Keras: Save and Load Your Keras Deep Learning Model
Sumber: https://machinelearningmastery.com/save-load-keras-deep-learning-models/
Keras is a simple and powerful Python library for deep learning.
Given that deep learning models can take hours, days and even weeks to train, it is important to know how to save and load them from disk.
In this post, you will discover how you can save your Keras models to file and load them up again to make predictions.
After reading this tutorial you will know:
How to save model weights and model architecture in separate files. How to save model architecture in both YAML and JSON format. How to save model weights and architecture into a single file for later use.
Let’s get started.
Update Mar 2017: Added instructions to install h5py first. Update Mar/2017: Updated examples for changes to the Keras API. Update Mar/2018: Added alternate link to download the dataset. Update May/2019: Added section on saving and loading the model to a single file.
Save and Load Your Keras Deep Learning Models
How to Save and Load Your Keras Deep Learning Models Photo by art_inthecity, some rights reserved. Tutorial Overview
Keras separates the concerns of saving your model architecture and saving your model weights.
Model weights are saved to HDF5 format. This is a grid format that is ideal for storing multi-dimensional arrays of numbers.
The model structure can be described and saved using two different formats: JSON and YAML.
In this post we are going to look at two examples of saving and loading your model to file:
Save Model to JSON. Save Model to YAML.
Each example will also demonstrate saving and loading your model weights to HDF5 formatted files.
The examples will use the same simple network trained on the Pima Indians onset of diabetes binary classification dataset. This is a small dataset that contains all numerical data and is easy to work with. You can download this dataset and place it in your working directory with the filename “pima-indians-diabetes.csv” (update: download from here).
Confirm that you have the latest version of Keras installed (e.g. v2.2.4 as of May 2019).
Note: Saving models requires that you have the h5py library installed. You can install it easily as follows:
sudo pip install h5py
Save Your Neural Network Model to JSON
JSON is a simple file format for describing data hierarchically.
Keras provides the ability to describe any model using JSON format with a to_json() function. This can be saved to file and later loaded via the model_from_json() function that will create a new model from the JSON specification.
The weights are saved directly from the model using the save_weights() function and later loaded using the symmetrical load_weights() function.
The example below trains and evaluates a simple model on the Pima Indians dataset. The model is then converted to JSON format and written to model.json in the local directory. The network weights are written to model.h5 in the local directory.
The model and weight data is loaded from the saved files and a new model is created. It is important to compile the loaded model before it is used. This is so that predictions made using the model can use the appropriate efficient computation from the Keras backend.
The model is evaluated in the same way printing the same evaluation score.
# MLP for Pima Indians Dataset Serialize to JSON and HDF5 from keras.models import Sequential from keras.layers import Dense from keras.models import model_from_json import numpy import os # fix random seed for reproducibility numpy.random.seed(7) # load pima indians dataset dataset = numpy.loadtxt("pima-indians-diabetes.csv", delimiter=",") # split into input (X) and output (Y) variables X = dataset[:,0:8] Y = dataset[:,8] # create model model = Sequential() model.add(Dense(12, input_dim=8, kernel_initializer='uniform', activation='relu')) model.add(Dense(8, kernel_initializer='uniform', activation='relu')) model.add(Dense(1, kernel_initializer='uniform', activation='sigmoid')) # Compile model model.compile(loss='binary_crossentropy', optimizer='adam', metrics=['accuracy']) # Fit the model model.fit(X, Y, epochs=150, batch_size=10, verbose=0) # evaluate the model scores = model.evaluate(X, Y, verbose=0) print("%s: %.2f%%" % (model.metrics_names[1], scores[1]*100)) # serialize model to JSON model_json = model.to_json() with open("model.json", "w") as json_file: json_file.write(model_json) # serialize weights to HDF5 model.save_weights("model.h5") print("Saved model to disk") # later... # load json and create model json_file = open('model.json', 'r') loaded_model_json = json_file.read() json_file.close() loaded_model = model_from_json(loaded_model_json) # load weights into new model loaded_model.load_weights("model.h5") print("Loaded model from disk") # evaluate loaded model on test data loaded_model.compile(loss='binary_crossentropy', optimizer='rmsprop', metrics=['accuracy']) score = loaded_model.evaluate(X, Y, verbose=0) print("%s: %.2f%%" % (loaded_model.metrics_names[1], score[1]*100))
Running this example provides the output below.
acc: 78.78% Saved model to disk Loaded model from disk acc: 78.78%
The JSON format of the model looks like the following:
{ "class_name":"Sequential", "config":{ "name":"sequential_1", "layers":[ { "class_name":"Dense", "config":{ "name":"dense_1", "trainable":true, "batch_input_shape":[ null, 8 ], "dtype":"float32", "units":12, "activation":"relu", "use_bias":true, "kernel_initializer":{ "class_name":"RandomUniform", "config":{ "minval":-0.05, "maxval":0.05, "seed":null } }, "bias_initializer":{ "class_name":"Zeros", "config":{ } }, "kernel_regularizer":null, "bias_regularizer":null, "activity_regularizer":null, "kernel_constraint":null, "bias_constraint":null } }, { "class_name":"Dense", "config":{ "name":"dense_2", "trainable":true, "units":8, "activation":"relu", "use_bias":true, "kernel_initializer":{ "class_name":"RandomUniform", "config":{ "minval":-0.05, "maxval":0.05, "seed":null } }, "bias_initializer":{ "class_name":"Zeros", "config":{ } }, "kernel_regularizer":null, "bias_regularizer":null, "activity_regularizer":null, "kernel_constraint":null, "bias_constraint":null } }, { "class_name":"Dense", "config":{ "name":"dense_3", "trainable":true, "units":1, "activation":"sigmoid", "use_bias":true, "kernel_initializer":{ "class_name":"RandomUniform", "config":{ "minval":-0.05, "maxval":0.05, "seed":null } }, "bias_initializer":{ "class_name":"Zeros", "config":{ } }, "kernel_regularizer":null, "bias_regularizer":null, "activity_regularizer":null, "kernel_constraint":null, "bias_constraint":null } } ] }, "keras_version":"2.2.4", "backend":"tensorflow" }
Save Your Neural Network Model to YAML
This example is much the same as the above JSON example, except the YAML format is used for the model specification.
The model is described using YAML, saved to file model.yaml and later loaded into a new model via the model_from_yaml() function. Weights are handled in the same way as above in HDF5 format as model.h5.
# MLP for Pima Indians Dataset serialize to YAML and HDF5 from keras.models import Sequential from keras.layers import Dense from keras.models import model_from_yaml import numpy import os # fix random seed for reproducibility seed = 7 numpy.random.seed(seed) # load pima indians dataset dataset = numpy.loadtxt("pima-indians-diabetes.csv", delimiter=",") # split into input (X) and output (Y) variables X = dataset[:,0:8] Y = dataset[:,8] # create model model = Sequential() model.add(Dense(12, input_dim=8, kernel_initializer='uniform', activation='relu')) model.add(Dense(8, kernel_initializer='uniform', activation='relu')) model.add(Dense(1, kernel_initializer='uniform', activation='sigmoid')) # Compile model model.compile(loss='binary_crossentropy', optimizer='adam', metrics=['accuracy']) # Fit the model model.fit(X, Y, epochs=150, batch_size=10, verbose=0) # evaluate the model scores = model.evaluate(X, Y, verbose=0) print("%s: %.2f%%" % (model.metrics_names[1], scores[1]*100)) # serialize model to YAML model_yaml = model.to_yaml() with open("model.yaml", "w") as yaml_file: yaml_file.write(model_yaml) # serialize weights to HDF5 model.save_weights("model.h5") print("Saved model to disk") # later... # load YAML and create model yaml_file = open('model.yaml', 'r') loaded_model_yaml = yaml_file.read() yaml_file.close() loaded_model = model_from_yaml(loaded_model_yaml) # load weights into new model loaded_model.load_weights("model.h5") print("Loaded model from disk") # evaluate loaded model on test data loaded_model.compile(loss='binary_crossentropy', optimizer='rmsprop', metrics=['accuracy']) score = loaded_model.evaluate(X, Y, verbose=0) print("%s: %.2f%%" % (loaded_model.metrics_names[1], score[1]*100))
Running the example displays the following output:
acc: 78.78% Saved model to disk Loaded model from disk acc: 78.78%
The model described in YAML format looks like the following:
backend: tensorflow class_name: Sequential config: layers: - class_name: Dense config: activation: relu activity_regularizer: null batch_input_shape: !!python/tuple [null, 8] bias_constraint: null bias_initializer: class_name: Zeros config: {} bias_regularizer: null dtype: float32 kernel_constraint: null kernel_initializer: class_name: RandomUniform config: {maxval: 0.05, minval: -0.05, seed: null} kernel_regularizer: null name: dense_1 trainable: true units: 12 use_bias: true - class_name: Dense config: activation: relu activity_regularizer: null bias_constraint: null bias_initializer: class_name: Zeros config: {} bias_regularizer: null kernel_constraint: null kernel_initializer: class_name: RandomUniform config: {maxval: 0.05, minval: -0.05, seed: null} kernel_regularizer: null name: dense_2 trainable: true units: 8 use_bias: true - class_name: Dense config: activation: sigmoid activity_regularizer: null bias_constraint: null bias_initializer: class_name: Zeros config: {} bias_regularizer: null kernel_constraint: null kernel_initializer: class_name: RandomUniform config: {maxval: 0.05, minval: -0.05, seed: null} kernel_regularizer: null name: dense_3 trainable: true units: 1 use_bias: true name: sequential_1 keras_version: 2.2.4
Save Model Weights and Architecture Together
Keras also supports a simpler interface to save both the model weights and model architecture together into a single H5 file.
Saving the model in this way includes everything we need to know about the model, including:
Model weights. Model architecture. Model compilation details (loss and metrics). Model optimizer state.
This means that we can load and use the model directly, without having to re-compile it as we did in the examples above.
Note: this is the preferred way for saving and loading your Keras model. How to Save a Keras Model
You can save your model by calling the save() function on the model and specifying the filename.
The example below demonstrates this by first fitting a model, evaluating it and saving it to the file model.h5.
# MLP for Pima Indians Dataset saved to single file from numpy import loadtxt from keras.models import Sequential from keras.layers import Dense # load pima indians dataset dataset = loadtxt("pima-indians-diabetes.csv", delimiter=",") # split into input (X) and output (Y) variables X = dataset[:,0:8] Y = dataset[:,8] # define model model = Sequential() model.add(Dense(12, input_dim=8, activation='relu')) model.add(Dense(8, activation='relu')) model.add(Dense(1, activation='sigmoid')) # compile model model.compile(loss='binary_crossentropy', optimizer='adam', metrics=['accuracy']) # Fit the model model.fit(X, Y, epochs=150, batch_size=10, verbose=0) # evaluate the model scores = model.evaluate(X, Y, verbose=0) print("%s: %.2f%%" % (model.metrics_names[1], scores[1]*100)) # save model and architecture to single file model.save("model.h5") print("Saved model to disk")
Running the example fits the model, summarizes the models performance on the training dataset and saves the model to file.
acc: 77.73% Saved model to disk
We can later load this model from file and use it.
How to Load a Keras Model
Your saved model can then be loaded later by calling the load_model() function and passing the filename. The function returns the model with the same architecture and weights.
In this case, we load the model, summarize the architecture and evaluate it on the same dataset to confirm the weights and architecture are the same.
# load and evaluate a saved model from numpy import loadtxt from keras.models import load_model # load model model = load_model('model.h5') # summarize model. model.summary() # load dataset dataset = loadtxt("pima-indians-diabetes.csv", delimiter=",") # split into input (X) and output (Y) variables X = dataset[:,0:8] Y = dataset[:,8] # evaluate the model score = model.evaluate(X, Y, verbose=0) print("%s: %.2f%%" % (model.metrics_names[1], score[1]*100))
Running the example first loads the model, prints a summary of the model architecture then evaluates the loaded model on the same dataset.
The model achieves the same accuracy score which in this case is 77%.
_________________________________________________________________ Layer (type) Output Shape Param # ================================================================= dense_1 (Dense) (None, 12) 108 _________________________________________________________________ dense_2 (Dense) (None, 8) 104 _________________________________________________________________ dense_3 (Dense) (None, 1) 9 ================================================================= Total params: 221 Trainable params: 221 Non-trainable params: 0 _________________________________________________________________ acc: 77.73%
Further Reading
How can I save a Keras model? in the Keras documentation. About Keras models in the Keras documentation.
Summary
In this post, you discovered how to serialize your Keras deep learning models.
You learned how you can save your trained models to files and later load them up and use them to make predictions.
You also learned that model weights are easily stored using HDF5 format and that the network structure can be saved in either JSON or YAML format.