/* Copyright (c) 2017 Christopher A. Taylor. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of Leopard-RS nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "LeopardFF8.h" #ifdef LEO_HAS_FF8 #include #ifdef _MSC_VER #pragma warning(disable: 4752) // found Intel(R) Advanced Vector Extensions; consider using /arch:AVX #endif namespace leopard { namespace ff8 { //------------------------------------------------------------------------------ // Datatypes and Constants // Basis used for generating logarithm tables static const ffe_t kCantorBasis[kBits] = { 1, 214, 152, 146, 86, 200, 88, 230 }; // Using the Cantor basis {2} here enables us to avoid a lot of extra calculations // when applying the formal derivative in decoding. //------------------------------------------------------------------------------ // Field Operations // z = x + y (mod kModulus) static inline ffe_t AddMod(const ffe_t a, const ffe_t b) { const unsigned sum = static_cast(a) + b; // Partial reduction step, allowing for kModulus to be returned return static_cast(sum + (sum >> kBits)); } // z = x - y (mod kModulus) static inline ffe_t SubMod(const ffe_t a, const ffe_t b) { const unsigned dif = static_cast(a) - b; // Partial reduction step, allowing for kModulus to be returned return static_cast(dif + (dif >> kBits)); } //------------------------------------------------------------------------------ // Fast Walsh-Hadamard Transform (FWHT) (mod kModulus) // {a, b} = {a + b, a - b} (Mod Q) static LEO_FORCE_INLINE void FWHT_2(ffe_t& LEO_RESTRICT a, ffe_t& LEO_RESTRICT b) { const ffe_t sum = AddMod(a, b); const ffe_t dif = SubMod(a, b); a = sum; b = dif; } static LEO_FORCE_INLINE void FWHT_4(ffe_t* data, unsigned s) { const unsigned s2 = s << 1; ffe_t t0 = data[0]; ffe_t t1 = data[s]; ffe_t t2 = data[s2]; ffe_t t3 = data[s2 + s]; FWHT_2(t0, t1); FWHT_2(t2, t3); FWHT_2(t0, t2); FWHT_2(t1, t3); data[0] = t0; data[s] = t1; data[s2] = t2; data[s2 + s] = t3; } // Decimation in time (DIT) Fast Walsh-Hadamard Transform // Unrolls pairs of layers to perform cross-layer operations in registers // m_truncated: Number of elements that are non-zero at the front of data static void FWHT(ffe_t* data, const unsigned m, const unsigned m_truncated) { // Decimation in time: Unroll 2 layers at a time unsigned dist = 1, dist4 = 4; for (; dist4 <= m; dist = dist4, dist4 <<= 2) { // For each set of dist*4 elements: for (unsigned r = 0; r < m_truncated; r += dist4) { // For each set of dist elements: for (unsigned i = r; i < r + dist; ++i) FWHT_4(data + i, dist); } } // If there is one layer left: if (dist < m) for (unsigned i = 0; i < dist; ++i) FWHT_2(data[i], data[i + dist]); } //------------------------------------------------------------------------------ // Logarithm Tables static ffe_t LogLUT[kOrder]; static ffe_t ExpLUT[kOrder]; // Returns a * Log(b) static ffe_t MultiplyLog(ffe_t a, ffe_t log_b) { /* 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)]; } // Initialize LogLUT[], ExpLUT[] static void InitializeLogarithmTables() { // LFSR table generation: unsigned state = 1; for (unsigned i = 0; i < kModulus; ++i) { ExpLUT[state] = static_cast(i); state <<= 1; if (state >= kOrder) state ^= kPolynomial; } ExpLUT[0] = kModulus; // Conversion to Cantor basis {2}: LogLUT[0] = 0; for (unsigned i = 0; i < kBits; ++i) { const ffe_t basis = kCantorBasis[i]; const unsigned width = static_cast(1UL << i); for (unsigned j = 0; j < width; ++j) LogLUT[j + width] = LogLUT[j] ^ basis; } for (unsigned i = 0; i < kOrder; ++i) LogLUT[i] = ExpLUT[LogLUT[i]]; // Generate Exp table from Log table: for (unsigned i = 0; i < kOrder; ++i) ExpLUT[LogLUT[i]] = i; // Note: Handles modulus wrap around with LUT ExpLUT[kModulus] = ExpLUT[0]; } //------------------------------------------------------------------------------ // Multiplies /* The multiplication algorithm used follows the approach outlined in {4}. Specifically section 6 outlines the algorithm used here for 8-bit fields. */ struct Multiply128LUT_t { LEO_M128 Value[2]; }; static const Multiply128LUT_t* Multiply128LUT = nullptr; // 128-bit x_reg ^= y_reg * log_m #define LEO_MULADD_128(x_reg, y_reg, table_lo, table_hi) { \ LEO_M128 lo = _mm_and_si128(y_reg, clr_mask); \ lo = _mm_shuffle_epi8(table_lo, lo); \ LEO_M128 hi = _mm_srli_epi64(y_reg, 4); \ hi = _mm_and_si128(hi, clr_mask); \ hi = _mm_shuffle_epi8(table_hi, hi); \ x_reg = _mm_xor_si128(x_reg, _mm_xor_si128(lo, hi)); } #if defined(LEO_TRY_AVX2) struct Multiply256LUT_t { LEO_M256 Value[2]; }; static const Multiply256LUT_t* Multiply256LUT = nullptr; // 256-bit x_reg ^= y_reg * log_m #define LEO_MULADD_256(x_reg, y_reg, table_lo, table_hi) { \ LEO_M256 lo = _mm256_and_si256(y_reg, clr_mask); \ lo = _mm256_shuffle_epi8(table_lo, lo); \ LEO_M256 hi = _mm256_srli_epi64(y_reg, 4); \ hi = _mm256_and_si256(hi, clr_mask); \ hi = _mm256_shuffle_epi8(table_hi, hi); \ x_reg = _mm256_xor_si256(x_reg, _mm256_xor_si256(lo, hi)); } #endif // LEO_TRY_AVX2 // Stores the product of x * y at offset x + y * 256 // Repeated accesses from the same y value are faster static const ffe_t* Multiply8LUT = nullptr; static void InitializeMultiplyTables() { // If we cannot use the PSHUFB instruction, generate Multiply8LUT: if (!CpuHasSSSE3) { Multiply8LUT = new ffe_t[256 * 256]; // For each left-multiplicand: for (unsigned x = 0; x < 256; ++x) { ffe_t* lut = (ffe_t*)Multiply8LUT + x; if (x == 0) { for (unsigned log_y = 0; log_y < 256; ++log_y, lut += 256) *lut = 0; } else { const ffe_t log_x = LogLUT[x]; for (unsigned log_y = 0; log_y < 256; ++log_y, lut += 256) { const ffe_t prod = ExpLUT[AddMod(log_x, log_y)]; *lut = prod; } } } return; } if (CpuHasAVX2) Multiply256LUT = reinterpret_cast(SIMDSafeAllocate(sizeof(Multiply256LUT_t) * kOrder)); else Multiply128LUT = reinterpret_cast(SIMDSafeAllocate(sizeof(Multiply128LUT_t) * kOrder)); // For each value we could multiply by: for (unsigned log_m = 0; log_m < kOrder; ++log_m) { // For each 4 bits of the finite field width in bits: for (unsigned i = 0, shift = 0; i < 2; ++i, shift += 4) { // Construct 16 entry LUT for PSHUFB uint8_t lut[16]; for (ffe_t x = 0; x < 16; ++x) lut[x] = MultiplyLog(x << shift, static_cast(log_m)); const LEO_M128 *v_ptr = reinterpret_cast(&lut[0]); const LEO_M128 value = _mm_loadu_si128(v_ptr); // Store in 128-bit wide table if (!CpuHasAVX2) _mm_storeu_si128((LEO_M128*)&Multiply128LUT[log_m].Value[i], value); // Store in 256-bit wide table #if defined(LEO_TRY_AVX2) if (CpuHasAVX2) { _mm256_storeu_si256((LEO_M256*)&Multiply256LUT[log_m].Value[i], _mm256_broadcastsi128_si256(value)); } #endif // LEO_TRY_AVX2 } } } static void mul_mem( void * LEO_RESTRICT x, const void * LEO_RESTRICT y, ffe_t log_m, uint64_t bytes) { #if defined(LEO_TRY_AVX2) if (CpuHasAVX2) { const LEO_M256 table_lo_y = _mm256_loadu_si256(&Multiply256LUT[log_m].Value[0]); const LEO_M256 table_hi_y = _mm256_loadu_si256(&Multiply256LUT[log_m].Value[1]); const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f); LEO_M256 * LEO_RESTRICT x32 = reinterpret_cast(x); const LEO_M256 * LEO_RESTRICT y32 = reinterpret_cast(y); do { #define LEO_MUL_256(x_ptr, y_ptr) { \ LEO_M256 data = _mm256_loadu_si256(y_ptr); \ LEO_M256 lo = _mm256_and_si256(data, clr_mask); \ lo = _mm256_shuffle_epi8(table_lo_y, lo); \ LEO_M256 hi = _mm256_srli_epi64(data, 4); \ hi = _mm256_and_si256(hi, clr_mask); \ hi = _mm256_shuffle_epi8(table_hi_y, hi); \ _mm256_storeu_si256(x_ptr, _mm256_xor_si256(lo, hi)); } LEO_MUL_256(x32 + 1, y32 + 1); LEO_MUL_256(x32, y32); y32 += 2, x32 += 2; bytes -= 64; } while (bytes > 0); return; } #endif // LEO_TRY_AVX2 if (CpuHasSSSE3) { const LEO_M128 table_lo_y = _mm_loadu_si128(&Multiply128LUT[log_m].Value[0]); const LEO_M128 table_hi_y = _mm_loadu_si128(&Multiply128LUT[log_m].Value[1]); const LEO_M128 clr_mask = _mm_set1_epi8(0x0f); LEO_M128 * LEO_RESTRICT x16 = reinterpret_cast(x); const LEO_M128 * LEO_RESTRICT y16 = reinterpret_cast(y); do { #define LEO_MUL_128(x_ptr, y_ptr) { \ LEO_M128 data = _mm_loadu_si128(y_ptr); \ LEO_M128 lo = _mm_and_si128(data, clr_mask); \ lo = _mm_shuffle_epi8(table_lo_y, lo); \ LEO_M128 hi = _mm_srli_epi64(data, 4); \ hi = _mm_and_si128(hi, clr_mask); \ hi = _mm_shuffle_epi8(table_hi_y, hi); \ _mm_storeu_si128(x_ptr, _mm_xor_si128(lo, hi)); } LEO_MUL_128(x16 + 3, y16 + 3); LEO_MUL_128(x16 + 2, y16 + 2); LEO_MUL_128(x16 + 1, y16 + 1); LEO_MUL_128(x16, y16); x16 += 4, y16 += 4; bytes -= 64; } while (bytes > 0); return; } // Reference version: const ffe_t* LEO_RESTRICT lut = Multiply8LUT + log_m * 256; ffe_t * LEO_RESTRICT x1 = reinterpret_cast(x); const ffe_t * LEO_RESTRICT y1 = reinterpret_cast(y); do { for (unsigned j = 0; j < 64; ++j) x1[j] = lut[y1[j]]; x1 += 64, y1 += 64; bytes -= 64; } while (bytes > 0); } //------------------------------------------------------------------------------ // FFT // Twisted factors used in FFT static ffe_t FFTSkew[kModulus]; // Factors used in the evaluation of the error locator polynomial static ffe_t LogWalsh[kOrder]; static void FFTInitialize() { ffe_t temp[kBits - 1]; // Generate FFT skew vector {1}: for (unsigned i = 1; i < kBits; ++i) temp[i - 1] = static_cast(1UL << i); for (unsigned m = 0; m < (kBits - 1); ++m) { const unsigned step = 1UL << (m + 1); FFTSkew[(1UL << m) - 1] = 0; for (unsigned i = m; i < (kBits - 1); ++i) { const unsigned s = (1UL << (i + 1)); for (unsigned j = (1UL << m) - 1; j < s; j += step) FFTSkew[j + s] = FFTSkew[j] ^ temp[i]; } temp[m] = kModulus - LogLUT[MultiplyLog(temp[m], LogLUT[temp[m] ^ 1])]; for (unsigned i = m + 1; i < (kBits - 1); ++i) { const ffe_t sum = AddMod(LogLUT[temp[i] ^ 1], temp[m]); temp[i] = MultiplyLog(temp[i], sum); } } for (unsigned i = 0; i < kModulus; ++i) FFTSkew[i] = LogLUT[FFTSkew[i]]; // Precalculate FWHT(Log[i]): for (unsigned i = 0; i < kOrder; ++i) LogWalsh[i] = LogLUT[i]; LogWalsh[0] = 0; FWHT(LogWalsh, kOrder, kOrder); } /* Decimation in time IFFT: The decimation in time IFFT algorithm allows us to unroll 2 layers at a time, performing calculations on local registers and faster cache memory. Each ^___^ below indicates a butterfly between the associated indices. The ifft_butterfly(x, y) operation: y[] ^= x[] if (log_m != kModulus) x[] ^= exp(log(y[]) + log_m) Layer 0: 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 ^_^ ^_^ ^_^ ^_^ ^_^ ^_^ ^_^ ^_^ Layer 1: 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 ^___^ ^___^ ^___^ ^___^ ^___^ ^___^ ^___^ ^___^ Layer 2: 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 ^_______^ ^_______^ ^_______^ ^_______^ ^_______^ ^_______^ ^_______^ ^_______^ Layer 3: 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 ^_______________^ ^_______________^ ^_______________^ ^_______________^ ^_______________^ ^_______________^ ^_______________^ ^_______________^ DIT layer 0-1 operations, grouped 4 at a time: {0-1, 2-3, 0-2, 1-3}, {4-5, 6-7, 4-6, 5-7}, DIT layer 1-2 operations, grouped 4 at a time: {0-2, 4-6, 0-4, 2-6}, {1-3, 5-7, 1-5, 3-7}, DIT layer 2-3 operations, grouped 4 at a time: {0-4, 0'-4', 0-0', 4-4'}, {1-5, 1'-5', 1-1', 5-5'}, */ // 2-way butterfly static void IFFT_DIT2( void * LEO_RESTRICT x, void * LEO_RESTRICT y, ffe_t log_m, uint64_t bytes) { #if defined(LEO_TRY_AVX2) if (CpuHasAVX2) { const LEO_M256 table_lo_y = _mm256_loadu_si256(&Multiply256LUT[log_m].Value[0]); const LEO_M256 table_hi_y = _mm256_loadu_si256(&Multiply256LUT[log_m].Value[1]); const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f); LEO_M256 * LEO_RESTRICT x32 = reinterpret_cast(x); LEO_M256 * LEO_RESTRICT y32 = reinterpret_cast(y); do { #define LEO_IFFTB_256(x_ptr, y_ptr) { \ LEO_M256 x_data = _mm256_loadu_si256(x_ptr); \ LEO_M256 y_data = _mm256_loadu_si256(y_ptr); \ y_data = _mm256_xor_si256(y_data, x_data); \ _mm256_storeu_si256(y_ptr, y_data); \ LEO_MULADD_256(x_data, y_data, table_lo_y, table_hi_y); \ _mm256_storeu_si256(x_ptr, x_data); } LEO_IFFTB_256(x32 + 1, y32 + 1); LEO_IFFTB_256(x32, y32); y32 += 2, x32 += 2; bytes -= 64; } while (bytes > 0); return; } #endif // LEO_TRY_AVX2 if (CpuHasSSSE3) { const LEO_M128 table_lo_y = _mm_loadu_si128(&Multiply128LUT[log_m].Value[0]); const LEO_M128 table_hi_y = _mm_loadu_si128(&Multiply128LUT[log_m].Value[1]); const LEO_M128 clr_mask = _mm_set1_epi8(0x0f); LEO_M128 * LEO_RESTRICT x16 = reinterpret_cast(x); LEO_M128 * LEO_RESTRICT y16 = reinterpret_cast(y); do { #define LEO_IFFTB_128(x_ptr, y_ptr) { \ LEO_M128 x_data = _mm_loadu_si128(x_ptr); \ LEO_M128 y_data = _mm_loadu_si128(y_ptr); \ y_data = _mm_xor_si128(y_data, x_data); \ _mm_storeu_si128(y_ptr, y_data); \ LEO_MULADD_128(x_data, y_data, table_lo_y, table_hi_y); \ _mm_storeu_si128(x_ptr, x_data); } LEO_IFFTB_128(x16 + 3, y16 + 3); LEO_IFFTB_128(x16 + 2, y16 + 2); LEO_IFFTB_128(x16 + 1, y16 + 1); LEO_IFFTB_128(x16, y16); x16 += 4, y16 += 4; bytes -= 64; } while (bytes > 0); return; } // Reference version: const ffe_t* LEO_RESTRICT lut = Multiply8LUT + log_m * 256; xor_mem(y, x, bytes); #ifdef LEO_TARGET_MOBILE ffe_t * LEO_RESTRICT x1 = reinterpret_cast(x); ffe_t * LEO_RESTRICT y1 = reinterpret_cast(y); do { for (unsigned j = 0; j < 64; ++j) x1[j] ^= lut[y1[j]]; x1 += 64, y1 += 64; bytes -= 64; } while (bytes > 0); #else uint64_t * LEO_RESTRICT x8 = reinterpret_cast(x); ffe_t * LEO_RESTRICT y1 = reinterpret_cast(y); do { for (unsigned j = 0; j < 8; ++j) { uint64_t x_0 = x8[j]; x_0 ^= (uint64_t)lut[y1[0]]; x_0 ^= (uint64_t)lut[y1[1]] << 8; x_0 ^= (uint64_t)lut[y1[2]] << 16; x_0 ^= (uint64_t)lut[y1[3]] << 24; x_0 ^= (uint64_t)lut[y1[4]] << 32; x_0 ^= (uint64_t)lut[y1[5]] << 40; x_0 ^= (uint64_t)lut[y1[6]] << 48; x_0 ^= (uint64_t)lut[y1[7]] << 56; x8[j] = x_0; y1 += 8; } x8 += 8; bytes -= 64; } while (bytes > 0); #endif } // 4-way butterfly static void IFFT_DIT4( uint64_t bytes, void** work, unsigned dist, const ffe_t log_m01, const ffe_t log_m23, const ffe_t log_m02) { #ifdef LEO_INTERLEAVE_BUTTERFLY4_OPT #if defined(LEO_TRY_AVX2) if (CpuHasAVX2) { const LEO_M256 t01_lo = _mm256_loadu_si256(&Multiply256LUT[log_m01].Value[0]); const LEO_M256 t01_hi = _mm256_loadu_si256(&Multiply256LUT[log_m01].Value[1]); const LEO_M256 t23_lo = _mm256_loadu_si256(&Multiply256LUT[log_m23].Value[0]); const LEO_M256 t23_hi = _mm256_loadu_si256(&Multiply256LUT[log_m23].Value[1]); const LEO_M256 t02_lo = _mm256_loadu_si256(&Multiply256LUT[log_m02].Value[0]); const LEO_M256 t02_hi = _mm256_loadu_si256(&Multiply256LUT[log_m02].Value[1]); const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f); LEO_M256 * LEO_RESTRICT work0 = reinterpret_cast(work[0]); LEO_M256 * LEO_RESTRICT work1 = reinterpret_cast(work[dist]); LEO_M256 * LEO_RESTRICT work2 = reinterpret_cast(work[dist * 2]); LEO_M256 * LEO_RESTRICT work3 = reinterpret_cast(work[dist * 3]); do { // First layer: LEO_M256 work0_reg = _mm256_loadu_si256(work0); LEO_M256 work1_reg = _mm256_loadu_si256(work1); work1_reg = _mm256_xor_si256(work0_reg, work1_reg); if (log_m01 != kModulus) LEO_MULADD_256(work0_reg, work1_reg, t01_lo, t01_hi); LEO_M256 work2_reg = _mm256_loadu_si256(work2); LEO_M256 work3_reg = _mm256_loadu_si256(work3); work3_reg = _mm256_xor_si256(work2_reg, work3_reg); if (log_m23 != kModulus) LEO_MULADD_256(work2_reg, work3_reg, t23_lo, t23_hi); // Second layer: work2_reg = _mm256_xor_si256(work0_reg, work2_reg); work3_reg = _mm256_xor_si256(work1_reg, work3_reg); if (log_m02 != kModulus) { LEO_MULADD_256(work0_reg, work2_reg, t02_lo, t02_hi); LEO_MULADD_256(work1_reg, work3_reg, t02_lo, t02_hi); } _mm256_storeu_si256(work0, work0_reg); _mm256_storeu_si256(work1, work1_reg); _mm256_storeu_si256(work2, work2_reg); _mm256_storeu_si256(work3, work3_reg); work0++, work1++, work2++, work3++; bytes -= 32; } while (bytes > 0); return; } #endif // LEO_TRY_AVX2 if (CpuHasSSSE3) { const LEO_M128 t01_lo = _mm_loadu_si128(&Multiply128LUT[log_m01].Value[0]); const LEO_M128 t01_hi = _mm_loadu_si128(&Multiply128LUT[log_m01].Value[1]); const LEO_M128 t23_lo = _mm_loadu_si128(&Multiply128LUT[log_m23].Value[0]); const LEO_M128 t23_hi = _mm_loadu_si128(&Multiply128LUT[log_m23].Value[1]); const LEO_M128 t02_lo = _mm_loadu_si128(&Multiply128LUT[log_m02].Value[0]); const LEO_M128 t02_hi = _mm_loadu_si128(&Multiply128LUT[log_m02].Value[1]); const LEO_M128 clr_mask = _mm_set1_epi8(0x0f); LEO_M128 * LEO_RESTRICT work0 = reinterpret_cast(work[0]); LEO_M128 * LEO_RESTRICT work1 = reinterpret_cast(work[dist]); LEO_M128 * LEO_RESTRICT work2 = reinterpret_cast(work[dist * 2]); LEO_M128 * LEO_RESTRICT work3 = reinterpret_cast(work[dist * 3]); do { // First layer: LEO_M128 work0_reg = _mm_loadu_si128(work0); LEO_M128 work1_reg = _mm_loadu_si128(work1); work1_reg = _mm_xor_si128(work0_reg, work1_reg); if (log_m01 != kModulus) LEO_MULADD_128(work0_reg, work1_reg, t01_lo, t01_hi); LEO_M128 work2_reg = _mm_loadu_si128(work2); LEO_M128 work3_reg = _mm_loadu_si128(work3); work3_reg = _mm_xor_si128(work2_reg, work3_reg); if (log_m23 != kModulus) LEO_MULADD_128(work2_reg, work3_reg, t23_lo, t23_hi); // Second layer: work2_reg = _mm_xor_si128(work0_reg, work2_reg); work3_reg = _mm_xor_si128(work1_reg, work3_reg); if (log_m02 != kModulus) { LEO_MULADD_128(work0_reg, work2_reg, t02_lo, t02_hi); LEO_MULADD_128(work1_reg, work3_reg, t02_lo, t02_hi); } _mm_storeu_si128(work0, work0_reg); _mm_storeu_si128(work1, work1_reg); _mm_storeu_si128(work2, work2_reg); _mm_storeu_si128(work3, work3_reg); work0++, work1++, work2++, work3++; bytes -= 16; } while (bytes > 0); return; } #endif // LEO_INTERLEAVE_BUTTERFLY4_OPT // First layer: if (log_m01 == kModulus) xor_mem(work[dist], work[0], bytes); else IFFT_DIT2(work[0], work[dist], log_m01, bytes); if (log_m23 == kModulus) xor_mem(work[dist * 3], work[dist * 2], bytes); else IFFT_DIT2(work[dist * 2], work[dist * 3], log_m23, bytes); // Second layer: if (log_m02 == kModulus) { xor_mem(work[dist * 2], work[0], bytes); xor_mem(work[dist * 3], work[dist], bytes); } else { IFFT_DIT2(work[0], work[dist * 2], log_m02, bytes); IFFT_DIT2(work[dist], work[dist * 3], log_m02, bytes); } } // {x_out, y_out} ^= IFFT_DIT2( {x_in, y_in} ) static void IFFT_DIT2_xor( void * LEO_RESTRICT x_in, void * LEO_RESTRICT y_in, void * LEO_RESTRICT x_out, void * LEO_RESTRICT y_out, const ffe_t log_m, uint64_t bytes) { #if defined(LEO_TRY_AVX2) if (CpuHasAVX2) { const LEO_M256 table_lo_y = _mm256_loadu_si256(&Multiply256LUT[log_m].Value[0]); const LEO_M256 table_hi_y = _mm256_loadu_si256(&Multiply256LUT[log_m].Value[1]); const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f); const LEO_M256 * LEO_RESTRICT x32_in = reinterpret_cast(x_in); const LEO_M256 * LEO_RESTRICT y32_in = reinterpret_cast(y_in); LEO_M256 * LEO_RESTRICT x32_out = reinterpret_cast(x_out); LEO_M256 * LEO_RESTRICT y32_out = reinterpret_cast(y_out); do { #define LEO_IFFTB_256_XOR(x_ptr_in, y_ptr_in, x_ptr_out, y_ptr_out) { \ LEO_M256 x_data_out = _mm256_loadu_si256(x_ptr_out); \ LEO_M256 y_data_out = _mm256_loadu_si256(y_ptr_out); \ LEO_M256 x_data_in = _mm256_loadu_si256(x_ptr_in); \ LEO_M256 y_data_in = _mm256_loadu_si256(y_ptr_in); \ y_data_in = _mm256_xor_si256(y_data_in, x_data_in); \ y_data_out = _mm256_xor_si256(y_data_out, y_data_in); \ _mm256_storeu_si256(y_ptr_out, y_data_out); \ LEO_MULADD_256(x_data_in, y_data_in, table_lo_y, table_hi_y); \ x_data_out = _mm256_xor_si256(x_data_out, x_data_in); \ _mm256_storeu_si256(x_ptr_out, x_data_out); } LEO_IFFTB_256_XOR(x32_in + 1, y32_in + 1, x32_out + 1, y32_out + 1); LEO_IFFTB_256_XOR(x32_in, y32_in, x32_out, y32_out); y32_in += 2, x32_in += 2, y32_out += 2, x32_out += 2; bytes -= 64; } while (bytes > 0); return; } #endif // LEO_TRY_AVX2 if (CpuHasSSSE3) { const LEO_M128 table_lo_y = _mm_loadu_si128(&Multiply128LUT[log_m].Value[0]); const LEO_M128 table_hi_y = _mm_loadu_si128(&Multiply128LUT[log_m].Value[1]); const LEO_M128 clr_mask = _mm_set1_epi8(0x0f); const LEO_M128 * LEO_RESTRICT x16_in = reinterpret_cast(x_in); const LEO_M128 * LEO_RESTRICT y16_in = reinterpret_cast(y_in); LEO_M128 * LEO_RESTRICT x16_out = reinterpret_cast(x_out); LEO_M128 * LEO_RESTRICT y16_out = reinterpret_cast(y_out); do { #define LEO_IFFTB_128_XOR(x_ptr_in, y_ptr_in, x_ptr_out, y_ptr_out) { \ LEO_M128 x_data_out = _mm_loadu_si128(x_ptr_out); \ LEO_M128 y_data_out = _mm_loadu_si128(y_ptr_out); \ LEO_M128 x_data_in = _mm_loadu_si128(x_ptr_in); \ LEO_M128 y_data_in = _mm_loadu_si128(y_ptr_in); \ y_data_in = _mm_xor_si128(y_data_in, x_data_in); \ y_data_out = _mm_xor_si128(y_data_out, y_data_in); \ _mm_storeu_si128(y_ptr_out, y_data_out); \ LEO_MULADD_128(x_data_in, y_data_in, table_lo_y, table_hi_y); \ x_data_out = _mm_xor_si128(x_data_out, x_data_in); \ _mm_storeu_si128(x_ptr_out, x_data_out); } LEO_IFFTB_128_XOR(x16_in + 3, y16_in + 3, x16_out + 3, y16_out + 3); LEO_IFFTB_128_XOR(x16_in + 2, y16_in + 2, x16_out + 2, y16_out + 2); LEO_IFFTB_128_XOR(x16_in + 1, y16_in + 1, x16_out + 1, y16_out + 1); LEO_IFFTB_128_XOR(x16_in, y16_in, x16_out, y16_out); y16_in += 4, x16_in += 4, y16_out += 4, x16_out += 4; bytes -= 64; } while (bytes > 0); return; } // Reference version: const ffe_t* LEO_RESTRICT lut = Multiply8LUT + log_m * 256; xor_mem(y_in, x_in, bytes); uint64_t count = bytes; ffe_t * LEO_RESTRICT y1 = reinterpret_cast(y_in); #ifdef LEO_TARGET_MOBILE ffe_t * LEO_RESTRICT x1 = reinterpret_cast(x_in); do { for (unsigned j = 0; j < 64; ++j) x1[j] ^= lut[y1[j]]; x1 += 64, y1 += 64; count -= 64; } while (count > 0); #else uint64_t * LEO_RESTRICT x8 = reinterpret_cast(x_in); do { for (unsigned j = 0; j < 8; ++j) { uint64_t x_0 = x8[j]; x_0 ^= (uint64_t)lut[y1[0]]; x_0 ^= (uint64_t)lut[y1[1]] << 8; x_0 ^= (uint64_t)lut[y1[2]] << 16; x_0 ^= (uint64_t)lut[y1[3]] << 24; x_0 ^= (uint64_t)lut[y1[4]] << 32; x_0 ^= (uint64_t)lut[y1[5]] << 40; x_0 ^= (uint64_t)lut[y1[6]] << 48; x_0 ^= (uint64_t)lut[y1[7]] << 56; x8[j] = x_0; y1 += 8; } x8 += 8; count -= 64; } while (count > 0); #endif xor_mem(y_out, y_in, bytes); xor_mem(x_out, x_in, bytes); } // xor_result ^= IFFT_DIT4(work) static void IFFT_DIT4_xor( uint64_t bytes, void** work_in, void** xor_out, unsigned dist, const ffe_t log_m01, const ffe_t log_m23, const ffe_t log_m02) { #ifdef LEO_INTERLEAVE_BUTTERFLY4_OPT #if defined(LEO_TRY_AVX2) if (CpuHasAVX2) { const LEO_M256 t01_lo = _mm256_loadu_si256(&Multiply256LUT[log_m01].Value[0]); const LEO_M256 t01_hi = _mm256_loadu_si256(&Multiply256LUT[log_m01].Value[1]); const LEO_M256 t23_lo = _mm256_loadu_si256(&Multiply256LUT[log_m23].Value[0]); const LEO_M256 t23_hi = _mm256_loadu_si256(&Multiply256LUT[log_m23].Value[1]); const LEO_M256 t02_lo = _mm256_loadu_si256(&Multiply256LUT[log_m02].Value[0]); const LEO_M256 t02_hi = _mm256_loadu_si256(&Multiply256LUT[log_m02].Value[1]); const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f); const LEO_M256 * LEO_RESTRICT work0 = reinterpret_cast(work_in[0]); const LEO_M256 * LEO_RESTRICT work1 = reinterpret_cast(work_in[dist]); const LEO_M256 * LEO_RESTRICT work2 = reinterpret_cast(work_in[dist * 2]); const LEO_M256 * LEO_RESTRICT work3 = reinterpret_cast(work_in[dist * 3]); LEO_M256 * LEO_RESTRICT xor0 = reinterpret_cast(xor_out[0]); LEO_M256 * LEO_RESTRICT xor1 = reinterpret_cast(xor_out[dist]); LEO_M256 * LEO_RESTRICT xor2 = reinterpret_cast(xor_out[dist * 2]); LEO_M256 * LEO_RESTRICT xor3 = reinterpret_cast(xor_out[dist * 3]); do { // First layer: LEO_M256 work0_reg = _mm256_loadu_si256(work0); LEO_M256 work1_reg = _mm256_loadu_si256(work1); work0++, work1++; work1_reg = _mm256_xor_si256(work0_reg, work1_reg); if (log_m01 != kModulus) LEO_MULADD_256(work0_reg, work1_reg, t01_lo, t01_hi); LEO_M256 work2_reg = _mm256_loadu_si256(work2); LEO_M256 work3_reg = _mm256_loadu_si256(work3); work2++, work3++; work3_reg = _mm256_xor_si256(work2_reg, work3_reg); if (log_m23 != kModulus) LEO_MULADD_256(work2_reg, work3_reg, t23_lo, t23_hi); // Second layer: work2_reg = _mm256_xor_si256(work0_reg, work2_reg); work3_reg = _mm256_xor_si256(work1_reg, work3_reg); if (log_m02 != kModulus) { LEO_MULADD_256(work0_reg, work2_reg, t02_lo, t02_hi); LEO_MULADD_256(work1_reg, work3_reg, t02_lo, t02_hi); } work0_reg = _mm256_xor_si256(work0_reg, _mm256_loadu_si256(xor0)); work1_reg = _mm256_xor_si256(work1_reg, _mm256_loadu_si256(xor1)); work2_reg = _mm256_xor_si256(work2_reg, _mm256_loadu_si256(xor2)); work3_reg = _mm256_xor_si256(work3_reg, _mm256_loadu_si256(xor3)); _mm256_storeu_si256(xor0, work0_reg); _mm256_storeu_si256(xor1, work1_reg); _mm256_storeu_si256(xor2, work2_reg); _mm256_storeu_si256(xor3, work3_reg); xor0++, xor1++, xor2++, xor3++; bytes -= 32; } while (bytes > 0); return; } #endif // LEO_TRY_AVX2 if (CpuHasSSSE3) { const LEO_M128 t01_lo = _mm_loadu_si128(&Multiply128LUT[log_m01].Value[0]); const LEO_M128 t01_hi = _mm_loadu_si128(&Multiply128LUT[log_m01].Value[1]); const LEO_M128 t23_lo = _mm_loadu_si128(&Multiply128LUT[log_m23].Value[0]); const LEO_M128 t23_hi = _mm_loadu_si128(&Multiply128LUT[log_m23].Value[1]); const LEO_M128 t02_lo = _mm_loadu_si128(&Multiply128LUT[log_m02].Value[0]); const LEO_M128 t02_hi = _mm_loadu_si128(&Multiply128LUT[log_m02].Value[1]); const LEO_M128 clr_mask = _mm_set1_epi8(0x0f); const LEO_M128 * LEO_RESTRICT work0 = reinterpret_cast(work_in[0]); const LEO_M128 * LEO_RESTRICT work1 = reinterpret_cast(work_in[dist]); const LEO_M128 * LEO_RESTRICT work2 = reinterpret_cast(work_in[dist * 2]); const LEO_M128 * LEO_RESTRICT work3 = reinterpret_cast(work_in[dist * 3]); LEO_M128 * LEO_RESTRICT xor0 = reinterpret_cast(xor_out[0]); LEO_M128 * LEO_RESTRICT xor1 = reinterpret_cast(xor_out[dist]); LEO_M128 * LEO_RESTRICT xor2 = reinterpret_cast(xor_out[dist * 2]); LEO_M128 * LEO_RESTRICT xor3 = reinterpret_cast(xor_out[dist * 3]); do { // First layer: LEO_M128 work0_reg = _mm_loadu_si128(work0); LEO_M128 work1_reg = _mm_loadu_si128(work1); work0++, work1++; work1_reg = _mm_xor_si128(work0_reg, work1_reg); if (log_m01 != kModulus) LEO_MULADD_128(work0_reg, work1_reg, t01_lo, t01_hi); LEO_M128 work2_reg = _mm_loadu_si128(work2); LEO_M128 work3_reg = _mm_loadu_si128(work3); work2++, work3++; work3_reg = _mm_xor_si128(work2_reg, work3_reg); if (log_m23 != kModulus) LEO_MULADD_128(work2_reg, work3_reg, t23_lo, t23_hi); // Second layer: work2_reg = _mm_xor_si128(work0_reg, work2_reg); work3_reg = _mm_xor_si128(work1_reg, work3_reg); if (log_m02 != kModulus) { LEO_MULADD_128(work0_reg, work2_reg, t02_lo, t02_hi); LEO_MULADD_128(work1_reg, work3_reg, t02_lo, t02_hi); } work0_reg = _mm_xor_si128(work0_reg, _mm_loadu_si128(xor0)); work1_reg = _mm_xor_si128(work1_reg, _mm_loadu_si128(xor1)); work2_reg = _mm_xor_si128(work2_reg, _mm_loadu_si128(xor2)); work3_reg = _mm_xor_si128(work3_reg, _mm_loadu_si128(xor3)); _mm_storeu_si128(xor0, work0_reg); _mm_storeu_si128(xor1, work1_reg); _mm_storeu_si128(xor2, work2_reg); _mm_storeu_si128(xor3, work3_reg); xor0++, xor1++, xor2++, xor3++; bytes -= 16; } while (bytes > 0); return; } #endif // LEO_INTERLEAVE_BUTTERFLY4_OPT // First layer: if (log_m01 == kModulus) xor_mem(work_in[dist], work_in[0], bytes); else IFFT_DIT2(work_in[0], work_in[dist], log_m01, bytes); if (log_m23 == kModulus) xor_mem(work_in[dist * 3], work_in[dist * 2], bytes); else IFFT_DIT2(work_in[dist * 2], work_in[dist * 3], log_m23, bytes); // Second layer: if (log_m02 == kModulus) { xor_mem(work_in[dist * 2], work_in[0], bytes); xor_mem(work_in[dist * 3], work_in[dist], bytes); } else { IFFT_DIT2(work_in[0], work_in[dist * 2], log_m02, bytes); IFFT_DIT2(work_in[dist], work_in[dist * 3], log_m02, bytes); } xor_mem(xor_out[0], work_in[0], bytes); xor_mem(xor_out[dist], work_in[dist], bytes); xor_mem(xor_out[dist * 2], work_in[dist * 2], bytes); xor_mem(xor_out[dist * 3], work_in[dist * 3], bytes); } // Unrolled IFFT for encoder static void IFFT_DIT_Encoder( const uint64_t bytes, const void* const* data, const unsigned m_truncated, void** work, void** xor_result, const unsigned m, const ffe_t* skewLUT) { // 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 (unsigned i = 0; i < m_truncated; ++i) memcpy(work[i], data[i], bytes); for (unsigned i = m_truncated; i < m; ++i) memset(work[i], 0, bytes); // 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 unsigned dist = 1, dist4 = 4; for (; dist4 <= m; dist = dist4, dist4 <<= 2) { // For each set of dist*4 elements: for (unsigned r = 0; r < m_truncated; r += dist4) { const unsigned i_end = r + dist; const ffe_t log_m01 = skewLUT[i_end]; const ffe_t log_m02 = skewLUT[i_end + dist]; const ffe_t log_m23 = skewLUT[i_end + dist * 2]; if (dist4 == m && xor_result) { // For each set of dist elements: for (unsigned i = r; i < i_end; ++i) { IFFT_DIT4_xor( bytes, work + i, xor_result + i, dist, log_m01, log_m23, log_m02); } } else { // For each set of dist elements: for (unsigned i = r; i < i_end; ++i) { IFFT_DIT4( bytes, work + i, dist, log_m01, log_m23, log_m02); } } } // 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 LEO_DEBUG_ASSERT(dist * 2 == m); const ffe_t log_m = skewLUT[dist]; if (xor_result) { if (log_m == kModulus) { for (unsigned i = 0; i < dist; ++i) xor_mem_2to1(xor_result[i], work[i], work[i + dist], bytes); } else { for (unsigned i = 0; i < dist; ++i) { IFFT_DIT2_xor( work[i], work[i + dist], xor_result[i], xor_result[i + dist], log_m, bytes); } } } else { if (log_m == kModulus) VectorXOR(bytes, dist, work + dist, work); else { for (unsigned i = 0; i < dist; ++i) { IFFT_DIT2( work[i], work[i + dist], log_m, bytes); } } } } } // Basic no-frills version for decoder static void IFFT_DIT_Decoder( const uint64_t bytes, const unsigned m_truncated, void** work, const unsigned m, const ffe_t* skewLUT) { // Decimation in time: Unroll 2 layers at a time unsigned dist = 1, dist4 = 4; for (; dist4 <= m; dist = dist4, dist4 <<= 2) { // For each set of dist*4 elements: for (unsigned r = 0; r < m_truncated; r += dist4) { const unsigned i_end = r + dist; const ffe_t log_m01 = skewLUT[i_end]; const ffe_t log_m02 = skewLUT[i_end + dist]; const ffe_t log_m23 = skewLUT[i_end + dist * 2]; // For each set of dist elements: for (unsigned i = r; i < i_end; ++i) { IFFT_DIT4( bytes, work + i, dist, log_m01, log_m23, log_m02); } } } // If there is one layer left: if (dist < m) { // Assuming that dist = m / 2 LEO_DEBUG_ASSERT(dist * 2 == m); const ffe_t log_m = skewLUT[dist]; if (log_m == kModulus) VectorXOR(bytes, dist, work + dist, work); else { for (unsigned i = 0; i < dist; ++i) { IFFT_DIT2( work[i], work[i + dist], log_m, bytes); } } } } /* Decimation in time FFT: The decimation in time FFT algorithm allows us to unroll 2 layers at a time, performing calculations on local registers and faster cache memory. Each ^___^ below indicates a butterfly between the associated indices. The fft_butterfly(x, y) operation: if (log_m != kModulus) x[] ^= exp(log(y[]) + log_m) y[] ^= x[] Layer 0: 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 ^_______________^ ^_______________^ ^_______________^ ^_______________^ ^_______________^ ^_______________^ ^_______________^ ^_______________^ Layer 1: 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 ^_______^ ^_______^ ^_______^ ^_______^ ^_______^ ^_______^ ^_______^ ^_______^ Layer 2: 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 ^___^ ^___^ ^___^ ^___^ ^___^ ^___^ ^___^ ^___^ Layer 3: 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 ^_^ ^_^ ^_^ ^_^ ^_^ ^_^ ^_^ ^_^ DIT layer 0-1 operations, grouped 4 at a time: {0-0', 4-4', 0-4, 0'-4'}, {1-1', 5-5', 1-5, 1'-5'}, DIT layer 1-2 operations, grouped 4 at a time: {0-4, 2-6, 0-2, 4-6}, {1-5, 3-7, 1-3, 5-7}, DIT layer 2-3 operations, grouped 4 at a time: {0-2, 1-3, 0-1, 2-3}, {4-6, 5-7, 4-5, 6-7}, */ // 2-way butterfly static void FFT_DIT2( void * LEO_RESTRICT x, void * LEO_RESTRICT y, ffe_t log_m, uint64_t bytes) { #if defined(LEO_TRY_AVX2) if (CpuHasAVX2) { const LEO_M256 table_lo_y = _mm256_loadu_si256(&Multiply256LUT[log_m].Value[0]); const LEO_M256 table_hi_y = _mm256_loadu_si256(&Multiply256LUT[log_m].Value[1]); const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f); LEO_M256 * LEO_RESTRICT x32 = reinterpret_cast(x); LEO_M256 * LEO_RESTRICT y32 = reinterpret_cast(y); do { #define LEO_FFTB_256(x_ptr, y_ptr) { \ LEO_M256 y_data = _mm256_loadu_si256(y_ptr); \ LEO_M256 x_data = _mm256_loadu_si256(x_ptr); \ LEO_MULADD_256(x_data, y_data, table_lo_y, table_hi_y); \ y_data = _mm256_xor_si256(y_data, x_data); \ _mm256_storeu_si256(x_ptr, x_data); \ _mm256_storeu_si256(y_ptr, y_data); } LEO_FFTB_256(x32 + 1, y32 + 1); LEO_FFTB_256(x32, y32); y32 += 2, x32 += 2; bytes -= 64; } while (bytes > 0); return; } #endif // LEO_TRY_AVX2 if (CpuHasSSSE3) { const LEO_M128 table_lo_y = _mm_loadu_si128(&Multiply128LUT[log_m].Value[0]); const LEO_M128 table_hi_y = _mm_loadu_si128(&Multiply128LUT[log_m].Value[1]); const LEO_M128 clr_mask = _mm_set1_epi8(0x0f); LEO_M128 * LEO_RESTRICT x16 = reinterpret_cast(x); LEO_M128 * LEO_RESTRICT y16 = reinterpret_cast(y); do { #define LEO_FFTB_128(x_ptr, y_ptr) { \ LEO_M128 y_data = _mm_loadu_si128(y_ptr); \ LEO_M128 x_data = _mm_loadu_si128(x_ptr); \ LEO_MULADD_128(x_data, y_data, table_lo_y, table_hi_y); \ y_data = _mm_xor_si128(y_data, x_data); \ _mm_storeu_si128(x_ptr, x_data); \ _mm_storeu_si128(y_ptr, y_data); } LEO_FFTB_128(x16 + 3, y16 + 3); LEO_FFTB_128(x16 + 2, y16 + 2); LEO_FFTB_128(x16 + 1, y16 + 1); LEO_FFTB_128(x16, y16); x16 += 4, y16 += 4; bytes -= 64; } while (bytes > 0); return; } // Reference version: const ffe_t* LEO_RESTRICT lut = Multiply8LUT + log_m * 256; #ifdef LEO_TARGET_MOBILE ffe_t * LEO_RESTRICT x1 = reinterpret_cast(x); ffe_t * LEO_RESTRICT y1 = reinterpret_cast(y); do { for (unsigned j = 0; j < 64; ++j) { ffe_t x_0 = x1[j]; ffe_t y_0 = y1[j]; x_0 ^= lut[y_0]; x1[j] = x_0; y1[j] = y_0 ^ x_0; } x1 += 64, y1 += 64; bytes -= 64; } while (bytes > 0); #else uint64_t * LEO_RESTRICT x8 = reinterpret_cast(x); uint64_t * LEO_RESTRICT y8 = reinterpret_cast(y); ffe_t * LEO_RESTRICT y1 = reinterpret_cast(y); do { for (unsigned j = 0; j < 8; ++j) { uint64_t x_0 = x8[j], y_0 = y8[j]; x_0 ^= (uint64_t)lut[y1[0]]; x_0 ^= (uint64_t)lut[y1[1]] << 8; x_0 ^= (uint64_t)lut[y1[2]] << 16; x_0 ^= (uint64_t)lut[y1[3]] << 24; x_0 ^= (uint64_t)lut[y1[4]] << 32; x_0 ^= (uint64_t)lut[y1[5]] << 40; x_0 ^= (uint64_t)lut[y1[6]] << 48; x_0 ^= (uint64_t)lut[y1[7]] << 56; x8[j] = x_0, y8[j] = y_0 ^ x_0; y1 += 8; } x8 += 8, y8 += 8; bytes -= 64; } while (bytes > 0); #endif } // 4-way butterfly static void FFT_DIT4( uint64_t bytes, void** work, unsigned dist, const ffe_t log_m01, const ffe_t log_m23, const ffe_t log_m02) { #ifdef LEO_INTERLEAVE_BUTTERFLY4_OPT if (CpuHasAVX2) { const LEO_M256 t01_lo = _mm256_loadu_si256(&Multiply256LUT[log_m01].Value[0]); const LEO_M256 t01_hi = _mm256_loadu_si256(&Multiply256LUT[log_m01].Value[1]); const LEO_M256 t23_lo = _mm256_loadu_si256(&Multiply256LUT[log_m23].Value[0]); const LEO_M256 t23_hi = _mm256_loadu_si256(&Multiply256LUT[log_m23].Value[1]); const LEO_M256 t02_lo = _mm256_loadu_si256(&Multiply256LUT[log_m02].Value[0]); const LEO_M256 t02_hi = _mm256_loadu_si256(&Multiply256LUT[log_m02].Value[1]); const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f); LEO_M256 * LEO_RESTRICT work0 = reinterpret_cast(work[0]); LEO_M256 * LEO_RESTRICT work1 = reinterpret_cast(work[dist]); LEO_M256 * LEO_RESTRICT work2 = reinterpret_cast(work[dist * 2]); LEO_M256 * LEO_RESTRICT work3 = reinterpret_cast(work[dist * 3]); do { LEO_M256 work0_reg = _mm256_loadu_si256(work0); LEO_M256 work2_reg = _mm256_loadu_si256(work2); LEO_M256 work1_reg = _mm256_loadu_si256(work1); LEO_M256 work3_reg = _mm256_loadu_si256(work3); // First layer: if (log_m02 != kModulus) { LEO_MULADD_256(work0_reg, work2_reg, t02_lo, t02_hi); LEO_MULADD_256(work1_reg, work3_reg, t02_lo, t02_hi); } work2_reg = _mm256_xor_si256(work0_reg, work2_reg); work3_reg = _mm256_xor_si256(work1_reg, work3_reg); // Second layer: if (log_m01 != kModulus) LEO_MULADD_256(work0_reg, work1_reg, t01_lo, t01_hi); work1_reg = _mm256_xor_si256(work0_reg, work1_reg); _mm256_storeu_si256(work0, work0_reg); _mm256_storeu_si256(work1, work1_reg); work0++, work1++; if (log_m23 != kModulus) LEO_MULADD_256(work2_reg, work3_reg, t23_lo, t23_hi); work3_reg = _mm256_xor_si256(work2_reg, work3_reg); _mm256_storeu_si256(work2, work2_reg); _mm256_storeu_si256(work3, work3_reg); work2++, work3++; bytes -= 32; } while (bytes > 0); return; } if (CpuHasSSSE3) { const LEO_M128 t01_lo = _mm_loadu_si128(&Multiply128LUT[log_m01].Value[0]); const LEO_M128 t01_hi = _mm_loadu_si128(&Multiply128LUT[log_m01].Value[1]); const LEO_M128 t23_lo = _mm_loadu_si128(&Multiply128LUT[log_m23].Value[0]); const LEO_M128 t23_hi = _mm_loadu_si128(&Multiply128LUT[log_m23].Value[1]); const LEO_M128 t02_lo = _mm_loadu_si128(&Multiply128LUT[log_m02].Value[0]); const LEO_M128 t02_hi = _mm_loadu_si128(&Multiply128LUT[log_m02].Value[1]); const LEO_M128 clr_mask = _mm_set1_epi8(0x0f); LEO_M128 * LEO_RESTRICT work0 = reinterpret_cast(work[0]); LEO_M128 * LEO_RESTRICT work1 = reinterpret_cast(work[dist]); LEO_M128 * LEO_RESTRICT work2 = reinterpret_cast(work[dist * 2]); LEO_M128 * LEO_RESTRICT work3 = reinterpret_cast(work[dist * 3]); do { LEO_M128 work0_reg = _mm_loadu_si128(work0); LEO_M128 work2_reg = _mm_loadu_si128(work2); LEO_M128 work1_reg = _mm_loadu_si128(work1); LEO_M128 work3_reg = _mm_loadu_si128(work3); // First layer: if (log_m02 != kModulus) { LEO_MULADD_128(work0_reg, work2_reg, t02_lo, t02_hi); LEO_MULADD_128(work1_reg, work3_reg, t02_lo, t02_hi); } work2_reg = _mm_xor_si128(work0_reg, work2_reg); work3_reg = _mm_xor_si128(work1_reg, work3_reg); // Second layer: if (log_m01 != kModulus) LEO_MULADD_128(work0_reg, work1_reg, t01_lo, t01_hi); work1_reg = _mm_xor_si128(work0_reg, work1_reg); _mm_storeu_si128(work0, work0_reg); _mm_storeu_si128(work1, work1_reg); work0++, work1++; if (log_m23 != kModulus) LEO_MULADD_128(work2_reg, work3_reg, t23_lo, t23_hi); work3_reg = _mm_xor_si128(work2_reg, work3_reg); _mm_storeu_si128(work2, work2_reg); _mm_storeu_si128(work3, work3_reg); work2++, work3++; bytes -= 16; } while (bytes > 0); return; } #endif // LEO_INTERLEAVE_BUTTERFLY4_OPT // First layer: if (log_m02 == kModulus) { xor_mem(work[dist * 2], work[0], bytes); xor_mem(work[dist * 3], work[dist], bytes); } else { FFT_DIT2(work[0], work[dist * 2], log_m02, bytes); FFT_DIT2(work[dist], work[dist * 3], log_m02, bytes); } // Second layer: if (log_m01 == kModulus) xor_mem(work[dist], work[0], bytes); else FFT_DIT2(work[0], work[dist], log_m01, bytes); if (log_m23 == kModulus) xor_mem(work[dist * 3], work[dist * 2], bytes); else FFT_DIT2(work[dist * 2], work[dist * 3], log_m23, bytes); } // In-place FFT for encoder and decoder static void FFT_DIT( const uint64_t bytes, void** work, const unsigned m_truncated, const unsigned m, const ffe_t* skewLUT) { // Decimation in time: Unroll 2 layers at a time unsigned dist4 = m, dist = m >> 2; for (; dist != 0; dist4 = dist, dist >>= 2) { // For each set of dist*4 elements: for (unsigned r = 0; r < m_truncated; r += dist4) { const unsigned i_end = r + dist; const ffe_t log_m01 = skewLUT[i_end]; const ffe_t log_m02 = skewLUT[i_end + dist]; const ffe_t log_m23 = skewLUT[i_end + dist * 2]; // For each set of dist elements: for (unsigned i = r; i < i_end; ++i) { FFT_DIT4( bytes, work + i, dist, log_m01, log_m23, log_m02); } } } // If there is one layer left: if (dist4 == 2) { for (unsigned r = 0; r < m_truncated; r += 2) { const ffe_t log_m = skewLUT[r + 1]; if (log_m == kModulus) xor_mem(work[r + 1], work[r], bytes); else { FFT_DIT2( work[r], work[r + 1], log_m, bytes); } } } } //------------------------------------------------------------------------------ // Reed-Solomon Encode void ReedSolomonEncode( uint64_t buffer_bytes, unsigned original_count, unsigned recovery_count, unsigned m, const void* const* data, void** work, bool multithreaded) { // work <- IFFT(data, m, m) const ffe_t* skewLUT = FFTSkew + m - 1; IFFT_DIT_Encoder( buffer_bytes, data, original_count < m ? original_count : m, work, nullptr, // No xor output m, skewLUT); const unsigned last_count = original_count % m; if (m >= original_count) goto skip_body; // For sets of m data pieces: for (unsigned i = m; i + m <= original_count; i += m) { data += m; skewLUT += m; // work <- work xor IFFT(data + i, m, m + i) IFFT_DIT_Encoder( buffer_bytes, data, // data source m, work + m, // temporary workspace work, // xor destination m, skewLUT); } // Handle final partial set of m pieces: if (last_count != 0) { const unsigned i = original_count - last_count; data += m; skewLUT += m; // work <- work xor IFFT(data + i, m, m + i) IFFT_DIT_Encoder( buffer_bytes, data, // data source last_count, work + m, // temporary workspace work, // xor destination m, skewLUT); } skip_body: // work <- FFT(work, m, 0) FFT_DIT( buffer_bytes, work, recovery_count, m, FFTSkew - 1); } //------------------------------------------------------------------------------ // ErrorBitfield #ifdef LEO_ERROR_BITFIELD_OPT // Used in decoding to decide which final FFT operations to perform class ErrorBitfield { static const unsigned kWords = kOrder / 64; uint64_t Words[7][kWords] = {}; public: LEO_FORCE_INLINE void Set(unsigned i) { Words[0][i / 64] |= (uint64_t)1 << (i % 64); } void Prepare(); LEO_FORCE_INLINE bool IsNeeded(unsigned mip_level, unsigned bit) const { if (mip_level >= 8) return true; return 0 != (Words[mip_level - 1][bit / 64] & ((uint64_t)1 << (bit % 64))); } }; static const uint64_t kHiMasks[5] = { 0xAAAAAAAAAAAAAAAAULL, 0xCCCCCCCCCCCCCCCCULL, 0xF0F0F0F0F0F0F0F0ULL, 0xFF00FF00FF00FF00ULL, 0xFFFF0000FFFF0000ULL, }; void ErrorBitfield::Prepare() { // First mip level is for final layer of FFT: pairs of data for (unsigned i = 0; i < kWords; ++i) { uint64_t w_i = Words[0][i]; const uint64_t hi2lo0 = w_i | ((w_i & kHiMasks[0]) >> 1); const uint64_t lo2hi0 = ((w_i & (kHiMasks[0] >> 1)) << 1); Words[0][i] = w_i = hi2lo0 | lo2hi0; for (unsigned j = 1, bits = 2; j < 5; ++j, bits <<= 1) { const uint64_t hi2lo_j = w_i | ((w_i & kHiMasks[j]) >> bits); const uint64_t lo2hi_j = ((w_i & (kHiMasks[j] >> bits)) << bits); Words[j][i] = w_i = hi2lo_j | lo2hi_j; } } for (unsigned i = 0; i < kWords; ++i) { uint64_t w = Words[4][i]; w |= w >> 32; w |= w << 32; Words[5][i] = w; } for (unsigned i = 0; i < kWords; i += 2) Words[6][i] = Words[6][i + 1] = Words[5][i] | Words[5][i + 1]; } static void FFT_DIT_ErrorBits( const uint64_t bytes, void** work, const unsigned n_truncated, const unsigned n, const ffe_t* skewLUT, const ErrorBitfield& error_bits) { unsigned mip_level = LastNonzeroBit32(n); // Decimation in time: Unroll 2 layers at a time unsigned dist4 = n, dist = n >> 2; for (; dist != 0; dist4 = dist, dist >>= 2, mip_level -=2) { // For each set of dist*4 elements: for (unsigned r = 0; r < n_truncated; r += dist4) { if (!error_bits.IsNeeded(mip_level, r)) continue; const ffe_t log_m01 = skewLUT[r + dist]; const ffe_t log_m23 = skewLUT[r + dist * 3]; const ffe_t log_m02 = skewLUT[r + dist * 2]; // For each set of dist elements: for (unsigned i = r; i < r + dist; ++i) { FFT_DIT4( bytes, work + i, dist, log_m01, log_m23, log_m02); } } } // If there is one layer left: if (dist4 == 2) { for (unsigned r = 0; r < n_truncated; r += 2) { const ffe_t log_m = skewLUT[r + 1]; if (log_m == kModulus) xor_mem(work[r + 1], work[r], bytes); else { FFT_DIT2( work[r], work[r + 1], log_m, bytes); } } } } #endif // LEO_ERROR_BITFIELD_OPT //------------------------------------------------------------------------------ // Reed-Solomon Decode void ReedSolomonDecode( uint64_t buffer_bytes, unsigned original_count, unsigned recovery_count, unsigned m, // NextPow2(recovery_count) unsigned n, // NextPow2(m + original_count) = work_count const void* const * const original, // original_count entries const void* const * const recovery, // recovery_count entries void** work, // n entries bool multithreaded) { // Fill in error locations #ifdef LEO_ERROR_BITFIELD_OPT ErrorBitfield error_bits; #endif // LEO_ERROR_BITFIELD_OPT ffe_t error_locations[kOrder] = {}; for (unsigned i = 0; i < recovery_count; ++i) if (!recovery[i]) error_locations[i] = 1; for (unsigned i = recovery_count; i < m; ++i) error_locations[i] = 1; for (unsigned i = 0; i < original_count; ++i) { if (!original[i]) { error_locations[i + m] = 1; #ifdef LEO_ERROR_BITFIELD_OPT error_bits.Set(i + m); #endif // LEO_ERROR_BITFIELD_OPT } } #ifdef LEO_ERROR_BITFIELD_OPT error_bits.Prepare(); #endif // LEO_ERROR_BITFIELD_OPT // Evaluate error locator polynomial FWHT(error_locations, kOrder, m + original_count); for (unsigned i = 0; i < kOrder; ++i) error_locations[i] = ((unsigned)error_locations[i] * (unsigned)LogWalsh[i]) % kModulus; FWHT(error_locations, kOrder, kOrder); // work <- recovery data for (unsigned i = 0; i < recovery_count; ++i) { if (recovery[i]) mul_mem(work[i], recovery[i], error_locations[i], buffer_bytes); else memset(work[i], 0, buffer_bytes); } for (unsigned i = recovery_count; i < m; ++i) memset(work[i], 0, buffer_bytes); // work <- original data for (unsigned i = 0; i < original_count; ++i) { if (original[i]) mul_mem(work[m + i], original[i], error_locations[m + i], buffer_bytes); else memset(work[m + i], 0, buffer_bytes); } for (unsigned i = m + original_count; i < n; ++i) memset(work[i], 0, buffer_bytes); // work <- IFFT(work, n, 0) IFFT_DIT_Decoder( buffer_bytes, m + original_count, work, n, FFTSkew - 1); // work <- FormalDerivative(work, n) for (unsigned i = 1; i < n; ++i) { const unsigned width = ((i ^ (i - 1)) + 1) >> 1; VectorXOR( buffer_bytes, width, work + i - width, work + i); } // work <- FFT(work, n, 0) truncated to m + original_count const unsigned output_count = m + original_count; #ifdef LEO_ERROR_BITFIELD_OPT FFT_DIT_ErrorBits(buffer_bytes, work, output_count, n, FFTSkew - 1, error_bits); #else FFT_DIT(buffer_bytes, work, output_count, n, FFTSkew - 1); #endif // Reveal erasures for (unsigned i = 0; i < original_count; ++i) if (!original[i]) mul_mem(work[i], work[i + m], kModulus - error_locations[i + m], buffer_bytes); } //------------------------------------------------------------------------------ // API static bool IsInitialized = false; bool Initialize() { if (IsInitialized) return true; InitializeLogarithmTables(); InitializeMultiplyTables(); FFTInitialize(); IsInitialized = true; return true; } }} // namespace leopard::ff8 #endif // LEO_HAS_FF8