src/clamp-nc.c - platform/external/XNNPACK - Git at Google

 // Copyright (c) Facebook, Inc. and its affiliates.
 // All rights reserved.
 //
 // Copyright 2019 Google LLC
 //
 // This source code is licensed under the BSD-style license found in the
 // LICENSE file in the root directory of this source tree.

 #include <math.h>
 #include <stddef.h>
 #include <stdint.h>
 #include <stdlib.h>

 #include <xnnpack.h>
 #include <xnnpack/allocator.h>
 #include <xnnpack/log.h>
 #include <xnnpack/operator.h>
 #include <xnnpack/params-init.h>
 #include <xnnpack/params.h>


 enum xnn_status xnn_create_clamp_nc_u8(
     size_t channels,
     size_t input_stride,
     size_t output_stride,
     uint8_t output_min,
     uint8_t output_max,
     uint32_t flags,
     xnn_operator_t* clamp_op_out)
 {
   xnn_operator_t clamp_op = NULL;
   enum xnn_status status = xnn_status_uninitialized;

   if (!xnn_params.initialized) {
     xnn_log_error("failed to create Clamp operator: XNNPACK is not initialized");
     goto error;
   }

   status = xnn_status_invalid_parameter;

   if (channels == 0) {
     xnn_log_error(
       "failed to create Clamp operator with %zu channels: number of channels must be non-zero", channels);
     goto error;
   }

   if (input_stride < channels) {
     xnn_log_error(
       "failed to create Clamp operator with input element stride of %zu: "
       "stride must be at least as large as the number of channels (%zu)",
       input_stride, channels);
     goto error;
   }

   if (output_stride < channels) {
     xnn_log_error(
       "failed to create Clamp operator with output element stride of %zu: "
       "stride must be at least as large as the number of channels (%zu)",
       output_stride, channels);
     goto error;
   }

   if (output_min >= output_max) {
     xnn_log_error(
       "failed to create Clamp operator with [%" PRIu8 ", %" PRIu8 "] output range: range min must be below range max",
       output_min, output_max);
     goto error;
   }

   status = xnn_status_out_of_memory;

   clamp_op = xnn_allocate_zero_simd_memory(sizeof(struct xnn_operator));
   if (clamp_op == NULL) {
     xnn_log_error("failed to allocate %zu bytes for Clamp operator descriptor", sizeof(struct xnn_operator));
     goto error;
   }

   clamp_op->channels = channels;
   clamp_op->input_pixel_stride = input_stride;
   clamp_op->output_pixel_stride = output_stride;
   clamp_op->u8_output_params = xnn_init_u8_output_params(output_min, output_max);

   clamp_op->type = xnn_operator_type_clamp_nc_u8;
   clamp_op->ukernel.type = xnn_ukernel_type_clamp;

   clamp_op->state = xnn_run_state_invalid;

   *clamp_op_out = clamp_op;
   return xnn_status_success;

 error:
   xnn_delete_operator(clamp_op);
   return status;
 }

 enum xnn_status xnn_create_clamp_nc_f32(
     size_t channels,
     size_t input_stride,
     size_t output_stride,
     float output_min,
     float output_max,
     uint32_t flags,
     xnn_operator_t* clamp_op_out)
 {
   xnn_operator_t clamp_op = NULL;
   enum xnn_status status = xnn_status_uninitialized;

   if (!xnn_params.initialized) {
     xnn_log_error("failed to create Clamp operator: XNNPACK is not initialized");
     goto error;
   }

   status = xnn_status_invalid_parameter;

   if (channels == 0) {
     xnn_log_error(
       "failed to create Clamp operator with %zu channels: number of channels must be non-zero", channels);
     goto error;
   }

   if (input_stride < channels) {
     xnn_log_error(
       "failed to create Clamp operator with input element stride of %zu: "
       "stride must be at least as large as the number of channels (%zu)",
       input_stride, channels);
     goto error;
   }

   if (output_stride < channels) {
     xnn_log_error(
       "failed to create Clamp operator with output element stride of %zu: "
       "stride must be at least as large as the number of channels (%zu)",
       output_stride, channels);
     goto error;
   }

   if (isnan(output_min)) {
     xnn_log_error(
       "failed to create Clamp operator with NaN output lower bound: lower bound must be non-NaN");
     goto error;
   }

   if (isnan(output_max)) {
     xnn_log_error(
       "failed to create Clamp operator with NaN output upper bound: upper bound must be non-NaN");
     goto error;
   }

   if (output_min >= output_max) {
     xnn_log_error(
       "failed to create Clamp operator with [%.7g, %.7g] output range: lower bound must be below upper bound",
       output_min, output_max);
     goto error;
   }

   status = xnn_status_out_of_memory;

   clamp_op = xnn_allocate_zero_simd_memory(sizeof(struct xnn_operator));
   if (clamp_op == NULL) {
     xnn_log_error("failed to allocate %zu bytes for Clamp operator descriptor", sizeof(struct xnn_operator));
     goto error;
   }

   clamp_op->channels = channels;
   clamp_op->input_pixel_stride = input_stride;
   clamp_op->output_pixel_stride = output_stride;
   clamp_op->f32_output_params = xnn_init_f32_output_params(output_min, output_max);

   clamp_op->type = xnn_operator_type_clamp_nc_f32;
   clamp_op->ukernel.type = xnn_ukernel_type_clamp;

   clamp_op->state = xnn_run_state_invalid;

   *clamp_op_out = clamp_op;
   return xnn_status_success;

 error:
   xnn_delete_operator(clamp_op);
   return status;
 }

 enum xnn_status xnn_setup_clamp_nc_u8(
     xnn_operator_t clamp_op,
     size_t batch_size,
     const uint8_t* input,
     uint8_t* output,
     pthreadpool_t threadpool)
 {
   if (clamp_op->type != xnn_operator_type_clamp_nc_u8) {
     xnn_log_error("failed to setup Clamp (NC, U8) operator: operator type mismatch");
     return xnn_status_invalid_parameter;
   }
   clamp_op->state = xnn_run_state_invalid;

   if (!xnn_params.initialized) {
     xnn_log_error("failed to setup Clamp operator: XNNPACK is not initialized");
     return xnn_status_uninitialized;
   }

   if (batch_size == 0) {
     clamp_op->state = xnn_run_state_skip;
     return xnn_status_success;
   }

   const size_t channels = clamp_op->channels;
   const size_t input_stride = clamp_op->input_pixel_stride;
   const size_t output_stride = clamp_op->output_pixel_stride;
   if ((((input_stride ^ channels) | (output_stride ^ channels)) == 0) || batch_size == 1) {
     const size_t block_size = 4096;
     clamp_op->context.univector_contiguous = (struct univector_contiguous_context) {
       .x = input,
       .x_stride = input_stride * sizeof(uint8_t),
       .y = output,
       .y_stride = output_stride * sizeof(uint8_t),
       .ukernel = xnn_params.u8.clamp,
       .params.u8_output = clamp_op->u8_output_params,
     };
     clamp_op->compute.type = xnn_parallelization_type_1d_tile_1d;
     clamp_op->compute.task_1d_tile_1d = (pthreadpool_task_1d_tile_1d_t) xnn_compute_univector_contiguous;
     clamp_op->compute.range[0] = batch_size * channels * sizeof(uint8_t);
     clamp_op->compute.tile[0] = block_size;
   } else {
     clamp_op->context.univector_strided = (struct univector_strided_context) {
       .n = channels * sizeof(uint8_t),
       .x = input,
       .x_stride = input_stride * sizeof(uint8_t),
       .y = output,
       .y_stride = output_stride * sizeof(uint8_t),
       .ukernel = xnn_params.u8.clamp,
       .params.u8_output = clamp_op->u8_output_params,
     };
     clamp_op->compute.type = xnn_parallelization_type_1d_tile_1d;
     clamp_op->compute.task_1d_tile_1d = (pthreadpool_task_1d_tile_1d_t) xnn_compute_univector_strided;
     clamp_op->compute.range[0] = batch_size;
     clamp_op->compute.tile[0] = 1;
   }
   clamp_op->state = xnn_run_state_ready;

   return xnn_status_success;
 }

 enum xnn_status xnn_setup_clamp_nc_f32(
     xnn_operator_t clamp_op,
     size_t batch_size,
     const float* input,
     float* output,
     pthreadpool_t threadpool)
 {
   if (clamp_op->type != xnn_operator_type_clamp_nc_f32) {
     xnn_log_error("failed to setup Clamp (NC, F32) operator: operator type mismatch");
     return xnn_status_invalid_parameter;
   }
   clamp_op->state = xnn_run_state_invalid;

   if (!xnn_params.initialized) {
     xnn_log_error("failed to setup Clamp operator: XNNPACK is not initialized");
     return xnn_status_uninitialized;
   }

   if (batch_size == 0) {
     clamp_op->state = xnn_run_state_skip;
     return xnn_status_success;
   }

   const size_t channels = clamp_op->channels;
   const size_t input_stride = clamp_op->input_pixel_stride;
   const size_t output_stride = clamp_op->output_pixel_stride;
   if ((((input_stride ^ channels) | (output_stride ^ channels)) == 0) || batch_size == 1) {
     const size_t block_size = 4096;
     clamp_op->context.univector_contiguous = (struct univector_contiguous_context) {
       .x = input,
       .x_stride = input_stride * sizeof(float),
       .y = output,
       .y_stride = output_stride * sizeof(float),
       .ukernel = xnn_params.f32.clamp,
       .params.f32_output = clamp_op->f32_output_params,
     };
     clamp_op->compute.type = xnn_parallelization_type_1d_tile_1d;
     clamp_op->compute.task_1d_tile_1d = (pthreadpool_task_1d_tile_1d_t) xnn_compute_univector_contiguous;
     clamp_op->compute.range[0] = batch_size * channels * sizeof(float);
     clamp_op->compute.tile[0] = block_size;
   } else {
     clamp_op->context.univector_strided = (struct univector_strided_context) {
       .n = channels * sizeof(float),
       .x = input,
       .x_stride = input_stride * sizeof(float),
       .y = output,
       .y_stride = output_stride * sizeof(float),
       .ukernel = xnn_params.f32.clamp,
       .params.f32_output = clamp_op->f32_output_params,
     };
     clamp_op->compute.type = xnn_parallelization_type_1d_tile_1d;
     clamp_op->compute.task_1d_tile_1d = (pthreadpool_task_1d_tile_1d_t) xnn_compute_univector_strided;
     clamp_op->compute.range[0] = batch_size;
     clamp_op->compute.tile[0] = 1;
   }
   clamp_op->state = xnn_run_state_ready;

   return xnn_status_success;
 }
	// Copyright (c) Facebook, Inc. and its affiliates.
	// All rights reserved.
	//
	// Copyright 2019 Google LLC
	//
	// This source code is licensed under the BSD-style license found in the
	// LICENSE file in the root directory of this source tree.

	#include <math.h>
	#include <stddef.h>
	#include <stdint.h>
	#include <stdlib.h>

	#include <xnnpack.h>
	#include <xnnpack/allocator.h>
	#include <xnnpack/log.h>
	#include <xnnpack/operator.h>
	#include <xnnpack/params-init.h>
	#include <xnnpack/params.h>


	enum xnn_status xnn_create_clamp_nc_u8(
	size_t channels,
	size_t input_stride,
	size_t output_stride,
	uint8_t output_min,
	uint8_t output_max,
	uint32_t flags,
	xnn_operator_t* clamp_op_out)
	{
	xnn_operator_t clamp_op = NULL;
	enum xnn_status status = xnn_status_uninitialized;

	if (!xnn_params.initialized) {
	xnn_log_error("failed to create Clamp operator: XNNPACK is not initialized");
	goto error;
	}

	status = xnn_status_invalid_parameter;

	if (channels == 0) {
	xnn_log_error(
	"failed to create Clamp operator with %zu channels: number of channels must be non-zero", channels);
	goto error;
	}

	if (input_stride < channels) {
	xnn_log_error(
	"failed to create Clamp operator with input element stride of %zu: "
	"stride must be at least as large as the number of channels (%zu)",
	input_stride, channels);
	goto error;
	}

	if (output_stride < channels) {
	xnn_log_error(
	"failed to create Clamp operator with output element stride of %zu: "
	"stride must be at least as large as the number of channels (%zu)",
	output_stride, channels);
	goto error;
	}

	if (output_min >= output_max) {
	xnn_log_error(
	"failed to create Clamp operator with [%" PRIu8 ", %" PRIu8 "] output range: range min must be below range max",
	output_min, output_max);
	goto error;
	}

	status = xnn_status_out_of_memory;

	clamp_op = xnn_allocate_zero_simd_memory(sizeof(struct xnn_operator));
	if (clamp_op == NULL) {
	xnn_log_error("failed to allocate %zu bytes for Clamp operator descriptor", sizeof(struct xnn_operator));
	goto error;
	}

	clamp_op->channels = channels;
	clamp_op->input_pixel_stride = input_stride;
	clamp_op->output_pixel_stride = output_stride;
	clamp_op->u8_output_params = xnn_init_u8_output_params(output_min, output_max);

	clamp_op->type = xnn_operator_type_clamp_nc_u8;
	clamp_op->ukernel.type = xnn_ukernel_type_clamp;

	clamp_op->state = xnn_run_state_invalid;

	*clamp_op_out = clamp_op;
	return xnn_status_success;

	error:
	xnn_delete_operator(clamp_op);
	return status;
	}

	enum xnn_status xnn_create_clamp_nc_f32(
	size_t channels,
	size_t input_stride,
	size_t output_stride,
	float output_min,
	float output_max,
	uint32_t flags,
	xnn_operator_t* clamp_op_out)
	{
	xnn_operator_t clamp_op = NULL;
	enum xnn_status status = xnn_status_uninitialized;

	if (!xnn_params.initialized) {
	xnn_log_error("failed to create Clamp operator: XNNPACK is not initialized");
	goto error;
	}

	status = xnn_status_invalid_parameter;

	if (channels == 0) {
	xnn_log_error(
	"failed to create Clamp operator with %zu channels: number of channels must be non-zero", channels);
	goto error;
	}

	if (input_stride < channels) {
	xnn_log_error(
	"failed to create Clamp operator with input element stride of %zu: "
	"stride must be at least as large as the number of channels (%zu)",
	input_stride, channels);
	goto error;
	}

	if (output_stride < channels) {
	xnn_log_error(
	"failed to create Clamp operator with output element stride of %zu: "
	"stride must be at least as large as the number of channels (%zu)",
	output_stride, channels);
	goto error;
	}

	if (isnan(output_min)) {
	xnn_log_error(
	"failed to create Clamp operator with NaN output lower bound: lower bound must be non-NaN");
	goto error;
	}

	if (isnan(output_max)) {
	xnn_log_error(
	"failed to create Clamp operator with NaN output upper bound: upper bound must be non-NaN");
	goto error;
	}

	if (output_min >= output_max) {
	xnn_log_error(
	"failed to create Clamp operator with [%.7g, %.7g] output range: lower bound must be below upper bound",
	output_min, output_max);
	goto error;
	}

	status = xnn_status_out_of_memory;

	clamp_op = xnn_allocate_zero_simd_memory(sizeof(struct xnn_operator));
	if (clamp_op == NULL) {
	xnn_log_error("failed to allocate %zu bytes for Clamp operator descriptor", sizeof(struct xnn_operator));
	goto error;
	}

	clamp_op->channels = channels;
	clamp_op->input_pixel_stride = input_stride;
	clamp_op->output_pixel_stride = output_stride;
	clamp_op->f32_output_params = xnn_init_f32_output_params(output_min, output_max);

	clamp_op->type = xnn_operator_type_clamp_nc_f32;
	clamp_op->ukernel.type = xnn_ukernel_type_clamp;

	clamp_op->state = xnn_run_state_invalid;

	*clamp_op_out = clamp_op;
	return xnn_status_success;

	error:
	xnn_delete_operator(clamp_op);
	return status;
	}

	enum xnn_status xnn_setup_clamp_nc_u8(
	xnn_operator_t clamp_op,
	size_t batch_size,
	const uint8_t* input,
	uint8_t* output,
	pthreadpool_t threadpool)
	{
	if (clamp_op->type != xnn_operator_type_clamp_nc_u8) {
	xnn_log_error("failed to setup Clamp (NC, U8) operator: operator type mismatch");
	return xnn_status_invalid_parameter;
	}
	clamp_op->state = xnn_run_state_invalid;

	if (!xnn_params.initialized) {
	xnn_log_error("failed to setup Clamp operator: XNNPACK is not initialized");
	return xnn_status_uninitialized;
	}

	if (batch_size == 0) {
	clamp_op->state = xnn_run_state_skip;
	return xnn_status_success;
	}

	const size_t channels = clamp_op->channels;
	const size_t input_stride = clamp_op->input_pixel_stride;
	const size_t output_stride = clamp_op->output_pixel_stride;
	if ((((input_stride ^ channels) \| (output_stride ^ channels)) == 0) \|\| batch_size == 1) {
	const size_t block_size = 4096;
	clamp_op->context.univector_contiguous = (struct univector_contiguous_context) {
	.x = input,
	.x_stride = input_stride * sizeof(uint8_t),
	.y = output,
	.y_stride = output_stride * sizeof(uint8_t),
	.ukernel = xnn_params.u8.clamp,
	.params.u8_output = clamp_op->u8_output_params,
	};
	clamp_op->compute.type = xnn_parallelization_type_1d_tile_1d;
	clamp_op->compute.task_1d_tile_1d = (pthreadpool_task_1d_tile_1d_t) xnn_compute_univector_contiguous;
	clamp_op->compute.range[0] = batch_size * channels * sizeof(uint8_t);
	clamp_op->compute.tile[0] = block_size;
	} else {
	clamp_op->context.univector_strided = (struct univector_strided_context) {
	.n = channels * sizeof(uint8_t),
	.x = input,
	.x_stride = input_stride * sizeof(uint8_t),
	.y = output,
	.y_stride = output_stride * sizeof(uint8_t),
	.ukernel = xnn_params.u8.clamp,
	.params.u8_output = clamp_op->u8_output_params,
	};
	clamp_op->compute.type = xnn_parallelization_type_1d_tile_1d;
	clamp_op->compute.task_1d_tile_1d = (pthreadpool_task_1d_tile_1d_t) xnn_compute_univector_strided;
	clamp_op->compute.range[0] = batch_size;
	clamp_op->compute.tile[0] = 1;
	}
	clamp_op->state = xnn_run_state_ready;

	return xnn_status_success;
	}

	enum xnn_status xnn_setup_clamp_nc_f32(
	xnn_operator_t clamp_op,
	size_t batch_size,
	const float* input,
	float* output,
	pthreadpool_t threadpool)
	{
	if (clamp_op->type != xnn_operator_type_clamp_nc_f32) {
	xnn_log_error("failed to setup Clamp (NC, F32) operator: operator type mismatch");
	return xnn_status_invalid_parameter;
	}
	clamp_op->state = xnn_run_state_invalid;

	if (!xnn_params.initialized) {
	xnn_log_error("failed to setup Clamp operator: XNNPACK is not initialized");
	return xnn_status_uninitialized;
	}

	if (batch_size == 0) {
	clamp_op->state = xnn_run_state_skip;
	return xnn_status_success;
	}

	const size_t channels = clamp_op->channels;
	const size_t input_stride = clamp_op->input_pixel_stride;
	const size_t output_stride = clamp_op->output_pixel_stride;
	if ((((input_stride ^ channels) \| (output_stride ^ channels)) == 0) \|\| batch_size == 1) {
	const size_t block_size = 4096;
	clamp_op->context.univector_contiguous = (struct univector_contiguous_context) {
	.x = input,
	.x_stride = input_stride * sizeof(float),
	.y = output,
	.y_stride = output_stride * sizeof(float),
	.ukernel = xnn_params.f32.clamp,
	.params.f32_output = clamp_op->f32_output_params,
	};
	clamp_op->compute.type = xnn_parallelization_type_1d_tile_1d;
	clamp_op->compute.task_1d_tile_1d = (pthreadpool_task_1d_tile_1d_t) xnn_compute_univector_contiguous;
	clamp_op->compute.range[0] = batch_size * channels * sizeof(float);
	clamp_op->compute.tile[0] = block_size;
	} else {
	clamp_op->context.univector_strided = (struct univector_strided_context) {
	.n = channels * sizeof(float),
	.x = input,
	.x_stride = input_stride * sizeof(float),
	.y = output,
	.y_stride = output_stride * sizeof(float),
	.ukernel = xnn_params.f32.clamp,
	.params.f32_output = clamp_op->f32_output_params,
	};
	clamp_op->compute.type = xnn_parallelization_type_1d_tile_1d;
	clamp_op->compute.task_1d_tile_1d = (pthreadpool_task_1d_tile_1d_t) xnn_compute_univector_strided;
	clamp_op->compute.range[0] = batch_size;
	clamp_op->compute.tile[0] = 1;
	}
	clamp_op->state = xnn_run_state_ready;

	return xnn_status_success;
	}