# Question

How should I "tell" tf that a certain cost function derives from a NN?

# (short) Answer

This is done by simply configuring your optimizer to minimize (or maximize) a tensor. For example, if I have a loss function like so

```
loss = tf.reduce_sum( tf.square( y0 - y_out ) )
```

where y0 is the **ground truth** (or desired output) and y_out is the calculated output, then I could minimize the loss by defining my training function like so

```
train = tf.train.GradientDescentOptimizer(1.0).minimize(loss)
```

This tells Tensorflow that when **train** is calculated, it is to apply gradient descent on loss to minimize it, and loss is calculated using y0 and y_out, and so gradient descent will also affect those (if they are trainable variables), and so on.

The variable **y0**, **y_out**, **loss**, and **train** are not standard python variables but instead descriptions of a computation graph. Tensorflow uses information about that computation graph to unroll it while applying gradient descent.

Specifically how it does that is beyond the scope of this answer. Here and here are two good starting points for more information about more specifics.

# Code Example

Let's walk through a code example. First the code.

```
### imports
import tensorflow as tf
### constant data
x = [[0.,0.],[1.,1.],[1.,0.],[0.,1.]]
y_ = [[0.],[0.],[1.],[1.]]
### induction
# 1x2 input -> 2x3 hidden sigmoid -> 3x1 sigmoid output
# Layer 0 = the x2 inputs
x0 = tf.constant( x , dtype=tf.float32 )
y0 = tf.constant( y_ , dtype=tf.float32 )
# Layer 1 = the 2x3 hidden sigmoid
m1 = tf.Variable( tf.random_uniform( [2,3] , minval=0.1 , maxval=0.9 , dtype=tf.float32 ))
b1 = tf.Variable( tf.random_uniform( [3] , minval=0.1 , maxval=0.9 , dtype=tf.float32 ))
h1 = tf.sigmoid( tf.matmul( x0,m1 ) + b1 )
# Layer 2 = the 3x1 sigmoid output
m2 = tf.Variable( tf.random_uniform( [3,1] , minval=0.1 , maxval=0.9 , dtype=tf.float32 ))
b2 = tf.Variable( tf.random_uniform( [1] , minval=0.1 , maxval=0.9 , dtype=tf.float32 ))
y_out = tf.sigmoid( tf.matmul( h1,m2 ) + b2 )
### loss
# loss : sum of the squares of y0 - y_out
loss = tf.reduce_sum( tf.square( y0 - y_out ) )
# training step : gradient decent (1.0) to minimize loss
train = tf.train.GradientDescentOptimizer(1.0).minimize(loss)
### training
# run 500 times using all the X and Y
# print out the loss and any other interesting info
with tf.Session() as sess:
sess.run( tf.global_variables_initializer() )
for step in range(500) :
sess.run(train)
results = sess.run([m1,b1,m2,b2,y_out,loss])
labels = "m1,b1,m2,b2,y_out,loss".split(",")
for label,result in zip(*(labels,results)) :
print ""
print label
print result
print ""
```

Let's go through it, but in reverse order starting with

```
sess.run(train)
```

This tells tensorflow to look up the graph node defined by **train** and calculate it. **Train** is defined as

```
train = tf.train.GradientDescentOptimizer(1.0).minimize(loss)
```

To calculate this tensorflow must compute the *automatic differentiation* for **loss**, which means walking the graph. **loss** is defined as

```
loss = tf.reduce_sum( tf.square( y0 - y_out ) )
```

Which is really tensorflow applying *automatic differentiation* to unroll first **tf.reduce_sum**, then **tf.square**, then **y0 - y_out**, which leads to then having to walk the graph for both y0 and y_out.

```
y0 = tf.constant( y_ , dtype=tf.float32 )
```

**y0** is a constant and will not be updated.

```
y_out = tf.sigmoid( tf.matmul( h1,m2 ) + b2 )
```

**y_out** will be processed similar to loss, first **tf.sigmoid** will be processed, etc...

All in all, each operation ( such as tf.sigmoid, tf.square ) not only defines the forward operation ( apply sigmoid or square ) but also information necessary for *automatic differentiation*. This is different than standard python math such as

```
x = 7 + 9
```

The above equation encodes nothing except how to update x, where as

```
z = y0 - y_out
```

encodes the graph of subtracting y_out from y0 and stores both the forward operation and enough to do *automatic differentiation* in **z**