0

Currently I have:

Require Import Coq.Init.Specif.
Require Import Coq.Arith.Arith. 

Definition Test(s: {x : nat | x > 1}) := True.

Lemma pTwoGt1 : 2 > 1. apply gt_Sn_n. Qed.

Eval compute in Test (exist _ 2 pTwoGt1).
  1. How can I prove for randomly high numbers, like: 10000 > 1 ?
  2. How can I simplify creation of a value for this sigma type? Currently I have to have separate few lines of code with a prove and even to have a name for it.
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For (1), you don't have to recurse all the way down the unary definition of 10000: you can just go two steps:

Lemma pLotsGt1 : 10000 > 1.
Proof.
  apply le_n_S, le_n_S, Nat.le_0_l.
Qed.

Unfortunately, the proof term is still rather big:

pLotsGt1 = 
le_n_S 1 (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (...)))))))))))))))))))))))
  (le_n_S 0 (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (...))))))))))))))))))))))
     (Nat.le_0_l (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (S (...)))))))))))))))))))))))
     : Init.Nat.of_num_uint
         (Number.UIntDecimal (Decimal.D1 (Decimal.D0 (Decimal.D0 (Decimal.D0 (Decimal.D0 Decimal.Nil)))))) >
       1

because le_n_S takes the (unary-encoded) big number as one of its arguments.

EDIT: Looking further, I notice that Coq actually represents big numbers like this as a list of digits. You can see it above, where we're calling of_num_uint on what is basically the list [1, 0, 0, 0, 0]. Unfolding things a bit, of_num_uint boils down to calls to Init.Nat.tail_addmul, which has a specification lemma:

Nat.tail_addmul_spec: forall r n m : nat, Nat.tail_addmul r n m = r + n * m

so you could actually handle your example with a decision procedure on the list of digits which would avoid having to construct the big unary expansion at any point.

Of course, this depends on where your "random" numbers are coming from in the first place. Presumably not from number literals in the source, so you probably are starting with the nat anyway.

1
  • Thanks! Interestingly Coq 8.12 do some automated optimisations and give me this message: To avoid stack overflow, large numbers in nat are interpreted as applications of Init.Nat.of_num_uint. [abstract-large-number,numbers]
    – The_Ghost
    Jan 12 at 21:13
1

You could follow chapter 7 of this book https://zenodo.org/record/4457887#.Ydbktdso-cM which covers how ordinals are formalized in the Math Comp library.

The key ingredient is to use a computational definition of >

1

I'm not sure this is what Enrico has in mind, but here is one possible way to proceed, using mathcomp finite types (which enable computation) instead of nat and ssreflect tactics language. Note that I_n.+1 is the finite type of ordinals of size n+1, i.e., naturals from 0 to n.

From mathcomp Require Import all_ssreflect.

Definition Test n (s : exists x : 'I_n.+1, x > 1) := true.

Lemma exists_gt_1 n (lt1n : 1 < n) : exists x : 'I_n.+1, x > 1.
Proof. by exists ord_max. Qed.

Eval compute in @Test 2 (exists_gt_1 2 is_true_true).
Eval compute in @Test 10000 (exists_gt_1 10000 is_true_true).

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