Examples of org.openquark.cal.internal.javamodel.JavaStatement$UnconditionalLoop

• org.openquark.cal.internal.javamodel.JavaStatement
  Represents an unconditional loop. i.e. while (true) {...} @author RCypher

                    new JavaExpression.ClassInstanceCreationExpression (
                            UNSUPPORTED_OPERATION_TYPE_NAME,
                            message,
                            JavaTypeName.STRING);

                JavaStatement throwStatement = new JavaStatement.ThrowStatement(createException);

                SwitchStatement.DefaultCase defaultCase =
                    new SwitchStatement.DefaultCase(throwStatement);
                switchStatement.addCase(defaultCase);

            // ThisType castObject = (ThisType)object;
            LocalVariable localVar =
                new LocalVariable ("cast" + argName, typeName);

            JavaStatement localVarDecl =
                new JavaStatement.LocalVariableDeclaration (
                        localVar,
                        new JavaExpression.CastExpression(typeName, objectArg));
            equals.addStatement (localVarDecl);

                VarInfo vi = variableContext.addArgument(QualifiedName.make(currentModuleName, argumentNames[i]), isArgStrict(i), getArgumentTypeName(i), getArgumentType(i));
                this.javaArgumentNames[i] = vi.getJavaName();
            }

            // Generate the body contribution
            JavaStatement bodyStatement = genS_R(body, variableContext);
            // Emit let variables
            bodyCode.addStatement(variableContext.popJavaScope());

            // Emit the body
            bodyCode.addStatement(new LineComment("Top level supercombinator logic"));

            Expression expressions[] = flattenTopLevelSeq(methodBody);
            if (expressions != null && (scheme == Scheme.E_SCHEME || scheme == Scheme.UNBOX_INTERNAL_SCHEME)) {
                for (int i = 0, n = expressions.length - 1; i < n; ++i) {
                    JavaStatement js = makeStrictStatementFromSeqArg(expressions[i], variableContext);
                    bodyCode.addStatement(js);
                }

                methodBody = expressions[expressions.length - 1];
            }

            Expression condExpression = conditionExpressions.getConditionExpression();
            ExpressionContextPair pair = generateUnboxedArgument(JavaTypeName.BOOLEAN, condExpression, variableContext);

            // Then
            variableContext.pushJavaScope();
            JavaStatement thenPart = genS_R (conditionExpressions.getThenExpression(), variableContext);

            Block thenBlock = variableContext.popJavaScope();
            thenBlock.addStatement(thenPart);

            // Else
            variableContext.pushJavaScope();
            JavaStatement elsePart = genS_R (conditionExpressions.getElseExpression(), variableContext);

            Block elseBlock = variableContext.popJavaScope();
            elseBlock.addStatement(elsePart);

            JavaExpression conditionExpression = pair.getJavaExpression();

            JavaStatement ite = new IfThenElseStatement(conditionExpression, thenBlock, elseBlock);

            Block contextBlock = pair.getContextBlock();
            contextBlock.addStatement(ite);

            // We don't need to call generateReturn() at this point.  Any return statements
            // will have been generated in the sub-parts of the if-then-else.
            return contextBlock;
        }


        // Expression is a case/switch?
        Expression.Switch eswitch = e.asSwitch();
        if (eswitch != null) {
            // We don't need to call generateReturn() at this point.  Any return statements
            // will have been generated in the sub-parts of the switch.
            return generateSwitch (eswitch, variableContext);
        }

        // Expression is a data constructor field selection?
        Expression.DataConsSelection eDCSelection = e.asDataConsSelection();
        if (eDCSelection != null) {
             return generateReturn(generateDCFieldSelection(eDCSelection, Scheme.R_SCHEME, variableContext), variableContext);
        }

        // e is a let var.
        if (e.asLetNonRec() != null) {
            return generateReturn (generateLetNonRec(e.asLetNonRec(), Scheme.R_SCHEME, null, variableContext), variableContext);
        }

        if (e.asLetRec() != null) {
            return generateReturn(generateLetRec(e.asLetRec(), Scheme.R_SCHEME, variableContext), variableContext);
        }

        // e is an application?
        Expression.Appl appl = e.asAppl();
        if (appl != null) {
            JavaStatement topLevelSeq = buildTopLevelSeq (appl, false, variableContext);
            if (topLevelSeq != null) {
                return topLevelSeq;
            }
            ExpressionContextPair ecp = buildApplicationChain (appl, Scheme.R_SCHEME, variableContext);
            if (ecp != null) {

        }


        //encode the result expression in the context of the extended variable scope.
        Expression resultExpr = recordCaseExpr.getResultExpr();
        JavaStatement resultJavaStatement = genS_R(resultExpr, variableContext);

        // Generate any let variables in this block and add them to the recordCaseBlock.
        recordCaseBlock.addStatement(variableContext.popJavaScope());

        // Add the body of the record case.

            final Method method = (Method)SCJavaDefn.getJavaProxy(invocationInfo);
            if (method.getReturnType() == void.class && (scheme != Scheme.R_SCHEME)) {
                ExpressionContextPair ecp = genS_C (e, variableContext);
                JavaExpression expr = ecp.getJavaExpression();
                JavaStatement block = ecp.getContextBlock();
                JavaExpression.MethodInvocation eval = createInvocation(expr, EVALUATE, EXECUTION_CONTEXT_VAR);
                return new ExpressionContextPair(eval, block);
            }

            int nJavaArgs = SCJavaDefn.getNArguments(foreignFunctionInfo);

            compiledBody = generateUnboxedArgument(unboxBodyType, let.getBody(), variableContext);
        } else if (scheme == Scheme.UNBOX_FOREIGN_SCHEME) {
            compiledBody = generateUnboxedForeignFunctionArgument(unboxBodyType, let.getBody(), variableContext);
        } else if (scheme == Scheme.R_SCHEME) {
            // Special case for scheme R (see Javadoc for this method).
            JavaStatement rStatement = genS_R(let.getBody(), variableContext);
            compiledBody = new ExpressionContextPair(null, rStatement);

        } else if (scheme == Scheme.E_SCHEME) {
            compiledBody = genS_E(let.getBody(), variableContext);

        }

        ExpressionContextPair returnValue = null;
        if (scheme == Scheme.R_SCHEME) {
            // Special case for scheme R (see Javadoc for this method).
            JavaStatement rStatement = genS_R (let.getBody(), variableContext);
            returnValue = new ExpressionContextPair(null, rStatement);

        } else if (scheme == Scheme.E_SCHEME) {
            returnValue = genS_E (let.getBody(), variableContext);

            // switch ((caseVar = expression.evaluate()).getIntValue())
            // We do the assignment of the local in the actual switch statement
            // because analysis of the generated bytecode has shown this to be
            // slightly more efficient than initializing the local as part of the
            // declaration.
            JavaStatement caseVarDeclaration = null;
            Expression switchExpression = eswitch.getSwitchExpr();

            // Generate a local variable and assign the evaluated value of the expression
            // we are switching on.
            JavaTypeName typeClassName = isEnumDataType ? JavaTypeNames.RTVALUE : CALToJavaNames.createTypeNameFromType(typeCons, module);
            caseVar = new LocalVariable("$case" + nestedCaseLevel, typeClassName);

            // Add the local variable declaration.
            caseVarDeclaration = new LocalVariableDeclaration(caseVar);
            switchBlock.addStatement(caseVarDeclaration);

            // Compile the expression we are switching on strictly.
            ExpressionContextPair pair = genS_E(switchExpression, variableContext);
            switchBlock.addStatement(pair.getContextBlock());

            JavaExpression caseExpression = pair.getJavaExpression();
            //caseExpression = releaseVarsInSwitchCondition(eswitch, caseExpression, variableContext);

            // We may need to cast the result of the case expression to the type of the local variable.
            caseExpression = (isEnumDataType || caseExpression instanceof ClassInstanceCreationExpression) ? caseExpression : new CastExpression(typeClassName, caseExpression);

            // Assign the result of the switch expression to the local an then get the ordinal value.
            JavaExpression assignLocal = new JavaExpression.Assignment(caseVar, caseExpression);
            JavaExpression getOrdinal = SCJavaDefn.createInvocation(assignLocal, SCJavaDefn.GETORDINALVALUE);

            switchStatement = new SwitchStatement(getOrdinal);
            switchBlock.addStatement(switchStatement);
        }

        // Populate the switch statement with case statement groups.
        for (final SwitchAlt alt : alts) {
            List<Object> altTags = alt.getAltTags();

            // If no variables are used, we can share the code among all data constructors for this alt.
            if (!alt.hasVars()) {

                Block caseBlock = new Block();

                // Add a comment for the data constructors in the group if any (ie. if not the default alt).
                if (alt.getFirstAltTag() instanceof DataConstructor) {
                    StringBuilder commentSB = new StringBuilder();

                    boolean firstDC = true;
                    for (final Object tag : altTags) {
                        DataConstructor tagDC = (DataConstructor)tag;
                        if (firstDC) {
                            firstDC = false;
                        } else {
                            commentSB.append(", ");
                        }
                        commentSB.append(tagDC.getName().getQualifiedName());

                    }
                    caseBlock.addStatement(new LineComment(commentSB.toString()));
                }

                // Create a new child variable scope to handle the alternate and any let variables it contains.
                variableContext.pushJavaScope();

                // Compile the body of the alternate.
                JavaStatement altStatement = genS_R(alt.getAltExpr(), variableContext);
                caseBlock.addStatement(variableContext.popJavaScope());
                caseBlock.addStatement(altStatement);

                if (alt.isDefaultAlt()) {
                    switchStatement.addCase(new SwitchStatement.DefaultCase(caseBlock));

                } else {
                    int[] caseLabels = new int[altTags.size()];
                    int index = 0;
                    for (final Object tag : altTags) {
                        if (!(tag instanceof DataConstructor)) {
                            throw new CodeGenerationException ("Unknown tag type in DC case statement in " + getFunctionName() + ": " + tag.getClass().getName());
                        }

                        caseLabels[index] = ((DataConstructor)tag).getOrdinal();
                        index++;
                    }

                    switchStatement.addCase(new SwitchStatement.IntCaseGroup(caseLabels, caseBlock));
                }

            } else {
                // The alts use variables.

                if (alt instanceof SwitchAlt.Positional) {
                    // Positional notation for extracted variables.
                    // For now, a separate code block must be generated for each data constructor in the case.

                    Collection<List<DataConstructor>> tagGroups = consolidatePositionalSwitchAlt((SwitchAlt.Positional)alt);

                    for (final List<DataConstructor> group : tagGroups) {
                        // Must be a data constructor tag, since there are field names (see Expression.Switch.SwitchAlt).

                        Block caseBlock = new Block();

                        int[] caseLabels = new int[group.size()];
                        int index = 0;
                        DataConstructor firstDC = null;
                        // Must be a data constructor tag, since there are field names (see Expression.Switch.SwitchAlt).
                        for (final DataConstructor tagDC : group) {
                            if (firstDC == null) {
                                firstDC = tagDC;
                            } else
                            if (tagDC.getOrdinal() < firstDC.getOrdinal()) {
                                firstDC = tagDC;
                            }
                            caseBlock.addStatement(new LineComment(tagDC.getName().getQualifiedName()));
                            caseLabels[index] = tagDC.getOrdinal();
                            index++;
                        }

                        caseBlock.addStatement(new LineComment("Decompose data type to access members."));

                        // Create a new child variable scope to handle the alternate and any let variables it contains.
                        variableContext.pushJavaScope();

                        // Get this alternative's variables.  These have to be added to the active list of scope variables
                        TypeExpr fieldTypes[] = SCJavaDefn.getFieldTypesForDC(firstDC);
                        for (final AltVarIndexPair altVarIndexPair : getAltVarIndexList(alt, firstDC)) {

                            String altVar = altVarIndexPair.getAltVar();
                            int fieldIndex = altVarIndexPair.getIndex();

                            QualifiedName qn = QualifiedName.make(currentModuleName, altVar);
                            VarInfo.DCMember vi = variableContext.addDCField(qn, fieldTypes[fieldIndex]);

                            boolean fieldIsStrict =
                                !LECCMachineConfiguration.IGNORE_STRICTNESS_ANNOTATIONS;

                            for (final DataConstructor tagDC : group) {
                                fieldIsStrict = fieldIsStrict && tagDC.isArgStrict(fieldIndex);
                            }

                            if (fieldIsStrict) {
                                vi.setEvaluated(true);
                            }

                            String fieldName = SCJavaDefn.getJavaFieldNameFromDC(firstDC, fieldIndex);
                            String fieldGetterName = "get" + fieldName;

                            // Generate the code defining the variable.
                            if (fieldIsStrict) {
                                if (SCJavaDefn.canTypeBeUnboxed(fieldTypes[fieldIndex])) {
                                    // This is a strict field of a primitive type so has both a boxed and unboxed form.
                                    JavaExpression unboxedInitializer =
                                        new JavaExpression.MethodInvocation.Instance(caseVar,
                                                                                     fieldGetterName + "_As_" + SCJavaDefn.getNameForPrimitive(fieldTypes[fieldIndex]),
                                                                                     SCJavaDefn.typeExprToTypeName(fieldTypes[fieldIndex]),
                                                                                     JavaExpression.MethodInvocation.InvocationType.VIRTUAL);

                                    vi.updateUnboxedVarDef(unboxedInitializer);
                                    JavaExpression localVar = new LocalVariable(vi.getJavaName()+"$U", vi.getUnboxedType());
                                    vi.updateUnboxedReference(localVar);
                                    JavaExpression boxedDef = SCJavaDefn.boxExpression(vi.getUnboxedType(), localVar);
                                    vi.updateStrictReference(boxedDef);
                                    vi.updateLazyReference(boxedDef);
                                } else {
                                    // RTValue altVarName = ((DCClass)caseVar).getFieldn();
                                    JavaExpression initializer = new JavaExpression.MethodInvocation.Instance(caseVar, fieldGetterName, JavaTypeNames.RTVALUE, JavaExpression.MethodInvocation.InvocationType.VIRTUAL);
                                    vi.updateStrictVarDef (initializer);
                                    JavaExpression localVar = new LocalVariable(vi.getJavaName(), JavaTypeNames.RTVALUE);
                                    vi.updateStrictReference(localVar);
                                    vi.updateLazyReference(localVar);
                                }
                            } else {
                                // RTValue altVarName = ((DCClass)caseVar).getFieldn();
                                JavaExpression initializer = new JavaExpression.MethodInvocation.Instance(caseVar, fieldGetterName, JavaTypeNames.RTVALUE, JavaExpression.MethodInvocation.InvocationType.VIRTUAL);
                                vi.updateLazyVarDef (initializer);
                                JavaExpression localVar = new LocalVariable(vi.getJavaName(), JavaTypeNames.RTVALUE);
                                vi.updateLazyReference(localVar);

                                JavaExpression evaluatedVar = SCJavaDefn.createInvocation(localVar, SCJavaDefn.EVALUATE, SCJavaDefn.EXECUTION_CONTEXT_VAR);
                                vi.updateStrictReference(evaluatedVar);
                                if (SCJavaDefn.canTypeBeUnboxed(fieldTypes[fieldIndex])) {
                                    vi.updateUnboxedReference(SCJavaDefn.unboxValue(vi.getUnboxedType(), evaluatedVar));
                                }
                            }
                        }

                        // Compile the actual body of the alternate.
                        JavaStatement altStatement = genS_R(alt.getAltExpr(), variableContext);
                        caseBlock.addStatement(variableContext.popJavaScope());
                        caseBlock.addStatement(altStatement);

                        switchStatement.addCase(new SwitchStatement.IntCaseGroup(caseLabels, caseBlock));
                    }
                } else {
                    // Matching notation for switch alternate.
                    Map<FieldName, String> fieldNameToVarNameMap = ((SwitchAlt.Matching)alt).getFieldNameToVarNameMap();

                    Block caseBlock = new Block();

                    int[] caseLabels = new int[altTags.size()];
                    int index = 0;
                    DataConstructor firstDC = null;
                    // Must be a data constructor tag, since there are field names (see Expression.Switch.SwitchAlt).
                    for (final Object altTag : altTags) {
                        DataConstructor tagDC = (DataConstructor)altTag;
                        if (firstDC == null) {
                            firstDC = tagDC;
                        } else if (tagDC.getOrdinal() < firstDC.getOrdinal()) {
                            firstDC = tagDC;
                        }
                        caseBlock.addStatement(new LineComment(tagDC.getName().getQualifiedName()));
                        caseLabels[index] = tagDC.getOrdinal();
                        index++;
                    }

                    caseBlock.addStatement(new LineComment("Decompose data type to access members."));

                    // Create a new child variable scope to handle the alternate and any let variables it contains.
                    variableContext.pushJavaScope();

                    for (int iField = 0; iField < firstDC.getArity(); ++iField) {
                        FieldName fn = firstDC.getNthFieldName(iField);
                        String altVar = fieldNameToVarNameMap.get(fn);
                        if (altVar == null) {
                            continue;
                        }

                        QualifiedName qn = QualifiedName.make(currentModuleName, altVar);
                        TypeExpr fieldType = SCJavaDefn.getFieldTypeForDC(firstDC, fn);

                        VarInfo.DCMember vi = variableContext.addDCField(qn, fieldType);

                        boolean fieldIsStrict = !LECCMachineConfiguration.IGNORE_STRICTNESS_ANNOTATIONS;
                        for (final Object altTag : altTags) {
                            DataConstructor tagDC = (DataConstructor)altTag;
                            fieldIsStrict = fieldIsStrict & tagDC.isArgStrict(tagDC.getFieldIndex(fn));
                        }

                        if (fieldIsStrict) {
                            vi.setEvaluated(true);
                        }

                        String fieldName = SCJavaDefn.getJavaFieldNameFromFieldName(fn);
                        String fieldGetterName = "get" + fieldName;

                        // Generate the code defining the variable.
                        if (fieldIsStrict) {
                            if (SCJavaDefn.canTypeBeUnboxed(fieldType)) {
                                // This is a strict field of a primitive type so has both a boxed and unboxed form.
                                JavaExpression unboxedInitializer =
                                    new JavaExpression.MethodInvocation.Instance(caseVar,
                                                                                 fieldGetterName + "_As_" + SCJavaDefn.getNameForPrimitive(fieldType),
                                                                                 SCJavaDefn.typeExprToTypeName(fieldType),
                                                                                 JavaExpression.MethodInvocation.InvocationType.VIRTUAL);

                                vi.updateUnboxedVarDef(unboxedInitializer);
                                JavaExpression localVar = new LocalVariable(vi.getJavaName()+"$U", vi.getUnboxedType());
                                vi.updateUnboxedReference(localVar);
                                JavaExpression boxedDef = SCJavaDefn.boxExpression(vi.getUnboxedType(), localVar);
                                vi.updateStrictReference(boxedDef);
                                vi.updateLazyReference(boxedDef);
                            } else {
                                // RTValue altVarName = ((DCClass)caseVar).getFieldn();
                                JavaExpression initializer = new JavaExpression.MethodInvocation.Instance(caseVar, fieldGetterName, JavaTypeNames.RTVALUE, JavaExpression.MethodInvocation.InvocationType.VIRTUAL);
                                vi.updateStrictVarDef (initializer);
                                JavaExpression localVar = new LocalVariable(vi.getJavaName(), JavaTypeNames.RTVALUE);
                                vi.updateStrictReference(localVar);
                                vi.updateLazyReference(localVar);
                            }
                        } else {
                            // RTValue altVarName = ((DCClass)caseVar).getFieldn();
                            JavaExpression initializer = new JavaExpression.MethodInvocation.Instance(caseVar, fieldGetterName, JavaTypeNames.RTVALUE, JavaExpression.MethodInvocation.InvocationType.VIRTUAL);
                            vi.updateLazyVarDef (initializer);
                            JavaExpression localVar = new LocalVariable(vi.getJavaName(), JavaTypeNames.RTVALUE);
                            vi.updateLazyReference(localVar);

                            JavaExpression evaluatedVar = SCJavaDefn.createInvocation(localVar, SCJavaDefn.EVALUATE, SCJavaDefn.EXECUTION_CONTEXT_VAR);
                            vi.updateStrictReference(evaluatedVar);
                            if (SCJavaDefn.canTypeBeUnboxed(fieldType)) {
                                vi.updateUnboxedReference(SCJavaDefn.unboxValue(vi.getUnboxedType(), evaluatedVar));
                            }
                        }
                    }

                    // Compile the actual body of the alternate.
                    JavaStatement altStatement = genS_R(alt.getAltExpr(), variableContext);
                    caseBlock.addStatement(variableContext.popJavaScope());
                    caseBlock.addStatement(altStatement);

                    switchStatement.addCase(new SwitchStatement.IntCaseGroup(caseLabels, caseBlock));
                }
            }
        }

        // If no default case is provided, add case alternates for any missing data constructors.
        // Switches in java are marginally more efficient if the case tags cover a contiguous block.
        JavaStatement defaultCase = switchStatement.getDefaultStatement();
        if (defaultCase == null) {

            // Iterate over the array.  For each case not provided, treat as an error.
            List<Integer> intTagList = new ArrayList<Integer>();
            for (int i = 0; i < caseExistsArray.length; ++i) {