phaser/Phaser/utils/PointUtils.ts

/// <reference path="../Game.ts" />
/// <reference path="../core/Point.ts" />

/**
* Phaser - PointUtils
*
* A collection of methods useful for manipulating and comparing Point objects.
*
* TODO: interpolate & polar
*/

module Phaser {

    class PointUtils {

        /**
         * Adds the coordinates of two points together to create a new point.
         * @method add
         * @param {Point} a - The first Point object.
         * @param {Point} b - The second Point object.
         * @param {Point} out - Optional Point to store the value in, if not supplied a new Point object will be created.
         * @return {Point} The new Point object.
         **/
        static add(a: Point, b: Point, out?: Point = new Point): Point {
            return out.setTo(a.x + b.x, a.y + b.y);
        }

        /**
         * Subtracts the coordinates of two points to create a new point.
         * @method subtract
         * @param {Point} a - The first Point object.
         * @param {Point} b - The second Point object.
         * @param {Point} out - Optional Point to store the value in, if not supplied a new Point object will be created.
         * @return {Point} The new Point object.
         **/
        static subtract(a: Point, b: Point, out?: Point = new Point): Point {
            return out.setTo(a.x - b.x, a.y - b.y);
        }

        /**
         * Multiplies the coordinates of two points to create a new point.
         * @method subtract
         * @param {Point} a - The first Point object.
         * @param {Point} b - The second Point object.
         * @param {Point} out - Optional Point to store the value in, if not supplied a new Point object will be created.
         * @return {Point} The new Point object.
         **/
        static multiply(a: Point, b: Point, out?: Point = new Point): Point {
            return out.setTo(a.x * b.x, a.y * b.y);
        }

        /**
         * Divides the coordinates of two points to create a new point.
         * @method subtract
         * @param {Point} a - The first Point object.
         * @param {Point} b - The second Point object.
         * @param {Point} out - Optional Point to store the value in, if not supplied a new Point object will be created.
         * @return {Point} The new Point object.
         **/
        static divide(a: Point, b: Point, out?: Point = new Point): Point {
            return out.setTo(a.x / b.x, a.y / b.y);
        }

        /**
         * Clamps the Point object values to be between the given min and max
         * @method clamp
         * @param {Point} a - The point.
         * @param {number} The minimum value to clamp this Point to
         * @param {number} The maximum value to clamp this Point to
         * @return {Point} This Point object.
         **/
        static clamp(a: Point, min: number, max: number): Point {

            PointUtils.clampX(a, min, max);
            PointUtils.clampY(a, min, max);
            return a;

        }

        /**
         * Clamps the x value of the given Point object to be between the min and max values.
         * @method clampX
         * @param {Point} a - The point.
         * @param {number} The minimum value to clamp this Point to
         * @param {number} The maximum value to clamp this Point to
         * @return {Point} This Point object.
         **/
        static clampX(a: Point, min: number, max: number): Point {

            a.x = Math.max(Math.min(a.x, max), min);
            return a;

        }

        /**
         * Clamps the y value of the given Point object to be between the min and max values.
         * @method clampY
         * @param {Point} a - The point.
         * @param {number} The minimum value to clamp this Point to
         * @param {number} The maximum value to clamp this Point to
         * @return {Point} This Point object.
         **/
        static clampY(a: Point, min: number, max: number): Point {

            a.y = Math.max(Math.min(a.y, max), min);
            return a;

        }

        /**
         * Creates a copy of the given Point.
         * @method clone
         * @param {Point} output Optional Point object. If given the values will be set into this object, otherwise a brand new Point object will be created and returned.
         * @return {Point} The new Point object.
         **/
        static clone(a: Point, output?: Point = new Point): Point {
            return output.setTo(a.x, a.y);
        }

        /**
         * Returns the distance between the two given Point objects.
         * @method distanceBetween
         * @param {Point} a - The first Point object.
         * @param {Point} b - The second Point object.
         * @param {Boolean} round - Round the distance to the nearest integer (default false)
         * @return {Number} The distance between the two Point objects.
         **/
        static distanceBetween(a: Point, b: Point, round?: bool = false): number {

            var dx = a.x - b.x;
            var dy = a.y - b.y;

            if (round === true)
            {
                return Math.round(Math.sqrt(dx * dx + dy * dy));
            }
            else
            {
                return Math.sqrt(dx * dx + dy * dy);
            }

        }

        /**
         * Determines whether the two given Point objects are equal. They are considered equal if they have the same x and y values.
         * @method equals
         * @param {Point} a - The first Point object.
         * @param {Point} b - The second Point object.
         * @return {Boolean} A value of true if the Points are equal, otherwise false.
         **/
        static equals(a: Point, b: Point): bool {
            return (a.x == b.x && a.y == b.y);
        }

        /**
         * Determines a point between two specified points. The parameter f determines where the new interpolated point is located relative to the two end points specified by parameters pt1 and pt2.
         * The closer the value of the parameter f is to 1.0, the closer the interpolated point is to the first point (parameter pt1). The closer the value of the parameter f is to 0, the closer the interpolated point is to the second point (parameter pt2).
         * @method interpolate
         * @param {Point} pointA - The first Point object.
         * @param {Point} pointB - The second Point object.
         * @param {Number} f - The level of interpolation between the two points. Indicates where the new point will be, along the line between pt1 and pt2. If f=1, pt1 is returned; if f=0, pt2 is returned.
         * @return {Point} The new interpolated Point object.
         **/
        //static interpolate(pointA, pointB, f) {
        //}

        /**
         * Converts a pair of polar coordinates to a Cartesian point coordinate.
         * @method polar
         * @param {Number} length - The length coordinate of the polar pair.
         * @param {Number} angle - The angle, in radians, of the polar pair.
         * @return {Point} The new Cartesian Point object.
         **/
        //static polar(length, angle) {
        //}

        /**
        * Rotates a Point around the x/y coordinates given to the desired angle.
        * @param a {Point} The Point object to rotate.
	    * @param x {number} The x coordinate of the anchor point
	    * @param y {number} The y coordinate of the anchor point
        * @param {Number} angle The angle in radians (unless asDegrees is true) to rotate the Point to.
	    * @param {Boolean} asDegrees Is the given angle in radians (false) or degrees (true)?
        * @param {Number} distance An optional distance constraint between the Point and the anchor.
        * @return The modified point object
        */
        static rotate(a: Point, x: number, y: number, angle: number, asDegrees: bool = false, distance?: number = null): Point {

            if (asDegrees)
            {
                angle = angle * GameMath.DEG_TO_RAD;
            }

            //  Get distance from origin (cx/cy) to this point
            if (distance === null)
            {
                distance = Math.sqrt(((x - a.x) * (x - a.x)) + ((y - a.y) * (y - a.y)));
            }

            return a.setTo(x + distance * Math.cos(angle), y + distance * Math.sin(angle));

        }

        /**
        * Rotates a Point around the given Point to the desired angle.
        * @param a {Point} The Point object to rotate.
        * @param b {Point} The Point object to serve as point of rotation.
	    * @param x {number} The x coordinate of the anchor point
	    * @param y {number} The y coordinate of the anchor point
        * @param {Number} angle The angle in radians (unless asDegrees is true) to rotate the Point to.
	    * @param {Boolean} asDegrees Is the given angle in radians (false) or degrees (true)?
        * @param {Number} distance An optional distance constraint between the Point and the anchor.
        * @return The modified point object
        */
        static rotateAroundPoint(a: Point, b: Point, angle: number, asDegrees: bool = false, distance?: number = null): Point {
            return PointUtils.rotate(a, b.x, b.y, angle, asDegrees, distance);
        }

    }

}
Refactoring ready for 1.0 release. 2013-05-25 03:21:24 +00:00			`/// <reference path="../Game.ts" />`
			`/// <reference path="../core/Point.ts" />`

			`/**`
			`* Phaser - PointUtils`
			`*`
			`* A collection of methods useful for manipulating and comparing Point objects.`
			`*`
			`* TODO: interpolate & polar`
			`*/`

			`module Phaser {`

			`class PointUtils {`

			`/**`
			`* Adds the coordinates of two points together to create a new point.`
			`* @method add`
			`* @param {Point} a - The first Point object.`
			`* @param {Point} b - The second Point object.`
			`* @param {Point} out - Optional Point to store the value in, if not supplied a new Point object will be created.`
			`* @return {Point} The new Point object.`
			`**/`
			`static add(a: Point, b: Point, out?: Point = new Point): Point {`
			`return out.setTo(a.x + b.x, a.y + b.y);`
			`}`

			`/**`
			`* Subtracts the coordinates of two points to create a new point.`
			`* @method subtract`
			`* @param {Point} a - The first Point object.`
			`* @param {Point} b - The second Point object.`
			`* @param {Point} out - Optional Point to store the value in, if not supplied a new Point object will be created.`
			`* @return {Point} The new Point object.`
			`**/`
			`static subtract(a: Point, b: Point, out?: Point = new Point): Point {`
			`return out.setTo(a.x - b.x, a.y - b.y);`
			`}`

			`/**`
			`* Multiplies the coordinates of two points to create a new point.`
			`* @method subtract`
			`* @param {Point} a - The first Point object.`
			`* @param {Point} b - The second Point object.`
			`* @param {Point} out - Optional Point to store the value in, if not supplied a new Point object will be created.`
			`* @return {Point} The new Point object.`
			`**/`
			`static multiply(a: Point, b: Point, out?: Point = new Point): Point {`
			`return out.setTo(a.x * b.x, a.y * b.y);`
			`}`

			`/**`
			`* Divides the coordinates of two points to create a new point.`
			`* @method subtract`
			`* @param {Point} a - The first Point object.`
			`* @param {Point} b - The second Point object.`
			`* @param {Point} out - Optional Point to store the value in, if not supplied a new Point object will be created.`
			`* @return {Point} The new Point object.`
			`**/`
			`static divide(a: Point, b: Point, out?: Point = new Point): Point {`
			`return out.setTo(a.x / b.x, a.y / b.y);`
			`}`

			`/**`
			`* Clamps the Point object values to be between the given min and max`
			`* @method clamp`
			`* @param {Point} a - The point.`
			`* @param {number} The minimum value to clamp this Point to`
			`* @param {number} The maximum value to clamp this Point to`
			`* @return {Point} This Point object.`
			`**/`
			`static clamp(a: Point, min: number, max: number): Point {`

			`PointUtils.clampX(a, min, max);`
			`PointUtils.clampY(a, min, max);`
			`return a;`

			`}`

			`/**`
			`* Clamps the x value of the given Point object to be between the min and max values.`
			`* @method clampX`
			`* @param {Point} a - The point.`
			`* @param {number} The minimum value to clamp this Point to`
			`* @param {number} The maximum value to clamp this Point to`
			`* @return {Point} This Point object.`
			`**/`
			`static clampX(a: Point, min: number, max: number): Point {`

			`a.x = Math.max(Math.min(a.x, max), min);`
			`return a;`

			`}`

			`/**`
			`* Clamps the y value of the given Point object to be between the min and max values.`
			`* @method clampY`
			`* @param {Point} a - The point.`
			`* @param {number} The minimum value to clamp this Point to`
			`* @param {number} The maximum value to clamp this Point to`
			`* @return {Point} This Point object.`
			`**/`
			`static clampY(a: Point, min: number, max: number): Point {`

			`a.y = Math.max(Math.min(a.y, max), min);`
			`return a;`

			`}`

			`/**`
			`* Creates a copy of the given Point.`
			`* @method clone`
			`* @param {Point} output Optional Point object. If given the values will be set into this object, otherwise a brand new Point object will be created and returned.`
			`* @return {Point} The new Point object.`
			`**/`
			`static clone(a: Point, output?: Point = new Point): Point {`
			`return output.setTo(a.x, a.y);`
			`}`

			`/**`
			`* Returns the distance between the two given Point objects.`
			`* @method distanceBetween`
			`* @param {Point} a - The first Point object.`
			`* @param {Point} b - The second Point object.`
			`* @param {Boolean} round - Round the distance to the nearest integer (default false)`
			`* @return {Number} The distance between the two Point objects.`
			`**/`
			`static distanceBetween(a: Point, b: Point, round?: bool = false): number {`

			`var dx = a.x - b.x;`
			`var dy = a.y - b.y;`

			`if (round === true)`
			`{`
			`return Math.round(Math.sqrt(dx * dx + dy * dy));`
			`}`
			`else`
			`{`
			`return Math.sqrt(dx * dx + dy * dy);`
			`}`

			`}`

			`/**`
			`* Determines whether the two given Point objects are equal. They are considered equal if they have the same x and y values.`
			`* @method equals`
			`* @param {Point} a - The first Point object.`
			`* @param {Point} b - The second Point object.`
			`* @return {Boolean} A value of true if the Points are equal, otherwise false.`
			`**/`
			`static equals(a: Point, b: Point): bool {`
			`return (a.x == b.x && a.y == b.y);`
			`}`

			`/**`
			`* Determines a point between two specified points. The parameter f determines where the new interpolated point is located relative to the two end points specified by parameters pt1 and pt2.`
			`* The closer the value of the parameter f is to 1.0, the closer the interpolated point is to the first point (parameter pt1). The closer the value of the parameter f is to 0, the closer the interpolated point is to the second point (parameter pt2).`
			`* @method interpolate`
			`* @param {Point} pointA - The first Point object.`
			`* @param {Point} pointB - The second Point object.`
			`* @param {Number} f - The level of interpolation between the two points. Indicates where the new point will be, along the line between pt1 and pt2. If f=1, pt1 is returned; if f=0, pt2 is returned.`
			`* @return {Point} The new interpolated Point object.`
			`**/`
			`//static interpolate(pointA, pointB, f) {`
			`//}`

			`/**`
			`* Converts a pair of polar coordinates to a Cartesian point coordinate.`
			`* @method polar`
			`* @param {Number} length - The length coordinate of the polar pair.`
			`* @param {Number} angle - The angle, in radians, of the polar pair.`
			`* @return {Point} The new Cartesian Point object.`
			`**/`
			`//static polar(length, angle) {`
			`//}`

			`/**`
			`* Rotates a Point around the x/y coordinates given to the desired angle.`
			`* @param a {Point} The Point object to rotate.`
			`* @param x {number} The x coordinate of the anchor point`
			`* @param y {number} The y coordinate of the anchor point`
			`* @param {Number} angle The angle in radians (unless asDegrees is true) to rotate the Point to.`
			`* @param {Boolean} asDegrees Is the given angle in radians (false) or degrees (true)?`
			`* @param {Number} distance An optional distance constraint between the Point and the anchor.`
			`* @return The modified point object`
			`*/`
			`static rotate(a: Point, x: number, y: number, angle: number, asDegrees: bool = false, distance?: number = null): Point {`

			`if (asDegrees)`
			`{`
			`angle = angle * GameMath.DEG_TO_RAD;`
			`}`

			`// Get distance from origin (cx/cy) to this point`
			`if (distance === null)`
			`{`
			`distance = Math.sqrt(((x - a.x) * (x - a.x)) + ((y - a.y) * (y - a.y)));`
			`}`

			`return a.setTo(x + distance * Math.cos(angle), y + distance * Math.sin(angle));`

			`}`

			`/**`
			`* Rotates a Point around the given Point to the desired angle.`
			`* @param a {Point} The Point object to rotate.`
			`* @param b {Point} The Point object to serve as point of rotation.`
			`* @param x {number} The x coordinate of the anchor point`
			`* @param y {number} The y coordinate of the anchor point`
			`* @param {Number} angle The angle in radians (unless asDegrees is true) to rotate the Point to.`
			`* @param {Boolean} asDegrees Is the given angle in radians (false) or degrees (true)?`
			`* @param {Number} distance An optional distance constraint between the Point and the anchor.`
			`* @return The modified point object`
			`*/`
			`static rotateAroundPoint(a: Point, b: Point, angle: number, asDegrees: bool = false, distance?: number = null): Point {`
			`return PointUtils.rotate(a, b.x, b.y, angle, asDegrees, distance);`
			`}`

			`}`

			`}`