runtime/lib/math_patch.dart - sdk.git - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 import "dart:typed_data";

 // A VM patch of the dart:math library.

 @patch
 T min<T extends num>(T a, T b) {
   // These partially redundant type checks improve code quality for dart2js.
   // Most of the improvement is at call sites from the inferred non-null num
   // return type.
   if (a is! num) throw new ArgumentError(a);
   if (b is! num) throw new ArgumentError(b);

   if (a > b) return b;
   if (a < b) return a;
   if (b is double) {
     // Special case for NaN and -0.0. If one argument is NaN return NaN.
     // [min] must also distinguish between -0.0 and 0.0.
     if (a is double) {
       if (a == 0.0) {
         // a is either 0.0 or -0.0. b is either 0.0, -0.0 or NaN.
         // The following returns -0.0 if either a or b is -0.0, and it
         // returns NaN if b is NaN.
         return (a + b) * a * b;
       }
     }
     // Check for NaN and b == -0.0.
     if (a == 0 && b.isNegative || b.isNaN) return b;
     return a;
   }
   return a;
 }

 @patch
 T max<T extends num>(T a, T b) {
   // These partially redundant type checks improve code quality for dart2js.
   // Most of the improvement is at call sites from the inferred non-null num
   // return type.
   if (a is! num) throw new ArgumentError(a);
   if (b is! num) throw new ArgumentError(b);

   if (a > b) return a;
   if (a < b) return b;
   if (b is double) {
     // Special case for NaN and -0.0. If one argument is NaN return NaN.
     // [max] must also distinguish between -0.0 and 0.0.
     if (a is double) {
       if (a == 0.0) {
         // a is either 0.0 or -0.0. b is either 0.0, -0.0, or NaN.
         // The following returns 0.0 if either a or b is 0.0, and it
         // returns NaN if b is NaN.
         return a + b;
       }
     }
     // Check for NaN.
     if (b.isNaN) return b;
     return a;
   }
   // max(-0.0, 0) must return 0.
   if (b == 0 && a.isNegative) return b;
   return a;
 }

 // If [x] is an [int] and [exponent] is a non-negative [int], the result is
 // an [int], otherwise the result is a [double].
 @patch
 num pow(num x, num exponent) {
   if ((x is int) && (exponent is int) && (exponent >= 0)) {
     return _intPow(x, exponent);
   }
   return _doublePow(x.toDouble(), exponent.toDouble());
 }

 double _doublePow(double base, double exponent) {
   if (exponent == 0.0) {
     return 1.0; // ECMA-262 15.8.2.13
   }
   // Speed up simple cases.
   if (exponent == 1.0) return base;
   if (exponent == 2.0) return base * base;
   if (exponent == 3.0) return base * base * base;

   if (base == 1.0) return 1.0;

   if (base.isNaN || exponent.isNaN) {
     return double.NAN;
   }
   if ((base != -double.INFINITY) && (exponent == 0.5)) {
     if (base == 0.0) {
       return 0.0;
     }
     return sqrt(base);
   }
   return _pow(base.toDouble(), exponent.toDouble());
 }

 double _pow(double base, double exponent) native "Math_doublePow";

 int _intPow(int base, int exponent) {
   // Exponentiation by squaring.
   int result = 1;
   while (exponent != 0) {
     if ((exponent & 1) == 1) {
       result *= base;
     }
     exponent >>= 1;
     // Skip unnecessary operation (can overflow to Mint or Bigint).
     if (exponent != 0) {
       base *= base;
     }
   }
   return result;
 }

 @patch
 double atan2(num a, num b) => _atan2(a.toDouble(), b.toDouble());
 @patch
 double sin(num radians) => _sin(radians.toDouble());
 @patch
 double cos(num radians) => _cos(radians.toDouble());
 @patch
 double tan(num radians) => _tan(radians.toDouble());
 @patch
 double acos(num x) => _acos(x.toDouble());
 @patch
 double asin(num x) => _asin(x.toDouble());
 @patch
 double atan(num x) => _atan(x.toDouble());
 @patch
 double sqrt(num x) => _sqrt(x.toDouble());
 @patch
 double exp(num x) => _exp(x.toDouble());
 @patch
 double log(num x) => _log(x.toDouble());

 double _atan2(double a, double b) native "Math_atan2";
 double _sin(double x) native "Math_sin";
 double _cos(double x) native "Math_cos";
 double _tan(double x) native "Math_tan";
 double _acos(double x) native "Math_acos";
 double _asin(double x) native "Math_asin";
 double _atan(double x) native "Math_atan";
 double _sqrt(double x) native "Math_sqrt";
 double _exp(double x) native "Math_exp";
 double _log(double x) native "Math_log";

 // TODO(iposva): Handle patch methods within a patch class correctly.
 @patch
 class Random {
   @patch
   factory Random([int seed]) {
     var state = _Random._setupSeed((seed == null) ? _Random._nextSeed() : seed);
     // Crank a couple of times to distribute the seed bits a bit further.
     return new _Random._withState(state)
       .._nextState()
       .._nextState()
       .._nextState()
       .._nextState();
   }

   @patch
   factory Random.secure() {
     return new _SecureRandom();
   }
 }

 class _Random implements Random {
   // Internal state of the random number generator.
   final Uint32List _state;
   static const _kSTATE_LO = 0;
   static const _kSTATE_HI = 1; // Unused in Dart code.

   _Random._withState(this._state);

   // The algorithm used here is Multiply with Carry (MWC) with a Base b = 2^32.
   // http://en.wikipedia.org/wiki/Multiply-with-carry
   // The constant A is selected from "Numerical Recipes 3rd Edition" p.348 B1.

   // Implements:
   //   var state =
   //       ((_A * (_state[_kSTATE_LO])) + _state[_kSTATE_HI]) & ((1 << 64) - 1);
   //   _state[_kSTATE_LO] = state & ((1 << 32) - 1);
   //   _state[_kSTATE_HI] = state >> 32;
   // This is a native to prevent 64-bit operations in Dart, which
   // fail with --throw_on_javascript_int_overflow.
   // TODO(regis): Implement in Dart and remove Random_nextState in math.cc.
   void _nextState() native "Random_nextState";

   int nextInt(int max) {
     const limit = 0x3FFFFFFF;
     if ((max <= 0) || ((max > limit) && (max > _POW2_32))) {
       throw new RangeError.range(
           max, 1, _POW2_32, "max", "Must be positive and <= 2^32");
     }
     if ((max & -max) == max) {
       // Fast case for powers of two.
       _nextState();
       return _state[_kSTATE_LO] & (max - 1);
     }

     var rnd32;
     var result;
     do {
       _nextState();
       rnd32 = _state[_kSTATE_LO];
       result = rnd32 % max;
     } while ((rnd32 - result + max) > _POW2_32);
     return result;
   }

   double nextDouble() {
     return ((nextInt(1 << 26) * _POW2_27_D) + nextInt(1 << 27)) / _POW2_53_D;
   }

   bool nextBool() {
     return nextInt(2) == 0;
   }

   // Constants used by the algorithm.
   static const _POW2_32 = 1 << 32;
   static const _POW2_53_D = 1.0 * (1 << 53);
   static const _POW2_27_D = 1.0 * (1 << 27);

   static const _A = 0xffffda61;

   // Use a singleton Random object to get a new seed if no seed was passed.
   static var _prng = new _Random._withState(_initialSeed());

   // This is a native to prevent 64-bit operations in Dart, which
   // fail with --throw_on_javascript_int_overflow.
   // TODO(regis): Implement here in Dart and remove native in math.cc.
   static Uint32List _setupSeed(int seed) native "Random_setupSeed";
   // Get a seed from the VM's random number provider.
   static Uint32List _initialSeed() native "Random_initialSeed";

   static int _nextSeed() {
     // Trigger the PRNG once to change the internal state.
     _prng._nextState();
     return _prng._state[_kSTATE_LO];
   }
 }

 class _SecureRandom implements Random {
   _SecureRandom() {
     // Throw early in constructor if entropy source is not hooked up.
     _getBytes(1);
   }

   // Return count bytes of entropy as a positive integer; count <= 8.
   static int _getBytes(int count) native "SecureRandom_getBytes";

   int nextInt(int max) {
     RangeError.checkValueInInterval(
         max, 1, _POW2_32, "max", "Must be positive and <= 2^32");
     final byteCount = ((max - 1).bitLength + 7) >> 3;
     if (byteCount == 0) {
       return 0; // Not random if max == 1.
     }
     var rnd;
     var result;
     do {
       rnd = _getBytes(byteCount);
       result = rnd % max;
     } while ((rnd - result + max) > (1 << (byteCount << 3)));
     return result;
   }

   double nextDouble() {
     return (_getBytes(7) >> 3) / _POW2_53_D;
   }

   bool nextBool() {
     return _getBytes(1).isEven;
   }

   // Constants used by the algorithm.
   static const _POW2_32 = 1 << 32;
   static const _POW2_53_D = 1.0 * (1 << 53);
 }
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	import "dart:typed_data";

	// A VM patch of the dart:math library.

	@patch
	T min<T extends num>(T a, T b) {
	// These partially redundant type checks improve code quality for dart2js.
	// Most of the improvement is at call sites from the inferred non-null num
	// return type.
	if (a is! num) throw new ArgumentError(a);
	if (b is! num) throw new ArgumentError(b);

	if (a > b) return b;
	if (a < b) return a;
	if (b is double) {
	// Special case for NaN and -0.0. If one argument is NaN return NaN.
	// [min] must also distinguish between -0.0 and 0.0.
	if (a is double) {
	if (a == 0.0) {
	// a is either 0.0 or -0.0. b is either 0.0, -0.0 or NaN.
	// The following returns -0.0 if either a or b is -0.0, and it
	// returns NaN if b is NaN.
	return (a + b) * a * b;
	}
	}
	// Check for NaN and b == -0.0.
	if (a == 0 && b.isNegative \|\| b.isNaN) return b;
	return a;
	}
	return a;
	}

	@patch
	T max<T extends num>(T a, T b) {
	// These partially redundant type checks improve code quality for dart2js.
	// Most of the improvement is at call sites from the inferred non-null num
	// return type.
	if (a is! num) throw new ArgumentError(a);
	if (b is! num) throw new ArgumentError(b);

	if (a > b) return a;
	if (a < b) return b;
	if (b is double) {
	// Special case for NaN and -0.0. If one argument is NaN return NaN.
	// [max] must also distinguish between -0.0 and 0.0.
	if (a is double) {
	if (a == 0.0) {
	// a is either 0.0 or -0.0. b is either 0.0, -0.0, or NaN.
	// The following returns 0.0 if either a or b is 0.0, and it
	// returns NaN if b is NaN.
	return a + b;
	}
	}
	// Check for NaN.
	if (b.isNaN) return b;
	return a;
	}
	// max(-0.0, 0) must return 0.
	if (b == 0 && a.isNegative) return b;
	return a;
	}

	// If [x] is an [int] and [exponent] is a non-negative [int], the result is
	// an [int], otherwise the result is a [double].
	@patch
	num pow(num x, num exponent) {
	if ((x is int) && (exponent is int) && (exponent >= 0)) {
	return _intPow(x, exponent);
	}
	return _doublePow(x.toDouble(), exponent.toDouble());
	}

	double _doublePow(double base, double exponent) {
	if (exponent == 0.0) {
	return 1.0; // ECMA-262 15.8.2.13
	}
	// Speed up simple cases.
	if (exponent == 1.0) return base;
	if (exponent == 2.0) return base * base;
	if (exponent == 3.0) return base * base * base;

	if (base == 1.0) return 1.0;

	if (base.isNaN \|\| exponent.isNaN) {
	return double.NAN;
	}
	if ((base != -double.INFINITY) && (exponent == 0.5)) {
	if (base == 0.0) {
	return 0.0;
	}
	return sqrt(base);
	}
	return _pow(base.toDouble(), exponent.toDouble());
	}

	double _pow(double base, double exponent) native "Math_doublePow";

	int _intPow(int base, int exponent) {
	// Exponentiation by squaring.
	int result = 1;
	while (exponent != 0) {
	if ((exponent & 1) == 1) {
	result *= base;
	}
	exponent >>= 1;
	// Skip unnecessary operation (can overflow to Mint or Bigint).
	if (exponent != 0) {
	base *= base;
	}
	}
	return result;
	}

	@patch
	double atan2(num a, num b) => _atan2(a.toDouble(), b.toDouble());
	@patch
	double sin(num radians) => _sin(radians.toDouble());
	@patch
	double cos(num radians) => _cos(radians.toDouble());
	@patch
	double tan(num radians) => _tan(radians.toDouble());
	@patch
	double acos(num x) => _acos(x.toDouble());
	@patch
	double asin(num x) => _asin(x.toDouble());
	@patch
	double atan(num x) => _atan(x.toDouble());
	@patch
	double sqrt(num x) => _sqrt(x.toDouble());
	@patch
	double exp(num x) => _exp(x.toDouble());
	@patch
	double log(num x) => _log(x.toDouble());

	double _atan2(double a, double b) native "Math_atan2";
	double _sin(double x) native "Math_sin";
	double _cos(double x) native "Math_cos";
	double _tan(double x) native "Math_tan";
	double _acos(double x) native "Math_acos";
	double _asin(double x) native "Math_asin";
	double _atan(double x) native "Math_atan";
	double _sqrt(double x) native "Math_sqrt";
	double _exp(double x) native "Math_exp";
	double _log(double x) native "Math_log";

	// TODO(iposva): Handle patch methods within a patch class correctly.
	@patch
	class Random {
	@patch
	factory Random([int seed]) {
	var state = _Random._setupSeed((seed == null) ? _Random._nextSeed() : seed);
	// Crank a couple of times to distribute the seed bits a bit further.
	return new _Random._withState(state)
	.._nextState()
	.._nextState()
	.._nextState()
	.._nextState();
	}

	@patch
	factory Random.secure() {
	return new _SecureRandom();
	}
	}

	class _Random implements Random {
	// Internal state of the random number generator.
	final Uint32List _state;
	static const _kSTATE_LO = 0;
	static const _kSTATE_HI = 1; // Unused in Dart code.

	_Random._withState(this._state);

	// The algorithm used here is Multiply with Carry (MWC) with a Base b = 2^32.
	// http://en.wikipedia.org/wiki/Multiply-with-carry
	// The constant A is selected from "Numerical Recipes 3rd Edition" p.348 B1.

	// Implements:
	// var state =
	// ((_A * (_state[_kSTATE_LO])) + _state[_kSTATE_HI]) & ((1 << 64) - 1);
	// _state[_kSTATE_LO] = state & ((1 << 32) - 1);
	// _state[_kSTATE_HI] = state >> 32;
	// This is a native to prevent 64-bit operations in Dart, which
	// fail with --throw_on_javascript_int_overflow.
	// TODO(regis): Implement in Dart and remove Random_nextState in math.cc.
	void _nextState() native "Random_nextState";

	int nextInt(int max) {
	const limit = 0x3FFFFFFF;
	if ((max <= 0) \|\| ((max > limit) && (max > _POW2_32))) {
	throw new RangeError.range(
	max, 1, _POW2_32, "max", "Must be positive and <= 2^32");
	}
	if ((max & -max) == max) {
	// Fast case for powers of two.
	_nextState();
	return _state[_kSTATE_LO] & (max - 1);
	}

	var rnd32;
	var result;
	do {
	_nextState();
	rnd32 = _state[_kSTATE_LO];
	result = rnd32 % max;
	} while ((rnd32 - result + max) > _POW2_32);
	return result;
	}

	double nextDouble() {
	return ((nextInt(1 << 26) * _POW2_27_D) + nextInt(1 << 27)) / _POW2_53_D;
	}

	bool nextBool() {
	return nextInt(2) == 0;
	}

	// Constants used by the algorithm.
	static const _POW2_32 = 1 << 32;
	static const _POW2_53_D = 1.0 * (1 << 53);
	static const _POW2_27_D = 1.0 * (1 << 27);

	static const _A = 0xffffda61;

	// Use a singleton Random object to get a new seed if no seed was passed.
	static var _prng = new _Random._withState(_initialSeed());

	// This is a native to prevent 64-bit operations in Dart, which
	// fail with --throw_on_javascript_int_overflow.
	// TODO(regis): Implement here in Dart and remove native in math.cc.
	static Uint32List _setupSeed(int seed) native "Random_setupSeed";
	// Get a seed from the VM's random number provider.
	static Uint32List _initialSeed() native "Random_initialSeed";

	static int _nextSeed() {
	// Trigger the PRNG once to change the internal state.
	_prng._nextState();
	return _prng._state[_kSTATE_LO];
	}
	}

	class _SecureRandom implements Random {
	_SecureRandom() {
	// Throw early in constructor if entropy source is not hooked up.
	_getBytes(1);
	}

	// Return count bytes of entropy as a positive integer; count <= 8.
	static int _getBytes(int count) native "SecureRandom_getBytes";

	int nextInt(int max) {
	RangeError.checkValueInInterval(
	max, 1, _POW2_32, "max", "Must be positive and <= 2^32");
	final byteCount = ((max - 1).bitLength + 7) >> 3;
	if (byteCount == 0) {
	return 0; // Not random if max == 1.
	}
	var rnd;
	var result;
	do {
	rnd = _getBytes(byteCount);
	result = rnd % max;
	} while ((rnd - result + max) > (1 << (byteCount << 3)));
	return result;
	}

	double nextDouble() {
	return (_getBytes(7) >> 3) / _POW2_53_D;
	}

	bool nextBool() {
	return _getBytes(1).isEven;
	}

	// Constants used by the algorithm.
	static const _POW2_32 = 1 << 32;
	static const _POW2_53_D = 1.0 * (1 << 53);
	}