Miscellaneous extensions¶
Program derivation¶
Coq comes with an extension called Derive
, which supports program
derivation. Typically in the style of Bird and Meertens or derivations
of program refinements. To use the Derive extension it must first be
required with Require Coq.derive.Derive
. When the extension is loaded,
it provides the following command:
-
Command
Derive ident1 SuchThat type As ident2
¶ ident1
can appear intype
. This command opens a new proof presenting the user with a goal fortype
in which the nameident1
is bound to an existential variable?x
(formally, there are other goals standing for the existential variables but they are shelved, as described inshelve
).When the proof ends two constants are defined:
- The first one is named
ident1
and is defined as the proof of the shelved goal (which is also the value of?x
). It is always transparent. - The second one is named
ident2
. It has typetype
, and its body is the proof of the initially visible goal. It is opaque if the proof ends withQed
, and transparent if the proof ends withDefined
.
- The first one is named
Example
- Require Coq.derive.Derive.
- [Loading ML file derive_plugin.cmxs ... done]
- Require Import Coq.Numbers.Natural.Peano.NPeano.
- Section P.
- Variables (n m k:nat).
- n is declared m is declared k is declared
- Derive p SuchThat ((k*n)+(k*m) = p) As h.
- 1 focused subgoal (shelved: 1) n, m, k : nat p := ?Goal : nat ============================ k * n + k * m = p
- Proof.
- rewrite <- Nat.mul_add_distr_l.
- 1 focused subgoal (shelved: 1) n, m, k : nat p := ?Goal : nat ============================ k * (n + m) = p
- subst p.
- 1 focused subgoal (shelved: 1) n, m, k : nat ============================ k * (n + m) = ?Goal
- reflexivity.
- No more subgoals.
- Qed.
- End P.
- Print p.
- p = fun n m k : nat => k * (n + m) : nat -> nat -> nat -> nat Argument scopes are [nat_scope nat_scope nat_scope]
- Check h.
- h : forall n m k : nat, k * n + k * m = p n m k
Any property can be used as term
, not only an equation. In particular,
it could be an order relation specifying some form of program
refinement or a non-executable property from which deriving a program
is convenient.