// Ported from musl, which is licensed under the MIT license: // https://git.musl-libc.org/cgit/musl/tree/COPYRIGHT // // https://git.musl-libc.org/cgit/musl/tree/src/math/acosf.c // https://git.musl-libc.org/cgit/musl/tree/src/math/acos.c // https://git.musl-libc.org/cgit/musl/tree/src/math/acosl.c // // Ported from ARM-software, which is licensed under the MIT license: // https://github.com/ARM-software/optimized-routines/blob/master/LICENSE // // https://github.com/ARM-software/optimized-routines/blob/master/math/aarch64/advsimd/acosf.c // https://github.com/ARM-software/optimized-routines/blob/master/math/aarch64/advsimd/acos.c const std = @import("../std.zig"); const math = std.math; const testing = std.testing; const builtin = @import("builtin"); const native_endian = builtin.cpu.arch.endian(); /// Returns the arc-cosine of x. /// /// Special cases: /// - acos(x) = nan if x < -1 or x > 1 pub fn acos(x: anytype) @TypeOf(x) { const T = @TypeOf(x); switch (@typeInfo(T)) { .float => |info| switch (info.bits) { 16 => return acosBinary16(x), 32 => return acosBinary32(x), 64 => return acosBinary64(x), 80 => return acosExtended80(x), 128 => return acosBinary128(x), else => comptime unreachable, }, .vector => |info| switch (info.child) { f32 => return acosBinary32Vec(info.len, x), f64 => return acosBinary64Vec(info.len, x), else => @compileError("unimplemented"), }, else => comptime unreachable, } } fn approxBinary16(z: f32) f32 { const S0: f32 = 1.0000001e0; const S1: f32 = 1.6664918e-1; const S2: f32 = 7.55022e-2; const S3: f32 = 3.9513987e-2; const S4: f32 = 5.0883885e-2; return S0 + z * (S1 + z * (S2 + z * (S3 + z * S4))); } fn acosBinary16(x: f16) f16 { const pio2: f32 = math.pi / 2.0; const hx: u16 = @bitCast(x); const ix: u16 = hx & 0x7fff; // |x| >= 1 or nan if (ix >= 0x3c00) { if (ix == 0x3c00) { if (hx >> 15 != 0) { return @floatCast(2.0 * pio2 + 0x1p-120); } return 0.0; } return 0.0 / (x - x); } const xf: f32 = @floatCast(x); // |x| < 0.5 if (ix < 0x3800) { return @floatCast(pio2 - xf * approxBinary16(xf * xf)); } // x < -0.5 if (hx >> 15 != 0) { const z = (1.0 + xf) * 0.5; const s = @sqrt(z); const w = approxBinary16(z) * s; return @floatCast(2.0 * (pio2 - w)); } // x > 0.5 const z = (1.0 - xf) * 0.5; const s = @sqrt(z); const w = approxBinary16(z) * s; return @floatCast(2.0 * w); } fn rationalApproxBinary32(z: f32) f32 { const pS0: f32 = 1.6666586697e-01; const pS1: f32 = -4.2743422091e-02; const pS2: f32 = -8.6563630030e-03; const qS1: f32 = -7.0662963390e-01; // f64 is used instead of f32 to avoid // a vectorization on x86_64. The vectorization // causes extra floating point execeptions // that are prohibited by libc-test. const p: f64 = @as(f64, @floatCast(z)) * (pS0 + z * (pS1 + z * pS2)); const q: f64 = 1.0 + z * qS1; return @floatCast(p / q); } fn acosBinary32(x: f32) f32 { const pio2_hi: f32 = 1.5707962513e+00; const pio2_lo: f32 = 7.5497894159e-08; const hx: u32 = @bitCast(x); const ix: u32 = hx & 0x7fff_ffff; // |x| >= 1 or nan if (ix >= 0x3f800000) { if (ix == 0x3f800000) { if (hx >> 31 != 0) { return 2.0 * pio2_hi + 0x1.0p-120; } return 0.0; } return 0.0 / (x - x); } // |x| < 0.5 if (ix < 0x3f00_0000) { // |x| < 2^(-26) if (ix <= 0x3280_0000) { return pio2_hi + 0x1.0p-120; } return pio2_hi - (x - (pio2_lo - x * rationalApproxBinary32(x * x))); } // x < -0.5 if (hx >> 31 != 0) { const z = (1 + x) * 0.5; const s = @sqrt(z); const w = rationalApproxBinary32(z) * s - pio2_lo; return 2.0 * (pio2_hi - (s + w)); } // x > 0.5 const z = (1.0 - x) * 0.5; const s = @sqrt(z); const hs: u32 = @bitCast(s); const df: f32 = @bitCast(hs & 0xffff_f000); const c = (z - df * df) / (s + df); const w = rationalApproxBinary32(z) * s + c; return 2.0 * (df + w); } fn rationalApproxBinary64(z: f64) f64 { const pS0: f64 = 1.66666666666666657415e-01; const pS1: f64 = -3.25565818622400915405e-01; const pS2: f64 = 2.01212532134862925881e-01; const pS3: f64 = -4.00555345006794114027e-02; const pS4: f64 = 7.91534994289814532176e-04; const pS5: f64 = 3.47933107596021167570e-05; const qS1: f64 = -2.40339491173441421878e+00; const qS2: f64 = 2.02094576023350569471e+00; const qS3: f64 = -6.88283971605453293030e-01; const qS4: f64 = 7.70381505559019352791e-02; const p = z * (pS0 + z * (pS1 + z * (pS2 + z * (pS3 + z * (pS4 + z * pS5))))); const q = 1.0 + z * (qS1 + z * (qS2 + z * (qS3 + z * qS4))); return p / q; } fn acosBinary64(x: f64) f64 { const pio2_hi: f64 = 1.57079632679489655800e+00; const pio2_lo: f64 = 6.12323399573676603587e-17; const hx: u32 = @intCast(@as(u64, @bitCast(x)) >> 32); const ix: u32 = hx & 0x7fff_ffff; // |x| >= 1 or nan if (ix >= 0x3ff0_0000) { const lx: u32 = @truncate(@as(u64, @bitCast(x))); if ((ix - 0x3ff0_0000 | lx) == 0) { if (hx >> 31 != 0) { return 2.0 * pio2_hi + 0x1.0p-120; } return 0.0; } return 0.0 / (x - x); } // |x| < 0.5 if (ix < 0x3fe0_0000) { // |x| < 2^(-57) if (ix <= 0x3c60_0000) { return pio2_hi + 0x1.0p-120; } return pio2_hi - (x - (pio2_lo - x * rationalApproxBinary64(x * x))); } // x < -0.5 if (hx >> 31 != 0) { const z = (1.0 + x) * 0.5; const s = @sqrt(z); const w = rationalApproxBinary64(z) * s - pio2_lo; return 2 * (pio2_hi - (s + w)); } // x > 0.5 const z = (1.0 - x) * 0.5; const s = @sqrt(z); const df: f64 = @bitCast(@as(u64, @bitCast(s)) & 0xffff_ffff_0000_0000); const c = (z - df * df) / (s + df); const w = rationalApproxBinary64(z) * s + c; return 2.0 * (df + w); } fn rationalApproxExtended80(z: f80) f80 { const pS0: f80 = 1.66666666666666666631e-01; const pS1: f80 = -4.16313987993683104320e-01; const pS2: f80 = 3.69068046323246813704e-01; const pS3: f80 = -1.36213932016738603108e-01; const pS4: f80 = 1.78324189708471965733e-02; const pS5: f80 = -2.19216428382605211588e-04; const pS6: f80 = -7.10526623669075243183e-06; const qS1: f80 = -2.94788392796209867269e+00; const qS2: f80 = 3.27309890266528636716e+00; const qS3: f80 = -1.68285799854822427013e+00; const qS4: f80 = 3.90699412641738801874e-01; const qS5: f80 = -3.14365703596053263322e-02; const p = z * (pS0 + z * (pS1 + z * (pS2 + z * (pS3 + z * (pS4 + z * (pS5 + z * pS6)))))); const q = 1.0 + z * (qS1 + z * (qS2 + z * (qS3 + z * (qS4 + z * qS5)))); return p / q; } fn acosExtended80(x: f80) f80 { const pio2_hi: f80 = 1.57079632679489661926; const pio2_lo: f80 = -2.50827880633416601173e-20; const hx: u80 = @bitCast(x); const se: u16 = @truncate(hx >> 64); const e = se & 0x7fff; // |x| >= 1 or nan if (e >= 0x3fff) { if (x == 1.0) { return 0.0; } if (x == -1.0) { return 2.0 * pio2_hi + 0x1p-120; } return 0.0 / (x - x); } // |x| < 0.5 if (e < 0x3fff - 1) { if (e < 0x3fff - math.floatFractionalBits(f80)) { return pio2_hi + 0x1p-120; } return pio2_hi - (rationalApproxExtended80(x * x) * x - pio2_lo + x); } // x < -0.5 if (se >> 15 != 0) { const z = (1 + x) * 0.5; const s = @sqrt(z); return 2.0 * (pio2_hi - (rationalApproxExtended80(z) * s - pio2_lo + s)); } // x > 0.5 const z = (1.0 - x) * 0.5; const s = @sqrt(z); const hs: u80 = @bitCast(s); const f: f80 = @bitCast(hs & 0xffff_ffff_ffff_0000_0000); const c = (z - f * f) / (s + f); return 2.0 * (rationalApproxExtended80(z) * s + c + f); } fn rationalApproxBinary128(z: f128) f128 { const pS0: f128 = 1.66666666666666666666666666666700314e-01; const pS1: f128 = -7.32816946414566252574527475428622708e-01; const pS2: f128 = 1.34215708714992334609030036562143589e+00; const pS3: f128 = -1.32483151677116409805070261790752040e+00; const pS4: f128 = 7.61206183613632558824485341162121989e-01; const pS5: f128 = -2.56165783329023486777386833928147375e-01; const pS6: f128 = 4.80718586374448793411019434585413855e-02; const pS7: f128 = -4.42523267167024279410230886239774718e-03; const pS8: f128 = 1.44551535183911458253205638280410064e-04; const pS9: f128 = -2.10558957916600254061591040482706179e-07; const qS1: f128 = -4.84690167848739751544716485245697428e+00; const qS2: f128 = 9.96619113536172610135016921140206980e+00; const qS3: f128 = -1.13177895428973036660836798461641458e+01; const qS4: f128 = 7.74004374389488266169304117714658761e+00; const qS5: f128 = -3.25871986053534084709023539900339905e+00; const qS6: f128 = 8.27830318881232209752469022352928864e-01; const qS7: f128 = -1.18768052702942805423330715206348004e-01; const qS8: f128 = 8.32600764660522313269101537926539470e-03; const qS9: f128 = -1.99407384882605586705979504567947007e-04; const p = z * (pS0 + z * (pS1 + z * (pS2 + z * (pS3 + z * (pS4 + z * (pS5 + z * (pS6 + z * (pS7 + z * (pS8 + z * pS9))))))))); const q = 1.0 + z * (qS1 + z * (qS2 + z * (qS3 + z * (qS4 + z * (qS5 + z * (qS6 + z * (qS7 + z * (qS8 + z * qS9)))))))); return p / q; } fn acosBinary128(x: f128) f128 { const pio2_hi: f128 = 1.57079632679489661923132169163975140; const pio2_lo: f128 = 4.33590506506189051239852201302167613e-35; const hx: u128 = @bitCast(x); const se: u16 = @truncate(hx >> 112); const e = se & 0x7fff; // |x| >= 1 or nan if (e >= 0x3fff) { if (x == 1.0) { return 0.0; } if (x == -1.0) { return 2 * pio2_hi + 0x1p-120; } return 0.0 / (x - x); } // |x| < 0.5 if (e < 0x3fff - 1) { if (e < 0x3fff - math.floatFractionalBits(f128)) { return pio2_hi + 0x1p-120; } return pio2_hi - (rationalApproxBinary128(x * x) * x - pio2_lo + x); } // x < -0.5 if (se >> 15 != 0) { const z = (1 + x) * 0.5; const s = @sqrt(z); return 2 * (pio2_hi - (rationalApproxBinary128(z) * s - pio2_lo + s)); } // x > 0.5 const z = (1.0 - x) * 0.5; const s = @sqrt(z); const hs: u128 = @bitCast(s); const f: f128 = @bitCast(hs & 0xffff_ffff_ffff_ffff_0000_0000_0000_0000); const c = (z - f * f) / (s + f); return 2.0 * (rationalApproxBinary128(z) * s + c + f); } test "acosBinary16.special" { try testing.expectApproxEqAbs(0x1.92p0, acosBinary16(0x0p+0), math.floatEpsAt(f16, 0x1.92p0)); try testing.expectApproxEqAbs(0x1.92p1, acosBinary16(-0x1p+0), math.floatEpsAt(f16, 0x1.92p1)); try testing.expectEqual(0x0p+0, acosBinary16(0x1p+0)); try testing.expect(math.isNan(acosBinary16(0x1.004p0))); try testing.expect(math.isNan(acosBinary16(-0x1.004p0))); try testing.expect(math.isNan(acosBinary16(math.inf(f16)))); try testing.expect(math.isNan(acosBinary16(-math.inf(f16)))); try testing.expect(math.isNan(acosBinary16(math.nan(f16)))); } test "acosBinary16" { try testing.expectApproxEqAbs(0x1.834p0, acosBinary16(0x1.db4p-5), math.floatEpsAt(f16, 0x1.834p0)); try testing.expectApproxEqAbs(0x1.d48p0, acosBinary16(-0x1.068p-2), math.floatEpsAt(f16, 0x1.d48p0)); try testing.expectApproxEqAbs(0x1.b7cp0, acosBinary16(-0x1.2c4p-3), math.floatEpsAt(f16, 0x1.b7cp0)); try testing.expectApproxEqAbs(0x1.654p0, acosBinary16(0x1.65p-3), math.floatEpsAt(f16, 0x1.654p0)); try testing.expectApproxEqAbs(0x1.6d8p-2, acosBinary16(0x1.dfcp-1), math.floatEpsAt(f16, 0x1.6d8p-2)); try testing.expectApproxEqAbs(0x1.32p1, acosBinary16(-0x1.764p-1), math.floatEpsAt(f16, 0x1.32p1)); try testing.expectApproxEqAbs(0x1.5b8p0, acosBinary16(0x1.b18p-3), math.floatEpsAt(f16, 0x1.5b8p0)); try testing.expectApproxEqAbs(0x1.668p0, acosBinary16(0x1.5acp-3), math.floatEpsAt(f16, 0x1.668p0)); try testing.expectApproxEqAbs(0x1.134p1, acosBinary16(-0x1.18cp-1), math.floatEpsAt(f16, 0x1.134p1)); try testing.expectApproxEqAbs(0x1.0dp1, acosBinary16(-0x1.03p-1), math.floatEpsAt(f16, 0x1.0dp1)); } test "acosBinary32.special" { try testing.expectApproxEqAbs(0x1.921fb6p+0, acosBinary32(0x0p+0), math.floatEpsAt(f32, 0x1.921fb6p+0)); try testing.expectApproxEqAbs(0x1.921fb6p+1, acosBinary32(-0x1p+0), math.floatEpsAt(f32, 0x1.921fb6p+1)); try testing.expectEqual(0x0p+0, acosBinary32(0x1p+0)); try testing.expect(math.isNan(acosBinary32(0x1.000002p+0))); try testing.expect(math.isNan(acosBinary32(-0x1.000002p+0))); try testing.expect(math.isNan(acosBinary32(math.inf(f32)))); try testing.expect(math.isNan(acosBinary32(-math.inf(f32)))); try testing.expect(math.isNan(acosBinary32(math.nan(f32)))); } test "acosBinary32" { try testing.expectApproxEqAbs(0x1.d7c4e6p+0, acosBinary32(-0x1.13284cp-2), math.floatEpsAt(f32, 0x1.d7c4e6p+0)); try testing.expectApproxEqAbs(0x1.8e6756p-1, acosBinary32(0x1.6ca8ep-1), math.floatEpsAt(f32, 0x1.8e6756p-1)); try testing.expectApproxEqAbs(0x1.f9d74cp-2, acosBinary32(0x1.c2ca6p-1), math.floatEpsAt(f32, 0x1.f9d74cp-2)); try testing.expectApproxEqAbs(0x1.26abdcp+1, acosBinary32(-0x1.55f12p-1), math.floatEpsAt(f32, 0x1.26abdcp+1)); try testing.expectApproxEqAbs(0x1.d85a44p+0, acosBinary32(-0x1.15679ep-2), math.floatEpsAt(f32, 0x1.d85a44p+0)); try testing.expectApproxEqAbs(0x1.9c2f68p+0, acosBinary32(-0x1.41e132p-5), math.floatEpsAt(f32, 0x1.9c2f68p+0)); try testing.expectApproxEqAbs(0x1.e881bp-1, acosBinary32(0x1.281b0ep-1), math.floatEpsAt(f32, 0x1.e881bp-1)); try testing.expectApproxEqAbs(0x1.1713f6p-1, acosBinary32(0x1.b5ce34p-1), math.floatEpsAt(f32, 0x1.1713f6p-1)); try testing.expectApproxEqAbs(0x1.bd5accp+0, acosBinary32(-0x1.583482p-3), math.floatEpsAt(f32, 0x1.bd5accp+0)); try testing.expectApproxEqAbs(0x1.6ce7d8p+1, acosBinary32(-0x1.ea8224p-1), math.floatEpsAt(f32, 0x1.6ce7d8p+1)); } test "acosBinary64.special" { try testing.expectApproxEqAbs(0x1.921fb54442d18p+0, acosBinary64(0x0p+0), math.floatEpsAt(f64, 0x1.921fb54442d18p+0)); try testing.expectApproxEqAbs(0x1.921fb54442d18p+1, acosBinary64(-0x1p+0), math.floatEpsAt(f64, 0x1.921fb54442d18p+1)); try testing.expectEqual(0x0p+0, acosBinary64(0x1p+0)); try testing.expect(math.isNan(acosBinary64(0x1.0000000000001p+0))); try testing.expect(math.isNan(acosBinary64(-0x1.0000000000001p+0))); try testing.expect(math.isNan(acosBinary64(math.inf(f64)))); try testing.expect(math.isNan(acosBinary64(-math.inf(f64)))); try testing.expect(math.isNan(acosBinary64(math.nan(f64)))); } test "acosBinary64" { try testing.expectApproxEqAbs(0x1.d7c4e61020905p+0, acosBinary64(-0x1.13284b2b5006dp-2), math.floatEpsAt(f64, 0x1.d7c4e61020905p+0)); try testing.expectApproxEqAbs(0x1.8e6756e27c366p-1, acosBinary64(0x1.6ca8dfb825911p-1), math.floatEpsAt(f64, 0x1.8e6756e27c366p-1)); try testing.expectApproxEqAbs(0x1.f9d748eaf956p-2, acosBinary64(0x1.c2ca609de7505p-1), math.floatEpsAt(f64, 0x1.f9d748eaf956p-2)); try testing.expectApproxEqAbs(0x1.26abdc68d07aap+1, acosBinary64(-0x1.55f11fba96889p-1), math.floatEpsAt(f64, 0x1.26abdc68d07aap+1)); try testing.expectApproxEqAbs(0x1.d85a44ea44fe4p+0, acosBinary64(-0x1.15679e27084ddp-2), math.floatEpsAt(f64, 0x1.d85a44ea44fe4p+0)); try testing.expectApproxEqAbs(0x1.9c2f688eee8abp+0, acosBinary64(-0x1.41e131b093c41p-5), math.floatEpsAt(f64, 0x1.9c2f688eee8abp+0)); try testing.expectApproxEqAbs(0x1.e881b1d4eb2a1p-1, acosBinary64(0x1.281b0d18455f5p-1), math.floatEpsAt(f64, 0x1.e881b1d4eb2a1p-1)); try testing.expectApproxEqAbs(0x1.1713f567a87efp-1, acosBinary64(0x1.b5ce34a51b239p-1), math.floatEpsAt(f64, 0x1.1713f567a87efp-1)); try testing.expectApproxEqAbs(0x1.bd5acbe8fcc59p+0, acosBinary64(-0x1.583481079de4dp-3), math.floatEpsAt(f64, 0x1.bd5acbe8fcc59p+0)); try testing.expectApproxEqAbs(0x1.6ce7d66f628e5p+1, acosBinary64(-0x1.ea8223103b871p-1), math.floatEpsAt(f64, 0x1.6ce7d66f628e5p+1)); } test "acosExtended80.special" { try testing.expectApproxEqAbs(0x1.921fb54442d1846ap+0, acosExtended80(0x0p+0), math.floatEpsAt(f80, 0x1.921fb54442d1846ap+0)); try testing.expectApproxEqAbs(0x1.921fb54442d1846ap+1, acosExtended80(-0x1p+0), math.floatEpsAt(f80, 0x1.921fb54442d1846ap+1)); try testing.expectEqual(0x0p+0, acosExtended80(0x1p+0)); try testing.expect(math.isNan(acosExtended80(0x1.0000000000000002p+0))); try testing.expect(math.isNan(acosExtended80(-0x1.0000000000000002p+0))); try testing.expect(math.isNan(acosExtended80(math.inf(f80)))); try testing.expect(math.isNan(acosExtended80(-math.inf(f80)))); try testing.expect(math.isNan(acosExtended80(math.nan(f80)))); } test "acosExtended80" { try testing.expectApproxEqAbs(0x1.86b349040d28f794p-1, acosExtended80(0x1.72068a321edc8804p-1), math.floatEpsAt(f80, 0x1.86b349040d28f794p-1)); try testing.expectApproxEqAbs(0x1.d4923ade73ec379cp0, acosExtended80(-0x1.06d0a467d22977ecp-2), math.floatEpsAt(f80, 0x1.d4923ade73ec379cp0)); try testing.expectApproxEqAbs(0x1.62e0e8898c6d04f2p0, acosExtended80(0x1.77d21385faa9798ap-3), math.floatEpsAt(f80, 0x1.62e0e8898c6d04f2p0)); try testing.expectApproxEqAbs(0x1.3123cbcd5dc4bd58p1, acosExtended80(-0x1.73ee3e8bc2a44dbep-1), math.floatEpsAt(f80, 0x1.3123cbcd5dc4bd58p1)); try testing.expectApproxEqAbs(0x1.062a6d562df2d316p0, acosExtended80(0x1.0a2dd1f6ffcf668ap-1), math.floatEpsAt(f80, 0x1.062a6d562df2d316p0)); try testing.expectApproxEqAbs(0x1.5ffd68b520aa55fap0, acosExtended80(0x1.8e835c490a3aff9ep-3), math.floatEpsAt(f80, 0x1.5ffd68b520aa55fap0)); try testing.expectApproxEqAbs(0x1.5bfe6cabda700684p0, acosExtended80(0x1.add20cdc1565064cp-3), math.floatEpsAt(f80, 0x1.5bfe6cabda700684p0)); try testing.expectApproxEqAbs(0x1.90fe1c993b571924p0, acosExtended80(0x1.21986d43727fca72p-8), math.floatEpsAt(f80, 0x1.90fe1c993b571924p0)); try testing.expectApproxEqAbs(0x1.18044ccc626e7f9ep0, acosExtended80(0x1.d61e0b3fae6a0564p-2), math.floatEpsAt(f80, 0x1.18044ccc626e7f9ep0)); try testing.expectApproxEqAbs(0x1.a39513b6c16532b4p0, acosExtended80(-0x1.171e7c4a41883ccap-4), math.floatEpsAt(f80, 0x1.a39513b6c16532b4p0)); } test "acosBinary128.special" { try testing.expectApproxEqAbs(0x1.921fb54442d18469898cc51701b8p0, acosBinary128(0x0p+0), math.floatEpsAt(f128, 0x1.921fb54442d18469898cc51701b8p0)); try testing.expectApproxEqAbs(0x1.921fb54442d18469898cc51701b8p1, acosBinary128(-0x1p+0), math.floatEpsAt(f128, 0x1.921fb54442d18469898cc51701b8p1)); try testing.expectEqual(0x0p+0, acosBinary128(0x1p+0)); try testing.expect(math.isNan(acosBinary128(0x1.0000000000000000000000000001p0))); try testing.expect(math.isNan(acosBinary128(-0x1.0000000000000000000000000001p0))); try testing.expect(math.isNan(acosBinary128(math.inf(f128)))); try testing.expect(math.isNan(acosBinary128(-math.inf(f128)))); try testing.expect(math.isNan(acosBinary128(math.nan(f128)))); } test "acosBinary128" { try testing.expectApproxEqAbs(0x1.250e9a58f049eeafa99db4360c88p1, acosBinary128(-0x1.511bdb99a3c4373bedf834ef4f68p-1), math.floatEpsAt(f128, 0x1.250e9a58f049eeafa99db4360c88p1)); try testing.expectApproxEqAbs(0x1.2786664b1c676c99437b68590004p1, acosBinary128(-0x1.5879cc3ad6dfd2a52e9891c69808p-1), math.floatEpsAt(f128, 0x1.2786664b1c676c99437b68590004p1)); try testing.expectApproxEqAbs(0x1.cb190cd361c7c03a09c470b4caebp-1, acosBinary128(0x1.3f988ba64a7eb97a751c5f0b3077p-1), math.floatEpsAt(f128, 0x1.cb190cd361c7c03a09c470b4caebp-1)); try testing.expectApproxEqAbs(0x1.1f373be697880111758f582b1a96p1, acosBinary128(-0x1.3f2d96c7768e4c4fa02315727959p-1), math.floatEpsAt(f128, 0x1.1f373be697880111758f582b1a96p1)); try testing.expectApproxEqAbs(0x1.0d92fd2a0a6ca3e4853c1de9ea6ap0, acosBinary128(0x1.fad303c2e28c1f4d8f9fd0e5686fp-2), math.floatEpsAt(f128, 0x1.0d92fd2a0a6ca3e4853c1de9ea6ap0)); try testing.expectApproxEqAbs(0x1.15d4b306e16fbf9ea4f29e82b154p0, acosBinary128(0x1.ddde322bd1a2ee50c5ba30c9c617p-2), math.floatEpsAt(f128, 0x1.15d4b306e16fbf9ea4f29e82b154p0)); try testing.expectApproxEqAbs(0x1.49b0a0355a5539052388e8a6dc11p1, acosBinary128(-0x1.b02f6adefcbeb1d48666b827ff17p-1), math.floatEpsAt(f128, 0x1.49b0a0355a5539052388e8a6dc11p1)); try testing.expectApproxEqAbs(0x1.1be0b757f4cef022f5d2422b9c78p0, acosBinary128(0x1.c8581cce7cd3f6efab0fc60d9b7dp-2), math.floatEpsAt(f128, 0x1.1be0b757f4cef022f5d2422b9c78p0)); try testing.expectApproxEqAbs(0x1.513270e671db2d840f20b0186c2cp1, acosBinary128(-0x1.bf887b8c4e33cbef59993056f3dep-1), math.floatEpsAt(f128, 0x1.513270e671db2d840f20b0186c2cp1)); try testing.expectApproxEqAbs(0x1.70851a509f0e8bfbe780aa8f29f9p0, acosBinary128(0x1.0c0f600ab6f9c84c6102942044cep-3), math.floatEpsAt(f128, 0x1.70851a509f0e8bfbe780aa8f29f9p0)); } fn acosBinary32Vec(comptime vec_len: comptime_int, x: @Vector(vec_len, f32)) @TypeOf(x) { const pi: @Vector(vec_len, f32) = @splat(math.pi); const pi_over_2: @Vector(vec_len, f32) = @splat(math.pi / 2.0); const zero: @Vector(vec_len, f32) = @splat(0.0); const half: @Vector(vec_len, f32) = @splat(0.5); const neg_one: @Vector(vec_len, f32) = @splat(-1.0); const two: @Vector(vec_len, f32) = @splat(2.0); const c0: @Vector(vec_len, f32) = @splat(0x1.55555ep-3); const c1: @Vector(vec_len, f32) = @splat(0x1.33261ap-4); const c2: @Vector(vec_len, f32) = @splat(0x1.70d7dcp-5); const c3: @Vector(vec_len, f32) = @splat(0x1.b059dp-6); const c4: @Vector(vec_len, f32) = @splat(0x1.3af7d8p-5); const ax = @abs(x); const ax_lt_half = ax < half; const is_neg = x < zero; const z2 = @select(f32, ax_lt_half, x * x, @mulAdd(@Vector(vec_len, f32), -half, ax, half)); const z = @select(f32, ax_lt_half, ax, @sqrt(z2)); const z3 = z2 * z; const p3_4 = @mulAdd(@Vector(vec_len, f32), z2, c4, c3); const p2_4 = @mulAdd(@Vector(vec_len, f32), z2, p3_4, c2); const p1_4 = @mulAdd(@Vector(vec_len, f32), z2, p2_4, c1); const p0_4 = @mulAdd(@Vector(vec_len, f32), z2, p1_4, c0); const p = @mulAdd(@Vector(vec_len, f32), z3, p0_4, z); const mul = @select(f32, ax_lt_half, neg_one, two); const add = @select(f32, ax_lt_half, pi_over_2, @select(f32, is_neg, pi, zero)); return @mulAdd(@Vector(vec_len, f32), mul, @select(f32, is_neg, -p, p), add); } fn acosBinary64Vec(comptime vec_len: comptime_int, x: @Vector(vec_len, f64)) @TypeOf(x) { const pi: @Vector(vec_len, f64) = @splat(math.pi); const pi_over_2: @Vector(vec_len, f64) = @splat(math.pi / 2.0); const zero: @Vector(vec_len, f64) = @splat(0.0); const half: @Vector(vec_len, f64) = @splat(0.5); const neg_one: @Vector(vec_len, f64) = @splat(-1.0); const two: @Vector(vec_len, f64) = @splat(2.0); const c0: @Vector(vec_len, f64) = @splat(0x1.555555555554ep-3); const c1: @Vector(vec_len, f64) = @splat(0x1.3333333337233p-4); const c2: @Vector(vec_len, f64) = @splat(0x1.6db6db67f6d9fp-5); const c3: @Vector(vec_len, f64) = @splat(0x1.f1c71fbd29fbbp-6); const c4: @Vector(vec_len, f64) = @splat(0x1.6e8b264d467d6p-6); const c5: @Vector(vec_len, f64) = @splat(0x1.1c5997c357e9dp-6); const c6: @Vector(vec_len, f64) = @splat(0x1.c86a22cd9389dp-7); const c7: @Vector(vec_len, f64) = @splat(0x1.856073c22ebbep-7); const c8: @Vector(vec_len, f64) = @splat(0x1.fd1151acb6bedp-8); const c9: @Vector(vec_len, f64) = @splat(0x1.087182f799c1dp-6); const c10: @Vector(vec_len, f64) = @splat(-0x1.6602748120927p-7); const c11: @Vector(vec_len, f64) = @splat(0x1.cfa0dd1f9478p-6); const ax = @abs(x); const ax_lt_half = ax < half; const is_neg = x < zero; const z2 = @select(f64, ax_lt_half, x * x, @mulAdd(@Vector(vec_len, f64), -half, ax, half)); const z = @select(f64, ax_lt_half, ax, @sqrt(z2)); const z3 = z2 * z; const z4 = z2 * z2; const z8 = z4 * z4; const p0_1 = @mulAdd(@Vector(vec_len, f64), z2, c1, c0); const p2_3 = @mulAdd(@Vector(vec_len, f64), z2, c3, c2); const p0_3 = @mulAdd(@Vector(vec_len, f64), z4, p2_3, p0_1); const p4_5 = @mulAdd(@Vector(vec_len, f64), z2, c5, c4); const p6_7 = @mulAdd(@Vector(vec_len, f64), z2, c7, c6); const p4_7 = @mulAdd(@Vector(vec_len, f64), z4, p6_7, p4_5); const p8_9 = @mulAdd(@Vector(vec_len, f64), z2, c9, c8); const p10_11 = @mulAdd(@Vector(vec_len, f64), z2, c11, c10); const p8_11 = @mulAdd(@Vector(vec_len, f64), z4, p10_11, p8_9); const p4_11 = @mulAdd(@Vector(vec_len, f64), z8, p8_11, p4_7); const p0_11 = @mulAdd(@Vector(vec_len, f64), z8, p4_11, p0_3); const p = @mulAdd(@Vector(vec_len, f64), z3, p0_11, z); const mul = @select(f64, ax_lt_half, neg_one, two); const add = @select(f64, ax_lt_half, pi_over_2, @select(f64, is_neg, pi, zero)); return @mulAdd(@Vector(vec_len, f64), mul, @select(f64, is_neg, -p, p), add); } test "acosBinary32Vec.special" { const input: @Vector(8, f32) = .{ 0x0p+0, -0x1p+0, 0x1p+0, 0x1.000002p+0, -0x1.000002p+0, math.inf(f32), -math.inf(f32), math.nan(f32), }; const output = acosBinary32Vec(8, input); try testing.expectApproxEqAbs(0x1.921fb6p+0, output[0], math.floatEpsAt(f32, 0x1.921fb6p+0)); try testing.expectApproxEqAbs(0x1.921fb6p+1, output[1], math.floatEpsAt(f32, 0x1.921fb6p+1)); try testing.expectEqual(0x0p+0, output[2]); try testing.expect(math.isNan(output[3])); try testing.expect(math.isNan(output[4])); try testing.expect(math.isNan(output[5])); try testing.expect(math.isNan(output[6])); try testing.expect(math.isNan(output[7])); } test "acosBinary32Vec" { const input: @Vector(10, f32) = .{ -0x1.13284cp-2, 0x1.6ca8ep-1, 0x1.c2ca6p-1, -0x1.55f12p-1, -0x1.15679ep-2, -0x1.41e132p-5, 0x1.281b0ep-1, 0x1.b5ce34p-1, -0x1.583482p-3, -0x1.ea8224p-1, }; const output = acosBinary32Vec(10, input); try testing.expectApproxEqAbs(0x1.d7c4e6p+0, output[0], math.floatEpsAt(f32, 0x1.d7c4e6p+0)); try testing.expectApproxEqAbs(0x1.8e6756p-1, output[1], math.floatEpsAt(f32, 0x1.8e6756p-1)); try testing.expectApproxEqAbs(0x1.f9d74cp-2, output[2], math.floatEpsAt(f32, 0x1.f9d74cp-2)); try testing.expectApproxEqAbs(0x1.26abdcp+1, output[3], math.floatEpsAt(f32, 0x1.26abdcp+1)); try testing.expectApproxEqAbs(0x1.d85a44p+0, output[4], math.floatEpsAt(f32, 0x1.d85a44p+0)); try testing.expectApproxEqAbs(0x1.9c2f68p+0, output[5], math.floatEpsAt(f32, 0x1.9c2f68p+0)); try testing.expectApproxEqAbs(0x1.e881bp-1, output[6], math.floatEpsAt(f32, 0x1.e881bp-1)); try testing.expectApproxEqAbs(0x1.1713f6p-1, output[7], math.floatEpsAt(f32, 0x1.1713f6p-1)); try testing.expectApproxEqAbs(0x1.bd5accp+0, output[8], math.floatEpsAt(f32, 0x1.bd5accp+0)); try testing.expectApproxEqAbs(0x1.6ce7d8p+1, output[9], math.floatEpsAt(f32, 0x1.6ce7d8p+1)); } test "acosBinary64Vec.special" { const input: @Vector(8, f64) = .{ 0x0p+0, -0x1p+0, 0x1p+0, 0x1.0000000000001p+0, -0x1.0000000000001p+0, math.inf(f64), -math.inf(f64), math.nan(f64), }; const output = acosBinary64Vec(8, input); try testing.expectApproxEqAbs(0x1.921fb54442d18p+0, output[0], math.floatEpsAt(f64, 0x1.921fb54442d18p+0)); try testing.expectApproxEqAbs(0x1.921fb54442d18p+1, output[1], math.floatEpsAt(f64, 0x1.921fb54442d18p+1)); try testing.expectEqual(0x0p+0, output[2]); try testing.expect(math.isNan(output[3])); try testing.expect(math.isNan(output[4])); try testing.expect(math.isNan(output[5])); try testing.expect(math.isNan(output[6])); try testing.expect(math.isNan(output[7])); } test "acosBinary64Vec" { const input: @Vector(10, f64) = .{ -0x1.13284b2b5006dp-2, 0x1.6ca8dfb825911p-1, 0x1.c2ca609de7505p-1, -0x1.55f11fba96889p-1, -0x1.15679e27084ddp-2, -0x1.41e131b093c41p-5, 0x1.281b0d18455f5p-1, 0x1.b5ce34a51b239p-1, -0x1.583481079de4dp-3, -0x1.ea8223103b871p-1, }; const output = acosBinary64Vec(10, input); try testing.expectApproxEqAbs(0x1.d7c4e61020905p+0, output[0], math.floatEpsAt(f64, 0x1.d7c4e61020905p+0)); try testing.expectApproxEqAbs(0x1.8e6756e27c366p-1, output[1], math.floatEpsAt(f64, 0x1.8e6756e27c366p-1)); try testing.expectApproxEqAbs(0x1.f9d748eaf956p-2, output[2], math.floatEpsAt(f64, 0x1.f9d748eaf956p-2)); try testing.expectApproxEqAbs(0x1.26abdc68d07aap+1, output[3], math.floatEpsAt(f64, 0x1.26abdc68d07aap+1)); try testing.expectApproxEqAbs(0x1.d85a44ea44fe4p+0, output[4], math.floatEpsAt(f64, 0x1.d85a44ea44fe4p+0)); try testing.expectApproxEqAbs(0x1.9c2f688eee8abp+0, output[5], math.floatEpsAt(f64, 0x1.9c2f688eee8abp+0)); try testing.expectApproxEqAbs(0x1.e881b1d4eb2a1p-1, output[6], math.floatEpsAt(f64, 0x1.e881b1d4eb2a1p-1)); try testing.expectApproxEqAbs(0x1.1713f567a87efp-1, output[7], math.floatEpsAt(f64, 0x1.1713f567a87efp-1)); try testing.expectApproxEqAbs(0x1.bd5acbe8fcc59p+0, output[8], math.floatEpsAt(f64, 0x1.bd5acbe8fcc59p+0)); try testing.expectApproxEqAbs(0x1.6ce7d66f628e5p+1, output[9], math.floatEpsAt(f64, 0x1.6ce7d66f628e5p+1)); }