src/qs8-vadd/sse-mul32-ld32.c.in - platform/external/XNNPACK - Git at Google

 // Copyright 2020 Google LLC
 //
 // This source code is licensed under the BSD-style license found in the
 // LICENSE file in the root directory of this source tree.

 $assert DATATYPE in ["QS8", "QU8"]
 $assert SSE == 4
 $assert not XOP or AVX
 $assert BATCH_TILE % 8 == 0
 $assert BATCH_TILE >= 8
 $ABC = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"
 #include <assert.h>

 $if XOP:
   #if defined(__GNUC__) || defined(__clang__)
     #include <x86intrin.h>
   #else
     #include <immintrin.h>
     #include <ammintrin.h>
   #endif
 $else:
   #include <immintrin.h>

 #include <xnnpack/intrinsics-polyfill.h>
 #include <xnnpack/unaligned.h>
 #include <xnnpack/vadd.h>


 $PARAMS_STRUCT = {"QS8": "sse4_mul32", "QU8": "sse4"}[DATATYPE]
 $XINT8_T = {"QS8": "int8_t", "QU8": "uint8_t"}[DATATYPE]
 $_MM_CVTEPX8_EPI32 = {"QS8": "_mm_cvtepi8_epi32", "QU8": "_mm_cvtepu8_epi32"}[DATATYPE]
 $_MM_PACKXS_EPI16 = {"QS8": "_mm_packs_epi16", "QU8": "_mm_packus_epi16"}[DATATYPE]
 $_MM_MIN_EPX8 = {"QS8": "_mm_min_epi8", "QU8": "_mm_min_epu8"}[DATATYPE]
 $_MM_MAX_EPX8 = {"QS8": "_mm_max_epi8", "QU8": "_mm_max_epu8"}[DATATYPE]
 $ISA = "xop" if XOP else "avx" if AVX else {4: "sse41"}[SSE]
 void xnn_${DATATYPE.lower()}_vadd_minmax_ukernel__${ISA}_mul32_ld32_x${BATCH_TILE}(
     size_t n,
     const ${XINT8_T}* input_a,
     const ${XINT8_T}* input_b,
     ${XINT8_T}* output,
     const union xnn_${DATATYPE.lower()}_add_minmax_params params[restrict XNN_MIN_ELEMENTS(1)]) XNN_OOB_READS
 {
   const __m128i vbias = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.bias);
   const __m128i va_multiplier = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.a_multiplier);
   const __m128i vb_multiplier = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.b_multiplier);
   const __m128i vshift = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.shift);
   const __m128i voutput_zero_point = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.output_zero_point);
   const __m128i voutput_min = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.output_min);
   const __m128i voutput_max = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.output_max);

   for (; n >= ${BATCH_TILE} * sizeof(${XINT8_T}); n -= ${BATCH_TILE} * sizeof(${XINT8_T})) {
     const __m128i va${ABC[0:4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_a)));
     const __m128i vb${ABC[0:4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_b)));
     $for N in range(4, BATCH_TILE, 4):
       const __m128i va${ABC[N:N+4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_a + ${N})));
       const __m128i vb${ABC[N:N+4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_b + ${N})));
     input_a += ${BATCH_TILE};
     input_b += ${BATCH_TILE};

     $if XOP:
       $for N in range(0, BATCH_TILE, 4):
         __m128i vacc${ABC[N:N+4]} = _mm_macc_epi32(va${ABC[N:N+4]}, va_multiplier, vbias);

       $for N in range(0, BATCH_TILE, 4):
         vacc${ABC[N:N+4]} = _mm_macc_epi32(vb${ABC[N:N+4]}, vb_multiplier, vacc${ABC[N:N+4]});
     $else:
       $for N in range(0, BATCH_TILE, 4):
         __m128i vacc${ABC[N:N+4]} = _mm_add_epi32(vbias, _mm_mullo_epi32(va${ABC[N:N+4]}, va_multiplier));

       $for N in range(0, BATCH_TILE, 4):
         vacc${ABC[N:N+4]} = _mm_add_epi32(vacc${ABC[N:N+4]}, _mm_mullo_epi32(vb${ABC[N:N+4]}, vb_multiplier));

     $for N in range(0, BATCH_TILE, 4):
       vacc${ABC[N:N+4]} = _mm_sra_epi32(vacc${ABC[N:N+4]}, vshift);

     $for N in range(0, BATCH_TILE, 8):
       const __m128i vout${ABC[N:N+8]} = _mm_adds_epi16(_mm_packs_epi32(vacc${ABC[N:N+4]}, vacc${ABC[N+4:N+8]}), voutput_zero_point);

     $for N in range(0, BATCH_TILE, 16):
       $if N + 8 < BATCH_TILE:
         __m128i vout${ABC[N:N+16]} = ${_MM_PACKXS_EPI16}(vout${ABC[N:N+8]}, vout${ABC[N+8:N+16]});
       $else:
         __m128i vout${ABC[N:N+8]}${ABC[N:N+8]} = ${_MM_PACKXS_EPI16}(vout${ABC[N:N+8]}, vout${ABC[N:N+8]});

     $for N in range(0, BATCH_TILE, 16):
       $if N + 8 < BATCH_TILE:
         vout${ABC[N:N+16]} = ${_MM_MAX_EPX8}(vout${ABC[N:N+16]}, voutput_min);
       $else:
         vout${ABC[N:N+8]}${ABC[N:N+8]} = ${_MM_MAX_EPX8}(vout${ABC[N:N+8]}${ABC[N:N+8]}, voutput_min);

     $for N in range(0, BATCH_TILE, 16):
       $if N + 8 < BATCH_TILE:
         vout${ABC[N:N+16]} = ${_MM_MIN_EPX8}(vout${ABC[N:N+16]}, voutput_max);
       $else:
         vout${ABC[N:N+8]}${ABC[N:N+8]} = ${_MM_MIN_EPX8}(vout${ABC[N:N+8]}${ABC[N:N+8]}, voutput_max);

     $if BATCH_TILE >= 16:
       _mm_storeu_si128((__m128i*) output, vout${ABC[0:16]});
     $else:
       _mm_storel_epi64((__m128i*) output, vout${ABC[0:8]}${ABC[0:8]});
     $for N in range(16, BATCH_TILE, 16):
       $if N + 8 < BATCH_TILE:
         _mm_storeu_si128((__m128i*) (output + ${N}), vout${ABC[N:N+16]});
       $else:
         _mm_storel_epi64((__m128i*) (output + ${N}), vout${ABC[N:N+8]}${ABC[N:N+8]});
     output += ${BATCH_TILE};
   }
   if XNN_UNLIKELY(n != 0) {
     ${"do " if BATCH_TILE > 8 else ""}{
       const __m128i va${ABC[0:4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_a)));
       const __m128i vb${ABC[0:4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_b)));
       const __m128i va${ABC[4:8]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_a + 4)));
       const __m128i vb${ABC[4:8]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_b + 4)));
       $if BATCH_TILE > 8:
         input_a += 8;
         input_b += 8;

       $if XOP:
         __m128i vacc${ABC[0:4]} = _mm_macc_epi32(va${ABC[0:4]}, va_multiplier, vbias);
         __m128i vacc${ABC[4:8]} = _mm_macc_epi32(va${ABC[4:8]}, va_multiplier, vbias);

         vacc${ABC[0:4]} = _mm_macc_epi32(vb${ABC[0:4]}, vb_multiplier, vacc${ABC[0:4]});
         vacc${ABC[4:8]} = _mm_macc_epi32(vb${ABC[4:8]}, vb_multiplier, vacc${ABC[4:8]});
       $else:
         __m128i vacc${ABC[0:4]} = _mm_add_epi32(vbias, _mm_mullo_epi32(va${ABC[0:4]}, va_multiplier));
         __m128i vacc${ABC[4:8]} = _mm_add_epi32(vbias, _mm_mullo_epi32(va${ABC[4:8]}, va_multiplier));

         vacc${ABC[0:4]} = _mm_add_epi32(vacc${ABC[0:4]}, _mm_mullo_epi32(vb${ABC[0:4]}, vb_multiplier));
         vacc${ABC[4:8]} = _mm_add_epi32(vacc${ABC[4:8]}, _mm_mullo_epi32(vb${ABC[4:8]}, vb_multiplier));

       vacc${ABC[0:4]} = _mm_sra_epi32(vacc${ABC[0:4]}, vshift);
       vacc${ABC[4:8]} = _mm_sra_epi32(vacc${ABC[4:8]}, vshift);

       const __m128i vout${ABC[0:8]} = _mm_adds_epi16(_mm_packs_epi32(vacc${ABC[0:4]}, vacc${ABC[4:8]}), voutput_zero_point);

       __m128i vout${ABC[0:8]}${ABC[0:8]} = ${_MM_PACKXS_EPI16}(vout${ABC[0:8]}, vout${ABC[0:8]});
       vout${ABC[0:8]}${ABC[0:8]} = ${_MM_MAX_EPX8}(vout${ABC[0:8]}${ABC[0:8]}, voutput_min);
       vout${ABC[0:8]}${ABC[0:8]} = ${_MM_MIN_EPX8}(vout${ABC[0:8]}${ABC[0:8]}, voutput_max);

       $if BATCH_TILE > 8:
         if XNN_LIKELY(n >= (8 * sizeof(${XINT8_T}))) {
           _mm_storel_epi64((__m128i*) output, vout${ABC[0:8]}${ABC[0:8]});
           output += 8;
           n -= 8 * sizeof(${XINT8_T});
         } else {
           if (n & (4 * sizeof(${XINT8_T}))) {
             unaligned_store_u32(output, (uint32_t) _mm_cvtsi128_si32(vout${ABC[0:8]}${ABC[0:8]}));
             vout${ABC[0:8]}${ABC[0:8]} = _mm_srli_epi64(vout${ABC[0:8]}${ABC[0:8]}, 32);
             output += 4;
           }
           if (n & (2 * sizeof(${XINT8_T}))) {
             unaligned_store_u16(output, (uint16_t) _mm_extract_epi16(vout${ABC[0:8]}${ABC[0:8]}, 0));
             vout${ABC[0:8]}${ABC[0:8]} = _mm_srli_epi32(vout${ABC[0:8]}${ABC[0:8]}, 16);
             output += 2;
           }
           if (n & (1 * sizeof(${XINT8_T}))) {
             *output = (${XINT8_T}) _mm_extract_epi8(vout${ABC[0:8]}${ABC[0:8]}, 0);
           }
           n = 0;
         }
       $else:
         if (n & (4 * sizeof(${XINT8_T}))) {
           unaligned_store_u32(output, (uint32_t) _mm_cvtsi128_si32(vout${ABC[0:8]}${ABC[0:8]}));
           vout${ABC[0:8]}${ABC[0:8]} = _mm_srli_epi64(vout${ABC[0:8]}${ABC[0:8]}, 32);
           output += 4;
         }
         if (n & (2 * sizeof(${XINT8_T}))) {
           unaligned_store_u16(output, (uint16_t) _mm_extract_epi16(vout${ABC[0:8]}${ABC[0:8]}, 0));
           vout${ABC[0:8]}${ABC[0:8]} = _mm_srli_epi32(vout${ABC[0:8]}${ABC[0:8]}, 16);
           output += 2;
         }
         if (n & (1 * sizeof(${XINT8_T}))) {
           *output = (${XINT8_T}) _mm_extract_epi8(vout${ABC[0:8]}${ABC[0:8]}, 0);
         }
     }${" while (n != 0);" if BATCH_TILE > 8 else ""}
   }
 }
	// Copyright 2020 Google LLC
	//
	// This source code is licensed under the BSD-style license found in the
	// LICENSE file in the root directory of this source tree.

	$assert DATATYPE in ["QS8", "QU8"]
	$assert SSE == 4
	$assert not XOP or AVX
	$assert BATCH_TILE % 8 == 0
	$assert BATCH_TILE >= 8
	$ABC = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"
	#include <assert.h>

	$if XOP:
	#if defined(__GNUC__) \|\| defined(__clang__)
	#include <x86intrin.h>
	#else
	#include <immintrin.h>
	#include <ammintrin.h>
	#endif
	$else:
	#include <immintrin.h>

	#include <xnnpack/intrinsics-polyfill.h>
	#include <xnnpack/unaligned.h>
	#include <xnnpack/vadd.h>


	$PARAMS_STRUCT = {"QS8": "sse4_mul32", "QU8": "sse4"}[DATATYPE]
	$XINT8_T = {"QS8": "int8_t", "QU8": "uint8_t"}[DATATYPE]
	$_MM_CVTEPX8_EPI32 = {"QS8": "_mm_cvtepi8_epi32", "QU8": "_mm_cvtepu8_epi32"}[DATATYPE]
	$_MM_PACKXS_EPI16 = {"QS8": "_mm_packs_epi16", "QU8": "_mm_packus_epi16"}[DATATYPE]
	$_MM_MIN_EPX8 = {"QS8": "_mm_min_epi8", "QU8": "_mm_min_epu8"}[DATATYPE]
	$_MM_MAX_EPX8 = {"QS8": "_mm_max_epi8", "QU8": "_mm_max_epu8"}[DATATYPE]
	$ISA = "xop" if XOP else "avx" if AVX else {4: "sse41"}[SSE]
	void xnn_${DATATYPE.lower()}_vadd_minmax_ukernel__${ISA}_mul32_ld32_x${BATCH_TILE}(
	size_t n,
	const ${XINT8_T}* input_a,
	const ${XINT8_T}* input_b,
	${XINT8_T}* output,
	const union xnn_${DATATYPE.lower()}_add_minmax_params params[restrict XNN_MIN_ELEMENTS(1)]) XNN_OOB_READS
	{
	const __m128i vbias = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.bias);
	const __m128i va_multiplier = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.a_multiplier);
	const __m128i vb_multiplier = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.b_multiplier);
	const __m128i vshift = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.shift);
	const __m128i voutput_zero_point = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.output_zero_point);
	const __m128i voutput_min = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.output_min);
	const __m128i voutput_max = _mm_load_si128((const __m128i*) params->${PARAMS_STRUCT}.output_max);

	for (; n >= ${BATCH_TILE} * sizeof(${XINT8_T}); n -= ${BATCH_TILE} * sizeof(${XINT8_T})) {
	const __m128i va${ABC[0:4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_a)));
	const __m128i vb${ABC[0:4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_b)));
	$for N in range(4, BATCH_TILE, 4):
	const __m128i va${ABC[N:N+4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_a + ${N})));
	const __m128i vb${ABC[N:N+4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_b + ${N})));
	input_a += ${BATCH_TILE};
	input_b += ${BATCH_TILE};

	$if XOP:
	$for N in range(0, BATCH_TILE, 4):
	__m128i vacc${ABC[N:N+4]} = _mm_macc_epi32(va${ABC[N:N+4]}, va_multiplier, vbias);

	$for N in range(0, BATCH_TILE, 4):
	vacc${ABC[N:N+4]} = _mm_macc_epi32(vb${ABC[N:N+4]}, vb_multiplier, vacc${ABC[N:N+4]});
	$else:
	$for N in range(0, BATCH_TILE, 4):
	__m128i vacc${ABC[N:N+4]} = _mm_add_epi32(vbias, _mm_mullo_epi32(va${ABC[N:N+4]}, va_multiplier));

	$for N in range(0, BATCH_TILE, 4):
	vacc${ABC[N:N+4]} = _mm_add_epi32(vacc${ABC[N:N+4]}, _mm_mullo_epi32(vb${ABC[N:N+4]}, vb_multiplier));

	$for N in range(0, BATCH_TILE, 4):
	vacc${ABC[N:N+4]} = _mm_sra_epi32(vacc${ABC[N:N+4]}, vshift);

	$for N in range(0, BATCH_TILE, 8):
	const __m128i vout${ABC[N:N+8]} = _mm_adds_epi16(_mm_packs_epi32(vacc${ABC[N:N+4]}, vacc${ABC[N+4:N+8]}), voutput_zero_point);

	$for N in range(0, BATCH_TILE, 16):
	$if N + 8 < BATCH_TILE:
	__m128i vout${ABC[N:N+16]} = ${_MM_PACKXS_EPI16}(vout${ABC[N:N+8]}, vout${ABC[N+8:N+16]});
	$else:
	__m128i vout${ABC[N:N+8]}${ABC[N:N+8]} = ${_MM_PACKXS_EPI16}(vout${ABC[N:N+8]}, vout${ABC[N:N+8]});

	$for N in range(0, BATCH_TILE, 16):
	$if N + 8 < BATCH_TILE:
	vout${ABC[N:N+16]} = ${_MM_MAX_EPX8}(vout${ABC[N:N+16]}, voutput_min);
	$else:
	vout${ABC[N:N+8]}${ABC[N:N+8]} = ${_MM_MAX_EPX8}(vout${ABC[N:N+8]}${ABC[N:N+8]}, voutput_min);

	$for N in range(0, BATCH_TILE, 16):
	$if N + 8 < BATCH_TILE:
	vout${ABC[N:N+16]} = ${_MM_MIN_EPX8}(vout${ABC[N:N+16]}, voutput_max);
	$else:
	vout${ABC[N:N+8]}${ABC[N:N+8]} = ${_MM_MIN_EPX8}(vout${ABC[N:N+8]}${ABC[N:N+8]}, voutput_max);

	$if BATCH_TILE >= 16:
	_mm_storeu_si128((__m128i*) output, vout${ABC[0:16]});
	$else:
	_mm_storel_epi64((__m128i*) output, vout${ABC[0:8]}${ABC[0:8]});
	$for N in range(16, BATCH_TILE, 16):
	$if N + 8 < BATCH_TILE:
	_mm_storeu_si128((__m128i*) (output + ${N}), vout${ABC[N:N+16]});
	$else:
	_mm_storel_epi64((__m128i*) (output + ${N}), vout${ABC[N:N+8]}${ABC[N:N+8]});
	output += ${BATCH_TILE};
	}
	if XNN_UNLIKELY(n != 0) {
	${"do " if BATCH_TILE > 8 else ""}{
	const __m128i va${ABC[0:4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_a)));
	const __m128i vb${ABC[0:4]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_b)));
	const __m128i va${ABC[4:8]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_a + 4)));
	const __m128i vb${ABC[4:8]} = ${_MM_CVTEPX8_EPI32}(_mm_cvtsi32_si128((int) unaligned_load_s32(input_b + 4)));
	$if BATCH_TILE > 8:
	input_a += 8;
	input_b += 8;

	$if XOP:
	__m128i vacc${ABC[0:4]} = _mm_macc_epi32(va${ABC[0:4]}, va_multiplier, vbias);
	__m128i vacc${ABC[4:8]} = _mm_macc_epi32(va${ABC[4:8]}, va_multiplier, vbias);

	vacc${ABC[0:4]} = _mm_macc_epi32(vb${ABC[0:4]}, vb_multiplier, vacc${ABC[0:4]});
	vacc${ABC[4:8]} = _mm_macc_epi32(vb${ABC[4:8]}, vb_multiplier, vacc${ABC[4:8]});
	$else:
	__m128i vacc${ABC[0:4]} = _mm_add_epi32(vbias, _mm_mullo_epi32(va${ABC[0:4]}, va_multiplier));
	__m128i vacc${ABC[4:8]} = _mm_add_epi32(vbias, _mm_mullo_epi32(va${ABC[4:8]}, va_multiplier));

	vacc${ABC[0:4]} = _mm_add_epi32(vacc${ABC[0:4]}, _mm_mullo_epi32(vb${ABC[0:4]}, vb_multiplier));
	vacc${ABC[4:8]} = _mm_add_epi32(vacc${ABC[4:8]}, _mm_mullo_epi32(vb${ABC[4:8]}, vb_multiplier));

	vacc${ABC[0:4]} = _mm_sra_epi32(vacc${ABC[0:4]}, vshift);
	vacc${ABC[4:8]} = _mm_sra_epi32(vacc${ABC[4:8]}, vshift);

	const __m128i vout${ABC[0:8]} = _mm_adds_epi16(_mm_packs_epi32(vacc${ABC[0:4]}, vacc${ABC[4:8]}), voutput_zero_point);

	__m128i vout${ABC[0:8]}${ABC[0:8]} = ${_MM_PACKXS_EPI16}(vout${ABC[0:8]}, vout${ABC[0:8]});
	vout${ABC[0:8]}${ABC[0:8]} = ${_MM_MAX_EPX8}(vout${ABC[0:8]}${ABC[0:8]}, voutput_min);
	vout${ABC[0:8]}${ABC[0:8]} = ${_MM_MIN_EPX8}(vout${ABC[0:8]}${ABC[0:8]}, voutput_max);

	$if BATCH_TILE > 8:
	if XNN_LIKELY(n >= (8 * sizeof(${XINT8_T}))) {
	_mm_storel_epi64((__m128i*) output, vout${ABC[0:8]}${ABC[0:8]});
	output += 8;
	n -= 8 * sizeof(${XINT8_T});
	} else {
	if (n & (4 * sizeof(${XINT8_T}))) {
	unaligned_store_u32(output, (uint32_t) _mm_cvtsi128_si32(vout${ABC[0:8]}${ABC[0:8]}));
	vout${ABC[0:8]}${ABC[0:8]} = _mm_srli_epi64(vout${ABC[0:8]}${ABC[0:8]}, 32);
	output += 4;
	}
	if (n & (2 * sizeof(${XINT8_T}))) {
	unaligned_store_u16(output, (uint16_t) _mm_extract_epi16(vout${ABC[0:8]}${ABC[0:8]}, 0));
	vout${ABC[0:8]}${ABC[0:8]} = _mm_srli_epi32(vout${ABC[0:8]}${ABC[0:8]}, 16);
	output += 2;
	}
	if (n & (1 * sizeof(${XINT8_T}))) {
	*output = (${XINT8_T}) _mm_extract_epi8(vout${ABC[0:8]}${ABC[0:8]}, 0);
	}
	n = 0;
	}
	$else:
	if (n & (4 * sizeof(${XINT8_T}))) {
	unaligned_store_u32(output, (uint32_t) _mm_cvtsi128_si32(vout${ABC[0:8]}${ABC[0:8]}));
	vout${ABC[0:8]}${ABC[0:8]} = _mm_srli_epi64(vout${ABC[0:8]}${ABC[0:8]}, 32);
	output += 4;
	}
	if (n & (2 * sizeof(${XINT8_T}))) {
	unaligned_store_u16(output, (uint16_t) _mm_extract_epi16(vout${ABC[0:8]}${ABC[0:8]}, 0));
	vout${ABC[0:8]}${ABC[0:8]} = _mm_srli_epi32(vout${ABC[0:8]}${ABC[0:8]}, 16);
	output += 2;
	}
	if (n & (1 * sizeof(${XINT8_T}))) {
	*output = (${XINT8_T}) _mm_extract_epi8(vout${ABC[0:8]}${ABC[0:8]}, 0);
	}
	}${" while (n != 0);" if BATCH_TILE > 8 else ""}
	}
	}