// lexicographic-weight.h // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // // Copyright 2005-2010 Google, Inc. // Author: rws@google.com (Richard Sproat) // // \file // Lexicographic weight set and associated semiring operation definitions. // // A lexicographic weight is a sequence of weights, each of which must have the // path property and Times() must be (strongly) cancellative // (for all a,b,c != Zero(): Times(c, a) = Times(c, b) => a = b, // Times(a, c) = Times(b, c) => a = b). // The + operation on two weights a and b is the lexicographically // prior of a and b. #ifndef FST_LIB_LEXICOGRAPHIC_WEIGHT_H__ #define FST_LIB_LEXICOGRAPHIC_WEIGHT_H__ #include #include #include namespace fst { template class LexicographicWeight : public PairWeight { public: using PairWeight::Value1; using PairWeight::Value2; using PairWeight::SetValue1; using PairWeight::SetValue2; using PairWeight::Zero; using PairWeight::One; using PairWeight::NoWeight; using PairWeight::Quantize; using PairWeight::Reverse; typedef LexicographicWeight ReverseWeight; LexicographicWeight() {} LexicographicWeight(const PairWeight& w) : PairWeight(w) {} LexicographicWeight(W1 w1, W2 w2) : PairWeight(w1, w2) { uint64 props = kPath; if ((W1::Properties() & props) != props) { FSTERROR() << "LexicographicWeight must " << "have the path property: " << W1::Type(); SetValue1(W1::NoWeight()); } if ((W2::Properties() & props) != props) { FSTERROR() << "LexicographicWeight must " << "have the path property: " << W2::Type(); SetValue2(W2::NoWeight()); } } static const LexicographicWeight &Zero() { static const LexicographicWeight zero(PairWeight::Zero()); return zero; } static const LexicographicWeight &One() { static const LexicographicWeight one(PairWeight::One()); return one; } static const LexicographicWeight &NoWeight() { static const LexicographicWeight no_weight( PairWeight::NoWeight()); return no_weight; } static const string &Type() { static const string type = W1::Type() + "_LT_" + W2::Type(); return type; } bool Member() const { if (!Value1().Member() || !Value2().Member()) return false; // Lexicographic weights cannot mix zeroes and non-zeroes. if (Value1() == W1::Zero() && Value2() == W2::Zero()) return true; if (Value1() != W1::Zero() && Value2() != W2::Zero()) return true; return false; } LexicographicWeight Quantize(float delta = kDelta) const { return PairWeight::Quantize(); } ReverseWeight Reverse() const { return PairWeight::Reverse(); } static uint64 Properties() { uint64 props1 = W1::Properties(); uint64 props2 = W2::Properties(); return props1 & props2 & (kLeftSemiring | kRightSemiring | kPath | kIdempotent | kCommutative); } }; template inline LexicographicWeight Plus(const LexicographicWeight &w, const LexicographicWeight &v) { if (!w.Member() || !v.Member()) return LexicographicWeight::NoWeight(); NaturalLess less1; NaturalLess less2; if (less1(w.Value1(), v.Value1())) return w; if (less1(v.Value1(), w.Value1())) return v; if (less2(w.Value2(), v.Value2())) return w; if (less2(v.Value2(), w.Value2())) return v; return w; } template inline LexicographicWeight Times(const LexicographicWeight &w, const LexicographicWeight &v) { return LexicographicWeight(Times(w.Value1(), v.Value1()), Times(w.Value2(), v.Value2())); } template inline LexicographicWeight Divide(const LexicographicWeight &w, const LexicographicWeight &v, DivideType typ = DIVIDE_ANY) { return LexicographicWeight(Divide(w.Value1(), v.Value1(), typ), Divide(w.Value2(), v.Value2(), typ)); } } // namespace fst #endif // FST_LIB_LEXICOGRAPHIC_WEIGHT_H__