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review.mlplatform.org / ml / ComputeLibrary / fadc9b1e0bba90d6a91beb65466b2a0895b3a5e4 / . / src / cpu / kernels / softmax / generic / sve2 / impl.cpp
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/*
* Copyright (c) 2021-2023 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.
*/
#include "src/cpu/kernels/softmax/generic/sve2/impl.h"
#include "arm_compute/core/Types.h"
#include "src/core/NEON/wrapper/wrapper.h"
namespace arm_compute
{
namespace cpu
{
/// TODO: (COMPMID-6505) Similar to Neon(TM), this implementation be converted to
/// a single kernel that performs softmax operation. Leaving the SVE2 code here for
/// future references. Implementation for Neon(TM) is introduced in COMPMID-6500
template <typename ScalarType>
void sve2_softmax_logits_1d_quantized(
const ITensor *in, const ITensor *max, void *const tmp, ITensor *out, float beta, bool is_log, const Window &window)
{
const int start_x = in->info()->valid_region().anchor.x();
const int input_width = in->info()->valid_region().shape.x();
const float scale_beta = -beta * in->info()->quantization_info().uniform().scale;
const auto scale_beta_vec = svdup_n_f32(scale_beta);
Iterator in_it(in, window);
Iterator max_it(max, window);
Iterator out_it(out, window);
const auto all_true_pg = wrapper::svptrue<ScalarType>();
using SVEType = typename wrapper::traits::sve_vector<ScalarType>::type;
const int inc_1 = static_cast<int>(svcntw());
const int inc_2 = static_cast<int>(2 * svcntw());
const int inc_3 = static_cast<int>(3 * svcntw());
execute_window_loop(
window,
[&](const Coordinates &)
{
/* Get pointers */
const auto in_ptr = reinterpret_cast<const ScalarType *>(in_it.ptr()) + start_x;
const auto out_ptr = reinterpret_cast<ScalarType *>(out_it.ptr()) + start_x;
const auto tmp_ptr = reinterpret_cast<float *>(tmp);
float sum{};
/* Compute exponentials and sum */
{
/* Get max value */
const auto max_val = *reinterpret_cast<const ScalarType *>(max_it.ptr());
const auto vec_max = wrapper::svdup_n(max_val);
/* Init sum to zero */
auto vec_sum_0 = svdup_n_f32(0.f);
auto vec_sum_1 = svdup_n_f32(0.f);
auto vec_sum_2 = svdup_n_f32(0.f);
auto vec_sum_3 = svdup_n_f32(0.f);
/* Loop over row and compute exponentials and sum */
int x = 0;
svbool_t pg = wrapper::svwhilelt<ScalarType>(x, input_width);
svbool_t pg_0 = svunpklo(svunpklo(pg));
svbool_t pg_1 = svunpkhi(svunpklo(pg));
svbool_t pg_2 = svunpklo(svunpkhi(pg));
svbool_t pg_3 = svunpkhi(svunpkhi(pg));
do
{
const auto vec_elements = svld1(pg, in_ptr + x);
const auto vec_elements_sub = svreinterpret_u8(svsub_z(pg, vec_max, vec_elements));
auto vec_elements_flt_0 = svcvt_f32_z(pg_0, svunpklo(svunpklo(vec_elements_sub)));
auto vec_elements_flt_1 = svcvt_f32_z(pg_1, svunpkhi(svunpklo(vec_elements_sub)));
auto vec_elements_flt_2 = svcvt_f32_z(pg_2, svunpklo(svunpkhi(vec_elements_sub)));
auto vec_elements_flt_3 = svcvt_f32_z(pg_3, svunpkhi(svunpkhi(vec_elements_sub)));
if (is_log)
{
vec_elements_flt_0 = svmul_f32_z(pg_0, vec_elements_flt_0, scale_beta_vec);
vec_elements_flt_1 = svmul_f32_z(pg_1, vec_elements_flt_1, scale_beta_vec);
vec_elements_flt_2 = svmul_f32_z(pg_2, vec_elements_flt_2, scale_beta_vec);
vec_elements_flt_3 = svmul_f32_z(pg_3, vec_elements_flt_3, scale_beta_vec);
vec_sum_0 = svadd_f32_m(pg_0, vec_sum_0, svexp_f32_z(pg_0, vec_elements_flt_0));
vec_sum_1 = svadd_f32_m(pg_1, vec_sum_1, svexp_f32_z(pg_1, vec_elements_flt_1));
vec_sum_2 = svadd_f32_m(pg_2, vec_sum_2, svexp_f32_z(pg_2, vec_elements_flt_2));
vec_sum_3 = svadd_f32_m(pg_3, vec_sum_3, svexp_f32_z(pg_3, vec_elements_flt_3));
}
else
{
vec_elements_flt_0 = svexp_f32_z(pg_0, svmul_f32_z(pg_0, vec_elements_flt_0, scale_beta_vec));
vec_elements_flt_1 = svexp_f32_z(pg_1, svmul_f32_z(pg_1, vec_elements_flt_1, scale_beta_vec));
vec_elements_flt_2 = svexp_f32_z(pg_2, svmul_f32_z(pg_2, vec_elements_flt_2, scale_beta_vec));
vec_elements_flt_3 = svexp_f32_z(pg_3, svmul_f32_z(pg_3, vec_elements_flt_3, scale_beta_vec));
vec_sum_0 = svadd_f32_m(pg_0, vec_sum_0, vec_elements_flt_0);
vec_sum_1 = svadd_f32_m(pg_1, vec_sum_1, vec_elements_flt_1);
vec_sum_2 = svadd_f32_m(pg_2, vec_sum_2, vec_elements_flt_2);
vec_sum_3 = svadd_f32_m(pg_3, vec_sum_3, vec_elements_flt_3);
}
svst1_f32(pg_0, tmp_ptr + x, vec_elements_flt_0);
svst1_f32(pg_1, tmp_ptr + x + inc_1, vec_elements_flt_1);
svst1_f32(pg_2, tmp_ptr + x + inc_2, vec_elements_flt_2);
svst1_f32(pg_3, tmp_ptr + x + inc_3, vec_elements_flt_3);
x += wrapper::svcnt<ScalarType>();
pg = wrapper::svwhilelt<ScalarType>(x, input_width);
pg_0 = svunpklo(svunpklo(pg));
pg_1 = svunpkhi(svunpklo(pg));
pg_2 = svunpklo(svunpkhi(pg));
pg_3 = svunpkhi(svunpkhi(pg));
} while (svptest_any(all_true_pg, pg));
/* Reduce sum */
const auto vec_sum = svadd_f32_z(all_true_pg, svadd_f32_z(all_true_pg, vec_sum_0, vec_sum_1),
svadd_f32_z(all_true_pg, vec_sum_2, vec_sum_3));
sum = svaddv_f32(all_true_pg, vec_sum);
/* Run remaining elements */
x = 0;
if (is_log)
{
sum = std::log(sum);
}
else
{
sum = 256.f / sum;
}
}
/* Normalize exponentials */
{
constexpr bool is_qasymm8_signed = std::is_same<ScalarType, qasymm8_signed_t>::value;
/* Loop over row and compute softmax */
int x = 0;
svbool_t pg = wrapper::svwhilelt<ScalarType>(x, input_width);
svbool_t pg_0 = svunpklo(svunpklo(pg));
svbool_t pg_1 = svunpkhi(svunpklo(pg));
svbool_t pg_2 = svunpklo(svunpkhi(pg));
svbool_t pg_3 = svunpkhi(svunpkhi(pg));
do
{
auto vec_in_0 = svld1_f32(pg_0, tmp_ptr + x);
auto vec_in_1 = svld1_f32(pg_1, tmp_ptr + x + inc_1);
auto vec_in_2 = svld1_f32(pg_2, tmp_ptr + x + inc_2);
auto vec_in_3 = svld1_f32(pg_3, tmp_ptr + x + inc_3);
svfloat32_t res_0{};
svfloat32_t res_1{};
svfloat32_t res_2{};
svfloat32_t res_3{};
if (is_log)
{
res_0 = svsub_f32_z(pg_0, vec_in_0, svdup_n_f32(sum));
res_1 = svsub_f32_z(pg_1, vec_in_1, svdup_n_f32(sum));
res_2 = svsub_f32_z(pg_2, vec_in_2, svdup_n_f32(sum));
res_3 = svsub_f32_z(pg_3, vec_in_3, svdup_n_f32(sum));
}
else
{
res_0 = svmul_f32_z(pg_0, vec_in_0, svdup_n_f32(sum));
res_1 = svmul_f32_z(pg_1, vec_in_1, svdup_n_f32(sum));
res_2 = svmul_f32_z(pg_2, vec_in_2, svdup_n_f32(sum));
res_3 = svmul_f32_z(pg_3, vec_in_3, svdup_n_f32(sum));
if (is_qasymm8_signed)
{
const auto offset_vec = svdup_n_f32(128.f);
res_0 = svsub_z(pg_0, res_0, offset_vec);
res_1 = svsub_z(pg_1, res_1, offset_vec);
res_2 = svsub_z(pg_2, res_2, offset_vec);
res_3 = svsub_z(pg_3, res_3, offset_vec);
}
}
// Store value
const auto out = convert_float_to_int<SVEType>(res_0, res_1, res_2, res_3);
svst1(pg, out_ptr + x, out);
x += wrapper::svcnt<ScalarType>();
pg = wrapper::svwhilelt<ScalarType>(x, input_width);
pg_0 = svunpklo(svunpklo(pg));
pg_1 = svunpkhi(svunpklo(pg));
pg_2 = svunpklo(svunpkhi(pg));
pg_3 = svunpkhi(svunpkhi(pg));
} while (svptest_any(all_true_pg, pg));
}
},
in_it, max_it, out_it);
}
} // namespace cpu
} // namespace arm_compute