infer_clone/sledge/lib/equality.mli

(*
 * Copyright (c) Facebook, Inc. and its affiliates.
 *
 * This source code is licensed under the MIT license found in the
 * LICENSE file in the root directory of this source tree.
 *)

(** Constraints representing equivalence relations over uninterpreted
    functions and linear rational arithmetic *)

type t [@@deriving compare, equal, sexp]

val pp : t pp
val pp_classes : t pp
val ppx_classes : Var.strength -> t pp
val ppx_classes_diff : Var.strength -> (t * t) pp

include Invariant.S with type t := t

val true_ : t
(** The diagonal relation, which only equates each term with itself. *)

val and_eq : Var.Set.t -> Term.t -> Term.t -> t -> Var.Set.t * t
(** Conjoin an equation to a relation. *)

val and_term : Var.Set.t -> Term.t -> t -> Var.Set.t * t
(** Conjoin a (Boolean) term to a relation. *)

val and_ : Var.Set.t -> t -> t -> Var.Set.t * t
(** Conjunction. *)

val or_ : Var.Set.t -> t -> t -> Var.Set.t * t
(** Disjunction. *)

val orN : Var.Set.t -> t list -> Var.Set.t * t
(** Nary disjunction. *)

val rename : t -> Var.Subst.t -> t
(** Apply a renaming substitution to the relation. *)

val fv : t -> Var.Set.t
(** The variables occurring in the terms of the relation. *)

val is_true : t -> bool
(** Test if the relation is diagonal. *)

val is_false : t -> bool
(** Test if the relation is empty / inconsistent. *)

val entails_eq : t -> Term.t -> Term.t -> bool
(** Test if an equation is entailed by a relation. *)

val entails : t -> t -> bool
(** Test if one relation entails another. *)

val class_of : t -> Term.t -> Term.t list
(** Equivalence class of [e]: all the terms [f] in the relation such that
    [e = f] is implied by the relation. *)

val normalize : t -> Term.t -> Term.t
(** Normalize a term [e] to [e'] such that [e = e'] is implied by the
    relation, where [e'] and its subterms are expressed in terms of the
    relation's canonical representatives of each equivalence class. *)

val difference : t -> Term.t -> Term.t -> Z.t option
(** The difference as an offset. [difference r a b = Some k] if [r] implies
    [a = b+k], or [None] if [a] and [b] are not equal up to an integer
    offset. *)

val fold_terms : t -> init:'a -> f:('a -> Term.t -> 'a) -> 'a

(** Solution Substitutions *)
module Subst : sig
  type t [@@deriving compare, equal, sexp]

  val pp : t pp
  val is_empty : t -> bool
  val fold : t -> init:'a -> f:(key:Term.t -> data:Term.t -> 'a -> 'a) -> 'a

  val subst : t -> Term.t -> Term.t
  (** Apply a substitution recursively to subterms. *)

  val partition_valid : Var.Set.t -> t -> t * Var.Set.t * t
  (** Partition ∃xs. σ into equivalent ∃xs. τ ∧ ∃ks. ν where ks
      and ν are maximal where ∃ks. ν is universally valid, xs ⊇ ks and
      ks ∩ fv(τ) = ∅. *)
end

val apply_subst : Var.Set.t -> Subst.t -> t -> Var.Set.t * t
(** Relation induced by applying a substitution to a set of equations
    generating the argument relation. *)

val solve_for_vars : Var.Set.t list -> t -> Subst.t
(** [solve_for_vars vss r] is a solution substitution that is entailed by
    [r] and consists of oriented equalities [x ↦ e] that map terms [x]
    with free variables contained in (the union of) a prefix [uss] of [vss]
    to terms [e] with free variables contained in as short a prefix of [uss]
    as possible. *)
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
+								(*
-												[copyright] Remove years

Reviewed By: jvillard

Differential Revision: D15771884

fbshipit-source-id: e2997e3a3

											
										
										
											6 years ago
+								 * Copyright (c) Facebook, Inc. and its affiliates.
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
+								 *
 								 * This source code is licensed under the MIT license found in the
 								 * LICENSE file in the root directory of this source tree.
 								 *)
 								(** Constraints representing equivalence relations over uninterpreted
 								    functions and linear rational arithmetic *)
-												[sledge] Use ppx_compare to define equal functions

Summary:
With ppx_compare 0.12, `[@deriving equal]` now generates efficient
`equal` functions.

Reviewed By: mbouaziz

Differential Revision: D14297866

fbshipit-source-id: a303090cb

											
										
										
											6 years ago
+								type t [@@deriving compare, equal, sexp]
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
 								val pp : t pp
-												[sledge] Improve consistency of naming Equality pp functions

Summary:
Match the `x` suffix naming convention of Term pp functions that take
a classification function.

Reviewed By: ngorogiannis

Differential Revision: D19282639

fbshipit-source-id: fc340e4bc

											
										
										
											5 years ago
+								val pp_classes : t pp
 								val ppx_classes : Var.strength -> t pp
 								val ppx_classes_diff : Var.strength -> (t * t) pp
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
 								include Invariant.S with type t := t
 								val true_ : t
-												[sledge] Distinguish program expressions and formula terms

Summary:
There are a number if issues with using the same type for expressions
in code and in formulas. One is that the type systems of the two
should be different. Another is that conflating the two compromises
the ability of Llair to correctly express aspects such as integer
overflow, floating point rounding, etc. Also, it could be beneficial
to have more source locations for program expressions than makes sense
for terms.

This diff simply unshares Exp, leading to a copy named Term. Likewise,
Reg is now a copy of Var. Simplifications to come.

Reviewed By: bennostein

Differential Revision: D17665250

fbshipit-source-id: 4359a80d5

											
										
										
											5 years ago
+								(** The diagonal relation, which only equates each term with itself. *)
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
-												[sledge] Support Equality.solve generating fresh variables

Reviewed By: ngorogiannis

Differential Revision: D19286633

fbshipit-source-id: 41ba53d65

											
										
										
											5 years ago
+								val and_eq : Var.Set.t -> Term.t -> Term.t -> t -> Var.Set.t * t
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
+								(** Conjoin an equation to a relation. *)
-												[sledge] Move mediation between Term and Equality APIs from Sh to Equality

Summary: Add `Equality.and_term` and replace most of `Sh.pure` with it.

Reviewed By: ngorogiannis

Differential Revision: D20029742

fbshipit-source-id: 07c2f1fe6

											
										
										
											5 years ago
+								val and_term : Var.Set.t -> Term.t -> t -> Var.Set.t * t
 								(** Conjoin a (Boolean) term to a relation. *)
-												[sledge] Support Equality.solve generating fresh variables

Reviewed By: ngorogiannis

Differential Revision: D19286633

fbshipit-source-id: 41ba53d65

											
										
										
											5 years ago
+								val and_ : Var.Set.t -> t -> t -> Var.Set.t * t
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
+								(** Conjunction. *)
-												[sledge] Support Equality.solve generating fresh variables

Reviewed By: ngorogiannis

Differential Revision: D19286633

fbshipit-source-id: 41ba53d65

											
										
										
											5 years ago
+								val or_ : Var.Set.t -> t -> t -> Var.Set.t * t
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
+								(** Disjunction. *)
-												[sledge] Eliminate redundant existential quantifiers

Summary:
This diff changes `Sh.simplify` from a logically-weakening syntactic
simplification to an equivalence-preserving rewrite. The
implementation is based on `Equality.solve_for_vars` which is also
used by `Solver` to witness existential variables.

Reviewed By: jvillard

Differential Revision: D20120274

fbshipit-source-id: 5e11659ea

											
										
										
											5 years ago
+								val orN : Var.Set.t -> t list -> Var.Set.t * t
 								(** Nary disjunction. *)
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
+								val rename : t -> Var.Subst.t -> t
 								(** Apply a renaming substitution to the relation. *)
 								val fv : t -> Var.Set.t
-												[sledge] Distinguish program expressions and formula terms

Summary:
There are a number if issues with using the same type for expressions
in code and in formulas. One is that the type systems of the two
should be different. Another is that conflating the two compromises
the ability of Llair to correctly express aspects such as integer
overflow, floating point rounding, etc. Also, it could be beneficial
to have more source locations for program expressions than makes sense
for terms.

This diff simply unshares Exp, leading to a copy named Term. Likewise,
Reg is now a copy of Var. Simplifications to come.

Reviewed By: bennostein

Differential Revision: D17665250

fbshipit-source-id: 4359a80d5

											
										
										
											5 years ago
+								(** The variables occurring in the terms of the relation. *)
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
 								val is_true : t -> bool
 								(** Test if the relation is diagonal. *)
 								val is_false : t -> bool
 								(** Test if the relation is empty / inconsistent. *)
-												[sledge] Distinguish program expressions and formula terms

Summary:
There are a number if issues with using the same type for expressions
in code and in formulas. One is that the type systems of the two
should be different. Another is that conflating the two compromises
the ability of Llair to correctly express aspects such as integer
overflow, floating point rounding, etc. Also, it could be beneficial
to have more source locations for program expressions than makes sense
for terms.

This diff simply unshares Exp, leading to a copy named Term. Likewise,
Reg is now a copy of Var. Simplifications to come.

Reviewed By: bennostein

Differential Revision: D17665250

fbshipit-source-id: 4359a80d5

											
										
										
											5 years ago
+								val entails_eq : t -> Term.t -> Term.t -> bool
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
+								(** Test if an equation is entailed by a relation. *)
 								val entails : t -> t -> bool
 								(** Test if one relation entails another. *)
-												[sledge] Distinguish program expressions and formula terms

Summary:
There are a number if issues with using the same type for expressions
in code and in formulas. One is that the type systems of the two
should be different. Another is that conflating the two compromises
the ability of Llair to correctly express aspects such as integer
overflow, floating point rounding, etc. Also, it could be beneficial
to have more source locations for program expressions than makes sense
for terms.

This diff simply unshares Exp, leading to a copy named Term. Likewise,
Reg is now a copy of Var. Simplifications to come.

Reviewed By: bennostein

Differential Revision: D17665250

fbshipit-source-id: 4359a80d5

											
										
										
											5 years ago
+								val class_of : t -> Term.t -> Term.t list
-												[ocamlformat] Enable parsing and reformatting docstrings

Summary:
This diff enables parsing and auto-formatting documentation
comments (aka docstrings).

I have looked at this entire diff and manually made some changes to
improve the formatting. In some cases it looked like it would take too
much time, or benefit from someone more familiar with the code doing
it, and I instead disabled auto-formatting docstrings in those files.

Also, there are some source files where the docstrings are invalid,
and some where the structure detected by the parser appears not to
match what was intended. Auto-formatting has been disabled for these
files.

Reviewed By: ezgicicek

Differential Revision: D18755888

fbshipit-source-id: 68d72465d

											
										
										
											5 years ago
+								(** Equivalence class of [e]: all the terms [f] in the relation such that
 								    [e = f] is implied by the relation. *)
-												[sledge] Function summarization: solver can show pre

Summary:
This diff is preparation for function summarization and focuses on
function calls and function summary precondition computation.

It introduces `-function-summaries` flag behind most of functionality is
hidden, when enabled on each call

* A function summary is computed by quantifying all the non-formal/global variables
  and removing all the segments that are not reachable from them
* `pre` and `foot` are computed from function summary and the calling context
  by replacing formals with actuals again.
* A solver is asked if `pre` entails `foot` and a frame is printed if it
  does

Currently this only works for formulas without disjunctions, so when
function summaries are enabled, that state is first moved to dnf and then
the call is done for each disjunct.

Reviewed By: ngorogiannis

Differential Revision: D15898928

fbshipit-source-id: 49d32504c

											
										
										
											5 years ago
-												[sledge] Distinguish program expressions and formula terms

Summary:
There are a number if issues with using the same type for expressions
in code and in formulas. One is that the type systems of the two
should be different. Another is that conflating the two compromises
the ability of Llair to correctly express aspects such as integer
overflow, floating point rounding, etc. Also, it could be beneficial
to have more source locations for program expressions than makes sense
for terms.

This diff simply unshares Exp, leading to a copy named Term. Likewise,
Reg is now a copy of Var. Simplifications to come.

Reviewed By: bennostein

Differential Revision: D17665250

fbshipit-source-id: 4359a80d5

											
										
										
											5 years ago
+								val normalize : t -> Term.t -> Term.t
 								(** Normalize a term [e] to [e'] such that [e = e'] is implied by the
 								    relation, where [e'] and its subterms are expressed in terms of the
-												[sledge] Function summarization: solver can show pre

Summary:
This diff is preparation for function summarization and focuses on
function calls and function summary precondition computation.

It introduces `-function-summaries` flag behind most of functionality is
hidden, when enabled on each call

* A function summary is computed by quantifying all the non-formal/global variables
  and removing all the segments that are not reachable from them
* `pre` and `foot` are computed from function summary and the calling context
  by replacing formals with actuals again.
* A solver is asked if `pre` entails `foot` and a frame is printed if it
  does

Currently this only works for formulas without disjunctions, so when
function summaries are enabled, that state is first moved to dnf and then
the call is done for each disjunct.

Reviewed By: ngorogiannis

Differential Revision: D15898928

fbshipit-source-id: 49d32504c

											
										
										
											5 years ago
+								    relation's canonical representatives of each equivalence class. *)
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
-												[sledge] Distinguish program expressions and formula terms

Summary:
There are a number if issues with using the same type for expressions
in code and in formulas. One is that the type systems of the two
should be different. Another is that conflating the two compromises
the ability of Llair to correctly express aspects such as integer
overflow, floating point rounding, etc. Also, it could be beneficial
to have more source locations for program expressions than makes sense
for terms.

This diff simply unshares Exp, leading to a copy named Term. Likewise,
Reg is now a copy of Var. Simplifications to come.

Reviewed By: bennostein

Differential Revision: D17665250

fbshipit-source-id: 4359a80d5

											
										
										
											5 years ago
+								val difference : t -> Term.t -> Term.t -> Z.t option
-												[sledge] Initial Shostak-style treatment of UIF+LIA

Summary:
This patch adds an embarrassingly inefficient implementation of a
decision procedure for equality in the theories of uninterpreted
functions and linear arithmetic. A Shostak-style approach, where a
single congruence closure structure is shared by all theories, is
used. This is mostly based on the corrected variant of Shostak's
algorithm from:

Harald Rueβ and Natarajan Shankar. 2001. Deconstructing Shostak. In
Proceedings of the 16th Annual IEEE Symposium on Logic in Computer
Science (LICS '01).

Reviewed By: jvillard

Differential Revision: D14251655

fbshipit-source-id: 8a080145f

											
										
										
											6 years ago
+								(** The difference as an offset. [difference r a b = Some k] if [r] implies
 								    [a = b+k], or [None] if [a] and [b] are not equal up to an integer
 								    offset. *)
-												[sledge] Distinguish program expressions and formula terms

Summary:
There are a number if issues with using the same type for expressions
in code and in formulas. One is that the type systems of the two
should be different. Another is that conflating the two compromises
the ability of Llair to correctly express aspects such as integer
overflow, floating point rounding, etc. Also, it could be beneficial
to have more source locations for program expressions than makes sense
for terms.

This diff simply unshares Exp, leading to a copy named Term. Likewise,
Reg is now a copy of Var. Simplifications to come.

Reviewed By: bennostein

Differential Revision: D17665250

fbshipit-source-id: 4359a80d5

											
										
										
											5 years ago
+								val fold_terms : t -> init:'a -> f:('a -> Term.t -> 'a) -> 'a
-												[sledge] Add Equality.solve_for_vars

Summary:
```
val solve_for_vars : Var.Set.t list -> t -> Subst.t
(** [solve_for_vars \[v₁;…\] r] is a solution substitution that is
    entailed by [r] and consists of oriented equalities [x ↦ u] such that
    [fv x ⊈ vᵢ ⊇ fv u] where [i] is minimal such that [vᵢ]
    distinguishes [fv x] and [fv u], if one exists. *)
```

To be used for existential witnessing and quantifier elimination.

Reviewed By: ngorogiannis

Differential Revision: D19282636

fbshipit-source-id: c5b006cea

											
										
										
											5 years ago
 								(** Solution Substitutions *)
 								module Subst : sig
 								  type t [@@deriving compare, equal, sexp]
-												[sledge] Strengthen Solver's treatment of existentials using Equality

Summary:
Equality.solve_for_var_contexts can produce solution substitutions
that witness existentials in more cases than the
single-existential-occurrence heuristic, and is more conservative in
cases where the latter is incomplete.

Reviewed By: ngorogiannis

Differential Revision: D19282634

fbshipit-source-id: f86f0a9cb

											
										
										
											5 years ago
 								  val pp : t pp
 								  val is_empty : t -> bool
 								  val fold : t -> init:'a -> f:(key:Term.t -> data:Term.t -> 'a -> 'a) -> 'a
-												[sledge] Eliminate redundant existential quantifiers

Summary:
This diff changes `Sh.simplify` from a logically-weakening syntactic
simplification to an equivalence-preserving rewrite. The
implementation is based on `Equality.solve_for_vars` which is also
used by `Solver` to witness existential variables.

Reviewed By: jvillard

Differential Revision: D20120274

fbshipit-source-id: 5e11659ea

											
										
										
											5 years ago
 								  val subst : t -> Term.t -> Term.t
 								  (** Apply a substitution recursively to subterms. *)
-												[sledge] Replace solution substitution trimming with partitioning

Summary:
Replace `Equality.Subst.trim` with `partition_valid` which has a
logical specification (and unsurprisingly fixes some corner case
bugs):

```
val partition_valid : Var.Set.t -> t -> t * Var.Set.t * t
(** Partition ∃xs. σ into equivalent ∃xs. τ ∧ ∃ks. ν where ks and ν
    are maximal where ∃ks. ν is universally valid, xs ⊇ ks and ks ∩
    fv(τ) = ∅. *)
```

Reviewed By: ngorogiannis

Differential Revision: D20004974

fbshipit-source-id: 5cb3b3835

											
										
										
											5 years ago
 								  val partition_valid : Var.Set.t -> t -> t * Var.Set.t * t
 								  (** Partition ∃xs. σ into equivalent ∃xs. τ ∧ ∃ks. ν where ks
 								      and ν are maximal where ∃ks. ν is universally valid, xs ⊇ ks and
 								      ks ∩ fv(τ) = ∅. *)
-												[sledge] Add Equality.solve_for_vars

Summary:
```
val solve_for_vars : Var.Set.t list -> t -> Subst.t
(** [solve_for_vars \[v₁;…\] r] is a solution substitution that is
    entailed by [r] and consists of oriented equalities [x ↦ u] such that
    [fv x ⊈ vᵢ ⊇ fv u] where [i] is minimal such that [vᵢ]
    distinguishes [fv x] and [fv u], if one exists. *)
```

To be used for existential witnessing and quantifier elimination.

Reviewed By: ngorogiannis

Differential Revision: D19282636

fbshipit-source-id: c5b006cea

											
										
										
											5 years ago
+								end
-												[sledge] Eliminate redundant existential quantifiers

Summary:
This diff changes `Sh.simplify` from a logically-weakening syntactic
simplification to an equivalence-preserving rewrite. The
implementation is based on `Equality.solve_for_vars` which is also
used by `Solver` to witness existential variables.

Reviewed By: jvillard

Differential Revision: D20120274

fbshipit-source-id: 5e11659ea

											
										
										
											5 years ago
+								val apply_subst : Var.Set.t -> Subst.t -> t -> Var.Set.t * t
 								(** Relation induced by applying a substitution to a set of equations
 								    generating the argument relation. *)
-												[sledge] Add Equality.solve_for_vars

Summary:
```
val solve_for_vars : Var.Set.t list -> t -> Subst.t
(** [solve_for_vars \[v₁;…\] r] is a solution substitution that is
    entailed by [r] and consists of oriented equalities [x ↦ u] such that
    [fv x ⊈ vᵢ ⊇ fv u] where [i] is minimal such that [vᵢ]
    distinguishes [fv x] and [fv u], if one exists. *)
```

To be used for existential witnessing and quantifier elimination.

Reviewed By: ngorogiannis

Differential Revision: D19282636

fbshipit-source-id: c5b006cea

											
										
										
											5 years ago
+								val solve_for_vars : Var.Set.t list -> t -> Subst.t
-												[sledge] Strengthen quantifier witnessing

Summary:
Strengthen existential quantifier witnessing to enable witnessing an
existential with a term containing another existential if no universal
witness is available. Additionally, strengthen existential witnessing
to enable terms of interpreted theories to witness existential
variables.

Also strengthen and simplify the representation invariant checking for
existential witnessing code.

Reviewed By: jvillard

Differential Revision: D20120271

fbshipit-source-id: 4c44fe9ef

											
										
										
											5 years ago
+								(** [solve_for_vars vss r] is a solution substitution that is entailed by
 								    [r] and consists of oriented equalities [x ↦ e] that map terms [x]
 								    with free variables contained in (the union of) a prefix [uss] of [vss]
 								    to terms [e] with free variables contained in as short a prefix of [uss]
 								    as possible. *)