DeepFaceLab/converters/ConvertMasked.py

import traceback

import cv2
import numpy as np

import imagelib
from facelib import FaceType, LandmarksProcessor
from interact import interact as io
from utils.cv2_utils import *


def ConvertMaskedFace (predictor_func, predictor_input_shape, cfg, frame_info, img_bgr_uint8, img_bgr, img_face_landmarks):

    #if debug:
    #    debugs = [img_bgr.copy()]

    img_size = img_bgr.shape[1], img_bgr.shape[0]

    img_face_mask_a = LandmarksProcessor.get_image_hull_mask (img_bgr.shape, img_face_landmarks)

    if cfg.mode == 'original':
        if cfg.export_mask_alpha:
            img_bgr = np.concatenate ( [img_bgr, img_face_mask_a], -1 )
        return img_bgr, img_face_mask_a

    out_img = img_bgr.copy()
    out_merging_mask = None

    output_size = predictor_input_shape[0]
    if cfg.super_resolution_mode != 0:
        output_size *= 2

    face_mat = LandmarksProcessor.get_transform_mat (img_face_landmarks, output_size, face_type=cfg.face_type)
    face_output_mat = LandmarksProcessor.get_transform_mat (img_face_landmarks, output_size, face_type=cfg.face_type, scale= 1.0 + 0.01*cfg.output_face_scale   )

    dst_face_bgr      = cv2.warpAffine( img_bgr        , face_mat, (output_size, output_size), flags=cv2.INTER_CUBIC )
    dst_face_mask_a_0 = cv2.warpAffine( img_face_mask_a, face_mat, (output_size, output_size), flags=cv2.INTER_CUBIC )

    predictor_input_bgr      = cv2.resize (dst_face_bgr, predictor_input_shape[0:2] )

    predicted = predictor_func (predictor_input_bgr)
    if isinstance(predicted, tuple):
        #converter return bgr,mask
        prd_face_bgr      = np.clip (predicted[0], 0, 1.0)
        prd_face_mask_a_0 = np.clip (predicted[1], 0, 1.0)
        predictor_masked = True
    else:
        #converter return bgr only, using dst mask
        prd_face_bgr      = np.clip (predicted, 0, 1.0 )
        prd_face_mask_a_0 = cv2.resize (dst_face_mask_a_0, predictor_input_shape[0:2] )
        predictor_masked = False

    if cfg.super_resolution_mode:
        #if debug:
        #    tmp = cv2.resize (prd_face_bgr,  (output_size,output_size), cv2.INTER_CUBIC)
        #    debugs += [ np.clip( cv2.warpAffine( tmp, face_output_mat, img_size, img_bgr.copy(), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]

        prd_face_bgr = cfg.superres_func(cfg.super_resolution_mode, prd_face_bgr)
        #if debug:
        #    debugs += [ np.clip( cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, img_bgr.copy(), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]

        if predictor_masked:
            prd_face_mask_a_0 = cv2.resize (prd_face_mask_a_0,  (output_size, output_size), cv2.INTER_CUBIC)
        else:
            prd_face_mask_a_0 = cv2.resize (dst_face_mask_a_0,  (output_size, output_size), cv2.INTER_CUBIC)

    if cfg.mask_mode == 2: #dst
        prd_face_mask_a_0 = cv2.resize (dst_face_mask_a_0, (output_size,output_size), cv2.INTER_CUBIC)
    elif cfg.mask_mode >= 3 and cfg.mask_mode <= 7:

        if cfg.mask_mode == 3 or cfg.mask_mode == 5 or cfg.mask_mode == 6:
            prd_face_fanseg_bgr = cv2.resize (prd_face_bgr, (cfg.fanseg_input_size,)*2 )
            prd_face_fanseg_mask = cfg.fanseg_extract_func(FaceType.FULL, prd_face_fanseg_bgr)
            FAN_prd_face_mask_a_0 = cv2.resize ( prd_face_fanseg_mask, (output_size, output_size), cv2.INTER_CUBIC)

        if cfg.mask_mode >= 4 or cfg.mask_mode <= 7:

            full_face_fanseg_mat = LandmarksProcessor.get_transform_mat (img_face_landmarks, cfg.fanseg_input_size, face_type=FaceType.FULL)
            dst_face_fanseg_bgr = cv2.warpAffine(img_bgr, full_face_fanseg_mat, (cfg.fanseg_input_size,)*2, flags=cv2.INTER_CUBIC )
            dst_face_fanseg_mask = cfg.fanseg_extract_func( FaceType.FULL, dst_face_fanseg_bgr )

            if cfg.face_type == FaceType.FULL:
                FAN_dst_face_mask_a_0 = cv2.resize (dst_face_fanseg_mask, (output_size,output_size), cv2.INTER_CUBIC)
            elif cfg.face_type == FaceType.HALF:
                half_face_fanseg_mat = LandmarksProcessor.get_transform_mat (img_face_landmarks, cfg.fanseg_input_size, face_type=FaceType.HALF)

                fanseg_rect_corner_pts = np.array ( [ [0,0], [cfg.fanseg_input_size-1,0], [0,cfg.fanseg_input_size-1] ], dtype=np.float32 )
                a = LandmarksProcessor.transform_points (fanseg_rect_corner_pts, half_face_fanseg_mat, invert=True )
                b = LandmarksProcessor.transform_points (a, full_face_fanseg_mat )
                m = cv2.getAffineTransform(b, fanseg_rect_corner_pts)
                FAN_dst_face_mask_a_0 = cv2.warpAffine(dst_face_fanseg_mask, m, (cfg.fanseg_input_size,)*2, flags=cv2.INTER_CUBIC )
                FAN_dst_face_mask_a_0 = cv2.resize (FAN_dst_face_mask_a_0, (output_size,output_size), cv2.INTER_CUBIC)
            else:
                raise ValueError ("cfg.face_type unsupported")

        if cfg.mask_mode == 3:   #FAN-prd
            prd_face_mask_a_0 = FAN_prd_face_mask_a_0
        elif cfg.mask_mode == 4: #FAN-dst
            prd_face_mask_a_0 = FAN_dst_face_mask_a_0
        elif cfg.mask_mode == 5:
            prd_face_mask_a_0 = FAN_prd_face_mask_a_0 * FAN_dst_face_mask_a_0
        elif cfg.mask_mode == 6:
            prd_face_mask_a_0 = prd_face_mask_a_0 * FAN_prd_face_mask_a_0 * FAN_dst_face_mask_a_0
        elif cfg.mask_mode == 7:
            prd_face_mask_a_0 = prd_face_mask_a_0 * FAN_dst_face_mask_a_0

    prd_face_mask_a_0[ prd_face_mask_a_0 < 0.001 ] = 0.0

    prd_face_mask_a   = prd_face_mask_a_0[...,np.newaxis]
    prd_face_mask_aaa = np.repeat (prd_face_mask_a, (3,), axis=-1)

    img_face_mask_aaa = cv2.warpAffine( prd_face_mask_aaa, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), flags=cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC )
    img_face_mask_aaa = np.clip (img_face_mask_aaa, 0.0, 1.0)
    img_face_mask_aaa [ img_face_mask_aaa <= 0.1 ] = 0.0 #get rid of noise

    #if debug:
    #    debugs += [img_face_mask_aaa.copy()]

    if 'raw' in cfg.mode:
        face_corner_pts = np.array ([ [0,0], [output_size-1,0], [output_size-1,output_size-1],  [0,output_size-1] ], dtype=np.float32)
        square_mask = np.zeros(img_bgr.shape, dtype=np.float32)
        cv2.fillConvexPoly(square_mask, \
                           LandmarksProcessor.transform_points (face_corner_pts, face_output_mat, invert=True ).astype(np.int), \
                           (1,1,1) )

        if cfg.mode == 'raw-rgb':
            out_merging_mask = square_mask

        if cfg.mode == 'raw-rgb' or cfg.mode == 'raw-rgb-mask':
            out_img = cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, out_img, cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT )

        if cfg.mode == 'raw-rgb-mask':
            out_img = np.concatenate ( [out_img, np.expand_dims (img_face_mask_aaa[:,:,0],-1)], -1 )
            out_merging_mask = square_mask

        elif cfg.mode == 'raw-mask-only':
            out_img = img_face_mask_aaa
            out_merging_mask = img_face_mask_aaa
        elif cfg.mode == 'raw-predicted-only':
            out_img = cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT )
            out_merging_mask = square_mask

        out_img = np.clip (out_img, 0.0, 1.0 )
    else:
        #averaging [lenx, leny, maskx, masky] by grayscale gradients of upscaled mask
        ar = []
        for i in range(1, 10):
            maxregion = np.argwhere( img_face_mask_aaa > i / 10.0 )
            if maxregion.size != 0:
                miny,minx = maxregion.min(axis=0)[:2]
                maxy,maxx = maxregion.max(axis=0)[:2]
                lenx = maxx - minx
                leny = maxy - miny
                if min(lenx,leny) >= 4:
                    ar += [ [ lenx, leny]  ]

        if len(ar) > 0:
            lenx, leny = np.mean ( ar, axis=0 )
            lowest_len = min (lenx, leny)
            #if debug:
            #    io.log_info ("lenx/leny:(%d/%d) " % (lenx, leny  ) )
            #    io.log_info ("lowest_len = %f" % (lowest_len) )

            if cfg.erode_mask_modifier != 0:
                ero  = int( lowest_len * ( 0.126 - lowest_len * 0.00004551365 ) * 0.01*cfg.erode_mask_modifier )
                #if debug:
                #    io.log_info ("erode_size = %d" % (ero) )
                if ero > 0:
                    img_face_mask_aaa = cv2.erode(img_face_mask_aaa, cv2.getStructuringElement(cv2.MORPH_ELLIPSE,(ero,ero)), iterations = 1 )
                elif ero < 0:
                    img_face_mask_aaa = cv2.dilate(img_face_mask_aaa, cv2.getStructuringElement(cv2.MORPH_ELLIPSE,(-ero,-ero)), iterations = 1 )

            if cfg.clip_hborder_mask_per > 0: #clip hborder before blur
                prd_hborder_rect_mask_a = np.ones ( prd_face_mask_a.shape, dtype=np.float32)
                prd_border_size = int ( prd_hborder_rect_mask_a.shape[1] * cfg.clip_hborder_mask_per )
                prd_hborder_rect_mask_a[:,0:prd_border_size,:] = 0
                prd_hborder_rect_mask_a[:,-prd_border_size:,:] = 0
                prd_hborder_rect_mask_a[-prd_border_size:,:,:] = 0
                prd_hborder_rect_mask_a = np.expand_dims(cv2.blur(prd_hborder_rect_mask_a, (prd_border_size, prd_border_size) ),-1)

                img_prd_hborder_rect_mask_a = cv2.warpAffine( prd_hborder_rect_mask_a, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC )
                img_prd_hborder_rect_mask_a = np.expand_dims (img_prd_hborder_rect_mask_a, -1)
                img_face_mask_aaa *= img_prd_hborder_rect_mask_a
                img_face_mask_aaa = np.clip( img_face_mask_aaa, 0, 1.0 )

                #if debug:
                #    debugs += [img_face_mask_aaa.copy()]

            if cfg.blur_mask_modifier > 0:
                blur = int( lowest_len * 0.10 * 0.01*cfg.blur_mask_modifier )
                #if debug:
                #    io.log_info ("blur_size = %d" % (blur) )
                if blur > 0:
                    img_face_mask_aaa = cv2.blur(img_face_mask_aaa, (blur, blur) )

            img_face_mask_aaa = np.clip( img_face_mask_aaa, 0, 1.0 )


            #if debug:
            #    debugs += [img_face_mask_aaa.copy()]

            if 'seamless' not in cfg.mode and cfg.color_transfer_mode != 0:
                if cfg.color_transfer_mode == 1: #rct
                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]

                    prd_face_bgr = imagelib.reinhard_color_transfer ( np.clip( (prd_face_bgr*255).astype(np.uint8), 0, 255),
                                                                      np.clip( (dst_face_bgr*255).astype(np.uint8), 0, 255),
                                                                      source_mask=prd_face_mask_a, target_mask=prd_face_mask_a)
                    prd_face_bgr = np.clip( prd_face_bgr.astype(np.float32) / 255.0, 0.0, 1.0)

                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]


                elif cfg.color_transfer_mode == 2: #lct
                    #if debug: 
                    #    debugs += [ np.clip( cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]

                    prd_face_bgr = imagelib.linear_color_transfer (prd_face_bgr, dst_face_bgr)
                    prd_face_bgr = np.clip( prd_face_bgr, 0.0, 1.0)

                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]
                elif cfg.color_transfer_mode == 3: #ebs
                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]

                    prd_face_bgr = cfg.ebs_ct_func ( np.clip( (dst_face_bgr*255), 0, 255).astype(np.uint8),
                                                     np.clip( (prd_face_bgr*255), 0, 255).astype(np.uint8),  )#prd_face_mask_a
                    prd_face_bgr = np.clip( prd_face_bgr.astype(np.float32) / 255.0, 0.0, 1.0)
                    
            if cfg.mode == 'hist-match-bw':
                prd_face_bgr = cv2.cvtColor(prd_face_bgr, cv2.COLOR_BGR2GRAY)
                prd_face_bgr = np.repeat( np.expand_dims (prd_face_bgr, -1), (3,), -1 )

            if cfg.mode == 'hist-match' or cfg.mode == 'hist-match-bw':
                #if debug:
                #    debugs += [ cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ) ]

                hist_mask_a = np.ones ( prd_face_bgr.shape[:2] + (1,) , dtype=np.float32)

                if cfg.masked_hist_match:
                    hist_mask_a *= prd_face_mask_a

                white =  (1.0-hist_mask_a)* np.ones ( prd_face_bgr.shape[:2] + (1,) , dtype=np.float32)

                hist_match_1 = prd_face_bgr*hist_mask_a + white
                hist_match_1[ hist_match_1 > 1.0 ] = 1.0

                hist_match_2 = dst_face_bgr*hist_mask_a + white
                hist_match_2[ hist_match_1 > 1.0 ] = 1.0

                prd_face_bgr = imagelib.color_hist_match(hist_match_1, hist_match_2, cfg.hist_match_threshold )

                #if cfg.masked_hist_match:
                #    prd_face_bgr -= white

            if cfg.mode == 'hist-match-bw':
                prd_face_bgr = prd_face_bgr.astype(dtype=np.float32)
                
            if 'seamless' in cfg.mode:
                #mask used for cv2.seamlessClone                
                img_face_mask_a = img_face_mask_aaa[...,0:1]
                
                if cfg.mode == 'seamless2':
                    img_face_mask_a = cv2.warpAffine( img_face_mask_a, face_output_mat, (output_size, output_size), flags=cv2.INTER_CUBIC )
                    
                img_face_seamless_mask_a = None
                for i in range(1,10):
                    a = img_face_mask_a > i / 10.0
                    if len(np.argwhere(a)) == 0:
                        continue
                    img_face_seamless_mask_a = img_face_mask_a.copy()
                    img_face_seamless_mask_a[a] = 1.0
                    img_face_seamless_mask_a[img_face_seamless_mask_a <= i / 10.0] = 0.0
                    break
                
            if cfg.mode == 'seamless2':
                
                face_seamless = imagelib.seamless_clone ( prd_face_bgr, dst_face_bgr, img_face_seamless_mask_a )
                
                out_img = cv2.warpAffine( face_seamless, face_output_mat, img_size, out_img, cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT )
            else:
                out_img = cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, out_img, cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT )
            
            out_img = np.clip(out_img, 0.0, 1.0)

            if 'seamless' in cfg.mode and cfg.mode != 'seamless2':
                try:
                    #calc same bounding rect and center point as in cv2.seamlessClone to prevent jittering (not flickering)
                    l,t,w,h = cv2.boundingRect( (img_face_seamless_mask_a*255).astype(np.uint8) )
                    s_maskx, s_masky = int(l+w/2), int(t+h/2)
                    out_img = cv2.seamlessClone( (out_img*255).astype(np.uint8), img_bgr_uint8, (img_face_seamless_mask_a*255).astype(np.uint8), (s_maskx,s_masky) , cv2.NORMAL_CLONE )
                    out_img = out_img.astype(dtype=np.float32) / 255.0
                except Exception as e:
                    #seamlessClone may fail in some cases
                    e_str = traceback.format_exc()

                    if 'MemoryError' in e_str:
                        raise Exception("Seamless fail: " + e_str) #reraise MemoryError in order to reprocess this data by other processes
                    else:
                        print ("Seamless fail: " + e_str)

                #if debug:
                #    debugs += [out_img.copy()]

            out_img = img_bgr*(1-img_face_mask_aaa) + (out_img*img_face_mask_aaa)

            out_face_bgr = cv2.warpAffine( out_img, face_mat, (output_size, output_size) )
            
            if 'seamless' in cfg.mode and cfg.color_transfer_mode != 0:
                if cfg.color_transfer_mode == 1:
                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( out_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]
                    face_mask_aaa = cv2.warpAffine( img_face_mask_aaa, face_mat, (output_size, output_size) )

                    out_face_bgr = imagelib.reinhard_color_transfer ( np.clip( (out_face_bgr*255), 0, 255).astype(np.uint8),
                                                                      np.clip( (dst_face_bgr*255), 0, 255).astype(np.uint8),
                                                                            source_mask=face_mask_aaa, target_mask=face_mask_aaa)
                    out_face_bgr = np.clip( out_face_bgr.astype(np.float32) / 255.0, 0.0, 1.0)

                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( out_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]

                elif cfg.color_transfer_mode == 2:
                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( out_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]

                    out_face_bgr = imagelib.linear_color_transfer (out_face_bgr, dst_face_bgr)
                    out_face_bgr = np.clip( out_face_bgr, 0.0, 1.0)

                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( out_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]
               
                elif cfg.color_transfer_mode == 3: #ebs
                    #if debug:
                    #    debugs += [ np.clip( cv2.warpAffine( prd_face_bgr, face_output_mat, img_size, np.zeros(img_bgr.shape, dtype=np.float32), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT ), 0, 1.0) ]

                    out_face_bgr = cfg.ebs_ct_func ( np.clip( (dst_face_bgr*255), 0, 255).astype(np.uint8),
                                                     np.clip( (out_face_bgr*255), 0, 255).astype(np.uint8),  )
                    out_face_bgr = np.clip( out_face_bgr.astype(np.float32) / 255.0, 0.0, 1.0)
                    
            if cfg.mode == 'seamless-hist-match':
                out_face_bgr = imagelib.color_hist_match(out_face_bgr, dst_face_bgr, cfg.hist_match_threshold)
            
            cfg_mp = cfg.motion_blur_power / 100.0
            if cfg_mp != 0:
                k_size = int(frame_info.motion_power*cfg_mp)
                if k_size >= 1:
                    k_size = np.clip (k_size+1, 2, 50)
                    if cfg.super_resolution_mode:
                        k_size *= 2
                    out_face_bgr = imagelib.LinearMotionBlur (out_face_bgr, k_size , frame_info.motion_deg)

            if cfg.sharpen_mode != 0 and cfg.sharpen_amount != 0:
                out_face_bgr = cfg.sharpen_func ( out_face_bgr, cfg.sharpen_mode, 3, cfg.sharpen_amount)
            
            new_out = cv2.warpAffine( out_face_bgr, face_mat, img_size, img_bgr.copy(), cv2.WARP_INVERSE_MAP | cv2.INTER_CUBIC, cv2.BORDER_TRANSPARENT )
            out_img =  np.clip( img_bgr*(1-img_face_mask_aaa) + (new_out*img_face_mask_aaa) , 0, 1.0 )


            if cfg.color_degrade_power != 0:
                #if debug:
                #    debugs += [out_img.copy()]
                out_img_reduced = imagelib.reduce_colors(out_img, 256)
                if cfg.color_degrade_power == 100:
                    out_img = out_img_reduced
                else:
                    alpha = cfg.color_degrade_power / 100.0
                    out_img = (out_img*(1.0-alpha) + out_img_reduced*alpha)

            if cfg.export_mask_alpha:
                out_img = np.concatenate ( [out_img, img_face_mask_aaa[:,:,0:1]], -1 )
        out_merging_mask = img_face_mask_aaa


    #if debug:
    #    debugs += [out_img.copy()]

    return out_img, out_merging_mask


def ConvertMasked (predictor_func, predictor_input_shape, cfg, frame_info):
    img_bgr_uint8 = cv2_imread(frame_info.filename)
    img_bgr_uint8 = imagelib.normalize_channels (img_bgr_uint8, 3)
    img_bgr = img_bgr_uint8.astype(np.float32) / 255.0

    outs = []
    for face_num, img_landmarks in enumerate( frame_info.landmarks_list ):
        out_img, out_img_merging_mask = ConvertMaskedFace (predictor_func, predictor_input_shape, cfg, frame_info, img_bgr_uint8, img_bgr, img_landmarks)
        outs += [ (out_img, out_img_merging_mask) ]

    #Combining multiple face outputs
    final_img = None
    for img, merging_mask in outs:
        h,w,c = img.shape

        if final_img is None:
            final_img = img
        else:
            merging_mask = merging_mask[...,0:1]
            if c == 3:
                final_img = final_img*(1-merging_mask) + img*merging_mask
            elif c == 4:
                final_img_bgr = final_img[...,0:3]*(1-merging_mask) + img[...,0:3]*merging_mask
                final_img_mask = np.clip ( final_img[...,3:4] + img[...,3:4], 0, 1 )
                final_img = np.concatenate ( [final_img_bgr, final_img_mask], -1 )

    return (final_img*255).astype(np.uint8)