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ce92ccccc961992c00a10e714ce9e799956c50f2
zig/src/target.zig
David Rubin ce92ccccc9 sema: resolve{Struct,Union}Inner don't throw away Semas 
before this, calls to `resolveTypeFieldsStruct` (now renamed to the more correct `resolveStructFieldTypes`) would just throw away the sema that `resolveStructInner` created and create its own. There is no reason to do this, and we fix it to preserve the sema through it all.
2024-08-25 15:18:20 -07:00

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Zig
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const std = @import("std");
const Type = @import("Type.zig");
const AddressSpace = std.builtin.AddressSpace;
const Alignment = @import("InternPool.zig").Alignment;
const Feature = @import("Zcu.zig").Feature;
pub const default_stack_protector_buffer_size = 4;
pub fn cannotDynamicLink(target: std.Target) bool {
return switch (target.os.tag) {
.freestanding => true,
else => target.isSpirV(),
};
}
/// On Darwin, we always link libSystem which contains libc.
/// Similarly on FreeBSD and NetBSD we always link system libc
/// since this is the stable syscall interface.
pub fn osRequiresLibC(target: std.Target) bool {
return target.os.requiresLibC();
}
pub fn libcNeedsLibUnwind(target: std.Target) bool {
return switch (target.os.tag) {
.macos,
.ios,
.watchos,
.tvos,
.visionos,
.freestanding,
.wasi, // Wasm/WASI currently doesn't offer support for libunwind, so don't link it.
=> false,
.windows => target.abi != .msvc,
else => true,
};
}
pub fn requiresPIE(target: std.Target) bool {
return target.isAndroid() or target.isDarwin() or target.os.tag == .openbsd;
}
/// This function returns whether non-pic code is completely invalid on the given target.
pub fn requiresPIC(target: std.Target, linking_libc: bool) bool {
return target.isAndroid() or
target.os.tag == .windows or target.os.tag == .uefi or
osRequiresLibC(target) or
(linking_libc and target.isGnuLibC()) or
(target.abi == .ohos and target.cpu.arch == .aarch64);
}
/// This is not whether the target supports Position Independent Code, but whether the -fPIC
/// C compiler argument is valid to Clang.
pub fn supports_fpic(target: std.Target) bool {
return target.os.tag != .windows and target.os.tag != .uefi;
}
pub fn alwaysSingleThreaded(target: std.Target) bool {
_ = target;
return false;
}
pub fn defaultSingleThreaded(target: std.Target) bool {
switch (target.cpu.arch) {
.wasm32, .wasm64 => return true,
else => {},
}
switch (target.os.tag) {
.haiku => return true,
else => {},
}
return false;
}
/// Valgrind supports more, but Zig does not support them yet.
pub fn hasValgrindSupport(target: std.Target) bool {
switch (target.cpu.arch) {
.x86,
.x86_64,
.aarch64,
.aarch64_be,
=> {
return target.os.tag == .linux or target.os.tag == .solaris or target.os.tag == .illumos or
(target.os.tag == .windows and target.abi != .msvc);
},
else => return false,
}
}
/// The set of targets that LLVM has non-experimental support for.
/// Used to select between LLVM backend and self-hosted backend when compiling in
/// release modes.
pub fn hasLlvmSupport(target: std.Target, ofmt: std.Target.ObjectFormat) bool {
switch (ofmt) {
// LLVM does not support these object formats:
.c,
.plan9,
=> return false,
.coff,
.dxcontainer,
.elf,
.goff,
.hex,
.macho,
.nvptx,
.spirv,
.raw,
.wasm,
.xcoff,
=> {},
}
return switch (target.cpu.arch) {
.arm,
.armeb,
.aarch64,
.aarch64_be,
.arc,
.avr,
.bpfel,
.bpfeb,
.csky,
.hexagon,
.loongarch32,
.loongarch64,
.m68k,
.mips,
.mipsel,
.mips64,
.mips64el,
.msp430,
.powerpc,
.powerpcle,
.powerpc64,
.powerpc64le,
.amdgcn,
.riscv32,
.riscv64,
.sparc,
.sparc64,
.s390x,
.thumb,
.thumbeb,
.x86,
.x86_64,
.xcore,
.xtensa,
.nvptx,
.nvptx64,
.lanai,
.wasm32,
.wasm64,
.ve,
=> true,
// An LLVM backend exists but we don't currently support using it.
.dxil,
.spirv,
.spirv32,
.spirv64,
=> false,
// No LLVM backend exists.
.kalimba,
.spu_2,
=> false,
};
}
/// The set of targets that Zig supports using LLD to link for.
pub fn hasLldSupport(ofmt: std.Target.ObjectFormat) bool {
return switch (ofmt) {
.elf, .coff, .wasm => true,
else => false,
};
}
/// The set of targets that our own self-hosted backends have robust support for.
/// Used to select between LLVM backend and self-hosted backend when compiling in
/// debug mode. A given target should only return true here if it is passing greater
/// than or equal to the number of behavior tests as the respective LLVM backend.
pub fn selfHostedBackendIsAsRobustAsLlvm(target: std.Target) bool {
_ = target;
return false;
}
pub fn supportsStackProbing(target: std.Target) bool {
return target.os.tag != .windows and target.os.tag != .uefi and
(target.cpu.arch == .x86 or target.cpu.arch == .x86_64);
}
pub fn supportsStackProtector(target: std.Target, backend: std.builtin.CompilerBackend) bool {
switch (target.os.tag) {
.plan9 => return false,
else => {},
}
switch (target.cpu.arch) {
.spirv, .spirv32, .spirv64 => return false,
else => {},
}
return switch (backend) {
.stage2_llvm => true,
else => false,
};
}
pub fn clangSupportsStackProtector(target: std.Target) bool {
return switch (target.cpu.arch) {
.spirv, .spirv32, .spirv64 => return false,
else => true,
};
}
pub fn libcProvidesStackProtector(target: std.Target) bool {
return !target.isMinGW() and target.os.tag != .wasi and !target.isSpirV();
}
pub fn supportsReturnAddress(target: std.Target) bool {
return switch (target.cpu.arch) {
.wasm32, .wasm64 => target.os.tag == .emscripten,
.bpfel, .bpfeb => false,
.spirv, .spirv32, .spirv64 => false,
else => true,
};
}
pub const CompilerRtClassification = enum { none, only_compiler_rt, only_libunwind, both };
pub fn classifyCompilerRtLibName(target: std.Target, name: []const u8) CompilerRtClassification {
if (target.abi.isGnu() and std.mem.eql(u8, name, "gcc_s")) {
// libgcc_s includes exception handling functions, so if linking this library
// is requested, zig needs to instead link libunwind. Otherwise we end up with
// the linker unable to find `_Unwind_RaiseException` and other related symbols.
return .both;
}
if (std.mem.eql(u8, name, "compiler_rt")) {
return .only_compiler_rt;
}
if (std.mem.eql(u8, name, "unwind")) {
return .only_libunwind;
}
return .none;
}
pub fn hasDebugInfo(target: std.Target) bool {
return switch (target.cpu.arch) {
.nvptx, .nvptx64 => std.Target.nvptx.featureSetHas(target.cpu.features, .ptx75) or
std.Target.nvptx.featureSetHas(target.cpu.features, .ptx76) or
std.Target.nvptx.featureSetHas(target.cpu.features, .ptx77) or
std.Target.nvptx.featureSetHas(target.cpu.features, .ptx78) or
std.Target.nvptx.featureSetHas(target.cpu.features, .ptx80) or
std.Target.nvptx.featureSetHas(target.cpu.features, .ptx81),
.bpfel, .bpfeb => false,
else => true,
};
}
pub fn defaultCompilerRtOptimizeMode(target: std.Target) std.builtin.OptimizeMode {
if (target.cpu.arch.isWasm() and target.os.tag == .freestanding) {
return .ReleaseSmall;
} else {
return .ReleaseFast;
}
}
pub fn hasRedZone(target: std.Target) bool {
return switch (target.cpu.arch) {
.x86_64,
.x86,
.aarch64,
.aarch64_be,
=> true,
else => false,
};
}
pub fn libcFullLinkFlags(target: std.Target) []const []const u8 {
// The linking order of these is significant and should match the order other
// c compilers such as gcc or clang use.
return switch (target.os.tag) {
.netbsd, .openbsd => &[_][]const u8{
"-lm",
"-lpthread",
"-lc",
"-lutil",
},
.solaris, .illumos => &[_][]const u8{
"-lm",
"-lsocket",
"-lnsl",
// Solaris releases after 10 merged the threading libraries into libc.
"-lc",
},
.haiku => &[_][]const u8{
"-lm",
"-lroot",
"-lpthread",
"-lc",
"-lnetwork",
},
else => switch (target.abi) {
.android => &[_][]const u8{
"-lm",
"-lc",
"-ldl",
},
else => &[_][]const u8{
"-lm",
"-lpthread",
"-lc",
"-ldl",
"-lrt",
"-lutil",
},
},
};
}
pub fn clangMightShellOutForAssembly(target: std.Target) bool {
// Clang defaults to using the system assembler over the internal one
// when targeting a non-BSD OS.
return target.cpu.arch.isSPARC();
}
/// Each backend architecture in Clang has a different codepath which may or may not
/// support an -mcpu flag.
pub fn clangAssemblerSupportsMcpuArg(target: std.Target) bool {
return switch (target.cpu.arch) {
.arm, .armeb, .thumb, .thumbeb => true,
else => false,
};
}
pub fn needUnwindTables(target: std.Target) bool {
return target.os.tag == .windows or target.isDarwin() or std.debug.Dwarf.abi.supportsUnwinding(target);
}
pub fn defaultAddressSpace(
target: std.Target,
context: enum {
/// Query the default address space for global constant values.
global_constant,
/// Query the default address space for global mutable values.
global_mutable,
/// Query the default address space for function-local values.
local,
/// Query the default address space for functions themselves.
function,
},
) AddressSpace {
// The default address space for functions on AVR is .flash to produce
// correct fixups into progmem.
if (context == .function and target.cpu.arch == .avr) return .flash;
return .generic;
}
/// Returns true if pointers in `from` can be converted to a pointer in `to`.
pub fn addrSpaceCastIsValid(
target: std.Target,
from: AddressSpace,
to: AddressSpace,
) bool {
const arch = target.cpu.arch;
switch (arch) {
.x86_64, .x86 => return arch.supportsAddressSpace(from) and arch.supportsAddressSpace(to),
.nvptx64, .nvptx, .amdgcn => {
const to_generic = arch.supportsAddressSpace(from) and to == .generic;
const from_generic = arch.supportsAddressSpace(to) and from == .generic;
return to_generic or from_generic;
},
else => return from == .generic and to == .generic,
}
}
pub fn llvmMachineAbi(target: std.Target) ?[:0]const u8 {
const have_float = switch (target.abi) {
.gnueabihf, .musleabihf, .eabihf => true,
else => false,
};
switch (target.cpu.arch) {
.riscv64 => {
const featureSetHas = std.Target.riscv.featureSetHas;
if (featureSetHas(target.cpu.features, .d)) {
return "lp64d";
} else if (have_float) {
return "lp64f";
} else {
return "lp64";
}
},
.riscv32 => {
const featureSetHas = std.Target.riscv.featureSetHas;
if (featureSetHas(target.cpu.features, .d)) {
return "ilp32d";
} else if (have_float) {
return "ilp32f";
} else if (featureSetHas(target.cpu.features, .e)) {
return "ilp32e";
} else {
return "ilp32";
}
},
//TODO add ARM, Mips, and PowerPC
else => return null,
}
}
/// This function returns 1 if function alignment is not observable or settable.
pub fn defaultFunctionAlignment(target: std.Target) Alignment {
return switch (target.cpu.arch) {
.arm, .armeb => .@"4",
.aarch64, .aarch64_be => .@"4",
.sparc, .sparc64 => .@"4",
.riscv64 => .@"2",
else => .@"1",
};
}
pub fn minFunctionAlignment(target: std.Target) Alignment {
return switch (target.cpu.arch) {
.arm,
.armeb,
.aarch64,
.aarch64_be,
.riscv32,
.riscv64,
.sparc,
.sparc64,
=> .@"2",
else => .@"1",
};
}
pub fn supportsFunctionAlignment(target: std.Target) bool {
return switch (target.cpu.arch) {
.wasm32, .wasm64 => false,
else => true,
};
}
pub fn supportsTailCall(target: std.Target, backend: std.builtin.CompilerBackend) bool {
switch (backend) {
.stage1, .stage2_llvm => return @import("codegen/llvm.zig").supportsTailCall(target),
.stage2_c => return true,
else => return false,
}
}
pub fn supportsThreads(target: std.Target, backend: std.builtin.CompilerBackend) bool {
return switch (backend) {
.stage2_x86_64 => target.ofmt == .macho or target.ofmt == .elf,
else => true,
};
}
pub fn libcFloatPrefix(float_bits: u16) []const u8 {
return switch (float_bits) {
16, 80 => "__",
32, 64, 128 => "",
else => unreachable,
};
}
pub fn libcFloatSuffix(float_bits: u16) []const u8 {
return switch (float_bits) {
16 => "h", // Non-standard
32 => "f",
64 => "",
80 => "x", // Non-standard
128 => "q", // Non-standard (mimics convention in GCC libquadmath)
else => unreachable,
};
}
pub fn compilerRtFloatAbbrev(float_bits: u16) []const u8 {
return switch (float_bits) {
16 => "h",
32 => "s",
64 => "d",
80 => "x",
128 => "t",
else => unreachable,
};
}
pub fn compilerRtIntAbbrev(bits: u16) []const u8 {
return switch (bits) {
16 => "h",
32 => "s",
64 => "d",
128 => "t",
else => "o", // Non-standard
};
}
pub fn fnCallConvAllowsZigTypes(target: std.Target, cc: std.builtin.CallingConvention) bool {
return switch (cc) {
.Unspecified, .Async, .Inline => true,
// For now we want to authorize PTX kernel to use zig objects, even if
// we end up exposing the ABI. The goal is to experiment with more
// integrated CPU/GPU code.
.Kernel => target.cpu.arch == .nvptx or target.cpu.arch == .nvptx64,
else => false,
};
}
pub fn zigBackend(target: std.Target, use_llvm: bool) std.builtin.CompilerBackend {
if (use_llvm) return .stage2_llvm;
if (target.ofmt == .c) return .stage2_c;
return switch (target.cpu.arch) {
.wasm32, .wasm64 => .stage2_wasm,
.arm, .armeb, .thumb, .thumbeb => .stage2_arm,
.x86_64 => .stage2_x86_64,
.x86 => .stage2_x86,
.aarch64, .aarch64_be => .stage2_aarch64,
.riscv64 => .stage2_riscv64,
.sparc64 => .stage2_sparc64,
.spirv64 => .stage2_spirv64,
else => .other,
};
}
pub inline fn backendSupportsFeature(backend: std.builtin.CompilerBackend, comptime feature: Feature) bool {
return switch (feature) {
.panic_fn => switch (backend) {
.stage2_c,
.stage2_llvm,
.stage2_x86_64,
.stage2_riscv64,
=> true,
else => false,
},
.panic_unwrap_error => switch (backend) {
.stage2_c, .stage2_llvm => true,
else => false,
},
.safety_check_formatted => switch (backend) {
.stage2_c, .stage2_llvm => true,
else => false,
},
.error_return_trace => switch (backend) {
.stage2_llvm => true,
else => false,
},
.is_named_enum_value => switch (backend) {
.stage2_llvm => true,
else => false,
},
.error_set_has_value => switch (backend) {
.stage2_llvm, .stage2_wasm => true,
else => false,
},
.field_reordering => switch (backend) {
.stage2_c, .stage2_llvm => true,
else => false,
},
.safety_checked_instructions => switch (backend) {
.stage2_llvm => true,
else => false,
},
.separate_thread => switch (backend) {
.stage2_llvm => false,
else => true,
},
};
}
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