I know xgboost need first gradient and second gradient, but anybody else has used "mae" as obj function?


A little bit of theory first, sorry! You asked for the grad and hessian for MAE, however, the MAE is not continuously twice differentiable so trying to calculate the first and second derivatives becomes tricky. Below we can see the "kink" at x=0 which prevents the MAE from being continuously differentiable.

Moreover, the second derivative is zero at all the points where it is well behaved. In XGBoost, the second derivative is used as a denominator in the leaf weights, and when zero, creates serious math-errors.

Given these complexities, our best bet is to try to approximate the MAE using some other, nicely behaved function. Let's take a look.

Some different loss functions

We can see above that there are several functions that approximate the absolute value. Clearly, for very small values, the Squared Error (MSE) is a fairly good approximation of the MAE. However, I assume that this is not sufficient for your use case.

Huber Loss is a well documented loss function. However, it is not smooth so we cannot guarantee smooth derivatives. We can approximate it using the Psuedo-Huber function. It can be implemented in python XGBoost as follows,

import xgboost as xgb

dtrain = xgb.DMatrix(x_train, label=y_train)
dtest = xgb.DMatrix(x_test, label=y_test)

param = {'max_depth': 5}
num_round = 10

def huber_approx_obj(preds, dtrain):
    d = preds - dtrain.get_labels() #remove .get_labels() for sklearn
    h = 1  #h is delta in the graphic
    scale = 1 + (d / h) ** 2
    scale_sqrt = np.sqrt(scale)
    grad = d / scale_sqrt
    hess = 1 / scale / scale_sqrt
    return grad, hess

bst = xgb.train(param, dtrain, num_round, obj=huber_approx_obj)  

Other function can be used by replacing the obj=huber_approx_obj.

Fair Loss is not well documented at all but it seems to work rather well. The fair loss function is:

Fair Loss Function

It can be implemented as such,

def fair_obj(preds, dtrain):
    """y = c * abs(x) - c**2 * np.log(abs(x)/c + 1)"""
    x = preds - dtrain.get_labels()
    c = 1
    den = abs(x) + c
    grad = c*x / den
    hess = c*c / den ** 2
    return grad, hess

This code is taken and adapted from the second place solution in the Kaggle Allstate Challenge.

Log-Cosh Loss function.

def log_cosh_obj(preds, dtrain):
    x = preds - dtrain.get_labels()
    grad = np.tanh(x)
    hess = 1 / np.cosh(x)**2
    return grad, hess

Finally, you can create your own custom loss functions using the above functions as templates.

  • 2
    Many thanks josh! A quick comment on the log-cosh code; np.cosh can overflow for some inputs, using the identity hess = 1- np.tanh(x)**2 will avoid these issues.
    – chepyle
    Jul 23 '18 at 3:10
  • 1
    I think the fair loss function mentioned above is wrong (though the implementation is correct). According to kaggle.com/c/allstate-claims-severity/discussion/24520, the correct 'Fair Loss' function is given by y = c * abs(x) - c**2 * np.log(abs(x)/c + 1).
    – kadee
    Aug 28 '18 at 13:51
  • 1
    @josh thanks (and I meant you and not kadee) that makes sense. Finally, could you comment on the answer by @hbar137? Shouldn't you have "d = preds - labels" instead?
    – zkurtz
    Sep 18 '18 at 12:42
  • 1
    @josh the line "grad = d / scale_sqrt" is not compatible with "the fact d is negative does not mean that there the first derivative becomes negative". The sign of the gradient is precisely the sign of d, since scale_sqrt is always positive. Empirically, I get vastly different and better results after flipping the sign.
    – zkurtz
    Sep 18 '18 at 17:21
  • 3
    I think that for sklearn you should invert the arguments passed to the objective function... 1st should be labels, 2nd should be predictions... it does not make much difference in this case I suppose, but it can create confusion..also get_labels -> get_label
    – gabboshow
    Jan 16 '19 at 13:20

For the Huber loss above, I think the gradient is missing a negative sign upfront. Should be as

grad = - d / scale_sqrt
  • 1
    Please add comments to the comments section of answers. Also, what makes you think this? I cannot see where the negative comes from. Thanks. Sep 18 '18 at 13:32
  • If correct, hbar137 deserves upvotes for pointing out something so crucial, slightly more important than your standard comment.
    – zkurtz
    Sep 18 '18 at 17:22
  • @zkurtz it would be if it were correct, but please checkout the derivative of the psuedo-huber. Sep 18 '18 at 20:16
  • @josh You had the correct formula in the abstract sense. But if you were to put (-x) in place of x, consider that when taking the derivative you would need to apply the chain rule, leading to a minus sign on the derivative. hbar137 was correct at the time they wrote this, but since you fixed your solution (thanks!), this answer is no longer needed.
    – zkurtz
    Sep 18 '18 at 20:33
  • Thank you both for your inputs and improving the answer!! Sep 18 '18 at 20:49

I am running the huber/fair metric from above on ~normally distributed Y, but for some reason with alpha <0 (and all the time for fair) the result prediction will equal to zero...

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