package reedsolomon // This is a O(n*log n) implementation of Reed-Solomon // codes, ported from the C++ library https://github.com/catid/leopard. // // The implementation is based on the paper // // S.-J. Lin, T. Y. Al-Naffouri, Y. S. Han, and W.-H. Chung, // "Novel Polynomial Basis with Fast Fourier Transform // and Its Application to Reed-Solomon Erasure Codes" // IEEE Trans. on Information Theory, pp. 6284-6299, November, 2016. import ( "bytes" "io" "math/bits" "sync" "unsafe" "github.com/klauspost/cpuid/v2" ) // leopardFF16 is like reedSolomon but for more than 256 total shards. type leopardFF16 struct { dataShards int // Number of data shards, should not be modified. parityShards int // Number of parity shards, should not be modified. totalShards int // Total number of shards. Calculated, and should not be modified. workPool sync.Pool o options } // newFF16 is like New, but for more than 256 total shards. func newFF16(dataShards, parityShards int, opt options) (*leopardFF16, error) { initConstants() if dataShards <= 0 || parityShards <= 0 { return nil, ErrInvShardNum } if dataShards+parityShards > 65536 { return nil, ErrMaxShardNum } r := &leopardFF16{ dataShards: dataShards, parityShards: parityShards, totalShards: dataShards + parityShards, o: opt, } return r, nil } var _ = Extensions(&leopardFF16{}) func (r *leopardFF16) ShardSizeMultiple() int { return 64 } func (r *leopardFF16) DataShards() int { return r.dataShards } func (r *leopardFF16) ParityShards() int { return r.parityShards } func (r *leopardFF16) TotalShards() int { return r.parityShards } type ffe uint16 const ( bitwidth = 16 order = 1 << bitwidth modulus = order - 1 polynomial = 0x1002D ) var ( fftSkew *[modulus]ffe logWalsh *[order]ffe ) // Logarithm Tables var ( logLUT *[order]ffe expLUT *[order]ffe ) // Stores the partial products of x * y at offset x + y * 65536 // Repeated accesses from the same y value are faster var mul16LUTs *[order]mul16LUT type mul16LUT struct { // Contains Lo product as a single lookup. // Should be XORed with Hi lookup for result. Lo [256]ffe Hi [256]ffe } // Stores lookup for avx2 var multiply256LUT *[order][8 * 16]byte func (r *leopardFF16) Encode(shards [][]byte) error { if len(shards) != r.totalShards { return ErrTooFewShards } if err := checkShards(shards, false); err != nil { return err } return r.encode(shards) } func (r *leopardFF16) encode(shards [][]byte) error { shardSize := shardSize(shards) if shardSize%64 != 0 { return ErrShardSize } m := ceilPow2(r.parityShards) var work [][]byte if w, ok := r.workPool.Get().([][]byte); ok { work = w } if cap(work) >= m*2 { work = work[:m*2] } else { work = make([][]byte, m*2) } for i := range work { if cap(work[i]) < shardSize { work[i] = make([]byte, shardSize) } else { work[i] = work[i][:shardSize] } } defer r.workPool.Put(work) mtrunc := m if r.dataShards < mtrunc { mtrunc = r.dataShards } skewLUT := fftSkew[m-1:] sh := shards ifftDITEncoder( sh[:r.dataShards], mtrunc, work, nil, // No xor output m, skewLUT, &r.o, ) lastCount := r.dataShards % m if m >= r.dataShards { goto skip_body } // For sets of m data pieces: for i := m; i+m <= r.dataShards; i += m { sh = sh[m:] skewLUT = skewLUT[m:] // work <- work xor IFFT(data + i, m, m + i) ifftDITEncoder( sh, // data source m, work[m:], // temporary workspace work, // xor destination m, skewLUT, &r.o, ) } // Handle final partial set of m pieces: if lastCount != 0 { sh = sh[m:] skewLUT = skewLUT[m:] // work <- work xor IFFT(data + i, m, m + i) ifftDITEncoder( sh, // data source lastCount, work[m:], // temporary workspace work, // xor destination m, skewLUT, &r.o, ) } skip_body: // work <- FFT(work, m, 0) fftDIT(work, r.parityShards, m, fftSkew[:], &r.o) for i, w := range work[:r.parityShards] { sh := shards[i+r.dataShards] if cap(sh) >= shardSize { sh = append(sh[:0], w...) } else { sh = w } shards[i+r.dataShards] = sh } return nil } func (r *leopardFF16) EncodeIdx(dataShard []byte, idx int, parity [][]byte) error { return ErrNotSupported } func (r *leopardFF16) Join(dst io.Writer, shards [][]byte, outSize int) error { // Do we have enough shards? if len(shards) < r.dataShards { return ErrTooFewShards } shards = shards[:r.dataShards] // Do we have enough data? size := 0 for _, shard := range shards { if shard == nil { return ErrReconstructRequired } size += len(shard) // Do we have enough data already? if size >= outSize { break } } if size < outSize { return ErrShortData } // Copy data to dst write := outSize for _, shard := range shards { if write < len(shard) { _, err := dst.Write(shard[:write]) return err } n, err := dst.Write(shard) if err != nil { return err } write -= n } return nil } func (r *leopardFF16) Update(shards [][]byte, newDatashards [][]byte) error { return ErrNotSupported } func (r *leopardFF16) Split(data []byte) ([][]byte, error) { if len(data) == 0 { return nil, ErrShortData } dataLen := len(data) // Calculate number of bytes per data shard. perShard := (len(data) + r.dataShards - 1) / r.dataShards perShard = ((perShard + 63) / 64) * 64 if cap(data) > len(data) { data = data[:cap(data)] } // Only allocate memory if necessary var padding []byte if len(data) < (r.totalShards * perShard) { // calculate maximum number of full shards in `data` slice fullShards := len(data) / perShard padding = make([]byte, r.totalShards*perShard-perShard*fullShards) copy(padding, data[perShard*fullShards:]) data = data[0 : perShard*fullShards] } else { for i := dataLen; i < dataLen+r.dataShards; i++ { data[i] = 0 } } // Split into equal-length shards. dst := make([][]byte, r.totalShards) i := 0 for ; i < len(dst) && len(data) >= perShard; i++ { dst[i] = data[:perShard:perShard] data = data[perShard:] } for j := 0; i+j < len(dst); j++ { dst[i+j] = padding[:perShard:perShard] padding = padding[perShard:] } return dst, nil } func (r *leopardFF16) ReconstructSome(shards [][]byte, required []bool) error { return r.ReconstructData(shards) } func (r *leopardFF16) Reconstruct(shards [][]byte) error { return r.reconstruct(shards, true) } func (r *leopardFF16) ReconstructData(shards [][]byte) error { return r.reconstruct(shards, false) } func (r *leopardFF16) Verify(shards [][]byte) (bool, error) { if len(shards) != r.totalShards { return false, ErrTooFewShards } if err := checkShards(shards, false); err != nil { return false, err } // Re-encode parity shards to temporary storage. shardSize := len(shards[0]) outputs := make([][]byte, r.totalShards) copy(outputs, shards[:r.dataShards]) for i := r.dataShards; i < r.totalShards; i++ { outputs[i] = make([]byte, shardSize) } if err := r.Encode(outputs); err != nil { return false, err } // Compare. for i := r.dataShards; i < r.totalShards; i++ { if !bytes.Equal(outputs[i], shards[i]) { return false, nil } } return true, nil } func (r *leopardFF16) reconstruct(shards [][]byte, recoverAll bool) error { if len(shards) != r.totalShards { return ErrTooFewShards } if err := checkShards(shards, true); err != nil { return err } // Quick check: are all of the shards present? If so, there's // nothing to do. numberPresent := 0 dataPresent := 0 for i := 0; i < r.totalShards; i++ { if len(shards[i]) != 0 { numberPresent++ if i < r.dataShards { dataPresent++ } } } if numberPresent == r.totalShards || !recoverAll && dataPresent == r.dataShards { // Cool. All of the shards have data. We don't // need to do anything. return nil } // Use only if we are missing less than 1/4 parity. useBits := r.totalShards-numberPresent <= r.parityShards/4 // Check if we have enough to reconstruct. if numberPresent < r.dataShards { return ErrTooFewShards } shardSize := shardSize(shards) if shardSize%64 != 0 { return ErrShardSize } m := ceilPow2(r.parityShards) n := ceilPow2(m + r.dataShards) const LEO_ERROR_BITFIELD_OPT = true // Fill in error locations. var errorBits errorBitfield var errLocs [order]ffe for i := 0; i < r.parityShards; i++ { if len(shards[i+r.dataShards]) == 0 { errLocs[i] = 1 if LEO_ERROR_BITFIELD_OPT && recoverAll { errorBits.set(i) } } } for i := r.parityShards; i < m; i++ { errLocs[i] = 1 if LEO_ERROR_BITFIELD_OPT && recoverAll { errorBits.set(i) } } for i := 0; i < r.dataShards; i++ { if len(shards[i]) == 0 { errLocs[i+m] = 1 if LEO_ERROR_BITFIELD_OPT { errorBits.set(i + m) } } } if LEO_ERROR_BITFIELD_OPT && useBits { errorBits.prepare() } // Evaluate error locator polynomial fwht(&errLocs, order, m+r.dataShards) for i := 0; i < order; i++ { errLocs[i] = ffe((uint(errLocs[i]) * uint(logWalsh[i])) % modulus) } fwht(&errLocs, order, order) var work [][]byte if w, ok := r.workPool.Get().([][]byte); ok { work = w } if cap(work) >= n { work = work[:n] } else { work = make([][]byte, n) } for i := range work { if cap(work[i]) < shardSize { work[i] = make([]byte, shardSize) } else { work[i] = work[i][:shardSize] } } defer r.workPool.Put(work) // work <- recovery data for i := 0; i < r.parityShards; i++ { if len(shards[i+r.dataShards]) != 0 { mulgf16(work[i], shards[i+r.dataShards], errLocs[i], &r.o) } else { memclr(work[i]) } } for i := r.parityShards; i < m; i++ { memclr(work[i]) } // work <- original data for i := 0; i < r.dataShards; i++ { if len(shards[i]) != 0 { mulgf16(work[m+i], shards[i], errLocs[m+i], &r.o) } else { memclr(work[m+i]) } } for i := m + r.dataShards; i < n; i++ { memclr(work[i]) } // work <- IFFT(work, n, 0) ifftDITDecoder( m+r.dataShards, work, n, fftSkew[:], &r.o, ) // work <- FormalDerivative(work, n) for i := 1; i < n; i++ { width := ((i ^ (i - 1)) + 1) >> 1 slicesXor(work[i-width:i], work[i:i+width], &r.o) } // work <- FFT(work, n, 0) truncated to m + dataShards outputCount := m + r.dataShards if LEO_ERROR_BITFIELD_OPT && useBits { errorBits.fftDIT(work, outputCount, n, fftSkew[:], &r.o) } else { fftDIT(work, outputCount, n, fftSkew[:], &r.o) } // Reveal erasures // // Original = -ErrLocator * FFT( Derivative( IFFT( ErrLocator * ReceivedData ) ) ) // mul_mem(x, y, log_m, ) equals x[] = y[] * log_m // // mem layout: [Recovery Data (Power of Two = M)] [Original Data (K)] [Zero Padding out to N] end := r.dataShards if recoverAll { end = r.totalShards } for i := 0; i < end; i++ { if len(shards[i]) != 0 { continue } if cap(shards[i]) >= shardSize { shards[i] = shards[i][:shardSize] } else { shards[i] = make([]byte, shardSize) } if i >= r.dataShards { // Parity shard. mulgf16(shards[i], work[i-r.dataShards], modulus-errLocs[i-r.dataShards], &r.o) } else { // Data shard. mulgf16(shards[i], work[i+m], modulus-errLocs[i+m], &r.o) } } return nil } // Basic no-frills version for decoder func ifftDITDecoder(mtrunc int, work [][]byte, m int, skewLUT []ffe, o *options) { // Decimation in time: Unroll 2 layers at a time dist := 1 dist4 := 4 for dist4 <= m { // For each set of dist*4 elements: for r := 0; r < mtrunc; r += dist4 { iend := r + dist log_m01 := skewLUT[iend-1] log_m02 := skewLUT[iend+dist-1] log_m23 := skewLUT[iend+dist*2-1] // For each set of dist elements: for i := r; i < iend; i++ { ifftDIT4(work[i:], dist, log_m01, log_m23, log_m02, o) } } dist = dist4 dist4 <<= 2 } // If there is one layer left: if dist < m { // Assuming that dist = m / 2 if dist*2 != m { panic("internal error") } log_m := skewLUT[dist-1] if log_m == modulus { slicesXor(work[dist:2*dist], work[:dist], o) } else { for i := 0; i < dist; i++ { ifftDIT2( work[i], work[i+dist], log_m, o, ) } } } } // In-place FFT for encoder and decoder func fftDIT(work [][]byte, mtrunc, m int, skewLUT []ffe, o *options) { // Decimation in time: Unroll 2 layers at a time dist4 := m dist := m >> 2 for dist != 0 { // For each set of dist*4 elements: for r := 0; r < mtrunc; r += dist4 { iend := r + dist log_m01 := skewLUT[iend-1] log_m02 := skewLUT[iend+dist-1] log_m23 := skewLUT[iend+dist*2-1] // For each set of dist elements: for i := r; i < iend; i++ { fftDIT4( work[i:], dist, log_m01, log_m23, log_m02, o, ) } } dist4 = dist dist >>= 2 } // If there is one layer left: if dist4 == 2 { for r := 0; r < mtrunc; r += 2 { log_m := skewLUT[r+1-1] if log_m == modulus { sliceXor(work[r], work[r+1], o) } else { fftDIT2(work[r], work[r+1], log_m, o) } } } } // 4-way butterfly func fftDIT4Ref(work [][]byte, dist int, log_m01, log_m23, log_m02 ffe, o *options) { // First layer: if log_m02 == modulus { sliceXor(work[0], work[dist*2], o) sliceXor(work[dist], work[dist*3], o) } else { fftDIT2(work[0], work[dist*2], log_m02, o) fftDIT2(work[dist], work[dist*3], log_m02, o) } // Second layer: if log_m01 == modulus { sliceXor(work[0], work[dist], o) } else { fftDIT2(work[0], work[dist], log_m01, o) } if log_m23 == modulus { sliceXor(work[dist*2], work[dist*3], o) } else { fftDIT2(work[dist*2], work[dist*3], log_m23, o) } } // Unrolled IFFT for encoder func ifftDITEncoder(data [][]byte, mtrunc int, work [][]byte, xorRes [][]byte, m int, skewLUT []ffe, o *options) { // I tried rolling the memcpy/memset into the first layer of the FFT and // found that it only yields a 4% performance improvement, which is not // worth the extra complexity. for i := 0; i < mtrunc; i++ { copy(work[i], data[i]) } for i := mtrunc; i < m; i++ { memclr(work[i]) } // I tried splitting up the first few layers into L3-cache sized blocks but // found that it only provides about 5% performance boost, which is not // worth the extra complexity. // Decimation in time: Unroll 2 layers at a time dist := 1 dist4 := 4 for dist4 <= m { // For each set of dist*4 elements: for r := 0; r < mtrunc; r += dist4 { iend := r + dist log_m01 := skewLUT[iend] log_m02 := skewLUT[iend+dist] log_m23 := skewLUT[iend+dist*2] // For each set of dist elements: for i := r; i < iend; i++ { ifftDIT4( work[i:], dist, log_m01, log_m23, log_m02, o, ) } } dist = dist4 dist4 <<= 2 // I tried alternating sweeps left->right and right->left to reduce cache misses. // It provides about 1% performance boost when done for both FFT and IFFT, so it // does not seem to be worth the extra complexity. } // If there is one layer left: if dist < m { // Assuming that dist = m / 2 if dist*2 != m { panic("internal error") } logm := skewLUT[dist] if logm == modulus { slicesXor(work[dist:dist*2], work[:dist], o) } else { for i := 0; i < dist; i++ { ifftDIT2(work[i], work[i+dist], logm, o) } } } // I tried unrolling this but it does not provide more than 5% performance // improvement for 16-bit finite fields, so it's not worth the complexity. if xorRes != nil { slicesXor(xorRes[:m], work[:m], o) } } func ifftDIT4Ref(work [][]byte, dist int, log_m01, log_m23, log_m02 ffe, o *options) { // First layer: if log_m01 == modulus { sliceXor(work[0], work[dist], o) } else { ifftDIT2(work[0], work[dist], log_m01, o) } if log_m23 == modulus { sliceXor(work[dist*2], work[dist*3], o) } else { ifftDIT2(work[dist*2], work[dist*3], log_m23, o) } // Second layer: if log_m02 == modulus { sliceXor(work[0], work[dist*2], o) sliceXor(work[dist], work[dist*3], o) } else { ifftDIT2(work[0], work[dist*2], log_m02, o) ifftDIT2(work[dist], work[dist*3], log_m02, o) } } // Reference version of muladd: x[] ^= y[] * log_m func refMulAdd(x, y []byte, log_m ffe) { lut := &mul16LUTs[log_m] for len(x) >= 64 { // Assert sizes for no bounds checks in loop hiA := y[32:64] loA := y[:32] dst := x[:64] // Needed, but not checked... for i, lo := range loA { hi := hiA[i] prod := lut.Lo[lo] ^ lut.Hi[hi] dst[i] ^= byte(prod) dst[i+32] ^= byte(prod >> 8) } x = x[64:] y = y[64:] } } func memclr(s []byte) { for i := range s { s[i] = 0 } } // slicesXor calls xor for every slice pair in v1, v2. func slicesXor(v1, v2 [][]byte, o *options) { for i, v := range v1 { sliceXor(v2[i], v, o) } } // Reference version of mul: x[] = y[] * log_m func refMul(x, y []byte, log_m ffe) { lut := &mul16LUTs[log_m] for off := 0; off < len(x); off += 64 { loA := y[off : off+32] hiA := y[off+32:] hiA = hiA[:len(loA)] for i, lo := range loA { hi := hiA[i] prod := lut.Lo[lo] ^ lut.Hi[hi] x[off+i] = byte(prod) x[off+i+32] = byte(prod >> 8) } } } // Returns a * Log(b) func mulLog(a, log_b ffe) ffe { /* Note that this operation is not a normal multiplication in a finite field because the right operand is already a logarithm. This is done because it moves K table lookups from the Decode() method into the initialization step that is less performance critical. The LogWalsh[] table below contains precalculated logarithms so it is easier to do all the other multiplies in that form as well. */ if a == 0 { return 0 } return expLUT[addMod(logLUT[a], log_b)] } // z = x + y (mod kModulus) func addMod(a, b ffe) ffe { sum := uint(a) + uint(b) // Partial reduction step, allowing for kModulus to be returned return ffe(sum + sum>>bitwidth) } // z = x - y (mod kModulus) func subMod(a, b ffe) ffe { dif := uint(a) - uint(b) // Partial reduction step, allowing for kModulus to be returned return ffe(dif + dif>>bitwidth) } // ceilPow2 returns power of two at or above n. func ceilPow2(n int) int { const w = int(unsafe.Sizeof(n) * 8) return 1 << (w - bits.LeadingZeros(uint(n-1))) } // Decimation in time (DIT) Fast Walsh-Hadamard Transform // Unrolls pairs of layers to perform cross-layer operations in registers // mtrunc: Number of elements that are non-zero at the front of data func fwht(data *[order]ffe, m, mtrunc int) { // Decimation in time: Unroll 2 layers at a time dist := 1 dist4 := 4 for dist4 <= m { // For each set of dist*4 elements: for r := 0; r < mtrunc; r += dist4 { // For each set of dist elements: // Use 16 bit indices to avoid bounds check on [65536]ffe. dist := uint16(dist) off := uint16(r) for i := uint16(0); i < dist; i++ { // fwht4(data[i:], dist) inlined... // Reading values appear faster than updating pointers. // Casting to uint is not faster. t0 := data[off] t1 := data[off+dist] t2 := data[off+dist*2] t3 := data[off+dist*3] t0, t1 = fwht2alt(t0, t1) t2, t3 = fwht2alt(t2, t3) t0, t2 = fwht2alt(t0, t2) t1, t3 = fwht2alt(t1, t3) data[off] = t0 data[off+dist] = t1 data[off+dist*2] = t2 data[off+dist*3] = t3 off++ } } dist = dist4 dist4 <<= 2 } // If there is one layer left: if dist < m { dist := uint16(dist) for i := uint16(0); i < dist; i++ { fwht2(&data[i], &data[i+dist]) } } } func fwht4(data []ffe, s int) { s2 := s << 1 t0 := &data[0] t1 := &data[s] t2 := &data[s2] t3 := &data[s2+s] fwht2(t0, t1) fwht2(t2, t3) fwht2(t0, t2) fwht2(t1, t3) } // {a, b} = {a + b, a - b} (Mod Q) func fwht2(a, b *ffe) { sum := addMod(*a, *b) dif := subMod(*a, *b) *a = sum *b = dif } // fwht2alt is as fwht2, but returns result. func fwht2alt(a, b ffe) (ffe, ffe) { return addMod(a, b), subMod(a, b) } var initOnce sync.Once func initConstants() { initOnce.Do(func() { initLUTs() initFFTSkew() initMul16LUT() }) } // Initialize logLUT, expLUT. func initLUTs() { cantorBasis := [bitwidth]ffe{ 0x0001, 0xACCA, 0x3C0E, 0x163E, 0xC582, 0xED2E, 0x914C, 0x4012, 0x6C98, 0x10D8, 0x6A72, 0xB900, 0xFDB8, 0xFB34, 0xFF38, 0x991E, } expLUT = &[order]ffe{} logLUT = &[order]ffe{} // LFSR table generation: state := 1 for i := ffe(0); i < modulus; i++ { expLUT[state] = i state <<= 1 if state >= order { state ^= polynomial } } expLUT[0] = modulus // Conversion to Cantor basis: logLUT[0] = 0 for i := 0; i < bitwidth; i++ { basis := cantorBasis[i] width := 1 << i for j := 0; j < width; j++ { logLUT[j+width] = logLUT[j] ^ basis } } for i := 0; i < order; i++ { logLUT[i] = expLUT[logLUT[i]] } for i := 0; i < order; i++ { expLUT[logLUT[i]] = ffe(i) } expLUT[modulus] = expLUT[0] } // Initialize fftSkew. func initFFTSkew() { var temp [bitwidth - 1]ffe // Generate FFT skew vector {1}: for i := 1; i < bitwidth; i++ { temp[i-1] = ffe(1 << i) } fftSkew = &[modulus]ffe{} logWalsh = &[order]ffe{} for m := 0; m < bitwidth-1; m++ { step := 1 << (m + 1) fftSkew[1<>4)+16)] lut.Hi[i] = tmp[((i&15)+32)] ^ tmp[((i>>4)+48)] } } if cpuid.CPU.Has(cpuid.SSSE3) || cpuid.CPU.Has(cpuid.AVX2) || cpuid.CPU.Has(cpuid.AVX512F) { multiply256LUT = &[order][16 * 8]byte{} for logM := range multiply256LUT[:] { // For each 4 bits of the finite field width in bits: shift := 0 for i := 0; i < 4; i++ { // Construct 16 entry LUT for PSHUFB prodLo := multiply256LUT[logM][i*16 : i*16+16] prodHi := multiply256LUT[logM][4*16+i*16 : 4*16+i*16+16] for x := range prodLo[:] { prod := mulLog(ffe(x<> 8) } shift += 4 } } } } const kWordMips = 5 const kWords = order / 64 const kBigMips = 6 const kBigWords = (kWords + 63) / 64 const kBiggestMips = 4 // errorBitfield contains progressive errors to help indicate which // shards need reconstruction. type errorBitfield struct { Words [kWordMips][kWords]uint64 BigWords [kBigMips][kBigWords]uint64 BiggestWords [kBiggestMips]uint64 } func (e *errorBitfield) set(i int) { e.Words[0][i/64] |= uint64(1) << (i & 63) } func (e *errorBitfield) isNeededFn(mipLevel int) func(bit int) bool { if mipLevel >= 16 { return func(bit int) bool { return true } } if mipLevel >= 12 { w := e.BiggestWords[mipLevel-12] return func(bit int) bool { bit /= 4096 return 0 != (w & (uint64(1) << bit)) } } if mipLevel >= 6 { w := e.BigWords[mipLevel-6][:] return func(bit int) bool { bit /= 64 return 0 != (w[bit/64] & (uint64(1) << (bit & 63))) } } if mipLevel > 0 { w := e.Words[mipLevel-1][:] return func(bit int) bool { return 0 != (w[bit/64] & (uint64(1) << (bit & 63))) } } return nil } func (e *errorBitfield) isNeeded(mipLevel int, bit uint) bool { if mipLevel >= 16 { return true } if mipLevel >= 12 { bit /= 4096 return 0 != (e.BiggestWords[mipLevel-12] & (uint64(1) << bit)) } if mipLevel >= 6 { bit /= 64 return 0 != (e.BigWords[mipLevel-6][bit/64] & (uint64(1) << (bit % 64))) } return 0 != (e.Words[mipLevel-1][bit/64] & (uint64(1) << (bit % 64))) } var kHiMasks = [5]uint64{ 0xAAAAAAAAAAAAAAAA, 0xCCCCCCCCCCCCCCCC, 0xF0F0F0F0F0F0F0F0, 0xFF00FF00FF00FF00, 0xFFFF0000FFFF0000, } func (e *errorBitfield) prepare() { // First mip level is for final layer of FFT: pairs of data for i := 0; i < kWords; i++ { w_i := e.Words[0][i] hi2lo0 := w_i | ((w_i & kHiMasks[0]) >> 1) lo2hi0 := (w_i & (kHiMasks[0] >> 1)) << 1 w_i = hi2lo0 | lo2hi0 e.Words[0][i] = w_i bits := 2 for j := 1; j < kWordMips; j++ { hi2lo_j := w_i | ((w_i & kHiMasks[j]) >> bits) lo2hi_j := (w_i & (kHiMasks[j] >> bits)) << bits w_i = hi2lo_j | lo2hi_j e.Words[j][i] = w_i bits <<= 1 } } for i := 0; i < kBigWords; i++ { w_i := uint64(0) bit := uint64(1) src := e.Words[kWordMips-1][i*64 : i*64+64] for _, w := range src { w_i |= (w | (w >> 32) | (w << 32)) & bit bit <<= 1 } e.BigWords[0][i] = w_i bits := 1 for j := 1; j < kBigMips; j++ { hi2lo_j := w_i | ((w_i & kHiMasks[j-1]) >> bits) lo2hi_j := (w_i & (kHiMasks[j-1] >> bits)) << bits w_i = hi2lo_j | lo2hi_j e.BigWords[j][i] = w_i bits <<= 1 } } w_i := uint64(0) bit := uint64(1) for _, w := range e.BigWords[kBigMips-1][:kBigWords] { w_i |= (w | (w >> 32) | (w << 32)) & bit bit <<= 1 } e.BiggestWords[0] = w_i bits := uint64(1) for j := 1; j < kBiggestMips; j++ { hi2lo_j := w_i | ((w_i & kHiMasks[j-1]) >> bits) lo2hi_j := (w_i & (kHiMasks[j-1] >> bits)) << bits w_i = hi2lo_j | lo2hi_j e.BiggestWords[j] = w_i bits <<= 1 } } func (e *errorBitfield) fftDIT(work [][]byte, mtrunc, m int, skewLUT []ffe, o *options) { // Decimation in time: Unroll 2 layers at a time mipLevel := bits.Len32(uint32(m)) - 1 dist4 := m dist := m >> 2 needed := e.isNeededFn(mipLevel) for dist != 0 { // For each set of dist*4 elements: for r := 0; r < mtrunc; r += dist4 { if !needed(r) { continue } iEnd := r + dist logM01 := skewLUT[iEnd-1] logM02 := skewLUT[iEnd+dist-1] logM23 := skewLUT[iEnd+dist*2-1] // For each set of dist elements: for i := r; i < iEnd; i++ { fftDIT4( work[i:], dist, logM01, logM23, logM02, o) } } dist4 = dist dist >>= 2 mipLevel -= 2 needed = e.isNeededFn(mipLevel) } // If there is one layer left: if dist4 == 2 { for r := 0; r < mtrunc; r += 2 { if !needed(r) { continue } logM := skewLUT[r+1-1] if logM == modulus { sliceXor(work[r], work[r+1], o) } else { fftDIT2(work[r], work[r+1], logM, o) } } } }