boofcv.alg.feature.detect.edge.impl.ImplGradientToEdgeFeatures Maven / Gradle / Ivy
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BoofCV is an open source Java library for real-time computer vision and robotics applications.
/*
* Copyright (c) 2011-2017, Peter Abeles. All Rights Reserved.
*
* This file is part of BoofCV (http://boofcv.org).
*
* 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
*
* http://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.
*/
package boofcv.alg.feature.detect.edge.impl;
import boofcv.struct.image.GrayF32;
import boofcv.struct.image.GrayS16;
import boofcv.struct.image.GrayS32;
/**
*
* Implementations of the core algorithms of {@link boofcv.alg.feature.detect.edge.GradientToEdgeFeatures}.
*
*
*
* WARNING: Do not modify. Automatically generated by {@link GenerateImplGradientToEdgeFeatures}.
*
*
* @author Peter Abeles
*/
public class ImplGradientToEdgeFeatures {
static public void intensityE(GrayF32 derivX , GrayF32 derivY , GrayF32 intensity )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexI = intensity.startIndex + y*intensity.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexI++ ) {
float dx = derivX.data[indexX];
float dy = derivY.data[indexY];
intensity.data[indexI] = (float)Math.sqrt(dx*dx + dy*dy);
}
}
}
static public void intensityAbs(GrayF32 derivX , GrayF32 derivY , GrayF32 intensity )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexI = intensity.startIndex + y*intensity.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexI++ ) {
intensity.data[indexI] = Math.abs(derivX.data[indexX]) + Math.abs(derivY.data[indexY]);
}
}
}
static public void direction(GrayF32 derivX , GrayF32 derivY , GrayF32 angle )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexA = angle.startIndex + y*angle.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexA++ ) {
float dx = derivX.data[indexX];
float dy = derivY.data[indexY];
// compute the angle while avoiding divided by zero errors
angle.data[indexA] = Math.abs(dx) < 1e-10f ? (float)(Math.PI/2.0) : (float)Math.atan(dy/dx);
}
}
}
static public void direction2(GrayF32 derivX , GrayF32 derivY , GrayF32 angle )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexA = angle.startIndex + y*angle.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexA++ ) {
float dx = derivX.data[indexX];
float dy = derivY.data[indexY];
// compute the angle while avoiding divided by zero errors
angle.data[indexA] = (float)Math.atan2(dy,dx);
}
}
}
static public void intensityE(GrayS16 derivX , GrayS16 derivY , GrayF32 intensity )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexI = intensity.startIndex + y*intensity.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexI++ ) {
int dx = derivX.data[indexX];
int dy = derivY.data[indexY];
intensity.data[indexI] = (float)Math.sqrt(dx*dx + dy*dy);
}
}
}
static public void intensityAbs(GrayS16 derivX , GrayS16 derivY , GrayF32 intensity )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexI = intensity.startIndex + y*intensity.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexI++ ) {
intensity.data[indexI] = Math.abs(derivX.data[indexX]) + Math.abs(derivY.data[indexY]);
}
}
}
static public void direction(GrayS16 derivX , GrayS16 derivY , GrayF32 angle )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexA = angle.startIndex + y*angle.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexA++ ) {
int dx = derivX.data[indexX];
int dy = derivY.data[indexY];
// compute the angle while avoiding divided by zero errors
angle.data[indexA] = dx == 0 ? (float)(Math.PI/2.0) : (float)Math.atan((double)dy/(double)dx);
}
}
}
static public void direction2(GrayS16 derivX , GrayS16 derivY , GrayF32 angle )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexA = angle.startIndex + y*angle.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexA++ ) {
int dx = derivX.data[indexX];
int dy = derivY.data[indexY];
// compute the angle while avoiding divided by zero errors
angle.data[indexA] = (float)Math.atan2(dy,dx);
}
}
}
static public void intensityE(GrayS32 derivX , GrayS32 derivY , GrayF32 intensity )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexI = intensity.startIndex + y*intensity.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexI++ ) {
int dx = derivX.data[indexX];
int dy = derivY.data[indexY];
intensity.data[indexI] = (float)Math.sqrt(dx*dx + dy*dy);
}
}
}
static public void intensityAbs(GrayS32 derivX , GrayS32 derivY , GrayF32 intensity )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexI = intensity.startIndex + y*intensity.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexI++ ) {
intensity.data[indexI] = Math.abs(derivX.data[indexX]) + Math.abs(derivY.data[indexY]);
}
}
}
static public void direction(GrayS32 derivX , GrayS32 derivY , GrayF32 angle )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexA = angle.startIndex + y*angle.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexA++ ) {
int dx = derivX.data[indexX];
int dy = derivY.data[indexY];
// compute the angle while avoiding divided by zero errors
angle.data[indexA] = dx == 0 ? (float)(Math.PI/2.0) : (float)Math.atan((double)dy/(double)dx);
}
}
}
static public void direction2(GrayS32 derivX , GrayS32 derivY , GrayF32 angle )
{
final int w = derivX.width;
final int h = derivY.height;
for( int y = 0; y < h; y++ ) {
int indexX = derivX.startIndex + y*derivX.stride;
int indexY = derivY.startIndex + y*derivY.stride;
int indexA = angle.startIndex + y*angle.stride;
int end = indexX + w;
for( ; indexX < end; indexX++ , indexY++ , indexA++ ) {
int dx = derivX.data[indexX];
int dy = derivY.data[indexY];
// compute the angle while avoiding divided by zero errors
angle.data[indexA] = (float)Math.atan2(dy,dx);
}
}
}
}
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