These are handled by Io.Dir now. This is part of an effort to eliminate
error.OperationCanceled from the std lib. Also an effort to delete
all std.posix functions.
this gets the build runner compiling again on linux
this work is incomplete; it only moves code around so that environment
variables can be wrangled properly. a future commit will need to audit
the cancelation and error handling of this moved logic.
The most interesting thing here is the replacement of the pthread futex
implementation with an implementation based on thread park/unpark APIs.
Thread parking tends to be the primitive provided by systems which do
not have a futex primitive, such as NetBSD, so this implementation is
far more efficient than the pthread one. It is also useful on Windows,
where `RtlWaitOnAddress` is itself a userland implementation based on
thread park/unpark; we can implement it ourselves including support for
features which Windows' implementation lacks, such as cancelation and
waking a number of waiters with 1<n<infinity.
Compared to the pthread implementation, this thread-parking-based one
also supports full robust cancelation. Thread parking also turns out to
be useful for implementing `sleep`, so is now used for that on Windows
and NetBSD.
This commit also introduces proper cancelation support for most Windows
operations. The most notable omission right now is DNS lookups through
`GetAddrInfoEx`, just because they're a little more work due to having
a unique cancelation mechanism---but the machinery is all there, so I'll
finish gluing it together soon.
As of this commit, there are very few parts of `Io.Threaded` which do
not support full robust cancelation. The only ones which actually really
matter (because they could block for a prolonged period of time) are DNS
lookups on Windows (as discussed above) and futex waits on WASM.
There's a good argument to not have this in the std lib but it's more
work to remove it than to leave it in, and this branch is already
20,000+ lines changed.
Maintaining the POSIX `stat` bits for Zig is a pain. The order and
bit-length of members differ between all architectures, and int types
can be signed or unsigned. The libcs deal with this by introducing the
own version of `struct stat` and copying the kernel structure members to
it. In the case of glibc, they did it twice thanks to the largefile
transition!
In practice, the project needs to maintain three versions of `struct
stat`:
- What the kernel defines.
- What musl wants for `struct stat`.
- What glibc wants for `struct stat64`. Make sure to use `fstatat64`!
This isn't as simple as running `zig translate-c`. In #21440 I had to:
- Compile toolchains for each arch+glibc/musl combo.
- Create a test `fstat` program with/without `FILE_OFFSET_BITS=64`.
- Dump the value for `struct stat`.
- Stare at `std.os.linux`/`std.c` and cry.
- Add some missing padding.
The fact that so many target checks in the `linux` and `posix` tests
exist is most likely due to writing to padding bits and failing later.
The solution to this madness is `statx(2)`:
- It takes a single structure that is the same for all arches AND libcs.
- It uses a custom timestamp format, but it is 64-bit ready.
- It gives the same info as `fstatat(2)` and more!
- Unlike `fstatat(2)`, you can request a subset of the info required
based on passing a mask.
It's so good that modern Linux arches (e.g. riscv) don't even implement
`stat`, with the libcs using a generic `struct stat` and copying from
`struct statx`.
Therefore, this commit rips out all the `stat` bits from `std.os.linux`
and `std.c`. `std.posix.Stat` is now `void`, and calling
`std.posix.*stat` is an compile-time error. A wrapper around `statx` has
been added to `std.os.linux`, and callers have been upgraded to use it.
Tests have also been updated to use `statx` where possible.
While I was here, I converted the mask and file attributes to be packed
struct bitfields. A nice side effect is checking that you actually
recieved the members you asked for via `Statx.mask`, which I have used
by adding `assert`s at specific callsites.
This also unifies the rename implementations, since previously `posix.renameW` used `MoveFileEx` while `posix.renameatW` used `NtOpenFile`/`NtSetInformationFile`. This, in turn, allows the `MoveFileEx` bindings to be deleted as `posix.renameW` was the only usage.
- Affects the following functions:
+ `std.fs.Dir.readLinkW`
+ `std.os.windows.ReadLink`
+ `std.os.windows.ntToWin32Namespace`
+ `std.posix.readlinkW`
+ `std.posix.readlinkatW`
Each of these functions (except `ntToWin32Namespace`) took WTF-16 as input and would output WTF-8, which makes optimal buffer re-use difficult at callsites and could force unnecessary WTF-16 <-> WTF-8 conversion during an intermediate step.
The functions have been updated to output WTF-16, and also allow for the path and the output to re-use the same buffer (i.e. in-place modification), which can reduce the stack usage at callsites. For example, all of `std.fs.Dir.readLink`/`readLinkZ`/`std.posix.readlink`/`readlinkZ`/`readlinkat`/`readlinkatZ` have had their stack usage reduced by one PathSpace struct (64 KiB) when targeting Windows.
The new `ntToWin32Namespace` takes an output buffer and returns a slice from that instead of returning a PathSpace, which is necessary to make the above possible.
The reasoning in the comment deleted by this commit no longer applies, since that same benefit can be obtained by using OpenFile with `.filter = .any`.
Also removes a stray debug.print
Apple's own headers and tbd files prefer to think of Mac Catalyst as a distinct
OS target. Earlier, when DriverKit support was added to LLVM, it was represented
a distinct OS. So why Apple decided to only represent Mac Catalyst as an ABI in
the target triple is beyond me. But this isn't the first time they've ignored
established target triple norms (see: armv7k and aarch64_32) and it probably
won't be the last.
While doing this, I also audited all Darwin OS prongs throughout the codebase
and made sure they cover all the tags.
Andrew Kelley