-/******************************************************************************\r
-*\r
-* Copyright (c) 2019 Intel.\r
-*\r
-* Licensed under the Apache License, Version 2.0 (the "License");\r
-* you may not use this file except in compliance with the License.\r
-* You may obtain a copy of the License at\r
-*\r
-* http://www.apache.org/licenses/LICENSE-2.0\r
-*\r
-* Unless required by applicable law or agreed to in writing, software\r
-* distributed under the License is distributed on an "AS IS" BASIS,\r
-* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.\r
-* See the License for the specific language governing permissions and\r
-* limitations under the License.\r
-*\r
-*******************************************************************************/\r
-\r
-#include "xran_compression.hpp"\r
-#include "xran_compression.h"\r
-#include <complex>\r
-#include <algorithm>\r
-#include <immintrin.h>\r
-#include <limits.h>\r
-#include <cstring>\r
-\r
-static int16_t saturateAbs(int16_t inVal)\r
-{\r
- int16_t result;\r
- if (inVal == std::numeric_limits<short>::min())\r
- {\r
- result = std::numeric_limits<short>::max();\r
- }\r
- else\r
- {\r
- result = (int16_t)std::abs(inVal);\r
- }\r
- return result;\r
-}\r
-\r
-\r
-/// Compute exponent value for a set of RB from the maximum absolute value\r
-void\r
-computeExponent(const BlockFloatCompander::ExpandedData& dataIn, int8_t* expStore)\r
-{\r
- __m512i maxAbs = __m512i();\r
-\r
- /// Load data and find max(abs(RB))\r
- const __m512i* rawData = reinterpret_cast<const __m512i*>(dataIn.dataExpanded);\r
- constexpr int k_numRBPerLoop = 4;\r
- constexpr int k_numInputLoopIts = BlockFloatCompander::k_numRB / k_numRBPerLoop;\r
-\r
-#pragma unroll(k_numInputLoopIts)\r
- for (int n = 0; n < k_numInputLoopIts; ++n)\r
- {\r
- /// Re-order the next 4RB in input data into 3 registers\r
- /// Input SIMD vectors are:\r
- /// [A A A A A A A A A A A A B B B B]\r
- /// [B B B B B B B B C C C C C C C C]\r
- /// [C C C C D D D D D D D D D D D D]\r
- /// Re-ordered SIMD vectors are:\r
- /// [A A A A B B B B C C C C D D D D]\r
- /// [A A A A B B B B C C C C D D D D]\r
- /// [A A A A B B B B C C C C D D D D]\r
- constexpr uint8_t k_msk1 = 0b11111100; // Copy first lane of src\r
- constexpr int k_shuff1 = 0x41;\r
- const auto z_w1 = _mm512_mask_shuffle_i64x2(rawData[3 * n + 0], k_msk1, rawData[3 * n + 1], rawData[3 * n + 2], k_shuff1);\r
-\r
- constexpr uint8_t k_msk2 = 0b11000011; // Copy middle two lanes of src\r
- constexpr int k_shuff2 = 0xB1;\r
- const auto z_w2 = _mm512_mask_shuffle_i64x2(rawData[3 * n + 1], k_msk2, rawData[3 * n + 0], rawData[3 * n + 2], k_shuff2);\r
-\r
- constexpr uint8_t k_msk3 = 0b00111111; // Copy last lane of src\r
- constexpr int k_shuff3 = 0xBE;\r
- const auto z_w3 = _mm512_mask_shuffle_i64x2(rawData[3 * n + 2], k_msk3, rawData[3 * n + 0], rawData[3 * n + 1], k_shuff3);\r
-\r
- /// Perform max abs on these 3 registers\r
- const auto abs16_1 = _mm512_abs_epi16(z_w1);\r
- const auto abs16_2 = _mm512_abs_epi16(z_w2);\r
- const auto abs16_3 = _mm512_abs_epi16(z_w3);\r
- const auto maxAbs_12 = _mm512_max_epi16(abs16_1, abs16_2);\r
- const auto maxAbs_123 = _mm512_max_epi16(maxAbs_12, abs16_3);\r
-\r
- /// Perform horizontal max over each lane\r
- /// Swap 64b in each lane and compute max\r
- const auto k_perm64b = _mm512_set_epi64(6, 7, 4, 5, 2, 3, 0, 1);\r
- auto maxAbsPerm = _mm512_permutexvar_epi64(k_perm64b, maxAbs_123);\r
- auto maxAbsHorz = _mm512_max_epi16(maxAbs_123, maxAbsPerm);\r
-\r
- /// Swap each pair of 32b in each lane and compute max\r
- const auto k_perm32b = _mm512_set_epi32(14, 15, 12, 13, 10, 11, 8, 9, 6, 7, 4, 5, 2, 3, 0, 1);\r
- maxAbsPerm = _mm512_permutexvar_epi32(k_perm32b, maxAbsHorz);\r
- maxAbsHorz = _mm512_max_epi16(maxAbsHorz, maxAbsPerm);\r
-\r
- /// Swap each IQ pair in each lane (via 32b rotation) and compute max\r
- maxAbsPerm = _mm512_rol_epi32(maxAbsHorz, BlockFloatCompander::k_numBitsIQ);\r
- maxAbsHorz = _mm512_max_epi16(maxAbsHorz, maxAbsPerm);\r
-\r
- /// Insert values into maxAbs\r
- /// Use sliding mask to insert wanted values into maxAbs\r
- /// Pairs of values will be inserted and corrected outside of loop\r
- const auto k_select4RB = _mm512_set_epi32(28, 24, 20, 16, 28, 24, 20, 16,\r
- 28, 24, 20, 16, 28, 24, 20, 16);\r
- constexpr uint16_t k_expMsk[k_numInputLoopIts] = { 0x000F, 0x00F0, 0x0F00, 0xF000 };\r
- maxAbs = _mm512_mask_permutex2var_epi32(maxAbs, k_expMsk[n], k_select4RB, maxAbsHorz);\r
- }\r
-\r
- /// Convert to 32b by removing repeated values in maxAbs\r
- const auto k_upperWordMask = _mm512_set_epi64(0x0000FFFF0000FFFF, 0x0000FFFF0000FFFF,\r
- 0x0000FFFF0000FFFF, 0x0000FFFF0000FFFF,\r
- 0x0000FFFF0000FFFF, 0x0000FFFF0000FFFF,\r
- 0x0000FFFF0000FFFF, 0x0000FFFF0000FFFF);\r
- maxAbs = _mm512_and_epi64(maxAbs, k_upperWordMask);\r
-\r
- /// Compute and store exponent\r
- const auto totShiftBits = _mm512_set1_epi32(32 - dataIn.iqWidth + 1);\r
- const auto lzCount = _mm512_lzcnt_epi32(maxAbs);\r
- const auto exponent = _mm512_sub_epi32(totShiftBits, lzCount);\r
- constexpr uint16_t k_expWriteMask = 0xFFFF;\r
- _mm512_mask_cvtepi32_storeu_epi8(expStore, k_expWriteMask, exponent);\r
-}\r
-\r
-\r
-/// Pack compressed 9 bit data in network byte order\r
-/// See https://soco.intel.com/docs/DOC-2665619\r
-__m512i\r
-networkBytePack9b(const __m512i compData)\r
-{\r
- /// Logical shift left to align network order byte parts\r
- const __m512i k_shiftLeft = _mm512_set_epi64(0x0000000100020003, 0x0004000500060007,\r
- 0x0000000100020003, 0x0004000500060007,\r
- 0x0000000100020003, 0x0004000500060007,\r
- 0x0000000100020003, 0x0004000500060007);\r
- auto compDataPacked = _mm512_sllv_epi16(compData, k_shiftLeft);\r
-\r
- /// First epi8 shuffle of even indexed samples\r
- const __m512i k_byteShuffleMask1 = _mm512_set_epi64(0x0000000000000000, 0x0C0D080904050001,\r
- 0x0000000000000000, 0x0C0D080904050001,\r
- 0x0000000000000000, 0x0C0D080904050001,\r
- 0x0000000000000000, 0x0C0D080904050001);\r
- constexpr uint64_t k_byteMask1 = 0x000000FF00FF00FF;\r
- auto compDataShuff1 = _mm512_maskz_shuffle_epi8(k_byteMask1, compDataPacked, k_byteShuffleMask1);\r
-\r
- /// Second epi8 shuffle of odd indexed samples\r
- const __m512i k_byteShuffleMask2 = _mm512_set_epi64(0x000000000000000E, 0x0F0A0B0607020300,\r
- 0x000000000000000E, 0x0F0A0B0607020300,\r
- 0x000000000000000E, 0x0F0A0B0607020300,\r
- 0x000000000000000E, 0x0F0A0B0607020300);\r
- constexpr uint64_t k_byteMask2 = 0x000001FE01FE01FE;\r
- auto compDataShuff2 = _mm512_maskz_shuffle_epi8(k_byteMask2, compDataPacked, k_byteShuffleMask2);\r
-\r
- /// Ternary blend of the two shuffled results\r
- const __m512i k_ternLogSelect = _mm512_set_epi64(0x00000000000000FF, 0x01FC07F01FC07F00,\r
- 0x00000000000000FF, 0x01FC07F01FC07F00,\r
- 0x00000000000000FF, 0x01FC07F01FC07F00,\r
- 0x00000000000000FF, 0x01FC07F01FC07F00);\r
- return _mm512_ternarylogic_epi64(compDataShuff1, compDataShuff2, k_ternLogSelect, 0xd8);\r
-}\r
-\r
-\r
-/// Pack compressed 10 bit data in network byte order\r
-/// See https://soco.intel.com/docs/DOC-2665619\r
-__m512i\r
-networkBytePack10b(const __m512i compData)\r
-{\r
- /// Logical shift left to align network order byte parts\r
- const __m512i k_shiftLeft = _mm512_set_epi64(0x0000000200040006, 0x0000000200040006,\r
- 0x0000000200040006, 0x0000000200040006,\r
- 0x0000000200040006, 0x0000000200040006,\r
- 0x0000000200040006, 0x0000000200040006);\r
- auto compDataPacked = _mm512_sllv_epi16(compData, k_shiftLeft);\r
-\r
- /// First epi8 shuffle of even indexed samples\r
- const __m512i k_byteShuffleMask1 = _mm512_set_epi64(0x000000000000000C, 0x0D08090004050001,\r
- 0x000000000000000C, 0x0D08090004050001,\r
- 0x000000000000000C, 0x0D08090004050001,\r
- 0x000000000000000C, 0x0D08090004050001);\r
- constexpr uint64_t k_byteMask1 = 0x000001EF01EF01EF;\r
- auto compDataShuff1 = _mm512_maskz_shuffle_epi8(k_byteMask1, compDataPacked, k_byteShuffleMask1);\r
-\r
- /// Second epi8 shuffle of odd indexed samples\r
- const __m512i k_byteShuffleMask2 = _mm512_set_epi64(0x0000000000000E0F, 0x0A0B000607020300,\r
- 0x0000000000000E0F, 0x0A0B000607020300,\r
- 0x0000000000000E0F, 0x0A0B000607020300,\r
- 0x0000000000000E0F, 0x0A0B000607020300);\r
- constexpr uint64_t k_byteMask2 = 0x000003DE03DE03DE;\r
- auto compDataShuff2 = _mm512_maskz_shuffle_epi8(k_byteMask2, compDataPacked, k_byteShuffleMask2);\r
-\r
- /// Ternary blend of the two shuffled results\r
- const __m512i k_ternLogSelect = _mm512_set_epi64(0x000000000000FF03, 0xF03F00FF03F03F00,\r
- 0x000000000000FF03, 0xF03F00FF03F03F00,\r
- 0x000000000000FF03, 0xF03F00FF03F03F00,\r
- 0x000000000000FF03, 0xF03F00FF03F03F00);\r
- return _mm512_ternarylogic_epi64(compDataShuff1, compDataShuff2, k_ternLogSelect, 0xd8);\r
-}\r
-\r
-\r
-/// Pack compressed 12 bit data in network byte order\r
-/// See https://soco.intel.com/docs/DOC-2665619\r
-__m512i\r
-networkBytePack12b(const __m512i compData)\r
-{\r
- /// Logical shift left to align network order byte parts\r
- const __m512i k_shiftLeft = _mm512_set_epi64(0x0000000400000004, 0x0000000400000004,\r
- 0x0000000400000004, 0x0000000400000004,\r
- 0x0000000400000004, 0x0000000400000004,\r
- 0x0000000400000004, 0x0000000400000004);\r
- auto compDataPacked = _mm512_sllv_epi16(compData, k_shiftLeft);\r
-\r
- /// First epi8 shuffle of even indexed samples\r
- const __m512i k_byteShuffleMask1 = _mm512_set_epi64(0x00000000000C0D00, 0x0809000405000001,\r
- 0x00000000000C0D00, 0x0809000405000001,\r
- 0x00000000000C0D00, 0x0809000405000001,\r
- 0x00000000000C0D00, 0x0809000405000001);\r
- constexpr uint64_t k_byteMask1 = 0x000006DB06DB06DB;\r
- auto compDataShuff1 = _mm512_maskz_shuffle_epi8(k_byteMask1, compDataPacked, k_byteShuffleMask1);\r
-\r
- /// Second epi8 shuffle of odd indexed samples\r
- const __m512i k_byteShuffleMask2 = _mm512_set_epi64(0x000000000E0F000A, 0x0B00060700020300,\r
- 0x000000000E0F000A, 0x0B00060700020300,\r
- 0x000000000E0F000A, 0x0B00060700020300,\r
- 0x000000000E0F000A, 0x0B00060700020300);\r
- constexpr uint64_t k_byteMask2 = 0x00000DB60DB60DB6;\r
- auto compDataShuff2 = _mm512_maskz_shuffle_epi8(k_byteMask2, compDataPacked, k_byteShuffleMask2);\r
-\r
- /// Ternary blend of the two shuffled results\r
- const __m512i k_ternLogSelect = _mm512_set_epi64(0x00000000FF0F00FF, 0x0F00FF0F00FF0F00,\r
- 0x00000000FF0F00FF, 0x0F00FF0F00FF0F00,\r
- 0x00000000FF0F00FF, 0x0F00FF0F00FF0F00,\r
- 0x00000000FF0F00FF, 0x0F00FF0F00FF0F00);\r
- return _mm512_ternarylogic_epi64(compDataShuff1, compDataShuff2, k_ternLogSelect, 0xd8);\r
-}\r
-\r
-\r
-/// Unpack compressed 9 bit data in network byte order\r
-/// See https://soco.intel.com/docs/DOC-2665619\r
-__m512i\r
-networkByteUnpack9b(const uint8_t* inData)\r
-{\r
- /// Align chunks of compressed bytes into lanes to allow for expansion\r
- const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(inData);\r
- const auto k_expPerm = _mm512_set_epi32(15, 14, 13, 12, 7, 6, 5, 4,\r
- 5, 4, 3, 2, 3, 2, 1, 0);\r
- auto expData = _mm512_permutexvar_epi32(k_expPerm, *rawDataIn);\r
-\r
- /// Byte shuffle to get all bits for each sample into 16b chunks\r
- /// Due to previous permute to get chunks of bytes into each lane, there is\r
- /// a different shuffle offset in each lane\r
- const __m512i k_byteShuffleMask = _mm512_set_epi64(0x0F0E0D0C0B0A0908, 0x0706050403020100,\r
- 0x090A080907080607, 0x0506040503040203,\r
- 0x0809070806070506, 0x0405030402030102,\r
- 0x0708060705060405, 0x0304020301020001);\r
- expData = _mm512_shuffle_epi8(expData, k_byteShuffleMask);\r
-\r
- /// Logical shift left to set sign bit\r
- const __m512i k_slBits = _mm512_set_epi64(0x0007000600050004, 0x0003000200010000,\r
- 0x0007000600050004, 0x0003000200010000,\r
- 0x0007000600050004, 0x0003000200010000,\r
- 0x0007000600050004, 0x0003000200010000);\r
- expData = _mm512_sllv_epi16(expData, k_slBits);\r
-\r
- /// Mask to zero unwanted bits\r
- const __m512i k_expMask = _mm512_set1_epi16(0xFF80);\r
- return _mm512_and_epi64(expData, k_expMask);\r
-}\r
-\r
-\r
-/// Unpack compressed 10 bit data in network byte order\r
-/// See https://soco.intel.com/docs/DOC-2665619\r
-__m512i\r
-networkByteUnpack10b(const uint8_t* inData)\r
-{\r
- /// Align chunks of compressed bytes into lanes to allow for expansion\r
- const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(inData);\r
- const auto k_expPerm = _mm512_set_epi32(15, 14, 13, 12, 8, 7, 6, 5,\r
- 5, 4, 3, 2, 3, 2, 1, 0);\r
- auto expData = _mm512_permutexvar_epi32(k_expPerm, *rawDataIn);\r
-\r
- /// Byte shuffle to get all bits for each sample into 16b chunks\r
- /// Due to previous permute to get chunks of bytes into each lane, lanes\r
- /// 0 and 2 happen to be aligned, but lane 1 is offset by 2 bytes\r
- const __m512i k_byteShuffleMask = _mm512_set_epi64(0x0809070806070506, 0x0304020301020001,\r
- 0x0809070806070506, 0x0304020301020001,\r
- 0x0A0B090A08090708, 0x0506040503040203,\r
- 0x0809070806070506, 0x0304020301020001);\r
- expData = _mm512_shuffle_epi8(expData, k_byteShuffleMask);\r
-\r
- /// Logical shift left to set sign bit\r
- const __m512i k_slBits = _mm512_set_epi64(0x0006000400020000, 0x0006000400020000,\r
- 0x0006000400020000, 0x0006000400020000,\r
- 0x0006000400020000, 0x0006000400020000,\r
- 0x0006000400020000, 0x0006000400020000);\r
- expData = _mm512_sllv_epi16(expData, k_slBits);\r
-\r
- /// Mask to zero unwanted bits\r
- const __m512i k_expMask = _mm512_set1_epi16(0xFFC0);\r
- return _mm512_and_epi64(expData, k_expMask);\r
-}\r
-\r
-\r
-/// Unpack compressed 12 bit data in network byte order\r
-/// See https://soco.intel.com/docs/DOC-2665619\r
-__m512i\r
-networkByteUnpack12b(const uint8_t* inData)\r
-{\r
- /// Align chunks of compressed bytes into lanes to allow for expansion\r
- const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(inData);\r
- const auto k_expPerm = _mm512_set_epi32(15, 14, 13, 12, 9, 8, 7, 6,\r
- 6, 5, 4, 3, 3, 2, 1, 0);\r
- auto expData = _mm512_permutexvar_epi32(k_expPerm, *rawDataIn);\r
-\r
- /// Byte shuffle to get all bits for each sample into 16b chunks\r
- /// For 12b mantissa all lanes post-permute are aligned and require same shuffle offset\r
- const __m512i k_byteShuffleMask = _mm512_set_epi64(0x0A0B090A07080607, 0x0405030401020001,\r
- 0x0A0B090A07080607, 0x0405030401020001,\r
- 0x0A0B090A07080607, 0x0405030401020001,\r
- 0x0A0B090A07080607, 0x0405030401020001);\r
- expData = _mm512_shuffle_epi8(expData, k_byteShuffleMask);\r
-\r
- /// Logical shift left to set sign bit\r
- const __m512i k_slBits = _mm512_set_epi64(0x0004000000040000, 0x0004000000040000,\r
- 0x0004000000040000, 0x0004000000040000,\r
- 0x0004000000040000, 0x0004000000040000,\r
- 0x0004000000040000, 0x0004000000040000);\r
- expData = _mm512_sllv_epi16(expData, k_slBits);\r
-\r
- /// Mask to zero unwanted bits\r
- const __m512i k_expMask = _mm512_set1_epi16(0xFFF0);\r
- return _mm512_and_epi64(expData, k_expMask);\r
-}\r
-\r
-\r
-/// 8 bit compression\r
-void\r
-BlockFloatCompander::BlockFloatCompress_8b_AVX512(const ExpandedData& dataIn, CompressedData* dataOut)\r
-{\r
- /// Compute exponent and store for later use\r
- int8_t storedExp[BlockFloatCompander::k_numRB] = {};\r
- computeExponent(dataIn, storedExp);\r
-\r
- /// Shift 1RB by corresponding exponent and write exponent and data to output\r
-#pragma unroll(BlockFloatCompander::k_numRB)\r
- for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)\r
- {\r
- const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(dataIn.dataExpanded + n * BlockFloatCompander::k_numREReal);\r
- auto compData = _mm512_srai_epi16(*rawDataIn, storedExp[n]);\r
- auto thisRBExpAddr = n * (BlockFloatCompander::k_numREReal + 1);\r
- /// Store exponent first\r
- dataOut->dataCompressed[thisRBExpAddr] = storedExp[n];\r
- /// Store compressed RB\r
- constexpr uint32_t k_rbMask = 0x00FFFFFF; // Write mask for 1RB (24 values)\r
- _mm256_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1, k_rbMask, _mm512_cvtepi16_epi8(compData));\r
- }\r
-}\r
-\r
-\r
-/// 9 bit compression\r
-void\r
-BlockFloatCompander::BlockFloatCompress_9b_AVX512(const ExpandedData& dataIn, CompressedData* dataOut)\r
-{\r
- /// Compute exponent and store for later use\r
- int8_t storedExp[BlockFloatCompander::k_numRB] = {};\r
- computeExponent(dataIn, storedExp);\r
-\r
- /// Shift 1RB by corresponding exponent and write exponent and data to output\r
- /// Output data is packed exponent first followed by corresponding compressed RB\r
-#pragma unroll(BlockFloatCompander::k_numRB)\r
- for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)\r
- {\r
- /// Apply exponent shift\r
- const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(dataIn.dataExpanded + n * BlockFloatCompander::k_numREReal);\r
- auto compData = _mm512_srai_epi16(*rawDataIn, storedExp[n]);\r
-\r
- /// Pack compressed data network byte order\r
- auto compDataBytePacked = networkBytePack9b(compData);\r
-\r
- /// Store exponent first\r
- constexpr int k_totNumBytesPerRB = 28;\r
- auto thisRBExpAddr = n * k_totNumBytesPerRB;\r
- dataOut->dataCompressed[thisRBExpAddr] = storedExp[n];\r
-\r
- /// Now have 1 RB worth of bytes separated into 3 chunks (1 per lane)\r
- /// Use three offset stores to join\r
- constexpr uint16_t k_RbWriteMask = 0x01FF;\r
- constexpr int k_numDataBytesPerLane = 9;\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 0));\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + k_numDataBytesPerLane, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 1));\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + (2 * k_numDataBytesPerLane), k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 2));\r
- }\r
-}\r
-\r
-\r
-/// 10 bit compression\r
-void\r
-BlockFloatCompander::BlockFloatCompress_10b_AVX512(const ExpandedData& dataIn, CompressedData* dataOut)\r
-{\r
- /// Compute exponent and store for later use\r
- int8_t storedExp[BlockFloatCompander::k_numRB] = {};\r
- computeExponent(dataIn, storedExp);\r
-\r
- /// Shift 1RB by corresponding exponent and write exponent and data to output\r
- /// Output data is packed exponent first followed by corresponding compressed RB\r
-#pragma unroll(BlockFloatCompander::k_numRB)\r
- for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)\r
- {\r
- /// Apply exponent shift\r
- const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(dataIn.dataExpanded + n * BlockFloatCompander::k_numREReal);\r
- auto compData = _mm512_srai_epi16(*rawDataIn, storedExp[n]);\r
-\r
- /// Pack compressed data network byte order\r
- auto compDataBytePacked = networkBytePack10b(compData);\r
-\r
- /// Store exponent first\r
- constexpr int k_totNumBytesPerRB = 31;\r
- auto thisRBExpAddr = n * k_totNumBytesPerRB;\r
- dataOut->dataCompressed[thisRBExpAddr] = storedExp[n];\r
-\r
- /// Now have 1 RB worth of bytes separated into 3 chunks (1 per lane)\r
- /// Use three offset stores to join\r
- constexpr uint16_t k_RbWriteMask = 0x03FF;\r
- constexpr int k_numDataBytesPerLane = 10;\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 0));\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + k_numDataBytesPerLane, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 1));\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + (2 * k_numDataBytesPerLane), k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 2));\r
- }\r
-}\r
-\r
-\r
-/// 12 bit compression\r
-void\r
-BlockFloatCompander::BlockFloatCompress_12b_AVX512(const ExpandedData& dataIn, CompressedData* dataOut)\r
-{\r
- /// Compute exponent and store for later use\r
- int8_t storedExp[BlockFloatCompander::k_numRB] = {};\r
- computeExponent(dataIn, storedExp);\r
-\r
- /// Shift 1RB by corresponding exponent and write exponent and data to output\r
- /// Output data is packed exponent first followed by corresponding compressed RB\r
-#pragma unroll(BlockFloatCompander::k_numRB)\r
- for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)\r
- {\r
- /// Apply exponent shift\r
- const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(dataIn.dataExpanded + n * BlockFloatCompander::k_numREReal);\r
- auto compData = _mm512_srai_epi16(*rawDataIn, storedExp[n]);\r
-\r
- /// Pack compressed data network byte order\r
- auto compDataBytePacked = networkBytePack12b(compData);\r
-\r
- /// Store exponent first\r
- constexpr int k_totNumBytesPerRB = 37;\r
- auto thisRBExpAddr = n * k_totNumBytesPerRB;\r
- dataOut->dataCompressed[thisRBExpAddr] = storedExp[n];\r
-\r
- /// Now have 1 RB worth of bytes separated into 3 chunks (1 per lane)\r
- /// Use three offset stores to join\r
- constexpr uint16_t k_RbWriteMask = 0x0FFF;\r
- constexpr int k_numDataBytesPerLane = 12;\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 0));\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + k_numDataBytesPerLane, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 1));\r
- _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + (2 * k_numDataBytesPerLane), k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 2));\r
- }\r
-}\r
-\r
-\r
-/// 8 bit expansion\r
-void\r
-BlockFloatCompander::BlockFloatExpand_8b_AVX512(const CompressedData& dataIn, ExpandedData* dataOut)\r
-{\r
-#pragma unroll(BlockFloatCompander::k_numRB)\r
- for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)\r
- {\r
- /// Expand 1RB of data\r
- auto expAddr = n * (BlockFloatCompander::k_numREReal + 1);\r
- const __m256i* rawDataIn = reinterpret_cast<const __m256i*>(dataIn.dataCompressed + expAddr + 1);\r
- const auto compData16 = _mm512_cvtepi8_epi16(*rawDataIn);\r
- const auto expData = _mm512_slli_epi16(compData16, *(dataIn.dataCompressed + expAddr));\r
- /// Write expanded data to output\r
- constexpr uint8_t k_rbMask64 = 0b00111111; // 64b write mask for 1RB (24 int16 values)\r
- _mm512_mask_storeu_epi64(dataOut->dataExpanded + n * BlockFloatCompander::k_numREReal, k_rbMask64, expData);\r
- }\r
-}\r
-\r
-\r
-/// 9 bit expansion\r
-void\r
-BlockFloatCompander::BlockFloatExpand_9b_AVX512(const CompressedData& dataIn, ExpandedData* dataOut)\r
-{\r
-#pragma unroll(BlockFloatCompander::k_numRB)\r
- for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)\r
- {\r
- constexpr int k_totNumBytesPerRB = 28;\r
- auto expAddr = n * k_totNumBytesPerRB;\r
-\r
- /// Unpack network order packed data\r
- auto expData = networkByteUnpack9b(dataIn.dataCompressed + expAddr + 1);\r
-\r
- /// Apply exponent scaling (by appropriate arithmetic shift right)\r
- constexpr int k_maxExpShift = 7;\r
- expData = _mm512_srai_epi16(expData, k_maxExpShift - *(dataIn.dataCompressed + expAddr));\r
-\r
- /// Write expanded data to output\r
- static constexpr uint32_t k_WriteMask = 0x00FFFFFF;\r
- _mm512_mask_storeu_epi16(dataOut->dataExpanded + n * BlockFloatCompander::k_numREReal, k_WriteMask, expData);\r
- }\r
-}\r
-\r
-\r
-/// 10 bit expansion\r
-void\r
-BlockFloatCompander::BlockFloatExpand_10b_AVX512(const CompressedData& dataIn, ExpandedData* dataOut)\r
-{\r
-#pragma unroll(BlockFloatCompander::k_numRB)\r
- for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)\r
- {\r
- constexpr int k_totNumBytesPerRB = 31;\r
- auto expAddr = n * k_totNumBytesPerRB;\r
-\r
- /// Unpack network order packed data\r
- auto expData = networkByteUnpack10b(dataIn.dataCompressed + expAddr + 1);\r
-\r
- /// Apply exponent scaling (by appropriate arithmetic shift right)\r
- constexpr int k_maxExpShift = 6;\r
- expData = _mm512_srai_epi16(expData, k_maxExpShift - *(dataIn.dataCompressed + expAddr));\r
-\r
- /// Write expanded data to output\r
- static constexpr uint32_t k_WriteMask = 0x00FFFFFF;\r
- _mm512_mask_storeu_epi16(dataOut->dataExpanded + n * BlockFloatCompander::k_numREReal, k_WriteMask, expData);\r
- }\r
-}\r
-\r
-\r
-/// 12 bit expansion\r
-void\r
-BlockFloatCompander::BlockFloatExpand_12b_AVX512(const CompressedData& dataIn, ExpandedData* dataOut)\r
-{\r
-#pragma unroll(BlockFloatCompander::k_numRB)\r
- for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)\r
- {\r
- constexpr int k_totNumBytesPerRB = 37;\r
- auto expAddr = n * k_totNumBytesPerRB;\r
-\r
- /// Unpack network order packed data\r
- auto expData = networkByteUnpack12b(dataIn.dataCompressed + expAddr + 1);\r
-\r
- /// Apply exponent scaling (by appropriate arithmetic shift right)\r
- constexpr int k_maxExpShift = 4;\r
- expData = _mm512_srai_epi16(expData, k_maxExpShift - *(dataIn.dataCompressed + expAddr));\r
-\r
- /// Write expanded data to output\r
- static constexpr uint32_t k_WriteMask = 0x00FFFFFF;\r
- _mm512_mask_storeu_epi16(dataOut->dataExpanded + n * BlockFloatCompander::k_numREReal, k_WriteMask, expData);\r
- }\r
-}\r
-\r
-\r
-/// Reference compression\r
-void\r
-BlockFloatCompander::BlockFloatCompress_Basic(const ExpandedData& dataIn, CompressedData* dataOut)\r
-{\r
- int dataOutIdx = 0;\r
- int16_t iqMask = (int16_t)((1 << dataIn.iqWidth) - 1);\r
- int byteShiftUnits = dataIn.iqWidth - 8;\r
-\r
- for (int rb = 0; rb < BlockFloatCompander::k_numRB; ++rb)\r
- {\r
- /// Find max abs value for this RB\r
- int16_t maxAbs = 0;\r
- for (int re = 0; re < BlockFloatCompander::k_numREReal; ++re)\r
- {\r
- auto dataIdx = rb * BlockFloatCompander::k_numREReal + re;\r
- auto dataAbs = saturateAbs(dataIn.dataExpanded[dataIdx]);\r
- maxAbs = std::max(maxAbs, dataAbs);\r
- }\r
-\r
- // Find exponent and insert into byte stream\r
- auto thisExp = (uint8_t)(std::max(0,(16 - dataIn.iqWidth + 1 - __lzcnt16(maxAbs))));\r
- dataOut->dataCompressed[dataOutIdx++] = thisExp;\r
-\r
- /// ARS data by exponent and pack bytes in Network order\r
- /// This uses a sliding buffer where one or more bytes are\r
- /// extracted after the insertion of each compressed sample\r
- static constexpr int k_byteMask = 0xFF;\r
- int byteShiftVal = -8;\r
- int byteBuffer = { 0 };\r
- for (int re = 0; re < BlockFloatCompander::k_numREReal; ++re)\r
- {\r
- auto dataIdxIn = rb * BlockFloatCompander::k_numREReal + re;\r
- auto thisRE = dataIn.dataExpanded[dataIdxIn] >> thisExp;\r
- byteBuffer = (byteBuffer << dataIn.iqWidth) + (int)(thisRE & iqMask);\r
-\r
- byteShiftVal += (8 + byteShiftUnits);\r
- while (byteShiftVal >= 0)\r
- {\r
- auto thisByte = (uint8_t)((byteBuffer >> byteShiftVal) & k_byteMask);\r
- dataOut->dataCompressed[dataOutIdx++] = thisByte;\r
- byteShiftVal -= 8;\r
- }\r
- }\r
- }\r
- dataOut->iqWidth = dataIn.iqWidth;\r
-}\r
-\r
-/// Reference expansion\r
-void\r
-BlockFloatCompander::BlockFloatExpand_Basic(const CompressedData& dataIn, ExpandedData* dataOut)\r
-{\r
- uint32_t iqMask = (uint32_t)(UINT_MAX - ((1 << (32 - dataIn.iqWidth)) - 1));\r
- uint32_t byteBuffer = { 0 };\r
- int numBytesPerRB = (3 * dataIn.iqWidth) + 1;\r
- int bitPointer = 0;\r
- int dataIdxOut = 0;\r
-\r
- for (int rb = 0; rb < BlockFloatCompander::k_numRB; ++rb)\r
- {\r
- auto expIdx = rb * numBytesPerRB;\r
- auto signExtShift = 32 - dataIn.iqWidth - dataIn.dataCompressed[expIdx];\r
-\r
- for (int b = 0; b < numBytesPerRB - 1; ++b)\r
- {\r
- auto dataIdxIn = (expIdx + 1) + b;\r
- auto thisByte = (uint16_t)dataIn.dataCompressed[dataIdxIn];\r
- byteBuffer = (uint32_t)((byteBuffer << 8) + thisByte);\r
- bitPointer += 8;\r
- while (bitPointer >= dataIn.iqWidth)\r
- {\r
- /// byteBuffer currently has enough data in it to extract a sample\r
- /// Shift left first to set sign bit at MSB, then shift right to\r
- /// sign extend down to iqWidth. Finally recast to int16.\r
- int32_t thisSample32 = (int32_t)((byteBuffer << (32 - bitPointer)) & iqMask);\r
- int16_t thisSample = (int16_t)(thisSample32 >> signExtShift);\r
- bitPointer -= dataIn.iqWidth;\r
- dataOut->dataExpanded[dataIdxOut++] = thisSample;\r
- }\r
- }\r
- }\r
-}\r
-\r
-/// Reference compression\r
-void\r
-BlockFloatCompanderBFW::BlockFloatCompress_Basic(const BlockFloatCompanderBFW::ExpandedData& dataIn, BlockFloatCompanderBFW::CompressedData* dataOut)\r
-{\r
- int dataOutIdx = 0;\r
- int16_t iqMask = (int16_t)((1 << dataIn.iqWidth) - 1);\r
- int byteShiftUnits = dataIn.iqWidth - 8;\r
-\r
- for (int rb = 0; rb < BlockFloatCompanderBFW::k_numRB; ++rb)\r
- {\r
- /// Find max abs value for this RB\r
- int16_t maxAbs = 0;\r
- for (int re = 0; re < BlockFloatCompanderBFW::k_numREReal; ++re)\r
- {\r
- auto dataIdx = rb * BlockFloatCompanderBFW::k_numREReal + re;\r
- auto dataAbs = saturateAbs(dataIn.dataExpanded[dataIdx]);\r
- maxAbs = std::max(maxAbs, dataAbs);\r
- }\r
-\r
- // Find exponent and insert into byte stream\r
- auto thisExp = (uint8_t)(std::max(0,(16 - dataIn.iqWidth + 1 - __lzcnt16(maxAbs))));\r
- dataOut->dataCompressed[dataOutIdx++] = thisExp;\r
-\r
- /// ARS data by exponent and pack bytes in Network order\r
- /// This uses a sliding buffer where one or more bytes are\r
- /// extracted after the insertion of each compressed sample\r
- static constexpr int k_byteMask = 0xFF;\r
- int byteShiftVal = -8;\r
- int byteBuffer = { 0 };\r
- for (int re = 0; re < BlockFloatCompanderBFW::k_numREReal; ++re)\r
- {\r
- auto dataIdxIn = rb * BlockFloatCompanderBFW::k_numREReal + re;\r
- auto thisRE = dataIn.dataExpanded[dataIdxIn] >> thisExp;\r
- byteBuffer = (byteBuffer << dataIn.iqWidth) + (int)(thisRE & iqMask);\r
-\r
- byteShiftVal += (8 + byteShiftUnits);\r
- while (byteShiftVal >= 0)\r
- {\r
- auto thisByte = (uint8_t)((byteBuffer >> byteShiftVal) & k_byteMask);\r
- dataOut->dataCompressed[dataOutIdx++] = thisByte;\r
- byteShiftVal -= 8;\r
- }\r
- }\r
- }\r
- dataOut->iqWidth = dataIn.iqWidth;\r
-}\r
-\r
-/// Reference expansion\r
-void\r
-BlockFloatCompanderBFW::BlockFloatExpand_Basic(const BlockFloatCompanderBFW::CompressedData& dataIn, BlockFloatCompanderBFW::ExpandedData* dataOut)\r
-{\r
- uint32_t iqMask = (uint32_t)(UINT_MAX - ((1 << (32 - dataIn.iqWidth)) - 1));\r
- uint32_t byteBuffer = { 0 };\r
- int numBytesPerRB = (3 * dataIn.iqWidth) + 1;\r
- int bitPointer = 0;\r
- int dataIdxOut = 0;\r
-\r
- for (int rb = 0; rb < BlockFloatCompanderBFW::k_numRB; ++rb)\r
- {\r
- auto expIdx = rb * numBytesPerRB;\r
- auto signExtShift = 32 - dataIn.iqWidth - dataIn.dataCompressed[expIdx];\r
-\r
- for (int b = 0; b < numBytesPerRB - 1; ++b)\r
- {\r
- auto dataIdxIn = (expIdx + 1) + b;\r
- auto thisByte = (uint16_t)dataIn.dataCompressed[dataIdxIn];\r
- byteBuffer = (uint32_t)((byteBuffer << 8) + thisByte);\r
- bitPointer += 8;\r
- while (bitPointer >= dataIn.iqWidth)\r
- {\r
- /// byteBuffer currently has enough data in it to extract a sample\r
- /// Shift left first to set sign bit at MSB, then shift right to\r
- /// sign extend down to iqWidth. Finally recast to int16.\r
- int32_t thisSample32 = (int32_t)((byteBuffer << (32 - bitPointer)) & iqMask);\r
- int16_t thisSample = (int16_t)(thisSample32 >> signExtShift);\r
- bitPointer -= dataIn.iqWidth;\r
- dataOut->dataExpanded[dataIdxOut++] = thisSample;\r
- }\r
- }\r
- }\r
-}\r
-\r
-#define RB_NUM_ROUNDUP(rb) \\r
- (BlockFloatCompander::k_numRB * ((rb + BlockFloatCompander::k_numRB - 1) / BlockFloatCompander::k_numRB))\r
-\r
-\r
-/** callback function type for Symbol packet */\r
-typedef void (*xran_bfp_compress_fn)(const BlockFloatCompander::ExpandedData& dataIn,\r
- BlockFloatCompander::CompressedData* dataOut);\r
-\r
-int32_t\r
-xranlib_compress_avx512(const struct xranlib_compress_request *request,\r
- struct xranlib_compress_response *response)\r
-{\r
- BlockFloatCompander::ExpandedData expandedDataInput;\r
- BlockFloatCompander::CompressedData compressedDataOut;\r
- xran_bfp_compress_fn com_fn = NULL;\r
- int16_t numRBs = request->numRBs;\r
- int16_t len = 0;\r
-\r
- switch (request->iqWidth){\r
- case 8:\r
- expandedDataInput.iqWidth = 8;\r
- com_fn = BlockFloatCompander::BlockFloatCompress_8b_AVX512;\r
- break;\r
- case 9:\r
- expandedDataInput.iqWidth = 9;\r
- com_fn = BlockFloatCompander::BlockFloatCompress_9b_AVX512;\r
- break;\r
- case 10:\r
- expandedDataInput.iqWidth = 10;\r
- com_fn = BlockFloatCompander::BlockFloatCompress_10b_AVX512;\r
- break;\r
- case 12:\r
- expandedDataInput.iqWidth = 12;\r
- com_fn = BlockFloatCompander::BlockFloatCompress_12b_AVX512;\r
- break;\r
- default:\r
- expandedDataInput.iqWidth = request->iqWidth;\r
- com_fn = BlockFloatCompander::BlockFloatCompress_Basic;\r
- break;\r
- }\r
-\r
- for (int16_t block_idx = 0;\r
- block_idx < RB_NUM_ROUNDUP(numRBs)/BlockFloatCompander::k_numRB /*+ 1*/; /* 16 RBs at time */\r
- block_idx++) {\r
-\r
- expandedDataInput.dataExpanded =\r
- &request->data_in[block_idx*BlockFloatCompander::k_numSampsExpanded];\r
- compressedDataOut.dataCompressed =\r
- (uint8_t*)&response->data_out[len];\r
-\r
- com_fn(expandedDataInput, &compressedDataOut);\r
- len += ((3 * expandedDataInput.iqWidth) + 1) * std::min((int16_t)BlockFloatCompander::k_numRB,(int16_t)numRBs);\r
- }\r
-\r
- response->len = ((3 * expandedDataInput.iqWidth) + 1) * numRBs;\r
-\r
- return 0;\r
-}\r
-\r
-/** callback function type for Symbol packet */\r
-typedef void (*xran_bfp_compress_bfw_fn)(const BlockFloatCompanderBFW::ExpandedData& dataIn, BlockFloatCompanderBFW::CompressedData* dataOut);\r
-\r
-int32_t\r
-xranlib_compress_avx512_bfw(const struct xranlib_compress_request *request,\r
- struct xranlib_compress_response *response)\r
-{\r
- BlockFloatCompanderBFW::ExpandedData expandedDataInput;\r
- BlockFloatCompanderBFW::CompressedData compressedDataKern;\r
- xran_bfp_compress_bfw_fn com_fn = NULL;\r
-\r
-#if 0\r
- for (int m = 0; m < BlockFloatCompander::k_numRB; ++m){\r
- for (int n = 0; n < BlockFloatCompander::k_numREReal; ++n){\r
- expandedDataInput.dataExpanded[m*BlockFloatCompander::k_numREReal+n] =\r
- request->data_in[m*BlockFloatCompander::k_numREReal+n];\r
- }\r
- }\r
-#endif\r
-\r
- expandedDataInput.dataExpanded = request->data_in;\r
- compressedDataKern.dataCompressed = (uint8_t*)response->data_out;\r
-\r
- com_fn = BlockFloatCompanderBFW::BlockFloatCompress_Basic;\r
- switch (request->iqWidth){\r
- case 8:\r
- expandedDataInput.iqWidth = 8;\r
- break;\r
- case 9:\r
- expandedDataInput.iqWidth = 9;\r
- //com_fn = BlockFloatCompanderBFW::BlockFloatExpand_9b_AVX512\r
- break;\r
- case 10:\r
- expandedDataInput.iqWidth = 10;\r
- break;\r
- case 12:\r
- expandedDataInput.iqWidth = 12;\r
- break;\r
- default:\r
- printf("bfwIqWidth is not supported %d\n", request->iqWidth);\r
- return -1;\r
- break;\r
- }\r
-\r
- com_fn(expandedDataInput, &compressedDataKern);\r
- response->len = ((BlockFloatCompanderBFW::k_numRE/16*4*expandedDataInput.iqWidth)+1)*BlockFloatCompanderBFW::k_numRB;\r
-\r
- return 0;\r
-}\r
-\r
-/** callback function type for Symbol packet */\r
-typedef void (*xran_bfp_decompress_fn)(const BlockFloatCompander::CompressedData& dataIn, BlockFloatCompander::ExpandedData* dataOut);\r
-\r
-\r
-int32_t\r
-xranlib_decompress_avx512(const struct xranlib_decompress_request *request,\r
- struct xranlib_decompress_response *response)\r
-{\r
-\r
- BlockFloatCompander::CompressedData compressedDataInput;\r
- BlockFloatCompander::ExpandedData expandedDataOut;\r
-\r
- xran_bfp_decompress_fn decom_fn = NULL;\r
- int16_t numRBs = request->numRBs;\r
- int16_t len = 0;\r
-\r
- switch (request->iqWidth){\r
- case 8:\r
- compressedDataInput.iqWidth = 8;\r
- decom_fn = BlockFloatCompander::BlockFloatExpand_8b_AVX512;\r
- break;\r
- case 9:\r
- compressedDataInput.iqWidth = 9;\r
- decom_fn = BlockFloatCompander::BlockFloatExpand_9b_AVX512;\r
- break;\r
- case 10:\r
- compressedDataInput.iqWidth = 10;\r
- decom_fn = BlockFloatCompander::BlockFloatExpand_10b_AVX512;\r
- break;\r
- case 12:\r
- compressedDataInput.iqWidth = 12;\r
- decom_fn = BlockFloatCompander::BlockFloatExpand_12b_AVX512;\r
- break;\r
- default:\r
- compressedDataInput.iqWidth = request->iqWidth;\r
- decom_fn = BlockFloatCompander::BlockFloatExpand_Basic;\r
- break;\r
- }\r
-\r
- for (int16_t block_idx = 0;\r
- block_idx < RB_NUM_ROUNDUP(numRBs)/BlockFloatCompander::k_numRB;\r
- block_idx++) {\r
-\r
- compressedDataInput.dataCompressed = (uint8_t*)&request->data_in[block_idx*(((3 * compressedDataInput.iqWidth ) + 1) * BlockFloatCompander::k_numRB)];\r
- expandedDataOut.dataExpanded = &response->data_out[len];\r
-\r
- decom_fn(compressedDataInput, &expandedDataOut);\r
- len += std::min((int16_t)BlockFloatCompander::k_numSampsExpanded, (int16_t)(numRBs*BlockFloatCompander::k_numREReal));\r
- }\r
-\r
- response->len = numRBs * BlockFloatCompander::k_numREReal* sizeof(int16_t);\r
-\r
- return 0;\r
-}\r
+/******************************************************************************
+*
+* Copyright (c) 2019 Intel.
+*
+* Licensed under the Apache License, Version 2.0 (the "License");
+* you may not use this file except in compliance with the License.
+* You may obtain a copy of the License at
+*
+* http://www.apache.org/licenses/LICENSE-2.0
+*
+* Unless required by applicable law or agreed to in writing, software
+* distributed under the License is distributed on an "AS IS" BASIS,
+* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+* See the License for the specific language governing permissions and
+* limitations under the License.
+*
+*******************************************************************************/
+
+#include "xran_compression.hpp"
+#include "xran_compression.h"
+#include <complex>
+#include <algorithm>
+#include <immintrin.h>
+#include <limits.h>
+#include <cstring>
+
+static int16_t saturateAbs(int16_t inVal)
+{
+ int16_t result;
+ if (inVal == std::numeric_limits<short>::min())
+ {
+ result = std::numeric_limits<short>::max();
+ }
+ else
+ {
+ result = (int16_t)std::abs(inVal);
+ }
+ return result;
+}
+
+
+/// Compute exponent value for a set of RB from the maximum absolute value
+void
+computeExponent(const BlockFloatCompander::ExpandedData& dataIn, int8_t* expStore)
+{
+ __m512i maxAbs = __m512i();
+
+ /// Load data and find max(abs(RB))
+ const __m512i* rawData = reinterpret_cast<const __m512i*>(dataIn.dataExpanded);
+ constexpr int k_numRBPerLoop = 4;
+ constexpr int k_numInputLoopIts = BlockFloatCompander::k_numRB / k_numRBPerLoop;
+
+#pragma unroll(k_numInputLoopIts)
+ for (int n = 0; n < k_numInputLoopIts; ++n)
+ {
+ /// Re-order the next 4RB in input data into 3 registers
+ /// Input SIMD vectors are:
+ /// [A A A A A A A A A A A A B B B B]
+ /// [B B B B B B B B C C C C C C C C]
+ /// [C C C C D D D D D D D D D D D D]
+ /// Re-ordered SIMD vectors are:
+ /// [A A A A B B B B C C C C D D D D]
+ /// [A A A A B B B B C C C C D D D D]
+ /// [A A A A B B B B C C C C D D D D]
+ constexpr uint8_t k_msk1 = 0b11111100; // Copy first lane of src
+ constexpr int k_shuff1 = 0x41;
+ const auto z_w1 = _mm512_mask_shuffle_i64x2(rawData[3 * n + 0], k_msk1, rawData[3 * n + 1], rawData[3 * n + 2], k_shuff1);
+
+ constexpr uint8_t k_msk2 = 0b11000011; // Copy middle two lanes of src
+ constexpr int k_shuff2 = 0xB1;
+ const auto z_w2 = _mm512_mask_shuffle_i64x2(rawData[3 * n + 1], k_msk2, rawData[3 * n + 0], rawData[3 * n + 2], k_shuff2);
+
+ constexpr uint8_t k_msk3 = 0b00111111; // Copy last lane of src
+ constexpr int k_shuff3 = 0xBE;
+ const auto z_w3 = _mm512_mask_shuffle_i64x2(rawData[3 * n + 2], k_msk3, rawData[3 * n + 0], rawData[3 * n + 1], k_shuff3);
+
+ /// Perform max abs on these 3 registers
+ const auto abs16_1 = _mm512_abs_epi16(z_w1);
+ const auto abs16_2 = _mm512_abs_epi16(z_w2);
+ const auto abs16_3 = _mm512_abs_epi16(z_w3);
+ const auto maxAbs_12 = _mm512_max_epi16(abs16_1, abs16_2);
+ const auto maxAbs_123 = _mm512_max_epi16(maxAbs_12, abs16_3);
+
+ /// Perform horizontal max over each lane
+ /// Swap 64b in each lane and compute max
+ const auto k_perm64b = _mm512_set_epi64(6, 7, 4, 5, 2, 3, 0, 1);
+ auto maxAbsPerm = _mm512_permutexvar_epi64(k_perm64b, maxAbs_123);
+ auto maxAbsHorz = _mm512_max_epi16(maxAbs_123, maxAbsPerm);
+
+ /// Swap each pair of 32b in each lane and compute max
+ const auto k_perm32b = _mm512_set_epi32(14, 15, 12, 13, 10, 11, 8, 9, 6, 7, 4, 5, 2, 3, 0, 1);
+ maxAbsPerm = _mm512_permutexvar_epi32(k_perm32b, maxAbsHorz);
+ maxAbsHorz = _mm512_max_epi16(maxAbsHorz, maxAbsPerm);
+
+ /// Swap each IQ pair in each lane (via 32b rotation) and compute max
+ maxAbsPerm = _mm512_rol_epi32(maxAbsHorz, BlockFloatCompander::k_numBitsIQ);
+ maxAbsHorz = _mm512_max_epi16(maxAbsHorz, maxAbsPerm);
+
+ /// Insert values into maxAbs
+ /// Use sliding mask to insert wanted values into maxAbs
+ /// Pairs of values will be inserted and corrected outside of loop
+ const auto k_select4RB = _mm512_set_epi32(28, 24, 20, 16, 28, 24, 20, 16,
+ 28, 24, 20, 16, 28, 24, 20, 16);
+ constexpr uint16_t k_expMsk[k_numInputLoopIts] = { 0x000F, 0x00F0, 0x0F00, 0xF000 };
+ maxAbs = _mm512_mask_permutex2var_epi32(maxAbs, k_expMsk[n], k_select4RB, maxAbsHorz);
+ }
+
+ /// Convert to 32b by removing repeated values in maxAbs
+ const auto k_upperWordMask = _mm512_set_epi64(0x0000FFFF0000FFFF, 0x0000FFFF0000FFFF,
+ 0x0000FFFF0000FFFF, 0x0000FFFF0000FFFF,
+ 0x0000FFFF0000FFFF, 0x0000FFFF0000FFFF,
+ 0x0000FFFF0000FFFF, 0x0000FFFF0000FFFF);
+ maxAbs = _mm512_and_epi64(maxAbs, k_upperWordMask);
+
+ /// Compute and store exponent
+ const auto totShiftBits = _mm512_set1_epi32(32 - dataIn.iqWidth + 1);
+ const auto lzCount = _mm512_lzcnt_epi32(maxAbs);
+ const auto exponent = _mm512_sub_epi32(totShiftBits, lzCount);
+ constexpr uint16_t k_expWriteMask = 0xFFFF;
+ _mm512_mask_cvtepi32_storeu_epi8(expStore, k_expWriteMask, exponent);
+}
+
+
+/// Pack compressed 9 bit data in network byte order
+/// See https://soco.intel.com/docs/DOC-2665619
+__m512i
+networkBytePack9b(const __m512i compData)
+{
+ /// Logical shift left to align network order byte parts
+ const __m512i k_shiftLeft = _mm512_set_epi64(0x0000000100020003, 0x0004000500060007,
+ 0x0000000100020003, 0x0004000500060007,
+ 0x0000000100020003, 0x0004000500060007,
+ 0x0000000100020003, 0x0004000500060007);
+ auto compDataPacked = _mm512_sllv_epi16(compData, k_shiftLeft);
+
+ /// First epi8 shuffle of even indexed samples
+ const __m512i k_byteShuffleMask1 = _mm512_set_epi64(0x0000000000000000, 0x0C0D080904050001,
+ 0x0000000000000000, 0x0C0D080904050001,
+ 0x0000000000000000, 0x0C0D080904050001,
+ 0x0000000000000000, 0x0C0D080904050001);
+ constexpr uint64_t k_byteMask1 = 0x000000FF00FF00FF;
+ auto compDataShuff1 = _mm512_maskz_shuffle_epi8(k_byteMask1, compDataPacked, k_byteShuffleMask1);
+
+ /// Second epi8 shuffle of odd indexed samples
+ const __m512i k_byteShuffleMask2 = _mm512_set_epi64(0x000000000000000E, 0x0F0A0B0607020300,
+ 0x000000000000000E, 0x0F0A0B0607020300,
+ 0x000000000000000E, 0x0F0A0B0607020300,
+ 0x000000000000000E, 0x0F0A0B0607020300);
+ constexpr uint64_t k_byteMask2 = 0x000001FE01FE01FE;
+ auto compDataShuff2 = _mm512_maskz_shuffle_epi8(k_byteMask2, compDataPacked, k_byteShuffleMask2);
+
+ /// Ternary blend of the two shuffled results
+ const __m512i k_ternLogSelect = _mm512_set_epi64(0x00000000000000FF, 0x01FC07F01FC07F00,
+ 0x00000000000000FF, 0x01FC07F01FC07F00,
+ 0x00000000000000FF, 0x01FC07F01FC07F00,
+ 0x00000000000000FF, 0x01FC07F01FC07F00);
+ return _mm512_ternarylogic_epi64(compDataShuff1, compDataShuff2, k_ternLogSelect, 0xd8);
+}
+
+
+/// Pack compressed 10 bit data in network byte order
+/// See https://soco.intel.com/docs/DOC-2665619
+__m512i
+networkBytePack10b(const __m512i compData)
+{
+ /// Logical shift left to align network order byte parts
+ const __m512i k_shiftLeft = _mm512_set_epi64(0x0000000200040006, 0x0000000200040006,
+ 0x0000000200040006, 0x0000000200040006,
+ 0x0000000200040006, 0x0000000200040006,
+ 0x0000000200040006, 0x0000000200040006);
+ auto compDataPacked = _mm512_sllv_epi16(compData, k_shiftLeft);
+
+ /// First epi8 shuffle of even indexed samples
+ const __m512i k_byteShuffleMask1 = _mm512_set_epi64(0x000000000000000C, 0x0D08090004050001,
+ 0x000000000000000C, 0x0D08090004050001,
+ 0x000000000000000C, 0x0D08090004050001,
+ 0x000000000000000C, 0x0D08090004050001);
+ constexpr uint64_t k_byteMask1 = 0x000001EF01EF01EF;
+ auto compDataShuff1 = _mm512_maskz_shuffle_epi8(k_byteMask1, compDataPacked, k_byteShuffleMask1);
+
+ /// Second epi8 shuffle of odd indexed samples
+ const __m512i k_byteShuffleMask2 = _mm512_set_epi64(0x0000000000000E0F, 0x0A0B000607020300,
+ 0x0000000000000E0F, 0x0A0B000607020300,
+ 0x0000000000000E0F, 0x0A0B000607020300,
+ 0x0000000000000E0F, 0x0A0B000607020300);
+ constexpr uint64_t k_byteMask2 = 0x000003DE03DE03DE;
+ auto compDataShuff2 = _mm512_maskz_shuffle_epi8(k_byteMask2, compDataPacked, k_byteShuffleMask2);
+
+ /// Ternary blend of the two shuffled results
+ const __m512i k_ternLogSelect = _mm512_set_epi64(0x000000000000FF03, 0xF03F00FF03F03F00,
+ 0x000000000000FF03, 0xF03F00FF03F03F00,
+ 0x000000000000FF03, 0xF03F00FF03F03F00,
+ 0x000000000000FF03, 0xF03F00FF03F03F00);
+ return _mm512_ternarylogic_epi64(compDataShuff1, compDataShuff2, k_ternLogSelect, 0xd8);
+}
+
+
+/// Pack compressed 12 bit data in network byte order
+/// See https://soco.intel.com/docs/DOC-2665619
+__m512i
+networkBytePack12b(const __m512i compData)
+{
+ /// Logical shift left to align network order byte parts
+ const __m512i k_shiftLeft = _mm512_set_epi64(0x0000000400000004, 0x0000000400000004,
+ 0x0000000400000004, 0x0000000400000004,
+ 0x0000000400000004, 0x0000000400000004,
+ 0x0000000400000004, 0x0000000400000004);
+ auto compDataPacked = _mm512_sllv_epi16(compData, k_shiftLeft);
+
+ /// First epi8 shuffle of even indexed samples
+ const __m512i k_byteShuffleMask1 = _mm512_set_epi64(0x00000000000C0D00, 0x0809000405000001,
+ 0x00000000000C0D00, 0x0809000405000001,
+ 0x00000000000C0D00, 0x0809000405000001,
+ 0x00000000000C0D00, 0x0809000405000001);
+ constexpr uint64_t k_byteMask1 = 0x000006DB06DB06DB;
+ auto compDataShuff1 = _mm512_maskz_shuffle_epi8(k_byteMask1, compDataPacked, k_byteShuffleMask1);
+
+ /// Second epi8 shuffle of odd indexed samples
+ const __m512i k_byteShuffleMask2 = _mm512_set_epi64(0x000000000E0F000A, 0x0B00060700020300,
+ 0x000000000E0F000A, 0x0B00060700020300,
+ 0x000000000E0F000A, 0x0B00060700020300,
+ 0x000000000E0F000A, 0x0B00060700020300);
+ constexpr uint64_t k_byteMask2 = 0x00000DB60DB60DB6;
+ auto compDataShuff2 = _mm512_maskz_shuffle_epi8(k_byteMask2, compDataPacked, k_byteShuffleMask2);
+
+ /// Ternary blend of the two shuffled results
+ const __m512i k_ternLogSelect = _mm512_set_epi64(0x00000000FF0F00FF, 0x0F00FF0F00FF0F00,
+ 0x00000000FF0F00FF, 0x0F00FF0F00FF0F00,
+ 0x00000000FF0F00FF, 0x0F00FF0F00FF0F00,
+ 0x00000000FF0F00FF, 0x0F00FF0F00FF0F00);
+ return _mm512_ternarylogic_epi64(compDataShuff1, compDataShuff2, k_ternLogSelect, 0xd8);
+}
+
+
+/// Unpack compressed 9 bit data in network byte order
+/// See https://soco.intel.com/docs/DOC-2665619
+__m512i
+networkByteUnpack9b(const uint8_t* inData)
+{
+ /// Align chunks of compressed bytes into lanes to allow for expansion
+ const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(inData);
+ const auto k_expPerm = _mm512_set_epi32(15, 14, 13, 12, 7, 6, 5, 4,
+ 5, 4, 3, 2, 3, 2, 1, 0);
+ auto expData = _mm512_permutexvar_epi32(k_expPerm, *rawDataIn);
+
+ /// Byte shuffle to get all bits for each sample into 16b chunks
+ /// Due to previous permute to get chunks of bytes into each lane, there is
+ /// a different shuffle offset in each lane
+ const __m512i k_byteShuffleMask = _mm512_set_epi64(0x0F0E0D0C0B0A0908, 0x0706050403020100,
+ 0x090A080907080607, 0x0506040503040203,
+ 0x0809070806070506, 0x0405030402030102,
+ 0x0708060705060405, 0x0304020301020001);
+ expData = _mm512_shuffle_epi8(expData, k_byteShuffleMask);
+
+ /// Logical shift left to set sign bit
+ const __m512i k_slBits = _mm512_set_epi64(0x0007000600050004, 0x0003000200010000,
+ 0x0007000600050004, 0x0003000200010000,
+ 0x0007000600050004, 0x0003000200010000,
+ 0x0007000600050004, 0x0003000200010000);
+ expData = _mm512_sllv_epi16(expData, k_slBits);
+
+ /// Mask to zero unwanted bits
+ const __m512i k_expMask = _mm512_set1_epi16(0xFF80);
+ return _mm512_and_epi64(expData, k_expMask);
+}
+
+
+/// Unpack compressed 10 bit data in network byte order
+/// See https://soco.intel.com/docs/DOC-2665619
+__m512i
+networkByteUnpack10b(const uint8_t* inData)
+{
+ /// Align chunks of compressed bytes into lanes to allow for expansion
+ const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(inData);
+ const auto k_expPerm = _mm512_set_epi32(15, 14, 13, 12, 8, 7, 6, 5,
+ 5, 4, 3, 2, 3, 2, 1, 0);
+ auto expData = _mm512_permutexvar_epi32(k_expPerm, *rawDataIn);
+
+ /// Byte shuffle to get all bits for each sample into 16b chunks
+ /// Due to previous permute to get chunks of bytes into each lane, lanes
+ /// 0 and 2 happen to be aligned, but lane 1 is offset by 2 bytes
+ const __m512i k_byteShuffleMask = _mm512_set_epi64(0x0809070806070506, 0x0304020301020001,
+ 0x0809070806070506, 0x0304020301020001,
+ 0x0A0B090A08090708, 0x0506040503040203,
+ 0x0809070806070506, 0x0304020301020001);
+ expData = _mm512_shuffle_epi8(expData, k_byteShuffleMask);
+
+ /// Logical shift left to set sign bit
+ const __m512i k_slBits = _mm512_set_epi64(0x0006000400020000, 0x0006000400020000,
+ 0x0006000400020000, 0x0006000400020000,
+ 0x0006000400020000, 0x0006000400020000,
+ 0x0006000400020000, 0x0006000400020000);
+ expData = _mm512_sllv_epi16(expData, k_slBits);
+
+ /// Mask to zero unwanted bits
+ const __m512i k_expMask = _mm512_set1_epi16(0xFFC0);
+ return _mm512_and_epi64(expData, k_expMask);
+}
+
+
+/// Unpack compressed 12 bit data in network byte order
+/// See https://soco.intel.com/docs/DOC-2665619
+__m512i
+networkByteUnpack12b(const uint8_t* inData)
+{
+ /// Align chunks of compressed bytes into lanes to allow for expansion
+ const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(inData);
+ const auto k_expPerm = _mm512_set_epi32(15, 14, 13, 12, 9, 8, 7, 6,
+ 6, 5, 4, 3, 3, 2, 1, 0);
+ auto expData = _mm512_permutexvar_epi32(k_expPerm, *rawDataIn);
+
+ /// Byte shuffle to get all bits for each sample into 16b chunks
+ /// For 12b mantissa all lanes post-permute are aligned and require same shuffle offset
+ const __m512i k_byteShuffleMask = _mm512_set_epi64(0x0A0B090A07080607, 0x0405030401020001,
+ 0x0A0B090A07080607, 0x0405030401020001,
+ 0x0A0B090A07080607, 0x0405030401020001,
+ 0x0A0B090A07080607, 0x0405030401020001);
+ expData = _mm512_shuffle_epi8(expData, k_byteShuffleMask);
+
+ /// Logical shift left to set sign bit
+ const __m512i k_slBits = _mm512_set_epi64(0x0004000000040000, 0x0004000000040000,
+ 0x0004000000040000, 0x0004000000040000,
+ 0x0004000000040000, 0x0004000000040000,
+ 0x0004000000040000, 0x0004000000040000);
+ expData = _mm512_sllv_epi16(expData, k_slBits);
+
+ /// Mask to zero unwanted bits
+ const __m512i k_expMask = _mm512_set1_epi16(0xFFF0);
+ return _mm512_and_epi64(expData, k_expMask);
+}
+
+
+/// 8 bit compression
+void
+BlockFloatCompander::BlockFloatCompress_8b_AVX512(const ExpandedData& dataIn, CompressedData* dataOut)
+{
+ /// Compute exponent and store for later use
+ int8_t storedExp[BlockFloatCompander::k_numRB] = {};
+ computeExponent(dataIn, storedExp);
+
+ /// Shift 1RB by corresponding exponent and write exponent and data to output
+#pragma unroll(BlockFloatCompander::k_numRB)
+ for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)
+ {
+ const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(dataIn.dataExpanded + n * BlockFloatCompander::k_numREReal);
+ auto compData = _mm512_srai_epi16(*rawDataIn, storedExp[n]);
+ auto thisRBExpAddr = n * (BlockFloatCompander::k_numREReal + 1);
+ /// Store exponent first
+ dataOut->dataCompressed[thisRBExpAddr] = storedExp[n];
+ /// Store compressed RB
+ constexpr uint32_t k_rbMask = 0x00FFFFFF; // Write mask for 1RB (24 values)
+ _mm256_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1, k_rbMask, _mm512_cvtepi16_epi8(compData));
+ }
+}
+
+
+/// 9 bit compression
+void
+BlockFloatCompander::BlockFloatCompress_9b_AVX512(const ExpandedData& dataIn, CompressedData* dataOut)
+{
+ /// Compute exponent and store for later use
+ int8_t storedExp[BlockFloatCompander::k_numRB] = {};
+ computeExponent(dataIn, storedExp);
+
+ /// Shift 1RB by corresponding exponent and write exponent and data to output
+ /// Output data is packed exponent first followed by corresponding compressed RB
+#pragma unroll(BlockFloatCompander::k_numRB)
+ for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)
+ {
+ /// Apply exponent shift
+ const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(dataIn.dataExpanded + n * BlockFloatCompander::k_numREReal);
+ auto compData = _mm512_srai_epi16(*rawDataIn, storedExp[n]);
+
+ /// Pack compressed data network byte order
+ auto compDataBytePacked = networkBytePack9b(compData);
+
+ /// Store exponent first
+ constexpr int k_totNumBytesPerRB = 28;
+ auto thisRBExpAddr = n * k_totNumBytesPerRB;
+ dataOut->dataCompressed[thisRBExpAddr] = storedExp[n];
+
+ /// Now have 1 RB worth of bytes separated into 3 chunks (1 per lane)
+ /// Use three offset stores to join
+ constexpr uint16_t k_RbWriteMask = 0x01FF;
+ constexpr int k_numDataBytesPerLane = 9;
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 0));
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + k_numDataBytesPerLane, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 1));
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + (2 * k_numDataBytesPerLane), k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 2));
+ }
+}
+
+
+/// 10 bit compression
+void
+BlockFloatCompander::BlockFloatCompress_10b_AVX512(const ExpandedData& dataIn, CompressedData* dataOut)
+{
+ /// Compute exponent and store for later use
+ int8_t storedExp[BlockFloatCompander::k_numRB] = {};
+ computeExponent(dataIn, storedExp);
+
+ /// Shift 1RB by corresponding exponent and write exponent and data to output
+ /// Output data is packed exponent first followed by corresponding compressed RB
+#pragma unroll(BlockFloatCompander::k_numRB)
+ for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)
+ {
+ /// Apply exponent shift
+ const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(dataIn.dataExpanded + n * BlockFloatCompander::k_numREReal);
+ auto compData = _mm512_srai_epi16(*rawDataIn, storedExp[n]);
+
+ /// Pack compressed data network byte order
+ auto compDataBytePacked = networkBytePack10b(compData);
+
+ /// Store exponent first
+ constexpr int k_totNumBytesPerRB = 31;
+ auto thisRBExpAddr = n * k_totNumBytesPerRB;
+ dataOut->dataCompressed[thisRBExpAddr] = storedExp[n];
+
+ /// Now have 1 RB worth of bytes separated into 3 chunks (1 per lane)
+ /// Use three offset stores to join
+ constexpr uint16_t k_RbWriteMask = 0x03FF;
+ constexpr int k_numDataBytesPerLane = 10;
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 0));
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + k_numDataBytesPerLane, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 1));
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + (2 * k_numDataBytesPerLane), k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 2));
+ }
+}
+
+
+/// 12 bit compression
+void
+BlockFloatCompander::BlockFloatCompress_12b_AVX512(const ExpandedData& dataIn, CompressedData* dataOut)
+{
+ /// Compute exponent and store for later use
+ int8_t storedExp[BlockFloatCompander::k_numRB] = {};
+ computeExponent(dataIn, storedExp);
+
+ /// Shift 1RB by corresponding exponent and write exponent and data to output
+ /// Output data is packed exponent first followed by corresponding compressed RB
+#pragma unroll(BlockFloatCompander::k_numRB)
+ for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)
+ {
+ /// Apply exponent shift
+ const __m512i* rawDataIn = reinterpret_cast<const __m512i*>(dataIn.dataExpanded + n * BlockFloatCompander::k_numREReal);
+ auto compData = _mm512_srai_epi16(*rawDataIn, storedExp[n]);
+
+ /// Pack compressed data network byte order
+ auto compDataBytePacked = networkBytePack12b(compData);
+
+ /// Store exponent first
+ constexpr int k_totNumBytesPerRB = 37;
+ auto thisRBExpAddr = n * k_totNumBytesPerRB;
+ dataOut->dataCompressed[thisRBExpAddr] = storedExp[n];
+
+ /// Now have 1 RB worth of bytes separated into 3 chunks (1 per lane)
+ /// Use three offset stores to join
+ constexpr uint16_t k_RbWriteMask = 0x0FFF;
+ constexpr int k_numDataBytesPerLane = 12;
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 0));
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + k_numDataBytesPerLane, k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 1));
+ _mm_mask_storeu_epi8(dataOut->dataCompressed + thisRBExpAddr + 1 + (2 * k_numDataBytesPerLane), k_RbWriteMask, _mm512_extracti64x2_epi64(compDataBytePacked, 2));
+ }
+}
+
+
+/// 8 bit expansion
+void
+BlockFloatCompander::BlockFloatExpand_8b_AVX512(const CompressedData& dataIn, ExpandedData* dataOut)
+{
+#pragma unroll(BlockFloatCompander::k_numRB)
+ for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)
+ {
+ /// Expand 1RB of data
+ auto expAddr = n * (BlockFloatCompander::k_numREReal + 1);
+ const __m256i* rawDataIn = reinterpret_cast<const __m256i*>(dataIn.dataCompressed + expAddr + 1);
+ const auto compData16 = _mm512_cvtepi8_epi16(*rawDataIn);
+ const auto expData = _mm512_slli_epi16(compData16, *(dataIn.dataCompressed + expAddr));
+ /// Write expanded data to output
+ constexpr uint8_t k_rbMask64 = 0b00111111; // 64b write mask for 1RB (24 int16 values)
+ _mm512_mask_storeu_epi64(dataOut->dataExpanded + n * BlockFloatCompander::k_numREReal, k_rbMask64, expData);
+ }
+}
+
+
+/// 9 bit expansion
+void
+BlockFloatCompander::BlockFloatExpand_9b_AVX512(const CompressedData& dataIn, ExpandedData* dataOut)
+{
+#pragma unroll(BlockFloatCompander::k_numRB)
+ for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)
+ {
+ constexpr int k_totNumBytesPerRB = 28;
+ auto expAddr = n * k_totNumBytesPerRB;
+
+ /// Unpack network order packed data
+ auto expData = networkByteUnpack9b(dataIn.dataCompressed + expAddr + 1);
+
+ /// Apply exponent scaling (by appropriate arithmetic shift right)
+ constexpr int k_maxExpShift = 7;
+ expData = _mm512_srai_epi16(expData, k_maxExpShift - *(dataIn.dataCompressed + expAddr));
+
+ /// Write expanded data to output
+ static constexpr uint32_t k_WriteMask = 0x00FFFFFF;
+ _mm512_mask_storeu_epi16(dataOut->dataExpanded + n * BlockFloatCompander::k_numREReal, k_WriteMask, expData);
+ }
+}
+
+
+/// 10 bit expansion
+void
+BlockFloatCompander::BlockFloatExpand_10b_AVX512(const CompressedData& dataIn, ExpandedData* dataOut)
+{
+#pragma unroll(BlockFloatCompander::k_numRB)
+ for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)
+ {
+ constexpr int k_totNumBytesPerRB = 31;
+ auto expAddr = n * k_totNumBytesPerRB;
+
+ /// Unpack network order packed data
+ auto expData = networkByteUnpack10b(dataIn.dataCompressed + expAddr + 1);
+
+ /// Apply exponent scaling (by appropriate arithmetic shift right)
+ constexpr int k_maxExpShift = 6;
+ expData = _mm512_srai_epi16(expData, k_maxExpShift - *(dataIn.dataCompressed + expAddr));
+
+ /// Write expanded data to output
+ static constexpr uint32_t k_WriteMask = 0x00FFFFFF;
+ _mm512_mask_storeu_epi16(dataOut->dataExpanded + n * BlockFloatCompander::k_numREReal, k_WriteMask, expData);
+ }
+}
+
+
+/// 12 bit expansion
+void
+BlockFloatCompander::BlockFloatExpand_12b_AVX512(const CompressedData& dataIn, ExpandedData* dataOut)
+{
+#pragma unroll(BlockFloatCompander::k_numRB)
+ for (int n = 0; n < BlockFloatCompander::k_numRB; ++n)
+ {
+ constexpr int k_totNumBytesPerRB = 37;
+ auto expAddr = n * k_totNumBytesPerRB;
+
+ /// Unpack network order packed data
+ auto expData = networkByteUnpack12b(dataIn.dataCompressed + expAddr + 1);
+
+ /// Apply exponent scaling (by appropriate arithmetic shift right)
+ constexpr int k_maxExpShift = 4;
+ expData = _mm512_srai_epi16(expData, k_maxExpShift - *(dataIn.dataCompressed + expAddr));
+
+ /// Write expanded data to output
+ static constexpr uint32_t k_WriteMask = 0x00FFFFFF;
+ _mm512_mask_storeu_epi16(dataOut->dataExpanded + n * BlockFloatCompander::k_numREReal, k_WriteMask, expData);
+ }
+}
+
+
+/// Reference compression
+void
+BlockFloatCompander::BlockFloatCompress_Basic(const ExpandedData& dataIn, CompressedData* dataOut)
+{
+ int dataOutIdx = 0;
+ int16_t iqMask = (int16_t)((1 << dataIn.iqWidth) - 1);
+ int byteShiftUnits = dataIn.iqWidth - 8;
+
+ for (int rb = 0; rb < BlockFloatCompander::k_numRB; ++rb)
+ {
+ /// Find max abs value for this RB
+ int16_t maxAbs = 0;
+ for (int re = 0; re < BlockFloatCompander::k_numREReal; ++re)
+ {
+ auto dataIdx = rb * BlockFloatCompander::k_numREReal + re;
+ auto dataAbs = saturateAbs(dataIn.dataExpanded[dataIdx]);
+ maxAbs = std::max(maxAbs, dataAbs);
+ }
+
+ // Find exponent and insert into byte stream
+ auto thisExp = (uint8_t)(std::max(0,(16 - dataIn.iqWidth + 1 - __lzcnt16(maxAbs))));
+ dataOut->dataCompressed[dataOutIdx++] = thisExp;
+
+ /// ARS data by exponent and pack bytes in Network order
+ /// This uses a sliding buffer where one or more bytes are
+ /// extracted after the insertion of each compressed sample
+ static constexpr int k_byteMask = 0xFF;
+ int byteShiftVal = -8;
+ int byteBuffer = { 0 };
+ for (int re = 0; re < BlockFloatCompander::k_numREReal; ++re)
+ {
+ auto dataIdxIn = rb * BlockFloatCompander::k_numREReal + re;
+ auto thisRE = dataIn.dataExpanded[dataIdxIn] >> thisExp;
+ byteBuffer = (byteBuffer << dataIn.iqWidth) + (int)(thisRE & iqMask);
+
+ byteShiftVal += (8 + byteShiftUnits);
+ while (byteShiftVal >= 0)
+ {
+ auto thisByte = (uint8_t)((byteBuffer >> byteShiftVal) & k_byteMask);
+ dataOut->dataCompressed[dataOutIdx++] = thisByte;
+ byteShiftVal -= 8;
+ }
+ }
+ }
+ dataOut->iqWidth = dataIn.iqWidth;
+}
+
+/// Reference expansion
+void
+BlockFloatCompander::BlockFloatExpand_Basic(const CompressedData& dataIn, ExpandedData* dataOut)
+{
+ uint32_t iqMask = (uint32_t)(UINT_MAX - ((1 << (32 - dataIn.iqWidth)) - 1));
+ uint32_t byteBuffer = { 0 };
+ int numBytesPerRB = (3 * dataIn.iqWidth) + 1;
+ int bitPointer = 0;
+ int dataIdxOut = 0;
+
+ for (int rb = 0; rb < BlockFloatCompander::k_numRB; ++rb)
+ {
+ auto expIdx = rb * numBytesPerRB;
+ auto signExtShift = 32 - dataIn.iqWidth - dataIn.dataCompressed[expIdx];
+
+ for (int b = 0; b < numBytesPerRB - 1; ++b)
+ {
+ auto dataIdxIn = (expIdx + 1) + b;
+ auto thisByte = (uint16_t)dataIn.dataCompressed[dataIdxIn];
+ byteBuffer = (uint32_t)((byteBuffer << 8) + thisByte);
+ bitPointer += 8;
+ while (bitPointer >= dataIn.iqWidth)
+ {
+ /// byteBuffer currently has enough data in it to extract a sample
+ /// Shift left first to set sign bit at MSB, then shift right to
+ /// sign extend down to iqWidth. Finally recast to int16.
+ int32_t thisSample32 = (int32_t)((byteBuffer << (32 - bitPointer)) & iqMask);
+ int16_t thisSample = (int16_t)(thisSample32 >> signExtShift);
+ bitPointer -= dataIn.iqWidth;
+ dataOut->dataExpanded[dataIdxOut++] = thisSample;
+ }
+ }
+ }
+}
+
+/// Reference compression
+void
+BlockFloatCompanderBFW::BlockFloatCompress_Basic(const BlockFloatCompanderBFW::ExpandedData& dataIn, BlockFloatCompanderBFW::CompressedData* dataOut)
+{
+ int dataOutIdx = 0;
+ int16_t iqMask = (int16_t)((1 << dataIn.iqWidth) - 1);
+ int byteShiftUnits = dataIn.iqWidth - 8;
+
+ for (int rb = 0; rb < BlockFloatCompanderBFW::k_numRB; ++rb)
+ {
+ /// Find max abs value for this RB
+ int16_t maxAbs = 0;
+ for (int re = 0; re < BlockFloatCompanderBFW::k_numREReal; ++re)
+ {
+ auto dataIdx = rb * BlockFloatCompanderBFW::k_numREReal + re;
+ auto dataAbs = saturateAbs(dataIn.dataExpanded[dataIdx]);
+ maxAbs = std::max(maxAbs, dataAbs);
+ }
+
+ // Find exponent and insert into byte stream
+ auto thisExp = (uint8_t)(std::max(0,(16 - dataIn.iqWidth + 1 - __lzcnt16(maxAbs))));
+ dataOut->dataCompressed[dataOutIdx++] = thisExp;
+
+ /// ARS data by exponent and pack bytes in Network order
+ /// This uses a sliding buffer where one or more bytes are
+ /// extracted after the insertion of each compressed sample
+ static constexpr int k_byteMask = 0xFF;
+ int byteShiftVal = -8;
+ int byteBuffer = { 0 };
+ for (int re = 0; re < BlockFloatCompanderBFW::k_numREReal; ++re)
+ {
+ auto dataIdxIn = rb * BlockFloatCompanderBFW::k_numREReal + re;
+ auto thisRE = dataIn.dataExpanded[dataIdxIn] >> thisExp;
+ byteBuffer = (byteBuffer << dataIn.iqWidth) + (int)(thisRE & iqMask);
+
+ byteShiftVal += (8 + byteShiftUnits);
+ while (byteShiftVal >= 0)
+ {
+ auto thisByte = (uint8_t)((byteBuffer >> byteShiftVal) & k_byteMask);
+ dataOut->dataCompressed[dataOutIdx++] = thisByte;
+ byteShiftVal -= 8;
+ }
+ }
+ }
+ dataOut->iqWidth = dataIn.iqWidth;
+}
+
+/// Reference expansion
+void
+BlockFloatCompanderBFW::BlockFloatExpand_Basic(const BlockFloatCompanderBFW::CompressedData& dataIn, BlockFloatCompanderBFW::ExpandedData* dataOut)
+{
+ uint32_t iqMask = (uint32_t)(UINT_MAX - ((1 << (32 - dataIn.iqWidth)) - 1));
+ uint32_t byteBuffer = { 0 };
+ int numBytesPerRB = (3 * dataIn.iqWidth) + 1;
+ int bitPointer = 0;
+ int dataIdxOut = 0;
+
+ for (int rb = 0; rb < BlockFloatCompanderBFW::k_numRB; ++rb)
+ {
+ auto expIdx = rb * numBytesPerRB;
+ auto signExtShift = 32 - dataIn.iqWidth - dataIn.dataCompressed[expIdx];
+
+ for (int b = 0; b < numBytesPerRB - 1; ++b)
+ {
+ auto dataIdxIn = (expIdx + 1) + b;
+ auto thisByte = (uint16_t)dataIn.dataCompressed[dataIdxIn];
+ byteBuffer = (uint32_t)((byteBuffer << 8) + thisByte);
+ bitPointer += 8;
+ while (bitPointer >= dataIn.iqWidth)
+ {
+ /// byteBuffer currently has enough data in it to extract a sample
+ /// Shift left first to set sign bit at MSB, then shift right to
+ /// sign extend down to iqWidth. Finally recast to int16.
+ int32_t thisSample32 = (int32_t)((byteBuffer << (32 - bitPointer)) & iqMask);
+ int16_t thisSample = (int16_t)(thisSample32 >> signExtShift);
+ bitPointer -= dataIn.iqWidth;
+ dataOut->dataExpanded[dataIdxOut++] = thisSample;
+ }
+ }
+ }
+}
+
+#define RB_NUM_ROUNDUP(rb) \
+ (BlockFloatCompander::k_numRB * ((rb + BlockFloatCompander::k_numRB - 1) / BlockFloatCompander::k_numRB))
+
+
+/** callback function type for Symbol packet */
+typedef void (*xran_bfp_compress_fn)(const BlockFloatCompander::ExpandedData& dataIn,
+ BlockFloatCompander::CompressedData* dataOut);
+
+int32_t
+xranlib_compress_avx512(const struct xranlib_compress_request *request,
+ struct xranlib_compress_response *response)
+{
+ BlockFloatCompander::ExpandedData expandedDataInput;
+ BlockFloatCompander::CompressedData compressedDataOut;
+ xran_bfp_compress_fn com_fn = NULL;
+ int16_t numRBs = request->numRBs;
+ int16_t len = 0;
+
+ switch (request->iqWidth){
+ case 8:
+ expandedDataInput.iqWidth = 8;
+ com_fn = BlockFloatCompander::BlockFloatCompress_8b_AVX512;
+ break;
+ case 9:
+ expandedDataInput.iqWidth = 9;
+ com_fn = BlockFloatCompander::BlockFloatCompress_9b_AVX512;
+ break;
+ case 10:
+ expandedDataInput.iqWidth = 10;
+ com_fn = BlockFloatCompander::BlockFloatCompress_10b_AVX512;
+ break;
+ case 12:
+ expandedDataInput.iqWidth = 12;
+ com_fn = BlockFloatCompander::BlockFloatCompress_12b_AVX512;
+ break;
+ default:
+ expandedDataInput.iqWidth = request->iqWidth;
+ com_fn = BlockFloatCompander::BlockFloatCompress_Basic;
+ break;
+ }
+
+ for (int16_t block_idx = 0;
+ block_idx < RB_NUM_ROUNDUP(numRBs)/BlockFloatCompander::k_numRB /*+ 1*/; /* 16 RBs at time */
+ block_idx++) {
+
+ expandedDataInput.dataExpanded =
+ &request->data_in[block_idx*BlockFloatCompander::k_numSampsExpanded];
+ compressedDataOut.dataCompressed =
+ (uint8_t*)&response->data_out[len];
+
+ com_fn(expandedDataInput, &compressedDataOut);
+ len += ((3 * expandedDataInput.iqWidth) + 1) * std::min((int16_t)BlockFloatCompander::k_numRB,(int16_t)numRBs);
+ }
+
+ response->len = ((3 * expandedDataInput.iqWidth) + 1) * numRBs;
+
+ return 0;
+}
+
+/** callback function type for Symbol packet */
+typedef void (*xran_bfp_compress_bfw_fn)(const BlockFloatCompanderBFW::ExpandedData& dataIn, BlockFloatCompanderBFW::CompressedData* dataOut);
+
+int32_t
+xranlib_compress_avx512_bfw(const struct xranlib_compress_request *request,
+ struct xranlib_compress_response *response)
+{
+ BlockFloatCompanderBFW::ExpandedData expandedDataInput;
+ BlockFloatCompanderBFW::CompressedData compressedDataKern;
+ xran_bfp_compress_bfw_fn com_fn = NULL;
+
+#if 0
+ for (int m = 0; m < BlockFloatCompander::k_numRB; ++m){
+ for (int n = 0; n < BlockFloatCompander::k_numREReal; ++n){
+ expandedDataInput.dataExpanded[m*BlockFloatCompander::k_numREReal+n] =
+ request->data_in[m*BlockFloatCompander::k_numREReal+n];
+ }
+ }
+#endif
+
+ expandedDataInput.dataExpanded = request->data_in;
+ compressedDataKern.dataCompressed = (uint8_t*)response->data_out;
+
+ com_fn = BlockFloatCompanderBFW::BlockFloatCompress_Basic;
+ switch (request->iqWidth){
+ case 8:
+ expandedDataInput.iqWidth = 8;
+ break;
+ case 9:
+ expandedDataInput.iqWidth = 9;
+ //com_fn = BlockFloatCompanderBFW::BlockFloatExpand_9b_AVX512
+ break;
+ case 10:
+ expandedDataInput.iqWidth = 10;
+ break;
+ case 12:
+ expandedDataInput.iqWidth = 12;
+ break;
+ default:
+ printf("bfwIqWidth is not supported %d\n", request->iqWidth);
+ return -1;
+ break;
+ }
+
+ com_fn(expandedDataInput, &compressedDataKern);
+ response->len = ((BlockFloatCompanderBFW::k_numRE/16*4*expandedDataInput.iqWidth)+1)*BlockFloatCompanderBFW::k_numRB;
+
+ return 0;
+}
+
+/** callback function type for Symbol packet */
+typedef void (*xran_bfp_decompress_fn)(const BlockFloatCompander::CompressedData& dataIn, BlockFloatCompander::ExpandedData* dataOut);
+
+
+int32_t
+xranlib_decompress_avx512(const struct xranlib_decompress_request *request,
+ struct xranlib_decompress_response *response)
+{
+
+ BlockFloatCompander::CompressedData compressedDataInput;
+ BlockFloatCompander::ExpandedData expandedDataOut;
+
+ xran_bfp_decompress_fn decom_fn = NULL;
+ int16_t numRBs = request->numRBs;
+ int16_t len = 0;
+
+ switch (request->iqWidth){
+ case 8:
+ compressedDataInput.iqWidth = 8;
+ decom_fn = BlockFloatCompander::BlockFloatExpand_8b_AVX512;
+ break;
+ case 9:
+ compressedDataInput.iqWidth = 9;
+ decom_fn = BlockFloatCompander::BlockFloatExpand_9b_AVX512;
+ break;
+ case 10:
+ compressedDataInput.iqWidth = 10;
+ decom_fn = BlockFloatCompander::BlockFloatExpand_10b_AVX512;
+ break;
+ case 12:
+ compressedDataInput.iqWidth = 12;
+ decom_fn = BlockFloatCompander::BlockFloatExpand_12b_AVX512;
+ break;
+ default:
+ compressedDataInput.iqWidth = request->iqWidth;
+ decom_fn = BlockFloatCompander::BlockFloatExpand_Basic;
+ break;
+ }
+
+ for (int16_t block_idx = 0;
+ block_idx < RB_NUM_ROUNDUP(numRBs)/BlockFloatCompander::k_numRB;
+ block_idx++) {
+
+ compressedDataInput.dataCompressed = (uint8_t*)&request->data_in[block_idx*(((3 * compressedDataInput.iqWidth ) + 1) * BlockFloatCompander::k_numRB)];
+ expandedDataOut.dataExpanded = &response->data_out[len];
+
+ decom_fn(compressedDataInput, &expandedDataOut);
+ len += std::min((int16_t)BlockFloatCompander::k_numSampsExpanded, (int16_t)(numRBs*BlockFloatCompander::k_numREReal));
+ }
+
+ response->len = numRBs * BlockFloatCompander::k_numREReal* sizeof(int16_t);
+
+ return 0;
+}