src/runtime/runtime-maths.cc - platform/external/v8 - Git at Google

 // Copyright 2014 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/arguments.h"
 #include "src/assembler.h"
 #include "src/codegen.h"
 #include "src/runtime/runtime-utils.h"
 #include "src/third_party/fdlibm/fdlibm.h"


 namespace v8 {
 namespace internal {

 #define RUNTIME_UNARY_MATH(Name, name)                       \
   RUNTIME_FUNCTION(Runtime_Math##Name) {                     \
     HandleScope scope(isolate);                              \
     DCHECK(args.length() == 1);                              \
     isolate->counters()->math_##name()->Increment();         \
     CONVERT_DOUBLE_ARG_CHECKED(x, 0);                        \
     return *isolate->factory()->NewHeapNumber(std::name(x)); \
   }

 RUNTIME_UNARY_MATH(Acos, acos)
 RUNTIME_UNARY_MATH(Asin, asin)
 RUNTIME_UNARY_MATH(Atan, atan)
 RUNTIME_UNARY_MATH(LogRT, log)
 #undef RUNTIME_UNARY_MATH


 RUNTIME_FUNCTION(Runtime_DoubleHi) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 1);
   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   uint64_t integer = double_to_uint64(x);
   integer = (integer >> 32) & 0xFFFFFFFFu;
   return *isolate->factory()->NewNumber(static_cast<int32_t>(integer));
 }


 RUNTIME_FUNCTION(Runtime_DoubleLo) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 1);
   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   return *isolate->factory()->NewNumber(
       static_cast<int32_t>(double_to_uint64(x) & 0xFFFFFFFFu));
 }


 RUNTIME_FUNCTION(Runtime_ConstructDouble) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 2);
   CONVERT_NUMBER_CHECKED(uint32_t, hi, Uint32, args[0]);
   CONVERT_NUMBER_CHECKED(uint32_t, lo, Uint32, args[1]);
   uint64_t result = (static_cast<uint64_t>(hi) << 32) | lo;
   return *isolate->factory()->NewNumber(uint64_to_double(result));
 }


 RUNTIME_FUNCTION(Runtime_RemPiO2) {
   HandleScope handle_scope(isolate);
   DCHECK(args.length() == 1);
   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   Factory* factory = isolate->factory();
   double y[2] = {0.0, 0.0};
   int n = fdlibm::rempio2(x, y);
   Handle<FixedArray> array = factory->NewFixedArray(3);
   Handle<HeapNumber> y0 = factory->NewHeapNumber(y[0]);
   Handle<HeapNumber> y1 = factory->NewHeapNumber(y[1]);
   array->set(0, Smi::FromInt(n));
   array->set(1, *y0);
   array->set(2, *y1);
   return *factory->NewJSArrayWithElements(array);
 }


 static const double kPiDividedBy4 = 0.78539816339744830962;


 RUNTIME_FUNCTION(Runtime_MathAtan2) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 2);
   isolate->counters()->math_atan2()->Increment();

   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   CONVERT_DOUBLE_ARG_CHECKED(y, 1);
   double result;
   if (std::isinf(x) && std::isinf(y)) {
     // Make sure that the result in case of two infinite arguments
     // is a multiple of Pi / 4. The sign of the result is determined
     // by the first argument (x) and the sign of the second argument
     // determines the multiplier: one or three.
     int multiplier = (x < 0) ? -1 : 1;
     if (y < 0) multiplier *= 3;
     result = multiplier * kPiDividedBy4;
   } else {
     result = std::atan2(x, y);
   }
   return *isolate->factory()->NewNumber(result);
 }


 RUNTIME_FUNCTION(Runtime_MathExpRT) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 1);
   isolate->counters()->math_exp()->Increment();

   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   lazily_initialize_fast_exp();
   return *isolate->factory()->NewNumber(fast_exp(x));
 }


 RUNTIME_FUNCTION(Runtime_MathFloorRT) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 1);
   isolate->counters()->math_floor()->Increment();

   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   return *isolate->factory()->NewNumber(Floor(x));
 }


 // Slow version of Math.pow.  We check for fast paths for special cases.
 // Used if VFP3 is not available.
 RUNTIME_FUNCTION(Runtime_MathPowSlow) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 2);
   isolate->counters()->math_pow()->Increment();

   CONVERT_DOUBLE_ARG_CHECKED(x, 0);

   // If the second argument is a smi, it is much faster to call the
   // custom powi() function than the generic pow().
   if (args[1]->IsSmi()) {
     int y = args.smi_at(1);
     return *isolate->factory()->NewNumber(power_double_int(x, y));
   }

   CONVERT_DOUBLE_ARG_CHECKED(y, 1);
   double result = power_helper(x, y);
   if (std::isnan(result)) return isolate->heap()->nan_value();
   return *isolate->factory()->NewNumber(result);
 }


 // Fast version of Math.pow if we know that y is not an integer and y is not
 // -0.5 or 0.5.  Used as slow case from full codegen.
 RUNTIME_FUNCTION(Runtime_MathPowRT) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 2);
   isolate->counters()->math_pow()->Increment();

   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   CONVERT_DOUBLE_ARG_CHECKED(y, 1);
   if (y == 0) {
     return Smi::FromInt(1);
   } else {
     double result = power_double_double(x, y);
     if (std::isnan(result)) return isolate->heap()->nan_value();
     return *isolate->factory()->NewNumber(result);
   }
 }


 RUNTIME_FUNCTION(Runtime_RoundNumber) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 1);
   CONVERT_NUMBER_ARG_HANDLE_CHECKED(input, 0);
   isolate->counters()->math_round()->Increment();

   if (!input->IsHeapNumber()) {
     DCHECK(input->IsSmi());
     return *input;
   }

   Handle<HeapNumber> number = Handle<HeapNumber>::cast(input);

   double value = number->value();
   int exponent = number->get_exponent();
   int sign = number->get_sign();

   if (exponent < -1) {
     // Number in range ]-0.5..0.5[. These always round to +/-zero.
     if (sign) return isolate->heap()->minus_zero_value();
     return Smi::FromInt(0);
   }

   // We compare with kSmiValueSize - 2 because (2^30 - 0.1) has exponent 29 and
   // should be rounded to 2^30, which is not smi (for 31-bit smis, similar
   // argument holds for 32-bit smis).
   if (!sign && exponent < kSmiValueSize - 2) {
     return Smi::FromInt(static_cast<int>(value + 0.5));
   }

   // If the magnitude is big enough, there's no place for fraction part. If we
   // try to add 0.5 to this number, 1.0 will be added instead.
   if (exponent >= 52) {
     return *number;
   }

   if (sign && value >= -0.5) return isolate->heap()->minus_zero_value();

   // Do not call NumberFromDouble() to avoid extra checks.
   return *isolate->factory()->NewNumber(Floor(value + 0.5));
 }


 RUNTIME_FUNCTION(Runtime_MathSqrtRT) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 1);
   isolate->counters()->math_sqrt()->Increment();

   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   return *isolate->factory()->NewNumber(fast_sqrt(x));
 }


 RUNTIME_FUNCTION(Runtime_MathFround) {
   HandleScope scope(isolate);
   DCHECK(args.length() == 1);

   CONVERT_DOUBLE_ARG_CHECKED(x, 0);
   float xf = DoubleToFloat32(x);
   return *isolate->factory()->NewNumber(xf);
 }


 RUNTIME_FUNCTION(RuntimeReference_MathPow) {
   SealHandleScope shs(isolate);
   return __RT_impl_Runtime_MathPowSlow(args, isolate);
 }


 RUNTIME_FUNCTION(RuntimeReference_IsMinusZero) {
   SealHandleScope shs(isolate);
   DCHECK(args.length() == 1);
   CONVERT_ARG_CHECKED(Object, obj, 0);
   if (!obj->IsHeapNumber()) return isolate->heap()->false_value();
   HeapNumber* number = HeapNumber::cast(obj);
   return isolate->heap()->ToBoolean(IsMinusZero(number->value()));
 }
 }
 }  // namespace v8::internal
	// Copyright 2014 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/arguments.h"
	#include "src/assembler.h"
	#include "src/codegen.h"
	#include "src/runtime/runtime-utils.h"
	#include "src/third_party/fdlibm/fdlibm.h"


	namespace v8 {
	namespace internal {

	#define RUNTIME_UNARY_MATH(Name, name) \
	RUNTIME_FUNCTION(Runtime_Math##Name) { \
	HandleScope scope(isolate); \
	DCHECK(args.length() == 1); \
	isolate->counters()->math_##name()->Increment(); \
	CONVERT_DOUBLE_ARG_CHECKED(x, 0); \
	return *isolate->factory()->NewHeapNumber(std::name(x)); \
	}

	RUNTIME_UNARY_MATH(Acos, acos)
	RUNTIME_UNARY_MATH(Asin, asin)
	RUNTIME_UNARY_MATH(Atan, atan)
	RUNTIME_UNARY_MATH(LogRT, log)
	#undef RUNTIME_UNARY_MATH


	RUNTIME_FUNCTION(Runtime_DoubleHi) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 1);
	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	uint64_t integer = double_to_uint64(x);
	integer = (integer >> 32) & 0xFFFFFFFFu;
	return *isolate->factory()->NewNumber(static_cast<int32_t>(integer));
	}


	RUNTIME_FUNCTION(Runtime_DoubleLo) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 1);
	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	return *isolate->factory()->NewNumber(
	static_cast<int32_t>(double_to_uint64(x) & 0xFFFFFFFFu));
	}


	RUNTIME_FUNCTION(Runtime_ConstructDouble) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 2);
	CONVERT_NUMBER_CHECKED(uint32_t, hi, Uint32, args[0]);
	CONVERT_NUMBER_CHECKED(uint32_t, lo, Uint32, args[1]);
	uint64_t result = (static_cast<uint64_t>(hi) << 32) \| lo;
	return *isolate->factory()->NewNumber(uint64_to_double(result));
	}


	RUNTIME_FUNCTION(Runtime_RemPiO2) {
	HandleScope handle_scope(isolate);
	DCHECK(args.length() == 1);
	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	Factory* factory = isolate->factory();
	double y[2] = {0.0, 0.0};
	int n = fdlibm::rempio2(x, y);
	Handle<FixedArray> array = factory->NewFixedArray(3);
	Handle<HeapNumber> y0 = factory->NewHeapNumber(y[0]);
	Handle<HeapNumber> y1 = factory->NewHeapNumber(y[1]);
	array->set(0, Smi::FromInt(n));
	array->set(1, *y0);
	array->set(2, *y1);
	return *factory->NewJSArrayWithElements(array);
	}


	static const double kPiDividedBy4 = 0.78539816339744830962;


	RUNTIME_FUNCTION(Runtime_MathAtan2) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 2);
	isolate->counters()->math_atan2()->Increment();

	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	CONVERT_DOUBLE_ARG_CHECKED(y, 1);
	double result;
	if (std::isinf(x) && std::isinf(y)) {
	// Make sure that the result in case of two infinite arguments
	// is a multiple of Pi / 4. The sign of the result is determined
	// by the first argument (x) and the sign of the second argument
	// determines the multiplier: one or three.
	int multiplier = (x < 0) ? -1 : 1;
	if (y < 0) multiplier *= 3;
	result = multiplier * kPiDividedBy4;
	} else {
	result = std::atan2(x, y);
	}
	return *isolate->factory()->NewNumber(result);
	}


	RUNTIME_FUNCTION(Runtime_MathExpRT) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 1);
	isolate->counters()->math_exp()->Increment();

	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	lazily_initialize_fast_exp();
	return *isolate->factory()->NewNumber(fast_exp(x));
	}


	RUNTIME_FUNCTION(Runtime_MathFloorRT) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 1);
	isolate->counters()->math_floor()->Increment();

	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	return *isolate->factory()->NewNumber(Floor(x));
	}


	// Slow version of Math.pow. We check for fast paths for special cases.
	// Used if VFP3 is not available.
	RUNTIME_FUNCTION(Runtime_MathPowSlow) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 2);
	isolate->counters()->math_pow()->Increment();

	CONVERT_DOUBLE_ARG_CHECKED(x, 0);

	// If the second argument is a smi, it is much faster to call the
	// custom powi() function than the generic pow().
	if (args[1]->IsSmi()) {
	int y = args.smi_at(1);
	return *isolate->factory()->NewNumber(power_double_int(x, y));
	}

	CONVERT_DOUBLE_ARG_CHECKED(y, 1);
	double result = power_helper(x, y);
	if (std::isnan(result)) return isolate->heap()->nan_value();
	return *isolate->factory()->NewNumber(result);
	}


	// Fast version of Math.pow if we know that y is not an integer and y is not
	// -0.5 or 0.5. Used as slow case from full codegen.
	RUNTIME_FUNCTION(Runtime_MathPowRT) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 2);
	isolate->counters()->math_pow()->Increment();

	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	CONVERT_DOUBLE_ARG_CHECKED(y, 1);
	if (y == 0) {
	return Smi::FromInt(1);
	} else {
	double result = power_double_double(x, y);
	if (std::isnan(result)) return isolate->heap()->nan_value();
	return *isolate->factory()->NewNumber(result);
	}
	}


	RUNTIME_FUNCTION(Runtime_RoundNumber) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 1);
	CONVERT_NUMBER_ARG_HANDLE_CHECKED(input, 0);
	isolate->counters()->math_round()->Increment();

	if (!input->IsHeapNumber()) {
	DCHECK(input->IsSmi());
	return *input;
	}

	Handle<HeapNumber> number = Handle<HeapNumber>::cast(input);

	double value = number->value();
	int exponent = number->get_exponent();
	int sign = number->get_sign();

	if (exponent < -1) {
	// Number in range ]-0.5..0.5[. These always round to +/-zero.
	if (sign) return isolate->heap()->minus_zero_value();
	return Smi::FromInt(0);
	}

	// We compare with kSmiValueSize - 2 because (2^30 - 0.1) has exponent 29 and
	// should be rounded to 2^30, which is not smi (for 31-bit smis, similar
	// argument holds for 32-bit smis).
	if (!sign && exponent < kSmiValueSize - 2) {
	return Smi::FromInt(static_cast<int>(value + 0.5));
	}

	// If the magnitude is big enough, there's no place for fraction part. If we
	// try to add 0.5 to this number, 1.0 will be added instead.
	if (exponent >= 52) {
	return *number;
	}

	if (sign && value >= -0.5) return isolate->heap()->minus_zero_value();

	// Do not call NumberFromDouble() to avoid extra checks.
	return *isolate->factory()->NewNumber(Floor(value + 0.5));
	}


	RUNTIME_FUNCTION(Runtime_MathSqrtRT) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 1);
	isolate->counters()->math_sqrt()->Increment();

	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	return *isolate->factory()->NewNumber(fast_sqrt(x));
	}


	RUNTIME_FUNCTION(Runtime_MathFround) {
	HandleScope scope(isolate);
	DCHECK(args.length() == 1);

	CONVERT_DOUBLE_ARG_CHECKED(x, 0);
	float xf = DoubleToFloat32(x);
	return *isolate->factory()->NewNumber(xf);
	}


	RUNTIME_FUNCTION(RuntimeReference_MathPow) {
	SealHandleScope shs(isolate);
	return __RT_impl_Runtime_MathPowSlow(args, isolate);
	}


	RUNTIME_FUNCTION(RuntimeReference_IsMinusZero) {
	SealHandleScope shs(isolate);
	DCHECK(args.length() == 1);
	CONVERT_ARG_CHECKED(Object, obj, 0);
	if (!obj->IsHeapNumber()) return isolate->heap()->false_value();
	HeapNumber* number = HeapNumber::cast(obj);
	return isolate->heap()->ToBoolean(IsMinusZero(number->value()));
	}
	}
	} // namespace v8::internal