util/cbfstool/fmd.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /*
  * fmd.c, parser frontend and utility functions for flashmap descriptor language
  *
  * Copyright (C) 2015 Google, Inc.
  *
  * This program 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; version 2 of the License.
  *
  * This program 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.
  */

 #include "fmd.h"

 #include "common.h"
 #include "fmd_parser.h"
 #include "fmd_scanner.h"
 #include "option.h"

 #include <assert.h>
 #include <search.h>
 #include <string.h>

 /*
  * Validate the given flashmap descriptor node's properties. In particular:
  *  - Ensure its name is globally unique.
  *  - Ensure its offset, if known, isn't located before the end of the previous
  *    section, if this can be determined.
  *  - Ensure its offset, if known, isn't located after the beginning of the next
  *    section or off the end of its parent section, if this can be determined.
  *  - Ensure its size is nonzero.
  *  - Ensure that the combination of its size and offset, if they are both
  *    known, doesn't place its end after the beginning of the next section or
  *    off the end of its parent section, if this can be determined.
  * In the case of a validation error, the particular problem is reported to
  * standard error and this function returns false. It should be noted that this
  * function makes no claim that the members of the node's child list are valid:
  * under no circumstances is any recursive validation performed.
  *
  * @param node  The flashmap descriptor node to be validated
  * @param start Optional minimum permissible base of the section to be
  *              validated, to be provided if known
  * @param end   Optional maximum permissible offset to the end of the section to
  *              be validated, to be provided if known
  * @return      Whether the node is valid
  */
 static bool validate_descriptor_node(const struct flashmap_descriptor *node,
 		struct unsigned_option start, struct unsigned_option end) {
 	assert(node);

 	ENTRY search_key = {node->name, NULL};
 	if (hsearch(search_key, FIND)) {
 		ERROR("Multiple sections with name '%s'\n", node->name);
 		return false;
 	}
 	if (!hsearch(search_key, ENTER))
 		assert(false);

 	if (node->offset_known) {
 		if (start.val_known && node->offset < start.val) {
 			ERROR("Section '%s' starts too low\n", node->name);
 			return false;
 		} else if (end.val_known && node->offset > end.val) {
 			ERROR("Section '%s' starts too high\n", node->name);
 			return false;
 		}
 	}

 	if (node->size_known) {
 		if (node->size == 0) {
 			ERROR("Section '%s' given no space\n", node->name);
 			return false;
 		} else if (node->offset_known) {
 			unsigned node_end = node->offset + node->size;
 			if (end.val_known && node_end > end.val) {
 				ERROR("Section '%s' too big\n", node->name);
 				return false;
 			}
 		}
 	}

 	return true;
 }

 /*
  * Performs reverse lateral processing of sibling nodes, as described by the
  * documentation of its caller, validate_and_complete_info(). If it encounters
  * a node that is invalid in a way that couldn't have been discovered earlier,
  * it explains the problem to standard output and returns false.
  *
  * @param first_incomplete_it First node whose offset or size couldn't be
  *                            determined during forward processing
  * @param cur_incomplete_it   Last node whose offset or size is unknown
  * @param end_watermark       Offset to the end of the unresolved region
  * @return                    Whether all completed nodes were still valid
  */
 static bool complete_missing_info_backward(
 			flashmap_descriptor_iterator_t first_incomplete_it,
 			flashmap_descriptor_iterator_t cur_incomplete_it,
 							unsigned end_watermark)
 {
 	assert(first_incomplete_it);
 	assert(cur_incomplete_it);
 	assert(cur_incomplete_it >= first_incomplete_it);

 	do {
 		struct flashmap_descriptor *cur = *cur_incomplete_it;

 		assert(cur->offset_known || cur->size_known);
 		if (!cur->offset_known) {
 			if (cur->size > end_watermark) {
 				ERROR("Section '%s' too big\n", cur->name);
 				return false;
 			}
 			cur->offset_known = true;
 			cur->offset = end_watermark -= cur->size;
 		} else if (!cur->size_known) {
 			if (cur->offset > end_watermark) {
 				ERROR("Section '%s' starts too high\n",
 								cur->name);
 				return false;
 			}
 			cur->size_known = true;
 			cur->size = end_watermark - cur->offset;
 			end_watermark = cur->offset;
 		}
 	} while (--cur_incomplete_it >= first_incomplete_it);

 	return true;
 }

 /*
  * Recursively examine each descendant of the provided flashmap descriptor node
  * to ensure its position and size are known, attempt to infer them otherwise,
  * and validate their values once they've been populated.
  * This processes nodes according to the following algorithm:
  *  - At each level of the tree, it moves laterally between siblings, keeping
  *    a watermark of its current offset relative to the previous section, which
  *    it uses to fill in any unknown offsets it encounters along the way.
  *  - The first time it encounters a sibling with unknown size, it loses track
  *    of the watermark, and is therefore unable to complete further offsets;
  *    instead, if the watermark was known before, it marks the current node as
  *    the first that couldn't be completed in the initial pass.
  *  - If the current watermark is unknown (i.e. a node has been marked as the
  *    first incomplete one) and one with a fixed offset is encountered, a
  *    reverse lateral traversal is dispatched that uses that provided offset as
  *    a reverse watermark to complete all unknown fields until it finishes with
  *    the node marked as the first incomplete one: at this point, that flag is
  *    cleared, the watermark is updated, and forward processing resumes from
  *    where it left off.
  *  - If the watermark is unknown (i.e. node(s) are incomplete) after traversing
  *    all children of a particular parent node, reverse processing is employed
  *    as described above, except that the reverse watermark is initialized to
  *    the parent node's size instead of the (nonexistent) next node's offset.
  *  - Once all of a node's children have been processed, the algorithm applies
  *    itself recursively to each of the child nodes; thus, lower levels of the
  *    tree are processed only after their containing levels are finished.
  * This approach can fail in two possible ways (in which case the problem is
  * reported to standard output and this function returns false):
  *  - Processing reveals that some node's provided value is invalid in some way.
  *  - Processing determines that one or more provided values require an omitted
  *    field to take a nonsensical value.
  *  - Processing determines that it is impossible to determine a group of
  *    omitted values. This state is detected when a node whose offset *and*
  *    value are omitted is encountered during forward processing and while the
  *    current watermark is unknown: in such a case, neither can be known without
  *    being provided with either the other or more context.
  * The function notably performs neither validation nor completion on the parent
  * node it is passed; thus, it is important to ensure that that node is valid.
  * (At the very least, it must have a valid size field in order for the
  * algorithm to work on its children.)
  *
  * @param cur_level Parent node, which must minimally already have a valid size
  * @return          Whether completing and validating the children succeeded
  */
 static bool validate_and_complete_info(struct flashmap_descriptor *cur_level)
 {
 	assert(cur_level);
 	assert(cur_level->size_known);

 	// Our watermark is only known when first_incomplete_it is NULL.
 	flashmap_descriptor_iterator_t first_incomplete_it = NULL;
 	unsigned watermark = 0;

 	fmd_foreach_child_iterator(cur_it, cur_level) {
 		struct flashmap_descriptor *cur_section = *cur_it;

 		if (first_incomplete_it) {
 			if (cur_section->offset_known) {
 				if (complete_missing_info_backward(
 						first_incomplete_it, cur_it - 1,
 							cur_section->offset)) {
 					first_incomplete_it = NULL;
 					watermark = cur_section->offset;
 				} else {
 					return false;
 				}
 			}
 			// Otherwise, we can't go back until a provided offset.
 		} else if (!cur_section->offset_known) {
 			cur_section->offset_known = true;
 			cur_section->offset = watermark;
 		}

 		assert(cur_level->size_known);
 		struct unsigned_option max_endpoint = {true, cur_level->size};
 		if (cur_it != cur_level->list + cur_level->list_len - 1) {
 			struct flashmap_descriptor *next_section = cur_it[1];
 			max_endpoint.val_known = next_section->offset_known;
 			max_endpoint.val = next_section->offset;
 		}
 		if (!validate_descriptor_node(cur_section,
 							(struct unsigned_option)
 					{!first_incomplete_it, watermark},
 								max_endpoint))
 			return false;

 		if (!cur_section->size_known) {
 			if (!cur_section->offset_known) {
 				ERROR("Cannot determine either offset or size of section '%s'\n",
 							cur_section->name);
 				return false;
 			} else if (!first_incomplete_it) {
 				first_incomplete_it = cur_it;
 			} else {
 				// We shouldn't find an unknown size within an
 				// incomplete region because the backward
 				// traversal at the beginning of this node's
 				// processing should have concluded said region.
 				assert(!first_incomplete_it);
 			}
 		} else if (!first_incomplete_it) {
 			watermark = cur_section->offset + cur_section->size;
 		}
 	}

 	if (first_incomplete_it &&
 			!complete_missing_info_backward(first_incomplete_it,
 				cur_level->list + cur_level->list_len - 1,
 							cur_level->size))
 		return false;

 	fmd_foreach_child(cur_section, cur_level) {
 		assert(cur_section->offset_known);
 		assert(cur_section->size_known);

 		if (!validate_and_complete_info(cur_section))
 			return false;
 	}

 	return true;
 }

 static void print_with_prefix(const struct flashmap_descriptor *tree,
 								const char *pre)
 {
 	assert(tree);
 	assert(pre);

 	printf("%ssection '%s' has ", pre, tree->name);

 	if (tree->offset_known)
 		printf("offset %uB, ", tree->offset);
 	else
 		fputs("unknown offset, ", stdout);

 	if (tree->size_known)
 		printf("size %uB, ", tree->size);
 	else
 		fputs("unknown size, ", stdout);

 	printf("and %zu subsections", tree->list_len);
 	if (tree->list_len) {
 		puts(":");

 		char child_prefix[strlen(pre) + 1];
 		strcpy(child_prefix, pre);
 		strcat(child_prefix, "\t");
 		fmd_foreach_child(each, tree)
 			print_with_prefix(each, child_prefix);
 	} else {
 		puts("");
 	}
 }

 struct flashmap_descriptor *fmd_create(FILE *stream)
 {
 	assert(stream);

 	yyin = stream;

 	struct flashmap_descriptor *ret = NULL;
 	if (yyparse() == 0)
 		ret = res;

 	yylex_destroy();
 	yyin = NULL;
 	res = NULL;

 	if (ret) {
 		// This hash table is used to store the declared name of each
 		// section and ensure that each is globally unique.
 		if (!hcreate(fmd_count_nodes(ret))) {
 			perror("E: While initializing hashtable");
 			fmd_cleanup(ret);
 			return NULL;
 		}

 		// Even though we haven't checked that the root node (ret) has
 		// a size field as required by this function, the parser
 		// warrants that it does because the grammar requires it.
 		if (!validate_and_complete_info(ret)) {
 			hdestroy();
 			fmd_cleanup(ret);
 			return NULL;
 		}

 		hdestroy();
 	}

 	return ret;
 }

 void fmd_cleanup(struct flashmap_descriptor *victim)
 {
 	if (!victim)
 		return;

 	free(victim->name);
 	for (unsigned idx = 0; idx < victim->list_len; ++idx)
 		fmd_cleanup(victim->list[idx]);
 	free(victim->list);
 	free(victim);
 }

 size_t fmd_count_nodes(const struct flashmap_descriptor *tree)
 {
 	assert(tree);

 	if (!tree->list_len)
 		return 1;

 	unsigned count = 1;
 	fmd_foreach_child(lower, tree)
 		count += fmd_count_nodes(lower);
 	return count;
 }

 const struct flashmap_descriptor *fmd_find_node(
 		const struct flashmap_descriptor *root, const char *name)
 {
 	assert(root);
 	assert(name);

 	if (strcmp(root->name, name) == 0)
 		return root;

 	fmd_foreach_child(descendant, root) {
 		const struct flashmap_descriptor *match =
 						fmd_find_node(descendant, name);
 		if (match)
 			return match;
 	}
 	return NULL;
 }

 unsigned fmd_calc_absolute_offset(const struct flashmap_descriptor *root,
 							const char *name)
 {
 	assert(root);
 	assert(name);

 	if (strcmp(root->name, name) == 0)
 		return 0;

 	fmd_foreach_child(descendant, root) {
 		unsigned subtotal = fmd_calc_absolute_offset(descendant, name);
 		if (subtotal != FMD_NOTFOUND)
 			return descendant->offset + subtotal;
 	}
 	return FMD_NOTFOUND;
 }

 void fmd_print(const struct flashmap_descriptor *tree)
 {
 	print_with_prefix(tree, "");
 }
	/*
	* fmd.c, parser frontend and utility functions for flashmap descriptor language
	*
	* Copyright (C) 2015 Google, Inc.
	*
	* This program 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; version 2 of the License.
	*
	* This program 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.
	*/

	#include "fmd.h"

	#include "common.h"
	#include "fmd_parser.h"
	#include "fmd_scanner.h"
	#include "option.h"

	#include <assert.h>
	#include <search.h>
	#include <string.h>

	/*
	* Validate the given flashmap descriptor node's properties. In particular:
	* - Ensure its name is globally unique.
	* - Ensure its offset, if known, isn't located before the end of the previous
	* section, if this can be determined.
	* - Ensure its offset, if known, isn't located after the beginning of the next
	* section or off the end of its parent section, if this can be determined.
	* - Ensure its size is nonzero.
	* - Ensure that the combination of its size and offset, if they are both
	* known, doesn't place its end after the beginning of the next section or
	* off the end of its parent section, if this can be determined.
	* In the case of a validation error, the particular problem is reported to
	* standard error and this function returns false. It should be noted that this
	* function makes no claim that the members of the node's child list are valid:
	* under no circumstances is any recursive validation performed.
	*
	* @param node The flashmap descriptor node to be validated
	* @param start Optional minimum permissible base of the section to be
	* validated, to be provided if known
	* @param end Optional maximum permissible offset to the end of the section to
	* be validated, to be provided if known
	* @return Whether the node is valid
	*/
	static bool validate_descriptor_node(const struct flashmap_descriptor *node,
	struct unsigned_option start, struct unsigned_option end) {
	assert(node);

	ENTRY search_key = {node->name, NULL};
	if (hsearch(search_key, FIND)) {
	ERROR("Multiple sections with name '%s'\n", node->name);
	return false;
	}
	if (!hsearch(search_key, ENTER))
	assert(false);

	if (node->offset_known) {
	if (start.val_known && node->offset < start.val) {
	ERROR("Section '%s' starts too low\n", node->name);
	return false;
	} else if (end.val_known && node->offset > end.val) {
	ERROR("Section '%s' starts too high\n", node->name);
	return false;
	}
	}

	if (node->size_known) {
	if (node->size == 0) {
	ERROR("Section '%s' given no space\n", node->name);
	return false;
	} else if (node->offset_known) {
	unsigned node_end = node->offset + node->size;
	if (end.val_known && node_end > end.val) {
	ERROR("Section '%s' too big\n", node->name);
	return false;
	}
	}
	}

	return true;
	}

	/*
	* Performs reverse lateral processing of sibling nodes, as described by the
	* documentation of its caller, validate_and_complete_info(). If it encounters
	* a node that is invalid in a way that couldn't have been discovered earlier,
	* it explains the problem to standard output and returns false.
	*
	* @param first_incomplete_it First node whose offset or size couldn't be
	* determined during forward processing
	* @param cur_incomplete_it Last node whose offset or size is unknown
	* @param end_watermark Offset to the end of the unresolved region
	* @return Whether all completed nodes were still valid
	*/
	static bool complete_missing_info_backward(
	flashmap_descriptor_iterator_t first_incomplete_it,
	flashmap_descriptor_iterator_t cur_incomplete_it,
	unsigned end_watermark)
	{
	assert(first_incomplete_it);
	assert(cur_incomplete_it);
	assert(cur_incomplete_it >= first_incomplete_it);

	do {
	struct flashmap_descriptor cur = cur_incomplete_it;

	assert(cur->offset_known \|\| cur->size_known);
	if (!cur->offset_known) {
	if (cur->size > end_watermark) {
	ERROR("Section '%s' too big\n", cur->name);
	return false;
	}
	cur->offset_known = true;
	cur->offset = end_watermark -= cur->size;
	} else if (!cur->size_known) {
	if (cur->offset > end_watermark) {
	ERROR("Section '%s' starts too high\n",
	cur->name);
	return false;
	}
	cur->size_known = true;
	cur->size = end_watermark - cur->offset;
	end_watermark = cur->offset;
	}
	} while (--cur_incomplete_it >= first_incomplete_it);

	return true;
	}

	/*
	* Recursively examine each descendant of the provided flashmap descriptor node
	* to ensure its position and size are known, attempt to infer them otherwise,
	* and validate their values once they've been populated.
	* This processes nodes according to the following algorithm:
	* - At each level of the tree, it moves laterally between siblings, keeping
	* a watermark of its current offset relative to the previous section, which
	* it uses to fill in any unknown offsets it encounters along the way.
	* - The first time it encounters a sibling with unknown size, it loses track
	* of the watermark, and is therefore unable to complete further offsets;
	* instead, if the watermark was known before, it marks the current node as
	* the first that couldn't be completed in the initial pass.
	* - If the current watermark is unknown (i.e. a node has been marked as the
	* first incomplete one) and one with a fixed offset is encountered, a
	* reverse lateral traversal is dispatched that uses that provided offset as
	* a reverse watermark to complete all unknown fields until it finishes with
	* the node marked as the first incomplete one: at this point, that flag is
	* cleared, the watermark is updated, and forward processing resumes from
	* where it left off.
	* - If the watermark is unknown (i.e. node(s) are incomplete) after traversing
	* all children of a particular parent node, reverse processing is employed
	* as described above, except that the reverse watermark is initialized to
	* the parent node's size instead of the (nonexistent) next node's offset.
	* - Once all of a node's children have been processed, the algorithm applies
	* itself recursively to each of the child nodes; thus, lower levels of the
	* tree are processed only after their containing levels are finished.
	* This approach can fail in two possible ways (in which case the problem is
	* reported to standard output and this function returns false):
	* - Processing reveals that some node's provided value is invalid in some way.
	* - Processing determines that one or more provided values require an omitted
	* field to take a nonsensical value.
	* - Processing determines that it is impossible to determine a group of
	* omitted values. This state is detected when a node whose offset and
	* value are omitted is encountered during forward processing and while the
	* current watermark is unknown: in such a case, neither can be known without
	* being provided with either the other or more context.
	* The function notably performs neither validation nor completion on the parent
	* node it is passed; thus, it is important to ensure that that node is valid.
	* (At the very least, it must have a valid size field in order for the
	* algorithm to work on its children.)
	*
	* @param cur_level Parent node, which must minimally already have a valid size
	* @return Whether completing and validating the children succeeded
	*/
	static bool validate_and_complete_info(struct flashmap_descriptor *cur_level)
	{
	assert(cur_level);
	assert(cur_level->size_known);

	// Our watermark is only known when first_incomplete_it is NULL.
	flashmap_descriptor_iterator_t first_incomplete_it = NULL;
	unsigned watermark = 0;

	fmd_foreach_child_iterator(cur_it, cur_level) {
	struct flashmap_descriptor cur_section = cur_it;

	if (first_incomplete_it) {
	if (cur_section->offset_known) {
	if (complete_missing_info_backward(
	first_incomplete_it, cur_it - 1,
	cur_section->offset)) {
	first_incomplete_it = NULL;
	watermark = cur_section->offset;
	} else {
	return false;
	}
	}
	// Otherwise, we can't go back until a provided offset.
	} else if (!cur_section->offset_known) {
	cur_section->offset_known = true;
	cur_section->offset = watermark;
	}

	assert(cur_level->size_known);
	struct unsigned_option max_endpoint = {true, cur_level->size};
	if (cur_it != cur_level->list + cur_level->list_len - 1) {
	struct flashmap_descriptor *next_section = cur_it[1];
	max_endpoint.val_known = next_section->offset_known;
	max_endpoint.val = next_section->offset;
	}
	if (!validate_descriptor_node(cur_section,
	(struct unsigned_option)
	{!first_incomplete_it, watermark},
	max_endpoint))
	return false;

	if (!cur_section->size_known) {
	if (!cur_section->offset_known) {
	ERROR("Cannot determine either offset or size of section '%s'\n",
	cur_section->name);
	return false;
	} else if (!first_incomplete_it) {
	first_incomplete_it = cur_it;
	} else {
	// We shouldn't find an unknown size within an
	// incomplete region because the backward
	// traversal at the beginning of this node's
	// processing should have concluded said region.
	assert(!first_incomplete_it);
	}
	} else if (!first_incomplete_it) {
	watermark = cur_section->offset + cur_section->size;
	}
	}

	if (first_incomplete_it &&
	!complete_missing_info_backward(first_incomplete_it,
	cur_level->list + cur_level->list_len - 1,
	cur_level->size))
	return false;

	fmd_foreach_child(cur_section, cur_level) {
	assert(cur_section->offset_known);
	assert(cur_section->size_known);

	if (!validate_and_complete_info(cur_section))
	return false;
	}

	return true;
	}

	static void print_with_prefix(const struct flashmap_descriptor *tree,
	const char *pre)
	{
	assert(tree);
	assert(pre);

	printf("%ssection '%s' has ", pre, tree->name);

	if (tree->offset_known)
	printf("offset %uB, ", tree->offset);
	else
	fputs("unknown offset, ", stdout);

	if (tree->size_known)
	printf("size %uB, ", tree->size);
	else
	fputs("unknown size, ", stdout);

	printf("and %zu subsections", tree->list_len);
	if (tree->list_len) {
	puts(":");

	char child_prefix[strlen(pre) + 1];
	strcpy(child_prefix, pre);
	strcat(child_prefix, "\t");
	fmd_foreach_child(each, tree)
	print_with_prefix(each, child_prefix);
	} else {
	puts("");
	}
	}

	struct flashmap_descriptor fmd_create(FILE stream)
	{
	assert(stream);

	yyin = stream;

	struct flashmap_descriptor *ret = NULL;
	if (yyparse() == 0)
	ret = res;

	yylex_destroy();
	yyin = NULL;
	res = NULL;

	if (ret) {
	// This hash table is used to store the declared name of each
	// section and ensure that each is globally unique.
	if (!hcreate(fmd_count_nodes(ret))) {
	perror("E: While initializing hashtable");
	fmd_cleanup(ret);
	return NULL;
	}

	// Even though we haven't checked that the root node (ret) has
	// a size field as required by this function, the parser
	// warrants that it does because the grammar requires it.
	if (!validate_and_complete_info(ret)) {
	hdestroy();
	fmd_cleanup(ret);
	return NULL;
	}

	hdestroy();
	}

	return ret;
	}

	void fmd_cleanup(struct flashmap_descriptor *victim)
	{
	if (!victim)
	return;

	free(victim->name);
	for (unsigned idx = 0; idx < victim->list_len; ++idx)
	fmd_cleanup(victim->list[idx]);
	free(victim->list);
	free(victim);
	}

	size_t fmd_count_nodes(const struct flashmap_descriptor *tree)
	{
	assert(tree);

	if (!tree->list_len)
	return 1;

	unsigned count = 1;
	fmd_foreach_child(lower, tree)
	count += fmd_count_nodes(lower);
	return count;
	}

	const struct flashmap_descriptor *fmd_find_node(
	const struct flashmap_descriptor root, const char name)
	{
	assert(root);
	assert(name);

	if (strcmp(root->name, name) == 0)
	return root;

	fmd_foreach_child(descendant, root) {
	const struct flashmap_descriptor *match =
	fmd_find_node(descendant, name);
	if (match)
	return match;
	}
	return NULL;
	}

	unsigned fmd_calc_absolute_offset(const struct flashmap_descriptor *root,
	const char *name)
	{
	assert(root);
	assert(name);

	if (strcmp(root->name, name) == 0)
	return 0;

	fmd_foreach_child(descendant, root) {
	unsigned subtotal = fmd_calc_absolute_offset(descendant, name);
	if (subtotal != FMD_NOTFOUND)
	return descendant->offset + subtotal;
	}
	return FMD_NOTFOUND;
	}

	void fmd_print(const struct flashmap_descriptor *tree)
	{
	print_with_prefix(tree, "");
	}