When needed.
For the external runtime we always include this wrapper.
For others, we only include it if we have an ViewTransitions affecting.
If we discover the ViewTransitions late, then we can upgrade an already
emitted instruction.
This doesn't yet do anything useful with it, that's coming in a follow
up. This is just the mechanism for how it gets installed.
Stacked on #33194 and #33200.
When Suspense boundaries reveal during streaming, the Fizz runtime will
be responsible for animating the reveal if necessary (not in this PR).
However, for the future runtime to know what to do it needs to know
about the `<ViewTransition>` configuration to apply.
Ofc, these are virtual nodes that disappear from the HTML. We could
model them as comments like we do with other virtual nodes like Suspense
and Activity. However, that doesn't let us target them with
querySelector and CSS (for no-JS transitions). We also don't have to
model every ViewTransition since not every combination can happen using
only the server runtime. So instead this collapses `<ViewTransition>`
and applies the configuration to the inner DOM nodes.
```js
<ViewTransition name="hi">
<div />
<div />
</ViewTransition>
```
Becomes:
```html
<div vt-name="hi" vt-update="auto"></div>
<div vt-name="hi_1" vt-update="auto"></div>
```
I use `vt-` prefix as opposed to `data-` to keep these virtual
attributes away from user specific ones but we're effectively claiming
this namespace.
There are four triggers `vt-update`, `vt-enter`, `vt-exit` and
`vt-share`. The server resolves which ones might apply to this DOM node.
The value represents the class name (after resolving
view-transition-type mappings) or `"auto"` if no specific class name is
needed but this is still a trigger.
The value can also be `"none"`. This is different from missing because
for example an `vt-update="none"` will block mutations inside it from
triggering the boundary where as a missing `vt-update` would bubble up
to be handled by a parent.
`vt-name` is technically only necessary when `vt-share` is specified to
find a pair. However, since an explicit name can also be used to target
specific CSS selectors, we include it even for other cases.
We want to exclude as many of these annotations as possible.
`vt-enter` can only affect the first DOM node inside a Suspense
boundary's content since the reveal would cause it to enter but nothing
deeper inside. Similarly `vt-exit` can only affect the first DOM node
inside a fallback. So for every other case we can exclude them. (For
future MPA ViewTransitions of the whole document it might also be
something we annotate to children inside the `<body>` as well.) Ideally
we'd only include `vt-enter` for Suspense boundaries that actually
flushed a fallback but since we prepare all that content earlier it's
hard to know.
`vt-share` can be anywhere inside an fallback or content. Technically we
don't have to include it outside the root most Suspense boundary or for
boundaries that are inlined into the root shell. However, this is tricky
to detect. It would also not be correct for future MPA ViewTransitions
because in that case the shared scenario can affect anything in the two
documents so it needs to be in every node everywhere which is
effectively what we do. If a `share` class is specified but it has no
explicit name, we can exclude it since it can't match anything.
`vt-update` is only necessary if something below or a sibling might
update like a Suspense boundary. However, since we don't know when
rendering a segment if it'll later asynchronously add a Suspense
boundary later we have to assume that anywhere might have a child. So
these are always included. We collapse to use the inner most one when
directly nested though since that's the one that ends up winning.
There are some weird edge cases that can't be fully modeled by the lack
of virtual nodes.
Removes the `isFallback` flag on Tasks and tracks it on the
formatContext instead.
Less memory and avoids passing and tracking extra arguments to all the
pushStartInstance branches that doesn't need it.
We'll need to be able to track more Suspense related contexts on this
for View Transitions anyway.
Enabled in experimental channel.
We know this is critical semantics to enforce at the HTML level since if
you don't then you can't add explicit boundaries after the fact.
However, this might have to go in a major release to allow for
upgrading.
Stacked on #33150.
We use `noop` functions in a lot of places as place holders. I don't
think there's any real optimizations we get from having separate
instances. This moves them to use a common instance in `shared/noop`.
`fragmentInstance.dispatchEvent(evt)` calls `element.dispatchEvent(evt)`
on the fragment's host parent. This mimics bubbling if the
`fragmentInstance` could receive an event itself.
If the parent is disconnected, there is a dev warning and no event is
dispatched.
This enables `focus` and `focusLast` methods on FragmentInstances to
search nested host components, depth first. Attempts focus on each child
and bails if one is successful. Previously, only the first level of host
children would attempt focus.
Now if we have an example like
```
component MenuItem() {
return (<div><a>{...}</a></div>)
}
component Menu() {
return <Fragment>{items.map(i => <MenuItem i={i} />)}</Fragment>
}
```
We can target focus on the first or last a tag, rather than checking
each wrapping div and then noop.
This adds `compareDocumentPosition(otherNode)` to fragment instances.
The semantics implemented are meant to match typical element
positioning, with some fragment specifics. See the unit tests for all
expectations.
- An element preceding a fragment is `Node.DOCUMENT_POSITION_PRECEDING`
- An element after a fragment is `Node.DOCUMENT_POSITION_FOLLOWING`
- An element containing the fragment is
`Node.DOCUMENT_POSITION_PRECEDING` and
`Node.DOCUMENT_POSITION_CONTAINING`
- An element within the fragment is
`Node.DOCUMENT_POSITION_CONTAINED_BY`
- An element compared against an empty fragment will result in
`Node.DOCUMENT_POSITION_DISCONNECTED` and
`Node.DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC`
Since we assume a fragment instances target children are DOM siblings
and we want to compare the full fragment as a pseudo container, we can
compare against the first target child outside of handling the special
cases (empty fragments and contained elements).
Stacked on #33129. Flagged behind `enableHydrationChangeEvent`.
If you type into a controlled input before hydration and something else
rerenders like a setState in an effect, then the controlled input will
reset to whatever React thought it was. Even with event replaying that
this is stacked on, if the second render happens before event replaying
has fired in a separate task.
We don't want to flush inside the commit phase because then things like
flushSync in these events wouldn't work since they're inside the commit
stack.
This flushes all event replaying between renders by flushing it at the
end of `flushSpawned` work. We've already committed at that point and is
about to either do subsequent renders or yield to event loop for passive
effects which could have these events fired anyway. This just ensures
that they've already happened by the time subsequent renders fire. This
means that there's now a type of event that fire between sync render
passes.
This fixes a long standing issue that controlled inputs gets out of sync
with the browser state if it's changed before we hydrate.
This resolves the issue by replaying the change events (click, input and
change) if the value has changed by the time we commit the hydration.
That way you can reflect the new value in state to bring it in sync. It
does this whether controlled or uncontrolled.
The idea is that this should be ok to replay because it's similar to the
continuous events in that it doesn't replay a sequence but only reflects
the current state of the tree.
Since this is a breaking change I added it behind
`enableHydrationChangeEvent` flag.
There is still an additional issue remaining that I intend to address in
a follow up. If a `useLayoutEffect` triggers an sync rerender on
hydration (always a bad idea) then that can rerender before we have had
a chance to replay the change events. If that renders through a input
then that input will always override the browser value with the
controlled value. Which will reset it before we've had a change to
update to the new value.
Because we now decided whether to outline in the flushing phase, when
we're writing the preamble we don't yet know if we will make that
decision so we don't know if it's safe to omit the external runtime.
However, if you are providing an external runtime it's probably a pretty
safe bet you're streaming something dynamically that's likely to need it
so we can always include it.
The main thing is that this makes it hard to test it because it affects
our tests in ways it wouldn't otherwise so we have to add a bunch of
conditions.
Stacked on #33076.
This fixes a bug where we used the "complete" status but the
DOMContentLoaded event. This checks for not "loading" instead.
We also add a new status where the boundary has been marked as complete
by the server but has not yet flushed either due to being throttled,
suspended on CSS or animating.
Stacked on #33073.
React semantics is that Suspense boundaries reveal with a throttle
(300ms). That helps avoid flashing reveals when a stream reveals many
individual steps back to back. It can also improve overall performance
by batching the layout and paint work that has to happen at each step.
Unfortunately we never implemented this for SSR streaming - only for
client navigations. This is highly noticeable on very dynamic sites with
lots of Suspense boundaries. It can look good with a client nav but feel
glitchy when you reload the page or initial load.
This fixes the Fizz runtime to be throttled and reveals batched into a
single paint at a time. We do this by first tracking the last paint
after the complete (this will be the first paint if `rel="expect"` is
respected). Then in the `completeBoundary` operation we queue the
operation and then flush it all into a throttled batch.
Another motivation is that View Transitions need to operate as a batch
and individual steps get queued in a sequence so it's extra important to
include as much content as possible in each animated step. This will be
done in a follow up for SSR View Transitions.
Stacked on #33066 and #33068.
Currently we're passing `errorDigest` to `completeBoundary` if there is
a client side error (only CSS loading atm). This only exists because of
`completeBoundaryWithStyles`. Normally if there's a server-side error
we'd emit the `clientRenderBoundary` instruction instead. This adds
unnecessary code to the common case where all styles are in the head.
This is about to get worse with batching because client render shouldn't
be throttled but complete should be.
The first commit moves the client render logic inline into
`completeBoundaryWithStyles` so we only pay for it when styles are used.
However, the approach I went with in the second commit is to reuse the
`$RX` instruction instead (`clientRenderBoundary`). That way if you have
both it ends up being amortized. However, it does mean we have to emit
the `$RX` (along with the `$RC` helper if any
`completeBoundaryWithStyles` instruction is needed.
Stacked on #33065.
The runtime is about to be a lot more complicated so we need to start
sharing some more code.
The problem with sharing code is that we want the inline runtime to as
much as possible be isolated in its scope using only a few global
variables to refer across runtimes.
A problem with Closure Compiler is that it refuses to inline functions
if they have closures inside of them. Which makes sense because of how
VMs work it can cause memory leaks. However, in our cases this doesn't
matter and code size matters more. So we can't use many clever tricks.
So this just favors writing the source in the inline form. Then we add
an extra compiler pass to turn those global variables into local
variables in the external runtime.
We normally expect the segment to exist whatever the client does while
streaming. However, when hydration errors at the root of the shell for a
whole document render, then we clear nodes from body which can include
our segments. We don't need them anymore because we switched to client
rendering.
It triggers an error accessing parent node which can safely be ignored.
This just helps avoid confusion in this scenario.
This also covers up the error in #33067. Which doesn't actually cause
any visible problems other than error logging. However, ideally we
wouldn't emit completeBoundary instructions if the boundary is inside a
cancelled fallback.
When we end up creating an incomplete state in the shell we end up not
flushing anything. As a hack, in this case we need to reset the
ResumableState because some of the ResumableState is still relevant
(e.g. any preloads that went into headers) but some of the
ResumableState needs to be reset since they assume that what we produced
actually flushed.
We didn't reset the instructions state but we haven't actually flushed
any of the instructions so it needs to reset.
The semantics of React is that anything outside of Suspense boundaries
in a transition doesn't display until it has fully unsuspended. With SSR
streaming the intention is to preserve that.
We explicitly don't want to support the mode of document streaming
normally supported by the browser where it can paint content as tags
stream in since that leads to content popping in and thrashing in
unpredictable ways. This should instead be modeled explictly by nested
Suspense boundaries or something like SuspenseList.
After the first shell any nested Suspense boundaries are only revealed,
by script, once they're fully streamed in to the next boundary. So this
is already the case there. However, for the initial shell we have been
at the mercy of browser heuristics for how long it decides to stream
before the first paint.
Chromium now has [an API explicitly for this use
case](https://developer.mozilla.org/en-US/docs/Web/API/View_Transition_API/Using#stabilizing_page_state_to_make_cross-document_transitions_consistent)
that lets us model the semantics that we want. This is always important
but especially so with MPA View Transitions.
After this a simple document looks like this:
```html
<!DOCTYPE html>
<html>
<head>
<link rel="expect" href="#«R»" blocking="render"/>
</head>
<body>
<p>hello world</p>
<script src="bootstrap.js" id="«R»" async=""></script>
...
</body>
</html>
```
The `rel="expect"` tag indicates that we want to wait to paint until we
have streamed far enough to be able to paint the id `"«R»"` which
indicates the shell.
Ideally this `id` would be assigned to the root most HTML element in the
body. However, this is tricky in our implementation because there can be
multiple and we can render them out of order.
So instead, we assign the id to the first bootstrap script if there is
one since these are always added to the end of the shell. If there isn't
a bootstrap script then we emit an empty `<template
id="«R»"></template>` instead as a marker.
Since we currently put as much as possible in the shell if it's loaded
by the time we render, this can have some negative effects for very
large documents. We should instead apply the heuristic where very large
Suspense boundaries get outlined outside the shell even if they're
immediately available. This means that even prerenders can end up with
script tags.
We only emit the `rel="expect"` if you're rendering a whole document.
I.e. if you rendered either a `<html>` or `<head>` tag. If you're
rendering a partial document, then we don't really know where the
streaming parts are anyway and can't provide such guarantees. This does
apply whether you're streaming or not because we still want to block
rendering until the end, but in practice any serialized state that needs
hydrate should still be embedded after the completion id.
Stacked on #32851 and #32900.
This implements the equivalent Configs for ActivityInstance as we have
for SuspenseInstance. These can be implemented as comments but they
don't have to be and can be implemented differently in the renderer.
This seems like a lot duplication but it's actually ends mostly just
calling the same methods underneath and the wrappers compiles out.
This doesn't leave the Activity dehydrated yet. It just hydrates into it
immediately.
Found this bug while working on Activity. There's a weird edge case when
a dehydrated Suspense boundary is a direct child of another Suspense
boundary which is hydrated but then it resuspends without forcing the
inner one to hydrate/delete.
It used to just leave that in place because hiding/unhiding didn't deal
with dehydrated fragments.
Not sure this is really worth fixing.
This lets us write them early in the render phase.
This should be safe because even if we write them deeply, then they
still can't be wrapped by a element because then they'd no longer be in
the document scope anymore. They end up flat in the body and so when we
search the content we'll discover them.
Uses `&` for Activity as opposed to `$` for Suspense. This will be used
to delimitate which nodes we can skip hydrating.
This isn't used on the client yet. It's just a noop on the client
because it's just an unknown comment. This just adds the SSR parts.
Even if the `enableSuspenseyImages` flag is off.
Started View Transitions already wait for Suspensey Fonts and this is
another Suspensey feature that is even more important for View
Transitions - even though we eventually want it all the time. So this
uses `<ViewTransition>` as an early opt-in for that tree into Suspensey
Images, which we can ship in a minor.
If you're doing an update inside a ViewTransition then we're eligible to
start a ViewTransition in any Transition that might suspend. Even if
that doesn't end up animating after all, we still consider it Suspensey.
We could try to suspend inside the startViewTransition but that's not
how it would work with `enableSuspenseyImages` on and we can't do that
for startGestureTransition.
Even so we still need some opt-in to trigger the Suspense fallback even
before we know whether we'll animate or not. So the simple solution is
just that `<ViewTransition>` opts in the whole subtree into Suspensey
Images in general.
In this PR I disable `enableSuspenseyImages` in experimental so that we
can instead test the path that only enables it inside `<ViewTransition>`
tree since that's the path that would next graduate to a minor.
Behind the `enableSrcObject` flag. This is revisiting a variant of what
was discussed in #11163.
Instead of supporting the [`srcObject`
property](https://developer.mozilla.org/en-US/docs/Web/API/HTMLMediaElement/srcObject)
as a separate name, this adds an overload of `src` to allow objects to
be passed. The DOM needs to add separate properties for the object forms
since you read back but it doesn't make sense for React's write-only API
to do that. Similar to how we'll like add an overload for
`popoverTarget` instead of calling it `popoverTargetElement` and how
`style` accepts an object and it's not `styleObject={{...}}`.
There are a number of reason to revisit this.
- It's just way more convenient to have this built-in and it makes
conceptual sense. We typically support declarative APIs and polyfill
them when necessary.
- RSC supports Blobs and by having it built-in you don't need a Client
Component wrapper to render it where as doing it with effects would
require more complex wrappers. By picking Blobs over base64,
client-navigations can use the more optimized binary encoding in the RSC
protocol.
- The timing aspect of coordinating it with Suspensey images and image
decoding is a bit tricky to get right because if you set it in an effect
it's too late because you've already rendered it.
- SSR gets complicated when done in user space because you have to
handle both branches. Likely with `useSyncExternalStore`.
- By having it built-in we could optimize the payloads shared between
RSC payloads embedded in the HTML and data URLs.
This does not support objects for `<source src>` nor `<img srcset>`.
Those don't really have equivalents in the DOM neither. They're mainly
for picking an option when you don't know programmatically. However, for
this use case you're really better off picking a variant before
generating the blobs.
We may support Response objects in the future too as per
https://github.com/whatwg/fetch/issues/49
Safari has a bug where if you put a block element inside an inline
element and the inline element has a `view-transition-name` assigned it
finds it as duplicate names.
https://bugs.webkit.org/show_bug.cgi?id=290923
This adds a warning if we detect this scenario in dev mode.
For the case where it renders into a single block, we can model this by
making the parent either `block` or `inline-block` automatically to fix
the issue. So we do that to automatically cover simple cases like
`<a><div>...</div></a>`. This unfortunately causes layout/styling thrash
so we might want to delete it once the bug has been fixed in enough
Safari versions.
We've known we've wanted this for many years and most of the
implementation was already done for Suspensey CSS. This waits to commit
until images have decoded by default or up to 500ms timeout (same as
suspensey fonts).
It only applies to Transitions, Retries (Suspense), Gesture Transitions
(flag) and Idle (doesn't exist). Sync updates just commit immediately.
`<img loading="lazy" src="..." />` opts out since you explicitly want it
to load lazily in that case.
`<img onLoad={...} src="..." />` also opts out since that implies you're
ok with managing your own reveal.
In the future, we may add an opt in e.g. `<img blocking="render"
src="..." />` that opts into longer timeouts and re-suspends even sync
updates. Perhaps also triggering error boundaries on errors.
The rollout for this would have to go in a major and we may have to
relax the default timeout to not delay too much by default. However, we
can also make this part of `enableViewTransition` so that if you opt-in
by using View Transitions then those animations will suspend on images.
That we could ship in a minor.
This can happen for example if you have duplicate names in the "old"
state. This errors the transition before the updateCallback is invoked
so we haven't yet applied mutations etc.
This runs through those phases after the error to get us back to a
consistent state.
The problem with setting both `children` or `dangerouslySetInnerHTML`
and also using a ref on a DOM node to either manually append children or
using it as a Container for `createRoot` or `createPortal` is that it's
ambiguous which children should win. Ideally you use one of the four
options to control children. Meaning that ideally you always use a leaf
container for refs like this.
Unfortunately it's very common to use a React owned thing with children
as a Container of a Portal. For example `document.body` can have both
regular React children and be used as a Portal container. This isn't
really fully supported and has some undefined behavior like relative
order isn't guaranteed but still very common.
It is extra bad if the children are a `string`/`number` or if
`dangerouslySetInnerHTML` is set. Because then when ever that reactively
updates it'll clear out any manually added DOM nodes. When this happens
isn't guaranteed. It's always happening as far as the reactivity is
concerned. See https://github.com/facebook/react/issues/31600
Therefore, we should warn for this specific pattern. This still allows
non-text children as a compromise even though that behavior is also
somewhat undefined.
Stacked on #32788.
Normally we track `addTransitionType` globally because of the async gap
that can happen in Actions where we lack AsyncContext to associate it
with a particular Transition. This unfortunately also means it's
possible to call outside of `startTransition` which is something we want
to warn for.
We need to be able to distinguish whether `addTransitionType` is for a
regular Transition or a Gesture Transition though.
Since `startGestureTransition` is only synchronous we can track it
within that execution scope and move it to a separate set. Since we know
for sure which call owns it we can properly associate it with that
specific provider's `ScheduledGesture`.
This does not yet handle calling `addTransitionType` inside the render
phase of a gesture. That would currently still be associated with the
next Transition instead.
When different animations in a View Transition have different durations,
we shouldn't stretch them out to run the full range of swipe. Because
then they wouldn't line up the same way as when played using plain time.
This adjusts the range start/end to be what it would've been when played
by time. Except since we are playing animations in reverse, the
animation-delay is actually applied from the range end and then the
duration from there to get closer to the start.
Reverse the range if the original animation was reversed.
Interestingly, the range it takes can be adjusted by what is in the
viewport since if a long duration animation is excluded then everything
else adjusts too.
I left some todos too. We really should also handle if the original
animation has multiple iterations. Currently we only play those once.
Stacked on #32785.
This is now replaced by `startGestureTransition` added in #32785.
I also renamed the flag from `enableSwipeTransition` to
`enableGestureTransition` to correspond to the new name.
Starting a View Transition is an async sequence. Since React can get a
sync update in the middle of sequence we sometimes interrupt that
sequence.
Currently, we don't actually cancel the View Transition so it can just
run as a partial. This ensures that we fully skip it when that happens,
as well as warn.
However, it's very easy to trigger this with just a setState in
useLayoutEffect right now. Therefore if we're inside the preparing
sequence of a startViewTransition, this delays work that would've
normally flushed in a microtask. ~Maybe we want to do the same for
Default work already scheduled through a scheduler Task.~ Edit: This was
already done.
`flushSync` currently will still lead to an interrupted View Transition
(with a warning). There's a tradeoff here whether we want to try our
best to preserve the guarantees of `flushSync` or favor the animation.
It's already possible to suspend at the root with `flushSync` which
means it's not always 100% guaranteed to commit anyway. We could treat
it as suspended. But let's see how much this is a problem in practice.
This implements `getRootNode(options)` on fragment instances as the
equivalent of calling `getRootNode` on the fragment's parent host node.
The parent host instance will also be used to proxy dispatchEvent in an
upcoming PR.
This works around this Safari bug.
https://bugs.webkit.org/show_bug.cgi?id=290146
This unfortunate because it may cause additional layouts if there's more
updates to the tree coming by manual mutation before it gets painted
naturally. However, we might end up wanting to read layout early anyway.
This affects the fixture because we clone the `<link>` from the `<head>`
which is itself another bug. However, it should be possible to have
`<link>` tags inserted into the new tree so this is still relevant.
Adds `getClientRects()` to fragment instances with a fixture test case.
`Element.getClientRect` returns a collection of `DOMRect`s (see example
of multiline span returning two `DOMRect` boxes).
`fragmentInstance.getClientRects` here flattens those collections into
an array of rects.
`focus()` was added in https://github.com/facebook/react/pull/32465.
Here we add `focusLast()` and `blur()`. I also extended `focus` to take
options.
`focus` will focus the first focusable element. `focusLast` will focus
the last focusable element. We could consider a `focusFirst` naming or
even the `focusWithin` used by test selector APIs as well.
`blur` will only have an effect if the current `document.activeElement`
is one of the fragment children.
This does the same thing for `measureUpdateViewTransition` that we did
for `measureNestedViewTransitions` in
https://github.com/facebook/react/pull/32612/commits/e3cbaffef05c7b476c07f7495e06788a9503e636.
If a boundary hasn't mutated and didn't change in size, we mark it for
cancellation. Otherwise we add names to it. The different from the
CommitViewTransition path is that the "old" names are added to the
clones so this is the first time the "new" names.
Now we also cancel any boundaries that were unchanged. So now the root
no longer animates. We still have to clone them. There are other
optimizations that can avoid cloning but once we've done all the layouts
we can still cancel the running animation and let them just be the
regular content if they didn't change. Just like the regular
fire-and-forget path.
This also fixes the measurement so that we measure clones by adjusting
their position back into the viewport.
This actually surfaces a bug in Safari that was already in #32612. It
turns out that the old names aren't picked up for some reason and so in
Safari they looked more like a cross-fade than what #32612 was supposed
to fix. However, now that bug is even more apparent because they
actually just disappear in Safari. I'm not sure what that bug is but
it's unrelated to this PR so will fix that separately.
This implements `observeUsing(observer)` and `unobserverUsing(observer)`
on fragment instances. IntersectionObservers and ResizeObservers can be
passed to observe each host child of the fragment. This is the
equivalent to calling `observer.observe(child)` or
`observer.unobserve(child)` for each child target.
Just like the addEventListener, the observer is held on the fragment
instance and applied to any newly mounted child. So you can do things
like wrap a paginated list in a fragment and have each child
automatically observed as they commit in.
Unlike, the event listeners though, we don't `unobserve` when a child is
removed. If a removed child is currently intersecting, the observer
callback will be called when it is removed with an empty rect. This lets
you track all the currently intersecting elements by setting state from
the observer callback and either adding or removing them from your list
depending on the intersecting state. If you want to track the removal of
items offscreen, you'd have to maintain that state separately and append
intersecting data to it in the observer callback. This is what the
fixture example does.
There could be more convenient ways of managing the state of multiple
child intersections, but basic examples are able to be modeled with the
simple implementation. Let's see how the usage goes as we integrate this
with more advanced loggers and other features.
For now you can only attach one observer to an instance. This could
change based on usage but the fragments are composable and could be
stacked as one way to apply multiple observers to the same elements.
In practice, one pattern we expect to enable is more composable logging
such as
```javascript
function Feed({ items }) {
return (
<ImpressionLogger>
{items.map((item) => (
<FeedItem />
))}
</ImpressionLogger>
);
}
```
where `ImpressionLogger` would set up the IntersectionObserver using a
fragment ref with the required business logic and various components
could layer it wherever the logging is needed. Currently most callsites
use a hook form, which can require wiring up refs through the tree and
merging refs for multiple loggers.
This is a nit but a Config should not have to know anything about the
internals of Fibers. Ideally it shouldn't even access them but we have
some cases where we need pointers back in like for this fragment.
The way we've typically abstracted this is using the
`ReactFiberTreeReflection` helper that's in the `react-reconciler`. Such
as in the event system.
https://github.com/facebook/react/blob/f3c956006a90dc68210bd3e19497d10fb9b028d3/packages/react-dom-bindings/src/events/ReactDOMEventListener.js#L22-L26
We sometimes cheat but we really should clean this up such that a
`Fiber` is actually an opaque type to the Configs and it can never dot
into it without using a helper.
So this just moves `traverseFragmentInstanceChildren` to
ReactFiberTreeReflection so that the ConfigDOM doesn't ever dot into its
fields itself. It just passes the Fiber through back into the
react-reconciler. I had to add a wrapper to read the `.child` to avoid
that being assumed too. I also noticed that FragmentInstanceType is not
actually passed through so that argument is unnecessary.
Follow up to #32540.
We do allow gestures to be cancelled early (we call skipTransition) if
the gesture stops before it has even started.
This happens in the fixture when we auto-scroll.
*This API is experimental and subject to change or removal.*
This PR is an alternative to
https://github.com/facebook/react/pull/32421 based on feedback:
https://github.com/facebook/react/pull/32421#pullrequestreview-2625382015
. The difference here is that we traverse from the Fragment's fiber at
operation time instead of keeping a set of children on the
`FragmentInstance`. We still need to handle newly added or removed child
nodes to apply event listeners and observers, so we treat those updates
as effects.
**Fragment Refs**
This PR extends React's Fragment component to accept a `ref` prop. The
Fragment's ref will attach to a custom host instance, which will provide
an Element-like API for working with the Fragment's host parent and host
children.
Here I've implemented `addEventListener`, `removeEventListener`, and
`focus` to get started but we'll be iterating on this by adding
additional APIs in future PRs. This sets up the mechanism to attach refs
and perform operations on children. The FragmentInstance is implemented
in `react-dom` here but is planned for Fabric as well.
The API works by targeting the first level of host children and proxying
Element-like APIs to allow developers to manage groups of elements or
elements that cannot be easily accessed such as from a third-party
library or deep in a tree of Functional Component wrappers.
```javascript
import {Fragment, useRef} from 'react';
const fragmentRef = useRef(null);
<Fragment ref={fragmentRef}>
<div id="A" />
<Wrapper>
<div id="B">
<div id="C" />
</div>
</Wrapper>
<div id="D" />
</Fragment>
```
In this case, calling `fragmentRef.current.addEventListener()` would
apply an event listener to `A`, `B`, and `D`. `C` is skipped because it
is nested under the first level of Host Component. If another Host
Component was appended as a sibling to `A`, `B`, or `D`, the event
listener would be applied to that element as well and any other APIs
would also affect the newly added child.
This is an implementation of the basic feature as a starting point for
feedback and further iteration.
This fixes a critical issue with moveBefore. I was told that the
disconnected -> connected case was going to be relaxed and not be an
error but apparently that is not the case.
This means that we can't use this for initial insertions. Only moves.
Unfortunately React's internals doesn't distinguish these cases. This
adds a hack that checks each nodes but this is pretty bad for
performance. We should only call this in one or the other case.
Given that we still need feature detection. Both of which means that
these calls are no longer inlined and this extra code. I wonder if it's
even worth it given that you can't even rely on it working anyway since
not all browsers have it. Kind of don't want to ship this until all
browsers have it.
Even then we'd ideally refactor React to use separate code paths for
initial insertion vs moves. Which leads to some unfortunate code
duplication.
Otherwise these can survive into the next View Transition and cause
havoc to that transition.
This was appearing as a flash in Safari in the fixture when going from
A->B. This triggers a View Transition and at the same time the scroll
position updates in an effect. That fires a scroll event which starts a
gesture. This shouldn't really happen and the SwipeRecognizer should
ideally ignore those but it's good to surface edge cases. That gesture
is blocked on the View Transition finishing and then immediately after
it starts a gesture View Transition. That gesture then picked up the
former Animation from the previous transition which caused issues. This
PR fixes that flash.
Setting the animation's currentTime causes a quirk where the transition
can end up off by a bit and the end state can be slightly off the end
time.
However, I realized that we don't have to because if we just set the
direction in the `animate()` call directly the Safari bug goes away.
This is really the essence mechanism of the `useSwipeTransition`
feature.
We don't want to immediately switch to the destination state when
starting a gesture. The effects remain mounted on the current state. We
want the current state to be "live". This is important to for example
allow a video to keeping playing while starting a swipe (think
TikTok/Reels) and not stop until you've committed the action. The only
thing that can be live is the "new" state. Therefore we treat the
destination as the "old" state and perform a reverse animation from
there.
Ideally we could apply the old state to the DOM tree, take a snapshot
and then revert it back in the mutation of `startViewTransition`.
Unfortunately, the way `startViewTransition` was designed it always
paints one frame of the "old" state which would lead this to cause a
flicker.
To work around this, we need to create a clone of any View Transition
boundary that might be mutated and then render that offscreen. That way
we can render the "current" state on screen and the "destination" state
offscreen for the screenshots. Being mutated can be either due to React
doing a DOM mutation or if a child boundary resizes that causes the
parent to relayout. We don't have to do this for insertions or deletions
since they only appear on one side.
The worst case scenario is that we have to clone the whole root. That's
what this first PR implements. We clone the container and if it's not
absolutely positioned, we position it on top of the current one. If the
container is `document` or `<html>` we instead clone the `<body>` tag
since it's the only one we can insert a duplicate of. If the container
is deep in the tree we clone just that even though technically we should
probably clone the whole document in that case. We just keep the impact
smaller. Ideally though we'd never hit this case. In fact, if we clone
the document we issue a warning (always for now) since you probably
should optimize this. In the future I intend to add optimizations when
affected View Transition boundaries are absolutely positioned since they
cannot possibly relayout the parent. This would be the ideal way to use
this feature most efficiently but it still works without it.
Since we render the "old" state outside the viewport, we need to then
adjust the animation to put it back into the viewport. This is the
trickiest part to get right while still preserving any customization of
the View Transitions done using CSS. This current approach reapplies all
the animations with adjusted keyframes.
In the case of an "exit" the pseudo-element itself is positioned outside
the viewport but since we can't programmatically update the style of the
pseudo-element itself we instead adjust all the keyframes to put it back
into the viewport. If there is no animation on the group we add one.
In the case of an "update" the pseudo-element is positioned on the new
state which is already inside the viewport. However, the auto-generated
animation of the group has a starting keyframe that starts outside the
viewport. In this case we need to adjust that keyframe.
In the future I might explore a technique that inserts stylesheets
instead of mutating the animations. It might be simpler. But whatever
hacks work to maximize the compatibility is best.
Sebastian Markbåge
Jack Pope
Keith Cirkel