Basically, an environment `p`

such as `[("x",4),("y",5)]`

defines the values for variables `x`

and `y`

. When you evaluate an expression which can involve such variables, the result depends on `p`

. This is represented by the `\p -> ...`

.

For instance, we could expect something like

```
Exp + Exp { \p -> $1 p + $2 p }
```

expressing the facts that both terms are evaluated using the same variable values as defined by `p`

.

Now, `let`

is peculiar because it defines a new variable, giving a value to it. To express this fact, we need to change `p`

augmenting it with the new association.

```
let var = Exp in Exp
$1 $2 $3 $4 $5 $6
```

Given `p`

, the value of $4 is simply `$4 p`

as we did in the previous sum example (we are assuming that `var`

is not visible in $4, that is, we do not allow `var`

to be recursively defined). Write

```
value_of_$4 = $4 p
```

However, the value of $6 is not `$6 p`

since $6 must "see" the newly defined `var`

. So we write

```
value_of_$6 = $6 (p augmented with the association <<var = value_of_$4>>)
```

that is

```
value_of_$6 = $6 ( ($2,value_of_$4) : p )
```

that is

```
value_of_$6 = $6 ( ($2, $4 p) : p )
```

So we end up with

```
let var = Exp in Exp { \p -> $6 ( ($2, $4 p) : p ) }
$1 $2 $3 $4 $5 $6
```