I know I can measure the execution time of a call to
sess.run(), but is it possible to get a finer granularity and measure the execution time of individual operations?
I have used the
Timeline object to get the time of execution for each node in the graph:
- you use a classic
sess.run()but also specify the optional arguments
- you then create a
Timelineobject with the
Here is an example program that measures the performance of a matrix multiplication:
import tensorflow as tf from tensorflow.python.client import timeline x = tf.random_normal([1000, 1000]) y = tf.random_normal([1000, 1000]) res = tf.matmul(x, y) # Run the graph with full trace option with tf.Session() as sess: run_options = tf.RunOptions(trace_level=tf.RunOptions.FULL_TRACE) run_metadata = tf.RunMetadata() sess.run(res, options=run_options, run_metadata=run_metadata) # Create the Timeline object, and write it to a json tl = timeline.Timeline(run_metadata.step_stats) ctf = tl.generate_chrome_trace_format() with open('timeline.json', 'w') as f: f.write(ctf)
You can then open Google Chrome, go to the page
chrome://tracing and load the
You should see something like:
Since this is high up when googling for "Tensorflow Profiling", note that the current (late 2017, TensorFlow 1.4) way of getting the Timeline is using a ProfilerHook. This works with the MonitoredSessions in tf.Estimator where tf.RunOptions are not available.
estimator = tf.estimator.Estimator(model_fn=...) hook = tf.train.ProfilerHook(save_steps=10, output_dir='.') estimator.train(input_fn=..., steps=..., hooks=[hook])
You can extract this information using runtime statistics. You will need to do something like this (check the full example in the above-mentioned link):
run_options = tf.RunOptions(trace_level=tf.RunOptions.FULL_TRACE) run_metadata = tf.RunMetadata() sess.run(<values_you_want_to_execute>, options=run_options, run_metadata=run_metadata) your_writer.add_run_metadata(run_metadata, 'step%d' % i)
Better than just printing it you can see it in tensorboard:
Additionally, clicking on a node will display the exact total memory, compute time, and tensor output sizes.
To update this answer, we do have some functionality for CPU profiling, focused on inference. If you look at https://github.com/tensorflow/tensorflow/tree/master/tensorflow/tools/benchmark you'll see a program you can run on a model to get per-op timings.
To profile TensorFlow sessions automatically you can use the StackImpact profiler. No need to instrument sessions or add any options. You just need to initialize the profiler:
import stackimpact agent = stackimpact.start( agent_key = 'agent key here', app_name = 'MyApp')
Both execution time and memory profiles will be available in the Dashboard.
Detailed info in this article: TensorFlow Profiling in Development and Production Environments.
Disclaimer: I work for StackImpact.
Recently released by Uber SBNet custom op library (http://www.github.com/uber/sbnet) has an implementation of cuda event based timers, which can be used in the following manner:
with tf.control_dependencies([input1, input2]): dt0 = sbnet_module.cuda_timer_start() with tf.control_dependencies([dt0]): input1 = tf.identity(input1) input2 = tf.identity(input2) ### portion of subgraph to time goes in here with tf.control_dependencies([result1, result2, dt0]): cuda_time = sbnet_module.cuda_timer_end(dt0) with tf.control_dependencies([cuda_time]): result1 = tf.identity(result1) result2 = tf.identity(result2) py_result1, py_result2, dt = session.run([result1, result2, cuda_time]) print "Milliseconds elapsed=", dt
Note that any portion of subgraph can be asynchronous you should be very careful with specifying all the input and output dependencies for the timer ops. Otherwise the timer might get inserted into the graph out of order and you can get erroneous time. I found both the timeline and time.time() timing of very limited utility for profiling Tensorflow graphs. Also note that cuda_timer APIs will synchronize on default stream, which is currently by design because TF uses multiple streams.
Having said this I personally recommend switching to PyTorch :) Development iteration is faster, code runs faster and everything is a lot less painful.
Another somewhat hacky and arcane approach to subtracting the overhead from tf.Session (which can be enormous) is to replicate the graph N times and run it for a variable N, solving for an equation of unknown fixed overhead. I.e. you'd measure around session.run() with N1=10 and N2=20 and you know that your time is t and overhead is x. So something like
N1*x+t = t1 N2*x+t = t2
Solve for x and t. Downside is this might require a lot of memory and is not necessarily accurate :) Also make sure that your inputs are completely different/random/independent otherwise TF will fold the entire subgraph and not run it N times... Have fun with TensorFlow :)