1

*Update at bottom

I am trying to use recall on 2 of 3 classes as a metric, so class B and C from classes A,B,C.

(The original nature of this is that my model is highly imbalanced in the classes [~90% is class A], such that when I use accuracy I get results of ~90% for prediciting class A everytime)

model.compile(
              loss='sparse_categorical_crossentropy', #or categorical_crossentropy
              optimizer=opt,
              metrics=[tf.keras.metrics.Recall(class_id=1, name='recall_1'),tf.keras.metrics.Recall(class_id=2, name='recall_2')]
              )

history = model.fit(train_x, train_y, batch_size=BATCH, epochs=EPOCHS, validation_data=(validation_x, validation_y), callbacks=[tensorboard, checkpoint])

This spits out an error:

raise ValueError("Shapes %s and %s are incompatible" % (self, other))

ValueError: Shapes (None, 3) and (None, 1) are incompatible

Model summary is:

Model: "sequential"
_________________________________________________________________
Layer (type)                 Output Shape              Param #
=================================================================
lstm (LSTM)                  (None, 120, 32)           19328
_________________________________________________________________
dropout (Dropout)            (None, 120, 32)           0
_________________________________________________________________
batch_normalization (BatchNo (None, 120, 32)           128
_________________________________________________________________
lstm_1 (LSTM)                (None, 120, 32)           8320
_________________________________________________________________
dropout_1 (Dropout)          (None, 120, 32)           0
_________________________________________________________________
batch_normalization_1 (Batch (None, 120, 32)           128
_________________________________________________________________
lstm_2 (LSTM)                (None, 32)                8320
_________________________________________________________________
dropout_2 (Dropout)          (None, 32)                0
_________________________________________________________________
batch_normalization_2 (Batch (None, 32)                128
_________________________________________________________________
dense (Dense)                (None, 32)                1056
_________________________________________________________________
dropout_3 (Dropout)          (None, 32)                0
_________________________________________________________________
dense_1 (Dense)              (None, 3)                 99
=================================================================
Total params: 37,507
Trainable params: 37,315
Non-trainable params: 192

Note that the model works fine without the errors if using:

metrics=['accuracy']

but this and this made me think something has not been implemented along the lines of tf.metrics.SparseCategoricalRecall()

from

tf.metrics.SparseCategoricalAccuracy()


So I diverted to a custom metric which decended into a rabbit hole of other issues as I am highly illeterate when it comes to classes and decorators.

I botched this together from an custom metric example (I have no idea how to use the sample_weight so I commented it out to come back to later):

class RelevantRecall(tf.keras.metrics.Metric):

    def __init__(self, name="Relevant_Recall", **kwargs):
        super(RelevantRecall, self).__init__(name=name, **kwargs)
        self.joined_recall = self.add_weight(name="B/C Recall", initializer="zeros")

    def update_state(self, y_true, y_pred, sample_weight=None):
        y_pred = tf.argmax(y_pred, axis=1)
        report_dictionary = classification_report(y_true, y_pred, output_dict = True)

        # if sample_weight is not None:
        #     sample_weight = tf.cast(sample_weight, "float32")
        #     values = tf.multiply(values, sample_weight)
        # self.joined_recall.assign_add(tf.reduce_sum(values))

        self.joined_recall.assign_add((float(report_dictionary['1.0']['recall'])+float(report_dictionary['2.0']['recall']))/2)
 
    def result(self):
        return self.joined_recall

    def reset_states(self):
        # The state of the metric will be reset at the start of each epoch.
        self.joined_recall.assign(0.0)


model.compile(
              loss='sparse_categorical_crossentropy', #or categorical_crossentropy
              optimizer=opt,
              metrics=[RelevantRecall()]
              )


history = model.fit(train_x, train_y, batch_size=BATCH, epochs=EPOCHS, validation_data=(validation_x, validation_y), callbacks=[tensorboard, checkpoint])

This aim is to return a metric of [recall(b)+recall(c)/2]. I'd imagine returning both recalls seperately like metrics=[recall(b),recall(c)] would be better but I can't get the former to work anyway.

I got a tensor bool error: OperatorNotAllowedInGraphError: using a 'tf.Tensor' as a Python 'bool' is not allowed: AutoGraph did convert this function. This might indicate you are trying to use an unsupported feature. which googling led me to add: @tf.function above my custom metric class.

This led to a old vs new class type error:

super(RelevantRecall, self).__init__(name=name, **kwargs)
TypeError: super() argument 1 must be type, not Function

which I didn't see how I had achieved since the class has an object?

As I said I'm quite new to all aspects of this so any help on how to achieve (and how best to achieve) using a metric of only a selection of prediciton classes would be really appreciated.

OR

if I am going about this entirely wrong let me know/guide me to the correct resource please

Ideally I'd like to go with the former method of using tf.keras.metrics.Recall(class_id=1.... as it seems the neatest way if it worked.

I am able to get the recall for each class when using a similar function in the callbacks part of the model, but this seems more intensive as I have to do a model.predict on val/test data at the end of each epoch. Also unclear if this even tells the model to focus on improving the selected class (i.e difference in implementing it in metric vs callback)


Callback code:

class MetricsCallback(Callback):
    def __init__(self, test_data, y_true):
        # Should be the label encoding of your classes
        self.y_true = y_true
        self.test_data = test_data

    def on_epoch_end(self, epoch, logs=None):
        # Here we get the probabilities - longer process
        y_pred = self.model.predict(self.test_data)

        # Here we get the actual classes
        y_pred = tf.argmax(y_pred,axis=1)
        report_dictionary = classification_report(self.y_true, y_pred, output_dict = True)
        print ("\n")
  
        print (f"Accuracy: {report_dictionary['accuracy']} - Holds: {report_dictionary['0.0']['recall']} - Sells: {report_dictionary['1.0']['recall']} - Buys: {report_dictionary['2.0']['recall']}")
        self._data = (float(report_dictionary['1.0']['recall'])+float(report_dictionary['2.0']['recall']))/2
        return

metrics_callback = MetricsCallback(test_data = validation_x, y_true = validation_y)

history = model.fit(train_x, train_y, batch_size=BATCH, epochs=EPOCHS, validation_data=(validation_x, validation_y), callbacks=[tensorboard, checkpoint, metrics_callback) 

Update 19/07/2021

  • I have resorted to using categorical_crossentropy for loss instead of sparse_categorical_crossentropy.
  • One-hot-encoding my class/target arrays.
  • Using tf recall: [tf.keras.metrics.Recall(class_id=1, name='recall_1')

I am now using the code below.

train_y = tf.one_hot(train_y, 3)
validation_y = tf.one_hot(validation_y, 3)
test_y = tf.one_hot(test_y, 3)

model.compile(
    loss='categorical_crossentropy',
    optimizer=opt,
    metrics=[tf.keras.metrics.Recall(class_id=1, name='No'),tf.keras.metrics.Recall(class_id=2, name='Yes')]
    ) #tf.keras.metrics.Recall(class_id=0, name='Wait')

history = model.fit(train_x, train_y, batch_size=BATCH, epochs=EPOCHS, validation_data=(validation_x, validation_y), callbacks=[tensorboard, checkpoint])

Thanks to Abhishek Prajapat

This achieves the same overall goal and probably has a very small difference/impact on performance due to a small number of mutually exclusive classes,

but in the case of a very large number of mutually exclusive classes I still don't have an solution to achieving the same goal as above using sparse_categorical_crossentropy

2
+100

Your problem is quite simple. I have put together a example for you:

import tensorflow as tf
from sklearn.datasets import make_classification

data = make_classification(n_samples=1000, n_features=20, n_classes=3, n_clusters_per_class=1)

model = tf.keras.Sequential([
    tf.keras.layers.InputLayer(input_shape=(20)),
    tf.keras.layers.Dense(3, activation='softmax')
])

model.compile(
              loss=tf.keras.losses.CategoricalCrossentropy(), #or categorical_crossentropy
              optimizer='adam',
              metrics = [tf.keras.metrics.Recall(class_id=1)]
              )

y = tf.keras.utils.to_categorical(data[1], num_classes=3)

dataset = tf.data.Dataset.from_tensor_slices((data[0], y))
dataset = dataset.batch(10)

model.fit(dataset, epochs=10)

Now as you can see that when you use metrics.Recall with a particular class id then your input y should be one-hot encoded. So if we have 3 classes then for 0 it should be -> [1, 0, 0] and so on 1 -> [0, 1, 0] and 2 -> [0, 0, 1].

Without using extra memory

import tensorflow as tf
from sklearn.datasets import make_classification

data = make_classification(n_samples=1000, n_features=20, n_classes=3, n_clusters_per_class=1)

model = tf.keras.Sequential([
    tf.keras.layers.InputLayer(input_shape=(20)),
    tf.keras.layers.Dense(3, activation='softmax')
])

model.compile(
              loss=tf.keras.losses.CategoricalCrossentropy(), #or categorical_crossentropy
              optimizer='adam',
              metrics = [tf.keras.metrics.Recall(class_id=1)]
              )

def encode(x, y):
    y = tf.one_hot(y, 3) # Here 3 is the number of classes
    return x, y

dataset = tf.data.Dataset.from_tensor_slices((data[0], data[1]))
dataset = dataset.map(encode)
dataset = dataset.batch(10)

model.fit(dataset, epochs=10)

New example -

import numpy as np
import tensorflow as tf
from sklearn.datasets import make_classification

data = make_classification(n_samples=1000, n_features=20, n_classes=3, n_clusters_per_class=1)

model = tf.keras.Sequential([
    tf.keras.layers.InputLayer(input_shape=(20)),
    tf.keras.layers.Dense(3, activation='softmax')
])

def encode(x, y):
    y = tf.one_hot(y, 3)
    return x, y

dataset = tf.data.Dataset.from_tensor_slices((data[0], data[1]))
dataset = dataset.map(encode)
dataset = dataset.batch(10)

m1 = tf.keras.metrics.Recall()
m2 = tf.keras.metrics.Recall()

def my_recall(y_true, y_pred):
    
    actual_a = y_true[:, 1]
    pred_a = y_pred[:, 1]
    
    actual_b = y_true[:, 2]
    pred_b = y_pred[:, 2]
    
    m1.update_state(actual_a, pred_a)
    m2.update_state(actual_b, pred_b)
    
    return (m1.result() + m2.result())/2

model.compile(
              loss=tf.keras.losses.CategoricalCrossentropy(), #or categorical_crossentropy
              optimizer='adam',
              metrics = [my_recall]
              )

model.fit(dataset, epochs=10)

For you updated question -

import numpy as np
import tensorflow as tf
from sklearn.datasets import make_classification

data = make_classification(n_samples=1000, n_features=20, n_classes=3, n_clusters_per_class=1)

model = tf.keras.Sequential([
    tf.keras.layers.InputLayer(input_shape=(20)),
    tf.keras.layers.Dense(3, activation='softmax')
])

dataset = tf.data.Dataset.from_tensor_slices((data[0], data[1]))
dataset = dataset.batch(10)

m1 = tf.keras.metrics.Recall()
m2 = tf.keras.metrics.Recall()

def my_recall(y_true, y_pred):
    y_true = tf.cast(y_true, dtype=tf.int32)
    actual_onehot = tf.one_hot(y_true, 3)
    actual_a = actual_onehot[1]
    pred_a = tf.reshape(y_pred[1], (1,3))
    actual_b = actual_onehot[2]
    pred_b = tf.reshape(y_pred[2], (1,3))  
    m1.update_state(actual_a, pred_a)
    m2.update_state(actual_b, pred_b)   
    return (m1.result() + m2.result())/2

model.compile(
              loss=tf.keras.losses.SparseCategoricalCrossentropy(),
              optimizer='adam',          
              metrics = [my_recall]
              )

model.fit(dataset, epochs=10)
17
  • this is for CategoricalCrossentropy. I am using sparse_categorical_crossentropy, unless you are suggesting that sparse_categorical_crossentropy is incorrectly being used? from what I gathered here, since my classes are mutually exclusive, I'd be wasting memory and time using CategoricalCrossentropy? So then is recall not available to use for sparse? which seemed to be what the github links in question posed..
    – Panda
    Jul 15 at 0:55
  • I have edited the answer for not creating memory overhead but as for Recall not available for Sparse that I am not sure about but as you can see that the metrics for Sparse have Sparce written in their implementation so that might be the case. Jul 15 at 1:09
  • @Panda if this solves your question then I will be happy to receive that bounty. Jul 15 at 2:30
  • Sorry not really got the a solution here. where is this "the metrics for Sparse have Sparce written"? as for the overhead I beleive this refers to feeding the model one hot coding lables instead of integers labels, as you have more information that is not needed, not in the actual implementation of one hot. Also I said I am able to get the recall using sparse_categorical_crossentropy from a custom call back so at the very lease I expect that to be something I can do for metrics. I've added the code for that, but here it has to do another predict on valuation data which to my mind is repetition
    – Panda
    Jul 15 at 7:07
  • oh... No problem. I put together another example for you. Here you go. As for "the metrics for Sparse have Sparse written" had a spelling mistake in Sparse and I have written that 'I am not sure' that's cause I have seen that in the metrics class name. You will be more sure if you look at this source code of Recall. github.com/tensorflow/tensorflow/blob/v2.5.0/tensorflow/python/…. Jul 15 at 14:25

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