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221 lines
9.5 KiB
C
221 lines
9.5 KiB
C
/**
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* Copyright 2013-2022 Software Radio Systems Limited
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*
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* This file is part of srsRAN.
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*
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* srsRAN is free software: you can redistribute it and/or modify
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* it under the terms of the GNU Affero General Public License as
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* published by the Free Software Foundation, either version 3 of
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* the License, or (at your option) any later version.
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*
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* srsRAN is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU Affero General Public License for more details.
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*
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* A copy of the GNU Affero General Public License can be found in
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* the LICENSE file in the top-level directory of this distribution
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* and at http://www.gnu.org/licenses/.
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*
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*/
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#ifndef SRSRAN_MAT_H
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#define SRSRAN_MAT_H
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#include "srsran/config.h"
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#include "srsran/phy/utils/simd.h"
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#include <inttypes.h>
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/* Generic implementation for complex reciprocal */
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SRSRAN_API cf_t srsran_mat_cf_recip_gen(cf_t a);
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/* Generic implementation for 2x2 determinant */
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SRSRAN_API cf_t srsran_mat_2x2_det_gen(cf_t a00, cf_t a01, cf_t a10, cf_t a11);
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/* Generic implementation for 2x2 Matrix Inversion */
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SRSRAN_API void
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srsran_mat_2x2_inv_gen(cf_t a00, cf_t a01, cf_t a10, cf_t a11, cf_t* r00, cf_t* r01, cf_t* r10, cf_t* r11);
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/* Generic implementation for Zero Forcing (ZF) solver */
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SRSRAN_API void
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srsran_mat_2x2_zf_gen(cf_t y0, cf_t y1, cf_t h00, cf_t h01, cf_t h10, cf_t h11, cf_t* x0, cf_t* x1, float norm);
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/* Generic implementation for Minimum Mean Squared Error (MMSE) solver */
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SRSRAN_API void srsran_mat_2x2_mmse_gen(cf_t y0,
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cf_t y1,
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cf_t h00,
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cf_t h01,
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cf_t h10,
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cf_t h11,
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cf_t* x0,
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cf_t* x1,
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float noise_estimate,
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float norm);
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SRSRAN_API void srsran_mat_2x2_mmse_csi_gen(cf_t y0,
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cf_t y1,
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cf_t h00,
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cf_t h01,
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cf_t h10,
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cf_t h11,
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cf_t* x0,
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cf_t* x1,
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float* csi0,
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float* csi1,
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float noise_estimate,
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float norm);
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SRSRAN_API int srsran_mat_2x2_cn(cf_t h00, cf_t h01, cf_t h10, cf_t h11, float* cn);
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#ifdef LV_HAVE_SSE
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/* SSE implementation for complex reciprocal */
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SRSRAN_API __m128 srsran_mat_cf_recip_sse(__m128 a);
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/* SSE implementation for 2x2 determinant */
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SRSRAN_API __m128 srsran_mat_2x2_det_sse(__m128 a00, __m128 a01, __m128 a10, __m128 a11);
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#endif /* LV_HAVE_SSE */
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#ifdef LV_HAVE_AVX
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/* AVX implementation for complex reciprocal */
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SRSRAN_API __m256 srsran_mat_cf_recip_avx(__m256 a);
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/* AVX implementation for 2x2 determinant */
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SRSRAN_API __m256 srsran_mat_2x2_det_avx(__m256 a00, __m256 a01, __m256 a10, __m256 a11);
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#endif /* LV_HAVE_AVX */
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#if SRSRAN_SIMD_CF_SIZE != 0
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/* Generic SIMD implementation for 2x2 determinant */
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static inline simd_cf_t srsran_mat_2x2_det_simd(simd_cf_t a00, simd_cf_t a01, simd_cf_t a10, simd_cf_t a11)
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{
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return srsran_simd_cf_sub(srsran_simd_cf_prod(a00, a11), srsran_simd_cf_prod(a01, a10));
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}
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/* Generic SIMD implementation for Zero Forcing (ZF) solver */
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static inline void srsran_mat_2x2_zf_csi_simd(simd_cf_t y0,
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simd_cf_t y1,
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simd_cf_t h00,
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simd_cf_t h01,
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simd_cf_t h10,
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simd_cf_t h11,
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simd_cf_t* x0,
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simd_cf_t* x1,
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simd_f_t* csi0,
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simd_f_t* csi1,
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float norm)
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{
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simd_cf_t det = srsran_mat_2x2_det_simd(h00, h01, h10, h11);
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simd_cf_t detrec = srsran_simd_cf_mul(srsran_simd_cf_rcp(det), srsran_simd_f_set1(norm));
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*x0 = srsran_simd_cf_prod(srsran_simd_cf_sub(srsran_simd_cf_prod(h11, y0), srsran_simd_cf_prod(h01, y1)), detrec);
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*x1 = srsran_simd_cf_prod(srsran_simd_cf_sub(srsran_simd_cf_prod(h00, y1), srsran_simd_cf_prod(h10, y0)), detrec);
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*csi0 = srsran_simd_f_set1(1.0f);
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*csi1 = srsran_simd_f_set1(1.0f);
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}
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static inline void srsran_mat_2x2_zf_simd(simd_cf_t y0,
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simd_cf_t y1,
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simd_cf_t h00,
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simd_cf_t h01,
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simd_cf_t h10,
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simd_cf_t h11,
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simd_cf_t* x0,
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simd_cf_t* x1,
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float norm)
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{
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simd_f_t csi1, csi2;
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srsran_mat_2x2_zf_csi_simd(y0, y1, h00, h01, h10, h11, x0, x1, &csi1, &csi2, norm);
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}
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/* Generic SIMD implementation for Minimum Mean Squared Error (MMSE) solver */
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static inline void srsran_mat_2x2_mmse_csi_simd(simd_cf_t y0,
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simd_cf_t y1,
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simd_cf_t h00,
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simd_cf_t h01,
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simd_cf_t h10,
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simd_cf_t h11,
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simd_cf_t* x0,
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simd_cf_t* x1,
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simd_f_t* csi0,
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simd_f_t* csi1,
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float noise_estimate,
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float norm)
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{
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simd_cf_t _noise_estimate;
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simd_f_t _norm = srsran_simd_f_set1(norm);
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#if HAVE_NEON
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_noise_estimate.val[0] = srsran_simd_f_set1(noise_estimate);
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_noise_estimate.val[1] = srsran_simd_f_zero();
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#else /* HAVE_NEON */
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_noise_estimate.re = srsran_simd_f_set1(noise_estimate);
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_noise_estimate.im = srsran_simd_f_zero();
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#endif /* HAVE_NEON */
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/* 1. A = H' x H + No*/
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simd_cf_t a00 = srsran_simd_cf_add(
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srsran_simd_cf_add(srsran_simd_cf_conjprod(h00, h00), srsran_simd_cf_conjprod(h10, h10)), _noise_estimate);
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simd_cf_t a01 = srsran_simd_cf_add(srsran_simd_cf_conjprod(h01, h00), srsran_simd_cf_conjprod(h11, h10));
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simd_cf_t a10 = srsran_simd_cf_add(srsran_simd_cf_conjprod(h00, h01), srsran_simd_cf_conjprod(h10, h11));
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simd_cf_t a11 = srsran_simd_cf_add(
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srsran_simd_cf_add(srsran_simd_cf_conjprod(h01, h01), srsran_simd_cf_conjprod(h11, h11)), _noise_estimate);
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simd_cf_t a_det_rcp = srsran_simd_cf_rcp(srsran_mat_2x2_det_simd(a00, a01, a10, a11));
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/* 2. B = inv(H' x H + No) = inv(A) */
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simd_cf_t _norm2 = srsran_simd_cf_mul(a_det_rcp, _norm);
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simd_cf_t b00 = srsran_simd_cf_prod(a11, _norm2);
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simd_cf_t b01 = srsran_simd_cf_prod(srsran_simd_cf_neg(a01), _norm2);
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simd_cf_t b10 = srsran_simd_cf_prod(srsran_simd_cf_neg(a10), _norm2);
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simd_cf_t b11 = srsran_simd_cf_prod(a00, _norm2);
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/* 3. W = inv(H' x H + No) x H' = B x H' */
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simd_cf_t w00 = srsran_simd_cf_add(srsran_simd_cf_conjprod(b00, h00), srsran_simd_cf_conjprod(b01, h01));
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simd_cf_t w01 = srsran_simd_cf_add(srsran_simd_cf_conjprod(b00, h10), srsran_simd_cf_conjprod(b01, h11));
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simd_cf_t w10 = srsran_simd_cf_add(srsran_simd_cf_conjprod(b10, h00), srsran_simd_cf_conjprod(b11, h01));
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simd_cf_t w11 = srsran_simd_cf_add(srsran_simd_cf_conjprod(b10, h10), srsran_simd_cf_conjprod(b11, h11));
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/* 4. X = W x Y */
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*x0 = srsran_simd_cf_add(srsran_simd_cf_prod(y0, w00), srsran_simd_cf_prod(y1, w01));
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*x1 = srsran_simd_cf_add(srsran_simd_cf_prod(y0, w10), srsran_simd_cf_prod(y1, w11));
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/* 5. Extract CSI */
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*csi0 = srsran_simd_f_rcp(srsran_simd_cf_re(b00));
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*csi1 = srsran_simd_f_rcp(srsran_simd_cf_re(b11));
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}
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static inline void srsran_mat_2x2_mmse_simd(simd_cf_t y0,
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simd_cf_t y1,
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simd_cf_t h00,
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simd_cf_t h01,
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simd_cf_t h10,
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simd_cf_t h11,
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simd_cf_t* x0,
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simd_cf_t* x1,
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float noise_estimate,
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float norm)
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{
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simd_f_t csi0, csi1;
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srsran_mat_2x2_mmse_csi_simd(y0, y1, h00, h01, h10, h11, x0, x1, &csi0, &csi1, noise_estimate, norm);
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}
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#endif /* SRSRAN_SIMD_CF_SIZE != 0 */
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typedef struct {
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uint32_t N;
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cf_t* row_buffer;
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cf_t* matrix;
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} srsran_matrix_NxN_inv_t;
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SRSRAN_API int srsran_matrix_NxN_inv_init(srsran_matrix_NxN_inv_t* q, uint32_t N);
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SRSRAN_API void srsran_matrix_NxN_inv_run(srsran_matrix_NxN_inv_t* q, cf_t* in, cf_t* out);
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SRSRAN_API void srsran_matrix_NxN_inv_free(srsran_matrix_NxN_inv_t* q);
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#endif /* SRSRAN_MAT_H */
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