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Spracherkennung für: .mjs vermutete Sprache: Unknown {[0] [0] [0]} [Methode: Schwerpunktbildung, einfache Gewichte, sechs Dimensionen] /**
* @license * Copyright 2019 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ const NODE_MODE$1 = false; const global$2 = window; /** * Whether the current browser supports `adoptedStyleSheets`. */ const supportsAdoptingStyleSheets = global$2.ShadowRoot && (global$2.ShadyCSS === undefined || global$2.ShadyCSS.nativeShadow) && 'adoptedStyleSheets' in Document.prototype && 'replace' in CSSStyleSheet.prototype; const constructionToken = Symbol(); const cssTagCache = new WeakMap(); /** * A container for a string of CSS text, that may be used to create a CSSStyleSheet. * * CSSResult is the return value of `css`-tagged template literals and * `unsafeCSS()`. In order to ensure that CSSResults are only created via the * `css` tag and `unsafeCSS()`, CSSResult cannot be constructed directly. */ class CSSResult { constructor(cssText, strings, safeToken) { // This property needs to remain unminified. this['_$cssResult$'] = true; if (safeToken !== constructionToken) { throw new Error('CSSResult is not constructable. Use `unsafeCSS` or `css` instead.'); } this.cssText = cssText; this._strings = strings; } // This is a getter so that it's lazy. In practice, this means stylesheets // are not created until the first element instance is made. get styleSheet() { // If `supportsAdoptingStyleSheets` is true then we assume CSSStyleSheet is // constructable. let styleSheet = this._styleSheet; const strings = this._strings; if (supportsAdoptingStyleSheets && styleSheet === undefined) { const cacheable = strings !== undefined && strings.length === 1; if (cacheable) { styleSheet = cssTagCache.get(strings); } if (styleSheet === undefined) { (this._styleSheet = styleSheet = new CSSStyleSheet()).replaceSync(this.cssText); if (cacheable) { cssTagCache.set(strings, styleSheet); } } } return styleSheet; } toString() { return this.cssText; } } const textFromCSSResult = (value) => { // This property needs to remain unminified. if (value['_$cssResult$'] === true) { return value.cssText; } else if (typeof value === 'number') { return value; } else { throw new Error(`Value passed to 'css' function must be a 'css' function result: ` + `${value}. Use 'unsafeCSS' to pass non-literal values, but take care ` + `to ensure page security.`); } }; /** * Wrap a value for interpolation in a {@linkcode css} tagged template literal. * * This is unsafe because untrusted CSS text can be used to phone home * or exfiltrate data to an attacker controlled site. Take care to only use * this with trusted input. */ const unsafeCSS = (value) => new CSSResult(typeof value === 'string' ? value : String(value), u /** * A template literal tag which can be used with LitElement's * {@linkcode LitElement.styles} property to set element styles. * * For security reasons, only literal string values and number may be used in * embedded expressions. To incorporate non-literal values {@linkcode unsafeCSS} * may be used inside an expression. */ const css = (strings, ...values) => { const cssText = strings.length === 1 ? strings[0] : values.reduce((acc, v, idx) => acc + textFromCSSResult(v) + strings[idx + 1], strings[0]); return new CSSResult(cssText, strings, constructionToken); }; /** * Applies the given styles to a `shadowRoot`. When Shadow DOM is * available but `adoptedStyleSheets` is not, styles are appended to the * `shadowRoot` to [mimic spec behavior](https://wicg.github.io/construct-stylesheets/ * Note, when shimming is used, any styles that are subsequently placed into * the shadowRoot should be placed *before* any shimmed adopted styles. This * will match spec behavior that gives adopted sheets precedence over styles in * shadowRoot. */ const adoptStyles = (renderRoot, styles) => { if (supportsAdoptingStyleSheets) { renderRoot.adoptedStyleSheets = styles.map((s) => s instanceof CSSStyleSheet ? s : s.styleS } else { styles.forEach((s) => { const style = document.createElement('style'); // eslint-disable-next-line @typescript-eslint/no-explicit-any const nonce = global$2['litNonce']; if (nonce !== undefined) { style.setAttribute('nonce', nonce); } style.textContent = s.cssText; renderRoot.appendChild(style); }); } }; const cssResultFromStyleSheet = (sheet) => { let cssText = ''; for (const rule of sheet.cssRules) { cssText += rule.cssText; } return unsafeCSS(cssText); }; const getCompatibleStyle = supportsAdoptingStyleSheets || (NODE_MODE$1 ) ? (s) => s : (s) => s instanceof CSSStyleSheet ? cssResultFromStyleSheet(s) : s; /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ var _d$1; var _e; const global$1 = window; const trustedTypes$1 = global$1 .trustedTypes; // Temporary workaround for https://crbug.com/993268 // Currently, any attribute starting with "on" is considered to be a // TrustedScript source. Such boolean attributes must be set to the equivalent // trusted emptyScript value. const emptyStringForBooleanAttribute$1 = trustedTypes$1 ? trustedTypes$1.emptyScript : ''; const polyfillSupport$2 = global$1.reactiveElementPolyfillSupport; /* * When using Closure Compiler, JSCompiler_renameProperty(property, object) is * replaced at compile time by the munged name for object[property]. We cannot * alias this function, so we have to use a small shim that has the same * behavior when not compiling. */ /*@__INLINE__*/ const JSCompiler_renameProperty = (prop, _obj) => prop; const defaultConverter = { toAttribute(value, type) { switch (type) { case Boolean: value = value ? emptyStringForBooleanAttribute$1 : null; break; case Object: case Array: // if the value is `null` or `undefined` pass this through // to allow removing/no change behavior. value = value == null ? value : JSON.stringify(value); break; } return value; }, fromAttribute(value, type) { let fromValue = value; switch (type) { case Boolean: fromValue = value !== null; break; case Number: fromValue = value === null ? null : Number(value); break; case Object: case Array: // Do *not* generate exception when invalid JSON is set as elements // don't normally complain on being mis-configured. // TODO(sorvell): Do generate exception in *dev mode*. try { // Assert to adhere to Bazel's "must type assert JSON parse" rule. fromValue = JSON.parse(value); } catch (e) { fromValue = null; } break; } return fromValue; }, }; /** * Change function that returns true if `value` is different from `oldValue`. * This method is used as the default for a property's `hasChanged` function. */ const notEqual = (value, old) => { // This ensures (old==NaN, value==NaN) always returns false return old !== value && (old === old || value === value); }; const defaultPropertyDeclaration = { attribute: true, type: String, converter: defaultConverter, reflect: false, hasChanged: notEqual, }; /** * The Closure JS Compiler doesn't currently have good support for static * property semantics where "this" is dynamic (e.g. * https://github.com/google/closure-compiler/issues/3177 and others) so we use * this hack to bypass any rewriting by the compiler. */ const finalized = 'finalized'; /** * Base element class which manages element properties and attributes. When * properties change, the `update` method is asynchronously called. This method * should be supplied by subclassers to render updates as desired. * @noInheritDoc */ class ReactiveElement extends HTMLElement { constructor() { super(); this.__instanceProperties = new Map(); /** * True if there is a pending update as a result of calling `requestUpdate()`. * Should only be read. * @category updates */ this.isUpdatePending = false; /** * Is set to `true` after the first update. The element code cannot assume * that `renderRoot` exists before the element `hasUpdated`. * @category updates */ this.hasUpdated = false; /** * Name of currently reflecting property */ this.__reflectingProperty = null; this._initialize(); } /** * Adds an initializer function to the class that is called during instance * construction. * * This is useful for code that runs against a `ReactiveElement` * subclass, such as a decorator, that needs to do work for each * instance, such as setting up a `ReactiveController`. * * ```ts * const myDecorator = (target: typeof ReactiveElement, key: string) => { * target.addInitializer((instance: ReactiveElement) => { * // This is run during construction of the element * new MyController(instance); * }); * } * ``` * * Decorating a field will then cause each instance to run an initializer * that adds a controller: * * ```ts * class MyElement extends LitElement { * @myDecorator foo; * } * ``` * * Initializers are stored per-constructor. Adding an initializer to a * subclass does not add it to a superclass. Since initializers are run in * constructors, initializers will run in order of the class hierarchy, * starting with superclasses and progressing to the instance's class. * * @nocollapse */ static addInitializer(initializer) { var _a; this.finalize(); ((_a = this._initializers) !== null && _a !== void 0 ? _a : (this._initializers = [])).push(initi } /** * Returns a list of attributes corresponding to the registered properties. * @nocollapse * @category attributes */ static get observedAttributes() { // note: piggy backing on this to ensure we're finalized. this.finalize(); const attributes = []; // Use forEach so this works even if for/of loops are compiled to for loops // expecting arrays this.elementProperties.forEach((v, p) => { const attr = this.__attributeNameForProperty(p, v); if (attr !== undefined) { this.__attributeToPropertyMap.set(attr, p); attributes.push(attr); } }); return attributes; } /** * Creates a property accessor on the element prototype if one does not exist * and stores a {@linkcode PropertyDeclaration} for the property with the * given options. The property setter calls the property's `hasChanged` * property option or uses a strict identity check to determine whether or not * to request an update. * * This method may be overridden to customize properties; however, * when doing so, it's important to call `super.createProperty` to ensure * the property is setup correctly. This method calls * `getPropertyDescriptor` internally to get a descriptor to install. * To customize what properties do when they are get or set, override * `getPropertyDescriptor`. To customize the options for a property, * implement `createProperty` like this: * * ```ts * static createProperty(name, options) { * options = Object.assign(options, {myOption: true}); * super.createProperty(name, options); * } * ``` * * @nocollapse * @category properties */ static createProperty(name, options = defaultPropertyDeclaration) { // if this is a state property, force the attribute to false. if (options.state) { // Cast as any since this is readonly. // eslint-disable-next-line @typescript-eslint/no-explicit-any options.attribute = false; } // Note, since this can be called by the `@property` decorator which // is called before `finalize`, we ensure finalization has been kicked off. this.finalize(); this.elementProperties.set(name, options); // Do not generate an accessor if the prototype already has one, since // it would be lost otherwise and that would never be the user's intention; // Instead, we expect users to call `requestUpdate` themselves from // user-defined accessors. Note that if the super has an accessor we will // still overwrite it if (!options.noAccessor && !this.prototype.hasOwnProperty(name)) { const key = typeof name === 'symbol' ? Symbol() : `__${name}`; const descriptor = this.getPropertyDescriptor(name, key, options); if (descriptor !== undefined) { Object.defineProperty(this.prototype, name, descriptor); } } } /** * Returns a property descriptor to be defined on the given named property. * If no descriptor is returned, the property will not become an accessor. * For example, * * ```ts * class MyElement extends LitElement { * static getPropertyDescriptor(name, key, options) { * const defaultDescriptor = * super.getPropertyDescriptor(name, key, options); * const setter = defaultDescriptor.set; * return { * get: defaultDescriptor.get, * set(value) { * setter.call(this, value); * // custom action. * }, * configurable: true, * enumerable: true * } * } * } * ``` * * @nocollapse * @category properties */ static getPropertyDescriptor(name, key, options) { return { // eslint-disable-next-line @typescript-eslint/no-explicit-any get() { return this[key]; }, set(value) { const oldValue = this[name]; this[key] = value; this.requestUpdate(name, oldValue, options); }, configurable: true, enumerable: true, }; } /** * Returns the property options associated with the given property. * These options are defined with a `PropertyDeclaration` via the `properties` * object or the `@property` decorator and are registered in * `createProperty(...)`. * * Note, this method should be considered "final" and not overridden. To * customize the options for a given property, override * {@linkcode createProperty}. * * @nocollapse * @final * @category properties */ static getPropertyOptions(name) { return this.elementProperties.get(name) || defaultPropertyDeclaration; } /** * Creates property accessors for registered properties, sets up element * styling, and ensures any superclasses are also finalized. Returns true if * the element was finalized. * @nocollapse */ static finalize() { if (this.hasOwnProperty(finalized)) { return false; } this[finalized] = true; // finalize any superclasses const superCtor = Object.getPrototypeOf(this); superCtor.finalize(); // Create own set of initializers for this class if any exist on the // superclass and copy them down. Note, for a small perf boost, avoid // creating initializers unless needed. if (superCtor._initializers !== undefined) { this._initializers = [...superCtor._initializers]; } this.elementProperties = new Map(superCtor.elementProperties); // initialize Map populated in observedAttributes this.__attributeToPropertyMap = new Map(); // make any properties // Note, only process "own" properties since this element will inherit // any properties defined on the superClass, and finalization ensures // the entire prototype chain is finalized. if (this.hasOwnProperty(JSCompiler_renameProperty('properties'))) { const props = this.properties; // support symbols in properties (IE11 does not support this) const propKeys = [ ...Object.getOwnPropertyNames(props), ...Object.getOwnPropertySymbols(props), ]; // This for/of is ok because propKeys is an array for (const p of propKeys) { // note, use of `any` is due to TypeScript lack of support for symbol in // index types // eslint-disable-next-line @typescript-eslint/no-explicit-any this.createProperty(p, props[p]); } } this.elementStyles = this.finalizeStyles(this.styles); return true; } /** * Takes the styles the user supplied via the `static styles` property and * returns the array of styles to apply to the element. * Override this method to integrate into a style management system. * * Styles are deduplicated preserving the _last_ instance in the list. This * is a performance optimization to avoid duplicated styles that can occur * especially when composing via subclassing. The last item is kept to try * to preserve the cascade order with the assumption that it's most important * that last added styles override previous styles. * * @nocollapse * @category styles */ static finalizeStyles(styles) { const elementStyles = []; if (Array.isArray(styles)) { // Dedupe the flattened array in reverse order to preserve the last items. // Casting to Array<unknown> works around TS error that // appears to come from trying to flatten a type CSSResultArray. const set = new Set(styles.flat(Infinity).reverse()); // Then preserve original order by adding the set items in reverse order. for (const s of set) { elementStyles.unshift(getCompatibleStyle(s)); } } else if (styles !== undefined) { elementStyles.push(getCompatibleStyle(styles)); } return elementStyles; } /** * Returns the property name for the given attribute `name`. * @nocollapse */ static __attributeNameForProperty(name, options) { const attribute = options.attribute; return attribute === false ? undefined : typeof attribute === 'string' ? attribute : typeof name === 'string' ? name.toLowerCase() : undefined; } /** * Internal only override point for customizing work done when elements * are constructed. * * @internal */ _initialize() { var _a; this.__updatePromise = new Promise((res) => (this.enableUpdating = res)); this._$changedProperties = new Map(); this.__saveInstanceProperties(); // ensures first update will be caught by an early access of // `updateComplete` this.requestUpdate(); (_a = this.constructor._initializers) === null || _a === void 0 ? void 0 : _a.forEach((i) => i(th } /** * Registers a `ReactiveController` to participate in the element's reactive * update cycle. The element automatically calls into any registered * controllers during its lifecycle callbacks. * * If the element is connected when `addController()` is called, the * controller's `hostConnected()` callback will be immediately called. * @category controllers */ addController(controller) { var _a, _b; ((_a = this.__controllers) !== null && _a !== void 0 ? _a : (this.__controllers = [])).push(contr // If a controller is added after the element has been connected, // call hostConnected. Note, re-using existence of `renderRoot` here // (which is set in connectedCallback) to avoid the need to track a // first connected state. if (this.renderRoot !== undefined && this.isConnected) { (_b = controller.hostConnected) === null || _b === void 0 ? void 0 : _b.call(controller); } } /** * Removes a `ReactiveController` from the element. * @category controllers */ removeController(controller) { var _a; // Note, if the indexOf is -1, the >>> will flip the sign which makes the // splice do nothing. (_a = this.__controllers) === null || _a === void 0 ? void 0 : _a.splice(this.__controllers.in } /** * Fixes any properties set on the instance before upgrade time. * Otherwise these would shadow the accessor and break these properties. * The properties are stored in a Map which is played back after the * constructor runs. Note, on very old versions of Safari (<=9) or Chrome * (<=41), properties created for native platform properties like (`id` or * `name`) may not have default values set in the element constructor. On * these browsers native properties appear on instances and therefore their * default value will overwrite any element default (e.g. if the element sets * this.id = 'id' in the constructor, the 'id' will become '' since this is * the native platform default). */ __saveInstanceProperties() { // Use forEach so this works even if for/of loops are compiled to for loops // expecting arrays this.constructor.elementProperties.forEach((_v, p) => { if (this.hasOwnProperty(p)) { this.__instanceProperties.set(p, this[p]); delete this[p]; } }); } /** * Returns the node into which the element should render and by default * creates and returns an open shadowRoot. Implement to customize where the * element's DOM is rendered. For example, to render into the element's * childNodes, return `this`. * * @return Returns a node into which to render. * @category rendering */ createRenderRoot() { var _a; const renderRoot = (_a = this.shadowRoot) !== null && _a !== void 0 ? _a : this.attachShadow(this. adoptStyles(renderRoot, this.constructor.elementStyles); return renderRoot; } /** * On first connection, creates the element's renderRoot, sets up * element styling, and enables updating. * @category lifecycle */ connectedCallback() { var _a; // create renderRoot before first update. if (this.renderRoot === undefined) { this.renderRoot = this.createRenderRoot(); } this.enableUpdating(true); (_a = this.__controllers) === null || _a === void 0 ? void 0 : _a.forEach((c) => { var _a; return (_a } /** * Note, this method should be considered final and not overridden. It is * overridden on the element instance with a function that triggers the first * update. * @category updates */ enableUpdating(_requestedUpdate) { } /** * Allows for `super.disconnectedCallback()` in extensions while * reserving the possibility of making non-breaking feature additions * when disconnecting at some point in the future. * @category lifecycle */ disconnectedCallback() { var _a; (_a = this.__controllers) === null || _a === void 0 ? void 0 : _a.forEach((c) => { var _a; return (_a } /** * Synchronizes property values when attributes change. * * Specifically, when an attribute is set, the corresponding property is set. * You should rarely need to implement this callback. If this method is * overridden, `super.attributeChangedCallback(name, _old, value)` must be * called. * * See [using the lifecycle callbacks](https://developer.mozilla.org/en-US/docs/Web/We * on MDN for more information about the `attributeChangedCallback`. * @category attributes */ attributeChangedCallback(name, _old, value) { this._$attributeToProperty(name, value); } __propertyToAttribute(name, value, options = defaultPropertyDeclaration) { var _a; const attr = this.constructor.__attributeNameForProperty(name, options); if (attr !== undefined && options.reflect === true) { const converter = ((_a = options.converter) === null || _a === void 0 ? void 0 : _a.toAttribute) ! undefined ? options.converter : defaultConverter; const attrValue = converter.toAttribute(value, options.type); // Track if the property is being reflected to avoid // setting the property again via `attributeChangedCallback`. Note: // 1. this takes advantage of the fact that the callback is synchronous. // 2. will behave incorrectly if multiple attributes are in the reaction // stack at time of calling. However, since we process attributes // in `update` this should not be possible (or an extreme corner case // that we'd like to discover). // mark state reflecting this.__reflectingProperty = name; if (attrValue == null) { this.removeAttribute(attr); } else { this.setAttribute(attr, attrValue); } // mark state not reflecting this.__reflectingProperty = null; } } /** @internal */ _$attributeToProperty(name, value) { var _a; const ctor = this.constructor; // Note, hint this as an `AttributeMap` so closure clearly understands // the type; it has issues with tracking types through statics const propName = ctor.__attributeToPropertyMap.get(name); // Use tracking info to avoid reflecting a property value to an attribute // if it was just set because the attribute changed. if (propName !== undefined && this.__reflectingProperty !== propName) { const options = ctor.getPropertyOptions(propName); const converter = typeof options.converter === 'function' ? { fromAttribute: options.converter } : ((_a = options.converter) === null || _a === void 0 ? void 0 : _a.fromAttribute) !== undefined ? options.converter : defaultConverter; // mark state reflecting this.__reflectingProperty = propName; this[propName] = converter.fromAttribute(value, options.type // eslint-disable-next-line @typescript-eslint/no-explicit-any ); // mark state not reflecting this.__reflectingProperty = null; } } /** * Requests an update which is processed asynchronously. This should be called * when an element should update based on some state not triggered by setting * a reactive property. In this case, pass no arguments. It should also be * called when manually implementing a property setter. In this case, pass the * property `name` and `oldValue` to ensure that any configured property * options are honored. * * @param name name of requesting property * @param oldValue old value of requesting property * @param options property options to use instead of the previously * configured options * @category updates */ requestUpdate(name, oldValue, options) { let shouldRequestUpdate = true; // If we have a property key, perform property update steps. if (name !== undefined) { options = options || this.constructor.getPropertyOptions(name); const hasChanged = options.hasChanged || notEqual; if (hasChanged(this[name], oldValue)) { if (!this._$changedProperties.has(name)) { this._$changedProperties.set(name, oldValue); } // Add to reflecting properties set. // Note, it's important that every change has a chance to add the // property to `_reflectingProperties`. This ensures setting // attribute + property reflects correctly. if (options.reflect === true && this.__reflectingProperty !== name) { if (this.__reflectingProperties === undefined) { this.__reflectingProperties = new Map(); } this.__reflectingProperties.set(name, options); } } else { // Abort the request if the property should not be considered changed. shouldRequestUpdate = false; } } if (!this.isUpdatePending && shouldRequestUpdate) { this.__updatePromise = this.__enqueueUpdate(); } // Note, since this no longer returns a promise, in dev mode we return a // thenable which warns if it's called. return undefined; } /** * Sets up the element to asynchronously update. */ async __enqueueUpdate() { this.isUpdatePending = true; try { // Ensure any previous update has resolved before updating. // This `await` also ensures that property changes are batched. await this.__updatePromise; } catch (e) { // Refire any previous errors async so they do not disrupt the update // cycle. Errors are refired so developers have a chance to observe // them, and this can be done by implementing // `window.onunhandledrejection`. Promise.reject(e); } const result = this.scheduleUpdate(); // If `scheduleUpdate` returns a Promise, we await it. This is done to // enable coordinating updates with a scheduler. Note, the result is // checked to avoid delaying an additional microtask unless we need to. if (result != null) { await result; } return !this.isUpdatePending; } /** * Schedules an element update. You can override this method to change the * timing of updates by returning a Promise. The update will await the * returned Promise, and you should resolve the Promise to allow the update * to proceed. If this method is overridden, `super.scheduleUpdate()` * must be called. * * For instance, to schedule updates to occur just before the next frame: * * ```ts * override protected async scheduleUpdate(): Promise<unknown> { * await new Promise((resolve) => requestAnimationFrame(() => resolve())); * super.scheduleUpdate(); * } * ``` * @category updates */ scheduleUpdate() { return this.performUpdate(); } /** * Performs an element update. Note, if an exception is thrown during the * update, `firstUpdated` and `updated` will not be called. * * Call `performUpdate()` to immediately process a pending update. This should * generally not be needed, but it can be done in rare cases when you need to * update synchronously. * * Note: To ensure `performUpdate()` synchronously completes a pending update, * it should not be overridden. In LitElement 2.x it was suggested to override * `performUpdate()` to also customizing update scheduling. Instead, you should now * override `scheduleUpdate()`. For backwards compatibility with LitElement 2.x, * scheduling updates via `performUpdate()` continues to work, but will make * also calling `performUpdate()` to synchronously process updates difficult. * * @category updates */ performUpdate() { var _b; // Abort any update if one is not pending when this is called. // This can happen if `performUpdate` is called early to "flush" // the update. if (!this.isUpdatePending) { return; } // create renderRoot before first update. if (!this.hasUpdated) ; // Mixin instance properties once, if they exist. if (this.__instanceProperties) { // Use forEach so this works even if for/of loops are compiled to for loops // expecting arrays // eslint-disable-next-line @typescript-eslint/no-explicit-any this.__instanceProperties.forEach((v, p) => (this[p] = v)); this.__instanceProperties = undefined; } let shouldUpdate = false; const changedProperties = this._$changedProperties; try { shouldUpdate = this.shouldUpdate(changedProperties); if (shouldUpdate) { this.willUpdate(changedProperties); (_b = this.__controllers) === null || _b === void 0 ? void 0 : _b.forEach((c) => { var _a; return (_a this.update(changedProperties); } else { this.__markUpdated(); } } catch (e) { // Prevent `firstUpdated` and `updated` from running when there's an // update exception. shouldUpdate = false; // Ensure element can accept additional updates after an exception. this.__markUpdated(); throw e; } // The update is no longer considered pending and further updates are now allowed. if (shouldUpdate) { this._$didUpdate(changedProperties); } } /** * Invoked before `update()` to compute values needed during the update. * * Implement `willUpdate` to compute property values that depend on other * properties and are used in the rest of the update process. * * ```ts * willUpdate(changedProperties) { * // only need to check changed properties for an expensive computation. * if (changedProperties.has('firstName') || changedProperties.has('lastName')) { * this.sha = computeSHA(`${this.firstName} ${this.lastName}`); * } * } * * render() { * return html`SHA: ${this.sha}`; * } * ``` * * @category updates */ willUpdate(_changedProperties) { } // Note, this is an override point for polyfill-support. // @internal _$didUpdate(changedProperties) { var _a; (_a = this.__controllers) === null || _a === void 0 ? void 0 : _a.forEach((c) => { var _a; return (_a if (!this.hasUpdated) { this.hasUpdated = true; this.firstUpdated(changedProperties); } this.updated(changedProperties); } __markUpdated() { this._$changedProperties = new Map(); this.isUpdatePending = false; } /** * Returns a Promise that resolves when the element has completed updating. * The Promise value is a boolean that is `true` if the element completed the * update without triggering another update. The Promise result is `false` if * a property was set inside `updated()`. If the Promise is rejected, an * exception was thrown during the update. * * To await additional asynchronous work, override the `getUpdateComplete` * method. For example, it is sometimes useful to await a rendered element * before fulfilling this Promise. To do this, first await * `super.getUpdateComplete()`, then any subsequent state. * * @return A promise of a boolean that resolves to true if the update completed * without triggering another update. * @category updates */ get updateComplete() { return this.getUpdateComplete(); } /** * Override point for the `updateComplete` promise. * * It is not safe to override the `updateComplete` getter directly due to a * limitation in TypeScript which means it is not possible to call a * superclass getter (e.g. `super.updateComplete.then(...)`) when the target * language is ES5 (https://github.com/microsoft/TypeScript/issues/338). * This method should be overridden instead. For example: * * ```ts * class MyElement extends LitElement { * override async getUpdateComplete() { * const result = await super.getUpdateComplete(); * await this._myChild.updateComplete; * return result; * } * } * ``` * * @return A promise of a boolean that resolves to true if the update completed * without triggering another update. * @category updates */ getUpdateComplete() { return this.__updatePromise; } /** * Controls whether or not `update()` should be called when the element requests * an update. By default, this method always returns `true`, but this can be * customized to control when to update. * * @param _changedProperties Map of changed properties with old values * @category updates */ shouldUpdate(_changedProperties) { return true; } /** * Updates the element. This method reflects property values to attributes. * It can be overridden to render and keep updated element DOM. * Setting properties inside this method will *not* trigger * another update. * * @param _changedProperties Map of changed properties with old values * @category updates */ update(_changedProperties) { if (this.__reflectingProperties !== undefined) { // Use forEach so this works even if for/of loops are compiled to for // loops expecting arrays this.__reflectingProperties.forEach((v, k) => this.__propertyToAttribute(k, this[k], v this.__reflectingProperties = undefined; } this.__markUpdated(); } /** * Invoked whenever the element is updated. Implement to perform * post-updating tasks via DOM APIs, for example, focusing an element. * * Setting properties inside this method will trigger the element to update * again after this update cycle completes. * * @param _changedProperties Map of changed properties with old values * @category updates */ updated(_changedProperties) { } /** * Invoked when the element is first updated. Implement to perform one time * work on the element after update. * * ```ts * firstUpdated() { * this.renderRoot.getElementById('my-text-area').focus(); * } * ``` * * Setting properties inside this method will trigger the element to update * again after this update cycle completes. * * @param _changedProperties Map of changed properties with old values * @category updates */ firstUpdated(_changedProperties) { } } _e = finalized; /** * Marks class as having finished creating properties. */ ReactiveElement[_e] = true; /** * Memoized list of all element properties, including any superclass properties. * Created lazily on user subclasses when finalizing the class. * @nocollapse * @category properties */ ReactiveElement.elementProperties = new Map(); /** * Memoized list of all element styles. * Created lazily on user subclasses when finalizing the class. * @nocollapse * @category styles */ ReactiveElement.elementStyles = []; /** * Options used when calling `attachShadow`. Set this property to customize * the options for the shadowRoot; for example, to create a closed * shadowRoot: `{mode: 'closed'}`. * * Note, these options are used in `createRenderRoot`. If this method * is customized, options should be respected if possible. * @nocollapse * @category rendering */ ReactiveElement.shadowRootOptions = { mode: 'open' }; // Apply polyfills if available polyfillSupport$2 === null || polyfillSupport$2 === void 0 ? void 0 : polyfillSupport$2({ Rea // IMPORTANT: do not change the property name or the assignment expression. // This line will be used in regexes to search for ReactiveElement usage. ((_d$1 = global$1.reactiveElementVersions) !== null && _d$1 !== void 0 ? _d$1 : (global$1.react /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ var _d; // Use window for browser builds because IE11 doesn't have globalThis. const global = window; const __moz_domParser = new DOMParser(); const wrap$1 = (node) => node; const trustedTypes = global.trustedTypes; /** * Our TrustedTypePolicy for HTML which is declared using the html template * tag function. * * That HTML is a developer-authored constant, and is parsed with innerHTML * before any untrusted expressions have been mixed in. Therefor it is * considered safe by construction. */ const policy = trustedTypes ? trustedTypes.createPolicy('lit-html', { createHTML: (s) => s, }) : undefined; // Added to an attribute name to mark the attribute as bound so we can find // it easily. const boundAttributeSuffix = '$lit$'; // This marker is used in many syntactic positions in HTML, so it must be // a valid element name and attribute name. We don't support dynamic names (yet) // but this at least ensures that the parse tree is closer to the template // intention. const marker = `lit$${String(Math.random()).slice(9)}$`; // String used to tell if a comment is a marker comment const markerMatch = '?' + marker; // Text used to insert a comment marker node. We use processing instruction // syntax because it's slightly smaller, but parses as a comment node. const nodeMarker = `<${markerMatch}>`; const d = document; // Creates a dynamic marker. We never have to search for these in the DOM. const createMarker$1 = (v = '') => d.createComment(v); const isPrimitive$1 = (value) => value === null || (typeof value != 'object' && typeof value != 'fun const isArray = Array.isArray; const isIterable = (value) => isArray(value) || // eslint-disable-next-line @typescript-eslint/no-explicit-any typeof (value === null || value === void 0 ? void 0 : value[Symbol.iterator]) === 'function'; const SPACE_CHAR = `[ \t\n\f\r]`; const ATTR_VALUE_CHAR = `[^ \t\n\f\r"'\`<>=]`; const NAME_CHAR = `[^\\s"'>=/]`; // These regexes represent the five parsing states that we care about in the // Template's HTML scanner. They match the *end* of the state they're named // after. // Depending on the match, we transition to a new state. If there's no match, // we stay in the same state. // Note that the regexes are stateful. We utilize lastIndex and sync it // across the multiple regexes used. In addition to the five regexes below // we also dynamically create a regex to find the matching end tags for raw // text elements. /** * End of text is: `<` followed by: * (comment start) or (tag) or (dynamic tag binding) */ const textEndRegex = /<(?:(!--|\/[^a-zA-Z])|(\/?[a-zA-Z][^>\s]*)|(\/?$))/g; const COMMENT_START = 1; const TAG_NAME = 2; const DYNAMIC_TAG_NAME = 3; const commentEndRegex = /-->/g; /** * Comments not started with <!--, like </{, can be ended by a single `>` */ const comment2EndRegex = />/g; /** * The tagEnd regex matches the end of the "inside an opening" tag syntax * position. It either matches a `>`, an attribute-like sequence, or the end * of the string after a space (attribute-name position ending). * * See attributes in the HTML spec: * https://www.w3.org/TR/html5/syntax.html#elements-attributes * * " \t\n\f\r" are HTML space characters: * https://infra.spec.whatwg.org/#ascii-whitespace * * So an attribute is: * * The name: any character except a whitespace character, ("), ('), ">", * "=", or "/". Note: this is different from the HTML spec which also excludes control characters * * Followed by zero or more space characters * * Followed by "=" * * Followed by zero or more space characters * * Followed by: * * Any character except space, ('), ("), "<", ">", "=", (`), or * * (") then any non-("), or * * (') then any non-(') */ const tagEndRegex = new RegExp(`>|${SPACE_CHAR}(?:(${NAME_CHAR}+)(${SPACE_CHAR}*=${SP const ENTIRE_MATCH = 0; const ATTRIBUTE_NAME = 1; const SPACES_AND_EQUALS = 2; const QUOTE_CHAR = 3; const singleQuoteAttrEndRegex = /'/g; const doubleQuoteAttrEndRegex = /"/g; /** * Matches the raw text elements. * * Comments are not parsed within raw text elements, so we need to search their * text content for marker strings. */ const rawTextElement = /^(?:script|style|textarea|title)$/i; /** TemplateResult types */ const HTML_RESULT$1 = 1; const SVG_RESULT$1 = 2; // TemplatePart types // IMPORTANT: these must match the values in PartType const ATTRIBUTE_PART = 1; const CHILD_PART = 2; const PROPERTY_PART = 3; const BOOLEAN_ATTRIBUTE_PART = 4; const EVENT_PART = 5; const ELEMENT_PART = 6; const COMMENT_PART = 7; /** * Generates a template literal tag function that returns a TemplateResult with * the given result type. */ const tag = (type) => (strings, ...values) => { return { // This property needs to remain unminified. ['_$litType$']: type, strings, values, }; }; /** * Interprets a template literal as an HTML template that can efficiently * render to and update a container. * * ```ts * const header = (title: string) => html`<h1>${title}</h1>`; * ``` * * The `html` tag returns a description of the DOM to render as a value. It is * lazy, meaning no work is done until the template is rendered. When rendering, * if a template comes from the same expression as a previously rendered result, * it's efficiently updated instead of replaced. */ const html$1 = tag(HTML_RESULT$1); /** * Interprets a template literal as an SVG fragment that can efficiently * render to and update a container. * * ```ts * const rect = svg`<rect width="10" height="10"></rect>`; * * const myImage = html` * <svg viewBox="0 0 10 10" xmlns="http://www.w3.org/2000/svg"> * ${rect} * </svg>`; * ``` * * The `svg` *tag function* should only be used for SVG fragments, or elements * that would be contained **inside** an `<svg>` HTML element. A common error is * placing an `<svg>` *element* in a template tagged with the `svg` tag * function. The `<svg>` element is an HTML element and should be used within a * template tagged with the {@linkcode html} tag function. * * In LitElement usage, it's invalid to return an SVG fragment from the * `render()` method, as the SVG fragment will be contained within the element's * shadow root and thus cannot be used within an `<svg>` HTML element. */ const svg$1 = tag(SVG_RESULT$1); /** * A sentinel value that signals that a value was handled by a directive and * should not be written to the DOM. */ const noChange = Symbol.for('lit-noChange'); /** * A sentinel value that signals a ChildPart to fully clear its content. * * ```ts * const button = html`${ * user.isAdmin * ? html`<button>DELETE</button>` * : nothing * }`; * ``` * * Prefer using `nothing` over other falsy values as it provides a consistent * behavior between various expression binding contexts. * * In child expressions, `undefined`, `null`, `''`, and `nothing` all behave the * same and render no nodes. In attribute expressions, `nothing` _removes_ the * attribute, while `undefined` and `null` will render an empty string. In * property expressions `nothing` becomes `undefined`. */ const nothing = Symbol.for('lit-nothing'); /** * The cache of prepared templates, keyed by the tagged TemplateStringsArray * and _not_ accounting for the specific template tag used. This means that * template tags cannot be dynamic - the must statically be one of html, svg, * or attr. This restriction simplifies the cache lookup, which is on the hot * path for rendering. */ const templateCache = new WeakMap(); const walker = d.createTreeWalker(d, 129 /* NodeFilter.SHOW_{ELEMENT|COMMENT} */, null, f /** * Returns an HTML string for the given TemplateStringsArray and result type * (HTML or SVG), along with the case-sensitive bound attribute names in * template order. The HTML contains comment markers denoting the `ChildPart`s * and suffixes on bound attributes denoting the `AttributeParts`. * * @param strings template strings array * @param type HTML or SVG * @return Array containing `[html, attrNames]` (array returned for terseness, * to avoid object fields since this code is shared with non-minified SSR * code) */ const getTemplateHtml = (strings, type) => { // Insert makers into the template HTML to represent the position of // bindings. The following code scans the template strings to determine the // syntactic position of the bindings. They can be in text position, where // we insert an HTML comment, attribute value position, where we insert a // sentinel string and re-write the attribute name, or inside a tag where // we insert the sentinel string. const l = strings.length - 1; // Stores the case-sensitive bound attribute names in the order of their // parts. ElementParts are also reflected in this array as undefined // rather than a string, to disambiguate from attribute bindings. const attrNames = []; let html = type === SVG_RESULT$1 ? '<svg>' : ''; // When we're inside a raw text tag (not it's text content), the regex // will still be tagRegex so we can find attributes, but will switch to // this regex when the tag ends. let rawTextEndRegex; // The current parsing state, represented as a reference to one of the // regexes let regex = textEndRegex; for (let i = 0; i < l; i++) { const s = strings[i]; // The index of the end of the last attribute name. When this is // positive at end of a string, it means we're in an attribute value // position and need to rewrite the attribute name. // We also use a special value of -2 to indicate that we encountered // the end of a string in attribute name position. let attrNameEndIndex = -1; let attrName; let lastIndex = 0; let match; // The conditions in this loop handle the current parse state, and the // assignments to the `regex` variable are the state transitions. while (lastIndex < s.length) { // Make sure we start searching from where we previously left off regex.lastIndex = lastIndex; match = regex.exec(s); if (match === null) { break; } lastIndex = regex.lastIndex; if (regex === textEndRegex) { if (match[COMMENT_START] === '!--') { regex = commentEndRegex; } else if (match[COMMENT_START] !== undefined) { // We started a weird comment, like </{ regex = comment2EndRegex; } else if (match[TAG_NAME] !== undefined) { if (rawTextElement.test(match[TAG_NAME])) { // Record if we encounter a raw-text element. We'll switch to // this regex at the end of the tag. rawTextEndRegex = new RegExp(`</${match[TAG_NAME]}`, 'g'); } regex = tagEndRegex; } else if (match[DYNAMIC_TAG_NAME] !== undefined) { regex = tagEndRegex; } } else if (regex === tagEndRegex) { if (match[ENTIRE_MATCH] === '>') { // End of a tag. If we had started a raw-text element, use that // regex regex = rawTextEndRegex !== null && rawTextEndRegex !== void 0 ? rawTextEndRegex : textEndRegex // We may be ending an unquoted attribute value, so make sure we // clear any pending attrNameEndIndex attrNameEndIndex = -1; } else if (match[ATTRIBUTE_NAME] === undefined) { // Attribute name position attrNameEndIndex = -2; } else { attrNameEndIndex = regex.lastIndex - match[SPACES_AND_EQUALS].length; attrName = match[ATTRIBUTE_NAME]; regex = match[QUOTE_CHAR] === undefined ? tagEndRegex : match[QUOTE_CHAR] === '"' ? doubleQuoteAttrEndRegex : singleQuoteAttrEndRegex; } } else if (regex === doubleQuoteAttrEndRegex || regex === singleQuoteAttrEndRegex) { regex = tagEndRegex; } else if (regex === commentEndRegex || regex === comment2EndRegex) { regex = textEndRegex; } else { // Not one of the five state regexes, so it must be the dynamically // created raw text regex and we're at the close of that element. regex = tagEndRegex; rawTextEndRegex = undefined; } } // We have four cases: // 1. We're in text position, and not in a raw text element // (regex === textEndRegex): insert a comment marker. // 2. We have a non-negative attrNameEndIndex which means we need to // rewrite the attribute name to add a bound attribute suffix. // 3. We're at the non-first binding in a multi-binding attribute, use a // plain marker. // 4. We're somewhere else inside the tag. If we're in attribute name // position (attrNameEndIndex === -2), add a sequential suffix to // generate a unique attribute name. // Detect a binding next to self-closing tag end and insert a space to // separate the marker from the tag end: const end = regex === tagEndRegex && strings[i + 1].startsWith('/>') ? ' ' : ''; html += regex === textEndRegex ? s + nodeMarker : attrNameEndIndex >= 0 ? (attrNames.push(attrName), s.slice(0, attrNameEndIndex) + boundAttributeSuffix + s.slice(attrNameEndIndex)) + marker + end : s + marker + (attrNameEndIndex === -2 ? (attrNames.push(undefined), i) : end); } const htmlResult = html + (strings[l] || '<?>') + (type === SVG_RESULT$1 ? '</svg>' : ''); // A security check to prevent spoofing of Lit template results. // In the future, we may be able to replace this with Array.isTemplateObject, // though we might need to make that check inside of the html and svg // functions, because precompiled templates don't come in as // TemplateStringArray objects. if (!Array.isArray(strings) || !strings.hasOwnProperty('raw')) { let message = 'invalid template strings array'; throw new Error(message); } // Returned as an array for terseness return [ policy !== undefined ? policy.createHTML(htmlResult) : htmlResult, attrNames, ]; }; class Template { constructor( // This property needs to remain unminified. { strings, ['_$litType$']: type }, options) { /** @internal */ this.parts = []; let node; let nodeIndex = 0; let attrNameIndex = 0; const partCount = strings.length - 1; const parts = this.parts; // Create template element const [html, attrNames] = getTemplateHtml(strings, type); this.el = Template.createElement(html, options); walker.currentNode = this.el.content; // Reparent SVG nodes into template root if (type === SVG_RESULT$1) { const content = this.el.content; const svgElement = content.firstChild; svgElement.remove(); content.append(...svgElement.childNodes); } // Walk the template to find binding markers and create TemplateParts while ((node = walker.nextNode()) !== null && parts.length < partCount) { if (node.nodeType === 1) { // TODO (justinfagnani): for attempted dynamic tag names, we don't // increment the bindingIndex, and it'll be off by 1 in the element // and off by two after it. if (node.hasAttributes()) { // We defer removing bound attributes because on IE we might not be // iterating attributes in their template order, and would sometimes // remove an attribute that we still need to create a part for. const attrsToRemove = []; for (const name of node.getAttributeNames()) { // `name` is the name of the attribute we're iterating over, but not // _neccessarily_ the name of the attribute we will create a part // for. They can be different in browsers that don't iterate on // attributes in source order. In that case the attrNames array // contains the attribute name we'll process next. We only need the // attribute name here to know if we should process a bound attribute // on this element. if (name.endsWith(boundAttributeSuffix) || name.startsWith(marker)) { const realName = attrNames[attrNameIndex++]; attrsToRemove.push(name); if (realName !== undefined) { // Lowercase for case-sensitive SVG attributes like viewBox const value = node.getAttribute(realName.toLowerCase() + boundAttributeSuffix); const statics = value.split(marker); const m = /([.?@])?(.*)/.exec(realName); parts.push({ type: ATTRIBUTE_PART, index: nodeIndex, name: m[2], strings: statics, ctor: m[1] === '.' ? PropertyPart : m[1] === '?' ? BooleanAttributePart : m[1] === '@' ? EventPart : AttributePart, }); } else { parts.push({ type: ELEMENT_PART, index: nodeIndex, }); } } } for (const name of attrsToRemove) { node.removeAttribute(name); } } // TODO (justinfagnani): benchmark the regex against testing for each // of the 3 raw text element names. if (rawTextElement.test(node.tagName)) { // For raw text elements we need to split the text content on // markers, create a Text node for each segment, and create // a TemplatePart for each marker. const strings = node.textContent.split(marker); const lastIndex = strings.length - 1; if (lastIndex > 0) { node.textContent = trustedTypes ? trustedTypes.emptyScript : ''; // Generate a new text node for each literal section // These nodes are also used as the markers for node parts // We can't use empty text nodes as markers because they're // normalized when cloning in IE (could simplify when // IE is no longer supported) for (let i = 0; i < lastIndex; i++) { node.append(strings[i], createMarker$1()); // Walk past the marker node we just added walker.nextNode(); parts.push({ type: CHILD_PART, index: ++nodeIndex }); } // Note because this marker is added after the walker's current // node, it will be walked to in the outer loop (and ignored), so // we don't need to adjust nodeIndex here node.append(strings[lastIndex], createMarker$1()); } } } else if (node.nodeType === 8) { const data = node.data; if (data === markerMatch) { parts.push({ type: CHILD_PART, index: nodeIndex }); } else { let i = -1; while ((i = node.data.indexOf(marker, i + 1)) !== -1) { // Comment node has a binding marker inside, make an inactive part // The binding won't work, but subsequent bindings will parts.push({ type: COMMENT_PART, index: nodeIndex }); // Move to the end of the match i += marker.length - 1; } } } nodeIndex++; } } // Overridden via `litHtmlPolyfillSupport` to provide platform support. /** @nocollapse */ static createElement(html, _options) { const doc = __moz_domParser.parseFromString(`<template>${html}</template>`, 'text/html') return document.importNode(doc.querySelector('template'), true); } } function resolveDirective(part, value, parent = part, attributeIndex) { var _a, _b, _c; var _d; // Bail early if the value is explicitly noChange. Note, this means any // nested directive is still attached and is not run. if (value === noChange) { return value; } let currentDirective = attributeIndex !== undefined ? (_a = parent.__directives) === null || _a === void 0 ? void 0 : _a[attributeIndex] : parent.__directive; const nextDirectiveConstructor = isPrimitive$1(value) ? undefined : // This property needs to remain unminified. value['_$litDirective$']; if ((currentDirective === null || currentDirective === void 0 ? void 0 : currentDirective.con // This property needs to remain unminified. (_b = currentDirective === null || currentDirective === void 0 ? void 0 : currentDirective['_$ if (nextDirectiveConstructor === undefined) { currentDirective = undefined; } else { currentDirective = new nextDirectiveConstructor(part); currentDirective._$initialize(part, parent, attributeIndex); } if (attributeIndex !== undefined) { ((_c = (_d = parent).__directives) !== null && _c !== void 0 ? _c : (_d.__directives = []))[attribu currentDirective; } else { parent.__directive = currentDirective; } } if (currentDirective !== undefined) { value = resolveDirective(part, currentDirective._$resolve(part, value.values), curren } return value; } /** * An updateable instance of a Template. Holds references to the Parts used to * update the template instance. */ class TemplateInstance { constructor(template, parent) { /** @internal */ this._parts = []; /** @internal */ this._$disconnectableChildren = undefined; this._$template = template; this._$parent = parent; } // Called by ChildPart parentNode getter get parentNode() { return this._$parent.parentNode; } // See comment in Disconnectable interface for why this is a getter get _$isConnected() { return this._$parent._$isConnected; } // This method is separate from the constructor because we need to return a // DocumentFragment and we don't want to hold onto it with an instance field. _clone(options) { var _a; const { el: { content }, parts: parts, } = this._$template; const fragment = ((_a = options === null || options === void 0 ? void 0 : options.creationScope) ! walker.currentNode = fragment; let node = walker.nextNode(); let nodeIndex = 0; let partIndex = 0; let templatePart = parts[0]; while (templatePart !== undefined) { if (nodeIndex === templatePart.index) { let part; if (templatePart.type === CHILD_PART) { part = new ChildPart$1(node, node.nextSibling, this, options); } else if (templatePart.type === ATTRIBUTE_PART) { part = new templatePart.ctor(node, templatePart.name, templatePart.strings, this, optio } else if (templatePart.type === ELEMENT_PART) { part = new ElementPart(node, this, options); } this._parts.push(part); templatePart = parts[++partIndex]; } if (nodeIndex !== (templatePart === null || templatePart === void 0 ? void 0 : templatePart.ind node = walker.nextNode(); nodeIndex++; } } return fragment; } _update(values) { let i = 0; for (const part of this._parts) { if (part !== undefined) { if (part.strings !== undefined) { part._$setValue(values, part, i); // The number of values the part consumes is part.strings.length - 1 // since values are in between template spans. We increment i by 1 // later in the loop, so increment it by part.strings.length - 2 here i += part.strings.length - 2; } else { part._$setValue(values[i]); } } i++; } } } class ChildPart$1 { constructor(startNode, endNode, parent, options) { var _a; this.type = CHILD_PART; this._$committedValue = nothing; // The following fields will be patched onto ChildParts when required by // AsyncDirective /** @internal */ this._$disconnectableChildren = undefined; this._$startNode = startNode; this._$endNode = endNode; this._$parent = parent; this.options = options; // Note __isConnected is only ever accessed on RootParts (i.e. when there is // no _$parent); the value on a non-root-part is "don't care", but checking // for parent would be more code this.__isConnected = (_a = options === null || options === void 0 ? void 0 : options.isConnected } // See comment in Disconnectable interface for why this is a getter get _$isConnected() { var _a, _b; // ChildParts that are not at the root should always be created with a // parent; only RootChildNode's won't, so they return the local isConnected // state return (_b = (_a = this._$parent) === null || _a === void 0 ? void 0 : _a._$isConnected) !== null && _b } /** * The parent node into which the part renders its content. * * A ChildPart's content consists of a range of adjacent child nodes of * `.parentNode`, possibly bordered by 'marker nodes' (`.startNode` and * `.endNode`). * * - If both `.startNode` and `.endNode` are non-null, then the part's content * consists of all siblings between `.startNode` and `.endNode`, exclusively. * * - If `.startNode` is non-null but `.endNode` is null, then the part's * content consists of all siblings following `.startNode`, up to and * including the last child of `.parentNode`. If `.endNode` is non-null, then * `.startNode` will always be non-null. * * - If both `.endNode` and `.startNode` are null, then the part's content * consists of all child nodes of `.parentNode`. */ get parentNode() { let parentNode = wrap$1(this._$startNode).parentNode; const parent = this._$parent; if (parent !== undefined && parentNode.nodeType === 11 /* Node.DOCUMENT_FRAGMENT */) { // If the parentNode is a DocumentFragment, it may be because the DOM is // still in the cloned fragment during initial render; if so, get the real // parentNode the part will be committed into by asking the parent. parentNode = parent.parentNode; } return parentNode; } /** * The part's leading marker node, if any. See `.parentNode` for more * information. */ get startNode() { return this._$startNode; } /** * The part's trailing marker node, if any. See `.parentNode` for more * information. */ get endNode() { return this._$endNode; } _$setValue(value, directiveParent = this) { value = resolveDirective(this, value, directiveParent); if (isPrimitive$1(value)) { // Non-rendering child values. It's important that these do not render // empty text nodes to avoid issues with preventing default <slot> // fallback content. if (value === nothing || value == null || value === '') { if (this._$committedValue !== nothing) { this._$clear(); } this._$committedValue = nothing; } else if (value !== this._$committedValue && value !== noChange) { this._commitText(value); } // This property needs to remain unminified. } else if (value['_$litType$'] !== undefined) { this._commitTemplateResult(value); } else if (value.nodeType !== undefined) { this._commitNode(value); } else if (isIterable(value)) { this._commitIterable(value); } else { // Fallback, will render the string representation this._commitText(value); } } _insert(node, ref = this._$endNode) { return wrap$1(wrap$1(this._$startNode).parentNode).insertBefore(node, ref); } _commitNode(value) { if (this._$committedValue !== value) { this._$clear(); this._$committedValue = this._insert(value); } } _commitText(value) { // If the committed value is a primitive it means we called _commitText on // the previous render, and we know that this._$startNode.nextSibling is a // Text node. We can now just replace the text content (.data) of the node. if (this._$committedValue !== nothing && isPrimitive$1(this._$committedValue)) { const node = wrap$1(this._$startNode).nextSibling; node.data = value; } else { { this._commitNode(d.createTextNode(value)); } } this._$committedValue = value; } _commitTemplateResult(result) { var _a; // This property needs to remain unminified. const { values, ['_$litType$']: type } = result; // If $litType$ is a number, result is a plain TemplateResult and we get // the template from the template cache. If not, result is a // CompiledTemplateResult and _$litType$ is a CompiledTemplate and we need // to create the <template> element the first time we see it. const template = typeof type === 'number' ? this._$getTemplate(result) : (type.el === undefined && (type.el = Template.createElement(type.h, this.options)), type); if (((_a = this._$committedValue) === null || _a === void 0 ? void 0 : _a._$template) === templat this._$committedValue._update(values); } else { const instance = new TemplateInstance(template, this); const fragment = instance._clone(this.options); instance._update(values); this._commitNode(fragment); this._$committedValue = instance; } } // Overridden via `litHtmlPolyfillSupport` to provide platform support. /** @internal */ _$getTemplate(result) { let template = templateCache.get(result.strings); if (template === undefined) { templateCache.set(result.strings, (template = new Template(result))); } return template; } _commitIterable(value) { // For an Iterable, we create a new InstancePart per item, then set its // value to the item. This is a little bit of overhead for every item in // an Iterable, but it lets us recurse easily and efficiently update Arrays // of TemplateResults that will be commonly returned from expressions like: // array.map((i) => html`${i}`), by reusing existing TemplateInstances. // If value is an array, then the previous render was of an // iterable and value will contain the ChildParts from the previous // render. If value is not an array, clear this part and make a new // array for ChildParts. if (!isArray(this._$committedValue)) { this._$committedValue = []; this._$clear(); } // Lets us keep track of how many items we stamped so we can clear leftover // items from a previous render const itemParts = this._$committedValue; let partIndex = 0; let itemPart; for (const item of value) { if (partIndex === itemParts.length) { // If no existing part, create a new one // TODO (justinfagnani): test perf impact of always creating two parts // instead of sharing parts between nodes // https://github.com/lit/lit/issues/1266 itemParts.push((itemPart = new ChildPart$1(this._insert(createMarker$1()), this._ins } else { // Reuse an existing part itemPart = itemParts[partIndex]; } itemPart._$setValue(item); partIndex++; } if (partIndex < itemParts.length) { // itemParts always have end nodes this._$clear(itemPart && wrap$1(itemPart._$endNode).nextSibling, partIndex); // Truncate the parts array so _value reflects the current state itemParts.length = partIndex; } } /** * Removes the nodes contained within this Part from the DOM. * * @param start Start node to clear from, for clearing a subset of the part's * DOM (used when truncating iterables) * @param from When `start` is specified, the index within the iterable from * which ChildParts are being removed, used for disconnecting directives in * those Parts. * * @internal */ _$clear(start = wrap$1(this._$startNode).nextSibling, from) { var _a; (_a = this._$notifyConnectionChanged) === null || _a === void 0 ? void 0 : _a.call(this, false, while (start && start !== this._$endNode) { const n = wrap$1(start).nextSibling; wrap$1(start).remove(); start = n; } } /** * Implementation of RootPart's `isConnected`. Note that this metod * should only be called on `RootPart`s (the `ChildPart` returned from a * top-level `render()` call). It has no effect on non-root ChildParts. * @param isConnected Whether to set * @internal */ setConnected(isConnected) { var _a; if (this._$parent === undefined) { this.__isConnected = isConnected; (_a = this._$notifyConnectionChanged) === null || _a === void 0 ? void 0 : _a.call(this, isConn } } } class AttributePart { constructor(element, name, strings, parent, options) { this.type = ATTRIBUTE_PART; /** @internal */ this._$committedValue = nothing; /** @internal */ this._$disconnectableChildren = undefined; this.element = element; this.name = name; this._$parent = parent; this.options = options; if (strings.length > 2 || strings[0] !== '' || strings[1] !== '') { this._$committedValue = new Array(strings.length - 1).fill(new String()); this.strings = strings; } else { this._$committedValue = nothing; } } get tagName() { return this.element.tagName; } // See comment in Disconnectable interface for why this is a getter get _$isConnected() { return this._$parent._$isConnected; } /** * Sets the value of this part by resolving the value from possibly multiple * values and static strings and committing it to the DOM. * If this part is single-valued, `this._strings` will be undefined, and the * method will be called with a single value argument. If this part is * multi-value, `this._strings` will be defined, and the method is called * with the value array of the part's owning TemplateInstance, and an offset * into the value array from which the values should be read. * This method is overloaded this way to eliminate short-lived array slices * of the template instance values, and allow a fast-path for single-valued * parts. * * @param value The part value, or an array of values for multi-valued parts * @param valueIndex the index to start reading values from. `undefined` for * single-valued parts * @param noCommit causes the part to not commit its value to the DOM. Used * in hydration to prime attribute parts with their first-rendered value, * but not set the attribute, and in SSR to no-op the DOM operation and * capture the value for serialization. * * @internal */ _$setValue(value, directiveParent = this, valueIndex, noCommit) { const strings = this.strings; // Whether any of the values has changed, for dirty-checking let change = false; if (strings === undefined) { // Single-value binding case value = resolveDirective(this, value, directiveParent, 0); change = !isPrimitive$1(value) || (value !== this._$committedValue && value !== noChange); if (change) { this._$committedValue = value; } } else { // Interpolation case const values = value; value = strings[0]; let i, v; for (i = 0; i < strings.length - 1; i++) { v = resolveDirective(this, values[valueIndex + i], directiveParent, i); if (v === noChange) { // If the user-provided value is `noChange`, use the previous value v = this._$committedValue[i]; } change || (change = !isPrimitive$1(v) || v !== this._$committedValue[i]); if (v === nothing) { value = nothing; } else if (value !== nothing) { value += (v !== null && v !== void 0 ? v : '') + strings[i + 1]; } // We always record each value, even if one is `nothing`, for future // change detection. this._$committedValue[i] = v; } } if (change && !noCommit) { this._commitValue(value); } } /** @internal */ _commitValue(value) { if (value === nothing) { wrap$1(this.element).removeAttribute(this.name); } else { wrap$1(this.element).setAttribute(this.name, (value !== null && value !== void 0 ? value : '') } } } class PropertyPart extends AttributePart { constructor() { super(...arguments); this.type = PROPERTY_PART; } /** @internal */ _commitValue(value) { // eslint-disable-next-line @typescript-eslint/no-explicit-any this.element[this.name] = value === nothing ? undefined : value; } } // Temporary workaround for https://crbug.com/993268 // Currently, any attribute starting with "on" is considered to be a // TrustedScript source. Such boolean attributes must be set to the equivalent // trusted emptyScript value. const emptyStringForBooleanAttribute = trustedTypes ? trustedTypes.emptyScript : ''; class BooleanAttributePart extends AttributePart { constructor() { super(...arguments); this.type = BOOLEAN_ATTRIBUTE_PART; } /** @internal */ _commitValue(value) { if (value && value !== nothing) { wrap$1(this.element).setAttribute(this.name, emptyStringForBooleanAttribute); } else { wrap$1(this.element).removeAttribute(this.name); } } } class EventPart extends AttributePart { constructor(element, name, strings, parent, options) { super(element, name, strings, parent, options); this.type = EVENT_PART; } // EventPart does not use the base _$setValue/_resolveValue implementation // since the dirty checking is more complex /** @internal */ _$setValue(newListener, directiveParent = this) { var _a; newListener = (_a = resolveDirective(this, newListener, directiveParent, 0)) !== null && _a !== void 0 ? _a : no if (newListener === noChange) { return; } const oldListener = this._$committedValue; // If the new value is nothing or any options change we have to remove the // part as a listener. const shouldRemoveListener = (newListener === nothing && oldListener !== nothing) || newListener.capture !== oldListener.capture || newListener.once !== oldListener.once || newListener.passive !== oldListener.passive; // If the new value is not nothing and we removed the listener, we have // to add the part as a listener. const shouldAddListener = newListener !== nothing && (oldListener === nothing || shouldRemoveListener); if (shouldRemoveListener) { this.element.removeEventListener(this.name, this, oldListener); } if (shouldAddListener) { // Beware: IE11 and Chrome 41 don't like using the listener as the // options object. Figure out how to deal w/ this in IE11 - maybe // patch addEventListener? this.element.addEventListener(this.name, this, newListener); } this._$committedValue = newListener; } handleEvent(event) { var _a, _b; if (typeof this._$committedValue === 'function') { this._$committedValue.call((_b = (_a = this.options) === null || _a === void 0 ? void 0 : _a.hos } else { this._$committedValue.handleEvent(event); } } } class ElementPart { constructor(element, parent, options) { this.element = element; this.type = ELEMENT_PART; /** @internal */ this._$disconnectableChildren = undefined; this._$parent = parent; this.options = options; } // See comment in Disconnectable interface for why this is a getter get _$isConnected() { return this._$parent._$isConnected; } _$setValue(value) { resolveDirective(this, value); } } /** * END USERS SHOULD NOT RELY ON THIS OBJECT. * * Private exports for use by other Lit packages, not intended for use by * external users. * * We currently do not make a mangled rollup build of the lit-ssr code. In order * to keep a number of (otherwise private) top-level exports mangled in the * client side code, we export a _$LH object containing those members (or * helper methods for accessing private fields of those members), and then * re-export them for use in lit-ssr. This keeps lit-ssr agnostic to whether the * client-side code is being used in `dev` mode or `prod` mode. * * This has a unique name, to disambiguate it from private exports in * lit-element, which re-exports all of lit-html. * * @private */ const _$LH = { // Used in lit-ssr _boundAttributeSuffix: boundAttributeSuffix, _marker: marker, _markerMatch: markerMatch, _HTML_RESULT: HTML_RESULT$1, _getTemplateHtml: getTemplateHtml, // Used in hydrate _TemplateInstance: TemplateInstance, _isIterable: isIterable, _resolveDirective: resolveDirective, // Used in tests and private-ssr-support _ChildPart: ChildPart$1, _AttributePart: AttributePart, _BooleanAttributePart: BooleanAttributePart, _EventPart: EventPart, _PropertyPart: PropertyPart, _ElementPart: ElementPart, }; // Apply polyfills if available const polyfillSupport$1 = global.litHtmlPolyfillSupport; polyfillSupport$1 === null || polyfillSupport$1 === void 0 ? void 0 : polyfillSupport$1(Temp // IMPORTANT: do not change the property name or the assignment expression. // This line will be used in regexes to search for lit-html usage. ((_d = global.litHtmlVersions) !== null && _d !== void 0 ? _d : (global.litHtmlVersions = [])).pu /** * Renders a value, usually a lit-html TemplateResult, to the container. * * This example renders the text "Hello, Zoe!" inside a paragraph tag, appending * it to the container `document.body`. * * ```js * import {html, render} from 'lit'; * * const name = "Zoe"; * render(html`<p>Hello, ${name}!</p>`, document.body); * ``` * * @param value Any [renderable * value](https://lit.dev/docs/templates/expressions/#child-expressions), * typically a {@linkcode TemplateResult} created by evaluating a template tag * like {@linkcode html} or {@linkcode svg}. * @param container A DOM container to render to. The first render will append * the rendered value to the container, and subsequent renders will * efficiently update the rendered value if the same result type was * previously rendered there. * @param options See {@linkcode RenderOptions} for options documentation. * @see * {@link https://lit.dev/docs/libraries/standalone-templates/#rendering-lit-html-t */ const render = (value, container, options) => { var _a, _b; const partOwnerNode = (_a = options === null || options === void 0 ? void 0 : options.renderBefor // This property needs to remain unminified. // eslint-disable-next-line @typescript-eslint/no-explicit-any let part = partOwnerNode['_$litPart$']; if (part === undefined) { const endNode = (_b = options === null || options === void 0 ? void 0 : options.renderBefore) !== n // This property needs to remain unminified. // eslint-disable-next-line @typescript-eslint/no-explicit-any partOwnerNode['_$litPart$'] = part = new ChildPart$1(container.insertBefore(createMar } part._$setValue(value); return part; }; /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ var _b, _c; // For backwards compatibility export ReactiveElement as UpdatingElement. Note, // IE transpilation requires exporting like this. const UpdatingElement = ReactiveElement; /** * Base element class that manages element properties and attributes, and * renders a lit-html template. * * To define a component, subclass `LitElement` and implement a * `render` method to provide the component's template. Define properties * using the {@linkcode LitElement.properties properties} property or the * {@linkcode property} decorator. */ class LitElement extends ReactiveElement { constructor() { super(...arguments); /** * @category rendering */ this.renderOptions = { host: this }; this.__childPart = undefined; } /** * @category rendering */ createRenderRoot() { var _a; var _b; const renderRoot = super.createRenderRoot(); // When adoptedStyleSheets are shimmed, they are inserted into the // shadowRoot by createRenderRoot. Adjust the renderBefore node so that // any styles in Lit content render before adoptedStyleSheets. This is // important so that adoptedStyleSheets have precedence over styles in // the shadowRoot. (_a = (_b = this.renderOptions).renderBefore) !== null && _a !== void 0 ? _a : (_b.renderBefore = r return renderRoot; } /** * Updates the element. This method reflects property values to attributes * and calls `render` to render DOM via lit-html. Setting properties inside * this method will *not* trigger another update. * @param changedProperties Map of changed properties with old values * @category updates */ update(changedProperties) { // Setting properties in `render` should not trigger an update. Since // updates are allowed after super.update, it's important to call `render` // before that. const value = this.render(); if (!this.hasUpdated) { this.renderOptions.isConnected = this.isConnected; } super.update(changedProperties); this.__childPart = render(value, this.renderRoot, this.renderOptions); } /** * Invoked when the component is added to the document's DOM. * * In `connectedCallback()` you should setup tasks that should only occur when * the element is connected to the document. The most common of these is * adding event listeners to nodes external to the element, like a keydown * event handler added to the window. * * ```ts * connectedCallback() { * super.connectedCallback(); * addEventListener('keydown', this._handleKeydown); * } * ``` * * Typically, anything done in `connectedCallback()` should be undone when the * element is disconnected, in `disconnectedCallback()`. * * @category lifecycle */ connectedCallback() { var _a; super.connectedCallback(); (_a = this.__childPart) === null || _a === void 0 ? void 0 : _a.setConnected(true); } /** * Invoked when the component is removed from the document's DOM. * * This callback is the main signal to the element that it may no longer be * used. `disconnectedCallback()` should ensure that nothing is holding a * reference to the element (such as event listeners added to nodes external * to the element), so that it is free to be garbage collected. * * ```ts * disconnectedCallback() { * super.disconnectedCallback(); * window.removeEventListener('keydown', this._handleKeydown); * } * ``` * * An element may be re-connected after being disconnected. * * @category lifecycle */ disconnectedCallback() { var _a; super.disconnectedCallback(); (_a = this.__childPart) === null || _a === void 0 ? void 0 : _a.setConnected(false); } /** * Invoked on each update to perform rendering tasks. This method may return * any value renderable by lit-html's `ChildPart` - typically a * `TemplateResult`. Setting properties inside this method will *not* trigger * the element to update. * @category rendering */ render() { return noChange; } } /** * Ensure this class is marked as `finalized` as an optimization ensuring * it will not needlessly try to `finalize`. * * Note this property name is a string to prevent breaking Closure JS Compiler * optimizations. See @lit/reactive-element for more information. */ LitElement['finalized'] = true; // This property needs to remain unminified. LitElement['_$litElement$'] = true; // Install hydration if available (_b = globalThis.litElementHydrateSupport) === null || _b === void 0 ? void 0 : _b.call(global // Apply polyfills if available const polyfillSupport = globalThis.litElementPolyfillSupport; polyfillSupport === null || polyfillSupport === void 0 ? void 0 : polyfillSupport({ LitElemen /** * END USERS SHOULD NOT RELY ON THIS OBJECT. * * Private exports for use by other Lit packages, not intended for use by * external users. * * We currently do not make a mangled rollup build of the lit-ssr code. In order * to keep a number of (otherwise private) top-level exports mangled in the * client side code, we export a _$LE object containing those members (or * helper methods for accessing private fields of those members), and then * re-export them for use in lit-ssr. This keeps lit-ssr agnostic to whether the * client-side code is being used in `dev` mode or `prod` mode. * * This has a unique name, to disambiguate it from private exports in * lit-html, since this module re-exports all of lit-html. * * @private */ const _$LE = { _$attributeToProperty: (el, name, value) => { // eslint-disable-next-line el._$attributeToProperty(name, value); }, // eslint-disable-next-line _$changedProperties: (el) => el._$changedProperties, }; // IMPORTANT: do not change the property name or the assignment expression. // This line will be used in regexes to search for LitElement usage. ((_c = globalThis.litElementVersions) !== null && _c !== void 0 ? _c : (globalThis.litElementVe /** * @license * Copyright 2022 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ /** * @fileoverview * * This file exports a boolean const whose value will depend on what environment * the module is being imported from. */ const NODE_MODE = false; /** * A boolean that will be `true` in server environments like Node, and `false` * in browser environments. Note that your server environment or toolchain must * support the `"node"` export condition for this to be `true`. * * This can be used when authoring components to change behavior based on * whether or not the component is executing in an SSR context. */ const isServer = NODE_MODE; /** * @license * Copyright 2020 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ const { _ChildPart: ChildPart } = _$LH; const wrap = (node) => node; /** * Tests if a value is a primitive value. * * See https://tc39.github.io/ecma262/#sec-typeof-operator */ const isPrimitive = (value) => value === null || (typeof value != 'object' && typeof value != 'funct const TemplateResultType = { HTML: 1, SVG: 2, }; /** * Tests if a value is a TemplateResult. */ const isTemplateResult = (value, type) => type === undefined ? // This property needs to remain unminified. (value === null || value === void 0 ? void 0 : value['_$litType$']) !== undefined : (value === null || value === void 0 ? void 0 : value['_$litType$']) === type; /** * Tests if a value is a DirectiveResult. */ const isDirectiveResult = (value) => // This property needs to remain unminified. (value === null || value === void 0 ? void 0 : value['_$litDirective$']) !== undefined; /** * Retrieves the Directive class for a DirectiveResult */ const getDirectiveClass = (value) => // This property needs to remain unminified. value === null || value === void 0 ? void 0 : value['_$litDirective$']; /** * Tests whether a part has only a single-expression with no strings to * interpolate between. * * Only AttributePart and PropertyPart can have multiple expressions. * Multi-expression parts have a `strings` property and single-expression * parts do not. */ const isSingleExpression = (part) => part.strings === undefined; const createMarker = () => document.createComment(''); /** * Inserts a ChildPart into the given container ChildPart's DOM, either at the * end of the container ChildPart, or before the optional `refPart`. * * This does not add the part to the containerPart's committed value. That must * be done by callers. * * @param containerPart Part within which to add the new ChildPart * @param refPart Part before which to add the new ChildPart; when omitted the * part added to the end of the `containerPart` * @param part Part to insert, or undefined to create a new part */ const insertPart = (containerPart, refPart, part) => { var _a; const container = wrap(containerPart._$startNode).parentNode; const refNode = refPart === undefined ? containerPart._$endNode : refPart._$startNode; if (part === undefined) { const startNode = wrap(container).insertBefore(createMarker(), refNode); const endNode = wrap(container).insertBefore(createMarker(), refNode); part = new ChildPart(startNode, endNode, containerPart, containerPart.options); } else { const endNode = wrap(part._$endNode).nextSibling; const oldParent = part._$parent; const parentChanged = oldParent !== containerPart; if (parentChanged) { (_a = part._$reparentDisconnectables) === null || _a === void 0 ? void 0 : _a.call(part, contai // Note that although `_$reparentDisconnectables` updates the part's // `_$parent` reference after unlinking from its current parent, that // method only exists if Disconnectables are present, so we need to // unconditionally set it here part._$parent = containerPart; // Since the _$isConnected getter is somewhat costly, only // read it once we know the subtree has directives that need // to be notified let newConnectionState; if (part._$notifyConnectionChanged !== undefined && (newConnectionState = containerPart._$isConnected) !== oldParent._$isConnected) { part._$notifyConnectionChanged(newConnectionState); } } if (endNode !== refNode || parentChanged) { let start = part._$startNode; while (start !== endNode) { const n = wrap(start).nextSibling; wrap(container).insertBefore(start, refNode); start = n; } } } return part; }; /** * Sets the value of a Part. * * Note that this should only be used to set/update the value of user-created * parts (i.e. those created using `insertPart`); it should not be used * by directives to set the value of the directive's container part. Directives * should return a value from `update`/`render` to update their part state. * * For directives that require setting their part value asynchronously, they * should extend `AsyncDirective` and call `this.setValue()`. * * @param part Part to set * @param value Value to set * @param index For `AttributePart`s, the index to set * @param directiveParent Used internally; should not be set by user */ const setChildPartValue = (part, value, directiveParent = part) => { part._$setValue(value, directiveParent); return part; }; // A sentinal value that can never appear as a part value except when set by // live(). Used to force a dirty-check to fail and cause a re-render. const RESET_VALUE = {}; /** * Sets the committed value of a ChildPart directly without triggering the * commit stage of the part. * * This is useful in cases where a directive needs to update the part such * that the next update detects a value change or not. When value is omitted, * the next update will be guaranteed to be detected as a change. * * @param part * @param value */ const setCommittedValue = (part, value = RESET_VALUE) => (part._$committedValue = value); /** * Returns the committed value of a ChildPart. * * The committed value is used for change detection and efficient updates of * the part. It can differ from the value set by the template or directive in * cases where the template value is transformed before being commited. * * - `TemplateResult`s are committed as a `TemplateInstance` * - Iterables are committed as `Array<ChildPart>` * - All other types are committed as the template value or value returned or * set by a directive. * * @param part */ const getCommittedValue = (part) => part._$committedValue; /** * Removes a ChildPart from the DOM, including any of its content. * * @param part The Part to remove */ const removePart = (part) => { var _a; (_a = part._$notifyConnectionChanged) === null || _a === void 0 ? void 0 : _a.call(part, false, let start = part._$startNode; const end = wrap(part._$endNode).nextSibling; while (start !== end) { const n = wrap(start).nextSibling; wrap(start).remove(); start = n; } }; const clearPart = (part) => { part._$clear(); }; /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ const PartType = { ATTRIBUTE: 1, CHILD: 2, PROPERTY: 3, BOOLEAN_ATTRIBUTE: 4, EVENT: 5, ELEMENT: 6, }; /** * Creates a user-facing directive function from a Directive class. This * function has the same parameters as the directive's render() method. */ const directive = (c) => (...values) => ({ // This property needs to remain unminified. ['_$litDirective$']: c, values, }); /** * Base class for creating custom directives. Users should extend this class, * implement `render` and/or `update`, and then pass their subclass to * `directive`. */ class Directive { constructor(_partInfo) { } // See comment in Disconnectable interface for why this is a getter get _$isConnected() { return this._$parent._$isConnected; } /** @internal */ _$initialize(part, parent, attributeIndex) { this.__part = part; this._$parent = parent; this.__attributeIndex = attributeIndex; } /** @internal */ _$resolve(part, props) { return this.update(part, props); } update(_part, props) { return this.render(...props); } } /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ /** * Recursively walks down the tree of Parts/TemplateInstances/Directives to set * the connected state of directives and run `disconnected`/ `reconnected` * callbacks. * * @return True if there were children to disconnect; false otherwise */ const notifyChildrenConnectedChanged = (parent, isConnected) => { var _a, _b; const children = parent._$disconnectableChildren; if (children === undefined) { return false; } for (const obj of children) { // The existence of `_$notifyDirectiveConnectionChanged` is used as a "brand" to // disambiguate AsyncDirectives from other DisconnectableChildren // (as opposed to using an instanceof check to know when to call it); the // redundancy of "Directive" in the API name is to avoid conflicting with // `_$notifyConnectionChanged`, which exists `ChildParts` which are also in // this list // Disconnect Directive (and any nested directives contained within) // This property needs to remain unminified. (_b = (_a = obj)['_$notifyDirectiveConnectionChanged']) === null || _b === void 0 ? void 0 : _b. // Disconnect Part/TemplateInstance notifyChildrenConnectedChanged(obj, isConnected); } return true; }; /** * Removes the given child from its parent list of disconnectable children, and * if the parent list becomes empty as a result, removes the parent from its * parent, and so forth up the tree when that causes subsequent parent lists to * become empty. */ const removeDisconnectableFromParent = (obj) => { let parent, children; do { if ((parent = obj._$parent) === undefined) { break; } children = parent._$disconnectableChildren; children.delete(obj); obj = parent; } while ((children === null || children === void 0 ? void 0 : children.size) === 0); }; const addDisconnectableToParent = (obj) => { // Climb the parent tree, creating a sparse tree of children needing // disconnection for (let parent; (parent = obj._$parent); obj = parent) { let children = parent._$disconnectableChildren; if (children === undefined) { parent._$disconnectableChildren = children = new Set(); } else if (children.has(obj)) { // Once we've reached a parent that already contains this child, we // can short-circuit break; } children.add(obj); installDisconnectAPI(parent); } }; /** * Changes the parent reference of the ChildPart, and updates the sparse tree of * Disconnectable children accordingly. * * Note, this method will be patched onto ChildPart instances and called from * the core code when parts are moved between different parents. */ function reparentDisconnectables(newParent) { if (this._$disconnectableChildren !== undefined) { removeDisconnectableFromParent(this); this._$parent = newParent; addDisconnectableToParent(this); } else { this._$parent = newParent; } } /** * Sets the connected state on any directives contained within the committed * value of this part (i.e. within a TemplateInstance or iterable of * ChildParts) and runs their `disconnected`/`reconnected`s, as well as within * any directives stored on the ChildPart (when `valueOnly` is false). * * `isClearingValue` should be passed as `true` on a top-level part that is * clearing itself, and not as a result of recursively disconnecting directives * as part of a `clear` operation higher up the tree. This both ensures that any * directive on this ChildPart that produced a value that caused the clear * operation is not disconnected, and also serves as a performance optimization * to avoid needless bookkeeping when a subtree is going away; when clearing a * subtree, only the top-most part need to remove itself from the parent. * * `fromPartIndex` is passed only in the case of a partial `_clear` running as a * result of truncating an iterable. * * Note, this method will be patched onto ChildPart instances and called from the * core code when parts are cleared or the connection state is changed by the * user. */ function notifyChildPartConnectedChanged(isConnected, isClearingValue = false, fromPa const value = this._$committedValue; const children = this._$disconnectableChildren; if (children === undefined || children.size === 0) { return; } if (isClearingValue) { if (Array.isArray(value)) { // Iterable case: Any ChildParts created by the iterable should be // disconnected and removed from this ChildPart's disconnectable // children (starting at `fromPartIndex` in the case of truncation) for (let i = fromPartIndex; i < value.length; i++) { notifyChildrenConnectedChanged(value[i], false); removeDisconnectableFromParent(value[i]); } } else if (value != null) { // TemplateInstance case: If the value has disconnectable children (will // only be in the case that it is a TemplateInstance), we disconnect it // and remove it from this ChildPart's disconnectable children notifyChildrenConnectedChanged(value, false); removeDisconnectableFromParent(value); } } else { notifyChildrenConnectedChanged(this, isConnected); } } /** * Patches disconnection API onto ChildParts. */ const installDisconnectAPI = (obj) => { var _a, _b; var _c, _d; if (obj.type == PartType.CHILD) { (_a = (_c = obj)._$notifyConnectionChanged) !== null && _a !== void 0 ? _a : (_c._$notifyConnecti (_b = (_d = obj)._$reparentDisconnectables) !== null && _b !== void 0 ? _b : (_d._$reparentDiscon } }; /** * An abstract `Directive` base class whose `disconnected` method will be * called when the part containing the directive is cleared as a result of * re-rendering, or when the user calls `part.setConnected(false)` on * a part that was previously rendered containing the directive (as happens * when e.g. a LitElement disconnects from the DOM). * * If `part.setConnected(true)` is subsequently called on a * containing part, the directive's `reconnected` method will be called prior * to its next `update`/`render` callbacks. When implementing `disconnected`, * `reconnected` should also be implemented to be compatible with reconnection. * * Note that updates may occur while the directive is disconnected. As such, * directives should generally check the `this.isConnected` flag during * render/update to determine whether it is safe to subscribe to resources * that may prevent garbage collection. */ class AsyncDirective extends Directive { constructor() { super(...arguments); // @internal this._$disconnectableChildren = undefined; } /** * Initialize the part with internal fields * @param part * @param parent * @param attributeIndex */ _$initialize(part, parent, attributeIndex) { super._$initialize(part, parent, attributeIndex); addDisconnectableToParent(this); this.isConnected = part._$isConnected; } // This property needs to remain unminified. /** * Called from the core code when a directive is going away from a part (in * which case `shouldRemoveFromParent` should be true), and from the * `setChildrenConnected` helper function when recursively changing the * connection state of a tree (in which case `shouldRemoveFromParent` should * be false). * * @param isConnected * @param isClearingDirective - True when the directive itself is being * removed; false when the tree is being disconnected * @internal */ ['_$notifyDirectiveConnectionChanged'](isConnected, isClearingDirective = true) { var _a, _b; if (isConnected !== this.isConnected) { this.isConnected = isConnected; if (isConnected) { (_a = this.reconnected) === null || _a === void 0 ? void 0 : _a.call(this); } else { (_b = this.disconnected) === null || _b === void 0 ? void 0 : _b.call(this); } } if (isClearingDirective) { notifyChildrenConnectedChanged(this, isConnected); removeDisconnectableFromParent(this); } } /** * Sets the value of the directive's Part outside the normal `update`/`render` * lifecycle of a directive. * * This method should not be called synchronously from a directive's `update` * or `render`. * * @param directive The directive to update * @param value The value to set */ setValue(value) { if (isSingleExpression(this.__part)) { this.__part._$setValue(value, this); } else { const newValues = [...this.__part._$committedValue]; newValues[this.__attributeIndex] = value; this.__part._$setValue(newValues, this, 0); } } /** * User callbacks for implementing logic to release any resources/subscriptions * that may have been retained by this directive. Since directives may also be * re-connected, `reconnected` should also be implemented to restore the * working state of the directive prior to the next render. */ disconnected() { } reconnected() { } } /** * @license * Copyright 2021 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ // Note, this module is not included in package exports so that it's private to // our first-party directives. If it ends up being useful, we can open it up and // export it. /** * Helper to iterate an AsyncIterable in its own closure. * @param iterable The iterable to iterate * @param callback The callback to call for each value. If the callback returns * `false`, the loop will be broken. */ const forAwaitOf = async (iterable, callback) => { for await (const v of iterable) { if ((await callback(v)) === false) { return; } } }; /** * Holds a reference to an instance that can be disconnected and reconnected, * so that a closure over the ref (e.g. in a then function to a promise) does * not strongly hold a ref to the instance. Approximates a WeakRef but must * be manually connected & disconnected to the backing instance. */ class PseudoWeakRef { constructor(ref) { this._ref = ref; } /** * Disassociates the ref with the backing instance. */ disconnect() { this._ref = undefined; } /** * Reassociates the ref with the backing instance. */ reconnect(ref) { this._ref = ref; } /** * Retrieves the backing instance (will be undefined when disconnected) */ deref() { return this._ref; } } /** * A helper to pause and resume waiting on a condition in an async function */ class Pauser { constructor() { this._promise = undefined; this._resolve = undefined; } /** * When paused, returns a promise to be awaited; when unpaused, returns * undefined. Note that in the microtask between the pauser being resumed * an an await of this promise resolving, the pauser could be paused again, * hence callers should check the promise in a loop when awaiting. * @returns A promise to be awaited when paused or undefined */ get() { return this._promise; } /** * Creates a promise to be awaited */ pause() { var _a; (_a = this._promise) !== null && _a !== void 0 ? _a : (this._promise = new Promise((resolve) => (this } /** * Resolves the promise which may be awaited */ resume() { var _a; (_a = this._resolve) === null || _a === void 0 ? void 0 : _a.call(this); this._promise = this._resolve = undefined; } } /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ class AsyncReplaceDirective extends AsyncDirective { constructor() { super(...arguments); this.__weakThis = new PseudoWeakRef(this); this.__pauser = new Pauser(); } // @ts-expect-error value not used, but we want a nice parameter for docs // eslint-disable-next-line @typescript-eslint/no-unused-vars render(value, _mapper) { return noChange; } update(_part, [value, mapper]) { // If our initial render occurs while disconnected, ensure that the pauser // and weakThis are in the disconnected state if (!this.isConnected) { this.disconnected(); } // If we've already set up this particular iterable, we don't need // to do anything. if (value === this.__value) { return; } this.__value = value; let i = 0; const { __weakThis: weakThis, __pauser: pauser } = this; // Note, the callback avoids closing over `this` so that the directive // can be gc'ed before the promise resolves; instead `this` is retrieved // from `weakThis`, which can break the hard reference in the closure when // the directive disconnects forAwaitOf(value, async (v) => { // The while loop here handles the case that the connection state // thrashes, causing the pauser to resume and then get re-paused while (pauser.get()) { await pauser.get(); } // If the callback gets here and there is no `this`, it means that the // directive has been disconnected and garbage collected and we don't // need to do anything else const _this = weakThis.deref(); if (_this !== undefined) { // Check to make sure that value is the still the current value of // the part, and if not bail because a new value owns this part if (_this.__value !== value) { return false; } // As a convenience, because functional-programming-style // transforms of iterables and async iterables requires a library, // we accept a mapper function. This is especially convenient for // rendering a template for each item. if (mapper !== undefined) { v = mapper(v, i); } _this.commitValue(v, i); i++; } return true; }); return noChange; } // Override point for AsyncAppend to append rather than replace commitValue(value, _index) { this.setValue(value); } disconnected() { this.__weakThis.disconnect(); this.__pauser.pause(); } reconnected() { this.__weakThis.reconnect(this); this.__pauser.resume(); } } /** * A directive that renders the items of an async iterable[1], replacing * previous values with new values, so that only one value is ever rendered * at a time. This directive may be used in any expression type. * * Async iterables are objects with a `[Symbol.asyncIterator]` method, which * returns an iterator who's `next()` method returns a Promise. When a new * value is available, the Promise resolves and the value is rendered to the * Part controlled by the directive. If another value other than this * directive has been set on the Part, the iterable will no longer be listened * to and new values won't be written to the Part. * * [1]: https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Statement * * @param value An async iterable * @param mapper An optional function that maps from (value, index) to another * value. Useful for generating templates for each item in the iterable. */ const asyncReplace = directive(AsyncReplaceDirective); /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ class AsyncAppendDirective extends AsyncReplaceDirective { // Override AsyncReplace to narrow the allowed part type to ChildPart only constructor(partInfo) { super(partInfo); if (partInfo.type !== PartType.CHILD) { throw new Error('asyncAppend can only be used in child expressions'); } } // Override AsyncReplace to save the part since we need to append into it update(part, params) { this.__childPart = part; return super.update(part, params); } // Override AsyncReplace to append rather than replace commitValue(value, index) { // When we get the first value, clear the part. This lets the // previous value display until we can replace it. if (index === 0) { clearPart(this.__childPart); } // Create and insert a new part and set its value to the next value const newPart = insertPart(this.__childPart); setChildPartValue(newPart, value); } } /** * A directive that renders the items of an async iterable[1], appending new * values after previous values, similar to the built-in support for iterables. * This directive is usable only in child expressions. * * Async iterables are objects with a [Symbol.asyncIterator] method, which * returns an iterator who's `next()` method returns a Promise. When a new * value is available, the Promise resolves and the value is appended to the * Part controlled by the directive. If another value other than this * directive has been set on the Part, the iterable will no longer be listened * to and new values won't be written to the Part. * * [1]: https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Statement * * @param value An async iterable * @param mapper An optional function that maps from (value, index) to another * value. Useful for generating templates for each item in the iterable. */ const asyncAppend = directive(AsyncAppendDirective); /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ class CacheDirective extends Directive { constructor(partInfo) { super(partInfo); this._templateCache = new WeakMap(); } render(v) { // Return an array of the value to induce lit-html to create a ChildPart // for the value that we can move into the cache. return [v]; } update(containerPart, [v]) { // If the previous value is a TemplateResult and the new value is not, // or is a different Template as the previous value, move the child part // into the cache. if (isTemplateResult(this._value) && (!isTemplateResult(v) || this._value.strings !== v.strings)) { // This is always an array because we return [v] in render() const partValue = getCommittedValue(containerPart); const childPart = partValue.pop(); let cachedContainerPart = this._templateCache.get(this._value.strings); if (cachedContainerPart === undefined) { const fragment = document.createDocumentFragment(); cachedContainerPart = render(nothing, fragment); cachedContainerPart.setConnected(false); this._templateCache.set(this._value.strings, cachedContainerPart); } // Move into cache setCommittedValue(cachedContainerPart, [childPart]); insertPart(cachedContainerPart, undefined, childPart); } // If the new value is a TemplateResult and the previous value is not, // or is a different Template as the previous value, restore the child // part from the cache. if (isTemplateResult(v)) { if (!isTemplateResult(this._value) || this._value.strings !== v.strings) { const cachedContainerPart = this._templateCache.get(v.strings); if (cachedContainerPart !== undefined) { // Move the cached part back into the container part value const partValue = getCommittedValue(cachedContainerPart); const cachedPart = partValue.pop(); // Move cached part back into DOM clearPart(containerPart); insertPart(containerPart, undefined, cachedPart); setCommittedValue(containerPart, [cachedPart]); } } this._value = v; } else { this._value = undefined; } return this.render(v); } } /** * Enables fast switching between multiple templates by caching the DOM nodes * and TemplateInstances produced by the templates. * * Example: * * ```js * let checked = false; * * html` * ${cache(checked ? html`input is checked` : html`input is not checked`)} * ` * ``` */ const cache = directive(CacheDirective); /** * @license * Copyright 2021 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ /** * Chooses and evaluates a template function from a list based on matching * the given `value` to a case. * * Cases are structured as `[caseValue, func]`. `value` is matched to * `caseValue` by strict equality. The first match is selected. Case values * can be of any type including primitives, objects, and symbols. * * This is similar to a switch statement, but as an expression and without * fallthrough. * * @example * * ```ts * render() { * return html` * ${choose(this.section, [ * ['home', () => html`<h1>Home</h1>`], * ['about', () => html`<h1>About</h1>`] * ], * () => html`<h1>Error</h1>`)} * `; * } * ``` */ const choose = (value, cases, defaultCase) => { for (const c of cases) { const caseValue = c[0]; if (caseValue === value) { const fn = c[1]; return fn(); } } return defaultCase === null || defaultCase === void 0 ? void 0 : defaultCase(); }; /** * @license * Copyright 2018 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ class ClassMapDirective extends Directive { constructor(partInfo) { var _a; super(partInfo); if (partInfo.type !== PartType.ATTRIBUTE || partInfo.name !== 'class' || ((_a = partInfo.strings) === null || _a === void 0 ? void 0 : _a.length) > 2) { throw new Error('`classMap()` can only be used in the `class` attribute ' + 'and must be the only part in the attribute.'); } } render(classInfo) { // Add spaces to ensure separation from static classes return (' ' + Object.keys(classInfo) .filter((key) => classInfo[key]) .join(' ') + ' '); } update(part, [classInfo]) { var _a, _b; // Remember dynamic classes on the first render if (this._previousClasses === undefined) { this._previousClasses = new Set(); if (part.strings !== undefined) { this._staticClasses = new Set(part.strings .join(' ') .split(/\s/) .filter((s) => s !== '')); } for (const name in classInfo) { if (classInfo[name] && !((_a = this._staticClasses) === null || _a === void 0 ? void 0 : _a.has(nam this._previousClasses.add(name); } } return this.render(classInfo); } const classList = part.element.classList; // Remove old classes that no longer apply // We use forEach() instead of for-of so that we don't require down-level // iteration. this._previousClasses.forEach((name) => { if (!(name in classInfo)) { classList.remove(name); this._previousClasses.delete(name); } }); // Add or remove classes based on their classMap value for (const name in classInfo) { // We explicitly want a loose truthy check of `value` because it seems // more convenient that '' and 0 are skipped. const value = !!classInfo[name]; if (value !== this._previousClasses.has(name) && !((_b = this._staticClasses) === null || _b === void 0 ? void 0 : _b.has(name))) { if (value) { classList.add(name); this._previousClasses.add(name); } else { classList.remove(name); this._previousClasses.delete(name); } } } return noChange; } } /** * A directive that applies dynamic CSS classes. * * This must be used in the `class` attribute and must be the only part used in * the attribute. It takes each property in the `classInfo` argument and adds * the property name to the element's `classList` if the property value is * truthy; if the property value is falsey, the property name is removed from * the element's `class`. * * For example `{foo: bar}` applies the class `foo` if the value of `bar` is * truthy. * * @param classInfo */ const classMap = directive(ClassMapDirective); /** * @license * Copyright 2018 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ // A sentinal that indicates guard() hasn't rendered anything yet const initialValue = {}; class GuardDirective extends Directive { constructor() { super(...arguments); this._previousValue = initialValue; } render(_value, f) { return f(); } update(_part, [value, f]) { if (Array.isArray(value)) { // Dirty-check arrays by item if (Array.isArray(this._previousValue) && this._previousValue.length === value.length && value.every((v, i) => v === this._previousValue[i])) { return noChange; } } else if (this._previousValue === value) { // Dirty-check non-arrays by identity return noChange; } // Copy the value if it's an array so that if it's mutated we don't forget // what the previous values were. this._previousValue = Array.isArray(value) ? Array.from(value) : value; const r = this.render(value, f); return r; } } /** * Prevents re-render of a template function until a single value or an array of * values changes. * * Values are checked against previous values with strict equality (`===`), and * so the check won't detect nested property changes inside objects or arrays. * Arrays values have each item checked against the previous value at the same * index with strict equality. Nested arrays are also checked only by strict * equality. * * Example: * * ```js * html` * <div> * ${guard([user.id, company.id], () => html`...`)} * </div> * ` * ``` * * In this case, the template only rerenders if either `user.id` or `company.id` * changes. * * guard() is useful with immutable data patterns, by preventing expensive work * until data updates. * * Example: * * ```js * html` * <div> * ${guard([immutableItems], () => immutableItems.map(i => html`${i}`))} * </div> * ` * ``` * * In this case, items are mapped over only when the array reference changes. * * @param value the value to check before re-rendering * @param f the template function */ const guard = directive(GuardDirective); /** * @license * Copyright 2018 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ /** * For AttributeParts, sets the attribute if the value is defined and removes * the attribute if the value is undefined. * * For other part types, this directive is a no-op. */ const ifDefined = (value) => value !== null && value !== void 0 ? value : nothing; /** * @license * Copyright 2021 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ function* join(items, joiner) { const isFunction = typeof joiner === 'function'; if (items !== undefined) { let i = -1; for (const value of items) { if (i > -1) { yield isFunction ? joiner(i) : joiner; } i++; yield value; } } } /** * @license * Copyright 2021 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ class Keyed extends Directive { constructor() { super(...arguments); this.key = nothing; } render(k, v) { this.key = k; return v; } update(part, [k, v]) { if (k !== this.key) { // Clear the part before returning a value. The one-arg form of // setCommittedValue sets the value to a sentinel which forces a // commit the next render. setCommittedValue(part); this.key = k; } return v; } } /** * Associates a renderable value with a unique key. When the key changes, the * previous DOM is removed and disposed before rendering the next value, even * if the value - such as a template - is the same. * * This is useful for forcing re-renders of stateful components, or working * with code that expects new data to generate new HTML elements, such as some * animation techniques. */ const keyed = directive(Keyed); /** * @license * Copyright 2020 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ class LiveDirective extends Directive { constructor(partInfo) { super(partInfo); if (!(partInfo.type === PartType.PROPERTY || partInfo.type === PartType.ATTRIBUTE || partInfo.type === PartType.BOOLEAN_ATTRIBUTE)) { throw new Error('The `live` directive is not allowed on child or event bindings'); } if (!isSingleExpression(partInfo)) { throw new Error('`live` bindings can only contain a single expression'); } } render(value) { return value; } update(part, [value]) { if (value === noChange || value === nothing) { return value; } const element = part.element; const name = part.name; if (part.type === PartType.PROPERTY) { // eslint-disable-next-line @typescript-eslint/no-explicit-any if (value === element[name]) { return noChange; } } else if (part.type === PartType.BOOLEAN_ATTRIBUTE) { if (!!value === element.hasAttribute(name)) { return noChange; } } else if (part.type === PartType.ATTRIBUTE) { if (element.getAttribute(name) === String(value)) { return noChange; } } // Resets the part's value, causing its dirty-check to fail so that it // always sets the value. setCommittedValue(part); return value; } } /** * Checks binding values against live DOM values, instead of previously bound * values, when determining whether to update the value. * * This is useful for cases where the DOM value may change from outside of * lit-html, such as with a binding to an `<input>` element's `value` property, * a content editable elements text, or to a custom element that changes it's * own properties or attributes. * * In these cases if the DOM value changes, but the value set through lit-html * bindings hasn't, lit-html won't know to update the DOM value and will leave * it alone. If this is not what you want--if you want to overwrite the DOM * value with the bound value no matter what--use the `live()` directive: * * ```js * html`<input .value=${live(x)}>` * ``` * * `live()` performs a strict equality check against the live DOM value, and if * the new value is equal to the live value, does nothing. This means that * `live()` should not be used when the binding will cause a type conversion. If * you use `live()` with an attribute binding, make sure that only strings are * passed in, or the binding will update every render. */ const live = directive(LiveDirective); /** * @license * Copyright 2021 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ /** * Returns an iterable containing the result of calling `f(value)` on each * value in `items`. * * @example * * ```ts * render() { * return html` * <ul> * ${map(items, (i) => html`<li>${i}</li>`)} * </ul> * `; * } * ``` */ function* map(items, f) { if (items !== undefined) { let i = 0; for (const value of items) { yield f(value, i++); } } } /** * @license * Copyright 2021 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ function* range(startOrEnd, end, step = 1) { const start = end === undefined ? 0 : startOrEnd; end !== null && end !== void 0 ? end : (end = startOrEnd); for (let i = start; step > 0 ? i < end : end < i; i += step) { yield i; } } /** * @license * Copyright 2020 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ /** * Creates a new Ref object, which is container for a reference to an element. */ const createRef = () => new Ref(); /** * An object that holds a ref value. */ class Ref { } // When callbacks are used for refs, this map tracks the last value the callback // was called with, for ensuring a directive doesn't clear the ref if the ref // has already been rendered to a new spot. It is double-keyed on both the // context (`options.host`) and the callback, since we auto-bind class methods // to `options.host`. const lastElementForContextAndCallback = new WeakMap(); class RefDirective extends AsyncDirective { render(_ref) { return nothing; } update(part, [ref]) { var _a; const refChanged = ref !== this._ref; if (refChanged && this._ref !== undefined) { // The ref passed to the directive has changed; // unset the previous ref's value this._updateRefValue(undefined); } if (refChanged || this._lastElementForRef !== this._element) { // We either got a new ref or this is the first render; // store the ref/element & update the ref value this._ref = ref; this._context = (_a = part.options) === null || _a === void 0 ? void 0 : _a.host; this._updateRefValue((this._element = part.element)); } return nothing; } _updateRefValue(element) { var _a; if (typeof this._ref === 'function') { // If the current ref was called with a previous value, call with // `undefined`; We do this to ensure callbacks are called in a consistent // way regardless of whether a ref might be moving up in the tree (in // which case it would otherwise be called with the new value before the // previous one unsets it) and down in the tree (where it would be unset // before being set). Note that element lookup is keyed by // both the context and the callback, since we allow passing unbound // functions that are called on options.host, and we want to treat // these as unique "instances" of a function. const context = (_a = this._context) !== null && _a !== void 0 ? _a : globalThis; let lastElementForCallback = lastElementForContextAndCallback.get(context); if (lastElementForCallback === undefined) { lastElementForCallback = new WeakMap(); lastElementForContextAndCallback.set(context, lastElementForCallback); } if (lastElementForCallback.get(this._ref) !== undefined) { this._ref.call(this._context, undefined); } lastElementForCallback.set(this._ref, element); // Call the ref with the new element value if (element !== undefined) { this._ref.call(this._context, element); } } else { this._ref.value = element; } } get _lastElementForRef() { var _a, _b, _c; return typeof this._ref === 'function' ? (_b = lastElementForContextAndCallback .get((_a = this._context) !== null && _a !== void 0 ? _a : globalThis)) === null || _b === void 0 ? void : (_c = this._ref) === null || _c === void 0 ? void 0 : _c.value; } disconnected() { // Only clear the box if our element is still the one in it (i.e. another // directive instance hasn't rendered its element to it before us); that // only happens in the event of the directive being cleared (not via manual // disconnection) if (this._lastElementForRef === this._element) { this._updateRefValue(undefined); } } reconnected() { // If we were manually disconnected, we can safely put our element back in // the box, since no rendering could have occurred to change its state this._updateRefValue(this._element); } } /** * Sets the value of a Ref object or calls a ref callback with the element it's * bound to. * * A Ref object acts as a container for a reference to an element. A ref * callback is a function that takes an element as its only argument. * * The ref directive sets the value of the Ref object or calls the ref callback * during rendering, if the referenced element changed. * * Note: If a ref callback is rendered to a different element position or is * removed in a subsequent render, it will first be called with `undefined`, * followed by another call with the new element it was rendered to (if any). * * ```js * // Using Ref object * const inputRef = createRef(); * render(html`<input ${ref(inputRef)}>`, container); * inputRef.value.focus(); * * // Using callback * const callback = (inputElement) => inputElement.focus(); * render(html`<input ${ref(callback)}>`, container); * ``` */ const ref = directive(RefDirective); /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ // Helper for generating a map of array item to its index over a subset // of an array (used to lazily generate `newKeyToIndexMap` and // `oldKeyToIndexMap`) const generateMap = (list, start, end) => { const map = new Map(); for (let i = start; i <= end; i++) { map.set(list[i], i); } return map; }; class RepeatDirective extends Directive { constructor(partInfo) { super(partInfo); if (partInfo.type !== PartType.CHILD) { throw new Error('repeat() can only be used in text expressions'); } } _getValuesAndKeys(items, keyFnOrTemplate, template) { let keyFn; if (template === undefined) { template = keyFnOrTemplate; } else if (keyFnOrTemplate !== undefined) { keyFn = keyFnOrTemplate; } const keys = []; const values = []; let index = 0; for (const item of items) { keys[index] = keyFn ? keyFn(item, index) : index; values[index] = template(item, index); index++; } return { values, keys, }; } render(items, keyFnOrTemplate, template) { return this._getValuesAndKeys(items, keyFnOrTemplate, template).values; } update(containerPart, [items, keyFnOrTemplate, template]) { var _a; // Old part & key lists are retrieved from the last update (which may // be primed by hydration) const oldParts = getCommittedValue(containerPart); const { values: newValues, keys: newKeys } = this._getValuesAndKeys(items, keyFnOrTemplat // We check that oldParts, the committed value, is an Array as an // indicator that the previous value came from a repeat() call. If // oldParts is not an Array then this is the first render and we return // an array for lit-html's array handling to render, and remember the // keys. if (!Array.isArray(oldParts)) { this._itemKeys = newKeys; return newValues; } // In SSR hydration it's possible for oldParts to be an arrray but for us // to not have item keys because the update() hasn't run yet. We set the // keys to an empty array. This will cause all oldKey/newKey comparisons // to fail and execution to fall to the last nested brach below which // reuses the oldPart. const oldKeys = ((_a = this._itemKeys) !== null && _a !== void 0 ? _a : (this._itemKeys = [])); // New part list will be built up as we go (either reused from // old parts or created for new keys in this update). This is // saved in the above cache at the end of the update. const newParts = []; // Maps from key to index for current and previous update; these // are generated lazily only when needed as a performance // optimization, since they are only required for multiple // non-contiguous changes in the list, which are less common. let newKeyToIndexMap; let oldKeyToIndexMap; // Head and tail pointers to old parts and new values let oldHead = 0; let oldTail = oldParts.length - 1; let newHead = 0; let newTail = newValues.length - 1; // Overview of O(n) reconciliation algorithm (general approach // based on ideas found in ivi, vue, snabbdom, etc.): // // * We start with the list of old parts and new values (and // arrays of their respective keys), head/tail pointers into // each, and we build up the new list of parts by updating // (and when needed, moving) old parts or creating new ones. // The initial scenario might look like this (for brevity of // the diagrams, the numbers in the array reflect keys // associated with the old parts or new values, although keys // and parts/values are actually stored in parallel arrays // indexed using the same head/tail pointers): // // oldHead v v oldTail // oldKeys: [0, 1, 2, 3, 4, 5, 6] // newParts: [ , , , , , , ] // newKeys: [0, 2, 1, 4, 3, 7, 6] <- reflects the user's new // item order // newHead ^ ^ newTail // // * Iterate old & new lists from both sides, updating, // swapping, or removing parts at the head/tail locations // until neither head nor tail can move. // // * Example below: keys at head pointers match, so update old // part 0 in-place (no need to move it) and record part 0 in // the `newParts` list. The last thing we do is advance the // `oldHead` and `newHead` pointers (will be reflected in the // next diagram). // // oldHead v v oldTail // oldKeys: [0, 1, 2, 3, 4, 5, 6] // newParts: [0, , , , , , ] <- heads matched: update 0 // newKeys: [0, 2, 1, 4, 3, 7, 6] and advance both oldHead // & newHead // newHead ^ ^ newTail // // * Example below: head pointers don't match, but tail // pointers do, so update part 6 in place (no need to move // it), and record part 6 in the `newParts` list. Last, // advance the `oldTail` and `oldHead` pointers. // // oldHead v v oldTail // oldKeys: [0, 1, 2, 3, 4, 5, 6] // newParts: [0, , , , , , 6] <- tails matched: update 6 // newKeys: [0, 2, 1, 4, 3, 7, 6] and advance both oldTail // & newTail // newHead ^ ^ newTail // // * If neither head nor tail match; next check if one of the // old head/tail items was removed. We first need to generate // the reverse map of new keys to index (`newKeyToIndexMap`), // which is done once lazily as a performance optimization, // since we only hit this case if multiple non-contiguous // changes were made. Note that for contiguous removal // anywhere in the list, the head and tails would advance // from either end and pass each other before we get to this // case and removals would be handled in the final while loop // without needing to generate the map. // // * Example below: The key at `oldTail` was removed (no longer // in the `newKeyToIndexMap`), so remove that part from the // DOM and advance just the `oldTail` pointer. // // oldHead v v oldTail // oldKeys: [0, 1, 2, 3, 4, 5, 6] // newParts: [0, , , , , , 6] <- 5 not in new map: remove // newKeys: [0, 2, 1, 4, 3, 7, 6] 5 and advance oldTail // newHead ^ ^ newTail // // * Once head and tail cannot move, any mismatches are due to // either new or moved items; if a new key is in the previous // "old key to old index" map, move the old part to the new // location, otherwise create and insert a new part. Note // that when moving an old part we null its position in the // oldParts array if it lies between the head and tail so we // know to skip it when the pointers get there. // // * Example below: neither head nor tail match, and neither // were removed; so find the `newHead` key in the // `oldKeyToIndexMap`, and move that old part's DOM into the // next head position (before `oldParts[oldHead]`). Last, // null the part in the `oldPart` array since it was // somewhere in the remaining oldParts still to be scanned // (between the head and tail pointers) so that we know to // skip that old part on future iterations. // // oldHead v v oldTail // oldKeys: [0, 1, -, 3, 4, 5, 6] // newParts: [0, 2, , , , , 6] <- stuck: update & move 2 // newKeys: [0, 2, 1, 4, 3, 7, 6] into place and advance // newHead // newHead ^ ^ newTail // // * Note that for moves/insertions like the one above, a part // inserted at the head pointer is inserted before the // current `oldParts[oldHead]`, and a part inserted at the // tail pointer is inserted before `newParts[newTail+1]`. The // seeming asymmetry lies in the fact that new parts are // moved into place outside in, so to the right of the head // pointer are old parts, and to the right of the tail // pointer are new parts. // // * We always restart back from the top of the algorithm, // allowing matching and simple updates in place to // continue... // // * Example below: the head pointers once again match, so // simply update part 1 and record it in the `newParts` // array. Last, advance both head pointers. // // oldHead v v oldTail // oldKeys: [0, 1, -, 3, 4, 5, 6] // newParts: [0, 2, 1, , , , 6] <- heads matched: update 1 // newKeys: [0, 2, 1, 4, 3, 7, 6] and advance both oldHead // & newHead // newHead ^ ^ newTail // // * As mentioned above, items that were moved as a result of // being stuck (the final else clause in the code below) are // marked with null, so we always advance old pointers over // these so we're comparing the next actual old value on // either end. // // * Example below: `oldHead` is null (already placed in // newParts), so advance `oldHead`. // // oldHead v v oldTail // oldKeys: [0, 1, -, 3, 4, 5, 6] <- old head already used: // newParts: [0, 2, 1, , , , 6] advance oldHead // newKeys: [0, 2, 1, 4, 3, 7, 6] // newHead ^ ^ newTail // // * Note it's not critical to mark old parts as null when they // are moved from head to tail or tail to head, since they // will be outside the pointer range and never visited again. // // * Example below: Here the old tail key matches the new head // key, so the part at the `oldTail` position and move its // DOM to the new head position (before `oldParts[oldHead]`). // Last, advance `oldTail` and `newHead` pointers. // // oldHead v v oldTail // oldKeys: [0, 1, -, 3, 4, 5, 6] // newParts: [0, 2, 1, 4, , , 6] <- old tail matches new // newKeys: [0, 2, 1, 4, 3, 7, 6] head: update & move 4, // advance oldTail & newHead // newHead ^ ^ newTail // // * Example below: Old and new head keys match, so update the // old head part in place, and advance the `oldHead` and // `newHead` pointers. // // oldHead v oldTail // oldKeys: [0, 1, -, 3, 4, 5, 6] // newParts: [0, 2, 1, 4, 3, ,6] <- heads match: update 3 // newKeys: [0, 2, 1, 4, 3, 7, 6] and advance oldHead & // newHead // newHead ^ ^ newTail // // * Once the new or old pointers move past each other then all // we have left is additions (if old list exhausted) or // removals (if new list exhausted). Those are handled in the // final while loops at the end. // // * Example below: `oldHead` exceeded `oldTail`, so we're done // with the main loop. Create the remaining part and insert // it at the new head position, and the update is complete. // // (oldHead > oldTail) // oldKeys: [0, 1, -, 3, 4, 5, 6] // newParts: [0, 2, 1, 4, 3, 7 ,6] <- create and insert 7 // newKeys: [0, 2, 1, 4, 3, 7, 6] // newHead ^ newTail // // * Note that the order of the if/else clauses is not // important to the algorithm, as long as the null checks // come first (to ensure we're always working on valid old // parts) and that the final else clause comes last (since // that's where the expensive moves occur). The order of // remaining clauses is is just a simple guess at which cases // will be most common. // // * Note, we could calculate the longest // increasing subsequence (LIS) of old items in new position, // and only move those not in the LIS set. However that costs // O(nlogn) time and adds a bit more code, and only helps // make rare types of mutations require fewer moves. The // above handles removes, adds, reversal, swaps, and single // moves of contiguous items in linear time, in the minimum // number of moves. As the number of multiple moves where LIS // might help approaches a random shuffle, the LIS // optimization becomes less helpful, so it seems not worth // the code at this point. Could reconsider if a compelling // case arises. while (oldHead <= oldTail && newHead <= newTail) { if (oldParts[oldHead] === null) { // `null` means old part at head has already been used // below; skip oldHead++; } else if (oldParts[oldTail] === null) { // `null` means old part at tail has already been used // below; skip oldTail--; } else if (oldKeys[oldHead] === newKeys[newHead]) { // Old head matches new head; update in place newParts[newHead] = setChildPartValue(oldParts[oldHead], newValues[newHead]); oldHead++; newHead++; } else if (oldKeys[oldTail] === newKeys[newTail]) { // Old tail matches new tail; update in place newParts[newTail] = setChildPartValue(oldParts[oldTail], newValues[newTail]); oldTail--; newTail--; } else if (oldKeys[oldHead] === newKeys[newTail]) { // Old head matches new tail; update and move to new tail newParts[newTail] = setChildPartValue(oldParts[oldHead], newValues[newTail]); insertPart(containerPart, newParts[newTail + 1], oldParts[oldHead]); oldHead++; newTail--; } else if (oldKeys[oldTail] === newKeys[newHead]) { // Old tail matches new head; update and move to new head newParts[newHead] = setChildPartValue(oldParts[oldTail], newValues[newHead]); insertPart(containerPart, oldParts[oldHead], oldParts[oldTail]); oldTail--; newHead++; } else { if (newKeyToIndexMap === undefined) { // Lazily generate key-to-index maps, used for removals & // moves below newKeyToIndexMap = generateMap(newKeys, newHead, newTail); oldKeyToIndexMap = generateMap(oldKeys, oldHead, oldTail); } if (!newKeyToIndexMap.has(oldKeys[oldHead])) { // Old head is no longer in new list; remove removePart(oldParts[oldHead]); oldHead++; } else if (!newKeyToIndexMap.has(oldKeys[oldTail])) { // Old tail is no longer in new list; remove removePart(oldParts[oldTail]); oldTail--; } else { // Any mismatches at this point are due to additions or // moves; see if we have an old part we can reuse and move // into place const oldIndex = oldKeyToIndexMap.get(newKeys[newHead]); const oldPart = oldIndex !== undefined ? oldParts[oldIndex] : null; if (oldPart === null) { // No old part for this value; create a new one and // insert it const newPart = insertPart(containerPart, oldParts[oldHead]); setChildPartValue(newPart, newValues[newHead]); newParts[newHead] = newPart; } else { // Reuse old part newParts[newHead] = setChildPartValue(oldPart, newValues[newHead]); insertPart(containerPart, oldParts[oldHead], oldPart); // This marks the old part as having been used, so that // it will be skipped in the first two checks above oldParts[oldIndex] = null; } newHead++; } } } // Add parts for any remaining new values while (newHead <= newTail) { // For all remaining additions, we insert before last new // tail, since old pointers are no longer valid const newPart = insertPart(containerPart, newParts[newTail + 1]); setChildPartValue(newPart, newValues[newHead]); newParts[newHead++] = newPart; } // Remove any remaining unused old parts while (oldHead <= oldTail) { const oldPart = oldParts[oldHead++]; if (oldPart !== null) { removePart(oldPart); } } // Save order of new parts for next round this._itemKeys = newKeys; // Directly set part value, bypassing it's dirty-checking setCommittedValue(containerPart, newParts); return noChange; } } /** * A directive that repeats a series of values (usually `TemplateResults`) * generated from an iterable, and updates those items efficiently when the * iterable changes based on user-provided `keys` associated with each item. * * Note that if a `keyFn` is provided, strict key-to-DOM mapping is maintained, * meaning previous DOM for a given key is moved into the new position if * needed, and DOM will never be reused with values for different keys (new DOM * will always be created for new keys). This is generally the most efficient * way to use `repeat` since it performs minimum unnecessary work for insertions * and removals. * * The `keyFn` takes two parameters, the item and its index, and returns a unique key value. * * ```js * html` * <ol> * ${repeat(this.items, (item) => item.id, (item, index) => { * return html`<li>${index}: ${item.name}</li>`; * })} * </ol> * ` * ``` * * **Important**: If providing a `keyFn`, keys *must* be unique for all items in a * given call to `repeat`. The behavior when two or more items have the same key * is undefined. * * If no `keyFn` is provided, this directive will perform similar to mapping * items to values, and DOM will be reused against potentially different items. */ const repeat = directive(RepeatDirective); /** * @license * Copyright 2018 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ class StyleMapDirective extends Directive { constructor(partInfo) { var _a; super(partInfo); if (partInfo.type !== PartType.ATTRIBUTE || partInfo.name !== 'style' || ((_a = partInfo.strings) === null || _a === void 0 ? void 0 : _a.length) > 2) { throw new Error('The `styleMap` directive must be used in the `style` attribute ' + 'and must be the only part in the attribute.'); } } render(styleInfo) { return Object.keys(styleInfo).reduce((style, prop) => { return style + prop.slice(0, 0); }, ''); } update(part, [styleInfo]) { const { style } = part.element; if (this._previousStyleProperties === undefined) { this._previousStyleProperties = new Set(); } // Remove old properties that no longer exist in styleInfo // We use forEach() instead of for-of so that re don't require down-level // iteration. this._previousStyleProperties.forEach((name) => { // If the name isn't in styleInfo or it's null/undefined if (styleInfo[name] == null) { this._previousStyleProperties.delete(name); if (name.includes('-')) { style.removeProperty(name); } else { // Note reset using empty string (vs null) as IE11 does not always // reset via null (https://developer.mozilla.org/en-US/docs/Web/API/ElementCSSInline // eslint-disable-next-line @typescript-eslint/no-explicit-any style[name] = ''; } } }); // Add or update properties for (const name in styleInfo) { const value = styleInfo[name]; if (value != null) { this._previousStyleProperties.add(name); if (name.includes('-')) { style.setProperty(name, value); } else { // eslint-disable-next-line @typescript-eslint/no-explicit-any style[name] = value; } } } return noChange; } } /** * A directive that applies CSS properties to an element. * * `styleMap` can only be used in the `style` attribute and must be the only * expression in the attribute. It takes the property names in the * {@link StyleInfo styleInfo} object and adds the property values as CSS * properties. Property names with dashes (`-`) are assumed to be valid CSS * property names and set on the element's style object using `setProperty()`. * Names without dashes are assumed to be camelCased JavaScript property names * and set on the element's style object using property assignment, allowing the * style object to translate JavaScript-style names to CSS property names. * * For example `styleMap({backgroundColor: 'red', 'border-top': '5px', '--size': * '0'})` sets the `background-color`, `border-top` and `--size` properties. * * @param styleInfo * @see {@link https://lit.dev/docs/templates/directives/#stylemap styleMap code sample */ const styleMap = directive(StyleMapDirective); /** * @license * Copyright 2020 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ class TemplateContentDirective extends Directive { constructor(partInfo) { super(partInfo); if (partInfo.type !== PartType.CHILD) { throw new Error('templateContent can only be used in child bindings'); } } render(template) { if (this._previousTemplate === template) { return noChange; } this._previousTemplate = template; return document.importNode(template.content, true); } } /** * Renders the content of a template element as HTML. * * Note, the template should be developer controlled and not user controlled. * Rendering a user-controlled template with this directive * could lead to cross-site-scripting vulnerabilities. */ const templateContent = directive(TemplateContentDirective); /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ const HTML_RESULT = 1; class UnsafeHTMLDirective extends Directive { constructor(partInfo) { super(partInfo); this._value = nothing; if (partInfo.type !== PartType.CHILD) { throw new Error(`${this.constructor.directiveName}() can only be used in child bindings`) } } render(value) { if (value === nothing || value == null) { this._templateResult = undefined; return (this._value = value); } if (value === noChange) { return value; } if (typeof value != 'string') { throw new Error(`${this.constructor.directiveName}() called with a non-string value`); } if (value === this._value) { return this._templateResult; } this._value = value; const strings = [value]; // eslint-disable-next-line @typescript-eslint/no-explicit-any strings.raw = strings; // WARNING: impersonating a TemplateResult like this is extremely // dangerous. Third-party directives should not do this. return (this._templateResult = { // Cast to a known set of integers that satisfy ResultType so that we // don't have to export ResultType and possibly encourage this pattern. // This property needs to remain unminified. ['_$litType$']: this.constructor .resultType, strings, values: [], }); } } UnsafeHTMLDirective.directiveName = 'unsafeHTML'; UnsafeHTMLDirective.resultType = HTML_RESULT; /** * Renders the result as HTML, rather than text. * * The values `undefined`, `null`, and `nothing`, will all result in no content * (empty string) being rendered. * * Note, this is unsafe to use with any user-provided input that hasn't been * sanitized or escaped, as it may lead to cross-site-scripting * vulnerabilities. */ const unsafeHTML = directive(UnsafeHTMLDirective); /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ const SVG_RESULT = 2; class UnsafeSVGDirective extends UnsafeHTMLDirective { } UnsafeSVGDirective.directiveName = 'unsafeSVG'; UnsafeSVGDirective.resultType = SVG_RESULT; /** * Renders the result as SVG, rather than text. * * The values `undefined`, `null`, and `nothing`, will all result in no content * (empty string) being rendered. * * Note, this is unsafe to use with any user-provided input that hasn't been * sanitized or escaped, as it may lead to cross-site-scripting * vulnerabilities. */ const unsafeSVG = directive(UnsafeSVGDirective); /** * @license * Copyright 2017 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ const isPromise = (x) => { return !isPrimitive(x) && typeof x.then === 'function'; }; // Effectively infinity, but a SMI. const _infinity = 0x3fffffff; class UntilDirective extends AsyncDirective { constructor() { super(...arguments); this.__lastRenderedIndex = _infinity; this.__values = []; this.__weakThis = new PseudoWeakRef(this); this.__pauser = new Pauser(); } render(...args) { var _a; return (_a = args.find((x) => !isPromise(x))) !== null && _a !== void 0 ? _a : noChange; } update(_part, args) { const previousValues = this.__values; let previousLength = previousValues.length; this.__values = args; const weakThis = this.__weakThis; const pauser = this.__pauser; // If our initial render occurs while disconnected, ensure that the pauser // and weakThis are in the disconnected state if (!this.isConnected) { this.disconnected(); } for (let i = 0; i < args.length; i++) { // If we've rendered a higher-priority value already, stop. if (i > this.__lastRenderedIndex) { break; } const value = args[i]; // Render non-Promise values immediately if (!isPromise(value)) { this.__lastRenderedIndex = i; // Since a lower-priority value will never overwrite a higher-priority // synchronous value, we can stop processing now. return value; } // If this is a Promise we've already handled, skip it. if (i < previousLength && value === previousValues[i]) { continue; } // We have a Promise that we haven't seen before, so priorities may have // changed. Forget what we rendered before. this.__lastRenderedIndex = _infinity; previousLength = 0; // Note, the callback avoids closing over `this` so that the directive // can be gc'ed before the promise resolves; instead `this` is retrieved // from `weakThis`, which can break the hard reference in the closure when // the directive disconnects Promise.resolve(value).then(async (result) => { // If we're disconnected, wait until we're (maybe) reconnected // The while loop here handles the case that the connection state // thrashes, causing the pauser to resume and then get re-paused while (pauser.get()) { await pauser.get(); } // If the callback gets here and there is no `this`, it means that the // directive has been disconnected and garbage collected and we don't // need to do anything else const _this = weakThis.deref(); if (_this !== undefined) { const index = _this.__values.indexOf(value); // If state.values doesn't contain the value, we've re-rendered without // the value, so don't render it. Then, only render if the value is // higher-priority than what's already been rendered. if (index > -1 && index < _this.__lastRenderedIndex) { _this.__lastRenderedIndex = index; _this.setValue(result); } } }); } return noChange; } disconnected() { this.__weakThis.disconnect(); this.__pauser.pause(); } reconnected() { this.__weakThis.reconnect(this); this.__pauser.resume(); } } /** * Renders one of a series of values, including Promises, to a Part. * * Values are rendered in priority order, with the first argument having the * highest priority and the last argument having the lowest priority. If a * value is a Promise, low-priority values will be rendered until it resolves. * * The priority of values can be used to create placeholder content for async * data. For example, a Promise with pending content can be the first, * highest-priority, argument, and a non_promise loading indicator template can * be used as the second, lower-priority, argument. The loading indicator will * render immediately, and the primary content will render when the Promise * resolves. * * Example: * * ```js * const content = fetch('./content.txt').then(r => r.text()); * html`${until(content, html`<span>Loading...</span>`)}` * ``` */ const until = directive(UntilDirective); /** * The type of the class that powers this directive. Necessary for naming the * directive's return type. */ // export type {UntilDirective}; /** * @license * Copyright 2021 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ function when(condition, trueCase, falseCase) { return condition ? trueCase() : falseCase === null || falseCase === void 0 ? void 0 : falseCase() } /** * @license * Copyright 2020 Google LLC * SPDX-License-Identifier: BSD-3-Clause */ /** * Prevents JSON injection attacks. * * The goals of this brand: * 1) fast to check * 2) code is small on the wire * 3) multiple versions of Lit in a single page will all produce mutually * interoperable StaticValues * 4) normal JSON.parse (without an unusual reviver) can not produce a * StaticValue * * Symbols satisfy (1), (2), and (4). We use Symbol.for to satisfy (3), but * we don't care about the key, so we break ties via (2) and use the empty * string. */ const brand = Symbol.for(''); /** Safely extracts the string part of a StaticValue. */ const unwrapStaticValue = (value) => { if ((value === null || value === void 0 ? void 0 : value.r) !== brand) { return undefined; } return value === null || value === void 0 ? void 0 : value['_$litStatic$']; }; /** * Wraps a string so that it behaves like part of the static template * strings instead of a dynamic value. * * Users must take care to ensure that adding the static string to the template * results in well-formed HTML, or else templates may break unexpectedly. * * Note that this function is unsafe to use on untrusted content, as it will be * directly parsed into HTML. Do not pass user input to this function * without sanitizing it. * * Static values can be changed, but they will cause a complete re-render * since they effectively create a new template. */ const unsafeStatic = (value) => ({ ['_$litStatic$']: value, r: brand, }); const textFromStatic = (value) => { if (value['_$litStatic$'] !== undefined) { return value['_$litStatic$']; } else { throw new Error(`Value passed to 'literal' function must be a 'literal' result: ${value}. Use take care to ensure page security.`); } }; /** * Tags a string literal so that it behaves like part of the static template * strings instead of a dynamic value. * * The only values that may be used in template expressions are other tagged * `literal` results or `unsafeStatic` values (note that untrusted content * should never be passed to `unsafeStatic`). * * Users must take care to ensure that adding the static string to the template * results in well-formed HTML, or else templates may break unexpectedly. * * Static values can be changed, but they will cause a complete re-render since * they effectively create a new template. */ const literal = (strings, ...values) => ({ ['_$litStatic$']: values.reduce((acc, v, idx) => acc + textFromStatic(v) + strings[idx + 1], r: brand, }); const stringsCache = new Map(); /** * Wraps a lit-html template tag (`html` or `svg`) to add static value support. */ const withStatic = (coreTag) => (strings, ...values) => { const l = values.length; let staticValue; let dynamicValue; const staticStrings = []; const dynamicValues = []; let i = 0; let hasStatics = false; let s; while (i < l) { s = strings[i]; // Collect any unsafeStatic values, and their following template strings // so that we treat a run of template strings and unsafe static values as // a single template string. while (i < l && ((dynamicValue = values[i]), (staticValue = unwrapStaticValue(dynamicValue))) !== undefined) { s += staticValue + strings[++i]; hasStatics = true; } dynamicValues.push(dynamicValue); staticStrings.push(s); i++; } // If the last value isn't static (which would have consumed the last // string), then we need to add the last string. if (i === l) { staticStrings.push(strings[l]); } if (hasStatics) { const key = staticStrings.join('$$lit$$'); strings = stringsCache.get(key); if (strings === undefined) { // Beware: in general this pattern is unsafe, and doing so may bypass // lit's security checks and allow an attacker to execute arbitrary // code and inject arbitrary content. // eslint-disable-next-line @typescript-eslint/no-explicit-any staticStrings.raw = staticStrings; stringsCache.set(key, (strings = staticStrings)); } values = dynamicValues; } return coreTag(strings, ...values); }; /** * Interprets a template literal as an HTML template that can efficiently * render to and update a container. * * Includes static value support from `lit-html/static.js`. */ const html = withStatic(html$1); /** * Interprets a template literal as an SVG template that can efficiently * render to and update a container. * * Includes static value support from `lit-html/static.js`. */ const svg = withStatic(svg$1); export { AsyncDirective, AsyncReplaceDirective, CSSResult, Directive, LitElement, PartT [Seitenstruktur0.113Druckenetwas mehr zur Ethik2026-04-27] |
2026-05-26