344 lines
9.0 KiB
Zig
344 lines
9.0 KiB
Zig
const std = @import("../std.zig");
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const builtin = std.builtin;
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const mem = std.mem;
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const debug = std.debug;
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const testing = std.testing;
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const warn = debug.warn;
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const meta = @import("../meta.zig");
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pub const TraitFn = fn (type) bool;
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//////Trait generators
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// TODO convert to tuples when #4335 is done
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pub const TraitList = []const TraitFn;
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pub fn multiTrait(comptime traits: TraitList) TraitFn {
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const Closure = struct {
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pub fn trait(comptime T: type) bool {
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inline for (traits) |t|
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if (!t(T)) return false;
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return true;
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}
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};
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return Closure.trait;
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}
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test "std.meta.trait.multiTrait" {
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const Vector2 = struct {
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const MyType = @This();
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x: u8,
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y: u8,
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pub fn add(self: MyType, other: MyType) MyType {
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return MyType{
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.x = self.x + other.x,
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.y = self.y + other.y,
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};
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}
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};
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const isVector = multiTrait(&[_]TraitFn{
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hasFn("add"),
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hasField("x"),
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hasField("y"),
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});
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testing.expect(isVector(Vector2));
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testing.expect(!isVector(u8));
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}
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pub fn hasFn(comptime name: []const u8) TraitFn {
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const Closure = struct {
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pub fn trait(comptime T: type) bool {
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if (!comptime isContainer(T)) return false;
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if (!comptime @hasDecl(T, name)) return false;
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const DeclType = @TypeOf(@field(T, name));
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return @typeInfo(DeclType) == .Fn;
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}
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};
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return Closure.trait;
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}
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test "std.meta.trait.hasFn" {
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const TestStruct = struct {
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pub fn useless() void {}
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};
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testing.expect(hasFn("useless")(TestStruct));
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testing.expect(!hasFn("append")(TestStruct));
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testing.expect(!hasFn("useless")(u8));
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}
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pub fn hasField(comptime name: []const u8) TraitFn {
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const Closure = struct {
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pub fn trait(comptime T: type) bool {
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const fields = switch (@typeInfo(T)) {
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.Struct => |s| s.fields,
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.Union => |u| u.fields,
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.Enum => |e| e.fields,
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else => return false,
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};
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inline for (fields) |field| {
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if (mem.eql(u8, field.name, name)) return true;
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}
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return false;
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}
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};
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return Closure.trait;
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}
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test "std.meta.trait.hasField" {
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const TestStruct = struct {
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value: u32,
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};
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testing.expect(hasField("value")(TestStruct));
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testing.expect(!hasField("value")(*TestStruct));
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testing.expect(!hasField("x")(TestStruct));
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testing.expect(!hasField("x")(**TestStruct));
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testing.expect(!hasField("value")(u8));
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}
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pub fn is(comptime id: builtin.TypeId) TraitFn {
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const Closure = struct {
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pub fn trait(comptime T: type) bool {
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return id == @typeInfo(T);
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}
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};
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return Closure.trait;
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}
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test "std.meta.trait.is" {
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testing.expect(is(.Int)(u8));
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testing.expect(!is(.Int)(f32));
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testing.expect(is(.Pointer)(*u8));
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testing.expect(is(.Void)(void));
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testing.expect(!is(.Optional)(anyerror));
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}
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pub fn isPtrTo(comptime id: builtin.TypeId) TraitFn {
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const Closure = struct {
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pub fn trait(comptime T: type) bool {
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if (!comptime isSingleItemPtr(T)) return false;
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return id == @typeInfo(meta.Child(T));
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}
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};
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return Closure.trait;
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}
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test "std.meta.trait.isPtrTo" {
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testing.expect(!isPtrTo(.Struct)(struct {}));
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testing.expect(isPtrTo(.Struct)(*struct {}));
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testing.expect(!isPtrTo(.Struct)(**struct {}));
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}
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pub fn isSliceOf(comptime id: builtin.TypeId) TraitFn {
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const Closure = struct {
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pub fn trait(comptime T: type) bool {
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if (!comptime isSlice(T)) return false;
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return id == @typeInfo(meta.Child(T));
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}
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};
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return Closure.trait;
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}
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test "std.meta.trait.isSliceOf" {
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testing.expect(!isSliceOf(.Struct)(struct {}));
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testing.expect(isSliceOf(.Struct)([]struct {}));
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testing.expect(!isSliceOf(.Struct)([][]struct {}));
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}
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///////////Strait trait Fns
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//@TODO:
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// Somewhat limited since we can't apply this logic to normal variables, fields, or
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// Fns yet. Should be isExternType?
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pub fn isExtern(comptime T: type) bool {
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return switch (@typeInfo(T)) {
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.Struct => |s| s.layout == .Extern,
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.Union => |u| u.layout == .Extern,
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.Enum => |e| e.layout == .Extern,
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else => false,
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};
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}
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test "std.meta.trait.isExtern" {
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const TestExStruct = extern struct {};
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const TestStruct = struct {};
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testing.expect(isExtern(TestExStruct));
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testing.expect(!isExtern(TestStruct));
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testing.expect(!isExtern(u8));
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}
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pub fn isPacked(comptime T: type) bool {
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return switch (@typeInfo(T)) {
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.Struct => |s| s.layout == .Packed,
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.Union => |u| u.layout == .Packed,
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.Enum => |e| e.layout == .Packed,
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else => false,
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};
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}
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test "std.meta.trait.isPacked" {
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const TestPStruct = packed struct {};
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const TestStruct = struct {};
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testing.expect(isPacked(TestPStruct));
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testing.expect(!isPacked(TestStruct));
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testing.expect(!isPacked(u8));
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}
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pub fn isUnsignedInt(comptime T: type) bool {
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return switch (@typeInfo(T)) {
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.Int => |i| !i.is_signed,
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else => false,
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};
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}
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test "isUnsignedInt" {
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testing.expect(isUnsignedInt(u32) == true);
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testing.expect(isUnsignedInt(comptime_int) == false);
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testing.expect(isUnsignedInt(i64) == false);
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testing.expect(isUnsignedInt(f64) == false);
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}
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pub fn isSignedInt(comptime T: type) bool {
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return switch (@typeInfo(T)) {
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.ComptimeInt => true,
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.Int => |i| i.is_signed,
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else => false,
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};
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}
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test "isSignedInt" {
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testing.expect(isSignedInt(u32) == false);
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testing.expect(isSignedInt(comptime_int) == true);
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testing.expect(isSignedInt(i64) == true);
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testing.expect(isSignedInt(f64) == false);
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}
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pub fn isSingleItemPtr(comptime T: type) bool {
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if (comptime is(.Pointer)(T)) {
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return @typeInfo(T).Pointer.size == .One;
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}
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return false;
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}
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test "std.meta.trait.isSingleItemPtr" {
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const array = [_]u8{0} ** 10;
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testing.expect(isSingleItemPtr(@TypeOf(&array[0])));
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testing.expect(!isSingleItemPtr(@TypeOf(array)));
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testing.expect(!isSingleItemPtr(@TypeOf(array[0..1])));
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}
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pub fn isManyItemPtr(comptime T: type) bool {
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if (comptime is(.Pointer)(T)) {
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return @typeInfo(T).Pointer.size == .Many;
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}
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return false;
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}
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test "std.meta.trait.isManyItemPtr" {
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const array = [_]u8{0} ** 10;
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const mip = @ptrCast([*]const u8, &array[0]);
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testing.expect(isManyItemPtr(@TypeOf(mip)));
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testing.expect(!isManyItemPtr(@TypeOf(array)));
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testing.expect(!isManyItemPtr(@TypeOf(array[0..1])));
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}
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pub fn isSlice(comptime T: type) bool {
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if (comptime is(.Pointer)(T)) {
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return @typeInfo(T).Pointer.size == .Slice;
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}
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return false;
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}
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test "std.meta.trait.isSlice" {
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const array = [_]u8{0} ** 10;
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testing.expect(isSlice(@TypeOf(array[0..])));
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testing.expect(!isSlice(@TypeOf(array)));
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testing.expect(!isSlice(@TypeOf(&array[0])));
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}
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pub fn isIndexable(comptime T: type) bool {
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if (comptime is(.Pointer)(T)) {
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if (@typeInfo(T).Pointer.size == .One) {
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return (comptime is(.Array)(meta.Child(T)));
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}
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return true;
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}
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return comptime is(.Array)(T);
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}
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test "std.meta.trait.isIndexable" {
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const array = [_]u8{0} ** 10;
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const slice = array[0..];
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testing.expect(isIndexable(@TypeOf(array)));
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testing.expect(isIndexable(@TypeOf(&array)));
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testing.expect(isIndexable(@TypeOf(slice)));
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testing.expect(!isIndexable(meta.Child(@TypeOf(slice))));
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}
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pub fn isNumber(comptime T: type) bool {
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return switch (@typeInfo(T)) {
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.Int, .Float, .ComptimeInt, .ComptimeFloat => true,
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else => false,
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};
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}
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test "std.meta.trait.isNumber" {
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const NotANumber = struct {
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number: u8,
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};
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testing.expect(isNumber(u32));
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testing.expect(isNumber(f32));
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testing.expect(isNumber(u64));
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testing.expect(isNumber(@TypeOf(102)));
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testing.expect(isNumber(@TypeOf(102.123)));
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testing.expect(!isNumber([]u8));
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testing.expect(!isNumber(NotANumber));
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}
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pub fn isConstPtr(comptime T: type) bool {
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if (!comptime is(.Pointer)(T)) return false;
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return @typeInfo(T).Pointer.is_const;
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}
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test "std.meta.trait.isConstPtr" {
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var t = @as(u8, 0);
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const c = @as(u8, 0);
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testing.expect(isConstPtr(*const @TypeOf(t)));
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testing.expect(isConstPtr(@TypeOf(&c)));
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testing.expect(!isConstPtr(*@TypeOf(t)));
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testing.expect(!isConstPtr(@TypeOf(6)));
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}
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pub fn isContainer(comptime T: type) bool {
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return switch (@typeInfo(T)) {
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.Struct, .Union, .Enum => true,
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else => false,
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};
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}
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test "std.meta.trait.isContainer" {
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const TestStruct = struct {};
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const TestUnion = union {
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a: void,
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};
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const TestEnum = enum {
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A,
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B,
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};
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testing.expect(isContainer(TestStruct));
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testing.expect(isContainer(TestUnion));
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testing.expect(isContainer(TestEnum));
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testing.expect(!isContainer(u8));
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}
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