11

I have only one output for my model, but I would like to combine two different loss functions:

def get_model():
    # create the model here
    model = Model(inputs=image, outputs=output)

    alpha = 0.2
    model.compile(loss=[mse, gse],
                      loss_weights=[1-alpha, alpha]
                      , ...)

but it complains that I need to have two outputs because I defined two losses:

ValueError: When passing a list as loss, it should have one entry per model outputs. 
The model has 1 outputs, but you passed loss=[<function mse at 0x0000024D7E1FB378>, <function gse at 0x0000024D7E1FB510>]

Can I possibly write my final loss function without having to create another loss function (because that would restrict me from changing the alpha outside the loss function)?

How do I do something like (1-alpha)*mse + alpha*gse?


Update:

Both my loss functions are equivalent to the function signature of any builtin keras loss function, takes in y_true and y_pred and gives a tensor back for loss (which can be reduced to a scalar using K.mean()), but I believe, how these loss functions are defined shouldn't affect the answer as long as they return valid losses.

def gse(y_true, y_pred):
    # some tensor operation on y_pred and y_true
    return K.mean(K.square(y_pred - y_true), axis=-1)
3
  • could you add your gse function? Aug 6, 2018 at 10:46
  • here a simple solution: stackoverflow.com/questions/62861773/… Jul 14, 2020 at 8:32
  • Is it necessary to multiply a value less than 1 to each of the individual losses or can one even multiply a value more than 1. Like for example 5*mse + 3*gse. In this case what can be the pros and cons of the loss formulation? I wanted to know why one needs to have l_1 + l_2 + ... + l_n = 1? Where l_i's are the constants added to each of the loss functions....
    – Jimut123
    Jun 25 at 6:52

4 Answers 4

15

Specify a custom function for the loss:

model = Model(inputs=image, outputs=output)

alpha = 0.2
model.compile(
    loss=lambda y_true, y_pred: (1 - alpha) * mse(y_true, y_pred) + alpha * gse(y_true, y_pred),
    ...)

Or if you don't want an ugly lambda make it into an actual function:

def my_loss(y_true, y_pred):
    return (1 - alpha) * mse(y_true, y_pred) + alpha * gse(y_true, y_pred)

model = Model(inputs=image, outputs=output)

alpha = 0.2
model.compile(loss=my_loss, ...)

EDIT:

If your alpha is not some global constant, you can have a "loss function factory":

def make_my_loss(alpha):
    def my_loss(y_true, y_pred):
        return (1 - alpha) * mse(y_true, y_pred) + alpha * gse(y_true, y_pred)
    return my_loss

model = Model(inputs=image, outputs=output)

alpha = 0.2
my_loss = make_my_loss(alpha)
model.compile(loss=my_loss, ...)
9
  • usually when I define custom losses, I will have to pass that in the dict when loading the model, but if I pass a lambda, do I need to pass that somehow or will it work just right? Aug 6, 2018 at 10:38
  • @SaravanabalagiRamachandran Not sure what dict you are referring to... Are you talking about the model definition part, or checkpointing, or something else? Where exactly would you usually need to put the custom loss you define?
    – jdehesa
    Aug 6, 2018 at 10:40
  • if I save a model with custom losses I will have to tell keras what they are when loading the same. So import gse from somewhere and then load_model(model_file, custom_objects={'gse':gse}. custom_objects dict...! Aug 6, 2018 at 10:42
  • @SaravanabalagiRamachandran Ahh I see, sorry I was not aware of this API of Keras models. I have only saved and restored models using TensorFlow tooling, I'm not sure how Keras mechanism works, so I wouldn't know for sure, but it does seem that all non-standard functions (including lambdas, I'd suspect) have to be passed as custom_objects or provided by a CustomObjectScope...
    – jdehesa
    Aug 6, 2018 at 10:49
  • Yep, it can't seem to get the anonymous function as expected. Throws ValueError: Unknown loss function:<lambda> error when loading the model after saving. Aug 6, 2018 at 10:56
0

Yes, define your own custom loss function and pass that to the loss argument upon compiling:

def custom_loss(y_true, y_pred):
    return (1-alpha) * K.mean(K.square(y_true-y_pred)) + alpha * gse

(Not sure what you mean with gse). It can be helpful to have a look at how the vanilla losses are implemented in Keras: https://github.com/keras-team/keras/blob/master/keras/losses.py

8
  • gse is a function just like mse (Updated the question), so we would have to pass in y_true and y_pred to it when calling, we can't do alpha * gse. Aug 6, 2018 at 10:59
  • Because gse is a function. Try writing it out as a single custom loss function as above.
    – sdcbr
    Aug 6, 2018 at 11:02
  • sorry if I misunderstood you, but alpha would be a scalar like 0.1 or 0.2 and keras wouldn't know how to multiply a function gse or mse with a scalar alpha and would throw TypeError: unsupported operand type(s) for *: 'function' and 'float', wouldn't it? Aug 6, 2018 at 11:05
  • Sorry, I meant that gse is a function. If you write it out as a single custom loss function like above, with gse replace by it's definition, do you still get the error?
    – sdcbr
    Aug 6, 2018 at 11:08
  • gotcha, you suggest to create another loss function incorporating both the losses inside. But alpha can't be changed when I define the model :( Aug 6, 2018 at 11:10
0

loss function should be one function.You are giving your model a list of two functions

try:

def mse(y_true, y_pred):
    return K.mean(K.square(y_pred - y_true), axis=-1)

model.compile(loss= (mse(y_true, y_pred)*(1-alpha) + gse(y_true, y_pred)*alpha),
              , ...)
4
  • You mean to say loss=(mse*(1-alpha) + gse*alpha)? Aug 6, 2018 at 10:34
  • I don't think we can do arithmetic on functions in Python, but anyway I tried but got TypeError: unsupported operand type(s) for *: 'function' and 'float' Aug 6, 2018 at 10:34
  • what is gse function? Aug 6, 2018 at 10:38
  • it is exactly like how you have defined mse in your answer. the problem is it doesn't know what function * float means, so it just complains unsupported operand Aug 6, 2018 at 10:39
0

Not that this answer particularly addresses the original question, I thought of writing it because the same error occurs when trying to load a keras model that has a custom loss using keras.models.load_model, and it's not been properly answered anywhere. Specifically, following the VAE example code in keras github repository, this error occurs when loading the VAE model after been saved with model.save.

The solution is to save only the weights using vae.save_weights('file.h5') instead of saving the full model. However, you would have to build and compile the model again before loading the weights using vae.load_weights('file.h5').

Following is an example implementation.

class VAE():
    def build_model(self): # latent_dim and intermediate_dim can be passed as arguments
        def sampling(args):
            """Reparameterization trick by sampling from an isotropic unit Gaussian.
            # Arguments
                args (tensor): mean and log of variance of Q(z|X)
            # Returns
                z (tensor): sampled latent vector
            """

            z_mean, z_log_var = args
            batch = K.shape(z_mean)[0]
            dim = K.int_shape(z_mean)[1]
            # by default, random_normal has mean = 0 and std = 1.0
            epsilon = K.random_normal(shape=(batch, dim))
            return z_mean + K.exp(0.5 * z_log_var) * epsilon

        # original_dim = self.no_features
        # intermediate_dim = 256
        latent_dim = 8
        inputs = Input(shape=(self.no_features,))
        x = Dense(256, activation='relu')(inputs)
        x = Dense(128, activation='relu')(x)
        x = Dense(64, activation='relu')(x)
        z_mean = Dense(latent_dim, name='z_mean')(x)
        z_log_var = Dense(latent_dim, name='z_log_var')(x)
        # use reparameterization trick to push the sampling out as input
        # note that "output_shape" isn't necessary with the TensorFlow backend
        z = Lambda(sampling, output_shape=(latent_dim,), name='z')([z_mean, z_log_var])
        # instantiate encoder model
        encoder = Model(inputs, [z_mean, z_log_var, z], name='encoder')


        # build decoder model
        latent_inputs = Input(shape=(latent_dim,), name='z_sampling')
        x = Dense(32, activation='relu')(latent_inputs)
        x = Dense(48, activation='relu')(x)
        x = Dense(64, activation='relu')(x)
        outputs = Dense(self.no_features, activation='linear')(x)

        # instantiate decoder model
        decoder = Model(latent_inputs, outputs, name='decoder')

        # instantiate VAE model
        outputs = decoder(encoder(inputs)[2])
        VAE = Model(inputs, outputs, name='vae_mlp')
        reconstruction_loss = mse(inputs, outputs)
        reconstruction_loss *= self.no_features
        kl_loss = 1 + z_log_var - K.square(z_mean) - K.exp(z_log_var)
        kl_loss = K.sum(kl_loss, axis=-1)
        kl_loss *= -0.5
        vae_loss = K.mean(reconstruction_loss + kl_loss)
        VAE.add_loss(vae_loss)
        VAE.compile(optimizer='adam')
        return VAE

Now,

vae_cls = VAE()
vae = vae_cls.build_model()
# vae.fit()
vae.save_weights('file.h5')

Load model and predict (if in a different script, you need to import the VAE class),

vae_cls = VAE()
vae = vae_cls.build_model()
vae.load_weights('file.h5')
# vae.predict()

Finally, The Difference: [ref]

Keras model.save saves,

  1. Model weights
  2. Model architecture
  3. Model compilation details (loss function(s) and metrics)
  4. Model optimizer and regularizer states

Keras model.save_weights saves only the model weights. Keras model.to_json() saves the model architecture.

Hope this helps someone experimenting with variational autoencoders.

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