15

I built a custom architecture with keras (a convnet). The network has 4 heads, each outputting a tensor of different size. I am trying to write a custom loss function as a function of this 4 outputs. I have been implementing cusutom losses before, but it was either a different loss for each head or the same loss for each head. In this case, I need to combine the 4 outputs to calculate the loss.

I am used to the following:

def custom_loss(y_true, y_pred):
    return something
model.compile(optimizer, loss=custom_loss)

but in my case, I would need y_pred to be a list of the 4 outputs. I can pad the outputs with zeros and add a concatenate layer in my model, but I was wondering if there was an easier way around.

Edit

My loss function is rather complex, can I write something like:

model.add_loss(custom_loss(input1, input2, output1, output2))

where custom loss is defined as:

def custom_loss(input1, input2, output1, output2):
    return loss

3 Answers 3

20

You could try the model.add_loss() function. The idea is to construct your custom loss as a tensor instead of a function, add it to the model, and compile the model without further specifying a loss. See also this implementation of a variational autoencoder where a similar idea is used.

Example:

import keras.backend as K
from keras.layers import Input, Dense
from keras.models import Model
from keras.losses import mse
import numpy as np

# Some random training data
features = np.random.rand(100,20)
labels_1 = np.random.rand(100,4)
labels_2 = np.random.rand(100,1)

# Input layer, one hidden layer
input_layer = Input((20,))
dense_1 = Dense(128)(input_layer)

# Two outputs
output_1 = Dense(4)(dense_1)
output_2 = Dense(1)(dense_1)

# Two additional 'inputs' for the labels
label_layer_1 = Input((4,))
label_layer_2 = Input((1,))

# Instantiate model, pass label layers as inputs
model = Model(inputs=[input_layer, label_layer_1, label_layer_2], outputs=[output_1, output_2])

# Construct your custom loss as a tensor
loss = K.mean(mse(output_1, label_layer_1) * mse(output_2, label_layer_2))

# Add loss to model
model.add_loss(loss)

# Compile without specifying a loss
model.compile(optimizer='sgd')

dummy = np.zeros((100,))
model.fit([features, labels_1, labels_2], dummy, epochs=2)
7
  • 3
    how do you pass validation data using this method? the bracketings does not follow the normal definition of val_data = (Xval, [Yval1, Yval2, ...])
    – Corse
    Dec 9, 2019 at 8:32
  • 5
    This solution is not valid for tensorflow==2.1.0 and not valid for Keras==2.3.1. Can you please help revise this answer to reflect the updated packages? And is it possible to recall what version of the packages was used to generate this answer? May 6, 2020 at 11:12
  • Hi, this was for sure with tensorflow 1.x. I don't really have time to figure it out right now, but I'll add a disclaimer to my answer
    – sdcbr
    May 6, 2020 at 15:45
  • 1
    This worked for me! I'm using tensorflow==2.2.0 and tf.keras. Perhaps vanilla keras does not have this functionality? Jun 27, 2020 at 5:28
  • 2
    I don't see a reason why this should not work. And in fact it does, just tested with the latest nightly from today (2.5.0.dev20201028). There is just a type-o in the loss function and the fit call was not correct, the latter leading to people thinking this does not work any more. I have edited the answer and hope this will get accepted soon.
    – Pedro
    Oct 28, 2020 at 15:54
1

You could pack your outputs together in a tf.ExtensionType, and unpack it again in the loss function.

I made a Colab Notebook that demonstrates how to do this in tensorflow 2.8.0. (https://colab.research.google.com/drive/1MjlddizqFlezAUu5SOOW8svlnKQH4rog#scrollTo=pDMskk-86wFY)

Pros of using this approach vs add_loss():

  • No need to define "dummy" labels at inference time.
  • No need to define the loss within the model.
  • pretty nice

Cons:

  • your model now outputs an object with the outputs as fields instead of the tensors directly (which is maybe a pro for your use case).
  • At the time of writing this answer, tf.ExtensionTypess don't work with Tensorflow Serving)

I'm adding the full code here, just in case I accidentally delete the Colab Notebook:

import tensorflow as tf
import tensorflow_datasets as tfds
# tf.__version__ should be >= 2.8.0
print(tf.__version__)


class PackedTensor(tf.experimental.BatchableExtensionType):
    __name__ = 'extension_type_colab.PackedTensor'

    output_0: tf.Tensor
    output_1: tf.Tensor

    # shape and dtype hold no meaning in this context, so we use a dummy
    # to stop Keras from complaining

    shape = property(lambda self: self.output_0.shape)
    dtype = property(lambda self: self.output_0.dtype)

    class Spec:

        def __init__(self, shape, dtype=tf.float32):
            self.output_0 = tf.TensorSpec(shape, dtype)
            self.output_1 = tf.TensorSpec(shape, dtype)

        # shape and dtype hold no meaning in this context, so we use a dummy
        # to stop Keras from complaining
        shape: tf.TensorShape = tf.constant(1.).shape 
        dtype: tf.DType = tf.constant(1.).dtype


# these two functions have no meaning, but need dummy implementations
# to stop Keras from complaining
@tf.experimental.dispatch_for_api(tf.shape)
def packed_shape(input: PackedTensor, out_type=tf.int32, name=None):
    return tf.shape(input.col_ids)

@tf.experimental.dispatch_for_api(tf.cast)
def packed_cast(x: PackedTensor, dtype: str, name=None):
    return x


class SCCEWithExtraOutput(tf.keras.losses.Loss):
    """ This custom loss function is designed for models with an PackedTensor as
    a single output, so with attributes outputs_0 and outputs_1. This loss will 
    train a model so that outputs_0 represent the predicted class of the input
    image, and outputs_1 will be trained to always be zero (as a dummy). 
    """
    def __init__(self, *args, **kwargs):
        super(SCCEWithExtraOutput, self).__init__(*args, **kwargs)
        self.loss_fn = tf.keras.losses.SparseCategoricalCrossentropy(from_logits=True)

    def call(self, y_true, y_pred):
        output_0, output_1 = y_pred.output_0, y_pred.output_1
        scce = self.loss_fn(y_true, output_0)
        return scce + tf.abs(output_1)



# load the datasets
(ds_train, ds_test), ds_info = tfds.load(
    'mnist',
    split=['train', 'test'],
    shuffle_files=True,
    as_supervised=True,
    with_info=True,
)
def normalize_img(image, label):
  """Normalizes images: `uint8` -> `float32`."""
  return tf.cast(image, tf.float32) / 255., label

ds_train = ds_train.map(normalize_img, num_parallel_calls=tf.data.AUTOTUNE)
ds_train = ds_train.cache()
ds_train = ds_train.shuffle(ds_info.splits['train'].num_examples)
ds_train = ds_train.batch(128)
ds_train = ds_train.prefetch(tf.data.AUTOTUNE)
ds_test = ds_test.map(normalize_img, num_parallel_calls=tf.data.AUTOTUNE)
ds_test = ds_test.batch(128)
ds_test = ds_test.cache()
ds_test = ds_test.prefetch(tf.data.AUTOTUNE)


# create a layer to combine to pack the outputs in a PackedTensor
class PackingLayer(tf.keras.layers.Layer):
  def call(self, inputs, training=None):
    first_output, second_output = inputs
    packed_output = PackedTensor(first_output, second_output)
    return packed_output

# define the model
#
# inputs -> flatten -> hidden -> Dense(10) -> PackingLayer() -> outputs
#                           |--> Dense(1)  ----^ 
inputs = tf.keras.Input(shape=(28, 28, 1), dtype=tf.float32)
flatten_layer = tf.keras.layers.Flatten()
hidden_layer = tf.keras.layers.Dense(128, activation='relu')
first_output_layer = tf.keras.layers.Dense(10)
second_output_layer = tf.keras.layers.Dense(1)
packing_layer = PackingLayer()

hidden = flatten_layer(inputs)
hidden = hidden_layer(hidden)
first_output = first_output_layer(hidden)
second_output = second_output_layer(hidden)
outputs = packing_layer((first_output, second_output))
model = tf.keras.Model(inputs=inputs, outputs=outputs)

model.compile(
    optimizer=tf.keras.optimizers.Adam(0.001),
    loss=SCCEWithExtraOutput(),
    # metrics=[tf.keras.metrics.SparseCategoricalAccuracy()],
)

model.fit(
    ds_train,
    epochs=1,
    # validation_data=ds_test,
)
model.save("savedmodel")

for index, sample in enumerate(ds_train):
  predicted_packed_tensor = model(sample[0])
  print(predicted_packed_tensor.output_0.shape, predicted_packed_tensor.output_1.shape)
  print(type(predicted_packed_tensor))
  if index > 10:
    break



# prove we can also load and infer the model in a completely new process
# notice that as the class PackedTensor does not exist in this process,
# the model now returns a tensorflow.python.framework.extension_type.AnonymousExtensionType
# with attributes "output_0" and "output_1".

import subprocess

script = """
import tensorflow as tf
import tensorflow_datasets as tfds
model = tf.saved_model.load("savedmodel")
(ds_train, ds_test), ds_info = tfds.load(
    'mnist',
    split=['train', 'test'],
    shuffle_files=True,
    as_supervised=True,
    with_info=True,
)
def normalize_img(image, label):
  return tf.cast(image, tf.float32) / 255., label

ds_train = ds_train.map(normalize_img, num_parallel_calls=tf.data.AUTOTUNE)
ds_train = ds_train.batch(20)

for index, sample in enumerate(ds_train):
  predicted = model(sample[0])
  print(predicted.output_0.shape, predicted.output_1.shape)
  print(type(predicted))
  if index > 5:
    break
"""
pipes = subprocess.Popen(["python3", "-c", script], stdout=subprocess.PIPE, stderr=subprocess.PIPE)
std_out, std_err = pipes.communicate()
for line in std_out.decode().split("\n"):
  print(line)

0

dummy variables are not needed when fit the model

so, you might use model.fit([features, labels_1, labels_2], epochs=2)

then it works well under

tensorflow version '1.14.0' keras.version '2.3.1'

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