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android / platform / external / XNNPACK / f3e24a5b0 / . / src / subgraph / deconvolution-2d.c
blob: 84b495600c740acc287bfc2aea45d4e3c6f2ac7a [file] [log] [blame]
// Copyright 2020 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 <xnnpack.h>
#include <xnnpack/common.h>
#include <xnnpack/log.h>
#include <xnnpack/operator.h>
#include <xnnpack/params.h>
#include <xnnpack/subgraph.h>
static enum xnn_status create_deconvolution_operator(
const struct xnn_node* node,
const struct xnn_value* values,
size_t num_values,
struct xnn_operator_data* opdata,
struct xnn_code_cache* code_cache)
{
assert(node->num_inputs >= 2);
assert(node->num_inputs <= 3);
const bool use_bias = node->num_inputs >= 3;
const uint32_t input_id = node->inputs[0];
assert(input_id != XNN_INVALID_VALUE_ID);
assert(input_id < num_values);
const uint32_t filter_id = node->inputs[1];
assert(filter_id != XNN_INVALID_VALUE_ID);
assert(filter_id < num_values);
const void* bias_data = NULL;
if (use_bias) {
const uint32_t bias_id = node->inputs[2];
assert(bias_id != XNN_INVALID_VALUE_ID);
assert(bias_id < num_values);
bias_data = values[bias_id].data;
assert(bias_data != NULL);
}
assert(node->num_outputs == 1);
const uint32_t output_id = node->outputs[0];
assert(output_id != XNN_INVALID_VALUE_ID);
assert(output_id < num_values);
const void* filter_data = values[filter_id].data;
assert(filter_data != NULL);
enum xnn_status status = xnn_status_uninitialized;
switch (node->compute_type) {
#ifndef XNN_NO_F16_OPERATORS
case xnn_compute_type_fp16:
status = xnn_create_deconvolution2d_nhwc_f16(
node->params.deconvolution_2d.padding_top,
node->params.deconvolution_2d.padding_right,
node->params.deconvolution_2d.padding_bottom,
node->params.deconvolution_2d.padding_left,
node->params.deconvolution_2d.kernel_height,
node->params.deconvolution_2d.kernel_width,
node->params.deconvolution_2d.upsampling_height,
node->params.deconvolution_2d.upsampling_width,
node->params.deconvolution_2d.dilation_height,
node->params.deconvolution_2d.dilation_width,
node->params.deconvolution_2d.groups,
node->params.deconvolution_2d.group_input_channels,
node->params.deconvolution_2d.group_output_channels,
node->params.deconvolution_2d.group_input_channels * node->params.deconvolution_2d.groups /* input_pixel_stride */,
node->params.deconvolution_2d.group_output_channels * node->params.deconvolution_2d.groups /* output_pixel_stride */,
filter_data,
bias_data,
node->activation.output_min,
node->activation.output_max,
node->flags | XNN_FLAG_FP32_STATIC_WEIGHTS,
code_cache,
&opdata->operator_objects[0]);
break;
#endif // !defined(XNN_NO_F16_OPERATORS)
case xnn_compute_type_fp32:
status = xnn_create_deconvolution2d_nhwc_f32(
node->params.deconvolution_2d.padding_top,
node->params.deconvolution_2d.padding_right,
node->params.deconvolution_2d.padding_bottom,
node->params.deconvolution_2d.padding_left,
node->params.deconvolution_2d.kernel_height,
node->params.deconvolution_2d.kernel_width,
node->params.deconvolution_2d.upsampling_height,
node->params.deconvolution_2d.upsampling_width,
node->params.deconvolution_2d.dilation_height,
node->params.deconvolution_2d.dilation_width,
node->params.deconvolution_2d.groups,
node->params.deconvolution_2d.group_input_channels,
node->params.deconvolution_2d.group_output_channels,
node->params.deconvolution_2d.group_input_channels * node->params.deconvolution_2d.groups /* input_pixel_stride */,
node->params.deconvolution_2d.group_output_channels * node->params.deconvolution_2d.groups /* output_pixel_stride */,
filter_data,
bias_data,
node->activation.output_min,
node->activation.output_max,
node->flags,
code_cache,
&opdata->operator_objects[0]);
break;
#ifndef XNN_NO_QS8_OPERATORS
case xnn_compute_type_qs8:
{
const float output_scale = values[output_id].quantization.scale;
const int32_t output_zero_point = values[output_id].quantization.zero_point;
const int8_t output_min =
(int8_t) lrintf(fminf(fmaxf(node->activation.output_min / output_scale + (float) output_zero_point, -128.0f), 127.0f));
const int8_t output_max =
(int8_t) lrintf(fminf(fmaxf(node->activation.output_max / output_scale + (float) output_zero_point, -128.0f), 127.0f));
status = xnn_create_deconvolution2d_nhwc_qs8(
node->params.deconvolution_2d.padding_top,
node->params.deconvolution_2d.padding_right,
node->params.deconvolution_2d.padding_bottom,
node->params.deconvolution_2d.padding_left,
node->params.deconvolution_2d.kernel_height,
node->params.deconvolution_2d.kernel_width,
node->params.deconvolution_2d.upsampling_height,
node->params.deconvolution_2d.upsampling_width,
node->params.deconvolution_2d.dilation_height,
node->params.deconvolution_2d.dilation_width,
node->params.deconvolution_2d.groups,
node->params.deconvolution_2d.group_input_channels,
node->params.deconvolution_2d.group_output_channels,
node->params.deconvolution_2d.group_input_channels * node->params.deconvolution_2d.groups /* input_pixel_stride */,
node->params.deconvolution_2d.group_output_channels * node->params.deconvolution_2d.groups /* output_pixel_stride */,
(int8_t) values[input_id].quantization.zero_point,
values[input_id].quantization.scale,
values[filter_id].quantization.scale,
filter_data,
bias_data,
output_zero_point,
output_scale,
output_min,
output_max,
node->flags,
code_cache,
&opdata->operator_objects[0]);
break;
}
#endif // !defined(XNN_NO_QS8_OPERATORS)
#ifndef XNN_NO_QU8_OPERATORS
case xnn_compute_type_qu8:
{
const float output_scale = values[output_id].quantization.scale;
const int32_t output_zero_point = values[output_id].quantization.zero_point;
const uint8_t output_min =
(uint8_t) lrintf(fminf(fmaxf(node->activation.output_min / output_scale + (float) output_zero_point, 0.0f), 255.0f));
const uint8_t output_max =
(uint8_t) lrintf(fminf(fmaxf(node->activation.output_max / output_scale + (float) output_zero_point, 0.0f), 255.0f));
status = xnn_create_deconvolution2d_nhwc_qu8(
node->params.deconvolution_2d.padding_top,
node->params.deconvolution_2d.padding_right,
node->params.deconvolution_2d.padding_bottom,
node->params.deconvolution_2d.padding_left,
node->params.deconvolution_2d.kernel_height,
node->params.deconvolution_2d.kernel_width,
node->params.deconvolution_2d.upsampling_height,
node->params.deconvolution_2d.upsampling_width,
node->params.deconvolution_2d.dilation_height,
node->params.deconvolution_2d.dilation_width,
node->params.deconvolution_2d.groups,
node->params.deconvolution_2d.group_input_channels,
node->params.deconvolution_2d.group_output_channels,
node->params.deconvolution_2d.group_input_channels * node->params.deconvolution_2d.groups /* input_pixel_stride */,
node->params.deconvolution_2d.group_output_channels * node->params.deconvolution_2d.groups /* output_pixel_stride */,
(uint8_t) values[input_id].quantization.zero_point,
values[input_id].quantization.scale,
(uint8_t) values[filter_id].quantization.zero_point,
values[filter_id].quantization.scale,
filter_data,
bias_data,
output_zero_point,
output_scale,
output_min,
output_max,
node->flags,
code_cache,
&opdata->operator_objects[0]);
break;
}
#endif // !defined(XNN_NO_QU8_OPERATORS)
default:
XNN_UNREACHABLE;
}
if (status == xnn_status_success) {
opdata->batch_size = values[input_id].shape.dim[0];
opdata->input_height = values[input_id].shape.dim[1];
opdata->input_width = values[input_id].shape.dim[2];
opdata->adjustment_height = node->params.deconvolution_2d.adjustment_height;
opdata->adjustment_width = node->params.deconvolution_2d.adjustment_width;
opdata->inputs[0] = input_id;
opdata->outputs[0] = output_id;
}
return status;
}
static enum xnn_status setup_deconvolution_operator(
const struct xnn_operator_data* opdata,
const struct xnn_blob* blobs,
size_t num_blobs,
pthreadpool_t threadpool)
{
const uint32_t input_id = opdata->inputs[0];
assert(input_id != XNN_INVALID_VALUE_ID);
assert(input_id < num_blobs);
const uint32_t output_id = opdata->outputs[0];
assert(output_id != XNN_INVALID_VALUE_ID);
assert(output_id < num_blobs);
const struct xnn_blob* input_blob = blobs + input_id;
const void* input_data = input_blob->data;
assert(input_data != NULL);
const struct xnn_blob* output_blob = blobs + output_id;
void* output_data = output_blob->data;
assert(output_data != NULL);
switch (opdata->operator_objects[0]->type) {
#ifndef XNN_NO_F16_OPERATORS
case xnn_operator_type_deconvolution_nhwc_f16:
return xnn_setup_deconvolution2d_nhwc_f16(
opdata->operator_objects[0],
opdata->batch_size,
opdata->input_height,
opdata->input_width,
opdata->adjustment_height,
opdata->adjustment_width,
input_data,
output_data,
threadpool);
break;
#endif // !defined(XNN_NO_F16_OPERATORS)
case xnn_operator_type_deconvolution_nhwc_f32:
return xnn_setup_deconvolution2d_nhwc_f32(
opdata->operator_objects[0],
opdata->batch_size,
opdata->input_height,
opdata->input_width,
opdata->adjustment_height,
opdata->adjustment_width,
input_data,
output_data,
threadpool);
break;
#ifndef XNN_NO_QS8_OPERATORS
case xnn_operator_type_deconvolution_nhwc_qs8:
return xnn_setup_deconvolution2d_nhwc_qs8(
opdata->operator_objects[0],
opdata->batch_size,
opdata->input_height,
opdata->input_width,
opdata->adjustment_height,
opdata->adjustment_width,
input_data,
output_data,
threadpool);
break;
#endif // !defined(XNN_NO_QS8_OPERATORS)
#ifndef XNN_NO_QU8_OPERATORS
case xnn_operator_type_deconvolution_nhwc_qu8:
return xnn_setup_deconvolution2d_nhwc_qu8(
opdata->operator_objects[0],
opdata->batch_size,
opdata->input_height,
opdata->input_width,
opdata->adjustment_height,
opdata->adjustment_width,
input_data,
output_data,
threadpool);
break;
#endif // !defined(XNN_NO_QU8_OPERATORS)
default:
XNN_UNREACHABLE;
}
}
static inline enum xnn_compute_type validate_datatypes_with_bias(
enum xnn_datatype input_datatype,
enum xnn_datatype filter_datatype,
enum xnn_datatype bias_datatype,
enum xnn_datatype output_datatype)
{
switch (filter_datatype) {
case xnn_datatype_fp32:
if (input_datatype == xnn_datatype_fp32 &&
bias_datatype == xnn_datatype_fp32 &&
output_datatype == xnn_datatype_fp32)
{
return xnn_compute_type_fp32;
}
break;
#ifndef XNN_NO_QS8_OPERATORS
case xnn_datatype_qint8:
if (input_datatype == xnn_datatype_qint8 &&
bias_datatype == xnn_datatype_qint32 &&
output_datatype == xnn_datatype_qint8)
{
return xnn_compute_type_qs8;
}
break;
#endif // !defined(XNN_NO_QS8_OPERATORS)
#ifndef XNN_NO_QU8_OPERATORS
case xnn_datatype_quint8:
if (input_datatype == xnn_datatype_quint8 &&
bias_datatype == xnn_datatype_qint32 &&
output_datatype == xnn_datatype_quint8)
{
return xnn_compute_type_qu8;
}
break;
#endif // !defined(XNN_NO_QU8_OPERATORS)
default:
XNN_UNREACHABLE;
}
return xnn_compute_type_invalid;
}
static inline enum xnn_compute_type validate_datatypes_without_bias(
enum xnn_datatype input_datatype,
enum xnn_datatype filter_datatype,
enum xnn_datatype output_datatype)
{
switch (filter_datatype) {
case xnn_datatype_fp32:
if (input_datatype == xnn_datatype_fp32 && output_datatype == xnn_datatype_fp32) {
return xnn_compute_type_fp32;
}
break;
#ifndef XNN_NO_QS8_OPERATORS
case xnn_datatype_qint8:
if (input_datatype == xnn_datatype_qint8 && output_datatype == xnn_datatype_qint8) {
return xnn_compute_type_qs8;
}
break;
#endif // !defined(XNN_NO_QS8_OPERATORS)
#ifndef XNN_NO_QU8_OPERATORS
case xnn_datatype_quint8:
if (input_datatype == xnn_datatype_quint8 && output_datatype == xnn_datatype_quint8) {
return xnn_compute_type_qu8;
}
break;
#endif // !defined(XNN_NO_QU8_OPERATORS)
default:
XNN_UNREACHABLE;
}
return xnn_compute_type_invalid;
}
enum xnn_status xnn_define_deconvolution_2d(
xnn_subgraph_t subgraph,
uint32_t padding_top,
uint32_t padding_right,
uint32_t padding_bottom,
uint32_t padding_left,
uint32_t adjustment_height,
uint32_t adjustment_width,
uint32_t kernel_height,
uint32_t kernel_width,
uint32_t upsampling_height,
uint32_t upsampling_width,
uint32_t dilation_height,
uint32_t dilation_width,
uint32_t groups,
size_t group_input_channels,
size_t group_output_channels,
float output_min,
float output_max,
uint32_t input_id,
uint32_t filter_id,
uint32_t bias_id,
uint32_t output_id,
uint32_t flags)
{
if ((xnn_params.init_flags & XNN_INIT_FLAG_XNNPACK) == 0) {
xnn_log_error("failed to define %s operator: XNNPACK is not initialized",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d));
return xnn_status_uninitialized;
}
if (kernel_width == 0 || kernel_height == 0) {
xnn_log_error(
"failed to define %s operator with %" PRIu32 "x%" PRIu32 " kernel: kernel dimensions must be non-zero",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), kernel_width, kernel_height);
return xnn_status_invalid_parameter;
}
if (upsampling_width == 0 || upsampling_height == 0) {
xnn_log_error(
"failed to define %s operator with %" PRIu32 "x%" PRIu32 " upsampling: upsampling dimensions must be non-zero",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), upsampling_width, upsampling_height);
return xnn_status_invalid_parameter;
}
if (dilation_width == 0 || dilation_height == 0) {
xnn_log_error(
"failed to define %s operator with %" PRIu32 "x%" PRIu32 " dilation: dilation dimensions must be non-zero",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), dilation_width, dilation_height);
return xnn_status_invalid_parameter;
}
if (groups == 0) {
xnn_log_error(
"failed to define %s operator with %" PRIu32 " groups: number of groups must be non-zero",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), groups);
return xnn_status_invalid_parameter;
}
if (group_input_channels == 0) {
xnn_log_error(
"failed to define %s operator with %zu input channels per group: number of channels must be non-zero",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), group_input_channels);
return xnn_status_invalid_parameter;
}
if (group_output_channels == 0) {
xnn_log_error(
"failed to define %s operator with %zu output channels per group: number of channels must be non-zero",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), group_output_channels);
return xnn_status_invalid_parameter;
}
if (isnan(output_min)) {
xnn_log_error(
"failed to define %s operator with NaN output lower bound: lower bound must be non-NaN",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d));
return xnn_status_invalid_parameter;
}
if (isnan(output_max)) {
xnn_log_error(
"failed to define %s operator with NaN output upper bound: upper bound must be non-NaN",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d));
return xnn_status_invalid_parameter;
}
if (output_min >= output_max) {
xnn_log_error(
"failed to define %s operator with [%.7g, %.7g] output range: lower bound must be below upper bound",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), output_min, output_max);
return xnn_status_invalid_parameter;
}
if (input_id >= subgraph->num_values) {
xnn_log_error(
"failed to define %s operator with input ID #%" PRIu32 ": invalid Value ID",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), input_id);
return xnn_status_invalid_parameter;
}
const struct xnn_value* input_value = &subgraph->values[input_id];
if (input_value->type != xnn_value_type_dense_tensor) {
xnn_log_error(
"failed to define %s operator with input ID #%" PRIu32 ": unsupported Value type %d (expected dense tensor)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), input_id, input_value->type);
return xnn_status_invalid_parameter;
}
switch (input_value->datatype) {
case xnn_datatype_fp32:
#ifndef XNN_NO_QS8_OPERATORS
case xnn_datatype_qint8:
#endif // !defined(XNN_NO_QS8_OPERATORS)
#ifndef XNN_NO_QU8_OPERATORS
case xnn_datatype_quint8:
#endif // !defined(XNN_NO_QU8_OPERATORS)
break;
default:
xnn_log_error(
"failed to define %s operator with input ID #%" PRIu32 ": unsupported Value datatype %s (%d)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), input_id,
xnn_datatype_to_string(input_value->datatype), input_value->datatype);
return xnn_status_invalid_parameter;
}
if (filter_id >= subgraph->num_values) {
xnn_log_error(
"failed to define %s operator with filter ID #%" PRIu32 ": invalid Value ID",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), filter_id);
return xnn_status_invalid_parameter;
}
const struct xnn_value* filter_value = &subgraph->values[filter_id];
if (filter_value->type != xnn_value_type_dense_tensor) {
xnn_log_error(
"failed to define %s operator with filter ID #%" PRIu32 ": unsupported Value type %d (expected dense tensor)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), filter_id, filter_value->type);
return xnn_status_invalid_parameter;
}
if (filter_value->data == NULL) {
xnn_log_error(
"failed to define %s operator with filter ID #%" PRIu32 ": non-static Value",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), filter_id);
return xnn_status_invalid_parameter;
}
switch (filter_value->datatype) {
case xnn_datatype_fp32:
break;
#ifndef XNN_NO_QS8_OPERATORS
case xnn_datatype_qint8:
if (filter_value->quantization.zero_point != 0) {
xnn_log_error(
"failed to define %s operator with filter ID #%" PRIu32 ": unsupported quantization zero point %" PRId32 " for datatype %s",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), filter_id,
filter_value->quantization.zero_point, xnn_datatype_to_string(filter_value->datatype));
}
break;
#endif // !defined(XNN_NO_QS8_OPERATORS)
#ifndef XNN_NO_QU8_OPERATORS
case xnn_datatype_quint8:
break;
#endif // !defined(XNN_NO_QU8_OPERATORS)
default:
xnn_log_error(
"failed to define %s operator with filter ID #%" PRIu32 ": unsupported Value datatype %s (%d)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), filter_id,
xnn_datatype_to_string(filter_value->datatype), filter_value->datatype);
return xnn_status_invalid_parameter;
}
const struct xnn_value* bias_value = NULL;
if (bias_id != XNN_INVALID_VALUE_ID) {
if (bias_id >= subgraph->num_values) {
xnn_log_error(
"failed to define %s operator with bias ID #%" PRIu32 ": invalid Value ID",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), bias_id);
return xnn_status_invalid_parameter;
}
bias_value = &subgraph->values[bias_id];
if (bias_value->type != xnn_value_type_dense_tensor) {
xnn_log_error(
"failed to define %s operator with bias ID #%" PRIu32 ": unsupported Value type %d (expected dense tensor)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), bias_id, bias_value->type);
return xnn_status_invalid_parameter;
}
if (bias_value->data == NULL) {
xnn_log_error(
"failed to define %s operator with bias ID #%" PRIu32 ": non-static Value",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), bias_id);
return xnn_status_invalid_parameter;
}
switch (bias_value->datatype) {
case xnn_datatype_fp32:
#if !defined(XNN_NO_QS8_OPERATORS) || !defined(XNN_NO_QU8_OPERATORS)
case xnn_datatype_qint32:
#endif // !defined(XNN_NO_QS8_OPERATORS) || !defined(XNN_NO_QU8_OPERATORS)
break;
default:
xnn_log_error(
"failed to define %s operator with bias ID #%" PRIu32 ": unsupported Value datatype %s (%d)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), bias_id,
xnn_datatype_to_string(bias_value->datatype), bias_value->datatype);
return xnn_status_invalid_parameter;
}
}
if (output_id >= subgraph->num_values) {
xnn_log_error(
"failed to define %s operator with output ID #%" PRIu32 ": invalid Value ID",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), output_id);
return xnn_status_invalid_parameter;
}
const struct xnn_value* output_value = &subgraph->values[output_id];
if (output_value->type != xnn_value_type_dense_tensor) {
xnn_log_error(
"failed to define %s operator with output ID #%" PRIu32 ": unsupported Value type %d (expected dense tensor)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), output_id, output_value->type);
return xnn_status_invalid_parameter;
}
switch (output_value->datatype) {
case xnn_datatype_fp32:
#ifndef XNN_NO_QS8_OPERATORS
case xnn_datatype_qint8:
#endif // !defined(XNN_NO_QS8_OPERATORS)
#ifndef XNN_NO_QU8_OPERATORS
case xnn_datatype_quint8:
#endif // !defined(XNN_NO_QU8_OPERATORS)
break;
default:
xnn_log_error(
"failed to define %s operator with output ID #%" PRIu32 ": unsupported Value datatype %s (%d)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), output_id,
xnn_datatype_to_string(output_value->datatype), output_value->datatype);
return xnn_status_invalid_parameter;
}
enum xnn_compute_type compute_type = xnn_compute_type_invalid;
if (bias_value != NULL) {
compute_type = validate_datatypes_with_bias(
input_value->datatype, filter_value->datatype, bias_value->datatype, output_value->datatype);
if (compute_type == xnn_compute_type_invalid) {
xnn_log_error(
"failed to define %s operator with input ID #%" PRIu32 ", filter ID #%" PRIu32 ", bias ID #%" PRIu32 ", and output ID #%" PRIu32
": mismatching datatypes across input (%s), filter (%s), bias (%s), and output (%s)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), input_id, filter_id, bias_id, output_id,
xnn_datatype_to_string(input_value->datatype),
xnn_datatype_to_string(filter_value->datatype),
xnn_datatype_to_string(bias_value->datatype),
xnn_datatype_to_string(output_value->datatype));
return xnn_status_invalid_parameter;
}
} else {
compute_type = validate_datatypes_without_bias(
input_value->datatype, filter_value->datatype, output_value->datatype);
if (compute_type == xnn_compute_type_invalid) {
xnn_log_error(
"failed to define %s operator with input ID #%" PRIu32 ", filter ID #%" PRIu32 ", and output ID #%" PRIu32
": mismatching datatypes across input (%s), filter (%s), and output (%s)",
xnn_node_type_to_string(xnn_node_type_deconvolution_2d), input_id, filter_id, output_id,
xnn_datatype_to_string(input_value->datatype),
xnn_datatype_to_string(filter_value->datatype),
xnn_datatype_to_string(output_value->datatype));
return xnn_status_invalid_parameter;
}
}
struct xnn_node* node = xnn_subgraph_new_node(subgraph);
if (node == NULL) {
return xnn_status_out_of_memory;
}
node->type = xnn_node_type_deconvolution_2d;
node->compute_type = compute_type;
node->params.deconvolution_2d.padding_top = padding_top;
node->params.deconvolution_2d.padding_right = padding_right;
node->params.deconvolution_2d.padding_bottom = padding_bottom;
node->params.deconvolution_2d.padding_left = padding_left;
node->params.deconvolution_2d.kernel_height = kernel_height;
node->params.deconvolution_2d.kernel_width = kernel_width;
node->params.deconvolution_2d.upsampling_height = upsampling_height;
node->params.deconvolution_2d.upsampling_width = upsampling_width;
node->params.deconvolution_2d.dilation_height = dilation_height;
node->params.deconvolution_2d.dilation_width = dilation_width;
node->params.deconvolution_2d.adjustment_height = adjustment_height;
node->params.deconvolution_2d.adjustment_width = adjustment_width;
node->params.deconvolution_2d.groups = groups;
node->params.deconvolution_2d.group_input_channels = group_input_channels;
node->params.deconvolution_2d.group_output_channels = group_output_channels;
node->activation.output_min = output_min;
node->activation.output_max = output_max;
node->num_inputs = 2 + (size_t) (bias_value != NULL);
node->inputs[0] = input_id;
node->inputs[1] = filter_id;
node->inputs[2] = bias_id;
node->num_outputs = 1;
node->outputs[0] = output_id;
node->flags = flags;
node->create = create_deconvolution_operator;
node->setup = setup_deconvolution_operator;
return xnn_status_success;
};