zig/lib/std/Build.zig
Andrew Kelley d97042ad2e std.Build: start using the cache system with RunStep
* Use std.Build.Cache.Directory instead of a string for storing the
   cache roots and build roots.
 * Set up a std.Build.Cache in build_runner.zig and use it in
   std.Build.RunStep for avoiding redundant work.
2023-02-13 06:42:26 -07:00

1804 lines
61 KiB
Zig

const std = @import("std.zig");
const builtin = @import("builtin");
const io = std.io;
const fs = std.fs;
const mem = std.mem;
const debug = std.debug;
const panic = std.debug.panic;
const assert = debug.assert;
const log = std.log;
const ArrayList = std.ArrayList;
const StringHashMap = std.StringHashMap;
const Allocator = mem.Allocator;
const process = std.process;
const EnvMap = std.process.EnvMap;
const fmt_lib = std.fmt;
const File = std.fs.File;
const CrossTarget = std.zig.CrossTarget;
const NativeTargetInfo = std.zig.system.NativeTargetInfo;
const Sha256 = std.crypto.hash.sha2.Sha256;
const Build = @This();
pub const Cache = @import("Build/Cache.zig");
/// deprecated: use `CompileStep`.
pub const LibExeObjStep = CompileStep;
/// deprecated: use `Build`.
pub const Builder = Build;
/// deprecated: use `InstallDirStep.Options`
pub const InstallDirectoryOptions = InstallDirStep.Options;
pub const Step = @import("Build/Step.zig");
pub const CheckFileStep = @import("Build/CheckFileStep.zig");
pub const CheckObjectStep = @import("Build/CheckObjectStep.zig");
pub const ConfigHeaderStep = @import("Build/ConfigHeaderStep.zig");
pub const EmulatableRunStep = @import("Build/EmulatableRunStep.zig");
pub const FmtStep = @import("Build/FmtStep.zig");
pub const InstallArtifactStep = @import("Build/InstallArtifactStep.zig");
pub const InstallDirStep = @import("Build/InstallDirStep.zig");
pub const InstallFileStep = @import("Build/InstallFileStep.zig");
pub const InstallRawStep = @import("Build/InstallRawStep.zig");
pub const CompileStep = @import("Build/CompileStep.zig");
pub const LogStep = @import("Build/LogStep.zig");
pub const OptionsStep = @import("Build/OptionsStep.zig");
pub const RemoveDirStep = @import("Build/RemoveDirStep.zig");
pub const RunStep = @import("Build/RunStep.zig");
pub const TranslateCStep = @import("Build/TranslateCStep.zig");
pub const WriteFileStep = @import("Build/WriteFileStep.zig");
install_tls: TopLevelStep,
uninstall_tls: TopLevelStep,
allocator: Allocator,
user_input_options: UserInputOptionsMap,
available_options_map: AvailableOptionsMap,
available_options_list: ArrayList(AvailableOption),
verbose: bool,
verbose_link: bool,
verbose_cc: bool,
verbose_air: bool,
verbose_llvm_ir: bool,
verbose_cimport: bool,
verbose_llvm_cpu_features: bool,
/// The purpose of executing the command is for a human to read compile errors from the terminal
prominent_compile_errors: bool,
color: enum { auto, on, off } = .auto,
reference_trace: ?u32 = null,
invalid_user_input: bool,
zig_exe: []const u8,
default_step: *Step,
env_map: *EnvMap,
top_level_steps: ArrayList(*TopLevelStep),
install_prefix: []const u8,
dest_dir: ?[]const u8,
lib_dir: []const u8,
exe_dir: []const u8,
h_dir: []const u8,
install_path: []const u8,
sysroot: ?[]const u8 = null,
search_prefixes: ArrayList([]const u8),
libc_file: ?[]const u8 = null,
installed_files: ArrayList(InstalledFile),
/// Path to the directory containing build.zig.
build_root: Cache.Directory,
cache_root: Cache.Directory,
global_cache_root: Cache.Directory,
cache: *Cache,
/// If non-null, overrides the default zig lib dir.
zig_lib_dir: ?[]const u8,
vcpkg_root: VcpkgRoot = .unattempted,
pkg_config_pkg_list: ?(PkgConfigError![]const PkgConfigPkg) = null,
args: ?[][]const u8 = null,
debug_log_scopes: []const []const u8 = &.{},
debug_compile_errors: bool = false,
/// Experimental. Use system Darling installation to run cross compiled macOS build artifacts.
enable_darling: bool = false,
/// Use system QEMU installation to run cross compiled foreign architecture build artifacts.
enable_qemu: bool = false,
/// Darwin. Use Rosetta to run x86_64 macOS build artifacts on arm64 macOS.
enable_rosetta: bool = false,
/// Use system Wasmtime installation to run cross compiled wasm/wasi build artifacts.
enable_wasmtime: bool = false,
/// Use system Wine installation to run cross compiled Windows build artifacts.
enable_wine: bool = false,
/// After following the steps in https://github.com/ziglang/zig/wiki/Updating-libc#glibc,
/// this will be the directory $glibc-build-dir/install/glibcs
/// Given the example of the aarch64 target, this is the directory
/// that contains the path `aarch64-linux-gnu/lib/ld-linux-aarch64.so.1`.
glibc_runtimes_dir: ?[]const u8 = null,
/// Information about the native target. Computed before build() is invoked.
host: NativeTargetInfo,
dep_prefix: []const u8 = "",
modules: std.StringArrayHashMap(*Module),
pub const ExecError = error{
ReadFailure,
ExitCodeFailure,
ProcessTerminated,
ExecNotSupported,
} || std.ChildProcess.SpawnError;
pub const PkgConfigError = error{
PkgConfigCrashed,
PkgConfigFailed,
PkgConfigNotInstalled,
PkgConfigInvalidOutput,
};
pub const PkgConfigPkg = struct {
name: []const u8,
desc: []const u8,
};
pub const CStd = enum {
C89,
C99,
C11,
};
const UserInputOptionsMap = StringHashMap(UserInputOption);
const AvailableOptionsMap = StringHashMap(AvailableOption);
const AvailableOption = struct {
name: []const u8,
type_id: TypeId,
description: []const u8,
/// If the `type_id` is `enum` this provides the list of enum options
enum_options: ?[]const []const u8,
};
const UserInputOption = struct {
name: []const u8,
value: UserValue,
used: bool,
};
const UserValue = union(enum) {
flag: void,
scalar: []const u8,
list: ArrayList([]const u8),
map: StringHashMap(*const UserValue),
};
const TypeId = enum {
bool,
int,
float,
@"enum",
string,
list,
};
const TopLevelStep = struct {
pub const base_id = .top_level;
step: Step,
description: []const u8,
};
pub const DirList = struct {
lib_dir: ?[]const u8 = null,
exe_dir: ?[]const u8 = null,
include_dir: ?[]const u8 = null,
};
pub fn create(
allocator: Allocator,
zig_exe: []const u8,
build_root: Cache.Directory,
cache_root: Cache.Directory,
global_cache_root: Cache.Directory,
host: NativeTargetInfo,
cache: *Cache,
) !*Build {
const env_map = try allocator.create(EnvMap);
env_map.* = try process.getEnvMap(allocator);
const self = try allocator.create(Build);
self.* = Build{
.zig_exe = zig_exe,
.build_root = build_root,
.cache_root = cache_root,
.global_cache_root = global_cache_root,
.cache = cache,
.verbose = false,
.verbose_link = false,
.verbose_cc = false,
.verbose_air = false,
.verbose_llvm_ir = false,
.verbose_cimport = false,
.verbose_llvm_cpu_features = false,
.prominent_compile_errors = false,
.invalid_user_input = false,
.allocator = allocator,
.user_input_options = UserInputOptionsMap.init(allocator),
.available_options_map = AvailableOptionsMap.init(allocator),
.available_options_list = ArrayList(AvailableOption).init(allocator),
.top_level_steps = ArrayList(*TopLevelStep).init(allocator),
.default_step = undefined,
.env_map = env_map,
.search_prefixes = ArrayList([]const u8).init(allocator),
.install_prefix = undefined,
.lib_dir = undefined,
.exe_dir = undefined,
.h_dir = undefined,
.dest_dir = env_map.get("DESTDIR"),
.installed_files = ArrayList(InstalledFile).init(allocator),
.install_tls = TopLevelStep{
.step = Step.initNoOp(.top_level, "install", allocator),
.description = "Copy build artifacts to prefix path",
},
.uninstall_tls = TopLevelStep{
.step = Step.init(.top_level, "uninstall", allocator, makeUninstall),
.description = "Remove build artifacts from prefix path",
},
.zig_lib_dir = null,
.install_path = undefined,
.args = null,
.host = host,
.modules = std.StringArrayHashMap(*Module).init(allocator),
};
try self.top_level_steps.append(&self.install_tls);
try self.top_level_steps.append(&self.uninstall_tls);
self.default_step = &self.install_tls.step;
return self;
}
fn createChild(
parent: *Build,
dep_name: []const u8,
build_root: Cache.Directory,
args: anytype,
) !*Build {
const child = try createChildOnly(parent, dep_name, build_root);
try applyArgs(child, args);
return child;
}
fn createChildOnly(parent: *Build, dep_name: []const u8, build_root: Cache.Directory) !*Build {
const allocator = parent.allocator;
const child = try allocator.create(Build);
child.* = .{
.allocator = allocator,
.install_tls = .{
.step = Step.initNoOp(.top_level, "install", allocator),
.description = "Copy build artifacts to prefix path",
},
.uninstall_tls = .{
.step = Step.init(.top_level, "uninstall", allocator, makeUninstall),
.description = "Remove build artifacts from prefix path",
},
.user_input_options = UserInputOptionsMap.init(allocator),
.available_options_map = AvailableOptionsMap.init(allocator),
.available_options_list = ArrayList(AvailableOption).init(allocator),
.verbose = parent.verbose,
.verbose_link = parent.verbose_link,
.verbose_cc = parent.verbose_cc,
.verbose_air = parent.verbose_air,
.verbose_llvm_ir = parent.verbose_llvm_ir,
.verbose_cimport = parent.verbose_cimport,
.verbose_llvm_cpu_features = parent.verbose_llvm_cpu_features,
.prominent_compile_errors = parent.prominent_compile_errors,
.color = parent.color,
.reference_trace = parent.reference_trace,
.invalid_user_input = false,
.zig_exe = parent.zig_exe,
.default_step = undefined,
.env_map = parent.env_map,
.top_level_steps = ArrayList(*TopLevelStep).init(allocator),
.install_prefix = undefined,
.dest_dir = parent.dest_dir,
.lib_dir = parent.lib_dir,
.exe_dir = parent.exe_dir,
.h_dir = parent.h_dir,
.install_path = parent.install_path,
.sysroot = parent.sysroot,
.search_prefixes = ArrayList([]const u8).init(allocator),
.libc_file = parent.libc_file,
.installed_files = ArrayList(InstalledFile).init(allocator),
.build_root = build_root,
.cache_root = parent.cache_root,
.global_cache_root = parent.global_cache_root,
.cache = parent.cache,
.zig_lib_dir = parent.zig_lib_dir,
.debug_log_scopes = parent.debug_log_scopes,
.debug_compile_errors = parent.debug_compile_errors,
.enable_darling = parent.enable_darling,
.enable_qemu = parent.enable_qemu,
.enable_rosetta = parent.enable_rosetta,
.enable_wasmtime = parent.enable_wasmtime,
.enable_wine = parent.enable_wine,
.glibc_runtimes_dir = parent.glibc_runtimes_dir,
.host = parent.host,
.dep_prefix = parent.fmt("{s}{s}.", .{ parent.dep_prefix, dep_name }),
.modules = std.StringArrayHashMap(*Module).init(allocator),
};
try child.top_level_steps.append(&child.install_tls);
try child.top_level_steps.append(&child.uninstall_tls);
child.default_step = &child.install_tls.step;
return child;
}
fn applyArgs(b: *Build, args: anytype) !void {
inline for (@typeInfo(@TypeOf(args)).Struct.fields) |field| {
const v = @field(args, field.name);
const T = @TypeOf(v);
switch (T) {
CrossTarget => {
try b.user_input_options.put(field.name, .{
.name = field.name,
.value = .{ .scalar = try v.zigTriple(b.allocator) },
.used = false,
});
try b.user_input_options.put("cpu", .{
.name = "cpu",
.value = .{ .scalar = try serializeCpu(b.allocator, v.getCpu()) },
.used = false,
});
},
[]const u8 => {
try b.user_input_options.put(field.name, .{
.name = field.name,
.value = .{ .scalar = v },
.used = false,
});
},
else => switch (@typeInfo(T)) {
.Bool => {
try b.user_input_options.put(field.name, .{
.name = field.name,
.value = .{ .scalar = if (v) "true" else "false" },
.used = false,
});
},
.Enum, .EnumLiteral => {
try b.user_input_options.put(field.name, .{
.name = field.name,
.value = .{ .scalar = @tagName(v) },
.used = false,
});
},
.Int => {
try b.user_input_options.put(field.name, .{
.name = field.name,
.value = .{ .scalar = try std.fmt.allocPrint(b.allocator, "{d}", .{v}) },
.used = false,
});
},
else => @compileError("option '" ++ field.name ++ "' has unsupported type: " ++ @typeName(T)),
},
}
}
const Hasher = std.crypto.auth.siphash.SipHash128(1, 3);
// Random bytes to make unique. Refresh this with new random bytes when
// implementation is modified in a non-backwards-compatible way.
var hash = Hasher.init("ZaEsvQ5ClaA2IdH9");
hash.update(b.dep_prefix);
// TODO additionally update the hash with `args`.
var digest: [16]u8 = undefined;
hash.final(&digest);
var hash_basename: [digest.len * 2]u8 = undefined;
_ = std.fmt.bufPrint(&hash_basename, "{s}", .{std.fmt.fmtSliceHexLower(&digest)}) catch
unreachable;
const install_prefix = try b.cache_root.join(b.allocator, &.{ "i", &hash_basename });
b.resolveInstallPrefix(install_prefix, .{});
}
pub fn destroy(self: *Build) void {
self.env_map.deinit();
self.top_level_steps.deinit();
self.allocator.destroy(self);
}
/// This function is intended to be called by lib/build_runner.zig, not a build.zig file.
pub fn resolveInstallPrefix(self: *Build, install_prefix: ?[]const u8, dir_list: DirList) void {
if (self.dest_dir) |dest_dir| {
self.install_prefix = install_prefix orelse "/usr";
self.install_path = self.pathJoin(&.{ dest_dir, self.install_prefix });
} else {
self.install_prefix = install_prefix orelse
(self.build_root.join(self.allocator, &.{"zig-out"}) catch @panic("unhandled error"));
self.install_path = self.install_prefix;
}
var lib_list = [_][]const u8{ self.install_path, "lib" };
var exe_list = [_][]const u8{ self.install_path, "bin" };
var h_list = [_][]const u8{ self.install_path, "include" };
if (dir_list.lib_dir) |dir| {
if (std.fs.path.isAbsolute(dir)) lib_list[0] = self.dest_dir orelse "";
lib_list[1] = dir;
}
if (dir_list.exe_dir) |dir| {
if (std.fs.path.isAbsolute(dir)) exe_list[0] = self.dest_dir orelse "";
exe_list[1] = dir;
}
if (dir_list.include_dir) |dir| {
if (std.fs.path.isAbsolute(dir)) h_list[0] = self.dest_dir orelse "";
h_list[1] = dir;
}
self.lib_dir = self.pathJoin(&lib_list);
self.exe_dir = self.pathJoin(&exe_list);
self.h_dir = self.pathJoin(&h_list);
}
pub fn addOptions(self: *Build) *OptionsStep {
return OptionsStep.create(self);
}
pub const ExecutableOptions = struct {
name: []const u8,
root_source_file: ?FileSource = null,
version: ?std.builtin.Version = null,
target: CrossTarget = .{},
optimize: std.builtin.Mode = .Debug,
linkage: ?CompileStep.Linkage = null,
};
pub fn addExecutable(b: *Build, options: ExecutableOptions) *CompileStep {
return CompileStep.create(b, .{
.name = options.name,
.root_source_file = options.root_source_file,
.version = options.version,
.target = options.target,
.optimize = options.optimize,
.kind = .exe,
.linkage = options.linkage,
});
}
pub const ObjectOptions = struct {
name: []const u8,
root_source_file: ?FileSource = null,
target: CrossTarget,
optimize: std.builtin.Mode,
};
pub fn addObject(b: *Build, options: ObjectOptions) *CompileStep {
return CompileStep.create(b, .{
.name = options.name,
.root_source_file = options.root_source_file,
.target = options.target,
.optimize = options.optimize,
.kind = .obj,
});
}
pub const SharedLibraryOptions = struct {
name: []const u8,
root_source_file: ?FileSource = null,
version: ?std.builtin.Version = null,
target: CrossTarget,
optimize: std.builtin.Mode,
};
pub fn addSharedLibrary(b: *Build, options: SharedLibraryOptions) *CompileStep {
return CompileStep.create(b, .{
.name = options.name,
.root_source_file = options.root_source_file,
.kind = .lib,
.linkage = .dynamic,
.version = options.version,
.target = options.target,
.optimize = options.optimize,
});
}
pub const StaticLibraryOptions = struct {
name: []const u8,
root_source_file: ?FileSource = null,
target: CrossTarget,
optimize: std.builtin.Mode,
version: ?std.builtin.Version = null,
};
pub fn addStaticLibrary(b: *Build, options: StaticLibraryOptions) *CompileStep {
return CompileStep.create(b, .{
.name = options.name,
.root_source_file = options.root_source_file,
.kind = .lib,
.linkage = .static,
.version = options.version,
.target = options.target,
.optimize = options.optimize,
});
}
pub const TestOptions = struct {
name: []const u8 = "test",
kind: CompileStep.Kind = .@"test",
root_source_file: FileSource,
target: CrossTarget = .{},
optimize: std.builtin.Mode = .Debug,
version: ?std.builtin.Version = null,
};
pub fn addTest(b: *Build, options: TestOptions) *CompileStep {
return CompileStep.create(b, .{
.name = options.name,
.kind = options.kind,
.root_source_file = options.root_source_file,
.target = options.target,
.optimize = options.optimize,
});
}
pub const AssemblyOptions = struct {
name: []const u8,
source_file: FileSource,
target: CrossTarget,
optimize: std.builtin.Mode,
};
pub fn addAssembly(b: *Build, options: AssemblyOptions) *CompileStep {
const obj_step = CompileStep.create(b, .{
.name = options.name,
.kind = .obj,
.root_source_file = null,
.target = options.target,
.optimize = options.optimize,
});
obj_step.addAssemblyFileSource(options.source_file.dupe(b));
return obj_step;
}
pub const AddModuleOptions = struct {
name: []const u8,
source_file: FileSource,
dependencies: []const ModuleDependency = &.{},
};
pub fn addModule(b: *Build, options: AddModuleOptions) void {
b.modules.put(b.dupe(options.name), b.createModule(.{
.source_file = options.source_file,
.dependencies = options.dependencies,
})) catch @panic("OOM");
}
pub const ModuleDependency = struct {
name: []const u8,
module: *Module,
};
pub const CreateModuleOptions = struct {
source_file: FileSource,
dependencies: []const ModuleDependency = &.{},
};
/// Prefer to use `addModule` which will make the module available to other
/// packages which depend on this package.
pub fn createModule(b: *Build, options: CreateModuleOptions) *Module {
const module = b.allocator.create(Module) catch @panic("OOM");
module.* = .{
.builder = b,
.source_file = options.source_file,
.dependencies = moduleDependenciesToArrayHashMap(b.allocator, options.dependencies),
};
return module;
}
fn moduleDependenciesToArrayHashMap(arena: Allocator, deps: []const ModuleDependency) std.StringArrayHashMap(*Module) {
var result = std.StringArrayHashMap(*Module).init(arena);
for (deps) |dep| {
result.put(dep.name, dep.module) catch @panic("OOM");
}
return result;
}
/// Initializes a RunStep with argv, which must at least have the path to the
/// executable. More command line arguments can be added with `addArg`,
/// `addArgs`, and `addArtifactArg`.
/// Be careful using this function, as it introduces a system dependency.
/// To run an executable built with zig build, see `CompileStep.run`.
pub fn addSystemCommand(self: *Build, argv: []const []const u8) *RunStep {
assert(argv.len >= 1);
const run_step = RunStep.create(self, self.fmt("run {s}", .{argv[0]}));
run_step.addArgs(argv);
return run_step;
}
/// Creates a `RunStep` with an executable built with `addExecutable`.
/// Add command line arguments with methods of `RunStep`.
pub fn addRunArtifact(b: *Build, exe: *CompileStep) *RunStep {
assert(exe.kind == .exe or exe.kind == .test_exe);
// It doesn't have to be native. We catch that if you actually try to run it.
// Consider that this is declarative; the run step may not be run unless a user
// option is supplied.
const run_step = RunStep.create(b, b.fmt("run {s}", .{exe.step.name}));
run_step.addArtifactArg(exe);
if (exe.kind == .test_exe) {
run_step.addArg(b.zig_exe);
}
if (exe.vcpkg_bin_path) |path| {
run_step.addPathDir(path);
}
return run_step;
}
/// Using the `values` provided, produces a C header file, possibly based on a
/// template input file (e.g. config.h.in).
/// When an input template file is provided, this function will fail the build
/// when an option not found in the input file is provided in `values`, and
/// when an option found in the input file is missing from `values`.
pub fn addConfigHeader(
b: *Build,
options: ConfigHeaderStep.Options,
values: anytype,
) *ConfigHeaderStep {
const config_header_step = ConfigHeaderStep.create(b, options);
config_header_step.addValues(values);
return config_header_step;
}
/// Allocator.dupe without the need to handle out of memory.
pub fn dupe(self: *Build, bytes: []const u8) []u8 {
return self.allocator.dupe(u8, bytes) catch @panic("OOM");
}
/// Duplicates an array of strings without the need to handle out of memory.
pub fn dupeStrings(self: *Build, strings: []const []const u8) [][]u8 {
const array = self.allocator.alloc([]u8, strings.len) catch @panic("OOM");
for (strings) |s, i| {
array[i] = self.dupe(s);
}
return array;
}
/// Duplicates a path and converts all slashes to the OS's canonical path separator.
pub fn dupePath(self: *Build, bytes: []const u8) []u8 {
const the_copy = self.dupe(bytes);
for (the_copy) |*byte| {
switch (byte.*) {
'/', '\\' => byte.* = fs.path.sep,
else => {},
}
}
return the_copy;
}
pub fn addWriteFile(self: *Build, file_path: []const u8, data: []const u8) *WriteFileStep {
const write_file_step = self.addWriteFiles();
write_file_step.add(file_path, data);
return write_file_step;
}
pub fn addWriteFiles(self: *Build) *WriteFileStep {
const write_file_step = self.allocator.create(WriteFileStep) catch @panic("OOM");
write_file_step.* = WriteFileStep.init(self);
return write_file_step;
}
pub fn addLog(self: *Build, comptime format: []const u8, args: anytype) *LogStep {
const data = self.fmt(format, args);
const log_step = self.allocator.create(LogStep) catch @panic("OOM");
log_step.* = LogStep.init(self, data);
return log_step;
}
pub fn addRemoveDirTree(self: *Build, dir_path: []const u8) *RemoveDirStep {
const remove_dir_step = self.allocator.create(RemoveDirStep) catch @panic("OOM");
remove_dir_step.* = RemoveDirStep.init(self, dir_path);
return remove_dir_step;
}
pub fn addFmt(self: *Build, paths: []const []const u8) *FmtStep {
return FmtStep.create(self, paths);
}
pub fn addTranslateC(self: *Build, options: TranslateCStep.Options) *TranslateCStep {
return TranslateCStep.create(self, options);
}
pub fn make(self: *Build, step_names: []const []const u8) !void {
var wanted_steps = ArrayList(*Step).init(self.allocator);
defer wanted_steps.deinit();
if (step_names.len == 0) {
try wanted_steps.append(self.default_step);
} else {
for (step_names) |step_name| {
const s = try self.getTopLevelStepByName(step_name);
try wanted_steps.append(s);
}
}
for (wanted_steps.items) |s| {
try self.makeOneStep(s);
}
}
pub fn getInstallStep(self: *Build) *Step {
return &self.install_tls.step;
}
pub fn getUninstallStep(self: *Build) *Step {
return &self.uninstall_tls.step;
}
fn makeUninstall(uninstall_step: *Step) anyerror!void {
const uninstall_tls = @fieldParentPtr(TopLevelStep, "step", uninstall_step);
const self = @fieldParentPtr(Build, "uninstall_tls", uninstall_tls);
for (self.installed_files.items) |installed_file| {
const full_path = self.getInstallPath(installed_file.dir, installed_file.path);
if (self.verbose) {
log.info("rm {s}", .{full_path});
}
fs.cwd().deleteTree(full_path) catch {};
}
// TODO remove empty directories
}
fn makeOneStep(self: *Build, s: *Step) anyerror!void {
if (s.loop_flag) {
log.err("Dependency loop detected:\n {s}", .{s.name});
return error.DependencyLoopDetected;
}
s.loop_flag = true;
for (s.dependencies.items) |dep| {
self.makeOneStep(dep) catch |err| {
if (err == error.DependencyLoopDetected) {
log.err(" {s}", .{s.name});
}
return err;
};
}
s.loop_flag = false;
try s.make();
}
fn getTopLevelStepByName(self: *Build, name: []const u8) !*Step {
for (self.top_level_steps.items) |top_level_step| {
if (mem.eql(u8, top_level_step.step.name, name)) {
return &top_level_step.step;
}
}
log.err("Cannot run step '{s}' because it does not exist", .{name});
return error.InvalidStepName;
}
pub fn option(self: *Build, comptime T: type, name_raw: []const u8, description_raw: []const u8) ?T {
const name = self.dupe(name_raw);
const description = self.dupe(description_raw);
const type_id = comptime typeToEnum(T);
const enum_options = if (type_id == .@"enum") blk: {
const fields = comptime std.meta.fields(T);
var options = ArrayList([]const u8).initCapacity(self.allocator, fields.len) catch @panic("OOM");
inline for (fields) |field| {
options.appendAssumeCapacity(field.name);
}
break :blk options.toOwnedSlice() catch @panic("OOM");
} else null;
const available_option = AvailableOption{
.name = name,
.type_id = type_id,
.description = description,
.enum_options = enum_options,
};
if ((self.available_options_map.fetchPut(name, available_option) catch @panic("OOM")) != null) {
panic("Option '{s}' declared twice", .{name});
}
self.available_options_list.append(available_option) catch @panic("OOM");
const option_ptr = self.user_input_options.getPtr(name) orelse return null;
option_ptr.used = true;
switch (type_id) {
.bool => switch (option_ptr.value) {
.flag => return true,
.scalar => |s| {
if (mem.eql(u8, s, "true")) {
return true;
} else if (mem.eql(u8, s, "false")) {
return false;
} else {
log.err("Expected -D{s} to be a boolean, but received '{s}'\n", .{ name, s });
self.markInvalidUserInput();
return null;
}
},
.list, .map => {
log.err("Expected -D{s} to be a boolean, but received a {s}.\n", .{
name, @tagName(option_ptr.value),
});
self.markInvalidUserInput();
return null;
},
},
.int => switch (option_ptr.value) {
.flag, .list, .map => {
log.err("Expected -D{s} to be an integer, but received a {s}.\n", .{
name, @tagName(option_ptr.value),
});
self.markInvalidUserInput();
return null;
},
.scalar => |s| {
const n = std.fmt.parseInt(T, s, 10) catch |err| switch (err) {
error.Overflow => {
log.err("-D{s} value {s} cannot fit into type {s}.\n", .{ name, s, @typeName(T) });
self.markInvalidUserInput();
return null;
},
else => {
log.err("Expected -D{s} to be an integer of type {s}.\n", .{ name, @typeName(T) });
self.markInvalidUserInput();
return null;
},
};
return n;
},
},
.float => switch (option_ptr.value) {
.flag, .map, .list => {
log.err("Expected -D{s} to be a float, but received a {s}.\n", .{
name, @tagName(option_ptr.value),
});
self.markInvalidUserInput();
return null;
},
.scalar => |s| {
const n = std.fmt.parseFloat(T, s) catch {
log.err("Expected -D{s} to be a float of type {s}.\n", .{ name, @typeName(T) });
self.markInvalidUserInput();
return null;
};
return n;
},
},
.@"enum" => switch (option_ptr.value) {
.flag, .map, .list => {
log.err("Expected -D{s} to be an enum, but received a {s}.\n", .{
name, @tagName(option_ptr.value),
});
self.markInvalidUserInput();
return null;
},
.scalar => |s| {
if (std.meta.stringToEnum(T, s)) |enum_lit| {
return enum_lit;
} else {
log.err("Expected -D{s} to be of type {s}.\n", .{ name, @typeName(T) });
self.markInvalidUserInput();
return null;
}
},
},
.string => switch (option_ptr.value) {
.flag, .list, .map => {
log.err("Expected -D{s} to be a string, but received a {s}.\n", .{
name, @tagName(option_ptr.value),
});
self.markInvalidUserInput();
return null;
},
.scalar => |s| return s,
},
.list => switch (option_ptr.value) {
.flag, .map => {
log.err("Expected -D{s} to be a list, but received a {s}.\n", .{
name, @tagName(option_ptr.value),
});
self.markInvalidUserInput();
return null;
},
.scalar => |s| {
return self.allocator.dupe([]const u8, &[_][]const u8{s}) catch @panic("OOM");
},
.list => |lst| return lst.items,
},
}
}
pub fn step(self: *Build, name: []const u8, description: []const u8) *Step {
const step_info = self.allocator.create(TopLevelStep) catch @panic("OOM");
step_info.* = TopLevelStep{
.step = Step.initNoOp(.top_level, name, self.allocator),
.description = self.dupe(description),
};
self.top_level_steps.append(step_info) catch @panic("OOM");
return &step_info.step;
}
pub const StandardOptimizeOptionOptions = struct {
preferred_optimize_mode: ?std.builtin.Mode = null,
};
pub fn standardOptimizeOption(self: *Build, options: StandardOptimizeOptionOptions) std.builtin.Mode {
if (options.preferred_optimize_mode) |mode| {
if (self.option(bool, "release", "optimize for end users") orelse false) {
return mode;
} else {
return .Debug;
}
} else {
return self.option(
std.builtin.Mode,
"optimize",
"prioritize performance, safety, or binary size (-O flag)",
) orelse .Debug;
}
}
pub const StandardTargetOptionsArgs = struct {
whitelist: ?[]const CrossTarget = null,
default_target: CrossTarget = CrossTarget{},
};
/// Exposes standard `zig build` options for choosing a target.
pub fn standardTargetOptions(self: *Build, args: StandardTargetOptionsArgs) CrossTarget {
const maybe_triple = self.option(
[]const u8,
"target",
"The CPU architecture, OS, and ABI to build for",
);
const mcpu = self.option([]const u8, "cpu", "Target CPU features to add or subtract");
if (maybe_triple == null and mcpu == null) {
return args.default_target;
}
const triple = maybe_triple orelse "native";
var diags: CrossTarget.ParseOptions.Diagnostics = .{};
const selected_target = CrossTarget.parse(.{
.arch_os_abi = triple,
.cpu_features = mcpu,
.diagnostics = &diags,
}) catch |err| switch (err) {
error.UnknownCpuModel => {
log.err("Unknown CPU: '{s}'\nAvailable CPUs for architecture '{s}':", .{
diags.cpu_name.?,
@tagName(diags.arch.?),
});
for (diags.arch.?.allCpuModels()) |cpu| {
log.err(" {s}", .{cpu.name});
}
self.markInvalidUserInput();
return args.default_target;
},
error.UnknownCpuFeature => {
log.err(
\\Unknown CPU feature: '{s}'
\\Available CPU features for architecture '{s}':
\\
, .{
diags.unknown_feature_name.?,
@tagName(diags.arch.?),
});
for (diags.arch.?.allFeaturesList()) |feature| {
log.err(" {s}: {s}", .{ feature.name, feature.description });
}
self.markInvalidUserInput();
return args.default_target;
},
error.UnknownOperatingSystem => {
log.err(
\\Unknown OS: '{s}'
\\Available operating systems:
\\
, .{diags.os_name.?});
inline for (std.meta.fields(std.Target.Os.Tag)) |field| {
log.err(" {s}", .{field.name});
}
self.markInvalidUserInput();
return args.default_target;
},
else => |e| {
log.err("Unable to parse target '{s}': {s}\n", .{ triple, @errorName(e) });
self.markInvalidUserInput();
return args.default_target;
},
};
const selected_canonicalized_triple = selected_target.zigTriple(self.allocator) catch @panic("OOM");
if (args.whitelist) |list| whitelist_check: {
// Make sure it's a match of one of the list.
var mismatch_triple = true;
var mismatch_cpu_features = true;
var whitelist_item = CrossTarget{};
for (list) |t| {
mismatch_cpu_features = true;
mismatch_triple = true;
const t_triple = t.zigTriple(self.allocator) catch @panic("OOM");
if (mem.eql(u8, t_triple, selected_canonicalized_triple)) {
mismatch_triple = false;
whitelist_item = t;
if (t.getCpuFeatures().isSuperSetOf(selected_target.getCpuFeatures())) {
mismatch_cpu_features = false;
break :whitelist_check;
} else {
break;
}
}
}
if (mismatch_triple) {
log.err("Chosen target '{s}' does not match one of the supported targets:", .{
selected_canonicalized_triple,
});
for (list) |t| {
const t_triple = t.zigTriple(self.allocator) catch @panic("OOM");
log.err(" {s}", .{t_triple});
}
} else {
assert(mismatch_cpu_features);
const whitelist_cpu = whitelist_item.getCpu();
const selected_cpu = selected_target.getCpu();
log.err("Chosen CPU model '{s}' does not match one of the supported targets:", .{
selected_cpu.model.name,
});
log.err(" Supported feature Set: ", .{});
const all_features = whitelist_cpu.arch.allFeaturesList();
var populated_cpu_features = whitelist_cpu.model.features;
populated_cpu_features.populateDependencies(all_features);
for (all_features) |feature, i_usize| {
const i = @intCast(std.Target.Cpu.Feature.Set.Index, i_usize);
const in_cpu_set = populated_cpu_features.isEnabled(i);
if (in_cpu_set) {
log.err("{s} ", .{feature.name});
}
}
log.err(" Remove: ", .{});
for (all_features) |feature, i_usize| {
const i = @intCast(std.Target.Cpu.Feature.Set.Index, i_usize);
const in_cpu_set = populated_cpu_features.isEnabled(i);
const in_actual_set = selected_cpu.features.isEnabled(i);
if (in_actual_set and !in_cpu_set) {
log.err("{s} ", .{feature.name});
}
}
}
self.markInvalidUserInput();
return args.default_target;
}
return selected_target;
}
pub fn addUserInputOption(self: *Build, name_raw: []const u8, value_raw: []const u8) !bool {
const name = self.dupe(name_raw);
const value = self.dupe(value_raw);
const gop = try self.user_input_options.getOrPut(name);
if (!gop.found_existing) {
gop.value_ptr.* = UserInputOption{
.name = name,
.value = .{ .scalar = value },
.used = false,
};
return false;
}
// option already exists
switch (gop.value_ptr.value) {
.scalar => |s| {
// turn it into a list
var list = ArrayList([]const u8).init(self.allocator);
try list.append(s);
try list.append(value);
try self.user_input_options.put(name, .{
.name = name,
.value = .{ .list = list },
.used = false,
});
},
.list => |*list| {
// append to the list
try list.append(value);
try self.user_input_options.put(name, .{
.name = name,
.value = .{ .list = list.* },
.used = false,
});
},
.flag => {
log.warn("Option '-D{s}={s}' conflicts with flag '-D{s}'.", .{ name, value, name });
return true;
},
.map => |*map| {
_ = map;
log.warn("TODO maps as command line arguments is not implemented yet.", .{});
return true;
},
}
return false;
}
pub fn addUserInputFlag(self: *Build, name_raw: []const u8) !bool {
const name = self.dupe(name_raw);
const gop = try self.user_input_options.getOrPut(name);
if (!gop.found_existing) {
gop.value_ptr.* = .{
.name = name,
.value = .{ .flag = {} },
.used = false,
};
return false;
}
// option already exists
switch (gop.value_ptr.value) {
.scalar => |s| {
log.err("Flag '-D{s}' conflicts with option '-D{s}={s}'.", .{ name, name, s });
return true;
},
.list, .map => {
log.err("Flag '-D{s}' conflicts with multiple options of the same name.", .{name});
return true;
},
.flag => {},
}
return false;
}
fn typeToEnum(comptime T: type) TypeId {
return switch (@typeInfo(T)) {
.Int => .int,
.Float => .float,
.Bool => .bool,
.Enum => .@"enum",
else => switch (T) {
[]const u8 => .string,
[]const []const u8 => .list,
else => @compileError("Unsupported type: " ++ @typeName(T)),
},
};
}
fn markInvalidUserInput(self: *Build) void {
self.invalid_user_input = true;
}
pub fn validateUserInputDidItFail(self: *Build) bool {
// make sure all args are used
var it = self.user_input_options.iterator();
while (it.next()) |entry| {
if (!entry.value_ptr.used) {
log.err("Invalid option: -D{s}", .{entry.key_ptr.*});
self.markInvalidUserInput();
}
}
return self.invalid_user_input;
}
pub fn spawnChild(self: *Build, argv: []const []const u8) !void {
return self.spawnChildEnvMap(null, self.env_map, argv);
}
fn printCmd(cwd: ?[]const u8, argv: []const []const u8) void {
if (cwd) |yes_cwd| std.debug.print("cd {s} && ", .{yes_cwd});
for (argv) |arg| {
std.debug.print("{s} ", .{arg});
}
std.debug.print("\n", .{});
}
pub fn spawnChildEnvMap(self: *Build, cwd: ?[]const u8, env_map: *const EnvMap, argv: []const []const u8) !void {
if (self.verbose) {
printCmd(cwd, argv);
}
if (!std.process.can_spawn)
return error.ExecNotSupported;
var child = std.ChildProcess.init(argv, self.allocator);
child.cwd = cwd;
child.env_map = env_map;
const term = child.spawnAndWait() catch |err| {
log.err("Unable to spawn {s}: {s}", .{ argv[0], @errorName(err) });
return err;
};
switch (term) {
.Exited => |code| {
if (code != 0) {
log.err("The following command exited with error code {}:", .{code});
printCmd(cwd, argv);
return error.UncleanExit;
}
},
else => {
log.err("The following command terminated unexpectedly:", .{});
printCmd(cwd, argv);
return error.UncleanExit;
},
}
}
pub fn installArtifact(self: *Build, artifact: *CompileStep) void {
self.getInstallStep().dependOn(&self.addInstallArtifact(artifact).step);
}
pub fn addInstallArtifact(self: *Build, artifact: *CompileStep) *InstallArtifactStep {
return InstallArtifactStep.create(self, artifact);
}
///`dest_rel_path` is relative to prefix path
pub fn installFile(self: *Build, src_path: []const u8, dest_rel_path: []const u8) void {
self.getInstallStep().dependOn(&self.addInstallFileWithDir(.{ .path = src_path }, .prefix, dest_rel_path).step);
}
pub fn installDirectory(self: *Build, options: InstallDirectoryOptions) void {
self.getInstallStep().dependOn(&self.addInstallDirectory(options).step);
}
///`dest_rel_path` is relative to bin path
pub fn installBinFile(self: *Build, src_path: []const u8, dest_rel_path: []const u8) void {
self.getInstallStep().dependOn(&self.addInstallFileWithDir(.{ .path = src_path }, .bin, dest_rel_path).step);
}
///`dest_rel_path` is relative to lib path
pub fn installLibFile(self: *Build, src_path: []const u8, dest_rel_path: []const u8) void {
self.getInstallStep().dependOn(&self.addInstallFileWithDir(.{ .path = src_path }, .lib, dest_rel_path).step);
}
/// Output format (BIN vs Intel HEX) determined by filename
pub fn installRaw(self: *Build, artifact: *CompileStep, dest_filename: []const u8, options: InstallRawStep.CreateOptions) *InstallRawStep {
const raw = self.addInstallRaw(artifact, dest_filename, options);
self.getInstallStep().dependOn(&raw.step);
return raw;
}
///`dest_rel_path` is relative to install prefix path
pub fn addInstallFile(self: *Build, source: FileSource, dest_rel_path: []const u8) *InstallFileStep {
return self.addInstallFileWithDir(source.dupe(self), .prefix, dest_rel_path);
}
///`dest_rel_path` is relative to bin path
pub fn addInstallBinFile(self: *Build, source: FileSource, dest_rel_path: []const u8) *InstallFileStep {
return self.addInstallFileWithDir(source.dupe(self), .bin, dest_rel_path);
}
///`dest_rel_path` is relative to lib path
pub fn addInstallLibFile(self: *Build, source: FileSource, dest_rel_path: []const u8) *InstallFileStep {
return self.addInstallFileWithDir(source.dupe(self), .lib, dest_rel_path);
}
pub fn addInstallHeaderFile(b: *Build, src_path: []const u8, dest_rel_path: []const u8) *InstallFileStep {
return b.addInstallFileWithDir(.{ .path = src_path }, .header, dest_rel_path);
}
pub fn addInstallRaw(self: *Build, artifact: *CompileStep, dest_filename: []const u8, options: InstallRawStep.CreateOptions) *InstallRawStep {
return InstallRawStep.create(self, artifact, dest_filename, options);
}
pub fn addInstallFileWithDir(
self: *Build,
source: FileSource,
install_dir: InstallDir,
dest_rel_path: []const u8,
) *InstallFileStep {
if (dest_rel_path.len == 0) {
panic("dest_rel_path must be non-empty", .{});
}
const install_step = self.allocator.create(InstallFileStep) catch @panic("OOM");
install_step.* = InstallFileStep.init(self, source.dupe(self), install_dir, dest_rel_path);
return install_step;
}
pub fn addInstallDirectory(self: *Build, options: InstallDirectoryOptions) *InstallDirStep {
const install_step = self.allocator.create(InstallDirStep) catch @panic("OOM");
install_step.* = InstallDirStep.init(self, options);
return install_step;
}
pub fn pushInstalledFile(self: *Build, dir: InstallDir, dest_rel_path: []const u8) void {
const file = InstalledFile{
.dir = dir,
.path = dest_rel_path,
};
self.installed_files.append(file.dupe(self)) catch @panic("OOM");
}
pub fn updateFile(self: *Build, source_path: []const u8, dest_path: []const u8) !void {
if (self.verbose) {
log.info("cp {s} {s} ", .{ source_path, dest_path });
}
const cwd = fs.cwd();
const prev_status = try fs.Dir.updateFile(cwd, source_path, cwd, dest_path, .{});
if (self.verbose) switch (prev_status) {
.stale => log.info("# installed", .{}),
.fresh => log.info("# up-to-date", .{}),
};
}
pub fn truncateFile(self: *Build, dest_path: []const u8) !void {
if (self.verbose) {
log.info("truncate {s}", .{dest_path});
}
const cwd = fs.cwd();
var src_file = cwd.createFile(dest_path, .{}) catch |err| switch (err) {
error.FileNotFound => blk: {
if (fs.path.dirname(dest_path)) |dirname| {
try cwd.makePath(dirname);
}
break :blk try cwd.createFile(dest_path, .{});
},
else => |e| return e,
};
src_file.close();
}
pub fn pathFromRoot(b: *Build, p: []const u8) []u8 {
return fs.path.resolve(b.allocator, &.{ b.build_root.path orelse ".", p }) catch @panic("OOM");
}
pub fn pathJoin(self: *Build, paths: []const []const u8) []u8 {
return fs.path.join(self.allocator, paths) catch @panic("OOM");
}
pub fn fmt(self: *Build, comptime format: []const u8, args: anytype) []u8 {
return fmt_lib.allocPrint(self.allocator, format, args) catch @panic("OOM");
}
pub fn findProgram(self: *Build, names: []const []const u8, paths: []const []const u8) ![]const u8 {
// TODO report error for ambiguous situations
const exe_extension = @as(CrossTarget, .{}).exeFileExt();
for (self.search_prefixes.items) |search_prefix| {
for (names) |name| {
if (fs.path.isAbsolute(name)) {
return name;
}
const full_path = self.pathJoin(&.{
search_prefix,
"bin",
self.fmt("{s}{s}", .{ name, exe_extension }),
});
return fs.realpathAlloc(self.allocator, full_path) catch continue;
}
}
if (self.env_map.get("PATH")) |PATH| {
for (names) |name| {
if (fs.path.isAbsolute(name)) {
return name;
}
var it = mem.tokenize(u8, PATH, &[_]u8{fs.path.delimiter});
while (it.next()) |path| {
const full_path = self.pathJoin(&.{
path,
self.fmt("{s}{s}", .{ name, exe_extension }),
});
return fs.realpathAlloc(self.allocator, full_path) catch continue;
}
}
}
for (names) |name| {
if (fs.path.isAbsolute(name)) {
return name;
}
for (paths) |path| {
const full_path = self.pathJoin(&.{
path,
self.fmt("{s}{s}", .{ name, exe_extension }),
});
return fs.realpathAlloc(self.allocator, full_path) catch continue;
}
}
return error.FileNotFound;
}
pub fn execAllowFail(
self: *Build,
argv: []const []const u8,
out_code: *u8,
stderr_behavior: std.ChildProcess.StdIo,
) ExecError![]u8 {
assert(argv.len != 0);
if (!std.process.can_spawn)
return error.ExecNotSupported;
const max_output_size = 400 * 1024;
var child = std.ChildProcess.init(argv, self.allocator);
child.stdin_behavior = .Ignore;
child.stdout_behavior = .Pipe;
child.stderr_behavior = stderr_behavior;
child.env_map = self.env_map;
try child.spawn();
const stdout = child.stdout.?.reader().readAllAlloc(self.allocator, max_output_size) catch {
return error.ReadFailure;
};
errdefer self.allocator.free(stdout);
const term = try child.wait();
switch (term) {
.Exited => |code| {
if (code != 0) {
out_code.* = @truncate(u8, code);
return error.ExitCodeFailure;
}
return stdout;
},
.Signal, .Stopped, .Unknown => |code| {
out_code.* = @truncate(u8, code);
return error.ProcessTerminated;
},
}
}
pub fn execFromStep(self: *Build, argv: []const []const u8, src_step: ?*Step) ![]u8 {
assert(argv.len != 0);
if (self.verbose) {
printCmd(null, argv);
}
if (!std.process.can_spawn) {
if (src_step) |s| log.err("{s}...", .{s.name});
log.err("Unable to spawn the following command: cannot spawn child process", .{});
printCmd(null, argv);
std.os.abort();
}
var code: u8 = undefined;
return self.execAllowFail(argv, &code, .Inherit) catch |err| switch (err) {
error.ExecNotSupported => {
if (src_step) |s| log.err("{s}...", .{s.name});
log.err("Unable to spawn the following command: cannot spawn child process", .{});
printCmd(null, argv);
std.os.abort();
},
error.FileNotFound => {
if (src_step) |s| log.err("{s}...", .{s.name});
log.err("Unable to spawn the following command: file not found", .{});
printCmd(null, argv);
std.os.exit(@truncate(u8, code));
},
error.ExitCodeFailure => {
if (src_step) |s| log.err("{s}...", .{s.name});
if (self.prominent_compile_errors) {
log.err("The step exited with error code {d}", .{code});
} else {
log.err("The following command exited with error code {d}:", .{code});
printCmd(null, argv);
}
std.os.exit(@truncate(u8, code));
},
error.ProcessTerminated => {
if (src_step) |s| log.err("{s}...", .{s.name});
log.err("The following command terminated unexpectedly:", .{});
printCmd(null, argv);
std.os.exit(@truncate(u8, code));
},
else => |e| return e,
};
}
pub fn exec(self: *Build, argv: []const []const u8) ![]u8 {
return self.execFromStep(argv, null);
}
pub fn addSearchPrefix(self: *Build, search_prefix: []const u8) void {
self.search_prefixes.append(self.dupePath(search_prefix)) catch @panic("OOM");
}
pub fn getInstallPath(self: *Build, dir: InstallDir, dest_rel_path: []const u8) []const u8 {
assert(!fs.path.isAbsolute(dest_rel_path)); // Install paths must be relative to the prefix
const base_dir = switch (dir) {
.prefix => self.install_path,
.bin => self.exe_dir,
.lib => self.lib_dir,
.header => self.h_dir,
.custom => |path| self.pathJoin(&.{ self.install_path, path }),
};
return fs.path.resolve(
self.allocator,
&[_][]const u8{ base_dir, dest_rel_path },
) catch @panic("OOM");
}
pub const Dependency = struct {
builder: *Build,
pub fn artifact(d: *Dependency, name: []const u8) *CompileStep {
var found: ?*CompileStep = null;
for (d.builder.install_tls.step.dependencies.items) |dep_step| {
const inst = dep_step.cast(InstallArtifactStep) orelse continue;
if (mem.eql(u8, inst.artifact.name, name)) {
if (found != null) panic("artifact name '{s}' is ambiguous", .{name});
found = inst.artifact;
}
}
return found orelse {
for (d.builder.install_tls.step.dependencies.items) |dep_step| {
const inst = dep_step.cast(InstallArtifactStep) orelse continue;
log.info("available artifact: '{s}'", .{inst.artifact.name});
}
panic("unable to find artifact '{s}'", .{name});
};
}
pub fn module(d: *Dependency, name: []const u8) *Module {
return d.builder.modules.get(name) orelse {
panic("unable to find module '{s}'", .{name});
};
}
};
pub fn dependency(b: *Build, name: []const u8, args: anytype) *Dependency {
const build_runner = @import("root");
const deps = build_runner.dependencies;
inline for (@typeInfo(deps.imports).Struct.decls) |decl| {
if (mem.startsWith(u8, decl.name, b.dep_prefix) and
mem.endsWith(u8, decl.name, name) and
decl.name.len == b.dep_prefix.len + name.len)
{
const build_zig = @field(deps.imports, decl.name);
const build_root = @field(deps.build_root, decl.name);
return dependencyInner(b, name, build_root, build_zig, args);
}
}
const full_path = b.pathFromRoot("build.zig.zon");
std.debug.print("no dependency named '{s}' in '{s}'. All packages used in build.zig must be declared in this file.\n", .{ name, full_path });
std.process.exit(1);
}
fn dependencyInner(
b: *Build,
name: []const u8,
build_root_string: []const u8,
comptime build_zig: type,
args: anytype,
) *Dependency {
const build_root: std.Build.Cache.Directory = .{
.path = build_root_string,
.handle = std.fs.cwd().openDir(build_root_string, .{}) catch |err| {
std.debug.print("unable to open '{s}': {s}\n", .{
build_root_string, @errorName(err),
});
std.process.exit(1);
},
};
const sub_builder = b.createChild(name, build_root, args) catch @panic("unhandled error");
sub_builder.runBuild(build_zig) catch @panic("unhandled error");
if (sub_builder.validateUserInputDidItFail()) {
std.debug.dumpCurrentStackTrace(@returnAddress());
}
const dep = b.allocator.create(Dependency) catch @panic("OOM");
dep.* = .{ .builder = sub_builder };
return dep;
}
pub fn runBuild(b: *Build, build_zig: anytype) anyerror!void {
switch (@typeInfo(@typeInfo(@TypeOf(build_zig.build)).Fn.return_type.?)) {
.Void => build_zig.build(b),
.ErrorUnion => try build_zig.build(b),
else => @compileError("expected return type of build to be 'void' or '!void'"),
}
}
test "builder.findProgram compiles" {
if (builtin.os.tag == .wasi) return error.SkipZigTest;
var arena = std.heap.ArenaAllocator.init(std.heap.page_allocator);
defer arena.deinit();
const host = try NativeTargetInfo.detect(.{});
const builder = try Build.create(
arena.allocator(),
"zig",
"zig-cache",
"zig-cache",
"zig-cache",
host,
);
defer builder.destroy();
_ = builder.findProgram(&[_][]const u8{}, &[_][]const u8{}) catch null;
}
pub const Module = struct {
builder: *Build,
/// This could either be a generated file, in which case the module
/// contains exactly one file, or it could be a path to the root source
/// file of directory of files which constitute the module.
source_file: FileSource,
dependencies: std.StringArrayHashMap(*Module),
};
/// A file that is generated by a build step.
/// This struct is an interface that is meant to be used with `@fieldParentPtr` to implement the actual path logic.
pub const GeneratedFile = struct {
/// The step that generates the file
step: *Step,
/// The path to the generated file. Must be either absolute or relative to the build root.
/// This value must be set in the `fn make()` of the `step` and must not be `null` afterwards.
path: ?[]const u8 = null,
pub fn getPath(self: GeneratedFile) []const u8 {
return self.path orelse std.debug.panic(
"getPath() was called on a GeneratedFile that wasn't build yet. Is there a missing Step dependency on step '{s}'?",
.{self.step.name},
);
}
};
/// A file source is a reference to an existing or future file.
///
pub const FileSource = union(enum) {
/// A plain file path, relative to build root or absolute.
path: []const u8,
/// A file that is generated by an interface. Those files usually are
/// not available until built by a build step.
generated: *const GeneratedFile,
/// Returns a new file source that will have a relative path to the build root guaranteed.
/// This should be preferred over setting `.path` directly as it documents that the files are in the project directory.
pub fn relative(path: []const u8) FileSource {
std.debug.assert(!std.fs.path.isAbsolute(path));
return FileSource{ .path = path };
}
/// Returns a string that can be shown to represent the file source.
/// Either returns the path or `"generated"`.
pub fn getDisplayName(self: FileSource) []const u8 {
return switch (self) {
.path => self.path,
.generated => "generated",
};
}
/// Adds dependencies this file source implies to the given step.
pub fn addStepDependencies(self: FileSource, other_step: *Step) void {
switch (self) {
.path => {},
.generated => |gen| other_step.dependOn(gen.step),
}
}
/// Should only be called during make(), returns a path relative to the build root or absolute.
pub fn getPath(self: FileSource, builder: *Build) []const u8 {
const path = switch (self) {
.path => |p| builder.pathFromRoot(p),
.generated => |gen| gen.getPath(),
};
return path;
}
/// Duplicates the file source for a given builder.
pub fn dupe(self: FileSource, b: *Build) FileSource {
return switch (self) {
.path => |p| .{ .path = b.dupePath(p) },
.generated => |gen| .{ .generated = gen },
};
}
};
/// Allocates a new string for assigning a value to a named macro.
/// If the value is omitted, it is set to 1.
/// `name` and `value` need not live longer than the function call.
pub fn constructCMacro(allocator: Allocator, name: []const u8, value: ?[]const u8) []const u8 {
var macro = allocator.alloc(
u8,
name.len + if (value) |value_slice| value_slice.len + 1 else 0,
) catch |err| if (err == error.OutOfMemory) @panic("Out of memory") else unreachable;
mem.copy(u8, macro, name);
if (value) |value_slice| {
macro[name.len] = '=';
mem.copy(u8, macro[name.len + 1 ..], value_slice);
}
return macro;
}
pub const VcpkgRoot = union(VcpkgRootStatus) {
unattempted: void,
not_found: void,
found: []const u8,
};
pub const VcpkgRootStatus = enum {
unattempted,
not_found,
found,
};
pub const InstallDir = union(enum) {
prefix: void,
lib: void,
bin: void,
header: void,
/// A path relative to the prefix
custom: []const u8,
/// Duplicates the install directory including the path if set to custom.
pub fn dupe(self: InstallDir, builder: *Build) InstallDir {
if (self == .custom) {
// Written with this temporary to avoid RLS problems
const duped_path = builder.dupe(self.custom);
return .{ .custom = duped_path };
} else {
return self;
}
}
};
pub const InstalledFile = struct {
dir: InstallDir,
path: []const u8,
/// Duplicates the installed file path and directory.
pub fn dupe(self: InstalledFile, builder: *Build) InstalledFile {
return .{
.dir = self.dir.dupe(builder),
.path = builder.dupe(self.path),
};
}
};
pub fn serializeCpu(allocator: Allocator, cpu: std.Target.Cpu) ![]const u8 {
// TODO this logic can disappear if cpu model + features becomes part of the target triple
const all_features = cpu.arch.allFeaturesList();
var populated_cpu_features = cpu.model.features;
populated_cpu_features.populateDependencies(all_features);
if (populated_cpu_features.eql(cpu.features)) {
// The CPU name alone is sufficient.
return cpu.model.name;
} else {
var mcpu_buffer = ArrayList(u8).init(allocator);
try mcpu_buffer.appendSlice(cpu.model.name);
for (all_features) |feature, i_usize| {
const i = @intCast(std.Target.Cpu.Feature.Set.Index, i_usize);
const in_cpu_set = populated_cpu_features.isEnabled(i);
const in_actual_set = cpu.features.isEnabled(i);
if (in_cpu_set and !in_actual_set) {
try mcpu_buffer.writer().print("-{s}", .{feature.name});
} else if (!in_cpu_set and in_actual_set) {
try mcpu_buffer.writer().print("+{s}", .{feature.name});
}
}
return try mcpu_buffer.toOwnedSlice();
}
}
test {
_ = CheckFileStep;
_ = CheckObjectStep;
_ = EmulatableRunStep;
_ = FmtStep;
_ = InstallArtifactStep;
_ = InstallDirStep;
_ = InstallFileStep;
_ = InstallRawStep;
_ = CompileStep;
_ = LogStep;
_ = OptionsStep;
_ = RemoveDirStep;
_ = RunStep;
_ = TranslateCStep;
_ = WriteFileStep;
}