[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 · 442c8e92f4
parent 13c06e4dd3
commit 442c8e92f4
37 changed files with 2402 additions and 648 deletions
--- a/sledge/src/control.ml
+++ b/sledge/src/control.ml
@ -13,7 +13,7 @@ type exec_opts =
  { bound: int
  ; skip_throw: bool
  ; function_summaries: bool
-  ; globals: [`Per_function of Var.Set.t Var.Map.t | `Declared of Var.Set.t]
+  ; globals: [`Per_function of Reg.Set.t Reg.Map.t | `Declared of Reg.Set.t]
  }
 module Make (Dom : Domain_sig.Dom) = struct
@ -31,15 +31,15 @@ module Make (Dom : Domain_sig.Dom) = struct
    val pop_throw :
         t
      -> init:'a
-      -> unwind:(Var.t list -> Var.Set.t -> Dom.from_call -> 'a -> 'a)
+      -> unwind:(Reg.t list -> Reg.Set.t -> Dom.from_call -> 'a -> 'a)
      -> (Dom.from_call * Llair.jump * t * 'a) option
  end = struct
    type t =
      | Return of
          { recursive: bool  (** return from a possibly-recursive call *)
          ; dst: Llair.Jump.t
-          ; params: Var.t list
+          ; params: Reg.t list
-          ; locals: Var.Set.t
+          ; locals: Reg.Set.t
          ; from_call: Dom.from_call
          ; stk: t }
      | Throw of Llair.Jump.t * t
@ -248,9 +248,9 @@ module Make (Dom : Domain_sig.Dom) = struct
      | None -> [%Trace.info "queue empty"] ; ()
  end
-  let used_globals : exec_opts -> Var.var -> Var.Set.t =
+  let used_globals : exec_opts -> Reg.reg -> Reg.Set.t =
   fun opts fn ->
-    [%Trace.call fun {pf} -> pf "%a" Var.pp fn]
+    [%Trace.call fun {pf} -> pf "%a" Reg.pp fn]
    ;
    ( match opts.globals with
    | `Declared set -> set
@ -261,21 +261,21 @@ module Make (Dom : Domain_sig.Dom) = struct
          fail
            "main analysis reached function %a that was not reached by \
             used-globals pre-analysis "
-            Var.pp fn () ) )
+            Reg.pp fn () ) )
    |>
-    [%Trace.retn fun {pf} r -> pf "%a" Var.Set.pp r]
+    [%Trace.retn fun {pf} r -> pf "%a" Reg.Set.pp r]
  let exec_jump stk state block Llair.{dst; retreating} =
    Work.add ~prev:block ~retreating stk state dst
-  let summary_table = Hashtbl.create (module Var)
+  let summary_table = Hashtbl.create (module Reg)
  let exec_call opts stk state block call globals =
    let Llair.{callee; args; areturn; return; recursive} = call in
    let Llair.{name; params; freturn; locals; entry} = callee in
    [%Trace.call fun {pf} ->
-      pf "%a from %a with state %a" Var.pp name.var Var.pp
+      pf "%a from %a with state %a" Reg.pp name.reg Reg.pp
-        return.dst.parent.name.var Dom.pp state]
+        return.dst.parent.name.reg Dom.pp state]
    ;
    let dnf_states =
      if opts.function_summaries then Dom.dnf state else [state]
@ -290,7 +290,7 @@ module Make (Dom : Domain_sig.Dom) = struct
          else
            let maybe_summary_post =
              let state = fst (domain_call ~summaries:false state) in
-              Hashtbl.find summary_table name.var
+              Hashtbl.find summary_table name.reg
              >>= List.find_map ~f:(Dom.apply_summary state)
            in
            [%Trace.info
@ -320,23 +320,23 @@ module Make (Dom : Domain_sig.Dom) = struct
    [%Trace.printf
      "@[<v>%t@]" (fun fs ->
          Hashtbl.iteri summary_table ~f:(fun ~key ~data ->
-              Format.fprintf fs "@[<v>%a:@ @[%a@]@]@ " Var.pp key
+              Format.fprintf fs "@[<v>%a:@ @[%a@]@]@ " Reg.pp key
                (List.pp "@," Dom.pp_summary)
                data ) )]
  let exec_return ~opts stk pre_state (block : Llair.block) exp =
    let Llair.{name; params; freturn; locals} = block.parent in
    [%Trace.call fun {pf} ->
-      pf "from %a with pre_state %a" Var.pp name.var Dom.pp pre_state]
+      pf "from %a with pre_state %a" Reg.pp name.reg Dom.pp pre_state]
    ;
    let summarize post_state =
      if opts.function_summaries then (
-        let globals = used_globals opts name.var in
+        let globals = used_globals opts name.reg in
        let function_summary, post_state =
          Dom.create_summary ~locals post_state
-            ~formals:(Set.union (Var.Set.of_list params) globals)
+            ~formals:(Set.union (Reg.Set.of_list params) globals)
        in
-        Hashtbl.add_multi summary_table ~key:name.var ~data:function_summary ;
+        Hashtbl.add_multi summary_table ~key:name.reg ~data:function_summary ;
        pp_st () ;
        post_state )
      else post_state
@ -359,7 +359,7 @@ module Make (Dom : Domain_sig.Dom) = struct
          opts.function_summaries
          && List.exists
               (Config.find_list "entry-points")
-               ~f:(String.equal (Var.name name.var))
+               ~f:(String.equal (Reg.name name.reg))
        then summarize exit_state |> (ignore : Dom.t -> unit) ;
        Work.skip )
    |>
@ -367,7 +367,7 @@ module Make (Dom : Domain_sig.Dom) = struct
  let exec_throw stk pre_state (block : Llair.block) exc =
    let func = block.parent in
-    [%Trace.call fun {pf} -> pf "from %a" Var.pp func.name.var]
+    [%Trace.call fun {pf} -> pf "from %a" Reg.pp func.name.reg]
    ;
    let unwind params scope from_call state =
      Dom.retn params (Some func.fthrow) from_call
@ -390,7 +390,7 @@ module Make (Dom : Domain_sig.Dom) = struct
         Stack.t
      -> Dom.t
      -> Llair.block
-      -> Var.t option
+      -> Reg.t option
      -> Llair.jump
      -> Work.x =
   fun stk state block areturn return ->
@ -423,7 +423,7 @@ module Make (Dom : Domain_sig.Dom) = struct
              Dom.exec_assume state
                (Exp.eq ptr
                   (Exp.label
-                      ~parent:(Var.name jump.dst.parent.name.var)
+                      ~parent:(Reg.name jump.dst.parent.name.reg)
                      ~name:jump.dst.lbl))
            with
            | Some state -> exec_jump stk state block jump |> Work.seq x
@ -439,7 +439,7 @@ module Make (Dom : Domain_sig.Dom) = struct
            List.fold callees ~init:Work.skip ~f:(fun x callee ->
                ( match
                    Dom.exec_intrinsic ~skip_throw:opts.skip_throw state
-                      areturn callee.name.var args
+                      areturn callee.name.reg args
                  with
                | Some (Error ()) ->
                    Report.invalid_access_term
@ -452,7 +452,7 @@ module Make (Dom : Domain_sig.Dom) = struct
                    exec_skip_func stk state block areturn return
                | None ->
                    exec_call opts stk state block {call with callee}
-                      (used_globals opts callee.name.var) )
+                      (used_globals opts callee.name.reg) )
                |> Work.seq x ) )
    | Return {exp} -> exec_return ~opts stk state block exp
    | Throw {exc} ->
@ -481,12 +481,12 @@ module Make (Dom : Domain_sig.Dom) = struct
    let entry_points = Config.find_list "entry-points" in
    List.find_map ~f:(Llair.Func.find pgm.functions) entry_points
    |> function
-    | Some {name= {var}; locals; params= []; entry} ->
+    | Some {name= {reg}; locals; params= []; entry} ->
        Some
          (Work.init
             (fst
                (Dom.call ~summaries:opts.function_summaries
-                   ~globals:(used_globals opts var) [] None [] ~locals
+                   ~globals:(used_globals opts reg) [] None [] ~locals
                   (Dom.init pgm.globals)))
             entry)
    | _ -> None
@ -501,9 +501,9 @@ module Make (Dom : Domain_sig.Dom) = struct
    |>
    [%Trace.retn fun {pf} _ -> pf ""]
-  let compute_summaries opts pgm : Dom.summary list Var.Map.t =
+  let compute_summaries opts pgm : Dom.summary list Reg.Map.t =
    assert opts.function_summaries ;
    exec_pgm opts pgm ;
-    Hashtbl.fold summary_table ~init:Var.Map.empty ~f:(fun ~key ~data map ->
+    Hashtbl.fold summary_table ~init:Reg.Map.empty ~f:(fun ~key ~data map ->
        match data with [] -> map | _ -> Map.set map ~key ~data )
 end
--- a/sledge/src/control.mli
+++ b/sledge/src/control.mli
@ -11,11 +11,11 @@ type exec_opts =
  { bound: int  (** Loop/recursion unrolling bound *)
  ; skip_throw: bool  (** Treat throw as unreachable *)
  ; function_summaries: bool  (** Use function summarisation *)
-  ; globals: [`Per_function of Var.Set.t Var.Map.t | `Declared of Var.Set.t]
+  ; globals: [`Per_function of Reg.Set.t Reg.Map.t | `Declared of Reg.Set.t]
        (** Either a per-function used-globals map or a program-wide set *)
  }
 module Make (Dom : Domain_sig.Dom) : sig
  val exec_pgm : exec_opts -> Llair.t -> unit
-  val compute_summaries : exec_opts -> Llair.t -> Dom.summary list Var.Map.t
+  val compute_summaries : exec_opts -> Llair.t -> Dom.summary list Reg.Map.t
 end
--- a/sledge/src/domain/domain_sig.ml
+++ b/sledge/src/domain/domain_sig.ml
@ -15,15 +15,15 @@ module type Dom = sig
  val join : t -> t -> t option
  val is_false : t -> bool
  val exec_assume : t -> Exp.t -> t option
-  val exec_kill : t -> Var.t -> t
+  val exec_kill : t -> Reg.t -> t
-  val exec_move : t -> Var.t -> Exp.t -> t
+  val exec_move : t -> Reg.t -> Exp.t -> t
  val exec_inst : t -> Llair.inst -> (t, unit) result
  val exec_intrinsic :
       skip_throw:bool
    -> t
-    -> Var.t option
+    -> Reg.t option
-    -> Var.t
+    -> Reg.t
    -> Exp.t list
    -> (t, unit) result option
@ -31,17 +31,17 @@ module type Dom = sig
  val call :
       summaries:bool
-    -> globals:Var.Set.t
+    -> globals:Reg.Set.t
    -> Exp.t list
-    -> Var.t option
+    -> Reg.t option
-    -> Var.t list
+    -> Reg.t list
-    -> locals:Var.Set.t
+    -> locals:Reg.Set.t
    -> t
    -> t * from_call
  val recursion_beyond_bound : [`skip | `prune]
-  val post : Var.Set.t -> from_call -> t -> t
+  val post : Reg.Set.t -> from_call -> t -> t
-  val retn : Var.t list -> Var.t option -> from_call -> t -> t
+  val retn : Reg.t list -> Reg.t option -> from_call -> t -> t
  val dnf : t -> t list
  val resolve_callee :
@ -52,7 +52,7 @@ module type Dom = sig
  val pp_summary : summary pp
  val create_summary :
-    locals:Var.Set.t -> formals:Var.Set.t -> t -> summary * t
+    locals:Reg.Set.t -> formals:Reg.Set.t -> t -> summary * t
  val apply_summary : t -> summary -> t option
 end
--- a/sledge/src/domain/relation.ml
+++ b/sledge/src/domain/relation.ml
@ -12,8 +12,8 @@ module type State_domain_sig = sig
  include Domain_sig.Dom
  val create_summary :
-       locals:Var.Set.t
+       locals:Reg.Set.t
-    -> formals:Var.Set.t
+    -> formals:Reg.Set.t
    -> entry:t
    -> current:t
    -> summary * t
@ -77,8 +77,8 @@ module Make (State_domain : State_domain_sig) = struct
      pf
        "@[<v>@[actuals: (@[%a@])@ formals: (@[%a@])@]@ locals: {@[%a@]}@ \
         globals: {@[%a@]}@ current: %a@]"
-        (List.pp ",@ " Exp.pp) (List.rev actuals) (List.pp ",@ " Var.pp)
+        (List.pp ",@ " Exp.pp) (List.rev actuals) (List.pp ",@ " Reg.pp)
-        (List.rev formals) Var.Set.pp locals Var.Set.pp globals
+        (List.rev formals) Reg.Set.pp locals Reg.Set.pp globals
        State_domain.pp current]
    ;
    let caller_current, state_from_call =
@ -91,7 +91,7 @@ module Make (State_domain : State_domain_sig) = struct
    [%Trace.retn fun {pf} (reln, _) -> pf "@,%a" pp reln]
  let post locals {state_from_call; caller_entry} (_, current) =
-    [%Trace.call fun {pf} -> pf "locals: %a" Var.Set.pp locals]
+    [%Trace.call fun {pf} -> pf "locals: %a" Reg.Set.pp locals]
    ;
    (caller_entry, State_domain.post locals state_from_call current)
    |>
--- a/sledge/src/domain/relation.mli
+++ b/sledge/src/domain/relation.mli
@ -12,8 +12,8 @@ module type State_domain_sig = sig
  include Domain_sig.Dom
  val create_summary :
-       locals:Var.Set.t
+       locals:Reg.Set.t
-    -> formals:Var.Set.t
+    -> formals:Reg.Set.t
    -> entry:t
    -> current:t
    -> summary * t
--- a/sledge/src/domain/unit.ml
+++ b/sledge/src/domain/unit.ml
@ -29,8 +29,8 @@ let retn _ _ _ _ = ()
 let dnf () = [()]
 let resolve_callee lookup ptr _ =
-  match Var.of_exp ptr with
+  match Reg.of_exp ptr with
-  | Some callee -> (lookup (Var.name callee), ())
+  | Some callee -> (lookup (Reg.name callee), ())
  | None -> ([], ())
 type summary = unit
--- a/sledge/src/domain/used_globals.ml
+++ b/sledge/src/domain/used_globals.ml
@ -7,11 +7,11 @@
 (** Used-globals abstract domain *)
-type t = Var.Set.t [@@deriving equal, sexp_of]
+type t = Reg.Set.t [@@deriving equal, sexp_of]
-let pp = Set.pp Var.pp
+let pp = Set.pp Reg.pp
 let report_fmt_thunk = Fn.flip pp
-let empty = Var.Set.empty
+let empty = Reg.Set.empty
 let init globals =
  [%Trace.info
@ -24,10 +24,10 @@ let is_false _ = false
 let post _ _ state = state
 let retn _ _ from_call post = Set.union from_call post
 let dnf t = [t]
-let add_if_global gs v = if Var.global v then Set.add gs v else gs
+let add_if_global gs v = if Reg.global v then Set.add gs v else gs
 let used_globals ?(init = empty) exp =
-  Exp.fold_vars exp ~init ~f:add_if_global
+  Exp.fold_regs exp ~init ~f:add_if_global
 let exec_assume st exp = Some (used_globals ~init:st exp)
 let exec_kill st _ = st
@ -44,7 +44,7 @@ let exec_inst st inst =
    Result.iter ~f:(fun uses -> pf "post:{%a}" pp uses)]
 let exec_intrinsic ~skip_throw:_ st _ intrinsic actuals =
-  let name = Var.name intrinsic in
+  let name = Reg.name intrinsic in
  if
    List.exists
      [ "malloc"; "aligned_alloc"; "calloc"; "posix_memalign"; "realloc"
@ -66,11 +66,11 @@ let call ~summaries:_ ~globals:_ actuals _ _ ~locals:_ st =
 let resolve_callee lookup ptr st =
  let st = used_globals ~init:st ptr in
-  match Var.of_exp ptr with
+  match Reg.of_exp ptr with
-  | Some callee -> (lookup (Var.name callee), st)
+  | Some callee -> (lookup (Reg.name callee), st)
  | None -> ([], st)
-(* A function summary is the set of global variables accessed by that
+(* A function summary is the set of global registers accessed by that
   function and its transitive callees *)
 type summary = t
--- a/sledge/src/domain/used_globals.mli
+++ b/sledge/src/domain/used_globals.mli
@ -7,4 +7,4 @@
 (** Used-globals abstract domain *)
-include Domain_sig.Dom with type summary = Var.Set.t
+include Domain_sig.Dom with type summary = Reg.Set.t
--- a/sledge/src/llair/exp.ml
+++ b/sledge/src/llair/exp.ml
@ -58,7 +58,7 @@ module rec T : sig
    | Memory of {siz: t; arr: t}
    | Concat of {args: t vector}
    (* nullary *)
-    | Var of {id: int; name: string; global: bool}
+    | Reg of {id: int; name: string; global: bool}
    | Nondet of {msg: string}
    | Label of {parent: string; name: string}
    (* curried application *)
@ -123,7 +123,7 @@ and T0 : sig
    | Splat of {byt: t; siz: t}
    | Memory of {siz: t; arr: t}
    | Concat of {args: t vector}
-    | Var of {id: int; name: string; global: bool}
+    | Reg of {id: int; name: string; global: bool}
    | Nondet of {msg: string}
    | Label of {parent: string; name: string}
    | App of {op: t; arg: t}
@ -167,7 +167,7 @@ end = struct
    | Splat of {byt: t; siz: t}
    | Memory of {siz: t; arr: t}
    | Concat of {args: t vector}
-    | Var of {id: int; name: string; global: bool}
+    | Reg of {id: int; name: string; global: bool}
    | Nondet of {msg: string}
    | Label of {parent: string; name: string}
    | App of {op: t; arg: t}
@ -236,10 +236,10 @@ let uncurry =
  uncurry_ []
 let rec pp ?is_x fs exp =
-  let get_var_style var =
+  let get_reg_style reg =
    match is_x with
    | None -> `None
-    | Some is_x -> if not (is_x var) then `Bold else `Cyan
+    | Some is_x -> if not (is_x reg) then `Bold else `Cyan
  in
  let pp_ pp fs exp =
    let pf fmt =
@ -247,12 +247,12 @@ let rec pp ?is_x fs exp =
      Format.kfprintf (fun fs -> Format.pp_close_box fs ()) fs fmt
    in
    match exp with
-    | Var {name; id= 0; global= true} as var ->
+    | Reg {name; id= 0; global= true} as reg ->
-        Trace.pp_styled (get_var_style var) "%@%s" fs name
+        Trace.pp_styled (get_reg_style reg) "%@%s" fs name
-    | Var {name; id= 0; global= false} as var ->
+    | Reg {name; id= 0; global= false} as reg ->
-        Trace.pp_styled (get_var_style var) "%%%s" fs name
+        Trace.pp_styled (get_reg_style reg) "%%%s" fs name
-    | Var {name; id; _} as var ->
+    | Reg {name; id; _} as reg ->
-        Trace.pp_styled (get_var_style var) "%%%s_%d" fs name id
+        Trace.pp_styled (get_reg_style reg) "%%%s_%d" fs name id
    | Nondet {msg} -> pf "nondet \"%s\"" msg
    | Label {name} -> pf "%s" name
    | Integer {data; typ= Pointer _} when Z.equal Z.zero data -> pf "null"
@ -455,7 +455,7 @@ let invariant ?(partial = false) e =
        assert_arity 0 ;
        assert (Z.numbits data <= bits) )
  | Integer _ -> assert false
-  | Var {id; global; _} ->
+  | Reg {id; global; _} ->
      assert_arity 0 ;
      assert ((not global) || id = 0)
  | Nondet _ | Label _ | Float _ -> assert_arity 0
@ -500,13 +500,13 @@ let bits_of_int exp =
    | None -> violates invariant exp )
  | _ -> fail "bits_of_int" ()
-(** Variables are the expressions constructed by [Var] *)
+(** Registers are the expressions constructed by [Reg] *)
-module Var = struct
+module Reg = struct
  include T
  let pp = pp
-  type var = t
+  type reg = t
  module Set = struct
    include (
@ -553,7 +553,7 @@ module Var = struct
      if !@status = 0 then demangled else None
  let pp_demangled fs = function
-    | Var {name} -> (
+    | Reg {name} -> (
      match demangle name with
      | Some demangled when not (String.equal name demangled) ->
          Format.fprintf fs "“%s”" demangled
@ -562,25 +562,25 @@ module Var = struct
  let invariant x =
    Invariant.invariant [%here] x [%sexp_of: t]
-    @@ fun () -> match x with Var _ -> invariant x | _ -> assert false
+    @@ fun () -> match x with Reg _ -> invariant x | _ -> assert false
-  let id = function Var {id} -> id | x -> violates invariant x
+  let id = function Reg {id} -> id | x -> violates invariant x
-  let name = function Var {name} -> name | x -> violates invariant x
+  let name = function Reg {name} -> name | x -> violates invariant x
-  let global = function Var {global} -> global | x -> violates invariant x
+  let global = function Reg {global} -> global | x -> violates invariant x
  let of_exp = function
-    | Var _ as v -> Some (v |> check invariant)
+    | Reg _ as x -> Some (x |> check invariant)
    | _ -> None
  let program ?global name =
-    Var {id= 0; name; global= Option.is_some global} |> check invariant
+    Reg {id= 0; name; global= Option.is_some global} |> check invariant
  let fresh name ~(wrt : Set.t) =
    let max = match Set.max_elt wrt with None -> 0 | Some max -> id max in
-    let x' = Var {name; id= max + 1; global= false} in
+    let x' = Reg {name; id= max + 1; global= false} in
    (x', Set.add wrt x')
-  (** Variable renaming substitutions *)
+  (** Register renaming substitutions *)
  module Subst = struct
    type t = T.t Map.M(T).t [@@deriving compare, equal, sexp]
@ -675,15 +675,15 @@ let fold_exps e ~init ~f =
 let iter_exps e ~f = fold_exps e ~init:() ~f:(fun () e -> f e)
-let fold_vars e ~init ~f =
+let fold_regs e ~init ~f =
  fold_exps e ~init ~f:(fun z -> function
-    | Var _ as v -> f z (v :> Var.t) | _ -> z )
+    | Reg _ as x -> f z (x :> Reg.t) | _ -> z )
-let fv e = fold_vars e ~f:Set.add ~init:Var.Set.empty
+let fv e = fold_regs e ~f:Set.add ~init:Reg.Set.empty
 (** Construct *)
-let var x = x
+let reg x = x
 let nondet msg = Nondet {msg} |> check invariant
 let label ~parent ~name = Label {parent; name} |> check invariant
 let integer data typ = Integer {data; typ} |> check invariant
@ -1331,7 +1331,7 @@ let map e ~f =
 let rename sub e =
  let rec rename_ sub e =
    match e with
-    | Var _ -> Var.Subst.apply sub e
+    | Reg _ -> Reg.Subst.apply sub e
    | _ -> map ~f:(rename_ sub) e
  in
  rename_ sub e |> check (invariant ~partial:true)
@ -1349,7 +1349,7 @@ let is_false = function
 let rec is_constant e =
  let is_constant_bin x y = is_constant x && is_constant y in
  match e with
-  | Var _ | Nondet _ -> false
+  | Reg _ | Nondet _ -> false
  | App {op= x; arg= y} | Splat {byt= x; siz= y} | Memory {siz= x; arr= y}
    ->
      is_constant_bin x y
@ -1413,4 +1413,4 @@ let solve e f =
  solve_ e f empty_map
  |>
  [%Trace.retn fun {pf} ->
-    function Some s -> pf "%a" Var.Subst.pp s | None -> pf "false"]
+    function Some s -> pf "%a" Reg.Subst.pp s | None -> pf "false"]
--- a/sledge/src/llair/exp.mli
+++ b/sledge/src/llair/exp.mli
@ -27,10 +27,10 @@ and t = private
      (** Iterated concatenation of a single byte *)
  | Memory of {siz: t; arr: t}  (** Size-tagged byte-array *)
  | Concat of {args: t vector}  (** Byte-array concatenation *)
-  | Var of {id: int; name: string; global: bool}
+  | Reg of {id: int; name: string; global: bool}
      (** Local variable / virtual register *)
  | Nondet of {msg: string}
-      (** Anonymous local variable with arbitrary value, representing
+      (** Anonymous register with arbitrary value, representing
          non-deterministic approximation of value described by [msg] *)
  | Label of {parent: string; name: string}
      (** Address of named code block within parent function *)
@ -81,28 +81,28 @@ val pp_full : ?is_x:(exp -> bool) -> t pp
 val pp : t pp
 val invariant : ?partial:bool -> t -> unit
-(** Exp.Var is re-exported as Var *)
+(** Exp.Reg is re-exported as Reg *)
-module Var : sig
+module Reg : sig
  type t = private exp [@@deriving compare, equal, hash, sexp]
-  type var = t
+  type reg = t
  include Comparator.S with type t := t
  module Set : sig
-    type t = (var, comparator_witness) Set.t
+    type t = (reg, comparator_witness) Set.t
    [@@deriving compare, equal, sexp]
    val pp_full : ?is_x:(exp -> bool) -> t pp
    val pp : t pp
    val empty : t
-    val of_option : var option -> t
+    val of_option : reg option -> t
-    val of_list : var list -> t
+    val of_list : reg list -> t
    val of_vector : reg vector -> t
    val union_list : t list -> t
    val of_vector : var vector -> t
  end
  module Map : sig
-    type 'a t = (var, 'a, comparator_witness) Map.t
+    type 'a t = (reg, 'a, comparator_witness) Map.t
    [@@deriving compare, equal, sexp]
    val empty : 'a t
@ -126,7 +126,7 @@ module Var : sig
    val pp : t pp
    val empty : t
    val freshen : Set.t -> wrt:Set.t -> t
-    val extend : t -> replace:var -> with_:var -> t
+    val extend : t -> replace:reg -> with_:reg -> t
    val invert : t -> t
    val exclude : t -> Set.t -> t
    val restrict : t -> Set.t -> t
@ -140,7 +140,7 @@ end
 (** Construct *)
-val var : Var.t -> t
+val reg : Reg.t -> t
 val nondet : string -> t
 val label : parent:string -> name:string -> t
 val null : t
@ -200,18 +200,18 @@ val size_of : Typ.t -> t option
 (** Access *)
 val iter : t -> f:(t -> unit) -> unit
-val fold_vars : t -> init:'a -> f:('a -> Var.t -> 'a) -> 'a
+val fold_regs : t -> init:'a -> f:('a -> Reg.t -> 'a) -> 'a
 val fold_exps : t -> init:'a -> f:('a -> t -> 'a) -> 'a
 val fold : t -> init:'a -> f:(t -> 'a -> 'a) -> 'a
 (** Transform *)
 val map : t -> f:(t -> t) -> t
-val rename : Var.Subst.t -> t -> t
+val rename : Reg.Subst.t -> t -> t
 (** Query *)
-val fv : t -> Var.Set.t
+val fv : t -> Reg.Set.t
 val is_true : t -> bool
 val is_false : t -> bool
 val typ : t -> Typ.t option
--- a/sledge/src/llair/frontend.ml
+++ b/sledge/src/llair/frontend.ml
@ -288,9 +288,10 @@ let xlate_float : Llvm.llvalue -> Exp.t =
  let data = suffix_after_last_space (Llvm.string_of_llvalue llv) in
  Exp.float data
-let xlate_name ?global llv = Var.program ?global (find_name llv)
+let xlate_name ?global : Llvm.llvalue -> Reg.t =
 fun llv -> Reg.program ?global (find_name llv)
-let xlate_name_opt : Llvm.llvalue -> Var.t option =
+let xlate_name_opt : Llvm.llvalue -> Reg.t option =
 fun instr ->
  match Llvm.classify_type (Llvm.type_of instr) with
  | Void -> None
@ -357,11 +358,11 @@ and xlate_value ?(inline = false) : x -> Llvm.llvalue -> Exp.t =
        let fname = Llvm.value_name func in
        match xlate_intrinsic_exp fname with
        | Some intrinsic when inline || should_inline llv -> intrinsic x llv
-        | _ -> Exp.var (xlate_name llv) )
+        | _ -> Exp.reg (xlate_name llv) )
    | Instruction (Invoke | Alloca | Load | PHI | LandingPad | VAArg)
     |Argument ->
-        Exp.var (xlate_name llv)
+        Exp.reg (xlate_name llv)
-    | Function | GlobalVariable -> Exp.var (xlate_global x llv).var
+    | Function | GlobalVariable -> Exp.reg (xlate_global x llv).reg
    | GlobalAlias -> xlate_value x (Llvm.operand llv 0)
    | ConstantInt -> xlate_int x llv
    | ConstantFP -> xlate_float llv
@ -407,7 +408,7 @@ and xlate_value ?(inline = false) : x -> Llvm.llvalue -> Exp.t =
          | Select | GetElementPtr | ExtractElement | InsertElement
          | ShuffleVector | ExtractValue | InsertValue ) as opcode ) ->
        if inline || should_inline llv then xlate_opcode x llv opcode
-        else Exp.var (xlate_name llv)
+        else Exp.reg (xlate_name llv)
    | ConstantExpr -> xlate_opcode x llv (Llvm.constexpr_opcode llv)
    | GlobalIFunc -> todo "ifuncs: %a" pp_llvalue llv ()
    | Instruction (CatchPad | CleanupPad | CatchSwitch) ->
@ -630,15 +631,15 @@ type pop_thunk = Loc.t -> Llair.inst list
 let pop_stack_frame_of_function :
    Llvm.llvalue -> Llvm.llbasicblock -> pop_thunk =
 fun func entry_blk ->
-  let append_stack_vars blk vars =
+  let append_stack_regs blk regs =
    Llvm.fold_right_instrs
-      (fun instr vars ->
+      (fun instr regs ->
        match Llvm.instr_opcode instr with
-        | Alloca -> xlate_name instr :: vars
+        | Alloca -> xlate_name instr :: regs
-        | _ -> vars )
+        | _ -> regs )
-      blk vars
+      blk regs
  in
-  let entry_vars = append_stack_vars entry_blk [] in
+  let entry_regs = append_stack_regs entry_blk [] in
  Llvm.iter_blocks
    (fun blk ->
      if not (Poly.equal entry_blk blk) then
@ -652,8 +653,8 @@ let pop_stack_frame_of_function :
          blk )
    func ;
  let pop retn_loc =
-    List.map entry_vars ~f:(fun var ->
+    List.map entry_regs ~f:(fun reg ->
-        Llair.Inst.free ~ptr:(Exp.var var) ~loc:retn_loc )
+        Llair.Inst.free ~ptr:(Exp.reg reg) ~loc:retn_loc )
  in
  pop
@ -690,7 +691,7 @@ let landingpad_typs : x -> Llvm.llvalue -> Typ.t * Typ.t * Llvm.lltype =
    the PHIs of [dst] translated to a move. *)
 let xlate_jump :
       x
-    -> ?reg_exps:(Var.var * Exp.t) list
+    -> ?reg_exps:(Reg.reg * Exp.t) list
    -> Llvm.llvalue
    -> Llvm.llbasicblock
    -> Loc.t
@ -753,7 +754,7 @@ let pp_code fs (insts, term, blocks) =
 let rec xlate_func_name x llv =
  match Llvm.classify_value llv with
-  | Function -> Exp.var (xlate_name ~global:() llv)
+  | Function -> Exp.reg (xlate_name ~global:() llv)
  | ConstantExpr -> xlate_opcode x llv (Llvm.constexpr_opcode llv)
  | Argument | Instruction _ -> xlate_value x llv
  | GlobalAlias -> xlate_func_name x (Llvm.operand llv 0)
@ -1076,8 +1077,8 @@ let xlate_instr :
         passing a value for the selector which the handler code tests to
         e.g. either cleanup or rethrow. *)
      let i32, tip, cxa_exception = landingpad_typs x instr in
-      let exc = Exp.var (Var.program (find_name instr ^ ".exc")) in
+      let exc = Exp.reg (Reg.program (find_name instr ^ ".exc")) in
-      let ti = Var.program (name ^ ".ti") in
+      let ti = Reg.program (name ^ ".ti") in
      (* std::type_info* ti = ((__cxa_exception* )exc - 1)->exceptionType *)
      let load_ti =
        let typ = cxa_exception in
@ -1093,7 +1094,7 @@ let xlate_instr :
        let len = Exp.integer (Z.of_int (size_of x typ)) Typ.siz in
        Llair.Inst.load ~reg:ti ~ptr ~len ~loc
      in
-      let ti = Exp.var ti in
+      let ti = Exp.reg ti in
      let typeid = xlate_llvm_eh_typeid_for x tip ti in
      let lbl = name ^ ".unwind" in
      let param = xlate_name instr in
@ -1245,10 +1246,10 @@ let xlate_function : x -> Llvm.llvalue -> Llair.func =
  let freturn =
    match name.typ with
    | Pointer {elt= Function {return= Some _; _}} ->
-        Some (Var.program "freturn")
+        Some (Reg.program "freturn")
    | _ -> None
  in
-  let fthrow = Var.program "fthrow" in
+  let fthrow = Reg.program "fthrow" in
  ( match Llvm.block_begin llf with
  | Before entry_blk ->
      let pop = pop_stack_frame_of_function llf entry_blk in
--- a/sledge/src/llair/global.ml
+++ b/sledge/src/llair/global.ml
@ -7,27 +7,27 @@
 (** Global variables *)
-type t = {var: Var.t; init: (Exp.t * int) option; typ: Typ.t; loc: Loc.t}
+type t = {reg: Reg.t; init: (Exp.t * int) option; typ: Typ.t; loc: Loc.t}
 [@@deriving compare, equal, hash, sexp]
-let pp fs {var} =
+let pp fs {reg} =
-  let name = Var.name var in
+  let name = Reg.name reg in
  let pf pp =
    Format.pp_open_box fs 2 ;
    Format.kfprintf (fun fs -> Format.pp_close_box fs ()) fs pp
  in
-  pf "@%s%a" name Var.pp_demangled var
+  pf "@%s%a" name Reg.pp_demangled reg
-let pp_defn fs {var; init; typ; loc} =
+let pp_defn fs {reg; init; typ; loc} =
-  Format.fprintf fs "@[<2>%a %a%a%a@]" Typ.pp typ Var.pp var Loc.pp loc
+  Format.fprintf fs "@[<2>%a %a%a%a@]" Typ.pp typ Reg.pp reg Loc.pp loc
    (Option.pp "@ = @[%a@]" (fun fs (init, _) -> Exp.pp fs init))
    init
 let invariant g =
  Invariant.invariant [%here] g [%sexp_of: t]
  @@ fun () ->
-  let {var; typ} = g in
+  let {reg; typ} = g in
  assert (Typ.is_sized typ) ;
-  assert (Var.global var)
+  assert (Reg.global reg)
-let mk ?init var typ loc = {var; init; typ; loc} |> check invariant
+let mk ?init reg typ loc = {reg; init; typ; loc} |> check invariant
--- a/sledge/src/llair/global.mli
+++ b/sledge/src/llair/global.mli
@ -8,7 +8,7 @@
 (** Global variables *)
 type t = private
-  {var: Var.t; init: (Exp.t * int) option; typ: Typ.t; loc: Loc.t}
+  {reg: Reg.t; init: (Exp.t * int) option; typ: Typ.t; loc: Loc.t}
 [@@deriving compare, equal, hash, sexp]
 val pp : t pp
@ -16,4 +16,4 @@ val pp_defn : t pp
 include Invariant.S with type t := t
-val mk : ?init:Exp.t * int -> Var.t -> Typ.t -> Loc.t -> t
+val mk : ?init:Exp.t * int -> Reg.t -> Typ.t -> Loc.t -> t
--- a/sledge/src/llair/llair.ml
+++ b/sledge/src/llair/llair.ml
@ -10,15 +10,15 @@
 [@@@warning "+9"]
 type inst =
-  | Move of {reg_exps: (Var.t * Exp.t) vector; loc: Loc.t}
+  | Move of {reg_exps: (Reg.t * Exp.t) vector; loc: Loc.t}
-  | Load of {reg: Var.t; ptr: Exp.t; len: Exp.t; loc: Loc.t}
+  | Load of {reg: Reg.t; ptr: Exp.t; len: Exp.t; loc: Loc.t}
  | Store of {ptr: Exp.t; exp: Exp.t; len: Exp.t; loc: Loc.t}
  | Memset of {dst: Exp.t; byt: Exp.t; len: Exp.t; loc: Loc.t}
  | Memcpy of {dst: Exp.t; src: Exp.t; len: Exp.t; loc: Loc.t}
  | Memmov of {dst: Exp.t; src: Exp.t; len: Exp.t; loc: Loc.t}
-  | Alloc of {reg: Var.t; num: Exp.t; len: Exp.t; loc: Loc.t}
+  | Alloc of {reg: Reg.t; num: Exp.t; len: Exp.t; loc: Loc.t}
  | Free of {ptr: Exp.t; loc: Loc.t}
-  | Nondet of {reg: Var.t option; msg: string; loc: Loc.t}
+  | Nondet of {reg: Reg.t option; msg: string; loc: Loc.t}
  | Abort of {loc: Loc.t}
 [@@deriving sexp]
@ -31,7 +31,7 @@ and 'a call =
  { callee: 'a
  ; typ: Typ.t
  ; args: Exp.t list
-  ; areturn: Var.t option
+  ; areturn: Reg.t option
  ; return: jump
  ; throw: jump option
  ; mutable recursive: bool
@ -57,10 +57,10 @@ and cfg = block vector
 (* [entry] is not part of [cfg] since it cannot be jumped to, only called. *)
 and func =
  { name: Global.t
-  ; params: Var.t list
+  ; params: Reg.t list
-  ; freturn: Var.t option
+  ; freturn: Reg.t option
-  ; fthrow: Var.t
+  ; fthrow: Reg.t
-  ; locals: Var.Set.t
+  ; locals: Reg.Set.t
  ; entry: block
  ; cfg: cfg }
@ -87,7 +87,7 @@ let sexp_of_term = function
          { callee: Exp.t
          ; typ: Typ.t
          ; args: Exp.t list
-          ; areturn: Var.t option
+          ; areturn: Reg.t option
          ; return: jump
          ; throw: jump option
          ; recursive: bool
@ -102,7 +102,7 @@ let sexp_of_block {lbl; cmnd; term; parent; sort_index} =
    { lbl: label
    ; cmnd: cmnd
    ; term: term
-    ; parent: Var.t = parent.name.var
+    ; parent: Reg.t = parent.name.reg
    ; sort_index: int }]
 let sexp_of_cfg v = [%sexp_of: block vector] v
@ -110,10 +110,10 @@ let sexp_of_cfg v = [%sexp_of: block vector] v
 let sexp_of_func {name; params; freturn; fthrow; locals; entry; cfg} =
  [%sexp
    { name: Global.t
-    ; params: Var.t list
+    ; params: Reg.t list
-    ; freturn: Var.t option
+    ; freturn: Reg.t option
-    ; fthrow: Var.t
+    ; fthrow: Reg.t
-    ; locals: Var.Set.t
+    ; locals: Reg.Set.t
    ; entry: block
    ; cfg: cfg }]
@ -131,10 +131,10 @@ let pp_inst fs inst =
  match inst with
  | Move {reg_exps; loc} ->
      let regs, exps = Vector.unzip reg_exps in
-      pf "@[<2>@[%a@]@ := @[%a@];@]\t%a" (Vector.pp ",@ " Var.pp) regs
+      pf "@[<2>@[%a@]@ := @[%a@];@]\t%a" (Vector.pp ",@ " Reg.pp) regs
        (Vector.pp ",@ " Exp.pp) exps Loc.pp loc
  | Load {reg; ptr; len; loc} ->
-      pf "@[<2>%a@ := load %a@ %a;@]\t%a" Var.pp reg Exp.pp len Exp.pp ptr
+      pf "@[<2>%a@ := load %a@ %a;@]\t%a" Reg.pp reg Exp.pp len Exp.pp ptr
        Loc.pp loc
  | Store {ptr; exp; len; loc} ->
      pf "@[<2>store %a@ %a@ %a;@]\t%a" Exp.pp len Exp.pp ptr Exp.pp exp
@ -149,19 +149,19 @@ let pp_inst fs inst =
      pf "@[<2>memmov %a %a %a;@]\t%a" Exp.pp len Exp.pp dst Exp.pp src
        Loc.pp loc
  | Alloc {reg; num; len; loc} ->
-      pf "@[<2>%a@ := alloc [%a x %a];@]\t%a" Var.pp reg Exp.pp num Exp.pp
+      pf "@[<2>%a@ := alloc [%a x %a];@]\t%a" Reg.pp reg Exp.pp num Exp.pp
        len Loc.pp loc
  | Free {ptr; loc} -> pf "@[<2>free %a;@]\t%a" Exp.pp ptr Loc.pp loc
  | Nondet {reg; msg; loc} ->
      pf "@[<2>%anondet \"%s\";@]\t%a"
-        (Option.pp "%a := " Var.pp)
+        (Option.pp "%a := " Reg.pp)
        reg msg Loc.pp loc
  | Abort {loc} -> pf "@[<2>abort;@]\t%a" Loc.pp loc
 let pp_args pp_arg fs args =
  Format.fprintf fs "@ (@[%a@])" (List.pp ",@ " pp_arg) (List.rev args)
-let pp_param fs var = Var.pp fs var
+let pp_param fs reg = Reg.pp fs reg
 let pp_jump fs {dst; retreating} =
  Format.fprintf fs "@[<2>%s%%%s@]"
@ -190,7 +190,7 @@ let pp_term fs term =
        tbl Loc.pp loc
  | Call {callee; args; areturn; return; throw; recursive; loc; _} ->
      pf "@[<2>@[<7>%acall @[<2>%s%a%a@]@]@ @[returnto %a%a;@]@]\t%a"
-        (Option.pp "%a := " Var.pp)
+        (Option.pp "%a := " Reg.pp)
        areturn
        (if recursive then "↑" else "")
        Exp.pp callee (pp_args Exp.pp) args pp_jump return
@ -219,13 +219,13 @@ let rec dummy_block =
  ; sort_index= 0 }
 and dummy_func =
-  let dummy_var = Var.program ~global:() "dummy" in
+  let dummy_reg = Reg.program ~global:() "dummy" in
  let dummy_ptr_typ = Typ.pointer ~elt:(Typ.opaque ~name:"dummy") in
-  { name= Global.mk dummy_var dummy_ptr_typ Loc.none
+  { name= Global.mk dummy_reg dummy_ptr_typ Loc.none
  ; params= []
  ; freturn= None
-  ; fthrow= dummy_var
+  ; fthrow= dummy_reg
-  ; locals= Var.Set.empty
+  ; locals= Reg.Set.empty
  ; entry= dummy_block
  ; cfg= Vector.empty }
@ -270,7 +270,7 @@ module Inst = struct
     |Abort _ ->
        vs
-  let locals inst = union_locals inst Var.Set.empty
+  let locals inst = union_locals inst Reg.Set.empty
  let fold_exps inst ~init ~f =
    match inst with
@ -408,7 +408,7 @@ module Func = struct
      ( match name.typ with
      | Pointer {elt= Function {return; _}} -> return
      | _ -> None )
-      (Option.pp " %a := " Var.pp)
+      (Option.pp " %a := " Reg.pp)
      freturn Global.pp name (pp_args pp_param) params
      (fun fs ->
        if is_undefined func then Format.fprintf fs " #%i@]" sort_index
@ -451,7 +451,7 @@ module Func = struct
      let locals_block locals block =
        locals_cmnd (Term.union_locals block.term locals) block.cmnd
      in
-      let init = locals_block Var.Set.empty entry in
+      let init = locals_block Reg.Set.empty entry in
      Vector.fold ~f:locals_block cfg ~init
    in
    let func = {name; params; freturn; fthrow; locals; entry; cfg} in
@ -509,17 +509,17 @@ module Block_label = struct
 end
 module BlockQ = Hash_queue.Make (Block_label)
-module FuncQ = Hash_queue.Make (Var)
+module FuncQ = Hash_queue.Make (Reg)
 let set_derived_metadata functions =
  let compute_roots functions =
    let roots = FuncQ.create () in
    Map.iter functions ~f:(fun func ->
-        FuncQ.enqueue_back_exn roots func.name.var func ) ;
+        FuncQ.enqueue_back_exn roots func.name.reg func ) ;
    Map.iter functions ~f:(fun func ->
        Func.fold_term func ~init:() ~f:(fun () -> function
          | Call {callee; _} -> (
-            match Var.of_exp callee with
+            match Reg.of_exp callee with
            | Some callee ->
                FuncQ.remove roots callee |> (ignore : [> ] -> unit)
            | None -> () )
@ -543,7 +543,7 @@ let set_derived_metadata functions =
        | Iswitch {tbl; _} -> Vector.iter tbl ~f:jump
        | Call ({callee; return; throw; _} as call) ->
            ( match
-                Var.of_exp callee >>| Var.name >>= Func.find functions
+                Reg.of_exp callee >>| Reg.name >>= Func.find functions
              with
            | Some func ->
                if Set.mem ancestors func.entry then call.recursive <- true
@ -575,7 +575,7 @@ let set_derived_metadata functions =
    List.fold functions
      ~init:(Map.empty (module String))
      ~f:(fun m func ->
-        Map.add_exn m ~key:(Var.name func.name.var) ~data:func )
+        Map.add_exn m ~key:(Reg.name func.name.reg) ~data:func )
  in
  let roots = compute_roots functions in
  let tips_to_roots = topsort functions roots in
@ -589,7 +589,7 @@ let invariant pgm =
  assert (
    not
      (Vector.contains_dup pgm.globals ~compare:(fun g1 g2 ->
-           Var.compare g1.Global.var g2.Global.var )) )
+           Reg.compare g1.Global.reg g2.Global.reg )) )
 let mk ~globals ~functions =
  { globals= Vector.of_list_rev globals
--- a/sledge/src/llair/llair.mli
+++ b/sledge/src/llair/llair.mli
@ -10,10 +10,10 @@
 (** Instructions for memory manipulation or other non-control effects. *)
 type inst = private
-  | Move of {reg_exps: (Var.t * Exp.t) vector; loc: Loc.t}
+  | Move of {reg_exps: (Reg.t * Exp.t) vector; loc: Loc.t}
      (** Move each value [exp] into corresponding register [reg]. All of
          the moves take effect simultaneously. *)
-  | Load of {reg: Var.t; ptr: Exp.t; len: Exp.t; loc: Loc.t}
+  | Load of {reg: Reg.t; ptr: Exp.t; len: Exp.t; loc: Loc.t}
      (** Read a [len]-byte value from the contents of memory at address
          [ptr] into [reg]. *)
  | Store of {ptr: Exp.t; exp: Exp.t; len: Exp.t; loc: Loc.t}
@ -25,12 +25,12 @@ type inst = private
          if ranges overlap. *)
  | Memmov of {dst: Exp.t; src: Exp.t; len: Exp.t; loc: Loc.t}
      (** Copy [len] bytes starting from address [src] to [dst]. *)
-  | Alloc of {reg: Var.t; num: Exp.t; len: Exp.t; loc: Loc.t}
+  | Alloc of {reg: Reg.t; num: Exp.t; len: Exp.t; loc: Loc.t}
      (** Allocate a block of memory large enough to store [num] elements of
          [len] bytes each and bind [reg] to the first address. *)
  | Free of {ptr: Exp.t; loc: Loc.t}
      (** Deallocate the previously allocated block at address [ptr]. *)
-  | Nondet of {reg: Var.t option; msg: string; loc: Loc.t}
+  | Nondet of {reg: Reg.t option; msg: string; loc: Loc.t}
      (** Bind [reg] to an arbitrary value, representing non-deterministic
          approximation of behavior described by [msg]. *)
  | Abort of {loc: Loc.t}  (** Trigger abnormal program termination *)
@ -49,7 +49,7 @@ and 'a call =
  { callee: 'a
  ; typ: Typ.t  (** Type of the callee. *)
  ; args: Exp.t list  (** Stack of arguments, first-arg-last. *)
-  ; areturn: Var.t option  (** Register to receive return value. *)
+  ; areturn: Reg.t option  (** Register to receive return value. *)
  ; return: jump  (** Return destination. *)
  ; throw: jump option  (** Handler destination. *)
  ; mutable recursive: bool
@ -89,10 +89,10 @@ and cfg
    parameters are the function parameters. *)
 and func = private
  { name: Global.t
-  ; params: Var.t list  (** Formal parameters, first-param-last stack *)
+  ; params: Reg.t list  (** Formal parameters, first-param-last stack *)
-  ; freturn: Var.t option
+  ; freturn: Reg.t option
-  ; fthrow: Var.t
+  ; fthrow: Reg.t
-  ; locals: Var.Set.t  (** Local variables *)
+  ; locals: Reg.Set.t  (** Local registers *)
  ; entry: block
  ; cfg: cfg }
@ -112,18 +112,18 @@ module Inst : sig
  type t = inst
  val pp : t pp
-  val move : reg_exps:(Var.t * Exp.t) vector -> loc:Loc.t -> inst
+  val move : reg_exps:(Reg.t * Exp.t) vector -> loc:Loc.t -> inst
-  val load : reg:Var.t -> ptr:Exp.t -> len:Exp.t -> loc:Loc.t -> inst
+  val load : reg:Reg.t -> ptr:Exp.t -> len:Exp.t -> loc:Loc.t -> inst
  val store : ptr:Exp.t -> exp:Exp.t -> len:Exp.t -> loc:Loc.t -> inst
  val memset : dst:Exp.t -> byt:Exp.t -> len:Exp.t -> loc:Loc.t -> inst
  val memcpy : dst:Exp.t -> src:Exp.t -> len:Exp.t -> loc:Loc.t -> inst
  val memmov : dst:Exp.t -> src:Exp.t -> len:Exp.t -> loc:Loc.t -> inst
-  val alloc : reg:Var.t -> num:Exp.t -> len:Exp.t -> loc:Loc.t -> inst
+  val alloc : reg:Reg.t -> num:Exp.t -> len:Exp.t -> loc:Loc.t -> inst
  val free : ptr:Exp.t -> loc:Loc.t -> inst
-  val nondet : reg:Var.t option -> msg:string -> loc:Loc.t -> inst
+  val nondet : reg:Reg.t option -> msg:string -> loc:Loc.t -> inst
  val abort : loc:Loc.t -> inst
  val loc : inst -> Loc.t
-  val locals : inst -> Var.Set.t
+  val locals : inst -> Reg.Set.t
  val fold_exps : inst -> init:'a -> f:('a -> Exp.t -> 'a) -> 'a
 end
@ -154,7 +154,7 @@ module Term : sig
       func:Exp.t
    -> typ:Typ.t
    -> args:Exp.t list
-    -> areturn:Var.t option
+    -> areturn:Reg.t option
    -> return:jump
    -> throw:jump option
    -> loc:Loc.t
@ -184,18 +184,18 @@ module Func : sig
  val mk :
       name:Global.t
-    -> params:Var.t list
+    -> params:Reg.t list
-    -> freturn:Var.t option
+    -> freturn:Reg.t option
-    -> fthrow:Var.t
+    -> fthrow:Reg.t
    -> entry:block
    -> cfg:block vector
    -> func
  val mk_undefined :
       name:Global.t
-    -> params:Var.t list
+    -> params:Reg.t list
-    -> freturn:Var.t option
+    -> freturn:Reg.t option
-    -> fthrow:Var.t
+    -> fthrow:Reg.t
    -> t
  val find : functions -> string -> func option
--- a/sledge/src/llair/reg.ml
+++ b/sledge/src/llair/reg.ml
@ -0,0 +1,10 @@
 (*
 * 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.
 *)
 (** Variables *)
 include Exp.Reg
--- a/sledge/src/llair/reg.mli
+++ b/sledge/src/llair/reg.mli
@ -0,0 +1,10 @@
 (*
 * 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.
 *)
 (** Variables *)
 include module type of Exp.Reg
--- a/sledge/src/report.ml
+++ b/sledge/src/report.ml
@ -16,8 +16,8 @@ let unknown_call call =
      (fun fs (call : Llair.Term.t) ->
        match call with
        | Call {callee} -> (
-          match Var.of_exp callee with
+          match Reg.of_exp callee with
-          | Some var -> Var.pp_demangled fs var
+          | Some reg -> Reg.pp_demangled fs reg
          | None -> Exp.pp fs callee )
        | _ -> () )
      call Llair.Term.pp call]
--- a/sledge/src/sledge.ml
+++ b/sledge/src/sledge.ml
@ -75,14 +75,14 @@ let used_globals pgm preanalyze =
        { bound= 1
        ; skip_throw= false
        ; function_summaries= true
-        ; globals= `Declared Var.Set.empty }
+        ; globals= `Declared Reg.Set.empty }
        pgm
    in
-    `Per_function (Map.map summary_table ~f:Var.Set.union_list)
+    `Per_function (Map.map summary_table ~f:Reg.Set.union_list)
  else
    `Declared
-      (Vector.fold pgm.globals ~init:Var.Set.empty ~f:(fun acc g ->
+      (Vector.fold pgm.globals ~init:Reg.Set.empty ~f:(fun acc g ->
-           Set.add acc g.var ))
+           Set.add acc g.reg ))
 let analyze =
  let%map_open bound =
--- a/sledge/src/symbheap/equality.ml
+++ b/sledge/src/symbheap/equality.ml
@ -7,11 +7,11 @@
 (** Equality over uninterpreted functions and linear rational arithmetic *)
-type 'a exp_map = 'a Map.M(Exp).t [@@deriving compare, equal, sexp]
+type 'a term_map = 'a Map.M(Term).t [@@deriving compare, equal, sexp]
-let empty_map = Map.empty (module Exp)
+let empty_map = Map.empty (module Term)
-type subst = Exp.t exp_map [@@deriving compare, equal, sexp]
+type subst = Term.t term_map [@@deriving compare, equal, sexp]
 (** see also [invariant] *)
 type t =
@ -24,7 +24,7 @@ type t =
 let classes r =
  Map.fold r.rep ~init:empty_map ~f:(fun ~key ~data cls ->
-      if Exp.equal key data then cls
+      if Term.equal key data then cls
      else Map.add_multi cls ~key:data ~data:key )
 (** Pretty-printing *)
@ -36,17 +36,17 @@ let pp fs {sat; rep} =
    in
    Format.fprintf fs "[@[<hv>%a@]]" (List.pp ";@ " pp_assoc) alist
  in
-  let pp_exp_v fs (k, v) = if not (Exp.equal k v) then Exp.pp fs v in
+  let pp_term_v fs (k, v) = if not (Term.equal k v) then Term.pp fs v in
  Format.fprintf fs "@[{@[<hv>sat= %b;@ rep= %a@]}@]" sat
-    (pp_alist Exp.pp pp_exp_v)
+    (pp_alist Term.pp pp_term_v)
    (Map.to_alist rep)
 let pp_classes ?is_x fs r =
  List.pp "@ @<2>∧ "
    (fun fs (key, data) ->
-      Format.fprintf fs "@[%a@ = %a@]" (Exp.pp_full ?is_x) key
+      Format.fprintf fs "@[%a@ = %a@]" (Term.pp_full ?is_x) key
-        (List.pp "@ = " (Exp.pp_full ?is_x))
+        (List.pp "@ = " (Term.pp_full ?is_x))
-        (List.sort ~compare:Exp.compare data) )
+        (List.sort ~compare:Term.compare data) )
    fs
    (Map.to_alist (classes r))
@ -66,17 +66,17 @@ let pp_diff fs (r, s) =
    | k, `Unequal vv ->
        Format.fprintf fs "[@[%a@ @<2>↦ %a@]]" pp_key k pp_sdiff_val vv
  in
-  let pp_sdiff_exp_map =
+  let pp_sdiff_term_map =
-    let pp_sdiff_exp fs (u, v) =
+    let pp_sdiff_term fs (u, v) =
-      Format.fprintf fs "-- %a ++ %a" Exp.pp u Exp.pp v
+      Format.fprintf fs "-- %a ++ %a" Term.pp u Term.pp v
    in
-    pp_sdiff_map (pp_sdiff_elt Exp.pp Exp.pp pp_sdiff_exp) Exp.equal
+    pp_sdiff_map (pp_sdiff_elt Term.pp Term.pp pp_sdiff_term) Term.equal
  in
  let pp_sat fs =
    if not (Bool.equal r.sat s.sat) then
      Format.fprintf fs "sat= @[-- %b@ ++ %b@];@ " r.sat s.sat
  in
-  let pp_rep fs = pp_sdiff_exp_map "rep" fs r.rep s.rep in
+  let pp_rep fs = pp_sdiff_term_map "rep" fs r.rep s.rep in
  Format.fprintf fs "@[{@[<hv>%t%t@]}@]" pp_sat pp_rep
 (** Invariant *)
@ -85,68 +85,68 @@ let pp_diff fs (r, s) =
 let in_car r e = Map.mem r.rep e
 let rec iter_max_solvables e ~f =
-  match Exp.classify e with
+  match Term.classify e with
-  | `Interpreted -> Exp.iter ~f:(iter_max_solvables ~f) e
+  | `Interpreted -> Term.iter ~f:(iter_max_solvables ~f) e
  | _ -> f e
 let invariant r =
  Invariant.invariant [%here] r [%sexp_of: t]
  @@ fun () ->
  Map.iteri r.rep ~f:(fun ~key:a ~data:_ ->
-      (* no interpreted exps in carrier *)
+      (* no interpreted terms in carrier *)
-      assert (Poly.(Exp.classify a <> `Interpreted)) ;
+      assert (Poly.(Term.classify a <> `Interpreted)) ;
-      (* carrier is closed under sub-expressions *)
+      (* carrier is closed under subterms *)
      iter_max_solvables a ~f:(fun b ->
          assert (
            in_car r b
-            || Trace.fail "@[subexp %a of %a not in carrier of@ %a@]" Exp.pp
+            || Trace.fail "@[subterm %a of %a not in carrier of@ %a@]"
-                 b Exp.pp a pp r ) ) )
+                 Term.pp b Term.pp a pp r ) ) )
 (** Core operations *)
 let true_ = {sat= true; rep= empty_map} |> check invariant
-(** apply a subst to an exp *)
+(** apply a subst to a term *)
 let apply s a = try Map.find_exn s a with Caml.Not_found -> a
-(** apply a subst to maximal non-interpreted subexps *)
+(** apply a subst to maximal non-interpreted subterms *)
 let rec norm s a =
-  match Exp.classify a with
+  match Term.classify a with
-  | `Interpreted -> Exp.map ~f:(norm s) a
+  | `Interpreted -> Term.map ~f:(norm s) a
-  | `Simplified -> apply s (Exp.map ~f:(norm s) a)
+  | `Simplified -> apply s (Term.map ~f:(norm s) a)
  | `Atomic | `Uninterpreted -> apply s a
-(** exps are congruent if equal after normalizing subexps *)
+(** terms are congruent if equal after normalizing subterms *)
 let congruent r a b =
-  Exp.equal (Exp.map ~f:(norm r.rep) a) (Exp.map ~f:(norm r.rep) b)
+  Term.equal (Term.map ~f:(norm r.rep) a) (Term.map ~f:(norm r.rep) b)
 (** [lookup r a] is [b'] if [a ~ b = b'] for some equation [b = b'] in rep *)
 let lookup r a =
  With_return.with_return
  @@ fun {return} ->
  (* congruent specialized to assume [a] canonized and [b] non-interpreted *)
-  let semi_congruent r a b = Exp.equal a (Exp.map ~f:(apply r.rep) b) in
+  let semi_congruent r a b = Term.equal a (Term.map ~f:(apply r.rep) b) in
  Map.iteri r.rep ~f:(fun ~key ~data ->
      if semi_congruent r a key then return data ) ;
  a
-(** rewrite an exp into canonical form using rep and, for uninterpreted
+(** rewrite a term into canonical form using rep and, for uninterpreted
-    exps, congruence composed with rep *)
+    terms, congruence composed with rep *)
 let rec canon r a =
-  match Exp.classify a with
+  match Term.classify a with
-  | `Interpreted -> Exp.map ~f:(canon r) a
+  | `Interpreted -> Term.map ~f:(canon r) a
-  | `Simplified | `Uninterpreted -> lookup r (Exp.map ~f:(canon r) a)
+  | `Simplified | `Uninterpreted -> lookup r (Term.map ~f:(canon r) a)
  | `Atomic -> apply r.rep a
-(** add an exp to the carrier *)
+(** add a term to the carrier *)
 let rec extend a r =
-  match Exp.classify a with
+  match Term.classify a with
-  | `Interpreted | `Simplified -> Exp.fold ~f:extend a ~init:r
+  | `Interpreted | `Simplified -> Term.fold ~f:extend a ~init:r
  | `Uninterpreted ->
      Map.find_or_add r.rep a
        ~if_found:(fun _ -> r)
        ~default:a
-        ~if_added:(fun rep -> Exp.fold ~f:extend a ~init:{r with rep})
+        ~if_added:(fun rep -> Term.fold ~f:extend a ~init:{r with rep})
  | `Atomic -> r
 let extend a r = extend a r |> check invariant
@ -155,15 +155,15 @@ let compose r s =
  let rep = Map.map ~f:(norm s) r.rep in
  let rep =
    Map.merge_skewed rep s ~combine:(fun ~key v1 v2 ->
-        if Exp.equal v1 v2 then v1
+        if Term.equal v1 v2 then v1
-        else fail "domains intersect: %a" Exp.pp key () )
+        else fail "domains intersect: %a" Term.pp key () )
  in
  {r with rep}
 let merge a b r =
-  [%Trace.call fun {pf} -> pf "%a@ %a@ %a" Exp.pp a Exp.pp b pp r]
+  [%Trace.call fun {pf} -> pf "%a@ %a@ %a" Term.pp a Term.pp b pp r]
  ;
-  ( match Exp.solve a b with
+  ( match Term.solve a b with
  | Some s -> compose r s
  | None -> {r with sat= false} )
  |>
@ -171,15 +171,15 @@ let merge a b r =
    pf "%a" pp_diff (r, r') ;
    invariant r']
-(** find an unproved equation between congruent exps *)
+(** find an unproved equation between congruent terms *)
 let find_missing r =
  With_return.with_return
  @@ fun {return} ->
  Map.iteri r.rep ~f:(fun ~key:a ~data:a' ->
      Map.iteri r.rep ~f:(fun ~key:b ~data:b' ->
          if
-            Exp.compare a b < 0
+            Term.compare a b < 0
-            && (not (Exp.equal a' b'))
+            && (not (Term.equal a' b'))
            && congruent r a b
          then return (Some (a', b')) ) ) ;
  None
@ -207,15 +207,15 @@ let and_eq a b r =
    let b' = canon r b in
    let r = extend a' r in
    let r = extend b' r in
-    if Exp.equal a' b' then r else close (merge a' b' r)
+    if Term.equal a' b' then r else close (merge a' b' r)
 (** Exposed interface *)
 let is_true {sat; rep} =
-  sat && Map.for_alli rep ~f:(fun ~key:a ~data:a' -> Exp.equal a a')
+  sat && Map.for_alli rep ~f:(fun ~key:a ~data:a' -> Term.equal a a')
 let is_false {sat} = not sat
-let entails_eq r d e = Exp.equal (canon r d) (canon r e)
+let entails_eq r d e = Term.equal (canon r d) (canon r e)
 let entails r s =
  Map.for_alli s.rep ~f:(fun ~key:e ~data:e' -> entails_eq r e e')
@ -227,15 +227,15 @@ let class_of r e =
  e' :: Map.find_multi (classes r) e'
 let difference r a b =
-  [%Trace.call fun {pf} -> pf "%a@ %a@ %a" Exp.pp a Exp.pp b pp r]
+  [%Trace.call fun {pf} -> pf "%a@ %a@ %a" Term.pp a Term.pp b pp r]
  ;
  let a = canon r a in
  let b = canon r b in
-  ( if Exp.equal a b then Some Z.zero
+  ( if Term.equal a b then Some Z.zero
  else
-    match (Exp.typ a, Exp.typ b) with
+    match (Term.typ a, Term.typ b) with
    | Some typ, _ | _, Some typ -> (
-      match normalize r (Exp.sub typ a b) with
+      match normalize r (Term.sub typ a b) with
      | Integer {data} -> Some data
      | _ -> None )
    | _ -> None )
@ -265,17 +265,17 @@ let or_ r s =
    let rs = merge_mems rs s r in
    rs
-(* assumes that f is injective and for any set of exps E, f[E] is disjoint
+(* assumes that f is injective and for any set of terms E, f[E] is disjoint
   from E *)
-let map_exps ({sat= _; rep} as r) ~f =
+let map_terms ({sat= _; rep} as r) ~f =
  [%Trace.call fun {pf} -> pf "%a" pp r]
  ;
  let map m =
    Map.fold m ~init:m ~f:(fun ~key ~data m ->
        let key' = f key in
        let data' = f data in
-        if Exp.equal key' key then
+        if Term.equal key' key then
-          if Exp.equal data' data then m else Map.set m ~key ~data:data'
+          if Term.equal data' data then m else Map.set m ~key ~data:data'
        else Map.remove m key |> Map.add_exn ~key:key' ~data:data' )
  in
  let rep' = map rep in
@ -285,12 +285,12 @@ let map_exps ({sat= _; rep} as r) ~f =
    pf "%a" pp_diff (r, r') ;
    invariant r']
-let rename r sub = map_exps r ~f:(Exp.rename sub)
+let rename r sub = map_terms r ~f:(Term.rename sub)
-let fold_exps r ~init ~f =
+let fold_terms r ~init ~f =
  Map.fold r.rep ~f:(fun ~key ~data z -> f (f z data) key) ~init
 let fold_vars r ~init ~f =
-  fold_exps r ~init ~f:(fun init -> Exp.fold_vars ~f ~init)
+  fold_terms r ~init ~f:(fun init -> Term.fold_vars ~f ~init)
 let fv e = fold_vars e ~f:Set.add ~init:Var.Set.empty
--- a/sledge/src/symbheap/equality.mli
+++ b/sledge/src/symbheap/equality.mli
@ -11,14 +11,14 @@
 type t [@@deriving compare, equal, sexp]
 val pp : t pp
-val pp_classes : ?is_x:(Exp.t -> bool) -> t pp
+val pp_classes : ?is_x:(Term.t -> bool) -> t pp
 include Invariant.S with type t := t
 val true_ : t
-(** The diagonal relation, which only equates each exp with itself. *)
+(** The diagonal relation, which only equates each term with itself. *)
-val and_eq : Exp.t -> Exp.t -> t -> t
+val and_eq : Term.t -> Term.t -> t -> t
 (** Conjoin an equation to a relation. *)
 val and_ : t -> t -> t
@ -31,7 +31,7 @@ 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 exps of the relation. *)
+(** The variables occurring in the terms of the relation. *)
 val is_true : t -> bool
 (** Test if the relation is diagonal. *)
@ -39,24 +39,24 @@ val is_true : t -> bool
 val is_false : t -> bool
 (** Test if the relation is empty / inconsistent. *)
-val entails_eq : t -> Exp.t -> Exp.t -> bool
+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 -> Exp.t -> Exp.t list
+val class_of : t -> Term.t -> Term.t list
-(** Equivalence class of [e]: all the expressions in [f] in the relation
+(** Equivalence class of [e]: all the terms [f] in the relation such that [e
-    such that [e = f] is implied by the relation. *)
+    = f] is implied by the relation. *)
-val normalize : t -> Exp.t -> Exp.t
+val normalize : t -> Term.t -> Term.t
-(** Normalize an exp [e] to [e'] such that [e = e'] is implied by the
+(** Normalize a term [e] to [e'] such that [e = e'] is implied by the
-    relation, where [e'] and its sub-exps are expressed in terms of the
+    relation, where [e'] and its subterms are expressed in terms of the
    relation's canonical representatives of each equivalence class. *)
-val difference : t -> Exp.t -> Exp.t -> Z.t option
+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_exps : t -> init:'a -> f:('a -> Exp.t -> 'a) -> 'a
+val fold_terms : t -> init:'a -> f:('a -> Term.t -> 'a) -> 'a
--- a/sledge/src/symbheap/equality_test.ml
+++ b/sledge/src/symbheap/equality_test.ml
@ -18,12 +18,12 @@ let%test_module _ =
    let of_eqs = List.fold ~init:true_ ~f:(fun r (a, b) -> and_eq a b r)
    let i8 = Typ.integer ~bits:8
    let i64 = Typ.integer ~bits:64
-    let ( ! ) i = Exp.integer (Z.of_int i) Typ.siz
+    let ( ! ) i = Term.integer (Z.of_int i) Typ.siz
-    let ( + ) = Exp.add Typ.siz
+    let ( + ) = Term.add Typ.siz
-    let ( - ) = Exp.sub Typ.siz
+    let ( - ) = Term.sub Typ.siz
-    let ( * ) = Exp.mul Typ.siz
+    let ( * ) = Term.mul Typ.siz
-    let f = Exp.convert ~dst:i64 ~src:i8
+    let f = Term.convert ~dst:i64 ~src:i8
-    let g = Exp.rem
+    let g = Term.rem
    let wrt = Var.Set.empty
    let t_, wrt = Var.fresh "t" ~wrt
    let u_, wrt = Var.fresh "u" ~wrt
@ -32,13 +32,13 @@ let%test_module _ =
    let x_, wrt = Var.fresh "x" ~wrt
    let y_, wrt = Var.fresh "y" ~wrt
    let z_, _ = Var.fresh "z" ~wrt
-    let t = Exp.var t_
+    let t = Term.var t_
-    let u = Exp.var u_
+    let u = Term.var u_
-    let v = Exp.var v_
+    let v = Term.var v_
-    let w = Exp.var w_
+    let w = Term.var w_
-    let x = Exp.var x_
+    let x = Term.var x_
-    let y = Exp.var y_
+    let y = Term.var y_
-    let z = Exp.var z_
+    let z = Term.var z_
    let f1 = of_eqs [(!0, !1)]
    let%test _ = is_false f1
@ -212,9 +212,9 @@ let%test_module _ =
      %v_3 = %w_4 = %x_5 = %y_6 = %z_7 |}]
    let%expect_test _ =
-      printf (List.pp " , " Exp.pp) (Equality.class_of r7 t) ;
+      printf (List.pp " , " Term.pp) (Equality.class_of r7 t) ;
-      printf (List.pp " , " Exp.pp) (Equality.class_of r7 x) ;
+      printf (List.pp " , " Term.pp) (Equality.class_of r7 x) ;
-      printf (List.pp " , " Exp.pp) (Equality.class_of r7 z) ;
+      printf (List.pp " , " Term.pp) (Equality.class_of r7 z) ;
      [%expect
        {|
        %t_1
@ -235,7 +235,7 @@ let%test_module _ =
      {sat= true;
       rep= [[%w_4 ↦ %v_3]; [%x_5 ↦ %v_3]; [%y_6 ↦ %v_3]; [%z_7 ↦ %v_3]]} |}]
-    let%test _ = normalize r7' w |> Exp.equal v
+    let%test _ = normalize r7' w |> Term.equal v
    let%test _ =
      entails_eq (of_eqs [(g w x, g y z); (x, z)]) (g w x) (g w z)
@ -275,10 +275,10 @@ let%test_module _ =
    let%expect_test _ =
      pp_classes r10 ;
      pp r10 ;
-      Format.printf "@.%a@." Exp.pp (z - (x + !8)) ;
+      Format.printf "@.%a@." Term.pp (z - (x + !8)) ;
-      Format.printf "@.%a@." Exp.pp (normalize r10 (z - (x + !8))) ;
+      Format.printf "@.%a@." Term.pp (normalize r10 (z - (x + !8))) ;
-      Format.printf "@.%a@." Exp.pp (x + !8 - z) ;
+      Format.printf "@.%a@." Term.pp (x + !8 - z) ;
-      Format.printf "@.%a@." Exp.pp (normalize r10 (x + !8 - z)) ;
+      Format.printf "@.%a@." Term.pp (normalize r10 (x + !8 - z)) ;
      [%expect
        {|
      (%z_7 + -16) = %x_5
@ -308,7 +308,7 @@ let%test_module _ =
    let%expect_test _ = pp_classes r12 ; [%expect {| (%z_7 + -16) = %x_5 |}]
-    let r13 = of_eqs [(Exp.eq x !2, y); (Exp.dq x !2, z); (y, z)]
+    let r13 = of_eqs [(Term.eq x !2, y); (Term.dq x !2, z); (y, z)]
    let%expect_test _ =
      pp r13 ;
@ -319,15 +319,15 @@ let%test_module _ =
    let%test _ = not (is_false r13) (* incomplete *)
-    let a = Exp.dq x !0
+    let a = Term.dq x !0
    let r14 = of_eqs [(a, a); (x, !1)]
    let%expect_test _ =
      pp r14 ; [%expect {| {sat= true; rep= [[%x_5 ↦ 1]]} |}]
-    let%test _ = entails_eq r14 a (Exp.bool true)
+    let%test _ = entails_eq r14 a (Term.bool true)
-    let b = Exp.dq y !0
+    let b = Term.dq y !0
    let r14 = of_eqs [(a, b); (x, !1)]
    let%expect_test _ =
@ -336,10 +336,10 @@ let%test_module _ =
        {|
          {sat= true; rep= [[%x_5 ↦ 1]; [(%y_6 ≠ 0) ↦ -1]]} |}]
-    let%test _ = entails_eq r14 a (Exp.bool true)
+    let%test _ = entails_eq r14 a (Term.bool true)
-    let%test _ = entails_eq r14 b (Exp.bool true)
+    let%test _ = entails_eq r14 b (Term.bool true)
-    let b = Exp.convert ~dst:i64 ~src:i8 (Exp.dq x !0)
+    let b = Term.convert ~dst:i64 ~src:i8 (Term.dq x !0)
    let r15 = of_eqs [(b, b); (x, !1)]
    let%expect_test _ =
--- a/sledge/src/symbheap/exec.ml
+++ b/sledge/src/symbheap/exec.ml
@ -17,11 +17,13 @@ type xseg = {us: Var.Set.t; xs: Var.Set.t; seg: Sh.seg}
 let fresh_var nam us xs =
  let var, us = Var.fresh nam ~wrt:us in
-  (Exp.var var, us, Set.add xs var)
+  (Term.var var, us, Set.add xs var)
 let fresh_seg ~loc ?bas ?len ?siz ?arr ?(xs = Var.Set.empty) us =
-  let freshen exp nam us xs =
+  let freshen term nam us xs =
-    match exp with Some exp -> (exp, us, xs) | None -> fresh_var nam us xs
+    match term with
    | Some term -> (term, us, xs)
    | None -> fresh_var nam us xs
  in
  let bas, us, xs = freshen bas "b" us xs in
  let len, us, xs = freshen len "m" us xs in
@ -29,8 +31,8 @@ let fresh_seg ~loc ?bas ?len ?siz ?arr ?(xs = Var.Set.empty) us =
  let arr, us, xs = freshen arr "a" us xs in
  {us; xs; seg= {loc; bas; len; siz; arr}}
-let null_eq ptr = Sh.pure (Exp.eq Exp.null ptr)
+let null_eq ptr = Sh.pure (Term.eq Term.null ptr)
-let zero = Exp.integer Z.zero Typ.siz
+let zero = Term.integer Z.zero Typ.siz
 (* Overwritten variables renaming and remaining modified variables. [ws] are
   the written variables; [rs] are the variables read or in the
@ -63,12 +65,12 @@ let move_spec us reg_exps =
  let ws, rs =
    Vector.fold reg_exps ~init:(Var.Set.empty, Var.Set.empty)
      ~f:(fun (ws, rs) (reg, exp) ->
-        (Set.add ws reg, Set.union rs (Exp.fv exp)) )
+        (Set.add ws reg, Set.union rs (Term.fv exp)) )
  in
  let sub, ms, _ = assign ~ws ~rs ~us in
  let post =
    Vector.fold reg_exps ~init:Sh.emp ~f:(fun post (reg, exp) ->
-        Sh.and_ (Exp.eq (Exp.var reg) (Exp.rename sub exp)) post )
+        Sh.and_ (Term.eq (Term.var reg) (Term.rename sub exp)) post )
  in
  {xs; foot; sub; ms; post}
@ -82,7 +84,7 @@ let load_spec us reg ptr len =
  let sub, ms, _ = assign ~ws:(Set.add Var.Set.empty reg) ~rs:foot.us ~us in
  let post =
    Sh.and_
-      (Exp.eq (Exp.var reg) (Exp.rename sub seg.arr))
+      (Term.eq (Term.var reg) (Term.rename sub seg.arr))
      (Sh.rename sub foot)
  in
  {xs; foot; sub; ms; post}
@ -104,7 +106,7 @@ let store_spec us ptr exp len =
 let memset_spec us dst byt len =
  let {us= _; xs; seg} = fresh_seg ~loc:dst ~siz:len us in
  let foot = Sh.seg seg in
-  let post = Sh.seg {seg with arr= Exp.splat ~byt ~siz:len} in
+  let post = Sh.seg {seg with arr= Term.splat ~byt ~siz:len} in
  {xs; foot; sub= Var.Subst.empty; ms= Var.Set.empty; post}
 (* { d=s * l=0 * d-[b;m)->⟨l,α⟩ }
@ -115,7 +117,7 @@ let memcpy_eq_spec us dst src len =
  let {us= _; xs; seg} = fresh_seg ~loc:dst ~len us in
  let dst_heap = Sh.seg seg in
  let foot =
-    Sh.and_ (Exp.eq dst src) (Sh.and_ (Exp.eq len zero) dst_heap)
+    Sh.and_ (Term.eq dst src) (Sh.and_ (Term.eq len zero) dst_heap)
  in
  let post = dst_heap in
  {xs; foot; sub= Var.Subst.empty; ms= Var.Set.empty; post}
@ -145,7 +147,7 @@ let memcpy_specs us dst src len =
 let memmov_eq_spec us dst src len =
  let {us= _; xs; seg= dst_seg} = fresh_seg ~loc:dst ~len us in
  let dst_heap = Sh.seg dst_seg in
-  let foot = Sh.and_ (Exp.eq dst src) dst_heap in
+  let foot = Sh.and_ (Term.eq dst src) dst_heap in
  let post = dst_heap in
  {xs; foot; sub= Var.Subst.empty; ms= Var.Set.empty; post}
@ -163,17 +165,17 @@ let memmov_foot us dst src len =
  let arr_dst, us, xs = fresh_var "a" us xs in
  let arr_mid, us, xs = fresh_var "a" us xs in
  let arr_src, us, xs = fresh_var "a" us xs in
-  let src_dst = Exp.sub Typ.siz src dst in
+  let src_dst = Term.sub Typ.siz src dst in
-  let mem_dst = Exp.memory ~siz:src_dst ~arr:arr_dst in
+  let mem_dst = Term.memory ~siz:src_dst ~arr:arr_dst in
-  let siz_mid = Exp.sub Typ.siz len src_dst in
+  let siz_mid = Term.sub Typ.siz len src_dst in
-  let mem_mid = Exp.memory ~siz:siz_mid ~arr:arr_mid in
+  let mem_mid = Term.memory ~siz:siz_mid ~arr:arr_mid in
-  let mem_src = Exp.memory ~siz:src_dst ~arr:arr_src in
+  let mem_src = Term.memory ~siz:src_dst ~arr:arr_src in
-  let mem_dst_mid_src = Exp.concat [|mem_dst; mem_mid; mem_src|] in
+  let mem_dst_mid_src = Term.concat [|mem_dst; mem_mid; mem_src|] in
  let siz_dst_mid_src, us, xs = fresh_var "m" us xs in
  let arr_dst_mid_src, _, xs = fresh_var "a" us xs in
  let eq_mem_dst_mid_src =
-    Exp.eq mem_dst_mid_src
+    Term.eq mem_dst_mid_src
-      (Exp.memory ~siz:siz_dst_mid_src ~arr:arr_dst_mid_src)
+      (Term.memory ~siz:siz_dst_mid_src ~arr:arr_dst_mid_src)
  in
  let seg =
    Sh.seg
@ -181,8 +183,8 @@ let memmov_foot us dst src len =
  in
  let foot =
    Sh.and_ eq_mem_dst_mid_src
-      (Sh.and_ (Exp.lt dst src)
+      (Sh.and_ (Term.lt dst src)
-         (Sh.and_ (Exp.lt src (Exp.add Typ.ptr dst len)) seg))
+         (Sh.and_ (Term.lt src (Term.add Typ.ptr dst len)) seg))
  in
  (xs, bas, siz, mem_dst, mem_mid, mem_src, foot)
@ -194,12 +196,12 @@ let memmov_dn_spec us dst src len =
  let xs, bas, siz, _, mem_mid, mem_src, foot =
    memmov_foot us dst src len
  in
-  let mem_mid_src_src = Exp.concat [|mem_mid; mem_src; mem_src|] in
+  let mem_mid_src_src = Term.concat [|mem_mid; mem_src; mem_src|] in
  let siz_mid_src_src, us, xs = fresh_var "m" us xs in
  let arr_mid_src_src, _, xs = fresh_var "a" us xs in
  let eq_mem_mid_src_src =
-    Exp.eq mem_mid_src_src
+    Term.eq mem_mid_src_src
-      (Exp.memory ~siz:siz_mid_src_src ~arr:arr_mid_src_src)
+      (Term.memory ~siz:siz_mid_src_src ~arr:arr_mid_src_src)
  in
  let post =
    Sh.and_ eq_mem_mid_src_src
@ -220,12 +222,12 @@ let memmov_up_spec us dst src len =
  let xs, bas, siz, mem_src, mem_mid, _, foot =
    memmov_foot us src dst len
  in
-  let mem_src_src_mid = Exp.concat [|mem_src; mem_src; mem_mid|] in
+  let mem_src_src_mid = Term.concat [|mem_src; mem_src; mem_mid|] in
  let siz_src_src_mid, us, xs = fresh_var "m" us xs in
  let arr_src_src_mid, _, xs = fresh_var "a" us xs in
  let eq_mem_src_src_mid =
-    Exp.eq mem_src_src_mid
+    Term.eq mem_src_src_mid
-      (Exp.memory ~siz:siz_src_src_mid ~arr:arr_src_src_mid)
+      (Term.memory ~siz:siz_src_src_mid ~arr:arr_src_src_mid)
  in
  let post =
    Sh.and_ eq_mem_src_src_mid
@ -250,12 +252,12 @@ let memmov_specs us dst src len =
 *)
 let alloc_spec us reg num len =
  let foot = Sh.emp in
-  let siz = Exp.mul Typ.siz num len in
+  let siz = Term.mul Typ.siz num len in
  let sub, ms, us =
-    assign ~ws:(Set.add Var.Set.empty reg) ~rs:(Exp.fv siz) ~us
+    assign ~ws:(Set.add Var.Set.empty reg) ~rs:(Term.fv siz) ~us
  in
-  let loc = Exp.var reg in
+  let loc = Term.var reg in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
  let {us= _; xs; seg} = fresh_seg ~loc ~bas:loc ~len:siz ~siz us in
  let post = Sh.seg seg in
  {xs; foot; sub; ms; post}
@ -293,12 +295,12 @@ let dallocx_spec us ptr =
 let malloc_spec us reg siz =
  let foot = Sh.emp in
  let sub, ms, us =
-    assign ~ws:(Set.add Var.Set.empty reg) ~rs:(Exp.fv siz) ~us
+    assign ~ws:(Set.add Var.Set.empty reg) ~rs:(Term.fv siz) ~us
  in
-  let loc = Exp.var reg in
+  let loc = Term.var reg in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
  let {us= _; xs; seg} = fresh_seg ~loc ~bas:loc ~len:siz ~siz us in
-  let post = Sh.or_ (null_eq (Exp.var reg)) (Sh.seg seg) in
+  let post = Sh.or_ (null_eq (Term.var reg)) (Sh.seg seg) in
  {xs; foot; sub; ms; post}
 (* { s≠0 }
@ -306,14 +308,14 @@ let malloc_spec us reg siz =
 * { r=0 ∨ ∃α'. r-[r;sΘ)->⟨sΘ,α'⟩ }
 *)
 let mallocx_spec us reg siz =
-  let foot = Sh.pure Exp.(dq siz zero) in
+  let foot = Sh.pure Term.(dq siz zero) in
  let sub, ms, us =
-    assign ~ws:(Set.add Var.Set.empty reg) ~rs:(Exp.fv siz) ~us
+    assign ~ws:(Set.add Var.Set.empty reg) ~rs:(Term.fv siz) ~us
  in
-  let loc = Exp.var reg in
+  let loc = Term.var reg in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
  let {us= _; xs; seg} = fresh_seg ~loc ~bas:loc ~len:siz ~siz us in
-  let post = Sh.or_ (null_eq (Exp.var reg)) (Sh.seg seg) in
+  let post = Sh.or_ (null_eq (Term.var reg)) (Sh.seg seg) in
  {xs; foot; sub; ms; post}
 (* { emp }
@ -322,18 +324,18 @@ let mallocx_spec us reg siz =
 *)
 let calloc_spec us reg num len =
  let foot = Sh.emp in
-  let siz = Exp.mul Typ.siz num len in
+  let siz = Term.mul Typ.siz num len in
  let sub, ms, us =
-    assign ~ws:(Set.add Var.Set.empty reg) ~rs:(Exp.fv siz) ~us
+    assign ~ws:(Set.add Var.Set.empty reg) ~rs:(Term.fv siz) ~us
  in
-  let loc = Exp.var reg in
+  let loc = Term.var reg in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
-  let arr = Exp.splat ~byt:(Exp.integer Z.zero Typ.byt) ~siz in
+  let arr = Term.splat ~byt:(Term.integer Z.zero Typ.byt) ~siz in
  let {us= _; xs; seg} = fresh_seg ~loc ~bas:loc ~len:siz ~siz ~arr us in
-  let post = Sh.or_ (null_eq (Exp.var reg)) (Sh.seg seg) in
+  let post = Sh.or_ (null_eq (Term.var reg)) (Sh.seg seg) in
  {xs; foot; sub; ms; post}
-let size_of_ptr = Option.value_exn (Exp.size_of Typ.ptr)
+let size_of_ptr = Option.value_exn (Term.size_of Typ.ptr)
 (* { p-[_;_)->⟨W,_⟩ }
 *   posix_memalign r p s
@ -347,7 +349,7 @@ let posix_memalign_spec us reg ptr siz =
  let sub, ms, us =
    assign
      ~ws:(Set.add Var.Set.empty reg)
-      ~rs:(Set.union foot.us (Exp.fv siz))
+      ~rs:(Set.union foot.us (Term.fv siz))
      ~us
  in
  let q, us, xs = fresh_var "q" us xs in
@ -355,13 +357,13 @@ let posix_memalign_spec us reg ptr siz =
  let {us= _; xs; seg= qseg} =
    fresh_seg ~loc:q ~bas:q ~len:siz ~siz ~xs us
  in
-  let eok = Exp.integer (Z.of_int 0) Typ.int in
+  let eok = Term.integer (Z.of_int 0) Typ.int in
-  let enomem = Exp.integer (Z.of_int 12) Typ.int in
+  let enomem = Term.integer (Z.of_int 12) Typ.int in
  let post =
    Sh.or_
-      (Sh.and_ (Exp.eq (Exp.var reg) enomem) (Sh.rename sub foot))
+      (Sh.and_ (Term.eq (Term.var reg) enomem) (Sh.rename sub foot))
      (Sh.and_
-         (Exp.eq (Exp.var reg) eok)
+         (Term.eq (Term.var reg) eok)
         (Sh.rename sub (Sh.star (Sh.seg pseg') (Sh.seg qseg))))
  in
  {xs; foot; sub; ms; post}
@ -381,20 +383,20 @@ let realloc_spec us reg ptr siz =
  let sub, ms, us =
    assign
      ~ws:(Set.add Var.Set.empty reg)
-      ~rs:(Set.union foot.us (Exp.fv siz))
+      ~rs:(Set.union foot.us (Term.fv siz))
      ~us
  in
-  let loc = Exp.var reg in
+  let loc = Term.var reg in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
  let {us; xs; seg= rseg} = fresh_seg ~loc ~bas:loc ~len:siz ~siz ~xs us in
  let a0 = pseg.arr in
  let a1 = rseg.arr in
  let a2, _, xs = fresh_var "a" us xs in
  let post =
    Sh.or_
-      (Sh.and_ Exp.(eq loc null) (Sh.rename sub foot))
+      (Sh.and_ Term.(eq loc null) (Sh.rename sub foot))
      (Sh.and_
-         Exp.(
+         Term.(
           conditional ~cnd:(le len siz)
             ~thn:
               (eq (memory ~siz ~arr:a1)
@ -422,21 +424,21 @@ let rallocx_spec us reg ptr siz =
    fresh_seg ~loc:ptr ~bas:ptr ~len ~siz:len ~xs us
  in
  let pheap = Sh.seg pseg in
-  let foot = Sh.and_ Exp.(dq siz zero) pheap in
+  let foot = Sh.and_ Term.(dq siz zero) pheap in
  let sub, ms, us =
    assign ~ws:(Set.add Var.Set.empty reg) ~rs:foot.us ~us
  in
-  let loc = Exp.var reg in
+  let loc = Term.var reg in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
  let {us; xs; seg= rseg} = fresh_seg ~loc ~bas:loc ~len:siz ~siz ~xs us in
  let a0 = pseg.arr in
  let a1 = rseg.arr in
  let a2, _, xs = fresh_var "a" us xs in
  let post =
    Sh.or_
-      (Sh.and_ Exp.(eq loc null) (Sh.rename sub pheap))
+      (Sh.and_ Term.(eq loc null) (Sh.rename sub pheap))
      (Sh.and_
-         Exp.(
+         Term.(
           conditional ~cnd:(le len siz)
             ~thn:
               (eq (memory ~siz ~arr:a1)
@ -460,17 +462,17 @@ let rallocx_spec us reg ptr siz =
 let xallocx_spec us reg ptr siz ext =
  let len, us, xs = fresh_var "m" us Var.Set.empty in
  let {us; xs; seg} = fresh_seg ~loc:ptr ~bas:ptr ~len ~siz:len ~xs us in
-  let foot = Sh.and_ Exp.(dq siz zero) (Sh.seg seg) in
+  let foot = Sh.and_ Term.(dq siz zero) (Sh.seg seg) in
  let sub, ms, us =
    assign
      ~ws:(Set.add Var.Set.empty reg)
-      ~rs:Set.(union foot.us (union (Exp.fv siz) (Exp.fv ext)))
+      ~rs:Set.(union foot.us (union (Term.fv siz) (Term.fv ext)))
      ~us
  in
-  let reg = Exp.var reg in
+  let reg = Term.var reg in
-  let ptr = Exp.rename sub ptr in
+  let ptr = Term.rename sub ptr in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
-  let ext = Exp.rename sub ext in
+  let ext = Term.rename sub ext in
  let {us; xs; seg= seg'} =
    fresh_seg ~loc:ptr ~bas:ptr ~len:reg ~siz:reg ~xs us
  in
@ -479,7 +481,7 @@ let xallocx_spec us reg ptr siz ext =
  let a2, _, xs = fresh_var "a" us xs in
  let post =
    Sh.and_
-      Exp.(
+      Term.(
        and_
          (conditional ~cnd:(le len siz)
             ~thn:
@ -506,7 +508,7 @@ let sallocx_spec us reg ptr =
  let {us; xs; seg} = fresh_seg ~loc:ptr ~bas:ptr ~len ~siz:len ~xs us in
  let foot = Sh.seg seg in
  let sub, ms, _ = assign ~ws:(Set.add Var.Set.empty reg) ~rs:foot.us ~us in
-  let post = Sh.and_ Exp.(eq (var reg) len) (Sh.rename sub foot) in
+  let post = Sh.and_ Term.(eq (var reg) len) (Sh.rename sub foot) in
  {xs; foot; sub; ms; post}
 (* { p-[p;m)->⟨m,α⟩ }
@ -518,7 +520,7 @@ let malloc_usable_size_spec us reg ptr =
  let {us; xs; seg} = fresh_seg ~loc:ptr ~bas:ptr ~len ~siz:len ~xs us in
  let foot = Sh.seg seg in
  let sub, ms, _ = assign ~ws:(Set.add Var.Set.empty reg) ~rs:foot.us ~us in
-  let post = Sh.and_ Exp.(le len (var reg)) (Sh.rename sub foot) in
+  let post = Sh.and_ Term.(le len (var reg)) (Sh.rename sub foot) in
  {xs; foot; sub; ms; post}
 (* { s≠0 }
@ -527,15 +529,15 @@ let malloc_usable_size_spec us reg ptr =
 *)
 let nallocx_spec us reg siz =
  let xs = Var.Set.empty in
-  let foot = Sh.pure (Exp.dq siz zero) in
+  let foot = Sh.pure (Term.dq siz zero) in
  let sub, ms, _ = assign ~ws:(Set.add Var.Set.empty reg) ~rs:foot.us ~us in
-  let loc = Exp.var reg in
+  let loc = Term.var reg in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
-  let post = Sh.or_ (null_eq loc) (Sh.pure (Exp.eq loc siz)) in
+  let post = Sh.or_ (null_eq loc) (Sh.pure (Term.eq loc siz)) in
  {xs; foot; sub; ms; post}
 let size_of_int_mul n =
-  Exp.mul Typ.siz (Option.value_exn (Exp.size_of Typ.siz)) n
+  Term.mul Typ.siz (Option.value_exn (Term.size_of Typ.siz)) n
 (* { r-[_;_)->⟨m,_⟩ * i-[_;_)->⟨_,m⟩ * w=0 * n=0 }
 *   mallctl r i w n
@ -547,8 +549,8 @@ let mallctl_read_spec us r i w n =
  let a, _, xs = fresh_var "a" us xs in
  let foot =
    Sh.and_
-      Exp.(eq w null)
+      Term.(eq w null)
-      (Sh.and_ Exp.(eq n zero) (Sh.star (Sh.seg iseg) (Sh.seg rseg)))
+      (Sh.and_ Term.(eq n zero) (Sh.star (Sh.seg iseg) (Sh.seg rseg)))
  in
  let rseg' = {rseg with arr= a} in
  let post = Sh.star (Sh.seg rseg') (Sh.seg iseg) in
@ -569,8 +571,8 @@ let mallctlbymib_read_spec us p l r i w n =
  let a, _, xs = fresh_var "a" us xs in
  let foot =
    Sh.and_
-      Exp.(eq w null)
+      Term.(eq w null)
-      (Sh.and_ Exp.(eq n zero) (Sh.star const (Sh.seg rseg)))
+      (Sh.and_ Term.(eq n zero) (Sh.star const (Sh.seg rseg)))
  in
  let rseg' = {rseg with arr= a} in
  let post = Sh.star (Sh.seg rseg') const in
@ -583,7 +585,7 @@ let mallctlbymib_read_spec us p l r i w n =
 let mallctl_write_spec us r i w n =
  let {us= _; xs; seg} = fresh_seg ~loc:w ~siz:n us in
  let post = Sh.seg seg in
-  let foot = Sh.and_ Exp.(eq r null) (Sh.and_ Exp.(eq i zero) post) in
+  let foot = Sh.and_ Term.(eq r null) (Sh.and_ Term.(eq i zero) post) in
  {xs; foot; sub= Var.Subst.empty; ms= Var.Set.empty; post}
 (* { p-[_;_)->⟨W×l,_⟩ * r=0 * i=0 * w-[_;_)->⟨n,_⟩ }
@ -596,7 +598,7 @@ let mallctlbymib_write_spec us p l r i w n =
  let {us; xs; seg= pseg} = fresh_seg ~loc:p ~siz:wl us in
  let {us= _; xs; seg= wseg} = fresh_seg ~loc:w ~siz:n ~xs us in
  let post = Sh.star (Sh.seg pseg) (Sh.seg wseg) in
-  let foot = Sh.and_ Exp.(eq r null) (Sh.and_ Exp.(eq i zero) post) in
+  let foot = Sh.and_ Term.(eq r null) (Sh.and_ Term.(eq i zero) post) in
  {xs; foot; sub= Var.Subst.empty; ms= Var.Set.empty; post}
 let mallctl_specs us r i w n =
@ -641,12 +643,14 @@ let strlen_spec us reg ptr =
  let sub, ms, _ = assign ~ws:(Set.add Var.Set.empty reg) ~rs:foot.us ~us in
  let {Sh.loc= p; bas= b; len= m; _} = seg in
  let ret =
-    Exp.sub Typ.siz
+    Term.sub Typ.siz
-      (Exp.sub Typ.siz (Exp.add Typ.siz b m) p)
+      (Term.sub Typ.siz (Term.add Typ.siz b m) p)
-      (Exp.integer Z.one Typ.siz)
+      (Term.integer Z.one Typ.siz)
  in
  let post =
-    Sh.and_ (Exp.eq (Exp.var reg) (Exp.rename sub ret)) (Sh.rename sub foot)
+    Sh.and_
      (Term.eq (Term.var reg) (Term.rename sub ret))
      (Sh.rename sub foot)
  in
  {xs; foot; sub; ms; post}
@ -705,20 +709,38 @@ let inst : Sh.t -> Llair.inst -> (Sh.t, unit) result =
 fun pre inst ->
  [%Trace.info
    "@[<2>exec inst %a from@ @[{ %a@ }@]@]" Llair.Inst.pp inst Sh.pp pre] ;
-  assert (Set.disjoint (Sh.fv pre) (Llair.Inst.locals inst)) ;
+  assert (
    Set.disjoint (Sh.fv pre) (Var.Set.of_regs (Llair.Inst.locals inst)) ) ;
  let us = pre.us in
  match inst with
-  | Move {reg_exps; _} -> exec_spec pre (move_spec us reg_exps)
+  | Move {reg_exps; _} ->
-  | Load {reg; ptr; len; _} -> exec_spec pre (load_spec us reg ptr len)
+      exec_spec pre
-  | Store {ptr; exp; len; _} -> exec_spec pre (store_spec us ptr exp len)
+        (move_spec us
-  | Memset {dst; byt; len; _} -> exec_spec pre (memset_spec us dst byt len)
+           (Vector.map reg_exps ~f:(fun (r, e) ->
                (Var.of_reg r, Term.of_exp e) )))
  | Load {reg; ptr; len; _} ->
      exec_spec pre
        (load_spec us (Var.of_reg reg) (Term.of_exp ptr) (Term.of_exp len))
  | Store {ptr; exp; len; _} ->
      exec_spec pre
        (store_spec us (Term.of_exp ptr) (Term.of_exp exp) (Term.of_exp len))
  | Memset {dst; byt; len; _} ->
      exec_spec pre
        (memset_spec us (Term.of_exp dst) (Term.of_exp byt)
           (Term.of_exp len))
  | Memcpy {dst; src; len; _} ->
-      exec_specs pre (memcpy_specs us dst src len)
+      exec_specs pre
        (memcpy_specs us (Term.of_exp dst) (Term.of_exp src)
           (Term.of_exp len))
  | Memmov {dst; src; len; _} ->
-      exec_specs pre (memmov_specs us dst src len)
+      exec_specs pre
-  | Alloc {reg; num; len; _} -> exec_spec pre (alloc_spec us reg num len)
+        (memmov_specs us (Term.of_exp dst) (Term.of_exp src)
-  | Free {ptr; _} -> exec_spec pre (free_spec us ptr)
+           (Term.of_exp len))
-  | Nondet {reg= Some reg; _} -> Ok (kill pre reg)
+  | Alloc {reg; num; len; _} ->
      exec_spec pre
        (alloc_spec us (Var.of_reg reg) (Term.of_exp num) (Term.of_exp len))
  | Free {ptr; _} -> exec_spec pre (free_spec us (Term.of_exp ptr))
  | Nondet {reg= Some reg; _} -> Ok (kill pre (Var.of_reg reg))
  | Nondet {reg= None; _} -> Ok pre
  | Abort _ -> Error ()
@ -728,13 +750,13 @@ let intrinsic ~skip_throw :
       Sh.t
    -> Var.t option
    -> Var.t
-    -> Exp.t list
+    -> Term.t list
    -> (Sh.t, unit) result option =
 fun pre areturn intrinsic actuals ->
  [%Trace.info
    "@[<2>exec intrinsic@ @[%a%a(@[%a@])@] from@ @[{ %a@ }@]@]"
      (Option.pp "%a := " Var.pp)
-      areturn Var.pp intrinsic (List.pp ",@ " Exp.pp) (List.rev actuals)
+      areturn Var.pp intrinsic (List.pp ",@ " Term.pp) (List.rev actuals)
      Sh.pp pre] ;
  let us = pre.us in
  let name =
--- a/sledge/src/symbheap/exec.mli
+++ b/sledge/src/symbheap/exec.mli
@ -7,9 +7,9 @@
 (** Symbolic Execution *)
-val assume : Sh.t -> Exp.t -> Sh.t option
+val assume : Sh.t -> Term.t -> Sh.t option
 val kill : Sh.t -> Var.t -> Sh.t
-val move : Sh.t -> Var.t -> Exp.t -> Sh.t
+val move : Sh.t -> Var.t -> Term.t -> Sh.t
 val inst : Sh.t -> Llair.inst -> (Sh.t, unit) result
 val intrinsic :
@ -17,5 +17,5 @@ val intrinsic :
  -> Sh.t
  -> Var.t option
  -> Var.t
-  -> Exp.t list
+  -> Term.t list
  -> (Sh.t, unit) result option
--- a/sledge/src/symbheap/sh.ml
+++ b/sledge/src/symbheap/sh.ml
@ -9,14 +9,14 @@
 [@@@warning "+9"]
-type seg = {loc: Exp.t; bas: Exp.t; len: Exp.t; siz: Exp.t; arr: Exp.t}
+type seg = {loc: Term.t; bas: Term.t; len: Term.t; siz: Term.t; arr: Term.t}
 [@@deriving compare, equal, sexp]
 type starjunction =
  { us: Var.Set.t
  ; xs: Var.Set.t
  ; cong: Equality.t
-  ; pure: Exp.t list
+  ; pure: Term.t list
  ; heap: seg list
  ; djns: disjunction list }
 [@@deriving compare, equal, sexp]
@ -29,12 +29,12 @@ let map_seg {loc; bas; len; siz; arr} ~f =
  {loc= f loc; bas= f bas; len= f len; siz= f siz; arr= f arr}
 let pp_seg ?is_x fs {loc; bas; len; siz; arr} =
-  let exp_pp = Exp.pp_full ?is_x in
+  let term_pp = Term.pp_full ?is_x in
-  Format.fprintf fs "@[<2>%a@ @[@[-[%a)->@]@ %a@]@]" exp_pp loc
+  Format.fprintf fs "@[<2>%a@ @[@[-[%a)->@]@ %a@]@]" term_pp loc
    (fun fs (bas, len) ->
-      if (not (Exp.equal loc bas)) || not (Exp.equal len siz) then
+      if (not (Term.equal loc bas)) || not (Term.equal len siz) then
-        Format.fprintf fs " %a, %a " exp_pp bas exp_pp len )
+        Format.fprintf fs " %a, %a " term_pp bas term_pp len )
-    (bas, len) exp_pp (Exp.memory ~siz ~arr)
+    (bas, len) term_pp (Term.memory ~siz ~arr)
 let pp_seg_norm cong fs seg =
  pp_seg fs (map_seg seg ~f:(Equality.normalize cong))
@ -46,7 +46,7 @@ let pp_us ?(pre = ("" : _ fmt)) fs us =
 let rec pp vs all_xs fs {us; xs; cong; pure; heap; djns} =
  Format.pp_open_hvbox fs 0 ;
  let all_xs = Set.union all_xs xs in
-  let is_x var = Set.mem all_xs (Option.value_exn (Var.of_exp var)) in
+  let is_x var = Set.mem all_xs (Option.value_exn (Var.of_term var)) in
  pp_us fs us ;
  let xs_i_vs, xs_d_vs = Set.inter_diff vs xs in
  if not (Set.is_empty xs_i_vs) then (
@ -57,15 +57,15 @@ let rec pp vs all_xs fs {us; xs; cong; pure; heap; djns} =
  let first = Equality.is_true cong in
  if not first then Format.fprintf fs "  " ;
  Equality.pp_classes ~is_x fs cong ;
-  let pure_exps =
+  let pure_terms =
    List.filter_map pure ~f:(fun e ->
        let e' = Equality.normalize cong e in
-        if Exp.is_true e' then None else Some e' )
+        if Term.is_true e' then None else Some e' )
  in
  List.pp
    ~pre:(if first then "  " else "@ @<2>∧ ")
-    "@ @<2>∧ " (Exp.pp_full ~is_x) fs pure_exps ;
+    "@ @<2>∧ " (Term.pp_full ~is_x) fs pure_terms ;
-  let first = first && List.is_empty pure_exps in
+  let first = first && List.is_empty pure_terms in
  if List.is_empty heap then
    Format.fprintf fs
      ( if first then if List.is_empty djns then "  emp" else ""
@ -78,11 +78,12 @@ let rec pp vs all_xs fs {us; xs; cong; pure; heap; djns} =
         (List.map ~f:(map_seg ~f:(Equality.normalize cong)) heap)
         ~compare:(fun s1 s2 ->
           let b_o = function
-             | Exp.App {op= App {op= Add _; arg}; arg= Integer {data; _}} ->
+             | Term.App {op= App {op= Add _; arg}; arg= Integer {data; _}}
               ->
                 (arg, data)
             | e -> (e, Z.zero)
           in
-           [%compare: Exp.t * (Exp.t * Z.t)]
+           [%compare: Term.t * (Term.t * Z.t)]
             (s1.bas, b_o s1.loc)
             (s2.bas, b_o s2.loc) )) ;
  let first = first && List.is_empty heap in
@ -105,34 +106,34 @@ and pp_djn vs all_xs fs = function
 let pp = pp Var.Set.empty Var.Set.empty
 let pp_djn = pp_djn Var.Set.empty Var.Set.empty
-let fold_exps_seg {loc; bas; len; siz; arr} ~init ~f =
+let fold_terms_seg {loc; bas; len; siz; arr} ~init ~f =
-  let f b z = Exp.fold_exps b ~init:z ~f in
+  let f b z = Term.fold_terms b ~init:z ~f in
  f loc (f bas (f len (f siz (f arr init))))
 let fold_vars_seg seg ~init ~f =
-  fold_exps_seg seg ~init ~f:(fun init -> Exp.fold_vars ~f ~init)
+  fold_terms_seg seg ~init ~f:(fun init -> Term.fold_vars ~f ~init)
 let fv_seg seg = fold_vars_seg seg ~f:Set.add ~init:Var.Set.empty
-let fold_exps fold_exps {us= _; xs= _; cong; pure; heap; djns} ~init ~f =
+let fold_terms fold_terms {us= _; xs= _; cong; pure; heap; djns} ~init ~f =
-  Equality.fold_exps ~init cong ~f
+  Equality.fold_terms ~init cong ~f
  |> fun init ->
-  List.fold ~init pure ~f:(fun init -> Exp.fold_exps ~f ~init)
+  List.fold ~init pure ~f:(fun init -> Term.fold_terms ~f ~init)
  |> fun init ->
-  List.fold ~init heap ~f:(fun init -> fold_exps_seg ~f ~init)
+  List.fold ~init heap ~f:(fun init -> fold_terms_seg ~f ~init)
  |> fun init ->
-  List.fold ~init djns ~f:(fun init -> List.fold ~init ~f:fold_exps)
+  List.fold ~init djns ~f:(fun init -> List.fold ~init ~f:fold_terms)
 let rec fv_union init q =
  Set.diff
-    (fold_exps fv_union q ~init ~f:(fun init ->
+    (fold_terms fv_union q ~init ~f:(fun init ->
-         Exp.fold_vars ~f:Set.add ~init ))
+         Term.fold_vars ~f:Set.add ~init ))
    q.xs
 let fv q = fv_union Var.Set.empty q
 let invariant_pure = function
-  | Exp.Integer {data; typ} ->
+  | Term.Integer {data; typ} ->
      assert (Typ.equal Typ.bool typ) ;
      assert (not (Z.is_false data))
  | _ -> assert true
@ -186,11 +187,11 @@ let rec simplify {us; xs; cong; pure; heap; djns} =
 (** Quantification and Vocabulary *)
 let rename_seg sub ({loc; bas; len; siz; arr} as h) =
-  let loc = Exp.rename sub loc in
+  let loc = Term.rename sub loc in
-  let bas = Exp.rename sub bas in
+  let bas = Term.rename sub bas in
-  let len = Exp.rename sub len in
+  let len = Term.rename sub len in
-  let siz = Exp.rename sub siz in
+  let siz = Term.rename sub siz in
-  let arr = Exp.rename sub arr in
+  let arr = Term.rename sub arr in
  ( if
    loc == h.loc && bas == h.bas && len == h.len && siz == h.siz
    && arr == h.arr
@ -203,7 +204,7 @@ let rename_seg sub ({loc; bas; len; siz; arr} as h) =
    invariant *)
 let rec apply_subst sub ({us= _; xs= _; cong; pure; heap; djns} as q) =
  let cong = Equality.rename cong sub in
-  let pure = List.map_preserving_phys_equal pure ~f:(Exp.rename sub) in
+  let pure = List.map_preserving_phys_equal pure ~f:(Term.rename sub) in
  let heap = List.map_preserving_phys_equal heap ~f:(rename_seg sub) in
  let djns =
    List.map_preserving_phys_equal djns ~f:(fun d ->
@ -375,10 +376,10 @@ let or_ q1 q2 =
    invariant q ;
    assert (Set.equal q.us (Set.union q1.us q2.us))]
-let rec pure (e : Exp.t) =
+let rec pure (e : Term.t) =
-  [%Trace.call fun {pf} -> pf "%a" Exp.pp e]
+  [%Trace.call fun {pf} -> pf "%a" Term.pp e]
  ;
-  let us = Exp.fv e in
+  let us = Term.fv e in
  ( match e with
  | Integer {data; typ= Integer {bits= 1}} ->
      if Z.is_false data then false_ us else emp
@ -388,7 +389,7 @@ let rec pure (e : Exp.t) =
    ->
      or_
        (star (pure cnd) (pure thn))
-        (star (pure (Exp.not_ Typ.bool cnd)) (pure els))
+        (star (pure (Term.not_ Typ.bool cnd)) (pure els))
  | App {op= App {op= Eq; arg= e1}; arg= e2} ->
      let cong = Equality.(and_eq e1 e2 true_) in
      if Equality.is_false cong then false_ us
@ -401,7 +402,7 @@ let and_ e q = star (pure e) q
 let seg pt =
  let us = fv_seg pt in
-  if Exp.equal Exp.null pt.loc then false_ us
+  if Term.equal Term.null pt.loc then false_ us
  else {emp with us; heap= [pt]} |> check invariant
 (** Update *)
@ -423,9 +424,10 @@ let is_emp = function
 let is_false = function
  | {djns= [[]]; _} -> true
  | {cong; pure; heap; _} ->
-      List.exists pure ~f:(fun b -> Exp.is_false (Equality.normalize cong b))
+      List.exists pure ~f:(fun b ->
          Term.is_false (Equality.normalize cong b) )
      || List.exists heap ~f:(fun seg ->
-             Equality.entails_eq cong seg.loc Exp.null )
+             Equality.entails_eq cong seg.loc Term.null )
 let rec pure_approx ({us; xs; cong; pure; heap= _; djns} as q) =
  let heap = emp.heap in
--- a/sledge/src/symbheap/sh.mli
+++ b/sledge/src/symbheap/sh.mli
@ -11,13 +11,13 @@
    size [siz], contained in an enclosing allocation-block starting at [bas]
    of length [len]. Byte-array expressions are either [Var]iables or
    [Splat] vectors. *)
-type seg = {loc: Exp.t; bas: Exp.t; len: Exp.t; siz: Exp.t; arr: Exp.t}
+type seg = {loc: Term.t; bas: Term.t; len: Term.t; siz: Term.t; arr: Term.t}
 type starjunction = private
  { us: Var.Set.t  (** vocabulary / variable context of formula *)
  ; xs: Var.Set.t  (** existentially-bound variables *)
  ; cong: Equality.t  (** congruence induced by rest of formula *)
-  ; pure: Exp.t list  (** conjunction of pure boolean constraints *)
+  ; pure: Term.t list  (** conjunction of pure boolean constraints *)
  ; heap: seg list  (** star-conjunction of segment atomic formulas *)
  ; djns: disjunction list  (** star-conjunction of disjunctions *) }
@ -25,7 +25,7 @@ and disjunction = starjunction list
 type t = starjunction [@@deriving equal, compare, sexp]
-val pp_seg : ?is_x:(Exp.t -> bool) -> seg pp
+val pp_seg : ?is_x:(Term.t -> bool) -> seg pp
 val pp_seg_norm : Equality.t -> seg pp
 val pp_us : ?pre:('a, 'a) fmt -> Var.Set.t pp
 val pp : t pp
@ -53,10 +53,10 @@ val or_ : t -> t -> t
 (** Disjoin formulas, extending to a common vocabulary, and avoiding
    capturing existentials. *)
-val pure : Exp.t -> t
+val pure : Term.t -> t
 (** Atomic pure boolean constraint formula. *)
-val and_ : Exp.t -> t -> t
+val and_ : Term.t -> t -> t
 (** Conjoin a boolean constraint to a formula. *)
 val and_cong : Equality.t -> t -> t
@ -65,7 +65,7 @@ val and_cong : Equality.t -> t -> t
 (** Update *)
-val with_pure : Exp.t list -> t -> t
+val with_pure : Term.t list -> t -> t
 (** [with_pure pure q] is [{q with pure}], which assumes that [q.pure] and
    [pure] are defined in the same vocabulary, induce the same congruence,
    etc. It can essentially only be used when [pure] is logically equivalent
--- a/sledge/src/symbheap/sh_domain.ml
+++ b/sledge/src/symbheap/sh_domain.ml
@ -19,29 +19,38 @@ let report_fmt_thunk = Fn.flip pp
 let init globals =
  Vector.fold globals ~init:Sh.emp ~f:(fun q -> function
-    | {Global.var; init= Some (arr, siz)} ->
+    | {Global.reg; init= Some (arr, siz)} ->
-        let loc = Exp.var var in
+        let loc = Term.var (Var.of_reg reg) in
-        let len = Exp.integer (Z.of_int siz) Typ.siz in
+        let len = Term.integer (Z.of_int siz) Typ.siz in
        let arr = Term.of_exp arr in
        Sh.star q (Sh.seg {loc; bas= loc; len; siz= len; arr})
    | _ -> q )
 let join l r = Some (Sh.or_ l r)
 let is_false = Sh.is_false
-let exec_assume = Exec.assume
+let exec_assume q b = Exec.assume q (Term.of_exp b)
-let exec_kill = Exec.kill
+let exec_kill q r = Exec.kill q (Var.of_reg r)
-let exec_move = Exec.move
+let exec_move q r e = Exec.move q (Var.of_reg r) (Term.of_exp e)
 let exec_inst = Exec.inst
-let exec_intrinsic = Exec.intrinsic
+
 let exec_intrinsic ~skip_throw q r i es =
  Exec.intrinsic ~skip_throw q
    (Option.map ~f:Var.of_reg r)
    (Var.of_reg i)
    (List.map ~f:Term.of_exp es)
 let dnf = Sh.dnf
-let exp_eq_class_has_only_vars_in fvs cong exp =
+let term_eq_class_has_only_vars_in fvs cong term =
  [%Trace.call fun {pf} ->
-    pf "@[<v> fvs: @[%a@] @,cong: @[%a@] @,exp: @[%a@]@]" Var.Set.pp fvs
+    pf "@[<v> fvs: @[%a@] @,cong: @[%a@] @,term: @[%a@]@]" Var.Set.pp fvs
-      Equality.pp cong Exp.pp exp]
+      Equality.pp cong Term.pp term]
  ;
-  let exp_has_only_vars_in fvs exp = Set.is_subset (Exp.fv exp) ~of_:fvs in
+  let term_has_only_vars_in fvs term =
-  let exp_eq_class = Equality.class_of cong exp in
+    Set.is_subset (Term.fv term) ~of_:fvs
-  List.exists ~f:(exp_has_only_vars_in fvs) exp_eq_class
+  in
  let term_eq_class = Equality.class_of cong term in
  List.exists ~f:(term_has_only_vars_in fvs) term_eq_class
  |>
  [%Trace.retn fun {pf} -> pf "%b"]
@ -55,16 +64,16 @@ let garbage_collect (q : t) ~wrt =
    else
      let new_set =
        List.fold ~init:current q.heap ~f:(fun current seg ->
-            if exp_eq_class_has_only_vars_in current q.cong seg.loc then
+            if term_eq_class_has_only_vars_in current q.cong seg.loc then
              List.fold (Equality.class_of q.cong seg.arr) ~init:current
-                ~f:(fun c e -> Set.union c (Exp.fv e))
+                ~f:(fun c e -> Set.union c (Term.fv e))
            else current )
      in
      all_reachable_vars current new_set q
  in
  let r_vars = all_reachable_vars Var.Set.empty wrt q in
  Sh.filter_heap q ~f:(fun seg ->
-      exp_eq_class_has_only_vars_in r_vars q.cong seg.loc )
+      term_eq_class_has_only_vars_in r_vars q.cong seg.loc )
  |>
  [%Trace.retn fun {pf} -> pf "%a" pp]
@ -79,15 +88,19 @@ let call ~summaries ~globals actuals areturn formals ~locals q =
    pf
      "@[<hv>actuals: (@[%a@])@ formals: (@[%a@])@ locals: {@[%a@]}@ \
       globals: {@[%a@]}@ q: %a@]"
-      (List.pp ",@ " Exp.pp) (List.rev actuals) (List.pp ",@ " Var.pp)
+      (List.pp ",@ " Exp.pp) (List.rev actuals) (List.pp ",@ " Reg.pp)
-      (List.rev formals) Var.Set.pp locals Var.Set.pp globals pp q]
+      (List.rev formals) Reg.Set.pp locals Reg.Set.pp globals pp q]
  ;
  let actuals = List.map ~f:Term.of_exp actuals in
  let areturn = Option.map ~f:Var.of_reg areturn in
  let formals = List.map ~f:Var.of_reg formals in
  let locals = Var.Set.of_regs locals in
  let q', freshen_locals =
    Sh.freshen q ~wrt:(Set.add_list formals locals)
  in
  let and_eq q formal actual =
-    let actual' = Exp.rename freshen_locals actual in
+    let actual' = Term.rename freshen_locals actual in
-    Sh.and_ (Exp.eq (Exp.var formal) actual') q
+    Sh.and_ (Term.eq (Term.var formal) actual') q
  in
  let and_eqs formals actuals q =
    List.fold2_exn ~f:and_eq formals actuals ~init:q
@ -101,7 +114,8 @@ let call ~summaries ~globals actuals areturn formals ~locals q =
       them *)
    let formals_set = Var.Set.of_list formals in
    let function_summary_pre =
-      garbage_collect q'' ~wrt:(Set.union formals_set globals)
+      garbage_collect q''
        ~wrt:(Set.union formals_set (Var.Set.of_regs globals))
    in
    [%Trace.info "function summary pre %a" pp function_summary_pre] ;
    let foot = Sh.exists formals_set function_summary_pre in
@ -124,8 +138,9 @@ let recursion_beyond_bound = `prune
 (** Leave scope of locals: existentially quantify locals. *)
 let post locals _ q =
  [%Trace.call fun {pf} ->
-    pf "@[<hv>locals: {@[%a@]}@ q: %a@]" Var.Set.pp locals Sh.pp q]
+    pf "@[<hv>locals: {@[%a@]}@ q: %a@]" Reg.Set.pp locals Sh.pp q]
  ;
  let locals = Var.Set.of_regs locals in
  Sh.exists locals q
  |>
  [%Trace.retn fun {pf} -> pf "%a" Sh.pp]
@ -136,13 +151,15 @@ let post locals _ q =
 let retn formals freturn {areturn; subst; frame} q =
  [%Trace.call fun {pf} ->
    pf "@[<v>formals: {@[%a@]}@ subst: %a@ q: %a@ frame: %a@]"
-      (List.pp ", " Var.pp) formals Var.Subst.pp (Var.Subst.invert subst) pp
+      (List.pp ", " Reg.pp) formals Var.Subst.pp (Var.Subst.invert subst) pp
      q pp frame]
  ;
  let formals = List.map ~f:Var.of_reg formals in
  let freturn = Option.map ~f:Var.of_reg freturn in
  let q =
    match (areturn, freturn) with
-    | Some areturn, Some freturn -> exec_move q areturn (Exp.var freturn)
+    | Some areturn, Some freturn -> Exec.move q areturn (Term.var freturn)
-    | Some areturn, None -> exec_kill q areturn
+    | Some areturn, None -> Exec.kill q areturn
    | _ -> q
  in
  let q = Sh.exists (Set.add_list formals (Var.Set.of_option freturn)) q in
@ -152,8 +169,8 @@ let retn formals freturn {areturn; subst; frame} q =
  [%Trace.retn fun {pf} -> pf "%a" pp]
 let resolve_callee lookup ptr q =
-  match Var.of_exp ptr with
+  match Reg.of_exp ptr with
-  | Some callee -> (lookup (Var.name callee), q)
+  | Some callee -> (lookup (Reg.name callee), q)
  | None -> ([], q)
 type summary = {xs: Var.Set.t; foot: t; post: t}
@ -164,16 +181,18 @@ let pp_summary fs {xs; foot; post} =
 let create_summary ~locals ~formals ~entry ~current:(post : Sh.t) =
  [%Trace.call fun {pf} ->
-    pf "formals %a@ entry: %a@ current: %a" Var.Set.pp formals pp entry pp
+    pf "formals %a@ entry: %a@ current: %a" Reg.Set.pp formals pp entry pp
      post]
  ;
  let locals = Var.Set.of_regs locals in
  let formals = Var.Set.of_regs formals in
  let foot = Sh.exists locals entry in
  let foot, subst = Sh.freshen ~wrt:(Set.union foot.us post.us) foot in
  let restore_formals q =
    Set.fold formals ~init:q ~f:(fun q var ->
-        let var = Exp.var var in
+        let var = Term.var var in
-        let renamed_var = Exp.rename subst var in
+        let renamed_var = Term.rename subst var in
-        Sh.and_ (Exp.eq renamed_var var) q )
+        Sh.and_ (Term.eq renamed_var var) q )
  in
  (* Add back the original formals name *)
  let post = Sh.rename subst post in
@ -227,11 +246,11 @@ let%test_module _ =
    let n_, wrt = Var.fresh "n" ~wrt
    let b_, wrt = Var.fresh "b" ~wrt
    let end_, _ = Var.fresh "end" ~wrt
-    let a = Exp.var a_
+    let a = Term.var a_
-    let main = Exp.var main_
+    let main = Term.var main_
-    let b = Exp.var b_
+    let b = Term.var b_
-    let n = Exp.var n_
+    let n = Term.var n_
-    let endV = Exp.var end_
+    let endV = Term.var end_
    let seg_main = Sh.seg {loc= main; bas= b; len= n; siz= n; arr= a}
    let seg_a = Sh.seg {loc= a; bas= b; len= n; siz= n; arr= endV}
    let seg_cycle = Sh.seg {loc= a; bas= b; len= n; siz= n; arr= main}
--- a/sledge/src/symbheap/sh_domain.mli
+++ b/sledge/src/symbheap/sh_domain.mli
@ -10,10 +10,10 @@
 include Domain_sig.Dom
 (* formals should include all the parameters of the summary. That is both
-   formals and globals.*)
+   formals and globals. *)
 val create_summary :
-     locals:Var.Set.t
+     locals:Reg.Set.t
-  -> formals:Var.Set.t
+  -> formals:Reg.Set.t
  -> entry:t
  -> current:t
  -> summary * t
--- a/sledge/src/symbheap/sh_test.ml
+++ b/sledge/src/symbheap/sh_test.ml
@ -13,13 +13,13 @@ let%test_module _ =
    let pp = Format.printf "@\n%a@." Sh.pp
    let pp_djn = Format.printf "@\n%a@." Sh.pp_djn
    let ( ~$ ) = Var.Set.of_list
-    let ( ! ) i = Exp.integer (Z.of_int i) Typ.siz
+    let ( ! ) i = Term.integer (Z.of_int i) Typ.siz
-    let ( = ) = Exp.eq
+    let ( = ) = Term.eq
    let wrt = Var.Set.empty
    let x_, wrt = Var.fresh "x" ~wrt
    let y_, _ = Var.fresh "y" ~wrt
-    let x = Exp.var x_
+    let x = Term.var x_
-    let y = Exp.var y_
+    let y = Term.var y_
    let%expect_test _ =
      let p = Sh.(exists ~$[x_] (extend_us ~$[x_] emp)) in
--- a/sledge/src/symbheap/solver.ml
+++ b/sledge/src/symbheap/solver.ml
@ -44,15 +44,15 @@ let fresh_var name vs zs ~wrt =
  let v, wrt = Var.fresh name ~wrt in
  let vs = Set.add vs v in
  let zs = Set.add zs v in
-  let v = Exp.var v in
+  let v = Term.var v in
  (v, vs, zs, wrt)
 type occurrences = Zero | One of Var.t | Many
-let single_existential_occurrence xs exp =
+let single_existential_occurrence xs term =
  let exception Multiple_existential_occurrences in
  try
-    Exp.fold_vars exp ~init:Zero ~f:(fun seen var ->
+    Term.fold_vars term ~init:Zero ~f:(fun seen var ->
        if not (Set.mem xs var) then seen
        else
          match seen with
@ -61,32 +61,32 @@ let single_existential_occurrence xs exp =
  with Multiple_existential_occurrences -> Many
 let special_cases xs = function
-  | Exp.App {op= App {op= Eq; arg= Var _}; arg= Var _} as e ->
+  | Term.App {op= App {op= Eq; arg= Var _}; arg= Var _} as e ->
-      if Set.is_subset (Exp.fv e) ~of_:xs then Exp.bool true else e
+      if Set.is_subset (Term.fv e) ~of_:xs then Term.bool true else e
  | e -> e
-let excise_exp ({us; min; xs} as goal) pure exp =
+let excise_term ({us; min; xs} as goal) pure term =
-  let exp' = Equality.normalize min.cong exp in
+  let term' = Equality.normalize min.cong term in
-  let exp' = special_cases xs exp' in
+  let term' = special_cases xs term' in
-  [%Trace.info "exp': %a" Exp.pp exp'] ;
+  [%Trace.info "term': %a" Term.pp term'] ;
-  if Exp.is_true exp' then Some ({goal with pgs= true}, pure)
+  if Term.is_true term' then Some ({goal with pgs= true}, pure)
  else
-    match single_existential_occurrence xs exp' with
+    match single_existential_occurrence xs term' with
    | Zero -> None
    | One x ->
        Some
          ( { goal with
              us= Set.add us x
-            ; min= Sh.and_ exp' min
+            ; min= Sh.and_ term' min
            ; xs= Set.remove xs x
            ; pgs= true }
          , pure )
-    | Many -> Some (goal, exp' :: pure)
+    | Many -> Some (goal, term' :: pure)
 let excise_pure ({sub} as goal) =
  [%Trace.info "@[<2>excise_pure@ %a@]" pp goal] ;
-  List.fold_option sub.pure ~init:(goal, []) ~f:(fun (goal, pure) exp ->
+  List.fold_option sub.pure ~init:(goal, []) ~f:(fun (goal, pure) term ->
-      excise_exp goal pure exp )
+      excise_term goal pure term )
  >>| fun (goal, pure) -> {goal with sub= Sh.with_pure pure sub}
 (*   [k; o)
@ -111,8 +111,8 @@ let excise_seg_same ({com; min; sub} as goal) msg ssg =
  let com = Sh.star (Sh.seg msg) com in
  let min = Sh.rem_seg msg min in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m') (Sh.and_ (Exp.eq a a') (Sh.rem_seg ssg sub)))
+      (Sh.and_ (Term.eq m m') (Sh.and_ (Term.eq a a') (Sh.rem_seg ssg sub)))
  in
  {goal with com; min; sub}
@ -136,24 +136,24 @@ let excise_seg_sub_prefix ({us; com; min; xs; sub; zs} as goal) msg ssg o_n
      msg (Sh.pp_seg_norm sub.cong) ssg pp goal] ;
  let {Sh.loc= k; bas= b; len= m; siz= o; arr= a} = msg in
  let {Sh.bas= b'; len= m'; siz= n; arr= a'} = ssg in
-  let o_n = Exp.integer o_n Typ.siz in
+  let o_n = Term.integer o_n Typ.siz in
  let a0, us, zs, wrt = fresh_var "a0" us zs ~wrt:(Set.union us xs) in
  let a1, us, zs, _ = fresh_var "a1" us zs ~wrt in
  let com = Sh.star (Sh.seg {msg with siz= n; arr= a0}) com in
  let min =
    Sh.and_
-      (Exp.eq
+      (Term.eq
-         (Exp.memory ~siz:o ~arr:a)
+         (Term.memory ~siz:o ~arr:a)
-         (Exp.concat
+         (Term.concat
-            [|Exp.memory ~siz:n ~arr:a0; Exp.memory ~siz:o_n ~arr:a1|]))
+            [|Term.memory ~siz:n ~arr:a0; Term.memory ~siz:o_n ~arr:a1|]))
      (Sh.star
         (Sh.seg
-            {loc= Exp.add Typ.ptr k n; bas= b; len= m; siz= o_n; arr= a1})
+            {loc= Term.add Typ.ptr k n; bas= b; len= m; siz= o_n; arr= a1})
         (Sh.rem_seg msg min))
  in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m') (Sh.and_ (Exp.eq a0 a') (Sh.rem_seg ssg sub)))
+      (Sh.and_ (Term.eq m m') (Sh.and_ (Term.eq a0 a') (Sh.rem_seg ssg sub)))
  in
  {goal with us; com; min; sub; zs}
@ -178,21 +178,22 @@ let excise_seg_min_prefix ({us; com; min; xs; sub; zs} as goal) msg ssg n_o
      msg (Sh.pp_seg_norm sub.cong) ssg pp goal] ;
  let {Sh.bas= b; len= m; siz= o; arr= a} = msg in
  let {Sh.loc= l; bas= b'; len= m'; siz= n; arr= a'} = ssg in
-  let n_o = Exp.integer n_o Typ.siz in
+  let n_o = Term.integer n_o Typ.siz in
  let com = Sh.star (Sh.seg msg) com in
  let min = Sh.rem_seg msg min in
  let a1', xs, zs, _ = fresh_var "a1" xs zs ~wrt:(Set.union us xs) in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m')
+      (Sh.and_ (Term.eq m m')
         (Sh.and_
-            (Exp.eq
+            (Term.eq
-               (Exp.concat
+               (Term.concat
-                  [|Exp.memory ~siz:o ~arr:a; Exp.memory ~siz:n_o ~arr:a1'|])
+                  [| Term.memory ~siz:o ~arr:a
-               (Exp.memory ~siz:n ~arr:a'))
+                   ; Term.memory ~siz:n_o ~arr:a1' |])
               (Term.memory ~siz:n ~arr:a'))
            (Sh.star
               (Sh.seg
-                  { loc= Exp.add Typ.ptr l o
+                  { loc= Term.add Typ.ptr l o
                  ; bas= b'
                  ; len= m'
                  ; siz= n_o
@ -221,7 +222,7 @@ let excise_seg_sub_suffix ({us; com; min; xs; sub; zs} as goal) msg ssg l_k
      msg (Sh.pp_seg_norm sub.cong) ssg pp goal] ;
  let {Sh.loc= k; bas= b; len= m; siz= o; arr= a} = msg in
  let {Sh.loc= l; bas= b'; len= m'; siz= n; arr= a'} = ssg in
-  let l_k = Exp.integer l_k Typ.siz in
+  let l_k = Term.integer l_k Typ.siz in
  let a0, us, zs, wrt = fresh_var "a0" us zs ~wrt:(Set.union us xs) in
  let a1, us, zs, _ = fresh_var "a1" us zs ~wrt in
  let com =
@ -229,17 +230,17 @@ let excise_seg_sub_suffix ({us; com; min; xs; sub; zs} as goal) msg ssg l_k
  in
  let min =
    Sh.and_
-      (Exp.eq
+      (Term.eq
-         (Exp.memory ~siz:o ~arr:a)
+         (Term.memory ~siz:o ~arr:a)
-         (Exp.concat
+         (Term.concat
-            [|Exp.memory ~siz:l_k ~arr:a0; Exp.memory ~siz:n ~arr:a1|]))
+            [|Term.memory ~siz:l_k ~arr:a0; Term.memory ~siz:n ~arr:a1|]))
      (Sh.star
         (Sh.seg {loc= k; bas= b; len= m; siz= l_k; arr= a0})
         (Sh.rem_seg msg min))
  in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m') (Sh.and_ (Exp.eq a1 a') (Sh.rem_seg ssg sub)))
+      (Sh.and_ (Term.eq m m') (Sh.and_ (Term.eq a1 a') (Sh.rem_seg ssg sub)))
  in
  {goal with us; com; min; sub; zs}
@ -264,8 +265,9 @@ let excise_seg_sub_infix ({us; com; min; xs; sub; zs} as goal) msg ssg l_k
      msg (Sh.pp_seg_norm sub.cong) ssg pp goal] ;
  let {Sh.loc= k; bas= b; len= m; siz= o; arr= a} = msg in
  let {Sh.loc= l; bas= b'; len= m'; siz= n; arr= a'} = ssg in
-  let l_k = Exp.integer l_k Typ.siz and ko_ln = Exp.integer ko_ln Typ.siz in
+  let l_k = Term.integer l_k Typ.siz
-  let ln = Exp.add Typ.ptr l n in
+  and ko_ln = Term.integer ko_ln Typ.siz in
  let ln = Term.add Typ.ptr l n in
  let a0, us, zs, wrt = fresh_var "a0" us zs ~wrt:(Set.union us xs) in
  let a1, us, zs, wrt = fresh_var "a1" us zs ~wrt in
  let a2, us, zs, _ = fresh_var "a2" us zs ~wrt in
@ -274,12 +276,12 @@ let excise_seg_sub_infix ({us; com; min; xs; sub; zs} as goal) msg ssg l_k
  in
  let min =
    Sh.and_
-      (Exp.eq
+      (Term.eq
-         (Exp.memory ~siz:o ~arr:a)
+         (Term.memory ~siz:o ~arr:a)
-         (Exp.concat
+         (Term.concat
-            [| Exp.memory ~siz:l_k ~arr:a0
+            [| Term.memory ~siz:l_k ~arr:a0
-             ; Exp.memory ~siz:n ~arr:a1
+             ; Term.memory ~siz:n ~arr:a1
-             ; Exp.memory ~siz:ko_ln ~arr:a2 |]))
+             ; Term.memory ~siz:ko_ln ~arr:a2 |]))
      (Sh.star
         (Sh.seg {loc= k; bas= b; len= m; siz= l_k; arr= a0})
         (Sh.star
@ -287,8 +289,8 @@ let excise_seg_sub_infix ({us; com; min; xs; sub; zs} as goal) msg ssg l_k
            (Sh.rem_seg msg min)))
  in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m') (Sh.and_ (Exp.eq a1 a') (Sh.rem_seg ssg sub)))
+      (Sh.and_ (Term.eq m m') (Sh.and_ (Term.eq a1 a') (Sh.rem_seg ssg sub)))
  in
  {goal with us; com; min; sub; zs}
@ -313,10 +315,10 @@ let excise_seg_min_skew ({us; com; min; xs; sub; zs} as goal) msg ssg l_k
      msg (Sh.pp_seg_norm sub.cong) ssg pp goal] ;
  let {Sh.loc= k; bas= b; len= m; siz= o; arr= a} = msg in
  let {Sh.loc= l; bas= b'; len= m'; siz= n; arr= a'} = ssg in
-  let l_k = Exp.integer l_k Typ.siz in
+  let l_k = Term.integer l_k Typ.siz in
-  let ko_l = Exp.integer ko_l Typ.siz in
+  let ko_l = Term.integer ko_l Typ.siz in
-  let ln_ko = Exp.integer ln_ko Typ.siz in
+  let ln_ko = Term.integer ln_ko Typ.siz in
-  let ko = Exp.add Typ.ptr k o in
+  let ko = Term.add Typ.ptr k o in
  let a0, us, zs, wrt = fresh_var "a0" us zs ~wrt:(Set.union us xs) in
  let a1, us, zs, wrt = fresh_var "a1" us zs ~wrt in
  let a2', xs, zs, _ = fresh_var "a2" xs zs ~wrt in
@ -325,23 +327,23 @@ let excise_seg_min_skew ({us; com; min; xs; sub; zs} as goal) msg ssg l_k
  in
  let min =
    Sh.and_
-      (Exp.eq
+      (Term.eq
-         (Exp.memory ~siz:o ~arr:a)
+         (Term.memory ~siz:o ~arr:a)
-         (Exp.concat
+         (Term.concat
-            [|Exp.memory ~siz:l_k ~arr:a0; Exp.memory ~siz:ko_l ~arr:a1|]))
+            [|Term.memory ~siz:l_k ~arr:a0; Term.memory ~siz:ko_l ~arr:a1|]))
      (Sh.star
         (Sh.seg {loc= k; bas= b; len= m; siz= l_k; arr= a0})
         (Sh.rem_seg msg min))
  in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m')
+      (Sh.and_ (Term.eq m m')
         (Sh.and_
-            (Exp.eq
+            (Term.eq
-               (Exp.concat
+               (Term.concat
-                  [| Exp.memory ~siz:ko_l ~arr:a1
+                  [| Term.memory ~siz:ko_l ~arr:a1
-                   ; Exp.memory ~siz:ln_ko ~arr:a2' |])
+                   ; Term.memory ~siz:ln_ko ~arr:a2' |])
-               (Exp.memory ~siz:n ~arr:a'))
+               (Term.memory ~siz:n ~arr:a'))
            (Sh.star
               (Sh.seg {loc= ko; bas= b'; len= m'; siz= ln_ko; arr= a2'})
               (Sh.rem_seg ssg sub))))
@ -369,18 +371,19 @@ let excise_seg_min_suffix ({us; com; min; xs; sub; zs} as goal) msg ssg k_l
      msg (Sh.pp_seg_norm sub.cong) ssg pp goal] ;
  let {Sh.bas= b; len= m; siz= o; arr= a} = msg in
  let {Sh.loc= l; bas= b'; len= m'; siz= n; arr= a'} = ssg in
-  let k_l = Exp.integer k_l Typ.siz in
+  let k_l = Term.integer k_l Typ.siz in
  let a0', xs, zs, _ = fresh_var "a0" xs zs ~wrt:(Set.union us xs) in
  let com = Sh.star (Sh.seg msg) com in
  let min = Sh.rem_seg msg min in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m')
+      (Sh.and_ (Term.eq m m')
         (Sh.and_
-            (Exp.eq
+            (Term.eq
-               (Exp.concat
+               (Term.concat
-                  [|Exp.memory ~siz:k_l ~arr:a0'; Exp.memory ~siz:o ~arr:a|])
+                  [| Term.memory ~siz:k_l ~arr:a0'
-               (Exp.memory ~siz:n ~arr:a'))
+                   ; Term.memory ~siz:o ~arr:a |])
               (Term.memory ~siz:n ~arr:a'))
            (Sh.star
               (Sh.seg {loc= l; bas= b'; len= m'; siz= k_l; arr= a0'})
               (Sh.rem_seg ssg sub))))
@ -409,23 +412,23 @@ let excise_seg_min_infix ({us; com; min; xs; sub; zs} as goal) msg ssg k_l
      msg (Sh.pp_seg_norm sub.cong) ssg pp goal] ;
  let {Sh.loc= k; bas= b; len= m; siz= o; arr= a} = msg in
  let {Sh.loc= l; bas= b'; len= m'; siz= n; arr= a'} = ssg in
-  let k_l = Exp.integer k_l Typ.siz in
+  let k_l = Term.integer k_l Typ.siz in
-  let ln_ko = Exp.integer ln_ko Typ.siz in
+  let ln_ko = Term.integer ln_ko Typ.siz in
-  let ko = Exp.add Typ.ptr k o in
+  let ko = Term.add Typ.ptr k o in
  let a0', xs, zs, wrt = fresh_var "a0" xs zs ~wrt:(Set.union us xs) in
  let a2', xs, zs, _ = fresh_var "a2" xs zs ~wrt in
  let com = Sh.star (Sh.seg msg) com in
  let min = Sh.rem_seg msg min in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m')
+      (Sh.and_ (Term.eq m m')
         (Sh.and_
-            (Exp.eq
+            (Term.eq
-               (Exp.concat
+               (Term.concat
-                  [| Exp.memory ~siz:k_l ~arr:a0'
+                  [| Term.memory ~siz:k_l ~arr:a0'
-                   ; Exp.memory ~siz:o ~arr:a
+                   ; Term.memory ~siz:o ~arr:a
-                   ; Exp.memory ~siz:ln_ko ~arr:a2' |])
+                   ; Term.memory ~siz:ln_ko ~arr:a2' |])
-               (Exp.memory ~siz:n ~arr:a'))
+               (Term.memory ~siz:n ~arr:a'))
            (Sh.star
               (Sh.seg {loc= l; bas= b'; len= m'; siz= k_l; arr= a0'})
               (Sh.star
@ -455,10 +458,10 @@ let excise_seg_sub_skew ({us; com; min; xs; sub; zs} as goal) msg ssg k_l
      msg (Sh.pp_seg_norm sub.cong) ssg pp goal] ;
  let {Sh.loc= k; bas= b; len= m; siz= o; arr= a} = msg in
  let {Sh.loc= l; bas= b'; len= m'; siz= n; arr= a'} = ssg in
-  let k_l = Exp.integer k_l Typ.siz in
+  let k_l = Term.integer k_l Typ.siz in
-  let ln_k = Exp.integer ln_k Typ.siz in
+  let ln_k = Term.integer ln_k Typ.siz in
-  let ko_ln = Exp.integer ko_ln Typ.siz in
+  let ko_ln = Term.integer ko_ln Typ.siz in
-  let ln = Exp.add Typ.ptr l n in
+  let ln = Term.add Typ.ptr l n in
  let a0', xs, zs, wrt = fresh_var "a0" xs zs ~wrt:(Set.union us xs) in
  let a1, us, zs, wrt = fresh_var "a1" us zs ~wrt in
  let a2, us, zs, _ = fresh_var "a2" us zs ~wrt in
@ -467,23 +470,23 @@ let excise_seg_sub_skew ({us; com; min; xs; sub; zs} as goal) msg ssg k_l
  in
  let min =
    Sh.and_
-      (Exp.eq
+      (Term.eq
-         (Exp.memory ~siz:o ~arr:a)
+         (Term.memory ~siz:o ~arr:a)
-         (Exp.concat
+         (Term.concat
-            [|Exp.memory ~siz:ln_k ~arr:a1; Exp.memory ~siz:ko_ln ~arr:a2|]))
+            [|Term.memory ~siz:ln_k ~arr:a1; Term.memory ~siz:ko_ln ~arr:a2|]))
      (Sh.star
         (Sh.seg {loc= ln; bas= b; len= m; siz= ko_ln; arr= a2})
         (Sh.rem_seg msg min))
  in
  let sub =
-    Sh.and_ (Exp.eq b b')
+    Sh.and_ (Term.eq b b')
-      (Sh.and_ (Exp.eq m m')
+      (Sh.and_ (Term.eq m m')
         (Sh.and_
-            (Exp.eq
+            (Term.eq
-               (Exp.concat
+               (Term.concat
-                  [| Exp.memory ~siz:k_l ~arr:a0'
+                  [| Term.memory ~siz:k_l ~arr:a0'
-                   ; Exp.memory ~siz:ln_k ~arr:a1 |])
+                   ; Term.memory ~siz:ln_k ~arr:a1 |])
-               (Exp.memory ~siz:n ~arr:a'))
+               (Term.memory ~siz:n ~arr:a'))
            (Sh.star
               (Sh.seg {loc= l; bas= b'; len= m'; siz= k_l; arr= a0'})
               (Sh.rem_seg ssg sub))))
@ -504,13 +507,14 @@ let excise_seg ({sub} as goal) msg ssg =
    || not (Equality.entails_eq sub.cong m m')
  then
    Some
-      {goal with sub= Sh.and_ (Exp.eq b b') (Sh.and_ (Exp.eq m m') goal.sub)}
+      { goal with
        sub= Sh.and_ (Term.eq b b') (Sh.and_ (Term.eq m m') goal.sub) }
  else
    match[@warning "-p"] Z.sign k_l with
    (* k-l < 0 so k < l *)
    | -1 -> (
-        let ko = Exp.add Typ.ptr k o in
+        let ko = Term.add Typ.ptr k o in
-        let ln = Exp.add Typ.ptr l n in
+        let ln = Term.add Typ.ptr l n in
        Equality.difference sub.cong ko ln
        >>= fun ko_ln ->
        match[@warning "-p"] Z.sign ko_ln with
@ -535,7 +539,7 @@ let excise_seg ({sub} as goal) msg ssg =
    (* k-l = 0 so k = l *)
    | 0 -> (
      match Equality.difference sub.cong o n with
-      | None -> Some {goal with sub= Sh.and_ (Exp.eq o n) goal.sub}
+      | None -> Some {goal with sub= Sh.and_ (Term.eq o n) goal.sub}
      | Some o_n -> (
        match[@warning "-p"] Z.sign o_n with
        (* o-n < 0      [k; o)
@ -549,8 +553,8 @@ let excise_seg ({sub} as goal) msg ssg =
        | 1 -> Some (excise_seg_sub_prefix goal msg ssg o_n) ) )
    (* k-l > 0 so k > l *)
    | 1 -> (
-        let ko = Exp.add Typ.ptr k o in
+        let ko = Term.add Typ.ptr k o in
-        let ln = Exp.add Typ.ptr l n in
+        let ln = Term.add Typ.ptr l n in
        Equality.difference sub.cong ko ln
        >>= fun ko_ln ->
        match[@warning "-p"] Z.sign ko_ln with
--- a/sledge/src/symbheap/solver_test.ml
+++ b/sledge/src/symbheap/solver_test.ml
@ -22,10 +22,10 @@ let%test_module _ =
      Solver.infer_frame p (Var.Set.of_list xs) q
      |> fun r -> assert (Option.is_some r)
-    let ( ! ) i = Exp.integer (Z.of_int i) Typ.siz
+    let ( ! ) i = Term.integer (Z.of_int i) Typ.siz
-    let ( + ) = Exp.add Typ.ptr
+    let ( + ) = Term.add Typ.ptr
-    let ( - ) = Exp.sub Typ.siz
+    let ( - ) = Term.sub Typ.siz
-    let ( * ) = Exp.mul Typ.siz
+    let ( * ) = Term.mul Typ.siz
    let wrt = Var.Set.empty
    let a_, wrt = Var.fresh "a" ~wrt
    let a2_, wrt = Var.fresh "a" ~wrt
@ -36,15 +36,15 @@ let%test_module _ =
    let l2_, wrt = Var.fresh "l" ~wrt
    let m_, wrt = Var.fresh "m" ~wrt
    let n_, _ = Var.fresh "n" ~wrt
-    let a = Exp.var a_
+    let a = Term.var a_
-    let a2 = Exp.var a2_
+    let a2 = Term.var a2_
-    let a3 = Exp.var a3_
+    let a3 = Term.var a3_
-    let b = Exp.var b_
+    let b = Term.var b_
-    let k = Exp.var k_
+    let k = Term.var k_
-    let l = Exp.var l_
+    let l = Term.var l_
-    let l2 = Exp.var l2_
+    let l2 = Term.var l2_
-    let m = Exp.var m_
+    let m = Term.var m_
-    let n = Exp.var n_
+    let n = Term.var n_
    let%expect_test _ =
      check_frame Sh.emp [] Sh.emp ;
@ -61,7 +61,7 @@ let%test_module _ =
        ) infer_frame:   false |}]
    let%expect_test _ =
-      check_frame Sh.emp [n_; m_] (Sh.and_ (Exp.eq m n) Sh.emp) ;
+      check_frame Sh.emp [n_; m_] (Sh.and_ (Term.eq m n) Sh.emp) ;
      [%expect
        {|
        ( infer_frame:   emp \- ∃ %m_8, %n_9 .   %m_8 = %n_9 ∧ emp
@ -93,7 +93,7 @@ let%test_module _ =
      let seg1 = Sh.seg {loc= l; bas= b; len= !10; siz= !10; arr= a} in
      let minued = Sh.star common seg1 in
      let subtrahend =
-        Sh.and_ (Exp.eq m n)
+        Sh.and_ (Term.eq m n)
          (Sh.exists
             (Var.Set.of_list [m_])
             (Sh.extend_us (Var.Set.of_list [m_]) common))
@ -235,7 +235,7 @@ let%test_module _ =
    let%expect_test _ =
      check_frame
        (Sh.and_
-           Exp.(or_ (or_ (eq n !0) (eq n !1)) (eq n !2))
+           Term.(or_ (or_ (eq n !0) (eq n !1)) (eq n !2))
           seg_split_symbolically)
        [m_; a_]
        (Sh.seg {loc= l; bas= l; len= m; siz= m; arr= a}) ;
@ -272,7 +272,7 @@ let%test_module _ =
    (* Incompleteness: equivalent to above but using ≤ instead of ∨ *)
    let%expect_test _ =
      infer_frame
-        (Sh.and_ (Exp.le n !2) seg_split_symbolically)
+        (Sh.and_ (Term.le n !2) seg_split_symbolically)
        [m_; a_]
        (Sh.seg {loc= l; bas= l; len= m; siz= m; arr= a}) ;
      [%expect
--- a/sledge/src/symbheap/term.ml
+++ b/sledge/src/symbheap/term.ml
--- a/sledge/src/symbheap/term.mli
+++ b/sledge/src/symbheap/term.mli
@ -0,0 +1,219 @@
 (*
 * 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.
 *)
 (** Terms
    Pure (heap-independent) terms are complex arithmetic, bitwise-logical,
    etc. operations over literal values and variables.
    Terms for operations that are uninterpreted in the analyzer are
    represented in curried form, where [App] is an application of a function
    symbol to an argument. This is done to simplify the definition of
    'subterm' and make it explicit. The specific constructor functions
    indicate and check the expected arity of the function symbols. *)
 type comparator_witness
 type qset = (t, comparator_witness) Qset.t
 and t = private
  | Add of {args: qset; typ: Typ.t}  (** Addition *)
  | Mul of {args: qset; typ: Typ.t}  (** Multiplication *)
  | Splat of {byt: t; siz: t}
      (** Iterated concatenation of a single byte *)
  | Memory of {siz: t; arr: t}  (** Size-tagged byte-array *)
  | Concat of {args: t vector}  (** Byte-array concatenation *)
  | Var of {id: int; name: string}  (** Local variable / virtual register *)
  | Nondet of {msg: string}
      (** Anonymous local variable with arbitrary value, representing
          non-deterministic approximation of value described by [msg] *)
  | Label of {parent: string; name: string}
      (** Address of named code block within parent function *)
  | App of {op: t; arg: t}
      (** Application of function symbol to argument, curried *)
  | Eq  (** Equal test *)
  | Dq  (** Disequal test *)
  | Gt  (** Greater-than test *)
  | Ge  (** Greater-than-or-equal test *)
  | Lt  (** Less-than test *)
  | Le  (** Less-than-or-equal test *)
  | Ugt  (** Unsigned greater-than test *)
  | Uge  (** Unsigned greater-than-or-equal test *)
  | Ult  (** Unsigned less-than test *)
  | Ule  (** Unsigned less-than-or-equal test *)
  | Ord  (** Ordered test (neither arg is nan) *)
  | Uno  (** Unordered test (some arg is nan) *)
  | Div  (** Division *)
  | Udiv  (** Unsigned division *)
  | Rem  (** Remainder of division *)
  | Urem  (** Remainder of unsigned division *)
  | And  (** Conjunction, boolean or bitwise *)
  | Or  (** Disjunction, boolean or bitwise *)
  | Xor  (** Exclusive-or, bitwise *)
  | Shl  (** Shift left, bitwise *)
  | Lshr  (** Logical shift right, bitwise *)
  | Ashr  (** Arithmetic shift right, bitwise *)
  | Conditional  (** If-then-else *)
  | Record  (** Record (array / struct) constant *)
  | Select  (** Select an index from a record *)
  | Update  (** Constant record with updated index *)
  | Struct_rec of {elts: t vector}
      (** Struct constant that may recursively refer to itself
          (transitively) from [elts]. NOTE: represented by cyclic values. *)
  | Convert of {signed: bool; dst: Typ.t; src: Typ.t}
      (** Convert between specified types, possibly with loss of information *)
  | Integer of {data: Z.t; typ: Typ.t}
      (** Integer constant, or if [typ] is a [Pointer], null pointer value
          that never refers to an object *)
  | Float of {data: string}  (** Floating-point constant *)
 [@@deriving compare, equal, hash, sexp]
 val comparator : (t, comparator_witness) Comparator.t
 type term = t
 val pp_full : ?is_x:(term -> bool) -> t pp
 val pp : t pp
 val invariant : ?partial:bool -> t -> unit
 (** Term.Var is re-exported as Var *)
 module Var : sig
  type t = private term [@@deriving compare, equal, hash, sexp]
  type var = t
  include Comparator.S with type t := t
  module Set : sig
    type t = (var, comparator_witness) Set.t
    [@@deriving compare, equal, sexp]
    val pp_full : ?is_x:(term -> bool) -> t pp
    val pp : t pp
    val empty : t
    val of_option : var option -> t
    val of_list : var list -> t
    val of_vector : var vector -> t
    val of_regs : Reg.Set.t -> t
  end
  module Map : sig
    type 'a t = (var, 'a, comparator_witness) Map.t
    [@@deriving compare, equal, sexp]
    val empty : 'a t
  end
  val pp : t pp
  val pp_demangled : t pp
  include Invariant.S with type t := t
  val of_reg : Reg.t -> t
  val of_term : term -> t option
  val program : string -> t
  val fresh : string -> wrt:Set.t -> t * Set.t
  val id : t -> int
  val name : t -> string
  module Subst : sig
    type t [@@deriving compare, equal, sexp]
    val pp : t pp
    val empty : t
    val freshen : Set.t -> wrt:Set.t -> t
    val extend : t -> replace:var -> with_:var -> t
    val invert : t -> t
    val exclude : t -> Set.t -> t
    val restrict : t -> Set.t -> t
    val is_empty : t -> bool
    val domain : t -> Set.t
    val range : t -> Set.t
    val apply_set : t -> Set.t -> Set.t
    val close_set : t -> Set.t -> Set.t
  end
 end
 (** Construct *)
 val of_exp : Exp.t -> t
 val var : Var.t -> t
 val nondet : string -> t
 val label : parent:string -> name:string -> t
 val null : t
 val splat : byt:t -> siz:t -> t
 val memory : siz:t -> arr:t -> t
 val concat : t array -> t
 val bool : bool -> t
 val integer : Z.t -> Typ.t -> t
 val rational : Q.t -> Typ.t -> t
 val float : string -> t
 val eq : t -> t -> t
 val dq : t -> t -> t
 val gt : t -> t -> t
 val ge : t -> t -> t
 val lt : t -> t -> t
 val le : t -> t -> t
 val ugt : t -> t -> t
 val uge : t -> t -> t
 val ult : t -> t -> t
 val ule : t -> t -> t
 val ord : t -> t -> t
 val uno : t -> t -> t
 val neg : Typ.t -> t -> t
 val add : Typ.t -> t -> t -> t
 val sub : Typ.t -> t -> t -> t
 val mul : Typ.t -> t -> t -> t
 val div : t -> t -> t
 val udiv : t -> t -> t
 val rem : t -> t -> t
 val urem : t -> t -> t
 val and_ : t -> t -> t
 val or_ : t -> t -> t
 val xor : t -> t -> t
 val not_ : Typ.t -> t -> t
 val shl : t -> t -> t
 val lshr : t -> t -> t
 val ashr : t -> t -> t
 val conditional : cnd:t -> thn:t -> els:t -> t
 val record : t list -> t
 val select : rcd:t -> idx:t -> t
 val update : rcd:t -> elt:t -> idx:t -> t
 val struct_rec :
     (module Hashtbl.Key with type t = 'id)
  -> (id:'id -> t lazy_t vector -> t) Staged.t
 (** [struct_rec Id id element_thunks] constructs a possibly-cyclic [Struct]
    value. Cycles are detected using [Id]. The caller of [struct_rec Id]
    must ensure that a single unstaging of [struct_rec Id] is used for each
    complete cyclic value. Also, the caller must ensure that recursive calls
    to [struct_rec Id] provide [id] values that uniquely identify at least
    one point on each cycle. Failure to obey these requirements will lead to
    stack overflow. *)
 val convert : ?signed:bool -> dst:Typ.t -> src:Typ.t -> t -> t
 val size_of : Typ.t -> t option
 (** Access *)
 val iter : t -> f:(t -> unit) -> unit
 val fold_vars : t -> init:'a -> f:('a -> Var.t -> 'a) -> 'a
 val fold_terms : t -> init:'a -> f:('a -> t -> 'a) -> 'a
 val fold : t -> init:'a -> f:(t -> 'a -> 'a) -> 'a
 (** Transform *)
 val map : t -> f:(t -> t) -> t
 val rename : Var.Subst.t -> t -> t
 (** Query *)
 val fv : t -> Var.Set.t
 val is_true : t -> bool
 val is_false : t -> bool
 val typ : t -> Typ.t option
 val classify : t -> [> `Atomic | `Interpreted | `Simplified | `Uninterpreted]
 val solve : t -> t -> (t, t, comparator_witness) Map.t option
--- a/sledge/src/symbheap/term_test.ml
+++ b/sledge/src/symbheap/term_test.ml
@ -9,48 +9,50 @@ let%test_module _ =
  ( module struct
    (* let () = Trace.init ~margin:68 ~config:all () *)
    let () = Trace.init ~margin:68 ~config:none ()
-    let pp = Format.printf "@\n%a@." Exp.pp
+    let pp = Format.printf "@\n%a@." Term.pp
    let char = Typ.integer ~bits:8
-    let ( ! ) i = Exp.integer (Z.of_int i) char
+    let ( ! ) i = Term.integer (Z.of_int i) char
-    let ( + ) = Exp.add char
+    let ( + ) = Term.add char
-    let ( - ) = Exp.sub char
+    let ( - ) = Term.sub char
-    let ( * ) = Exp.mul char
+    let ( * ) = Term.mul char
-    let ( = ) = Exp.eq
+    let ( = ) = Term.eq
-    let ( != ) = Exp.dq
+    let ( != ) = Term.dq
-    let ( > ) = Exp.gt
+    let ( > ) = Term.gt
-    let ( >= ) = Exp.ge
+    let ( >= ) = Term.ge
-    let ( < ) = Exp.lt
+    let ( < ) = Term.lt
-    let ( <= ) = Exp.le
+    let ( <= ) = Term.le
-    let ( && ) = Exp.and_
+    let ( && ) = Term.and_
-    let ( || ) = Exp.or_
+    let ( || ) = Term.or_
-    let ( ~~ ) = Exp.not_ Typ.bool
+    let ( ~~ ) = Term.not_ Typ.bool
    let wrt = Var.Set.empty
    let y_, wrt = Var.fresh "y" ~wrt
    let z_, _ = Var.fresh "z" ~wrt
-    let y = Exp.var y_
+    let y = Term.var y_
-    let z = Exp.var z_
+    let z = Term.var z_
    let%test "booleans distinct" =
-      Exp.is_false
+      Term.is_false
-        (Exp.eq
+        (Term.eq
-           (Exp.integer Z.minus_one Typ.bool)
+           (Term.integer Z.minus_one Typ.bool)
-           (Exp.integer Z.zero Typ.bool))
+           (Term.integer Z.zero Typ.bool))
    let%test "unsigned booleans distinct" =
-      Exp.is_false
+      Term.is_false
-        (Exp.eq (Exp.integer Z.one Typ.bool) (Exp.integer Z.zero Typ.bool))
+        (Term.eq
           (Term.integer Z.one Typ.bool)
           (Term.integer Z.zero Typ.bool))
    let%test "boolean overflow" =
-      Exp.is_true
+      Term.is_true
-        (Exp.eq
+        (Term.eq
-           (Exp.integer Z.minus_one Typ.bool)
+           (Term.integer Z.minus_one Typ.bool)
-           (Exp.integer Z.one Typ.bool))
+           (Term.integer Z.one Typ.bool))
    let%test "unsigned boolean overflow" =
-      Exp.is_true
+      Term.is_true
-        (Exp.uge
+        (Term.uge
-           (Exp.integer Z.minus_one Typ.bool)
+           (Term.integer Z.minus_one Typ.bool)
-           (Exp.integer Z.one Typ.bool))
+           (Term.integer Z.one Typ.bool))
    let%expect_test _ =
      pp (!42 + !13) ;
@ -176,19 +178,19 @@ let%test_module _ =
      [%expect {| 0 |}]
    let%expect_test _ =
-      pp (!3 * y = z = Exp.bool true) ;
+      pp (!3 * y = z = Term.bool true) ;
      [%expect {| ((3 × %y_1) = %z_2) |}]
    let%expect_test _ =
-      pp (Exp.bool true = (!3 * y = z)) ;
+      pp (Term.bool true = (!3 * y = z)) ;
      [%expect {| ((3 × %y_1) = %z_2) |}]
    let%expect_test _ =
-      pp (!3 * y = z = Exp.bool false) ;
+      pp (!3 * y = z = Term.bool false) ;
      [%expect {| ((3 × %y_1) ≠ %z_2) |}]
    let%expect_test _ =
-      pp (Exp.bool false = (!3 * y = z)) ;
+      pp (Term.bool false = (!3 * y = z)) ;
      [%expect {| ((3 × %y_1) ≠ %z_2) |}]
    let%expect_test _ =
@ -208,11 +210,11 @@ let%test_module _ =
      [%expect {| ((-3 × %y_1 + 4) = %y_1) |}]
    let%expect_test _ =
-      pp (Exp.sub Typ.bool (Exp.bool true) (z = !4)) ;
+      pp (Term.sub Typ.bool (Term.bool true) (z = !4)) ;
      [%expect {| (-1 × (%z_2 = 4) + -1) |}]
    let%expect_test _ =
-      pp (Exp.add Typ.bool (Exp.bool true) (z = !4) = (z = !4)) ;
+      pp (Term.add Typ.bool (Term.bool true) (z = !4) = (z = !4)) ;
      [%expect {| (((%z_2 = 4) + -1) = (%z_2 = 4)) |}]
    let%expect_test _ =
@ -244,9 +246,9 @@ let%test_module _ =
      [%expect {| ((%y_1 < 2) && (%z_2 ≥ 3)) |}]
    let%expect_test _ =
-      pp Exp.(eq z null) ;
+      pp Term.(eq z null) ;
-      pp Exp.(eq null z) ;
+      pp Term.(eq null z) ;
-      pp Exp.(dq (eq null z) (bool false)) ;
+      pp Term.(dq (eq null z) (bool false)) ;
      [%expect
        {|
        (%z_2 = null)
--- a/sledge/src/symbheap/term_test.mli
+++ b/sledge/src/symbheap/term_test.mli
--- a/sledge/src/symbheap/var.ml
+++ b/sledge/src/symbheap/var.ml
@ -7,4 +7,4 @@
 (** Variables *)
-include Exp.Var
+include Term.Var
--- a/sledge/src/symbheap/var.mli
+++ b/sledge/src/symbheap/var.mli
@ -7,4 +7,4 @@
 (** Variables *)
-include module type of Exp.Var
+include module type of Term.Var
`@ -7,4 +7,4 @@`

	`(** Used-globals abstract domain *)`	`(** Used-globals abstract domain *)`

	`include Domain_sig.Dom with type summary = Var.Set.t`	`include Domain_sig.Dom with type summary = Reg.Set.t`
`@ -7,4 +7,4 @@`

	`(** Variables *)`	`(** Variables *)`

	`include Exp.Var`	`include Term.Var`