I came across this phenomenon several times. Here are my observations:
Gradient blow up
Reason: large gradients throw the learning process off-track.
What you should expect: Looking at the runtime log, you should look at the loss values per-iteration. You'll notice that the loss starts to grow significantly from iteration to iteration, eventually the loss will be too large to be represented by a floating point variable and it will become
What can you do: Decrease the
base_lr (in the solver.prototxt) by an order of magnitude (at least). If you have several loss layers, you should inspect the log to see which layer is responsible for the gradient blow up and decrease the
loss_weight (in train_val.prototxt) for that specific layer, instead of the general
Bad learning rate policy and params
Reason: caffe fails to compute a valid learning rate and gets
'nan' instead, this invalid rate multiplies all updates and thus invalidating all parameters.
What you should expect: Looking at the runtime log, you should see that the learning rate itself becomes
'nan', for example:
... sgd_solver.cpp:106] Iteration 0, lr = -nan
What can you do: fix all parameters affecting the learning rate in your
For instance, if you use
lr_policy: "poly" and you forget to define
max_iter parameter, you'll end up with
lr = nan...
For more information about learning rate in caffe, see this thread.
Faulty Loss function
Reason: Sometimes the computations of the loss in the loss layers causes
nans to appear. For example, Feeding
InfogainLoss layer with non-normalized values, using custom loss layer with bugs, etc.
What you should expect: Looking at the runtime log you probably won't notice anything unusual: loss is decreasing gradually, and all of a sudden a
What can you do: See if you can reproduce the error, add printout to the loss layer and debug the error.
For example: Once I used a loss that normalized the penalty by the frequency of label occurrence in a batch. It just so happened that if one of the training labels did not appear in the batch at all - the loss computed produced
nans. In that case, working with large enough batches (with respect to the number of labels in the set) was enough to avoid this error.
Reason: you have an input with
nan in it!
What you should expect: once the learning process "hits" this faulty input - output becomes
nan. Looking at the runtime log you probably won't notice anything unusual: loss is decreasing gradually, and all of a sudden a
What can you do: re-build your input datasets (lmdb/leveldn/hdf5...) make sure you do not have bad image files in your training/validation set. For debug you can build a simple net that read the input layer, has a dummy loss on top of it and runs through all the inputs: if one of them is faulty, this dummy net should also produce
stride larger than kernel size in
For some reason, choosing
kernel_size for pooling may results with
nans. For example:
It was reported that under some settings
"BatchNorm" layer may output
nans due to numerical instabilities.
This issue was raised in bvlc/caffe and PR #5136 is attempting to fix it.
Recently, I became aware of
debug_info flag: setting
debug_info: true in
'solver.prototxt' will make caffe print to log more debug information (including gradient magnitudes and activation values) during training: This information can help in spotting gradient blowups and other problems in the training process.