Variations on Semantics of Programming Languages
This example provides solutions to exercises proposed by Olivier Danvy. It proposes several variations around different ways of defining the semantics of a language. It is presented in the paper Formalizing semantics with an automatic program verifier.
Auteurs: Claude Marché / Martin Clochard
Catégories: Semantics of languages / Inductive predicates
Outils: Why3
see also the index (by topic, by tool, by reference, by year)
Defunctionalization
This is inspired from student exercises proposed by Olivier Danvy at the JFLA 2014 conference
Simple Arithmetic Expressions
module Expr use export int.Int
Grammar of expressions
n : int e : expression e ::= n | e - e p : program p ::= e
type expr = Cte int | Sub expr expr type prog = expr
Examples:
p0 = 0 p1 = 10 - 6 p2 = (10 - 6) - (7 - 2) p3 = (7 - 2) - (10 - 6) p4 = 10 - (2 - 3)
let constant p0 : prog = Cte 0 let constant p1 : prog = Sub (Cte 10) (Cte 6) let constant p2 : prog = Sub (Sub (Cte 10) (Cte 6)) (Sub (Cte 7) (Cte 2)) let constant p3 : prog = Sub (Sub (Cte 7) (Cte 2)) (Sub (Cte 10) (Cte 6)) let constant p4 : prog = Sub (Cte 10) (Sub (Cte 2) (Cte 3)) end
Direct Semantics
module DirectSem use Expr
Values:
Expressible Values:v : value v ::= n
Interpretation:ve : expressible_value ve ::= v
------
n => n
e1 => n1 e2 => n2 n1 - n2 = n3
----------------------------------
e1 - e2 => n3
holds.e => n
Exercise 0.0
Program the interpreter above and test it on the examples.
eval_0 : expression -> expressible_value interpret_0 : program -> expressible_value
(* Note: Why3 definitions introduced by "function" belong to the logic part of Why3 language *) let rec function eval_0 (e:expr) : int = match e with | Cte n -> n | Sub e1 e2 -> eval_0 e1 - eval_0 e2 end let function interpret_0 (p:prog) : int = eval_0 p
Tests, can be replayed using
(Why3 version at least 0.82 required)why3 defunctionalization.mlw --exec DirectSem.test
let test () = interpret_0 p0, interpret_0 p1, interpret_0 p2, interpret_0 p3, interpret_0 p4 constant v3 : int = eval_0 p3 goal eval_p3 : v3 = 1 end
CPS: Continuation Passing Style
module CPS use Expr
Exercise 0.1
CPS-transform (call by value, left to right) the function eval_0,
and call it from the main interpreter with the identity function as
initial continuation
eval_1 : expression -> (expressible_value -> 'a) -> 'a
interpret_1 : program -> expressible_value
use DirectSem let rec eval_1 (e:expr) (k: int->'a) : 'a variant { e } ensures { result = k (eval_0 e) } = match e with | Cte n -> k n | Sub e1 e2 -> eval_1 e1 (fun v1 -> eval_1 e2 (fun v2 -> k (v1 - v2))) end let interpret_1 (p : prog) : int ensures { result = eval_0 p } = eval_1 p (fun n -> n) end
Defunctionalization
module Defunctionalization use Expr use DirectSem
Exercise 0.2
De-functionalize the continuation of eval_1.
cont ::= ...
continue_2 : cont -> value -> value
eval_2 : expression -> cont -> value
interpret_2 : program -> value
cont represents the grammar of contexts.
The two mutually recursive functions eval_2 and continue_2
implement an abstract machine, that is a state transition system.
type cont = A1 expr cont | A2 int cont | I
One would want to write in Why:
function eval_cont (c:cont) (v:int) : int =
match c with
| A1 e2 k ->
let v2 = eval_0 e2 in
eval_cont (A2 v k) v2
| A2 v1 k -> eval_cont k (v1 - v)
| I -> v
end
We replace that with a relational definition, an inductive one.
inductive eval_cont cont int int = | a1 : forall e2:expr, k:cont, v:int, r:int. eval_cont (A2 v k) (eval_0 e2) r -> eval_cont (A1 e2 k) v r | a2 : forall v1:int, k:cont, v:int, r:int. eval_cont k (v1 - v) r -> eval_cont (A2 v1 k) v r | a3 : forall v:int. eval_cont I v v
Some functions to serve as measures for the termination proof
function size_e (e:expr) : int = match e with | Cte _ -> 1 | Sub e1 e2 -> 3 + size_e e1 + size_e e2 end lemma size_e_pos: forall e: expr. size_e e >= 1 function size_c (c:cont) : int = match c with | I -> 0 | A1 e2 k -> 2 + size_e e2 + size_c k | A2 _ k -> 1 + size_c k end lemma size_c_pos: forall c: cont. size_c c >= 0
WhyML programs (declared with let instead of function),
mutually recursive, resulting from de-functionalization
let rec continue_2 (c:cont) (v:int) : int variant { size_c c } ensures { eval_cont c v result } = match c with | A1 e2 k -> eval_2 e2 (A2 v k) | A2 v1 k -> continue_2 k (v1 - v) | I -> v end with eval_2 (e:expr) (c:cont) : int variant { size_c c + size_e e } ensures { eval_cont c (eval_0 e) result } = match e with | Cte n -> continue_2 c n | Sub e1 e2 -> eval_2 e1 (A1 e2 c) end
The interpreter. The post-condition specifies that this program
computes the same thing as eval_0
let interpret_2 (p:prog) : int ensures { result = eval_0 p } = eval_2 p I let test () = interpret_2 p0, interpret_2 p1, interpret_2 p2, interpret_2 p3, interpret_2 p4 end
Defunctionalization with an algebraic variant
module Defunctionalization2 use Expr use DirectSem
Exercise 0.2
De-functionalize the continuation of eval_1.
cont ::= ...
continue_2 : cont -> value -> value
eval_2 : expression -> cont -> value
interpret_2 : program -> value
cont represents the grammar of contexts.
The two mutually recursive functions eval_2 and continue_2
implement an abstract machine, that is a state transition system.
type cont = A1 expr cont | A2 int cont | I
One would want to write in Why:
function eval_cont (c:cont) (v:int) : int =
match c with
| A1 e2 k ->
let v2 = eval_0 e2 in
eval_cont (A2 v k) v2
| A2 v1 k -> eval_cont k (v1 - v)
| I -> v
end
We replace that with a relational definition, an inductive one.
inductive eval_cont cont int int = | a1 : forall e2:expr, k:cont, v:int, r:int. eval_cont (A2 v k) (eval_0 e2) r -> eval_cont (A1 e2 k) v r | a2 : forall v1:int, k:cont, v:int, r:int. eval_cont k (v1 - v) r -> eval_cont (A2 v1 k) v r | a3 : forall v:int. eval_cont I v v
Peano naturals to serve as the measure for the termination proof
type nat = S nat | O function size_e (e:expr) (acc:nat) : nat = match e with | Cte _ -> S acc | Sub e1 e2 -> S (size_e e1 (S (size_e e2 (S acc)))) end function size_c (c:cont) (acc:nat) : nat = match c with | I -> acc | A1 e2 k -> S (size_e e2 (S (size_c k acc))) | A2 _ k -> S (size_c k acc) end
WhyML programs (declared with let instead of function),
mutually recursive, resulting from de-functionalization
let rec continue_2 (c:cont) (v:int) : int variant { size_c c O } ensures { eval_cont c v result } = match c with | A1 e2 k -> eval_2 e2 (A2 v k) | A2 v1 k -> continue_2 k (v1 - v) | I -> v end with eval_2 (e:expr) (c:cont) : int variant { size_e e (size_c c O) } ensures { eval_cont c (eval_0 e) result } = match e with | Cte n -> continue_2 c n | Sub e1 e2 -> eval_2 e1 (A1 e2 c) end
The interpreter. The post-condition specifies that this program
computes the same thing as eval_0
let interpret_2 (p:prog) : int ensures { result = eval_0 p } = eval_2 p I let test () = interpret_2 p0, interpret_2 p1, interpret_2 p2, interpret_2 p3, interpret_2 p4 end
Semantics with errors
module SemWithError use Expr
Errors:
Expressible values:s : error
ve : expressible_value ve ::= v | s
type value = Vnum int | Underflow (* in (Vnum n), n should always be >= 0 *)
Interpretation:
------
n => n
e1 => s
------------
e1 - e2 => s
e1 => n1 e2 => s
------------------
e1 - e2 => s
e1 => n1 e2 => n2 n1 < n2
-----------------------------
e1 - e2 => "underflow"
e1 => n1 e2 => n2 n1 >= n2 n1 - n2 = n3
---------------------------------------------
e1 - e2 => n3
e into value n if the judgement
holds, and into errore => n
s if the judgement
holds.e => s
Exercise 1.0
Program the interpreter above and test it on the examples.
eval_0 : expr -> expressible_value interpret_0 : program -> expressible_value
function eval_0 (e:expr) : value = match e with | Cte n -> if n >= 0 then Vnum n else Underflow | Sub e1 e2 -> match eval_0 e1 with | Underflow -> Underflow | Vnum v1 -> match eval_0 e2 with | Underflow -> Underflow | Vnum v2 -> if v1 >= v2 then Vnum (v1 - v2) else Underflow end end end function interpret_0 (p:prog) : value = eval_0 p
Exercise 1.1
CPS-transform (call by value, from left to right)
the function eval_0, call it from the main interpreter
with the identity function as initial continuation.
eval_1 : expr -> (expressible_value -> 'a) -> 'a
interpret_1 : program -> expressible_value
function eval_1 (e:expr) (k:value -> 'a) : 'a = match e with | Cte n -> k (if n >= 0 then Vnum n else Underflow) | Sub e1 e2 -> eval_1 e1 (fun v1 -> match v1 with | Underflow -> k Underflow | Vnum v1 -> eval_1 e2 (fun v2 -> match v2 with | Underflow -> k Underflow | Vnum v2 -> k (if v1 >= v2 then Vnum (v1 - v2) else Underflow) end) end) end function interpret_1 (p : prog) : value = eval_1 p (fun n -> n) lemma cps_correct_expr: forall e: expr. forall k:value -> 'a. eval_1 e k = k (eval_0 e) lemma cps_correct: forall p. interpret_1 p = interpret_0 p
Exercise 1.2
Divide the continuation
expressible_value -> 'a
(value -> 'a) * (error -> 'a)
eval_1 and interpret_1 as
eval_2 : expr -> (value -> 'a) -> (error -> 'a) -> 'a
interpret_2 : program -> expressible_value
(* function eval_2 (e:expr) (k:int -> 'a) (kerr: unit -> 'a) : 'a = match e with | Cte n -> if n >= 0 then k n else kerr () | Sub e1 e2 -> eval_2 e1 (fun v1 -> eval_2 e2 (fun v2 -> if v1 >= v2 then k (v1 - v2) else kerr ()) kerr) kerr end *) function eval_2 (e:expr) (k:int -> 'a) (kerr: unit -> 'a) : 'a = match e with | Cte n -> if n >= 0 then k n else kerr () | Sub e1 e2 -> eval_2 e1 (eval_2a e2 k kerr) kerr end with eval_2a (e2:expr) (k:int -> 'a) (kerr : unit -> 'a) : int -> 'a = (fun v1 -> eval_2 e2 (eval_2b v1 k kerr) kerr) with eval_2b (v1:int) (k:int -> 'a) (kerr : unit -> 'a) : int -> 'a = (fun v2 -> if v1 >= v2 then k (v1 - v2) else kerr ()) function interpret_2 (p : prog) : value = eval_2 p (fun n -> Vnum n) (fun _ -> Underflow) lemma cps2_correct_expr_aux: forall k: int -> 'a, e1 e2, kerr: unit -> 'a. eval_2 (Sub e1 e2) k kerr = eval_2 e1 (eval_2a e2 k kerr) kerr lemma cps2_correct_expr: forall e, kerr: unit->'a, k:int -> 'a. eval_2 e k kerr = match eval_0 e with Vnum n -> k n | Underflow -> kerr () end lemma cps2_correct: forall p. interpret_2 p = interpret_0 p
Exercise 1.3
Specialize the codomain of the continuations and of the evaluation function
so that it is not polymorphic anymore but is expressible_value, and
then short-circuit the second continuation to stop in case of error
eval_3 : expr -> (value -> expressible_value) -> expressible_value
interpret_3 : program -> expressible_value
function eval_3 (e:expr) (k:int -> value) : value = match e with | Cte n -> if n >= 0 then k n else Underflow | Sub e1 e2 -> eval_3 e1 (eval_3a e2 k) end with eval_3a (e2:expr) (k:int -> value) : int -> value = (fun v1 -> eval_3 e2 (eval_3b v1 k)) with eval_3b (v1:int) (k:int -> value) : int -> value = (fun v2 -> if v1 >= v2 then k (v1 - v2) else Underflow) function interpret_3 (p : prog) : value = eval_3 p (fun n -> Vnum n) let rec lemma cps3_correct_expr (e:expr) : unit variant { e } ensures { forall k. eval_3 e k = match eval_0 e with Vnum n -> k n | Underflow -> Underflow end } = match e with | Cte _ -> () | Sub e1 e2 -> cps3_correct_expr e1; cps3_correct_expr e2; assert {forall k. eval_3 e k = eval_3 e1 (eval_3a e2 k) } end lemma cps3_correct: forall p. interpret_3 p = interpret_0 p
Exercise 1.4
De-functionalize the continuation of eval_3.
cont ::= ...
continue_4 : cont -> value -> expressible_value
eval_4 : expr -> cont -> expressible_value
interprete_4 : program -> expressible_value
cont represents the grammar of contexts.
(NB. has it changed w.r.t to previous exercise?)
The two mutually recursive functions eval_4 and continue_4
implement an abstract machine, that is a transition system that
stops immediately in case of error, or and the end of computation.
type cont = I | A expr cont | B int cont end </pre></blockquote>} But since the recursion is not structural, Why3 kernel rejects it (definitions in the logic part of the language must be total)
One would want to write in Why:
function eval_cont (c:cont) (v:value) : value = match v with | Underflow -> Underflow | Vnum v -> match c with | A e2 k -> eval_cont (B (Vnum v) k) (eval_0 e2) | B v1 k -> eval_cont k (if v1 >= v then Vnum (v1 - v) else Underflow) | I -> Vnum v (* v >= 0 by construction
We replace that with a relational definition, an inductive one. *) inductive eval_cont cont value value = | underflow : forall k:cont. eval_cont k Underflow Underflow | a1 : forall e2:expr, k:cont, v:int, r:value. eval_cont (B v k) (eval_0 e2) r -> eval_cont (A e2 k) (Vnum v) r | a2 : forall v1:int, k:cont, v:int, r:value. eval_cont k (if v1 >= v then Vnum (v1 - v) else Underflow) r -> eval_cont (B v1 k) (Vnum v) r | a3 : forall v:int. eval_cont I (Vnum v) (Vnum v)
Some functions to serve as measures for the termination proof
function size_e (e:expr) : int = match e with | Cte _ -> 1 | Sub e1 e2 -> 3 + size_e e1 + size_e e2 end lemma size_e_pos: forall e: expr. size_e e >= 1 use Defunctionalization as D function size_c (c:cont) : int = match c with | I -> 0 | A e2 k -> 2 + D.size_e e2 + size_c k | B _ k -> 1 + size_c k end lemma size_c_pos: forall c: cont. size_c c >= 0 let rec continue_4 (c:cont) (v:int) : value requires { v >= 0 } variant { size_c c } ensures { eval_cont c (Vnum v) result } = match c with | A e2 k -> eval_4 e2 (B v k) | B v1 k -> if v1 >= v then continue_4 k (v1 - v) else Underflow | I -> Vnum v end with eval_4 (e:expr) (c:cont) : value variant { size_c c + D.size_e e } ensures { eval_cont c (eval_0 e) result } = match e with | Cte n -> if n >= 0 then continue_4 c n else Underflow | Sub e1 e2 -> eval_4 e1 (A e2 c) end
The interpreter. The post-condition specifies that this program
computes the same thing as eval_0
let interpret_4 (p:prog) : value ensures { result = eval_0 p } = eval_4 p I let test () = interpret_4 p0, interpret_4 p1, interpret_4 p2, interpret_4 p3, interpret_4 p4 end
Reduction Semantics
module ReductionSemantics
A small step semantics, defined iteratively with reduction contexts
use Expr use DirectSem
Expressions:
n : int e : expression e ::= n | e - e p : program p ::= e
Values:
v : value v ::= n
Potential Redexes:
rp ::= n1 - n2
Reduction Rule:
(in the case of relative integers Z, all potential redexes are true redexes; but for natural numbers, not all of them are true ones:n1 - n2 -> n3
a potential redex that is not a true one is stuck.)n1 - n2 -> n3 if n1 >= n2
Contraction Function:
and if there are only non-negative numbers:contract : redex_potentiel -> expression + stuck contract (n1 - n2) = n3 si n3 = n1 - n2
contract (n1 - n2) = n3 if n1 >= n2 and n3 = n1 - n2 contract (n1 - n2) = stuck if n1 < n2
predicate is_a_redex (e:expr) = match e with | Sub (Cte _) (Cte _) -> true | _ -> false end let contract (e:expr) : expr requires { is_a_redex e } ensures { eval_0 result = eval_0 e } = match e with | Sub (Cte v1) (Cte v2) -> Cte (v1 - v2) | _ -> absurd end
Reduction Contexts:
C : cont C ::= [] | [C e] | [v C]
type context = Empty | Left context expr | Right int context
Recomposition:
recompose : cont * expression -> expression
recompose ([], e) = e
recompose ([C e2], e1) = recompose (C, e1 - e2)
recompose ([n1 C], e2) = recompose (C, n1 - e2)
let rec function recompose (c:context) (e:expr) : expr = match c with | Empty -> e | Left c e2 -> recompose c (Sub e e2) | Right n1 c -> recompose c (Sub (Cte n1) e) end let rec lemma recompose_values (c:context) (e1 e2:expr) : unit requires { eval_0 e1 = eval_0 e2 } variant { c } ensures { eval_0 (recompose c e1) = eval_0 (recompose c e2) } = match c with | Empty -> () | Left c e -> recompose_values c (Sub e1 e) (Sub e2 e) | Right n c -> recompose_values c (Sub (Cte n) e1) (Sub (Cte n) e2) end (* not needed anymore let rec lemma recompose_inversion (c:context) (e:expr) requires { match c with Empty -> false | _ -> true end \/ match e with Cte _ -> false | Sub _ _ -> true end } variant { c } ensures { match recompose c e with Cte _ -> false | Sub _ _ -> true end } = match c with | Empty -> () | Left c e2 -> recompose_inversion c (Sub e e2) | Right n1 c -> recompose_inversion c (Sub (Cte n1) e) end *)
Decomposition:
Decomposition function:dec_or_val = (C, rp) | v
decompose_term : expression * cont -> dec_or_val
decompose_term (n, C) = decompose_cont (C, n)
decompose_term (e1 - e2, C) = decompose_term (e1, [C e2])
decompose_cont : cont * value -> dec_or_val
decompose_cont ([], n) = n
decompose_cont ([C e], n) = decompose_term (e, [n c])
decompose_term ([n1 C], n2) = (C, n1 - n2)
decompose : expression -> dec_or_val
decompose e = decompose_term (e, [])
exception Stuck predicate is_a_value (e:expr) = match e with | Cte _ -> true | _ -> false end predicate is_empty_context (c:context) = match c with | Empty -> true | _ -> false end use Defunctionalization as D (* for size_e *) function size_e (e:expr) : int = D.size_e e function size_c (c:context) : int = match c with | Empty -> 0 | Left c e -> 2 + size_c c + size_e e | Right _ c -> 1 + size_c c end lemma size_c_pos: forall c: context. size_c c >= 0 let rec decompose_term (e:expr) (c:context) : (context, expr) variant { size_e e + size_c c } ensures { let c1,e1 = result in recompose c1 e1 = recompose c e /\ is_a_redex e1 } raises { Stuck -> is_empty_context c /\ is_a_value e } (* raises { Stuck -> is_a_value (recompose c e) } *) = match e with | Cte n -> decompose_cont c n | Sub e1 e2 -> decompose_term e1 (Left c e2) end with decompose_cont (c:context) (n:int) : (context, expr) variant { size_c c } ensures { let c1,e1 = result in recompose c1 e1 = recompose c (Cte n) /\ is_a_redex e1 } raises { Stuck -> is_empty_context c } (* raises { Stuck -> is_a_value (recompose c (Cte n)) } *) = match c with | Empty -> raise Stuck | Left c e -> decompose_term e (Right n c) | Right n1 c -> c, Sub (Cte n1) (Cte n) end let decompose (e:expr) : (context, expr) ensures { let c1,e1 = result in recompose c1 e1 = e /\ is_a_redex e1 } raises { Stuck -> is_a_value e } = decompose_term e Empty
One reduction step:
reduce : expression -> expression + stuck if decompose e = v then reduce e = stuck if decompose e = (C, rp) and contract rp = stuck then reduce e = stuck if decompose e = (C, rp) and contract rp = c then reduce e = recompose (C, c)
Exercise 2.0
Implement the reduction semantics above and test it
let reduce (e:expr) : expr ensures { eval_0 result = eval_0 e } raises { Stuck -> is_a_value e } = let c,r = decompose e in recompose c (contract r)
Evaluation based on iterated reduction:
itere : red_ou_val -> value + erreur itere v = v if contract rp = stuck then itere (C, rp) = stuck if contract rp = c then itere (C, rp) = itere (decompose (recompose (C, c)))
let rec itere (e:expr) : int diverges (* termination could be proved but that's not the point *) ensures { eval_0 e = result } = match reduce e with | e' -> itere e' | exception Stuck -> match e with | Cte n -> n | _ -> absurd end end
Exercise 2.1
Optimize the step recomposition / decomposition
into a single function refocus.
let refocus c e ensures { let c1,e1 = result in recompose c1 e1 = recompose c e /\ is_a_redex e1 } raises { Stuck -> is_empty_context c /\ is_a_value e } = decompose_term e c let rec itere_opt (c:context) (e:expr) : int diverges ensures { result = eval_0 (recompose c e) } = match refocus c e with | c, r -> itere_opt c (contract r) | exception Stuck -> assert { is_empty_context c }; match e with | Cte n -> n | _ -> absurd end end let rec normalize (e:expr) diverges ensures { result = eval_0 e } = itere_opt Empty e
Exercise 2.2
Derive an abstract machine
(c,Cte n)_1 -> (c,n)_2 (c,Sub e1 e2)_1 -> (Left c e2,e1)_1 (Empty,n)_2 -> stop with result = n (Left c e,n)_2 -> (Right n c,e)_1 (Right n1 c,n)_2 -> (c,Cte (n1 - n))_1
let rec eval_1 c e variant { 2 * (size_c c + size_e e) } ensures { result = eval_0 (recompose c e) } = match e with | Cte n -> eval_2 c n | Sub e1 e2 -> eval_1 (Left c e2) e1 end with eval_2 c n variant { 1 + 2 * size_c c } ensures { result = eval_0 (recompose c (Cte n)) } = match c with | Empty -> n | Left c e -> eval_1 (Right n c) e | Right n1 c -> eval_1 c (Cte (n1 - n)) end let interpret p ensures { result = eval_0 p } = eval_1 Empty p let test () = interpret p0, interpret p1, interpret p2, interpret p3, interpret p4 end module RWithError use Expr use SemWithError
Exercise 2.3
An abstract machine for the case with errors
(c,Cte n)_1 -> stop on Underflow if n < 0 (c,Cte n)_1 -> (c,n)_2 if n >= 0 (c,Sub e1 e2)_1 -> (Left c e2,e1)_1 (Empty,n)_2 -> stop on Vnum n (Left c e,n)_2 -> (Right n c,e)_1 (Right n1 c,n)_2 -> stop on Underflow if n1 < n (Right n1 c,n)_2 -> (c,Cte (n1 - n))_1 if n1 >= n
type context = Empty | Left context expr | Right int context use Defunctionalization as D (* for size_e *) function size_e (e:expr) : int = D.size_e e function size_c (c:context) : int = match c with | Empty -> 0 | Left c e -> 2 + size_c c + size_e e | Right _ c -> 1 + size_c c end lemma size_c_pos: forall c: context. size_c c >= 0 function recompose (c:context) (e:expr) : expr = match c with | Empty -> e | Left c e2 -> recompose c (Sub e e2) | Right n1 c -> recompose c (Sub (Cte n1) e) end let rec lemma recompose_values (c:context) (e1 e2:expr) : unit requires { eval_0 e1 = eval_0 e2 } variant { c } ensures { eval_0 (recompose c e1) = eval_0 (recompose c e2) } = match c with | Empty -> () | Left c e -> recompose_values c (Sub e1 e) (Sub e2 e) | Right n c -> recompose_values c (Sub (Cte n) e1) (Sub (Cte n) e2) end let rec lemma recompose_underflow (c:context) (e:expr) : unit requires { eval_0 e = Underflow } variant { c } ensures { eval_0 (recompose c e) = Underflow } = match c with | Empty -> () | Left c e1 -> recompose_underflow c (Sub e e1) | Right n c -> recompose_underflow c (Sub (Cte n) e) end let rec eval_1 c e variant { 2 * (size_c c + size_e e) } ensures { result = eval_0 (recompose c e) } = match e with | Cte n -> if n >= 0 then eval_2 c n else Underflow | Sub e1 e2 -> eval_1 (Left c e2) e1 end with eval_2 c n variant { 1 + 2 * size_c c } requires { n >= 0 } ensures { result = eval_0 (recompose c (Cte n)) } = match c with | Empty -> Vnum n | Left c e -> eval_1 (Right n c) e | Right n1 c -> if n1 >= n then eval_1 c (Cte (n1 - n)) else Underflow end let interpret p ensures { result = eval_0 p } = eval_1 Empty p let test () = interpret p0, interpret p1, interpret p2, interpret p3, interpret p4 end
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