Rename all references of sparcv9 to sparc64, to make Zig align more with
other projects. Also, added new function to convert glibc arch name to Zig
arch name, since it refers to the architecture as sparcv9.
This is based on the suggestion by @kubkon in PR 11847.
(https://github.com/ziglang/zig/pull/11487#pullrequestreview-963761757)
* back out the changes to RunStep
* move the disabled test to the .cpp code and avoid a confusing
name-collision with the _LIBCPP macro prefix
* fix merge conflict with the edits to the same test that ensure global
initializers are called.
Now this branch is only concerned with single-threaded targets and
passing the correct macro defines to libc++.
stage2: change logic for detecting whether the main package is inside
the std package. Previously it relied on realpath() which is not portable.
This uses resolve() which is how imports already work.
* stage2: fix cleanup bug when creating Module
* flatten lib/std/special/* to lib/*
- this was motivated by making main_pkg_is_inside_std false for
compiler_rt & friends.
* rename "mini libc" to "universal libc"
Instead, just return ChildProcess directly. This structure does not
require a stable address, so we can put it on the stack just fine. If
someone wants it on the heap they should do.
const proc = try allocator.create(ChildProcess);
proc.* = ChildProcess.init(args, allocator);
This reverts commit a430630002bf02162ccbf8d3eb10fd73e490cefd.
Wait a minute, I'm sorry, I need to revert this. The whole premise
of this change is broken because the point of the hash is that it tells
whether the same compilation has been done before. This requires items
to be added to the hash in the same sequence every time. This means that
introducing a lock is fundamentally broken because the order needs to be
the same in future runs of the compiler, and not decided by threads
racing against each other.
The proper solution to this is to, in whole cache mode, append the hash
inputs to some data structure, and then after the compilation is
complete, do some kind of sorting on the hash inputs so that they will
be the same order every time, then apply them in sequence. No lock on
the Cache object is needed for this scheme.
This makes stage2 and stage3 have different cache namespaces, so that
building something with stage3 does not try to reuse the same cached
artifacts as were produced by stage2. This makes sense since the code
of stage3 is produced by the self-hosted compiler, whereas the code of
stage2 is produced by the bootstrap compiler. Note also that stage4 and
stage3 will share the same zig_backend, end hence cache namespace.
Ideally stage4 and stage3 are identical binaries, so this checks out.
Rather than allocating Decl objects with an Allocator, we instead allocate
them with a SegmentedList. This provides four advantages:
* Stable memory so that one thread can access a Decl object while another
thread allocates additional Decl objects from this list.
* It allows us to use u32 indexes to reference Decl objects rather than
pointers, saving memory in Type, Value, and dependency sets.
* Using integers to reference Decl objects rather than pointers makes
serialization trivial.
* It provides a unique integer to be used for anonymous symbol names,
avoiding multi-threaded contention on an atomic counter.
This flag is used when building stage1 to omit the stage2 backends from
the compiler to save memory on the CI server. It regressed with the
merging of e8813b296bc55a13b534bd9b2a03e1f6af366915 because Value
functions started calling into Sema functions.
The end goal for this build option is to eliminate it.
With this change, we can now bake in entitlements into the binary.
Additionally, I see this as the first step towards full code signature
support which includes baking in Apple issued certificates for
redistribution, etc.
Introduce `Module.ensureFuncBodyAnalyzed` and corresponding `Sema`
function. This mirrors `ensureDeclAnalyzed` except also waits until the
function body has been semantically analyzed, meaning that inferred
error sets will have been populated.
Resolving error sets can now emit a "unable to resolve inferred error
set" error instead of producing an incorrect error set type. Resolving
error sets now calls `ensureFuncBodyAnalyzed`. Closes#11046.
`coerceInMemoryAllowedErrorSets` now does a lot more work to avoid
resolving an inferred error set if possible. Same with
`wrapErrorUnionSet`.
Inferred error set types no longer check the `func` field to determine if
they are equal. That was incorrect because an inline or comptime function
call produces a unique error set which has the same `*Module.Fn` value for
this field. Instead we use the `*Module.Fn.InferredErrorSet` pointers to
test equality of inferred error sets.
Previously, Zig ignored -lgcc_s with a warning that this dependency is
redundant because it is satisfied by compiler-rt. However, sfackler
pointed out that it also provides exception handling functions. So if
Zig sees -lgcc_s on the linker line, it needs to fulfill this dependency
with libunwind.
I also made link_libc inferred to be on if libunwind is linked since
libunwind depends on libc.
In accordance with the requesting issue (#10750):
- `zig test` skips any tests that it cannot spawn, returning success
- `zig run` and `zig build` exit with failure, reporting the command the cannot be run
- `zig clang`, `zig ar`, etc. already punt directly to the appropriate clang/lld main(), even before this change
- Native `libc` Detection is not supported
Additionally, `exec()` and related Builder functions error at run-time, reporting the command that cannot be run
First step towards #10634.
Treating stub files as C++ allows to use zig c++ as a host
compiler for nvcc.
Treating cu files as C++ allow using zig c++ as a host compiler in
CMake. CMake calls the host compiler with -E on a cu file to identify
the compiler.
Using zig c++ to directly compile CUDA code is untested.
This is only relevant for ELF files.
I also fixed a bug where passing a zig source file to `zig cc` would
incorrectly punt to clang because it thought there were no positional
arguments.
After #10656, function pointers are represented with e.g.
`*const fn()void` rather than `fn()void`.
This commit adds code to translate-c to emit different code
depending on whether the output zig source code is intended
to be compiled with stage1 or stage2.
Ideally we will have stage1 and stage2 support the exact same
Zig language, but for now they diverge because I would rather
focus on finishing and shipping stage2 than implementing the
features in stage1.
AstGen:
* rename the known_has_bits flag to known_non_opv to make it better
reflect what it actually means.
* add a known_comptime_only flag.
* make the flags take advantage of identifiers of primitives and the
fact that zig has no shadowing.
* correct the known_non_opv flag for function bodies.
Sema:
* Rename `hasCodeGenBits` to `hasRuntimeBits` to better reflect what it
does.
- This function got a bit more complicated in this commit because of
the duality of function bodies: on one hand they have runtime bits,
but on the other hand they require being comptime known.
* WipAnonDecl now takes a LazySrcDecl parameter and performs the type
resolutions that it needs during finish().
* Implement comptime `@ptrToInt`.
Codegen:
* Improved handling of lowering decl_ref; make it work for
comptime-known ptr-to-int values.
- This same change had to be made many different times; perhaps we
should look into merging the implementations of `genTypedValue`
across x86, arm, aarch64, and riscv.
Instead use the standarized option for communicating the
zig compiler backend at comptime, which is `zig_backend`. This was
introduced in commit 1c24ef0d0b09a12a1fe98056f2fc04de78a82df3.
This exposes a function from stage2 to stage1 to append symbols to automatically export them.
This happends under the following conditions:
- Target is wasm
- User has not provided --export/--rdynamic flags themselves.
This allows Zig code to perform conditional compilation based on a tag
by which a Zig compiler implementation identifies itself.
See the doc comment in this commit for more details.
Doc comments reproduced here:
This function is called by the frontend before flush(). It communicates that
`options.bin_file.emit` directory needs to be renamed from
`[zig-cache]/tmp/[random]` to `[zig-cache]/o/[digest]`.
The frontend would like to simply perform a file system rename, however,
some linker backends care about the file paths of the objects they are linking.
So this function call tells linker backends to rename the paths of object files
to observe the new directory path.
Linker backends which do not have this requirement can fall back to the simple
implementation at the bottom of this function.
This function is only called when CacheMode is `whole`.
This solves stack trace regressions on Windows and macOS because the
linker backends do not observe object file paths until flush().
Instead of juggling GPA-allocated sub_path (and ultimately dropping the
ball, in this analogy), `Compilation.create` allocates an
already-exactly-correct size `sub_path` that has the digest unpopulated.
This is then overwritten in place as necessary and used as the
`emit_bin.sub_path` value, and no allocations/frees are performed for
this file path.
