src/commonlib/bsd/cbfs_mcache.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /* SPDX-License-Identifier: BSD-3-Clause OR GPL-2.0-or-later */

 #include <assert.h>
 #include <commonlib/bsd/cbfs_private.h>
 #include <commonlib/bsd/helpers.h>

 /*
  * A CBFS metadata cache is an in memory data structure storing CBFS file headers (= metadata).
  * It is defined by its start pointer and size. It contains a sequence of variable-length
  * union mcache_entry entries. There is no overall header structure for the cache.
  *
  * Each mcache_entry is the raw metadata for a CBFS file (including attributes) in the same form
  * as stored on flash (i.e. values in big-endian), except that the CBFS magic signature in the
  * first 8 bytes ('LARCHIVE') is overwritten with mcache-internal bookkeeping data. The first 4
  * bytes are a magic number (MCACHE_MAGIC_FILE) and the next 4 bytes are the absolute offset in
  * bytes on the cbfs_dev_t that this metadata blob was found at. (Note that depending on the
  * implementation of cbfs_dev_t, this offset may still be relative to the start of a subregion
  * of the underlying storage device.)
  *
  * The length of an mcache_entry (i.e. length of the underlying metadata blob) is encoded in the
  * metadata (entry->file.h.offset). The next mcache_entry begins at the next
  * CBFS_MCACHE_ALIGNMENT boundary after that. The cache is terminated by a special 4-byte
  * mcache_entry that consists only of a magic number (MCACHE_MAGIC_END or MCACHE_MAGIC_FULL).
  */

 #define MCACHE_MAGIC_FILE	0x454c4946	/* 'FILE' */
 #define MCACHE_MAGIC_FULL	0x4c4c5546	/* 'FULL' */
 #define MCACHE_MAGIC_END	0x444e4524	/* '$END' */

 union mcache_entry {
 	union cbfs_mdata file;
 	struct {	/* These fields exactly overlap file.h.magic */
 		uint32_t magic;
 		uint32_t offset;
 	};
 };

 struct cbfs_mcache_build_args {
 	void *mcache;
 	void *end;
 	int count;
 };

 static enum cb_err build_walker(cbfs_dev_t dev, size_t offset, const union cbfs_mdata *mdata,
 				size_t already_read, void *arg)
 {
 	struct cbfs_mcache_build_args *args = arg;
 	union mcache_entry *entry = args->mcache;
 	const uint32_t data_offset = be32toh(mdata->h.offset);

 	if (args->end - args->mcache < data_offset)
 		return CB_CBFS_CACHE_FULL;

 	if (cbfs_copy_fill_metadata(args->mcache, mdata, already_read, dev, offset))
 		return CB_CBFS_IO;

 	entry->magic = MCACHE_MAGIC_FILE;
 	entry->offset = offset;

 	args->mcache += ALIGN_UP(data_offset, CBFS_MCACHE_ALIGNMENT);
 	args->count++;

 	return CB_CBFS_NOT_FOUND;
 }

 enum cb_err cbfs_mcache_build(cbfs_dev_t dev, void *mcache, size_t size,
 			      struct vb2_hash *metadata_hash)
 {
 	struct cbfs_mcache_build_args args = {
 		.mcache = mcache,
 		.end = mcache + ALIGN_DOWN(size, CBFS_MCACHE_ALIGNMENT)
 		       - sizeof(uint32_t), /* leave space for terminating magic */
 		.count = 0,
 	};

 	assert(size > sizeof(uint32_t) && IS_ALIGNED((uintptr_t)mcache, CBFS_MCACHE_ALIGNMENT));
 	enum cb_err ret = cbfs_walk(dev, build_walker, &args, metadata_hash, 0);
 	union mcache_entry *entry = args.mcache;
 	if (ret == CB_CBFS_NOT_FOUND) {
 		ret = CB_SUCCESS;
 		entry->magic = MCACHE_MAGIC_END;
 	} else if (ret == CB_CBFS_CACHE_FULL) {
 		ERROR("mcache overflow, should increase CBFS_MCACHE size!\n");
 		entry->magic = MCACHE_MAGIC_FULL;
 	}

 	LOG("mcache @%p built for %d files, used %#zx of %#zx bytes\n", mcache,
 	    args.count, args.mcache + sizeof(entry->magic) - mcache, size);
 	return ret;
 }

 enum cb_err cbfs_mcache_lookup(const void *mcache, size_t mcache_size, const char *name,
 			       union cbfs_mdata *mdata_out, size_t *data_offset_out)
 {
 	const size_t namesize = strlen(name) + 1; /* Count trailing \0 so we can memcmp() it. */
 	const void *end = mcache + mcache_size;
 	const void *current = mcache;

 	while (current + sizeof(uint32_t) <= end) {
 		const union mcache_entry *entry = current;

 		if (entry->magic == MCACHE_MAGIC_END)
 			return CB_CBFS_NOT_FOUND;
 		if (entry->magic == MCACHE_MAGIC_FULL)
 			return CB_CBFS_CACHE_FULL;

 		assert(entry->magic == MCACHE_MAGIC_FILE);
 		const uint32_t data_offset = be32toh(entry->file.h.offset);
 		const uint32_t data_length = be32toh(entry->file.h.len);
 		if (namesize <= data_offset - offsetof(union cbfs_mdata, h.filename) &&
 		    memcmp(name, entry->file.h.filename, namesize) == 0) {
 			LOG("Found '%s' @%#x size %#x in mcache @%p\n",
 			    name, entry->offset, data_length, current);
 			*data_offset_out = entry->offset + data_offset;
 			memcpy(mdata_out, &entry->file, data_offset);
 			return CB_SUCCESS;
 		}

 		current += ALIGN_UP(data_offset, CBFS_MCACHE_ALIGNMENT);
 	}

 	ERROR("CBFS mcache is not terminated!\n");	/* should never happen */
 	return CB_ERR;
 }

 size_t cbfs_mcache_real_size(const void *mcache, size_t mcache_size)
 {
 	const void *end = mcache + mcache_size;
 	const void *current = mcache;

 	while (current + sizeof(uint32_t) <= end) {
 		const union mcache_entry *entry = current;

 		if (entry->magic == MCACHE_MAGIC_FULL || entry->magic == MCACHE_MAGIC_END) {
 			current += sizeof(entry->magic);
 			break;
 		}

 		assert(entry->magic == MCACHE_MAGIC_FILE);
 		current += ALIGN_UP(be32toh(entry->file.h.offset), CBFS_MCACHE_ALIGNMENT);
 	}

 	return current - mcache;
 }
	/* SPDX-License-Identifier: BSD-3-Clause OR GPL-2.0-or-later */

	#include <assert.h>
	#include <commonlib/bsd/cbfs_private.h>
	#include <commonlib/bsd/helpers.h>

	/*
	* A CBFS metadata cache is an in memory data structure storing CBFS file headers (= metadata).
	* It is defined by its start pointer and size. It contains a sequence of variable-length
	* union mcache_entry entries. There is no overall header structure for the cache.
	*
	* Each mcache_entry is the raw metadata for a CBFS file (including attributes) in the same form
	* as stored on flash (i.e. values in big-endian), except that the CBFS magic signature in the
	* first 8 bytes ('LARCHIVE') is overwritten with mcache-internal bookkeeping data. The first 4
	* bytes are a magic number (MCACHE_MAGIC_FILE) and the next 4 bytes are the absolute offset in
	* bytes on the cbfs_dev_t that this metadata blob was found at. (Note that depending on the
	* implementation of cbfs_dev_t, this offset may still be relative to the start of a subregion
	* of the underlying storage device.)
	*
	* The length of an mcache_entry (i.e. length of the underlying metadata blob) is encoded in the
	* metadata (entry->file.h.offset). The next mcache_entry begins at the next
	* CBFS_MCACHE_ALIGNMENT boundary after that. The cache is terminated by a special 4-byte
	* mcache_entry that consists only of a magic number (MCACHE_MAGIC_END or MCACHE_MAGIC_FULL).
	*/

	#define MCACHE_MAGIC_FILE 0x454c4946 /* 'FILE' */
	#define MCACHE_MAGIC_FULL 0x4c4c5546 /* 'FULL' */
	#define MCACHE_MAGIC_END 0x444e4524 /* '$END' */

	union mcache_entry {
	union cbfs_mdata file;
	struct { /* These fields exactly overlap file.h.magic */
	uint32_t magic;
	uint32_t offset;
	};
	};

	struct cbfs_mcache_build_args {
	void *mcache;
	void *end;
	int count;
	};

	static enum cb_err build_walker(cbfs_dev_t dev, size_t offset, const union cbfs_mdata *mdata,
	size_t already_read, void *arg)
	{
	struct cbfs_mcache_build_args *args = arg;
	union mcache_entry *entry = args->mcache;
	const uint32_t data_offset = be32toh(mdata->h.offset);

	if (args->end - args->mcache < data_offset)
	return CB_CBFS_CACHE_FULL;

	if (cbfs_copy_fill_metadata(args->mcache, mdata, already_read, dev, offset))
	return CB_CBFS_IO;

	entry->magic = MCACHE_MAGIC_FILE;
	entry->offset = offset;

	args->mcache += ALIGN_UP(data_offset, CBFS_MCACHE_ALIGNMENT);
	args->count++;

	return CB_CBFS_NOT_FOUND;
	}

	enum cb_err cbfs_mcache_build(cbfs_dev_t dev, void *mcache, size_t size,
	struct vb2_hash *metadata_hash)
	{
	struct cbfs_mcache_build_args args = {
	.mcache = mcache,
	.end = mcache + ALIGN_DOWN(size, CBFS_MCACHE_ALIGNMENT)
	- sizeof(uint32_t), /* leave space for terminating magic */
	.count = 0,
	};

	assert(size > sizeof(uint32_t) && IS_ALIGNED((uintptr_t)mcache, CBFS_MCACHE_ALIGNMENT));
	enum cb_err ret = cbfs_walk(dev, build_walker, &args, metadata_hash, 0);
	union mcache_entry *entry = args.mcache;
	if (ret == CB_CBFS_NOT_FOUND) {
	ret = CB_SUCCESS;
	entry->magic = MCACHE_MAGIC_END;
	} else if (ret == CB_CBFS_CACHE_FULL) {
	ERROR("mcache overflow, should increase CBFS_MCACHE size!\n");
	entry->magic = MCACHE_MAGIC_FULL;
	}

	LOG("mcache @%p built for %d files, used %#zx of %#zx bytes\n", mcache,
	args.count, args.mcache + sizeof(entry->magic) - mcache, size);
	return ret;
	}

	enum cb_err cbfs_mcache_lookup(const void mcache, size_t mcache_size, const char name,
	union cbfs_mdata mdata_out, size_t data_offset_out)
	{
	const size_t namesize = strlen(name) + 1; /* Count trailing \0 so we can memcmp() it. */
	const void *end = mcache + mcache_size;
	const void *current = mcache;

	while (current + sizeof(uint32_t) <= end) {
	const union mcache_entry *entry = current;

	if (entry->magic == MCACHE_MAGIC_END)
	return CB_CBFS_NOT_FOUND;
	if (entry->magic == MCACHE_MAGIC_FULL)
	return CB_CBFS_CACHE_FULL;

	assert(entry->magic == MCACHE_MAGIC_FILE);
	const uint32_t data_offset = be32toh(entry->file.h.offset);
	const uint32_t data_length = be32toh(entry->file.h.len);
	if (namesize <= data_offset - offsetof(union cbfs_mdata, h.filename) &&
	memcmp(name, entry->file.h.filename, namesize) == 0) {
	LOG("Found '%s' @%#x size %#x in mcache @%p\n",
	name, entry->offset, data_length, current);
	*data_offset_out = entry->offset + data_offset;
	memcpy(mdata_out, &entry->file, data_offset);
	return CB_SUCCESS;
	}

	current += ALIGN_UP(data_offset, CBFS_MCACHE_ALIGNMENT);
	}

	ERROR("CBFS mcache is not terminated!\n"); /* should never happen */
	return CB_ERR;
	}

	size_t cbfs_mcache_real_size(const void *mcache, size_t mcache_size)
	{
	const void *end = mcache + mcache_size;
	const void *current = mcache;

	while (current + sizeof(uint32_t) <= end) {
	const union mcache_entry *entry = current;

	if (entry->magic == MCACHE_MAGIC_FULL \|\| entry->magic == MCACHE_MAGIC_END) {
	current += sizeof(entry->magic);
	break;
	}

	assert(entry->magic == MCACHE_MAGIC_FILE);
	current += ALIGN_UP(be32toh(entry->file.h.offset), CBFS_MCACHE_ALIGNMENT);
	}

	return current - mcache;
	}