src/bf16-gemm/c2-neonbf16-bfdot-lane-ld128.c.in - platform/external/XNNPACK - Git at Google

 // Copyright 2022 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 NR % 4 == 0
 $ABC = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"

 #include <assert.h>

 #include <arm_neon.h>

 #include <xnnpack/gemm.h>


 void xnn_bf16_gemm_minmax_ukernel_${MR}x${NR}c2__neonbf16_bfdot_lane_ld128(
     size_t mr,
     size_t nc,
     size_t kc,
     const void* restrict a,
     size_t a_stride,
     const void* restrict w_ptr,
     void* restrict c,
     size_t cm_stride,
     size_t cn_stride,
     const union xnn_bf16_minmax_params params[restrict XNN_MIN_ELEMENTS(1)])
 {
   assert(mr != 0);
   assert(mr <= ${MR});
   assert(nc != 0);
   assert(kc != 0);
   assert(kc % sizeof(bfloat16_t) == 0);
   assert(a != NULL);
   assert(w_ptr != NULL);
   assert(c != NULL);

   const bfloat16_t* a0 = (const bfloat16_t*) a;
   bfloat16_t* c0 = (bfloat16_t*) c;
   $for M in range(1, MR):
     const bfloat16_t* a${M} = (const bfloat16_t*) ((uintptr_t) a${M-1} + a_stride);
     bfloat16_t* c${M} = (bfloat16_t*) ((uintptr_t) c${M-1} + cm_stride);
     $if M % 2 == 0:
       if XNN_UNPREDICTABLE(mr <= ${M}) {
         a${M} = a${M-1};
         c${M} = c${M-1};
       }
     $elif M + 1 == MR:
       if XNN_UNPREDICTABLE(mr != ${M+1}) {
         a${M} = a${M-1};
         c${M} = c${M-1};
       }
     $else:
       if XNN_UNPREDICTABLE(mr < ${M+1}) {
         a${M} = a${M-1};
         c${M} = c${M-1};
       }

   const bfloat16_t* w = (const bfloat16_t*) w_ptr;
   do {
     $for N in range(0, NR, 4):
       float32x4_t vacc0x${ABC[N:N+4]} = vcvt_f32_bf16(vld1_bf16(w)); w += 4;
     $for M in range(1, MR):
       $for N in range(0, NR, 4):
         float32x4_t vacc${M}x${ABC[N:N+4]} = vacc0x${ABC[N:N+4]};

     size_t k = kc;
     for (; k >= 8 * sizeof(bfloat16_t); k -= 8 * sizeof(bfloat16_t)) {
       $for M in range(MR):
         const bfloat16x8_t va${M} = vld1q_bf16(a${M}); a${M} += 8;

       $for K in range(4):
         $for N in range(0, NR, 4):
           const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[2*K:2*K+2]} = vld1q_bf16(w); w += 8;

         $for N in range(0, NR, 4):
           $for M in range(MR):
             vacc${M}x${ABC[N:N+4]} = vbfdotq_laneq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[2*K:2*K+2]}, va${M}, ${K});
     }
     if XNN_UNLIKELY(k != 0) {
       $for M in range(MR):
         const bfloat16x8_t va${M} = vld1q_bf16(a${M}); a${M} = (const bfloat16_t*) ((uintptr_t) a${M} + k);

       $for N in range(0, NR, 4):
         const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[0:2]} = vld1q_bf16(w); w += 8;

       $for M in range(MR):
         const uint32x4_t va${M}c${ABC[0:2]} = vdupq_lane_u32(vreinterpret_u32_bf16(vget_low_bf16(va${M})), 0);

       $for N in range(0, NR, 4):
         const uint32x4_t vm${ABC[N:N+4]}c${ABC[0:2]} = vreinterpretq_u32_u16(vceqq_u16(vreinterpretq_u16_bf16(vb${ABC[N:N+4]}c${ABC[0:2]}), vmovq_n_u16(0)));

       $for N in range(0, NR, 4):
         $for M in range(MR):
           const uint32x4_t va${M}x${ABC[N:N+4]}c${ABC[0:2]} = vbicq_u32(va${M}c${ABC[0:2]}, vm${ABC[N:N+4]}c${ABC[0:2]});
           vacc${M}x${ABC[N:N+4]} = vbfdotq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[0:2]}, vreinterpretq_bf16_u32(va${M}x${ABC[N:N+4]}c${ABC[0:2]}));

       if (k > 2 * sizeof(bfloat16_t)) {
         $for N in range(0, NR, 4):
           const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[2:4]} = vld1q_bf16(w); w += 8;

         $for M in range(MR):
           const uint32x4_t va${M}c${ABC[2:4]} = vdupq_lane_u32(vreinterpret_u32_bf16(vget_low_bf16(va${M})), 1);

         $for N in range(0, NR, 4):
           const uint32x4_t vm${ABC[N:N+4]}c${ABC[2:4]} = vreinterpretq_u32_u16(vceqq_u16(vreinterpretq_u16_bf16(vb${ABC[N:N+4]}c${ABC[2:4]}), vmovq_n_u16(0)));

         $for N in range(0, NR, 4):
           $for M in range(MR):
             const uint32x4_t va${M}x${ABC[N:N+4]}c${ABC[2:4]} = vbicq_u32(va${M}c${ABC[2:4]}, vm${ABC[N:N+4]}c${ABC[2:4]});
             vacc${M}x${ABC[N:N+4]} = vbfdotq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[2:4]}, vreinterpretq_bf16_u32(va${M}x${ABC[N:N+4]}c${ABC[2:4]}));

         if (k > 4 * sizeof(bfloat16_t)) {
           $for N in range(0, NR, 4):
             const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[4:6]} = vld1q_bf16(w); w += 8;

           $for M in range(MR):
             const uint32x4_t va${M}c${ABC[4:6]} = vdupq_lane_u32(vreinterpret_u32_bf16(vget_high_bf16(va${M})), 0);

           $for N in range(0, NR, 4):
             const uint32x4_t vm${ABC[N:N+4]}c${ABC[4:6]} = vreinterpretq_u32_u16(vceqq_u16(vreinterpretq_u16_bf16(vb${ABC[N:N+4]}c${ABC[4:6]}), vmovq_n_u16(0)));

           $for N in range(0, NR, 4):
             $for M in range(MR):
               const uint32x4_t va${M}x${ABC[N:N+4]}c${ABC[4:6]} = vbicq_u32(va${M}c${ABC[4:6]}, vm${ABC[N:N+4]}c${ABC[4:6]});
               vacc${M}x${ABC[N:N+4]} = vbfdotq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[4:6]}, vreinterpretq_bf16_u32(va${M}x${ABC[N:N+4]}c${ABC[4:6]}));

           if (k > 6 * sizeof(bfloat16_t)) {
             $for N in range(0, NR, 4):
               const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[6:8]} = vld1q_bf16(w); w += 8;

             $for M in range(MR):
               const uint32x4_t va${M}c${ABC[6:8]} = vdupq_lane_u32(vreinterpret_u32_bf16(vget_high_bf16(va${M})), 1);

             $for N in range(0, NR, 4):
               const uint32x4_t vm${ABC[N:N+4]}c${ABC[6:8]} = vreinterpretq_u32_u16(vceqq_u16(vreinterpretq_u16_bf16(vb${ABC[N:N+4]}c${ABC[6:8]}), vmovq_n_u16(0)));

             $for N in range(0, NR, 4):
               $for M in range(MR):
                 const uint32x4_t va${M}x${ABC[N:N+4]}c${ABC[6:8]} = vbicq_u32(va${M}c${ABC[6:8]}, vm${ABC[N:N+4]}c${ABC[6:8]});
                 vacc${M}x${ABC[N:N+4]} = vbfdotq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[6:8]}, vreinterpretq_bf16_u32(va${M}x${ABC[N:N+4]}c${ABC[6:8]}));
           }
         }
       }
     }

     const float32x4_t vmax = vld1q_dup_f32(&params->scalar.max);
     $for N in range(0, NR, 4):
       $for M in range(MR):
         vacc${M}x${ABC[N:N+4]} = vminq_f32(vacc${M}x${ABC[N:N+4]}, vmax);

     const float32x4_t vmin = vld1q_dup_f32(&params->scalar.min);
     $for N in range(0, NR, 4):
       $for M in range(MR):
         vacc${M}x${ABC[N:N+4]} = vmaxq_f32(vacc${M}x${ABC[N:N+4]}, vmin);

     $for N in range(0, NR, 4):
       $for M in range(MR):
         bfloat16x4_t vout${M}x${ABC[N:N+4]} = vcvt_bf16_f32(vacc${M}x${ABC[N:N+4]});

     if XNN_LIKELY(nc >= ${NR}) {
       $for M in range(MR):
         vst1_bf16(c${M}, vout${M}x${ABC[0:4]});
         $for N in range(4, NR, 4):
           vst1_bf16(c${M} + ${N}, vout${M}x${ABC[N:N+4]});
         c${M} = (bfloat16_t*) ((uintptr_t) c${M} + cn_stride);

       $for M in range(MR):
         a${M} = (const bfloat16_t*) ((uintptr_t) a${M} - kc);

       nc -= ${NR};
     } else {
       $for LOG2N in reversed(range(NR.bit_length())):
         $if NR != 1 << LOG2N:
           if (nc & ${1 << LOG2N}) {
             $if LOG2N >= 2:
               $for N in range(0, 1 << LOG2N, 4):
                 $for M in range(MR):
                   vst1_bf16(c${M}, vout${M}x${ABC[N:N+4]}); c${M} += 4;

               $for M in range(MR):
                 $for N in range(0, 1 << (LOG2N - 1), 4):
                   vout${M}x${ABC[N:N+4]} = vout${M}x${ABC[N + (1 << LOG2N):N + (1 << LOG2N)+4]};
             $elif LOG2N == 1:
               $for M in range(MR):
                 vst1_lane_u32((void*) c${M}, vreinterpret_u32_bf16(vout${M}x${ABC[0:4]}), 0); c${M} += 2;

               $for M in range(MR):
                 vout${M}x${ABC[0:4]} = vreinterpret_bf16_u16(vext_u16(vreinterpret_u16_bf16(vout${M}x${ABC[0:4]}), vreinterpret_u16_bf16(vout${M}x${ABC[0:4]}), 2));
             $elif LOG2N == 0:
               $for M in range(MR):
                 vst1_lane_bf16(c${M}, vout${M}x${ABC[0:4]}, 0);
           }

       nc = 0;
     }
   } while (nc != 0);
 }
	// Copyright 2022 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 NR % 4 == 0
	$ABC = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"

	#include <assert.h>

	#include <arm_neon.h>

	#include <xnnpack/gemm.h>


	void xnn_bf16_gemm_minmax_ukernel_${MR}x${NR}c2__neonbf16_bfdot_lane_ld128(
	size_t mr,
	size_t nc,
	size_t kc,
	const void* restrict a,
	size_t a_stride,
	const void* restrict w_ptr,
	void* restrict c,
	size_t cm_stride,
	size_t cn_stride,
	const union xnn_bf16_minmax_params params[restrict XNN_MIN_ELEMENTS(1)])
	{
	assert(mr != 0);
	assert(mr <= ${MR});
	assert(nc != 0);
	assert(kc != 0);
	assert(kc % sizeof(bfloat16_t) == 0);
	assert(a != NULL);
	assert(w_ptr != NULL);
	assert(c != NULL);

	const bfloat16_t* a0 = (const bfloat16_t*) a;
	bfloat16_t* c0 = (bfloat16_t*) c;
	$for M in range(1, MR):
	const bfloat16_t* a${M} = (const bfloat16_t*) ((uintptr_t) a${M-1} + a_stride);
	bfloat16_t* c${M} = (bfloat16_t*) ((uintptr_t) c${M-1} + cm_stride);
	$if M % 2 == 0:
	if XNN_UNPREDICTABLE(mr <= ${M}) {
	a${M} = a${M-1};
	c${M} = c${M-1};
	}
	$elif M + 1 == MR:
	if XNN_UNPREDICTABLE(mr != ${M+1}) {
	a${M} = a${M-1};
	c${M} = c${M-1};
	}
	$else:
	if XNN_UNPREDICTABLE(mr < ${M+1}) {
	a${M} = a${M-1};
	c${M} = c${M-1};
	}

	const bfloat16_t* w = (const bfloat16_t*) w_ptr;
	do {
	$for N in range(0, NR, 4):
	float32x4_t vacc0x${ABC[N:N+4]} = vcvt_f32_bf16(vld1_bf16(w)); w += 4;
	$for M in range(1, MR):
	$for N in range(0, NR, 4):
	float32x4_t vacc${M}x${ABC[N:N+4]} = vacc0x${ABC[N:N+4]};

	size_t k = kc;
	for (; k >= 8 * sizeof(bfloat16_t); k -= 8 * sizeof(bfloat16_t)) {
	$for M in range(MR):
	const bfloat16x8_t va${M} = vld1q_bf16(a${M}); a${M} += 8;

	$for K in range(4):
	$for N in range(0, NR, 4):
	const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[2K:2K+2]} = vld1q_bf16(w); w += 8;

	$for N in range(0, NR, 4):
	$for M in range(MR):
	vacc${M}x${ABC[N:N+4]} = vbfdotq_laneq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[2K:2K+2]}, va${M}, ${K});
	}
	if XNN_UNLIKELY(k != 0) {
	$for M in range(MR):
	const bfloat16x8_t va${M} = vld1q_bf16(a${M}); a${M} = (const bfloat16_t*) ((uintptr_t) a${M} + k);

	$for N in range(0, NR, 4):
	const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[0:2]} = vld1q_bf16(w); w += 8;

	$for M in range(MR):
	const uint32x4_t va${M}c${ABC[0:2]} = vdupq_lane_u32(vreinterpret_u32_bf16(vget_low_bf16(va${M})), 0);

	$for N in range(0, NR, 4):
	const uint32x4_t vm${ABC[N:N+4]}c${ABC[0:2]} = vreinterpretq_u32_u16(vceqq_u16(vreinterpretq_u16_bf16(vb${ABC[N:N+4]}c${ABC[0:2]}), vmovq_n_u16(0)));

	$for N in range(0, NR, 4):
	$for M in range(MR):
	const uint32x4_t va${M}x${ABC[N:N+4]}c${ABC[0:2]} = vbicq_u32(va${M}c${ABC[0:2]}, vm${ABC[N:N+4]}c${ABC[0:2]});
	vacc${M}x${ABC[N:N+4]} = vbfdotq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[0:2]}, vreinterpretq_bf16_u32(va${M}x${ABC[N:N+4]}c${ABC[0:2]}));

	if (k > 2 * sizeof(bfloat16_t)) {
	$for N in range(0, NR, 4):
	const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[2:4]} = vld1q_bf16(w); w += 8;

	$for M in range(MR):
	const uint32x4_t va${M}c${ABC[2:4]} = vdupq_lane_u32(vreinterpret_u32_bf16(vget_low_bf16(va${M})), 1);

	$for N in range(0, NR, 4):
	const uint32x4_t vm${ABC[N:N+4]}c${ABC[2:4]} = vreinterpretq_u32_u16(vceqq_u16(vreinterpretq_u16_bf16(vb${ABC[N:N+4]}c${ABC[2:4]}), vmovq_n_u16(0)));

	$for N in range(0, NR, 4):
	$for M in range(MR):
	const uint32x4_t va${M}x${ABC[N:N+4]}c${ABC[2:4]} = vbicq_u32(va${M}c${ABC[2:4]}, vm${ABC[N:N+4]}c${ABC[2:4]});
	vacc${M}x${ABC[N:N+4]} = vbfdotq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[2:4]}, vreinterpretq_bf16_u32(va${M}x${ABC[N:N+4]}c${ABC[2:4]}));

	if (k > 4 * sizeof(bfloat16_t)) {
	$for N in range(0, NR, 4):
	const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[4:6]} = vld1q_bf16(w); w += 8;

	$for M in range(MR):
	const uint32x4_t va${M}c${ABC[4:6]} = vdupq_lane_u32(vreinterpret_u32_bf16(vget_high_bf16(va${M})), 0);

	$for N in range(0, NR, 4):
	const uint32x4_t vm${ABC[N:N+4]}c${ABC[4:6]} = vreinterpretq_u32_u16(vceqq_u16(vreinterpretq_u16_bf16(vb${ABC[N:N+4]}c${ABC[4:6]}), vmovq_n_u16(0)));

	$for N in range(0, NR, 4):
	$for M in range(MR):
	const uint32x4_t va${M}x${ABC[N:N+4]}c${ABC[4:6]} = vbicq_u32(va${M}c${ABC[4:6]}, vm${ABC[N:N+4]}c${ABC[4:6]});
	vacc${M}x${ABC[N:N+4]} = vbfdotq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[4:6]}, vreinterpretq_bf16_u32(va${M}x${ABC[N:N+4]}c${ABC[4:6]}));

	if (k > 6 * sizeof(bfloat16_t)) {
	$for N in range(0, NR, 4):
	const bfloat16x8_t vb${ABC[N:N+4]}c${ABC[6:8]} = vld1q_bf16(w); w += 8;

	$for M in range(MR):
	const uint32x4_t va${M}c${ABC[6:8]} = vdupq_lane_u32(vreinterpret_u32_bf16(vget_high_bf16(va${M})), 1);

	$for N in range(0, NR, 4):
	const uint32x4_t vm${ABC[N:N+4]}c${ABC[6:8]} = vreinterpretq_u32_u16(vceqq_u16(vreinterpretq_u16_bf16(vb${ABC[N:N+4]}c${ABC[6:8]}), vmovq_n_u16(0)));

	$for N in range(0, NR, 4):
	$for M in range(MR):
	const uint32x4_t va${M}x${ABC[N:N+4]}c${ABC[6:8]} = vbicq_u32(va${M}c${ABC[6:8]}, vm${ABC[N:N+4]}c${ABC[6:8]});
	vacc${M}x${ABC[N:N+4]} = vbfdotq_f32(vacc${M}x${ABC[N:N+4]}, vb${ABC[N:N+4]}c${ABC[6:8]}, vreinterpretq_bf16_u32(va${M}x${ABC[N:N+4]}c${ABC[6:8]}));
	}
	}
	}
	}

	const float32x4_t vmax = vld1q_dup_f32(&params->scalar.max);
	$for N in range(0, NR, 4):
	$for M in range(MR):
	vacc${M}x${ABC[N:N+4]} = vminq_f32(vacc${M}x${ABC[N:N+4]}, vmax);

	const float32x4_t vmin = vld1q_dup_f32(&params->scalar.min);
	$for N in range(0, NR, 4):
	$for M in range(MR):
	vacc${M}x${ABC[N:N+4]} = vmaxq_f32(vacc${M}x${ABC[N:N+4]}, vmin);

	$for N in range(0, NR, 4):
	$for M in range(MR):
	bfloat16x4_t vout${M}x${ABC[N:N+4]} = vcvt_bf16_f32(vacc${M}x${ABC[N:N+4]});

	if XNN_LIKELY(nc >= ${NR}) {
	$for M in range(MR):
	vst1_bf16(c${M}, vout${M}x${ABC[0:4]});
	$for N in range(4, NR, 4):
	vst1_bf16(c${M} + ${N}, vout${M}x${ABC[N:N+4]});
	c${M} = (bfloat16_t*) ((uintptr_t) c${M} + cn_stride);

	$for M in range(MR):
	a${M} = (const bfloat16_t*) ((uintptr_t) a${M} - kc);

	nc -= ${NR};
	} else {
	$for LOG2N in reversed(range(NR.bit_length())):
	$if NR != 1 << LOG2N:
	if (nc & ${1 << LOG2N}) {
	$if LOG2N >= 2:
	$for N in range(0, 1 << LOG2N, 4):
	$for M in range(MR):
	vst1_bf16(c${M}, vout${M}x${ABC[N:N+4]}); c${M} += 4;

	$for M in range(MR):
	$for N in range(0, 1 << (LOG2N - 1), 4):
	vout${M}x${ABC[N:N+4]} = vout${M}x${ABC[N + (1 << LOG2N):N + (1 << LOG2N)+4]};
	$elif LOG2N == 1:
	$for M in range(MR):
	vst1_lane_u32((void*) c${M}, vreinterpret_u32_bf16(vout${M}x${ABC[0:4]}), 0); c${M} += 2;

	$for M in range(MR):
	vout${M}x${ABC[0:4]} = vreinterpret_bf16_u16(vext_u16(vreinterpret_u16_bf16(vout${M}x${ABC[0:4]}), vreinterpret_u16_bf16(vout${M}x${ABC[0:4]}), 2));
	$elif LOG2N == 0:
	$for M in range(MR):
	vst1_lane_bf16(c${M}, vout${M}x${ABC[0:4]}, 0);
	}

	nc = 0;
	}
	} while (nc != 0);
	}