
+ * WIMLIB_ERR_DECOMPRESSION (errno set to EINVAL)
+ *
+ * or other error code returned by the @cb function.
+ */
static int
-read_partial_wim_resource(const struct wim_lookup_table_entry *lte,
- u64 size,
- consume_data_callback_t cb,
- void *ctx_or_buf,
- int flags,
- u64 offset)
-{
- WIMStruct *wim;
- int in_fd;
- int ret;
+read_partial_wim_resource(const struct wim_resource_descriptor *rdesc,
+ u64 offset, u64 size,
+ consume_data_callback_t cb, void *cb_ctx)
+{
+ /* Sanity checks. */
+ wimlib_assert(offset + size >= offset);
+ wimlib_assert(offset + size <= rdesc->uncompressed_size);
- wimlib_assert(lte->resource_location == RESOURCE_IN_WIM);
+ DEBUG("Reading %"PRIu64" @ %"PRIu64" from WIM resource "
+ "%"PRIu64" => %"PRIu64" @ %"PRIu64,
+ size, offset, rdesc->uncompressed_size,
+ rdesc->size_in_wim, rdesc->offset_in_wim);
- wim = lte->wim;
- in_fd = wim->in_fd;
+ /* Trivial case. */
+ if (size == 0)
+ return 0;
- if (lte->resource_entry.flags & WIM_RESHDR_FLAG_COMPRESSED &&
- !(flags & WIMLIB_RESOURCE_FLAG_RAW))
- {
- ret = read_compressed_resource(in_fd,
- lte->resource_entry.size,
- lte->resource_entry.original_size,
- lte->resource_entry.offset,
- wim->compression_type,
- size,
- offset,
- cb,
- ctx_or_buf);
+ if (resource_is_compressed(rdesc)) {
+ struct data_range range = {
+ .offset = offset,
+ .size = size,
+ };
+ return read_compressed_wim_resource(rdesc, &range, 1,
+ cb, cb_ctx);
} else {
- offset += lte->resource_entry.offset;
- if (cb) {
- /* Send data to callback function */
- u8 buf[min(WIM_CHUNK_SIZE, size)];
- while (size) {
- size_t bytes_to_read = min(WIM_CHUNK_SIZE, size);
- size_t bytes_read = full_pread(in_fd, buf,
- bytes_to_read, offset);
- if (bytes_read != bytes_to_read)
- goto read_error;
- ret = cb(buf, bytes_read, ctx_or_buf);
- if (ret)
- goto out;
- size -= bytes_read;
- offset += bytes_read;
- }
+ /* Reading uncompressed resource. For completeness, handle the
+ * weird case where size_in_wim < uncompressed_size. */
+
+ u64 read_size;
+ u64 zeroes_size;
+ int ret;
+
+ if (likely(offset + size <= rdesc->size_in_wim) ||
+ rdesc->is_pipable)
+ {
+ read_size = size;
+ zeroes_size = 0;
} else {
- /* Send data directly to a buffer */
- if (full_pread(in_fd, ctx_or_buf, size, offset) != size)
- goto read_error;
+ if (offset >= rdesc->size_in_wim) {
+ read_size = 0;
+ zeroes_size = size;
+ } else {
+ read_size = rdesc->size_in_wim - offset;
+ zeroes_size = offset + size - rdesc->size_in_wim;
+ }
}
- ret = 0;
- }
- goto out;
-read_error:
- ERROR_WITH_ERRNO("Error reading data from WIM");
- ret = WIMLIB_ERR_READ;
-out:
- if (ret) {
- if (errno == 0)
- errno = EIO;
+
+ ret = read_raw_file_data(&rdesc->wim->in_fd,
+ rdesc->offset_in_wim + offset,
+ read_size,
+ cb,
+ cb_ctx);
+ if (ret)
+ return ret;
+
+ return fill_zeroes(zeroes_size, cb, cb_ctx);
}
- return ret;
}
-
+/* Read the specified range of uncompressed data from the specified blob, which
+ * must be located into a WIM file, into the specified buffer. */
int
-read_partial_wim_resource_into_buf(const struct wim_lookup_table_entry *lte,
- size_t size, u64 offset, void *buf)
+read_partial_wim_blob_into_buf(const struct blob_descriptor *blob,
+ size_t size, u64 offset, void *_buf)
{
- return read_partial_wim_resource(lte, size, NULL, buf, 0, offset);
+ u8 *buf = _buf;
+
+ wimlib_assert(blob->blob_location == BLOB_IN_WIM);
+
+ return read_partial_wim_resource(blob->rdesc,
+ blob->offset_in_res + offset,
+ size,
+ bufferer_cb,
+ &buf);
}
+/* A consume_data_callback_t implementation that simply ignores the data
+ * received. */
static int
-read_wim_resource_prefix(const struct wim_lookup_table_entry *lte,
- u64 size,
- consume_data_callback_t cb,
- void *ctx_or_buf,
- int flags)
+skip_chunk_cb(const void *chunk, size_t size, void *_ctx)
{
- return read_partial_wim_resource(lte, size, cb, ctx_or_buf, flags, 0);
+ return 0;
}
+/* Skip over the data of the specified WIM resource. */
+int
+skip_wim_resource(struct wim_resource_descriptor *rdesc)
+{
+ DEBUG("Skipping resource (size=%"PRIu64")", rdesc->uncompressed_size);
+ return read_partial_wim_resource(rdesc, 0, rdesc->uncompressed_size,
+ skip_chunk_cb, NULL);
+}
-#ifndef __WIN32__
static int
-read_file_on_disk_prefix(const struct wim_lookup_table_entry *lte,
- u64 size,
- consume_data_callback_t cb,
- void *ctx_or_buf,
- int _ignored_flags)
+read_wim_blob_prefix(const struct blob_descriptor *blob, u64 size,
+ consume_data_callback_t cb, void *cb_ctx)
+{
+ return read_partial_wim_resource(blob->rdesc, blob->offset_in_res, size,
+ cb, cb_ctx);
+}
+
+/* This function handles reading blob data that is located in an external file,
+ * such as a file that has been added to the WIM image through execution of a
+ * wimlib_add_command.
+ *
+ * This assumes the file can be accessed using the standard POSIX open(),
+ * read(), and close(). On Windows this will not necessarily be the case (since
+ * the file may need FILE_FLAG_BACKUP_SEMANTICS to be opened, or the file may be
+ * encrypted), so Windows uses its own code for its equivalent case. */
+static int
+read_file_on_disk_prefix(const struct blob_descriptor *blob, u64 size,
+ consume_data_callback_t cb, void *cb_ctx)
{
- const tchar *filename = lte->file_on_disk;
int ret;
- int fd;
- size_t bytes_read;
+ int raw_fd;
+ struct filedes fd;
+
+ wimlib_assert(size <= blob->size);
- fd = open(filename, O_RDONLY);
- if (fd < 0) {
- ERROR_WITH_ERRNO("Can't open \"%"TS"\"", filename);
+ DEBUG("Reading %"PRIu64" bytes from \"%"TS"\"", size, blob->file_on_disk);
+
+ raw_fd = topen(blob->file_on_disk, O_BINARY | O_RDONLY);
+ if (raw_fd < 0) {
+ ERROR_WITH_ERRNO("Can't open \"%"TS"\"", blob->file_on_disk);
return WIMLIB_ERR_OPEN;
}
- if (cb) {
- /* Send data to callback function */
- u8 buf[min(WIM_CHUNK_SIZE, size)];
- size_t bytes_to_read;
- while (size) {
- bytes_to_read = min(WIM_CHUNK_SIZE, size);
- bytes_read = full_read(fd, buf, bytes_to_read);
- if (bytes_read != bytes_to_read)
- goto read_error;
- ret = cb(buf, bytes_read, ctx_or_buf);
- if (ret)
- goto out_close;
- size -= bytes_read;
- }
- } else {
- /* Send data directly to a buffer */
- bytes_read = full_read(fd, ctx_or_buf, size);
- if (bytes_read != size)
- goto read_error;
- }
- ret = 0;
- goto out_close;
-read_error:
- ERROR_WITH_ERRNO("Error reading \"%"TS"\"", filename);
- ret = WIMLIB_ERR_READ;
-out_close:
- close(fd);
+ filedes_init(&fd, raw_fd);
+ ret = read_raw_file_data(&fd, 0, size, cb, cb_ctx);
+ filedes_close(&fd);
return ret;
}
-#endif /* !__WIN32__ */
+#ifdef WITH_FUSE
static int
-read_buffer_prefix(const struct wim_lookup_table_entry *lte,
- u64 size, consume_data_callback_t cb,
- void *ctx_or_buf, int _ignored_flags)
+read_staging_file_prefix(const struct blob_descriptor *blob, u64 size,
+ consume_data_callback_t cb, void *cb_ctx)
{
- const void *inbuf = lte->attached_buffer;
+ int raw_fd;
+ struct filedes fd;
int ret;
- if (cb) {
- while (size) {
- size_t chunk_size = min(WIM_CHUNK_SIZE, size);
- ret = cb(inbuf, chunk_size, ctx_or_buf);
- if (ret)
- return ret;
- size -= chunk_size;
- inbuf += chunk_size;
- }
- } else {
- memcpy(ctx_or_buf, inbuf, size);
+ wimlib_assert(size <= blob->size);
+
+ DEBUG("Reading %"PRIu64" bytes from staging file \"%s\"",
+ size, blob->staging_file_name);
+
+ raw_fd = openat(blob->staging_dir_fd, blob->staging_file_name,
+ O_RDONLY | O_NOFOLLOW);
+ if (raw_fd < 0) {
+ ERROR_WITH_ERRNO("Can't open staging file \"%s\"",
+ blob->staging_file_name);
+ return WIMLIB_ERR_OPEN;
}
- return 0;
+ filedes_init(&fd, raw_fd);
+ ret = read_raw_file_data(&fd, 0, size, cb, cb_ctx);
+ filedes_close(&fd);
+ return ret;
}
+#endif
-typedef int (*read_resource_prefix_handler_t)(const struct wim_lookup_table_entry *lte,
- u64 size,
- consume_data_callback_t cb,
- void *ctx_or_buf,
- int flags);
+/* This function handles the trivial case of reading blob data that is, in fact,
+ * already located in an in-memory buffer. */
+static int
+read_buffer_prefix(const struct blob_descriptor *blob,
+ u64 size, consume_data_callback_t cb, void *cb_ctx)
+{
+ wimlib_assert(size <= blob->size);
+ return (*cb)(blob->attached_buffer, size, cb_ctx);
+}
+
+typedef int (*read_blob_prefix_handler_t)(const struct blob_descriptor *blob,
+ u64 size,
+ consume_data_callback_t cb,
+ void *cb_ctx);
/*
- * Read the first @size bytes from a generic "resource", which may be located in
- * the WIM (compressed or uncompressed), in an external file, or directly in an
- * in-memory buffer.
+ * read_blob_prefix()-
*
- * Feed the data either to a callback function (cb != NULL, passing it
- * ctx_or_buf), or write it directly into a buffer (cb == NULL, ctx_or_buf
- * specifies the buffer, which must have room for @size bytes).
+ * Reads the first @size bytes from a generic "blob", which may be located in
+ * any one of several locations, such as in a WIM file (compressed or
+ * uncompressed), in an external file, or directly in an in-memory buffer.
*
- * When using a callback function, it is called with chunks up to 32768 bytes in
- * size until the resource is exhausted.
+ * This function feeds the data to a callback function @cb in chunks of
+ * unspecified size.
*
- * If the resource is located in a WIM file, @flags can be:
- * * WIMLIB_RESOURCE_FLAG_RAW if the raw compressed data is to be supplied
- * instead of the uncompressed data.
- * Otherwise, the @flags are ignored.
+ * Returns 0 on success; nonzero on error. A nonzero value will be returned if
+ * the blob data cannot be successfully read (for a number of different reasons,
+ * depending on the blob location), or if @cb returned nonzero in which case
+ * that error code will be returned.
*/
-int
-read_resource_prefix(const struct wim_lookup_table_entry *lte,
- u64 size, consume_data_callback_t cb, void *ctx_or_buf,
- int flags)
-{
- static const read_resource_prefix_handler_t handlers[] = {
- [RESOURCE_IN_WIM] = read_wim_resource_prefix,
- #ifndef __WIN32__
- [RESOURCE_IN_FILE_ON_DISK] = read_file_on_disk_prefix,
- #endif
- [RESOURCE_IN_ATTACHED_BUFFER] = read_buffer_prefix,
+static int
+read_blob_prefix(const struct blob_descriptor *blob, u64 size,
+ consume_data_callback_t cb, void *cb_ctx)
+{
+ static const read_blob_prefix_handler_t handlers[] = {
+ [BLOB_IN_WIM] = read_wim_blob_prefix,
+ [BLOB_IN_FILE_ON_DISK] = read_file_on_disk_prefix,
+ [BLOB_IN_ATTACHED_BUFFER] = read_buffer_prefix,
#ifdef WITH_FUSE
- [RESOURCE_IN_STAGING_FILE] = read_file_on_disk_prefix,
+ [BLOB_IN_STAGING_FILE] = read_staging_file_prefix,
#endif
#ifdef WITH_NTFS_3G
- [RESOURCE_IN_NTFS_VOLUME] = read_ntfs_file_prefix,
+ [BLOB_IN_NTFS_VOLUME] = read_ntfs_attribute_prefix,
#endif
#ifdef __WIN32__
- [RESOURCE_WIN32] = read_win32_file_prefix,
- [RESOURCE_WIN32_ENCRYPTED] = read_win32_encrypted_file_prefix,
+ [BLOB_IN_WINNT_FILE_ON_DISK] = read_winnt_stream_prefix,
+ [BLOB_WIN32_ENCRYPTED] = read_win32_encrypted_file_prefix,
#endif
};
- wimlib_assert(lte->resource_location < ARRAY_LEN(handlers)
- && handlers[lte->resource_location] != NULL);
- return handlers[lte->resource_location](lte, size, cb, ctx_or_buf, flags);
+ wimlib_assert(blob->blob_location < ARRAY_LEN(handlers)
+ && handlers[blob->blob_location] != NULL);
+ return handlers[blob->blob_location](blob, size, cb, cb_ctx);
+}
+
+/* Read the full uncompressed data of the specified blob into the specified
+ * buffer, which must have space for at least blob->size bytes. */
+int
+read_full_blob_into_buf(const struct blob_descriptor *blob, void *_buf)
+{
+ u8 *buf = _buf;
+ return read_blob_prefix(blob, blob->size, bufferer_cb, &buf);
}
+/* Retrieve the full uncompressed data of the specified blob. A buffer large
+ * enough hold the data is allocated and returned in @buf_ret. */
int
-read_full_resource_into_buf(const struct wim_lookup_table_entry *lte,
- void *buf)
+read_full_blob_into_alloc_buf(const struct blob_descriptor *blob, void **buf_ret)
{
- return read_resource_prefix(lte, wim_resource_size(lte), NULL, buf, 0);
+ int ret;
+ void *buf;
+
+ if ((size_t)blob->size != blob->size) {
+ ERROR("Can't read %"PRIu64" byte blob into memory", blob->size);
+ return WIMLIB_ERR_NOMEM;
+ }
+
+ buf = MALLOC(blob->size);
+ if (buf == NULL)
+ return WIMLIB_ERR_NOMEM;
+
+ ret = read_full_blob_into_buf(blob, buf);
+ if (ret) {
+ FREE(buf);
+ return ret;
+ }
+
+ *buf_ret = buf;
+ return 0;
+}
+
+/* Retrieve the full uncompressed data of a WIM resource specified as a raw
+ * `wim_reshdr' and the corresponding WIM file. A buffer large enough hold the
+ * data is allocated and returned in @buf_ret. */
+int
+wim_reshdr_to_data(const struct wim_reshdr *reshdr, WIMStruct *wim, void **buf_ret)
+{
+ struct wim_resource_descriptor rdesc;
+ struct blob_descriptor blob;
+
+ wim_res_hdr_to_desc(reshdr, wim, &rdesc);
+ blob_set_is_located_in_nonsolid_wim_resource(&blob, &rdesc);
+
+ return read_full_blob_into_alloc_buf(&blob, buf_ret);
+}
+
+int
+wim_reshdr_to_hash(const struct wim_reshdr *reshdr, WIMStruct *wim,
+ u8 hash[SHA1_HASH_SIZE])
+{
+ struct wim_resource_descriptor rdesc;
+ struct blob_descriptor blob;
+ int ret;
+
+ wim_res_hdr_to_desc(reshdr, wim, &rdesc);
+ blob_set_is_located_in_nonsolid_wim_resource(&blob, &rdesc);
+ blob.unhashed = 1;
+
+ ret = sha1_blob(&blob);
+ if (ret)
+ return ret;
+ copy_hash(hash, blob.hash);
+ return 0;
+}
+
+struct blobifier_context {
+ struct read_blob_list_callbacks cbs;
+ struct blob_descriptor *cur_blob;
+ struct blob_descriptor *next_blob;
+ u64 cur_blob_offset;
+ struct blob_descriptor *final_blob;
+ size_t list_head_offset;
+};
+
+static struct blob_descriptor *
+next_blob(struct blob_descriptor *blob, size_t list_head_offset)
+{
+ struct list_head *cur;
+
+ cur = (struct list_head*)((u8*)blob + list_head_offset);
+
+ return (struct blob_descriptor*)((u8*)cur->next - list_head_offset);
+}
+
+/* A consume_data_callback_t implementation that translates raw resource data
+ * into blobs, calling the begin_blob, consume_chunk, and end_blob callback
+ * functions as appropriate. */
+static int
+blobifier_cb(const void *chunk, size_t size, void *_ctx)
+{
+ struct blobifier_context *ctx = _ctx;
+ int ret;
+
+ DEBUG("%zu bytes passed to blobifier", size);
+
+ wimlib_assert(ctx->cur_blob != NULL);
+ wimlib_assert(size <= ctx->cur_blob->size - ctx->cur_blob_offset);
+
+ if (ctx->cur_blob_offset == 0) {
+
+ /* Starting a new blob. */
+ DEBUG("Begin new blob (size=%"PRIu64").", ctx->cur_blob->size);
+
+ ret = (*ctx->cbs.begin_blob)(ctx->cur_blob,
+ ctx->cbs.begin_blob_ctx);
+ if (ret)
+ return ret;
+ }
+
+ /* Consume the chunk. */
+ ret = (*ctx->cbs.consume_chunk)(chunk, size,
+ ctx->cbs.consume_chunk_ctx);
+ ctx->cur_blob_offset += size;
+ if (ret)
+ return ret;
+
+ if (ctx->cur_blob_offset == ctx->cur_blob->size) {
+ /* Finished reading all the data for a blob. */
+
+ ctx->cur_blob_offset = 0;
+
+ DEBUG("End blob (size=%"PRIu64").", ctx->cur_blob->size);
+ ret = (*ctx->cbs.end_blob)(ctx->cur_blob, 0,
+ ctx->cbs.end_blob_ctx);
+ if (ret)
+ return ret;
+
+ /* Advance to next blob. */
+ ctx->cur_blob = ctx->next_blob;
+ if (ctx->cur_blob != NULL) {
+ if (ctx->cur_blob != ctx->final_blob)
+ ctx->next_blob = next_blob(ctx->cur_blob,
+ ctx->list_head_offset);
+ else
+ ctx->next_blob = NULL;
+ }
+ }
+ return 0;
}
-struct extract_ctx {
+struct hasher_context {
SHA_CTX sha_ctx;
- consume_data_callback_t extract_chunk;
- void *extract_chunk_arg;
+ int flags;
+ struct read_blob_list_callbacks cbs;
};
+/* Callback for starting to read a blob while calculating its SHA-1 message
+ * digest. */
static int
-extract_chunk_sha1_wrapper(const void *chunk, size_t chunk_size,
- void *_ctx)
+hasher_begin_blob(struct blob_descriptor *blob, void *_ctx)
{
- struct extract_ctx *ctx = _ctx;
+ struct hasher_context *ctx = _ctx;
- sha1_update(&ctx->sha_ctx, chunk, chunk_size);
- return ctx->extract_chunk(chunk, chunk_size, ctx->extract_chunk_arg);
+ sha1_init(&ctx->sha_ctx);
+
+ if (ctx->cbs.begin_blob == NULL)
+ return 0;
+ else
+ return (*ctx->cbs.begin_blob)(blob, ctx->cbs.begin_blob_ctx);
}
-/* Extracts the first @size bytes of a WIM resource to somewhere. In the
- * process, the SHA1 message digest of the resource is checked if the full
- * resource is being extracted.
- *
- * @extract_chunk is a function that is called to extract each chunk of the
- * resource. */
-int
-extract_wim_resource(const struct wim_lookup_table_entry *lte,
- u64 size,
- consume_data_callback_t extract_chunk,
- void *extract_chunk_arg)
+/* A consume_data_callback_t implementation that continues calculating the SHA-1
+ * message digest of the blob being read, then optionally passes the data on to
+ * another consume_data_callback_t implementation. This allows checking the
+ * SHA-1 message digest of a blob being extracted, for example. */
+static int
+hasher_consume_chunk(const void *chunk, size_t size, void *_ctx)
{
+ struct hasher_context *ctx = _ctx;
+
+ sha1_update(&ctx->sha_ctx, chunk, size);
+ if (ctx->cbs.consume_chunk == NULL)
+ return 0;
+ else
+ return (*ctx->cbs.consume_chunk)(chunk, size, ctx->cbs.consume_chunk_ctx);
+}
+
+/* Callback for finishing reading a blob while calculating its SHA-1 message
+ * digest. */
+static int
+hasher_end_blob(struct blob_descriptor *blob, int status, void *_ctx)
+{
+ struct hasher_context *ctx = _ctx;
+ u8 hash[SHA1_HASH_SIZE];
int ret;
- if (size == wim_resource_size(lte)) {
- /* Do SHA1 */
- struct extract_ctx ctx;
- ctx.extract_chunk = extract_chunk;
- ctx.extract_chunk_arg = extract_chunk_arg;
- sha1_init(&ctx.sha_ctx);
- ret = read_resource_prefix(lte, size,
- extract_chunk_sha1_wrapper,
- &ctx, 0);
- if (ret == 0) {
- u8 hash[SHA1_HASH_SIZE];
- sha1_final(hash, &ctx.sha_ctx);
- if (!hashes_equal(hash, lte->hash)) {
+
+ if (status) {
+ /* Error occurred; the full blob may not have been read. */
+ ret = status;
+ goto out_next_cb;
+ }
+
+ /* Retrieve the final SHA-1 message digest. */
+ sha1_final(hash, &ctx->sha_ctx);
+
+ if (blob->unhashed) {
+ if (ctx->flags & COMPUTE_MISSING_BLOB_HASHES) {
+ /* No SHA-1 message digest was previously present for the
+ * blob. Set it to the one just calculated. */
+ DEBUG("Set SHA-1 message digest for blob "
+ "(size=%"PRIu64").", blob->size);
+ copy_hash(blob->hash, hash);
+ }
+ } else {
+ if (ctx->flags & VERIFY_BLOB_HASHES) {
+ /* The blob already had a SHA-1 message digest present.
+ * Verify that it is the same as the calculated value.
+ */
+ if (!hashes_equal(hash, blob->hash)) {
if (wimlib_print_errors) {
- ERROR("Invalid SHA1 message digest "
- "on the following WIM resource:");
- print_lookup_table_entry(lte, stderr);
- if (lte->resource_location == RESOURCE_IN_WIM)
- ERROR("The WIM file appears to be corrupt!");
+ tchar expected_hashstr[SHA1_HASH_SIZE * 2 + 1];
+ tchar actual_hashstr[SHA1_HASH_SIZE * 2 + 1];
+ sprint_hash(blob->hash, expected_hashstr);
+ sprint_hash(hash, actual_hashstr);
+ ERROR("The blob is corrupted!\n"
+ " (Expected SHA-1=%"TS",\n"
+ " got SHA-1=%"TS")",
+ expected_hashstr, actual_hashstr);
}
ret = WIMLIB_ERR_INVALID_RESOURCE_HASH;
+ errno = EINVAL;
+ goto out_next_cb;
}
+ DEBUG("SHA-1 message digest okay for "
+ "blob (size=%"PRIu64").", blob->size);
}
- } else {
- /* Don't do SHA1 */
- ret = read_resource_prefix(lte, size, extract_chunk,
- extract_chunk_arg, 0);
}
- return ret;
+ ret = 0;
+out_next_cb:
+ if (ctx->cbs.end_blob == NULL)
+ return ret;
+ else
+ return (*ctx->cbs.end_blob)(blob, ret, ctx->cbs.end_blob_ctx);
}
static int
-extract_wim_chunk_to_fd(const void *buf, size_t len, void *_fd_p)
+read_full_blob_with_cbs(struct blob_descriptor *blob,
+ const struct read_blob_list_callbacks *cbs)
{
- int fd = *(int*)_fd_p;
- ssize_t ret = full_write(fd, buf, len);
- if (ret < len) {
- ERROR_WITH_ERRNO("Error writing to file descriptor");
- return WIMLIB_ERR_WRITE;
+ int ret;
+
+ ret = (*cbs->begin_blob)(blob, cbs->begin_blob_ctx);
+ if (ret)
+ return ret;
+
+ ret = read_blob_prefix(blob, blob->size, cbs->consume_chunk,
+ cbs->consume_chunk_ctx);
+
+ return (*cbs->end_blob)(blob, ret, cbs->end_blob_ctx);
+}
+
+/* Read the full data of the specified blob, passing the data into the specified
+ * callbacks (all of which are optional) and either checking or computing the
+ * SHA-1 message digest of the blob. */
+static int
+read_full_blob_with_sha1(struct blob_descriptor *blob,
+ const struct read_blob_list_callbacks *cbs)
+{
+ struct hasher_context hasher_ctx = {
+ .flags = VERIFY_BLOB_HASHES | COMPUTE_MISSING_BLOB_HASHES,
+ .cbs = *cbs,
+ };
+ struct read_blob_list_callbacks hasher_cbs = {
+ .begin_blob = hasher_begin_blob,
+ .begin_blob_ctx = &hasher_ctx,
+ .consume_chunk = hasher_consume_chunk,
+ .consume_chunk_ctx = &hasher_ctx,
+ .end_blob = hasher_end_blob,
+ .end_blob_ctx = &hasher_ctx,
+ };
+ return read_full_blob_with_cbs(blob, &hasher_cbs);
+}
+
+static int
+read_blobs_in_solid_resource(struct blob_descriptor *first_blob,
+ struct blob_descriptor *last_blob,
+ u64 blob_count,
+ size_t list_head_offset,
+ const struct read_blob_list_callbacks *sink_cbs)
+{
+ struct data_range *ranges;
+ bool ranges_malloced;
+ struct blob_descriptor *cur_blob;
+ size_t i;
+ int ret;
+ u64 ranges_alloc_size;
+
+ DEBUG("Reading %"PRIu64" blobs combined in same WIM resource",
+ blob_count);
+
+ /* Setup data ranges array (one range per blob to read); this way
+ * read_compressed_wim_resource() does not need to be aware of blobs.
+ */
+
+ ranges_alloc_size = blob_count * sizeof(ranges[0]);
+
+ if (unlikely((size_t)ranges_alloc_size != ranges_alloc_size)) {
+ ERROR("Too many blobs in one resource!");
+ return WIMLIB_ERR_NOMEM;
+ }
+ if (likely(ranges_alloc_size <= STACK_MAX)) {
+ ranges = alloca(ranges_alloc_size);
+ ranges_malloced = false;
} else {
- return 0;
+ ranges = MALLOC(ranges_alloc_size);
+ if (ranges == NULL) {
+ ERROR("Too many blobs in one resource!");
+ return WIMLIB_ERR_NOMEM;
+ }
+ ranges_malloced = true;
+ }
+
+ for (i = 0, cur_blob = first_blob;
+ i < blob_count;
+ i++, cur_blob = next_blob(cur_blob, list_head_offset))
+ {
+ ranges[i].offset = cur_blob->offset_in_res;
+ ranges[i].size = cur_blob->size;
+ }
+
+ struct blobifier_context blobifier_ctx = {
+ .cbs = *sink_cbs,
+ .cur_blob = first_blob,
+ .next_blob = next_blob(first_blob, list_head_offset),
+ .cur_blob_offset = 0,
+ .final_blob = last_blob,
+ .list_head_offset = list_head_offset,
+ };
+
+ ret = read_compressed_wim_resource(first_blob->rdesc,
+ ranges,
+ blob_count,
+ blobifier_cb,
+ &blobifier_ctx);
+
+ if (ranges_malloced)
+ FREE(ranges);
+
+ if (ret) {
+ if (blobifier_ctx.cur_blob_offset != 0) {
+ ret = (*blobifier_ctx.cbs.end_blob)
+ (blobifier_ctx.cur_blob,
+ ret,
+ blobifier_ctx.cbs.end_blob_ctx);
+ }
}
+ return ret;
}
+/*
+ * Read a list of blobs, each of which may be in any supported location (e.g.
+ * in a WIM or in an external file). This function optimizes the case where
+ * multiple blobs are combined into a single solid compressed WIM resource by
+ * reading the blobs in sequential order, only decompressing the solid resource
+ * one time.
+ *
+ * @blob_list
+ * List of blobs to read.
+ * @list_head_offset
+ * Offset of the `struct list_head' within each `struct blob_descriptor' that makes up
+ * the @blob_list.
+ * @cbs
+ * Callback functions to accept the blob data.
+ * @flags
+ * Bitwise OR of zero or more of the following flags:
+ *
+ * VERIFY_BLOB_HASHES:
+ * For all blobs being read that have already had SHA-1 message
+ * digests computed, calculate the SHA-1 message digest of the read
+ * data and compare it with the previously computed value. If they
+ * do not match, return WIMLIB_ERR_INVALID_RESOURCE_HASH.
+ *
+ * COMPUTE_MISSING_BLOB_HASHES
+ * For all blobs being read that have not yet had their SHA-1
+ * message digests computed, calculate and save their SHA-1 message
+ * digests.
+ *
+ * BLOB_LIST_ALREADY_SORTED
+ * @blob_list is already sorted in sequential order for reading.
+ *
+ * The callback functions are allowed to delete the current blob from the list
+ * if necessary.
+ *
+ * Returns 0 on success; a nonzero error code on failure. Failure can occur due
+ * to an error reading the data or due to an error status being returned by any
+ * of the callback functions.
+ */
int
-extract_wim_resource_to_fd(const struct wim_lookup_table_entry *lte,
- int fd, u64 size)
+read_blob_list(struct list_head *blob_list,
+ size_t list_head_offset,
+ const struct read_blob_list_callbacks *cbs,
+ int flags)
{
- return extract_wim_resource(lte, size, extract_wim_chunk_to_fd, &fd);
+ int ret;
+ struct list_head *cur, *next;
+ struct blob_descriptor *blob;
+ struct hasher_context *hasher_ctx;
+ struct read_blob_list_callbacks *sink_cbs;
+
+ if (!(flags & BLOB_LIST_ALREADY_SORTED)) {
+ ret = sort_blob_list_by_sequential_order(blob_list, list_head_offset);
+ if (ret)
+ return ret;
+ }
+
+ if (flags & (VERIFY_BLOB_HASHES | COMPUTE_MISSING_BLOB_HASHES)) {
+ hasher_ctx = alloca(sizeof(*hasher_ctx));
+ *hasher_ctx = (struct hasher_context) {
+ .flags = flags,
+ .cbs = *cbs,
+ };
+ sink_cbs = alloca(sizeof(*sink_cbs));
+ *sink_cbs = (struct read_blob_list_callbacks) {
+ .begin_blob = hasher_begin_blob,
+ .begin_blob_ctx = hasher_ctx,
+ .consume_chunk = hasher_consume_chunk,
+ .consume_chunk_ctx = hasher_ctx,
+ .end_blob = hasher_end_blob,
+ .end_blob_ctx = hasher_ctx,
+ };
+ } else {
+ sink_cbs = (struct read_blob_list_callbacks*)cbs;
+ }
+
+ for (cur = blob_list->next, next = cur->next;
+ cur != blob_list;
+ cur = next, next = cur->next)
+ {
+ blob = (struct blob_descriptor*)((u8*)cur - list_head_offset);
+
+ if (blob->blob_location == BLOB_IN_WIM &&
+ blob->size != blob->rdesc->uncompressed_size)
+ {
+ struct blob_descriptor *blob_next, *blob_last;
+ struct list_head *next2;
+ u64 blob_count;
+
+ /* The next blob is a proper sub-sequence of a WIM
+ * resource. See if there are other blobs in the same
+ * resource that need to be read. Since
+ * sort_blob_list_by_sequential_order() sorted the blobs
+ * by offset in the WIM, this can be determined by
+ * simply scanning forward in the list. */
+
+ blob_last = blob;
+ blob_count = 1;
+ for (next2 = next;
+ next2 != blob_list
+ && (blob_next = (struct blob_descriptor*)
+ ((u8*)next2 - list_head_offset),
+ blob_next->blob_location == BLOB_IN_WIM
+ && blob_next->rdesc == blob->rdesc);
+ next2 = next2->next)
+ {
+ blob_last = blob_next;
+ blob_count++;
+ }
+ if (blob_count > 1) {
+ /* Reading multiple blobs combined into a single
+ * WIM resource. They are in the blob list,
+ * sorted by offset; @blob specifies the first
+ * blob in the resource that needs to be read
+ * and @blob_last specifies the last blob in the
+ * resource that needs to be read. */
+ next = next2;
+ ret = read_blobs_in_solid_resource(blob, blob_last,
+ blob_count,
+ list_head_offset,
+ sink_cbs);
+ if (ret)
+ return ret;
+ continue;
+ }
+ }
+
+ ret = read_full_blob_with_cbs(blob, sink_cbs);
+ if (ret && ret != BEGIN_BLOB_STATUS_SKIP_BLOB)
+ return ret;
+ }
+ return 0;
}
+/*
+ * Extract the first @size bytes of the specified blob.
+ *
+ * If @size specifies the full uncompressed size of the blob, then the SHA-1
+ * message digest of the uncompressed blob is checked while being extracted.
+ *
+ * The uncompressed data of the blob is passed in chunks of unspecified size to
+ * the @extract_chunk function, passing it @extract_chunk_arg.
+ */
+int
+extract_blob(struct blob_descriptor *blob, u64 size,
+ consume_data_callback_t extract_chunk, void *extract_chunk_arg)
+{
+ wimlib_assert(size <= blob->size);
+ if (size == blob->size) {
+ /* Do SHA-1. */
+ struct read_blob_list_callbacks cbs = {
+ .consume_chunk = extract_chunk,
+ .consume_chunk_ctx = extract_chunk_arg,
+ };
+ return read_full_blob_with_sha1(blob, &cbs);
+ } else {
+ /* Don't do SHA-1. */
+ return read_blob_prefix(blob, size, extract_chunk,
+ extract_chunk_arg);
+ }
+}
+/* A consume_data_callback_t implementation that writes the chunk of data to a
+ * file descriptor. */
static int
-sha1_chunk(const void *buf, size_t len, void *ctx)
+extract_chunk_to_fd(const void *chunk, size_t size, void *_fd_p)
{
- sha1_update(ctx, buf, len);
+ struct filedes *fd = _fd_p;
+
+ int ret = full_write(fd, chunk, size);
+ if (ret) {
+ ERROR_WITH_ERRNO("Error writing to file descriptor");
+ return ret;
+ }
return 0;
}
-/* Calculate the SHA1 message digest of a stream. */
+/* Extract the first @size bytes of the specified blob to the specified file
+ * descriptor. */
int
-sha1_resource(struct wim_lookup_table_entry *lte)
+extract_blob_to_fd(struct blob_descriptor *blob, struct filedes *fd, u64 size)
{
- int ret;
- SHA_CTX sha_ctx;
+ return extract_blob(blob, size, extract_chunk_to_fd, fd);
+}
- sha1_init(&sha_ctx);
- ret = read_resource_prefix(lte, wim_resource_size(lte),
- sha1_chunk, &sha_ctx, 0);
- if (ret == 0)
- sha1_final(lte->hash, &sha_ctx);
- return ret;
+/* Extract the full uncompressed contents of the specified blob to the specified
+ * file descriptor. */
+int
+extract_full_blob_to_fd(struct blob_descriptor *blob, struct filedes *fd)
+{
+ return extract_blob_to_fd(blob, fd, blob->size);
+}
+
+/* Calculate the SHA-1 message digest of a blob and store it in @blob->hash. */
+int
+sha1_blob(struct blob_descriptor *blob)
+{
+ wimlib_assert(blob->unhashed);
+ struct read_blob_list_callbacks cbs = {
+ };
+ return read_full_blob_with_sha1(blob, &cbs);
}
/*
- * Copies the file resource specified by the lookup table entry @lte from the
- * input WIM to the output WIM that has its FILE * given by
- * ((WIMStruct*)wim)->out_fp.
+ * Convert a short WIM resource header to a stand-alone WIM resource descriptor.
*
- * The output_resource_entry, out_refcnt, and part_number fields of @lte are
- * updated.
- *
- * (This function is confusing and should be refactored somehow.)
+ * Note: for solid resources some fields still need to be overridden.
*/
-int
-copy_resource(struct wim_lookup_table_entry *lte, void *wim)
+void
+wim_res_hdr_to_desc(const struct wim_reshdr *reshdr, WIMStruct *wim,
+ struct wim_resource_descriptor *rdesc)
{
- WIMStruct *w = wim;
- int ret;
-
- ret = write_wim_resource(lte, w->out_fd,
- wim_resource_compression_type(lte),
- <e->output_resource_entry, 0);
- if (ret == 0) {
- lte->out_refcnt = lte->refcnt;
- lte->part_number = w->hdr.part_number;
+ rdesc->wim = wim;
+ rdesc->offset_in_wim = reshdr->offset_in_wim;
+ rdesc->size_in_wim = reshdr->size_in_wim;
+ rdesc->uncompressed_size = reshdr->uncompressed_size;
+ INIT_LIST_HEAD(&rdesc->blob_list);
+ rdesc->flags = reshdr->flags;
+ rdesc->is_pipable = wim_is_pipable(wim);
+ if (rdesc->flags & WIM_RESHDR_FLAG_COMPRESSED) {
+ rdesc->compression_type = wim->compression_type;
+ rdesc->chunk_size = wim->chunk_size;
+ } else {
+ rdesc->compression_type = WIMLIB_COMPRESSION_TYPE_NONE;
+ rdesc->chunk_size = 0;
}
- return ret;
+}
+
+/* Convert a stand-alone resource descriptor to a WIM resource header. */
+void
+wim_res_desc_to_hdr(const struct wim_resource_descriptor *rdesc,
+ struct wim_reshdr *reshdr)
+{
+ reshdr->offset_in_wim = rdesc->offset_in_wim;
+ reshdr->size_in_wim = rdesc->size_in_wim;
+ reshdr->flags = rdesc->flags;
+ reshdr->uncompressed_size = rdesc->uncompressed_size;
+}
+
+/* Translates a WIM resource header from the on-disk format into an in-memory
+ * format. */
+void
+get_wim_reshdr(const struct wim_reshdr_disk *disk_reshdr,
+ struct wim_reshdr *reshdr)
+{
+ reshdr->offset_in_wim = le64_to_cpu(disk_reshdr->offset_in_wim);
+ reshdr->size_in_wim = (((u64)disk_reshdr->size_in_wim[0] << 0) |
+ ((u64)disk_reshdr->size_in_wim[1] << 8) |
+ ((u64)disk_reshdr->size_in_wim[2] << 16) |
+ ((u64)disk_reshdr->size_in_wim[3] << 24) |
+ ((u64)disk_reshdr->size_in_wim[4] << 32) |
+ ((u64)disk_reshdr->size_in_wim[5] << 40) |
+ ((u64)disk_reshdr->size_in_wim[6] << 48));
+ reshdr->uncompressed_size = le64_to_cpu(disk_reshdr->uncompressed_size);
+ reshdr->flags = disk_reshdr->flags;
+}
+
+/* Translates a WIM resource header from an in-memory format into the on-disk
+ * format. */
+void
+put_wim_reshdr(const struct wim_reshdr *reshdr,
+ struct wim_reshdr_disk *disk_reshdr)
+{
+ disk_reshdr->size_in_wim[0] = reshdr->size_in_wim >> 0;
+ disk_reshdr->size_in_wim[1] = reshdr->size_in_wim >> 8;
+ disk_reshdr->size_in_wim[2] = reshdr->size_in_wim >> 16;
+ disk_reshdr->size_in_wim[3] = reshdr->size_in_wim >> 24;
+ disk_reshdr->size_in_wim[4] = reshdr->size_in_wim >> 32;
+ disk_reshdr->size_in_wim[5] = reshdr->size_in_wim >> 40;
+ disk_reshdr->size_in_wim[6] = reshdr->size_in_wim >> 48;
+ disk_reshdr->flags = reshdr->flags;
+ disk_reshdr->offset_in_wim = cpu_to_le64(reshdr->offset_in_wim);
+ disk_reshdr->uncompressed_size = cpu_to_le64(reshdr->uncompressed_size);
}