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ReactFiberLane.js
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ReactFiberLane.js
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/**
* Copyright (c) Facebook, Inc. and its affiliates.
*
* This source code is licensed under the MIT license found in the
* LICENSE file in the root directory of this source tree.
*
* @flow
*/
import type {FiberRoot, ReactPriorityLevel} from './ReactInternalTypes';
export opaque type LanePriority =
| 0
| 1
| 2
| 3
| 4
| 5
| 6
| 7
| 8
| 9
| 10
| 11
| 12
| 13
| 14
| 15
| 16
| 17;
export opaque type Lanes = number;
export opaque type Lane = number;
export opaque type LaneMap<T> = Array<T>;
import invariant from 'shared/invariant';
import {
ImmediatePriority as ImmediateSchedulerPriority,
UserBlockingPriority as UserBlockingSchedulerPriority,
NormalPriority as NormalSchedulerPriority,
LowPriority as LowSchedulerPriority,
IdlePriority as IdleSchedulerPriority,
NoPriority as NoSchedulerPriority,
} from './SchedulerWithReactIntegration.new';
export const SyncLanePriority: LanePriority = 15;
export const SyncBatchedLanePriority: LanePriority = 14;
const InputDiscreteHydrationLanePriority: LanePriority = 13;
export const InputDiscreteLanePriority: LanePriority = 12;
const InputContinuousHydrationLanePriority: LanePriority = 11;
export const InputContinuousLanePriority: LanePriority = 10;
const DefaultHydrationLanePriority: LanePriority = 9;
export const DefaultLanePriority: LanePriority = 8;
const TransitionHydrationPriority: LanePriority = 7;
export const TransitionPriority: LanePriority = 6;
const RetryLanePriority: LanePriority = 5;
const SelectiveHydrationLanePriority: LanePriority = 4;
const IdleHydrationLanePriority: LanePriority = 3;
const IdleLanePriority: LanePriority = 2;
const OffscreenLanePriority: LanePriority = 1;
export const NoLanePriority: LanePriority = 0;
const TotalLanes = 31;
export const NoLanes: Lanes = /* */ 0b0000000000000000000000000000000;
export const NoLane: Lane = /* */ 0b0000000000000000000000000000000;
export const SyncLane: Lane = /* */ 0b0000000000000000000000000000001;
export const SyncBatchedLane: Lane = /* */ 0b0000000000000000000000000000010;
export const InputDiscreteHydrationLane: Lane = /* */ 0b0000000000000000000000000000100;
const InputDiscreteLanes: Lanes = /* */ 0b0000000000000000000000000011000;
const InputContinuousHydrationLane: Lane = /* */ 0b0000000000000000000000000100000;
const InputContinuousLanes: Lanes = /* */ 0b0000000000000000000000011000000;
export const DefaultHydrationLane: Lane = /* */ 0b0000000000000000000000100000000;
export const DefaultLanes: Lanes = /* */ 0b0000000000000000000111000000000;
const TransitionHydrationLane: Lane = /* */ 0b0000000000000000001000000000000;
const TransitionLanes: Lanes = /* */ 0b0000000001111111110000000000000;
const RetryLanes: Lanes = /* */ 0b0000011110000000000000000000000;
export const SomeRetryLane: Lanes = /* */ 0b0000010000000000000000000000000;
export const SelectiveHydrationLane: Lane = /* */ 0b0000100000000000000000000000000;
const NonIdleLanes = /* */ 0b0000111111111111111111111111111;
export const IdleHydrationLane: Lane = /* */ 0b0001000000000000000000000000000;
const IdleLanes: Lanes = /* */ 0b0110000000000000000000000000000;
export const OffscreenLane: Lane = /* */ 0b1000000000000000000000000000000;
export const NoTimestamp = -1;
let currentUpdateLanePriority: LanePriority = NoLanePriority;
export function getCurrentUpdateLanePriority(): LanePriority {
return currentUpdateLanePriority;
}
export function setCurrentUpdateLanePriority(newLanePriority: LanePriority) {
currentUpdateLanePriority = newLanePriority;
}
// "Registers" used to "return" multiple values
// Used by getHighestPriorityLanes and getNextLanes:
let return_highestLanePriority: LanePriority = DefaultLanePriority;
function getHighestPriorityLanes(lanes: Lanes | Lane): Lanes {
if ((SyncLane & lanes) !== NoLanes) {
return_highestLanePriority = SyncLanePriority;
return SyncLane;
}
if ((SyncBatchedLane & lanes) !== NoLanes) {
return_highestLanePriority = SyncBatchedLanePriority;
return SyncBatchedLane;
}
if ((InputDiscreteHydrationLane & lanes) !== NoLanes) {
return_highestLanePriority = InputDiscreteHydrationLanePriority;
return InputDiscreteHydrationLane;
}
const inputDiscreteLanes = InputDiscreteLanes & lanes;
if (inputDiscreteLanes !== NoLanes) {
return_highestLanePriority = InputDiscreteLanePriority;
return inputDiscreteLanes;
}
if ((lanes & InputContinuousHydrationLane) !== NoLanes) {
return_highestLanePriority = InputContinuousHydrationLanePriority;
return InputContinuousHydrationLane;
}
const inputContinuousLanes = InputContinuousLanes & lanes;
if (inputContinuousLanes !== NoLanes) {
return_highestLanePriority = InputContinuousLanePriority;
return inputContinuousLanes;
}
if ((lanes & DefaultHydrationLane) !== NoLanes) {
return_highestLanePriority = DefaultHydrationLanePriority;
return DefaultHydrationLane;
}
const defaultLanes = DefaultLanes & lanes;
if (defaultLanes !== NoLanes) {
return_highestLanePriority = DefaultLanePriority;
return defaultLanes;
}
if ((lanes & TransitionHydrationLane) !== NoLanes) {
return_highestLanePriority = TransitionHydrationPriority;
return TransitionHydrationLane;
}
const transitionLanes = TransitionLanes & lanes;
if (transitionLanes !== NoLanes) {
return_highestLanePriority = TransitionPriority;
return transitionLanes;
}
const retryLanes = RetryLanes & lanes;
if (retryLanes !== NoLanes) {
return_highestLanePriority = RetryLanePriority;
return retryLanes;
}
if (lanes & SelectiveHydrationLane) {
return_highestLanePriority = SelectiveHydrationLanePriority;
return SelectiveHydrationLane;
}
if ((lanes & IdleHydrationLane) !== NoLanes) {
return_highestLanePriority = IdleHydrationLanePriority;
return IdleHydrationLane;
}
const idleLanes = IdleLanes & lanes;
if (idleLanes !== NoLanes) {
return_highestLanePriority = IdleLanePriority;
return idleLanes;
}
if ((OffscreenLane & lanes) !== NoLanes) {
return_highestLanePriority = OffscreenLanePriority;
return OffscreenLane;
}
if (__DEV__) {
console.error('Should have found matching lanes. This is a bug in React.');
}
// This shouldn't be reachable, but as a fallback, return the entire bitmask.
return_highestLanePriority = DefaultLanePriority;
return lanes;
}
export function schedulerPriorityToLanePriority(
schedulerPriorityLevel: ReactPriorityLevel,
): LanePriority {
switch (schedulerPriorityLevel) {
case ImmediateSchedulerPriority:
return SyncLanePriority;
case UserBlockingSchedulerPriority:
return InputContinuousLanePriority;
case NormalSchedulerPriority:
case LowSchedulerPriority:
// TODO: Handle LowSchedulerPriority, somehow. Maybe the same lane as hydration.
return DefaultLanePriority;
case IdleSchedulerPriority:
return IdleLanePriority;
default:
return NoLanePriority;
}
}
export function lanePriorityToSchedulerPriority(
lanePriority: LanePriority,
): ReactPriorityLevel {
switch (lanePriority) {
case SyncLanePriority:
case SyncBatchedLanePriority:
return ImmediateSchedulerPriority;
case InputDiscreteHydrationLanePriority:
case InputDiscreteLanePriority:
case InputContinuousHydrationLanePriority:
case InputContinuousLanePriority:
return UserBlockingSchedulerPriority;
case DefaultHydrationLanePriority:
case DefaultLanePriority:
case TransitionHydrationPriority:
case TransitionPriority:
case SelectiveHydrationLanePriority:
case RetryLanePriority:
return NormalSchedulerPriority;
case IdleHydrationLanePriority:
case IdleLanePriority:
case OffscreenLanePriority:
return IdleSchedulerPriority;
case NoLanePriority:
return NoSchedulerPriority;
default:
invariant(
false,
'Invalid update priority: %s. This is a bug in React.',
lanePriority,
);
}
}
export function getNextLanes(root: FiberRoot, wipLanes: Lanes): Lanes {
// Early bailout if there's no pending work left.
const pendingLanes = root.pendingLanes;
if (pendingLanes === NoLanes) {
return_highestLanePriority = NoLanePriority;
return NoLanes;
}
let nextLanes = NoLanes;
let nextLanePriority = NoLanePriority;
const expiredLanes = root.expiredLanes;
const suspendedLanes = root.suspendedLanes;
const pingedLanes = root.pingedLanes;
// Check if any work has expired.
if (expiredLanes !== NoLanes) {
nextLanes = expiredLanes;
nextLanePriority = return_highestLanePriority = SyncLanePriority;
} else {
// Do not work on any idle work until all the non-idle work has finished,
// even if the work is suspended.
const nonIdlePendingLanes = pendingLanes & NonIdleLanes;
if (nonIdlePendingLanes !== NoLanes) {
const nonIdleUnblockedLanes = nonIdlePendingLanes & ~suspendedLanes;
if (nonIdleUnblockedLanes !== NoLanes) {
nextLanes = getHighestPriorityLanes(nonIdleUnblockedLanes);
nextLanePriority = return_highestLanePriority;
} else {
const nonIdlePingedLanes = nonIdlePendingLanes & pingedLanes;
if (nonIdlePingedLanes !== NoLanes) {
nextLanes = getHighestPriorityLanes(nonIdlePingedLanes);
nextLanePriority = return_highestLanePriority;
}
}
} else {
// The only remaining work is Idle.
const unblockedLanes = pendingLanes & ~suspendedLanes;
if (unblockedLanes !== NoLanes) {
nextLanes = getHighestPriorityLanes(unblockedLanes);
nextLanePriority = return_highestLanePriority;
} else {
if (pingedLanes !== NoLanes) {
nextLanes = getHighestPriorityLanes(pingedLanes);
nextLanePriority = return_highestLanePriority;
}
}
}
}
if (nextLanes === NoLanes) {
// This should only be reachable if we're suspended
// TODO: Consider warning in this path if a fallback timer is not scheduled.
return NoLanes;
}
// If there are higher priority lanes, we'll include them even if they
// are suspended.
nextLanes = pendingLanes & getEqualOrHigherPriorityLanes(nextLanes);
// If we're already in the middle of a render, switching lanes will interrupt
// it and we'll lose our progress. We should only do this if the new lanes are
// higher priority.
if (
wipLanes !== NoLanes &&
wipLanes !== nextLanes &&
// If we already suspended with a delay, then interrupting is fine. Don't
// bother waiting until the root is complete.
(wipLanes & suspendedLanes) === NoLanes
) {
getHighestPriorityLanes(wipLanes);
const wipLanePriority = return_highestLanePriority;
if (nextLanePriority <= wipLanePriority) {
return wipLanes;
} else {
return_highestLanePriority = nextLanePriority;
}
}
// Check for entangled lanes and add them to the batch.
//
// A lane is said to be entangled with another when it's not allowed to render
// in a batch that does not also include the other lane. Typically we do this
// when multiple updates have the same source, and we only want to respond to
// the most recent event from that source.
//
// Note that we apply entanglements *after* checking for partial work above.
// This means that if a lane is entangled during an interleaved event while
// it's already rendering, we won't interrupt it. This is intentional, since
// entanglement is usually "best effort": we'll try our best to render the
// lanes in the same batch, but it's not worth throwing out partially
// completed work in order to do it.
//
// For those exceptions where entanglement is semantically important, like
// useMutableSource, we should ensure that there is no partial work at the
// time we apply the entanglement.
const entangledLanes = root.entangledLanes;
if (entangledLanes !== NoLanes) {
const entanglements = root.entanglements;
let lanes = nextLanes & entangledLanes;
while (lanes > 0) {
const index = pickArbitraryLaneIndex(lanes);
const lane = 1 << index;
nextLanes |= entanglements[index];
lanes &= ~lane;
}
}
return nextLanes;
}
export function getMostRecentEventTime(root: FiberRoot, lanes: Lanes): number {
const eventTimes = root.eventTimes;
let mostRecentEventTime = NoTimestamp;
while (lanes > 0) {
const index = pickArbitraryLaneIndex(lanes);
const lane = 1 << index;
const eventTime = eventTimes[index];
if (eventTime > mostRecentEventTime) {
mostRecentEventTime = eventTime;
}
lanes &= ~lane;
}
return mostRecentEventTime;
}
function computeExpirationTime(lane: Lane, currentTime: number) {
// TODO: Expiration heuristic is constant per lane, so could use a map.
getHighestPriorityLanes(lane);
const priority = return_highestLanePriority;
if (priority >= InputContinuousLanePriority) {
// User interactions should expire slightly more quickly.
//
// NOTE: This is set to the corresponding constant as in Scheduler.js. When
// we made it larger, a product metric in www regressed, suggesting there's
// a user interaction that's being starved by a series of synchronous
// updates. If that theory is correct, the proper solution is to fix the
// starvation. However, this scenario supports the idea that expiration
// times are an important safeguard when starvation does happen.
//
// Also note that, in the case of user input specifically, this will soon no
// longer be an issue because we plan to make user input synchronous by
// default (until you enter `startTransition`, of course.)
//
// If weren't planning to make these updates synchronous soon anyway, I
// would probably make this number a configurable parameter.
return currentTime + 250;
} else if (priority >= TransitionPriority) {
return currentTime + 5000;
} else {
// Anything idle priority or lower should never expire.
return NoTimestamp;
}
}
export function markStarvedLanesAsExpired(
root: FiberRoot,
currentTime: number,
): void {
// TODO: This gets called every time we yield. We can optimize by storing
// the earliest expiration time on the root. Then use that to quickly bail out
// of this function.
const pendingLanes = root.pendingLanes;
const suspendedLanes = root.suspendedLanes;
const pingedLanes = root.pingedLanes;
const expirationTimes = root.expirationTimes;
// Iterate through the pending lanes and check if we've reached their
// expiration time. If so, we'll assume the update is being starved and mark
// it as expired to force it to finish.
let lanes = pendingLanes;
while (lanes > 0) {
const index = pickArbitraryLaneIndex(lanes);
const lane = 1 << index;
const expirationTime = expirationTimes[index];
if (expirationTime === NoTimestamp) {
// Found a pending lane with no expiration time. If it's not suspended, or
// if it's pinged, assume it's CPU-bound. Compute a new expiration time
// using the current time.
if (
(lane & suspendedLanes) === NoLanes ||
(lane & pingedLanes) !== NoLanes
) {
// Assumes timestamps are monotonically increasing.
expirationTimes[index] = computeExpirationTime(lane, currentTime);
}
} else if (expirationTime <= currentTime) {
// This lane expired
root.expiredLanes |= lane;
}
lanes &= ~lane;
}
}
// This returns the highest priority pending lanes regardless of whether they
// are suspended.
export function getHighestPriorityPendingLanes(root: FiberRoot) {
return getHighestPriorityLanes(root.pendingLanes);
}
export function getLanesToRetrySynchronouslyOnError(root: FiberRoot): Lanes {
const everythingButOffscreen = root.pendingLanes & ~OffscreenLane;
if (everythingButOffscreen !== NoLanes) {
return everythingButOffscreen;
}
if (everythingButOffscreen & OffscreenLane) {
return OffscreenLane;
}
return NoLanes;
}
export function returnNextLanesPriority() {
return return_highestLanePriority;
}
export function includesNonIdleWork(lanes: Lanes) {
return (lanes & NonIdleLanes) !== NoLanes;
}
export function includesOnlyRetries(lanes: Lanes) {
return (lanes & RetryLanes) === lanes;
}
export function includesOnlyTransitions(lanes: Lanes) {
return (lanes & TransitionLanes) === lanes;
}
// To ensure consistency across multiple updates in the same event, this should
// be a pure function, so that it always returns the same lane for given inputs.
export function findUpdateLane(
lanePriority: LanePriority,
wipLanes: Lanes,
): Lane {
switch (lanePriority) {
case NoLanePriority:
break;
case SyncLanePriority:
return SyncLane;
case SyncBatchedLanePriority:
return SyncBatchedLane;
case InputDiscreteLanePriority: {
const lane = pickArbitraryLane(InputDiscreteLanes & ~wipLanes);
if (lane === NoLane) {
// Shift to the next priority level
return findUpdateLane(InputContinuousLanePriority, wipLanes);
}
return lane;
}
case InputContinuousLanePriority: {
const lane = pickArbitraryLane(InputContinuousLanes & ~wipLanes);
if (lane === NoLane) {
// Shift to the next priority level
return findUpdateLane(DefaultLanePriority, wipLanes);
}
return lane;
}
case DefaultLanePriority: {
let lane = pickArbitraryLane(DefaultLanes & ~wipLanes);
if (lane === NoLane) {
// If all the default lanes are already being worked on, look for a
// lane in the transition range.
lane = pickArbitraryLane(TransitionLanes & ~wipLanes);
if (lane === NoLane) {
// All the transition lanes are taken, too. This should be very
// rare, but as a last resort, pick a default lane. This will have
// the effect of interrupting the current work-in-progress render.
lane = pickArbitraryLane(DefaultLanes);
}
}
return lane;
}
case TransitionPriority: // Should be handled by findTransitionLane instead
case RetryLanePriority: // Should be handled by findRetryLane instead
break;
case IdleLanePriority:
let lane = pickArbitraryLane(IdleLanes & ~wipLanes);
if (lane === NoLane) {
lane = pickArbitraryLane(IdleLanes);
}
return lane;
default:
// The remaining priorities are not valid for updates
break;
}
invariant(
false,
'Invalid update priority: %s. This is a bug in React.',
lanePriority,
);
}
// To ensure consistency across multiple updates in the same event, this should
// be pure function, so that it always returns the same lane for given inputs.
export function findTransitionLane(wipLanes: Lanes, pendingLanes: Lanes): Lane {
// First look for lanes that are completely unclaimed, i.e. have no
// pending work.
let lane = pickArbitraryLane(TransitionLanes & ~pendingLanes);
if (lane === NoLane) {
// If all lanes have pending work, look for a lane that isn't currently
// being worked on.
lane = pickArbitraryLane(TransitionLanes & ~wipLanes);
if (lane === NoLane) {
// If everything is being worked on, pick any lane. This has the
// effect of interrupting the current work-in-progress.
lane = pickArbitraryLane(TransitionLanes);
}
}
return lane;
}
// To ensure consistency across multiple updates in the same event, this should
// be pure function, so that it always returns the same lane for given inputs.
export function findRetryLane(wipLanes: Lanes): Lane {
// This is a fork of `findUpdateLane` designed specifically for Suspense
// "retries" — a special update that attempts to flip a Suspense boundary
// from its placeholder state to its primary/resolved state.
let lane = pickArbitraryLane(RetryLanes & ~wipLanes);
if (lane === NoLane) {
lane = pickArbitraryLane(RetryLanes);
}
return lane;
}
function getHighestPriorityLane(lanes: Lanes) {
return lanes & -lanes;
}
function getLowestPriorityLane(lanes: Lanes): Lane {
// This finds the most significant non-zero bit.
const index = 31 - clz32(lanes);
return index < 0 ? NoLanes : 1 << index;
}
function getEqualOrHigherPriorityLanes(lanes: Lanes | Lane): Lanes {
return (getLowestPriorityLane(lanes) << 1) - 1;
}
export function pickArbitraryLane(lanes: Lanes): Lane {
// This wrapper function gets inlined. Only exists so to communicate that it
// doesn't matter which bit is selected; you can pick any bit without
// affecting the algorithms where its used. Here I'm using
// getHighestPriorityLane because it requires the fewest operations.
return getHighestPriorityLane(lanes);
}
function pickArbitraryLaneIndex(lanes: Lanes) {
return 31 - clz32(lanes);
}
function laneToIndex(lane: Lane) {
return pickArbitraryLaneIndex(lane);
}
export function includesSomeLane(a: Lanes | Lane, b: Lanes | Lane) {
return (a & b) !== NoLanes;
}
export function isSubsetOfLanes(set: Lanes, subset: Lanes | Lane) {
return (set & subset) === subset;
}
export function mergeLanes(a: Lanes | Lane, b: Lanes | Lane): Lanes {
return a | b;
}
export function removeLanes(set: Lanes, subset: Lanes | Lane): Lanes {
return set & ~subset;
}
// Seems redundant, but it changes the type from a single lane (used for
// updates) to a group of lanes (used for flushing work).
export function laneToLanes(lane: Lane): Lanes {
return lane;
}
export function higherPriorityLane(a: Lane, b: Lane) {
// This works because the bit ranges decrease in priority as you go left.
return a !== NoLane && a < b ? a : b;
}
export function higherLanePriority(
a: LanePriority,
b: LanePriority,
): LanePriority {
return a !== NoLanePriority && a > b ? a : b;
}
export function createLaneMap<T>(initial: T): LaneMap<T> {
// Intentionally pushing one by one.
// https://v8.dev/blog/elements-kinds#avoid-creating-holes
const laneMap = [];
for (let i = 0; i < TotalLanes; i++) {
laneMap.push(initial);
}
return laneMap;
}
export function markRootUpdated(
root: FiberRoot,
updateLane: Lane,
eventTime: number,
) {
root.pendingLanes |= updateLane;
// TODO: Theoretically, any update to any lane can unblock any other lane. But
// it's not practical to try every single possible combination. We need a
// heuristic to decide which lanes to attempt to render, and in which batches.
// For now, we use the same heuristic as in the old ExpirationTimes model:
// retry any lane at equal or lower priority, but don't try updates at higher
// priority without also including the lower priority updates. This works well
// when considering updates across different priority levels, but isn't
// sufficient for updates within the same priority, since we want to treat
// those updates as parallel.
// Unsuspend any update at equal or lower priority.
const higherPriorityLanes = updateLane - 1; // Turns 0b1000 into 0b0111
root.suspendedLanes &= higherPriorityLanes;
root.pingedLanes &= higherPriorityLanes;
const eventTimes = root.eventTimes;
const index = laneToIndex(updateLane);
// We can always overwrite an existing timestamp because we prefer the most
// recent event, and we assume time is monotonically increasing.
eventTimes[index] = eventTime;
}
export function markRootSuspended(root: FiberRoot, suspendedLanes: Lanes) {
root.suspendedLanes |= suspendedLanes;
root.pingedLanes &= ~suspendedLanes;
// The suspended lanes are no longer CPU-bound. Clear their expiration times.
const expirationTimes = root.expirationTimes;
let lanes = suspendedLanes;
while (lanes > 0) {
const index = pickArbitraryLaneIndex(lanes);
const lane = 1 << index;
expirationTimes[index] = NoTimestamp;
lanes &= ~lane;
}
}
export function markRootPinged(
root: FiberRoot,
pingedLanes: Lanes,
eventTime: number,
) {
root.pingedLanes |= root.suspendedLanes & pingedLanes;
}
export function markRootExpired(root: FiberRoot, expiredLanes: Lanes) {
root.expiredLanes |= expiredLanes & root.pendingLanes;
}
export function markDiscreteUpdatesExpired(root: FiberRoot) {
root.expiredLanes |= InputDiscreteLanes & root.pendingLanes;
}
export function hasDiscreteLanes(lanes: Lanes) {
return (lanes & InputDiscreteLanes) !== NoLanes;
}
export function markRootMutableRead(root: FiberRoot, updateLane: Lane) {
root.mutableReadLanes |= updateLane & root.pendingLanes;
}
export function markRootFinished(root: FiberRoot, remainingLanes: Lanes) {
const noLongerPendingLanes = root.pendingLanes & ~remainingLanes;
root.pendingLanes = remainingLanes;
// Let's try everything again
root.suspendedLanes = 0;
root.pingedLanes = 0;
root.expiredLanes &= remainingLanes;
root.mutableReadLanes &= remainingLanes;
root.entangledLanes &= remainingLanes;
const entanglements = root.entanglements;
const eventTimes = root.eventTimes;
const expirationTimes = root.expirationTimes;
// Clear the lanes that no longer have pending work
let lanes = noLongerPendingLanes;
while (lanes > 0) {
const index = pickArbitraryLaneIndex(lanes);
const lane = 1 << index;
entanglements[index] = NoLanes;
eventTimes[index] = NoTimestamp;
expirationTimes[index] = NoTimestamp;
lanes &= ~lane;
}
}
export function markRootEntangled(root: FiberRoot, entangledLanes: Lanes) {
root.entangledLanes |= entangledLanes;
const entanglements = root.entanglements;
let lanes = entangledLanes;
while (lanes > 0) {
const index = pickArbitraryLaneIndex(lanes);
const lane = 1 << index;
entanglements[index] |= entangledLanes;
lanes &= ~lane;
}
}
export function getBumpedLaneForHydration(
root: FiberRoot,
renderLanes: Lanes,
): Lane {
getHighestPriorityLanes(renderLanes);
const highestLanePriority = return_highestLanePriority;
let lane;
switch (highestLanePriority) {
case SyncLanePriority:
case SyncBatchedLanePriority:
lane = NoLane;
break;
case InputDiscreteHydrationLanePriority:
case InputDiscreteLanePriority:
lane = InputDiscreteHydrationLane;
break;
case InputContinuousHydrationLanePriority:
case InputContinuousLanePriority:
lane = InputContinuousHydrationLane;
break;
case DefaultHydrationLanePriority:
case DefaultLanePriority:
lane = DefaultHydrationLane;
break;
case TransitionHydrationPriority:
case TransitionPriority:
lane = TransitionHydrationLane;
break;
case RetryLanePriority:
// Shouldn't be reachable under normal circumstances, so there's no
// dedicated lane for retry priority. Use the one for long transitions.
lane = TransitionHydrationLane;
break;
case SelectiveHydrationLanePriority:
lane = SelectiveHydrationLane;
break;
case IdleHydrationLanePriority:
case IdleLanePriority:
lane = IdleHydrationLane;
break;
case OffscreenLanePriority:
case NoLanePriority:
lane = NoLane;
break;
default:
invariant(false, 'Invalid lane: %s. This is a bug in React.', lane);
}
// Check if the lane we chose is suspended. If so, that indicates that we
// already attempted and failed to hydrate at that level. Also check if we're
// already rendering that lane, which is rare but could happen.
if ((lane & (root.suspendedLanes | renderLanes)) !== NoLane) {
// Give up trying to hydrate and fall back to client render.
return NoLane;
}
return lane;
}
const clz32 = Math.clz32 ? Math.clz32 : clz32Fallback;
// Count leading zeros. Only used on lanes, so assume input is an integer.
// Based on:
// https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Global_Objects/Math/clz32
const log = Math.log;
const LN2 = Math.LN2;
function clz32Fallback(lanes: Lanes | Lane) {
if (lanes === 0) {
return 32;
}
return (31 - ((log(lanes) / LN2) | 0)) | 0;
}