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Diffstat (limited to 'src/core/NEON/NEAsymm.h')
-rw-r--r-- | src/core/NEON/NEAsymm.h | 753 |
1 files changed, 753 insertions, 0 deletions
diff --git a/src/core/NEON/NEAsymm.h b/src/core/NEON/NEAsymm.h new file mode 100644 index 0000000000..70d48d5835 --- /dev/null +++ b/src/core/NEON/NEAsymm.h @@ -0,0 +1,753 @@ +/* + * Copyright (c) 2017-2020 Arm Limited. + * + * SPDX-License-Identifier: MIT + * + * Permission is hereby granted, free of charge, to any person obtaining a copy + * of this software and associated documentation files (the "Software"), to + * deal in the Software without restriction, including without limitation the + * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or + * sell copies of the Software, and to permit persons to whom the Software is + * furnished to do so, subject to the following conditions: + * + * The above copyright notice and this permission notice shall be included in all + * copies or substantial portions of the Software. + * + * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE + * SOFTWARE. + */ +#ifndef ARM_COMPUTE_NEASYMM_H +#define ARM_COMPUTE_NEASYMM_H + +#include "src/core/NEON/NEMath.h" +#include <arm_neon.h> + +namespace arm_compute +{ +using qasymm8x8_t = uint8x8_t; /**< 8 bit quantized asymmetric vector with 8 elements */ +using qasymm8x8x2_t = uint8x8x2_t; /**< 8 bit quantized asymmetric vector with 16 elements */ +using qasymm8x8x3_t = uint8x8x3_t; /**< 8 bit quantized asymmetric vector with 24 elements */ +using qasymm8x8x4_t = uint8x8x4_t; /**< 8 bit quantized asymmetric vector with 32 elements */ +using qasymm8x16_t = uint8x16_t; /**< 8 bit quantized asymmetric vector with 16 elements */ + +using qasymm8x8_signed_t = int8x8_t; /**< 8 bit quantized signed asymmetric vector with 8 elements */ +using qasymm8x8x2_signed_t = int8x8x2_t; /**< 8 bit quantized signed asymmetric vector with 16 elements */ +using qasymm8x8x3_signed_t = int8x8x3_t; /**< 8 bit quantized signed asymmetric vector with 24 elements */ +using qasymm8x8x4_signed_t = int8x8x4_t; /**< 8 bit quantized signed asymmetric vector with 32 elements */ +using qasymm8x16_signed_t = int8x16_t; /**< 8 bit quantized signed asymmetric vector with 16 elements */ + +/** Perform a multiply-accumulate on all 16 components of a QASYMM8 vector + * + * vd*vs + vo + * + * @param[in] vd Input vector value in QASYMM8 format + * @param[in] vs Vector multiplier in F32 format. The multiplier value must be duplicated across all four lanes. + * @param[in] vo Vector addend in F32 format. The addend value must be duplicated across all four lanes. + * + * @return A 16-component vector in QASYMM8 format, saturated to fit + */ +uint8x16_t vmlaq_qasymm8(qasymm8x16_t vd, float32x4_t vs, float32x4_t vo); + +/** Perform a multiply-accumulate on all 16 components of a QASYMM8_SIGNED vector + * + * vd*vs + vo + * + * @param[in] vd Input vector value in QASYMM8_SIGNED format + * @param[in] vs Vector multiplier in F32 format. The multiplier value must be duplicated across all four lanes. + * @param[in] vo Vector addend in F32 format. The addend value must be duplicated across all four lanes. + * + * @return A 16-component vector in QASYMM8_SIGNED format, saturated to fit + */ +int8x16_t vmlaq_qasymm8_signed(qasymm8x16_signed_t vd, float32x4_t vs, float32x4_t vo); + +/** Performs final quantization step on 16 elements + * + * @param[in] in_s32 Input to be quantized. + * @param[in] result_fixedpoint_multiplier Result multiplier parameter + * @param[in] result_shift Result shift parameter + * @param[in] result_offset_after_shift_s32 Result offset parameter + * @param[in] min_u8 Relu lower bound + * @param[in] max_u8 Relu upper bound + * @param[in] is_bounded_relu Specified if a fused bounded relu should be applied + * + * @return Quantized values + */ +inline uint8x16_t finalize_quantization(int32x4x4_t &in_s32, + int result_fixedpoint_multiplier, + int32_t result_shift, + int32x4_t result_offset_after_shift_s32, + uint8x16_t min_u8, + uint8x16_t max_u8, + bool is_bounded_relu) +{ + const static int32x4_t zero_s32 = vdupq_n_s32(0); + + if(result_shift < 0) + { + in_s32.val[0] = vmulq_n_s32(in_s32.val[0], (1 << (-result_shift))); + in_s32.val[1] = vmulq_n_s32(in_s32.val[1], (1 << (-result_shift))); + in_s32.val[2] = vmulq_n_s32(in_s32.val[2], (1 << (-result_shift))); + in_s32.val[3] = vmulq_n_s32(in_s32.val[3], (1 << (-result_shift))); + + in_s32.val[0] = vqrdmulhq_n_s32(in_s32.val[0], result_fixedpoint_multiplier); + in_s32.val[1] = vqrdmulhq_n_s32(in_s32.val[1], result_fixedpoint_multiplier); + in_s32.val[2] = vqrdmulhq_n_s32(in_s32.val[2], result_fixedpoint_multiplier); + in_s32.val[3] = vqrdmulhq_n_s32(in_s32.val[3], result_fixedpoint_multiplier); + } + else + { + // Fixed point multiplication with vector saturating rounding doubling multiply high with scalar + in_s32.val[0] = vqrdmulhq_n_s32(in_s32.val[0], result_fixedpoint_multiplier); + in_s32.val[1] = vqrdmulhq_n_s32(in_s32.val[1], result_fixedpoint_multiplier); + in_s32.val[2] = vqrdmulhq_n_s32(in_s32.val[2], result_fixedpoint_multiplier); + in_s32.val[3] = vqrdmulhq_n_s32(in_s32.val[3], result_fixedpoint_multiplier); + + // Round to the nearest division by a power-of-two using result_shift_s32 + in_s32.val[0] = rounding_divide_by_pow2(in_s32.val[0], result_shift); + in_s32.val[1] = rounding_divide_by_pow2(in_s32.val[1], result_shift); + in_s32.val[2] = rounding_divide_by_pow2(in_s32.val[2], result_shift); + in_s32.val[3] = rounding_divide_by_pow2(in_s32.val[3], result_shift); + } + + // Add the offset terms + in_s32.val[0] = vaddq_s32(in_s32.val[0], result_offset_after_shift_s32); + in_s32.val[1] = vaddq_s32(in_s32.val[1], result_offset_after_shift_s32); + in_s32.val[2] = vaddq_s32(in_s32.val[2], result_offset_after_shift_s32); + in_s32.val[3] = vaddq_s32(in_s32.val[3], result_offset_after_shift_s32); + + // Saturate negative values + in_s32.val[0] = vmaxq_s32(in_s32.val[0], zero_s32); + in_s32.val[1] = vmaxq_s32(in_s32.val[1], zero_s32); + in_s32.val[2] = vmaxq_s32(in_s32.val[2], zero_s32); + in_s32.val[3] = vmaxq_s32(in_s32.val[3], zero_s32); + + // Convert S32 to S16 + const int16x8x2_t in_s16 = + { + { + vcombine_s16(vqmovn_s32(in_s32.val[0]), vqmovn_s32(in_s32.val[1])), + vcombine_s16(vqmovn_s32(in_s32.val[2]), vqmovn_s32(in_s32.val[3])) + } + }; + + // Convert S16 to U8 + uint8x16_t out_u8 = vcombine_u8(vqmovun_s16(in_s16.val[0]), vqmovun_s16(in_s16.val[1])); + + if(is_bounded_relu) + { + out_u8 = vmaxq_u8(out_u8, min_u8); + out_u8 = vminq_u8(out_u8, max_u8); + } + + return out_u8; +} + +/** Performs final quantization step on 16 elements + * + * @param[in] in_s32 Input to be quantized. + * @param[in] result_fixedpoint_multiplier Result multiplier parameter + * @param[in] result_shift Result shift parameter + * @param[in] result_offset_after_shift_s32 Result offset parameter + * @param[in] min_s8 Relu lower bound + * @param[in] max_s8 Relu upper bound + * @param[in] is_bounded_relu Specified if a fused bounded relu should be applied + * + * @return Quantized values + */ +inline int8x16_t finalize_quantization(int32x4x4_t &in_s32, + int result_fixedpoint_multiplier, + int32_t result_shift, + int32x4_t result_offset_after_shift_s32, + int8x16_t min_s8, + int8x16_t max_s8, + bool is_bounded_relu) +{ + if(result_shift < 0) + { + in_s32.val[0] = vmulq_n_s32(in_s32.val[0], (1 << (-result_shift))); + in_s32.val[1] = vmulq_n_s32(in_s32.val[1], (1 << (-result_shift))); + in_s32.val[2] = vmulq_n_s32(in_s32.val[2], (1 << (-result_shift))); + in_s32.val[3] = vmulq_n_s32(in_s32.val[3], (1 << (-result_shift))); + + in_s32.val[0] = vqrdmulhq_n_s32(in_s32.val[0], result_fixedpoint_multiplier); + in_s32.val[1] = vqrdmulhq_n_s32(in_s32.val[1], result_fixedpoint_multiplier); + in_s32.val[2] = vqrdmulhq_n_s32(in_s32.val[2], result_fixedpoint_multiplier); + in_s32.val[3] = vqrdmulhq_n_s32(in_s32.val[3], result_fixedpoint_multiplier); + } + else + { + // Fixed point multiplication with vector saturating rounding doubling multiply high with scalar + in_s32.val[0] = vqrdmulhq_n_s32(in_s32.val[0], result_fixedpoint_multiplier); + in_s32.val[1] = vqrdmulhq_n_s32(in_s32.val[1], result_fixedpoint_multiplier); + in_s32.val[2] = vqrdmulhq_n_s32(in_s32.val[2], result_fixedpoint_multiplier); + in_s32.val[3] = vqrdmulhq_n_s32(in_s32.val[3], result_fixedpoint_multiplier); + + // Round to the nearest division by a power-of-two using result_shift_s32 + in_s32.val[0] = rounding_divide_by_pow2(in_s32.val[0], result_shift); + in_s32.val[1] = rounding_divide_by_pow2(in_s32.val[1], result_shift); + in_s32.val[2] = rounding_divide_by_pow2(in_s32.val[2], result_shift); + in_s32.val[3] = rounding_divide_by_pow2(in_s32.val[3], result_shift); + } + + // Add the offset terms + in_s32.val[0] = vaddq_s32(in_s32.val[0], result_offset_after_shift_s32); + in_s32.val[1] = vaddq_s32(in_s32.val[1], result_offset_after_shift_s32); + in_s32.val[2] = vaddq_s32(in_s32.val[2], result_offset_after_shift_s32); + in_s32.val[3] = vaddq_s32(in_s32.val[3], result_offset_after_shift_s32); + + // Convert S32 to S16 + const int16x8x2_t in_s16 = + { + { + vcombine_s16(vqmovn_s32(in_s32.val[0]), vqmovn_s32(in_s32.val[1])), + vcombine_s16(vqmovn_s32(in_s32.val[2]), vqmovn_s32(in_s32.val[3])) + } + }; + + // Convert S16 to S8 + int8x16_t out_s8 = vcombine_s8(vqmovn_s16(in_s16.val[0]), vqmovn_s16(in_s16.val[1])); + + if(is_bounded_relu) + { + out_s8 = vmaxq_s8(out_s8, min_s8); + out_s8 = vminq_s8(out_s8, max_s8); + } + + return out_s8; +} + +/** Performs final quantization step on 16 elements for symmetric quantization + * + * @param[in] in_s32 Input to be quantized. + * @param[in] result_fixedpoint_multiplier Result multiplier parameter + * @param[in] result_shift Result shift parameter + * @param[in] result_offset_after_shift_s32 Result offset parameter + * @param[in] min_s8 Relu lower bound + * @param[in] max_s8 Relu upper bound + * @param[in] is_bounded_relu Specified if a fused bounded relu should be applied + * + * @return Quantized values + */ +inline int8x16_t finalize_quantization_symm(int32x4x4_t &in_s32, + const int32x4x4_t &result_fixedpoint_multiplier, + const int32x4x4_t &result_shift, + const int32x4_t &result_offset_after_shift_s32, + const int8x16_t &min_s8, + const int8x16_t &max_s8, + const bool is_bounded_relu) +{ + const static int32x4_t one_s32 = vdupq_n_s32(1); + + // Fixed point multiplication with vector saturating rounding doubling multiply high with scalar + int32x4x4_t res_shift_gt0 = + { + vqrdmulhq_s32(in_s32.val[0], result_fixedpoint_multiplier.val[0]), + vqrdmulhq_s32(in_s32.val[1], result_fixedpoint_multiplier.val[1]), + vqrdmulhq_s32(in_s32.val[2], result_fixedpoint_multiplier.val[2]), + vqrdmulhq_s32(in_s32.val[3], result_fixedpoint_multiplier.val[3]), + }; + // Round to the nearest division by a power-of-two using result_shift_s32 + res_shift_gt0.val[0] = rounding_divide_by_pow2(res_shift_gt0.val[0], result_shift.val[0]); + res_shift_gt0.val[1] = rounding_divide_by_pow2(res_shift_gt0.val[1], result_shift.val[1]); + res_shift_gt0.val[2] = rounding_divide_by_pow2(res_shift_gt0.val[2], result_shift.val[2]); + res_shift_gt0.val[3] = rounding_divide_by_pow2(res_shift_gt0.val[3], result_shift.val[3]); + + int32x4x4_t res_shift_lt0 = + { + vmulq_s32(in_s32.val[0], vshlq_s32(one_s32, vnegq_s32(result_shift.val[0]))), + vmulq_s32(in_s32.val[1], vshlq_s32(one_s32, vnegq_s32(result_shift.val[1]))), + vmulq_s32(in_s32.val[2], vshlq_s32(one_s32, vnegq_s32(result_shift.val[2]))), + vmulq_s32(in_s32.val[3], vshlq_s32(one_s32, vnegq_s32(result_shift.val[3]))), + }; + res_shift_lt0.val[0] = vqrdmulhq_s32(res_shift_lt0.val[0], result_fixedpoint_multiplier.val[0]); + res_shift_lt0.val[1] = vqrdmulhq_s32(res_shift_lt0.val[1], result_fixedpoint_multiplier.val[1]); + res_shift_lt0.val[2] = vqrdmulhq_s32(res_shift_lt0.val[2], result_fixedpoint_multiplier.val[2]); + res_shift_lt0.val[3] = vqrdmulhq_s32(res_shift_lt0.val[3], result_fixedpoint_multiplier.val[3]); + + // Select result depending on shift value + const uint32x4x4_t mask_lt0 = + { +#ifdef __aarch64__ + vcltzq_s32(result_shift.val[0]), + vcltzq_s32(result_shift.val[1]), + vcltzq_s32(result_shift.val[2]), + vcltzq_s32(result_shift.val[3]), +#else //__aarch64__ + vcltq_s32(result_shift.val[0], vdupq_n_s32(0)), + vcltq_s32(result_shift.val[1], vdupq_n_s32(0)), + vcltq_s32(result_shift.val[2], vdupq_n_s32(0)), + vcltq_s32(result_shift.val[3], vdupq_n_s32(0)), +#endif //__aarch64__ + }; + + in_s32.val[0] = vbslq_s32(mask_lt0.val[0], res_shift_lt0.val[0], res_shift_gt0.val[0]); + in_s32.val[1] = vbslq_s32(mask_lt0.val[1], res_shift_lt0.val[1], res_shift_gt0.val[1]); + in_s32.val[2] = vbslq_s32(mask_lt0.val[2], res_shift_lt0.val[2], res_shift_gt0.val[2]); + in_s32.val[3] = vbslq_s32(mask_lt0.val[3], res_shift_lt0.val[3], res_shift_gt0.val[3]); + + // Add the offset terms + in_s32.val[0] = vaddq_s32(in_s32.val[0], result_offset_after_shift_s32); + in_s32.val[1] = vaddq_s32(in_s32.val[1], result_offset_after_shift_s32); + in_s32.val[2] = vaddq_s32(in_s32.val[2], result_offset_after_shift_s32); + in_s32.val[3] = vaddq_s32(in_s32.val[3], result_offset_after_shift_s32); + + // Convert S32 to S16 + const int16x8x2_t in_s16 = + { + { + vcombine_s16(vqmovn_s32(in_s32.val[0]), vqmovn_s32(in_s32.val[1])), + vcombine_s16(vqmovn_s32(in_s32.val[2]), vqmovn_s32(in_s32.val[3])) + } + }; + + // Convert S16 to S8 + int8x16_t out_s8 = vcombine_s8(vqmovn_s16(in_s16.val[0]), vqmovn_s16(in_s16.val[1])); + + if(is_bounded_relu) + { + out_s8 = vmaxq_s8(out_s8, min_s8); + out_s8 = vminq_s8(out_s8, max_s8); + } + + return out_s8; +} + +/** Performs final quantization step on single element + * + * @param[in] in_value Input to be quantized. + * @param[in] result_fixedpoint_multiplier Result multiplier parameter + * @param[in] result_shift Result shift parameter + * @param[in] result_offset_after_shift_s32 Result offset parameter + * @param[in] min_u8 Relu lower bound + * @param[in] max_u8 Relu upper bound + * @param[in] is_bounded_relu Specified if a fused bounded relu should be applied + * + * @return Quantized value + */ +inline uint8_t finalize_quantization(int32_t in_value, int result_fixedpoint_multiplier, + int32_t result_shift, int32_t result_offset_after_shift_s32, + uint8_t min_u8, uint8_t max_u8, bool is_bounded_relu) +{ + int32x4_t in_s32 = vdupq_n_s32(in_value); + + if(result_shift < 0) + { + in_value = vgetq_lane_s32(vqrdmulhq_n_s32(vmulq_n_s32(in_s32, (1 << (-result_shift))), result_fixedpoint_multiplier), 0); + } + else + { + // Fixed point multiplication with vector saturating rounding doubling multiply high with scalar + in_value = vgetq_lane_s32(vqrdmulhq_n_s32(in_s32, result_fixedpoint_multiplier), 0); + // Shift value by result_shift_s32 + in_value = rounding_divide_by_pow2(in_value, result_shift); + } + + // Add the offset term + in_value += result_offset_after_shift_s32; + + // Bound the result + uint8_t out_u8 = static_cast<uint8_t>(std::max<int32_t>(0, std::min<int32_t>(255, in_value))); + if(is_bounded_relu) + { + out_u8 = static_cast<uint8_t>(std::max(min_u8, std::min(max_u8, out_u8))); + } + + return out_u8; +} + +/** Performs final quantization step on single element + * + * @param[in] in_value Input to be quantized. + * @param[in] result_fixedpoint_multiplier Result multiplier parameter + * @param[in] result_shift Result shift parameter + * @param[in] result_offset_after_shift_s32 Result offset parameter + * @param[in] min_s8 Relu lower bound + * @param[in] max_s8 Relu upper bound + * @param[in] is_bounded_relu Specified if a fused bounded relu should be applied + * + * @return Quantized value + */ +inline int8_t finalize_quantization(int32_t in_value, int result_fixedpoint_multiplier, + int32_t result_shift, int32_t result_offset_after_shift_s32, + int8_t min_s8, int8_t max_s8, bool is_bounded_relu) +{ + int32x4_t in_s32 = vdupq_n_s32(in_value); + + if(result_shift < 0) + { + in_value = vgetq_lane_s32(vqrdmulhq_n_s32(vmulq_n_s32(in_s32, (1 << (-result_shift))), result_fixedpoint_multiplier), 0); + } + else + { + // Fixed point multiplication with vector saturating rounding doubling multiply high with scalar + in_value = vgetq_lane_s32(vqrdmulhq_n_s32(in_s32, result_fixedpoint_multiplier), 0); + + // Shift value by result_shift_s32 + in_value = rounding_divide_by_pow2(in_value, result_shift); + } + + // Add the offset term + in_value += result_offset_after_shift_s32; + + // Bound the result + int8_t out_s8 = static_cast<int8_t>(std::max<int32_t>(-128, std::min<int32_t>(127, in_value))); + if(is_bounded_relu) + { + out_s8 = static_cast<int8_t>(std::max(min_s8, std::min(max_s8, out_s8))); + } + + return out_s8; +} + +/** Dequantize a neon vector holding 8 quantized values. + * + * @param[in] qv Input values to be dequantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return Dequantized values in a neon vector + */ +inline float32x4x2_t vdequantize(const uint8x8_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const int32x4_t voffset = vdupq_n_s32(offset); + const float32x4_t vscale = vdupq_n_f32(scale); + const float32x4x2_t vdequantized_input = + { + { + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_low_u16(vmovl_u8(qv)))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_high_u16(vmovl_u8(qv)))), voffset)), vscale), + } + }; + return vdequantized_input; +} + +/** Dequantize a neon vector holding 8 singed quantized values. + * + * @param[in] qv Input values to be dequantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return Dequantized values in a neon vector + */ +inline float32x4x2_t vdequantize(const int8x8_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const int32x4_t voffset = vdupq_n_s32(offset); + const float32x4_t vscale = vdupq_n_f32(scale); + const float32x4x2_t vdequantized_input = + { + { + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_low_s16(vmovl_s8(qv))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_high_s16(vmovl_s8(qv))), voffset)), vscale), + } + }; + return vdequantized_input; +} + +/** Dequantize a neon vector holding 16 quantized values. + * + * @param[in] qv Input values to be dequantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return Dequantized values in a neon vector + */ +inline float32x4x4_t vdequantize(const uint8x16_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const int32x4_t voffset = vdupq_n_s32(offset); + const float32x4_t vscale = vdupq_n_f32(scale); + const float32x4x4_t vdequantized_input = + { + { + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_low_u16(vmovl_u8(vget_low_u8(qv))))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_high_u16(vmovl_u8(vget_low_u8(qv))))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_low_u16(vmovl_u8(vget_high_u8(qv))))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_high_u16(vmovl_u8(vget_high_u8(qv))))), voffset)), vscale), + } + }; + return vdequantized_input; +} + +/** Dequantize a neon vector holding 16 signed quantized values. + * + * @param[in] qv Input values to be dequantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return Dequantized values in a neon vector + */ +inline float32x4x4_t vdequantize(const int8x16_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const int32x4_t voffset = vdupq_n_s32(offset); + const float32x4_t vscale = vdupq_n_f32(scale); + const float32x4x4_t vdequantized_input = + { + { + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_low_s16(vmovl_s8(vget_low_s8(qv)))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_high_s16(vmovl_s8(vget_low_s8(qv)))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_low_s16(vmovl_s8(vget_high_s8(qv)))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_high_s16(vmovl_s8(vget_high_s8(qv)))), voffset)), vscale), + } + }; + return vdequantized_input; +} + +/** Dequantize following an asymmetric quantization scheme a neon vector holding 16 quantized values. + * + * @param[in] qv Input values to be dequantized. + * @param[in] scale Quantization scaling factor. + * @param[in] offset Zero quantization offset. + * + * @return Dequantized values in a neon vector + */ +inline float32x4x4_t vdequantize(const uint8x16_t &qv, float scale, int32_t offset) +{ + const int32x4_t voffset = vdupq_n_s32(offset); + const float32x4_t vscale = vdupq_n_f32(scale); + const float32x4x4_t vdequantized_input = + { + { + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_low_u16(vmovl_u8(vget_low_u8(qv))))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_high_u16(vmovl_u8(vget_low_u8(qv))))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_low_u16(vmovl_u8(vget_high_u8(qv))))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vreinterpretq_s32_u32(vmovl_u16(vget_high_u16(vmovl_u8(vget_high_u8(qv))))), voffset)), vscale), + } + }; + return vdequantized_input; +} + +/** Dequantize a vector of 16 values stored as signed asymmetric. + * + * @param[in] qv Input values to be dequantized. + * @param[in] scale Quantization scaling factor. + * @param[in] offset Zero quantization offset. + * + * @return Dequantized values in a neon vector + */ +inline float32x4x4_t vdequantize(const int8x16_t &qv, float scale, int32_t offset) +{ + const int32x4_t voffset = vdupq_n_s32(offset); + const float32x4_t vscale = vdupq_n_f32(scale); + const float32x4x4_t vdequantized_input = + { + { + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_low_s16(vmovl_s8(vget_low_s8(qv)))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_high_s16(vmovl_s8(vget_low_s8(qv)))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_low_s16(vmovl_s8(vget_high_s8(qv)))), voffset)), vscale), + vmulq_f32(vcvtq_f32_s32(vsubq_s32(vmovl_s16(vget_high_s16(vmovl_s8(vget_high_s8(qv)))), voffset)), vscale), + } + }; + return vdequantized_input; +} + +/** Dequantize following symmetric quantization scheme a neon vector holding 16 quantized values. + * + * @param[in] qv Input values to be dequantized. + * @param[in] vscale Vector containing quantization scaling factors. + * + * @return Dequantized values in a neon vector + */ +inline float32x4x4_t vdequantize(const int8x16_t &qv, const float32x4x4_t vscale) +{ + const float32x4x4_t vdequantized_input = + { + { + vmulq_f32(vcvtq_f32_s32(vmovl_s16(vget_low_s16(vmovl_s8(vget_low_s8(qv))))), vscale.val[0]), + vmulq_f32(vcvtq_f32_s32(vmovl_s16(vget_high_s16(vmovl_s8(vget_low_s8(qv))))), vscale.val[1]), + vmulq_f32(vcvtq_f32_s32(vmovl_s16(vget_low_s16(vmovl_s8(vget_high_s8(qv))))), vscale.val[2]), + vmulq_f32(vcvtq_f32_s32(vmovl_s16(vget_high_s16(vmovl_s8(vget_high_s8(qv))))), vscale.val[3]), + } + }; + return vdequantized_input; +} + +/** Dequantize following a symmetric quantization scheme a neon vector holding 16 quantized values. + * + * @param[in] qv Input values to be dequantized. + * @param[in] scale Quantization scaling factor. + * + * @return Dequantized values in a neon vector + */ +inline float32x4x4_t vdequantize(const int8x16_t &qv, float scale) +{ + const float32x4_t vscale = vdupq_n_f32(scale); + const float32x4x4_t vdequantized_input = + { + { + vmulq_f32(vcvtq_f32_s32(vmovl_s16(vget_low_s16(vmovl_s8(vget_low_s8(qv))))), vscale), + vmulq_f32(vcvtq_f32_s32(vmovl_s16(vget_high_s16(vmovl_s8(vget_low_s8(qv))))), vscale), + vmulq_f32(vcvtq_f32_s32(vmovl_s16(vget_low_s16(vmovl_s8(vget_high_s8(qv))))), vscale), + vmulq_f32(vcvtq_f32_s32(vmovl_s16(vget_high_s16(vmovl_s8(vget_high_s8(qv))))), vscale), + } + }; + return vdequantized_input; +} + +/** Quantize a neon vector holding 8 floating point values. + * + * @param[in] qv Input values to be quantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return A neon vector holding the quantized values + */ +inline uint8x8_t vquantize(const float32x4x2_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const float32x4_t voffset = vdupq_n_f32(offset); + const float32x4_t vinvscale = vdupq_n_f32(1.f / scale); + const int32x4x4_t rf = + { + { +#ifdef __aarch64__ + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), +#else //__aarch64__ + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), +#endif //__aarch64__ + } + }; + return vqmovun_s16(vcombine_s16(vqmovn_s32(rf.val[0]), vqmovn_s32(rf.val[1]))); +} + +/** Quantize a neon vector holding 8 floating point values. + * + * @param[in] qv Input values to be quantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return A neon vector holding the singed quantized values + */ +inline int8x8_t vquantize_signed(const float32x4x2_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const float32x4_t voffset = vdupq_n_f32(offset); + const float32x4_t vinvscale = vdupq_n_f32(1.f / scale); + const int32x4x4_t rf = + { + { +#ifdef __aarch64__ + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), +#else //__aarch64__ + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), +#endif //__aarch64__ + } + }; + return vqmovn_s16(vcombine_s16(vqmovn_s32(rf.val[0]), vqmovn_s32(rf.val[1]))); +} + +/** Quantize a neon vector holding 16 floating point values. + * + * @param[in] qv Input values to be quantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return A neon vector holding the quantized values + */ +inline uint8x16_t vquantize(const float32x4x4_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const float32x4_t voffset = vdupq_n_f32(offset); + const float32x4_t vinvscale = vdupq_n_f32(1.f / scale); + const int32x4x4_t rf = + { + { +#ifdef __aarch64__ + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[2], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[3], vinvscale)), +#else //__aarch64__ + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[2], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[3], vinvscale)), +#endif //__aarch64__ + } + }; + const uint8x8_t pa = vqmovun_s16(vcombine_s16(vqmovn_s32(rf.val[0]), vqmovn_s32(rf.val[1]))); + const uint8x8_t pb = vqmovun_s16(vcombine_s16(vqmovn_s32(rf.val[2]), vqmovn_s32(rf.val[3]))); + return vcombine_u8(pa, pb); +} + +/** Signed quantize a neon vector holding 16 floating point values. + * + * @param[in] qv Input values to be quantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return A neon vector holding the quantized values + */ +inline int8x16_t vquantize_signed(const float32x4x4_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const float32x4_t voffset = vdupq_n_f32(offset); + const float32x4_t vinvscale = vdupq_n_f32(1.f / scale); + const int32x4x4_t rf = + { + { +#ifdef __aarch64__ + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[2], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[3], vinvscale)), +#else //__aarch64__ + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[2], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[3], vinvscale)), +#endif //__aarch64__ + } + }; + const int8x8_t pa = vqmovn_s16(vcombine_s16(vqmovn_s32(rf.val[0]), vqmovn_s32(rf.val[1]))); + const int8x8_t pb = vqmovn_s16(vcombine_s16(vqmovn_s32(rf.val[2]), vqmovn_s32(rf.val[3]))); + return vcombine_s8(pa, pb); +} + +/** Quantize to QASYMM16 a neon vector holding 16 floating point values. + * + * @param[in] qv Input values to be quantized. + * @param[in] qi Quantization information to be used in the computation. + * + * @return A neon vector holding the quantized values + */ +inline uint16x8x2_t vquantize_qasymm16(const float32x4x4_t &qv, const UniformQuantizationInfo &qi) +{ + const float scale = qi.scale; + const int offset = qi.offset; + const float32x4_t voffset = vdupq_n_f32(offset); + const float32x4_t vinvscale = vdupq_n_f32(1.f / scale); + const int32x4x4_t rf = + { + { +#ifdef __aarch64__ + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[2], vinvscale)), + vcvtnq_s32_f32(vmlaq_f32(voffset, qv.val[3], vinvscale)), +#else //__aarch64__ + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[0], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[1], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[2], vinvscale)), + vcvtq_s32_f32(vmlaq_f32(voffset, qv.val[3], vinvscale)), +#endif //__aarch64__ + } + }; + const uint16x8_t pa = vcombine_u16(vqmovun_s32(rf.val[0]), vqmovun_s32(rf.val[1])); + const uint16x8_t pb = vcombine_u16(vqmovun_s32(rf.val[2]), vqmovun_s32(rf.val[3])); + return { pa, pb }; +} +} // namespace arm_compute +#include "src/core/NEON/NEAsymm.inl" +#endif // ARM_COMPUTE_NEASYMM_H |