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b8ed0cb374
now that we depend on LLVM 5.0.0 we can remove the workaround. closes #393
202 lines
5.1 KiB
Zig
202 lines
5.1 KiB
Zig
// Special Cases:
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//
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// - modf(+-inf) = +-inf, nan
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// - modf(nan) = nan, nan
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const math = @import("index.zig");
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const assert = @import("../debug.zig").assert;
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fn modf_result(comptime T: type) -> type {
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struct {
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fpart: T,
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ipart: T,
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}
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}
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pub const modf32_result = modf_result(f32);
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pub const modf64_result = modf_result(f64);
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pub fn modf(x: var) -> modf_result(@typeOf(x)) {
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const T = @typeOf(x);
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switch (T) {
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f32 => @inlineCall(modf32, x),
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f64 => @inlineCall(modf64, x),
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else => @compileError("modf not implemented for " ++ @typeName(T)),
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}
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}
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fn modf32(x: f32) -> modf32_result {
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var result: modf32_result = undefined;
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const u = @bitCast(u32, x);
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const e = i32((u >> 23) & 0xFF) - 0x7F;
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const us = u & 0x80000000;
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// TODO: Shouldn't need this.
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if (math.isInf(x)) {
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result.ipart = x;
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result.fpart = math.nan(f32);
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return result;
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}
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// no fractional part
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if (e >= 23) {
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result.ipart = x;
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if (e == 0x80 and u << 9 != 0) { // nan
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result.fpart = x;
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} else {
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result.fpart = @bitCast(f32, us);
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}
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return result;
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}
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// no integral part
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if (e < 0) {
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result.ipart = @bitCast(f32, us);
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result.fpart = x;
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return result;
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}
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const mask = u32(0x007FFFFF) >> u5(e);
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if (u & mask == 0) {
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result.ipart = x;
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result.fpart = @bitCast(f32, us);
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return result;
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}
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const uf = @bitCast(f32, u & ~mask);
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result.ipart = uf;
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result.fpart = x - uf;
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result
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}
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fn modf64(x: f64) -> modf64_result {
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var result: modf64_result = undefined;
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const u = @bitCast(u64, x);
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const e = i32((u >> 52) & 0x7FF) - 0x3FF;
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const us = u & (1 << 63);
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if (math.isInf(x)) {
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result.ipart = x;
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result.fpart = math.nan(f64);
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return result;
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}
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// no fractional part
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if (e >= 52) {
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result.ipart = x;
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if (e == 0x400 and u << 12 != 0) { // nan
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result.fpart = x;
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} else {
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result.fpart = @bitCast(f64, us);
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}
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return result;
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}
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// no integral part
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if (e < 0) {
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result.ipart = @bitCast(f64, us);
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result.fpart = x;
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return result;
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}
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const mask = u64(@maxValue(u64) >> 12) >> u6(e);
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if (u & mask == 0) {
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result.ipart = x;
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result.fpart = @bitCast(f64, us);
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return result;
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}
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const uf = @bitCast(f64, u & ~mask);
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result.ipart = uf;
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result.fpart = x - uf;
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result
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}
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test "math.modf" {
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const a = modf(f32(1.0));
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const b = modf32(1.0);
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// NOTE: No struct comparison on generic return type function? non-named, makes sense, but still.
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assert(a.ipart == b.ipart and a.fpart == b.fpart);
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const c = modf(f64(1.0));
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const d = modf64(1.0);
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assert(a.ipart == b.ipart and a.fpart == b.fpart);
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}
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test "math.modf32" {
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const epsilon = 0.000001;
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var r: modf32_result = undefined;
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r = modf32(1.0);
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assert(math.approxEq(f32, r.ipart, 1.0, epsilon));
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assert(math.approxEq(f32, r.fpart, 0.0, epsilon));
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r = modf32(2.545);
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assert(math.approxEq(f32, r.ipart, 2.0, epsilon));
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assert(math.approxEq(f32, r.fpart, 0.545, epsilon));
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r = modf32(3.978123);
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assert(math.approxEq(f32, r.ipart, 3.0, epsilon));
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assert(math.approxEq(f32, r.fpart, 0.978123, epsilon));
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r = modf32(43874.3);
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assert(math.approxEq(f32, r.ipart, 43874, epsilon));
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assert(math.approxEq(f32, r.fpart, 0.300781, epsilon));
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r = modf32(1234.340780);
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assert(math.approxEq(f32, r.ipart, 1234, epsilon));
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assert(math.approxEq(f32, r.fpart, 0.340820, epsilon));
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}
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test "math.modf64" {
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const epsilon = 0.000001;
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var r: modf64_result = undefined;
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r = modf64(1.0);
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assert(math.approxEq(f64, r.ipart, 1.0, epsilon));
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assert(math.approxEq(f64, r.fpart, 0.0, epsilon));
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r = modf64(2.545);
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assert(math.approxEq(f64, r.ipart, 2.0, epsilon));
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assert(math.approxEq(f64, r.fpart, 0.545, epsilon));
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r = modf64(3.978123);
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assert(math.approxEq(f64, r.ipart, 3.0, epsilon));
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assert(math.approxEq(f64, r.fpart, 0.978123, epsilon));
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r = modf64(43874.3);
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assert(math.approxEq(f64, r.ipart, 43874, epsilon));
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assert(math.approxEq(f64, r.fpart, 0.3, epsilon));
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r = modf64(1234.340780);
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assert(math.approxEq(f64, r.ipart, 1234, epsilon));
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assert(math.approxEq(f64, r.fpart, 0.340780, epsilon));
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}
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test "math.modf32.special" {
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var r: modf32_result = undefined;
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r = modf32(math.inf(f32));
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assert(math.isPositiveInf(r.ipart) and math.isNan(r.fpart));
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r = modf32(-math.inf(f32));
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assert(math.isNegativeInf(r.ipart) and math.isNan(r.fpart));
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r = modf32(math.nan(f32));
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assert(math.isNan(r.ipart) and math.isNan(r.fpart));
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}
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test "math.modf64.special" {
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var r: modf64_result = undefined;
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r = modf64(math.inf(f64));
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assert(math.isPositiveInf(r.ipart) and math.isNan(r.fpart));
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r = modf64(-math.inf(f64));
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assert(math.isNegativeInf(r.ipart) and math.isNan(r.fpart));
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r = modf64(math.nan(f64));
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assert(math.isNan(r.ipart) and math.isNan(r.fpart));
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}
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