mirror of
https://github.com/ziglang/zig.git
synced 2024-12-04 19:09:32 +00:00
8139c5a516
Reverted #1628 and changed the grammar+parser of the language to not allow certain expr where types are expected
717 lines
23 KiB
Zig
717 lines
23 KiB
Zig
const builtin = @import("builtin");
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const std = @import("../index.zig");
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const TypeId = builtin.TypeId;
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const assert = std.debug.assert;
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pub const e = 2.71828182845904523536028747135266249775724709369995;
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pub const pi = 3.14159265358979323846264338327950288419716939937510;
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// float.h details
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pub const f64_true_min = 4.94065645841246544177e-324;
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pub const f64_min = 2.2250738585072014e-308;
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pub const f64_max = 1.79769313486231570815e+308;
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pub const f64_epsilon = 2.22044604925031308085e-16;
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pub const f64_toint = 1.0 / f64_epsilon;
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pub const f32_true_min = 1.40129846432481707092e-45;
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pub const f32_min = 1.17549435082228750797e-38;
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pub const f32_max = 3.40282346638528859812e+38;
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pub const f32_epsilon = 1.1920928955078125e-07;
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pub const f32_toint = 1.0 / f32_epsilon;
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pub const f16_true_min = 0.000000059604644775390625; // 2**-24
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pub const f16_min = 0.00006103515625; // 2**-14
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pub const f16_max = 65504;
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pub const f16_epsilon = 0.0009765625; // 2**-10
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pub const f16_toint = 1.0 / f16_epsilon;
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pub const nan_u16 = u16(0x7C01);
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pub const nan_f16 = @bitCast(f16, nan_u16);
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pub const inf_u16 = u16(0x7C00);
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pub const inf_f16 = @bitCast(f16, inf_u16);
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pub const nan_u32 = u32(0x7F800001);
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pub const nan_f32 = @bitCast(f32, nan_u32);
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pub const inf_u32 = u32(0x7F800000);
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pub const inf_f32 = @bitCast(f32, inf_u32);
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pub const nan_u64 = u64(0x7FF << 52) | 1;
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pub const nan_f64 = @bitCast(f64, nan_u64);
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pub const inf_u64 = u64(0x7FF << 52);
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pub const inf_f64 = @bitCast(f64, inf_u64);
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pub const nan = @import("nan.zig").nan;
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pub const snan = @import("nan.zig").snan;
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pub const inf = @import("inf.zig").inf;
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pub fn approxEq(comptime T: type, x: T, y: T, epsilon: T) bool {
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assert(@typeId(T) == TypeId.Float);
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return fabs(x - y) < epsilon;
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}
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// TODO: Hide the following in an internal module.
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pub fn forceEval(value: var) void {
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const T = @typeOf(value);
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switch (T) {
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f16 => {
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var x: f16 = undefined;
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const p = @ptrCast(*volatile f16, &x);
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p.* = x;
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},
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f32 => {
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var x: f32 = undefined;
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const p = @ptrCast(*volatile f32, &x);
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p.* = x;
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},
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f64 => {
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var x: f64 = undefined;
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const p = @ptrCast(*volatile f64, &x);
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p.* = x;
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},
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else => {
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@compileError("forceEval not implemented for " ++ @typeName(T));
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},
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}
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}
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pub fn raiseInvalid() void {
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// Raise INVALID fpu exception
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}
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pub fn raiseUnderflow() void {
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// Raise UNDERFLOW fpu exception
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}
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pub fn raiseOverflow() void {
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// Raise OVERFLOW fpu exception
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}
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pub fn raiseInexact() void {
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// Raise INEXACT fpu exception
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}
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pub fn raiseDivByZero() void {
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// Raise INEXACT fpu exception
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}
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pub const isNan = @import("isnan.zig").isNan;
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pub const isSignalNan = @import("isnan.zig").isSignalNan;
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pub const fabs = @import("fabs.zig").fabs;
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pub const ceil = @import("ceil.zig").ceil;
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pub const floor = @import("floor.zig").floor;
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pub const trunc = @import("trunc.zig").trunc;
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pub const round = @import("round.zig").round;
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pub const frexp = @import("frexp.zig").frexp;
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pub const frexp32_result = @import("frexp.zig").frexp32_result;
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pub const frexp64_result = @import("frexp.zig").frexp64_result;
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pub const modf = @import("modf.zig").modf;
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pub const modf32_result = @import("modf.zig").modf32_result;
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pub const modf64_result = @import("modf.zig").modf64_result;
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pub const copysign = @import("copysign.zig").copysign;
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pub const isFinite = @import("isfinite.zig").isFinite;
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pub const isInf = @import("isinf.zig").isInf;
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pub const isPositiveInf = @import("isinf.zig").isPositiveInf;
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pub const isNegativeInf = @import("isinf.zig").isNegativeInf;
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pub const isNormal = @import("isnormal.zig").isNormal;
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pub const signbit = @import("signbit.zig").signbit;
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pub const scalbn = @import("scalbn.zig").scalbn;
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pub const pow = @import("pow.zig").pow;
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pub const powi = @import("powi.zig").powi;
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pub const sqrt = @import("sqrt.zig").sqrt;
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pub const cbrt = @import("cbrt.zig").cbrt;
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pub const acos = @import("acos.zig").acos;
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pub const asin = @import("asin.zig").asin;
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pub const atan = @import("atan.zig").atan;
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pub const atan2 = @import("atan2.zig").atan2;
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pub const hypot = @import("hypot.zig").hypot;
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pub const exp = @import("exp.zig").exp;
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pub const exp2 = @import("exp2.zig").exp2;
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pub const expm1 = @import("expm1.zig").expm1;
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pub const ilogb = @import("ilogb.zig").ilogb;
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pub const ln = @import("ln.zig").ln;
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pub const log = @import("log.zig").log;
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pub const log2 = @import("log2.zig").log2;
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pub const log10 = @import("log10.zig").log10;
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pub const log1p = @import("log1p.zig").log1p;
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pub const fma = @import("fma.zig").fma;
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pub const asinh = @import("asinh.zig").asinh;
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pub const acosh = @import("acosh.zig").acosh;
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pub const atanh = @import("atanh.zig").atanh;
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pub const sinh = @import("sinh.zig").sinh;
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pub const cosh = @import("cosh.zig").cosh;
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pub const tanh = @import("tanh.zig").tanh;
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pub const cos = @import("cos.zig").cos;
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pub const sin = @import("sin.zig").sin;
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pub const tan = @import("tan.zig").tan;
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pub const complex = @import("complex/index.zig");
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pub const Complex = complex.Complex;
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pub const big = @import("big/index.zig");
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test "math" {
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_ = @import("nan.zig");
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_ = @import("isnan.zig");
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_ = @import("fabs.zig");
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_ = @import("ceil.zig");
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_ = @import("floor.zig");
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_ = @import("trunc.zig");
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_ = @import("round.zig");
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_ = @import("frexp.zig");
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_ = @import("modf.zig");
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_ = @import("copysign.zig");
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_ = @import("isfinite.zig");
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_ = @import("isinf.zig");
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_ = @import("isnormal.zig");
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_ = @import("signbit.zig");
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_ = @import("scalbn.zig");
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_ = @import("pow.zig");
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_ = @import("powi.zig");
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_ = @import("sqrt.zig");
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_ = @import("cbrt.zig");
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_ = @import("acos.zig");
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_ = @import("asin.zig");
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_ = @import("atan.zig");
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_ = @import("atan2.zig");
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_ = @import("hypot.zig");
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_ = @import("exp.zig");
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_ = @import("exp2.zig");
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_ = @import("expm1.zig");
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_ = @import("ilogb.zig");
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_ = @import("ln.zig");
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_ = @import("log.zig");
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_ = @import("log2.zig");
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_ = @import("log10.zig");
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_ = @import("log1p.zig");
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_ = @import("fma.zig");
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_ = @import("asinh.zig");
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_ = @import("acosh.zig");
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_ = @import("atanh.zig");
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_ = @import("sinh.zig");
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_ = @import("cosh.zig");
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_ = @import("tanh.zig");
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_ = @import("sin.zig");
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_ = @import("cos.zig");
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_ = @import("tan.zig");
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_ = @import("complex/index.zig");
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_ = @import("big/index.zig");
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}
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pub fn floatMantissaBits(comptime T: type) comptime_int {
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assert(@typeId(T) == builtin.TypeId.Float);
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return switch (T.bit_count) {
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16 => 10,
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32 => 23,
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64 => 52,
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80 => 64,
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128 => 112,
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else => @compileError("unknown floating point type " ++ @typeName(T)),
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};
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}
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pub fn floatExponentBits(comptime T: type) comptime_int {
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assert(@typeId(T) == builtin.TypeId.Float);
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return switch (T.bit_count) {
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16 => 5,
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32 => 8,
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64 => 11,
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80 => 15,
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128 => 15,
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else => @compileError("unknown floating point type " ++ @typeName(T)),
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};
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}
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pub fn min(x: var, y: var) @typeOf(x + y) {
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return if (x < y) x else y;
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}
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test "math.min" {
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assert(min(i32(-1), i32(2)) == -1);
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}
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pub fn max(x: var, y: var) @typeOf(x + y) {
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return if (x > y) x else y;
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}
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test "math.max" {
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assert(max(i32(-1), i32(2)) == 2);
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}
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pub fn mul(comptime T: type, a: T, b: T) (error{Overflow}!T) {
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var answer: T = undefined;
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return if (@mulWithOverflow(T, a, b, &answer)) error.Overflow else answer;
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}
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pub fn add(comptime T: type, a: T, b: T) (error{Overflow}!T) {
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var answer: T = undefined;
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return if (@addWithOverflow(T, a, b, &answer)) error.Overflow else answer;
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}
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pub fn sub(comptime T: type, a: T, b: T) (error{Overflow}!T) {
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var answer: T = undefined;
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return if (@subWithOverflow(T, a, b, &answer)) error.Overflow else answer;
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}
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pub fn negate(x: var) !@typeOf(x) {
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return sub(@typeOf(x), 0, x);
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}
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pub fn shlExact(comptime T: type, a: T, shift_amt: Log2Int(T)) !T {
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var answer: T = undefined;
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return if (@shlWithOverflow(T, a, shift_amt, &answer)) error.Overflow else answer;
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}
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/// Shifts left. Overflowed bits are truncated.
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/// A negative shift amount results in a right shift.
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pub fn shl(comptime T: type, a: T, shift_amt: var) T {
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const abs_shift_amt = absCast(shift_amt);
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const casted_shift_amt = if (abs_shift_amt >= T.bit_count) return 0 else @intCast(Log2Int(T), abs_shift_amt);
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if (@typeOf(shift_amt).is_signed) {
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if (shift_amt >= 0) {
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return a << casted_shift_amt;
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} else {
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return a >> casted_shift_amt;
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}
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}
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return a << casted_shift_amt;
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}
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test "math.shl" {
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assert(shl(u8, 0b11111111, usize(3)) == 0b11111000);
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assert(shl(u8, 0b11111111, usize(8)) == 0);
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assert(shl(u8, 0b11111111, usize(9)) == 0);
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assert(shl(u8, 0b11111111, isize(-2)) == 0b00111111);
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}
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/// Shifts right. Overflowed bits are truncated.
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/// A negative shift amount results in a lefft shift.
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pub fn shr(comptime T: type, a: T, shift_amt: var) T {
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const abs_shift_amt = absCast(shift_amt);
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const casted_shift_amt = if (abs_shift_amt >= T.bit_count) return 0 else @intCast(Log2Int(T), abs_shift_amt);
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if (@typeOf(shift_amt).is_signed) {
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if (shift_amt >= 0) {
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return a >> casted_shift_amt;
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} else {
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return a << casted_shift_amt;
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}
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}
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return a >> casted_shift_amt;
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}
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test "math.shr" {
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assert(shr(u8, 0b11111111, usize(3)) == 0b00011111);
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assert(shr(u8, 0b11111111, usize(8)) == 0);
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assert(shr(u8, 0b11111111, usize(9)) == 0);
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assert(shr(u8, 0b11111111, isize(-2)) == 0b11111100);
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}
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/// Rotates right. Only unsigned values can be rotated.
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/// Negative shift values results in shift modulo the bit count.
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pub fn rotr(comptime T: type, x: T, r: var) T {
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if (T.is_signed) {
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@compileError("cannot rotate signed integer");
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} else {
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const ar = @mod(r, T.bit_count);
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return shr(T, x, ar) | shl(T, x, T.bit_count - ar);
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}
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}
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test "math.rotr" {
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assert(rotr(u8, 0b00000001, usize(0)) == 0b00000001);
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assert(rotr(u8, 0b00000001, usize(9)) == 0b10000000);
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assert(rotr(u8, 0b00000001, usize(8)) == 0b00000001);
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assert(rotr(u8, 0b00000001, usize(4)) == 0b00010000);
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assert(rotr(u8, 0b00000001, isize(-1)) == 0b00000010);
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}
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/// Rotates left. Only unsigned values can be rotated.
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/// Negative shift values results in shift modulo the bit count.
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pub fn rotl(comptime T: type, x: T, r: var) T {
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if (T.is_signed) {
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@compileError("cannot rotate signed integer");
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} else {
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const ar = @mod(r, T.bit_count);
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return shl(T, x, ar) | shr(T, x, T.bit_count - ar);
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}
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}
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test "math.rotl" {
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assert(rotl(u8, 0b00000001, usize(0)) == 0b00000001);
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assert(rotl(u8, 0b00000001, usize(9)) == 0b00000010);
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assert(rotl(u8, 0b00000001, usize(8)) == 0b00000001);
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assert(rotl(u8, 0b00000001, usize(4)) == 0b00010000);
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assert(rotl(u8, 0b00000001, isize(-1)) == 0b10000000);
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}
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pub fn Log2Int(comptime T: type) type {
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// comptime ceil log2
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comptime var count = 0;
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comptime var s = T.bit_count - 1;
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inline while (s != 0) : (s >>= 1) {
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count += 1;
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}
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return @IntType(false, count);
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}
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test "math overflow functions" {
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testOverflow();
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comptime testOverflow();
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}
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fn testOverflow() void {
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assert((mul(i32, 3, 4) catch unreachable) == 12);
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assert((add(i32, 3, 4) catch unreachable) == 7);
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assert((sub(i32, 3, 4) catch unreachable) == -1);
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assert((shlExact(i32, 0b11, 4) catch unreachable) == 0b110000);
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}
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pub fn absInt(x: var) !@typeOf(x) {
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const T = @typeOf(x);
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comptime assert(@typeId(T) == builtin.TypeId.Int); // must pass an integer to absInt
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comptime assert(T.is_signed); // must pass a signed integer to absInt
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if (x == minInt(@typeOf(x))) {
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return error.Overflow;
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} else {
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@setRuntimeSafety(false);
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return if (x < 0) -x else x;
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}
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}
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test "math.absInt" {
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testAbsInt();
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comptime testAbsInt();
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}
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fn testAbsInt() void {
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assert((absInt(i32(-10)) catch unreachable) == 10);
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assert((absInt(i32(10)) catch unreachable) == 10);
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}
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pub const absFloat = @import("fabs.zig").fabs;
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pub fn divTrunc(comptime T: type, numerator: T, denominator: T) !T {
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@setRuntimeSafety(false);
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if (denominator == 0) return error.DivisionByZero;
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if (@typeId(T) == builtin.TypeId.Int and T.is_signed and numerator == minInt(T) and denominator == -1) return error.Overflow;
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return @divTrunc(numerator, denominator);
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}
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test "math.divTrunc" {
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testDivTrunc();
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comptime testDivTrunc();
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}
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fn testDivTrunc() void {
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assert((divTrunc(i32, 5, 3) catch unreachable) == 1);
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assert((divTrunc(i32, -5, 3) catch unreachable) == -1);
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if (divTrunc(i8, -5, 0)) |_| unreachable else |err| assert(err == error.DivisionByZero);
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if (divTrunc(i8, -128, -1)) |_| unreachable else |err| assert(err == error.Overflow);
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assert((divTrunc(f32, 5.0, 3.0) catch unreachable) == 1.0);
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assert((divTrunc(f32, -5.0, 3.0) catch unreachable) == -1.0);
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}
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pub fn divFloor(comptime T: type, numerator: T, denominator: T) !T {
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@setRuntimeSafety(false);
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if (denominator == 0) return error.DivisionByZero;
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if (@typeId(T) == builtin.TypeId.Int and T.is_signed and numerator == minInt(T) and denominator == -1) return error.Overflow;
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return @divFloor(numerator, denominator);
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}
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test "math.divFloor" {
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testDivFloor();
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comptime testDivFloor();
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}
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fn testDivFloor() void {
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assert((divFloor(i32, 5, 3) catch unreachable) == 1);
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assert((divFloor(i32, -5, 3) catch unreachable) == -2);
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if (divFloor(i8, -5, 0)) |_| unreachable else |err| assert(err == error.DivisionByZero);
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if (divFloor(i8, -128, -1)) |_| unreachable else |err| assert(err == error.Overflow);
|
|
|
|
assert((divFloor(f32, 5.0, 3.0) catch unreachable) == 1.0);
|
|
assert((divFloor(f32, -5.0, 3.0) catch unreachable) == -2.0);
|
|
}
|
|
|
|
pub fn divExact(comptime T: type, numerator: T, denominator: T) !T {
|
|
@setRuntimeSafety(false);
|
|
if (denominator == 0) return error.DivisionByZero;
|
|
if (@typeId(T) == builtin.TypeId.Int and T.is_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 "math.divExact" {
|
|
testDivExact();
|
|
comptime testDivExact();
|
|
}
|
|
fn testDivExact() void {
|
|
assert((divExact(i32, 10, 5) catch unreachable) == 2);
|
|
assert((divExact(i32, -10, 5) catch unreachable) == -2);
|
|
if (divExact(i8, -5, 0)) |_| unreachable else |err| assert(err == error.DivisionByZero);
|
|
if (divExact(i8, -128, -1)) |_| unreachable else |err| assert(err == error.Overflow);
|
|
if (divExact(i32, 5, 2)) |_| unreachable else |err| assert(err == error.UnexpectedRemainder);
|
|
|
|
assert((divExact(f32, 10.0, 5.0) catch unreachable) == 2.0);
|
|
assert((divExact(f32, -10.0, 5.0) catch unreachable) == -2.0);
|
|
if (divExact(f32, 5.0, 2.0)) |_| unreachable else |err| assert(err == error.UnexpectedRemainder);
|
|
}
|
|
|
|
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 "math.mod" {
|
|
testMod();
|
|
comptime testMod();
|
|
}
|
|
fn testMod() void {
|
|
assert((mod(i32, -5, 3) catch unreachable) == 1);
|
|
assert((mod(i32, 5, 3) catch unreachable) == 2);
|
|
if (mod(i32, 10, -1)) |_| unreachable else |err| assert(err == error.NegativeDenominator);
|
|
if (mod(i32, 10, 0)) |_| unreachable else |err| assert(err == error.DivisionByZero);
|
|
|
|
assert((mod(f32, -5, 3) catch unreachable) == 1);
|
|
assert((mod(f32, 5, 3) catch unreachable) == 2);
|
|
if (mod(f32, 10, -1)) |_| unreachable else |err| assert(err == error.NegativeDenominator);
|
|
if (mod(f32, 10, 0)) |_| unreachable else |err| assert(err == error.DivisionByZero);
|
|
}
|
|
|
|
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 "math.rem" {
|
|
testRem();
|
|
comptime testRem();
|
|
}
|
|
fn testRem() void {
|
|
assert((rem(i32, -5, 3) catch unreachable) == -2);
|
|
assert((rem(i32, 5, 3) catch unreachable) == 2);
|
|
if (rem(i32, 10, -1)) |_| unreachable else |err| assert(err == error.NegativeDenominator);
|
|
if (rem(i32, 10, 0)) |_| unreachable else |err| assert(err == error.DivisionByZero);
|
|
|
|
assert((rem(f32, -5, 3) catch unreachable) == -2);
|
|
assert((rem(f32, 5, 3) catch unreachable) == 2);
|
|
if (rem(f32, 10, -1)) |_| unreachable else |err| assert(err == error.NegativeDenominator);
|
|
if (rem(f32, 10, 0)) |_| unreachable else |err| assert(err == error.DivisionByZero);
|
|
}
|
|
|
|
/// Returns the absolute value of the integer parameter.
|
|
/// Result is an unsigned integer.
|
|
pub fn absCast(x: var) @IntType(false, @typeOf(x).bit_count) {
|
|
const uint = @IntType(false, @typeOf(x).bit_count);
|
|
if (x >= 0) return @intCast(uint, x);
|
|
|
|
return @intCast(uint, -(x + 1)) + 1;
|
|
}
|
|
|
|
test "math.absCast" {
|
|
assert(absCast(i32(-999)) == 999);
|
|
assert(@typeOf(absCast(i32(-999))) == u32);
|
|
|
|
assert(absCast(i32(999)) == 999);
|
|
assert(@typeOf(absCast(i32(999))) == u32);
|
|
|
|
assert(absCast(i32(minInt(i32))) == -minInt(i32));
|
|
assert(@typeOf(absCast(i32(minInt(i32)))) == u32);
|
|
}
|
|
|
|
/// Returns the negation of the integer parameter.
|
|
/// Result is a signed integer.
|
|
pub fn negateCast(x: var) !@IntType(true, @typeOf(x).bit_count) {
|
|
if (@typeOf(x).is_signed) return negate(x);
|
|
|
|
const int = @IntType(true, @typeOf(x).bit_count);
|
|
if (x > -minInt(int)) return error.Overflow;
|
|
|
|
if (x == -minInt(int)) return minInt(int);
|
|
|
|
return -@intCast(int, x);
|
|
}
|
|
|
|
test "math.negateCast" {
|
|
assert((negateCast(u32(999)) catch unreachable) == -999);
|
|
assert(@typeOf(negateCast(u32(999)) catch unreachable) == i32);
|
|
|
|
assert((negateCast(u32(-minInt(i32))) catch unreachable) == minInt(i32));
|
|
assert(@typeOf(negateCast(u32(-minInt(i32))) catch unreachable) == i32);
|
|
|
|
if (negateCast(u32(maxInt(i32) + 10))) |_| unreachable else |err| assert(err == error.Overflow);
|
|
}
|
|
|
|
/// Cast an integer to a different integer type. If the value doesn't fit,
|
|
/// return an error.
|
|
pub fn cast(comptime T: type, x: var) (error{Overflow}!T) {
|
|
comptime assert(@typeId(T) == builtin.TypeId.Int); // must pass an integer
|
|
comptime assert(@typeId(@typeOf(x)) == builtin.TypeId.Int); // must pass an integer
|
|
if (maxInt(@typeOf(x)) > maxInt(T) and x > maxInt(T)) {
|
|
return error.Overflow;
|
|
} else if (minInt(@typeOf(x)) < minInt(T) and x < minInt(T)) {
|
|
return error.Overflow;
|
|
} else {
|
|
return @intCast(T, x);
|
|
}
|
|
}
|
|
|
|
test "math.cast" {
|
|
if (cast(u8, u32(300))) |_| @panic("fail") else |err| assert(err == error.Overflow);
|
|
if (cast(i8, i32(-200))) |_| @panic("fail") else |err| assert(err == error.Overflow);
|
|
if (cast(u8, i8(-1))) |_| @panic("fail") else |err| assert(err == error.Overflow);
|
|
if (cast(u64, i8(-1))) |_| @panic("fail") else |err| assert(err == error.Overflow);
|
|
|
|
assert((try cast(u8, u32(255))) == u8(255));
|
|
assert(@typeOf(try cast(u8, u32(255))) == u8);
|
|
}
|
|
|
|
pub const AlignCastError = error{UnalignedMemory};
|
|
|
|
/// Align cast a pointer but return an error if it's the wrong alignment
|
|
pub fn alignCast(comptime alignment: u29, ptr: var) AlignCastError!@typeOf(@alignCast(alignment, ptr)) {
|
|
const addr = @ptrToInt(ptr);
|
|
if (addr % alignment != 0) {
|
|
return error.UnalignedMemory;
|
|
}
|
|
return @alignCast(alignment, ptr);
|
|
}
|
|
|
|
pub fn floorPowerOfTwo(comptime T: type, value: T) T {
|
|
var x = value;
|
|
|
|
comptime var i = 1;
|
|
inline while (T.bit_count > i) : (i *= 2) {
|
|
x |= (x >> i);
|
|
}
|
|
|
|
return x - (x >> 1);
|
|
}
|
|
|
|
test "math.floorPowerOfTwo" {
|
|
testFloorPowerOfTwo();
|
|
comptime testFloorPowerOfTwo();
|
|
}
|
|
|
|
pub fn log2_int(comptime T: type, x: T) Log2Int(T) {
|
|
assert(x != 0);
|
|
return @intCast(Log2Int(T), T.bit_count - 1 - @clz(x));
|
|
}
|
|
|
|
pub fn log2_int_ceil(comptime T: type, x: T) Log2Int(T) {
|
|
assert(x != 0);
|
|
const log2_val = log2_int(T, x);
|
|
if (T(1) << log2_val == x)
|
|
return log2_val;
|
|
return log2_val + 1;
|
|
}
|
|
|
|
test "std.math.log2_int_ceil" {
|
|
assert(log2_int_ceil(u32, 1) == 0);
|
|
assert(log2_int_ceil(u32, 2) == 1);
|
|
assert(log2_int_ceil(u32, 3) == 2);
|
|
assert(log2_int_ceil(u32, 4) == 2);
|
|
assert(log2_int_ceil(u32, 5) == 3);
|
|
assert(log2_int_ceil(u32, 6) == 3);
|
|
assert(log2_int_ceil(u32, 7) == 3);
|
|
assert(log2_int_ceil(u32, 8) == 3);
|
|
assert(log2_int_ceil(u32, 9) == 4);
|
|
assert(log2_int_ceil(u32, 10) == 4);
|
|
}
|
|
|
|
fn testFloorPowerOfTwo() void {
|
|
assert(floorPowerOfTwo(u32, 63) == 32);
|
|
assert(floorPowerOfTwo(u32, 64) == 64);
|
|
assert(floorPowerOfTwo(u32, 65) == 64);
|
|
assert(floorPowerOfTwo(u4, 7) == 4);
|
|
assert(floorPowerOfTwo(u4, 8) == 8);
|
|
assert(floorPowerOfTwo(u4, 9) == 8);
|
|
}
|
|
|
|
pub fn lossyCast(comptime T: type, value: var) T {
|
|
switch (@typeInfo(@typeOf(value))) {
|
|
builtin.TypeId.Int => return @intToFloat(T, value),
|
|
builtin.TypeId.Float => return @floatCast(T, value),
|
|
builtin.TypeId.ComptimeInt => return T(value),
|
|
builtin.TypeId.ComptimeFloat => return T(value),
|
|
else => @compileError("bad type"),
|
|
}
|
|
}
|
|
|
|
test "math.f64_min" {
|
|
const f64_min_u64 = 0x0010000000000000;
|
|
const fmin: f64 = f64_min;
|
|
assert(@bitCast(u64, fmin) == f64_min_u64);
|
|
}
|
|
|
|
pub fn maxInt(comptime T: type) comptime_int {
|
|
const info = @typeInfo(T);
|
|
const bit_count = comptime_int(info.Int.bits); // TODO #1683
|
|
if (bit_count == 0) return 0;
|
|
return (1 << (bit_count - @boolToInt(info.Int.is_signed))) - 1;
|
|
}
|
|
|
|
pub fn minInt(comptime T: type) comptime_int {
|
|
const info = @typeInfo(T);
|
|
const bit_count = comptime_int(info.Int.bits); // TODO #1683
|
|
if (!info.Int.is_signed) return 0;
|
|
if (bit_count == 0) return 0;
|
|
return -(1 << (bit_count - 1));
|
|
}
|
|
|
|
test "minInt and maxInt" {
|
|
assert(maxInt(u0) == 0);
|
|
assert(maxInt(u1) == 1);
|
|
assert(maxInt(u8) == 255);
|
|
assert(maxInt(u16) == 65535);
|
|
assert(maxInt(u32) == 4294967295);
|
|
assert(maxInt(u64) == 18446744073709551615);
|
|
|
|
assert(maxInt(i0) == 0);
|
|
assert(maxInt(i1) == 0);
|
|
assert(maxInt(i8) == 127);
|
|
assert(maxInt(i16) == 32767);
|
|
assert(maxInt(i32) == 2147483647);
|
|
assert(maxInt(i63) == 4611686018427387903);
|
|
assert(maxInt(i64) == 9223372036854775807);
|
|
|
|
assert(minInt(u0) == 0);
|
|
assert(minInt(u1) == 0);
|
|
assert(minInt(u8) == 0);
|
|
assert(minInt(u16) == 0);
|
|
assert(minInt(u32) == 0);
|
|
assert(minInt(u63) == 0);
|
|
assert(minInt(u64) == 0);
|
|
|
|
assert(minInt(i0) == 0);
|
|
assert(minInt(i1) == -1);
|
|
assert(minInt(i8) == -128);
|
|
assert(minInt(i16) == -32768);
|
|
assert(minInt(i32) == -2147483648);
|
|
assert(minInt(i63) == -4611686018427387904);
|
|
assert(minInt(i64) == -9223372036854775808);
|
|
}
|
|
|
|
test "max value type" {
|
|
// If the type of maxInt(i32) was i32 then this implicit cast to
|
|
// u32 would not work. But since the value is a number literal,
|
|
// it works fine.
|
|
const x: u32 = maxInt(i32);
|
|
assert(x == 2147483647);
|
|
}
|