#include #include #include #include #include #include #include #include "tree_fragment.h" #include "translator.h" #include "hg.h" #include "sentence_metadata.h" #include "filelib.h" #include "stringlib.h" #include "tdict.h" #include "verbose.h" using namespace std; struct Tree2StringGrammarNode { map next; vector rules; }; void ReadTree2StringGrammar(istream* in, Tree2StringGrammarNode* root) { string line; while(getline(*in, line)) { size_t pos = line.find("|||"); assert(pos != string::npos); assert(pos > 3); unsigned xc = 0; while (line[pos - 1] == ' ') { --pos; xc++; } cdec::TreeFragment rule_src(line.substr(0, pos), true); Tree2StringGrammarNode* cur = root; ostringstream os; int lhs = -(rule_src.root & cdec::ALL_MASK); // build source RHS for SCFG projection // TODO - this is buggy - it will generate a well-formed SCFG rule // but it will not generate source strings correctly vector frhs; for (auto sym : rule_src) { cur = &cur->next[sym]; if (sym) { if (cdec::IsFrontier(sym)) { // frontier symbols -> variables int nt = (sym & cdec::ALL_MASK); frhs.push_back(-nt); } else if (cdec::IsTerminal(sym)) { frhs.push_back(sym); } } } os << '[' << TD::Convert(-lhs) << "] |||"; for (auto x : frhs) { os << ' '; if (x < 0) os << '[' << TD::Convert(-x) << ']'; else os << TD::Convert(x); } pos += 3 + xc; while(line[pos] == ' ') { ++pos; } os << " ||| " << line.substr(pos); TRulePtr rule(new TRule(os.str())); cur->rules.push_back(rule); } } struct ParserState { ParserState() : in_iter(), node() {} cdec::TreeFragment::iterator in_iter; ParserState(const cdec::TreeFragment::iterator& it, Tree2StringGrammarNode* n) : in_iter(it), input_node_idx(it.node_idx()), node(n) {} ParserState(const cdec::TreeFragment::iterator& it, Tree2StringGrammarNode* n, const ParserState& p) : in_iter(it), future_work(p.future_work), input_node_idx(p.input_node_idx), node(n) {} bool operator==(const ParserState& o) const { return node == o.node && input_node_idx == o.input_node_idx && future_work == o.future_work && in_iter == o.in_iter; } vector future_work; int input_node_idx; // lhs of top level NT Tree2StringGrammarNode* node; }; namespace std { template<> struct hash { size_t operator()(const ParserState& s) const { size_t h = boost::hash_range(s.future_work.begin(), s.future_work.end()); boost::hash_combine(h, boost::hash_value(s.node)); boost::hash_combine(h, boost::hash_value(s.input_node_idx)); //boost::hash_combine(h, ); return h; } }; }; struct Tree2StringTranslatorImpl { vector> root; bool add_pass_through_rules; Tree2StringTranslatorImpl(const boost::program_options::variables_map& conf) : add_pass_through_rules(conf.count("add_pass_through_rules")) { if (conf.count("grammar")) { const vector gf = conf["grammar"].as>(); root.resize(gf.size()); unsigned gc = 0; for (auto& f : gf) { ReadFile rf(f); root[gc].reset(new Tree2StringGrammarNode); ReadTree2StringGrammar(rf.stream(), &*root[gc++]); } } } bool Translate(const string& input, SentenceMetadata* smeta, const vector& weights, Hypergraph* minus_lm_forest) { cdec::TreeFragment input_tree(input, false); Hypergraph hg; hg.ReserveNodes(input_tree.nodes.size()); vector tree2hg(input_tree.nodes.size() + 1, -1); queue q; unordered_set unique; // only create items one time for (auto& g : root) { q.push(ParserState(input_tree.begin(), g.get())); unique.insert(q.back()); } unsigned tree_top = q.front().input_node_idx; while(!q.empty()) { ParserState& s = q.front(); if (s.in_iter.at_end()) { // completed a traversal of a subtree //cerr << "I traversed a subtree of the input rooted at node=" << s.input_node_idx << " sym=" << // TD::Convert(input_tree.nodes[s.input_node_idx].lhs & cdec::ALL_MASK) << endl; if (s.node->rules.size()) { int& node_id = tree2hg[s.input_node_idx]; if (node_id < 0) node_id = hg.AddNode(-(input_tree.nodes[s.input_node_idx].lhs & cdec::ALL_MASK))->id_; TailNodeVector tail; for (auto n : s.future_work) { int& nix = tree2hg[n]; if (nix < 0) nix = hg.AddNode(-(input_tree.nodes[n].lhs & cdec::ALL_MASK))->id_; tail.push_back(nix); } for (auto& r : s.node->rules) { assert(tail.size() == r->Arity()); HG::Edge* new_edge = hg.AddEdge(r, tail); new_edge->feature_values_ = r->GetFeatureValues(); // TODO: set i and j hg.ConnectEdgeToHeadNode(new_edge, &hg.nodes_[node_id]); } for (auto n : s.future_work) { const auto it = input_tree.begin(n); // start tree iterator at node n for (auto& g : root) { ParserState s(it, g.get()); if (unique.insert(s).second) q.push(s); } } } else { //cerr << "I can't build anything :(\n"; } } else { // more input tree to match unsigned sym = *s.in_iter; if (cdec::IsLHS(sym)) { auto nit = s.node->next.find(sym); if (nit != s.node->next.end()) { //cerr << "MATCHED LHS: " << TD::Convert(sym & cdec::ALL_MASK) << endl; ParserState news(++s.in_iter, &nit->second, s); if (unique.insert(news).second) q.push(news); } } else if (cdec::IsRHS(sym)) { //cerr << "Attempting to match RHS: " << TD::Convert(sym & cdec::ALL_MASK) << endl; cdec::TreeFragment::iterator var = s.in_iter; var.truncate(); auto nit1 = s.node->next.find(sym); auto nit2 = s.node->next.find(*var); if (nit2 != s.node->next.end()) { //cerr << "MATCHED VAR RHS: " << TD::Convert(sym & cdec::ALL_MASK) << endl; ++var; const unsigned new_work = s.in_iter.child_node(); ParserState new_s(var, &nit2->second, s); new_s.future_work.push_back(new_work); // if this traversal of the input succeeds, future_work goes on the q if (unique.insert(new_s).second) q.push(new_s); } if (nit1 != s.node->next.end()) { //cerr << "MATCHED FULL RHS: " << TD::Convert(sym & cdec::ALL_MASK) << endl; const ParserState new_s(++s.in_iter, &nit1->second, s); if (unique.insert(new_s).second) q.push(new_s); } } else if (cdec::IsTerminal(sym)) { auto nit = s.node->next.find(sym); if (nit != s.node->next.end()) { //cerr << "MATCHED TERMINAL: " << TD::Convert(sym) << endl; const ParserState new_s(++s.in_iter, &nit->second, s); if (unique.insert(new_s).second) q.push(new_s); } } else { cerr << "This can never happen!\n"; abort(); } } q.pop(); } int goal = tree2hg[tree_top]; if (goal < 0) return false; //cerr << "Goal node: " << goal << endl; hg.TopologicallySortNodesAndEdges(goal); hg.Reweight(weights); // there might be nodes that cannot be derived // the following takes care of them vector prune(hg.edges_.size(), false); hg.PruneEdges(prune, true); if (hg.edges_.size() == 0) return false; //hg.PrintGraphviz(); minus_lm_forest->swap(hg); return true; } }; Tree2StringTranslator::Tree2StringTranslator(const boost::program_options::variables_map& conf) : pimpl_(new Tree2StringTranslatorImpl(conf)) {} bool Tree2StringTranslator::TranslateImpl(const string& input, SentenceMetadata* smeta, const vector& weights, Hypergraph* minus_lm_forest) { return pimpl_->Translate(input, smeta, weights, minus_lm_forest); } void Tree2StringTranslator::ProcessMarkupHintsImpl(const map& kv) { } void Tree2StringTranslator::SentenceCompleteImpl() { } std::string Tree2StringTranslator::GetDecoderType() const { return "tree2string"; }