I am basically playing around with duplicating AlphaZero. It has worked for some small games, but I am trying to scale it up to work with a more complicated game. However, now my network after training on 2-10 million moves will just fill up with NaNs. Unfortunately, due to the fact that it isn't deterministic and the failure point occurs in such a wide range using the debugger has not been very effective. It takes about 5 minutes to train 12000 moves when I am having tfdbg check for "has_inf_or_nan". So the debugger is doing nothing for me because it would take a very long time to hit the error.
At the very bottom of this post, I'll describe what the model looks like.
Here is how I am using certain things that are common sources of NaNs:
Loss Functions (Single network with 2 outputs: policy (odds of selecting a move) and value (quality of the board position for the active player)):
Note: move_result_placeholder gets filled with a batch of moves that are the output of a MonteCarlo Tree Search. Since most of the move positions are invalid it is typically full of 0s with 5-10 that are floats that represent the odds of selecting that move. I have an assert that verifies they all sum to 1. When running training I also have asserts that verify none of the inputs are NaN. I select uniformly at random from a collection of the last 1,000,000 (Board State, Move, Reward) when populating the batch. Then I feed the board states, moves, and rewards into the training step.
self.loss_policy = tf.losses.softmax_cross_entropy(self.move_result_placeholder, out_dense)
self.loss_value =
tf.losses.mean_squared_error(self.value_result_placeholder,
tf.reshape(self.out_value_layer, shape=[-1,]))
self.total_loss = self.loss_policy + self.loss_value
Optimizer (learning rate 1e-4):
self.train_step = tf.train.AdamOptimizer(learning_rate=self.learning_rate_placeholder).minimize(self.total_loss, name="optimizer")
Softmax:
self.out_policy_layer = tf.nn.softmax(out_dense, name="out_policy_layer")
Batch Normalization (is_training is a placeholder that is 1 when training and 0 when playing games) batch_norm_decay is .999:
input_bn = tf.contrib.layers.batch_norm(input_conv, center=True, scale=True, is_training=self.is_training, decay=self._config.batch_norm_decay)
Regularization (L2 on all weights in layers scale is 1e-4):
initializer=tf.contrib.layers.xavier_initializer()
if use_regularizer:
regularizer = tf.contrib.layers.l2_regularizer(scale=self._config.l2_regularizer_scale)
weights = tf.get_variable(name, shape=shape, initializer=initializer, regularizer=regularizer)
MODEL DESCRIPTION:
The model is created in tensorflow and consists of an input layer that is 4x8x3 (batch size 1024). This captures the state of the 4x8 board and how many moves have been made since a player has scored and how many times that board state has been seen during that specific game. That feeds into a conv2d layer with kernel size of 3x3 and strides=1. I then apply BatchNormalization tf.contrib.layers.batch_norm(input_conv, center=True, scale=True, is_training=self.is_training, decay=self._config.batch_norm_decay)
and relu. At the end of the input relu the size is 4x8x64.
After that there are 5 residual blocks. After the residual block it splits into two. The first is the policy network output which runs it through another convolutional layer with kernal size of 1x1 with strides of 1 and a batch normalization and a ReLU. At this point it is 4x8x2 and it gets flattened and run through a dense layer and then to a softmax to output 256 outputs that represent the odds that it will pick any given move. The 256 outputs map to the 4x8 board with planes for the direction the piece is moving. So the first 4x8 would tell you the odds of selecting a piece and moving it Northwest. The second would tell you the odds of selecting a piece and moving it Northeast, etc.
On the other side of the split is the value output. On that side it runs through a convolutional layer then it gets flattened and goes through a dense layer and finally through a TanH so it outputs a single value that tells us the quality of that board state.
Weights for all of the layers are using L2 Regularization (1e-4).
Loss is Cross Entropy for the policy side and Mean Squared Error for the value side, and I am using the Adam Optimizer.