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zig/src/Compilation.zig
mlugg 9eb400ef19
compiler: rework backend pipeline to separate codegen and link 
The idea here is that instead of the linker calling into codegen,
instead codegen should run before we touch the linker, and after MIR is
produced, it is sent to the linker. Aside from simplifying the call
graph (by preventing N linkers from each calling into M codegen
backends!), this has the huge benefit that it is possible to
parallellize codegen separately from linking. The threading model can
look like this:

* 1 semantic analysis thread, which generates AIR
* N codegen threads, which process AIR into MIR
* 1 linker thread, which emits MIR to the binary

The codegen threads are also responsible for `Air.Legalize` and
`Air.Liveness`; it's more efficient to do this work here instead of
blocking the main thread for this trivially parallel task.

I have repurposed the `Zcu.Feature.separate_thread` backend feature to
indicate support for this 1:N:1 threading pattern. This commit makes the
C backend support this feature, since it was relatively easy to divorce
from `link.C`: it just required eliminating some shared buffers. Other
backends don't currently support this feature. In fact, they don't even
compile -- the next few commits will fix them back up.
2025-06-12 13:55:40 +01:00

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const Compilation = @This();
const std = @import("std");
const builtin = @import("builtin");
const fs = std.fs;
const mem = std.mem;
const Allocator = std.mem.Allocator;
const assert = std.debug.assert;
const log = std.log.scoped(.compilation);
const Target = std.Target;
const ThreadPool = std.Thread.Pool;
const WaitGroup = std.Thread.WaitGroup;
const ErrorBundle = std.zig.ErrorBundle;
const fatal = std.process.fatal;
const Value = @import("Value.zig");
const Type = @import("Type.zig");
const target_util = @import("target.zig");
const Package = @import("Package.zig");
const introspect = @import("introspect.zig");
const link = @import("link.zig");
const tracy = @import("tracy.zig");
const trace = tracy.trace;
const build_options = @import("build_options");
const LibCInstallation = std.zig.LibCInstallation;
const glibc = @import("libs/glibc.zig");
const musl = @import("libs/musl.zig");
const freebsd = @import("libs/freebsd.zig");
const netbsd = @import("libs/netbsd.zig");
const mingw = @import("libs/mingw.zig");
const libunwind = @import("libs/libunwind.zig");
const libcxx = @import("libs/libcxx.zig");
const wasi_libc = @import("libs/wasi_libc.zig");
const clangMain = @import("main.zig").clangMain;
const Zcu = @import("Zcu.zig");
const Sema = @import("Sema.zig");
const InternPool = @import("InternPool.zig");
const Cache = std.Build.Cache;
const c_codegen = @import("codegen/c.zig");
const libtsan = @import("libs/libtsan.zig");
const Zir = std.zig.Zir;
const Air = @import("Air.zig");
const Builtin = @import("Builtin.zig");
const LlvmObject = @import("codegen/llvm.zig").Object;
const dev = @import("dev.zig");
pub const Config = @import("Compilation/Config.zig");
/// General-purpose allocator. Used for both temporary and long-term storage.
gpa: Allocator,
/// Arena-allocated memory, mostly used during initialization. However, it can
/// be used for other things requiring the same lifetime as the `Compilation`.
/// Not thread-safe - lock `mutex` if potentially accessing from multiple
/// threads at once.
arena: Allocator,
/// Not every Compilation compiles .zig code! For example you could do `zig build-exe foo.o`.
zcu: ?*Zcu,
/// Contains different state depending on whether the Compilation uses
/// incremental or whole cache mode.
cache_use: CacheUse,
/// All compilations have a root module because this is where some important
/// settings are stored, such as target and optimization mode. This module
/// might not have any .zig code associated with it, however.
root_mod: *Package.Module,
/// User-specified settings that have all the defaults resolved into concrete values.
config: Config,
/// The main output file.
/// In whole cache mode, this is null except for during the body of the update
/// function. In incremental cache mode, this is a long-lived object.
/// In both cases, this is `null` when `-fno-emit-bin` is used.
bin_file: ?*link.File,
/// The root path for the dynamic linker and system libraries (as well as frameworks on Darwin)
sysroot: ?[]const u8,
/// This is `null` when not building a Windows DLL, or when `-fno-emit-implib` is used.
implib_emit: ?Cache.Path,
/// This is non-null when `-femit-docs` is provided.
docs_emit: ?Cache.Path,
root_name: [:0]const u8,
compiler_rt_strat: RtStrat,
ubsan_rt_strat: RtStrat,
/// Resolved into known paths, any GNU ld scripts already resolved.
link_inputs: []const link.Input,
/// Needed only for passing -F args to clang.
framework_dirs: []const []const u8,
/// These are only for DLLs dependencies fulfilled by the `.def` files shipped
/// with Zig. Static libraries are provided as `link.Input` values.
windows_libs: std.StringArrayHashMapUnmanaged(void),
version: ?std.SemanticVersion,
libc_installation: ?*const LibCInstallation,
skip_linker_dependencies: bool,
function_sections: bool,
data_sections: bool,
link_eh_frame_hdr: bool,
native_system_include_paths: []const []const u8,
/// List of symbols forced as undefined in the symbol table
/// thus forcing their resolution by the linker.
/// Corresponds to `-u <symbol>` for ELF/MachO and `/include:<symbol>` for COFF/PE.
force_undefined_symbols: std.StringArrayHashMapUnmanaged(void),
c_object_table: std.AutoArrayHashMapUnmanaged(*CObject, void) = .empty,
win32_resource_table: if (dev.env.supports(.win32_resource)) std.AutoArrayHashMapUnmanaged(*Win32Resource, void) else struct {
pub fn keys(_: @This()) [0]void {
return .{};
}
pub fn count(_: @This()) u0 {
return 0;
}
pub fn deinit(_: @This(), _: Allocator) void {}
} = .{},
link_diags: link.Diags,
link_task_queue: link.Queue = .empty,
/// Set of work that can be represented by only flags to determine whether the
/// work is queued or not.
queued_jobs: QueuedJobs,
work_queues: [
len: {
var len: usize = 0;
for (std.enums.values(Job.Tag)) |tag| {
len = @max(Job.stage(tag) + 1, len);
}
break :len len;
}
]std.fifo.LinearFifo(Job, .Dynamic),
/// These jobs are to invoke the Clang compiler to create an object file, which
/// gets linked with the Compilation.
c_object_work_queue: std.fifo.LinearFifo(*CObject, .Dynamic),
/// These jobs are to invoke the RC compiler to create a compiled resource file (.res), which
/// gets linked with the Compilation.
win32_resource_work_queue: if (dev.env.supports(.win32_resource)) std.fifo.LinearFifo(*Win32Resource, .Dynamic) else struct {
pub fn ensureUnusedCapacity(_: @This(), _: u0) error{}!void {}
pub fn readItem(_: @This()) ?noreturn {
return null;
}
pub fn deinit(_: @This()) void {}
},
/// The ErrorMsg memory is owned by the `CObject`, using Compilation's general purpose allocator.
/// This data is accessed by multiple threads and is protected by `mutex`.
failed_c_objects: std.AutoArrayHashMapUnmanaged(*CObject, *CObject.Diag.Bundle) = .empty,
/// The ErrorBundle memory is owned by the `Win32Resource`, using Compilation's general purpose allocator.
/// This data is accessed by multiple threads and is protected by `mutex`.
failed_win32_resources: if (dev.env.supports(.win32_resource)) std.AutoArrayHashMapUnmanaged(*Win32Resource, ErrorBundle) else struct {
pub fn values(_: @This()) [0]void {
return .{};
}
pub fn deinit(_: @This(), _: Allocator) void {}
} = .{},
/// Miscellaneous things that can fail.
misc_failures: std.AutoArrayHashMapUnmanaged(MiscTask, MiscError) = .empty,
/// When this is `true` it means invoking clang as a sub-process is expected to inherit
/// stdin, stdout, stderr, and if it returns non success, to forward the exit code.
/// Otherwise we attempt to parse the error messages and expose them via the Compilation API.
/// This is `true` for `zig cc`, `zig c++`, and `zig translate-c`.
clang_passthrough_mode: bool,
clang_preprocessor_mode: ClangPreprocessorMode,
/// Whether to print clang argvs to stdout.
verbose_cc: bool,
verbose_air: bool,
verbose_intern_pool: bool,
verbose_generic_instances: bool,
verbose_llvm_ir: ?[]const u8,
verbose_llvm_bc: ?[]const u8,
verbose_cimport: bool,
verbose_llvm_cpu_features: bool,
verbose_link: bool,
disable_c_depfile: bool,
time_report: bool,
stack_report: bool,
debug_compiler_runtime_libs: bool,
debug_compile_errors: bool,
/// Do not check this field directly. Instead, use the `debugIncremental` wrapper function.
debug_incremental: bool,
incremental: bool,
alloc_failure_occurred: bool = false,
last_update_was_cache_hit: bool = false,
c_source_files: []const CSourceFile,
rc_source_files: []const RcSourceFile,
global_cc_argv: []const []const u8,
cache_parent: *Cache,
/// Populated when a sub-Compilation is created during the `update` of its parent.
/// In this case the child must additionally add file system inputs to this object.
parent_whole_cache: ?ParentWholeCache,
/// Path to own executable for invoking `zig clang`.
self_exe_path: ?[]const u8,
/// Owned by the caller of `Compilation.create`.
dirs: Directories,
libc_include_dir_list: []const []const u8,
libc_framework_dir_list: []const []const u8,
rc_includes: RcIncludes,
mingw_unicode_entry_point: bool,
thread_pool: *ThreadPool,
/// Populated when we build the libc++ static library. A Job to build this is placed in the queue
/// and resolved before calling linker.flush().
libcxx_static_lib: ?CrtFile = null,
/// Populated when we build the libc++abi static library. A Job to build this is placed in the queue
/// and resolved before calling linker.flush().
libcxxabi_static_lib: ?CrtFile = null,
/// Populated when we build the libunwind static library. A Job to build this is placed in the queue
/// and resolved before calling linker.flush().
libunwind_static_lib: ?CrtFile = null,
/// Populated when we build the TSAN library. A Job to build this is placed in the queue
/// and resolved before calling linker.flush().
tsan_lib: ?CrtFile = null,
/// Populated when we build the UBSAN library. A Job to build this is placed in the queue
/// and resolved before calling linker.flush().
ubsan_rt_lib: ?CrtFile = null,
/// Populated when we build the UBSAN object. A Job to build this is placed in the queue
/// and resolved before calling linker.flush().
ubsan_rt_obj: ?CrtFile = null,
/// Populated when we build the libc static library. A Job to build this is placed in the queue
/// and resolved before calling linker.flush().
zigc_static_lib: ?CrtFile = null,
/// Populated when we build the libcompiler_rt static library. A Job to build this is indicated
/// by setting `queued_jobs.compiler_rt_lib` and resolved before calling linker.flush().
compiler_rt_lib: ?CrtFile = null,
/// Populated when we build the compiler_rt_obj object. A Job to build this is indicated
/// by setting `queued_jobs.compiler_rt_obj` and resolved before calling linker.flush().
compiler_rt_obj: ?CrtFile = null,
/// Populated when we build the libfuzzer static library. A Job to build this
/// is indicated by setting `queued_jobs.fuzzer_lib` and resolved before
/// calling linker.flush().
fuzzer_lib: ?CrtFile = null,
glibc_so_files: ?glibc.BuiltSharedObjects = null,
freebsd_so_files: ?freebsd.BuiltSharedObjects = null,
netbsd_so_files: ?netbsd.BuiltSharedObjects = null,
wasi_emulated_libs: []const wasi_libc.CrtFile,
/// For example `Scrt1.o` and `libc_nonshared.a`. These are populated after building libc from source,
/// The set of needed CRT (C runtime) files differs depending on the target and compilation settings.
/// The key is the basename, and the value is the absolute path to the completed build artifact.
crt_files: std.StringHashMapUnmanaged(CrtFile) = .empty,
/// How many lines of reference trace should be included per compile error.
/// Null means only show snippet on first error.
reference_trace: ?u32 = null,
/// This mutex guards all `Compilation` mutable state.
/// Disabled in single-threaded mode because the thread pool spawns in the same thread.
mutex: if (builtin.single_threaded) struct {
pub inline fn tryLock(_: @This()) void {}
pub inline fn lock(_: @This()) void {}
pub inline fn unlock(_: @This()) void {}
} else std.Thread.Mutex = .{},
test_filters: []const []const u8,
test_name_prefix: ?[]const u8,
emit_asm: ?EmitLoc,
emit_llvm_ir: ?EmitLoc,
emit_llvm_bc: ?EmitLoc,
link_task_wait_group: WaitGroup = .{},
work_queue_progress_node: std.Progress.Node = .none,
llvm_opt_bisect_limit: c_int,
file_system_inputs: ?*std.ArrayListUnmanaged(u8),
/// This is the digest of the cache for the current compilation.
/// This digest will be known after update() is called.
digest: ?[Cache.bin_digest_len]u8 = null,
const QueuedJobs = struct {
compiler_rt_lib: bool = false,
compiler_rt_obj: bool = false,
ubsan_rt_lib: bool = false,
ubsan_rt_obj: bool = false,
fuzzer_lib: bool = false,
musl_crt_file: [@typeInfo(musl.CrtFile).@"enum".fields.len]bool = @splat(false),
glibc_crt_file: [@typeInfo(glibc.CrtFile).@"enum".fields.len]bool = @splat(false),
freebsd_crt_file: [@typeInfo(freebsd.CrtFile).@"enum".fields.len]bool = @splat(false),
netbsd_crt_file: [@typeInfo(netbsd.CrtFile).@"enum".fields.len]bool = @splat(false),
/// one of WASI libc static objects
wasi_libc_crt_file: [@typeInfo(wasi_libc.CrtFile).@"enum".fields.len]bool = @splat(false),
/// one of the mingw-w64 static objects
mingw_crt_file: [@typeInfo(mingw.CrtFile).@"enum".fields.len]bool = @splat(false),
/// all of the glibc shared objects
glibc_shared_objects: bool = false,
freebsd_shared_objects: bool = false,
netbsd_shared_objects: bool = false,
/// libunwind.a, usually needed when linking libc
libunwind: bool = false,
libcxx: bool = false,
libcxxabi: bool = false,
libtsan: bool = false,
zigc_lib: bool = false,
};
/// A filesystem path, represented relative to one of a few specific directories where possible.
/// Every path (considering symlinks as distinct paths) has a canonical representation in this form.
/// This abstraction allows us to:
/// * always open files relative to a consistent root on the filesystem
/// * detect when two paths correspond to the same file, e.g. for deduplicating `@import`s
pub const Path = struct {
root: Root,
/// This path is always in a normalized form, where:
/// * All components are separated by `fs.path.sep`
/// * There are no repeated separators (like "foo//bar")
/// * There are no "." or ".." components
/// * There is no trailing path separator
///
/// There is a leading separator iff `root` is `.none` *and* `builtin.target.os.tag != .wasi`.
///
/// If this `Path` exactly represents a `Root`, the sub path is "", not ".".
sub_path: []u8,
const Root = enum {
/// `sub_path` is relative to the Zig lib directory on `Compilation`.
zig_lib,
/// `sub_path` is relative to the global cache directory on `Compilation`.
global_cache,
/// `sub_path` is relative to the local cache directory on `Compilation`.
local_cache,
/// `sub_path` is not relative to any of the roots listed above.
/// It is resolved starting with `Directories.cwd`; so it is an absolute path on most
/// targets, but cwd-relative on WASI. We do not make it cwd-relative on other targets
/// so that `Path.digest` gives hashes which can be stored in the Zig cache (as they
/// don't depend on a specific compiler instance).
none,
};
/// In general, we can only construct canonical `Path`s at runtime, because weird nesting might
/// mean that e.g. a sub path inside zig/lib/ is actually in the global cache. However, because
/// `Directories` guarantees that `zig_lib` is a distinct path from both cache directories, it's
/// okay for us to construct this path, and only this path, as a comptime constant.
pub const zig_lib_root: Path = .{ .root = .zig_lib, .sub_path = "" };
pub fn deinit(p: Path, gpa: Allocator) void {
gpa.free(p.sub_path);
}
/// The added data is relocatable across any compiler process using the same lib and cache
/// directories; it does not depend on cwd.
pub fn addToHasher(p: Path, h: *Cache.Hasher) void {
h.update(&.{@intFromEnum(p.root)});
h.update(p.sub_path);
}
/// Small convenience wrapper around `addToHasher`.
pub fn digest(p: Path) Cache.BinDigest {
var h = Cache.hasher_init;
p.addToHasher(&h);
return h.finalResult();
}
/// Given a `Path`, returns the directory handle and sub path to be used to open the path.
pub fn openInfo(p: Path, dirs: Directories) struct { fs.Dir, []const u8 } {
const dir = switch (p.root) {
.none => {
const cwd_sub_path = absToCwdRelative(p.sub_path, dirs.cwd);
return .{ fs.cwd(), cwd_sub_path };
},
.zig_lib => dirs.zig_lib.handle,
.global_cache => dirs.global_cache.handle,
.local_cache => dirs.local_cache.handle,
};
if (p.sub_path.len == 0) return .{ dir, "." };
assert(!fs.path.isAbsolute(p.sub_path));
return .{ dir, p.sub_path };
}
pub const format = unreachable; // do not format direcetly
pub fn fmt(p: Path, comp: *Compilation) Formatter {
return .{ .p = p, .comp = comp };
}
const Formatter = struct {
p: Path,
comp: *Compilation,
pub fn format(f: Formatter, comptime unused_fmt: []const u8, options: std.fmt.FormatOptions, w: anytype) !void {
comptime assert(unused_fmt.len == 0);
_ = options;
const root_path: []const u8 = switch (f.p.root) {
.zig_lib => f.comp.dirs.zig_lib.path orelse ".",
.global_cache => f.comp.dirs.global_cache.path orelse ".",
.local_cache => f.comp.dirs.local_cache.path orelse ".",
.none => {
const cwd_sub_path = absToCwdRelative(f.p.sub_path, f.comp.dirs.cwd);
try w.writeAll(cwd_sub_path);
return;
},
};
assert(root_path.len != 0);
try w.writeAll(root_path);
if (f.p.sub_path.len > 0) {
try w.writeByte(fs.path.sep);
try w.writeAll(f.p.sub_path);
}
}
};
/// Given the `sub_path` of a `Path` with `Path.root == .none`, attempts to convert
/// the (absolute) path to a cwd-relative path. Otherwise, returns the absolute path
/// unmodified. The returned string is never empty: "" is converted to ".".
fn absToCwdRelative(sub_path: []const u8, cwd_path: []const u8) []const u8 {
if (builtin.target.os.tag == .wasi) {
if (sub_path.len == 0) return ".";
assert(!fs.path.isAbsolute(sub_path));
return sub_path;
}
assert(fs.path.isAbsolute(sub_path));
if (!std.mem.startsWith(u8, sub_path, cwd_path)) return sub_path;
if (sub_path.len == cwd_path.len) return "."; // the strings are equal
if (sub_path[cwd_path.len] != fs.path.sep) return sub_path; // last component before cwd differs
return sub_path[cwd_path.len + 1 ..]; // remove '/path/to/cwd/' prefix
}
/// From an unresolved path (which can be made of multiple not-yet-joined strings), construct a
/// canonical `Path`.
pub fn fromUnresolved(gpa: Allocator, dirs: Compilation.Directories, unresolved_parts: []const []const u8) Allocator.Error!Path {
const resolved = try introspect.resolvePath(gpa, dirs.cwd, unresolved_parts);
errdefer gpa.free(resolved);
// If, for instance, `dirs.local_cache.path` is within the lib dir, it must take priority,
// so that we prefer `.root = .local_cache` over `.root = .zig_lib`. The easiest way to do
// this is simply to prioritize the longest root path.
const PathAndRoot = struct { ?[]const u8, Root };
var roots: [3]PathAndRoot = .{
.{ dirs.zig_lib.path, .zig_lib },
.{ dirs.global_cache.path, .global_cache },
.{ dirs.local_cache.path, .local_cache },
};
// This must be a stable sort, because the global and local cache directories may be the same, in
// which case we need to make a consistent choice.
std.mem.sort(PathAndRoot, &roots, {}, struct {
fn lessThan(_: void, lhs: PathAndRoot, rhs: PathAndRoot) bool {
const lhs_path_len = if (lhs[0]) |p| p.len else 0;
const rhs_path_len = if (rhs[0]) |p| p.len else 0;
return lhs_path_len > rhs_path_len; // '>' instead of '<' to sort descending
}
}.lessThan);
for (roots) |path_and_root| {
const opt_root_path, const root = path_and_root;
const root_path = opt_root_path orelse {
// This root is the cwd.
if (!fs.path.isAbsolute(resolved)) {
return .{
.root = root,
.sub_path = resolved,
};
}
continue;
};
if (!mem.startsWith(u8, resolved, root_path)) continue;
const sub: []const u8 = if (resolved.len != root_path.len) sub: {
// Check the trailing slash, so that we don't match e.g. `/foo/bar` with `/foo/barren`
if (resolved[root_path.len] != fs.path.sep) continue;
break :sub resolved[root_path.len + 1 ..];
} else "";
const duped = try gpa.dupe(u8, sub);
gpa.free(resolved);
return .{ .root = root, .sub_path = duped };
}
// We're not relative to any root, so we will use an absolute path (on targets where they are available).
if (builtin.target.os.tag == .wasi or fs.path.isAbsolute(resolved)) {
// `resolved` is already absolute (or we're on WASI, where absolute paths don't really exist).
return .{ .root = .none, .sub_path = resolved };
}
if (resolved.len == 0) {
// We just need the cwd path, no trailing separator. Note that `gpa.free(resolved)` would be a nop.
return .{ .root = .none, .sub_path = try gpa.dupe(u8, dirs.cwd) };
}
// We need to make an absolute path. Because `resolved` came from `introspect.resolvePath`, we can just
// join the paths with a simple format string.
const abs_path = try std.fmt.allocPrint(gpa, "{s}{c}{s}", .{ dirs.cwd, fs.path.sep, resolved });
gpa.free(resolved);
return .{ .root = .none, .sub_path = abs_path };
}
/// Constructs a canonical `Path` representing `sub_path` relative to `root`.
///
/// If `sub_path` is resolved, this is almost like directly constructing a `Path`, but this
/// function also canonicalizes the result, which matters because `sub_path` may move us into
/// a different root.
///
/// For instance, if the Zig lib directory is inside the global cache, passing `root` as
/// `.global_cache` could still end up returning a `Path` with `Path.root == .zig_lib`.
pub fn fromRoot(
gpa: Allocator,
dirs: Compilation.Directories,
root: Path.Root,
sub_path: []const u8,
) Allocator.Error!Path {
// Currently, this just wraps `fromUnresolved` for simplicity. A more efficient impl is
// probably possible if this function ever ends up impacting performance somehow.
return .fromUnresolved(gpa, dirs, &.{
switch (root) {
.zig_lib => dirs.zig_lib.path orelse "",
.global_cache => dirs.global_cache.path orelse "",
.local_cache => dirs.local_cache.path orelse "",
.none => "",
},
sub_path,
});
}
/// Given a `Path` and an (unresolved) sub path relative to it, construct a `Path` representing
/// the joined path `p/sub_path`. Note that, like with `fromRoot`, the `sub_path` might cause us
/// to move into a different `Path.Root`.
pub fn join(
p: Path,
gpa: Allocator,
dirs: Compilation.Directories,
sub_path: []const u8,
) Allocator.Error!Path {
// Currently, this just wraps `fromUnresolved` for simplicity. A more efficient impl is
// probably possible if this function ever ends up impacting performance somehow.
return .fromUnresolved(gpa, dirs, &.{
switch (p.root) {
.zig_lib => dirs.zig_lib.path orelse "",
.global_cache => dirs.global_cache.path orelse "",
.local_cache => dirs.local_cache.path orelse "",
.none => "",
},
p.sub_path,
sub_path,
});
}
/// Like `join`, but `sub_path` is relative to the dirname of `p` instead of `p` itself.
pub fn upJoin(
p: Path,
gpa: Allocator,
dirs: Compilation.Directories,
sub_path: []const u8,
) Allocator.Error!Path {
return .fromUnresolved(gpa, dirs, &.{
switch (p.root) {
.zig_lib => dirs.zig_lib.path orelse "",
.global_cache => dirs.global_cache.path orelse "",
.local_cache => dirs.local_cache.path orelse "",
.none => "",
},
p.sub_path,
"..",
sub_path,
});
}
pub fn toCachePath(p: Path, dirs: Directories) Cache.Path {
const root_dir: Cache.Directory = switch (p.root) {
.zig_lib => dirs.zig_lib,
.global_cache => dirs.global_cache,
.local_cache => dirs.local_cache,
else => {
const cwd_sub_path = absToCwdRelative(p.sub_path, dirs.cwd);
return .{
.root_dir = .cwd(),
.sub_path = cwd_sub_path,
};
},
};
assert(!fs.path.isAbsolute(p.sub_path));
return .{
.root_dir = root_dir,
.sub_path = p.sub_path,
};
}
/// This should not be used for most of the compiler pipeline, but is useful when emitting
/// paths from the compilation (e.g. in debug info), because they will not depend on the cwd.
/// The returned path is owned by the caller and allocated into `gpa`.
pub fn toAbsolute(p: Path, dirs: Directories, gpa: Allocator) Allocator.Error![]u8 {
const root_path: []const u8 = switch (p.root) {
.zig_lib => dirs.zig_lib.path orelse "",
.global_cache => dirs.global_cache.path orelse "",
.local_cache => dirs.local_cache.path orelse "",
.none => "",
};
return fs.path.resolve(gpa, &.{
dirs.cwd,
root_path,
p.sub_path,
});
}
pub fn isNested(inner: Path, outer: Path) union(enum) {
/// Value is the sub path, which is a sub-slice of `inner.sub_path`.
yes: []const u8,
no,
different_roots,
} {
if (inner.root != outer.root) return .different_roots;
if (!mem.startsWith(u8, inner.sub_path, outer.sub_path)) return .no;
if (inner.sub_path.len == outer.sub_path.len) return .no;
if (outer.sub_path.len == 0) return .{ .yes = inner.sub_path };
if (inner.sub_path[outer.sub_path.len] != fs.path.sep) return .no;
return .{ .yes = inner.sub_path[outer.sub_path.len + 1 ..] };
}
/// Returns whether this `Path` is illegal to have as a user-imported `Zcu.File` (including
/// as the root of a module). Such paths exist in directories which the Zig compiler treats
/// specially, like 'global_cache/b/', which stores 'builtin.zig' files.
pub fn isIllegalZigImport(p: Path, gpa: Allocator, dirs: Directories) Allocator.Error!bool {
const zig_builtin_dir: Path = try .fromRoot(gpa, dirs, .global_cache, "b");
defer zig_builtin_dir.deinit(gpa);
return switch (p.isNested(zig_builtin_dir)) {
.yes => true,
.no, .different_roots => false,
};
}
};
pub const Directories = struct {
/// The string returned by `introspect.getResolvedCwd`. This is typically an absolute path,
/// but on WASI is the empty string "" instead, because WASI does not have absolute paths.
cwd: []const u8,
/// The Zig 'lib' directory.
/// `zig_lib.path` is resolved (`introspect.resolvePath`) or `null` for cwd.
/// Guaranteed to be a different path from `global_cache` and `local_cache`.
zig_lib: Cache.Directory,
/// The global Zig cache directory.
/// `global_cache.path` is resolved (`introspect.resolvePath`) or `null` for cwd.
global_cache: Cache.Directory,
/// The local Zig cache directory.
/// `local_cache.path` is resolved (`introspect.resolvePath`) or `null` for cwd.
/// This may be the same as `global_cache`.
local_cache: Cache.Directory,
pub fn deinit(dirs: *Directories) void {
// The local and global caches could be the same.
const close_local = dirs.local_cache.handle.fd != dirs.global_cache.handle.fd;
dirs.global_cache.handle.close();
if (close_local) dirs.local_cache.handle.close();
dirs.zig_lib.handle.close();
}
/// Returns a `Directories` where `local_cache` is replaced with `global_cache`, intended for
/// use by sub-compilations (e.g. compiler_rt). Do not `deinit` the returned `Directories`; it
/// shares handles with `dirs`.
pub fn withoutLocalCache(dirs: Directories) Directories {
return .{
.cwd = dirs.cwd,
.zig_lib = dirs.zig_lib,
.global_cache = dirs.global_cache,
.local_cache = dirs.global_cache,
};
}
/// Uses `std.process.fatal` on error conditions.
pub fn init(
arena: Allocator,
override_zig_lib: ?[]const u8,
override_global_cache: ?[]const u8,
local_cache_strat: union(enum) {
override: []const u8,
search,
global,
},
wasi_preopens: switch (builtin.target.os.tag) {
.wasi => std.fs.wasi.Preopens,
else => void,
},
self_exe_path: switch (builtin.target.os.tag) {
.wasi => void,
else => []const u8,
},
) Directories {
const wasi = builtin.target.os.tag == .wasi;
const cwd = introspect.getResolvedCwd(arena) catch |err| {
fatal("unable to get cwd: {s}", .{@errorName(err)});
};
const zig_lib: Cache.Directory = d: {
if (override_zig_lib) |path| break :d openUnresolved(arena, cwd, path, .@"zig lib");
if (wasi) break :d openWasiPreopen(wasi_preopens, "/lib");
break :d introspect.findZigLibDirFromSelfExe(arena, cwd, self_exe_path) catch |err| {
fatal("unable to find zig installation directory '{s}': {s}", .{ self_exe_path, @errorName(err) });
};
};
const global_cache: Cache.Directory = d: {
if (override_global_cache) |path| break :d openUnresolved(arena, cwd, path, .@"global cache");
if (wasi) break :d openWasiPreopen(wasi_preopens, "/cache");
const path = introspect.resolveGlobalCacheDir(arena) catch |err| {
fatal("unable to resolve zig cache directory: {s}", .{@errorName(err)});
};
break :d openUnresolved(arena, cwd, path, .@"global cache");
};
const local_cache: Cache.Directory = switch (local_cache_strat) {
.override => |path| openUnresolved(arena, cwd, path, .@"local cache"),
.search => d: {
const maybe_path = introspect.resolveSuitableLocalCacheDir(arena, cwd) catch |err| {
fatal("unable to resolve zig cache directory: {s}", .{@errorName(err)});
};
const path = maybe_path orelse break :d global_cache;
break :d openUnresolved(arena, cwd, path, .@"local cache");
},
.global => global_cache,
};
if (std.mem.eql(u8, zig_lib.path orelse "", global_cache.path orelse "")) {
fatal("zig lib directory '{}' cannot be equal to global cache directory '{}'", .{ zig_lib, global_cache });
}
if (std.mem.eql(u8, zig_lib.path orelse "", local_cache.path orelse "")) {
fatal("zig lib directory '{}' cannot be equal to local cache directory '{}'", .{ zig_lib, local_cache });
}
return .{
.cwd = cwd,
.zig_lib = zig_lib,
.global_cache = global_cache,
.local_cache = local_cache,
};
}
fn openWasiPreopen(preopens: std.fs.wasi.Preopens, name: []const u8) Cache.Directory {
return .{
.path = if (std.mem.eql(u8, name, ".")) null else name,
.handle = .{
.fd = preopens.find(name) orelse fatal("WASI preopen not found: '{s}'", .{name}),
},
};
}
fn openUnresolved(arena: Allocator, cwd: []const u8, unresolved_path: []const u8, thing: enum { @"zig lib", @"global cache", @"local cache" }) Cache.Directory {
const path = introspect.resolvePath(arena, cwd, &.{unresolved_path}) catch |err| {
fatal("unable to resolve {s} directory: {s}", .{ @tagName(thing), @errorName(err) });
};
const nonempty_path = if (path.len == 0) "." else path;
const handle_or_err = switch (thing) {
.@"zig lib" => std.fs.cwd().openDir(nonempty_path, .{}),
.@"global cache", .@"local cache" => std.fs.cwd().makeOpenPath(nonempty_path, .{}),
};
return .{
.path = if (path.len == 0) null else path,
.handle = handle_or_err catch |err| {
const extra_str: []const u8 = e: {
if (thing == .@"global cache") switch (err) {
error.AccessDenied, error.ReadOnlyFileSystem => break :e "\n" ++
"If this location is not writable then consider specifying an alternative with " ++
"the ZIG_GLOBAL_CACHE_DIR environment variable or the --global-cache-dir option.",
else => {},
};
break :e "";
};
fatal("unable to open {s} directory '{s}': {s}{s}", .{ @tagName(thing), nonempty_path, @errorName(err), extra_str });
},
};
}
};
/// This small wrapper function just checks whether debug extensions are enabled before checking
/// `comp.debug_incremental`. It is inline so that comptime-known `false` propagates to the caller,
/// preventing debugging features from making it into release builds of the compiler.
pub inline fn debugIncremental(comp: *const Compilation) bool {
if (!build_options.enable_debug_extensions or builtin.single_threaded) return false;
return comp.debug_incremental;
}
pub const default_stack_protector_buffer_size = target_util.default_stack_protector_buffer_size;
pub const SemaError = Zcu.SemaError;
pub const CrtFile = struct {
lock: Cache.Lock,
full_object_path: Cache.Path,
pub fn isObject(cf: CrtFile) bool {
return switch (classifyFileExt(cf.full_object_path.sub_path)) {
.object => true,
else => false,
};
}
pub fn deinit(self: *CrtFile, gpa: Allocator) void {
self.lock.release();
gpa.free(self.full_object_path.sub_path);
self.* = undefined;
}
};
/// Supported languages for "zig clang -x <lang>".
/// Loosely based on llvm-project/clang/include/clang/Driver/Types.def
pub const LangToExt = std.StaticStringMap(FileExt).initComptime(.{
.{ "c", .c },
.{ "c-header", .h },
.{ "c++", .cpp },
.{ "c++-header", .hpp },
.{ "objective-c", .m },
.{ "objective-c-header", .hm },
.{ "objective-c++", .mm },
.{ "objective-c++-header", .hmm },
.{ "assembler", .assembly },
.{ "assembler-with-cpp", .assembly_with_cpp },
});
/// For passing to a C compiler.
pub const CSourceFile = struct {
/// Many C compiler flags are determined by settings contained in the owning Module.
owner: *Package.Module,
src_path: []const u8,
extra_flags: []const []const u8 = &.{},
/// Same as extra_flags except they are not added to the Cache hash.
cache_exempt_flags: []const []const u8 = &.{},
/// This field is non-null if and only if the language was explicitly set
/// with "-x lang".
ext: ?FileExt = null,
};
/// For passing to resinator.
pub const RcSourceFile = struct {
owner: *Package.Module,
src_path: []const u8,
extra_flags: []const []const u8 = &.{},
};
pub const RcIncludes = enum {
/// Use MSVC if available, fall back to MinGW.
any,
/// Use MSVC include paths (MSVC install + Windows SDK, must be present on the system).
msvc,
/// Use MinGW include paths (distributed with Zig).
gnu,
/// Do not use any autodetected include paths.
none,
};
const Job = union(enum) {
/// Given the generated AIR for a function, put it onto the code generation queue.
/// This `Job` exists (instead of the `link.ZcuTask` being directly queued) to ensure that
/// all types are resolved before the linker task is queued.
/// If the backend does not support `Zcu.Feature.separate_thread`, codegen and linking happen immediately.
codegen_func: struct {
func: InternPool.Index,
/// The AIR emitted from analyzing `func`; owned by this `Job` in `gpa`.
air: Air,
},
/// Queue a `link.ZcuTask` to emit this non-function `Nav` into the output binary.
/// This `Job` exists (instead of the `link.ZcuTask` being directly queued) to ensure that
/// all types are resolved before the linker task is queued.
/// If the backend does not support `Zcu.Feature.separate_thread`, the task is run immediately.
link_nav: InternPool.Nav.Index,
/// Queue a `link.ZcuTask` to emit debug information for this container type.
/// This `Job` exists (instead of the `link.ZcuTask` being directly queued) to ensure that
/// all types are resolved before the linker task is queued.
/// If the backend does not support `Zcu.Feature.separate_thread`, the task is run immediately.
link_type: InternPool.Index,
update_line_number: InternPool.TrackedInst.Index,
/// The `AnalUnit`, which is *not* a `func`, must be semantically analyzed.
/// This may be its first time being analyzed, or it may be outdated.
/// If the unit is a test function, an `analyze_func` job will then be queued.
analyze_comptime_unit: InternPool.AnalUnit,
/// This function must be semantically analyzed.
/// This may be its first time being analyzed, or it may be outdated.
/// After analysis, a `codegen_func` job will be queued.
/// These must be separate jobs to ensure any needed type resolution occurs *before* codegen.
/// This job is separate from `analyze_comptime_unit` because it has a different priority.
analyze_func: InternPool.Index,
/// The main source file for the module needs to be analyzed.
analyze_mod: *Package.Module,
/// Fully resolve the given `struct` or `union` type.
resolve_type_fully: InternPool.Index,
/// The value is the index into `windows_libs`.
windows_import_lib: usize,
const Tag = @typeInfo(Job).@"union".tag_type.?;
fn stage(tag: Tag) usize {
return switch (tag) {
// Prioritize functions so that codegen can get to work on them on a
// separate thread, while Sema goes back to its own work.
.resolve_type_fully, .analyze_func, .codegen_func => 0,
else => 1,
};
}
comptime {
// Job dependencies
assert(stage(.resolve_type_fully) <= stage(.codegen_func));
}
};
pub const CObject = struct {
/// Relative to cwd. Owned by arena.
src: CSourceFile,
status: union(enum) {
new,
success: struct {
/// The outputted result. `sub_path` owned by gpa.
object_path: Cache.Path,
/// This is a file system lock on the cache hash manifest representing this
/// object. It prevents other invocations of the Zig compiler from interfering
/// with this object until released.
lock: Cache.Lock,
},
/// There will be a corresponding ErrorMsg in Compilation.failed_c_objects.
failure,
/// A transient failure happened when trying to compile the C Object; it may
/// succeed if we try again. There may be a corresponding ErrorMsg in
/// Compilation.failed_c_objects. If there is not, the failure is out of memory.
failure_retryable,
},
pub const Diag = struct {
level: u32 = 0,
category: u32 = 0,
msg: []const u8 = &.{},
src_loc: SrcLoc = .{},
src_ranges: []const SrcRange = &.{},
sub_diags: []const Diag = &.{},
pub const SrcLoc = struct {
file: u32 = 0,
line: u32 = 0,
column: u32 = 0,
offset: u32 = 0,
};
pub const SrcRange = struct {
start: SrcLoc = .{},
end: SrcLoc = .{},
};
pub fn deinit(diag: *Diag, gpa: Allocator) void {
gpa.free(diag.msg);
gpa.free(diag.src_ranges);
for (diag.sub_diags) |sub_diag| {
var sub_diag_mut = sub_diag;
sub_diag_mut.deinit(gpa);
}
gpa.free(diag.sub_diags);
diag.* = undefined;
}
pub fn count(diag: Diag) u32 {
var total: u32 = 1;
for (diag.sub_diags) |sub_diag| total += sub_diag.count();
return total;
}
pub fn addToErrorBundle(diag: Diag, eb: *ErrorBundle.Wip, bundle: Bundle, note: *u32) !void {
const err_msg = try eb.addErrorMessage(try diag.toErrorMessage(eb, bundle, 0));
eb.extra.items[note.*] = @intFromEnum(err_msg);
note.* += 1;
for (diag.sub_diags) |sub_diag| try sub_diag.addToErrorBundle(eb, bundle, note);
}
pub fn toErrorMessage(
diag: Diag,
eb: *ErrorBundle.Wip,
bundle: Bundle,
notes_len: u32,
) !ErrorBundle.ErrorMessage {
var start = diag.src_loc.offset;
var end = diag.src_loc.offset;
for (diag.src_ranges) |src_range| {
if (src_range.start.file == diag.src_loc.file and
src_range.start.line == diag.src_loc.line)
{
start = @min(src_range.start.offset, start);
}
if (src_range.end.file == diag.src_loc.file and
src_range.end.line == diag.src_loc.line)
{
end = @max(src_range.end.offset, end);
}
}
const file_name = bundle.file_names.get(diag.src_loc.file) orelse "";
const source_line = source_line: {
if (diag.src_loc.offset == 0 or diag.src_loc.column == 0) break :source_line 0;
const file = std.fs.cwd().openFile(file_name, .{}) catch break :source_line 0;
defer file.close();
file.seekTo(diag.src_loc.offset + 1 - diag.src_loc.column) catch break :source_line 0;
var line = std.ArrayList(u8).init(eb.gpa);
defer line.deinit();
file.reader().readUntilDelimiterArrayList(&line, '\n', 1 << 10) catch break :source_line 0;
break :source_line try eb.addString(line.items);
};
return .{
.msg = try eb.addString(diag.msg),
.src_loc = try eb.addSourceLocation(.{
.src_path = try eb.addString(file_name),
.line = diag.src_loc.line -| 1,
.column = diag.src_loc.column -| 1,
.span_start = start,
.span_main = diag.src_loc.offset,
.span_end = end + 1,
.source_line = source_line,
}),
.notes_len = notes_len,
};
}
pub const Bundle = struct {
file_names: std.AutoArrayHashMapUnmanaged(u32, []const u8) = .empty,
category_names: std.AutoArrayHashMapUnmanaged(u32, []const u8) = .empty,
diags: []Diag = &.{},
pub fn destroy(bundle: *Bundle, gpa: Allocator) void {
for (bundle.file_names.values()) |file_name| gpa.free(file_name);
for (bundle.category_names.values()) |category_name| gpa.free(category_name);
for (bundle.diags) |*diag| diag.deinit(gpa);
gpa.free(bundle.diags);
gpa.destroy(bundle);
}
pub fn parse(gpa: Allocator, path: []const u8) !*Bundle {
const BlockId = enum(u32) {
Meta = 8,
Diag,
_,
};
const RecordId = enum(u32) {
Version = 1,
DiagInfo,
SrcRange,
DiagFlag,
CatName,
FileName,
FixIt,
_,
};
const WipDiag = struct {
level: u32 = 0,
category: u32 = 0,
msg: []const u8 = &.{},
src_loc: SrcLoc = .{},
src_ranges: std.ArrayListUnmanaged(SrcRange) = .empty,
sub_diags: std.ArrayListUnmanaged(Diag) = .empty,
fn deinit(wip_diag: *@This(), allocator: Allocator) void {
allocator.free(wip_diag.msg);
wip_diag.src_ranges.deinit(allocator);
for (wip_diag.sub_diags.items) |*sub_diag| sub_diag.deinit(allocator);
wip_diag.sub_diags.deinit(allocator);
wip_diag.* = undefined;
}
};
const file = try std.fs.cwd().openFile(path, .{});
defer file.close();
var br = std.io.bufferedReader(file.reader());
const reader = br.reader();
var bc = std.zig.llvm.BitcodeReader.init(gpa, .{ .reader = reader.any() });
defer bc.deinit();
var file_names: std.AutoArrayHashMapUnmanaged(u32, []const u8) = .empty;
errdefer {
for (file_names.values()) |file_name| gpa.free(file_name);
file_names.deinit(gpa);
}
var category_names: std.AutoArrayHashMapUnmanaged(u32, []const u8) = .empty;
errdefer {
for (category_names.values()) |category_name| gpa.free(category_name);
category_names.deinit(gpa);
}
var stack: std.ArrayListUnmanaged(WipDiag) = .empty;
defer {
for (stack.items) |*wip_diag| wip_diag.deinit(gpa);
stack.deinit(gpa);
}
try stack.append(gpa, .{});
try bc.checkMagic("DIAG");
while (try bc.next()) |item| switch (item) {
.start_block => |block| switch (@as(BlockId, @enumFromInt(block.id))) {
.Meta => if (stack.items.len > 0) try bc.skipBlock(block),
.Diag => try stack.append(gpa, .{}),
_ => try bc.skipBlock(block),
},
.record => |record| switch (@as(RecordId, @enumFromInt(record.id))) {
.Version => if (record.operands[0] != 2) return error.InvalidVersion,
.DiagInfo => {
const top = &stack.items[stack.items.len - 1];
top.level = @intCast(record.operands[0]);
top.src_loc = .{
.file = @intCast(record.operands[1]),
.line = @intCast(record.operands[2]),
.column = @intCast(record.operands[3]),
.offset = @intCast(record.operands[4]),
};
top.category = @intCast(record.operands[5]);
top.msg = try gpa.dupe(u8, record.blob);
},
.SrcRange => try stack.items[stack.items.len - 1].src_ranges.append(gpa, .{
.start = .{
.file = @intCast(record.operands[0]),
.line = @intCast(record.operands[1]),
.column = @intCast(record.operands[2]),
.offset = @intCast(record.operands[3]),
},
.end = .{
.file = @intCast(record.operands[4]),
.line = @intCast(record.operands[5]),
.column = @intCast(record.operands[6]),
.offset = @intCast(record.operands[7]),
},
}),
.DiagFlag => {},
.CatName => {
try category_names.ensureUnusedCapacity(gpa, 1);
category_names.putAssumeCapacity(
@intCast(record.operands[0]),
try gpa.dupe(u8, record.blob),
);
},
.FileName => {
try file_names.ensureUnusedCapacity(gpa, 1);
file_names.putAssumeCapacity(
@intCast(record.operands[0]),
try gpa.dupe(u8, record.blob),
);
},
.FixIt => {},
_ => {},
},
.end_block => |block| switch (@as(BlockId, @enumFromInt(block.id))) {
.Meta => {},
.Diag => {
var wip_diag = stack.pop().?;
errdefer wip_diag.deinit(gpa);
const src_ranges = try wip_diag.src_ranges.toOwnedSlice(gpa);
errdefer gpa.free(src_ranges);
const sub_diags = try wip_diag.sub_diags.toOwnedSlice(gpa);
errdefer {
for (sub_diags) |*sub_diag| sub_diag.deinit(gpa);
gpa.free(sub_diags);
}
try stack.items[stack.items.len - 1].sub_diags.append(gpa, .{
.level = wip_diag.level,
.category = wip_diag.category,
.msg = wip_diag.msg,
.src_loc = wip_diag.src_loc,
.src_ranges = src_ranges,
.sub_diags = sub_diags,
});
},
_ => {},
},
};
const bundle = try gpa.create(Bundle);
assert(stack.items.len == 1);
bundle.* = .{
.file_names = file_names,
.category_names = category_names,
.diags = try stack.items[0].sub_diags.toOwnedSlice(gpa),
};
return bundle;
}
pub fn addToErrorBundle(bundle: Bundle, eb: *ErrorBundle.Wip) !void {
for (bundle.diags) |diag| {
const notes_len = diag.count() - 1;
try eb.addRootErrorMessage(try diag.toErrorMessage(eb, bundle, notes_len));
if (notes_len > 0) {
var note = try eb.reserveNotes(notes_len);
for (diag.sub_diags) |sub_diag|
try sub_diag.addToErrorBundle(eb, bundle, &note);
}
}
}
};
};
/// Returns if there was failure.
pub fn clearStatus(self: *CObject, gpa: Allocator) bool {
switch (self.status) {
.new => return false,
.failure, .failure_retryable => {
self.status = .new;
return true;
},
.success => |*success| {
gpa.free(success.object_path.sub_path);
success.lock.release();
self.status = .new;
return false;
},
}
}
pub fn destroy(self: *CObject, gpa: Allocator) void {
_ = self.clearStatus(gpa);
gpa.destroy(self);
}
};
pub const Win32Resource = struct {
/// Relative to cwd. Owned by arena.
src: union(enum) {
rc: RcSourceFile,
manifest: []const u8,
},
status: union(enum) {
new,
success: struct {
/// The outputted result. Owned by gpa.
res_path: []u8,
/// This is a file system lock on the cache hash manifest representing this
/// object. It prevents other invocations of the Zig compiler from interfering
/// with this object until released.
lock: Cache.Lock,
},
/// There will be a corresponding ErrorMsg in Compilation.failed_win32_resources.
failure,
/// A transient failure happened when trying to compile the resource file; it may
/// succeed if we try again. There may be a corresponding ErrorMsg in
/// Compilation.failed_win32_resources. If there is not, the failure is out of memory.
failure_retryable,
},
/// Returns true if there was failure.
pub fn clearStatus(self: *Win32Resource, gpa: Allocator) bool {
switch (self.status) {
.new => return false,
.failure, .failure_retryable => {
self.status = .new;
return true;
},
.success => |*success| {
gpa.free(success.res_path);
success.lock.release();
self.status = .new;
return false;
},
}
}
pub fn destroy(self: *Win32Resource, gpa: Allocator) void {
_ = self.clearStatus(gpa);
gpa.destroy(self);
}
};
pub const MiscTask = enum {
write_builtin_zig,
rename_results,
check_whole_cache,
glibc_crt_file,
glibc_shared_objects,
musl_crt_file,
freebsd_crt_file,
freebsd_shared_objects,
netbsd_crt_file,
netbsd_shared_objects,
mingw_crt_file,
windows_import_lib,
libunwind,
libcxx,
libcxxabi,
libtsan,
libubsan,
libfuzzer,
wasi_libc_crt_file,
compiler_rt,
libzigc,
analyze_mod,
docs_copy,
docs_wasm,
@"musl crt1.o",
@"musl rcrt1.o",
@"musl Scrt1.o",
@"musl libc.a",
@"musl libc.so",
@"wasi crt1-reactor.o",
@"wasi crt1-command.o",
@"wasi libc.a",
@"wasi libdl.a",
@"libwasi-emulated-process-clocks.a",
@"libwasi-emulated-getpid.a",
@"libwasi-emulated-mman.a",
@"libwasi-emulated-signal.a",
@"glibc Scrt1.o",
@"glibc libc_nonshared.a",
@"glibc shared object",
@"freebsd libc Scrt1.o",
@"freebsd libc shared object",
@"netbsd libc Scrt0.o",
@"netbsd libc shared object",
@"mingw-w64 crt2.o",
@"mingw-w64 dllcrt2.o",
@"mingw-w64 libmingw32.lib",
};
pub const MiscError = struct {
/// Allocated with gpa.
msg: []u8,
children: ?ErrorBundle = null,
pub fn deinit(misc_err: *MiscError, gpa: Allocator) void {
gpa.free(misc_err.msg);
if (misc_err.children) |*children| {
children.deinit(gpa);
}
misc_err.* = undefined;
}
};
pub const EmitLoc = struct {
/// If this is `null` it means the file will be output to the cache directory.
/// When provided, both the open file handle and the path name must outlive the `Compilation`.
directory: ?Cache.Directory,
/// This may not have sub-directories in it.
basename: []const u8,
};
pub const cache_helpers = struct {
pub fn addModule(hh: *Cache.HashHelper, mod: *const Package.Module) void {
addResolvedTarget(hh, mod.resolved_target);
hh.add(mod.optimize_mode);
hh.add(mod.code_model);
hh.add(mod.single_threaded);
hh.add(mod.error_tracing);
hh.add(mod.valgrind);
hh.add(mod.pic);
hh.add(mod.strip);
hh.add(mod.omit_frame_pointer);
hh.add(mod.stack_check);
hh.add(mod.red_zone);
hh.add(mod.sanitize_c);
hh.add(mod.sanitize_thread);
hh.add(mod.fuzz);
hh.add(mod.unwind_tables);
hh.add(mod.structured_cfg);
hh.add(mod.no_builtin);
hh.addListOfBytes(mod.cc_argv);
}
pub fn addResolvedTarget(
hh: *Cache.HashHelper,
resolved_target: Package.Module.ResolvedTarget,
) void {
const target = resolved_target.result;
hh.add(target.cpu.arch);
hh.addBytes(target.cpu.model.name);
hh.add(target.cpu.features.ints);
hh.add(target.os.tag);
hh.add(target.os.versionRange());
hh.add(target.abi);
hh.add(target.ofmt);
hh.add(resolved_target.is_native_os);
hh.add(resolved_target.is_native_abi);
hh.add(resolved_target.is_explicit_dynamic_linker);
}
pub fn addEmitLoc(hh: *Cache.HashHelper, emit_loc: EmitLoc) void {
hh.addBytes(emit_loc.basename);
}
pub fn addOptionalEmitLoc(hh: *Cache.HashHelper, optional_emit_loc: ?EmitLoc) void {
hh.add(optional_emit_loc != null);
addEmitLoc(hh, optional_emit_loc orelse return);
}
pub fn addOptionalDebugFormat(hh: *Cache.HashHelper, x: ?Config.DebugFormat) void {
hh.add(x != null);
addDebugFormat(hh, x orelse return);
}
pub fn addDebugFormat(hh: *Cache.HashHelper, x: Config.DebugFormat) void {
const tag: @typeInfo(Config.DebugFormat).@"union".tag_type.? = x;
hh.add(tag);
switch (x) {
.strip, .code_view => {},
.dwarf => |f| hh.add(f),
}
}
pub fn hashCSource(self: *Cache.Manifest, c_source: CSourceFile) !void {
_ = try self.addFile(c_source.src_path, null);
// Hash the extra flags, with special care to call addFile for file parameters.
// TODO this logic can likely be improved by utilizing clang_options_data.zig.
const file_args = [_][]const u8{"-include"};
var arg_i: usize = 0;
while (arg_i < c_source.extra_flags.len) : (arg_i += 1) {
const arg = c_source.extra_flags[arg_i];
self.hash.addBytes(arg);
for (file_args) |file_arg| {
if (mem.eql(u8, file_arg, arg) and arg_i + 1 < c_source.extra_flags.len) {
arg_i += 1;
_ = try self.addFile(c_source.extra_flags[arg_i], null);
}
}
}
}
};
pub const ClangPreprocessorMode = enum {
no,
/// This means we are doing `zig cc -E -o <path>`.
yes,
/// This means we are doing `zig cc -E`.
stdout,
/// precompiled C header
pch,
};
pub const Framework = link.File.MachO.Framework;
pub const SystemLib = link.SystemLib;
pub const CacheMode = enum { incremental, whole };
pub const ParentWholeCache = struct {
manifest: *Cache.Manifest,
mutex: *std.Thread.Mutex,
prefix_map: [4]u8,
};
const CacheUse = union(CacheMode) {
incremental: *Incremental,
whole: *Whole,
const Whole = struct {
/// This is a pointer to a local variable inside `update()`.
cache_manifest: ?*Cache.Manifest = null,
cache_manifest_mutex: std.Thread.Mutex = .{},
/// null means -fno-emit-bin.
/// This is mutable memory allocated into the Compilation-lifetime arena (`arena`)
/// of exactly the correct size for "o/[digest]/[basename]".
/// The basename is of the outputted binary file in case we don't know the directory yet.
bin_sub_path: ?[]u8,
/// Same as `bin_sub_path` but for implibs.
implib_sub_path: ?[]u8,
docs_sub_path: ?[]u8,
lf_open_opts: link.File.OpenOptions,
tmp_artifact_directory: ?Cache.Directory,
/// Prevents other processes from clobbering files in the output directory.
lock: ?Cache.Lock,
fn releaseLock(whole: *Whole) void {
if (whole.lock) |*lock| {
lock.release();
whole.lock = null;
}
}
fn moveLock(whole: *Whole) Cache.Lock {
const result = whole.lock.?;
whole.lock = null;
return result;
}
};
const Incremental = struct {
/// Where build artifacts and incremental compilation metadata serialization go.
artifact_directory: Cache.Directory,
};
fn deinit(cu: CacheUse) void {
switch (cu) {
.incremental => |incremental| {
incremental.artifact_directory.handle.close();
},
.whole => |whole| {
whole.releaseLock();
},
}
}
};
pub const CreateOptions = struct {
dirs: Directories,
thread_pool: *ThreadPool,
self_exe_path: ?[]const u8 = null,
/// Options that have been resolved by calling `resolveDefaults`.
config: Compilation.Config,
root_mod: *Package.Module,
/// Normally, `main_mod` and `root_mod` are the same. The exception is `zig
/// test`, in which `root_mod` is the test runner, and `main_mod` is the
/// user's source file which has the tests.
main_mod: ?*Package.Module = null,
/// This is provided so that the API user has a chance to tweak the
/// per-module settings of the standard library.
/// When this is null, a default configuration of the std lib is created
/// based on the settings of root_mod.
std_mod: ?*Package.Module = null,
root_name: []const u8,
sysroot: ?[]const u8 = null,
/// `null` means to not emit a binary file.
emit_bin: ?EmitLoc,
/// `null` means to not emit a C header file.
emit_h: ?EmitLoc = null,
/// `null` means to not emit assembly.
emit_asm: ?EmitLoc = null,
/// `null` means to not emit LLVM IR.
emit_llvm_ir: ?EmitLoc = null,
/// `null` means to not emit LLVM module bitcode.
emit_llvm_bc: ?EmitLoc = null,
/// `null` means to not emit docs.
emit_docs: ?EmitLoc = null,
/// `null` means to not emit an import lib.
emit_implib: ?EmitLoc = null,
/// Normally when using LLD to link, Zig uses a file named "lld.id" in the
/// same directory as the output binary which contains the hash of the link
/// operation, allowing Zig to skip linking when the hash would be unchanged.
/// In the case that the output binary is being emitted into a directory which
/// is externally modified - essentially anything other than zig-cache - then
/// this flag would be set to disable this machinery to avoid false positives.
disable_lld_caching: bool = false,
cache_mode: CacheMode = .incremental,
/// This field is intended to be removed.
/// The ELF implementation no longer uses this data, however the MachO and COFF
/// implementations still do.
lib_directories: []const Cache.Directory = &.{},
rpath_list: []const []const u8 = &[0][]const u8{},
symbol_wrap_set: std.StringArrayHashMapUnmanaged(void) = .empty,
c_source_files: []const CSourceFile = &.{},
rc_source_files: []const RcSourceFile = &.{},
manifest_file: ?[]const u8 = null,
rc_includes: RcIncludes = .any,
link_inputs: []const link.Input = &.{},
framework_dirs: []const []const u8 = &[0][]const u8{},
frameworks: []const Framework = &.{},
windows_lib_names: []const []const u8 = &.{},
/// These correspond to the WASI libc emulated subcomponents including:
/// * process clocks
/// * getpid
/// * mman
/// * signal
wasi_emulated_libs: []const wasi_libc.CrtFile = &.{},
/// This means that if the output mode is an executable it will be a
/// Position Independent Executable. If the output mode is not an
/// executable this field is ignored.
want_compiler_rt: ?bool = null,
want_ubsan_rt: ?bool = null,
function_sections: bool = false,
data_sections: bool = false,
time_report: bool = false,
stack_report: bool = false,
link_eh_frame_hdr: bool = false,
link_emit_relocs: bool = false,
linker_script: ?[]const u8 = null,
version_script: ?[]const u8 = null,
linker_allow_undefined_version: bool = false,
linker_enable_new_dtags: ?bool = null,
soname: ?[]const u8 = null,
linker_gc_sections: ?bool = null,
linker_repro: ?bool = null,
linker_allow_shlib_undefined: ?bool = null,
linker_bind_global_refs_locally: ?bool = null,
linker_import_symbols: bool = false,
linker_import_table: bool = false,
linker_export_table: bool = false,
linker_initial_memory: ?u64 = null,
linker_max_memory: ?u64 = null,
linker_global_base: ?u64 = null,
linker_export_symbol_names: []const []const u8 = &.{},
linker_print_gc_sections: bool = false,
linker_print_icf_sections: bool = false,
linker_print_map: bool = false,
llvm_opt_bisect_limit: i32 = -1,
build_id: ?std.zig.BuildId = null,
disable_c_depfile: bool = false,
linker_z_nodelete: bool = false,
linker_z_notext: bool = false,
linker_z_defs: bool = false,
linker_z_origin: bool = false,
linker_z_now: bool = true,
linker_z_relro: bool = true,
linker_z_nocopyreloc: bool = false,
linker_z_common_page_size: ?u64 = null,
linker_z_max_page_size: ?u64 = null,
linker_tsaware: bool = false,
linker_nxcompat: bool = false,
linker_dynamicbase: bool = true,
linker_compress_debug_sections: ?link.File.Lld.Elf.CompressDebugSections = null,
linker_module_definition_file: ?[]const u8 = null,
linker_sort_section: ?link.File.Lld.Elf.SortSection = null,
major_subsystem_version: ?u16 = null,
minor_subsystem_version: ?u16 = null,
clang_passthrough_mode: bool = false,
verbose_cc: bool = false,
verbose_link: bool = false,
verbose_air: bool = false,
verbose_intern_pool: bool = false,
verbose_generic_instances: bool = false,
verbose_llvm_ir: ?[]const u8 = null,
verbose_llvm_bc: ?[]const u8 = null,
verbose_cimport: bool = false,
verbose_llvm_cpu_features: bool = false,
debug_compiler_runtime_libs: bool = false,
debug_compile_errors: bool = false,
debug_incremental: bool = false,
incremental: bool = false,
/// Normally when you create a `Compilation`, Zig will automatically build
/// and link in required dependencies, such as compiler-rt and libc. When
/// building such dependencies themselves, this flag must be set to avoid
/// infinite recursion.
skip_linker_dependencies: bool = false,
hash_style: link.File.Lld.Elf.HashStyle = .both,
entry: Entry = .default,
force_undefined_symbols: std.StringArrayHashMapUnmanaged(void) = .empty,
stack_size: ?u64 = null,
image_base: ?u64 = null,
version: ?std.SemanticVersion = null,
compatibility_version: ?std.SemanticVersion = null,
libc_installation: ?*const LibCInstallation = null,
native_system_include_paths: []const []const u8 = &.{},
clang_preprocessor_mode: ClangPreprocessorMode = .no,
reference_trace: ?u32 = null,
test_filters: []const []const u8 = &.{},
test_name_prefix: ?[]const u8 = null,
test_runner_path: ?[]const u8 = null,
subsystem: ?std.Target.SubSystem = null,
mingw_unicode_entry_point: bool = false,
/// (Zig compiler development) Enable dumping linker's state as JSON.
enable_link_snapshots: bool = false,
/// (Darwin) Install name of the dylib
install_name: ?[]const u8 = null,
/// (Darwin) Path to entitlements file
entitlements: ?[]const u8 = null,
/// (Darwin) size of the __PAGEZERO segment
pagezero_size: ?u64 = null,
/// (Darwin) set minimum space for future expansion of the load commands
headerpad_size: ?u32 = null,
/// (Darwin) set enough space as if all paths were MATPATHLEN
headerpad_max_install_names: bool = false,
/// (Darwin) remove dylibs that are unreachable by the entry point or exported symbols
dead_strip_dylibs: bool = false,
/// (Darwin) Force load all members of static archives that implement an Objective-C class or category
force_load_objc: bool = false,
/// Whether local symbols should be discarded from the symbol table.
discard_local_symbols: bool = false,
/// (Windows) PDB source path prefix to instruct the linker how to resolve relative
/// paths when consolidating CodeView streams into a single PDB file.
pdb_source_path: ?[]const u8 = null,
/// (Windows) PDB output path
pdb_out_path: ?[]const u8 = null,
error_limit: ?Zcu.ErrorInt = null,
global_cc_argv: []const []const u8 = &.{},
/// Tracks all files that can cause the Compilation to be invalidated and need a rebuild.
file_system_inputs: ?*std.ArrayListUnmanaged(u8) = null,
parent_whole_cache: ?ParentWholeCache = null,
pub const Entry = link.File.OpenOptions.Entry;
};
fn addModuleTableToCacheHash(
zcu: *Zcu,
arena: Allocator,
hash: *Cache.HashHelper,
hash_type: union(enum) { path_bytes, files: *Cache.Manifest },
) error{
OutOfMemory,
Unexpected,
CurrentWorkingDirectoryUnlinked,
}!void {
assert(zcu.module_roots.count() != 0); // module_roots is populated
for (zcu.module_roots.keys(), zcu.module_roots.values()) |mod, opt_mod_root_file| {
if (mod == zcu.std_mod) continue; // redundant
if (opt_mod_root_file.unwrap()) |mod_root_file| {
if (zcu.fileByIndex(mod_root_file).is_builtin) continue; // redundant
}
cache_helpers.addModule(hash, mod);
switch (hash_type) {
.path_bytes => {
hash.add(mod.root.root);
hash.addBytes(mod.root.sub_path);
hash.addBytes(mod.root_src_path);
},
.files => |man| if (mod.root_src_path.len != 0) {
const root_src_path = try mod.root.toCachePath(zcu.comp.dirs).join(arena, mod.root_src_path);
_ = try man.addFilePath(root_src_path, null);
},
}
hash.addListOfBytes(mod.deps.keys());
}
}
const RtStrat = enum { none, lib, obj, zcu };
pub fn create(gpa: Allocator, arena: Allocator, options: CreateOptions) !*Compilation {
const output_mode = options.config.output_mode;
const is_dyn_lib = switch (output_mode) {
.Obj, .Exe => false,
.Lib => options.config.link_mode == .dynamic,
};
const is_exe_or_dyn_lib = switch (output_mode) {
.Obj => false,
.Lib => is_dyn_lib,
.Exe => true,
};
if (options.linker_export_table and options.linker_import_table) {
return error.ExportTableAndImportTableConflict;
}
const have_zcu = options.config.have_zcu;
const comp: *Compilation = comp: {
// We put the `Compilation` itself in the arena. Freeing the arena will free the module.
// It's initialized later after we prepare the initialization options.
const root_name = try arena.dupeZ(u8, options.root_name);
const use_llvm = options.config.use_llvm;
// The "any" values provided by resolved config only account for
// explicitly-provided settings. We now make them additionally account
// for default setting resolution.
const any_unwind_tables = options.config.any_unwind_tables or options.root_mod.unwind_tables != .none;
const any_non_single_threaded = options.config.any_non_single_threaded or !options.root_mod.single_threaded;
const any_sanitize_thread = options.config.any_sanitize_thread or options.root_mod.sanitize_thread;
const any_sanitize_c: std.zig.SanitizeC = switch (options.config.any_sanitize_c) {
.off => options.root_mod.sanitize_c,
.trap => if (options.root_mod.sanitize_c == .full)
.full
else
.trap,
.full => .full,
};
const any_fuzz = options.config.any_fuzz or options.root_mod.fuzz;
const link_eh_frame_hdr = options.link_eh_frame_hdr or any_unwind_tables;
const build_id = options.build_id orelse .none;
const link_libc = options.config.link_libc;
const libc_dirs = try std.zig.LibCDirs.detect(
arena,
options.dirs.zig_lib.path.?,
options.root_mod.resolved_target.result,
options.root_mod.resolved_target.is_native_abi,
link_libc,
options.libc_installation,
);
const sysroot = options.sysroot orelse libc_dirs.sysroot;
const compiler_rt_strat: RtStrat = s: {
if (options.skip_linker_dependencies) break :s .none;
const want = options.want_compiler_rt orelse is_exe_or_dyn_lib;
if (!want) break :s .none;
if (have_zcu and output_mode == .Obj) break :s .zcu;
if (is_exe_or_dyn_lib) break :s .lib;
break :s .obj;
};
if (compiler_rt_strat == .zcu) {
// For objects, this mechanism relies on essentially `_ = @import("compiler-rt");`
// injected into the object.
const compiler_rt_mod = try Package.Module.create(arena, .{
.paths = .{
.root = .zig_lib_root,
.root_src_path = "compiler_rt.zig",
},
.fully_qualified_name = "compiler_rt",
.cc_argv = &.{},
.inherited = .{
.stack_check = false,
.stack_protector = 0,
.no_builtin = true,
},
.global = options.config,
.parent = options.root_mod,
});
try options.root_mod.deps.putNoClobber(arena, "compiler_rt", compiler_rt_mod);
}
// unlike compiler_rt, we always want to go through the `_ = @import("ubsan-rt")`
// approach, since the ubsan runtime uses quite a lot of the standard library
// and this reduces unnecessary bloat.
const ubsan_rt_strat: RtStrat = s: {
const can_build_ubsan_rt = target_util.canBuildLibUbsanRt(options.root_mod.resolved_target.result);
const want_ubsan_rt = options.want_ubsan_rt orelse (can_build_ubsan_rt and any_sanitize_c == .full and is_exe_or_dyn_lib);
if (!want_ubsan_rt) break :s .none;
if (options.skip_linker_dependencies) break :s .none;
if (have_zcu) break :s .zcu;
if (is_exe_or_dyn_lib) break :s .lib;
break :s .obj;
};
if (ubsan_rt_strat == .zcu) {
const ubsan_rt_mod = try Package.Module.create(arena, .{
.paths = .{
.root = .zig_lib_root,
.root_src_path = "ubsan_rt.zig",
},
.fully_qualified_name = "ubsan_rt",
.cc_argv = &.{},
.inherited = .{},
.global = options.config,
.parent = options.root_mod,
});
try options.root_mod.deps.putNoClobber(arena, "ubsan_rt", ubsan_rt_mod);
}
if (options.verbose_llvm_cpu_features) {
if (options.root_mod.resolved_target.llvm_cpu_features) |cf| print: {
const target = options.root_mod.resolved_target.result;
std.debug.lockStdErr();
defer std.debug.unlockStdErr();
const stderr = std.io.getStdErr().writer();
nosuspend {
stderr.print("compilation: {s}\n", .{options.root_name}) catch break :print;
stderr.print(" target: {s}\n", .{try target.zigTriple(arena)}) catch break :print;
stderr.print(" cpu: {s}\n", .{target.cpu.model.name}) catch break :print;
stderr.print(" features: {s}\n", .{cf}) catch {};
}
}
}
const error_limit = options.error_limit orelse (std.math.maxInt(u16) - 1);
// We put everything into the cache hash that *cannot be modified
// during an incremental update*. For example, one cannot change the
// target between updates, but one can change source files, so the
// target goes into the cache hash, but source files do not. This is so
// that we can find the same binary and incrementally update it even if
// there are modified source files. We do this even if outputting to
// the current directory because we need somewhere to store incremental
// compilation metadata.
const cache = try arena.create(Cache);
cache.* = .{
.gpa = gpa,
.manifest_dir = try options.dirs.local_cache.handle.makeOpenPath("h", .{}),
};
// These correspond to std.zig.Server.Message.PathPrefix.
cache.addPrefix(.{ .path = null, .handle = std.fs.cwd() });
cache.addPrefix(options.dirs.zig_lib);
cache.addPrefix(options.dirs.local_cache);
cache.addPrefix(options.dirs.global_cache);
errdefer cache.manifest_dir.close();
// This is shared hasher state common to zig source and all C source files.
cache.hash.addBytes(build_options.version);
cache.hash.add(builtin.zig_backend);
cache.hash.add(options.config.pie);
cache.hash.add(options.config.lto);
cache.hash.add(options.config.link_mode);
cache.hash.add(options.config.any_unwind_tables);
cache.hash.add(options.config.any_non_single_threaded);
cache.hash.add(options.config.any_sanitize_thread);
cache.hash.add(options.config.any_sanitize_c);
cache.hash.add(options.config.any_fuzz);
cache.hash.add(options.function_sections);
cache.hash.add(options.data_sections);
cache.hash.add(link_libc);
cache.hash.add(options.config.link_libcpp);
cache.hash.add(options.config.link_libunwind);
cache.hash.add(output_mode);
cache_helpers.addDebugFormat(&cache.hash, options.config.debug_format);
cache_helpers.addOptionalEmitLoc(&cache.hash, options.emit_bin);
cache_helpers.addOptionalEmitLoc(&cache.hash, options.emit_implib);
cache_helpers.addOptionalEmitLoc(&cache.hash, options.emit_docs);
cache.hash.addBytes(options.root_name);
cache.hash.add(options.config.wasi_exec_model);
cache.hash.add(options.config.san_cov_trace_pc_guard);
cache.hash.add(options.debug_compiler_runtime_libs);
// TODO audit this and make sure everything is in it
const main_mod = options.main_mod orelse options.root_mod;
const comp = try arena.create(Compilation);
const opt_zcu: ?*Zcu = if (have_zcu) blk: {
// Pre-open the directory handles for cached ZIR code so that it does not need
// to redundantly happen for each AstGen operation.
const zir_sub_dir = "z";
var local_zir_dir = try options.dirs.local_cache.handle.makeOpenPath(zir_sub_dir, .{});
errdefer local_zir_dir.close();
const local_zir_cache: Cache.Directory = .{
.handle = local_zir_dir,
.path = try options.dirs.local_cache.join(arena, &.{zir_sub_dir}),
};
var global_zir_dir = try options.dirs.global_cache.handle.makeOpenPath(zir_sub_dir, .{});
errdefer global_zir_dir.close();
const global_zir_cache: Cache.Directory = .{
.handle = global_zir_dir,
.path = try options.dirs.global_cache.join(arena, &.{zir_sub_dir}),
};
const std_mod = options.std_mod orelse try Package.Module.create(arena, .{
.paths = .{
.root = try .fromRoot(arena, options.dirs, .zig_lib, "std"),
.root_src_path = "std.zig",
},
.fully_qualified_name = "std",
.cc_argv = &.{},
.inherited = .{},
.global = options.config,
.parent = options.root_mod,
});
const zcu = try arena.create(Zcu);
zcu.* = .{
.gpa = gpa,
.comp = comp,
.main_mod = main_mod,
.root_mod = options.root_mod,
.std_mod = std_mod,
.global_zir_cache = global_zir_cache,
.local_zir_cache = local_zir_cache,
.error_limit = error_limit,
.llvm_object = null,
};
try zcu.init(options.thread_pool.getIdCount());
break :blk zcu;
} else blk: {
if (options.emit_h != null) return error.NoZigModuleForCHeader;
break :blk null;
};
errdefer if (opt_zcu) |zcu| zcu.deinit();
var windows_libs = try std.StringArrayHashMapUnmanaged(void).init(gpa, options.windows_lib_names, &.{});
errdefer windows_libs.deinit(gpa);
comp.* = .{
.gpa = gpa,
.arena = arena,
.zcu = opt_zcu,
.cache_use = undefined, // populated below
.bin_file = null, // populated below
.implib_emit = null, // handled below
.docs_emit = null, // handled below
.root_mod = options.root_mod,
.config = options.config,
.dirs = options.dirs,
.emit_asm = options.emit_asm,
.emit_llvm_ir = options.emit_llvm_ir,
.emit_llvm_bc = options.emit_llvm_bc,
.work_queues = @splat(.init(gpa)),
.c_object_work_queue = std.fifo.LinearFifo(*CObject, .Dynamic).init(gpa),
.win32_resource_work_queue = if (dev.env.supports(.win32_resource)) std.fifo.LinearFifo(*Win32Resource, .Dynamic).init(gpa) else .{},
.c_source_files = options.c_source_files,
.rc_source_files = options.rc_source_files,
.cache_parent = cache,
.self_exe_path = options.self_exe_path,
.libc_include_dir_list = libc_dirs.libc_include_dir_list,
.libc_framework_dir_list = libc_dirs.libc_framework_dir_list,
.rc_includes = options.rc_includes,
.mingw_unicode_entry_point = options.mingw_unicode_entry_point,
.thread_pool = options.thread_pool,
.clang_passthrough_mode = options.clang_passthrough_mode,
.clang_preprocessor_mode = options.clang_preprocessor_mode,
.verbose_cc = options.verbose_cc,
.verbose_air = options.verbose_air,
.verbose_intern_pool = options.verbose_intern_pool,
.verbose_generic_instances = options.verbose_generic_instances,
.verbose_llvm_ir = options.verbose_llvm_ir,
.verbose_llvm_bc = options.verbose_llvm_bc,
.verbose_cimport = options.verbose_cimport,
.verbose_llvm_cpu_features = options.verbose_llvm_cpu_features,
.verbose_link = options.verbose_link,
.disable_c_depfile = options.disable_c_depfile,
.reference_trace = options.reference_trace,
.time_report = options.time_report,
.stack_report = options.stack_report,
.test_filters = options.test_filters,
.test_name_prefix = options.test_name_prefix,
.debug_compiler_runtime_libs = options.debug_compiler_runtime_libs,
.debug_compile_errors = options.debug_compile_errors,
.debug_incremental = options.debug_incremental,
.incremental = options.incremental,
.root_name = root_name,
.sysroot = sysroot,
.windows_libs = windows_libs,
.version = options.version,
.libc_installation = libc_dirs.libc_installation,
.compiler_rt_strat = compiler_rt_strat,
.ubsan_rt_strat = ubsan_rt_strat,
.link_inputs = options.link_inputs,
.framework_dirs = options.framework_dirs,
.llvm_opt_bisect_limit = options.llvm_opt_bisect_limit,
.skip_linker_dependencies = options.skip_linker_dependencies,
.queued_jobs = .{},
.function_sections = options.function_sections,
.data_sections = options.data_sections,
.native_system_include_paths = options.native_system_include_paths,
.wasi_emulated_libs = options.wasi_emulated_libs,
.force_undefined_symbols = options.force_undefined_symbols,
.link_eh_frame_hdr = link_eh_frame_hdr,
.global_cc_argv = options.global_cc_argv,
.file_system_inputs = options.file_system_inputs,
.parent_whole_cache = options.parent_whole_cache,
.link_diags = .init(gpa),
};
// Prevent some footguns by making the "any" fields of config reflect
// the default Module settings.
comp.config.any_unwind_tables = any_unwind_tables;
comp.config.any_non_single_threaded = any_non_single_threaded;
comp.config.any_sanitize_thread = any_sanitize_thread;
comp.config.any_sanitize_c = any_sanitize_c;
comp.config.any_fuzz = any_fuzz;
if (opt_zcu) |zcu| {
// Populate `zcu.module_roots`.
const pt: Zcu.PerThread = .activate(zcu, .main);
defer pt.deactivate();
try pt.populateModuleRootTable();
}
const lf_open_opts: link.File.OpenOptions = .{
.linker_script = options.linker_script,
.z_nodelete = options.linker_z_nodelete,
.z_notext = options.linker_z_notext,
.z_defs = options.linker_z_defs,
.z_origin = options.linker_z_origin,
.z_nocopyreloc = options.linker_z_nocopyreloc,
.z_now = options.linker_z_now,
.z_relro = options.linker_z_relro,
.z_common_page_size = options.linker_z_common_page_size,
.z_max_page_size = options.linker_z_max_page_size,
.darwin_sdk_layout = libc_dirs.darwin_sdk_layout,
.frameworks = options.frameworks,
.lib_directories = options.lib_directories,
.framework_dirs = options.framework_dirs,
.rpath_list = options.rpath_list,
.symbol_wrap_set = options.symbol_wrap_set,
.repro = options.linker_repro orelse (options.root_mod.optimize_mode != .Debug),
.allow_shlib_undefined = options.linker_allow_shlib_undefined,
.bind_global_refs_locally = options.linker_bind_global_refs_locally orelse false,
.compress_debug_sections = options.linker_compress_debug_sections orelse .none,
.module_definition_file = options.linker_module_definition_file,
.sort_section = options.linker_sort_section,
.import_symbols = options.linker_import_symbols,
.import_table = options.linker_import_table,
.export_table = options.linker_export_table,
.initial_memory = options.linker_initial_memory,
.max_memory = options.linker_max_memory,
.global_base = options.linker_global_base,
.export_symbol_names = options.linker_export_symbol_names,
.print_gc_sections = options.linker_print_gc_sections,
.print_icf_sections = options.linker_print_icf_sections,
.print_map = options.linker_print_map,
.tsaware = options.linker_tsaware,
.nxcompat = options.linker_nxcompat,
.dynamicbase = options.linker_dynamicbase,
.major_subsystem_version = options.major_subsystem_version,
.minor_subsystem_version = options.minor_subsystem_version,
.entry = options.entry,
.stack_size = options.stack_size,
.image_base = options.image_base,
.version_script = options.version_script,
.allow_undefined_version = options.linker_allow_undefined_version,
.enable_new_dtags = options.linker_enable_new_dtags,
.gc_sections = options.linker_gc_sections,
.emit_relocs = options.link_emit_relocs,
.soname = options.soname,
.compatibility_version = options.compatibility_version,
.build_id = build_id,
.disable_lld_caching = options.disable_lld_caching or options.cache_mode == .whole,
.subsystem = options.subsystem,
.hash_style = options.hash_style,
.enable_link_snapshots = options.enable_link_snapshots,
.install_name = options.install_name,
.entitlements = options.entitlements,
.pagezero_size = options.pagezero_size,
.headerpad_size = options.headerpad_size,
.headerpad_max_install_names = options.headerpad_max_install_names,
.dead_strip_dylibs = options.dead_strip_dylibs,
.force_load_objc = options.force_load_objc,
.discard_local_symbols = options.discard_local_symbols,
.pdb_source_path = options.pdb_source_path,
.pdb_out_path = options.pdb_out_path,
.entry_addr = null, // CLI does not expose this option (yet?)
.object_host_name = "env",
};
switch (options.cache_mode) {
.incremental => {
// Options that are specific to zig source files, that cannot be
// modified between incremental updates.
var hash = cache.hash;
// Synchronize with other matching comments: ZigOnlyHashStuff
hash.add(use_llvm);
hash.add(options.config.use_lib_llvm);
hash.add(options.config.dll_export_fns);
hash.add(options.config.is_test);
hash.addListOfBytes(options.test_filters);
hash.addOptionalBytes(options.test_name_prefix);
hash.add(options.skip_linker_dependencies);
hash.add(options.emit_h != null);
hash.add(error_limit);
// Here we put the root source file path name, but *not* with addFile.
// We want the hash to be the same regardless of the contents of the
// source file, because incremental compilation will handle it, but we
// do want to namespace different source file names because they are
// likely different compilations and therefore this would be likely to
// cause cache hits.
if (comp.zcu) |zcu| {
try addModuleTableToCacheHash(zcu, arena, &hash, .path_bytes);
} else {
cache_helpers.addModule(&hash, options.root_mod);
}
// In the case of incremental cache mode, this `artifact_directory`
// is computed based on a hash of non-linker inputs, and it is where all
// build artifacts are stored (even while in-progress).
comp.digest = hash.peekBin();
const digest = hash.final();
const artifact_sub_dir = "o" ++ std.fs.path.sep_str ++ digest;
var artifact_dir = try options.dirs.local_cache.handle.makeOpenPath(artifact_sub_dir, .{});
errdefer artifact_dir.close();
const artifact_directory: Cache.Directory = .{
.handle = artifact_dir,
.path = try options.dirs.local_cache.join(arena, &.{artifact_sub_dir}),
};
const incremental = try arena.create(CacheUse.Incremental);
incremental.* = .{
.artifact_directory = artifact_directory,
};
comp.cache_use = .{ .incremental = incremental };
if (options.emit_bin) |emit_bin| {
const emit: Cache.Path = .{
.root_dir = emit_bin.directory orelse artifact_directory,
.sub_path = emit_bin.basename,
};
comp.bin_file = try link.File.open(arena, comp, emit, lf_open_opts);
}
if (options.emit_implib) |emit_implib| {
comp.implib_emit = .{
.root_dir = emit_implib.directory orelse artifact_directory,
.sub_path = emit_implib.basename,
};
}
if (options.emit_docs) |emit_docs| {
comp.docs_emit = .{
.root_dir = emit_docs.directory orelse artifact_directory,
.sub_path = emit_docs.basename,
};
}
},
.whole => {
// For whole cache mode, we don't know where to put outputs from
// the linker until the final cache hash, which is available after
// the compilation is complete.
//
// Therefore, bin_file is left null until the beginning of update(),
// where it may find a cache hit, or use a temporary directory to
// hold output artifacts.
const whole = try arena.create(CacheUse.Whole);
whole.* = .{
// This is kept here so that link.File.open can be called later.
.lf_open_opts = lf_open_opts,
// This is so that when doing `CacheMode.whole`, the mechanism in update()
// can use it for communicating the result directory via `bin_file.emit`.
// This is used to distinguish between -fno-emit-bin and -femit-bin
// for `CacheMode.whole`.
// This memory will be overwritten with the real digest in update() but
// the basename will be preserved.
.bin_sub_path = try prepareWholeEmitSubPath(arena, options.emit_bin),
.implib_sub_path = try prepareWholeEmitSubPath(arena, options.emit_implib),
.docs_sub_path = try prepareWholeEmitSubPath(arena, options.emit_docs),
.tmp_artifact_directory = null,
.lock = null,
};
comp.cache_use = .{ .whole = whole };
},
}
if (use_llvm) {
if (opt_zcu) |zcu| {
zcu.llvm_object = try LlvmObject.create(arena, comp);
}
}
break :comp comp;
};
errdefer comp.destroy();
const target = comp.root_mod.resolved_target.result;
const can_build_compiler_rt = target_util.canBuildLibCompilerRt(target, comp.config.use_llvm, build_options.have_llvm);
// Add a `CObject` for each `c_source_files`.
try comp.c_object_table.ensureTotalCapacity(gpa, options.c_source_files.len);
for (options.c_source_files) |c_source_file| {
const c_object = try gpa.create(CObject);
errdefer gpa.destroy(c_object);
c_object.* = .{
.status = .{ .new = {} },
.src = c_source_file,
};
comp.c_object_table.putAssumeCapacityNoClobber(c_object, {});
}
comp.link_task_queue.pending_prelink_tasks += @intCast(comp.c_object_table.count());
// Add a `Win32Resource` for each `rc_source_files` and one for `manifest_file`.
const win32_resource_count =
options.rc_source_files.len + @intFromBool(options.manifest_file != null);
if (win32_resource_count > 0) {
dev.check(.win32_resource);
try comp.win32_resource_table.ensureTotalCapacity(gpa, win32_resource_count);
// Add this after adding logic to updateWin32Resource to pass the
// result into link.loadInput. loadInput integration is not implemented
// for Windows linking logic yet.
//comp.link_task_queue.pending_prelink_tasks += @intCast(win32_resource_count);
for (options.rc_source_files) |rc_source_file| {
const win32_resource = try gpa.create(Win32Resource);
errdefer gpa.destroy(win32_resource);
win32_resource.* = .{
.status = .{ .new = {} },
.src = .{ .rc = rc_source_file },
};
comp.win32_resource_table.putAssumeCapacityNoClobber(win32_resource, {});
}
if (options.manifest_file) |manifest_path| {
const win32_resource = try gpa.create(Win32Resource);
errdefer gpa.destroy(win32_resource);
win32_resource.* = .{
.status = .{ .new = {} },
.src = .{ .manifest = manifest_path },
};
comp.win32_resource_table.putAssumeCapacityNoClobber(win32_resource, {});
}
}
const have_bin_emit = switch (comp.cache_use) {
.whole => |whole| whole.bin_sub_path != null,
.incremental => comp.bin_file != null,
};
if (have_bin_emit and target.ofmt != .c) {
if (!comp.skip_linker_dependencies) {
// If we need to build libc for the target, add work items for it.
// We go through the work queue so that building can be done in parallel.
// If linking against host libc installation, instead queue up jobs
// for loading those files in the linker.
if (comp.config.link_libc and is_exe_or_dyn_lib) {
// If the "is darwin" check is moved below the libc_installation check below,
// error.LibCInstallationMissingCrtDir is returned from lci.resolveCrtPaths().
if (target.isDarwinLibC()) {
// TODO delete logic from MachO flush() and queue up tasks here instead.
} else if (comp.libc_installation) |lci| {
const basenames = LibCInstallation.CrtBasenames.get(.{
.target = target,
.link_libc = comp.config.link_libc,
.output_mode = comp.config.output_mode,
.link_mode = comp.config.link_mode,
.pie = comp.config.pie,
});
const paths = try lci.resolveCrtPaths(arena, basenames, target);
const fields = @typeInfo(@TypeOf(paths)).@"struct".fields;
try comp.link_task_queue.queued_prelink.ensureUnusedCapacity(gpa, fields.len + 1);
inline for (fields) |field| {
if (@field(paths, field.name)) |path| {
comp.link_task_queue.queued_prelink.appendAssumeCapacity(.{ .load_object = path });
}
}
// Loads the libraries provided by `target_util.libcFullLinkFlags(target)`.
comp.link_task_queue.queued_prelink.appendAssumeCapacity(.load_host_libc);
} else if (target.isMuslLibC()) {
if (!std.zig.target.canBuildLibC(target)) return error.LibCUnavailable;
if (musl.needsCrt0(comp.config.output_mode, comp.config.link_mode, comp.config.pie)) |f| {
comp.queued_jobs.musl_crt_file[@intFromEnum(f)] = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
switch (comp.config.link_mode) {
.static => comp.queued_jobs.musl_crt_file[@intFromEnum(musl.CrtFile.libc_a)] = true,
.dynamic => comp.queued_jobs.musl_crt_file[@intFromEnum(musl.CrtFile.libc_so)] = true,
}
comp.link_task_queue.pending_prelink_tasks += 1;
} else if (target.isGnuLibC()) {
if (!std.zig.target.canBuildLibC(target)) return error.LibCUnavailable;
if (glibc.needsCrt0(comp.config.output_mode)) |f| {
comp.queued_jobs.glibc_crt_file[@intFromEnum(f)] = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
comp.queued_jobs.glibc_shared_objects = true;
comp.link_task_queue.pending_prelink_tasks += glibc.sharedObjectsCount(&target);
comp.queued_jobs.glibc_crt_file[@intFromEnum(glibc.CrtFile.libc_nonshared_a)] = true;
comp.link_task_queue.pending_prelink_tasks += 1;
} else if (target.isFreeBSDLibC()) {
if (!std.zig.target.canBuildLibC(target)) return error.LibCUnavailable;
if (freebsd.needsCrt0(comp.config.output_mode)) |f| {
comp.queued_jobs.freebsd_crt_file[@intFromEnum(f)] = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
comp.queued_jobs.freebsd_shared_objects = true;
comp.link_task_queue.pending_prelink_tasks += freebsd.sharedObjectsCount();
} else if (target.isNetBSDLibC()) {
if (!std.zig.target.canBuildLibC(target)) return error.LibCUnavailable;
if (netbsd.needsCrt0(comp.config.output_mode)) |f| {
comp.queued_jobs.netbsd_crt_file[@intFromEnum(f)] = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
comp.queued_jobs.netbsd_shared_objects = true;
comp.link_task_queue.pending_prelink_tasks += netbsd.sharedObjectsCount();
} else if (target.isWasiLibC()) {
if (!std.zig.target.canBuildLibC(target)) return error.LibCUnavailable;
for (comp.wasi_emulated_libs) |crt_file| {
comp.queued_jobs.wasi_libc_crt_file[@intFromEnum(crt_file)] = true;
}
comp.link_task_queue.pending_prelink_tasks += @intCast(comp.wasi_emulated_libs.len);
comp.queued_jobs.wasi_libc_crt_file[@intFromEnum(wasi_libc.execModelCrtFile(comp.config.wasi_exec_model))] = true;
comp.queued_jobs.wasi_libc_crt_file[@intFromEnum(wasi_libc.CrtFile.libc_a)] = true;
comp.link_task_queue.pending_prelink_tasks += 2;
} else if (target.isMinGW()) {
if (!std.zig.target.canBuildLibC(target)) return error.LibCUnavailable;
const main_crt_file: mingw.CrtFile = if (is_dyn_lib) .dllcrt2_o else .crt2_o;
comp.queued_jobs.mingw_crt_file[@intFromEnum(main_crt_file)] = true;
comp.queued_jobs.mingw_crt_file[@intFromEnum(mingw.CrtFile.libmingw32_lib)] = true;
comp.link_task_queue.pending_prelink_tasks += 2;
// When linking mingw-w64 there are some import libs we always need.
try comp.windows_libs.ensureUnusedCapacity(gpa, mingw.always_link_libs.len);
for (mingw.always_link_libs) |name| comp.windows_libs.putAssumeCapacity(name, {});
} else {
return error.LibCUnavailable;
}
if ((target.isMuslLibC() and comp.config.link_mode == .static) or
target.isWasiLibC() or
target.isMinGW())
{
comp.queued_jobs.zigc_lib = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
}
// Generate Windows import libs.
if (target.os.tag == .windows) {
const count = comp.windows_libs.count();
for (0..count) |i| {
try comp.queueJob(.{ .windows_import_lib = i });
}
// when integrating coff linker with prelink, the above
// queueJob will need to change into something else since those
// jobs are dispatched *after* the link_task_wait_group.wait()
// that happens when separateCodegenThreadOk() is false.
}
if (comp.wantBuildLibUnwindFromSource()) {
comp.queued_jobs.libunwind = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
if (build_options.have_llvm and is_exe_or_dyn_lib and comp.config.link_libcpp) {
comp.queued_jobs.libcxx = true;
comp.queued_jobs.libcxxabi = true;
comp.link_task_queue.pending_prelink_tasks += 2;
}
if (build_options.have_llvm and is_exe_or_dyn_lib and comp.config.any_sanitize_thread) {
comp.queued_jobs.libtsan = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
if (can_build_compiler_rt) {
if (comp.compiler_rt_strat == .lib) {
log.debug("queuing a job to build compiler_rt_lib", .{});
comp.queued_jobs.compiler_rt_lib = true;
comp.link_task_queue.pending_prelink_tasks += 1;
} else if (comp.compiler_rt_strat == .obj) {
log.debug("queuing a job to build compiler_rt_obj", .{});
// In this case we are making a static library, so we ask
// for a compiler-rt object to put in it.
comp.queued_jobs.compiler_rt_obj = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
if (comp.ubsan_rt_strat == .lib) {
log.debug("queuing a job to build ubsan_rt_lib", .{});
comp.queued_jobs.ubsan_rt_lib = true;
comp.link_task_queue.pending_prelink_tasks += 1;
} else if (comp.ubsan_rt_strat == .obj) {
log.debug("queuing a job to build ubsan_rt_obj", .{});
comp.queued_jobs.ubsan_rt_obj = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
if (is_exe_or_dyn_lib and comp.config.any_fuzz) {
log.debug("queuing a job to build libfuzzer", .{});
comp.queued_jobs.fuzzer_lib = true;
comp.link_task_queue.pending_prelink_tasks += 1;
}
}
}
try comp.link_task_queue.queued_prelink.append(gpa, .load_explicitly_provided);
}
log.debug("queued prelink tasks: {d}", .{comp.link_task_queue.queued_prelink.items.len});
log.debug("pending prelink tasks: {d}", .{comp.link_task_queue.pending_prelink_tasks});
return comp;
}
pub fn destroy(comp: *Compilation) void {
const gpa = comp.gpa;
// This needs to be destroyed first, because it might contain MIR which we only know
// how to interpret (which kind of MIR it is) from `comp.bin_file`.
comp.link_task_queue.deinit(comp);
if (comp.bin_file) |lf| lf.destroy();
if (comp.zcu) |zcu| zcu.deinit();
comp.cache_use.deinit();
for (comp.work_queues) |work_queue| work_queue.deinit();
comp.c_object_work_queue.deinit();
comp.win32_resource_work_queue.deinit();
comp.windows_libs.deinit(gpa);
{
var it = comp.crt_files.iterator();
while (it.next()) |entry| {
gpa.free(entry.key_ptr.*);
entry.value_ptr.deinit(gpa);
}
comp.crt_files.deinit(gpa);
}
if (comp.libunwind_static_lib) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.libcxx_static_lib) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.libcxxabi_static_lib) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.compiler_rt_lib) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.compiler_rt_obj) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.ubsan_rt_lib) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.ubsan_rt_obj) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.fuzzer_lib) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.zigc_static_lib) |*crt_file| {
crt_file.deinit(gpa);
}
if (comp.glibc_so_files) |*glibc_file| {
glibc_file.deinit(gpa);
}
if (comp.freebsd_so_files) |*freebsd_file| {
freebsd_file.deinit(gpa);
}
if (comp.netbsd_so_files) |*netbsd_file| {
netbsd_file.deinit(gpa);
}
for (comp.c_object_table.keys()) |key| {
key.destroy(gpa);
}
comp.c_object_table.deinit(gpa);
for (comp.failed_c_objects.values()) |bundle| {
bundle.destroy(gpa);
}
comp.failed_c_objects.deinit(gpa);
for (comp.win32_resource_table.keys()) |key| {
key.destroy(gpa);
}
comp.win32_resource_table.deinit(gpa);
for (comp.failed_win32_resources.values()) |*value| {
value.deinit(gpa);
}
comp.failed_win32_resources.deinit(gpa);
comp.link_diags.deinit();
comp.clearMiscFailures();
comp.cache_parent.manifest_dir.close();
}
pub fn clearMiscFailures(comp: *Compilation) void {
comp.alloc_failure_occurred = false;
comp.link_diags.flags = .{};
for (comp.misc_failures.values()) |*value| {
value.deinit(comp.gpa);
}
comp.misc_failures.deinit(comp.gpa);
comp.misc_failures = .{};
}
pub fn getTarget(self: Compilation) Target {
return self.root_mod.resolved_target.result;
}
/// Only legal to call when cache mode is incremental and a link file is present.
pub fn hotCodeSwap(
comp: *Compilation,
prog_node: std.Progress.Node,
pid: std.process.Child.Id,
) !void {
const lf = comp.bin_file.?;
lf.child_pid = pid;
try lf.makeWritable();
try comp.update(prog_node);
try lf.makeExecutable();
}
fn cleanupAfterUpdate(comp: *Compilation) void {
switch (comp.cache_use) {
.incremental => return,
.whole => |whole| {
if (whole.cache_manifest) |man| {
man.deinit();
whole.cache_manifest = null;
}
if (comp.bin_file) |lf| {
lf.destroy();
comp.bin_file = null;
}
if (whole.tmp_artifact_directory) |*directory| {
directory.handle.close();
if (directory.path) |p| comp.gpa.free(p);
whole.tmp_artifact_directory = null;
}
},
}
}
/// Detect changes to source files, perform semantic analysis, and update the output files.
pub fn update(comp: *Compilation, main_progress_node: std.Progress.Node) !void {
const tracy_trace = trace(@src());
defer tracy_trace.end();
// This arena is scoped to this one update.
const gpa = comp.gpa;
var arena_allocator = std.heap.ArenaAllocator.init(gpa);
defer arena_allocator.deinit();
const arena = arena_allocator.allocator();
comp.clearMiscFailures();
comp.last_update_was_cache_hit = false;
var man: Cache.Manifest = undefined;
defer cleanupAfterUpdate(comp);
var tmp_dir_rand_int: u64 = undefined;
// If using the whole caching strategy, we check for *everything* up front, including
// C source files.
switch (comp.cache_use) {
.whole => |whole| {
assert(comp.bin_file == null);
// We are about to obtain this lock, so here we give other processes a chance first.
whole.releaseLock();
man = comp.cache_parent.obtain();
whole.cache_manifest = &man;
try addNonIncrementalStuffToCacheManifest(comp, arena, &man);
const is_hit = man.hit() catch |err| switch (err) {
error.CacheCheckFailed => switch (man.diagnostic) {
.none => unreachable,
.manifest_create, .manifest_read, .manifest_lock, .manifest_seek => |e| return comp.setMiscFailure(
.check_whole_cache,
"failed to check cache: {s} {s}",
.{ @tagName(man.diagnostic), @errorName(e) },
),
.file_open, .file_stat, .file_read, .file_hash => |op| {
const pp = man.files.keys()[op.file_index].prefixed_path;
const prefix = man.cache.prefixes()[pp.prefix];
return comp.setMiscFailure(
.check_whole_cache,
"failed to check cache: '{}{s}' {s} {s}",
.{ prefix, pp.sub_path, @tagName(man.diagnostic), @errorName(op.err) },
);
},
},
error.OutOfMemory => return error.OutOfMemory,
error.InvalidFormat => return comp.setMiscFailure(
.check_whole_cache,
"failed to check cache: invalid manifest file format",
.{},
),
};
if (is_hit) {
// In this case the cache hit contains the full set of file system inputs. Nice!
if (comp.file_system_inputs) |buf| try man.populateFileSystemInputs(buf);
if (comp.parent_whole_cache) |pwc| {
pwc.mutex.lock();
defer pwc.mutex.unlock();
try man.populateOtherManifest(pwc.manifest, pwc.prefix_map);
}
comp.last_update_was_cache_hit = true;
log.debug("CacheMode.whole cache hit for {s}", .{comp.root_name});
const bin_digest = man.finalBin();
const hex_digest = Cache.binToHex(bin_digest);
comp.digest = bin_digest;
comp.wholeCacheModeSetBinFilePath(whole, &hex_digest);
assert(whole.lock == null);
whole.lock = man.toOwnedLock();
return;
}
log.debug("CacheMode.whole cache miss for {s}", .{comp.root_name});
// Compile the artifacts to a temporary directory.
const tmp_artifact_directory: Cache.Directory = d: {
const s = std.fs.path.sep_str;
tmp_dir_rand_int = std.crypto.random.int(u64);
const tmp_dir_sub_path = "tmp" ++ s ++ std.fmt.hex(tmp_dir_rand_int);
const path = try comp.dirs.local_cache.join(gpa, &.{tmp_dir_sub_path});
errdefer gpa.free(path);
const handle = try comp.dirs.local_cache.handle.makeOpenPath(tmp_dir_sub_path, .{});
errdefer handle.close();
break :d .{
.path = path,
.handle = handle,
};
};
whole.tmp_artifact_directory = tmp_artifact_directory;
// Now that the directory is known, it is time to create the Emit
// objects and call link.File.open.
if (whole.implib_sub_path) |sub_path| {
comp.implib_emit = .{
.root_dir = tmp_artifact_directory,
.sub_path = std.fs.path.basename(sub_path),
};
}
if (whole.docs_sub_path) |sub_path| {
comp.docs_emit = .{
.root_dir = tmp_artifact_directory,
.sub_path = std.fs.path.basename(sub_path),
};
}
if (whole.bin_sub_path) |sub_path| {
const emit: Cache.Path = .{
.root_dir = tmp_artifact_directory,
.sub_path = std.fs.path.basename(sub_path),
};
comp.bin_file = try link.File.createEmpty(arena, comp, emit, whole.lf_open_opts);
}
},
.incremental => {
log.debug("Compilation.update for {s}, CacheMode.incremental", .{comp.root_name});
},
}
// From this point we add a preliminary set of file system inputs that
// affects both incremental and whole cache mode. For incremental cache
// mode, the long-lived compiler state will track additional file system
// inputs discovered after this point. For whole cache mode, we rely on
// these inputs to make it past AstGen, and once there, we can rely on
// learning file system inputs from the Cache object.
// For compiling C objects, we rely on the cache hash system to avoid duplicating work.
// Add a Job for each C object.
try comp.c_object_work_queue.ensureUnusedCapacity(comp.c_object_table.count());
for (comp.c_object_table.keys()) |c_object| {
comp.c_object_work_queue.writeItemAssumeCapacity(c_object);
try comp.appendFileSystemInput(try .fromUnresolved(arena, comp.dirs, &.{c_object.src.src_path}));
}
// For compiling Win32 resources, we rely on the cache hash system to avoid duplicating work.
// Add a Job for each Win32 resource file.
try comp.win32_resource_work_queue.ensureUnusedCapacity(comp.win32_resource_table.count());
for (comp.win32_resource_table.keys()) |win32_resource| {
comp.win32_resource_work_queue.writeItemAssumeCapacity(win32_resource);
switch (win32_resource.src) {
.rc => |f| {
try comp.appendFileSystemInput(try .fromUnresolved(arena, comp.dirs, &.{f.src_path}));
},
.manifest => {},
}
}
if (comp.zcu) |zcu| {
const pt: Zcu.PerThread = .activate(zcu, .main);
defer pt.deactivate();
zcu.skip_analysis_this_update = false;
// TODO: doing this in `resolveReferences` later could avoid adding inputs for dead embedfiles. Investigate!
for (zcu.embed_table.keys()) |embed_file| {
try comp.appendFileSystemInput(embed_file.path);
}
zcu.analysis_roots.clear();
zcu.analysis_roots.appendAssumeCapacity(zcu.std_mod);
// Normally we rely on importing std to in turn import the root source file in the start code.
// However, the main module is distinct from the root module in tests, so that won't happen there.
if (comp.config.is_test and zcu.main_mod != zcu.std_mod) {
zcu.analysis_roots.appendAssumeCapacity(zcu.main_mod);
}
if (zcu.root_mod.deps.get("compiler_rt")) |compiler_rt_mod| {
zcu.analysis_roots.appendAssumeCapacity(compiler_rt_mod);
}
if (zcu.root_mod.deps.get("ubsan_rt")) |ubsan_rt_mod| {
zcu.analysis_roots.appendAssumeCapacity(ubsan_rt_mod);
}
}
try comp.performAllTheWork(main_progress_node);
if (comp.zcu) |zcu| {
const pt: Zcu.PerThread = .activate(zcu, .main);
defer pt.deactivate();
if (!zcu.skip_analysis_this_update) {
if (comp.config.is_test) {
// The `test_functions` decl has been intentionally postponed until now,
// at which point we must populate it with the list of test functions that
// have been discovered and not filtered out.
try pt.populateTestFunctions(main_progress_node);
}
try pt.processExports();
}
if (build_options.enable_debug_extensions and comp.verbose_intern_pool) {
std.debug.print("intern pool stats for '{s}':\n", .{
comp.root_name,
});
zcu.intern_pool.dump();
}
if (build_options.enable_debug_extensions and comp.verbose_generic_instances) {
std.debug.print("generic instances for '{s}:0x{x}':\n", .{
comp.root_name,
@intFromPtr(zcu),
});
zcu.intern_pool.dumpGenericInstances(gpa);
}
}
if (anyErrors(comp)) {
// Skip flushing and keep source files loaded for error reporting.
return;
}
// Flush below handles -femit-bin but there is still -femit-llvm-ir,
// -femit-llvm-bc, and -femit-asm, in the case of C objects.
comp.emitOthers();
switch (comp.cache_use) {
.whole => |whole| {
if (comp.file_system_inputs) |buf| try man.populateFileSystemInputs(buf);
if (comp.parent_whole_cache) |pwc| {
pwc.mutex.lock();
defer pwc.mutex.unlock();
try man.populateOtherManifest(pwc.manifest, pwc.prefix_map);
}
const bin_digest = man.finalBin();
const hex_digest = Cache.binToHex(bin_digest);
// Rename the temporary directory into place.
// Close tmp dir and link.File to avoid open handle during rename.
if (whole.tmp_artifact_directory) |*tmp_directory| {
tmp_directory.handle.close();
if (tmp_directory.path) |p| gpa.free(p);
whole.tmp_artifact_directory = null;
} else unreachable;
const s = std.fs.path.sep_str;
const tmp_dir_sub_path = "tmp" ++ s ++ std.fmt.hex(tmp_dir_rand_int);
const o_sub_path = "o" ++ s ++ hex_digest;
// Work around windows `AccessDenied` if any files within this
// directory are open by closing and reopening the file handles.
const need_writable_dance: enum { no, lf_only, lf_and_debug } = w: {
if (builtin.os.tag == .windows) {
if (comp.bin_file) |lf| {
// We cannot just call `makeExecutable` as it makes a false
// assumption that we have a file handle open only when linking
// an executable file. This used to be true when our linkers
// were incapable of emitting relocatables and static archive.
// Now that they are capable, we need to unconditionally close
// the file handle and re-open it in the follow up call to
// `makeWritable`.
if (lf.file) |f| {
f.close();
lf.file = null;
if (lf.closeDebugInfo()) break :w .lf_and_debug;
break :w .lf_only;
}
}
}
break :w .no;
};
renameTmpIntoCache(comp.dirs.local_cache, tmp_dir_sub_path, o_sub_path) catch |err| {
return comp.setMiscFailure(
.rename_results,
"failed to rename compilation results ('{}{s}') into local cache ('{}{s}'): {s}",
.{
comp.dirs.local_cache, tmp_dir_sub_path,
comp.dirs.local_cache, o_sub_path,
@errorName(err),
},
);
};
comp.digest = bin_digest;
comp.wholeCacheModeSetBinFilePath(whole, &hex_digest);
// The linker flush functions need to know the final output path
// for debug info purposes because executable debug info contains
// references object file paths.
if (comp.bin_file) |lf| {
lf.emit = .{
.root_dir = comp.dirs.local_cache,
.sub_path = whole.bin_sub_path.?,
};
// Has to be after the `wholeCacheModeSetBinFilePath` above.
switch (need_writable_dance) {
.no => {},
.lf_only => try lf.makeWritable(),
.lf_and_debug => {
try lf.makeWritable();
try lf.reopenDebugInfo();
},
}
}
try flush(comp, arena, .{
.root_dir = comp.dirs.local_cache,
.sub_path = o_sub_path,
}, .main, main_progress_node);
// Calling `flush` may have produced errors, in which case the
// cache manifest must not be written.
if (anyErrors(comp)) return;
// Failure here only means an unnecessary cache miss.
man.writeManifest() catch |err| {
log.warn("failed to write cache manifest: {s}", .{@errorName(err)});
};
if (comp.bin_file) |lf| {
lf.destroy();
comp.bin_file = null;
}
assert(whole.lock == null);
whole.lock = man.toOwnedLock();
},
.incremental => |incremental| {
try flush(comp, arena, .{
.root_dir = incremental.artifact_directory,
}, .main, main_progress_node);
},
}
}
pub fn appendFileSystemInput(comp: *Compilation, path: Compilation.Path) Allocator.Error!void {
const gpa = comp.gpa;
const fsi = comp.file_system_inputs orelse return;
const prefixes = comp.cache_parent.prefixes();
const want_prefix_dir: Cache.Directory = switch (path.root) {
.zig_lib => comp.dirs.zig_lib,
.global_cache => comp.dirs.global_cache,
.local_cache => comp.dirs.local_cache,
.none => .cwd(),
};
const prefix: u8 = for (prefixes, 1..) |prefix_dir, i| {
if (prefix_dir.eql(want_prefix_dir)) {
break @intCast(i);
}
} else std.debug.panic(
"missing prefix directory '{s}' ('{}') for '{s}'",
.{ @tagName(path.root), want_prefix_dir, path.sub_path },
);
try fsi.ensureUnusedCapacity(gpa, path.sub_path.len + 3);
if (fsi.items.len > 0) fsi.appendAssumeCapacity(0);
fsi.appendAssumeCapacity(prefix);
fsi.appendSliceAssumeCapacity(path.sub_path);
}
fn flush(
comp: *Compilation,
arena: Allocator,
default_artifact_directory: Cache.Path,
tid: Zcu.PerThread.Id,
prog_node: std.Progress.Node,
) !void {
if (comp.zcu) |zcu| {
if (zcu.llvm_object) |llvm_object| {
// Emit the ZCU object from LLVM now; it's required to flush the output file.
// If there's an output file, it wants to decide where the LLVM object goes!
const zcu_obj_emit_loc: ?EmitLoc = if (comp.bin_file) |lf| .{
.directory = null,
.basename = lf.zcu_object_sub_path.?,
} else null;
const sub_prog_node = prog_node.start("LLVM Emit Object", 0);
defer sub_prog_node.end();
try llvm_object.emit(.{
.pre_ir_path = comp.verbose_llvm_ir,
.pre_bc_path = comp.verbose_llvm_bc,
.bin_path = try resolveEmitLoc(arena, default_artifact_directory, zcu_obj_emit_loc),
.asm_path = try resolveEmitLoc(arena, default_artifact_directory, comp.emit_asm),
.post_ir_path = try resolveEmitLoc(arena, default_artifact_directory, comp.emit_llvm_ir),
.post_bc_path = try resolveEmitLoc(arena, default_artifact_directory, comp.emit_llvm_bc),
.is_debug = comp.root_mod.optimize_mode == .Debug,
.is_small = comp.root_mod.optimize_mode == .ReleaseSmall,
.time_report = comp.time_report,
.sanitize_thread = comp.config.any_sanitize_thread,
.fuzz = comp.config.any_fuzz,
.lto = comp.config.lto,
});
}
}
if (comp.bin_file) |lf| {
// This is needed before reading the error flags.
lf.flush(arena, tid, prog_node) catch |err| switch (err) {
error.LinkFailure => {}, // Already reported.
error.OutOfMemory => return error.OutOfMemory,
};
}
if (comp.zcu) |zcu| {
try link.File.C.flushEmitH(zcu);
}
}
/// 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`.
fn renameTmpIntoCache(
cache_directory: Cache.Directory,
tmp_dir_sub_path: []const u8,
o_sub_path: []const u8,
) !void {
var seen_eaccess = false;
while (true) {
std.fs.rename(
cache_directory.handle,
tmp_dir_sub_path,
cache_directory.handle,
o_sub_path,
) catch |err| switch (err) {
// On Windows, rename fails with `AccessDenied` rather than `PathAlreadyExists`.
// See https://github.com/ziglang/zig/issues/8362
error.AccessDenied => switch (builtin.os.tag) {
.windows => {
if (seen_eaccess) return error.AccessDenied;
seen_eaccess = true;
try cache_directory.handle.deleteTree(o_sub_path);
continue;
},
else => return error.AccessDenied,
},
error.PathAlreadyExists => {
try cache_directory.handle.deleteTree(o_sub_path);
continue;
},
error.FileNotFound => {
try cache_directory.handle.makePath("o");
continue;
},
else => |e| return e,
};
break;
}
}
/// Communicate the output binary location to parent Compilations.
fn wholeCacheModeSetBinFilePath(
comp: *Compilation,
whole: *CacheUse.Whole,
digest: *const [Cache.hex_digest_len]u8,
) void {
const digest_start = 2; // "o/[digest]/[basename]"
if (whole.bin_sub_path) |sub_path| {
@memcpy(sub_path[digest_start..][0..digest.len], digest);
}
if (whole.implib_sub_path) |sub_path| {
@memcpy(sub_path[digest_start..][0..digest.len], digest);
comp.implib_emit = .{
.root_dir = comp.dirs.local_cache,
.sub_path = sub_path,
};
}
if (whole.docs_sub_path) |sub_path| {
@memcpy(sub_path[digest_start..][0..digest.len], digest);
comp.docs_emit = .{
.root_dir = comp.dirs.local_cache,
.sub_path = sub_path,
};
}
}
fn prepareWholeEmitSubPath(arena: Allocator, opt_emit: ?EmitLoc) error{OutOfMemory}!?[]u8 {
const emit = opt_emit orelse return null;
if (emit.directory != null) return null;
const s = std.fs.path.sep_str;
const format = "o" ++ s ++ ("x" ** Cache.hex_digest_len) ++ s ++ "{s}";
return try std.fmt.allocPrint(arena, format, .{emit.basename});
}
/// This is only observed at compile-time and used to emit a compile error
/// to remind the programmer to update multiple related pieces of code that
/// are in different locations. Bump this number when adding or deleting
/// anything from the link cache manifest.
pub const link_hash_implementation_version = 14;
fn addNonIncrementalStuffToCacheManifest(
comp: *Compilation,
arena: Allocator,
man: *Cache.Manifest,
) !void {
comptime assert(link_hash_implementation_version == 14);
if (comp.zcu) |zcu| {
try addModuleTableToCacheHash(zcu, arena, &man.hash, .{ .files = man });
// Synchronize with other matching comments: ZigOnlyHashStuff
man.hash.addListOfBytes(comp.test_filters);
man.hash.addOptionalBytes(comp.test_name_prefix);
man.hash.add(comp.skip_linker_dependencies);
//man.hash.add(zcu.emit_h != null);
man.hash.add(zcu.error_limit);
} else {
cache_helpers.addModule(&man.hash, comp.root_mod);
}
try link.hashInputs(man, comp.link_inputs);
for (comp.c_object_table.keys()) |key| {
_ = try man.addFile(key.src.src_path, null);
man.hash.addOptional(key.src.ext);
man.hash.addListOfBytes(key.src.extra_flags);
}
for (comp.win32_resource_table.keys()) |key| {
switch (key.src) {
.rc => |rc_src| {
_ = try man.addFile(rc_src.src_path, null);
man.hash.addListOfBytes(rc_src.extra_flags);
},
.manifest => |manifest_path| {
_ = try man.addFile(manifest_path, null);
},
}
}
man.hash.add(comp.config.use_llvm);
man.hash.add(comp.config.use_lib_llvm);
man.hash.add(comp.config.is_test);
man.hash.add(comp.config.import_memory);
man.hash.add(comp.config.export_memory);
man.hash.add(comp.config.shared_memory);
man.hash.add(comp.config.dll_export_fns);
man.hash.add(comp.config.rdynamic);
man.hash.addOptionalBytes(comp.sysroot);
man.hash.addOptional(comp.version);
man.hash.add(comp.link_eh_frame_hdr);
man.hash.add(comp.skip_linker_dependencies);
man.hash.add(comp.compiler_rt_strat);
man.hash.add(comp.ubsan_rt_strat);
man.hash.add(comp.rc_includes);
man.hash.addListOfBytes(comp.force_undefined_symbols.keys());
man.hash.addListOfBytes(comp.framework_dirs);
man.hash.addListOfBytes(comp.windows_libs.keys());
cache_helpers.addOptionalEmitLoc(&man.hash, comp.emit_asm);
cache_helpers.addOptionalEmitLoc(&man.hash, comp.emit_llvm_ir);
cache_helpers.addOptionalEmitLoc(&man.hash, comp.emit_llvm_bc);
man.hash.addListOfBytes(comp.global_cc_argv);
const opts = comp.cache_use.whole.lf_open_opts;
try man.addOptionalFile(opts.linker_script);
try man.addOptionalFile(opts.version_script);
man.hash.add(opts.allow_undefined_version);
man.hash.addOptional(opts.enable_new_dtags);
man.hash.addOptional(opts.stack_size);
man.hash.addOptional(opts.image_base);
man.hash.addOptional(opts.gc_sections);
man.hash.add(opts.emit_relocs);
const target = comp.root_mod.resolved_target.result;
if (target.ofmt == .macho or target.ofmt == .coff) {
// TODO remove this, libraries need to be resolved by the frontend. this is already
// done by ELF.
for (opts.lib_directories) |lib_directory| man.hash.addOptionalBytes(lib_directory.path);
}
man.hash.addListOfBytes(opts.rpath_list);
man.hash.addListOfBytes(opts.symbol_wrap_set.keys());
if (comp.config.link_libc) {
man.hash.add(comp.libc_installation != null);
if (comp.libc_installation) |libc_installation| {
man.hash.addOptionalBytes(libc_installation.crt_dir);
if (target.abi == .msvc or target.abi == .itanium) {
man.hash.addOptionalBytes(libc_installation.msvc_lib_dir);
man.hash.addOptionalBytes(libc_installation.kernel32_lib_dir);
}
}
man.hash.addOptionalBytes(target.dynamic_linker.get());
}
man.hash.add(opts.repro);
man.hash.addOptional(opts.allow_shlib_undefined);
man.hash.add(opts.bind_global_refs_locally);
// ELF specific stuff
man.hash.add(opts.z_nodelete);
man.hash.add(opts.z_notext);
man.hash.add(opts.z_defs);
man.hash.add(opts.z_origin);
man.hash.add(opts.z_nocopyreloc);
man.hash.add(opts.z_now);
man.hash.add(opts.z_relro);
man.hash.add(opts.z_common_page_size orelse 0);
man.hash.add(opts.z_max_page_size orelse 0);
man.hash.add(opts.hash_style);
man.hash.add(opts.compress_debug_sections);
man.hash.addOptional(opts.sort_section);
man.hash.addOptionalBytes(opts.soname);
man.hash.add(opts.build_id);
// WASM specific stuff
man.hash.addOptional(opts.initial_memory);
man.hash.addOptional(opts.max_memory);
man.hash.addOptional(opts.global_base);
man.hash.addListOfBytes(opts.export_symbol_names);
// Mach-O specific stuff
try link.File.MachO.hashAddFrameworks(man, opts.frameworks);
try man.addOptionalFile(opts.entitlements);
man.hash.addOptional(opts.pagezero_size);
man.hash.addOptional(opts.headerpad_size);
man.hash.add(opts.headerpad_max_install_names);
man.hash.add(opts.dead_strip_dylibs);
man.hash.add(opts.force_load_objc);
man.hash.add(opts.discard_local_symbols);
// COFF specific stuff
man.hash.addOptional(opts.subsystem);
man.hash.add(opts.tsaware);
man.hash.add(opts.nxcompat);
man.hash.add(opts.dynamicbase);
man.hash.addOptional(opts.major_subsystem_version);
man.hash.addOptional(opts.minor_subsystem_version);
}
fn emitOthers(comp: *Compilation) void {
if (comp.config.output_mode != .Obj or comp.zcu != null or
comp.c_object_table.count() == 0)
{
return;
}
const obj_path = comp.c_object_table.keys()[0].status.success.object_path;
const ext = std.fs.path.extension(obj_path.sub_path);
const dirname = obj_path.sub_path[0 .. obj_path.sub_path.len - ext.len];
// This obj path always ends with the object file extension, but if we change the
// extension to .ll, .bc, or .s, then it will be the path to those things.
const outs = [_]struct {
emit: ?EmitLoc,
ext: []const u8,
}{
.{ .emit = comp.emit_asm, .ext = ".s" },
.{ .emit = comp.emit_llvm_ir, .ext = ".ll" },
.{ .emit = comp.emit_llvm_bc, .ext = ".bc" },
};
for (outs) |out| {
if (out.emit) |loc| {
if (loc.directory) |directory| {
const src_path = std.fmt.allocPrint(comp.gpa, "{s}{s}", .{
dirname, out.ext,
}) catch |err| {
log.err("unable to copy {s}{s}: {s}", .{ dirname, out.ext, @errorName(err) });
continue;
};
defer comp.gpa.free(src_path);
obj_path.root_dir.handle.copyFile(src_path, directory.handle, loc.basename, .{}) catch |err| {
log.err("unable to copy {s}: {s}", .{ src_path, @errorName(err) });
};
}
}
}
}
fn resolveEmitLoc(
arena: Allocator,
default_artifact_directory: Cache.Path,
opt_loc: ?EmitLoc,
) Allocator.Error!?[*:0]const u8 {
const loc = opt_loc orelse return null;
const slice = if (loc.directory) |directory|
try directory.joinZ(arena, &.{loc.basename})
else
try default_artifact_directory.joinStringZ(arena, loc.basename);
return slice.ptr;
}
/// Having the file open for writing is problematic as far as executing the
/// binary is concerned. This will remove the write flag, or close the file,
/// or whatever is needed so that it can be executed.
/// After this, one must call` makeFileWritable` before calling `update`.
pub fn makeBinFileExecutable(comp: *Compilation) !void {
if (!dev.env.supports(.make_executable)) return;
const lf = comp.bin_file orelse return;
return lf.makeExecutable();
}
pub fn makeBinFileWritable(comp: *Compilation) !void {
const lf = comp.bin_file orelse return;
return lf.makeWritable();
}
const Header = extern struct {
intern_pool: extern struct {
thread_count: u32,
src_hash_deps_len: u32,
nav_val_deps_len: u32,
nav_ty_deps_len: u32,
interned_deps_len: u32,
zon_file_deps_len: u32,
embed_file_deps_len: u32,
namespace_deps_len: u32,
namespace_name_deps_len: u32,
first_dependency_len: u32,
dep_entries_len: u32,
free_dep_entries_len: u32,
},
const PerThread = extern struct {
intern_pool: extern struct {
items_len: u32,
extra_len: u32,
limbs_len: u32,
string_bytes_len: u32,
tracked_insts_len: u32,
files_len: u32,
},
};
};
/// Note that all state that is included in the cache hash namespace is *not*
/// saved, such as the target and most CLI flags. A cache hit will only occur
/// when subsequent compiler invocations use the same set of flags.
pub fn saveState(comp: *Compilation) !void {
dev.check(.incremental);
const lf = comp.bin_file orelse return;
const gpa = comp.gpa;
var bufs = std.ArrayList(std.posix.iovec_const).init(gpa);
defer bufs.deinit();
var pt_headers = std.ArrayList(Header.PerThread).init(gpa);
defer pt_headers.deinit();
if (comp.zcu) |zcu| {
const ip = &zcu.intern_pool;
const header: Header = .{
.intern_pool = .{
.thread_count = @intCast(ip.locals.len),
.src_hash_deps_len = @intCast(ip.src_hash_deps.count()),
.nav_val_deps_len = @intCast(ip.nav_val_deps.count()),
.nav_ty_deps_len = @intCast(ip.nav_ty_deps.count()),
.interned_deps_len = @intCast(ip.interned_deps.count()),
.zon_file_deps_len = @intCast(ip.zon_file_deps.count()),
.embed_file_deps_len = @intCast(ip.embed_file_deps.count()),
.namespace_deps_len = @intCast(ip.namespace_deps.count()),
.namespace_name_deps_len = @intCast(ip.namespace_name_deps.count()),
.first_dependency_len = @intCast(ip.first_dependency.count()),
.dep_entries_len = @intCast(ip.dep_entries.items.len),
.free_dep_entries_len = @intCast(ip.free_dep_entries.items.len),
},
};
try pt_headers.ensureTotalCapacityPrecise(header.intern_pool.thread_count);
for (ip.locals) |*local| pt_headers.appendAssumeCapacity(.{
.intern_pool = .{
.items_len = @intCast(local.mutate.items.len),
.extra_len = @intCast(local.mutate.extra.len),
.limbs_len = @intCast(local.mutate.limbs.len),
.string_bytes_len = @intCast(local.mutate.strings.len),
.tracked_insts_len = @intCast(local.mutate.tracked_insts.len),
.files_len = @intCast(local.mutate.files.len),
},
});
try bufs.ensureTotalCapacityPrecise(14 + 8 * pt_headers.items.len);
addBuf(&bufs, mem.asBytes(&header));
addBuf(&bufs, mem.sliceAsBytes(pt_headers.items));
addBuf(&bufs, mem.sliceAsBytes(ip.src_hash_deps.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.src_hash_deps.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.nav_val_deps.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.nav_val_deps.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.nav_ty_deps.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.nav_ty_deps.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.interned_deps.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.interned_deps.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.zon_file_deps.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.zon_file_deps.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.embed_file_deps.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.embed_file_deps.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.namespace_deps.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.namespace_deps.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.namespace_name_deps.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.namespace_name_deps.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.first_dependency.keys()));
addBuf(&bufs, mem.sliceAsBytes(ip.first_dependency.values()));
addBuf(&bufs, mem.sliceAsBytes(ip.dep_entries.items));
addBuf(&bufs, mem.sliceAsBytes(ip.free_dep_entries.items));
for (ip.locals, pt_headers.items) |*local, pt_header| {
if (pt_header.intern_pool.limbs_len > 0) {
addBuf(&bufs, mem.sliceAsBytes(local.shared.limbs.view().items(.@"0")[0..pt_header.intern_pool.limbs_len]));
}
if (pt_header.intern_pool.extra_len > 0) {
addBuf(&bufs, mem.sliceAsBytes(local.shared.extra.view().items(.@"0")[0..pt_header.intern_pool.extra_len]));
}
if (pt_header.intern_pool.items_len > 0) {
addBuf(&bufs, mem.sliceAsBytes(local.shared.items.view().items(.data)[0..pt_header.intern_pool.items_len]));
addBuf(&bufs, mem.sliceAsBytes(local.shared.items.view().items(.tag)[0..pt_header.intern_pool.items_len]));
}
if (pt_header.intern_pool.string_bytes_len > 0) {
addBuf(&bufs, local.shared.strings.view().items(.@"0")[0..pt_header.intern_pool.string_bytes_len]);
}
if (pt_header.intern_pool.tracked_insts_len > 0) {
addBuf(&bufs, mem.sliceAsBytes(local.shared.tracked_insts.view().items(.@"0")[0..pt_header.intern_pool.tracked_insts_len]));
}
if (pt_header.intern_pool.files_len > 0) {
addBuf(&bufs, mem.sliceAsBytes(local.shared.files.view().items(.bin_digest)[0..pt_header.intern_pool.files_len]));
addBuf(&bufs, mem.sliceAsBytes(local.shared.files.view().items(.root_type)[0..pt_header.intern_pool.files_len]));
}
}
//// TODO: compilation errors
//// TODO: namespaces
//// TODO: decls
}
// linker state
switch (lf.tag) {
.wasm => {
dev.check(link.File.Tag.wasm.devFeature());
const wasm = lf.cast(.wasm).?;
const is_obj = comp.config.output_mode == .Obj;
try bufs.ensureUnusedCapacity(85);
addBuf(&bufs, wasm.string_bytes.items);
// TODO make it well-defined memory layout
//addBuf(&bufs, mem.sliceAsBytes(wasm.objects.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.func_types.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_function_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_function_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_functions.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_global_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_global_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_globals.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_table_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_table_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_tables.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_memory_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_memory_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_memories.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_relocations.items(.tag)));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_relocations.items(.offset)));
// TODO handle the union safety field
//addBuf(&bufs, mem.sliceAsBytes(wasm.object_relocations.items(.pointee)));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_relocations.items(.addend)));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_init_funcs.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_data_segments.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_datas.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_data_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_data_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_custom_segments.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_custom_segments.values()));
// TODO make it well-defined memory layout
// addBuf(&bufs, mem.sliceAsBytes(wasm.object_comdats.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_relocations_table.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_relocations_table.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_comdat_symbols.items(.kind)));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_comdat_symbols.items(.index)));
addBuf(&bufs, mem.sliceAsBytes(wasm.out_relocs.items(.tag)));
addBuf(&bufs, mem.sliceAsBytes(wasm.out_relocs.items(.offset)));
// TODO handle the union safety field
//addBuf(&bufs, mem.sliceAsBytes(wasm.out_relocs.items(.pointee)));
addBuf(&bufs, mem.sliceAsBytes(wasm.out_relocs.items(.addend)));
addBuf(&bufs, mem.sliceAsBytes(wasm.uav_fixups.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.nav_fixups.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.func_table_fixups.items));
if (is_obj) {
addBuf(&bufs, mem.sliceAsBytes(wasm.navs_obj.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.navs_obj.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.uavs_obj.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.uavs_obj.values()));
} else {
addBuf(&bufs, mem.sliceAsBytes(wasm.navs_exe.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.navs_exe.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.uavs_exe.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.uavs_exe.values()));
}
addBuf(&bufs, mem.sliceAsBytes(wasm.overaligned_uavs.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.overaligned_uavs.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.zcu_funcs.keys()));
// TODO handle the union safety field
// addBuf(&bufs, mem.sliceAsBytes(wasm.zcu_funcs.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.nav_exports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.nav_exports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.uav_exports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.uav_exports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.missing_exports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.function_exports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.function_exports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.hidden_function_exports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.hidden_function_exports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.global_exports.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.functions.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.function_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.function_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.data_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.data_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.data_segments.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.globals.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.global_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.global_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.tables.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.table_imports.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.table_imports.values()));
addBuf(&bufs, mem.sliceAsBytes(wasm.zcu_indirect_function_set.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_indirect_function_import_set.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.object_indirect_function_set.keys()));
addBuf(&bufs, mem.sliceAsBytes(wasm.mir_instructions.items(.tag)));
// TODO handle the union safety field
//addBuf(&bufs, mem.sliceAsBytes(wasm.mir_instructions.items(.data)));
addBuf(&bufs, mem.sliceAsBytes(wasm.mir_extra.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.all_zcu_locals.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.tag_name_bytes.items));
addBuf(&bufs, mem.sliceAsBytes(wasm.tag_name_offs.items));
// TODO add as header fields
// entry_resolution: FunctionImport.Resolution
// function_exports_len: u32
// global_exports_len: u32
// functions_end_prelink: u32
// globals_end_prelink: u32
// error_name_table_ref_count: u32
// tag_name_table_ref_count: u32
// any_tls_relocs: bool
// any_passive_inits: bool
},
else => log.err("TODO implement saving linker state for {s}", .{@tagName(lf.tag)}),
}
var basename_buf: [255]u8 = undefined;
const basename = std.fmt.bufPrint(&basename_buf, "{s}.zcs", .{
comp.root_name,
}) catch o: {
basename_buf[basename_buf.len - 4 ..].* = ".zcs".*;
break :o &basename_buf;
};
// Using an atomic file prevents a crash or power failure from corrupting
// the previous incremental compilation state.
var af = try lf.emit.root_dir.handle.atomicFile(basename, .{});
defer af.deinit();
try af.file.pwritevAll(bufs.items, 0);
try af.finish();
}
fn addBuf(list: *std.ArrayList(std.posix.iovec_const), buf: []const u8) void {
// Even when len=0, the undefined pointer might cause EFAULT.
if (buf.len == 0) return;
list.appendAssumeCapacity(.{ .base = buf.ptr, .len = buf.len });
}
/// This function is temporally single-threaded.
pub fn getAllErrorsAlloc(comp: *Compilation) !ErrorBundle {
const gpa = comp.gpa;
var bundle: ErrorBundle.Wip = undefined;
try bundle.init(gpa);
defer bundle.deinit();
for (comp.failed_c_objects.values()) |diag_bundle| {
try diag_bundle.addToErrorBundle(&bundle);
}
for (comp.failed_win32_resources.values()) |error_bundle| {
try bundle.addBundleAsRoots(error_bundle);
}
for (comp.link_diags.lld.items) |lld_error| {
const notes_len = @as(u32, @intCast(lld_error.context_lines.len));
try bundle.addRootErrorMessage(.{
.msg = try bundle.addString(lld_error.msg),
.notes_len = notes_len,
});
const notes_start = try bundle.reserveNotes(notes_len);
for (notes_start.., lld_error.context_lines) |note, context_line| {
bundle.extra.items[note] = @intFromEnum(bundle.addErrorMessageAssumeCapacity(.{
.msg = try bundle.addString(context_line),
}));
}
}
for (comp.misc_failures.values()) |*value| {
try bundle.addRootErrorMessage(.{
.msg = try bundle.addString(value.msg),
.notes_len = if (value.children) |b| b.errorMessageCount() else 0,
});
if (value.children) |b| try bundle.addBundleAsNotes(b);
}
if (comp.alloc_failure_occurred or comp.link_diags.flags.alloc_failure_occurred) {
try bundle.addRootErrorMessage(.{
.msg = try bundle.addString("memory allocation failure"),
});
}
if (comp.zcu) |zcu| zcu_errors: {
if (zcu.multi_module_err != null) {
try zcu.addFileInMultipleModulesError(&bundle);
break :zcu_errors;
}
for (zcu.failed_imports.items) |failed| {
assert(zcu.alive_files.contains(failed.file_index)); // otherwise it wouldn't have been added
const file = zcu.fileByIndex(failed.file_index);
const source = try file.getSource(zcu);
const tree = try file.getTree(zcu);
const start = tree.tokenStart(failed.import_token);
const end = start + tree.tokenSlice(failed.import_token).len;
const loc = std.zig.findLineColumn(source.bytes, start);
try bundle.addRootErrorMessage(.{
.msg = switch (failed.kind) {
.file_outside_module_root => try bundle.addString("import of file outside module path"),
.illegal_zig_import => try bundle.addString("this compiler implementation does not allow importing files from this directory"),
},
.src_loc = try bundle.addSourceLocation(.{
.src_path = try bundle.printString("{}", .{file.path.fmt(comp)}),
.span_start = start,
.span_main = start,
.span_end = @intCast(end),
.line = @intCast(loc.line),
.column = @intCast(loc.column),
.source_line = try bundle.addString(loc.source_line),
}),
.notes_len = 0,
});
}
// Before iterating `failed_files`, we need to sort it into a consistent order so that error
// messages appear consistently despite different ordering from the AstGen worker pool. File
// paths are a great key for this sort! We are using sorting the `ArrayHashMap` itself to
// make sure it reindexes; that's important because these entries need to be retained for
// future updates.
const FileSortCtx = struct {
zcu: *Zcu,
failed_files_keys: []const Zcu.File.Index,
pub fn lessThan(ctx: @This(), lhs_index: usize, rhs_index: usize) bool {
const lhs_path = ctx.zcu.fileByIndex(ctx.failed_files_keys[lhs_index]).path;
const rhs_path = ctx.zcu.fileByIndex(ctx.failed_files_keys[rhs_index]).path;
if (lhs_path.root != rhs_path.root) return @intFromEnum(lhs_path.root) < @intFromEnum(rhs_path.root);
return std.mem.order(u8, lhs_path.sub_path, rhs_path.sub_path).compare(.lt);
}
};
zcu.failed_files.sort(@as(FileSortCtx, .{
.zcu = zcu,
.failed_files_keys = zcu.failed_files.keys(),
}));
for (zcu.failed_files.keys(), zcu.failed_files.values()) |file_index, error_msg| {
if (!zcu.alive_files.contains(file_index)) continue;
const file = zcu.fileByIndex(file_index);
const is_retryable = switch (file.status) {
.retryable_failure => true,
.success, .astgen_failure => false,
.never_loaded => unreachable,
};
if (error_msg) |msg| {
assert(is_retryable);
try addWholeFileError(zcu, &bundle, file_index, msg);
} else {
assert(!is_retryable);
// AstGen/ZoirGen succeeded with errors. Note that this may include AST errors.
_ = try file.getTree(zcu); // Tree must be loaded.
const path = try std.fmt.allocPrint(gpa, "{}", .{file.path.fmt(comp)});
defer gpa.free(path);
if (file.zir != null) {
try bundle.addZirErrorMessages(file.zir.?, file.tree.?, file.source.?, path);
} else if (file.zoir != null) {
try bundle.addZoirErrorMessages(file.zoir.?, file.tree.?, file.source.?, path);
} else {
// Either Zir or Zoir must have been loaded.
unreachable;
}
}
}
if (zcu.skip_analysis_this_update) break :zcu_errors;
var sorted_failed_analysis: std.AutoArrayHashMapUnmanaged(InternPool.AnalUnit, *Zcu.ErrorMsg).DataList.Slice = s: {
const SortOrder = struct {
zcu: *Zcu,
errors: []const *Zcu.ErrorMsg,
err: *?Error,
const Error = @typeInfo(
@typeInfo(@TypeOf(Zcu.LazySrcLoc.lessThan)).@"fn".return_type.?,
).error_union.error_set;
pub fn lessThan(ctx: @This(), lhs_index: usize, rhs_index: usize) bool {
if (ctx.err.* != null) return lhs_index < rhs_index;
return ctx.errors[lhs_index].src_loc.lessThan(ctx.errors[rhs_index].src_loc, ctx.zcu) catch |e| {
ctx.err.* = e;
return lhs_index < rhs_index;
};
}
};
// We can't directly sort `zcu.failed_analysis.entries`, because that would leave the map
// in an invalid state, and we need it intact for future incremental updates. The amount
// of data here is only as large as the number of analysis errors, so just dupe it all.
var entries = try zcu.failed_analysis.entries.clone(gpa);
errdefer entries.deinit(gpa);
var err: ?SortOrder.Error = null;
entries.sort(SortOrder{
.zcu = zcu,
.errors = entries.items(.value),
.err = &err,
});
if (err) |e| return e;
break :s entries.slice();
};
defer sorted_failed_analysis.deinit(gpa);
var added_any_analysis_error = false;
for (sorted_failed_analysis.items(.key), sorted_failed_analysis.items(.value)) |anal_unit, error_msg| {
if (comp.incremental) {
const refs = try zcu.resolveReferences();
if (!refs.contains(anal_unit)) continue;
}
std.log.scoped(.zcu).debug("analysis error '{s}' reported from unit '{}'", .{
error_msg.msg,
zcu.fmtAnalUnit(anal_unit),
});
try addModuleErrorMsg(zcu, &bundle, error_msg.*, added_any_analysis_error);
added_any_analysis_error = true;
if (zcu.cimport_errors.get(anal_unit)) |errors| {
for (errors.getMessages()) |err_msg_index| {
const err_msg = errors.getErrorMessage(err_msg_index);
try bundle.addRootErrorMessage(.{
.msg = try bundle.addString(errors.nullTerminatedString(err_msg.msg)),
.src_loc = if (err_msg.src_loc != .none) blk: {
const src_loc = errors.getSourceLocation(err_msg.src_loc);
break :blk try bundle.addSourceLocation(.{
.src_path = try bundle.addString(errors.nullTerminatedString(src_loc.src_path)),
.span_start = src_loc.span_start,
.span_main = src_loc.span_main,
.span_end = src_loc.span_end,
.line = src_loc.line,
.column = src_loc.column,
.source_line = if (src_loc.source_line != 0) try bundle.addString(errors.nullTerminatedString(src_loc.source_line)) else 0,
});
} else .none,
});
}
}
}
for (zcu.failed_codegen.values()) |error_msg| {
try addModuleErrorMsg(zcu, &bundle, error_msg.*, false);
}
for (zcu.failed_types.values()) |error_msg| {
try addModuleErrorMsg(zcu, &bundle, error_msg.*, false);
}
for (zcu.failed_exports.values()) |value| {
try addModuleErrorMsg(zcu, &bundle, value.*, false);
}
const actual_error_count = zcu.intern_pool.global_error_set.getNamesFromMainThread().len;
if (actual_error_count > zcu.error_limit) {
try bundle.addRootErrorMessage(.{
.msg = try bundle.printString("ZCU used more errors than possible: used {d}, max {d}", .{
actual_error_count, zcu.error_limit,
}),
.notes_len = 1,
});
const notes_start = try bundle.reserveNotes(1);
bundle.extra.items[notes_start] = @intFromEnum(try bundle.addErrorMessage(.{
.msg = try bundle.printString("use '--error-limit {d}' to increase limit", .{
actual_error_count,
}),
}));
}
}
if (bundle.root_list.items.len == 0) {
if (comp.link_diags.flags.no_entry_point_found) {
try bundle.addRootErrorMessage(.{
.msg = try bundle.addString("no entry point found"),
});
}
}
if (comp.link_diags.flags.missing_libc) {
try bundle.addRootErrorMessage(.{
.msg = try bundle.addString("libc not available"),
.notes_len = 2,
});
const notes_start = try bundle.reserveNotes(2);
bundle.extra.items[notes_start + 0] = @intFromEnum(try bundle.addErrorMessage(.{
.msg = try bundle.addString("run 'zig libc -h' to learn about libc installations"),
}));
bundle.extra.items[notes_start + 1] = @intFromEnum(try bundle.addErrorMessage(.{
.msg = try bundle.addString("run 'zig targets' to see the targets for which zig can always provide libc"),
}));
}
try comp.link_diags.addMessagesToBundle(&bundle, comp.bin_file);
const compile_log_text: []const u8 = compile_log_text: {
const zcu = comp.zcu orelse break :compile_log_text "";
if (zcu.skip_analysis_this_update) break :compile_log_text "";
if (zcu.compile_logs.count() == 0) break :compile_log_text "";
// If there are no other errors, we include a "found compile log statement" error.
// Otherwise, we just show the compile log output, with no error.
const include_compile_log_sources = bundle.root_list.items.len == 0;
const refs = try zcu.resolveReferences();
var messages: std.ArrayListUnmanaged(Zcu.ErrorMsg) = .empty;
defer messages.deinit(gpa);
for (zcu.compile_logs.keys(), zcu.compile_logs.values()) |logging_unit, compile_log| {
if (!refs.contains(logging_unit)) continue;
try messages.append(gpa, .{
.src_loc = compile_log.src(),
.msg = undefined, // populated later
.notes = &.{},
// We actually clear this later for most of these, but we populate
// this field for now to avoid having to allocate more data to track
// which compile log text this corresponds to.
.reference_trace_root = logging_unit.toOptional(),
});
}
if (messages.items.len == 0) break :compile_log_text "";
// Okay, there *are* referenced compile logs. Sort them into a consistent order.
const SortContext = struct {
err: *?Error,
zcu: *Zcu,
const Error = @typeInfo(
@typeInfo(@TypeOf(Zcu.LazySrcLoc.lessThan)).@"fn".return_type.?,
).error_union.error_set;
fn lessThan(ctx: @This(), lhs: Zcu.ErrorMsg, rhs: Zcu.ErrorMsg) bool {
if (ctx.err.* != null) return false;
return lhs.src_loc.lessThan(rhs.src_loc, ctx.zcu) catch |e| {
ctx.err.* = e;
return false;
};
}
};
var sort_err: ?SortContext.Error = null;
std.mem.sort(Zcu.ErrorMsg, messages.items, @as(SortContext, .{ .err = &sort_err, .zcu = zcu }), SortContext.lessThan);
if (sort_err) |e| return e;
var log_text: std.ArrayListUnmanaged(u8) = .empty;
defer log_text.deinit(gpa);
// Index 0 will be the root message; the rest will be notes.
// Only the actual message, i.e. index 0, will retain its reference trace.
try appendCompileLogLines(&log_text, zcu, messages.items[0].reference_trace_root.unwrap().?);
messages.items[0].notes = messages.items[1..];
messages.items[0].msg = "found compile log statement";
for (messages.items[1..]) |*note| {
try appendCompileLogLines(&log_text, zcu, note.reference_trace_root.unwrap().?);
note.reference_trace_root = .none; // notes don't have reference traces
note.msg = "also here";
}
// We don't actually include the error here if `!include_compile_log_sources`.
// The sorting above was still necessary, though, to get `log_text` in the right order.
if (include_compile_log_sources) {
try addModuleErrorMsg(zcu, &bundle, messages.items[0], false);
}
break :compile_log_text try log_text.toOwnedSlice(gpa);
};
// TODO: eventually, this should be behind `std.debug.runtime_safety`. But right now, this is a
// very common way for incremental compilation bugs to manifest, so let's always check it.
if (comp.zcu) |zcu| if (comp.incremental and bundle.root_list.items.len == 0) {
for (zcu.transitive_failed_analysis.keys()) |failed_unit| {
const refs = try zcu.resolveReferences();
var ref = refs.get(failed_unit) orelse continue;
// This AU is referenced and has a transitive compile error, meaning it referenced something with a compile error.
// However, we haven't reported any such error.
// This is a compiler bug.
const stderr = std.io.getStdErr().writer();
try stderr.writeAll("referenced transitive analysis errors, but none actually emitted\n");
try stderr.print("{} [transitive failure]\n", .{zcu.fmtAnalUnit(failed_unit)});
while (ref) |r| {
try stderr.print("referenced by: {}{s}\n", .{
zcu.fmtAnalUnit(r.referencer),
if (zcu.transitive_failed_analysis.contains(r.referencer)) " [transitive failure]" else "",
});
ref = refs.get(r.referencer).?;
}
@panic("referenced transitive analysis errors, but none actually emitted");
}
};
return bundle.toOwnedBundle(compile_log_text);
}
/// Writes all compile log lines belonging to `logging_unit` into `log_text` using `zcu.gpa`.
fn appendCompileLogLines(log_text: *std.ArrayListUnmanaged(u8), zcu: *Zcu, logging_unit: InternPool.AnalUnit) Allocator.Error!void {
const gpa = zcu.gpa;
const ip = &zcu.intern_pool;
var opt_line_idx = zcu.compile_logs.get(logging_unit).?.first_line.toOptional();
while (opt_line_idx.unwrap()) |line_idx| {
const line = line_idx.get(zcu).*;
opt_line_idx = line.next;
const line_slice = line.data.toSlice(ip);
try log_text.ensureUnusedCapacity(gpa, line_slice.len + 1);
log_text.appendSliceAssumeCapacity(line_slice);
log_text.appendAssumeCapacity('\n');
}
}
fn anyErrors(comp: *Compilation) bool {
return (totalErrorCount(comp) catch return true) != 0;
}
fn totalErrorCount(comp: *Compilation) !u32 {
var errors = try comp.getAllErrorsAlloc();
defer errors.deinit(comp.gpa);
return errors.errorMessageCount();
}
pub const ErrorNoteHashContext = struct {
eb: *const ErrorBundle.Wip,
pub fn hash(ctx: ErrorNoteHashContext, key: ErrorBundle.ErrorMessage) u32 {
var hasher = std.hash.Wyhash.init(0);
const eb = ctx.eb.tmpBundle();
hasher.update(eb.nullTerminatedString(key.msg));
if (key.src_loc != .none) {
const src = eb.getSourceLocation(key.src_loc);
hasher.update(eb.nullTerminatedString(src.src_path));
std.hash.autoHash(&hasher, src.line);
std.hash.autoHash(&hasher, src.column);
std.hash.autoHash(&hasher, src.span_main);
}
return @as(u32, @truncate(hasher.final()));
}
pub fn eql(
ctx: ErrorNoteHashContext,
a: ErrorBundle.ErrorMessage,
b: ErrorBundle.ErrorMessage,
b_index: usize,
) bool {
_ = b_index;
const eb = ctx.eb.tmpBundle();
const msg_a = eb.nullTerminatedString(a.msg);
const msg_b = eb.nullTerminatedString(b.msg);
if (!mem.eql(u8, msg_a, msg_b)) return false;
if (a.src_loc == .none and b.src_loc == .none) return true;
if (a.src_loc == .none or b.src_loc == .none) return false;
const src_a = eb.getSourceLocation(a.src_loc);
const src_b = eb.getSourceLocation(b.src_loc);
const src_path_a = eb.nullTerminatedString(src_a.src_path);
const src_path_b = eb.nullTerminatedString(src_b.src_path);
return mem.eql(u8, src_path_a, src_path_b) and
src_a.line == src_b.line and
src_a.column == src_b.column and
src_a.span_main == src_b.span_main;
}
};
const default_reference_trace_len = 2;
pub fn addModuleErrorMsg(
zcu: *Zcu,
eb: *ErrorBundle.Wip,
module_err_msg: Zcu.ErrorMsg,
/// If `-freference-trace` is not specified, we only want to show the one reference trace.
/// So, this is whether we have already emitted an error with a reference trace.
already_added_error: bool,
) !void {
const gpa = eb.gpa;
const ip = &zcu.intern_pool;
const err_src_loc = module_err_msg.src_loc.upgrade(zcu);
const err_source = err_src_loc.file_scope.getSource(zcu) catch |err| {
try eb.addRootErrorMessage(.{
.msg = try eb.printString("unable to load '{}': {s}", .{
err_src_loc.file_scope.path.fmt(zcu.comp), @errorName(err),
}),
});
return;
};
const err_span = try err_src_loc.span(zcu);
const err_loc = std.zig.findLineColumn(err_source.bytes, err_span.main);
var ref_traces: std.ArrayListUnmanaged(ErrorBundle.ReferenceTrace) = .empty;
defer ref_traces.deinit(gpa);
rt: {
const rt_root = module_err_msg.reference_trace_root.unwrap() orelse break :rt;
const max_references = zcu.comp.reference_trace orelse refs: {
if (already_added_error) break :rt;
break :refs default_reference_trace_len;
};
const all_references = try zcu.resolveReferences();
var seen: std.AutoHashMapUnmanaged(InternPool.AnalUnit, void) = .empty;
defer seen.deinit(gpa);
var referenced_by = rt_root;
while (all_references.get(referenced_by)) |maybe_ref| {
const ref = maybe_ref orelse break;
const gop = try seen.getOrPut(gpa, ref.referencer);
if (gop.found_existing) break;
if (ref_traces.items.len < max_references) {
var last_call_src = ref.src;
var opt_inline_frame = ref.inline_frame;
while (opt_inline_frame.unwrap()) |inline_frame| {
const f = inline_frame.ptr(zcu).*;
const func_nav = ip.indexToKey(f.callee).func.owner_nav;
const func_name = ip.getNav(func_nav).name.toSlice(ip);
try addReferenceTraceFrame(zcu, eb, &ref_traces, func_name, last_call_src, true);
last_call_src = f.call_src;
opt_inline_frame = f.parent;
}
const root_name: ?[]const u8 = switch (ref.referencer.unwrap()) {
.@"comptime" => "comptime",
.nav_val, .nav_ty => |nav| ip.getNav(nav).name.toSlice(ip),
.type => |ty| Type.fromInterned(ty).containerTypeName(ip).toSlice(ip),
.func => |f| ip.getNav(zcu.funcInfo(f).owner_nav).name.toSlice(ip),
.memoized_state => null,
};
if (root_name) |n| {
try addReferenceTraceFrame(zcu, eb, &ref_traces, n, last_call_src, false);
}
}
referenced_by = ref.referencer;
}
if (seen.count() > ref_traces.items.len) {
try ref_traces.append(gpa, .{
.decl_name = @intCast(seen.count() - ref_traces.items.len),
.src_loc = .none,
});
}
}
const src_loc = try eb.addSourceLocation(.{
.src_path = try eb.printString("{}", .{err_src_loc.file_scope.path.fmt(zcu.comp)}),
.span_start = err_span.start,
.span_main = err_span.main,
.span_end = err_span.end,
.line = @intCast(err_loc.line),
.column = @intCast(err_loc.column),
.source_line = try eb.addString(err_loc.source_line),
.reference_trace_len = @intCast(ref_traces.items.len),
});
for (ref_traces.items) |rt| {
try eb.addReferenceTrace(rt);
}
// De-duplicate error notes. The main use case in mind for this is
// too many "note: called from here" notes when eval branch quota is reached.
var notes: std.ArrayHashMapUnmanaged(ErrorBundle.ErrorMessage, void, ErrorNoteHashContext, true) = .empty;
defer notes.deinit(gpa);
var last_note_loc: ?std.zig.Loc = null;
for (module_err_msg.notes) |module_note| {
const note_src_loc = module_note.src_loc.upgrade(zcu);
const source = try note_src_loc.file_scope.getSource(zcu);
const span = try note_src_loc.span(zcu);
const loc = std.zig.findLineColumn(source.bytes, span.main);
const omit_source_line = loc.eql(err_loc) or (last_note_loc != null and loc.eql(last_note_loc.?));
last_note_loc = loc;
const gop = try notes.getOrPutContext(gpa, .{
.msg = try eb.addString(module_note.msg),
.src_loc = try eb.addSourceLocation(.{
.src_path = try eb.printString("{}", .{note_src_loc.file_scope.path.fmt(zcu.comp)}),
.span_start = span.start,
.span_main = span.main,
.span_end = span.end,
.line = @intCast(loc.line),
.column = @intCast(loc.column),
.source_line = if (omit_source_line) 0 else try eb.addString(loc.source_line),
}),
}, .{ .eb = eb });
if (gop.found_existing) {
gop.key_ptr.count += 1;
}
}
const notes_len: u32 = @intCast(notes.entries.len);
try eb.addRootErrorMessage(.{
.msg = try eb.addString(module_err_msg.msg),
.src_loc = src_loc,
.notes_len = notes_len,
});
const notes_start = try eb.reserveNotes(notes_len);
for (notes_start.., notes.keys()) |i, note| {
eb.extra.items[i] = @intFromEnum(try eb.addErrorMessage(note));
}
}
fn addReferenceTraceFrame(
zcu: *Zcu,
eb: *ErrorBundle.Wip,
ref_traces: *std.ArrayListUnmanaged(ErrorBundle.ReferenceTrace),
name: []const u8,
lazy_src: Zcu.LazySrcLoc,
inlined: bool,
) !void {
const gpa = zcu.gpa;
const src = lazy_src.upgrade(zcu);
const source = try src.file_scope.getSource(zcu);
const span = try src.span(zcu);
const loc = std.zig.findLineColumn(source.bytes, span.main);
try ref_traces.append(gpa, .{
.decl_name = try eb.printString("{s}{s}", .{ name, if (inlined) " [inlined]" else "" }),
.src_loc = try eb.addSourceLocation(.{
.src_path = try eb.printString("{}", .{src.file_scope.path.fmt(zcu.comp)}),
.span_start = span.start,
.span_main = span.main,
.span_end = span.end,
.line = @intCast(loc.line),
.column = @intCast(loc.column),
.source_line = 0,
}),
});
}
pub fn addWholeFileError(
zcu: *Zcu,
eb: *ErrorBundle.Wip,
file_index: Zcu.File.Index,
msg: []const u8,
) !void {
// note: "file imported here" on the import reference token
const imported_note: ?ErrorBundle.MessageIndex = switch (zcu.alive_files.get(file_index).?) {
.analysis_root => null,
.import => |import| try eb.addErrorMessage(.{
.msg = try eb.addString("file imported here"),
.src_loc = try zcu.fileByIndex(import.importer).errorBundleTokenSrc(import.tok, zcu, eb),
}),
};
try eb.addRootErrorMessage(.{
.msg = try eb.addString(msg),
.src_loc = try zcu.fileByIndex(file_index).errorBundleWholeFileSrc(zcu, eb),
.notes_len = if (imported_note != null) 1 else 0,
});
if (imported_note) |n| {
const note_idx = try eb.reserveNotes(1);
eb.extra.items[note_idx] = @intFromEnum(n);
}
}
pub fn performAllTheWork(
comp: *Compilation,
main_progress_node: std.Progress.Node,
) JobError!void {
comp.work_queue_progress_node = main_progress_node;
defer comp.work_queue_progress_node = .none;
defer if (comp.zcu) |zcu| {
zcu.sema_prog_node.end();
zcu.sema_prog_node = .none;
zcu.codegen_prog_node.end();
zcu.codegen_prog_node = .none;
zcu.generation += 1;
};
try comp.performAllTheWorkInner(main_progress_node);
}
fn performAllTheWorkInner(
comp: *Compilation,
main_progress_node: std.Progress.Node,
) JobError!void {
// Here we queue up all the AstGen tasks first, followed by C object compilation.
// We wait until the AstGen tasks are all completed before proceeding to the
// (at least for now) single-threaded main work queue. However, C object compilation
// only needs to be finished by the end of this function.
var work_queue_wait_group: WaitGroup = .{};
defer work_queue_wait_group.wait();
comp.link_task_wait_group.reset();
defer comp.link_task_wait_group.wait();
comp.link_task_queue.start(comp);
if (comp.docs_emit != null) {
dev.check(.docs_emit);
comp.thread_pool.spawnWg(&work_queue_wait_group, workerDocsCopy, .{comp});
work_queue_wait_group.spawnManager(workerDocsWasm, .{ comp, main_progress_node });
}
// In case it failed last time, try again. `clearMiscFailures` was already
// called at the start of `update`.
if (comp.queued_jobs.compiler_rt_lib and comp.compiler_rt_lib == null) {
// LLVM disables LTO for its compiler-rt and we've had various issues with LTO of our
// compiler-rt due to LLD bugs as well, e.g.:
//
// https://github.com/llvm/llvm-project/issues/43698#issuecomment-2542660611
comp.link_task_wait_group.spawnManager(buildRt, .{
comp,
"compiler_rt.zig",
"compiler_rt",
.Lib,
.compiler_rt,
main_progress_node,
RtOptions{
.checks_valgrind = true,
.allow_lto = false,
},
&comp.compiler_rt_lib,
});
}
if (comp.queued_jobs.compiler_rt_obj and comp.compiler_rt_obj == null) {
comp.link_task_wait_group.spawnManager(buildRt, .{
comp,
"compiler_rt.zig",
"compiler_rt",
.Obj,
.compiler_rt,
main_progress_node,
RtOptions{
.checks_valgrind = true,
.allow_lto = false,
},
&comp.compiler_rt_obj,
});
}
if (comp.queued_jobs.fuzzer_lib and comp.fuzzer_lib == null) {
comp.link_task_wait_group.spawnManager(buildRt, .{
comp,
"fuzzer.zig",
"fuzzer",
.Lib,
.libfuzzer,
main_progress_node,
RtOptions{},
&comp.fuzzer_lib,
});
}
if (comp.queued_jobs.ubsan_rt_lib and comp.ubsan_rt_lib == null) {
comp.link_task_wait_group.spawnManager(buildRt, .{
comp,
"ubsan_rt.zig",
"ubsan_rt",
.Lib,
.libubsan,
main_progress_node,
RtOptions{
.allow_lto = false,
},
&comp.ubsan_rt_lib,
});
}
if (comp.queued_jobs.ubsan_rt_obj and comp.ubsan_rt_obj == null) {
comp.link_task_wait_group.spawnManager(buildRt, .{
comp,
"ubsan_rt.zig",
"ubsan_rt",
.Obj,
.libubsan,
main_progress_node,
RtOptions{
.allow_lto = false,
},
&comp.ubsan_rt_obj,
});
}
if (comp.queued_jobs.glibc_shared_objects) {
comp.link_task_wait_group.spawnManager(buildGlibcSharedObjects, .{ comp, main_progress_node });
}
if (comp.queued_jobs.freebsd_shared_objects) {
comp.link_task_wait_group.spawnManager(buildFreeBSDSharedObjects, .{ comp, main_progress_node });
}
if (comp.queued_jobs.netbsd_shared_objects) {
comp.link_task_wait_group.spawnManager(buildNetBSDSharedObjects, .{ comp, main_progress_node });
}
if (comp.queued_jobs.libunwind) {
comp.link_task_wait_group.spawnManager(buildLibUnwind, .{ comp, main_progress_node });
}
if (comp.queued_jobs.libcxx) {
comp.link_task_wait_group.spawnManager(buildLibCxx, .{ comp, main_progress_node });
}
if (comp.queued_jobs.libcxxabi) {
comp.link_task_wait_group.spawnManager(buildLibCxxAbi, .{ comp, main_progress_node });
}
if (comp.queued_jobs.libtsan) {
comp.link_task_wait_group.spawnManager(buildLibTsan, .{ comp, main_progress_node });
}
if (comp.queued_jobs.zigc_lib and comp.zigc_static_lib == null) {
comp.link_task_wait_group.spawnManager(buildLibZigC, .{ comp, main_progress_node });
}
for (0..@typeInfo(musl.CrtFile).@"enum".fields.len) |i| {
if (comp.queued_jobs.musl_crt_file[i]) {
const tag: musl.CrtFile = @enumFromInt(i);
comp.link_task_wait_group.spawnManager(buildMuslCrtFile, .{ comp, tag, main_progress_node });
}
}
for (0..@typeInfo(glibc.CrtFile).@"enum".fields.len) |i| {
if (comp.queued_jobs.glibc_crt_file[i]) {
const tag: glibc.CrtFile = @enumFromInt(i);
comp.link_task_wait_group.spawnManager(buildGlibcCrtFile, .{ comp, tag, main_progress_node });
}
}
for (0..@typeInfo(freebsd.CrtFile).@"enum".fields.len) |i| {
if (comp.queued_jobs.freebsd_crt_file[i]) {
const tag: freebsd.CrtFile = @enumFromInt(i);
comp.link_task_wait_group.spawnManager(buildFreeBSDCrtFile, .{ comp, tag, main_progress_node });
}
}
for (0..@typeInfo(netbsd.CrtFile).@"enum".fields.len) |i| {
if (comp.queued_jobs.netbsd_crt_file[i]) {
const tag: netbsd.CrtFile = @enumFromInt(i);
comp.link_task_wait_group.spawnManager(buildNetBSDCrtFile, .{ comp, tag, main_progress_node });
}
}
for (0..@typeInfo(wasi_libc.CrtFile).@"enum".fields.len) |i| {
if (comp.queued_jobs.wasi_libc_crt_file[i]) {
const tag: wasi_libc.CrtFile = @enumFromInt(i);
comp.link_task_wait_group.spawnManager(buildWasiLibcCrtFile, .{ comp, tag, main_progress_node });
}
}
for (0..@typeInfo(mingw.CrtFile).@"enum".fields.len) |i| {
if (comp.queued_jobs.mingw_crt_file[i]) {
const tag: mingw.CrtFile = @enumFromInt(i);
comp.link_task_wait_group.spawnManager(buildMingwCrtFile, .{ comp, tag, main_progress_node });
}
}
{
const astgen_frame = tracy.namedFrame("astgen");
defer astgen_frame.end();
const zir_prog_node = main_progress_node.start("AST Lowering", 0);
defer zir_prog_node.end();
var astgen_wait_group: WaitGroup = .{};
defer astgen_wait_group.wait();
if (comp.zcu) |zcu| {
const gpa = zcu.gpa;
// We cannot reference `zcu.import_table` after we spawn any `workerUpdateFile` jobs,
// because on single-threaded targets the worker will be run eagerly, meaning the
// `import_table` could be mutated, and not even holding `comp.mutex` will save us. So,
// build up a list of the files to update *before* we spawn any jobs.
var astgen_work_items: std.MultiArrayList(struct {
file_index: Zcu.File.Index,
file: *Zcu.File,
}) = .empty;
defer astgen_work_items.deinit(gpa);
// Not every item in `import_table` will need updating, because some are builtin.zig
// files. However, most will, so let's just reserve sufficient capacity upfront.
try astgen_work_items.ensureTotalCapacity(gpa, zcu.import_table.count());
for (zcu.import_table.keys()) |file_index| {
const file = zcu.fileByIndex(file_index);
if (file.is_builtin) {
// This is a `builtin.zig`, so updating is redundant. However, we want to make
// sure the file contents are still correct on disk, since it can improve the
// debugging experience better. That job only needs `file`, so we can kick it
// off right now.
comp.thread_pool.spawnWg(&astgen_wait_group, workerUpdateBuiltinFile, .{ comp, file });
continue;
}
astgen_work_items.appendAssumeCapacity(.{
.file_index = file_index,
.file = file,
});
}
// Now that we're not going to touch `zcu.import_table` again, we can spawn `workerUpdateFile` jobs.
for (astgen_work_items.items(.file_index), astgen_work_items.items(.file)) |file_index, file| {
comp.thread_pool.spawnWgId(&astgen_wait_group, workerUpdateFile, .{
comp, file, file_index, zir_prog_node, &astgen_wait_group,
});
}
// On the other hand, it's fine to directly iterate `zcu.embed_table.keys()` here
// because `workerUpdateEmbedFile` can't invalidate it. The different here is that one
// `@embedFile` can't trigger analysis of a new `@embedFile`!
for (0.., zcu.embed_table.keys()) |ef_index_usize, ef| {
const ef_index: Zcu.EmbedFile.Index = @enumFromInt(ef_index_usize);
comp.thread_pool.spawnWgId(&astgen_wait_group, workerUpdateEmbedFile, .{
comp, ef_index, ef,
});
}
}
while (comp.c_object_work_queue.readItem()) |c_object| {
comp.thread_pool.spawnWg(&comp.link_task_wait_group, workerUpdateCObject, .{
comp, c_object, main_progress_node,
});
}
while (comp.win32_resource_work_queue.readItem()) |win32_resource| {
comp.thread_pool.spawnWg(&comp.link_task_wait_group, workerUpdateWin32Resource, .{
comp, win32_resource, main_progress_node,
});
}
}
if (comp.zcu) |zcu| {
const pt: Zcu.PerThread = .activate(zcu, .main);
defer pt.deactivate();
const gpa = zcu.gpa;
// On an incremental update, a source file might become "dead", in that all imports of
// the file were removed. This could even change what module the file belongs to! As such,
// we do a traversal over the files, to figure out which ones are alive and the modules
// they belong to.
const any_fatal_files = try pt.computeAliveFiles();
// If the cache mode is `whole`, add every alive source file to the manifest.
switch (comp.cache_use) {
.whole => |whole| if (whole.cache_manifest) |man| {
for (zcu.alive_files.keys()) |file_index| {
const file = zcu.fileByIndex(file_index);
switch (file.status) {
.never_loaded => unreachable, // AstGen tried to load it
.retryable_failure => continue, // the file cannot be read; this is a guaranteed error
.astgen_failure, .success => {}, // the file was read successfully
}
const path = try file.path.toAbsolute(comp.dirs, gpa);
defer gpa.free(path);
const result = res: {
whole.cache_manifest_mutex.lock();
defer whole.cache_manifest_mutex.unlock();
if (file.source) |source| {
break :res man.addFilePostContents(path, source, file.stat);
} else {
break :res man.addFilePost(path);
}
};
result catch |err| switch (err) {
error.OutOfMemory => |e| return e,
else => {
try pt.reportRetryableFileError(file_index, "unable to update cache: {s}", .{@errorName(err)});
continue;
},
};
}
},
.incremental => {},
}
if (any_fatal_files or
zcu.multi_module_err != null or
zcu.failed_imports.items.len > 0 or
comp.alloc_failure_occurred)
{
// We give up right now! No updating of ZIR refs, no nothing. The idea is that this prevents
// us from invalidating lots of incremental dependencies due to files with e.g. parse errors.
// However, this means our analysis data is invalid, so we want to omit all analysis errors.
zcu.skip_analysis_this_update = true;
return;
}
if (comp.incremental) {
const update_zir_refs_node = main_progress_node.start("Update ZIR References", 0);
defer update_zir_refs_node.end();
try pt.updateZirRefs();
}
try zcu.flushRetryableFailures();
// It's analysis time! Queue up our initial analysis.
for (zcu.analysis_roots.slice()) |mod| {
try comp.queueJob(.{ .analyze_mod = mod });
}
zcu.sema_prog_node = main_progress_node.start("Semantic Analysis", 0);
zcu.codegen_prog_node = if (comp.bin_file != null) main_progress_node.start("Code Generation", 0) else .none;
}
if (!comp.separateCodegenThreadOk()) {
// Waits until all input files have been parsed.
comp.link_task_wait_group.wait();
comp.link_task_wait_group.reset();
std.log.scoped(.link).debug("finished waiting for link_task_wait_group", .{});
if (comp.link_task_queue.pending_prelink_tasks > 0) {
// Indicates an error occurred preventing prelink phase from completing.
return;
}
}
work: while (true) {
for (&comp.work_queues) |*work_queue| if (work_queue.readItem()) |job| {
try processOneJob(@intFromEnum(Zcu.PerThread.Id.main), comp, job);
continue :work;
};
if (comp.zcu) |zcu| {
// If there's no work queued, check if there's anything outdated
// which we need to work on, and queue it if so.
if (try zcu.findOutdatedToAnalyze()) |outdated| {
try comp.queueJob(switch (outdated.unwrap()) {
.func => |f| .{ .analyze_func = f },
.memoized_state,
.@"comptime",
.nav_ty,
.nav_val,
.type,
=> .{ .analyze_comptime_unit = outdated },
});
continue;
}
zcu.sema_prog_node.end();
zcu.sema_prog_node = .none;
}
break;
}
}
const JobError = Allocator.Error;
pub fn queueJob(comp: *Compilation, job: Job) !void {
try comp.work_queues[Job.stage(job)].writeItem(job);
}
pub fn queueJobs(comp: *Compilation, jobs: []const Job) !void {
for (jobs) |job| try comp.queueJob(job);
}
fn processOneJob(tid: usize, comp: *Compilation, job: Job) JobError!void {
switch (job) {
.codegen_func => |func| {
const zcu = comp.zcu.?;
const gpa = zcu.gpa;
var air = func.air;
errdefer air.deinit(gpa);
if (!air.typesFullyResolved(zcu)) {
// Type resolution failed in a way which affects this function. This is a transitive
// failure, but it doesn't need recording, because this function semantically depends
// on the failed type, so when it is changed the function is updated.
air.deinit(gpa);
return;
}
const pt: Zcu.PerThread = .activate(comp.zcu.?, @enumFromInt(tid));
defer pt.deactivate();
const shared_mir = try gpa.create(link.ZcuTask.LinkFunc.SharedMir);
shared_mir.* = .{
.status = .init(.pending),
.value = undefined,
};
if (comp.separateCodegenThreadOk()) {
// `workerZcuCodegen` takes ownership of `air`.
comp.thread_pool.spawnWgId(&comp.link_task_wait_group, workerZcuCodegen, .{ comp, func.func, air, shared_mir });
comp.dispatchZcuLinkTask(tid, .{ .link_func = .{
.func = func.func,
.mir = shared_mir,
.air = undefined,
} });
} else {
const emit_needs_air = !zcu.backendSupportsFeature(.separate_thread);
pt.runCodegen(func.func, &air, shared_mir);
assert(shared_mir.status.load(.monotonic) != .pending);
comp.dispatchZcuLinkTask(tid, .{ .link_func = .{
.func = func.func,
.mir = shared_mir,
.air = if (emit_needs_air) &air else undefined,
} });
air.deinit(gpa);
}
},
.link_nav => |nav_index| {
const zcu = comp.zcu.?;
const nav = zcu.intern_pool.getNav(nav_index);
if (nav.analysis != null) {
const unit: InternPool.AnalUnit = .wrap(.{ .nav_val = nav_index });
if (zcu.failed_analysis.contains(unit) or zcu.transitive_failed_analysis.contains(unit)) {
return;
}
}
assert(nav.status == .fully_resolved);
if (!Air.valFullyResolved(zcu.navValue(nav_index), zcu)) {
// Type resolution failed in a way which affects this `Nav`. This is a transitive
// failure, but it doesn't need recording, because this `Nav` semantically depends
// on the failed type, so when it is changed the `Nav` will be updated.
return;
}
comp.dispatchZcuLinkTask(tid, .{ .link_nav = nav_index });
},
.link_type => |ty| {
const zcu = comp.zcu.?;
if (zcu.failed_types.fetchSwapRemove(ty)) |*entry| entry.value.deinit(zcu.gpa);
if (!Air.typeFullyResolved(.fromInterned(ty), zcu)) {
// Type resolution failed in a way which affects this type. This is a transitive
// failure, but it doesn't need recording, because this type semantically depends
// on the failed type, so when that is changed, this type will be updated.
return;
}
comp.dispatchZcuLinkTask(tid, .{ .link_type = ty });
},
.update_line_number => |ti| {
comp.dispatchZcuLinkTask(tid, .{ .update_line_number = ti });
},
.analyze_func => |func| {
const named_frame = tracy.namedFrame("analyze_func");
defer named_frame.end();
const pt: Zcu.PerThread = .activate(comp.zcu.?, @enumFromInt(tid));
defer pt.deactivate();
pt.ensureFuncBodyUpToDate(func) catch |err| switch (err) {
error.OutOfMemory => |e| return e,
error.AnalysisFail => return,
};
},
.analyze_comptime_unit => |unit| {
const named_frame = tracy.namedFrame("analyze_comptime_unit");
defer named_frame.end();
const pt: Zcu.PerThread = .activate(comp.zcu.?, @enumFromInt(tid));
defer pt.deactivate();
const maybe_err: Zcu.SemaError!void = switch (unit.unwrap()) {
.@"comptime" => |cu| pt.ensureComptimeUnitUpToDate(cu),
.nav_ty => |nav| pt.ensureNavTypeUpToDate(nav),
.nav_val => |nav| pt.ensureNavValUpToDate(nav),
.type => |ty| if (pt.ensureTypeUpToDate(ty)) |_| {} else |err| err,
.memoized_state => |stage| pt.ensureMemoizedStateUpToDate(stage),
.func => unreachable,
};
maybe_err catch |err| switch (err) {
error.OutOfMemory => |e| return e,
error.AnalysisFail => return,
};
queue_test_analysis: {
if (!comp.config.is_test) break :queue_test_analysis;
const nav = switch (unit.unwrap()) {
.nav_val => |nav| nav,
else => break :queue_test_analysis,
};
// Check if this is a test function.
const ip = &pt.zcu.intern_pool;
if (!pt.zcu.test_functions.contains(nav)) {
break :queue_test_analysis;
}
// Tests are always emitted in test binaries. The decl_refs are created by
// Zcu.populateTestFunctions, but this will not queue body analysis, so do
// that now.
try pt.zcu.ensureFuncBodyAnalysisQueued(ip.getNav(nav).status.fully_resolved.val);
}
},
.resolve_type_fully => |ty| {
const named_frame = tracy.namedFrame("resolve_type_fully");
defer named_frame.end();
const pt: Zcu.PerThread = .activate(comp.zcu.?, @enumFromInt(tid));
defer pt.deactivate();
Type.fromInterned(ty).resolveFully(pt) catch |err| switch (err) {
error.OutOfMemory => return error.OutOfMemory,
error.AnalysisFail => return,
};
},
.analyze_mod => |mod| {
const named_frame = tracy.namedFrame("analyze_mod");
defer named_frame.end();
const pt: Zcu.PerThread = .activate(comp.zcu.?, @enumFromInt(tid));
defer pt.deactivate();
pt.semaMod(mod) catch |err| switch (err) {
error.OutOfMemory => return error.OutOfMemory,
error.AnalysisFail => return,
};
},
.windows_import_lib => |index| {
const named_frame = tracy.namedFrame("windows_import_lib");
defer named_frame.end();
const link_lib = comp.windows_libs.keys()[index];
mingw.buildImportLib(comp, link_lib) catch |err| {
// TODO Surface more error details.
comp.lockAndSetMiscFailure(
.windows_import_lib,
"unable to generate DLL import .lib file for {s}: {s}",
.{ link_lib, @errorName(err) },
);
};
},
}
}
pub fn separateCodegenThreadOk(comp: *const Compilation) bool {
if (InternPool.single_threaded) return false;
const zcu = comp.zcu orelse return true;
return zcu.backendSupportsFeature(.separate_thread);
}
fn workerDocsCopy(comp: *Compilation) void {
docsCopyFallible(comp) catch |err| {
return comp.lockAndSetMiscFailure(
.docs_copy,
"unable to copy autodocs artifacts: {s}",
.{@errorName(err)},
);
};
}
fn docsCopyFallible(comp: *Compilation) anyerror!void {
const zcu = comp.zcu orelse
return comp.lockAndSetMiscFailure(.docs_copy, "no Zig code to document", .{});
const emit = comp.docs_emit.?;
var out_dir = emit.root_dir.handle.makeOpenPath(emit.sub_path, .{}) catch |err| {
return comp.lockAndSetMiscFailure(
.docs_copy,
"unable to create output directory '{}{s}': {s}",
.{ emit.root_dir, emit.sub_path, @errorName(err) },
);
};
defer out_dir.close();
for (&[_][]const u8{ "docs/main.js", "docs/index.html" }) |sub_path| {
const basename = std.fs.path.basename(sub_path);
comp.dirs.zig_lib.handle.copyFile(sub_path, out_dir, basename, .{}) catch |err| {
comp.lockAndSetMiscFailure(.docs_copy, "unable to copy {s}: {s}", .{
sub_path,
@errorName(err),
});
return;
};
}
var tar_file = out_dir.createFile("sources.tar", .{}) catch |err| {
return comp.lockAndSetMiscFailure(
.docs_copy,
"unable to create '{}{s}/sources.tar': {s}",
.{ emit.root_dir, emit.sub_path, @errorName(err) },
);
};
defer tar_file.close();
var seen_table: std.AutoArrayHashMapUnmanaged(*Package.Module, []const u8) = .empty;
defer seen_table.deinit(comp.gpa);
try seen_table.put(comp.gpa, zcu.main_mod, comp.root_name);
try seen_table.put(comp.gpa, zcu.std_mod, zcu.std_mod.fully_qualified_name);
var i: usize = 0;
while (i < seen_table.count()) : (i += 1) {
const mod = seen_table.keys()[i];
try comp.docsCopyModule(mod, seen_table.values()[i], tar_file);
const deps = mod.deps.values();
try seen_table.ensureUnusedCapacity(comp.gpa, deps.len);
for (deps) |dep| seen_table.putAssumeCapacity(dep, dep.fully_qualified_name);
}
}
fn docsCopyModule(comp: *Compilation, module: *Package.Module, name: []const u8, tar_file: std.fs.File) !void {
const root = module.root;
var mod_dir = d: {
const root_dir, const sub_path = root.openInfo(comp.dirs);
break :d root_dir.openDir(sub_path, .{ .iterate = true });
} catch |err| {
return comp.lockAndSetMiscFailure(.docs_copy, "unable to open directory '{}': {s}", .{
root.fmt(comp), @errorName(err),
});
};
defer mod_dir.close();
var walker = try mod_dir.walk(comp.gpa);
defer walker.deinit();
var archiver = std.tar.writer(tar_file.writer().any());
archiver.prefix = name;
while (try walker.next()) |entry| {
switch (entry.kind) {
.file => {
if (!std.mem.endsWith(u8, entry.basename, ".zig")) continue;
if (std.mem.eql(u8, entry.basename, "test.zig")) continue;
if (std.mem.endsWith(u8, entry.basename, "_test.zig")) continue;
},
else => continue,
}
var file = mod_dir.openFile(entry.path, .{}) catch |err| {
return comp.lockAndSetMiscFailure(.docs_copy, "unable to open '{}{s}': {s}", .{
root.fmt(comp), entry.path, @errorName(err),
});
};
defer file.close();
archiver.writeFile(entry.path, file) catch |err| {
return comp.lockAndSetMiscFailure(.docs_copy, "unable to archive '{}{s}': {s}", .{
root.fmt(comp), entry.path, @errorName(err),
});
};
}
}
fn workerDocsWasm(comp: *Compilation, parent_prog_node: std.Progress.Node) void {
const prog_node = parent_prog_node.start("Compile Autodocs", 0);
defer prog_node.end();
workerDocsWasmFallible(comp, prog_node) catch |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.docs_wasm, "unable to build autodocs: {s}", .{
@errorName(err),
}),
};
}
fn workerDocsWasmFallible(comp: *Compilation, prog_node: std.Progress.Node) anyerror!void {
const gpa = comp.gpa;
var arena_allocator = std.heap.ArenaAllocator.init(gpa);
defer arena_allocator.deinit();
const arena = arena_allocator.allocator();
const optimize_mode = std.builtin.OptimizeMode.ReleaseSmall;
const output_mode = std.builtin.OutputMode.Exe;
const resolved_target: Package.Module.ResolvedTarget = .{
.result = std.zig.system.resolveTargetQuery(.{
.cpu_arch = .wasm32,
.os_tag = .freestanding,
.cpu_features_add = std.Target.wasm.featureSet(&.{
.atomics,
// .extended_const, not supported by Safari
.reference_types,
//.relaxed_simd, not supported by Firefox or Safari
// observed to cause Error occured during wast conversion :
// Unknown operator: 0xfd058 in Firefox 117
//.simd128,
// .tail_call, not supported by Safari
}),
}) catch unreachable,
.is_native_os = false,
.is_native_abi = false,
.is_explicit_dynamic_linker = false,
};
const config = try Config.resolve(.{
.output_mode = output_mode,
.resolved_target = resolved_target,
.is_test = false,
.have_zcu = true,
.emit_bin = true,
.root_optimize_mode = optimize_mode,
.link_libc = false,
.rdynamic = true,
});
const src_basename = "main.zig";
const root_name = std.fs.path.stem(src_basename);
const dirs = comp.dirs.withoutLocalCache();
const root_mod = try Package.Module.create(arena, .{
.paths = .{
.root = try .fromRoot(arena, dirs, .zig_lib, "docs/wasm"),
.root_src_path = src_basename,
},
.fully_qualified_name = root_name,
.inherited = .{
.resolved_target = resolved_target,
.optimize_mode = optimize_mode,
},
.global = config,
.cc_argv = &.{},
.parent = null,
});
const walk_mod = try Package.Module.create(arena, .{
.paths = .{
.root = try .fromRoot(arena, dirs, .zig_lib, "docs/wasm"),
.root_src_path = "Walk.zig",
},
.fully_qualified_name = "Walk",
.inherited = .{
.resolved_target = resolved_target,
.optimize_mode = optimize_mode,
},
.global = config,
.cc_argv = &.{},
.parent = root_mod,
});
try root_mod.deps.put(arena, "Walk", walk_mod);
const bin_basename = try std.zig.binNameAlloc(arena, .{
.root_name = root_name,
.target = resolved_target.result,
.output_mode = output_mode,
});
const sub_compilation = try Compilation.create(gpa, arena, .{
.dirs = dirs,
.self_exe_path = comp.self_exe_path,
.config = config,
.root_mod = root_mod,
.entry = .disabled,
.cache_mode = .whole,
.root_name = root_name,
.thread_pool = comp.thread_pool,
.libc_installation = comp.libc_installation,
.emit_bin = .{
.directory = null, // Put it in the cache directory.
.basename = bin_basename,
},
.verbose_cc = comp.verbose_cc,
.verbose_link = comp.verbose_link,
.verbose_air = comp.verbose_air,
.verbose_intern_pool = comp.verbose_intern_pool,
.verbose_generic_instances = comp.verbose_intern_pool,
.verbose_llvm_ir = comp.verbose_llvm_ir,
.verbose_llvm_bc = comp.verbose_llvm_bc,
.verbose_cimport = comp.verbose_cimport,
.verbose_llvm_cpu_features = comp.verbose_llvm_cpu_features,
});
defer sub_compilation.destroy();
try comp.updateSubCompilation(sub_compilation, .docs_wasm, prog_node);
const emit = comp.docs_emit.?;
var out_dir = emit.root_dir.handle.makeOpenPath(emit.sub_path, .{}) catch |err| {
return comp.lockAndSetMiscFailure(
.docs_copy,
"unable to create output directory '{}{s}': {s}",
.{ emit.root_dir, emit.sub_path, @errorName(err) },
);
};
defer out_dir.close();
sub_compilation.dirs.local_cache.handle.copyFile(
sub_compilation.cache_use.whole.bin_sub_path.?,
out_dir,
"main.wasm",
.{},
) catch |err| {
return comp.lockAndSetMiscFailure(.docs_copy, "unable to copy '{}{s}' to '{}{s}': {s}", .{
sub_compilation.dirs.local_cache,
sub_compilation.cache_use.whole.bin_sub_path.?,
emit.root_dir,
emit.sub_path,
@errorName(err),
});
};
}
fn workerUpdateFile(
tid: usize,
comp: *Compilation,
file: *Zcu.File,
file_index: Zcu.File.Index,
prog_node: std.Progress.Node,
wg: *WaitGroup,
) void {
const child_prog_node = prog_node.start(std.fs.path.basename(file.path.sub_path), 0);
defer child_prog_node.end();
const pt: Zcu.PerThread = .activate(comp.zcu.?, @enumFromInt(tid));
defer pt.deactivate();
pt.updateFile(file_index, file) catch |err| {
pt.reportRetryableFileError(file_index, "unable to load '{s}': {s}", .{ std.fs.path.basename(file.path.sub_path), @errorName(err) }) catch |oom| switch (oom) {
error.OutOfMemory => {
comp.mutex.lock();
defer comp.mutex.unlock();
comp.setAllocFailure();
},
};
return;
};
switch (file.getMode()) {
.zig => {}, // continue to logic below
.zon => return, // ZON can't import anything so we're done
}
// Discover all imports in the file. Imports of modules we ignore for now since we don't
// know which module we're in, but imports of file paths might need us to queue up other
// AstGen jobs.
const imports_index = file.zir.?.extra[@intFromEnum(Zir.ExtraIndex.imports)];
if (imports_index != 0) {
const extra = file.zir.?.extraData(Zir.Inst.Imports, imports_index);
var import_i: u32 = 0;
var extra_index = extra.end;
while (import_i < extra.data.imports_len) : (import_i += 1) {
const item = file.zir.?.extraData(Zir.Inst.Imports.Item, extra_index);
extra_index = item.end;
const import_path = file.zir.?.nullTerminatedString(item.data.name);
if (pt.discoverImport(file.path, import_path)) |res| switch (res) {
.module, .existing_file => {},
.new_file => |new| {
comp.thread_pool.spawnWgId(wg, workerUpdateFile, .{
comp, new.file, new.index, prog_node, wg,
});
},
} else |err| switch (err) {
error.OutOfMemory => {
comp.mutex.lock();
defer comp.mutex.unlock();
comp.setAllocFailure();
},
}
}
}
}
fn workerUpdateBuiltinFile(comp: *Compilation, file: *Zcu.File) void {
Builtin.updateFileOnDisk(file, comp) catch |err| {
comp.mutex.lock();
defer comp.mutex.unlock();
comp.setMiscFailure(
.write_builtin_zig,
"unable to write '{}': {s}",
.{ file.path.fmt(comp), @errorName(err) },
);
};
}
fn workerUpdateEmbedFile(tid: usize, comp: *Compilation, ef_index: Zcu.EmbedFile.Index, ef: *Zcu.EmbedFile) void {
comp.detectEmbedFileUpdate(@enumFromInt(tid), ef_index, ef) catch |err| switch (err) {
error.OutOfMemory => {
comp.mutex.lock();
defer comp.mutex.unlock();
comp.setAllocFailure();
},
};
}
fn detectEmbedFileUpdate(comp: *Compilation, tid: Zcu.PerThread.Id, ef_index: Zcu.EmbedFile.Index, ef: *Zcu.EmbedFile) !void {
const zcu = comp.zcu.?;
const pt: Zcu.PerThread = .activate(zcu, tid);
defer pt.deactivate();
const old_val = ef.val;
const old_err = ef.err;
try pt.updateEmbedFile(ef, null);
if (ef.val != .none and ef.val == old_val) return; // success, value unchanged
if (ef.val == .none and old_val == .none and ef.err == old_err) return; // failure, error unchanged
comp.mutex.lock();
defer comp.mutex.unlock();
try zcu.markDependeeOutdated(.not_marked_po, .{ .embed_file = ef_index });
}
pub fn obtainCObjectCacheManifest(
comp: *const Compilation,
owner_mod: *Package.Module,
) Cache.Manifest {
var man = comp.cache_parent.obtain();
// Only things that need to be added on top of the base hash, and only things
// that apply both to @cImport and compiling C objects. No linking stuff here!
// Also nothing that applies only to compiling .zig code.
cache_helpers.addModule(&man.hash, owner_mod);
man.hash.addListOfBytes(comp.global_cc_argv);
man.hash.add(comp.config.link_libcpp);
// When libc_installation is null it means that Zig generated this dir list
// based on the zig library directory alone. The zig lib directory file
// path is purposefully either in the cache or not in the cache. The
// decision should not be overridden here.
if (comp.libc_installation != null) {
man.hash.addListOfBytes(comp.libc_include_dir_list);
}
return man;
}
pub fn obtainWin32ResourceCacheManifest(comp: *const Compilation) Cache.Manifest {
var man = comp.cache_parent.obtain();
man.hash.add(comp.rc_includes);
return man;
}
pub const CImportResult = struct {
digest: [Cache.bin_digest_len]u8,
cache_hit: bool,
errors: std.zig.ErrorBundle,
pub fn deinit(result: *CImportResult, gpa: mem.Allocator) void {
result.errors.deinit(gpa);
}
};
/// Caller owns returned memory.
pub fn cImport(comp: *Compilation, c_src: []const u8, owner_mod: *Package.Module) !CImportResult {
dev.check(.translate_c_command);
const tracy_trace = trace(@src());
defer tracy_trace.end();
const cimport_zig_basename = "cimport.zig";
var man = comp.obtainCObjectCacheManifest(owner_mod);
defer man.deinit();
man.hash.add(@as(u16, 0xb945)); // Random number to distinguish translate-c from compiling C objects
man.hash.addBytes(c_src);
man.hash.add(comp.config.c_frontend);
// If the previous invocation resulted in clang errors, we will see a hit
// here with 0 files in the manifest, in which case it is actually a miss.
// We need to "unhit" in this case, to keep the digests matching.
const prev_hash_state = man.hash.peekBin();
const actual_hit = hit: {
_ = try man.hit();
if (man.files.entries.len == 0) {
man.unhit(prev_hash_state, 0);
break :hit false;
}
break :hit true;
};
const digest = if (!actual_hit) digest: {
var arena_allocator = std.heap.ArenaAllocator.init(comp.gpa);
defer arena_allocator.deinit();
const arena = arena_allocator.allocator();
const tmp_digest = man.hash.peek();
const tmp_dir_sub_path = try std.fs.path.join(arena, &[_][]const u8{ "o", &tmp_digest });
var zig_cache_tmp_dir = try comp.dirs.local_cache.handle.makeOpenPath(tmp_dir_sub_path, .{});
defer zig_cache_tmp_dir.close();
const cimport_basename = "cimport.h";
const out_h_path = try comp.dirs.local_cache.join(arena, &[_][]const u8{
tmp_dir_sub_path, cimport_basename,
});
const out_dep_path = try std.fmt.allocPrint(arena, "{s}.d", .{out_h_path});
try zig_cache_tmp_dir.writeFile(.{ .sub_path = cimport_basename, .data = c_src });
if (comp.verbose_cimport) {
log.info("C import source: {s}", .{out_h_path});
}
var argv = std.ArrayList([]const u8).init(comp.gpa);
defer argv.deinit();
try argv.append(@tagName(comp.config.c_frontend)); // argv[0] is program name, actual args start at [1]
try comp.addTranslateCCArgs(arena, &argv, .c, out_dep_path, owner_mod);
try argv.append(out_h_path);
if (comp.verbose_cc) {
dump_argv(argv.items);
}
var tree = switch (comp.config.c_frontend) {
.aro => tree: {
if (true) @panic("TODO");
break :tree undefined;
},
.clang => tree: {
if (!build_options.have_llvm) unreachable;
const translate_c = @import("translate_c.zig");
// Convert to null terminated args.
const new_argv_with_sentinel = try arena.alloc(?[*:0]const u8, argv.items.len + 1);
new_argv_with_sentinel[argv.items.len] = null;
const new_argv = new_argv_with_sentinel[0..argv.items.len :null];
for (argv.items, 0..) |arg, i| {
new_argv[i] = try arena.dupeZ(u8, arg);
}
const c_headers_dir_path_z = try comp.dirs.zig_lib.joinZ(arena, &.{"include"});
var errors = std.zig.ErrorBundle.empty;
errdefer errors.deinit(comp.gpa);
break :tree translate_c.translate(
comp.gpa,
new_argv.ptr,
new_argv.ptr + new_argv.len,
&errors,
c_headers_dir_path_z,
) catch |err| switch (err) {
error.OutOfMemory => return error.OutOfMemory,
error.SemanticAnalyzeFail => {
return CImportResult{
.digest = undefined,
.cache_hit = actual_hit,
.errors = errors,
};
},
};
},
};
defer tree.deinit(comp.gpa);
if (comp.verbose_cimport) {
log.info("C import .d file: {s}", .{out_dep_path});
}
const dep_basename = std.fs.path.basename(out_dep_path);
try man.addDepFilePost(zig_cache_tmp_dir, dep_basename);
switch (comp.cache_use) {
.whole => |whole| if (whole.cache_manifest) |whole_cache_manifest| {
whole.cache_manifest_mutex.lock();
defer whole.cache_manifest_mutex.unlock();
try whole_cache_manifest.addDepFilePost(zig_cache_tmp_dir, dep_basename);
},
.incremental => {},
}
const bin_digest = man.finalBin();
const hex_digest = Cache.binToHex(bin_digest);
const o_sub_path = "o" ++ std.fs.path.sep_str ++ hex_digest;
var o_dir = try comp.dirs.local_cache.handle.makeOpenPath(o_sub_path, .{});
defer o_dir.close();
var out_zig_file = try o_dir.createFile(cimport_zig_basename, .{});
defer out_zig_file.close();
const formatted = try tree.render(comp.gpa);
defer comp.gpa.free(formatted);
try out_zig_file.writeAll(formatted);
break :digest bin_digest;
} else man.finalBin();
if (man.have_exclusive_lock) {
// Write the updated manifest. This is a no-op if the manifest is not dirty. Note that it is
// possible we had a hit and the manifest is dirty, for example if the file mtime changed but
// the contents were the same, we hit the cache but the manifest is dirty and we need to update
// it to prevent doing a full file content comparison the next time around.
man.writeManifest() catch |err| {
log.warn("failed to write cache manifest for C import: {s}", .{@errorName(err)});
};
}
return CImportResult{
.digest = digest,
.cache_hit = actual_hit,
.errors = std.zig.ErrorBundle.empty,
};
}
fn workerUpdateCObject(
comp: *Compilation,
c_object: *CObject,
progress_node: std.Progress.Node,
) void {
comp.updateCObject(c_object, progress_node) catch |err| switch (err) {
error.AnalysisFail => return,
else => {
comp.reportRetryableCObjectError(c_object, err) catch |oom| switch (oom) {
// Swallowing this error is OK because it's implied to be OOM when
// there is a missing failed_c_objects error message.
error.OutOfMemory => {},
};
},
};
}
fn workerUpdateWin32Resource(
comp: *Compilation,
win32_resource: *Win32Resource,
progress_node: std.Progress.Node,
) void {
comp.updateWin32Resource(win32_resource, progress_node) catch |err| switch (err) {
error.AnalysisFail => return,
else => {
comp.reportRetryableWin32ResourceError(win32_resource, err) catch |oom| switch (oom) {
// Swallowing this error is OK because it's implied to be OOM when
// there is a missing failed_win32_resources error message.
error.OutOfMemory => {},
};
},
};
}
pub const RtOptions = struct {
checks_valgrind: bool = false,
allow_lto: bool = true,
};
fn workerZcuCodegen(
tid: usize,
comp: *Compilation,
func_index: InternPool.Index,
orig_air: Air,
out: *link.ZcuTask.LinkFunc.SharedMir,
) void {
var air = orig_air;
// We own `air` now, so we are responsbile for freeing it.
defer air.deinit(comp.gpa);
const pt: Zcu.PerThread = .activate(comp.zcu.?, @enumFromInt(tid));
defer pt.deactivate();
pt.runCodegen(func_index, &air, out);
}
fn buildRt(
comp: *Compilation,
root_source_name: []const u8,
root_name: []const u8,
output_mode: std.builtin.OutputMode,
misc_task: MiscTask,
prog_node: std.Progress.Node,
options: RtOptions,
out: *?CrtFile,
) void {
comp.buildOutputFromZig(
root_source_name,
root_name,
output_mode,
misc_task,
prog_node,
options,
out,
) catch |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(misc_task, "unable to build {s}: {s}", .{
@tagName(misc_task), @errorName(err),
}),
};
}
fn buildMuslCrtFile(comp: *Compilation, crt_file: musl.CrtFile, prog_node: std.Progress.Node) void {
if (musl.buildCrtFile(comp, crt_file, prog_node)) |_| {
comp.queued_jobs.musl_crt_file[@intFromEnum(crt_file)] = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.musl_crt_file, "unable to build musl {s}: {s}", .{
@tagName(crt_file), @errorName(err),
}),
}
}
fn buildGlibcCrtFile(comp: *Compilation, crt_file: glibc.CrtFile, prog_node: std.Progress.Node) void {
if (glibc.buildCrtFile(comp, crt_file, prog_node)) |_| {
comp.queued_jobs.glibc_crt_file[@intFromEnum(crt_file)] = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.glibc_crt_file, "unable to build glibc {s}: {s}", .{
@tagName(crt_file), @errorName(err),
}),
}
}
fn buildGlibcSharedObjects(comp: *Compilation, prog_node: std.Progress.Node) void {
if (glibc.buildSharedObjects(comp, prog_node)) |_| {
// The job should no longer be queued up since it succeeded.
comp.queued_jobs.glibc_shared_objects = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.glibc_shared_objects, "unable to build glibc shared objects: {s}", .{
@errorName(err),
}),
}
}
fn buildFreeBSDCrtFile(comp: *Compilation, crt_file: freebsd.CrtFile, prog_node: std.Progress.Node) void {
if (freebsd.buildCrtFile(comp, crt_file, prog_node)) |_| {
comp.queued_jobs.freebsd_crt_file[@intFromEnum(crt_file)] = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.freebsd_crt_file, "unable to build FreeBSD {s}: {s}", .{
@tagName(crt_file), @errorName(err),
}),
}
}
fn buildFreeBSDSharedObjects(comp: *Compilation, prog_node: std.Progress.Node) void {
if (freebsd.buildSharedObjects(comp, prog_node)) |_| {
// The job should no longer be queued up since it succeeded.
comp.queued_jobs.freebsd_shared_objects = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.freebsd_shared_objects, "unable to build FreeBSD libc shared objects: {s}", .{
@errorName(err),
}),
}
}
fn buildNetBSDCrtFile(comp: *Compilation, crt_file: netbsd.CrtFile, prog_node: std.Progress.Node) void {
if (netbsd.buildCrtFile(comp, crt_file, prog_node)) |_| {
comp.queued_jobs.netbsd_crt_file[@intFromEnum(crt_file)] = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.netbsd_crt_file, "unable to build NetBSD {s}: {s}", .{
@tagName(crt_file), @errorName(err),
}),
}
}
fn buildNetBSDSharedObjects(comp: *Compilation, prog_node: std.Progress.Node) void {
if (netbsd.buildSharedObjects(comp, prog_node)) |_| {
// The job should no longer be queued up since it succeeded.
comp.queued_jobs.netbsd_shared_objects = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.netbsd_shared_objects, "unable to build NetBSD libc shared objects: {s}", .{
@errorName(err),
}),
}
}
fn buildMingwCrtFile(comp: *Compilation, crt_file: mingw.CrtFile, prog_node: std.Progress.Node) void {
if (mingw.buildCrtFile(comp, crt_file, prog_node)) |_| {
comp.queued_jobs.mingw_crt_file[@intFromEnum(crt_file)] = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.mingw_crt_file, "unable to build mingw-w64 {s}: {s}", .{
@tagName(crt_file), @errorName(err),
}),
}
}
fn buildWasiLibcCrtFile(comp: *Compilation, crt_file: wasi_libc.CrtFile, prog_node: std.Progress.Node) void {
if (wasi_libc.buildCrtFile(comp, crt_file, prog_node)) |_| {
comp.queued_jobs.wasi_libc_crt_file[@intFromEnum(crt_file)] = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.wasi_libc_crt_file, "unable to build WASI libc {s}: {s}", .{
@tagName(crt_file), @errorName(err),
}),
}
}
fn buildLibUnwind(comp: *Compilation, prog_node: std.Progress.Node) void {
if (libunwind.buildStaticLib(comp, prog_node)) |_| {
comp.queued_jobs.libunwind = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.libunwind, "unable to build libunwind: {s}", .{@errorName(err)}),
}
}
fn buildLibCxx(comp: *Compilation, prog_node: std.Progress.Node) void {
if (libcxx.buildLibCxx(comp, prog_node)) |_| {
comp.queued_jobs.libcxx = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.libcxx, "unable to build libcxx: {s}", .{@errorName(err)}),
}
}
fn buildLibCxxAbi(comp: *Compilation, prog_node: std.Progress.Node) void {
if (libcxx.buildLibCxxAbi(comp, prog_node)) |_| {
comp.queued_jobs.libcxxabi = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.libcxxabi, "unable to build libcxxabi: {s}", .{@errorName(err)}),
}
}
fn buildLibTsan(comp: *Compilation, prog_node: std.Progress.Node) void {
if (libtsan.buildTsan(comp, prog_node)) |_| {
comp.queued_jobs.libtsan = false;
} else |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.libtsan, "unable to build TSAN library: {s}", .{@errorName(err)}),
}
}
fn buildLibZigC(comp: *Compilation, prog_node: std.Progress.Node) void {
comp.buildOutputFromZig(
"c.zig",
"zigc",
.Lib,
.libzigc,
prog_node,
.{},
&comp.zigc_static_lib,
) catch |err| switch (err) {
error.SubCompilationFailed => return, // error reported already
else => comp.lockAndSetMiscFailure(.libzigc, "unable to build libzigc: {s}", .{@errorName(err)}),
};
}
fn reportRetryableCObjectError(
comp: *Compilation,
c_object: *CObject,
err: anyerror,
) error{OutOfMemory}!void {
c_object.status = .failure_retryable;
switch (comp.failCObj(c_object, "{s}", .{@errorName(err)})) {
error.AnalysisFail => return,
else => |e| return e,
}
}
fn reportRetryableWin32ResourceError(
comp: *Compilation,
win32_resource: *Win32Resource,
err: anyerror,
) error{OutOfMemory}!void {
win32_resource.status = .failure_retryable;
var bundle: ErrorBundle.Wip = undefined;
try bundle.init(comp.gpa);
errdefer bundle.deinit();
try bundle.addRootErrorMessage(.{
.msg = try bundle.printString("{s}", .{@errorName(err)}),
.src_loc = try bundle.addSourceLocation(.{
.src_path = try bundle.addString(switch (win32_resource.src) {
.rc => |rc_src| rc_src.src_path,
.manifest => |manifest_src| manifest_src,
}),
.line = 0,
.column = 0,
.span_start = 0,
.span_main = 0,
.span_end = 0,
}),
});
const finished_bundle = try bundle.toOwnedBundle("");
{
comp.mutex.lock();
defer comp.mutex.unlock();
try comp.failed_win32_resources.putNoClobber(comp.gpa, win32_resource, finished_bundle);
}
}
fn updateCObject(comp: *Compilation, c_object: *CObject, c_obj_prog_node: std.Progress.Node) !void {
if (comp.config.c_frontend == .aro) {
return comp.failCObj(c_object, "aro does not support compiling C objects yet", .{});
}
if (!build_options.have_llvm) {
return comp.failCObj(c_object, "clang not available: compiler built without LLVM extensions", .{});
}
const self_exe_path = comp.self_exe_path orelse
return comp.failCObj(c_object, "clang compilation disabled", .{});
const tracy_trace = trace(@src());
defer tracy_trace.end();
log.debug("updating C object: {s}", .{c_object.src.src_path});
const gpa = comp.gpa;
if (c_object.clearStatus(gpa)) {
// There was previous failure.
comp.mutex.lock();
defer comp.mutex.unlock();
// If the failure was OOM, there will not be an entry here, so we do
// not assert discard.
_ = comp.failed_c_objects.swapRemove(c_object);
}
var man = comp.obtainCObjectCacheManifest(c_object.src.owner);
defer man.deinit();
man.hash.add(comp.clang_preprocessor_mode);
cache_helpers.addOptionalEmitLoc(&man.hash, comp.emit_asm);
cache_helpers.addOptionalEmitLoc(&man.hash, comp.emit_llvm_ir);
cache_helpers.addOptionalEmitLoc(&man.hash, comp.emit_llvm_bc);
try cache_helpers.hashCSource(&man, c_object.src);
var arena_allocator = std.heap.ArenaAllocator.init(gpa);
defer arena_allocator.deinit();
const arena = arena_allocator.allocator();
const c_source_basename = std.fs.path.basename(c_object.src.src_path);
const child_progress_node = c_obj_prog_node.start(c_source_basename, 0);
defer child_progress_node.end();
// Special case when doing build-obj for just one C file. When there are more than one object
// file and building an object we need to link them together, but with just one it should go
// directly to the output file.
const direct_o = comp.c_source_files.len == 1 and comp.zcu == null and
comp.config.output_mode == .Obj and !link.anyObjectInputs(comp.link_inputs);
const o_basename_noext = if (direct_o)
comp.root_name
else
c_source_basename[0 .. c_source_basename.len - std.fs.path.extension(c_source_basename).len];
const target = comp.getTarget();
const o_ext = target.ofmt.fileExt(target.cpu.arch);
const digest = if (!comp.disable_c_depfile and try man.hit()) man.final() else blk: {
var argv = std.ArrayList([]const u8).init(gpa);
defer argv.deinit();
// In case we are doing passthrough mode, we need to detect -S and -emit-llvm.
const out_ext = e: {
if (!comp.clang_passthrough_mode)
break :e o_ext;
if (comp.emit_asm != null)
break :e ".s";
if (comp.emit_llvm_ir != null)
break :e ".ll";
if (comp.emit_llvm_bc != null)
break :e ".bc";
break :e o_ext;
};
const o_basename = try std.fmt.allocPrint(arena, "{s}{s}", .{ o_basename_noext, out_ext });
const ext = c_object.src.ext orelse classifyFileExt(c_object.src.src_path);
try argv.appendSlice(&[_][]const u8{ self_exe_path, "clang" });
// if "ext" is explicit, add "-x <lang>". Otherwise let clang do its thing.
if (c_object.src.ext != null or ext.clangNeedsLanguageOverride()) {
try argv.appendSlice(&[_][]const u8{ "-x", switch (ext) {
.assembly => "assembler",
.assembly_with_cpp => "assembler-with-cpp",
.c => "c",
.h => "c-header",
.cpp => "c++",
.hpp => "c++-header",
.m => "objective-c",
.hm => "objective-c-header",
.mm => "objective-c++",
.hmm => "objective-c++-header",
else => fatal("language '{s}' is unsupported in this context", .{@tagName(ext)}),
} });
}
try argv.append(c_object.src.src_path);
// When all these flags are true, it means that the entire purpose of
// this compilation is to perform a single zig cc operation. This means
// that we could "tail call" clang by doing an execve, and any use of
// the caching system would actually be problematic since the user is
// presumably doing their own caching by using dep file flags.
if (std.process.can_execv and direct_o and
comp.disable_c_depfile and comp.clang_passthrough_mode)
{
try comp.addCCArgs(arena, &argv, ext, null, c_object.src.owner);
try argv.appendSlice(c_object.src.extra_flags);
try argv.appendSlice(c_object.src.cache_exempt_flags);
const out_obj_path = if (comp.bin_file) |lf|
try lf.emit.root_dir.join(arena, &.{lf.emit.sub_path})
else
"/dev/null";
try argv.ensureUnusedCapacity(6);
switch (comp.clang_preprocessor_mode) {
.no => argv.appendSliceAssumeCapacity(&.{ "-c", "-o", out_obj_path }),
.yes => argv.appendSliceAssumeCapacity(&.{ "-E", "-o", out_obj_path }),
.pch => argv.appendSliceAssumeCapacity(&.{ "-Xclang", "-emit-pch", "-o", out_obj_path }),
.stdout => argv.appendAssumeCapacity("-E"),
}
if (comp.emit_asm != null) {
argv.appendAssumeCapacity("-S");
} else if (comp.emit_llvm_ir != null) {
argv.appendSliceAssumeCapacity(&[_][]const u8{ "-emit-llvm", "-S" });
} else if (comp.emit_llvm_bc != null) {
argv.appendAssumeCapacity("-emit-llvm");
}
if (comp.verbose_cc) {
dump_argv(argv.items);
}
const err = std.process.execv(arena, argv.items);
fatal("unable to execv clang: {s}", .{@errorName(err)});
}
// We can't know the digest until we do the C compiler invocation,
// so we need a temporary filename.
const out_obj_path = try comp.tmpFilePath(arena, o_basename);
var zig_cache_tmp_dir = try comp.dirs.local_cache.handle.makeOpenPath("tmp", .{});
defer zig_cache_tmp_dir.close();
const out_diag_path = if (comp.clang_passthrough_mode or !ext.clangSupportsDiagnostics())
null
else
try std.fmt.allocPrint(arena, "{s}.diag", .{out_obj_path});
const out_dep_path = if (comp.disable_c_depfile or !ext.clangSupportsDepFile())
null
else
try std.fmt.allocPrint(arena, "{s}.d", .{out_obj_path});
try comp.addCCArgs(arena, &argv, ext, out_dep_path, c_object.src.owner);
try argv.appendSlice(c_object.src.extra_flags);
try argv.appendSlice(c_object.src.cache_exempt_flags);
try argv.ensureUnusedCapacity(6);
switch (comp.clang_preprocessor_mode) {
.no => argv.appendSliceAssumeCapacity(&.{ "-c", "-o", out_obj_path }),
.yes => argv.appendSliceAssumeCapacity(&.{ "-E", "-o", out_obj_path }),
.pch => argv.appendSliceAssumeCapacity(&.{ "-Xclang", "-emit-pch", "-o", out_obj_path }),
.stdout => argv.appendAssumeCapacity("-E"),
}
if (out_diag_path) |diag_file_path| {
argv.appendSliceAssumeCapacity(&.{ "--serialize-diagnostics", diag_file_path });
} else if (comp.clang_passthrough_mode) {
if (comp.emit_asm != null) {
argv.appendAssumeCapacity("-S");
} else if (comp.emit_llvm_ir != null) {
argv.appendSliceAssumeCapacity(&.{ "-emit-llvm", "-S" });
} else if (comp.emit_llvm_bc != null) {
argv.appendAssumeCapacity("-emit-llvm");
}
}
if (comp.verbose_cc) {
dump_argv(argv.items);
}
// Just to save disk space, we delete the files that are never needed again.
defer if (out_diag_path) |diag_file_path| zig_cache_tmp_dir.deleteFile(std.fs.path.basename(diag_file_path)) catch |err| switch (err) {
error.FileNotFound => {}, // the file wasn't created due to an error we reported
else => log.warn("failed to delete '{s}': {s}", .{ diag_file_path, @errorName(err) }),
};
defer if (out_dep_path) |dep_file_path| zig_cache_tmp_dir.deleteFile(std.fs.path.basename(dep_file_path)) catch |err| switch (err) {
error.FileNotFound => {}, // the file wasn't created due to an error we reported
else => log.warn("failed to delete '{s}': {s}", .{ dep_file_path, @errorName(err) }),
};
if (std.process.can_spawn) {
var child = std.process.Child.init(argv.items, arena);
if (comp.clang_passthrough_mode) {
child.stdin_behavior = .Inherit;
child.stdout_behavior = .Inherit;
child.stderr_behavior = .Inherit;
const term = child.spawnAndWait() catch |err| {
return comp.failCObj(c_object, "failed to spawn zig clang (passthrough mode) {s}: {s}", .{ argv.items[0], @errorName(err) });
};
switch (term) {
.Exited => |code| {
if (code != 0) {
std.process.exit(code);
}
if (comp.clang_preprocessor_mode == .stdout)
std.process.exit(0);
},
else => std.process.abort(),
}
} else {
child.stdin_behavior = .Ignore;
child.stdout_behavior = .Ignore;
child.stderr_behavior = .Pipe;
try child.spawn();
const stderr = try child.stderr.?.reader().readAllAlloc(arena, std.math.maxInt(usize));
const term = child.wait() catch |err| {
return comp.failCObj(c_object, "failed to spawn zig clang {s}: {s}", .{ argv.items[0], @errorName(err) });
};
switch (term) {
.Exited => |code| if (code != 0) if (out_diag_path) |diag_file_path| {
const bundle = CObject.Diag.Bundle.parse(gpa, diag_file_path) catch |err| {
log.err("{}: failed to parse clang diagnostics: {s}", .{ err, stderr });
return comp.failCObj(c_object, "clang exited with code {d}", .{code});
};
return comp.failCObjWithOwnedDiagBundle(c_object, bundle);
} else {
log.err("clang failed with stderr: {s}", .{stderr});
return comp.failCObj(c_object, "clang exited with code {d}", .{code});
},
else => {
log.err("clang terminated with stderr: {s}", .{stderr});
return comp.failCObj(c_object, "clang terminated unexpectedly", .{});
},
}
}
} else {
const exit_code = try clangMain(arena, argv.items);
if (exit_code != 0) {
if (comp.clang_passthrough_mode) {
std.process.exit(exit_code);
} else {
return comp.failCObj(c_object, "clang exited with code {d}", .{exit_code});
}
}
if (comp.clang_passthrough_mode and
comp.clang_preprocessor_mode == .stdout)
{
std.process.exit(0);
}
}
if (out_dep_path) |dep_file_path| {
const dep_basename = std.fs.path.basename(dep_file_path);
// Add the files depended on to the cache system.
try man.addDepFilePost(zig_cache_tmp_dir, dep_basename);
switch (comp.cache_use) {
.whole => |whole| {
if (whole.cache_manifest) |whole_cache_manifest| {
whole.cache_manifest_mutex.lock();
defer whole.cache_manifest_mutex.unlock();
try whole_cache_manifest.addDepFilePost(zig_cache_tmp_dir, dep_basename);
}
},
.incremental => {},
}
}
// We don't actually care whether it's a cache hit or miss; we just need the digest and the lock.
if (comp.disable_c_depfile) _ = try man.hit();
// Rename into place.
const digest = man.final();
const o_sub_path = try std.fs.path.join(arena, &[_][]const u8{ "o", &digest });
var o_dir = try comp.dirs.local_cache.handle.makeOpenPath(o_sub_path, .{});
defer o_dir.close();
const tmp_basename = std.fs.path.basename(out_obj_path);
try std.fs.rename(zig_cache_tmp_dir, tmp_basename, o_dir, o_basename);
break :blk digest;
};
if (man.have_exclusive_lock) {
// Write the updated manifest. This is a no-op if the manifest is not dirty. Note that it is
// possible we had a hit and the manifest is dirty, for example if the file mtime changed but
// the contents were the same, we hit the cache but the manifest is dirty and we need to update
// it to prevent doing a full file content comparison the next time around.
man.writeManifest() catch |err| {
log.warn("failed to write cache manifest when compiling '{s}': {s}", .{
c_object.src.src_path, @errorName(err),
});
};
}
const o_basename = try std.fmt.allocPrint(arena, "{s}{s}", .{ o_basename_noext, o_ext });
c_object.status = .{
.success = .{
.object_path = .{
.root_dir = comp.dirs.local_cache,
.sub_path = try std.fs.path.join(gpa, &.{ "o", &digest, o_basename }),
},
.lock = man.toOwnedLock(),
},
};
comp.queuePrelinkTasks(&.{.{ .load_object = c_object.status.success.object_path }});
}
fn updateWin32Resource(comp: *Compilation, win32_resource: *Win32Resource, win32_resource_prog_node: std.Progress.Node) !void {
if (!std.process.can_spawn) {
return comp.failWin32Resource(win32_resource, "{s} does not support spawning a child process", .{@tagName(builtin.os.tag)});
}
const self_exe_path = comp.self_exe_path orelse
return comp.failWin32Resource(win32_resource, "unable to find self exe path", .{});
const tracy_trace = trace(@src());
defer tracy_trace.end();
const src_path = switch (win32_resource.src) {
.rc => |rc_src| rc_src.src_path,
.manifest => |src_path| src_path,
};
const src_basename = std.fs.path.basename(src_path);
log.debug("updating win32 resource: {s}", .{src_path});
var arena_allocator = std.heap.ArenaAllocator.init(comp.gpa);
defer arena_allocator.deinit();
const arena = arena_allocator.allocator();
if (win32_resource.clearStatus(comp.gpa)) {
// There was previous failure.
comp.mutex.lock();
defer comp.mutex.unlock();
// If the failure was OOM, there will not be an entry here, so we do
// not assert discard.
_ = comp.failed_win32_resources.swapRemove(win32_resource);
}
const child_progress_node = win32_resource_prog_node.start(src_basename, 0);
defer child_progress_node.end();
var man = comp.obtainWin32ResourceCacheManifest();
defer man.deinit();
// For .manifest files, we ultimately just want to generate a .res with
// the XML data as a RT_MANIFEST resource. This means we can skip preprocessing,
// include paths, CLI options, etc.
if (win32_resource.src == .manifest) {
_ = try man.addFile(src_path, null);
const rc_basename = try std.fmt.allocPrint(arena, "{s}.rc", .{src_basename});
const res_basename = try std.fmt.allocPrint(arena, "{s}.res", .{src_basename});
const digest = if (try man.hit()) man.final() else blk: {
// The digest only depends on the .manifest file, so we can
// get the digest now and write the .res directly to the cache
const digest = man.final();
const o_sub_path = try std.fs.path.join(arena, &.{ "o", &digest });
var o_dir = try comp.dirs.local_cache.handle.makeOpenPath(o_sub_path, .{});
defer o_dir.close();
const in_rc_path = try comp.dirs.local_cache.join(comp.gpa, &.{
o_sub_path, rc_basename,
});
const out_res_path = try comp.dirs.local_cache.join(comp.gpa, &.{
o_sub_path, res_basename,
});
// In .rc files, a " within a quoted string is escaped as ""
const fmtRcEscape = struct {
fn formatRcEscape(bytes: []const u8, comptime fmt: []const u8, options: std.fmt.FormatOptions, writer: anytype) !void {
_ = fmt;
_ = options;
for (bytes) |byte| switch (byte) {
'"' => try writer.writeAll("\"\""),
'\\' => try writer.writeAll("\\\\"),
else => try writer.writeByte(byte),
};
}
pub fn fmtRcEscape(bytes: []const u8) std.fmt.Formatter(formatRcEscape) {
return .{ .data = bytes };
}
}.fmtRcEscape;
// https://learn.microsoft.com/en-us/windows/win32/sbscs/using-side-by-side-assemblies-as-a-resource
// WinUser.h defines:
// CREATEPROCESS_MANIFEST_RESOURCE_ID to 1, which is the default
// ISOLATIONAWARE_MANIFEST_RESOURCE_ID to 2, which must be used for .dlls
const resource_id: u32 = if (comp.config.output_mode == .Lib and comp.config.link_mode == .dynamic) 2 else 1;
// 24 is RT_MANIFEST
const resource_type = 24;
const input = try std.fmt.allocPrint(arena, "{} {} \"{s}\"", .{ resource_id, resource_type, fmtRcEscape(src_path) });
try o_dir.writeFile(.{ .sub_path = rc_basename, .data = input });
var argv = std.ArrayList([]const u8).init(comp.gpa);
defer argv.deinit();
try argv.appendSlice(&.{
self_exe_path,
"rc",
"--zig-integration",
"/:no-preprocess",
"/x", // ignore INCLUDE environment variable
"/c65001", // UTF-8 codepage
"/:auto-includes",
"none",
});
try argv.appendSlice(&.{ "--", in_rc_path, out_res_path });
try spawnZigRc(comp, win32_resource, arena, argv.items, child_progress_node);
break :blk digest;
};
if (man.have_exclusive_lock) {
man.writeManifest() catch |err| {
log.warn("failed to write cache manifest when compiling '{s}': {s}", .{ src_path, @errorName(err) });
};
}
win32_resource.status = .{
.success = .{
.res_path = try comp.dirs.local_cache.join(comp.gpa, &[_][]const u8{
"o", &digest, res_basename,
}),
.lock = man.toOwnedLock(),
},
};
return;
}
// We now know that we're compiling an .rc file
const rc_src = win32_resource.src.rc;
_ = try man.addFile(rc_src.src_path, null);
man.hash.addListOfBytes(rc_src.extra_flags);
const rc_basename_noext = src_basename[0 .. src_basename.len - std.fs.path.extension(src_basename).len];
const digest = if (try man.hit()) man.final() else blk: {
var zig_cache_tmp_dir = try comp.dirs.local_cache.handle.makeOpenPath("tmp", .{});
defer zig_cache_tmp_dir.close();
const res_filename = try std.fmt.allocPrint(arena, "{s}.res", .{rc_basename_noext});
// We can't know the digest until we do the compilation,
// so we need a temporary filename.
const out_res_path = try comp.tmpFilePath(arena, res_filename);
var argv = std.ArrayList([]const u8).init(comp.gpa);
defer argv.deinit();
const depfile_filename = try std.fmt.allocPrint(arena, "{s}.d.json", .{rc_basename_noext});
const out_dep_path = try comp.tmpFilePath(arena, depfile_filename);
try argv.appendSlice(&.{
self_exe_path,
"rc",
"--zig-integration",
"/:depfile",
out_dep_path,
"/:depfile-fmt",
"json",
"/x", // ignore INCLUDE environment variable
"/:auto-includes",
@tagName(comp.rc_includes),
});
// While these defines are not normally present when calling rc.exe directly,
// them being defined matches the behavior of how MSVC calls rc.exe which is the more
// relevant behavior in this case.
switch (rc_src.owner.optimize_mode) {
.Debug, .ReleaseSafe => {},
.ReleaseFast, .ReleaseSmall => try argv.append("-DNDEBUG"),
}
try argv.appendSlice(rc_src.extra_flags);
try argv.appendSlice(&.{ "--", rc_src.src_path, out_res_path });
try spawnZigRc(comp, win32_resource, arena, argv.items, child_progress_node);
// Read depfile and update cache manifest
{
const dep_basename = std.fs.path.basename(out_dep_path);
const dep_file_contents = try zig_cache_tmp_dir.readFileAlloc(arena, dep_basename, 50 * 1024 * 1024);
defer arena.free(dep_file_contents);
const value = try std.json.parseFromSliceLeaky(std.json.Value, arena, dep_file_contents, .{});
if (value != .array) {
return comp.failWin32Resource(win32_resource, "depfile from zig rc has unexpected format", .{});
}
for (value.array.items) |element| {
if (element != .string) {
return comp.failWin32Resource(win32_resource, "depfile from zig rc has unexpected format", .{});
}
const dep_file_path = element.string;
try man.addFilePost(dep_file_path);
switch (comp.cache_use) {
.whole => |whole| if (whole.cache_manifest) |whole_cache_manifest| {
whole.cache_manifest_mutex.lock();
defer whole.cache_manifest_mutex.unlock();
try whole_cache_manifest.addFilePost(dep_file_path);
},
.incremental => {},
}
}
}
// Rename into place.
const digest = man.final();
const o_sub_path = try std.fs.path.join(arena, &[_][]const u8{ "o", &digest });
var o_dir = try comp.dirs.local_cache.handle.makeOpenPath(o_sub_path, .{});
defer o_dir.close();
const tmp_basename = std.fs.path.basename(out_res_path);
try std.fs.rename(zig_cache_tmp_dir, tmp_basename, o_dir, res_filename);
break :blk digest;
};
if (man.have_exclusive_lock) {
// Write the updated manifest. This is a no-op if the manifest is not dirty. Note that it is
// possible we had a hit and the manifest is dirty, for example if the file mtime changed but
// the contents were the same, we hit the cache but the manifest is dirty and we need to update
// it to prevent doing a full file content comparison the next time around.
man.writeManifest() catch |err| {
log.warn("failed to write cache manifest when compiling '{s}': {s}", .{ rc_src.src_path, @errorName(err) });
};
}
const res_basename = try std.fmt.allocPrint(arena, "{s}.res", .{rc_basename_noext});
win32_resource.status = .{
.success = .{
.res_path = try comp.dirs.local_cache.join(comp.gpa, &[_][]const u8{
"o", &digest, res_basename,
}),
.lock = man.toOwnedLock(),
},
};
}
fn spawnZigRc(
comp: *Compilation,
win32_resource: *Win32Resource,
arena: Allocator,
argv: []const []const u8,
child_progress_node: std.Progress.Node,
) !void {
var node_name: std.ArrayListUnmanaged(u8) = .empty;
defer node_name.deinit(arena);
var child = std.process.Child.init(argv, arena);
child.stdin_behavior = .Ignore;
child.stdout_behavior = .Pipe;
child.stderr_behavior = .Pipe;
child.progress_node = child_progress_node;
child.spawn() catch |err| {
return comp.failWin32Resource(win32_resource, "unable to spawn {s} rc: {s}", .{ argv[0], @errorName(err) });
};
var poller = std.io.poll(comp.gpa, enum { stdout }, .{
.stdout = child.stdout.?,
});
defer poller.deinit();
const stdout = poller.fifo(.stdout);
poll: while (true) {
while (stdout.readableLength() < @sizeOf(std.zig.Server.Message.Header)) {
if (!(try poller.poll())) break :poll;
}
const header = stdout.reader().readStruct(std.zig.Server.Message.Header) catch unreachable;
while (stdout.readableLength() < header.bytes_len) {
if (!(try poller.poll())) break :poll;
}
const body = stdout.readableSliceOfLen(header.bytes_len);
switch (header.tag) {
// We expect exactly one ErrorBundle, and if any error_bundle header is
// sent then it's a fatal error.
.error_bundle => {
const EbHdr = std.zig.Server.Message.ErrorBundle;
const eb_hdr = @as(*align(1) const EbHdr, @ptrCast(body));
const extra_bytes =
body[@sizeOf(EbHdr)..][0 .. @sizeOf(u32) * eb_hdr.extra_len];
const string_bytes =
body[@sizeOf(EbHdr) + extra_bytes.len ..][0..eb_hdr.string_bytes_len];
const unaligned_extra = std.mem.bytesAsSlice(u32, extra_bytes);
const extra_array = try comp.gpa.alloc(u32, unaligned_extra.len);
@memcpy(extra_array, unaligned_extra);
const error_bundle = std.zig.ErrorBundle{
.string_bytes = try comp.gpa.dupe(u8, string_bytes),
.extra = extra_array,
};
return comp.failWin32ResourceWithOwnedBundle(win32_resource, error_bundle);
},
else => {}, // ignore other messages
}
stdout.discard(body.len);
}
// Just in case there's a failure that didn't send an ErrorBundle (e.g. an error return trace)
const stderr_reader = child.stderr.?.reader();
const stderr = try stderr_reader.readAllAlloc(arena, 10 * 1024 * 1024);
const term = child.wait() catch |err| {
return comp.failWin32Resource(win32_resource, "unable to wait for {s} rc: {s}", .{ argv[0], @errorName(err) });
};
switch (term) {
.Exited => |code| {
if (code != 0) {
log.err("zig rc failed with stderr:\n{s}", .{stderr});
return comp.failWin32Resource(win32_resource, "zig rc exited with code {d}", .{code});
}
},
else => {
log.err("zig rc terminated with stderr:\n{s}", .{stderr});
return comp.failWin32Resource(win32_resource, "zig rc terminated unexpectedly", .{});
},
}
}
pub fn tmpFilePath(comp: Compilation, ally: Allocator, suffix: []const u8) error{OutOfMemory}![]const u8 {
const s = std.fs.path.sep_str;
const rand_int = std.crypto.random.int(u64);
if (comp.dirs.local_cache.path) |p| {
return std.fmt.allocPrint(ally, "{s}" ++ s ++ "tmp" ++ s ++ "{x}-{s}", .{ p, rand_int, suffix });
} else {
return std.fmt.allocPrint(ally, "tmp" ++ s ++ "{x}-{s}", .{ rand_int, suffix });
}
}
pub fn addTranslateCCArgs(
comp: *Compilation,
arena: Allocator,
argv: *std.ArrayList([]const u8),
ext: FileExt,
out_dep_path: ?[]const u8,
owner_mod: *Package.Module,
) !void {
try argv.appendSlice(&.{ "-x", "c" });
try comp.addCCArgs(arena, argv, ext, out_dep_path, owner_mod);
// This gives us access to preprocessing entities, presumably at the cost of performance.
try argv.appendSlice(&.{ "-Xclang", "-detailed-preprocessing-record" });
}
/// Add common C compiler args between translate-c and C object compilation.
pub fn addCCArgs(
comp: *const Compilation,
arena: Allocator,
argv: *std.ArrayList([]const u8),
ext: FileExt,
out_dep_path: ?[]const u8,
mod: *Package.Module,
) !void {
const target = mod.resolved_target.result;
// As of Clang 16.x, it will by default read extra flags from /etc/clang.
// I'm sure the person who implemented this means well, but they have a lot
// to learn about abstractions and where the appropriate boundaries between
// them are. The road to hell is paved with good intentions. Fortunately it
// can be disabled.
try argv.append("--no-default-config");
// We don't ever put `-fcolor-diagnostics` or `-fno-color-diagnostics` because in passthrough mode
// we want Clang to infer it, and in normal mode we always want it off, which will be true since
// clang will detect stderr as a pipe rather than a terminal.
if (!comp.clang_passthrough_mode and ext.clangSupportsDiagnostics()) {
// Make stderr more easily parseable.
try argv.append("-fno-caret-diagnostics");
}
// We never want clang to invoke the system assembler for anything. So we would want
// this option always enabled. However, it only matters for some targets. To avoid
// "unused parameter" warnings, and to keep CLI spam to a minimum, we only put this
// flag on the command line if it is necessary.
if (target_util.clangMightShellOutForAssembly(target)) {
try argv.append("-integrated-as");
}
const llvm_triple = try @import("codegen/llvm.zig").targetTriple(arena, target);
try argv.appendSlice(&[_][]const u8{ "-target", llvm_triple });
switch (target.os.tag) {
.ios, .macos, .tvos, .watchos => |os| {
try argv.ensureUnusedCapacity(2);
// Pass the proper -m<os>-version-min argument for darwin.
const ver = target.os.version_range.semver.min;
argv.appendAssumeCapacity(try std.fmt.allocPrint(arena, "-m{s}{s}-version-min={d}.{d}.{d}", .{
@tagName(os),
switch (target.abi) {
.simulator => "-simulator",
else => "",
},
ver.major,
ver.minor,
ver.patch,
}));
// This avoids a warning that sometimes occurs when
// providing both a -target argument that contains a
// version as well as the -mmacosx-version-min argument.
// Zig provides the correct value in both places, so it
// doesn't matter which one gets overridden.
argv.appendAssumeCapacity("-Wno-overriding-option");
},
else => {},
}
if (target.cpu.arch.isArm()) {
try argv.append(if (target.cpu.arch.isThumb()) "-mthumb" else "-mno-thumb");
}
if (target_util.llvmMachineAbi(target)) |mabi| {
// Clang's integrated Arm assembler doesn't support `-mabi` yet...
// Clang's FreeBSD driver doesn't support `-mabi` on PPC64 (ELFv2 is used anyway).
if (!(target.cpu.arch.isArm() and (ext == .assembly or ext == .assembly_with_cpp)) and
!(target.cpu.arch.isPowerPC64() and target.os.tag == .freebsd))
{
try argv.append(try std.fmt.allocPrint(arena, "-mabi={s}", .{mabi}));
}
}
// We might want to support -mfloat-abi=softfp for Arm and CSKY here in the future.
if (target_util.clangSupportsFloatAbiArg(target)) {
const fabi = @tagName(target.abi.float());
try argv.append(switch (target.cpu.arch) {
// For whatever reason, Clang doesn't support `-mfloat-abi` for s390x.
.s390x => try std.fmt.allocPrint(arena, "-m{s}-float", .{fabi}),
else => try std.fmt.allocPrint(arena, "-mfloat-abi={s}", .{fabi}),
});
}
if (target_util.supports_fpic(target)) {
// PIE needs to go before PIC because Clang interprets `-fno-PIE` to imply `-fno-PIC`, which
// we don't necessarily want.
try argv.append(if (comp.config.pie) "-fPIE" else "-fno-PIE");
try argv.append(if (mod.pic) "-fPIC" else "-fno-PIC");
}
if (comp.mingw_unicode_entry_point) {
try argv.append("-municode");
}
if (mod.code_model != .default) {
try argv.append(try std.fmt.allocPrint(arena, "-mcmodel={s}", .{@tagName(mod.code_model)}));
}
try argv.ensureUnusedCapacity(2);
switch (comp.config.debug_format) {
.strip => {},
.code_view => {
// -g is required here because -gcodeview doesn't trigger debug info
// generation, it only changes the type of information generated.
argv.appendSliceAssumeCapacity(&.{ "-g", "-gcodeview" });
},
.dwarf => |f| {
argv.appendAssumeCapacity("-gdwarf-4");
switch (f) {
.@"32" => argv.appendAssumeCapacity("-gdwarf32"),
.@"64" => argv.appendAssumeCapacity("-gdwarf64"),
}
},
}
switch (comp.config.lto) {
.none => try argv.append("-fno-lto"),
.full => try argv.append("-flto=full"),
.thin => try argv.append("-flto=thin"),
}
// This only works for preprocessed files. Guarded by `FileExt.clangSupportsDepFile`.
if (out_dep_path) |p| {
try argv.appendSlice(&[_][]const u8{ "-MD", "-MV", "-MF", p });
}
// Non-preprocessed assembly files don't support these flags.
if (ext != .assembly) {
try argv.append(if (target.os.tag == .freestanding) "-ffreestanding" else "-fhosted");
if (target_util.clangSupportsNoImplicitFloatArg(target) and target.abi.float() == .soft) {
try argv.append("-mno-implicit-float");
}
if (target_util.hasRedZone(target)) {
try argv.append(if (mod.red_zone) "-mred-zone" else "-mno-red-zone");
}
try argv.append(if (mod.omit_frame_pointer) "-fomit-frame-pointer" else "-fno-omit-frame-pointer");
const ssp_buf_size = mod.stack_protector;
if (ssp_buf_size != 0) {
try argv.appendSlice(&[_][]const u8{
"-fstack-protector-strong",
"--param",
try std.fmt.allocPrint(arena, "ssp-buffer-size={d}", .{ssp_buf_size}),
});
} else {
try argv.append("-fno-stack-protector");
}
try argv.append(if (mod.no_builtin) "-fno-builtin" else "-fbuiltin");
try argv.append(if (comp.function_sections) "-ffunction-sections" else "-fno-function-sections");
try argv.append(if (comp.data_sections) "-fdata-sections" else "-fno-data-sections");
switch (mod.unwind_tables) {
.none => {
try argv.append("-fno-unwind-tables");
try argv.append("-fno-asynchronous-unwind-tables");
},
.sync => {
// Need to override Clang's convoluted default logic.
try argv.append("-fno-asynchronous-unwind-tables");
try argv.append("-funwind-tables");
},
.@"async" => try argv.append("-fasynchronous-unwind-tables"),
}
try argv.append("-nostdinc");
if (ext == .cpp or ext == .hpp) {
try argv.append("-nostdinc++");
}
// LLVM IR files don't support these flags.
if (ext != .ll and ext != .bc) {
switch (mod.optimize_mode) {
.Debug => {},
.ReleaseSafe => {
try argv.append("-D_FORTIFY_SOURCE=2");
},
.ReleaseFast, .ReleaseSmall => {
try argv.append("-DNDEBUG");
},
}
if (comp.config.link_libc) {
if (target.isGnuLibC()) {
const target_version = target.os.versionRange().gnuLibCVersion().?;
const glibc_minor_define = try std.fmt.allocPrint(arena, "-D__GLIBC_MINOR__={d}", .{
target_version.minor,
});
try argv.append(glibc_minor_define);
} else if (target.isMinGW()) {
try argv.append("-D__MSVCRT_VERSION__=0xE00"); // use ucrt
const minver: u16 = @truncate(@intFromEnum(target.os.versionRange().windows.min) >> 16);
try argv.append(
try std.fmt.allocPrint(arena, "-D_WIN32_WINNT=0x{x:0>4}", .{minver}),
);
} else if (target.isFreeBSDLibC()) {
// https://docs.freebsd.org/en/books/porters-handbook/versions
const min_ver = target.os.version_range.semver.min;
try argv.append(try std.fmt.allocPrint(arena, "-D__FreeBSD_version={d}", .{
// We don't currently respect the minor and patch components. This wouldn't be particularly
// helpful because our abilists file only tracks major FreeBSD releases, so the link-time stub
// symbols would be inconsistent with header declarations.
min_ver.major * 100_000,
}));
} else if (target.isNetBSDLibC()) {
const min_ver = target.os.version_range.semver.min;
try argv.append(try std.fmt.allocPrint(arena, "-D__NetBSD_Version__={d}", .{
// We don't currently respect the patch component. This wouldn't be particularly helpful because
// our abilists file only tracks major and minor NetBSD releases, so the link-time stub symbols
// would be inconsistent with header declarations.
(min_ver.major * 100_000_000) + (min_ver.minor * 1_000_000),
}));
}
}
if (comp.config.link_libcpp) {
try argv.append("-isystem");
try argv.append(try std.fs.path.join(arena, &[_][]const u8{
comp.dirs.zig_lib.path.?, "libcxx", "include",
}));
try argv.append("-isystem");
try argv.append(try std.fs.path.join(arena, &[_][]const u8{
comp.dirs.zig_lib.path.?, "libcxxabi", "include",
}));
try libcxx.addCxxArgs(comp, arena, argv);
}
// According to Rich Felker libc headers are supposed to go before C language headers.
// However as noted by @dimenus, appending libc headers before compiler headers breaks
// intrinsics and other compiler specific items.
try argv.append("-isystem");
try argv.append(try std.fs.path.join(arena, &.{ comp.dirs.zig_lib.path.?, "include" }));
try argv.ensureUnusedCapacity(comp.libc_include_dir_list.len * 2);
for (comp.libc_include_dir_list) |include_dir| {
try argv.append("-isystem");
try argv.append(include_dir);
}
if (mod.resolved_target.is_native_os and mod.resolved_target.is_native_abi) {
try argv.ensureUnusedCapacity(comp.native_system_include_paths.len * 2);
for (comp.native_system_include_paths) |include_path| {
argv.appendAssumeCapacity("-isystem");
argv.appendAssumeCapacity(include_path);
}
}
if (comp.config.link_libunwind) {
try argv.append("-isystem");
try argv.append(try std.fs.path.join(arena, &[_][]const u8{
comp.dirs.zig_lib.path.?, "libunwind", "include",
}));
}
try argv.ensureUnusedCapacity(comp.libc_framework_dir_list.len * 2);
for (comp.libc_framework_dir_list) |framework_dir| {
try argv.appendSlice(&.{ "-iframework", framework_dir });
}
try argv.ensureUnusedCapacity(comp.framework_dirs.len * 2);
for (comp.framework_dirs) |framework_dir| {
try argv.appendSlice(&.{ "-F", framework_dir });
}
}
}
// Only C-family files support these flags.
switch (ext) {
.c,
.h,
.cpp,
.hpp,
.m,
.hm,
.mm,
.hmm,
=> {
try argv.append("-fno-spell-checking");
if (target.os.tag == .windows and target.abi.isGnu()) {
// windows.h has files such as pshpack1.h which do #pragma packing,
// triggering a clang warning. So for this target, we disable this warning.
try argv.append("-Wno-pragma-pack");
}
if (mod.optimize_mode != .Debug) {
try argv.append("-Werror=date-time");
}
},
else => {},
}
// Only assembly files support these flags.
switch (ext) {
.assembly,
.assembly_with_cpp,
=> {
// The Clang assembler does not accept the list of CPU features like the
// compiler frontend does. Therefore we must hard-code the -m flags for
// all CPU features here.
switch (target.cpu.arch) {
.riscv32, .riscv64 => {
const RvArchFeat = struct { char: u8, feat: std.Target.riscv.Feature };
const letters = [_]RvArchFeat{
.{ .char = 'm', .feat = .m },
.{ .char = 'a', .feat = .a },
.{ .char = 'f', .feat = .f },
.{ .char = 'd', .feat = .d },
.{ .char = 'c', .feat = .c },
};
const prefix: []const u8 = if (target.cpu.arch == .riscv64) "rv64" else "rv32";
const prefix_len = 4;
assert(prefix.len == prefix_len);
var march_buf: [prefix_len + letters.len + 1]u8 = undefined;
var march_index: usize = prefix_len;
@memcpy(march_buf[0..prefix.len], prefix);
if (target.cpu.has(.riscv, .e)) {
march_buf[march_index] = 'e';
} else {
march_buf[march_index] = 'i';
}
march_index += 1;
for (letters) |letter| {
if (target.cpu.has(.riscv, letter.feat)) {
march_buf[march_index] = letter.char;
march_index += 1;
}
}
const march_arg = try std.fmt.allocPrint(arena, "-march={s}", .{
march_buf[0..march_index],
});
try argv.append(march_arg);
if (target.cpu.has(.riscv, .relax)) {
try argv.append("-mrelax");
} else {
try argv.append("-mno-relax");
}
if (target.cpu.has(.riscv, .save_restore)) {
try argv.append("-msave-restore");
} else {
try argv.append("-mno-save-restore");
}
},
.mips, .mipsel, .mips64, .mips64el => {
if (target.cpu.model.llvm_name) |llvm_name| {
try argv.append(try std.fmt.allocPrint(arena, "-march={s}", .{llvm_name}));
}
},
else => {
// TODO
},
}
if (target_util.clangAssemblerSupportsMcpuArg(target)) {
if (target.cpu.model.llvm_name) |llvm_name| {
try argv.append(try std.fmt.allocPrint(arena, "-mcpu={s}", .{llvm_name}));
}
}
},
else => {},
}
// Only compiled files support these flags.
switch (ext) {
.c,
.h,
.cpp,
.hpp,
.m,
.hm,
.mm,
.hmm,
.ll,
.bc,
=> {
if (target_util.clangSupportsTargetCpuArg(target)) {
if (target.cpu.model.llvm_name) |llvm_name| {
try argv.appendSlice(&[_][]const u8{
"-Xclang", "-target-cpu", "-Xclang", llvm_name,
});
}
}
// It would be really nice if there was a more compact way to communicate this info to Clang.
const all_features_list = target.cpu.arch.allFeaturesList();
try argv.ensureUnusedCapacity(all_features_list.len * 4);
for (all_features_list, 0..) |feature, index_usize| {
const index = @as(std.Target.Cpu.Feature.Set.Index, @intCast(index_usize));
const is_enabled = target.cpu.features.isEnabled(index);
if (feature.llvm_name) |llvm_name| {
// We communicate float ABI to Clang through the dedicated options.
if (std.mem.startsWith(u8, llvm_name, "soft-float") or
std.mem.startsWith(u8, llvm_name, "hard-float"))
continue;
// Ignore these until we figure out how to handle the concept of omitting features.
// See https://github.com/ziglang/zig/issues/23539
if (target_util.isDynamicAMDGCNFeature(target, feature)) continue;
argv.appendSliceAssumeCapacity(&[_][]const u8{ "-Xclang", "-target-feature", "-Xclang" });
const plus_or_minus = "-+"[@intFromBool(is_enabled)];
const arg = try std.fmt.allocPrint(arena, "{c}{s}", .{ plus_or_minus, llvm_name });
argv.appendAssumeCapacity(arg);
}
}
{
var san_arg: std.ArrayListUnmanaged(u8) = .empty;
const prefix = "-fsanitize=";
if (mod.sanitize_c != .off) {
if (san_arg.items.len == 0) try san_arg.appendSlice(arena, prefix);
try san_arg.appendSlice(arena, "undefined,");
}
if (mod.sanitize_thread) {
if (san_arg.items.len == 0) try san_arg.appendSlice(arena, prefix);
try san_arg.appendSlice(arena, "thread,");
}
if (mod.fuzz) {
if (san_arg.items.len == 0) try san_arg.appendSlice(arena, prefix);
try san_arg.appendSlice(arena, "fuzzer-no-link,");
}
// Chop off the trailing comma and append to argv.
if (san_arg.pop()) |_| {
try argv.append(san_arg.items);
switch (mod.sanitize_c) {
.off => {},
.trap => {
try argv.append("-fsanitize-trap=undefined");
},
.full => {
// This check requires implementing the Itanium C++ ABI.
// We would make it `-fsanitize-trap=vptr`, however this check requires
// a full runtime due to the type hashing involved.
try argv.append("-fno-sanitize=vptr");
// It is very common, and well-defined, for a pointer on one side of a C ABI
// to have a different but compatible element type. Examples include:
// `char*` vs `uint8_t*` on a system with 8-bit bytes
// `const char*` vs `char*`
// `char*` vs `unsigned char*`
// Without this flag, Clang would invoke UBSAN when such an extern
// function was called.
try argv.append("-fno-sanitize=function");
// This is necessary because, by default, Clang instructs LLVM to embed
// a COFF link dependency on `libclang_rt.ubsan_standalone.a` when the
// UBSan runtime is used.
if (target.os.tag == .windows) {
try argv.append("-fno-rtlib-defaultlib");
}
},
}
}
if (comp.config.san_cov_trace_pc_guard) {
try argv.append("-fsanitize-coverage=trace-pc-guard");
}
}
switch (mod.optimize_mode) {
.Debug => {
// Clang has -Og for compatibility with GCC, but currently it is just equivalent
// to -O1. Besides potentially impairing debugging, -O1/-Og significantly
// increases compile times.
try argv.append("-O0");
},
.ReleaseSafe => {
// See the comment in the BuildModeFastRelease case for why we pass -O2 rather
// than -O3 here.
try argv.append("-O2");
},
.ReleaseFast => {
// Here we pass -O2 rather than -O3 because, although we do the equivalent of
// -O3 in Zig code, the justification for the difference here is that Zig
// has better detection and prevention of undefined behavior, so -O3 is safer for
// Zig code than it is for C code. Also, C programmers are used to their code
// running in -O2 and thus the -O3 path has been tested less.
try argv.append("-O2");
},
.ReleaseSmall => {
try argv.append("-Os");
},
}
},
else => {},
}
try argv.appendSlice(comp.global_cc_argv);
try argv.appendSlice(mod.cc_argv);
}
fn failCObj(
comp: *Compilation,
c_object: *CObject,
comptime format: []const u8,
args: anytype,
) SemaError {
@branchHint(.cold);
const diag_bundle = blk: {
const diag_bundle = try comp.gpa.create(CObject.Diag.Bundle);
diag_bundle.* = .{};
errdefer diag_bundle.destroy(comp.gpa);
try diag_bundle.file_names.ensureTotalCapacity(comp.gpa, 1);
diag_bundle.file_names.putAssumeCapacity(1, try comp.gpa.dupe(u8, c_object.src.src_path));
diag_bundle.diags = try comp.gpa.alloc(CObject.Diag, 1);
diag_bundle.diags[0] = .{};
diag_bundle.diags[0].level = 3;
diag_bundle.diags[0].msg = try std.fmt.allocPrint(comp.gpa, format, args);
diag_bundle.diags[0].src_loc.file = 1;
break :blk diag_bundle;
};
return comp.failCObjWithOwnedDiagBundle(c_object, diag_bundle);
}
fn failCObjWithOwnedDiagBundle(
comp: *Compilation,
c_object: *CObject,
diag_bundle: *CObject.Diag.Bundle,
) SemaError {
@branchHint(.cold);
assert(diag_bundle.diags.len > 0);
{
comp.mutex.lock();
defer comp.mutex.unlock();
{
errdefer diag_bundle.destroy(comp.gpa);
try comp.failed_c_objects.ensureUnusedCapacity(comp.gpa, 1);
}
comp.failed_c_objects.putAssumeCapacityNoClobber(c_object, diag_bundle);
}
c_object.status = .failure;
return error.AnalysisFail;
}
fn failWin32Resource(comp: *Compilation, win32_resource: *Win32Resource, comptime format: []const u8, args: anytype) SemaError {
@branchHint(.cold);
var bundle: ErrorBundle.Wip = undefined;
try bundle.init(comp.gpa);
errdefer bundle.deinit();
try bundle.addRootErrorMessage(.{
.msg = try bundle.printString(format, args),
.src_loc = try bundle.addSourceLocation(.{
.src_path = try bundle.addString(switch (win32_resource.src) {
.rc => |rc_src| rc_src.src_path,
.manifest => |manifest_src| manifest_src,
}),
.line = 0,
.column = 0,
.span_start = 0,
.span_main = 0,
.span_end = 0,
}),
});
const finished_bundle = try bundle.toOwnedBundle("");
return comp.failWin32ResourceWithOwnedBundle(win32_resource, finished_bundle);
}
fn failWin32ResourceWithOwnedBundle(
comp: *Compilation,
win32_resource: *Win32Resource,
err_bundle: ErrorBundle,
) SemaError {
@branchHint(.cold);
{
comp.mutex.lock();
defer comp.mutex.unlock();
try comp.failed_win32_resources.putNoClobber(comp.gpa, win32_resource, err_bundle);
}
win32_resource.status = .failure;
return error.AnalysisFail;
}
pub const FileExt = enum {
c,
cpp,
h,
hpp,
hm,
hmm,
m,
mm,
ll,
bc,
assembly,
assembly_with_cpp,
shared_library,
object,
static_library,
zig,
def,
rc,
res,
manifest,
unknown,
pub fn clangNeedsLanguageOverride(ext: FileExt) bool {
return switch (ext) {
.h,
.hpp,
.hm,
.hmm,
=> true,
.c,
.cpp,
.m,
.mm,
.ll,
.bc,
.assembly,
.assembly_with_cpp,
.shared_library,
.object,
.static_library,
.zig,
.def,
.rc,
.res,
.manifest,
.unknown,
=> false,
};
}
pub fn clangSupportsDiagnostics(ext: FileExt) bool {
return switch (ext) {
.c, .cpp, .h, .hpp, .hm, .hmm, .m, .mm, .ll, .bc => true,
.assembly,
.assembly_with_cpp,
.shared_library,
.object,
.static_library,
.zig,
.def,
.rc,
.res,
.manifest,
.unknown,
=> false,
};
}
pub fn clangSupportsDepFile(ext: FileExt) bool {
return switch (ext) {
.assembly_with_cpp, .c, .cpp, .h, .hpp, .hm, .hmm, .m, .mm => true,
.ll,
.bc,
.assembly,
.shared_library,
.object,
.static_library,
.zig,
.def,
.rc,
.res,
.manifest,
.unknown,
=> false,
};
}
pub fn canonicalName(ext: FileExt, target: Target) [:0]const u8 {
return switch (ext) {
.c => ".c",
.cpp => ".cpp",
.h => ".h",
.hpp => ".hpp",
.hm => ".hm",
.hmm => ".hmm",
.m => ".m",
.mm => ".mm",
.ll => ".ll",
.bc => ".bc",
.assembly => ".s",
.assembly_with_cpp => ".S",
.shared_library => target.dynamicLibSuffix(),
.object => target.ofmt.fileExt(target.cpu.arch),
.static_library => target.staticLibSuffix(),
.zig => ".zig",
.def => ".def",
.rc => ".rc",
.res => ".res",
.manifest => ".manifest",
.unknown => "",
};
}
};
pub fn hasObjectExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".o") or
mem.endsWith(u8, filename, ".lo") or
mem.endsWith(u8, filename, ".obj") or
mem.endsWith(u8, filename, ".rmeta");
}
pub fn hasStaticLibraryExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".a") or
mem.endsWith(u8, filename, ".lib") or
mem.endsWith(u8, filename, ".rlib");
}
pub fn hasCExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".c");
}
pub fn hasCHExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".h");
}
pub fn hasCppExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".C") or
mem.endsWith(u8, filename, ".cc") or
mem.endsWith(u8, filename, ".cp") or
mem.endsWith(u8, filename, ".CPP") or
mem.endsWith(u8, filename, ".cpp") or
mem.endsWith(u8, filename, ".cxx") or
mem.endsWith(u8, filename, ".c++");
}
pub fn hasCppHExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".hh") or
mem.endsWith(u8, filename, ".hpp") or
mem.endsWith(u8, filename, ".hxx");
}
pub fn hasObjCExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".m");
}
pub fn hasObjCHExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".hm");
}
pub fn hasObjCppExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".M") or
mem.endsWith(u8, filename, ".mm");
}
pub fn hasObjCppHExt(filename: []const u8) bool {
return mem.endsWith(u8, filename, ".hmm");
}
pub fn hasSharedLibraryExt(filename: []const u8) bool {
if (mem.endsWith(u8, filename, ".so") or
mem.endsWith(u8, filename, ".dll") or
mem.endsWith(u8, filename, ".dylib") or
mem.endsWith(u8, filename, ".tbd"))
{
return true;
}
// Look for .so.X, .so.X.Y, .so.X.Y.Z
var it = mem.splitScalar(u8, filename, '.');
_ = it.first();
var so_txt = it.next() orelse return false;
while (!mem.eql(u8, so_txt, "so")) {
so_txt = it.next() orelse return false;
}
const n1 = it.next() orelse return false;
const n2 = it.next();
const n3 = it.next();
_ = std.fmt.parseInt(u32, n1, 10) catch return false;
if (n2) |x| _ = std.fmt.parseInt(u32, x, 10) catch return false;
if (n3) |x| _ = std.fmt.parseInt(u32, x, 10) catch return false;
if (it.next() != null) return false;
return true;
}
pub fn classifyFileExt(filename: []const u8) FileExt {
if (hasCExt(filename)) {
return .c;
} else if (hasCHExt(filename)) {
return .h;
} else if (hasCppExt(filename)) {
return .cpp;
} else if (hasCppHExt(filename)) {
return .hpp;
} else if (hasObjCExt(filename)) {
return .m;
} else if (hasObjCHExt(filename)) {
return .hm;
} else if (hasObjCppExt(filename)) {
return .mm;
} else if (hasObjCppHExt(filename)) {
return .hmm;
} else if (mem.endsWith(u8, filename, ".ll")) {
return .ll;
} else if (mem.endsWith(u8, filename, ".bc")) {
return .bc;
} else if (mem.endsWith(u8, filename, ".s")) {
return .assembly;
} else if (mem.endsWith(u8, filename, ".S")) {
return .assembly_with_cpp;
} else if (mem.endsWith(u8, filename, ".zig")) {
return .zig;
} else if (hasSharedLibraryExt(filename)) {
return .shared_library;
} else if (hasStaticLibraryExt(filename)) {
return .static_library;
} else if (hasObjectExt(filename)) {
return .object;
} else if (mem.endsWith(u8, filename, ".def")) {
return .def;
} else if (std.ascii.endsWithIgnoreCase(filename, ".rc")) {
return .rc;
} else if (std.ascii.endsWithIgnoreCase(filename, ".res")) {
return .res;
} else if (std.ascii.endsWithIgnoreCase(filename, ".manifest")) {
return .manifest;
} else {
return .unknown;
}
}
test "classifyFileExt" {
try std.testing.expectEqual(FileExt.cpp, classifyFileExt("foo.cc"));
try std.testing.expectEqual(FileExt.m, classifyFileExt("foo.m"));
try std.testing.expectEqual(FileExt.mm, classifyFileExt("foo.mm"));
try std.testing.expectEqual(FileExt.unknown, classifyFileExt("foo.nim"));
try std.testing.expectEqual(FileExt.shared_library, classifyFileExt("foo.so"));
try std.testing.expectEqual(FileExt.shared_library, classifyFileExt("foo.so.1"));
try std.testing.expectEqual(FileExt.shared_library, classifyFileExt("foo.so.1.2"));
try std.testing.expectEqual(FileExt.shared_library, classifyFileExt("foo.so.1.2.3"));
try std.testing.expectEqual(FileExt.unknown, classifyFileExt("foo.so.1.2.3~"));
try std.testing.expectEqual(FileExt.zig, classifyFileExt("foo.zig"));
}
fn get_libc_crt_file(comp: *Compilation, arena: Allocator, basename: []const u8) !Cache.Path {
return (try crtFilePath(&comp.crt_files, basename)) orelse {
const lci = comp.libc_installation orelse return error.LibCInstallationNotAvailable;
const crt_dir_path = lci.crt_dir orelse return error.LibCInstallationMissingCrtDir;
const full_path = try std.fs.path.join(arena, &[_][]const u8{ crt_dir_path, basename });
return Cache.Path.initCwd(full_path);
};
}
pub fn crtFileAsString(comp: *Compilation, arena: Allocator, basename: []const u8) ![]const u8 {
const path = try get_libc_crt_file(comp, arena, basename);
return path.toString(arena);
}
fn crtFilePath(crt_files: *std.StringHashMapUnmanaged(CrtFile), basename: []const u8) Allocator.Error!?Cache.Path {
const crt_file = crt_files.get(basename) orelse return null;
return crt_file.full_object_path;
}
fn wantBuildLibUnwindFromSource(comp: *Compilation) bool {
const is_exe_or_dyn_lib = switch (comp.config.output_mode) {
.Obj => false,
.Lib => comp.config.link_mode == .dynamic,
.Exe => true,
};
const ofmt = comp.root_mod.resolved_target.result.ofmt;
return is_exe_or_dyn_lib and comp.config.link_libunwind and ofmt != .c;
}
pub fn setAllocFailure(comp: *Compilation) void {
@branchHint(.cold);
log.debug("memory allocation failure", .{});
comp.alloc_failure_occurred = true;
}
/// Assumes that Compilation mutex is locked.
/// See also `lockAndSetMiscFailure`.
pub fn setMiscFailure(
comp: *Compilation,
tag: MiscTask,
comptime format: []const u8,
args: anytype,
) void {
comp.misc_failures.ensureUnusedCapacity(comp.gpa, 1) catch return comp.setAllocFailure();
const msg = std.fmt.allocPrint(comp.gpa, format, args) catch return comp.setAllocFailure();
const gop = comp.misc_failures.getOrPutAssumeCapacity(tag);
if (gop.found_existing) {
gop.value_ptr.deinit(comp.gpa);
}
gop.value_ptr.* = .{ .msg = msg };
}
/// See also `setMiscFailure`.
pub fn lockAndSetMiscFailure(
comp: *Compilation,
tag: MiscTask,
comptime format: []const u8,
args: anytype,
) void {
comp.mutex.lock();
defer comp.mutex.unlock();
return setMiscFailure(comp, tag, format, args);
}
pub fn dump_argv(argv: []const []const u8) void {
std.debug.lockStdErr();
defer std.debug.unlockStdErr();
const stderr = std.io.getStdErr().writer();
for (argv[0 .. argv.len - 1]) |arg| {
nosuspend stderr.print("{s} ", .{arg}) catch return;
}
nosuspend stderr.print("{s}\n", .{argv[argv.len - 1]}) catch {};
}
pub fn getZigBackend(comp: Compilation) std.builtin.CompilerBackend {
const target = comp.root_mod.resolved_target.result;
return target_util.zigBackend(target, comp.config.use_llvm);
}
pub fn updateSubCompilation(
parent_comp: *Compilation,
sub_comp: *Compilation,
misc_task: MiscTask,
prog_node: std.Progress.Node,
) !void {
{
const sub_node = prog_node.start(@tagName(misc_task), 0);
defer sub_node.end();
try sub_comp.update(sub_node);
}
// Look for compilation errors in this sub compilation
const gpa = parent_comp.gpa;
var keep_errors = false;
var errors = try sub_comp.getAllErrorsAlloc();
defer if (!keep_errors) errors.deinit(gpa);
if (errors.errorMessageCount() > 0) {
try parent_comp.misc_failures.ensureUnusedCapacity(gpa, 1);
parent_comp.misc_failures.putAssumeCapacityNoClobber(misc_task, .{
.msg = try std.fmt.allocPrint(gpa, "sub-compilation of {s} failed", .{
@tagName(misc_task),
}),
.children = errors,
});
keep_errors = true;
return error.SubCompilationFailed;
}
}
fn buildOutputFromZig(
comp: *Compilation,
src_basename: []const u8,
root_name: []const u8,
output_mode: std.builtin.OutputMode,
misc_task_tag: MiscTask,
prog_node: std.Progress.Node,
options: RtOptions,
out: *?CrtFile,
) !void {
const tracy_trace = trace(@src());
defer tracy_trace.end();
const gpa = comp.gpa;
var arena_allocator = std.heap.ArenaAllocator.init(gpa);
defer arena_allocator.deinit();
const arena = arena_allocator.allocator();
assert(output_mode != .Exe);
const strip = comp.compilerRtStrip();
const optimize_mode = comp.compilerRtOptMode();
const config = try Config.resolve(.{
.output_mode = output_mode,
.link_mode = .static,
.resolved_target = comp.root_mod.resolved_target,
.is_test = false,
.have_zcu = true,
.emit_bin = true,
.root_optimize_mode = optimize_mode,
.root_strip = strip,
.link_libc = comp.config.link_libc,
.any_unwind_tables = comp.root_mod.unwind_tables != .none,
.any_error_tracing = false,
.root_error_tracing = false,
.lto = if (options.allow_lto) comp.config.lto else .none,
});
const root_mod = try Package.Module.create(arena, .{
.paths = .{
.root = .zig_lib_root,
.root_src_path = src_basename,
},
.fully_qualified_name = "root",
.inherited = .{
.resolved_target = comp.root_mod.resolved_target,
.strip = strip,
.stack_check = false,
.stack_protector = 0,
.red_zone = comp.root_mod.red_zone,
.omit_frame_pointer = comp.root_mod.omit_frame_pointer,
.unwind_tables = comp.root_mod.unwind_tables,
.pic = comp.root_mod.pic,
.optimize_mode = optimize_mode,
.structured_cfg = comp.root_mod.structured_cfg,
.no_builtin = true,
.code_model = comp.root_mod.code_model,
.error_tracing = false,
.valgrind = if (options.checks_valgrind) comp.root_mod.valgrind else null,
},
.global = config,
.cc_argv = &.{},
.parent = null,
});
const target = comp.getTarget();
const bin_basename = try std.zig.binNameAlloc(arena, .{
.root_name = root_name,
.target = target,
.output_mode = output_mode,
});
const parent_whole_cache: ?ParentWholeCache = switch (comp.cache_use) {
.whole => |whole| .{
.manifest = whole.cache_manifest.?,
.mutex = &whole.cache_manifest_mutex,
.prefix_map = .{
0, // cwd is the same
1, // zig lib dir is the same
3, // local cache is mapped to global cache
3, // global cache is the same
},
},
.incremental => null,
};
const sub_compilation = try Compilation.create(gpa, arena, .{
.dirs = comp.dirs.withoutLocalCache(),
.cache_mode = .whole,
.parent_whole_cache = parent_whole_cache,
.self_exe_path = comp.self_exe_path,
.config = config,
.root_mod = root_mod,
.root_name = root_name,
.thread_pool = comp.thread_pool,
.libc_installation = comp.libc_installation,
.emit_bin = .{
.directory = null, // Put it in the cache directory.
.basename = bin_basename,
},
.function_sections = true,
.data_sections = true,
.emit_h = null,
.verbose_cc = comp.verbose_cc,
.verbose_link = comp.verbose_link,
.verbose_air = comp.verbose_air,
.verbose_intern_pool = comp.verbose_intern_pool,
.verbose_generic_instances = comp.verbose_intern_pool,
.verbose_llvm_ir = comp.verbose_llvm_ir,
.verbose_llvm_bc = comp.verbose_llvm_bc,
.verbose_cimport = comp.verbose_cimport,
.verbose_llvm_cpu_features = comp.verbose_llvm_cpu_features,
.clang_passthrough_mode = comp.clang_passthrough_mode,
.skip_linker_dependencies = true,
});
defer sub_compilation.destroy();
try comp.updateSubCompilation(sub_compilation, misc_task_tag, prog_node);
const crt_file = try sub_compilation.toCrtFile();
assert(out.* == null);
out.* = crt_file;
comp.queuePrelinkTaskMode(crt_file.full_object_path, &config);
}
pub const CrtFileOptions = struct {
function_sections: ?bool = null,
data_sections: ?bool = null,
omit_frame_pointer: ?bool = null,
unwind_tables: ?std.builtin.UnwindTables = null,
pic: ?bool = null,
no_builtin: ?bool = null,
allow_lto: bool = true,
};
pub fn build_crt_file(
comp: *Compilation,
root_name: []const u8,
output_mode: std.builtin.OutputMode,
misc_task_tag: MiscTask,
prog_node: std.Progress.Node,
/// These elements have to get mutated to add the owner module after it is
/// created within this function.
c_source_files: []CSourceFile,
options: CrtFileOptions,
) !void {
const tracy_trace = trace(@src());
defer tracy_trace.end();
const gpa = comp.gpa;
var arena_allocator = std.heap.ArenaAllocator.init(gpa);
defer arena_allocator.deinit();
const arena = arena_allocator.allocator();
const basename = try std.zig.binNameAlloc(gpa, .{
.root_name = root_name,
.target = comp.root_mod.resolved_target.result,
.output_mode = output_mode,
});
const config = try Config.resolve(.{
.output_mode = output_mode,
.resolved_target = comp.root_mod.resolved_target,
.is_test = false,
.have_zcu = false,
.emit_bin = true,
.root_optimize_mode = comp.compilerRtOptMode(),
.root_strip = comp.compilerRtStrip(),
.link_libc = false,
.any_unwind_tables = options.unwind_tables != .none,
.lto = switch (output_mode) {
.Lib => if (options.allow_lto) comp.config.lto else .none,
.Obj, .Exe => .none,
},
});
const root_mod = try Package.Module.create(arena, .{
.paths = .{
.root = .zig_lib_root,
.root_src_path = "",
},
.fully_qualified_name = "root",
.inherited = .{
.resolved_target = comp.root_mod.resolved_target,
.strip = comp.compilerRtStrip(),
.stack_check = false,
.stack_protector = 0,
.sanitize_c = .off,
.sanitize_thread = false,
.red_zone = comp.root_mod.red_zone,
// Some libcs (e.g. musl) are opinionated about -fomit-frame-pointer.
.omit_frame_pointer = options.omit_frame_pointer orelse comp.root_mod.omit_frame_pointer,
.valgrind = false,
// Some libcs (e.g. MinGW) are opinionated about -funwind-tables.
.unwind_tables = options.unwind_tables orelse .none,
// Some CRT objects (e.g. musl's rcrt1.o and Scrt1.o) are opinionated about PIC.
.pic = options.pic orelse comp.root_mod.pic,
.optimize_mode = comp.compilerRtOptMode(),
.structured_cfg = comp.root_mod.structured_cfg,
// Some libcs (e.g. musl) are opinionated about -fno-builtin.
.no_builtin = options.no_builtin orelse comp.root_mod.no_builtin,
.code_model = comp.root_mod.code_model,
},
.global = config,
.cc_argv = &.{},
.parent = null,
});
for (c_source_files) |*item| {
item.owner = root_mod;
}
const sub_compilation = try Compilation.create(gpa, arena, .{
.dirs = comp.dirs.withoutLocalCache(),
.self_exe_path = comp.self_exe_path,
.cache_mode = .whole,
.config = config,
.root_mod = root_mod,
.root_name = root_name,
.thread_pool = comp.thread_pool,
.libc_installation = comp.libc_installation,
.emit_bin = .{
.directory = null, // Put it in the cache directory.
.basename = basename,
},
.function_sections = options.function_sections orelse false,
.data_sections = options.data_sections orelse false,
.emit_h = null,
.c_source_files = c_source_files,
.verbose_cc = comp.verbose_cc,
.verbose_link = comp.verbose_link,
.verbose_air = comp.verbose_air,
.verbose_intern_pool = comp.verbose_intern_pool,
.verbose_generic_instances = comp.verbose_generic_instances,
.verbose_llvm_ir = comp.verbose_llvm_ir,
.verbose_llvm_bc = comp.verbose_llvm_bc,
.verbose_cimport = comp.verbose_cimport,
.verbose_llvm_cpu_features = comp.verbose_llvm_cpu_features,
.clang_passthrough_mode = comp.clang_passthrough_mode,
.skip_linker_dependencies = true,
});
defer sub_compilation.destroy();
try comp.updateSubCompilation(sub_compilation, misc_task_tag, prog_node);
const crt_file = try sub_compilation.toCrtFile();
comp.queuePrelinkTaskMode(crt_file.full_object_path, &config);
{
comp.mutex.lock();
defer comp.mutex.unlock();
try comp.crt_files.ensureUnusedCapacity(gpa, 1);
comp.crt_files.putAssumeCapacityNoClobber(basename, crt_file);
}
}
pub fn queuePrelinkTaskMode(comp: *Compilation, path: Cache.Path, config: *const Compilation.Config) void {
comp.queuePrelinkTasks(switch (config.output_mode) {
.Exe => unreachable,
.Obj => &.{.{ .load_object = path }},
.Lib => &.{switch (config.link_mode) {
.static => .{ .load_archive = path },
.dynamic => .{ .load_dso = path },
}},
});
}
/// Only valid to call during `update`. Automatically handles queuing up a
/// linker worker task if there is not already one.
pub fn queuePrelinkTasks(comp: *Compilation, tasks: []const link.PrelinkTask) void {
comp.link_task_queue.enqueuePrelink(comp, tasks) catch |err| switch (err) {
error.OutOfMemory => return comp.setAllocFailure(),
};
}
/// The reason for the double-queue here is that the first queue ensures any
/// resolve_type_fully tasks are complete before this dispatch function is called.
fn dispatchZcuLinkTask(comp: *Compilation, tid: usize, task: link.ZcuTask) void {
if (!comp.separateCodegenThreadOk()) {
assert(tid == 0);
if (task == .link_func) {
assert(task.link_func.mir.status.load(.monotonic) != .pending);
}
link.doZcuTask(comp, tid, task);
task.deinit(comp.zcu.?);
return;
}
comp.link_task_queue.enqueueZcu(comp, task) catch |err| switch (err) {
error.OutOfMemory => {
task.deinit(comp.zcu.?);
comp.setAllocFailure();
},
};
}
pub fn toCrtFile(comp: *Compilation) Allocator.Error!CrtFile {
return .{
.full_object_path = .{
.root_dir = comp.dirs.local_cache,
.sub_path = try comp.gpa.dupe(u8, comp.cache_use.whole.bin_sub_path.?),
},
.lock = comp.cache_use.whole.moveLock(),
};
}
pub fn getCrtPaths(
comp: *Compilation,
arena: Allocator,
) error{ OutOfMemory, LibCInstallationMissingCrtDir }!LibCInstallation.CrtPaths {
const target = comp.root_mod.resolved_target.result;
return getCrtPathsInner(arena, target, comp.config, comp.libc_installation, &comp.crt_files);
}
fn getCrtPathsInner(
arena: Allocator,
target: std.Target,
config: Config,
libc_installation: ?*const LibCInstallation,
crt_files: *std.StringHashMapUnmanaged(CrtFile),
) error{ OutOfMemory, LibCInstallationMissingCrtDir }!LibCInstallation.CrtPaths {
const basenames = LibCInstallation.CrtBasenames.get(.{
.target = target,
.link_libc = config.link_libc,
.output_mode = config.output_mode,
.link_mode = config.link_mode,
.pie = config.pie,
});
if (libc_installation) |lci| return lci.resolveCrtPaths(arena, basenames, target);
return .{
.crt0 = if (basenames.crt0) |basename| try crtFilePath(crt_files, basename) else null,
.crti = if (basenames.crti) |basename| try crtFilePath(crt_files, basename) else null,
.crtbegin = if (basenames.crtbegin) |basename| try crtFilePath(crt_files, basename) else null,
.crtend = if (basenames.crtend) |basename| try crtFilePath(crt_files, basename) else null,
.crtn = if (basenames.crtn) |basename| try crtFilePath(crt_files, basename) else null,
};
}
pub fn addLinkLib(comp: *Compilation, lib_name: []const u8) !void {
// Avoid deadlocking on building import libs such as kernel32.lib
// This can happen when the user uses `build-exe foo.obj -lkernel32` and
// then when we create a sub-Compilation for zig libc, it also tries to
// build kernel32.lib.
if (comp.skip_linker_dependencies) return;
const target = comp.root_mod.resolved_target.result;
if (target.os.tag != .windows or target.ofmt == .c) return;
// This happens when an `extern "foo"` function is referenced.
// If we haven't seen this library yet and we're targeting Windows, we need
// to queue up a work item to produce the DLL import library for this.
const gop = try comp.windows_libs.getOrPut(comp.gpa, lib_name);
if (!gop.found_existing) try comp.queueJob(.{ .windows_import_lib = comp.windows_libs.count() - 1 });
}
/// This decides the optimization mode for all zig-provided libraries, including
/// compiler-rt, libcxx, libc, libunwind, etc.
pub fn compilerRtOptMode(comp: Compilation) std.builtin.OptimizeMode {
if (comp.debug_compiler_runtime_libs) {
return comp.root_mod.optimize_mode;
}
const target = comp.root_mod.resolved_target.result;
switch (comp.root_mod.optimize_mode) {
.Debug, .ReleaseSafe => return target_util.defaultCompilerRtOptimizeMode(target),
.ReleaseFast => return .ReleaseFast,
.ReleaseSmall => return .ReleaseSmall,
}
}
/// This decides whether to strip debug info for all zig-provided libraries, including
/// compiler-rt, libcxx, libc, libunwind, etc.
pub fn compilerRtStrip(comp: Compilation) bool {
return comp.root_mod.strip;
}
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