Yannick Estève / ONTRAC-Kaldi

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tools/openfst-1.6.7/src/include/fst/sparse-power-weight.h 6.55 KB
  // See www.openfst.org for extensive documentation on this weighted
  // finite-state transducer library.
  //
  // Cartesian power weight semiring operation definitions, using
  // SparseTupleWeight as underlying representation.
  
  #ifndef FST_SPARSE_POWER_WEIGHT_H_
  #define FST_SPARSE_POWER_WEIGHT_H_
  
  #include <climits>
  #include <string>
  
  #include <fst/sparse-tuple-weight.h>
  #include <fst/weight.h>
  
  
  namespace fst {
  
  // Sparse cartesian power semiring: W ^ n
  //
  // Forms:
  //
  //  - a left semimodule when W is a left semiring,
  //  - a right semimodule when W is a right semiring,
  //  - a bisemimodule when W is a semiring,
  //    the free semimodule of rank n over W
  //
  // The Times operation is overloaded to provide the left and right scalar
  // products.
  //
  // K is the key value type. kNoKey (-1) is reserved for internal use
  template <class W, class K = int>
  class SparsePowerWeight : public SparseTupleWeight<W, K> {
   public:
    using ReverseWeight = SparsePowerWeight<typename W::ReverseWeight, K>;
  
    SparsePowerWeight() {}
  
    explicit SparsePowerWeight(const SparseTupleWeight<W, K> &weight)
        : SparseTupleWeight<W, K>(weight) {}
  
    template <class Iterator>
    SparsePowerWeight(Iterator begin, Iterator end)
        : SparseTupleWeight<W, K>(begin, end) {}
  
    // Initialize component `key` to `weight`, with `default_weight` for all
    // other components.
    SparsePowerWeight(const K &key, const W &weight,
                      const W &default_weight = W::Zero())
        : SparseTupleWeight<W, K>(key, weight, default_weight) {}
  
    static const SparsePowerWeight &Zero() {
      static const SparsePowerWeight zero(SparseTupleWeight<W, K>::Zero());
      return zero;
    }
  
    static const SparsePowerWeight &One() {
      static const SparsePowerWeight one(SparseTupleWeight<W, K>::One());
      return one;
    }
  
    static const SparsePowerWeight &NoWeight() {
      static const SparsePowerWeight no_weight(
          SparseTupleWeight<W, K>::NoWeight());
      return no_weight;
    }
  
    // Overide this: Overwrite the Type method to reflect the key type if using
    // a non-default key type.
    static const string &Type() {
      static const string *const type = [] {
        string type = W::Type() + "_^n";
        if (sizeof(K) != sizeof(uint32)) {
          type += "_" + std::to_string(CHAR_BIT * sizeof(K));
        }
        return new string(type);
      }();
      return *type;
    }
  
    static constexpr uint64 Properties() {
      return W::Properties() &
             (kLeftSemiring | kRightSemiring | kCommutative | kIdempotent);
    }
  
    SparsePowerWeight Quantize(float delta = kDelta) const {
      return SparsePowerWeight(SparseTupleWeight<W, K>::Quantize(delta));
    }
  
    ReverseWeight Reverse() const {
      return ReverseWeight(SparseTupleWeight<W, K>::Reverse());
    }
  };
  
  template <class W, class K, class M>
  inline SparsePowerWeight<W, K> SparsePowerWeightMap(
      const SparsePowerWeight<W, K> &w1,
      const SparsePowerWeight<W, K> &w2,
      const M &operator_mapper) {
    SparsePowerWeight<W, K> result;
    SparseTupleWeightMap(&result, w1, w2, operator_mapper);
    return result;
  }
  
  // Semimodule plus operation.
  template <class W, class K>
  inline SparsePowerWeight<W, K> Plus(const SparsePowerWeight<W, K> &w1,
                                      const SparsePowerWeight<W, K> &w2) {
    return SparsePowerWeightMap(w1, w2, [](const K &k, const W &v1, const W &v2) {
      return Plus(v1, v2);
    });
  }
  
  // Semimodule times operation.
  template <class W, class K>
  inline SparsePowerWeight<W, K> Times(const SparsePowerWeight<W, K> &w1,
                                       const SparsePowerWeight<W, K> &w2) {
    return SparsePowerWeightMap(w1, w2, [](const K &k, const W &v1, const W &v2) {
      return Times(v1, v2);
    });
  }
  
  // Semimodule divide operation.
  template <class W, class K>
  inline SparsePowerWeight<W, K> Divide(const SparsePowerWeight<W, K> &w1,
                                        const SparsePowerWeight<W, K> &w2,
                                        DivideType type = DIVIDE_ANY) {
    return SparsePowerWeightMap(w1, w2,
                                [type](const K &k, const W &v1, const W &v2) {
                                  return Divide(v1, v2, type);
                                });
  }
  
  // Semimodule dot product operation.
  template <class W, class K>
  inline const W &DotProduct(const SparsePowerWeight<W, K> &w1,
                             const SparsePowerWeight<W, K> &w2) {
    const SparsePowerWeight<W, K> product = Times(w1, w2);
    W result(W::Zero());
    for (SparseTupleWeightIterator<W, K> it(product); !it.Done(); it.Next()) {
      result = Plus(result, it.Value().second);
    }
    return result;
  }
  
  template <class W, class K>
  inline bool ApproxEqual(const SparsePowerWeight<W, K> &w1,
                          const SparsePowerWeight<W, K> &w2,
                          float delta = kDelta) {
    auto result = SparsePowerWeightMap(
        w1, w2, [delta](const K &k, const W &v1, const W &v2) {
          return ApproxEqual(v1, v2, delta) ? W::One() : W::Zero();
        });
    return result == SparsePowerWeight<W, K>::One();
  }
  
  template <class W, class K>
  inline SparsePowerWeight<W, K> Times(const W &k,
                                       const SparsePowerWeight<W, K> &w2) {
    const SparseTupleWeight<W, K> t2(k);
    const SparsePowerWeight<W, K> w1(t2);
    return Times(w1, w2);
  }
  
  template <class W, class K>
  inline SparsePowerWeight<W, K> Times(const SparsePowerWeight<W, K> &w1,
                                       const W &k) {
    const SparseTupleWeight<W, K> t2(k);
    const SparsePowerWeight<W, K> w2(t2);
    return Times(w1, w2);
  }
  
  template <class W, class K>
  inline SparsePowerWeight<W, K> Divide(const SparsePowerWeight<W, K> &w1,
                                        const W &k,
                                        DivideType divide_type = DIVIDE_ANY) {
    const SparseTupleWeight<W, K> t2(k);
    const SparsePowerWeight<W, K> w2(t2);
    return Divide(w1, w2, divide_type);
  }
  
  // This function object generates weights over the Cartesian power of rank
  // n over the underlying weight. This is intended primarily for testing.
  template <class W, class K>
  class WeightGenerate<SparsePowerWeight<W, K>> {
   public:
    using Weight = SparsePowerWeight<W, K>;
    using Generate = WeightGenerate<W>;
  
    explicit WeightGenerate(bool allow_zero = true,
                            size_t sparse_power_rank = 3)
        : generate_(allow_zero), sparse_power_rank_(sparse_power_rank) {}
  
    Weight operator()() const {
      Weight weight;
      for (size_t i = 1; i <= sparse_power_rank_; ++i) {
        weight.PushBack(i, generate_(), true);
      }
      return weight;
    }
  
   private:
    const Generate generate_;
    const size_t sparse_power_rank_;
  };
  
  }  // namespace fst
  
  #endif  // FST_SPARSE_POWER_WEIGHT_H_