const std = @import("std.zig"); const builtin = @import("builtin"); const debug = std.debug; const mem = std.mem; const math = std.math; const testing = std.testing; pub const trait = @import("meta/trait.zig"); const TypeInfo = builtin.TypeInfo; pub fn tagName(v: var) []const u8 { const T = @TypeOf(v); switch (@typeInfo(T)) { .ErrorSet => return @errorName(v), else => return @tagName(v), } } test "std.meta.tagName" { const E1 = enum { A, B, }; const E2 = enum(u8) { C = 33, D, }; const U1 = union(enum) { G: u8, H: u16, }; const U2 = union(E2) { C: u8, D: u16, }; var u1g = U1{ .G = 0 }; var u1h = U1{ .H = 0 }; var u2a = U2{ .C = 0 }; var u2b = U2{ .D = 0 }; testing.expect(mem.eql(u8, tagName(E1.A), "A")); testing.expect(mem.eql(u8, tagName(E1.B), "B")); testing.expect(mem.eql(u8, tagName(E2.C), "C")); testing.expect(mem.eql(u8, tagName(E2.D), "D")); testing.expect(mem.eql(u8, tagName(error.E), "E")); testing.expect(mem.eql(u8, tagName(error.F), "F")); testing.expect(mem.eql(u8, tagName(u1g), "G")); testing.expect(mem.eql(u8, tagName(u1h), "H")); testing.expect(mem.eql(u8, tagName(u2a), "C")); testing.expect(mem.eql(u8, tagName(u2b), "D")); } pub fn stringToEnum(comptime T: type, str: []const u8) ?T { // Using ComptimeStringMap here is more performant, but it will start to take too // long to compile if the enum is large enough, due to the current limits of comptime // performance when doing things like constructing lookup maps at comptime. // TODO The '100' here is arbitrary and should be increased when possible: // - https://github.com/ziglang/zig/issues/4055 // - https://github.com/ziglang/zig/issues/3863 if (@typeInfo(T).Enum.fields.len <= 100) { const kvs = comptime build_kvs: { // In order to generate an array of structs that play nice with anonymous // list literals, we need to give them "0" and "1" field names. // TODO https://github.com/ziglang/zig/issues/4335 const EnumKV = struct { @"0": []const u8, @"1": T, }; var kvs_array: [@typeInfo(T).Enum.fields.len]EnumKV = undefined; inline for (@typeInfo(T).Enum.fields) |enumField, i| { kvs_array[i] = .{ .@"0" = enumField.name, .@"1" = @field(T, enumField.name) }; } break :build_kvs kvs_array[0..]; }; const map = std.ComptimeStringMap(T, kvs); return map.get(str); } else { inline for (@typeInfo(T).Enum.fields) |enumField| { if (mem.eql(u8, str, enumField.name)) { return @field(T, enumField.name); } } return null; } } test "std.meta.stringToEnum" { const E1 = enum { A, B, }; testing.expect(E1.A == stringToEnum(E1, "A").?); testing.expect(E1.B == stringToEnum(E1, "B").?); testing.expect(null == stringToEnum(E1, "C")); } pub fn bitCount(comptime T: type) comptime_int { return switch (@typeInfo(T)) { .Bool => 1, .Int => |info| info.bits, .Float => |info| info.bits, else => @compileError("Expected bool, int or float type, found '" ++ @typeName(T) ++ "'"), }; } test "std.meta.bitCount" { testing.expect(bitCount(u8) == 8); testing.expect(bitCount(f32) == 32); } pub fn alignment(comptime T: type) comptime_int { //@alignOf works on non-pointer types const P = if (comptime trait.is(.Pointer)(T)) T else *T; return @typeInfo(P).Pointer.alignment; } test "std.meta.alignment" { testing.expect(alignment(u8) == 1); testing.expect(alignment(*align(1) u8) == 1); testing.expect(alignment(*align(2) u8) == 2); testing.expect(alignment([]align(1) u8) == 1); testing.expect(alignment([]align(2) u8) == 2); } pub fn Child(comptime T: type) type { return switch (@typeInfo(T)) { .Array => |info| info.child, .Vector => |info| info.child, .Pointer => |info| info.child, .Optional => |info| info.child, else => @compileError("Expected pointer, optional, array or vector type, found '" ++ @typeName(T) ++ "'"), }; } test "std.meta.Child" { testing.expect(Child([1]u8) == u8); testing.expect(Child(*u8) == u8); testing.expect(Child([]u8) == u8); testing.expect(Child(?u8) == u8); testing.expect(Child(Vector(2, u8)) == u8); } /// Given a "memory span" type, returns the "element type". pub fn Elem(comptime T: type) type { switch (@typeInfo(T)) { .Array, => |info| return info.child, .Vector, => |info| return info.child, .Pointer => |info| switch (info.size) { .One => switch (@typeInfo(info.child)) { .Array => |array_info| return array_info.child, .Vector => |vector_info| return vector_info.child, else => {}, }, .Many, .C, .Slice => return info.child, }, else => {}, } @compileError("Expected pointer, slice, array or vector type, found '" ++ @typeName(T) ++ "'"); } test "std.meta.Elem" { testing.expect(Elem([1]u8) == u8); testing.expect(Elem([*]u8) == u8); testing.expect(Elem([]u8) == u8); testing.expect(Elem(*[10]u8) == u8); testing.expect(Elem(Vector(2, u8)) == u8); testing.expect(Elem(*Vector(2, u8)) == u8); } /// Given a type which can have a sentinel e.g. `[:0]u8`, returns the sentinel value, /// or `null` if there is not one. /// Types which cannot possibly have a sentinel will be a compile error. pub fn sentinel(comptime T: type) ?Elem(T) { switch (@typeInfo(T)) { .Array => |info| return info.sentinel, .Pointer => |info| { switch (info.size) { .Many, .Slice => return info.sentinel, .One => switch (@typeInfo(info.child)) { .Array => |array_info| return array_info.sentinel, else => {}, }, else => {}, } }, else => {}, } @compileError("type '" ++ @typeName(T) ++ "' cannot possibly have a sentinel"); } test "std.meta.sentinel" { testSentinel(); comptime testSentinel(); } fn testSentinel() void { testing.expectEqual(@as(u8, 0), sentinel([:0]u8).?); testing.expectEqual(@as(u8, 0), sentinel([*:0]u8).?); testing.expectEqual(@as(u8, 0), sentinel([5:0]u8).?); testing.expectEqual(@as(u8, 0), sentinel(*const [5:0]u8).?); testing.expect(sentinel([]u8) == null); testing.expect(sentinel([*]u8) == null); testing.expect(sentinel([5]u8) == null); testing.expect(sentinel(*const [5]u8) == null); } pub fn containerLayout(comptime T: type) TypeInfo.ContainerLayout { return switch (@typeInfo(T)) { .Struct => |info| info.layout, .Enum => |info| info.layout, .Union => |info| info.layout, else => @compileError("Expected struct, enum or union type, found '" ++ @typeName(T) ++ "'"), }; } test "std.meta.containerLayout" { const E1 = enum { A, }; const E2 = packed enum { A, }; const E3 = extern enum { A, }; const S1 = struct {}; const S2 = packed struct {}; const S3 = extern struct {}; const U1 = union { a: u8, }; const U2 = packed union { a: u8, }; const U3 = extern union { a: u8, }; testing.expect(containerLayout(E1) == .Auto); testing.expect(containerLayout(E2) == .Packed); testing.expect(containerLayout(E3) == .Extern); testing.expect(containerLayout(S1) == .Auto); testing.expect(containerLayout(S2) == .Packed); testing.expect(containerLayout(S3) == .Extern); testing.expect(containerLayout(U1) == .Auto); testing.expect(containerLayout(U2) == .Packed); testing.expect(containerLayout(U3) == .Extern); } pub fn declarations(comptime T: type) []TypeInfo.Declaration { return switch (@typeInfo(T)) { .Struct => |info| info.decls, .Enum => |info| info.decls, .Union => |info| info.decls, else => @compileError("Expected struct, enum or union type, found '" ++ @typeName(T) ++ "'"), }; } test "std.meta.declarations" { const E1 = enum { A, fn a() void {} }; const S1 = struct { fn a() void {} }; const U1 = union { a: u8, fn a() void {} }; const decls = comptime [_][]TypeInfo.Declaration{ declarations(E1), declarations(S1), declarations(U1), }; inline for (decls) |decl| { testing.expect(decl.len == 1); testing.expect(comptime mem.eql(u8, decl[0].name, "a")); } } pub fn declarationInfo(comptime T: type, comptime decl_name: []const u8) TypeInfo.Declaration { inline for (comptime declarations(T)) |decl| { if (comptime mem.eql(u8, decl.name, decl_name)) return decl; } @compileError("'" ++ @typeName(T) ++ "' has no declaration '" ++ decl_name ++ "'"); } test "std.meta.declarationInfo" { const E1 = enum { A, fn a() void {} }; const S1 = struct { fn a() void {} }; const U1 = union { a: u8, fn a() void {} }; const infos = comptime [_]TypeInfo.Declaration{ declarationInfo(E1, "a"), declarationInfo(S1, "a"), declarationInfo(U1, "a"), }; inline for (infos) |info| { testing.expect(comptime mem.eql(u8, info.name, "a")); testing.expect(!info.is_pub); } } pub fn fields(comptime T: type) switch (@typeInfo(T)) { .Struct => []TypeInfo.StructField, .Union => []TypeInfo.UnionField, .ErrorSet => []TypeInfo.Error, .Enum => []TypeInfo.EnumField, else => @compileError("Expected struct, union, error set or enum type, found '" ++ @typeName(T) ++ "'"), } { return switch (@typeInfo(T)) { .Struct => |info| info.fields, .Union => |info| info.fields, .Enum => |info| info.fields, .ErrorSet => |errors| errors.?, // must be non global error set else => @compileError("Expected struct, union, error set or enum type, found '" ++ @typeName(T) ++ "'"), }; } test "std.meta.fields" { const E1 = enum { A, }; const E2 = error{A}; const S1 = struct { a: u8, }; const U1 = union { a: u8, }; const e1f = comptime fields(E1); const e2f = comptime fields(E2); const sf = comptime fields(S1); const uf = comptime fields(U1); testing.expect(e1f.len == 1); testing.expect(e2f.len == 1); testing.expect(sf.len == 1); testing.expect(uf.len == 1); testing.expect(mem.eql(u8, e1f[0].name, "A")); testing.expect(mem.eql(u8, e2f[0].name, "A")); testing.expect(mem.eql(u8, sf[0].name, "a")); testing.expect(mem.eql(u8, uf[0].name, "a")); testing.expect(comptime sf[0].field_type == u8); testing.expect(comptime uf[0].field_type == u8); } pub fn fieldInfo(comptime T: type, comptime field_name: []const u8) switch (@typeInfo(T)) { .Struct => TypeInfo.StructField, .Union => TypeInfo.UnionField, .ErrorSet => TypeInfo.Error, .Enum => TypeInfo.EnumField, else => @compileError("Expected struct, union, error set or enum type, found '" ++ @typeName(T) ++ "'"), } { inline for (comptime fields(T)) |field| { if (comptime mem.eql(u8, field.name, field_name)) return field; } @compileError("'" ++ @typeName(T) ++ "' has no field '" ++ field_name ++ "'"); } test "std.meta.fieldInfo" { const E1 = enum { A, }; const E2 = error{A}; const S1 = struct { a: u8, }; const U1 = union { a: u8, }; const e1f = comptime fieldInfo(E1, "A"); const e2f = comptime fieldInfo(E2, "A"); const sf = comptime fieldInfo(S1, "a"); const uf = comptime fieldInfo(U1, "a"); testing.expect(mem.eql(u8, e1f.name, "A")); testing.expect(mem.eql(u8, e2f.name, "A")); testing.expect(mem.eql(u8, sf.name, "a")); testing.expect(mem.eql(u8, uf.name, "a")); testing.expect(comptime sf.field_type == u8); testing.expect(comptime uf.field_type == u8); } pub fn TagType(comptime T: type) type { return switch (@typeInfo(T)) { .Enum => |info| info.tag_type, .Union => |info| if (info.tag_type) |Tag| Tag else null, else => @compileError("expected enum or union type, found '" ++ @typeName(T) ++ "'"), }; } test "std.meta.TagType" { const E = enum(u8) { C = 33, D, }; const U = union(E) { C: u8, D: u16, }; testing.expect(TagType(E) == u8); testing.expect(TagType(U) == E); } ///Returns the active tag of a tagged union pub fn activeTag(u: var) @TagType(@TypeOf(u)) { const T = @TypeOf(u); return @as(@TagType(T), u); } test "std.meta.activeTag" { const UE = enum { Int, Float, }; const U = union(UE) { Int: u32, Float: f32, }; var u = U{ .Int = 32 }; testing.expect(activeTag(u) == UE.Int); u = U{ .Float = 112.9876 }; testing.expect(activeTag(u) == UE.Float); } ///Given a tagged union type, and an enum, return the type of the union /// field corresponding to the enum tag. pub fn TagPayloadType(comptime U: type, tag: @TagType(U)) type { testing.expect(trait.is(.Union)(U)); const info = @typeInfo(U).Union; inline for (info.fields) |field_info| { if (field_info.enum_field.?.value == @enumToInt(tag)) return field_info.field_type; } unreachable; } test "std.meta.TagPayloadType" { const Event = union(enum) { Moved: struct { from: i32, to: i32, }, }; const MovedEvent = TagPayloadType(Event, Event.Moved); var e: Event = undefined; testing.expect(MovedEvent == @TypeOf(e.Moved)); } /// Compares two of any type for equality. Containers are compared on a field-by-field basis, /// where possible. Pointers are not followed. pub fn eql(a: var, b: @TypeOf(a)) bool { const T = @TypeOf(a); switch (@typeInfo(T)) { .Struct => |info| { inline for (info.fields) |field_info| { if (!eql(@field(a, field_info.name), @field(b, field_info.name))) return false; } return true; }, .ErrorUnion => { if (a) |a_p| { if (b) |b_p| return eql(a_p, b_p) else |_| return false; } else |a_e| { if (b) |_| return false else |b_e| return a_e == b_e; } }, .Union => |info| { if (info.tag_type) |_| { const tag_a = activeTag(a); const tag_b = activeTag(b); if (tag_a != tag_b) return false; inline for (info.fields) |field_info| { const enum_field = field_info.enum_field.?; if (enum_field.value == @enumToInt(tag_a)) { return eql(@field(a, enum_field.name), @field(b, enum_field.name)); } } return false; } @compileError("cannot compare untagged union type " ++ @typeName(T)); }, .Array => { if (a.len != b.len) return false; for (a) |e, i| if (!eql(e, b[i])) return false; return true; }, .Vector => |info| { var i: usize = 0; while (i < info.len) : (i += 1) { if (!eql(a[i], b[i])) return false; } return true; }, .Pointer => |info| { return switch (info.size) { .One, .Many, .C => a == b, .Slice => a.ptr == b.ptr and a.len == b.len, }; }, .Optional => { if (a == null and b == null) return true; if (a == null or b == null) return false; return eql(a.?, b.?); }, else => return a == b, } } test "std.meta.eql" { const S = struct { a: u32, b: f64, c: [5]u8, }; const U = union(enum) { s: S, f: ?f32, }; const s_1 = S{ .a = 134, .b = 123.3, .c = "12345".*, }; const s_2 = S{ .a = 1, .b = 123.3, .c = "54321".*, }; const s_3 = S{ .a = 134, .b = 123.3, .c = "12345".*, }; const u_1 = U{ .f = 24 }; const u_2 = U{ .s = s_1 }; const u_3 = U{ .f = 24 }; testing.expect(eql(s_1, s_3)); testing.expect(eql(&s_1, &s_1)); testing.expect(!eql(&s_1, &s_3)); testing.expect(eql(u_1, u_3)); testing.expect(!eql(u_1, u_2)); var a1 = "abcdef".*; var a2 = "abcdef".*; var a3 = "ghijkl".*; testing.expect(eql(a1, a2)); testing.expect(!eql(a1, a3)); testing.expect(!eql(a1[0..], a2[0..])); const EU = struct { fn tst(err: bool) !u8 { if (err) return error.Error; return @as(u8, 5); } }; testing.expect(eql(EU.tst(true), EU.tst(true))); testing.expect(eql(EU.tst(false), EU.tst(false))); testing.expect(!eql(EU.tst(false), EU.tst(true))); var v1 = @splat(4, @as(u32, 1)); var v2 = @splat(4, @as(u32, 1)); var v3 = @splat(4, @as(u32, 2)); testing.expect(eql(v1, v2)); testing.expect(!eql(v1, v3)); } test "intToEnum with error return" { const E1 = enum { A, }; const E2 = enum { A, B, }; var zero: u8 = 0; var one: u16 = 1; testing.expect(intToEnum(E1, zero) catch unreachable == E1.A); testing.expect(intToEnum(E2, one) catch unreachable == E2.B); testing.expectError(error.InvalidEnumTag, intToEnum(E1, one)); } pub const IntToEnumError = error{InvalidEnumTag}; pub fn intToEnum(comptime Tag: type, tag_int: var) IntToEnumError!Tag { inline for (@typeInfo(Tag).Enum.fields) |f| { const this_tag_value = @field(Tag, f.name); if (tag_int == @enumToInt(this_tag_value)) { return this_tag_value; } } return error.InvalidEnumTag; } /// Given a type and a name, return the field index according to source order. /// Returns `null` if the field is not found. pub fn fieldIndex(comptime T: type, comptime name: []const u8) ?comptime_int { inline for (fields(T)) |field, i| { if (mem.eql(u8, field.name, name)) return i; } return null; } /// Given a type, reference all the declarations inside, so that the semantic analyzer sees them. pub fn refAllDecls(comptime T: type) void { if (!builtin.is_test) return; inline for (declarations(T)) |decl| { _ = decl; } } /// Returns a slice of pointers to public declarations of a namespace. pub fn declList(comptime Namespace: type, comptime Decl: type) []const *const Decl { const S = struct { fn declNameLessThan(lhs: *const Decl, rhs: *const Decl) bool { return mem.lessThan(u8, lhs.name, rhs.name); } }; comptime { const decls = declarations(Namespace); var array: [decls.len]*const Decl = undefined; for (decls) |decl, i| { array[i] = &@field(Namespace, decl.name); } std.sort.sort(*const Decl, &array, S.declNameLessThan); return &array; } } /// Deprecated: use Int pub const IntType = Int; pub fn Int(comptime is_signed: bool, comptime bit_count: u16) type { return @Type(TypeInfo{ .Int = .{ .is_signed = is_signed, .bits = bit_count, }, }); } pub fn Vector(comptime len: u32, comptime child: type) type { return @Type(TypeInfo{ .Vector = .{ .len = len, .child = child, }, }); }