Here are three different graph visualizations using different tools.
In order to generate example visualizations, I'll use a simple RNN to perform sentiment analysis taken from an online tutorial:
def __init__(self, input_dim, embedding_dim, hidden_dim, output_dim):
self.embedding = nn.Embedding(input_dim, embedding_dim)
self.rnn = nn.RNN(embedding_dim, hidden_dim)
self.fc = nn.Linear(hidden_dim, output_dim)
def forward(self, text):
embedding = self.embedding(text)
output, hidden = self.rnn(embedding)
Here is the output if you
print() the model.
(embedding): Embedding(25002, 100)
(rnn): RNN(100, 256)
(fc): Linear(in_features=256, out_features=1, bias=True)
Below are the results from three different visualization tools.
For all of them, you need to have dummy input that can pass through the model's
forward() method. A simple way to get this input is to retrieve a batch from your Dataloader, like this:
batch = next(iter(dataloader_train))
yhat = model(batch.text) # Give dummy batch to forward().
I believe this tool generates its graph using the backwards pass, so all the boxes use the PyTorch components for back-propagation.
from torchviz import make_dot
make_dot(yhat, params=dict(list(model.named_parameters()))).render("rnn_torchviz", format="png")
This tool produces the following output file:
This is the only output that clearly mentions the three layers in my model,
fc. The operator names are taken from the backward pass, so some of them are difficult to understand.
This tool uses the forward pass, I believe.
import hiddenlayer as hl
transforms = [ hl.transforms.Prune('Constant') ] # Removes Constant nodes from graph.
graph = hl.build_graph(model, batch.text, transforms=transforms)
graph.theme = hl.graph.THEMES['blue'].copy()
Here is the output. I like the shade of blue.
I find that the output has too much detail and obfuscates my architecture. For example, why is
unsqueeze mentioned so many times?
This tool is a desktop application for Mac, Windows, and Linux. It relies on the model being first exported into ONNX format. The application then reads the ONNX file and renders it. There is then an option to export the model to an image file.
input_names = ['Sentence']
output_names = ['yhat']
torch.onnx.export(model, batch.text, 'rnn.onnx', input_names=input_names, output_names=output_names)
Here's what the model looks like in the application. I think this tool is pretty slick: you can zoom and pan around, and you can drill into the layers and operators. The only negative I've found is that it only does vertical layouts.