File: //home/arjun/projects/propbase/propbase_website/node_modules/framer-motion/dist/cjs/client.js
'use strict';
Object.defineProperty(exports, '__esModule', { value: true });
var jsxRuntime = require('react/jsx-runtime');
var react = require('react');
function isAnimationControls(v) {
return (v !== null &&
typeof v === "object" &&
typeof v.start === "function");
}
const isKeyframesTarget = (v) => {
return Array.isArray(v);
};
function shallowCompare(next, prev) {
if (!Array.isArray(prev))
return false;
const prevLength = prev.length;
if (prevLength !== next.length)
return false;
for (let i = 0; i < prevLength; i++) {
if (prev[i] !== next[i])
return false;
}
return true;
}
/**
* Decides if the supplied variable is variant label
*/
function isVariantLabel(v) {
return typeof v === "string" || Array.isArray(v);
}
function getValueState(visualElement) {
const state = [{}, {}];
visualElement === null || visualElement === void 0 ? void 0 : visualElement.values.forEach((value, key) => {
state[0][key] = value.get();
state[1][key] = value.getVelocity();
});
return state;
}
function resolveVariantFromProps(props, definition, custom, visualElement) {
/**
* If the variant definition is a function, resolve.
*/
if (typeof definition === "function") {
const [current, velocity] = getValueState(visualElement);
definition = definition(custom !== undefined ? custom : props.custom, current, velocity);
}
/**
* If the variant definition is a variant label, or
* the function returned a variant label, resolve.
*/
if (typeof definition === "string") {
definition = props.variants && props.variants[definition];
}
/**
* At this point we've resolved both functions and variant labels,
* but the resolved variant label might itself have been a function.
* If so, resolve. This can only have returned a valid target object.
*/
if (typeof definition === "function") {
const [current, velocity] = getValueState(visualElement);
definition = definition(custom !== undefined ? custom : props.custom, current, velocity);
}
return definition;
}
function resolveVariant(visualElement, definition, custom) {
const props = visualElement.getProps();
return resolveVariantFromProps(props, definition, custom !== undefined ? custom : props.custom, visualElement);
}
const variantPriorityOrder = [
"animate",
"whileInView",
"whileFocus",
"whileHover",
"whileTap",
"whileDrag",
"exit",
];
const variantProps = ["initial", ...variantPriorityOrder];
/**
* Generate a list of every possible transform key.
*/
const transformPropOrder = [
"transformPerspective",
"x",
"y",
"z",
"translateX",
"translateY",
"translateZ",
"scale",
"scaleX",
"scaleY",
"rotate",
"rotateX",
"rotateY",
"rotateZ",
"skew",
"skewX",
"skewY",
];
/**
* A quick lookup for transform props.
*/
const transformProps = new Set(transformPropOrder);
/**
* Converts seconds to milliseconds
*
* @param seconds - Time in seconds.
* @return milliseconds - Converted time in milliseconds.
*/
const secondsToMilliseconds = (seconds) => seconds * 1000;
const millisecondsToSeconds = (milliseconds) => milliseconds / 1000;
const underDampedSpring = {
type: "spring",
stiffness: 500,
damping: 25,
restSpeed: 10,
};
const criticallyDampedSpring = (target) => ({
type: "spring",
stiffness: 550,
damping: target === 0 ? 2 * Math.sqrt(550) : 30,
restSpeed: 10,
});
const keyframesTransition = {
type: "keyframes",
duration: 0.8,
};
/**
* Default easing curve is a slightly shallower version of
* the default browser easing curve.
*/
const ease = {
type: "keyframes",
ease: [0.25, 0.1, 0.35, 1],
duration: 0.3,
};
const getDefaultTransition = (valueKey, { keyframes }) => {
if (keyframes.length > 2) {
return keyframesTransition;
}
else if (transformProps.has(valueKey)) {
return valueKey.startsWith("scale")
? criticallyDampedSpring(keyframes[1])
: underDampedSpring;
}
return ease;
};
function getValueTransition(transition, key) {
return transition
? transition[key] ||
transition["default"] ||
transition
: undefined;
}
const MotionGlobalConfig = {
skipAnimations: false,
useManualTiming: false,
};
const isNotNull = (value) => value !== null;
function getFinalKeyframe(keyframes, { repeat, repeatType = "loop" }, finalKeyframe) {
const resolvedKeyframes = keyframes.filter(isNotNull);
const index = repeat && repeatType !== "loop" && repeat % 2 === 1
? 0
: resolvedKeyframes.length - 1;
return !index || finalKeyframe === undefined
? resolvedKeyframes[index]
: finalKeyframe;
}
const noop = (any) => any;
function createRenderStep(runNextFrame) {
/**
* We create and reuse two queues, one to queue jobs for the current frame
* and one for the next. We reuse to avoid triggering GC after x frames.
*/
let thisFrame = new Set();
let nextFrame = new Set();
/**
* Track whether we're currently processing jobs in this step. This way
* we can decide whether to schedule new jobs for this frame or next.
*/
let isProcessing = false;
let flushNextFrame = false;
/**
* A set of processes which were marked keepAlive when scheduled.
*/
const toKeepAlive = new WeakSet();
let latestFrameData = {
delta: 0.0,
timestamp: 0.0,
isProcessing: false,
};
function triggerCallback(callback) {
if (toKeepAlive.has(callback)) {
step.schedule(callback);
runNextFrame();
}
callback(latestFrameData);
}
const step = {
/**
* Schedule a process to run on the next frame.
*/
schedule: (callback, keepAlive = false, immediate = false) => {
const addToCurrentFrame = immediate && isProcessing;
const queue = addToCurrentFrame ? thisFrame : nextFrame;
if (keepAlive)
toKeepAlive.add(callback);
if (!queue.has(callback))
queue.add(callback);
return callback;
},
/**
* Cancel the provided callback from running on the next frame.
*/
cancel: (callback) => {
nextFrame.delete(callback);
toKeepAlive.delete(callback);
},
/**
* Execute all schedule callbacks.
*/
process: (frameData) => {
latestFrameData = frameData;
/**
* If we're already processing we've probably been triggered by a flushSync
* inside an existing process. Instead of executing, mark flushNextFrame
* as true and ensure we flush the following frame at the end of this one.
*/
if (isProcessing) {
flushNextFrame = true;
return;
}
isProcessing = true;
[thisFrame, nextFrame] = [nextFrame, thisFrame];
// Clear the next frame queue
nextFrame.clear();
// Execute this frame
thisFrame.forEach(triggerCallback);
isProcessing = false;
if (flushNextFrame) {
flushNextFrame = false;
step.process(frameData);
}
},
};
return step;
}
const stepsOrder = [
"read", // Read
"resolveKeyframes", // Write/Read/Write/Read
"update", // Compute
"preRender", // Compute
"render", // Write
"postRender", // Compute
];
const maxElapsed = 40;
function createRenderBatcher(scheduleNextBatch, allowKeepAlive) {
let runNextFrame = false;
let useDefaultElapsed = true;
const state = {
delta: 0.0,
timestamp: 0.0,
isProcessing: false,
};
const flagRunNextFrame = () => (runNextFrame = true);
const steps = stepsOrder.reduce((acc, key) => {
acc[key] = createRenderStep(flagRunNextFrame);
return acc;
}, {});
const { read, resolveKeyframes, update, preRender, render, postRender } = steps;
const processBatch = () => {
const timestamp = performance.now();
runNextFrame = false;
state.delta = useDefaultElapsed
? 1000 / 60
: Math.max(Math.min(timestamp - state.timestamp, maxElapsed), 1);
state.timestamp = timestamp;
state.isProcessing = true;
// Unrolled render loop for better per-frame performance
read.process(state);
resolveKeyframes.process(state);
update.process(state);
preRender.process(state);
render.process(state);
postRender.process(state);
state.isProcessing = false;
if (runNextFrame && allowKeepAlive) {
useDefaultElapsed = false;
scheduleNextBatch(processBatch);
}
};
const wake = () => {
runNextFrame = true;
useDefaultElapsed = true;
if (!state.isProcessing) {
scheduleNextBatch(processBatch);
}
};
const schedule = stepsOrder.reduce((acc, key) => {
const step = steps[key];
acc[key] = (process, keepAlive = false, immediate = false) => {
if (!runNextFrame)
wake();
return step.schedule(process, keepAlive, immediate);
};
return acc;
}, {});
const cancel = (process) => {
for (let i = 0; i < stepsOrder.length; i++) {
steps[stepsOrder[i]].cancel(process);
}
};
return { schedule, cancel, state, steps };
}
const { schedule: frame, cancel: cancelFrame, state: frameData, steps: frameSteps, } = createRenderBatcher(typeof requestAnimationFrame !== "undefined" ? requestAnimationFrame : noop, true);
/*
Bezier function generator
This has been modified from Gaëtan Renaudeau's BezierEasing
https://github.com/gre/bezier-easing/blob/master/src/index.js
https://github.com/gre/bezier-easing/blob/master/LICENSE
I've removed the newtonRaphsonIterate algo because in benchmarking it
wasn't noticiably faster than binarySubdivision, indeed removing it
usually improved times, depending on the curve.
I also removed the lookup table, as for the added bundle size and loop we're
only cutting ~4 or so subdivision iterations. I bumped the max iterations up
to 12 to compensate and this still tended to be faster for no perceivable
loss in accuracy.
Usage
const easeOut = cubicBezier(.17,.67,.83,.67);
const x = easeOut(0.5); // returns 0.627...
*/
// Returns x(t) given t, x1, and x2, or y(t) given t, y1, and y2.
const calcBezier = (t, a1, a2) => (((1.0 - 3.0 * a2 + 3.0 * a1) * t + (3.0 * a2 - 6.0 * a1)) * t + 3.0 * a1) *
t;
const subdivisionPrecision = 0.0000001;
const subdivisionMaxIterations = 12;
function binarySubdivide(x, lowerBound, upperBound, mX1, mX2) {
let currentX;
let currentT;
let i = 0;
do {
currentT = lowerBound + (upperBound - lowerBound) / 2.0;
currentX = calcBezier(currentT, mX1, mX2) - x;
if (currentX > 0.0) {
upperBound = currentT;
}
else {
lowerBound = currentT;
}
} while (Math.abs(currentX) > subdivisionPrecision &&
++i < subdivisionMaxIterations);
return currentT;
}
function cubicBezier(mX1, mY1, mX2, mY2) {
// If this is a linear gradient, return linear easing
if (mX1 === mY1 && mX2 === mY2)
return noop;
const getTForX = (aX) => binarySubdivide(aX, 0, 1, mX1, mX2);
// If animation is at start/end, return t without easing
return (t) => t === 0 || t === 1 ? t : calcBezier(getTForX(t), mY1, mY2);
}
// Accepts an easing function and returns a new one that outputs mirrored values for
// the second half of the animation. Turns easeIn into easeInOut.
const mirrorEasing = (easing) => (p) => p <= 0.5 ? easing(2 * p) / 2 : (2 - easing(2 * (1 - p))) / 2;
// Accepts an easing function and returns a new one that outputs reversed values.
// Turns easeIn into easeOut.
const reverseEasing = (easing) => (p) => 1 - easing(1 - p);
const backOut = /*@__PURE__*/ cubicBezier(0.33, 1.53, 0.69, 0.99);
const backIn = /*@__PURE__*/ reverseEasing(backOut);
const backInOut = /*@__PURE__*/ mirrorEasing(backIn);
const anticipate = (p) => (p *= 2) < 1 ? 0.5 * backIn(p) : 0.5 * (2 - Math.pow(2, -10 * (p - 1)));
const circIn = (p) => 1 - Math.sin(Math.acos(p));
const circOut = reverseEasing(circIn);
const circInOut = mirrorEasing(circIn);
/**
* Check if the value is a zero value string like "0px" or "0%"
*/
const isZeroValueString = (v) => /^0[^.\s]+$/u.test(v);
function isNone(value) {
if (typeof value === "number") {
return value === 0;
}
else if (value !== null) {
return value === "none" || value === "0" || isZeroValueString(value);
}
else {
return true;
}
}
let warning = noop;
let invariant = noop;
if (process.env.NODE_ENV !== "production") {
warning = (check, message) => {
if (!check && typeof console !== "undefined") {
console.warn(message);
}
};
invariant = (check, message) => {
if (!check) {
throw new Error(message);
}
};
}
/**
* Check if value is a numerical string, ie a string that is purely a number eg "100" or "-100.1"
*/
const isNumericalString = (v) => /^-?(?:\d+(?:\.\d+)?|\.\d+)$/u.test(v);
const checkStringStartsWith = (token) => (key) => typeof key === "string" && key.startsWith(token);
const isCSSVariableName =
/*@__PURE__*/ checkStringStartsWith("--");
const startsAsVariableToken =
/*@__PURE__*/ checkStringStartsWith("var(--");
const isCSSVariableToken = (value) => {
const startsWithToken = startsAsVariableToken(value);
if (!startsWithToken)
return false;
// Ensure any comments are stripped from the value as this can harm performance of the regex.
return singleCssVariableRegex.test(value.split("/*")[0].trim());
};
const singleCssVariableRegex = /var\(--(?:[\w-]+\s*|[\w-]+\s*,(?:\s*[^)(\s]|\s*\((?:[^)(]|\([^)(]*\))*\))+\s*)\)$/iu;
/**
* Parse Framer's special CSS variable format into a CSS token and a fallback.
*
* ```
* `var(--foo, #fff)` => [`--foo`, '#fff']
* ```
*
* @param current
*/
const splitCSSVariableRegex =
// eslint-disable-next-line redos-detector/no-unsafe-regex -- false positive, as it can match a lot of words
/^var\(--(?:([\w-]+)|([\w-]+), ?([a-zA-Z\d ()%#.,-]+))\)/u;
function parseCSSVariable(current) {
const match = splitCSSVariableRegex.exec(current);
if (!match)
return [,];
const [, token1, token2, fallback] = match;
return [`--${token1 !== null && token1 !== void 0 ? token1 : token2}`, fallback];
}
const maxDepth = 4;
function getVariableValue(current, element, depth = 1) {
invariant(depth <= maxDepth, `Max CSS variable fallback depth detected in property "${current}". This may indicate a circular fallback dependency.`);
const [token, fallback] = parseCSSVariable(current);
// No CSS variable detected
if (!token)
return;
// Attempt to read this CSS variable off the element
const resolved = window.getComputedStyle(element).getPropertyValue(token);
if (resolved) {
const trimmed = resolved.trim();
return isNumericalString(trimmed) ? parseFloat(trimmed) : trimmed;
}
return isCSSVariableToken(fallback)
? getVariableValue(fallback, element, depth + 1)
: fallback;
}
const clamp = (min, max, v) => {
if (v > max)
return max;
if (v < min)
return min;
return v;
};
const number = {
test: (v) => typeof v === "number",
parse: parseFloat,
transform: (v) => v,
};
const alpha = {
...number,
transform: (v) => clamp(0, 1, v),
};
const scale = {
...number,
default: 1,
};
const createUnitType = (unit) => ({
test: (v) => typeof v === "string" && v.endsWith(unit) && v.split(" ").length === 1,
parse: parseFloat,
transform: (v) => `${v}${unit}`,
});
const degrees = /*@__PURE__*/ createUnitType("deg");
const percent = /*@__PURE__*/ createUnitType("%");
const px = /*@__PURE__*/ createUnitType("px");
const vh = /*@__PURE__*/ createUnitType("vh");
const vw = /*@__PURE__*/ createUnitType("vw");
const progressPercentage = {
...percent,
parse: (v) => percent.parse(v) / 100,
transform: (v) => percent.transform(v * 100),
};
const positionalKeys = new Set([
"width",
"height",
"top",
"left",
"right",
"bottom",
"x",
"y",
"translateX",
"translateY",
]);
const isNumOrPxType = (v) => v === number || v === px;
const getPosFromMatrix = (matrix, pos) => parseFloat(matrix.split(", ")[pos]);
const getTranslateFromMatrix = (pos2, pos3) => (_bbox, { transform }) => {
if (transform === "none" || !transform)
return 0;
const matrix3d = transform.match(/^matrix3d\((.+)\)$/u);
if (matrix3d) {
return getPosFromMatrix(matrix3d[1], pos3);
}
else {
const matrix = transform.match(/^matrix\((.+)\)$/u);
if (matrix) {
return getPosFromMatrix(matrix[1], pos2);
}
else {
return 0;
}
}
};
const transformKeys = new Set(["x", "y", "z"]);
const nonTranslationalTransformKeys = transformPropOrder.filter((key) => !transformKeys.has(key));
function removeNonTranslationalTransform(visualElement) {
const removedTransforms = [];
nonTranslationalTransformKeys.forEach((key) => {
const value = visualElement.getValue(key);
if (value !== undefined) {
removedTransforms.push([key, value.get()]);
value.set(key.startsWith("scale") ? 1 : 0);
}
});
return removedTransforms;
}
const positionalValues = {
// Dimensions
width: ({ x }, { paddingLeft = "0", paddingRight = "0" }) => x.max - x.min - parseFloat(paddingLeft) - parseFloat(paddingRight),
height: ({ y }, { paddingTop = "0", paddingBottom = "0" }) => y.max - y.min - parseFloat(paddingTop) - parseFloat(paddingBottom),
top: (_bbox, { top }) => parseFloat(top),
left: (_bbox, { left }) => parseFloat(left),
bottom: ({ y }, { top }) => parseFloat(top) + (y.max - y.min),
right: ({ x }, { left }) => parseFloat(left) + (x.max - x.min),
// Transform
x: getTranslateFromMatrix(4, 13),
y: getTranslateFromMatrix(5, 14),
};
// Alias translate longform names
positionalValues.translateX = positionalValues.x;
positionalValues.translateY = positionalValues.y;
/**
* Tests a provided value against a ValueType
*/
const testValueType = (v) => (type) => type.test(v);
/**
* ValueType for "auto"
*/
const auto = {
test: (v) => v === "auto",
parse: (v) => v,
};
/**
* A list of value types commonly used for dimensions
*/
const dimensionValueTypes = [number, px, percent, degrees, vw, vh, auto];
/**
* Tests a dimensional value against the list of dimension ValueTypes
*/
const findDimensionValueType = (v) => dimensionValueTypes.find(testValueType(v));
const toResolve = new Set();
let isScheduled = false;
let anyNeedsMeasurement = false;
function measureAllKeyframes() {
if (anyNeedsMeasurement) {
const resolversToMeasure = Array.from(toResolve).filter((resolver) => resolver.needsMeasurement);
const elementsToMeasure = new Set(resolversToMeasure.map((resolver) => resolver.element));
const transformsToRestore = new Map();
/**
* Write pass
* If we're measuring elements we want to remove bounding box-changing transforms.
*/
elementsToMeasure.forEach((element) => {
const removedTransforms = removeNonTranslationalTransform(element);
if (!removedTransforms.length)
return;
transformsToRestore.set(element, removedTransforms);
element.render();
});
// Read
resolversToMeasure.forEach((resolver) => resolver.measureInitialState());
// Write
elementsToMeasure.forEach((element) => {
element.render();
const restore = transformsToRestore.get(element);
if (restore) {
restore.forEach(([key, value]) => {
var _a;
(_a = element.getValue(key)) === null || _a === void 0 ? void 0 : _a.set(value);
});
}
});
// Read
resolversToMeasure.forEach((resolver) => resolver.measureEndState());
// Write
resolversToMeasure.forEach((resolver) => {
if (resolver.suspendedScrollY !== undefined) {
window.scrollTo(0, resolver.suspendedScrollY);
}
});
}
anyNeedsMeasurement = false;
isScheduled = false;
toResolve.forEach((resolver) => resolver.complete());
toResolve.clear();
}
function readAllKeyframes() {
toResolve.forEach((resolver) => {
resolver.readKeyframes();
if (resolver.needsMeasurement) {
anyNeedsMeasurement = true;
}
});
}
function flushKeyframeResolvers() {
readAllKeyframes();
measureAllKeyframes();
}
class KeyframeResolver {
constructor(unresolvedKeyframes, onComplete, name, motionValue, element, isAsync = false) {
/**
* Track whether this resolver has completed. Once complete, it never
* needs to attempt keyframe resolution again.
*/
this.isComplete = false;
/**
* Track whether this resolver is async. If it is, it'll be added to the
* resolver queue and flushed in the next frame. Resolvers that aren't going
* to trigger read/write thrashing don't need to be async.
*/
this.isAsync = false;
/**
* Track whether this resolver needs to perform a measurement
* to resolve its keyframes.
*/
this.needsMeasurement = false;
/**
* Track whether this resolver is currently scheduled to resolve
* to allow it to be cancelled and resumed externally.
*/
this.isScheduled = false;
this.unresolvedKeyframes = [...unresolvedKeyframes];
this.onComplete = onComplete;
this.name = name;
this.motionValue = motionValue;
this.element = element;
this.isAsync = isAsync;
}
scheduleResolve() {
this.isScheduled = true;
if (this.isAsync) {
toResolve.add(this);
if (!isScheduled) {
isScheduled = true;
frame.read(readAllKeyframes);
frame.resolveKeyframes(measureAllKeyframes);
}
}
else {
this.readKeyframes();
this.complete();
}
}
readKeyframes() {
const { unresolvedKeyframes, name, element, motionValue } = this;
/**
* If a keyframe is null, we hydrate it either by reading it from
* the instance, or propagating from previous keyframes.
*/
for (let i = 0; i < unresolvedKeyframes.length; i++) {
if (unresolvedKeyframes[i] === null) {
/**
* If the first keyframe is null, we need to find its value by sampling the element
*/
if (i === 0) {
const currentValue = motionValue === null || motionValue === void 0 ? void 0 : motionValue.get();
const finalKeyframe = unresolvedKeyframes[unresolvedKeyframes.length - 1];
if (currentValue !== undefined) {
unresolvedKeyframes[0] = currentValue;
}
else if (element && name) {
const valueAsRead = element.readValue(name, finalKeyframe);
if (valueAsRead !== undefined && valueAsRead !== null) {
unresolvedKeyframes[0] = valueAsRead;
}
}
if (unresolvedKeyframes[0] === undefined) {
unresolvedKeyframes[0] = finalKeyframe;
}
if (motionValue && currentValue === undefined) {
motionValue.set(unresolvedKeyframes[0]);
}
}
else {
unresolvedKeyframes[i] = unresolvedKeyframes[i - 1];
}
}
}
}
setFinalKeyframe() { }
measureInitialState() { }
renderEndStyles() { }
measureEndState() { }
complete() {
this.isComplete = true;
this.onComplete(this.unresolvedKeyframes, this.finalKeyframe);
toResolve.delete(this);
}
cancel() {
if (!this.isComplete) {
this.isScheduled = false;
toResolve.delete(this);
}
}
resume() {
if (!this.isComplete)
this.scheduleResolve();
}
}
// If this number is a decimal, make it just five decimal places
// to avoid exponents
const sanitize = (v) => Math.round(v * 100000) / 100000;
const floatRegex = /-?(?:\d+(?:\.\d+)?|\.\d+)/gu;
function isNullish(v) {
return v == null;
}
const singleColorRegex = /^(?:#[\da-f]{3,8}|(?:rgb|hsl)a?\((?:-?[\d.]+%?[,\s]+){2}-?[\d.]+%?\s*(?:[,/]\s*)?(?:\b\d+(?:\.\d+)?|\.\d+)?%?\))$/iu;
/**
* Returns true if the provided string is a color, ie rgba(0,0,0,0) or #000,
* but false if a number or multiple colors
*/
const isColorString = (type, testProp) => (v) => {
return Boolean((typeof v === "string" &&
singleColorRegex.test(v) &&
v.startsWith(type)) ||
(testProp &&
!isNullish(v) &&
Object.prototype.hasOwnProperty.call(v, testProp)));
};
const splitColor = (aName, bName, cName) => (v) => {
if (typeof v !== "string")
return v;
const [a, b, c, alpha] = v.match(floatRegex);
return {
[aName]: parseFloat(a),
[bName]: parseFloat(b),
[cName]: parseFloat(c),
alpha: alpha !== undefined ? parseFloat(alpha) : 1,
};
};
const clampRgbUnit = (v) => clamp(0, 255, v);
const rgbUnit = {
...number,
transform: (v) => Math.round(clampRgbUnit(v)),
};
const rgba = {
test: /*@__PURE__*/ isColorString("rgb", "red"),
parse: /*@__PURE__*/ splitColor("red", "green", "blue"),
transform: ({ red, green, blue, alpha: alpha$1 = 1 }) => "rgba(" +
rgbUnit.transform(red) +
", " +
rgbUnit.transform(green) +
", " +
rgbUnit.transform(blue) +
", " +
sanitize(alpha.transform(alpha$1)) +
")",
};
function parseHex(v) {
let r = "";
let g = "";
let b = "";
let a = "";
// If we have 6 characters, ie #FF0000
if (v.length > 5) {
r = v.substring(1, 3);
g = v.substring(3, 5);
b = v.substring(5, 7);
a = v.substring(7, 9);
// Or we have 3 characters, ie #F00
}
else {
r = v.substring(1, 2);
g = v.substring(2, 3);
b = v.substring(3, 4);
a = v.substring(4, 5);
r += r;
g += g;
b += b;
a += a;
}
return {
red: parseInt(r, 16),
green: parseInt(g, 16),
blue: parseInt(b, 16),
alpha: a ? parseInt(a, 16) / 255 : 1,
};
}
const hex = {
test: /*@__PURE__*/ isColorString("#"),
parse: parseHex,
transform: rgba.transform,
};
const hsla = {
test: /*@__PURE__*/ isColorString("hsl", "hue"),
parse: /*@__PURE__*/ splitColor("hue", "saturation", "lightness"),
transform: ({ hue, saturation, lightness, alpha: alpha$1 = 1 }) => {
return ("hsla(" +
Math.round(hue) +
", " +
percent.transform(sanitize(saturation)) +
", " +
percent.transform(sanitize(lightness)) +
", " +
sanitize(alpha.transform(alpha$1)) +
")");
},
};
const color = {
test: (v) => rgba.test(v) || hex.test(v) || hsla.test(v),
parse: (v) => {
if (rgba.test(v)) {
return rgba.parse(v);
}
else if (hsla.test(v)) {
return hsla.parse(v);
}
else {
return hex.parse(v);
}
},
transform: (v) => {
return typeof v === "string"
? v
: v.hasOwnProperty("red")
? rgba.transform(v)
: hsla.transform(v);
},
};
const colorRegex = /(?:#[\da-f]{3,8}|(?:rgb|hsl)a?\((?:-?[\d.]+%?[,\s]+){2}-?[\d.]+%?\s*(?:[,/]\s*)?(?:\b\d+(?:\.\d+)?|\.\d+)?%?\))/giu;
function test(v) {
var _a, _b;
return (isNaN(v) &&
typeof v === "string" &&
(((_a = v.match(floatRegex)) === null || _a === void 0 ? void 0 : _a.length) || 0) +
(((_b = v.match(colorRegex)) === null || _b === void 0 ? void 0 : _b.length) || 0) >
0);
}
const NUMBER_TOKEN = "number";
const COLOR_TOKEN = "color";
const VAR_TOKEN = "var";
const VAR_FUNCTION_TOKEN = "var(";
const SPLIT_TOKEN = "${}";
// this regex consists of the `singleCssVariableRegex|rgbHSLValueRegex|digitRegex`
const complexRegex = /var\s*\(\s*--(?:[\w-]+\s*|[\w-]+\s*,(?:\s*[^)(\s]|\s*\((?:[^)(]|\([^)(]*\))*\))+\s*)\)|#[\da-f]{3,8}|(?:rgb|hsl)a?\((?:-?[\d.]+%?[,\s]+){2}-?[\d.]+%?\s*(?:[,/]\s*)?(?:\b\d+(?:\.\d+)?|\.\d+)?%?\)|-?(?:\d+(?:\.\d+)?|\.\d+)/giu;
function analyseComplexValue(value) {
const originalValue = value.toString();
const values = [];
const indexes = {
color: [],
number: [],
var: [],
};
const types = [];
let i = 0;
const tokenised = originalValue.replace(complexRegex, (parsedValue) => {
if (color.test(parsedValue)) {
indexes.color.push(i);
types.push(COLOR_TOKEN);
values.push(color.parse(parsedValue));
}
else if (parsedValue.startsWith(VAR_FUNCTION_TOKEN)) {
indexes.var.push(i);
types.push(VAR_TOKEN);
values.push(parsedValue);
}
else {
indexes.number.push(i);
types.push(NUMBER_TOKEN);
values.push(parseFloat(parsedValue));
}
++i;
return SPLIT_TOKEN;
});
const split = tokenised.split(SPLIT_TOKEN);
return { values, split, indexes, types };
}
function parseComplexValue(v) {
return analyseComplexValue(v).values;
}
function createTransformer(source) {
const { split, types } = analyseComplexValue(source);
const numSections = split.length;
return (v) => {
let output = "";
for (let i = 0; i < numSections; i++) {
output += split[i];
if (v[i] !== undefined) {
const type = types[i];
if (type === NUMBER_TOKEN) {
output += sanitize(v[i]);
}
else if (type === COLOR_TOKEN) {
output += color.transform(v[i]);
}
else {
output += v[i];
}
}
}
return output;
};
}
const convertNumbersToZero = (v) => typeof v === "number" ? 0 : v;
function getAnimatableNone$1(v) {
const parsed = parseComplexValue(v);
const transformer = createTransformer(v);
return transformer(parsed.map(convertNumbersToZero));
}
const complex = {
test,
parse: parseComplexValue,
createTransformer,
getAnimatableNone: getAnimatableNone$1,
};
/**
* Properties that should default to 1 or 100%
*/
const maxDefaults = new Set(["brightness", "contrast", "saturate", "opacity"]);
function applyDefaultFilter(v) {
const [name, value] = v.slice(0, -1).split("(");
if (name === "drop-shadow")
return v;
const [number] = value.match(floatRegex) || [];
if (!number)
return v;
const unit = value.replace(number, "");
let defaultValue = maxDefaults.has(name) ? 1 : 0;
if (number !== value)
defaultValue *= 100;
return name + "(" + defaultValue + unit + ")";
}
const functionRegex = /\b([a-z-]*)\(.*?\)/gu;
const filter = {
...complex,
getAnimatableNone: (v) => {
const functions = v.match(functionRegex);
return functions ? functions.map(applyDefaultFilter).join(" ") : v;
},
};
const browserNumberValueTypes = {
// Border props
borderWidth: px,
borderTopWidth: px,
borderRightWidth: px,
borderBottomWidth: px,
borderLeftWidth: px,
borderRadius: px,
radius: px,
borderTopLeftRadius: px,
borderTopRightRadius: px,
borderBottomRightRadius: px,
borderBottomLeftRadius: px,
// Positioning props
width: px,
maxWidth: px,
height: px,
maxHeight: px,
top: px,
right: px,
bottom: px,
left: px,
// Spacing props
padding: px,
paddingTop: px,
paddingRight: px,
paddingBottom: px,
paddingLeft: px,
margin: px,
marginTop: px,
marginRight: px,
marginBottom: px,
marginLeft: px,
// Misc
backgroundPositionX: px,
backgroundPositionY: px,
};
const transformValueTypes = {
rotate: degrees,
rotateX: degrees,
rotateY: degrees,
rotateZ: degrees,
scale,
scaleX: scale,
scaleY: scale,
scaleZ: scale,
skew: degrees,
skewX: degrees,
skewY: degrees,
distance: px,
translateX: px,
translateY: px,
translateZ: px,
x: px,
y: px,
z: px,
perspective: px,
transformPerspective: px,
opacity: alpha,
originX: progressPercentage,
originY: progressPercentage,
originZ: px,
};
const int = {
...number,
transform: Math.round,
};
const numberValueTypes = {
...browserNumberValueTypes,
...transformValueTypes,
zIndex: int,
size: px,
// SVG
fillOpacity: alpha,
strokeOpacity: alpha,
numOctaves: int,
};
/**
* A map of default value types for common values
*/
const defaultValueTypes = {
...numberValueTypes,
// Color props
color,
backgroundColor: color,
outlineColor: color,
fill: color,
stroke: color,
// Border props
borderColor: color,
borderTopColor: color,
borderRightColor: color,
borderBottomColor: color,
borderLeftColor: color,
filter,
WebkitFilter: filter,
};
/**
* Gets the default ValueType for the provided value key
*/
const getDefaultValueType = (key) => defaultValueTypes[key];
function getAnimatableNone(key, value) {
let defaultValueType = getDefaultValueType(key);
if (defaultValueType !== filter)
defaultValueType = complex;
// If value is not recognised as animatable, ie "none", create an animatable version origin based on the target
return defaultValueType.getAnimatableNone
? defaultValueType.getAnimatableNone(value)
: undefined;
}
/**
* If we encounter keyframes like "none" or "0" and we also have keyframes like
* "#fff" or "200px 200px" we want to find a keyframe to serve as a template for
* the "none" keyframes. In this case "#fff" or "200px 200px" - then these get turned into
* zero equivalents, i.e. "#fff0" or "0px 0px".
*/
const invalidTemplates = new Set(["auto", "none", "0"]);
function makeNoneKeyframesAnimatable(unresolvedKeyframes, noneKeyframeIndexes, name) {
let i = 0;
let animatableTemplate = undefined;
while (i < unresolvedKeyframes.length && !animatableTemplate) {
const keyframe = unresolvedKeyframes[i];
if (typeof keyframe === "string" &&
!invalidTemplates.has(keyframe) &&
analyseComplexValue(keyframe).values.length) {
animatableTemplate = unresolvedKeyframes[i];
}
i++;
}
if (animatableTemplate && name) {
for (const noneIndex of noneKeyframeIndexes) {
unresolvedKeyframes[noneIndex] = getAnimatableNone(name, animatableTemplate);
}
}
}
class DOMKeyframesResolver extends KeyframeResolver {
constructor(unresolvedKeyframes, onComplete, name, motionValue, element) {
super(unresolvedKeyframes, onComplete, name, motionValue, element, true);
}
readKeyframes() {
const { unresolvedKeyframes, element, name } = this;
if (!element || !element.current)
return;
super.readKeyframes();
/**
* If any keyframe is a CSS variable, we need to find its value by sampling the element
*/
for (let i = 0; i < unresolvedKeyframes.length; i++) {
let keyframe = unresolvedKeyframes[i];
if (typeof keyframe === "string") {
keyframe = keyframe.trim();
if (isCSSVariableToken(keyframe)) {
const resolved = getVariableValue(keyframe, element.current);
if (resolved !== undefined) {
unresolvedKeyframes[i] = resolved;
}
if (i === unresolvedKeyframes.length - 1) {
this.finalKeyframe = keyframe;
}
}
}
}
/**
* Resolve "none" values. We do this potentially twice - once before and once after measuring keyframes.
* This could be seen as inefficient but it's a trade-off to avoid measurements in more situations, which
* have a far bigger performance impact.
*/
this.resolveNoneKeyframes();
/**
* Check to see if unit type has changed. If so schedule jobs that will
* temporarily set styles to the destination keyframes.
* Skip if we have more than two keyframes or this isn't a positional value.
* TODO: We can throw if there are multiple keyframes and the value type changes.
*/
if (!positionalKeys.has(name) || unresolvedKeyframes.length !== 2) {
return;
}
const [origin, target] = unresolvedKeyframes;
const originType = findDimensionValueType(origin);
const targetType = findDimensionValueType(target);
/**
* Either we don't recognise these value types or we can animate between them.
*/
if (originType === targetType)
return;
/**
* If both values are numbers or pixels, we can animate between them by
* converting them to numbers.
*/
if (isNumOrPxType(originType) && isNumOrPxType(targetType)) {
for (let i = 0; i < unresolvedKeyframes.length; i++) {
const value = unresolvedKeyframes[i];
if (typeof value === "string") {
unresolvedKeyframes[i] = parseFloat(value);
}
}
}
else {
/**
* Else, the only way to resolve this is by measuring the element.
*/
this.needsMeasurement = true;
}
}
resolveNoneKeyframes() {
const { unresolvedKeyframes, name } = this;
const noneKeyframeIndexes = [];
for (let i = 0; i < unresolvedKeyframes.length; i++) {
if (isNone(unresolvedKeyframes[i])) {
noneKeyframeIndexes.push(i);
}
}
if (noneKeyframeIndexes.length) {
makeNoneKeyframesAnimatable(unresolvedKeyframes, noneKeyframeIndexes, name);
}
}
measureInitialState() {
const { element, unresolvedKeyframes, name } = this;
if (!element || !element.current)
return;
if (name === "height") {
this.suspendedScrollY = window.pageYOffset;
}
this.measuredOrigin = positionalValues[name](element.measureViewportBox(), window.getComputedStyle(element.current));
unresolvedKeyframes[0] = this.measuredOrigin;
// Set final key frame to measure after next render
const measureKeyframe = unresolvedKeyframes[unresolvedKeyframes.length - 1];
if (measureKeyframe !== undefined) {
element.getValue(name, measureKeyframe).jump(measureKeyframe, false);
}
}
measureEndState() {
var _a;
const { element, name, unresolvedKeyframes } = this;
if (!element || !element.current)
return;
const value = element.getValue(name);
value && value.jump(this.measuredOrigin, false);
const finalKeyframeIndex = unresolvedKeyframes.length - 1;
const finalKeyframe = unresolvedKeyframes[finalKeyframeIndex];
unresolvedKeyframes[finalKeyframeIndex] = positionalValues[name](element.measureViewportBox(), window.getComputedStyle(element.current));
if (finalKeyframe !== null && this.finalKeyframe === undefined) {
this.finalKeyframe = finalKeyframe;
}
// If we removed transform values, reapply them before the next render
if ((_a = this.removedTransforms) === null || _a === void 0 ? void 0 : _a.length) {
this.removedTransforms.forEach(([unsetTransformName, unsetTransformValue]) => {
element
.getValue(unsetTransformName)
.set(unsetTransformValue);
});
}
this.resolveNoneKeyframes();
}
}
function isGenerator(type) {
return typeof type === "function";
}
let now;
function clearTime() {
now = undefined;
}
/**
* An eventloop-synchronous alternative to performance.now().
*
* Ensures that time measurements remain consistent within a synchronous context.
* Usually calling performance.now() twice within the same synchronous context
* will return different values which isn't useful for animations when we're usually
* trying to sync animations to the same frame.
*/
const time = {
now: () => {
if (now === undefined) {
time.set(frameData.isProcessing || MotionGlobalConfig.useManualTiming
? frameData.timestamp
: performance.now());
}
return now;
},
set: (newTime) => {
now = newTime;
queueMicrotask(clearTime);
},
};
/**
* Check if a value is animatable. Examples:
*
* ✅: 100, "100px", "#fff"
* ❌: "block", "url(2.jpg)"
* @param value
*
* @internal
*/
const isAnimatable = (value, name) => {
// If the list of keys tat might be non-animatable grows, replace with Set
if (name === "zIndex")
return false;
// If it's a number or a keyframes array, we can animate it. We might at some point
// need to do a deep isAnimatable check of keyframes, or let Popmotion handle this,
// but for now lets leave it like this for performance reasons
if (typeof value === "number" || Array.isArray(value))
return true;
if (typeof value === "string" && // It's animatable if we have a string
(complex.test(value) || value === "0") && // And it contains numbers and/or colors
!value.startsWith("url(") // Unless it starts with "url("
) {
return true;
}
return false;
};
function hasKeyframesChanged(keyframes) {
const current = keyframes[0];
if (keyframes.length === 1)
return true;
for (let i = 0; i < keyframes.length; i++) {
if (keyframes[i] !== current)
return true;
}
}
function canAnimate(keyframes, name, type, velocity) {
/**
* Check if we're able to animate between the start and end keyframes,
* and throw a warning if we're attempting to animate between one that's
* animatable and another that isn't.
*/
const originKeyframe = keyframes[0];
if (originKeyframe === null)
return false;
/**
* These aren't traditionally animatable but we do support them.
* In future we could look into making this more generic or replacing
* this function with mix() === mixImmediate
*/
if (name === "display" || name === "visibility")
return true;
const targetKeyframe = keyframes[keyframes.length - 1];
const isOriginAnimatable = isAnimatable(originKeyframe, name);
const isTargetAnimatable = isAnimatable(targetKeyframe, name);
warning(isOriginAnimatable === isTargetAnimatable, `You are trying to animate ${name} from "${originKeyframe}" to "${targetKeyframe}". ${originKeyframe} is not an animatable value - to enable this animation set ${originKeyframe} to a value animatable to ${targetKeyframe} via the \`style\` property.`);
// Always skip if any of these are true
if (!isOriginAnimatable || !isTargetAnimatable) {
return false;
}
return (hasKeyframesChanged(keyframes) ||
((type === "spring" || isGenerator(type)) && velocity));
}
/**
* Maximum time allowed between an animation being created and it being
* resolved for us to use the latter as the start time.
*
* This is to ensure that while we prefer to "start" an animation as soon
* as it's triggered, we also want to avoid a visual jump if there's a big delay
* between these two moments.
*/
const MAX_RESOLVE_DELAY = 40;
class BaseAnimation {
constructor({ autoplay = true, delay = 0, type = "keyframes", repeat = 0, repeatDelay = 0, repeatType = "loop", ...options }) {
// Track whether the animation has been stopped. Stopped animations won't restart.
this.isStopped = false;
this.hasAttemptedResolve = false;
this.createdAt = time.now();
this.options = {
autoplay,
delay,
type,
repeat,
repeatDelay,
repeatType,
...options,
};
this.updateFinishedPromise();
}
/**
* This method uses the createdAt and resolvedAt to calculate the
* animation startTime. *Ideally*, we would use the createdAt time as t=0
* as the following frame would then be the first frame of the animation in
* progress, which would feel snappier.
*
* However, if there's a delay (main thread work) between the creation of
* the animation and the first commited frame, we prefer to use resolvedAt
* to avoid a sudden jump into the animation.
*/
calcStartTime() {
if (!this.resolvedAt)
return this.createdAt;
return this.resolvedAt - this.createdAt > MAX_RESOLVE_DELAY
? this.resolvedAt
: this.createdAt;
}
/**
* A getter for resolved data. If keyframes are not yet resolved, accessing
* this.resolved will synchronously flush all pending keyframe resolvers.
* This is a deoptimisation, but at its worst still batches read/writes.
*/
get resolved() {
if (!this._resolved && !this.hasAttemptedResolve) {
flushKeyframeResolvers();
}
return this._resolved;
}
/**
* A method to be called when the keyframes resolver completes. This method
* will check if its possible to run the animation and, if not, skip it.
* Otherwise, it will call initPlayback on the implementing class.
*/
onKeyframesResolved(keyframes, finalKeyframe) {
this.resolvedAt = time.now();
this.hasAttemptedResolve = true;
const { name, type, velocity, delay, onComplete, onUpdate, isGenerator, } = this.options;
/**
* If we can't animate this value with the resolved keyframes
* then we should complete it immediately.
*/
if (!isGenerator && !canAnimate(keyframes, name, type, velocity)) {
// Finish immediately
if (!delay) {
onUpdate === null || onUpdate === void 0 ? void 0 : onUpdate(getFinalKeyframe(keyframes, this.options, finalKeyframe));
onComplete === null || onComplete === void 0 ? void 0 : onComplete();
this.resolveFinishedPromise();
return;
}
// Finish after a delay
else {
this.options.duration = 0;
}
}
const resolvedAnimation = this.initPlayback(keyframes, finalKeyframe);
if (resolvedAnimation === false)
return;
this._resolved = {
keyframes,
finalKeyframe,
...resolvedAnimation,
};
this.onPostResolved();
}
onPostResolved() { }
/**
* Allows the returned animation to be awaited or promise-chained. Currently
* resolves when the animation finishes at all but in a future update could/should
* reject if its cancels.
*/
then(resolve, reject) {
return this.currentFinishedPromise.then(resolve, reject);
}
flatten() {
this.options.type = "keyframes";
this.options.ease = "linear";
}
updateFinishedPromise() {
this.currentFinishedPromise = new Promise((resolve) => {
this.resolveFinishedPromise = resolve;
});
}
}
/*
Convert velocity into velocity per second
@param [number]: Unit per frame
@param [number]: Frame duration in ms
*/
function velocityPerSecond(velocity, frameDuration) {
return frameDuration ? velocity * (1000 / frameDuration) : 0;
}
const velocitySampleDuration = 5; // ms
function calcGeneratorVelocity(resolveValue, t, current) {
const prevT = Math.max(t - velocitySampleDuration, 0);
return velocityPerSecond(current - resolveValue(prevT), t - prevT);
}
const safeMin = 0.001;
const minDuration = 0.01;
const maxDuration$1 = 10.0;
const minDamping = 0.05;
const maxDamping = 1;
function findSpring({ duration = 800, bounce = 0.25, velocity = 0, mass = 1, }) {
let envelope;
let derivative;
warning(duration <= secondsToMilliseconds(maxDuration$1), "Spring duration must be 10 seconds or less");
let dampingRatio = 1 - bounce;
/**
* Restrict dampingRatio and duration to within acceptable ranges.
*/
dampingRatio = clamp(minDamping, maxDamping, dampingRatio);
duration = clamp(minDuration, maxDuration$1, millisecondsToSeconds(duration));
if (dampingRatio < 1) {
/**
* Underdamped spring
*/
envelope = (undampedFreq) => {
const exponentialDecay = undampedFreq * dampingRatio;
const delta = exponentialDecay * duration;
const a = exponentialDecay - velocity;
const b = calcAngularFreq(undampedFreq, dampingRatio);
const c = Math.exp(-delta);
return safeMin - (a / b) * c;
};
derivative = (undampedFreq) => {
const exponentialDecay = undampedFreq * dampingRatio;
const delta = exponentialDecay * duration;
const d = delta * velocity + velocity;
const e = Math.pow(dampingRatio, 2) * Math.pow(undampedFreq, 2) * duration;
const f = Math.exp(-delta);
const g = calcAngularFreq(Math.pow(undampedFreq, 2), dampingRatio);
const factor = -envelope(undampedFreq) + safeMin > 0 ? -1 : 1;
return (factor * ((d - e) * f)) / g;
};
}
else {
/**
* Critically-damped spring
*/
envelope = (undampedFreq) => {
const a = Math.exp(-undampedFreq * duration);
const b = (undampedFreq - velocity) * duration + 1;
return -safeMin + a * b;
};
derivative = (undampedFreq) => {
const a = Math.exp(-undampedFreq * duration);
const b = (velocity - undampedFreq) * (duration * duration);
return a * b;
};
}
const initialGuess = 5 / duration;
const undampedFreq = approximateRoot(envelope, derivative, initialGuess);
duration = secondsToMilliseconds(duration);
if (isNaN(undampedFreq)) {
return {
stiffness: 100,
damping: 10,
duration,
};
}
else {
const stiffness = Math.pow(undampedFreq, 2) * mass;
return {
stiffness,
damping: dampingRatio * 2 * Math.sqrt(mass * stiffness),
duration,
};
}
}
const rootIterations = 12;
function approximateRoot(envelope, derivative, initialGuess) {
let result = initialGuess;
for (let i = 1; i < rootIterations; i++) {
result = result - envelope(result) / derivative(result);
}
return result;
}
function calcAngularFreq(undampedFreq, dampingRatio) {
return undampedFreq * Math.sqrt(1 - dampingRatio * dampingRatio);
}
const durationKeys = ["duration", "bounce"];
const physicsKeys = ["stiffness", "damping", "mass"];
function isSpringType(options, keys) {
return keys.some((key) => options[key] !== undefined);
}
function getSpringOptions(options) {
let springOptions = {
velocity: 0.0,
stiffness: 100,
damping: 10,
mass: 1.0,
isResolvedFromDuration: false,
...options,
};
// stiffness/damping/mass overrides duration/bounce
if (!isSpringType(options, physicsKeys) &&
isSpringType(options, durationKeys)) {
const derived = findSpring(options);
springOptions = {
...springOptions,
...derived,
mass: 1.0,
};
springOptions.isResolvedFromDuration = true;
}
return springOptions;
}
function spring({ keyframes, restDelta, restSpeed, ...options }) {
const origin = keyframes[0];
const target = keyframes[keyframes.length - 1];
/**
* This is the Iterator-spec return value. We ensure it's mutable rather than using a generator
* to reduce GC during animation.
*/
const state = { done: false, value: origin };
const { stiffness, damping, mass, duration, velocity, isResolvedFromDuration, } = getSpringOptions({
...options,
velocity: -millisecondsToSeconds(options.velocity || 0),
});
const initialVelocity = velocity || 0.0;
const dampingRatio = damping / (2 * Math.sqrt(stiffness * mass));
const initialDelta = target - origin;
const undampedAngularFreq = millisecondsToSeconds(Math.sqrt(stiffness / mass));
/**
* If we're working on a granular scale, use smaller defaults for determining
* when the spring is finished.
*
* These defaults have been selected emprically based on what strikes a good
* ratio between feeling good and finishing as soon as changes are imperceptible.
*/
const isGranularScale = Math.abs(initialDelta) < 5;
restSpeed || (restSpeed = isGranularScale ? 0.01 : 2);
restDelta || (restDelta = isGranularScale ? 0.005 : 0.5);
let resolveSpring;
if (dampingRatio < 1) {
const angularFreq = calcAngularFreq(undampedAngularFreq, dampingRatio);
// Underdamped spring
resolveSpring = (t) => {
const envelope = Math.exp(-dampingRatio * undampedAngularFreq * t);
return (target -
envelope *
(((initialVelocity +
dampingRatio * undampedAngularFreq * initialDelta) /
angularFreq) *
Math.sin(angularFreq * t) +
initialDelta * Math.cos(angularFreq * t)));
};
}
else if (dampingRatio === 1) {
// Critically damped spring
resolveSpring = (t) => target -
Math.exp(-undampedAngularFreq * t) *
(initialDelta +
(initialVelocity + undampedAngularFreq * initialDelta) * t);
}
else {
// Overdamped spring
const dampedAngularFreq = undampedAngularFreq * Math.sqrt(dampingRatio * dampingRatio - 1);
resolveSpring = (t) => {
const envelope = Math.exp(-dampingRatio * undampedAngularFreq * t);
// When performing sinh or cosh values can hit Infinity so we cap them here
const freqForT = Math.min(dampedAngularFreq * t, 300);
return (target -
(envelope *
((initialVelocity +
dampingRatio * undampedAngularFreq * initialDelta) *
Math.sinh(freqForT) +
dampedAngularFreq *
initialDelta *
Math.cosh(freqForT))) /
dampedAngularFreq);
};
}
return {
calculatedDuration: isResolvedFromDuration ? duration || null : null,
next: (t) => {
const current = resolveSpring(t);
if (!isResolvedFromDuration) {
let currentVelocity = 0.0;
/**
* We only need to calculate velocity for under-damped springs
* as over- and critically-damped springs can't overshoot, so
* checking only for displacement is enough.
*/
if (dampingRatio < 1) {
currentVelocity =
t === 0
? secondsToMilliseconds(initialVelocity)
: calcGeneratorVelocity(resolveSpring, t, current);
}
const isBelowVelocityThreshold = Math.abs(currentVelocity) <= restSpeed;
const isBelowDisplacementThreshold = Math.abs(target - current) <= restDelta;
state.done =
isBelowVelocityThreshold && isBelowDisplacementThreshold;
}
else {
state.done = t >= duration;
}
state.value = state.done ? target : current;
return state;
},
};
}
function inertia({ keyframes, velocity = 0.0, power = 0.8, timeConstant = 325, bounceDamping = 10, bounceStiffness = 500, modifyTarget, min, max, restDelta = 0.5, restSpeed, }) {
const origin = keyframes[0];
const state = {
done: false,
value: origin,
};
const isOutOfBounds = (v) => (min !== undefined && v < min) || (max !== undefined && v > max);
const nearestBoundary = (v) => {
if (min === undefined)
return max;
if (max === undefined)
return min;
return Math.abs(min - v) < Math.abs(max - v) ? min : max;
};
let amplitude = power * velocity;
const ideal = origin + amplitude;
const target = modifyTarget === undefined ? ideal : modifyTarget(ideal);
/**
* If the target has changed we need to re-calculate the amplitude, otherwise
* the animation will start from the wrong position.
*/
if (target !== ideal)
amplitude = target - origin;
const calcDelta = (t) => -amplitude * Math.exp(-t / timeConstant);
const calcLatest = (t) => target + calcDelta(t);
const applyFriction = (t) => {
const delta = calcDelta(t);
const latest = calcLatest(t);
state.done = Math.abs(delta) <= restDelta;
state.value = state.done ? target : latest;
};
/**
* Ideally this would resolve for t in a stateless way, we could
* do that by always precalculating the animation but as we know
* this will be done anyway we can assume that spring will
* be discovered during that.
*/
let timeReachedBoundary;
let spring$1;
const checkCatchBoundary = (t) => {
if (!isOutOfBounds(state.value))
return;
timeReachedBoundary = t;
spring$1 = spring({
keyframes: [state.value, nearestBoundary(state.value)],
velocity: calcGeneratorVelocity(calcLatest, t, state.value), // TODO: This should be passing * 1000
damping: bounceDamping,
stiffness: bounceStiffness,
restDelta,
restSpeed,
});
};
checkCatchBoundary(0);
return {
calculatedDuration: null,
next: (t) => {
/**
* We need to resolve the friction to figure out if we need a
* spring but we don't want to do this twice per frame. So here
* we flag if we updated for this frame and later if we did
* we can skip doing it again.
*/
let hasUpdatedFrame = false;
if (!spring$1 && timeReachedBoundary === undefined) {
hasUpdatedFrame = true;
applyFriction(t);
checkCatchBoundary(t);
}
/**
* If we have a spring and the provided t is beyond the moment the friction
* animation crossed the min/max boundary, use the spring.
*/
if (timeReachedBoundary !== undefined && t >= timeReachedBoundary) {
return spring$1.next(t - timeReachedBoundary);
}
else {
!hasUpdatedFrame && applyFriction(t);
return state;
}
},
};
}
const easeIn = /*@__PURE__*/ cubicBezier(0.42, 0, 1, 1);
const easeOut = /*@__PURE__*/ cubicBezier(0, 0, 0.58, 1);
const easeInOut = /*@__PURE__*/ cubicBezier(0.42, 0, 0.58, 1);
const isEasingArray = (ease) => {
return Array.isArray(ease) && typeof ease[0] !== "number";
};
const isBezierDefinition = (easing) => Array.isArray(easing) && typeof easing[0] === "number";
const easingLookup = {
linear: noop,
easeIn,
easeInOut,
easeOut,
circIn,
circInOut,
circOut,
backIn,
backInOut,
backOut,
anticipate,
};
const easingDefinitionToFunction = (definition) => {
if (isBezierDefinition(definition)) {
// If cubic bezier definition, create bezier curve
invariant(definition.length === 4, `Cubic bezier arrays must contain four numerical values.`);
const [x1, y1, x2, y2] = definition;
return cubicBezier(x1, y1, x2, y2);
}
else if (typeof definition === "string") {
// Else lookup from table
invariant(easingLookup[definition] !== undefined, `Invalid easing type '${definition}'`);
return easingLookup[definition];
}
return definition;
};
/**
* Pipe
* Compose other transformers to run linearily
* pipe(min(20), max(40))
* @param {...functions} transformers
* @return {function}
*/
const combineFunctions = (a, b) => (v) => b(a(v));
const pipe = (...transformers) => transformers.reduce(combineFunctions);
/*
Progress within given range
Given a lower limit and an upper limit, we return the progress
(expressed as a number 0-1) represented by the given value, and
limit that progress to within 0-1.
@param [number]: Lower limit
@param [number]: Upper limit
@param [number]: Value to find progress within given range
@return [number]: Progress of value within range as expressed 0-1
*/
const progress = (from, to, value) => {
const toFromDifference = to - from;
return toFromDifference === 0 ? 1 : (value - from) / toFromDifference;
};
/*
Value in range from progress
Given a lower limit and an upper limit, we return the value within
that range as expressed by progress (usually a number from 0 to 1)
So progress = 0.5 would change
from -------- to
to
from ---- to
E.g. from = 10, to = 20, progress = 0.5 => 15
@param [number]: Lower limit of range
@param [number]: Upper limit of range
@param [number]: The progress between lower and upper limits expressed 0-1
@return [number]: Value as calculated from progress within range (not limited within range)
*/
const mixNumber$1 = (from, to, progress) => {
return from + (to - from) * progress;
};
// Adapted from https://gist.github.com/mjackson/5311256
function hueToRgb(p, q, t) {
if (t < 0)
t += 1;
if (t > 1)
t -= 1;
if (t < 1 / 6)
return p + (q - p) * 6 * t;
if (t < 1 / 2)
return q;
if (t < 2 / 3)
return p + (q - p) * (2 / 3 - t) * 6;
return p;
}
function hslaToRgba({ hue, saturation, lightness, alpha }) {
hue /= 360;
saturation /= 100;
lightness /= 100;
let red = 0;
let green = 0;
let blue = 0;
if (!saturation) {
red = green = blue = lightness;
}
else {
const q = lightness < 0.5
? lightness * (1 + saturation)
: lightness + saturation - lightness * saturation;
const p = 2 * lightness - q;
red = hueToRgb(p, q, hue + 1 / 3);
green = hueToRgb(p, q, hue);
blue = hueToRgb(p, q, hue - 1 / 3);
}
return {
red: Math.round(red * 255),
green: Math.round(green * 255),
blue: Math.round(blue * 255),
alpha,
};
}
function mixImmediate(a, b) {
return (p) => (p > 0 ? b : a);
}
// Linear color space blending
// Explained https://www.youtube.com/watch?v=LKnqECcg6Gw
// Demonstrated http://codepen.io/osublake/pen/xGVVaN
const mixLinearColor = (from, to, v) => {
const fromExpo = from * from;
const expo = v * (to * to - fromExpo) + fromExpo;
return expo < 0 ? 0 : Math.sqrt(expo);
};
const colorTypes = [hex, rgba, hsla];
const getColorType = (v) => colorTypes.find((type) => type.test(v));
function asRGBA(color) {
const type = getColorType(color);
warning(Boolean(type), `'${color}' is not an animatable color. Use the equivalent color code instead.`);
if (!Boolean(type))
return false;
let model = type.parse(color);
if (type === hsla) {
// TODO Remove this cast - needed since Motion's stricter typing
model = hslaToRgba(model);
}
return model;
}
const mixColor = (from, to) => {
const fromRGBA = asRGBA(from);
const toRGBA = asRGBA(to);
if (!fromRGBA || !toRGBA) {
return mixImmediate(from, to);
}
const blended = { ...fromRGBA };
return (v) => {
blended.red = mixLinearColor(fromRGBA.red, toRGBA.red, v);
blended.green = mixLinearColor(fromRGBA.green, toRGBA.green, v);
blended.blue = mixLinearColor(fromRGBA.blue, toRGBA.blue, v);
blended.alpha = mixNumber$1(fromRGBA.alpha, toRGBA.alpha, v);
return rgba.transform(blended);
};
};
const invisibleValues = new Set(["none", "hidden"]);
/**
* Returns a function that, when provided a progress value between 0 and 1,
* will return the "none" or "hidden" string only when the progress is that of
* the origin or target.
*/
function mixVisibility(origin, target) {
if (invisibleValues.has(origin)) {
return (p) => (p <= 0 ? origin : target);
}
else {
return (p) => (p >= 1 ? target : origin);
}
}
function mixNumber(a, b) {
return (p) => mixNumber$1(a, b, p);
}
function getMixer(a) {
if (typeof a === "number") {
return mixNumber;
}
else if (typeof a === "string") {
return isCSSVariableToken(a)
? mixImmediate
: color.test(a)
? mixColor
: mixComplex;
}
else if (Array.isArray(a)) {
return mixArray;
}
else if (typeof a === "object") {
return color.test(a) ? mixColor : mixObject;
}
return mixImmediate;
}
function mixArray(a, b) {
const output = [...a];
const numValues = output.length;
const blendValue = a.map((v, i) => getMixer(v)(v, b[i]));
return (p) => {
for (let i = 0; i < numValues; i++) {
output[i] = blendValue[i](p);
}
return output;
};
}
function mixObject(a, b) {
const output = { ...a, ...b };
const blendValue = {};
for (const key in output) {
if (a[key] !== undefined && b[key] !== undefined) {
blendValue[key] = getMixer(a[key])(a[key], b[key]);
}
}
return (v) => {
for (const key in blendValue) {
output[key] = blendValue[key](v);
}
return output;
};
}
function matchOrder(origin, target) {
var _a;
const orderedOrigin = [];
const pointers = { color: 0, var: 0, number: 0 };
for (let i = 0; i < target.values.length; i++) {
const type = target.types[i];
const originIndex = origin.indexes[type][pointers[type]];
const originValue = (_a = origin.values[originIndex]) !== null && _a !== void 0 ? _a : 0;
orderedOrigin[i] = originValue;
pointers[type]++;
}
return orderedOrigin;
}
const mixComplex = (origin, target) => {
const template = complex.createTransformer(target);
const originStats = analyseComplexValue(origin);
const targetStats = analyseComplexValue(target);
const canInterpolate = originStats.indexes.var.length === targetStats.indexes.var.length &&
originStats.indexes.color.length === targetStats.indexes.color.length &&
originStats.indexes.number.length >= targetStats.indexes.number.length;
if (canInterpolate) {
if ((invisibleValues.has(origin) &&
!targetStats.values.length) ||
(invisibleValues.has(target) &&
!originStats.values.length)) {
return mixVisibility(origin, target);
}
return pipe(mixArray(matchOrder(originStats, targetStats), targetStats.values), template);
}
else {
warning(true, `Complex values '${origin}' and '${target}' too different to mix. Ensure all colors are of the same type, and that each contains the same quantity of number and color values. Falling back to instant transition.`);
return mixImmediate(origin, target);
}
};
function mix(from, to, p) {
if (typeof from === "number" &&
typeof to === "number" &&
typeof p === "number") {
return mixNumber$1(from, to, p);
}
const mixer = getMixer(from);
return mixer(from, to);
}
function createMixers(output, ease, customMixer) {
const mixers = [];
const mixerFactory = customMixer || mix;
const numMixers = output.length - 1;
for (let i = 0; i < numMixers; i++) {
let mixer = mixerFactory(output[i], output[i + 1]);
if (ease) {
const easingFunction = Array.isArray(ease) ? ease[i] || noop : ease;
mixer = pipe(easingFunction, mixer);
}
mixers.push(mixer);
}
return mixers;
}
/**
* Create a function that maps from a numerical input array to a generic output array.
*
* Accepts:
* - Numbers
* - Colors (hex, hsl, hsla, rgb, rgba)
* - Complex (combinations of one or more numbers or strings)
*
* ```jsx
* const mixColor = interpolate([0, 1], ['#fff', '#000'])
*
* mixColor(0.5) // 'rgba(128, 128, 128, 1)'
* ```
*
* TODO Revist this approach once we've moved to data models for values,
* probably not needed to pregenerate mixer functions.
*
* @public
*/
function interpolate(input, output, { clamp: isClamp = true, ease, mixer } = {}) {
const inputLength = input.length;
invariant(inputLength === output.length, "Both input and output ranges must be the same length");
/**
* If we're only provided a single input, we can just make a function
* that returns the output.
*/
if (inputLength === 1)
return () => output[0];
if (inputLength === 2 && input[0] === input[1])
return () => output[1];
// If input runs highest -> lowest, reverse both arrays
if (input[0] > input[inputLength - 1]) {
input = [...input].reverse();
output = [...output].reverse();
}
const mixers = createMixers(output, ease, mixer);
const numMixers = mixers.length;
const interpolator = (v) => {
let i = 0;
if (numMixers > 1) {
for (; i < input.length - 2; i++) {
if (v < input[i + 1])
break;
}
}
const progressInRange = progress(input[i], input[i + 1], v);
return mixers[i](progressInRange);
};
return isClamp
? (v) => interpolator(clamp(input[0], input[inputLength - 1], v))
: interpolator;
}
function fillOffset(offset, remaining) {
const min = offset[offset.length - 1];
for (let i = 1; i <= remaining; i++) {
const offsetProgress = progress(0, remaining, i);
offset.push(mixNumber$1(min, 1, offsetProgress));
}
}
function defaultOffset(arr) {
const offset = [0];
fillOffset(offset, arr.length - 1);
return offset;
}
function convertOffsetToTimes(offset, duration) {
return offset.map((o) => o * duration);
}
function defaultEasing(values, easing) {
return values.map(() => easing || easeInOut).splice(0, values.length - 1);
}
function keyframes({ duration = 300, keyframes: keyframeValues, times, ease = "easeInOut", }) {
/**
* Easing functions can be externally defined as strings. Here we convert them
* into actual functions.
*/
const easingFunctions = isEasingArray(ease)
? ease.map(easingDefinitionToFunction)
: easingDefinitionToFunction(ease);
/**
* This is the Iterator-spec return value. We ensure it's mutable rather than using a generator
* to reduce GC during animation.
*/
const state = {
done: false,
value: keyframeValues[0],
};
/**
* Create a times array based on the provided 0-1 offsets
*/
const absoluteTimes = convertOffsetToTimes(
// Only use the provided offsets if they're the correct length
// TODO Maybe we should warn here if there's a length mismatch
times && times.length === keyframeValues.length
? times
: defaultOffset(keyframeValues), duration);
const mapTimeToKeyframe = interpolate(absoluteTimes, keyframeValues, {
ease: Array.isArray(easingFunctions)
? easingFunctions
: defaultEasing(keyframeValues, easingFunctions),
});
return {
calculatedDuration: duration,
next: (t) => {
state.value = mapTimeToKeyframe(t);
state.done = t >= duration;
return state;
},
};
}
/**
* Implement a practical max duration for keyframe generation
* to prevent infinite loops
*/
const maxGeneratorDuration = 20000;
function calcGeneratorDuration(generator) {
let duration = 0;
const timeStep = 50;
let state = generator.next(duration);
while (!state.done && duration < maxGeneratorDuration) {
duration += timeStep;
state = generator.next(duration);
}
return duration >= maxGeneratorDuration ? Infinity : duration;
}
const frameloopDriver = (update) => {
const passTimestamp = ({ timestamp }) => update(timestamp);
return {
start: () => frame.update(passTimestamp, true),
stop: () => cancelFrame(passTimestamp),
/**
* If we're processing this frame we can use the
* framelocked timestamp to keep things in sync.
*/
now: () => (frameData.isProcessing ? frameData.timestamp : time.now()),
};
};
const generators = {
decay: inertia,
inertia,
tween: keyframes,
keyframes: keyframes,
spring,
};
const percentToProgress = (percent) => percent / 100;
/**
* Animation that runs on the main thread. Designed to be WAAPI-spec in the subset of
* features we expose publically. Mostly the compatibility is to ensure visual identity
* between both WAAPI and main thread animations.
*/
class MainThreadAnimation extends BaseAnimation {
constructor(options) {
super(options);
/**
* The time at which the animation was paused.
*/
this.holdTime = null;
/**
* The time at which the animation was cancelled.
*/
this.cancelTime = null;
/**
* The current time of the animation.
*/
this.currentTime = 0;
/**
* Playback speed as a factor. 0 would be stopped, -1 reverse and 2 double speed.
*/
this.playbackSpeed = 1;
/**
* The state of the animation to apply when the animation is resolved. This
* allows calls to the public API to control the animation before it is resolved,
* without us having to resolve it first.
*/
this.pendingPlayState = "running";
/**
* The time at which the animation was started.
*/
this.startTime = null;
this.state = "idle";
/**
* This method is bound to the instance to fix a pattern where
* animation.stop is returned as a reference from a useEffect.
*/
this.stop = () => {
this.resolver.cancel();
this.isStopped = true;
if (this.state === "idle")
return;
this.teardown();
const { onStop } = this.options;
onStop && onStop();
};
const { name, motionValue, element, keyframes } = this.options;
const KeyframeResolver$1 = (element === null || element === void 0 ? void 0 : element.KeyframeResolver) || KeyframeResolver;
const onResolved = (resolvedKeyframes, finalKeyframe) => this.onKeyframesResolved(resolvedKeyframes, finalKeyframe);
this.resolver = new KeyframeResolver$1(keyframes, onResolved, name, motionValue, element);
this.resolver.scheduleResolve();
}
flatten() {
super.flatten();
// If we've already resolved the animation, re-initialise it
if (this._resolved) {
Object.assign(this._resolved, this.initPlayback(this._resolved.keyframes));
}
}
initPlayback(keyframes$1) {
const { type = "keyframes", repeat = 0, repeatDelay = 0, repeatType, velocity = 0, } = this.options;
const generatorFactory = isGenerator(type)
? type
: generators[type] || keyframes;
/**
* If our generator doesn't support mixing numbers, we need to replace keyframes with
* [0, 100] and then make a function that maps that to the actual keyframes.
*
* 100 is chosen instead of 1 as it works nicer with spring animations.
*/
let mapPercentToKeyframes;
let mirroredGenerator;
if (generatorFactory !== keyframes &&
typeof keyframes$1[0] !== "number") {
if (process.env.NODE_ENV !== "production") {
invariant(keyframes$1.length === 2, `Only two keyframes currently supported with spring and inertia animations. Trying to animate ${keyframes$1}`);
}
mapPercentToKeyframes = pipe(percentToProgress, mix(keyframes$1[0], keyframes$1[1]));
keyframes$1 = [0, 100];
}
const generator = generatorFactory({ ...this.options, keyframes: keyframes$1 });
/**
* If we have a mirror repeat type we need to create a second generator that outputs the
* mirrored (not reversed) animation and later ping pong between the two generators.
*/
if (repeatType === "mirror") {
mirroredGenerator = generatorFactory({
...this.options,
keyframes: [...keyframes$1].reverse(),
velocity: -velocity,
});
}
/**
* If duration is undefined and we have repeat options,
* we need to calculate a duration from the generator.
*
* We set it to the generator itself to cache the duration.
* Any timeline resolver will need to have already precalculated
* the duration by this step.
*/
if (generator.calculatedDuration === null) {
generator.calculatedDuration = calcGeneratorDuration(generator);
}
const { calculatedDuration } = generator;
const resolvedDuration = calculatedDuration + repeatDelay;
const totalDuration = resolvedDuration * (repeat + 1) - repeatDelay;
return {
generator,
mirroredGenerator,
mapPercentToKeyframes,
calculatedDuration,
resolvedDuration,
totalDuration,
};
}
onPostResolved() {
const { autoplay = true } = this.options;
this.play();
if (this.pendingPlayState === "paused" || !autoplay) {
this.pause();
}
else {
this.state = this.pendingPlayState;
}
}
tick(timestamp, sample = false) {
const { resolved } = this;
// If the animations has failed to resolve, return the final keyframe.
if (!resolved) {
const { keyframes } = this.options;
return { done: true, value: keyframes[keyframes.length - 1] };
}
const { finalKeyframe, generator, mirroredGenerator, mapPercentToKeyframes, keyframes, calculatedDuration, totalDuration, resolvedDuration, } = resolved;
if (this.startTime === null)
return generator.next(0);
const { delay, repeat, repeatType, repeatDelay, onUpdate } = this.options;
/**
* requestAnimationFrame timestamps can come through as lower than
* the startTime as set by performance.now(). Here we prevent this,
* though in the future it could be possible to make setting startTime
* a pending operation that gets resolved here.
*/
if (this.speed > 0) {
this.startTime = Math.min(this.startTime, timestamp);
}
else if (this.speed < 0) {
this.startTime = Math.min(timestamp - totalDuration / this.speed, this.startTime);
}
// Update currentTime
if (sample) {
this.currentTime = timestamp;
}
else if (this.holdTime !== null) {
this.currentTime = this.holdTime;
}
else {
// Rounding the time because floating point arithmetic is not always accurate, e.g. 3000.367 - 1000.367 =
// 2000.0000000000002. This is a problem when we are comparing the currentTime with the duration, for
// example.
this.currentTime =
Math.round(timestamp - this.startTime) * this.speed;
}
// Rebase on delay
const timeWithoutDelay = this.currentTime - delay * (this.speed >= 0 ? 1 : -1);
const isInDelayPhase = this.speed >= 0
? timeWithoutDelay < 0
: timeWithoutDelay > totalDuration;
this.currentTime = Math.max(timeWithoutDelay, 0);
// If this animation has finished, set the current time to the total duration.
if (this.state === "finished" && this.holdTime === null) {
this.currentTime = totalDuration;
}
let elapsed = this.currentTime;
let frameGenerator = generator;
if (repeat) {
/**
* Get the current progress (0-1) of the animation. If t is >
* than duration we'll get values like 2.5 (midway through the
* third iteration)
*/
const progress = Math.min(this.currentTime, totalDuration) / resolvedDuration;
/**
* Get the current iteration (0 indexed). For instance the floor of
* 2.5 is 2.
*/
let currentIteration = Math.floor(progress);
/**
* Get the current progress of the iteration by taking the remainder
* so 2.5 is 0.5 through iteration 2
*/
let iterationProgress = progress % 1.0;
/**
* If iteration progress is 1 we count that as the end
* of the previous iteration.
*/
if (!iterationProgress && progress >= 1) {
iterationProgress = 1;
}
iterationProgress === 1 && currentIteration--;
currentIteration = Math.min(currentIteration, repeat + 1);
/**
* Reverse progress if we're not running in "normal" direction
*/
const isOddIteration = Boolean(currentIteration % 2);
if (isOddIteration) {
if (repeatType === "reverse") {
iterationProgress = 1 - iterationProgress;
if (repeatDelay) {
iterationProgress -= repeatDelay / resolvedDuration;
}
}
else if (repeatType === "mirror") {
frameGenerator = mirroredGenerator;
}
}
elapsed = clamp(0, 1, iterationProgress) * resolvedDuration;
}
/**
* If we're in negative time, set state as the initial keyframe.
* This prevents delay: x, duration: 0 animations from finishing
* instantly.
*/
const state = isInDelayPhase
? { done: false, value: keyframes[0] }
: frameGenerator.next(elapsed);
if (mapPercentToKeyframes) {
state.value = mapPercentToKeyframes(state.value);
}
let { done } = state;
if (!isInDelayPhase && calculatedDuration !== null) {
done =
this.speed >= 0
? this.currentTime >= totalDuration
: this.currentTime <= 0;
}
const isAnimationFinished = this.holdTime === null &&
(this.state === "finished" || (this.state === "running" && done));
if (isAnimationFinished && finalKeyframe !== undefined) {
state.value = getFinalKeyframe(keyframes, this.options, finalKeyframe);
}
if (onUpdate) {
onUpdate(state.value);
}
if (isAnimationFinished) {
this.finish();
}
return state;
}
get duration() {
const { resolved } = this;
return resolved ? millisecondsToSeconds(resolved.calculatedDuration) : 0;
}
get time() {
return millisecondsToSeconds(this.currentTime);
}
set time(newTime) {
newTime = secondsToMilliseconds(newTime);
this.currentTime = newTime;
if (this.holdTime !== null || this.speed === 0) {
this.holdTime = newTime;
}
else if (this.driver) {
this.startTime = this.driver.now() - newTime / this.speed;
}
}
get speed() {
return this.playbackSpeed;
}
set speed(newSpeed) {
const hasChanged = this.playbackSpeed !== newSpeed;
this.playbackSpeed = newSpeed;
if (hasChanged) {
this.time = millisecondsToSeconds(this.currentTime);
}
}
play() {
if (!this.resolver.isScheduled) {
this.resolver.resume();
}
if (!this._resolved) {
this.pendingPlayState = "running";
return;
}
if (this.isStopped)
return;
const { driver = frameloopDriver, onPlay, startTime } = this.options;
if (!this.driver) {
this.driver = driver((timestamp) => this.tick(timestamp));
}
onPlay && onPlay();
const now = this.driver.now();
if (this.holdTime !== null) {
this.startTime = now - this.holdTime;
}
else if (!this.startTime) {
this.startTime = startTime !== null && startTime !== void 0 ? startTime : this.calcStartTime();
}
else if (this.state === "finished") {
this.startTime = now;
}
if (this.state === "finished") {
this.updateFinishedPromise();
}
this.cancelTime = this.startTime;
this.holdTime = null;
/**
* Set playState to running only after we've used it in
* the previous logic.
*/
this.state = "running";
this.driver.start();
}
pause() {
var _a;
if (!this._resolved) {
this.pendingPlayState = "paused";
return;
}
this.state = "paused";
this.holdTime = (_a = this.currentTime) !== null && _a !== void 0 ? _a : 0;
}
complete() {
if (this.state !== "running") {
this.play();
}
this.pendingPlayState = this.state = "finished";
this.holdTime = null;
}
finish() {
this.teardown();
this.state = "finished";
const { onComplete } = this.options;
onComplete && onComplete();
}
cancel() {
if (this.cancelTime !== null) {
this.tick(this.cancelTime);
}
this.teardown();
this.updateFinishedPromise();
}
teardown() {
this.state = "idle";
this.stopDriver();
this.resolveFinishedPromise();
this.updateFinishedPromise();
this.startTime = this.cancelTime = null;
this.resolver.cancel();
}
stopDriver() {
if (!this.driver)
return;
this.driver.stop();
this.driver = undefined;
}
sample(time) {
this.startTime = 0;
return this.tick(time, true);
}
}
/**
* A list of values that can be hardware-accelerated.
*/
const acceleratedValues = new Set([
"opacity",
"clipPath",
"filter",
"transform",
// TODO: Can be accelerated but currently disabled until https://issues.chromium.org/issues/41491098 is resolved
// or until we implement support for linear() easing.
// "background-color"
]);
// Create a linear easing point for every 10 ms
const resolution = 10;
const generateLinearEasing = (easing, duration // as milliseconds
) => {
let points = "";
const numPoints = Math.max(Math.round(duration / resolution), 2);
for (let i = 0; i < numPoints; i++) {
points += easing(progress(0, numPoints - 1, i)) + ", ";
}
return `linear(${points.substring(0, points.length - 2)})`;
};
function memo(callback) {
let result;
return () => {
if (result === undefined)
result = callback();
return result;
};
}
/**
* Add the ability for test suites to manually set support flags
* to better test more environments.
*/
const supportsFlags = {
linearEasing: undefined,
};
function memoSupports(callback, supportsFlag) {
const memoized = memo(callback);
return () => { var _a; return (_a = supportsFlags[supportsFlag]) !== null && _a !== void 0 ? _a : memoized(); };
}
const supportsLinearEasing = /*@__PURE__*/ memoSupports(() => {
try {
document
.createElement("div")
.animate({ opacity: 0 }, { easing: "linear(0, 1)" });
}
catch (e) {
return false;
}
return true;
}, "linearEasing");
function isWaapiSupportedEasing(easing) {
return Boolean((typeof easing === "function" && supportsLinearEasing()) ||
!easing ||
(typeof easing === "string" &&
(easing in supportedWaapiEasing || supportsLinearEasing())) ||
isBezierDefinition(easing) ||
(Array.isArray(easing) && easing.every(isWaapiSupportedEasing)));
}
const cubicBezierAsString = ([a, b, c, d]) => `cubic-bezier(${a}, ${b}, ${c}, ${d})`;
const supportedWaapiEasing = {
linear: "linear",
ease: "ease",
easeIn: "ease-in",
easeOut: "ease-out",
easeInOut: "ease-in-out",
circIn: /*@__PURE__*/ cubicBezierAsString([0, 0.65, 0.55, 1]),
circOut: /*@__PURE__*/ cubicBezierAsString([0.55, 0, 1, 0.45]),
backIn: /*@__PURE__*/ cubicBezierAsString([0.31, 0.01, 0.66, -0.59]),
backOut: /*@__PURE__*/ cubicBezierAsString([0.33, 1.53, 0.69, 0.99]),
};
function mapEasingToNativeEasing(easing, duration) {
if (!easing) {
return undefined;
}
else if (typeof easing === "function" && supportsLinearEasing()) {
return generateLinearEasing(easing, duration);
}
else if (isBezierDefinition(easing)) {
return cubicBezierAsString(easing);
}
else if (Array.isArray(easing)) {
return easing.map((segmentEasing) => mapEasingToNativeEasing(segmentEasing, duration) ||
supportedWaapiEasing.easeOut);
}
else {
return supportedWaapiEasing[easing];
}
}
function startWaapiAnimation(element, valueName, keyframes, { delay = 0, duration = 300, repeat = 0, repeatType = "loop", ease = "easeInOut", times, } = {}) {
const keyframeOptions = { [valueName]: keyframes };
if (times)
keyframeOptions.offset = times;
const easing = mapEasingToNativeEasing(ease, duration);
/**
* If this is an easing array, apply to keyframes, not animation as a whole
*/
if (Array.isArray(easing))
keyframeOptions.easing = easing;
return element.animate(keyframeOptions, {
delay,
duration,
easing: !Array.isArray(easing) ? easing : "linear",
fill: "both",
iterations: repeat + 1,
direction: repeatType === "reverse" ? "alternate" : "normal",
});
}
function attachTimeline(animation, timeline) {
animation.timeline = timeline;
animation.onfinish = null;
}
const supportsWaapi = /*@__PURE__*/ memo(() => Object.hasOwnProperty.call(Element.prototype, "animate"));
/**
* 10ms is chosen here as it strikes a balance between smooth
* results (more than one keyframe per frame at 60fps) and
* keyframe quantity.
*/
const sampleDelta = 10; //ms
/**
* Implement a practical max duration for keyframe generation
* to prevent infinite loops
*/
const maxDuration = 20000;
/**
* Check if an animation can run natively via WAAPI or requires pregenerated keyframes.
* WAAPI doesn't support spring or function easings so we run these as JS animation before
* handing off.
*/
function requiresPregeneratedKeyframes(options) {
return (isGenerator(options.type) ||
options.type === "spring" ||
!isWaapiSupportedEasing(options.ease));
}
function pregenerateKeyframes(keyframes, options) {
/**
* Create a main-thread animation to pregenerate keyframes.
* We sample this at regular intervals to generate keyframes that we then
* linearly interpolate between.
*/
const sampleAnimation = new MainThreadAnimation({
...options,
keyframes,
repeat: 0,
delay: 0,
isGenerator: true,
});
let state = { done: false, value: keyframes[0] };
const pregeneratedKeyframes = [];
/**
* Bail after 20 seconds of pre-generated keyframes as it's likely
* we're heading for an infinite loop.
*/
let t = 0;
while (!state.done && t < maxDuration) {
state = sampleAnimation.sample(t);
pregeneratedKeyframes.push(state.value);
t += sampleDelta;
}
return {
times: undefined,
keyframes: pregeneratedKeyframes,
duration: t - sampleDelta,
ease: "linear",
};
}
const unsupportedEasingFunctions = {
anticipate,
backInOut,
circInOut,
};
function isUnsupportedEase(key) {
return key in unsupportedEasingFunctions;
}
class AcceleratedAnimation extends BaseAnimation {
constructor(options) {
super(options);
const { name, motionValue, element, keyframes } = this.options;
this.resolver = new DOMKeyframesResolver(keyframes, (resolvedKeyframes, finalKeyframe) => this.onKeyframesResolved(resolvedKeyframes, finalKeyframe), name, motionValue, element);
this.resolver.scheduleResolve();
}
initPlayback(keyframes, finalKeyframe) {
var _a;
let { duration = 300, times, ease, type, motionValue, name, startTime, } = this.options;
/**
* If element has since been unmounted, return false to indicate
* the animation failed to initialised.
*/
if (!((_a = motionValue.owner) === null || _a === void 0 ? void 0 : _a.current)) {
return false;
}
/**
* If the user has provided an easing function name that isn't supported
* by WAAPI (like "anticipate"), we need to provide the corressponding
* function. This will later get converted to a linear() easing function.
*/
if (typeof ease === "string" &&
supportsLinearEasing() &&
isUnsupportedEase(ease)) {
ease = unsupportedEasingFunctions[ease];
}
/**
* If this animation needs pre-generated keyframes then generate.
*/
if (requiresPregeneratedKeyframes(this.options)) {
const { onComplete, onUpdate, motionValue, element, ...options } = this.options;
const pregeneratedAnimation = pregenerateKeyframes(keyframes, options);
keyframes = pregeneratedAnimation.keyframes;
// If this is a very short animation, ensure we have
// at least two keyframes to animate between as older browsers
// can't animate between a single keyframe.
if (keyframes.length === 1) {
keyframes[1] = keyframes[0];
}
duration = pregeneratedAnimation.duration;
times = pregeneratedAnimation.times;
ease = pregeneratedAnimation.ease;
type = "keyframes";
}
const animation = startWaapiAnimation(motionValue.owner.current, name, keyframes, { ...this.options, duration, times, ease });
// Override the browser calculated startTime with one synchronised to other JS
// and WAAPI animations starting this event loop.
animation.startTime = startTime !== null && startTime !== void 0 ? startTime : this.calcStartTime();
if (this.pendingTimeline) {
attachTimeline(animation, this.pendingTimeline);
this.pendingTimeline = undefined;
}
else {
/**
* Prefer the `onfinish` prop as it's more widely supported than
* the `finished` promise.
*
* Here, we synchronously set the provided MotionValue to the end
* keyframe. If we didn't, when the WAAPI animation is finished it would
* be removed from the element which would then revert to its old styles.
*/
animation.onfinish = () => {
const { onComplete } = this.options;
motionValue.set(getFinalKeyframe(keyframes, this.options, finalKeyframe));
onComplete && onComplete();
this.cancel();
this.resolveFinishedPromise();
};
}
return {
animation,
duration,
times,
type,
ease,
keyframes: keyframes,
};
}
get duration() {
const { resolved } = this;
if (!resolved)
return 0;
const { duration } = resolved;
return millisecondsToSeconds(duration);
}
get time() {
const { resolved } = this;
if (!resolved)
return 0;
const { animation } = resolved;
return millisecondsToSeconds(animation.currentTime || 0);
}
set time(newTime) {
const { resolved } = this;
if (!resolved)
return;
const { animation } = resolved;
animation.currentTime = secondsToMilliseconds(newTime);
}
get speed() {
const { resolved } = this;
if (!resolved)
return 1;
const { animation } = resolved;
return animation.playbackRate;
}
set speed(newSpeed) {
const { resolved } = this;
if (!resolved)
return;
const { animation } = resolved;
animation.playbackRate = newSpeed;
}
get state() {
const { resolved } = this;
if (!resolved)
return "idle";
const { animation } = resolved;
return animation.playState;
}
get startTime() {
const { resolved } = this;
if (!resolved)
return null;
const { animation } = resolved;
// Coerce to number as TypeScript incorrectly types this
// as CSSNumberish
return animation.startTime;
}
/**
* Replace the default DocumentTimeline with another AnimationTimeline.
* Currently used for scroll animations.
*/
attachTimeline(timeline) {
if (!this._resolved) {
this.pendingTimeline = timeline;
}
else {
const { resolved } = this;
if (!resolved)
return noop;
const { animation } = resolved;
attachTimeline(animation, timeline);
}
return noop;
}
play() {
if (this.isStopped)
return;
const { resolved } = this;
if (!resolved)
return;
const { animation } = resolved;
if (animation.playState === "finished") {
this.updateFinishedPromise();
}
animation.play();
}
pause() {
const { resolved } = this;
if (!resolved)
return;
const { animation } = resolved;
animation.pause();
}
stop() {
this.resolver.cancel();
this.isStopped = true;
if (this.state === "idle")
return;
this.resolveFinishedPromise();
this.updateFinishedPromise();
const { resolved } = this;
if (!resolved)
return;
const { animation, keyframes, duration, type, ease, times } = resolved;
if (animation.playState === "idle" ||
animation.playState === "finished") {
return;
}
/**
* WAAPI doesn't natively have any interruption capabilities.
*
* Rather than read commited styles back out of the DOM, we can
* create a renderless JS animation and sample it twice to calculate
* its current value, "previous" value, and therefore allow
* Motion to calculate velocity for any subsequent animation.
*/
if (this.time) {
const { motionValue, onUpdate, onComplete, element, ...options } = this.options;
const sampleAnimation = new MainThreadAnimation({
...options,
keyframes,
duration,
type,
ease,
times,
isGenerator: true,
});
const sampleTime = secondsToMilliseconds(this.time);
motionValue.setWithVelocity(sampleAnimation.sample(sampleTime - sampleDelta).value, sampleAnimation.sample(sampleTime).value, sampleDelta);
}
const { onStop } = this.options;
onStop && onStop();
this.cancel();
}
complete() {
const { resolved } = this;
if (!resolved)
return;
resolved.animation.finish();
}
cancel() {
const { resolved } = this;
if (!resolved)
return;
resolved.animation.cancel();
}
static supports(options) {
const { motionValue, name, repeatDelay, repeatType, damping, type } = options;
return (supportsWaapi() &&
name &&
acceleratedValues.has(name) &&
motionValue &&
motionValue.owner &&
motionValue.owner.current instanceof HTMLElement &&
/**
* If we're outputting values to onUpdate then we can't use WAAPI as there's
* no way to read the value from WAAPI every frame.
*/
!motionValue.owner.getProps().onUpdate &&
!repeatDelay &&
repeatType !== "mirror" &&
damping !== 0 &&
type !== "inertia");
}
}
const supportsScrollTimeline = memo(() => window.ScrollTimeline !== undefined);
class GroupPlaybackControls {
constructor(animations) {
// Bound to accomodate common `return animation.stop` pattern
this.stop = () => this.runAll("stop");
this.animations = animations.filter(Boolean);
}
then(onResolve, onReject) {
return Promise.all(this.animations).then(onResolve).catch(onReject);
}
/**
* TODO: Filter out cancelled or stopped animations before returning
*/
getAll(propName) {
return this.animations[0][propName];
}
setAll(propName, newValue) {
for (let i = 0; i < this.animations.length; i++) {
this.animations[i][propName] = newValue;
}
}
attachTimeline(timeline, fallback) {
const subscriptions = this.animations.map((animation) => {
if (supportsScrollTimeline() && animation.attachTimeline) {
return animation.attachTimeline(timeline);
}
else {
return fallback(animation);
}
});
return () => {
subscriptions.forEach((cancel, i) => {
cancel && cancel();
this.animations[i].stop();
});
};
}
get time() {
return this.getAll("time");
}
set time(time) {
this.setAll("time", time);
}
get speed() {
return this.getAll("speed");
}
set speed(speed) {
this.setAll("speed", speed);
}
get startTime() {
return this.getAll("startTime");
}
get duration() {
let max = 0;
for (let i = 0; i < this.animations.length; i++) {
max = Math.max(max, this.animations[i].duration);
}
return max;
}
runAll(methodName) {
this.animations.forEach((controls) => controls[methodName]());
}
flatten() {
this.runAll("flatten");
}
play() {
this.runAll("play");
}
pause() {
this.runAll("pause");
}
cancel() {
this.runAll("cancel");
}
complete() {
this.runAll("complete");
}
}
/**
* Decide whether a transition is defined on a given Transition.
* This filters out orchestration options and returns true
* if any options are left.
*/
function isTransitionDefined({ when, delay: _delay, delayChildren, staggerChildren, staggerDirection, repeat, repeatType, repeatDelay, from, elapsed, ...transition }) {
return !!Object.keys(transition).length;
}
const animateMotionValue = (name, value, target, transition = {}, element, isHandoff) => (onComplete) => {
const valueTransition = getValueTransition(transition, name) || {};
/**
* Most transition values are currently completely overwritten by value-specific
* transitions. In the future it'd be nicer to blend these transitions. But for now
* delay actually does inherit from the root transition if not value-specific.
*/
const delay = valueTransition.delay || transition.delay || 0;
/**
* Elapsed isn't a public transition option but can be passed through from
* optimized appear effects in milliseconds.
*/
let { elapsed = 0 } = transition;
elapsed = elapsed - secondsToMilliseconds(delay);
let options = {
keyframes: Array.isArray(target) ? target : [null, target],
ease: "easeOut",
velocity: value.getVelocity(),
...valueTransition,
delay: -elapsed,
onUpdate: (v) => {
value.set(v);
valueTransition.onUpdate && valueTransition.onUpdate(v);
},
onComplete: () => {
onComplete();
valueTransition.onComplete && valueTransition.onComplete();
},
name,
motionValue: value,
element: isHandoff ? undefined : element,
};
/**
* If there's no transition defined for this value, we can generate
* unqiue transition settings for this value.
*/
if (!isTransitionDefined(valueTransition)) {
options = {
...options,
...getDefaultTransition(name, options),
};
}
/**
* Both WAAPI and our internal animation functions use durations
* as defined by milliseconds, while our external API defines them
* as seconds.
*/
if (options.duration) {
options.duration = secondsToMilliseconds(options.duration);
}
if (options.repeatDelay) {
options.repeatDelay = secondsToMilliseconds(options.repeatDelay);
}
if (options.from !== undefined) {
options.keyframes[0] = options.from;
}
let shouldSkip = false;
if (options.type === false ||
(options.duration === 0 && !options.repeatDelay)) {
options.duration = 0;
if (options.delay === 0) {
shouldSkip = true;
}
}
/**
* If we can or must skip creating the animation, and apply only
* the final keyframe, do so. We also check once keyframes are resolved but
* this early check prevents the need to create an animation at all.
*/
if (shouldSkip && !isHandoff && value.get() !== undefined) {
const finalKeyframe = getFinalKeyframe(options.keyframes, valueTransition);
if (finalKeyframe !== undefined) {
frame.update(() => {
options.onUpdate(finalKeyframe);
options.onComplete();
});
// We still want to return some animation controls here rather
// than returning undefined
return new GroupPlaybackControls([]);
}
}
/**
* Animate via WAAPI if possible. If this is a handoff animation, the optimised animation will be running via
* WAAPI. Therefore, this animation must be JS to ensure it runs "under" the
* optimised animation.
*/
if (!isHandoff && AcceleratedAnimation.supports(options)) {
return new AcceleratedAnimation(options);
}
else {
return new MainThreadAnimation(options);
}
};
const isCustomValue = (v) => {
return Boolean(v && typeof v === "object" && v.mix && v.toValue);
};
const resolveFinalValueInKeyframes = (v) => {
// TODO maybe throw if v.length - 1 is placeholder token?
return isKeyframesTarget(v) ? v[v.length - 1] || 0 : v;
};
function addUniqueItem(arr, item) {
if (arr.indexOf(item) === -1)
arr.push(item);
}
function removeItem(arr, item) {
const index = arr.indexOf(item);
if (index > -1)
arr.splice(index, 1);
}
class SubscriptionManager {
constructor() {
this.subscriptions = [];
}
add(handler) {
addUniqueItem(this.subscriptions, handler);
return () => removeItem(this.subscriptions, handler);
}
notify(a, b, c) {
const numSubscriptions = this.subscriptions.length;
if (!numSubscriptions)
return;
if (numSubscriptions === 1) {
/**
* If there's only a single handler we can just call it without invoking a loop.
*/
this.subscriptions[0](a, b, c);
}
else {
for (let i = 0; i < numSubscriptions; i++) {
/**
* Check whether the handler exists before firing as it's possible
* the subscriptions were modified during this loop running.
*/
const handler = this.subscriptions[i];
handler && handler(a, b, c);
}
}
}
getSize() {
return this.subscriptions.length;
}
clear() {
this.subscriptions.length = 0;
}
}
const warned = new Set();
function warnOnce(condition, message, element) {
if (condition || warned.has(message))
return;
console.warn(message);
if (element)
console.warn(element);
warned.add(message);
}
/**
* Maximum time between the value of two frames, beyond which we
* assume the velocity has since been 0.
*/
const MAX_VELOCITY_DELTA = 30;
const isFloat = (value) => {
return !isNaN(parseFloat(value));
};
/**
* `MotionValue` is used to track the state and velocity of motion values.
*
* @public
*/
class MotionValue {
/**
* @param init - The initiating value
* @param config - Optional configuration options
*
* - `transformer`: A function to transform incoming values with.
*
* @internal
*/
constructor(init, options = {}) {
/**
* This will be replaced by the build step with the latest version number.
* When MotionValues are provided to motion components, warn if versions are mixed.
*/
this.version = "11.11.17";
/**
* Tracks whether this value can output a velocity. Currently this is only true
* if the value is numerical, but we might be able to widen the scope here and support
* other value types.
*
* @internal
*/
this.canTrackVelocity = null;
/**
* An object containing a SubscriptionManager for each active event.
*/
this.events = {};
this.updateAndNotify = (v, render = true) => {
const currentTime = time.now();
/**
* If we're updating the value during another frame or eventloop
* than the previous frame, then the we set the previous frame value
* to current.
*/
if (this.updatedAt !== currentTime) {
this.setPrevFrameValue();
}
this.prev = this.current;
this.setCurrent(v);
// Update update subscribers
if (this.current !== this.prev && this.events.change) {
this.events.change.notify(this.current);
}
// Update render subscribers
if (render && this.events.renderRequest) {
this.events.renderRequest.notify(this.current);
}
};
this.hasAnimated = false;
this.setCurrent(init);
this.owner = options.owner;
}
setCurrent(current) {
this.current = current;
this.updatedAt = time.now();
if (this.canTrackVelocity === null && current !== undefined) {
this.canTrackVelocity = isFloat(this.current);
}
}
setPrevFrameValue(prevFrameValue = this.current) {
this.prevFrameValue = prevFrameValue;
this.prevUpdatedAt = this.updatedAt;
}
/**
* Adds a function that will be notified when the `MotionValue` is updated.
*
* It returns a function that, when called, will cancel the subscription.
*
* When calling `onChange` inside a React component, it should be wrapped with the
* `useEffect` hook. As it returns an unsubscribe function, this should be returned
* from the `useEffect` function to ensure you don't add duplicate subscribers..
*
* ```jsx
* export const MyComponent = () => {
* const x = useMotionValue(0)
* const y = useMotionValue(0)
* const opacity = useMotionValue(1)
*
* useEffect(() => {
* function updateOpacity() {
* const maxXY = Math.max(x.get(), y.get())
* const newOpacity = transform(maxXY, [0, 100], [1, 0])
* opacity.set(newOpacity)
* }
*
* const unsubscribeX = x.on("change", updateOpacity)
* const unsubscribeY = y.on("change", updateOpacity)
*
* return () => {
* unsubscribeX()
* unsubscribeY()
* }
* }, [])
*
* return <motion.div style={{ x }} />
* }
* ```
*
* @param subscriber - A function that receives the latest value.
* @returns A function that, when called, will cancel this subscription.
*
* @deprecated
*/
onChange(subscription) {
if (process.env.NODE_ENV !== "production") {
warnOnce(false, `value.onChange(callback) is deprecated. Switch to value.on("change", callback).`);
}
return this.on("change", subscription);
}
on(eventName, callback) {
if (!this.events[eventName]) {
this.events[eventName] = new SubscriptionManager();
}
const unsubscribe = this.events[eventName].add(callback);
if (eventName === "change") {
return () => {
unsubscribe();
/**
* If we have no more change listeners by the start
* of the next frame, stop active animations.
*/
frame.read(() => {
if (!this.events.change.getSize()) {
this.stop();
}
});
};
}
return unsubscribe;
}
clearListeners() {
for (const eventManagers in this.events) {
this.events[eventManagers].clear();
}
}
/**
* Attaches a passive effect to the `MotionValue`.
*
* @internal
*/
attach(passiveEffect, stopPassiveEffect) {
this.passiveEffect = passiveEffect;
this.stopPassiveEffect = stopPassiveEffect;
}
/**
* Sets the state of the `MotionValue`.
*
* @remarks
*
* ```jsx
* const x = useMotionValue(0)
* x.set(10)
* ```
*
* @param latest - Latest value to set.
* @param render - Whether to notify render subscribers. Defaults to `true`
*
* @public
*/
set(v, render = true) {
if (!render || !this.passiveEffect) {
this.updateAndNotify(v, render);
}
else {
this.passiveEffect(v, this.updateAndNotify);
}
}
setWithVelocity(prev, current, delta) {
this.set(current);
this.prev = undefined;
this.prevFrameValue = prev;
this.prevUpdatedAt = this.updatedAt - delta;
}
/**
* Set the state of the `MotionValue`, stopping any active animations,
* effects, and resets velocity to `0`.
*/
jump(v, endAnimation = true) {
this.updateAndNotify(v);
this.prev = v;
this.prevUpdatedAt = this.prevFrameValue = undefined;
endAnimation && this.stop();
if (this.stopPassiveEffect)
this.stopPassiveEffect();
}
/**
* Returns the latest state of `MotionValue`
*
* @returns - The latest state of `MotionValue`
*
* @public
*/
get() {
return this.current;
}
/**
* @public
*/
getPrevious() {
return this.prev;
}
/**
* Returns the latest velocity of `MotionValue`
*
* @returns - The latest velocity of `MotionValue`. Returns `0` if the state is non-numerical.
*
* @public
*/
getVelocity() {
const currentTime = time.now();
if (!this.canTrackVelocity ||
this.prevFrameValue === undefined ||
currentTime - this.updatedAt > MAX_VELOCITY_DELTA) {
return 0;
}
const delta = Math.min(this.updatedAt - this.prevUpdatedAt, MAX_VELOCITY_DELTA);
// Casts because of parseFloat's poor typing
return velocityPerSecond(parseFloat(this.current) -
parseFloat(this.prevFrameValue), delta);
}
/**
* Registers a new animation to control this `MotionValue`. Only one
* animation can drive a `MotionValue` at one time.
*
* ```jsx
* value.start()
* ```
*
* @param animation - A function that starts the provided animation
*
* @internal
*/
start(startAnimation) {
this.stop();
return new Promise((resolve) => {
this.hasAnimated = true;
this.animation = startAnimation(resolve);
if (this.events.animationStart) {
this.events.animationStart.notify();
}
}).then(() => {
if (this.events.animationComplete) {
this.events.animationComplete.notify();
}
this.clearAnimation();
});
}
/**
* Stop the currently active animation.
*
* @public
*/
stop() {
if (this.animation) {
this.animation.stop();
if (this.events.animationCancel) {
this.events.animationCancel.notify();
}
}
this.clearAnimation();
}
/**
* Returns `true` if this value is currently animating.
*
* @public
*/
isAnimating() {
return !!this.animation;
}
clearAnimation() {
delete this.animation;
}
/**
* Destroy and clean up subscribers to this `MotionValue`.
*
* The `MotionValue` hooks like `useMotionValue` and `useTransform` automatically
* handle the lifecycle of the returned `MotionValue`, so this method is only necessary if you've manually
* created a `MotionValue` via the `motionValue` function.
*
* @public
*/
destroy() {
this.clearListeners();
this.stop();
if (this.stopPassiveEffect) {
this.stopPassiveEffect();
}
}
}
function motionValue(init, options) {
return new MotionValue(init, options);
}
/**
* Set VisualElement's MotionValue, creating a new MotionValue for it if
* it doesn't exist.
*/
function setMotionValue(visualElement, key, value) {
if (visualElement.hasValue(key)) {
visualElement.getValue(key).set(value);
}
else {
visualElement.addValue(key, motionValue(value));
}
}
function setTarget(visualElement, definition) {
const resolved = resolveVariant(visualElement, definition);
let { transitionEnd = {}, transition = {}, ...target } = resolved || {};
target = { ...target, ...transitionEnd };
for (const key in target) {
const value = resolveFinalValueInKeyframes(target[key]);
setMotionValue(visualElement, key, value);
}
}
/**
* Convert camelCase to dash-case properties.
*/
const camelToDash = (str) => str.replace(/([a-z])([A-Z])/gu, "$1-$2").toLowerCase();
const optimizedAppearDataId = "framerAppearId";
const optimizedAppearDataAttribute = "data-" + camelToDash(optimizedAppearDataId);
function getOptimisedAppearId(visualElement) {
return visualElement.props[optimizedAppearDataAttribute];
}
const isMotionValue = (value) => Boolean(value && value.getVelocity);
function isWillChangeMotionValue(value) {
return Boolean(isMotionValue(value) && value.add);
}
function addValueToWillChange(visualElement, key) {
const willChange = visualElement.getValue("willChange");
/**
* It could be that a user has set willChange to a regular MotionValue,
* in which case we can't add the value to it.
*/
if (isWillChangeMotionValue(willChange)) {
return willChange.add(key);
}
}
/**
* Decide whether we should block this animation. Previously, we achieved this
* just by checking whether the key was listed in protectedKeys, but this
* posed problems if an animation was triggered by afterChildren and protectedKeys
* had been set to true in the meantime.
*/
function shouldBlockAnimation({ protectedKeys, needsAnimating }, key) {
const shouldBlock = protectedKeys.hasOwnProperty(key) && needsAnimating[key] !== true;
needsAnimating[key] = false;
return shouldBlock;
}
function animateTarget(visualElement, targetAndTransition, { delay = 0, transitionOverride, type } = {}) {
var _a;
let { transition = visualElement.getDefaultTransition(), transitionEnd, ...target } = targetAndTransition;
if (transitionOverride)
transition = transitionOverride;
const animations = [];
const animationTypeState = type &&
visualElement.animationState &&
visualElement.animationState.getState()[type];
for (const key in target) {
const value = visualElement.getValue(key, (_a = visualElement.latestValues[key]) !== null && _a !== void 0 ? _a : null);
const valueTarget = target[key];
if (valueTarget === undefined ||
(animationTypeState &&
shouldBlockAnimation(animationTypeState, key))) {
continue;
}
const valueTransition = {
delay,
...getValueTransition(transition || {}, key),
};
/**
* If this is the first time a value is being animated, check
* to see if we're handling off from an existing animation.
*/
let isHandoff = false;
if (window.MotionHandoffAnimation) {
const appearId = getOptimisedAppearId(visualElement);
if (appearId) {
const startTime = window.MotionHandoffAnimation(appearId, key, frame);
if (startTime !== null) {
valueTransition.startTime = startTime;
isHandoff = true;
}
}
}
addValueToWillChange(visualElement, key);
value.start(animateMotionValue(key, value, valueTarget, visualElement.shouldReduceMotion && transformProps.has(key)
? { type: false }
: valueTransition, visualElement, isHandoff));
const animation = value.animation;
if (animation) {
animations.push(animation);
}
}
if (transitionEnd) {
Promise.all(animations).then(() => {
frame.update(() => {
transitionEnd && setTarget(visualElement, transitionEnd);
});
});
}
return animations;
}
function animateVariant(visualElement, variant, options = {}) {
var _a;
const resolved = resolveVariant(visualElement, variant, options.type === "exit"
? (_a = visualElement.presenceContext) === null || _a === void 0 ? void 0 : _a.custom
: undefined);
let { transition = visualElement.getDefaultTransition() || {} } = resolved || {};
if (options.transitionOverride) {
transition = options.transitionOverride;
}
/**
* If we have a variant, create a callback that runs it as an animation.
* Otherwise, we resolve a Promise immediately for a composable no-op.
*/
const getAnimation = resolved
? () => Promise.all(animateTarget(visualElement, resolved, options))
: () => Promise.resolve();
/**
* If we have children, create a callback that runs all their animations.
* Otherwise, we resolve a Promise immediately for a composable no-op.
*/
const getChildAnimations = visualElement.variantChildren && visualElement.variantChildren.size
? (forwardDelay = 0) => {
const { delayChildren = 0, staggerChildren, staggerDirection, } = transition;
return animateChildren(visualElement, variant, delayChildren + forwardDelay, staggerChildren, staggerDirection, options);
}
: () => Promise.resolve();
/**
* If the transition explicitly defines a "when" option, we need to resolve either
* this animation or all children animations before playing the other.
*/
const { when } = transition;
if (when) {
const [first, last] = when === "beforeChildren"
? [getAnimation, getChildAnimations]
: [getChildAnimations, getAnimation];
return first().then(() => last());
}
else {
return Promise.all([getAnimation(), getChildAnimations(options.delay)]);
}
}
function animateChildren(visualElement, variant, delayChildren = 0, staggerChildren = 0, staggerDirection = 1, options) {
const animations = [];
const maxStaggerDuration = (visualElement.variantChildren.size - 1) * staggerChildren;
const generateStaggerDuration = staggerDirection === 1
? (i = 0) => i * staggerChildren
: (i = 0) => maxStaggerDuration - i * staggerChildren;
Array.from(visualElement.variantChildren)
.sort(sortByTreeOrder)
.forEach((child, i) => {
child.notify("AnimationStart", variant);
animations.push(animateVariant(child, variant, {
...options,
delay: delayChildren + generateStaggerDuration(i),
}).then(() => child.notify("AnimationComplete", variant)));
});
return Promise.all(animations);
}
function sortByTreeOrder(a, b) {
return a.sortNodePosition(b);
}
function animateVisualElement(visualElement, definition, options = {}) {
visualElement.notify("AnimationStart", definition);
let animation;
if (Array.isArray(definition)) {
const animations = definition.map((variant) => animateVariant(visualElement, variant, options));
animation = Promise.all(animations);
}
else if (typeof definition === "string") {
animation = animateVariant(visualElement, definition, options);
}
else {
const resolvedDefinition = typeof definition === "function"
? resolveVariant(visualElement, definition, options.custom)
: definition;
animation = Promise.all(animateTarget(visualElement, resolvedDefinition, options));
}
return animation.then(() => {
visualElement.notify("AnimationComplete", definition);
});
}
const numVariantProps = variantProps.length;
function getVariantContext(visualElement) {
if (!visualElement)
return undefined;
if (!visualElement.isControllingVariants) {
const context = visualElement.parent
? getVariantContext(visualElement.parent) || {}
: {};
if (visualElement.props.initial !== undefined) {
context.initial = visualElement.props.initial;
}
return context;
}
const context = {};
for (let i = 0; i < numVariantProps; i++) {
const name = variantProps[i];
const prop = visualElement.props[name];
if (isVariantLabel(prop) || prop === false) {
context[name] = prop;
}
}
return context;
}
const reversePriorityOrder = [...variantPriorityOrder].reverse();
const numAnimationTypes = variantPriorityOrder.length;
function animateList(visualElement) {
return (animations) => Promise.all(animations.map(({ animation, options }) => animateVisualElement(visualElement, animation, options)));
}
function createAnimationState(visualElement) {
let animate = animateList(visualElement);
let state = createState();
let isInitialRender = true;
/**
* This function will be used to reduce the animation definitions for
* each active animation type into an object of resolved values for it.
*/
const buildResolvedTypeValues = (type) => (acc, definition) => {
var _a;
const resolved = resolveVariant(visualElement, definition, type === "exit"
? (_a = visualElement.presenceContext) === null || _a === void 0 ? void 0 : _a.custom
: undefined);
if (resolved) {
const { transition, transitionEnd, ...target } = resolved;
acc = { ...acc, ...target, ...transitionEnd };
}
return acc;
};
/**
* This just allows us to inject mocked animation functions
* @internal
*/
function setAnimateFunction(makeAnimator) {
animate = makeAnimator(visualElement);
}
/**
* When we receive new props, we need to:
* 1. Create a list of protected keys for each type. This is a directory of
* value keys that are currently being "handled" by types of a higher priority
* so that whenever an animation is played of a given type, these values are
* protected from being animated.
* 2. Determine if an animation type needs animating.
* 3. Determine if any values have been removed from a type and figure out
* what to animate those to.
*/
function animateChanges(changedActiveType) {
const { props } = visualElement;
const context = getVariantContext(visualElement.parent) || {};
/**
* A list of animations that we'll build into as we iterate through the animation
* types. This will get executed at the end of the function.
*/
const animations = [];
/**
* Keep track of which values have been removed. Then, as we hit lower priority
* animation types, we can check if they contain removed values and animate to that.
*/
const removedKeys = new Set();
/**
* A dictionary of all encountered keys. This is an object to let us build into and
* copy it without iteration. Each time we hit an animation type we set its protected
* keys - the keys its not allowed to animate - to the latest version of this object.
*/
let encounteredKeys = {};
/**
* If a variant has been removed at a given index, and this component is controlling
* variant animations, we want to ensure lower-priority variants are forced to animate.
*/
let removedVariantIndex = Infinity;
/**
* Iterate through all animation types in reverse priority order. For each, we want to
* detect which values it's handling and whether or not they've changed (and therefore
* need to be animated). If any values have been removed, we want to detect those in
* lower priority props and flag for animation.
*/
for (let i = 0; i < numAnimationTypes; i++) {
const type = reversePriorityOrder[i];
const typeState = state[type];
const prop = props[type] !== undefined
? props[type]
: context[type];
const propIsVariant = isVariantLabel(prop);
/**
* If this type has *just* changed isActive status, set activeDelta
* to that status. Otherwise set to null.
*/
const activeDelta = type === changedActiveType ? typeState.isActive : null;
if (activeDelta === false)
removedVariantIndex = i;
/**
* If this prop is an inherited variant, rather than been set directly on the
* component itself, we want to make sure we allow the parent to trigger animations.
*
* TODO: Can probably change this to a !isControllingVariants check
*/
let isInherited = prop === context[type] &&
prop !== props[type] &&
propIsVariant;
/**
*
*/
if (isInherited &&
isInitialRender &&
visualElement.manuallyAnimateOnMount) {
isInherited = false;
}
/**
* Set all encountered keys so far as the protected keys for this type. This will
* be any key that has been animated or otherwise handled by active, higher-priortiy types.
*/
typeState.protectedKeys = { ...encounteredKeys };
// Check if we can skip analysing this prop early
if (
// If it isn't active and hasn't *just* been set as inactive
(!typeState.isActive && activeDelta === null) ||
// If we didn't and don't have any defined prop for this animation type
(!prop && !typeState.prevProp) ||
// Or if the prop doesn't define an animation
isAnimationControls(prop) ||
typeof prop === "boolean") {
continue;
}
/**
* As we go look through the values defined on this type, if we detect
* a changed value or a value that was removed in a higher priority, we set
* this to true and add this prop to the animation list.
*/
const variantDidChange = checkVariantsDidChange(typeState.prevProp, prop);
let shouldAnimateType = variantDidChange ||
// If we're making this variant active, we want to always make it active
(type === changedActiveType &&
typeState.isActive &&
!isInherited &&
propIsVariant) ||
// If we removed a higher-priority variant (i is in reverse order)
(i > removedVariantIndex && propIsVariant);
let handledRemovedValues = false;
/**
* As animations can be set as variant lists, variants or target objects, we
* coerce everything to an array if it isn't one already
*/
const definitionList = Array.isArray(prop) ? prop : [prop];
/**
* Build an object of all the resolved values. We'll use this in the subsequent
* animateChanges calls to determine whether a value has changed.
*/
let resolvedValues = definitionList.reduce(buildResolvedTypeValues(type), {});
if (activeDelta === false)
resolvedValues = {};
/**
* Now we need to loop through all the keys in the prev prop and this prop,
* and decide:
* 1. If the value has changed, and needs animating
* 2. If it has been removed, and needs adding to the removedKeys set
* 3. If it has been removed in a higher priority type and needs animating
* 4. If it hasn't been removed in a higher priority but hasn't changed, and
* needs adding to the type's protectedKeys list.
*/
const { prevResolvedValues = {} } = typeState;
const allKeys = {
...prevResolvedValues,
...resolvedValues,
};
const markToAnimate = (key) => {
shouldAnimateType = true;
if (removedKeys.has(key)) {
handledRemovedValues = true;
removedKeys.delete(key);
}
typeState.needsAnimating[key] = true;
const motionValue = visualElement.getValue(key);
if (motionValue)
motionValue.liveStyle = false;
};
for (const key in allKeys) {
const next = resolvedValues[key];
const prev = prevResolvedValues[key];
// If we've already handled this we can just skip ahead
if (encounteredKeys.hasOwnProperty(key))
continue;
/**
* If the value has changed, we probably want to animate it.
*/
let valueHasChanged = false;
if (isKeyframesTarget(next) && isKeyframesTarget(prev)) {
valueHasChanged = !shallowCompare(next, prev);
}
else {
valueHasChanged = next !== prev;
}
if (valueHasChanged) {
if (next !== undefined && next !== null) {
// If next is defined and doesn't equal prev, it needs animating
markToAnimate(key);
}
else {
// If it's undefined, it's been removed.
removedKeys.add(key);
}
}
else if (next !== undefined && removedKeys.has(key)) {
/**
* If next hasn't changed and it isn't undefined, we want to check if it's
* been removed by a higher priority
*/
markToAnimate(key);
}
else {
/**
* If it hasn't changed, we add it to the list of protected values
* to ensure it doesn't get animated.
*/
typeState.protectedKeys[key] = true;
}
}
/**
* Update the typeState so next time animateChanges is called we can compare the
* latest prop and resolvedValues to these.
*/
typeState.prevProp = prop;
typeState.prevResolvedValues = resolvedValues;
/**
*
*/
if (typeState.isActive) {
encounteredKeys = { ...encounteredKeys, ...resolvedValues };
}
if (isInitialRender && visualElement.blockInitialAnimation) {
shouldAnimateType = false;
}
/**
* If this is an inherited prop we want to skip this animation
* unless the inherited variants haven't changed on this render.
*/
const willAnimateViaParent = isInherited && variantDidChange;
const needsAnimating = !willAnimateViaParent || handledRemovedValues;
if (shouldAnimateType && needsAnimating) {
animations.push(...definitionList.map((animation) => ({
animation: animation,
options: { type },
})));
}
}
/**
* If there are some removed value that haven't been dealt with,
* we need to create a new animation that falls back either to the value
* defined in the style prop, or the last read value.
*/
if (removedKeys.size) {
const fallbackAnimation = {};
removedKeys.forEach((key) => {
const fallbackTarget = visualElement.getBaseTarget(key);
const motionValue = visualElement.getValue(key);
if (motionValue)
motionValue.liveStyle = true;
// @ts-expect-error - @mattgperry to figure if we should do something here
fallbackAnimation[key] = fallbackTarget !== null && fallbackTarget !== void 0 ? fallbackTarget : null;
});
animations.push({ animation: fallbackAnimation });
}
let shouldAnimate = Boolean(animations.length);
if (isInitialRender &&
(props.initial === false || props.initial === props.animate) &&
!visualElement.manuallyAnimateOnMount) {
shouldAnimate = false;
}
isInitialRender = false;
return shouldAnimate ? animate(animations) : Promise.resolve();
}
/**
* Change whether a certain animation type is active.
*/
function setActive(type, isActive) {
var _a;
// If the active state hasn't changed, we can safely do nothing here
if (state[type].isActive === isActive)
return Promise.resolve();
// Propagate active change to children
(_a = visualElement.variantChildren) === null || _a === void 0 ? void 0 : _a.forEach((child) => { var _a; return (_a = child.animationState) === null || _a === void 0 ? void 0 : _a.setActive(type, isActive); });
state[type].isActive = isActive;
const animations = animateChanges(type);
for (const key in state) {
state[key].protectedKeys = {};
}
return animations;
}
return {
animateChanges,
setActive,
setAnimateFunction,
getState: () => state,
reset: () => {
state = createState();
isInitialRender = true;
},
};
}
function checkVariantsDidChange(prev, next) {
if (typeof next === "string") {
return next !== prev;
}
else if (Array.isArray(next)) {
return !shallowCompare(next, prev);
}
return false;
}
function createTypeState(isActive = false) {
return {
isActive,
protectedKeys: {},
needsAnimating: {},
prevResolvedValues: {},
};
}
function createState() {
return {
animate: createTypeState(true),
whileInView: createTypeState(),
whileHover: createTypeState(),
whileTap: createTypeState(),
whileDrag: createTypeState(),
whileFocus: createTypeState(),
exit: createTypeState(),
};
}
class Feature {
constructor(node) {
this.isMounted = false;
this.node = node;
}
update() { }
}
class AnimationFeature extends Feature {
/**
* We dynamically generate the AnimationState manager as it contains a reference
* to the underlying animation library. We only want to load that if we load this,
* so people can optionally code split it out using the `m` component.
*/
constructor(node) {
super(node);
node.animationState || (node.animationState = createAnimationState(node));
}
updateAnimationControlsSubscription() {
const { animate } = this.node.getProps();
if (isAnimationControls(animate)) {
this.unmountControls = animate.subscribe(this.node);
}
}
/**
* Subscribe any provided AnimationControls to the component's VisualElement
*/
mount() {
this.updateAnimationControlsSubscription();
}
update() {
const { animate } = this.node.getProps();
const { animate: prevAnimate } = this.node.prevProps || {};
if (animate !== prevAnimate) {
this.updateAnimationControlsSubscription();
}
}
unmount() {
var _a;
this.node.animationState.reset();
(_a = this.unmountControls) === null || _a === void 0 ? void 0 : _a.call(this);
}
}
let id$1 = 0;
class ExitAnimationFeature extends Feature {
constructor() {
super(...arguments);
this.id = id$1++;
}
update() {
if (!this.node.presenceContext)
return;
const { isPresent, onExitComplete } = this.node.presenceContext;
const { isPresent: prevIsPresent } = this.node.prevPresenceContext || {};
if (!this.node.animationState || isPresent === prevIsPresent) {
return;
}
const exitAnimation = this.node.animationState.setActive("exit", !isPresent);
if (onExitComplete && !isPresent) {
exitAnimation.then(() => onExitComplete(this.id));
}
}
mount() {
const { register } = this.node.presenceContext || {};
if (register) {
this.unmount = register(this.id);
}
}
unmount() { }
}
const animations = {
animation: {
Feature: AnimationFeature,
},
exit: {
Feature: ExitAnimationFeature,
},
};
const isPrimaryPointer = (event) => {
if (event.pointerType === "mouse") {
return typeof event.button !== "number" || event.button <= 0;
}
else {
/**
* isPrimary is true for all mice buttons, whereas every touch point
* is regarded as its own input. So subsequent concurrent touch points
* will be false.
*
* Specifically match against false here as incomplete versions of
* PointerEvents in very old browser might have it set as undefined.
*/
return event.isPrimary !== false;
}
};
function extractEventInfo(event, pointType = "page") {
return {
point: {
x: event[`${pointType}X`],
y: event[`${pointType}Y`],
},
};
}
const addPointerInfo = (handler) => {
return (event) => isPrimaryPointer(event) && handler(event, extractEventInfo(event));
};
function addDomEvent(target, eventName, handler, options = { passive: true }) {
target.addEventListener(eventName, handler, options);
return () => target.removeEventListener(eventName, handler);
}
function addPointerEvent(target, eventName, handler, options) {
return addDomEvent(target, eventName, addPointerInfo(handler), options);
}
const distance = (a, b) => Math.abs(a - b);
function distance2D(a, b) {
// Multi-dimensional
const xDelta = distance(a.x, b.x);
const yDelta = distance(a.y, b.y);
return Math.sqrt(xDelta ** 2 + yDelta ** 2);
}
/**
* @internal
*/
class PanSession {
constructor(event, handlers, { transformPagePoint, contextWindow, dragSnapToOrigin = false } = {}) {
/**
* @internal
*/
this.startEvent = null;
/**
* @internal
*/
this.lastMoveEvent = null;
/**
* @internal
*/
this.lastMoveEventInfo = null;
/**
* @internal
*/
this.handlers = {};
/**
* @internal
*/
this.contextWindow = window;
this.updatePoint = () => {
if (!(this.lastMoveEvent && this.lastMoveEventInfo))
return;
const info = getPanInfo(this.lastMoveEventInfo, this.history);
const isPanStarted = this.startEvent !== null;
// Only start panning if the offset is larger than 3 pixels. If we make it
// any larger than this we'll want to reset the pointer history
// on the first update to avoid visual snapping to the cursoe.
const isDistancePastThreshold = distance2D(info.offset, { x: 0, y: 0 }) >= 3;
if (!isPanStarted && !isDistancePastThreshold)
return;
const { point } = info;
const { timestamp } = frameData;
this.history.push({ ...point, timestamp });
const { onStart, onMove } = this.handlers;
if (!isPanStarted) {
onStart && onStart(this.lastMoveEvent, info);
this.startEvent = this.lastMoveEvent;
}
onMove && onMove(this.lastMoveEvent, info);
};
this.handlePointerMove = (event, info) => {
this.lastMoveEvent = event;
this.lastMoveEventInfo = transformPoint(info, this.transformPagePoint);
// Throttle mouse move event to once per frame
frame.update(this.updatePoint, true);
};
this.handlePointerUp = (event, info) => {
this.end();
const { onEnd, onSessionEnd, resumeAnimation } = this.handlers;
if (this.dragSnapToOrigin)
resumeAnimation && resumeAnimation();
if (!(this.lastMoveEvent && this.lastMoveEventInfo))
return;
const panInfo = getPanInfo(event.type === "pointercancel"
? this.lastMoveEventInfo
: transformPoint(info, this.transformPagePoint), this.history);
if (this.startEvent && onEnd) {
onEnd(event, panInfo);
}
onSessionEnd && onSessionEnd(event, panInfo);
};
// If we have more than one touch, don't start detecting this gesture
if (!isPrimaryPointer(event))
return;
this.dragSnapToOrigin = dragSnapToOrigin;
this.handlers = handlers;
this.transformPagePoint = transformPagePoint;
this.contextWindow = contextWindow || window;
const info = extractEventInfo(event);
const initialInfo = transformPoint(info, this.transformPagePoint);
const { point } = initialInfo;
const { timestamp } = frameData;
this.history = [{ ...point, timestamp }];
const { onSessionStart } = handlers;
onSessionStart &&
onSessionStart(event, getPanInfo(initialInfo, this.history));
this.removeListeners = pipe(addPointerEvent(this.contextWindow, "pointermove", this.handlePointerMove), addPointerEvent(this.contextWindow, "pointerup", this.handlePointerUp), addPointerEvent(this.contextWindow, "pointercancel", this.handlePointerUp));
}
updateHandlers(handlers) {
this.handlers = handlers;
}
end() {
this.removeListeners && this.removeListeners();
cancelFrame(this.updatePoint);
}
}
function transformPoint(info, transformPagePoint) {
return transformPagePoint ? { point: transformPagePoint(info.point) } : info;
}
function subtractPoint(a, b) {
return { x: a.x - b.x, y: a.y - b.y };
}
function getPanInfo({ point }, history) {
return {
point,
delta: subtractPoint(point, lastDevicePoint(history)),
offset: subtractPoint(point, startDevicePoint(history)),
velocity: getVelocity(history, 0.1),
};
}
function startDevicePoint(history) {
return history[0];
}
function lastDevicePoint(history) {
return history[history.length - 1];
}
function getVelocity(history, timeDelta) {
if (history.length < 2) {
return { x: 0, y: 0 };
}
let i = history.length - 1;
let timestampedPoint = null;
const lastPoint = lastDevicePoint(history);
while (i >= 0) {
timestampedPoint = history[i];
if (lastPoint.timestamp - timestampedPoint.timestamp >
secondsToMilliseconds(timeDelta)) {
break;
}
i--;
}
if (!timestampedPoint) {
return { x: 0, y: 0 };
}
const time = millisecondsToSeconds(lastPoint.timestamp - timestampedPoint.timestamp);
if (time === 0) {
return { x: 0, y: 0 };
}
const currentVelocity = {
x: (lastPoint.x - timestampedPoint.x) / time,
y: (lastPoint.y - timestampedPoint.y) / time,
};
if (currentVelocity.x === Infinity) {
currentVelocity.x = 0;
}
if (currentVelocity.y === Infinity) {
currentVelocity.y = 0;
}
return currentVelocity;
}
function createLock(name) {
let lock = null;
return () => {
const openLock = () => {
lock = null;
};
if (lock === null) {
lock = name;
return openLock;
}
return false;
};
}
const globalHorizontalLock = createLock("dragHorizontal");
const globalVerticalLock = createLock("dragVertical");
function getGlobalLock(drag) {
let lock = false;
if (drag === "y") {
lock = globalVerticalLock();
}
else if (drag === "x") {
lock = globalHorizontalLock();
}
else {
const openHorizontal = globalHorizontalLock();
const openVertical = globalVerticalLock();
if (openHorizontal && openVertical) {
lock = () => {
openHorizontal();
openVertical();
};
}
else {
// Release the locks because we don't use them
if (openHorizontal)
openHorizontal();
if (openVertical)
openVertical();
}
}
return lock;
}
function isDragActive() {
// Check the gesture lock - if we get it, it means no drag gesture is active
// and we can safely fire the tap gesture.
const openGestureLock = getGlobalLock(true);
if (!openGestureLock)
return true;
openGestureLock();
return false;
}
function isRefObject(ref) {
return (ref &&
typeof ref === "object" &&
Object.prototype.hasOwnProperty.call(ref, "current"));
}
const SCALE_PRECISION = 0.0001;
const SCALE_MIN = 1 - SCALE_PRECISION;
const SCALE_MAX = 1 + SCALE_PRECISION;
const TRANSLATE_PRECISION = 0.01;
const TRANSLATE_MIN = 0 - TRANSLATE_PRECISION;
const TRANSLATE_MAX = 0 + TRANSLATE_PRECISION;
function calcLength(axis) {
return axis.max - axis.min;
}
function isNear(value, target, maxDistance) {
return Math.abs(value - target) <= maxDistance;
}
function calcAxisDelta(delta, source, target, origin = 0.5) {
delta.origin = origin;
delta.originPoint = mixNumber$1(source.min, source.max, delta.origin);
delta.scale = calcLength(target) / calcLength(source);
delta.translate =
mixNumber$1(target.min, target.max, delta.origin) - delta.originPoint;
if ((delta.scale >= SCALE_MIN && delta.scale <= SCALE_MAX) ||
isNaN(delta.scale)) {
delta.scale = 1.0;
}
if ((delta.translate >= TRANSLATE_MIN &&
delta.translate <= TRANSLATE_MAX) ||
isNaN(delta.translate)) {
delta.translate = 0.0;
}
}
function calcBoxDelta(delta, source, target, origin) {
calcAxisDelta(delta.x, source.x, target.x, origin ? origin.originX : undefined);
calcAxisDelta(delta.y, source.y, target.y, origin ? origin.originY : undefined);
}
function calcRelativeAxis(target, relative, parent) {
target.min = parent.min + relative.min;
target.max = target.min + calcLength(relative);
}
function calcRelativeBox(target, relative, parent) {
calcRelativeAxis(target.x, relative.x, parent.x);
calcRelativeAxis(target.y, relative.y, parent.y);
}
function calcRelativeAxisPosition(target, layout, parent) {
target.min = layout.min - parent.min;
target.max = target.min + calcLength(layout);
}
function calcRelativePosition(target, layout, parent) {
calcRelativeAxisPosition(target.x, layout.x, parent.x);
calcRelativeAxisPosition(target.y, layout.y, parent.y);
}
/**
* Apply constraints to a point. These constraints are both physical along an
* axis, and an elastic factor that determines how much to constrain the point
* by if it does lie outside the defined parameters.
*/
function applyConstraints(point, { min, max }, elastic) {
if (min !== undefined && point < min) {
// If we have a min point defined, and this is outside of that, constrain
point = elastic
? mixNumber$1(min, point, elastic.min)
: Math.max(point, min);
}
else if (max !== undefined && point > max) {
// If we have a max point defined, and this is outside of that, constrain
point = elastic
? mixNumber$1(max, point, elastic.max)
: Math.min(point, max);
}
return point;
}
/**
* Calculate constraints in terms of the viewport when defined relatively to the
* measured axis. This is measured from the nearest edge, so a max constraint of 200
* on an axis with a max value of 300 would return a constraint of 500 - axis length
*/
function calcRelativeAxisConstraints(axis, min, max) {
return {
min: min !== undefined ? axis.min + min : undefined,
max: max !== undefined
? axis.max + max - (axis.max - axis.min)
: undefined,
};
}
/**
* Calculate constraints in terms of the viewport when
* defined relatively to the measured bounding box.
*/
function calcRelativeConstraints(layoutBox, { top, left, bottom, right }) {
return {
x: calcRelativeAxisConstraints(layoutBox.x, left, right),
y: calcRelativeAxisConstraints(layoutBox.y, top, bottom),
};
}
/**
* Calculate viewport constraints when defined as another viewport-relative axis
*/
function calcViewportAxisConstraints(layoutAxis, constraintsAxis) {
let min = constraintsAxis.min - layoutAxis.min;
let max = constraintsAxis.max - layoutAxis.max;
// If the constraints axis is actually smaller than the layout axis then we can
// flip the constraints
if (constraintsAxis.max - constraintsAxis.min <
layoutAxis.max - layoutAxis.min) {
[min, max] = [max, min];
}
return { min, max };
}
/**
* Calculate viewport constraints when defined as another viewport-relative box
*/
function calcViewportConstraints(layoutBox, constraintsBox) {
return {
x: calcViewportAxisConstraints(layoutBox.x, constraintsBox.x),
y: calcViewportAxisConstraints(layoutBox.y, constraintsBox.y),
};
}
/**
* Calculate a transform origin relative to the source axis, between 0-1, that results
* in an asthetically pleasing scale/transform needed to project from source to target.
*/
function calcOrigin$1(source, target) {
let origin = 0.5;
const sourceLength = calcLength(source);
const targetLength = calcLength(target);
if (targetLength > sourceLength) {
origin = progress(target.min, target.max - sourceLength, source.min);
}
else if (sourceLength > targetLength) {
origin = progress(source.min, source.max - targetLength, target.min);
}
return clamp(0, 1, origin);
}
/**
* Rebase the calculated viewport constraints relative to the layout.min point.
*/
function rebaseAxisConstraints(layout, constraints) {
const relativeConstraints = {};
if (constraints.min !== undefined) {
relativeConstraints.min = constraints.min - layout.min;
}
if (constraints.max !== undefined) {
relativeConstraints.max = constraints.max - layout.min;
}
return relativeConstraints;
}
const defaultElastic = 0.35;
/**
* Accepts a dragElastic prop and returns resolved elastic values for each axis.
*/
function resolveDragElastic(dragElastic = defaultElastic) {
if (dragElastic === false) {
dragElastic = 0;
}
else if (dragElastic === true) {
dragElastic = defaultElastic;
}
return {
x: resolveAxisElastic(dragElastic, "left", "right"),
y: resolveAxisElastic(dragElastic, "top", "bottom"),
};
}
function resolveAxisElastic(dragElastic, minLabel, maxLabel) {
return {
min: resolvePointElastic(dragElastic, minLabel),
max: resolvePointElastic(dragElastic, maxLabel),
};
}
function resolvePointElastic(dragElastic, label) {
return typeof dragElastic === "number"
? dragElastic
: dragElastic[label] || 0;
}
const createAxisDelta = () => ({
translate: 0,
scale: 1,
origin: 0,
originPoint: 0,
});
const createDelta = () => ({
x: createAxisDelta(),
y: createAxisDelta(),
});
const createAxis = () => ({ min: 0, max: 0 });
const createBox = () => ({
x: createAxis(),
y: createAxis(),
});
function eachAxis(callback) {
return [callback("x"), callback("y")];
}
/**
* Bounding boxes tend to be defined as top, left, right, bottom. For various operations
* it's easier to consider each axis individually. This function returns a bounding box
* as a map of single-axis min/max values.
*/
function convertBoundingBoxToBox({ top, left, right, bottom, }) {
return {
x: { min: left, max: right },
y: { min: top, max: bottom },
};
}
function convertBoxToBoundingBox({ x, y }) {
return { top: y.min, right: x.max, bottom: y.max, left: x.min };
}
/**
* Applies a TransformPoint function to a bounding box. TransformPoint is usually a function
* provided by Framer to allow measured points to be corrected for device scaling. This is used
* when measuring DOM elements and DOM event points.
*/
function transformBoxPoints(point, transformPoint) {
if (!transformPoint)
return point;
const topLeft = transformPoint({ x: point.left, y: point.top });
const bottomRight = transformPoint({ x: point.right, y: point.bottom });
return {
top: topLeft.y,
left: topLeft.x,
bottom: bottomRight.y,
right: bottomRight.x,
};
}
function isIdentityScale(scale) {
return scale === undefined || scale === 1;
}
function hasScale({ scale, scaleX, scaleY }) {
return (!isIdentityScale(scale) ||
!isIdentityScale(scaleX) ||
!isIdentityScale(scaleY));
}
function hasTransform(values) {
return (hasScale(values) ||
has2DTranslate(values) ||
values.z ||
values.rotate ||
values.rotateX ||
values.rotateY ||
values.skewX ||
values.skewY);
}
function has2DTranslate(values) {
return is2DTranslate(values.x) || is2DTranslate(values.y);
}
function is2DTranslate(value) {
return value && value !== "0%";
}
/**
* Scales a point based on a factor and an originPoint
*/
function scalePoint(point, scale, originPoint) {
const distanceFromOrigin = point - originPoint;
const scaled = scale * distanceFromOrigin;
return originPoint + scaled;
}
/**
* Applies a translate/scale delta to a point
*/
function applyPointDelta(point, translate, scale, originPoint, boxScale) {
if (boxScale !== undefined) {
point = scalePoint(point, boxScale, originPoint);
}
return scalePoint(point, scale, originPoint) + translate;
}
/**
* Applies a translate/scale delta to an axis
*/
function applyAxisDelta(axis, translate = 0, scale = 1, originPoint, boxScale) {
axis.min = applyPointDelta(axis.min, translate, scale, originPoint, boxScale);
axis.max = applyPointDelta(axis.max, translate, scale, originPoint, boxScale);
}
/**
* Applies a translate/scale delta to a box
*/
function applyBoxDelta(box, { x, y }) {
applyAxisDelta(box.x, x.translate, x.scale, x.originPoint);
applyAxisDelta(box.y, y.translate, y.scale, y.originPoint);
}
const TREE_SCALE_SNAP_MIN = 0.999999999999;
const TREE_SCALE_SNAP_MAX = 1.0000000000001;
/**
* Apply a tree of deltas to a box. We do this to calculate the effect of all the transforms
* in a tree upon our box before then calculating how to project it into our desired viewport-relative box
*
* This is the final nested loop within updateLayoutDelta for future refactoring
*/
function applyTreeDeltas(box, treeScale, treePath, isSharedTransition = false) {
const treeLength = treePath.length;
if (!treeLength)
return;
// Reset the treeScale
treeScale.x = treeScale.y = 1;
let node;
let delta;
for (let i = 0; i < treeLength; i++) {
node = treePath[i];
delta = node.projectionDelta;
/**
* TODO: Prefer to remove this, but currently we have motion components with
* display: contents in Framer.
*/
const { visualElement } = node.options;
if (visualElement &&
visualElement.props.style &&
visualElement.props.style.display === "contents") {
continue;
}
if (isSharedTransition &&
node.options.layoutScroll &&
node.scroll &&
node !== node.root) {
transformBox(box, {
x: -node.scroll.offset.x,
y: -node.scroll.offset.y,
});
}
if (delta) {
// Incoporate each ancestor's scale into a culmulative treeScale for this component
treeScale.x *= delta.x.scale;
treeScale.y *= delta.y.scale;
// Apply each ancestor's calculated delta into this component's recorded layout box
applyBoxDelta(box, delta);
}
if (isSharedTransition && hasTransform(node.latestValues)) {
transformBox(box, node.latestValues);
}
}
/**
* Snap tree scale back to 1 if it's within a non-perceivable threshold.
* This will help reduce useless scales getting rendered.
*/
if (treeScale.x < TREE_SCALE_SNAP_MAX &&
treeScale.x > TREE_SCALE_SNAP_MIN) {
treeScale.x = 1.0;
}
if (treeScale.y < TREE_SCALE_SNAP_MAX &&
treeScale.y > TREE_SCALE_SNAP_MIN) {
treeScale.y = 1.0;
}
}
function translateAxis(axis, distance) {
axis.min = axis.min + distance;
axis.max = axis.max + distance;
}
/**
* Apply a transform to an axis from the latest resolved motion values.
* This function basically acts as a bridge between a flat motion value map
* and applyAxisDelta
*/
function transformAxis(axis, axisTranslate, axisScale, boxScale, axisOrigin = 0.5) {
const originPoint = mixNumber$1(axis.min, axis.max, axisOrigin);
// Apply the axis delta to the final axis
applyAxisDelta(axis, axisTranslate, axisScale, originPoint, boxScale);
}
/**
* Apply a transform to a box from the latest resolved motion values.
*/
function transformBox(box, transform) {
transformAxis(box.x, transform.x, transform.scaleX, transform.scale, transform.originX);
transformAxis(box.y, transform.y, transform.scaleY, transform.scale, transform.originY);
}
function measureViewportBox(instance, transformPoint) {
return convertBoundingBoxToBox(transformBoxPoints(instance.getBoundingClientRect(), transformPoint));
}
function measurePageBox(element, rootProjectionNode, transformPagePoint) {
const viewportBox = measureViewportBox(element, transformPagePoint);
const { scroll } = rootProjectionNode;
if (scroll) {
translateAxis(viewportBox.x, scroll.offset.x);
translateAxis(viewportBox.y, scroll.offset.y);
}
return viewportBox;
}
// Fixes https://github.com/framer/motion/issues/2270
const getContextWindow = ({ current }) => {
return current ? current.ownerDocument.defaultView : null;
};
const elementDragControls = new WeakMap();
/**
*
*/
// let latestPointerEvent: PointerEvent
class VisualElementDragControls {
constructor(visualElement) {
// This is a reference to the global drag gesture lock, ensuring only one component
// can "capture" the drag of one or both axes.
// TODO: Look into moving this into pansession?
this.openGlobalLock = null;
this.isDragging = false;
this.currentDirection = null;
this.originPoint = { x: 0, y: 0 };
/**
* The permitted boundaries of travel, in pixels.
*/
this.constraints = false;
this.hasMutatedConstraints = false;
/**
* The per-axis resolved elastic values.
*/
this.elastic = createBox();
this.visualElement = visualElement;
}
start(originEvent, { snapToCursor = false } = {}) {
/**
* Don't start dragging if this component is exiting
*/
const { presenceContext } = this.visualElement;
if (presenceContext && presenceContext.isPresent === false)
return;
const onSessionStart = (event) => {
const { dragSnapToOrigin } = this.getProps();
// Stop or pause any animations on both axis values immediately. This allows the user to throw and catch
// the component.
dragSnapToOrigin ? this.pauseAnimation() : this.stopAnimation();
if (snapToCursor) {
this.snapToCursor(extractEventInfo(event, "page").point);
}
};
const onStart = (event, info) => {
// Attempt to grab the global drag gesture lock - maybe make this part of PanSession
const { drag, dragPropagation, onDragStart } = this.getProps();
if (drag && !dragPropagation) {
if (this.openGlobalLock)
this.openGlobalLock();
this.openGlobalLock = getGlobalLock(drag);
// If we don 't have the lock, don't start dragging
if (!this.openGlobalLock)
return;
}
this.isDragging = true;
this.currentDirection = null;
this.resolveConstraints();
if (this.visualElement.projection) {
this.visualElement.projection.isAnimationBlocked = true;
this.visualElement.projection.target = undefined;
}
/**
* Record gesture origin
*/
eachAxis((axis) => {
let current = this.getAxisMotionValue(axis).get() || 0;
/**
* If the MotionValue is a percentage value convert to px
*/
if (percent.test(current)) {
const { projection } = this.visualElement;
if (projection && projection.layout) {
const measuredAxis = projection.layout.layoutBox[axis];
if (measuredAxis) {
const length = calcLength(measuredAxis);
current = length * (parseFloat(current) / 100);
}
}
}
this.originPoint[axis] = current;
});
// Fire onDragStart event
if (onDragStart) {
frame.postRender(() => onDragStart(event, info));
}
addValueToWillChange(this.visualElement, "transform");
const { animationState } = this.visualElement;
animationState && animationState.setActive("whileDrag", true);
};
const onMove = (event, info) => {
// latestPointerEvent = event
const { dragPropagation, dragDirectionLock, onDirectionLock, onDrag, } = this.getProps();
// If we didn't successfully receive the gesture lock, early return.
if (!dragPropagation && !this.openGlobalLock)
return;
const { offset } = info;
// Attempt to detect drag direction if directionLock is true
if (dragDirectionLock && this.currentDirection === null) {
this.currentDirection = getCurrentDirection(offset);
// If we've successfully set a direction, notify listener
if (this.currentDirection !== null) {
onDirectionLock && onDirectionLock(this.currentDirection);
}
return;
}
// Update each point with the latest position
this.updateAxis("x", info.point, offset);
this.updateAxis("y", info.point, offset);
/**
* Ideally we would leave the renderer to fire naturally at the end of
* this frame but if the element is about to change layout as the result
* of a re-render we want to ensure the browser can read the latest
* bounding box to ensure the pointer and element don't fall out of sync.
*/
this.visualElement.render();
/**
* This must fire after the render call as it might trigger a state
* change which itself might trigger a layout update.
*/
onDrag && onDrag(event, info);
};
const onSessionEnd = (event, info) => this.stop(event, info);
const resumeAnimation = () => eachAxis((axis) => {
var _a;
return this.getAnimationState(axis) === "paused" &&
((_a = this.getAxisMotionValue(axis).animation) === null || _a === void 0 ? void 0 : _a.play());
});
const { dragSnapToOrigin } = this.getProps();
this.panSession = new PanSession(originEvent, {
onSessionStart,
onStart,
onMove,
onSessionEnd,
resumeAnimation,
}, {
transformPagePoint: this.visualElement.getTransformPagePoint(),
dragSnapToOrigin,
contextWindow: getContextWindow(this.visualElement),
});
}
stop(event, info) {
const isDragging = this.isDragging;
this.cancel();
if (!isDragging)
return;
const { velocity } = info;
this.startAnimation(velocity);
const { onDragEnd } = this.getProps();
if (onDragEnd) {
frame.postRender(() => onDragEnd(event, info));
}
}
cancel() {
this.isDragging = false;
const { projection, animationState } = this.visualElement;
if (projection) {
projection.isAnimationBlocked = false;
}
this.panSession && this.panSession.end();
this.panSession = undefined;
const { dragPropagation } = this.getProps();
if (!dragPropagation && this.openGlobalLock) {
this.openGlobalLock();
this.openGlobalLock = null;
}
animationState && animationState.setActive("whileDrag", false);
}
updateAxis(axis, _point, offset) {
const { drag } = this.getProps();
// If we're not dragging this axis, do an early return.
if (!offset || !shouldDrag(axis, drag, this.currentDirection))
return;
const axisValue = this.getAxisMotionValue(axis);
let next = this.originPoint[axis] + offset[axis];
// Apply constraints
if (this.constraints && this.constraints[axis]) {
next = applyConstraints(next, this.constraints[axis], this.elastic[axis]);
}
axisValue.set(next);
}
resolveConstraints() {
var _a;
const { dragConstraints, dragElastic } = this.getProps();
const layout = this.visualElement.projection &&
!this.visualElement.projection.layout
? this.visualElement.projection.measure(false)
: (_a = this.visualElement.projection) === null || _a === void 0 ? void 0 : _a.layout;
const prevConstraints = this.constraints;
if (dragConstraints && isRefObject(dragConstraints)) {
if (!this.constraints) {
this.constraints = this.resolveRefConstraints();
}
}
else {
if (dragConstraints && layout) {
this.constraints = calcRelativeConstraints(layout.layoutBox, dragConstraints);
}
else {
this.constraints = false;
}
}
this.elastic = resolveDragElastic(dragElastic);
/**
* If we're outputting to external MotionValues, we want to rebase the measured constraints
* from viewport-relative to component-relative.
*/
if (prevConstraints !== this.constraints &&
layout &&
this.constraints &&
!this.hasMutatedConstraints) {
eachAxis((axis) => {
if (this.constraints !== false &&
this.getAxisMotionValue(axis)) {
this.constraints[axis] = rebaseAxisConstraints(layout.layoutBox[axis], this.constraints[axis]);
}
});
}
}
resolveRefConstraints() {
const { dragConstraints: constraints, onMeasureDragConstraints } = this.getProps();
if (!constraints || !isRefObject(constraints))
return false;
const constraintsElement = constraints.current;
invariant(constraintsElement !== null, "If `dragConstraints` is set as a React ref, that ref must be passed to another component's `ref` prop.");
const { projection } = this.visualElement;
// TODO
if (!projection || !projection.layout)
return false;
const constraintsBox = measurePageBox(constraintsElement, projection.root, this.visualElement.getTransformPagePoint());
let measuredConstraints = calcViewportConstraints(projection.layout.layoutBox, constraintsBox);
/**
* If there's an onMeasureDragConstraints listener we call it and
* if different constraints are returned, set constraints to that
*/
if (onMeasureDragConstraints) {
const userConstraints = onMeasureDragConstraints(convertBoxToBoundingBox(measuredConstraints));
this.hasMutatedConstraints = !!userConstraints;
if (userConstraints) {
measuredConstraints = convertBoundingBoxToBox(userConstraints);
}
}
return measuredConstraints;
}
startAnimation(velocity) {
const { drag, dragMomentum, dragElastic, dragTransition, dragSnapToOrigin, onDragTransitionEnd, } = this.getProps();
const constraints = this.constraints || {};
const momentumAnimations = eachAxis((axis) => {
if (!shouldDrag(axis, drag, this.currentDirection)) {
return;
}
let transition = (constraints && constraints[axis]) || {};
if (dragSnapToOrigin)
transition = { min: 0, max: 0 };
/**
* Overdamp the boundary spring if `dragElastic` is disabled. There's still a frame
* of spring animations so we should look into adding a disable spring option to `inertia`.
* We could do something here where we affect the `bounceStiffness` and `bounceDamping`
* using the value of `dragElastic`.
*/
const bounceStiffness = dragElastic ? 200 : 1000000;
const bounceDamping = dragElastic ? 40 : 10000000;
const inertia = {
type: "inertia",
velocity: dragMomentum ? velocity[axis] : 0,
bounceStiffness,
bounceDamping,
timeConstant: 750,
restDelta: 1,
restSpeed: 10,
...dragTransition,
...transition,
};
// If we're not animating on an externally-provided `MotionValue` we can use the
// component's animation controls which will handle interactions with whileHover (etc),
// otherwise we just have to animate the `MotionValue` itself.
return this.startAxisValueAnimation(axis, inertia);
});
// Run all animations and then resolve the new drag constraints.
return Promise.all(momentumAnimations).then(onDragTransitionEnd);
}
startAxisValueAnimation(axis, transition) {
const axisValue = this.getAxisMotionValue(axis);
addValueToWillChange(this.visualElement, axis);
return axisValue.start(animateMotionValue(axis, axisValue, 0, transition, this.visualElement, false));
}
stopAnimation() {
eachAxis((axis) => this.getAxisMotionValue(axis).stop());
}
pauseAnimation() {
eachAxis((axis) => { var _a; return (_a = this.getAxisMotionValue(axis).animation) === null || _a === void 0 ? void 0 : _a.pause(); });
}
getAnimationState(axis) {
var _a;
return (_a = this.getAxisMotionValue(axis).animation) === null || _a === void 0 ? void 0 : _a.state;
}
/**
* Drag works differently depending on which props are provided.
*
* - If _dragX and _dragY are provided, we output the gesture delta directly to those motion values.
* - Otherwise, we apply the delta to the x/y motion values.
*/
getAxisMotionValue(axis) {
const dragKey = `_drag${axis.toUpperCase()}`;
const props = this.visualElement.getProps();
const externalMotionValue = props[dragKey];
return externalMotionValue
? externalMotionValue
: this.visualElement.getValue(axis, (props.initial
? props.initial[axis]
: undefined) || 0);
}
snapToCursor(point) {
eachAxis((axis) => {
const { drag } = this.getProps();
// If we're not dragging this axis, do an early return.
if (!shouldDrag(axis, drag, this.currentDirection))
return;
const { projection } = this.visualElement;
const axisValue = this.getAxisMotionValue(axis);
if (projection && projection.layout) {
const { min, max } = projection.layout.layoutBox[axis];
axisValue.set(point[axis] - mixNumber$1(min, max, 0.5));
}
});
}
/**
* When the viewport resizes we want to check if the measured constraints
* have changed and, if so, reposition the element within those new constraints
* relative to where it was before the resize.
*/
scalePositionWithinConstraints() {
if (!this.visualElement.current)
return;
const { drag, dragConstraints } = this.getProps();
const { projection } = this.visualElement;
if (!isRefObject(dragConstraints) || !projection || !this.constraints)
return;
/**
* Stop current animations as there can be visual glitching if we try to do
* this mid-animation
*/
this.stopAnimation();
/**
* Record the relative position of the dragged element relative to the
* constraints box and save as a progress value.
*/
const boxProgress = { x: 0, y: 0 };
eachAxis((axis) => {
const axisValue = this.getAxisMotionValue(axis);
if (axisValue && this.constraints !== false) {
const latest = axisValue.get();
boxProgress[axis] = calcOrigin$1({ min: latest, max: latest }, this.constraints[axis]);
}
});
/**
* Update the layout of this element and resolve the latest drag constraints
*/
const { transformTemplate } = this.visualElement.getProps();
this.visualElement.current.style.transform = transformTemplate
? transformTemplate({}, "")
: "none";
projection.root && projection.root.updateScroll();
projection.updateLayout();
this.resolveConstraints();
/**
* For each axis, calculate the current progress of the layout axis
* within the new constraints.
*/
eachAxis((axis) => {
if (!shouldDrag(axis, drag, null))
return;
/**
* Calculate a new transform based on the previous box progress
*/
const axisValue = this.getAxisMotionValue(axis);
const { min, max } = this.constraints[axis];
axisValue.set(mixNumber$1(min, max, boxProgress[axis]));
});
}
addListeners() {
if (!this.visualElement.current)
return;
elementDragControls.set(this.visualElement, this);
const element = this.visualElement.current;
/**
* Attach a pointerdown event listener on this DOM element to initiate drag tracking.
*/
const stopPointerListener = addPointerEvent(element, "pointerdown", (event) => {
const { drag, dragListener = true } = this.getProps();
drag && dragListener && this.start(event);
});
const measureDragConstraints = () => {
const { dragConstraints } = this.getProps();
if (isRefObject(dragConstraints) && dragConstraints.current) {
this.constraints = this.resolveRefConstraints();
}
};
const { projection } = this.visualElement;
const stopMeasureLayoutListener = projection.addEventListener("measure", measureDragConstraints);
if (projection && !projection.layout) {
projection.root && projection.root.updateScroll();
projection.updateLayout();
}
frame.read(measureDragConstraints);
/**
* Attach a window resize listener to scale the draggable target within its defined
* constraints as the window resizes.
*/
const stopResizeListener = addDomEvent(window, "resize", () => this.scalePositionWithinConstraints());
/**
* If the element's layout changes, calculate the delta and apply that to
* the drag gesture's origin point.
*/
const stopLayoutUpdateListener = projection.addEventListener("didUpdate", (({ delta, hasLayoutChanged }) => {
if (this.isDragging && hasLayoutChanged) {
eachAxis((axis) => {
const motionValue = this.getAxisMotionValue(axis);
if (!motionValue)
return;
this.originPoint[axis] += delta[axis].translate;
motionValue.set(motionValue.get() + delta[axis].translate);
});
this.visualElement.render();
}
}));
return () => {
stopResizeListener();
stopPointerListener();
stopMeasureLayoutListener();
stopLayoutUpdateListener && stopLayoutUpdateListener();
};
}
getProps() {
const props = this.visualElement.getProps();
const { drag = false, dragDirectionLock = false, dragPropagation = false, dragConstraints = false, dragElastic = defaultElastic, dragMomentum = true, } = props;
return {
...props,
drag,
dragDirectionLock,
dragPropagation,
dragConstraints,
dragElastic,
dragMomentum,
};
}
}
function shouldDrag(direction, drag, currentDirection) {
return ((drag === true || drag === direction) &&
(currentDirection === null || currentDirection === direction));
}
/**
* Based on an x/y offset determine the current drag direction. If both axis' offsets are lower
* than the provided threshold, return `null`.
*
* @param offset - The x/y offset from origin.
* @param lockThreshold - (Optional) - the minimum absolute offset before we can determine a drag direction.
*/
function getCurrentDirection(offset, lockThreshold = 10) {
let direction = null;
if (Math.abs(offset.y) > lockThreshold) {
direction = "y";
}
else if (Math.abs(offset.x) > lockThreshold) {
direction = "x";
}
return direction;
}
class DragGesture extends Feature {
constructor(node) {
super(node);
this.removeGroupControls = noop;
this.removeListeners = noop;
this.controls = new VisualElementDragControls(node);
}
mount() {
// If we've been provided a DragControls for manual control over the drag gesture,
// subscribe this component to it on mount.
const { dragControls } = this.node.getProps();
if (dragControls) {
this.removeGroupControls = dragControls.subscribe(this.controls);
}
this.removeListeners = this.controls.addListeners() || noop;
}
unmount() {
this.removeGroupControls();
this.removeListeners();
}
}
const asyncHandler = (handler) => (event, info) => {
if (handler) {
frame.postRender(() => handler(event, info));
}
};
class PanGesture extends Feature {
constructor() {
super(...arguments);
this.removePointerDownListener = noop;
}
onPointerDown(pointerDownEvent) {
this.session = new PanSession(pointerDownEvent, this.createPanHandlers(), {
transformPagePoint: this.node.getTransformPagePoint(),
contextWindow: getContextWindow(this.node),
});
}
createPanHandlers() {
const { onPanSessionStart, onPanStart, onPan, onPanEnd } = this.node.getProps();
return {
onSessionStart: asyncHandler(onPanSessionStart),
onStart: asyncHandler(onPanStart),
onMove: onPan,
onEnd: (event, info) => {
delete this.session;
if (onPanEnd) {
frame.postRender(() => onPanEnd(event, info));
}
},
};
}
mount() {
this.removePointerDownListener = addPointerEvent(this.node.current, "pointerdown", (event) => this.onPointerDown(event));
}
update() {
this.session && this.session.updateHandlers(this.createPanHandlers());
}
unmount() {
this.removePointerDownListener();
this.session && this.session.end();
}
}
const borders = ["TopLeft", "TopRight", "BottomLeft", "BottomRight"];
const numBorders = borders.length;
const asNumber = (value) => typeof value === "string" ? parseFloat(value) : value;
const isPx = (value) => typeof value === "number" || px.test(value);
function mixValues(target, follow, lead, progress, shouldCrossfadeOpacity, isOnlyMember) {
if (shouldCrossfadeOpacity) {
target.opacity = mixNumber$1(0,
// TODO Reinstate this if only child
lead.opacity !== undefined ? lead.opacity : 1, easeCrossfadeIn(progress));
target.opacityExit = mixNumber$1(follow.opacity !== undefined ? follow.opacity : 1, 0, easeCrossfadeOut(progress));
}
else if (isOnlyMember) {
target.opacity = mixNumber$1(follow.opacity !== undefined ? follow.opacity : 1, lead.opacity !== undefined ? lead.opacity : 1, progress);
}
/**
* Mix border radius
*/
for (let i = 0; i < numBorders; i++) {
const borderLabel = `border${borders[i]}Radius`;
let followRadius = getRadius(follow, borderLabel);
let leadRadius = getRadius(lead, borderLabel);
if (followRadius === undefined && leadRadius === undefined)
continue;
followRadius || (followRadius = 0);
leadRadius || (leadRadius = 0);
const canMix = followRadius === 0 ||
leadRadius === 0 ||
isPx(followRadius) === isPx(leadRadius);
if (canMix) {
target[borderLabel] = Math.max(mixNumber$1(asNumber(followRadius), asNumber(leadRadius), progress), 0);
if (percent.test(leadRadius) || percent.test(followRadius)) {
target[borderLabel] += "%";
}
}
else {
target[borderLabel] = leadRadius;
}
}
/**
* Mix rotation
*/
if (follow.rotate || lead.rotate) {
target.rotate = mixNumber$1(follow.rotate || 0, lead.rotate || 0, progress);
}
}
function getRadius(values, radiusName) {
return values[radiusName] !== undefined
? values[radiusName]
: values.borderRadius;
}
// /**
// * We only want to mix the background color if there's a follow element
// * that we're not crossfading opacity between. For instance with switch
// * AnimateSharedLayout animations, this helps the illusion of a continuous
// * element being animated but also cuts down on the number of paints triggered
// * for elements where opacity is doing that work for us.
// */
// if (
// !hasFollowElement &&
// latestLeadValues.backgroundColor &&
// latestFollowValues.backgroundColor
// ) {
// /**
// * This isn't ideal performance-wise as mixColor is creating a new function every frame.
// * We could probably create a mixer that runs at the start of the animation but
// * the idea behind the crossfader is that it runs dynamically between two potentially
// * changing targets (ie opacity or borderRadius may be animating independently via variants)
// */
// leadState.backgroundColor = followState.backgroundColor = mixColor(
// latestFollowValues.backgroundColor as string,
// latestLeadValues.backgroundColor as string
// )(p)
// }
const easeCrossfadeIn = /*@__PURE__*/ compress(0, 0.5, circOut);
const easeCrossfadeOut = /*@__PURE__*/ compress(0.5, 0.95, noop);
function compress(min, max, easing) {
return (p) => {
// Could replace ifs with clamp
if (p < min)
return 0;
if (p > max)
return 1;
return easing(progress(min, max, p));
};
}
/**
* Reset an axis to the provided origin box.
*
* This is a mutative operation.
*/
function copyAxisInto(axis, originAxis) {
axis.min = originAxis.min;
axis.max = originAxis.max;
}
/**
* Reset a box to the provided origin box.
*
* This is a mutative operation.
*/
function copyBoxInto(box, originBox) {
copyAxisInto(box.x, originBox.x);
copyAxisInto(box.y, originBox.y);
}
/**
* Reset a delta to the provided origin box.
*
* This is a mutative operation.
*/
function copyAxisDeltaInto(delta, originDelta) {
delta.translate = originDelta.translate;
delta.scale = originDelta.scale;
delta.originPoint = originDelta.originPoint;
delta.origin = originDelta.origin;
}
/**
* Remove a delta from a point. This is essentially the steps of applyPointDelta in reverse
*/
function removePointDelta(point, translate, scale, originPoint, boxScale) {
point -= translate;
point = scalePoint(point, 1 / scale, originPoint);
if (boxScale !== undefined) {
point = scalePoint(point, 1 / boxScale, originPoint);
}
return point;
}
/**
* Remove a delta from an axis. This is essentially the steps of applyAxisDelta in reverse
*/
function removeAxisDelta(axis, translate = 0, scale = 1, origin = 0.5, boxScale, originAxis = axis, sourceAxis = axis) {
if (percent.test(translate)) {
translate = parseFloat(translate);
const relativeProgress = mixNumber$1(sourceAxis.min, sourceAxis.max, translate / 100);
translate = relativeProgress - sourceAxis.min;
}
if (typeof translate !== "number")
return;
let originPoint = mixNumber$1(originAxis.min, originAxis.max, origin);
if (axis === originAxis)
originPoint -= translate;
axis.min = removePointDelta(axis.min, translate, scale, originPoint, boxScale);
axis.max = removePointDelta(axis.max, translate, scale, originPoint, boxScale);
}
/**
* Remove a transforms from an axis. This is essentially the steps of applyAxisTransforms in reverse
* and acts as a bridge between motion values and removeAxisDelta
*/
function removeAxisTransforms(axis, transforms, [key, scaleKey, originKey], origin, sourceAxis) {
removeAxisDelta(axis, transforms[key], transforms[scaleKey], transforms[originKey], transforms.scale, origin, sourceAxis);
}
/**
* The names of the motion values we want to apply as translation, scale and origin.
*/
const xKeys = ["x", "scaleX", "originX"];
const yKeys = ["y", "scaleY", "originY"];
/**
* Remove a transforms from an box. This is essentially the steps of applyAxisBox in reverse
* and acts as a bridge between motion values and removeAxisDelta
*/
function removeBoxTransforms(box, transforms, originBox, sourceBox) {
removeAxisTransforms(box.x, transforms, xKeys, originBox ? originBox.x : undefined, sourceBox ? sourceBox.x : undefined);
removeAxisTransforms(box.y, transforms, yKeys, originBox ? originBox.y : undefined, sourceBox ? sourceBox.y : undefined);
}
function isAxisDeltaZero(delta) {
return delta.translate === 0 && delta.scale === 1;
}
function isDeltaZero(delta) {
return isAxisDeltaZero(delta.x) && isAxisDeltaZero(delta.y);
}
function axisEquals(a, b) {
return a.min === b.min && a.max === b.max;
}
function boxEquals(a, b) {
return axisEquals(a.x, b.x) && axisEquals(a.y, b.y);
}
function axisEqualsRounded(a, b) {
return (Math.round(a.min) === Math.round(b.min) &&
Math.round(a.max) === Math.round(b.max));
}
function boxEqualsRounded(a, b) {
return axisEqualsRounded(a.x, b.x) && axisEqualsRounded(a.y, b.y);
}
function aspectRatio(box) {
return calcLength(box.x) / calcLength(box.y);
}
function axisDeltaEquals(a, b) {
return (a.translate === b.translate &&
a.scale === b.scale &&
a.originPoint === b.originPoint);
}
class NodeStack {
constructor() {
this.members = [];
}
add(node) {
addUniqueItem(this.members, node);
node.scheduleRender();
}
remove(node) {
removeItem(this.members, node);
if (node === this.prevLead) {
this.prevLead = undefined;
}
if (node === this.lead) {
const prevLead = this.members[this.members.length - 1];
if (prevLead) {
this.promote(prevLead);
}
}
}
relegate(node) {
const indexOfNode = this.members.findIndex((member) => node === member);
if (indexOfNode === 0)
return false;
/**
* Find the next projection node that is present
*/
let prevLead;
for (let i = indexOfNode; i >= 0; i--) {
const member = this.members[i];
if (member.isPresent !== false) {
prevLead = member;
break;
}
}
if (prevLead) {
this.promote(prevLead);
return true;
}
else {
return false;
}
}
promote(node, preserveFollowOpacity) {
const prevLead = this.lead;
if (node === prevLead)
return;
this.prevLead = prevLead;
this.lead = node;
node.show();
if (prevLead) {
prevLead.instance && prevLead.scheduleRender();
node.scheduleRender();
node.resumeFrom = prevLead;
if (preserveFollowOpacity) {
node.resumeFrom.preserveOpacity = true;
}
if (prevLead.snapshot) {
node.snapshot = prevLead.snapshot;
node.snapshot.latestValues =
prevLead.animationValues || prevLead.latestValues;
}
if (node.root && node.root.isUpdating) {
node.isLayoutDirty = true;
}
const { crossfade } = node.options;
if (crossfade === false) {
prevLead.hide();
}
/**
* TODO:
* - Test border radius when previous node was deleted
* - boxShadow mixing
* - Shared between element A in scrolled container and element B (scroll stays the same or changes)
* - Shared between element A in transformed container and element B (transform stays the same or changes)
* - Shared between element A in scrolled page and element B (scroll stays the same or changes)
* ---
* - Crossfade opacity of root nodes
* - layoutId changes after animation
* - layoutId changes mid animation
*/
}
}
exitAnimationComplete() {
this.members.forEach((node) => {
const { options, resumingFrom } = node;
options.onExitComplete && options.onExitComplete();
if (resumingFrom) {
resumingFrom.options.onExitComplete &&
resumingFrom.options.onExitComplete();
}
});
}
scheduleRender() {
this.members.forEach((node) => {
node.instance && node.scheduleRender(false);
});
}
/**
* Clear any leads that have been removed this render to prevent them from being
* used in future animations and to prevent memory leaks
*/
removeLeadSnapshot() {
if (this.lead && this.lead.snapshot) {
this.lead.snapshot = undefined;
}
}
}
const scaleCorrectors = {};
function addScaleCorrector(correctors) {
Object.assign(scaleCorrectors, correctors);
}
function buildProjectionTransform(delta, treeScale, latestTransform) {
let transform = "";
/**
* The translations we use to calculate are always relative to the viewport coordinate space.
* But when we apply scales, we also scale the coordinate space of an element and its children.
* For instance if we have a treeScale (the culmination of all parent scales) of 0.5 and we need
* to move an element 100 pixels, we actually need to move it 200 in within that scaled space.
*/
const xTranslate = delta.x.translate / treeScale.x;
const yTranslate = delta.y.translate / treeScale.y;
const zTranslate = (latestTransform === null || latestTransform === void 0 ? void 0 : latestTransform.z) || 0;
if (xTranslate || yTranslate || zTranslate) {
transform = `translate3d(${xTranslate}px, ${yTranslate}px, ${zTranslate}px) `;
}
/**
* Apply scale correction for the tree transform.
* This will apply scale to the screen-orientated axes.
*/
if (treeScale.x !== 1 || treeScale.y !== 1) {
transform += `scale(${1 / treeScale.x}, ${1 / treeScale.y}) `;
}
if (latestTransform) {
const { transformPerspective, rotate, rotateX, rotateY, skewX, skewY } = latestTransform;
if (transformPerspective)
transform = `perspective(${transformPerspective}px) ${transform}`;
if (rotate)
transform += `rotate(${rotate}deg) `;
if (rotateX)
transform += `rotateX(${rotateX}deg) `;
if (rotateY)
transform += `rotateY(${rotateY}deg) `;
if (skewX)
transform += `skewX(${skewX}deg) `;
if (skewY)
transform += `skewY(${skewY}deg) `;
}
/**
* Apply scale to match the size of the element to the size we want it.
* This will apply scale to the element-orientated axes.
*/
const elementScaleX = delta.x.scale * treeScale.x;
const elementScaleY = delta.y.scale * treeScale.y;
if (elementScaleX !== 1 || elementScaleY !== 1) {
transform += `scale(${elementScaleX}, ${elementScaleY})`;
}
return transform || "none";
}
const compareByDepth = (a, b) => a.depth - b.depth;
class FlatTree {
constructor() {
this.children = [];
this.isDirty = false;
}
add(child) {
addUniqueItem(this.children, child);
this.isDirty = true;
}
remove(child) {
removeItem(this.children, child);
this.isDirty = true;
}
forEach(callback) {
this.isDirty && this.children.sort(compareByDepth);
this.isDirty = false;
this.children.forEach(callback);
}
}
/**
* If the provided value is a MotionValue, this returns the actual value, otherwise just the value itself
*
* TODO: Remove and move to library
*/
function resolveMotionValue(value) {
const unwrappedValue = isMotionValue(value) ? value.get() : value;
return isCustomValue(unwrappedValue)
? unwrappedValue.toValue()
: unwrappedValue;
}
/**
* This should only ever be modified on the client otherwise it'll
* persist through server requests. If we need instanced states we
* could lazy-init via root.
*/
const globalProjectionState = {
/**
* Global flag as to whether the tree has animated since the last time
* we resized the window
*/
hasAnimatedSinceResize: true,
/**
* We set this to true once, on the first update. Any nodes added to the tree beyond that
* update will be given a `data-projection-id` attribute.
*/
hasEverUpdated: false,
};
/**
* Timeout defined in ms
*/
function delay(callback, timeout) {
const start = time.now();
const checkElapsed = ({ timestamp }) => {
const elapsed = timestamp - start;
if (elapsed >= timeout) {
cancelFrame(checkElapsed);
callback(elapsed - timeout);
}
};
frame.read(checkElapsed, true);
return () => cancelFrame(checkElapsed);
}
const visualElementStore = new WeakMap();
function isSVGElement(element) {
return element instanceof SVGElement && element.tagName !== "svg";
}
function isForcedMotionValue(key, { layout, layoutId }) {
return (transformProps.has(key) ||
key.startsWith("origin") ||
((layout || layoutId !== undefined) &&
(!!scaleCorrectors[key] || key === "opacity")));
}
function scrapeMotionValuesFromProps$1(props, prevProps, visualElement) {
var _a;
const { style } = props;
const newValues = {};
for (const key in style) {
if (isMotionValue(style[key]) ||
(prevProps.style &&
isMotionValue(prevProps.style[key])) ||
isForcedMotionValue(key, props) ||
((_a = visualElement === null || visualElement === void 0 ? void 0 : visualElement.getValue(key)) === null || _a === void 0 ? void 0 : _a.liveStyle) !== undefined) {
newValues[key] = style[key];
}
}
return newValues;
}
function scrapeMotionValuesFromProps(props, prevProps, visualElement) {
const newValues = scrapeMotionValuesFromProps$1(props, prevProps, visualElement);
for (const key in props) {
if (isMotionValue(props[key]) ||
isMotionValue(prevProps[key])) {
const targetKey = transformPropOrder.indexOf(key) !== -1
? "attr" + key.charAt(0).toUpperCase() + key.substring(1)
: key;
newValues[targetKey] = props[key];
}
}
return newValues;
}
const isBrowser = typeof window !== "undefined";
// Does this device prefer reduced motion? Returns `null` server-side.
const prefersReducedMotion = { current: null };
const hasReducedMotionListener = { current: false };
function initPrefersReducedMotion() {
hasReducedMotionListener.current = true;
if (!isBrowser)
return;
if (window.matchMedia) {
const motionMediaQuery = window.matchMedia("(prefers-reduced-motion)");
const setReducedMotionPreferences = () => (prefersReducedMotion.current = motionMediaQuery.matches);
motionMediaQuery.addListener(setReducedMotionPreferences);
setReducedMotionPreferences();
}
else {
prefersReducedMotion.current = false;
}
}
function isControllingVariants(props) {
return (isAnimationControls(props.animate) ||
variantProps.some((name) => isVariantLabel(props[name])));
}
function isVariantNode(props) {
return Boolean(isControllingVariants(props) || props.variants);
}
function updateMotionValuesFromProps(element, next, prev) {
for (const key in next) {
const nextValue = next[key];
const prevValue = prev[key];
if (isMotionValue(nextValue)) {
/**
* If this is a motion value found in props or style, we want to add it
* to our visual element's motion value map.
*/
element.addValue(key, nextValue);
/**
* Check the version of the incoming motion value with this version
* and warn against mismatches.
*/
if (process.env.NODE_ENV === "development") {
warnOnce(nextValue.version === "11.11.17", `Attempting to mix Motion versions ${nextValue.version} with 11.11.17 may not work as expected.`);
}
}
else if (isMotionValue(prevValue)) {
/**
* If we're swapping from a motion value to a static value,
* create a new motion value from that
*/
element.addValue(key, motionValue(nextValue, { owner: element }));
}
else if (prevValue !== nextValue) {
/**
* If this is a flat value that has changed, update the motion value
* or create one if it doesn't exist. We only want to do this if we're
* not handling the value with our animation state.
*/
if (element.hasValue(key)) {
const existingValue = element.getValue(key);
if (existingValue.liveStyle === true) {
existingValue.jump(nextValue);
}
else if (!existingValue.hasAnimated) {
existingValue.set(nextValue);
}
}
else {
const latestValue = element.getStaticValue(key);
element.addValue(key, motionValue(latestValue !== undefined ? latestValue : nextValue, { owner: element }));
}
}
}
// Handle removed values
for (const key in prev) {
if (next[key] === undefined)
element.removeValue(key);
}
return next;
}
const featureProps = {
animation: [
"animate",
"variants",
"whileHover",
"whileTap",
"exit",
"whileInView",
"whileFocus",
"whileDrag",
],
exit: ["exit"],
drag: ["drag", "dragControls"],
focus: ["whileFocus"],
hover: ["whileHover", "onHoverStart", "onHoverEnd"],
tap: ["whileTap", "onTap", "onTapStart", "onTapCancel"],
pan: ["onPan", "onPanStart", "onPanSessionStart", "onPanEnd"],
inView: ["whileInView", "onViewportEnter", "onViewportLeave"],
layout: ["layout", "layoutId"],
};
const featureDefinitions = {};
for (const key in featureProps) {
featureDefinitions[key] = {
isEnabled: (props) => featureProps[key].some((name) => !!props[name]),
};
}
/**
* A list of all ValueTypes
*/
const valueTypes = [...dimensionValueTypes, color, complex];
/**
* Tests a value against the list of ValueTypes
*/
const findValueType = (v) => valueTypes.find(testValueType(v));
const propEventHandlers = [
"AnimationStart",
"AnimationComplete",
"Update",
"BeforeLayoutMeasure",
"LayoutMeasure",
"LayoutAnimationStart",
"LayoutAnimationComplete",
];
/**
* A VisualElement is an imperative abstraction around UI elements such as
* HTMLElement, SVGElement, Three.Object3D etc.
*/
class VisualElement {
/**
* This method takes React props and returns found MotionValues. For example, HTML
* MotionValues will be found within the style prop, whereas for Three.js within attribute arrays.
*
* This isn't an abstract method as it needs calling in the constructor, but it is
* intended to be one.
*/
scrapeMotionValuesFromProps(_props, _prevProps, _visualElement) {
return {};
}
constructor({ parent, props, presenceContext, reducedMotionConfig, blockInitialAnimation, visualState, }, options = {}) {
/**
* A reference to the current underlying Instance, e.g. a HTMLElement
* or Three.Mesh etc.
*/
this.current = null;
/**
* A set containing references to this VisualElement's children.
*/
this.children = new Set();
/**
* Determine what role this visual element should take in the variant tree.
*/
this.isVariantNode = false;
this.isControllingVariants = false;
/**
* Decides whether this VisualElement should animate in reduced motion
* mode.
*
* TODO: This is currently set on every individual VisualElement but feels
* like it could be set globally.
*/
this.shouldReduceMotion = null;
/**
* A map of all motion values attached to this visual element. Motion
* values are source of truth for any given animated value. A motion
* value might be provided externally by the component via props.
*/
this.values = new Map();
this.KeyframeResolver = KeyframeResolver;
/**
* Cleanup functions for active features (hover/tap/exit etc)
*/
this.features = {};
/**
* A map of every subscription that binds the provided or generated
* motion values onChange listeners to this visual element.
*/
this.valueSubscriptions = new Map();
/**
* A reference to the previously-provided motion values as returned
* from scrapeMotionValuesFromProps. We use the keys in here to determine
* if any motion values need to be removed after props are updated.
*/
this.prevMotionValues = {};
/**
* An object containing a SubscriptionManager for each active event.
*/
this.events = {};
/**
* An object containing an unsubscribe function for each prop event subscription.
* For example, every "Update" event can have multiple subscribers via
* VisualElement.on(), but only one of those can be defined via the onUpdate prop.
*/
this.propEventSubscriptions = {};
this.notifyUpdate = () => this.notify("Update", this.latestValues);
this.render = () => {
if (!this.current)
return;
this.triggerBuild();
this.renderInstance(this.current, this.renderState, this.props.style, this.projection);
};
this.renderScheduledAt = 0.0;
this.scheduleRender = () => {
const now = time.now();
if (this.renderScheduledAt < now) {
this.renderScheduledAt = now;
frame.render(this.render, false, true);
}
};
const { latestValues, renderState } = visualState;
this.latestValues = latestValues;
this.baseTarget = { ...latestValues };
this.initialValues = props.initial ? { ...latestValues } : {};
this.renderState = renderState;
this.parent = parent;
this.props = props;
this.presenceContext = presenceContext;
this.depth = parent ? parent.depth + 1 : 0;
this.reducedMotionConfig = reducedMotionConfig;
this.options = options;
this.blockInitialAnimation = Boolean(blockInitialAnimation);
this.isControllingVariants = isControllingVariants(props);
this.isVariantNode = isVariantNode(props);
if (this.isVariantNode) {
this.variantChildren = new Set();
}
this.manuallyAnimateOnMount = Boolean(parent && parent.current);
/**
* Any motion values that are provided to the element when created
* aren't yet bound to the element, as this would technically be impure.
* However, we iterate through the motion values and set them to the
* initial values for this component.
*
* TODO: This is impure and we should look at changing this to run on mount.
* Doing so will break some tests but this isn't necessarily a breaking change,
* more a reflection of the test.
*/
const { willChange, ...initialMotionValues } = this.scrapeMotionValuesFromProps(props, {}, this);
for (const key in initialMotionValues) {
const value = initialMotionValues[key];
if (latestValues[key] !== undefined && isMotionValue(value)) {
value.set(latestValues[key], false);
}
}
}
mount(instance) {
this.current = instance;
visualElementStore.set(instance, this);
if (this.projection && !this.projection.instance) {
this.projection.mount(instance);
}
if (this.parent && this.isVariantNode && !this.isControllingVariants) {
this.removeFromVariantTree = this.parent.addVariantChild(this);
}
this.values.forEach((value, key) => this.bindToMotionValue(key, value));
if (!hasReducedMotionListener.current) {
initPrefersReducedMotion();
}
this.shouldReduceMotion =
this.reducedMotionConfig === "never"
? false
: this.reducedMotionConfig === "always"
? true
: prefersReducedMotion.current;
if (process.env.NODE_ENV !== "production") {
warnOnce(this.shouldReduceMotion !== true, "You have Reduced Motion enabled on your device. Animations may not appear as expected.");
}
if (this.parent)
this.parent.children.add(this);
this.update(this.props, this.presenceContext);
}
unmount() {
visualElementStore.delete(this.current);
this.projection && this.projection.unmount();
cancelFrame(this.notifyUpdate);
cancelFrame(this.render);
this.valueSubscriptions.forEach((remove) => remove());
this.valueSubscriptions.clear();
this.removeFromVariantTree && this.removeFromVariantTree();
this.parent && this.parent.children.delete(this);
for (const key in this.events) {
this.events[key].clear();
}
for (const key in this.features) {
const feature = this.features[key];
if (feature) {
feature.unmount();
feature.isMounted = false;
}
}
this.current = null;
}
bindToMotionValue(key, value) {
if (this.valueSubscriptions.has(key)) {
this.valueSubscriptions.get(key)();
}
const valueIsTransform = transformProps.has(key);
const removeOnChange = value.on("change", (latestValue) => {
this.latestValues[key] = latestValue;
this.props.onUpdate && frame.preRender(this.notifyUpdate);
if (valueIsTransform && this.projection) {
this.projection.isTransformDirty = true;
}
});
const removeOnRenderRequest = value.on("renderRequest", this.scheduleRender);
let removeSyncCheck;
if (window.MotionCheckAppearSync) {
removeSyncCheck = window.MotionCheckAppearSync(this, key, value);
}
this.valueSubscriptions.set(key, () => {
removeOnChange();
removeOnRenderRequest();
if (removeSyncCheck)
removeSyncCheck();
if (value.owner)
value.stop();
});
}
sortNodePosition(other) {
/**
* If these nodes aren't even of the same type we can't compare their depth.
*/
if (!this.current ||
!this.sortInstanceNodePosition ||
this.type !== other.type) {
return 0;
}
return this.sortInstanceNodePosition(this.current, other.current);
}
updateFeatures() {
let key = "animation";
for (key in featureDefinitions) {
const featureDefinition = featureDefinitions[key];
if (!featureDefinition)
continue;
const { isEnabled, Feature: FeatureConstructor } = featureDefinition;
/**
* If this feature is enabled but not active, make a new instance.
*/
if (!this.features[key] &&
FeatureConstructor &&
isEnabled(this.props)) {
this.features[key] = new FeatureConstructor(this);
}
/**
* If we have a feature, mount or update it.
*/
if (this.features[key]) {
const feature = this.features[key];
if (feature.isMounted) {
feature.update();
}
else {
feature.mount();
feature.isMounted = true;
}
}
}
}
triggerBuild() {
this.build(this.renderState, this.latestValues, this.props);
}
/**
* Measure the current viewport box with or without transforms.
* Only measures axis-aligned boxes, rotate and skew must be manually
* removed with a re-render to work.
*/
measureViewportBox() {
return this.current
? this.measureInstanceViewportBox(this.current, this.props)
: createBox();
}
getStaticValue(key) {
return this.latestValues[key];
}
setStaticValue(key, value) {
this.latestValues[key] = value;
}
/**
* Update the provided props. Ensure any newly-added motion values are
* added to our map, old ones removed, and listeners updated.
*/
update(props, presenceContext) {
if (props.transformTemplate || this.props.transformTemplate) {
this.scheduleRender();
}
this.prevProps = this.props;
this.props = props;
this.prevPresenceContext = this.presenceContext;
this.presenceContext = presenceContext;
/**
* Update prop event handlers ie onAnimationStart, onAnimationComplete
*/
for (let i = 0; i < propEventHandlers.length; i++) {
const key = propEventHandlers[i];
if (this.propEventSubscriptions[key]) {
this.propEventSubscriptions[key]();
delete this.propEventSubscriptions[key];
}
const listenerName = ("on" + key);
const listener = props[listenerName];
if (listener) {
this.propEventSubscriptions[key] = this.on(key, listener);
}
}
this.prevMotionValues = updateMotionValuesFromProps(this, this.scrapeMotionValuesFromProps(props, this.prevProps, this), this.prevMotionValues);
if (this.handleChildMotionValue) {
this.handleChildMotionValue();
}
}
getProps() {
return this.props;
}
/**
* Returns the variant definition with a given name.
*/
getVariant(name) {
return this.props.variants ? this.props.variants[name] : undefined;
}
/**
* Returns the defined default transition on this component.
*/
getDefaultTransition() {
return this.props.transition;
}
getTransformPagePoint() {
return this.props.transformPagePoint;
}
getClosestVariantNode() {
return this.isVariantNode
? this
: this.parent
? this.parent.getClosestVariantNode()
: undefined;
}
/**
* Add a child visual element to our set of children.
*/
addVariantChild(child) {
const closestVariantNode = this.getClosestVariantNode();
if (closestVariantNode) {
closestVariantNode.variantChildren &&
closestVariantNode.variantChildren.add(child);
return () => closestVariantNode.variantChildren.delete(child);
}
}
/**
* Add a motion value and bind it to this visual element.
*/
addValue(key, value) {
// Remove existing value if it exists
const existingValue = this.values.get(key);
if (value !== existingValue) {
if (existingValue)
this.removeValue(key);
this.bindToMotionValue(key, value);
this.values.set(key, value);
this.latestValues[key] = value.get();
}
}
/**
* Remove a motion value and unbind any active subscriptions.
*/
removeValue(key) {
this.values.delete(key);
const unsubscribe = this.valueSubscriptions.get(key);
if (unsubscribe) {
unsubscribe();
this.valueSubscriptions.delete(key);
}
delete this.latestValues[key];
this.removeValueFromRenderState(key, this.renderState);
}
/**
* Check whether we have a motion value for this key
*/
hasValue(key) {
return this.values.has(key);
}
getValue(key, defaultValue) {
if (this.props.values && this.props.values[key]) {
return this.props.values[key];
}
let value = this.values.get(key);
if (value === undefined && defaultValue !== undefined) {
value = motionValue(defaultValue === null ? undefined : defaultValue, { owner: this });
this.addValue(key, value);
}
return value;
}
/**
* If we're trying to animate to a previously unencountered value,
* we need to check for it in our state and as a last resort read it
* directly from the instance (which might have performance implications).
*/
readValue(key, target) {
var _a;
let value = this.latestValues[key] !== undefined || !this.current
? this.latestValues[key]
: (_a = this.getBaseTargetFromProps(this.props, key)) !== null && _a !== void 0 ? _a : this.readValueFromInstance(this.current, key, this.options);
if (value !== undefined && value !== null) {
if (typeof value === "string" &&
(isNumericalString(value) || isZeroValueString(value))) {
// If this is a number read as a string, ie "0" or "200", convert it to a number
value = parseFloat(value);
}
else if (!findValueType(value) && complex.test(target)) {
value = getAnimatableNone(key, target);
}
this.setBaseTarget(key, isMotionValue(value) ? value.get() : value);
}
return isMotionValue(value) ? value.get() : value;
}
/**
* Set the base target to later animate back to. This is currently
* only hydrated on creation and when we first read a value.
*/
setBaseTarget(key, value) {
this.baseTarget[key] = value;
}
/**
* Find the base target for a value thats been removed from all animation
* props.
*/
getBaseTarget(key) {
var _a;
const { initial } = this.props;
let valueFromInitial;
if (typeof initial === "string" || typeof initial === "object") {
const variant = resolveVariantFromProps(this.props, initial, (_a = this.presenceContext) === null || _a === void 0 ? void 0 : _a.custom);
if (variant) {
valueFromInitial = variant[key];
}
}
/**
* If this value still exists in the current initial variant, read that.
*/
if (initial && valueFromInitial !== undefined) {
return valueFromInitial;
}
/**
* Alternatively, if this VisualElement config has defined a getBaseTarget
* so we can read the value from an alternative source, try that.
*/
const target = this.getBaseTargetFromProps(this.props, key);
if (target !== undefined && !isMotionValue(target))
return target;
/**
* If the value was initially defined on initial, but it doesn't any more,
* return undefined. Otherwise return the value as initially read from the DOM.
*/
return this.initialValues[key] !== undefined &&
valueFromInitial === undefined
? undefined
: this.baseTarget[key];
}
on(eventName, callback) {
if (!this.events[eventName]) {
this.events[eventName] = new SubscriptionManager();
}
return this.events[eventName].add(callback);
}
notify(eventName, ...args) {
if (this.events[eventName]) {
this.events[eventName].notify(...args);
}
}
}
class DOMVisualElement extends VisualElement {
constructor() {
super(...arguments);
this.KeyframeResolver = DOMKeyframesResolver;
}
sortInstanceNodePosition(a, b) {
/**
* compareDocumentPosition returns a bitmask, by using the bitwise &
* we're returning true if 2 in that bitmask is set to true. 2 is set
* to true if b preceeds a.
*/
return a.compareDocumentPosition(b) & 2 ? 1 : -1;
}
getBaseTargetFromProps(props, key) {
return props.style
? props.style[key]
: undefined;
}
removeValueFromRenderState(key, { vars, style }) {
delete vars[key];
delete style[key];
}
}
/**
* Provided a value and a ValueType, returns the value as that value type.
*/
const getValueAsType = (value, type) => {
return type && typeof value === "number"
? type.transform(value)
: value;
};
const translateAlias = {
x: "translateX",
y: "translateY",
z: "translateZ",
transformPerspective: "perspective",
};
const numTransforms = transformPropOrder.length;
/**
* Build a CSS transform style from individual x/y/scale etc properties.
*
* This outputs with a default order of transforms/scales/rotations, this can be customised by
* providing a transformTemplate function.
*/
function buildTransform(latestValues, transform, transformTemplate) {
// The transform string we're going to build into.
let transformString = "";
let transformIsDefault = true;
/**
* Loop over all possible transforms in order, adding the ones that
* are present to the transform string.
*/
for (let i = 0; i < numTransforms; i++) {
const key = transformPropOrder[i];
const value = latestValues[key];
if (value === undefined)
continue;
let valueIsDefault = true;
if (typeof value === "number") {
valueIsDefault = value === (key.startsWith("scale") ? 1 : 0);
}
else {
valueIsDefault = parseFloat(value) === 0;
}
if (!valueIsDefault || transformTemplate) {
const valueAsType = getValueAsType(value, numberValueTypes[key]);
if (!valueIsDefault) {
transformIsDefault = false;
const transformName = translateAlias[key] || key;
transformString += `${transformName}(${valueAsType}) `;
}
if (transformTemplate) {
transform[key] = valueAsType;
}
}
}
transformString = transformString.trim();
// If we have a custom `transform` template, pass our transform values and
// generated transformString to that before returning
if (transformTemplate) {
transformString = transformTemplate(transform, transformIsDefault ? "" : transformString);
}
else if (transformIsDefault) {
transformString = "none";
}
return transformString;
}
function buildHTMLStyles(state, latestValues, transformTemplate) {
const { style, vars, transformOrigin } = state;
// Track whether we encounter any transform or transformOrigin values.
let hasTransform = false;
let hasTransformOrigin = false;
/**
* Loop over all our latest animated values and decide whether to handle them
* as a style or CSS variable.
*
* Transforms and transform origins are kept separately for further processing.
*/
for (const key in latestValues) {
const value = latestValues[key];
if (transformProps.has(key)) {
// If this is a transform, flag to enable further transform processing
hasTransform = true;
continue;
}
else if (isCSSVariableName(key)) {
vars[key] = value;
continue;
}
else {
// Convert the value to its default value type, ie 0 -> "0px"
const valueAsType = getValueAsType(value, numberValueTypes[key]);
if (key.startsWith("origin")) {
// If this is a transform origin, flag and enable further transform-origin processing
hasTransformOrigin = true;
transformOrigin[key] =
valueAsType;
}
else {
style[key] = valueAsType;
}
}
}
if (!latestValues.transform) {
if (hasTransform || transformTemplate) {
style.transform = buildTransform(latestValues, state.transform, transformTemplate);
}
else if (style.transform) {
/**
* If we have previously created a transform but currently don't have any,
* reset transform style to none.
*/
style.transform = "none";
}
}
/**
* Build a transformOrigin style. Uses the same defaults as the browser for
* undefined origins.
*/
if (hasTransformOrigin) {
const { originX = "50%", originY = "50%", originZ = 0, } = transformOrigin;
style.transformOrigin = `${originX} ${originY} ${originZ}`;
}
}
function calcOrigin(origin, offset, size) {
return typeof origin === "string"
? origin
: px.transform(offset + size * origin);
}
/**
* The SVG transform origin defaults are different to CSS and is less intuitive,
* so we use the measured dimensions of the SVG to reconcile these.
*/
function calcSVGTransformOrigin(dimensions, originX, originY) {
const pxOriginX = calcOrigin(originX, dimensions.x, dimensions.width);
const pxOriginY = calcOrigin(originY, dimensions.y, dimensions.height);
return `${pxOriginX} ${pxOriginY}`;
}
const dashKeys = {
offset: "stroke-dashoffset",
array: "stroke-dasharray",
};
const camelKeys = {
offset: "strokeDashoffset",
array: "strokeDasharray",
};
/**
* Build SVG path properties. Uses the path's measured length to convert
* our custom pathLength, pathSpacing and pathOffset into stroke-dashoffset
* and stroke-dasharray attributes.
*
* This function is mutative to reduce per-frame GC.
*/
function buildSVGPath(attrs, length, spacing = 1, offset = 0, useDashCase = true) {
// Normalise path length by setting SVG attribute pathLength to 1
attrs.pathLength = 1;
// We use dash case when setting attributes directly to the DOM node and camel case
// when defining props on a React component.
const keys = useDashCase ? dashKeys : camelKeys;
// Build the dash offset
attrs[keys.offset] = px.transform(-offset);
// Build the dash array
const pathLength = px.transform(length);
const pathSpacing = px.transform(spacing);
attrs[keys.array] = `${pathLength} ${pathSpacing}`;
}
/**
* Build SVG visual attrbutes, like cx and style.transform
*/
function buildSVGAttrs(state, { attrX, attrY, attrScale, originX, originY, pathLength, pathSpacing = 1, pathOffset = 0,
// This is object creation, which we try to avoid per-frame.
...latest }, isSVGTag, transformTemplate) {
buildHTMLStyles(state, latest, transformTemplate);
/**
* For svg tags we just want to make sure viewBox is animatable and treat all the styles
* as normal HTML tags.
*/
if (isSVGTag) {
if (state.style.viewBox) {
state.attrs.viewBox = state.style.viewBox;
}
return;
}
state.attrs = state.style;
state.style = {};
const { attrs, style, dimensions } = state;
/**
* However, we apply transforms as CSS transforms. So if we detect a transform we take it from attrs
* and copy it into style.
*/
if (attrs.transform) {
if (dimensions)
style.transform = attrs.transform;
delete attrs.transform;
}
// Parse transformOrigin
if (dimensions &&
(originX !== undefined || originY !== undefined || style.transform)) {
style.transformOrigin = calcSVGTransformOrigin(dimensions, originX !== undefined ? originX : 0.5, originY !== undefined ? originY : 0.5);
}
// Render attrX/attrY/attrScale as attributes
if (attrX !== undefined)
attrs.x = attrX;
if (attrY !== undefined)
attrs.y = attrY;
if (attrScale !== undefined)
attrs.scale = attrScale;
// Build SVG path if one has been defined
if (pathLength !== undefined) {
buildSVGPath(attrs, pathLength, pathSpacing, pathOffset, false);
}
}
/**
* A set of attribute names that are always read/written as camel case.
*/
const camelCaseAttributes = new Set([
"baseFrequency",
"diffuseConstant",
"kernelMatrix",
"kernelUnitLength",
"keySplines",
"keyTimes",
"limitingConeAngle",
"markerHeight",
"markerWidth",
"numOctaves",
"targetX",
"targetY",
"surfaceScale",
"specularConstant",
"specularExponent",
"stdDeviation",
"tableValues",
"viewBox",
"gradientTransform",
"pathLength",
"startOffset",
"textLength",
"lengthAdjust",
]);
function renderHTML(element, { style, vars }, styleProp, projection) {
Object.assign(element.style, style, projection && projection.getProjectionStyles(styleProp));
// Loop over any CSS variables and assign those.
for (const key in vars) {
element.style.setProperty(key, vars[key]);
}
}
function renderSVG(element, renderState, _styleProp, projection) {
renderHTML(element, renderState, undefined, projection);
for (const key in renderState.attrs) {
element.setAttribute(!camelCaseAttributes.has(key) ? camelToDash(key) : key, renderState.attrs[key]);
}
}
const isSVGTag = (tag) => typeof tag === "string" && tag.toLowerCase() === "svg";
class SVGVisualElement extends DOMVisualElement {
constructor() {
super(...arguments);
this.type = "svg";
this.isSVGTag = false;
this.measureInstanceViewportBox = createBox;
}
getBaseTargetFromProps(props, key) {
return props[key];
}
readValueFromInstance(instance, key) {
if (transformProps.has(key)) {
const defaultType = getDefaultValueType(key);
return defaultType ? defaultType.default || 0 : 0;
}
key = !camelCaseAttributes.has(key) ? camelToDash(key) : key;
return instance.getAttribute(key);
}
scrapeMotionValuesFromProps(props, prevProps, visualElement) {
return scrapeMotionValuesFromProps(props, prevProps, visualElement);
}
build(renderState, latestValues, props) {
buildSVGAttrs(renderState, latestValues, this.isSVGTag, props.transformTemplate);
}
renderInstance(instance, renderState, styleProp, projection) {
renderSVG(instance, renderState, styleProp, projection);
}
mount(instance) {
this.isSVGTag = isSVGTag(instance.tagName);
super.mount(instance);
}
}
function getComputedStyle(element) {
return window.getComputedStyle(element);
}
class HTMLVisualElement extends DOMVisualElement {
constructor() {
super(...arguments);
this.type = "html";
this.renderInstance = renderHTML;
}
readValueFromInstance(instance, key) {
if (transformProps.has(key)) {
const defaultType = getDefaultValueType(key);
return defaultType ? defaultType.default || 0 : 0;
}
else {
const computedStyle = getComputedStyle(instance);
const value = (isCSSVariableName(key)
? computedStyle.getPropertyValue(key)
: computedStyle[key]) || 0;
return typeof value === "string" ? value.trim() : value;
}
}
measureInstanceViewportBox(instance, { transformPagePoint }) {
return measureViewportBox(instance, transformPagePoint);
}
build(renderState, latestValues, props) {
buildHTMLStyles(renderState, latestValues, props.transformTemplate);
}
scrapeMotionValuesFromProps(props, prevProps, visualElement) {
return scrapeMotionValuesFromProps$1(props, prevProps, visualElement);
}
handleChildMotionValue() {
if (this.childSubscription) {
this.childSubscription();
delete this.childSubscription;
}
const { children } = this.props;
if (isMotionValue(children)) {
this.childSubscription = children.on("change", (latest) => {
if (this.current)
this.current.textContent = `${latest}`;
});
}
}
}
function animateSingleValue(value, keyframes, options) {
const motionValue$1 = isMotionValue(value) ? value : motionValue(value);
motionValue$1.start(animateMotionValue("", motionValue$1, keyframes, options));
return motionValue$1.animation;
}
const { schedule: microtask, cancel: cancelMicrotask } = createRenderBatcher(queueMicrotask, false);
const metrics = {
type: "projectionFrame",
totalNodes: 0,
resolvedTargetDeltas: 0,
recalculatedProjection: 0,
};
const isDebug = typeof window !== "undefined" && window.MotionDebug !== undefined;
const transformAxes = ["", "X", "Y", "Z"];
const hiddenVisibility = { visibility: "hidden" };
/**
* We use 1000 as the animation target as 0-1000 maps better to pixels than 0-1
* which has a noticeable difference in spring animations
*/
const animationTarget = 1000;
let id = 0;
function resetDistortingTransform(key, visualElement, values, sharedAnimationValues) {
const { latestValues } = visualElement;
// Record the distorting transform and then temporarily set it to 0
if (latestValues[key]) {
values[key] = latestValues[key];
visualElement.setStaticValue(key, 0);
if (sharedAnimationValues) {
sharedAnimationValues[key] = 0;
}
}
}
function cancelTreeOptimisedTransformAnimations(projectionNode) {
projectionNode.hasCheckedOptimisedAppear = true;
if (projectionNode.root === projectionNode)
return;
const { visualElement } = projectionNode.options;
if (!visualElement)
return;
const appearId = getOptimisedAppearId(visualElement);
if (window.MotionHasOptimisedAnimation(appearId, "transform")) {
const { layout, layoutId } = projectionNode.options;
window.MotionCancelOptimisedAnimation(appearId, "transform", frame, !(layout || layoutId));
}
const { parent } = projectionNode;
if (parent && !parent.hasCheckedOptimisedAppear) {
cancelTreeOptimisedTransformAnimations(parent);
}
}
function createProjectionNode$1({ attachResizeListener, defaultParent, measureScroll, checkIsScrollRoot, resetTransform, }) {
return class ProjectionNode {
constructor(latestValues = {}, parent = defaultParent === null || defaultParent === void 0 ? void 0 : defaultParent()) {
/**
* A unique ID generated for every projection node.
*/
this.id = id++;
/**
* An id that represents a unique session instigated by startUpdate.
*/
this.animationId = 0;
/**
* A Set containing all this component's children. This is used to iterate
* through the children.
*
* TODO: This could be faster to iterate as a flat array stored on the root node.
*/
this.children = new Set();
/**
* Options for the node. We use this to configure what kind of layout animations
* we should perform (if any).
*/
this.options = {};
/**
* We use this to detect when its safe to shut down part of a projection tree.
* We have to keep projecting children for scale correction and relative projection
* until all their parents stop performing layout animations.
*/
this.isTreeAnimating = false;
this.isAnimationBlocked = false;
/**
* Flag to true if we think this layout has been changed. We can't always know this,
* currently we set it to true every time a component renders, or if it has a layoutDependency
* if that has changed between renders. Additionally, components can be grouped by LayoutGroup
* and if one node is dirtied, they all are.
*/
this.isLayoutDirty = false;
/**
* Flag to true if we think the projection calculations for this node needs
* recalculating as a result of an updated transform or layout animation.
*/
this.isProjectionDirty = false;
/**
* Flag to true if the layout *or* transform has changed. This then gets propagated
* throughout the projection tree, forcing any element below to recalculate on the next frame.
*/
this.isSharedProjectionDirty = false;
/**
* Flag transform dirty. This gets propagated throughout the whole tree but is only
* respected by shared nodes.
*/
this.isTransformDirty = false;
/**
* Block layout updates for instant layout transitions throughout the tree.
*/
this.updateManuallyBlocked = false;
this.updateBlockedByResize = false;
/**
* Set to true between the start of the first `willUpdate` call and the end of the `didUpdate`
* call.
*/
this.isUpdating = false;
/**
* If this is an SVG element we currently disable projection transforms
*/
this.isSVG = false;
/**
* Flag to true (during promotion) if a node doing an instant layout transition needs to reset
* its projection styles.
*/
this.needsReset = false;
/**
* Flags whether this node should have its transform reset prior to measuring.
*/
this.shouldResetTransform = false;
/**
* Store whether this node has been checked for optimised appear animations. As
* effects fire bottom-up, and we want to look up the tree for appear animations,
* this makes sure we only check each path once, stopping at nodes that
* have already been checked.
*/
this.hasCheckedOptimisedAppear = false;
/**
* An object representing the calculated contextual/accumulated/tree scale.
* This will be used to scale calculcated projection transforms, as these are
* calculated in screen-space but need to be scaled for elements to layoutly
* make it to their calculated destinations.
*
* TODO: Lazy-init
*/
this.treeScale = { x: 1, y: 1 };
/**
*
*/
this.eventHandlers = new Map();
this.hasTreeAnimated = false;
// Note: Currently only running on root node
this.updateScheduled = false;
this.scheduleUpdate = () => this.update();
this.projectionUpdateScheduled = false;
this.checkUpdateFailed = () => {
if (this.isUpdating) {
this.isUpdating = false;
this.clearAllSnapshots();
}
};
/**
* This is a multi-step process as shared nodes might be of different depths. Nodes
* are sorted by depth order, so we need to resolve the entire tree before moving to
* the next step.
*/
this.updateProjection = () => {
this.projectionUpdateScheduled = false;
/**
* Reset debug counts. Manually resetting rather than creating a new
* object each frame.
*/
if (isDebug) {
metrics.totalNodes =
metrics.resolvedTargetDeltas =
metrics.recalculatedProjection =
0;
}
this.nodes.forEach(propagateDirtyNodes);
this.nodes.forEach(resolveTargetDelta);
this.nodes.forEach(calcProjection);
this.nodes.forEach(cleanDirtyNodes);
if (isDebug) {
window.MotionDebug.record(metrics);
}
};
/**
* Frame calculations
*/
this.resolvedRelativeTargetAt = 0.0;
this.hasProjected = false;
this.isVisible = true;
this.animationProgress = 0;
/**
* Shared layout
*/
// TODO Only running on root node
this.sharedNodes = new Map();
this.latestValues = latestValues;
this.root = parent ? parent.root || parent : this;
this.path = parent ? [...parent.path, parent] : [];
this.parent = parent;
this.depth = parent ? parent.depth + 1 : 0;
for (let i = 0; i < this.path.length; i++) {
this.path[i].shouldResetTransform = true;
}
if (this.root === this)
this.nodes = new FlatTree();
}
addEventListener(name, handler) {
if (!this.eventHandlers.has(name)) {
this.eventHandlers.set(name, new SubscriptionManager());
}
return this.eventHandlers.get(name).add(handler);
}
notifyListeners(name, ...args) {
const subscriptionManager = this.eventHandlers.get(name);
subscriptionManager && subscriptionManager.notify(...args);
}
hasListeners(name) {
return this.eventHandlers.has(name);
}
/**
* Lifecycles
*/
mount(instance, isLayoutDirty = this.root.hasTreeAnimated) {
if (this.instance)
return;
this.isSVG = isSVGElement(instance);
this.instance = instance;
const { layoutId, layout, visualElement } = this.options;
if (visualElement && !visualElement.current) {
visualElement.mount(instance);
}
this.root.nodes.add(this);
this.parent && this.parent.children.add(this);
if (isLayoutDirty && (layout || layoutId)) {
this.isLayoutDirty = true;
}
if (attachResizeListener) {
let cancelDelay;
const resizeUnblockUpdate = () => (this.root.updateBlockedByResize = false);
attachResizeListener(instance, () => {
this.root.updateBlockedByResize = true;
cancelDelay && cancelDelay();
cancelDelay = delay(resizeUnblockUpdate, 250);
if (globalProjectionState.hasAnimatedSinceResize) {
globalProjectionState.hasAnimatedSinceResize = false;
this.nodes.forEach(finishAnimation);
}
});
}
if (layoutId) {
this.root.registerSharedNode(layoutId, this);
}
// Only register the handler if it requires layout animation
if (this.options.animate !== false &&
visualElement &&
(layoutId || layout)) {
this.addEventListener("didUpdate", ({ delta, hasLayoutChanged, hasRelativeTargetChanged, layout: newLayout, }) => {
if (this.isTreeAnimationBlocked()) {
this.target = undefined;
this.relativeTarget = undefined;
return;
}
// TODO: Check here if an animation exists
const layoutTransition = this.options.transition ||
visualElement.getDefaultTransition() ||
defaultLayoutTransition;
const { onLayoutAnimationStart, onLayoutAnimationComplete, } = visualElement.getProps();
/**
* The target layout of the element might stay the same,
* but its position relative to its parent has changed.
*/
const targetChanged = !this.targetLayout ||
!boxEqualsRounded(this.targetLayout, newLayout) ||
hasRelativeTargetChanged;
/**
* If the layout hasn't seemed to have changed, it might be that the
* element is visually in the same place in the document but its position
* relative to its parent has indeed changed. So here we check for that.
*/
const hasOnlyRelativeTargetChanged = !hasLayoutChanged && hasRelativeTargetChanged;
if (this.options.layoutRoot ||
(this.resumeFrom && this.resumeFrom.instance) ||
hasOnlyRelativeTargetChanged ||
(hasLayoutChanged &&
(targetChanged || !this.currentAnimation))) {
if (this.resumeFrom) {
this.resumingFrom = this.resumeFrom;
this.resumingFrom.resumingFrom = undefined;
}
this.setAnimationOrigin(delta, hasOnlyRelativeTargetChanged);
const animationOptions = {
...getValueTransition(layoutTransition, "layout"),
onPlay: onLayoutAnimationStart,
onComplete: onLayoutAnimationComplete,
};
if (visualElement.shouldReduceMotion ||
this.options.layoutRoot) {
animationOptions.delay = 0;
animationOptions.type = false;
}
this.startAnimation(animationOptions);
}
else {
/**
* If the layout hasn't changed and we have an animation that hasn't started yet,
* finish it immediately. Otherwise it will be animating from a location
* that was probably never commited to screen and look like a jumpy box.
*/
if (!hasLayoutChanged) {
finishAnimation(this);
}
if (this.isLead() && this.options.onExitComplete) {
this.options.onExitComplete();
}
}
this.targetLayout = newLayout;
});
}
}
unmount() {
this.options.layoutId && this.willUpdate();
this.root.nodes.remove(this);
const stack = this.getStack();
stack && stack.remove(this);
this.parent && this.parent.children.delete(this);
this.instance = undefined;
cancelFrame(this.updateProjection);
}
// only on the root
blockUpdate() {
this.updateManuallyBlocked = true;
}
unblockUpdate() {
this.updateManuallyBlocked = false;
}
isUpdateBlocked() {
return this.updateManuallyBlocked || this.updateBlockedByResize;
}
isTreeAnimationBlocked() {
return (this.isAnimationBlocked ||
(this.parent && this.parent.isTreeAnimationBlocked()) ||
false);
}
// Note: currently only running on root node
startUpdate() {
if (this.isUpdateBlocked())
return;
this.isUpdating = true;
this.nodes && this.nodes.forEach(resetSkewAndRotation);
this.animationId++;
}
getTransformTemplate() {
const { visualElement } = this.options;
return visualElement && visualElement.getProps().transformTemplate;
}
willUpdate(shouldNotifyListeners = true) {
this.root.hasTreeAnimated = true;
if (this.root.isUpdateBlocked()) {
this.options.onExitComplete && this.options.onExitComplete();
return;
}
/**
* If we're running optimised appear animations then these must be
* cancelled before measuring the DOM. This is so we can measure
* the true layout of the element rather than the WAAPI animation
* which will be unaffected by the resetSkewAndRotate step.
*
* Note: This is a DOM write. Worst case scenario is this is sandwiched
* between other snapshot reads which will cause unnecessary style recalculations.
* This has to happen here though, as we don't yet know which nodes will need
* snapshots in startUpdate(), but we only want to cancel optimised animations
* if a layout animation measurement is actually going to be affected by them.
*/
if (window.MotionCancelOptimisedAnimation &&
!this.hasCheckedOptimisedAppear) {
cancelTreeOptimisedTransformAnimations(this);
}
!this.root.isUpdating && this.root.startUpdate();
if (this.isLayoutDirty)
return;
this.isLayoutDirty = true;
for (let i = 0; i < this.path.length; i++) {
const node = this.path[i];
node.shouldResetTransform = true;
node.updateScroll("snapshot");
if (node.options.layoutRoot) {
node.willUpdate(false);
}
}
const { layoutId, layout } = this.options;
if (layoutId === undefined && !layout)
return;
const transformTemplate = this.getTransformTemplate();
this.prevTransformTemplateValue = transformTemplate
? transformTemplate(this.latestValues, "")
: undefined;
this.updateSnapshot();
shouldNotifyListeners && this.notifyListeners("willUpdate");
}
update() {
this.updateScheduled = false;
const updateWasBlocked = this.isUpdateBlocked();
// When doing an instant transition, we skip the layout update,
// but should still clean up the measurements so that the next
// snapshot could be taken correctly.
if (updateWasBlocked) {
this.unblockUpdate();
this.clearAllSnapshots();
this.nodes.forEach(clearMeasurements);
return;
}
if (!this.isUpdating) {
this.nodes.forEach(clearIsLayoutDirty);
}
this.isUpdating = false;
/**
* Write
*/
this.nodes.forEach(resetTransformStyle);
/**
* Read ==================
*/
// Update layout measurements of updated children
this.nodes.forEach(updateLayout);
/**
* Write
*/
// Notify listeners that the layout is updated
this.nodes.forEach(notifyLayoutUpdate);
this.clearAllSnapshots();
/**
* Manually flush any pending updates. Ideally
* we could leave this to the following requestAnimationFrame but this seems
* to leave a flash of incorrectly styled content.
*/
const now = time.now();
frameData.delta = clamp(0, 1000 / 60, now - frameData.timestamp);
frameData.timestamp = now;
frameData.isProcessing = true;
frameSteps.update.process(frameData);
frameSteps.preRender.process(frameData);
frameSteps.render.process(frameData);
frameData.isProcessing = false;
}
didUpdate() {
if (!this.updateScheduled) {
this.updateScheduled = true;
microtask.read(this.scheduleUpdate);
}
}
clearAllSnapshots() {
this.nodes.forEach(clearSnapshot);
this.sharedNodes.forEach(removeLeadSnapshots);
}
scheduleUpdateProjection() {
if (!this.projectionUpdateScheduled) {
this.projectionUpdateScheduled = true;
frame.preRender(this.updateProjection, false, true);
}
}
scheduleCheckAfterUnmount() {
/**
* If the unmounting node is in a layoutGroup and did trigger a willUpdate,
* we manually call didUpdate to give a chance to the siblings to animate.
* Otherwise, cleanup all snapshots to prevents future nodes from reusing them.
*/
frame.postRender(() => {
if (this.isLayoutDirty) {
this.root.didUpdate();
}
else {
this.root.checkUpdateFailed();
}
});
}
/**
* Update measurements
*/
updateSnapshot() {
if (this.snapshot || !this.instance)
return;
this.snapshot = this.measure();
}
updateLayout() {
if (!this.instance)
return;
// TODO: Incorporate into a forwarded scroll offset
this.updateScroll();
if (!(this.options.alwaysMeasureLayout && this.isLead()) &&
!this.isLayoutDirty) {
return;
}
/**
* When a node is mounted, it simply resumes from the prevLead's
* snapshot instead of taking a new one, but the ancestors scroll
* might have updated while the prevLead is unmounted. We need to
* update the scroll again to make sure the layout we measure is
* up to date.
*/
if (this.resumeFrom && !this.resumeFrom.instance) {
for (let i = 0; i < this.path.length; i++) {
const node = this.path[i];
node.updateScroll();
}
}
const prevLayout = this.layout;
this.layout = this.measure(false);
this.layoutCorrected = createBox();
this.isLayoutDirty = false;
this.projectionDelta = undefined;
this.notifyListeners("measure", this.layout.layoutBox);
const { visualElement } = this.options;
visualElement &&
visualElement.notify("LayoutMeasure", this.layout.layoutBox, prevLayout ? prevLayout.layoutBox : undefined);
}
updateScroll(phase = "measure") {
let needsMeasurement = Boolean(this.options.layoutScroll && this.instance);
if (this.scroll &&
this.scroll.animationId === this.root.animationId &&
this.scroll.phase === phase) {
needsMeasurement = false;
}
if (needsMeasurement) {
const isRoot = checkIsScrollRoot(this.instance);
this.scroll = {
animationId: this.root.animationId,
phase,
isRoot,
offset: measureScroll(this.instance),
wasRoot: this.scroll ? this.scroll.isRoot : isRoot,
};
}
}
resetTransform() {
if (!resetTransform)
return;
const isResetRequested = this.isLayoutDirty ||
this.shouldResetTransform ||
this.options.alwaysMeasureLayout;
const hasProjection = this.projectionDelta && !isDeltaZero(this.projectionDelta);
const transformTemplate = this.getTransformTemplate();
const transformTemplateValue = transformTemplate
? transformTemplate(this.latestValues, "")
: undefined;
const transformTemplateHasChanged = transformTemplateValue !== this.prevTransformTemplateValue;
if (isResetRequested &&
(hasProjection ||
hasTransform(this.latestValues) ||
transformTemplateHasChanged)) {
resetTransform(this.instance, transformTemplateValue);
this.shouldResetTransform = false;
this.scheduleRender();
}
}
measure(removeTransform = true) {
const pageBox = this.measurePageBox();
let layoutBox = this.removeElementScroll(pageBox);
/**
* Measurements taken during the pre-render stage
* still have transforms applied so we remove them
* via calculation.
*/
if (removeTransform) {
layoutBox = this.removeTransform(layoutBox);
}
roundBox(layoutBox);
return {
animationId: this.root.animationId,
measuredBox: pageBox,
layoutBox,
latestValues: {},
source: this.id,
};
}
measurePageBox() {
var _a;
const { visualElement } = this.options;
if (!visualElement)
return createBox();
const box = visualElement.measureViewportBox();
const wasInScrollRoot = ((_a = this.scroll) === null || _a === void 0 ? void 0 : _a.wasRoot) || this.path.some(checkNodeWasScrollRoot);
if (!wasInScrollRoot) {
// Remove viewport scroll to give page-relative coordinates
const { scroll } = this.root;
if (scroll) {
translateAxis(box.x, scroll.offset.x);
translateAxis(box.y, scroll.offset.y);
}
}
return box;
}
removeElementScroll(box) {
var _a;
const boxWithoutScroll = createBox();
copyBoxInto(boxWithoutScroll, box);
if ((_a = this.scroll) === null || _a === void 0 ? void 0 : _a.wasRoot) {
return boxWithoutScroll;
}
/**
* Performance TODO: Keep a cumulative scroll offset down the tree
* rather than loop back up the path.
*/
for (let i = 0; i < this.path.length; i++) {
const node = this.path[i];
const { scroll, options } = node;
if (node !== this.root && scroll && options.layoutScroll) {
/**
* If this is a new scroll root, we want to remove all previous scrolls
* from the viewport box.
*/
if (scroll.wasRoot) {
copyBoxInto(boxWithoutScroll, box);
}
translateAxis(boxWithoutScroll.x, scroll.offset.x);
translateAxis(boxWithoutScroll.y, scroll.offset.y);
}
}
return boxWithoutScroll;
}
applyTransform(box, transformOnly = false) {
const withTransforms = createBox();
copyBoxInto(withTransforms, box);
for (let i = 0; i < this.path.length; i++) {
const node = this.path[i];
if (!transformOnly &&
node.options.layoutScroll &&
node.scroll &&
node !== node.root) {
transformBox(withTransforms, {
x: -node.scroll.offset.x,
y: -node.scroll.offset.y,
});
}
if (!hasTransform(node.latestValues))
continue;
transformBox(withTransforms, node.latestValues);
}
if (hasTransform(this.latestValues)) {
transformBox(withTransforms, this.latestValues);
}
return withTransforms;
}
removeTransform(box) {
const boxWithoutTransform = createBox();
copyBoxInto(boxWithoutTransform, box);
for (let i = 0; i < this.path.length; i++) {
const node = this.path[i];
if (!node.instance)
continue;
if (!hasTransform(node.latestValues))
continue;
hasScale(node.latestValues) && node.updateSnapshot();
const sourceBox = createBox();
const nodeBox = node.measurePageBox();
copyBoxInto(sourceBox, nodeBox);
removeBoxTransforms(boxWithoutTransform, node.latestValues, node.snapshot ? node.snapshot.layoutBox : undefined, sourceBox);
}
if (hasTransform(this.latestValues)) {
removeBoxTransforms(boxWithoutTransform, this.latestValues);
}
return boxWithoutTransform;
}
setTargetDelta(delta) {
this.targetDelta = delta;
this.root.scheduleUpdateProjection();
this.isProjectionDirty = true;
}
setOptions(options) {
this.options = {
...this.options,
...options,
crossfade: options.crossfade !== undefined ? options.crossfade : true,
};
}
clearMeasurements() {
this.scroll = undefined;
this.layout = undefined;
this.snapshot = undefined;
this.prevTransformTemplateValue = undefined;
this.targetDelta = undefined;
this.target = undefined;
this.isLayoutDirty = false;
}
forceRelativeParentToResolveTarget() {
if (!this.relativeParent)
return;
/**
* If the parent target isn't up-to-date, force it to update.
* This is an unfortunate de-optimisation as it means any updating relative
* projection will cause all the relative parents to recalculate back
* up the tree.
*/
if (this.relativeParent.resolvedRelativeTargetAt !==
frameData.timestamp) {
this.relativeParent.resolveTargetDelta(true);
}
}
resolveTargetDelta(forceRecalculation = false) {
var _a;
/**
* Once the dirty status of nodes has been spread through the tree, we also
* need to check if we have a shared node of a different depth that has itself
* been dirtied.
*/
const lead = this.getLead();
this.isProjectionDirty || (this.isProjectionDirty = lead.isProjectionDirty);
this.isTransformDirty || (this.isTransformDirty = lead.isTransformDirty);
this.isSharedProjectionDirty || (this.isSharedProjectionDirty = lead.isSharedProjectionDirty);
const isShared = Boolean(this.resumingFrom) || this !== lead;
/**
* We don't use transform for this step of processing so we don't
* need to check whether any nodes have changed transform.
*/
const canSkip = !(forceRecalculation ||
(isShared && this.isSharedProjectionDirty) ||
this.isProjectionDirty ||
((_a = this.parent) === null || _a === void 0 ? void 0 : _a.isProjectionDirty) ||
this.attemptToResolveRelativeTarget ||
this.root.updateBlockedByResize);
if (canSkip)
return;
const { layout, layoutId } = this.options;
/**
* If we have no layout, we can't perform projection, so early return
*/
if (!this.layout || !(layout || layoutId))
return;
this.resolvedRelativeTargetAt = frameData.timestamp;
/**
* If we don't have a targetDelta but do have a layout, we can attempt to resolve
* a relativeParent. This will allow a component to perform scale correction
* even if no animation has started.
*/
if (!this.targetDelta && !this.relativeTarget) {
const relativeParent = this.getClosestProjectingParent();
if (relativeParent &&
relativeParent.layout &&
this.animationProgress !== 1) {
this.relativeParent = relativeParent;
this.forceRelativeParentToResolveTarget();
this.relativeTarget = createBox();
this.relativeTargetOrigin = createBox();
calcRelativePosition(this.relativeTargetOrigin, this.layout.layoutBox, relativeParent.layout.layoutBox);
copyBoxInto(this.relativeTarget, this.relativeTargetOrigin);
}
else {
this.relativeParent = this.relativeTarget = undefined;
}
}
/**
* If we have no relative target or no target delta our target isn't valid
* for this frame.
*/
if (!this.relativeTarget && !this.targetDelta)
return;
/**
* Lazy-init target data structure
*/
if (!this.target) {
this.target = createBox();
this.targetWithTransforms = createBox();
}
/**
* If we've got a relative box for this component, resolve it into a target relative to the parent.
*/
if (this.relativeTarget &&
this.relativeTargetOrigin &&
this.relativeParent &&
this.relativeParent.target) {
this.forceRelativeParentToResolveTarget();
calcRelativeBox(this.target, this.relativeTarget, this.relativeParent.target);
/**
* If we've only got a targetDelta, resolve it into a target
*/
}
else if (this.targetDelta) {
if (Boolean(this.resumingFrom)) {
// TODO: This is creating a new object every frame
this.target = this.applyTransform(this.layout.layoutBox);
}
else {
copyBoxInto(this.target, this.layout.layoutBox);
}
applyBoxDelta(this.target, this.targetDelta);
}
else {
/**
* If no target, use own layout as target
*/
copyBoxInto(this.target, this.layout.layoutBox);
}
/**
* If we've been told to attempt to resolve a relative target, do so.
*/
if (this.attemptToResolveRelativeTarget) {
this.attemptToResolveRelativeTarget = false;
const relativeParent = this.getClosestProjectingParent();
if (relativeParent &&
Boolean(relativeParent.resumingFrom) ===
Boolean(this.resumingFrom) &&
!relativeParent.options.layoutScroll &&
relativeParent.target &&
this.animationProgress !== 1) {
this.relativeParent = relativeParent;
this.forceRelativeParentToResolveTarget();
this.relativeTarget = createBox();
this.relativeTargetOrigin = createBox();
calcRelativePosition(this.relativeTargetOrigin, this.target, relativeParent.target);
copyBoxInto(this.relativeTarget, this.relativeTargetOrigin);
}
else {
this.relativeParent = this.relativeTarget = undefined;
}
}
/**
* Increase debug counter for resolved target deltas
*/
if (isDebug) {
metrics.resolvedTargetDeltas++;
}
}
getClosestProjectingParent() {
if (!this.parent ||
hasScale(this.parent.latestValues) ||
has2DTranslate(this.parent.latestValues)) {
return undefined;
}
if (this.parent.isProjecting()) {
return this.parent;
}
else {
return this.parent.getClosestProjectingParent();
}
}
isProjecting() {
return Boolean((this.relativeTarget ||
this.targetDelta ||
this.options.layoutRoot) &&
this.layout);
}
calcProjection() {
var _a;
const lead = this.getLead();
const isShared = Boolean(this.resumingFrom) || this !== lead;
let canSkip = true;
/**
* If this is a normal layout animation and neither this node nor its nearest projecting
* is dirty then we can't skip.
*/
if (this.isProjectionDirty || ((_a = this.parent) === null || _a === void 0 ? void 0 : _a.isProjectionDirty)) {
canSkip = false;
}
/**
* If this is a shared layout animation and this node's shared projection is dirty then
* we can't skip.
*/
if (isShared &&
(this.isSharedProjectionDirty || this.isTransformDirty)) {
canSkip = false;
}
/**
* If we have resolved the target this frame we must recalculate the
* projection to ensure it visually represents the internal calculations.
*/
if (this.resolvedRelativeTargetAt === frameData.timestamp) {
canSkip = false;
}
if (canSkip)
return;
const { layout, layoutId } = this.options;
/**
* If this section of the tree isn't animating we can
* delete our target sources for the following frame.
*/
this.isTreeAnimating = Boolean((this.parent && this.parent.isTreeAnimating) ||
this.currentAnimation ||
this.pendingAnimation);
if (!this.isTreeAnimating) {
this.targetDelta = this.relativeTarget = undefined;
}
if (!this.layout || !(layout || layoutId))
return;
/**
* Reset the corrected box with the latest values from box, as we're then going
* to perform mutative operations on it.
*/
copyBoxInto(this.layoutCorrected, this.layout.layoutBox);
/**
* Record previous tree scales before updating.
*/
const prevTreeScaleX = this.treeScale.x;
const prevTreeScaleY = this.treeScale.y;
/**
* Apply all the parent deltas to this box to produce the corrected box. This
* is the layout box, as it will appear on screen as a result of the transforms of its parents.
*/
applyTreeDeltas(this.layoutCorrected, this.treeScale, this.path, isShared);
/**
* If this layer needs to perform scale correction but doesn't have a target,
* use the layout as the target.
*/
if (lead.layout &&
!lead.target &&
(this.treeScale.x !== 1 || this.treeScale.y !== 1)) {
lead.target = lead.layout.layoutBox;
lead.targetWithTransforms = createBox();
}
const { target } = lead;
if (!target) {
/**
* If we don't have a target to project into, but we were previously
* projecting, we want to remove the stored transform and schedule
* a render to ensure the elements reflect the removed transform.
*/
if (this.prevProjectionDelta) {
this.createProjectionDeltas();
this.scheduleRender();
}
return;
}
if (!this.projectionDelta || !this.prevProjectionDelta) {
this.createProjectionDeltas();
}
else {
copyAxisDeltaInto(this.prevProjectionDelta.x, this.projectionDelta.x);
copyAxisDeltaInto(this.prevProjectionDelta.y, this.projectionDelta.y);
}
/**
* Update the delta between the corrected box and the target box before user-set transforms were applied.
* This will allow us to calculate the corrected borderRadius and boxShadow to compensate
* for our layout reprojection, but still allow them to be scaled correctly by the user.
* It might be that to simplify this we may want to accept that user-set scale is also corrected
* and we wouldn't have to keep and calc both deltas, OR we could support a user setting
* to allow people to choose whether these styles are corrected based on just the
* layout reprojection or the final bounding box.
*/
calcBoxDelta(this.projectionDelta, this.layoutCorrected, target, this.latestValues);
if (this.treeScale.x !== prevTreeScaleX ||
this.treeScale.y !== prevTreeScaleY ||
!axisDeltaEquals(this.projectionDelta.x, this.prevProjectionDelta.x) ||
!axisDeltaEquals(this.projectionDelta.y, this.prevProjectionDelta.y)) {
this.hasProjected = true;
this.scheduleRender();
this.notifyListeners("projectionUpdate", target);
}
/**
* Increase debug counter for recalculated projections
*/
if (isDebug) {
metrics.recalculatedProjection++;
}
}
hide() {
this.isVisible = false;
// TODO: Schedule render
}
show() {
this.isVisible = true;
// TODO: Schedule render
}
scheduleRender(notifyAll = true) {
var _a;
(_a = this.options.visualElement) === null || _a === void 0 ? void 0 : _a.scheduleRender();
if (notifyAll) {
const stack = this.getStack();
stack && stack.scheduleRender();
}
if (this.resumingFrom && !this.resumingFrom.instance) {
this.resumingFrom = undefined;
}
}
createProjectionDeltas() {
this.prevProjectionDelta = createDelta();
this.projectionDelta = createDelta();
this.projectionDeltaWithTransform = createDelta();
}
setAnimationOrigin(delta, hasOnlyRelativeTargetChanged = false) {
const snapshot = this.snapshot;
const snapshotLatestValues = snapshot
? snapshot.latestValues
: {};
const mixedValues = { ...this.latestValues };
const targetDelta = createDelta();
if (!this.relativeParent ||
!this.relativeParent.options.layoutRoot) {
this.relativeTarget = this.relativeTargetOrigin = undefined;
}
this.attemptToResolveRelativeTarget = !hasOnlyRelativeTargetChanged;
const relativeLayout = createBox();
const snapshotSource = snapshot ? snapshot.source : undefined;
const layoutSource = this.layout ? this.layout.source : undefined;
const isSharedLayoutAnimation = snapshotSource !== layoutSource;
const stack = this.getStack();
const isOnlyMember = !stack || stack.members.length <= 1;
const shouldCrossfadeOpacity = Boolean(isSharedLayoutAnimation &&
!isOnlyMember &&
this.options.crossfade === true &&
!this.path.some(hasOpacityCrossfade));
this.animationProgress = 0;
let prevRelativeTarget;
this.mixTargetDelta = (latest) => {
const progress = latest / 1000;
mixAxisDelta(targetDelta.x, delta.x, progress);
mixAxisDelta(targetDelta.y, delta.y, progress);
this.setTargetDelta(targetDelta);
if (this.relativeTarget &&
this.relativeTargetOrigin &&
this.layout &&
this.relativeParent &&
this.relativeParent.layout) {
calcRelativePosition(relativeLayout, this.layout.layoutBox, this.relativeParent.layout.layoutBox);
mixBox(this.relativeTarget, this.relativeTargetOrigin, relativeLayout, progress);
/**
* If this is an unchanged relative target we can consider the
* projection not dirty.
*/
if (prevRelativeTarget &&
boxEquals(this.relativeTarget, prevRelativeTarget)) {
this.isProjectionDirty = false;
}
if (!prevRelativeTarget)
prevRelativeTarget = createBox();
copyBoxInto(prevRelativeTarget, this.relativeTarget);
}
if (isSharedLayoutAnimation) {
this.animationValues = mixedValues;
mixValues(mixedValues, snapshotLatestValues, this.latestValues, progress, shouldCrossfadeOpacity, isOnlyMember);
}
this.root.scheduleUpdateProjection();
this.scheduleRender();
this.animationProgress = progress;
};
this.mixTargetDelta(this.options.layoutRoot ? 1000 : 0);
}
startAnimation(options) {
this.notifyListeners("animationStart");
this.currentAnimation && this.currentAnimation.stop();
if (this.resumingFrom && this.resumingFrom.currentAnimation) {
this.resumingFrom.currentAnimation.stop();
}
if (this.pendingAnimation) {
cancelFrame(this.pendingAnimation);
this.pendingAnimation = undefined;
}
/**
* Start the animation in the next frame to have a frame with progress 0,
* where the target is the same as when the animation started, so we can
* calculate the relative positions correctly for instant transitions.
*/
this.pendingAnimation = frame.update(() => {
globalProjectionState.hasAnimatedSinceResize = true;
this.currentAnimation = animateSingleValue(0, animationTarget, {
...options,
onUpdate: (latest) => {
this.mixTargetDelta(latest);
options.onUpdate && options.onUpdate(latest);
},
onComplete: () => {
options.onComplete && options.onComplete();
this.completeAnimation();
},
});
if (this.resumingFrom) {
this.resumingFrom.currentAnimation = this.currentAnimation;
}
this.pendingAnimation = undefined;
});
}
completeAnimation() {
if (this.resumingFrom) {
this.resumingFrom.currentAnimation = undefined;
this.resumingFrom.preserveOpacity = undefined;
}
const stack = this.getStack();
stack && stack.exitAnimationComplete();
this.resumingFrom =
this.currentAnimation =
this.animationValues =
undefined;
this.notifyListeners("animationComplete");
}
finishAnimation() {
if (this.currentAnimation) {
this.mixTargetDelta && this.mixTargetDelta(animationTarget);
this.currentAnimation.stop();
}
this.completeAnimation();
}
applyTransformsToTarget() {
const lead = this.getLead();
let { targetWithTransforms, target, layout, latestValues } = lead;
if (!targetWithTransforms || !target || !layout)
return;
/**
* If we're only animating position, and this element isn't the lead element,
* then instead of projecting into the lead box we instead want to calculate
* a new target that aligns the two boxes but maintains the layout shape.
*/
if (this !== lead &&
this.layout &&
layout &&
shouldAnimatePositionOnly(this.options.animationType, this.layout.layoutBox, layout.layoutBox)) {
target = this.target || createBox();
const xLength = calcLength(this.layout.layoutBox.x);
target.x.min = lead.target.x.min;
target.x.max = target.x.min + xLength;
const yLength = calcLength(this.layout.layoutBox.y);
target.y.min = lead.target.y.min;
target.y.max = target.y.min + yLength;
}
copyBoxInto(targetWithTransforms, target);
/**
* Apply the latest user-set transforms to the targetBox to produce the targetBoxFinal.
* This is the final box that we will then project into by calculating a transform delta and
* applying it to the corrected box.
*/
transformBox(targetWithTransforms, latestValues);
/**
* Update the delta between the corrected box and the final target box, after
* user-set transforms are applied to it. This will be used by the renderer to
* create a transform style that will reproject the element from its layout layout
* into the desired bounding box.
*/
calcBoxDelta(this.projectionDeltaWithTransform, this.layoutCorrected, targetWithTransforms, latestValues);
}
registerSharedNode(layoutId, node) {
if (!this.sharedNodes.has(layoutId)) {
this.sharedNodes.set(layoutId, new NodeStack());
}
const stack = this.sharedNodes.get(layoutId);
stack.add(node);
const config = node.options.initialPromotionConfig;
node.promote({
transition: config ? config.transition : undefined,
preserveFollowOpacity: config && config.shouldPreserveFollowOpacity
? config.shouldPreserveFollowOpacity(node)
: undefined,
});
}
isLead() {
const stack = this.getStack();
return stack ? stack.lead === this : true;
}
getLead() {
var _a;
const { layoutId } = this.options;
return layoutId ? ((_a = this.getStack()) === null || _a === void 0 ? void 0 : _a.lead) || this : this;
}
getPrevLead() {
var _a;
const { layoutId } = this.options;
return layoutId ? (_a = this.getStack()) === null || _a === void 0 ? void 0 : _a.prevLead : undefined;
}
getStack() {
const { layoutId } = this.options;
if (layoutId)
return this.root.sharedNodes.get(layoutId);
}
promote({ needsReset, transition, preserveFollowOpacity, } = {}) {
const stack = this.getStack();
if (stack)
stack.promote(this, preserveFollowOpacity);
if (needsReset) {
this.projectionDelta = undefined;
this.needsReset = true;
}
if (transition)
this.setOptions({ transition });
}
relegate() {
const stack = this.getStack();
if (stack) {
return stack.relegate(this);
}
else {
return false;
}
}
resetSkewAndRotation() {
const { visualElement } = this.options;
if (!visualElement)
return;
// If there's no detected skew or rotation values, we can early return without a forced render.
let hasDistortingTransform = false;
/**
* An unrolled check for rotation values. Most elements don't have any rotation and
* skipping the nested loop and new object creation is 50% faster.
*/
const { latestValues } = visualElement;
if (latestValues.z ||
latestValues.rotate ||
latestValues.rotateX ||
latestValues.rotateY ||
latestValues.rotateZ ||
latestValues.skewX ||
latestValues.skewY) {
hasDistortingTransform = true;
}
// If there's no distorting values, we don't need to do any more.
if (!hasDistortingTransform)
return;
const resetValues = {};
if (latestValues.z) {
resetDistortingTransform("z", visualElement, resetValues, this.animationValues);
}
// Check the skew and rotate value of all axes and reset to 0
for (let i = 0; i < transformAxes.length; i++) {
resetDistortingTransform(`rotate${transformAxes[i]}`, visualElement, resetValues, this.animationValues);
resetDistortingTransform(`skew${transformAxes[i]}`, visualElement, resetValues, this.animationValues);
}
// Force a render of this element to apply the transform with all skews and rotations
// set to 0.
visualElement.render();
// Put back all the values we reset
for (const key in resetValues) {
visualElement.setStaticValue(key, resetValues[key]);
if (this.animationValues) {
this.animationValues[key] = resetValues[key];
}
}
// Schedule a render for the next frame. This ensures we won't visually
// see the element with the reset rotate value applied.
visualElement.scheduleRender();
}
getProjectionStyles(styleProp) {
var _a, _b;
if (!this.instance || this.isSVG)
return undefined;
if (!this.isVisible) {
return hiddenVisibility;
}
const styles = {
visibility: "",
};
const transformTemplate = this.getTransformTemplate();
if (this.needsReset) {
this.needsReset = false;
styles.opacity = "";
styles.pointerEvents =
resolveMotionValue(styleProp === null || styleProp === void 0 ? void 0 : styleProp.pointerEvents) || "";
styles.transform = transformTemplate
? transformTemplate(this.latestValues, "")
: "none";
return styles;
}
const lead = this.getLead();
if (!this.projectionDelta || !this.layout || !lead.target) {
const emptyStyles = {};
if (this.options.layoutId) {
emptyStyles.opacity =
this.latestValues.opacity !== undefined
? this.latestValues.opacity
: 1;
emptyStyles.pointerEvents =
resolveMotionValue(styleProp === null || styleProp === void 0 ? void 0 : styleProp.pointerEvents) || "";
}
if (this.hasProjected && !hasTransform(this.latestValues)) {
emptyStyles.transform = transformTemplate
? transformTemplate({}, "")
: "none";
this.hasProjected = false;
}
return emptyStyles;
}
const valuesToRender = lead.animationValues || lead.latestValues;
this.applyTransformsToTarget();
styles.transform = buildProjectionTransform(this.projectionDeltaWithTransform, this.treeScale, valuesToRender);
if (transformTemplate) {
styles.transform = transformTemplate(valuesToRender, styles.transform);
}
const { x, y } = this.projectionDelta;
styles.transformOrigin = `${x.origin * 100}% ${y.origin * 100}% 0`;
if (lead.animationValues) {
/**
* If the lead component is animating, assign this either the entering/leaving
* opacity
*/
styles.opacity =
lead === this
? (_b = (_a = valuesToRender.opacity) !== null && _a !== void 0 ? _a : this.latestValues.opacity) !== null && _b !== void 0 ? _b : 1
: this.preserveOpacity
? this.latestValues.opacity
: valuesToRender.opacityExit;
}
else {
/**
* Or we're not animating at all, set the lead component to its layout
* opacity and other components to hidden.
*/
styles.opacity =
lead === this
? valuesToRender.opacity !== undefined
? valuesToRender.opacity
: ""
: valuesToRender.opacityExit !== undefined
? valuesToRender.opacityExit
: 0;
}
/**
* Apply scale correction
*/
for (const key in scaleCorrectors) {
if (valuesToRender[key] === undefined)
continue;
const { correct, applyTo } = scaleCorrectors[key];
/**
* Only apply scale correction to the value if we have an
* active projection transform. Otherwise these values become
* vulnerable to distortion if the element changes size without
* a corresponding layout animation.
*/
const corrected = styles.transform === "none"
? valuesToRender[key]
: correct(valuesToRender[key], lead);
if (applyTo) {
const num = applyTo.length;
for (let i = 0; i < num; i++) {
styles[applyTo[i]] = corrected;
}
}
else {
styles[key] = corrected;
}
}
/**
* Disable pointer events on follow components. This is to ensure
* that if a follow component covers a lead component it doesn't block
* pointer events on the lead.
*/
if (this.options.layoutId) {
styles.pointerEvents =
lead === this
? resolveMotionValue(styleProp === null || styleProp === void 0 ? void 0 : styleProp.pointerEvents) || ""
: "none";
}
return styles;
}
clearSnapshot() {
this.resumeFrom = this.snapshot = undefined;
}
// Only run on root
resetTree() {
this.root.nodes.forEach((node) => { var _a; return (_a = node.currentAnimation) === null || _a === void 0 ? void 0 : _a.stop(); });
this.root.nodes.forEach(clearMeasurements);
this.root.sharedNodes.clear();
}
};
}
function updateLayout(node) {
node.updateLayout();
}
function notifyLayoutUpdate(node) {
var _a;
const snapshot = ((_a = node.resumeFrom) === null || _a === void 0 ? void 0 : _a.snapshot) || node.snapshot;
if (node.isLead() &&
node.layout &&
snapshot &&
node.hasListeners("didUpdate")) {
const { layoutBox: layout, measuredBox: measuredLayout } = node.layout;
const { animationType } = node.options;
const isShared = snapshot.source !== node.layout.source;
// TODO Maybe we want to also resize the layout snapshot so we don't trigger
// animations for instance if layout="size" and an element has only changed position
if (animationType === "size") {
eachAxis((axis) => {
const axisSnapshot = isShared
? snapshot.measuredBox[axis]
: snapshot.layoutBox[axis];
const length = calcLength(axisSnapshot);
axisSnapshot.min = layout[axis].min;
axisSnapshot.max = axisSnapshot.min + length;
});
}
else if (shouldAnimatePositionOnly(animationType, snapshot.layoutBox, layout)) {
eachAxis((axis) => {
const axisSnapshot = isShared
? snapshot.measuredBox[axis]
: snapshot.layoutBox[axis];
const length = calcLength(layout[axis]);
axisSnapshot.max = axisSnapshot.min + length;
/**
* Ensure relative target gets resized and rerendererd
*/
if (node.relativeTarget && !node.currentAnimation) {
node.isProjectionDirty = true;
node.relativeTarget[axis].max =
node.relativeTarget[axis].min + length;
}
});
}
const layoutDelta = createDelta();
calcBoxDelta(layoutDelta, layout, snapshot.layoutBox);
const visualDelta = createDelta();
if (isShared) {
calcBoxDelta(visualDelta, node.applyTransform(measuredLayout, true), snapshot.measuredBox);
}
else {
calcBoxDelta(visualDelta, layout, snapshot.layoutBox);
}
const hasLayoutChanged = !isDeltaZero(layoutDelta);
let hasRelativeTargetChanged = false;
if (!node.resumeFrom) {
const relativeParent = node.getClosestProjectingParent();
/**
* If the relativeParent is itself resuming from a different element then
* the relative snapshot is not relavent
*/
if (relativeParent && !relativeParent.resumeFrom) {
const { snapshot: parentSnapshot, layout: parentLayout } = relativeParent;
if (parentSnapshot && parentLayout) {
const relativeSnapshot = createBox();
calcRelativePosition(relativeSnapshot, snapshot.layoutBox, parentSnapshot.layoutBox);
const relativeLayout = createBox();
calcRelativePosition(relativeLayout, layout, parentLayout.layoutBox);
if (!boxEqualsRounded(relativeSnapshot, relativeLayout)) {
hasRelativeTargetChanged = true;
}
if (relativeParent.options.layoutRoot) {
node.relativeTarget = relativeLayout;
node.relativeTargetOrigin = relativeSnapshot;
node.relativeParent = relativeParent;
}
}
}
}
node.notifyListeners("didUpdate", {
layout,
snapshot,
delta: visualDelta,
layoutDelta,
hasLayoutChanged,
hasRelativeTargetChanged,
});
}
else if (node.isLead()) {
const { onExitComplete } = node.options;
onExitComplete && onExitComplete();
}
/**
* Clearing transition
* TODO: Investigate why this transition is being passed in as {type: false } from Framer
* and why we need it at all
*/
node.options.transition = undefined;
}
function propagateDirtyNodes(node) {
/**
* Increase debug counter for nodes encountered this frame
*/
if (isDebug) {
metrics.totalNodes++;
}
if (!node.parent)
return;
/**
* If this node isn't projecting, propagate isProjectionDirty. It will have
* no performance impact but it will allow the next child that *is* projecting
* but *isn't* dirty to just check its parent to see if *any* ancestor needs
* correcting.
*/
if (!node.isProjecting()) {
node.isProjectionDirty = node.parent.isProjectionDirty;
}
/**
* Propagate isSharedProjectionDirty and isTransformDirty
* throughout the whole tree. A future revision can take another look at
* this but for safety we still recalcualte shared nodes.
*/
node.isSharedProjectionDirty || (node.isSharedProjectionDirty = Boolean(node.isProjectionDirty ||
node.parent.isProjectionDirty ||
node.parent.isSharedProjectionDirty));
node.isTransformDirty || (node.isTransformDirty = node.parent.isTransformDirty);
}
function cleanDirtyNodes(node) {
node.isProjectionDirty =
node.isSharedProjectionDirty =
node.isTransformDirty =
false;
}
function clearSnapshot(node) {
node.clearSnapshot();
}
function clearMeasurements(node) {
node.clearMeasurements();
}
function clearIsLayoutDirty(node) {
node.isLayoutDirty = false;
}
function resetTransformStyle(node) {
const { visualElement } = node.options;
if (visualElement && visualElement.getProps().onBeforeLayoutMeasure) {
visualElement.notify("BeforeLayoutMeasure");
}
node.resetTransform();
}
function finishAnimation(node) {
node.finishAnimation();
node.targetDelta = node.relativeTarget = node.target = undefined;
node.isProjectionDirty = true;
}
function resolveTargetDelta(node) {
node.resolveTargetDelta();
}
function calcProjection(node) {
node.calcProjection();
}
function resetSkewAndRotation(node) {
node.resetSkewAndRotation();
}
function removeLeadSnapshots(stack) {
stack.removeLeadSnapshot();
}
function mixAxisDelta(output, delta, p) {
output.translate = mixNumber$1(delta.translate, 0, p);
output.scale = mixNumber$1(delta.scale, 1, p);
output.origin = delta.origin;
output.originPoint = delta.originPoint;
}
function mixAxis(output, from, to, p) {
output.min = mixNumber$1(from.min, to.min, p);
output.max = mixNumber$1(from.max, to.max, p);
}
function mixBox(output, from, to, p) {
mixAxis(output.x, from.x, to.x, p);
mixAxis(output.y, from.y, to.y, p);
}
function hasOpacityCrossfade(node) {
return (node.animationValues && node.animationValues.opacityExit !== undefined);
}
const defaultLayoutTransition = {
duration: 0.45,
ease: [0.4, 0, 0.1, 1],
};
const userAgentContains = (string) => typeof navigator !== "undefined" &&
navigator.userAgent &&
navigator.userAgent.toLowerCase().includes(string);
/**
* Measured bounding boxes must be rounded in Safari and
* left untouched in Chrome, otherwise non-integer layouts within scaled-up elements
* can appear to jump.
*/
const roundPoint = userAgentContains("applewebkit/") && !userAgentContains("chrome/")
? Math.round
: noop;
function roundAxis(axis) {
// Round to the nearest .5 pixels to support subpixel layouts
axis.min = roundPoint(axis.min);
axis.max = roundPoint(axis.max);
}
function roundBox(box) {
roundAxis(box.x);
roundAxis(box.y);
}
function shouldAnimatePositionOnly(animationType, snapshot, layout) {
return (animationType === "position" ||
(animationType === "preserve-aspect" &&
!isNear(aspectRatio(snapshot), aspectRatio(layout), 0.2)));
}
function checkNodeWasScrollRoot(node) {
var _a;
return node !== node.root && ((_a = node.scroll) === null || _a === void 0 ? void 0 : _a.wasRoot);
}
const DocumentProjectionNode = createProjectionNode$1({
attachResizeListener: (ref, notify) => addDomEvent(ref, "resize", notify),
measureScroll: () => ({
x: document.documentElement.scrollLeft || document.body.scrollLeft,
y: document.documentElement.scrollTop || document.body.scrollTop,
}),
checkIsScrollRoot: () => true,
});
const rootProjectionNode = {
current: undefined,
};
const HTMLProjectionNode = createProjectionNode$1({
measureScroll: (instance) => ({
x: instance.scrollLeft,
y: instance.scrollTop,
}),
defaultParent: () => {
if (!rootProjectionNode.current) {
const documentNode = new DocumentProjectionNode({});
documentNode.mount(window);
documentNode.setOptions({ layoutScroll: true });
rootProjectionNode.current = documentNode;
}
return rootProjectionNode.current;
},
resetTransform: (instance, value) => {
instance.style.transform = value !== undefined ? value : "none";
},
checkIsScrollRoot: (instance) => Boolean(window.getComputedStyle(instance).position === "fixed"),
});
function pixelsToPercent(pixels, axis) {
if (axis.max === axis.min)
return 0;
return (pixels / (axis.max - axis.min)) * 100;
}
/**
* We always correct borderRadius as a percentage rather than pixels to reduce paints.
* For example, if you are projecting a box that is 100px wide with a 10px borderRadius
* into a box that is 200px wide with a 20px borderRadius, that is actually a 10%
* borderRadius in both states. If we animate between the two in pixels that will trigger
* a paint each time. If we animate between the two in percentage we'll avoid a paint.
*/
const correctBorderRadius = {
correct: (latest, node) => {
if (!node.target)
return latest;
/**
* If latest is a string, if it's a percentage we can return immediately as it's
* going to be stretched appropriately. Otherwise, if it's a pixel, convert it to a number.
*/
if (typeof latest === "string") {
if (px.test(latest)) {
latest = parseFloat(latest);
}
else {
return latest;
}
}
/**
* If latest is a number, it's a pixel value. We use the current viewportBox to calculate that
* pixel value as a percentage of each axis
*/
const x = pixelsToPercent(latest, node.target.x);
const y = pixelsToPercent(latest, node.target.y);
return `${x}% ${y}%`;
},
};
const correctBoxShadow = {
correct: (latest, { treeScale, projectionDelta }) => {
const original = latest;
const shadow = complex.parse(latest);
// TODO: Doesn't support multiple shadows
if (shadow.length > 5)
return original;
const template = complex.createTransformer(latest);
const offset = typeof shadow[0] !== "number" ? 1 : 0;
// Calculate the overall context scale
const xScale = projectionDelta.x.scale * treeScale.x;
const yScale = projectionDelta.y.scale * treeScale.y;
shadow[0 + offset] /= xScale;
shadow[1 + offset] /= yScale;
/**
* Ideally we'd correct x and y scales individually, but because blur and
* spread apply to both we have to take a scale average and apply that instead.
* We could potentially improve the outcome of this by incorporating the ratio between
* the two scales.
*/
const averageScale = mixNumber$1(xScale, yScale, 0.5);
// Blur
if (typeof shadow[2 + offset] === "number")
shadow[2 + offset] /= averageScale;
// Spread
if (typeof shadow[3 + offset] === "number")
shadow[3 + offset] /= averageScale;
return template(shadow);
},
};
/**
* @public
*/
const PresenceContext = react.createContext(null);
/**
* When a component is the child of `AnimatePresence`, it can use `usePresence`
* to access information about whether it's still present in the React tree.
*
* ```jsx
* import { usePresence } from "framer-motion"
*
* export const Component = () => {
* const [isPresent, safeToRemove] = usePresence()
*
* useEffect(() => {
* !isPresent && setTimeout(safeToRemove, 1000)
* }, [isPresent])
*
* return <div />
* }
* ```
*
* If `isPresent` is `false`, it means that a component has been removed the tree, but
* `AnimatePresence` won't really remove it until `safeToRemove` has been called.
*
* @public
*/
function usePresence() {
const context = react.useContext(PresenceContext);
if (context === null)
return [true, null];
const { isPresent, onExitComplete, register } = context;
// It's safe to call the following hooks conditionally (after an early return) because the context will always
// either be null or non-null for the lifespan of the component.
const id = react.useId();
react.useEffect(() => register(id), []);
const safeToRemove = react.useCallback(() => onExitComplete && onExitComplete(id), [id, onExitComplete]);
return !isPresent && onExitComplete ? [false, safeToRemove] : [true];
}
const LayoutGroupContext = react.createContext({});
/**
* Internal, exported only for usage in Framer
*/
const SwitchLayoutGroupContext = react.createContext({});
class MeasureLayoutWithContext extends react.Component {
/**
* This only mounts projection nodes for components that
* need measuring, we might want to do it for all components
* in order to incorporate transforms
*/
componentDidMount() {
const { visualElement, layoutGroup, switchLayoutGroup, layoutId } = this.props;
const { projection } = visualElement;
addScaleCorrector(defaultScaleCorrectors);
if (projection) {
if (layoutGroup.group)
layoutGroup.group.add(projection);
if (switchLayoutGroup && switchLayoutGroup.register && layoutId) {
switchLayoutGroup.register(projection);
}
projection.root.didUpdate();
projection.addEventListener("animationComplete", () => {
this.safeToRemove();
});
projection.setOptions({
...projection.options,
onExitComplete: () => this.safeToRemove(),
});
}
globalProjectionState.hasEverUpdated = true;
}
getSnapshotBeforeUpdate(prevProps) {
const { layoutDependency, visualElement, drag, isPresent } = this.props;
const projection = visualElement.projection;
if (!projection)
return null;
/**
* TODO: We use this data in relegate to determine whether to
* promote a previous element. There's no guarantee its presence data
* will have updated by this point - if a bug like this arises it will
* have to be that we markForRelegation and then find a new lead some other way,
* perhaps in didUpdate
*/
projection.isPresent = isPresent;
if (drag ||
prevProps.layoutDependency !== layoutDependency ||
layoutDependency === undefined) {
projection.willUpdate();
}
else {
this.safeToRemove();
}
if (prevProps.isPresent !== isPresent) {
if (isPresent) {
projection.promote();
}
else if (!projection.relegate()) {
/**
* If there's another stack member taking over from this one,
* it's in charge of the exit animation and therefore should
* be in charge of the safe to remove. Otherwise we call it here.
*/
frame.postRender(() => {
const stack = projection.getStack();
if (!stack || !stack.members.length) {
this.safeToRemove();
}
});
}
}
return null;
}
componentDidUpdate() {
const { projection } = this.props.visualElement;
if (projection) {
projection.root.didUpdate();
microtask.postRender(() => {
if (!projection.currentAnimation && projection.isLead()) {
this.safeToRemove();
}
});
}
}
componentWillUnmount() {
const { visualElement, layoutGroup, switchLayoutGroup: promoteContext, } = this.props;
const { projection } = visualElement;
if (projection) {
projection.scheduleCheckAfterUnmount();
if (layoutGroup && layoutGroup.group)
layoutGroup.group.remove(projection);
if (promoteContext && promoteContext.deregister)
promoteContext.deregister(projection);
}
}
safeToRemove() {
const { safeToRemove } = this.props;
safeToRemove && safeToRemove();
}
render() {
return null;
}
}
function MeasureLayout(props) {
const [isPresent, safeToRemove] = usePresence();
const layoutGroup = react.useContext(LayoutGroupContext);
return (jsxRuntime.jsx(MeasureLayoutWithContext, { ...props, layoutGroup: layoutGroup, switchLayoutGroup: react.useContext(SwitchLayoutGroupContext), isPresent: isPresent, safeToRemove: safeToRemove }));
}
const defaultScaleCorrectors = {
borderRadius: {
...correctBorderRadius,
applyTo: [
"borderTopLeftRadius",
"borderTopRightRadius",
"borderBottomLeftRadius",
"borderBottomRightRadius",
],
},
borderTopLeftRadius: correctBorderRadius,
borderTopRightRadius: correctBorderRadius,
borderBottomLeftRadius: correctBorderRadius,
borderBottomRightRadius: correctBorderRadius,
boxShadow: correctBoxShadow,
};
const drag = {
pan: {
Feature: PanGesture,
},
drag: {
Feature: DragGesture,
ProjectionNode: HTMLProjectionNode,
MeasureLayout,
},
};
function addHoverEvent(node, isActive) {
const eventName = isActive ? "pointerenter" : "pointerleave";
const callbackName = isActive ? "onHoverStart" : "onHoverEnd";
const handleEvent = (event, info) => {
if (event.pointerType === "touch" || isDragActive())
return;
const props = node.getProps();
if (node.animationState && props.whileHover) {
node.animationState.setActive("whileHover", isActive);
}
const callback = props[callbackName];
if (callback) {
frame.postRender(() => callback(event, info));
}
};
return addPointerEvent(node.current, eventName, handleEvent, {
passive: !node.getProps()[callbackName],
});
}
class HoverGesture extends Feature {
mount() {
this.unmount = pipe(addHoverEvent(this.node, true), addHoverEvent(this.node, false));
}
unmount() { }
}
class FocusGesture extends Feature {
constructor() {
super(...arguments);
this.isActive = false;
}
onFocus() {
let isFocusVisible = false;
/**
* If this element doesn't match focus-visible then don't
* apply whileHover. But, if matches throws that focus-visible
* is not a valid selector then in that browser outline styles will be applied
* to the element by default and we want to match that behaviour with whileFocus.
*/
try {
isFocusVisible = this.node.current.matches(":focus-visible");
}
catch (e) {
isFocusVisible = true;
}
if (!isFocusVisible || !this.node.animationState)
return;
this.node.animationState.setActive("whileFocus", true);
this.isActive = true;
}
onBlur() {
if (!this.isActive || !this.node.animationState)
return;
this.node.animationState.setActive("whileFocus", false);
this.isActive = false;
}
mount() {
this.unmount = pipe(addDomEvent(this.node.current, "focus", () => this.onFocus()), addDomEvent(this.node.current, "blur", () => this.onBlur()));
}
unmount() { }
}
/**
* Recursively traverse up the tree to check whether the provided child node
* is the parent or a descendant of it.
*
* @param parent - Element to find
* @param child - Element to test against parent
*/
const isNodeOrChild = (parent, child) => {
if (!child) {
return false;
}
else if (parent === child) {
return true;
}
else {
return isNodeOrChild(parent, child.parentElement);
}
};
function fireSyntheticPointerEvent(name, handler) {
if (!handler)
return;
const syntheticPointerEvent = new PointerEvent("pointer" + name);
handler(syntheticPointerEvent, extractEventInfo(syntheticPointerEvent));
}
class PressGesture extends Feature {
constructor() {
super(...arguments);
this.removeStartListeners = noop;
this.removeEndListeners = noop;
this.removeAccessibleListeners = noop;
this.startPointerPress = (startEvent, startInfo) => {
if (this.isPressing)
return;
this.removeEndListeners();
const props = this.node.getProps();
const endPointerPress = (endEvent, endInfo) => {
if (!this.checkPressEnd())
return;
const { onTap, onTapCancel, globalTapTarget } = this.node.getProps();
/**
* We only count this as a tap gesture if the event.target is the same
* as, or a child of, this component's element
*/
const handler = !globalTapTarget &&
!isNodeOrChild(this.node.current, endEvent.target)
? onTapCancel
: onTap;
if (handler) {
frame.update(() => handler(endEvent, endInfo));
}
};
const removePointerUpListener = addPointerEvent(window, "pointerup", endPointerPress, {
passive: !(props.onTap || props["onPointerUp"]),
});
const removePointerCancelListener = addPointerEvent(window, "pointercancel", (cancelEvent, cancelInfo) => this.cancelPress(cancelEvent, cancelInfo), {
passive: !(props.onTapCancel ||
props["onPointerCancel"]),
});
this.removeEndListeners = pipe(removePointerUpListener, removePointerCancelListener);
this.startPress(startEvent, startInfo);
};
this.startAccessiblePress = () => {
const handleKeydown = (keydownEvent) => {
if (keydownEvent.key !== "Enter" || this.isPressing)
return;
const handleKeyup = (keyupEvent) => {
if (keyupEvent.key !== "Enter" || !this.checkPressEnd())
return;
fireSyntheticPointerEvent("up", (event, info) => {
const { onTap } = this.node.getProps();
if (onTap) {
frame.postRender(() => onTap(event, info));
}
});
};
this.removeEndListeners();
this.removeEndListeners = addDomEvent(this.node.current, "keyup", handleKeyup);
fireSyntheticPointerEvent("down", (event, info) => {
this.startPress(event, info);
});
};
const removeKeydownListener = addDomEvent(this.node.current, "keydown", handleKeydown);
const handleBlur = () => {
if (!this.isPressing)
return;
fireSyntheticPointerEvent("cancel", (cancelEvent, cancelInfo) => this.cancelPress(cancelEvent, cancelInfo));
};
const removeBlurListener = addDomEvent(this.node.current, "blur", handleBlur);
this.removeAccessibleListeners = pipe(removeKeydownListener, removeBlurListener);
};
}
startPress(event, info) {
this.isPressing = true;
const { onTapStart, whileTap } = this.node.getProps();
/**
* Ensure we trigger animations before firing event callback
*/
if (whileTap && this.node.animationState) {
this.node.animationState.setActive("whileTap", true);
}
if (onTapStart) {
frame.postRender(() => onTapStart(event, info));
}
}
checkPressEnd() {
this.removeEndListeners();
this.isPressing = false;
const props = this.node.getProps();
if (props.whileTap && this.node.animationState) {
this.node.animationState.setActive("whileTap", false);
}
return !isDragActive();
}
cancelPress(event, info) {
if (!this.checkPressEnd())
return;
const { onTapCancel } = this.node.getProps();
if (onTapCancel) {
frame.postRender(() => onTapCancel(event, info));
}
}
mount() {
const props = this.node.getProps();
const removePointerListener = addPointerEvent(props.globalTapTarget ? window : this.node.current, "pointerdown", this.startPointerPress, {
passive: !(props.onTapStart ||
props["onPointerStart"]),
});
const removeFocusListener = addDomEvent(this.node.current, "focus", this.startAccessiblePress);
this.removeStartListeners = pipe(removePointerListener, removeFocusListener);
}
unmount() {
this.removeStartListeners();
this.removeEndListeners();
this.removeAccessibleListeners();
}
}
/**
* Map an IntersectionHandler callback to an element. We only ever make one handler for one
* element, so even though these handlers might all be triggered by different
* observers, we can keep them in the same map.
*/
const observerCallbacks = new WeakMap();
/**
* Multiple observers can be created for multiple element/document roots. Each with
* different settings. So here we store dictionaries of observers to each root,
* using serialised settings (threshold/margin) as lookup keys.
*/
const observers = new WeakMap();
const fireObserverCallback = (entry) => {
const callback = observerCallbacks.get(entry.target);
callback && callback(entry);
};
const fireAllObserverCallbacks = (entries) => {
entries.forEach(fireObserverCallback);
};
function initIntersectionObserver({ root, ...options }) {
const lookupRoot = root || document;
/**
* If we don't have an observer lookup map for this root, create one.
*/
if (!observers.has(lookupRoot)) {
observers.set(lookupRoot, {});
}
const rootObservers = observers.get(lookupRoot);
const key = JSON.stringify(options);
/**
* If we don't have an observer for this combination of root and settings,
* create one.
*/
if (!rootObservers[key]) {
rootObservers[key] = new IntersectionObserver(fireAllObserverCallbacks, { root, ...options });
}
return rootObservers[key];
}
function observeIntersection(element, options, callback) {
const rootInteresectionObserver = initIntersectionObserver(options);
observerCallbacks.set(element, callback);
rootInteresectionObserver.observe(element);
return () => {
observerCallbacks.delete(element);
rootInteresectionObserver.unobserve(element);
};
}
const thresholdNames = {
some: 0,
all: 1,
};
class InViewFeature extends Feature {
constructor() {
super(...arguments);
this.hasEnteredView = false;
this.isInView = false;
}
startObserver() {
this.unmount();
const { viewport = {} } = this.node.getProps();
const { root, margin: rootMargin, amount = "some", once } = viewport;
const options = {
root: root ? root.current : undefined,
rootMargin,
threshold: typeof amount === "number" ? amount : thresholdNames[amount],
};
const onIntersectionUpdate = (entry) => {
const { isIntersecting } = entry;
/**
* If there's been no change in the viewport state, early return.
*/
if (this.isInView === isIntersecting)
return;
this.isInView = isIntersecting;
/**
* Handle hasEnteredView. If this is only meant to run once, and
* element isn't visible, early return. Otherwise set hasEnteredView to true.
*/
if (once && !isIntersecting && this.hasEnteredView) {
return;
}
else if (isIntersecting) {
this.hasEnteredView = true;
}
if (this.node.animationState) {
this.node.animationState.setActive("whileInView", isIntersecting);
}
/**
* Use the latest committed props rather than the ones in scope
* when this observer is created
*/
const { onViewportEnter, onViewportLeave } = this.node.getProps();
const callback = isIntersecting ? onViewportEnter : onViewportLeave;
callback && callback(entry);
};
return observeIntersection(this.node.current, options, onIntersectionUpdate);
}
mount() {
this.startObserver();
}
update() {
if (typeof IntersectionObserver === "undefined")
return;
const { props, prevProps } = this.node;
const hasOptionsChanged = ["amount", "margin", "root"].some(hasViewportOptionChanged(props, prevProps));
if (hasOptionsChanged) {
this.startObserver();
}
}
unmount() { }
}
function hasViewportOptionChanged({ viewport = {} }, { viewport: prevViewport = {} } = {}) {
return (name) => viewport[name] !== prevViewport[name];
}
const gestureAnimations = {
inView: {
Feature: InViewFeature,
},
tap: {
Feature: PressGesture,
},
focus: {
Feature: FocusGesture,
},
hover: {
Feature: HoverGesture,
},
};
const layout = {
layout: {
ProjectionNode: HTMLProjectionNode,
MeasureLayout,
},
};
/**
* @public
*/
const MotionConfigContext = react.createContext({
transformPagePoint: (p) => p,
isStatic: false,
reducedMotion: "never",
});
const MotionContext = react.createContext({});
const useIsomorphicLayoutEffect = isBrowser ? react.useLayoutEffect : react.useEffect;
const LazyContext = react.createContext({ strict: false });
function useVisualElement(Component, visualState, props, createVisualElement, ProjectionNodeConstructor) {
var _a, _b;
const { visualElement: parent } = react.useContext(MotionContext);
const lazyContext = react.useContext(LazyContext);
const presenceContext = react.useContext(PresenceContext);
const reducedMotionConfig = react.useContext(MotionConfigContext).reducedMotion;
const visualElementRef = react.useRef();
/**
* If we haven't preloaded a renderer, check to see if we have one lazy-loaded
*/
createVisualElement = createVisualElement || lazyContext.renderer;
if (!visualElementRef.current && createVisualElement) {
visualElementRef.current = createVisualElement(Component, {
visualState,
parent,
props,
presenceContext,
blockInitialAnimation: presenceContext
? presenceContext.initial === false
: false,
reducedMotionConfig,
});
}
const visualElement = visualElementRef.current;
/**
* Load Motion gesture and animation features. These are rendered as renderless
* components so each feature can optionally make use of React lifecycle methods.
*/
const initialLayoutGroupConfig = react.useContext(SwitchLayoutGroupContext);
if (visualElement &&
!visualElement.projection &&
ProjectionNodeConstructor &&
(visualElement.type === "html" || visualElement.type === "svg")) {
createProjectionNode(visualElementRef.current, props, ProjectionNodeConstructor, initialLayoutGroupConfig);
}
const isMounted = react.useRef(false);
react.useInsertionEffect(() => {
/**
* Check the component has already mounted before calling
* `update` unnecessarily. This ensures we skip the initial update.
*/
if (visualElement && isMounted.current) {
visualElement.update(props, presenceContext);
}
});
/**
* Cache this value as we want to know whether HandoffAppearAnimations
* was present on initial render - it will be deleted after this.
*/
const optimisedAppearId = props[optimizedAppearDataAttribute];
const wantsHandoff = react.useRef(Boolean(optimisedAppearId) &&
!((_a = window.MotionHandoffIsComplete) === null || _a === void 0 ? void 0 : _a.call(window, optimisedAppearId)) &&
((_b = window.MotionHasOptimisedAnimation) === null || _b === void 0 ? void 0 : _b.call(window, optimisedAppearId)));
useIsomorphicLayoutEffect(() => {
if (!visualElement)
return;
isMounted.current = true;
window.MotionIsMounted = true;
visualElement.updateFeatures();
microtask.render(visualElement.render);
/**
* Ideally this function would always run in a useEffect.
*
* However, if we have optimised appear animations to handoff from,
* it needs to happen synchronously to ensure there's no flash of
* incorrect styles in the event of a hydration error.
*
* So if we detect a situtation where optimised appear animations
* are running, we use useLayoutEffect to trigger animations.
*/
if (wantsHandoff.current && visualElement.animationState) {
visualElement.animationState.animateChanges();
}
});
react.useEffect(() => {
if (!visualElement)
return;
if (!wantsHandoff.current && visualElement.animationState) {
visualElement.animationState.animateChanges();
}
if (wantsHandoff.current) {
// This ensures all future calls to animateChanges() in this component will run in useEffect
queueMicrotask(() => {
var _a;
(_a = window.MotionHandoffMarkAsComplete) === null || _a === void 0 ? void 0 : _a.call(window, optimisedAppearId);
});
wantsHandoff.current = false;
}
});
return visualElement;
}
function createProjectionNode(visualElement, props, ProjectionNodeConstructor, initialPromotionConfig) {
const { layoutId, layout, drag, dragConstraints, layoutScroll, layoutRoot, } = props;
visualElement.projection = new ProjectionNodeConstructor(visualElement.latestValues, props["data-framer-portal-id"]
? undefined
: getClosestProjectingNode(visualElement.parent));
visualElement.projection.setOptions({
layoutId,
layout,
alwaysMeasureLayout: Boolean(drag) || (dragConstraints && isRefObject(dragConstraints)),
visualElement,
/**
* TODO: Update options in an effect. This could be tricky as it'll be too late
* to update by the time layout animations run.
* We also need to fix this safeToRemove by linking it up to the one returned by usePresence,
* ensuring it gets called if there's no potential layout animations.
*
*/
animationType: typeof layout === "string" ? layout : "both",
initialPromotionConfig,
layoutScroll,
layoutRoot,
});
}
function getClosestProjectingNode(visualElement) {
if (!visualElement)
return undefined;
return visualElement.options.allowProjection !== false
? visualElement.projection
: getClosestProjectingNode(visualElement.parent);
}
/**
* Creates a ref function that, when called, hydrates the provided
* external ref and VisualElement.
*/
function useMotionRef(visualState, visualElement, externalRef) {
return react.useCallback((instance) => {
instance && visualState.mount && visualState.mount(instance);
if (visualElement) {
if (instance) {
visualElement.mount(instance);
}
else {
visualElement.unmount();
}
}
if (externalRef) {
if (typeof externalRef === "function") {
externalRef(instance);
}
else if (isRefObject(externalRef)) {
externalRef.current = instance;
}
}
},
/**
* Only pass a new ref callback to React if we've received a visual element
* factory. Otherwise we'll be mounting/remounting every time externalRef
* or other dependencies change.
*/
[visualElement]);
}
function getCurrentTreeVariants(props, context) {
if (isControllingVariants(props)) {
const { initial, animate } = props;
return {
initial: initial === false || isVariantLabel(initial)
? initial
: undefined,
animate: isVariantLabel(animate) ? animate : undefined,
};
}
return props.inherit !== false ? context : {};
}
function useCreateMotionContext(props) {
const { initial, animate } = getCurrentTreeVariants(props, react.useContext(MotionContext));
return react.useMemo(() => ({ initial, animate }), [variantLabelsAsDependency(initial), variantLabelsAsDependency(animate)]);
}
function variantLabelsAsDependency(prop) {
return Array.isArray(prop) ? prop.join(" ") : prop;
}
function loadFeatures(features) {
for (const key in features) {
featureDefinitions[key] = {
...featureDefinitions[key],
...features[key],
};
}
}
const motionComponentSymbol = Symbol.for("motionComponentSymbol");
/**
* Create a `motion` component.
*
* This function accepts a Component argument, which can be either a string (ie "div"
* for `motion.div`), or an actual React component.
*
* Alongside this is a config option which provides a way of rendering the provided
* component "offline", or outside the React render cycle.
*/
function createRendererMotionComponent({ preloadedFeatures, createVisualElement, useRender, useVisualState, Component, }) {
preloadedFeatures && loadFeatures(preloadedFeatures);
function MotionComponent(props, externalRef) {
/**
* If we need to measure the element we load this functionality in a
* separate class component in order to gain access to getSnapshotBeforeUpdate.
*/
let MeasureLayout;
const configAndProps = {
...react.useContext(MotionConfigContext),
...props,
layoutId: useLayoutId(props),
};
const { isStatic } = configAndProps;
const context = useCreateMotionContext(props);
const visualState = useVisualState(props, isStatic);
if (!isStatic && isBrowser) {
useStrictMode(configAndProps, preloadedFeatures);
const layoutProjection = getProjectionFunctionality(configAndProps);
MeasureLayout = layoutProjection.MeasureLayout;
/**
* Create a VisualElement for this component. A VisualElement provides a common
* interface to renderer-specific APIs (ie DOM/Three.js etc) as well as
* providing a way of rendering to these APIs outside of the React render loop
* for more performant animations and interactions
*/
context.visualElement = useVisualElement(Component, visualState, configAndProps, createVisualElement, layoutProjection.ProjectionNode);
}
/**
* The mount order and hierarchy is specific to ensure our element ref
* is hydrated by the time features fire their effects.
*/
return (jsxRuntime.jsxs(MotionContext.Provider, { value: context, children: [MeasureLayout && context.visualElement ? (jsxRuntime.jsx(MeasureLayout, { visualElement: context.visualElement, ...configAndProps })) : null, useRender(Component, props, useMotionRef(visualState, context.visualElement, externalRef), visualState, isStatic, context.visualElement)] }));
}
const ForwardRefMotionComponent = react.forwardRef(MotionComponent);
ForwardRefMotionComponent[motionComponentSymbol] = Component;
return ForwardRefMotionComponent;
}
function useLayoutId({ layoutId }) {
const layoutGroupId = react.useContext(LayoutGroupContext).id;
return layoutGroupId && layoutId !== undefined
? layoutGroupId + "-" + layoutId
: layoutId;
}
function useStrictMode(configAndProps, preloadedFeatures) {
const isStrict = react.useContext(LazyContext).strict;
/**
* If we're in development mode, check to make sure we're not rendering a motion component
* as a child of LazyMotion, as this will break the file-size benefits of using it.
*/
if (process.env.NODE_ENV !== "production" &&
preloadedFeatures &&
isStrict) {
const strictMessage = "You have rendered a `motion` component within a `LazyMotion` component. This will break tree shaking. Import and render a `m` component instead.";
configAndProps.ignoreStrict
? warning(false, strictMessage)
: invariant(false, strictMessage);
}
}
function getProjectionFunctionality(props) {
const { drag, layout } = featureDefinitions;
if (!drag && !layout)
return {};
const combined = { ...drag, ...layout };
return {
MeasureLayout: (drag === null || drag === void 0 ? void 0 : drag.isEnabled(props)) || (layout === null || layout === void 0 ? void 0 : layout.isEnabled(props))
? combined.MeasureLayout
: undefined,
ProjectionNode: combined.ProjectionNode,
};
}
/**
* We keep these listed separately as we use the lowercase tag names as part
* of the runtime bundle to detect SVG components
*/
const lowercaseSVGElements = [
"animate",
"circle",
"defs",
"desc",
"ellipse",
"g",
"image",
"line",
"filter",
"marker",
"mask",
"metadata",
"path",
"pattern",
"polygon",
"polyline",
"rect",
"stop",
"switch",
"symbol",
"svg",
"text",
"tspan",
"use",
"view",
];
function isSVGComponent(Component) {
if (
/**
* If it's not a string, it's a custom React component. Currently we only support
* HTML custom React components.
*/
typeof Component !== "string" ||
/**
* If it contains a dash, the element is a custom HTML webcomponent.
*/
Component.includes("-")) {
return false;
}
else if (
/**
* If it's in our list of lowercase SVG tags, it's an SVG component
*/
lowercaseSVGElements.indexOf(Component) > -1 ||
/**
* If it contains a capital letter, it's an SVG component
*/
/[A-Z]/u.test(Component)) {
return true;
}
return false;
}
/**
* Creates a constant value over the lifecycle of a component.
*
* Even if `useMemo` is provided an empty array as its final argument, it doesn't offer
* a guarantee that it won't re-run for performance reasons later on. By using `useConstant`
* you can ensure that initialisers don't execute twice or more.
*/
function useConstant(init) {
const ref = react.useRef(null);
if (ref.current === null) {
ref.current = init();
}
return ref.current;
}
function makeState({ scrapeMotionValuesFromProps, createRenderState, onMount, }, props, context, presenceContext) {
const state = {
latestValues: makeLatestValues(props, context, presenceContext, scrapeMotionValuesFromProps),
renderState: createRenderState(),
};
if (onMount) {
state.mount = (instance) => onMount(props, instance, state);
}
return state;
}
const makeUseVisualState = (config) => (props, isStatic) => {
const context = react.useContext(MotionContext);
const presenceContext = react.useContext(PresenceContext);
const make = () => makeState(config, props, context, presenceContext);
return isStatic ? make() : useConstant(make);
};
function makeLatestValues(props, context, presenceContext, scrapeMotionValues) {
const values = {};
const motionValues = scrapeMotionValues(props, {});
for (const key in motionValues) {
values[key] = resolveMotionValue(motionValues[key]);
}
let { initial, animate } = props;
const isControllingVariants$1 = isControllingVariants(props);
const isVariantNode$1 = isVariantNode(props);
if (context &&
isVariantNode$1 &&
!isControllingVariants$1 &&
props.inherit !== false) {
if (initial === undefined)
initial = context.initial;
if (animate === undefined)
animate = context.animate;
}
let isInitialAnimationBlocked = presenceContext
? presenceContext.initial === false
: false;
isInitialAnimationBlocked = isInitialAnimationBlocked || initial === false;
const variantToSet = isInitialAnimationBlocked ? animate : initial;
if (variantToSet &&
typeof variantToSet !== "boolean" &&
!isAnimationControls(variantToSet)) {
const list = Array.isArray(variantToSet) ? variantToSet : [variantToSet];
for (let i = 0; i < list.length; i++) {
const resolved = resolveVariantFromProps(props, list[i]);
if (resolved) {
const { transitionEnd, transition, ...target } = resolved;
for (const key in target) {
let valueTarget = target[key];
if (Array.isArray(valueTarget)) {
/**
* Take final keyframe if the initial animation is blocked because
* we want to initialise at the end of that blocked animation.
*/
const index = isInitialAnimationBlocked
? valueTarget.length - 1
: 0;
valueTarget = valueTarget[index];
}
if (valueTarget !== null) {
values[key] = valueTarget;
}
}
for (const key in transitionEnd) {
values[key] = transitionEnd[key];
}
}
}
}
return values;
}
const createHtmlRenderState = () => ({
style: {},
transform: {},
transformOrigin: {},
vars: {},
});
const createSvgRenderState = () => ({
...createHtmlRenderState(),
attrs: {},
});
const svgMotionConfig = {
useVisualState: makeUseVisualState({
scrapeMotionValuesFromProps: scrapeMotionValuesFromProps,
createRenderState: createSvgRenderState,
onMount: (props, instance, { renderState, latestValues }) => {
frame.read(() => {
try {
renderState.dimensions =
typeof instance.getBBox ===
"function"
? instance.getBBox()
: instance.getBoundingClientRect();
}
catch (e) {
// Most likely trying to measure an unrendered element under Firefox
renderState.dimensions = {
x: 0,
y: 0,
width: 0,
height: 0,
};
}
});
frame.render(() => {
buildSVGAttrs(renderState, latestValues, isSVGTag(instance.tagName), props.transformTemplate);
renderSVG(instance, renderState);
});
},
}),
};
const htmlMotionConfig = {
useVisualState: makeUseVisualState({
scrapeMotionValuesFromProps: scrapeMotionValuesFromProps$1,
createRenderState: createHtmlRenderState,
}),
};
function copyRawValuesOnly(target, source, props) {
for (const key in source) {
if (!isMotionValue(source[key]) && !isForcedMotionValue(key, props)) {
target[key] = source[key];
}
}
}
function useInitialMotionValues({ transformTemplate }, visualState) {
return react.useMemo(() => {
const state = createHtmlRenderState();
buildHTMLStyles(state, visualState, transformTemplate);
return Object.assign({}, state.vars, state.style);
}, [visualState]);
}
function useStyle(props, visualState) {
const styleProp = props.style || {};
const style = {};
/**
* Copy non-Motion Values straight into style
*/
copyRawValuesOnly(style, styleProp, props);
Object.assign(style, useInitialMotionValues(props, visualState));
return style;
}
function useHTMLProps(props, visualState) {
// The `any` isn't ideal but it is the type of createElement props argument
const htmlProps = {};
const style = useStyle(props, visualState);
if (props.drag && props.dragListener !== false) {
// Disable the ghost element when a user drags
htmlProps.draggable = false;
// Disable text selection
style.userSelect =
style.WebkitUserSelect =
style.WebkitTouchCallout =
"none";
// Disable scrolling on the draggable direction
style.touchAction =
props.drag === true
? "none"
: `pan-${props.drag === "x" ? "y" : "x"}`;
}
if (props.tabIndex === undefined &&
(props.onTap || props.onTapStart || props.whileTap)) {
htmlProps.tabIndex = 0;
}
htmlProps.style = style;
return htmlProps;
}
/**
* A list of all valid MotionProps.
*
* @privateRemarks
* This doesn't throw if a `MotionProp` name is missing - it should.
*/
const validMotionProps = new Set([
"animate",
"exit",
"variants",
"initial",
"style",
"values",
"variants",
"transition",
"transformTemplate",
"custom",
"inherit",
"onBeforeLayoutMeasure",
"onAnimationStart",
"onAnimationComplete",
"onUpdate",
"onDragStart",
"onDrag",
"onDragEnd",
"onMeasureDragConstraints",
"onDirectionLock",
"onDragTransitionEnd",
"_dragX",
"_dragY",
"onHoverStart",
"onHoverEnd",
"onViewportEnter",
"onViewportLeave",
"globalTapTarget",
"ignoreStrict",
"viewport",
]);
/**
* Check whether a prop name is a valid `MotionProp` key.
*
* @param key - Name of the property to check
* @returns `true` is key is a valid `MotionProp`.
*
* @public
*/
function isValidMotionProp(key) {
return (key.startsWith("while") ||
(key.startsWith("drag") && key !== "draggable") ||
key.startsWith("layout") ||
key.startsWith("onTap") ||
key.startsWith("onPan") ||
key.startsWith("onLayout") ||
validMotionProps.has(key));
}
let shouldForward = (key) => !isValidMotionProp(key);
function loadExternalIsValidProp(isValidProp) {
if (!isValidProp)
return;
// Explicitly filter our events
shouldForward = (key) => key.startsWith("on") ? !isValidMotionProp(key) : isValidProp(key);
}
/**
* Emotion and Styled Components both allow users to pass through arbitrary props to their components
* to dynamically generate CSS. They both use the `@emotion/is-prop-valid` package to determine which
* of these should be passed to the underlying DOM node.
*
* However, when styling a Motion component `styled(motion.div)`, both packages pass through *all* props
* as it's seen as an arbitrary component rather than a DOM node. Motion only allows arbitrary props
* passed through the `custom` prop so it doesn't *need* the payload or computational overhead of
* `@emotion/is-prop-valid`, however to fix this problem we need to use it.
*
* By making it an optionalDependency we can offer this functionality only in the situations where it's
* actually required.
*/
try {
/**
* We attempt to import this package but require won't be defined in esm environments, in that case
* isPropValid will have to be provided via `MotionContext`. In a 6.0.0 this should probably be removed
* in favour of explicit injection.
*/
loadExternalIsValidProp(require("@emotion/is-prop-valid").default);
}
catch (_a) {
// We don't need to actually do anything here - the fallback is the existing `isPropValid`.
}
function filterProps(props, isDom, forwardMotionProps) {
const filteredProps = {};
for (const key in props) {
/**
* values is considered a valid prop by Emotion, so if it's present
* this will be rendered out to the DOM unless explicitly filtered.
*
* We check the type as it could be used with the `feColorMatrix`
* element, which we support.
*/
if (key === "values" && typeof props.values === "object")
continue;
if (shouldForward(key) ||
(forwardMotionProps === true && isValidMotionProp(key)) ||
(!isDom && !isValidMotionProp(key)) ||
// If trying to use native HTML drag events, forward drag listeners
(props["draggable"] &&
key.startsWith("onDrag"))) {
filteredProps[key] =
props[key];
}
}
return filteredProps;
}
function useSVGProps(props, visualState, _isStatic, Component) {
const visualProps = react.useMemo(() => {
const state = createSvgRenderState();
buildSVGAttrs(state, visualState, isSVGTag(Component), props.transformTemplate);
return {
...state.attrs,
style: { ...state.style },
};
}, [visualState]);
if (props.style) {
const rawStyles = {};
copyRawValuesOnly(rawStyles, props.style, props);
visualProps.style = { ...rawStyles, ...visualProps.style };
}
return visualProps;
}
function createUseRender(forwardMotionProps = false) {
const useRender = (Component, props, ref, { latestValues }, isStatic) => {
const useVisualProps = isSVGComponent(Component)
? useSVGProps
: useHTMLProps;
const visualProps = useVisualProps(props, latestValues, isStatic, Component);
const filteredProps = filterProps(props, typeof Component === "string", forwardMotionProps);
const elementProps = Component !== react.Fragment
? { ...filteredProps, ...visualProps, ref }
: {};
/**
* If component has been handed a motion value as its child,
* memoise its initial value and render that. Subsequent updates
* will be handled by the onChange handler
*/
const { children } = props;
const renderedChildren = react.useMemo(() => (isMotionValue(children) ? children.get() : children), [children]);
return react.createElement(Component, {
...elementProps,
children: renderedChildren,
});
};
return useRender;
}
function createMotionComponentFactory(preloadedFeatures, createVisualElement) {
return function createMotionComponent(Component, { forwardMotionProps } = { forwardMotionProps: false }) {
const baseConfig = isSVGComponent(Component)
? svgMotionConfig
: htmlMotionConfig;
const config = {
...baseConfig,
preloadedFeatures,
useRender: createUseRender(forwardMotionProps),
createVisualElement,
Component,
};
return createRendererMotionComponent(config);
};
}
const createDomVisualElement = (Component, options) => {
return isSVGComponent(Component)
? new SVGVisualElement(options)
: new HTMLVisualElement(options, {
allowProjection: Component !== react.Fragment,
});
};
const createMotionComponent = /*@__PURE__*/ createMotionComponentFactory({
...animations,
...gestureAnimations,
...drag,
...layout,
}, createDomVisualElement);
/**
* HTML components
*/
const MotionA = /*@__PURE__*/ createMotionComponent("a");
const MotionAbbr = /*@__PURE__*/ createMotionComponent("abbr");
const MotionAddress = /*@__PURE__*/ createMotionComponent("address");
const MotionArea = /*@__PURE__*/ createMotionComponent("area");
const MotionArticle = /*@__PURE__*/ createMotionComponent("article");
const MotionAside = /*@__PURE__*/ createMotionComponent("aside");
const MotionAudio = /*@__PURE__*/ createMotionComponent("audio");
const MotionB = /*@__PURE__*/ createMotionComponent("b");
const MotionBase = /*@__PURE__*/ createMotionComponent("base");
const MotionBdi = /*@__PURE__*/ createMotionComponent("bdi");
const MotionBdo = /*@__PURE__*/ createMotionComponent("bdo");
const MotionBig = /*@__PURE__*/ createMotionComponent("big");
const MotionBlockquote =
/*@__PURE__*/ createMotionComponent("blockquote");
const MotionBody = /*@__PURE__*/ createMotionComponent("body");
const MotionButton = /*@__PURE__*/ createMotionComponent("button");
const MotionCanvas = /*@__PURE__*/ createMotionComponent("canvas");
const MotionCaption = /*@__PURE__*/ createMotionComponent("caption");
const MotionCite = /*@__PURE__*/ createMotionComponent("cite");
const MotionCode = /*@__PURE__*/ createMotionComponent("code");
const MotionCol = /*@__PURE__*/ createMotionComponent("col");
const MotionColgroup = /*@__PURE__*/ createMotionComponent("colgroup");
const MotionData = /*@__PURE__*/ createMotionComponent("data");
const MotionDatalist = /*@__PURE__*/ createMotionComponent("datalist");
const MotionDd = /*@__PURE__*/ createMotionComponent("dd");
const MotionDel = /*@__PURE__*/ createMotionComponent("del");
const MotionDetails = /*@__PURE__*/ createMotionComponent("details");
const MotionDfn = /*@__PURE__*/ createMotionComponent("dfn");
const MotionDialog = /*@__PURE__*/ createMotionComponent("dialog");
const MotionDiv = /*@__PURE__*/ createMotionComponent("div");
const MotionDl = /*@__PURE__*/ createMotionComponent("dl");
const MotionDt = /*@__PURE__*/ createMotionComponent("dt");
const MotionEm = /*@__PURE__*/ createMotionComponent("em");
const MotionEmbed = /*@__PURE__*/ createMotionComponent("embed");
const MotionFieldset = /*@__PURE__*/ createMotionComponent("fieldset");
const MotionFigcaption =
/*@__PURE__*/ createMotionComponent("figcaption");
const MotionFigure = /*@__PURE__*/ createMotionComponent("figure");
const MotionFooter = /*@__PURE__*/ createMotionComponent("footer");
const MotionForm = /*@__PURE__*/ createMotionComponent("form");
const MotionH1 = /*@__PURE__*/ createMotionComponent("h1");
const MotionH2 = /*@__PURE__*/ createMotionComponent("h2");
const MotionH3 = /*@__PURE__*/ createMotionComponent("h3");
const MotionH4 = /*@__PURE__*/ createMotionComponent("h4");
const MotionH5 = /*@__PURE__*/ createMotionComponent("h5");
const MotionH6 = /*@__PURE__*/ createMotionComponent("h6");
const MotionHead = /*@__PURE__*/ createMotionComponent("head");
const MotionHeader = /*@__PURE__*/ createMotionComponent("header");
const MotionHgroup = /*@__PURE__*/ createMotionComponent("hgroup");
const MotionHr = /*@__PURE__*/ createMotionComponent("hr");
const MotionHtml = /*@__PURE__*/ createMotionComponent("html");
const MotionI = /*@__PURE__*/ createMotionComponent("i");
const MotionIframe = /*@__PURE__*/ createMotionComponent("iframe");
const MotionImg = /*@__PURE__*/ createMotionComponent("img");
const MotionInput = /*@__PURE__*/ createMotionComponent("input");
const MotionIns = /*@__PURE__*/ createMotionComponent("ins");
const MotionKbd = /*@__PURE__*/ createMotionComponent("kbd");
const MotionKeygen = /*@__PURE__*/ createMotionComponent("keygen");
const MotionLabel = /*@__PURE__*/ createMotionComponent("label");
const MotionLegend = /*@__PURE__*/ createMotionComponent("legend");
const MotionLi = /*@__PURE__*/ createMotionComponent("li");
const MotionLink = /*@__PURE__*/ createMotionComponent("link");
const MotionMain = /*@__PURE__*/ createMotionComponent("main");
const MotionMap = /*@__PURE__*/ createMotionComponent("map");
const MotionMark = /*@__PURE__*/ createMotionComponent("mark");
const MotionMenu = /*@__PURE__*/ createMotionComponent("menu");
const MotionMenuitem = /*@__PURE__*/ createMotionComponent("menuitem");
const MotionMeter = /*@__PURE__*/ createMotionComponent("meter");
const MotionNav = /*@__PURE__*/ createMotionComponent("nav");
const MotionObject = /*@__PURE__*/ createMotionComponent("object");
const MotionOl = /*@__PURE__*/ createMotionComponent("ol");
const MotionOptgroup = /*@__PURE__*/ createMotionComponent("optgroup");
const MotionOption = /*@__PURE__*/ createMotionComponent("option");
const MotionOutput = /*@__PURE__*/ createMotionComponent("output");
const MotionP = /*@__PURE__*/ createMotionComponent("p");
const MotionParam = /*@__PURE__*/ createMotionComponent("param");
const MotionPicture = /*@__PURE__*/ createMotionComponent("picture");
const MotionPre = /*@__PURE__*/ createMotionComponent("pre");
const MotionProgress = /*@__PURE__*/ createMotionComponent("progress");
const MotionQ = /*@__PURE__*/ createMotionComponent("q");
const MotionRp = /*@__PURE__*/ createMotionComponent("rp");
const MotionRt = /*@__PURE__*/ createMotionComponent("rt");
const MotionRuby = /*@__PURE__*/ createMotionComponent("ruby");
const MotionS = /*@__PURE__*/ createMotionComponent("s");
const MotionSamp = /*@__PURE__*/ createMotionComponent("samp");
const MotionScript = /*@__PURE__*/ createMotionComponent("script");
const MotionSection = /*@__PURE__*/ createMotionComponent("section");
const MotionSelect = /*@__PURE__*/ createMotionComponent("select");
const MotionSmall = /*@__PURE__*/ createMotionComponent("small");
const MotionSource = /*@__PURE__*/ createMotionComponent("source");
const MotionSpan = /*@__PURE__*/ createMotionComponent("span");
const MotionStrong = /*@__PURE__*/ createMotionComponent("strong");
const MotionStyle = /*@__PURE__*/ createMotionComponent("style");
const MotionSub = /*@__PURE__*/ createMotionComponent("sub");
const MotionSummary = /*@__PURE__*/ createMotionComponent("summary");
const MotionSup = /*@__PURE__*/ createMotionComponent("sup");
const MotionTable = /*@__PURE__*/ createMotionComponent("table");
const MotionTbody = /*@__PURE__*/ createMotionComponent("tbody");
const MotionTd = /*@__PURE__*/ createMotionComponent("td");
const MotionTextarea = /*@__PURE__*/ createMotionComponent("textarea");
const MotionTfoot = /*@__PURE__*/ createMotionComponent("tfoot");
const MotionTh = /*@__PURE__*/ createMotionComponent("th");
const MotionThead = /*@__PURE__*/ createMotionComponent("thead");
const MotionTime = /*@__PURE__*/ createMotionComponent("time");
const MotionTitle = /*@__PURE__*/ createMotionComponent("title");
const MotionTr = /*@__PURE__*/ createMotionComponent("tr");
const MotionTrack = /*@__PURE__*/ createMotionComponent("track");
const MotionU = /*@__PURE__*/ createMotionComponent("u");
const MotionUl = /*@__PURE__*/ createMotionComponent("ul");
const MotionVideo = /*@__PURE__*/ createMotionComponent("video");
const MotionWbr = /*@__PURE__*/ createMotionComponent("wbr");
const MotionWebview = /*@__PURE__*/ createMotionComponent("webview");
/**
* SVG components
*/
const MotionAnimate = /*@__PURE__*/ createMotionComponent("animate");
const MotionCircle = /*@__PURE__*/ createMotionComponent("circle");
const MotionDefs = /*@__PURE__*/ createMotionComponent("defs");
const MotionDesc = /*@__PURE__*/ createMotionComponent("desc");
const MotionEllipse = /*@__PURE__*/ createMotionComponent("ellipse");
const MotionG = /*@__PURE__*/ createMotionComponent("g");
const MotionImage = /*@__PURE__*/ createMotionComponent("image");
const MotionLine = /*@__PURE__*/ createMotionComponent("line");
const MotionFilter = /*@__PURE__*/ createMotionComponent("filter");
const MotionMarker = /*@__PURE__*/ createMotionComponent("marker");
const MotionMask = /*@__PURE__*/ createMotionComponent("mask");
const MotionMetadata = /*@__PURE__*/ createMotionComponent("metadata");
const MotionPath = /*@__PURE__*/ createMotionComponent("path");
const MotionPattern = /*@__PURE__*/ createMotionComponent("pattern");
const MotionPolygon = /*@__PURE__*/ createMotionComponent("polygon");
const MotionPolyline = /*@__PURE__*/ createMotionComponent("polyline");
const MotionRect = /*@__PURE__*/ createMotionComponent("rect");
const MotionStop = /*@__PURE__*/ createMotionComponent("stop");
const MotionSvg = /*@__PURE__*/ createMotionComponent("svg");
const MotionSymbol = /*@__PURE__*/ createMotionComponent("symbol");
const MotionText = /*@__PURE__*/ createMotionComponent("text");
const MotionTspan = /*@__PURE__*/ createMotionComponent("tspan");
const MotionUse = /*@__PURE__*/ createMotionComponent("use");
const MotionView = /*@__PURE__*/ createMotionComponent("view");
const MotionClipPath = /*@__PURE__*/ createMotionComponent("clipPath");
const MotionFeBlend = /*@__PURE__*/ createMotionComponent("feBlend");
const MotionFeColorMatrix =
/*@__PURE__*/ createMotionComponent("feColorMatrix");
const MotionFeComponentTransfer = /*@__PURE__*/ createMotionComponent("feComponentTransfer");
const MotionFeComposite =
/*@__PURE__*/ createMotionComponent("feComposite");
const MotionFeConvolveMatrix =
/*@__PURE__*/ createMotionComponent("feConvolveMatrix");
const MotionFeDiffuseLighting =
/*@__PURE__*/ createMotionComponent("feDiffuseLighting");
const MotionFeDisplacementMap =
/*@__PURE__*/ createMotionComponent("feDisplacementMap");
const MotionFeDistantLight =
/*@__PURE__*/ createMotionComponent("feDistantLight");
const MotionFeDropShadow =
/*@__PURE__*/ createMotionComponent("feDropShadow");
const MotionFeFlood = /*@__PURE__*/ createMotionComponent("feFlood");
const MotionFeFuncA = /*@__PURE__*/ createMotionComponent("feFuncA");
const MotionFeFuncB = /*@__PURE__*/ createMotionComponent("feFuncB");
const MotionFeFuncG = /*@__PURE__*/ createMotionComponent("feFuncG");
const MotionFeFuncR = /*@__PURE__*/ createMotionComponent("feFuncR");
const MotionFeGaussianBlur =
/*@__PURE__*/ createMotionComponent("feGaussianBlur");
const MotionFeImage = /*@__PURE__*/ createMotionComponent("feImage");
const MotionFeMerge = /*@__PURE__*/ createMotionComponent("feMerge");
const MotionFeMergeNode =
/*@__PURE__*/ createMotionComponent("feMergeNode");
const MotionFeMorphology =
/*@__PURE__*/ createMotionComponent("feMorphology");
const MotionFeOffset = /*@__PURE__*/ createMotionComponent("feOffset");
const MotionFePointLight =
/*@__PURE__*/ createMotionComponent("fePointLight");
const MotionFeSpecularLighting =
/*@__PURE__*/ createMotionComponent("feSpecularLighting");
const MotionFeSpotLight =
/*@__PURE__*/ createMotionComponent("feSpotLight");
const MotionFeTile = /*@__PURE__*/ createMotionComponent("feTile");
const MotionFeTurbulence =
/*@__PURE__*/ createMotionComponent("feTurbulence");
const MotionForeignObject =
/*@__PURE__*/ createMotionComponent("foreignObject");
const MotionLinearGradient =
/*@__PURE__*/ createMotionComponent("linearGradient");
const MotionRadialGradient =
/*@__PURE__*/ createMotionComponent("radialGradient");
const MotionTextPath = /*@__PURE__*/ createMotionComponent("textPath");
exports.a = MotionA;
exports.abbr = MotionAbbr;
exports.address = MotionAddress;
exports.animate = MotionAnimate;
exports.area = MotionArea;
exports.article = MotionArticle;
exports.aside = MotionAside;
exports.audio = MotionAudio;
exports.b = MotionB;
exports.base = MotionBase;
exports.bdi = MotionBdi;
exports.bdo = MotionBdo;
exports.big = MotionBig;
exports.blockquote = MotionBlockquote;
exports.body = MotionBody;
exports.button = MotionButton;
exports.canvas = MotionCanvas;
exports.caption = MotionCaption;
exports.circle = MotionCircle;
exports.cite = MotionCite;
exports.clipPath = MotionClipPath;
exports.code = MotionCode;
exports.col = MotionCol;
exports.colgroup = MotionColgroup;
exports.create = createMotionComponent;
exports.data = MotionData;
exports.datalist = MotionDatalist;
exports.dd = MotionDd;
exports.defs = MotionDefs;
exports.del = MotionDel;
exports.desc = MotionDesc;
exports.details = MotionDetails;
exports.dfn = MotionDfn;
exports.dialog = MotionDialog;
exports.div = MotionDiv;
exports.dl = MotionDl;
exports.dt = MotionDt;
exports.ellipse = MotionEllipse;
exports.em = MotionEm;
exports.embed = MotionEmbed;
exports.feBlend = MotionFeBlend;
exports.feColorMatrix = MotionFeColorMatrix;
exports.feComponentTransfer = MotionFeComponentTransfer;
exports.feComposite = MotionFeComposite;
exports.feConvolveMatrix = MotionFeConvolveMatrix;
exports.feDiffuseLighting = MotionFeDiffuseLighting;
exports.feDisplacementMap = MotionFeDisplacementMap;
exports.feDistantLight = MotionFeDistantLight;
exports.feDropShadow = MotionFeDropShadow;
exports.feFlood = MotionFeFlood;
exports.feFuncA = MotionFeFuncA;
exports.feFuncB = MotionFeFuncB;
exports.feFuncG = MotionFeFuncG;
exports.feFuncR = MotionFeFuncR;
exports.feGaussianBlur = MotionFeGaussianBlur;
exports.feImage = MotionFeImage;
exports.feMerge = MotionFeMerge;
exports.feMergeNode = MotionFeMergeNode;
exports.feMorphology = MotionFeMorphology;
exports.feOffset = MotionFeOffset;
exports.fePointLight = MotionFePointLight;
exports.feSpecularLighting = MotionFeSpecularLighting;
exports.feSpotLight = MotionFeSpotLight;
exports.feTile = MotionFeTile;
exports.feTurbulence = MotionFeTurbulence;
exports.fieldset = MotionFieldset;
exports.figcaption = MotionFigcaption;
exports.figure = MotionFigure;
exports.filter = MotionFilter;
exports.footer = MotionFooter;
exports.foreignObject = MotionForeignObject;
exports.form = MotionForm;
exports.g = MotionG;
exports.h1 = MotionH1;
exports.h2 = MotionH2;
exports.h3 = MotionH3;
exports.h4 = MotionH4;
exports.h5 = MotionH5;
exports.h6 = MotionH6;
exports.head = MotionHead;
exports.header = MotionHeader;
exports.hgroup = MotionHgroup;
exports.hr = MotionHr;
exports.html = MotionHtml;
exports.i = MotionI;
exports.iframe = MotionIframe;
exports.image = MotionImage;
exports.img = MotionImg;
exports.input = MotionInput;
exports.ins = MotionIns;
exports.kbd = MotionKbd;
exports.keygen = MotionKeygen;
exports.label = MotionLabel;
exports.legend = MotionLegend;
exports.li = MotionLi;
exports.line = MotionLine;
exports.linearGradient = MotionLinearGradient;
exports.link = MotionLink;
exports.main = MotionMain;
exports.map = MotionMap;
exports.mark = MotionMark;
exports.marker = MotionMarker;
exports.mask = MotionMask;
exports.menu = MotionMenu;
exports.menuitem = MotionMenuitem;
exports.metadata = MotionMetadata;
exports.meter = MotionMeter;
exports.nav = MotionNav;
exports.object = MotionObject;
exports.ol = MotionOl;
exports.optgroup = MotionOptgroup;
exports.option = MotionOption;
exports.output = MotionOutput;
exports.p = MotionP;
exports.param = MotionParam;
exports.path = MotionPath;
exports.pattern = MotionPattern;
exports.picture = MotionPicture;
exports.polygon = MotionPolygon;
exports.polyline = MotionPolyline;
exports.pre = MotionPre;
exports.progress = MotionProgress;
exports.q = MotionQ;
exports.radialGradient = MotionRadialGradient;
exports.rect = MotionRect;
exports.rp = MotionRp;
exports.rt = MotionRt;
exports.ruby = MotionRuby;
exports.s = MotionS;
exports.samp = MotionSamp;
exports.script = MotionScript;
exports.section = MotionSection;
exports.select = MotionSelect;
exports.small = MotionSmall;
exports.source = MotionSource;
exports.span = MotionSpan;
exports.stop = MotionStop;
exports.strong = MotionStrong;
exports.style = MotionStyle;
exports.sub = MotionSub;
exports.summary = MotionSummary;
exports.sup = MotionSup;
exports.svg = MotionSvg;
exports.symbol = MotionSymbol;
exports.table = MotionTable;
exports.tbody = MotionTbody;
exports.td = MotionTd;
exports.text = MotionText;
exports.textPath = MotionTextPath;
exports.textarea = MotionTextarea;
exports.tfoot = MotionTfoot;
exports.th = MotionTh;
exports.thead = MotionThead;
exports.time = MotionTime;
exports.title = MotionTitle;
exports.tr = MotionTr;
exports.track = MotionTrack;
exports.tspan = MotionTspan;
exports.u = MotionU;
exports.ul = MotionUl;
exports.use = MotionUse;
exports.video = MotionVideo;
exports.view = MotionView;
exports.wbr = MotionWbr;
exports.webview = MotionWebview;