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mermaid

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Markdown-ish syntax for generating flowcharts, mindmaps, sequence diagrams, class diagrams, gantt charts, git graphs and more.

github.com/mermaid-js/mermaid

mermaid-js/mermaid

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JavaScript

import { getSubGraphTitleMargins } from "./chunk-SVWLYT5M.mjs"; import { createText, getIconSVG } from "./chunk-EECOFZZB.mjs"; import { calculateTextWidth, decodeEntities, handleUndefinedAttr, parseFontSize } from "./chunk-BF2ETNBY.mjs"; import { common_default, defaultConfig_default, evaluate, getConfig, getConfig2, hasKatex, log, parseGenericTypes, renderKatex, sanitizeText, sanitizeText2, select_default } from "./chunk-SSVL3WCV.mjs"; import { __name } from "./chunk-DLQEHMXD.mjs"; // src/rendering-util/rendering-elements/shapes/util.ts var labelHelper = /* @__PURE__ */ __name(async (parent, node, _classes) => { let cssClasses; const useHtmlLabels = node.useHtmlLabels || evaluate(getConfig2()?.htmlLabels); if (!_classes) { cssClasses = "node default"; } else { cssClasses = _classes; } const shapeSvg = parent.insert("g").attr("class", cssClasses).attr("id", node.domId || node.id); const labelEl = shapeSvg.insert("g").attr("class", "label").attr("style", handleUndefinedAttr(node.labelStyle)); let label; if (node.label === void 0) { label = ""; } else { label = typeof node.label === "string" ? node.label : node.label[0]; } const text2 = await createText(labelEl, sanitizeText(decodeEntities(label), getConfig2()), { useHtmlLabels, width: node.width || getConfig2().flowchart?.wrappingWidth, // @ts-expect-error -- This is currently not used. Should this be `classes` instead? cssClasses: "markdown-node-label", style: node.labelStyle, addSvgBackground: !!node.icon || !!node.img }); let bbox = text2.getBBox(); const halfPadding = (node?.padding ?? 0) / 2; if (useHtmlLabels) { const div = text2.children[0]; const dv = select_default(text2); const images = div.getElementsByTagName("img"); if (images) { const noImgText = label.replace(/<img[^>]*>/g, "").trim() === ""; await Promise.all( [...images].map( (img) => new Promise((res) => { function setupImage() { img.style.display = "flex"; img.style.flexDirection = "column"; if (noImgText) { const bodyFontSize = getConfig2().fontSize ? getConfig2().fontSize : window.getComputedStyle(document.body).fontSize; const enlargingFactor = 5; const [parsedBodyFontSize = defaultConfig_default.fontSize] = parseFontSize(bodyFontSize); const width = parsedBodyFontSize * enlargingFactor + "px"; img.style.minWidth = width; img.style.maxWidth = width; } else { img.style.width = "100%"; } res(img); } __name(setupImage, "setupImage"); setTimeout(() => { if (img.complete) { setupImage(); } }); img.addEventListener("error", setupImage); img.addEventListener("load", setupImage); }) ) ); } bbox = div.getBoundingClientRect(); dv.attr("width", bbox.width); dv.attr("height", bbox.height); } if (useHtmlLabels) { labelEl.attr("transform", "translate(" + -bbox.width / 2 + ", " + -bbox.height / 2 + ")"); } else { labelEl.attr("transform", "translate(0, " + -bbox.height / 2 + ")"); } if (node.centerLabel) { labelEl.attr("transform", "translate(" + -bbox.width / 2 + ", " + -bbox.height / 2 + ")"); } labelEl.insert("rect", ":first-child"); return { shapeSvg, bbox, halfPadding, label: labelEl }; }, "labelHelper"); var insertLabel = /* @__PURE__ */ __name(async (parent, label, options) => { const useHtmlLabels = options.useHtmlLabels || evaluate(getConfig2()?.flowchart?.htmlLabels); const labelEl = parent.insert("g").attr("class", "label").attr("style", options.labelStyle || ""); const text2 = await createText(labelEl, sanitizeText(decodeEntities(label), getConfig2()), { useHtmlLabels, width: options.width || getConfig2()?.flowchart?.wrappingWidth, style: options.labelStyle, addSvgBackground: !!options.icon || !!options.img }); let bbox = text2.getBBox(); const halfPadding = options.padding / 2; if (evaluate(getConfig2()?.flowchart?.htmlLabels)) { const div = text2.children[0]; const dv = select_default(text2); bbox = div.getBoundingClientRect(); dv.attr("width", bbox.width); dv.attr("height", bbox.height); } if (useHtmlLabels) { labelEl.attr("transform", "translate(" + -bbox.width / 2 + ", " + -bbox.height / 2 + ")"); } else { labelEl.attr("transform", "translate(0, " + -bbox.height / 2 + ")"); } if (options.centerLabel) { labelEl.attr("transform", "translate(" + -bbox.width / 2 + ", " + -bbox.height / 2 + ")"); } labelEl.insert("rect", ":first-child"); return { shapeSvg: parent, bbox, halfPadding, label: labelEl }; }, "insertLabel"); var updateNodeBounds = /* @__PURE__ */ __name((node, element) => { const bbox = element.node().getBBox(); node.width = bbox.width; node.height = bbox.height; }, "updateNodeBounds"); var getNodeClasses = /* @__PURE__ */ __name((node, extra) => (node.look === "handDrawn" ? "rough-node" : "node") + " " + node.cssClasses + " " + (extra || ""), "getNodeClasses"); function createPathFromPoints(points) { const pointStrings = points.map((p2, i2) => `${i2 === 0 ? "M" : "L"}${p2.x},${p2.y}`); pointStrings.push("Z"); return pointStrings.join(" "); } __name(createPathFromPoints, "createPathFromPoints"); function generateFullSineWavePoints(x1, y1, x2, y2, amplitude, numCycles) { const points = []; const steps = 50; const deltaX = x2 - x1; const deltaY = y2 - y1; const cycleLength = deltaX / numCycles; const frequency = 2 * Math.PI / cycleLength; const midY = y1 + deltaY / 2; for (let i2 = 0; i2 <= steps; i2++) { const t2 = i2 / steps; const x3 = x1 + t2 * deltaX; const y3 = midY + amplitude * Math.sin(frequency * (x3 - x1)); points.push({ x: x3, y: y3 }); } return points; } __name(generateFullSineWavePoints, "generateFullSineWavePoints"); function generateCirclePoints(centerX, centerY, radius, numPoints, startAngle, endAngle) { const points = []; const startAngleRad = startAngle * Math.PI / 180; const endAngleRad = endAngle * Math.PI / 180; const angleRange = endAngleRad - startAngleRad; const angleStep = angleRange / (numPoints - 1); for (let i2 = 0; i2 < numPoints; i2++) { const angle = startAngleRad + i2 * angleStep; const x2 = centerX + radius * Math.cos(angle); const y2 = centerY + radius * Math.sin(angle); points.push({ x: -x2, y: -y2 }); } return points; } __name(generateCirclePoints, "generateCirclePoints"); // ../../node_modules/.pnpm/roughjs@4.6.6_patch_hash=3543d47108cb41b68ec6a671c0e1f9d0cfe2ce524fea5b0992511ae84c3c6b64/node_modules/roughjs/bundled/rough.esm.js function t(t2, e2, s2) { if (t2 && t2.length) { const [n2, o2] = e2, a2 = Math.PI / 180 * s2, h2 = Math.cos(a2), r2 = Math.sin(a2); for (const e3 of t2) { const [t3, s3] = e3; e3[0] = (t3 - n2) * h2 - (s3 - o2) * r2 + n2, e3[1] = (t3 - n2) * r2 + (s3 - o2) * h2 + o2; } } } __name(t, "t"); function e(t2, e2) { return t2[0] === e2[0] && t2[1] === e2[1]; } __name(e, "e"); function s(s2, n2, o2, a2 = 1) { const h2 = o2, r2 = Math.max(n2, 0.1), i2 = s2[0] && s2[0][0] && "number" == typeof s2[0][0] ? [s2] : s2, c2 = [0, 0]; if (h2) for (const e2 of i2) t(e2, c2, h2); const l2 = function(t2, s3, n3) { const o3 = []; for (const s4 of t2) { const t3 = [...s4]; e(t3[0], t3[t3.length - 1]) || t3.push([t3[0][0], t3[0][1]]), t3.length > 2 && o3.push(t3); } const a3 = []; s3 = Math.max(s3, 0.1); const h3 = []; for (const t3 of o3) for (let e2 = 0; e2 < t3.length - 1; e2++) { const s4 = t3[e2], n4 = t3[e2 + 1]; if (s4[1] !== n4[1]) { const t4 = Math.min(s4[1], n4[1]); h3.push({ ymin: t4, ymax: Math.max(s4[1], n4[1]), x: t4 === s4[1] ? s4[0] : n4[0], islope: (n4[0] - s4[0]) / (n4[1] - s4[1]) }); } } if (h3.sort((t3, e2) => t3.ymin < e2.ymin ? -1 : t3.ymin > e2.ymin ? 1 : t3.x < e2.x ? -1 : t3.x > e2.x ? 1 : t3.ymax === e2.ymax ? 0 : (t3.ymax - e2.ymax) / Math.abs(t3.ymax - e2.ymax)), !h3.length) return a3; let r3 = [], i3 = h3[0].ymin, c3 = 0; for (; r3.length || h3.length; ) { if (h3.length) { let t3 = -1; for (let e2 = 0; e2 < h3.length && !(h3[e2].ymin > i3); e2++) t3 = e2; h3.splice(0, t3 + 1).forEach((t4) => { r3.push({ s: i3, edge: t4 }); }); } if (r3 = r3.filter((t3) => !(t3.edge.ymax <= i3)), r3.sort((t3, e2) => t3.edge.x === e2.edge.x ? 0 : (t3.edge.x - e2.edge.x) / Math.abs(t3.edge.x - e2.edge.x)), (1 !== n3 || c3 % s3 == 0) && r3.length > 1) for (let t3 = 0; t3 < r3.length; t3 += 2) { const e2 = t3 + 1; if (e2 >= r3.length) break; const s4 = r3[t3].edge, n4 = r3[e2].edge; a3.push([[Math.round(s4.x), i3], [Math.round(n4.x), i3]]); } i3 += n3, r3.forEach((t3) => { t3.edge.x = t3.edge.x + n3 * t3.edge.islope; }), c3++; } return a3; }(i2, r2, a2); if (h2) { for (const e2 of i2) t(e2, c2, -h2); !function(e2, s3, n3) { const o3 = []; e2.forEach((t2) => o3.push(...t2)), t(o3, s3, n3); }(l2, c2, -h2); } return l2; } __name(s, "s"); function n(t2, e2) { var n2; const o2 = e2.hachureAngle + 90; let a2 = e2.hachureGap; a2 < 0 && (a2 = 4 * e2.strokeWidth), a2 = Math.round(Math.max(a2, 0.1)); let h2 = 1; return e2.roughness >= 1 && ((null === (n2 = e2.randomizer) || void 0 === n2 ? void 0 : n2.next()) || Math.random()) > 0.7 && (h2 = a2), s(t2, a2, o2, h2 || 1); } __name(n, "n"); var o = class { static { __name(this, "o"); } constructor(t2) { this.helper = t2; } fillPolygons(t2, e2) { return this._fillPolygons(t2, e2); } _fillPolygons(t2, e2) { const s2 = n(t2, e2); return { type: "fillSketch", ops: this.renderLines(s2, e2) }; } renderLines(t2, e2) { const s2 = []; for (const n2 of t2) s2.push(...this.helper.doubleLineOps(n2[0][0], n2[0][1], n2[1][0], n2[1][1], e2)); return s2; } }; function a(t2) { const e2 = t2[0], s2 = t2[1]; return Math.sqrt(Math.pow(e2[0] - s2[0], 2) + Math.pow(e2[1] - s2[1], 2)); } __name(a, "a"); var h = class extends o { static { __name(this, "h"); } fillPolygons(t2, e2) { let s2 = e2.hachureGap; s2 < 0 && (s2 = 4 * e2.strokeWidth), s2 = Math.max(s2, 0.1); const o2 = n(t2, Object.assign({}, e2, { hachureGap: s2 })), h2 = Math.PI / 180 * e2.hachureAngle, r2 = [], i2 = 0.5 * s2 * Math.cos(h2), c2 = 0.5 * s2 * Math.sin(h2); for (const [t3, e3] of o2) a([t3, e3]) && r2.push([[t3[0] - i2, t3[1] + c2], [...e3]], [[t3[0] + i2, t3[1] - c2], [...e3]]); return { type: "fillSketch", ops: this.renderLines(r2, e2) }; } }; var r = class extends o { static { __name(this, "r"); } fillPolygons(t2, e2) { const s2 = this._fillPolygons(t2, e2), n2 = Object.assign({}, e2, { hachureAngle: e2.hachureAngle + 90 }), o2 = this._fillPolygons(t2, n2); return s2.ops = s2.ops.concat(o2.ops), s2; } }; var i = class { static { __name(this, "i"); } constructor(t2) { this.helper = t2; } fillPolygons(t2, e2) { const s2 = n(t2, e2 = Object.assign({}, e2, { hachureAngle: 0 })); return this.dotsOnLines(s2, e2); } dotsOnLines(t2, e2) { const s2 = []; let n2 = e2.hachureGap; n2 < 0 && (n2 = 4 * e2.strokeWidth), n2 = Math.max(n2, 0.1); let o2 = e2.fillWeight; o2 < 0 && (o2 = e2.strokeWidth / 2); const h2 = n2 / 4; for (const r2 of t2) { const t3 = a(r2), i2 = t3 / n2, c2 = Math.ceil(i2) - 1, l2 = t3 - c2 * n2, u2 = (r2[0][0] + r2[1][0]) / 2 - n2 / 4, p2 = Math.min(r2[0][1], r2[1][1]); for (let t4 = 0; t4 < c2; t4++) { const a2 = p2 + l2 + t4 * n2, r3 = u2 - h2 + 2 * Math.random() * h2, i3 = a2 - h2 + 2 * Math.random() * h2, c3 = this.helper.ellipse(r3, i3, o2, o2, e2); s2.push(...c3.ops); } } return { type: "fillSketch", ops: s2 }; } }; var c = class { static { __name(this, "c"); } constructor(t2) { this.helper = t2; } fillPolygons(t2, e2) { const s2 = n(t2, e2); return { type: "fillSketch", ops: this.dashedLine(s2, e2) }; } dashedLine(t2, e2) { const s2 = e2.dashOffset < 0 ? e2.hachureGap < 0 ? 4 * e2.strokeWidth : e2.hachureGap : e2.dashOffset, n2 = e2.dashGap < 0 ? e2.hachureGap < 0 ? 4 * e2.strokeWidth : e2.hachureGap : e2.dashGap, o2 = []; return t2.forEach((t3) => { const h2 = a(t3), r2 = Math.floor(h2 / (s2 + n2)), i2 = (h2 + n2 - r2 * (s2 + n2)) / 2; let c2 = t3[0], l2 = t3[1]; c2[0] > l2[0] && (c2 = t3[1], l2 = t3[0]); const u2 = Math.atan((l2[1] - c2[1]) / (l2[0] - c2[0])); for (let t4 = 0; t4 < r2; t4++) { const a2 = t4 * (s2 + n2), h3 = a2 + s2, r3 = [c2[0] + a2 * Math.cos(u2) + i2 * Math.cos(u2), c2[1] + a2 * Math.sin(u2) + i2 * Math.sin(u2)], l3 = [c2[0] + h3 * Math.cos(u2) + i2 * Math.cos(u2), c2[1] + h3 * Math.sin(u2) + i2 * Math.sin(u2)]; o2.push(...this.helper.doubleLineOps(r3[0], r3[1], l3[0], l3[1], e2)); } }), o2; } }; var l = class { static { __name(this, "l"); } constructor(t2) { this.helper = t2; } fillPolygons(t2, e2) { const s2 = e2.hachureGap < 0 ? 4 * e2.strokeWidth : e2.hachureGap, o2 = e2.zigzagOffset < 0 ? s2 : e2.zigzagOffset, a2 = n(t2, e2 = Object.assign({}, e2, { hachureGap: s2 + o2 })); return { type: "fillSketch", ops: this.zigzagLines(a2, o2, e2) }; } zigzagLines(t2, e2, s2) { const n2 = []; return t2.forEach((t3) => { const o2 = a(t3), h2 = Math.round(o2 / (2 * e2)); let r2 = t3[0], i2 = t3[1]; r2[0] > i2[0] && (r2 = t3[1], i2 = t3[0]); const c2 = Math.atan((i2[1] - r2[1]) / (i2[0] - r2[0])); for (let t4 = 0; t4 < h2; t4++) { const o3 = 2 * t4 * e2, a2 = 2 * (t4 + 1) * e2, h3 = Math.sqrt(2 * Math.pow(e2, 2)), i3 = [r2[0] + o3 * Math.cos(c2), r2[1] + o3 * Math.sin(c2)], l2 = [r2[0] + a2 * Math.cos(c2), r2[1] + a2 * Math.sin(c2)], u2 = [i3[0] + h3 * Math.cos(c2 + Math.PI / 4), i3[1] + h3 * Math.sin(c2 + Math.PI / 4)]; n2.push(...this.helper.doubleLineOps(i3[0], i3[1], u2[0], u2[1], s2), ...this.helper.doubleLineOps(u2[0], u2[1], l2[0], l2[1], s2)); } }), n2; } }; var u = {}; var p = class { static { __name(this, "p"); } constructor(t2) { this.seed = t2; } next() { return this.seed ? (2 ** 31 - 1 & (this.seed = Math.imul(48271, this.seed))) / 2 ** 31 : Math.random(); } }; var f = 0; var d = 1; var g = 2; var M = { A: 7, a: 7, C: 6, c: 6, H: 1, h: 1, L: 2, l: 2, M: 2, m: 2, Q: 4, q: 4, S: 4, s: 4, T: 2, t: 2, V: 1, v: 1, Z: 0, z: 0 }; function k(t2, e2) { return t2.type === e2; } __name(k, "k"); function b(t2) { const e2 = [], s2 = function(t3) { const e3 = new Array(); for (; "" !== t3; ) if (t3.match(/^([ \t\r\n,]+)/)) t3 = t3.substr(RegExp.$1.length); else if (t3.match(/^([aAcChHlLmMqQsStTvVzZ])/)) e3[e3.length] = { type: f, text: RegExp.$1 }, t3 = t3.substr(RegExp.$1.length); else { if (!t3.match(/^(([-+]?[0-9]+(\.[0-9]*)?|[-+]?\.[0-9]+)([eE][-+]?[0-9]+)?)/)) return []; e3[e3.length] = { type: d, text: `${parseFloat(RegExp.$1)}` }, t3 = t3.substr(RegExp.$1.length); } return e3[e3.length] = { type: g, text: "" }, e3; }(t2); let n2 = "BOD", o2 = 0, a2 = s2[o2]; for (; !k(a2, g); ) { let h2 = 0; const r2 = []; if ("BOD" === n2) { if ("M" !== a2.text && "m" !== a2.text) return b("M0,0" + t2); o2++, h2 = M[a2.text], n2 = a2.text; } else k(a2, d) ? h2 = M[n2] : (o2++, h2 = M[a2.text], n2 = a2.text); if (!(o2 + h2 < s2.length)) throw new Error("Path data ended short"); for (let t3 = o2; t3 < o2 + h2; t3++) { const e3 = s2[t3]; if (!k(e3, d)) throw new Error("Param not a number: " + n2 + "," + e3.text); r2[r2.length] = +e3.text; } if ("number" != typeof M[n2]) throw new Error("Bad segment: " + n2); { const t3 = { key: n2, data: r2 }; e2.push(t3), o2 += h2, a2 = s2[o2], "M" === n2 && (n2 = "L"), "m" === n2 && (n2 = "l"); } } return e2; } __name(b, "b"); function y(t2) { let e2 = 0, s2 = 0, n2 = 0, o2 = 0; const a2 = []; for (const { key: h2, data: r2 } of t2) switch (h2) { case "M": a2.push({ key: "M", data: [...r2] }), [e2, s2] = r2, [n2, o2] = r2; break; case "m": e2 += r2[0], s2 += r2[1], a2.push({ key: "M", data: [e2, s2] }), n2 = e2, o2 = s2; break; case "L": a2.push({ key: "L", data: [...r2] }), [e2, s2] = r2; break; case "l": e2 += r2[0], s2 += r2[1], a2.push({ key: "L", data: [e2, s2] }); break; case "C": a2.push({ key: "C", data: [...r2] }), e2 = r2[4], s2 = r2[5]; break; case "c": { const t3 = r2.map((t4, n3) => n3 % 2 ? t4 + s2 : t4 + e2); a2.push({ key: "C", data: t3 }), e2 = t3[4], s2 = t3[5]; break; } case "Q": a2.push({ key: "Q", data: [...r2] }), e2 = r2[2], s2 = r2[3]; break; case "q": { const t3 = r2.map((t4, n3) => n3 % 2 ? t4 + s2 : t4 + e2); a2.push({ key: "Q", data: t3 }), e2 = t3[2], s2 = t3[3]; break; } case "A": a2.push({ key: "A", data: [...r2] }), e2 = r2[5], s2 = r2[6]; break; case "a": e2 += r2[5], s2 += r2[6], a2.push({ key: "A", data: [r2[0], r2[1], r2[2], r2[3], r2[4], e2, s2] }); break; case "H": a2.push({ key: "H", data: [...r2] }), e2 = r2[0]; break; case "h": e2 += r2[0], a2.push({ key: "H", data: [e2] }); break; case "V": a2.push({ key: "V", data: [...r2] }), s2 = r2[0]; break; case "v": s2 += r2[0], a2.push({ key: "V", data: [s2] }); break; case "S": a2.push({ key: "S", data: [...r2] }), e2 = r2[2], s2 = r2[3]; break; case "s": { const t3 = r2.map((t4, n3) => n3 % 2 ? t4 + s2 : t4 + e2); a2.push({ key: "S", data: t3 }), e2 = t3[2], s2 = t3[3]; break; } case "T": a2.push({ key: "T", data: [...r2] }), e2 = r2[0], s2 = r2[1]; break; case "t": e2 += r2[0], s2 += r2[1], a2.push({ key: "T", data: [e2, s2] }); break; case "Z": case "z": a2.push({ key: "Z", data: [] }), e2 = n2, s2 = o2; } return a2; } __name(y, "y"); function m(t2) { const e2 = []; let s2 = "", n2 = 0, o2 = 0, a2 = 0, h2 = 0, r2 = 0, i2 = 0; for (const { key: c2, data: l2 } of t2) { switch (c2) { case "M": e2.push({ key: "M", data: [...l2] }), [n2, o2] = l2, [a2, h2] = l2; break; case "C": e2.push({ key: "C", data: [...l2] }), n2 = l2[4], o2 = l2[5], r2 = l2[2], i2 = l2[3]; break; case "L": e2.push({ key: "L", data: [...l2] }), [n2, o2] = l2; break; case "H": n2 = l2[0], e2.push({ key: "L", data: [n2, o2] }); break; case "V": o2 = l2[0], e2.push({ key: "L", data: [n2, o2] }); break; case "S": { let t3 = 0, a3 = 0; "C" === s2 || "S" === s2 ? (t3 = n2 + (n2 - r2), a3 = o2 + (o2 - i2)) : (t3 = n2, a3 = o2), e2.push({ key: "C", data: [t3, a3, ...l2] }), r2 = l2[0], i2 = l2[1], n2 = l2[2], o2 = l2[3]; break; } case "T": { const [t3, a3] = l2; let h3 = 0, c3 = 0; "Q" === s2 || "T" === s2 ? 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(o2.push({ op: "move", data: [t2[1][0], t2[1][1]] }), o2.push({ op: "bcurveTo", data: [t2[1][0], t2[1][1], t2[2][0], t2[2][1], t2[2][0], t2[2][1]] })) : 2 === n2 && o2.push(...R(t2[0][0], t2[0][1], t2[1][0], t2[1][1], s2, true, true)); return o2; } __name(q, "q"); function F(t2, e2, s2, n2, o2, a2, h2, r2) { const i2 = [], c2 = []; if (0 === r2.roughness) { t2 /= 4, c2.push([e2 + n2 * Math.cos(-t2), s2 + o2 * Math.sin(-t2)]); for (let a3 = 0; a3 <= 2 * Math.PI; a3 += t2) { const t3 = [e2 + n2 * Math.cos(a3), s2 + o2 * Math.sin(a3)]; i2.push(t3), c2.push(t3); } c2.push([e2 + n2 * Math.cos(0), s2 + o2 * Math.sin(0)]), c2.push([e2 + n2 * Math.cos(t2), s2 + o2 * Math.sin(t2)]); } else { const l2 = G(0.5, r2) - Math.PI / 2; c2.push([G(a2, r2) + e2 + 0.9 * n2 * Math.cos(l2 - t2), G(a2, r2) + s2 + 0.9 * o2 * Math.sin(l2 - t2)]); const u2 = 2 * Math.PI + l2 - 0.01; for (let h3 = l2; h3 < u2; h3 += t2) { const t3 = [G(a2, r2) + e2 + n2 * Math.cos(h3), G(a2, r2) + s2 + o2 * Math.sin(h3)]; i2.push(t3), c2.push(t3); } c2.push([G(a2, r2) + e2 + n2 * Math.cos(l2 + 2 * Math.PI + 0.5 * h2), G(a2, r2) + s2 + o2 * Math.sin(l2 + 2 * Math.PI + 0.5 * h2)]), c2.push([G(a2, r2) + e2 + 0.98 * n2 * Math.cos(l2 + h2), G(a2, r2) + s2 + 0.98 * o2 * Math.sin(l2 + h2)]), c2.push([G(a2, r2) + e2 + 0.9 * n2 * Math.cos(l2 + 0.5 * h2), G(a2, r2) + s2 + 0.9 * o2 * Math.sin(l2 + 0.5 * h2)]); } return [c2, i2]; } __name(F, "F"); function V(t2, e2, s2, n2, o2, a2, h2, r2, i2) { const c2 = a2 + G(0.1, i2), l2 = []; l2.push([G(r2, i2) + e2 + 0.9 * n2 * Math.cos(c2 - t2), G(r2, i2) + s2 + 0.9 * o2 * Math.sin(c2 - t2)]); for (let a3 = c2; a3 <= h2; a3 += t2) l2.push([G(r2, i2) + e2 + n2 * Math.cos(a3), G(r2, i2) + s2 + o2 * Math.sin(a3)]); return l2.push([e2 + n2 * Math.cos(h2), s2 + o2 * Math.sin(h2)]), l2.push([e2 + n2 * Math.cos(h2), s2 + o2 * Math.sin(h2)]), q(l2, null, i2); } __name(V, "V"); function Z(t2, e2, s2, n2, o2, a2, h2, r2) { const i2 = [], c2 = [r2.maxRandomnessOffset || 1, (r2.maxRandomnessOffset || 1) + 0.3]; let l2 = [0, 0]; const u2 = r2.disableMultiStroke ? 1 : 2, p2 = r2.preserveVertices; for (let f2 = 0; f2 < u2; f2++) 0 === f2 ? i2.push({ op: "move", data: [h2[0], h2[1]] }) : i2.push({ op: "move", data: [h2[0] + (p2 ? 0 : G(c2[0], r2)), h2[1] + (p2 ? 0 : G(c2[0], r2))] }), l2 = p2 ? [o2, a2] : [o2 + G(c2[f2], r2), a2 + G(c2[f2], r2)], i2.push({ op: "bcurveTo", data: [t2 + G(c2[f2], r2), e2 + G(c2[f2], r2), s2 + G(c2[f2], r2), n2 + G(c2[f2], r2), l2[0], l2[1]] }); return i2; } __name(Z, "Z"); function Q(t2) { return [...t2]; } __name(Q, "Q"); function H(t2, e2 = 0) { const s2 = t2.length; if (s2 < 3) throw new Error("A curve must have at least three points."); const n2 = []; if (3 === s2) n2.push(Q(t2[0]), Q(t2[1]), Q(t2[2]), Q(t2[2])); else { const s3 = []; s3.push(t2[0], t2[0]); for (let e3 = 1; e3 < t2.length; e3++) s3.push(t2[e3]), e3 === t2.length - 1 && s3.push(t2[e3]); const o2 = [], a2 = 1 - e2; n2.push(Q(s3[0])); for (let t3 = 1; t3 + 2 < s3.length; t3++) { const e3 = s3[t3]; o2[0] = [e3[0], e3[1]], o2[1] = [e3[0] + (a2 * s3[t3 + 1][0] - a2 * s3[t3 - 1][0]) / 6, e3[1] + (a2 * s3[t3 + 1][1] - a2 * s3[t3 - 1][1]) / 6], o2[2] = [s3[t3 + 1][0] + (a2 * s3[t3][0] - a2 * s3[t3 + 2][0]) / 6, s3[t3 + 1][1] + (a2 * s3[t3][1] - a2 * s3[t3 + 2][1]) / 6], o2[3] = [s3[t3 + 1][0], s3[t3 + 1][1]], n2.push(o2[1], o2[2], o2[3]); } } return n2; } __name(H, "H"); function N(t2, e2) { return Math.pow(t2[0] - e2[0], 2) + Math.pow(t2[1] - e2[1], 2); } __name(N, "N"); function B(t2, e2, s2) { const n2 = N(e2, s2); if (0 === n2) return N(t2, e2); let o2 = ((t2[0] - e2[0]) * (s2[0] - e2[0]) + (t2[1] - e2[1]) * (s2[1] - e2[1])) / n2; return o2 = Math.max(0, Math.min(1, o2)), N(t2, J(e2, s2, o2)); } __name(B, "B"); function J(t2, e2, s2) { return [t2[0] + (e2[0] - t2[0]) * s2, t2[1] + (e2[1] - t2[1]) * s2]; } __name(J, "J"); function K(t2, e2, s2, n2) { const o2 = n2 || []; if (function(t3, e3) { const s3 = t3[e3 + 0], n3 = t3[e3 + 1], o3 = t3[e3 + 2], a3 = t3[e3 + 3]; let h3 = 3 * n3[0] - 2 * s3[0] - a3[0]; h3 *= h3; let r2 = 3 * n3[1] - 2 * s3[1] - a3[1]; r2 *= r2; let i2 = 3 * o3[0] - 2 * a3[0] - s3[0]; i2 *= i2; let c2 = 3 * o3[1] - 2 * a3[1] - s3[1]; return c2 *= c2, h3 < i2 && (h3 = i2), r2 < c2 && (r2 = c2), h3 + r2; }(t2, e2) < s2) { const s3 = t2[e2 + 0]; if (o2.length) { (a2 = o2[o2.length - 1], h2 = s3, Math.sqrt(N(a2, h2))) > 1 && o2.push(s3); } else o2.push(s3); o2.push(t2[e2 + 3]); } else { const n3 = 0.5, a3 = t2[e2 + 0], h3 = t2[e2 + 1], r2 = t2[e2 + 2], i2 = t2[e2 + 3], c2 = J(a3, h3, n3), l2 = J(h3, r2, n3), u2 = J(r2, i2, n3), p2 = J(c2, l2, n3), f2 = J(l2, u2, n3), d2 = J(p2, f2, n3); K([a3, c2, p2, d2], 0, s2, o2), K([d2, f2, u2, i2], 0, s2, o2); } var a2, h2; return o2; } __name(K, "K"); function U(t2, e2) { return X(t2, 0, t2.length, e2); } __name(U, "U"); function X(t2, e2, s2, n2, o2) { const a2 = o2 || [], h2 = t2[e2], r2 = t2[s2 - 1]; let i2 = 0, c2 = 1; for (let n3 = e2 + 1; n3 < s2 - 1; ++n3) { const e3 = B(t2[n3], h2, r2); e3 > i2 && (i2 = e3, c2 = n3); } return Math.sqrt(i2) > n2 ? (X(t2, e2, c2 + 1, n2, a2), X(t2, c2, s2, n2, a2)) : (a2.length || a2.push(h2), a2.push(r2)), a2; } __name(X, "X"); function Y(t2, e2 = 0.15, s2) { const n2 = [], o2 = (t2.length - 1) / 3; for (let s3 = 0; s3 < o2; s3++) { K(t2, 3 * s3, e2, n2); } return s2 && s2 > 0 ? X(n2, 0, n2.length, s2) : n2; } __name(Y, "Y"); var tt = "none"; var et = class { static { __name(this, "et"); } constructor(t2) { this.defaultOptions = { maxRandomnessOffset: 2, roughness: 1, bowing: 1, stroke: "#000", strokeWidth: 1, curveTightness: 0, curveFitting: 0.95, curveStepCount: 9, fillStyle: "hachure", fillWeight: -1, hachureAngle: -41, hachureGap: -1, dashOffset: -1, dashGap: -1, zigzagOffset: -1, seed: 0, disableMultiStroke: false, disableMultiStrokeFill: false, preserveVertices: false, fillShapeRoughnessGain: 0.8 }, this.config = t2 || {}, this.config.options && (this.defaultOptions = this._o(this.config.options)); } static newSeed() { return Math.floor(Math.random() * 2 ** 31); } _o(t2) { return t2 ? Object.assign({}, this.defaultOptions, t2) : this.defaultOptions; } _d(t2, e2, s2) { return { shape: t2, sets: e2 || [], options: s2 || this.defaultOptions }; } line(t2, e2, s2, n2, o2) { const a2 = this._o(o2); return this._d("line", [v(t2, e2, s2, n2, a2)], a2); } rectangle(t2, e2, s2, n2, o2) { const a2 = this._o(o2), h2 = [], r2 = O(t2, e2, s2, n2, a2); if (a2.fill) { const o3 = [[t2, e2], [t2 + s2, e2], [t2 + s2, e2 + n2], [t2, e2 + n2]]; "solid" === a2.fillStyle ? h2.push(I([o3], a2)) : h2.push(C([o3], a2)); } return a2.stroke !== tt && h2.push(r2), this._d("rectangle", h2, a2); } ellipse(t2, e2, s2, n2, o2) { const a2 = this._o(o2), h2 = [], r2 = T(s2, n2, a2), i2 = D(t2, e2, a2, r2); if (a2.fill) if ("solid" === a2.fillStyle) { const s3 = D(t2, e2, a2, r2).opset; s3.type = "fillPath", h2.push(s3); } else h2.push(C([i2.estimatedPoints], a2)); return a2.stroke !== tt && h2.push(i2.opset), this._d("ellipse", h2, a2); } circle(t2, e2, s2, n2) { const o2 = this.ellipse(t2, e2, s2, s2, n2); return o2.shape = "circle", o2; } linearPath(t2, e2) { const s2 = this._o(e2); return this._d("linearPath", [S(t2, false, s2)], s2); } arc(t2, e2, s2, n2, o2, a2, h2 = false, r2) { const i2 = this._o(r2), c2 = [], l2 = A(t2, e2, s2, n2, o2, a2, h2, true, i2); if (h2 && i2.fill) if ("solid" === i2.fillStyle) { const h3 = Object.assign({}, i2); h3.disableMultiStroke = true; const r3 = A(t2, e2, s2, n2, o2, a2, true, false, h3); r3.type = "fillPath", c2.push(r3); } else c2.push(function(t3, e3, s3, n3, o3, a3, h3) { const r3 = t3, i3 = e3; let c3 = Math.abs(s3 / 2), l3 = Math.abs(n3 / 2); c3 += G(0.01 * c3, h3), l3 += G(0.01 * l3, h3); let u2 = o3, p2 = a3; for (; u2 < 0; ) u2 += 2 * Math.PI, p2 += 2 * Math.PI; p2 - u2 > 2 * Math.PI && (u2 = 0, p2 = 2 * Math.PI); const f2 = (p2 - u2) / h3.curveStepCount, d2 = []; for (let t4 = u2; t4 <= p2; t4 += f2) d2.push([r3 + c3 * Math.cos(t4), i3 + l3 * Math.sin(t4)]); return d2.push([r3 + c3 * Math.cos(p2), i3 + l3 * Math.sin(p2)]), d2.push([r3, i3]), C([d2], h3); }(t2, e2, s2, n2, o2, a2, i2)); return i2.stroke !== tt && c2.push(l2), this._d("arc", c2, i2); } curve(t2, e2) { const s2 = this._o(e2), n2 = [], o2 = L(t2, s2); if (s2.fill && s2.fill !== tt) if ("solid" === s2.fillStyle) { const e3 = L(t2, Object.assign(Object.assign({}, s2), { disableMultiStroke: true, roughness: s2.roughness ? s2.roughness + s2.fillShapeRoughnessGain : 0 })); n2.push({ type: "fillPath", ops: this._mergedShape(e3.ops) }); } else { const e3 = [], o3 = t2; if (o3.length) { const t3 = "number" == typeof o3[0][0] ? [o3] : o3; for (const n3 of t3) n3.length < 3 ? e3.push(...n3) : 3 === n3.length ? e3.push(...Y(H([n3[0], n3[0], n3[1], n3[2]]), 10, (1 + s2.roughness) / 2)) : e3.push(...Y(H(n3), 10, (1 + s2.roughness) / 2)); } e3.length && n2.push(C([e3], s2)); } return s2.stroke !== tt && n2.push(o2), this._d("curve", n2, s2); } polygon(t2, e2) { const s2 = this._o(e2), n2 = [], o2 = S(t2, true, s2); return s2.fill && ("solid" === s2.fillStyle ? n2.push(I([t2], s2)) : n2.push(C([t2], s2))), s2.stroke !== tt && n2.push(o2), this._d("polygon", n2, s2); } path(t2, e2) { const s2 = this._o(e2), n2 = []; if (!t2) return this._d("path", n2, s2); t2 = (t2 || "").replace(/\n/g, " ").replace(/(-\s)/g, "-").replace("/(ss)/g", " "); const o2 = s2.fill && "transparent" !== s2.fill && s2.fill !== tt, a2 = s2.stroke !== tt, h2 = !!(s2.simplification && s2.simplification < 1), r2 = function(t3, e3, s3) { const n3 = m(y(b(t3))), o3 = []; let a3 = [], h3 = [0, 0], r3 = []; const i3 = /* @__PURE__ */ __name(() => { r3.length >= 4 && a3.push(...Y(r3, e3)), r3 = []; }, "i"), c2 = /* @__PURE__ */ __name(() => { i3(), a3.length && (o3.push(a3), a3 = []); }, "c"); for (const { key: t4, data: e4 } of n3) switch (t4) { case "M": c2(), h3 = [e4[0], e4[1]], a3.push(h3); break; case "L": i3(), a3.push([e4[0], e4[1]]); break; case "C": if (!r3.length) { const t5 = a3.length ? a3[a3.length - 1] : h3; r3.push([t5[0], t5[1]]); } r3.push([e4[0], e4[1]]), r3.push([e4[2], e4[3]]), r3.push([e4[4], e4[5]]); break; case "Z": i3(), a3.push([h3[0], h3[1]]); } if (c2(), !s3) return o3; const l2 = []; for (const t4 of o3) { const e4 = U(t4, s3); e4.length && l2.push(e4); } return l2; }(t2, 1, h2 ? 4 - 4 * (s2.simplification || 1) : (1 + s2.roughness) / 2), i2 = _(t2, s2); if (o2) if ("solid" === s2.fillStyle) if (1 === r2.length) { const e3 = _(t2, Object.assign(Object.assign({}, s2), { disableMultiStroke: true, roughness: s2.roughness ? s2.roughness + s2.fillShapeRoughnessGain : 0 })); n2.push({ type: "fillPath", ops: this._mergedShape(e3.ops) }); } else n2.push(I(r2, s2)); else n2.push(C(r2, s2)); return a2 && (h2 ? r2.forEach((t3) => { n2.push(S(t3, false, s2)); }) : n2.push(i2)), this._d("path", n2, s2); } opsToPath(t2, e2) { let s2 = ""; for (const n2 of t2.ops) { const t3 = "number" == typeof e2 && e2 >= 0 ? n2.data.map((t4) => +t4.toFixed(e2)) : n2.data; switch (n2.op) { case "move": s2 += `M${t3[0]} ${t3[1]} `; break; case "bcurveTo": s2 += `C${t3[0]} ${t3[1]}, ${t3[2]} ${t3[3]}, ${t3[4]} ${t3[5]} `; break; case "lineTo": s2 += `L${t3[0]} ${t3[1]} `; } } return s2.trim(); } toPaths(t2) { const e2 = t2.sets || [], s2 = t2.options || this.defaultOptions, n2 = []; for (const t3 of e2) { let e3 = null; switch (t3.type) { case "path": e3 = { d: this.opsToPath(t3), stroke: s2.stroke, strokeWidth: s2.strokeWidth, fill: tt }; break; case "fillPath": e3 = { d: this.opsToPath(t3), stroke: tt, strokeWidth: 0, fill: s2.fill || tt }; break; case "fillSketch": e3 = this.fillSketch(t3, s2); } e3 && n2.push(e3); } return n2; } fillSketch(t2, e2) { let s2 = e2.fillWeight; return s2 < 0 && (s2 = e2.strokeWidth / 2), { d: this.opsToPath(t2), stroke: e2.fill || tt, strokeWidth: s2, fill: tt }; } _mergedShape(t2) { return t2.filter((t3, e2) => 0 === e2 || "move" !== t3.op); } }; var st = class { static { __name(this, "st"); } constructor(t2, e2) { this.canvas = t2, this.ctx = this.canvas.getContext("2d"), this.gen = new et(e2); } draw(t2) { const e2 = t2.sets || [], s2 = t2.options || this.getDefaultOptions(), n2 = this.ctx, o2 = t2.options.fixedDecimalPlaceDigits; for (const a2 of e2) switch (a2.type) { case "path": n2.save(), n2.strokeStyle = "none" === s2.stroke ? "transparent" : s2.stroke, n2.lineWidth = s2.strokeWidth, s2.strokeLineDash && n2.setLineDash(s2.strokeLineDash), s2.strokeLineDashOffset && (n2.lineDashOffset = s2.strokeLineDashOffset), this._drawToContext(n2, a2, o2), n2.restore(); break; case "fillPath": { n2.save(), n2.fillStyle = s2.fill || ""; const e3 = "curve" === t2.shape || "polygon" === t2.shape || "path" === t2.shape ? "evenodd" : "nonzero"; this._drawToContext(n2, a2, o2, e3), n2.restore(); break; } case "fillSketch": this.fillSketch(n2, a2, s2); } } fillSketch(t2, e2, s2) { let n2 = s2.fillWeight; n2 < 0 && (n2 = s2.strokeWidth / 2), t2.save(), s2.fillLineDash && t2.setLineDash(s2.fillLineDash), s2.fillLineDashOffset && (t2.lineDashOffset = s2.fillLineDashOffset), t2.strokeStyle = s2.fill || "", t2.lineWidth = n2, this._drawToContext(t2, e2, s2.fixedDecimalPlaceDigits), t2.restore(); } _drawToContext(t2, e2, s2, n2 = "nonzero") { t2.beginPath(); for (const n3 of e2.ops) { const e3 = "number" == typeof s2 && s2 >= 0 ? n3.data.map((t3) => +t3.toFixed(s2)) : n3.data; switch (n3.op) { case "move": t2.moveTo(e3[0], e3[1]); break; case "bcurveTo": t2.bezierCurveTo(e3[0], e3[1], e3[2], e3[3], e3[4], e3[5]); break; case "lineTo": t2.lineTo(e3[0], e3[1]); } } "fillPath" === e2.type ? t2.fill(n2) : t2.stroke(); } get generator() { return this.gen; } getDefaultOptions() { return this.gen.defaultOptions; } line(t2, e2, s2, n2, o2) { const a2 = this.gen.line(t2, e2, s2, n2, o2); return this.draw(a2), a2; } rectangle(t2, e2, s2, n2, o2) { const a2 = this.gen.rectangle(t2, e2, s2, n2, o2); return this.draw(a2), a2; } ellipse(t2, e2, s2, n2, o2) { const a2 = this.gen.ellipse(t2, e2, s2, n2, o2); return this.draw(a2), a2; } circle(t2, e2, s2, n2) { const o2 = this.gen.circle(t2, e2, s2, n2); return this.draw(o2), o2; } linearPath(t2, e2) { const s2 = this.gen.linearPath(t2, e2); return this.draw(s2), s2; } polygon(t2, e2) { const s2 = this.gen.polygon(t2, e2); return this.draw(s2), s2; } arc(t2, e2, s2, n2, o2, a2, h2 = false, r2) { const i2 = this.gen.arc(t2, e2, s2, n2, o2, a2, h2, r2); return this.draw(i2), i2; } curve(t2, e2) { const s2 = this.gen.curve(t2, e2); return this.draw(s2), s2; } path(t2, e2) { const s2 = this.gen.path(t2, e2); return this.draw(s2), s2; } }; var nt = "http://www.w3.org/2000/svg"; var ot = class { static { __name(this, "ot"); } constructor(t2, e2) { this.svg = t2, this.gen = new et(e2); } draw(t2) { const e2 = t2.sets || [], s2 = t2.options || this.getDefaultOptions(), n2 = this.svg.ownerDocument || window.document, o2 = n2.createElementNS(nt, "g"), a2 = t2.options.fixedDecimalPlaceDigits; for (const h2 of e2) { let e3 = null; switch (h2.type) { case "path": e3 = n2.createElementNS(nt, "path"), e3.setAttribute("d", this.opsToPath(h2, a2)), e3.setAttribute("stroke", s2.stroke), e3.setAttribute("stroke-width", s2.strokeWidth + ""), e3.setAttribute("fill", "none"), s2.strokeLineDash && e3.setAttribute("stroke-dasharray", s2.strokeLineDash.join(" ").trim()), s2.strokeLineDashOffset && e3.setAttribute("stroke-dashoffset", `${s2.strokeLineDashOffset}`); break; case "fillPath": e3 = n2.createElementNS(nt, "path"), e3.setAttribute("d", this.opsToPath(h2, a2)), e3.setAttribute("stroke", "none"), e3.setAttribute("stroke-width", "0"), e3.setAttribute("fill", s2.fill || ""), "curve" !== t2.shape && "polygon" !== t2.shape || e3.setAttribute("fill-rule", "evenodd"); break; case "fillSketch": e3 = this.fillSketch(n2, h2, s2); } e3 && o2.appendChild(e3); } return o2; } fillSketch(t2, e2, s2) { let n2 = s2.fillWeight; n2 < 0 && (n2 = s2.strokeWidth / 2); const o2 = t2.createElementNS(nt, "path"); return o2.setAttribute("d", this.opsToPath(e2, s2.fixedDecimalPlaceDigits)), o2.setAttribute("stroke", s2.fill || ""), o2.setAttribute("stroke-width", n2 + ""), o2.setAttribute("fill", "none"), s2.fillLineDash && o2.setAttribute("stroke-dasharray", s2.fillLineDash.join(" ").trim()), s2.fillLineDashOffset && o2.setAttribute("stroke-dashoffset", `${s2.fillLineDashOffset}`), o2; } get generator() { return this.gen; } getDefaultOptions() { return this.gen.defaultOptions; } opsToPath(t2, e2) { return this.gen.opsToPath(t2, e2); } line(t2, e2, s2, n2, o2) { const a2 = this.gen.line(t2, e2, s2, n2, o2); return this.draw(a2); } rectangle(t2, e2, s2, n2, o2) { const a2 = this.gen.rectangle(t2, e2, s2, n2, o2); return this.draw(a2); } ellipse(t2, e2, s2, n2, o2) { const a2 = this.gen.ellipse(t2, e2, s2, n2, o2);