/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2020 - Raw Material Software Limited JUCE is an open source library subject to commercial or open-source licensing. By using JUCE, you agree to the terms of both the JUCE 6 End-User License Agreement and JUCE Privacy Policy (both effective as of the 16th June 2020). End User License Agreement: www.juce.com/juce-6-licence Privacy Policy: www.juce.com/juce-privacy-policy Or: You may also use this code under the terms of the GPL v3 (see www.gnu.org/licenses). JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE DISCLAIMED. ============================================================================== */ namespace juce { //============================================================================== /** A pair of (x, y) coordinates. The ValueType template should be a primitive type such as int, float, double, rather than a class. @see Line, Path, AffineTransform @tags{Graphics} */ template class Point { public: /** Creates a point at the origin */ constexpr Point() = default; /** Creates a copy of another point. */ constexpr Point (const Point&) = default; /** Creates a point from an (x, y) position. */ constexpr Point (ValueType initialX, ValueType initialY) noexcept : x (initialX), y (initialY) {} //============================================================================== /** Copies this point from another one. */ Point& operator= (const Point&) = default; constexpr inline bool operator== (Point other) const noexcept { return x == other.x && y == other.y; } constexpr inline bool operator!= (Point other) const noexcept { return x != other.x || y != other.y; } /** Returns true if the point is (0, 0). */ constexpr bool isOrigin() const noexcept { return x == ValueType() && y == ValueType(); } /** Returns true if the coordinates are finite values. */ constexpr inline bool isFinite() const noexcept { return juce_isfinite(x) && juce_isfinite(y); } /** Returns the point's x coordinate. */ constexpr inline ValueType getX() const noexcept { return x; } /** Returns the point's y coordinate. */ constexpr inline ValueType getY() const noexcept { return y; } /** Sets the point's x coordinate. */ inline void setX (ValueType newX) noexcept { x = newX; } /** Sets the point's y coordinate. */ inline void setY (ValueType newY) noexcept { y = newY; } /** Returns a point which has the same Y position as this one, but a new X. */ constexpr Point withX (ValueType newX) const noexcept { return Point (newX, y); } /** Returns a point which has the same X position as this one, but a new Y. */ constexpr Point withY (ValueType newY) const noexcept { return Point (x, newY); } /** Changes the point's x and y coordinates. */ void setXY (ValueType newX, ValueType newY) noexcept { x = newX; y = newY; } /** Adds a pair of coordinates to this value. */ void addXY (ValueType xToAdd, ValueType yToAdd) noexcept { x += xToAdd; y += yToAdd; } //============================================================================== /** Returns a point with a given offset from this one. */ constexpr Point translated (ValueType deltaX, ValueType deltaY) const noexcept { return Point (x + deltaX, y + deltaY); } /** Adds two points together */ constexpr Point operator+ (Point other) const noexcept { return Point (x + other.x, y + other.y); } /** Adds another point's coordinates to this one */ Point& operator+= (Point other) noexcept { x += other.x; y += other.y; return *this; } /** Subtracts one points from another */ constexpr Point operator- (Point other) const noexcept { return Point (x - other.x, y - other.y); } /** Subtracts another point's coordinates to this one */ Point& operator-= (Point other) noexcept { x -= other.x; y -= other.y; return *this; } /** Multiplies two points together */ template constexpr Point operator* (Point other) const noexcept { return Point ((ValueType) (x * other.x), (ValueType) (y * other.y)); } /** Multiplies another point's coordinates to this one */ template Point& operator*= (Point other) noexcept { *this = *this * other; return *this; } /** Divides one point by another */ template constexpr Point operator/ (Point other) const noexcept { return Point ((ValueType) (x / other.x), (ValueType) (y / other.y)); } /** Divides this point's coordinates by another */ template Point& operator/= (Point other) noexcept { *this = *this / other; return *this; } /** Returns a point whose coordinates are multiplied by a given scalar value. */ template constexpr Point operator* (OtherType multiplier) const noexcept { using CommonType = typename std::common_type::type; return Point ((ValueType) ((CommonType) x * (CommonType) multiplier), (ValueType) ((CommonType) y * (CommonType) multiplier)); } /** Returns a point whose coordinates are divided by a given scalar value. */ template constexpr Point operator/ (OtherType divisor) const noexcept { using CommonType = typename std::common_type::type; return Point ((ValueType) ((CommonType) x / (CommonType) divisor), (ValueType) ((CommonType) y / (CommonType) divisor)); } /** Multiplies the point's coordinates by a scalar value. */ template Point& operator*= (FloatType multiplier) noexcept { x = (ValueType) (x * multiplier); y = (ValueType) (y * multiplier); return *this; } /** Divides the point's coordinates by a scalar value. */ template Point& operator/= (FloatType divisor) noexcept { x = (ValueType) (x / divisor); y = (ValueType) (y / divisor); return *this; } /** Returns the inverse of this point. */ constexpr Point operator-() const noexcept { return Point (-x, -y); } //============================================================================== /** This type will be double if the Point's type is double, otherwise it will be float. */ using FloatType = typename TypeHelpers::SmallestFloatType::type; //============================================================================== /** Returns the straight-line distance between this point and the origin. */ ValueType getDistanceFromOrigin() const noexcept { return juce_hypot (x, y); } /** Returns the straight-line distance between this point and another one. */ ValueType getDistanceFrom (Point other) const noexcept { return juce_hypot (x - other.x, y - other.y); } /** Returns the square of the straight-line distance between this point and the origin. */ constexpr ValueType getDistanceSquaredFromOrigin() const noexcept { return x * x + y * y; } /** Returns the square of the straight-line distance between this point and another one. */ constexpr ValueType getDistanceSquaredFrom (Point other) const noexcept { return (*this - other).getDistanceSquaredFromOrigin(); } /** Returns the angle from this point to another one. Taking this point to be the centre of a circle, and the other point being a position on the circumference, the return value is the number of radians clockwise from the 12 o'clock direction. So 12 o'clock = 0, 3 o'clock = Pi/2, 6 o'clock = Pi, 9 o'clock = -Pi/2 */ FloatType getAngleToPoint (Point other) const noexcept { return static_cast (std::atan2 (static_cast (other.x - x), static_cast (y - other.y))); } /** Returns the point that would be reached by rotating this point clockwise about the origin by the specified angle. */ Point rotatedAboutOrigin (ValueType angleRadians) const noexcept { return Point (x * std::cos (angleRadians) - y * std::sin (angleRadians), x * std::sin (angleRadians) + y * std::cos (angleRadians)); } /** Taking this point to be the centre of a circle, this returns a point on its circumference. @param radius the radius of the circle. @param angle the angle of the point, in radians clockwise from the 12 o'clock position. */ Point getPointOnCircumference (float radius, float angle) const noexcept { return Point (static_cast (x + radius * std::sin (angle)), static_cast (y - radius * std::cos (angle))); } /** Taking this point to be the centre of an ellipse, this returns a point on its circumference. @param radiusX the horizontal radius of the circle. @param radiusY the vertical radius of the circle. @param angle the angle of the point, in radians clockwise from the 12 o'clock position. */ Point getPointOnCircumference (float radiusX, float radiusY, float angle) const noexcept { return Point (static_cast (x + radiusX * std::sin (angle)), static_cast (y - radiusY * std::cos (angle))); } /** Returns the dot-product of two points (x1 * x2 + y1 * y2). */ constexpr FloatType getDotProduct (Point other) const noexcept { return x * other.x + y * other.y; } //============================================================================== /** Uses a transform to change the point's coordinates. This will only compile if ValueType = float! @see AffineTransform::transformPoint */ void applyTransform (const AffineTransform& transform) noexcept { transform.transformPoint (x, y); } /** Returns the position of this point, if it is transformed by a given AffineTransform. */ Point transformedBy (const AffineTransform& transform) const noexcept { return Point (static_cast (transform.mat00 * (float) x + transform.mat01 * (float) y + transform.mat02), static_cast (transform.mat10 * (float) x + transform.mat11 * (float) y + transform.mat12)); } //============================================================================== /** Casts this point to a Point object. */ constexpr Point toInt() const noexcept { return Point (static_cast (x), static_cast (y)); } /** Casts this point to a Point object. */ constexpr Point toFloat() const noexcept { return Point (static_cast (x), static_cast (y)); } /** Casts this point to a Point object. */ constexpr Point toDouble() const noexcept { return Point (static_cast (x), static_cast (y)); } /** Casts this point to a Point object using roundToInt() to convert the values. */ constexpr Point roundToInt() const noexcept { return Point (juce::roundToInt (x), juce::roundToInt (y)); } /** Returns the point as a string in the form "x, y". */ String toString() const { return String (x) + ", " + String (y); } //============================================================================== ValueType x{}; /**< The point's X coordinate. */ ValueType y{}; /**< The point's Y coordinate. */ }; /** Multiplies the point's coordinates by a scalar value. */ template Point operator* (ValueType value, Point p) noexcept { return p * value; } } // namespace juce