const builtin = @import("builtin"); const std = @import("std.zig"); const float = @import("math/float.zig"); const assert = std.debug.assert; const mem = std.mem; const testing = std.testing; /// Euler's number (e) pub const e = 2.71828182845904523536028747135266249775724709369995; /// Archimedes' constant (π) pub const pi = 3.14159265358979323846264338327950288419716939937510; /// Phi or Golden ratio constant (Φ) = (1 + sqrt(5))/2 pub const phi = 1.6180339887498948482045868343656381177203091798057628621; /// Circle constant (τ) pub const tau = 2 * pi; /// log2(e) pub const log2e = 1.442695040888963407359924681001892137; /// log10(e) pub const log10e = 0.434294481903251827651128918916605082; /// ln(2) pub const ln2 = 0.693147180559945309417232121458176568; /// ln(10) pub const ln10 = 2.302585092994045684017991454684364208; /// 2/sqrt(π) pub const two_sqrtpi = 1.128379167095512573896158903121545172; /// sqrt(2) pub const sqrt2 = 1.414213562373095048801688724209698079; /// 1/sqrt(2) pub const sqrt1_2 = 0.707106781186547524400844362104849039; /// pi/180.0 pub const rad_per_deg = 0.0174532925199432957692369076848861271344287188854172545609719144; /// 180.0/pi pub const deg_per_rad = 57.295779513082320876798154814105170332405472466564321549160243861; pub const floatExponentBits = float.floatExponentBits; pub const floatMantissaBits = float.floatMantissaBits; pub const floatFractionalBits = float.floatFractionalBits; pub const floatExponentMin = float.floatExponentMin; pub const floatExponentMax = float.floatExponentMax; pub const floatTrueMin = float.floatTrueMin; pub const floatMin = float.floatMin; pub const floatMax = float.floatMax; pub const floatEps = float.floatEps; pub const floatEpsAt = float.floatEpsAt; pub const inf = float.inf; pub const nan = float.nan; pub const snan = float.snan; /// Performs an approximate comparison of two floating point values `x` and `y`. /// Returns true if the absolute difference between them is less or equal than /// the specified tolerance. /// /// The `tolerance` parameter is the absolute tolerance used when determining if /// the two numbers are close enough; a good value for this parameter is a small /// multiple of `floatEps(T)`. /// /// Note that this function is recommended for comparing small numbers /// around zero; using `approxEqRel` is suggested otherwise. /// /// NaN values are never considered equal to any value. pub fn approxEqAbs(comptime T: type, x: T, y: T, tolerance: T) bool { assert(@typeInfo(T) == .float or @typeInfo(T) == .comptime_float); assert(tolerance >= 0); // Fast path for equal values (and signed zeros and infinites). if (x == y) return true; if (isNan(x) or isNan(y)) return false; return @abs(x - y) <= tolerance; } /// Performs an approximate comparison of two floating point values `x` and `y`. /// Returns true if the absolute difference between them is less or equal than /// `max(|x|, |y|) * tolerance`, where `tolerance` is a positive number greater /// than zero. /// /// The `tolerance` parameter is the relative tolerance used when determining if /// the two numbers are close enough; a good value for this parameter is usually /// `sqrt(floatEps(T))`, meaning that the two numbers are considered equal if at /// least half of the digits are equal. /// /// Note that for comparisons of small numbers around zero this function won't /// give meaningful results, use `approxEqAbs` instead. /// /// NaN values are never considered equal to any value. pub fn approxEqRel(comptime T: type, x: T, y: T, tolerance: T) bool { assert(@typeInfo(T) == .float or @typeInfo(T) == .comptime_float); assert(tolerance > 0); // Fast path for equal values (and signed zeros and infinites). if (x == y) return true; if (isNan(x) or isNan(y)) return false; return @abs(x - y) <= @max(@abs(x), @abs(y)) * tolerance; } test approxEqAbs { inline for ([_]type{ f16, f32, f64, f128 }) |T| { const eps_value = comptime floatEps(T); const min_value = comptime floatMin(T); try testing.expect(approxEqAbs(T, 0.0, 0.0, eps_value)); try testing.expect(approxEqAbs(T, -0.0, -0.0, eps_value)); try testing.expect(approxEqAbs(T, 0.0, -0.0, eps_value)); try testing.expect(!approxEqAbs(T, 1.0 + 2 * eps_value, 1.0, eps_value)); try testing.expect(approxEqAbs(T, 1.0 + 1 * eps_value, 1.0, eps_value)); try testing.expect(approxEqAbs(T, min_value, 0.0, eps_value * 2)); try testing.expect(approxEqAbs(T, -min_value, 0.0, eps_value * 2)); } comptime { // `comptime_float` is guaranteed to have the same precision and operations of // the largest other floating point type, which is f128 but it doesn't have a // defined layout so we can't rely on `@bitCast` to construct the smallest // possible epsilon value like we do in the tests above. In the same vein, we // also can't represent a max/min, `NaN` or `Inf` values. const eps_value = 1e-4; try testing.expect(approxEqAbs(comptime_float, 0.0, 0.0, eps_value)); try testing.expect(approxEqAbs(comptime_float, -0.0, -0.0, eps_value)); try testing.expect(approxEqAbs(comptime_float, 0.0, -0.0, eps_value)); try testing.expect(!approxEqAbs(comptime_float, 1.0 + 2 * eps_value, 1.0, eps_value)); try testing.expect(approxEqAbs(comptime_float, 1.0 + 1 * eps_value, 1.0, eps_value)); } } test approxEqRel { inline for ([_]type{ f16, f32, f64, f128 }) |T| { const eps_value = comptime floatEps(T); const sqrt_eps_value = comptime sqrt(eps_value); const nan_value = comptime nan(T); const inf_value = comptime inf(T); const min_value = comptime floatMin(T); try testing.expect(approxEqRel(T, 1.0, 1.0, sqrt_eps_value)); try testing.expect(!approxEqRel(T, 1.0, 0.0, sqrt_eps_value)); try testing.expect(!approxEqRel(T, 1.0, nan_value, sqrt_eps_value)); try testing.expect(!approxEqRel(T, nan_value, nan_value, sqrt_eps_value)); try testing.expect(approxEqRel(T, inf_value, inf_value, sqrt_eps_value)); try testing.expect(approxEqRel(T, min_value, min_value, sqrt_eps_value)); try testing.expect(approxEqRel(T, -min_value, -min_value, sqrt_eps_value)); } comptime { // `comptime_float` is guaranteed to have the same precision and operations of // the largest other floating point type, which is f128 but it doesn't have a // defined layout so we can't rely on `@bitCast` to construct the smallest // possible epsilon value like we do in the tests above. In the same vein, we // also can't represent a max/min, `NaN` or `Inf` values. const eps_value = 1e-4; const sqrt_eps_value = sqrt(eps_value); try testing.expect(approxEqRel(comptime_float, 1.0, 1.0, sqrt_eps_value)); try testing.expect(!approxEqRel(comptime_float, 1.0, 0.0, sqrt_eps_value)); } } pub fn raiseInvalid() void { // Raise INVALID fpu exception } pub fn raiseUnderflow() void { // Raise UNDERFLOW fpu exception } pub fn raiseOverflow() void { // Raise OVERFLOW fpu exception } pub fn raiseInexact() void { // Raise INEXACT fpu exception } pub fn raiseDivByZero() void { // Raise INEXACT fpu exception } pub const isNan = @import("math/isnan.zig").isNan; pub const isSignalNan = @import("math/isnan.zig").isSignalNan; pub const frexp = @import("math/frexp.zig").frexp; pub const Frexp = @import("math/frexp.zig").Frexp; pub const modf = @import("math/modf.zig").modf; pub const Modf = @import("math/modf.zig").Modf; pub const copysign = @import("math/copysign.zig").copysign; pub const isFinite = @import("math/isfinite.zig").isFinite; pub const isInf = @import("math/isinf.zig").isInf; pub const isPositiveInf = @import("math/isinf.zig").isPositiveInf; pub const isNegativeInf = @import("math/isinf.zig").isNegativeInf; pub const isPositiveZero = @import("math/iszero.zig").isPositiveZero; pub const isNegativeZero = @import("math/iszero.zig").isNegativeZero; pub const isNormal = @import("math/isnormal.zig").isNormal; pub const nextAfter = @import("math/nextafter.zig").nextAfter; pub const signbit = @import("math/signbit.zig").signbit; pub const scalbn = @import("math/scalbn.zig").scalbn; pub const ldexp = @import("math/ldexp.zig").ldexp; pub const pow = @import("math/pow.zig").pow; pub const powi = @import("math/powi.zig").powi; pub const sqrt = @import("math/sqrt.zig").sqrt; pub const cbrt = @import("math/cbrt.zig").cbrt; pub const acos = @import("math/acos.zig").acos; pub const asin = @import("math/asin.zig").asin; pub const atan = @import("math/atan.zig").atan; pub const atan2 = @import("math/atan2.zig").atan2; pub const hypot = @import("math/hypot.zig").hypot; pub const expm1 = @import("math/expm1.zig").expm1; pub const ilogb = @import("math/ilogb.zig").ilogb; pub const log = @import("math/log.zig").log; pub const log2 = @import("math/log2.zig").log2; pub const log10 = @import("math/log10.zig").log10; pub const log10_int = @import("math/log10.zig").log10_int; pub const log_int = @import("math/log_int.zig").log_int; pub const log1p = @import("math/log1p.zig").log1p; pub const asinh = @import("math/asinh.zig").asinh; pub const acosh = @import("math/acosh.zig").acosh; pub const atanh = @import("math/atanh.zig").atanh; pub const sinh = @import("math/sinh.zig").sinh; pub const cosh = @import("math/cosh.zig").cosh; pub const tanh = @import("math/tanh.zig").tanh; pub const gcd = @import("math/gcd.zig").gcd; pub const gamma = @import("math/gamma.zig").gamma; pub const lgamma = @import("math/gamma.zig").lgamma; /// Sine trigonometric function on a floating point number. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @sin pub inline fn sin(value: anytype) @TypeOf(value) { return @sin(value); } /// Cosine trigonometric function on a floating point number. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @cos pub inline fn cos(value: anytype) @TypeOf(value) { return @cos(value); } /// Tangent trigonometric function on a floating point number. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @tan pub inline fn tan(value: anytype) @TypeOf(value) { return @tan(value); } /// Converts an angle in radians to degrees. T must be a float or comptime number or a vector of floats. pub fn radiansToDegrees(ang: anytype) if (@TypeOf(ang) == comptime_int) comptime_float else @TypeOf(ang) { const T = @TypeOf(ang); switch (@typeInfo(T)) { .float, .comptime_float, .comptime_int => return ang * deg_per_rad, .vector => |V| if (@typeInfo(V.child) == .float) return ang * @as(T, @splat(deg_per_rad)), else => {}, } @compileError("Input must be float or a comptime number, or a vector of floats."); } test radiansToDegrees { const zero: f32 = 0; const half_pi: f32 = pi / 2.0; const neg_quart_pi: f32 = -pi / 4.0; const one_pi: f32 = pi; const two_pi: f32 = 2.0 * pi; try std.testing.expectApproxEqAbs(@as(f32, 0), radiansToDegrees(zero), 1e-6); try std.testing.expectApproxEqAbs(@as(f32, 90), radiansToDegrees(half_pi), 1e-6); try std.testing.expectApproxEqAbs(@as(f32, -45), radiansToDegrees(neg_quart_pi), 1e-6); try std.testing.expectApproxEqAbs(@as(f32, 180), radiansToDegrees(one_pi), 1e-6); try std.testing.expectApproxEqAbs(@as(f32, 360), radiansToDegrees(two_pi), 1e-6); const result = radiansToDegrees(@Vector(4, f32){ half_pi, neg_quart_pi, one_pi, two_pi, }); try std.testing.expectApproxEqAbs(@as(f32, 90), result[0], 1e-6); try std.testing.expectApproxEqAbs(@as(f32, -45), result[1], 1e-6); try std.testing.expectApproxEqAbs(@as(f32, 180), result[2], 1e-6); try std.testing.expectApproxEqAbs(@as(f32, 360), result[3], 1e-6); } /// Converts an angle in degrees to radians. T must be a float or comptime number or a vector of floats. pub fn degreesToRadians(ang: anytype) if (@TypeOf(ang) == comptime_int) comptime_float else @TypeOf(ang) { const T = @TypeOf(ang); switch (@typeInfo(T)) { .float, .comptime_float, .comptime_int => return ang * rad_per_deg, .vector => |V| if (@typeInfo(V.child) == .float) return ang * @as(T, @splat(rad_per_deg)), else => {}, } @compileError("Input must be float or a comptime number, or a vector of floats."); } test degreesToRadians { const ninety: f32 = 90; const neg_two_seventy: f32 = -270; const three_sixty: f32 = 360; try std.testing.expectApproxEqAbs(@as(f32, pi / 2.0), degreesToRadians(ninety), 1e-6); try std.testing.expectApproxEqAbs(@as(f32, -3 * pi / 2.0), degreesToRadians(neg_two_seventy), 1e-6); try std.testing.expectApproxEqAbs(@as(f32, 2 * pi), degreesToRadians(three_sixty), 1e-6); const result = degreesToRadians(@Vector(3, f32){ ninety, neg_two_seventy, three_sixty, }); try std.testing.expectApproxEqAbs(@as(f32, pi / 2.0), result[0], 1e-6); try std.testing.expectApproxEqAbs(@as(f32, -3 * pi / 2.0), result[1], 1e-6); try std.testing.expectApproxEqAbs(@as(f32, 2 * pi), result[2], 1e-6); } /// Base-e exponential function on a floating point number. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @exp pub inline fn exp(value: anytype) @TypeOf(value) { return @exp(value); } /// Base-2 exponential function on a floating point number. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @exp2 pub inline fn exp2(value: anytype) @TypeOf(value) { return @exp2(value); } pub const complex = @import("math/complex.zig"); pub const Complex = complex.Complex; pub const big = @import("math/big.zig"); test { _ = floatExponentBits; _ = floatMantissaBits; _ = floatFractionalBits; _ = floatExponentMin; _ = floatExponentMax; _ = floatTrueMin; _ = floatMin; _ = floatMax; _ = floatEps; _ = inf; _ = nan; _ = snan; _ = isNan; _ = isSignalNan; _ = frexp; _ = Frexp; _ = modf; _ = Modf; _ = copysign; _ = isFinite; _ = isInf; _ = isPositiveInf; _ = isNegativeInf; _ = isNormal; _ = nextAfter; _ = signbit; _ = scalbn; _ = ldexp; _ = pow; _ = powi; _ = sqrt; _ = cbrt; _ = acos; _ = asin; _ = atan; _ = atan2; _ = hypot; _ = expm1; _ = ilogb; _ = log; _ = log2; _ = log10; _ = log10_int; _ = log_int; _ = log1p; _ = asinh; _ = acosh; _ = atanh; _ = sinh; _ = cosh; _ = tanh; _ = gcd; _ = gamma; _ = lgamma; _ = complex; _ = Complex; _ = big; } /// Given two types, returns the smallest one which is capable of holding the /// full range of the minimum value. pub fn Min(comptime A: type, comptime B: type) type { switch (@typeInfo(A)) { .int => |a_info| switch (@typeInfo(B)) { .int => |b_info| if (a_info.signedness == .unsigned and b_info.signedness == .unsigned) { if (a_info.bits < b_info.bits) { return A; } else { return B; } }, else => {}, }, else => {}, } return @TypeOf(@as(A, 0) + @as(B, 0)); } /// Odd sawtooth function /// ``` /// | /// / | / / /// / |/ / /// --/----/----/-- /// / /| / /// / / | / /// | /// ``` /// Limit x to the half-open interval [-r, r). pub fn wrap(x: anytype, r: anytype) @TypeOf(x) { const info_x = @typeInfo(@TypeOf(x)); const info_r = @typeInfo(@TypeOf(r)); if (info_x == .int and info_x.int.signedness != .signed) { @compileError("x must be floating point, comptime integer, or signed integer."); } switch (info_r) { .int => { // in the rare usecase of r not being comptime_int or float, // take the penalty of having an intermediary type conversion, // otherwise the alternative is to unwind iteratively to avoid overflow const R = comptime do: { var info = info_r; info.int.bits += 1; info.int.signedness = .signed; break :do @Type(info); }; const radius: if (info_r.int.signedness == .signed) @TypeOf(r) else R = r; return @intCast(@mod(x - radius, 2 * @as(R, r)) - r); // provably impossible to overflow }, else => { return @mod(x - r, 2 * r) - r; }, } } test wrap { // Within range try testing.expect(wrap(@as(i32, -75), @as(i32, 180)) == -75); try testing.expect(wrap(@as(i32, -75), @as(i32, -180)) == -75); // Below try testing.expect(wrap(@as(i32, -225), @as(i32, 180)) == 135); try testing.expect(wrap(@as(i32, -225), @as(i32, -180)) == 135); // Above try testing.expect(wrap(@as(i32, 361), @as(i32, 180)) == 1); try testing.expect(wrap(@as(i32, 361), @as(i32, -180)) == 1); // One period, right limit, positive r try testing.expect(wrap(@as(i32, 180), @as(i32, 180)) == -180); // One period, left limit, positive r try testing.expect(wrap(@as(i32, -180), @as(i32, 180)) == -180); // One period, right limit, negative r try testing.expect(wrap(@as(i32, 180), @as(i32, -180)) == 180); // One period, left limit, negative r try testing.expect(wrap(@as(i32, -180), @as(i32, -180)) == 180); // Two periods, right limit, positive r try testing.expect(wrap(@as(i32, 540), @as(i32, 180)) == -180); // Two periods, left limit, positive r try testing.expect(wrap(@as(i32, -540), @as(i32, 180)) == -180); // Two periods, right limit, negative r try testing.expect(wrap(@as(i32, 540), @as(i32, -180)) == 180); // Two periods, left limit, negative r try testing.expect(wrap(@as(i32, -540), @as(i32, -180)) == 180); // Floating point try testing.expect(wrap(@as(f32, 1.125), @as(f32, 1.0)) == -0.875); try testing.expect(wrap(@as(f32, -127.5), @as(f32, 180)) == -127.5); // Mix of comptime and non-comptime var i: i32 = 1; _ = &i; try testing.expect(wrap(i, 10) == 1); const limit: i32 = 180; // Within range try testing.expect(wrap(@as(i32, -75), limit) == -75); // Below try testing.expect(wrap(@as(i32, -225), limit) == 135); // Above try testing.expect(wrap(@as(i32, 361), limit) == 1); } /// Odd ramp function /// ``` /// | _____ /// | / /// |/ /// -------/------- /// /| /// _____/ | /// | /// ``` /// Limit val to the inclusive range [lower, upper]. pub fn clamp(val: anytype, lower: anytype, upper: anytype) @TypeOf(val, lower, upper) { const T = @TypeOf(val, lower, upper); switch (@typeInfo(T)) { .int, .float, .comptime_int, .comptime_float => assert(lower <= upper), .vector => |vinfo| switch (@typeInfo(vinfo.child)) { .int, .float => assert(@reduce(.And, lower <= upper)), else => @compileError("Expected vector of ints or floats, found " ++ @typeName(T)), }, else => @compileError("Expected an int, float or vector of one, found " ++ @typeName(T)), } return @max(lower, @min(val, upper)); } test clamp { // Within range try testing.expect(std.math.clamp(@as(i32, -1), @as(i32, -4), @as(i32, 7)) == -1); // Below try testing.expect(std.math.clamp(@as(i32, -5), @as(i32, -4), @as(i32, 7)) == -4); // Above try testing.expect(std.math.clamp(@as(i32, 8), @as(i32, -4), @as(i32, 7)) == 7); // Floating point try testing.expect(std.math.clamp(@as(f32, 1.1), @as(f32, 0.0), @as(f32, 1.0)) == 1.0); try testing.expect(std.math.clamp(@as(f32, -127.5), @as(f32, -200), @as(f32, -100)) == -127.5); // Vector try testing.expect(@reduce(.And, std.math.clamp(@as(@Vector(3, f32), .{ 1.4, 15.23, 28.3 }), @as(@Vector(3, f32), .{ 9.8, 13.2, 15.6 }), @as(@Vector(3, f32), .{ 15.2, 22.8, 26.3 })) == @as(@Vector(3, f32), .{ 9.8, 15.23, 26.3 }))); // Mix of comptime and non-comptime var i: i32 = 1; _ = &i; try testing.expect(std.math.clamp(i, 0, 1) == 1); } /// Returns the product of a and b. Returns an error on overflow. pub fn mul(comptime T: type, a: T, b: T) (error{Overflow}!T) { if (T == comptime_int) return a * b; const ov = @mulWithOverflow(a, b); if (ov[1] != 0) return error.Overflow; return ov[0]; } /// Returns the sum of a and b. Returns an error on overflow. pub fn add(comptime T: type, a: T, b: T) (error{Overflow}!T) { if (T == comptime_int) return a + b; const ov = @addWithOverflow(a, b); if (ov[1] != 0) return error.Overflow; return ov[0]; } /// Returns a - b, or an error on overflow. pub fn sub(comptime T: type, a: T, b: T) (error{Overflow}!T) { if (T == comptime_int) return a - b; const ov = @subWithOverflow(a, b); if (ov[1] != 0) return error.Overflow; return ov[0]; } pub fn negate(x: anytype) !@TypeOf(x) { return sub(@TypeOf(x), 0, x); } /// Shifts a left by shift_amt. Returns an error on overflow. shift_amt /// is unsigned. pub fn shlExact(comptime T: type, a: T, shift_amt: Log2Int(T)) !T { if (T == comptime_int) return a << shift_amt; const ov = @shlWithOverflow(a, shift_amt); if (ov[1] != 0) return error.Overflow; return ov[0]; } /// Shifts left. Overflowed bits are truncated. /// A negative shift amount results in a right shift. pub fn shl(comptime T: type, a: T, shift_amt: anytype) T { const abs_shift_amt = @abs(shift_amt); const casted_shift_amt = blk: { if (@typeInfo(T) == .vector) { const C = @typeInfo(T).vector.child; const len = @typeInfo(T).vector.len; if (abs_shift_amt >= @typeInfo(C).int.bits) return @splat(0); break :blk @as(@Vector(len, Log2Int(C)), @splat(@as(Log2Int(C), @intCast(abs_shift_amt)))); } else { if (abs_shift_amt >= @typeInfo(T).int.bits) return 0; break :blk @as(Log2Int(T), @intCast(abs_shift_amt)); } }; if (@TypeOf(shift_amt) == comptime_int or @typeInfo(@TypeOf(shift_amt)).int.signedness == .signed) { if (shift_amt < 0) { return a >> casted_shift_amt; } } return a << casted_shift_amt; } test shl { try testing.expect(shl(u8, 0b11111111, @as(usize, 3)) == 0b11111000); try testing.expect(shl(u8, 0b11111111, @as(usize, 8)) == 0); try testing.expect(shl(u8, 0b11111111, @as(usize, 9)) == 0); try testing.expect(shl(u8, 0b11111111, @as(isize, -2)) == 0b00111111); try testing.expect(shl(u8, 0b11111111, 3) == 0b11111000); try testing.expect(shl(u8, 0b11111111, 8) == 0); try testing.expect(shl(u8, 0b11111111, 9) == 0); try testing.expect(shl(u8, 0b11111111, -2) == 0b00111111); try testing.expect(shl(@Vector(1, u32), @Vector(1, u32){42}, @as(usize, 1))[0] == @as(u32, 42) << 1); try testing.expect(shl(@Vector(1, u32), @Vector(1, u32){42}, @as(isize, -1))[0] == @as(u32, 42) >> 1); try testing.expect(shl(@Vector(1, u32), @Vector(1, u32){42}, 33)[0] == 0); } /// Shifts right. Overflowed bits are truncated. /// A negative shift amount results in a left shift. pub fn shr(comptime T: type, a: T, shift_amt: anytype) T { const abs_shift_amt = @abs(shift_amt); const casted_shift_amt = blk: { if (@typeInfo(T) == .vector) { const C = @typeInfo(T).vector.child; const len = @typeInfo(T).vector.len; if (abs_shift_amt >= @typeInfo(C).int.bits) return @splat(0); break :blk @as(@Vector(len, Log2Int(C)), @splat(@as(Log2Int(C), @intCast(abs_shift_amt)))); } else { if (abs_shift_amt >= @typeInfo(T).int.bits) return 0; break :blk @as(Log2Int(T), @intCast(abs_shift_amt)); } }; if (@TypeOf(shift_amt) == comptime_int or @typeInfo(@TypeOf(shift_amt)).int.signedness == .signed) { if (shift_amt < 0) { return a << casted_shift_amt; } } return a >> casted_shift_amt; } test shr { try testing.expect(shr(u8, 0b11111111, @as(usize, 3)) == 0b00011111); try testing.expect(shr(u8, 0b11111111, @as(usize, 8)) == 0); try testing.expect(shr(u8, 0b11111111, @as(usize, 9)) == 0); try testing.expect(shr(u8, 0b11111111, @as(isize, -2)) == 0b11111100); try testing.expect(shr(u8, 0b11111111, 3) == 0b00011111); try testing.expect(shr(u8, 0b11111111, 8) == 0); try testing.expect(shr(u8, 0b11111111, 9) == 0); try testing.expect(shr(u8, 0b11111111, -2) == 0b11111100); try testing.expect(shr(@Vector(1, u32), @Vector(1, u32){42}, @as(usize, 1))[0] == @as(u32, 42) >> 1); try testing.expect(shr(@Vector(1, u32), @Vector(1, u32){42}, @as(isize, -1))[0] == @as(u32, 42) << 1); try testing.expect(shr(@Vector(1, u32), @Vector(1, u32){42}, 33)[0] == 0); } /// Rotates right. Only unsigned values can be rotated. Negative shift /// values result in shift modulo the bit count. pub fn rotr(comptime T: type, x: T, r: anytype) T { if (@typeInfo(T) == .vector) { const C = @typeInfo(T).vector.child; if (C == u0) return 0; if (@typeInfo(C).int.signedness == .signed) { @compileError("cannot rotate signed integers"); } const ar: Log2Int(C) = @intCast(@mod(r, @typeInfo(C).int.bits)); return (x >> @splat(ar)) | (x << @splat(1 + ~ar)); } else if (@typeInfo(T).int.signedness == .signed) { @compileError("cannot rotate signed integer"); } else { if (T == u0) return 0; if (comptime isPowerOfTwo(@typeInfo(T).int.bits)) { const ar: Log2Int(T) = @intCast(@mod(r, @typeInfo(T).int.bits)); return x >> ar | x << (1 +% ~ar); } else { const ar = @mod(r, @typeInfo(T).int.bits); return shr(T, x, ar) | shl(T, x, @typeInfo(T).int.bits - ar); } } } test rotr { try testing.expect(rotr(u0, 0b0, @as(usize, 3)) == 0b0); try testing.expect(rotr(u5, 0b00001, @as(usize, 0)) == 0b00001); try testing.expect(rotr(u6, 0b000001, @as(usize, 7)) == 0b100000); try testing.expect(rotr(u8, 0b00000001, @as(usize, 0)) == 0b00000001); try testing.expect(rotr(u8, 0b00000001, @as(usize, 9)) == 0b10000000); try testing.expect(rotr(u8, 0b00000001, @as(usize, 8)) == 0b00000001); try testing.expect(rotr(u8, 0b00000001, @as(usize, 4)) == 0b00010000); try testing.expect(rotr(u8, 0b00000001, @as(isize, -1)) == 0b00000010); try testing.expect(rotr(u12, 0o7777, 1) == 0o7777); try testing.expect(rotr(@Vector(1, u32), @Vector(1, u32){1}, @as(usize, 1))[0] == @as(u32, 1) << 31); try testing.expect(rotr(@Vector(1, u32), @Vector(1, u32){1}, @as(isize, -1))[0] == @as(u32, 1) << 1); } /// Rotates left. Only unsigned values can be rotated. Negative shift /// values result in shift modulo the bit count. pub fn rotl(comptime T: type, x: T, r: anytype) T { if (@typeInfo(T) == .vector) { const C = @typeInfo(T).vector.child; if (C == u0) return 0; if (@typeInfo(C).int.signedness == .signed) { @compileError("cannot rotate signed integers"); } const ar: Log2Int(C) = @intCast(@mod(r, @typeInfo(C).int.bits)); return (x << @splat(ar)) | (x >> @splat(1 +% ~ar)); } else if (@typeInfo(T).int.signedness == .signed) { @compileError("cannot rotate signed integer"); } else { if (T == u0) return 0; if (comptime isPowerOfTwo(@typeInfo(T).int.bits)) { const ar: Log2Int(T) = @intCast(@mod(r, @typeInfo(T).int.bits)); return x << ar | x >> 1 +% ~ar; } else { const ar = @mod(r, @typeInfo(T).int.bits); return shl(T, x, ar) | shr(T, x, @typeInfo(T).int.bits - ar); } } } test rotl { try testing.expect(rotl(u0, 0b0, @as(usize, 3)) == 0b0); try testing.expect(rotl(u5, 0b00001, @as(usize, 0)) == 0b00001); try testing.expect(rotl(u6, 0b000001, @as(usize, 7)) == 0b000010); try testing.expect(rotl(u8, 0b00000001, @as(usize, 0)) == 0b00000001); try testing.expect(rotl(u8, 0b00000001, @as(usize, 9)) == 0b00000010); try testing.expect(rotl(u8, 0b00000001, @as(usize, 8)) == 0b00000001); try testing.expect(rotl(u8, 0b00000001, @as(usize, 4)) == 0b00010000); try testing.expect(rotl(u8, 0b00000001, @as(isize, -1)) == 0b10000000); try testing.expect(rotl(u12, 0o7777, 1) == 0o7777); try testing.expect(rotl(@Vector(1, u32), @Vector(1, u32){1 << 31}, @as(usize, 1))[0] == 1); try testing.expect(rotl(@Vector(1, u32), @Vector(1, u32){1 << 31}, @as(isize, -1))[0] == @as(u32, 1) << 30); } /// Returns an unsigned int type that can hold the number of bits in T - 1. /// Suitable for 0-based bit indices of T. pub fn Log2Int(comptime T: type) type { // comptime ceil log2 if (T == comptime_int) return comptime_int; const bits: u16 = @typeInfo(T).int.bits; const log2_bits = 16 - @clz(bits - 1); return std.meta.Int(.unsigned, log2_bits); } /// Returns an unsigned int type that can hold the number of bits in T. pub fn Log2IntCeil(comptime T: type) type { // comptime ceil log2 if (T == comptime_int) return comptime_int; const bits: u16 = @typeInfo(T).int.bits; const log2_bits = 16 - @clz(bits); return std.meta.Int(.unsigned, log2_bits); } /// Returns the smallest integer type that can hold both from and to. pub fn IntFittingRange(comptime from: comptime_int, comptime to: comptime_int) type { assert(from <= to); if (from == 0 and to == 0) { return u0; } const signedness: std.builtin.Signedness = if (from < 0) .signed else .unsigned; const largest_positive_integer = @max(if (from < 0) (-from) - 1 else from, to); // two's complement const base = log2(largest_positive_integer); const upper = (1 << base) - 1; var magnitude_bits = if (upper >= largest_positive_integer) base else base + 1; if (signedness == .signed) { magnitude_bits += 1; } return std.meta.Int(signedness, magnitude_bits); } test IntFittingRange { try testing.expect(IntFittingRange(0, 0) == u0); try testing.expect(IntFittingRange(0, 1) == u1); try testing.expect(IntFittingRange(0, 2) == u2); try testing.expect(IntFittingRange(0, 3) == u2); try testing.expect(IntFittingRange(0, 4) == u3); try testing.expect(IntFittingRange(0, 7) == u3); try testing.expect(IntFittingRange(0, 8) == u4); try testing.expect(IntFittingRange(0, 9) == u4); try testing.expect(IntFittingRange(0, 15) == u4); try testing.expect(IntFittingRange(0, 16) == u5); try testing.expect(IntFittingRange(0, 17) == u5); try testing.expect(IntFittingRange(0, 4095) == u12); try testing.expect(IntFittingRange(2000, 4095) == u12); try testing.expect(IntFittingRange(0, 4096) == u13); try testing.expect(IntFittingRange(2000, 4096) == u13); try testing.expect(IntFittingRange(0, 4097) == u13); try testing.expect(IntFittingRange(2000, 4097) == u13); try testing.expect(IntFittingRange(0, 123456789123456798123456789) == u87); try testing.expect(IntFittingRange(0, 123456789123456798123456789123456789123456798123456789) == u177); try testing.expect(IntFittingRange(-1, -1) == i1); try testing.expect(IntFittingRange(-1, 0) == i1); try testing.expect(IntFittingRange(-1, 1) == i2); try testing.expect(IntFittingRange(-2, -2) == i2); try testing.expect(IntFittingRange(-2, -1) == i2); try testing.expect(IntFittingRange(-2, 0) == i2); try testing.expect(IntFittingRange(-2, 1) == i2); try testing.expect(IntFittingRange(-2, 2) == i3); try testing.expect(IntFittingRange(-1, 2) == i3); try testing.expect(IntFittingRange(-1, 3) == i3); try testing.expect(IntFittingRange(-1, 4) == i4); try testing.expect(IntFittingRange(-1, 7) == i4); try testing.expect(IntFittingRange(-1, 8) == i5); try testing.expect(IntFittingRange(-1, 9) == i5); try testing.expect(IntFittingRange(-1, 15) == i5); try testing.expect(IntFittingRange(-1, 16) == i6); try testing.expect(IntFittingRange(-1, 17) == i6); try testing.expect(IntFittingRange(-1, 4095) == i13); try testing.expect(IntFittingRange(-4096, 4095) == i13); try testing.expect(IntFittingRange(-1, 4096) == i14); try testing.expect(IntFittingRange(-4097, 4095) == i14); try testing.expect(IntFittingRange(-1, 4097) == i14); try testing.expect(IntFittingRange(-1, 123456789123456798123456789) == i88); try testing.expect(IntFittingRange(-1, 123456789123456798123456789123456789123456798123456789) == i178); } test "overflow functions" { try testOverflow(); try comptime testOverflow(); } fn testOverflow() !void { try testing.expect((mul(i32, 3, 4) catch unreachable) == 12); try testing.expect((add(i32, 3, 4) catch unreachable) == 7); try testing.expect((sub(i32, 3, 4) catch unreachable) == -1); try testing.expect((shlExact(i32, 0b11, 4) catch unreachable) == 0b110000); } /// Divide numerator by denominator, rounding toward zero. Returns an /// error on overflow or when denominator is zero. pub fn divTrunc(comptime T: type, numerator: T, denominator: T) !T { @setRuntimeSafety(false); if (denominator == 0) return error.DivisionByZero; if (@typeInfo(T) == .int and @typeInfo(T).int.signedness == .signed and numerator == minInt(T) and denominator == -1) return error.Overflow; return @divTrunc(numerator, denominator); } test divTrunc { try testDivTrunc(); try comptime testDivTrunc(); } fn testDivTrunc() !void { try testing.expect((divTrunc(i32, 5, 3) catch unreachable) == 1); try testing.expect((divTrunc(i32, -5, 3) catch unreachable) == -1); try testing.expectError(error.DivisionByZero, divTrunc(i8, -5, 0)); try testing.expectError(error.Overflow, divTrunc(i8, -128, -1)); try testing.expect((divTrunc(f32, 5.0, 3.0) catch unreachable) == 1.0); try testing.expect((divTrunc(f32, -5.0, 3.0) catch unreachable) == -1.0); } /// Divide numerator by denominator, rounding toward negative /// infinity. Returns an error on overflow or when denominator is /// zero. pub fn divFloor(comptime T: type, numerator: T, denominator: T) !T { @setRuntimeSafety(false); if (denominator == 0) return error.DivisionByZero; if (@typeInfo(T) == .int and @typeInfo(T).int.signedness == .signed and numerator == minInt(T) and denominator == -1) return error.Overflow; return @divFloor(numerator, denominator); } test divFloor { try testDivFloor(); try comptime testDivFloor(); } fn testDivFloor() !void { try testing.expect((divFloor(i32, 5, 3) catch unreachable) == 1); try testing.expect((divFloor(i32, -5, 3) catch unreachable) == -2); try testing.expectError(error.DivisionByZero, divFloor(i8, -5, 0)); try testing.expectError(error.Overflow, divFloor(i8, -128, -1)); try testing.expect((divFloor(f32, 5.0, 3.0) catch unreachable) == 1.0); try testing.expect((divFloor(f32, -5.0, 3.0) catch unreachable) == -2.0); } /// Divide numerator by denominator, rounding toward positive /// infinity. Returns an error on overflow or when denominator is /// zero. pub fn divCeil(comptime T: type, numerator: T, denominator: T) !T { @setRuntimeSafety(false); if (denominator == 0) return error.DivisionByZero; const info = @typeInfo(T); switch (info) { .comptime_float, .float => return @ceil(numerator / denominator), .comptime_int, .int => { if (numerator < 0 and denominator < 0) { if (info == .int and numerator == minInt(T) and denominator == -1) return error.Overflow; return @divFloor(numerator + 1, denominator) + 1; } if (numerator > 0 and denominator > 0) return @divFloor(numerator - 1, denominator) + 1; return @divTrunc(numerator, denominator); }, else => @compileError("divCeil unsupported on " ++ @typeName(T)), } } test divCeil { try testDivCeil(); try comptime testDivCeil(); } fn testDivCeil() !void { try testing.expectEqual(@as(i32, 2), divCeil(i32, 5, 3) catch unreachable); try testing.expectEqual(@as(i32, -1), divCeil(i32, -5, 3) catch unreachable); try testing.expectEqual(@as(i32, -1), divCeil(i32, 5, -3) catch unreachable); try testing.expectEqual(@as(i32, 2), divCeil(i32, -5, -3) catch unreachable); try testing.expectEqual(@as(i32, 0), divCeil(i32, 0, 5) catch unreachable); try testing.expectEqual(@as(u32, 0), divCeil(u32, 0, 5) catch unreachable); try testing.expectError(error.DivisionByZero, divCeil(i8, -5, 0)); try testing.expectError(error.Overflow, divCeil(i8, -128, -1)); try testing.expectEqual(@as(f32, 0.0), divCeil(f32, 0.0, 5.0) catch unreachable); try testing.expectEqual(@as(f32, 2.0), divCeil(f32, 5.0, 3.0) catch unreachable); try testing.expectEqual(@as(f32, -1.0), divCeil(f32, -5.0, 3.0) catch unreachable); try testing.expectEqual(@as(f32, -1.0), divCeil(f32, 5.0, -3.0) catch unreachable); try testing.expectEqual(@as(f32, 2.0), divCeil(f32, -5.0, -3.0) catch unreachable); try testing.expectEqual(6, divCeil(comptime_int, 23, 4) catch unreachable); try testing.expectEqual(-5, divCeil(comptime_int, -23, 4) catch unreachable); try testing.expectEqual(-5, divCeil(comptime_int, 23, -4) catch unreachable); try testing.expectEqual(6, divCeil(comptime_int, -23, -4) catch unreachable); try testing.expectError(error.DivisionByZero, divCeil(comptime_int, 23, 0)); try testing.expectEqual(6.0, divCeil(comptime_float, 23.0, 4.0) catch unreachable); try testing.expectEqual(-5.0, divCeil(comptime_float, -23.0, 4.0) catch unreachable); try testing.expectEqual(-5.0, divCeil(comptime_float, 23.0, -4.0) catch unreachable); try testing.expectEqual(6.0, divCeil(comptime_float, -23.0, -4.0) catch unreachable); try testing.expectError(error.DivisionByZero, divCeil(comptime_float, 23.0, 0.0)); } /// Divide numerator by denominator. Return an error if quotient is /// not an integer, denominator is zero, or on overflow. pub fn divExact(comptime T: type, numerator: T, denominator: T) !T { @setRuntimeSafety(false); if (denominator == 0) return error.DivisionByZero; if (@typeInfo(T) == .int and @typeInfo(T).int.signedness == .signed and numerator == minInt(T) and denominator == -1) return error.Overflow; const result = @divTrunc(numerator, denominator); if (result * denominator != numerator) return error.UnexpectedRemainder; return result; } test divExact { try testDivExact(); try comptime testDivExact(); } fn testDivExact() !void { try testing.expect((divExact(i32, 10, 5) catch unreachable) == 2); try testing.expect((divExact(i32, -10, 5) catch unreachable) == -2); try testing.expectError(error.DivisionByZero, divExact(i8, -5, 0)); try testing.expectError(error.Overflow, divExact(i8, -128, -1)); try testing.expectError(error.UnexpectedRemainder, divExact(i32, 5, 2)); try testing.expect((divExact(f32, 10.0, 5.0) catch unreachable) == 2.0); try testing.expect((divExact(f32, -10.0, 5.0) catch unreachable) == -2.0); try testing.expectError(error.UnexpectedRemainder, divExact(f32, 5.0, 2.0)); } /// Returns numerator modulo denominator, or an error if denominator is /// zero or negative. Negative numerators never result in negative /// return values. pub fn mod(comptime T: type, numerator: T, denominator: T) !T { @setRuntimeSafety(false); if (denominator == 0) return error.DivisionByZero; if (denominator < 0) return error.NegativeDenominator; return @mod(numerator, denominator); } test mod { try testMod(); try comptime testMod(); } fn testMod() !void { try testing.expect((mod(i32, -5, 3) catch unreachable) == 1); try testing.expect((mod(i32, 5, 3) catch unreachable) == 2); try testing.expectError(error.NegativeDenominator, mod(i32, 10, -1)); try testing.expectError(error.DivisionByZero, mod(i32, 10, 0)); try testing.expect((mod(f32, -5, 3) catch unreachable) == 1); try testing.expect((mod(f32, 5, 3) catch unreachable) == 2); try testing.expectError(error.NegativeDenominator, mod(f32, 10, -1)); try testing.expectError(error.DivisionByZero, mod(f32, 10, 0)); } /// Returns the remainder when numerator is divided by denominator, or /// an error if denominator is zero or negative. Negative numerators /// can give negative results. pub fn rem(comptime T: type, numerator: T, denominator: T) !T { @setRuntimeSafety(false); if (denominator == 0) return error.DivisionByZero; if (denominator < 0) return error.NegativeDenominator; return @rem(numerator, denominator); } test rem { try testRem(); try comptime testRem(); } fn testRem() !void { try testing.expect((rem(i32, -5, 3) catch unreachable) == -2); try testing.expect((rem(i32, 5, 3) catch unreachable) == 2); try testing.expectError(error.NegativeDenominator, rem(i32, 10, -1)); try testing.expectError(error.DivisionByZero, rem(i32, 10, 0)); try testing.expect((rem(f32, -5, 3) catch unreachable) == -2); try testing.expect((rem(f32, 5, 3) catch unreachable) == 2); try testing.expectError(error.NegativeDenominator, rem(f32, 10, -1)); try testing.expectError(error.DivisionByZero, rem(f32, 10, 0)); } /// Returns the negation of the integer parameter. /// Result is a signed integer. pub fn negateCast(x: anytype) !std.meta.Int(.signed, @bitSizeOf(@TypeOf(x))) { if (@typeInfo(@TypeOf(x)).int.signedness == .signed) return negate(x); const int = std.meta.Int(.signed, @bitSizeOf(@TypeOf(x))); if (x > -minInt(int)) return error.Overflow; if (x == -minInt(int)) return minInt(int); return -@as(int, @intCast(x)); } test negateCast { try testing.expect((negateCast(@as(u32, 999)) catch unreachable) == -999); try testing.expect(@TypeOf(negateCast(@as(u32, 999)) catch unreachable) == i32); try testing.expect((negateCast(@as(u32, -minInt(i32))) catch unreachable) == minInt(i32)); try testing.expect(@TypeOf(negateCast(@as(u32, -minInt(i32))) catch unreachable) == i32); try testing.expectError(error.Overflow, negateCast(@as(u32, maxInt(i32) + 10))); } /// Cast an integer to a different integer type. If the value doesn't fit, /// return null. pub fn cast(comptime T: type, x: anytype) ?T { comptime assert(@typeInfo(T) == .int); // must pass an integer const is_comptime = @TypeOf(x) == comptime_int; comptime assert(is_comptime or @typeInfo(@TypeOf(x)) == .int); // must pass an integer if ((is_comptime or maxInt(@TypeOf(x)) > maxInt(T)) and x > maxInt(T)) { return null; } else if ((is_comptime or minInt(@TypeOf(x)) < minInt(T)) and x < minInt(T)) { return null; } else { return @as(T, @intCast(x)); } } test cast { try testing.expect(cast(u8, 300) == null); try testing.expect(cast(u8, @as(u32, 300)) == null); try testing.expect(cast(i8, -200) == null); try testing.expect(cast(i8, @as(i32, -200)) == null); try testing.expect(cast(u8, -1) == null); try testing.expect(cast(u8, @as(i8, -1)) == null); try testing.expect(cast(u64, -1) == null); try testing.expect(cast(u64, @as(i8, -1)) == null); try testing.expect(cast(u8, 255).? == @as(u8, 255)); try testing.expect(cast(u8, @as(u32, 255)).? == @as(u8, 255)); try testing.expect(@TypeOf(cast(u8, 255).?) == u8); try testing.expect(@TypeOf(cast(u8, @as(u32, 255)).?) == u8); } pub const AlignCastError = error{UnalignedMemory}; fn AlignCastResult(comptime alignment: u29, comptime Ptr: type) type { var ptr_info = @typeInfo(Ptr); ptr_info.pointer.alignment = alignment; return @Type(ptr_info); } /// Align cast a pointer but return an error if it's the wrong alignment pub fn alignCast(comptime alignment: u29, ptr: anytype) AlignCastError!AlignCastResult(alignment, @TypeOf(ptr)) { const addr = @intFromPtr(ptr); if (addr % alignment != 0) { return error.UnalignedMemory; } return @alignCast(ptr); } /// Asserts `int > 0`. pub fn isPowerOfTwo(int: anytype) bool { assert(int > 0); return (int & (int - 1)) == 0; } test isPowerOfTwo { try testing.expect(isPowerOfTwo(@as(u8, 1))); try testing.expect(isPowerOfTwo(2)); try testing.expect(!isPowerOfTwo(@as(i16, 3))); try testing.expect(isPowerOfTwo(4)); try testing.expect(!isPowerOfTwo(@as(u32, 31))); try testing.expect(isPowerOfTwo(32)); try testing.expect(!isPowerOfTwo(@as(i64, 63))); try testing.expect(isPowerOfTwo(128)); try testing.expect(isPowerOfTwo(@as(u128, 256))); } /// Aligns the given integer type bit width to a width divisible by 8. pub fn ByteAlignedInt(comptime T: type) type { const info = @typeInfo(T).int; const bits = (info.bits + 7) / 8 * 8; const extended_type = std.meta.Int(info.signedness, bits); return extended_type; } test ByteAlignedInt { try testing.expect(ByteAlignedInt(u0) == u0); try testing.expect(ByteAlignedInt(i0) == i0); try testing.expect(ByteAlignedInt(u3) == u8); try testing.expect(ByteAlignedInt(u8) == u8); try testing.expect(ByteAlignedInt(i111) == i112); try testing.expect(ByteAlignedInt(u129) == u136); } /// Rounds the given floating point number to the nearest integer. /// If two integers are equally close, rounds away from zero. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @round pub inline fn round(value: anytype) @TypeOf(value) { return @round(value); } /// Rounds the given floating point number to an integer, towards zero. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @trunc pub inline fn trunc(value: anytype) @TypeOf(value) { return @trunc(value); } /// Returns the largest integral value not greater than the given floating point number. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @floor pub inline fn floor(value: anytype) @TypeOf(value) { return @floor(value); } /// Returns the nearest power of two less than or equal to value, or /// zero if value is less than or equal to zero. pub fn floorPowerOfTwo(comptime T: type, value: T) T { const uT = std.meta.Int(.unsigned, @typeInfo(T).int.bits); if (value <= 0) return 0; return @as(T, 1) << log2_int(uT, @as(uT, @intCast(value))); } test floorPowerOfTwo { try testFloorPowerOfTwo(); try comptime testFloorPowerOfTwo(); } fn testFloorPowerOfTwo() !void { try testing.expect(floorPowerOfTwo(u32, 63) == 32); try testing.expect(floorPowerOfTwo(u32, 64) == 64); try testing.expect(floorPowerOfTwo(u32, 65) == 64); try testing.expect(floorPowerOfTwo(u32, 0) == 0); try testing.expect(floorPowerOfTwo(u4, 7) == 4); try testing.expect(floorPowerOfTwo(u4, 8) == 8); try testing.expect(floorPowerOfTwo(u4, 9) == 8); try testing.expect(floorPowerOfTwo(u4, 0) == 0); try testing.expect(floorPowerOfTwo(i4, 7) == 4); try testing.expect(floorPowerOfTwo(i4, -8) == 0); try testing.expect(floorPowerOfTwo(i4, -1) == 0); try testing.expect(floorPowerOfTwo(i4, 0) == 0); } /// Returns the smallest integral value not less than the given floating point number. /// Uses a dedicated hardware instruction when available. /// This is the same as calling the builtin @ceil pub inline fn ceil(value: anytype) @TypeOf(value) { return @ceil(value); } /// Returns the next power of two (if the value is not already a power of two). /// Only unsigned integers can be used. Zero is not an allowed input. /// Result is a type with 1 more bit than the input type. pub fn ceilPowerOfTwoPromote(comptime T: type, value: T) std.meta.Int(@typeInfo(T).int.signedness, @typeInfo(T).int.bits + 1) { comptime assert(@typeInfo(T) == .int); comptime assert(@typeInfo(T).int.signedness == .unsigned); assert(value != 0); const PromotedType = std.meta.Int(@typeInfo(T).int.signedness, @typeInfo(T).int.bits + 1); const ShiftType = std.math.Log2Int(PromotedType); return @as(PromotedType, 1) << @as(ShiftType, @intCast(@typeInfo(T).int.bits - @clz(value - 1))); } /// Returns the next power of two (if the value is not already a power of two). /// Only unsigned integers can be used. Zero is not an allowed input. /// If the value doesn't fit, returns an error. pub fn ceilPowerOfTwo(comptime T: type, value: T) (error{Overflow}!T) { comptime assert(@typeInfo(T) == .int); const info = @typeInfo(T).int; comptime assert(info.signedness == .unsigned); const PromotedType = std.meta.Int(info.signedness, info.bits + 1); const overflowBit = @as(PromotedType, 1) << info.bits; const x = ceilPowerOfTwoPromote(T, value); if (overflowBit & x != 0) { return error.Overflow; } return @as(T, @intCast(x)); } /// Returns the next power of two (if the value is not already a power /// of two). Only unsigned integers can be used. Zero is not an /// allowed input. Asserts that the value fits. pub fn ceilPowerOfTwoAssert(comptime T: type, value: T) T { return ceilPowerOfTwo(T, value) catch unreachable; } test ceilPowerOfTwoPromote { try testCeilPowerOfTwoPromote(); try comptime testCeilPowerOfTwoPromote(); } fn testCeilPowerOfTwoPromote() !void { try testing.expectEqual(@as(u33, 1), ceilPowerOfTwoPromote(u32, 1)); try testing.expectEqual(@as(u33, 2), ceilPowerOfTwoPromote(u32, 2)); try testing.expectEqual(@as(u33, 64), ceilPowerOfTwoPromote(u32, 63)); try testing.expectEqual(@as(u33, 64), ceilPowerOfTwoPromote(u32, 64)); try testing.expectEqual(@as(u33, 128), ceilPowerOfTwoPromote(u32, 65)); try testing.expectEqual(@as(u6, 8), ceilPowerOfTwoPromote(u5, 7)); try testing.expectEqual(@as(u6, 8), ceilPowerOfTwoPromote(u5, 8)); try testing.expectEqual(@as(u6, 16), ceilPowerOfTwoPromote(u5, 9)); try testing.expectEqual(@as(u5, 16), ceilPowerOfTwoPromote(u4, 9)); } test ceilPowerOfTwo { try testCeilPowerOfTwo(); try comptime testCeilPowerOfTwo(); } fn testCeilPowerOfTwo() !void { try testing.expectEqual(@as(u32, 1), try ceilPowerOfTwo(u32, 1)); try testing.expectEqual(@as(u32, 2), try ceilPowerOfTwo(u32, 2)); try testing.expectEqual(@as(u32, 64), try ceilPowerOfTwo(u32, 63)); try testing.expectEqual(@as(u32, 64), try ceilPowerOfTwo(u32, 64)); try testing.expectEqual(@as(u32, 128), try ceilPowerOfTwo(u32, 65)); try testing.expectEqual(@as(u5, 8), try ceilPowerOfTwo(u5, 7)); try testing.expectEqual(@as(u5, 8), try ceilPowerOfTwo(u5, 8)); try testing.expectEqual(@as(u5, 16), try ceilPowerOfTwo(u5, 9)); try testing.expectError(error.Overflow, ceilPowerOfTwo(u4, 9)); } /// Return the log base 2 of integer value x, rounding down to the /// nearest integer. pub fn log2_int(comptime T: type, x: T) Log2Int(T) { if (@typeInfo(T) != .int or @typeInfo(T).int.signedness != .unsigned) @compileError("log2_int requires an unsigned integer, found " ++ @typeName(T)); assert(x != 0); return @as(Log2Int(T), @intCast(@typeInfo(T).int.bits - 1 - @clz(x))); } /// Return the log base 2 of integer value x, rounding up to the /// nearest integer. pub fn log2_int_ceil(comptime T: type, x: T) Log2IntCeil(T) { if (@typeInfo(T) != .int or @typeInfo(T).int.signedness != .unsigned) @compileError("log2_int_ceil requires an unsigned integer, found " ++ @typeName(T)); assert(x != 0); if (x == 1) return 0; const log2_val: Log2IntCeil(T) = log2_int(T, x - 1); return log2_val + 1; } test log2_int_ceil { try testing.expect(log2_int_ceil(u32, 1) == 0); try testing.expect(log2_int_ceil(u32, 2) == 1); try testing.expect(log2_int_ceil(u32, 3) == 2); try testing.expect(log2_int_ceil(u32, 4) == 2); try testing.expect(log2_int_ceil(u32, 5) == 3); try testing.expect(log2_int_ceil(u32, 6) == 3); try testing.expect(log2_int_ceil(u32, 7) == 3); try testing.expect(log2_int_ceil(u32, 8) == 3); try testing.expect(log2_int_ceil(u32, 9) == 4); try testing.expect(log2_int_ceil(u32, 10) == 4); } /// Cast a value to a different type. If the value doesn't fit in, or /// can't be perfectly represented by, the new type, it will be /// converted to the closest possible representation. pub fn lossyCast(comptime T: type, value: anytype) T { switch (@typeInfo(T)) { .float => { switch (@typeInfo(@TypeOf(value))) { .int => return @floatFromInt(value), .float => return @floatCast(value), .comptime_int => return value, .comptime_float => return value, else => @compileError("bad type"), } }, .int => { switch (@typeInfo(@TypeOf(value))) { .int, .comptime_int => { if (value >= maxInt(T)) { return maxInt(T); } else if (value <= minInt(T)) { return minInt(T); } else { return @intCast(value); } }, .float, .comptime_float => { if (isNan(value)) { return 0; } else if (value >= maxInt(T)) { return maxInt(T); } else if (value <= minInt(T)) { return minInt(T); } else { return @intFromFloat(value); } }, else => @compileError("bad type"), } }, else => @compileError("bad result type"), } } test lossyCast { try testing.expect(lossyCast(i16, 70000.0) == @as(i16, 32767)); try testing.expect(lossyCast(u32, @as(i16, -255)) == @as(u32, 0)); try testing.expect(lossyCast(i9, @as(u32, 200)) == @as(i9, 200)); try testing.expect(lossyCast(u32, @as(f32, maxInt(u32))) == maxInt(u32)); try testing.expect(lossyCast(u32, nan(f32)) == 0); } /// Performs linear interpolation between *a* and *b* based on *t*. /// *t* ranges from 0.0 to 1.0, but may exceed these bounds. /// Supports floats and vectors of floats. /// /// This does not guarantee returning *b* if *t* is 1 due to floating-point errors. /// This is monotonic. pub fn lerp(a: anytype, b: anytype, t: anytype) @TypeOf(a, b, t) { const Type = @TypeOf(a, b, t); return @mulAdd(Type, b - a, t, a); } test lerp { if (builtin.zig_backend == .stage2_c) return error.SkipZigTest; // https://github.com/ziglang/zig/issues/17884 if (builtin.zig_backend == .stage2_x86_64 and !comptime std.Target.x86.featureSetHas(builtin.cpu.features, .fma)) return error.SkipZigTest; // https://github.com/ziglang/zig/issues/17884 try testing.expectEqual(@as(f64, 75), lerp(50, 100, 0.5)); try testing.expectEqual(@as(f32, 43.75), lerp(50, 25, 0.25)); try testing.expectEqual(@as(f64, -31.25), lerp(-50, 25, 0.25)); try testing.expectEqual(@as(f64, 30), lerp(10, 20, 2.0)); try testing.expectEqual(@as(f64, 5), lerp(10, 20, -0.5)); try testing.expectApproxEqRel(@as(f32, -7.16067345e+03), lerp(-10000.12345, -5000.12345, 0.56789), 1e-19); try testing.expectApproxEqRel(@as(f64, 7.010987590521e+62), lerp(0.123456789e-64, 0.123456789e64, 0.56789), 1e-33); try testing.expectEqual(@as(f32, 0.0), lerp(@as(f32, 1.0e8), 1.0, 1.0)); try testing.expectEqual(@as(f64, 0.0), lerp(@as(f64, 1.0e16), 1.0, 1.0)); try testing.expectEqual(@as(f32, 1.0), lerp(@as(f32, 1.0e7), 1.0, 1.0)); try testing.expectEqual(@as(f64, 1.0), lerp(@as(f64, 1.0e15), 1.0, 1.0)); { const a: @Vector(3, f32) = @splat(0); const b: @Vector(3, f32) = @splat(50); const t: @Vector(3, f32) = @splat(0.5); try testing.expectEqual( @Vector(3, f32){ 25, 25, 25 }, lerp(a, b, t), ); } { const a: @Vector(3, f64) = @splat(50); const b: @Vector(3, f64) = @splat(100); const t: @Vector(3, f64) = @splat(0.5); try testing.expectEqual( @Vector(3, f64){ 75, 75, 75 }, lerp(a, b, t), ); } { const a: @Vector(2, f32) = @splat(40); const b: @Vector(2, f32) = @splat(80); const t: @Vector(2, f32) = @Vector(2, f32){ 0.25, 0.75 }; try testing.expectEqual( @Vector(2, f32){ 50, 70 }, lerp(a, b, t), ); } } /// Returns the maximum value of integer type T. pub fn maxInt(comptime T: type) comptime_int { const info = @typeInfo(T); const bit_count = info.int.bits; if (bit_count == 0) return 0; return (1 << (bit_count - @intFromBool(info.int.signedness == .signed))) - 1; } /// Returns the minimum value of integer type T. pub fn minInt(comptime T: type) comptime_int { const info = @typeInfo(T); const bit_count = info.int.bits; if (info.int.signedness == .unsigned) return 0; if (bit_count == 0) return 0; return -(1 << (bit_count - 1)); } test maxInt { try testing.expect(maxInt(u0) == 0); try testing.expect(maxInt(u1) == 1); try testing.expect(maxInt(u8) == 255); try testing.expect(maxInt(u16) == 65535); try testing.expect(maxInt(u32) == 4294967295); try testing.expect(maxInt(u64) == 18446744073709551615); try testing.expect(maxInt(u128) == 340282366920938463463374607431768211455); try testing.expect(maxInt(i0) == 0); try testing.expect(maxInt(i1) == 0); try testing.expect(maxInt(i8) == 127); try testing.expect(maxInt(i16) == 32767); try testing.expect(maxInt(i32) == 2147483647); try testing.expect(maxInt(i63) == 4611686018427387903); try testing.expect(maxInt(i64) == 9223372036854775807); try testing.expect(maxInt(i128) == 170141183460469231731687303715884105727); } test minInt { try testing.expect(minInt(u0) == 0); try testing.expect(minInt(u1) == 0); try testing.expect(minInt(u8) == 0); try testing.expect(minInt(u16) == 0); try testing.expect(minInt(u32) == 0); try testing.expect(minInt(u63) == 0); try testing.expect(minInt(u64) == 0); try testing.expect(minInt(u128) == 0); try testing.expect(minInt(i0) == 0); try testing.expect(minInt(i1) == -1); try testing.expect(minInt(i8) == -128); try testing.expect(minInt(i16) == -32768); try testing.expect(minInt(i32) == -2147483648); try testing.expect(minInt(i63) == -4611686018427387904); try testing.expect(minInt(i64) == -9223372036854775808); try testing.expect(minInt(i128) == -170141183460469231731687303715884105728); } test "max value type" { const x: u32 = maxInt(i32); try testing.expect(x == 2147483647); } /// Multiply a and b. Return type is wide enough to guarantee no /// overflow. pub fn mulWide(comptime T: type, a: T, b: T) std.meta.Int( @typeInfo(T).int.signedness, @typeInfo(T).int.bits * 2, ) { const ResultInt = std.meta.Int( @typeInfo(T).int.signedness, @typeInfo(T).int.bits * 2, ); return @as(ResultInt, a) * @as(ResultInt, b); } test mulWide { try testing.expect(mulWide(u8, 5, 5) == 25); try testing.expect(mulWide(i8, 5, -5) == -25); try testing.expect(mulWide(u8, 100, 100) == 10000); } /// See also `CompareOperator`. pub const Order = enum { /// Greater than (`>`) gt, /// Less than (`<`) lt, /// Equal (`==`) eq, pub fn invert(self: Order) Order { return switch (self) { .lt => .gt, .eq => .eq, .gt => .lt, }; } test invert { try testing.expect(Order.invert(order(0, 0)) == .eq); try testing.expect(Order.invert(order(1, 0)) == .lt); try testing.expect(Order.invert(order(-1, 0)) == .gt); } pub fn differ(self: Order) ?Order { return if (self != .eq) self else null; } test differ { const neg: i32 = -1; const zero: i32 = 0; const pos: i32 = 1; try testing.expect(order(zero, neg).differ() orelse order(pos, zero) == .gt); try testing.expect(order(zero, zero).differ() orelse order(zero, zero) == .eq); try testing.expect(order(pos, pos).differ() orelse order(neg, zero) == .lt); try testing.expect(order(zero, zero).differ() orelse order(pos, neg).differ() orelse order(neg, zero) == .gt); try testing.expect(order(pos, pos).differ() orelse order(pos, pos).differ() orelse order(neg, neg) == .eq); try testing.expect(order(zero, pos).differ() orelse order(neg, pos).differ() orelse order(pos, neg) == .lt); } pub fn compare(self: Order, op: CompareOperator) bool { return switch (self) { .lt => switch (op) { .lt => true, .lte => true, .eq => false, .gte => false, .gt => false, .neq => true, }, .eq => switch (op) { .lt => false, .lte => true, .eq => true, .gte => true, .gt => false, .neq => false, }, .gt => switch (op) { .lt => false, .lte => false, .eq => false, .gte => true, .gt => true, .neq => true, }, }; } // https://github.com/ziglang/zig/issues/19295 test "compare" { try testing.expect(order(-1, 0).compare(.lt)); try testing.expect(order(-1, 0).compare(.lte)); try testing.expect(order(0, 0).compare(.lte)); try testing.expect(order(0, 0).compare(.eq)); try testing.expect(order(0, 0).compare(.gte)); try testing.expect(order(1, 0).compare(.gte)); try testing.expect(order(1, 0).compare(.gt)); try testing.expect(order(1, 0).compare(.neq)); } }; /// Given two numbers, this function returns the order they are with respect to each other. pub fn order(a: anytype, b: anytype) Order { if (a == b) { return .eq; } else if (a < b) { return .lt; } else if (a > b) { return .gt; } else { unreachable; } } /// See also `Order`. pub const CompareOperator = enum { /// Less than (`<`) lt, /// Less than or equal (`<=`) lte, /// Equal (`==`) eq, /// Greater than or equal (`>=`) gte, /// Greater than (`>`) gt, /// Not equal (`!=`) neq, /// Reverse the direction of the comparison. /// Use when swapping the left and right hand operands. pub fn reverse(op: CompareOperator) CompareOperator { return switch (op) { .lt => .gt, .lte => .gte, .gt => .lt, .gte => .lte, .eq => .eq, .neq => .neq, }; } test reverse { inline for (@typeInfo(CompareOperator).@"enum".fields) |op_field| { const op = @as(CompareOperator, @enumFromInt(op_field.value)); try testing.expect(compare(2, op, 3) == compare(3, op.reverse(), 2)); try testing.expect(compare(3, op, 3) == compare(3, op.reverse(), 3)); try testing.expect(compare(4, op, 3) == compare(3, op.reverse(), 4)); } } }; /// This function does the same thing as comparison operators, however the /// operator is a runtime-known enum value. Works on any operands that /// support comparison operators. pub fn compare(a: anytype, op: CompareOperator, b: anytype) bool { return switch (op) { .lt => a < b, .lte => a <= b, .eq => a == b, .neq => a != b, .gt => a > b, .gte => a >= b, }; } test compare { try testing.expect(compare(@as(i8, -1), .lt, @as(u8, 255))); try testing.expect(compare(@as(i8, 2), .gt, @as(u8, 1))); try testing.expect(!compare(@as(i8, -1), .gte, @as(u8, 255))); try testing.expect(compare(@as(u8, 255), .gt, @as(i8, -1))); try testing.expect(!compare(@as(u8, 255), .lte, @as(i8, -1))); try testing.expect(compare(@as(i8, -1), .lt, @as(u9, 255))); try testing.expect(!compare(@as(i8, -1), .gte, @as(u9, 255))); try testing.expect(compare(@as(u9, 255), .gt, @as(i8, -1))); try testing.expect(!compare(@as(u9, 255), .lte, @as(i8, -1))); try testing.expect(compare(@as(i9, -1), .lt, @as(u8, 255))); try testing.expect(!compare(@as(i9, -1), .gte, @as(u8, 255))); try testing.expect(compare(@as(u8, 255), .gt, @as(i9, -1))); try testing.expect(!compare(@as(u8, 255), .lte, @as(i9, -1))); try testing.expect(compare(@as(u8, 1), .lt, @as(u8, 2))); try testing.expect(@as(u8, @bitCast(@as(i8, -1))) == @as(u8, 255)); try testing.expect(!compare(@as(u8, 255), .eq, @as(i8, -1))); try testing.expect(compare(@as(u8, 1), .eq, @as(u8, 1))); } test order { try testing.expect(order(0, 0) == .eq); try testing.expect(order(1, 0) == .gt); try testing.expect(order(-1, 0) == .lt); } /// Returns a mask of all ones if value is true, /// and a mask of all zeroes if value is false. /// Compiles to one instruction for register sized integers. pub inline fn boolMask(comptime MaskInt: type, value: bool) MaskInt { if (@typeInfo(MaskInt) != .int) @compileError("boolMask requires an integer mask type."); if (MaskInt == u0 or MaskInt == i0) @compileError("boolMask cannot convert to u0 or i0, they are too small."); // The u1 and i1 cases tend to overflow, // so we special case them here. if (MaskInt == u1) return @intFromBool(value); if (MaskInt == i1) { // The @as here is a workaround for #7950 return @as(i1, @bitCast(@as(u1, @intFromBool(value)))); } return -%@as(MaskInt, @intCast(@intFromBool(value))); } test boolMask { const runTest = struct { fn runTest() !void { try testing.expectEqual(@as(u1, 0), boolMask(u1, false)); try testing.expectEqual(@as(u1, 1), boolMask(u1, true)); try testing.expectEqual(@as(i1, 0), boolMask(i1, false)); try testing.expectEqual(@as(i1, -1), boolMask(i1, true)); try testing.expectEqual(@as(u13, 0), boolMask(u13, false)); try testing.expectEqual(@as(u13, 0x1FFF), boolMask(u13, true)); try testing.expectEqual(@as(i13, 0), boolMask(i13, false)); try testing.expectEqual(@as(i13, -1), boolMask(i13, true)); try testing.expectEqual(@as(u32, 0), boolMask(u32, false)); try testing.expectEqual(@as(u32, 0xFFFF_FFFF), boolMask(u32, true)); try testing.expectEqual(@as(i32, 0), boolMask(i32, false)); try testing.expectEqual(@as(i32, -1), boolMask(i32, true)); } }.runTest; try runTest(); try comptime runTest(); } /// Return the mod of `num` with the smallest integer type pub fn comptimeMod(num: anytype, comptime denom: comptime_int) IntFittingRange(0, denom - 1) { return @as(IntFittingRange(0, denom - 1), @intCast(@mod(num, denom))); } pub const F80 = struct { fraction: u64, exp: u16, pub fn toFloat(self: F80) f80 { const int = (@as(u80, self.exp) << 64) | self.fraction; return @as(f80, @bitCast(int)); } pub fn fromFloat(x: f80) F80 { const int = @as(u80, @bitCast(x)); return .{ .fraction = @as(u64, @truncate(int)), .exp = @as(u16, @truncate(int >> 64)), }; } }; /// Returns -1, 0, or 1. /// Supports integer and float types and vectors of integer and float types. /// Unsigned integer types will always return 0 or 1. /// Branchless. pub inline fn sign(i: anytype) @TypeOf(i) { const T = @TypeOf(i); return switch (@typeInfo(T)) { .int, .comptime_int => @as(T, @intFromBool(i > 0)) - @as(T, @intFromBool(i < 0)), .float, .comptime_float => @as(T, @floatFromInt(@intFromBool(i > 0))) - @as(T, @floatFromInt(@intFromBool(i < 0))), .vector => |vinfo| blk: { switch (@typeInfo(vinfo.child)) { .int, .float => { const zero: T = @splat(0); const one: T = @splat(1); break :blk @select(vinfo.child, i > zero, one, zero) - @select(vinfo.child, i < zero, one, zero); }, else => @compileError("Expected vector of ints or floats, found " ++ @typeName(T)), } }, else => @compileError("Expected an int, float or vector of one, found " ++ @typeName(T)), }; } fn testSign() !void { // each of the following blocks checks the inputs // 2, -2, 0, { 2, -2, 0 } provide expected output // 1, -1, 0, { 1, -1, 0 } for the given T // (negative values omitted for unsigned types) { const T = i8; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, -1), sign(@as(T, -2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(3, T){ 1, -1, 0 }, sign(@Vector(3, T){ 2, -2, 0 })); } { const T = i32; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, -1), sign(@as(T, -2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(3, T){ 1, -1, 0 }, sign(@Vector(3, T){ 2, -2, 0 })); } { const T = i64; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, -1), sign(@as(T, -2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(3, T){ 1, -1, 0 }, sign(@Vector(3, T){ 2, -2, 0 })); } { const T = u8; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(2, T){ 1, 0 }, sign(@Vector(2, T){ 2, 0 })); } { const T = u32; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(2, T){ 1, 0 }, sign(@Vector(2, T){ 2, 0 })); } { const T = u64; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(2, T){ 1, 0 }, sign(@Vector(2, T){ 2, 0 })); } { const T = f16; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, -1), sign(@as(T, -2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(3, T){ 1, -1, 0 }, sign(@Vector(3, T){ 2, -2, 0 })); } { const T = f32; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, -1), sign(@as(T, -2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(3, T){ 1, -1, 0 }, sign(@Vector(3, T){ 2, -2, 0 })); } { const T = f64; try std.testing.expectEqual(@as(T, 1), sign(@as(T, 2))); try std.testing.expectEqual(@as(T, -1), sign(@as(T, -2))); try std.testing.expectEqual(@as(T, 0), sign(@as(T, 0))); try std.testing.expectEqual(@Vector(3, T){ 1, -1, 0 }, sign(@Vector(3, T){ 2, -2, 0 })); } // comptime_int try std.testing.expectEqual(-1, sign(-10)); try std.testing.expectEqual(1, sign(10)); try std.testing.expectEqual(0, sign(0)); // comptime_float try std.testing.expectEqual(-1.0, sign(-10.0)); try std.testing.expectEqual(1.0, sign(10.0)); try std.testing.expectEqual(0.0, sign(0.0)); } test sign { try testSign(); try comptime testSign(); }