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react/compiled/facebook-www/React-dev.classic.js
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jackpope 0db83ce329 Add useModernStrictMode as dynamic flag on www (#28346) 
## Summary

Preparing modern strict mode rollout with dynamic feature flag

## How did you test this change?

![Screenshot 2024-02-15 at 10 09
49 AM](https://github.com/facebook/react/assets/8965173/9e90efc2-3578-4e63-ae2c-63d4a4e194b3)

DiffTrain build for [ef72271c2d](https://github.com/facebook/react/commit/ef72271c2d1234c9d1e1358f8083021089a50faa)
2024-02-16 20:22:50 +00:00

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/**
* Copyright (c) Meta Platforms, Inc. and affiliates.
*
* This source code is licensed under the MIT license found in the
* LICENSE file in the root directory of this source tree.
*
* @noflow
* @nolint
* @preventMunge
* @preserve-invariant-messages
*/
"use strict";
if (__DEV__) {
(function () {
"use strict";
/* global __REACT_DEVTOOLS_GLOBAL_HOOK__ */
if (
typeof __REACT_DEVTOOLS_GLOBAL_HOOK__ !== "undefined" &&
typeof __REACT_DEVTOOLS_GLOBAL_HOOK__.registerInternalModuleStart ===
"function"
) {
__REACT_DEVTOOLS_GLOBAL_HOOK__.registerInternalModuleStart(new Error());
}
var ReactVersion = "18.3.0-www-classic-435f93e8";
// ATTENTION
// When adding new symbols to this file,
// Please consider also adding to 'react-devtools-shared/src/backend/ReactSymbols'
// The Symbol used to tag the ReactElement-like types.
var REACT_ELEMENT_TYPE = Symbol.for("react.element");
var REACT_PORTAL_TYPE = Symbol.for("react.portal");
var REACT_FRAGMENT_TYPE = Symbol.for("react.fragment");
var REACT_STRICT_MODE_TYPE = Symbol.for("react.strict_mode");
var REACT_PROFILER_TYPE = Symbol.for("react.profiler");
var REACT_PROVIDER_TYPE = Symbol.for("react.provider"); // TODO: Delete with enableRenderableContext
var REACT_CONSUMER_TYPE = Symbol.for("react.consumer");
var REACT_CONTEXT_TYPE = Symbol.for("react.context");
var REACT_FORWARD_REF_TYPE = Symbol.for("react.forward_ref");
var REACT_SUSPENSE_TYPE = Symbol.for("react.suspense");
var REACT_SUSPENSE_LIST_TYPE = Symbol.for("react.suspense_list");
var REACT_MEMO_TYPE = Symbol.for("react.memo");
var REACT_LAZY_TYPE = Symbol.for("react.lazy");
var REACT_SCOPE_TYPE = Symbol.for("react.scope");
var REACT_DEBUG_TRACING_MODE_TYPE = Symbol.for("react.debug_trace_mode");
var REACT_OFFSCREEN_TYPE = Symbol.for("react.offscreen");
var REACT_LEGACY_HIDDEN_TYPE = Symbol.for("react.legacy_hidden");
var REACT_CACHE_TYPE = Symbol.for("react.cache");
var REACT_TRACING_MARKER_TYPE = Symbol.for("react.tracing_marker");
var MAYBE_ITERATOR_SYMBOL = Symbol.iterator;
var FAUX_ITERATOR_SYMBOL = "@@iterator";
function getIteratorFn(maybeIterable) {
if (maybeIterable === null || typeof maybeIterable !== "object") {
return null;
}
var maybeIterator =
(MAYBE_ITERATOR_SYMBOL && maybeIterable[MAYBE_ITERATOR_SYMBOL]) ||
maybeIterable[FAUX_ITERATOR_SYMBOL];
if (typeof maybeIterator === "function") {
return maybeIterator;
}
return null;
}
// This refers to a WWW module.
var warningWWW = require("warning");
function warn(format) {
{
{
for (
var _len = arguments.length,
args = new Array(_len > 1 ? _len - 1 : 0),
_key = 1;
_key < _len;
_key++
) {
args[_key - 1] = arguments[_key];
}
printWarning("warn", format, args);
}
}
}
function error(format) {
{
{
for (
var _len2 = arguments.length,
args = new Array(_len2 > 1 ? _len2 - 1 : 0),
_key2 = 1;
_key2 < _len2;
_key2++
) {
args[_key2 - 1] = arguments[_key2];
}
printWarning("error", format, args);
}
}
}
function printWarning(level, format, args) {
{
var React = require("react");
var ReactSharedInternals =
React.__SECRET_INTERNALS_DO_NOT_USE_OR_YOU_WILL_BE_FIRED; // Defensive in case this is fired before React is initialized.
if (ReactSharedInternals != null) {
var ReactDebugCurrentFrame =
ReactSharedInternals.ReactDebugCurrentFrame;
var stack = ReactDebugCurrentFrame.getStackAddendum();
if (stack !== "") {
format += "%s";
args.push(stack);
}
} // TODO: don't ignore level and pass it down somewhere too.
args.unshift(format);
args.unshift(false);
warningWWW.apply(null, args);
}
}
var didWarnStateUpdateForUnmountedComponent = {};
function warnNoop(publicInstance, callerName) {
{
var _constructor = publicInstance.constructor;
var componentName =
(_constructor && (_constructor.displayName || _constructor.name)) ||
"ReactClass";
var warningKey = componentName + "." + callerName;
if (didWarnStateUpdateForUnmountedComponent[warningKey]) {
return;
}
error(
"Can't call %s on a component that is not yet mounted. " +
"This is a no-op, but it might indicate a bug in your application. " +
"Instead, assign to `this.state` directly or define a `state = {};` " +
"class property with the desired state in the %s component.",
callerName,
componentName
);
didWarnStateUpdateForUnmountedComponent[warningKey] = true;
}
}
/**
* This is the abstract API for an update queue.
*/
var ReactNoopUpdateQueue = {
/**
* Checks whether or not this composite component is mounted.
* @param {ReactClass} publicInstance The instance we want to test.
* @return {boolean} True if mounted, false otherwise.
* @protected
* @final
*/
isMounted: function (publicInstance) {
return false;
},
/**
* Forces an update. This should only be invoked when it is known with
* certainty that we are **not** in a DOM transaction.
*
* You may want to call this when you know that some deeper aspect of the
* component's state has changed but `setState` was not called.
*
* This will not invoke `shouldComponentUpdate`, but it will invoke
* `componentWillUpdate` and `componentDidUpdate`.
*
* @param {ReactClass} publicInstance The instance that should rerender.
* @param {?function} callback Called after component is updated.
* @param {?string} callerName name of the calling function in the public API.
* @internal
*/
enqueueForceUpdate: function (publicInstance, callback, callerName) {
warnNoop(publicInstance, "forceUpdate");
},
/**
* Replaces all of the state. Always use this or `setState` to mutate state.
* You should treat `this.state` as immutable.
*
* There is no guarantee that `this.state` will be immediately updated, so
* accessing `this.state` after calling this method may return the old value.
*
* @param {ReactClass} publicInstance The instance that should rerender.
* @param {object} completeState Next state.
* @param {?function} callback Called after component is updated.
* @param {?string} callerName name of the calling function in the public API.
* @internal
*/
enqueueReplaceState: function (
publicInstance,
completeState,
callback,
callerName
) {
warnNoop(publicInstance, "replaceState");
},
/**
* Sets a subset of the state. This only exists because _pendingState is
* internal. This provides a merging strategy that is not available to deep
* properties which is confusing. TODO: Expose pendingState or don't use it
* during the merge.
*
* @param {ReactClass} publicInstance The instance that should rerender.
* @param {object} partialState Next partial state to be merged with state.
* @param {?function} callback Called after component is updated.
* @param {?string} Name of the calling function in the public API.
* @internal
*/
enqueueSetState: function (
publicInstance,
partialState,
callback,
callerName
) {
warnNoop(publicInstance, "setState");
}
};
var assign = Object.assign;
var emptyObject = {};
{
Object.freeze(emptyObject);
}
/**
* Base class helpers for the updating state of a component.
*/
function Component(props, context, updater) {
this.props = props;
this.context = context; // If a component has string refs, we will assign a different object later.
this.refs = emptyObject; // We initialize the default updater but the real one gets injected by the
// renderer.
this.updater = updater || ReactNoopUpdateQueue;
}
Component.prototype.isReactComponent = {};
/**
* Sets a subset of the state. Always use this to mutate
* state. You should treat `this.state` as immutable.
*
* There is no guarantee that `this.state` will be immediately updated, so
* accessing `this.state` after calling this method may return the old value.
*
* There is no guarantee that calls to `setState` will run synchronously,
* as they may eventually be batched together. You can provide an optional
* callback that will be executed when the call to setState is actually
* completed.
*
* When a function is provided to setState, it will be called at some point in
* the future (not synchronously). It will be called with the up to date
* component arguments (state, props, context). These values can be different
* from this.* because your function may be called after receiveProps but before
* shouldComponentUpdate, and this new state, props, and context will not yet be
* assigned to this.
*
* @param {object|function} partialState Next partial state or function to
* produce next partial state to be merged with current state.
* @param {?function} callback Called after state is updated.
* @final
* @protected
*/
Component.prototype.setState = function (partialState, callback) {
if (
typeof partialState !== "object" &&
typeof partialState !== "function" &&
partialState != null
) {
throw new Error(
"setState(...): takes an object of state variables to update or a " +
"function which returns an object of state variables."
);
}
this.updater.enqueueSetState(this, partialState, callback, "setState");
};
/**
* Forces an update. This should only be invoked when it is known with
* certainty that we are **not** in a DOM transaction.
*
* You may want to call this when you know that some deeper aspect of the
* component's state has changed but `setState` was not called.
*
* This will not invoke `shouldComponentUpdate`, but it will invoke
* `componentWillUpdate` and `componentDidUpdate`.
*
* @param {?function} callback Called after update is complete.
* @final
* @protected
*/
Component.prototype.forceUpdate = function (callback) {
this.updater.enqueueForceUpdate(this, callback, "forceUpdate");
};
/**
* Deprecated APIs. These APIs used to exist on classic React classes but since
* we would like to deprecate them, we're not going to move them over to this
* modern base class. Instead, we define a getter that warns if it's accessed.
*/
{
var deprecatedAPIs = {
isMounted: [
"isMounted",
"Instead, make sure to clean up subscriptions and pending requests in " +
"componentWillUnmount to prevent memory leaks."
],
replaceState: [
"replaceState",
"Refactor your code to use setState instead (see " +
"https://github.com/facebook/react/issues/3236)."
]
};
var defineDeprecationWarning = function (methodName, info) {
Object.defineProperty(Component.prototype, methodName, {
get: function () {
warn(
"%s(...) is deprecated in plain JavaScript React classes. %s",
info[0],
info[1]
);
return undefined;
}
});
};
for (var fnName in deprecatedAPIs) {
if (deprecatedAPIs.hasOwnProperty(fnName)) {
defineDeprecationWarning(fnName, deprecatedAPIs[fnName]);
}
}
}
function ComponentDummy() {}
ComponentDummy.prototype = Component.prototype;
/**
* Convenience component with default shallow equality check for sCU.
*/
function PureComponent(props, context, updater) {
this.props = props;
this.context = context; // If a component has string refs, we will assign a different object later.
this.refs = emptyObject;
this.updater = updater || ReactNoopUpdateQueue;
}
var pureComponentPrototype = (PureComponent.prototype =
new ComponentDummy());
pureComponentPrototype.constructor = PureComponent; // Avoid an extra prototype jump for these methods.
assign(pureComponentPrototype, Component.prototype);
pureComponentPrototype.isPureReactComponent = true;
// an immutable object with a single mutable value
function createRef() {
var refObject = {
current: null
};
{
Object.seal(refObject);
}
return refObject;
}
var isArrayImpl = Array.isArray; // eslint-disable-next-line no-redeclare
function isArray(a) {
return isArrayImpl(a);
}
/*
* The `'' + value` pattern (used in perf-sensitive code) throws for Symbol
* and Temporal.* types. See https://github.com/facebook/react/pull/22064.
*
* The functions in this module will throw an easier-to-understand,
* easier-to-debug exception with a clear errors message message explaining the
* problem. (Instead of a confusing exception thrown inside the implementation
* of the `value` object).
*/
// $FlowFixMe[incompatible-return] only called in DEV, so void return is not possible.
function typeName(value) {
{
// toStringTag is needed for namespaced types like Temporal.Instant
var hasToStringTag = typeof Symbol === "function" && Symbol.toStringTag;
var type =
(hasToStringTag && value[Symbol.toStringTag]) ||
value.constructor.name ||
"Object"; // $FlowFixMe[incompatible-return]
return type;
}
} // $FlowFixMe[incompatible-return] only called in DEV, so void return is not possible.
function willCoercionThrow(value) {
{
try {
testStringCoercion(value);
return false;
} catch (e) {
return true;
}
}
}
function testStringCoercion(value) {
// If you ended up here by following an exception call stack, here's what's
// happened: you supplied an object or symbol value to React (as a prop, key,
// DOM attribute, CSS property, string ref, etc.) and when React tried to
// coerce it to a string using `'' + value`, an exception was thrown.
//
// The most common types that will cause this exception are `Symbol` instances
// and Temporal objects like `Temporal.Instant`. But any object that has a
// `valueOf` or `[Symbol.toPrimitive]` method that throws will also cause this
// exception. (Library authors do this to prevent users from using built-in
// numeric operators like `+` or comparison operators like `>=` because custom
// methods are needed to perform accurate arithmetic or comparison.)
//
// To fix the problem, coerce this object or symbol value to a string before
// passing it to React. The most reliable way is usually `String(value)`.
//
// To find which value is throwing, check the browser or debugger console.
// Before this exception was thrown, there should be `console.error` output
// that shows the type (Symbol, Temporal.PlainDate, etc.) that caused the
// problem and how that type was used: key, atrribute, input value prop, etc.
// In most cases, this console output also shows the component and its
// ancestor components where the exception happened.
//
// eslint-disable-next-line react-internal/safe-string-coercion
return "" + value;
}
function checkKeyStringCoercion(value) {
{
if (willCoercionThrow(value)) {
error(
"The provided key is an unsupported type %s." +
" This value must be coerced to a string before using it here.",
typeName(value)
);
return testStringCoercion(value); // throw (to help callers find troubleshooting comments)
}
}
}
// Re-export dynamic flags from the www version.
var dynamicFeatureFlags = require("ReactFeatureFlags");
var enableDebugTracing = dynamicFeatureFlags.enableDebugTracing,
enableTransitionTracing = dynamicFeatureFlags.enableTransitionTracing,
enableRenderableContext = dynamicFeatureFlags.enableRenderableContext;
// On WWW, false is used for a new modern build.
function getWrappedName(outerType, innerType, wrapperName) {
var displayName = outerType.displayName;
if (displayName) {
return displayName;
}
var functionName = innerType.displayName || innerType.name || "";
return functionName !== ""
? wrapperName + "(" + functionName + ")"
: wrapperName;
} // Keep in sync with react-reconciler/getComponentNameFromFiber
function getContextName(type) {
return type.displayName || "Context";
}
var REACT_CLIENT_REFERENCE$3 = Symbol.for("react.client.reference"); // Note that the reconciler package should generally prefer to use getComponentNameFromFiber() instead.
function getComponentNameFromType(type) {
if (type == null) {
// Host root, text node or just invalid type.
return null;
}
if (typeof type === "function") {
if (type.$$typeof === REACT_CLIENT_REFERENCE$3) {
// TODO: Create a convention for naming client references with debug info.
return null;
}
return type.displayName || type.name || null;
}
if (typeof type === "string") {
return type;
}
switch (type) {
case REACT_FRAGMENT_TYPE:
return "Fragment";
case REACT_PORTAL_TYPE:
return "Portal";
case REACT_PROFILER_TYPE:
return "Profiler";
case REACT_STRICT_MODE_TYPE:
return "StrictMode";
case REACT_SUSPENSE_TYPE:
return "Suspense";
case REACT_SUSPENSE_LIST_TYPE:
return "SuspenseList";
case REACT_CACHE_TYPE: {
return "Cache";
}
// Fall through
case REACT_TRACING_MARKER_TYPE:
if (enableTransitionTracing) {
return "TracingMarker";
}
}
if (typeof type === "object") {
{
if (typeof type.tag === "number") {
error(
"Received an unexpected object in getComponentNameFromType(). " +
"This is likely a bug in React. Please file an issue."
);
}
}
switch (type.$$typeof) {
case REACT_PROVIDER_TYPE:
if (enableRenderableContext) {
return null;
} else {
var provider = type;
return getContextName(provider._context) + ".Provider";
}
case REACT_CONTEXT_TYPE:
var context = type;
if (enableRenderableContext) {
return getContextName(context) + ".Provider";
} else {
return getContextName(context) + ".Consumer";
}
case REACT_CONSUMER_TYPE:
if (enableRenderableContext) {
var consumer = type;
return getContextName(consumer._context) + ".Consumer";
} else {
return null;
}
case REACT_FORWARD_REF_TYPE:
return getWrappedName(type, type.render, "ForwardRef");
case REACT_MEMO_TYPE:
var outerName = type.displayName || null;
if (outerName !== null) {
return outerName;
}
return getComponentNameFromType(type.type) || "Memo";
case REACT_LAZY_TYPE: {
var lazyComponent = type;
var payload = lazyComponent._payload;
var init = lazyComponent._init;
try {
return getComponentNameFromType(init(payload));
} catch (x) {
return null;
}
}
}
}
return null;
}
// $FlowFixMe[method-unbinding]
var hasOwnProperty = Object.prototype.hasOwnProperty;
/**
* Keeps track of the current owner.
*
* The current owner is the component who should own any components that are
* currently being constructed.
*/
var ReactCurrentOwner$2 = {
/**
* @internal
* @type {ReactComponent}
*/
current: null
};
var specialPropKeyWarningShown$1,
specialPropRefWarningShown$1,
didWarnAboutStringRefs$1;
{
didWarnAboutStringRefs$1 = {};
}
function hasValidRef$1(config) {
{
if (hasOwnProperty.call(config, "ref")) {
var getter = Object.getOwnPropertyDescriptor(config, "ref").get;
if (getter && getter.isReactWarning) {
return false;
}
}
}
return config.ref !== undefined;
}
function hasValidKey$1(config) {
{
if (hasOwnProperty.call(config, "key")) {
var getter = Object.getOwnPropertyDescriptor(config, "key").get;
if (getter && getter.isReactWarning) {
return false;
}
}
}
return config.key !== undefined;
}
function defineKeyPropWarningGetter$1(props, displayName) {
var warnAboutAccessingKey = function () {
{
if (!specialPropKeyWarningShown$1) {
specialPropKeyWarningShown$1 = true;
error(
"%s: `key` is not a prop. Trying to access it will result " +
"in `undefined` being returned. If you need to access the same " +
"value within the child component, you should pass it as a different " +
"prop. (https://reactjs.org/link/special-props)",
displayName
);
}
}
};
warnAboutAccessingKey.isReactWarning = true;
Object.defineProperty(props, "key", {
get: warnAboutAccessingKey,
configurable: true
});
}
function defineRefPropWarningGetter$1(props, displayName) {
var warnAboutAccessingRef = function () {
{
if (!specialPropRefWarningShown$1) {
specialPropRefWarningShown$1 = true;
error(
"%s: `ref` is not a prop. Trying to access it will result " +
"in `undefined` being returned. If you need to access the same " +
"value within the child component, you should pass it as a different " +
"prop. (https://reactjs.org/link/special-props)",
displayName
);
}
}
};
warnAboutAccessingRef.isReactWarning = true;
Object.defineProperty(props, "ref", {
get: warnAboutAccessingRef,
configurable: true
});
}
function warnIfStringRefCannotBeAutoConverted$1(config) {
{
if (
typeof config.ref === "string" &&
ReactCurrentOwner$2.current &&
config.__self &&
ReactCurrentOwner$2.current.stateNode !== config.__self
) {
var componentName = getComponentNameFromType(
ReactCurrentOwner$2.current.type
);
if (!didWarnAboutStringRefs$1[componentName]) {
error(
'Component "%s" contains the string ref "%s". ' +
"Support for string refs will be removed in a future major release. " +
"This case cannot be automatically converted to an arrow function. " +
"We ask you to manually fix this case by using useRef() or createRef() instead. " +
"Learn more about using refs safely here: " +
"https://reactjs.org/link/strict-mode-string-ref",
componentName,
config.ref
);
didWarnAboutStringRefs$1[componentName] = true;
}
}
}
}
/**
* Factory method to create a new React element. This no longer adheres to
* the class pattern, so do not use new to call it. Also, instanceof check
* will not work. Instead test $$typeof field against Symbol.for('react.element') to check
* if something is a React Element.
*
* @param {*} type
* @param {*} props
* @param {*} key
* @param {string|object} ref
* @param {*} owner
* @param {*} self A *temporary* helper to detect places where `this` is
* different from the `owner` when React.createElement is called, so that we
* can warn. We want to get rid of owner and replace string `ref`s with arrow
* functions, and as long as `this` and owner are the same, there will be no
* change in behavior.
* @param {*} source An annotation object (added by a transpiler or otherwise)
* indicating filename, line number, and/or other information.
* @internal
*/
function ReactElement$1(type, key, ref, owner, props) {
var element = {
// This tag allows us to uniquely identify this as a React Element
$$typeof: REACT_ELEMENT_TYPE,
// Built-in properties that belong on the element
type: type,
key: key,
ref: ref,
props: props,
// Record the component responsible for creating this element.
_owner: owner
};
{
// The validation flag is currently mutative. We put it on
// an external backing store so that we can freeze the whole object.
// This can be replaced with a WeakMap once they are implemented in
// commonly used development environments.
element._store = {}; // To make comparing ReactElements easier for testing purposes, we make
// the validation flag non-enumerable (where possible, which should
// include every environment we run tests in), so the test framework
// ignores it.
Object.defineProperty(element._store, "validated", {
configurable: false,
enumerable: false,
writable: true,
value: false
}); // debugInfo contains Server Component debug information.
Object.defineProperty(element, "_debugInfo", {
configurable: false,
enumerable: false,
writable: true,
value: null
});
if (Object.freeze) {
Object.freeze(element.props);
Object.freeze(element);
}
}
return element;
}
/**
* Create and return a new ReactElement of the given type.
* See https://reactjs.org/docs/react-api.html#createelement
*/
function createElement$1(type, config, children) {
var propName; // Reserved names are extracted
var props = {};
var key = null;
var ref = null;
if (config != null) {
if (hasValidRef$1(config)) {
ref = config.ref;
{
warnIfStringRefCannotBeAutoConverted$1(config);
}
}
if (hasValidKey$1(config)) {
{
checkKeyStringCoercion(config.key);
}
key = "" + config.key;
} // Remaining properties are added to a new props object
for (propName in config) {
if (
hasOwnProperty.call(config, propName) && // Skip over reserved prop names
propName !== "key" && // TODO: `ref` will no longer be reserved in the next major
propName !== "ref" && // ...and maybe these, too, though we currently rely on them for
// warnings and debug information in dev. Need to decide if we're OK
// with dropping them. In the jsx() runtime it's not an issue because
// the data gets passed as separate arguments instead of props, but
// it would be nice to stop relying on them entirely so we can drop
// them from the internal Fiber field.
propName !== "__self" &&
propName !== "__source"
) {
props[propName] = config[propName];
}
}
} // Children can be more than one argument, and those are transferred onto
// the newly allocated props object.
var childrenLength = arguments.length - 2;
if (childrenLength === 1) {
props.children = children;
} else if (childrenLength > 1) {
var childArray = Array(childrenLength);
for (var i = 0; i < childrenLength; i++) {
childArray[i] = arguments[i + 2];
}
{
if (Object.freeze) {
Object.freeze(childArray);
}
}
props.children = childArray;
} // Resolve default props
if (type && type.defaultProps) {
var defaultProps = type.defaultProps;
for (propName in defaultProps) {
if (props[propName] === undefined) {
props[propName] = defaultProps[propName];
}
}
}
{
if (key || ref) {
var displayName =
typeof type === "function"
? type.displayName || type.name || "Unknown"
: type;
if (key) {
defineKeyPropWarningGetter$1(props, displayName);
}
if (ref) {
defineRefPropWarningGetter$1(props, displayName);
}
}
}
return ReactElement$1(type, key, ref, ReactCurrentOwner$2.current, props);
}
function cloneAndReplaceKey(oldElement, newKey) {
var newElement = ReactElement$1(
oldElement.type,
newKey,
oldElement.ref,
oldElement._owner,
oldElement.props
);
return newElement;
}
/**
* Clone and return a new ReactElement using element as the starting point.
* See https://reactjs.org/docs/react-api.html#cloneelement
*/
function cloneElement$1(element, config, children) {
if (element === null || element === undefined) {
throw new Error(
"React.cloneElement(...): The argument must be a React element, but you passed " +
element +
"."
);
}
var propName; // Original props are copied
var props = assign({}, element.props); // Reserved names are extracted
var key = element.key;
var ref = element.ref; // Owner will be preserved, unless ref is overridden
var owner = element._owner;
if (config != null) {
if (hasValidRef$1(config)) {
// Silently steal the ref from the parent.
ref = config.ref;
owner = ReactCurrentOwner$2.current;
}
if (hasValidKey$1(config)) {
{
checkKeyStringCoercion(config.key);
}
key = "" + config.key;
} // Remaining properties override existing props
var defaultProps;
if (element.type && element.type.defaultProps) {
defaultProps = element.type.defaultProps;
}
for (propName in config) {
if (
hasOwnProperty.call(config, propName) && // Skip over reserved prop names
propName !== "key" && // TODO: `ref` will no longer be reserved in the next major
propName !== "ref" && // ...and maybe these, too, though we currently rely on them for
// warnings and debug information in dev. Need to decide if we're OK
// with dropping them. In the jsx() runtime it's not an issue because
// the data gets passed as separate arguments instead of props, but
// it would be nice to stop relying on them entirely so we can drop
// them from the internal Fiber field.
propName !== "__self" &&
propName !== "__source"
) {
if (config[propName] === undefined && defaultProps !== undefined) {
// Resolve default props
props[propName] = defaultProps[propName];
} else {
props[propName] = config[propName];
}
}
}
} // Children can be more than one argument, and those are transferred onto
// the newly allocated props object.
var childrenLength = arguments.length - 2;
if (childrenLength === 1) {
props.children = children;
} else if (childrenLength > 1) {
var childArray = Array(childrenLength);
for (var i = 0; i < childrenLength; i++) {
childArray[i] = arguments[i + 2];
}
props.children = childArray;
}
return ReactElement$1(element.type, key, ref, owner, props);
}
/**
* Verifies the object is a ReactElement.
* See https://reactjs.org/docs/react-api.html#isvalidelement
* @param {?object} object
* @return {boolean} True if `object` is a ReactElement.
* @final
*/
function isValidElement$1(object) {
return (
typeof object === "object" &&
object !== null &&
object.$$typeof === REACT_ELEMENT_TYPE
);
}
var REACT_CLIENT_REFERENCE$2 = Symbol.for("react.client.reference");
function isValidElementType(type) {
if (typeof type === "string" || typeof type === "function") {
return true;
} // Note: typeof might be other than 'symbol' or 'number' (e.g. if it's a polyfill).
if (
type === REACT_FRAGMENT_TYPE ||
type === REACT_PROFILER_TYPE ||
(enableDebugTracing && type === REACT_DEBUG_TRACING_MODE_TYPE) ||
type === REACT_STRICT_MODE_TYPE ||
type === REACT_SUSPENSE_TYPE ||
type === REACT_SUSPENSE_LIST_TYPE ||
type === REACT_LEGACY_HIDDEN_TYPE ||
type === REACT_OFFSCREEN_TYPE ||
type === REACT_SCOPE_TYPE ||
type === REACT_CACHE_TYPE ||
(enableTransitionTracing && type === REACT_TRACING_MARKER_TYPE)
) {
return true;
}
if (typeof type === "object" && type !== null) {
if (
type.$$typeof === REACT_LAZY_TYPE ||
type.$$typeof === REACT_MEMO_TYPE ||
type.$$typeof === REACT_CONTEXT_TYPE ||
(!enableRenderableContext && type.$$typeof === REACT_PROVIDER_TYPE) ||
(enableRenderableContext && type.$$typeof === REACT_CONSUMER_TYPE) ||
type.$$typeof === REACT_FORWARD_REF_TYPE || // This needs to include all possible module reference object
// types supported by any Flight configuration anywhere since
// we don't know which Flight build this will end up being used
// with.
type.$$typeof === REACT_CLIENT_REFERENCE$2 ||
type.getModuleId !== undefined
) {
return true;
}
}
return false;
}
// Helpers to patch console.logs to avoid logging during side-effect free
// replaying on render function. This currently only patches the object
// lazily which won't cover if the log function was extracted eagerly.
// We could also eagerly patch the method.
var disabledDepth = 0;
var prevLog;
var prevInfo;
var prevWarn;
var prevError;
var prevGroup;
var prevGroupCollapsed;
var prevGroupEnd;
function disabledLog() {}
disabledLog.__reactDisabledLog = true;
function disableLogs() {
{
if (disabledDepth === 0) {
/* eslint-disable react-internal/no-production-logging */
prevLog = console.log;
prevInfo = console.info;
prevWarn = console.warn;
prevError = console.error;
prevGroup = console.group;
prevGroupCollapsed = console.groupCollapsed;
prevGroupEnd = console.groupEnd; // https://github.com/facebook/react/issues/19099
var props = {
configurable: true,
enumerable: true,
value: disabledLog,
writable: true
}; // $FlowFixMe[cannot-write] Flow thinks console is immutable.
Object.defineProperties(console, {
info: props,
log: props,
warn: props,
error: props,
group: props,
groupCollapsed: props,
groupEnd: props
});
/* eslint-enable react-internal/no-production-logging */
}
disabledDepth++;
}
}
function reenableLogs() {
{
disabledDepth--;
if (disabledDepth === 0) {
/* eslint-disable react-internal/no-production-logging */
var props = {
configurable: true,
enumerable: true,
writable: true
}; // $FlowFixMe[cannot-write] Flow thinks console is immutable.
Object.defineProperties(console, {
log: assign({}, props, {
value: prevLog
}),
info: assign({}, props, {
value: prevInfo
}),
warn: assign({}, props, {
value: prevWarn
}),
error: assign({}, props, {
value: prevError
}),
group: assign({}, props, {
value: prevGroup
}),
groupCollapsed: assign({}, props, {
value: prevGroupCollapsed
}),
groupEnd: assign({}, props, {
value: prevGroupEnd
})
});
/* eslint-enable react-internal/no-production-logging */
}
if (disabledDepth < 0) {
error(
"disabledDepth fell below zero. " +
"This is a bug in React. Please file an issue."
);
}
}
}
/**
* Keeps track of the current dispatcher.
*/
var ReactCurrentDispatcher$1 = {
current: null
};
/**
* Keeps track of the current Cache dispatcher.
*/
var ReactCurrentCache = {
current: null
};
/**
* Keeps track of the current batch's configuration such as how long an update
* should suspend for if it needs to.
*/
var ReactCurrentBatchConfig = {
transition: null
};
var ReactCurrentActQueue = {
current: null,
// Used to reproduce behavior of `batchedUpdates` in legacy mode.
isBatchingLegacy: false,
didScheduleLegacyUpdate: false,
// Tracks whether something called `use` during the current batch of work.
// Determines whether we should yield to microtasks to unwrap already resolved
// promises without suspending.
didUsePromise: false
};
var ReactDebugCurrentFrame$2 = {};
var currentExtraStackFrame = null;
function setExtraStackFrame(stack) {
{
currentExtraStackFrame = stack;
}
}
{
ReactDebugCurrentFrame$2.setExtraStackFrame = function (stack) {
{
currentExtraStackFrame = stack;
}
}; // Stack implementation injected by the current renderer.
ReactDebugCurrentFrame$2.getCurrentStack = null;
ReactDebugCurrentFrame$2.getStackAddendum = function () {
var stack = ""; // Add an extra top frame while an element is being validated
if (currentExtraStackFrame) {
stack += currentExtraStackFrame;
} // Delegate to the injected renderer-specific implementation
var impl = ReactDebugCurrentFrame$2.getCurrentStack;
if (impl) {
stack += impl() || "";
}
return stack;
};
}
var ReactSharedInternals = {
ReactCurrentDispatcher: ReactCurrentDispatcher$1,
ReactCurrentCache: ReactCurrentCache,
ReactCurrentBatchConfig: ReactCurrentBatchConfig,
ReactCurrentOwner: ReactCurrentOwner$2
};
{
ReactSharedInternals.ReactDebugCurrentFrame = ReactDebugCurrentFrame$2;
ReactSharedInternals.ReactCurrentActQueue = ReactCurrentActQueue;
}
var ReactCurrentDispatcher = ReactSharedInternals.ReactCurrentDispatcher;
var prefix;
function describeBuiltInComponentFrame(name, ownerFn) {
{
if (prefix === undefined) {
// Extract the VM specific prefix used by each line.
try {
throw Error();
} catch (x) {
var match = x.stack.trim().match(/\n( *(at )?)/);
prefix = (match && match[1]) || "";
}
} // We use the prefix to ensure our stacks line up with native stack frames.
return "\n" + prefix + name;
}
}
var reentry = false;
var componentFrameCache;
{
var PossiblyWeakMap = typeof WeakMap === "function" ? WeakMap : Map;
componentFrameCache = new PossiblyWeakMap();
}
/**
* Leverages native browser/VM stack frames to get proper details (e.g.
* filename, line + col number) for a single component in a component stack. We
* do this by:
* (1) throwing and catching an error in the function - this will be our
* control error.
* (2) calling the component which will eventually throw an error that we'll
* catch - this will be our sample error.
* (3) diffing the control and sample error stacks to find the stack frame
* which represents our component.
*/
function describeNativeComponentFrame(fn, construct) {
// If something asked for a stack inside a fake render, it should get ignored.
if (!fn || reentry) {
return "";
}
{
var frame = componentFrameCache.get(fn);
if (frame !== undefined) {
return frame;
}
}
reentry = true;
var previousPrepareStackTrace = Error.prepareStackTrace; // $FlowFixMe[incompatible-type] It does accept undefined.
Error.prepareStackTrace = undefined;
var previousDispatcher;
{
previousDispatcher = ReactCurrentDispatcher.current; // Set the dispatcher in DEV because this might be call in the render function
// for warnings.
ReactCurrentDispatcher.current = null;
disableLogs();
}
/**
* Finding a common stack frame between sample and control errors can be
* tricky given the different types and levels of stack trace truncation from
* different JS VMs. So instead we'll attempt to control what that common
* frame should be through this object method:
* Having both the sample and control errors be in the function under the
* `DescribeNativeComponentFrameRoot` property, + setting the `name` and
* `displayName` properties of the function ensures that a stack
* frame exists that has the method name `DescribeNativeComponentFrameRoot` in
* it for both control and sample stacks.
*/
var RunInRootFrame = {
DetermineComponentFrameRoot: function () {
var control;
try {
// This should throw.
if (construct) {
// Something should be setting the props in the constructor.
var Fake = function () {
throw Error();
}; // $FlowFixMe[prop-missing]
Object.defineProperty(Fake.prototype, "props", {
set: function () {
// We use a throwing setter instead of frozen or non-writable props
// because that won't throw in a non-strict mode function.
throw Error();
}
});
if (typeof Reflect === "object" && Reflect.construct) {
// We construct a different control for this case to include any extra
// frames added by the construct call.
try {
Reflect.construct(Fake, []);
} catch (x) {
control = x;
}
Reflect.construct(fn, [], Fake);
} else {
try {
Fake.call();
} catch (x) {
control = x;
} // $FlowFixMe[prop-missing] found when upgrading Flow
fn.call(Fake.prototype);
}
} else {
try {
throw Error();
} catch (x) {
control = x;
} // TODO(luna): This will currently only throw if the function component
// tries to access React/ReactDOM/props. We should probably make this throw
// in simple components too
var maybePromise = fn(); // If the function component returns a promise, it's likely an async
// component, which we don't yet support. Attach a noop catch handler to
// silence the error.
// TODO: Implement component stacks for async client components?
if (maybePromise && typeof maybePromise.catch === "function") {
maybePromise.catch(function () {});
}
}
} catch (sample) {
// This is inlined manually because closure doesn't do it for us.
if (sample && control && typeof sample.stack === "string") {
return [sample.stack, control.stack];
}
}
return [null, null];
}
}; // $FlowFixMe[prop-missing]
RunInRootFrame.DetermineComponentFrameRoot.displayName =
"DetermineComponentFrameRoot";
var namePropDescriptor = Object.getOwnPropertyDescriptor(
RunInRootFrame.DetermineComponentFrameRoot,
"name"
); // Before ES6, the `name` property was not configurable.
if (namePropDescriptor && namePropDescriptor.configurable) {
// V8 utilizes a function's `name` property when generating a stack trace.
Object.defineProperty(
RunInRootFrame.DetermineComponentFrameRoot, // Configurable properties can be updated even if its writable descriptor
// is set to `false`.
// $FlowFixMe[cannot-write]
"name",
{
value: "DetermineComponentFrameRoot"
}
);
}
try {
var _RunInRootFrame$Deter =
RunInRootFrame.DetermineComponentFrameRoot(),
sampleStack = _RunInRootFrame$Deter[0],
controlStack = _RunInRootFrame$Deter[1];
if (sampleStack && controlStack) {
// This extracts the first frame from the sample that isn't also in the control.
// Skipping one frame that we assume is the frame that calls the two.
var sampleLines = sampleStack.split("\n");
var controlLines = controlStack.split("\n");
var s = 0;
var c = 0;
while (
s < sampleLines.length &&
!sampleLines[s].includes("DetermineComponentFrameRoot")
) {
s++;
}
while (
c < controlLines.length &&
!controlLines[c].includes("DetermineComponentFrameRoot")
) {
c++;
} // We couldn't find our intentionally injected common root frame, attempt
// to find another common root frame by search from the bottom of the
// control stack...
if (s === sampleLines.length || c === controlLines.length) {
s = sampleLines.length - 1;
c = controlLines.length - 1;
while (s >= 1 && c >= 0 && sampleLines[s] !== controlLines[c]) {
// We expect at least one stack frame to be shared.
// Typically this will be the root most one. However, stack frames may be
// cut off due to maximum stack limits. In this case, one maybe cut off
// earlier than the other. We assume that the sample is longer or the same
// and there for cut off earlier. So we should find the root most frame in
// the sample somewhere in the control.
c--;
}
}
for (; s >= 1 && c >= 0; s--, c--) {
// Next we find the first one that isn't the same which should be the
// frame that called our sample function and the control.
if (sampleLines[s] !== controlLines[c]) {
// In V8, the first line is describing the message but other VMs don't.
// If we're about to return the first line, and the control is also on the same
// line, that's a pretty good indicator that our sample threw at same line as
// the control. I.e. before we entered the sample frame. So we ignore this result.
// This can happen if you passed a class to function component, or non-function.
if (s !== 1 || c !== 1) {
do {
s--;
c--; // We may still have similar intermediate frames from the construct call.
// The next one that isn't the same should be our match though.
if (c < 0 || sampleLines[s] !== controlLines[c]) {
// V8 adds a "new" prefix for native classes. Let's remove it to make it prettier.
var _frame =
"\n" + sampleLines[s].replace(" at new ", " at "); // If our component frame is labeled "<anonymous>"
// but we have a user-provided "displayName"
// splice it in to make the stack more readable.
if (fn.displayName && _frame.includes("<anonymous>")) {
_frame = _frame.replace("<anonymous>", fn.displayName);
}
if (true) {
if (typeof fn === "function") {
componentFrameCache.set(fn, _frame);
}
} // Return the line we found.
return _frame;
}
} while (s >= 1 && c >= 0);
}
break;
}
}
}
} finally {
reentry = false;
{
ReactCurrentDispatcher.current = previousDispatcher;
reenableLogs();
}
Error.prepareStackTrace = previousPrepareStackTrace;
} // Fallback to just using the name if we couldn't make it throw.
var name = fn ? fn.displayName || fn.name : "";
var syntheticFrame = name ? describeBuiltInComponentFrame(name) : "";
{
if (typeof fn === "function") {
componentFrameCache.set(fn, syntheticFrame);
}
}
return syntheticFrame;
}
function describeFunctionComponentFrame(fn, ownerFn) {
{
return describeNativeComponentFrame(fn, false);
}
}
function shouldConstruct(Component) {
var prototype = Component.prototype;
return !!(prototype && prototype.isReactComponent);
}
function describeUnknownElementTypeFrameInDEV(type, ownerFn) {
if (type == null) {
return "";
}
if (typeof type === "function") {
{
return describeNativeComponentFrame(type, shouldConstruct(type));
}
}
if (typeof type === "string") {
return describeBuiltInComponentFrame(type);
}
switch (type) {
case REACT_SUSPENSE_TYPE:
return describeBuiltInComponentFrame("Suspense");
case REACT_SUSPENSE_LIST_TYPE:
return describeBuiltInComponentFrame("SuspenseList");
}
if (typeof type === "object") {
switch (type.$$typeof) {
case REACT_FORWARD_REF_TYPE:
return describeFunctionComponentFrame(type.render);
case REACT_MEMO_TYPE:
// Memo may contain any component type so we recursively resolve it.
return describeUnknownElementTypeFrameInDEV(type.type, ownerFn);
case REACT_LAZY_TYPE: {
var lazyComponent = type;
var payload = lazyComponent._payload;
var init = lazyComponent._init;
try {
// Lazy may contain any component type so we recursively resolve it.
return describeUnknownElementTypeFrameInDEV(
init(payload),
ownerFn
);
} catch (x) {}
}
}
}
return "";
}
var loggedTypeFailures = {};
var ReactDebugCurrentFrame$1 = ReactSharedInternals.ReactDebugCurrentFrame;
function setCurrentlyValidatingElement$2(element) {
{
if (element) {
var owner = element._owner;
var stack = describeUnknownElementTypeFrameInDEV(
element.type,
owner ? owner.type : null
);
ReactDebugCurrentFrame$1.setExtraStackFrame(stack);
} else {
ReactDebugCurrentFrame$1.setExtraStackFrame(null);
}
}
}
function checkPropTypes(
typeSpecs,
values,
location,
componentName,
element
) {
{
// $FlowFixMe[incompatible-use] This is okay but Flow doesn't know it.
var has = Function.call.bind(hasOwnProperty);
for (var typeSpecName in typeSpecs) {
if (has(typeSpecs, typeSpecName)) {
var error$1 = void 0; // Prop type validation may throw. In case they do, we don't want to
// fail the render phase where it didn't fail before. So we log it.
// After these have been cleaned up, we'll let them throw.
try {
// This is intentionally an invariant that gets caught. It's the same
// behavior as without this statement except with a better message.
if (typeof typeSpecs[typeSpecName] !== "function") {
// eslint-disable-next-line react-internal/prod-error-codes
var err = Error(
(componentName || "React class") +
": " +
location +
" type `" +
typeSpecName +
"` is invalid; " +
"it must be a function, usually from the `prop-types` package, but received `" +
typeof typeSpecs[typeSpecName] +
"`." +
"This often happens because of typos such as `PropTypes.function` instead of `PropTypes.func`."
);
err.name = "Invariant Violation";
throw err;
}
error$1 = typeSpecs[typeSpecName](
values,
typeSpecName,
componentName,
location,
null,
"SECRET_DO_NOT_PASS_THIS_OR_YOU_WILL_BE_FIRED"
);
} catch (ex) {
error$1 = ex;
}
if (error$1 && !(error$1 instanceof Error)) {
setCurrentlyValidatingElement$2(element);
error(
"%s: type specification of %s" +
" `%s` is invalid; the type checker " +
"function must return `null` or an `Error` but returned a %s. " +
"You may have forgotten to pass an argument to the type checker " +
"creator (arrayOf, instanceOf, objectOf, oneOf, oneOfType, and " +
"shape all require an argument).",
componentName || "React class",
location,
typeSpecName,
typeof error$1
);
setCurrentlyValidatingElement$2(null);
}
if (
error$1 instanceof Error &&
!(error$1.message in loggedTypeFailures)
) {
// Only monitor this failure once because there tends to be a lot of the
// same error.
loggedTypeFailures[error$1.message] = true;
setCurrentlyValidatingElement$2(element);
error("Failed %s type: %s", location, error$1.message);
setCurrentlyValidatingElement$2(null);
}
}
}
}
}
var REACT_CLIENT_REFERENCE$1 = Symbol.for("react.client.reference");
function setCurrentlyValidatingElement$1(element) {
{
if (element) {
var owner = element._owner;
var stack = describeUnknownElementTypeFrameInDEV(
element.type,
owner ? owner.type : null
);
setExtraStackFrame(stack);
} else {
setExtraStackFrame(null);
}
}
}
var propTypesMisspellWarningShown$1;
{
propTypesMisspellWarningShown$1 = false;
}
function getDeclarationErrorAddendum$1() {
if (ReactCurrentOwner$2.current) {
var name = getComponentNameFromType(ReactCurrentOwner$2.current.type);
if (name) {
return "\n\nCheck the render method of `" + name + "`.";
}
}
return "";
}
function getSourceInfoErrorAddendum$1(source) {
if (source !== undefined) {
var fileName = source.fileName.replace(/^.*[\\\/]/, "");
var lineNumber = source.lineNumber;
return "\n\nCheck your code at " + fileName + ":" + lineNumber + ".";
}
return "";
}
function getSourceInfoErrorAddendumForProps(elementProps) {
if (elementProps !== null && elementProps !== undefined) {
return getSourceInfoErrorAddendum$1(elementProps.__source);
}
return "";
}
/**
* Warn if there's no key explicitly set on dynamic arrays of children or
* object keys are not valid. This allows us to keep track of children between
* updates.
*/
var ownerHasKeyUseWarning$1 = {};
function getCurrentComponentErrorInfo$1(parentType) {
var info = getDeclarationErrorAddendum$1();
if (!info) {
var parentName = getComponentNameFromType(parentType);
if (parentName) {
info =
"\n\nCheck the top-level render call using <" + parentName + ">.";
}
}
return info;
}
/**
* Warn if the element doesn't have an explicit key assigned to it.
* This element is in an array. The array could grow and shrink or be
* reordered. All children that haven't already been validated are required to
* have a "key" property assigned to it. Error statuses are cached so a warning
* will only be shown once.
*
* @internal
* @param {ReactElement} element Element that requires a key.
* @param {*} parentType element's parent's type.
*/
function validateExplicitKey$1(element, parentType) {
if (!element._store || element._store.validated || element.key != null) {
return;
}
element._store.validated = true;
var currentComponentErrorInfo =
getCurrentComponentErrorInfo$1(parentType);
if (ownerHasKeyUseWarning$1[currentComponentErrorInfo]) {
return;
}
ownerHasKeyUseWarning$1[currentComponentErrorInfo] = true; // Usually the current owner is the offender, but if it accepts children as a
// property, it may be the creator of the child that's responsible for
// assigning it a key.
var childOwner = "";
if (
element &&
element._owner &&
element._owner !== ReactCurrentOwner$2.current
) {
// Give the component that originally created this child.
childOwner =
" It was passed a child from " +
getComponentNameFromType(element._owner.type) +
".";
}
{
setCurrentlyValidatingElement$1(element);
error(
'Each child in a list should have a unique "key" prop.' +
"%s%s See https://reactjs.org/link/warning-keys for more information.",
currentComponentErrorInfo,
childOwner
);
setCurrentlyValidatingElement$1(null);
}
}
/**
* Ensure that every element either is passed in a static location, in an
* array with an explicit keys property defined, or in an object literal
* with valid key property.
*
* @internal
* @param {ReactNode} node Statically passed child of any type.
* @param {*} parentType node's parent's type.
*/
function validateChildKeys$1(node, parentType) {
if (typeof node !== "object" || !node) {
return;
}
if (node.$$typeof === REACT_CLIENT_REFERENCE$1);
else if (isArray(node)) {
for (var i = 0; i < node.length; i++) {
var child = node[i];
if (isValidElement$1(child)) {
validateExplicitKey$1(child, parentType);
}
}
} else if (isValidElement$1(node)) {
// This element was passed in a valid location.
if (node._store) {
node._store.validated = true;
}
} else {
var iteratorFn = getIteratorFn(node);
if (typeof iteratorFn === "function") {
// Entry iterators used to provide implicit keys,
// but now we print a separate warning for them later.
if (iteratorFn !== node.entries) {
var iterator = iteratorFn.call(node);
var step;
while (!(step = iterator.next()).done) {
if (isValidElement$1(step.value)) {
validateExplicitKey$1(step.value, parentType);
}
}
}
}
}
}
/**
* Given an element, validate that its props follow the propTypes definition,
* provided by the type.
*
* @param {ReactElement} element
*/
function validatePropTypes$1(element) {
{
var type = element.type;
if (type === null || type === undefined || typeof type === "string") {
return;
}
if (type.$$typeof === REACT_CLIENT_REFERENCE$1) {
return;
}
var propTypes;
if (typeof type === "function") {
propTypes = type.propTypes;
} else if (
typeof type === "object" &&
(type.$$typeof === REACT_FORWARD_REF_TYPE || // Note: Memo only checks outer props here.
// Inner props are checked in the reconciler.
type.$$typeof === REACT_MEMO_TYPE)
) {
propTypes = type.propTypes;
} else {
return;
}
if (propTypes) {
// Intentionally inside to avoid triggering lazy initializers:
var name = getComponentNameFromType(type);
checkPropTypes(propTypes, element.props, "prop", name, element);
} else if (
type.PropTypes !== undefined &&
!propTypesMisspellWarningShown$1
) {
propTypesMisspellWarningShown$1 = true; // Intentionally inside to avoid triggering lazy initializers:
var _name = getComponentNameFromType(type);
error(
"Component %s declared `PropTypes` instead of `propTypes`. Did you misspell the property assignment?",
_name || "Unknown"
);
}
if (
typeof type.getDefaultProps === "function" &&
!type.getDefaultProps.isReactClassApproved
) {
error(
"getDefaultProps is only used on classic React.createClass " +
"definitions. Use a static property named `defaultProps` instead."
);
}
}
}
/**
* Given a fragment, validate that it can only be provided with fragment props
* @param {ReactElement} fragment
*/
function validateFragmentProps$1(fragment) {
{
var keys = Object.keys(fragment.props);
for (var i = 0; i < keys.length; i++) {
var key = keys[i];
if (key !== "children" && key !== "key") {
setCurrentlyValidatingElement$1(fragment);
error(
"Invalid prop `%s` supplied to `React.Fragment`. " +
"React.Fragment can only have `key` and `children` props.",
key
);
setCurrentlyValidatingElement$1(null);
break;
}
}
if (fragment.ref !== null) {
setCurrentlyValidatingElement$1(fragment);
error("Invalid attribute `ref` supplied to `React.Fragment`.");
setCurrentlyValidatingElement$1(null);
}
}
}
function createElementWithValidation(type, props, children) {
var validType = isValidElementType(type); // We warn in this case but don't throw. We expect the element creation to
// succeed and there will likely be errors in render.
if (!validType) {
var info = "";
if (
type === undefined ||
(typeof type === "object" &&
type !== null &&
Object.keys(type).length === 0)
) {
info +=
" You likely forgot to export your component from the file " +
"it's defined in, or you might have mixed up default and named imports.";
}
var sourceInfo = getSourceInfoErrorAddendumForProps(props);
if (sourceInfo) {
info += sourceInfo;
} else {
info += getDeclarationErrorAddendum$1();
}
var typeString;
if (type === null) {
typeString = "null";
} else if (isArray(type)) {
typeString = "array";
} else if (type !== undefined && type.$$typeof === REACT_ELEMENT_TYPE) {
typeString =
"<" + (getComponentNameFromType(type.type) || "Unknown") + " />";
info =
" Did you accidentally export a JSX literal instead of a component?";
} else {
typeString = typeof type;
}
{
error(
"React.createElement: type is invalid -- expected a string (for " +
"built-in components) or a class/function (for composite " +
"components) but got: %s.%s",
typeString,
info
);
}
}
var element = createElement$1.apply(this, arguments); // The result can be nullish if a mock or a custom function is used.
// TODO: Drop this when these are no longer allowed as the type argument.
if (element == null) {
return element;
} // Skip key warning if the type isn't valid since our key validation logic
// doesn't expect a non-string/function type and can throw confusing errors.
// We don't want exception behavior to differ between dev and prod.
// (Rendering will throw with a helpful message and as soon as the type is
// fixed, the key warnings will appear.)
if (validType) {
for (var i = 2; i < arguments.length; i++) {
validateChildKeys$1(arguments[i], type);
}
}
if (type === REACT_FRAGMENT_TYPE) {
validateFragmentProps$1(element);
} else {
validatePropTypes$1(element);
}
return element;
}
var didWarnAboutDeprecatedCreateFactory = false;
function createFactoryWithValidation(type) {
var validatedFactory = createElementWithValidation.bind(null, type);
validatedFactory.type = type;
{
if (!didWarnAboutDeprecatedCreateFactory) {
didWarnAboutDeprecatedCreateFactory = true;
warn(
"React.createFactory() is deprecated and will be removed in " +
"a future major release. Consider using JSX " +
"or use React.createElement() directly instead."
);
} // Legacy hook: remove it
Object.defineProperty(validatedFactory, "type", {
enumerable: false,
get: function () {
warn(
"Factory.type is deprecated. Access the class directly " +
"before passing it to createFactory."
);
Object.defineProperty(this, "type", {
value: type
});
return type;
}
});
}
return validatedFactory;
}
function cloneElementWithValidation(element, props, children) {
var newElement = cloneElement$1.apply(this, arguments);
for (var i = 2; i < arguments.length; i++) {
validateChildKeys$1(arguments[i], newElement.type);
}
validatePropTypes$1(newElement);
return newElement;
}
var createElement = createElementWithValidation;
var cloneElement = cloneElementWithValidation;
var createFactory = createFactoryWithValidation;
var SEPARATOR = ".";
var SUBSEPARATOR = ":";
/**
* Escape and wrap key so it is safe to use as a reactid
*
* @param {string} key to be escaped.
* @return {string} the escaped key.
*/
function escape(key) {
var escapeRegex = /[=:]/g;
var escaperLookup = {
"=": "=0",
":": "=2"
};
var escapedString = key.replace(escapeRegex, function (match) {
return escaperLookup[match];
});
return "$" + escapedString;
}
/**
* TODO: Test that a single child and an array with one item have the same key
* pattern.
*/
var didWarnAboutMaps = false;
var userProvidedKeyEscapeRegex = /\/+/g;
function escapeUserProvidedKey(text) {
return text.replace(userProvidedKeyEscapeRegex, "$&/");
}
/**
* Generate a key string that identifies a element within a set.
*
* @param {*} element A element that could contain a manual key.
* @param {number} index Index that is used if a manual key is not provided.
* @return {string}
*/
function getElementKey(element, index) {
// Do some typechecking here since we call this blindly. We want to ensure
// that we don't block potential future ES APIs.
if (
typeof element === "object" &&
element !== null &&
element.key != null
) {
// Explicit key
{
checkKeyStringCoercion(element.key);
}
return escape("" + element.key);
} // Implicit key determined by the index in the set
return index.toString(36);
}
function noop$1() {}
function resolveThenable(thenable) {
switch (thenable.status) {
case "fulfilled": {
var fulfilledValue = thenable.value;
return fulfilledValue;
}
case "rejected": {
var rejectedError = thenable.reason;
throw rejectedError;
}
default: {
if (typeof thenable.status === "string") {
// Only instrument the thenable if the status if not defined. If
// it's defined, but an unknown value, assume it's been instrumented by
// some custom userspace implementation. We treat it as "pending".
// Attach a dummy listener, to ensure that any lazy initialization can
// happen. Flight lazily parses JSON when the value is actually awaited.
thenable.then(noop$1, noop$1);
} else {
// This is an uncached thenable that we haven't seen before.
// TODO: Detect infinite ping loops caused by uncached promises.
var pendingThenable = thenable;
pendingThenable.status = "pending";
pendingThenable.then(
function (fulfilledValue) {
if (thenable.status === "pending") {
var fulfilledThenable = thenable;
fulfilledThenable.status = "fulfilled";
fulfilledThenable.value = fulfilledValue;
}
},
function (error) {
if (thenable.status === "pending") {
var rejectedThenable = thenable;
rejectedThenable.status = "rejected";
rejectedThenable.reason = error;
}
}
);
} // Check one more time in case the thenable resolved synchronously.
switch (thenable.status) {
case "fulfilled": {
var fulfilledThenable = thenable;
return fulfilledThenable.value;
}
case "rejected": {
var rejectedThenable = thenable;
var _rejectedError = rejectedThenable.reason;
throw _rejectedError;
}
}
}
}
throw thenable;
}
function mapIntoArray(children, array, escapedPrefix, nameSoFar, callback) {
var type = typeof children;
if (type === "undefined" || type === "boolean") {
// All of the above are perceived as null.
children = null;
}
var invokeCallback = false;
if (children === null) {
invokeCallback = true;
} else {
switch (type) {
case "string":
case "number":
invokeCallback = true;
break;
case "object":
switch (children.$$typeof) {
case REACT_ELEMENT_TYPE:
case REACT_PORTAL_TYPE:
invokeCallback = true;
break;
case REACT_LAZY_TYPE:
var payload = children._payload;
var init = children._init;
return mapIntoArray(
init(payload),
array,
escapedPrefix,
nameSoFar,
callback
);
}
}
}
if (invokeCallback) {
var _child = children;
var mappedChild = callback(_child); // If it's the only child, treat the name as if it was wrapped in an array
// so that it's consistent if the number of children grows:
var childKey =
nameSoFar === "" ? SEPARATOR + getElementKey(_child, 0) : nameSoFar;
if (isArray(mappedChild)) {
var escapedChildKey = "";
if (childKey != null) {
escapedChildKey = escapeUserProvidedKey(childKey) + "/";
}
mapIntoArray(mappedChild, array, escapedChildKey, "", function (c) {
return c;
});
} else if (mappedChild != null) {
if (isValidElement$1(mappedChild)) {
{
// The `if` statement here prevents auto-disabling of the safe
// coercion ESLint rule, so we must manually disable it below.
// $FlowFixMe[incompatible-type] Flow incorrectly thinks React.Portal doesn't have a key
if (
mappedChild.key &&
(!_child || _child.key !== mappedChild.key)
) {
checkKeyStringCoercion(mappedChild.key);
}
}
mappedChild = cloneAndReplaceKey(
mappedChild, // Keep both the (mapped) and old keys if they differ, just as
// traverseAllChildren used to do for objects as children
escapedPrefix + // $FlowFixMe[incompatible-type] Flow incorrectly thinks React.Portal doesn't have a key
(mappedChild.key && (!_child || _child.key !== mappedChild.key)
? escapeUserProvidedKey(
// $FlowFixMe[unsafe-addition]
"" + mappedChild.key // eslint-disable-line react-internal/safe-string-coercion
) + "/"
: "") +
childKey
);
}
array.push(mappedChild);
}
return 1;
}
var child;
var nextName;
var subtreeCount = 0; // Count of children found in the current subtree.
var nextNamePrefix =
nameSoFar === "" ? SEPARATOR : nameSoFar + SUBSEPARATOR;
if (isArray(children)) {
for (var i = 0; i < children.length; i++) {
child = children[i];
nextName = nextNamePrefix + getElementKey(child, i);
subtreeCount += mapIntoArray(
child,
array,
escapedPrefix,
nextName,
callback
);
}
} else {
var iteratorFn = getIteratorFn(children);
if (typeof iteratorFn === "function") {
var iterableChildren = children;
{
// Warn about using Maps as children
if (iteratorFn === iterableChildren.entries) {
if (!didWarnAboutMaps) {
warn(
"Using Maps as children is not supported. " +
"Use an array of keyed ReactElements instead."
);
}
didWarnAboutMaps = true;
}
}
var iterator = iteratorFn.call(iterableChildren);
var step;
var ii = 0; // $FlowFixMe[incompatible-use] `iteratorFn` might return null according to typing.
while (!(step = iterator.next()).done) {
child = step.value;
nextName = nextNamePrefix + getElementKey(child, ii++);
subtreeCount += mapIntoArray(
child,
array,
escapedPrefix,
nextName,
callback
);
}
} else if (type === "object") {
if (typeof children.then === "function") {
return mapIntoArray(
resolveThenable(children),
array,
escapedPrefix,
nameSoFar,
callback
);
} // eslint-disable-next-line react-internal/safe-string-coercion
var childrenString = String(children);
throw new Error(
"Objects are not valid as a React child (found: " +
(childrenString === "[object Object]"
? "object with keys {" + Object.keys(children).join(", ") + "}"
: childrenString) +
"). " +
"If you meant to render a collection of children, use an array " +
"instead."
);
}
}
return subtreeCount;
}
/**
* Maps children that are typically specified as `props.children`.
*
* See https://reactjs.org/docs/react-api.html#reactchildrenmap
*
* The provided mapFunction(child, index) will be called for each
* leaf child.
*
* @param {?*} children Children tree container.
* @param {function(*, int)} func The map function.
* @param {*} context Context for mapFunction.
* @return {object} Object containing the ordered map of results.
*/
function mapChildren(children, func, context) {
if (children == null) {
// $FlowFixMe limitation refining abstract types in Flow
return children;
}
var result = [];
var count = 0;
mapIntoArray(children, result, "", "", function (child) {
return func.call(context, child, count++);
});
return result;
}
/**
* Count the number of children that are typically specified as
* `props.children`.
*
* See https://reactjs.org/docs/react-api.html#reactchildrencount
*
* @param {?*} children Children tree container.
* @return {number} The number of children.
*/
function countChildren(children) {
var n = 0;
mapChildren(children, function () {
n++; // Don't return anything
});
return n;
}
/**
* Iterates through children that are typically specified as `props.children`.
*
* See https://reactjs.org/docs/react-api.html#reactchildrenforeach
*
* The provided forEachFunc(child, index) will be called for each
* leaf child.
*
* @param {?*} children Children tree container.
* @param {function(*, int)} forEachFunc
* @param {*} forEachContext Context for forEachContext.
*/
function forEachChildren(children, forEachFunc, forEachContext) {
mapChildren(
children, // $FlowFixMe[missing-this-annot]
function () {
forEachFunc.apply(this, arguments); // Don't return anything.
},
forEachContext
);
}
/**
* Flatten a children object (typically specified as `props.children`) and
* return an array with appropriately re-keyed children.
*
* See https://reactjs.org/docs/react-api.html#reactchildrentoarray
*/
function toArray(children) {
return (
mapChildren(children, function (child) {
return child;
}) || []
);
}
/**
* Returns the first child in a collection of children and verifies that there
* is only one child in the collection.
*
* See https://reactjs.org/docs/react-api.html#reactchildrenonly
*
* The current implementation of this function assumes that a single child gets
* passed without a wrapper, but the purpose of this helper function is to
* abstract away the particular structure of children.
*
* @param {?object} children Child collection structure.
* @return {ReactElement} The first and only `ReactElement` contained in the
* structure.
*/
function onlyChild(children) {
if (!isValidElement$1(children)) {
throw new Error(
"React.Children.only expected to receive a single React element child."
);
}
return children;
}
function createContext(defaultValue) {
// TODO: Second argument used to be an optional `calculateChangedBits`
// function. Warn to reserve for future use?
var context = {
$$typeof: REACT_CONTEXT_TYPE,
// As a workaround to support multiple concurrent renderers, we categorize
// some renderers as primary and others as secondary. We only expect
// there to be two concurrent renderers at most: React Native (primary) and
// Fabric (secondary); React DOM (primary) and React ART (secondary).
// Secondary renderers store their context values on separate fields.
_currentValue: defaultValue,
_currentValue2: defaultValue,
// Used to track how many concurrent renderers this context currently
// supports within in a single renderer. Such as parallel server rendering.
_threadCount: 0,
// These are circular
Provider: null,
Consumer: null
};
if (enableRenderableContext) {
context.Provider = context;
context.Consumer = {
$$typeof: REACT_CONSUMER_TYPE,
_context: context
};
} else {
context.Provider = {
$$typeof: REACT_PROVIDER_TYPE,
_context: context
};
{
var Consumer = {
$$typeof: REACT_CONTEXT_TYPE,
_context: context
};
Object.defineProperties(Consumer, {
Provider: {
get: function () {
return context.Provider;
},
set: function (_Provider) {
context.Provider = _Provider;
}
},
_currentValue: {
get: function () {
return context._currentValue;
},
set: function (_currentValue) {
context._currentValue = _currentValue;
}
},
_currentValue2: {
get: function () {
return context._currentValue2;
},
set: function (_currentValue2) {
context._currentValue2 = _currentValue2;
}
},
_threadCount: {
get: function () {
return context._threadCount;
},
set: function (_threadCount) {
context._threadCount = _threadCount;
}
},
Consumer: {
get: function () {
return context.Consumer;
}
},
displayName: {
get: function () {
return context.displayName;
},
set: function (displayName) {}
}
});
context.Consumer = Consumer;
}
}
{
context._currentRenderer = null;
context._currentRenderer2 = null;
}
return context;
}
var Uninitialized = -1;
var Pending = 0;
var Resolved = 1;
var Rejected = 2;
function lazyInitializer(payload) {
if (payload._status === Uninitialized) {
var ctor = payload._result;
var thenable = ctor(); // Transition to the next state.
// This might throw either because it's missing or throws. If so, we treat it
// as still uninitialized and try again next time. Which is the same as what
// happens if the ctor or any wrappers processing the ctor throws. This might
// end up fixing it if the resolution was a concurrency bug.
thenable.then(
function (moduleObject) {
if (
payload._status === Pending ||
payload._status === Uninitialized
) {
// Transition to the next state.
var resolved = payload;
resolved._status = Resolved;
resolved._result = moduleObject;
}
},
function (error) {
if (
payload._status === Pending ||
payload._status === Uninitialized
) {
// Transition to the next state.
var rejected = payload;
rejected._status = Rejected;
rejected._result = error;
}
}
);
if (payload._status === Uninitialized) {
// In case, we're still uninitialized, then we're waiting for the thenable
// to resolve. Set it as pending in the meantime.
var pending = payload;
pending._status = Pending;
pending._result = thenable;
}
}
if (payload._status === Resolved) {
var moduleObject = payload._result;
{
if (moduleObject === undefined) {
error(
"lazy: Expected the result of a dynamic imp" +
"ort() call. " +
"Instead received: %s\n\nYour code should look like: \n " + // Break up imports to avoid accidentally parsing them as dependencies.
"const MyComponent = lazy(() => imp" +
"ort('./MyComponent'))\n\n" +
"Did you accidentally put curly braces around the import?",
moduleObject
);
}
}
{
if (!("default" in moduleObject)) {
error(
"lazy: Expected the result of a dynamic imp" +
"ort() call. " +
"Instead received: %s\n\nYour code should look like: \n " + // Break up imports to avoid accidentally parsing them as dependencies.
"const MyComponent = lazy(() => imp" +
"ort('./MyComponent'))",
moduleObject
);
}
}
return moduleObject.default;
} else {
throw payload._result;
}
}
function lazy(ctor) {
var payload = {
// We use these fields to store the result.
_status: Uninitialized,
_result: ctor
};
var lazyType = {
$$typeof: REACT_LAZY_TYPE,
_payload: payload,
_init: lazyInitializer
};
{
// In production, this would just set it on the object.
var defaultProps;
var propTypes; // $FlowFixMe[prop-missing]
Object.defineProperties(lazyType, {
defaultProps: {
configurable: true,
get: function () {
return defaultProps;
},
// $FlowFixMe[missing-local-annot]
set: function (newDefaultProps) {
error(
"React.lazy(...): It is not supported to assign `defaultProps` to " +
"a lazy component import. Either specify them where the component " +
"is defined, or create a wrapping component around it."
);
defaultProps = newDefaultProps; // Match production behavior more closely:
// $FlowFixMe[prop-missing]
Object.defineProperty(lazyType, "defaultProps", {
enumerable: true
});
}
},
propTypes: {
configurable: true,
get: function () {
return propTypes;
},
// $FlowFixMe[missing-local-annot]
set: function (newPropTypes) {
error(
"React.lazy(...): It is not supported to assign `propTypes` to " +
"a lazy component import. Either specify them where the component " +
"is defined, or create a wrapping component around it."
);
propTypes = newPropTypes; // Match production behavior more closely:
// $FlowFixMe[prop-missing]
Object.defineProperty(lazyType, "propTypes", {
enumerable: true
});
}
}
});
}
return lazyType;
}
function forwardRef(render) {
{
if (render != null && render.$$typeof === REACT_MEMO_TYPE) {
error(
"forwardRef requires a render function but received a `memo` " +
"component. Instead of forwardRef(memo(...)), use " +
"memo(forwardRef(...))."
);
} else if (typeof render !== "function") {
error(
"forwardRef requires a render function but was given %s.",
render === null ? "null" : typeof render
);
} else {
if (render.length !== 0 && render.length !== 2) {
error(
"forwardRef render functions accept exactly two parameters: props and ref. %s",
render.length === 1
? "Did you forget to use the ref parameter?"
: "Any additional parameter will be undefined."
);
}
}
if (render != null) {
if (render.defaultProps != null) {
error(
"forwardRef render functions do not support defaultProps. " +
"Did you accidentally pass a React component?"
);
}
}
}
var elementType = {
$$typeof: REACT_FORWARD_REF_TYPE,
render: render
};
{
var ownName;
Object.defineProperty(elementType, "displayName", {
enumerable: false,
configurable: true,
get: function () {
return ownName;
},
set: function (name) {
ownName = name; // The inner component shouldn't inherit this display name in most cases,
// because the component may be used elsewhere.
// But it's nice for anonymous functions to inherit the name,
// so that our component-stack generation logic will display their frames.
// An anonymous function generally suggests a pattern like:
// React.forwardRef((props, ref) => {...});
// This kind of inner function is not used elsewhere so the side effect is okay.
if (!render.name && !render.displayName) {
render.displayName = name;
}
}
});
}
return elementType;
}
function memo(type, compare) {
{
if (!isValidElementType(type)) {
error(
"memo: The first argument must be a component. Instead " +
"received: %s",
type === null ? "null" : typeof type
);
}
}
var elementType = {
$$typeof: REACT_MEMO_TYPE,
type: type,
compare: compare === undefined ? null : compare
};
{
var ownName;
Object.defineProperty(elementType, "displayName", {
enumerable: false,
configurable: true,
get: function () {
return ownName;
},
set: function (name) {
ownName = name; // The inner component shouldn't inherit this display name in most cases,
// because the component may be used elsewhere.
// But it's nice for anonymous functions to inherit the name,
// so that our component-stack generation logic will display their frames.
// An anonymous function generally suggests a pattern like:
// React.memo((props) => {...});
// This kind of inner function is not used elsewhere so the side effect is okay.
if (!type.name && !type.displayName) {
type.displayName = name;
}
}
});
}
return elementType;
}
function noopCache(fn) {
// On the client (i.e. not a Server Components environment) `cache` has
// no caching behavior. We just return the function as-is.
//
// We intend to implement client caching in a future major release. In the
// meantime, it's only exposed as an API so that Shared Components can use
// per-request caching on the server without breaking on the client. But it
// does mean they need to be aware of the behavioral difference.
//
// The rest of the behavior is the same as the server implementation — it
// returns a new reference, extra properties like `displayName` are not
// preserved, the length of the new function is 0, etc. That way apps can't
// accidentally depend on those details.
return function () {
// $FlowFixMe[incompatible-call]: We don't want to use rest arguments since we transpile the code.
return fn.apply(null, arguments);
};
}
var cache = noopCache;
function resolveDispatcher() {
var dispatcher = ReactCurrentDispatcher$1.current;
{
if (dispatcher === null) {
error(
"Invalid hook call. Hooks can only be called inside of the body of a function component. This could happen for" +
" one of the following reasons:\n" +
"1. You might have mismatching versions of React and the renderer (such as React DOM)\n" +
"2. You might be breaking the Rules of Hooks\n" +
"3. You might have more than one copy of React in the same app\n" +
"See https://reactjs.org/link/invalid-hook-call for tips about how to debug and fix this problem."
);
}
} // Will result in a null access error if accessed outside render phase. We
// intentionally don't throw our own error because this is in a hot path.
// Also helps ensure this is inlined.
return dispatcher;
}
function getCacheSignal() {
var dispatcher = ReactCurrentCache.current;
if (!dispatcher) {
// If we have no cache to associate with this call, then we don't know
// its lifetime. We abort early since that's safer than letting it live
// for ever. Unlike just caching which can be a functional noop outside
// of React, these should generally always be associated with some React
// render but we're not limiting quite as much as making it a Hook.
// It's safer than erroring early at runtime.
var controller = new AbortController();
var reason = new Error(
"This CacheSignal was requested outside React which means that it is " +
"immediately aborted."
);
controller.abort(reason);
return controller.signal;
}
return dispatcher.getCacheSignal();
}
function getCacheForType(resourceType) {
var dispatcher = ReactCurrentCache.current;
if (!dispatcher) {
// If there is no dispatcher, then we treat this as not being cached.
return resourceType();
}
return dispatcher.getCacheForType(resourceType);
}
function useContext(Context) {
var dispatcher = resolveDispatcher();
{
if (Context.$$typeof === REACT_CONSUMER_TYPE) {
error(
"Calling useContext(Context.Consumer) is not supported and will cause bugs. " +
"Did you mean to call useContext(Context) instead?"
);
}
}
return dispatcher.useContext(Context);
}
function useState(initialState) {
var dispatcher = resolveDispatcher();
return dispatcher.useState(initialState);
}
function useReducer(reducer, initialArg, init) {
var dispatcher = resolveDispatcher();
return dispatcher.useReducer(reducer, initialArg, init);
}
function useRef(initialValue) {
var dispatcher = resolveDispatcher();
return dispatcher.useRef(initialValue);
}
function useEffect(create, deps) {
var dispatcher = resolveDispatcher();
return dispatcher.useEffect(create, deps);
}
function useInsertionEffect(create, deps) {
var dispatcher = resolveDispatcher();
return dispatcher.useInsertionEffect(create, deps);
}
function useLayoutEffect(create, deps) {
var dispatcher = resolveDispatcher();
return dispatcher.useLayoutEffect(create, deps);
}
function useCallback(callback, deps) {
var dispatcher = resolveDispatcher();
return dispatcher.useCallback(callback, deps);
}
function useMemo(create, deps) {
var dispatcher = resolveDispatcher();
return dispatcher.useMemo(create, deps);
}
function useImperativeHandle(ref, create, deps) {
var dispatcher = resolveDispatcher();
return dispatcher.useImperativeHandle(ref, create, deps);
}
function useDebugValue(value, formatterFn) {
{
var dispatcher = resolveDispatcher();
return dispatcher.useDebugValue(value, formatterFn);
}
}
function useTransition() {
var dispatcher = resolveDispatcher();
return dispatcher.useTransition();
}
function useDeferredValue(value, initialValue) {
var dispatcher = resolveDispatcher();
return dispatcher.useDeferredValue(value, initialValue);
}
function useId() {
var dispatcher = resolveDispatcher();
return dispatcher.useId();
}
function useSyncExternalStore(subscribe, getSnapshot, getServerSnapshot) {
var dispatcher = resolveDispatcher();
return dispatcher.useSyncExternalStore(
subscribe,
getSnapshot,
getServerSnapshot
);
}
function useCacheRefresh() {
var dispatcher = resolveDispatcher(); // $FlowFixMe[not-a-function] This is unstable, thus optional
return dispatcher.useCacheRefresh();
}
function use(usable) {
var dispatcher = resolveDispatcher();
return dispatcher.use(usable);
}
function useMemoCache(size) {
var dispatcher = resolveDispatcher(); // $FlowFixMe[not-a-function] This is unstable, thus optional
return dispatcher.useMemoCache(size);
}
function useEffectEvent(callback) {
var dispatcher = resolveDispatcher(); // $FlowFixMe[not-a-function] This is unstable, thus optional
return dispatcher.useEffectEvent(callback);
}
function useOptimistic(passthrough, reducer) {
var dispatcher = resolveDispatcher(); // $FlowFixMe[not-a-function] This is unstable, thus optional
return dispatcher.useOptimistic(passthrough, reducer);
}
function startTransition(scope, options) {
var prevTransition = ReactCurrentBatchConfig.transition; // Each renderer registers a callback to receive the return value of
// the scope function. This is used to implement async actions.
var callbacks = new Set();
var transition = {
_callbacks: callbacks
};
ReactCurrentBatchConfig.transition = transition;
var currentTransition = ReactCurrentBatchConfig.transition;
{
ReactCurrentBatchConfig.transition._updatedFibers = new Set();
}
if (enableTransitionTracing) {
if (options !== undefined && options.name !== undefined) {
// $FlowFixMe[incompatible-use] found when upgrading Flow
ReactCurrentBatchConfig.transition.name = options.name; // $FlowFixMe[incompatible-use] found when upgrading Flow
ReactCurrentBatchConfig.transition.startTime = -1;
}
}
{
try {
var returnValue = scope();
if (
typeof returnValue === "object" &&
returnValue !== null &&
typeof returnValue.then === "function"
) {
callbacks.forEach(function (callback) {
return callback(currentTransition, returnValue);
});
returnValue.then(noop, onError);
}
} catch (error) {
onError(error);
} finally {
warnAboutTransitionSubscriptions(prevTransition, currentTransition);
ReactCurrentBatchConfig.transition = prevTransition;
}
}
}
function warnAboutTransitionSubscriptions(
prevTransition,
currentTransition
) {
{
if (prevTransition === null && currentTransition._updatedFibers) {
var updatedFibersCount = currentTransition._updatedFibers.size;
currentTransition._updatedFibers.clear();
if (updatedFibersCount > 10) {
warn(
"Detected a large number of updates inside startTransition. " +
"If this is due to a subscription please re-write it to use React provided hooks. " +
"Otherwise concurrent mode guarantees are off the table."
);
}
}
}
}
function noop() {} // Use reportError, if it exists. Otherwise console.error. This is the same as
// the default for onRecoverableError.
var onError =
typeof reportError === "function" // In modern browsers, reportError will dispatch an error event,
? // emulating an uncaught JavaScript error.
reportError
: function (error) {
// In older browsers and test environments, fallback to console.error.
// eslint-disable-next-line react-internal/no-production-logging
console["error"](error);
};
var didWarnAboutMessageChannel = false;
var enqueueTaskImpl = null;
function enqueueTask(task) {
if (enqueueTaskImpl === null) {
try {
// read require off the module object to get around the bundlers.
// we don't want them to detect a require and bundle a Node polyfill.
var requireString = ("require" + Math.random()).slice(0, 7);
var nodeRequire = module && module[requireString]; // assuming we're in node, let's try to get node's
// version of setImmediate, bypassing fake timers if any.
enqueueTaskImpl = nodeRequire.call(module, "timers").setImmediate;
} catch (_err) {
// we're in a browser
// we can't use regular timers because they may still be faked
// so we try MessageChannel+postMessage instead
enqueueTaskImpl = function (callback) {
{
if (didWarnAboutMessageChannel === false) {
didWarnAboutMessageChannel = true;
if (typeof MessageChannel === "undefined") {
error(
"This browser does not have a MessageChannel implementation, " +
"so enqueuing tasks via await act(async () => ...) will fail. " +
"Please file an issue at https://github.com/facebook/react/issues " +
"if you encounter this warning."
);
}
}
}
var channel = new MessageChannel();
channel.port1.onmessage = callback;
channel.port2.postMessage(undefined);
};
}
}
return enqueueTaskImpl(task);
}
// number of `act` scopes on the stack.
var actScopeDepth = 0; // We only warn the first time you neglect to await an async `act` scope.
var didWarnNoAwaitAct = false;
function act(callback) {
{
// When ReactCurrentActQueue.current is not null, it signals to React that
// we're currently inside an `act` scope. React will push all its tasks to
// this queue instead of scheduling them with platform APIs.
//
// We set this to an empty array when we first enter an `act` scope, and
// only unset it once we've left the outermost `act` scope — remember that
// `act` calls can be nested.
//
// If we're already inside an `act` scope, reuse the existing queue.
var prevIsBatchingLegacy = ReactCurrentActQueue.isBatchingLegacy;
var prevActQueue = ReactCurrentActQueue.current;
var prevActScopeDepth = actScopeDepth;
actScopeDepth++;
var queue = (ReactCurrentActQueue.current =
prevActQueue !== null ? prevActQueue : []); // Used to reproduce behavior of `batchedUpdates` in legacy mode. Only
// set to `true` while the given callback is executed, not for updates
// triggered during an async event, because this is how the legacy
// implementation of `act` behaved.
ReactCurrentActQueue.isBatchingLegacy = true;
var result; // This tracks whether the `act` call is awaited. In certain cases, not
// awaiting it is a mistake, so we will detect that and warn.
var didAwaitActCall = false;
try {
// Reset this to `false` right before entering the React work loop. The
// only place we ever read this fields is just below, right after running
// the callback. So we don't need to reset after the callback runs.
ReactCurrentActQueue.didScheduleLegacyUpdate = false;
result = callback();
var didScheduleLegacyUpdate =
ReactCurrentActQueue.didScheduleLegacyUpdate; // Replicate behavior of original `act` implementation in legacy mode,
// which flushed updates immediately after the scope function exits, even
// if it's an async function.
if (!prevIsBatchingLegacy && didScheduleLegacyUpdate) {
flushActQueue(queue);
} // `isBatchingLegacy` gets reset using the regular stack, not the async
// one used to track `act` scopes. Why, you may be wondering? Because
// that's how it worked before version 18. Yes, it's confusing! We should
// delete legacy mode!!
ReactCurrentActQueue.isBatchingLegacy = prevIsBatchingLegacy;
} catch (error) {
// `isBatchingLegacy` gets reset using the regular stack, not the async
// one used to track `act` scopes. Why, you may be wondering? Because
// that's how it worked before version 18. Yes, it's confusing! We should
// delete legacy mode!!
ReactCurrentActQueue.isBatchingLegacy = prevIsBatchingLegacy;
popActScope(prevActQueue, prevActScopeDepth);
throw error;
}
if (
result !== null &&
typeof result === "object" && // $FlowFixMe[method-unbinding]
typeof result.then === "function"
) {
// A promise/thenable was returned from the callback. Wait for it to
// resolve before flushing the queue.
//
// If `act` were implemented as an async function, this whole block could
// be a single `await` call. That's really the only difference between
// this branch and the next one.
var thenable = result; // Warn if the an `act` call with an async scope is not awaited. In a
// future release, consider making this an error.
queueSeveralMicrotasks(function () {
if (!didAwaitActCall && !didWarnNoAwaitAct) {
didWarnNoAwaitAct = true;
error(
"You called act(async () => ...) without await. " +
"This could lead to unexpected testing behaviour, " +
"interleaving multiple act calls and mixing their " +
"scopes. " +
"You should - await act(async () => ...);"
);
}
});
return {
then: function (resolve, reject) {
didAwaitActCall = true;
thenable.then(
function (returnValue) {
popActScope(prevActQueue, prevActScopeDepth);
if (prevActScopeDepth === 0) {
// We're exiting the outermost `act` scope. Flush the queue.
try {
flushActQueue(queue);
enqueueTask(function () {
return (
// Recursively flush tasks scheduled by a microtask.
recursivelyFlushAsyncActWork(
returnValue,
resolve,
reject
)
);
});
} catch (error) {
// `thenable` might not be a real promise, and `flushActQueue`
// might throw, so we need to wrap `flushActQueue` in a
// try/catch.
reject(error);
}
} else {
resolve(returnValue);
}
},
function (error) {
popActScope(prevActQueue, prevActScopeDepth);
reject(error);
}
);
}
};
} else {
var returnValue = result; // The callback is not an async function. Exit the current
// scope immediately.
popActScope(prevActQueue, prevActScopeDepth);
if (prevActScopeDepth === 0) {
// We're exiting the outermost `act` scope. Flush the queue.
flushActQueue(queue); // If the queue is not empty, it implies that we intentionally yielded
// to the main thread, because something suspended. We will continue
// in an asynchronous task.
//
// Warn if something suspends but the `act` call is not awaited.
// In a future release, consider making this an error.
if (queue.length !== 0) {
queueSeveralMicrotasks(function () {
if (!didAwaitActCall && !didWarnNoAwaitAct) {
didWarnNoAwaitAct = true;
error(
"A component suspended inside an `act` scope, but the " +
"`act` call was not awaited. When testing React " +
"components that depend on asynchronous data, you must " +
"await the result:\n\n" +
"await act(() => ...)"
);
}
});
} // Like many things in this module, this is next part is confusing.
//
// We do not currently require every `act` call that is passed a
// callback to be awaited, through arguably we should. Since this
// callback was synchronous, we need to exit the current scope before
// returning.
//
// However, if thenable we're about to return *is* awaited, we'll
// immediately restore the current scope. So it shouldn't observable.
//
// This doesn't affect the case where the scope callback is async,
// because we always require those calls to be awaited.
//
// TODO: In a future version, consider always requiring all `act` calls
// to be awaited, regardless of whether the callback is sync or async.
ReactCurrentActQueue.current = null;
}
return {
then: function (resolve, reject) {
didAwaitActCall = true;
if (prevActScopeDepth === 0) {
// If the `act` call is awaited, restore the queue we were
// using before (see long comment above) so we can flush it.
ReactCurrentActQueue.current = queue;
enqueueTask(function () {
return (
// Recursively flush tasks scheduled by a microtask.
recursivelyFlushAsyncActWork(returnValue, resolve, reject)
);
});
} else {
resolve(returnValue);
}
}
};
}
}
}
function popActScope(prevActQueue, prevActScopeDepth) {
{
if (prevActScopeDepth !== actScopeDepth - 1) {
error(
"You seem to have overlapping act() calls, this is not supported. " +
"Be sure to await previous act() calls before making a new one. "
);
}
actScopeDepth = prevActScopeDepth;
}
}
function recursivelyFlushAsyncActWork(returnValue, resolve, reject) {
{
// Check if any tasks were scheduled asynchronously.
var queue = ReactCurrentActQueue.current;
if (queue !== null) {
if (queue.length !== 0) {
// Async tasks were scheduled, mostly likely in a microtask.
// Keep flushing until there are no more.
try {
flushActQueue(queue); // The work we just performed may have schedule additional async
// tasks. Wait a macrotask and check again.
enqueueTask(function () {
return recursivelyFlushAsyncActWork(
returnValue,
resolve,
reject
);
});
} catch (error) {
// Leave remaining tasks on the queue if something throws.
reject(error);
}
} else {
// The queue is empty. We can finish.
ReactCurrentActQueue.current = null;
resolve(returnValue);
}
} else {
resolve(returnValue);
}
}
}
var isFlushing = false;
function flushActQueue(queue) {
{
if (!isFlushing) {
// Prevent re-entrance.
isFlushing = true;
var i = 0;
try {
for (; i < queue.length; i++) {
var callback = queue[i];
do {
ReactCurrentActQueue.didUsePromise = false;
var continuation = callback(false);
if (continuation !== null) {
if (ReactCurrentActQueue.didUsePromise) {
// The component just suspended. Yield to the main thread in
// case the promise is already resolved. If so, it will ping in
// a microtask and we can resume without unwinding the stack.
queue[i] = callback;
queue.splice(0, i);
return;
}
callback = continuation;
} else {
break;
}
} while (true);
} // We flushed the entire queue.
queue.length = 0;
} catch (error) {
// If something throws, leave the remaining callbacks on the queue.
queue.splice(0, i + 1);
throw error;
} finally {
isFlushing = false;
}
}
}
} // Some of our warnings attempt to detect if the `act` call is awaited by
// checking in an asynchronous task. Wait a few microtasks before checking. The
// only reason one isn't sufficient is we want to accommodate the case where an
// `act` call is returned from an async function without first being awaited,
// since that's a somewhat common pattern. If you do this too many times in a
// nested sequence, you might get a warning, but you can always fix by awaiting
// the call.
//
// A macrotask would also work (and is the fallback) but depending on the test
// environment it may cause the warning to fire too late.
var queueSeveralMicrotasks =
typeof queueMicrotask === "function"
? function (callback) {
queueMicrotask(function () {
return queueMicrotask(callback);
});
}
: enqueueTask;
var Children = {
map: mapChildren,
forEach: forEachChildren,
count: countChildren,
toArray: toArray,
only: onlyChild
};
var ReactCurrentOwner$1 = ReactSharedInternals.ReactCurrentOwner;
var specialPropKeyWarningShown;
var specialPropRefWarningShown;
var didWarnAboutStringRefs;
{
didWarnAboutStringRefs = {};
}
function hasValidRef(config) {
{
if (hasOwnProperty.call(config, "ref")) {
var getter = Object.getOwnPropertyDescriptor(config, "ref").get;
if (getter && getter.isReactWarning) {
return false;
}
}
}
return config.ref !== undefined;
}
function hasValidKey(config) {
{
if (hasOwnProperty.call(config, "key")) {
var getter = Object.getOwnPropertyDescriptor(config, "key").get;
if (getter && getter.isReactWarning) {
return false;
}
}
}
return config.key !== undefined;
}
function warnIfStringRefCannotBeAutoConverted(config, self) {
{
if (
typeof config.ref === "string" &&
ReactCurrentOwner$1.current &&
self &&
ReactCurrentOwner$1.current.stateNode !== self
) {
var componentName = getComponentNameFromType(
ReactCurrentOwner$1.current.type
);
if (!didWarnAboutStringRefs[componentName]) {
error(
'Component "%s" contains the string ref "%s". ' +
"Support for string refs will be removed in a future major release. " +
"This case cannot be automatically converted to an arrow function. " +
"We ask you to manually fix this case by using useRef() or createRef() instead. " +
"Learn more about using refs safely here: " +
"https://reactjs.org/link/strict-mode-string-ref",
getComponentNameFromType(ReactCurrentOwner$1.current.type),
config.ref
);
didWarnAboutStringRefs[componentName] = true;
}
}
}
}
function defineKeyPropWarningGetter(props, displayName) {
{
var warnAboutAccessingKey = function () {
if (!specialPropKeyWarningShown) {
specialPropKeyWarningShown = true;
error(
"%s: `key` is not a prop. Trying to access it will result " +
"in `undefined` being returned. If you need to access the same " +
"value within the child component, you should pass it as a different " +
"prop. (https://reactjs.org/link/special-props)",
displayName
);
}
};
warnAboutAccessingKey.isReactWarning = true;
Object.defineProperty(props, "key", {
get: warnAboutAccessingKey,
configurable: true
});
}
}
function defineRefPropWarningGetter(props, displayName) {
{
var warnAboutAccessingRef = function () {
if (!specialPropRefWarningShown) {
specialPropRefWarningShown = true;
error(
"%s: `ref` is not a prop. Trying to access it will result " +
"in `undefined` being returned. If you need to access the same " +
"value within the child component, you should pass it as a different " +
"prop. (https://reactjs.org/link/special-props)",
displayName
);
}
};
warnAboutAccessingRef.isReactWarning = true;
Object.defineProperty(props, "ref", {
get: warnAboutAccessingRef,
configurable: true
});
}
}
/**
* Factory method to create a new React element. This no longer adheres to
* the class pattern, so do not use new to call it. Also, instanceof check
* will not work. Instead test $$typeof field against Symbol.for('react.element') to check
* if something is a React Element.
*
* @param {*} type
* @param {*} props
* @param {*} key
* @param {string|object} ref
* @param {*} owner
* @param {*} self A *temporary* helper to detect places where `this` is
* different from the `owner` when React.createElement is called, so that we
* can warn. We want to get rid of owner and replace string `ref`s with arrow
* functions, and as long as `this` and owner are the same, there will be no
* change in behavior.
* @param {*} source An annotation object (added by a transpiler or otherwise)
* indicating filename, line number, and/or other information.
* @internal
*/
function ReactElement(type, key, ref, self, source, owner, props) {
var element = {
// This tag allows us to uniquely identify this as a React Element
$$typeof: REACT_ELEMENT_TYPE,
// Built-in properties that belong on the element
type: type,
key: key,
ref: ref,
props: props,
// Record the component responsible for creating this element.
_owner: owner
};
{
// The validation flag is currently mutative. We put it on
// an external backing store so that we can freeze the whole object.
// This can be replaced with a WeakMap once they are implemented in
// commonly used development environments.
element._store = {}; // To make comparing ReactElements easier for testing purposes, we make
// the validation flag non-enumerable (where possible, which should
// include every environment we run tests in), so the test framework
// ignores it.
Object.defineProperty(element._store, "validated", {
configurable: false,
enumerable: false,
writable: true,
value: false
}); // debugInfo contains Server Component debug information.
Object.defineProperty(element, "_debugInfo", {
configurable: false,
enumerable: false,
writable: true,
value: null
});
if (Object.freeze) {
Object.freeze(element.props);
Object.freeze(element);
}
}
return element;
}
/**
* https://github.com/reactjs/rfcs/pull/107
* @param {*} type
* @param {object} props
* @param {string} key
*/
function jsxDEV$1(type, config, maybeKey, source, self) {
{
var propName; // Reserved names are extracted
var props = {};
var key = null;
var ref = null; // Currently, key can be spread in as a prop. This causes a potential
// issue if key is also explicitly declared (ie. <div {...props} key="Hi" />
// or <div key="Hi" {...props} /> ). We want to deprecate key spread,
// but as an intermediary step, we will use jsxDEV for everything except
// <div {...props} key="Hi" />, because we aren't currently able to tell if
// key is explicitly declared to be undefined or not.
if (maybeKey !== undefined) {
{
checkKeyStringCoercion(maybeKey);
}
key = "" + maybeKey;
}
if (hasValidKey(config)) {
{
checkKeyStringCoercion(config.key);
}
key = "" + config.key;
}
if (hasValidRef(config)) {
ref = config.ref;
warnIfStringRefCannotBeAutoConverted(config, self);
} // Remaining properties are added to a new props object
for (propName in config) {
if (
hasOwnProperty.call(config, propName) && // Skip over reserved prop names
propName !== "key" && // TODO: `ref` will no longer be reserved in the next major
propName !== "ref"
) {
props[propName] = config[propName];
}
} // Resolve default props
if (type && type.defaultProps) {
var defaultProps = type.defaultProps;
for (propName in defaultProps) {
if (props[propName] === undefined) {
props[propName] = defaultProps[propName];
}
}
}
if (key || ref) {
var displayName =
typeof type === "function"
? type.displayName || type.name || "Unknown"
: type;
if (key) {
defineKeyPropWarningGetter(props, displayName);
}
if (ref) {
defineRefPropWarningGetter(props, displayName);
}
}
return ReactElement(
type,
key,
ref,
self,
source,
ReactCurrentOwner$1.current,
props
);
}
}
var ReactCurrentOwner = ReactSharedInternals.ReactCurrentOwner;
var ReactDebugCurrentFrame = ReactSharedInternals.ReactDebugCurrentFrame;
var REACT_CLIENT_REFERENCE = Symbol.for("react.client.reference");
function setCurrentlyValidatingElement(element) {
{
if (element) {
var owner = element._owner;
var stack = describeUnknownElementTypeFrameInDEV(
element.type,
owner ? owner.type : null
);
ReactDebugCurrentFrame.setExtraStackFrame(stack);
} else {
ReactDebugCurrentFrame.setExtraStackFrame(null);
}
}
}
var propTypesMisspellWarningShown;
{
propTypesMisspellWarningShown = false;
}
/**
* Verifies the object is a ReactElement.
* See https://reactjs.org/docs/react-api.html#isvalidelement
* @param {?object} object
* @return {boolean} True if `object` is a ReactElement.
* @final
*/
function isValidElement(object) {
{
return (
typeof object === "object" &&
object !== null &&
object.$$typeof === REACT_ELEMENT_TYPE
);
}
}
function getDeclarationErrorAddendum() {
{
if (ReactCurrentOwner.current) {
var name = getComponentNameFromType(ReactCurrentOwner.current.type);
if (name) {
return "\n\nCheck the render method of `" + name + "`.";
}
}
return "";
}
}
function getSourceInfoErrorAddendum(source) {
{
if (source !== undefined) {
var fileName = source.fileName.replace(/^.*[\\\/]/, "");
var lineNumber = source.lineNumber;
return "\n\nCheck your code at " + fileName + ":" + lineNumber + ".";
}
return "";
}
}
/**
* Warn if there's no key explicitly set on dynamic arrays of children or
* object keys are not valid. This allows us to keep track of children between
* updates.
*/
var ownerHasKeyUseWarning = {};
function getCurrentComponentErrorInfo(parentType) {
{
var info = getDeclarationErrorAddendum();
if (!info) {
var parentName = getComponentNameFromType(parentType);
if (parentName) {
info =
"\n\nCheck the top-level render call using <" + parentName + ">.";
}
}
return info;
}
}
/**
* Warn if the element doesn't have an explicit key assigned to it.
* This element is in an array. The array could grow and shrink or be
* reordered. All children that haven't already been validated are required to
* have a "key" property assigned to it. Error statuses are cached so a warning
* will only be shown once.
*
* @internal
* @param {ReactElement} element Element that requires a key.
* @param {*} parentType element's parent's type.
*/
function validateExplicitKey(element, parentType) {
{
if (
!element._store ||
element._store.validated ||
element.key != null
) {
return;
}
element._store.validated = true;
var currentComponentErrorInfo =
getCurrentComponentErrorInfo(parentType);
if (ownerHasKeyUseWarning[currentComponentErrorInfo]) {
return;
}
ownerHasKeyUseWarning[currentComponentErrorInfo] = true; // Usually the current owner is the offender, but if it accepts children as a
// property, it may be the creator of the child that's responsible for
// assigning it a key.
var childOwner = "";
if (
element &&
element._owner &&
element._owner !== ReactCurrentOwner.current
) {
// Give the component that originally created this child.
childOwner =
" It was passed a child from " +
getComponentNameFromType(element._owner.type) +
".";
}
setCurrentlyValidatingElement(element);
error(
'Each child in a list should have a unique "key" prop.' +
"%s%s See https://reactjs.org/link/warning-keys for more information.",
currentComponentErrorInfo,
childOwner
);
setCurrentlyValidatingElement(null);
}
}
/**
* Ensure that every element either is passed in a static location, in an
* array with an explicit keys property defined, or in an object literal
* with valid key property.
*
* @internal
* @param {ReactNode} node Statically passed child of any type.
* @param {*} parentType node's parent's type.
*/
function validateChildKeys(node, parentType) {
{
if (typeof node !== "object" || !node) {
return;
}
if (node.$$typeof === REACT_CLIENT_REFERENCE);
else if (isArray(node)) {
for (var i = 0; i < node.length; i++) {
var child = node[i];
if (isValidElement(child)) {
validateExplicitKey(child, parentType);
}
}
} else if (isValidElement(node)) {
// This element was passed in a valid location.
if (node._store) {
node._store.validated = true;
}
} else {
var iteratorFn = getIteratorFn(node);
if (typeof iteratorFn === "function") {
// Entry iterators used to provide implicit keys,
// but now we print a separate warning for them later.
if (iteratorFn !== node.entries) {
var iterator = iteratorFn.call(node);
var step;
while (!(step = iterator.next()).done) {
if (isValidElement(step.value)) {
validateExplicitKey(step.value, parentType);
}
}
}
}
}
}
}
/**
* Given an element, validate that its props follow the propTypes definition,
* provided by the type.
*
* @param {ReactElement} element
*/
function validatePropTypes(element) {
{
var type = element.type;
if (type === null || type === undefined || typeof type === "string") {
return;
}
if (type.$$typeof === REACT_CLIENT_REFERENCE) {
return;
}
var propTypes;
if (typeof type === "function") {
propTypes = type.propTypes;
} else if (
typeof type === "object" &&
(type.$$typeof === REACT_FORWARD_REF_TYPE || // Note: Memo only checks outer props here.
// Inner props are checked in the reconciler.
type.$$typeof === REACT_MEMO_TYPE)
) {
propTypes = type.propTypes;
} else {
return;
}
if (propTypes) {
// Intentionally inside to avoid triggering lazy initializers:
var name = getComponentNameFromType(type);
checkPropTypes(propTypes, element.props, "prop", name, element);
} else if (
type.PropTypes !== undefined &&
!propTypesMisspellWarningShown
) {
propTypesMisspellWarningShown = true; // Intentionally inside to avoid triggering lazy initializers:
var _name = getComponentNameFromType(type);
error(
"Component %s declared `PropTypes` instead of `propTypes`. Did you misspell the property assignment?",
_name || "Unknown"
);
}
if (
typeof type.getDefaultProps === "function" &&
!type.getDefaultProps.isReactClassApproved
) {
error(
"getDefaultProps is only used on classic React.createClass " +
"definitions. Use a static property named `defaultProps` instead."
);
}
}
}
/**
* Given a fragment, validate that it can only be provided with fragment props
* @param {ReactElement} fragment
*/
function validateFragmentProps(fragment) {
{
var keys = Object.keys(fragment.props);
for (var i = 0; i < keys.length; i++) {
var key = keys[i];
if (key !== "children" && key !== "key") {
setCurrentlyValidatingElement(fragment);
error(
"Invalid prop `%s` supplied to `React.Fragment`. " +
"React.Fragment can only have `key` and `children` props.",
key
);
setCurrentlyValidatingElement(null);
break;
}
}
if (fragment.ref !== null) {
setCurrentlyValidatingElement(fragment);
error("Invalid attribute `ref` supplied to `React.Fragment`.");
setCurrentlyValidatingElement(null);
}
}
}
var didWarnAboutKeySpread = {};
function jsxWithValidation(
type,
props,
key,
isStaticChildren,
source,
self
) {
{
var validType = isValidElementType(type); // We warn in this case but don't throw. We expect the element creation to
// succeed and there will likely be errors in render.
if (!validType) {
var info = "";
if (
type === undefined ||
(typeof type === "object" &&
type !== null &&
Object.keys(type).length === 0)
) {
info +=
" You likely forgot to export your component from the file " +
"it's defined in, or you might have mixed up default and named imports.";
}
var sourceInfo = getSourceInfoErrorAddendum(source);
if (sourceInfo) {
info += sourceInfo;
} else {
info += getDeclarationErrorAddendum();
}
var typeString;
if (type === null) {
typeString = "null";
} else if (isArray(type)) {
typeString = "array";
} else if (
type !== undefined &&
type.$$typeof === REACT_ELEMENT_TYPE
) {
typeString =
"<" + (getComponentNameFromType(type.type) || "Unknown") + " />";
info =
" Did you accidentally export a JSX literal instead of a component?";
} else {
typeString = typeof type;
}
error(
"React.jsx: type is invalid -- expected a string (for " +
"built-in components) or a class/function (for composite " +
"components) but got: %s.%s",
typeString,
info
);
}
var element = jsxDEV$1(type, props, key, source, self); // The result can be nullish if a mock or a custom function is used.
// TODO: Drop this when these are no longer allowed as the type argument.
if (element == null) {
return element;
} // Skip key warning if the type isn't valid since our key validation logic
// doesn't expect a non-string/function type and can throw confusing errors.
// We don't want exception behavior to differ between dev and prod.
// (Rendering will throw with a helpful message and as soon as the type is
// fixed, the key warnings will appear.)
if (validType) {
var children = props.children;
if (children !== undefined) {
if (isStaticChildren) {
if (isArray(children)) {
for (var i = 0; i < children.length; i++) {
validateChildKeys(children[i], type);
}
if (Object.freeze) {
Object.freeze(children);
}
} else {
error(
"React.jsx: Static children should always be an array. " +
"You are likely explicitly calling React.jsxs or React.jsxDEV. " +
"Use the Babel transform instead."
);
}
} else {
validateChildKeys(children, type);
}
}
}
if (hasOwnProperty.call(props, "key")) {
var componentName = getComponentNameFromType(type);
var keys = Object.keys(props).filter(function (k) {
return k !== "key";
});
var beforeExample =
keys.length > 0
? "{key: someKey, " + keys.join(": ..., ") + ": ...}"
: "{key: someKey}";
if (!didWarnAboutKeySpread[componentName + beforeExample]) {
var afterExample =
keys.length > 0 ? "{" + keys.join(": ..., ") + ": ...}" : "{}";
error(
'A props object containing a "key" prop is being spread into JSX:\n' +
" let props = %s;\n" +
" <%s {...props} />\n" +
"React keys must be passed directly to JSX without using spread:\n" +
" let props = %s;\n" +
" <%s key={someKey} {...props} />",
beforeExample,
componentName,
afterExample,
componentName
);
didWarnAboutKeySpread[componentName + beforeExample] = true;
}
}
if (type === REACT_FRAGMENT_TYPE) {
validateFragmentProps(element);
} else {
validatePropTypes(element);
}
return element;
}
} // These two functions exist to still get child warnings in dev
// even with the prod transform. This means that jsxDEV is purely
// opt-in behavior for better messages but that we won't stop
// giving you warnings if you use production apis.
function jsxWithValidationStatic(type, props, key) {
{
return jsxWithValidation(type, props, key, true);
}
}
function jsxWithValidationDynamic(type, props, key) {
{
return jsxWithValidation(type, props, key, false);
}
}
var jsx = jsxWithValidationDynamic; // we may want to special case jsxs internally to take advantage of static children.
// for now we can ship identical prod functions
var jsxs = jsxWithValidationStatic;
var jsxDEV = jsxWithValidation;
exports.Children = Children;
exports.Component = Component;
exports.Fragment = REACT_FRAGMENT_TYPE;
exports.Profiler = REACT_PROFILER_TYPE;
exports.PureComponent = PureComponent;
exports.StrictMode = REACT_STRICT_MODE_TYPE;
exports.Suspense = REACT_SUSPENSE_TYPE;
exports.__SECRET_INTERNALS_DO_NOT_USE_OR_YOU_WILL_BE_FIRED =
ReactSharedInternals;
exports.act = act;
exports.cache = cache;
exports.cloneElement = cloneElement;
exports.createContext = createContext;
exports.createElement = createElement;
exports.createFactory = createFactory;
exports.createRef = createRef;
exports.experimental_useEffectEvent = useEffectEvent;
exports.forwardRef = forwardRef;
exports.isValidElement = isValidElement$1;
exports.jsx = jsx;
exports.jsxDEV = jsxDEV;
exports.jsxs = jsxs;
exports.lazy = lazy;
exports.memo = memo;
exports.startTransition = startTransition;
exports.unstable_Activity = REACT_OFFSCREEN_TYPE;
exports.unstable_Cache = REACT_CACHE_TYPE;
exports.unstable_DebugTracingMode = REACT_DEBUG_TRACING_MODE_TYPE;
exports.unstable_LegacyHidden = REACT_LEGACY_HIDDEN_TYPE;
exports.unstable_Scope = REACT_SCOPE_TYPE;
exports.unstable_SuspenseList = REACT_SUSPENSE_LIST_TYPE;
exports.unstable_TracingMarker = REACT_TRACING_MARKER_TYPE;
exports.unstable_getCacheForType = getCacheForType;
exports.unstable_getCacheSignal = getCacheSignal;
exports.unstable_useCacheRefresh = useCacheRefresh;
exports.unstable_useMemoCache = useMemoCache;
exports.use = use;
exports.useCallback = useCallback;
exports.useContext = useContext;
exports.useDebugValue = useDebugValue;
exports.useDeferredValue = useDeferredValue;
exports.useEffect = useEffect;
exports.useId = useId;
exports.useImperativeHandle = useImperativeHandle;
exports.useInsertionEffect = useInsertionEffect;
exports.useLayoutEffect = useLayoutEffect;
exports.useMemo = useMemo;
exports.useOptimistic = useOptimistic;
exports.useReducer = useReducer;
exports.useRef = useRef;
exports.useState = useState;
exports.useSyncExternalStore = useSyncExternalStore;
exports.useTransition = useTransition;
exports.version = ReactVersion;
/* global __REACT_DEVTOOLS_GLOBAL_HOOK__ */
if (
typeof __REACT_DEVTOOLS_GLOBAL_HOOK__ !== "undefined" &&
typeof __REACT_DEVTOOLS_GLOBAL_HOOK__.registerInternalModuleStop ===
"function"
) {
__REACT_DEVTOOLS_GLOBAL_HOOK__.registerInternalModuleStop(new Error());
}
})();
}
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