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0fe3fd01dd
The compiler actually doesn't need any functional changes for this: Sema does reification based on the tag indices of `std.builtin.Type` already! So, no zig1.wasm update is necessary. This change is necessary to disallow name clashes between fields and decls on a type, which is a prerequisite of #9938.
204 lines
8.2 KiB
Zig
204 lines
8.2 KiB
Zig
const std = @import("std");
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const math = std.math;
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const builtin = @import("builtin");
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const common = @import("./common.zig");
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/// Ported from:
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/// https://github.com/llvm/llvm-project/blob/2ffb1b0413efa9a24eb3c49e710e36f92e2cb50b/compiler-rt/lib/builtins/fp_mul_impl.inc
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pub inline fn mulf3(comptime T: type, a: T, b: T) T {
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@setRuntimeSafety(builtin.is_test);
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const typeWidth = @typeInfo(T).float.bits;
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const significandBits = math.floatMantissaBits(T);
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const fractionalBits = math.floatFractionalBits(T);
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const exponentBits = math.floatExponentBits(T);
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const Z = std.meta.Int(.unsigned, typeWidth);
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// ZSignificand is large enough to contain the significand, including an explicit integer bit
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const ZSignificand = PowerOfTwoSignificandZ(T);
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const ZSignificandBits = @typeInfo(ZSignificand).int.bits;
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const roundBit = (1 << (ZSignificandBits - 1));
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const signBit = (@as(Z, 1) << (significandBits + exponentBits));
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const maxExponent = ((1 << exponentBits) - 1);
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const exponentBias = (maxExponent >> 1);
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const integerBit = (@as(ZSignificand, 1) << fractionalBits);
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const quietBit = integerBit >> 1;
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const significandMask = (@as(Z, 1) << significandBits) - 1;
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const absMask = signBit - 1;
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const qnanRep = @as(Z, @bitCast(math.nan(T))) | quietBit;
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const infRep: Z = @bitCast(math.inf(T));
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const minNormalRep: Z = @bitCast(math.floatMin(T));
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const ZExp = if (typeWidth >= 32) u32 else Z;
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const aExponent: ZExp = @truncate((@as(Z, @bitCast(a)) >> significandBits) & maxExponent);
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const bExponent: ZExp = @truncate((@as(Z, @bitCast(b)) >> significandBits) & maxExponent);
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const productSign: Z = (@as(Z, @bitCast(a)) ^ @as(Z, @bitCast(b))) & signBit;
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var aSignificand: ZSignificand = @intCast(@as(Z, @bitCast(a)) & significandMask);
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var bSignificand: ZSignificand = @intCast(@as(Z, @bitCast(b)) & significandMask);
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var scale: i32 = 0;
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// Detect if a or b is zero, denormal, infinity, or NaN.
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if (aExponent -% 1 >= maxExponent - 1 or bExponent -% 1 >= maxExponent - 1) {
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const aAbs: Z = @as(Z, @bitCast(a)) & absMask;
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const bAbs: Z = @as(Z, @bitCast(b)) & absMask;
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// NaN * anything = qNaN
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if (aAbs > infRep) return @bitCast(@as(Z, @bitCast(a)) | quietBit);
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// anything * NaN = qNaN
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if (bAbs > infRep) return @bitCast(@as(Z, @bitCast(b)) | quietBit);
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if (aAbs == infRep) {
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// infinity * non-zero = +/- infinity
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if (bAbs != 0) {
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return @bitCast(aAbs | productSign);
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} else {
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// infinity * zero = NaN
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return @bitCast(qnanRep);
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}
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}
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if (bAbs == infRep) {
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//? non-zero * infinity = +/- infinity
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if (aAbs != 0) {
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return @bitCast(bAbs | productSign);
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} else {
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// zero * infinity = NaN
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return @bitCast(qnanRep);
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}
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}
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// zero * anything = +/- zero
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if (aAbs == 0) return @bitCast(productSign);
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// anything * zero = +/- zero
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if (bAbs == 0) return @bitCast(productSign);
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// one or both of a or b is denormal, the other (if applicable) is a
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// normal number. Renormalize one or both of a and b, and set scale to
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// include the necessary exponent adjustment.
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if (aAbs < minNormalRep) scale += normalize(T, &aSignificand);
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if (bAbs < minNormalRep) scale += normalize(T, &bSignificand);
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}
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// Or in the implicit significand bit. (If we fell through from the
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// denormal path it was already set by normalize( ), but setting it twice
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// won't hurt anything.)
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aSignificand |= integerBit;
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bSignificand |= integerBit;
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// Get the significand of a*b. Before multiplying the significands, shift
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// one of them left to left-align it in the field. Thus, the product will
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// have (exponentBits + 2) integral digits, all but two of which must be
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// zero. Normalizing this result is just a conditional left-shift by one
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// and bumping the exponent accordingly.
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var productHi: ZSignificand = undefined;
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var productLo: ZSignificand = undefined;
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const left_align_shift = ZSignificandBits - fractionalBits - 1;
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common.wideMultiply(ZSignificand, aSignificand, bSignificand << left_align_shift, &productHi, &productLo);
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var productExponent: i32 = @as(i32, @intCast(aExponent + bExponent)) - exponentBias + scale;
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// Normalize the significand, adjust exponent if needed.
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if ((productHi & integerBit) != 0) {
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productExponent +%= 1;
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} else {
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productHi = (productHi << 1) | (productLo >> (ZSignificandBits - 1));
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productLo = productLo << 1;
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}
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// If we have overflowed the type, return +/- infinity.
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if (productExponent >= maxExponent) return @bitCast(infRep | productSign);
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var result: Z = undefined;
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if (productExponent <= 0) {
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// Result is denormal before rounding
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//
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// If the result is so small that it just underflows to zero, return
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// a zero of the appropriate sign. Mathematically there is no need to
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// handle this case separately, but we make it a special case to
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// simplify the shift logic.
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const shift: u32 = @truncate(@as(Z, 1) -% @as(u32, @bitCast(productExponent)));
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if (shift >= ZSignificandBits) return @bitCast(productSign);
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// Otherwise, shift the significand of the result so that the round
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// bit is the high bit of productLo.
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const sticky = wideShrWithTruncation(ZSignificand, &productHi, &productLo, shift);
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productLo |= @intFromBool(sticky);
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result = productHi;
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// We include the integer bit so that rounding will carry to the exponent,
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// but it will be removed later if the result is still denormal
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if (significandBits != fractionalBits) result |= integerBit;
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} else {
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// Result is normal before rounding; insert the exponent.
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result = productHi & significandMask;
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result |= @as(Z, @intCast(productExponent)) << significandBits;
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}
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// Final rounding. The final result may overflow to infinity, or underflow
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// to zero, but those are the correct results in those cases. We use the
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// default IEEE-754 round-to-nearest, ties-to-even rounding mode.
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if (productLo > roundBit) result +%= 1;
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if (productLo == roundBit) result +%= result & 1;
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// Restore any explicit integer bit, if it was rounded off
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if (significandBits != fractionalBits) {
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if ((result >> significandBits) != 0) {
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result |= integerBit;
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} else {
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result &= ~integerBit;
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}
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}
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// Insert the sign of the result:
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result |= productSign;
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return @bitCast(result);
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}
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/// Returns `true` if the right shift is inexact (i.e. any bit shifted out is non-zero)
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///
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/// This is analogous to an shr version of `@shlWithOverflow`
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fn wideShrWithTruncation(comptime Z: type, hi: *Z, lo: *Z, count: u32) bool {
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@setRuntimeSafety(builtin.is_test);
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const typeWidth = @typeInfo(Z).int.bits;
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var inexact = false;
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if (count < typeWidth) {
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inexact = (lo.* << @intCast(typeWidth -% count)) != 0;
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lo.* = (hi.* << @intCast(typeWidth -% count)) | (lo.* >> @intCast(count));
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hi.* = hi.* >> @intCast(count);
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} else if (count < 2 * typeWidth) {
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inexact = (hi.* << @intCast(2 * typeWidth -% count) | lo.*) != 0;
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lo.* = hi.* >> @intCast(count -% typeWidth);
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hi.* = 0;
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} else {
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inexact = (hi.* | lo.*) != 0;
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lo.* = 0;
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hi.* = 0;
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}
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return inexact;
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}
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fn normalize(comptime T: type, significand: *PowerOfTwoSignificandZ(T)) i32 {
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const Z = PowerOfTwoSignificandZ(T);
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const integerBit = @as(Z, 1) << math.floatFractionalBits(T);
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const shift = @clz(significand.*) - @clz(integerBit);
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significand.* <<= @intCast(shift);
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return @as(i32, 1) - shift;
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}
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/// Returns a power-of-two integer type that is large enough to contain
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/// the significand of T, including an explicit integer bit
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fn PowerOfTwoSignificandZ(comptime T: type) type {
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const bits = math.ceilPowerOfTwoAssert(u16, math.floatFractionalBits(T) + 1);
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return std.meta.Int(.unsigned, bits);
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}
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test {
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_ = @import("mulf3_test.zig");
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}
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