## Hot answers tagged theorem-proving

48

The following is a stunt, but it's quite a safe stunt so do try it at home. It uses some of the entertaining new toys to bake order invariants into mergeSort.
{-# LANGUAGE GADTs, PolyKinds, KindSignatures, MultiParamTypeClasses,
FlexibleInstances, RankNTypes, FlexibleContexts #-}
I'll have natural numbers, just to keep things simple.
data Nat = Z | S ...

32

Coq is an interactive theorem prover (aka proof assistant). It provides a language to write mathematical definitions, algorithms and theorems. It also provides an environment for producing machine checked proofs. Coq has been used to formalize mathematical theorems, and provide the semantics of programming languages. Today, we can find many papers at POPL ...

25

The short answer is: “no, nobody tried to prove Z3 using Z3 itself” :-)
The sentence “we proved program X to be correct” is very misleading.
The main problem is: what does it mean to be correct.
In the case of Z3, one could say that Z3 is correct if, at least, it never returns “sat” for an unsatisfiable problem, and “unsat” for a satisfiable one.
This ...

21

Yes.
You encode your invariants in the Haskell type system. The compiler will then enforce (e.g. perform type checking), to prevent your program from compiling if the invariants are not held.
For ordered lists, you might consider a cheap approach of implementing a smart constructor which changes the type of a list upon sorting.
module Sorted (Sorted, ...

19

If You like "programming" in combinatory logic, then
You can automatically "translate" some logic problems into another field: proving equality of combinatory logic terms.
With a good functional programming practice, You can solve that,
and afterwards, You can translate the answer back to a Hilbert style proof of Your original logic problem.
The ...

17

SMT solvers are not any more powerful than SAT solvers. They will still run in exponential time or be incomplete for the same problems in SAT. The advantage of SMT is that many things that are obvious in SMT can take a long time for an equivalent sat solver to rediscover.
So with software verification as an example, if you use a QF BV (quantifier-free ...

15

When I started learning Agda about a year ago I think I tried all available tutorials and each taught me something new.
You should probably give Coq a try, because it has a larger user base and there are two nice books available for it:
Coq'Art - slightly dated, but beginner friendly
Certified Programming with Dependent Types
Software Foundations is ...

13

Well, the answer is yes and no. There's no way to just write an invariant separate from a type and check it. There was an implementation of this in a research fork of Haskell called ESC/Haskell, however: http://lambda-the-ultimate.org/node/1689
You do have various other options. For one, you can use asserts: ...

11

Conor McBride gave a great series of lectures last year on dependently-typed programming using Agda. It's a good place to go if you want a break from pouring through terse tutorials on the topic. I believe there are also accompanying exercises.

10

One way to accomplish this is using one of the APIs, along with the model generation capability. You can then use the generated model from one satisfiability check to add constraints to prevent previous model values from being used in subsequent satisfiability checks, until there are no more satisfying assignments. Of course, you have to be using finite ...

10

I think what you're asking isn't really related to the difference between the Definition and Let commands in Coq. Instead, you seem to be wondering about why some definitions in Coq contain proof scripts.
One interesting feature of Coq is that the language that one uses for writing proofs and programs is actually the same. This language is known as Gallina, ...

9

Z3 command line tool does not have such option. Moreover, Z3 contains several solvers and pre-processing steps. It is unclear which step would be useful for you. The Z3 source code is available at http://z3.codeplex.com. When Z3 is compiled in debug mode, it provides an extra command line option -tr:<tag>. This option can be used to selectively dump ...

8

You can try using the try command in Isabelle; it runs sledgehammer, nitpick, quickcheck and a number of other solvers (such as auto, simp, force, etc) in parallel, giving you the results of the first one that finishes.
For example, running the following:
lemma "(a * (b + 1)) = (a * b + a)"
try
will return a counter-example from nitpick, indicating ...

8

It is an easy exercise to implement a prover for Horn logic in a few lines of Prolog. Start with the Vanilla Meta-interpreter, then modify it to use the standard unify_with_occurs_check/2 predicate for all unifications, and to use a complete search procedure - iterative deepening depth first search is the simplest to implement.
See @mat's page A Couple of ...

8

I do not entirely understand how to
read the (init (x ∷ xs) | (initLast (x
∷ xs) | initLast xs)) component. I
suppose my questions are; is it
possible, how and what does that term
mean.
This tells you that the value init (x ∷ xs) depends on the value of everything to the right of the |. When you prove something about in a function in Agda your ...

7

I've had good experience using STP for symbolic execution. STP was designed precisely for this task. Also, there have been a number of symbolic execution tools that have successfully used STP for this purpose, so there is reason to believe that STP doesn't suck. I would definitely recommend STP to others as a default choice for this sort of ...

6

The Hilbert system is not normally used in automated theorem proving. It is much easier to write a computer program to do proofs using natural deduction. From the material of a CS course:
Some FAQ’s about the Hilbert system:
Q: How does one know which axiom
schemata to use, and which
substitutions to make? Since there are
infinitely many ...

6

Some textbooks define I as mere alias for ((S K) K). In this case they are identical (as terms) per definitionem. To prove their equality (as functions), we need only to prove that equality is reflexive, which can be achieved by a reflexivity axiom scheme:
Proposition ``E = E'' is deducible (Reflexivity axiom scheme, instantiated for each possible terms ...

6

Concerning your statement sledgehammer is one of the most important parts of Isabelle:
You never need sledgehammer to succeed with a proof. But of course sledgehammer is very convenient and can save a lot of tedious reasoning. Thus it is definitely a very important part for making Isabelle more usable for people who did not spend many years using it (and ...

6

There are two mechanisms for writing custom tactics in Idris: high-level and low-level reflection.
Using high-level reflection, you write a function that runs on syntax rather than on evaluated data - it won't reduce its argument. These functions return a new tactic, defined using the pre-existing tactics in Idris. If you want to return a proof term ...

6

The simple answer is that you can't. Reasoning about functions is fairly awkward in intensional type theories. For example, Martin-Löf's type theory is unable to prove:
S x + y = S (x + y)
0 + y = y
x +′ S y = S (x + y)
x +′ 0 = x
_+_ ≡ _+′_ -- ???
(as far as I know, this is an actual theorem and not just "proof by lack of imagination"; however, I ...

6

You can explicitly change the type of f x:
Π-equal : ∀ {α β} {A : Set α} {B : A -> Set β} {f : (x : A) -> B x} {x y : A}
-> (p : x ≡ y) -> P.subst B p (f x) ≡ f y
Π-equal refl = refl
Or
Π-equal'T : ∀ {α β} {A : Set α} {B : A -> Set β} -> ((x : A) -> B x) -> (x y : A) -> x ≡ y -> Set β
Π-equal'T f x y p with f x | f y
...

6

Names in type declarations which begin with a lower case letter are implicitly bound, so it's treating 'type' as a type parameter. You can either give 'type' a new name which begins with a capital (by convention this is what most people do in Idris) or you can explicitly qualify the name with the module it's in (Main, here).
Idris used to try guessing ...

6

I'm reading it as "given a term which requires l ~ r, return that
term"
It's "given a term whose type contains l, return that term with all ls being substituted by rs in the type" (or in the other direction r -> l). It's a very neat trick, that allows you to delegate all cong, trans, subst and similar stuff to GHC.
Here is an example:
{-# ...

5

The data type constructors are disjoint. I'd say it's a theorem in Agda's type-system meta-theory.
You can try to case the eq proof (C-c C-c), and Agda will find the contradiction:
lemma : ∀ {a b} {A : Set a} {B : Set b} {x : A} {y : B} → ¬ inj₁ x ≡ inj₂ y
lemma ()
This happily type-checks.

5

The problem here is that the iota rule is restricted for fixpoints: the Coq manual explicitly states that iota can only be applied to a fixpoint if the decreasing argument starts with a constructor.
This is done to ensure that the calculus of inductive constructions is strongly normalizing as a rewriting system: if we could always apply iota, then it would ...

5

Finding proofs in Hilbert calculus is very hard.
You could try to translate proofs in sequent calculus or natural deduction to Hilbert calculus.

5

ACL2 is notorious -- we used to say it was an expert system, and so could only be used by experts, who had to learn from Warren Hunt, J Moore, or Bob Boyer. The thing you need to do in ACL2 is really really understand how the proof system itself works; then you can "hint" it in directions that reduce the search space.
There are several other systems that ...

5

You can approach the problem also by setting ¬ α = α → ⊥. We can then adopt the Hilbert style system as shown in the appendix of one of the answers, and make it classical by adding the following two axioms respectively constants:
Ex Falso Quodlibet: Eα : ⊥ → α
Consequentia Mirabilis: Mα : (¬ α → α) → α
A sequent proof of ¬ (α → ¬ β) → α then reads as ...

5

You probably want to define the following function (even if you annotate it properly you [le_S m n x] does not have the type you want) :
Fixpoint lesseq (m n : nat) : option (m <= n) :=
match n with
| 0 =>
match m with
| 0 => Some (le_n 0)
| S m0 => None
end
| S p =>
match ...

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