zig/lib/std /
Build.zig
Shared state among all Build instances.
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 Target = std.Target;
const process = std.process;
const EnvMap = std.process.EnvMap;
const File = fs.File;
const Sha256 = std.crypto.hash.sha2.Sha256;
const Build = @This();
Cache
Build/Cache.zigPath to the directory containing build.zig.
pub const Cache = @import("Build/Cache.zig");
Step
Build/Step.zigNumber of stack frames captured when a StackTrace is recorded for debug purposes,
in particular at Step creation.
Set to 0 to disable stack collection.
pub const Step = @import("Build/Step.zig");
Module
Build/Module.zigExperimental. Use system Darling installation to run cross compiled macOS build artifacts.
pub const Module = @import("Build/Module.zig");
Watch
Build/Watch.zigUse system QEMU installation to run cross compiled foreign architecture build artifacts.
pub const Watch = @import("Build/Watch.zig");
Fuzz
Build/Fuzz.zigDarwin. Use Rosetta to run x86_64 macOS build artifacts on arm64 macOS.
pub const Fuzz = @import("Build/Fuzz.zig");
WebServer
Build/WebServer.zigUse system Wasmtime installation to run cross compiled wasm/wasi build artifacts.
pub const WebServer = @import("Build/WebServer.zig");
abi
Build/abi.zigUse system Wine installation to run cross compiled Windows build artifacts.
pub const abi = @import("Build/abi.zig");
ReleaseMode
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.
Also works for dynamic musl.
/// Shared state among all Build instances.
graph: *Graph,
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: ?[]const u8,
verbose_llvm_bc: ?[]const u8,
verbose_cimport: bool,
verbose_llvm_cpu_features: bool,
reference_trace: ?u32 = null,
invalid_user_input: bool,
default_step: *Step,
top_level_steps: std.StringArrayHashMapUnmanaged(*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: std.ArrayListUnmanaged([]const u8),
libc_file: ?[]const u8 = null,
/// Path to the directory containing build.zig.
build_root: Cache.Directory,
cache_root: Cache.Directory,
pkg_config_pkg_list: ?(PkgConfigError![]const PkgConfigPkg) = null,
args: ?[]const []const u8 = null,
debug_log_scopes: []const []const u8 = &.{},
debug_compile_errors: bool = false,
debug_incremental: bool = false,
debug_pkg_config: bool = false,
/// Number of stack frames captured when a `StackTrace` is recorded for debug purposes,
/// in particular at `Step` creation.
/// Set to 0 to disable stack collection.
debug_stack_frames_count: u8 = 8,
Graph
The hash of this instance's package. "" means that this is the root package.
/// 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`. /// Also works for dynamic musl. libc_runtimes_dir: ?[]const u8 = null,
hash()
A mapping from dependency names to package hashes.
dep_prefix: []const u8 = "",
eql()
Shared state among all Build instances. Settings that are here rather than in Build are not configurable per-package.
modules: std.StringArrayHashMap(*Module),
RunError
Information about the native target. Computed before build() is invoked.
named_writefiles: std.StringArrayHashMap(*Step.WriteFile), named_lazy_paths: std.StringArrayHashMap(LazyPath), /// The hash of this instance's package. `""` means that this is the root package. pkg_hash: []const u8, /// A mapping from dependency names to package hashes. available_deps: AvailableDeps,
PkgConfigError
User asked for the library to be disabled. The build runner has not confirmed whether the setting is recognized yet.
release_mode: ReleaseMode,
PkgConfigPkg
User asked for the library to be enabled. The build runner has not confirmed whether the setting is recognized yet.
build_id: ?std.zig.BuildId = null,
base_id:
The build runner has confirmed that this setting is recognized. System integration with this library has been resolved to off.
pub const ReleaseMode = enum {
off,
any,
fast,
safe,
small,
};
DirList
The build runner has confirmed that this setting is recognized. System integration with this library has been resolved to on.
/// Shared state among all Build instances.
/// Settings that are here rather than in Build are not configurable per-package.
pub const Graph = struct {
arena: Allocator,
system_library_options: std.StringArrayHashMapUnmanaged(SystemLibraryMode) = .empty,
system_package_mode: bool = false,
debug_compiler_runtime_libs: bool = false,
cache: Cache,
zig_exe: [:0]const u8,
env_map: EnvMap,
global_cache_root: Cache.Directory,
zig_lib_directory: Cache.Directory,
needed_lazy_dependencies: std.StringArrayHashMapUnmanaged(void) = .empty,
/// Information about the native target. Computed before build() is invoked.
host: ResolvedTarget,
incremental: ?bool = null,
random_seed: u32 = 0,
dependency_cache: InitializedDepMap = .empty,
allow_so_scripts: ?bool = null,
time_report: bool,
};
create()
If the type_id is enum or enum_list this provides the list of enum options
const AvailableDeps = []const struct { []const u8, []const u8 };
resolveInstallPrefix()
If null, the value won't be added, but T will still be type-checked.
const SystemLibraryMode = enum {
/// User asked for the library to be disabled.
/// The build runner has not confirmed whether the setting is recognized yet.
user_disabled,
/// User asked for the library to be enabled.
/// The build runner has not confirmed whether the setting is recognized yet.
user_enabled,
/// The build runner has confirmed that this setting is recognized.
/// System integration with this library has been resolved to off.
declared_disabled,
/// The build runner has confirmed that this setting is recognized.
/// System integration with this library has been resolved to on.
declared_enabled,
};
addOptions()
This function is intended to be called by lib/build_runner.zig, not a build.zig file.
const InitializedDepMap = std.HashMapUnmanaged(InitializedDepKey, *Dependency, InitializedDepContext, std.hash_map.default_max_load_percentage);
const InitializedDepKey = struct {
build_root_string: []const u8,
user_input_options: UserInputOptionsMap,
};
ExecutableOptions
Create a set of key-value pairs that can be converted into a Zig source
file and then inserted into a Zig compilation's module table for importing.
In other words, this provides a way to expose build.zig values to Zig
source code with @import.
Related: Module.addOptions.
const InitializedDepContext = struct {
allocator: Allocator,
addExecutable()
Embed a .manifest file in the compilation if the object format supports it.
https://learn.microsoft.com/en-us/windows/win32/sbscs/manifest-files-reference
Manifest files must have the extension .manifest.
Can be set regardless of target. The .manifest file will be ignored
if the target object format does not support embedded manifests.
pub fn hash(ctx: @This(), k: InitializedDepKey) u64 {
var hasher = std.hash.Wyhash.init(0);
hasher.update(k.build_root_string);
hashUserInputOptionsMap(ctx.allocator, k.user_input_options, &hasher);
return hasher.final();
}
ObjectOptions
Embed a .manifest file in the compilation if the object format supports it.
https://learn.microsoft.com/en-us/windows/win32/sbscs/manifest-files-reference
Manifest files must have the extension .manifest.
Can be set regardless of target. The .manifest file will be ignored
if the target object format does not support embedded manifests.
pub fn eql(_: @This(), lhs: InitializedDepKey, rhs: InitializedDepKey) bool {
if (!std.mem.eql(u8, lhs.build_root_string, rhs.build_root_string))
return false;
addObject()
Emits an object file instead of a test binary.
The object must be linked separately.
Usually used in conjunction with a custom test_runner.
if (lhs.user_input_options.count() != rhs.user_input_options.count())
return false;
LibraryOptions
Creates an executable containing unit tests.
Equivalent to running the command zig test --test-no-exec ....
**This step does not run the unit tests**. Typically, the result of this
function will be passed to addRunArtifact, creating a Step.Run. These
two steps are separated because they are independently configured and
cached.
var it = lhs.user_input_options.iterator();
while (it.next()) |lhs_entry| {
const rhs_value = rhs.user_input_options.get(lhs_entry.key_ptr.*) orelse return false;
if (!userValuesAreSame(lhs_entry.value_ptr.*.value, rhs_value.value))
return false;
}
addLibrary()
To choose the same computer as the one building the package, pass the
host field of the package's Build instance.
return true;
}
};
TestOptions
This function creates a module and adds it to the package's module set, making
it available to other packages which depend on this one.
createModule can be used instead to create a private module.
pub const RunError = error{
ReadFailure,
ExitCodeFailure,
ProcessTerminated,
ExecNotSupported,
} || std.process.Child.SpawnError;
addTest()
This function creates a private module, to be used by the current package,
but not exposed to other packages depending on this one.
addModule can be used instead to create a public module.
pub const PkgConfigError = error{
PkgConfigCrashed,
PkgConfigFailed,
PkgConfigNotInstalled,
PkgConfigInvalidOutput,
};
AssemblyOptions
Initializes a Step.Run 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 Step.Compile.run.
pub const PkgConfigPkg = struct {
name: []const u8,
desc: []const u8,
};
addModule()
Creates a Step.Run with an executable built with addExecutable.
Add command line arguments with methods of Step.Run.
const UserInputOptionsMap = StringHashMap(UserInputOption); const AvailableOptionsMap = StringHashMap(AvailableOption);
createModule()
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.
const AvailableOption = struct {
name: []const u8,
type_id: TypeId,
description: []const u8,
/// If the `type_id` is `enum` or `enum_list` this provides the list of enum options
enum_options: ?[]const []const u8,
};
addSystemCommand()
Allocator.dupe without the need to handle out of memory.
const UserInputOption = struct {
name: []const u8,
value: UserValue,
used: bool,
};
addRunArtifact()
Duplicates an array of strings without the need to handle out of memory.
const UserValue = union(enum) {
flag: void,
scalar: []const u8,
list: ArrayList([]const u8),
map: StringHashMap(*const UserValue),
lazy_path: LazyPath,
lazy_path_list: ArrayList(LazyPath),
};
addConfigHeader()
Duplicates a path and converts all slashes to the OS's canonical path separator.
const TypeId = enum {
bool,
int,
float,
@"enum",
enum_list,
string,
list,
build_id,
lazy_path,
lazy_path_list,
};
dupe()
Creates a configuration option to be passed to the build.zig script.
When a user directly runs zig build, they can set these options with -D arguments.
When a project depends on a Zig package as a dependency, it programmatically sets
these options when calling the dependency's build.zig script as a function.
null is returned when an option is left to default.
const TopLevelStep = struct {
pub const base_id: Step.Id = .top_level;
dupeInner()
Exposes standard zig build options for choosing a target and additionally
resolves the target query.
step: Step,
description: []const u8,
};
dupeStrings()
Obtain a target query from a string, reporting diagnostics to stderr if the
parsing failed.
Asserts that the diagnostics field of options is null. This use case
is handled instead by calling std.Target.Query.parse directly.
pub const DirList = struct {
lib_dir: ?[]const u8 = null,
exe_dir: ?[]const u8 = null,
include_dir: ?[]const u8 = null,
};
dupePath()
Exposes standard zig build options for choosing a target.
pub fn create(
graph: *Graph,
build_root: Cache.Directory,
cache_root: Cache.Directory,
available_deps: AvailableDeps,
) error{OutOfMemory}!*Build {
const arena = graph.arena;
addWriteFile()
This creates the install step and adds it to the dependencies of the
top-level install step, using all the default options.
See addInstallArtifact for a more flexible function.
const b = try arena.create(Build);
b.* = .{
.graph = graph,
.build_root = build_root,
.cache_root = cache_root,
.verbose = false,
.verbose_link = false,
.verbose_cc = false,
.verbose_air = false,
.verbose_llvm_ir = null,
.verbose_llvm_bc = null,
.verbose_cimport = false,
.verbose_llvm_cpu_features = false,
.invalid_user_input = false,
.allocator = arena,
.user_input_options = UserInputOptionsMap.init(arena),
.available_options_map = AvailableOptionsMap.init(arena),
.available_options_list = ArrayList(AvailableOption).init(arena),
.top_level_steps = .{},
.default_step = undefined,
.search_prefixes = .{},
.install_prefix = undefined,
.lib_dir = undefined,
.exe_dir = undefined,
.h_dir = undefined,
.dest_dir = graph.env_map.get("DESTDIR"),
.install_tls = .{
.step = .init(.{
.id = TopLevelStep.base_id,
.name = "install",
.owner = b,
}),
.description = "Copy build artifacts to prefix path",
},
.uninstall_tls = .{
.step = .init(.{
.id = TopLevelStep.base_id,
.name = "uninstall",
.owner = b,
.makeFn = makeUninstall,
}),
.description = "Remove build artifacts from prefix path",
},
.install_path = undefined,
.args = null,
.modules = .init(arena),
.named_writefiles = .init(arena),
.named_lazy_paths = .init(arena),
.pkg_hash = "",
.available_deps = available_deps,
.release_mode = .off,
};
try b.top_level_steps.put(arena, b.install_tls.step.name, &b.install_tls);
try b.top_level_steps.put(arena, b.uninstall_tls.step.name, &b.uninstall_tls);
b.default_step = &b.install_tls.step;
return b;
parseTargetQuery()
This merely creates the step; it does not add it to the dependencies of the top-level install step.
}
addNamedLazyPath()
dest_rel_path is relative to prefix path
fn createChild(
parent: *Build,
dep_name: []const u8,
build_root: Cache.Directory,
pkg_hash: []const u8,
pkg_deps: AvailableDeps,
user_input_options: UserInputOptionsMap,
) error{OutOfMemory}!*Build {
const child = try createChildOnly(parent, dep_name, build_root, pkg_hash, pkg_deps, user_input_options);
try determineAndApplyInstallPrefix(child);
return child;
parseTargetQuery()
dest_rel_path is relative to bin path
}
addUpdateSourceFiles()
dest_rel_path is relative to lib path
fn createChildOnly(
parent: *Build,
dep_name: []const u8,
build_root: Cache.Directory,
pkg_hash: []const u8,
pkg_deps: AvailableDeps,
user_input_options: UserInputOptionsMap,
) error{OutOfMemory}!*Build {
const allocator = parent.allocator;
const child = try allocator.create(Build);
child.* = .{
.graph = parent.graph,
.allocator = allocator,
.install_tls = .{
.step = .init(.{
.id = TopLevelStep.base_id,
.name = "install",
.owner = child,
}),
.description = "Copy build artifacts to prefix path",
},
.uninstall_tls = .{
.step = .init(.{
.id = TopLevelStep.base_id,
.name = "uninstall",
.owner = child,
.makeFn = makeUninstall,
}),
.description = "Remove build artifacts from prefix path",
},
.user_input_options = user_input_options,
.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_llvm_bc = parent.verbose_llvm_bc,
.verbose_cimport = parent.verbose_cimport,
.verbose_llvm_cpu_features = parent.verbose_llvm_cpu_features,
.reference_trace = parent.reference_trace,
.invalid_user_input = false,
.default_step = undefined,
.top_level_steps = .{},
.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 = parent.search_prefixes,
.libc_file = parent.libc_file,
.build_root = build_root,
.cache_root = parent.cache_root,
.debug_log_scopes = parent.debug_log_scopes,
.debug_compile_errors = parent.debug_compile_errors,
.debug_incremental = parent.debug_incremental,
.debug_pkg_config = parent.debug_pkg_config,
.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,
.libc_runtimes_dir = parent.libc_runtimes_dir,
.dep_prefix = parent.fmt("{s}{s}.", .{ parent.dep_prefix, dep_name }),
.modules = .init(allocator),
.named_writefiles = .init(allocator),
.named_lazy_paths = .init(allocator),
.pkg_hash = pkg_hash,
.available_deps = pkg_deps,
.release_mode = parent.release_mode,
};
try child.top_level_steps.put(allocator, child.install_tls.step.name, &child.install_tls);
try child.top_level_steps.put(allocator, child.uninstall_tls.step.name, &child.uninstall_tls);
child.default_step = &child.install_tls.step;
return child;
parseTargetQuery()
dest_rel_path is relative to install prefix path
}
addFail()
dest_rel_path is relative to bin path
fn userInputOptionsFromArgs(arena: Allocator, args: anytype) UserInputOptionsMap {
var map = UserInputOptionsMap.init(arena);
inline for (@typeInfo(@TypeOf(args)).@"struct".fields) |field| {
if (field.type == @Type(.null)) continue;
addUserInputOptionFromArg(arena, &map, field, field.type, @field(args, field.name));
}
return map;
parseTargetQuery()
dest_rel_path is relative to lib path
}
addTranslateC()
dest_rel_path is relative to header path
fn addUserInputOptionFromArg(
arena: Allocator,
map: *UserInputOptionsMap,
field: std.builtin.Type.StructField,
comptime T: type,
/// If null, the value won't be added, but `T` will still be type-checked.
maybe_value: ?T,
installArtifact()
References a file or directory relative to the source root.
) void {
switch (T) {
Target.Query => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .scalar = v.zigTriple(arena) catch @panic("OOM") },
.used = false,
}) catch @panic("OOM");
map.put("cpu", .{
.name = "cpu",
.value = .{ .scalar = v.serializeCpuAlloc(arena) catch @panic("OOM") },
.used = false,
}) catch @panic("OOM");
},
ResolvedTarget => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .scalar = v.query.zigTriple(arena) catch @panic("OOM") },
.used = false,
}) catch @panic("OOM");
map.put("cpu", .{
.name = "cpu",
.value = .{ .scalar = v.query.serializeCpuAlloc(arena) catch @panic("OOM") },
.used = false,
}) catch @panic("OOM");
},
std.zig.BuildId => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .scalar = std.fmt.allocPrint(arena, "{f}", .{v}) catch @panic("OOM") },
.used = false,
}) catch @panic("OOM");
},
LazyPath => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .lazy_path = v.dupeInner(arena) },
.used = false,
}) catch @panic("OOM");
},
[]const LazyPath => return if (maybe_value) |v| {
var list = ArrayList(LazyPath).initCapacity(arena, v.len) catch @panic("OOM");
for (v) |lp| list.appendAssumeCapacity(lp.dupeInner(arena));
map.put(field.name, .{
.name = field.name,
.value = .{ .lazy_path_list = list },
.used = false,
}) catch @panic("OOM");
},
[]const u8 => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .scalar = arena.dupe(u8, v) catch @panic("OOM") },
.used = false,
}) catch @panic("OOM");
},
[]const []const u8 => return if (maybe_value) |v| {
var list = ArrayList([]const u8).initCapacity(arena, v.len) catch @panic("OOM");
for (v) |s| list.appendAssumeCapacity(arena.dupe(u8, s) catch @panic("OOM"));
map.put(field.name, .{
.name = field.name,
.value = .{ .list = list },
.used = false,
}) catch @panic("OOM");
},
else => switch (@typeInfo(T)) {
.bool => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .scalar = if (v) "true" else "false" },
.used = false,
}) catch @panic("OOM");
},
.@"enum", .enum_literal => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .scalar = @tagName(v) },
.used = false,
}) catch @panic("OOM");
},
.comptime_int, .int => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .scalar = std.fmt.allocPrint(arena, "{d}", .{v}) catch @panic("OOM") },
.used = false,
}) catch @panic("OOM");
},
.comptime_float, .float => return if (maybe_value) |v| {
map.put(field.name, .{
.name = field.name,
.value = .{ .scalar = std.fmt.allocPrint(arena, "{x}", .{v}) catch @panic("OOM") },
.used = false,
}) catch @panic("OOM");
},
.pointer => |ptr_info| switch (ptr_info.size) {
.one => switch (@typeInfo(ptr_info.child)) {
.array => |array_info| {
comptime var slice_info = ptr_info;
slice_info.size = .slice;
slice_info.is_const = true;
slice_info.child = array_info.child;
slice_info.sentinel_ptr = null;
addUserInputOptionFromArg(
arena,
map,
field,
@Type(.{ .pointer = slice_info }),
maybe_value orelse null,
);
return;
},
else => {},
},
.slice => switch (@typeInfo(ptr_info.child)) {
.@"enum" => return if (maybe_value) |v| {
var list = ArrayList([]const u8).initCapacity(arena, v.len) catch @panic("OOM");
for (v) |tag| list.appendAssumeCapacity(@tagName(tag));
map.put(field.name, .{
.name = field.name,
.value = .{ .list = list },
.used = false,
}) catch @panic("OOM");
},
else => {
comptime var slice_info = ptr_info;
slice_info.is_const = true;
slice_info.sentinel_ptr = null;
addUserInputOptionFromArg(
arena,
map,
field,
@Type(.{ .pointer = slice_info }),
maybe_value orelse null,
);
return;
},
},
else => {},
},
.null => unreachable,
.optional => |info| switch (@typeInfo(info.child)) {
.optional => {},
else => {
addUserInputOptionFromArg(
arena,
map,
field,
info.child,
maybe_value orelse null,
);
return;
},
},
else => {},
},
}
@compileError("option '" ++ field.name ++ "' has unsupported type: " ++ @typeName(field.type));
parseTargetQuery()
This is low-level implementation details of the build system, not meant to be called by users' build scripts. Even in the build system itself it is a code smell to call this function.
}
option()
This is a helper function to be called from build.zig scripts, *not* from inside step make() functions. If any errors occur, it fails the build with a helpful message.
const OrderedUserValue = union(enum) {
flag: void,
scalar: []const u8,
list: ArrayList([]const u8),
map: ArrayList(Pair),
lazy_path: LazyPath,
lazy_path_list: ArrayList(LazyPath),
step()
When this function is called, it means that the current build does, in
fact, require this dependency. If the dependency is already fetched, it
proceeds in the same manner as dependency. However if the dependency was
not fetched, then when the build script is finished running, the build will
not proceed to the make phase. Instead, the parent process will
additionally fetch all the lazy dependencies that were actually required by
running the build script, rebuild the build script, and then run it again.
In other words, if this function returns null it means that the only
purpose of completing the configure phase is to find out all the other lazy
dependencies that are also required.
It is allowed to use this function for non-lazy dependencies, in which case
it will never return null. This allows toggling laziness via
build.zig.zon without changing build.zig logic.
const Pair = struct {
name: []const u8,
value: OrderedUserValue,
fn lessThan(_: void, lhs: Pair, rhs: Pair) bool {
return std.ascii.lessThanIgnoreCase(lhs.name, rhs.name);
}
};
StandardOptimizeOptionOptions
In a build.zig file, this function is to @import what lazyDependency is to dependency.
If the dependency is lazy and has not yet been fetched, it instructs the parent process to fetch
that dependency after the build script has finished running, then returns null.
If the dependency is lazy but has already been fetched, or if it is eager, it returns
the build.zig struct of that dependency, just like a regular @import.
fn hash(val: OrderedUserValue, hasher: *std.hash.Wyhash) void {
hasher.update(&std.mem.toBytes(std.meta.activeTag(val)));
switch (val) {
.flag => {},
.scalar => |scalar| hasher.update(scalar),
// lists are already ordered
.list => |list| for (list.items) |list_entry|
hasher.update(list_entry),
.map => |map| for (map.items) |map_entry| {
hasher.update(map_entry.name);
map_entry.value.hash(hasher);
},
.lazy_path => |lp| hashLazyPath(lp, hasher),
.lazy_path_list => |lp_list| for (lp_list.items) |lp| {
hashLazyPath(lp, hasher);
},
}
}
standardOptimizeOption()
The build.zig struct of the package importing the dependency.
When calling this function from the build function of a build.zig file's, you normally
pass @This().
fn hashLazyPath(lp: LazyPath, hasher: *std.hash.Wyhash) void {
switch (lp) {
.src_path => |sp| {
hasher.update(sp.owner.pkg_hash);
hasher.update(sp.sub_path);
},
.generated => |gen| {
hasher.update(gen.file.step.owner.pkg_hash);
hasher.update(std.mem.asBytes(&gen.up));
hasher.update(gen.sub_path);
},
.cwd_relative => |rel_path| {
hasher.update(rel_path);
},
.dependency => |dep| {
hasher.update(dep.dependency.builder.pkg_hash);
hasher.update(dep.sub_path);
},
}
}
StandardTargetOptionsArgs
The build.zig struct of the dependency, normally obtained by @import of the dependency.
If called from the build.zig file itself, use @This to obtain a reference to the struct.
fn mapFromUnordered(allocator: Allocator, unordered: std.StringHashMap(*const UserValue)) ArrayList(Pair) {
var ordered = ArrayList(Pair).init(allocator);
var it = unordered.iterator();
while (it.next()) |entry| {
ordered.append(.{
.name = entry.key_ptr.*,
.value = OrderedUserValue.fromUnordered(allocator, entry.value_ptr.*.*),
}) catch @panic("OOM");
}
standardTargetOptions()
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.
std.mem.sortUnstable(Pair, ordered.items, {}, Pair.lessThan);
return ordered;
}
parseTargetQuery()
The step that generates the file
fn fromUnordered(allocator: Allocator, unordered: UserValue) OrderedUserValue {
return switch (unordered) {
.flag => .{ .flag = {} },
.scalar => |scalar| .{ .scalar = scalar },
.list => |list| .{ .list = list },
.map => |map| .{ .map = OrderedUserValue.mapFromUnordered(allocator, map) },
.lazy_path => |lp| .{ .lazy_path = lp },
.lazy_path_list => |list| .{ .lazy_path_list = list },
};
}
};
standardTargetOptionsQueryOnly()
The path to the generated file. Must be either absolute or relative to the build runner cwd.
This value must be set in the fn make() of the step and must not be null afterwards.
const OrderedUserInputOption = struct {
name: []const u8,
value: OrderedUserValue,
used: bool,
addUserInputOption()
Deprecated, see getPath2.
fn hash(opt: OrderedUserInputOption, hasher: *std.hash.Wyhash) void {
hasher.update(opt.name);
opt.value.hash(hasher);
}
addUserInputFlag()
A reference to an existing or future path.
fn fromUnordered(allocator: Allocator, user_input_option: UserInputOption) OrderedUserInputOption {
return OrderedUserInputOption{
.name = user_input_option.name,
.used = user_input_option.used,
.value = OrderedUserValue.fromUnordered(allocator, user_input_option.value),
};
}
validateUserInputDidItFail()
A source file path relative to build root.
fn lessThan(_: void, lhs: OrderedUserInputOption, rhs: OrderedUserInputOption) bool {
return std.ascii.lessThanIgnoreCase(lhs.name, rhs.name);
}
};
installArtifact()
The number of parent directories to go up. 0 means the generated file itself. 1 means the directory of the generated file. 2 means the parent of that directory, and so on.
// The hash should be consistent with the same values given a different order.
// This function takes a user input map, orders it, then hashes the contents.
fn hashUserInputOptionsMap(allocator: Allocator, user_input_options: UserInputOptionsMap, hasher: *std.hash.Wyhash) void {
var ordered = ArrayList(OrderedUserInputOption).init(allocator);
var it = user_input_options.iterator();
while (it.next()) |entry|
ordered.append(OrderedUserInputOption.fromUnordered(allocator, entry.value_ptr.*)) catch @panic("OOM");
addInstallArtifact()
Applied after up.
std.mem.sortUnstable(OrderedUserInputOption, ordered.items, {}, OrderedUserInputOption.lessThan);
installFile()
An absolute path or a path relative to the current working directory of
the build runner process.
This is uncommon but used for system environment paths such as --zig-lib-dir which
ignore the file system path of build.zig and instead are relative to the directory from
which zig build was invoked.
Use of this tag indicates a dependency on the host system.
// juice it
for (ordered.items) |user_option|
user_option.hash(hasher);
findProgram()
Returns a lazy path referring to the directory containing this path. The dirname is not allowed to escape the logical root for underlying path. For example, if the path is relative to the build root, the dirname is not allowed to traverse outside of the build root. Similarly, if the path is a generated file inside zig-cache, the dirname is not allowed to traverse outside of zig-cache.
}
installBinFile()
Returns a string that can be shown to represent the file source.
Either returns the path, "generated", or "dependency".
fn determineAndApplyInstallPrefix(b: *Build) error{OutOfMemory}!void {
// Create an installation directory local to this package. This will be used when
// dependant packages require a standard prefix, such as include directories for C headers.
var hash = b.graph.cache.hash;
// Random bytes to make unique. Refresh this with new random bytes when
// implementation is modified in a non-backwards-compatible way.
hash.add(@as(u32, 0xd8cb0055));
hash.addBytes(b.dep_prefix);
installLibFile()
Adds dependencies this file source implies to the given step.
var wyhash = std.hash.Wyhash.init(0);
hashUserInputOptionsMap(b.allocator, b.user_input_options, &wyhash);
hash.add(wyhash.final());
addObjCopy()
Deprecated, see getPath3.
const digest = hash.final();
const install_prefix = try b.cache_root.join(b.allocator, &.{ "i", &digest });
b.resolveInstallPrefix(install_prefix, .{});
findProgram()
Deprecated, see getPath3.
}
addInstallBinFile()
Intended to be used during the make phase only.
asking_step is only used for debugging purposes; it's the step being
run that is asking for the path.
/// This function is intended to be called by lib/build_runner.zig, not a build.zig file.
pub fn resolveInstallPrefix(b: *Build, install_prefix: ?[]const u8, dir_list: DirList) void {
if (b.dest_dir) |dest_dir| {
b.install_prefix = install_prefix orelse "/usr";
b.install_path = b.pathJoin(&.{ dest_dir, b.install_prefix });
} else {
b.install_prefix = install_prefix orelse
(b.build_root.join(b.allocator, &.{"zig-out"}) catch @panic("unhandled error"));
b.install_path = b.install_prefix;
}
addInstallLibFile()
Copies the internal strings.
The b parameter is only used for its allocator. All *Build instances
share the same allocator.
var lib_list = [_][]const u8{ b.install_path, "lib" };
var exe_list = [_][]const u8{ b.install_path, "bin" };
var h_list = [_][]const u8{ b.install_path, "include" };
addInstallHeaderFile()
In this function the stderr mutex has already been locked.
if (dir_list.lib_dir) |dir| {
if (fs.path.isAbsolute(dir)) lib_list[0] = b.dest_dir orelse "";
lib_list[1] = dir;
}
addInstallFileWithDir()
A path relative to the prefix
if (dir_list.exe_dir) |dir| {
if (fs.path.isAbsolute(dir)) exe_list[0] = b.dest_dir orelse "";
exe_list[1] = dir;
}
addInstallDirectory()
Duplicates the install directory including the path if set to custom.
if (dir_list.include_dir) |dir| {
if (fs.path.isAbsolute(dir)) h_list[0] = b.dest_dir orelse "";
h_list[1] = dir;
}
addCheckFile()
This function is intended to be called in the configure phase only.
It returns an absolute directory path, which is potentially going to be a
source of API breakage in the future, so keep that in mind when using this
function.
b.lib_dir = b.pathJoin(&lib_list);
b.exe_dir = b.pathJoin(&exe_list);
b.h_dir = b.pathJoin(&h_list);
findProgram()
A pair of target query and fully resolved target. This type is generally required by build system API that need to be given a target. The query is kept because the Zig toolchain needs to know which parts of the target are "native". This can apply to the CPU, the OS, or even the ABI.
}
path()
Converts a target query into a fully resolved target that can be passed to various parts of the API.
/// Create a set of key-value pairs that can be converted into a Zig source
/// file and then inserted into a Zig compilation's module table for importing.
/// In other words, this provides a way to expose build.zig values to Zig
/// source code with `@import`.
/// Related: `Module.addOptions`.
pub fn addOptions(b: *Build) *Step.Options {
return Step.Options.create(b);
findProgram()
If left as null, then the default will depend on system_package_mode.
}
pathJoin()
pub const ExecutableOptions = struct {
name: []const u8,
root_module: *Module,
version: ?std.SemanticVersion = null,
linkage: ?std.builtin.LinkMode = null,
max_rss: usize = 0,
use_llvm: ?bool = null,
use_lld: ?bool = null,
zig_lib_dir: ?LazyPath = null,
/// Embed a `.manifest` file in the compilation if the object format supports it.
/// https://learn.microsoft.com/en-us/windows/win32/sbscs/manifest-files-reference
/// Manifest files must have the extension `.manifest`.
/// Can be set regardless of target. The `.manifest` file will be ignored
/// if the target object format does not support embedded manifests.
win32_manifest: ?LazyPath = null,
};
pathResolve()
pub fn addExecutable(b: *Build, options: ExecutableOptions) *Step.Compile {
return .create(b, .{
.name = options.name,
.root_module = options.root_module,
.version = options.version,
.kind = .exe,
.linkage = options.linkage,
.max_rss = options.max_rss,
.use_llvm = options.use_llvm,
.use_lld = options.use_lld,
.zig_lib_dir = options.zig_lib_dir,
.win32_manifest = options.win32_manifest,
});
findProgram()
}
findProgram()
pub const ObjectOptions = struct {
name: []const u8,
root_module: *Module,
max_rss: usize = 0,
use_llvm: ?bool = null,
use_lld: ?bool = null,
zig_lib_dir: ?LazyPath = null,
};
runAllowFail()
pub fn addObject(b: *Build, options: ObjectOptions) *Step.Compile {
return .create(b, .{
.name = options.name,
.root_module = options.root_module,
.kind = .obj,
.max_rss = options.max_rss,
.use_llvm = options.use_llvm,
.use_lld = options.use_lld,
.zig_lib_dir = options.zig_lib_dir,
});
}
run()
pub const LibraryOptions = struct {
linkage: std.builtin.LinkMode = .static,
name: []const u8,
root_module: *Module,
version: ?std.SemanticVersion = null,
max_rss: usize = 0,
use_llvm: ?bool = null,
use_lld: ?bool = null,
zig_lib_dir: ?LazyPath = null,
/// Embed a `.manifest` file in the compilation if the object format supports it.
/// https://learn.microsoft.com/en-us/windows/win32/sbscs/manifest-files-reference
/// Manifest files must have the extension `.manifest`.
/// Can be set regardless of target. The `.manifest` file will be ignored
/// if the target object format does not support embedded manifests.
win32_manifest: ?LazyPath = null,
};
addSearchPrefix()
pub fn addLibrary(b: *Build, options: LibraryOptions) *Step.Compile {
return .create(b, .{
.name = options.name,
.root_module = options.root_module,
.kind = .lib,
.linkage = options.linkage,
.version = options.version,
.max_rss = options.max_rss,
.use_llvm = options.use_llvm,
.use_lld = options.use_lld,
.zig_lib_dir = options.zig_lib_dir,
.win32_manifest = options.win32_manifest,
});
}
getInstallPath()
pub const TestOptions = struct {
name: []const u8 = "test",
root_module: *Module,
max_rss: usize = 0,
filters: []const []const u8 = &.{},
test_runner: ?Step.Compile.TestRunner = null,
use_llvm: ?bool = null,
use_lld: ?bool = null,
zig_lib_dir: ?LazyPath = null,
/// Emits an object file instead of a test binary.
/// The object must be linked separately.
/// Usually used in conjunction with a custom `test_runner`.
emit_object: bool = false,
};
Dependency
/// Creates an executable containing unit tests.
///
/// Equivalent to running the command `zig test --test-no-exec ...`.
///
/// **This step does not run the unit tests**. Typically, the result of this
/// function will be passed to `addRunArtifact`, creating a `Step.Run`. These
/// two steps are separated because they are independently configured and
/// cached.
pub fn addTest(b: *Build, options: TestOptions) *Step.Compile {
return .create(b, .{
.name = options.name,
.kind = if (options.emit_object) .test_obj else .@"test",
.root_module = options.root_module,
.max_rss = options.max_rss,
.filters = b.dupeStrings(options.filters),
.test_runner = options.test_runner,
.use_llvm = options.use_llvm,
.use_lld = options.use_lld,
.zig_lib_dir = options.zig_lib_dir,
});
}
artifact()
pub const AssemblyOptions = struct {
name: []const u8,
source_file: LazyPath,
/// To choose the same computer as the one building the package, pass the
/// `host` field of the package's `Build` instance.
target: ResolvedTarget,
optimize: std.builtin.OptimizeMode,
max_rss: usize = 0,
zig_lib_dir: ?LazyPath = null,
};
module()
/// This function creates a module and adds it to the package's module set, making
/// it available to other packages which depend on this one.
/// `createModule` can be used instead to create a private module.
pub fn addModule(b: *Build, name: []const u8, options: Module.CreateOptions) *Module {
const module = Module.create(b, options);
b.modules.put(b.dupe(name), module) catch @panic("OOM");
return module;
}
namedWriteFiles()
/// This function creates a private module, to be used by the current package,
/// but not exposed to other packages depending on this one.
/// `addModule` can be used instead to create a public module.
pub fn createModule(b: *Build, options: Module.CreateOptions) *Module {
return Module.create(b, options);
}
namedLazyPath()
/// Initializes a `Step.Run` 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 `Step.Compile.run`.
pub fn addSystemCommand(b: *Build, argv: []const []const u8) *Step.Run {
assert(argv.len >= 1);
const run_step = Step.Run.create(b, b.fmt("run {s}", .{argv[0]}));
run_step.addArgs(argv);
return run_step;
}
path()
/// Creates a `Step.Run` with an executable built with `addExecutable`.
/// Add command line arguments with methods of `Step.Run`.
pub fn addRunArtifact(b: *Build, exe: *Step.Compile) *Step.Run {
// 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.
lazyDependency()
// Avoid the common case of the step name looking like "run test test".
const step_name = if (exe.kind.isTest() and mem.eql(u8, exe.name, "test"))
b.fmt("run {s}", .{@tagName(exe.kind)})
else
b.fmt("run {s} {s}", .{ @tagName(exe.kind), exe.name });
dependency()
const run_step = Step.Run.create(b, step_name);
run_step.producer = exe;
if (exe.kind == .@"test") {
if (exe.exec_cmd_args) |exec_cmd_args| {
for (exec_cmd_args) |cmd_arg| {
if (cmd_arg) |arg| {
run_step.addArg(arg);
} else {
run_step.addArtifactArg(exe);
}
}
} else {
run_step.addArtifactArg(exe);
}
lazyImport()
const test_server_mode = if (exe.test_runner) |r| r.mode == .server else true;
if (test_server_mode) run_step.enableTestRunnerMode();
} else {
run_step.addArtifactArg(exe);
}
dependencyFromBuildZig()
return run_step;
}
runBuild()
/// 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: Step.ConfigHeader.Options,
values: anytype,
) *Step.ConfigHeader {
var options_copy = options;
if (options_copy.first_ret_addr == null)
options_copy.first_ret_addr = @returnAddress();
GeneratedFile
const config_header_step = Step.ConfigHeader.create(b, options_copy);
config_header_step.addValues(values);
return config_header_step;
}
getPath()
/// Allocator.dupe without the need to handle out of memory.
pub fn dupe(b: *Build, bytes: []const u8) []u8 {
return dupeInner(b.allocator, bytes);
}
getPath2()
pub fn dupeInner(allocator: std.mem.Allocator, bytes: []const u8) []u8 {
return allocator.dupe(u8, bytes) catch @panic("OOM");
}
Test: dirnameAllowEmpty
/// Duplicates an array of strings without the need to handle out of memory.
pub fn dupeStrings(b: *Build, strings: []const []const u8) [][]u8 {
const array = b.allocator.alloc([]u8, strings.len) catch @panic("OOM");
for (array, strings) |*dest, source| dest.* = b.dupe(source);
return array;
}
LazyPath
/// Duplicates a path and converts all slashes to the OS's canonical path separator.
pub fn dupePath(b: *Build, bytes: []const u8) []u8 {
return dupePathInner(b.allocator, bytes);
}
dirname()
fn dupePathInner(allocator: std.mem.Allocator, bytes: []const u8) []u8 {
const the_copy = dupeInner(allocator, bytes);
for (the_copy) |*byte| {
switch (byte.*) {
'/', '\\' => byte.* = fs.path.sep,
else => {},
}
}
return the_copy;
}
path()
pub fn addWriteFile(b: *Build, file_path: []const u8, data: []const u8) *Step.WriteFile {
const write_file_step = b.addWriteFiles();
_ = write_file_step.add(file_path, data);
return write_file_step;
}
join()
pub fn addNamedWriteFiles(b: *Build, name: []const u8) *Step.WriteFile {
const wf = Step.WriteFile.create(b);
b.named_writefiles.put(b.dupe(name), wf) catch @panic("OOM");
return wf;
}
getDisplayName()
pub fn addNamedLazyPath(b: *Build, name: []const u8, lp: LazyPath) void {
b.named_lazy_paths.put(b.dupe(name), lp.dupe(b)) catch @panic("OOM");
}
addStepDependencies()
pub fn addWriteFiles(b: *Build) *Step.WriteFile {
return Step.WriteFile.create(b);
}
getPath()
pub fn addUpdateSourceFiles(b: *Build) *Step.UpdateSourceFiles {
return Step.UpdateSourceFiles.create(b);
}
getPath2()
pub fn addRemoveDirTree(b: *Build, dir_path: LazyPath) *Step.RemoveDir {
return Step.RemoveDir.create(b, dir_path);
}
getPath3()
pub fn addFail(b: *Build, error_msg: []const u8) *Step.Fail {
return Step.Fail.create(b, error_msg);
}
basename()
pub fn addFmt(b: *Build, options: Step.Fmt.Options) *Step.Fmt {
return Step.Fmt.create(b, options);
}
dupe()
pub fn addTranslateC(b: *Build, options: Step.TranslateC.Options) *Step.TranslateC {
return Step.TranslateC.create(b, options);
}
dumpBadGetPathHelp()
pub fn getInstallStep(b: *Build) *Step {
return &b.install_tls.step;
}
InstallDir
pub fn getUninstallStep(b: *Build) *Step {
return &b.uninstall_tls.step;
}
dupe()
fn makeUninstall(uninstall_step: *Step, options: Step.MakeOptions) anyerror!void {
_ = options;
const uninstall_tls: *TopLevelStep = @fieldParentPtr("step", uninstall_step);
const b: *Build = @fieldParentPtr("uninstall_tls", uninstall_tls);
makeTempPath()
_ = b;
@panic("TODO implement https://github.com/ziglang/zig/issues/14943");
}
ResolvedTarget
/// Creates a configuration option to be passed to the build.zig script.
/// When a user directly runs `zig build`, they can set these options with `-D` arguments.
/// When a project depends on a Zig package as a dependency, it programmatically sets
/// these options when calling the dependency's build.zig script as a function.
/// `null` is returned when an option is left to default.
pub fn option(b: *Build, comptime T: type, name_raw: []const u8, description_raw: []const u8) ?T {
const name = b.dupe(name_raw);
const description = b.dupe(description_raw);
const type_id = comptime typeToEnum(T);
const enum_options = if (type_id == .@"enum" or type_id == .enum_list) blk: {
const EnumType = if (type_id == .enum_list) @typeInfo(T).pointer.child else T;
const fields = comptime std.meta.fields(EnumType);
var options = ArrayList([]const u8).initCapacity(b.allocator, fields.len) catch @panic("OOM");
resolveTargetQuery()
inline for (fields) |field| {
options.appendAssumeCapacity(field.name);
}
wantSharedLibSymLinks()
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 ((b.available_options_map.fetchPut(name, available_option) catch @panic("OOM")) != null) {
panic("Option '{s}' declared twice", .{name});
}
b.available_options_list.append(available_option) catch @panic("OOM");
SystemIntegrationOptionConfig
const option_ptr = b.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}'", .{ name, s });
b.markInvalidUserInput();
return null;
}
},
.list, .map, .lazy_path, .lazy_path_list => {
log.err("Expected -D{s} to be a boolean, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.markInvalidUserInput();
return null;
},
},
.int => switch (option_ptr.value) {
.flag, .list, .map, .lazy_path, .lazy_path_list => {
log.err("Expected -D{s} to be an integer, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.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}.", .{ name, s, @typeName(T) });
b.markInvalidUserInput();
return null;
},
else => {
log.err("Expected -D{s} to be an integer of type {s}.", .{ name, @typeName(T) });
b.markInvalidUserInput();
return null;
},
};
return n;
},
},
.float => switch (option_ptr.value) {
.flag, .map, .list, .lazy_path, .lazy_path_list => {
log.err("Expected -D{s} to be a float, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.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}.", .{ name, @typeName(T) });
b.markInvalidUserInput();
return null;
};
return n;
},
},
.@"enum" => switch (option_ptr.value) {
.flag, .map, .list, .lazy_path, .lazy_path_list => {
log.err("Expected -D{s} to be an enum, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.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}.", .{ name, @typeName(T) });
b.markInvalidUserInput();
return null;
}
},
},
.string => switch (option_ptr.value) {
.flag, .list, .map, .lazy_path, .lazy_path_list => {
log.err("Expected -D{s} to be a string, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.markInvalidUserInput();
return null;
},
.scalar => |s| return s,
},
.build_id => switch (option_ptr.value) {
.flag, .map, .list, .lazy_path, .lazy_path_list => {
log.err("Expected -D{s} to be an enum, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.markInvalidUserInput();
return null;
},
.scalar => |s| {
if (std.zig.BuildId.parse(s)) |build_id| {
return build_id;
} else |err| {
log.err("unable to parse option '-D{s}': {s}", .{ name, @errorName(err) });
b.markInvalidUserInput();
return null;
}
},
},
.list => switch (option_ptr.value) {
.flag, .map, .lazy_path, .lazy_path_list => {
log.err("Expected -D{s} to be a list, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.markInvalidUserInput();
return null;
},
.scalar => |s| {
return b.allocator.dupe([]const u8, &[_][]const u8{s}) catch @panic("OOM");
},
.list => |lst| return lst.items,
},
.enum_list => switch (option_ptr.value) {
.flag, .map, .lazy_path, .lazy_path_list => {
log.err("Expected -D{s} to be a list, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.markInvalidUserInput();
return null;
},
.scalar => |s| {
const Child = @typeInfo(T).pointer.child;
const value = std.meta.stringToEnum(Child, s) orelse {
log.err("Expected -D{s} to be of type {s}.", .{ name, @typeName(Child) });
b.markInvalidUserInput();
return null;
};
return b.allocator.dupe(Child, &[_]Child{value}) catch @panic("OOM");
},
.list => |lst| {
const Child = @typeInfo(T).pointer.child;
const new_list = b.allocator.alloc(Child, lst.items.len) catch @panic("OOM");
for (new_list, lst.items) |*new_item, str| {
new_item.* = std.meta.stringToEnum(Child, str) orelse {
log.err("Expected -D{s} to be of type {s}.", .{ name, @typeName(Child) });
b.markInvalidUserInput();
b.allocator.free(new_list);
return null;
};
}
return new_list;
},
},
.lazy_path => switch (option_ptr.value) {
.scalar => |s| return .{ .cwd_relative = s },
.lazy_path => |lp| return lp,
.flag, .map, .list, .lazy_path_list => {
log.err("Expected -D{s} to be a path, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.markInvalidUserInput();
return null;
},
},
.lazy_path_list => switch (option_ptr.value) {
.scalar => |s| return b.allocator.dupe(LazyPath, &[_]LazyPath{.{ .cwd_relative = s }}) catch @panic("OOM"),
.lazy_path => |lp| return b.allocator.dupe(LazyPath, &[_]LazyPath{lp}) catch @panic("OOM"),
.list => |lst| {
const new_list = b.allocator.alloc(LazyPath, lst.items.len) catch @panic("OOM");
for (new_list, lst.items) |*new_item, str| {
new_item.* = .{ .cwd_relative = str };
}
return new_list;
},
.lazy_path_list => |lp_list| return lp_list.items,
.flag, .map => {
log.err("Expected -D{s} to be a path, but received a {s}.", .{
name, @tagName(option_ptr.value),
});
b.markInvalidUserInput();
return null;
},
},
}
}
systemIntegrationOption()
pub fn step(b: *Build, name: []const u8, description: []const u8) *Step {
const step_info = b.allocator.create(TopLevelStep) catch @panic("OOM");
step_info.* = .{
.step = .init(.{
.id = TopLevelStep.base_id,
.name = name,
.owner = b,
}),
.description = b.dupe(description),
};
const gop = b.top_level_steps.getOrPut(b.allocator, name) catch @panic("OOM");
if (gop.found_existing) std.debug.panic("A top-level step with name \"{s}\" already exists", .{name});
gop.key_ptr.* = step_info.step.name;
gop.value_ptr.* = step_info;
return &step_info.step;
}
pub const StandardOptimizeOptionOptions = struct {
preferred_optimize_mode: ?std.builtin.OptimizeMode = null,
};
pub fn standardOptimizeOption(b: *Build, options: StandardOptimizeOptionOptions) std.builtin.OptimizeMode {
if (options.preferred_optimize_mode) |mode| {
if (b.option(bool, "release", "optimize for end users") orelse (b.release_mode != .off)) {
return mode;
} else {
return .Debug;
}
}
if (b.option(
std.builtin.OptimizeMode,
"optimize",
"Prioritize performance, safety, or binary size",
)) |mode| {
return mode;
}
return switch (b.release_mode) {
.off => .Debug,
.any => {
std.debug.print("the project does not declare a preferred optimization mode. choose: --release=fast, --release=safe, or --release=small\n", .{});
process.exit(1);
},
.fast => .ReleaseFast,
.safe => .ReleaseSafe,
.small => .ReleaseSmall,
};
}
pub const StandardTargetOptionsArgs = struct {
whitelist: ?[]const Target.Query = null,
default_target: Target.Query = .{},
};
/// Exposes standard `zig build` options for choosing a target and additionally
/// resolves the target query.
pub fn standardTargetOptions(b: *Build, args: StandardTargetOptionsArgs) ResolvedTarget {
const query = b.standardTargetOptionsQueryOnly(args);
return b.resolveTargetQuery(query);
}
/// Obtain a target query from a string, reporting diagnostics to stderr if the
/// parsing failed.
/// Asserts that the `diagnostics` field of `options` is `null`. This use case
/// is handled instead by calling `std.Target.Query.parse` directly.
pub fn parseTargetQuery(options: std.Target.Query.ParseOptions) error{ParseFailed}!std.Target.Query {
assert(options.diagnostics == null);
var diags: Target.Query.ParseOptions.Diagnostics = .{};
var opts_copy = options;
opts_copy.diagnostics = &diags;
return std.Target.Query.parse(opts_copy) catch |err| switch (err) {
error.UnknownCpuModel => {
std.debug.print("unknown CPU: '{s}'\navailable CPUs for architecture '{s}':\n", .{
diags.cpu_name.?, @tagName(diags.arch.?),
});
for (diags.arch.?.allCpuModels()) |cpu| {
std.debug.print(" {s}\n", .{cpu.name});
}
return error.ParseFailed;
},
error.UnknownCpuFeature => {
std.debug.print(
\\unknown CPU feature: '{s}'
\\available CPU features for architecture '{s}':
\\
, .{
diags.unknown_feature_name.?,
@tagName(diags.arch.?),
});
for (diags.arch.?.allFeaturesList()) |feature| {
std.debug.print(" {s}: {s}\n", .{ feature.name, feature.description });
}
return error.ParseFailed;
},
error.UnknownOperatingSystem => {
std.debug.print(
\\unknown OS: '{s}'
\\available operating systems:
\\
, .{diags.os_name.?});
inline for (std.meta.fields(Target.Os.Tag)) |field| {
std.debug.print(" {s}\n", .{field.name});
}
return error.ParseFailed;
},
else => |e| {
std.debug.print("unable to parse target '{s}': {s}\n", .{
options.arch_os_abi, @errorName(e),
});
return error.ParseFailed;
},
};
}
/// Exposes standard `zig build` options for choosing a target.
pub fn standardTargetOptionsQueryOnly(b: *Build, args: StandardTargetOptionsArgs) Target.Query {
const maybe_triple = b.option(
[]const u8,
"target",
"The CPU architecture, OS, and ABI to build for",
);
const mcpu = b.option(
[]const u8,
"cpu",
"Target CPU features to add or subtract",
);
const ofmt = b.option(
[]const u8,
"ofmt",
"Target object format",
);
const dynamic_linker = b.option(
[]const u8,
"dynamic-linker",
"Path to interpreter on the target system",
);
if (maybe_triple == null and mcpu == null and ofmt == null and dynamic_linker == null)
return args.default_target;
const triple = maybe_triple orelse "native";
const selected_target = parseTargetQuery(.{
.arch_os_abi = triple,
.cpu_features = mcpu,
.object_format = ofmt,
.dynamic_linker = dynamic_linker,
}) catch |err| switch (err) {
error.ParseFailed => {
b.markInvalidUserInput();
return args.default_target;
},
};
const whitelist = args.whitelist orelse return selected_target;
// Make sure it's a match of one of the list.
for (whitelist) |q| {
if (q.eql(selected_target))
return selected_target;
}
for (whitelist) |q| {
log.info("allowed target: -Dtarget={s} -Dcpu={s}", .{
q.zigTriple(b.allocator) catch @panic("OOM"),
q.serializeCpuAlloc(b.allocator) catch @panic("OOM"),
});
}
log.err("chosen target '{s}' does not match one of the allowed targets", .{
selected_target.zigTriple(b.allocator) catch @panic("OOM"),
});
b.markInvalidUserInput();
return args.default_target;
}
pub fn addUserInputOption(b: *Build, name_raw: []const u8, value_raw: []const u8) error{OutOfMemory}!bool {
const name = b.dupe(name_raw);
const value = b.dupe(value_raw);
const gop = try b.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(b.allocator);
try list.append(s);
try list.append(value);
try b.user_input_options.put(name, .{
.name = name,
.value = .{ .list = list },
.used = false,
});
},
.list => |*list| {
// append to the list
try list.append(value);
try b.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;
},
.lazy_path, .lazy_path_list => {
log.warn("the lazy path value type isn't added from the CLI, but somehow '{s}' is a .{f}", .{ name, std.zig.fmtId(@tagName(gop.value_ptr.value)) });
return true;
},
}
return false;
}
pub fn addUserInputFlag(b: *Build, name_raw: []const u8) error{OutOfMemory}!bool {
const name = b.dupe(name_raw);
const gop = try b.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, .lazy_path_list => {
log.err("Flag '-D{s}' conflicts with multiple options of the same name.", .{name});
return true;
},
.lazy_path => |lp| {
log.err("Flag '-D{s}' conflicts with option '-D{s}={s}'.", .{ name, name, lp.getDisplayName() });
return true;
},
.flag => {},
}
return false;
}
fn typeToEnum(comptime T: type) TypeId {
return switch (T) {
std.zig.BuildId => .build_id,
LazyPath => .lazy_path,
else => return switch (@typeInfo(T)) {
.int => .int,
.float => .float,
.bool => .bool,
.@"enum" => .@"enum",
.pointer => |pointer| switch (pointer.child) {
u8 => .string,
[]const u8 => .list,
LazyPath => .lazy_path_list,
else => switch (@typeInfo(pointer.child)) {
.@"enum" => .enum_list,
else => @compileError("Unsupported type: " ++ @typeName(T)),
},
},
else => @compileError("Unsupported type: " ++ @typeName(T)),
},
};
}
fn markInvalidUserInput(b: *Build) void {
b.invalid_user_input = true;
}
pub fn validateUserInputDidItFail(b: *Build) bool {
// Make sure all args are used.
var it = b.user_input_options.iterator();
while (it.next()) |entry| {
if (!entry.value_ptr.used) {
log.err("invalid option: -D{s}", .{entry.key_ptr.*});
b.markInvalidUserInput();
}
}
return b.invalid_user_input;
}
fn allocPrintCmd(gpa: Allocator, opt_cwd: ?[]const u8, argv: []const []const u8) error{OutOfMemory}![]u8 {
var buf: std.ArrayListUnmanaged(u8) = .empty;
if (opt_cwd) |cwd| try buf.print(gpa, "cd {s} && ", .{cwd});
for (argv) |arg| {
try buf.print(gpa, "{s} ", .{arg});
}
return buf.toOwnedSlice(gpa);
}
fn printCmd(ally: Allocator, cwd: ?[]const u8, argv: []const []const u8) void {
const text = allocPrintCmd(ally, cwd, argv) catch @panic("OOM");
std.debug.print("{s}\n", .{text});
}
/// This creates the install step and adds it to the dependencies of the
/// top-level install step, using all the default options.
/// See `addInstallArtifact` for a more flexible function.
pub fn installArtifact(b: *Build, artifact: *Step.Compile) void {
b.getInstallStep().dependOn(&b.addInstallArtifact(artifact, .{}).step);
}
/// This merely creates the step; it does not add it to the dependencies of the
/// top-level install step.
pub fn addInstallArtifact(
b: *Build,
artifact: *Step.Compile,
options: Step.InstallArtifact.Options,
) *Step.InstallArtifact {
return Step.InstallArtifact.create(b, artifact, options);
}
///`dest_rel_path` is relative to prefix path
pub fn installFile(b: *Build, src_path: []const u8, dest_rel_path: []const u8) void {
b.getInstallStep().dependOn(&b.addInstallFileWithDir(b.path(src_path), .prefix, dest_rel_path).step);
}
pub fn installDirectory(b: *Build, options: Step.InstallDir.Options) void {
b.getInstallStep().dependOn(&b.addInstallDirectory(options).step);
}
///`dest_rel_path` is relative to bin path
pub fn installBinFile(b: *Build, src_path: []const u8, dest_rel_path: []const u8) void {
b.getInstallStep().dependOn(&b.addInstallFileWithDir(b.path(src_path), .bin, dest_rel_path).step);
}
///`dest_rel_path` is relative to lib path
pub fn installLibFile(b: *Build, src_path: []const u8, dest_rel_path: []const u8) void {
b.getInstallStep().dependOn(&b.addInstallFileWithDir(b.path(src_path), .lib, dest_rel_path).step);
}
pub fn addObjCopy(b: *Build, source: LazyPath, options: Step.ObjCopy.Options) *Step.ObjCopy {
return Step.ObjCopy.create(b, source, options);
}
/// `dest_rel_path` is relative to install prefix path
pub fn addInstallFile(b: *Build, source: LazyPath, dest_rel_path: []const u8) *Step.InstallFile {
return b.addInstallFileWithDir(source, .prefix, dest_rel_path);
}
/// `dest_rel_path` is relative to bin path
pub fn addInstallBinFile(b: *Build, source: LazyPath, dest_rel_path: []const u8) *Step.InstallFile {
return b.addInstallFileWithDir(source, .bin, dest_rel_path);
}
/// `dest_rel_path` is relative to lib path
pub fn addInstallLibFile(b: *Build, source: LazyPath, dest_rel_path: []const u8) *Step.InstallFile {
return b.addInstallFileWithDir(source, .lib, dest_rel_path);
}
/// `dest_rel_path` is relative to header path
pub fn addInstallHeaderFile(b: *Build, source: LazyPath, dest_rel_path: []const u8) *Step.InstallFile {
return b.addInstallFileWithDir(source, .header, dest_rel_path);
}
pub fn addInstallFileWithDir(
b: *Build,
source: LazyPath,
install_dir: InstallDir,
dest_rel_path: []const u8,
) *Step.InstallFile {
return Step.InstallFile.create(b, source, install_dir, dest_rel_path);
}
pub fn addInstallDirectory(b: *Build, options: Step.InstallDir.Options) *Step.InstallDir {
return Step.InstallDir.create(b, options);
}
pub fn addCheckFile(
b: *Build,
file_source: LazyPath,
options: Step.CheckFile.Options,
) *Step.CheckFile {
return Step.CheckFile.create(b, file_source, options);
}
pub fn truncateFile(b: *Build, dest_path: []const u8) (fs.Dir.MakeError || fs.Dir.StatFileError)!void {
if (b.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();
}
/// References a file or directory relative to the source root.
pub fn path(b: *Build, sub_path: []const u8) LazyPath {
if (fs.path.isAbsolute(sub_path)) {
std.debug.panic("sub_path is expected to be relative to the build root, but was this absolute path: '{s}'. It is best avoid absolute paths, but if you must, it is supported by LazyPath.cwd_relative", .{
sub_path,
});
}
return .{ .src_path = .{
.owner = b,
.sub_path = sub_path,
} };
}
/// This is low-level implementation details of the build system, not meant to
/// be called by users' build scripts. Even in the build system itself it is a
/// code smell to call this function.
pub fn pathFromRoot(b: *Build, sub_path: []const u8) []u8 {
return b.pathResolve(&.{ b.build_root.path orelse ".", sub_path });
}
fn pathFromCwd(b: *Build, sub_path: []const u8) []u8 {
const cwd = process.getCwdAlloc(b.allocator) catch @panic("OOM");
return b.pathResolve(&.{ cwd, sub_path });
}
pub fn pathJoin(b: *Build, paths: []const []const u8) []u8 {
return fs.path.join(b.allocator, paths) catch @panic("OOM");
}
pub fn pathResolve(b: *Build, paths: []const []const u8) []u8 {
return fs.path.resolve(b.allocator, paths) catch @panic("OOM");
}
pub fn fmt(b: *Build, comptime format: []const u8, args: anytype) []u8 {
return std.fmt.allocPrint(b.allocator, format, args) catch @panic("OOM");
}
fn supportedWindowsProgramExtension(ext: []const u8) bool {
inline for (@typeInfo(std.process.Child.WindowsExtension).@"enum".fields) |field| {
if (std.ascii.eqlIgnoreCase(ext, "." ++ field.name)) return true;
}
return false;
}
fn tryFindProgram(b: *Build, full_path: []const u8) ?[]const u8 {
if (fs.realpathAlloc(b.allocator, full_path)) |p| {
return p;
} else |err| switch (err) {
error.OutOfMemory => @panic("OOM"),
else => {},
}
if (builtin.os.tag == .windows) {
if (b.graph.env_map.get("PATHEXT")) |PATHEXT| {
var it = mem.tokenizeScalar(u8, PATHEXT, fs.path.delimiter);
while (it.next()) |ext| {
if (!supportedWindowsProgramExtension(ext)) continue;
return fs.realpathAlloc(b.allocator, b.fmt("{s}{s}", .{ full_path, ext })) catch |err| switch (err) {
error.OutOfMemory => @panic("OOM"),
else => continue,
};
}
}
}
return null;
}
pub fn findProgram(b: *Build, names: []const []const u8, paths: []const []const u8) error{FileNotFound}![]const u8 {
// TODO report error for ambiguous situations
for (b.search_prefixes.items) |search_prefix| {
for (names) |name| {
if (fs.path.isAbsolute(name)) {
return name;
}
return tryFindProgram(b, b.pathJoin(&.{ search_prefix, "bin", name })) orelse continue;
}
}
if (b.graph.env_map.get("PATH")) |PATH| {
for (names) |name| {
if (fs.path.isAbsolute(name)) {
return name;
}
var it = mem.tokenizeScalar(u8, PATH, fs.path.delimiter);
while (it.next()) |p| {
return tryFindProgram(b, b.pathJoin(&.{ p, name })) orelse continue;
}
}
}
for (names) |name| {
if (fs.path.isAbsolute(name)) {
return name;
}
for (paths) |p| {
return tryFindProgram(b, b.pathJoin(&.{ p, name })) orelse continue;
}
}
return error.FileNotFound;
}
pub fn runAllowFail(
b: *Build,
argv: []const []const u8,
out_code: *u8,
stderr_behavior: std.process.Child.StdIo,
) RunError![]u8 {
assert(argv.len != 0);
if (!process.can_spawn)
return error.ExecNotSupported;
const max_output_size = 400 * 1024;
var child = std.process.Child.init(argv, b.allocator);
child.stdin_behavior = .Ignore;
child.stdout_behavior = .Pipe;
child.stderr_behavior = stderr_behavior;
child.env_map = &b.graph.env_map;
try Step.handleVerbose2(b, null, child.env_map, argv);
try child.spawn();
const stdout = child.stdout.?.deprecatedReader().readAllAlloc(b.allocator, max_output_size) catch {
return error.ReadFailure;
};
errdefer b.allocator.free(stdout);
const term = try child.wait();
switch (term) {
.Exited => |code| {
if (code != 0) {
out_code.* = @as(u8, @truncate(code));
return error.ExitCodeFailure;
}
return stdout;
},
.Signal, .Stopped, .Unknown => |code| {
out_code.* = @as(u8, @truncate(code));
return error.ProcessTerminated;
},
}
}
/// This is a helper function to be called from build.zig scripts, *not* from
/// inside step make() functions. If any errors occur, it fails the build with
/// a helpful message.
pub fn run(b: *Build, argv: []const []const u8) []u8 {
if (!process.can_spawn) {
std.debug.print("unable to spawn the following command: cannot spawn child process\n{s}\n", .{
try allocPrintCmd(b.allocator, null, argv),
});
process.exit(1);
}
var code: u8 = undefined;
return b.runAllowFail(argv, &code, .Inherit) catch |err| {
const printed_cmd = allocPrintCmd(b.allocator, null, argv) catch @panic("OOM");
std.debug.print("unable to spawn the following command: {s}\n{s}\n", .{
@errorName(err), printed_cmd,
});
process.exit(1);
};
}
pub fn addSearchPrefix(b: *Build, search_prefix: []const u8) void {
b.search_prefixes.append(b.allocator, b.dupePath(search_prefix)) catch @panic("OOM");
}
pub fn getInstallPath(b: *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 => b.install_path,
.bin => b.exe_dir,
.lib => b.lib_dir,
.header => b.h_dir,
.custom => |p| b.pathJoin(&.{ b.install_path, p }),
};
return b.pathResolve(&.{ base_dir, dest_rel_path });
}
pub const Dependency = struct {
builder: *Build,
pub fn artifact(d: *Dependency, name: []const u8) *Step.Compile {
var found: ?*Step.Compile = null;
for (d.builder.install_tls.step.dependencies.items) |dep_step| {
const inst = dep_step.cast(Step.InstallArtifact) 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(Step.InstallArtifact) 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 namedWriteFiles(d: *Dependency, name: []const u8) *Step.WriteFile {
return d.builder.named_writefiles.get(name) orelse {
panic("unable to find named writefiles '{s}'", .{name});
};
}
pub fn namedLazyPath(d: *Dependency, name: []const u8) LazyPath {
return d.builder.named_lazy_paths.get(name) orelse {
panic("unable to find named lazypath '{s}'", .{name});
};
}
pub fn path(d: *Dependency, sub_path: []const u8) LazyPath {
return .{
.dependency = .{
.dependency = d,
.sub_path = sub_path,
},
};
}
};
fn findPkgHashOrFatal(b: *Build, name: []const u8) []const u8 {
for (b.available_deps) |dep| {
if (mem.eql(u8, dep[0], name)) return dep[1];
}
const full_path = b.pathFromRoot("build.zig.zon");
std.debug.panic("no dependency named '{s}' in '{s}'. All packages used in build.zig must be declared in this file", .{ name, full_path });
}
inline fn findImportPkgHashOrFatal(b: *Build, comptime asking_build_zig: type, comptime dep_name: []const u8) []const u8 {
const build_runner = @import("root");
const deps = build_runner.dependencies;
const b_pkg_hash, const b_pkg_deps = comptime for (@typeInfo(deps.packages).@"struct".decls) |decl| {
const pkg_hash = decl.name;
const pkg = @field(deps.packages, pkg_hash);
if (@hasDecl(pkg, "build_zig") and pkg.build_zig == asking_build_zig) break .{ pkg_hash, pkg.deps };
} else .{ "", deps.root_deps };
if (!std.mem.eql(u8, b_pkg_hash, b.pkg_hash)) {
std.debug.panic("'{}' is not the struct that corresponds to '{s}'", .{ asking_build_zig, b.pathFromRoot("build.zig") });
}
comptime for (b_pkg_deps) |dep| {
if (std.mem.eql(u8, dep[0], dep_name)) return dep[1];
};
const full_path = b.pathFromRoot("build.zig.zon");
std.debug.panic("no dependency named '{s}' in '{s}'. All packages used in build.zig must be declared in this file", .{ dep_name, full_path });
}
fn markNeededLazyDep(b: *Build, pkg_hash: []const u8) void {
b.graph.needed_lazy_dependencies.put(b.graph.arena, pkg_hash, {}) catch @panic("OOM");
}
/// When this function is called, it means that the current build does, in
/// fact, require this dependency. If the dependency is already fetched, it
/// proceeds in the same manner as `dependency`. However if the dependency was
/// not fetched, then when the build script is finished running, the build will
/// not proceed to the make phase. Instead, the parent process will
/// additionally fetch all the lazy dependencies that were actually required by
/// running the build script, rebuild the build script, and then run it again.
/// In other words, if this function returns `null` it means that the only
/// purpose of completing the configure phase is to find out all the other lazy
/// dependencies that are also required.
/// It is allowed to use this function for non-lazy dependencies, in which case
/// it will never return `null`. This allows toggling laziness via
/// build.zig.zon without changing build.zig logic.
pub fn lazyDependency(b: *Build, name: []const u8, args: anytype) ?*Dependency {
const build_runner = @import("root");
const deps = build_runner.dependencies;
const pkg_hash = findPkgHashOrFatal(b, name);
inline for (@typeInfo(deps.packages).@"struct".decls) |decl| {
if (mem.eql(u8, decl.name, pkg_hash)) {
const pkg = @field(deps.packages, decl.name);
const available = !@hasDecl(pkg, "available") or pkg.available;
if (!available) {
markNeededLazyDep(b, pkg_hash);
return null;
}
return dependencyInner(b, name, pkg.build_root, if (@hasDecl(pkg, "build_zig")) pkg.build_zig else null, pkg_hash, pkg.deps, args);
}
}
unreachable; // Bad @dependencies source
}
pub fn dependency(b: *Build, name: []const u8, args: anytype) *Dependency {
const build_runner = @import("root");
const deps = build_runner.dependencies;
const pkg_hash = findPkgHashOrFatal(b, name);
inline for (@typeInfo(deps.packages).@"struct".decls) |decl| {
if (mem.eql(u8, decl.name, pkg_hash)) {
const pkg = @field(deps.packages, decl.name);
if (@hasDecl(pkg, "available")) {
std.debug.panic("dependency '{s}{s}' is marked as lazy in build.zig.zon which means it must use the lazyDependency function instead", .{ b.dep_prefix, name });
}
return dependencyInner(b, name, pkg.build_root, if (@hasDecl(pkg, "build_zig")) pkg.build_zig else null, pkg_hash, pkg.deps, args);
}
}
unreachable; // Bad @dependencies source
}
/// In a build.zig file, this function is to `@import` what `lazyDependency` is to `dependency`.
/// If the dependency is lazy and has not yet been fetched, it instructs the parent process to fetch
/// that dependency after the build script has finished running, then returns `null`.
/// If the dependency is lazy but has already been fetched, or if it is eager, it returns
/// the build.zig struct of that dependency, just like a regular `@import`.
pub inline fn lazyImport(
b: *Build,
/// The build.zig struct of the package importing the dependency.
/// When calling this function from the `build` function of a build.zig file's, you normally
/// pass `@This()`.
comptime asking_build_zig: type,
comptime dep_name: []const u8,
) ?type {
const build_runner = @import("root");
const deps = build_runner.dependencies;
const pkg_hash = findImportPkgHashOrFatal(b, asking_build_zig, dep_name);
inline for (@typeInfo(deps.packages).@"struct".decls) |decl| {
if (comptime mem.eql(u8, decl.name, pkg_hash)) {
const pkg = @field(deps.packages, decl.name);
const available = !@hasDecl(pkg, "available") or pkg.available;
if (!available) {
markNeededLazyDep(b, pkg_hash);
return null;
}
return if (@hasDecl(pkg, "build_zig"))
pkg.build_zig
else
@compileError("dependency '" ++ dep_name ++ "' does not have a build.zig");
}
}
comptime unreachable; // Bad @dependencies source
}
pub fn dependencyFromBuildZig(
b: *Build,
/// The build.zig struct of the dependency, normally obtained by `@import` of the dependency.
/// If called from the build.zig file itself, use `@This` to obtain a reference to the struct.
comptime build_zig: type,
args: anytype,
) *Dependency {
const build_runner = @import("root");
const deps = build_runner.dependencies;
find_dep: {
const pkg, const pkg_hash = inline for (@typeInfo(deps.packages).@"struct".decls) |decl| {
const pkg_hash = decl.name;
const pkg = @field(deps.packages, pkg_hash);
if (@hasDecl(pkg, "build_zig") and pkg.build_zig == build_zig) break .{ pkg, pkg_hash };
} else break :find_dep;
const dep_name = for (b.available_deps) |dep| {
if (mem.eql(u8, dep[1], pkg_hash)) break dep[1];
} else break :find_dep;
return dependencyInner(b, dep_name, pkg.build_root, pkg.build_zig, pkg_hash, pkg.deps, args);
}
const full_path = b.pathFromRoot("build.zig.zon");
debug.panic("'{}' is not a build.zig struct of a dependency in '{s}'", .{ build_zig, full_path });
}
fn userValuesAreSame(lhs: UserValue, rhs: UserValue) bool {
if (std.meta.activeTag(lhs) != rhs) return false;
switch (lhs) {
.flag => {},
.scalar => |lhs_scalar| {
const rhs_scalar = rhs.scalar;
if (!std.mem.eql(u8, lhs_scalar, rhs_scalar))
return false;
},
.list => |lhs_list| {
const rhs_list = rhs.list;
if (lhs_list.items.len != rhs_list.items.len)
return false;
for (lhs_list.items, rhs_list.items) |lhs_list_entry, rhs_list_entry| {
if (!std.mem.eql(u8, lhs_list_entry, rhs_list_entry))
return false;
}
},
.map => |lhs_map| {
const rhs_map = rhs.map;
if (lhs_map.count() != rhs_map.count())
return false;
var lhs_it = lhs_map.iterator();
while (lhs_it.next()) |lhs_entry| {
const rhs_value = rhs_map.get(lhs_entry.key_ptr.*) orelse return false;
if (!userValuesAreSame(lhs_entry.value_ptr.*.*, rhs_value.*))
return false;
}
},
.lazy_path => |lhs_lp| {
const rhs_lp = rhs.lazy_path;
return userLazyPathsAreTheSame(lhs_lp, rhs_lp);
},
.lazy_path_list => |lhs_lp_list| {
const rhs_lp_list = rhs.lazy_path_list;
if (lhs_lp_list.items.len != rhs_lp_list.items.len) return false;
for (lhs_lp_list.items, rhs_lp_list.items) |lhs_lp, rhs_lp| {
if (!userLazyPathsAreTheSame(lhs_lp, rhs_lp)) return false;
}
return true;
},
}
return true;
}
fn userLazyPathsAreTheSame(lhs_lp: LazyPath, rhs_lp: LazyPath) bool {
if (std.meta.activeTag(lhs_lp) != rhs_lp) return false;
switch (lhs_lp) {
.src_path => |lhs_sp| {
const rhs_sp = rhs_lp.src_path;
if (lhs_sp.owner != rhs_sp.owner) return false;
if (std.mem.eql(u8, lhs_sp.sub_path, rhs_sp.sub_path)) return false;
},
.generated => |lhs_gen| {
const rhs_gen = rhs_lp.generated;
if (lhs_gen.file != rhs_gen.file) return false;
if (lhs_gen.up != rhs_gen.up) return false;
if (std.mem.eql(u8, lhs_gen.sub_path, rhs_gen.sub_path)) return false;
},
.cwd_relative => |lhs_rel_path| {
const rhs_rel_path = rhs_lp.cwd_relative;
if (!std.mem.eql(u8, lhs_rel_path, rhs_rel_path)) return false;
},
.dependency => |lhs_dep| {
const rhs_dep = rhs_lp.dependency;
if (lhs_dep.dependency != rhs_dep.dependency) return false;
if (!std.mem.eql(u8, lhs_dep.sub_path, rhs_dep.sub_path)) return false;
},
}
return true;
}
fn dependencyInner(
b: *Build,
name: []const u8,
build_root_string: []const u8,
comptime build_zig: ?type,
pkg_hash: []const u8,
pkg_deps: AvailableDeps,
args: anytype,
) *Dependency {
const user_input_options = userInputOptionsFromArgs(b.allocator, args);
if (b.graph.dependency_cache.getContext(.{
.build_root_string = build_root_string,
.user_input_options = user_input_options,
}, .{ .allocator = b.graph.arena })) |dep|
return dep;
const build_root: std.Build.Cache.Directory = .{
.path = build_root_string,
.handle = fs.cwd().openDir(build_root_string, .{}) catch |err| {
std.debug.print("unable to open '{s}': {s}\n", .{
build_root_string, @errorName(err),
});
process.exit(1);
},
};
const sub_builder = b.createChild(name, build_root, pkg_hash, pkg_deps, user_input_options) catch @panic("unhandled error");
if (build_zig) |bz| {
sub_builder.runBuild(bz) 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 };
b.graph.dependency_cache.putContext(b.graph.arena, .{
.build_root_string = build_root_string,
.user_input_options = user_input_options,
}, dep, .{ .allocator = b.graph.arena }) catch @panic("OOM");
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),
.error_union => try build_zig.build(b),
else => @compileError("expected return type of build to be 'void' or '!void'"),
}
}
/// 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 runner cwd.
/// This value must be set in the `fn make()` of the `step` and must not be `null` afterwards.
path: ?[]const u8 = null,
/// Deprecated, see `getPath2`.
pub fn getPath(gen: GeneratedFile) []const u8 {
return gen.step.owner.pathFromCwd(gen.path orelse std.debug.panic(
"getPath() was called on a GeneratedFile that wasn't built yet. Is there a missing Step dependency on step '{s}'?",
.{gen.step.name},
));
}
pub fn getPath2(gen: GeneratedFile, src_builder: *Build, asking_step: ?*Step) []const u8 {
return gen.path orelse {
const w = debug.lockStderrWriter(&.{});
dumpBadGetPathHelp(gen.step, w, .detect(.stderr()), src_builder, asking_step) catch {};
debug.unlockStderrWriter();
@panic("misconfigured build script");
};
}
};
// dirnameAllowEmpty is a variant of fs.path.dirname
// that allows "" to refer to the root for relative paths.
//
// For context, dirname("foo") and dirname("") are both null.
// However, for relative paths, we want dirname("foo") to be ""
// so that we can join it with another path (e.g. build root, cache root, etc.)
//
// dirname("") should still be null, because we can't go up any further.
fn dirnameAllowEmpty(full_path: []const u8) ?[]const u8 {
return fs.path.dirname(full_path) orelse {
if (fs.path.isAbsolute(full_path) or full_path.len == 0) return null;
return "";
};
}
test dirnameAllowEmpty {
try std.testing.expectEqualStrings(
"foo",
dirnameAllowEmpty("foo" ++ fs.path.sep_str ++ "bar") orelse @panic("unexpected null"),
);
try std.testing.expectEqualStrings(
"",
dirnameAllowEmpty("foo") orelse @panic("unexpected null"),
);
try std.testing.expect(dirnameAllowEmpty("") == null);
}
/// A reference to an existing or future path.
pub const LazyPath = union(enum) {
/// A source file path relative to build root.
src_path: struct {
owner: *std.Build,
sub_path: []const u8,
},
generated: struct {
file: *const GeneratedFile,
/// The number of parent directories to go up.
/// 0 means the generated file itself.
/// 1 means the directory of the generated file.
/// 2 means the parent of that directory, and so on.
up: usize = 0,
/// Applied after `up`.
sub_path: []const u8 = "",
},
/// An absolute path or a path relative to the current working directory of
/// the build runner process.
/// This is uncommon but used for system environment paths such as `--zig-lib-dir` which
/// ignore the file system path of build.zig and instead are relative to the directory from
/// which `zig build` was invoked.
/// Use of this tag indicates a dependency on the host system.
cwd_relative: []const u8,
dependency: struct {
dependency: *Dependency,
sub_path: []const u8,
},
/// Returns a lazy path referring to the directory containing this path.
///
/// The dirname is not allowed to escape the logical root for underlying path.
/// For example, if the path is relative to the build root,
/// the dirname is not allowed to traverse outside of the build root.
/// Similarly, if the path is a generated file inside zig-cache,
/// the dirname is not allowed to traverse outside of zig-cache.
pub fn dirname(lazy_path: LazyPath) LazyPath {
return switch (lazy_path) {
.src_path => |sp| .{ .src_path = .{
.owner = sp.owner,
.sub_path = dirnameAllowEmpty(sp.sub_path) orelse {
dumpBadDirnameHelp(null, null, "dirname() attempted to traverse outside the build root\n", .{}) catch {};
@panic("misconfigured build script");
},
} },
.generated => |generated| .{ .generated = if (dirnameAllowEmpty(generated.sub_path)) |sub_dirname| .{
.file = generated.file,
.up = generated.up,
.sub_path = sub_dirname,
} else .{
.file = generated.file,
.up = generated.up + 1,
.sub_path = "",
} },
.cwd_relative => |rel_path| .{
.cwd_relative = dirnameAllowEmpty(rel_path) orelse {
// If we get null, it means one of two things:
// - rel_path was absolute, and is now root
// - rel_path was relative, and is now ""
// In either case, the build script tried to go too far
// and we should panic.
if (fs.path.isAbsolute(rel_path)) {
dumpBadDirnameHelp(null, null,
\\dirname() attempted to traverse outside the root.
\\No more directories left to go up.
\\
, .{}) catch {};
@panic("misconfigured build script");
} else {
dumpBadDirnameHelp(null, null,
\\dirname() attempted to traverse outside the current working directory.
\\
, .{}) catch {};
@panic("misconfigured build script");
}
},
},
.dependency => |dep| .{ .dependency = .{
.dependency = dep.dependency,
.sub_path = dirnameAllowEmpty(dep.sub_path) orelse {
dumpBadDirnameHelp(null, null,
\\dirname() attempted to traverse outside the dependency root.
\\
, .{}) catch {};
@panic("misconfigured build script");
},
} },
};
}
pub fn path(lazy_path: LazyPath, b: *Build, sub_path: []const u8) LazyPath {
return lazy_path.join(b.allocator, sub_path) catch @panic("OOM");
}
pub fn join(lazy_path: LazyPath, arena: Allocator, sub_path: []const u8) Allocator.Error!LazyPath {
return switch (lazy_path) {
.src_path => |src| .{ .src_path = .{
.owner = src.owner,
.sub_path = try fs.path.resolve(arena, &.{ src.sub_path, sub_path }),
} },
.generated => |gen| .{ .generated = .{
.file = gen.file,
.up = gen.up,
.sub_path = try fs.path.resolve(arena, &.{ gen.sub_path, sub_path }),
} },
.cwd_relative => |cwd_relative| .{
.cwd_relative = try fs.path.resolve(arena, &.{ cwd_relative, sub_path }),
},
.dependency => |dep| .{ .dependency = .{
.dependency = dep.dependency,
.sub_path = try fs.path.resolve(arena, &.{ dep.sub_path, sub_path }),
} },
};
}
/// Returns a string that can be shown to represent the file source.
/// Either returns the path, `"generated"`, or `"dependency"`.
pub fn getDisplayName(lazy_path: LazyPath) []const u8 {
return switch (lazy_path) {
.src_path => |sp| sp.sub_path,
.cwd_relative => |p| p,
.generated => "generated",
.dependency => "dependency",
};
}
/// Adds dependencies this file source implies to the given step.
pub fn addStepDependencies(lazy_path: LazyPath, other_step: *Step) void {
switch (lazy_path) {
.src_path, .cwd_relative, .dependency => {},
.generated => |gen| other_step.dependOn(gen.file.step),
}
}
/// Deprecated, see `getPath3`.
pub fn getPath(lazy_path: LazyPath, src_builder: *Build) []const u8 {
return getPath2(lazy_path, src_builder, null);
}
/// Deprecated, see `getPath3`.
pub fn getPath2(lazy_path: LazyPath, src_builder: *Build, asking_step: ?*Step) []const u8 {
const p = getPath3(lazy_path, src_builder, asking_step);
return src_builder.pathResolve(&.{ p.root_dir.path orelse ".", p.sub_path });
}
/// Intended to be used during the make phase only.
///
/// `asking_step` is only used for debugging purposes; it's the step being
/// run that is asking for the path.
pub fn getPath3(lazy_path: LazyPath, src_builder: *Build, asking_step: ?*Step) Cache.Path {
switch (lazy_path) {
.src_path => |sp| return .{
.root_dir = sp.owner.build_root,
.sub_path = sp.sub_path,
},
.cwd_relative => |sub_path| return .{
.root_dir = Cache.Directory.cwd(),
.sub_path = sub_path,
},
.generated => |gen| {
// TODO make gen.file.path not be absolute and use that as the
// basis for not traversing up too many directories.
var file_path: Cache.Path = .{
.root_dir = Cache.Directory.cwd(),
.sub_path = gen.file.path orelse {
const w = debug.lockStderrWriter(&.{});
dumpBadGetPathHelp(gen.file.step, w, .detect(.stderr()), src_builder, asking_step) catch {};
debug.unlockStderrWriter();
@panic("misconfigured build script");
},
};
if (gen.up > 0) {
const cache_root_path = src_builder.cache_root.path orelse
(src_builder.cache_root.join(src_builder.allocator, &.{"."}) catch @panic("OOM"));
for (0..gen.up) |_| {
if (mem.eql(u8, file_path.sub_path, cache_root_path)) {
// If we hit the cache root and there's still more to go,
// the script attempted to go too far.
dumpBadDirnameHelp(gen.file.step, asking_step,
\\dirname() attempted to traverse outside the cache root.
\\This is not allowed.
\\
, .{}) catch {};
@panic("misconfigured build script");
}
// path is absolute.
// dirname will return null only if we're at root.
// Typically, we'll stop well before that at the cache root.
file_path.sub_path = fs.path.dirname(file_path.sub_path) orelse {
dumpBadDirnameHelp(gen.file.step, asking_step,
\\dirname() reached root.
\\No more directories left to go up.
\\
, .{}) catch {};
@panic("misconfigured build script");
};
}
}
return file_path.join(src_builder.allocator, gen.sub_path) catch @panic("OOM");
},
.dependency => |dep| return .{
.root_dir = dep.dependency.builder.build_root,
.sub_path = dep.sub_path,
},
}
}
pub fn basename(lazy_path: LazyPath, src_builder: *Build, asking_step: ?*Step) []const u8 {
return fs.path.basename(switch (lazy_path) {
.src_path => |sp| sp.sub_path,
.cwd_relative => |sub_path| sub_path,
.generated => |gen| if (gen.sub_path.len > 0)
gen.sub_path
else
gen.file.getPath2(src_builder, asking_step),
.dependency => |dep| dep.sub_path,
});
}
/// Copies the internal strings.
///
/// The `b` parameter is only used for its allocator. All *Build instances
/// share the same allocator.
pub fn dupe(lazy_path: LazyPath, b: *Build) LazyPath {
return lazy_path.dupeInner(b.allocator);
}
fn dupeInner(lazy_path: LazyPath, allocator: std.mem.Allocator) LazyPath {
return switch (lazy_path) {
.src_path => |sp| .{ .src_path = .{
.owner = sp.owner,
.sub_path = sp.owner.dupePath(sp.sub_path),
} },
.cwd_relative => |p| .{ .cwd_relative = dupePathInner(allocator, p) },
.generated => |gen| .{ .generated = .{
.file = gen.file,
.up = gen.up,
.sub_path = dupePathInner(allocator, gen.sub_path),
} },
.dependency => |dep| .{ .dependency = dep },
};
}
};
fn dumpBadDirnameHelp(
fail_step: ?*Step,
asking_step: ?*Step,
comptime msg: []const u8,
args: anytype,
) anyerror!void {
const w = debug.lockStderrWriter(&.{});
defer debug.unlockStderrWriter();
try w.print(msg, args);
const tty_config = std.io.tty.detectConfig(.stderr());
if (fail_step) |s| {
tty_config.setColor(w, .red) catch {};
try w.writeAll(" The step was created by this stack trace:\n");
tty_config.setColor(w, .reset) catch {};
s.dump(w, tty_config);
}
if (asking_step) |as| {
tty_config.setColor(w, .red) catch {};
try w.print(" The step '{s}' that is missing a dependency on the above step was created by this stack trace:\n", .{as.name});
tty_config.setColor(w, .reset) catch {};
as.dump(w, tty_config);
}
tty_config.setColor(w, .red) catch {};
try w.writeAll(" Hope that helps. Proceeding to panic.\n");
tty_config.setColor(w, .reset) catch {};
}
/// In this function the stderr mutex has already been locked.
pub fn dumpBadGetPathHelp(
s: *Step,
w: *std.io.Writer,
tty_config: std.io.tty.Config,
src_builder: *Build,
asking_step: ?*Step,
) anyerror!void {
try w.print(
\\getPath() was called on a GeneratedFile that wasn't built yet.
\\ source package path: {s}
\\ Is there a missing Step dependency on step '{s}'?
\\
, .{
src_builder.build_root.path orelse ".",
s.name,
});
tty_config.setColor(w, .red) catch {};
try w.writeAll(" The step was created by this stack trace:\n");
tty_config.setColor(w, .reset) catch {};
s.dump(w, tty_config);
if (asking_step) |as| {
tty_config.setColor(w, .red) catch {};
try w.print(" The step '{s}' that is missing a dependency on the above step was created by this stack trace:\n", .{as.name});
tty_config.setColor(w, .reset) catch {};
as.dump(w, tty_config);
}
tty_config.setColor(w, .red) catch {};
try w.writeAll(" Hope that helps. Proceeding to panic.\n");
tty_config.setColor(w, .reset) catch {};
}
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(dir: InstallDir, builder: *Build) InstallDir {
if (dir == .custom) {
return .{ .custom = builder.dupe(dir.custom) };
} else {
return dir;
}
}
};
/// This function is intended to be called in the `configure` phase only.
/// It returns an absolute directory path, which is potentially going to be a
/// source of API breakage in the future, so keep that in mind when using this
/// function.
pub fn makeTempPath(b: *Build) []const u8 {
const rand_int = std.crypto.random.int(u64);
const tmp_dir_sub_path = "tmp" ++ fs.path.sep_str ++ std.fmt.hex(rand_int);
const result_path = b.cache_root.join(b.allocator, &.{tmp_dir_sub_path}) catch @panic("OOM");
b.cache_root.handle.makePath(tmp_dir_sub_path) catch |err| {
std.debug.print("unable to make tmp path '{s}': {s}\n", .{
result_path, @errorName(err),
});
};
return result_path;
}
/// A pair of target query and fully resolved target.
/// This type is generally required by build system API that need to be given a
/// target. The query is kept because the Zig toolchain needs to know which parts
/// of the target are "native". This can apply to the CPU, the OS, or even the ABI.
pub const ResolvedTarget = struct {
query: Target.Query,
result: Target,
};
/// Converts a target query into a fully resolved target that can be passed to
/// various parts of the API.
pub fn resolveTargetQuery(b: *Build, query: Target.Query) ResolvedTarget {
if (query.isNative()) {
// Hot path. This is faster than querying the native CPU and OS again.
return b.graph.host;
}
return .{
.query = query,
.result = std.zig.system.resolveTargetQuery(query) catch
@panic("unable to resolve target query"),
};
}
pub fn wantSharedLibSymLinks(target: Target) bool {
return target.os.tag != .windows;
}
pub const SystemIntegrationOptionConfig = struct {
/// If left as null, then the default will depend on system_package_mode.
default: ?bool = null,
};
pub fn systemIntegrationOption(
b: *Build,
name: []const u8,
config: SystemIntegrationOptionConfig,
) bool {
const gop = b.graph.system_library_options.getOrPut(b.allocator, name) catch @panic("OOM");
if (gop.found_existing) switch (gop.value_ptr.*) {
.user_disabled => {
gop.value_ptr.* = .declared_disabled;
return false;
},
.user_enabled => {
gop.value_ptr.* = .declared_enabled;
return true;
},
.declared_disabled => return false,
.declared_enabled => return true,
} else {
gop.key_ptr.* = b.dupe(name);
if (config.default orelse b.graph.system_package_mode) {
gop.value_ptr.* = .declared_enabled;
return true;
} else {
gop.value_ptr.* = .declared_disabled;
return false;
}
}
}
test {
_ = Cache;
_ = Step;
}