zig/build.zig

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const builtin = @import("builtin");
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const std = @import("std");
const Builder = std.build.Builder;
const tests = @import("test/tests.zig");
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const BufMap = std.BufMap;
const warn = std.debug.warn;
const mem = std.mem;
const ArrayList = std.ArrayList;
const Buffer = std.Buffer;
const io = std.io;
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const fs = std.fs;
const InstallDirectoryOptions = std.build.InstallDirectoryOptions;
pub fn build(b: *Builder) !void {
b.setPreferredReleaseMode(.ReleaseFast);
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const mode = b.standardReleaseOptions();
var docgen_exe = b.addExecutable("docgen", "doc/docgen.zig");
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const rel_zig_exe = try fs.path.relative(b.allocator, b.build_root, b.zig_exe);
const langref_out_path = fs.path.join(
b.allocator,
[_][]const u8{ b.cache_root, "langref.html" },
) catch unreachable;
breaking changes to zig build API and improved caching * in Zig build scripts, getOutputPath() is no longer a valid function to call, unless setOutputDir() was used, or within a custom make() function. Instead there is more convenient API to use which takes advantage of the caching system. Search this commit diff for `exe.run()` for an example. * Zig build by default enables caching. All build artifacts will go into zig-cache. If you want to access build artifacts in a convenient location, it is recommended to add an `install` step. Otherwise you can use the `run()` API mentioned above to execute programs directly from their location in the cache. Closes #330. `addSystemCommand` is available for programs not built with Zig build. * Please note that Zig does no cache evicting yet. You may have to manually delete zig-cache directories periodically to keep disk usage down. It's planned for this to be a simple Least Recently Used eviction system eventually. * `--output`, `--output-lib`, and `--output-h` are removed. Instead, use `--output-dir` which defaults to the current working directory. Or take advantage of `--cache on`, which will print the main output path to stdout, and the other artifacts will be in the same directory with predictable file names. `--disable-gen-h` is available when one wants to prevent .h file generation. * `@cImport` is always independently cached now. Closes #2015. It always writes the generated Zig code to disk which makes debug info and compile errors better. No more "TODO: remember C source location to display here" * Fix .d file parsing. (Fixes the MacOS CI failure) * Zig no longer creates "temporary files" other than inside a zig-cache directory. This breaks the CLI API that Godbolt uses. The suggested new invocation can be found in this commit diff, in the changes to `test/cli.zig`.
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var docgen_cmd = docgen_exe.run();
docgen_cmd.addArgs([_][]const u8{
rel_zig_exe,
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"doc" ++ fs.path.sep_str ++ "langref.html.in",
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langref_out_path,
});
docgen_cmd.step.dependOn(&docgen_exe.step);
const docs_step = b.step("docs", "Build documentation");
docs_step.dependOn(&docgen_cmd.step);
const test_step = b.step("test", "Run all the tests");
// find the stage0 build artifacts because we're going to re-use config.h and zig_cpp library
const build_info = try b.exec([_][]const u8{
b.zig_exe,
"BUILD_INFO",
});
var index: usize = 0;
var ctx = Context{
.cmake_binary_dir = nextValue(&index, build_info),
.cxx_compiler = nextValue(&index, build_info),
.llvm_config_exe = nextValue(&index, build_info),
.lld_include_dir = nextValue(&index, build_info),
.lld_libraries = nextValue(&index, build_info),
.dia_guids_lib = nextValue(&index, build_info),
.llvm = undefined,
};
ctx.llvm = try findLLVM(b, ctx.llvm_config_exe);
var test_stage2 = b.addTest("src-self-hosted/test.zig");
test_stage2.setBuildMode(builtin.Mode.Debug);
const fmt_build_zig = b.addFmt([_][]const u8{"build.zig"});
var exe = b.addExecutable("zig", "src-self-hosted/main.zig");
exe.setBuildMode(mode);
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try configureStage2(b, test_stage2, ctx);
try configureStage2(b, exe, ctx);
addLibUserlandStep(b, mode);
stage1 is now a hybrid of C++ and Zig This modifies the build process of Zig to put all of the source files into libcompiler.a, except main.cpp and userland.cpp. Next, the build process links main.cpp, userland.cpp, and libcompiler.a into zig1. userland.cpp is a shim for functions that will later be replaced with self-hosted implementations. Next, the build process uses zig1 to build src-self-hosted/stage1.zig into libuserland.a, which does not depend on any of the things that are shimmed in userland.cpp, such as translate-c. Finally, the build process re-links main.cpp and libcompiler.a, except with libuserland.a instead of userland.cpp. Now the shims are replaced with .zig code. This provides all of the Zig standard library to the stage1 C++ compiler, and enables us to move certain things to userland, such as translate-c. As a proof of concept I have made the `zig zen` command use text defined in userland. I added `zig translate-c-2` which is a work-in-progress reimplementation of translate-c in userland, which currently calls `std.debug.panic("unimplemented")` and you can see the stack trace makes it all the way back into the C++ main() function (Thanks LemonBoy for improving that!). This could potentially let us move other things into userland, such as hashing algorithms, the entire cache system, .d file parsing, pretty much anything that libuserland.a itself doesn't need to depend on. This can also let us have `zig fmt` in stage1 without the overhead of child process execution, and without the initial compilation delay before it gets cached. See #1964
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const skip_release = b.option(bool, "skip-release", "Main test suite skips release builds") orelse false;
const skip_release_small = b.option(bool, "skip-release-small", "Main test suite skips release-small builds") orelse skip_release;
const skip_release_fast = b.option(bool, "skip-release-fast", "Main test suite skips release-fast builds") orelse skip_release;
const skip_release_safe = b.option(bool, "skip-release-safe", "Main test suite skips release-safe builds") orelse skip_release;
const skip_non_native = b.option(bool, "skip-non-native", "Main test suite skips non-native builds") orelse false;
significantly increase test coverage * add zig build option `-Dskip-libc` to skip tests that build libc (e.g. if you don't want to wait for musl to build) * add `-Denable-wine` option which uses wine to run cross compiled windows tests on non-windows hosts * add `-Denable-qemu` option which uses qemu to run cross compiled foreign architecture tests * add `-Denable-foreign-glibc=path` option which combined with `-Denable-qemu` enables running cross compiled tests that link against glibc. See https://github.com/ziglang/zig/wiki/Updating-libc#glibc for how to produce this directory. * the test matrix is done manually. release test builds are only enabled by default for the native target. this should save us some CI time, while still providing decent coverage of release builds. - add test coverage for `x86_64-linux-musl -lc` (building musl libc) - add test coverage for `x86_64-linux-gnu -lc` (building glibc) - add test coverage for `aarch64v8_5a-linux-none` - add test coverage for `aarch64v8_5a-linux-musl -lc` (building musl libc) - add test coverage for `aarch64v8_5a-linux-gnu -lc` (building glibc) - add test coverage for `arm-linux-none` - test coverage for `arm-linux-musleabihf -lc` (building musl libc) is disabled due to #3286 - test coverage for `arm-linux-gnueabihf -lc` (building glibc) is disabled due to #3287 - test coverage for `x86_64-windows-gnu -lc` (building mingw-w64) is disabled due to #3285 * enable qemu testing on the Linux CI job. There's not really a good reason to enable wine, since we have a Windows CI job as well. * remove the no longer needed `--build-file ../build.zig` from CI scripts * fix bug in glibc compilation where it wasn't properly reading the abi list txt files, resulting in "key not found" error. * std.build.Target gains: - isNetBSD - isLinux - osRequiresLibC - getArchPtrBitWidth - getExternalExecutor * zig build system gains support for enabling wine and enabling qemu. `artifact.enable_wine = true;`, `artifact.enable_qemu = true;`. This communicates that the system has these tools installed and the build system will use them to run tests. * zig build system gains support for overriding the dynamic linker of an executable artifact. * fix std.c.lseek prototype. makes behavior tests for arm-linux-musleabihf pass. * disable std lib tests that are failing on ARM. See #3288, #3289 * provide `std.os.off_t`. * disable some of the compiler_rt symbols for arm 32 bit. Fixes compiler_rt tests for arm 32 bit * add __stack_chk_guard when linking against glibc. Fixes std lib tests for aarch64-linux-gnu * workaround for "unable to inline function" using `@inlineCall`. Fixes compiler_rt tests for arm 32 bit.
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const skip_libc = b.option(bool, "skip-libc", "Main test suite skips tests that link libc") orelse false;
const skip_self_hosted = b.option(bool, "skip-self-hosted", "Main test suite skips building self hosted compiler") orelse false;
if (!skip_self_hosted) {
// TODO re-enable this after https://github.com/ziglang/zig/issues/2377
//test_step.dependOn(&exe.step);
}
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const only_install_lib_files = b.option(bool, "lib-files-only", "Only install library files") orelse false;
if (!only_install_lib_files) {
b.default_step.dependOn(&exe.step);
exe.install();
}
b.installDirectory(InstallDirectoryOptions{
.source_dir = "lib",
.install_dir = .Lib,
.install_subdir = "zig",
.exclude_extensions = [_][]const u8{ "test.zig", "README.md" },
});
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const test_filter = b.option([]const u8, "test-filter", "Skip tests that do not match filter");
significantly increase test coverage * add zig build option `-Dskip-libc` to skip tests that build libc (e.g. if you don't want to wait for musl to build) * add `-Denable-wine` option which uses wine to run cross compiled windows tests on non-windows hosts * add `-Denable-qemu` option which uses qemu to run cross compiled foreign architecture tests * add `-Denable-foreign-glibc=path` option which combined with `-Denable-qemu` enables running cross compiled tests that link against glibc. See https://github.com/ziglang/zig/wiki/Updating-libc#glibc for how to produce this directory. * the test matrix is done manually. release test builds are only enabled by default for the native target. this should save us some CI time, while still providing decent coverage of release builds. - add test coverage for `x86_64-linux-musl -lc` (building musl libc) - add test coverage for `x86_64-linux-gnu -lc` (building glibc) - add test coverage for `aarch64v8_5a-linux-none` - add test coverage for `aarch64v8_5a-linux-musl -lc` (building musl libc) - add test coverage for `aarch64v8_5a-linux-gnu -lc` (building glibc) - add test coverage for `arm-linux-none` - test coverage for `arm-linux-musleabihf -lc` (building musl libc) is disabled due to #3286 - test coverage for `arm-linux-gnueabihf -lc` (building glibc) is disabled due to #3287 - test coverage for `x86_64-windows-gnu -lc` (building mingw-w64) is disabled due to #3285 * enable qemu testing on the Linux CI job. There's not really a good reason to enable wine, since we have a Windows CI job as well. * remove the no longer needed `--build-file ../build.zig` from CI scripts * fix bug in glibc compilation where it wasn't properly reading the abi list txt files, resulting in "key not found" error. * std.build.Target gains: - isNetBSD - isLinux - osRequiresLibC - getArchPtrBitWidth - getExternalExecutor * zig build system gains support for enabling wine and enabling qemu. `artifact.enable_wine = true;`, `artifact.enable_qemu = true;`. This communicates that the system has these tools installed and the build system will use them to run tests. * zig build system gains support for overriding the dynamic linker of an executable artifact. * fix std.c.lseek prototype. makes behavior tests for arm-linux-musleabihf pass. * disable std lib tests that are failing on ARM. See #3288, #3289 * provide `std.os.off_t`. * disable some of the compiler_rt symbols for arm 32 bit. Fixes compiler_rt tests for arm 32 bit * add __stack_chk_guard when linking against glibc. Fixes std lib tests for aarch64-linux-gnu * workaround for "unable to inline function" using `@inlineCall`. Fixes compiler_rt tests for arm 32 bit.
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const is_wine_enabled = b.option(bool, "enable-wine", "Use Wine to run cross compiled Windows tests") orelse false;
const is_qemu_enabled = b.option(bool, "enable-qemu", "Use QEMU to run cross compiled foreign architecture tests") orelse false;
const glibc_multi_dir = b.option([]const u8, "enable-foreign-glibc", "Provide directory with glibc installations to run cross compiled tests that link glibc");
const test_stage2_step = b.step("test-stage2", "Run the stage2 compiler tests");
test_stage2_step.dependOn(&test_stage2.step);
// TODO see https://github.com/ziglang/zig/issues/1364
if (false) {
test_step.dependOn(test_stage2_step);
}
var chosen_modes: [4]builtin.Mode = undefined;
var chosen_mode_index: usize = 0;
chosen_modes[chosen_mode_index] = builtin.Mode.Debug;
chosen_mode_index += 1;
if (!skip_release_safe) {
chosen_modes[chosen_mode_index] = builtin.Mode.ReleaseSafe;
chosen_mode_index += 1;
}
if (!skip_release_fast) {
chosen_modes[chosen_mode_index] = builtin.Mode.ReleaseFast;
chosen_mode_index += 1;
}
if (!skip_release_small) {
chosen_modes[chosen_mode_index] = builtin.Mode.ReleaseSmall;
chosen_mode_index += 1;
}
const modes = chosen_modes[0..chosen_mode_index];
// run stage1 `zig fmt` on this build.zig file just to make sure it works
test_step.dependOn(&fmt_build_zig.step);
const fmt_step = b.step("test-fmt", "Run zig fmt against build.zig to make sure it works");
fmt_step.dependOn(&fmt_build_zig.step);
significantly increase test coverage * add zig build option `-Dskip-libc` to skip tests that build libc (e.g. if you don't want to wait for musl to build) * add `-Denable-wine` option which uses wine to run cross compiled windows tests on non-windows hosts * add `-Denable-qemu` option which uses qemu to run cross compiled foreign architecture tests * add `-Denable-foreign-glibc=path` option which combined with `-Denable-qemu` enables running cross compiled tests that link against glibc. See https://github.com/ziglang/zig/wiki/Updating-libc#glibc for how to produce this directory. * the test matrix is done manually. release test builds are only enabled by default for the native target. this should save us some CI time, while still providing decent coverage of release builds. - add test coverage for `x86_64-linux-musl -lc` (building musl libc) - add test coverage for `x86_64-linux-gnu -lc` (building glibc) - add test coverage for `aarch64v8_5a-linux-none` - add test coverage for `aarch64v8_5a-linux-musl -lc` (building musl libc) - add test coverage for `aarch64v8_5a-linux-gnu -lc` (building glibc) - add test coverage for `arm-linux-none` - test coverage for `arm-linux-musleabihf -lc` (building musl libc) is disabled due to #3286 - test coverage for `arm-linux-gnueabihf -lc` (building glibc) is disabled due to #3287 - test coverage for `x86_64-windows-gnu -lc` (building mingw-w64) is disabled due to #3285 * enable qemu testing on the Linux CI job. There's not really a good reason to enable wine, since we have a Windows CI job as well. * remove the no longer needed `--build-file ../build.zig` from CI scripts * fix bug in glibc compilation where it wasn't properly reading the abi list txt files, resulting in "key not found" error. * std.build.Target gains: - isNetBSD - isLinux - osRequiresLibC - getArchPtrBitWidth - getExternalExecutor * zig build system gains support for enabling wine and enabling qemu. `artifact.enable_wine = true;`, `artifact.enable_qemu = true;`. This communicates that the system has these tools installed and the build system will use them to run tests. * zig build system gains support for overriding the dynamic linker of an executable artifact. * fix std.c.lseek prototype. makes behavior tests for arm-linux-musleabihf pass. * disable std lib tests that are failing on ARM. See #3288, #3289 * provide `std.os.off_t`. * disable some of the compiler_rt symbols for arm 32 bit. Fixes compiler_rt tests for arm 32 bit * add __stack_chk_guard when linking against glibc. Fixes std lib tests for aarch64-linux-gnu * workaround for "unable to inline function" using `@inlineCall`. Fixes compiler_rt tests for arm 32 bit.
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test_step.dependOn(tests.addPkgTests(b, test_filter, "test/stage1/behavior.zig", "behavior", "Run the behavior tests", modes, false, skip_non_native, skip_libc, is_wine_enabled, is_qemu_enabled, glibc_multi_dir));
test_step.dependOn(tests.addPkgTests(b, test_filter, "lib/std/std.zig", "std", "Run the standard library tests", modes, false, skip_non_native, skip_libc, is_wine_enabled, is_qemu_enabled, glibc_multi_dir));
test_step.dependOn(tests.addPkgTests(b, test_filter, "lib/std/special/compiler_rt.zig", "compiler-rt", "Run the compiler_rt tests", modes, true, skip_non_native, true, is_wine_enabled, is_qemu_enabled, glibc_multi_dir));
test_step.dependOn(tests.addCompareOutputTests(b, test_filter, modes));
test_step.dependOn(tests.addStandaloneTests(b, test_filter, modes));
test_step.dependOn(tests.addStackTraceTests(b, test_filter, modes));
test_step.dependOn(tests.addCliTests(b, test_filter, modes));
test_step.dependOn(tests.addAssembleAndLinkTests(b, test_filter, modes));
test_step.dependOn(tests.addRuntimeSafetyTests(b, test_filter, modes));
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test_step.dependOn(tests.addTranslateCTests(b, test_filter));
test_step.dependOn(tests.addGenHTests(b, test_filter));
test_step.dependOn(tests.addCompileErrorTests(b, test_filter, modes));
test_step.dependOn(docs_step);
}
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fn dependOnLib(b: *Builder, lib_exe_obj: var, dep: LibraryDep) void {
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for (dep.libdirs.toSliceConst()) |lib_dir| {
lib_exe_obj.addLibPath(lib_dir);
}
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const lib_dir = fs.path.join(
b.allocator,
[_][]const u8{ dep.prefix, "lib" },
) catch unreachable;
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for (dep.system_libs.toSliceConst()) |lib| {
const static_bare_name = if (mem.eql(u8, lib, "curses"))
([]const u8)("libncurses.a")
else
b.fmt("lib{}.a", lib);
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const static_lib_name = fs.path.join(
b.allocator,
[_][]const u8{ lib_dir, static_bare_name },
) catch unreachable;
const have_static = fileExists(static_lib_name) catch unreachable;
if (have_static) {
lib_exe_obj.addObjectFile(static_lib_name);
} else {
lib_exe_obj.linkSystemLibrary(lib);
}
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}
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for (dep.libs.toSliceConst()) |lib| {
lib_exe_obj.addObjectFile(lib);
}
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for (dep.includes.toSliceConst()) |include_path| {
lib_exe_obj.addIncludeDir(include_path);
}
}
fn fileExists(filename: []const u8) !bool {
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fs.File.access(filename) catch |err| switch (err) {
error.FileNotFound => return false,
else => return err,
};
return true;
}
fn addCppLib(b: *Builder, lib_exe_obj: var, cmake_binary_dir: []const u8, lib_name: []const u8) void {
lib_exe_obj.addObjectFile(fs.path.join(b.allocator, [_][]const u8{
cmake_binary_dir,
"zig_cpp",
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b.fmt("{}{}{}", lib_exe_obj.target.libPrefix(), lib_name, lib_exe_obj.target.staticLibSuffix()),
}) catch unreachable);
}
const LibraryDep = struct {
prefix: []const u8,
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libdirs: ArrayList([]const u8),
libs: ArrayList([]const u8),
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system_libs: ArrayList([]const u8),
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includes: ArrayList([]const u8),
};
fn findLLVM(b: *Builder, llvm_config_exe: []const u8) !LibraryDep {
const shared_mode = try b.exec([_][]const u8{ llvm_config_exe, "--shared-mode" });
const is_static = mem.startsWith(u8, shared_mode, "static");
const libs_output = if (is_static)
try b.exec([_][]const u8{
llvm_config_exe,
"--libfiles",
"--system-libs",
})
else
try b.exec([_][]const u8{
llvm_config_exe,
"--libs",
});
const includes_output = try b.exec([_][]const u8{ llvm_config_exe, "--includedir" });
const libdir_output = try b.exec([_][]const u8{ llvm_config_exe, "--libdir" });
const prefix_output = try b.exec([_][]const u8{ llvm_config_exe, "--prefix" });
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var result = LibraryDep{
.prefix = mem.tokenize(prefix_output, " \r\n").next().?,
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.libs = ArrayList([]const u8).init(b.allocator),
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.system_libs = ArrayList([]const u8).init(b.allocator),
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.includes = ArrayList([]const u8).init(b.allocator),
.libdirs = ArrayList([]const u8).init(b.allocator),
};
{
var it = mem.tokenize(libs_output, " \r\n");
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while (it.next()) |lib_arg| {
if (mem.startsWith(u8, lib_arg, "-l")) {
try result.system_libs.append(lib_arg[2..]);
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} else {
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if (fs.path.isAbsolute(lib_arg)) {
try result.libs.append(lib_arg);
} else {
try result.system_libs.append(lib_arg);
}
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}
}
}
{
var it = mem.tokenize(includes_output, " \r\n");
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while (it.next()) |include_arg| {
if (mem.startsWith(u8, include_arg, "-I")) {
try result.includes.append(include_arg[2..]);
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} else {
try result.includes.append(include_arg);
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}
}
}
{
var it = mem.tokenize(libdir_output, " \r\n");
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while (it.next()) |libdir| {
if (mem.startsWith(u8, libdir, "-L")) {
try result.libdirs.append(libdir[2..]);
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} else {
try result.libdirs.append(libdir);
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}
}
}
return result;
}
fn nextValue(index: *usize, build_info: []const u8) []const u8 {
const start = index.*;
while (true) : (index.* += 1) {
switch (build_info[index.*]) {
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'\n' => {
const result = build_info[start..index.*];
index.* += 1;
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return result;
},
'\r' => {
const result = build_info[start..index.*];
index.* += 2;
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return result;
},
else => continue,
}
}
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}
fn configureStage2(b: *Builder, exe: var, ctx: Context) !void {
exe.addIncludeDir("src");
exe.addIncludeDir(ctx.cmake_binary_dir);
addCppLib(b, exe, ctx.cmake_binary_dir, "zig_cpp");
if (ctx.lld_include_dir.len != 0) {
exe.addIncludeDir(ctx.lld_include_dir);
var it = mem.tokenize(ctx.lld_libraries, ";");
while (it.next()) |lib| {
exe.addObjectFile(lib);
}
} else {
addCppLib(b, exe, ctx.cmake_binary_dir, "embedded_lld_wasm");
addCppLib(b, exe, ctx.cmake_binary_dir, "embedded_lld_elf");
addCppLib(b, exe, ctx.cmake_binary_dir, "embedded_lld_coff");
addCppLib(b, exe, ctx.cmake_binary_dir, "embedded_lld_lib");
}
dependOnLib(b, exe, ctx.llvm);
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if (exe.target.getOs() == .linux) {
try addCxxKnownPath(b, ctx, exe, "libstdc++.a",
\\Unable to determine path to libstdc++.a
\\On Fedora, install libstdc++-static and try again.
);
exe.linkSystemLibrary("pthread");
} else if (exe.target.isFreeBSD()) {
try addCxxKnownPath(b, ctx, exe, "libc++.a", null);
exe.linkSystemLibrary("pthread");
} else if (exe.target.isDarwin()) {
if (addCxxKnownPath(b, ctx, exe, "libgcc_eh.a", "")) {
// Compiler is GCC.
try addCxxKnownPath(b, ctx, exe, "libstdc++.a", null);
exe.linkSystemLibrary("pthread");
// TODO LLD cannot perform this link.
// See https://github.com/ziglang/zig/issues/1535
exe.enableSystemLinkerHack();
} else |err| switch (err) {
error.RequiredLibraryNotFound => {
// System compiler, not gcc.
exe.linkSystemLibrary("c++");
},
else => return err,
}
}
if (ctx.dia_guids_lib.len != 0) {
exe.addObjectFile(ctx.dia_guids_lib);
}
exe.linkSystemLibrary("c");
}
fn addCxxKnownPath(
b: *Builder,
ctx: Context,
exe: var,
objname: []const u8,
errtxt: ?[]const u8,
) !void {
const path_padded = try b.exec([_][]const u8{
ctx.cxx_compiler,
b.fmt("-print-file-name={}", objname),
});
const path_unpadded = mem.tokenize(path_padded, "\r\n").next().?;
if (mem.eql(u8, path_unpadded, objname)) {
if (errtxt) |msg| {
warn("{}", msg);
} else {
warn("Unable to determine path to {}\n", objname);
}
return error.RequiredLibraryNotFound;
}
exe.addObjectFile(path_unpadded);
}
const Context = struct {
cmake_binary_dir: []const u8,
cxx_compiler: []const u8,
llvm_config_exe: []const u8,
lld_include_dir: []const u8,
lld_libraries: []const u8,
dia_guids_lib: []const u8,
llvm: LibraryDep,
};
stage1 is now a hybrid of C++ and Zig This modifies the build process of Zig to put all of the source files into libcompiler.a, except main.cpp and userland.cpp. Next, the build process links main.cpp, userland.cpp, and libcompiler.a into zig1. userland.cpp is a shim for functions that will later be replaced with self-hosted implementations. Next, the build process uses zig1 to build src-self-hosted/stage1.zig into libuserland.a, which does not depend on any of the things that are shimmed in userland.cpp, such as translate-c. Finally, the build process re-links main.cpp and libcompiler.a, except with libuserland.a instead of userland.cpp. Now the shims are replaced with .zig code. This provides all of the Zig standard library to the stage1 C++ compiler, and enables us to move certain things to userland, such as translate-c. As a proof of concept I have made the `zig zen` command use text defined in userland. I added `zig translate-c-2` which is a work-in-progress reimplementation of translate-c in userland, which currently calls `std.debug.panic("unimplemented")` and you can see the stack trace makes it all the way back into the C++ main() function (Thanks LemonBoy for improving that!). This could potentially let us move other things into userland, such as hashing algorithms, the entire cache system, .d file parsing, pretty much anything that libuserland.a itself doesn't need to depend on. This can also let us have `zig fmt` in stage1 without the overhead of child process execution, and without the initial compilation delay before it gets cached. See #1964
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fn addLibUserlandStep(b: *Builder, mode: builtin.Mode) void {
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const artifact = b.addStaticLibrary("userland", "src-self-hosted/stage1.zig");
stage1 is now a hybrid of C++ and Zig This modifies the build process of Zig to put all of the source files into libcompiler.a, except main.cpp and userland.cpp. Next, the build process links main.cpp, userland.cpp, and libcompiler.a into zig1. userland.cpp is a shim for functions that will later be replaced with self-hosted implementations. Next, the build process uses zig1 to build src-self-hosted/stage1.zig into libuserland.a, which does not depend on any of the things that are shimmed in userland.cpp, such as translate-c. Finally, the build process re-links main.cpp and libcompiler.a, except with libuserland.a instead of userland.cpp. Now the shims are replaced with .zig code. This provides all of the Zig standard library to the stage1 C++ compiler, and enables us to move certain things to userland, such as translate-c. As a proof of concept I have made the `zig zen` command use text defined in userland. I added `zig translate-c-2` which is a work-in-progress reimplementation of translate-c in userland, which currently calls `std.debug.panic("unimplemented")` and you can see the stack trace makes it all the way back into the C++ main() function (Thanks LemonBoy for improving that!). This could potentially let us move other things into userland, such as hashing algorithms, the entire cache system, .d file parsing, pretty much anything that libuserland.a itself doesn't need to depend on. This can also let us have `zig fmt` in stage1 without the overhead of child process execution, and without the initial compilation delay before it gets cached. See #1964
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artifact.disable_gen_h = true;
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artifact.bundle_compiler_rt = true;
artifact.setTarget(builtin.arch, builtin.os, builtin.abi);
artifact.setBuildMode(mode);
artifact.force_pic = true;
if (mode != .Debug) {
artifact.strip = true;
}
artifact.linkSystemLibrary("c");
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if (builtin.os == .windows) {
artifact.linkSystemLibrary("ntdll");
}
stage1 is now a hybrid of C++ and Zig This modifies the build process of Zig to put all of the source files into libcompiler.a, except main.cpp and userland.cpp. Next, the build process links main.cpp, userland.cpp, and libcompiler.a into zig1. userland.cpp is a shim for functions that will later be replaced with self-hosted implementations. Next, the build process uses zig1 to build src-self-hosted/stage1.zig into libuserland.a, which does not depend on any of the things that are shimmed in userland.cpp, such as translate-c. Finally, the build process re-links main.cpp and libcompiler.a, except with libuserland.a instead of userland.cpp. Now the shims are replaced with .zig code. This provides all of the Zig standard library to the stage1 C++ compiler, and enables us to move certain things to userland, such as translate-c. As a proof of concept I have made the `zig zen` command use text defined in userland. I added `zig translate-c-2` which is a work-in-progress reimplementation of translate-c in userland, which currently calls `std.debug.panic("unimplemented")` and you can see the stack trace makes it all the way back into the C++ main() function (Thanks LemonBoy for improving that!). This could potentially let us move other things into userland, such as hashing algorithms, the entire cache system, .d file parsing, pretty much anything that libuserland.a itself doesn't need to depend on. This can also let us have `zig fmt` in stage1 without the overhead of child process execution, and without the initial compilation delay before it gets cached. See #1964
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const libuserland_step = b.step("libuserland", "Build the userland compiler library for use in stage1");
libuserland_step.dependOn(&artifact.step);
const output_dir = b.option(
[]const u8,
"output-dir",
"For libuserland step, where to put the output",
) orelse return;
artifact.setOutputDir(output_dir);
}