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// RUN: %dafny /compile:0 /print:"%t.print" /dprint:"%t.dprint" "%s" > "%t"
// RUN: %diff "%s.expect" "%t"
// --------------------------------------------------
module CoRecursion {
codatatype Stream<T> = More(head: T, rest: Stream);
function AscendingChain(n: int): Stream<int>
{
More(n, AscendingChain(n+1))
}
function AscendingChainAndRead(n: nat): Stream<int>
reads this; // with a reads clause, this function is not a co-recusvie function
{
More(n, AscendingChainAndRead(n+1)) // error: cannot prove termination
}
function AscendingChainAndPostcondition(n: nat): Stream<int>
ensures false; // with an ensures clause, this function is not a co-recusvie function
{
More(n, AscendingChainAndPostcondition(n+1)) // error: cannot prove termination
}
datatype List<T> = Nil | Cons(T, List);
function Prefix(n: nat, s: Stream): List
{
if n == 0 then Nil else
Cons(s.head, Prefix(n-1, s.rest))
}
}
// --------------------------------------------------
module CoRecursionNotUsed {
codatatype Stream<T> = More(T, Stream);
function F(s: Stream, n: nat): Stream
decreases n, true;
{
G(s, n)
}
function G(s: Stream, n: nat): Stream
decreases n, false;
{
if n == 0 then s else Tail(F(s, n-1))
}
function Tail(s: Stream): Stream
{
match s case More(hd, tl) => tl
}
function Diverge(n: nat): nat
{
Diverge(n) // error: cannot prove termination
}
}
// --------------------------------------------------
module EqualityIsSuperDestructive {
codatatype Stream<T> = Cons(head: T, tail: Stream)
function F(s: Stream<int>): Stream<int>
{
// Co-recursive calls are not allowed in arguments of equality, so the following call to
// F(s) is a recursive call.
if Cons(1, F(s)) == Cons(1, Cons(1, s)) // error: cannot prove termination
then Cons(2, s) else Cons(1, s)
}
lemma Lemma(s: Stream<int>)
{
// The following three assertions follow from the definition of F, so F had better
// generate some error (which it does -- the recursive call to F in F does not terminate).
assert F(s) == Cons(1, s);
assert F(s) == Cons(2, s);
assert false;
}
}
// --------------------------------------------------
module MixRecursiveAndCorecursive {
codatatype Stream<T> = Cons(head: T, tail: Stream)
function F(n: nat): Stream<int>
{
if n == 0 then
Cons(0, F(5)) // error: cannot prove termination -- by itself, this would look like a properly guarded co-recursive call...
else
F(n - 1).tail // but the fact that this recursive call is not tail recursive means that call in the 'then' branch is not
// allowed to be a co-recursive
}
// same thing but with some mutual recursion going on
function G(n: nat): Stream<int>
{
if n == 0 then
Cons(0, H(5)) // error: cannot prove termination
else
H(n)
}
function H(n: nat): Stream<int>
requires n != 0;
decreases n, 0;
{
G(n-1).tail
}
// but if all the recursive calls are tail recursive, then all is cool
function X(n: nat): Stream<int>
{
if n == 0 then
Cons(0, Y(5)) // error: cannot prove termination
else
Y(n)
}
function Y(n: nat): Stream<int>
requires n != 0;
decreases n, 0;
{
X(n-1)
}
}
// --------------------------------------------------
module FunctionSCCsWithMethods {
codatatype Stream<T> = Cons(head: T, tail: Stream)
lemma M(n: nat)
decreases n, 0;
{
if n != 0 {
var p := Cons(10, F(n-1));
}
}
function F(n: nat): Stream<int>
decreases n;
{
M(n);
// the following call to F is not considered co-recursive, because the SCC contains a method
Cons(5, F(n)) // error: cannot prove termination
}
function G(): Stream<int>
{
Lemma();
H()
}
function H(): Stream<int>
decreases 0;
{
// the following call to G is not considered co-recursive, because the SCC contains a method
Cons(5, G()) // error: cannot prove termination
}
lemma Lemma()
decreases 1;
{
var h := H();
}
}
// --------------------------------------------------
module AutomaticPrefixingOfCoClusterDecreasesClauses {
codatatype Stream<T> = Cons(head: T, tail: Stream)
// The following three functions will verify automatically
function H(): Stream<int> // automatic: decreases 1;
{
F(true)
}
function F(b: bool): Stream<int> // automatic: decreases 0, b;
{
if b then Cons(5, G()) else Cons(7, H())
}
function G(): Stream<int> // automatic: decreases 1;
{
F(false)
}
// In the following, A gets a default decreases clause of 1, because
// the only recursive call to A is a self-call. B, on the other
// hand, has a mutually recursive call from A, and therefore it gets
// a decreases clause of 0.
function A(n: nat): Stream<int> // automatic: decreases 1, n;
{
if n < 100 then
B(n) // the automatic decreases clauses take care of the termination of this call
else
A(n - 1) // termination proved on account of decreasing 1,n
}
function B(n: nat): Stream<int> // automatic: decreases 0, n;
{
if n < 100 then
Cons(n, A(n + 102)) // co-recursive call, so no termination check
else
B(n - 1) // termination proved on account of decreasing 0,n
}
}
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