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/**
* @vue/reactivity v3.5.1
* (c) 2018-present Yuxi (Evan) You and Vue contributors
* @license MIT
**/
var VueReactivity = (function (exports) {
'use strict';
/*! #__NO_SIDE_EFFECTS__ */
// @__NO_SIDE_EFFECTS__
function makeMap(str, expectsLowerCase) {
const set = new Set(str.split(","));
return (val) => set.has(val);
}
const EMPTY_OBJ = Object.freeze({}) ;
const NOOP = () => {
};
const extend = Object.assign;
const remove = (arr, el) => {
const i = arr.indexOf(el);
if (i > -1) {
arr.splice(i, 1);
}
};
const hasOwnProperty$1 = Object.prototype.hasOwnProperty;
const hasOwn = (val, key) => hasOwnProperty$1.call(val, key);
const isArray = Array.isArray;
const isMap = (val) => toTypeString(val) === "[object Map]";
const isSet = (val) => toTypeString(val) === "[object Set]";
const isFunction = (val) => typeof val === "function";
const isString = (val) => typeof val === "string";
const isSymbol = (val) => typeof val === "symbol";
const isObject = (val) => val !== null && typeof val === "object";
const objectToString = Object.prototype.toString;
const toTypeString = (value) => objectToString.call(value);
const toRawType = (value) => {
return toTypeString(value).slice(8, -1);
};
const isPlainObject = (val) => toTypeString(val) === "[object Object]";
const isIntegerKey = (key) => isString(key) && key !== "NaN" && key[0] !== "-" && "" + parseInt(key, 10) === key;
const cacheStringFunction = (fn) => {
const cache = /* @__PURE__ */ Object.create(null);
return (str) => {
const hit = cache[str];
return hit || (cache[str] = fn(str));
};
};
const capitalize = cacheStringFunction((str) => {
return str.charAt(0).toUpperCase() + str.slice(1);
});
const hasChanged = (value, oldValue) => !Object.is(value, oldValue);
const def = (obj, key, value, writable = false) => {
Object.defineProperty(obj, key, {
configurable: true,
enumerable: false,
writable,
value
});
};
function warn(msg, ...args) {
console.warn(`[Vue warn] ${msg}`, ...args);
}
let activeEffectScope;
class EffectScope {
constructor(detached = false) {
this.detached = detached;
/**
* @internal
*/
this._active = true;
/**
* @internal
*/
this.effects = [];
/**
* @internal
*/
this.cleanups = [];
this._isPaused = false;
this.parent = activeEffectScope;
if (!detached && activeEffectScope) {
this.index = (activeEffectScope.scopes || (activeEffectScope.scopes = [])).push(
this
) - 1;
}
}
get active() {
return this._active;
}
pause() {
if (this._active) {
this._isPaused = true;
let i, l;
if (this.scopes) {
for (i = 0, l = this.scopes.length; i < l; i++) {
this.scopes[i].pause();
}
}
for (i = 0, l = this.effects.length; i < l; i++) {
this.effects[i].pause();
}
}
}
/**
* Resumes the effect scope, including all child scopes and effects.
*/
resume() {
if (this._active) {
if (this._isPaused) {
this._isPaused = false;
let i, l;
if (this.scopes) {
for (i = 0, l = this.scopes.length; i < l; i++) {
this.scopes[i].resume();
}
}
for (i = 0, l = this.effects.length; i < l; i++) {
this.effects[i].resume();
}
}
}
}
run(fn) {
if (this._active) {
const currentEffectScope = activeEffectScope;
try {
activeEffectScope = this;
return fn();
} finally {
activeEffectScope = currentEffectScope;
}
} else {
warn(`cannot run an inactive effect scope.`);
}
}
/**
* This should only be called on non-detached scopes
* @internal
*/
on() {
activeEffectScope = this;
}
/**
* This should only be called on non-detached scopes
* @internal
*/
off() {
activeEffectScope = this.parent;
}
stop(fromParent) {
if (this._active) {
let i, l;
for (i = 0, l = this.effects.length; i < l; i++) {
this.effects[i].stop();
}
for (i = 0, l = this.cleanups.length; i < l; i++) {
this.cleanups[i]();
}
if (this.scopes) {
for (i = 0, l = this.scopes.length; i < l; i++) {
this.scopes[i].stop(true);
}
}
if (!this.detached && this.parent && !fromParent) {
const last = this.parent.scopes.pop();
if (last && last !== this) {
this.parent.scopes[this.index] = last;
last.index = this.index;
}
}
this.parent = void 0;
this._active = false;
}
}
}
function effectScope(detached) {
return new EffectScope(detached);
}
function getCurrentScope() {
return activeEffectScope;
}
function onScopeDispose(fn, failSilently = false) {
if (activeEffectScope) {
activeEffectScope.cleanups.push(fn);
} else if (!failSilently) {
warn(
`onScopeDispose() is called when there is no active effect scope to be associated with.`
);
}
}
let activeSub;
const EffectFlags = {
"ACTIVE": 1,
"1": "ACTIVE",
"RUNNING": 2,
"2": "RUNNING",
"TRACKING": 4,
"4": "TRACKING",
"NOTIFIED": 8,
"8": "NOTIFIED",
"DIRTY": 16,
"16": "DIRTY",
"ALLOW_RECURSE": 32,
"32": "ALLOW_RECURSE",
"PAUSED": 64,
"64": "PAUSED"
};
const pausedQueueEffects = /* @__PURE__ */ new WeakSet();
class ReactiveEffect {
constructor(fn) {
this.fn = fn;
/**
* @internal
*/
this.deps = void 0;
/**
* @internal
*/
this.depsTail = void 0;
/**
* @internal
*/
this.flags = 1 | 4;
/**
* @internal
*/
this.nextEffect = void 0;
/**
* @internal
*/
this.cleanup = void 0;
this.scheduler = void 0;
if (activeEffectScope && activeEffectScope.active) {
activeEffectScope.effects.push(this);
}
}
pause() {
this.flags |= 64;
}
resume() {
if (this.flags & 64) {
this.flags &= ~64;
if (pausedQueueEffects.has(this)) {
pausedQueueEffects.delete(this);
this.trigger();
}
}
}
/**
* @internal
*/
notify() {
if (this.flags & 2 && !(this.flags & 32)) {
return;
}
if (!(this.flags & 8)) {
this.flags |= 8;
this.nextEffect = batchedEffect;
batchedEffect = this;
}
}
run() {
if (!(this.flags & 1)) {
return this.fn();
}
this.flags |= 2;
cleanupEffect(this);
prepareDeps(this);
const prevEffect = activeSub;
const prevShouldTrack = shouldTrack;
activeSub = this;
shouldTrack = true;
try {
return this.fn();
} finally {
if (activeSub !== this) {
warn(
"Active effect was not restored correctly - this is likely a Vue internal bug."
);
}
cleanupDeps(this);
activeSub = prevEffect;
shouldTrack = prevShouldTrack;
this.flags &= ~2;
}
}
stop() {
if (this.flags & 1) {
for (let link = this.deps; link; link = link.nextDep) {
removeSub(link);
}
this.deps = this.depsTail = void 0;
cleanupEffect(this);
this.onStop && this.onStop();
this.flags &= ~1;
}
}
trigger() {
if (this.flags & 64) {
pausedQueueEffects.add(this);
} else if (this.scheduler) {
this.scheduler();
} else {
this.runIfDirty();
}
}
/**
* @internal
*/
runIfDirty() {
if (isDirty(this)) {
this.run();
}
}
get dirty() {
return isDirty(this);
}
}
let batchDepth = 0;
let batchedEffect;
function startBatch() {
batchDepth++;
}
function endBatch() {
if (--batchDepth > 0) {
return;
}
let error;
while (batchedEffect) {
let e = batchedEffect;
batchedEffect = void 0;
while (e) {
const next = e.nextEffect;
e.nextEffect = void 0;
e.flags &= ~8;
if (e.flags & 1) {
try {
e.trigger();
} catch (err) {
if (!error) error = err;
}
}
e = next;
}
}
if (error) throw error;
}
function prepareDeps(sub) {
for (let link = sub.deps; link; link = link.nextDep) {
link.version = -1;
link.prevActiveLink = link.dep.activeLink;
link.dep.activeLink = link;
}
}
function cleanupDeps(sub) {
let head;
let tail = sub.depsTail;
for (let link = tail; link; link = link.prevDep) {
if (link.version === -1) {
if (link === tail) tail = link.prevDep;
removeSub(link);
removeDep(link);
} else {
head = link;
}
link.dep.activeLink = link.prevActiveLink;
link.prevActiveLink = void 0;
}
sub.deps = head;
sub.depsTail = tail;
}
function isDirty(sub) {
for (let link = sub.deps; link; link = link.nextDep) {
if (link.dep.version !== link.version || link.dep.computed && refreshComputed(link.dep.computed) === false || link.dep.version !== link.version) {
return true;
}
}
if (sub._dirty) {
return true;
}
return false;
}
function refreshComputed(computed) {
if (computed.flags & 2) {
return false;
}
if (computed.flags & 4 && !(computed.flags & 16)) {
return;
}
computed.flags &= ~16;
if (computed.globalVersion === globalVersion) {
return;
}
computed.globalVersion = globalVersion;
const dep = computed.dep;
computed.flags |= 2;
if (dep.version > 0 && !computed.isSSR && !isDirty(computed)) {
computed.flags &= ~2;
return;
}
const prevSub = activeSub;
const prevShouldTrack = shouldTrack;
activeSub = computed;
shouldTrack = true;
try {
prepareDeps(computed);
const value = computed.fn();
if (dep.version === 0 || hasChanged(value, computed._value)) {
computed._value = value;
dep.version++;
}
} catch (err) {
dep.version++;
throw err;
} finally {
activeSub = prevSub;
shouldTrack = prevShouldTrack;
cleanupDeps(computed);
computed.flags &= ~2;
}
}
function removeSub(link) {
const { dep, prevSub, nextSub } = link;
if (prevSub) {
prevSub.nextSub = nextSub;
link.prevSub = void 0;
}
if (nextSub) {
nextSub.prevSub = prevSub;
link.nextSub = void 0;
}
if (dep.subs === link) {
dep.subs = prevSub;
}
if (!dep.subs && dep.computed) {
dep.computed.flags &= ~4;
for (let l = dep.computed.deps; l; l = l.nextDep) {
removeSub(l);
}
}
}
function removeDep(link) {
const { prevDep, nextDep } = link;
if (prevDep) {
prevDep.nextDep = nextDep;
link.prevDep = void 0;
}
if (nextDep) {
nextDep.prevDep = prevDep;
link.nextDep = void 0;
}
}
function effect(fn, options) {
if (fn.effect instanceof ReactiveEffect) {
fn = fn.effect.fn;
}
const e = new ReactiveEffect(fn);
if (options) {
extend(e, options);
}
try {
e.run();
} catch (err) {
e.stop();
throw err;
}
const runner = e.run.bind(e);
runner.effect = e;
return runner;
}
function stop(runner) {
runner.effect.stop();
}
let shouldTrack = true;
const trackStack = [];
function pauseTracking() {
trackStack.push(shouldTrack);
shouldTrack = false;
}
function enableTracking() {
trackStack.push(shouldTrack);
shouldTrack = true;
}
function resetTracking() {
const last = trackStack.pop();
shouldTrack = last === void 0 ? true : last;
}
function onEffectCleanup(fn, failSilently = false) {
if (activeSub instanceof ReactiveEffect) {
activeSub.cleanup = fn;
} else if (!failSilently) {
warn(
`onEffectCleanup() was called when there was no active effect to associate with.`
);
}
}
function cleanupEffect(e) {
const { cleanup } = e;
e.cleanup = void 0;
if (cleanup) {
const prevSub = activeSub;
activeSub = void 0;
try {
cleanup();
} finally {
activeSub = prevSub;
}
}
}
let globalVersion = 0;
class Dep {
constructor(computed) {
this.computed = computed;
this.version = 0;
/**
* Link between this dep and the current active effect
*/
this.activeLink = void 0;
/**
* Doubly linked list representing the subscribing effects (tail)
*/
this.subs = void 0;
{
this.subsHead = void 0;
}
}
track(debugInfo) {
if (!activeSub || !shouldTrack) {
return;
}
let link = this.activeLink;
if (link === void 0 || link.sub !== activeSub) {
link = this.activeLink = {
dep: this,
sub: activeSub,
version: this.version,
nextDep: void 0,
prevDep: void 0,
nextSub: void 0,
prevSub: void 0,
prevActiveLink: void 0
};
if (!activeSub.deps) {
activeSub.deps = activeSub.depsTail = link;
} else {
link.prevDep = activeSub.depsTail;
activeSub.depsTail.nextDep = link;
activeSub.depsTail = link;
}
if (activeSub.flags & 4) {
addSub(link);
}
} else if (link.version === -1) {
link.version = this.version;
if (link.nextDep) {
const next = link.nextDep;
next.prevDep = link.prevDep;
if (link.prevDep) {
link.prevDep.nextDep = next;
}
link.prevDep = activeSub.depsTail;
link.nextDep = void 0;
activeSub.depsTail.nextDep = link;
activeSub.depsTail = link;
if (activeSub.deps === link) {
activeSub.deps = next;
}
}
}
if (activeSub.onTrack) {
activeSub.onTrack(
extend(
{
effect: activeSub
},
debugInfo
)
);
}
return link;
}
trigger(debugInfo) {
this.version++;
globalVersion++;
this.notify(debugInfo);
}
notify(debugInfo) {
startBatch();
try {
if (true) {
for (let head = this.subsHead; head; head = head.nextSub) {
if (head.sub.onTrigger && !(head.sub.flags & 8)) {
head.sub.onTrigger(
extend(
{
effect: head.sub
},
debugInfo
)
);
}
}
}
for (let link = this.subs; link; link = link.prevSub) {
link.sub.notify();
}
} finally {
endBatch();
}
}
}
function addSub(link) {
const computed = link.dep.computed;
if (computed && !link.dep.subs) {
computed.flags |= 4 | 16;
for (let l = computed.deps; l; l = l.nextDep) {
addSub(l);
}
}
const currentTail = link.dep.subs;
if (currentTail !== link) {
link.prevSub = currentTail;
if (currentTail) currentTail.nextSub = link;
}
if (link.dep.subsHead === void 0) {
link.dep.subsHead = link;
}
link.dep.subs = link;
}
const targetMap = /* @__PURE__ */ new WeakMap();
const ITERATE_KEY = Symbol(
"Object iterate"
);
const MAP_KEY_ITERATE_KEY = Symbol(
"Map keys iterate"
);
const ARRAY_ITERATE_KEY = Symbol(
"Array iterate"
);
function track(target, type, key) {
if (shouldTrack && activeSub) {
let depsMap = targetMap.get(target);
if (!depsMap) {
targetMap.set(target, depsMap = /* @__PURE__ */ new Map());
}
let dep = depsMap.get(key);
if (!dep) {
depsMap.set(key, dep = new Dep());
}
{
dep.track({
target,
type,
key
});
}
}
}
function trigger(target, type, key, newValue, oldValue, oldTarget) {
const depsMap = targetMap.get(target);
if (!depsMap) {
globalVersion++;
return;
}
let deps = [];
if (type === "clear") {
deps = [...depsMap.values()];
} else {
const targetIsArray = isArray(target);
const isArrayIndex = targetIsArray && isIntegerKey(key);
if (targetIsArray && key === "length") {
const newLength = Number(newValue);
depsMap.forEach((dep, key2) => {
if (key2 === "length" || key2 === ARRAY_ITERATE_KEY || !isSymbol(key2) && key2 >= newLength) {
deps.push(dep);
}
});
} else {
const push = (dep) => dep && deps.push(dep);
if (key !== void 0) {
push(depsMap.get(key));
}
if (isArrayIndex) {
push(depsMap.get(ARRAY_ITERATE_KEY));
}
switch (type) {
case "add":
if (!targetIsArray) {
push(depsMap.get(ITERATE_KEY));
if (isMap(target)) {
push(depsMap.get(MAP_KEY_ITERATE_KEY));
}
} else if (isArrayIndex) {
push(depsMap.get("length"));
}
break;
case "delete":
if (!targetIsArray) {
push(depsMap.get(ITERATE_KEY));
if (isMap(target)) {
push(depsMap.get(MAP_KEY_ITERATE_KEY));
}
}
break;
case "set":
if (isMap(target)) {
push(depsMap.get(ITERATE_KEY));
}
break;
}
}
}
startBatch();
for (const dep of deps) {
{
dep.trigger({
target,
type,
key,
newValue,
oldValue,
oldTarget
});
}
}
endBatch();
}
function getDepFromReactive(object, key) {
var _a;
return (_a = targetMap.get(object)) == null ? void 0 : _a.get(key);
}
function reactiveReadArray(array) {
const raw = toRaw(array);
if (raw === array) return raw;
track(raw, "iterate", ARRAY_ITERATE_KEY);
return isShallow(array) ? raw : raw.map(toReactive);
}
function shallowReadArray(arr) {
track(arr = toRaw(arr), "iterate", ARRAY_ITERATE_KEY);
return arr;
}
const arrayInstrumentations = {
__proto__: null,
[Symbol.iterator]() {
return iterator(this, Symbol.iterator, toReactive);
},
concat(...args) {
return reactiveReadArray(this).concat(
...args.map((x) => isArray(x) ? reactiveReadArray(x) : x)
);
},
entries() {
return iterator(this, "entries", (value) => {
value[1] = toReactive(value[1]);
return value;
});
},
every(fn, thisArg) {
return apply(this, "every", fn, thisArg, void 0, arguments);
},
filter(fn, thisArg) {
return apply(this, "filter", fn, thisArg, (v) => v.map(toReactive), arguments);
},
find(fn, thisArg) {
return apply(this, "find", fn, thisArg, toReactive, arguments);
},
findIndex(fn, thisArg) {
return apply(this, "findIndex", fn, thisArg, void 0, arguments);
},
findLast(fn, thisArg) {
return apply(this, "findLast", fn, thisArg, toReactive, arguments);
},
findLastIndex(fn, thisArg) {
return apply(this, "findLastIndex", fn, thisArg, void 0, arguments);
},
// flat, flatMap could benefit from ARRAY_ITERATE but are not straight-forward to implement
forEach(fn, thisArg) {
return apply(this, "forEach", fn, thisArg, void 0, arguments);
},
includes(...args) {
return searchProxy(this, "includes", args);
},
indexOf(...args) {
return searchProxy(this, "indexOf", args);
},
join(separator) {
return reactiveReadArray(this).join(separator);
},
// keys() iterator only reads `length`, no optimisation required
lastIndexOf(...args) {
return searchProxy(this, "lastIndexOf", args);
},
map(fn, thisArg) {
return apply(this, "map", fn, thisArg, void 0, arguments);
},
pop() {
return noTracking(this, "pop");
},
push(...args) {
return noTracking(this, "push", args);
},
reduce(fn, ...args) {
return reduce(this, "reduce", fn, args);
},
reduceRight(fn, ...args) {
return reduce(this, "reduceRight", fn, args);
},
shift() {
return noTracking(this, "shift");
},
// slice could use ARRAY_ITERATE but also seems to beg for range tracking
some(fn, thisArg) {
return apply(this, "some", fn, thisArg, void 0, arguments);
},
splice(...args) {
return noTracking(this, "splice", args);
},
toReversed() {
return reactiveReadArray(this).toReversed();
},
toSorted(comparer) {
return reactiveReadArray(this).toSorted(comparer);
},
toSpliced(...args) {
return reactiveReadArray(this).toSpliced(...args);
},
unshift(...args) {
return noTracking(this, "unshift", args);
},
values() {
return iterator(this, "values", toReactive);
}
};
function iterator(self, method, wrapValue) {
const arr = shallowReadArray(self);
const iter = arr[method]();
if (arr !== self && !isShallow(self)) {
iter._next = iter.next;
iter.next = () => {
const result = iter._next();
if (result.value) {
result.value = wrapValue(result.value);
}
return result;
};
}
return iter;
}
const arrayProto = Array.prototype;
function apply(self, method, fn, thisArg, wrappedRetFn, args) {
const arr = shallowReadArray(self);
const needsWrap = arr !== self && !isShallow(self);
const methodFn = arr[method];
if (methodFn !== arrayProto[method]) {
const result2 = methodFn.apply(self, args);
return needsWrap ? toReactive(result2) : result2;
}
let wrappedFn = fn;
if (arr !== self) {
if (needsWrap) {
wrappedFn = function(item, index) {
return fn.call(this, toReactive(item), index, self);
};
} else if (fn.length > 2) {
wrappedFn = function(item, index) {
return fn.call(this, item, index, self);
};
}
}
const result = methodFn.call(arr, wrappedFn, thisArg);
return needsWrap && wrappedRetFn ? wrappedRetFn(result) : result;
}
function reduce(self, method, fn, args) {
const arr = shallowReadArray(self);
let wrappedFn = fn;
if (arr !== self) {
if (!isShallow(self)) {
wrappedFn = function(acc, item, index) {
return fn.call(this, acc, toReactive(item), index, self);
};
} else if (fn.length > 3) {
wrappedFn = function(acc, item, index) {
return fn.call(this, acc, item, index, self);
};
}
}
return arr[method](wrappedFn, ...args);
}
function searchProxy(self, method, args) {
const arr = toRaw(self);
track(arr, "iterate", ARRAY_ITERATE_KEY);
const res = arr[method](...args);
if ((res === -1 || res === false) && isProxy(args[0])) {
args[0] = toRaw(args[0]);
return arr[method](...args);
}
return res;
}
function noTracking(self, method, args = []) {
pauseTracking();
startBatch();
const res = toRaw(self)[method].apply(self, args);
endBatch();
resetTracking();
return res;
}
const isNonTrackableKeys = /* @__PURE__ */ makeMap(`__proto__,__v_isRef,__isVue`);
const builtInSymbols = new Set(
/* @__PURE__ */ Object.getOwnPropertyNames(Symbol).filter((key) => key !== "arguments" && key !== "caller").map((key) => Symbol[key]).filter(isSymbol)
);
function hasOwnProperty(key) {
if (!isSymbol(key)) key = String(key);
const obj = toRaw(this);
track(obj, "has", key);
return obj.hasOwnProperty(key);
}
class BaseReactiveHandler {
constructor(_isReadonly = false, _isShallow = false) {
this._isReadonly = _isReadonly;
this._isShallow = _isShallow;
}
get(target, key, receiver) {
const isReadonly2 = this._isReadonly, isShallow2 = this._isShallow;
if (key === "__v_isReactive") {
return !isReadonly2;
} else if (key === "__v_isReadonly") {
return isReadonly2;
} else if (key === "__v_isShallow") {
return isShallow2;
} else if (key === "__v_raw") {
if (receiver === (isReadonly2 ? isShallow2 ? shallowReadonlyMap : readonlyMap : isShallow2 ? shallowReactiveMap : reactiveMap).get(target) || // receiver is not the reactive proxy, but has the same prototype
// this means the receiver is a user proxy of the reactive proxy
Object.getPrototypeOf(target) === Object.getPrototypeOf(receiver)) {
return target;
}
return;
}
const targetIsArray = isArray(target);
if (!isReadonly2) {
let fn;
if (targetIsArray && (fn = arrayInstrumentations[key])) {
return fn;
}
if (key === "hasOwnProperty") {
return hasOwnProperty;
}
}
const res = Reflect.get(
target,
key,
// if this is a proxy wrapping a ref, return methods using the raw ref
// as receiver so that we don't have to call `toRaw` on the ref in all
// its class methods
isRef(target) ? target : receiver
);
if (isSymbol(key) ? builtInSymbols.has(key) : isNonTrackableKeys(key)) {
return res;
}
if (!isReadonly2) {
track(target, "get", key);
}
if (isShallow2) {
return res;
}
if (isRef(res)) {
return targetIsArray && isIntegerKey(key) ? res : res.value;
}
if (isObject(res)) {
return isReadonly2 ? readonly(res) : reactive(res);
}
return res;
}
}
class MutableReactiveHandler extends BaseReactiveHandler {
constructor(isShallow2 = false) {
super(false, isShallow2);
}
set(target, key, value, receiver) {
let oldValue = target[key];
if (!this._isShallow) {
const isOldValueReadonly = isReadonly(oldValue);
if (!isShallow(value) && !isReadonly(value)) {
oldValue = toRaw(oldValue);
value = toRaw(value);
}
if (!isArray(target) && isRef(oldValue) && !isRef(value)) {
if (isOldValueReadonly) {
return false;
} else {
oldValue.value = value;
return true;
}
}
}
const hadKey = isArray(target) && isIntegerKey(key) ? Number(key) < target.length : hasOwn(target, key);
const result = Reflect.set(
target,
key,
value,
isRef(target) ? target : receiver
);
if (target === toRaw(receiver)) {
if (!hadKey) {
trigger(target, "add", key, value);
} else if (hasChanged(value, oldValue)) {
trigger(target, "set", key, value, oldValue);
}
}
return result;
}
deleteProperty(target, key) {
const hadKey = hasOwn(target, key);
const oldValue = target[key];
const result = Reflect.deleteProperty(target, key);
if (result && hadKey) {
trigger(target, "delete", key, void 0, oldValue);
}
return result;
}
has(target, key) {
const result = Reflect.has(target, key);
if (!isSymbol(key) || !builtInSymbols.has(key)) {
track(target, "has", key);
}
return result;
}
ownKeys(target) {
track(
target,
"iterate",
isArray(target) ? "length" : ITERATE_KEY
);
return Reflect.ownKeys(target);
}
}
class ReadonlyReactiveHandler extends BaseReactiveHandler {
constructor(isShallow2 = false) {
super(true, isShallow2);
}
set(target, key) {
{
warn(
`Set operation on key "${String(key)}" failed: target is readonly.`,
target
);
}
return true;
}
deleteProperty(target, key) {
{
warn(
`Delete operation on key "${String(key)}" failed: target is readonly.`,
target
);
}
return true;
}
}
const mutableHandlers = /* @__PURE__ */ new MutableReactiveHandler();
const readonlyHandlers = /* @__PURE__ */ new ReadonlyReactiveHandler();
const shallowReactiveHandlers = /* @__PURE__ */ new MutableReactiveHandler(true);
const shallowReadonlyHandlers = /* @__PURE__ */ new ReadonlyReactiveHandler(true);
const toShallow = (value) => value;
const getProto = (v) => Reflect.getPrototypeOf(v);
function get(target, key, isReadonly2 = false, isShallow2 = false) {
target = target["__v_raw"];
const rawTarget = toRaw(target);
const rawKey = toRaw(key);
if (!isReadonly2) {
if (hasChanged(key, rawKey)) {
track(rawTarget, "get", key);
}
track(rawTarget, "get", rawKey);
}
const { has: has2 } = getProto(rawTarget);
const wrap = isShallow2 ? toShallow : isReadonly2 ? toReadonly : toReactive;
if (has2.call(rawTarget, key)) {
return wrap(target.get(key));
} else if (has2.call(rawTarget, rawKey)) {
return wrap(target.get(rawKey));
} else if (target !== rawTarget) {
target.get(key);
}
}
function has(key, isReadonly2 = false) {
const target = this["__v_raw"];
const rawTarget = toRaw(target);
const rawKey = toRaw(key);
if (!isReadonly2) {
if (hasChanged(key, rawKey)) {
track(rawTarget, "has", key);
}
track(rawTarget, "has", rawKey);
}
return key === rawKey ? target.has(key) : target.has(key) || target.has(rawKey);
}
function size(target, isReadonly2 = false) {
target = target["__v_raw"];
!isReadonly2 && track(toRaw(target), "iterate", ITERATE_KEY);
return Reflect.get(target, "size", target);
}
function add(value, _isShallow = false) {
if (!_isShallow && !isShallow(value) && !isReadonly(value)) {
value = toRaw(value);
}
const target = toRaw(this);
const proto = getProto(target);
const hadKey = proto.has.call(target, value);
if (!hadKey) {
target.add(value);
trigger(target, "add", value, value);
}
return this;
}
function set(key, value, _isShallow = false) {
if (!_isShallow && !isShallow(value) && !isReadonly(value)) {
value = toRaw(value);
}
const target = toRaw(this);
const { has: has2, get: get2 } = getProto(target);
let hadKey = has2.call(target, key);
if (!hadKey) {
key = toRaw(key);
hadKey = has2.call(target, key);
} else {
checkIdentityKeys(target, has2, key);
}
const oldValue = get2.call(target, key);
target.set(key, value);
if (!hadKey) {
trigger(target, "add", key, value);
} else if (hasChanged(value, oldValue)) {
trigger(target, "set", key, value, oldValue);
}
return this;
}
function deleteEntry(key) {
const target = toRaw(this);
const { has: has2, get: get2 } = getProto(target);
let hadKey = has2.call(target, key);
if (!hadKey) {
key = toRaw(key);
hadKey = has2.call(target, key);
} else {
checkIdentityKeys(target, has2, key);
}
const oldValue = get2 ? get2.call(target, key) : void 0;
const result = target.delete(key);
if (hadKey) {
trigger(target, "delete", key, void 0, oldValue);
}
return result;
}
function clear() {
const target = toRaw(this);
const hadItems = target.size !== 0;
const oldTarget = isMap(target) ? new Map(target) : new Set(target) ;
const result = target.clear();
if (hadItems) {
trigger(target, "clear", void 0, void 0, oldTarget);
}
return result;
}
function createForEach(isReadonly2, isShallow2) {
return function forEach(callback, thisArg) {
const observed = this;
const target = observed["__v_raw"];
const rawTarget = toRaw(target);
const wrap = isShallow2 ? toShallow : isReadonly2 ? toReadonly : toReactive;
!isReadonly2 && track(rawTarget, "iterate", ITERATE_KEY);
return target.forEach((value, key) => {
return callback.call(thisArg, wrap(value), wrap(key), observed);
});
};
}
function createIterableMethod(method, isReadonly2, isShallow2) {
return function(...args) {
const target = this["__v_raw"];
const rawTarget = toRaw(target);
const targetIsMap = isMap(rawTarget);
const isPair = method === "entries" || method === Symbol.iterator && targetIsMap;
const isKeyOnly = method === "keys" && targetIsMap;
const innerIterator = target[method](...args);
const wrap = isShallow2 ? toShallow : isReadonly2 ? toReadonly : toReactive;
!isReadonly2 && track(
rawTarget,
"iterate",
isKeyOnly ? MAP_KEY_ITERATE_KEY : ITERATE_KEY
);
return {
// iterator protocol
next() {
const { value, done } = innerIterator.next();
return done ? { value, done } : {
value: isPair ? [wrap(value[0]), wrap(value[1])] : wrap(value),
done
};
},
// iterable protocol
[Symbol.iterator]() {
return this;
}
};
};
}
function createReadonlyMethod(type) {
return function(...args) {
{
const key = args[0] ? `on key "${args[0]}" ` : ``;
warn(
`${capitalize(type)} operation ${key}failed: target is readonly.`,
toRaw(this)
);
}
return type === "delete" ? false : type === "clear" ? void 0 : this;
};
}
function createInstrumentations() {
const mutableInstrumentations2 = {
get(key) {
return get(this, key);
},
get size() {
return size(this);
},
has,
add,
set,
delete: deleteEntry,
clear,
forEach: createForEach(false, false)
};
const shallowInstrumentations2 = {
get(key) {
return get(this, key, false, true);
},
get size() {
return size(this);
},
has,
add(value) {
return add.call(this, value, true);
},
set(key, value) {
return set.call(this, key, value, true);
},
delete: deleteEntry,
clear,
forEach: createForEach(false, true)
};
const readonlyInstrumentations2 = {
get(key) {
return get(this, key, true);
},
get size() {
return size(this, true);
},
has(key) {
return has.call(this, key, true);
},
add: createReadonlyMethod("add"),
set: createReadonlyMethod("set"),
delete: createReadonlyMethod("delete"),
clear: createReadonlyMethod("clear"),
forEach: createForEach(true, false)
};
const shallowReadonlyInstrumentations2 = {
get(key) {
return get(this, key, true, true);
},
get size() {
return size(this, true);
},
has(key) {
return has.call(this, key, true);
},
add: createReadonlyMethod("add"),
set: createReadonlyMethod("set"),
delete: createReadonlyMethod("delete"),
clear: createReadonlyMethod("clear"),
forEach: createForEach(true, true)
};
const iteratorMethods = [
"keys",
"values",
"entries",
Symbol.iterator
];
iteratorMethods.forEach((method) => {
mutableInstrumentations2[method] = createIterableMethod(method, false, false);
readonlyInstrumentations2[method] = createIterableMethod(method, true, false);
shallowInstrumentations2[method] = createIterableMethod(method, false, true);
shallowReadonlyInstrumentations2[method] = createIterableMethod(
method,
true,
true
);
});
return [
mutableInstrumentations2,
readonlyInstrumentations2,
shallowInstrumentations2,
shallowReadonlyInstrumentations2
];
}
const [
mutableInstrumentations,
readonlyInstrumentations,
shallowInstrumentations,
shallowReadonlyInstrumentations
] = /* @__PURE__ */ createInstrumentations();
function createInstrumentationGetter(isReadonly2, shallow) {
const instrumentations = shallow ? isReadonly2 ? shallowReadonlyInstrumentations : shallowInstrumentations : isReadonly2 ? readonlyInstrumentations : mutableInstrumentations;
return (target, key, receiver) => {
if (key === "__v_isReactive") {
return !isReadonly2;
} else if (key === "__v_isReadonly") {
return isReadonly2;
} else if (key === "__v_raw") {
return target;
}
return Reflect.get(
hasOwn(instrumentations, key) && key in target ? instrumentations : target,
key,
receiver
);
};
}
const mutableCollectionHandlers = {
get: /* @__PURE__ */ createInstrumentationGetter(false, false)
};
const shallowCollectionHandlers = {
get: /* @__PURE__ */ createInstrumentationGetter(false, true)
};
const readonlyCollectionHandlers = {
get: /* @__PURE__ */ createInstrumentationGetter(true, false)
};
const shallowReadonlyCollectionHandlers = {
get: /* @__PURE__ */ createInstrumentationGetter(true, true)
};
function checkIdentityKeys(target, has2, key) {
const rawKey = toRaw(key);
if (rawKey !== key && has2.call(target, rawKey)) {
const type = toRawType(target);
warn(
`Reactive ${type} contains both the raw and reactive versions of the same object${type === `Map` ? ` as keys` : ``}, which can lead to inconsistencies. Avoid differentiating between the raw and reactive versions of an object and only use the reactive version if possible.`
);
}
}
const reactiveMap = /* @__PURE__ */ new WeakMap();
const shallowReactiveMap = /* @__PURE__ */ new WeakMap();
const readonlyMap = /* @__PURE__ */ new WeakMap();
const shallowReadonlyMap = /* @__PURE__ */ new WeakMap();
function targetTypeMap(rawType) {
switch (rawType) {
case "Object":
case "Array":
return 1 /* COMMON */;
case "Map":
case "Set":
case "WeakMap":
case "WeakSet":
return 2 /* COLLECTION */;
default:
return 0 /* INVALID */;
}
}
function getTargetType(value) {
return value["__v_skip"] || !Object.isExtensible(value) ? 0 /* INVALID */ : targetTypeMap(toRawType(value));
}
function reactive(target) {
if (isReadonly(target)) {
return target;
}
return createReactiveObject(
target,
false,
mutableHandlers,
mutableCollectionHandlers,
reactiveMap
);
}
function shallowReactive(target) {
return createReactiveObject(
target,
false,
shallowReactiveHandlers,
shallowCollectionHandlers,
shallowReactiveMap
);
}
function readonly(target) {
return createReactiveObject(
target,
true,
readonlyHandlers,
readonlyCollectionHandlers,
readonlyMap
);
}
function shallowReadonly(target) {
return createReactiveObject(
target,
true,
shallowReadonlyHandlers,
shallowReadonlyCollectionHandlers,
shallowReadonlyMap
);
}
function createReactiveObject(target, isReadonly2, baseHandlers, collectionHandlers, proxyMap) {
if (!isObject(target)) {
{
warn(
`value cannot be made ${isReadonly2 ? "readonly" : "reactive"}: ${String(
target
)}`
);
}
return target;
}
if (target["__v_raw"] && !(isReadonly2 && target["__v_isReactive"])) {
return target;
}
const existingProxy = proxyMap.get(target);
if (existingProxy) {
return existingProxy;
}
const targetType = getTargetType(target);
if (targetType === 0 /* INVALID */) {
return target;
}
const proxy = new Proxy(
target,
targetType === 2 /* COLLECTION */ ? collectionHandlers : baseHandlers
);
proxyMap.set(target, proxy);
return proxy;
}
function isReactive(value) {
if (isReadonly(value)) {
return isReactive(value["__v_raw"]);
}
return !!(value && value["__v_isReactive"]);
}
function isReadonly(value) {
return !!(value && value["__v_isReadonly"]);
}
function isShallow(value) {
return !!(value && value["__v_isShallow"]);
}
function isProxy(value) {
return value ? !!value["__v_raw"] : false;
}
function toRaw(observed) {
const raw = observed && observed["__v_raw"];
return raw ? toRaw(raw) : observed;
}
function markRaw(value) {
if (Object.isExtensible(value)) {
def(value, "__v_skip", true);
}
return value;
}
const toReactive = (value) => isObject(value) ? reactive(value) : value;
const toReadonly = (value) => isObject(value) ? readonly(value) : value;
function isRef(r) {
return r ? r["__v_isRef"] === true : false;
}
function ref(value) {
return createRef(value, false);
}
function shallowRef(value) {
return createRef(value, true);
}
function createRef(rawValue, shallow) {
if (isRef(rawValue)) {
return rawValue;
}
return new RefImpl(rawValue, shallow);
}
class RefImpl {
constructor(value, isShallow2) {
this.dep = new Dep();
this["__v_isRef"] = true;
this["__v_isShallow"] = false;
this._rawValue = isShallow2 ? value : toRaw(value);
this._value = isShallow2 ? value : toReactive(value);
this["__v_isShallow"] = isShallow2;
}
get value() {
{
this.dep.track({
target: this,
type: "get",
key: "value"
});
}
return this._value;
}
set value(newValue) {
const oldValue = this._rawValue;
const useDirectValue = this["__v_isShallow"] || isShallow(newValue) || isReadonly(newValue);
newValue = useDirectValue ? newValue : toRaw(newValue);
if (hasChanged(newValue, oldValue)) {
this._rawValue = newValue;
this._value = useDirectValue ? newValue : toReactive(newValue);
{
this.dep.trigger({
target: this,
type: "set",
key: "value",
newValue,
oldValue
});
}
}
}
}
function triggerRef(ref2) {
{
ref2.dep.trigger({
target: ref2,
type: "set",
key: "value",
newValue: ref2._value
});
}
}
function unref(ref2) {
return isRef(ref2) ? ref2.value : ref2;
}
function toValue(source) {
return isFunction(source) ? source() : unref(source);
}
const shallowUnwrapHandlers = {
get: (target, key, receiver) => unref(Reflect.get(target, key, receiver)),
set: (target, key, value, receiver) => {
const oldValue = target[key];
if (isRef(oldValue) && !isRef(value)) {
oldValue.value = value;
return true;
} else {
return Reflect.set(target, key, value, receiver);
}
}
};
function proxyRefs(objectWithRefs) {
return isReactive(objectWithRefs) ? objectWithRefs : new Proxy(objectWithRefs, shallowUnwrapHandlers);
}
class CustomRefImpl {
constructor(factory) {
this["__v_isRef"] = true;
this._value = void 0;
const dep = this.dep = new Dep();
const { get, set } = factory(dep.track.bind(dep), dep.trigger.bind(dep));
this._get = get;
this._set = set;
}
get value() {
return this._value = this._get();
}
set value(newVal) {
this._set(newVal);
}
}
function customRef(factory) {
return new CustomRefImpl(factory);
}
function toRefs(object) {
if (!isProxy(object)) {
warn(`toRefs() expects a reactive object but received a plain one.`);
}
const ret = isArray(object) ? new Array(object.length) : {};
for (const key in object) {
ret[key] = propertyToRef(object, key);
}
return ret;
}
class ObjectRefImpl {
constructor(_object, _key, _defaultValue) {
this._object = _object;
this._key = _key;
this._defaultValue = _defaultValue;
this["__v_isRef"] = true;
this._value = void 0;
}
get value() {
const val = this._object[this._key];
return this._value = val === void 0 ? this._defaultValue : val;
}
set value(newVal) {
this._object[this._key] = newVal;
}
get dep() {
return getDepFromReactive(toRaw(this._object), this._key);
}
}
class GetterRefImpl {
constructor(_getter) {
this._getter = _getter;
this["__v_isRef"] = true;
this["__v_isReadonly"] = true;
this._value = void 0;
}
get value() {
return this._value = this._getter();
}
}
function toRef(source, key, defaultValue) {
if (isRef(source)) {
return source;
} else if (isFunction(source)) {
return new GetterRefImpl(source);
} else if (isObject(source) && arguments.length > 1) {
return propertyToRef(source, key, defaultValue);
} else {
return ref(source);
}
}
function propertyToRef(source, key, defaultValue) {
const val = source[key];
return isRef(val) ? val : new ObjectRefImpl(source, key, defaultValue);
}
class ComputedRefImpl {
constructor(fn, setter, isSSR) {
this.fn = fn;
this.setter = setter;
/**
* @internal
*/
this._value = void 0;
/**
* @internal
*/
this.dep = new Dep(this);
/**
* @internal
*/
this.__v_isRef = true;
// TODO isolatedDeclarations "__v_isReadonly"
// A computed is also a subscriber that tracks other deps
/**
* @internal
*/
this.deps = void 0;
/**
* @internal
*/
this.depsTail = void 0;
/**
* @internal
*/
this.flags = 16;
/**
* @internal
*/
this.globalVersion = globalVersion - 1;
// for backwards compat
this.effect = this;
this["__v_isReadonly"] = !setter;
this.isSSR = isSSR;
}
/**
* @internal
*/
notify() {
if (activeSub !== this) {
this.flags |= 16;
this.dep.notify();
}
}
get value() {
const link = this.dep.track({
target: this,
type: "get",
key: "value"
}) ;
refreshComputed(this);
if (link) {
link.version = this.dep.version;
}
return this._value;
}
set value(newValue) {
if (this.setter) {
this.setter(newValue);
} else {
warn("Write operation failed: computed value is readonly");
}
}
}
function computed(getterOrOptions, debugOptions, isSSR = false) {
let getter;
let setter;
if (isFunction(getterOrOptions)) {
getter = getterOrOptions;
} else {
getter = getterOrOptions.get;
setter = getterOrOptions.set;
}
const cRef = new ComputedRefImpl(getter, setter, isSSR);
if (debugOptions && !isSSR) {
cRef.onTrack = debugOptions.onTrack;
cRef.onTrigger = debugOptions.onTrigger;
}
return cRef;
}
const TrackOpTypes = {
"GET": "get",
"HAS": "has",
"ITERATE": "iterate"
};
const TriggerOpTypes = {
"SET": "set",
"ADD": "add",
"DELETE": "delete",
"CLEAR": "clear"
};
const ReactiveFlags = {
"SKIP": "__v_skip",
"IS_REACTIVE": "__v_isReactive",
"IS_READONLY": "__v_isReadonly",
"IS_SHALLOW": "__v_isShallow",
"RAW": "__v_raw",
"IS_REF": "__v_isRef"
};
const WatchErrorCodes = {
"WATCH_GETTER": 2,
"2": "WATCH_GETTER",
"WATCH_CALLBACK": 3,
"3": "WATCH_CALLBACK",
"WATCH_CLEANUP": 4,
"4": "WATCH_CLEANUP"
};
const INITIAL_WATCHER_VALUE = {};
const cleanupMap = /* @__PURE__ */ new WeakMap();
let activeWatcher = void 0;
function getCurrentWatcher() {
return activeWatcher;
}
function onWatcherCleanup(cleanupFn, failSilently = false, owner = activeWatcher) {
if (owner) {
let cleanups = cleanupMap.get(owner);
if (!cleanups) cleanupMap.set(owner, cleanups = []);
cleanups.push(cleanupFn);
} else if (!failSilently) {
warn(
`onWatcherCleanup() was called when there was no active watcher to associate with.`
);
}
}
function watch(source, cb, options = EMPTY_OBJ) {
const { immediate, deep, once, scheduler, augmentJob, call } = options;
const warnInvalidSource = (s) => {
(options.onWarn || warn)(
`Invalid watch source: `,
s,
`A watch source can only be a getter/effect function, a ref, a reactive object, or an array of these types.`
);
};
const reactiveGetter = (source2) => {
if (deep) return source2;
if (isShallow(source2) || deep === false || deep === 0)
return traverse(source2, 1);
return traverse(source2);
};
let effect;
let getter;
let cleanup;
let boundCleanup;
let forceTrigger = false;
let isMultiSource = false;
if (isRef(source)) {
getter = () => source.value;
forceTrigger = isShallow(source);
} else if (isReactive(source)) {
getter = () => reactiveGetter(source);
forceTrigger = true;
} else if (isArray(source)) {
isMultiSource = true;
forceTrigger = source.some((s) => isReactive(s) || isShallow(s));
getter = () => source.map((s) => {
if (isRef(s)) {
return s.value;
} else if (isReactive(s)) {
return reactiveGetter(s);
} else if (isFunction(s)) {
return call ? call(s, 2) : s();
} else {
warnInvalidSource(s);
}
});
} else if (isFunction(source)) {
if (cb) {
getter = call ? () => call(source, 2) : source;
} else {
getter = () => {
if (cleanup) {
pauseTracking();
try {
cleanup();
} finally {
resetTracking();
}
}
const currentEffect = activeWatcher;
activeWatcher = effect;
try {
return call ? call(source, 3, [boundCleanup]) : source(boundCleanup);
} finally {
activeWatcher = currentEffect;
}
};
}
} else {
getter = NOOP;
warnInvalidSource(source);
}
if (cb && deep) {
const baseGetter = getter;
const depth = deep === true ? Infinity : deep;
getter = () => traverse(baseGetter(), depth);
}
const scope = getCurrentScope();
const watchHandle = () => {
effect.stop();
if (scope) {
remove(scope.effects, effect);
}
};
if (once) {
if (cb) {
const _cb = cb;
cb = (...args) => {
_cb(...args);
watchHandle();
};
} else {
const _getter = getter;
getter = () => {
_getter();
watchHandle();
};
}
}
let oldValue = isMultiSource ? new Array(source.length).fill(INITIAL_WATCHER_VALUE) : INITIAL_WATCHER_VALUE;
const job = (immediateFirstRun) => {
if (!(effect.flags & 1) || !effect.dirty && !immediateFirstRun) {
return;
}
if (cb) {
const newValue = effect.run();
if (deep || forceTrigger || (isMultiSource ? newValue.some((v, i) => hasChanged(v, oldValue[i])) : hasChanged(newValue, oldValue))) {
if (cleanup) {
cleanup();
}
const currentWatcher = activeWatcher;
activeWatcher = effect;
try {
const args = [
newValue,
// pass undefined as the old value when it's changed for the first time
oldValue === INITIAL_WATCHER_VALUE ? void 0 : isMultiSource && oldValue[0] === INITIAL_WATCHER_VALUE ? [] : oldValue,
boundCleanup
];
call ? call(cb, 3, args) : (
// @ts-expect-error
cb(...args)
);
oldValue = newValue;
} finally {
activeWatcher = currentWatcher;
}
}
} else {
effect.run();
}
};
if (augmentJob) {
augmentJob(job);
}
effect = new ReactiveEffect(getter);
effect.scheduler = scheduler ? () => scheduler(job, false) : job;
boundCleanup = (fn) => onWatcherCleanup(fn, false, effect);
cleanup = effect.onStop = () => {
const cleanups = cleanupMap.get(effect);
if (cleanups) {
if (call) {
call(cleanups, 4);
} else {
for (const cleanup2 of cleanups) cleanup2();
}
cleanupMap.delete(effect);
}
};
{
effect.onTrack = options.onTrack;
effect.onTrigger = options.onTrigger;
}
if (cb) {
if (immediate) {
job(true);
} else {
oldValue = effect.run();
}
} else if (scheduler) {
scheduler(job.bind(null, true), true);
} else {
effect.run();
}
watchHandle.pause = effect.pause.bind(effect);
watchHandle.resume = effect.resume.bind(effect);
watchHandle.stop = watchHandle;
return watchHandle;
}
function traverse(value, depth = Infinity, seen) {
if (depth <= 0 || !isObject(value) || value["__v_skip"]) {
return value;
}
seen = seen || /* @__PURE__ */ new Set();
if (seen.has(value)) {
return value;
}
seen.add(value);
depth--;
if (isRef(value)) {
traverse(value.value, depth, seen);
} else if (isArray(value)) {
for (let i = 0; i < value.length; i++) {
traverse(value[i], depth, seen);
}
} else if (isSet(value) || isMap(value)) {
value.forEach((v) => {
traverse(v, depth, seen);
});
} else if (isPlainObject(value)) {
for (const key in value) {
traverse(value[key], depth, seen);
}
for (const key of Object.getOwnPropertySymbols(value)) {
if (Object.prototype.propertyIsEnumerable.call(value, key)) {
traverse(value[key], depth, seen);
}
}
}
return value;
}
exports.ARRAY_ITERATE_KEY = ARRAY_ITERATE_KEY;
exports.EffectFlags = EffectFlags;
exports.EffectScope = EffectScope;
exports.ITERATE_KEY = ITERATE_KEY;
exports.MAP_KEY_ITERATE_KEY = MAP_KEY_ITERATE_KEY;
exports.ReactiveEffect = ReactiveEffect;
exports.ReactiveFlags = ReactiveFlags;
exports.TrackOpTypes = TrackOpTypes;
exports.TriggerOpTypes = TriggerOpTypes;
exports.WatchErrorCodes = WatchErrorCodes;
exports.computed = computed;
exports.customRef = customRef;
exports.effect = effect;
exports.effectScope = effectScope;
exports.enableTracking = enableTracking;
exports.getCurrentScope = getCurrentScope;
exports.getCurrentWatcher = getCurrentWatcher;
exports.isProxy = isProxy;
exports.isReactive = isReactive;
exports.isReadonly = isReadonly;
exports.isRef = isRef;
exports.isShallow = isShallow;
exports.markRaw = markRaw;
exports.onEffectCleanup = onEffectCleanup;
exports.onScopeDispose = onScopeDispose;
exports.onWatcherCleanup = onWatcherCleanup;
exports.pauseTracking = pauseTracking;
exports.proxyRefs = proxyRefs;
exports.reactive = reactive;
exports.reactiveReadArray = reactiveReadArray;
exports.readonly = readonly;
exports.ref = ref;
exports.resetTracking = resetTracking;
exports.shallowReactive = shallowReactive;
exports.shallowReadArray = shallowReadArray;
exports.shallowReadonly = shallowReadonly;
exports.shallowRef = shallowRef;
exports.stop = stop;
exports.toRaw = toRaw;
exports.toReactive = toReactive;
exports.toReadonly = toReadonly;
exports.toRef = toRef;
exports.toRefs = toRefs;
exports.toValue = toValue;
exports.track = track;
exports.traverse = traverse;
exports.trigger = trigger;
exports.triggerRef = triggerRef;
exports.unref = unref;
exports.watch = watch;
return exports;
})({});