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// Dafny prelude
// Created 9 February 2008 by Rustan Leino.
// Converted to Boogie 2 on 28 June 2008.
// Edited sequence axioms 20 October 2009 by Alex Summers.
// Copyright (c) 2008-2010, Microsoft.
const $$Language$Dafny: bool; // To be recognizable to the ModelViewer as
axiom $$Language$Dafny; // coming from a Dafny program.
// ---------------------------------------------------------------
// -- References -------------------------------------------------
// ---------------------------------------------------------------
type ref;
const null: ref;
// ---------------------------------------------------------------
// -- Axiomatization of sets -------------------------------------
// ---------------------------------------------------------------
type Set T = [T]bool;
function Set#Empty<T>() returns (Set T);
axiom (forall<T> o: T :: { Set#Empty()[o] } !Set#Empty()[o]);
function Set#Singleton<T>(T) returns (Set T);
axiom (forall<T> r: T :: { Set#Singleton(r) } Set#Singleton(r)[r]);
axiom (forall<T> r: T, o: T :: { Set#Singleton(r)[o] } Set#Singleton(r)[o] <==> r == o);
function Set#UnionOne<T>(Set T, T) returns (Set T);
axiom (forall<T> a: Set T, x: T, o: T :: { Set#UnionOne(a,x)[o] }
Set#UnionOne(a,x)[o] <==> o == x || a[o]);
axiom (forall<T> a: Set T, x: T :: { Set#UnionOne(a, x) }
Set#UnionOne(a, x)[x]);
axiom (forall<T> a: Set T, x: T, y: T :: { Set#UnionOne(a, x), a[y] }
a[y] ==> Set#UnionOne(a, x)[y]);
function Set#Union<T>(Set T, Set T) returns (Set T);
axiom (forall<T> a: Set T, b: Set T, o: T :: { Set#Union(a,b)[o] }
Set#Union(a,b)[o] <==> a[o] || b[o]);
axiom (forall<T> a, b: Set T, y: T :: { Set#Union(a, b), a[y] }
a[y] ==> Set#Union(a, b)[y]);
axiom (forall<T> a, b: Set T, y: T :: { Set#Union(a, b), b[y] }
b[y] ==> Set#Union(a, b)[y]);
axiom (forall<T> a, b: Set T :: { Set#Union(a, b) }
Set#Disjoint(a, b) ==>
Set#Difference(Set#Union(a, b), a) == b &&
Set#Difference(Set#Union(a, b), b) == a);
function Set#Intersection<T>(Set T, Set T) returns (Set T);
axiom (forall<T> a: Set T, b: Set T, o: T :: { Set#Intersection(a,b)[o] }
Set#Intersection(a,b)[o] <==> a[o] && b[o]);
axiom (forall<T> a, b: Set T :: { Set#Union(Set#Union(a, b), b) }
Set#Union(Set#Union(a, b), b) == Set#Union(a, b));
axiom (forall<T> a, b: Set T :: { Set#Union(a, Set#Union(a, b)) }
Set#Union(a, Set#Union(a, b)) == Set#Union(a, b));
axiom (forall<T> a, b: Set T :: { Set#Intersection(Set#Intersection(a, b), b) }
Set#Intersection(Set#Intersection(a, b), b) == Set#Intersection(a, b));
axiom (forall<T> a, b: Set T :: { Set#Intersection(a, Set#Intersection(a, b)) }
Set#Intersection(a, Set#Intersection(a, b)) == Set#Intersection(a, b));
function Set#Difference<T>(Set T, Set T) returns (Set T);
axiom (forall<T> a: Set T, b: Set T, o: T :: { Set#Difference(a,b)[o] }
Set#Difference(a,b)[o] <==> a[o] && !b[o]);
axiom (forall<T> a, b: Set T, y: T :: { Set#Difference(a, b), b[y] }
b[y] ==> !Set#Difference(a, b)[y] );
function Set#Subset<T>(Set T, Set T) returns (bool);
axiom(forall<T> a: Set T, b: Set T :: { Set#Subset(a,b) }
Set#Subset(a,b) <==> (forall o: T :: {a[o]} {b[o]} a[o] ==> b[o]));
function Set#Equal<T>(Set T, Set T) returns (bool);
axiom(forall<T> a: Set T, b: Set T :: { Set#Equal(a,b) }
Set#Equal(a,b) <==> (forall o: T :: {a[o]} {b[o]} a[o] <==> b[o]));
axiom(forall<T> a: Set T, b: Set T :: { Set#Equal(a,b) } // extensionality axiom for sets
Set#Equal(a,b) ==> a == b);
function Set#Disjoint<T>(Set T, Set T) returns (bool);
axiom (forall<T> a: Set T, b: Set T :: { Set#Disjoint(a,b) }
Set#Disjoint(a,b) <==> (forall o: T :: {a[o]} {b[o]} !a[o] || !b[o]));
// ---------------------------------------------------------------
// -- Axiomatization of sequences --------------------------------
// ---------------------------------------------------------------
type Seq T;
function Seq#Length<T>(Seq T) returns (int);
axiom (forall<T> s: Seq T :: { Seq#Length(s) } 0 <= Seq#Length(s));
function Seq#Empty<T>() returns (Seq T);
axiom (forall<T> :: Seq#Length(Seq#Empty(): Seq T) == 0);
axiom (forall<T> s: Seq T :: { Seq#Length(s) } Seq#Length(s) == 0 ==> s == Seq#Empty());
function Seq#Singleton<T>(T) returns (Seq T);
axiom (forall<T> t: T :: { Seq#Length(Seq#Singleton(t)) } Seq#Length(Seq#Singleton(t)) == 1);
function Seq#Build<T>(s: Seq T, index: int, val: T, newLength: int) returns (Seq T);
axiom (forall<T> s: Seq T, i: int, v: T, len: int :: { Seq#Length(Seq#Build(s,i,v,len)) }
0 <= len ==> Seq#Length(Seq#Build(s,i,v,len)) == len);
function Seq#Append<T>(Seq T, Seq T) returns (Seq T);
axiom (forall<T> s0: Seq T, s1: Seq T :: { Seq#Length(Seq#Append(s0,s1)) }
Seq#Length(Seq#Append(s0,s1)) == Seq#Length(s0) + Seq#Length(s1));
function Seq#Index<T>(Seq T, int) returns (T);
axiom (forall<T> t: T :: { Seq#Index(Seq#Singleton(t), 0) } Seq#Index(Seq#Singleton(t), 0) == t);
axiom (forall<T> s0: Seq T, s1: Seq T, n: int :: { Seq#Index(Seq#Append(s0,s1), n) }
(n < Seq#Length(s0) ==> Seq#Index(Seq#Append(s0,s1), n) == Seq#Index(s0, n)) &&
(Seq#Length(s0) <= n ==> Seq#Index(Seq#Append(s0,s1), n) == Seq#Index(s1, n - Seq#Length(s0))));
axiom (forall<T> s: Seq T, i: int, v: T, len: int, n: int :: { Seq#Index(Seq#Build(s,i,v,len),n) }
0 <= n && n < len ==>
(i == n ==> Seq#Index(Seq#Build(s,i,v,len),n) == v) &&
(i != n ==> Seq#Index(Seq#Build(s,i,v,len),n) == Seq#Index(s,n)));
function Seq#Update<T>(Seq T, int, T) returns (Seq T);
axiom (forall<T> s: Seq T, i: int, v: T :: { Seq#Length(Seq#Update(s,i,v)) }
0 <= i && i < Seq#Length(s) ==> Seq#Length(Seq#Update(s,i,v)) == Seq#Length(s));
axiom (forall<T> s: Seq T, i: int, v: T, n: int :: { Seq#Index(Seq#Update(s,i,v),n) }
0 <= n && n < Seq#Length(s) ==>
(i == n ==> Seq#Index(Seq#Update(s,i,v),n) == v) &&
(i != n ==> Seq#Index(Seq#Update(s,i,v),n) == Seq#Index(s,n)));
function Seq#Contains<T>(Seq T, T) returns (bool);
axiom (forall<T> s: Seq T, x: T :: { Seq#Contains(s,x) }
Seq#Contains(s,x) <==>
(exists i: int :: { Seq#Index(s,i) } 0 <= i && i < Seq#Length(s) && Seq#Index(s,i) == x));
axiom (forall x: ref ::
{ Seq#Contains(Seq#Empty(), x) }
!Seq#Contains(Seq#Empty(), x));
axiom (forall<T> s0: Seq T, s1: Seq T, x: T ::
{ Seq#Contains(Seq#Append(s0, s1), x) }
Seq#Contains(Seq#Append(s0, s1), x) <==>
Seq#Contains(s0, x) || Seq#Contains(s1, x));
axiom (forall<T> s: Seq T, i: int, v: T, len: int, x: T ::
{ Seq#Contains(Seq#Build(s, i, v, len), x) }
Seq#Contains(Seq#Build(s, i, v, len), x) <==>
(0 <= i && i < len && x == v) ||
(exists j: int :: { Seq#Index(s,j) } 0 <= j && j < Seq#Length(s) && j < len && j!=i && Seq#Index(s,j) == x));
axiom (forall<T> s: Seq T, n: int, x: T ::
{ Seq#Contains(Seq#Take(s, n), x) }
Seq#Contains(Seq#Take(s, n), x) <==>
(exists i: int :: { Seq#Index(s, i) }
0 <= i && i < n && i < Seq#Length(s) && Seq#Index(s, i) == x));
axiom (forall<T> s: Seq T, n: int, x: T ::
{ Seq#Contains(Seq#Drop(s, n), x) }
Seq#Contains(Seq#Drop(s, n), x) <==>
(exists i: int :: { Seq#Index(s, i) }
0 <= n && n <= i && i < Seq#Length(s) && Seq#Index(s, i) == x));
function Seq#Equal<T>(Seq T, Seq T) returns (bool);
axiom (forall<T> s0: Seq T, s1: Seq T :: { Seq#Equal(s0,s1) }
Seq#Equal(s0,s1) <==>
Seq#Length(s0) == Seq#Length(s1) &&
(forall j: int :: { Seq#Index(s0,j) } { Seq#Index(s1,j) }
0 <= j && j < Seq#Length(s0) ==> Seq#Index(s0,j) == Seq#Index(s1,j)));
axiom(forall<T> a: Seq T, b: Seq T :: { Seq#Equal(a,b) } // extensionality axiom for sequences
Seq#Equal(a,b) ==> a == b);
function Seq#SameUntil<T>(Seq T, Seq T, int) returns (bool);
axiom (forall<T> s0: Seq T, s1: Seq T, n: int :: { Seq#SameUntil(s0,s1,n) }
Seq#SameUntil(s0,s1,n) <==>
(forall j: int :: { Seq#Index(s0,j) } { Seq#Index(s1,j) }
0 <= j && j < n ==> Seq#Index(s0,j) == Seq#Index(s1,j)));
function Seq#Take<T>(s: Seq T, howMany: int) returns (Seq T);
axiom (forall<T> s: Seq T, n: int :: { Seq#Length(Seq#Take(s,n)) }
0 <= n ==>
(n <= Seq#Length(s) ==> Seq#Length(Seq#Take(s,n)) == n) &&
(Seq#Length(s) < n ==> Seq#Length(Seq#Take(s,n)) == Seq#Length(s)));
axiom (forall<T> s: Seq T, n: int, j: int :: { Seq#Index(Seq#Take(s,n), j) } {:weight 25}
0 <= j && j < n && j < Seq#Length(s) ==>
Seq#Index(Seq#Take(s,n), j) == Seq#Index(s, j));
function Seq#Drop<T>(s: Seq T, howMany: int) returns (Seq T);
axiom (forall<T> s: Seq T, n: int :: { Seq#Length(Seq#Drop(s,n)) }
0 <= n ==>
(n <= Seq#Length(s) ==> Seq#Length(Seq#Drop(s,n)) == Seq#Length(s) - n) &&
(Seq#Length(s) < n ==> Seq#Length(Seq#Drop(s,n)) == 0));
axiom (forall<T> s: Seq T, n: int, j: int :: { Seq#Index(Seq#Drop(s,n), j) } {:weight 25}
0 <= n && 0 <= j && j < Seq#Length(s)-n ==>
Seq#Index(Seq#Drop(s,n), j) == Seq#Index(s, j+n));
axiom (forall<T> s, t: Seq T ::
{ Seq#Append(s, t) }
Seq#Take(Seq#Append(s, t), Seq#Length(s)) == s &&
Seq#Drop(Seq#Append(s, t), Seq#Length(s)) == t);
// ---------------------------------------------------------------
// -- Boxing and unboxing ----------------------------------------
// ---------------------------------------------------------------
type BoxType;
function $Box<T>(T) returns (BoxType);
function $Unbox<T>(BoxType) returns (T);
axiom (forall<T> x: T :: { $Box(x) } $Unbox($Box(x)) == x);
axiom (forall b: BoxType :: { $Unbox(b): int } $Box($Unbox(b): int) == b);
axiom (forall b: BoxType :: { $Unbox(b): ref } $Box($Unbox(b): ref) == b);
axiom (forall b: BoxType :: { $Unbox(b): Set BoxType } $Box($Unbox(b): Set BoxType) == b);
axiom (forall b: BoxType :: { $Unbox(b): Seq BoxType } $Box($Unbox(b): Seq BoxType) == b);
axiom (forall b: BoxType :: { $Unbox(b): DatatypeType } $Box($Unbox(b): DatatypeType) == b);
// note: an axiom like this for bool would not be sound
// ---------------------------------------------------------------
// -- Encoding of type names -------------------------------------
// ---------------------------------------------------------------
type ClassName;
const unique class.int: ClassName;
const unique class.bool: ClassName;
const unique class.set: ClassName;
const unique class.seq: ClassName;
function /*{:never_pattern true}*/ dtype(ref) returns (ClassName);
function /*{:never_pattern true}*/ TypeParams(ref, int) returns (ClassName);
function TypeTuple(a: ClassName, b: ClassName) returns (ClassName);
function TypeTupleCar(ClassName) returns (ClassName);
function TypeTupleCdr(ClassName) returns (ClassName);
// TypeTuple is injective in both arguments:
axiom (forall a: ClassName, b: ClassName :: { TypeTuple(a,b) }
TypeTupleCar(TypeTuple(a,b)) == a &&
TypeTupleCdr(TypeTuple(a,b)) == b);
// ---------------------------------------------------------------
// -- Datatypes --------------------------------------------------
// ---------------------------------------------------------------
type DatatypeType;
function /*{:never_pattern true}*/ DtType(DatatypeType) returns (ClassName); // the analog of dtype for datatype values
function /*{:never_pattern true}*/ DtTypeParams(DatatypeType, int) returns (ClassName); // the analog of TypeParams
type DtCtorId;
function DatatypeCtorId(DatatypeType) returns (DtCtorId);
function DtRank(DatatypeType) returns (int);
// ---------------------------------------------------------------
// -- Axiom contexts ---------------------------------------------
// ---------------------------------------------------------------
// used to make sure function axioms are not used while their consistency is being checked
const $ModuleContextHeight: int;
const $FunctionContextHeight: int;
const $InMethodContext: bool;
// ---------------------------------------------------------------
// -- Fields -----------------------------------------------------
// ---------------------------------------------------------------
type Field alpha;
function FDim<T>(Field T): int;
function IndexField(int): Field BoxType;
axiom (forall i: int :: { IndexField(i) } FDim(IndexField(i)) == 1);
function IndexField_Inverse<T>(Field T): int;
axiom (forall i: int :: { IndexField(i) } IndexField_Inverse(IndexField(i)) == i);
function MultiIndexField(Field BoxType, int): Field BoxType;
axiom (forall f: Field BoxType, i: int :: { MultiIndexField(f,i) } FDim(MultiIndexField(f,i)) == FDim(f) + 1);
function MultiIndexField_Inverse0<T>(Field T): Field T;
function MultiIndexField_Inverse1<T>(Field T): int;
axiom (forall f: Field BoxType, i: int :: { MultiIndexField(f,i) }
MultiIndexField_Inverse0(MultiIndexField(f,i)) == f &&
MultiIndexField_Inverse1(MultiIndexField(f,i)) == i);
function DeclType<T>(Field T) returns (ClassName);
// ---------------------------------------------------------------
// -- Allocatedness ----------------------------------------------
// ---------------------------------------------------------------
const unique alloc: Field bool;
axiom FDim(alloc) == 0;
function DtAlloc(DatatypeType, HeapType): bool;
axiom (forall h, k: HeapType, d: DatatypeType ::
{ $HeapSucc(h, k), DtAlloc(d, h) }
{ $HeapSucc(h, k), DtAlloc(d, k) }
$HeapSucc(h, k) ==> DtAlloc(d, h) ==> DtAlloc(d, k));
function GenericAlloc(BoxType, HeapType): bool;
axiom (forall h: HeapType, k: HeapType, d: BoxType ::
{ $HeapSucc(h, k), GenericAlloc(d, h) }
{ $HeapSucc(h, k), GenericAlloc(d, k) }
$HeapSucc(h, k) ==> GenericAlloc(d, h) ==> GenericAlloc(d, k));
// GenericAlloc ==>
axiom (forall b: BoxType, h: HeapType ::
{ GenericAlloc(b, h), h[$Unbox(b): ref, alloc] }
GenericAlloc(b, h) ==>
$Unbox(b): ref == null || h[$Unbox(b): ref, alloc]);
axiom (forall b: BoxType, h: HeapType, i: int ::
{ GenericAlloc(b, h), Seq#Index($Unbox(b): Seq BoxType, i) }
GenericAlloc(b, h) &&
0 <= i && i < Seq#Length($Unbox(b): Seq BoxType) ==>
GenericAlloc( Seq#Index($Unbox(b): Seq BoxType, i), h ) );
axiom (forall b: BoxType, h: HeapType, t: BoxType ::
{ GenericAlloc(b, h), ($Unbox(b): Set BoxType)[t] }
GenericAlloc(b, h) && ($Unbox(b): Set BoxType)[t] ==>
GenericAlloc(t, h));
axiom (forall b: BoxType, h: HeapType ::
{ GenericAlloc(b, h), DtType($Unbox(b): DatatypeType) }
GenericAlloc(b, h) ==> DtAlloc($Unbox(b): DatatypeType, h));
// ==> GenericAlloc
axiom (forall b: bool, h: HeapType ::
$IsGoodHeap(h) ==> GenericAlloc($Box(b), h));
axiom (forall x: int, h: HeapType ::
$IsGoodHeap(h) ==> GenericAlloc($Box(x), h));
axiom (forall r: ref, h: HeapType ::
{ GenericAlloc($Box(r), h) }
$IsGoodHeap(h) && (r == null || h[r,alloc]) ==> GenericAlloc($Box(r), h));
// ---------------------------------------------------------------
// -- Arrays -----------------------------------------------------
// ---------------------------------------------------------------
procedure UpdateArrayRange(arr: ref, low: int, high: int, rhs: BoxType);
modifies $Heap;
ensures $HeapSucc(old($Heap), $Heap);
ensures (forall i: int :: { read($Heap, arr, IndexField(i)) } low <= i && i < high ==> read($Heap, arr, IndexField(i)) == rhs);
ensures (forall<alpha> o: ref, f: Field alpha :: { read($Heap, o, f) } read($Heap, o, f) == read(old($Heap), o, f) ||
(o == arr && FDim(f) == 1 && low <= IndexField_Inverse(f) && IndexField_Inverse(f) < high));
// ---------------------------------------------------------------
// -- The heap ---------------------------------------------------
// ---------------------------------------------------------------
type HeapType = <alpha>[ref,Field alpha]alpha;
function {:inline true} read<alpha>(H:HeapType, r:ref, f:Field alpha): alpha { H[r, f] }
function {:inline true} update<alpha>(H:HeapType, r:ref, f:Field alpha, v:alpha): HeapType { H[r,f := v] }
function $IsGoodHeap(HeapType) returns (bool);
var $Heap: HeapType where $IsGoodHeap($Heap);
function $HeapSucc(HeapType, HeapType) returns (bool);
axiom (forall<alpha> h: HeapType, r: ref, f: Field alpha, x: alpha :: { update(h, r, f, x) }
$HeapSucc(h, update(h, r, f, x)));
axiom (forall a,b,c: HeapType :: { $HeapSucc(a,b), $HeapSucc(b,c) }
$HeapSucc(a,b) && $HeapSucc(b,c) ==> $HeapSucc(a,c));
axiom (forall h: HeapType, k: HeapType :: { $HeapSucc(h,k) }
$HeapSucc(h,k) ==> (forall o: ref :: { read(k, o, alloc) } read(h, o, alloc) ==> read(k, o, alloc)));
// ---------------------------------------------------------------
// -- Arithmetic -------------------------------------------------
// ---------------------------------------------------------------
// the connection between % and /
axiom (forall x:int, y:int :: {x % y} {x / y} x % y == x - x / y * y);
// sign of denominator determines sign of remainder
axiom (forall x:int, y:int :: {x % y} 0 < y ==> 0 <= x % y && x % y < y);
axiom (forall x:int, y:int :: {x % y} y < 0 ==> y < x % y && x % y <= 0);
// the following axiom has some unfortunate matching, but it does state a property about % that
// is sometime useful
axiom (forall a: int, b: int, d: int :: { a % d, b % d } 2 <= d && a % d == b % d && a < b ==> a + d <= b);
// ---------------------------------------------------------------
|