src/f32-bilinear/sse.c.in - platform/external/XNNPACK - Git at Google

 // Copyright 2019 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 CHANNEL_TILE % 4 == 0
 $assert CHANNEL_TILE >= 4
 $assert PIXEL_TILE == 1
 $ABC = "0123456789ABCDEFGHIJKLMN"
 #include <assert.h>

 #include <xmmintrin.h>

 #include <xnnpack/bilinear.h>


 void xnn_f32_bilinear_ukernel__sse_c${CHANNEL_TILE}${"" if PIXEL_TILE == 1 else "x%d" % PIXEL_TILE}(
     size_t output_pixels,
     size_t channels,
     const float**restrict input,
     size_t input_offset,
     const float*restrict weights,
     float*restrict output,
     size_t output_increment)
 {
   assert(output_pixels != 0);
   assert(channels != 0);
   assert(channels % sizeof(float) == 0);

   do {
     const float* i0 = (const float*) ((uintptr_t) input[0] + input_offset);
     const float* i1 = (const float*) ((uintptr_t) input[1] + input_offset);
     const float* i2 = (const float*) ((uintptr_t) input[2] + input_offset);
     const float* i3 = (const float*) ((uintptr_t) input[3] + input_offset);
     input += 4;

     __m128 valphahv = _mm_loadl_pi(_mm_undefined_ps(), (const __m64*) weights);
     valphahv = _mm_unpacklo_ps(valphahv, valphahv);
     const __m128 valphah = _mm_movelh_ps(valphahv, valphahv);
     const __m128 valphav = _mm_movehl_ps(valphahv, valphahv);
     weights += 2;

     size_t c = channels;
     for (; c >= ${CHANNEL_TILE} * sizeof(float); c -= ${CHANNEL_TILE} * sizeof(float)) {
       const __m128 vtl${ABC[0:4]} = _mm_loadu_ps(i0);
       const __m128 vtr${ABC[0:4]} = _mm_loadu_ps(i1);
       const __m128 vbl${ABC[0:4]} = _mm_loadu_ps(i2);
       const __m128 vbr${ABC[0:4]} = _mm_loadu_ps(i3);
       $for C in range(4, CHANNEL_TILE, 4):
         const __m128 vtl${ABC[C:C+4]} = _mm_loadu_ps(i0 + ${C});
         const __m128 vtr${ABC[C:C+4]} = _mm_loadu_ps(i1 + ${C});
         const __m128 vbl${ABC[C:C+4]} = _mm_loadu_ps(i2 + ${C});
         const __m128 vbr${ABC[C:C+4]} = _mm_loadu_ps(i3 + ${C});
       i0 += ${CHANNEL_TILE};
       i1 += ${CHANNEL_TILE};
       i2 += ${CHANNEL_TILE};
       i3 += ${CHANNEL_TILE};

       $for C in range(0, CHANNEL_TILE, 4):
         const __m128 vtd${ABC[C:C+4]} = _mm_sub_ps(vtr${ABC[C:C+4]}, vtl${ABC[C:C+4]});
         const __m128 vbd${ABC[C:C+4]} = _mm_sub_ps(vbr${ABC[C:C+4]}, vbl${ABC[C:C+4]});

       $for C in range(0, CHANNEL_TILE, 4):
         const __m128 vt${ABC[C:C+4]} = _mm_add_ps(vtl${ABC[C:C+4]}, _mm_mul_ps(vtd${ABC[C:C+4]}, valphah));
         const __m128 vb${ABC[C:C+4]} = _mm_add_ps(vbl${ABC[C:C+4]}, _mm_mul_ps(vbd${ABC[C:C+4]}, valphah));

       $for C in range(0, CHANNEL_TILE, 4):
         const __m128 vd${ABC[C:C+4]} = _mm_sub_ps(vb${ABC[C:C+4]}, vt${ABC[C:C+4]});

       $for C in range(0, CHANNEL_TILE, 4):
         const __m128 vo${ABC[C:C+4]} = _mm_add_ps(vt${ABC[C:C+4]}, _mm_mul_ps(vd${ABC[C:C+4]}, valphav));

       _mm_storeu_ps(output, vo${ABC[0:4]});
       $for C in range(4, CHANNEL_TILE, 4):
         _mm_storeu_ps(output + ${C}, vo${ABC[C:C+4]});
       output += ${CHANNEL_TILE};
     }
     $if CHANNEL_TILE > 4:
       for (; c >= 4 * sizeof(float); c -= 4 * sizeof(float)) {
         const __m128 vtl0123 = _mm_loadu_ps(i0);
         const __m128 vtr0123 = _mm_loadu_ps(i1);
         const __m128 vbl0123 = _mm_loadu_ps(i2);
         const __m128 vbr0123 = _mm_loadu_ps(i3);
         i0 += 4;
         i1 += 4;
         i2 += 4;
         i3 += 4;

         const __m128 vtd0123 = _mm_sub_ps(vtr0123, vtl0123);
         const __m128 vbd0123 = _mm_sub_ps(vbr0123, vbl0123);

         const __m128 vt0123 = _mm_add_ps(vtl0123, _mm_mul_ps(vtd0123, valphah));
         const __m128 vb0123 = _mm_add_ps(vbl0123, _mm_mul_ps(vbd0123, valphah));

         const __m128 vd0123 = _mm_sub_ps(vb0123, vt0123);

         const __m128 vo0123 = _mm_add_ps(vt0123, _mm_mul_ps(vd0123, valphav));

         _mm_storeu_ps(output, vo0123);
         output += 4;
       }
     if XNN_UNLIKELY(c != 0) {
       const __m128 vtl0123 = _mm_loadu_ps(i0);
       const __m128 vtr0123 = _mm_loadu_ps(i1);
       const __m128 vbl0123 = _mm_loadu_ps(i2);
       const __m128 vbr0123 = _mm_loadu_ps(i3);

       const __m128 vtd0123 = _mm_sub_ps(vtr0123, vtl0123);
       const __m128 vbd0123 = _mm_sub_ps(vbr0123, vbl0123);

       const __m128 vt0123 = _mm_add_ps(vtl0123, _mm_mul_ps(vtd0123, valphah));
       const __m128 vb0123 = _mm_add_ps(vbl0123, _mm_mul_ps(vbd0123, valphah));

       const __m128 vd0123 = _mm_sub_ps(vb0123, vt0123);

       __m128 vo0123 = _mm_add_ps(vt0123, _mm_mul_ps(vd0123, valphav));

       if (c & (2 * sizeof(float))) {
         _mm_storel_pi((__m64*) output, vo0123);
         vo0123 = _mm_movehl_ps(vo0123, vo0123);
         output += 2;
       }
       if (c & (1 * sizeof(float))) {
         _mm_store_ss(output, vo0123);
         output += 1;
       }
     }

     output = (float*) ((uintptr_t) output + output_increment);
   } while (--output_pixels != 0);
 }
	// Copyright 2019 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 CHANNEL_TILE % 4 == 0
	$assert CHANNEL_TILE >= 4
	$assert PIXEL_TILE == 1
	$ABC = "0123456789ABCDEFGHIJKLMN"
	#include <assert.h>

	#include <xmmintrin.h>

	#include <xnnpack/bilinear.h>


	void xnn_f32_bilinear_ukernel__sse_c${CHANNEL_TILE}${"" if PIXEL_TILE == 1 else "x%d" % PIXEL_TILE}(
	size_t output_pixels,
	size_t channels,
	const float**restrict input,
	size_t input_offset,
	const float*restrict weights,
	float*restrict output,
	size_t output_increment)
	{
	assert(output_pixels != 0);
	assert(channels != 0);
	assert(channels % sizeof(float) == 0);

	do {
	const float* i0 = (const float*) ((uintptr_t) input[0] + input_offset);
	const float* i1 = (const float*) ((uintptr_t) input[1] + input_offset);
	const float* i2 = (const float*) ((uintptr_t) input[2] + input_offset);
	const float* i3 = (const float*) ((uintptr_t) input[3] + input_offset);
	input += 4;

	__m128 valphahv = _mm_loadl_pi(_mm_undefined_ps(), (const __m64*) weights);
	valphahv = _mm_unpacklo_ps(valphahv, valphahv);
	const __m128 valphah = _mm_movelh_ps(valphahv, valphahv);
	const __m128 valphav = _mm_movehl_ps(valphahv, valphahv);
	weights += 2;

	size_t c = channels;
	for (; c >= ${CHANNEL_TILE} * sizeof(float); c -= ${CHANNEL_TILE} * sizeof(float)) {
	const __m128 vtl${ABC[0:4]} = _mm_loadu_ps(i0);
	const __m128 vtr${ABC[0:4]} = _mm_loadu_ps(i1);
	const __m128 vbl${ABC[0:4]} = _mm_loadu_ps(i2);
	const __m128 vbr${ABC[0:4]} = _mm_loadu_ps(i3);
	$for C in range(4, CHANNEL_TILE, 4):
	const __m128 vtl${ABC[C:C+4]} = _mm_loadu_ps(i0 + ${C});
	const __m128 vtr${ABC[C:C+4]} = _mm_loadu_ps(i1 + ${C});
	const __m128 vbl${ABC[C:C+4]} = _mm_loadu_ps(i2 + ${C});
	const __m128 vbr${ABC[C:C+4]} = _mm_loadu_ps(i3 + ${C});
	i0 += ${CHANNEL_TILE};
	i1 += ${CHANNEL_TILE};
	i2 += ${CHANNEL_TILE};
	i3 += ${CHANNEL_TILE};

	$for C in range(0, CHANNEL_TILE, 4):
	const __m128 vtd${ABC[C:C+4]} = _mm_sub_ps(vtr${ABC[C:C+4]}, vtl${ABC[C:C+4]});
	const __m128 vbd${ABC[C:C+4]} = _mm_sub_ps(vbr${ABC[C:C+4]}, vbl${ABC[C:C+4]});

	$for C in range(0, CHANNEL_TILE, 4):
	const __m128 vt${ABC[C:C+4]} = _mm_add_ps(vtl${ABC[C:C+4]}, _mm_mul_ps(vtd${ABC[C:C+4]}, valphah));
	const __m128 vb${ABC[C:C+4]} = _mm_add_ps(vbl${ABC[C:C+4]}, _mm_mul_ps(vbd${ABC[C:C+4]}, valphah));

	$for C in range(0, CHANNEL_TILE, 4):
	const __m128 vd${ABC[C:C+4]} = _mm_sub_ps(vb${ABC[C:C+4]}, vt${ABC[C:C+4]});

	$for C in range(0, CHANNEL_TILE, 4):
	const __m128 vo${ABC[C:C+4]} = _mm_add_ps(vt${ABC[C:C+4]}, _mm_mul_ps(vd${ABC[C:C+4]}, valphav));

	_mm_storeu_ps(output, vo${ABC[0:4]});
	$for C in range(4, CHANNEL_TILE, 4):
	_mm_storeu_ps(output + ${C}, vo${ABC[C:C+4]});
	output += ${CHANNEL_TILE};
	}
	$if CHANNEL_TILE > 4:
	for (; c >= 4 * sizeof(float); c -= 4 * sizeof(float)) {
	const __m128 vtl0123 = _mm_loadu_ps(i0);
	const __m128 vtr0123 = _mm_loadu_ps(i1);
	const __m128 vbl0123 = _mm_loadu_ps(i2);
	const __m128 vbr0123 = _mm_loadu_ps(i3);
	i0 += 4;
	i1 += 4;
	i2 += 4;
	i3 += 4;

	const __m128 vtd0123 = _mm_sub_ps(vtr0123, vtl0123);
	const __m128 vbd0123 = _mm_sub_ps(vbr0123, vbl0123);

	const __m128 vt0123 = _mm_add_ps(vtl0123, _mm_mul_ps(vtd0123, valphah));
	const __m128 vb0123 = _mm_add_ps(vbl0123, _mm_mul_ps(vbd0123, valphah));

	const __m128 vd0123 = _mm_sub_ps(vb0123, vt0123);

	const __m128 vo0123 = _mm_add_ps(vt0123, _mm_mul_ps(vd0123, valphav));

	_mm_storeu_ps(output, vo0123);
	output += 4;
	}
	if XNN_UNLIKELY(c != 0) {
	const __m128 vtl0123 = _mm_loadu_ps(i0);
	const __m128 vtr0123 = _mm_loadu_ps(i1);
	const __m128 vbl0123 = _mm_loadu_ps(i2);
	const __m128 vbr0123 = _mm_loadu_ps(i3);

	const __m128 vtd0123 = _mm_sub_ps(vtr0123, vtl0123);
	const __m128 vbd0123 = _mm_sub_ps(vbr0123, vbl0123);

	const __m128 vt0123 = _mm_add_ps(vtl0123, _mm_mul_ps(vtd0123, valphah));
	const __m128 vb0123 = _mm_add_ps(vbl0123, _mm_mul_ps(vbd0123, valphah));

	const __m128 vd0123 = _mm_sub_ps(vb0123, vt0123);

	__m128 vo0123 = _mm_add_ps(vt0123, _mm_mul_ps(vd0123, valphav));

	if (c & (2 * sizeof(float))) {
	_mm_storel_pi((__m64*) output, vo0123);
	vo0123 = _mm_movehl_ps(vo0123, vo0123);
	output += 2;
	}
	if (c & (1 * sizeof(float))) {
	_mm_store_ss(output, vo0123);
	output += 1;
	}
	}

	output = (float*) ((uintptr_t) output + output_increment);
	} while (--output_pixels != 0);
	}