816 lines
21 KiB
JavaScript
816 lines
21 KiB
JavaScript
'use strict';
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/**
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* @typedef {import('../lib/types').XastElement} XastElement
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* @typedef {import('../lib/types').PathDataItem} PathDataItem
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*/
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const { parsePathData, stringifyPathData } = require('../lib/path.js');
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/**
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* @type {[number, number]}
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*/
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var prevCtrlPoint;
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/**
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* Convert path string to JS representation.
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*
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* @type {(path: XastElement) => Array<PathDataItem>}
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*/
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const path2js = (path) => {
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// @ts-ignore legacy
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if (path.pathJS) return path.pathJS;
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/**
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* @type {Array<PathDataItem>}
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*/
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const pathData = []; // JS representation of the path data
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const newPathData = parsePathData(path.attributes.d);
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for (const { command, args } of newPathData) {
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pathData.push({ command, args });
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}
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// First moveto is actually absolute. Subsequent coordinates were separated above.
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if (pathData.length && pathData[0].command == 'm') {
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pathData[0].command = 'M';
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}
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// @ts-ignore legacy
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path.pathJS = pathData;
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return pathData;
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};
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exports.path2js = path2js;
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/**
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* Convert relative Path data to absolute.
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*
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* @type {(data: Array<PathDataItem>) => Array<PathDataItem>}
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*
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*/
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const convertRelativeToAbsolute = (data) => {
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/**
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* @type {Array<PathDataItem>}
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*/
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const newData = [];
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let start = [0, 0];
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let cursor = [0, 0];
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for (let { command, args } of data) {
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args = args.slice();
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// moveto (x y)
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if (command === 'm') {
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args[0] += cursor[0];
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args[1] += cursor[1];
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command = 'M';
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}
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if (command === 'M') {
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cursor[0] = args[0];
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cursor[1] = args[1];
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start[0] = cursor[0];
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start[1] = cursor[1];
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}
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// horizontal lineto (x)
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if (command === 'h') {
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args[0] += cursor[0];
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command = 'H';
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}
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if (command === 'H') {
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cursor[0] = args[0];
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}
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// vertical lineto (y)
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if (command === 'v') {
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args[0] += cursor[1];
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command = 'V';
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}
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if (command === 'V') {
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cursor[1] = args[0];
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}
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// lineto (x y)
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if (command === 'l') {
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args[0] += cursor[0];
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args[1] += cursor[1];
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command = 'L';
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}
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if (command === 'L') {
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cursor[0] = args[0];
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cursor[1] = args[1];
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}
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// curveto (x1 y1 x2 y2 x y)
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if (command === 'c') {
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args[0] += cursor[0];
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args[1] += cursor[1];
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args[2] += cursor[0];
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args[3] += cursor[1];
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args[4] += cursor[0];
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args[5] += cursor[1];
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command = 'C';
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}
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if (command === 'C') {
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cursor[0] = args[4];
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cursor[1] = args[5];
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}
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// smooth curveto (x2 y2 x y)
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if (command === 's') {
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args[0] += cursor[0];
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args[1] += cursor[1];
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args[2] += cursor[0];
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args[3] += cursor[1];
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command = 'S';
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}
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if (command === 'S') {
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cursor[0] = args[2];
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cursor[1] = args[3];
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}
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// quadratic Bézier curveto (x1 y1 x y)
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if (command === 'q') {
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args[0] += cursor[0];
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args[1] += cursor[1];
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args[2] += cursor[0];
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args[3] += cursor[1];
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command = 'Q';
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}
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if (command === 'Q') {
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cursor[0] = args[2];
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cursor[1] = args[3];
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}
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// smooth quadratic Bézier curveto (x y)
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if (command === 't') {
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args[0] += cursor[0];
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args[1] += cursor[1];
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command = 'T';
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}
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if (command === 'T') {
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cursor[0] = args[0];
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cursor[1] = args[1];
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}
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// elliptical arc (rx ry x-axis-rotation large-arc-flag sweep-flag x y)
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if (command === 'a') {
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args[5] += cursor[0];
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args[6] += cursor[1];
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command = 'A';
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}
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if (command === 'A') {
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cursor[0] = args[5];
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cursor[1] = args[6];
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}
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// closepath
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if (command === 'z' || command === 'Z') {
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cursor[0] = start[0];
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cursor[1] = start[1];
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command = 'z';
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}
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newData.push({ command, args });
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}
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return newData;
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};
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/**
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* @typedef {{ floatPrecision?: number, noSpaceAfterFlags?: boolean }} Js2PathParams
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*/
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/**
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* Convert path array to string.
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*
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* @type {(path: XastElement, data: Array<PathDataItem>, params: Js2PathParams) => void}
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*/
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exports.js2path = function (path, data, params) {
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// @ts-ignore legacy
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path.pathJS = data;
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const pathData = [];
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for (const item of data) {
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// remove moveto commands which are followed by moveto commands
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if (
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pathData.length !== 0 &&
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(item.command === 'M' || item.command === 'm')
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) {
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const last = pathData[pathData.length - 1];
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if (last.command === 'M' || last.command === 'm') {
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pathData.pop();
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}
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}
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pathData.push({
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command: item.command,
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args: item.args,
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});
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}
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path.attributes.d = stringifyPathData({
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pathData,
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precision: params.floatPrecision,
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disableSpaceAfterFlags: params.noSpaceAfterFlags,
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});
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};
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/**
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* @type {(dest: Array<number>, source: Array<number>) => Array<number>}
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*/
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function set(dest, source) {
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dest[0] = source[source.length - 2];
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dest[1] = source[source.length - 1];
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return dest;
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}
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/**
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* Checks if two paths have an intersection by checking convex hulls
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* collision using Gilbert-Johnson-Keerthi distance algorithm
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* https://web.archive.org/web/20180822200027/http://entropyinteractive.com/2011/04/gjk-algorithm/
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*
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* @type {(path1: Array<PathDataItem>, path2: Array<PathDataItem>) => boolean}
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*/
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exports.intersects = function (path1, path2) {
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// Collect points of every subpath.
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const points1 = gatherPoints(convertRelativeToAbsolute(path1));
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const points2 = gatherPoints(convertRelativeToAbsolute(path2));
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// Axis-aligned bounding box check.
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if (
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points1.maxX <= points2.minX ||
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points2.maxX <= points1.minX ||
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points1.maxY <= points2.minY ||
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points2.maxY <= points1.minY ||
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points1.list.every((set1) => {
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return points2.list.every((set2) => {
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return (
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set1.list[set1.maxX][0] <= set2.list[set2.minX][0] ||
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set2.list[set2.maxX][0] <= set1.list[set1.minX][0] ||
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set1.list[set1.maxY][1] <= set2.list[set2.minY][1] ||
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set2.list[set2.maxY][1] <= set1.list[set1.minY][1]
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);
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});
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})
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)
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return false;
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// Get a convex hull from points of each subpath. Has the most complexity O(n·log n).
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const hullNest1 = points1.list.map(convexHull);
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const hullNest2 = points2.list.map(convexHull);
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// Check intersection of every subpath of the first path with every subpath of the second.
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return hullNest1.some(function (hull1) {
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if (hull1.list.length < 3) return false;
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return hullNest2.some(function (hull2) {
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if (hull2.list.length < 3) return false;
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var simplex = [getSupport(hull1, hull2, [1, 0])], // create the initial simplex
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direction = minus(simplex[0]); // set the direction to point towards the origin
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var iterations = 1e4; // infinite loop protection, 10 000 iterations is more than enough
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// eslint-disable-next-line no-constant-condition
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while (true) {
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// eslint-disable-next-line no-constant-condition
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if (iterations-- == 0) {
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console.error(
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'Error: infinite loop while processing mergePaths plugin.'
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);
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return true; // true is the safe value that means “do nothing with paths”
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}
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// add a new point
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simplex.push(getSupport(hull1, hull2, direction));
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// see if the new point was on the correct side of the origin
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if (dot(direction, simplex[simplex.length - 1]) <= 0) return false;
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// process the simplex
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if (processSimplex(simplex, direction)) return true;
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}
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});
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});
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/**
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* @type {(a: Point, b: Point, direction: Array<number>) => Array<number>}
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*/
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function getSupport(a, b, direction) {
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return sub(supportPoint(a, direction), supportPoint(b, minus(direction)));
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}
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// Computes farthest polygon point in particular direction.
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// Thanks to knowledge of min/max x and y coordinates we can choose a quadrant to search in.
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// Since we're working on convex hull, the dot product is increasing until we find the farthest point.
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/**
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* @type {(polygon: Point, direction: Array<number>) => Array<number>}
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*/
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function supportPoint(polygon, direction) {
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var index =
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direction[1] >= 0
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? direction[0] < 0
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? polygon.maxY
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: polygon.maxX
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: direction[0] < 0
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? polygon.minX
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: polygon.minY,
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max = -Infinity,
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value;
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while ((value = dot(polygon.list[index], direction)) > max) {
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max = value;
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index = ++index % polygon.list.length;
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}
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return polygon.list[(index || polygon.list.length) - 1];
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}
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};
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/**
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* @type {(simplex: Array<Array<number>>, direction: Array<number>) => boolean}
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*/
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function processSimplex(simplex, direction) {
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// we only need to handle to 1-simplex and 2-simplex
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if (simplex.length == 2) {
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// 1-simplex
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let a = simplex[1],
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b = simplex[0],
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AO = minus(simplex[1]),
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AB = sub(b, a);
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// AO is in the same direction as AB
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if (dot(AO, AB) > 0) {
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// get the vector perpendicular to AB facing O
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set(direction, orth(AB, a));
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} else {
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set(direction, AO);
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// only A remains in the simplex
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simplex.shift();
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}
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} else {
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// 2-simplex
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let a = simplex[2], // [a, b, c] = simplex
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b = simplex[1],
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c = simplex[0],
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AB = sub(b, a),
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AC = sub(c, a),
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AO = minus(a),
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ACB = orth(AB, AC), // the vector perpendicular to AB facing away from C
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ABC = orth(AC, AB); // the vector perpendicular to AC facing away from B
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if (dot(ACB, AO) > 0) {
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if (dot(AB, AO) > 0) {
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// region 4
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set(direction, ACB);
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simplex.shift(); // simplex = [b, a]
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} else {
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// region 5
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set(direction, AO);
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simplex.splice(0, 2); // simplex = [a]
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}
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} else if (dot(ABC, AO) > 0) {
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if (dot(AC, AO) > 0) {
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// region 6
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set(direction, ABC);
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simplex.splice(1, 1); // simplex = [c, a]
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} else {
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// region 5 (again)
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set(direction, AO);
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simplex.splice(0, 2); // simplex = [a]
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}
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} // region 7
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else return true;
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}
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return false;
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}
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/**
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* @type {(v: Array<number>) => Array<number>}
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*/
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function minus(v) {
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return [-v[0], -v[1]];
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}
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/**
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* @type {(v1: Array<number>, v2: Array<number>) => Array<number>}
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*/
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function sub(v1, v2) {
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return [v1[0] - v2[0], v1[1] - v2[1]];
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}
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/**
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* @type {(v1: Array<number>, v2: Array<number>) => number}
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*/
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function dot(v1, v2) {
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return v1[0] * v2[0] + v1[1] * v2[1];
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}
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/**
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* @type {(v1: Array<number>, v2: Array<number>) => Array<number>}
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*/
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function orth(v, from) {
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var o = [-v[1], v[0]];
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return dot(o, minus(from)) < 0 ? minus(o) : o;
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}
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/**
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* @typedef {{
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* list: Array<Array<number>>,
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* minX: number,
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* minY: number,
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* maxX: number,
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* maxY: number
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* }} Point
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*/
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/**
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* @typedef {{
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* list: Array<Point>,
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* minX: number,
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* minY: number,
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* maxX: number,
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* maxY: number
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* }} Points
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*/
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/**
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* @type {(pathData: Array<PathDataItem>) => Points}
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*/
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function gatherPoints(pathData) {
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/**
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* @type {Points}
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*/
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const points = { list: [], minX: 0, minY: 0, maxX: 0, maxY: 0 };
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// Writes data about the extreme points on each axle
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/**
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* @type {(path: Point, point: Array<number>) => void}
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*/
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const addPoint = (path, point) => {
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if (!path.list.length || point[1] > path.list[path.maxY][1]) {
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path.maxY = path.list.length;
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points.maxY = points.list.length
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? Math.max(point[1], points.maxY)
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: point[1];
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}
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if (!path.list.length || point[0] > path.list[path.maxX][0]) {
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path.maxX = path.list.length;
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points.maxX = points.list.length
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? Math.max(point[0], points.maxX)
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: point[0];
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}
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if (!path.list.length || point[1] < path.list[path.minY][1]) {
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path.minY = path.list.length;
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points.minY = points.list.length
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? Math.min(point[1], points.minY)
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: point[1];
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}
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if (!path.list.length || point[0] < path.list[path.minX][0]) {
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path.minX = path.list.length;
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points.minX = points.list.length
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? Math.min(point[0], points.minX)
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: point[0];
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}
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path.list.push(point);
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};
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for (let i = 0; i < pathData.length; i += 1) {
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const pathDataItem = pathData[i];
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let subPath =
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points.list.length === 0
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? { list: [], minX: 0, minY: 0, maxX: 0, maxY: 0 }
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: points.list[points.list.length - 1];
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let prev = i === 0 ? null : pathData[i - 1];
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let basePoint =
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subPath.list.length === 0 ? null : subPath.list[subPath.list.length - 1];
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let data = pathDataItem.args;
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let ctrlPoint = basePoint;
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/**
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* @type {(n: number, i: number) => number}
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* TODO fix null hack
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*/
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const toAbsolute = (n, i) => n + (basePoint == null ? 0 : basePoint[i % 2]);
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switch (pathDataItem.command) {
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case 'M':
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subPath = { list: [], minX: 0, minY: 0, maxX: 0, maxY: 0 };
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points.list.push(subPath);
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break;
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case 'H':
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if (basePoint != null) {
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addPoint(subPath, [data[0], basePoint[1]]);
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}
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break;
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case 'V':
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if (basePoint != null) {
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addPoint(subPath, [basePoint[0], data[0]]);
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}
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break;
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case 'Q':
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addPoint(subPath, data.slice(0, 2));
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prevCtrlPoint = [data[2] - data[0], data[3] - data[1]]; // Save control point for shorthand
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break;
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case 'T':
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if (
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basePoint != null &&
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prev != null &&
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(prev.command == 'Q' || prev.command == 'T')
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) {
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ctrlPoint = [
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basePoint[0] + prevCtrlPoint[0],
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basePoint[1] + prevCtrlPoint[1],
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];
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addPoint(subPath, ctrlPoint);
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prevCtrlPoint = [data[0] - ctrlPoint[0], data[1] - ctrlPoint[1]];
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}
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break;
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case 'C':
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if (basePoint != null) {
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// Approximate quibic Bezier curve with middle points between control points
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addPoint(subPath, [
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0.5 * (basePoint[0] + data[0]),
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0.5 * (basePoint[1] + data[1]),
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]);
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}
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addPoint(subPath, [
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0.5 * (data[0] + data[2]),
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0.5 * (data[1] + data[3]),
|
|
]);
|
|
addPoint(subPath, [
|
|
0.5 * (data[2] + data[4]),
|
|
0.5 * (data[3] + data[5]),
|
|
]);
|
|
prevCtrlPoint = [data[4] - data[2], data[5] - data[3]]; // Save control point for shorthand
|
|
break;
|
|
|
|
case 'S':
|
|
if (
|
|
basePoint != null &&
|
|
prev != null &&
|
|
(prev.command == 'C' || prev.command == 'S')
|
|
) {
|
|
addPoint(subPath, [
|
|
basePoint[0] + 0.5 * prevCtrlPoint[0],
|
|
basePoint[1] + 0.5 * prevCtrlPoint[1],
|
|
]);
|
|
ctrlPoint = [
|
|
basePoint[0] + prevCtrlPoint[0],
|
|
basePoint[1] + prevCtrlPoint[1],
|
|
];
|
|
}
|
|
if (ctrlPoint != null) {
|
|
addPoint(subPath, [
|
|
0.5 * (ctrlPoint[0] + data[0]),
|
|
0.5 * (ctrlPoint[1] + data[1]),
|
|
]);
|
|
}
|
|
addPoint(subPath, [
|
|
0.5 * (data[0] + data[2]),
|
|
0.5 * (data[1] + data[3]),
|
|
]);
|
|
prevCtrlPoint = [data[2] - data[0], data[3] - data[1]];
|
|
break;
|
|
|
|
case 'A':
|
|
if (basePoint != null) {
|
|
// Convert the arc to bezier curves and use the same approximation
|
|
// @ts-ignore no idea what's going on here
|
|
var curves = a2c.apply(0, basePoint.concat(data));
|
|
for (
|
|
var cData;
|
|
(cData = curves.splice(0, 6).map(toAbsolute)).length;
|
|
|
|
) {
|
|
if (basePoint != null) {
|
|
addPoint(subPath, [
|
|
0.5 * (basePoint[0] + cData[0]),
|
|
0.5 * (basePoint[1] + cData[1]),
|
|
]);
|
|
}
|
|
addPoint(subPath, [
|
|
0.5 * (cData[0] + cData[2]),
|
|
0.5 * (cData[1] + cData[3]),
|
|
]);
|
|
addPoint(subPath, [
|
|
0.5 * (cData[2] + cData[4]),
|
|
0.5 * (cData[3] + cData[5]),
|
|
]);
|
|
if (curves.length) addPoint(subPath, (basePoint = cData.slice(-2)));
|
|
}
|
|
}
|
|
break;
|
|
}
|
|
|
|
// Save final command coordinates
|
|
if (data.length >= 2) addPoint(subPath, data.slice(-2));
|
|
}
|
|
|
|
return points;
|
|
}
|
|
|
|
/**
|
|
* Forms a convex hull from set of points of every subpath using monotone chain convex hull algorithm.
|
|
* https://en.wikibooks.org/wiki/Algorithm_Implementation/Geometry/Convex_hull/Monotone_chain
|
|
*
|
|
* @type {(points: Point) => Point}
|
|
*/
|
|
function convexHull(points) {
|
|
points.list.sort(function (a, b) {
|
|
return a[0] == b[0] ? a[1] - b[1] : a[0] - b[0];
|
|
});
|
|
|
|
var lower = [],
|
|
minY = 0,
|
|
bottom = 0;
|
|
for (let i = 0; i < points.list.length; i++) {
|
|
while (
|
|
lower.length >= 2 &&
|
|
cross(lower[lower.length - 2], lower[lower.length - 1], points.list[i]) <=
|
|
0
|
|
) {
|
|
lower.pop();
|
|
}
|
|
if (points.list[i][1] < points.list[minY][1]) {
|
|
minY = i;
|
|
bottom = lower.length;
|
|
}
|
|
lower.push(points.list[i]);
|
|
}
|
|
|
|
var upper = [],
|
|
maxY = points.list.length - 1,
|
|
top = 0;
|
|
for (let i = points.list.length; i--; ) {
|
|
while (
|
|
upper.length >= 2 &&
|
|
cross(upper[upper.length - 2], upper[upper.length - 1], points.list[i]) <=
|
|
0
|
|
) {
|
|
upper.pop();
|
|
}
|
|
if (points.list[i][1] > points.list[maxY][1]) {
|
|
maxY = i;
|
|
top = upper.length;
|
|
}
|
|
upper.push(points.list[i]);
|
|
}
|
|
|
|
// last points are equal to starting points of the other part
|
|
upper.pop();
|
|
lower.pop();
|
|
|
|
const hullList = lower.concat(upper);
|
|
|
|
/**
|
|
* @type {Point}
|
|
*/
|
|
const hull = {
|
|
list: hullList,
|
|
minX: 0, // by sorting
|
|
maxX: lower.length,
|
|
minY: bottom,
|
|
maxY: (lower.length + top) % hullList.length,
|
|
};
|
|
|
|
return hull;
|
|
}
|
|
|
|
/**
|
|
* @type {(o: Array<number>, a: Array<number>, b: Array<number>) => number}
|
|
*/
|
|
function cross(o, a, b) {
|
|
return (a[0] - o[0]) * (b[1] - o[1]) - (a[1] - o[1]) * (b[0] - o[0]);
|
|
}
|
|
|
|
/**
|
|
* Based on code from Snap.svg (Apache 2 license). http://snapsvg.io/
|
|
* Thanks to Dmitry Baranovskiy for his great work!
|
|
*
|
|
* @type {(
|
|
* x1: number,
|
|
* y1: number,
|
|
* rx: number,
|
|
* ry: number,
|
|
* angle: number,
|
|
* large_arc_flag: number,
|
|
* sweep_flag: number,
|
|
* x2: number,
|
|
* y2: number,
|
|
* recursive: Array<number>
|
|
* ) => Array<number>}
|
|
*/
|
|
const a2c = (
|
|
x1,
|
|
y1,
|
|
rx,
|
|
ry,
|
|
angle,
|
|
large_arc_flag,
|
|
sweep_flag,
|
|
x2,
|
|
y2,
|
|
recursive
|
|
) => {
|
|
// for more information of where this Math came from visit:
|
|
// https://www.w3.org/TR/SVG11/implnote.html#ArcImplementationNotes
|
|
const _120 = (Math.PI * 120) / 180;
|
|
const rad = (Math.PI / 180) * (+angle || 0);
|
|
/**
|
|
* @type {Array<number>}
|
|
*/
|
|
let res = [];
|
|
/**
|
|
* @type {(x: number, y: number, rad: number) => number}
|
|
*/
|
|
const rotateX = (x, y, rad) => {
|
|
return x * Math.cos(rad) - y * Math.sin(rad);
|
|
};
|
|
/**
|
|
* @type {(x: number, y: number, rad: number) => number}
|
|
*/
|
|
const rotateY = (x, y, rad) => {
|
|
return x * Math.sin(rad) + y * Math.cos(rad);
|
|
};
|
|
if (!recursive) {
|
|
x1 = rotateX(x1, y1, -rad);
|
|
y1 = rotateY(x1, y1, -rad);
|
|
x2 = rotateX(x2, y2, -rad);
|
|
y2 = rotateY(x2, y2, -rad);
|
|
var x = (x1 - x2) / 2,
|
|
y = (y1 - y2) / 2;
|
|
var h = (x * x) / (rx * rx) + (y * y) / (ry * ry);
|
|
if (h > 1) {
|
|
h = Math.sqrt(h);
|
|
rx = h * rx;
|
|
ry = h * ry;
|
|
}
|
|
var rx2 = rx * rx;
|
|
var ry2 = ry * ry;
|
|
var k =
|
|
(large_arc_flag == sweep_flag ? -1 : 1) *
|
|
Math.sqrt(
|
|
Math.abs(
|
|
(rx2 * ry2 - rx2 * y * y - ry2 * x * x) / (rx2 * y * y + ry2 * x * x)
|
|
)
|
|
);
|
|
var cx = (k * rx * y) / ry + (x1 + x2) / 2;
|
|
var cy = (k * -ry * x) / rx + (y1 + y2) / 2;
|
|
var f1 = Math.asin(Number(((y1 - cy) / ry).toFixed(9)));
|
|
var f2 = Math.asin(Number(((y2 - cy) / ry).toFixed(9)));
|
|
|
|
f1 = x1 < cx ? Math.PI - f1 : f1;
|
|
f2 = x2 < cx ? Math.PI - f2 : f2;
|
|
f1 < 0 && (f1 = Math.PI * 2 + f1);
|
|
f2 < 0 && (f2 = Math.PI * 2 + f2);
|
|
if (sweep_flag && f1 > f2) {
|
|
f1 = f1 - Math.PI * 2;
|
|
}
|
|
if (!sweep_flag && f2 > f1) {
|
|
f2 = f2 - Math.PI * 2;
|
|
}
|
|
} else {
|
|
f1 = recursive[0];
|
|
f2 = recursive[1];
|
|
cx = recursive[2];
|
|
cy = recursive[3];
|
|
}
|
|
var df = f2 - f1;
|
|
if (Math.abs(df) > _120) {
|
|
var f2old = f2,
|
|
x2old = x2,
|
|
y2old = y2;
|
|
f2 = f1 + _120 * (sweep_flag && f2 > f1 ? 1 : -1);
|
|
x2 = cx + rx * Math.cos(f2);
|
|
y2 = cy + ry * Math.sin(f2);
|
|
res = a2c(x2, y2, rx, ry, angle, 0, sweep_flag, x2old, y2old, [
|
|
f2,
|
|
f2old,
|
|
cx,
|
|
cy,
|
|
]);
|
|
}
|
|
df = f2 - f1;
|
|
var c1 = Math.cos(f1),
|
|
s1 = Math.sin(f1),
|
|
c2 = Math.cos(f2),
|
|
s2 = Math.sin(f2),
|
|
t = Math.tan(df / 4),
|
|
hx = (4 / 3) * rx * t,
|
|
hy = (4 / 3) * ry * t,
|
|
m = [
|
|
-hx * s1,
|
|
hy * c1,
|
|
x2 + hx * s2 - x1,
|
|
y2 - hy * c2 - y1,
|
|
x2 - x1,
|
|
y2 - y1,
|
|
];
|
|
if (recursive) {
|
|
return m.concat(res);
|
|
} else {
|
|
res = m.concat(res);
|
|
var newres = [];
|
|
for (var i = 0, n = res.length; i < n; i++) {
|
|
newres[i] =
|
|
i % 2
|
|
? rotateY(res[i - 1], res[i], rad)
|
|
: rotateX(res[i], res[i + 1], rad);
|
|
}
|
|
return newres;
|
|
}
|
|
};
|