src/test/weight-tester.h - platform/external/openfst - Git at Google

 // weight-tester.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: riley@google.com (Michael Riley)
 //
 // \file
 // Utility class for regression testing of Fst weights.

 #ifndef FST_TEST_WEIGHT_TESTER_H_
 #define FST_TEST_WEIGHT_TESTER_H_

 #include <iostream>
 #include <sstream>

 #include <fst/random-weight.h>

 namespace fst {

 // This class tests a variety of identities and properties that must
 // hold for the Weight class to be well-defined. It calls function object
 // WEIGHT_GENERATOR to select weights that are used in the tests.
 template<class Weight, class WeightGenerator>
 class WeightTester {
  public:
   WeightTester(WeightGenerator generator) : weight_generator_(generator) {}

   void Test(int iterations, bool test_division = true) {
     for (int i = 0; i < iterations; ++i) {
       // Selects the test weights.
       Weight w1 = weight_generator_();
       Weight w2 = weight_generator_();
       Weight w3 = weight_generator_();

       VLOG(1) << "weight type = " << Weight::Type();
       VLOG(1) << "w1 = " << w1;
       VLOG(1) << "w2 = " << w2;
       VLOG(1) << "w3 = " << w3;

       TestSemiring(w1, w2, w3);
       if (test_division)
         TestDivision(w1, w2);
       TestReverse(w1, w2);
       TestEquality(w1, w2, w3);
       TestIO(w1);
       TestCopy(w1);
     }
   }

  private:
   // Note in the tests below we use ApproxEqual rather than == and add
   // kDelta to inequalities where the weights might be inexact.

   // Tests (Plus, Times, Zero, One) defines a commutative semiring.
   void TestSemiring(Weight w1, Weight w2, Weight w3) {
     // Checks that the operations are closed.
     CHECK(Plus(w1, w2).Member());
     CHECK(Times(w1, w2).Member());

     // Checks that the operations are associative.
     CHECK(ApproxEqual(Plus(w1, Plus(w2, w3)), Plus(Plus(w1, w2), w3)));
     CHECK(ApproxEqual(Times(w1, Times(w2, w3)), Times(Times(w1, w2), w3)));

     // Checks the identity elements.
     CHECK(Plus(w1, Weight::Zero()) == w1);
     CHECK(Plus(Weight::Zero(), w1) == w1);
     CHECK(Times(w1, Weight::One()) == w1);
     CHECK(Times(Weight::One(), w1) == w1);

     // Check the no weight element.
     CHECK(!Weight::NoWeight().Member());
     CHECK(!Plus(w1, Weight::NoWeight()).Member());
     CHECK(!Plus(Weight::NoWeight(), w1).Member());
     CHECK(!Times(w1, Weight::NoWeight()).Member());
     CHECK(!Times(Weight::NoWeight(), w1).Member());

     // Checks that the operations commute.
     CHECK(ApproxEqual(Plus(w1, w2), Plus(w2, w1)));
     if (Weight::Properties() & kCommutative)
       CHECK(ApproxEqual(Times(w1, w2), Times(w2, w1)));

     // Checks Zero() is the annihilator.
     CHECK(Times(w1, Weight::Zero()) == Weight::Zero());
     CHECK(Times(Weight::Zero(), w1) == Weight::Zero());

     // Check Power(w, 0) is Weight::One()
     CHECK(Power(w1, 0) == Weight::One());

     // Check Power(w, 1) is w
     CHECK(Power(w1, 1) == w1);

     // Check Power(w, 3) is Times(w, Times(w, w))
     CHECK(Power(w1, 3) == Times(w1, Times(w1, w1)));

     // Checks distributivity.
     if (Weight::Properties() & kLeftSemiring)
       CHECK(ApproxEqual(Times(w1, Plus(w2, w3)),
                         Plus(Times(w1, w2), Times(w1, w3))));
     if (Weight::Properties() & kRightSemiring)
       CHECK(ApproxEqual(Times(Plus(w1, w2), w3),
                         Plus(Times(w1, w3), Times(w2, w3))));

     if (Weight::Properties() & kIdempotent)
       CHECK(Plus(w1, w1) == w1);

     if (Weight::Properties() & kPath)
       CHECK(Plus(w1, w2) == w1 || Plus(w1, w2) == w2);

     // Ensure weights form a left or right semiring.
     CHECK(Weight::Properties() & (kLeftSemiring | kRightSemiring));

     // Check when Times() is commutative that it is marked as a semiring.
     if (Weight::Properties() & kCommutative)
       CHECK(Weight::Properties() & kSemiring);
   }

   // Tests division operation.
   void TestDivision(Weight w1, Weight w2) {
     Weight p = Times(w1, w2);

     if (Weight::Properties() & kLeftSemiring) {
       Weight d = Divide(p, w1, DIVIDE_LEFT);
       if (d.Member())
         CHECK(ApproxEqual(p, Times(w1, d)));
       CHECK(!Divide(w1, Weight::NoWeight(), DIVIDE_LEFT).Member());
       CHECK(!Divide(Weight::NoWeight(), w1, DIVIDE_LEFT).Member());
     }

     if (Weight::Properties() & kRightSemiring) {
       Weight d = Divide(p, w2, DIVIDE_RIGHT);
       if (d.Member())
         CHECK(ApproxEqual(p, Times(d, w2)));
       CHECK(!Divide(w1, Weight::NoWeight(), DIVIDE_RIGHT).Member());
       CHECK(!Divide(Weight::NoWeight(), w1, DIVIDE_RIGHT).Member());
     }

     if (Weight::Properties() & kCommutative) {
       Weight d = Divide(p, w1, DIVIDE_RIGHT);
       if (d.Member())
         CHECK(ApproxEqual(p, Times(d, w1)));
     }
   }

   // Tests reverse operation.
   void TestReverse(Weight w1, Weight w2) {
     typedef typename Weight::ReverseWeight ReverseWeight;

     ReverseWeight rw1 = w1.Reverse();
     ReverseWeight rw2 = w2.Reverse();

     CHECK(rw1.Reverse() == w1);
     CHECK(Plus(w1, w2).Reverse() == Plus(rw1, rw2));
     CHECK(Times(w1, w2).Reverse() == Times(rw2, rw1));
   }

   // Tests == is an equivalence relation.
   void TestEquality(Weight w1, Weight w2, Weight w3) {
     // Checks reflexivity.
     CHECK(w1 == w1);

     // Checks symmetry.
     CHECK((w1 == w2) == (w2 == w1));

     // Checks transitivity.
     if (w1 == w2 && w2 == w3)
       CHECK(w1 == w3);
   }

   // Tests binary serialization and textual I/O.
   void TestIO(Weight w) {
     // Tests binary I/O
     {
     ostringstream os;
     w.Write(os);
     os.flush();
     istringstream is(os.str());
     Weight v;
     v.Read(is);
     CHECK_EQ(w, v);
     }

     // Tests textual I/O.
     {
       ostringstream os;
       os << w;
       istringstream is(os.str());
       Weight v(Weight::One());
       is >> v;
       CHECK(ApproxEqual(w, v));
     }
   }

   // Tests copy constructor and assignment operator
   void TestCopy(Weight w) {
     Weight x = w;
     CHECK(w == x);

     x = Weight(w);
     CHECK(w == x);

     x.operator=(x);
     CHECK(w == x);

   }

   // Generates weights used in testing.
   WeightGenerator weight_generator_;

   DISALLOW_COPY_AND_ASSIGN(WeightTester);
 };

 }  // namespace fst

 #endif  // FST_TEST_WEIGHT_TESTER_H_
	// weight-tester.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: riley@google.com (Michael Riley)
	//
	// \file
	// Utility class for regression testing of Fst weights.

	#ifndef FST_TEST_WEIGHT_TESTER_H_
	#define FST_TEST_WEIGHT_TESTER_H_

	#include <iostream>
	#include <sstream>

	#include <fst/random-weight.h>

	namespace fst {

	// This class tests a variety of identities and properties that must
	// hold for the Weight class to be well-defined. It calls function object
	// WEIGHT_GENERATOR to select weights that are used in the tests.
	template<class Weight, class WeightGenerator>
	class WeightTester {
	public:
	WeightTester(WeightGenerator generator) : weight_generator_(generator) {}

	void Test(int iterations, bool test_division = true) {
	for (int i = 0; i < iterations; ++i) {
	// Selects the test weights.
	Weight w1 = weight_generator_();
	Weight w2 = weight_generator_();
	Weight w3 = weight_generator_();

	VLOG(1) << "weight type = " << Weight::Type();
	VLOG(1) << "w1 = " << w1;
	VLOG(1) << "w2 = " << w2;
	VLOG(1) << "w3 = " << w3;

	TestSemiring(w1, w2, w3);
	if (test_division)
	TestDivision(w1, w2);
	TestReverse(w1, w2);
	TestEquality(w1, w2, w3);
	TestIO(w1);
	TestCopy(w1);
	}
	}

	private:
	// Note in the tests below we use ApproxEqual rather than == and add
	// kDelta to inequalities where the weights might be inexact.

	// Tests (Plus, Times, Zero, One) defines a commutative semiring.
	void TestSemiring(Weight w1, Weight w2, Weight w3) {
	// Checks that the operations are closed.
	CHECK(Plus(w1, w2).Member());
	CHECK(Times(w1, w2).Member());

	// Checks that the operations are associative.
	CHECK(ApproxEqual(Plus(w1, Plus(w2, w3)), Plus(Plus(w1, w2), w3)));
	CHECK(ApproxEqual(Times(w1, Times(w2, w3)), Times(Times(w1, w2), w3)));

	// Checks the identity elements.
	CHECK(Plus(w1, Weight::Zero()) == w1);
	CHECK(Plus(Weight::Zero(), w1) == w1);
	CHECK(Times(w1, Weight::One()) == w1);
	CHECK(Times(Weight::One(), w1) == w1);

	// Check the no weight element.
	CHECK(!Weight::NoWeight().Member());
	CHECK(!Plus(w1, Weight::NoWeight()).Member());
	CHECK(!Plus(Weight::NoWeight(), w1).Member());
	CHECK(!Times(w1, Weight::NoWeight()).Member());
	CHECK(!Times(Weight::NoWeight(), w1).Member());

	// Checks that the operations commute.
	CHECK(ApproxEqual(Plus(w1, w2), Plus(w2, w1)));
	if (Weight::Properties() & kCommutative)
	CHECK(ApproxEqual(Times(w1, w2), Times(w2, w1)));

	// Checks Zero() is the annihilator.
	CHECK(Times(w1, Weight::Zero()) == Weight::Zero());
	CHECK(Times(Weight::Zero(), w1) == Weight::Zero());

	// Check Power(w, 0) is Weight::One()
	CHECK(Power(w1, 0) == Weight::One());

	// Check Power(w, 1) is w
	CHECK(Power(w1, 1) == w1);

	// Check Power(w, 3) is Times(w, Times(w, w))
	CHECK(Power(w1, 3) == Times(w1, Times(w1, w1)));

	// Checks distributivity.
	if (Weight::Properties() & kLeftSemiring)
	CHECK(ApproxEqual(Times(w1, Plus(w2, w3)),
	Plus(Times(w1, w2), Times(w1, w3))));
	if (Weight::Properties() & kRightSemiring)
	CHECK(ApproxEqual(Times(Plus(w1, w2), w3),
	Plus(Times(w1, w3), Times(w2, w3))));

	if (Weight::Properties() & kIdempotent)
	CHECK(Plus(w1, w1) == w1);

	if (Weight::Properties() & kPath)
	CHECK(Plus(w1, w2) == w1 \|\| Plus(w1, w2) == w2);

	// Ensure weights form a left or right semiring.
	CHECK(Weight::Properties() & (kLeftSemiring \| kRightSemiring));

	// Check when Times() is commutative that it is marked as a semiring.
	if (Weight::Properties() & kCommutative)
	CHECK(Weight::Properties() & kSemiring);
	}

	// Tests division operation.
	void TestDivision(Weight w1, Weight w2) {
	Weight p = Times(w1, w2);

	if (Weight::Properties() & kLeftSemiring) {
	Weight d = Divide(p, w1, DIVIDE_LEFT);
	if (d.Member())
	CHECK(ApproxEqual(p, Times(w1, d)));
	CHECK(!Divide(w1, Weight::NoWeight(), DIVIDE_LEFT).Member());
	CHECK(!Divide(Weight::NoWeight(), w1, DIVIDE_LEFT).Member());
	}

	if (Weight::Properties() & kRightSemiring) {
	Weight d = Divide(p, w2, DIVIDE_RIGHT);
	if (d.Member())
	CHECK(ApproxEqual(p, Times(d, w2)));
	CHECK(!Divide(w1, Weight::NoWeight(), DIVIDE_RIGHT).Member());
	CHECK(!Divide(Weight::NoWeight(), w1, DIVIDE_RIGHT).Member());
	}

	if (Weight::Properties() & kCommutative) {
	Weight d = Divide(p, w1, DIVIDE_RIGHT);
	if (d.Member())
	CHECK(ApproxEqual(p, Times(d, w1)));
	}
	}

	// Tests reverse operation.
	void TestReverse(Weight w1, Weight w2) {
	typedef typename Weight::ReverseWeight ReverseWeight;

	ReverseWeight rw1 = w1.Reverse();
	ReverseWeight rw2 = w2.Reverse();

	CHECK(rw1.Reverse() == w1);
	CHECK(Plus(w1, w2).Reverse() == Plus(rw1, rw2));
	CHECK(Times(w1, w2).Reverse() == Times(rw2, rw1));
	}

	// Tests == is an equivalence relation.
	void TestEquality(Weight w1, Weight w2, Weight w3) {
	// Checks reflexivity.
	CHECK(w1 == w1);

	// Checks symmetry.
	CHECK((w1 == w2) == (w2 == w1));

	// Checks transitivity.
	if (w1 == w2 && w2 == w3)
	CHECK(w1 == w3);
	}

	// Tests binary serialization and textual I/O.
	void TestIO(Weight w) {
	// Tests binary I/O
	{
	ostringstream os;
	w.Write(os);
	os.flush();
	istringstream is(os.str());
	Weight v;
	v.Read(is);
	CHECK_EQ(w, v);
	}

	// Tests textual I/O.
	{
	ostringstream os;
	os << w;
	istringstream is(os.str());
	Weight v(Weight::One());
	is >> v;
	CHECK(ApproxEqual(w, v));
	}
	}

	// Tests copy constructor and assignment operator
	void TestCopy(Weight w) {
	Weight x = w;
	CHECK(w == x);

	x = Weight(w);
	CHECK(w == x);

	x.operator=(x);
	CHECK(w == x);

	}

	// Generates weights used in testing.
	WeightGenerator weight_generator_;

	DISALLOW_COPY_AND_ASSIGN(WeightTester);
	};

	} // namespace fst

	#endif // FST_TEST_WEIGHT_TESTER_H_