ma_cisco_malware/models/__init__.py

import keras.backend as K

from . import pauls_networks
from . import renes_networks


def get_models_by_params(params: dict):
    # decomposing param section
    # mainly embedding model
    network_type = params.get("type")
    network_depth = params.get("depth")
    embedding_size = params.get("embedding_size")
    input_length = params.get("input_length")
    filter_embedding = params.get("filter_embedding")
    kernel_embedding = params.get("kernel_embedding")
    hidden_embedding = params.get("dense_embedding")
    dropout = params.get("dropout")
    # mainly prediction model
    flow_features = params.get("flow_features")
    domain_features = params.get("domain_features")
    window_size = params.get("window_size")
    domain_length = params.get("domain_length")
    filter_main = params.get("filter_main")
    kernel_main = params.get("kernel_main")
    dense_dim = params.get("dense_main")
    model_output = params.get("model_output", "both")
    # create models
    if network_depth == "small":
        networks = pauls_networks
    elif network_depth == "medium":
        networks = renes_networks
    else:
        raise Exception("network not found")
    embedding_model = networks.get_embedding(embedding_size, input_length, filter_embedding, kernel_embedding,
                                             hidden_embedding, 0.5)

    old_model = networks.get_model(0.25, flow_features, domain_features, window_size, domain_length,
                                   filter_main, kernel_main, dense_dim, embedding_model, model_output)

    new_model = networks.get_new_model(0.25, flow_features, domain_features, window_size, domain_length,
                                       filter_main, kernel_main, dense_dim, embedding_model, model_output)

    return embedding_model, old_model, new_model


def get_metrics():
    return dict([
        ("precision", precision),
        ("recall", recall),
        ("f1_score", f1_score),
    ])


def get_metric_functions():
    return [precision, recall, f1_score]


def precision(y_true, y_pred):
    # Count positive samples.
    true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1)))
    predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1)))
    return true_positives / (predicted_positives + K.epsilon())


def recall(y_true, y_pred):
    # Count positive samples.
    true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1)))
    possible_positives = K.sum(K.round(K.clip(y_true, 0, 1)))
    return true_positives / (possible_positives + K.epsilon())


def f1_score(y_true, y_pred):
    return f_score(1)(y_true, y_pred)


def f05_score(y_true, y_pred):
    return f_score(0.5)(y_true, y_pred)


def f_score(beta):
    def _f(y_true, y_pred):
        p = precision(y_true, y_pred)
        r = recall(y_true, y_pred)

        bb = beta ** 2

        fbeta_score = (1 + bb) * (p * r) / (bb * p + r + K.epsilon())

        return fbeta_score

    return _f
add visualization for training curves, pr, roc 2017-07-14 14:58:17 +02:00			`import keras.backend as K`

refactor models package: create separate modules for pauls and renes networks 2017-07-05 18:10:22 +02:00			`from . import pauls_networks`
			`from . import renes_networks`
refactor main functions - separate things into different functions 2017-07-07 08:43:16 +02:00

			`def get_models_by_params(params: dict):`
			`# decomposing param section`
			`# mainly embedding model`
			`network_type = params.get("type")`
refactor visualization, change arguments for model type and its depth 2017-09-01 10:42:26 +02:00			`network_depth = params.get("depth")`
refactor main functions - separate things into different functions 2017-07-07 08:43:16 +02:00			`embedding_size = params.get("embedding_size")`
			`input_length = params.get("input_length")`
			`filter_embedding = params.get("filter_embedding")`
			`kernel_embedding = params.get("kernel_embedding")`
change argument interface - add more properties for network specification - change names for consistency 2017-09-07 15:53:58 +02:00			`hidden_embedding = params.get("dense_embedding")`
refactor main functions - separate things into different functions 2017-07-07 08:43:16 +02:00			`dropout = params.get("dropout")`
			`# mainly prediction model`
			`flow_features = params.get("flow_features")`
			`domain_features = params.get("domain_features")`
			`window_size = params.get("window_size")`
			`domain_length = params.get("domain_length")`
			`filter_main = params.get("filter_main")`
change argument interface - add more properties for network specification - change names for consistency 2017-09-07 15:53:58 +02:00			`kernel_main = params.get("kernel_main")`
refactor main functions - separate things into different functions 2017-07-07 08:43:16 +02:00			`dense_dim = params.get("dense_main")`
add argument for model outputs BUG: need to check --new_model --model_output server 2017-08-02 12:58:09 +02:00			`model_output = params.get("model_output", "both")`
refactor main functions - separate things into different functions 2017-07-07 08:43:16 +02:00			`# create models`
refactor visualization, change arguments for model type and its depth 2017-09-01 10:42:26 +02:00			`if network_depth == "small":`
			`networks = pauls_networks`
			`elif network_depth == "medium":`
			`networks = renes_networks`
			`else:`
			`raise Exception("network not found")`
move vocab_size into implementation (not user dependent) 2017-07-30 13:47:11 +02:00			`embedding_model = networks.get_embedding(embedding_size, input_length, filter_embedding, kernel_embedding,`
change argument interface - add more properties for network specification - change names for consistency 2017-09-07 15:53:58 +02:00			`hidden_embedding, 0.5)`
refactor main functions - separate things into different functions 2017-07-07 08:43:16 +02:00
change argument interface - add more properties for network specification - change names for consistency 2017-09-07 15:53:58 +02:00			`old_model = networks.get_model(0.25, flow_features, domain_features, window_size, domain_length,`
add staggered model training for intermediate sever prediction; refactor model return values 2017-09-07 14:24:55 +02:00			`filter_main, kernel_main, dense_dim, embedding_model, model_output)`
refactor main functions - separate things into different functions 2017-07-07 08:43:16 +02:00
change argument interface - add more properties for network specification - change names for consistency 2017-09-07 15:53:58 +02:00			`new_model = networks.get_new_model(0.25, flow_features, domain_features, window_size, domain_length,`
add argument for model outputs BUG: need to check --new_model --model_output server 2017-08-02 12:58:09 +02:00			`filter_main, kernel_main, dense_dim, embedding_model, model_output)`
add new network architecture - server label moves to the middle 2017-07-29 19:42:36 +02:00
add staggered model training for intermediate sever prediction; refactor model return values 2017-09-07 14:24:55 +02:00			`return embedding_model, old_model, new_model`
add visualization for training curves, pr, roc 2017-07-14 14:58:17 +02:00

			`def get_metrics():`
			`return dict([`
			`("precision", precision),`
			`("recall", recall),`
			`("f1_score", f1_score),`
			`])`


			`def get_metric_functions():`
			`return [precision, recall, f1_score]`


			`def precision(y_true, y_pred):`
			`# Count positive samples.`
			`true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1)))`
			`predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1)))`
			`return true_positives / (predicted_positives + K.epsilon())`


			`def recall(y_true, y_pred):`
			`# Count positive samples.`
			`true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1)))`
			`possible_positives = K.sum(K.round(K.clip(y_true, 0, 1)))`
			`return true_positives / (possible_positives + K.epsilon())`


			`def f1_score(y_true, y_pred):`
			`return f_score(1)(y_true, y_pred)`


			`def f05_score(y_true, y_pred):`
			`return f_score(0.5)(y_true, y_pred)`


			`def f_score(beta):`
			`def _f(y_true, y_pred):`
			`p = precision(y_true, y_pred)`
			`r = recall(y_true, y_pred)`

			`bb = beta ** 2`

			`fbeta_score = (1 + bb) * (p * r) / (bb * p + r + K.epsilon())`

			`return fbeta_score`

			`return _f`