I've been trying to experiment with Region Based: Dice Loss but there have been a lot of variations on the internet to a varying degree that I could not find two identical implementations. The problem is that all of these produce varying results. Below are the implementations that I found. Some uses smoothing factor which the authors in this paper have called epsilon, some use it in both numerator and denominator, one implementation used Gamma etc etc.

Could someone please help me with the correct implementation.

import tensorflow as tf
import tensorflow.keras.backend as K
import numpy as np

def dice_loss1(y_true, y_pred, smooth=1e-6):
    y_pred = tf.convert_to_tensor(y_pred)
    y_true = tf.cast(y_true, y_pred.dtype)
    smooth = tf.cast(smooth, y_pred.dtype)
    y_pred = K.flatten(y_pred)
    y_true = K.flatten(y_true)
    intersection = K.sum(K.dot(y_true, y_pred))    
    dice_coef = (2*intersection + smooth) / (K.sum(y_true) + K.sum(y_pred) + smooth)
    dice_loss = 1-dice_coef
    return dice_loss

def dice_loss2(y_true, y_pred, smooth=1e-6): # Only Smooth
    y_pred = tf.convert_to_tensor(y_pred)
    y_true = tf.cast(y_true, y_pred.dtype)
    smooth = tf.cast(smooth, y_pred.dtype)
    intersection = K.sum(K.abs(y_true * y_pred), axis=-1)
    dice_coef  = (2. * intersection + smooth) / (K.sum(K.square(y_true),-1) + K.sum(K.square(y_pred),-1) + smooth)
    return 1- dice_coef

def dice_loss3(y_true, y_pred): # No gamma, no smooth
    y_pred = tf.convert_to_tensor(y_pred)
    y_true = tf.cast(y_true, y_pred.dtype)
    y_pred = tf.math.sigmoid(y_pred)
    numerator = 2 * tf.reduce_sum(y_true * y_pred)
    denominator = tf.reduce_sum(y_true + y_pred)

    return 1 - numerator / denominator

def dice_loss4(y_true, y_pred, smooth=1e-6, gama=1): # Gama + Smooth is used
    y_pred = tf.convert_to_tensor(y_pred)
    y_true = tf.cast(y_true, y_pred.dtype)
    smooth = tf.cast(smooth, y_pred.dtype)
    gama = tf.cast(gama, y_pred.dtype)

    nominator = 2 * tf.reduce_sum(tf.multiply(y_pred, y_true)) + smooth
    denominator = tf.reduce_sum(y_pred ** gama) + tf.reduce_sum(y_true ** gama) + smooth

    result = 1 - tf.divide(nominator, denominator)
    return result

y_true = np.array([[0,0,1,0],

y_pred = np.array([[0,0,0.9,0],

# print(dice_loss1(y_true, y_pred)) # Gives you error in K.dot()
print(dice_loss2(y_true, y_pred))
print(dice_loss3(y_true, y_pred)) # provides array of values
print(dice_loss4(y_true, y_pred))

2 Answers 2


I utilized a variation of the dice loss for brain tumor segmentation. The implementation for the dice coefficient which I used for such results was:

def dice_coef(y_true, y_pred, smooth=100):        
    y_true_f = K.flatten(y_true)
    y_pred_f = K.flatten(y_pred)
    intersection = K.sum(y_true_f * y_pred_f)
    dice = (2. * intersection + smooth) / (K.sum(y_true_f) + K.sum(y_pred_f) + smooth)
    return dice

In order to make it a loss, it needs to be made into a function we want to minimize. This can be accomplished by making it negative:

def dice_coef_loss(y_true, y_pred):
    return -dice_coef(y_true, y_pred)

or subtracting it from 1:

def dice_coef_loss(y_true, y_pred):
    return 1 - dice_coef(y_true, y_pred)

or applying some other function then negating - for example, taking the negative logarithm (which could smooth the gradients):

def dice_coef_loss(y_true, y_pred):
    return -K.log(dice_coef(y_true, y_pred))

The variable smooth represents your observation in other implementations with various names (smoothing, epsilon, etc.). Just for clarity, this smoothing variable exists to handle the case where the ground truth has very few white (or no) white pixels (assuming white pixels belonging to a class or boundary of an object, depending on your implementation).

If smooth is set too low, when the ground truth has few to 0 white pixels and the predicted image has some non-zero number of white pixels, the model will be penalized more heavily. Setting smooth higher means if the predicted image has some low amount of white pixels when the ground truth has none, the loss value will be lower. Depending on how aggressive the model needs to be, though, maybe a lower value is good.

Here's an illustrative example:

import numpy as np
import tensorflow as tf
from tensorflow.keras import backend as K

def dice_coef(y_true, y_pred, smooth):
    y_true_f = K.flatten(y_true)
    y_pred_f = K.flatten(y_pred)
    intersection = K.sum(y_true_f * y_pred_f)
    dice = (2. * intersection + smooth) / (K.sum(y_true_f) + K.sum(y_pred_f) + smooth)
    return dice

def dice_coef_loss(y_true, y_pred, smooth):
    return 1 - dice_coef(y_true, y_pred, smooth)

if __name__ == '__main__':
    smooth = 10e-6
    y_pred = np.zeros((1, 128, 128))
    # one pixel is set to 1
    y_pred[0, 0, 0] = 1
    y_pred = tf.convert_to_tensor(y_pred, dtype=tf.float32)
    y_true = tf.zeros((1, 128, 128), dtype=tf.float32)
    print(dice_coef(y_true, y_pred, smooth=smooth))
    print(dice_coef_loss(y_true, y_pred, smooth=smooth))

will print out:

tf.Tensor(9.9999e-06, shape=(), dtype=float32)
tf.Tensor(0.99999, shape=(), dtype=float32)

But if smooth is set to 100:

tf.Tensor(0.990099, shape=(), dtype=float32)
tf.Tensor(0.009900987, shape=(), dtype=float32)

Showing the loss reduces to 0.009 instead of 0.99.

For completeness, if you have multiple segmentation channels (B X W X H X K, where B is the batch size, W and H are the dimensions of your image, and K are the different segmentations channels), the same concepts apply, but it can be implemented as follows:

def dice_coef_multilabel(y_true, y_pred, M, smooth):
    dice = 0
    for index in range(M):
        dice += dice_coef(y_true[:,:,:,index], y_pred[:,:,:,index], smooth)
    return dice

And it can be converted to a loss function through negation or subtraction, in the same way as dice_coef is. smooth could also be tuned per channel, if you supply a list or some other sequence (e.g; smooth_list):

def dice_coef_multilabel(y_true, y_pred, M, smooth_list):
    dice = 0
    for index in range(M):
        dice += dice_coef(y_true[:,:,:,index], y_pred[:,:,:,index], smooth_list[index])
    return dice
  • 2
    Thanks a ton for some of the insights specially on Multi Label classification
    – Deshwal
    Commented May 23, 2022 at 5:31
  • I assume that, for single channel prediction, Dice expects labels and model outputs in the form [batch_size, width, height ], with values in the range 0 to 1 (e.g. a trivial example of a single label item: [ [1, 0, 1], [0, 1, 0], [1, 0, 1] ])? Commented Dec 9, 2022 at 17:47
  • Yup! The expectation is labels are [0, 1] and output from the model are [0, 1] (which is true if you're using softmax or sigmoid activation in the output layer) Commented Dec 15, 2022 at 14:09
  • @danielcahall for dice_coef_multilabel with the same smooth parameter, wouldn't dice_coef work? Because in dice_coef there is K.flatten, is there a need to loop over segmentation class channels?
    – RaZ0rr
    Commented Mar 20 at 17:15

Just wanted to say that depending on your input scaling, you could get a negative Dice loss due to differences there. This could happen if your mask is all 0 and 1's and your predicted mask values are coming from say a sigmoid activation function where the output would range from 0-1. To avoid this, I thresholded the predicted y value in the dice loss function. Not sure if this is how other people handle it, but it really worked for me.

def dice_coeff(y_true, y_pred):
    smooth = 100
    # Flatten
    y_true_f = tf.cast(tf.reshape(y_true, [-1]),'float32')
    y_pred_f = tf.cast(tf.reshape(y_pred > 0.5, [-1]),'float32')

    intersection = tf.reduce_sum(tf.math.multiply(y_true_f,y_pred_f))
    score = (2. * intersection + smooth) / (tf.reduce_sum(y_true_f) + tf.reduce_sum(y_pred_f) + smooth)
    return score
  • This does not really answer the question. If you have a different question, you can ask it by clicking Ask Question. To get notified when this question gets new answers, you can follow this question. Once you have enough reputation, you can also add a bounty to draw more attention to this question. - From Review
    – bedbad
    Commented Jul 30, 2023 at 23:46

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.