# Expressions Lean is based on dependent type theory, and is very similar to the one used in the [Boole](https://github.com/avigad/boole) and [Coq](http://coq.inria.fr/) systems. In contrast to Coq, Lean is classical. In Lean, we have the following kind of expressions: _constants_, ,_function applications_, _(heterogeneous) equality_, _local variables_, _lambdas_, _dependent function spaces_ (aka _Pis_), _let expressions_, and _Types_. ## Constants Constants are essentially references to variable declarations, definitions, axioms and theorems in the environment. In the following example, we use the command `variables` to declare `x` and `y` as integers. The `check` command displays the type of the given expression. The `x` and `y` in the `check` command are constants. They reference the objects declared using the command `variables`. ```lean variables x y : Nat check x + y ``` In the following example, we define the constant `s` as the sum of `x` and `y` using the `definition` command. The `eval` command evaluates (normalizes) the expression `s + 1`. In this example, `eval` will just expand the definition of `s`, and return `x + y + 1`. ```lean definition s := x + y eval s + 1 ``` ## Function applications In Lean, the expression `f t` is a function application, where `f` is a function that is applied to `t`. In the following example, we define the function `max`. The `eval` command evaluates the application `double 3`, and returns the value `6`. ```lean import tactic -- load basic tactics such as 'simp' definition double (x : Nat) : Nat := x + x eval double 3 ``` In the following command, we define the function `inc`, and evaluate some expressions using `inc` and `max`. ```lean definition inc (x : Nat) : Nat := x + 1 eval inc (inc (inc 2)) eval double (inc 3) ```