// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "google/bdict_reader.h" #include #include "base/logging.h" namespace hunspell { // Like the "Visitor" design pattern, this lightweight object provides an // interface around a serialized trie node at the given address in the memory. class NodeReader { public: // Return values for GetChildAt. enum FindResult { // A node is found. FIND_NODE, // There are no more children for this node, no child node is returned. FIND_DONE, // There is no node at this location, but there are more if you continue // iterating. This happens when there is a lookup node with empty entries. FIND_NOTHING }; // The default constructor makes an invalid reader. NodeReader(); NodeReader(const unsigned char* bdict_data, size_t bdict_length, size_t node_offset, int node_depth); // Returns true if the reader is valid. False means you shouldn't use it. bool is_valid() const { return is_valid_; } // Recursively finds the given NULL terminated word. // See BDictReader::FindWord. int FindWord(const unsigned char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const; // Allows iterating over the children of this node. When it returns // FIND_NODE, |*result| will be populated with the reader for the found node. // The first index is 0. The single character for this node will be placed // into |*found_char|. FindResult GetChildAt(int index, char* found_char, NodeReader* result) const; // Leaf ---------------------------------------------------------------------- inline bool is_leaf() const { // If id_byte() sets is_valid_ to false, we need an extra check to avoid // returning true for this type. return (id_byte() & BDict::LEAF_NODE_TYPE_MASK) == BDict::LEAF_NODE_TYPE_VALUE && is_valid_; } // If this is a leaf node with an additional string, this function will return // a pointer to the beginning of the additional string. It will be NULL // terminated. If it is not a leaf or has no additional string, it will return // NULL. inline const unsigned char* additional_string_for_leaf() const { // Leaf nodes with additional strings start with bits "01" in the ID byte. if ((id_byte() & BDict::LEAF_NODE_ADDITIONAL_MASK) == BDict::LEAF_NODE_ADDITIONAL_VALUE) { if (node_offset_ < (bdict_length_ - 2)) return &bdict_data_[node_offset_ + 2]; // Starts after the 2 byte ID. // Otherwise the dictionary is corrupt. is_valid_ = false; } return NULL; } // Returns the first affix ID corresponding to the given leaf node. The // current node must be a leaf or this will do the wrong thing. There may be // additional affix IDs following the node when leaf_has_following is set, // but this will not handle those. inline int affix_id_for_leaf() const { if (node_offset_ >= bdict_length_ - 2) { is_valid_ = false; return 0; } // Take the lowest 6 bits of the first byte, and all 8 bits of the second. return ((bdict_data_[node_offset_ + 0] & BDict::LEAF_NODE_FIRST_BYTE_AFFIX_MASK) << 8) + bdict_data_[node_offset_ + 1]; } // Returns true if there is a list of additional affix matches following this // leaf node. inline bool leaf_has_following() const { return ((id_byte() & BDict::LEAF_NODE_FOLLOWING_MASK) == BDict::LEAF_NODE_FOLLOWING_VALUE); } // Fills the affix indices into the output array given a matching leaf node. // |additional_bytes| is the number of bytes of the additional string, // including the NULL terminator, following this leaf node. This will be 0 if // there is no additional string. int FillAffixesForLeafMatch( size_t additional_bytes, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const; // Lookup -------------------------------------------------------------------- inline bool is_lookup() const { return (id_byte() & BDict::LOOKUP_NODE_TYPE_MASK) == BDict::LOOKUP_NODE_TYPE_VALUE; } inline bool is_lookup_32() const { return (id_byte() & BDict::LOOKUP_NODE_32BIT_MASK) == BDict::LOOKUP_NODE_32BIT_VALUE; } inline bool lookup_has_0th() const { return (id_byte() & BDict::LOOKUP_NODE_0TH_MASK) == BDict::LOOKUP_NODE_0TH_VALUE; } // Returns the first entry after the lookup table header. When there is a // magic 0th entry, it will be that address. // The caller checks that the result is in-bounds. inline size_t zeroth_entry_offset() const { return node_offset_ + 3; } // Returns the index of the first element in the lookup table. This skips any // magic 0th entry. // The caller checks that the result is in-bounds. size_t lookup_table_offset() const { size_t table_offset = zeroth_entry_offset(); if (lookup_has_0th()) return table_offset + (is_lookup_32() ? 4 : 2); return table_offset; } inline int lookup_first_char() const { if (node_offset_ >= bdict_length_ - 1) { is_valid_ = false; return 0; } return bdict_data_[node_offset_ + 1]; } inline int lookup_num_chars() const { if (node_offset_ >= bdict_length_ - 2) { is_valid_ = false; return 0; } return bdict_data_[node_offset_ + 2]; } // Computes a node reader for the magic 0th entry of the table. This assumes // it has a 0th entry. This will always return FOUND_NODE (for compatilibility // with GetChildAt). FindResult ReaderForLookup0th(NodeReader* result) const; // Gets a node reader for the |offset|th element in the table, not counting // the magic 0th element, if any (so passing 0 here will give you the first // element in the regular lookup table). The offset is assumed to be valid. // // |child_node_char| is the character value that the child node will // represent. The single character for this node will be placed into // |*found_char|. FindResult ReaderForLookupAt(size_t index, char* found_char, NodeReader* result) const; // List ---------------------------------------------------------------------- inline bool is_list() const { return (id_byte() & BDict::LIST_NODE_TYPE_MASK) == BDict::LIST_NODE_TYPE_VALUE; } inline int is_list_16() const { // 16 bit lst nodes have the high 4 bits of 1. return (id_byte() & BDict::LIST_NODE_16BIT_MASK) == BDict::LIST_NODE_16BIT_VALUE; } inline size_t list_item_count() const { // The list count is stored in the low 4 bits of the ID. return id_byte() & BDict::LIST_NODE_COUNT_MASK; } // Returns a NodeReader for the list item with the given index. The single // character for this node will be placed into |*found_char|. FindResult ReaderForListAt(size_t index, char* found_char, NodeReader* result) const; private: inline unsigned char id_byte() const { if (!is_valid_) return 0; // Don't continue with a corrupt node. if (node_offset_ >= bdict_length_) { // Return zero if out of bounds; we'll check is_valid_ in caller. is_valid_ = false; return 0; } return bdict_data_[node_offset_]; } // Checks the given leaf node to see if it's a match for the given word. // The parameters and return values are the same as BDictReader::FindWord. int CompareLeafNode(const unsigned char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const; // Recursive calls used by FindWord to look up child nodes of different types. int FindInLookup(const unsigned char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const; int FindInList(const unsigned char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const; // The entire bdict file. This will be NULL if it is invalid. const unsigned char* bdict_data_; size_t bdict_length_; // Points to the end of the file (for length checking convenience). const unsigned char* bdict_end_; // Absolute offset within |bdict_data_| of the beginning of this node. size_t node_offset_; // The character index into the word that this node represents. int node_depth_; // Signals that dictionary corruption was found during node traversal. mutable bool is_valid_; }; NodeReader::NodeReader() : bdict_data_(NULL), bdict_length_(0), bdict_end_(NULL), node_offset_(0), node_depth_(0), is_valid_(false) { } NodeReader::NodeReader(const unsigned char* bdict_data, size_t bdict_length, size_t node_offset, int node_depth) : bdict_data_(bdict_data), bdict_length_(bdict_length), bdict_end_(bdict_data + bdict_length), node_offset_(node_offset), node_depth_(node_depth), is_valid_(bdict_data != NULL && node_offset < bdict_length) { } int NodeReader::FindWord(const unsigned char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const { // Return 0 if the dictionary is corrupt as BDictReader::FindWord() does. if (!bdict_data_ || node_offset_ > bdict_length_) return 0; if (is_leaf()) return CompareLeafNode(word, affix_indices); if (is_lookup()) return FindInLookup(word, affix_indices); if (is_list()) return FindInList(word, affix_indices); return 0; // Corrupt file. } NodeReader::FindResult NodeReader::GetChildAt(int index, char* found_char, NodeReader* result) const { if (is_lookup()) { if (lookup_has_0th()) { if (index == 0) { *found_char = 0; return ReaderForLookup0th(result); } index--; // Make index relative to the non-0th-element table. } return ReaderForLookupAt(index, found_char, result); } if (is_list()) { return ReaderForListAt(index, found_char, result); } return FIND_DONE; } int NodeReader::CompareLeafNode( const unsigned char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const { // See if there is an additional string. const unsigned char* additional = additional_string_for_leaf(); if (!additional) { // No additional string. This means we should have reached the end of the // word to get a match. if (word[node_depth_] != 0) return 0; return FillAffixesForLeafMatch(0, affix_indices); } // Check the additional string. int cur = 0; while (&additional[cur] < bdict_end_ && additional[cur]) { if (word[node_depth_ + cur] != additional[cur]) return 0; // Not a match. cur++; } if (&additional[cur] == bdict_end_) { is_valid_ = false; return 0; } // Got to the end of the additional string, the word should also be over for // a match (the same as above). if (word[node_depth_ + cur] != 0) return 0; return FillAffixesForLeafMatch(cur + 1, affix_indices); } int NodeReader::FillAffixesForLeafMatch( size_t additional_bytes, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const { // The first match is easy, it always comes from the affix_id included in the // leaf node. affix_indices[0] = affix_id_for_leaf(); if (!leaf_has_following() && affix_indices[0] != BDict::FIRST_AFFIX_IS_UNUSED) return 1; // Common case: no additional affix group IDs. // We may or may not need to ignore that first value we just read, since it // could be a dummy placeholder value. The |list_offset| is the starting // position in the output list to write the rest of the values, which may // overwrite the first value. int list_offset = 1; if (affix_indices[0] == BDict::FIRST_AFFIX_IS_UNUSED) list_offset = 0; // Save the end pointer (accounting for an odd number of bytes). size_t array_start = node_offset_ + additional_bytes + 2; const uint16_t* const bdict_short_end = reinterpret_cast( &bdict_data_[((bdict_length_ - array_start) & -2) + array_start]); // Process all remaining matches. const uint16_t* following_array = reinterpret_cast(&bdict_data_[array_start]); for (int i = 0; i < BDict::MAX_AFFIXES_PER_WORD - list_offset; i++) { if (&following_array[i] >= bdict_short_end) { is_valid_ = false; return 0; } if (following_array[i] == BDict::LEAF_NODE_FOLLOWING_LIST_TERMINATOR) return i + list_offset; // Found the end of the list. affix_indices[i + list_offset] = following_array[i]; } return BDict::MAX_AFFIXES_PER_WORD; } int NodeReader::FindInLookup( const unsigned char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const { unsigned char next_char = word[node_depth_]; NodeReader child_reader; if (next_char == 0 && lookup_has_0th()) { if (ReaderForLookup0th(&child_reader) != FIND_NODE) return 0; } else { // Look up in the regular part of the table. int offset_in_table = static_cast(next_char) - lookup_first_char(); if (offset_in_table < 0 || offset_in_table > lookup_num_chars()) return 0; // Table can not include this value. char dummy_char; if (ReaderForLookupAt(offset_in_table, &dummy_char, &child_reader) != FIND_NODE) return 0; DCHECK(dummy_char == static_cast(next_char)); } if (!child_reader.is_valid()) return 0; // Something is messed up. // Now recurse into that child node. return child_reader.FindWord(word, affix_indices); } NodeReader::FindResult NodeReader::ReaderForLookup0th( NodeReader* result) const { size_t child_offset; if (is_lookup_32()) { child_offset = *reinterpret_cast( &bdict_data_[zeroth_entry_offset()]); } else { child_offset = *reinterpret_cast( &bdict_data_[zeroth_entry_offset()]); child_offset += node_offset_; } // Range check the offset; if (child_offset >= bdict_length_) { is_valid_ = false; return FIND_DONE; } // Now recurse into that child node. We don't advance to the next character // here since the 0th element will be a leaf (see ReaderForLookupAt). *result = NodeReader(bdict_data_, bdict_length_, child_offset, node_depth_); return FIND_NODE; } NodeReader::FindResult NodeReader::ReaderForLookupAt( size_t index, char* found_char, NodeReader* result) const { const unsigned char* table_begin = &bdict_data_[lookup_table_offset()]; if (index >= static_cast(lookup_num_chars()) || !is_valid_) return FIND_DONE; size_t child_offset; if (is_lookup_32()) { // Table contains 32-bit absolute offsets. child_offset = reinterpret_cast(table_begin)[index]; if (!child_offset) return FIND_NOTHING; // This entry in the table is empty. } else { // Table contains 16-bit offsets relative to the current node. child_offset = reinterpret_cast(table_begin)[index]; if (!child_offset) return FIND_NOTHING; // This entry in the table is empty. child_offset += node_offset_; } // Range check the offset; if (child_offset >= bdict_length_) { is_valid_ = false; return FIND_DONE; // Error. } // This is a bit tricky. When we've just reached the end of a word, the word // itself will be stored in a leaf "node" off of this node. That node, of // course, will want to know that it's the end of the word and so we have to // have it use the same index into the word as we're using at this level. // // This happens when there is a word in the dictionary that is a strict // prefix of other words in the dictionary, and so we'll have a non-leaf // node representing the entire word before the ending leaf node. // // In all other cases, we want to advance to the next character. Even if the // child node is a leaf, it will have an additional character that it will // want to check. *found_char = static_cast(index + lookup_first_char()); if (!is_valid_) return FIND_DONE; int char_advance = *found_char == 0 ? 0 : 1; *result = NodeReader(bdict_data_, bdict_length_, child_offset, node_depth_ + char_advance); return FIND_NODE; } int NodeReader::FindInList( const unsigned char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const { unsigned char next_char = word[node_depth_]; // TODO(brettw) replace with binary search. size_t list_count = list_item_count(); const unsigned char* list_begin = &bdict_data_[node_offset_ + 1]; int bytes_per_index = (is_list_16() ? 3 : 2); for (size_t i = 0; i < list_count; i++) { const unsigned char* list_current = &list_begin[i * bytes_per_index]; if (list_current >= bdict_end_) { is_valid_ = false; return 0; } if (*list_current == next_char) { // Found a match. char dummy_char; NodeReader child_reader; if (ReaderForListAt(i, &dummy_char, &child_reader) != FIND_NODE) return 0; DCHECK(dummy_char == static_cast(next_char)); return child_reader.FindWord(word, affix_indices); } } return 0; } NodeReader::FindResult NodeReader::ReaderForListAt( size_t index, char* found_char, NodeReader* result) const { size_t list_begin = node_offset_ + 1; if (index >= list_item_count()) return FIND_DONE; size_t offset; if (is_list_16()) { const unsigned char* list_item_begin = bdict_data_ + list_begin + index * 3; *found_char = static_cast(list_item_begin[0]); // The children begin right after the list. size_t children_begin = list_begin + list_item_count() * 3; offset = children_begin + *reinterpret_cast( &list_item_begin[1]); } else { const unsigned char* list_item_begin = bdict_data_ + list_begin + index * 2; *found_char = list_item_begin[0]; size_t children_begin = list_begin + list_item_count() * 2; offset = children_begin + list_item_begin[1]; } if (offset == 0 || node_offset_ >= bdict_length_) { is_valid_ = false; return FIND_DONE; // Error, should not happen except for corruption. } int char_advance = *found_char == 0 ? 0 : 1; // See ReaderForLookupAt. *result = NodeReader(bdict_data_, bdict_length_, offset, node_depth_ + char_advance); return FIND_NODE; } // WordIterator ---------------------------------------------------------------- struct WordIterator::NodeInfo { // The current offset is set to -1 so we start iterating at 0 when Advance // is called. NodeInfo(const NodeReader& rdr, char add) : reader(rdr), addition(add), cur_offset(-1) { } // The reader for this node level. NodeReader reader; // The character that this level represents. For the 0th level, this will // be 0 (since it is the root that represents no characters). char addition; // The current index into the reader that we're reading. Combined with the // |stack_|, this allows us to iterate over the tree in depth-first order. int cur_offset; }; WordIterator::WordIterator(const NodeReader& reader) { NodeInfo info(reader, 0); stack_.push_back(info); } WordIterator::WordIterator(const WordIterator& other) { operator=(other); } WordIterator::~WordIterator() { // Can't be in the header for the NodeReader destructor. } WordIterator& WordIterator::operator=(const WordIterator& other) { stack_ = other.stack_; return *this; } int WordIterator::Advance(char* output_buffer, size_t output_len, int affix_ids[BDict::MAX_AFFIXES_PER_WORD]) { // In-order tree walker. This uses a loop for fake tail recursion. while (!stack_.empty()) { NodeInfo& cur = stack_.back(); cur.cur_offset++; char cur_char; NodeReader child_reader; /*if (cur.reader.is_leaf()) { child_reader = cur.reader; cur_char = cur.addition; stack_.pop_back(); return FoundLeaf(child_reader, cur_char, output_buffer, output_len, affix_ids); }*/ switch (cur.reader.GetChildAt(cur.cur_offset, &cur_char, &child_reader)) { case NodeReader::FIND_NODE: // Got a valid child node. if (child_reader.is_leaf()) { return FoundLeaf(child_reader, cur_char, output_buffer, output_len, affix_ids); } // Not a leaf. Add the new node to our stack and try again. stack_.push_back(NodeInfo(child_reader, cur_char)); break; case NodeReader::FIND_NOTHING: // This one is empty, but we're not done. Continue on. break; case NodeReader::FIND_DONE: // No more children at this level, pop the stack and go back one. stack_.pop_back(); } } return false; } int WordIterator::FoundLeaf(const NodeReader& reader, char cur_char, char* output_buffer, size_t output_len, int affix_ids[BDict::MAX_AFFIXES_PER_WORD]) { // Remember that the first item in the stack is the root and so doesn't count. int i; for (i = 0; i < static_cast(stack_.size()) - 1 && i < static_cast(output_len) - 1; i++) output_buffer[i] = stack_[i + 1].addition; output_buffer[i++] = cur_char; // The one we just found. // Possibly add any extra parts. size_t additional_string_length = 0; const char* additional = reinterpret_cast( reader.additional_string_for_leaf()); for (; i < static_cast(output_len) - 1 && additional && additional[additional_string_length] != 0; i++, additional_string_length++) output_buffer[i] = additional[additional_string_length]; if (additional_string_length) additional_string_length++; // Account for the null terminator. output_buffer[i] = 0; return reader.FillAffixesForLeafMatch(additional_string_length, affix_ids); } // LineIterator ---------------------------------------------------------------- LineIterator::LineIterator( const unsigned char* bdict_data, size_t bdict_length, size_t first_offset) : bdict_data_(bdict_data), bdict_length_(bdict_length), cur_offset_(first_offset) { } // Returns true when all data has been read. We're done when we reach a // double-NULL or a the end of the input (shouldn't happen). bool LineIterator::IsDone() const { return cur_offset_ >= bdict_length_ || bdict_data_[cur_offset_] == 0; } const char* LineIterator::Advance() { if (IsDone()) return NULL; const char* begin = reinterpret_cast(&bdict_data_[cur_offset_]); // Advance over this word to find the end. while (cur_offset_ < bdict_length_ && bdict_data_[cur_offset_]) cur_offset_++; cur_offset_++; // Advance over the NULL terminator. return begin; } bool LineIterator::AdvanceAndCopy(char* buf, size_t buf_len) { if (IsDone()) return false; const char* begin = reinterpret_cast(&bdict_data_[cur_offset_]); // Advance over this word to find the end. size_t i; for (i = 0; i < buf_len && cur_offset_ < bdict_length_ && bdict_data_[cur_offset_]; i++, cur_offset_++) { buf[i] = bdict_data_[cur_offset_]; } // Handle the NULL terminator. cur_offset_++; // Consume in the input if (i < buf_len) buf[i] = 0; // Save in the output. else buf[buf_len - 1] = 0; // Overflow, make sure it's terminated. return !!buf[0]; } // ReplacementIterator --------------------------------------------------------- // Fills pointers to NULL terminated strings into the given output params. // Returns false if there are no more pairs and nothing was filled in. bool ReplacementIterator::GetNext(const char** first, const char** second) { if (IsDone()) return false; *first = Advance(); *second = Advance(); return *first && *second; } // BDictReader ----------------------------------------------------------------- BDictReader::BDictReader() : bdict_data_(NULL), bdict_length_(0), header_(NULL) { } bool BDictReader::Init(const unsigned char* bdict_data, size_t bdict_length) { if (bdict_length < sizeof(BDict::Header)) return false; // Check header. header_ = reinterpret_cast(bdict_data); if (header_->signature != BDict::SIGNATURE || header_->major_version > BDict::MAJOR_VERSION || header_->dic_offset > bdict_length) return false; // Get the affix header, make sure there is enough room for it. if (header_->aff_offset + sizeof(BDict::AffHeader) > bdict_length) return false; aff_header_ = reinterpret_cast( &bdict_data[header_->aff_offset]); // Make sure there is enough room for the affix group count dword. if (aff_header_->affix_group_offset > bdict_length - sizeof(uint32_t)) return false; // This function is called from SpellCheck::SpellCheckWord(), which blocks // WebKit. To avoid blocking WebKit for a long time, we do not check the MD5 // digest here. Instead we check the MD5 digest when Chrome finishes // downloading a dictionary. // Don't set these until the end. This way, NULL bdict_data_ will indicate // failure. bdict_data_ = bdict_data; bdict_length_ = bdict_length; return true; } int BDictReader::FindWord( const char* word, int affix_indices[BDict::MAX_AFFIXES_PER_WORD]) const { if (!bdict_data_ || header_->dic_offset >= bdict_length_) { // When the dictionary is corrupt, we return 0 which means the word is valid // and has no rules. This means when there is some problem, we'll default // to no spellchecking rather than marking everything as misspelled. return 0; } NodeReader reader(bdict_data_, bdict_length_, header_->dic_offset, 0); return reader.FindWord(reinterpret_cast(word), affix_indices); } LineIterator BDictReader::GetAfLineIterator() const { if (!bdict_data_ || aff_header_->affix_group_offset == 0 || aff_header_->affix_group_offset >= bdict_length_) return LineIterator(bdict_data_, 0, 0); // Item is empty or invalid. return LineIterator(bdict_data_, bdict_length_, aff_header_->affix_group_offset); } LineIterator BDictReader::GetAffixLineIterator() const { if (!bdict_data_ || aff_header_->affix_rule_offset == 0 || aff_header_->affix_rule_offset >= bdict_length_) return LineIterator(bdict_data_, 0, 0); // Item is empty or invalid. return LineIterator(bdict_data_, bdict_length_, aff_header_->affix_rule_offset); } LineIterator BDictReader::GetOtherLineIterator() const { if (!bdict_data_ || aff_header_->other_offset == 0 || aff_header_->other_offset >= bdict_length_) return LineIterator(bdict_data_, 0, 0); // Item is empty or invalid. return LineIterator(bdict_data_, bdict_length_, aff_header_->other_offset); } ReplacementIterator BDictReader::GetReplacementIterator() const { return ReplacementIterator(bdict_data_, bdict_length_, aff_header_->rep_offset); } WordIterator BDictReader::GetAllWordIterator() const { NodeReader reader(bdict_data_, bdict_length_, header_->dic_offset, 0); return WordIterator(reader); } } // namespace hunspell