This answer is based on the experimentation I have done on the getting started tutorial code.

Mad Wombat has given a detailed explanation of the terms *num_epochs*, *batch_size* and *steps*. This answer is an extension to his answer.

*num_epochs* - The maximum number of times the program can iterate over the entire dataset in one `train()`

. Using this argument, we can restrict the number of batches that can be processed during execution of one `train()`

method.

*batch_size* - The number of examples in a single batch emitted by the *input_fn*

*steps* - Number of batches the `LinearRegressor.train()`

method can process in one execution

*max_steps* is another argument for `LinearRegressor.train()`

method. This argument defines the maximum number of steps (batches) can process in the `LinearRegressor()`

objects lifetime.

Let's whats this means. The following experiments change two lines of the code provided by the tutorial. Rest of the code remains as is.

**Note: For all the examples, assume the number of training i.e. the length of ***x_train* to be equal to 4.

**Ex 1:**

```
input_fn = tf.estimator.inputs.numpy_input_fn(
{"x": x_train}, y_train, batch_size=4, num_epochs=2, shuffle=True)
```

`estimator.train(input_fn=input_fn, steps=10)`

In this example, we defined the *batch_size* = 4 and *num_epochs* = 2. So, the `input_fn`

can emit just 2 batches of input data for one execution of `train()`

. Even though we defined *steps* = 10, the `train()`

method stops after 2 steps.

Now, execute the `estimator.train(input_fn=input_fn, steps=10)`

again. We can see that 2 more steps have been executed. We can keep executing the `train()`

method again and again. If we execute `train()`

50 times, a total of 100 steps have been executed.

**Ex 2:**

```
input_fn = tf.estimator.inputs.numpy_input_fn(
{"x": x_train}, y_train, batch_size=2, num_epochs=2, shuffle=True)
```

`estimator.train(input_fn=input_fn, steps=10)`

In this example, the value of *batch_size* is changed to 2 (it was equal to 4 in Ex 1). Now, in each execution of `train()`

method, 4 steps are processed. After the 4th step, there are no batches to run on. If the `train()`

method is executed again, another 4 steps are processed making it a total of 8 steps.

Here, the value of *steps* doesn't matter because the `train()`

method can get a maximum of 4 batches. If the value of *steps* is less than (*num_epochs* x *training_size*) / *batch_size*, see ex 3.

**Ex 3:**

```
input_fn = tf.estimator.inputs.numpy_input_fn(
{"x": x_train}, y_train, batch_size=2, num_epochs=8, shuffle=True)
```

`estimator.train(input_fn=input_fn, steps=10)`

Now, let *batch_size* = 2, *num_epochs* = 8 and *steps* = 10. The `input_fn`

can emit a total of 16 batches in one run of `train()`

method. However, *steps* is set to 10. This means that eventhough `input_fn`

can provide 16 batches for execution, `train()`

must stop after 10 steps. Ofcourse, `train()`

method can be re-executed for more steps cumulatively.

From examples 1, 2, & 3, we can clearly see how the values of *steps*, *num_epoch* and *batch_size* affect the number of steps that can be executed by `train()`

method in one run.

The *max_steps* argument of `train()`

method restricts the total number of steps that can be run cumulatively by `train()`

**Ex 4:**

If *batch_size* = 4, *num_epochs* = 2, the `input_fn`

can emit 2 batches for one `train()`

execution. But, if `max_steps`

is set to 20, no matter how many times `train()`

is executed only 20 steps will run in optimization. This is in contrast to example 1, where the optimizer can run to 200 steps if the `train()`

method is exuted 100 times.

Hope this gives a detailed understanding of what these arguments mean.