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Camera_driver: refactored version of camera driver

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This commit is contained in:
Petr Malanik
2023-01-23 19:36:57 +01:00
parent 34b9eaafc2
commit d99e4b27e6
1292 changed files with 1100905 additions and 0 deletions
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101
resources/FC_camera/Drivers/CMSIS/NN/Source/ActivationFunctions/arm_nn_activations_q15.c Normal file
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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_nn_activations_q15.c
* Description: Q15 neural network activation function using direct table look-up
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_common_tables.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup Acti
* @{
*/
/**
* @brief Q15 neural network activation function using direct table look-up
* @param[in,out] data pointer to input
* @param[in] size number of elements
* @param[in] int_width bit-width of the integer part, assume to be smaller than 3
* @param[in] type type of activation functions
* @return none.
*
* @details
*
* This is the direct table look-up approach.
*
* Assume here the integer part of the fixed-point is <= 3.
* More than 3 just not making much sense, makes no difference with
* saturation followed by any of these activation functions.
*/
void arm_nn_activations_direct_q15(q15_t * data, uint16_t size, uint16_t int_width, arm_nn_activation_type type)
{
uint16_t i = size;
q15_t *pIn = data;
q15_t *pOut = data;
uint16_t shift_size = 8 + 3 - int_width;
uint32_t bit_mask = 0x7FF >> int_width;
uint32_t full_frac = bit_mask + 1;
const q15_t *lookup_table;
switch (type)
{
case ARM_SIGMOID:
lookup_table = sigmoidTable_q15;
break;
case ARM_TANH:
default:
lookup_table = tanhTable_q15;
break;
}
while (i)
{
q15_t out;
q15_t in = *pIn++;
q15_t frac = (uint32_t) in & bit_mask;
q15_t value = lookup_table[__USAT(in >> shift_size, 8)];
q15_t value2 = lookup_table[__USAT(1 + (in >> shift_size), 8)];
/* doing the interpolation here for better accuracy */
out = ((q31_t) (full_frac - frac) * value + (q31_t) value2 * frac) >> shift_size;
*pOut++ = out;
i--;
}
}
/**
* @} end of Acti group
*/

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resources/FC_camera/Drivers/CMSIS/NN/Source/ActivationFunctions/arm_nn_activations_q7.c Normal file
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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_nn_activations_q7.c
* Description: Q7 neural network activation function using direct table look-up
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_common_tables.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup Acti
* @{
*/
/**
* @brief Q7 neural network activation function using direct table look-up
* @param[in,out] data pointer to input
* @param[in] size number of elements
* @param[in] int_width bit-width of the integer part, assume to be smaller than 3
* @param[in] type type of activation functions
* @return none.
*
* @details
*
* This is the direct table look-up approach.
*
* Assume here the integer part of the fixed-point is <= 3.
* More than 3 just not making much sense, makes no difference with
* saturation followed by any of these activation functions.
*/
void arm_nn_activations_direct_q7(q7_t * data, uint16_t size, uint16_t int_width, arm_nn_activation_type type)
{
uint16_t i = size;
q7_t *pIn = data;
q7_t *pOut = data;
q7_t in;
q7_t out;
uint16_t shift_size = 3 - int_width;
const q7_t *lookup_table;
switch (type)
{
case ARM_SIGMOID:
lookup_table = sigmoidTable_q7;
break;
case ARM_TANH:
default:
lookup_table = tanhTable_q7;
break;
}
while (i)
{
in = *pIn++;
out = lookup_table[(uint8_t) (in >> shift_size)];
*pOut++ = out;
i--;
}
}
/**
* @} end of Acti group
*/

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resources/FC_camera/Drivers/CMSIS/NN/Source/ActivationFunctions/arm_relu_q15.c Normal file
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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_relu_q15.c
* Description: Q15 version of ReLU
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup Acti
* @{
*/
/**
* @brief Q15 RELU function
* @param[in,out] data pointer to input
* @param[in] size number of elements
* @return none.
*
* @details
*
* Optimized relu with QSUB instructions.
*
*/
void arm_relu_q15(q15_t * data, uint16_t size)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
uint16_t i = size >> 1;
q15_t *pIn = data;
q15_t *pOut = data;
q31_t in;
q31_t buf;
q31_t mask;
while (i)
{
in = *__SIMD32(pIn)++;
/* extract the first bit */
buf = __ROR(in & 0x80008000, 15);
/* if MSB=1, mask will be 0xFF, 0x0 otherwise */
mask = __QSUB16(0x00000000, buf);
*__SIMD32(pOut)++ = in & (~mask);
i--;
}
if (size & 0x1)
{
if (*pIn < 0)
{
*pIn = 0;
}
pIn++;
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i;
for (i = 0; i < size; i++)
{
if (data[i] < 0)
data[i] = 0;
}
#endif /* ARM_MATH_DSP */
}
/**
* @} end of Acti group
*/

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resources/FC_camera/Drivers/CMSIS/NN/Source/ActivationFunctions/arm_relu_q7.c Normal file
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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_relu_q7.c
* Description: Q7 version of ReLU
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup Acti
* @{
*/
/**
* @brief Q7 RELU function
* @param[in,out] data pointer to input
* @param[in] size number of elements
* @return none.
*
* @details
*
* Optimized relu with QSUB instructions.
*
*/
void arm_relu_q7(q7_t * data, uint16_t size)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
uint16_t i = size >> 2;
q7_t *pIn = data;
q7_t *pOut = data;
q31_t in;
q31_t buf;
q31_t mask;
while (i)
{
in = *__SIMD32(pIn)++;
/* extract the first bit */
buf = __ROR(in & 0x80808080, 7);
/* if MSB=1, mask will be 0xFF, 0x0 otherwise */
mask = __QSUB8(0x00000000, buf);
*__SIMD32(pOut)++ = in & (~mask);
i--;
}
i = size & 0x3;
while (i)
{
if (*pIn < 0)
{
*pIn = 0;
}
pIn++;
i--;
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i;
for (i = 0; i < size; i++)
{
if (data[i] < 0)
data[i] = 0;
}
#endif /* ARM_MATH_DSP */
}
/**
* @} end of Acti group
*/

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resources/FC_camera/Drivers/CMSIS/NN/Source/ConvolutionFunctions/arm_convolve_1x1_HWC_q7_fast_nonsquare.c Normal file
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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_1x1_HWC_q7_fast_nonsquare.c
* Description: Fast Q7 version of 1x1 convolution (non-square shape)
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Fast Q7 version of 1x1 convolution (non-sqaure shape)
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in_x input tensor dimention x
* @param[in] dim_im_in_y input tensor dimention y
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel_x filter kernel size x
* @param[in] dim_kernel_y filter kernel size y
* @param[in] padding_x padding size x
* @param[in] padding_y padding size y
* @param[in] stride_x convolution stride x
* @param[in] stride_y convolution stride y
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out_x output tensor dimension x
* @param[in] dim_im_out_y output tensor dimension y
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns either
* <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
*
* This function is optimized for convolution with 1x1 kernel size (i.e., dim_kernel_x=1
* and dim_kernel_y=1). It can be used for the second half of MobileNets [1] after depthwise
* separable convolution.
*
* This function is the version with full list of optimization tricks, but with
* some contraints:
* ch_im_in is multiple of 4
* ch_im_out is multiple of 2
*
* [1] MobileNets: Efficient Convolutional Neural Networks for Mobile Vision Applications
* https://arxiv.org/abs/1704.04861
*/
arm_status arm_convolve_1x1_HWC_q7_fast_nonsquare(const q7_t * Im_in,
const uint16_t dim_im_in_x,
const uint16_t dim_im_in_y,
const uint16_t ch_im_in,
const q7_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel_x,
const uint16_t dim_kernel_y,
const uint16_t padding_x,
const uint16_t padding_y,
const uint16_t stride_x,
const uint16_t stride_y,
const q7_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q7_t * Im_out,
const uint16_t dim_im_out_x,
const uint16_t dim_im_out_y,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_out_y, i_out_x;
int16_t i_ch_out;
/* -----------------------
* Here we use bufferA as q15_t internally as computation are done with q15_t level
* im2col are done to output in q15_t format from q7_t input
*/
q15_t *pBuffer = bufferA;
q7_t *pOut = Im_out;
if (ch_im_in % 4 != 0 || ch_im_out % 2 != 0 || dim_kernel_x != 1 || dim_kernel_y != 1
|| padding_x != 0 || padding_y != 0 || stride_x != 1 || stride_y != 1)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
for (i_out_y = 0; i_out_y < dim_im_out_y; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out_x; i_out_x++)
{
/* This part implements the im2col function */
arm_q7_to_q15_reordered_no_shift((q7_t *) Im_in + (i_out_y * dim_im_in_x + i_out_x) * ch_im_in, pBuffer,
ch_im_in);
pBuffer += ch_im_in;
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel_x * dim_kernel_y)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt, bufferA, ch_im_out, ch_im_in, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
/* check if there is left-over for compute */
if (pBuffer != bufferA)
{
const q7_t *pA = wt;
for (i_ch_out = 0; i_ch_out < ch_im_out; i_ch_out++)
{
q31_t sum = ((q31_t)(bias[i_ch_out]) << bias_shift) + NN_ROUND(out_shift);
q15_t *pB = bufferA;
/* basically each time it process 4 entries */
uint16_t colCnt = ch_im_in * dim_kernel_x * dim_kernel_y >> 2;
while (colCnt)
{
q31_t inA1, inA2;
q31_t inB1, inB2;
pA = (const q7_t *)read_and_pad_reordered((void *)pA, &inA1, &inA2);
inB1 = *__SIMD32(pB)++;
sum = __SMLAD(inA1, inB1, sum);
inB2 = *__SIMD32(pB)++;
sum = __SMLAD(inA2, inB2, sum);
colCnt--;
}
colCnt = ch_im_in * dim_kernel_y * dim_kernel_x & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
sum += inA1 * inB1;
colCnt--;
}
*pOut = (q7_t) __SSAT((sum >> out_shift), 8);
pOut++;
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
int i, j, k, l, m, n;
int conv_out;
int in_row, in_col;
if (ch_im_in % 4 != 0 || ch_im_out % 2 != 0 || dim_kernel_x != 1 || dim_kernel_y != 1
|| padding_x != 0 || padding_y != 0 || stride_x != 1 || stride_y != 1)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out_y; j++)
{
for (k = 0; k < dim_im_out_x; k++)
{
conv_out = ((q31_t)(bias[i]) << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel_y; m++)
{
for (n = 0; n < dim_kernel_x; n++)
{
// if-for implementation
in_row = stride_y * j + m - padding_y;
in_col = stride_x * k + n - padding_x;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in_y && in_col < dim_im_in_x)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out += Im_in[(in_row * dim_im_in_x + in_col) * ch_im_in + l] *
wt[i * ch_im_in * dim_kernel_y * dim_kernel_x + (m * dim_kernel_y + n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out_x + k) * ch_im_out] = (q7_t) __SSAT((conv_out >> out_shift), 8);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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resources/FC_camera/Drivers/CMSIS/NN/Source/ConvolutionFunctions/arm_convolve_HWC_q15_basic.c Normal file
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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_HWC_q15_basic.c
* Description: Q15 version of convolution
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Basic Q15 convolution function
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in input tensor dimention
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel filter kernel size
* @param[in] padding padding sizes
* @param[in] stride convolution stride
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out output tensor dimension
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: ch_im_in*dim_kernel*dim_kernel
*
* bufferB size: 0
*
* This basic version is designed to work for any input tensor and weight
* dimension.
*/
arm_status
arm_convolve_HWC_q15_basic(const q15_t * Im_in,
const uint16_t dim_im_in,
const uint16_t ch_im_in,
const q15_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel,
const uint16_t padding,
const uint16_t stride,
const q15_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q15_t * Im_out,
const uint16_t dim_im_out,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_out_y, i_out_x, i_ker_y, i_ker_x;
uint16_t im2col_out_pixel_index = 0;
q15_t *pBuffer = bufferA;
q15_t *pOut = Im_out;
q15_t *im_buffer = bufferA;
const q15_t *pA;
int i;
/* This part implements the im2col function */
for (i_out_y = 0; i_out_y < dim_im_out; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out; i_out_x++)
{
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in || i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* Filling 0 for out-of-bound paddings */
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
/* arm_copy_q15((q15_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, pBuffer, ch_im_in); */
memcpy(pBuffer, (q15_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, sizeof(q15_t)*ch_im_in);
}
pBuffer += ch_im_in;
}
}
pA = wt;
for (i = 0; i < ch_im_out; i++)
{
q31_t sum = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
q15_t *pB = im_buffer;
uint16_t colCnt = ch_im_in * dim_kernel * dim_kernel >> 2;
while (colCnt)
{
q31_t inA1 = *__SIMD32(pA)++;
q31_t inB1 = *__SIMD32(pB)++;
q31_t inA2 = *__SIMD32(pA)++;
q31_t inB2 = *__SIMD32(pB)++;
sum = __SMLAD(inA1, inB1, sum);
sum = __SMLAD(inA2, inB2, sum);
colCnt--;
}
colCnt = ch_im_in * dim_kernel * dim_kernel & 0x3;
while (colCnt)
{
q15_t inA1 = *pA++;
q15_t inB1 = *pB++;
sum += inA1 * inB1;
colCnt--;
}
*pOut = (q15_t) __SSAT((sum >> out_shift), 16);
pOut++;
}
/* counter reset */
pBuffer = im_buffer;
im2col_out_pixel_index++;
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i, j, k, l, m, n;
int conv_out;
signed char in_row, in_col;
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out; j++)
{
for (k = 0; k < dim_im_out; k++)
{
conv_out = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel; m++)
{
for (n = 0; n < dim_kernel; n++)
{
in_row = stride * j + m - padding;
in_col = stride * k + n - padding;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in && in_col < dim_im_in)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out +=
Im_in[(in_row * dim_im_in + in_col) * ch_im_in +
l] * wt[i * ch_im_in * dim_kernel * dim_kernel + (m * dim_kernel +
n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out + k) * ch_im_out] = (q15_t) __SSAT((conv_out >> out_shift), 16);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_HWC_q15_fast.c
* Description: Fast Q15 version of convolution
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Fast Q15 convolution function
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in input tensor dimention
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel filter kernel size
* @param[in] padding padding sizes
* @param[in] stride convolution stride
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out output tensor dimension
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns either
* <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: 2*ch_im_in*dim_kernel*dim_kernel
*
* bufferB size: 0
*
* <b>Input dimension constraints:</b>
*
* ch_im_in is multiple of 2
*
* ch_im_out is multipe of 2
*
*/
arm_status
arm_convolve_HWC_q15_fast(const q15_t * Im_in,
const uint16_t dim_im_in,
const uint16_t ch_im_in,
const q15_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel,
const uint16_t padding,
const uint16_t stride,
const q15_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q15_t * Im_out,
const uint16_t dim_im_out,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
int16_t i_out_y, i_out_x, i_ker_y, i_ker_x;
q15_t *pBuffer = bufferA;
q15_t *im_buffer = bufferA;
q15_t *pOut = Im_out;
if (ch_im_in % 2 != 0 || ch_im_out % 2 != 0)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
/* Run the following code for Cortex-M4 and Cortex-M7 */
/* This part implements the im2col function */
for (i_out_y = 0; i_out_y < dim_im_out; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out; i_out_x++)
{
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in || i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
/* arm_copy_q15((q15_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, pBuffer, ch_im_in); */
memcpy(pBuffer, (q15_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, sizeof(q15_t)*ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (i_out_x & 0x1)
{
int i;
/* initialize the matrix pointers for A */
const q15_t *pA = wt;
/* set up the second output pointers */
q15_t *pOut2 = pOut + ch_im_out;
/* this loop over rows in A */
for (i = 0; i < ch_im_out; i += 2)
{
/* setup pointers for B */
q15_t *pB = im_buffer;
const q15_t *pB2 = pB + ch_im_in * dim_kernel * dim_kernel;
/* aling the second pointer for A */
const q15_t *pA2 = pA + ch_im_in * dim_kernel * dim_kernel;
/* init the sum with bias */
q31_t sum = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)bias[i + 1] << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)bias[i + 1] << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = ch_im_in * dim_kernel * dim_kernel >> 1;
/* accumulate over the vector */
while (colCnt)
{
q31_t inA1 = *__SIMD32(pA)++;
q31_t inB1 = *__SIMD32(pB)++;
q31_t inA2 = *__SIMD32(pA2)++;
q31_t inB2 = *__SIMD32(pB2)++;
sum = __SMLAD(inA1, inB1, sum);
sum2 = __SMLAD(inA1, inB2, sum2);
sum3 = __SMLAD(inA2, inB1, sum3);
sum4 = __SMLAD(inA2, inB2, sum4);
colCnt--;
} /* while over colCnt */
colCnt = ch_im_in * dim_kernel * dim_kernel & 0x1;
while (colCnt)
{
q15_t inA1 = *pA++;
q15_t inB1 = *pB++;
q15_t inA2 = *pA2++;
q15_t inB2 = *pB2++;
sum += inA1 * inB1;
sum2 += inA1 * inB2;
sum3 += inA2 * inB1;
sum4 += inA2 * inB2;
colCnt--;
} /* while over colCnt */
*pOut++ = (q15_t) __SSAT(sum >> out_shift, 16);
*pOut++ = (q15_t) __SSAT(sum3 >> out_shift, 16);
*pOut2++ = (q15_t) __SSAT(sum2 >> out_shift, 16);
*pOut2++ = (q15_t) __SSAT(sum4 >> out_shift, 16);
/* skip the row computed with A2 */
pA += ch_im_in * dim_kernel * dim_kernel;
} /* for over ch_im_out */
pOut += ch_im_out;
/* counter reset */
pBuffer = im_buffer;
}
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i, j, k, l, m, n;
int conv_out;
signed char in_row, in_col;
if (ch_im_in % 2 != 0 || ch_im_out % 2 != 0)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out; j++)
{
for (k = 0; k < dim_im_out; k++)
{
conv_out = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel; m++)
{
for (n = 0; n < dim_kernel; n++)
{
in_row = stride * j + m - padding;
in_col = stride * k + n - padding;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in && in_col < dim_im_in)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out +=
Im_in[(in_row * dim_im_in + in_col) * ch_im_in +
l] * wt[i * ch_im_in * dim_kernel * dim_kernel + (m * dim_kernel +
n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out + k) * ch_im_out] = (q15_t) __SSAT((conv_out >> out_shift), 16);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_HWC_q15_fast.c
* Description: Fast Q15 version of convolution
*
* $Date: 24. May 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Fast Q15 convolution function (non-sqaure shape)
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in_x input tensor dimention x
* @param[in] dim_im_in_y input tensor dimention y
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel_x filter kernel size x
* @param[in] dim_kernel_y filter kernel size y
* @param[in] padding_x padding size x
* @param[in] padding_y padding size y
* @param[in] stride_x convolution stride x
* @param[in] stride_y convolution stride y
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out_x output tensor dimension x
* @param[in] dim_im_out_y output tensor dimension y
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns either
* <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: 2*ch_im_in*dim_kernel*dim_kernel
*
* bufferB size: 0
*
* <b>Input dimension constraints:</b>
*
* ch_im_in is multiple of 2
*
* ch_im_out is multipe of 2
*
*/
arm_status
arm_convolve_HWC_q15_fast_nonsquare(const q15_t * Im_in,
const uint16_t dim_im_in_x,
const uint16_t dim_im_in_y,
const uint16_t ch_im_in,
const q15_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel_x,
const uint16_t dim_kernel_y,
const uint16_t padding_x,
const uint16_t padding_y,
const uint16_t stride_x,
const uint16_t stride_y,
const q15_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q15_t * Im_out,
const uint16_t dim_im_out_x,
const uint16_t dim_im_out_y,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
int16_t i_out_y, i_out_x, i_ker_y, i_ker_x;
q15_t *pBuffer = bufferA;
q15_t *im_buffer = bufferA;
q15_t *pOut = Im_out;
if (ch_im_in % 2 != 0 || ch_im_out % 2 != 0)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
/* Run the following code for Cortex-M4 and Cortex-M7 */
/* This part implements the im2col function */
for (i_out_y = 0; i_out_y < dim_im_out_y; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out_x; i_out_x++)
{
for (i_ker_y = i_out_y * stride_y - padding_y; i_ker_y < i_out_y * stride_y - padding_y + dim_kernel_y; i_ker_y++)
{
for (i_ker_x = i_out_x * stride_x - padding_x; i_ker_x < i_out_x * stride_x - padding_x + dim_kernel_x; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in_y || i_ker_x < 0 || i_ker_x >= dim_im_in_x)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
/* arm_copy_q15((q15_t *) Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in, pBuffer, ch_im_in); */
memcpy(pBuffer, (q15_t *) Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in, sizeof(q15_t)*ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (i_out_x & 0x1)
{
int i;
/* initialize the matrix pointers for A */
const q15_t *pA = wt;
/* set up the second output pointers */
q15_t *pOut2 = pOut + ch_im_out;
/* this loop over rows in A */
for (i = 0; i < ch_im_out; i += 2)
{
/* setup pointers for B */
q15_t *pB = im_buffer;
const q15_t *pB2 = pB + ch_im_in * dim_kernel_y * dim_kernel_x;
/* aling the second pointer for A */
const q15_t *pA2 = pA + ch_im_in * dim_kernel_y * dim_kernel_x;
/* init the sum with bias */
q31_t sum = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)bias[i + 1] << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)bias[i + 1] << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = ch_im_in * dim_kernel_y * dim_kernel_x >> 1;
/* accumulate over the vector */
while (colCnt)
{
q31_t inA1 = *__SIMD32(pA)++;
q31_t inB1 = *__SIMD32(pB)++;
q31_t inA2 = *__SIMD32(pA2)++;
q31_t inB2 = *__SIMD32(pB2)++;
sum = __SMLAD(inA1, inB1, sum);
sum2 = __SMLAD(inA1, inB2, sum2);
sum3 = __SMLAD(inA2, inB1, sum3);
sum4 = __SMLAD(inA2, inB2, sum4);
colCnt--;
} /* while over colCnt */
colCnt = ch_im_in * dim_kernel_y * dim_kernel_x & 0x1;
while (colCnt)
{
q15_t inA1 = *pA++;
q15_t inB1 = *pB++;
q15_t inA2 = *pA2++;
q15_t inB2 = *pB2++;
sum += inA1 * inB1;
sum2 += inA1 * inB2;
sum3 += inA2 * inB1;
sum4 += inA2 * inB2;
colCnt--;
} /* while over colCnt */
*pOut++ = (q15_t) __SSAT(sum >> out_shift, 16);
*pOut++ = (q15_t) __SSAT(sum3 >> out_shift, 16);
*pOut2++ = (q15_t) __SSAT(sum2 >> out_shift, 16);
*pOut2++ = (q15_t) __SSAT(sum4 >> out_shift, 16);
/* skip the row computed with A2 */
pA += ch_im_in * dim_kernel_y * dim_kernel_x;
} /* for over ch_im_out */
pOut += ch_im_out;
/* counter reset */
pBuffer = im_buffer;
}
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i, j, k, l, m, n;
int conv_out;
signed char in_row, in_col;
if (ch_im_in % 2 != 0 || ch_im_out % 2 != 0)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out_y; j++)
{
for (k = 0; k < dim_im_out_x; k++)
{
conv_out = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel_y; m++)
{
for (n = 0; n < dim_kernel_x; n++)
{
in_row = stride_y * j + m - padding_y;
in_col = stride_x * k + n - padding_x;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in_y && in_col < dim_im_in_x)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out +=
Im_in[(in_row * dim_im_in_x + in_col) * ch_im_in +
l] * wt[i * ch_im_in * dim_kernel_x * dim_kernel_y + (m * dim_kernel_x +
n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out_x + k) * ch_im_out] = (q15_t) __SSAT((conv_out >> out_shift), 16);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_HWC_q7_RGB.c
* Description: Q7 version of convolution for RGB image
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Q7 convolution function for RGB image
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in input tensor dimention
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel filter kernel size
* @param[in] padding padding sizes
* @param[in] stride convolution stride
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out output tensor dimension
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns either
* <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: 2*ch_im_in*dim_kernel*dim_kernel
*
* bufferB size: 0
*
* <b>Input dimension constraints:</b>
*
* ch_im_in equals 3
*
* This kernel is written exclusively for convolution with ch_im_in
* equals 3. This applies on the first layer of CNNs which has input
* image with RGB format.
*/
arm_status
arm_convolve_HWC_q7_RGB(const q7_t * Im_in,
const uint16_t dim_im_in,
const uint16_t ch_im_in,
const q7_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel,
const uint16_t padding,
const uint16_t stride,
const q7_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q7_t * Im_out, const uint16_t dim_im_out, q15_t * bufferA, q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_out_y, i_out_x, i_ker_y, i_ker_x;
/*
* Here we use bufferA as q15_t internally as computation are done with q15_t level
* im2col are done to output in q15_t format from q7_t input
*/
q15_t *pBuffer = bufferA;
q7_t *pOut = Im_out;
// check if number of input channels is 3
if (ch_im_in != 3)
{
return ARM_MATH_SIZE_MISMATCH;
}
// This part implements the im2col function
for (i_out_y = 0; i_out_y < dim_im_out; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out; i_out_x++)
{
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in || i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* Equivalent to arm_fill_q15(0, pBuffer, ch_im_in) with assumption: ch_im_in = 3 */
*__SIMD32(pBuffer) = 0x0;
*(pBuffer + 2) = 0;
pBuffer += 3;
} else
{
/*
* Equivalent to:
* arm_q7_to_q15_no_shift( (q7_t*)Im_in+(i_ker_y*dim_im_in+i_ker_x)*3, pBuffer, 3);
*/
const q7_t *pPixel = Im_in + (i_ker_y * dim_im_in + i_ker_x) * 3;
q31_t buf = *__SIMD32(pPixel);
union arm_nnword top;
union arm_nnword bottom;
top.word = __SXTB16(buf);
bottom.word = __SXTB16(__ROR(buf, 8));
#ifndef ARM_MATH_BIG_ENDIAN
/*
* little-endian, | omit | 3rd | 2nd | 1st |
* MSB LSB
* top | 3rd | 1st |; bottom | omit | 2nd |
*
* version 1, need to swap 2nd and 3rd weight
* *__SIMD32(pBuffer) = top.word;
* *(pBuffer+2) = bottom.half_words[0];
*
* version 2, no weight shuffling required
*/
*pBuffer++ = top.half_words[0];
*__SIMD32(pBuffer) = __PKHBT(bottom.word, top.word, 0);
#else
/*
* big-endian, | 1st | 2nd | 3rd | omit |
* MSB LSB
* top | 2nd | omit |; bottom | 1st | 3rd |
*
* version 1, need to swap 2nd and 3rd weight
* *__SIMD32(pBuffer) = bottom.word;
* *(pBuffer+2) = top.half_words[1];
*
* version 2, no weight shuffling required
*/
*pBuffer++ = bottom.half_words[0];
*__SIMD32(pBuffer) = __PKHTB(top.word, bottom.word, 0);
#endif
pBuffer += 2;
}
}
}
if (pBuffer == bufferA + 2 * 3 * dim_kernel * dim_kernel)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15(wt, bufferA,
ch_im_out,
3 * dim_kernel * dim_kernel, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
/* left-over because odd number of output pixels */
if (pBuffer != bufferA)
{
const q7_t *pA = wt;
int i;
for (i = 0; i < ch_im_out; i++)
{
q31_t sum = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
q15_t *pB = bufferA;
/* basically each time it process 4 entries */
uint16_t colCnt = 3 * dim_kernel * dim_kernel >> 2;
while (colCnt)
{
q31_t inA1, inA2;
q31_t inB1, inB2;
pA = (q7_t *) read_and_pad((void *)pA, &inA1, &inA2);
inB1 = *__SIMD32(pB)++;
sum = __SMLAD(inA1, inB1, sum);
inB2 = *__SIMD32(pB)++;
sum = __SMLAD(inA2, inB2, sum);
colCnt--;
}
colCnt = 3 * dim_kernel * dim_kernel & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
sum += inA1 * inB1;
colCnt--;
}
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i, j, k, l, m, n;
int conv_out;
signed char in_row, in_col;
// check if number of input channels is 3
if (ch_im_in != 3)
{
return ARM_MATH_SIZE_MISMATCH;
}
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out; j++)
{
for (k = 0; k < dim_im_out; k++)
{
conv_out = (bias[i] << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel; m++)
{
for (n = 0; n < dim_kernel; n++)
{
/* if-for implementation */
in_row = stride * j + m - padding;
in_col = stride * k + n - padding;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in && in_col < dim_im_in)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out +=
Im_in[(in_row * dim_im_in + in_col) * ch_im_in +
l] * wt[i * ch_im_in * dim_kernel * dim_kernel + (m * dim_kernel +
n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out + k) * ch_im_out] = (q7_t) __SSAT((conv_out >> out_shift), 8);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return (ARM_MATH_SUCCESS);
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_HWC_q7_basic.c
* Description: Q7 version of convolution
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Basic Q7 convolution function
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in input tensor dimention
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel filter kernel size
* @param[in] padding padding sizes
* @param[in] stride convolution stride
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out output tensor dimension
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: 2*ch_im_in*dim_kernel*dim_kernel
*
* bufferB size: 0
*
* This basic version is designed to work for any input tensor and weight
* dimension.
*/
arm_status
arm_convolve_HWC_q7_basic(const q7_t * Im_in,
const uint16_t dim_im_in,
const uint16_t ch_im_in,
const q7_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel,
const uint16_t padding,
const uint16_t stride,
const q7_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q7_t * Im_out,
const uint16_t dim_im_out,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_out_y, i_out_x, i_ker_y, i_ker_x;
/*
* Here we use bufferA as q15_t internally as computation are done with q15_t level
* im2col are done to output in q15_t format from q7_t input
*/
q15_t *pBuffer = bufferA;
q7_t *pOut = Im_out;
/* This part implements the im2col function */
for (i_out_y = 0; i_out_y < dim_im_out; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out; i_out_x++)
{
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in || i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* Filling 0 for out-of-bound paddings */
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
/* Copying the pixel data to column */
arm_q7_to_q15_no_shift((q7_t *)
Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
/* Computation is filed for every 2 columns */
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel * dim_kernel)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15(wt, bufferA,
ch_im_out,
ch_im_in *
dim_kernel * dim_kernel, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
/* left-over because odd number of output pixels */
if (pBuffer != bufferA)
{
const q7_t *pA = wt;
int i;
for (i = 0; i < ch_im_out; i++)
{
/* Load the accumulator with bias first */
q31_t sum = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
/* Point to the beging of the im2col buffer */
q15_t *pB = bufferA;
/* Each time it process 4 entries */
uint16_t colCnt = ch_im_in * dim_kernel * dim_kernel >> 2;
while (colCnt)
{
q31_t inA1, inA2;
q31_t inB1, inB2;
pA = (q7_t *) read_and_pad((void *)pA, &inA1, &inA2);
inB1 = *__SIMD32(pB)++;
sum = __SMLAD(inA1, inB1, sum);
inB2 = *__SIMD32(pB)++;
sum = __SMLAD(inA2, inB2, sum);
colCnt--;
}
colCnt = ch_im_in * dim_kernel * dim_kernel & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
sum += inA1 * inB1;
colCnt--;
}
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i, j, k, l, m, n;
int conv_out;
signed char in_row, in_col;
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out; j++)
{
for (k = 0; k < dim_im_out; k++)
{
conv_out = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel; m++)
{
for (n = 0; n < dim_kernel; n++)
{
// if-for implementation
in_row = stride * j + m - padding;
in_col = stride * k + n - padding;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in && in_col < dim_im_in)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out +=
Im_in[(in_row * dim_im_in + in_col) * ch_im_in +
l] * wt[i * ch_im_in * dim_kernel * dim_kernel + (m * dim_kernel +
n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out + k) * ch_im_out] = (q7_t) __SSAT((conv_out >> out_shift), 8);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_HWC_q7_basic.c
* Description: Q7 version of convolution
*
* $Date: 13. July 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Basic Q7 convolution function (non-sqaure shape)
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in_x input tensor dimention x
* @param[in] dim_im_in_y input tensor dimention y
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel_x filter kernel size x
* @param[in] dim_kernel_y filter kernel size y
* @param[in] padding_x padding size x
* @param[in] padding_y padding size y
* @param[in] stride_x convolution stride x
* @param[in] stride_y convolution stride y
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out_x output tensor dimension x
* @param[in] dim_im_out_y output tensor dimension y
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*/
arm_status arm_convolve_HWC_q7_basic_nonsquare(const q7_t * Im_in,
const uint16_t dim_im_in_x,
const uint16_t dim_im_in_y,
const uint16_t ch_im_in,
const q7_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel_x,
const uint16_t dim_kernel_y,
const uint16_t padding_x,
const uint16_t padding_y,
const uint16_t stride_x,
const uint16_t stride_y,
const q7_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q7_t * Im_out,
const uint16_t dim_im_out_x,
const uint16_t dim_im_out_y,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_out_y, i_out_x, i_ker_y, i_ker_x;
/*
* Here we use bufferA as q15_t internally as computation are done with q15_t level
* im2col are done to output in q15_t format from q7_t input
*/
q15_t *pBuffer = bufferA;
q7_t *pOut = Im_out;
/* This part implements the im2col function */
for (i_out_y = 0; i_out_y < dim_im_out_y; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out_x; i_out_x++)
{
for (i_ker_y = i_out_y * stride_y - padding_y; i_ker_y < i_out_y * stride_y - padding_y + dim_kernel_y; i_ker_y++)
{
for (i_ker_x = i_out_x * stride_x - padding_x; i_ker_x < i_out_x * stride_x - padding_x + dim_kernel_x; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in_y || i_ker_x < 0 || i_ker_x >= dim_im_in_x)
{
/* Filling 0 for out-of-bound paddings */
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
/* Copying the pixel data to column */
arm_q7_to_q15_no_shift((q7_t *)
Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in, pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
/* Computation is filed for every 2 columns */
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel_y * dim_kernel_x)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15(wt, bufferA,
ch_im_out,
ch_im_in *
dim_kernel_y * dim_kernel_x, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
/* left-over because odd number of output pixels */
if (pBuffer != bufferA)
{
const q7_t *pA = wt;
int i;
for (i = 0; i < ch_im_out; i++)
{
/* Load the accumulator with bias first */
q31_t sum = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
/* Point to the beging of the im2col buffer */
q15_t *pB = bufferA;
/* Each time it process 4 entries */
uint16_t colCnt = ch_im_in * dim_kernel_y * dim_kernel_x >> 2;
while (colCnt)
{
q31_t inA1, inA2;
q31_t inB1, inB2;
pA = (q7_t *) read_and_pad((void *)pA, &inA1, &inA2);
inB1 = *__SIMD32(pB)++;
sum = __SMLAD(inA1, inB1, sum);
inB2 = *__SIMD32(pB)++;
sum = __SMLAD(inA2, inB2, sum);
colCnt--;
}
colCnt = ch_im_in * dim_kernel_y * dim_kernel_x & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
sum += inA1 * inB1;
colCnt--;
}
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i, j, k, l, m, n;
int conv_out;
signed char in_row, in_col;
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out_y; j++)
{
for (k = 0; k < dim_im_out_x; k++)
{
conv_out = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel_y; m++)
{
for (n = 0; n < dim_kernel_x; n++)
{
// if-for implementation
in_row = stride_y * j + m - padding_y;
in_col = stride_x * k + n - padding_x;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in_y && in_col < dim_im_in_x)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out +=
Im_in[(in_row * dim_im_in_x + in_col) * ch_im_in + l] *
wt[i * ch_im_in * dim_kernel_y * dim_kernel_x +
(m * dim_kernel_x + n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out_x + k) * ch_im_out] = (q7_t) __SSAT((conv_out >> out_shift), 8);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_HWC_q7_fast.c
* Description: Fast Q7 version of convolution
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Fast Q7 convolution function
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in input tensor dimention
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel filter kernel size
* @param[in] padding padding sizes
* @param[in] stride convolution stride
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out output tensor dimension
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns either
* <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: 2*ch_im_in*dim_kernel*dim_kernel
*
* bufferB size: 0
*
* <b>Input dimension constraints:</b>
*
* ch_im_in is multiple of 4 ( because of the SIMD32 read and swap )
*
* ch_im_out is multipe of 2 ( bacause 2x2 mat_mult kernel )
*
* The im2col converts the Q7 tensor input into Q15 column, which is stored in
* bufferA. There is reordering happenning during this im2col process with
* arm_q7_to_q15_reordered_no_shift. For every four elements, the second and
* third elements are swapped.
*
* The computation kernel arm_nn_mat_mult_kernel_q7_q15_reordered does the
* GEMM computation with the reordered columns.
*
* To speed-up the determination of the padding condition, we split the
* computation into 3x3 parts, i.e., {top, mid, bottom} X {left, mid, right}.
* This reduces the total number of boundary condition checks and improves
* the data copying performance.
*/
arm_status
arm_convolve_HWC_q7_fast(const q7_t * Im_in,
const uint16_t dim_im_in,
const uint16_t ch_im_in,
const q7_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel,
const uint16_t padding,
const uint16_t stride,
const q7_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q7_t * Im_out,
const uint16_t dim_im_out,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_out_y, i_out_x, i_ker_y, i_ker_x;
/*
* Here we use bufferA as q15_t internally as computation are done with q15_t level
* im2col are done to output in q15_t format from q7_t input
*/
q15_t *pBuffer = bufferA;
q7_t *pOut = Im_out;
if (ch_im_in % 4 != 0 || ch_im_out % 2 != 0)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
/*
* Here we split the entire matrix into three regions depending on the padding situation
* Top: i_out_y from 0 to padding - 1
* Middle: i_out_y from padding to dim_im_out-padding-1
* Bottom: i_out_y from dim_im_out-padding to dim_im_out-1
*/
/* top part */
for (i_out_y = 0; i_out_y < padding; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in || i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
arm_q7_to_q15_reordered_no_shift
((q7_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel * dim_kernel)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt,
bufferA,
ch_im_out,
ch_im_in
*
dim_kernel * dim_kernel, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
/* middle part, here we also divide the x into left, mid and right */
for (; i_out_y < dim_im_out - padding; i_out_y++)
{
/* left part */
for (i_out_x = 0; i_out_x < padding; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
arm_q7_to_q15_reordered_no_shift
((q7_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel * dim_kernel)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt,
bufferA,
ch_im_out,
ch_im_in
*
dim_kernel * dim_kernel, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
/* mid part */
for (; i_out_x < dim_im_out - padding; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
arm_q7_to_q15_reordered_no_shift((q7_t *) Im_in
+
(i_ker_y *
dim_im_in +
i_out_x *
stride - padding) * ch_im_in, pBuffer, ch_im_in * dim_kernel);
pBuffer += ch_im_in * dim_kernel;
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel * dim_kernel)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt,
bufferA,
ch_im_out,
ch_im_in
*
dim_kernel * dim_kernel, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
/* right part */
for (; i_out_x < dim_im_out; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
arm_q7_to_q15_reordered_no_shift
((q7_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel * dim_kernel)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt,
bufferA,
ch_im_out,
ch_im_in
*
dim_kernel * dim_kernel, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
for (; i_out_y < dim_im_out; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in || i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
arm_q7_to_q15_reordered_no_shift
((q7_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel * dim_kernel)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt,
bufferA,
ch_im_out,
ch_im_in
*
dim_kernel * dim_kernel, bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
/* check if there is left-over for compute */
if (pBuffer != bufferA)
{
const q7_t *pA = wt;
int i;
for (i = 0; i < ch_im_out; i++)
{
q31_t sum = ((q31_t)bias[i] << bias_shift) + NN_ROUND(out_shift);
q15_t *pB = bufferA;
/* each time it process 4 entries */
uint16_t colCnt = ch_im_in * dim_kernel * dim_kernel >> 2;
while (colCnt)
{
q31_t inA1, inA2;
q31_t inB1, inB2;
pA = (q7_t *) read_and_pad_reordered((void *)pA, &inA1, &inA2);
inB1 = *__SIMD32(pB)++;
sum = __SMLAD(inA1, inB1, sum);
inB2 = *__SIMD32(pB)++;
sum = __SMLAD(inA2, inB2, sum);
colCnt--;
}
colCnt = ch_im_in * dim_kernel * dim_kernel & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
sum += inA1 * inB1;
colCnt--;
}
*pOut = (q7_t) __SSAT((sum >> out_shift), 8);
pOut++;
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t i, j, k, l, m, n;
int conv_out;
signed char in_row, in_col;
if (ch_im_in % 4 != 0 || ch_im_out % 2 != 0)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out; j++)
{
for (k = 0; k < dim_im_out; k++)
{
conv_out = (bias[i] << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel; m++)
{
for (n = 0; n < dim_kernel; n++)
{
// if-for implementation
in_row = stride * j + m - padding;
in_col = stride * k + n - padding;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in && in_col < dim_im_in)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out +=
Im_in[(in_row * dim_im_in + in_col) * ch_im_in +
l] * wt[i * ch_im_in * dim_kernel * dim_kernel + (m * dim_kernel +
n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out + k) * ch_im_out] = (q7_t) __SSAT((conv_out >> out_shift), 8);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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@ -0,0 +1,379 @@
/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_convolve_HWC_q7_fast_nonsquare.c
* Description: Fast Q7 version of convolution (non-sqaure shape)
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Fast Q7 convolution function (non-sqaure shape)
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in_x input tensor dimention x
* @param[in] dim_im_in_y input tensor dimention y
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel_x filter kernel size x
* @param[in] dim_kernel_y filter kernel size y
* @param[in] padding_x padding size x
* @param[in] padding_y padding size y
* @param[in] stride_x convolution stride x
* @param[in] stride_y convolution stride y
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out_x output tensor dimension x
* @param[in] dim_im_out_y output tensor dimension y
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns either
* <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
*
* This function is the version with full list of optimization tricks, but with
* some contraints:
* ch_im_in is multiple of 4
* ch_im_out is multiple of 2
*/
arm_status arm_convolve_HWC_q7_fast_nonsquare(const q7_t * Im_in,
const uint16_t dim_im_in_x,
const uint16_t dim_im_in_y,
const uint16_t ch_im_in,
const q7_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel_x,
const uint16_t dim_kernel_y,
const uint16_t padding_x,
const uint16_t padding_y,
const uint16_t stride_x,
const uint16_t stride_y,
const q7_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q7_t * Im_out,
const uint16_t dim_im_out_x,
const uint16_t dim_im_out_y,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_out_y, i_out_x, i_ker_y, i_ker_x;
/* -----------------------
* Here we use bufferA as q15_t internally as computation are done with q15_t level
* im2col are done to output in q15_t format from q7_t input
*/
q15_t *pBuffer = bufferA;
q7_t *pOut = Im_out;
if (ch_im_in % 4 != 0 || ch_im_out % 2 != 0)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
/*
* Here we split the entire matrix into three regions depending on the padding situation
* Top: i_out_y from 0 to padding - 1
* Middle: i_out_y from padding to dim_im_out-padding-1
* Bottom: i_out_y from dim_im_out-padding to dim_im_out-1
*/
/* top part */
for (i_out_y = 0; i_out_y < padding_y; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out_x; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride_y - padding_y; i_ker_y < i_out_y * stride_y - padding_y + dim_kernel_y;
i_ker_y++)
{
for (i_ker_x = i_out_x * stride_x - padding_x; i_ker_x < i_out_x * stride_x - padding_x + dim_kernel_x;
i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in_y || i_ker_x < 0 || i_ker_x >= dim_im_in_x)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
arm_q7_to_q15_reordered_no_shift((q7_t *) Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in,
pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel_x * dim_kernel_y)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt, bufferA, ch_im_out, ch_im_in * dim_kernel_x * dim_kernel_y,
bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
/* middle part, here we also divide the x into left, mid and right */
for (; i_out_y < dim_im_out_y - padding_y; i_out_y++)
{
/* left part */
for (i_out_x = 0; i_out_x < padding_x; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride_y - padding_y; i_ker_y < i_out_y * stride_y - padding_y + dim_kernel_y;
i_ker_y++)
{
for (i_ker_x = i_out_x * stride_x - padding_x; i_ker_x < i_out_x * stride_x - padding_x + dim_kernel_x;
i_ker_x++)
{
if (i_ker_x < 0 || i_ker_x >= dim_im_in_x)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
arm_q7_to_q15_reordered_no_shift((q7_t *) Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in,
pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel_x * dim_kernel_y)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt, bufferA, ch_im_out, ch_im_in * dim_kernel_x * dim_kernel_y,
bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
/* mid part */
for (; i_out_x < dim_im_out_x - padding_x; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride_y - padding_y; i_ker_y < i_out_y * stride_y - padding_y + dim_kernel_y;
i_ker_y++)
{
arm_q7_to_q15_reordered_no_shift((q7_t *) Im_in +
(i_ker_y * dim_im_in_x + i_out_x * stride_x - padding_x) * ch_im_in,
pBuffer, ch_im_in * dim_kernel_x);
pBuffer += ch_im_in * dim_kernel_x;
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel_x * dim_kernel_y)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt, bufferA, ch_im_out, ch_im_in * dim_kernel_x * dim_kernel_y,
bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
/* right part */
for (; i_out_x < dim_im_out_x; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride_y - padding_y; i_ker_y < i_out_y * stride_y - padding_y + dim_kernel_y;
i_ker_y++)
{
for (i_ker_x = i_out_x * stride_x - padding_x; i_ker_x < i_out_x * stride_x - padding_x + dim_kernel_x;
i_ker_x++)
{
if (i_ker_x < 0 || i_ker_x >= dim_im_in_x)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
arm_q7_to_q15_reordered_no_shift((q7_t *) Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in,
pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel_x * dim_kernel_y)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt, bufferA, ch_im_out, ch_im_in * dim_kernel_x * dim_kernel_y,
bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
for (; i_out_y < dim_im_out_y; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out_x; i_out_x++)
{
/* This part implements the im2col function */
for (i_ker_y = i_out_y * stride_y - padding_y; i_ker_y < i_out_y * stride_y - padding_y + dim_kernel_y;
i_ker_y++)
{
for (i_ker_x = i_out_x * stride_x - padding_x; i_ker_x < i_out_x * stride_x - padding_x + dim_kernel_x;
i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in_y || i_ker_x < 0 || i_ker_x >= dim_im_in_x)
{
/* arm_fill_q15(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, sizeof(q15_t)*ch_im_in);
} else
{
arm_q7_to_q15_reordered_no_shift((q7_t *) Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in,
pBuffer, ch_im_in);
}
pBuffer += ch_im_in;
}
}
if (pBuffer == bufferA + 2 * ch_im_in * dim_kernel_x * dim_kernel_y)
{
pOut =
arm_nn_mat_mult_kernel_q7_q15_reordered(wt, bufferA, ch_im_out, ch_im_in * dim_kernel_x * dim_kernel_y,
bias_shift, out_shift, bias, pOut);
/* counter reset */
pBuffer = bufferA;
}
}
}
/* check if there is left-over for compute */
if (pBuffer != bufferA)
{
const q7_t *pA = wt;
int i;
for (i = 0; i < ch_im_out; i++)
{
q31_t sum = ((q31_t)(bias[i]) << bias_shift) + NN_ROUND(out_shift);
q15_t *pB = bufferA;
/* basically each time it process 4 entries */
uint16_t colCnt = ch_im_in * dim_kernel_x * dim_kernel_y >> 2;
while (colCnt)
{
q31_t inA1, inA2;
q31_t inB1, inB2;
pA = (const q7_t *)read_and_pad_reordered((void *)pA, &inA1, &inA2);
inB1 = *__SIMD32(pB)++;
sum = __SMLAD(inA1, inB1, sum);
inB2 = *__SIMD32(pB)++;
sum = __SMLAD(inA2, inB2, sum);
colCnt--;
}
colCnt = (ch_im_in * dim_kernel_y * dim_kernel_x) & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
sum += inA1 * inB1;
colCnt--;
}
*pOut = (q7_t) __SSAT((sum >> out_shift), 8);
pOut++;
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
int i, j, k, l, m, n;
int conv_out;
int in_row, in_col;
if (ch_im_in % 4 != 0 || ch_im_out % 2 != 0)
{
/* check if the input dimension meets the constraints */
return ARM_MATH_SIZE_MISMATCH;
}
for (i = 0; i < ch_im_out; i++)
{
for (j = 0; j < dim_im_out_y; j++)
{
for (k = 0; k < dim_im_out_x; k++)
{
conv_out = ((q31_t)(bias[i]) << bias_shift) + NN_ROUND(out_shift);
for (m = 0; m < dim_kernel_y; m++)
{
for (n = 0; n < dim_kernel_x; n++)
{
/* if-for implementation */
in_row = stride_y * j + m - padding_y;
in_col = stride_x * k + n - padding_x;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in_y && in_col < dim_im_in_x)
{
for (l = 0; l < ch_im_in; l++)
{
conv_out += Im_in[(in_row * dim_im_in_x + in_col) * ch_im_in + l] *
wt[i * ch_im_in * dim_kernel_y * dim_kernel_x + (m * dim_kernel_x + n) * ch_im_in + l];
}
}
}
}
Im_out[i + (j * dim_im_out_x + k) * ch_im_out] = (q7_t) __SSAT((conv_out >> out_shift), 8);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2019 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_depthwise_conv_u8_basic_ver1.c
* Description: u8 depthwise convolution function
*
* $Date: June, 2019
* $Revision: V.0.8.0
*
* Target : Cortex-M cores with DSP extension
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
#include <stdint.h>
#include <stdio.h>
#define DILATION_X (1)
#define DILATION_Y (1)
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief uint8 depthwise convolution function with asymmetric quantization for even number of channel multiplier
* and input channels. Unless specified otherwise, arguments are mandatory. Both square and non-square inputs
* are accepted.
*
* @param[in] input Pointer to input tensor
* @param[in] input_x Width of input tensor
* @param[in] input_y Height of input tensor
* @param[in] input_ch Channels in input tensor
* @param[in] kernel Pointer to kernel weights
* @param[in] kernel_x Width of kernel
* @param[in] kernel_y Height of kernel
* @param[in] ch_mult Number of channel multiplier
* @param[in] pad_x Padding sizes x
* @param[in] pad_y Padding sizes y
* @param[in] stride_x Convolution stride along the width
* @param[in] stride_y Convolution stride along the height
* @param[in] dilation_x Dilation along width. Not used and intended for future enhancement.
* @param[in] dilation_y Dilation along height. Not used and intended for future enhancement.
* @param[in] bias Pointer to optional bias values. If no bias is
* availble, NULL is expected
* @param[in] input_offset Input tensor zero offset
* @param[in] filter_offset Kernel tensor zero offset
* @param[in] output_offset Output tensor zero offset
* @param[in,out] output Pointer to output tensor
* @param[in] output_x Width of output tensor
* @param[in] output_y Height of output tensor
* @param[in] output_activation_min Minimum value to clamp the output to. Range : {0, 255}
* @param[in] output_activation_max Minimum value to clamp the output to. Range : {0, 255}
* @param[in] out_shift Amount of right-shift for output
* @param[in] out_mult Output multiplier for requantization
* @return The function returns one of the following
* <code>ARM_MATH_SIZE_MISMATCH</code> - Not supported dimension of tensors
* <code>ARM_MATH_SUCCESS</code> - Successful operation
* <code>ARM_MATH_ARGUMENT_ERROR</code> - Implementation not available
*
* <b> Input constraints</b>
* ch_mult is multiple of 2
* kernel_x is multiple of 2
*
*/
arm_status arm_depthwise_conv_u8_basic_ver1(const uint8_t *input,
const uint16_t input_x,
const uint16_t input_y,
const uint16_t input_ch,
const uint8_t *kernel,
const uint16_t kernel_x,
const uint16_t kernel_y,
const int16_t ch_mult,
const int16_t pad_x,
const int16_t pad_y,
const int16_t stride_x,
const int16_t stride_y,
const int16_t dilation_x,
const int16_t dilation_y,
const int32_t *bias,
const int32_t input_offset,
const int32_t filter_offset,
const int32_t output_offset,
uint8_t *output,
const uint16_t output_x,
const uint16_t output_y,
const int32_t output_activation_min,
const int32_t output_activation_max,
const int32_t out_shift,
const int32_t out_mult)
{
arm_status status = ARM_MATH_SUCCESS;
#if defined (ARM_MATH_DSP)
int i_out = 0;
(void)dilation_x;
(void)dilation_y;
const int32_t input_offset_pkd = (input_offset & 0xFFFF) | (input_offset & 0xFFFF) << 16;
const int32_t kernel_offset_pkd = (filter_offset & 0xFFFF) | (filter_offset & 0xFFFF) << 16;
if (0 != ch_mult % 2 || 0 != kernel_x % 2)
{
return ARM_MATH_SIZE_MISMATCH;
}
for (int i_out_y = 0; i_out_y < output_y; i_out_y++)
{
const int16_t base_idx_y = (i_out_y * stride_y) - pad_y;
for (int i_out_x = 0; i_out_x < output_x; i_out_x++)
{
const int16_t base_idx_x = (i_out_x * stride_x) - pad_x;
for (int i_input_ch = 0; i_input_ch < input_ch; i_input_ch++)
{
for (int i_ch_mult = 0; i_ch_mult < ch_mult; i_ch_mult += 2)
{
const int idx_out_ch = i_ch_mult + i_input_ch * ch_mult;
int32_t acc_0 = 0;
int32_t acc_1 = 0;
if (NULL != bias)
{
acc_0 = bias[idx_out_ch];
acc_1 = bias[idx_out_ch + 1];
}
for (int i_ker_y = 0; i_ker_y < kernel_y; i_ker_y++)
{
const int32_t idx_y = base_idx_y + DILATION_Y * i_ker_y;
const int32_t y_in_range = (idx_y >= 0) && (idx_y < input_y);
for (int i_ker_x = 0; i_ker_x < kernel_x; i_ker_x += 2)
{
if (1 == y_in_range)
{
const int32_t idx_x = base_idx_x + DILATION_X * i_ker_x;
const int32_t idx_x1 = base_idx_x + DILATION_X * (i_ker_x + 1);
/* Range check for first input */
if (idx_x >= 0 && idx_x < input_x)
{
const int32_t idx_0 = (idx_y * input_x + idx_x) * input_ch + i_input_ch;
const int32_t ker_idx_0 =
(i_ker_y * kernel_x + i_ker_x) * (input_ch * ch_mult) + idx_out_ch;
const int32_t ker_idx_1 = ker_idx_0 + input_ch * ch_mult;
int32_t input_pkd = input[idx_0] | (input[idx_0 + input_ch] << 16);
int32_t kernel_pkd = kernel[ker_idx_0] | (kernel[ker_idx_1] << 16);
input_pkd = __SADD16(input_pkd, input_offset_pkd);
kernel_pkd = __SADD16(kernel_pkd, kernel_offset_pkd);
/* Range check for second input */
if (idx_x1 >= input_x)
{
input_pkd &= 0xFFFF;
}
acc_0 = __SMLAD(input_pkd, kernel_pkd, acc_0);
kernel_pkd = kernel[ker_idx_0 + 1] | (kernel[ker_idx_1 + 1] << 16);
kernel_pkd = __SADD16(kernel_pkd, kernel_offset_pkd);
acc_1 = __SMLAD(input_pkd, kernel_pkd, acc_1);
}
}
}
}
/* Requantize and clamp output to provided range */
acc_0 = arm_nn_divide_by_power_of_two(arm_nn_sat_doubling_high_mult(
acc_0 * (1 << LEFT_SHIFT(out_shift)), out_mult),
RIGHT_SHIFT(out_shift));
acc_0 += output_offset;
if (output_activation_min > acc_0)
{
acc_0 = output_activation_min;
}
if (acc_0 > output_activation_max)
{
acc_0 = output_activation_max;
}
output[i_out++] = acc_0;
/* Requantize and clamp output to provided range */
acc_1 = arm_nn_divide_by_power_of_two(arm_nn_sat_doubling_high_mult(
acc_1 * (1 << LEFT_SHIFT(out_shift)), out_mult),
RIGHT_SHIFT(out_shift));
acc_1 += output_offset;
if (output_activation_min > acc_1)
{
acc_1 = output_activation_min;
}
if (acc_1 > output_activation_max)
{
acc_1 = output_activation_max;
}
output[i_out++] = acc_1;
}
}
}
}
#else
/* No available implementation. */
status = ARM_MATH_ARGUMENT_ERROR;
#endif
return status;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_depthwise_separable_conv_HWC_q7.c
* Description: Q7 depthwise separable convolution function
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Q7 depthwise separable convolution function
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in input tensor dimention
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel filter kernel size
* @param[in] padding padding sizes
* @param[in] stride convolution stride
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out output tensor dimension
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns either
* <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: 2*ch_im_in*dim_kernel*dim_kernel
*
* bufferB size: 0
*
* <b>Input dimension constraints:</b>
*
* ch_im_in equals ch_im_out
*
* Implementation:
* There are 3 nested loop here:
* Inner loop: calculate each output value with MAC instruction over an accumulator
* Mid loop: loop over different output channel
* Outer loop: loop over different output (x, y)
*/
arm_status arm_depthwise_separable_conv_HWC_q7(const q7_t * Im_in,
const uint16_t dim_im_in,
const uint16_t ch_im_in,
const q7_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel,
const uint16_t padding,
const uint16_t stride,
const q7_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q7_t * Im_out,
const uint16_t dim_im_out,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_out_y, i_out_x;
int16_t i_ker_y, i_ker_x;
q7_t *colBuffer = (q7_t *) bufferA;
q7_t *pBuffer = colBuffer;
const q7_t *pBias = bias;
q7_t *pOut = Im_out;
uint16_t rowCnt;
uint16_t row_shift;
/* do some checking here, basically ch_im_in == ch_im_out */
if (ch_im_in != ch_im_out)
{
return ARM_MATH_SIZE_MISMATCH;
}
for (i_out_y = 0; i_out_y < dim_im_out; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out; i_out_x++)
{
/* we first do im2col here */
for (i_ker_y = i_out_y * stride - padding; i_ker_y < i_out_y * stride - padding + dim_kernel; i_ker_y++)
{
for (i_ker_x = i_out_x * stride - padding; i_ker_x < i_out_x * stride - padding + dim_kernel; i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in || i_ker_x < 0 || i_ker_x >= dim_im_in)
{
/* arm_fill_q7(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, ch_im_in);
} else
{
/* arm_copy_q7((q7_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, pBuffer, ch_im_in); */
memcpy(pBuffer, (q7_t *) Im_in + (i_ker_y * dim_im_in + i_ker_x) * ch_im_in, ch_im_in);
}
pBuffer += ch_im_in;
}
}
/* we will do the computation here for each channel */
rowCnt = ch_im_out >> 2;
row_shift = 0;
pBias = bias;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = (dim_kernel * dim_kernel) >> 1;
q7_t *pB = colBuffer + row_shift;
const q7_t *pA = wt + row_shift;
row_shift += 4;
#ifdef USE_INTRINSIC
#ifndef ARM_MATH_BIG_ENDIAN
while (colCnt)
{
q31_t inA1, inA2, inB1, inB2, opA, opB;
inB1 = *__SIMD32(pB);
pB += ch_im_in;
opB = *__SIMD32(pB);
pB += ch_im_in;
inB2 = __PKHTB(opB, inB1, 16);
inB1 = __PKHBT(inB1, opB, 16);
inA1 = *__SIMD32(pA);
pA += ch_im_in;
opB = *__SIMD32(pA);
pA += ch_im_in;
inA2 = __PKHTB(opB, inA1, 16);
inA1 = __PKHBT(inA1, opB, 16);
opA = __SXTB16(inA1);
opB = __SXTB16(inB1);
sum = __SMLAD(opA, opB, sum);
opA = __SXTB16(__ROR(inA1, 8));
opB = __SXTB16(__ROR(inB1, 8));
sum2 = __SMLAD(opA, opB, sum2);
opA = __SXTB16(inA2);
opB = __SXTB16(inB2);
sum3 = __SMLAD(opA, opB, sum3);
opA = __SXTB16(__ROR(inA2, 8));
opB = __SXTB16(__ROR(inB2, 8));
sum4 = __SMLAD(opA, opB, sum4);
colCnt--;
}
#else
while (colCnt)
{
q31_t inA1, inA2, inB1, inB2, opA, opB;
inB1 = *__SIMD32(pB);
pB += ch_im_in;
opB = *__SIMD32(pB);
pB += ch_im_in;
inB2 = __PKHBT(opB, inB1, 16);
inB1 = __PKHTB(inB1, opB, 16);
inA1 = *__SIMD32(pA);
pA += ch_im_in;
opB = *__SIMD32(pA);
pA += ch_im_in;
inA2 = __PKHBT(opB, inA1, 16);
inA1 = __PKHTB(inA1, opB, 16);
opA = __SXTB16(inA1);
opB = __SXTB16(inB1);
sum2 = __SMLAD(opA, opB, sum2);
opA = __SXTB16(__ROR(inA1, 8));
opB = __SXTB16(__ROR(inB1, 8));
sum = __SMLAD(opA, opB, sum);
opA = __SXTB16(inA2);
opB = __SXTB16(inB2);
sum4 = __SMLAD(opA, opB, sum4);
opA = __SXTB16(__ROR(inA2, 8));
opB = __SXTB16(__ROR(inB2, 8));
sum3 = __SMLAD(opA, opB, sum3);
colCnt--;
}
#endif /* ARM_MATH_BIG_ENDIAN */
#else
#ifndef ARM_MATH_BIG_ENDIAN
/*
* r0 r1 r2 r3 r4 r5
* inA1, inA2, inB1, inB2, opA, opB
*/
asm volatile ("COL_LOOP_%=:\n"
"ldr.w r2, [%[pB], #0]\n"
"add.w %[pB], %[pB], %[ch_im_in]\n"
"ldr.w r5, [%[pB], #0]\n"
"add.w %[pB], %[pB], %[ch_im_in]\n"
"pkhtb r3, r5, r2, ASR #16\n"
"pkhbt r2, r2, r5, LSL #16\n"
"ldr.w r0, [%[pA], #0]\n"
"add.w %[pA], %[pA], %[ch_im_in]\n"
"ldr.w r5, [%[pA], #0]\n"
"add.w %[pA], %[pA], %[ch_im_in]\n"
"pkhtb r1, r5, r0, ASR #16\n"
"pkhbt r0, r0, r5, LSL #16\n"
"sxtb16 r4, r0\n"
"sxtb16 r5, r2\n"
"smlad %[sum], r4, r5, %[sum]\n"
"mov.w r4, r0, ror #8\n"
"mov.w r5, r2, ror #8\n"
"sxtb16 r4, r4\n"
"sxtb16 r5, r5\n"
"smlad %[sum2], r4, r5, %[sum2]\n"
"sxtb16 r4, r1\n"
"sxtb16 r5, r3\n"
"smlad %[sum3], r4, r5, %[sum3]\n"
"mov.w r4, r1, ror #8\n"
"mov.w r5, r3, ror #8\n"
"sxtb16 r4, r4\n"
"sxtb16 r5, r5\n"
"smlad %[sum4], r4, r5, %[sum4]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP_%=\n":[sum]
"+r"(sum),[sum2] "+r"(sum2),
[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),
[pA] "+r"(pA):[colCnt]
"r"(colCnt),[ch_im_in] "r"(ch_im_in):"r0", "r1", "r2", "r3", "r4", "r5");
#else
/*
* r0 r1 r2 r3 r4 r5
* inA1, inA2, inB1, inB2, opA, opB
*/
asm volatile ("COL_LOOP_%=:\n"
"ldr.w r2, [%[pB], #0]\n"
"add.w %[pB], %[pB], %[ch_im_in]\n"
"ldr.w r5, [%[pB], #0]\n"
"add.w %[pB], %[pB], %[ch_im_in]\n"
"pkhbt r3, r5, r2, LSL #16\n"
"pkhtb r2, r2, r5, ASR #16\n"
"ldr.w r0, [%[pA], #0]\n"
"add.w %[pA], %[pA], %[ch_im_in]\n"
"ldr.w r5, [%[pA], #0]\n"
"add.w %[pA], %[pA], %[ch_im_in]\n"
"pkhbt r1, r5, r0, LSL #16\n"
"pkhtb r0, r0, r5, ASR #16\n"
"sxtb16 r4, r0\n"
"sxtb16 r5, r2\n"
"smlad %[sum2], r4, r5, %[sum2]\n"
"mov.w r4, r0, ror #8\n"
"mov.w r5, r2, ror #8\n"
"sxtb16 r4, r4\n"
"sxtb16 r5, r5\n"
"smlad %[sum], r4, r5, %[sum]\n"
"sxtb16 r4, r1\n"
"sxtb16 r5, r3\n"
"smlad %[sum4], r4, r5, %[sum4]\n"
"mov.w r4, r1, ror #8\n"
"mov.w r5, r3, ror #8\n"
"sxtb16 r4, r4\n"
"sxtb16 r5, r5\n"
"smlad %[sum3], r4, r5, %[sum3]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP_%=\n":[sum]
"+r"(sum),[sum2] "+r"(sum2),
[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),
[pA] "+r"(pA):[colCnt]
"r"(colCnt),[ch_im_in] "r"(ch_im_in):"r0", "r1", "r2", "r3", "r4", "r5");
#endif /* ARM_MATH_BIG_ENDIAN */
#endif /* USE_INTRINSIC */
colCnt = (dim_kernel * dim_kernel) & 0x1;
while (colCnt)
{
union arm_nnword inA, inB;
inA.word = *__SIMD32(pA);
pA += ch_im_in;
inB.word = *__SIMD32(pB);
pB += ch_im_in;
sum += inA.bytes[0] * inB.bytes[0];
sum2 += inA.bytes[1] * inB.bytes[1];
sum3 += inA.bytes[2] * inB.bytes[2];
sum4 += inA.bytes[3] * inB.bytes[3];
colCnt--;
}
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
*pOut++ = (q7_t) __SSAT((sum2 >> out_shift), 8);
*pOut++ = (q7_t) __SSAT((sum3 >> out_shift), 8);
*pOut++ = (q7_t) __SSAT((sum4 >> out_shift), 8);
rowCnt--;
}
rowCnt = ch_im_out & 0x3;
while (rowCnt)
{
q7_t *pB = colBuffer + row_shift;
const q7_t *pA = wt + row_shift;
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = (dim_kernel * dim_kernel);
row_shift += 1;
while (colCnt)
{
q7_t A1 = *pA;
q7_t B1 = *pB;
pA += ch_im_in;
pB += ch_im_in;
sum += A1 * B1;
colCnt--;
}
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
rowCnt--;
}
/* clear counter and pointers */
pBuffer = colBuffer;
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
int i_out_y, i_out_x, i_ch_out, i_ker_x, i_ker_y;
int conv_out;
/* do some checking here, basically ch_im_in == ch_im_out */
if (ch_im_in != ch_im_out)
{
return ARM_MATH_SIZE_MISMATCH;
}
for (i_out_y = 0; i_out_y < dim_im_out; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out; i_out_x++)
{
for (i_ch_out = 0; i_ch_out < ch_im_out; i_ch_out++)
{
// for each output
conv_out = ((q31_t)(bias[i_ch_out]) << bias_shift) + NN_ROUND(out_shift);
for (i_ker_y = 0; i_ker_y < dim_kernel; i_ker_y++)
{
for (i_ker_x = 0; i_ker_x < dim_kernel; i_ker_x++)
{
int in_row = stride * i_out_y + i_ker_y - padding;
int in_col = stride * i_out_x + i_ker_x - padding;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in && in_col < dim_im_in)
{
conv_out +=
Im_in[(in_row *
dim_im_in +
in_col) *
ch_im_in +
i_ch_out] * wt[(i_ker_y * dim_kernel + i_ker_x) * ch_im_out + i_ch_out];
}
}
}
Im_out[(i_out_y * dim_im_out +
i_out_x) * ch_im_out + i_ch_out] = (q7_t) __SSAT((conv_out >> out_shift), 8);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_depthwise_separable_conv_HWC_q7_nonsquare.c
* Description: Q7 depthwise separable convolution function (non-square shape)
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup NNConv
* @{
*/
/**
* @brief Q7 depthwise separable convolution function (non-square shape)
* @param[in] Im_in pointer to input tensor
* @param[in] dim_im_in_x input tensor dimention x
* @param[in] dim_im_in_y input tensor dimention y
* @param[in] ch_im_in number of input tensor channels
* @param[in] wt pointer to kernel weights
* @param[in] ch_im_out number of filters, i.e., output tensor channels
* @param[in] dim_kernel_x filter kernel size x
* @param[in] dim_kernel_y filter kernel size y
* @param[in] padding_x padding sizes x
* @param[in] padding_y padding sizes y
* @param[in] stride_x convolution stride x
* @param[in] stride_y convolution stride y
* @param[in] bias pointer to bias
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in,out] Im_out pointer to output tensor
* @param[in] dim_im_out_x output tensor dimension x
* @param[in] dim_im_out_y output tensor dimension y
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] bufferB pointer to buffer space for output
* @return The function returns either
* <code>ARM_MATH_SIZE_MISMATCH</code> or <code>ARM_MATH_SUCCESS</code> based on the outcome of size checking.
*
* This function is the version with full list of optimization tricks, but with
* some contraints:
* ch_im_in is multiple of 2
* ch_im_out is multiple of 2
*/
arm_status arm_depthwise_separable_conv_HWC_q7_nonsquare(const q7_t * Im_in,
const uint16_t dim_im_in_x,
const uint16_t dim_im_in_y,
const uint16_t ch_im_in,
const q7_t * wt,
const uint16_t ch_im_out,
const uint16_t dim_kernel_x,
const uint16_t dim_kernel_y,
const uint16_t padding_x,
const uint16_t padding_y,
const uint16_t stride_x,
const uint16_t stride_y,
const q7_t * bias,
const uint16_t bias_shift,
const uint16_t out_shift,
q7_t * Im_out,
const uint16_t dim_im_out_x,
const uint16_t dim_im_out_y,
q15_t * bufferA,
q7_t * bufferB)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
/*
* Implementation:
* There are 3 nested loop here:
* Inner loop: calculate each output value with MAC instruction over an accumulator
* Mid loop: loop over different output channel
* Outer loop: loop over different output (x, y)
*
*/
int16_t i_out_y, i_out_x;
int16_t i_ker_y, i_ker_x;
q7_t *colBuffer = (q7_t *) bufferA;
q7_t *pBuffer = colBuffer;
const q7_t *pBias = bias;
q7_t *pOut = Im_out;
uint16_t rowCnt;
uint16_t row_shift;
/* do some checking here, basically ch_im_in == ch_im_out */
if (ch_im_in != ch_im_out)
{
return ARM_MATH_SIZE_MISMATCH;
}
for (i_out_y = 0; i_out_y < dim_im_out_y; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out_x; i_out_x++)
{
/* we first do im2col here */
for (i_ker_y = i_out_y * stride_y - padding_y; i_ker_y < i_out_y * stride_y - padding_y + dim_kernel_y;
i_ker_y++)
{
for (i_ker_x = i_out_x * stride_x - padding_x; i_ker_x < i_out_x * stride_x - padding_x + dim_kernel_x;
i_ker_x++)
{
if (i_ker_y < 0 || i_ker_y >= dim_im_in_y || i_ker_x < 0 || i_ker_x >= dim_im_in_x)
{
/* arm_fill_q7(0, pBuffer, ch_im_in); */
memset(pBuffer, 0, ch_im_in);
} else
{
/* arm_copy_q7((q7_t *) Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in, pBuffer, ch_im_in); */
memcpy(pBuffer, (q7_t *) Im_in + (i_ker_y * dim_im_in_x + i_ker_x) * ch_im_in, ch_im_in);
}
pBuffer += ch_im_in;
}
}
/* we will do the computation here for each channel */
rowCnt = ch_im_out >> 2;
row_shift = 0;
pBias = bias;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = (dim_kernel_x * dim_kernel_y) >> 1;
q7_t *pB = colBuffer + row_shift;
const q7_t *pA = wt + row_shift;
row_shift += 4;
#ifdef USE_INTRINSIC
#ifndef ARM_MATH_BIG_ENDIAN
while (colCnt)
{
q31_t inA1, inA2, inB1, inB2, opA, opB;
inB1 = *__SIMD32(pB);
pB += ch_im_in;
opB = *__SIMD32(pB);
pB += ch_im_in;
inB2 = __PKHTB(opB, inB1, 16);
inB1 = __PKHBT(inB1, opB, 16);
inA1 = *__SIMD32(pA);
pA += ch_im_in;
opB = *__SIMD32(pA);
pA += ch_im_in;
inA2 = __PKHTB(opB, inA1, 16);
inA1 = __PKHBT(inA1, opB, 16);
opA = __SXTB16(inA1);
opB = __SXTB16(inB1);
sum = __SMLAD(opA, opB, sum);
opA = __SXTB16(__ROR(inA1, 8));
opB = __SXTB16(__ROR(inB1, 8));
sum2 = __SMLAD(opA, opB, sum2);
opA = __SXTB16(inA2);
opB = __SXTB16(inB2);
sum3 = __SMLAD(opA, opB, sum3);
opA = __SXTB16(__ROR(inA2, 8));
opB = __SXTB16(__ROR(inB2, 8));
sum4 = __SMLAD(opA, opB, sum4);
colCnt--;
}
#else
while (colCnt)
{
q31_t inA1, inA2, inB1, inB2, opA, opB;
inB1 = *__SIMD32(pB);
pB += ch_im_in;
opB = *__SIMD32(pB);
pB += ch_im_in;
inB2 = __PKHBT(opB, inB1, 16);
inB1 = __PKHTB(inB1, opB, 16);
inA1 = *__SIMD32(pA);
pA += ch_im_in;
opB = *__SIMD32(pA);
pA += ch_im_in;
inA2 = __PKHBT(opB, inA1, 16);
inA1 = __PKHTB(inA1, opB, 16);
opA = __SXTB16(inA1);
opB = __SXTB16(inB1);
sum2 = __SMLAD(opA, opB, sum2);
opA = __SXTB16(__ROR(inA1, 8));
opB = __SXTB16(__ROR(inB1, 8));
sum = __SMLAD(opA, opB, sum);
opA = __SXTB16(inA2);
opB = __SXTB16(inB2);
sum4 = __SMLAD(opA, opB, sum4);
opA = __SXTB16(__ROR(inA2, 8));
opB = __SXTB16(__ROR(inB2, 8));
sum3 = __SMLAD(opA, opB, sum3);
colCnt--;
}
#endif /* ARM_MATH_BIG_ENDIAN */
#else
#ifndef ARM_MATH_BIG_ENDIAN
// r0 r1 r2 r3 r4 r5
// inA1, inA2, inB1, inB2, opA, opB
asm volatile ("COL_LOOP:\n"
"ldr.w r2, [%[pB], #0]\n"
"add.w %[pB], %[pB], %[ch_im_in]\n"
"ldr.w r5, [%[pB], #0]\n"
"add.w %[pB], %[pB], %[ch_im_in]\n"
"pkhtb r3, r5, r2, ASR #16\n"
"pkhbt r2, r2, r5, LSL #16\n"
"ldr.w r0, [%[pA], #0]\n"
"add.w %[pA], %[pA], %[ch_im_in]\n"
"ldr.w r5, [%[pA], #0]\n"
"add.w %[pA], %[pA], %[ch_im_in]\n"
"pkhtb r1, r5, r0, ASR #16\n"
"pkhbt r0, r0, r5, LSL #16\n"
"sxtb16 r4, r0\n"
"sxtb16 r5, r2\n"
"smlad %[sum], r4, r5, %[sum]\n"
"mov.w r4, r0, ror #8\n"
"mov.w r5, r2, ror #8\n"
"sxtb16 r4, r4\n"
"sxtb16 r5, r5\n"
"smlad %[sum2], r4, r5, %[sum2]\n"
"sxtb16 r4, r1\n"
"sxtb16 r5, r3\n"
"smlad %[sum3], r4, r5, %[sum3]\n"
"mov.w r4, r1, ror #8\n"
"mov.w r5, r3, ror #8\n"
"sxtb16 r4, r4\n"
"sxtb16 r5, r5\n"
"smlad %[sum4], r4, r5, %[sum4]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP\n":[sum] "+r"(sum),[sum2] "+r"(sum2),[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),[pA] "+r"(pA):[colCnt] "r"(colCnt),
[ch_im_in] "r"(ch_im_in):"r0", "r1", "r2", "r3", "r4", "r5");
#else
// r0 r1 r2 r3 r4 r5
// inA1, inA2, inB1, inB2, opA, opB
asm volatile ("COL_LOOP:\n"
"ldr.w r2, [%[pB], #0]\n"
"add.w %[pB], %[pB], %[ch_im_in]\n"
"ldr.w r5, [%[pB], #0]\n"
"add.w %[pB], %[pB], %[ch_im_in]\n"
"pkhbt r3, r5, r2, LSL #16\n"
"pkhtb r2, r2, r5, ASR #16\n"
"ldr.w r0, [%[pA], #0]\n"
"add.w %[pA], %[pA], %[ch_im_in]\n"
"ldr.w r5, [%[pA], #0]\n"
"add.w %[pA], %[pA], %[ch_im_in]\n"
"pkhbt r1, r5, r0, LSL #16\n"
"pkhtb r0, r0, r5, ASR #16\n"
"sxtb16 r4, r0\n"
"sxtb16 r5, r2\n"
"smlad %[sum2], r4, r5, %[sum2]\n"
"mov.w r4, r0, ror #8\n"
"mov.w r5, r2, ror #8\n"
"sxtb16 r4, r4\n"
"sxtb16 r5, r5\n"
"smlad %[sum], r4, r5, %[sum]\n"
"sxtb16 r4, r1\n"
"sxtb16 r5, r3\n"
"smlad %[sum4], r4, r5, %[sum4]\n"
"mov.w r4, r1, ror #8\n"
"mov.w r5, r3, ror #8\n"
"sxtb16 r4, r4\n"
"sxtb16 r5, r5\n"
"smlad %[sum3], r4, r5, %[sum3]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP\n":[sum] "+r"(sum),[sum2] "+r"(sum2),[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),[pA] "+r"(pA):[colCnt] "r"(colCnt),
[ch_im_in] "r"(ch_im_in):"r0", "r1", "r2", "r3", "r4", "r5");
#endif /*ARM_MATH_BIG_ENDIAN */
#endif /* USE_INTRINSIC */
colCnt = (dim_kernel_x * dim_kernel_y) & 0x1;
while (colCnt)
{
union arm_nnword inA, inB;
inA.word = *__SIMD32(pA);
pA += ch_im_in;
inB.word = *__SIMD32(pB);
pB += ch_im_in;
sum += inA.bytes[0] * inB.bytes[0];
sum2 += inA.bytes[1] * inB.bytes[1];
sum3 += inA.bytes[2] * inB.bytes[2];
sum4 += inA.bytes[3] * inB.bytes[3];
colCnt--;
}
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
*pOut++ = (q7_t) __SSAT((sum2 >> out_shift), 8);
*pOut++ = (q7_t) __SSAT((sum3 >> out_shift), 8);
*pOut++ = (q7_t) __SSAT((sum4 >> out_shift), 8);
rowCnt--;
}
rowCnt = ch_im_out & 0x3;
while (rowCnt)
{
q7_t *pB = colBuffer + row_shift;
const q7_t *pA = wt + row_shift;
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = (dim_kernel_x * dim_kernel_y);
row_shift += 1;
while (colCnt)
{
q7_t A1 = *pA;
q7_t B1 = *pB;
pA += ch_im_in;
pB += ch_im_in;
sum += A1 * B1;
colCnt--;
}
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
rowCnt--;
}
// clear counter and pointers
pBuffer = colBuffer;
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
int i_out_y, i_out_x, i_ch_out;
int i_ker_y, i_ker_x;
/* do some checking here, basically ch_im_in == ch_im_out */
if (ch_im_in != ch_im_out)
{
return ARM_MATH_SIZE_MISMATCH;
}
for (i_out_y = 0; i_out_y < dim_im_out_y; i_out_y++)
{
for (i_out_x = 0; i_out_x < dim_im_out_x; i_out_x++)
{
for (i_ch_out = 0; i_ch_out < ch_im_out; i_ch_out++)
{
// for each output
int conv_out = ((q31_t)(bias[i_ch_out]) << bias_shift) + NN_ROUND(out_shift);
for (i_ker_y = 0; i_ker_y < dim_kernel_y; i_ker_y++)
{
for (i_ker_x = 0; i_ker_x < dim_kernel_x; i_ker_x++)
{
int in_row = stride_y * i_out_y + i_ker_y - padding_y;
int in_col = stride_x * i_out_x + i_ker_x - padding_x;
if (in_row >= 0 && in_col >= 0 && in_row < dim_im_in_y && in_col < dim_im_in_x)
{
conv_out += Im_in[(in_row * dim_im_in_x + in_col) * ch_im_in + i_ch_out] *
wt[(i_ker_y * dim_kernel_x + i_ker_x) * ch_im_out + i_ch_out];
}
}
}
Im_out[(i_out_y * dim_im_out_x + i_out_x) * ch_im_out + i_ch_out] =
(q7_t) __SSAT((conv_out >> out_shift), 8);
}
}
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return ARM_MATH_SUCCESS;
}
/**
* @} end of NNConv group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_nn_mat_mult_kernel_q7_q15.c
* Description: Matrix-multiplication function for convolution
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @brief Matrix-multiplication function for convolution
* @param[in] pA pointer to operand A
* @param[in] pInBuffer pointer to operand B, always conssists of 2 vectors
* @param[in] ch_im_out numRow of A
* @param[in] numCol_A numCol of A
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in] bias the bias
* @param[in,out] pOut pointer to output
* @return The function returns the incremented output pointer
*
* @details
*
* This function does the matrix multiplication with weight matrix
* and 2 columns from im2col.
*/
q7_t *arm_nn_mat_mult_kernel_q7_q15(const q7_t * pA,
const q15_t * pInBuffer,
const uint16_t ch_im_out,
const uint16_t numCol_A,
const uint16_t bias_shift,
const uint16_t out_shift,
const q7_t * bias,
q7_t * pOut)
{
#if defined (ARM_MATH_DSP)
/* set up the second output pointers */
q7_t *pOut2 = pOut + ch_im_out;
const q7_t *pBias = bias;
uint16_t rowCnt = ch_im_out >> 1;
/* this loop over rows in A */
while (rowCnt)
{
/* setup pointers for B */
const q15_t *pB = pInBuffer;
const q15_t *pB2 = pB + numCol_A;
/* align the second pointer for A */
const q7_t *pA2 = pA + numCol_A;
/* init the sum with bias */
q31_t sum = ((q31_t)(*pBias) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = numCol_A >> 2;
/* accumulate over the vector */
while (colCnt)
{
q31_t inA11, inA12, inA21, inA22;
q31_t inB1 = *__SIMD32(pB)++;
q31_t inB2 = *__SIMD32(pB2)++;
pA = (q7_t *) read_and_pad((void *)pA, &inA11, &inA12);
pA2 = (q7_t *) read_and_pad((void *)pA2, &inA21, &inA22);
sum = __SMLAD(inA11, inB1, sum);
sum2 = __SMLAD(inA11, inB2, sum2);
sum3 = __SMLAD(inA21, inB1, sum3);
sum4 = __SMLAD(inA21, inB2, sum4);
inB1 = *__SIMD32(pB)++;
inB2 = *__SIMD32(pB2)++;
sum = __SMLAD(inA12, inB1, sum);
sum2 = __SMLAD(inA12, inB2, sum2);
sum3 = __SMLAD(inA22, inB1, sum3);
sum4 = __SMLAD(inA22, inB2, sum4);
colCnt--;
} /* while over colCnt */
colCnt = numCol_A & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
q7_t inA2 = *pA2++;
q15_t inB2 = *pB2++;
sum += inA1 * inB1;
sum2 += inA1 * inB2;
sum3 += inA2 * inB1;
sum4 += inA2 * inB2;
colCnt--;
} /* while over colCnt */
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
*pOut++ = (q7_t) __SSAT((sum3 >> out_shift), 8);
*pOut2++ = (q7_t) __SSAT((sum2 >> out_shift), 8);
*pOut2++ = (q7_t) __SSAT((sum4 >> out_shift), 8);
/* skip the row computed with A2 */
pA += numCol_A;
rowCnt--;
} /* for over ch_im_out */
/* compute left-over row if any */
if (ch_im_out & 0x1)
{
/* setup pointers for B */
const q15_t *pB = pInBuffer;
const q15_t *pB2 = pB + numCol_A;
/* load the bias */
q31_t sum = ((q31_t)(*pBias) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = numCol_A >> 2;
while (colCnt)
{
q31_t inA11, inA12;
q31_t inB1 = *__SIMD32(pB)++;
q31_t inB2 = *__SIMD32(pB2)++;
pA = (q7_t *) read_and_pad((void *)pA, &inA11, &inA12);
sum = __SMLAD(inA11, inB1, sum);
sum2 = __SMLAD(inA11, inB2, sum2);
inB1 = *__SIMD32(pB)++;
inB2 = *__SIMD32(pB2)++;
sum = __SMLAD(inA12, inB1, sum);
sum2 = __SMLAD(inA12, inB2, sum2);
colCnt--;
}
colCnt = numCol_A & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
q15_t inB2 = *pB2++;
sum += inA1 * inB1;
sum2 += inA1 * inB2;
colCnt--;
}
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
*pOut2++ = (q7_t) __SSAT((sum2 >> out_shift), 8);
}
pOut += ch_im_out;
/* return the new output pointer with offset */
return pOut;
#else
/* To be completed */
return NULL;
#endif /* ARM_MATH_DSP */
}

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_nn_mat_mult_kernel_q7_q15_reordered.c
* Description: Matrix-multiplication function for convolution with reordered columns
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
* -------------------------------------------------------------------- */
#include "arm_nnfunctions.h"
#include "arm_math.h"
/**
* @brief Matrix-multiplication function for convolution with reordered columns
* @param[in] pA pointer to operand A
* @param[in] pInBuffer pointer to operand B, always conssists of 2 vectors
* @param[in] ch_im_out numRow of A
* @param[in] numCol_A numCol of A
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in] bias the bias
* @param[in,out] pOut pointer to output
* @return The function returns the incremented output pointer
*
* @details
*
* This function assumes that data in pInBuffer are reordered
*/
q7_t *arm_nn_mat_mult_kernel_q7_q15_reordered(const q7_t * pA,
const q15_t * pInBuffer,
const uint16_t ch_im_out,
const uint16_t numCol_A,
const uint16_t bias_shift,
const uint16_t out_shift,
const q7_t * bias,
q7_t * pOut)
{
#if defined (ARM_MATH_DSP)
/* set up the second output pointers */
q7_t *pOut2 = pOut + ch_im_out;
int i;
/* this loop over rows in A */
for (i = 0; i < ch_im_out; i += 2)
{
/* setup pointers for B */
const q15_t *pB = pInBuffer;
const q15_t *pB2 = pB + numCol_A;
/* align the second pointer for A */
const q7_t *pA2 = pA + numCol_A;
/* init the sum with bias */
q31_t sum = ((q31_t)(bias[i]) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(bias[i]) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(bias[i + 1]) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(bias[i + 1]) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = numCol_A >> 2;
/* accumulate over the vector */
while (colCnt)
{
q31_t inA11, inA12, inA21, inA22;
q31_t inB1 = *__SIMD32(pB)++;
q31_t inB2 = *__SIMD32(pB2)++;
pA = (q7_t *) read_and_pad_reordered((void *)pA, &inA11, &inA12);
pA2 = (q7_t *) read_and_pad_reordered((void *)pA2, &inA21, &inA22);
sum = __SMLAD(inA11, inB1, sum);
sum2 = __SMLAD(inA11, inB2, sum2);
sum3 = __SMLAD(inA21, inB1, sum3);
sum4 = __SMLAD(inA21, inB2, sum4);
inB1 = *__SIMD32(pB)++;
inB2 = *__SIMD32(pB2)++;
sum = __SMLAD(inA12, inB1, sum);
sum2 = __SMLAD(inA12, inB2, sum2);
sum3 = __SMLAD(inA22, inB1, sum3);
sum4 = __SMLAD(inA22, inB2, sum4);
colCnt--;
} /* while over colCnt */
colCnt = numCol_A & 0x3;
while (colCnt)
{
q7_t inA1 = *pA++;
q15_t inB1 = *pB++;
q7_t inA2 = *pA2++;
q15_t inB2 = *pB2++;
sum += inA1 * inB1;
sum2 += inA1 * inB2;
sum3 += inA2 * inB1;
sum4 += inA2 * inB2;
colCnt--;
} /* while over colCnt */
*pOut++ = (q7_t) __SSAT((sum >> out_shift), 8);
*pOut++ = (q7_t) __SSAT((sum3 >> out_shift), 8);
*pOut2++ = (q7_t) __SSAT((sum2 >> out_shift), 8);
*pOut2++ = (q7_t) __SSAT((sum4 >> out_shift), 8);
/* skip the row computed with A2 */
pA += numCol_A;
} /* for over ch_im_out */
pOut += ch_im_out;
/* return the new output pointer with offset */
return pOut;
#else
/* To be completed */
return NULL;
#endif /* ARM_MATH_DSP */
}

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_fully_connected_mat_q7_vec_q15.c
* Description: Mixed Q15-Q7 fully-connected layer function
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup FC
* @{
*/
/**
* @brief Mixed Q15-Q7 fully-connected layer function
* @param[in] pV pointer to input vector
* @param[in] pM pointer to matrix weights
* @param[in] dim_vec length of the vector
* @param[in] num_of_rows number of rows in weight matrix
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in] bias pointer to bias
* @param[in,out] pOut pointer to output vector
* @param[in,out] vec_buffer pointer to buffer space for input
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*
* @details
*
* <b>Buffer size:</b>
*
* vec_buffer size: 0
*
* Q7_Q15 version of the fully connected layer
*
* Weights are in q7_t and Activations are in q15_t
*
*/
arm_status
arm_fully_connected_mat_q7_vec_q15(const q15_t * pV,
const q7_t * pM,
const uint16_t dim_vec,
const uint16_t num_of_rows,
const uint16_t bias_shift,
const uint16_t out_shift,
const q7_t * bias,
q15_t * pOut,
q15_t * vec_buffer)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
const q7_t *pB = pM;
const q7_t *pB2;
q15_t *pO = pOut;
const q7_t *pBias = bias;
const q15_t *pA = pV;
uint16_t rowCnt = num_of_rows >> 1;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = pV;
pB2 = pB + dim_vec;
while (colCnt)
{
q31_t inV, inM11, inM12, inM21, inM22;
pB = (q7_t *) read_and_pad((void *)pB, &inM11, &inM12);
pB2 = (q7_t *) read_and_pad((void *)pB2, &inM21, &inM22);
inV = *__SIMD32(pA)++;
sum = __SMLAD(inV, inM11, sum);
sum2 = __SMLAD(inV, inM21, sum2);
inV = *__SIMD32(pA)++;
sum = __SMLAD(inV, inM12, sum);
sum2 = __SMLAD(inV, inM22, sum2);
colCnt--;
}
colCnt = dim_vec & 0x3;
while (colCnt)
{
q15_t inV = *pA++;
q7_t inM = *pB++;
q7_t inM2 = *pB2++;
sum += inV * inM;
sum2 += inV * inM2;
colCnt--;
} /* while over colCnt */
*pO++ = (q15_t) (__SSAT((sum >> out_shift), 16));
*pO++ = (q15_t) (__SSAT((sum2 >> out_shift), 16));
/*adjust the pointers and counters */
pB += dim_vec;
rowCnt--;
}
/* left-over part of the rows */
rowCnt = num_of_rows & 0x1;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = pV;
while (colCnt)
{
q31_t inV1, inV2, inM11, inM12;
pB = (q7_t *) read_and_pad((void *)pB, &inM11, &inM12);
inV1 = *__SIMD32(pA)++;
sum = __SMLAD(inV1, inM11, sum);
inV2 = *__SIMD32(pA)++;
sum = __SMLAD(inV2, inM12, sum);
colCnt--;
}
/* left-over of the vector */
colCnt = dim_vec & 0x3;
while (colCnt)
{
q15_t inV = *pA++;
q7_t inM = *pB++;
sum += inV * inM;
colCnt--;
}
*pO++ = (q15_t) (__SSAT((sum >> out_shift), 16));
rowCnt--;
}
#else
int i, j;
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
for (i = 0; i < num_of_rows; i++)
{
int ip_out = ((q31_t)(bias[i]) << bias_shift) + NN_ROUND(out_shift);
for (j = 0; j < dim_vec; j++)
{
ip_out += pV[j] * pM[i * dim_vec + j];
}
pOut[i] = (q15_t) __SSAT((ip_out >> out_shift), 16);
}
#endif /* ARM_MATH_DSP */
/* Return to ARM_MATH_SUCCESS */
return (ARM_MATH_SUCCESS);
}
/**
* @} end of FC group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_fully_connected_mat_q7_vec_q15_opt.c
* Description: Mixed Q15-Q7 opt fully-connected layer function
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup FC
* @{
*/
/**
* @brief Mixed Q15-Q7 opt fully-connected layer function
* @param[in] pV pointer to input vector
* @param[in] pM pointer to matrix weights
* @param[in] dim_vec length of the vector
* @param[in] num_of_rows number of rows in weight matrix
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in] bias pointer to bias
* @param[in,out] pOut pointer to output vector
* @param[in,out] vec_buffer pointer to buffer space for input
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*
* @details
*
* <b>Buffer size:</b>
*
* vec_buffer size: 0
*
* Q7_Q15 version of the fully connected layer
*
* Weights are in q7_t and Activations are in q15_t
*
* Limitation: x4 version requires weight reordering to work
*
* Here we use only one pointer to read 4 rows in the weight
* matrix. So if the original q7_t matrix looks like this:
*
* | a11 | a12 | a13 | a14 | a15 | a16 | a17 |
*
* | a21 | a22 | a23 | a24 | a25 | a26 | a27 |
*
* | a31 | a32 | a33 | a34 | a35 | a36 | a37 |
*
* | a41 | a42 | a43 | a44 | a45 | a46 | a47 |
*
* | a51 | a52 | a53 | a54 | a55 | a56 | a57 |
*
* | a61 | a62 | a63 | a64 | a65 | a66 | a67 |
*
* We operates on multiple-of-4 rows, so the first four rows becomes
*
* | a11 | a21 | a12 | a22 | a31 | a41 | a32 | a42 |
*
* | a13 | a23 | a14 | a24 | a33 | a43 | a34 | a44 |
*
* | a15 | a25 | a16 | a26 | a35 | a45 | a36 | a46 |
*
* The column left over will be in-order.
* which is:
* | a17 | a27 | a37 | a47 |
*
* For the left-over rows, we do 1x1 computation, so the data remains
* as its original order.
*
* So the stored weight matrix looks like this:
*
* | a11 | a21 | a12 | a22 | a31 | a41 |
*
* | a32 | a42 | a13 | a23 | a14 | a24 |
*
* | a33 | a43 | a34 | a44 | a15 | a25 |
*
* | a16 | a26 | a35 | a45 | a36 | a46 |
*
* | a17 | a27 | a37 | a47 | a51 | a52 |
*
* | a53 | a54 | a55 | a56 | a57 | a61 |
*
* | a62 | a63 | a64 | a65 | a66 | a67 |
*
*/
arm_status
arm_fully_connected_mat_q7_vec_q15_opt(const q15_t * pV,
const q7_t * pM,
const uint16_t dim_vec,
const uint16_t num_of_rows,
const uint16_t bias_shift,
const uint16_t out_shift, const q7_t * bias, q15_t * pOut, q15_t * vec_buffer)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
const q7_t *pB = pM;
q15_t *pO = pOut;
const q7_t *pBias = bias;
const q15_t *pA = pV;
uint16_t rowCnt = num_of_rows >> 2;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 1;
pA = pV;
#ifdef USE_INTRINSIC
#ifndef ARM_MATH_BIG_ENDIAN
while (colCnt)
{
q31_t inM11, inM12, inM13, inM14;
q31_t inV;
inV = *__SIMD32(pA)++;
inM11 = *__SIMD32(pB)++;
inM12 = __SXTB16(__ROR(inM11, 8));
inM11 = __SXTB16(inM11);
sum = __SMLAD(inM11, inV, sum);
sum2 = __SMLAD(inM12, inV, sum2);
inM13 = *__SIMD32(pB)++;
inM14 = __SXTB16(__ROR(inM13, 8));
inM13 = __SXTB16(inM13);
sum3 = __SMLAD(inM13, inV, sum3);
sum4 = __SMLAD(inM14, inV, sum4);
colCnt--;
}
#else
while (colCnt)
{
q31_t inM11, inM12, inM13, inM14;
q31_t inV;
inV = *__SIMD32(pA)++;
inM11 = *__SIMD32(pB)++;
inM12 = __SXTB16(__ROR(inM11, 8));
inM11 = __SXTB16(inM11);
sum = __SMLAD(inM12, inV, sum);
sum2 = __SMLAD(inM11, inV, sum2);
inM13 = *__SIMD32(pB)++;
inM14 = __SXTB16(__ROR(inM13, 8));
inM13 = __SXTB16(inM13);
sum3 = __SMLAD(inM14, inV, sum3);
sum4 = __SMLAD(inM13, inV, sum4);
colCnt--;
}
#endif /* ARM_MATH_BIG_ENDIAN */
#else
/*
* register needed:
* loop counter: colCnt
* accumulators: sum, sum2, sum3, sum4
* pointers: pB, pA
* weight data: inM11, inM12, inM13, inM14
* activation data: inV
*/
#ifndef ARM_MATH_BIG_ENDIAN
asm volatile ("COL_LOOP_%=:\n"
"ldr.w r4, [%[pA]], #4\n"
"ldr.w r1, [%[pB]], #8\n"
"mov.w r0, r1, ror #8\n"
"sxtb16 r0, r0\n"
"sxtb16 r1, r1\n"
"smlad %[sum], r4, r1, %[sum]\n"
"smlad %[sum2], r4, r0, %[sum2]\n"
"ldr.w r3, [%[pB], #-4]\n"
"mov.w r2, r3, ror #8\n"
"sxtb16 r2, r2\n"
"sxtb16 r3, r3\n"
"smlad %[sum3], r4, r3, %[sum3]\n"
"smlad %[sum4], r4, r2, %[sum4]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP_%=\n":[sum] "+r"(sum),
[sum2] "+r"(sum2),[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),[pA] "+r"(pA):[colCnt] "r"(colCnt):"r0", "r1", "r2", "r3", "r4");
#else
asm volatile ("COL_LOOP_%=:\n"
"ldr.w r4, [%[pA]], #4\n"
"ldr.w r1, [%[pB]], #8\n"
"mov.w r0, r1, ror #8\n"
"sxtb16 r0, r0\n"
"sxtb16 r1, r1\n"
"smlad %[sum], r4, r0, %[sum]\n"
"smlad %[sum2], r4, r1, %[sum2]\n"
"ldr.w r3, [%[pB], #-4]\n"
"mov.w r2, r3, ror #8\n"
"sxtb16 r2, r2\n"
"sxtb16 r3, r3\n"
"smlad %[sum3], r4, r2, %[sum3]\n"
"smlad %[sum4], r4, r3, %[sum4]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP_%=\n":[sum] "+r"(sum),
[sum2] "+r"(sum2),[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),[pA] "+r"(pA):[colCnt] "r"(colCnt):"r0", "r1", "r2", "r3", "r4");
#endif /* ARM_MATH_BIG_ENDIAN */
#endif /* USE_INTRINSIC */
colCnt = dim_vec & 0x1;
while (colCnt)
{
q15_t inV = *pA++;
q7_t inM = *pB++;
q7_t inM2 = *pB++;
q7_t inM3 = *pB++;
q7_t inM4 = *pB++;
sum += inV * inM;
sum2 += inV * inM2;
sum3 += inV * inM3;
sum4 += inV * inM4;
colCnt--;
} /* while over colCnt */
*pO++ = (q15_t) (__SSAT((sum >> out_shift), 16));
*pO++ = (q15_t) (__SSAT((sum2 >> out_shift), 16));
*pO++ = (q15_t) (__SSAT((sum3 >> out_shift), 16));
*pO++ = (q15_t) (__SSAT((sum4 >> out_shift), 16));
/* adjust the pointers and counters */
rowCnt--;
}
/* left-over part of the rows */
rowCnt = num_of_rows & 0x3;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = pV;
while (colCnt)
{
q31_t inV1, inV2, inM11, inM12;
pB = (q7_t *) read_and_pad((void *)pB, &inM11, &inM12);
inV1 = *__SIMD32(pA)++;
sum = __SMLAD(inV1, inM11, sum);
inV2 = *__SIMD32(pA)++;
sum = __SMLAD(inV2, inM12, sum);
colCnt--;
}
/* left-over of the vector */
colCnt = dim_vec & 0x3;
while (colCnt)
{
q15_t inV = *pA++;
q7_t inM = *pB++;
sum += inV * inM;
colCnt--;
}
*pO++ = (q15_t) (__SSAT((sum >> out_shift), 16));
rowCnt--;
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t rowCnt = num_of_rows >> 2;
const q7_t *pB = pM;
const q15_t *pA;
q15_t *pO = pOut;
const q7_t *pBias = bias;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 1;
pA = pV;
while (colCnt)
{
q15_t inA1 = *pA++;
q15_t inA2 = *pA++;
q7_t inB1 = *pB++;
q7_t inB3 = *pB++;
q7_t inB2 = *pB++;
q7_t inB4 = *pB++;
sum += inA1 * inB1 + inA2 * inB2;
sum2 += inA1 * inB3 + inA2 * inB4;
inB1 = *pB++;
inB3 = *pB++;
inB2 = *pB++;
inB4 = *pB++;
sum3 += inA1 * inB1 + inA2 * inB2;
sum4 += inA1 * inB3 + inA2 * inB4;
colCnt--;
}
colCnt = dim_vec & 0x1;
while (colCnt)
{
q15_t inA = *pA++;
q7_t inB = *pB++;
sum += inA * inB;
inB = *pB++;
sum2 += inA * inB;
inB = *pB++;
sum3 += inA * inB;
inB = *pB++;
sum4 += inA * inB;
colCnt--;
}
*pO++ = (q15_t) __SSAT((sum >> out_shift), 16);
*pO++ = (q15_t) __SSAT((sum2 >> out_shift), 16);
*pO++ = (q15_t) __SSAT((sum3 >> out_shift), 16);
*pO++ = (q15_t) __SSAT((sum4 >> out_shift), 16);
rowCnt--;
}
rowCnt = num_of_rows & 0x3;
while (rowCnt)
{
int ip_out = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
int j;
pA = pV;
for (j = 0; j < dim_vec; j++)
{
q15_t inA = *pA++;
q7_t inB = *pB++;
ip_out += inA * inB;
}
*pO++ = (q15_t) __SSAT((ip_out >> out_shift), 16);
rowCnt--;
}
#endif /* ARM_MATH_DSP */
/* Return to ARM_MATH_SUCCESS */
return (ARM_MATH_SUCCESS);
}
/**
* @} end of FC group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_fully_connected_q15.c
* Description: Q15 basic fully-connected layer function
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup FC
* @{
*/
/**
* @brief Q15 opt fully-connected layer function
* @param[in] pV pointer to input vector
* @param[in] pM pointer to matrix weights
* @param[in] dim_vec length of the vector
* @param[in] num_of_rows number of rows in weight matrix
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in] bias pointer to bias
* @param[in,out] pOut pointer to output vector
* @param[in,out] vec_buffer pointer to buffer space for input
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*
*
* @details
*
* <b>Buffer size:</b>
*
* vec_buffer size: 0
*
*/
arm_status
arm_fully_connected_q15(const q15_t * pV,
const q15_t * pM,
const uint16_t dim_vec,
const uint16_t num_of_rows,
const uint16_t bias_shift,
const uint16_t out_shift,
const q15_t * bias,
q15_t * pOut,
q15_t * vec_buffer)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
const q15_t *pB = pM;
const q15_t *pB2 = pB + dim_vec;
q15_t *pO = pOut;
const q15_t *pA;
const q15_t *pBias = bias;
uint16_t rowCnt = num_of_rows >> 1;
/* this loop loops over different output */
while (rowCnt) {
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = pV;
pB2 = pB + dim_vec;
while (colCnt)
{
q31_t inV1, inM1, inM2;
inV1 = *__SIMD32(pA)++;
inM1 = *__SIMD32(pB)++;
sum = __SMLAD(inV1, inM1, sum);
inM2 = *__SIMD32(pB2)++;
sum2 = __SMLAD(inV1, inM2, sum2);
inV1 = *__SIMD32(pA)++;
inM1 = *__SIMD32(pB)++;
sum = __SMLAD(inV1, inM1, sum);
inM2 = *__SIMD32(pB2)++;
sum2 = __SMLAD(inV1, inM2, sum2);
colCnt--;
}
colCnt = dim_vec & 0x3;
while (colCnt)
{
q15_t inV = *pA++;
q15_t inM = *pB++;
q15_t inM2 = *pB2++;
sum += inV * inM;
sum2 += inV * inM2;
colCnt--;
} /* while over colCnt */
*pO++ = (q15_t) (__SSAT((sum >> out_shift), 16));
*pO++ = (q15_t) (__SSAT((sum2>> out_shift), 16));
/* adjust the pointers and counters */
pB = pB + dim_vec;
rowCnt --;
}
rowCnt = num_of_rows & 0x1;
while (rowCnt) {
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = pV;
while (colCnt) {
q31_t inV1, inM1;
inV1 = *__SIMD32(pA)++;
inM1 = *__SIMD32(pB)++;
sum = __SMLAD(inV1, inM1, sum);
inV1 = *__SIMD32(pA)++;
inM1 = *__SIMD32(pB)++;
sum = __SMLAD(inV1, inM1, sum);
colCnt--;
}
/* left-over of the vector */
colCnt = dim_vec & 0x3;
while(colCnt) {
q15_t inV = *pA++;
q15_t inM = *pB++;
sum += inV * inM;
colCnt--;
}
*pO++ = (q15_t) (__SSAT((sum >> out_shift), 16));
rowCnt --;
}
#else
int i, j;
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
for (i = 0; i < num_of_rows; i++)
{
int ip_out = ((q31_t)(bias[i]) << bias_shift) + NN_ROUND(out_shift);
for (j = 0; j < dim_vec; j++)
{
ip_out += pV[j] * pM[i * dim_vec + j];
}
pOut[i] = (q15_t) __SSAT((ip_out >> out_shift), 16);
}
#endif /* ARM_MATH_DSP */
/* Return to application */
return (ARM_MATH_SUCCESS);
}
/**
* @} end of FC group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_fully_connected_q15_opt.c
* Description: Q15 opt fully-connected layer function
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup FC
* @{
*/
/**
* @brief Q15 opt fully-connected layer function
* @param[in] pV pointer to input vector
* @param[in] pM pointer to matrix weights
* @param[in] dim_vec length of the vector
* @param[in] num_of_rows number of rows in weight matrix
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in] bias pointer to bias
* @param[in,out] pOut pointer to output vector
* @param[in,out] vec_buffer pointer to buffer space for input
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*
*
* @details
*
* <b>Buffer size:</b>
*
* vec_buffer size: 0
*
* Here we use only one pointer to read 4 rows in the weight
* matrix. So if the original matrix looks like this:
*
* | a11 | a12 | a13 |
*
* | a21 | a22 | a23 |
*
* | a31 | a32 | a33 |
*
* | a41 | a42 | a43 |
*
* | a51 | a52 | a53 |
*
* | a61 | a62 | a63 |
*
* We operates on multiple-of-4 rows, so the first four rows becomes
*
* | a11 | a12 | a21 | a22 | a31 | a32 | a41 | a42 |
*
* | a13 | a23 | a33 | a43 |
*
* Remaining rows are kept the same original order.
*
* So the stored weight matrix looks like this:
*
*
* | a11 | a12 | a21 | a22 | a31 | a32 | a41 | a42 |
*
* | a13 | a23 | a33 | a43 | a51 | a52 | a53 | a61 |
*
* | a62 | a63 |
*/
arm_status
arm_fully_connected_q15_opt(const q15_t * pV,
const q15_t * pM,
const uint16_t dim_vec,
const uint16_t num_of_rows,
const uint16_t bias_shift,
const uint16_t out_shift,
const q15_t * bias,
q15_t * pOut,
q15_t * vec_buffer)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
const q15_t *pB = pM;
q15_t *pO = pOut;
const q15_t *pBias = bias;
const q15_t *pA = pV;
uint16_t rowCnt = num_of_rows >> 2;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 1;
pA = pV;
#ifdef USE_INTRINSIC
while (colCnt)
{
q31_t inM11, inM12, inM13, inM14;
q31_t inV;
inV = *__SIMD32(pA)++;
inM11 = *__SIMD32(pB)++;
sum = __SMLAD(inV, inM11, sum);
inM12 = *__SIMD32(pB)++;
sum2 = __SMLAD(inV, inM12, sum2);
inM13 = *__SIMD32(pB)++;
sum3 = __SMLAD(inV, inM13, sum3);
inM14 = *__SIMD32(pB)++;
sum4 = __SMLAD(inV, inM14, sum4);
colCnt--;
}
#else
/*
* register needed:
* loop counter: colCnt
* accumulators: sum, sum2, sum3, sum4
* pointers: pB, pA
* weight data: inM11, inM12, inM13, inM14
* activation data: inV
*/
asm volatile ("COL_LOOP_%=:\n"
"ldr.w r4, [%[pA]], #4\n"
"ldr.w r0, [%[pB]], #16\n"
"smlad %[sum], r4, r0, %[sum]\n"
"ldr.w r1, [%[pB] , #-12]\n"
"smlad %[sum2], r4, r1, %[sum2]\n"
"ldr.w r2, [%[pB] , #-8]\n"
"smlad %[sum3], r4, r2, %[sum3]\n"
"ldr.w r3, [%[pB] , #-4]\n"
"smlad %[sum4], r4, r3, %[sum4]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP_%=\n":[sum] "+r"(sum),
[sum2] "+r"(sum2),[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),[pA] "+r"(pA):[colCnt] "r"(colCnt):"r0", "r1", "r2", "r3", "r4");
#endif /* USE_INTRINSIC */
colCnt = dim_vec & 0x1;
while (colCnt)
{
q15_t inV = *pA++;
q15_t inM = *pB++;
q15_t inM2 = *pB++;
q15_t inM3 = *pB++;
q15_t inM4 = *pB++;
sum += inV * inM;
sum2 += inV * inM2;
sum3 += inV * inM3;
sum4 += inV * inM4;
colCnt--;
} /* while over colCnt */
*pO++ = (q15_t) (__SSAT((sum >> out_shift), 16));
*pO++ = (q15_t) (__SSAT((sum2 >> out_shift), 16));
*pO++ = (q15_t) (__SSAT((sum3 >> out_shift), 16));
*pO++ = (q15_t) (__SSAT((sum4 >> out_shift), 16));
/* adjust the pointers and counters */
rowCnt--;
}
/* left-over part of the rows */
rowCnt = num_of_rows & 0x3;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = pV;
while (colCnt)
{
q31_t inV1, inV2, inM1, inM2;
inM1 = *__SIMD32(pB)++;
inV1 = *__SIMD32(pA)++;
sum = __SMLAD(inV1, inM1, sum);
inM2 = *__SIMD32(pB)++;
inV2 = *__SIMD32(pA)++;
sum = __SMLAD(inV2, inM2, sum);
colCnt--;
}
/* left-over of the vector */
colCnt = dim_vec & 0x3;
while (colCnt)
{
q15_t inV = *pA++;
q15_t inM = *pB++;
sum += inV * inM;
colCnt--;
}
*pO++ = (q15_t) (__SSAT((sum >> out_shift), 16));
rowCnt--;
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t rowCnt = num_of_rows >> 2;
const q15_t *pB = pM;
const q15_t *pA;
q15_t *pO = pOut;
const q15_t *pBias = bias;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 1;
pA = pV;
while (colCnt)
{
q15_t inA1 = *pA++;
q15_t inA2 = *pA++;
q15_t inB1 = *pB++;
q15_t inB2 = *pB++;
sum += inA1 * inB1 + inA2 * inB2;
inB1 = *pB++;
inB2 = *pB++;
sum2 += inA1 * inB1 + inA2 * inB2;
inB1 = *pB++;
inB2 = *pB++;
sum3 += inA1 * inB1 + inA2 * inB2;
inB1 = *pB++;
inB2 = *pB++;
sum4 += inA1 * inB1 + inA2 * inB2;
colCnt--;
}
colCnt = dim_vec & 0x1;
while (colCnt)
{
q15_t inA = *pA++;
q15_t inB = *pB++;
sum += inA * inB;
inB = *pB++;
sum2 += inA * inB;
inB = *pB++;
sum3 += inA * inB;
inB = *pB++;
sum4 += inA * inB;
colCnt--;
}
*pO++ = (q15_t) __SSAT((sum >> out_shift), 16);
*pO++ = (q15_t) __SSAT((sum2 >> out_shift), 16);
*pO++ = (q15_t) __SSAT((sum3 >> out_shift), 16);
*pO++ = (q15_t) __SSAT((sum4 >> out_shift), 16);
rowCnt--;
}
rowCnt = num_of_rows & 0x3;
while (rowCnt)
{
int ip_out = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
int j;
pA = pV;
for (j = 0; j < dim_vec; j++)
{
q15_t inA = *pA++;
q15_t inB = *pB++;
ip_out += inA * inB;
}
*pO++ = (q15_t) __SSAT((ip_out >> out_shift), 16);
rowCnt--;
}
#endif /* ARM_MATH_DSP */
/* Return to ARM_MATH_SUCCESS */
return (ARM_MATH_SUCCESS);
}
/**
* @} end of FC group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_fully_connected_q7.c
* Description: Q7 basic fully-connected layer function
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup FC
* @{
*/
/**
* @brief Q7 basic fully-connected layer function
* @param[in] pV pointer to input vector
* @param[in] pM pointer to matrix weights
* @param[in] dim_vec length of the vector
* @param[in] num_of_rows number of rows in weight matrix
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in] bias pointer to bias
* @param[in,out] pOut pointer to output vector
* @param[in,out] vec_buffer pointer to buffer space for input
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*
* @details
*
* <b>Buffer size:</b>
*
* vec_buffer size: dim_vec
*
* This basic function is designed to work with regular weight
* matrix without interleaving.
*
*/
arm_status
arm_fully_connected_q7(const q7_t * pV,
const q7_t * pM,
const uint16_t dim_vec,
const uint16_t num_of_rows,
const uint16_t bias_shift,
const uint16_t out_shift, const q7_t * bias, q7_t * pOut, q15_t * vec_buffer)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
const q7_t *pB = pM;
const q7_t *pB2;
q7_t *pO = pOut;
const q7_t *pBias = bias;
q15_t *pA;
uint16_t rowCnt = num_of_rows >> 1;
/* expand the vector into the buffer */
arm_q7_to_q15_reordered_no_shift(pV, vec_buffer, dim_vec);
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = vec_buffer;
pB2 = pB + dim_vec;
while (colCnt)
{
q31_t inV, inM11, inM12, inM21, inM22;
pB = (q7_t *) read_and_pad_reordered((void *)pB, &inM11, &inM12);
pB2 = (q7_t *) read_and_pad_reordered((void *)pB2, &inM21, &inM22);
inV = *__SIMD32(pA)++;
sum = __SMLAD(inV, inM11, sum);
sum2 = __SMLAD(inV, inM21, sum2);
inV = *__SIMD32(pA)++;
sum = __SMLAD(inV, inM12, sum);
sum2 = __SMLAD(inV, inM22, sum2);
colCnt--;
}
colCnt = dim_vec & 0x3;
while (colCnt)
{
q7_t inV = *pA++;
q15_t inM = *pB++;
q15_t inM2 = *pB2++;
sum += inV * inM;
sum2 += inV * inM2;
colCnt--;
} /* while over colCnt */
*pO++ = (q7_t) (__SSAT((sum >> out_shift), 8));
*pO++ = (q7_t) (__SSAT((sum2 >> out_shift), 8));
/* adjust the pointers and counters */
pB += dim_vec;
rowCnt--;
}
/* left-over part of the rows */
rowCnt = num_of_rows & 0x1;
while (rowCnt)
{
uint16_t colCnt = dim_vec >> 2;
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
pA = vec_buffer;
while (colCnt)
{
q31_t inV1, inV2, inM11, inM12;
pB = (q7_t *) read_and_pad_reordered((void *)pB, &inM11, &inM12);
inV1 = *__SIMD32(pA)++;
sum = __SMLAD(inV1, inM11, sum);
inV2 = *__SIMD32(pA)++;
sum = __SMLAD(inV2, inM12, sum);
colCnt--;
}
/* left-over of the vector */
colCnt = dim_vec & 0x3;
while (colCnt)
{
q7_t inV = *pA++;
q15_t inM = *pB++;
sum += inV * inM;
colCnt--;
}
*pO++ = (q7_t) (__SSAT((sum >> out_shift), 8));
rowCnt--;
}
#else
int i, j;
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
for (i = 0; i < num_of_rows; i++)
{
int ip_out = ((q31_t)(bias[i]) << bias_shift) + NN_ROUND(out_shift);
for (j = 0; j < dim_vec; j++)
{
ip_out += pV[j] * pM[i * dim_vec + j];
}
pOut[i] = (q7_t) __SSAT((ip_out >> out_shift), 8);
}
#endif /* ARM_MATH_DSP */
/* Return to ARM_MATH_SUCCESS */
return (ARM_MATH_SUCCESS);
}
/**
* @} end of FC group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_fully_connected_q7_opt.c
* Description: Q7 basic fully-connected layer function
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup FC
* @{
*/
/**
* @brief Q7 opt fully-connected layer function
* @param[in] pV pointer to input vector
* @param[in] pM pointer to matrix weights
* @param[in] dim_vec length of the vector
* @param[in] num_of_rows number of rows in weight matrix
* @param[in] bias_shift amount of left-shift for bias
* @param[in] out_shift amount of right-shift for output
* @param[in] bias pointer to bias
* @param[in,out] pOut pointer to output vector
* @param[in,out] vec_buffer pointer to buffer space for input
* @return The function returns <code>ARM_MATH_SUCCESS</code>
*
* @details
*
* <b>Buffer size:</b>
*
* vec_buffer size: dim_vec
*
* This opt function is designed to work with interleaved weight
* matrix. The vector input is assumed in q7_t format, we call
* arm_q7_to_q15_no_shift_shuffle function to expand into
* q15_t format with certain weight re-ordering, refer to the function
* comments for more details.
* Here we use only one pointer to read 4 rows in the weight
* matrix. So if the original q7_t matrix looks like this:
*
* | a11 | a12 | a13 | a14 | a15 | a16 | a17 |
*
* | a21 | a22 | a23 | a24 | a25 | a26 | a27 |
*
* | a31 | a32 | a33 | a34 | a35 | a36 | a37 |
*
* | a41 | a42 | a43 | a44 | a45 | a46 | a47 |
*
* | a51 | a52 | a53 | a54 | a55 | a56 | a57 |
*
* | a61 | a62 | a63 | a64 | a65 | a66 | a67 |
*
*
* We operates on multiple-of-4 rows, so the first four rows becomes
*
* | a11 | a21 | a13 | a23 | a31 | a41 | a33 | a43 |
*
* | a12 | a22 | a14 | a24 | a32 | a42 | a34 | a44 |
*
* | a15 | a25 | a35 | a45 | a16 | a26 | a36 | a46 |
*
* So within the kernel, we first read the re-ordered vector in as:
*
* | b1 | b3 | and | b2 | b4 |
*
* the four q31_t weights will look like
*
* | a11 | a13 |, | a21 | a23 |, | a31 | a33 |, | a41 | a43 |
*
* | a12 | a14 |, | a22 | a24 |, | a32 | a34 |, | a42 | a44 |
*
* The column left over will be in-order.
* which is:
*
* | a17 | a27 | a37 | a47 |
*
* For the left-over rows, we do 1x1 computation, so the data remains
* as its original order.
*
* So the stored weight matrix looks like this:
*
* | a11 | a21 | a13 | a23 | a31 | a41 |
*
* | a33 | a43 | a12 | a22 | a14 | a24 |
*
* | a32 | a42 | a34 | a44 | a15 | a25 |
*
* | a35 | a45 | a16 | a26 | a36 | a46 |
*
* | a17 | a27 | a37 | a47 | a51 | a52 |
*
* | a53 | a54 | a55 | a56 | a57 | a61 |
*
* | a62 | a63 | a64 | a65 | a66 | a67 |
*
*
*/
arm_status
arm_fully_connected_q7_opt(const q7_t * pV,
const q7_t * pM,
const uint16_t dim_vec,
const uint16_t num_of_rows,
const uint16_t bias_shift,
const uint16_t out_shift,
const q7_t * bias,
q7_t * pOut,
q15_t * vec_buffer)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
const q7_t *pB = pM;
q7_t *pO = pOut;
const q7_t *pBias = bias;
q15_t *pA;
uint16_t rowCnt = num_of_rows >> 2;
arm_q7_to_q15_reordered_no_shift(pV, vec_buffer, dim_vec);
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = vec_buffer;
#ifdef USE_INTRINSIC
#ifndef ARM_MATH_BIG_ENDIAN
while (colCnt)
{
q31_t inM11, inM12, inM13, inM14;
q31_t inV;
inV = *__SIMD32(pA)++;
inM11 = *__SIMD32(pB)++;
inM12 = __SXTB16(__ROR(inM11, 8));
inM11 = __SXTB16(inM11);
sum = __SMLAD(inM11, inV, sum);
sum2 = __SMLAD(inM12, inV, sum2);
inM13 = *__SIMD32(pB)++;
inM14 = __SXTB16(__ROR(inM13, 8));
inM13 = __SXTB16(inM13);
sum3 = __SMLAD(inM13, inV, sum3);
sum4 = __SMLAD(inM14, inV, sum4);
inV = *__SIMD32(pA)++;
inM11 = *__SIMD32(pB)++;
inM12 = __SXTB16(__ROR(inM11, 8));
inM11 = __SXTB16(inM11);
sum = __SMLAD(inM11, inV, sum);
sum2 = __SMLAD(inM12, inV, sum2);
inM13 = *__SIMD32(pB)++;
inM14 = __SXTB16(__ROR(inM13, 8));
inM13 = __SXTB16(inM13);
sum3 = __SMLAD(inM13, inV, sum3);
sum4 = __SMLAD(inM14, inV, sum4);
colCnt--;
}
#else
while (colCnt)
{
q31_t inM11, inM12, inM13, inM14;
q31_t inV;
inV = *__SIMD32(pA)++;
inM11 = *__SIMD32(pB)++;
inM12 = __SXTB16(__ROR(inM11, 8));
inM11 = __SXTB16(inM11);
sum = __SMLAD(inM12, inV, sum);
sum2 = __SMLAD(inM11, inV, sum2);
inM13 = *__SIMD32(pB)++;
inM14 = __SXTB16(__ROR(inM13, 8));
inM13 = __SXTB16(inM13);
sum3 = __SMLAD(inM14, inV, sum3);
sum4 = __SMLAD(inM13, inV, sum4);
inV = *__SIMD32(pA)++;
inM11 = *__SIMD32(pB)++;
inM12 = __SXTB16(__ROR(inM11, 8));
inM11 = __SXTB16(inM11);
sum = __SMLAD(inM12, inV, sum);
sum2 = __SMLAD(inM11, inV, sum2);
inM13 = *__SIMD32(pB)++;
inM14 = __SXTB16(__ROR(inM13, 8));
inM13 = __SXTB16(inM13);
sum3 = __SMLAD(inM14, inV, sum3);
sum4 = __SMLAD(inM13, inV, sum4);
colCnt--;
}
#endif /* ARM_MATH_BIG_ENDIAN */
#else
/*
* register needed:
* loop counter: colCnt
* accumulators: sum, sum2, sum3, sum4
* pointers: pB, pA
* weight data: inM11, inM12, inM13, inM14
* activation data: inV
*/
#ifndef ARM_MATH_BIG_ENDIAN
asm volatile ("COL_LOOP_%=:\n"
"ldr.w r4, [%[pA]], #8\n"
"ldr.w r1, [%[pB]], #16\n"
"mov.w r0, r1, ror #8\n"
"sxtb16 r0, r0\n"
"sxtb16 r1, r1\n"
"smlad %[sum], r4, r1, %[sum]\n"
"smlad %[sum2], r4, r0, %[sum2]\n"
"ldr.w r3, [%[pB], #-12]\n"
"mov.w r2, r3, ror #8\n"
"sxtb16 r2, r2\n"
"sxtb16 r3, r3\n"
"smlad %[sum3], r4, r3, %[sum3]\n"
"smlad %[sum4], r4, r2, %[sum4]\n"
"ldr.w r4, [%[pA], #-4]\n"
"ldr.w r1, [%[pB], #-8]\n"
"mov.w r0, r1, ror #8\n"
"sxtb16 r0, r0\n"
"sxtb16 r1, r1\n"
"smlad %[sum], r4, r1, %[sum]\n"
"smlad %[sum2], r4, r0, %[sum2]\n"
"ldr.w r3, [%[pB], #-4]\n"
"mov.w r2, r3, ror #8\n"
"sxtb16 r2, r2\n"
"sxtb16 r3, r3\n"
"smlad %[sum3], r4, r3, %[sum3]\n"
"smlad %[sum4], r4, r2, %[sum4]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP_%=\n":[sum] "+r"(sum),
[sum2] "+r"(sum2),[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),[pA] "+r"(pA):[colCnt] "r"(colCnt):"r0", "r1", "r2", "r3", "r4");
#else
asm volatile ("COL_LOOP_%=:\n"
"ldr.w r4, [%[pA]], #8\n"
"ldr.w r1, [%[pB]], #16\n"
"mov.w r0, r1, ror #8\n"
"sxtb16 r0, r0\n"
"sxtb16 r1, r1\n"
"smlad %[sum], r4, r0, %[sum]\n"
"smlad %[sum2], r4, r1, %[sum2]\n"
"ldr.w r3, [%[pB], #-12]\n"
"mov.w r2, r3, ror #8\n"
"sxtb16 r2, r2\n"
"sxtb16 r3, r3\n"
"smlad %[sum3], r4, r2, %[sum3]\n"
"smlad %[sum4], r4, r3, %[sum4]\n"
"ldr.w r4, [%[pA], #-4]\n"
"ldr.w r1, [%[pB], #-8]\n"
"mov.w r0, r1, ror #8\n"
"sxtb16 r0, r0\n"
"sxtb16 r1, r1\n"
"smlad %[sum], r4, r0, %[sum]\n"
"smlad %[sum2], r4, r1, %[sum2]\n"
"ldr.w r3, [%[pB], #-4]\n"
"mov.w r2, r3, ror #8\n"
"sxtb16 r2, r2\n"
"sxtb16 r3, r3\n"
"smlad %[sum3], r4, r2, %[sum3]\n"
"smlad %[sum4], r4, r3, %[sum4]\n"
"subs %[colCnt], #1\n"
"bne COL_LOOP_%=\n":[sum] "+r"(sum),
[sum2] "+r"(sum2),[sum3] "+r"(sum3),
[sum4] "+r"(sum4),[pB] "+r"(pB),[pA] "+r"(pA):[colCnt] "r"(colCnt):"r0", "r1", "r2", "r3", "r4");
#endif /* ARM_MATH_BIG_ENDIAN */
#endif /* USE_INTRINSIC */
colCnt = dim_vec & 0x3;
while (colCnt)
{
q15_t inV = *pA++;
q7_t inM = *pB++;
q7_t inM2 = *pB++;
q7_t inM3 = *pB++;
q7_t inM4 = *pB++;
sum += inV * inM;
sum2 += inV * inM2;
sum3 += inV * inM3;
sum4 += inV * inM4;
colCnt--;
} /* while over colCnt */
*pO++ = (q7_t) (__SSAT((sum >> out_shift), 8));
*pO++ = (q7_t) (__SSAT((sum2 >> out_shift), 8));
*pO++ = (q7_t) (__SSAT((sum3 >> out_shift), 8));
*pO++ = (q7_t) (__SSAT((sum4 >> out_shift), 8));
/* adjust the pointers and counters */
rowCnt--;
}
/* left-over part of the rows */
rowCnt = num_of_rows & 0x3;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = vec_buffer;
while (colCnt)
{
q31_t inV1, inV2, inM11, inM12;
pB = (q7_t *) read_and_pad_reordered((void *)pB, &inM11, &inM12);
inV1 = *__SIMD32(pA)++;
sum = __SMLAD(inV1, inM11, sum);
inV2 = *__SIMD32(pA)++;
sum = __SMLAD(inV2, inM12, sum);
colCnt--;
}
/* left-over of the vector */
colCnt = dim_vec & 0x3;
while (colCnt)
{
q15_t inV = *pA++;
q7_t inM = *pB++;
sum += inV * inM;
colCnt--;
}
*pO++ = (q7_t) (__SSAT((sum >> out_shift), 8));
rowCnt--;
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
uint16_t rowCnt = num_of_rows >> 2;
const q7_t *pB = pM;
const q7_t *pA;
q7_t *pO = pOut;
const q7_t *pBias = bias;
while (rowCnt)
{
q31_t sum = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum2 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum3 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
q31_t sum4 = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
uint16_t colCnt = dim_vec >> 2;
pA = pV;
while (colCnt)
{
q7_t inA1 = *pA++;
q7_t inA3 = *pA++;
q7_t inA2 = *pA++;
q7_t inA4 = *pA++;
q7_t inB1 = *pB++;
q7_t inB3 = *pB++;
q7_t inB2 = *pB++;
q7_t inB4 = *pB++;
sum += inA1 * inB1 + inA2 * inB2;
sum2 += inA1 * inB3 + inA2 * inB4;
inB1 = *pB++;
inB3 = *pB++;
inB2 = *pB++;
inB4 = *pB++;
sum3 += inA1 * inB1 + inA2 * inB2;
sum4 += inA1 * inB3 + inA2 * inB4;
inB1 = *pB++;
inB3 = *pB++;
inB2 = *pB++;
inB4 = *pB++;
sum += inA3 * inB1 + inA4 * inB2;
sum2 += inA3 * inB3 + inA4 * inB4;
inB1 = *pB++;
inB3 = *pB++;
inB2 = *pB++;
inB4 = *pB++;
sum3 += inA3 * inB1 + inA4 * inB2;
sum4 += inA3 * inB3 + inA4 * inB4;
colCnt--;
}
colCnt = dim_vec & 0x3;
while (colCnt)
{
q7_t inA = *pA++;
q7_t inB = *pB++;
sum += inA * inB;
inB = *pB++;
sum2 += inA * inB;
inB = *pB++;
sum3 += inA * inB;
inB = *pB++;
sum4 += inA * inB;
colCnt--;
}
*pO++ = (q7_t) __SSAT((sum >> out_shift), 8);
*pO++ = (q7_t) __SSAT((sum2 >> out_shift), 8);
*pO++ = (q7_t) __SSAT((sum3 >> out_shift), 8);
*pO++ = (q7_t) __SSAT((sum4 >> out_shift), 8);
rowCnt--;
}
rowCnt = num_of_rows & 0x3;
while (rowCnt)
{
int ip_out = ((q31_t)(*pBias++) << bias_shift) + NN_ROUND(out_shift);
int j;
pA = pV;
for (j = 0; j < dim_vec; j++)
{
q7_t inA = *pA++;
q7_t inB = *pB++;
ip_out += inA * inB;
}
*pO++ = (q7_t) __SSAT((ip_out >> out_shift), 8);
rowCnt--;
}
#endif /* ARM_MATH_DSP */
/* Return to ARM_MATH_SUCCESS */
return (ARM_MATH_SUCCESS);
}
/**
* @} end of FC group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_nn_mult_q15.c
* Description: Q15 vector multiplication with variable output shifts
*
* $Date: 13. July 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_nnfunctions.h"
/**
* @ingroup groupSupport
*/
/**
* @addtogroup NNBasicMath
* @{
*/
/**
* @brief Q7 vector multiplication with variable output shifts
* @param[in] *pSrcA pointer to the first input vector
* @param[in] *pSrcB pointer to the second input vector
* @param[out] *pDst pointer to the output vector
* @param[in] out_shift amount of right-shift for output
* @param[in] blockSize number of samples in each vector
* @return none.
*
* <b>Scaling and Overflow Behavior:</b>
* \par
* The function uses saturating arithmetic.
* Results outside of the allowable Q15 range [0x8000 0x7FFF] will be saturated.
*/
void arm_nn_mult_q15(
q15_t * pSrcA,
q15_t * pSrcB,
q15_t * pDst,
const uint16_t out_shift,
uint32_t blockSize)
{
uint32_t blkCnt; /* loop counters */
#if defined (ARM_MATH_DSP)
/* Run the below code for Cortex-M4 and Cortex-M3 */
q31_t inA1, inA2, inB1, inB2; /* temporary input variables */
q15_t out1, out2, out3, out4; /* temporary output variables */
q31_t mul1, mul2, mul3, mul4; /* temporary variables */
/* loop Unrolling */
blkCnt = blockSize >> 2U;
/* First part of the processing with loop unrolling. Compute 4 outputs at a time.
** a second loop below computes the remaining 1 to 3 samples. */
while (blkCnt > 0U)
{
/* read two samples at a time from sourceA */
inA1 = *__SIMD32(pSrcA)++;
/* read two samples at a time from sourceB */
inB1 = *__SIMD32(pSrcB)++;
/* read two samples at a time from sourceA */
inA2 = *__SIMD32(pSrcA)++;
/* read two samples at a time from sourceB */
inB2 = *__SIMD32(pSrcB)++;
/* multiply mul = sourceA * sourceB */
mul1 = (q31_t) ((q15_t) (inA1 >> 16) * (q15_t) (inB1 >> 16));
mul2 = (q31_t) ((q15_t) inA1 * (q15_t) inB1);
mul3 = (q31_t) ((q15_t) (inA2 >> 16) * (q15_t) (inB2 >> 16));
mul4 = (q31_t) ((q15_t) inA2 * (q15_t) inB2);
/* saturate result to 16 bit */
out1 = (q15_t) __SSAT((mul1 + NN_ROUND(out_shift)) >> out_shift, 16);
out2 = (q15_t) __SSAT((mul2 + NN_ROUND(out_shift)) >> out_shift, 16);
out3 = (q15_t) __SSAT((mul3 + NN_ROUND(out_shift)) >> out_shift, 16);
out4 = (q15_t) __SSAT((mul4 + NN_ROUND(out_shift)) >> out_shift, 16);
/* store the result */
#ifndef ARM_MATH_BIG_ENDIAN
*__SIMD32(pDst)++ = __PKHBT(out2, out1, 16);
*__SIMD32(pDst)++ = __PKHBT(out4, out3, 16);
#else
*__SIMD32(pDst)++ = __PKHBT(out2, out1, 16);
*__SIMD32(pDst)++ = __PKHBT(out4, out3, 16);
#endif /* #ifndef ARM_MATH_BIG_ENDIAN */
/* Decrement the blockSize loop counter */
blkCnt--;
}
/* If the blockSize is not a multiple of 4, compute any remaining output samples here.
** No loop unrolling is used. */
blkCnt = blockSize % 0x4U;
#else
/* Run the below code for Cortex-M0 */
/* Initialize blkCnt with number of samples */
blkCnt = blockSize;
#endif /* #if defined (ARM_MATH_DSP) */
while (blkCnt > 0U)
{
/* C = A * B */
/* Multiply the inputs and store the result in the destination buffer */
*pDst++ = (q15_t) __SSAT((((q31_t) (*pSrcA++) * (*pSrcB++) + NN_ROUND(out_shift)) >> out_shift), 16);
/* Decrement the blockSize loop counter */
blkCnt--;
}
}
/**
* @} end of NNBasicMath group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_nn_mult_q7.c
* Description: Q7 vector multiplication with variable output shifts
*
* $Date: 13. July 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_nnfunctions.h"
/**
* @ingroup groupSupport
*/
/**
* @addtogroup NNBasicMath
* @{
*/
/**
* @brief Q7 vector multiplication with variable output shifts
* @param[in] *pSrcA pointer to the first input vector
* @param[in] *pSrcB pointer to the second input vector
* @param[out] *pDst pointer to the output vector
* @param[in] out_shift amount of right-shift for output
* @param[in] blockSize number of samples in each vector
* @return none.
*
* <b>Scaling and Overflow Behavior:</b>
* \par
* The function uses saturating arithmetic.
* Results outside of the allowable Q7 range [0x80 0x7F] will be saturated.
*/
void arm_nn_mult_q7(
q7_t * pSrcA,
q7_t * pSrcB,
q7_t * pDst,
const uint16_t out_shift,
uint32_t blockSize)
{
uint32_t blkCnt; /* loop counters */
#if defined (ARM_MATH_DSP)
/* Run the below code for Cortex-M4 and Cortex-M3 */
q7_t out1, out2, out3, out4; /* Temporary variables to store the product */
/* loop Unrolling */
blkCnt = blockSize >> 2U;
/* First part of the processing with loop unrolling. Compute 4 outputs at a time.
** a second loop below computes the remaining 1 to 3 samples. */
while (blkCnt > 0U)
{
/* C = A * B */
/* Multiply the inputs and store the results in temporary variables */
out1 = (q7_t) __SSAT((((q15_t) (*pSrcA++) * (*pSrcB++) + NN_ROUND(out_shift)) >> out_shift), 8);
out2 = (q7_t) __SSAT((((q15_t) (*pSrcA++) * (*pSrcB++) + NN_ROUND(out_shift)) >> out_shift), 8);
out3 = (q7_t) __SSAT((((q15_t) (*pSrcA++) * (*pSrcB++) + NN_ROUND(out_shift)) >> out_shift), 8);
out4 = (q7_t) __SSAT((((q15_t) (*pSrcA++) * (*pSrcB++) + NN_ROUND(out_shift)) >> out_shift), 8);
/* Store the results of 4 inputs in the destination buffer in single cycle by packing */
*__SIMD32(pDst)++ = __PACKq7(out1, out2, out3, out4);
/* Decrement the blockSize loop counter */
blkCnt--;
}
/* If the blockSize is not a multiple of 4, compute any remaining output samples here.
** No loop unrolling is used. */
blkCnt = blockSize % 0x4U;
#else
/* Run the below code for Cortex-M0 */
/* Initialize blkCnt with number of samples */
blkCnt = blockSize;
#endif /* #if defined (ARM_MATH_DSP) */
while (blkCnt > 0U)
{
/* C = A * B */
/* Multiply the inputs and store the result in the destination buffer */
*pDst++ = (q7_t) __SSAT((((q15_t) (*pSrcA++) * (*pSrcB++) + NN_ROUND(out_shift)) >> out_shift), 8);
/* Decrement the blockSize loop counter */
blkCnt--;
}
}
/**
* @} end of NNBasicMath group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_nntables.c
* Description: Converts the elements of the Q7 vector to Q15 vector without left-shift
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_nnsupportfunctions.h"
/**
* @brief tables for various activation functions
*
* This file include the declaration of common tables.
* Most of them are used for activation functions
*
* Assumption:
* Unified table: input is 3.x format, i.e, range of [-8, 8)
* sigmoid(8) = 0.9996646498695336
* tanh(8) = 0.9999997749296758
* The accuracy here should be good enough
*
* 2-stage HL table:
*
* The entire input range is divided into two parts:
*
* Low range table: 0x000x xxxx or 0x111x xxxx
* table entry will be the binary number excluding the first
* two digits, i.e., 0x0x xxxx or 0x1x xxxx
*
*
*
* High range table 0x0010 0000 -- 0x0111 1111
* 0x1000 0000 -- 0x1101 1111
*
* For positive numbers, table entry will be
* 0x0010 0000 -- 0x0111 1111 minus 0x0010 0000
* i.e., 0x0000 0000 - 0x0101 11111
*
* same thing for the negative numbers, table entry will be
* 0x1000 0000 -- 0x1101 1111 minux 0x0010 0000
* i.e., 0x0110 0000 - 0x1011 1111
*/
const q7_t sigmoidTable_q7[256] = {
0x40, 0x42, 0x44, 0x46, 0x48, 0x4a, 0x4c, 0x4e,
0x50, 0x52, 0x53, 0x55, 0x57, 0x59, 0x5a, 0x5c,
0x5e, 0x5f, 0x61, 0x62, 0x63, 0x65, 0x66, 0x67,
0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70,
0x71, 0x72, 0x72, 0x73, 0x74, 0x74, 0x75, 0x76,
0x76, 0x77, 0x77, 0x78, 0x78, 0x79, 0x79, 0x7a,
0x7a, 0x7a, 0x7b, 0x7b, 0x7b, 0x7c, 0x7c, 0x7c,
0x7c, 0x7c, 0x7d, 0x7d, 0x7d, 0x7d, 0x7d, 0x7e,
0x7e, 0x7e, 0x7e, 0x7e, 0x7e, 0x7e, 0x7e, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01,
0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01,
0x01, 0x01, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02,
0x02, 0x02, 0x03, 0x03, 0x03, 0x03, 0x03, 0x04,
0x04, 0x04, 0x04, 0x04, 0x05, 0x05, 0x05, 0x06,
0x06, 0x06, 0x07, 0x07, 0x08, 0x08, 0x09, 0x09,
0x0a, 0x0a, 0x0b, 0x0c, 0x0c, 0x0d, 0x0e, 0x0e,
0x0f, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16,
0x17, 0x19, 0x1a, 0x1b, 0x1d, 0x1e, 0x1f, 0x21,
0x22, 0x24, 0x26, 0x27, 0x29, 0x2b, 0x2d, 0x2e,
0x30, 0x32, 0x34, 0x36, 0x38, 0x3a, 0x3c, 0x3e,
};
const q15_t sigmoidTable_q15[256] = {
0x4000, 0x4200, 0x43ff, 0x45fc, 0x47f5, 0x49eb, 0x4bdc, 0x4dc8,
0x4fad, 0x518a, 0x5360, 0x552c, 0x56ef, 0x58a8, 0x5a57, 0x5bfb,
0x5d93, 0x5f20, 0x60a1, 0x6216, 0x637f, 0x64db, 0x662b, 0x676f,
0x68a6, 0x69d2, 0x6af1, 0x6c05, 0x6d0d, 0x6e09, 0x6efb, 0x6fe2,
0x70be, 0x7190, 0x7258, 0x7316, 0x73cc, 0x7478, 0x751b, 0x75b7,
0x764a, 0x76d6, 0x775b, 0x77d8, 0x784f, 0x78c0, 0x792a, 0x798f,
0x79ee, 0x7a48, 0x7a9d, 0x7aed, 0x7b39, 0x7b80, 0x7bc4, 0x7c03,
0x7c3f, 0x7c78, 0x7cad, 0x7ce0, 0x7d0f, 0x7d3c, 0x7d66, 0x7d8d,
0x7db3, 0x7dd6, 0x7df7, 0x7e16, 0x7e33, 0x7e4f, 0x7e69, 0x7e81,
0x7e98, 0x7eae, 0x7ec2, 0x7ed5, 0x7ee7, 0x7ef8, 0x7f08, 0x7f17,
0x7f25, 0x7f32, 0x7f3e, 0x7f4a, 0x7f55, 0x7f5f, 0x7f69, 0x7f72,
0x7f7b, 0x7f83, 0x7f8a, 0x7f91, 0x7f98, 0x7f9e, 0x7fa4, 0x7faa,
0x7faf, 0x7fb4, 0x7fb8, 0x7fbd, 0x7fc1, 0x7fc5, 0x7fc8, 0x7fcc,
0x7fcf, 0x7fd2, 0x7fd5, 0x7fd7, 0x7fda, 0x7fdc, 0x7fde, 0x7fe0,
0x7fe2, 0x7fe4, 0x7fe6, 0x7fe7, 0x7fe9, 0x7fea, 0x7feb, 0x7fed,
0x7fee, 0x7fef, 0x7ff0, 0x7ff1, 0x7ff2, 0x7ff3, 0x7ff4, 0x7ff4,
0x000b, 0x000c, 0x000c, 0x000d, 0x000e, 0x000f, 0x0010, 0x0011,
0x0012, 0x0013, 0x0015, 0x0016, 0x0017, 0x0019, 0x001a, 0x001c,
0x001e, 0x0020, 0x0022, 0x0024, 0x0026, 0x0029, 0x002b, 0x002e,
0x0031, 0x0034, 0x0038, 0x003b, 0x003f, 0x0043, 0x0048, 0x004c,
0x0051, 0x0056, 0x005c, 0x0062, 0x0068, 0x006f, 0x0076, 0x007d,
0x0085, 0x008e, 0x0097, 0x00a1, 0x00ab, 0x00b6, 0x00c2, 0x00ce,
0x00db, 0x00e9, 0x00f8, 0x0108, 0x0119, 0x012b, 0x013e, 0x0152,
0x0168, 0x017f, 0x0197, 0x01b1, 0x01cd, 0x01ea, 0x0209, 0x022a,
0x024d, 0x0273, 0x029a, 0x02c4, 0x02f1, 0x0320, 0x0353, 0x0388,
0x03c1, 0x03fd, 0x043c, 0x0480, 0x04c7, 0x0513, 0x0563, 0x05b8,
0x0612, 0x0671, 0x06d6, 0x0740, 0x07b1, 0x0828, 0x08a5, 0x092a,
0x09b6, 0x0a49, 0x0ae5, 0x0b88, 0x0c34, 0x0cea, 0x0da8, 0x0e70,
0x0f42, 0x101e, 0x1105, 0x11f7, 0x12f3, 0x13fb, 0x150f, 0x162e,
0x175a, 0x1891, 0x19d5, 0x1b25, 0x1c81, 0x1dea, 0x1f5f, 0x20e0,
0x226d, 0x2405, 0x25a9, 0x2758, 0x2911, 0x2ad4, 0x2ca0, 0x2e76,
0x3053, 0x3238, 0x3424, 0x3615, 0x380b, 0x3a04, 0x3c01, 0x3e00,
};
const q15_t sigmoidLTable_q15[128] = {
0x4000, 0x4100, 0x4200, 0x42ff, 0x43ff, 0x44fd, 0x45fc, 0x46f9,
0x47f5, 0x48f1, 0x49eb, 0x4ae5, 0x4bdc, 0x4cd3, 0x4dc8, 0x4ebb,
0x4fad, 0x509c, 0x518a, 0x5276, 0x5360, 0x5447, 0x552c, 0x560f,
0x56ef, 0x57cd, 0x58a8, 0x5981, 0x5a57, 0x5b2a, 0x5bfb, 0x5cc9,
0x5d93, 0x5e5b, 0x5f20, 0x5fe2, 0x60a1, 0x615d, 0x6216, 0x62cc,
0x637f, 0x642e, 0x64db, 0x6584, 0x662b, 0x66ce, 0x676f, 0x680c,
0x68a6, 0x693d, 0x69d2, 0x6a63, 0x6af1, 0x6b7c, 0x6c05, 0x6c8a,
0x6d0d, 0x6d8d, 0x6e09, 0x6e84, 0x6efb, 0x6f70, 0x6fe2, 0x7051,
0x0f42, 0x0faf, 0x101e, 0x1090, 0x1105, 0x117c, 0x11f7, 0x1273,
0x12f3, 0x1376, 0x13fb, 0x1484, 0x150f, 0x159d, 0x162e, 0x16c3,
0x175a, 0x17f4, 0x1891, 0x1932, 0x19d5, 0x1a7c, 0x1b25, 0x1bd2,
0x1c81, 0x1d34, 0x1dea, 0x1ea3, 0x1f5f, 0x201e, 0x20e0, 0x21a5,
0x226d, 0x2337, 0x2405, 0x24d6, 0x25a9, 0x267f, 0x2758, 0x2833,
0x2911, 0x29f1, 0x2ad4, 0x2bb9, 0x2ca0, 0x2d8a, 0x2e76, 0x2f64,
0x3053, 0x3145, 0x3238, 0x332d, 0x3424, 0x351b, 0x3615, 0x370f,
0x380b, 0x3907, 0x3a04, 0x3b03, 0x3c01, 0x3d01, 0x3e00, 0x3f00,
};
const q15_t sigmoidHTable_q15[192] = {
0x70be, 0x7190, 0x7258, 0x7316, 0x73cc, 0x7478, 0x751b, 0x75b7,
0x764a, 0x76d6, 0x775b, 0x77d8, 0x784f, 0x78c0, 0x792a, 0x798f,
0x79ee, 0x7a48, 0x7a9d, 0x7aed, 0x7b39, 0x7b80, 0x7bc4, 0x7c03,
0x7c3f, 0x7c78, 0x7cad, 0x7ce0, 0x7d0f, 0x7d3c, 0x7d66, 0x7d8d,
0x7db3, 0x7dd6, 0x7df7, 0x7e16, 0x7e33, 0x7e4f, 0x7e69, 0x7e81,
0x7e98, 0x7eae, 0x7ec2, 0x7ed5, 0x7ee7, 0x7ef8, 0x7f08, 0x7f17,
0x7f25, 0x7f32, 0x7f3e, 0x7f4a, 0x7f55, 0x7f5f, 0x7f69, 0x7f72,
0x7f7b, 0x7f83, 0x7f8a, 0x7f91, 0x7f98, 0x7f9e, 0x7fa4, 0x7faa,
0x7faf, 0x7fb4, 0x7fb8, 0x7fbd, 0x7fc1, 0x7fc5, 0x7fc8, 0x7fcc,
0x7fcf, 0x7fd2, 0x7fd5, 0x7fd7, 0x7fda, 0x7fdc, 0x7fde, 0x7fe0,
0x7fe2, 0x7fe4, 0x7fe6, 0x7fe7, 0x7fe9, 0x7fea, 0x7feb, 0x7fed,
0x7fee, 0x7fef, 0x7ff0, 0x7ff1, 0x7ff2, 0x7ff3, 0x7ff4, 0x7ff4,
0x000b, 0x000c, 0x000c, 0x000d, 0x000e, 0x000f, 0x0010, 0x0011,
0x0012, 0x0013, 0x0015, 0x0016, 0x0017, 0x0019, 0x001a, 0x001c,
0x001e, 0x0020, 0x0022, 0x0024, 0x0026, 0x0029, 0x002b, 0x002e,
0x0031, 0x0034, 0x0038, 0x003b, 0x003f, 0x0043, 0x0048, 0x004c,
0x0051, 0x0056, 0x005c, 0x0062, 0x0068, 0x006f, 0x0076, 0x007d,
0x0085, 0x008e, 0x0097, 0x00a1, 0x00ab, 0x00b6, 0x00c2, 0x00ce,
0x00db, 0x00e9, 0x00f8, 0x0108, 0x0119, 0x012b, 0x013e, 0x0152,
0x0168, 0x017f, 0x0197, 0x01b1, 0x01cd, 0x01ea, 0x0209, 0x022a,
0x024d, 0x0273, 0x029a, 0x02c4, 0x02f1, 0x0320, 0x0353, 0x0388,
0x03c1, 0x03fd, 0x043c, 0x0480, 0x04c7, 0x0513, 0x0563, 0x05b8,
0x0612, 0x0671, 0x06d6, 0x0740, 0x07b1, 0x0828, 0x08a5, 0x092a,
0x09b6, 0x0a49, 0x0ae5, 0x0b88, 0x0c34, 0x0cea, 0x0da8, 0x0e70,
};
const q7_t tanhTable_q7[256] = {
0x00, 0x08, 0x10, 0x18, 0x1f, 0x27, 0x2e, 0x35,
0x3b, 0x41, 0x47, 0x4c, 0x51, 0x56, 0x5a, 0x5e,
0x61, 0x65, 0x68, 0x6a, 0x6d, 0x6f, 0x71, 0x72,
0x74, 0x75, 0x76, 0x78, 0x78, 0x79, 0x7a, 0x7b,
0x7b, 0x7c, 0x7c, 0x7d, 0x7d, 0x7e, 0x7e, 0x7e,
0x7e, 0x7e, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f, 0x7f,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x81,
0x81, 0x81, 0x81, 0x81, 0x81, 0x81, 0x81, 0x82,
0x82, 0x82, 0x82, 0x82, 0x83, 0x83, 0x84, 0x84,
0x85, 0x85, 0x86, 0x87, 0x88, 0x88, 0x8a, 0x8b,
0x8c, 0x8e, 0x8f, 0x91, 0x93, 0x96, 0x98, 0x9b,
0x9f, 0xa2, 0xa6, 0xaa, 0xaf, 0xb4, 0xb9, 0xbf,
0xc5, 0xcb, 0xd2, 0xd9, 0xe1, 0xe8, 0xf0, 0xf8,
};
const q15_t tanhTable_q15[256] = {
0x0000, 0x07fd, 0x0feb, 0x17b9, 0x1f59, 0x26bf, 0x2ddf, 0x34ae,
0x3b27, 0x4142, 0x46fd, 0x4c56, 0x514d, 0x55e2, 0x5a1a, 0x5df6,
0x617c, 0x64b0, 0x6797, 0x6a37, 0x6c95, 0x6eb5, 0x709e, 0x7254,
0x73dc, 0x753a, 0x7672, 0x7788, 0x787f, 0x795b, 0x7a1e, 0x7acb,
0x7b65, 0x7bee, 0x7c66, 0x7cd1, 0x7d30, 0x7d84, 0x7dce, 0x7e0f,
0x7e49, 0x7e7d, 0x7eaa, 0x7ed2, 0x7ef5, 0x7f14, 0x7f30, 0x7f48,
0x7f5e, 0x7f71, 0x7f82, 0x7f91, 0x7f9e, 0x7fa9, 0x7fb3, 0x7fbc,
0x7fc4, 0x7fcb, 0x7fd1, 0x7fd7, 0x7fdc, 0x7fe0, 0x7fe4, 0x7fe7,
0x7fea, 0x7fed, 0x7fef, 0x7ff1, 0x7ff3, 0x7ff4, 0x7ff6, 0x7ff7,
0x7ff8, 0x7ff9, 0x7ffa, 0x7ffa, 0x7ffb, 0x7ffc, 0x7ffc, 0x7ffd,
0x7ffd, 0x7ffd, 0x7ffe, 0x7ffe, 0x7ffe, 0x7ffe, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000,
0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000,
0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000,
0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000,
0x8000, 0x8000, 0x8001, 0x8001, 0x8001, 0x8001, 0x8001, 0x8001,
0x8001, 0x8001, 0x8001, 0x8002, 0x8002, 0x8002, 0x8002, 0x8003,
0x8003, 0x8003, 0x8004, 0x8004, 0x8005, 0x8006, 0x8006, 0x8007,
0x8008, 0x8009, 0x800a, 0x800c, 0x800d, 0x800f, 0x8011, 0x8013,
0x8016, 0x8019, 0x801c, 0x8020, 0x8024, 0x8029, 0x802f, 0x8035,
0x803c, 0x8044, 0x804d, 0x8057, 0x8062, 0x806f, 0x807e, 0x808f,
0x80a2, 0x80b8, 0x80d0, 0x80ec, 0x810b, 0x812e, 0x8156, 0x8183,
0x81b7, 0x81f1, 0x8232, 0x827c, 0x82d0, 0x832f, 0x839a, 0x8412,
0x849b, 0x8535, 0x85e2, 0x86a5, 0x8781, 0x8878, 0x898e, 0x8ac6,
0x8c24, 0x8dac, 0x8f62, 0x914b, 0x936b, 0x95c9, 0x9869, 0x9b50,
0x9e84, 0xa20a, 0xa5e6, 0xaa1e, 0xaeb3, 0xb3aa, 0xb903, 0xbebe,
0xc4d9, 0xcb52, 0xd221, 0xd941, 0xe0a7, 0xe847, 0xf015, 0xf803,
};
const q15_t tanhLTable_q15[128] = {
0x0000, 0x0400, 0x07fd, 0x0bf7, 0x0feb, 0x13d7, 0x17b9, 0x1b90,
0x1f59, 0x2314, 0x26bf, 0x2a58, 0x2ddf, 0x3151, 0x34ae, 0x37f6,
0x3b27, 0x3e40, 0x4142, 0x442c, 0x46fd, 0x49b6, 0x4c56, 0x4edd,
0x514d, 0x53a3, 0x55e2, 0x580a, 0x5a1a, 0x5c13, 0x5df6, 0x5fc4,
0x617c, 0x6320, 0x64b0, 0x662d, 0x6797, 0x68f0, 0x6a37, 0x6b6e,
0x6c95, 0x6dac, 0x6eb5, 0x6fb0, 0x709e, 0x717f, 0x7254, 0x731e,
0x73dc, 0x7490, 0x753a, 0x75da, 0x7672, 0x7701, 0x7788, 0x7807,
0x787f, 0x78f0, 0x795b, 0x79bf, 0x7a1e, 0x7a77, 0x7acb, 0x7b1b,
0x849b, 0x84e5, 0x8535, 0x8589, 0x85e2, 0x8641, 0x86a5, 0x8710,
0x8781, 0x87f9, 0x8878, 0x88ff, 0x898e, 0x8a26, 0x8ac6, 0x8b70,
0x8c24, 0x8ce2, 0x8dac, 0x8e81, 0x8f62, 0x9050, 0x914b, 0x9254,
0x936b, 0x9492, 0x95c9, 0x9710, 0x9869, 0x99d3, 0x9b50, 0x9ce0,
0x9e84, 0xa03c, 0xa20a, 0xa3ed, 0xa5e6, 0xa7f6, 0xaa1e, 0xac5d,
0xaeb3, 0xb123, 0xb3aa, 0xb64a, 0xb903, 0xbbd4, 0xbebe, 0xc1c0,
0xc4d9, 0xc80a, 0xcb52, 0xceaf, 0xd221, 0xd5a8, 0xd941, 0xdcec,
0xe0a7, 0xe470, 0xe847, 0xec29, 0xf015, 0xf409, 0xf803, 0xfc00,
};
const q15_t tanhHTable_q15[192] = {
0x7b65, 0x7bee, 0x7c66, 0x7cd1, 0x7d30, 0x7d84, 0x7dce, 0x7e0f,
0x7e49, 0x7e7d, 0x7eaa, 0x7ed2, 0x7ef5, 0x7f14, 0x7f30, 0x7f48,
0x7f5e, 0x7f71, 0x7f82, 0x7f91, 0x7f9e, 0x7fa9, 0x7fb3, 0x7fbc,
0x7fc4, 0x7fcb, 0x7fd1, 0x7fd7, 0x7fdc, 0x7fe0, 0x7fe4, 0x7fe7,
0x7fea, 0x7fed, 0x7fef, 0x7ff1, 0x7ff3, 0x7ff4, 0x7ff6, 0x7ff7,
0x7ff8, 0x7ff9, 0x7ffa, 0x7ffa, 0x7ffb, 0x7ffc, 0x7ffc, 0x7ffd,
0x7ffd, 0x7ffd, 0x7ffe, 0x7ffe, 0x7ffe, 0x7ffe, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff, 0x7fff,
0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000,
0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000,
0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000,
0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000, 0x8000,
0x8000, 0x8000, 0x8001, 0x8001, 0x8001, 0x8001, 0x8001, 0x8001,
0x8001, 0x8001, 0x8001, 0x8002, 0x8002, 0x8002, 0x8002, 0x8003,
0x8003, 0x8003, 0x8004, 0x8004, 0x8005, 0x8006, 0x8006, 0x8007,
0x8008, 0x8009, 0x800a, 0x800c, 0x800d, 0x800f, 0x8011, 0x8013,
0x8016, 0x8019, 0x801c, 0x8020, 0x8024, 0x8029, 0x802f, 0x8035,
0x803c, 0x8044, 0x804d, 0x8057, 0x8062, 0x806f, 0x807e, 0x808f,
0x80a2, 0x80b8, 0x80d0, 0x80ec, 0x810b, 0x812e, 0x8156, 0x8183,
0x81b7, 0x81f1, 0x8232, 0x827c, 0x82d0, 0x832f, 0x839a, 0x8412,
};

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_q7_to_q15_no_shift.c
* Description: Converts the elements of the Q7 vector to Q15 vector without left-shift
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_nnsupportfunctions.h"
/**
* @ingroup groupSupport
*/
/**
* @addtogroup nndata_convert
* @{
*/
/**
* @brief Converts the elements of the Q7 vector to Q15 vector without left-shift
* @param[in] *pSrc points to the Q7 input vector
* @param[out] *pDst points to the Q15 output vector
* @param[in] blockSize length of the input vector
* @return none.
*
* \par Description:
*
* The equation used for the conversion process is:
*
* <pre>
* pDst[n] = (q15_t) pSrc[n]; 0 <= n < blockSize.
* </pre>
*
*/
void arm_q7_to_q15_no_shift(const q7_t * pSrc, q15_t * pDst, uint32_t blockSize)
{
const q7_t *pIn = pSrc; /* Src pointer */
uint32_t blkCnt; /* loop counter */
#ifndef ARM_MATH_CM0_FAMILY
q31_t in;
q31_t in1, in2;
q31_t out1, out2;
/* Run the below code for Cortex-M4 and Cortex-M3 */
/*loop Unrolling */
blkCnt = blockSize >> 2u;
/* First part of the processing with loop unrolling. Compute 4 outputs at a time.
** a second loop below computes the remaining 1 to 3 samples. */
while (blkCnt > 0u)
{
/* C = (q15_t) A << 8 */
/* convert from q7 to q15 and then store the results in the destination buffer */
in = *__SIMD32(pIn)++;
/* rotatate in by 8 and extend two q7_t values to q15_t values */
in1 = __SXTB16(__ROR(in, 8));
/* extend remainig two q7_t values to q15_t values */
in2 = __SXTB16(in);
#ifndef ARM_MATH_BIG_ENDIAN
out2 = __PKHTB(in1, in2, 16);
out1 = __PKHBT(in2, in1, 16);
#else
out1 = __PKHTB(in1, in2, 16);
out2 = __PKHBT(in2, in1, 16);
#endif
*__SIMD32(pDst)++ = out1;
*__SIMD32(pDst)++ = out2;
/* Decrement the loop counter */
blkCnt--;
}
/* If the blockSize is not a multiple of 4, compute any remaining output samples here.
** No loop unrolling is used. */
blkCnt = blockSize % 0x4u;
#else
/* Run the below code for Cortex-M0 */
/* Loop over blockSize number of values */
blkCnt = blockSize;
#endif /* #ifndef ARM_MATH_CM0_FAMILY */
while (blkCnt > 0u)
{
/* C = (q15_t) A << 8 */
/* convert from q7 to q15 and then store the results in the destination buffer */
*pDst++ = (q15_t) * pIn++;
/* Decrement the loop counter */
blkCnt--;
}
}
/**
* @} end of nndata_convert group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_q7_to_q15_reordered_no_shift.c
* Description: Converts the elements of the Q7 vector to reordered Q15 vector without left-shift
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_nnsupportfunctions.h"
/**
* @ingroup groupSupport
*/
/**
* @addtogroup nndata_convert
* @{
*/
/**
* @brief Converts the elements of the Q7 vector to reordered Q15 vector without left-shift
* @param[in] *pSrc points to the Q7 input vector
* @param[out] *pDst points to the Q15 output vector
* @param[in] blockSize length of the input vector
* @return none.
*
* @details
*
* This function does the q7 to q15 expansion with re-ordering
*
* <pre>
* | A1 | A2 | A3 | A4 |
*
* 0 7 8 15 16 23 24 31
* </pre>
*
* is converted into:
*
* <pre>
* | A1 | A3 | and | A2 | A4 |
*
* 0 15 16 31 0 15 16 31
* </pre>
*
*
* This looks strange but is natural considering how sign-extension is done at
* assembly level.
*
* The expansion of other other oprand will follow the same rule so that the end
* results are the same.
*
* The tail (i.e., last (N % 4) elements) will still be in original order.
*
*/
void arm_q7_to_q15_reordered_no_shift(const q7_t * pSrc, q15_t * pDst, uint32_t blockSize)
{
const q7_t *pIn = pSrc; /* Src pointer */
uint32_t blkCnt; /* loop counter */
#ifndef ARM_MATH_CM0_FAMILY
q31_t in;
q31_t in1, in2;
/* Run the below code for Cortex-M4 and Cortex-M3 */
/*loop Unrolling */
blkCnt = blockSize >> 2u;
/* First part of the processing with loop unrolling. Compute 4 outputs at a time.
** a second loop below computes the remaining 1 to 3 samples. */
while (blkCnt > 0u)
{
/* C = (q15_t) A << 8 */
/* convert from q7 to q15 and then store the results in the destination buffer */
in = *__SIMD32(pIn)++;
/* rotatate in by 8 and extend two q7_t values to q15_t values */
in1 = __SXTB16(__ROR(in, 8));
/* extend remainig two q7_t values to q15_t values */
in2 = __SXTB16(in);
#ifndef ARM_MATH_BIG_ENDIAN
*__SIMD32(pDst)++ = in2;
*__SIMD32(pDst)++ = in1;
#else
*__SIMD32(pDst)++ = in1;
*__SIMD32(pDst)++ = in2;
#endif
/* Decrement the loop counter */
blkCnt--;
}
/* If the blockSize is not a multiple of 4, compute any remaining output samples here.
** No loop unrolling is used. */
blkCnt = blockSize % 0x4u;
#else
/* Run the below code for Cortex-M0 */
/* Loop over blockSize number of values */
blkCnt = blockSize;
#endif /* #ifndef ARM_MATH_CM0_FAMILY */
while (blkCnt > 0u)
{
/* C = (q15_t) A << 8 */
/* convert from q7 to q15 and then store the results in the destination buffer */
*pDst++ = (q15_t) * pIn++;
/* Decrement the loop counter */
blkCnt--;
}
}
/**
* @} end of q7_to_x group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_pool_q7_HWC.c
* Description: Pooling function implementations
*
* $Date: 17. January 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
#if defined (ARM_MATH_DSP)
/**
* @brief A few utility functions used by pooling functions
*
*
*/
static void buffer_scale_back_q15_to_q7(q15_t * buffer, q7_t * target, uint16_t length, uint16_t scale)
{
int i;
for (i = 0; i < length; i++)
{
target[i] = (q7_t) (buffer[i] / scale);
}
}
static void compare_and_replace_if_larger_q7(q7_t * base, // base data
const q7_t * target, // compare target
const uint16_t length // data length
)
{
q7_t *pIn = base;
const q7_t *pCom = target;
union arm_nnword in;
union arm_nnword com;
uint16_t cnt = length >> 2;
while (cnt > 0u)
{
in.word = *__SIMD32(pIn);
com.word = *__SIMD32(pCom)++;
// if version
if (com.bytes[0] > in.bytes[0])
in.bytes[0] = com.bytes[0];
if (com.bytes[1] > in.bytes[1])
in.bytes[1] = com.bytes[1];
if (com.bytes[2] > in.bytes[2])
in.bytes[2] = com.bytes[2];
if (com.bytes[3] > in.bytes[3])
in.bytes[3] = com.bytes[3];
*__SIMD32(pIn)++ = in.word;
cnt--;
}
cnt = length & 0x3;
while (cnt > 0u)
{
if (*pCom > *pIn)
{
*pIn = *pCom;
}
pIn++;
pCom++;
cnt--;
}
}
static void accumulate_q7_to_q15(q15_t * base, q7_t * target, const uint16_t length)
{
q15_t *pCnt = base;
q7_t *pV = target;
q31_t v1, v2, vo1, vo2;
uint16_t cnt = length >> 2;
q31_t in;
while (cnt > 0u)
{
q31_t value = *__SIMD32(pV)++;
v1 = __SXTB16(__ROR(value, 8));
v2 = __SXTB16(value);
#ifndef ARM_MATH_BIG_ENDIAN
vo2 = __PKHTB(v1, v2, 16);
vo1 = __PKHBT(v2, v1, 16);
#else
vo1 = __PKHTB(v1, v2, 16);
vo2 = __PKHBT(v2, v1, 16);
#endif
in = *__SIMD32(pCnt);
*__SIMD32(pCnt)++ = __QADD16(vo1, in);
in = *__SIMD32(pCnt);
*__SIMD32(pCnt)++ = __QADD16(vo2, in);
cnt--;
}
cnt = length & 0x3;
while (cnt > 0u)
{
*pCnt++ += *pV++;
cnt--;
}
}
#endif // ARM_MATH_DSP
/**
* @ingroup groupNN
*/
/**
* @addtogroup Pooling
* @{
*/
/**
* @brief Q7 max pooling function
* @param[in, out] Im_in pointer to input tensor
* @param[in] dim_im_in input tensor dimention
* @param[in] ch_im_in number of input tensor channels
* @param[in] dim_kernel filter kernel size
* @param[in] padding padding sizes
* @param[in] stride convolution stride
* @param[in] dim_im_out output tensor dimension
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] Im_out pointer to output tensor
* @return none.
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: 0
*
* The pooling function is implemented as split x-pooling then
* y-pooling.
*
* This pooling function is input-destructive. Input data is undefined
* after calling this function.
*
*/
void
arm_maxpool_q7_HWC(q7_t * Im_in,
const uint16_t dim_im_in,
const uint16_t ch_im_in,
const uint16_t dim_kernel,
const uint16_t padding,
const uint16_t stride, const uint16_t dim_im_out, q7_t * bufferA, q7_t * Im_out)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
int16_t i_x, i_y;
/* first does the pooling along x axis */
for (i_y = 0; i_y < dim_im_in; i_y++)
{
for (i_x = 0; i_x < dim_im_out; i_x++)
{
/* for each output pixel */
q7_t *target = Im_in + (i_y * dim_im_in + i_x) * ch_im_in;
q7_t *win_start;
q7_t *win_stop;
if (i_x * stride - padding < 0)
{
win_start = target;
} else
{
win_start = Im_in + (i_y * dim_im_in + i_x * stride - padding) * ch_im_in;
}
if (i_x * stride - padding + dim_kernel >= dim_im_in)
{
win_stop = Im_in + (i_y * dim_im_in + dim_im_in) * ch_im_in;
} else
{
win_stop = Im_in + (i_y * dim_im_in + i_x * stride - padding + dim_kernel) * ch_im_in;
}
/* first step is to copy over initial data */
/* arm_copy_q7(win_start, target, ch_im_in); */
memmove(target, win_start, ch_im_in);
/* start the max operation from the second part */
win_start += ch_im_in;
for (; win_start < win_stop; win_start += ch_im_in)
{
compare_and_replace_if_larger_q7(target, win_start, ch_im_in);
}
}
}
/* then does the pooling along y axis */
for (i_y = 0; i_y < dim_im_out; i_y++)
{
/* for each output row */
q7_t *target = Im_out + i_y * dim_im_out * ch_im_in;
q7_t *row_start;
q7_t *row_end;
/* setting the starting row */
if (i_y * stride - padding < 0)
{
row_start = Im_in;
} else
{
row_start = Im_in + (i_y * stride - padding) * dim_im_in * ch_im_in;
}
/* setting the stopping row */
if (i_y * stride - padding + dim_kernel >= dim_im_in)
{
row_end = Im_in + dim_im_in * dim_im_in * ch_im_in;
} else
{
row_end = Im_in + (i_y * stride - padding + dim_kernel) * dim_im_in * ch_im_in;
}
/* copy over the first row */
/* arm_copy_q7(row_start, target, dim_im_out * ch_im_in); */
memmove(target, row_start, dim_im_out * ch_im_in);
/* move over to next row */
row_start += ch_im_in * dim_im_in;
for (; row_start < row_end; row_start += dim_im_in * ch_im_in)
{
compare_and_replace_if_larger_q7(target, row_start, dim_im_out * ch_im_in);
}
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
int16_t i_ch_in, i_x, i_y;
int16_t k_x, k_y;
for (i_ch_in = 0; i_ch_in < ch_im_in; i_ch_in++)
{
for (i_y = 0; i_y < dim_im_out; i_y++)
{
for (i_x = 0; i_x < dim_im_out; i_x++)
{
int max = -129;
for (k_y = i_y * stride - padding; k_y < i_y * stride - padding + dim_kernel; k_y++)
{
for (k_x = i_x * stride - padding; k_x < i_x * stride - padding + dim_kernel; k_x++)
{
if (k_y >= 0 && k_x >= 0 && k_y < dim_im_in && k_x < dim_im_in)
{
if (Im_in[i_ch_in + ch_im_in * (k_x + k_y * dim_im_in)] > max)
{
max = Im_in[i_ch_in + ch_im_in * (k_x + k_y * dim_im_in)];
}
}
}
}
Im_out[i_ch_in + ch_im_in * (i_x + i_y * dim_im_out)] = max;
}
}
}
#endif /* ARM_MATH_DSP */
}
/**
* @brief Q7 average pooling function
* @param[in,out] Im_in pointer to input tensor
* @param[in] dim_im_in input tensor dimention
* @param[in] ch_im_in number of input tensor channels
* @param[in] dim_kernel filter kernel size
* @param[in] padding padding sizes
* @param[in] stride convolution stride
* @param[in] dim_im_out output tensor dimension
* @param[in,out] bufferA pointer to buffer space for input
* @param[in,out] Im_out pointer to output tensor
* @return none.
*
* @details
*
* <b>Buffer size:</b>
*
* bufferA size: 2*dim_im_out*ch_im_in
*
* The pooling function is implemented as split x-pooling then
* y-pooling.
*
* This pooling function is input-destructive. Input data is undefined
* after calling this function.
*
*/
void
arm_avepool_q7_HWC(q7_t * Im_in,
const uint16_t dim_im_in,
const uint16_t ch_im_in,
const uint16_t dim_kernel,
const uint16_t padding,
const uint16_t stride, const uint16_t dim_im_out, q7_t * bufferA, q7_t * Im_out)
{
#if defined (ARM_MATH_DSP)
/* Run the following code for Cortex-M4 and Cortex-M7 */
q15_t *buffer = (q15_t *) bufferA;
int16_t i_x, i_y;
int16_t count = 0;
/* first does the pooling along x axis */
for (i_y = 0; i_y < dim_im_in; i_y++)
{
for (i_x = 0; i_x < dim_im_out; i_x++)
{
/* for each output pixel */
q7_t *target = Im_in + (i_y * dim_im_in + i_x) * ch_im_in;
q7_t *win_start;
q7_t *win_stop;
if (i_x * stride - padding < 0)
{
win_start = target;
} else
{
win_start = Im_in + (i_y * dim_im_in + i_x * stride - padding) * ch_im_in;
}
if (i_x * stride - padding + dim_kernel >= dim_im_in)
{
win_stop = Im_in + (i_y * dim_im_in + dim_im_in) * ch_im_in;
} else
{
win_stop = Im_in + (i_y * dim_im_in + i_x * stride - padding + dim_kernel) * ch_im_in;
}
/* first step is to copy over initial data */
arm_q7_to_q15_no_shift(win_start, buffer, ch_im_in);
count = 1;
/* start the max operation from the second part */
win_start += ch_im_in;
for (; win_start < win_stop; win_start += ch_im_in)
{
accumulate_q7_to_q15(buffer, win_start, ch_im_in);
count++;
}
buffer_scale_back_q15_to_q7(buffer, target, ch_im_in, count);
}
}
/* then does the pooling along y axis */
for (i_y = 0; i_y < dim_im_out; i_y++)
{
/* for each output row */
q7_t *target = Im_out + i_y * dim_im_out * ch_im_in;
q7_t *row_start;
q7_t *row_end;
/* setting the starting row */
if (i_y * stride - padding < 0)
{
row_start = Im_in;
} else
{
row_start = Im_in + (i_y * stride - padding) * dim_im_in * ch_im_in;
}
/* setting the stopping row */
if (i_y * stride - padding + dim_kernel >= dim_im_in)
{
row_end = Im_in + dim_im_in * dim_im_in * ch_im_in;
} else
{
row_end = Im_in + (i_y * stride - padding + dim_kernel) * dim_im_in * ch_im_in;
}
/* copy over the first row */
arm_q7_to_q15_no_shift(row_start, buffer, dim_im_out * ch_im_in);
count = 1;
/* move over to next row */
row_start += ch_im_in * dim_im_in;
for (; row_start < row_end; row_start += dim_im_in * ch_im_in)
{
accumulate_q7_to_q15(buffer, row_start, dim_im_out * ch_im_in);
count++;
}
buffer_scale_back_q15_to_q7(buffer, target, dim_im_out * ch_im_in, count);
}
#else
/* Run the following code as reference implementation for Cortex-M0 and Cortex-M3 */
int16_t i_ch_in, i_x, i_y;
int16_t k_x, k_y;
for (i_ch_in = 0; i_ch_in < ch_im_in; i_ch_in++)
{
for (i_y = 0; i_y < dim_im_out; i_y++)
{
for (i_x = 0; i_x < dim_im_out; i_x++)
{
int sum = 0;
int count = 0;
for (k_y = i_y * stride - padding; k_y < i_y * stride - padding + dim_kernel; k_y++)
{
for (k_x = i_x * stride - padding; k_x < i_x * stride - padding + dim_kernel; k_x++)
{
if (k_y >= 0 && k_x >= 0 && k_y < dim_im_in && k_x < dim_im_in)
{
sum += Im_in[i_ch_in + ch_im_in * (k_x + k_y * dim_im_in)];
count++;
}
}
}
Im_out[i_ch_in + ch_im_in * (i_x + i_y * dim_im_out)] = sum / count;
}
}
}
#endif /* ARM_MATH_DSP */
}
/**
* @} end of Pooling group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_softmax_q15.c
* Description: Q15 softmax function
*
* $Date: 20. February 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup Softmax
* @{
*/
/**
* @brief Q15 softmax function
* @param[in] vec_in pointer to input vector
* @param[in] dim_vec input vector dimention
* @param[out] p_out pointer to output vector
* @return none.
*
* @details
*
* Here, instead of typical e based softmax, we use
* 2-based softmax, i.e.,:
*
* y_i = 2^(x_i) / sum(2^x_j)
*
* The relative output will be different here.
* But mathematically, the gradient will be the same
* with a log(2) scaling factor.
*
*/
void arm_softmax_q15(const q15_t * vec_in, const uint16_t dim_vec, q15_t * p_out)
{
q31_t sum;
int16_t i;
uint8_t shift;
q31_t base;
base = -1 * 0x100000;
for (i = 0; i < dim_vec; i++)
{
if (vec_in[i] > base)
{
base = vec_in[i];
}
}
/* we ignore really small values
* anyway, they will be 0 after shrinking
* to q15_t
*/
base = base - 16;
sum = 0;
for (i = 0; i < dim_vec; i++)
{
if (vec_in[i] > base)
{
shift = (uint8_t)__USAT(vec_in[i] - base, 5);
sum += 0x1 << shift;
}
}
/* This is effectively (0x1 << 32) / sum */
int64_t div_base = 0x100000000LL;
int output_base = (int32_t)(div_base / sum);
/* Final confidence will be output_base >> ( 17 - (vec_in[i] - base) )
* so 32768 (0x1<<15) -> 100% confidence when sum = 0x1 << 16, output_base = 0x1 << 16
* and vec_in[i]-base = 16
*/
for (i = 0; i < dim_vec; i++)
{
if (vec_in[i] > base)
{
/* Here minimum value of 17+base-vec[i] will be 1 */
shift = (uint8_t)__USAT(17+base-vec_in[i], 5);
p_out[i] = (q15_t) __SSAT((output_base >> shift), 16);
} else
{
p_out[i] = 0;
}
}
}
/**
* @} end of Softmax group
*/

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/*
* Copyright (C) 2010-2018 Arm Limited or its affiliates. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* ----------------------------------------------------------------------
* Project: CMSIS NN Library
* Title: arm_softmax_q7.c
* Description: Q7 softmax function
*
* $Date: 20. February 2018
* $Revision: V.1.0.0
*
* Target Processor: Cortex-M cores
*
* -------------------------------------------------------------------- */
#include "arm_math.h"
#include "arm_nnfunctions.h"
/**
* @ingroup groupNN
*/
/**
* @addtogroup Softmax
* @{
*/
/**
* @brief Q7 softmax function
* @param[in] vec_in pointer to input vector
* @param[in] dim_vec input vector dimention
* @param[out] p_out pointer to output vector
* @return none.
*
* @details
*
* Here, instead of typical natural logarithm e based softmax, we use
* 2-based softmax here, i.e.,:
*
* y_i = 2^(x_i) / sum(2^x_j)
*
* The relative output will be different here.
* But mathematically, the gradient will be the same
* with a log(2) scaling factor.
*
*/
void arm_softmax_q7(const q7_t * vec_in, const uint16_t dim_vec, q7_t * p_out)
{
q31_t sum;
int16_t i;
uint8_t shift;
q15_t base;
base = -257;
/* We first search for the maximum */
for (i = 0; i < dim_vec; i++)
{
if (vec_in[i] > base)
{
base = vec_in[i];
}
}
/*
* So the base is set to max-8, meaning
* that we ignore really small values.
* anyway, they will be 0 after shrinking to q7_t.
*/
base = base - 8;
sum = 0;
for (i = 0; i < dim_vec; i++)
{
if (vec_in[i] > base)
{
shift = (uint8_t)__USAT(vec_in[i] - base, 5);
sum += 0x1 << shift;
}
}
/* This is effectively (0x1 << 20) / sum */
int output_base = 0x100000 / sum;
/*
* Final confidence will be output_base >> ( 13 - (vec_in[i] - base) )
* so 128 (0x1<<7) -> 100% confidence when sum = 0x1 << 8, output_base = 0x1 << 12
* and vec_in[i]-base = 8
*/
for (i = 0; i < dim_vec; i++)
{
if (vec_in[i] > base)
{
/* Here minimum value of 13+base-vec_in[i] will be 5 */
shift = (uint8_t)__USAT(13+base-vec_in[i], 5);
p_out[i] = (q7_t) __SSAT((output_base >> shift), 8);
} else {
p_out[i] = 0;
}
}
}
/**
* @} end of Softmax group
*/