/**************************************************************************** ** ** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies). ** All rights reserved. ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the QtCore module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the Technology Preview License Agreement accompanying ** this package. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** ** ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #ifndef QMATH_H #define QMATH_H #include #include #ifdef Q_OS_SYMBIAN # include #endif QT_BEGIN_HEADER QT_BEGIN_NAMESPACE QT_MODULE(Core) #define QT_SINE_TABLE_SIZE 256 extern Q_CORE_EXPORT const qreal qt_sine_table[QT_SINE_TABLE_SIZE]; inline int qCeil(qreal v) { #ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return int(ceilf(float(v))); else #endif return int(ceil(v)); } inline int qFloor(qreal v) { #ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return int(floorf(float(v))); else #endif return int(floor(v)); } inline qreal qFabs(qreal v) { #ifdef QT_USE_MATH_H_FLOATS if(sizeof(qreal) == sizeof(float)) return fabsf(float(v)); else #endif return fabs(v); } inline qreal qSin(qreal v) { #ifdef Q_OS_SYMBIAN TReal sin_v; Math::Sin(sin_v, static_cast(v)); return static_cast(sin_v); #else # ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return sinf(float(v)); else # endif return sin(v); #endif } inline qreal qCos(qreal v) { #ifdef Q_OS_SYMBIAN TReal cos_v; Math::Cos(cos_v, static_cast(v)); return static_cast(cos_v); #else # ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return cosf(float(v)); else # endif return cos(v); #endif } inline qreal qTan(qreal v) { #ifdef Q_OS_SYMBIAN TReal tan_v; Math::Tan(tan_v, static_cast(v)); return static_cast(tan_v); #else # ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return tanf(float(v)); else # endif return tan(v); #endif } inline qreal qAcos(qreal v) { #ifdef Q_OS_SYMBIAN TReal acos_v; Math::ACos(acos_v, static_cast(v)); return static_cast(acos_v); #else # ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return acosf(float(v)); else # endif return acos(v); #endif } inline qreal qAsin(qreal v) { #ifdef Q_OS_SYMBIAN TReal asin_v; Math::ASin(asin_v, static_cast(v)); return static_cast(asin_v); #else # ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return asinf(float(v)); else # endif return asin(v); #endif } inline qreal qAtan(qreal v) { #ifdef Q_OS_SYMBIAN TReal atan_v; Math::ATan(atan_v, static_cast(v)); return static_cast(atan_v); #else # ifdef QT_USE_MATH_H_FLOATS if(sizeof(qreal) == sizeof(float)) return atanf(float(v)); else # endif return atan(v); #endif } inline qreal qAtan2(qreal x, qreal y) { #ifdef Q_OS_SYMBIAN TReal atan2_v; Math::ATan(atan2_v, static_cast(x), static_cast(y)); return static_cast(atan2_v); #else # ifdef QT_USE_MATH_H_FLOATS if(sizeof(qreal) == sizeof(float)) return atan2f(float(x), float(y)); else # endif return atan2(x, y); #endif } inline qreal qSqrt(qreal v) { #ifdef Q_OS_SYMBIAN TReal sqrt_v; Math::Sqrt(sqrt_v, static_cast(v)); return static_cast(sqrt_v); #else # ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return sqrtf(float(v)); else # endif return sqrt(v); #endif } inline qreal qLn(qreal v) { #ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return logf(float(v)); else #endif return log(v); } inline qreal qExp(qreal v) { #ifdef Q_OS_SYMBIAN TReal exp_v; Math::Exp(exp_v, static_cast(v)); return static_cast(exp_v); #else // only one signature // exists, exp(double) return exp(v); #endif } inline qreal qPow(qreal x, qreal y) { #ifdef Q_OS_SYMBIAN TReal pow_v; Math::Pow(pow_v, static_cast(x), static_cast(y)); return static_cast(pow_v); #else # ifdef QT_USE_MATH_H_FLOATS if (sizeof(qreal) == sizeof(float)) return powf(float(x), float(y)); else # endif return pow(x, y); #endif } #ifndef M_PI #define M_PI (3.14159265358979323846) #endif inline qreal qFastSin(qreal x) { int si = int(x * (0.5 * QT_SINE_TABLE_SIZE / M_PI)); // Would be more accurate with qRound, but slower. qreal d = x - si * (2.0 * M_PI / QT_SINE_TABLE_SIZE); int ci = si + QT_SINE_TABLE_SIZE / 4; si &= QT_SINE_TABLE_SIZE - 1; ci &= QT_SINE_TABLE_SIZE - 1; return qt_sine_table[si] + (qt_sine_table[ci] - 0.5 * qt_sine_table[si] * d) * d; } inline qreal qFastCos(qreal x) { int ci = int(x * (0.5 * QT_SINE_TABLE_SIZE / M_PI)); // Would be more accurate with qRound, but slower. qreal d = x - ci * (2.0 * M_PI / QT_SINE_TABLE_SIZE); int si = ci + QT_SINE_TABLE_SIZE / 4; si &= QT_SINE_TABLE_SIZE - 1; ci &= QT_SINE_TABLE_SIZE - 1; return qt_sine_table[si] - (qt_sine_table[ci] + 0.5 * qt_sine_table[si] * d) * d; } QT_END_NAMESPACE QT_END_HEADER #endif // QMATH_H