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372 lines
6.0 KiB
ReStructuredText
372 lines
6.0 KiB
ReStructuredText
Cookbook
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========
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.. highlight:: python
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Here is a collection of code fragments demonstrating some features
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of the OpenCV Python bindings.
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Convert an image
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----------------
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.. doctest::
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>>> import cv
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>>> im = cv.LoadImageM("building.jpg")
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>>> print type(im)
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<type 'cv.cvmat'>
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>>> cv.SaveImage("foo.png", im)
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..
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Resize an image
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---------------
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To resize an image in OpenCV, create a destination image of the appropriate size, then call
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:ref:`Resize`
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.
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.. doctest::
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>>> import cv
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>>> original = cv.LoadImageM("building.jpg")
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>>> thumbnail = cv.CreateMat(original.rows / 10, original.cols / 10, cv.CV_8UC3)
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>>> cv.Resize(original, thumbnail)
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..
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Compute the Laplacian
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---------------------
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.. doctest::
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>>> import cv
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>>> im = cv.LoadImageM("building.jpg", 1)
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>>> dst = cv.CreateImage(cv.GetSize(im), cv.IPL_DEPTH_16S, 3)
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>>> laplace = cv.Laplace(im, dst)
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>>> cv.SaveImage("foo-laplace.png", dst)
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..
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Using GoodFeaturesToTrack
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-------------------------
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To find the 10 strongest corner features in an image, use
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:ref:`GoodFeaturesToTrack`
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like this:
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.. doctest::
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>>> import cv
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>>> img = cv.LoadImageM("building.jpg", cv.CV_LOAD_IMAGE_GRAYSCALE)
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>>> eig_image = cv.CreateMat(img.rows, img.cols, cv.CV_32FC1)
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>>> temp_image = cv.CreateMat(img.rows, img.cols, cv.CV_32FC1)
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>>> for (x,y) in cv.GoodFeaturesToTrack(img, eig_image, temp_image, 10, 0.04, 1.0, useHarris = True):
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... print "good feature at", x,y
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good feature at 198.0 514.0
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good feature at 791.0 260.0
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good feature at 370.0 467.0
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good feature at 374.0 469.0
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good feature at 490.0 520.0
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good feature at 262.0 278.0
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good feature at 781.0 134.0
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good feature at 3.0 247.0
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good feature at 667.0 321.0
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good feature at 764.0 304.0
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..
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Using GetSubRect
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----------------
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GetSubRect returns a rectangular part of another image. It does this without copying any data.
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.. doctest::
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>>> import cv
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>>> img = cv.LoadImageM("building.jpg")
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>>> sub = cv.GetSubRect(img, (60, 70, 32, 32)) # sub is 32x32 patch within img
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>>> cv.SetZero(sub) # clear sub to zero, which also clears 32x32 pixels in img
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..
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Using CreateMat, and accessing an element
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-----------------------------------------
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.. doctest::
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>>> import cv
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>>> mat = cv.CreateMat(5, 5, cv.CV_32FC1)
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>>> cv.Set(mat, 1.0)
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>>> mat[3,1] += 0.375
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>>> print mat[3,1]
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1.375
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>>> print [mat[3,i] for i in range(5)]
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[1.0, 1.375, 1.0, 1.0, 1.0]
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..
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ROS image message to OpenCV
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---------------------------
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See this tutorial:
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`Using CvBridge to convert between ROS images And OpenCV images <http://www.ros.org/wiki/cv_bridge/Tutorials/UsingCvBridgeToConvertBetweenROSImagesAndOpenCVImages>`_
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.
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PIL Image to OpenCV
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-------------------
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(For details on PIL see the
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`PIL handbook <http://www.pythonware.com/library/pil/handbook/image.htm>`_
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.)
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.. doctest::
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>>> import Image, cv
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>>> pi = Image.open('building.jpg') # PIL image
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>>> cv_im = cv.CreateImageHeader(pi.size, cv.IPL_DEPTH_8U, 3)
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>>> cv.SetData(cv_im, pi.tostring())
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>>> print pi.size, cv.GetSize(cv_im)
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(868, 600) (868, 600)
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>>> print pi.tostring() == cv_im.tostring()
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True
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..
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OpenCV to PIL Image
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-------------------
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.. doctest::
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>>> import Image, cv
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>>> cv_im = cv.CreateImage((320,200), cv.IPL_DEPTH_8U, 1)
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>>> pi = Image.fromstring("L", cv.GetSize(cv_im), cv_im.tostring())
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>>> print pi.size
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(320, 200)
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..
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NumPy and OpenCV
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----------------
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Using the
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`array interface <http://docs.scipy.org/doc/numpy/reference/arrays.interface.html>`_
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, to use an OpenCV CvMat in NumPy:
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.. doctest::
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>>> import cv, numpy
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>>> mat = cv.CreateMat(3, 5, cv.CV_32FC1)
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>>> cv.Set(mat, 7)
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>>> a = numpy.asarray(mat)
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>>> print a
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[[ 7. 7. 7. 7. 7.]
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[ 7. 7. 7. 7. 7.]
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[ 7. 7. 7. 7. 7.]]
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..
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and to use a NumPy array in OpenCV:
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.. doctest::
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>>> import cv, numpy
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>>> a = numpy.ones((480, 640))
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>>> mat = cv.fromarray(a)
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>>> print mat.rows
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480
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>>> print mat.cols
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640
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..
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also, most OpenCV functions can work on NumPy arrays directly, for example:
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.. doctest::
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>>> picture = numpy.ones((640, 480))
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>>> cv.Smooth(picture, picture, cv.CV_GAUSSIAN, 15, 15)
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..
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Given a 2D array,
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the
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:ref:`fromarray`
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function (or the implicit version shown above)
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returns a single-channel
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:ref:`CvMat`
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of the same size.
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For a 3D array of size
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:math:`j \times k \times l`
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, it returns a
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:ref:`CvMat`
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sized
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:math:`j \times k`
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with
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:math:`l`
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channels.
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Alternatively, use
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:ref:`fromarray`
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with the
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``allowND``
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option to always return a
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:ref:`cvMatND`
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OpenCV to pygame
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----------------
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To convert an OpenCV image to a
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`pygame <http://www.pygame.org/>`_
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surface:
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.. doctest::
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>>> import pygame.image, cv
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>>> src = cv.LoadImage("lena.jpg")
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>>> src_rgb = cv.CreateMat(src.height, src.width, cv.CV_8UC3)
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>>> cv.CvtColor(src, src_rgb, cv.CV_BGR2RGB)
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>>> pg_img = pygame.image.frombuffer(src_rgb.tostring(), cv.GetSize(src_rgb), "RGB")
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>>> print pg_img
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<Surface(512x512x24 SW)>
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..
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OpenCV and OpenEXR
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------------------
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Using
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`OpenEXR's Python bindings <http://www.excamera.com/sphinx/articles-openexr.html>`_
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you can make a simple
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image viewer:
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::
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import OpenEXR, Imath, cv
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filename = "GoldenGate.exr"
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exrimage = OpenEXR.InputFile(filename)
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dw = exrimage.header()['dataWindow']
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(width, height) = (dw.max.x - dw.min.x + 1, dw.max.y - dw.min.y + 1)
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def fromstr(s):
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mat = cv.CreateMat(height, width, cv.CV_32FC1)
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cv.SetData(mat, s)
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return mat
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pt = Imath.PixelType(Imath.PixelType.FLOAT)
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(r, g, b) = [fromstr(s) for s in exrimage.channels("RGB", pt)]
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bgr = cv.CreateMat(height, width, cv.CV_32FC3)
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cv.Merge(b, g, r, None, bgr)
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cv.ShowImage(filename, bgr)
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cv.WaitKey()
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..
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