| import collections |
| import math |
| from enum import IntEnum |
|
|
| import cv2 |
| import numpy as np |
|
|
| from core import imagelib |
| from core.cv2ex import * |
| from core.imagelib import sd |
| from facelib import FaceType, LandmarksProcessor |
|
|
|
|
| class SampleProcessor(object): |
| class SampleType(IntEnum): |
| NONE = 0 |
| IMAGE = 1 |
| FACE_IMAGE = 2 |
| FACE_MASK = 3 |
| LANDMARKS_ARRAY = 4 |
| PITCH_YAW_ROLL = 5 |
| PITCH_YAW_ROLL_SIGMOID = 6 |
|
|
| class ChannelType(IntEnum): |
| NONE = 0 |
| BGR = 1 |
| G = 2 |
| GGG = 3 |
|
|
| class FaceMaskType(IntEnum): |
| NONE = 0 |
| FULL_FACE = 1 |
| EYES = 2 |
| EYES_MOUTH = 3 |
|
|
| class Options(object): |
| def __init__(self, random_flip = True, rotation_range=[-10,10], scale_range=[-0.05, 0.05], tx_range=[-0.05, 0.05], ty_range=[-0.05, 0.05] ): |
| self.random_flip = random_flip |
| self.rotation_range = rotation_range |
| self.scale_range = scale_range |
| self.tx_range = tx_range |
| self.ty_range = ty_range |
|
|
| @staticmethod |
| def process (samples, sample_process_options, output_sample_types, debug, ct_sample=None): |
| SPST = SampleProcessor.SampleType |
| SPCT = SampleProcessor.ChannelType |
| SPFMT = SampleProcessor.FaceMaskType |
|
|
| |
| outputs = [] |
| for sample in samples: |
| sample_rnd_seed = np.random.randint(0x80000000) |
| |
| sample_face_type = sample.face_type |
| sample_bgr = sample.load_bgr() |
| sample_landmarks = sample.landmarks |
| ct_sample_bgr = None |
| h,w,c = sample_bgr.shape |
| |
| def get_full_face_mask(): |
| xseg_mask = sample.get_xseg_mask() |
| if xseg_mask is not None: |
| if xseg_mask.shape[0] != h or xseg_mask.shape[1] != w: |
| xseg_mask = cv2.resize(xseg_mask, (w,h), interpolation=cv2.INTER_CUBIC) |
| xseg_mask = imagelib.normalize_channels(xseg_mask, 1) |
| return np.clip(xseg_mask, 0, 1) |
| else: |
| full_face_mask = LandmarksProcessor.get_image_hull_mask (sample_bgr.shape, sample_landmarks, eyebrows_expand_mod=sample.eyebrows_expand_mod ) |
| return np.clip(full_face_mask, 0, 1) |
| |
| def get_eyes_mask(): |
| eyes_mask = LandmarksProcessor.get_image_eye_mask (sample_bgr.shape, sample_landmarks) |
| return np.clip(eyes_mask, 0, 1) |
| |
| def get_eyes_mouth_mask(): |
| eyes_mask = LandmarksProcessor.get_image_eye_mask (sample_bgr.shape, sample_landmarks) |
| mouth_mask = LandmarksProcessor.get_image_mouth_mask (sample_bgr.shape, sample_landmarks) |
| mask = eyes_mask + mouth_mask |
| return np.clip(mask, 0, 1) |
| |
| is_face_sample = sample_landmarks is not None |
|
|
| if debug and is_face_sample: |
| LandmarksProcessor.draw_landmarks (sample_bgr, sample_landmarks, (0, 1, 0)) |
|
|
| outputs_sample = [] |
| for opts in output_sample_types: |
| resolution = opts.get('resolution', 0) |
| sample_type = opts.get('sample_type', SPST.NONE) |
| channel_type = opts.get('channel_type', SPCT.NONE) |
| nearest_resize_to = opts.get('nearest_resize_to', None) |
| warp = opts.get('warp', False) |
| transform = opts.get('transform', False) |
| random_hsv_shift_amount = opts.get('random_hsv_shift_amount', 0) |
| normalize_tanh = opts.get('normalize_tanh', False) |
| ct_mode = opts.get('ct_mode', None) |
| data_format = opts.get('data_format', 'NHWC') |
| |
| rnd_seed_shift = opts.get('rnd_seed_shift', 0) |
| warp_rnd_seed_shift = opts.get('warp_rnd_seed_shift', rnd_seed_shift) |
| |
| rnd_state = np.random.RandomState (sample_rnd_seed+rnd_seed_shift) |
| warp_rnd_state = np.random.RandomState (sample_rnd_seed+warp_rnd_seed_shift) |
| |
| warp_params = imagelib.gen_warp_params(resolution, |
| sample_process_options.random_flip, |
| rotation_range=sample_process_options.rotation_range, |
| scale_range=sample_process_options.scale_range, |
| tx_range=sample_process_options.tx_range, |
| ty_range=sample_process_options.ty_range, |
| rnd_state=rnd_state, |
| warp_rnd_state=warp_rnd_state, |
| ) |
| |
| if sample_type == SPST.FACE_MASK or sample_type == SPST.IMAGE: |
| border_replicate = False |
| elif sample_type == SPST.FACE_IMAGE: |
| border_replicate = True |
| |
| |
| border_replicate = opts.get('border_replicate', border_replicate) |
| borderMode = cv2.BORDER_REPLICATE if border_replicate else cv2.BORDER_CONSTANT |
| |
| |
| if sample_type == SPST.FACE_IMAGE or sample_type == SPST.FACE_MASK: |
| if not is_face_sample: |
| raise ValueError("face_samples should be provided for sample_type FACE_*") |
|
|
| if sample_type == SPST.FACE_IMAGE or sample_type == SPST.FACE_MASK: |
| face_type = opts.get('face_type', None) |
| face_mask_type = opts.get('face_mask_type', SPFMT.NONE) |
| |
| if face_type is None: |
| raise ValueError("face_type must be defined for face samples") |
|
|
| if sample_type == SPST.FACE_MASK: |
| if face_mask_type == SPFMT.FULL_FACE: |
| img = get_full_face_mask() |
| elif face_mask_type == SPFMT.EYES: |
| img = get_eyes_mask() |
| elif face_mask_type == SPFMT.EYES_MOUTH: |
| mask = get_full_face_mask().copy() |
| mask[mask != 0.0] = 1.0 |
| img = get_eyes_mouth_mask()*mask |
| else: |
| img = np.zeros ( sample_bgr.shape[0:2]+(1,), dtype=np.float32) |
|
|
| if sample_face_type == FaceType.MARK_ONLY: |
| raise NotImplementedError() |
| mat = LandmarksProcessor.get_transform_mat (sample_landmarks, warp_resolution, face_type) |
| img = cv2.warpAffine( img, mat, (warp_resolution, warp_resolution), flags=cv2.INTER_LINEAR ) |
| |
| img = imagelib.warp_by_params (warp_params, img, warp, transform, can_flip=True, border_replicate=border_replicate, cv2_inter=cv2.INTER_LINEAR) |
| img = cv2.resize( img, (resolution,resolution), interpolation=cv2.INTER_LINEAR ) |
| else: |
| if face_type != sample_face_type: |
| mat = LandmarksProcessor.get_transform_mat (sample_landmarks, resolution, face_type) |
| img = cv2.warpAffine( img, mat, (resolution,resolution), borderMode=borderMode, flags=cv2.INTER_LINEAR ) |
| else: |
| if w != resolution: |
| img = cv2.resize( img, (resolution, resolution), interpolation=cv2.INTER_LINEAR ) |
| |
| img = imagelib.warp_by_params (warp_params, img, warp, transform, can_flip=True, border_replicate=border_replicate, cv2_inter=cv2.INTER_LINEAR) |
|
|
| if face_mask_type == SPFMT.EYES_MOUTH: |
| div = img.max() |
| if div != 0.0: |
| img = img / div |
| |
| if len(img.shape) == 2: |
| img = img[...,None] |
| |
| if channel_type == SPCT.G: |
| out_sample = img.astype(np.float32) |
| else: |
| raise ValueError("only channel_type.G supported for the mask") |
|
|
| elif sample_type == SPST.FACE_IMAGE: |
| img = sample_bgr |
| |
| if face_type != sample_face_type: |
| mat = LandmarksProcessor.get_transform_mat (sample_landmarks, resolution, face_type) |
| img = cv2.warpAffine( img, mat, (resolution,resolution), borderMode=borderMode, flags=cv2.INTER_CUBIC ) |
| else: |
| if w != resolution: |
| img = cv2.resize( img, (resolution, resolution), interpolation=cv2.INTER_CUBIC ) |
| |
| |
| if ct_mode is not None and ct_sample is not None: |
| if ct_sample_bgr is None: |
| ct_sample_bgr = ct_sample.load_bgr() |
| img = imagelib.color_transfer (ct_mode, img, cv2.resize( ct_sample_bgr, (resolution,resolution), interpolation=cv2.INTER_LINEAR ) ) |
| |
| if random_hsv_shift_amount != 0: |
| a = random_hsv_shift_amount |
| h_amount = max(1, int(360*a*0.5)) |
| img_h, img_s, img_v = cv2.split(cv2.cvtColor(img, cv2.COLOR_BGR2HSV)) |
| img_h = (img_h + rnd_state.randint(-h_amount, h_amount+1) ) % 360 |
| img_s = np.clip (img_s + (rnd_state.random()-0.5)*a, 0, 1 ) |
| img_v = np.clip (img_v + (rnd_state.random()-0.5)*a, 0, 1 ) |
| img = np.clip( cv2.cvtColor(cv2.merge([img_h, img_s, img_v]), cv2.COLOR_HSV2BGR) , 0, 1 ) |
|
|
| img = imagelib.warp_by_params (warp_params, img, warp, transform, can_flip=True, border_replicate=border_replicate) |
| |
| img = np.clip(img.astype(np.float32), 0, 1) |
|
|
| |
| if channel_type == SPCT.BGR: |
| out_sample = img |
| elif channel_type == SPCT.G: |
| out_sample = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)[...,None] |
| elif channel_type == SPCT.GGG: |
| out_sample = np.repeat ( np.expand_dims(cv2.cvtColor(img, cv2.COLOR_BGR2GRAY),-1), (3,), -1) |
|
|
| |
| if nearest_resize_to is not None: |
| out_sample = cv2_resize(out_sample, (nearest_resize_to,nearest_resize_to), interpolation=cv2.INTER_NEAREST) |
| |
| if not debug: |
| if normalize_tanh: |
| out_sample = np.clip (out_sample * 2.0 - 1.0, -1.0, 1.0) |
| if data_format == "NCHW": |
| out_sample = np.transpose(out_sample, (2,0,1) ) |
| elif sample_type == SPST.IMAGE: |
| img = sample_bgr |
| img = imagelib.warp_by_params (warp_params, img, warp, transform, can_flip=True, border_replicate=True) |
| img = cv2.resize( img, (resolution, resolution), interpolation=cv2.INTER_CUBIC ) |
| out_sample = img |
| |
| if data_format == "NCHW": |
| out_sample = np.transpose(out_sample, (2,0,1) ) |
| |
| |
| elif sample_type == SPST.LANDMARKS_ARRAY: |
| l = sample_landmarks |
| l = np.concatenate ( [ np.expand_dims(l[:,0] / w,-1), np.expand_dims(l[:,1] / h,-1) ], -1 ) |
| l = np.clip(l, 0.0, 1.0) |
| out_sample = l |
| elif sample_type == SPST.PITCH_YAW_ROLL or sample_type == SPST.PITCH_YAW_ROLL_SIGMOID: |
| pitch,yaw,roll = sample.get_pitch_yaw_roll() |
| if warp_params['flip']: |
| yaw = -yaw |
|
|
| if sample_type == SPST.PITCH_YAW_ROLL_SIGMOID: |
| pitch = np.clip( (pitch / math.pi) / 2.0 + 0.5, 0, 1) |
| yaw = np.clip( (yaw / math.pi) / 2.0 + 0.5, 0, 1) |
| roll = np.clip( (roll / math.pi) / 2.0 + 0.5, 0, 1) |
|
|
| out_sample = (pitch, yaw) |
| else: |
| raise ValueError ('expected sample_type') |
|
|
| outputs_sample.append ( out_sample ) |
| outputs += [outputs_sample] |
|
|
| return outputs |
|
|
|
|
