// ---------------------- duplicate types within a module module Wazzup { class WazzupA { } class WazzupA { } // error: duplicate type datatype WazzupA = W_A_X; // error: duplicate type type WazzupA; // error: duplicate type type WazzupB; type WazzupB; // error: duplicate type class WazzupB { } // error: duplicate type datatype WazzupB = W_B_X; // error: duplicate type } // ---------------------- duplicate types across modules module M { class T { } class U { } } module N { class T { } } module U { import NN = N; } module A { // Note, this has the effect of importing two different T's, // but that's okay as long as the module doesn't try to access // one of them import MM = M; import NN = N; class X { var t: MM.T; // error: use of the ambiguous name T function F(x: MM.T): // error: use of the ambiguous name T MM.T // error: use of the ambiguous name T { x } method M(x: NN.T) // error: use of the ambiguous name T returns (y: NN.T) // error: use of the ambiguous name T } } // --------------- calls module X0 { class MyClass0 { method Down() { } method Up(x1: MyClass1, // error: MyClass1 is not in scope x2: MyClass2) { // error: MyClass2 is not in scope } } } module X1 { import X0' = X0; class MyClass1 { method Down(x0: X0'.MyClass0) { x0.Down(); } method Up(x2: MyClass2) { // error: class MyClass2 is not in scope } } } module X2 { class MyClass2 { method Down(x1: MyClass1, x0: MyClass0) { x1.Down(x0); } method WayDown(x0: MyClass0) { x0.Down(); } method Up() { } method Somewhere(y: MyClassY) { y.M(); } } } module YY { class MyClassY { method M() { } method P(g: ClassG) { // error: ClassG is not in scope } } } class ClassG { method T() { } function method TFunc(): int { 10 } method V(y: MyClassY) { // Note, MyClassY is in scope, since we are in the _default // module, which imports everything y.M(); } } method Ping() { Pong(); // allowed: intra-module call } method Pong() { Ping(); // allowed: intra-module call } method ProcG(g: ClassG) { g.T(); // allowed: intra-module call var t := g.TFunc(); // allowed: intra-module call } // ---------------------- some ghost stuff ------------------------ class Ghosty { method Caller() { var x := 3; ghost var y := 3; Callee(x, y); // fine Callee(x, x); // fine Callee(y, x); // error: cannot pass in ghost to a physical formal Theorem(x); // fine Theorem(y); // fine, because it's a ghost method } method Callee(a: int, ghost b: int) { } ghost method Theorem(a: int) { } } var SomeField: int; method SpecialFunctions() modifies this; { SomeField := SomeField + 4; var a := old(SomeField); // error: old can only be used in ghost contexts var b := fresh(this); // error: fresh can only be used in ghost contexts var c := allocated(this); // error: allocated can only be used in ghost contexts if (fresh(this)) { // this guard makes the if statement a ghost statement ghost var x := old(SomeField); // this is a ghost context, so it's okay ghost var y := allocated(this); // this is a ghost context, so it's okay } } // ---------------------- illegal match expressions --------------- datatype Tree = Nil | Cons(int, Tree, Tree); function NestedMatch0(tree: Tree): int { match tree case Nil => 0 case Cons(h,l,r) => match tree // error: cannot match on "tree" again case Nil => 0 case Cons(hh,ll,rr) => hh } function NestedMatch1(tree: Tree): int { match tree case Nil => 0 case Cons(h,l,r) => match l case Nil => 0 case Cons(h0,l0,r0) => match r case Nil => 0 case Cons(h1,l1,r1) => h + h0 + h1 } function NestedMatch2(tree: Tree): int { match tree case Nil => 0 case Cons(h,l,r) => match l case Nil => 0 case Cons(h,l0,tree) => // fine to declare another "h" and "tree" here match r case Nil => 0 case Cons(h1,l1,r1) => h + h1 } function NestedMatch3(tree: Tree): int { match tree case Nil => 0 case Cons(h,l,r) => match l case Nil => 0 case Cons(h0,l0,r0) => match l // error: cannot match on "l" again case Nil => 0 case Cons(h1,l1,r1) => h + h0 + h1 } // ---------------------- direct imports are not transitive module ATr { class X { method M() returns (q: int) { q := 16; } static method Q() returns (q: int) { q := 18; } } } module BTr { import A = ATr; class Y { method N() returns (x: A.X) ensures x != null; { x := new X; } } } module CTr { import B = BTr; class Z { var b: B.Y; // fine var a: B.X; // error: imports don't reach name X explicitly } } module CTs { import B = BTr; method P() { var y := new B.Y; var x := y.N(); // this is allowed and will correctly infer the type of x to // be X, but X could not have been mentioned explicitly var q := x.M(); var r := X.Q(); // error: X is not in scope var s := x.DoesNotExist(); // error: method not declared in class X } } // ---------------------- module-local declarations override imported declarations module NonLocalA { class A { method M() { } } class Common { method P() { } } } module NonLocalB { class B { method N() { } } class D { method K() returns (b: B) ensures b != null; { return new B; } } class Common { method P() { } } } module Local { import AA = NonLocalA; import BB = NonLocalB; class MyClass { method MyMethod() { var b := new B; var c := new Common; var d := new D; c.Q(); // this is fine, since c's type is the local class Common b.R(); // fine, since B refers to the locally declared class var nonLocalB := d.K(); nonLocalB.N(); nonLocalB.R(); // error: this is not the local type B } } class B { method R() { } } class Common { method Q() { } } } // ------ qualified type names ---------------------------------- module Q_Imp { class Node { } datatype List = Nil | Cons(T, List); class Klassy { method Init() } } module Q_M { method MyMethod(root: Q_Imp.Node, S: set) requires root in S; // error: the element type of S does not agree with the type of root { var i := new Q_Imp.Node; var j := new Node; assert i != j; // error: i and j have different types var k: LongLostModule.Node; // error: undeclared module var l: Wazzup.WazzupA; // error: undeclared module (it has not been imported) var m: Q_Imp.Edon; // error: undeclared class in module Q_Imp var n: Q_Imp.List; var o := new Q_Imp.List; // error: not a class declared in module Q_Imp var p := new Q_Imp.Klassy.Create(); // error: Create is not a method var q := new Q_Imp.Klassy.Init(); } class Node { } }