#63: WIP
This commit is contained in:
Benjamin Loison
@@ -25,32 +25,30 @@ imagesCamerasFileNames = {camera: os.listdir(imageCameraFolder) for camera, imag
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random.seed(0)
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# To not have a bias (chronological for instance) when split to make training and testing sets.
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for camera in IMAGES_CAMERAS_FOLDER:
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#print(imagesCamerasFileNames[camera][:3])
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random.shuffle(imagesCamerasFileNames[camera])
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#print(imagesCamerasFileNames[camera][:3])
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#exit(1)
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minimumNumberOfImagesCameras = 10#min([len(imagesCamerasFileNames[camera]) for camera in IMAGES_CAMERAS_FOLDER])
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#print(minimumNumberOfImagesCameras)
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#exit(1)
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for camera in IMAGES_CAMERAS_FOLDER:
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IMAGES_CAMERAS_FOLDER[camera] = IMAGES_CAMERAS_FOLDER[camera][:minimumNumberOfImagesCameras]
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numberOfCameras = len(IMAGES_CAMERAS_FOLDER)
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camerasIterativeMean = [iterativeMean() for _ in range(numberOfCameras)]
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camerasIterativeMean = {camera: iterativeMean() for camera in IMAGES_CAMERAS_FOLDER}
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minColor = None
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maxColor = None
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accuracy = []
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numberOfTrainingImages = int(minimumNumberOfImagesCameras * TRAINING_PORTION)
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numberOfTestingImages = minimumNumberOfImagesCameras - int(minimumNumberOfImagesCameras * TRAINING_PORTION)
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cameraTestingImagesNoise = {}#{camera: [] for camera in IMAGES_CAMERAS_FOLDER}
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returnSingleColorChannelImage = lambda singleColorChannelImage, _minColor, _maxColor: singleColorChannelImage
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for computeExtremes in tqdm(([True] if minColor is None or maxColor is None else []) + [False], 'Compute extremes'):
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rescaleIfNeeded = returnSingleColorChannelImage if computeExtremes else rescaleRawImageForDenoiser
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for cameraImageIndex in tqdm(range(minimumNumberOfImagesCameras * TRAINING_PORTION), 'Camera image index'):
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for cameraIndex, camera in enumerate(tqdm(IMAGES_CAMERAS_FOLDER, 'Camera')):
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imageFileName = imagesCamerasFileNames[camera][cameraImageIndex]
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for cameraTrainingImageIndex in tqdm(range(minimumNumberOfImagesCameras if computeExtremes else numberOfTrainingImages), 'Camera training image index'):
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for camera in tqdm(IMAGES_CAMERAS_FOLDER, 'Camera'):
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imageFileName = imagesCamerasFileNames[camera][cameraTrainingImageIndex]
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imageFilePath = f'{IMAGES_CAMERAS_FOLDER[camera]}/{imageFileName}'
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singleColorChannelImages = {color: rescaleIfNeeded(getColorChannel(imageFilePath, color), minColor, maxColor) for color in Color}
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multipleColorsImage = mergeSingleColorChannelImagesAccordingToBayerFilter(singleColorChannelImages)
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@@ -63,16 +61,33 @@ for computeExtremes in tqdm(([True] if minColor is None or maxColor is None else
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multipleColorsDenoisedImage = mergeSingleColorChannelImagesAccordingToBayerFilter(singleColorChannelDenoisedImages)
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imagePrnuEstimateNpArray = multipleColorsImage - multipleColorsDenoisedImage
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cameraIterativeMean = subgroupsIterativeMean[cameraIndex]
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cameraIterativeMean = camerasIterativeMean[camera]
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cameraIterativeMean.add(imagePrnuEstimateNpArray)
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if cameraIndex == numberOfCameras - 1:
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rms = rmsDiffNumpy(subgroupIterativeMean.mean, subgroupsIterativeMean[1 - cameraIndex].mean)
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rmss += [rms]
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for cameraTestingImageIndex in tqdm(range(numberOfTrainingImages), 'Camera testing image index'):
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singleColorChannelImages = {color: rescaleIfNeeded(getColorChannel(imageFilePath, color), minColor, maxColor) for color in Color}
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multipleColorsImage = mergeSingleColorChannelImagesAccordingToBayerFilter(singleColorChannelImages)
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singleColorChannelDenoisedImages = {color: denoise(singleColorChannelImages[color], DENOISER) for color in Color}
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multipleColorsDenoisedImage = mergeSingleColorChannelImagesAccordingToBayerFilter(singleColorChannelDenoisedImages)
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rms = rmsDiffNumpy(subgroupIterativeMean.mean, subgroupsIterativeMean[1 - cameraIndex].mean)
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accuracy += [rms]
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if computeExtremes:
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print(f'{minColor=} {maxColor=}')
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print('Extracting noise of testing images')
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for camera in tqdm(IMAGES_CAMERAS_FOLDER, 'Camera'):
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for cameraTestingImageIndex in tqdm(range(numberOfTestingImages), 'Camera testing image index'):
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imageFilePath =
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singleColorChannelImages = {color: rescaleIfNeeded(getColorChannel(imageFilePath, color), minColor, maxColor) for color in Color}
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multipleColorsImage = mergeSingleColorChannelImagesAccordingToBayerFilter(singleColorChannelImages)
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singleColorChannelDenoisedImages = {color: denoise(singleColorChannelImages[color], DENOISER) for color in Color}
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multipleColorsDenoisedImage = mergeSingleColorChannelImagesAccordingToBayerFilter(singleColorChannelDenoisedImages)
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imagePrnuEstimateNpArray = multipleColorsImage - multipleColorsDenoisedImage
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cameraTestingImagesNoise[camera] = cameraTestingImagesNoise.get(camera, []) + [multipleColorsDenoisedImage]
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for camera in range(IMAGES_CAMERAS_FOLDER):
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plt.imsave(f'{setting}_estimated_prnu_subgroup_{escapeFilePath(camera)}.png', (subgroupsIterativeMean[cameraIndex].mean))
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plt.imsave(f'{setting}_estimated_prnu_subgroup_{escapeFilePath(camera)}.png', (camerasIterativeMean[camera].mean))
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plt.title(f'Accuracy of camera source attribution thanks to a given number of images to estimate PRNUs with {DENOISER} denoiser')
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plt.xlabel('Number of images to estimate PRNU')
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