/*
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copy or use the software.
License Agreement
For Open Source Computer Vision Library
(3-clause BSD License)
Copyright (C) 2013, OpenCV Foundation, all rights reserved.
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Redistribution and use in source and binary forms, with or without modification,
are permitted provided that the following conditions are met:
* Redistributions of source code must retain the above copyright notice,
this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright notice,
this list of conditions and the following disclaimer in the documentation
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* Neither the names of the copyright holders nor the names of the contributors
may be used to endorse or promote products derived from this software
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This software is provided by the copyright holders and contributors "as is" and
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*/
#ifndef __OPENCV_XOBJDETECT_XOBJDETECT_HPP__
#define __OPENCV_XOBJDETECT_XOBJDETECT_HPP__
#include <opencv2/core.hpp>
#include <vector>
#include <string>
namespace cv
{
namespace xobjdetect
{
/* Compute channel pyramid for acf features
image — image, for which channels should be computed
channels — output array for computed channels
*/
void computeChannels(InputArray image, OutputArrayOfArrays channels);
class CV_EXPORTS ACFFeatureEvaluator : public Algorithm
{
public:
/* Set channels for feature evaluation */
virtual void setChannels(InputArrayOfArrays channels) = 0;
/* Set window position */
virtual void setPosition(Size position) = 0;
/* Evaluate feature with given index for current channels
and window position */
virtual int evaluate(size_t feature_ind) const = 0;
/* Evaluate all features for current channels and window position
Returns matrix-column of features
*/
virtual void evaluateAll(OutputArray feature_values) const = 0;
};
/* Construct evaluator, set features to evaluate */
CV_EXPORTS Ptr<ACFFeatureEvaluator>
createACFFeatureEvaluator(const std::vector<Point3i>& features);
/* Generate acf features
window_size — size of window in which features should be evaluated
count — number of features to generate.
Max number of features is min(count, # possible distinct features)
Returns vector of distinct acf features
*/
std::vector<Point3i>
generateFeatures(Size window_size, int count = INT_MAX);
struct CV_EXPORTS WaldBoostParams
{
int weak_count;
float alpha;
WaldBoostParams(): weak_count(100), alpha(0.01f)
{}
};
class CV_EXPORTS WaldBoost : public Algorithm
{
public:
/* Train WaldBoost cascade for given data
data — matrix of feature values, size M x N, one feature per row
labels — matrix of sample class labels, size 1 x N. Labels can be from
{-1, +1}
Returns feature indices chosen for cascade.
Feature enumeration starts from 0
*/
virtual std::vector<int> train(const Mat& data,
const Mat& labels) = 0;
/* Predict object class given object that can compute object features
feature_evaluator — object that can compute features by demand
Returns confidence_value — measure of confidense that object
is from class +1
*/
virtual float predict(
const Ptr<ACFFeatureEvaluator>& feature_evaluator) const = 0;
};
CV_EXPORTS Ptr<WaldBoost>
createWaldBoost(const WaldBoostParams& params = WaldBoostParams());
struct CV_EXPORTS ICFDetectorParams
{
int feature_count;
int weak_count;
int model_n_rows;
int model_n_cols;
double overlap;
ICFDetectorParams(): feature_count(UINT_MAX), weak_count(100),
model_n_rows(40), model_n_cols(40), overlap(0.0)
{}
};
class CV_EXPORTS ICFDetector
{
public:
/* Train detector
image_filenames — filenames of images for training
labelling — vector of object bounding boxes per every image
params — parameters for detector training
*/
void train(const std::vector<std::string>& image_filenames,
const std::vector<std::vector<cv::Rect> >& labelling,
ICFDetectorParams params = ICFDetectorParams());
/* Save detector in file, return true on success, false otherwise */
bool save(const std::string& filename);
};
} /* namespace xobjdetect */
} /* namespace cv */
#endif /* __OPENCV_XOBJDETECT_XOBJDETECT_HPP__ */