import {
ExcalidrawElement,
ExcalidrawLinearElement,
Arrowhead,
ExcalidrawFreeDrawElement,
} from "./types";
import { distance2d, rotate } from "../math";
import rough from "roughjs/bin/rough";
import { Drawable, Op } from "roughjs/bin/core";
import { Point } from "../types";
import {
getShapeForElement,
generateRoughOptions,
} from "../renderer/renderElement";
import { isFreeDrawElement, isLinearElement } from "./typeChecks";
import { rescalePoints } from "../points";
// x and y position of top left corner, x and y position of bottom right corner
export type Bounds = readonly [number, number, number, number];
// If the element is created from right to left, the width is going to be negative
// This set of functions retrieves the absolute position of the 4 points.
export const getElementAbsoluteCoords = (
element: ExcalidrawElement,
): Bounds => {
if (isFreeDrawElement(element)) {
return getFreeDrawElementAbsoluteCoords(element);
} else if (isLinearElement(element)) {
return getLinearElementAbsoluteCoords(element);
}
return [
element.x,
element.y,
element.x + element.width,
element.y + element.height,
];
};
export const pointRelativeTo = (
element: ExcalidrawElement,
absoluteCoords: Point,
): Point => {
return [absoluteCoords[0] - element.x, absoluteCoords[1] - element.y];
};
export const getDiamondPoints = (element: ExcalidrawElement) => {
// Here we add +1 to avoid these numbers to be 0
// otherwise rough.js will throw an error complaining about it
const topX = Math.floor(element.width / 2) + 1;
const topY = 0;
const rightX = element.width;
const rightY = Math.floor(element.height / 2) + 1;
const bottomX = topX;
const bottomY = element.height;
const leftX = 0;
const leftY = rightY;
return [topX, topY, rightX, rightY, bottomX, bottomY, leftX, leftY];
};
export const getCurvePathOps = (shape: Drawable): Op[] => {
for (const set of shape.sets) {
if (set.type === "path") {
return set.ops;
}
}
return shape.sets[0].ops;
};
const getMinMaxXYFromCurvePathOps = (
ops: Op[],
transformXY?: (x: number, y: number) => [number, number],
): [number, number, number, number] => {
let currentP: Point = [0, 0];
const { minX, minY, maxX, maxY } = ops.reduce(
(limits, { op, data }) => {
// There are only four operation types:
// move, bcurveTo, lineTo, and curveTo
if (op === "move") {
// change starting point
currentP = (data as unknown) as Point;
// move operation does not draw anything; so, it always
// returns false
} else if (op === "bcurveTo") {
// create points from bezier curve
// bezier curve stores data as a flattened array of three positions
// [x1, y1, x2, y2, x3, y3]
const p1 = [data[0], data[1]] as Point;
const p2 = [data[2], data[3]] as Point;
const p3 = [data[4], data[5]] as Point;
const p0 = currentP;
currentP = p3;
const equation = (t: number, idx: number) =>
Math.pow(1 - t, 3) * p3[idx] +
3 * t * Math.pow(1 - t, 2) * p2[idx] +
3 * Math.pow(t, 2) * (1 - t) * p1[idx] +
p0[idx] * Math.pow(t, 3);
let t = 0;
while (t <= 1.0) {
let x = equation(t, 0);
let y = equation(t, 1);
if (transformXY) {
[x, y] = transformXY(x, y);
}
limits.minY = Math.min(limits.minY, y);
limits.minX = Math.min(limits.minX, x);
limits.maxX = Math.max(limits.maxX, x);
limits.maxY = Math.max(limits.maxY, y);
t += 0.1;
}
} else if (op === "lineTo") {
// TODO: Implement this
} else if (op === "qcurveTo") {
// TODO: Implement this
}
return limits;
},
{ minX: Infinity, minY: Infinity, maxX: -Infinity, maxY: -Infinity },
);
return [minX, minY, maxX, maxY];
};
const getBoundsFromPoints = (
points: ExcalidrawFreeDrawElement["points"],
): [number, number, number, number] => {
let minX = Infinity;
let minY = Infinity;
let maxX = -Infinity;
let maxY = -Infinity;
for (const [x, y] of points) {
minX = Math.min(minX, x);
minY = Math.min(minY, y);
maxX = Math.max(maxX, x);
maxY = Math.max(maxY, y);
}
return [minX, minY, maxX, maxY];
};
const getFreeDrawElementAbsoluteCoords = (
element: ExcalidrawFreeDrawElement,
): [number, number, number, number] => {
const [minX, minY, maxX, maxY] = getBoundsFromPoints(element.points);
return [
minX + element.x,
minY + element.y,
maxX + element.x,
maxY + element.y,
];
};
const getLinearElementAbsoluteCoords = (
element: ExcalidrawLinearElement,
): [number, number, number, number] => {
let coords: [number, number, number, number];
if (element.points.length < 2 || !getShapeForElement(element)) {
// XXX this is just a poor estimate and not very useful
const { minX, minY, maxX, maxY } = element.points.reduce(
(limits, [x, y]) => {
limits.minY = Math.min(limits.minY, y);
limits.minX = Math.min(limits.minX, x);
limits.maxX = Math.max(limits.maxX, x);
limits.maxY = Math.max(limits.maxY, y);
return limits;
},
{ minX: Infinity, minY: Infinity, maxX: -Infinity, maxY: -Infinity },
);
coords = [
minX + element.x,
minY + element.y,
maxX + element.x,
maxY + element.y,
];
} else {
const shape = getShapeForElement(element) as Drawable[];
// first element is always the curve
const ops = getCurvePathOps(shape[0]);
const [minX, minY, maxX, maxY] = getMinMaxXYFromCurvePathOps(ops);
coords = [
minX + element.x,
minY + element.y,
maxX + element.x,
maxY + element.y,
];
}
return coords;
};
export const getArrowheadPoints = (
element: ExcalidrawLinearElement,
shape: Drawable[],
position: "start" | "end",
arrowhead: Arrowhead,
) => {
const ops = getCurvePathOps(shape[0]);
if (ops.length < 1) {
return null;
}
// The index of the bCurve operation to examine.
const index = position === "start" ? 1 : ops.length - 1;
const data = ops[index].data;
const p3 = [data[4], data[5]] as Point;
const p2 = [data[2], data[3]] as Point;
const p1 = [data[0], data[1]] as Point;
// We need to find p0 of the bezier curve.
// It is typically the last point of the previous
// curve; it can also be the position of moveTo operation.
const prevOp = ops[index - 1];
let p0: Point = [0, 0];
if (prevOp.op === "move") {
p0 = (prevOp.data as unknown) as Point;
} else if (prevOp.op === "bcurveTo") {
p0 = [prevOp.data[4], prevOp.data[5]];
}
// B(t) = p0 * (1-t)^3 + 3p1 * t * (1-t)^2 + 3p2 * t^2 * (1-t) + p3 * t^3
const equation = (t: number, idx: number) =>
Math.pow(1 - t, 3) * p3[idx] +
3 * t * Math.pow(1 - t, 2) * p2[idx] +
3 * Math.pow(t, 2) * (1 - t) * p1[idx] +
p0[idx] * Math.pow(t, 3);
// Ee know the last point of the arrow (or the first, if start arrowhead).
const [x2, y2] = position === "start" ? p0 : p3;
// By using cubic bezier equation (B(t)) and the given parameters,
// we calculate a point that is closer to the last point.
// The value 0.3 is chosen arbitrarily and it works best for all
// the tested cases.
const [x1, y1] = [equation(0.3, 0), equation(0.3, 1)];
// Find the normalized direction vector based on the
// previously calculated points.
const distance = Math.hypot(x2 - x1, y2 - y1);
const nx = (x2 - x1) / distance;
const ny = (y2 - y1) / distance;
const size = {
arrow: 30,
bar: 15,
dot: 15,
}[arrowhead]; // pixels (will differ for each arrowhead)
const length = element.points.reduce((total, [cx, cy], idx, points) => {
const [px, py] = idx > 0 ? points[idx - 1] : [0, 0];
return total + Math.hypot(cx - px, cy - py);
}, 0);
// Scale down the arrowhead until we hit a certain size so that it doesn't look weird.
// This value is selected by minimizing a minimum size with the whole length of the
// arrowhead instead of last segment of the arrowhead.
const minSize = Math.min(size, length / 2);
const xs = x2 - nx * minSize;
const ys = y2 - ny * minSize;
if (arrowhead === "dot") {
const r = Math.hypot(ys - y2, xs - x2) + element.strokeWidth;
return [x2, y2, r];
}
const angle = {
arrow: 20,
bar: 90,
}[arrowhead]; // degrees
// Return points
const [x3, y3] = rotate(xs, ys, x2, y2, (-angle * Math.PI) / 180);
const [x4, y4] = rotate(xs, ys, x2, y2, (angle * Math.PI) / 180);
return [x2, y2, x3, y3, x4, y4];
};
const getLinearElementRotatedBounds = (
element: ExcalidrawLinearElement,
cx: number,
cy: number,
): [number, number, number, number] => {
if (element.points.length < 2 || !getShapeForElement(element)) {
// XXX this is just a poor estimate and not very useful
const { minX, minY, maxX, maxY } = element.points.reduce(
(limits, [x, y]) => {
[x, y] = rotate(element.x + x, element.y + y, cx, cy, element.angle);
limits.minY = Math.min(limits.minY, y);
limits.minX = Math.min(limits.minX, x);
limits.maxX = Math.max(limits.maxX, x);
limits.maxY = Math.max(limits.maxY, y);
return limits;
},
{ minX: Infinity, minY: Infinity, maxX: -Infinity, maxY: -Infinity },
);
return [minX, minY, maxX, maxY];
}
const shape = getShapeForElement(element) as Drawable[];
// first element is always the curve
const ops = getCurvePathOps(shape[0]);
const transformXY = (x: number, y: number) =>
rotate(element.x + x, element.y + y, cx, cy, element.angle);
return getMinMaxXYFromCurvePathOps(ops, transformXY);
};
// We could cache this stuff
export const getElementBounds = (
element: ExcalidrawElement,
): [number, number, number, number] => {
let bounds: [number, number, number, number];
const [x1, y1, x2, y2] = getElementAbsoluteCoords(element);
const cx = (x1 + x2) / 2;
const cy = (y1 + y2) / 2;
if (isFreeDrawElement(element)) {
const [minX, minY, maxX, maxY] = getBoundsFromPoints(
element.points.map(([x, y]) =>
rotate(x, y, cx - element.x, cy - element.y, element.angle),
),
);
return [
minX + element.x,
minY + element.y,
maxX + element.x,
maxY + element.y,
];
} else if (isLinearElement(element)) {
bounds = getLinearElementRotatedBounds(element, cx, cy);
} else if (element.type === "diamond") {
const [x11, y11] = rotate(cx, y1, cx, cy, element.angle);
const [x12, y12] = rotate(cx, y2, cx, cy, element.angle);
const [x22, y22] = rotate(x1, cy, cx, cy, element.angle);
const [x21, y21] = rotate(x2, cy, cx, cy, element.angle);
const minX = Math.min(x11, x12, x22, x21);
const minY = Math.min(y11, y12, y22, y21);
const maxX = Math.max(x11, x12, x22, x21);
const maxY = Math.max(y11, y12, y22, y21);
bounds = [minX, minY, maxX, maxY];
} else if (element.type === "ellipse") {
const w = (x2 - x1) / 2;
const h = (y2 - y1) / 2;
const cos = Math.cos(element.angle);
const sin = Math.sin(element.angle);
const ww = Math.hypot(w * cos, h * sin);
const hh = Math.hypot(h * cos, w * sin);
bounds = [cx - ww, cy - hh, cx + ww, cy + hh];
} else {
const [x11, y11] = rotate(x1, y1, cx, cy, element.angle);
const [x12, y12] = rotate(x1, y2, cx, cy, element.angle);
const [x22, y22] = rotate(x2, y2, cx, cy, element.angle);
const [x21, y21] = rotate(x2, y1, cx, cy, element.angle);
const minX = Math.min(x11, x12, x22, x21);
const minY = Math.min(y11, y12, y22, y21);
const maxX = Math.max(x11, x12, x22, x21);
const maxY = Math.max(y11, y12, y22, y21);
bounds = [minX, minY, maxX, maxY];
}
return bounds;
};
export const getCommonBounds = (
elements: readonly ExcalidrawElement[],
): [number, number, number, number] => {
if (!elements.length) {
return [0, 0, 0, 0];
}
let minX = Infinity;
let maxX = -Infinity;
let minY = Infinity;
let maxY = -Infinity;
elements.forEach((element) => {
const [x1, y1, x2, y2] = getElementBounds(element);
minX = Math.min(minX, x1);
minY = Math.min(minY, y1);
maxX = Math.max(maxX, x2);
maxY = Math.max(maxY, y2);
});
return [minX, minY, maxX, maxY];
};
export const getResizedElementAbsoluteCoords = (
element: ExcalidrawElement,
nextWidth: number,
nextHeight: number,
): [number, number, number, number] => {
if (!(isLinearElement(element) || isFreeDrawElement(element))) {
return [
element.x,
element.y,
element.x + nextWidth,
element.y + nextHeight,
];
}
const points = rescalePoints(
0,
nextWidth,
rescalePoints(1, nextHeight, element.points),
);
let bounds: [number, number, number, number];
if (isFreeDrawElement(element)) {
// Free Draw
bounds = getBoundsFromPoints(points);
} else {
// Line
const gen = rough.generator();
const curve =
element.strokeSharpness === "sharp"
? gen.linearPath(
points as [number, number][],
generateRoughOptions(element),
)
: gen.curve(
points as [number, number][],
generateRoughOptions(element),
);
const ops = getCurvePathOps(curve);
bounds = getMinMaxXYFromCurvePathOps(ops);
}
const [minX, minY, maxX, maxY] = bounds;
return [
minX + element.x,
minY + element.y,
maxX + element.x,
maxY + element.y,
];
};
export const getElementPointsCoords = (
element: ExcalidrawLinearElement,
points: readonly (readonly [number, number])[],
sharpness: ExcalidrawElement["strokeSharpness"],
): [number, number, number, number] => {
// This might be computationally heavey
const gen = rough.generator();
const curve =
sharpness === "sharp"
? gen.linearPath(
points as [number, number][],
generateRoughOptions(element),
)
: gen.curve(points as [number, number][], generateRoughOptions(element));
const ops = getCurvePathOps(curve);
const [minX, minY, maxX, maxY] = getMinMaxXYFromCurvePathOps(ops);
return [
minX + element.x,
minY + element.y,
maxX + element.x,
maxY + element.y,
];
};
export const getClosestElementBounds = (
elements: readonly ExcalidrawElement[],
from: { x: number; y: number },
): [number, number, number, number] => {
if (!elements.length) {
return [0, 0, 0, 0];
}
let minDistance = Infinity;
let closestElement = elements[0];
elements.forEach((element) => {
const [x1, y1, x2, y2] = getElementBounds(element);
const distance = distance2d((x1 + x2) / 2, (y1 + y2) / 2, from.x, from.y);
if (distance < minDistance) {
minDistance = distance;
closestElement = element;
}
});
return getElementBounds(closestElement);
};