@fdx/fxmath
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A helper library for vector math and generative art
441 lines • 14.2 kB
JavaScript
"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports._V2 = exports._v2 = void 0;
const common_1 = require("./common");
const _v2 = (x, y) => {
return new _V2(x, y);
};
exports._v2 = _v2;
class _V2 {
/**
* Creates a vector from point A to point B.
* @param {V2} a - The starting point.
* @param {V2} b - The ending point.
* @returns {V2} The resulting vector.
*/
static fromTo(a, b) {
return _v2(b.x - a.x, b.y - a.y);
}
/**
* Checks if two vectors are identical.
* @param {_V2} a - First vector.
* @param {_V2} b - Second vector.
* @returns {boolean} `true` if the vectors are the same, otherwise `false`.
*/
static sameLike(a, b) {
return a.x === b.x && a.y === b.y;
}
/**
* Computes the intersection of two line segments.
* @param {_V2} pA - First segment start.
* @param {_V2} pA2 - First segment end.
* @param {_V2} pB - Second segment start.
* @param {_V2} pB2 - Second segment end.
* @returns {_V2 | false} The intersection point or `false` if no intersection exists.
*/
static linesIntersect(pA, pA2, pB, pB2) {
let denominator = (pB2.y - pB.y) * (pA2.x - pA.x) - (pB2.x - pB.x) * (pA2.y - pA.y);
if (denominator === 0)
return false; // Parallel lines
let ua = ((pB2.x - pB.x) * (pA.y - pB.y) - (pB2.y - pB.y) * (pA.x - pB.x)) /
denominator;
let ub = ((pA2.x - pA.x) * (pA.y - pB.y) - (pA2.y - pA.y) * (pA.x - pB.x)) /
denominator;
if (ua < 0 || ua > 1 || ub < 0 || ub > 1)
return false;
let x = pA.x + ua * (pA2.x - pA.x);
let y = pA.y + ua * (pA2.y - pA.y);
return _v2(x, y);
}
/**
* Checks if a point is inside a polygon.
* @param {_V2} p - The point to check.
* @param {_V2[]} polygon - An array of vectors defining the polygon.
* @returns {boolean} `true` if the point is inside, otherwise `false`.
*/
static isPointInPolygon(p, polygon) {
let len = polygon.length;
let inside = false;
for (let i = 0, j = len - 1; i < len; j = i++) {
if ((polygon[i].y > p.y) !== (polygon[j].y > p.y) &&
p.x <
((polygon[j].x - polygon[i].x) * (p.y - polygon[i].y)) /
(polygon[j].y - polygon[i].y) +
polygon[i].x) {
inside = !inside;
}
}
return inside;
}
/**
* Creates a new 2D vector.
* @param {number} x - The X-coordinate.
* @param {number} y - The Y-coordinate.
* @returns {_V2} A new _V2 instance.
*/
static create(x, y) {
return new _V2(x, y);
}
/**
* Creates a vector using a magnitude and an angle.
* @param {number} mag - The magnitude (length) of the vector.
* @param {number} angle - The angle in radians.
* @returns {_V2} The resulting vector.
*/
static createByMagnitudeAndAngle(mag, angle) {
return new _V2(mag * Math.cos(angle), mag * Math.sin(angle));
}
/**
* Computes the angle of a vector in radians.
* @param {_V2} v - The vector.
* @returns {number} The angle in radians.
*/
static getAngle(v) {
return Math.atan2(v.y, v.x);
}
/**
* Calculates the angle between two vectors.
* @param {_V2} a - First vector.
* @param {_V2} b - Second vector.
* @returns {number} The angle in radians.
*/
static angleBetween(a, b) {
return Math.acos(_V2.dotprod(a, b) / (a.magnitude * b.magnitude));
}
/**
* Clones a vector.
* @param {_V2} v - The vector to clone.
* @returns {_V2} A new instance with the same values.
*/
static clone(v) {
return new _V2(v.x, v.y);
}
/**
* Computes the magnitude (length) of a vector.
* @param {_V2} v - The vector.
* @returns {number} The magnitude of the vector.
*/
static magnitude(v) {
return v.magnitude;
}
/**
* Computes the squared magnitude of a vector (avoiding square root for performance).
* @param {_V2} v - The vector.
* @returns {number} The squared magnitude.
*/
static squareMagnitude(v) {
return v.squareMagnitude;
}
/**
* Computes the distance between two vectors.
* @param {_V2} v1 - First vector.
* @param {_V2} v2 - Second vector.
* @returns {number} The distance between `v1` and `v2`.
*/
static distance(v1, v2) {
return _V2.subtract(v1, v2).magnitude;
}
/**
* Adds two vectors.
* @param {_V2} v1 - First vector.
* @param {_V2} v2 - Second vector.
* @returns {_V2} The resulting vector.
*/
static add(v1, v2) {
return new _V2(v1.x + v2.x, v1.y + v2.y);
}
/**
* Subtracts one vector from another.
* @param {_V2} v1 - The vector to subtract from.
* @param {_V2} v2 - The vector to subtract.
* @returns {_V2} The resulting vector.
*/
static subtract(v1, v2) {
return new _V2(v1.x - v2.x, v1.y - v2.y);
}
/**
* Alias for `subtract`.
* @param {_V2} v1 - The vector to subtract from.
* @param {_V2} v2 - The vector to subtract.
* @returns {_V2} The resulting vector.
*/
static sub(v1, v2) {
return _V2.subtract(v1, v2);
}
/**
* Multiplies a vector by a scalar.
* @param {_V2} vector - The vector to multiply.
* @param {number} scalar - The scalar value.
* @returns {_V2} The scaled vector.
*/
static multiply(vector, scalar) {
return new _V2(vector.x * scalar, vector.y * scalar);
}
/**
* Multiplies two vectors component-wise.
* @param {_V2} v0 - First vector.
* @param {_V2} v1 - Second vector.
* @returns {_V2} The resulting vector.
*/
static multVec(v0, v1) {
return new _V2(v0.x * v1.x, v0.y * v1.y);
}
/**
* Divides a vector by a scalar.
* @param {_V2} v - The vector to divide.
* @param {number} scalar - The scalar value.
* @returns {_V2} The resulting vector.
*/
static divide(v, scalar) {
return _V2.multiply(v, 1 / scalar);
}
/**
* Computes the dot product of two vectors.
* @param {_V2} v1 - First vector.
* @param {_V2} v2 - Second vector.
* @returns {number} The dot product.
*/
static dotprod(v1, v2) {
return v1.x * v2.x + v1.y * v2.y;
}
/**
* Alias for `dotprod`.
* @param {_V2} v1 - First vector.
* @param {_V2} v2 - Second vector.
* @returns {number} The dot product.
*/
static dot(v1, v2) {
return _V2.dotprod(v1, v2);
}
/**
* Computes the cross product of two vectors.
* @param {_V2} v1 - First vector.
* @param {_V2} v2 - Second vector.
* @returns {number} The cross product (a scalar value).
*/
static crossprod(v1, v2) {
return v1.x * v2.y - v1.y * v2.x;
}
/**
* Returns the unit vector (normalized) of a given vector.
* @param {_V2} v - The vector to normalize.
* @returns {_V2} The unit vector.
*/
static unitVec(v) {
return _V2.divide(v, v.magnitude);
}
/**
* Projects vector `v1` onto vector `v2`.
* @param {_V2} v1 - The vector to be projected.
* @param {_V2} v2 - The vector onto which `v1` is projected.
* @returns {_V2} The projected vector.
*/
static projectionFromTo(v1, v2) {
let unitVector = _V2.unitVec(v2);
return _V2.multiply(unitVector, _V2.dotprod(v1, unitVector));
}
/**
* Rotates a vector around the origin.
* @param {_V2} v - The vector to rotate.
* @param {number} angle - The rotation angle in radians.
* @returns {_V2} The rotated vector.
*/
static rotate(v, angle) {
const cosA = Math.cos(angle);
const sinA = Math.sin(angle);
return new _V2(v.x * cosA - v.y * sinA, v.x * sinA + v.y * cosA);
}
/**
* Rotates a vector around a pivot point.
* @param {_V2} point - The vector to rotate.
* @param {_V2} pivot - The pivot point.
* @param {number} angleRad - The rotation angle in radians.
* @returns {_V2} The rotated vector.
*/
static rotateAroundPivot(point, pivot, angleRad) {
const cos = Math.cos(angleRad);
const sin = Math.sin(angleRad);
const dx = point.x - pivot.x;
const dy = point.y - pivot.y;
return new _V2(cos * dx - sin * dy + pivot.x, sin * dx + cos * dy + pivot.y);
}
/**
* Computes the left normal of a vector.
* @param {_V2} v - The vector.
* @returns {_V2} The left normal vector.
*/
static normalLeft(v) {
return new _V2(-v.y, v.x);
}
/**
* Computes the right normal of a vector.
* @param {_V2} v - The vector.
* @returns {_V2} The right normal vector.
*/
static normalRight(v) {
return new _V2(v.y, -v.x);
}
/**
* Computes the Manhattan distance between two vectors.
* @param {_V2} v1 - First vector.
* @param {_V2} v2 - Second vector.
* @returns {number} The Manhattan distance.
*/
static manhattanDistance(v1, v2) {
return Math.abs(v1.x - v2.x) + Math.abs(v1.y - v2.y);
}
/**
* Linearly interpolates between two vectors.
* @param {_V2} v1 - First vector.
* @param {_V2} v2 - Second vector.
* @param {number} amt - Interpolation amount (0 to 1).
* @returns {_V2} The interpolated vector.
*/
static lerp(v1, v2, amt) {
return new _V2((0, common_1.lerp)(v1.x, v2.x, amt), (0, common_1.lerp)(v1.y, v2.y, amt));
}
/**
* Creates a new immutable 2D vector.
* @param {number} x - The X-coordinate.
* @param {number} y - The Y-coordinate.
*/
constructor(x, y) {
this.x = x;
this.y = y;
}
/**
* Creates a new vector with the same values.
* @returns {_V2} A new copy of this vector.
*/
clone() {
return new _V2(this.x, this.y);
}
/**
* Adds another vector and returns a new vector.
* @param {_V2} v - The vector to add.
* @returns {_V2} A new vector with the result.
*/
add(v) {
return new _V2(this.x + v.x, this.y + v.y);
}
/**
* Subtracts another vector and returns a new vector.
* @param {_V2} v - The vector to subtract.
* @returns {_V2} A new vector with the result.
*/
subtract(v) {
return new _V2(this.x - v.x, this.y - v.y);
}
/**
* Multiplies this vector by a scalar.
* @param {number} scalar - The scalar to multiply.
* @returns {_V2} A new vector with the result.
*/
multiply(scalar) {
return new _V2(this.x * scalar, this.y * scalar);
}
/**
* Divides this vector by a scalar.
* @param {number} scalar - The scalar to divide by.
* @returns {_V2} A new vector with the result.
*/
divide(scalar) {
return new _V2(this.x / scalar, this.y / scalar);
}
/**
* Computes the dot product with another vector.
* @param {_V2} v - The other vector.
* @returns {number} The dot product.
*/
dot(v) {
return this.x * v.x + this.y * v.y;
}
/**
* Computes the cross product with another vector.
* @param {_V2} v - The other vector.
* @returns {number} The cross product.
*/
cross(v) {
return this.x * v.y - this.y * v.x;
}
/**
* Returns the normalized (unit) vector.
* @returns {_V2} A new unit vector.
*/
normalize() {
const mag = this.magnitude;
return mag === 0 ? new _V2(0, 0) : this.divide(mag);
}
/**
* Rotates this vector by a given angle in radians.
* @param {number} angle - The angle in radians.
* @returns {_V2} A new rotated vector.
*/
rotate(angle) {
const cos = Math.cos(angle);
const sin = Math.sin(angle);
return new _V2(this.x * cos - this.y * sin, this.x * sin + this.y * cos);
}
/**
* Computes the perpendicular left normal vector (90° counterclockwise).
* @returns {_V2} A new vector rotated 90° counterclockwise.
*/
normalLeft() {
return new _V2(-this.y, this.x);
}
/**
* Computes the perpendicular right normal vector (90° clockwise).
* @returns {_V2} A new vector rotated 90° clockwise.
*/
normalRight() {
return new _V2(this.y, -this.x);
}
/**
* Gets the magnitude (length) of the vector.
* @returns {number} The magnitude of the vector.
*/
get magnitude() {
return Math.sqrt(this.x * this.x + this.y * this.y);
}
/**
* Gets the squared magnitude of the vector (faster than `magnitude()`).
* @returns {number} The squared magnitude.
*/
get squareMagnitude() {
return this.x * this.x + this.y * this.y;
}
/**
* Computes the distance to another vector.
* @param {_V2} v - The other vector.
* @returns {number} The distance.
*/
distance(v) {
return this.subtract(v).magnitude;
}
/**
* Linearly interpolates between this vector and another.
* @param {_V2} v - The target vector.
* @param {number} amt - The interpolation amount (0 to 1).
* @returns {_V2} The interpolated vector.
*/
lerp(v, amt) {
return new _V2((0, common_1.lerp)(this.x, v.x, amt), (0, common_1.lerp)(this.y, v.y, amt));
}
/**
* Floors the values of the vector components.
* @returns {_V2} A new vector with floored values.
*/
floor() {
return new _V2(Math.floor(this.x), Math.floor(this.y));
}
/**
* Checks if this vector is inside a given polygon.
* @param {_V2[]} polygon - The polygon as an array of vectors.
* @returns {boolean} `true` if inside, otherwise `false`.
*/
isInPolygon(polygon) {
return _V2.isPointInPolygon(this, polygon);
}
}
exports._V2 = _V2;
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