mirror of
https://github.com/ziglang/zig.git
synced 2024-12-03 18:38:45 +00:00
30f2bb8464
When we're compiling compiler_rt for any WebAssembly target, we do not want to expose all the compiler-rt functions to the host runtime. By setting the visibility of all exports to `hidden`, we allow the linker to resolve the symbols during linktime, while not expose the functions to the host runtime. This also means the linker can properly garbage collect any compiler-rt function that does not get resolved. The symbol visibility for all target remains the same as before: `default`.
191 lines
6.3 KiB
Zig
191 lines
6.3 KiB
Zig
//! Ported from musl, which is licensed under the MIT license:
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//! https://git.musl-libc.org/cgit/musl/tree/COPYRIGHT
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//!
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//! https://git.musl-libc.org/cgit/musl/tree/src/math/sinf.c
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//! https://git.musl-libc.org/cgit/musl/tree/src/math/sin.c
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const std = @import("std");
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const builtin = @import("builtin");
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const arch = builtin.cpu.arch;
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const math = std.math;
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const expect = std.testing.expect;
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const common = @import("common.zig");
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const trig = @import("trig.zig");
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const rem_pio2 = @import("rem_pio2.zig").rem_pio2;
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const rem_pio2f = @import("rem_pio2f.zig").rem_pio2f;
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pub const panic = common.panic;
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comptime {
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@export(__sinh, .{ .name = "__sinh", .linkage = common.linkage, .visibility = common.visibility });
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@export(sinf, .{ .name = "sinf", .linkage = common.linkage, .visibility = common.visibility });
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@export(sin, .{ .name = "sin", .linkage = common.linkage, .visibility = common.visibility });
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@export(__sinx, .{ .name = "__sinx", .linkage = common.linkage, .visibility = common.visibility });
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if (common.want_ppc_abi) {
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@export(sinq, .{ .name = "sinf128", .linkage = common.linkage, .visibility = common.visibility });
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}
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@export(sinq, .{ .name = "sinq", .linkage = common.linkage, .visibility = common.visibility });
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@export(sinl, .{ .name = "sinl", .linkage = common.linkage, .visibility = common.visibility });
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}
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pub fn __sinh(x: f16) callconv(.C) f16 {
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// TODO: more efficient implementation
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return @floatCast(f16, sinf(x));
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}
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pub fn sinf(x: f32) callconv(.C) f32 {
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// Small multiples of pi/2 rounded to double precision.
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const s1pio2: f64 = 1.0 * math.pi / 2.0; // 0x3FF921FB, 0x54442D18
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const s2pio2: f64 = 2.0 * math.pi / 2.0; // 0x400921FB, 0x54442D18
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const s3pio2: f64 = 3.0 * math.pi / 2.0; // 0x4012D97C, 0x7F3321D2
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const s4pio2: f64 = 4.0 * math.pi / 2.0; // 0x401921FB, 0x54442D18
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var ix = @bitCast(u32, x);
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const sign = ix >> 31 != 0;
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ix &= 0x7fffffff;
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if (ix <= 0x3f490fda) { // |x| ~<= pi/4
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if (ix < 0x39800000) { // |x| < 2**-12
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// raise inexact if x!=0 and underflow if subnormal
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math.doNotOptimizeAway(if (ix < 0x00800000) x / 0x1p120 else x + 0x1p120);
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return x;
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}
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return trig.__sindf(x);
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}
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if (ix <= 0x407b53d1) { // |x| ~<= 5*pi/4
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if (ix <= 0x4016cbe3) { // |x| ~<= 3pi/4
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if (sign) {
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return -trig.__cosdf(x + s1pio2);
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} else {
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return trig.__cosdf(x - s1pio2);
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}
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}
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return trig.__sindf(if (sign) -(x + s2pio2) else -(x - s2pio2));
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}
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if (ix <= 0x40e231d5) { // |x| ~<= 9*pi/4
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if (ix <= 0x40afeddf) { // |x| ~<= 7*pi/4
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if (sign) {
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return trig.__cosdf(x + s3pio2);
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} else {
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return -trig.__cosdf(x - s3pio2);
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}
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}
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return trig.__sindf(if (sign) x + s4pio2 else x - s4pio2);
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}
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// sin(Inf or NaN) is NaN
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if (ix >= 0x7f800000) {
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return x - x;
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}
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var y: f64 = undefined;
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const n = rem_pio2f(x, &y);
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return switch (n & 3) {
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0 => trig.__sindf(y),
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1 => trig.__cosdf(y),
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2 => trig.__sindf(-y),
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else => -trig.__cosdf(y),
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};
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}
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pub fn sin(x: f64) callconv(.C) f64 {
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var ix = @bitCast(u64, x) >> 32;
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ix &= 0x7fffffff;
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// |x| ~< pi/4
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if (ix <= 0x3fe921fb) {
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if (ix < 0x3e500000) { // |x| < 2**-26
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// raise inexact if x != 0 and underflow if subnormal
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math.doNotOptimizeAway(if (ix < 0x00100000) x / 0x1p120 else x + 0x1p120);
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return x;
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}
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return trig.__sin(x, 0.0, 0);
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}
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// sin(Inf or NaN) is NaN
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if (ix >= 0x7ff00000) {
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return x - x;
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}
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var y: [2]f64 = undefined;
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const n = rem_pio2(x, &y);
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return switch (n & 3) {
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0 => trig.__sin(y[0], y[1], 1),
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1 => trig.__cos(y[0], y[1]),
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2 => -trig.__sin(y[0], y[1], 1),
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else => -trig.__cos(y[0], y[1]),
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};
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}
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pub fn __sinx(x: f80) callconv(.C) f80 {
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// TODO: more efficient implementation
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return @floatCast(f80, sinq(x));
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}
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pub fn sinq(x: f128) callconv(.C) f128 {
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// TODO: more correct implementation
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return sin(@floatCast(f64, x));
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}
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pub fn sinl(x: c_longdouble) callconv(.C) c_longdouble {
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switch (@typeInfo(c_longdouble).Float.bits) {
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16 => return __sinh(x),
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32 => return sinf(x),
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64 => return sin(x),
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80 => return __sinx(x),
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128 => return sinq(x),
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else => @compileError("unreachable"),
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}
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}
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test "sin32" {
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const epsilon = 0.00001;
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try expect(math.approxEqAbs(f32, sinf(0.0), 0.0, epsilon));
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try expect(math.approxEqAbs(f32, sinf(0.2), 0.198669, epsilon));
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try expect(math.approxEqAbs(f32, sinf(0.8923), 0.778517, epsilon));
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try expect(math.approxEqAbs(f32, sinf(1.5), 0.997495, epsilon));
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try expect(math.approxEqAbs(f32, sinf(-1.5), -0.997495, epsilon));
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try expect(math.approxEqAbs(f32, sinf(37.45), -0.246544, epsilon));
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try expect(math.approxEqAbs(f32, sinf(89.123), 0.916166, epsilon));
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}
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test "sin64" {
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const epsilon = 0.000001;
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try expect(math.approxEqAbs(f64, sin(0.0), 0.0, epsilon));
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try expect(math.approxEqAbs(f64, sin(0.2), 0.198669, epsilon));
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try expect(math.approxEqAbs(f64, sin(0.8923), 0.778517, epsilon));
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try expect(math.approxEqAbs(f64, sin(1.5), 0.997495, epsilon));
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try expect(math.approxEqAbs(f64, sin(-1.5), -0.997495, epsilon));
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try expect(math.approxEqAbs(f64, sin(37.45), -0.246543, epsilon));
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try expect(math.approxEqAbs(f64, sin(89.123), 0.916166, epsilon));
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}
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test "sin32.special" {
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try expect(sinf(0.0) == 0.0);
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try expect(sinf(-0.0) == -0.0);
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try expect(math.isNan(sinf(math.inf(f32))));
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try expect(math.isNan(sinf(-math.inf(f32))));
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try expect(math.isNan(sinf(math.nan(f32))));
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}
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test "sin64.special" {
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try expect(sin(0.0) == 0.0);
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try expect(sin(-0.0) == -0.0);
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try expect(math.isNan(sin(math.inf(f64))));
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try expect(math.isNan(sin(-math.inf(f64))));
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try expect(math.isNan(sin(math.nan(f64))));
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}
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test "sin32 #9901" {
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const float = @bitCast(f32, @as(u32, 0b11100011111111110000000000000000));
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_ = sinf(float);
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}
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test "sin64 #9901" {
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const float = @bitCast(f64, @as(u64, 0b1111111101000001000000001111110111111111100000000000000000000001));
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_ = sin(float);
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}
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