#ifndef Magnum_Math_Vector2_h #define Magnum_Math_Vector2_h /* This file is part of Magnum. Copyright © 2010, 2011, 2012, 2013, 2014, 2015, 2016, 2017, 2018 Vladimír Vondruš Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /** @file * @brief Class @ref Magnum::Math::Vector2 */ #include "Magnum/Math/Vector.h" namespace Magnum { namespace Math { /** @brief 2D cross product 2D version of cross product, also called perp-dot product, equivalent to calling @ref cross(const Vector3&, const Vector3&) with Z coordinate set to `0` and extracting only Z coordinate from the result (X and Y coordinates are always zero). Returns `0` either when one of the vectors is zero or they are parallel or antiparallel and `1` when two *normalized* vectors are perpendicular. @f[ \boldsymbol a \times \boldsymbol b = \boldsymbol a_\bot \cdot \boldsymbol b = a_xb_y - a_yb_x @f] @see @ref Vector2::perpendicular(), @ref dot(const Vector&, const Vector&) */ template inline T cross(const Vector2& a, const Vector2& b) { return dot(a.perpendicular(), b); } /** @brief Two-component vector @tparam T Data type See @ref matrix-vector for brief introduction. @see @ref Magnum::Vector2, @ref Magnum::Vector2i, @ref Magnum::Vector2ui, @ref Magnum::Vector2d @configurationvalueref{Magnum::Math::Vector2} */ template class Vector2: public Vector<2, T> { public: /** * @brief Vector in direction of X axis (right) * * Usable for translation in given axis, for example: * * @code{.cpp} * Matrix3::translation(Vector2::xAxis(5.0f)); // same as Matrix3::translation({5.0f, 0.0f}); * @endcode * * @see @ref yAxis(), @ref xScale(), @ref Matrix3::right() */ constexpr static Vector2 xAxis(T length = T(1)) { return {length, T(0)}; } /** * @brief Vector in direction of Y axis (up) * * See @ref xAxis() for more information. * @see @ref yScale(), @ref Matrix3::up() */ constexpr static Vector2 yAxis(T length = T(1)) { return {T(0), length}; } /** * @brief Scaling vector in direction of X axis (width) * * Usable for scaling along given direction, for example: * * @code{.cpp} * Matrix3::scaling(Vector2::xScale(-2.0f)); // same as Matrix3::scaling({-2.0f, 1.0f}); * @endcode * * @see @ref yScale(), @ref xAxis() */ constexpr static Vector2 xScale(T scale) { return {scale, T(1)}; } /** * @brief Scaling vector in direction of Y axis (height) * * See @ref xScale() for more information. * @see @ref yAxis() */ constexpr static Vector2 yScale(T scale) { return {T(1), scale}; } /** @copydoc Vector::Vector(ZeroInitT) */ constexpr /*implicit*/ Vector2(ZeroInitT = ZeroInit) noexcept /** @todoc remove workaround when doxygen is sane */ #ifndef DOXYGEN_GENERATING_OUTPUT : Vector<2, T>{ZeroInit} #endif {} /** @copydoc Vector::Vector(NoInitT) */ explicit Vector2(NoInitT) noexcept /** @todoc remove workaround when doxygen is sane */ #ifndef DOXYGEN_GENERATING_OUTPUT : Vector<2, T>{NoInit} #endif {} /** @copydoc Vector::Vector(T) */ constexpr explicit Vector2(T value) noexcept: Vector<2, T>(value) {} /** * @brief Constructor * * @f[ * \boldsymbol v = \begin{pmatrix} x \\ y \end{pmatrix} * @f] */ constexpr /*implicit*/ Vector2(T x, T y) noexcept: Vector<2, T>(x, y) {} /** @copydoc Vector::Vector(const Vector&) */ template constexpr explicit Vector2(const Vector<2, U>& other) noexcept: Vector<2, T>(other) {} /** @brief Construct vector from external representation */ template::from(std::declval())) #else decltype(Implementation::VectorConverter<2, T, U>()) #endif > constexpr explicit Vector2(const U& other): Vector<2, T>(Implementation::VectorConverter<2, T, U>::from(other)) {} /** @brief Copy constructor */ constexpr /*implicit*/ Vector2(const Vector<2, T>& other) noexcept: Vector<2, T>(other) {} T& x() { return (*this)[0]; } /**< @brief X component */ constexpr T x() const { return (*this)[0]; } /**< @overload */ T& y() { return (*this)[1]; } /**< @brief Y component */ constexpr T y() const { return (*this)[1]; } /**< @overload */ /** * @brief Perpendicular vector * * Returns vector rotated 90° counterclockwise. @f[ * \boldsymbol v_\bot = \begin{pmatrix} -v_y \\ v_x \end{pmatrix} * @f] * @see @ref cross(), * @ref dot(const Vector&, const Vector&), * @ref operator-() const */ Vector2 perpendicular() const { return {-y(), x()}; } /** * @brief Aspect ratio * * Returns quotient of the two elements. @f[ * a = \frac{v_x}{v_y} * @f] */ T aspectRatio() const { return x()/y(); } MAGNUM_VECTOR_SUBCLASS_IMPLEMENTATION(2, Vector2) }; #ifndef DOXYGEN_GENERATING_OUTPUT MAGNUM_VECTORn_OPERATOR_IMPLEMENTATION(2, Vector2) #endif namespace Implementation { template struct TypeForSize; template struct TypeForSize<2, T> { typedef Math::Vector2 Type; }; } }} namespace Corrade { namespace Utility { /** @configurationvalue{Magnum::Math::Vector2} */ template struct ConfigurationValue>: public ConfigurationValue> {}; }} #endif