// Copyright (c) 2011 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 "chrome/browser/history/query_parser.h" #include <algorithm> #include "base/i18n/break_iterator.h" #include "base/logging.h" #include "base/memory/scoped_vector.h" #include "base/string_util.h" #include "base/utf_string_conversions.h" #include "ui/base/l10n/l10n_util.h" #include "unicode/uscript.h" namespace { // Returns true if |mp1.first| is less than |mp2.first|. This is used to // sort match positions. int CompareMatchPosition(const Snippet::MatchPosition& mp1, const Snippet::MatchPosition& mp2) { return mp1.first < mp2.first; } // Returns true if |mp2| intersects |mp1|. This is intended for use by // CoalesceMatchesFrom and isn't meant as a general intersectpion comparison // function. bool SnippetIntersects(const Snippet::MatchPosition& mp1, const Snippet::MatchPosition& mp2) { return mp2.first >= mp1.first && mp2.first <= mp1.second; } // Coalesces match positions in |matches| after index that intersect the match // position at |index|. void CoalesceMatchesFrom(size_t index, Snippet::MatchPositions* matches) { Snippet::MatchPosition& mp = (*matches)[index]; for (Snippet::MatchPositions::iterator i = matches->begin() + index + 1; i != matches->end(); ) { if (SnippetIntersects(mp, *i)) { mp.second = i->second; i = matches->erase(i); } else { return; } } } // Sorts the match positions in |matches| by their first index, then coalesces // any match positions that intersect each other. void CoalseAndSortMatchPositions(Snippet::MatchPositions* matches) { std::sort(matches->begin(), matches->end(), &CompareMatchPosition); // WARNING: we don't use iterator here as CoalesceMatchesFrom may remove // from matches. for (size_t i = 0; i < matches->size(); ++i) CoalesceMatchesFrom(i, matches); } } // namespace // Inheritance structure: // Queries are represented as trees of QueryNodes. // QueryNodes are either a collection of subnodes (a QueryNodeList) // or a single word (a QueryNodeWord). // A QueryNodeWord is a single word in the query. class QueryNodeWord : public QueryNode { public: explicit QueryNodeWord(const string16& word) : word_(word), literal_(false) {} virtual ~QueryNodeWord() {} virtual int AppendToSQLiteQuery(string16* query) const; virtual bool IsWord() const { return true; } const string16& word() const { return word_; } void set_literal(bool literal) { literal_ = literal; } virtual bool HasMatchIn(const std::vector<QueryWord>& words, Snippet::MatchPositions* match_positions) const; virtual bool Matches(const string16& word, bool exact) const; virtual void AppendWords(std::vector<string16>* words) const; private: string16 word_; bool literal_; }; bool QueryNodeWord::HasMatchIn(const std::vector<QueryWord>& words, Snippet::MatchPositions* match_positions) const { for (size_t i = 0; i < words.size(); ++i) { if (Matches(words[i].word, false)) { size_t match_start = words[i].position; match_positions->push_back( Snippet::MatchPosition(match_start, match_start + static_cast<int>(word_.size()))); return true; } } return false; } bool QueryNodeWord::Matches(const string16& word, bool exact) const { if (exact || !QueryParser::IsWordLongEnoughForPrefixSearch(word_)) return word == word_; return word.size() >= word_.size() && (word_.compare(0, word_.size(), word, 0, word_.size()) == 0); } void QueryNodeWord::AppendWords(std::vector<string16>* words) const { words->push_back(word_); } int QueryNodeWord::AppendToSQLiteQuery(string16* query) const { query->append(word_); // Use prefix search if we're not literal and long enough. if (!literal_ && QueryParser::IsWordLongEnoughForPrefixSearch(word_)) *query += L'*'; return 1; } // A QueryNodeList has a collection of child QueryNodes // which it cleans up after. class QueryNodeList : public QueryNode { public: virtual ~QueryNodeList(); virtual int AppendToSQLiteQuery(string16* query) const { return AppendChildrenToString(query); } virtual bool IsWord() const { return false; } void AddChild(QueryNode* node) { children_.push_back(node); } typedef std::vector<QueryNode*> QueryNodeVector; QueryNodeVector* children() { return &children_; } // Remove empty subnodes left over from other parsing. void RemoveEmptySubnodes(); // QueryNodeList is never used with Matches or HasMatchIn. virtual bool Matches(const string16& word, bool exact) const { NOTREACHED(); return false; } virtual bool HasMatchIn(const std::vector<QueryWord>& words, Snippet::MatchPositions* match_positions) const { NOTREACHED(); return false; } virtual void AppendWords(std::vector<string16>* words) const; protected: int AppendChildrenToString(string16* query) const; QueryNodeVector children_; }; QueryNodeList::~QueryNodeList() { for (QueryNodeVector::iterator node = children_.begin(); node != children_.end(); ++node) delete *node; } void QueryNodeList::RemoveEmptySubnodes() { for (size_t i = 0; i < children_.size(); ++i) { if (children_[i]->IsWord()) continue; QueryNodeList* list_node = static_cast<QueryNodeList*>(children_[i]); list_node->RemoveEmptySubnodes(); if (list_node->children()->empty()) { children_.erase(children_.begin() + i); --i; delete list_node; } } } void QueryNodeList::AppendWords(std::vector<string16>* words) const { for (size_t i = 0; i < children_.size(); ++i) children_[i]->AppendWords(words); } int QueryNodeList::AppendChildrenToString(string16* query) const { int num_words = 0; for (QueryNodeVector::const_iterator node = children_.begin(); node != children_.end(); ++node) { if (node != children_.begin()) query->push_back(L' '); num_words += (*node)->AppendToSQLiteQuery(query); } return num_words; } // A QueryNodePhrase is a phrase query ("quoted"). class QueryNodePhrase : public QueryNodeList { public: virtual int AppendToSQLiteQuery(string16* query) const { query->push_back(L'"'); int num_words = AppendChildrenToString(query); query->push_back(L'"'); return num_words; } virtual bool Matches(const string16& word, bool exact) const; virtual bool HasMatchIn(const std::vector<QueryWord>& words, Snippet::MatchPositions* match_positions) const; }; bool QueryNodePhrase::Matches(const string16& word, bool exact) const { NOTREACHED(); return false; } bool QueryNodePhrase::HasMatchIn( const std::vector<QueryWord>& words, Snippet::MatchPositions* match_positions) const { if (words.size() < children_.size()) return false; for (size_t i = 0, max = words.size() - children_.size() + 1; i < max; ++i) { bool matched_all = true; for (size_t j = 0; j < children_.size(); ++j) { if (!children_[j]->Matches(words[i + j].word, true)) { matched_all = false; break; } } if (matched_all) { const QueryWord& last_word = words[i + children_.size() - 1]; match_positions->push_back( Snippet::MatchPosition(words[i].position, last_word.position + last_word.word.length())); return true; } } return false; } QueryParser::QueryParser() { } // static bool QueryParser::IsWordLongEnoughForPrefixSearch(const string16& word) { DCHECK(!word.empty()); size_t minimum_length = 3; // We intentionally exclude Hangul Jamos (both Conjoining and compatibility) // because they 'behave like' Latin letters. Moreover, we should // normalize the former before reaching here. if (0xAC00 <= word[0] && word[0] <= 0xD7A3) minimum_length = 2; return word.size() >= minimum_length; } // Returns true if the character is considered a quote. static bool IsQueryQuote(wchar_t ch) { return ch == '"' || ch == 0xab || // left pointing double angle bracket ch == 0xbb || // right pointing double angle bracket ch == 0x201c || // left double quotation mark ch == 0x201d || // right double quotation mark ch == 0x201e; // double low-9 quotation mark } int QueryParser::ParseQuery(const string16& query, string16* sqlite_query) { QueryNodeList root; if (!ParseQueryImpl(query, &root)) return 0; return root.AppendToSQLiteQuery(sqlite_query); } void QueryParser::ParseQuery(const string16& query, std::vector<QueryNode*>* nodes) { QueryNodeList root; if (ParseQueryImpl(l10n_util::ToLower(query), &root)) nodes->swap(*root.children()); } void QueryParser::ExtractQueryWords(const string16& query, std::vector<string16>* words) { QueryNodeList root; if (!ParseQueryImpl(query, &root)) return; root.AppendWords(words); } bool QueryParser::DoesQueryMatch(const string16& text, const std::vector<QueryNode*>& query_nodes, Snippet::MatchPositions* match_positions) { if (query_nodes.empty()) return false; std::vector<QueryWord> query_words; string16 lower_text = l10n_util::ToLower(text); ExtractQueryWords(lower_text, &query_words); if (query_words.empty()) return false; Snippet::MatchPositions matches; for (size_t i = 0; i < query_nodes.size(); ++i) { if (!query_nodes[i]->HasMatchIn(query_words, &matches)) return false; } if (lower_text.length() != text.length()) { // The lower case string differs from the original string. The matches are // meaningless. // TODO(sky): we need a better way to align the positions so that we don't // completely punt here. match_positions->clear(); } else { CoalseAndSortMatchPositions(&matches); match_positions->swap(matches); } return true; } bool QueryParser::ParseQueryImpl(const string16& query, QueryNodeList* root) { base::BreakIterator iter(&query, base::BreakIterator::BREAK_WORD); // TODO(evanm): support a locale here if (!iter.Init()) return false; // To handle nesting, we maintain a stack of QueryNodeLists. // The last element (back) of the stack contains the current, deepest node. std::vector<QueryNodeList*> query_stack; query_stack.push_back(root); bool in_quotes = false; // whether we're currently in a quoted phrase while (iter.Advance()) { // Just found a span between 'prev' (inclusive) and 'pos' (exclusive). It // is not necessarily a word, but could also be a sequence of punctuation // or whitespace. if (iter.IsWord()) { string16 word = iter.GetString(); QueryNodeWord* word_node = new QueryNodeWord(word); if (in_quotes) word_node->set_literal(true); query_stack.back()->AddChild(word_node); } else { // Punctuation. if (IsQueryQuote(query[iter.prev()])) { if (!in_quotes) { QueryNodeList* quotes_node = new QueryNodePhrase; query_stack.back()->AddChild(quotes_node); query_stack.push_back(quotes_node); in_quotes = true; } else { query_stack.pop_back(); // Stop adding to the quoted phrase. in_quotes = false; } } } } root->RemoveEmptySubnodes(); return true; } void QueryParser::ExtractQueryWords(const string16& text, std::vector<QueryWord>* words) { base::BreakIterator iter(&text, base::BreakIterator::BREAK_WORD); // TODO(evanm): support a locale here if (!iter.Init()) return; while (iter.Advance()) { // Just found a span between 'prev' (inclusive) and 'pos' (exclusive). It // is not necessarily a word, but could also be a sequence of punctuation // or whitespace. if (iter.IsWord()) { string16 word = iter.GetString(); if (!word.empty()) { words->push_back(QueryWord()); words->back().word = word; words->back().position = iter.prev(); } } } }