This disables symbol renaming in production builds. The original
variable and function names are preserved. All other forms of
compression applied by Closure (dead code elimination, inlining, etc)
are unchanged — the final program is identical to what we were producing
before, just in a more readable form.
The motivation is to make it easier to debug React issues that only
occur in production — the same reason we decided to start shipping
sourcemaps in #28827 and #28827.
However, because most apps run their own minification step on their npm
dependencies, it's not necessary for us to minify the symbols before
publishing — it'll be handled the app, if desired.
This is the same strategy Meta has used to ship React for years. The
React build itself has unminified symbols, but they get minified as part
of Meta's regular build pipeline.
Even if an app does not minify their npm dependencies, gzip covers most
of the cost of symbol renaming anyway.
This saves us from having to ship sourcemaps, which means even apps that
don't have sourcemaps configured will be able to debug the React build
as easily as they would any other npm dependency.
Follow up to #28783 and #28786.
Since we've changed the implementations of these we can rename them to
something a bit more descriptive while we're at it, since anyone
depending on them will need to upgrade their code anyway.
"react" with no condition:
`__CLIENT_INTERNALS_DO_NOT_USE_OR_WARN_USERS_THEY_CANNOT_UPGRADE`
"react" with "react-server" condition:
`__SERVER_INTERNALS_DO_NOT_USE_OR_WARN_USERS_THEY_CANNOT_UPGRADE`
"react-dom":
`__DOM_INTERNALS_DO_NOT_USE_OR_WARN_USERS_THEY_CANNOT_UPGRADE`
The old version of prettier we were using didn't support the Flow syntax
to access properties in a type using `SomeType['prop']`. This updates
`prettier` and `rollup-plugin-prettier` to the latest versions.
I added the prettier config `arrowParens: "avoid"` to reduce the diff
size as the default has changed in Prettier 2.0. The largest amount of
changes comes from function expressions now having a space. This doesn't
have an option to preserve the old behavior, so we have to update this.
Hermes parser is the preferred parser for Flow code going forward. We
need to upgrade to this parser to support new Flow syntax like function
`this` context type annotations or `ObjectType['prop']` syntax.
Unfortunately, there's quite a few upgrades here to make it work somehow
(dependencies between the changes)
- ~Upgrade `eslint` to `8.*`~ reverted this as the React eslint plugin
tests depend on the older version and there's a [yarn
bug](https://github.com/yarnpkg/yarn/issues/6285) that prevents
`devDependencies` and `peerDependencies` to different versions.
- Remove `eslint-config-fbjs` preset dependency and inline the rules,
imho this makes it a lot clearer what the rules are.
- Remove the turned off `jsx-a11y/*` rules and it's dependency instead
of inlining those from the `fbjs` config.
- Update parser and dependency from `babel-eslint` to `hermes-eslint`.
- `ft-flow/no-unused-expressions` rule replaces `no-unused-expressions`
which now allows standalone type asserts, e.g. `(foo: number);`
- Bunch of globals added to the eslint config
- Disabled `no-redeclare`, seems like the eslint upgrade started making
this more precise and warn against re-defined globals like
`__EXPERIMENTAL__` (in rollup scripts) or `fetch` (when importing fetch
from node-fetch).
- Minor lint fixes like duplicate keys in objects.
* Facebook -> Meta in copyright
rg --files | xargs sed -i 's#Copyright (c) Facebook, Inc. and its affiliates.#Copyright (c) Meta Platforms, Inc. and affiliates.#g'
* Manual tweaks
* Yield to main thread if continuation is returned
Instead of using an imperative method `requestYield` to ask Scheduler to
yield to the main thread, we can assume that any time a Scheduler task
returns a continuation callback, it's because it wants to yield to the
main thread. We can assume the task already checked some condition that
caused it to return a continuation, so we don't need to do any
additional checks — we can immediately yield and schedule a new task
for the continuation.
The replaces the `requestYield` API that I added in ca990e9.
* Move unwind after error into main work loop
I need to be able to yield to the main thread in between when an error
is thrown and when the stack is unwound. (This is the motivation behind
the refactor, but it isn't implemented in this commit.) Currently the
unwind is inlined directly into `handleError`.
Instead, I've moved the unwind logic into the main work loop. At the
very beginning of the function, we check to see if the work-in-progress
is in a "suspended" state — that is, whether it needs to be unwound. If
it is, we will enter the unwind phase instead of the begin phase.
We only need to perform this check when we first enter the work loop:
at the beginning of a Scheduler chunk, or after something throws. We
don't need to perform it after every unit of work.
* Yield to main thread whenever a fiber suspends
When a fiber suspends, we should yield to the main thread in case the
data is already cached, to unblock a potential ping event.
By itself, this commit isn't useful because we don't do anything special
in the case where to do receive an immediate ping event. I've split this
out only to demonstrate that it doesn't break any existing behavior.
See the next commit for full context and motivation.
* Resume immediately pinged fiber without unwinding
If a fiber suspends, and is pinged immediately in a microtask (or a
regular task that fires before React resumes rendering), try rendering
the same fiber again without unwinding the stack. This can be super
helpful when working with promises and async-await, because even if the
outermost promise hasn't been cached before, the underlying data may
have been preloaded. In many cases, we can continue rendering
immediately without having to show a fallback.
This optimization should work during any concurrent (time-sliced)
render. It doesn't work during discrete updates because those are
semantically required to finish synchronously — those get the current
behavior.
We need a way to yield control of the main thread and schedule a
continuation in a separate macrotask. (This is related to some Suspense
optimizations we have planned.)
Our solution needs account for how Scheduler is implemented. Scheduler
tasks are not 1:1 with real browser macrotasks — many Scheduler "tasks"
can be executed within a single browser task. If a Scheduler task yields
control and posts a continuation, but there's still time left in the
frame, Scheduler will execute the continuation immediately
(synchronously) without yielding control back to the main thread. That's
not what we want — we want to schedule a new macrotask regardless of
where we are in the browser's render cycle.
There are several ways we could approach this. What I ended up doing was
adding a new Scheduler method `unstable_requestYield`. (It's similar to
the existing `unstable_requestPaint` that we use to yield at the end of
the frame.)
It works by setting the internal start time of the current work loop to
a large negative number, so that when the `shouldYield` call computes
how much time has elapsed, it's guaranteed to exceed the deadline. The
advantage of doing it this way is that there are no additional checks in
the normal hot path of the work loop.
The existing layering between Scheduler and React DOM is not ideal. None
of the APIs are public, so despite the fact that Scheduler is a separate
package, I consider that a private implementation detail, and think of
them as part of the same unit.
So for now, though, I think it makes sense to implement this macrotask
logic directly inside of Scheduler instead of layering it on top.
The rough eventual plan for Scheduler is turn it into a `postTask`
prollyfill. Because `postTask` does not yet have an equivalent for
`shouldYield`, we would split that out into its own layer, perhaps
directly inside the reconciler. In that world, the macrotask logic I've
added in this commit would likely live in that same layer. When the
native `postTask` is available, we may not even need any additional
logic because it uses actual browser tasks.
* Clean up Scheduler forks
* Un-shadow variables
* Use timer globals directly, add a test for overrides
* Remove more window references
* Don't crash for undefined globals + tests
* Update lint config globals
* Fix test by using async act
* Add test fixture
* Delete test fixture
* Reduce code to necessities
* Switch to postTask API
* Add SchedulerPostTask tests
* Updates from review
* Fix typo from review
* Generate build of unstable_post_task
* Revert "Revert "[Scheduler] Profiling features (#16145)" (#16392)"
This reverts commit 4ba1412305.
* Fix copy paste mistake
* Remove init path dependency on ArrayBuffer
* Add a regression test for cancelling multiple tasks
* Prevent deopt from adding isQueued later
* Remove pop() calls that were added for profiling
* Verify that Suspend/Unsuspend events match up in tests
This currently breaks tests.
* Treat Suspend and Resume as exiting and entering work loop
Their definitions used to be more fuzzy. For example, Suspend didn't always fire on exit, and sometimes fired when we did _not_ exit (such as at task enqueue).
I chatted to Boone, and he's saying treating Suspend and Resume as strictly exiting and entering the loop is fine for their use case.
* Revert "Prevent deopt from adding isQueued later"
This reverts commit 9c30b0b695d81e9c43b296ab93d895e4416ef713.
Unnecessary because GCC
* Start counter with 1
* Group exports into unstable_Profiling namespace
* No catch in PROD codepath
* No label TODO
* No null checks
* [Scheduler] Mark user-timing events
Marks when Scheduler starts and stops running a task. Also marks when
a task is initially scheduled, and when Scheduler is waiting for a
callback, which can't be inferred from a sample-based JavaScript CPU
profile alone.
The plan is to use the user-timing events to build a Scheduler profiler
that shows how the lifetime of tasks interact with each other and
with unscheduled main thread work.
The test suite works by printing an text representation of a
Scheduler flamegraph.
* Expose shared array buffer with profiling info
Array contains
- the priority Scheduler is currently running
- the size of the queue
- the id of the currently running task
* Replace user-timing calls with event log
Events are written to an array buffer using a custom instruction format.
For now, this is only meant to be used during page start up, before the
profiler worker has a chance to start up. Once the worker is ready, call
`stopLoggingProfilerEvents` to return the log up to that point, then
send the array buffer to the worker.
Then switch to the sampling based approach.
* Record the current run ID
Each synchronous block of Scheduler work is given a unique run ID. This
is different than a task ID because a single task will have more than
one run if it yields with a continuation.
* [Scheduler] requestPaint
Signals to Scheduler that the browser needs to paint the screen. React
will call it in the commit phase. Scheduler will yield at the end of
the current frame, even if there is no pending input.
When `isInputPending` is not available, this has no effect, because we
yield at the end of every frame regardless.
React will call `requestPaint` in the commit phase as long as there's at
least one effect. We could choose not to call it if none of the effects
are DOM mutations, but this is so rare that it doesn't seem worthwhile
to bother checking.
* Fall back gracefully if requestPaint is missing
* Add new mock build of Scheduler with flush, yield API
Test environments need a way to take control of the Scheduler queue and
incrementally flush work. Our current tests accomplish this either using
dynamic injection, or by using Jest's fake timers feature. Both of these
options are fragile and rely too much on implementation details.
In this new approach, we have a separate build of Scheduler that is
specifically designed for test environments. We mock the default
implementation like we would any other module; in our case, via Jest.
This special build has methods like `flushAll` and `yieldValue` that
control when work is flushed. These methods are based on equivalent
methods we've been using to write incremental React tests. Eventually
we may want to migrate the React tests to interact with the mock
Scheduler directly, instead of going through the host config like we
currently do.
For now, I'm using our custom static injection infrastructure to create
the two builds of Scheduler — a default build for DOM (which falls back
to a naive timer based implementation), and the new mock build. I did it
this way because it allows me to share most of the implementation, which
isn't specific to a host environment — e.g. everything related to the
priority queue. It may be better to duplicate the shared code instead,
especially considering that future environments (like React Native) may
have entirely forked implementations. I'd prefer to wait until the
implementation stabilizes before worrying about that, but I'm open to
changing this now if we decide it's important enough.
* Mock Scheduler in bundle tests, too
* Remove special case by making regex more restrictive
* Add Scheduler.unstable_next
* Use Scheduler to prioritize updates
Changes the implementation of syncUpdates, deferredUpdates, and
interactiveUpdates to use runWithPriority, so
This is the minimum integration between Scheduler and React needed to
unblock use of the Scheduler.next API.
* Add Scheduler.unstable_next
* Use Scheduler to prioritize updates
Changes the implementation of syncUpdates, deferredUpdates, and
interactiveUpdates to use runWithPriority, so
This is the minimum integration between Scheduler and React needed to
unblock use of the Scheduler.next API.
* [scheduler] Deadline object -> shouldYield
Instead of using a requestIdleCallback-style deadline object, expose a
method Scheduler.shouldYield that returns true if there's a higher
priority event in the queue.
* Nits
All of these features are based on features of React's internal
scheduler. The eventual goal is to lift as much as possible out of the
React internals into the Scheduler package.
Includes some renaming of existing methods.
- `scheduleWork` is now `scheduleCallback`
- `cancelScheduledWork` is now `cancelCallback`
Priority levels
---------------
Adds the ability to schedule callbacks at different priority levels.
The current levels are (final names TBD):
- Immediate priority. Fires at the end of the outermost currently
executing (similar to a microtask).
- Interactive priority. Fires within a few hundred milliseconds. This
should only be used to provide quick feedback to the user as a result
of an interaction.
- Normal priority. This is the default. Fires within several seconds.
- "Maybe" priority. Only fires if there's nothing else to do. Used for
prerendering or warming a cache.
The priority is changed using `runWithPriority`:
```js
runWithPriority(InteractivePriority, () => {
scheduleCallback(callback);
});
```
Continuations
-------------
Adds the ability for a callback to yield without losing its place
in the queue, by returning a continuation. The continuation will have
the same expiration as the callback that yielded.
Wrapped callbacks
-----------------
Adds the ability to wrap a callback so that, when it is called, it
receives the priority of the current execution context.
