Rename `wait` to `await` to be consistent with Future API. The
convention here is that this set of functionality goes together:
* async/concurrent
* await/cancel
Also rename Select `wait` to `await` for the same reason.
`Group.await` now can return `error.Canceled`. Furthermore,
`Group.await` does not auto-propagate cancelation. Instead, users should
follow the pattern of `defer group.cancel(io);` after initialization,
and doing `try group.await(io);` at the end of the success path.
Advanced logic can choose to do something other than this pattern in the
event of cancelation.
Additionally, fixes a bug in `std.Io.Threaded` future await, in which it
swallowed an `error.Canceled`. Now if a task is canceled while awaiting
a future, after propagating the cancel request, it also recancels,
meaning that the awaiting task will properly detect its own cancelation
at the next cancelation point.
Furthermore, fixes a bug in the compiler where `error.Canceled` was
being swallowed in `dispatchPrelinkWork`.
Finally, fixes std.crypto code that inappropriately used
`catch unreachable` in response to cancelation without even so much as a
comment explaining why it was believed to be unreachable. Now, those
functions have `error.Canceled` in the error set and propagate
cancelation properly.
With this way of doing things, `Group.await` has a nice property: even if
all tasks in the group are CPU bound and without cancelation points, the
`Group.await` can still be canceled. In such case, the task that was
waiting for `await` wakes up with a chance to do some more resource
cleanup tasks, such as canceling more things, before entering the
deferred `Group.cancel` call at which point it has to suspend until the
canceled but uninterruptible CPU bound tasks complete.
closes#30601
`std.Io.tty.Config.detect` may be an expensive check (e.g. involving
syscalls), and doing it every time we need to print isn't really
necessary; under normal usage, we can compute the value once and cache
it for the whole program's execution. Since anyone outputting to stderr
may reasonably want this information (in fact they are very likely to),
it makes sense to cache it and return it from `lockStderrWriter`. Call
sites who do not need it will experience no significant overhead, and
can just ignore the TTY config with a `const w, _` destructure.
As with Solaris (dba1bf9353), we have no way to
actually audit contributions for these OSs. IBM also makes it even harder than
Oracle to actually obtain these OSs.
closes#23695closes#23694closes#3655closes#23693
* Remove the generic model; we already have generic_la32 and generic_la64 and
pick appropriately based on bitness.
* Remove the loongarch64 model. We used this as our baseline for 64-bit, but it's
actually pretty misleading and useless; it doesn't represent any real CPU and
has less features than generic_la64.
* Add la64v1_0 and la64v1_1 models.
* Change our baseline CPU model for 64-bit to be la64v1_0, thus adding LSX to
the baseline feature set.
This will mainly be used when targeting our wasm2c implementation which has no
problem with zero-length bulk memory operations, as a non-standard extension.
See: https://github.com/WebAssembly/tool-conventions/pull/235
This is not *quite* using the same features as the spec'd lime1 model because
LLVM 19 doesn't have the level of feature granularity that we need for that.
This will be fixed once we upgrade to LLVM 20.
Part of #21818.
To my knowledge there isn't an implementation of `sse4.2` that doesn't have `crc32`.
The Clang driver also sets `crc32` to be implicitly enabled when an explicit `-crc32`
wasn't provided. This matches that behaviour.
We need this behaviour to compile libraries like `rocksdb` which currently guard against
`crc32` intrinsics by checking for `sse4.2`.
* Cleanup the argument handling logic to allow for optional arguments.
* Add a filter for which `llvm_target` to process.
* Switch to using a threadpool, needed for skipping llvm targets cleanly
and better distributes the work.
* Remove a seemingly useless piece of logic. I re-ran the script and it gave identical outputs.
Like d1d95294fd, this is more Apple nonsense where
they abused the arch component of the triple to encode what's really an ABI.
Handling this correctly in Zig's target triple model would take quite a bit of
work. Fortunately, the last Armv7-based Apple Watch was released in 2017 and
these targets are now considered legacy. By the time Zig hits 1.0, they will be
a distant memory. So just remove them.
At bare minimum, the compiler expects std.Target.<arch>.cpu.generic to work for
any given architecture when generating the builtin module. So rather than try to
hack that into working when the affected modules are omitted, just actually keep
them.
This affected lanai and xcore.
cortex-m85 already has 8msecext, which is not the same as trustzone. The former
is for the M profile, while the latter is for the A profile.
Revert of a small part of #18498.
* Add `ProcessorAlias` support.
* Bump output buffer size.
* Include `i` extension in RISC-V baselines.
* Update evaluation branch quota for RISC-V.
* Retain some CPU features that LLVM removed.
* Flatten more 'meta-features' used for CPU models.
* Remove some superfluous dependencies.
The compiler actually doesn't need any functional changes for this: Sema
does reification based on the tag indices of `std.builtin.Type` already!
So, no zig1.wasm update is necessary.
This change is necessary to disallow name clashes between fields and
decls on a type, which is a prerequisite of #9938.
Before this commit, the name `v9.5a` was being used for two different features, and one was overwriting the other in the `all_features` array.
`arrowlake_s` is an alias for `arrowlake-s`
