Rover is an automated theorem prover for first-order logic written in Ruby.It is translation of theorem-prover from Python.
For any provable formula, this program is guaranteed to find the proof (eventually). However, as a consequence of the negative answer to Hilbert's Entscheidungsproblem, there are some unprovable formulae that will cause this program to loop forever.
To get started, please gem install rover_prover:
$ rover_prover
Rover: First-Order Logic Theorem Prover
2019 Koki Ryu
2014 Stephan Boyer
Terms:
x (variable)
f(term, ...) (function)
Formulae:
P(term) (predicate)
not P (complement)
P or Q (disjunction)
P and Q (conjunction)
P implies Q (implication)
forall x. P (universal quantification)
exists x. P (existential quantification)
Enter formulae at the prompt. The following commands are also available for manipulating axioms:
axioms (list axioms)
lemmas (list lemmas)
axiom <formula> (add an axiom)
lemma <formula> (prove and add a lemma)
remove <formula> (remove an axiom or lemma)
reset (remove all axioms and lemmas)
Enter 'exit' command to exit the prompt.
Rover>
Example session:
Rover> P or not P
0. ⊢ (P ∨ ¬P)
1. ⊢ P, ¬P
2. P ⊢ P
Formula proven: (P ∨ ¬P)
Rover> P and not P
0. ⊢ (P ∧ ¬P)
1. ⊢ ¬P
2. P ⊢
Formula unprovable: (P ∧ ¬P)
Rover> forall x. P(x) implies (Q(x) implies P(x))
0. ⊢ (∀x. (P(x) -> (Q(x) -> P(x))))
1. ⊢ (P(v1) -> (Q(v1) -> P(v1)))
2. P(v1) ⊢ (Q(v1) -> P(v1))
3. P(v1), Q(v1) ⊢ P(v1)
Formula proven: (∀x. (P(x) -> (Q(x) -> P(x))))
Rover> exists x. (P(x) implies forall y. P(y))
0. ⊢ (∃x. (P(x) -> (∀y. P(y))))
1. ⊢ (∃x. (P(x) -> (∀y. P(y)))), (P(t1) -> (∀y. P(y)))
2. ⊢ (∃x. (P(x) -> (∀y. P(y)))), (P(t1) -> (∀y. P(y))), (P(t2) -> (∀y. P(y)))
3. P(t1) ⊢ (∃x. (P(x) -> (∀y. P(y)))), (P(t2) -> (∀y. P(y))), (∀y. P(y))
4. P(t1) ⊢ (∃x. (P(x) -> (∀y. P(y)))), (P(t2) -> (∀y. P(y))), (∀y. P(y)), (P(t3) -> (∀y. P(y)))
5. P(t1), P(t2) ⊢ (∃x. (P(x) -> (∀y. P(y)))), (∀y. P(y)), (P(t3) -> (∀y. P(y))), (∀y. P(y))
6. P(t1), P(t2) ⊢ (∃x. (P(x) -> (∀y. P(y)))), (P(t3) -> (∀y. P(y))), (∀y. P(y)), P(v1)
7. P(t1), P(t2) ⊢ (∃x. (P(x) -> (∀y. P(y)))), (P(t3) -> (∀y. P(y))), (∀y. P(y)), P(v1), (P(t4) -> (∀y. P(y)))
8. P(t1), P(t2), P(t3) ⊢ (∃x. (P(x) -> (∀y. P(y)))), (∀y. P(y)), P(v1), (P(t4) -> (∀y. P(y))), (∀y. P(y))
9. P(t1), P(t2), P(t3) ⊢ (∃x. (P(x) -> (∀y. P(y)))), P(v1), (P(t4) -> (∀y. P(y))), (∀y. P(y)), P(v2)
10. P(t1), P(t2), P(t3) ⊢ (∃x. (P(x) -> (∀y. P(y)))), P(v1), (P(t4) -> (∀y. P(y))), (∀y. P(y)), P(v2), (P(t5) -> (∀y. P(y)))
11. P(t1), P(t2), P(t3), P(t4) ⊢ (∃x. (P(x) -> (∀y. P(y)))), P(v1), (∀y. P(y)), P(v2), (P(t5) -> (∀y. P(y))), (∀y. P(y))
t4 = v1
Formula proven: (∃x. (P(x) -> (∀y. P(y))))
Rover> axiom forall x. Equals(x, x)
Axiom added: (∀x. Equals(x, x))
Rover> axioms
(∀x. Equals(x, x))
Rover> lemma Equals(a, a)
0. (∀x. Equals(x, x)) ⊢ Equals(a, a)
1. (∀x. Equals(x, x)), Equals(t1, t1) ⊢ Equals(a, a)
t1 = a
Lemma proven: Equals(a, a)
Rover> lemmas
Equals(a, a)
Rover> remove forall x. Equals(x, x)
Axiom removed: (∀x. Equals(x, x))
Dependent axioms are also removed:
Equals(a, a)