mt-polygon-simplification/lib/simplify-js-alternative/simplify.js

// square distance between 2 points
function getSqDist(p1, p2) {

    var dx = p1[0] - p2[0],
        dy = p1[1] - p2[1];

    return dx * dx + dy * dy;
}

// square distance from a point to a segment
function getSqSegDist(p, p1, p2) {

    var x = p1[0],
        y = p1[1],
        dx = p2[0] - x,
        dy = p2[1] - y;

    if (dx !== 0 || dy !== 0) {

        var t = ((p[0] - x) * dx + (p[1] - y) * dy) / (dx * dx + dy * dy);

        if (t > 1) {
            x = p2[0];
            y = p2[1];

        } else if (t > 0) {
            x += dx * t;
            y += dy * t;
        }
    }

    dx = p[0] - x;
    dy = p[1] - y;

    return dx * dx + dy * dy;
}
// rest of the code doesn't care about point format

// basic distance-based simplification
function simplifyRadialDist(points, sqTolerance) {

    var prevPoint = points[0],
        newPoints = [prevPoint],
        point;

    for (var i = 1, len = points.length; i < len; i++) {
        point = points[i];

        if (getSqDist(point, prevPoint) > sqTolerance) {
            newPoints.push(point);
            prevPoint = point;
        }
    }

    if (prevPoint !== point) newPoints.push(point);

    return newPoints;
}

function simplifyDPStep(points, first, last, sqTolerance, simplified) {
    var maxSqDist = sqTolerance,
        index;

    for (var i = first + 1; i < last; i++) {
        var sqDist = getSqSegDist(points[i], points[first], points[last]);

        if (sqDist > maxSqDist) {
            index = i;
            maxSqDist = sqDist;
        }
    }

    if (maxSqDist > sqTolerance) {
        if (index - first > 1) simplifyDPStep(points, first, index, sqTolerance, simplified);
        simplified.push(points[index]);
        if (last - index > 1) simplifyDPStep(points, index, last, sqTolerance, simplified);
    }
}

// simplification using Ramer-Douglas-Peucker algorithm
function simplifyDouglasPeucker(points, sqTolerance) {
    var last = points.length - 1;

    var simplified = [points[0]];
    simplifyDPStep(points, 0, last, sqTolerance, simplified);
    simplified.push(points[last]);

    return simplified;
}

// both algorithms combined for awesome performance
export default function simplify(points, tolerance, highestQuality) {

    if (points.length <= 2) return points;

    var sqTolerance = tolerance !== undefined ? tolerance * tolerance : 1;

    points = highestQuality ? points : simplifyRadialDist(points, sqTolerance);
    points = simplifyDouglasPeucker(points, sqTolerance);

    return points;
}
initial commit 2019-07-14 20:37:26 +02:00			`// square distance between 2 points`
			`function getSqDist(p1, p2) {`

			`var dx = p1[0] - p2[0],`
			`dy = p1[1] - p2[1];`

			`return dx * dx + dy * dy;`
			`}`

			`// square distance from a point to a segment`
			`function getSqSegDist(p, p1, p2) {`

			`var x = p1[0],`
			`y = p1[1],`
			`dx = p2[0] - x,`
			`dy = p2[1] - y;`

			`if (dx !== 0 \|\| dy !== 0) {`

			`var t = ((p[0] - x) * dx + (p[1] - y) * dy) / (dx * dx + dy * dy);`

			`if (t > 1) {`
			`x = p2[0];`
			`y = p2[1];`

			`} else if (t > 0) {`
			`x += dx * t;`
			`y += dy * t;`
			`}`
			`}`

			`dx = p[0] - x;`
			`dy = p[1] - y;`

			`return dx * dx + dy * dy;`
			`}`
			`// rest of the code doesn't care about point format`

			`// basic distance-based simplification`
			`function simplifyRadialDist(points, sqTolerance) {`

			`var prevPoint = points[0],`
			`newPoints = [prevPoint],`
			`point;`

			`for (var i = 1, len = points.length; i < len; i++) {`
			`point = points[i];`

			`if (getSqDist(point, prevPoint) > sqTolerance) {`
			`newPoints.push(point);`
			`prevPoint = point;`
			`}`
			`}`

			`if (prevPoint !== point) newPoints.push(point);`

			`return newPoints;`
			`}`

			`function simplifyDPStep(points, first, last, sqTolerance, simplified) {`
			`var maxSqDist = sqTolerance,`
			`index;`

			`for (var i = first + 1; i < last; i++) {`
			`var sqDist = getSqSegDist(points[i], points[first], points[last]);`

			`if (sqDist > maxSqDist) {`
			`index = i;`
			`maxSqDist = sqDist;`
			`}`
			`}`

			`if (maxSqDist > sqTolerance) {`
			`if (index - first > 1) simplifyDPStep(points, first, index, sqTolerance, simplified);`
			`simplified.push(points[index]);`
			`if (last - index > 1) simplifyDPStep(points, index, last, sqTolerance, simplified);`
			`}`
			`}`

			`// simplification using Ramer-Douglas-Peucker algorithm`
			`function simplifyDouglasPeucker(points, sqTolerance) {`
			`var last = points.length - 1;`

			`var simplified = [points[0]];`
			`simplifyDPStep(points, 0, last, sqTolerance, simplified);`
			`simplified.push(points[last]);`

			`return simplified;`
			`}`

			`// both algorithms combined for awesome performance`
			`export default function simplify(points, tolerance, highestQuality) {`

			`if (points.length <= 2) return points;`

			`var sqTolerance = tolerance !== undefined ? tolerance * tolerance : 1;`

			`points = highestQuality ? points : simplifyRadialDist(points, sqTolerance);`
			`points = simplifyDouglasPeucker(points, sqTolerance);`

			`return points;`
			`}`