test/unittests/runtime/runtime-interpreter-unittest.cc - v8/v8 - Git at Google

 // Copyright 2015 the V8 project 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 "src/v8.h"

 #include "src/factory.h"
 #include "src/heap/heap.h"
 #include "src/heap/heap-inl.h"
 #include "src/runtime/runtime.h"
 #include "test/unittests/test-utils.h"

 namespace v8 {
 namespace internal {
 namespace interpreter {

 class RuntimeInterpreterTest : public TestWithIsolateAndZone {
  public:
   typedef Object* (*RuntimeMethod)(int, Object**, Isolate*);

   RuntimeInterpreterTest() {}
   ~RuntimeInterpreterTest() override {}

   bool TestOperatorWithObjects(RuntimeMethod method, Handle<Object> lhs,
                                Handle<Object> rhs, bool expected);
   bool TestOperator(RuntimeMethod method, int32_t lhs, int32_t rhs,
                     bool expected);
   bool TestOperator(RuntimeMethod method, double lhs, double rhs,
                     bool expected);
   bool TestOperator(RuntimeMethod method, const char* lhs, const char* rhs,
                     bool expected);
 };


 bool RuntimeInterpreterTest::TestOperatorWithObjects(RuntimeMethod method,
                                                      Handle<Object> lhs,
                                                      Handle<Object> rhs,
                                                      bool expected) {
   Object* args_object[] = {*rhs, *lhs};
   Handle<Object> result =
       handle(method(2, &args_object[1], isolate()), isolate());
   CHECK(result->IsTrue() || result->IsFalse());
   return result->IsTrue() == expected;
 }


 bool RuntimeInterpreterTest::TestOperator(RuntimeMethod method, int32_t lhs,
                                           int32_t rhs, bool expected) {
   Handle<Object> x = isolate()->factory()->NewNumberFromInt(lhs);
   Handle<Object> y = isolate()->factory()->NewNumberFromInt(rhs);
   return TestOperatorWithObjects(method, x, y, expected);
 }


 bool RuntimeInterpreterTest::TestOperator(RuntimeMethod method, double lhs,
                                           double rhs, bool expected) {
   Handle<Object> x = isolate()->factory()->NewNumber(lhs);
   Handle<Object> y = isolate()->factory()->NewNumber(rhs);
   CHECK_EQ(HeapNumber::cast(*x)->value(), lhs);
   CHECK_EQ(HeapNumber::cast(*y)->value(), rhs);
   return TestOperatorWithObjects(method, x, y, expected);
 }


 bool RuntimeInterpreterTest::TestOperator(RuntimeMethod method, const char* lhs,
                                           const char* rhs, bool expected) {
   Handle<Object> x = isolate()->factory()->NewStringFromAsciiChecked(lhs);
   Handle<Object> y = isolate()->factory()->NewStringFromAsciiChecked(rhs);
   return TestOperatorWithObjects(method, x, y, expected);
 }


 TEST_F(RuntimeInterpreterTest, TestOperatorsWithIntegers) {
   int32_t inputs[] = {kMinInt, Smi::kMinValue, -17,    -1, 0, 1,
                       991,     Smi::kMaxValue, kMaxInt};
   TRACED_FOREACH(int, lhs, inputs) {
     TRACED_FOREACH(int, rhs, inputs) {
 #define INTEGER_OPERATOR_CHECK(r, op, x, y) \
   CHECK(TestOperator(Runtime_Interpreter##r, x, y, x op y))
       INTEGER_OPERATOR_CHECK(Equals, ==, lhs, rhs);
       INTEGER_OPERATOR_CHECK(NotEquals, !=, lhs, rhs);
       INTEGER_OPERATOR_CHECK(StrictEquals, ==, lhs, rhs);
       INTEGER_OPERATOR_CHECK(StrictNotEquals, !=, lhs, rhs);
       INTEGER_OPERATOR_CHECK(LessThan, <, lhs, rhs);
       INTEGER_OPERATOR_CHECK(GreaterThan, >, lhs, rhs);
       INTEGER_OPERATOR_CHECK(LessThanOrEqual, <=, lhs, rhs);
       INTEGER_OPERATOR_CHECK(GreaterThanOrEqual, >=, lhs, rhs);
 #undef INTEGER_OPERATOR_CHECK
     }
   }
 }


 TEST_F(RuntimeInterpreterTest, TestOperatorsWithDoubles) {
   double inputs[] = {std::numeric_limits<double>::min(),
                      std::numeric_limits<double>::max(),
                      -0.001,
                      0.01,
                      3.14,
                      -6.02214086e23};
   TRACED_FOREACH(double, lhs, inputs) {
     TRACED_FOREACH(double, rhs, inputs) {
 #define DOUBLE_OPERATOR_CHECK(r, op, x, y) \
   CHECK(TestOperator(Runtime_Interpreter##r, x, y, x op y))
       DOUBLE_OPERATOR_CHECK(Equals, ==, lhs, rhs);
       DOUBLE_OPERATOR_CHECK(NotEquals, !=, lhs, rhs);
       DOUBLE_OPERATOR_CHECK(StrictEquals, ==, lhs, rhs);
       DOUBLE_OPERATOR_CHECK(StrictNotEquals, !=, lhs, rhs);
       DOUBLE_OPERATOR_CHECK(LessThan, <, lhs, rhs);
       DOUBLE_OPERATOR_CHECK(GreaterThan, >, lhs, rhs);
       DOUBLE_OPERATOR_CHECK(LessThanOrEqual, <=, lhs, rhs);
       DOUBLE_OPERATOR_CHECK(GreaterThanOrEqual, >=, lhs, rhs);
 #undef DOUBLE_OPERATOR_CHECK
     }
   }
 }


 TEST_F(RuntimeInterpreterTest, TestOperatorsWithString) {
   const char* inputs[] = {"abc", "a", "def", "0"};
   TRACED_FOREACH(const char*, lhs, inputs) {
     TRACED_FOREACH(const char*, rhs, inputs) {
 #define STRING_OPERATOR_CHECK(r, op, x, y)         \
   CHECK(TestOperator(Runtime_Interpreter##r, x, y, \
                      std::string(x) op std::string(y)))
       STRING_OPERATOR_CHECK(Equals, ==, lhs, rhs);
       STRING_OPERATOR_CHECK(NotEquals, !=, lhs, rhs);
       STRING_OPERATOR_CHECK(StrictEquals, ==, lhs, rhs);
       STRING_OPERATOR_CHECK(StrictNotEquals, !=, lhs, rhs);
       STRING_OPERATOR_CHECK(LessThan, <, lhs, rhs);
       STRING_OPERATOR_CHECK(GreaterThan, >, lhs, rhs);
       STRING_OPERATOR_CHECK(LessThanOrEqual, <=, lhs, rhs);
       STRING_OPERATOR_CHECK(GreaterThanOrEqual, >=, lhs, rhs);
 #undef STRING_OPERATOR_CHECK
     }
   }
 }


 TEST_F(RuntimeInterpreterTest, ToBoolean) {
   double quiet_nan = std::numeric_limits<double>::quiet_NaN();
   std::pair<Handle<Object>, bool> cases[] = {
       std::make_pair(isolate()->factory()->NewNumberFromInt(0), false),
       std::make_pair(isolate()->factory()->NewNumberFromInt(1), true),
       std::make_pair(isolate()->factory()->NewNumberFromInt(100), true),
       std::make_pair(isolate()->factory()->NewNumberFromInt(-1), true),
       std::make_pair(isolate()->factory()->NewNumber(7.7), true),
       std::make_pair(isolate()->factory()->NewNumber(0.00001), true),
       std::make_pair(isolate()->factory()->NewNumber(quiet_nan), false),
       std::make_pair(isolate()->factory()->NewHeapNumber(0.0), false),
       std::make_pair(isolate()->factory()->undefined_value(), false),
       std::make_pair(isolate()->factory()->null_value(), false),
       std::make_pair(isolate()->factory()->true_value(), true),
       std::make_pair(isolate()->factory()->false_value(), false),
       std::make_pair(isolate()->factory()->NewStringFromStaticChars(""), false),
       std::make_pair(isolate()->factory()->NewStringFromStaticChars("_"), true),
   };

   for (size_t i = 0; i < arraysize(cases); i++) {
     auto& value_expected_tuple = cases[i];
     Object* args_object[] = {*value_expected_tuple.first};
     Handle<Object> result = handle(
         Runtime_InterpreterToBoolean(1, &args_object[0], isolate()), isolate());
     CHECK(result->IsBoolean());
     CHECK_EQ(result->IsTrue(), value_expected_tuple.second);
   }
 }


 }  // Namespace interpreter
 }  // namespace internal
 }  // namespace v8
	// Copyright 2015 the V8 project 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 "src/v8.h"

	#include "src/factory.h"
	#include "src/heap/heap.h"
	#include "src/heap/heap-inl.h"
	#include "src/runtime/runtime.h"
	#include "test/unittests/test-utils.h"

	namespace v8 {
	namespace internal {
	namespace interpreter {

	class RuntimeInterpreterTest : public TestWithIsolateAndZone {
	public:
	typedef Object* (RuntimeMethod)(int, Object, Isolate);

	RuntimeInterpreterTest() {}
	~RuntimeInterpreterTest() override {}

	bool TestOperatorWithObjects(RuntimeMethod method, Handle<Object> lhs,
	Handle<Object> rhs, bool expected);
	bool TestOperator(RuntimeMethod method, int32_t lhs, int32_t rhs,
	bool expected);
	bool TestOperator(RuntimeMethod method, double lhs, double rhs,
	bool expected);
	bool TestOperator(RuntimeMethod method, const char* lhs, const char* rhs,
	bool expected);
	};


	bool RuntimeInterpreterTest::TestOperatorWithObjects(RuntimeMethod method,
	Handle<Object> lhs,
	Handle<Object> rhs,
	bool expected) {
	Object* args_object[] = {rhs, lhs};
	Handle<Object> result =
	handle(method(2, &args_object[1], isolate()), isolate());
	CHECK(result->IsTrue() \|\| result->IsFalse());
	return result->IsTrue() == expected;
	}


	bool RuntimeInterpreterTest::TestOperator(RuntimeMethod method, int32_t lhs,
	int32_t rhs, bool expected) {
	Handle<Object> x = isolate()->factory()->NewNumberFromInt(lhs);
	Handle<Object> y = isolate()->factory()->NewNumberFromInt(rhs);
	return TestOperatorWithObjects(method, x, y, expected);
	}


	bool RuntimeInterpreterTest::TestOperator(RuntimeMethod method, double lhs,
	double rhs, bool expected) {
	Handle<Object> x = isolate()->factory()->NewNumber(lhs);
	Handle<Object> y = isolate()->factory()->NewNumber(rhs);
	CHECK_EQ(HeapNumber::cast(*x)->value(), lhs);
	CHECK_EQ(HeapNumber::cast(*y)->value(), rhs);
	return TestOperatorWithObjects(method, x, y, expected);
	}


	bool RuntimeInterpreterTest::TestOperator(RuntimeMethod method, const char* lhs,
	const char* rhs, bool expected) {
	Handle<Object> x = isolate()->factory()->NewStringFromAsciiChecked(lhs);
	Handle<Object> y = isolate()->factory()->NewStringFromAsciiChecked(rhs);
	return TestOperatorWithObjects(method, x, y, expected);
	}


	TEST_F(RuntimeInterpreterTest, TestOperatorsWithIntegers) {
	int32_t inputs[] = {kMinInt, Smi::kMinValue, -17, -1, 0, 1,
	991, Smi::kMaxValue, kMaxInt};
	TRACED_FOREACH(int, lhs, inputs) {
	TRACED_FOREACH(int, rhs, inputs) {
	#define INTEGER_OPERATOR_CHECK(r, op, x, y) \
	CHECK(TestOperator(Runtime_Interpreter##r, x, y, x op y))
	INTEGER_OPERATOR_CHECK(Equals, ==, lhs, rhs);
	INTEGER_OPERATOR_CHECK(NotEquals, !=, lhs, rhs);
	INTEGER_OPERATOR_CHECK(StrictEquals, ==, lhs, rhs);
	INTEGER_OPERATOR_CHECK(StrictNotEquals, !=, lhs, rhs);
	INTEGER_OPERATOR_CHECK(LessThan, <, lhs, rhs);
	INTEGER_OPERATOR_CHECK(GreaterThan, >, lhs, rhs);
	INTEGER_OPERATOR_CHECK(LessThanOrEqual, <=, lhs, rhs);
	INTEGER_OPERATOR_CHECK(GreaterThanOrEqual, >=, lhs, rhs);
	#undef INTEGER_OPERATOR_CHECK
	}
	}
	}


	TEST_F(RuntimeInterpreterTest, TestOperatorsWithDoubles) {
	double inputs[] = {std::numeric_limits<double>::min(),
	std::numeric_limits<double>::max(),
	-0.001,
	0.01,
	3.14,
	-6.02214086e23};
	TRACED_FOREACH(double, lhs, inputs) {
	TRACED_FOREACH(double, rhs, inputs) {
	#define DOUBLE_OPERATOR_CHECK(r, op, x, y) \
	CHECK(TestOperator(Runtime_Interpreter##r, x, y, x op y))
	DOUBLE_OPERATOR_CHECK(Equals, ==, lhs, rhs);
	DOUBLE_OPERATOR_CHECK(NotEquals, !=, lhs, rhs);
	DOUBLE_OPERATOR_CHECK(StrictEquals, ==, lhs, rhs);
	DOUBLE_OPERATOR_CHECK(StrictNotEquals, !=, lhs, rhs);
	DOUBLE_OPERATOR_CHECK(LessThan, <, lhs, rhs);
	DOUBLE_OPERATOR_CHECK(GreaterThan, >, lhs, rhs);
	DOUBLE_OPERATOR_CHECK(LessThanOrEqual, <=, lhs, rhs);
	DOUBLE_OPERATOR_CHECK(GreaterThanOrEqual, >=, lhs, rhs);
	#undef DOUBLE_OPERATOR_CHECK
	}
	}
	}


	TEST_F(RuntimeInterpreterTest, TestOperatorsWithString) {
	const char* inputs[] = {"abc", "a", "def", "0"};
	TRACED_FOREACH(const char*, lhs, inputs) {
	TRACED_FOREACH(const char*, rhs, inputs) {
	#define STRING_OPERATOR_CHECK(r, op, x, y) \
	CHECK(TestOperator(Runtime_Interpreter##r, x, y, \
	std::string(x) op std::string(y)))
	STRING_OPERATOR_CHECK(Equals, ==, lhs, rhs);
	STRING_OPERATOR_CHECK(NotEquals, !=, lhs, rhs);
	STRING_OPERATOR_CHECK(StrictEquals, ==, lhs, rhs);
	STRING_OPERATOR_CHECK(StrictNotEquals, !=, lhs, rhs);
	STRING_OPERATOR_CHECK(LessThan, <, lhs, rhs);
	STRING_OPERATOR_CHECK(GreaterThan, >, lhs, rhs);
	STRING_OPERATOR_CHECK(LessThanOrEqual, <=, lhs, rhs);
	STRING_OPERATOR_CHECK(GreaterThanOrEqual, >=, lhs, rhs);
	#undef STRING_OPERATOR_CHECK
	}
	}
	}


	TEST_F(RuntimeInterpreterTest, ToBoolean) {
	double quiet_nan = std::numeric_limits<double>::quiet_NaN();
	std::pair<Handle<Object>, bool> cases[] = {
	std::make_pair(isolate()->factory()->NewNumberFromInt(0), false),
	std::make_pair(isolate()->factory()->NewNumberFromInt(1), true),
	std::make_pair(isolate()->factory()->NewNumberFromInt(100), true),
	std::make_pair(isolate()->factory()->NewNumberFromInt(-1), true),
	std::make_pair(isolate()->factory()->NewNumber(7.7), true),
	std::make_pair(isolate()->factory()->NewNumber(0.00001), true),
	std::make_pair(isolate()->factory()->NewNumber(quiet_nan), false),
	std::make_pair(isolate()->factory()->NewHeapNumber(0.0), false),
	std::make_pair(isolate()->factory()->undefined_value(), false),
	std::make_pair(isolate()->factory()->null_value(), false),
	std::make_pair(isolate()->factory()->true_value(), true),
	std::make_pair(isolate()->factory()->false_value(), false),
	std::make_pair(isolate()->factory()->NewStringFromStaticChars(""), false),
	std::make_pair(isolate()->factory()->NewStringFromStaticChars("_"), true),
	};

	for (size_t i = 0; i < arraysize(cases); i++) {
	auto& value_expected_tuple = cases[i];
	Object* args_object[] = {*value_expected_tuple.first};
	Handle<Object> result = handle(
	Runtime_InterpreterToBoolean(1, &args_object[0], isolate()), isolate());
	CHECK(result->IsBoolean());
	CHECK_EQ(result->IsTrue(), value_expected_tuple.second);
	}
	}


	} // Namespace interpreter
	} // namespace internal
	} // namespace v8