Geometric.js
A JavaScript library for doing geometry.
Installation
Web browser
In vanilla, a geometric
global is exported. You can use the latest version from unpkg.
<script src="https://unpkg.com/geometric@2.5.5/build/geometric.js"></script>
<script src="https://unpkg.com/geometric@2.5.5/build/geometric.min.js"></script>
If you'd rather host it yourself, download the latest release from the build
directory.
npm
npm i geometric -S
const geometric = require("geometric");
API
Geometric.js uses the geometric primitives points, lines, and polygons.
- Points are represented as arrays of two numbers, such as [0, 0].
- Lines are represented as arrays of two points, such as [[0, 0], [1, 0]]. Because they have endpoints, these are technically line segments, but Geometric.js refers to them as lines for simplicity's sake.
- Polygons are represented as arrays of vertices, each of which is a point, such as [[0, 0], [1, 0], [1, 1], [0, 1]]. Polygons can be closed – the first and last vertex are the same – or open.
- There are also functions to calculate relationships between these primitives.
You will also encounter angles, areas, distances, and lengths.
- Angles are represented as numbers, measured in degrees. Geometric.js also provides functions to convert angles from degrees to radians or vice versa.
- Areas, distances, and lengths are represented as numbers, measured in pixels.
Points
# geometric.pointRotate(point, angle[, origin]) · Source, Example
Returns the coordinates resulting from rotating a point about an origin by an angle in degrees. If origin is not specified, the origin defaults to [0, 0].
# geometric.pointTranslate(point, angle, distance) · Source, Example
Returns the coordinates resulting from translating a point by an angle in degrees and a distance.
Lines
# geometric.lineAngle(line) · Source, Example
Returns the angle of a line, in degrees, with respect to the horizontal axis.
# geometric.lineInterpolate(line[, clamp]) · Source, Example
Returns an interpolator function given a line [a, b]. The returned interpolator function takes a single argument t, where t is a number in [0, 1]; a value of 0 returns a, while a value of 1 returns b. Intermediate values interpolate from a to b along the line segment.
By default, the interpolator will return points outside of the line segment if t is less than 0 or greater than 1. You can pass an optional boolean indicating whether to clamp the returned point to inside of the line segment, even if t is greater than 1 or less than 0.
# geometric.lineLength(line) · Source, Example
Returns the length of a line.
# geometric.lineMidpoint(line) · Source, Example
Returns the midpoint of a line.
# geometric.lineRotate(line, angle[, origin]) · Source, Example
Returns the coordinates resulting from rotating a line about an origin by an angle in degrees. If origin is not specified, the origin defaults to the midpoint of the line.
# geometric.lineTranslate(line, angle, distance) · Source, Example
Returns the coordinates resulting from translating a line by an angle in degrees and a distance.
Polygons
# geometric.polygonArea(polygon[, signed]) · Source, Example
Returns the area of a polygon. You can pass a boolean indicating whether the returned area is signed, which defaults to false.
# geometric.polygonBounds(polygon) · Source, Example
Returns the bounds of a polygon, ignoring points with invalid values (null, undefined, NaN, Infinity). The returned bounds are represented as an array of two points, where the first point is the top-left corner and the second point is the bottom-right corner. For example:
const rectangle = [[0, 0], [0, 1], [1, 1], [1, 0]];
const bounds = geometric.polygonBounds(rectangle); // [[0, 0], [1, 1]]
Returns null if the polygon has fewer than three points.
# geometric.polygonCentroid(polygon) · Source, Example
Returns the weighted centroid of a polygon. Not to be confused with a mean center.
# geometric.polygonHull(points) · Source, Example
Returns the convex hull, represented as a polygon, for an array of points. Returns null if the input array has fewer than three points. Uses Andrew’s monotone chain algorithm.
# geometric.polygonInterpolate(polygon]) · Source, Example
Returns an interpolator function given a polygon of vertices [a, ..., n]. The returned interpolator function takes a single argument t, where t is a number in [0, 1]; a value of 0 returns a, while a value of 1 returns n. Intermediate values interpolate from a to n along the polygon's perimeter.
# geometric.polygonLength(polygon) · Source, Example
Returns the length of a polygon's perimeter.
# geometric.polygonMean(polygon) · Source, Example
Returns the arithmetic mean of the vertices of a polygon. Keeps duplicate vertices, resulting in different values for open and closed polygons. Not to be confused with a centroid.
# geometric.polygonRandom([sides[, area[, centroid]]]) · Source, Example
Returns the vertices of a random convex polygon of the specified number of sides, area, and centroid coordinates. If sides is not specified, defaults to 3. If area is not specified, defaults to 100. If centroid is not specified, defaults to [0, 0]. The returned polygon's winding order will be counter-clockwise. Based on an algorithm by Pavel Valtr and an implementation by Maneesh Agrawala.
# geometric.polygonReflectX(polygon[, reflectFactor]) · Source, Example
Reflects a polygon over its vertical midline. Pass an optional reflectFactor between 0 and 1, where 1 indicates a full reflection, 0 leaves the polygon unchanged, and 0.5 collapses the polygon on its vertical midline.
# geometric.polygonReflectY(polygon[, reflectFactor]) · Source, Example
Reflects a polygon over its horizontal midline. Pass an optional reflectFactor between 0 and 1, where 1 indicates a full reflection, 0 leaves the polygon unchanged, and 0.5 collapses the polygon on its horizontal midline.
# geometric.polygonRegular([sides[, area[, center]]]) · Source, Example
Returns the vertices of a regular polygon of the specified number of sides, area, and center coordinates. If sides is not specified, defaults to 3. If area is not specified, defaults to 100. If center is not specified, defaults to [0, 0]. The returned polygon's winding order will be counter-clockwise.
# geometric.polygonRotate(polygon, angle[, origin]) · Source, Example
Returns the vertices resulting from rotating a polygon about an origin by an angle in degrees. If origin is not specified, the origin defaults to [0, 0].
# geometric.polygonScale(polygon, scaleFactor[, origin]) · Source, Example
Returns the vertices resulting from scaling a polygon by a scaleFactor (where 1 is the polygon's current size) from an origin point. If origin is not specified, the origin defaults to the polygon's centroid.
The returned polygon's area is equal to the input polygon's area multiplied by the square of the scaleFactor. To scale the polygon's area by the scaleFactor itself, see geometric.polygonScaleArea.
# geometric.polygonScaleArea(polygon, scaleFactor[, origin]) · Source, Example
Returns the vertices resulting from scaling a polygon by a scaleFactor (where 1 is the polygon's current size) from an origin point. If origin is not specified, the origin defaults to the polygon's centroid.
The returned polygon's area is equal to the input polygon's area multiplied by the scaleFactor. To scale the polygon's area by the square of the scaleFactor, see geometric.polygonScale.
# geometric.polygonScaleX(polygon, scaleFactor[, origin]) · Source, Example
Returns the vertices resulting from scaling the horizontal coordinates of a polygon by a scaleFactor (where 1 is the polygon's current size) from an origin point. The vertical coordinates remain unchanged. If origin is not specified, the origin defaults to the polygon's centroid.
The returned polygon's area is equal to the input polygon's area multiplied by the scaleFactor.
# geometric.polygonScaleY(polygon, scaleFactor[, origin]) · Source, Example
Returns the vertices resulting from scaling the vertical coordinates of a polygon by a scaleFactor (where 1 is the polygon's current size) from an origin point. The horizontal coordinates remain unchanged. If origin is not specified, the origin defaults to the polygon's centroid.
The returned polygon's area is equal to the input polygon's area multiplied by the scaleFactor.
# geometric.polygonTranslate(polygon, angle, distance) · Source, Example
Returns the vertices resulting from translating a polygon by an angle in degrees and a distance.
# geometric.polygonWind(polygon[, order]) · Source, Example
Returns a polygon in the specified winding order. If an order string is passed as either "cw" or "clockwise", returns a polygon with a clockwise winding order. Otherwise, returns a polygon with a counter-clockwise winding order. Returns null if the polygon has fewer than three points.
On computer screens where the top-left corner is at [0, 0], a polygon with a negative signed area has a counter-clockwise winding order.
Relationships
# geometric.lineIntersectsLine(lineA, lineB) · Source, Example
Returns a boolean representing whether lineA intersects lineB.
# geometric.lineIntersectsPolygon(line, polygon) · Source, Example
Returns a boolean representing whether a line intersects a polygon.
# geometric.pointInPolygon(point, polygon) · Source, Example
Returns a boolean representing whether a point is inside of a polygon. Uses ray casting.
# geometric.pointOnPolygon(point, polygon[, epsilon]) · Source, Example
Returns a boolean representing whether a point is located on one of the edges of a polygon. An optional epsilon number, such as 1e-6, can be passed to reduce the precision with which the relationship is measured.
# geometric.pointOnLine(point, line[, epsilon]) · Source, Example
Returns a boolean representing whether a point is collinear with a line and is also located on the line segment. An optional epsilon number, such as 1e-6, can be passed to reduce the precision with which the relationship is measured. See also pointWithLine.
# geometric.pointWithLine(point, line[, epsilon]) · Source, Example
Returns a boolean representing whether a point is collinear with a line. An optional epsilon number, such as 1e-6, can be passed to reduce the precision with which the relationship is measured. See also pointOnLine.
# geometric.pointLeftofLine(point, line) · Source, Example
Returns a boolean representing whether a point is to the left of a line.
# geometric.pointRightofLine(point, line) · Source, Example
Returns a boolean representing whether a point is to the right of a line.
# geometric.polygonInPolygon(polygonA, polygonB) · Source, Example
Returns a boolean representing whether polygonA is contained by polygonB.
# geometric.polygonIntersectsPolygon(polygonA, polygonB) · Source, Example
Returns a boolean representing whether polygonA intersects but is not contained by polygonB.
Angles
# geometric.angleReflect(incidence, surface) · Source, Example
Returns the angle of reflection given a starting angle, also known as the angle of incidence, and the angle of the surface off of which it is reflected.
# geometric.angleToDegrees(angle) · Source
Returns the result of converting an angle in radians to the same angle in degrees.
# geometric.angleToRadians(angle) · Source
Returns the result of converting an angle in degrees to the same angle in radians.