private static JoinNode getJoinNode() { return new JoinNode(new InnerJoinOperatorBase<String, String, String, FlatJoinFunction<String, String, String>>(new DummyFlatJoinFunction<String>(), new BinaryOperatorInformation<String, String, String>(BasicTypeInfo.STRING_TYPE_INFO, BasicTypeInfo.STRING_TYPE_INFO, BasicTypeInfo.STRING_TYPE_INFO), new int[] {1}, new int[] {2}, "join op")); } }
FlatJoinFunction<String, String,Integer> > base = new InnerJoinOperatorBase(joiner, new BinaryOperatorInformation(BasicTypeInfo.STRING_TYPE_INFO, BasicTypeInfo.STRING_TYPE_INFO, BasicTypeInfo.INT_TYPE_INFO), new int[0], new int[0], "TestJoiner");
RichFlatJoinFunction<String, String, Integer>> base = new InnerJoinOperatorBase<String, String, Integer, RichFlatJoinFunction<String, String, Integer>>(joiner, new BinaryOperatorInformation<String, String, Integer>(BasicTypeInfo.STRING_TYPE_INFO, BasicTypeInfo.STRING_TYPE_INFO,
String>, Tuple2<Double, String>>> base = new InnerJoinOperatorBase<Tuple3<String, Double, Integer>, Tuple2<Integer, String>, Tuple2<Double, String>, FlatJoinFunction<Tuple3<String, Double, Integer>, Tuple2<Integer, String>, Tuple2<Double, String>>>(joiner, binaryOpInfo, leftKeys, rightKeys, taskName);
@SuppressWarnings("unchecked") public JoinOperatorBase<?, ?, OUT, ?> build() { JoinOperatorBase<?, ?, OUT, ?> operator; if (joinType.isOuter()) { operator = new OuterJoinOperatorBase<>( udf, new BinaryOperatorInformation(input1Type, input2Type, resultType), this.keys1.computeLogicalKeyPositions(), this.keys2.computeLogicalKeyPositions(), this.name, getOuterJoinType()); } else { operator = new InnerJoinOperatorBase<>( udf, new BinaryOperatorInformation(input1Type, input2Type, resultType), this.keys1.computeLogicalKeyPositions(), this.keys2.computeLogicalKeyPositions(), this.name); } operator.setFirstInput(input1); operator.setSecondInput(input2); operator.setParallelism(parallelism); operator.setCustomPartitioner(partitioner); operator.setJoinHint(joinHint); return operator; }
@SuppressWarnings("unchecked") public JoinOperatorBase<?, ?, OUT, ?> build() { JoinOperatorBase<?, ?, OUT, ?> operator; if (joinType.isOuter()) { operator = new OuterJoinOperatorBase<>( udf, new BinaryOperatorInformation(input1Type, input2Type, resultType), this.keys1.computeLogicalKeyPositions(), this.keys2.computeLogicalKeyPositions(), this.name, getOuterJoinType()); } else { operator = new InnerJoinOperatorBase<>( udf, new BinaryOperatorInformation(input1Type, input2Type, resultType), this.keys1.computeLogicalKeyPositions(), this.keys2.computeLogicalKeyPositions(), this.name); } operator.setFirstInput(input1); operator.setSecondInput(input2); operator.setParallelism(parallelism); operator.setCustomPartitioner(partitioner); operator.setJoinHint(joinHint); return operator; }
@SuppressWarnings("unchecked") public JoinOperatorBase<?, ?, OUT, ?> build() { JoinOperatorBase<?, ?, OUT, ?> operator; if (joinType.isOuter()) { operator = new OuterJoinOperatorBase<>( udf, new BinaryOperatorInformation(input1Type, input2Type, resultType), this.keys1.computeLogicalKeyPositions(), this.keys2.computeLogicalKeyPositions(), this.name, getOuterJoinType()); } else { operator = new InnerJoinOperatorBase<>( udf, new BinaryOperatorInformation(input1Type, input2Type, resultType), this.keys1.computeLogicalKeyPositions(), this.keys2.computeLogicalKeyPositions(), this.name); } operator.setFirstInput(input1); operator.setSecondInput(input2); operator.setParallelism(parallelism); operator.setCustomPartitioner(partitioner); operator.setJoinHint(joinHint); return operator; }