// Copyright 2023 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 ["QC8", "QD8", "QS8"] $assert DATATYPE == "QD8" or REQUANTIZATION == "FP32" $assert DATATYPE != "QD8" or not REQUANTIZATION $assert MR <= 4 $assert NR == 4 or NR == 8 $assert (SDOT == 0 and DATATYPE == "QC8") or SDOT == 1 #include #include #include "xnnpack/gemm.h" #include "xnnpack/math.h" $ABC = "012345678" $DATATYPE_SPEC = {"QC8": "qs8_qc8w", "QD8": "qd8_f32_qc8w", "QS8": "qs8"}[DATATYPE] $REQUANTIZATION_SPEC = "_" + REQUANTIZATION.lower() if REQUANTIZATION else "" $PARAMS_TYPE = {"QC8": "union xnn_qs8_qc8w_conv_minmax_params", "QD8": "union xnn_f32_minmax_params", "QS8": "union xnn_qs8_conv_minmax_params"}[DATATYPE] $OUT_T = "float" if DATATYPE == "QD8" else "int8_t" void xnn_${DATATYPE_SPEC}_igemm_minmax${REQUANTIZATION_SPEC}_ukernel_${MR}x${NR}c16__wasm${"sdot" if SDOT else "usdot"}( size_t mr, size_t nc, size_t kc, size_t ks, const int8_t** restrict a, const void* restrict w, ${OUT_T}* restrict c, size_t cm_stride, size_t cn_stride, size_t a_offset, const int8_t* zero, $if DATATYPE in ["QD8"]: const int8_t* zero_data, const ${PARAMS_TYPE} params[restrict XNN_MIN_ELEMENTS(1)], const struct xnn_qd8_quantization_params quantization_params[restrict XNN_MIN_ELEMENTS(1)]) XNN_OOB_READS $else: const ${PARAMS_TYPE} params[restrict XNN_MIN_ELEMENTS(1)]) XNN_OOB_READS { assert(mr != 0); assert(mr <= ${MR}); assert(nc != 0); assert(kc != 0); assert(ks != 0); assert(ks % (${MR} * sizeof(void*)) == 0); assert(a_offset % sizeof(int8_t) == 0); assert(a != NULL); assert(w != NULL); assert(c != NULL); kc = round_up_po2(kc, 16 * sizeof(int8_t)); ${OUT_T}* c0 = c; $for M in range(1, MR): ${OUT_T}* c${M} = (${OUT_T}*) ((uintptr_t) c${M-1} + cm_stride); $if M % 2 == 0: if XNN_UNPREDICTABLE(mr <= ${M}) { c${M} = c${M-1}; } $elif M + 1 == MR: if XNN_UNPREDICTABLE(mr != ${M+1}) { c${M} = c${M-1}; } $else: if XNN_UNPREDICTABLE(mr < ${M+1}) { c${M} = c${M-1}; } $if DATATYPE == "QD8": const v128_t vmin = wasm_v128_load32_splat(¶ms->scalar.min); const v128_t vmax = wasm_v128_load32_splat(¶ms->scalar.max); XNN_FORCE_REALIZATION(vmin); XNN_FORCE_REALIZATION(vmax); $else: $if DATATYPE != "QC8": const v128_t vscale = wasm_v128_load32_splat(¶ms->fp32_scalar.scale); XNN_FORCE_REALIZATION(vscale); const v128_t vmagic_bias = wasm_f32x4_const_splat(12582912.0f); const int32_t output_min_less_zero_point = (int32_t) params->fp32_scalar.output_min - (int32_t) params->fp32_scalar.output_zero_point; const v128_t vmagic_min = wasm_i32x4_splat((int32_t) float_as_uint32(12582912.0f + output_min_less_zero_point)); const v128_t vmagic_bias_less_output_zero_point = wasm_i32x4_splat(INT32_C(0x4B400000) - (int32_t) params->fp32_scalar.output_zero_point); const v128_t voutput_max = wasm_i8x16_splat(params->fp32_scalar.output_max); XNN_FORCE_REALIZATION(vmagic_bias); XNN_FORCE_REALIZATION(vmagic_min); XNN_FORCE_REALIZATION(vmagic_bias_less_output_zero_point); XNN_FORCE_REALIZATION(voutput_max); $if not SDOT: const v128_t vsign_mask = wasm_u8x16_const_splat(UINT8_C(0x80)); XNN_FORCE_REALIZATION(vsign_mask); do { $if DATATYPE == "QD8": $assert NR != 8 $assert SDOT == 1 v128_t vksum0 = wasm_v128_load32_zero(w); $for N in range(1, NR): v128_t vksum${N} = wasm_v128_load32_zero((const int32_t*) w + ${N}); const v128_t vinput_zero_point = wasm_v128_load32_splat(&quantization_params->zero_point); $for M in range(MR): $for N in range(NR): v128_t vacc${M}x${N} = wasm_i32x4_mul(vksum${N}, vinput_zero_point); $else: v128_t vacc0x0 = wasm_v128_load32_zero(w); $for N in range(1, NR): v128_t vacc0x${N} = wasm_v128_load32_zero((const int32_t*) w + ${N}); $for M in range(1, MR): $for N in range(NR): v128_t vacc${M}x${N} = vacc0x${N}; w = (const int32_t*) w + ${NR}; size_t p = ks; do { $for M in range(MR): const int8_t* restrict a${M} = a[${M}]; if XNN_UNPREDICTABLE(a${M} != zero) { a${M} = (const int8_t*) ((uintptr_t) a${M} + a_offset); $if DATATYPE == "QD8": } else { a${M} = zero_data; } a += ${MR}; size_t k = kc; do { $for M in range(MR): $if SDOT: const v128_t va${M} = wasm_v128_load(a${M}); $else: const v128_t va${M} = wasm_v128_xor(wasm_v128_load(a${M}), vsign_mask); a${M} += 16; $for N in range(NR): $if N == 0: const v128_t vb${N} = wasm_v128_load(w); $else: const v128_t vb${N} = wasm_v128_load((const int8_t*) w + ${N * 16}); $for M in range(MR): vacc${M}x${N} = wasm_i32x4_relaxed_dot_i8x16_i7x16_add(vb${N}, va${M}, vacc${M}x${N}); w = (const int8_t*) w + ${NR * 16}; k -= 16 * sizeof(int8_t); } while (k != 0); p -= ${MR} * sizeof(void*); } while (p != 0); $for M in range(MR): $for N in range(0, NR, 4): const v128_t vacc${M}x${N}${N+2} = wasm_i32x4_add(wasm_v32x4_shuffle(vacc${M}x${N}, vacc${M}x${N+2}, 0, 4, 1, 5), wasm_v32x4_shuffle(vacc${M}x${N}, vacc${M}x${N+2}, 2, 6, 3, 7)); const v128_t vacc${M}x${N+1}${N+3} = wasm_i32x4_add(wasm_v32x4_shuffle(vacc${M}x${N+1}, vacc${M}x${N+3}, 0, 4, 1, 5), wasm_v32x4_shuffle(vacc${M}x${N+1}, vacc${M}x${N+3}, 2, 6, 3, 7)); $for M in range(MR): $for N in range(0, NR, 4): v128_t vacc${M}x${ABC[N:N+4]} = wasm_i32x4_add(wasm_v32x4_shuffle(vacc${M}x${N}${N+2}, vacc${M}x${N+1}${N+3}, 0, 4, 1, 5), wasm_v32x4_shuffle(vacc${M}x${N}${N+2}, vacc${M}x${N+1}${N+3}, 2, 6, 3, 7)); $for M in range(MR): $for N in range(0, NR, 4): vacc${M}x${ABC[N:N+4]} = wasm_f32x4_convert_i32x4(vacc${M}x${ABC[N:N+4]}); $if DATATYPE == "QD8": const v128_t vinput_scale = wasm_v128_load32_splat(&quantization_params->inv_scale); $for M in range(MR): vacc${M}x0123 = wasm_f32x4_mul(vacc${M}x0123, vinput_scale); const v128_t vfilter_output_scale0123 = wasm_v128_load(w); $for M in range(MR): vacc${M}x0123 = wasm_f32x4_mul(vacc${M}x0123, vfilter_output_scale0123); w = (const float*) w + 4; const v128_t vbias0123 = wasm_v128_load(w); $for M in range(MR): vacc${M}x0123 = wasm_f32x4_add(vacc${M}x0123, vbias0123); w = (const float*) w + 4; $for M in range(MR): vacc${M}x0123 = wasm_f32x4_pmax(vacc${M}x0123, vmin); $for M in range(MR): vacc${M}x0123 = wasm_f32x4_pmin(vacc${M}x0123, vmax); if XNN_LIKELY(nc >= 4) { $for M in reversed(range(MR)): wasm_v128_store(c${M}, vacc${M}x0123); $for M in range(MR): c${M} = (float*) ((uintptr_t) c${M} + cn_stride); a = (const int8_t**restrict) ((uintptr_t) a - ks); nc -= 4; } else { if (nc & 2) { $for M in reversed(range(MR)): wasm_v128_store64_lane(c${M}, vacc${M}x0123, 0); vacc${M}x0123 = wasm_v64x2_shuffle(vacc${M}x0123, vacc${M}x0123, 1, 1); c${M} += 2; } if (nc & 1) { $for M in reversed(range(MR)): wasm_v128_store32_lane(c${M}, vacc${M}x0123, 0); } nc = 0; } $else: $if DATATYPE == "QC8": $for N in range(0, NR, 4): const v128_t vscale${ABC[N:N+4]} = wasm_v128_load(w); w = (const float*) w + 4; $for M in range(MR): $for N in range(0, NR, 4): vacc${M}x${ABC[N:N+4]} = wasm_f32x4_mul(vacc${M}x${ABC[N:N+4]}, vscale${ABC[N:N+4]}); $else: $for M in range(MR): vacc${M}x0123 = wasm_f32x4_mul(vacc${M}x0123, vscale); $for M in range(MR): $for N in range(0, NR, 4): vacc${M}x${ABC[N:N+4]} = wasm_f32x4_add(vacc${M}x${ABC[N:N+4]}, vmagic_bias); $for M in range(MR): $for N in range(0, NR, 4): vacc${M}x${ABC[N:N+4]} = wasm_i32x4_max(vacc${M}x${ABC[N:N+4]}, vmagic_min); $for M in range(MR): $for N in range(0, NR, 4): vacc${M}x${ABC[N:N+4]} = wasm_i32x4_sub(vacc${M}x${ABC[N:N+4]}, vmagic_bias_less_output_zero_point); $if NR == 4: $for M in range(0, MR, 2): v128_t vacc${M}${min(M+1, MR-1)}x0123 = wasm_i16x8_narrow_i32x4(vacc${M}x0123, vacc${min(M+1, MR-1)}x0123); $else: $for M in range(MR): v128_t vacc${M}x01234567 = wasm_i16x8_narrow_i32x4(vacc${M}x0123, vacc${M}x4567); $if NR == 4: $if MR > 2: v128_t vout = wasm_i8x16_narrow_i16x8(vacc0${min(1, MR-1)}x0123, vacc${min(2, MR-1)}${min(3, MR-1)}x0123); $else: v128_t vout = wasm_i8x16_narrow_i16x8(vacc0${min(1, MR-1)}x0123, vacc0${min(1, MR-1)}x0123); $else: $if MR > 2: v128_t vout0x01234567_1x01234567 = wasm_i8x16_narrow_i16x8(vacc0x01234567, vacc1x01234567); v128_t vout2x01234567_${min(3, MR-1)}x01234567 = wasm_i8x16_narrow_i16x8(vacc2x01234567, vacc${min(3, MR-1)}x01234567); $else: v128_t vout0x01234567_${min(1, MR-1)}x01234567 = wasm_i8x16_narrow_i16x8(vacc0x01234567, vacc${min(1, MR-1)}x01234567); $if NR == 4: vout = wasm_i8x16_min(vout, voutput_max); $else: $if MR > 2: vout0x01234567_1x01234567 = wasm_i8x16_min(vout0x01234567_1x01234567, voutput_max); vout2x01234567_${min(3, MR-1)}x01234567 = wasm_i8x16_min(vout2x01234567_${min(3, MR-1)}x01234567, voutput_max); $else: vout0x01234567_${min(1, MR-1)}x01234567 = wasm_i8x16_min(vout0x01234567_${min(1, MR-1)}x01234567, voutput_max); if (nc >= ${NR}) { $if NR == 4: $for M in reversed(range(MR)): wasm_v128_store32_lane(c${M}, vout, ${M}); $else: $for M in reversed(range(MR)): wasm_v128_store64_lane(c${M}, vout${(M>>1)*2}x01234567_${min(MR-1, (M>>1)*2+1)}x01234567, ${M%2}); $for M in reversed(range(MR)): c${M} = (int8_t*) ((uintptr_t) c${M} + cn_stride); a = (const int8_t**restrict) ((uintptr_t) a - ks); nc -= ${NR}; } else { $if NR == 8: if (nc & 4) { $for M in reversed(range(MR)): wasm_v128_store32_lane(c${M}, vout${(M>>1)*2}x01234567_${min(MR-1, (M>>1)*2+1)}x01234567, ${M%2*2}); c${M} += 4; $for M in range(0, MR, 2): vout${(M>>1)*2}x01234567_${min(MR-1, (M>>1)*2+1)}x01234567 = wasm_u64x2_shr(vout${(M>>1)*2}x01234567_${min(MR-1, (M>>1)*2+1)}x01234567, 32); } if (nc & 2) { $if NR == 4: $for M in reversed(range(MR)): wasm_v128_store16_lane(c${M}, vout, ${2 * M}); c${M} += 2; vout = wasm_u32x4_shr(vout, 16); $else: $for M in reversed(range(MR)): wasm_v128_store16_lane(c${M}, vout${(M>>1)*2}x01234567_${min(MR-1, (M>>1)*2+1)}x01234567, ${M%2*4}); c${M} += 2; $for M in range(0, MR, 2): vout${(M>>1)*2}x01234567_${min(MR-1, (M>>1)*2+1)}x01234567 = wasm_u32x4_shr(vout${(M>>1)*2}x01234567_${min(MR-1, (M>>1)*2+1)}x01234567, 16); } if (nc & 1) { $for M in reversed(range(MR)): $if NR == 4: wasm_v128_store8_lane(c${M}, vout, ${4 * M}); $else: wasm_v128_store8_lane(c${M}, vout${(M>>1)*2}x01234567_${min(MR-1, (M>>1)*2+1)}x01234567, ${M%2*8}); } nc = 0; } } while (nc != 0); }