# Coq MSet of bounded naturals

I am trying to define a type for Set of natural numbers with given upper bound. Standard library's `MSet` seems to be a way to go. I found this discussion which gives a nice example of how to define a Set of `nat`. However I do could not figure out how to extend it to subset types. I tried something like this:

``````Module OWL.
Parameter n : nat.
Definition t := {i:nat | i<n}.
Definition eq := @eq t.
Instance eq_equiv : @Equivalence t eq := eq_equivalence.
Definition lt (a b:t) := Peano.lt (proj1_sig a) (proj1_sig b).
Instance lt_strorder : @StrictOrder t lt.
...
``````

I will be working with sets with different upper bounds. But I do not see how to instantiate this Module with given 'n'. Ideally, I would like to be able to write something like this:

``````Module BoundedMNatSets := MakeWithLeibniz OWL.
Definition BoundedMNatSetN (n:nat) : Type := BoundedMNatSets n.
``````

P.S. This question is probably rooted in my insufficient understanding of Coq module system, and not specific to Sets.

• Does `Module OWL <: OrderedType.` help? Mar 29, 2017 at 8:03
• I think my problem not with ordering but with parametrization. I would like to have a set parametrized by `n`. Mar 29, 2017 at 16:51
• You will need to use a functor I'm afraid. Mar 29, 2017 at 17:26
• I am not entirely sure what application you have in mind, but did you consider type classes or canonical structures. Mar 30, 2017 at 8:24
• I will gladly consider type classes. What I need is fairly basic library supporting sets of bounded natural numbers. I will need to construct these sets, preferably using index functions and perform simple basic operations like set union, intersection, and difference. I looked at what math-classes have to offer but I have not figured how to apply these easily to bounded naturals. A small example would be greatly appreciated! Since I am already using math-classes it would be great to use it for sets also! Mar 30, 2017 at 8:58

You need to use a functor. Something like:

``````Require Import Orders.

Module Type FIXED_NAT.
Parameter n : nat.
End FIXED_NAT.

Module OWL (N : FIXED_NAT) <: OrderedType.
Definition t := {i:nat | i < N.n}.
...
End OWL.
``````

You can then apply `OWL` to modules of signature `FIXED_NAT`.

``````Module N1 <: FIXED_NAT.
Definition n := 10.
End N1.

Module OWL1 := OWL N1.

Require Import MSets.

Module M1 := Make OWL1.
``````

``````Require Import Orders.
Require Import OrdersEx.
Require Import MSets.
Require Import Arith.

Module M := Make Nat_as_OT.

Definition has_upper_bound s n := M.For_all (ge n) s.

Definition t n := {s : M.t | has_upper_bound s n}.
``````
• Thanks! It helps a bit, but this is not exactly what I want to achieve. I would like to have `n` to be a parameter of type MNatSet, so I can use different sizes in different situations, without each time instantiating a module. For example using `Ensembles` I could do something like this: Require Import Coq.Sets.Ensembles. Definition EFinNatSet (n:nat) : Type := Ensemble {x:nat | (x<n)}. Definition singleS (n:nat) (i:nat): EFinNatSet n := .... Mar 29, 2017 at 15:37
• I am playing with the last solution you suggested in the update. It looks interesting. I will update here once I will understand it better. Thanks! Mar 30, 2017 at 17:52
• It looks like the suggested way may work for me. I have just a quick follow-up questions: 1) Why you chose `bool` instead of `prop`. 2) Why `fold` not `For_all` 3) How do I get additional lemmas such as in MSetFacts or MSetInterface for this set? Thanks! P.S. Here is a small example reworking your suggestion to Prop/Forall and trying to prove a simple lemma using it. ideone.com/gKcl6j Any comments are very welcome. Mar 30, 2017 at 22:59
• Really good questions ! 2) is because I did not know `for_all` and 1) is because I did not know `For_all`. I will update the answer. I am not sure if I understand 3). The basic answer would be to apply functors, such as `Module F := Facts M.`. If you want to import at the same time, you can do directly `Module Import F := Facts M.`. Mar 31, 2017 at 8:46