public override Expression VisitOldExpression(OldExpression oldExpression) { if (this.topLevelClosureClass != null) { #region In Closure ==> Create a field // Since we're within a closure, we can't create a local to hold the value of the old expression // but instead have to create a field for it. That field can be a member of the top-level // closure class since nothing mentioned in the old expression (except possibly for the // bound variables of enclosing quantifications) should be anything captured from // an inner anonymous delegate. // BUT, first we have to know if the old expression depends on any of the bound // variables of the closures in which it is located. If not, then we can implement // it as a scalar and just generate the assignment "closure_class.field := e" for // "Old(e)" to take a snapshot of e's value in the prestate. If it does depend on // any of the bound variables, then we need to generate a set of for-loops that // compute the indices and values of e for each tuple of indices so it can be retrieved // (given the indices) in the post-state. CollectBoundVariables cbv = new CollectBoundVariables(this.stackOfBoundVariables); cbv.VisitExpression(oldExpression.expression); SubstituteClosureClassWithinOldExpressions subst = new SubstituteClosureClassWithinOldExpressions(this.closureLocals); Expression e = subst.VisitExpression(oldExpression.expression); if (cbv.FoundVariables.Count == 0) { #region Use a scalar for the old variable Local closureLocal; if (!this.closureLocals.TryGetValue(this.topLevelClosureClass, out closureLocal)) { Contract.Assume(false, "can't find closure local!"); } #region Define a scalar var clTemplate = HelperMethods.Unspecialize(this.topLevelClosureClass); Field f = new Field(clTemplate, null, FieldFlags.CompilerControlled | FieldFlags.Public, Identifier.For("_old" + oldExpression.expression.UniqueKey.ToString()), // unique name for this old expr. oldExpression.Type, null); clTemplate.Members.Add(f); // now produce properly instantiated field f = (Field)Rewriter.GetMemberInstanceReference(f, this.topLevelClosureClass); #endregion #region Generate code to store value in prestate this.prestateValuesOfOldExpressions.Statements.Add(new AssignmentStatement(new MemberBinding(closureLocal, f), e)); #endregion #region Return expression to be used in poststate // Return an expression that will evaluate in the poststate to the value of the old // expression in the prestate. This will be this.up.f where "up" is the field C# // generated to point to the instance of the top-level closure class. if (this.PointerToTopLevelClosureClass == null) { // then the old expression occurs in the top-level closure class. Just return "this.f" // where "this" refers to the top-level closure class. return new MemberBinding(new This(this.currentClosureClass), f); } else { return new MemberBinding( new MemberBinding(new This(this.currentClosureClass), this.PointerToTopLevelClosureClass), f); } #endregion #endregion } else { // the Old expression *does* depend upon at least one of the bound variable // in a ForAll or Exists expression #region Use an indexed variable for the old variable TypeNode oldVariableTypeDomain; #region Decide if domain is one-dimensional or not bool oneDimensional = cbv.FoundVariables.Count == 1 && cbv.FoundVariables[0].Type.IsValueType; if (oneDimensional) { // a one-dimensional old-expression can use the index variable directly oldVariableTypeDomain = cbv.FoundVariables[0].Type; } else { oldVariableTypeDomain = SystemTypes.GenericList.GetTemplateInstance(this.module, SystemTypes.Int32); } #endregion TypeNode oldVariableTypeRange = oldExpression.Type; TypeNode oldVariableType = SystemTypes.GenericDictionary.GetTemplateInstance(this.module, oldVariableTypeDomain, oldVariableTypeRange); Local closureLocal; if (!this.closureLocals.TryGetValue(this.topLevelClosureClass, out closureLocal)) { Contract.Assume(false, "can't find closure local"); } #region Define an indexed variable var clTemplate = HelperMethods.Unspecialize(this.topLevelClosureClass); Field f = new Field(clTemplate, null, FieldFlags.CompilerControlled | FieldFlags.Assembly, // can't be private or protected because it needs to be accessed from inner (closure) classes that don't inherit from the class this field is added to. Identifier.For("_old" + oldExpression.expression.UniqueKey.ToString()), // unique name for this old expr. oldVariableType, null); clTemplate.Members.Add(f); // instantiate f f = (Field)Rewriter.GetMemberInstanceReference(f, closureLocal.Type); #endregion #region Generate code to initialize the indexed variable Statement init = new AssignmentStatement( new MemberBinding(closureLocal, f), new Construct(new MemberBinding(null, oldVariableType.GetConstructor()), null)); this.prestateValuesOfOldExpressions.Statements.Add(init); #endregion #region Generate code to store values in prestate #region Create assignment: this.closure.f[i,j,k,...] = e; Method setItem = oldVariableType.GetMethod(Identifier.For("set_Item"), oldVariableTypeDomain, oldVariableTypeRange); Expression index; if (oneDimensional) { index = cbv.FoundVariables[0]; } else { //InstanceInitializer ctor = // ContractNodes.TupleClass.GetConstructor(SystemTypes.Int32.GetArrayType(1)); //Expression index = new Construct(new MemberBinding(null,ctor),new ExpressionList( index = Literal.Null; } MethodCall mc = new MethodCall(new MemberBinding(new MemberBinding(closureLocal, f), setItem), new ExpressionList(index, e)); Statement stat = new ExpressionStatement(mc); #endregion List<Local> locals = new List<Local>(this.stackOfBoundVariables.Count); TrivialHashtable paramMap = new TrivialHashtable(); #region Generate a local for each bound variable to use in for-loop foreach (Variable v in this.stackOfBoundVariables) { Local l = new Local(Identifier.Empty, v.Type); paramMap[v.UniqueKey] = l; locals.Add(l); } #endregion #region Substitute locals for bound variables in old expression *AND* in inner loop bounds SubstituteParameters sps = new SubstituteParameters(paramMap, this.stackOfBoundVariables); sps.Visit(stat); #endregion #region Create nested for-loops around assignment // keep track of when the first variable is used (from innermost to outermost) // as soon as the first one is needed because the old expression depends on it, // then keep all enclosing loops. It would be possible to keep only those where // the necessary loops have loop bounds that depend on an enclosing loop, but I // haven't calculated that, so just keep them all. For instance, if the old expression // depends on j and the loops are "for i,0,n" and inside that "for j,0,i", then need // both loops. If the inner loop bounds were 0 and n, then wouldn't need the outer // loop. bool usedAVariable = false; for (int i = this.stackOfBoundVariables.Count - 1; 0 <= i; i--) { if (!usedAVariable && !cbv.FoundVariables.Contains(this.stackOfBoundVariables[i])) continue; usedAVariable = true; Expression lowerBound = new Duplicator(this.module, this.currentClosureClass).VisitExpression( this.stackOfMethods[i].Operands[0]); lowerBound = subst.VisitExpression(lowerBound); lowerBound = sps.VisitExpression(lowerBound); Expression upperBound = new Duplicator(this.module, this.currentClosureClass).VisitExpression( this.stackOfMethods[i].Operands[1]); upperBound = subst.VisitExpression(upperBound); upperBound = sps.VisitExpression(upperBound); stat = RewriteHelper.GenerateForLoop(locals[i], lowerBound, upperBound, stat); } #endregion this.prestateValuesOfOldExpressions.Statements.Add(stat); #endregion #region Return expression to be used in poststate Method getItem = oldVariableType.GetMethod(Identifier.For("get_Item"), oldVariableTypeDomain); if (oneDimensional) { index = cbv.FoundReferences[0]; } else { //InstanceInitializer ctor = // ContractNodes.TupleClass.GetConstructor(SystemTypes.Int32.GetArrayType(1)); //Expression index = new Construct(new MemberBinding(null,ctor),new ExpressionList( index = Literal.Null; } // Return an expression that will evaluate in the poststate to the value of the old // expression in the prestate. This will be this.up.f[i,j,k,...] where "up" is the field C# // generated to point to the instance of the top-level closure class. MemberBinding thisDotF; if (this.PointerToTopLevelClosureClass == null) { // then the old expression occurs in the top-level closure class. Just return "this.f" // where "this" refers to the top-level closure class. Contract.Assume(f != null); thisDotF = new MemberBinding(new This(clTemplate), HelperMethods.Unspecialize(f)); } else { thisDotF = new MemberBinding( new MemberBinding(new This(clTemplate), this.PointerToTopLevelClosureClass), f); } return new MethodCall(new MemberBinding(thisDotF, getItem), new ExpressionList(index)); #endregion #endregion } #endregion } else { #region Not in closure ==> Create a local variable Local l = GetLocalForOldExpression(oldExpression); #region Make sure local can be seen in the debugger (for the entire method, unfortunately) if (currentMethod.LocalList == null) { currentMethod.LocalList = new LocalList(); } currentMethod.LocalList.Add(l); currentMethod.Body.HasLocals = true; #endregion this.prestateValuesOfOldExpressions.Statements.Add( new AssignmentStatement(l, oldExpression.expression)); // Return an expression that will evaluate in the poststate to the value of the old // expression in the prestate. When we're not in a closure, this is just the local // itself. return l; #endregion } }
public override Expression VisitOldExpression(OldExpression oldExpression) { if (this.topLevelClosureClass != null) { // In Closure ==> Create a field // Since we're within a closure, we can't create a local to hold the value of the old expression // but instead have to create a field for it. That field can be a member of the top-level // closure class since nothing mentioned in the old expression (except possibly for the // bound variables of enclosing quantifications) should be anything captured from // an inner anonymous delegate. // BUT, first we have to know if the old expression depends on any of the bound // variables of the closures in which it is located. If not, then we can implement // it as a scalar and just generate the assignment "closure_class.field := e" for // "Old(e)" to take a snapshot of e's value in the prestate. If it does depend on // any of the bound variables, then we need to generate a set of for-loops that // compute the indices and values of e for each tuple of indices so it can be retrieved // (given the indices) in the post-state. CollectBoundVariables cbv = new CollectBoundVariables(this.stackOfBoundVariables); cbv.VisitExpression(oldExpression.expression); SubstituteClosureClassWithinOldExpressions subst = new SubstituteClosureClassWithinOldExpressions(this.closureLocals); Expression e = subst.VisitExpression(oldExpression.expression); if (cbv.FoundVariables.Count == 0) { // Use a scalar for the old variable Local closureLocal; if (!this.closureLocals.TryGetValue(this.topLevelClosureClass, out closureLocal)) { Contract.Assume(false, "can't find closure local!"); } // Define a scalar var clTemplate = HelperMethods.Unspecialize(this.topLevelClosureClass); Field f = new Field(clTemplate, null, FieldFlags.CompilerControlled | FieldFlags.Public, Identifier.For("_old" + oldExpression.expression.UniqueKey.ToString()), // unique name for this old expr. oldExpression.Type, null); clTemplate.Members.Add(f); // now produce properly instantiated field f = (Field)Rewriter.GetMemberInstanceReference(f, this.topLevelClosureClass); // Generate code to store value in prestate this.prestateValuesOfOldExpressions.Statements.Add( new AssignmentStatement(new MemberBinding(closureLocal, f), e)); // Return expression to be used in poststate // Return an expression that will evaluate in the poststate to the value of the old // expression in the prestate. This will be this.up.f where "up" is the field C# // generated to point to the instance of the top-level closure class. if (this.PointerToTopLevelClosureClass == null) { // then the old expression occurs in the top-level closure class. Just return "this.f" // where "this" refers to the top-level closure class. return(new MemberBinding(new This(this.currentClosureClass), f)); } else { return(new MemberBinding( new MemberBinding(new This(this.currentClosureClass), this.PointerToTopLevelClosureClass), f)); } } else { // the Old expression *does* depend upon at least one of the bound variable // in a ForAll or Exists expression // Use an indexed variable for the old variable TypeNode oldVariableTypeDomain; // Decide if domain is one-dimensional or not bool oneDimensional = cbv.FoundVariables.Count == 1 && cbv.FoundVariables[0].Type.IsValueType; if (oneDimensional) { // a one-dimensional old-expression can use the index variable directly oldVariableTypeDomain = cbv.FoundVariables[0].Type; } else { oldVariableTypeDomain = SystemTypes.GenericList.GetTemplateInstance(this.module, SystemTypes.Int32); } TypeNode oldVariableTypeRange = oldExpression.Type; TypeNode oldVariableType = SystemTypes.GenericDictionary.GetTemplateInstance(this.module, oldVariableTypeDomain, oldVariableTypeRange); Local closureLocal; if (!this.closureLocals.TryGetValue(this.topLevelClosureClass, out closureLocal)) { Contract.Assume(false, "can't find closure local"); } // Define an indexed variable var clTemplate = HelperMethods.Unspecialize(this.topLevelClosureClass); Field f = new Field(clTemplate, null, FieldFlags.CompilerControlled | FieldFlags.Assembly, // can't be private or protected because it needs to be accessed from inner (closure) classes that don't inherit from the class this field is added to. Identifier.For("_old" + oldExpression.expression.UniqueKey.ToString()), // unique name for this old expr. oldVariableType, null); clTemplate.Members.Add(f); // instantiate f f = (Field)Rewriter.GetMemberInstanceReference(f, closureLocal.Type); // Generate code to initialize the indexed variable Statement init = new AssignmentStatement( new MemberBinding(closureLocal, f), new Construct(new MemberBinding(null, oldVariableType.GetConstructor()), null)); this.prestateValuesOfOldExpressions.Statements.Add(init); // Generate code to store values in prestate // Create assignment: this.closure.f[i,j,k,...] = e; Method setItem = oldVariableType.GetMethod(Identifier.For("set_Item"), oldVariableTypeDomain, oldVariableTypeRange); Expression index; if (oneDimensional) { index = cbv.FoundVariables[0]; } else { //InstanceInitializer ctor = // ContractNodes.TupleClass.GetConstructor(SystemTypes.Int32.GetArrayType(1)); //Expression index = new Construct(new MemberBinding(null,ctor),new ExpressionList( index = Literal.Null; } MethodCall mc = new MethodCall(new MemberBinding(new MemberBinding(closureLocal, f), setItem), new ExpressionList(index, e)); Statement stat = new ExpressionStatement(mc); List <Local> locals = new List <Local>(this.stackOfBoundVariables.Count); TrivialHashtable paramMap = new TrivialHashtable(); // Generate a local for each bound variable to use in for-loop foreach (Variable v in this.stackOfBoundVariables) { Local l = new Local(Identifier.Empty, v.Type); paramMap[v.UniqueKey] = l; locals.Add(l); } // Substitute locals for bound variables in old expression *AND* in inner loop bounds SubstituteParameters sps = new SubstituteParameters(paramMap, this.stackOfBoundVariables); sps.Visit(stat); // Create nested for-loops around assignment // keep track of when the first variable is used (from innermost to outermost) // as soon as the first one is needed because the old expression depends on it, // then keep all enclosing loops. It would be possible to keep only those where // the necessary loops have loop bounds that depend on an enclosing loop, but I // haven't calculated that, so just keep them all. For instance, if the old expression // depends on j and the loops are "for i,0,n" and inside that "for j,0,i", then need // both loops. If the inner loop bounds were 0 and n, then wouldn't need the outer // loop. bool usedAVariable = false; for (int i = this.stackOfBoundVariables.Count - 1; 0 <= i; i--) { if (!usedAVariable && !cbv.FoundVariables.Contains(this.stackOfBoundVariables[i])) { continue; } usedAVariable = true; Expression lowerBound = new Duplicator(this.module, this.currentClosureClass).VisitExpression( this.stackOfMethods[i].Operands[0]); lowerBound = subst.VisitExpression(lowerBound); lowerBound = sps.VisitExpression(lowerBound); Expression upperBound = new Duplicator(this.module, this.currentClosureClass).VisitExpression( this.stackOfMethods[i].Operands[1]); upperBound = subst.VisitExpression(upperBound); upperBound = sps.VisitExpression(upperBound); stat = RewriteHelper.GenerateForLoop(locals[i], lowerBound, upperBound, stat); } this.prestateValuesOfOldExpressions.Statements.Add(stat); // Return expression to be used in poststate Method getItem = oldVariableType.GetMethod(Identifier.For("get_Item"), oldVariableTypeDomain); if (oneDimensional) { index = cbv.FoundReferences[0]; } else { //InstanceInitializer ctor = // ContractNodes.TupleClass.GetConstructor(SystemTypes.Int32.GetArrayType(1)); //Expression index = new Construct(new MemberBinding(null,ctor),new ExpressionList( index = Literal.Null; } // Return an expression that will evaluate in the poststate to the value of the old // expression in the prestate. This will be this.up.f[i,j,k,...] where "up" is the field C# // generated to point to the instance of the top-level closure class. MemberBinding thisDotF; if (this.PointerToTopLevelClosureClass == null) { // then the old expression occurs in the top-level closure class. Just return "this.f" // where "this" refers to the top-level closure class. Contract.Assume(f != null); thisDotF = new MemberBinding(new This(clTemplate), HelperMethods.Unspecialize(f)); } else { thisDotF = new MemberBinding( new MemberBinding(new This(clTemplate), this.PointerToTopLevelClosureClass), f); } return(new MethodCall(new MemberBinding(thisDotF, getItem), new ExpressionList(index))); } } else { // Not in closure ==> Create a local variable Local l = GetLocalForOldExpression(oldExpression); // Make sure local can be seen in the debugger (for the entire method, unfortunately) if (currentMethod.LocalList == null) { currentMethod.LocalList = new LocalList(); } currentMethod.LocalList.Add(l); currentMethod.Body.HasLocals = true; this.prestateValuesOfOldExpressions.Statements.Add(new AssignmentStatement(l, oldExpression.expression)); // Return an expression that will evaluate in the poststate to the value of the old // expression in the prestate. When we're not in a closure, this is just the local // itself. return(l); } }