wko-projekt/API/train.py

"""
Retrain the YOLO model for your own dataset.
"""

import numpy as np
import keras.backend as K
from keras.layers import Input, Lambda
from keras.models import Model
from keras.optimizers import Adam
from keras.callbacks import TensorBoard, ModelCheckpoint, ReduceLROnPlateau, EarlyStopping

from yolo3.model import preprocess_true_boxes, yolo_body, tiny_yolo_body, yolo_loss
from yolo3.utils import get_random_data


def _main():
    # './export/_annotations.txt'
    annotation_path = '_annotations.txt'
    log_dir = 'logs/000/'
    # './export/_annotations.txt'
    classes_path = '_classes.txt'
    anchors_path = 'model_data/yolo_anchors.txt'
    class_names = get_classes(classes_path)
    print("-------------------CLASS NAMES-------------------")
    print(class_names)
    print("-------------------CLASS NAMES-------------------")
    num_classes = len(class_names)
    anchors = get_anchors(anchors_path)

    input_shape = (416,416) # multiple of 32, hw

    is_tiny_version = len(anchors)==6 # default setting
    if is_tiny_version:
        model = create_tiny_model(input_shape, anchors, num_classes,
                                  freeze_body=2, weights_path='model_data/tiny_yolo_weights.h5')
    else:
        model = create_model(input_shape, anchors, num_classes,
                             freeze_body=2, weights_path='model_data/yolo.h5') # make sure you know what you freeze

    logging = TensorBoard(log_dir=log_dir)
    checkpoint = ModelCheckpoint(log_dir + 'ep{epoch:03d}-loss{loss:.3f}-val_loss{val_loss:.3f}.h5',
        monitor='val_loss', save_weights_only=True, save_best_only=True, period=3)
    reduce_lr = ReduceLROnPlateau(monitor='val_loss', factor=0.1, patience=3, verbose=1)
    early_stopping = EarlyStopping(monitor='val_loss', min_delta=0, patience=10, verbose=1)

    val_split = 0.2
    with open(annotation_path) as f:
        lines = f.readlines()
    np.random.seed(10101)
    np.random.shuffle(lines)
    np.random.seed(None)
    num_val = int(len(lines)*val_split)
    num_train = len(lines) - num_val

    # Train with frozen layers first, to get a stable loss.
    # Adjust num epochs to your dataset. This step is enough to obtain a not bad model.
    if True:
        model.compile(optimizer=Adam(lr=1e-3), loss={
            # use custom yolo_loss Lambda layer.
            'yolo_loss': lambda y_true, y_pred: y_pred})

        batch_size = 32
        print('Train on {} samples, val on {} samples, with batch size {}.'.format(num_train, num_val, batch_size))
        model.fit_generator(data_generator_wrapper(lines[:num_train], batch_size, input_shape, anchors, num_classes),
                steps_per_epoch=max(1, num_train//batch_size),
                validation_data=data_generator_wrapper(lines[num_train:], batch_size, input_shape, anchors, num_classes),
                validation_steps=max(1, num_val//batch_size),
                epochs=500,
                initial_epoch=0,
                callbacks=[logging, checkpoint])
        model.save_weights(log_dir + 'trained_weights_stage_1.h5')

    # Unfreeze and continue training, to fine-tune.
    # Train longer if the result is not good.
    if True:
        for i in range(len(model.layers)):
            model.layers[i].trainable = True
        model.compile(optimizer=Adam(lr=1e-4), loss={'yolo_loss': lambda y_true, y_pred: y_pred}) # recompile to apply the change
        print('Unfreeze all of the layers.')

        batch_size = 32 # note that more GPU memory is required after unfreezing the body
        print('Train on {} samples, val on {} samples, with batch size {}.'.format(num_train, num_val, batch_size))
        model.fit_generator(data_generator_wrapper(lines[:num_train], batch_size, input_shape, anchors, num_classes),
            steps_per_epoch=max(1, num_train//batch_size),
            validation_data=data_generator_wrapper(lines[num_train:], batch_size, input_shape, anchors, num_classes),
            validation_steps=max(1, num_val//batch_size),
            epochs=100,
            initial_epoch=50,
            callbacks=[logging, checkpoint, reduce_lr, early_stopping])
        model.save_weights(log_dir + 'trained_weights_final.h5')

    # Further training if needed.


def get_classes(classes_path):
    '''loads the classes'''
    with open(classes_path) as f:
        class_names = f.readlines()
    class_names = [c.strip() for c in class_names]
    return class_names

def get_anchors(anchors_path):
    '''loads the anchors from a file'''
    with open(anchors_path) as f:
        anchors = f.readline()
    anchors = [float(x) for x in anchors.split(',')]
    return np.array(anchors).reshape(-1, 2)


def create_model(input_shape, anchors, num_classes, load_pretrained=True, freeze_body=2,
            weights_path='model_data/yolo.h5'):
    '''create the training model'''
    K.clear_session() # get a new session
    image_input = Input(shape=(None, None, 3))
    h, w = input_shape
    num_anchors = len(anchors)

    y_true = [Input(shape=(h//{0:32, 1:16, 2:8}[l], w//{0:32, 1:16, 2:8}[l], \
        num_anchors//3, num_classes+5)) for l in range(3)]

    model_body = yolo_body(image_input, num_anchors//3, num_classes)
    print('Create YOLOv3 model with {} anchors and {} classes.'.format(num_anchors, num_classes))

    if load_pretrained:
        model_body.load_weights(weights_path, by_name=True, skip_mismatch=True)
        print('Load weights {}.'.format(weights_path))
        if freeze_body in [1, 2]:
            # Freeze darknet53 body or freeze all but 3 output layers.
            num = (185, len(model_body.layers)-3)[freeze_body-1]
            for i in range(num): model_body.layers[i].trainable = False
            print('Freeze the first {} layers of total {} layers.'.format(num, len(model_body.layers)))

    model_loss = Lambda(yolo_loss, output_shape=(1,), name='yolo_loss',
        arguments={'anchors': anchors, 'num_classes': num_classes, 'ignore_thresh': 0.5})(
        [*model_body.output, *y_true])
    model = Model([model_body.input, *y_true], model_loss)

    return model

def create_tiny_model(input_shape, anchors, num_classes, load_pretrained=True, freeze_body=2,
            weights_path='model_data/tiny_yolo_weights.h5'):
    '''create the training model, for Tiny YOLOv3'''
    K.clear_session() # get a new session
    image_input = Input(shape=(None, None, 3))
    h, w = input_shape
    num_anchors = len(anchors)

    y_true = [Input(shape=(h//{0:32, 1:16}[l], w//{0:32, 1:16}[l], \
        num_anchors//2, num_classes+5)) for l in range(2)]

    model_body = tiny_yolo_body(image_input, num_anchors//2, num_classes)
    print('Create Tiny YOLOv3 model with {} anchors and {} classes.'.format(num_anchors, num_classes))

    if load_pretrained:
        model_body.load_weights(weights_path, by_name=True, skip_mismatch=True)
        print('Load weights {}.'.format(weights_path))
        if freeze_body in [1, 2]:
            # Freeze the darknet body or freeze all but 2 output layers.
            num = (20, len(model_body.layers)-2)[freeze_body-1]
            for i in range(num): model_body.layers[i].trainable = False
            print('Freeze the first {} layers of total {} layers.'.format(num, len(model_body.layers)))

    model_loss = Lambda(yolo_loss, output_shape=(1,), name='yolo_loss',
        arguments={'anchors': anchors, 'num_classes': num_classes, 'ignore_thresh': 0.7})(
        [*model_body.output, *y_true])
    model = Model([model_body.input, *y_true], model_loss)

    return model

def data_generator(annotation_lines, batch_size, input_shape, anchors, num_classes):
    '''data generator for fit_generator'''
    n = len(annotation_lines)
    i = 0
    while True:
        image_data = []
        box_data = []
        for b in range(batch_size):
            if i==0:
                np.random.shuffle(annotation_lines)
            image, box = get_random_data(annotation_lines[i], input_shape, random=True)
            image_data.append(image)
            box_data.append(box)
            i = (i+1) % n
        image_data = np.array(image_data)
        box_data = np.array(box_data)
        y_true = preprocess_true_boxes(box_data, input_shape, anchors, num_classes)
        yield [image_data, *y_true], np.zeros(batch_size)

def data_generator_wrapper(annotation_lines, batch_size, input_shape, anchors, num_classes):
    n = len(annotation_lines)
    if n==0 or batch_size<=0: return None
    return data_generator(annotation_lines, batch_size, input_shape, anchors, num_classes)

if __name__ == '__main__':
    _main()
add yolov3 and ocr to detect license plate numbers 2023-01-22 21:00:32 +01:00			`"""`
			`Retrain the YOLO model for your own dataset.`
			`"""`

			`import numpy as np`
			`import keras.backend as K`
			`from keras.layers import Input, Lambda`
			`from keras.models import Model`
			`from keras.optimizers import Adam`
			`from keras.callbacks import TensorBoard, ModelCheckpoint, ReduceLROnPlateau, EarlyStopping`

			`from yolo3.model import preprocess_true_boxes, yolo_body, tiny_yolo_body, yolo_loss`
			`from yolo3.utils import get_random_data`


			`def _main():`
			`# './export/_annotations.txt'`
			`annotation_path = '_annotations.txt'`
			`log_dir = 'logs/000/'`
			`# './export/_annotations.txt'`
			`classes_path = '_classes.txt'`
			`anchors_path = 'model_data/yolo_anchors.txt'`
			`class_names = get_classes(classes_path)`
			`print("-------------------CLASS NAMES-------------------")`
			`print(class_names)`
			`print("-------------------CLASS NAMES-------------------")`
			`num_classes = len(class_names)`
			`anchors = get_anchors(anchors_path)`

			`input_shape = (416,416) # multiple of 32, hw`

			`is_tiny_version = len(anchors)==6 # default setting`
			`if is_tiny_version:`
			`model = create_tiny_model(input_shape, anchors, num_classes,`
move API to dedicated dir 2023-02-01 00:25:23 +01:00			`freeze_body=2, weights_path='model_data/tiny_yolo_weights.h5')`
add yolov3 and ocr to detect license plate numbers 2023-01-22 21:00:32 +01:00			`else:`
			`model = create_model(input_shape, anchors, num_classes,`
move API to dedicated dir 2023-02-01 00:25:23 +01:00			`freeze_body=2, weights_path='model_data/yolo.h5') # make sure you know what you freeze`
add yolov3 and ocr to detect license plate numbers 2023-01-22 21:00:32 +01:00
			`logging = TensorBoard(log_dir=log_dir)`
			`checkpoint = ModelCheckpoint(log_dir + 'ep{epoch:03d}-loss{loss:.3f}-val_loss{val_loss:.3f}.h5',`
			`monitor='val_loss', save_weights_only=True, save_best_only=True, period=3)`
			`reduce_lr = ReduceLROnPlateau(monitor='val_loss', factor=0.1, patience=3, verbose=1)`
			`early_stopping = EarlyStopping(monitor='val_loss', min_delta=0, patience=10, verbose=1)`

			`val_split = 0.2`
			`with open(annotation_path) as f:`
			`lines = f.readlines()`
			`np.random.seed(10101)`
			`np.random.shuffle(lines)`
			`np.random.seed(None)`
			`num_val = int(len(lines)*val_split)`
			`num_train = len(lines) - num_val`

			`# Train with frozen layers first, to get a stable loss.`
			`# Adjust num epochs to your dataset. This step is enough to obtain a not bad model.`
			`if True:`
			`model.compile(optimizer=Adam(lr=1e-3), loss={`
			`# use custom yolo_loss Lambda layer.`
			`'yolo_loss': lambda y_true, y_pred: y_pred})`

			`batch_size = 32`
			`print('Train on {} samples, val on {} samples, with batch size {}.'.format(num_train, num_val, batch_size))`
			`model.fit_generator(data_generator_wrapper(lines[:num_train], batch_size, input_shape, anchors, num_classes),`
			`steps_per_epoch=max(1, num_train//batch_size),`
			`validation_data=data_generator_wrapper(lines[num_train:], batch_size, input_shape, anchors, num_classes),`
			`validation_steps=max(1, num_val//batch_size),`
			`epochs=500,`
			`initial_epoch=0,`
			`callbacks=[logging, checkpoint])`
			`model.save_weights(log_dir + 'trained_weights_stage_1.h5')`

			`# Unfreeze and continue training, to fine-tune.`
			`# Train longer if the result is not good.`
			`if True:`
			`for i in range(len(model.layers)):`
			`model.layers[i].trainable = True`
			`model.compile(optimizer=Adam(lr=1e-4), loss={'yolo_loss': lambda y_true, y_pred: y_pred}) # recompile to apply the change`
			`print('Unfreeze all of the layers.')`

			`batch_size = 32 # note that more GPU memory is required after unfreezing the body`
			`print('Train on {} samples, val on {} samples, with batch size {}.'.format(num_train, num_val, batch_size))`
			`model.fit_generator(data_generator_wrapper(lines[:num_train], batch_size, input_shape, anchors, num_classes),`
			`steps_per_epoch=max(1, num_train//batch_size),`
			`validation_data=data_generator_wrapper(lines[num_train:], batch_size, input_shape, anchors, num_classes),`
			`validation_steps=max(1, num_val//batch_size),`
			`epochs=100,`
			`initial_epoch=50,`
			`callbacks=[logging, checkpoint, reduce_lr, early_stopping])`
			`model.save_weights(log_dir + 'trained_weights_final.h5')`

			`# Further training if needed.`


			`def get_classes(classes_path):`
			`'''loads the classes'''`
			`with open(classes_path) as f:`
			`class_names = f.readlines()`
			`class_names = [c.strip() for c in class_names]`
			`return class_names`

			`def get_anchors(anchors_path):`
			`'''loads the anchors from a file'''`
			`with open(anchors_path) as f:`
			`anchors = f.readline()`
			`anchors = [float(x) for x in anchors.split(',')]`
			`return np.array(anchors).reshape(-1, 2)`


			`def create_model(input_shape, anchors, num_classes, load_pretrained=True, freeze_body=2,`
			`weights_path='model_data/yolo.h5'):`
			`'''create the training model'''`
			`K.clear_session() # get a new session`
			`image_input = Input(shape=(None, None, 3))`
			`h, w = input_shape`
			`num_anchors = len(anchors)`

			`y_true = [Input(shape=(h//{0:32, 1:16, 2:8}[l], w//{0:32, 1:16, 2:8}[l], \`
			`num_anchors//3, num_classes+5)) for l in range(3)]`

			`model_body = yolo_body(image_input, num_anchors//3, num_classes)`
			`print('Create YOLOv3 model with {} anchors and {} classes.'.format(num_anchors, num_classes))`

			`if load_pretrained:`
			`model_body.load_weights(weights_path, by_name=True, skip_mismatch=True)`
			`print('Load weights {}.'.format(weights_path))`
			`if freeze_body in [1, 2]:`
			`# Freeze darknet53 body or freeze all but 3 output layers.`
			`num = (185, len(model_body.layers)-3)[freeze_body-1]`
			`for i in range(num): model_body.layers[i].trainable = False`
			`print('Freeze the first {} layers of total {} layers.'.format(num, len(model_body.layers)))`

			`model_loss = Lambda(yolo_loss, output_shape=(1,), name='yolo_loss',`
			`arguments={'anchors': anchors, 'num_classes': num_classes, 'ignore_thresh': 0.5})(`
			`[model_body.output, y_true])`
			`model = Model([model_body.input, *y_true], model_loss)`

			`return model`

			`def create_tiny_model(input_shape, anchors, num_classes, load_pretrained=True, freeze_body=2,`
			`weights_path='model_data/tiny_yolo_weights.h5'):`
			`'''create the training model, for Tiny YOLOv3'''`
			`K.clear_session() # get a new session`
			`image_input = Input(shape=(None, None, 3))`
			`h, w = input_shape`
			`num_anchors = len(anchors)`

			`y_true = [Input(shape=(h//{0:32, 1:16}[l], w//{0:32, 1:16}[l], \`
			`num_anchors//2, num_classes+5)) for l in range(2)]`

			`model_body = tiny_yolo_body(image_input, num_anchors//2, num_classes)`
			`print('Create Tiny YOLOv3 model with {} anchors and {} classes.'.format(num_anchors, num_classes))`

			`if load_pretrained:`
			`model_body.load_weights(weights_path, by_name=True, skip_mismatch=True)`
			`print('Load weights {}.'.format(weights_path))`
			`if freeze_body in [1, 2]:`
			`# Freeze the darknet body or freeze all but 2 output layers.`
			`num = (20, len(model_body.layers)-2)[freeze_body-1]`
			`for i in range(num): model_body.layers[i].trainable = False`
			`print('Freeze the first {} layers of total {} layers.'.format(num, len(model_body.layers)))`

			`model_loss = Lambda(yolo_loss, output_shape=(1,), name='yolo_loss',`
			`arguments={'anchors': anchors, 'num_classes': num_classes, 'ignore_thresh': 0.7})(`
			`[model_body.output, y_true])`
			`model = Model([model_body.input, *y_true], model_loss)`

			`return model`

			`def data_generator(annotation_lines, batch_size, input_shape, anchors, num_classes):`
			`'''data generator for fit_generator'''`
			`n = len(annotation_lines)`
			`i = 0`
			`while True:`
			`image_data = []`
			`box_data = []`
			`for b in range(batch_size):`
			`if i==0:`
			`np.random.shuffle(annotation_lines)`
			`image, box = get_random_data(annotation_lines[i], input_shape, random=True)`
			`image_data.append(image)`
			`box_data.append(box)`
			`i = (i+1) % n`
			`image_data = np.array(image_data)`
			`box_data = np.array(box_data)`
			`y_true = preprocess_true_boxes(box_data, input_shape, anchors, num_classes)`
			`yield [image_data, *y_true], np.zeros(batch_size)`

			`def data_generator_wrapper(annotation_lines, batch_size, input_shape, anchors, num_classes):`
			`n = len(annotation_lines)`
			`if n==0 or batch_size<=0: return None`
			`return data_generator(annotation_lines, batch_size, input_shape, anchors, num_classes)`

			`if __name__ == '__main__':`
			`_main()`