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TensorBoard: Graph Visualization

TensorFlow computation graphs are powerful but complicated. The graph visualization can help you understand and debug them. Here's an example of the visualization at work.

Visualization of a TensorFlow graph Visualization of a TensorFlow graph.

To see your own graph, run TensorBoard pointing it to the log directory of the job, click on the graph tab on the top pane and select the appropriate run using the menu at the upper left corner. For in depth information on how to run TensorBoard and make sure you are logging all the necessary information, see Summaries and TensorBoard.

Name scoping and nodes

Typical TensorFlow graphs can have many thousands of nodes--far too many to see easily all at once, or even to lay out using standard graph tools. To simplify, variable names can be scoped and the visualization uses this information to define a hierarchy on the nodes in the graph. By default, only the top of this hierarchy is shown. Here is an example that defines three operations under the hidden name scope using tf.name_scope:

import tensorflow as tf

with tf.name_scope('hidden') as scope:
  a = tf.constant(5, name='alpha')
  W = tf.Variable(tf.random_uniform([1, 2], -1.0, 1.0), name='weights')
  b = tf.Variable(tf.zeros([1]), name='biases')

This results in the following three op names:

  • hidden/alpha
  • hidden/weights
  • hidden/biases

By default, the visualization will collapse all three into a node labeled hidden. The extra detail isn't lost. You can double-click, or click on the orange + sign in the top right to expand the node, and then you'll see three subnodes for alpha, weights and biases.

Here's a real-life example of a more complicated node in its initial and expanded states.

Unexpanded name scope Expanded name scope
Initial view of top-level name scope pool_1. Clicking on the orange + button on the top right or double-clicking on the node itself will expand it. Expanded view of pool_1 name scope. Clicking on the orange - button on the top right or double-clicking on the node itself will collapse the name scope.

Grouping nodes by name scopes is critical to making a legible graph. If you're building a model, name scopes give you control over the resulting visualization. The better your name scopes, the better your visualization.

The figure above illustrates a second aspect of the visualization. TensorFlow graphs have two kinds of connections: data dependencies and control dependencies. Data dependencies show the flow of tensors between two ops and are shown as solid arrows, while control dependencies use dotted lines. In the expanded view (right side of the figure above) all the connections are data dependencies with the exception of the dotted line connecting CheckNumerics and control_dependency.

There's a second trick to simplifying the layout. Most TensorFlow graphs have a few nodes with many connections to other nodes. For example, many nodes might have a control dependencies on an initialization step. Drawing all edges between the init node and its dependencies would create a very cluttered view.

To reduce clutter, the visualization separates out all high-degree nodes to an auxiliary area on the right and doesn't draw lines to represent their edges. Instead of lines, we draw small node icons to indicate the connections. Separating out the auxiliary nodes typically doesn't remove critical information since these nodes are usually related to bookkeeping functions.

conv_1 is part of the main graph save is extracted as auxiliary node
Node conv_1 is connected to save. Note the little save node icon on its right. save has a high degree, and will appear as an auxiliary node. The connection with conv_1 is shown as a node icon on its left. To further reduce clutter, since save has a lot of connections, we show the first 5 and abbreviate the others as ... 12 more.

One last structural simplification is series collapsing. Sequential motifs--that is, nodes whose names differ by a number at the end and have isomorphic structures--are collapsed into a single stack of nodes, as shown below. For networks with long sequences, this greatly simplifies the view. As with hierarchical nodes, double-clicking expands the series.

Sequence of nodes Expanded sequence of nodes
A collapsed view of a node sequence. A small piece of the expanded view, after double-click.

Finally, as one last aid to legibility, the visualization uses special icons for constants and summary nodes. To summarize, here's a table of node symbols:

Symbol Meaning
Name scope High-level node representing a name scope. Double-click to expand a high-level node.
Sequence of unconnected nodes Sequence of numbered nodes that are not connected to each other.
Sequence of connected nodes Sequence of numbered nodes that are connected to each other.
Operation node An individual operation node.
Constant node A constant.
Summary node A summary node.
Data flow edge Edge showing the data flow between operations.
Control dependency edge Edge showing the control dependency between operations.
Reference edge A reference edge showing that the outgoing operation node can mutate the incoming tensor.

Interaction

Navigate the graph by panning and zooming. Click and drag to pan, and use a scroll gesture to zoom. Double-click on a node, or click on its + button, to expand a name scope that represents a group of operations. To easily keep track of the current viewpoint when zooming and panning, there is a minimap in the bottom right corner.

To close an open node, double-click it again or click its - button. You can also click once to select a node. It will turn a darker color, and details about it and the nodes it connects to will appear in the info card at upper right corner of the visualization.

Info card of a name scope Info card of operation node
Info card showing detailed information for the conv2 name scope. The inputs and outputs are combined from the inputs and outputs of the operation nodes inside the name scope. For name scopes no attributes are shown. Info card showing detailed information for the DecodeRaw operation node. In addition to inputs and outputs, the card shows the device and the attributes associated with the current operation.

Selection can also be helpful in understanding high-degree nodes. Select any high-degree node, and the corresponding node icons for its other connections will be selected as well. This makes it easy, for example, to see which nodes are being saved--and which aren't.

Clicking on a node name in the info card will select it. If necessary, the viewpoint will automatically pan so that the node is visible.

Finally, you can choose two color schemes for your graph, using the color menu above the legend. The default Structure View shows structure: when two high-level nodes have the same structure, they appear in the same color of the rainbow. Uniquely structured nodes are gray. There's a second view, which shows what device the different operations run on. Name scopes are colored proportionally to the fraction of devices for the operations inside them.

The images below give an illustration for a piece of a real-life graph.

Color by structure Color by device
Structure view: The gray nodes have unique structure. The orange conv1 and conv2 nodes have the same structure, and analogously for nodes with other colors. Device view: Name scopes are colored proportionally to the fraction of devices of the operation nodes inside them. Here, purple means GPU and the green is CPU.