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zig/lib/std/builtin.zig
Alex Rønne Petersen 9ab7eec23e represent Mac Catalyst as aarch64-maccatalyst-none rather than aarch64-ios-macabi 
Apple's own headers and tbd files prefer to think of Mac Catalyst as a distinct
OS target. Earlier, when DriverKit support was added to LLVM, it was represented
a distinct OS. So why Apple decided to only represent Mac Catalyst as an ABI in
the target triple is beyond me. But this isn't the first time they've ignored
established target triple norms (see: armv7k and aarch64_32) and it probably
won't be the last.

While doing this, I also audited all Darwin OS prongs throughout the codebase
and made sure they cover all the tags.
2025-11-14 11:33:35 +01:00

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//! Types and values provided by the Zig language.
const builtin = @import("builtin");
const std = @import("std.zig");
const root = @import("root");
pub const assembly = @import("builtin/assembly.zig");
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const StackTrace = struct {
index: usize,
instruction_addresses: []usize,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const GlobalLinkage = enum(u2) {
internal,
strong,
weak,
link_once,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const SymbolVisibility = enum(u2) {
default,
hidden,
protected,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const AtomicOrder = enum {
unordered,
monotonic,
acquire,
release,
acq_rel,
seq_cst,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const ReduceOp = enum {
And,
Or,
Xor,
Min,
Max,
Add,
Mul,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const AtomicRmwOp = enum {
/// Exchange - store the operand unmodified.
/// Supports enums, integers, and floats.
Xchg,
/// Add operand to existing value.
/// Supports integers and floats.
/// For integers, two's complement wraparound applies.
Add,
/// Subtract operand from existing value.
/// Supports integers and floats.
/// For integers, two's complement wraparound applies.
Sub,
/// Perform bitwise AND on existing value with operand.
/// Supports integers.
And,
/// Perform bitwise NAND on existing value with operand.
/// Supports integers.
Nand,
/// Perform bitwise OR on existing value with operand.
/// Supports integers.
Or,
/// Perform bitwise XOR on existing value with operand.
/// Supports integers.
Xor,
/// Store operand if it is larger than the existing value.
/// Supports integers and floats.
Max,
/// Store operand if it is smaller than the existing value.
/// Supports integers and floats.
Min,
};
/// The code model puts constraints on the location of symbols and the size of code and data.
/// The selection of a code model is a trade off on speed and restrictions that needs to be selected on a per application basis to meet its requirements.
/// A slightly more detailed explanation can be found in (for example) the [System V Application Binary Interface (x86_64)](https://github.com/hjl-tools/x86-psABI/wiki/x86-64-psABI-1.0.pdf) 3.5.1.
///
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const CodeModel = enum {
default,
extreme,
kernel,
large,
medany,
medium,
medlow,
medmid,
normal,
small,
tiny,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const OptimizeMode = enum {
Debug,
ReleaseSafe,
ReleaseFast,
ReleaseSmall,
};
/// The calling convention of a function defines how arguments and return values are passed, as well
/// as any other requirements which callers and callees must respect, such as register preservation
/// and stack alignment.
///
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const CallingConvention = union(enum(u8)) {
pub const Tag = @typeInfo(CallingConvention).@"union".tag_type.?;
/// This is an alias for the default C calling convention for this target.
/// Functions marked as `extern` or `export` are given this calling convention by default.
pub const c = builtin.target.cCallingConvention().?;
pub const winapi: CallingConvention = switch (builtin.target.cpu.arch) {
.x86_64 => .{ .x86_64_win = .{} },
.x86 => .{ .x86_stdcall = .{} },
.aarch64 => .{ .aarch64_aapcs_win = .{} },
.thumb => .{ .arm_aapcs_vfp = .{} },
else => unreachable,
};
pub const kernel: CallingConvention = switch (builtin.target.cpu.arch) {
.amdgcn => .amdgcn_kernel,
.nvptx, .nvptx64 => .nvptx_kernel,
.spirv32, .spirv64 => .spirv_kernel,
else => unreachable,
};
/// The default Zig calling convention when neither `export` nor `inline` is specified.
/// This calling convention makes no guarantees about stack alignment, registers, etc.
/// It can only be used within this Zig compilation unit.
auto,
/// The calling convention of a function that can be called with `async` syntax. An `async` call
/// of a runtime-known function must target a function with this calling convention.
/// Comptime-known functions with other calling conventions may be coerced to this one.
async,
/// Functions with this calling convention have no prologue or epilogue, making the function
/// uncallable in regular Zig code. This can be useful when integrating with assembly.
naked,
/// This calling convention is exactly equivalent to using the `inline` keyword on a function
/// definition. This function will be semantically inlined by the Zig compiler at call sites.
/// Pointers to inline functions are comptime-only.
@"inline",
// Calling conventions for the `x86_64` architecture.
x86_64_sysv: CommonOptions,
x86_64_x32: CommonOptions,
x86_64_win: CommonOptions,
x86_64_regcall_v3_sysv: CommonOptions,
x86_64_regcall_v4_win: CommonOptions,
x86_64_vectorcall: CommonOptions,
x86_64_interrupt: CommonOptions,
// Calling conventions for the `x86` architecture.
x86_sysv: X86RegparmOptions,
x86_win: X86RegparmOptions,
x86_stdcall: X86RegparmOptions,
x86_fastcall: CommonOptions,
x86_thiscall: CommonOptions,
x86_thiscall_mingw: CommonOptions,
x86_regcall_v3: CommonOptions,
x86_regcall_v4_win: CommonOptions,
x86_vectorcall: CommonOptions,
x86_interrupt: CommonOptions,
// Calling conventions for the `x86_16` architecture.
x86_16_cdecl: CommonOptions,
x86_16_stdcall: CommonOptions,
x86_16_regparmcall: CommonOptions,
x86_16_interrupt: CommonOptions,
// Calling conventions for the `aarch64` and `aarch64_be` architectures.
aarch64_aapcs: CommonOptions,
aarch64_aapcs_darwin: CommonOptions,
aarch64_aapcs_win: CommonOptions,
aarch64_vfabi: CommonOptions,
aarch64_vfabi_sve: CommonOptions,
/// The standard `alpha` calling convention.
alpha_osf: CommonOptions,
// Calling convetions for the `arm`, `armeb`, `thumb`, and `thumbeb` architectures.
/// ARM Architecture Procedure Call Standard
arm_aapcs: CommonOptions,
/// ARM Architecture Procedure Call Standard Vector Floating-Point
arm_aapcs_vfp: CommonOptions,
arm_interrupt: ArmInterruptOptions,
// Calling conventions for the `mips64` and `mips64el` architectures.
mips64_n64: CommonOptions,
mips64_n32: CommonOptions,
mips64_interrupt: MipsInterruptOptions,
// Calling conventions for the `mips` and `mipsel` architectures.
mips_o32: CommonOptions,
mips_interrupt: MipsInterruptOptions,
// Calling conventions for the `riscv64` architecture.
riscv64_lp64: CommonOptions,
riscv64_lp64_v: CommonOptions,
riscv64_interrupt: RiscvInterruptOptions,
// Calling conventions for the `riscv32` architecture.
riscv32_ilp32: CommonOptions,
riscv32_ilp32_v: CommonOptions,
riscv32_interrupt: RiscvInterruptOptions,
// Calling conventions for the `sparc64` architecture.
sparc64_sysv: CommonOptions,
// Calling conventions for the `sparc` architecture.
sparc_sysv: CommonOptions,
// Calling conventions for the `powerpc64` and `powerpc64le` architectures.
powerpc64_elf: CommonOptions,
powerpc64_elf_altivec: CommonOptions,
powerpc64_elf_v2: CommonOptions,
// Calling conventions for the `powerpc` and `powerpcle` architectures.
powerpc_sysv: CommonOptions,
powerpc_sysv_altivec: CommonOptions,
powerpc_aix: CommonOptions,
powerpc_aix_altivec: CommonOptions,
/// The standard `wasm32` and `wasm64` calling convention, as specified in the WebAssembly Tool Conventions.
wasm_mvp: CommonOptions,
/// The standard `arc`/`arceb` calling convention.
arc_sysv: CommonOptions,
arc_interrupt: ArcInterruptOptions,
// Calling conventions for the `avr` architecture.
avr_gnu,
avr_builtin,
avr_signal,
avr_interrupt,
/// The standard `bpfel`/`bpfeb` calling convention.
bpf_std: CommonOptions,
// Calling conventions for the `csky` architecture.
csky_sysv: CommonOptions,
csky_interrupt: CommonOptions,
// Calling conventions for the `hexagon` architecture.
hexagon_sysv: CommonOptions,
hexagon_sysv_hvx: CommonOptions,
/// The standard `hppa` calling convention.
hppa_elf: CommonOptions,
/// The standard `hppa64` calling convention.
hppa64_elf: CommonOptions,
kvx_lp64: CommonOptions,
kvx_ilp32: CommonOptions,
/// The standard `lanai` calling convention.
lanai_sysv: CommonOptions,
/// The standard `loongarch64` calling convention.
loongarch64_lp64: CommonOptions,
/// The standard `loongarch32` calling convention.
loongarch32_ilp32: CommonOptions,
// Calling conventions for the `m68k` architecture.
m68k_sysv: CommonOptions,
m68k_gnu: CommonOptions,
m68k_rtd: CommonOptions,
m68k_interrupt: CommonOptions,
/// The standard `microblaze`/`microblazeel` calling convention.
microblaze_std: CommonOptions,
microblaze_interrupt: MicroblazeInterruptOptions,
/// The standard `msp430` calling convention.
msp430_eabi: CommonOptions,
msp430_interrupt: CommonOptions,
/// The standard `or1k` calling convention.
or1k_sysv: CommonOptions,
/// The standard `propeller` calling convention.
propeller_sysv: CommonOptions,
// Calling conventions for the `s390x` architecture.
s390x_sysv: CommonOptions,
s390x_sysv_vx: CommonOptions,
// Calling conventions for the `sh`/`sheb` architecture.
sh_gnu: CommonOptions,
sh_renesas: CommonOptions,
sh_interrupt: ShInterruptOptions,
/// The standard `ve` calling convention.
ve_sysv: CommonOptions,
// Calling conventions for the `xcore` architecture.
xcore_xs1: CommonOptions,
xcore_xs2: CommonOptions,
// Calling conventions for the `xtensa`/`xtensaeb` architecture.
xtensa_call0: CommonOptions,
xtensa_windowed: CommonOptions,
// Calling conventions for the `amdgcn` architecture.
amdgcn_device: CommonOptions,
amdgcn_kernel,
amdgcn_cs: CommonOptions,
// Calling conventions for the `nvptx` and `nvptx64` architectures.
nvptx_device,
nvptx_kernel,
// Calling conventions for kernels and shaders on the `spirv`, `spirv32`, and `spirv64` architectures.
spirv_device,
spirv_kernel,
spirv_fragment,
spirv_vertex,
/// Options shared across most calling conventions.
pub const CommonOptions = struct {
/// The boundary the stack is aligned to when the function is called.
/// `null` means the default for this calling convention.
incoming_stack_alignment: ?u64 = null,
};
/// Options for x86 calling conventions which support the regparm attribute to pass some
/// arguments in registers.
pub const X86RegparmOptions = struct {
/// The boundary the stack is aligned to when the function is called.
/// `null` means the default for this calling convention.
incoming_stack_alignment: ?u64 = null,
/// The number of arguments to pass in registers before passing the remaining arguments
/// according to the calling convention.
/// Equivalent to `__attribute__((regparm(x)))` in Clang and GCC.
register_params: u2 = 0,
};
/// Options for the `arc_interrupt` calling convention.
pub const ArcInterruptOptions = struct {
/// The boundary the stack is aligned to when the function is called.
/// `null` means the default for this calling convention.
incoming_stack_alignment: ?u64 = null,
/// The kind of interrupt being received.
type: InterruptType,
pub const InterruptType = enum(u2) {
ilink1,
ilink2,
ilink,
firq,
};
};
/// Options for the `arm_interrupt` calling convention.
pub const ArmInterruptOptions = struct {
/// The boundary the stack is aligned to when the function is called.
/// `null` means the default for this calling convention.
incoming_stack_alignment: ?u64 = null,
/// The kind of interrupt being received.
type: InterruptType = .generic,
pub const InterruptType = enum(u3) {
generic,
irq,
fiq,
swi,
abort,
undef,
};
};
/// Options for the `microblaze_interrupt` calling convention.
pub const MicroblazeInterruptOptions = struct {
/// The boundary the stack is aligned to when the function is called.
/// `null` means the default for this calling convention.
incoming_stack_alignment: ?u64 = null,
type: InterruptType = .regular,
pub const InterruptType = enum(u2) {
/// User exception; return with `rtsd`.
user,
/// Regular interrupt; return with `rtid`.
regular,
/// Fast interrupt; return with `rtid`.
fast,
/// Software breakpoint; return with `rtbd`.
breakpoint,
};
};
/// Options for the `mips_interrupt` and `mips64_interrupt` calling conventions.
pub const MipsInterruptOptions = struct {
/// The boundary the stack is aligned to when the function is called.
/// `null` means the default for this calling convention.
incoming_stack_alignment: ?u64 = null,
/// The interrupt mode.
mode: InterruptMode = .eic,
pub const InterruptMode = enum(u4) {
eic,
sw0,
sw1,
hw0,
hw1,
hw2,
hw3,
hw4,
hw5,
};
};
/// Options for the `riscv32_interrupt` and `riscv64_interrupt` calling conventions.
pub const RiscvInterruptOptions = struct {
/// The boundary the stack is aligned to when the function is called.
/// `null` means the default for this calling convention.
incoming_stack_alignment: ?u64 = null,
/// The privilege mode.
mode: PrivilegeMode,
pub const PrivilegeMode = enum(u2) {
supervisor,
machine,
};
};
/// Options for the `sh_interrupt` calling convention.
pub const ShInterruptOptions = struct {
/// The boundary the stack is aligned to when the function is called.
/// `null` means the default for this calling convention.
incoming_stack_alignment: ?u64 = null,
save: SaveBehavior = .full,
pub const SaveBehavior = enum(u3) {
/// Save only fpscr (if applicable).
fpscr,
/// Save only high-numbered registers, i.e. r0 through r7 are *not* saved.
high,
/// Save all registers normally.
full,
/// Save all registers using the CPU's fast register bank.
bank,
};
};
/// Returns the array of `std.Target.Cpu.Arch` to which this `CallingConvention` applies.
/// Asserts that `cc` is not `.auto`, `.@"async"`, `.naked`, or `.@"inline"`.
pub fn archs(cc: CallingConvention) []const std.Target.Cpu.Arch {
return std.Target.Cpu.Arch.fromCallingConvention(cc);
}
pub fn eql(a: CallingConvention, b: CallingConvention) bool {
return std.meta.eql(a, b);
}
pub fn withStackAlign(cc: CallingConvention, incoming_stack_alignment: u64) CallingConvention {
const tag: CallingConvention.Tag = cc;
var result = cc;
@field(result, @tagName(tag)).incoming_stack_alignment = incoming_stack_alignment;
return result;
}
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const AddressSpace = enum(u5) {
// CPU address spaces.
generic,
gs,
fs,
ss,
// x86_16 extra address spaces.
/// Allows addressing the entire address space by storing both segment and offset.
far,
// GPU address spaces.
global,
constant,
param,
shared,
local,
input,
output,
uniform,
push_constant,
storage_buffer,
physical_storage_buffer,
// AVR address spaces.
flash,
flash1,
flash2,
flash3,
flash4,
flash5,
// Propeller address spaces.
/// This address space only addresses the cog-local ram.
cog,
/// This address space only addresses shared hub ram.
hub,
/// This address space only addresses the "lookup" ram
lut,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const SourceLocation = struct {
/// The name chosen when compiling. Not a file path.
module: [:0]const u8,
/// Relative to the root directory of its module.
file: [:0]const u8,
fn_name: [:0]const u8,
line: u32,
column: u32,
};
pub const TypeId = std.meta.Tag(Type);
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Type = union(enum) {
type: void,
void: void,
bool: void,
noreturn: void,
int: Int,
float: Float,
pointer: Pointer,
array: Array,
@"struct": Struct,
comptime_float: void,
comptime_int: void,
undefined: void,
null: void,
optional: Optional,
error_union: ErrorUnion,
error_set: ErrorSet,
@"enum": Enum,
@"union": Union,
@"fn": Fn,
@"opaque": Opaque,
frame: Frame,
@"anyframe": AnyFrame,
vector: Vector,
enum_literal: void,
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Int = struct {
signedness: Signedness,
bits: u16,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Float = struct {
bits: u16,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Pointer = struct {
size: Size,
is_const: bool,
is_volatile: bool,
/// TODO make this u16 instead of comptime_int
alignment: comptime_int,
address_space: AddressSpace,
child: type,
is_allowzero: bool,
/// The type of the sentinel is the element type of the pointer, which is
/// the value of the `child` field in this struct. However there is no way
/// to refer to that type here, so we use `*const anyopaque`.
/// See also: `sentinel`
sentinel_ptr: ?*const anyopaque,
/// Loads the pointer type's sentinel value from `sentinel_ptr`.
/// Returns `null` if the pointer type has no sentinel.
pub inline fn sentinel(comptime ptr: Pointer) ?ptr.child {
const sp: *const ptr.child = @ptrCast(@alignCast(ptr.sentinel_ptr orelse return null));
return sp.*;
}
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Size = enum(u2) {
one,
many,
slice,
c,
};
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Array = struct {
len: comptime_int,
child: type,
/// The type of the sentinel is the element type of the array, which is
/// the value of the `child` field in this struct. However there is no way
/// to refer to that type here, so we use `*const anyopaque`.
/// See also: `sentinel`.
sentinel_ptr: ?*const anyopaque,
/// Loads the array type's sentinel value from `sentinel_ptr`.
/// Returns `null` if the array type has no sentinel.
pub inline fn sentinel(comptime arr: Array) ?arr.child {
const sp: *const arr.child = @ptrCast(@alignCast(arr.sentinel_ptr orelse return null));
return sp.*;
}
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const ContainerLayout = enum(u2) {
auto,
@"extern",
@"packed",
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const StructField = struct {
name: [:0]const u8,
type: type,
/// The type of the default value is the type of this struct field, which
/// is the value of the `type` field in this struct. However there is no
/// way to refer to that type here, so we use `*const anyopaque`.
/// See also: `defaultValue`.
default_value_ptr: ?*const anyopaque,
is_comptime: bool,
alignment: comptime_int,
/// Loads the field's default value from `default_value_ptr`.
/// Returns `null` if the field has no default value.
pub inline fn defaultValue(comptime sf: StructField) ?sf.type {
const dp: *const sf.type = @ptrCast(@alignCast(sf.default_value_ptr orelse return null));
return dp.*;
}
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Struct = struct {
layout: ContainerLayout,
/// Only valid if layout is .@"packed"
backing_integer: ?type = null,
fields: []const StructField,
decls: []const Declaration,
is_tuple: bool,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Optional = struct {
child: type,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const ErrorUnion = struct {
error_set: type,
payload: type,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Error = struct {
name: [:0]const u8,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const ErrorSet = ?[]const Error;
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const EnumField = struct {
name: [:0]const u8,
value: comptime_int,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Enum = struct {
tag_type: type,
fields: []const EnumField,
decls: []const Declaration,
is_exhaustive: bool,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const UnionField = struct {
name: [:0]const u8,
type: type,
alignment: comptime_int,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Union = struct {
layout: ContainerLayout,
tag_type: ?type,
fields: []const UnionField,
decls: []const Declaration,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Fn = struct {
calling_convention: CallingConvention,
is_generic: bool,
is_var_args: bool,
/// TODO change the language spec to make this not optional.
return_type: ?type,
params: []const Param,
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Param = struct {
is_generic: bool,
is_noalias: bool,
type: ?type,
};
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Opaque = struct {
decls: []const Declaration,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Frame = struct {
function: *const anyopaque,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const AnyFrame = struct {
child: ?type,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Vector = struct {
len: comptime_int,
child: type,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Declaration = struct {
name: [:0]const u8,
};
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const FloatMode = enum {
strict,
optimized,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Endian = enum {
big,
little,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const Signedness = enum(u1) {
signed,
unsigned,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const OutputMode = enum {
Exe,
Lib,
Obj,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const LinkMode = enum {
static,
dynamic,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const UnwindTables = enum {
none,
sync,
async,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const WasiExecModel = enum {
command,
reactor,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const CallModifier = enum {
/// Equivalent to function call syntax.
auto,
/// Prevents tail call optimization. This guarantees that the return
/// address will point to the callsite, as opposed to the callsite's
/// callsite. If the call is otherwise required to be tail-called
/// or inlined, a compile error is emitted instead.
never_tail,
/// Guarantees that the call will not be inlined. If the call is
/// otherwise required to be inlined, a compile error is emitted instead.
never_inline,
/// Asserts that the function call will not suspend. This allows a
/// non-async function to call an async function.
no_suspend,
/// Guarantees that the call will be generated with tail call optimization.
/// If this is not possible, a compile error is emitted instead.
always_tail,
/// Guarantees that the call will be inlined at the callsite.
/// If this is not possible, a compile error is emitted instead.
always_inline,
/// Evaluates the call at compile-time. If the call cannot be completed at
/// compile-time, a compile error is emitted instead.
compile_time,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListAarch64 = extern struct {
__stack: *anyopaque,
__gr_top: *anyopaque,
__vr_top: *anyopaque,
__gr_offs: c_int,
__vr_offs: c_int,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListAlpha = extern struct {
__base: *anyopaque,
__offset: c_int,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListArm = extern struct {
__ap: *anyopaque,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListHexagon = extern struct {
__gpr: c_long,
__fpr: c_long,
__overflow_arg_area: *anyopaque,
__reg_save_area: *anyopaque,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListPowerPc = extern struct {
gpr: u8,
fpr: u8,
reserved: c_ushort,
overflow_arg_area: *anyopaque,
reg_save_area: *anyopaque,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListS390x = extern struct {
__current_saved_reg_area_pointer: *anyopaque,
__saved_reg_area_end_pointer: *anyopaque,
__overflow_area_pointer: *anyopaque,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListSh = extern struct {
__va_next_o: *anyopaque,
__va_next_o_limit: *anyopaque,
__va_next_fp: *anyopaque,
__va_next_fp_limit: *anyopaque,
__va_next_stack: *anyopaque,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListX86_64 = extern struct {
gp_offset: c_uint,
fp_offset: c_uint,
overflow_arg_area: *anyopaque,
reg_save_area: *anyopaque,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaListXtensa = extern struct {
__va_stk: *c_int,
__va_reg: *c_int,
__va_ndx: c_int,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const VaList = switch (builtin.cpu.arch) {
.amdgcn,
.msp430,
.nvptx,
.nvptx64,
.powerpc64,
.powerpc64le,
.x86,
=> *u8,
.arc,
.arceb,
.avr,
.bpfel,
.bpfeb,
.csky,
.hppa,
.hppa64,
.kvx,
.lanai,
.loongarch32,
.loongarch64,
.m68k,
.microblaze,
.microblazeel,
.mips,
.mipsel,
.mips64,
.mips64el,
.riscv32,
.riscv32be,
.riscv64,
.riscv64be,
.sparc,
.sparc64,
.spirv32,
.spirv64,
.ve,
.wasm32,
.wasm64,
.xcore,
=> *anyopaque,
.aarch64, .aarch64_be => switch (builtin.os.tag) {
.driverkit, .ios, .maccatalyst, .macos, .tvos, .visionos, .watchos, .windows => *u8,
else => switch (builtin.zig_backend) {
else => VaListAarch64,
.stage2_llvm => @compileError("disabled due to miscompilations"),
},
},
.alpha => VaListAlpha,
.arm, .armeb, .thumb, .thumbeb => VaListArm,
.hexagon => if (builtin.target.abi.isMusl()) VaListHexagon else *u8,
.powerpc, .powerpcle => VaListPowerPc,
.s390x => VaListS390x,
.sh, .sheb => VaListSh, // This is wrong for `sh_renesas`: https://github.com/ziglang/zig/issues/24692#issuecomment-3150779829
.x86_64 => switch (builtin.os.tag) {
.uefi, .windows => switch (builtin.zig_backend) {
else => *u8,
.stage2_llvm => @compileError("disabled due to miscompilations"),
},
else => VaListX86_64,
},
.xtensa, .xtensaeb => VaListXtensa,
else => @compileError("VaList not supported for this target yet"),
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const PrefetchOptions = struct {
/// Whether the prefetch should prepare for a read or a write.
rw: Rw = .read,
/// The data's locality in an inclusive range from 0 to 3.
///
/// 0 means no temporal locality. That is, the data can be immediately
/// dropped from the cache after it is accessed.
///
/// 3 means high temporal locality. That is, the data should be kept in
/// the cache as it is likely to be accessed again soon.
locality: u2 = 3,
/// The cache that the prefetch should be performed on.
cache: Cache = .data,
pub const Rw = enum(u1) {
read,
write,
};
pub const Cache = enum(u1) {
instruction,
data,
};
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const ExportOptions = struct {
name: []const u8,
linkage: GlobalLinkage = .strong,
section: ?[]const u8 = null,
visibility: SymbolVisibility = .default,
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const ExternOptions = struct {
name: []const u8,
library_name: ?[]const u8 = null,
linkage: GlobalLinkage = .strong,
visibility: SymbolVisibility = .default,
/// Setting this to `true` makes the `@extern` a runtime value.
is_thread_local: bool = false,
is_dll_import: bool = false,
relocation: Relocation = .any,
pub const Relocation = enum(u1) {
/// Any type of relocation is allowed.
any,
/// A program-counter-relative relocation is required.
/// Using this value makes the `@extern` a runtime value.
pcrel,
};
};
/// This data structure is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const BranchHint = enum(u3) {
/// Equivalent to no hint given.
none,
/// This branch of control flow is more likely to be reached than its peers.
/// The optimizer should optimize for reaching it.
likely,
/// This branch of control flow is less likely to be reached than its peers.
/// The optimizer should optimize for not reaching it.
unlikely,
/// This branch of control flow is unlikely to *ever* be reached.
/// The optimizer may place it in a different page of memory to optimize other branches.
cold,
/// It is difficult to predict whether this branch of control flow will be reached.
/// The optimizer should avoid branching behavior with expensive mispredictions.
unpredictable,
};
/// This enum is set by the compiler and communicates which compiler backend is
/// used to produce machine code.
/// Think carefully before deciding to observe this value. Nearly all code should
/// be agnostic to the backend that implements the language. The use case
/// to use this value is to **work around problems with compiler implementations.**
///
/// Avoid failing the compilation if the compiler backend does not match a
/// whitelist of backends; rather one should detect that a known problem would
/// occur in a blacklist of backends.
///
/// The enum is nonexhaustive so that alternate Zig language implementations may
/// choose a number as their tag (please use a random number generator rather
/// than a "cute" number) and codebases can interact with these values even if
/// this upstream enum does not have a name for the number. Of course, upstream
/// is happy to accept pull requests to add Zig implementations to this enum.
///
/// This data structure is part of the Zig language specification.
pub const CompilerBackend = enum(u64) {
/// It is allowed for a compiler implementation to not reveal its identity,
/// in which case this value is appropriate. Be cool and make sure your
/// code supports `other` Zig compilers!
other = 0,
/// The original Zig compiler created in 2015 by Andrew Kelley. Implemented
/// in C++. Used LLVM. Deleted from the ZSF ziglang/zig codebase on
/// December 6th, 2022.
stage1 = 1,
/// The reference implementation self-hosted compiler of Zig, using the
/// LLVM backend.
stage2_llvm = 2,
/// The reference implementation self-hosted compiler of Zig, using the
/// backend that generates C source code.
/// Note that one can observe whether the compilation will output C code
/// directly with `object_format` value rather than the `compiler_backend` value.
stage2_c = 3,
/// The reference implementation self-hosted compiler of Zig, using the
/// WebAssembly backend.
stage2_wasm = 4,
/// The reference implementation self-hosted compiler of Zig, using the
/// arm backend.
stage2_arm = 5,
/// The reference implementation self-hosted compiler of Zig, using the
/// x86_64 backend.
stage2_x86_64 = 6,
/// The reference implementation self-hosted compiler of Zig, using the
/// aarch64 backend.
stage2_aarch64 = 7,
/// The reference implementation self-hosted compiler of Zig, using the
/// x86 backend.
stage2_x86 = 8,
/// The reference implementation self-hosted compiler of Zig, using the
/// riscv64 backend.
stage2_riscv64 = 9,
/// The reference implementation self-hosted compiler of Zig, using the
/// sparc64 backend.
stage2_sparc64 = 10,
/// The reference implementation self-hosted compiler of Zig, using the
/// spirv backend.
stage2_spirv = 11,
/// The reference implementation self-hosted compiler of Zig, using the
/// powerpc backend.
stage2_powerpc = 12,
_,
};
/// This function type is used by the Zig language code generation and
/// therefore must be kept in sync with the compiler implementation.
pub const TestFn = struct {
name: []const u8,
func: *const fn () anyerror!void,
};
/// This namespace is used by the Zig compiler to emit various kinds of safety
/// panics. These can be overridden by making a public `panic` namespace in the
/// root source file.
pub const panic: type = p: {
if (@hasDecl(root, "panic")) {
if (@TypeOf(root.panic) != type) {
// Deprecated; make `panic` a namespace instead.
break :p std.debug.FullPanic(struct {
fn panic(msg: []const u8, ra: ?usize) noreturn {
root.panic(msg, @errorReturnTrace(), ra);
}
}.panic);
}
break :p root.panic;
}
break :p switch (builtin.zig_backend) {
.stage2_powerpc,
.stage2_riscv64,
=> std.debug.simple_panic,
else => std.debug.FullPanic(std.debug.defaultPanic),
};
};
pub noinline fn returnError() void {
@branchHint(.unlikely);
@setRuntimeSafety(false);
const st = @errorReturnTrace().?;
if (st.index < st.instruction_addresses.len)
st.instruction_addresses[st.index] = @returnAddress();
st.index += 1;
}
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