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Introduction {#intro}
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============
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OpenCV (Open Source Computer Vision Library: <http://opencv.org>) is an open-source
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library that includes several hundreds of computer vision algorithms. The document describes the
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so-called OpenCV 2.x API, which is essentially a C++ API, as opposed to the C-based OpenCV 1.x API
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(C API is deprecated and not tested with "C" compiler since OpenCV 2.4 releases)
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OpenCV has a modular structure, which means that the package includes several shared or static
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libraries. The following modules are available:
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- @ref core (**core**) - a compact module defining basic data structures, including the dense
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multi-dimensional array Mat and basic functions used by all other modules.
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- @ref imgproc (**imgproc**) - an image processing module that includes linear and non-linear image filtering,
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geometrical image transformations (resize, affine and perspective warping, generic table-based
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remapping), color space conversion, histograms, and so on.
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- @ref video (**video**) - a video analysis module that includes motion estimation, background subtraction,
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and object tracking algorithms.
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- @ref calib3d (**calib3d**) - basic multiple-view geometry algorithms, single and stereo camera calibration,
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object pose estimation, stereo correspondence algorithms, and elements of 3D reconstruction.
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- @ref features2d (**features2d**) - salient feature detectors, descriptors, and descriptor matchers.
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- @ref objdetect (**objdetect**) - detection of objects and instances of the predefined classes (for example,
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faces, eyes, mugs, people, cars, and so on).
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- @ref highgui (**highgui**) - an easy-to-use interface to simple UI capabilities.
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- @ref videoio (**videoio**) - an easy-to-use interface to video capturing and video codecs.
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- ... some other helper modules, such as FLANN and Google test wrappers, Python bindings, and
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others.
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The further chapters of the document describe functionality of each module. But first, make sure to
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get familiar with the common API concepts used thoroughly in the library.
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API Concepts
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------------
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### cv Namespace
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All the OpenCV classes and functions are placed into the `cv` namespace. Therefore, to access this
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functionality from your code, use the `cv::` specifier or `using namespace cv;` directive:
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```.cpp
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#include "opencv2/core.hpp"
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...
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cv::Mat H = cv::findHomography(points1, points2, cv::RANSAC, 5);
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...
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```
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or :
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```.cpp
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#include "opencv2/core.hpp"
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using namespace cv;
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...
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Mat H = findHomography(points1, points2, RANSAC, 5 );
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...
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```
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Some of the current or future OpenCV external names may conflict with STL or other libraries. In
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this case, use explicit namespace specifiers to resolve the name conflicts:
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```.cpp
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Mat a(100, 100, CV_32F);
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randu(a, Scalar::all(1), Scalar::all(std::rand()));
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cv::log(a, a);
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a /= std::log(2.);
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```
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### Automatic Memory Management
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OpenCV handles all the memory automatically.
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First of all, std::vector, cv::Mat, and other data structures used by the functions and methods have
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destructors that deallocate the underlying memory buffers when needed. This means that the
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destructors do not always deallocate the buffers as in case of Mat. They take into account possible
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data sharing. A destructor decrements the reference counter associated with the matrix data buffer.
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The buffer is deallocated if and only if the reference counter reaches zero, that is, when no other
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structures refer to the same buffer. Similarly, when a Mat instance is copied, no actual data is
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really copied. Instead, the reference counter is incremented to memorize that there is another owner
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of the same data. There is also the Mat::clone method that creates a full copy of the matrix data.
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See the example below:
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```.cpp
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// create a big 8Mb matrix
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Mat A(1000, 1000, CV_64F);
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// create another header for the same matrix;
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// this is an instant operation, regardless of the matrix size.
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Mat B = A;
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// create another header for the 3-rd row of A; no data is copied either
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Mat C = B.row(3);
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// now create a separate copy of the matrix
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Mat D = B.clone();
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// copy the 5-th row of B to C, that is, copy the 5-th row of A
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// to the 3-rd row of A.
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B.row(5).copyTo(C);
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// now let A and D share the data; after that the modified version
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// of A is still referenced by B and C.
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A = D;
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// now make B an empty matrix (which references no memory buffers),
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// but the modified version of A will still be referenced by C,
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// despite that C is just a single row of the original A
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B.release();
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// finally, make a full copy of C. As a result, the big modified
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// matrix will be deallocated, since it is not referenced by anyone
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C = C.clone();
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```
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You see that the use of Mat and other basic structures is simple. But what about high-level classes
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or even user data types created without taking automatic memory management into account? For them,
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OpenCV offers the cv::Ptr template class that is similar to std::shared_ptr from C++11. So, instead of
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using plain pointers:
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```.cpp
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T* ptr = new T(...);
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```
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you can use:
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```.cpp
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Ptr<T> ptr(new T(...));
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```
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or:
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```.cpp
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Ptr<T> ptr = makePtr<T>(...);
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```
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`Ptr<T>` encapsulates a pointer to a T instance and a reference counter associated with the pointer.
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See the cv::Ptr description for details.
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### Automatic Allocation of the Output Data
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OpenCV deallocates the memory automatically, as well as automatically allocates the memory for
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output function parameters most of the time. So, if a function has one or more input arrays (cv::Mat
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instances) and some output arrays, the output arrays are automatically allocated or reallocated. The
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size and type of the output arrays are determined from the size and type of input arrays. If needed,
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the functions take extra parameters that help to figure out the output array properties.
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Example:
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```.cpp
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#include "opencv2/imgproc.hpp"
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#include "opencv2/highgui.hpp"
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using namespace cv;
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int main(int, char**)
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{
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VideoCapture cap(0);
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if(!cap.isOpened()) return -1;
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Mat frame, edges;
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namedWindow("edges", WINDOW_AUTOSIZE);
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for(;;)
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{
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cap >> frame;
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cvtColor(frame, edges, COLOR_BGR2GRAY);
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GaussianBlur(edges, edges, Size(7,7), 1.5, 1.5);
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Canny(edges, edges, 0, 30, 3);
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imshow("edges", edges);
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if(waitKey(30) >= 0) break;
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}
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return 0;
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}
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```
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The array frame is automatically allocated by the `>>` operator since the video frame resolution and
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the bit-depth is known to the video capturing module. The array edges is automatically allocated by
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the cvtColor function. It has the same size and the bit-depth as the input array. The number of
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channels is 1 because the color conversion code cv::COLOR_BGR2GRAY is passed, which means a color to
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grayscale conversion. Note that frame and edges are allocated only once during the first execution
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of the loop body since all the next video frames have the same resolution. If you somehow change the
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video resolution, the arrays are automatically reallocated.
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The key component of this technology is the Mat::create method. It takes the desired array size and
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type. If the array already has the specified size and type, the method does nothing. Otherwise, it
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releases the previously allocated data, if any (this part involves decrementing the reference
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counter and comparing it with zero), and then allocates a new buffer of the required size. Most
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functions call the Mat::create method for each output array, and so the automatic output data
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allocation is implemented.
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Some notable exceptions from this scheme are cv::mixChannels, cv::RNG::fill, and a few other
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functions and methods. They are not able to allocate the output array, so you have to do this in
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advance.
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### Saturation Arithmetics
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As a computer vision library, OpenCV deals a lot with image pixels that are often encoded in a
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compact, 8- or 16-bit per channel, form and thus have a limited value range. Furthermore, certain
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operations on images, like color space conversions, brightness/contrast adjustments, sharpening,
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complex interpolation (bi-cubic, Lanczos) can produce values out of the available range. If you just
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store the lowest 8 (16) bits of the result, this results in visual artifacts and may affect a
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further image analysis. To solve this problem, the so-called *saturation* arithmetics is used. For
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example, to store r, the result of an operation, to an 8-bit image, you find the nearest value
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within the 0..255 range:
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\f[I(x,y)= \min ( \max (\textrm{round}(r), 0), 255)\f]
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Similar rules are applied to 8-bit signed, 16-bit signed and unsigned types. This semantics is used
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everywhere in the library. In C++ code, it is done using the `cv::saturate_cast<>` functions that
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resemble standard C++ cast operations. See below the implementation of the formula provided above:
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```.cpp
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I.at<uchar>(y, x) = saturate_cast<uchar>(r);
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```
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where cv::uchar is an OpenCV 8-bit unsigned integer type. In the optimized SIMD code, such SSE2
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instructions as paddusb, packuswb, and so on are used. They help achieve exactly the same behavior
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as in C++ code.
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@note Saturation is not applied when the result is 32-bit integer.
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### Fixed Pixel Types. Limited Use of Templates
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Templates is a great feature of C++ that enables implementation of very powerful, efficient and yet
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safe data structures and algorithms. However, the extensive use of templates may dramatically
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increase compilation time and code size. Besides, it is difficult to separate an interface and
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implementation when templates are used exclusively. This could be fine for basic algorithms but not
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good for computer vision libraries where a single algorithm may span thousands lines of code.
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Because of this and also to simplify development of bindings for other languages, like Python, Java,
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Matlab that do not have templates at all or have limited template capabilities, the current OpenCV
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implementation is based on polymorphism and runtime dispatching over templates. In those places
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where runtime dispatching would be too slow (like pixel access operators), impossible (generic
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`cv::Ptr<>` implementation), or just very inconvenient (`cv::saturate_cast<>()`) the current implementation
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introduces small template classes, methods, and functions. Anywhere else in the current OpenCV
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version the use of templates is limited.
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Consequently, there is a limited fixed set of primitive data types the library can operate on. That
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is, array elements should have one of the following types:
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- 8-bit unsigned integer (uchar)
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- 8-bit signed integer (schar)
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- 16-bit unsigned integer (ushort)
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- 16-bit signed integer (short)
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- 32-bit signed integer (int)
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- 32-bit floating-point number (float)
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- 64-bit floating-point number (double)
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- a tuple of several elements where all elements have the same type (one of the above). An array
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whose elements are such tuples, are called multi-channel arrays, as opposite to the
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single-channel arrays, whose elements are scalar values. The maximum possible number of
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channels is defined by the #CV_CN_MAX constant, which is currently set to 512.
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For these basic types, the following enumeration is applied:
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```.cpp
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enum { CV_8U=0, CV_8S=1, CV_16U=2, CV_16S=3, CV_32S=4, CV_32F=5, CV_64F=6 };
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```
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Multi-channel (n-channel) types can be specified using the following options:
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- #CV_8UC1 ... #CV_64FC4 constants (for a number of channels from 1 to 4)
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- CV_8UC(n) ... CV_64FC(n) or CV_MAKETYPE(CV_8U, n) ... CV_MAKETYPE(CV_64F, n) macros when
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the number of channels is more than 4 or unknown at the compilation time.
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@note `#CV_32FC1 == #CV_32F, #CV_32FC2 == #CV_32FC(2) == #CV_MAKETYPE(CV_32F, 2)`, and
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`#CV_MAKETYPE(depth, n) == ((depth&7) + ((n-1)<<3)`. This means that the constant type is formed from the
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depth, taking the lowest 3 bits, and the number of channels minus 1, taking the next
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`log2(CV_CN_MAX)` bits.
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Examples:
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```.cpp
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Mat mtx(3, 3, CV_32F); // make a 3x3 floating-point matrix
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Mat cmtx(10, 1, CV_64FC2); // make a 10x1 2-channel floating-point
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// matrix (10-element complex vector)
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Mat img(Size(1920, 1080), CV_8UC3); // make a 3-channel (color) image
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// of 1920 columns and 1080 rows.
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Mat grayscale(image.size(), CV_MAKETYPE(image.depth(), 1)); // make a 1-channel image of
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// the same size and same
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// channel type as img
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```
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Arrays with more complex elements cannot be constructed or processed using OpenCV. Furthermore, each
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function or method can handle only a subset of all possible array types. Usually, the more complex
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the algorithm is, the smaller the supported subset of formats is. See below typical examples of such
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limitations:
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- The face detection algorithm only works with 8-bit grayscale or color images.
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- Linear algebra functions and most of the machine learning algorithms work with floating-point
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arrays only.
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- Basic functions, such as cv::add, support all types.
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- Color space conversion functions support 8-bit unsigned, 16-bit unsigned, and 32-bit
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floating-point types.
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The subset of supported types for each function has been defined from practical needs and could be
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extended in future based on user requests.
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### InputArray and OutputArray
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Many OpenCV functions process dense 2-dimensional or multi-dimensional numerical arrays. Usually,
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such functions take cppMat as parameters, but in some cases it's more convenient to use
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`std::vector<>` (for a point set, for example) or `cv::Matx<>` (for 3x3 homography matrix and such). To
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avoid many duplicates in the API, special "proxy" classes have been introduced. The base "proxy"
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class is cv::InputArray. It is used for passing read-only arrays on a function input. The derived from
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InputArray class cv::OutputArray is used to specify an output array for a function. Normally, you should
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not care of those intermediate types (and you should not declare variables of those types
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explicitly) - it will all just work automatically. You can assume that instead of
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InputArray/OutputArray you can always use `Mat`, `std::vector<>`, `cv::Matx<>`, `cv::Vec<>` or `cv::Scalar`. When a
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function has an optional input or output array, and you do not have or do not want one, pass
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cv::noArray().
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### Error Handling
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OpenCV uses exceptions to signal critical errors. When the input data has a correct format and
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belongs to the specified value range, but the algorithm cannot succeed for some reason (for example,
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the optimization algorithm did not converge), it returns a special error code (typically, just a
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boolean variable).
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The exceptions can be instances of the cv::Exception class or its derivatives. In its turn,
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cv::Exception is a derivative of std::exception. So it can be gracefully handled in the code using
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other standard C++ library components.
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The exception is typically thrown either using the `#CV_Error(errcode, description)` macro, or its
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printf-like `#CV_Error_(errcode, (printf-spec, printf-args))` variant, or using the
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#CV_Assert(condition) macro that checks the condition and throws an exception when it is not
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satisfied. For performance-critical code, there is #CV_DbgAssert(condition) that is only retained in
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the Debug configuration. Due to the automatic memory management, all the intermediate buffers are
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automatically deallocated in case of a sudden error. You only need to add a try statement to catch
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exceptions, if needed: :
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```.cpp
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try
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{
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... // call OpenCV
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}
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catch (const cv::Exception& e)
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{
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const char* err_msg = e.what();
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std::cout << "exception caught: " << err_msg << std::endl;
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}
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```
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### Multi-threading and Re-enterability
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The current OpenCV implementation is fully re-enterable.
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That is, the same function or the same methods of different class instances
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can be called from different threads.
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Also, the same Mat can be used in different threads
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because the reference-counting operations use the architecture-specific atomic instructions.
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