Implicit Coercions¶
 Author
Amokrane Saïbi
General Presentation¶
This section describes the inheritance mechanism of Coq. In Coq with inheritance, we are not interested in adding any expressive power to our theory, but only convenience. Given a term, possibly not typable, we are interested in the problem of determining if it can be well typed modulo insertion of appropriate coercions. We allow to write:
f a
wheref:(forall x:A,B)
anda:A'
whenA'
can be seen in some sense as a subtype ofA
.
x:A
whenA
is not a type, but can be seen in a certain sense as a type: set, group, category etc.
f a
whenf
is not a function, but can be seen in a certain sense as a function: bijection, functor, any structure morphism etc.
Classes¶
A class with \(n\) parameters is any defined name with a type
forall (ident_{1} : type_{1})..(ident_{n}:type_{n}), sort
. Thus a class with
parameters is considered as a single class and not as a family of
classes. An object of a class is any term of type class term_{1} .. term_{n}
.
In addition to these userdefined classes, we have two builtin classes:
Sortclass
, the class of sorts; its objects are the terms whose type is a sort (e.g.Prop
orType
).
Funclass
, the class of functions; its objects are all the terms with a functional type, i.e. of formforall x:A,B
.
Formally, the syntax of classes is defined as:
Coercions¶
A name f
can be declared as a coercion between a source userdefined class
C
with \(n\) parameters and a target class D
if one of these
conditions holds:
D
is a userdefined class, then the type off
must have the formforall (x₁:A₁)..(xₙ:Aₙ)(y:C x₁..xₙ), D u₁..uₘ
where \(m\) is the number of parameters ofD
.
D
isFunclass
, then the type off
must have the formforall (x₁:A₁)..(xₙ:Aₙ)(y:C x₁..xₙ)(x:A), B
.
D
isSortclass
, then the type off
must have the formforall (x₁:A₁)..(xₙ:Aₙ)(y:C x₁..xₙ), s
withs
a sort.
We then write f : C >> D
. The restriction on the type
of coercions is called the uniform inheritance condition.
Note
The builtin class Sortclass
can be used as a source class, but
the builtin class Funclass
cannot.
To coerce an object t:C t₁..tₙ
of C
towards D
, we have to
apply the coercion f
to it; the obtained term f t₁..tₙ t
is
then an object of D
.
Identity Coercions¶
Identity coercions are special cases of coercions used to go around
the uniform inheritance condition. Let C
and D
be two classes
with respectively n
and m
parameters and
f:forall (x₁:T₁)..(xₖ:Tₖ)(y:C u₁..uₙ), D v₁..vₘ
a function which
does not verify the uniform inheritance condition. To declare f
as
coercion, one has first to declare a subclass C'
of C
:
C' := fun (x₁:T₁)..(xₖ:Tₖ) => C u₁..uₙ
We then define an identity coercion between C'
and C
:
Id_C'_C := fun (x₁:T₁)..(xₖ:Tₖ)(y:C' x₁..xₖ) => (y:C u₁..uₙ)
We can now declare f
as coercion from C'
to D
, since we can
"cast" its type as
forall (x₁:T₁)..(xₖ:Tₖ)(y:C' x₁..xₖ),D v₁..vₘ
.
The identity coercions have a special status: to coerce an object
t:C' t₁..tₖ
of C'
towards C
, we do not have to insert explicitly Id_C'_C
since Id_C'_C t₁..tₖ t
is convertible with t
. However we
"rewrite" the type of t
to become an object of C
; in this case,
it becomes C uₙ'..uₖ'
where each uᵢ'
is the result of the
substitution in uᵢ
of the variables xⱼ
by tⱼ
.
Inheritance Graph¶
Coercions form an inheritance graph with classes as nodes. We call
coercion path an ordered list of coercions between two nodes of
the graph. A class C
is said to be a subclass of D
if there is a
coercion path in the graph from C
to D
; we also say that C
inherits from D
. Our mechanism supports multiple inheritance since a
class may inherit from several classes, contrary to simple inheritance
where a class inherits from at most one class. However there must be
at most one path between two classes. If this is not the case, only
the oldest one is valid and the others are ignored. So the order
of declaration of coercions is important.
We extend notations for coercions to coercion paths. For instance
[f₁;..;fₖ] : C >> D
is the coercion path composed
by the coercions f₁..fₖ
. The application of a coercion path to a
term consists of the successive application of its coercions.
Declaring Coercions¶

Command
Coercion reference : class >> class
¶ 
Command
Coercion ident univ_decl? def_body
 name
Coercion; _
The first form declares the construction denoted by
reference
as a coercion between the two given classes. The second form definesident
just likeDefinition
ident univ_decl? def_body
and then declaresident
as a coercion between it source and its target. Both forms support thelocal
attribute, which makes the coercion local to the current section.
Error
Funclass cannot be a source class.
¶

Error
Found target class ... instead of ...
¶

Warning
New coercion path ... is ambiguous with existing ...
¶ When the coercion
qualid
is added to the inheritance graph, new coercion paths which have the same classes as existing ones are ignored. TheCoercion
command tries to check the convertibility of new ones and existing ones. The paths for which this check fails are displayed by a warning in the form[f₁;..;fₙ] : C >> D
.The convertibility checking procedure for coercion paths is complete for paths consisting of coercions satisfying the uniform inheritance condition, but some coercion paths could be reported as ambiguous even if they are convertible with existing ones when they have coercions that don't satisfy the uniform inheritance condition.

Warning
... is not definitionally an identity function.
¶ If a coercion path has the same source and target class, that is said to be circular. When a new circular coercion path is not convertible with the identity function, it will be reported as ambiguous.
Some objects can be declared as coercions when they are defined.
This applies to assumptions and
constructors of inductive types and record fields.
Use :>
instead of :
before the
type
of the assumption to do so. See of_type
.

Command
Identity Coercion ident : class >> class
¶ If
C
is the sourceclass
andD
the destination, we check thatC
is a constant with a body of the formfun (x₁:T₁)..(xₙ:Tₙ) => D t₁..tₘ
wherem
is the number of parameters ofD
. Then we define an identity function with typeforall (x₁:T₁)..(xₙ:Tₙ)(y:C x₁..xₙ),D t₁..tₘ
, and we declare it as an identity coercion betweenC
andD
.This command supports the
local
attribute, which makes the coercion local to the current section.
Command
SubClass ident_decl def_body
¶ If
type
is a classident'
applied to some arguments thenident
is defined and an identity coercion of nameId_ident_ident'
is declared. Otherwise said, this is an abbreviation forDefinition ident := type.
Identity Coercion Id_ident_ident' : ident >> ident'
.This command supports the
local
attribute, which makes the coercion local to the current section.

Command
Displaying Available Coercions¶

Command
Print Classes
¶ Print the list of declared classes in the current context.

Command
Print Coercions
¶ Print the list of declared coercions in the current context.

Command
Print Graph
¶ Print the list of valid coercion paths in the current context.
Activating the Printing of Coercions¶

Flag
Printing Coercions
¶ When on, this flag forces all the coercions to be printed. By default, coercions are not printed.
Classes as Records¶
Structures with Inheritance may be defined using the Record
command.
Use >
before the record name to declare the constructor name as
a coercion from the class of the last field type to the record name
(this may fail if the uniform inheritance condition is not
satisfied). See record_definition
.
Use :>
in the field type to declare the field as a coercion from the record name
to the class of the field type. See of_type
.
Coercions and Sections¶
The inheritance mechanism is compatible with the section mechanism. The global classes and coercions defined inside a section are redefined after its closing, using their new value and new type. The classes and coercions which are local to the section are simply forgotten. Coercions with a local source class or a local target class, and coercions which do not verify the uniform inheritance condition any longer are also forgotten.
Coercions and Modules¶
The coercions present in a module are activated only when the module is explicitly imported.
Examples¶
There are three situations:
Coercion at function application¶
f a
is illtyped where f:forall x:A,B
and a:A'
. If there is a
coercion path between A'
and A
, then f a
is transformed into
f a'
where a'
is the result of the application of this
coercion path to a
.
We first give an example of coercion between atomic inductive types
 Definition bool_in_nat (b:bool) := if b then 0 else 1.
 bool_in_nat is defined
 Coercion bool_in_nat : bool >> nat.
 bool_in_nat is now a coercion
 Check (0 = true).
 0 = true : Prop
 Set Printing Coercions.
 Check (0 = true).
 0 = bool_in_nat true : Prop
 Unset Printing Coercions.
Warning
Note that Check (true = O)
would fail. This is "normal" behavior of
coercions. To validate true=O
, the coercion is searched from
nat
to bool
. There is none.
We give an example of coercion between classes with parameters.
 Parameters (C : nat > Set) (D : nat > bool > Set) (E : bool > Set).
 C is declared D is declared E is declared
 Parameter f : forall n:nat, C n > D (S n) true.
 f is declared
 Coercion f : C >> D.
 f is now a coercion
 Parameter g : forall (n:nat) (b:bool), D n b > E b.
 g is declared
 Coercion g : D >> E.
 g is now a coercion
 Parameter c : C 0.
 c is declared
 Parameter T : E true > nat.
 T is declared
 Check (T c).
 T c : nat
 Set Printing Coercions.
 Check (T c).
 T (g 1 true (f 0 c)) : nat
 Unset Printing Coercions.
We give now an example using identity coercions.
 Definition D' (b:bool) := D 1 b.
 D' is defined
 Identity Coercion IdD'D : D' >> D.
 Print IdD'D.
 IdD'D = (fun (b : bool) (x : D' b) => x) : forall b : bool, D' b > D 1 b : forall b : bool, D' b > D 1 b Arguments IdD'D _%bool_scope IdD'D is a coercion
 Parameter d' : D' true.
 d' is declared
 Check (T d').
 T d' : nat
 Set Printing Coercions.
 Check (T d').
 T (g 1 true d') : nat
 Unset Printing Coercions.
In the case of functional arguments, we use the monotonic rule of
subtyping. To coerce t : forall x : A, B
towards
forall x : A', B'
, we have to coerce A'
towards A
and B
towards B'
. An example is given below:
 Parameters (A B : Set) (h : A > B).
 A is declared B is declared h is declared
 Coercion h : A >> B.
 h is now a coercion
 Parameter U : (A > E true) > nat.
 U is declared
 Parameter t : B > C 0.
 t is declared
 Check (U t).
 U (fun x : A => t x) : nat
 Set Printing Coercions.
 Check (U t).
 U (fun x : A => g 1 true (f 0 (t (h x)))) : nat
 Unset Printing Coercions.
Remark the changes in the result following the modification of the previous example.
 Parameter U' : (C 0 > B) > nat.
 U' is declared
 Parameter t' : E true > A.
 t' is declared
 Check (U' t').
 U' (fun x : C 0 => t' x) : nat
 Set Printing Coercions.
 Check (U' t').
 U' (fun x : C 0 => h (t' (g 1 true (f 0 x)))) : nat
 Unset Printing Coercions.
Coercion to a type¶
An assumption x:A
when A
is not a type, is illtyped. It is
replaced by x:A'
where A'
is the result of the application to
A
of the coercion path between the class of A
and
Sortclass
if it exists. This case occurs in the abstraction
fun x:A => t
, universal quantification forall x:A,B
, global
variables and parameters of (co)inductive definitions and
functions. In forall x:A,B
, such a coercion path may also be applied
to B
if necessary.
 Parameter Graph : Type.
 Graph is declared
 Parameter Node : Graph > Type.
 Node is declared
 Coercion Node : Graph >> Sortclass.
 Node is now a coercion
 Parameter G : Graph.
 G is declared
 Parameter Arrows : G > G > Type.
 Arrows is declared
 Check Arrows.
 Arrows : G > G > Type
 Parameter fg : G > G.
 fg is declared
 Check fg.
 fg : G > G
 Set Printing Coercions.
 Check fg.
 fg : Node G > Node G
 Unset Printing Coercions.
Coercion to a function¶
f a
is illtyped because f:A
is not a function. The term
f
is replaced by the term obtained by applying to f
the
coercion path between A
and Funclass
if it exists.
 Parameter bij : Set > Set > Set.
 bij is declared
 Parameter ap : forall A B:Set, bij A B > A > B.
 ap is declared
 Coercion ap : bij >> Funclass.
 ap is now a coercion
 Parameter b : bij nat nat.
 b is declared
 Check (b 0).
 b 0 : nat
 Set Printing Coercions.
 Check (b 0).
 ap nat nat b 0 : nat
 Unset Printing Coercions.
Let us see the resulting graph after all these examples.
 Print Graph.
 [bool_in_nat] : bool >> nat [f] : C >> D [f; g] : C >> E [g] : D >> E [IdD'D] : D' >> D [IdD'D; g] : D' >> E [h] : A >> B [Node] : Graph >> Sortclass [ap] : bij >> Funclass