diff --git a/comfy_extras/nodes_post_processing.py b/comfy_extras/nodes_post_processing.py index 2c0ad8b96..b2eaa650a 100644 --- a/comfy_extras/nodes_post_processing.py +++ b/comfy_extras/nodes_post_processing.py @@ -27,32 +27,38 @@ class Dither: CATEGORY = "postprocessing" def dither(self, image: torch.Tensor, bits: int): - tensor_image = image.numpy()[0] - img = (tensor_image * 255) - height, width, _ = img.shape + batch_size, height, width, _ = image.shape + result = torch.zeros_like(image) - scale = 255 / (2**bits - 1) + for b in range(batch_size): + tensor_image = image[b].numpy() + img = (tensor_image * 255) + height, width, _ = img.shape - for y in range(height): - for x in range(width): - old_pixel = img[y, x].copy() - new_pixel = np.round(old_pixel / scale) * scale - img[y, x] = new_pixel + scale = 255 / (2**bits - 1) - quant_error = old_pixel - new_pixel + for y in range(height): + for x in range(width): + old_pixel = img[y, x].copy() + new_pixel = np.round(old_pixel / scale) * scale + img[y, x] = new_pixel + + quant_error = old_pixel - new_pixel - if x + 1 < width: - img[y, x + 1] += quant_error * 7 / 16 - if y + 1 < height: - if x - 1 >= 0: - img[y + 1, x - 1] += quant_error * 3 / 16 - img[y + 1, x] += quant_error * 5 / 16 if x + 1 < width: - img[y + 1, x + 1] += quant_error * 1 / 16 + img[y, x + 1] += quant_error * 7 / 16 + if y + 1 < height: + if x - 1 >= 0: + img[y + 1, x - 1] += quant_error * 3 / 16 + img[y + 1, x] += quant_error * 5 / 16 + if x + 1 < width: + img[y + 1, x + 1] += quant_error * 1 / 16 - dithered = img / 255 - tensor = torch.from_numpy(dithered).unsqueeze(0) - return (tensor,) + dithered = img / 255 + tensor = torch.from_numpy(dithered).unsqueeze(0) + result[b] = tensor + + return (result,) class KMeansQuantize: def __init__(self): @@ -84,25 +90,31 @@ class KMeansQuantize: CATEGORY = "postprocessing" def kmeans_quantize(self, image: torch.Tensor, colors: int, precision: int): - tensor_image = image.numpy()[0].astype(np.float32) - img = tensor_image + batch_size, height, width, _ = image.shape + result = torch.zeros_like(image) - height, width, c = img.shape + for b in range(batch_size): + tensor_image = image[b].numpy().astype(np.float32) + img = tensor_image - criteria = ( - cv2.TERM_CRITERIA_EPS + cv2.TERM_CRITERIA_MAX_ITER, - precision * 5, 0.01 - ) + height, width, c = img.shape - img_copy = img.reshape(-1, c) - _, label, center = cv2.kmeans( - img_copy, colors, None, - criteria, 1, cv2.KMEANS_PP_CENTERS - ) + criteria = ( + cv2.TERM_CRITERIA_EPS + cv2.TERM_CRITERIA_MAX_ITER, + precision * 5, 0.01 + ) - result = center[label.flatten()].reshape(*img.shape) - tensor = torch.from_numpy(result).unsqueeze(0) - return (tensor,) + img_copy = img.reshape(-1, c) + _, label, center = cv2.kmeans( + img_copy, colors, None, + criteria, 1, cv2.KMEANS_PP_CENTERS + ) + + img = center[label.flatten()].reshape(*img.shape) + tensor = torch.from_numpy(img).unsqueeze(0) + result[b] = tensor + + return (result,) class GaussianBlur: def __init__(self): @@ -134,10 +146,16 @@ class GaussianBlur: CATEGORY = "postprocessing" def blur(self, image: torch.Tensor, kernel_size: int, sigma: float): - tensor_image = image.numpy()[0] - blurred = cv2.GaussianBlur(tensor_image, (kernel_size, kernel_size), sigma) - tensor = torch.from_numpy(blurred).unsqueeze(0) - return (tensor,) + batch_size, height, width, _ = image.shape + result = torch.zeros_like(image) + + for b in range(batch_size): + tensor_image = image[b].numpy() + blurred = cv2.GaussianBlur(tensor_image, (kernel_size, kernel_size), sigma) + tensor = torch.from_numpy(blurred).unsqueeze(0) + result[b] = tensor + + return (result,) class Sharpen: def __init__(self): @@ -169,18 +187,24 @@ class Sharpen: CATEGORY = "postprocessing" def sharpen(self, image: torch.Tensor, kernel_size: int, alpha: float): - tensor_image = image.numpy()[0] + batch_size, height, width, _ = image.shape + result = torch.zeros_like(image) - kernel = np.ones((kernel_size, kernel_size), dtype=np.float32) * -1 - center = kernel_size // 2 - kernel[center, center] = kernel_size**2 - kernel *= alpha + for b in range(batch_size): + tensor_image = image[b].numpy() - sharpened = cv2.filter2D(tensor_image, -1, kernel) + kernel = np.ones((kernel_size, kernel_size), dtype=np.float32) * -1 + center = kernel_size // 2 + kernel[center, center] = kernel_size**2 + kernel *= alpha - tensor = torch.from_numpy(sharpened).unsqueeze(0) - tensor = torch.clamp(tensor, 0, 1) - return (tensor,) + sharpened = cv2.filter2D(tensor_image, -1, kernel) + + tensor = torch.from_numpy(sharpened).unsqueeze(0) + tensor = torch.clamp(tensor, 0, 1) + result[b] = tensor + + return (result,) class CannyEdgeDetection: def __init__(self): @@ -212,11 +236,17 @@ class CannyEdgeDetection: CATEGORY = "postprocessing" def canny(self, image: torch.Tensor, lower_threshold: int, upper_threshold: int): - tensor_image = image.numpy()[0] - gray_image = (cv2.cvtColor(tensor_image, cv2.COLOR_BGR2GRAY) * 255).astype(np.uint8) - canny = cv2.Canny(gray_image, lower_threshold, upper_threshold) - tensor = torch.from_numpy(canny).unsqueeze(0) - return (tensor,) + batch_size, height, width, _ = image.shape + result = torch.zeros(batch_size, height, width) + + for b in range(batch_size): + tensor_image = image[b].numpy().copy() + gray_image = (cv2.cvtColor(tensor_image, cv2.COLOR_RGB2GRAY) * 255).astype(np.uint8) + canny = cv2.Canny(gray_image, lower_threshold, upper_threshold) + tensor = torch.from_numpy(canny) + result[b] = tensor + + return (result,) class ColorCorrect: def __init__(self): @@ -272,52 +302,57 @@ class ColorCorrect: CATEGORY = "postprocessing" def color_correct(self, image: torch.Tensor, temperature: float, hue: float, brightness: float, contrast: float, saturation: float, gamma: float): - tensor_image = image.numpy()[0] + batch_size, height, width, _ = image.shape + result = torch.zeros_like(image) - brightness /= 100 - contrast /= 100 - saturation /= 100 - temperature /= 100 + for b in range(batch_size): + tensor_image = image[b].numpy() - brightness = 1 + brightness - contrast = 1 + contrast - saturation = 1 + saturation + brightness /= 100 + contrast /= 100 + saturation /= 100 + temperature /= 100 - modified_image = Image.fromarray((tensor_image * 255).astype(np.uint8)) + brightness = 1 + brightness + contrast = 1 + contrast + saturation = 1 + saturation - # brightness - modified_image = ImageEnhance.Brightness(modified_image).enhance(brightness) + modified_image = Image.fromarray((tensor_image * 255).astype(np.uint8)) - # contrast - modified_image = ImageEnhance.Contrast(modified_image).enhance(contrast) - modified_image = np.array(modified_image).astype(np.float32) + # brightness + modified_image = ImageEnhance.Brightness(modified_image).enhance(brightness) - # temperature - if temperature > 0: - modified_image[:, :, 0] *= 1 + temperature - modified_image[:, :, 1] *= 1 + temperature * 0.4 - elif temperature < 0: - modified_image[:, :, 2] *= 1 - temperature - modified_image = np.clip(modified_image, 0, 255)/255 + # contrast + modified_image = ImageEnhance.Contrast(modified_image).enhance(contrast) + modified_image = np.array(modified_image).astype(np.float32) - # gamma - modified_image = np.clip(np.power(modified_image, gamma), 0, 1) + # temperature + if temperature > 0: + modified_image[:, :, 0] *= 1 + temperature + modified_image[:, :, 1] *= 1 + temperature * 0.4 + elif temperature < 0: + modified_image[:, :, 2] *= 1 - temperature + modified_image = np.clip(modified_image, 0, 255)/255 - # saturation - hls_img = cv2.cvtColor(modified_image, cv2.COLOR_RGB2HLS) - hls_img[:, :, 2] = np.clip(saturation*hls_img[:, :, 2], 0, 1) - modified_image = cv2.cvtColor(hls_img, cv2.COLOR_HLS2RGB) * 255 + # gamma + modified_image = np.clip(np.power(modified_image, gamma), 0, 1) - # hue - hsv_img = cv2.cvtColor(modified_image, cv2.COLOR_RGB2HSV) - hsv_img[:, :, 0] = (hsv_img[:, :, 0] + hue) % 360 - modified_image = cv2.cvtColor(hsv_img, cv2.COLOR_HSV2RGB) + # saturation + hls_img = cv2.cvtColor(modified_image, cv2.COLOR_RGB2HLS) + hls_img[:, :, 2] = np.clip(saturation*hls_img[:, :, 2], 0, 1) + modified_image = cv2.cvtColor(hls_img, cv2.COLOR_HLS2RGB) * 255 - modified_image = modified_image.astype(np.uint8) - modified_image = modified_image / 255 - modified_image = torch.from_numpy(modified_image).unsqueeze(0) + # hue + hsv_img = cv2.cvtColor(modified_image, cv2.COLOR_RGB2HSV) + hsv_img[:, :, 0] = (hsv_img[:, :, 0] + hue) % 360 + modified_image = cv2.cvtColor(hsv_img, cv2.COLOR_HSV2RGB) - return (modified_image, ) + modified_image = modified_image.astype(np.uint8) + modified_image = modified_image / 255 + modified_image = torch.from_numpy(modified_image).unsqueeze(0) + result[b] = modified_image + + return (result, ) NODE_CLASS_MAPPINGS = {