def getnextpacket(self): if not self.data or self.dataoffset >= len(self.data): try: cd, id = v.GetCaptureData() except sv.error: return None data = cd.InterleaveFields(1) cd.UnlockCaptureData() if self.justright: self.data = data else: self.data = imageop.crop(data, 1, \ self.realwidth, \ self.realheight, \ self.x0, self.y0, \ self.x1, self.y1) self.lpos = 0 self.dataoffset = 0 if self.type == 'mono': self.data = imageop.dither2mono(self.data, \ self.width, self.height) elif self.type == 'grey2': self.data = imageop.dither2grey2(self.data, \ self.width, self.height) elif self.type == 'grey4': self.data = imageop.grey2grey4(self.data, \ self.width, self.height) data = self.data[self.dataoffset:self.dataoffset+self.pktsize] lpos = self.lpos self.dataoffset = self.dataoffset + self.pktsize self.lpos = self.lpos + self.lpp return lpos, data
def main(use_rgbimg=1): # Create binary test files uu.decode(get_qualified_path('testrgb'+os.extsep+'uue'), 'test'+os.extsep+'rgb') if use_rgbimg: image, width, height = getrgbimage('test'+os.extsep+'rgb') else: image, width, height = getimage('test'+os.extsep+'rgb') # Return the selected part of image, which should by width by height # in size and consist of pixels of psize bytes. if verbose: print 'crop' newimage = imageop.crop (image, 4, width, height, 0, 0, 1, 1) # Return image scaled to size newwidth by newheight. No interpolation # is done, scaling is done by simple-minded pixel duplication or removal. # Therefore, computer-generated images or dithered images will # not look nice after scaling. if verbose: print 'scale' scaleimage = imageop.scale(image, 4, width, height, 1, 1) # Run a vertical low-pass filter over an image. It does so by computing # each destination pixel as the average of two vertically-aligned source # pixels. The main use of this routine is to forestall excessive flicker # if the image two vertically-aligned source pixels, hence the name. if verbose: print 'tovideo' videoimage = imageop.tovideo (image, 4, width, height) # Convert an rgb image to an 8 bit rgb if verbose: print 'rgb2rgb8' greyimage = imageop.rgb2rgb8(image, width, height) # Convert an 8 bit rgb image to a 24 bit rgb image if verbose: print 'rgb82rgb' image = imageop.rgb82rgb(greyimage, width, height) # Convert an rgb image to an 8 bit greyscale image if verbose: print 'rgb2grey' greyimage = imageop.rgb2grey(image, width, height) # Convert an 8 bit greyscale image to a 24 bit rgb image if verbose: print 'grey2rgb' image = imageop.grey2rgb(greyimage, width, height) # Convert a 8-bit deep greyscale image to a 1-bit deep image by # thresholding all the pixels. The resulting image is tightly packed # and is probably only useful as an argument to mono2grey. if verbose: print 'grey2mono' monoimage = imageop.grey2mono (greyimage, width, height, 0) # monoimage, width, height = getimage('monotest.rgb') # Convert a 1-bit monochrome image to an 8 bit greyscale or color image. # All pixels that are zero-valued on input get value p0 on output and # all one-value input pixels get value p1 on output. To convert a # monochrome black-and-white image to greyscale pass the values 0 and # 255 respectively. if verbose: print 'mono2grey' greyimage = imageop.mono2grey (monoimage, width, height, 0, 255) # Convert an 8-bit greyscale image to a 1-bit monochrome image using a # (simple-minded) dithering algorithm. if verbose: print 'dither2mono' monoimage = imageop.dither2mono (greyimage, width, height) # Convert an 8-bit greyscale image to a 4-bit greyscale image without # dithering. if verbose: print 'grey2grey4' grey4image = imageop.grey2grey4 (greyimage, width, height) # Convert an 8-bit greyscale image to a 2-bit greyscale image without # dithering. if verbose: print 'grey2grey2' grey2image = imageop.grey2grey2 (greyimage, width, height) # Convert an 8-bit greyscale image to a 2-bit greyscale image with # dithering. As for dither2mono, the dithering algorithm is currently # very simple. if verbose: print 'dither2grey2' grey2image = imageop.dither2grey2 (greyimage, width, height) # Convert a 4-bit greyscale image to an 8-bit greyscale image. if verbose: print 'grey42grey' greyimage = imageop.grey42grey (grey4image, width, height) # Convert a 2-bit greyscale image to an 8-bit greyscale image. if verbose: print 'grey22grey' image = imageop.grey22grey (grey2image, width, height) # Cleanup unlink('test'+os.extsep+'rgb')
# Live video input class.
def main(use_rgbimg=1): # Create binary test files uu.decode(get_qualified_path('testrgb' + os.extsep + 'uue'), 'test' + os.extsep + 'rgb') if use_rgbimg: image, width, height = getrgbimage('test' + os.extsep + 'rgb') else: image, width, height = getimage('test' + os.extsep + 'rgb') # Return the selected part of image, which should by width by height # in size and consist of pixels of psize bytes. if verbose: print 'crop' newimage = imageop.crop(image, 4, width, height, 0, 0, 1, 1) # Return image scaled to size newwidth by newheight. No interpolation # is done, scaling is done by simple-minded pixel duplication or removal. # Therefore, computer-generated images or dithered images will # not look nice after scaling. if verbose: print 'scale' scaleimage = imageop.scale(image, 4, width, height, 1, 1) # Run a vertical low-pass filter over an image. It does so by computing # each destination pixel as the average of two vertically-aligned source # pixels. The main use of this routine is to forestall excessive flicker # if the image two vertically-aligned source pixels, hence the name. if verbose: print 'tovideo' videoimage = imageop.tovideo(image, 4, width, height) # Convert an rgb image to an 8 bit rgb if verbose: print 'rgb2rgb8' greyimage = imageop.rgb2rgb8(image, width, height) # Convert an 8 bit rgb image to a 24 bit rgb image if verbose: print 'rgb82rgb' image = imageop.rgb82rgb(greyimage, width, height) # Convert an rgb image to an 8 bit greyscale image if verbose: print 'rgb2grey' greyimage = imageop.rgb2grey(image, width, height) # Convert an 8 bit greyscale image to a 24 bit rgb image if verbose: print 'grey2rgb' image = imageop.grey2rgb(greyimage, width, height) # Convert a 8-bit deep greyscale image to a 1-bit deep image by # thresholding all the pixels. The resulting image is tightly packed # and is probably only useful as an argument to mono2grey. if verbose: print 'grey2mono' monoimage = imageop.grey2mono(greyimage, width, height, 0) # monoimage, width, height = getimage('monotest.rgb') # Convert a 1-bit monochrome image to an 8 bit greyscale or color image. # All pixels that are zero-valued on input get value p0 on output and # all one-value input pixels get value p1 on output. To convert a # monochrome black-and-white image to greyscale pass the values 0 and # 255 respectively. if verbose: print 'mono2grey' greyimage = imageop.mono2grey(monoimage, width, height, 0, 255) # Convert an 8-bit greyscale image to a 1-bit monochrome image using a # (simple-minded) dithering algorithm. if verbose: print 'dither2mono' monoimage = imageop.dither2mono(greyimage, width, height) # Convert an 8-bit greyscale image to a 4-bit greyscale image without # dithering. if verbose: print 'grey2grey4' grey4image = imageop.grey2grey4(greyimage, width, height) # Convert an 8-bit greyscale image to a 2-bit greyscale image without # dithering. if verbose: print 'grey2grey2' grey2image = imageop.grey2grey2(greyimage, width, height) # Convert an 8-bit greyscale image to a 2-bit greyscale image with # dithering. As for dither2mono, the dithering algorithm is currently # very simple. if verbose: print 'dither2grey2' grey2image = imageop.dither2grey2(greyimage, width, height) # Convert a 4-bit greyscale image to an 8-bit greyscale image. if verbose: print 'grey42grey' greyimage = imageop.grey42grey(grey4image, width, height) # Convert a 2-bit greyscale image to an 8-bit greyscale image. if verbose: print 'grey22grey' image = imageop.grey22grey(grey2image, width, height) # Cleanup unlink('test' + os.extsep + 'rgb')
#! /usr/bin/env python