src/animator/SkDisplayMath.cpp - skia - Git at Google


 /*
  * Copyright 2006 The Android Open Source Project
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */


 #include "SkDisplayMath.h"

 enum SkDisplayMath_Properties {
     SK_PROPERTY(E),
     SK_PROPERTY(LN10),
     SK_PROPERTY(LN2),
     SK_PROPERTY(LOG10E),
     SK_PROPERTY(LOG2E),
     SK_PROPERTY(PI),
     SK_PROPERTY(SQRT1_2),
     SK_PROPERTY(SQRT2)
 };

 const SkScalar SkDisplayMath::gConstants[] = {
     2.718281828f,   // E
     2.302585093f,   // LN10
     0.693147181f,   // LN2
     0.434294482f,   // LOG10E
     1.442695041f,   // LOG2E
     3.141592654f,   // PI
     0.707106781f,   // SQRT1_2
     1.414213562f        // SQRT2
 };

 enum SkDisplayMath_Functions {
     SK_FUNCTION(abs),
     SK_FUNCTION(acos),
     SK_FUNCTION(asin),
     SK_FUNCTION(atan),
     SK_FUNCTION(atan2),
     SK_FUNCTION(ceil),
     SK_FUNCTION(cos),
     SK_FUNCTION(exp),
     SK_FUNCTION(floor),
     SK_FUNCTION(log),
     SK_FUNCTION(max),
     SK_FUNCTION(min),
     SK_FUNCTION(pow),
     SK_FUNCTION(random),
     SK_FUNCTION(round),
     SK_FUNCTION(sin),
     SK_FUNCTION(sqrt),
     SK_FUNCTION(tan)
 };

 const SkFunctionParamType SkDisplayMath::fFunctionParameters[] = {
     (SkFunctionParamType) SkType_Float, // abs
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // acos
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // asin
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // atan
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // atan2
     (SkFunctionParamType) SkType_Float,
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // ceil
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // cos
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // exp
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // floor
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // log
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Array, // max
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Array, // min
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // pow
     (SkFunctionParamType) SkType_Float,
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // random
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // round
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // sin
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // sqrt
     (SkFunctionParamType) 0,
     (SkFunctionParamType) SkType_Float, // tan
     (SkFunctionParamType) 0
 };

 #if SK_USE_CONDENSED_INFO == 0

 const SkMemberInfo SkDisplayMath::fInfo[] = {
     SK_MEMBER_PROPERTY(E, Float),
     SK_MEMBER_PROPERTY(LN10, Float),
     SK_MEMBER_PROPERTY(LN2, Float),
     SK_MEMBER_PROPERTY(LOG10E, Float),
     SK_MEMBER_PROPERTY(LOG2E, Float),
     SK_MEMBER_PROPERTY(PI, Float),
     SK_MEMBER_PROPERTY(SQRT1_2, Float),
     SK_MEMBER_PROPERTY(SQRT2, Float),
     SK_MEMBER_FUNCTION(abs, Float),
     SK_MEMBER_FUNCTION(acos, Float),
     SK_MEMBER_FUNCTION(asin, Float),
     SK_MEMBER_FUNCTION(atan, Float),
     SK_MEMBER_FUNCTION(atan2, Float),
     SK_MEMBER_FUNCTION(ceil, Float),
     SK_MEMBER_FUNCTION(cos, Float),
     SK_MEMBER_FUNCTION(exp, Float),
     SK_MEMBER_FUNCTION(floor, Float),
     SK_MEMBER_FUNCTION(log, Float),
     SK_MEMBER_FUNCTION(max, Float),
     SK_MEMBER_FUNCTION(min, Float),
     SK_MEMBER_FUNCTION(pow, Float),
     SK_MEMBER_FUNCTION(random, Float),
     SK_MEMBER_FUNCTION(round, Float),
     SK_MEMBER_FUNCTION(sin, Float),
     SK_MEMBER_FUNCTION(sqrt, Float),
     SK_MEMBER_FUNCTION(tan, Float)
 };

 #endif

 DEFINE_GET_MEMBER(SkDisplayMath);

 void SkDisplayMath::executeFunction(SkDisplayable* target, int index,
         SkTDArray<SkScriptValue>& parameters, SkDisplayTypes type,
         SkScriptValue* scriptValue) {
     if (scriptValue == NULL)
         return;
     SkASSERT(target == this);
     SkScriptValue* array = parameters.begin();
     SkScriptValue* end = parameters.end();
     SkScalar input = parameters[0].fOperand.fScalar;
     SkScalar scalarResult;
     switch (index) {
         case SK_FUNCTION(abs):
             scalarResult = SkScalarAbs(input);
             break;
         case SK_FUNCTION(acos):
             scalarResult = SkScalarACos(input);
             break;
         case SK_FUNCTION(asin):
             scalarResult = SkScalarASin(input);
             break;
         case SK_FUNCTION(atan):
             scalarResult = SkScalarATan2(input, SK_Scalar1);
             break;
         case SK_FUNCTION(atan2):
             scalarResult = SkScalarATan2(input, parameters[1].fOperand.fScalar);
             break;
         case SK_FUNCTION(ceil):
             scalarResult = SkScalarCeilToScalar(input);
             break;
         case SK_FUNCTION(cos):
             scalarResult = SkScalarCos(input);
             break;
         case SK_FUNCTION(exp):
             scalarResult = SkScalarExp(input);
             break;
         case SK_FUNCTION(floor):
             scalarResult = SkScalarFloorToScalar(input);
             break;
         case SK_FUNCTION(log):
             scalarResult = SkScalarLog(input);
             break;
         case SK_FUNCTION(max):
             scalarResult = -SK_ScalarMax;
             while (array < end) {
                 scalarResult = SkMaxScalar(scalarResult, array->fOperand.fScalar);
                 array++;
             }
             break;
         case SK_FUNCTION(min):
             scalarResult = SK_ScalarMax;
             while (array < end) {
                 scalarResult = SkMinScalar(scalarResult, array->fOperand.fScalar);
                 array++;
             }
             break;
         case SK_FUNCTION(pow):
             // not the greatest -- but use x^y = e^(y * ln(x))
             scalarResult = SkScalarLog(input);
             scalarResult = SkScalarMul(parameters[1].fOperand.fScalar, scalarResult);
             scalarResult = SkScalarExp(scalarResult);
             break;
         case SK_FUNCTION(random):
             scalarResult = fRandom.nextUScalar1();
             break;
         case SK_FUNCTION(round):
             scalarResult = SkScalarRoundToScalar(input);
             break;
         case SK_FUNCTION(sin):
             scalarResult = SkScalarSin(input);
             break;
         case SK_FUNCTION(sqrt): {
             SkASSERT(parameters.count() == 1);
             SkASSERT(type == SkType_Float);
             scalarResult = SkScalarSqrt(input);
             } break;
         case SK_FUNCTION(tan):
             scalarResult = SkScalarTan(input);
             break;
         default:
             SkASSERT(0);
             scalarResult = SK_ScalarNaN;
     }
     scriptValue->fOperand.fScalar = scalarResult;
     scriptValue->fType = SkType_Float;
 }

 const SkFunctionParamType* SkDisplayMath::getFunctionsParameters() {
     return fFunctionParameters;
 }

 bool SkDisplayMath::getProperty(int index, SkScriptValue* value) const {
     if ((unsigned)index < SK_ARRAY_COUNT(gConstants)) {
         value->fOperand.fScalar = gConstants[index];
         value->fType = SkType_Float;
         return true;
     }
     SkASSERT(0);
     return false;
 }

	/*
	* Copyright 2006 The Android Open Source Project
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/


	#include "SkDisplayMath.h"

	enum SkDisplayMath_Properties {
	SK_PROPERTY(E),
	SK_PROPERTY(LN10),
	SK_PROPERTY(LN2),
	SK_PROPERTY(LOG10E),
	SK_PROPERTY(LOG2E),
	SK_PROPERTY(PI),
	SK_PROPERTY(SQRT1_2),
	SK_PROPERTY(SQRT2)
	};

	const SkScalar SkDisplayMath::gConstants[] = {
	2.718281828f, // E
	2.302585093f, // LN10
	0.693147181f, // LN2
	0.434294482f, // LOG10E
	1.442695041f, // LOG2E
	3.141592654f, // PI
	0.707106781f, // SQRT1_2
	1.414213562f // SQRT2
	};

	enum SkDisplayMath_Functions {
	SK_FUNCTION(abs),
	SK_FUNCTION(acos),
	SK_FUNCTION(asin),
	SK_FUNCTION(atan),
	SK_FUNCTION(atan2),
	SK_FUNCTION(ceil),
	SK_FUNCTION(cos),
	SK_FUNCTION(exp),
	SK_FUNCTION(floor),
	SK_FUNCTION(log),
	SK_FUNCTION(max),
	SK_FUNCTION(min),
	SK_FUNCTION(pow),
	SK_FUNCTION(random),
	SK_FUNCTION(round),
	SK_FUNCTION(sin),
	SK_FUNCTION(sqrt),
	SK_FUNCTION(tan)
	};

	const SkFunctionParamType SkDisplayMath::fFunctionParameters[] = {
	(SkFunctionParamType) SkType_Float, // abs
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // acos
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // asin
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // atan
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // atan2
	(SkFunctionParamType) SkType_Float,
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // ceil
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // cos
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // exp
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // floor
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // log
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Array, // max
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Array, // min
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // pow
	(SkFunctionParamType) SkType_Float,
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // random
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // round
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // sin
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // sqrt
	(SkFunctionParamType) 0,
	(SkFunctionParamType) SkType_Float, // tan
	(SkFunctionParamType) 0
	};

	#if SK_USE_CONDENSED_INFO == 0

	const SkMemberInfo SkDisplayMath::fInfo[] = {
	SK_MEMBER_PROPERTY(E, Float),
	SK_MEMBER_PROPERTY(LN10, Float),
	SK_MEMBER_PROPERTY(LN2, Float),
	SK_MEMBER_PROPERTY(LOG10E, Float),
	SK_MEMBER_PROPERTY(LOG2E, Float),
	SK_MEMBER_PROPERTY(PI, Float),
	SK_MEMBER_PROPERTY(SQRT1_2, Float),
	SK_MEMBER_PROPERTY(SQRT2, Float),
	SK_MEMBER_FUNCTION(abs, Float),
	SK_MEMBER_FUNCTION(acos, Float),
	SK_MEMBER_FUNCTION(asin, Float),
	SK_MEMBER_FUNCTION(atan, Float),
	SK_MEMBER_FUNCTION(atan2, Float),
	SK_MEMBER_FUNCTION(ceil, Float),
	SK_MEMBER_FUNCTION(cos, Float),
	SK_MEMBER_FUNCTION(exp, Float),
	SK_MEMBER_FUNCTION(floor, Float),
	SK_MEMBER_FUNCTION(log, Float),
	SK_MEMBER_FUNCTION(max, Float),
	SK_MEMBER_FUNCTION(min, Float),
	SK_MEMBER_FUNCTION(pow, Float),
	SK_MEMBER_FUNCTION(random, Float),
	SK_MEMBER_FUNCTION(round, Float),
	SK_MEMBER_FUNCTION(sin, Float),
	SK_MEMBER_FUNCTION(sqrt, Float),
	SK_MEMBER_FUNCTION(tan, Float)
	};

	#endif

	DEFINE_GET_MEMBER(SkDisplayMath);

	void SkDisplayMath::executeFunction(SkDisplayable* target, int index,
	SkTDArray<SkScriptValue>& parameters, SkDisplayTypes type,
	SkScriptValue* scriptValue) {
	if (scriptValue == NULL)
	return;
	SkASSERT(target == this);
	SkScriptValue* array = parameters.begin();
	SkScriptValue* end = parameters.end();
	SkScalar input = parameters[0].fOperand.fScalar;
	SkScalar scalarResult;
	switch (index) {
	case SK_FUNCTION(abs):
	scalarResult = SkScalarAbs(input);
	break;
	case SK_FUNCTION(acos):
	scalarResult = SkScalarACos(input);
	break;
	case SK_FUNCTION(asin):
	scalarResult = SkScalarASin(input);
	break;
	case SK_FUNCTION(atan):
	scalarResult = SkScalarATan2(input, SK_Scalar1);
	break;
	case SK_FUNCTION(atan2):
	scalarResult = SkScalarATan2(input, parameters[1].fOperand.fScalar);
	break;
	case SK_FUNCTION(ceil):
	scalarResult = SkScalarCeilToScalar(input);
	break;
	case SK_FUNCTION(cos):
	scalarResult = SkScalarCos(input);
	break;
	case SK_FUNCTION(exp):
	scalarResult = SkScalarExp(input);
	break;
	case SK_FUNCTION(floor):
	scalarResult = SkScalarFloorToScalar(input);
	break;
	case SK_FUNCTION(log):
	scalarResult = SkScalarLog(input);
	break;
	case SK_FUNCTION(max):
	scalarResult = -SK_ScalarMax;
	while (array < end) {
	scalarResult = SkMaxScalar(scalarResult, array->fOperand.fScalar);
	array++;
	}
	break;
	case SK_FUNCTION(min):
	scalarResult = SK_ScalarMax;
	while (array < end) {
	scalarResult = SkMinScalar(scalarResult, array->fOperand.fScalar);
	array++;
	}
	break;
	case SK_FUNCTION(pow):
	// not the greatest -- but use x^y = e^(y * ln(x))
	scalarResult = SkScalarLog(input);
	scalarResult = SkScalarMul(parameters[1].fOperand.fScalar, scalarResult);
	scalarResult = SkScalarExp(scalarResult);
	break;
	case SK_FUNCTION(random):
	scalarResult = fRandom.nextUScalar1();
	break;
	case SK_FUNCTION(round):
	scalarResult = SkScalarRoundToScalar(input);
	break;
	case SK_FUNCTION(sin):
	scalarResult = SkScalarSin(input);
	break;
	case SK_FUNCTION(sqrt): {
	SkASSERT(parameters.count() == 1);
	SkASSERT(type == SkType_Float);
	scalarResult = SkScalarSqrt(input);
	} break;
	case SK_FUNCTION(tan):
	scalarResult = SkScalarTan(input);
	break;
	default:
	SkASSERT(0);
	scalarResult = SK_ScalarNaN;
	}
	scriptValue->fOperand.fScalar = scalarResult;
	scriptValue->fType = SkType_Float;
	}

	const SkFunctionParamType* SkDisplayMath::getFunctionsParameters() {
	return fFunctionParameters;
	}

	bool SkDisplayMath::getProperty(int index, SkScriptValue* value) const {
	if ((unsigned)index < SK_ARRAY_COUNT(gConstants)) {
	value->fOperand.fScalar = gConstants[index];
	value->fType = SkType_Float;
	return true;
	}
	SkASSERT(0);
	return false;
	}