Module Projection

Representation of projections from closures and blocks.

type project_closure = {
set_of_closures : Variable.t;(*

must yield a set of closures

*)
closure_id : Closure_id.t;
}

The selection of one closure given a set of closures, required before a function defined by said set of closures can be applied. See more detailed documentation below on set_of_closures.

type move_within_set_of_closures = {
closure : Variable.t;(*

must yield a closure

*)
start_from : Closure_id.t;
move_to : Closure_id.t;
}

The selection of one closure given another closure in the same set of closures. See more detailed documentation below on set_of_closures. The move_to closure must be part of the free variables of start_from.

type project_var = {
closure : Variable.t;(*

must yield a closure

*)
closure_id : Closure_id.t;
var : Var_within_closure.t;
}

The selection from a closure of a variable bound by said closure. In other words, access to a function's environment. Also see more detailed documentation below on set_of_closures.

val print_project_closure : Format.formatter -> project_closure -> unit
val print_move_within_set_of_closures : Format.formatter -> move_within_set_of_closures -> unit
val print_project_var : Format.formatter -> project_var -> unit
val compare_project_var : project_var -> project_var -> int
val compare_project_closure : project_closure -> project_closure -> int
val compare_move_within_set_of_closures : move_within_set_of_closures -> move_within_set_of_closures -> int
type t =
| Project_var of project_var
| Project_closure of project_closure
| Move_within_set_of_closures of move_within_set_of_closures
| Field of int * Variable.t
include Identifiable.S with type t := t
module T : Identifiable.Thing with type t = t
include Identifiable.Thing with type t := T.t
include Hashtbl.HashedType with type t := T.t
val equal : T.t -> T.t -> bool

The equality predicate used to compare keys.

val hash : T.t -> int

A hashing function on keys. It must be such that if two keys are equal according to equal, then they have identical hash values as computed by hash. Examples: suitable (equal, hash) pairs for arbitrary key types include

  • ((=), hash) for comparing objects by structure (provided objects do not contain floats)
  • ((fun x y -> compare x y = 0), hash) for comparing objects by structure and handling Stdlib.nan correctly
  • ((==), hash) for comparing objects by physical equality (e.g. for mutable or cyclic objects).
include Map.OrderedType with type t := T.t
val compare : T.t -> T.t -> int

A total ordering function over the keys. This is a two-argument function f such that f e1 e2 is zero if the keys e1 and e2 are equal, f e1 e2 is strictly negative if e1 is smaller than e2, and f e1 e2 is strictly positive if e1 is greater than e2. Example: a suitable ordering function is the generic structural comparison function Stdlib.compare.

val output : out_channel -> T.t -> unit
val print : Format.formatter -> T.t -> unit
module Set : Identifiable.Set with module T := T
module Map : Identifiable.Map with module T := T
module Tbl : Identifiable.Tbl with module T := T
val projecting_from : t -> Variable.t

Return which variable the given projection projects from.

val map_projecting_from : t -> f:(Variable.t -> Variable.t) -> t

Change the variable that the given projection projects from.