// Special Cases: // // - frexp(+-0) = +-0, 0 // - frexp(+-inf) = +-inf, 0 // - frexp(nan) = nan, 0 const math = @import("index.zig"); const assert = @import("../debug.zig").assert; // TODO issue #393 pub const frexp = frexp_workaround; fn frexp_result(comptime T: type) -> type { struct { significand: T, exponent: i32, } } pub const frexp32_result = frexp_result(f32); pub const frexp64_result = frexp_result(f64); pub fn frexp_workaround(x: var) -> frexp_result(@typeOf(x)) { const T = @typeOf(x); switch (T) { f32 => @inlineCall(frexp32, x), f64 => @inlineCall(frexp64, x), else => @compileError("frexp not implemented for " ++ @typeName(T)), } } fn frexp32(x: f32) -> frexp32_result { var result: frexp32_result = undefined; var y = @bitCast(u32, x); const e = i32(y >> 23) & 0xFF; if (e == 0) { if (x != 0) { // subnormal result = frexp32(x * 0x1.0p64); result.exponent -= 64; } else { // frexp(+-0) = (+-0, 0) result.significand = x; result.exponent = 0; } return result; } else if (e == 0xFF) { // frexp(nan) = (nan, 0) result.significand = x; result.exponent = 0; return result; } result.exponent = e - 0x7E; y &= 0x807FFFFF; y |= 0x3F000000; result.significand = @bitCast(f32, y); result } fn frexp64(x: f64) -> frexp64_result { var result: frexp64_result = undefined; var y = @bitCast(u64, x); const e = i32(y >> 52) & 0x7FF; if (e == 0) { if (x != 0) { // subnormal result = frexp64(x * 0x1.0p64); result.exponent -= 64; } else { // frexp(+-0) = (+-0, 0) result.significand = x; result.exponent = 0; } return result; } else if (e == 0x7FF) { result.significand = x; result.exponent = 0; return result; } result.exponent = e - 0x3FE; y &= 0x800FFFFFFFFFFFFF; y |= 0x3FE0000000000000; result.significand = @bitCast(f64, y); result } test "math.frexp" { const a = frexp(f32(1.3)); const b = frexp32(1.3); assert(a.significand == b.significand and a.exponent == b.exponent); const c = frexp(f64(1.3)); const d = frexp64(1.3); assert(c.significand == d.significand and c.exponent == d.exponent); } test "math.frexp32" { const epsilon = 0.000001; var r: frexp32_result = undefined; r = frexp32(1.3); assert(math.approxEq(f32, r.significand, 0.65, epsilon) and r.exponent == 1); r = frexp32(78.0234); assert(math.approxEq(f32, r.significand, 0.609558, epsilon) and r.exponent == 7); } test "math.frexp64" { const epsilon = 0.000001; var r: frexp64_result = undefined; r = frexp64(1.3); assert(math.approxEq(f64, r.significand, 0.65, epsilon) and r.exponent == 1); r = frexp64(78.0234); assert(math.approxEq(f64, r.significand, 0.609558, epsilon) and r.exponent == 7); } test "math.frexp32.special" { var r: frexp32_result = undefined; r = frexp32(0.0); assert(r.significand == 0.0 and r.exponent == 0); r = frexp32(-0.0); assert(r.significand == -0.0 and r.exponent == 0); r = frexp32(math.inf(f32)); assert(math.isPositiveInf(r.significand) and r.exponent == 0); r = frexp32(-math.inf(f32)); assert(math.isNegativeInf(r.significand) and r.exponent == 0); r = frexp32(math.nan(f32)); assert(math.isNan(r.significand) and r.exponent == 0); } test "math.frexp64.special" { var r: frexp64_result = undefined; r = frexp64(0.0); assert(r.significand == 0.0 and r.exponent == 0); r = frexp64(-0.0); assert(r.significand == -0.0 and r.exponent == 0); r = frexp64(math.inf(f64)); assert(math.isPositiveInf(r.significand) and r.exponent == 0); r = frexp64(-math.inf(f64)); assert(math.isNegativeInf(r.significand) and r.exponent == 0); r = frexp64(math.nan(f64)); assert(math.isNan(r.significand) and r.exponent == 0); }