sd-webui-deforum/scripts/deforum_helpers/hybrid_video.py

import cv2
import os
import pathlib
import numpy as np
import random
from PIL import Image, ImageChops, ImageOps, ImageEnhance
from .video_audio_utilities import vid2frames, get_quick_vid_info, get_frame_name, get_next_frame
from .human_masking import video2humanmasks

def delete_all_imgs_in_folder(folder_path):
        files = list(pathlib.Path(folder_path).glob('*.jpg'))
        files.extend(list(pathlib.Path(folder_path).glob('*.png')))
        for f in files: os.remove(f)

def hybrid_generation(args, anim_args, root):
    video_in_frame_path = os.path.join(args.outdir, 'inputframes')
    hybrid_frame_path = os.path.join(args.outdir, 'hybridframes')
    human_masks_path = os.path.join(args.outdir, 'human_masks')

    if anim_args.hybrid_generate_inputframes:
        # create folders for the video input frames and optional hybrid frames to live in
        os.makedirs(video_in_frame_path, exist_ok=True)
        os.makedirs(hybrid_frame_path, exist_ok=True)
        
        # delete frames if overwrite = true
        if anim_args.overwrite_extracted_frames:
            delete_all_imgs_in_folder(hybrid_frame_path)

        # save the video frames from input video
        print(f"Video to extract: {anim_args.video_init_path}")
        print(f"Extracting video (1 every {anim_args.extract_nth_frame}) frames to {video_in_frame_path}...")
        video_fps = vid2frames(video_path=anim_args.video_init_path, video_in_frame_path=video_in_frame_path, n=anim_args.extract_nth_frame, overwrite=anim_args.overwrite_extracted_frames, extract_from_frame=anim_args.extract_from_frame, extract_to_frame=anim_args.extract_to_frame)
    
    # extract alpha masks of humans from the extracted input video imgs
    if anim_args.hybrid_generate_human_masks != "None":
        # create a folder for the human masks imgs to live in
        print(f"Checking /creating a folder for the human masks")
        os.makedirs(human_masks_path, exist_ok=True)
            
        # delete frames if overwrite = true
        if anim_args.overwrite_extracted_frames:
            delete_all_imgs_in_folder(human_masks_path)
        
        # in case that generate_input_frames isn't selected, we won't get the video fps rate as vid2frames isn't called, So we'll check the video fps in here instead
        if not anim_args.hybrid_generate_inputframes:
            _, video_fps, _ = get_quick_vid_info(anim_args.video_init_path)
            
        # calculate the correct fps of the masked video according to the original video fps and 'extract_nth_frame'
        output_fps = video_fps/anim_args.extract_nth_frame
        
        # generate the actual alpha masks from the input imgs
        print(f"Extracting alpha humans masks from the input frames")
        video2humanmasks(video_in_frame_path, human_masks_path, anim_args.hybrid_generate_human_masks, output_fps)
        
    # determine max frames from length of input frames
    anim_args.max_frames = len([f for f in pathlib.Path(video_in_frame_path).glob('*.jpg')])
    print(f"Using {anim_args.max_frames} input frames from {video_in_frame_path}...")

    # get sorted list of inputfiles
    inputfiles = sorted(pathlib.Path(video_in_frame_path).glob('*.jpg'))

    # use first frame as init
    if anim_args.hybrid_use_first_frame_as_init_image:
        for f in inputfiles:
            args.init_image = str(f)
            args.use_init = True
            print(f"Using init_image from video: {args.init_image}")
            break

    return args, anim_args, inputfiles

def hybrid_composite(args, anim_args, frame_idx, prev_img, depth_model, hybrid_comp_schedules, root):
    video_frame = os.path.join(args.outdir, 'inputframes', get_frame_name(anim_args.video_init_path) + f"{frame_idx:05}.jpg")
    video_depth_frame = os.path.join(args.outdir, 'hybridframes', get_frame_name(anim_args.video_init_path) + f"_vid_depth{frame_idx:05}.jpg")
    depth_frame = os.path.join(args.outdir, f"{args.timestring}_depth_{frame_idx-1:05}.png")
    mask_frame = os.path.join(args.outdir, 'hybridframes', get_frame_name(anim_args.video_init_path) + f"_mask{frame_idx:05}.jpg")
    comp_frame = os.path.join(args.outdir, 'hybridframes', get_frame_name(anim_args.video_init_path) + f"_comp{frame_idx:05}.jpg")
    prev_frame = os.path.join(args.outdir, 'hybridframes', get_frame_name(anim_args.video_init_path) + f"_prev{frame_idx:05}.jpg")
    prev_img = cv2.cvtColor(prev_img, cv2.COLOR_BGR2RGB)
    prev_img_hybrid = Image.fromarray(prev_img)
    video_image = Image.open(video_frame)
    video_image = video_image.resize((args.W, args.H), Image.Resampling.LANCZOS)
    hybrid_mask = None

    # composite mask types
    if anim_args.hybrid_comp_mask_type == 'Depth': # get depth from last generation
        hybrid_mask = Image.open(depth_frame)
    elif anim_args.hybrid_comp_mask_type == 'Video Depth': # get video depth
        video_depth = depth_model.predict(np.array(video_image), anim_args.midas_weight, root.half_precision)
        depth_model.save(video_depth_frame, video_depth)
        hybrid_mask = Image.open(video_depth_frame)
    elif anim_args.hybrid_comp_mask_type == 'Blend': # create blend mask image
        hybrid_mask = Image.blend(ImageOps.grayscale(prev_img_hybrid), ImageOps.grayscale(video_image), hybrid_comp_schedules['mask_blend_alpha'])
    elif anim_args.hybrid_comp_mask_type == 'Difference': # create difference mask image
        hybrid_mask = ImageChops.difference(ImageOps.grayscale(prev_img_hybrid), ImageOps.grayscale(video_image))
        
    # optionally invert mask, if mask type is defined
    if anim_args.hybrid_comp_mask_inverse and anim_args.hybrid_comp_mask_type != "None":
        hybrid_mask = ImageOps.invert(hybrid_mask)

    # if a mask type is selected, make composition
    if hybrid_mask == None:
        hybrid_comp = video_image
    else:
        # ensure grayscale
        hybrid_mask = ImageOps.grayscale(hybrid_mask)
        # equalization before
        if anim_args.hybrid_comp_mask_equalize in ['Before', 'Both']:
            hybrid_mask = ImageOps.equalize(hybrid_mask)        
        # contrast
        hybrid_mask = ImageEnhance.Contrast(hybrid_mask).enhance(hybrid_comp_schedules['mask_contrast'])
        # auto contrast with cutoffs lo/hi
        if anim_args.hybrid_comp_mask_auto_contrast:
            hybrid_mask = autocontrast_grayscale(np.array(hybrid_mask), hybrid_comp_schedules['mask_auto_contrast_cutoff_low'], hybrid_comp_schedules['mask_auto_contrast_cutoff_high'])
            hybrid_mask = Image.fromarray(hybrid_mask)
            hybrid_mask = ImageOps.grayscale(hybrid_mask)   
        if anim_args.hybrid_comp_save_extra_frames:
            hybrid_mask.save(mask_frame)        
        # equalization after
        if anim_args.hybrid_comp_mask_equalize in ['After', 'Both']:
            hybrid_mask = ImageOps.equalize(hybrid_mask)        
        # do compositing and save
        hybrid_comp = Image.composite(prev_img_hybrid, video_image, hybrid_mask)            
        if anim_args.hybrid_comp_save_extra_frames:
            hybrid_comp.save(comp_frame)

    # final blend of composite with prev_img, or just a blend if no composite is selected
    hybrid_blend = Image.blend(prev_img_hybrid, hybrid_comp, hybrid_comp_schedules['alpha'])  
    if anim_args.hybrid_comp_save_extra_frames:
        hybrid_blend.save(prev_frame)

    prev_img = cv2.cvtColor(np.array(hybrid_blend), cv2.COLOR_RGB2BGR)

    # restore to np array and return
    return args, prev_img

def get_matrix_for_hybrid_motion(frame_idx, dimensions, inputfiles, hybrid_motion):
    img1 = cv2.cvtColor(get_resized_image_from_filename(str(inputfiles[frame_idx-1]), dimensions), cv2.COLOR_BGR2GRAY)
    img2 = cv2.cvtColor(get_resized_image_from_filename(str(inputfiles[frame_idx]), dimensions), cv2.COLOR_BGR2GRAY)
    matrix = get_transformation_matrix_from_images(img1, img2, hybrid_motion)
    print(f"Calculating {hybrid_motion} RANSAC matrix for frames {frame_idx} to {frame_idx+1}")
    return matrix

def get_matrix_for_hybrid_motion_prev(frame_idx, dimensions, inputfiles, prev_img, hybrid_motion):
    # first handle invalid images from cadence by returning default matrix
    height, width = prev_img.shape[:2]
    if height == 0 or width == 0 or prev_img != np.uint8:
        return get_hybrid_motion_default_matrix(hybrid_motion)
    else:
        prev_img_gray = cv2.cvtColor(prev_img, cv2.COLOR_BGR2GRAY)
        img = cv2.cvtColor(get_resized_image_from_filename(str(inputfiles[frame_idx]), dimensions), cv2.COLOR_BGR2GRAY)
        matrix = get_transformation_matrix_from_images(prev_img_gray, img, hybrid_motion)
        print(f"Calculating {hybrid_motion} RANSAC matrix for frames {frame_idx} to {frame_idx+1}")
        return matrix

def get_flow_for_hybrid_motion(frame_idx, dimensions, inputfiles, hybrid_frame_path, method, do_flow_visualization=False):
    print(f"Calculating {method} optical flow for frames {frame_idx} to {frame_idx+1}")
    i1 = get_resized_image_from_filename(str(inputfiles[frame_idx]), dimensions)
    i2 = get_resized_image_from_filename(str(inputfiles[frame_idx+1]), dimensions)
    flow = get_flow_from_images(i1, i2, method)
    if do_flow_visualization:
        save_flow_visualization(frame_idx, dimensions, flow, inputfiles, hybrid_frame_path)
    return flow

def get_flow_for_hybrid_motion_prev(frame_idx, dimensions, inputfiles, hybrid_frame_path, prev_img, method, do_flow_visualization=False):
    print(f"Calculating {method} optical flow for frames {frame_idx} to {frame_idx+1}")
    # first handle invalid images from cadence by returning default matrix
    height, width = prev_img.shape[:2]   
    if height == 0 or width == 0:
        flow = get_hybrid_motion_default_flow(dimensions)
    else:
        i1 = prev_img.astype(np.uint8)
        i2 = get_resized_image_from_filename(str(inputfiles[frame_idx]), dimensions)
        flow = get_flow_from_images(i1, i2, method)
    if do_flow_visualization:
        save_flow_visualization(frame_idx, dimensions, flow, inputfiles, hybrid_frame_path)
    return flow

def image_transform_ransac(image_cv2, xform, hybrid_motion, border_mode=cv2.BORDER_REPLICATE):
    if hybrid_motion == "Perspective":
        return image_transform_perspective(image_cv2, xform, border_mode=border_mode)
    else: # Affine
        return image_transform_affine(image_cv2, xform, border_mode=border_mode)

def image_transform_optical_flow(img, flow, border_mode=cv2.BORDER_REPLICATE, flow_reverse=False):
    if not flow_reverse:
        flow = -flow
    h, w = img.shape[:2]
    flow[:, :, 0] += np.arange(w)
    flow[:, :, 1] += np.arange(h)[:,np.newaxis]
    return remap(img, flow, border_mode)

def image_transform_affine(image_cv2, xform, border_mode=cv2.BORDER_REPLICATE):
    return cv2.warpAffine(
        image_cv2,
        xform,
        (image_cv2.shape[1],image_cv2.shape[0]),
        borderMode=border_mode
    )

def image_transform_perspective(image_cv2, xform, border_mode=cv2.BORDER_REPLICATE):
    return cv2.warpPerspective(
        image_cv2,
        xform,
        (image_cv2.shape[1], image_cv2.shape[0]),
        borderMode=border_mode
    )

def get_hybrid_motion_default_matrix(hybrid_motion):
    if hybrid_motion == "Perspective":
        arr = np.array([[1., 0., 0.], [0., 1., 0.], [0., 0., 1.]])
    else:
        arr = np.array([[1., 0., 0.], [0., 1., 0.]])
    return arr

def get_hybrid_motion_default_flow(dimensions):
    cols, rows = dimensions
    flow = np.zeros((rows, cols, 2), np.float32)
    return flow

def get_transformation_matrix_from_images(img1, img2, hybrid_motion, max_corners=200, quality_level=0.01, min_distance=30, block_size=3):
    # Detect feature points in previous frame
    prev_pts = cv2.goodFeaturesToTrack(img1,
                                        maxCorners=max_corners,
                                        qualityLevel=quality_level,
                                        minDistance=min_distance,
                                        blockSize=block_size)

    if prev_pts is None or len(prev_pts) < 8 or img1 is None or img2 is None:
        return get_hybrid_motion_default_matrix(hybrid_motion)

    # Get optical flow
    curr_pts, status, err = cv2.calcOpticalFlowPyrLK(img1, img2, prev_pts, None) 
   
    # Filter only valid points
    idx = np.where(status==1)[0]
    prev_pts = prev_pts[idx]
    curr_pts = curr_pts[idx]

    if len(prev_pts) < 8 or len(curr_pts) < 8:
        return get_hybrid_motion_default_matrix(hybrid_motion)
    
    if hybrid_motion == "Perspective":  # Perspective - Find the transformation between points
        transformation_matrix, mask = cv2.findHomography(prev_pts, curr_pts, cv2.RANSAC, 5.0)
        return transformation_matrix
    else: # Affine - Compute a rigid transformation (without depth, only scale + rotation + translation)
        transformation_rigid_matrix, rigid_mask = cv2.estimateAffinePartial2D(prev_pts, curr_pts)
        return transformation_rigid_matrix

def get_flow_from_images(i1, i2, method):
    if method =="DIS Medium":
        r = get_flow_from_images_DIS(i1, i2, cv2.DISOPTICAL_FLOW_PRESET_MEDIUM)
    elif method =="DIS Fast":
        r = get_flow_from_images_DIS(i1, i2, cv2.DISOPTICAL_FLOW_PRESET_FAST)
    elif method =="DIS UltraFast":
        r = get_flow_from_images_DIS(i1, i2, cv2.DISOPTICAL_FLOW_PRESET_ULTRAFAST)
    elif method == "DenseRLOF": # requires running opencv-contrib-python (full opencv) INSTEAD of opencv-python
        r = get_flow_from_images_Dense_RLOF(i1, i2)
    elif method == "SF": # requires running opencv-contrib-python (full opencv) INSTEAD of opencv-python
        r = get_flow_from_images_SF(i1, i2)
    elif method =="Farneback Fine":
        r = get_flow_from_images_Farneback(i1, i2, 'fine')
    else: # Farneback Normal:
        r = get_flow_from_images_Farneback(i1, i2)
    return r

def get_flow_from_images_DIS(i1, i2, preset):
    i1 = cv2.cvtColor(i1, cv2.COLOR_BGR2GRAY)
    i2 = cv2.cvtColor(i2, cv2.COLOR_BGR2GRAY)
    dis=cv2.DISOpticalFlow_create(preset)
    return dis.calc(i1, i2, None)

def get_flow_from_images_Dense_RLOF(i1, i2, last_flow=None):
    return cv2.optflow.calcOpticalFlowDenseRLOF(i1, i2, flow = last_flow)

def get_flow_from_images_SF(i1, i2, last_flow=None, layers = 3, averaging_block_size = 2, max_flow = 4):
    return cv2.optflow.calcOpticalFlowSF(i1, i2, layers, averaging_block_size, max_flow)

def get_flow_from_images_Farneback(i1, i2, preset="normal", last_flow=None, pyr_scale = 0.5, levels = 3, winsize = 15, iterations = 3, poly_n = 5, poly_sigma = 1.2, flags = 0):
    flags = cv2.OPTFLOW_FARNEBACK_GAUSSIAN         # Specify the operation flags
    pyr_scale = 0.5   # The image scale (<1) to build pyramids for each image
    if preset == "fine":
        levels = 13       # The number of pyramid layers, including the initial image
        winsize = 77      # The averaging window size
        iterations = 13   # The number of iterations at each pyramid level
        poly_n = 15       # The size of the pixel neighborhood used to find polynomial expansion in each pixel
        poly_sigma = 0.8  # The standard deviation of the Gaussian used to smooth derivatives used as a basis for the polynomial expansion
    else: # "normal"
        levels = 5        # The number of pyramid layers, including the initial image
        winsize = 21      # The averaging window size
        iterations = 5    # The number of iterations at each pyramid level
        poly_n = 7        # The size of the pixel neighborhood used to find polynomial expansion in each pixel
        poly_sigma = 1.2  # The standard deviation of the Gaussian used to smooth derivatives used as a basis for the polynomial expansion
    i1 = cv2.cvtColor(i1, cv2.COLOR_BGR2GRAY)
    i2 = cv2.cvtColor(i2, cv2.COLOR_BGR2GRAY)
    flags = 0 # flags = cv2.OPTFLOW_USE_INITIAL_FLOW    
    flow = cv2.calcOpticalFlowFarneback(i1, i2, last_flow, pyr_scale, levels, winsize, iterations, poly_n, poly_sigma, flags)
    return flow

def save_flow_visualization(frame_idx, dimensions, flow, inputfiles, hybrid_frame_path):
    flow_img_file = os.path.join(hybrid_frame_path, f"flow{frame_idx:05}.jpg")
    flow_img = cv2.imread(str(inputfiles[frame_idx]))
    flow_img = cv2.resize(flow_img, (dimensions[0], dimensions[1]), cv2.INTER_AREA)
    flow_img = cv2.cvtColor(flow_img, cv2.COLOR_RGB2GRAY)
    flow_img = cv2.cvtColor(flow_img, cv2.COLOR_GRAY2BGR)
    flow_img = draw_flow_lines_in_grid_in_color(flow_img, flow)
    flow_img = cv2.cvtColor(flow_img, cv2.COLOR_BGR2RGB)
    cv2.imwrite(flow_img_file, flow_img)
    print(f"Saved optical flow visualization: {flow_img_file}")

def draw_flow_lines_in_grid_in_color(img, flow, step=8, magnitude_multiplier=1, min_magnitude = 1, max_magnitude = 10000):
    flow = flow * magnitude_multiplier
    h, w = img.shape[:2]
    y, x = np.mgrid[step/2:h:step, step/2:w:step].reshape(2,-1).astype(int)
    fx, fy = flow[y,x].T
    lines = np.vstack([x, y, x+fx, y+fy]).T.reshape(-1, 2, 2)
    lines = np.int32(lines + 0.5)
    vis = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
    vis = cv2.cvtColor(vis, cv2.COLOR_GRAY2BGR)

    mag, ang = cv2.cartToPolar(flow[...,0], flow[...,1])
    hsv = np.zeros((flow.shape[0], flow.shape[1], 3), dtype=np.uint8)
    hsv[...,0] = ang*180/np.pi/2
    hsv[...,1] = 255
    hsv[...,2] = cv2.normalize(mag, None, 0, 255, cv2.NORM_MINMAX)
    bgr = cv2.cvtColor(hsv, cv2.COLOR_HSV2BGR)
    vis = cv2.add(vis, bgr)

    # Iterate through the lines
    for (x1, y1), (x2, y2) in lines:
        # Calculate the magnitude of the line
        magnitude = np.sqrt((x2 - x1)**2 + (y2 - y1)**2)

        # Only draw the line if it falls within the magnitude range
        if min_magnitude <= magnitude <= max_magnitude:
            b = int(bgr[y1, x1, 0])
            g = int(bgr[y1, x1, 1])
            r = int(bgr[y1, x1, 2])
            color = (b, g, r)
            cv2.arrowedLine(vis, (x1, y1), (x2, y2), color, thickness=1, tipLength=0.1)    
    return vis

def draw_flow_lines_in_color(img, flow, threshold=3, magnitude_multiplier=1, min_magnitude = 0, max_magnitude = 10000):
    # h, w = img.shape[:2]
    vis = img.copy()  # Create a copy of the input image
    
    # Find the locations in the flow field where the magnitude of the flow is greater than the threshold
    mag, ang = cv2.cartToPolar(flow[...,0], flow[...,1])
    idx = np.where(mag > threshold)

    # Create HSV image
    hsv = np.zeros((flow.shape[0], flow.shape[1], 3), dtype=np.uint8)
    hsv[...,0] = ang*180/np.pi/2
    hsv[...,1] = 255
    hsv[...,2] = cv2.normalize(mag, None, 0, 255, cv2.NORM_MINMAX)

    # Convert HSV image to BGR
    bgr = cv2.cvtColor(hsv, cv2.COLOR_HSV2BGR)

    # Add color from bgr 
    vis = cv2.add(vis, bgr)

    # Draw an arrow at each of these locations to indicate the direction of the flow
    for i, (y, x) in enumerate(zip(idx[0], idx[1])):
        # Calculate the magnitude of the line
        x2 = x + magnitude_multiplier * int(flow[y, x, 0])
        y2 = y + magnitude_multiplier * int(flow[y, x, 1])
        magnitude = np.sqrt((x2 - x)**2 + (y2 - y)**2)

        # Only draw the line if it falls within the magnitude range
        if min_magnitude <= magnitude <= max_magnitude:
            if i % random.randint(100, 200) == 0:
                b = int(bgr[y, x, 0])
                g = int(bgr[y, x, 1])
                r = int(bgr[y, x, 2])
                color = (b, g, r)
                cv2.arrowedLine(vis, (x, y), (x2, y2), color, thickness=1, tipLength=0.25)

    return vis

def autocontrast_grayscale(image, low_cutoff=0, high_cutoff=100):
    # Perform autocontrast on a grayscale np array image.
    # Find the minimum and maximum values in the image
    min_val = np.percentile(image, low_cutoff)
    max_val = np.percentile(image, high_cutoff)

    # Scale the image so that the minimum value is 0 and the maximum value is 255
    image = 255 * (image - min_val) / (max_val - min_val)

    # Clip values that fall outside the range [0, 255]
    image = np.clip(image, 0, 255)

    return image

def get_resized_image_from_filename(im, dimensions):
    img = cv2.imread(im)
    return cv2.resize(img, (dimensions[0], dimensions[1]), cv2.INTER_AREA)

def remap(img, flow, border_mode = cv2.BORDER_REFLECT_101):
    # copyMakeBorder doesn't support wrap, but supports replicate. Replaces wrap with reflect101.
    if border_mode == cv2.BORDER_WRAP:
        border_mode = cv2.BORDER_REFLECT_101
    h, w = img.shape[:2]
    displacement = int(h * 0.25), int(w * 0.25)
    larger_img = cv2.copyMakeBorder(img, displacement[0], displacement[0], displacement[1], displacement[1], border_mode)
    lh, lw = larger_img.shape[:2]
    larger_flow = extend_flow(flow, lw, lh)
    remapped_img = cv2.remap(larger_img, larger_flow, None, cv2.INTER_LINEAR, border_mode)
    output_img = center_crop_image(remapped_img, w, h)
    return output_img

def center_crop_image(img, w, h):
    y, x, _ = img.shape
    width_indent = int((x - w) / 2)
    height_indent = int((y - h) / 2)
    cropped_img = img[height_indent:y-height_indent, width_indent:x-width_indent]
    return cropped_img

def extend_flow(flow, w, h):
    # Get the shape of the original flow image
    flow_h, flow_w = flow.shape[:2]
    # Calculate the position of the image in the new image
    x_offset = int((w - flow_w) / 2)
    y_offset = int((h - flow_h) / 2)
    # Generate the X and Y grids
    x_grid, y_grid = np.meshgrid(np.arange(w), np.arange(h))
    # Create the new flow image and set it to the X and Y grids
    new_flow = np.dstack((x_grid, y_grid)).astype(np.float32)
    # Shift the values of the original flow by the size of the border
    flow[:,:,0] += x_offset
    flow[:,:,1] += y_offset
    # Overwrite the middle of the grid with the original flow
    new_flow[y_offset:y_offset+flow_h, x_offset:x_offset+flow_w, :] = flow
    # Return the extended image
    return new_flow