public void onMatch(RelOptRuleCall call) { CalcRel calc = (CalcRel) call.getRels()[0]; RexProgram program = calc.getProgram(); final List<RexNode> exprList = program.getExprList(); // Form a list of expressions with sub-expressions fully // expanded. final List<RexNode> expandedExprList = new ArrayList<RexNode>(exprList.size()); final RexShuttle shuttle = new RexShuttle() { public RexNode visitLocalRef(RexLocalRef localRef) { return expandedExprList.get(localRef.getIndex()); } }; for (RexNode expr : exprList) { expandedExprList.add(expr.accept(shuttle)); } if (reduceExpressions(calc, expandedExprList)) { final RexProgramBuilder builder = new RexProgramBuilder( calc.getChild().getRowType(), calc.getCluster().getRexBuilder()); List<RexLocalRef> list = new ArrayList<RexLocalRef>(); for (RexNode expr : expandedExprList) { list.add(builder.registerInput(expr)); } if (program.getCondition() != null) { final int conditionIndex = program.getCondition().getIndex(); final RexNode newConditionExp = expandedExprList.get(conditionIndex); if (newConditionExp.isAlwaysTrue()) { // condition is always TRUE - drop it } else if ((newConditionExp instanceof RexLiteral) || RexUtil.isNullLiteral(newConditionExp, true)) { // condition is always NULL or FALSE - replace calc // with empty call.transformTo(new EmptyRel(calc.getCluster(), calc.getRowType())); return; } else { builder.addCondition(list.get(conditionIndex)); } } int k = 0; for (RexLocalRef projectExpr : program.getProjectList()) { final int index = projectExpr.getIndex(); builder.addProject( list.get(index).getIndex(), program.getOutputRowType().getFieldList().get(k++).getName()); } call.transformTo( new CalcRel( calc.getCluster(), calc.getTraits(), calc.getChild(), calc.getRowType(), builder.getProgram(), calc.getCollationList())); // New plan is absolutely better than old plan. call.getPlanner().setImportance(calc, 0.0); } }
public static Expression translateCondition( List<Expression> inputs, RexProgram program, JavaTypeFactory typeFactory, List<Statement> list) { List<Expression> x = new RexToLixTranslator(program, typeFactory, inputs) .translate(list, Collections.singletonList(program.getCondition())); assert x.size() == 1; return x.get(0); }
// implement RelOptRule public void onMatch(RelOptRuleCall call) { CalcRel calcRel = (CalcRel) call.rels[0]; RexProgram program = calcRel.getProgram(); // check the projection List<Integer> projOrdinals = new ArrayList<Integer>(); RelDataType outputRowType = isProjectSimple(calcRel, projOrdinals); if (outputRowType == null) { return; } RexLocalRef condition = program.getCondition(); CompOperatorEnum compOp = CompOperatorEnum.COMP_NOOP; Integer[] filterOrdinals = {}; List<RexLiteral> filterLiterals = new ArrayList<RexLiteral>(); // check the condition if (condition != null) { RexNode filterExprs = program.expandLocalRef(condition); List<Integer> filterList = new ArrayList<Integer>(); List<CompOperatorEnum> op = new ArrayList<CompOperatorEnum>(); if (!isConditionSimple(calcRel, filterExprs, filterList, filterLiterals, op)) { return; } compOp = op.get(0); filterOrdinals = filterList.toArray(new Integer[filterList.size()]); } RelNode fennelInput = mergeTraitsAndConvert( calcRel.getTraits(), FennelRel.FENNEL_EXEC_CONVENTION, calcRel.getChild()); if (fennelInput == null) { return; } Integer[] projection = projOrdinals.toArray(new Integer[projOrdinals.size()]); FennelReshapeRel reshapeRel = new FennelReshapeRel( calcRel.getCluster(), fennelInput, projection, outputRowType, compOp, filterOrdinals, filterLiterals, new FennelRelParamId[] {}, new Integer[] {}, null); call.transformTo(reshapeRel); }
/** * Generates code for a Java expression satisfying the {@link org.eigenbase.runtime.TupleIter} * interface. The generated code allocates a {@link org.eigenbase.runtime.CalcTupleIter} with a * dynamic {@link org.eigenbase.runtime.TupleIter#fetchNext()} method. If the "abort on error" * flag is false, or an error handling tag is specified, then fetchNext is written to handle row * errors. * * <p>Row errors are handled by wrapping expressions that can fail with a try/catch block. A * caught RuntimeException is then published to an "connection variable." In the event that errors * can overflow, an "error buffering" flag allows them to be posted again on the next iteration of * fetchNext. * * @param implementor an object that implements relations as Java code * @param rel the relation to be implemented * @param childExp the implemented child of the relation * @param varInputRow the Java variable to use for the input row * @param inputRowType the rel data type of the input row * @param outputRowType the rel data type of the output row * @param program the rex program to implemented by the relation * @param tag an error handling tag * @return a Java expression satisfying the TupleIter interface */ public static Expression implementAbstractTupleIter( JavaRelImplementor implementor, JavaRel rel, Expression childExp, Variable varInputRow, final RelDataType inputRowType, final RelDataType outputRowType, RexProgram program, String tag) { MemberDeclarationList memberList = new MemberDeclarationList(); // Perform error recovery if continuing on errors or if // an error handling tag has been specified boolean errorRecovery = !abortOnError || (tag != null); // Error buffering should not be enabled unless error recovery is assert !errorBuffering || errorRecovery; // Allow backwards compatibility until all Farrago extensions are // satisfied with the new error handling semantics. The new semantics // include: // (1) cast input object to input row object outside of try block, // should be fine, at least for base Farrago // (2) maintain a columnIndex counter to better locate of error, // at the cost of a few cycles // (3) publish errors to the runtime context. FarragoRuntimeContext // now supports this API boolean backwardsCompatible = true; if (tag != null) { backwardsCompatible = false; } RelDataTypeFactory typeFactory = implementor.getTypeFactory(); OJClass outputRowClass = OJUtil.typeToOJClass(outputRowType, typeFactory); OJClass inputRowClass = OJUtil.typeToOJClass(inputRowType, typeFactory); Variable varOutputRow = implementor.newVariable(); FieldDeclaration inputRowVarDecl = new FieldDeclaration( new ModifierList(ModifierList.PRIVATE), TypeName.forOJClass(inputRowClass), varInputRow.toString(), null); FieldDeclaration outputRowVarDecl = new FieldDeclaration( new ModifierList(ModifierList.PRIVATE), TypeName.forOJClass(outputRowClass), varOutputRow.toString(), new AllocationExpression(outputRowClass, new ExpressionList())); // The method body for fetchNext, a main target of code generation StatementList nextMethodBody = new StatementList(); // First, post an error if it overflowed the previous time // if (pendingError) { // rc = handleRowError(...); // if (rc instanceof NoDataReason) { // return rc; // } // pendingError = false; // } if (errorBuffering) { // add to next method body... } // Most of fetchNext falls within a while() block. The while block // allows us to try multiple input rows against a filter condition // before returning a single row. // while (true) { // Object varInputObj = inputIterator.fetchNext(); // if (varInputObj instanceof TupleIter.NoDataReason) { // return varInputObj; // } // varInputRow = (InputRowClass) varInputObj; // int columnIndex = 0; // [calculation statements] // } StatementList whileBody = new StatementList(); Variable varInputObj = implementor.newVariable(); whileBody.add( new VariableDeclaration( OJUtil.typeNameForClass(Object.class), varInputObj.toString(), new MethodCall(new FieldAccess("inputIterator"), "fetchNext", new ExpressionList()))); StatementList ifNoDataReasonBody = new StatementList(); whileBody.add( new IfStatement( new InstanceofExpression( varInputObj, OJUtil.typeNameForClass(TupleIter.NoDataReason.class)), ifNoDataReasonBody)); ifNoDataReasonBody.add(new ReturnStatement(varInputObj)); // Push up the row declaration for new error handling so that the // input row is available to the error handler if (!backwardsCompatible) { whileBody.add(assignInputRow(inputRowClass, varInputRow, varInputObj)); } Variable varColumnIndex = null; if (errorRecovery && !backwardsCompatible) { // NOTE jvs 7-Oct-2006: Declare varColumnIndex as a member // (rather than a local) in case in the future we want // to decompose complex expressions into helper methods. varColumnIndex = implementor.newVariable(); FieldDeclaration varColumnIndexDecl = new FieldDeclaration( new ModifierList(ModifierList.PRIVATE), OJUtil.typeNameForClass(int.class), varColumnIndex.toString(), null); memberList.add(varColumnIndexDecl); whileBody.add( new ExpressionStatement( new AssignmentExpression( varColumnIndex, AssignmentExpression.EQUALS, Literal.makeLiteral(0)))); } // Calculator (projection, filtering) statements are later appended // to calcStmts. Typically, this target will be the while list itself. StatementList calcStmts; if (!errorRecovery) { calcStmts = whileBody; } else { // For error recovery, we wrap the calc statements // (e.g., everything but the code that reads rows from the // inputIterator) in a try/catch that publishes exceptions. calcStmts = new StatementList(); // try { /* calcStmts */ } // catch(RuntimeException ex) { // Object rc = connection.handleRowError(...); // [buffer error if necessary] // } StatementList catchStmts = new StatementList(); if (backwardsCompatible) { catchStmts.add( new ExpressionStatement( new MethodCall( new MethodCall( OJUtil.typeNameForClass(EigenbaseTrace.class), "getStatementTracer", null), "log", new ExpressionList( new FieldAccess(OJUtil.typeNameForClass(Level.class), "WARNING"), Literal.makeLiteral("java calc exception"), new FieldAccess("ex"))))); } else { Variable varRc = implementor.newVariable(); ExpressionList handleRowErrorArgs = new ExpressionList(varInputRow, new FieldAccess("ex"), varColumnIndex); handleRowErrorArgs.add(Literal.makeLiteral(tag)); catchStmts.add( new VariableDeclaration( OJUtil.typeNameForClass(Object.class), varRc.toString(), new MethodCall( implementor.getConnectionVariable(), "handleRowError", handleRowErrorArgs))); // Buffer an error if it overflowed // if (rc instanceof NoDataReason) { // pendingError = true; // [save error state] // return rc; // } if (errorBuffering) { // add to catch statements... } } CatchList catchList = new CatchList( new CatchBlock( new Parameter(OJUtil.typeNameForClass(RuntimeException.class), "ex"), catchStmts)); TryStatement tryStmt = new TryStatement(calcStmts, catchList); whileBody.add(tryStmt); } if (backwardsCompatible) { calcStmts.add(assignInputRow(inputRowClass, varInputRow, varInputObj)); } StatementList condBody; RexToOJTranslator translator = implementor.newStmtTranslator(rel, calcStmts, memberList); try { translator.pushProgram(program); if (program.getCondition() != null) { // TODO jvs 8-Oct-2006: move condition to its own // method if big, as below for project exprs. condBody = new StatementList(); RexNode rexIsTrue = rel.getCluster() .getRexBuilder() .makeCall(SqlStdOperatorTable.isTrueOperator, program.getCondition()); Expression conditionExp = translator.translateRexNode(rexIsTrue); calcStmts.add(new IfStatement(conditionExp, condBody)); } else { condBody = calcStmts; } RelDataTypeField[] fields = outputRowType.getFields(); final List<RexLocalRef> projectRefList = program.getProjectList(); int i = -1; for (RexLocalRef rhs : projectRefList) { // NOTE jvs 14-Sept-2006: Put complicated project expressions // into their own method, otherwise a big select list can easily // blow the 64K Java limit on method bytecode size. Make // methods private final in the hopes that they will get inlined // JIT. For now we decide "complicated" based on the size of // the generated Java parse tree. A big enough select list of // simple expressions could still blow the limit, so we may need // to group them together, sub-divide, etc. StatementList projMethodBody = new StatementList(); if (errorRecovery && !backwardsCompatible) { projMethodBody.add( new ExpressionStatement( new UnaryExpression(varColumnIndex, UnaryExpression.POST_INCREMENT))); } ++i; RexToOJTranslator projTranslator = translator.push(projMethodBody); String javaFieldName = Util.toJavaId(fields[i].getName(), i); Expression lhs = new FieldAccess(varOutputRow, javaFieldName); projTranslator.translateAssignment(fields[i], lhs, rhs); int complexity = OJUtil.countParseTreeNodes(projMethodBody); // REVIEW: HCP 5/18/2011 // The projMethod should be checked // for causing possible compiler errors caused by the use of // variables declared in other projMethods. Also the // local declaration of variabled used by other proj methods // should also be checked. // Fixing for backswing integration 14270 // TODO: check if abstracting this method body will cause // a compiler error if (true) { // No method needed; just append. condBody.addAll(projMethodBody); continue; } // Need a separate method. String projMethodName = "calc_" + varOutputRow.toString() + "_f_" + i; MemberDeclaration projMethodDecl = new MethodDeclaration( new ModifierList(ModifierList.PRIVATE | ModifierList.FINAL), TypeName.forOJClass(OJSystem.VOID), projMethodName, new ParameterList(), null, projMethodBody); memberList.add(projMethodDecl); condBody.add(new ExpressionStatement(new MethodCall(projMethodName, new ExpressionList()))); } } finally { translator.popProgram(program); } condBody.add(new ReturnStatement(varOutputRow)); WhileStatement whileStmt = new WhileStatement(Literal.makeLiteral(true), whileBody); nextMethodBody.add(whileStmt); MemberDeclaration fetchNextMethodDecl = new MethodDeclaration( new ModifierList(ModifierList.PUBLIC), OJUtil.typeNameForClass(Object.class), "fetchNext", new ParameterList(), null, nextMethodBody); // The restart() method should reset variables used to buffer errors // pendingError = false if (errorBuffering) { // declare refinement of restart() and add to member list... } memberList.add(inputRowVarDecl); memberList.add(outputRowVarDecl); memberList.add(fetchNextMethodDecl); Expression newTupleIterExp = new AllocationExpression( OJUtil.typeNameForClass(CalcTupleIter.class), new ExpressionList(childExp), memberList); return newTupleIterExp; }