leopard/LeopardFF16.cpp

1457 lines
44 KiB
C++

/*
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 "LeopardFF16.h"
#ifdef LEO_HAS_FF16
#include <string.h>
namespace leopard { namespace ff16 {
//------------------------------------------------------------------------------
// Datatypes and Constants
// Basis used for generating logarithm tables
static const ffe_t kCantorBasis[kBits] = {
0x0001, 0xACCA, 0x3C0E, 0x163E,
0xC582, 0xED2E, 0x914C, 0x4012,
0x6C98, 0x10D8, 0x6A72, 0xB900,
0xFDB8, 0xFB34, 0xFF38, 0x991E
};
// Using the Cantor basis 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 = (unsigned)a + b;
// Partial reduction step, allowing for kModulus to be returned
return static_cast<ffe_t>(sum + (sum >> kBits));
}
// z = x - y (mod kModulus)
static inline ffe_t SubMod(const ffe_t a, const ffe_t b)
{
const unsigned dif = (unsigned)a - b;
// Partial reduction step, allowing for kModulus to be returned
return static_cast<ffe_t>(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;
}
#if defined(LEO_FWHT_OPT)
static LEO_FORCE_INLINE void FWHT_4(ffe_t* data)
{
ffe_t t0 = data[0];
ffe_t t1 = data[1];
ffe_t t2 = data[2];
ffe_t t3 = data[3];
FWHT_2(t0, t1);
FWHT_2(t2, t3);
FWHT_2(t0, t2);
FWHT_2(t1, t3);
data[0] = t0;
data[1] = t1;
data[2] = t2;
data[3] = t3;
}
static LEO_FORCE_INLINE void FWHT_4(ffe_t* data, unsigned s)
{
unsigned x = 0;
ffe_t t0 = data[x]; x += s;
ffe_t t1 = data[x]; x += s;
ffe_t t2 = data[x]; x += s;
ffe_t t3 = data[x];
FWHT_2(t0, t1);
FWHT_2(t2, t3);
FWHT_2(t0, t2);
FWHT_2(t1, t3);
unsigned y = 0;
data[y] = t0; y += s;
data[y] = t1; y += s;
data[y] = t2; y += s;
data[y] = t3;
}
static inline void FWHT_8(ffe_t* data)
{
ffe_t t0 = data[0];
ffe_t t1 = data[1];
ffe_t t2 = data[2];
ffe_t t3 = data[3];
ffe_t t4 = data[4];
ffe_t t5 = data[5];
ffe_t t6 = data[6];
ffe_t t7 = data[7];
FWHT_2(t0, t1);
FWHT_2(t2, t3);
FWHT_2(t4, t5);
FWHT_2(t6, t7);
FWHT_2(t0, t2);
FWHT_2(t1, t3);
FWHT_2(t4, t6);
FWHT_2(t5, t7);
FWHT_2(t0, t4);
FWHT_2(t1, t5);
FWHT_2(t2, t6);
FWHT_2(t3, t7);
data[0] = t0;
data[1] = t1;
data[2] = t2;
data[3] = t3;
data[4] = t4;
data[5] = t5;
data[6] = t6;
data[7] = t7;
}
static inline void FWHT_16(ffe_t* data)
{
ffe_t t0 = data[0];
ffe_t t1 = data[1];
ffe_t t2 = data[2];
ffe_t t3 = data[3];
ffe_t t4 = data[4];
ffe_t t5 = data[5];
ffe_t t6 = data[6];
ffe_t t7 = data[7];
ffe_t t8 = data[8];
ffe_t t9 = data[9];
ffe_t t10 = data[10];
ffe_t t11 = data[11];
ffe_t t12 = data[12];
ffe_t t13 = data[13];
ffe_t t14 = data[14];
ffe_t t15 = data[15];
FWHT_2(t0, t1);
FWHT_2(t2, t3);
FWHT_2(t4, t5);
FWHT_2(t6, t7);
FWHT_2(t8, t9);
FWHT_2(t10, t11);
FWHT_2(t12, t13);
FWHT_2(t14, t15);
FWHT_2(t0, t2);
FWHT_2(t1, t3);
FWHT_2(t4, t6);
FWHT_2(t5, t7);
FWHT_2(t8, t10);
FWHT_2(t9, t11);
FWHT_2(t12, t14);
FWHT_2(t13, t15);
FWHT_2(t0, t4);
FWHT_2(t1, t5);
FWHT_2(t2, t6);
FWHT_2(t3, t7);
FWHT_2(t8, t12);
FWHT_2(t9, t13);
FWHT_2(t10, t14);
FWHT_2(t11, t15);
FWHT_2(t0, t8);
FWHT_2(t1, t9);
FWHT_2(t2, t10);
FWHT_2(t3, t11);
FWHT_2(t4, t12);
FWHT_2(t5, t13);
FWHT_2(t6, t14);
FWHT_2(t7, t15);
data[0] = t0;
data[1] = t1;
data[2] = t2;
data[3] = t3;
data[4] = t4;
data[5] = t5;
data[6] = t6;
data[7] = t7;
data[8] = t8;
data[9] = t9;
data[10] = t10;
data[11] = t11;
data[12] = t12;
data[13] = t13;
data[14] = t14;
data[15] = t15;
}
static void FWHT_SmallData(ffe_t* data, unsigned bits)
{
const unsigned n = (1UL << bits);
if (n <= 2)
{
if (n == 2)
FWHT_2(data[0], data[1]);
return;
}
for (unsigned i = bits; i > 3; i -= 2)
{
unsigned m = (1UL << i);
unsigned m4 = (m >> 2);
for (unsigned r = 0; r < n; r += m)
for (unsigned j = 0; j < m4; j++)
FWHT_4(data + j + r, m4);
}
if (bits & 1)
{
for (unsigned i0 = 0; i0 < n; i0 += 8)
FWHT_8(data + i0);
}
else
{
for (unsigned i0 = 0; i0 < n; i0 += 4)
FWHT_4(data + i0);
}
}
// Decimation in time (DIT) version
static void FWHT(ffe_t* data, const unsigned bits)
{
if (bits <= 13)
{
FWHT_SmallData(data, bits);
return;
}
FWHT_2(data[2], data[3]);
FWHT_4(data + 4);
FWHT_8(data + 8);
FWHT_16(data + 16);
for (unsigned i = 5; i < bits; ++i)
FWHT(data + (unsigned)(1UL << i), i);
for (unsigned i = 0; i < bits; ++i)
{
const unsigned mh = (1UL << i);
for (unsigned t1 = 0, t2 = mh; t1 < mh; ++t1, ++t2)
FWHT_2(data[t1], data[t2]);
}
}
#else // LEO_FWHT_OPT
// Reference implementation
void FWHT(ffe_t* data, const unsigned bits)
{
const unsigned size = (unsigned)(1UL << bits);
for (unsigned width = 1; width < size; width <<= 1)
for (unsigned i = 0; i < size; i += (width << 1))
for (unsigned j = i; j < (width + i); ++j)
FWHT_2(data[j], data[j + width]);
}
#endif // LEO_FWHT_OPT
// Transform specialized for the finite field order
void FWHT(ffe_t data[kOrder])
{
FWHT(data, kBits);
}
//------------------------------------------------------------------------------
// 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<ffe_t>(i);
state <<= 1;
if (state >= kOrder)
state ^= kPolynomial;
}
ExpLUT[0] = kModulus;
// Conversion to Cantor basis:
LogLUT[0] = 0;
for (unsigned i = 0; i < kBits; ++i)
{
const ffe_t basis = kCantorBasis[i];
const unsigned width = static_cast<unsigned>(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]];
for (unsigned i = 0; i < kOrder; ++i)
ExpLUT[LogLUT[i]] = i;
ExpLUT[kModulus] = ExpLUT[0];
}
//------------------------------------------------------------------------------
// Multiplies
/*
The multiplication algorithm used follows the approach outlined in {4}.
Specifically section 7 outlines the algorithm used here for 16-bit fields.
The ALTMAP memory layout is used since there is no need to convert in/out.
*/
struct {
LEO_ALIGNED LEO_M128 Lo[4];
LEO_ALIGNED LEO_M128 Hi[4];
} static Multiply128LUT[kOrder];
#if defined(LEO_TRY_AVX2)
struct {
LEO_ALIGNED LEO_M256 Lo[4];
LEO_ALIGNED LEO_M256 Hi[4];
} static Multiply256LUT[kOrder];
#endif // LEO_TRY_AVX2
void InitializeMultiplyTables()
{
// 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 < 4; ++i, shift += 4)
{
// Construct 16 entry LUT for PSHUFB
uint8_t prod_lo[16], prod_hi[16];
for (ffe_t x = 0; x < 16; ++x)
{
const ffe_t prod = MultiplyLog(x << shift, static_cast<ffe_t>(log_m));
prod_lo[x] = static_cast<uint8_t>(prod);
prod_hi[x] = static_cast<uint8_t>(prod >> 8);
}
const LEO_M128 value_lo = _mm_loadu_si128((LEO_M128*)prod_lo);
const LEO_M128 value_hi = _mm_loadu_si128((LEO_M128*)prod_hi);
// Store in 128-bit wide table
_mm_storeu_si128(&Multiply128LUT[log_m].Lo[i], value_lo);
_mm_storeu_si128(&Multiply128LUT[log_m].Hi[i], value_hi);
// Store in 256-bit wide table
#if defined(LEO_TRY_AVX2)
if (CpuHasAVX2)
{
_mm256_storeu_si256(&Multiply256LUT[log_m].Lo[i],
_mm256_broadcastsi128_si256(value_lo));
_mm256_storeu_si256(&Multiply256LUT[log_m].Hi[i],
_mm256_broadcastsi128_si256(value_hi));
}
#endif // LEO_TRY_AVX2
}
}
}
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)
{
#define LEO_MUL_TABLES_256() \
const LEO_M256 T0_lo = _mm256_loadu_si256(&Multiply256LUT[log_m].Lo[0]); \
const LEO_M256 T1_lo = _mm256_loadu_si256(&Multiply256LUT[log_m].Lo[1]); \
const LEO_M256 T2_lo = _mm256_loadu_si256(&Multiply256LUT[log_m].Lo[2]); \
const LEO_M256 T3_lo = _mm256_loadu_si256(&Multiply256LUT[log_m].Lo[3]); \
const LEO_M256 T0_hi = _mm256_loadu_si256(&Multiply256LUT[log_m].Hi[0]); \
const LEO_M256 T1_hi = _mm256_loadu_si256(&Multiply256LUT[log_m].Hi[1]); \
const LEO_M256 T2_hi = _mm256_loadu_si256(&Multiply256LUT[log_m].Hi[2]); \
const LEO_M256 T3_hi = _mm256_loadu_si256(&Multiply256LUT[log_m].Hi[3]);
LEO_MUL_TABLES_256();
const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f);
LEO_M256 * LEO_RESTRICT x32 = reinterpret_cast<LEO_M256 *>(x);
const LEO_M256 * LEO_RESTRICT y32 = reinterpret_cast<const LEO_M256 *>(y);
do
{
#define LEO_MUL_256(x_ptr, y_ptr) { \
const LEO_M256 A_lo = _mm256_loadu_si256(y_ptr); \
const LEO_M256 A_hi = _mm256_loadu_si256(y_ptr + 1); \
LEO_M256 data_0 = _mm256_and_si256(A_lo, clr_mask); \
LEO_M256 data_1 = _mm256_srli_epi64(A_lo, 4); \
data_1 = _mm256_and_si256(data_1, clr_mask); \
LEO_M256 data_2 = _mm256_and_si256(A_hi, clr_mask); \
LEO_M256 data_3 = _mm256_srli_epi64(A_hi, 4); \
data_3 = _mm256_and_si256(data_3, clr_mask); \
LEO_M256 output_lo = _mm256_shuffle_epi8(T0_lo, data_0); \
output_lo = _mm256_xor_si256(output_lo, _mm256_shuffle_epi8(T1_lo, data_1)); \
output_lo = _mm256_xor_si256(output_lo, _mm256_shuffle_epi8(T2_lo, data_2)); \
output_lo = _mm256_xor_si256(output_lo, _mm256_shuffle_epi8(T3_lo, data_3)); \
LEO_M256 output_hi = _mm256_shuffle_epi8(T0_hi, data_0); \
output_hi = _mm256_xor_si256(output_hi, _mm256_shuffle_epi8(T1_hi, data_1)); \
output_hi = _mm256_xor_si256(output_hi, _mm256_shuffle_epi8(T2_hi, data_2)); \
output_hi = _mm256_xor_si256(output_hi, _mm256_shuffle_epi8(T3_hi, data_3)); \
_mm256_storeu_si256(x_ptr, output_lo); \
_mm256_storeu_si256(x_ptr + 1, output_hi); }
LEO_MUL_256(x32, y32);
y32 += 2, x32 += 2;
bytes -= 64;
} while (bytes > 0);
return;
}
#endif // LEO_TRY_AVX2
#define LEO_MUL_TABLES_128() \
const LEO_M128 T0_lo = _mm_loadu_si128(&Multiply128LUT[log_m].Lo[0]); \
const LEO_M128 T1_lo = _mm_loadu_si128(&Multiply128LUT[log_m].Lo[1]); \
const LEO_M128 T2_lo = _mm_loadu_si128(&Multiply128LUT[log_m].Lo[2]); \
const LEO_M128 T3_lo = _mm_loadu_si128(&Multiply128LUT[log_m].Lo[3]); \
const LEO_M128 T0_hi = _mm_loadu_si128(&Multiply128LUT[log_m].Hi[0]); \
const LEO_M128 T1_hi = _mm_loadu_si128(&Multiply128LUT[log_m].Hi[1]); \
const LEO_M128 T2_hi = _mm_loadu_si128(&Multiply128LUT[log_m].Hi[2]); \
const LEO_M128 T3_hi = _mm_loadu_si128(&Multiply128LUT[log_m].Hi[3]);
LEO_MUL_TABLES_128();
const LEO_M128 clr_mask = _mm_set1_epi8(0x0f);
LEO_M128 * LEO_RESTRICT x16 = reinterpret_cast<LEO_M128 *>(x);
const LEO_M128 * LEO_RESTRICT y16 = reinterpret_cast<const LEO_M128 *>(y);
do
{
#define LEO_MUL_128(x_ptr, y_ptr) { \
const LEO_M128 A_lo = _mm_loadu_si128(y_ptr); \
const LEO_M128 A_hi = _mm_loadu_si128(y_ptr + 2); \
LEO_M128 data_0 = _mm_and_si128(A_lo, clr_mask); \
LEO_M128 data_1 = _mm_srli_epi64(A_lo, 4); \
data_1 = _mm_and_si128(data_1, clr_mask); \
LEO_M128 data_2 = _mm_and_si128(A_hi, clr_mask); \
LEO_M128 data_3 = _mm_srli_epi64(A_hi, 4); \
data_3 = _mm_and_si128(data_3, clr_mask); \
LEO_M128 output_lo = _mm_shuffle_epi8(T0_lo, data_0); \
output_lo = _mm_xor_si128(output_lo, _mm_shuffle_epi8(T1_lo, data_1)); \
output_lo = _mm_xor_si128(output_lo, _mm_shuffle_epi8(T2_lo, data_2)); \
output_lo = _mm_xor_si128(output_lo, _mm_shuffle_epi8(T3_lo, data_3)); \
LEO_M128 output_hi = _mm_shuffle_epi8(T0_hi, data_0); \
output_hi = _mm_xor_si128(output_hi, _mm_shuffle_epi8(T1_hi, data_1)); \
output_hi = _mm_xor_si128(output_hi, _mm_shuffle_epi8(T2_hi, data_2)); \
output_hi = _mm_xor_si128(output_hi, _mm_shuffle_epi8(T3_hi, data_3)); \
_mm_storeu_si128(x_ptr, output_lo); \
_mm_storeu_si128(x_ptr + 2, output_hi); }
LEO_MUL_128(x16 + 1, y16 + 1);
LEO_MUL_128(x16, y16);
x16 += 4, y16 += 4;
bytes -= 64;
} while (bytes > 0);
}
//------------------------------------------------------------------------------
// FFT Operations
void fft_butterfly(
void * LEO_RESTRICT x, void * LEO_RESTRICT y,
ffe_t log_m, uint64_t bytes)
{
#if defined(LEO_TRY_AVX2)
if (CpuHasAVX2)
{
LEO_MUL_TABLES_256();
const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f);
LEO_M256 * LEO_RESTRICT x32 = reinterpret_cast<LEO_M256 *>(x);
LEO_M256 * LEO_RESTRICT y32 = reinterpret_cast<LEO_M256 *>(y);
do
{
#define LEO_FFTB_256(x_ptr, y_ptr) { \
LEO_M256 y_lo = _mm256_loadu_si256(y_ptr); \
LEO_M256 data_0 = _mm256_and_si256(y_lo, clr_mask); \
LEO_M256 data_1 = _mm256_srli_epi64(y_lo, 4); \
data_1 = _mm256_and_si256(data_1, clr_mask); \
LEO_M256 prod_lo = _mm256_shuffle_epi8(T0_lo, data_0); \
prod_lo = _mm256_xor_si256(prod_lo, _mm256_shuffle_epi8(T1_lo, data_1)); \
LEO_M256 prod_hi = _mm256_shuffle_epi8(T0_hi, data_0); \
prod_hi = _mm256_xor_si256(prod_hi, _mm256_shuffle_epi8(T1_hi, data_1)); \
LEO_M256 y_hi = _mm256_loadu_si256(y_ptr + 1); \
data_0 = _mm256_and_si256(y_hi, clr_mask); \
data_1 = _mm256_srli_epi64(y_hi, 4); \
data_1 = _mm256_and_si256(data_1, clr_mask); \
prod_lo = _mm256_xor_si256(prod_lo, _mm256_shuffle_epi8(T2_lo, data_0)); \
prod_lo = _mm256_xor_si256(prod_lo, _mm256_shuffle_epi8(T3_lo, data_1)); \
prod_hi = _mm256_xor_si256(prod_hi, _mm256_shuffle_epi8(T2_hi, data_0)); \
prod_hi = _mm256_xor_si256(prod_hi, _mm256_shuffle_epi8(T3_hi, data_1)); \
LEO_M256 x_lo = _mm256_loadu_si256(x_ptr); \
LEO_M256 x_hi = _mm256_loadu_si256(x_ptr + 1); \
x_lo = _mm256_xor_si256(prod_lo, x_lo); \
_mm256_storeu_si256(x_ptr, x_lo); \
x_hi = _mm256_xor_si256(prod_hi, x_hi); \
_mm256_storeu_si256(x_ptr + 1, x_hi); \
y_lo = _mm256_xor_si256(y_lo, x_lo); \
_mm256_storeu_si256(y_ptr, y_lo); \
y_hi = _mm256_xor_si256(y_hi, x_hi); \
_mm256_storeu_si256(y_ptr + 1, y_hi); }
LEO_FFTB_256(x32, y32);
y32 += 2, x32 += 2;
bytes -= 64;
} while (bytes > 0);
return;
}
#endif // LEO_TRY_AVX2
LEO_MUL_TABLES_128();
const LEO_M128 clr_mask = _mm_set1_epi8(0x0f);
LEO_M128 * LEO_RESTRICT x16 = reinterpret_cast<LEO_M128 *>(x);
LEO_M128 * LEO_RESTRICT y16 = reinterpret_cast<LEO_M128 *>(y);
do
{
#define LEO_FFTB_128(x_ptr, y_ptr) { \
LEO_M128 y_lo = _mm_loadu_si128(y_ptr); \
LEO_M128 data_0 = _mm_and_si128(y_lo, clr_mask); \
LEO_M128 data_1 = _mm_srli_epi64(y_lo, 4); \
data_1 = _mm_and_si128(data_1, clr_mask); \
LEO_M128 prod_lo = _mm_shuffle_epi8(T0_lo, data_0); \
prod_lo = _mm_xor_si128(prod_lo, _mm_shuffle_epi8(T1_lo, data_1)); \
LEO_M128 prod_hi = _mm_shuffle_epi8(T0_hi, data_0); \
prod_hi = _mm_xor_si128(prod_hi, _mm_shuffle_epi8(T1_hi, data_1)); \
LEO_M128 y_hi = _mm_loadu_si128(y_ptr + 2); \
data_0 = _mm_and_si128(y_hi, clr_mask); \
data_1 = _mm_srli_epi64(y_hi, 4); \
data_1 = _mm_and_si128(data_1, clr_mask); \
prod_lo = _mm_xor_si128(prod_lo, _mm_shuffle_epi8(T2_lo, data_0)); \
prod_lo = _mm_xor_si128(prod_lo, _mm_shuffle_epi8(T3_lo, data_1)); \
prod_hi = _mm_xor_si128(prod_hi, _mm_shuffle_epi8(T2_hi, data_0)); \
prod_hi = _mm_xor_si128(prod_hi, _mm_shuffle_epi8(T3_hi, data_1)); \
LEO_M128 x_lo = _mm_loadu_si128(x_ptr); \
LEO_M128 x_hi = _mm_loadu_si128(x_ptr + 2); \
x_lo = _mm_xor_si128(prod_lo, x_lo); \
_mm_storeu_si128(x_ptr, x_lo); \
x_hi = _mm_xor_si128(prod_hi, x_hi); \
_mm_storeu_si128(x_ptr + 2, x_hi); \
y_lo = _mm_xor_si128(y_lo, x_lo); \
_mm_storeu_si128(y_ptr, y_lo); \
y_hi = _mm_xor_si128(y_hi, x_hi); \
_mm_storeu_si128(y_ptr + 2, y_hi); }
LEO_FFTB_128(x16 + 1, y16 + 1);
LEO_FFTB_128(x16, y16);
x16 += 4, y16 += 4;
bytes -= 64;
} while (bytes > 0);
}
#ifdef LEO_USE_VECTOR4_OPT
void fft_butterfly4(
void * LEO_RESTRICT x_0, void * LEO_RESTRICT y_0,
void * LEO_RESTRICT x_1, void * LEO_RESTRICT y_1,
void * LEO_RESTRICT x_2, void * LEO_RESTRICT y_2,
void * LEO_RESTRICT x_3, void * LEO_RESTRICT y_3,
ffe_t log_m, uint64_t bytes)
{
#if defined(LEO_TRY_AVX2)
if (CpuHasAVX2)
{
LEO_MUL_TABLES_256();
const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f);
LEO_M256 * LEO_RESTRICT x32_0 = reinterpret_cast<LEO_M256 *>(x_0);
LEO_M256 * LEO_RESTRICT y32_0 = reinterpret_cast<LEO_M256 *>(y_0);
LEO_M256 * LEO_RESTRICT x32_1 = reinterpret_cast<LEO_M256 *>(x_1);
LEO_M256 * LEO_RESTRICT y32_1 = reinterpret_cast<LEO_M256 *>(y_1);
LEO_M256 * LEO_RESTRICT x32_2 = reinterpret_cast<LEO_M256 *>(x_2);
LEO_M256 * LEO_RESTRICT y32_2 = reinterpret_cast<LEO_M256 *>(y_2);
LEO_M256 * LEO_RESTRICT x32_3 = reinterpret_cast<LEO_M256 *>(x_3);
LEO_M256 * LEO_RESTRICT y32_3 = reinterpret_cast<LEO_M256 *>(y_3);
do
{
LEO_FFTB_256(x32_0, y32_0);
y32_0 += 2, x32_0 += 2;
LEO_FFTB_256(x32_1, y32_1);
y32_1 += 2, x32_1 += 2;
LEO_FFTB_256(x32_2, y32_2);
y32_2 += 2, x32_2 += 2;
LEO_FFTB_256(x32_3, y32_3);
y32_3 += 2, x32_3 += 2;
bytes -= 64;
} while (bytes > 0);
return;
}
#endif // LEO_TRY_AVX2
LEO_MUL_TABLES_128();
const LEO_M128 clr_mask = _mm_set1_epi8(0x0f);
LEO_M128 * LEO_RESTRICT x16_0 = reinterpret_cast<LEO_M128 *>(x_0);
LEO_M128 * LEO_RESTRICT y16_0 = reinterpret_cast<LEO_M128 *>(y_0);
LEO_M128 * LEO_RESTRICT x16_1 = reinterpret_cast<LEO_M128 *>(x_1);
LEO_M128 * LEO_RESTRICT y16_1 = reinterpret_cast<LEO_M128 *>(y_1);
LEO_M128 * LEO_RESTRICT x16_2 = reinterpret_cast<LEO_M128 *>(x_2);
LEO_M128 * LEO_RESTRICT y16_2 = reinterpret_cast<LEO_M128 *>(y_2);
LEO_M128 * LEO_RESTRICT x16_3 = reinterpret_cast<LEO_M128 *>(x_3);
LEO_M128 * LEO_RESTRICT y16_3 = reinterpret_cast<LEO_M128 *>(y_3);
do
{
LEO_FFTB_128(x16_0 + 1, y16_0 + 1);
LEO_FFTB_128(x16_0, y16_0);
x16_0 += 4, y16_0 += 4;
LEO_FFTB_128(x16_1 + 1, y16_1 + 1);
LEO_FFTB_128(x16_1, y16_1);
x16_1 += 4, y16_1 += 4;
LEO_FFTB_128(x16_2 + 1, y16_2 + 1);
LEO_FFTB_128(x16_2, y16_2);
x16_2 += 4, y16_2 += 4;
LEO_FFTB_128(x16_3 + 1, y16_3 + 1);
LEO_FFTB_128(x16_3, y16_3);
x16_3 += 4, y16_3 += 4;
bytes -= 64;
} while (bytes > 0);
}
#endif // LEO_USE_VECTOR4_OPT
//------------------------------------------------------------------------------
// IFFT Operations
void ifft_butterfly(
void * LEO_RESTRICT x, void * LEO_RESTRICT y,
ffe_t log_m, uint64_t bytes)
{
#if defined(LEO_TRY_AVX2)
if (CpuHasAVX2)
{
LEO_MUL_TABLES_256();
const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f);
LEO_M256 * LEO_RESTRICT x32 = reinterpret_cast<LEO_M256 *>(x);
LEO_M256 * LEO_RESTRICT y32 = reinterpret_cast<LEO_M256 *>(y);
do
{
#define LEO_IFFTB_256(x_ptr, y_ptr) { \
LEO_M256 x_lo = _mm256_loadu_si256(x_ptr); \
LEO_M256 y_lo = _mm256_loadu_si256(y_ptr); \
y_lo = _mm256_xor_si256(y_lo, x_lo); \
_mm256_storeu_si256(y_ptr, y_lo); \
LEO_M256 data_0 = _mm256_and_si256(y_lo, clr_mask); \
LEO_M256 data_1 = _mm256_srli_epi64(y_lo, 4); \
data_1 = _mm256_and_si256(data_1, clr_mask); \
LEO_M256 prod_lo = _mm256_shuffle_epi8(T0_lo, data_0); \
prod_lo = _mm256_xor_si256(prod_lo, _mm256_shuffle_epi8(T1_lo, data_1)); \
LEO_M256 prod_hi = _mm256_shuffle_epi8(T0_hi, data_0); \
prod_hi = _mm256_xor_si256(prod_hi, _mm256_shuffle_epi8(T1_hi, data_1)); \
LEO_M256 x_hi = _mm256_loadu_si256(x_ptr + 1); \
LEO_M256 y_hi = _mm256_loadu_si256(y_ptr + 1); \
y_hi = _mm256_xor_si256(y_hi, x_hi); \
_mm256_storeu_si256(y_ptr + 1, y_hi); \
data_0 = _mm256_and_si256(y_hi, clr_mask); \
data_1 = _mm256_srli_epi64(y_hi, 4); \
data_1 = _mm256_and_si256(data_1, clr_mask); \
prod_lo = _mm256_xor_si256(prod_lo, _mm256_shuffle_epi8(T2_lo, data_0)); \
prod_lo = _mm256_xor_si256(prod_lo, _mm256_shuffle_epi8(T3_lo, data_1)); \
prod_hi = _mm256_xor_si256(prod_hi, _mm256_shuffle_epi8(T2_hi, data_0)); \
prod_hi = _mm256_xor_si256(prod_hi, _mm256_shuffle_epi8(T3_hi, data_1)); \
x_lo = _mm256_xor_si256(prod_lo, x_lo); \
_mm256_storeu_si256(x_ptr, x_lo); \
x_hi = _mm256_xor_si256(prod_hi, x_hi); \
_mm256_storeu_si256(x_ptr + 1, x_hi); }
LEO_IFFTB_256(x32, y32);
y32 += 2, x32 += 2;
bytes -= 64;
} while (bytes > 0);
return;
}
#endif // LEO_TRY_AVX2
LEO_MUL_TABLES_128();
const LEO_M128 clr_mask = _mm_set1_epi8(0x0f);
LEO_M128 * LEO_RESTRICT x16 = reinterpret_cast<LEO_M128 *>(x);
LEO_M128 * LEO_RESTRICT y16 = reinterpret_cast<LEO_M128 *>(y);
do
{
#define LEO_IFFTB_128(x_ptr, y_ptr) { \
LEO_M128 x_lo = _mm_loadu_si128(x_ptr); \
LEO_M128 y_lo = _mm_loadu_si128(y_ptr); \
y_lo = _mm_xor_si128(y_lo, x_lo); \
_mm_storeu_si128(y_ptr, y_lo); \
LEO_M128 data_0 = _mm_and_si128(y_lo, clr_mask); \
LEO_M128 data_1 = _mm_srli_epi64(y_lo, 4); \
data_1 = _mm_and_si128(data_1, clr_mask); \
LEO_M128 prod_lo = _mm_shuffle_epi8(T0_lo, data_0); \
prod_lo = _mm_xor_si128(prod_lo, _mm_shuffle_epi8(T1_lo, data_1)); \
LEO_M128 prod_hi = _mm_shuffle_epi8(T0_hi, data_0); \
prod_hi = _mm_xor_si128(prod_hi, _mm_shuffle_epi8(T1_hi, data_1)); \
LEO_M128 x_hi = _mm_loadu_si128(x_ptr + 2); \
LEO_M128 y_hi = _mm_loadu_si128(y_ptr + 2); \
y_hi = _mm_xor_si128(y_hi, x_hi); \
_mm_storeu_si128(y_ptr + 2, y_hi); \
data_0 = _mm_and_si128(y_hi, clr_mask); \
data_1 = _mm_srli_epi64(y_hi, 4); \
data_1 = _mm_and_si128(data_1, clr_mask); \
prod_lo = _mm_xor_si128(prod_lo, _mm_shuffle_epi8(T2_lo, data_0)); \
prod_lo = _mm_xor_si128(prod_lo, _mm_shuffle_epi8(T3_lo, data_1)); \
prod_hi = _mm_xor_si128(prod_hi, _mm_shuffle_epi8(T2_hi, data_0)); \
prod_hi = _mm_xor_si128(prod_hi, _mm_shuffle_epi8(T3_hi, data_1)); \
x_lo = _mm_xor_si128(prod_lo, x_lo); \
_mm_storeu_si128(x_ptr, x_lo); \
x_hi = _mm_xor_si128(prod_hi, x_hi); \
_mm_storeu_si128(x_ptr + 2, x_hi); }
LEO_IFFTB_128(x16 + 1, y16 + 1);
LEO_IFFTB_128(x16, y16);
x16 += 4, y16 += 4;
bytes -= 64;
} while (bytes > 0);
}
#ifdef LEO_USE_VECTOR4_OPT
void ifft_butterfly4(
void * LEO_RESTRICT x_0, void * LEO_RESTRICT y_0,
void * LEO_RESTRICT x_1, void * LEO_RESTRICT y_1,
void * LEO_RESTRICT x_2, void * LEO_RESTRICT y_2,
void * LEO_RESTRICT x_3, void * LEO_RESTRICT y_3,
ffe_t log_m, uint64_t bytes)
{
#if defined(LEO_TRY_AVX2)
if (CpuHasAVX2)
{
LEO_MUL_TABLES_256();
const LEO_M256 clr_mask = _mm256_set1_epi8(0x0f);
LEO_M256 * LEO_RESTRICT x32_0 = reinterpret_cast<LEO_M256 *>(x_0);
LEO_M256 * LEO_RESTRICT y32_0 = reinterpret_cast<LEO_M256 *>(y_0);
LEO_M256 * LEO_RESTRICT x32_1 = reinterpret_cast<LEO_M256 *>(x_1);
LEO_M256 * LEO_RESTRICT y32_1 = reinterpret_cast<LEO_M256 *>(y_1);
LEO_M256 * LEO_RESTRICT x32_2 = reinterpret_cast<LEO_M256 *>(x_2);
LEO_M256 * LEO_RESTRICT y32_2 = reinterpret_cast<LEO_M256 *>(y_2);
LEO_M256 * LEO_RESTRICT x32_3 = reinterpret_cast<LEO_M256 *>(x_3);
LEO_M256 * LEO_RESTRICT y32_3 = reinterpret_cast<LEO_M256 *>(y_3);
do
{
LEO_IFFTB_256(x32_0, y32_0);
y32_0 += 2, x32_0 += 2;
LEO_IFFTB_256(x32_1, y32_1);
y32_1 += 2, x32_1 += 2;
LEO_IFFTB_256(x32_2, y32_2);
y32_2 += 2, x32_2 += 2;
LEO_IFFTB_256(x32_3, y32_3);
y32_3 += 2, x32_3 += 2;
bytes -= 64;
} while (bytes > 0);
return;
}
#endif // LEO_TRY_AVX2
LEO_MUL_TABLES_128();
const LEO_M128 clr_mask = _mm_set1_epi8(0x0f);
LEO_M128 * LEO_RESTRICT x16_0 = reinterpret_cast<LEO_M128 *>(x_0);
LEO_M128 * LEO_RESTRICT y16_0 = reinterpret_cast<LEO_M128 *>(y_0);
LEO_M128 * LEO_RESTRICT x16_1 = reinterpret_cast<LEO_M128 *>(x_1);
LEO_M128 * LEO_RESTRICT y16_1 = reinterpret_cast<LEO_M128 *>(y_1);
LEO_M128 * LEO_RESTRICT x16_2 = reinterpret_cast<LEO_M128 *>(x_2);
LEO_M128 * LEO_RESTRICT y16_2 = reinterpret_cast<LEO_M128 *>(y_2);
LEO_M128 * LEO_RESTRICT x16_3 = reinterpret_cast<LEO_M128 *>(x_3);
LEO_M128 * LEO_RESTRICT y16_3 = reinterpret_cast<LEO_M128 *>(y_3);
do
{
LEO_IFFTB_128(x16_0 + 1, y16_0 + 1);
LEO_IFFTB_128(x16_0, y16_0);
x16_0 += 4, y16_0 += 4;
LEO_IFFTB_128(x16_1 + 1, y16_1 + 1);
LEO_IFFTB_128(x16_1, y16_1);
x16_1 += 4, y16_1 += 4;
LEO_IFFTB_128(x16_2 + 1, y16_2 + 1);
LEO_IFFTB_128(x16_2, y16_2);
x16_2 += 4, y16_2 += 4;
LEO_IFFTB_128(x16_3 + 1, y16_3 + 1);
LEO_IFFTB_128(x16_3, y16_3);
x16_3 += 4, y16_3 += 4;
bytes -= 64;
} while (bytes > 0);
}
#endif // LEO_USE_VECTOR4_OPT
//------------------------------------------------------------------------------
// 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<ffe_t>(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 < kOrder; ++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, kBits);
}
void VectorFFTButterfly(
const uint64_t bytes,
unsigned count,
void** x,
void** y,
const ffe_t log_m)
{
if (log_m == kModulus)
{
VectorXOR(bytes, count, y, x);
return;
}
#ifdef LEO_USE_VECTOR4_OPT
while (count >= 4)
{
fft_butterfly4(
x[0], y[0],
x[1], y[1],
x[2], y[2],
x[3], y[3],
log_m, bytes);
x += 4, y += 4;
count -= 4;
}
#endif // LEO_USE_VECTOR4_OPT
for (unsigned i = 0; i < count; ++i)
fft_butterfly(x[i], y[i], log_m, bytes);
}
void VectorIFFTButterfly(
const uint64_t bytes,
unsigned count,
void** x,
void** y,
const ffe_t log_m)
{
if (log_m == kModulus)
{
VectorXOR(bytes, count, y, x);
return;
}
#ifdef LEO_USE_VECTOR4_OPT
while (count >= 4)
{
ifft_butterfly4(
x[0], y[0],
x[1], y[1],
x[2], y[2],
x[3], y[3],
log_m, bytes);
x += 4, y += 4;
count -= 4;
}
#endif // LEO_USE_VECTOR4_OPT
for (unsigned i = 0; i < count; ++i)
ifft_butterfly(x[i], y[i], log_m, bytes);
}
//------------------------------------------------------------------------------
// Reed-Solomon Encode
void ReedSolomonEncode(
uint64_t buffer_bytes,
unsigned original_count,
unsigned recovery_count,
unsigned m,
void* const * data,
void** work)
{
// work <- data
// TBD: Unroll first loop to eliminate this
unsigned first_end = m;
if (original_count < m)
{
first_end = original_count;
for (unsigned i = original_count; i < m; ++i)
memset(work[i], 0, buffer_bytes);
}
for (unsigned i = 0; i < first_end; ++i)
memcpy(work[i], data[i], buffer_bytes);
// work <- IFFT(data, m, m)
for (unsigned width = 1; width < m; width <<= 1)
{
const unsigned range = width << 1;
const ffe_t* skewLUT = FFTSkew + width + m - 1;
#ifdef LEO_SCHEDULE_OPT
for (unsigned j = 0; j < first_end; j += range)
#else
for (unsigned j = 0; j < m; j += range)
#endif
{
VectorIFFTButterfly(
buffer_bytes,
width,
work + j,
work + j + width,
skewLUT[j]);
}
}
if (m >= original_count)
goto skip_body;
for (unsigned i = m; i + m <= original_count; i += m)
{
// temp <- data + i
data += m;
void** temp = work + m;
// TBD: Unroll first loop to eliminate this
for (unsigned j = 0; j < m; ++j)
memcpy(temp[j], data[j], buffer_bytes);
// temp <- IFFT(temp, m, m + i)
const ffe_t* skewLUT = FFTSkew + m + i - 1;
for (unsigned width = 1; width < m; width <<= 1)
{
const unsigned range = width << 1;
for (unsigned j = width; j < m; j += range)
{
VectorIFFTButterfly(
buffer_bytes,
width,
temp + j - width,
temp + j,
skewLUT[j]);
}
}
// work <- work XOR temp
// TBD: Unroll last loop to eliminate this
VectorXOR(
buffer_bytes,
m,
work,
temp);
}
const unsigned last_count = original_count % m;
if (last_count != 0)
{
const unsigned i = original_count - last_count;
// temp <- data + i
data += m;
void** temp = work + m;
for (unsigned j = 0; j < last_count; ++j)
memcpy(temp[j], data[j], buffer_bytes);
for (unsigned j = last_count; j < m; ++j)
memset(temp[j], 0, buffer_bytes);
// temp <- IFFT(temp, m, m + i)
for (unsigned width = 1, shift = 1; width < m; width <<= 1, ++shift)
{
const unsigned range = width << 1;
const ffe_t* skewLUT = FFTSkew + width + m + i - 1;
#ifdef LEO_SCHEDULE_OPT
// Calculate stop considering that the right is all zeroes
const unsigned stop = ((last_count + range - 1) >> shift) << shift;
for (unsigned j = 0; j < stop; j += range)
#else
for (unsigned j = 0; j < m; j += range)
#endif
{
VectorIFFTButterfly(
buffer_bytes,
width,
temp + j,
temp + j + width,
skewLUT[j]);
}
}
// work <- work XOR temp
// TBD: Unroll last loop to eliminate this
VectorXOR(
buffer_bytes,
m,
work,
temp);
}
skip_body:
// work <- FFT(work, m, 0)
for (unsigned width = (m >> 1); width > 0; width >>= 1)
{
const ffe_t* skewLUT = FFTSkew + width - 1;
const unsigned range = width << 1;
#ifdef LEO_SCHEDULE_OPT
for (unsigned j = 0; j < recovery_count; j += range)
#else
for (unsigned j = 0; j < m; j += range)
#endif
{
VectorFFTButterfly(
buffer_bytes,
width,
work + j,
work + j + width,
skewLUT[j]);
}
}
}
//------------------------------------------------------------------------------
// ErrorBitfield
#ifdef LEO_ERROR_BITFIELD_OPT
// Used in decoding to decide which final FFT operations to perform
class ErrorBitfield
{
static const unsigned kWordMips = 5;
static const unsigned kWords = kOrder / 64;
uint64_t Words[kWordMips][kWords] = {};
static const unsigned kBigMips = 6;
static const unsigned kBigWords = (kWords + 63) / 64;
uint64_t BigWords[kBigMips][kBigWords] = {};
static const unsigned kBiggestMips = 4;
uint64_t BiggestWords[kBiggestMips] = {};
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 >= 16)
return true;
if (mip_level >= 12)
{
bit /= 4096;
return 0 != (BiggestWords[mip_level - 12] & ((uint64_t)1 << bit));
}
if (mip_level >= 6)
{
bit /= 64;
return 0 != (BigWords[mip_level - 6][bit / 64] & ((uint64_t)1 << (bit % 64)));
}
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 < kWordMips; ++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 < kBigWords; ++i)
{
uint64_t w_i = 0;
uint64_t bit = 1;
const uint64_t* src = &Words[kWordMips - 1][i * 64];
for (unsigned j = 0; j < 64; ++j, bit <<= 1)
{
const uint64_t w = src[j];
w_i |= (w | (w >> 32) | (w << 32)) & bit;
}
BigWords[0][i] = w_i;
for (unsigned j = 1, bits = 1; j < kBigMips; ++j, bits <<= 1)
{
const uint64_t hi2lo_j = w_i | ((w_i & kHiMasks[j - 1]) >> bits);
const uint64_t lo2hi_j = ((w_i & (kHiMasks[j - 1] >> bits)) << bits);
BigWords[j][i] = w_i = hi2lo_j | lo2hi_j;
}
}
uint64_t w_i = 0;
uint64_t bit = 1;
const uint64_t* src = &BigWords[kBigMips - 1][0];
for (unsigned j = 0; j < kBigWords; ++j, bit <<= 1)
{
const uint64_t w = src[j];
w_i |= (w | (w >> 32) | (w << 32)) & bit;
}
BiggestWords[0] = w_i;
for (unsigned j = 1, bits = 1; j < kBiggestMips; ++j, bits <<= 1)
{
const uint64_t hi2lo_j = w_i | ((w_i & kHiMasks[j - 1]) >> bits);
const uint64_t lo2hi_j = ((w_i & (kHiMasks[j - 1] >> bits)) << bits);
BiggestWords[j] = w_i = hi2lo_j | lo2hi_j;
}
}
#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
void* const * const original, // original_count entries
void* const * const recovery, // recovery_count entries
void** work) // n entries
{
// Fill in error locations
#ifdef LEO_ERROR_BITFIELD_OPT
ErrorBitfield ErrorBits;
#endif // LEO_ERROR_BITFIELD_OPT
ffe_t ErrorLocations[kOrder] = {};
for (unsigned i = 0; i < recovery_count; ++i)
if (!recovery[i])
ErrorLocations[i] = 1;
for (unsigned i = recovery_count; i < m; ++i)
ErrorLocations[i] = 1;
for (unsigned i = 0; i < original_count; ++i)
{
if (!original[i])
{
ErrorLocations[i + m] = 1;
#ifdef LEO_ERROR_BITFIELD_OPT
ErrorBits.Set(i + m);
#endif // LEO_ERROR_BITFIELD_OPT
}
}
#ifdef LEO_ERROR_BITFIELD_OPT
ErrorBits.Prepare();
#endif // LEO_ERROR_BITFIELD_OPT
// Evaluate error locator polynomial
FWHT(ErrorLocations);
for (unsigned i = 0; i < kOrder; ++i)
ErrorLocations[i] = ((unsigned)ErrorLocations[i] * (unsigned)LogWalsh[i]) % kModulus;
FWHT(ErrorLocations);
// work <- recovery data
for (unsigned i = 0; i < recovery_count; ++i)
{
if (recovery[i])
mul_mem(work[i], recovery[i], ErrorLocations[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], ErrorLocations[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)
const unsigned input_count = m + original_count;
unsigned mip_level = 0;
for (unsigned width = 1; width < n; width <<= 1, ++mip_level)
{
const unsigned range = width << 1;
for (unsigned j = width; j < n; j += range)
{
VectorIFFTButterfly(
buffer_bytes,
width,
work + j - width,
work + j,
FFTSkew[j - 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;
for (unsigned width = (n >> 1); width > 0; width >>= 1, --mip_level)
{
const ffe_t* skewLUT = FFTSkew + width - 1;
const unsigned range = width << 1;
#ifdef LEO_SCHEDULE_OPT
for (unsigned j = (m < range) ? 0 : m; j < output_count; j += range)
#else
for (unsigned j = 0; j < n; j += range)
#endif
{
#ifdef LEO_ERROR_BITFIELD_OPT
if (!ErrorBits.IsNeeded(mip_level, j))
continue;
#endif // LEO_ERROR_BITFIELD_OPT
VectorFFTButterfly(
buffer_bytes,
width,
work + j,
work + j + width,
skewLUT[j]);
}
}
// Reveal erasures
for (unsigned i = 0; i < original_count; ++i)
if (!original[i])
mul_mem(work[i], work[i + m], kModulus - ErrorLocations[i + m], buffer_bytes);
}
//------------------------------------------------------------------------------
// API
static bool IsInitialized = false;
bool Initialize()
{
if (IsInitialized)
return true;
if (!CpuHasSSSE3)
return false;
InitializeLogarithmTables();
InitializeMultiplyTables();
FFTInitialize();
IsInitialized = true;
return true;
}
}} // namespace leopard::ff16
#endif // LEO_HAS_FF16