SProp (proof irrelevant propositions)¶
Warning
The status of strict propositions is experimental.
In particular, conversion checking through bytecode or native code compilation currently does not understand proof irrelevance.
This section describes the extension of Coq with definitionally proof irrelevant propositions (types in the sort \(\SProp\), also known as strict propositions) as described in [GCST19].
Use of \(\SProp\) may be disabled by passing -disallow-sprop
to the
Coq program or by turning the Allow StrictProp
flag off.
- Flag Allow StrictProp¶
This flag enables or disables the use of \(\SProp\). It is enabled by default. The command-line flag
-disallow-sprop
disables \(\SProp\) at startup.- Error SProp is disallowed because the "Allow StrictProp" flag is off.¶
Some of the definitions described in this document are available
through Coq.Logic.StrictProp
, which see.
Basic constructs¶
The purpose of \(\SProp\) is to provide types where all elements are convertible:
- Theorem irrelevance (A : SProp) (P : A -> Prop) : forall x : A, P x -> forall y : A, P y.
- 1 goal A : SProp P : A -> Prop ============================ forall x : A, P x -> forall y : A, P y
- Proof.
- intros * Hx *.
- 1 goal A : SProp P : A -> Prop x : A Hx : P x y : A ============================ P y
- exact Hx.
- No more goals.
- Qed.
Since we have definitional η-expansion for functions, the property of being a type of definitionally irrelevant values is impredicative, and so is \(\SProp\):
- Check fun (A:Type) (B:A -> SProp) => (forall x:A, B x) : SProp.
- fun (A : Type) (B : A -> SProp) => (forall x : A, B x) : SProp : forall A : Type, (A -> SProp) -> SProp
In order to keep conversion tractable, cumulativity for \(\SProp\) is forbidden.
- Fail Check (fun (A:SProp) => A : Type).
- The command has indeed failed with message: In environment A : SProp The term "A" has type "SProp" while it is expected to have type "Type" (universe inconsistency: Cannot enforce SProp <= Top.2).
We can explicitly lift strict propositions into the relevant world by using a wrapping inductive type. The inductive stops definitional proof irrelevance from escaping.
- Inductive Box (A:SProp) : Prop := box : A -> Box A.
- Box is defined Box_rect is defined Box_ind is defined Box_rec is defined Box_sind is defined
- Arguments box {_} _.
- Fail Check fun (A:SProp) (x y : Box A) => eq_refl : x = y.
- The command has indeed failed with message: In environment A : SProp x : Box A y : Box A The term "eq_refl" has type "x = x" while it is expected to have type "x = y" (cannot unify "x" and "y").
- Definition box_irrelevant (A:SProp) (x y : Box A) : x = y := match x, y with box x, box y => eq_refl end.
- box_irrelevant is defined
In the other direction, we can use impredicativity to "squash" a relevant type, making an irrelevant approximation.
Or more conveniently (but equivalently)
Most inductives types defined in \(\SProp\) are squashed types, i.e. they can only be eliminated to construct proofs of other strict propositions. Empty types are the only exception.
- Inductive sEmpty : SProp := .
- sEmpty is defined sEmpty_rect is defined sEmpty_ind is defined sEmpty_rec is defined sEmpty_sind is defined
- Check sEmpty_rect.
- sEmpty_rect : forall (P : sEmpty -> Type) (s : sEmpty), P s
Note
Eliminators to strict propositions are called foo_sind
, in the
same way that eliminators to propositions are called foo_ind
.
Primitive records in \(\SProp\) are allowed when fields are strict propositions, for instance:
- Set Primitive Projections.
- Record sProd (A B : SProp) : SProp := { sfst : A; ssnd : B }.
- sProd is defined sfst is defined ssnd is defined
On the other hand, to avoid having definitionally irrelevant types in non-\(\SProp\) sorts (through record η-extensionality), primitive records in relevant sorts must have at least one relevant field.
- Set Warnings "+non-primitive-record".
- Fail Record rBox (A:SProp) : Prop := rbox { runbox : A }.
- The command has indeed failed with message: The record rBox could not be defined as a primitive record. [non-primitive-record,records,default]
Note that rBox
works as an emulated record, which is equivalent to
the Box inductive.
Encodings for strict propositions¶
The elimination for unit types can be encoded by a trivial function thanks to proof irrelevance:
By using empty and unit types as base values, we can encode other strict propositions. For instance:
Definitional UIP¶
- Flag Definitional UIP¶
This flag, off by default, allows the declaration of non-squashed inductive types with 1 constructor which takes no argument in \(\SProp\). Since this includes equality types, it provides definitional uniqueness of identity proofs.
Because squashing is a universe restriction, unsetting
Universe Checking
is stronger than settingDefinitional UIP
.
Definitional UIP involves a special reduction rule through which reduction depends on conversion. Consider the following code:
- Set Definitional UIP.
- Inductive seq {A} (a:A) : A -> SProp := srefl : seq a a.
- seq is defined seq_rect is defined seq_ind is defined seq_rec is defined seq_sind is defined
- Axiom e : seq 0 0.
- e is declared
- Definition hidden_arrow := match e return Set with srefl _ => nat -> nat end.
- hidden_arrow is defined
- Check (fun (f : hidden_arrow) (x:nat) => (f : nat -> nat) x).
- fun (f : hidden_arrow) (x : nat) => (f : nat -> nat) x : hidden_arrow -> nat -> nat
By the usual reduction rules hidden_arrow
is a stuck match, but
by proof irrelevance e
is convertible to srefl 0
and then by
congruence hidden_arrow
is convertible to nat -> nat
.
The special reduction reduces any match on a type which uses
definitional UIP when the indices are convertible to those of the
constructor. For seq
, this means a match on a value of type seq x
y
reduces if and only if x
and y
are convertible.
Such matches are indicated in the printed representation by inserting a cast around the discriminee:
- Print hidden_arrow.
- hidden_arrow = match e with | srefl _ => nat -> nat end : Set
Non Termination with UIP¶
The special reduction rule of UIP combined with an impredicative sort breaks termination of reduction [AC19]:
- Axiom all_eq : forall (P Q:Prop), P -> Q -> seq P Q.
- all_eq is declared
- Definition transport (P Q:Prop) (x:P) (y:Q) : Q := match all_eq P Q x y with srefl _ => x end.
- transport is defined
- Definition top : Prop := forall P : Prop, P -> P.
- top is defined
- Definition c : top := fun P p => transport (top -> top) P (fun x : top => x (top -> top) (fun x => x) x) p.
- c is defined
- Fail Timeout 1 Eval lazy in c (top -> top) (fun x => x) c.
- The command has indeed failed with message: Timeout!
The term c (top -> top) (fun x => x) c
infinitely reduces to itself.
Debugging \(\SProp\) issues¶
Every binder in a term (such as fun x
or forall x
) caches
information called the relevance mark indicating whether its type is
in \(\SProp\) or not. This is used to efficiently implement proof
irrelevance.
The user should usually not be concerned with relevance marks, so by default they are not displayed. However code outside the kernel may generate incorrect marks resulting in bugs. Typically this means a conversion will incorrectly fail as a variable was incorrectly marked proof relevant.
- Warning Bad relevance¶
This is a developer warning, which is treated as an error by default. It is emitted by the kernel when it is passed a term with incorrect relevance marks. This is always caused by a bug in Coq (or a plugin), which should thus be reported and fixed. In order to allow the user to work around such bugs, we leave the ability to unset the
bad-relevance
warning for the time being, so that the kernel will silently repair the proof term instead of failing.
- Flag Printing Relevance Marks¶
This flag enables debug printing of relevance marks. It is off by default. Note that
Printing All
does not affect printing of relevance marks.- Set Printing Relevance Marks.
- Check fun x : nat => x.
- fun x : (* Relevant *) nat => x : nat -> nat
- Check fun (P:SProp) (p:P) => p.
- fun (P : (* Relevant *) SProp) (p : (* Irrelevant *) P) => p : forall P : (* Relevant *) SProp, P -> P