File: /var/www/vhost/disk-apps/pwa.sports-crowd.com/node_modules/ionicons/dist/cjs/index-53856ad1.js
'use strict';
function _interopNamespace(e) {
if (e && e.__esModule) return e;
var n = Object.create(null);
if (e) {
Object.keys(e).forEach(function (k) {
if (k !== 'default') {
var d = Object.getOwnPropertyDescriptor(e, k);
Object.defineProperty(n, k, d.get ? d : {
enumerable: true,
get: function () {
return e[k];
}
});
}
});
}
n['default'] = e;
return Object.freeze(n);
}
const NAMESPACE = 'ionicons';
let scopeId;
let hostTagName;
let isSvgMode = false;
let queuePending = false;
const win = typeof window !== 'undefined' ? window : {};
const doc = win.document || { head: {} };
const plt = {
$flags$: 0,
$resourcesUrl$: '',
jmp: (h) => h(),
raf: (h) => requestAnimationFrame(h),
ael: (el, eventName, listener, opts) => el.addEventListener(eventName, listener, opts),
rel: (el, eventName, listener, opts) => el.removeEventListener(eventName, listener, opts),
ce: (eventName, opts) => new CustomEvent(eventName, opts),
};
const promiseResolve = (v) => Promise.resolve(v);
const supportsConstructableStylesheets = /*@__PURE__*/ (() => {
try {
new CSSStyleSheet();
return typeof new CSSStyleSheet().replaceSync === 'function';
}
catch (e) { }
return false;
})()
;
const HYDRATED_CSS = '{visibility:hidden}.hydrated{visibility:inherit}';
const XLINK_NS = 'http://www.w3.org/1999/xlink';
const createTime = (fnName, tagName = '') => {
{
return () => {
return;
};
}
};
const uniqueTime = (key, measureText) => {
{
return () => {
return;
};
}
};
const rootAppliedStyles = /*@__PURE__*/ new WeakMap();
const registerStyle = (scopeId, cssText, allowCS) => {
let style = styles.get(scopeId);
if (supportsConstructableStylesheets && allowCS) {
style = (style || new CSSStyleSheet());
if (typeof style === 'string') {
style = cssText;
}
else {
style.replaceSync(cssText);
}
}
else {
style = cssText;
}
styles.set(scopeId, style);
};
const addStyle = (styleContainerNode, cmpMeta, mode, hostElm) => {
let scopeId = getScopeId(cmpMeta);
const style = styles.get(scopeId);
// if an element is NOT connected then getRootNode() will return the wrong root node
// so the fallback is to always use the document for the root node in those cases
styleContainerNode = styleContainerNode.nodeType === 11 /* NODE_TYPE.DocumentFragment */ ? styleContainerNode : doc;
if (style) {
if (typeof style === 'string') {
styleContainerNode = styleContainerNode.head || styleContainerNode;
let appliedStyles = rootAppliedStyles.get(styleContainerNode);
let styleElm;
if (!appliedStyles) {
rootAppliedStyles.set(styleContainerNode, (appliedStyles = new Set()));
}
if (!appliedStyles.has(scopeId)) {
{
{
styleElm = doc.createElement('style');
styleElm.innerHTML = style;
}
styleContainerNode.insertBefore(styleElm, styleContainerNode.querySelector('link'));
}
if (appliedStyles) {
appliedStyles.add(scopeId);
}
}
}
else if (!styleContainerNode.adoptedStyleSheets.includes(style)) {
styleContainerNode.adoptedStyleSheets = [...styleContainerNode.adoptedStyleSheets, style];
}
}
return scopeId;
};
const attachStyles = (hostRef) => {
const cmpMeta = hostRef.$cmpMeta$;
const elm = hostRef.$hostElement$;
const flags = cmpMeta.$flags$;
const endAttachStyles = createTime('attachStyles', cmpMeta.$tagName$);
const scopeId = addStyle(elm.shadowRoot ? elm.shadowRoot : elm.getRootNode(), cmpMeta);
if (flags & 10 /* CMP_FLAGS.needsScopedEncapsulation */) {
// only required when we're NOT using native shadow dom (slot)
// or this browser doesn't support native shadow dom
// and this host element was NOT created with SSR
// let's pick out the inner content for slot projection
// create a node to represent where the original
// content was first placed, which is useful later on
// DOM WRITE!!
elm['s-sc'] = scopeId;
elm.classList.add(scopeId + '-h');
}
endAttachStyles();
};
const getScopeId = (cmp, mode) => 'sc-' + (cmp.$tagName$);
/**
* Default style mode id
*/
/**
* Reusable empty obj/array
* Don't add values to these!!
*/
const EMPTY_OBJ = {};
const isDef = (v) => v != null;
const isComplexType = (o) => {
// https://jsperf.com/typeof-fn-object/5
o = typeof o;
return o === 'object' || o === 'function';
};
/**
* Production h() function based on Preact by
* Jason Miller (@developit)
* Licensed under the MIT License
* https://github.com/developit/preact/blob/master/LICENSE
*
* Modified for Stencil's compiler and vdom
*/
// const stack: any[] = [];
// export function h(nodeName: string | d.FunctionalComponent, vnodeData: d.PropsType, child?: d.ChildType): d.VNode;
// export function h(nodeName: string | d.FunctionalComponent, vnodeData: d.PropsType, ...children: d.ChildType[]): d.VNode;
const h = (nodeName, vnodeData, ...children) => {
let child = null;
let key = null;
let simple = false;
let lastSimple = false;
const vNodeChildren = [];
const walk = (c) => {
for (let i = 0; i < c.length; i++) {
child = c[i];
if (Array.isArray(child)) {
walk(child);
}
else if (child != null && typeof child !== 'boolean') {
if ((simple = typeof nodeName !== 'function' && !isComplexType(child))) {
child = String(child);
}
if (simple && lastSimple) {
// If the previous child was simple (string), we merge both
vNodeChildren[vNodeChildren.length - 1].$text$ += child;
}
else {
// Append a new vNode, if it's text, we create a text vNode
vNodeChildren.push(simple ? newVNode(null, child) : child);
}
lastSimple = simple;
}
}
};
walk(children);
if (vnodeData) {
// normalize class / classname attributes
if (vnodeData.key) {
key = vnodeData.key;
}
{
const classData = vnodeData.className || vnodeData.class;
if (classData) {
vnodeData.class =
typeof classData !== 'object'
? classData
: Object.keys(classData)
.filter((k) => classData[k])
.join(' ');
}
}
}
const vnode = newVNode(nodeName, null);
vnode.$attrs$ = vnodeData;
if (vNodeChildren.length > 0) {
vnode.$children$ = vNodeChildren;
}
{
vnode.$key$ = key;
}
return vnode;
};
const newVNode = (tag, text) => {
const vnode = {
$flags$: 0,
$tag$: tag,
$text$: text,
$elm$: null,
$children$: null,
};
{
vnode.$attrs$ = null;
}
{
vnode.$key$ = null;
}
return vnode;
};
const Host = {};
const isHost = (node) => node && node.$tag$ === Host;
/**
* Production setAccessor() function based on Preact by
* Jason Miller (@developit)
* Licensed under the MIT License
* https://github.com/developit/preact/blob/master/LICENSE
*
* Modified for Stencil's compiler and vdom
*/
const setAccessor = (elm, memberName, oldValue, newValue, isSvg, flags) => {
if (oldValue !== newValue) {
let isProp = isMemberInElement(elm, memberName);
let ln = memberName.toLowerCase();
if (memberName === 'class') {
const classList = elm.classList;
const oldClasses = parseClassList(oldValue);
const newClasses = parseClassList(newValue);
classList.remove(...oldClasses.filter((c) => c && !newClasses.includes(c)));
classList.add(...newClasses.filter((c) => c && !oldClasses.includes(c)));
}
else if (memberName === 'style') {
// update style attribute, css properties and values
{
for (const prop in oldValue) {
if (!newValue || newValue[prop] == null) {
if (prop.includes('-')) {
elm.style.removeProperty(prop);
}
else {
elm.style[prop] = '';
}
}
}
}
for (const prop in newValue) {
if (!oldValue || newValue[prop] !== oldValue[prop]) {
if (prop.includes('-')) {
elm.style.setProperty(prop, newValue[prop]);
}
else {
elm.style[prop] = newValue[prop];
}
}
}
}
else if (memberName === 'key')
;
else if (memberName === 'ref') {
// minifier will clean this up
if (newValue) {
newValue(elm);
}
}
else if ((!isProp ) &&
memberName[0] === 'o' &&
memberName[1] === 'n') {
// Event Handlers
// so if the member name starts with "on" and the 3rd characters is
// a capital letter, and it's not already a member on the element,
// then we're assuming it's an event listener
if (memberName[2] === '-') {
// on- prefixed events
// allows to be explicit about the dom event to listen without any magic
// under the hood:
// <my-cmp on-click> // listens for "click"
// <my-cmp on-Click> // listens for "Click"
// <my-cmp on-ionChange> // listens for "ionChange"
// <my-cmp on-EVENTS> // listens for "EVENTS"
memberName = memberName.slice(3);
}
else if (isMemberInElement(win, ln)) {
// standard event
// the JSX attribute could have been "onMouseOver" and the
// member name "onmouseover" is on the window's prototype
// so let's add the listener "mouseover", which is all lowercased
memberName = ln.slice(2);
}
else {
// custom event
// the JSX attribute could have been "onMyCustomEvent"
// so let's trim off the "on" prefix and lowercase the first character
// and add the listener "myCustomEvent"
// except for the first character, we keep the event name case
memberName = ln[2] + memberName.slice(3);
}
if (oldValue) {
plt.rel(elm, memberName, oldValue, false);
}
if (newValue) {
plt.ael(elm, memberName, newValue, false);
}
}
else {
// Set property if it exists and it's not a SVG
const isComplex = isComplexType(newValue);
if ((isProp || (isComplex && newValue !== null)) && !isSvg) {
try {
if (!elm.tagName.includes('-')) {
const n = newValue == null ? '' : newValue;
// Workaround for Safari, moving the <input> caret when re-assigning the same valued
if (memberName === 'list') {
isProp = false;
}
else if (oldValue == null || elm[memberName] != n) {
elm[memberName] = n;
}
}
else {
elm[memberName] = newValue;
}
}
catch (e) { }
}
/**
* Need to manually update attribute if:
* - memberName is not an attribute
* - if we are rendering the host element in order to reflect attribute
* - if it's a SVG, since properties might not work in <svg>
* - if the newValue is null/undefined or 'false'.
*/
let xlink = false;
{
if (ln !== (ln = ln.replace(/^xlink\:?/, ''))) {
memberName = ln;
xlink = true;
}
}
if (newValue == null || newValue === false) {
if (newValue !== false || elm.getAttribute(memberName) === '') {
if (xlink) {
elm.removeAttributeNS(XLINK_NS, memberName);
}
else {
elm.removeAttribute(memberName);
}
}
}
else if ((!isProp || flags & 4 /* VNODE_FLAGS.isHost */ || isSvg) && !isComplex) {
newValue = newValue === true ? '' : newValue;
if (xlink) {
elm.setAttributeNS(XLINK_NS, memberName, newValue);
}
else {
elm.setAttribute(memberName, newValue);
}
}
}
}
};
const parseClassListRegex = /\s/;
const parseClassList = (value) => (!value ? [] : value.split(parseClassListRegex));
const updateElement = (oldVnode, newVnode, isSvgMode, memberName) => {
// if the element passed in is a shadow root, which is a document fragment
// then we want to be adding attrs/props to the shadow root's "host" element
// if it's not a shadow root, then we add attrs/props to the same element
const elm = newVnode.$elm$.nodeType === 11 /* NODE_TYPE.DocumentFragment */ && newVnode.$elm$.host
? newVnode.$elm$.host
: newVnode.$elm$;
const oldVnodeAttrs = (oldVnode && oldVnode.$attrs$) || EMPTY_OBJ;
const newVnodeAttrs = newVnode.$attrs$ || EMPTY_OBJ;
{
// remove attributes no longer present on the vnode by setting them to undefined
for (memberName in oldVnodeAttrs) {
if (!(memberName in newVnodeAttrs)) {
setAccessor(elm, memberName, oldVnodeAttrs[memberName], undefined, isSvgMode, newVnode.$flags$);
}
}
}
// add new & update changed attributes
for (memberName in newVnodeAttrs) {
setAccessor(elm, memberName, oldVnodeAttrs[memberName], newVnodeAttrs[memberName], isSvgMode, newVnode.$flags$);
}
};
/**
* Create a DOM Node corresponding to one of the children of a given VNode.
*
* @param oldParentVNode the parent VNode from the previous render
* @param newParentVNode the parent VNode from the current render
* @param childIndex the index of the VNode, in the _new_ parent node's
* children, for which we will create a new DOM node
* @param parentElm the parent DOM node which our new node will be a child of
* @returns the newly created node
*/
const createElm = (oldParentVNode, newParentVNode, childIndex, parentElm) => {
// tslint:disable-next-line: prefer-const
const newVNode = newParentVNode.$children$[childIndex];
let i = 0;
let elm;
let childNode;
if (newVNode.$text$ !== null) {
// create text node
elm = newVNode.$elm$ = doc.createTextNode(newVNode.$text$);
}
else {
// create element
elm = newVNode.$elm$ = (doc.createElement(newVNode.$tag$));
// add css classes, attrs, props, listeners, etc.
{
updateElement(null, newVNode, isSvgMode);
}
if (isDef(scopeId) && elm['s-si'] !== scopeId) {
// if there is a scopeId and this is the initial render
// then let's add the scopeId as a css class
elm.classList.add((elm['s-si'] = scopeId));
}
if (newVNode.$children$) {
for (i = 0; i < newVNode.$children$.length; ++i) {
// create the node
childNode = createElm(oldParentVNode, newVNode, i);
// return node could have been null
if (childNode) {
// append our new node
elm.appendChild(childNode);
}
}
}
}
return elm;
};
const addVnodes = (parentElm, before, parentVNode, vnodes, startIdx, endIdx) => {
let containerElm = (parentElm);
let childNode;
if (containerElm.shadowRoot && containerElm.tagName === hostTagName) {
containerElm = containerElm.shadowRoot;
}
for (; startIdx <= endIdx; ++startIdx) {
if (vnodes[startIdx]) {
childNode = createElm(null, parentVNode, startIdx);
if (childNode) {
vnodes[startIdx].$elm$ = childNode;
containerElm.insertBefore(childNode, before);
}
}
}
};
const removeVnodes = (vnodes, startIdx, endIdx, vnode, elm) => {
for (; startIdx <= endIdx; ++startIdx) {
if ((vnode = vnodes[startIdx])) {
elm = vnode.$elm$;
callNodeRefs(vnode);
// remove the vnode's element from the dom
elm.remove();
}
}
};
/**
* Reconcile the children of a new VNode with the children of an old VNode by
* traversing the two collections of children, identifying nodes that are
* conserved or changed, calling out to `patch` to make any necessary
* updates to the DOM, and rearranging DOM nodes as needed.
*
* The algorithm for reconciling children works by analyzing two 'windows' onto
* the two arrays of children (`oldCh` and `newCh`). We keep track of the
* 'windows' by storing start and end indices and references to the
* corresponding array entries. Initially the two 'windows' are basically equal
* to the entire array, but we progressively narrow the windows until there are
* no children left to update by doing the following:
*
* 1. Skip any `null` entries at the beginning or end of the two arrays, so
* that if we have an initial array like the following we'll end up dealing
* only with a window bounded by the highlighted elements:
*
* [null, null, VNode1 , ... , VNode2, null, null]
* ^^^^^^ ^^^^^^
*
* 2. Check to see if the elements at the head and tail positions are equal
* across the windows. This will basically detect elements which haven't
* been added, removed, or changed position, i.e. if you had the following
* VNode elements (represented as HTML):
*
* oldVNode: `<div><p><span>HEY</span></p></div>`
* newVNode: `<div><p><span>THERE</span></p></div>`
*
* Then when comparing the children of the `<div>` tag we check the equality
* of the VNodes corresponding to the `<p>` tags and, since they are the
* same tag in the same position, we'd be able to avoid completely
* re-rendering the subtree under them with a new DOM element and would just
* call out to `patch` to handle reconciling their children and so on.
*
* 3. Check, for both windows, to see if the element at the beginning of the
* window corresponds to the element at the end of the other window. This is
* a heuristic which will let us identify _some_ situations in which
* elements have changed position, for instance it _should_ detect that the
* children nodes themselves have not changed but merely moved in the
* following example:
*
* oldVNode: `<div><element-one /><element-two /></div>`
* newVNode: `<div><element-two /><element-one /></div>`
*
* If we find cases like this then we also need to move the concrete DOM
* elements corresponding to the moved children to write the re-order to the
* DOM.
*
* 4. Finally, if VNodes have the `key` attribute set on them we check for any
* nodes in the old children which have the same key as the first element in
* our window on the new children. If we find such a node we handle calling
* out to `patch`, moving relevant DOM nodes, and so on, in accordance with
* what we find.
*
* Finally, once we've narrowed our 'windows' to the point that either of them
* collapse (i.e. they have length 0) we then handle any remaining VNode
* insertion or deletion that needs to happen to get a DOM state that correctly
* reflects the new child VNodes. If, for instance, after our window on the old
* children has collapsed we still have more nodes on the new children that
* we haven't dealt with yet then we need to add them, or if the new children
* collapse but we still have unhandled _old_ children then we need to make
* sure the corresponding DOM nodes are removed.
*
* @param parentElm the node into which the parent VNode is rendered
* @param oldCh the old children of the parent node
* @param newVNode the new VNode which will replace the parent
* @param newCh the new children of the parent node
*/
const updateChildren = (parentElm, oldCh, newVNode, newCh) => {
let oldStartIdx = 0;
let newStartIdx = 0;
let idxInOld = 0;
let i = 0;
let oldEndIdx = oldCh.length - 1;
let oldStartVnode = oldCh[0];
let oldEndVnode = oldCh[oldEndIdx];
let newEndIdx = newCh.length - 1;
let newStartVnode = newCh[0];
let newEndVnode = newCh[newEndIdx];
let node;
let elmToMove;
while (oldStartIdx <= oldEndIdx && newStartIdx <= newEndIdx) {
if (oldStartVnode == null) {
// VNode might have been moved left
oldStartVnode = oldCh[++oldStartIdx];
}
else if (oldEndVnode == null) {
oldEndVnode = oldCh[--oldEndIdx];
}
else if (newStartVnode == null) {
newStartVnode = newCh[++newStartIdx];
}
else if (newEndVnode == null) {
newEndVnode = newCh[--newEndIdx];
}
else if (isSameVnode(oldStartVnode, newStartVnode)) {
// if the start nodes are the same then we should patch the new VNode
// onto the old one, and increment our `newStartIdx` and `oldStartIdx`
// indices to reflect that. We don't need to move any DOM Nodes around
// since things are matched up in order.
patch(oldStartVnode, newStartVnode);
oldStartVnode = oldCh[++oldStartIdx];
newStartVnode = newCh[++newStartIdx];
}
else if (isSameVnode(oldEndVnode, newEndVnode)) {
// likewise, if the end nodes are the same we patch new onto old and
// decrement our end indices, and also likewise in this case we don't
// need to move any DOM Nodes.
patch(oldEndVnode, newEndVnode);
oldEndVnode = oldCh[--oldEndIdx];
newEndVnode = newCh[--newEndIdx];
}
else if (isSameVnode(oldStartVnode, newEndVnode)) {
patch(oldStartVnode, newEndVnode);
// We need to move the element for `oldStartVnode` into a position which
// will be appropriate for `newEndVnode`. For this we can use
// `.insertBefore` and `oldEndVnode.$elm$.nextSibling`. If there is a
// sibling for `oldEndVnode.$elm$` then we want to move the DOM node for
// `oldStartVnode` between `oldEndVnode` and it's sibling, like so:
//
// <old-start-node />
// <some-intervening-node />
// <old-end-node />
// <!-- -> <-- `oldStartVnode.$elm$` should be inserted here
// <next-sibling />
//
// If instead `oldEndVnode.$elm$` has no sibling then we just want to put
// the node for `oldStartVnode` at the end of the children of
// `parentElm`. Luckily, `Node.nextSibling` will return `null` if there
// aren't any siblings, and passing `null` to `Node.insertBefore` will
// append it to the children of the parent element.
parentElm.insertBefore(oldStartVnode.$elm$, oldEndVnode.$elm$.nextSibling);
oldStartVnode = oldCh[++oldStartIdx];
newEndVnode = newCh[--newEndIdx];
}
else if (isSameVnode(oldEndVnode, newStartVnode)) {
patch(oldEndVnode, newStartVnode);
// We've already checked above if `oldStartVnode` and `newStartVnode` are
// the same node, so since we're here we know that they are not. Thus we
// can move the element for `oldEndVnode` _before_ the element for
// `oldStartVnode`, leaving `oldStartVnode` to be reconciled in the
// future.
parentElm.insertBefore(oldEndVnode.$elm$, oldStartVnode.$elm$);
oldEndVnode = oldCh[--oldEndIdx];
newStartVnode = newCh[++newStartIdx];
}
else {
// Here we do some checks to match up old and new nodes based on the
// `$key$` attribute, which is set by putting a `key="my-key"` attribute
// in the JSX for a DOM element in the implementation of a Stencil
// component.
//
// First we check to see if there are any nodes in the array of old
// children which have the same key as the first node in the new
// children.
idxInOld = -1;
{
for (i = oldStartIdx; i <= oldEndIdx; ++i) {
if (oldCh[i] && oldCh[i].$key$ !== null && oldCh[i].$key$ === newStartVnode.$key$) {
idxInOld = i;
break;
}
}
}
if (idxInOld >= 0) {
// We found a node in the old children which matches up with the first
// node in the new children! So let's deal with that
elmToMove = oldCh[idxInOld];
if (elmToMove.$tag$ !== newStartVnode.$tag$) {
// the tag doesn't match so we'll need a new DOM element
node = createElm(oldCh && oldCh[newStartIdx], newVNode, idxInOld);
}
else {
patch(elmToMove, newStartVnode);
// invalidate the matching old node so that we won't try to update it
// again later on
oldCh[idxInOld] = undefined;
node = elmToMove.$elm$;
}
newStartVnode = newCh[++newStartIdx];
}
else {
// We either didn't find an element in the old children that matches
// the key of the first new child OR the build is not using `key`
// attributes at all. In either case we need to create a new element
// for the new node.
node = createElm(oldCh && oldCh[newStartIdx], newVNode, newStartIdx);
newStartVnode = newCh[++newStartIdx];
}
if (node) {
// if we created a new node then handle inserting it to the DOM
{
oldStartVnode.$elm$.parentNode.insertBefore(node, oldStartVnode.$elm$);
}
}
}
}
if (oldStartIdx > oldEndIdx) {
// we have some more new nodes to add which don't match up with old nodes
addVnodes(parentElm, newCh[newEndIdx + 1] == null ? null : newCh[newEndIdx + 1].$elm$, newVNode, newCh, newStartIdx, newEndIdx);
}
else if (newStartIdx > newEndIdx) {
// there are nodes in the `oldCh` array which no longer correspond to nodes
// in the new array, so lets remove them (which entails cleaning up the
// relevant DOM nodes)
removeVnodes(oldCh, oldStartIdx, oldEndIdx);
}
};
/**
* Compare two VNodes to determine if they are the same
*
* **NB**: This function is an equality _heuristic_ based on the available
* information set on the two VNodes and can be misleading under certain
* circumstances. In particular, if the two nodes do not have `key` attrs
* (available under `$key$` on VNodes) then the function falls back on merely
* checking that they have the same tag.
*
* So, in other words, if `key` attrs are not set on VNodes which may be
* changing order within a `children` array or something along those lines then
* we could obtain a false positive and then have to do needless re-rendering.
*
* @param leftVNode the first VNode to check
* @param rightVNode the second VNode to check
* @returns whether they're equal or not
*/
const isSameVnode = (leftVNode, rightVNode) => {
// compare if two vnode to see if they're "technically" the same
// need to have the same element tag, and same key to be the same
if (leftVNode.$tag$ === rightVNode.$tag$) {
// this will be set if components in the build have `key` attrs set on them
{
return leftVNode.$key$ === rightVNode.$key$;
}
}
return false;
};
/**
* Handle reconciling an outdated VNode with a new one which corresponds to
* it. This function handles flushing updates to the DOM and reconciling the
* children of the two nodes (if any).
*
* @param oldVNode an old VNode whose DOM element and children we want to update
* @param newVNode a new VNode representing an updated version of the old one
*/
const patch = (oldVNode, newVNode) => {
const elm = (newVNode.$elm$ = oldVNode.$elm$);
const oldChildren = oldVNode.$children$;
const newChildren = newVNode.$children$;
const text = newVNode.$text$;
if (text === null) {
{
{
// either this is the first render of an element OR it's an update
// AND we already know it's possible it could have changed
// this updates the element's css classes, attrs, props, listeners, etc.
updateElement(oldVNode, newVNode, isSvgMode);
}
}
if (oldChildren !== null && newChildren !== null) {
// looks like there's child vnodes for both the old and new vnodes
// so we need to call `updateChildren` to reconcile them
updateChildren(elm, oldChildren, newVNode, newChildren);
}
else if (newChildren !== null) {
// no old child vnodes, but there are new child vnodes to add
if (oldVNode.$text$ !== null) {
// the old vnode was text, so be sure to clear it out
elm.textContent = '';
}
// add the new vnode children
addVnodes(elm, null, newVNode, newChildren, 0, newChildren.length - 1);
}
else if (oldChildren !== null) {
// no new child vnodes, but there are old child vnodes to remove
removeVnodes(oldChildren, 0, oldChildren.length - 1);
}
}
else if (oldVNode.$text$ !== text) {
// update the text content for the text only vnode
// and also only if the text is different than before
elm.data = text;
}
};
const callNodeRefs = (vNode) => {
{
vNode.$attrs$ && vNode.$attrs$.ref && vNode.$attrs$.ref(null);
vNode.$children$ && vNode.$children$.map(callNodeRefs);
}
};
const renderVdom = (hostRef, renderFnResults) => {
const hostElm = hostRef.$hostElement$;
const cmpMeta = hostRef.$cmpMeta$;
const oldVNode = hostRef.$vnode$ || newVNode(null, null);
const rootVnode = isHost(renderFnResults) ? renderFnResults : h(null, null, renderFnResults);
hostTagName = hostElm.tagName;
if (cmpMeta.$attrsToReflect$) {
rootVnode.$attrs$ = rootVnode.$attrs$ || {};
cmpMeta.$attrsToReflect$.map(([propName, attribute]) => (rootVnode.$attrs$[attribute] = hostElm[propName]));
}
rootVnode.$tag$ = null;
rootVnode.$flags$ |= 4 /* VNODE_FLAGS.isHost */;
hostRef.$vnode$ = rootVnode;
rootVnode.$elm$ = oldVNode.$elm$ = (hostElm.shadowRoot || hostElm );
{
scopeId = hostElm['s-sc'];
}
// synchronous patch
patch(oldVNode, rootVnode);
};
const getElement = (ref) => (getHostRef(ref).$hostElement$ );
/**
* Helper function to create & dispatch a custom Event on a provided target
* @param elm the target of the Event
* @param name the name to give the custom Event
* @param opts options for configuring a custom Event
* @returns the custom Event
*/
const emitEvent = (elm, name, opts) => {
const ev = plt.ce(name, opts);
elm.dispatchEvent(ev);
return ev;
};
const attachToAncestor = (hostRef, ancestorComponent) => {
if (ancestorComponent && !hostRef.$onRenderResolve$ && ancestorComponent['s-p']) {
ancestorComponent['s-p'].push(new Promise((r) => (hostRef.$onRenderResolve$ = r)));
}
};
const scheduleUpdate = (hostRef, isInitialLoad) => {
{
hostRef.$flags$ |= 16 /* HOST_FLAGS.isQueuedForUpdate */;
}
if (hostRef.$flags$ & 4 /* HOST_FLAGS.isWaitingForChildren */) {
hostRef.$flags$ |= 512 /* HOST_FLAGS.needsRerender */;
return;
}
attachToAncestor(hostRef, hostRef.$ancestorComponent$);
// there is no ancestor component or the ancestor component
// has already fired off its lifecycle update then
// fire off the initial update
const dispatch = () => dispatchHooks(hostRef, isInitialLoad);
return writeTask(dispatch) ;
};
const dispatchHooks = (hostRef, isInitialLoad) => {
const endSchedule = createTime('scheduleUpdate', hostRef.$cmpMeta$.$tagName$);
const instance = hostRef.$lazyInstance$ ;
let promise;
if (isInitialLoad) {
{
promise = safeCall(instance, 'componentWillLoad');
}
}
endSchedule();
return then(promise, () => updateComponent(hostRef, instance, isInitialLoad));
};
const updateComponent = async (hostRef, instance, isInitialLoad) => {
// updateComponent
const elm = hostRef.$hostElement$;
const endUpdate = createTime('update', hostRef.$cmpMeta$.$tagName$);
const rc = elm['s-rc'];
if (isInitialLoad) {
// DOM WRITE!
attachStyles(hostRef);
}
const endRender = createTime('render', hostRef.$cmpMeta$.$tagName$);
{
callRender(hostRef, instance);
}
if (rc) {
// ok, so turns out there are some child host elements
// waiting on this parent element to load
// let's fire off all update callbacks waiting
rc.map((cb) => cb());
elm['s-rc'] = undefined;
}
endRender();
endUpdate();
{
const childrenPromises = elm['s-p'];
const postUpdate = () => postUpdateComponent(hostRef);
if (childrenPromises.length === 0) {
postUpdate();
}
else {
Promise.all(childrenPromises).then(postUpdate);
hostRef.$flags$ |= 4 /* HOST_FLAGS.isWaitingForChildren */;
childrenPromises.length = 0;
}
}
};
const callRender = (hostRef, instance, elm) => {
try {
instance = instance.render() ;
{
hostRef.$flags$ &= ~16 /* HOST_FLAGS.isQueuedForUpdate */;
}
{
hostRef.$flags$ |= 2 /* HOST_FLAGS.hasRendered */;
}
{
{
// looks like we've got child nodes to render into this host element
// or we need to update the css class/attrs on the host element
// DOM WRITE!
{
renderVdom(hostRef, instance);
}
}
}
}
catch (e) {
consoleError(e, hostRef.$hostElement$);
}
return null;
};
const postUpdateComponent = (hostRef) => {
const tagName = hostRef.$cmpMeta$.$tagName$;
const elm = hostRef.$hostElement$;
const endPostUpdate = createTime('postUpdate', tagName);
const ancestorComponent = hostRef.$ancestorComponent$;
if (!(hostRef.$flags$ & 64 /* HOST_FLAGS.hasLoadedComponent */)) {
hostRef.$flags$ |= 64 /* HOST_FLAGS.hasLoadedComponent */;
{
// DOM WRITE!
addHydratedFlag(elm);
}
endPostUpdate();
{
hostRef.$onReadyResolve$(elm);
if (!ancestorComponent) {
appDidLoad();
}
}
}
else {
endPostUpdate();
}
// load events fire from bottom to top
// the deepest elements load first then bubbles up
{
if (hostRef.$onRenderResolve$) {
hostRef.$onRenderResolve$();
hostRef.$onRenderResolve$ = undefined;
}
if (hostRef.$flags$ & 512 /* HOST_FLAGS.needsRerender */) {
nextTick(() => scheduleUpdate(hostRef, false));
}
hostRef.$flags$ &= ~(4 /* HOST_FLAGS.isWaitingForChildren */ | 512 /* HOST_FLAGS.needsRerender */);
}
// ( •_•)
// ( •_•)>⌐■-■
// (⌐■_■)
};
const appDidLoad = (who) => {
// on appload
// we have finish the first big initial render
{
addHydratedFlag(doc.documentElement);
}
nextTick(() => emitEvent(win, 'appload', { detail: { namespace: NAMESPACE } }));
};
const safeCall = (instance, method, arg) => {
if (instance && instance[method]) {
try {
return instance[method](arg);
}
catch (e) {
consoleError(e);
}
}
return undefined;
};
const then = (promise, thenFn) => {
return promise && promise.then ? promise.then(thenFn) : thenFn();
};
const addHydratedFlag = (elm) => elm.classList.add('hydrated')
;
/**
* Parse a new property value for a given property type.
*
* While the prop value can reasonably be expected to be of `any` type as far as TypeScript's type checker is concerned,
* it is not safe to assume that the string returned by evaluating `typeof propValue` matches:
* 1. `any`, the type given to `propValue` in the function signature
* 2. the type stored from `propType`.
*
* This function provides the capability to parse/coerce a property's value to potentially any other JavaScript type.
*
* Property values represented in TSX preserve their type information. In the example below, the number 0 is passed to
* a component. This `propValue` will preserve its type information (`typeof propValue === 'number'`). Note that is
* based on the type of the value being passed in, not the type declared of the class member decorated with `@Prop`.
* ```tsx
* <my-cmp prop-val={0}></my-cmp>
* ```
*
* HTML prop values on the other hand, will always a string
*
* @param propValue the new value to coerce to some type
* @param propType the type of the prop, expressed as a binary number
* @returns the parsed/coerced value
*/
const parsePropertyValue = (propValue, propType) => {
// ensure this value is of the correct prop type
if (propValue != null && !isComplexType(propValue)) {
if (propType & 4 /* MEMBER_FLAGS.Boolean */) {
// per the HTML spec, any string value means it is a boolean true value
// but we'll cheat here and say that the string "false" is the boolean false
return propValue === 'false' ? false : propValue === '' || !!propValue;
}
if (propType & 1 /* MEMBER_FLAGS.String */) {
// could have been passed as a number or boolean
// but we still want it as a string
return String(propValue);
}
// redundant return here for better minification
return propValue;
}
// not sure exactly what type we want
// so no need to change to a different type
return propValue;
};
const getValue = (ref, propName) => getHostRef(ref).$instanceValues$.get(propName);
const setValue = (ref, propName, newVal, cmpMeta) => {
// check our new property value against our internal value
const hostRef = getHostRef(ref);
const elm = hostRef.$hostElement$ ;
const oldVal = hostRef.$instanceValues$.get(propName);
const flags = hostRef.$flags$;
const instance = hostRef.$lazyInstance$ ;
newVal = parsePropertyValue(newVal, cmpMeta.$members$[propName][0]);
// explicitly check for NaN on both sides, as `NaN === NaN` is always false
const areBothNaN = Number.isNaN(oldVal) && Number.isNaN(newVal);
const didValueChange = newVal !== oldVal && !areBothNaN;
if ((!(flags & 8 /* HOST_FLAGS.isConstructingInstance */) || oldVal === undefined) && didValueChange) {
// gadzooks! the property's value has changed!!
// set our new value!
hostRef.$instanceValues$.set(propName, newVal);
if (instance) {
// get an array of method names of watch functions to call
if (cmpMeta.$watchers$ && flags & 128 /* HOST_FLAGS.isWatchReady */) {
const watchMethods = cmpMeta.$watchers$[propName];
if (watchMethods) {
// this instance is watching for when this property changed
watchMethods.map((watchMethodName) => {
try {
// fire off each of the watch methods that are watching this property
instance[watchMethodName](newVal, oldVal, propName);
}
catch (e) {
consoleError(e, elm);
}
});
}
}
if ((flags & (2 /* HOST_FLAGS.hasRendered */ | 16 /* HOST_FLAGS.isQueuedForUpdate */)) === 2 /* HOST_FLAGS.hasRendered */) {
// looks like this value actually changed, so we've got work to do!
// but only if we've already rendered, otherwise just chill out
// queue that we need to do an update, but don't worry about queuing
// up millions cuz this function ensures it only runs once
scheduleUpdate(hostRef, false);
}
}
}
};
const proxyComponent = (Cstr, cmpMeta, flags) => {
if (cmpMeta.$members$) {
if (Cstr.watchers) {
cmpMeta.$watchers$ = Cstr.watchers;
}
// It's better to have a const than two Object.entries()
const members = Object.entries(cmpMeta.$members$);
const prototype = Cstr.prototype;
members.map(([memberName, [memberFlags]]) => {
if ((memberFlags & 31 /* MEMBER_FLAGS.Prop */ ||
((flags & 2 /* PROXY_FLAGS.proxyState */) && memberFlags & 32 /* MEMBER_FLAGS.State */))) {
// proxyComponent - prop
Object.defineProperty(prototype, memberName, {
get() {
// proxyComponent, get value
return getValue(this, memberName);
},
set(newValue) {
// proxyComponent, set value
setValue(this, memberName, newValue, cmpMeta);
},
configurable: true,
enumerable: true,
});
}
});
if ((flags & 1 /* PROXY_FLAGS.isElementConstructor */)) {
const attrNameToPropName = new Map();
prototype.attributeChangedCallback = function (attrName, _oldValue, newValue) {
plt.jmp(() => {
const propName = attrNameToPropName.get(attrName);
// In a web component lifecycle the attributeChangedCallback runs prior to connectedCallback
// in the case where an attribute was set inline.
// ```html
// <my-component some-attribute="some-value"></my-component>
// ```
//
// There is an edge case where a developer sets the attribute inline on a custom element and then
// programmatically changes it before it has been upgraded as shown below:
//
// ```html
// <!-- this component has _not_ been upgraded yet -->
// <my-component id="test" some-attribute="some-value"></my-component>
// <script>
// // grab non-upgraded component
// el = document.querySelector("#test");
// el.someAttribute = "another-value";
// // upgrade component
// customElements.define('my-component', MyComponent);
// </script>
// ```
// In this case if we do not unshadow here and use the value of the shadowing property, attributeChangedCallback
// will be called with `newValue = "some-value"` and will set the shadowed property (this.someAttribute = "another-value")
// to the value that was set inline i.e. "some-value" from above example. When
// the connectedCallback attempts to unshadow it will use "some-value" as the initial value rather than "another-value"
//
// The case where the attribute was NOT set inline but was not set programmatically shall be handled/unshadowed
// by connectedCallback as this attributeChangedCallback will not fire.
//
// https://developers.google.com/web/fundamentals/web-components/best-practices#lazy-properties
//
// TODO(STENCIL-16) we should think about whether or not we actually want to be reflecting the attributes to
// properties here given that this goes against best practices outlined here
// https://developers.google.com/web/fundamentals/web-components/best-practices#avoid-reentrancy
if (this.hasOwnProperty(propName)) {
newValue = this[propName];
delete this[propName];
}
else if (prototype.hasOwnProperty(propName) &&
typeof this[propName] === 'number' &&
this[propName] == newValue) {
// if the propName exists on the prototype of `Cstr`, this update may be a result of Stencil using native
// APIs to reflect props as attributes. Calls to `setAttribute(someElement, propName)` will result in
// `propName` to be converted to a `DOMString`, which may not be what we want for other primitive props.
return;
}
this[propName] = newValue === null && typeof this[propName] === 'boolean' ? false : newValue;
});
};
// create an array of attributes to observe
// and also create a map of html attribute name to js property name
Cstr.observedAttributes = members
.filter(([_, m]) => m[0] & 15 /* MEMBER_FLAGS.HasAttribute */) // filter to only keep props that should match attributes
.map(([propName, m]) => {
const attrName = m[1] || propName;
attrNameToPropName.set(attrName, propName);
if (m[0] & 512 /* MEMBER_FLAGS.ReflectAttr */) {
cmpMeta.$attrsToReflect$.push([propName, attrName]);
}
return attrName;
});
}
}
return Cstr;
};
const initializeComponent = async (elm, hostRef, cmpMeta, hmrVersionId, Cstr) => {
// initializeComponent
if ((hostRef.$flags$ & 32 /* HOST_FLAGS.hasInitializedComponent */) === 0) {
{
// we haven't initialized this element yet
hostRef.$flags$ |= 32 /* HOST_FLAGS.hasInitializedComponent */;
// lazy loaded components
// request the component's implementation to be
// wired up with the host element
Cstr = loadModule(cmpMeta);
if (Cstr.then) {
// Await creates a micro-task avoid if possible
const endLoad = uniqueTime();
Cstr = await Cstr;
endLoad();
}
if (!Cstr.isProxied) {
// we've never proxied this Constructor before
// let's add the getters/setters to its prototype before
// the first time we create an instance of the implementation
{
cmpMeta.$watchers$ = Cstr.watchers;
}
proxyComponent(Cstr, cmpMeta, 2 /* PROXY_FLAGS.proxyState */);
Cstr.isProxied = true;
}
const endNewInstance = createTime('createInstance', cmpMeta.$tagName$);
// ok, time to construct the instance
// but let's keep track of when we start and stop
// so that the getters/setters don't incorrectly step on data
{
hostRef.$flags$ |= 8 /* HOST_FLAGS.isConstructingInstance */;
}
// construct the lazy-loaded component implementation
// passing the hostRef is very important during
// construction in order to directly wire together the
// host element and the lazy-loaded instance
try {
new Cstr(hostRef);
}
catch (e) {
consoleError(e);
}
{
hostRef.$flags$ &= ~8 /* HOST_FLAGS.isConstructingInstance */;
}
{
hostRef.$flags$ |= 128 /* HOST_FLAGS.isWatchReady */;
}
endNewInstance();
fireConnectedCallback(hostRef.$lazyInstance$);
}
if (Cstr.style) {
// this component has styles but we haven't registered them yet
let style = Cstr.style;
const scopeId = getScopeId(cmpMeta);
if (!styles.has(scopeId)) {
const endRegisterStyles = createTime('registerStyles', cmpMeta.$tagName$);
registerStyle(scopeId, style, !!(cmpMeta.$flags$ & 1 /* CMP_FLAGS.shadowDomEncapsulation */));
endRegisterStyles();
}
}
}
// we've successfully created a lazy instance
const ancestorComponent = hostRef.$ancestorComponent$;
const schedule = () => scheduleUpdate(hostRef, true);
if (ancestorComponent && ancestorComponent['s-rc']) {
// this is the initial load and this component it has an ancestor component
// but the ancestor component has NOT fired its will update lifecycle yet
// so let's just cool our jets and wait for the ancestor to continue first
// this will get fired off when the ancestor component
// finally gets around to rendering its lazy self
// fire off the initial update
ancestorComponent['s-rc'].push(schedule);
}
else {
schedule();
}
};
const fireConnectedCallback = (instance) => {
{
safeCall(instance, 'connectedCallback');
}
};
const connectedCallback = (elm) => {
if ((plt.$flags$ & 1 /* PLATFORM_FLAGS.isTmpDisconnected */) === 0) {
const hostRef = getHostRef(elm);
const cmpMeta = hostRef.$cmpMeta$;
const endConnected = createTime('connectedCallback', cmpMeta.$tagName$);
if (!(hostRef.$flags$ & 1 /* HOST_FLAGS.hasConnected */)) {
// first time this component has connected
hostRef.$flags$ |= 1 /* HOST_FLAGS.hasConnected */;
{
// find the first ancestor component (if there is one) and register
// this component as one of the actively loading child components for its ancestor
let ancestorComponent = elm;
while ((ancestorComponent = ancestorComponent.parentNode || ancestorComponent.host)) {
// climb up the ancestors looking for the first
// component that hasn't finished its lifecycle update yet
if (ancestorComponent['s-p']) {
// we found this components first ancestor component
// keep a reference to this component's ancestor component
attachToAncestor(hostRef, (hostRef.$ancestorComponent$ = ancestorComponent));
break;
}
}
}
// Lazy properties
// https://developers.google.com/web/fundamentals/web-components/best-practices#lazy-properties
if (cmpMeta.$members$) {
Object.entries(cmpMeta.$members$).map(([memberName, [memberFlags]]) => {
if (memberFlags & 31 /* MEMBER_FLAGS.Prop */ && elm.hasOwnProperty(memberName)) {
const value = elm[memberName];
delete elm[memberName];
elm[memberName] = value;
}
});
}
{
initializeComponent(elm, hostRef, cmpMeta);
}
}
else {
// fire off connectedCallback() on component instance
fireConnectedCallback(hostRef.$lazyInstance$);
}
endConnected();
}
};
const disconnectedCallback = (elm) => {
if ((plt.$flags$ & 1 /* PLATFORM_FLAGS.isTmpDisconnected */) === 0) {
const hostRef = getHostRef(elm);
const instance = hostRef.$lazyInstance$ ;
{
safeCall(instance, 'disconnectedCallback');
}
}
};
const bootstrapLazy = (lazyBundles, options = {}) => {
const endBootstrap = createTime();
const cmpTags = [];
const exclude = options.exclude || [];
const customElements = win.customElements;
const head = doc.head;
const metaCharset = /*@__PURE__*/ head.querySelector('meta[charset]');
const visibilityStyle = /*@__PURE__*/ doc.createElement('style');
const deferredConnectedCallbacks = [];
let appLoadFallback;
let isBootstrapping = true;
Object.assign(plt, options);
plt.$resourcesUrl$ = new URL(options.resourcesUrl || './', doc.baseURI).href;
lazyBundles.map((lazyBundle) => {
lazyBundle[1].map((compactMeta) => {
const cmpMeta = {
$flags$: compactMeta[0],
$tagName$: compactMeta[1],
$members$: compactMeta[2],
$listeners$: compactMeta[3],
};
{
cmpMeta.$members$ = compactMeta[2];
}
{
cmpMeta.$attrsToReflect$ = [];
}
{
cmpMeta.$watchers$ = {};
}
const tagName = cmpMeta.$tagName$;
const HostElement = class extends HTMLElement {
// StencilLazyHost
constructor(self) {
// @ts-ignore
super(self);
self = this;
registerHost(self, cmpMeta);
if (cmpMeta.$flags$ & 1 /* CMP_FLAGS.shadowDomEncapsulation */) {
// this component is using shadow dom
// and this browser supports shadow dom
// add the read-only property "shadowRoot" to the host element
// adding the shadow root build conditionals to minimize runtime
{
{
self.attachShadow({ mode: 'open' });
}
}
}
}
connectedCallback() {
if (appLoadFallback) {
clearTimeout(appLoadFallback);
appLoadFallback = null;
}
if (isBootstrapping) {
// connectedCallback will be processed once all components have been registered
deferredConnectedCallbacks.push(this);
}
else {
plt.jmp(() => connectedCallback(this));
}
}
disconnectedCallback() {
plt.jmp(() => disconnectedCallback(this));
}
componentOnReady() {
return getHostRef(this).$onReadyPromise$;
}
};
cmpMeta.$lazyBundleId$ = lazyBundle[0];
if (!exclude.includes(tagName) && !customElements.get(tagName)) {
cmpTags.push(tagName);
customElements.define(tagName, proxyComponent(HostElement, cmpMeta, 1 /* PROXY_FLAGS.isElementConstructor */));
}
});
});
{
visibilityStyle.innerHTML = cmpTags + HYDRATED_CSS;
visibilityStyle.setAttribute('data-styles', '');
head.insertBefore(visibilityStyle, metaCharset ? metaCharset.nextSibling : head.firstChild);
}
// Process deferred connectedCallbacks now all components have been registered
isBootstrapping = false;
if (deferredConnectedCallbacks.length) {
deferredConnectedCallbacks.map((host) => host.connectedCallback());
}
else {
{
plt.jmp(() => (appLoadFallback = setTimeout(appDidLoad, 30)));
}
}
// Fallback appLoad event
endBootstrap();
};
const getAssetPath = (path) => {
const assetUrl = new URL(path, plt.$resourcesUrl$);
return assetUrl.origin !== win.location.origin ? assetUrl.href : assetUrl.pathname;
};
const hostRefs = /*@__PURE__*/ new WeakMap();
const getHostRef = (ref) => hostRefs.get(ref);
const registerInstance = (lazyInstance, hostRef) => hostRefs.set((hostRef.$lazyInstance$ = lazyInstance), hostRef);
const registerHost = (elm, cmpMeta) => {
const hostRef = {
$flags$: 0,
$hostElement$: elm,
$cmpMeta$: cmpMeta,
$instanceValues$: new Map(),
};
{
hostRef.$onReadyPromise$ = new Promise((r) => (hostRef.$onReadyResolve$ = r));
elm['s-p'] = [];
elm['s-rc'] = [];
}
return hostRefs.set(elm, hostRef);
};
const isMemberInElement = (elm, memberName) => memberName in elm;
const consoleError = (e, el) => (0, console.error)(e, el);
const cmpModules = /*@__PURE__*/ new Map();
const loadModule = (cmpMeta, hostRef, hmrVersionId) => {
// loadModuleImport
const exportName = cmpMeta.$tagName$.replace(/-/g, '_');
const bundleId = cmpMeta.$lazyBundleId$;
const module = cmpModules.get(bundleId) ;
if (module) {
return module[exportName];
}
/*!__STENCIL_STATIC_IMPORT_SWITCH__*/
return Promise.resolve().then(function () { return /*#__PURE__*/_interopNamespace(require(
/* @vite-ignore */
/* webpackInclude: /\.entry\.js$/ */
/* webpackExclude: /\.system\.entry\.js$/ */
/* webpackMode: "lazy" */
`./${bundleId}.entry.js${''}`)); }).then((importedModule) => {
{
cmpModules.set(bundleId, importedModule);
}
return importedModule[exportName];
}, consoleError);
};
const styles = /*@__PURE__*/ new Map();
const queueDomReads = [];
const queueDomWrites = [];
const queueTask = (queue, write) => (cb) => {
queue.push(cb);
if (!queuePending) {
queuePending = true;
if (write && plt.$flags$ & 4 /* PLATFORM_FLAGS.queueSync */) {
nextTick(flush);
}
else {
plt.raf(flush);
}
}
};
const consume = (queue) => {
for (let i = 0; i < queue.length; i++) {
try {
queue[i](performance.now());
}
catch (e) {
consoleError(e);
}
}
queue.length = 0;
};
const flush = () => {
// always force a bunch of medium callbacks to run, but still have
// a throttle on how many can run in a certain time
// DOM READS!!!
consume(queueDomReads);
// DOM WRITES!!!
{
consume(queueDomWrites);
if ((queuePending = queueDomReads.length > 0)) {
// still more to do yet, but we've run out of time
// let's let this thing cool off and try again in the next tick
plt.raf(flush);
}
}
};
const nextTick = /*@__PURE__*/ (cb) => promiseResolve().then(cb);
const writeTask = /*@__PURE__*/ queueTask(queueDomWrites, true);
exports.Host = Host;
exports.bootstrapLazy = bootstrapLazy;
exports.getAssetPath = getAssetPath;
exports.getElement = getElement;
exports.h = h;
exports.promiseResolve = promiseResolve;
exports.registerInstance = registerInstance;