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This path being relative is unconventional and causes issues for us
if the output artifact is ever used from a different cwd than the one it
was built from. The behavior implemented by this commit of always
emitting these paths as absolute was actually the behavior in 0.14.x,
but it regressed in 0.15.1 due to internal reworks to path handling
which led to relative paths being more common in the compiler internals.
Resolves: #25433
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This iteration already has significantly better incremental support.
Closes #24110
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missing `extern` on a struct.
but also all these instances that call pwriteAll with a `@ptrCast` are
endianness bugs.
this should be changed to use File.Writer and call writeSliceEndian
instead.
this commit fixes one immediate problem but does not fix everything.
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std.fmt.Formatter -> std.fmt.Alt
std.fmt.format -> std.Io.Writer.print
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Also, breaking API changes to:
* std.fs.Dir.readFileAlloc
* std.fs.Dir.readFileAllocOptions
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and delete deprecated alias std.io
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Closes #24259
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This commit expands on the foundations laid by https://github.com/ziglang/zig/pull/23177
and moves even more `Sema`-only functionality from `Value`
to `Sema.arith`. Specifically all shift and bitwise operations,
`@truncate`, `@bitReverse` and `@byteSwap` have been moved and
adapted to the new rules around `undefined`.
Especially the comptime shift operations have been basically
rewritten, fixing many open issues in the process.
New rules applied to operators:
* `<<`, `@shlExact`, `@shlWithOverflow`, `>>`, `@shrExact`: compile error if any operand is undef
* `<<|`, `~`, `^`, `@truncate`, `@bitReverse`, `@byteSwap`: return undef if any operand is undef
* `&`, `|`: Return undef if both operands are undef, turn undef into actual `0xAA` bytes otherwise
Additionally this commit canonicalizes the representation of
aggregates with all-undefined members in the `InternPool` by
disallowing them and enforcing the usage of a single typed
`undef` value instead. This reduces the amount of edge cases
and fixes a bunch of bugs related to partially undefined vecs.
List of operations directly affected by this patch:
* `<<`, `<<|`, `@shlExact`, `@shlWithOverflow`
* `>>`, `@shrExact`
* `&`, `|`, `~`, `^` and their atomic rmw + reduce pendants
* `@truncate`, `@bitReverse`, `@byteSwap`
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This experimental target was never fully completed. The operating system
is not that interesting or popular anyway, and the maintainer is no
longer around.
Not worth the maintenance burden. This code can be resurrected later if
it is worth it. In such case it will be subject to greater scrutiny.
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Basically everything that has a direct replacement or no uses left.
Notable omissions:
- std.ArrayHashMap: Too much fallout, needs a separate cleanup.
- std.debug.runtime_safety: Too much fallout.
- std.heap.GeneralPurposeAllocator: Lots of references to it remain, not
a simple find and replace as "debug allocator" is not equivalent to
"general purpose allocator".
- std.io.Reader: Is being reworked at the moment.
- std.unicode.utf8Decode(): No replacement, needs a new API first.
- Manifest backwards compat options: Removal would break test data used
by TestFetchBuilder.
- panic handler needs to be a namespace: Many tests still rely on it
being a function, needs a separate cleanup.
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Introduces `std.fmt.alt` which is a helper for calling alternate format
methods besides one named "format".
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added adapter to AnyWriter and GenericWriter to help bridge the gap
between old and new API
make std.testing.expectFmt work at compile-time
std.fmt no longer has a dependency on std.unicode. Formatted printing
was never properly unicode-aware. Now it no longer pretends to be.
Breakage/deprecations:
* std.fs.File.reader -> std.fs.File.deprecatedReader
* std.fs.File.writer -> std.fs.File.deprecatedWriter
* std.io.GenericReader -> std.io.Reader
* std.io.GenericWriter -> std.io.Writer
* std.io.AnyReader -> std.io.Reader
* std.io.AnyWriter -> std.io.Writer
* std.fmt.format -> std.fmt.deprecatedFormat
* std.fmt.fmtSliceEscapeLower -> std.ascii.hexEscape
* std.fmt.fmtSliceEscapeUpper -> std.ascii.hexEscape
* std.fmt.fmtSliceHexLower -> {x}
* std.fmt.fmtSliceHexUpper -> {X}
* std.fmt.fmtIntSizeDec -> {B}
* std.fmt.fmtIntSizeBin -> {Bi}
* std.fmt.fmtDuration -> {D}
* std.fmt.fmtDurationSigned -> {D}
* {} -> {f} when there is a format method
* format method signature
- anytype -> *std.io.Writer
- inferred error set -> error{WriteFailed}
- options -> (deleted)
* std.fmt.Formatted
- now takes context type explicitly
- no fmt string
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Now that codegen has no references to linker state this is much easier.
Closes #24153
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This struct is larger than 256 bytes and code that copies it
consistently shows up in profiles of the compiler.
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As of this commit, every backend other than self-hosted Wasm and
self-hosted SPIR-V compiles and (at least somewhat) functions again.
Those two backends are currently disabled with panics.
Note that `Zcu.Feature.separate_thread` is *not* enabled for the fixed
backends. Avoiding linker references from codegen is a non-trivial task,
and can be done after this branch.
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Similar to the previous commit, this commit untangles LLD integration
from the self-hosted linkers. Despite the big network of functions which
were involved, it turns out what was going on here is quite simple. The
LLD linking logic is actually very self-contained; it requires a few
flags from the `link.File.OpenOptions`, but that's really about it. We
don't need any of the mutable state on `Elf`/`Coff`/`Wasm`, for
instance. There was some legacy code trying to handle support for using
self-hosted codegen with LLD, but that's not a supported use case, so
I've just stripped it out.
For now, I've just pasted the logic for linking the 3 targets we
currently support using LLD for into this new linker implementation,
`link.Lld`; however, it's almost certainly possible to combine some of
the logic and simplify this file a bit. But to be honest, it's not
actually that bad right now.
This commit ends up eliminating the distinction between `flush` and
`flushZcu` (formerly `flushModule`) in linkers, where the latter
previously meant something along the lines of "flush, but if you're
going to be linking with LLD, just flush the ZCU object file, don't
actually link"?. The distinction here doesn't seem like it was properly
defined, and most linkers seem to treat them as essentially identical
anyway. Regardless, all calls to `flushZcu` are gone now, so it's
deleted -- one `flush` to rule them all!
The end result of this commit and the preceding one is that LLVM and LLD
fit into the pipeline much more sanely:
* If we're using LLVM for the ZCU, that state is on `zcu.llvm_object`
* If we're using LLD to link, then the `link.File` is a `link.Lld`
* Calls to "ZCU link functions" (e.g. `updateNav`) lower to calls to the
LLVM object if it's available, or otherwise to the `link.File` if it's
available (neither is available under `-fno-emit-bin`)
* After everything is done, linking is finalized by calling `flush` on
the `link.File`; for `link.Lld` this invokes LLD, for other linkers it
flushes self-hosted linker state
There's one messy thing remaining, and that's how self-hosted function
codegen in a ZCU works; right now, we process AIR with a call sequence
something like this:
* `link.doTask`
* `Zcu.PerThread.linkerUpdateFunc`
* `link.File.updateFunc`
* `link.Elf.updateFunc`
* `link.Elf.ZigObject.updateFunc`
* `codegen.generateFunction`
* `arch.x86_64.CodeGen.generate`
So, we start in the linker, take a scenic detour through `Zcu`, go back
to the linker, into its implementation, and then... right back out, into
code which is generic over the linker implementation, and then dispatch
on the *backend* instead! Of course, within `arch.x86_64.CodeGen`, there
are some more places which switch on the `link` implementation being
used. This is all pretty silly... so it shall be my next target.
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The main goal of this commit is to make it easier to decouple codegen
from the linkers by being able to do LLVM codegen without going through
the `link.File`; however, this ended up being a nice refactor anyway.
Previously, every linker stored an optional `llvm.Object`, which was
populated when using LLVM for the ZCU *and* linking an output binary;
and `Zcu` also stored an optional `llvm.Object`, which was used only
when we needed LLVM for the ZCU (e.g. for `-femit-llvm-bc`) but were not
emitting a binary.
This situation was incredibly silly. It meant there were N+1 places the
LLVM object might be instead of just 1, and it meant that every linker
had to start a bunch of methods by checking for an LLVM object, and just
dispatching to the corresponding method on *it* instead if it was not
`null`.
Instead, we now always store the LLVM object on the `Zcu` -- which makes
sense, because it corresponds to the object emitted by, well, the Zig
Compilation Unit! The linkers now mostly don't make reference to LLVM.
`Compilation` makes sure to emit the LLVM object if necessary before
calling `flush`, so it is ready for the linker. Also, all of the
`link.File` methods which act on the ZCU -- like `updateNav` -- now
check for the LLVM object in `link.zig` instead of in every single
individual linker implementation. Notably, the change to LLVM emit
improves this rather ludicrous call chain in the `-fllvm -flld` case:
* Compilation.flush
* link.File.flush
* link.Elf.flush
* link.Elf.linkWithLLD
* link.Elf.flushModule
* link.emitLlvmObject
* Compilation.emitLlvmObject
* llvm.Object.emit
Replacing it with this one:
* Compilation.flush
* llvm.Object.emit
...although we do currently still end up in `link.Elf.linkWithLLD` to do
the actual linking. The logic for invoking LLD should probably also be
unified at least somewhat; I haven't done that in this commit.
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Each target can opt into different sets of legalize features.
By performing these transformations before liveness, instructions
that become unreferenced will have up-to-date liveness information.
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This commit makes some big changes to how we track state for Zig source
files. In particular, it changes:
* How `File` tracks its path on-disk
* How AstGen discovers files
* How file-level errors are tracked
* How `builtin.zig` files and modules are created
The original motivation here was to address incremental compilation bugs
with the handling of files, such as #22696. To fix this, a few changes
are necessary.
Just like declarations may become unreferenced on an incremental update,
meaning we suppress analysis errors associated with them, it is also
possible for all imports of a file to be removed on an incremental
update, in which case file-level errors for that file should be
suppressed. As such, after AstGen, the compiler must traverse files
(starting from analysis roots) and discover the set of "live files" for
this update.
Additionally, the compiler's previous handling of retryable file errors
was not very good; the source location the error was reported as was
based only on the first discovered import of that file. This source
location also disappeared on future incremental updates. So, as a part
of the file traversal above, we also need to figure out the source
locations of imports which errors should be reported against.
Another observation I made is that the "file exists in multiple modules"
error was not implemented in a particularly good way (I get to say that
because I wrote it!). It was subject to races, where the order in which
different imports of a file were discovered affects both how errors are
printed, and which module the file is arbitrarily assigned, with the
latter in turn affecting which other files are considered for import.
The thing I realised here is that while the AstGen worker pool is
running, we cannot know for sure which module(s) a file is in; we could
always discover an import later which changes the answer.
So, here's how the AstGen workers have changed. We initially ensure that
`zcu.import_table` contains the root files for all modules in this Zcu,
even if we don't know any imports for them yet. Then, the AstGen
workers do not need to be aware of modules. Instead, they simply ignore
module imports, and only spin off more workers when they see a by-path
import.
During AstGen, we can't use module-root-relative paths, since we don't
know which modules files are in; but we don't want to unnecessarily use
absolute files either, because those are non-portable and can make
`error.NameTooLong` more likely. As such, I have introduced a new
abstraction, `Compilation.Path`. This type is a way of representing a
filesystem path which has a *canonical form*. The path is represented
relative to one of a few special directories: the lib directory, the
global cache directory, or the local cache directory. As a fallback, we
use absolute (or cwd-relative on WASI) paths. This is kind of similar to
`std.Build.Cache.Path` with a pre-defined list of possible
`std.Build.Cache.Directory`, but has stricter canonicalization rules
based on path resolution to make sure deduplicating files works
properly. A `Compilation.Path` can be trivially converted to a
`std.Build.Cache.Path` from a `Compilation`, but is smaller, has a
canonical form, and has a digest which will be consistent across
different compiler processes with the same lib and cache directories
(important when we serialize incremental compilation state in the
future). `Zcu.File` and `Zcu.EmbedFile` both contain a
`Compilation.Path`, which is used to access the file on-disk;
module-relative sub paths are used quite rarely (`EmbedFile` doesn't
even have one now for simplicity).
After the AstGen workers all complete, we know that any file which might
be imported is definitely in `import_table` and up-to-date. So, we
perform a single-threaded graph traversal; similar to what
`resolveReferences` plays for `AnalUnit`s, but for files instead. We
figure out which files are alive, and which module each file is in. If a
file turns out to be in multiple modules, we set a field on `Zcu` to
indicate this error. If a file is in a different module to a prior
update, we set a flag instructing `updateZirRefs` to invalidate all
dependencies on the file. This traversal also discovers "import errors";
these are errors associated with a specific `@import`. With Zig's
current design, there is only one possible error here: "import outside
of module root". This must be identified during this traversal instead
of during AstGen, because it depends on which module the file is in. I
tried also representing "module not found" errors in this same way, but
it turns out to be much more useful to report those in Sema, because of
use cases like optional dependencies where a module import is behind a
comptime-known build option.
For simplicity, `failed_files` now just maps to `?[]u8`, since the
source location is always the whole file. In fact, this allows removing
`LazySrcLoc.Offset.entire_file` completely, slightly simplifying some
error reporting logic. File-level errors are now directly built in the
`std.zig.ErrorBundle.Wip`. If the payload is not `null`, it is the
message for a retryable error (i.e. an error loading the source file),
and will be reported with a "file imported here" note pointing to the
import site discovered during the single-threaded file traversal.
The last piece of fallout here is how `Builtin` works. Rather than
constructing "builtin" modules when creating `Package.Module`s, they are
now constructed on-the-fly by `Zcu`. The map `Zcu.builtin_modules` maps
from digests to `*Package.Module`s. These digests are abstract hashes of
the `Builtin` value; i.e. all of the options which are placed into
"builtin.zig". During the file traversal, we populate `builtin_modules`
as needed, so that when we see this imports in Sema, we just grab the
relevant entry from this map. This eliminates a bunch of awkward state
tracking during construction of the module graph. It's also now clearer
exactly what options the builtin module has, since previously it
inherited some options arbitrarily from the first-created module with
that "builtin" module!
The user-visible effects of this commit are:
* retryable file errors are now consistently reported against the whole
file, with a note pointing to a live import of that file
* some theoretical bugs where imports are wrongly considered distinct
(when the import path moves out of the cwd and then back in) are fixed
* some consistency issues with how file-level errors are reported are
fixed; these errors will now always be printed in the same order
regardless of how the AstGen pass assigns file indices
* incremental updates do not print retryable file errors differently
between updates or depending on file structure/contents
* incremental updates support files changing modules
* incremental updates support files becoming unreferenced
Resolves: #22696
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Rename `trimLeft` to `trimStart`, and `trimRight` to `trimEnd`.
`trimLeft` and `trimRight` functions remain as deprecated aliases for
these new names.
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