8172_impact_indicators_workflow #284

Merged
miriam.baglioni merged 49 commits from 8172_impact_indicators_workflow into beta 2023-08-14 15:50:48 +02:00
23 changed files with 2508 additions and 75 deletions

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@ -6,13 +6,14 @@ import static eu.dnetlib.dhp.common.SparkSessionSupport.runWithSparkSession;
import java.io.Serializable;
import java.util.List;
import java.util.Optional;
import java.util.stream.Collectors;
import org.apache.commons.io.IOUtils;
import org.apache.hadoop.io.Text;
import org.apache.hadoop.io.compress.GzipCodec;
import org.apache.hadoop.mapred.SequenceFileOutputFormat;
import org.apache.spark.SparkConf;
import org.apache.spark.api.java.JavaPairRDD;
import org.apache.spark.api.java.JavaRDD;
import org.apache.spark.api.java.JavaSparkContext;
import org.apache.spark.api.java.function.MapFunction;
@ -24,8 +25,9 @@ import org.slf4j.LoggerFactory;
import com.fasterxml.jackson.databind.ObjectMapper;
import eu.dnetlib.dhp.actionmanager.bipmodel.BipDeserialize;
import eu.dnetlib.dhp.actionmanager.bipmodel.BipScore;
import eu.dnetlib.dhp.actionmanager.bipmodel.score.deserializers.BipProjectModel;
import eu.dnetlib.dhp.actionmanager.bipmodel.score.deserializers.BipResultModel;
import eu.dnetlib.dhp.application.ArgumentApplicationParser;
import eu.dnetlib.dhp.common.HdfsSupport;
import eu.dnetlib.dhp.schema.action.AtomicAction;
@ -40,7 +42,6 @@ import scala.Tuple2;
*/
public class SparkAtomicActionScoreJob implements Serializable {
private static final String DOI = "doi";
private static final Logger log = LoggerFactory.getLogger(SparkAtomicActionScoreJob.class);
private static final ObjectMapper OBJECT_MAPPER = new ObjectMapper();
@ -56,18 +57,17 @@ public class SparkAtomicActionScoreJob implements Serializable {
parser.parseArgument(args);
Boolean isSparkSessionManaged = Optional
.ofNullable(parser.get("isSparkSessionManaged"))
.map(Boolean::valueOf)
.orElse(Boolean.TRUE);
Boolean isSparkSessionManaged = isSparkSessionManaged(parser);
log.info("isSparkSessionManaged: {}", isSparkSessionManaged);
final String inputPath = parser.get("inputPath");
log.info("inputPath {}: ", inputPath);
final String resultsInputPath = parser.get("resultsInputPath");
log.info("resultsInputPath: {}", resultsInputPath);
final String projectsInputPath = parser.get("projectsInputPath");
log.info("projectsInputPath: {}", projectsInputPath);
final String outputPath = parser.get("outputPath");
log.info("outputPath {}: ", outputPath);
log.info("outputPath: {}", outputPath);
SparkConf conf = new SparkConf();
@ -76,17 +76,45 @@ public class SparkAtomicActionScoreJob implements Serializable {
isSparkSessionManaged,
spark -> {
removeOutputDir(spark, outputPath);
prepareResults(spark, inputPath, outputPath);
JavaPairRDD<Text, Text> resultsRDD = prepareResults(spark, resultsInputPath, outputPath);
JavaPairRDD<Text, Text> projectsRDD = prepareProjects(spark, projectsInputPath, outputPath);
resultsRDD
.union(projectsRDD)
.saveAsHadoopFile(
outputPath, Text.class, Text.class, SequenceFileOutputFormat.class, GzipCodec.class);
});
}
private static <I extends Result> void prepareResults(SparkSession spark, String bipScorePath, String outputPath) {
private static <I extends Project> JavaPairRDD<Text, Text> prepareProjects(SparkSession spark, String inputPath,
String outputPath) {
// read input bip project scores
Dataset<BipProjectModel> projectScores = readPath(spark, inputPath, BipProjectModel.class);
return projectScores.map((MapFunction<BipProjectModel, Project>) bipProjectScores -> {
Project project = new Project();
project.setId(bipProjectScores.getProjectId());
project.setMeasures(bipProjectScores.toMeasures());
return project;
}, Encoders.bean(Project.class))
.toJavaRDD()
.map(p -> new AtomicAction(Project.class, p))
.mapToPair(
aa -> new Tuple2<>(new Text(aa.getClazz().getCanonicalName()),
new Text(OBJECT_MAPPER.writeValueAsString(aa))));
}
private static <I extends Result> JavaPairRDD<Text, Text> prepareResults(SparkSession spark, String bipScorePath,
String outputPath) {
final JavaSparkContext sc = JavaSparkContext.fromSparkContext(spark.sparkContext());
JavaRDD<BipDeserialize> bipDeserializeJavaRDD = sc
JavaRDD<BipResultModel> bipDeserializeJavaRDD = sc
.textFile(bipScorePath)
.map(item -> OBJECT_MAPPER.readValue(item, BipDeserialize.class));
.map(item -> OBJECT_MAPPER.readValue(item, BipResultModel.class));
Dataset<BipScore> bipScores = spark
.createDataset(bipDeserializeJavaRDD.flatMap(entry -> entry.keySet().stream().map(key -> {
@ -96,24 +124,20 @@ public class SparkAtomicActionScoreJob implements Serializable {
return bs;
}).collect(Collectors.toList()).iterator()).rdd(), Encoders.bean(BipScore.class));
bipScores
return bipScores.map((MapFunction<BipScore, Result>) bs -> {
Result ret = new Result();
.map((MapFunction<BipScore, Result>) bs -> {
Result ret = new Result();
ret.setId(bs.getId());
ret.setId(bs.getId());
ret.setMeasures(getMeasure(bs));
ret.setMeasures(getMeasure(bs));
return ret;
}, Encoders.bean(Result.class))
return ret;
}, Encoders.bean(Result.class))
.toJavaRDD()
.map(p -> new AtomicAction(Result.class, p))
.mapToPair(
aa -> new Tuple2<>(new Text(aa.getClazz().getCanonicalName()),
new Text(OBJECT_MAPPER.writeValueAsString(aa))))
.saveAsHadoopFile(outputPath, Text.class, Text.class, SequenceFileOutputFormat.class);
new Text(OBJECT_MAPPER.writeValueAsString(aa))));
}
private static List<Measure> getMeasure(BipScore value) {
@ -159,12 +183,4 @@ public class SparkAtomicActionScoreJob implements Serializable {
HdfsSupport.remove(path, spark.sparkContext().hadoopConfiguration());
}
public static <R> Dataset<R> readPath(
SparkSession spark, String inputPath, Class<R> clazz) {
return spark
.read()
.textFile(inputPath)
.map((MapFunction<String, R>) value -> OBJECT_MAPPER.readValue(value, clazz), Encoders.bean(clazz));
}
}

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@ -0,0 +1,74 @@
package eu.dnetlib.dhp.actionmanager.bipmodel.score.deserializers;
import static eu.dnetlib.dhp.actionmanager.Constants.*;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.List;
import com.opencsv.bean.CsvBindByPosition;
import eu.dnetlib.dhp.schema.common.ModelConstants;
import eu.dnetlib.dhp.schema.oaf.KeyValue;
import eu.dnetlib.dhp.schema.oaf.Measure;
import eu.dnetlib.dhp.schema.oaf.utils.OafMapperUtils;
import lombok.AllArgsConstructor;
import lombok.Getter;
import lombok.NoArgsConstructor;
import lombok.Setter;
@NoArgsConstructor
@AllArgsConstructor
@Getter
@Setter
public class BipProjectModel {
String projectId;
String numOfInfluentialResults;
String numOfPopularResults;
String totalImpulse;
String totalCitationCount;
// each project bip measure has exactly one value, hence one key-value pair
private Measure createMeasure(String measureId, String measureValue) {
KeyValue kv = new KeyValue();
kv.setKey("score");
kv.setValue(measureValue);
kv
.setDataInfo(
OafMapperUtils
.dataInfo(
false,
UPDATE_DATA_INFO_TYPE,
true,
false,
OafMapperUtils
.qualifier(
UPDATE_MEASURE_BIP_CLASS_ID,
UPDATE_CLASS_NAME,
ModelConstants.DNET_PROVENANCE_ACTIONS,
ModelConstants.DNET_PROVENANCE_ACTIONS),
""));
Measure measure = new Measure();
measure.setId(measureId);
measure.setUnit(Collections.singletonList(kv));
return measure;
}
public List<Measure> toMeasures() {
return Arrays
.asList(
createMeasure("numOfInfluentialResults", numOfInfluentialResults),
createMeasure("numOfPopularResults", numOfPopularResults),
createMeasure("totalImpulse", totalImpulse),
createMeasure("totalCitationCount", totalCitationCount));
}
}

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@ -1,19 +1,21 @@
package eu.dnetlib.dhp.actionmanager.bipmodel;
package eu.dnetlib.dhp.actionmanager.bipmodel.score.deserializers;
import java.io.Serializable;
import java.util.ArrayList;
import java.util.HashMap;
import java.util.List;
import eu.dnetlib.dhp.actionmanager.bipmodel.Score;
/**
* Class that maps the model of the bipFinder! input data.
* Only needed for deserialization purposes
*/
public class BipDeserialize extends HashMap<String, List<Score>> implements Serializable {
public class BipResultModel extends HashMap<String, List<Score>> implements Serializable {
public BipDeserialize() {
public BipResultModel() {
super();
}

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@ -24,8 +24,8 @@ import org.slf4j.LoggerFactory;
import com.fasterxml.jackson.databind.ObjectMapper;
import eu.dnetlib.dhp.actionmanager.bipmodel.BipDeserialize;
import eu.dnetlib.dhp.actionmanager.bipmodel.BipScore;
import eu.dnetlib.dhp.actionmanager.bipmodel.score.deserializers.BipResultModel;
import eu.dnetlib.dhp.application.ArgumentApplicationParser;
import eu.dnetlib.dhp.common.HdfsSupport;
import eu.dnetlib.dhp.schema.common.ModelConstants;
@ -82,9 +82,9 @@ public class PrepareBipFinder implements Serializable {
final JavaSparkContext sc = JavaSparkContext.fromSparkContext(spark.sparkContext());
JavaRDD<BipDeserialize> bipDeserializeJavaRDD = sc
JavaRDD<BipResultModel> bipDeserializeJavaRDD = sc
.textFile(inputPath)
.map(item -> OBJECT_MAPPER.readValue(item, BipDeserialize.class));
.map(item -> OBJECT_MAPPER.readValue(item, BipResultModel.class));
spark
.createDataset(bipDeserializeJavaRDD.flatMap(entry -> entry.keySet().stream().map(key -> {

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@ -6,9 +6,15 @@
"paramRequired": false
},
{
"paramName": "ip",
"paramLongName": "inputPath",
"paramDescription": "the URL from where to get the programme file",
"paramName": "rip",
"paramLongName": "resultsInputPath",
"paramDescription": "the URL from where to get the input file for results",
"paramRequired": true
},
{
"paramName": "pip",
"paramLongName": "projectsInputPath",
"paramDescription": "the URL from where to get the input file for projects",
"paramRequired": true
},
{

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@ -6,7 +6,8 @@ import static org.junit.jupiter.api.Assertions.*;
import java.io.IOException;
import java.nio.file.Files;
import java.nio.file.Path;
import java.util.List;
import javax.xml.crypto.Data;
import org.apache.commons.io.FileUtils;
import org.apache.hadoop.io.Text;
@ -27,7 +28,9 @@ import org.slf4j.LoggerFactory;
import com.fasterxml.jackson.databind.ObjectMapper;
import eu.dnetlib.dhp.schema.action.AtomicAction;
import eu.dnetlib.dhp.schema.oaf.Publication;
import eu.dnetlib.dhp.schema.oaf.KeyValue;
import eu.dnetlib.dhp.schema.oaf.OafEntity;
import eu.dnetlib.dhp.schema.oaf.Project;
import eu.dnetlib.dhp.schema.oaf.Result;
public class SparkAtomicActionScoreJobTest {
@ -37,8 +40,8 @@ public class SparkAtomicActionScoreJobTest {
private static SparkSession spark;
private static Path workingDir;
private static final Logger log = LoggerFactory
.getLogger(SparkAtomicActionScoreJobTest.class);
private static final Logger log = LoggerFactory.getLogger(SparkAtomicActionScoreJobTest.class);
@BeforeAll
public static void beforeAll() throws IOException {
@ -69,47 +72,64 @@ public class SparkAtomicActionScoreJobTest {
spark.stop();
}
@Test
void testMatch() throws Exception {
String bipScoresPath = getClass()
.getResource("/eu/dnetlib/dhp/actionmanager/bipfinder/bip_scores_oid.json")
.getPath();
private void runJob(String resultsInputPath, String projectsInputPath, String outputPath) throws Exception {
SparkAtomicActionScoreJob
.main(
new String[] {
"-isSparkSessionManaged",
Boolean.FALSE.toString(),
"-inputPath",
bipScoresPath,
"-outputPath",
workingDir.toString() + "/actionSet"
"-isSparkSessionManaged", Boolean.FALSE.toString(),
"-resultsInputPath", resultsInputPath,
"-projectsInputPath", projectsInputPath,
"-outputPath", outputPath,
});
}
@Test
void testScores() throws Exception {
String resultsInputPath = getClass()
.getResource("/eu/dnetlib/dhp/actionmanager/bipfinder/result_bip_scores.json")
.getPath();
String projectsInputPath = getClass()
.getResource("/eu/dnetlib/dhp/actionmanager/bipfinder/project_bip_scores.json")
.getPath();
String outputPath = workingDir.toString() + "/actionSet";
// execute the job to generate the action sets for result scores
runJob(resultsInputPath, projectsInputPath, outputPath);
final JavaSparkContext sc = new JavaSparkContext(spark.sparkContext());
JavaRDD<Result> tmp = sc
.sequenceFile(workingDir.toString() + "/actionSet", Text.class, Text.class)
JavaRDD<OafEntity> tmp = sc
.sequenceFile(outputPath, Text.class, Text.class)
.map(value -> OBJECT_MAPPER.readValue(value._2().toString(), AtomicAction.class))
.map(aa -> ((Result) aa.getPayload()));
.map(aa -> ((OafEntity) aa.getPayload()));
assertEquals(4, tmp.count());
assertEquals(8, tmp.count());
Dataset<Result> verificationDataset = spark.createDataset(tmp.rdd(), Encoders.bean(Result.class));
Dataset<OafEntity> verificationDataset = spark.createDataset(tmp.rdd(), Encoders.bean(OafEntity.class));
verificationDataset.createOrReplaceTempView("result");
Dataset<Row> execVerification = spark
Dataset<Row> testDataset = spark
.sql(
"Select p.id oaid, mes.id, mUnit.value from result p " +
"lateral view explode(measures) m as mes " +
"lateral view explode(mes.unit) u as mUnit ");
Assertions.assertEquals(12, execVerification.count());
// execVerification.show();
Assertions.assertEquals(28, testDataset.count());
assertResultImpactScores(testDataset);
assertProjectImpactScores(testDataset);
}
void assertResultImpactScores(Dataset<Row> testDataset) {
Assertions
.assertEquals(
"6.63451994567e-09", execVerification
"6.63451994567e-09", testDataset
.filter(
"oaid='50|arXiv_dedup_::4a2d5fd8d71daec016c176ec71d957b1' " +
"and id = 'influence'")
@ -119,7 +139,7 @@ public class SparkAtomicActionScoreJobTest {
.getString(0));
Assertions
.assertEquals(
"0.348694533145", execVerification
"0.348694533145", testDataset
.filter(
"oaid='50|arXiv_dedup_::4a2d5fd8d71daec016c176ec71d957b1' " +
"and id = 'popularity_alt'")
@ -129,7 +149,7 @@ public class SparkAtomicActionScoreJobTest {
.getString(0));
Assertions
.assertEquals(
"2.16094680115e-09", execVerification
"2.16094680115e-09", testDataset
.filter(
"oaid='50|arXiv_dedup_::4a2d5fd8d71daec016c176ec71d957b1' " +
"and id = 'popularity'")
@ -137,7 +157,49 @@ public class SparkAtomicActionScoreJobTest {
.collectAsList()
.get(0)
.getString(0));
}
void assertProjectImpactScores(Dataset<Row> testDataset) throws Exception {
Assertions
.assertEquals(
"0", testDataset
.filter(
"oaid='40|nih_________::c02a8233e9b60f05bb418f0c9b714833' " +
"and id = 'numOfInfluentialResults'")
.select("value")
.collectAsList()
.get(0)
.getString(0));
Assertions
.assertEquals(
"1", testDataset
.filter(
"oaid='40|nih_________::c02a8233e9b60f05bb418f0c9b714833' " +
"and id = 'numOfPopularResults'")
.select("value")
.collectAsList()
.get(0)
.getString(0));
Assertions
.assertEquals(
"25", testDataset
.filter(
"oaid='40|nih_________::c02a8233e9b60f05bb418f0c9b714833' " +
"and id = 'totalImpulse'")
.select("value")
.collectAsList()
.get(0)
.getString(0));
Assertions
.assertEquals(
"43", testDataset
.filter(
"oaid='40|nih_________::c02a8233e9b60f05bb418f0c9b714833' " +
"and id = 'totalCitationCount'")
.select("value")
.collectAsList()
.get(0)
.getString(0));
}
}

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@ -92,7 +92,7 @@ public class PrepareH2020ProgrammeTest {
Assertions.assertEquals(0, verificationDataset.filter("classification = ''").count());
//tmp.foreach(csvProgramme -> System.out.println(OBJECT_MAPPER.writeValueAsString(csvProgramme)));
// tmp.foreach(csvProgramme -> System.out.println(OBJECT_MAPPER.writeValueAsString(csvProgramme)));
Assertions
.assertEquals(

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@ -98,7 +98,7 @@ public class ReadProjectsTest {
Assertions.assertEquals("H2020-EU.1.3.", project.getLegalBasis());
Assertions.assertEquals("MSCA-IF-2019", project.getTopics());
//tmp.foreach(p -> System.out.println(OBJECT_MAPPER.writeValueAsString(p)));
// tmp.foreach(p -> System.out.println(OBJECT_MAPPER.writeValueAsString(p)));
}
}

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@ -93,7 +93,7 @@ public class ReadTopicTest {
Assertions.assertEquals("Individual Fellowships", topic.getTitle());
Assertions.assertEquals("MSCA-IF-2019", topic.getTopic());
//tmp.foreach(p -> System.out.println(OBJECT_MAPPER.writeValueAsString(p)));
// tmp.foreach(p -> System.out.println(OBJECT_MAPPER.writeValueAsString(p)));
}
}

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@ -0,0 +1,4 @@
{"projectId":"40|nsf_________::d93e50d22374a1cf59f6a232413ea027","numOfInfluentialResults":0,"numOfPopularResults":10,"totalImpulse":181,"totalCitationCount":235}
{"projectId":"40|nih_________::1c93debc7085e440f245fbe70b2e8b21","numOfInfluentialResults":14,"numOfPopularResults":17,"totalImpulse":1558,"totalCitationCount":4226}
{"projectId":"40|nih_________::c02a8233e9b60f05bb418f0c9b714833","numOfInfluentialResults":0,"numOfPopularResults":1,"totalImpulse":25,"totalCitationCount":43}
{"projectId":"40|corda_______::d91dcf3a87dd7f72248fab0b8a4ba273","numOfInfluentialResults":2,"numOfPopularResults":3,"totalImpulse":78,"totalCitationCount":178}

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@ -0,0 +1,36 @@
# Ranking Workflow for OpenAIRE Publications
This project contains the files for running a paper ranking workflow on the openaire graph using apache oozie.
All scripts are written in python and the project setup follows the typical oozie workflow structure:
- a workflow.xml file containing the workflow specification
- a job.properties file specifying parameter values for the parameters used by the workflow
- a set of python scripts used by the workflow
**NOTE**: the workflow depends on the external library of ranking scripts called [BiP! Ranker](https://github.com/athenarc/Bip-Ranker).
You can check out a specific tag/release of BIP! Ranker using maven, as described in the following section.
## Build and deploy
Use the following command for packaging:
```
mvn package -Poozie-package -Dworkflow.source.dir=eu/dnetlib/dhp/oa/graph/impact_indicators -DskipTests
```
Deploy and run:
```
mvn package -Poozie-package,deploy,run -Dworkflow.source.dir=eu/dnetlib/dhp/oa/graph/impact_indicators -DskipTests
```
Note: edit the property `bip.ranker.tag` of the `pom.xml` file to specify the tag of [BIP-Ranker](https://github.com/athenarc/Bip-Ranker) that you want to use.
Job info and logs:
```
export OOZIE_URL=http://iis-cdh5-test-m3:11000/oozie
oozie job -info <jobId>
oozie job -log <jobId>
```
where `jobId` is the id of the job returned by the `run_workflow.sh` script.

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@ -0,0 +1,62 @@
<?xml version="1.0" encoding="UTF-8"?>
<project xmlns="http://maven.apache.org/POM/4.0.0"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://maven.apache.org/POM/4.0.0 http://maven.apache.org/xsd/maven-4.0.0.xsd">
<modelVersion>4.0.0</modelVersion>
<parent>
<groupId>eu.dnetlib.dhp</groupId>
<artifactId>dhp-workflows</artifactId>
<version>1.2.5-SNAPSHOT</version>
</parent>
<artifactId>dhp-impact-indicators</artifactId>
<properties>
<maven.compiler.source>8</maven.compiler.source>
<maven.compiler.target>8</maven.compiler.target>
<project.build.sourceEncoding>UTF-8</project.build.sourceEncoding>
<!-- Use this property to fetch a specific tag -->
<bip.ranker.tag>v1.0.0</bip.ranker.tag>
</properties>
<scm>
<url>https://github.com/athenarc/Bip-Ranker</url>
<connection>scm:git:https://github.com/athenarc/Bip-Ranker.git</connection>
</scm>
<build>
<plugins>
<plugin>
<groupId>org.apache.maven.plugins</groupId>
<artifactId>maven-scm-plugin</artifactId>
<version>1.8.1</version>
<configuration>
<connectionType>connection</connectionType>
<scmVersionType>tag</scmVersionType><!-- 'branch' can also be provided here -->
<scmVersion>${bip.ranker.tag}</scmVersion><!-- in case of scmVersionType == 'branch', this field points to the branch name -->
<checkoutDirectory>${project.build.directory}/${oozie.package.file.name}/${oozieAppDir}/bip-ranker</checkoutDirectory>
</configuration>
<executions>
<execution>
<id>checkout-bip-ranker</id>
<phase>prepare-package</phase>
<goals>
<goal>checkout</goal>
</goals>
</execution>
</executions>
</plugin>
</plugins>
</build>
<dependencies>
<dependency>
<groupId>eu.dnetlib.dhp</groupId>
<artifactId>dhp-aggregation</artifactId>
<version>${projectVersion}</version>
<scope>compile</scope>
</dependency>
</dependencies>
</project>

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@ -0,0 +1,105 @@
# The following set of properties are defined in https://support.openaire.eu/projects/openaire/wiki/Hadoop_clusters
# and concern the parameterization required for running workflows on the @GARR cluster
# --- You can override the following properties (if needed) coming from your ~/.dhp/application.properties ---
# dhp.hadoop.frontend.temp.dir=/home/ilias.kanellos
# dhp.hadoop.frontend.user.name=ilias.kanellos
# dhp.hadoop.frontend.host.name=iis-cdh5-test-gw.ocean.icm.edu.pl
# dhp.hadoop.frontend.port.ssh=22
# oozieServiceLoc=http://iis-cdh5-test-m3:11000/oozie
# jobTracker=yarnRM
# nameNode=hdfs://nameservice1
# oozie.execution.log.file.location = target/extract-and-run-on-remote-host.log
# maven.executable=mvn
# Some memory and driver settings for more demanding tasks
sparkHighDriverMemory=20G
sparkNormalDriverMemory=10G
sparkHighExecutorMemory=20G
sparkNormalExecutorMemory=10G
sparkExecutorCores=4
sparkShufflePartitions=7680
# The above is given differently in an example I found online
oozie.action.sharelib.for.spark=spark2
oozieActionShareLibForSpark2=spark2
spark2YarnHistoryServerAddress=http://iis-cdh5-test-gw.ocean.icm.edu.pl:18089
spark2EventLogDir=/user/spark/spark2ApplicationHistory
sparkSqlWarehouseDir=/user/hive/warehouse
hiveMetastoreUris=thrift://iis-cdh5-test-m3.ocean.icm.edu.pl:9083
# This MAY avoid the no library used error
oozie.use.system.libpath=true
# Some stuff copied from openaire's jobs
spark2ExtraListeners=com.cloudera.spark.lineage.NavigatorAppListener
spark2SqlQueryExecutionListeners=com.cloudera.spark.lineage.NavigatorQueryListener
# Some stuff copied from openaire's jobs
spark2ExtraListeners=com.cloudera.spark.lineage.NavigatorAppListener
spark2SqlQueryExecutionListeners=com.cloudera.spark.lineage.NavigatorQueryListener
# ------------------------------------------------------------------------------ #
# The following set of properties are my own custom ones
# Based on the page linked to at the start of the file, if we use yarn as a resource manager, its address is given as follows
resourceManager=http://iis-cdh5-test-m2.ocean.icm.edu.pl:8088/cluster
# current year used when creating graph / by some ranking methods
currentYear=2023
# Alpha value for pagerank
pageRankAlpha=0.5
# AttRank values
attrankAlpha=0.2
attrankBeta=0.5
attrankGamma=0.3
attrankRho=-0.16
# attrankCurrentYear=2023
attrankStartYear=2021
# Ram values
ramGamma=0.6
# ramCurrentYear=2023
# Convergence error for pagerank
convergenceError=0.000000000001
# I think this should be the oozie workflow directory
# oozieWorkflowPath=user/ilias.kanellos/workflow_example/
# Directory where json data containing scores will be output
bipScorePath=${workingDir}/openaire_universe_scores/
# Directory where dataframes are checkpointed
checkpointDir=${nameNode}/${workingDir}/check/
# The directory for the doi-based bip graph
# bipGraphFilePath=${nameNode}/${workingDir}/bipdbv8_graph
# The folder from which synonyms of openaire-ids are read
# openaireDataInput=${nameNode}/tmp/beta_provision/graph/21_graph_cleaned/
openaireDataInput=/tmp/prod_provision/graph/18_graph_blacklisted
# A folder where we will write the openaire to doi mapping
synonymFolder=${nameNode}/${workingDir}/openaireid_to_dois/
# This will be where we store the openaire graph input. They told us on GARR to use a directory under /data
openaireGraphInputPath=${nameNode}/${workingDir}/openaire_id_graph
# The workflow application path
wfAppPath=${oozieTopWfApplicationPath}
# The following is needed as a property of a workflow
#oozie.wf.application.path=${wfAppPath}
oozie.wf.application.path=${oozieTopWfApplicationPath}
# Path where the final output should be?
actionSetOutputPath=${workingDir}/bip_actionsets
# The directory to store project impact indicators
projectImpactIndicatorsOutput=${workingDir}/project_indicators
resume=entry-point-decision

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#!/usr/bin/python3
# Create openaire id - openaire id graph from openaire data
#############################################################################################################
# Program proceeds as follows:
# 1. We read the input folder provided from hdfs.
# This contains subfolders with openaire graph objects and openaire graph relations
# 2. We select all openaire graph objects of interest. We filter out based on visibility
# and inference criteria. We also filter out based on the availability of publication year
# 3. Get reference type dataframes from openaire. Then filter each one of them based on the
# existence of citing and cited in the above filtered dataset. Get only citations
# produced by publication objects, or otherresearchproducts of types:
# [TBD]
# 4. Get objects that don't appear in the relations (from those gathered in step 1) and add
# them to the graph
# 5. Group relations by citing paper and do graph-specific formatting
#############################################################################################################
# ---------- Imports ------------- #
import sys
# import pyspark
# from pyspark import SparkConf, SparkContext
from pyspark.sql import SparkSession
# Functions to effectively handle data
# manipulation for DataFrames
import pyspark.sql.functions as F
# Diagnostics
from timeit import default_timer as timer
# from datetime import timedelta, datetime
# -------------------------------- #
if len(sys.argv) < 5:
print ("Usage: ./create_openaire_ranking_graph.py <openaire_graph_data_folder> <current_year> <num_partitions> <output_folder>")
sys.exit(0)
# Inputs will be:
# 1. Folder where openaire graph is stored
graph_folder = sys.argv[1]
# 2. Current year (this will be needed for filtering)
current_year = int(sys.argv[2])
# 3. Number of partitions
num_partitions = int(sys.argv[3])
# 4. where to write output
output_folder = sys.argv[4]
# Lists of results types we want to inclued in the citations
# valid_result_types = ['publication', 'other']
valid_result_types = ['publication']
# list of types in otherresearchproduct which are considered valid for citations
valid_other = ['']
# Create the spark session
spark = SparkSession.builder.appName('oa ranking graph creation').getOrCreate()
# Set context level logging to WARN
spark.sparkContext.setLogLevel("WARN")
############################################################################################################################
# 1. Get the research objects and filter based on conditions.
# These will also be the unique identifiers we should find in the final graph
# Initialize an empty dataframe
oa_objects_df = None
# There is a directory structure on hdfs under the provided path.
# We need to parse data from the folders: ["publication", "dataset", "software", "otherresearchproduct"]
# which are rankable oa result objects.
# Loop subfolders
for sub_folder in ["publication", "dataset", "software", "otherresearchproduct"]:
# Read the json data of the graph into a dataframe initially
if not oa_objects_df:
oa_objects_df = spark.read.json(graph_folder + "/" + sub_folder).select('id', 'resulttype.classname', 'datainfo.deletedbyinference', 'datainfo.invisible', F.year('dateofacceptance.value').alias('year'))
oa_objects_df = oa_objects_df.where( 'datainfo.deletedbyinference = false' ).where( 'datainfo.invisible = false' ).repartition(num_partitions, 'id').cache()
# If we already have data, simply add more to it
else:
sub_df = spark.read.json(graph_folder + "/" + sub_folder).select('id', 'resulttype.classname','datainfo.deletedbyinference', 'datainfo.invisible', F.year('dateofacceptance.value').alias('year'))
sub_df = sub_df.where( 'datainfo.deletedbyinference = false ' ).where( 'datainfo.invisible = false ').cache()
# Add the data to the openaire objects dataframe
oa_objects_df = oa_objects_df.union(sub_df).repartition(num_partitions, 'id').cache()
# Clear memory
sub_df.unpersist(True)
# Remove those records without year
oa_objects_df = oa_objects_df.where(F.col('year').isNotNull())
# Now replace years where > (current_year+1) with 0
oa_objects_df = oa_objects_df.withColumn('clean_year', F.when(F.col('year').cast('int') > (current_year+1), 0).otherwise(F.col('year')))\
.drop('year').withColumnRenamed('clean_year', 'year').repartition(num_partitions, 'id')
# -------------------------------------------------------------------- #
'''
# Some diagnostics
print ("Min and max years:" )
oa_objects_df.select(F.max('year')).show()
oa_objects_df.select(F.min('year')).show()
# This should be slow due to not repartitioning by year
print ("Distinct years:")
oa_objects_df.select('year').distinct().sort(F.col('year')).show(5000, False)
# Show distinct values of deletedbyinference and invisible to ensure we have the correct data
print ("Distinct deleted by inference:")
oa_objects_df.select('deletedbyinference').distinct().show()
print ("Distinct invisible values:")
oa_objects_df.select('invisible').distinct().show()
# Output total count
print ("Total num of research objects: " + str(oa_objects_df.count()))
'''
# -------------------------------------------------------------------- #
# Keep only required fields - we still keep resulttype.classname to
# filter the citation relationships we consider valid
oa_objects_df = oa_objects_df.drop('deletedbyinference').drop('invisible').distinct().cache()
'''
print ("OA objects Schema:")
oa_objects_df.printSchema()
sys.exit(0)
'''
############################################################################################################################
# 2. Get the relation objects and filter them based on their existence in the oa_objects_df
# NOTE: we are only interested in citations of type "cites"
# Further, we
# Deprecated line
# references_df = spark.read.json(graph_folder + "/relation").select(F.col('source').alias('citing'), F.col('target').alias('cited'), 'relClass')\
# .where( 'relClass = "References"' ).repartition(num_partitions, 'citing').drop('relClass')
# print ("References df has: " + str(references_df.count()) + " entries")
# Collect only valid citations i.e., invisible = false & deletedbyinference=false
cites_df = spark.read.json(graph_folder + "/relation")\
.select(F.col('source').alias('citing'), F.col('target').alias('cited'), 'collectedfrom.value', 'relClass', 'dataInfo.deletedbyinference', 'dataInfo.invisible')\
.where( (F.col('relClass') == "Cites") \
& (F.col('dataInfo.deletedbyinference') == "false")\
& (F.col('dataInfo.invisible') == "false"))\
.drop('dataInfo.deletedbyinference').drop('dataInfo.invisible')\
.drop('deletedbyinference').drop('invisible')\
.repartition(num_partitions, 'citing').drop('relClass')\
.withColumn('collected_lower', F.expr('transform(value, x -> lower(x))'))\
.drop('collectedfrom.value')\
.drop('value')\
.where(
(F.array_contains(F.col('collected_lower'), "opencitations"))
| (F.array_contains(F.col('collected_lower'), "crossref"))
| (F.array_contains(F.col('collected_lower'), "microsoft academic graph"))
).drop('collected_lower')
# print ("Cited df has: " + str(cites_df.count()) + " entries")
# DEPRECATED
# cited_by_df = spark.read.json(graph_folder + "/relation").select(F.col('target').alias('citing'), F.col('source').alias('cited'), 'relClass')\
# .where( 'relClass = "IsCitedBy"' ).repartition(num_partitions, 'citing').drop('relClass')
# print ("Cited by df has: " + str(cited_by_df.count()) + " entries")
# DEPRECATED
# Keep only relations where citing and cited are in the oa_objects_df
# references_df = references_df.join(oa_objects_df.select('id'), references_df.citing == oa_objects_df.id).drop('id')
# references_df = references_df.repartition(num_partitions, 'cited').join(oa_objects_df.select('id'), references_df.cited == oa_objects_df.id).drop('id').distinct().repartition(num_partitions, 'citing').cache()
# print ("References df now has: " + str(references_df.count()) + " entries")
cites_df = cites_df.join(oa_objects_df.select('id', 'classname'), cites_df.citing == oa_objects_df.id).where( F.col('classname').isin(valid_result_types) ).drop('id').drop('classname')
cites_df = cites_df.repartition(num_partitions, 'cited').join(oa_objects_df.select('id'), cites_df.cited == oa_objects_df.id).distinct().repartition(num_partitions, 'citing').cache()
# TODO: add here a clause filtering out the citations
# originating from "other" types of research objects which we consider valid
# print ("Cites df now has: " + str(cites_df.count()) + " entries")
# DEPRECATED
# cited_by_df = cited_by_df.join(oa_objects_df.select('id'), cited_by_df.citing == oa_objects_df.id).drop('id')
# cited_by_df = cited_by_df.repartition(num_partitions, 'cited').join(oa_objects_df.select('id'), cited_by_df.cited == oa_objects_df.id).drop('id').distinct().repartition(num_partitions, 'citing').cache()
# print ("Cited BY df now has: " + str(cited_by_df.count()) + " entries")
# DEPRECATED
# Join all the above into a single set
# citations_df = references_df.union(cites_df).distinct().repartition(num_partitions, 'citing').cache()
# Free space
# references_df.unpersist(True)
# cites_df.unpersist(True)
# citations_df = citations_df.union(cited_by_df).distinct().repartition(num_partitions, 'citing').cache()
# ALL citations we keep are in the cited_df dataframe
citations_df = cites_df
'''
# Show schema
print ("Citation schema:")
citations_df.printSchema()
print ("Objects schema:")
oa_objects_df.printSchema()
'''
# Free space
# cited_by_df.unpersist(True)
# Show total num of unique citations
'''
num_unique_citations = citations_df.count()
print ("Total unique citations: " + str(num_unique_citations))
'''
############################################################################################################################
# 3. Get any potentially missing 'citing' papers from references (these are dangling nodes w/o any outgoing references)
dangling_nodes = oa_objects_df.join(citations_df.select('citing').distinct(), citations_df.citing == oa_objects_df.id, 'left_anti')\
.select(F.col('id').alias('citing')).withColumn('cited', F.array([F.lit("0")])).repartition(num_partitions, 'citing')
# Count dangling nodes
'''
dangling_num = dangling_nodes.count()
print ("Number of dangling nodes: " + str(dangling_num))
'''
# print ("Dangling nodes sample:")
# dangling_nodes.show(10, False)
############################################################################################################################
# 4. Group the citation dataframe by citing doi, and create the cited dois list. Add dangling nodes to the result
graph = citations_df.groupBy('citing').agg(F.collect_set('cited').alias('cited')).repartition(num_partitions, 'citing').cache()
# Free space
citations_df.unpersist(True)
'''
num_nodes = graph.count()
print ("Entries in graph before dangling nodes:" + str(num_nodes))
'''
# print ("Sample in graph: ")
# graph.show(10, False)
# Add dangling nodes
graph = graph.union(dangling_nodes).repartition(num_partitions, 'citing')
# Count current number of results
num_nodes = graph.count()
print ("Num entries after adding dangling nodes: " + str(num_nodes))
# Add publication year
graph = graph.join(oa_objects_df, graph.citing == oa_objects_df.id).select('citing', 'cited', 'year').cache()
num_nodes_final = graph.count()
print ("After adding year: " + str(num_nodes_final))
# print ("Graph sample:")
# graph.show(20, False)
# Calculate initial score of nodes (1/N)
initial_score = float(1)/float(num_nodes_final)
############################################################################################################################
# 5. Write graph to output file!
print("Writing output to: " + output_folder)
graph.select('citing', F.concat_ws("|", F.concat_ws(",",'cited'), F.when(F.col('cited').getItem(1) != "0", F.size('cited')).otherwise(F.lit("0")), F.lit(str(initial_score)) ).alias('cited'), 'year').withColumn('prev_pr', F.lit("0")).select('citing', 'cited', 'prev_pr', 'year')\
.write.mode("overwrite").option("delimiter","\t").csv(output_folder, compression="gzip")
if num_nodes_final != num_nodes:
print ("WARNING: the number of nodes after keeping only nodes where year is available went from: " + str(num_nodes) + " to " + str(num_nodes_final) + "\n")
print ("Check for any mistakes...")
############################################################################################################################
print ("\nDONE!\n\n")
# Wrap up
spark.stop()

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# This program reads hdfs directories containing ranking results from openaire's cluster.
# Based on the parameters provided by the user, it will create different types of output files.
# Modes available are:
# 1. bip
# This will result in output of the form required for bip-finder's update.
# Its lines conform to the following format:
# <doi> \t <pagerank> \t <pagerank_normalized> \t <attrank> \t <attrank_normalized> \t <citation_count> \t <citation_count_normalized> \t <3y_cc> \t <3y_cc_normalized> \t <tar_ram> \t <references_count>
# 2. zenodo
# This is the format used in zenodo for Bip-DB. (6 way classes will be named C1, C2, ..., C6)
# This should output two files per ranking method with each line having the following data:
# a. <id> <score> <6-way-class>
# NOTE: this should also run for openaire-id files, hence we should have a total of 4 files per ranking (2 for each type of identifier)
# In 'zenodo' mode the user specifies only a single file, for which zenodo-based output will be created
# 3. json
# This if the format used to provide openAIRE / claudio with data containing 1 json per identifier
# An example of such a json format follows:
#{
# "50|dedup_wf_001::08823c8f5c3ca2eae523817036cdda67": [
# {
# "id": "influence",
# "unit": [
# {
# "key": "score",
# "value": "5.06690394631e-09"
# },
# {
# "key": "class",
# "value": "C"
# }
# ]
# },
# {
# "id": "popularity_alt",
# "unit": [
# {
# "key": "score",
# "value": "0.0"
# },
# {
# "key": "class",
# "value": "C"
# }
# ]
# },
# {
# "id": "popularity",
# "unit": [
# {
# "key": "score",
# "value": "3.11855618382e-09"
# },
# {
# "key": "class",
# "value": "C"
# }
# ]
# },
# {
# "id": "influence_alt",
# "unit": [
# {
# "key": "score",
# "value": "0.0"
# },
# {
# "key": "class",
# "value": "C"
# }
# ]
# },
# {
# "id": "impulse",
# "unit": [
# {
# "key": "score",
# "value": "0.0"
# },
# {
# "key": "class",
# "value": "C"
# }
# ]
# }
# ]
#}
#################################################################################################
# Imports
import sys
import time
# Sparksession lib to communicate with cluster via session object
from pyspark.sql import SparkSession
# Import sql types to define the schema of score output files
from pyspark.sql.types import *
# Import sql functions with shorthand alias
import pyspark.sql.functions as F
from pyspark.sql.functions import udf
# Json specific encoding
import json
#################################################################################################
# Clean up directory name
def clean_directory_name(dir_name):
# We have a name with the form *_bip_universe<digits>_* or *_graph_universe<digits>_*
# and we need to keep the parts in *
dir_name_parts = dir_name.split('_')
dir_name_parts = [part for part in dir_name_parts if ('bip' not in part and 'graph' not in part and 'universe' not in part and 'from' not in part)]
clean_name = '_'.join(dir_name_parts)
clean_name = clean_name.replace('_id', '_ids')
clean_name = clean_name.replace('.txt', '')
clean_name = clean_name.replace('.gz', '')
if 'openaire_ids_' in clean_name:
clean_name = clean_name.replace('openaire_ids_', '')
clean_name = clean_name + '_openaire_ids.txt.gz'
else:
clean_name = clean_name + '.txt.gz/'
return clean_name
# --------------------------------------------------------------------------------------------- #
# User defined function to escape special characters in a string that will turn into a json key
@udf(StringType())
def json_encode_key(doi_string):
return json.dumps(doi_string)
#################################################################################################
# --------------------------------------------------------------------------------------------- #
# Arguments from command line and initializations
# Time initialization
start_time = time.time()
# Check whether input is correct, otherwise exit with appropriate message
if len(sys.argv) < 2:
print ("Usage: ./format_ranking_results.py <mode> <input_file|input_file_list> <num_partitions>")
sys.exit(0)
# Define valid modes:
valid_modes = ['json', 'zenodo', 'bip', 'json-5-way']
# Read mode provided by user
mode = sys.argv[1].strip()
# If mode isn't valid, exit
if mode not in valid_modes:
print ("Usage: ./format_ranking_results.py <mode> <input_file|input_file_list> <num_partitions>\n")
print ("Invalid mode provided. Valid modes: ['zenodo', 'bip', 'json', 'json-5-way']")
sys.exit(0)
# Once here, we should be more or less okay to run.
# Define the spark session object
spark = SparkSession.builder.appName('Parse Scores - ' + str(mode) + ' mode').getOrCreate()
# Set Log Level for spark session
spark.sparkContext.setLogLevel('WARN')
# Here we define the schema shared by all score output files
# - citation count variants have a slightly different schema, due to their scores being integers
float_schema = StructType([
StructField('id', StringType(), False),
StructField('score', FloatType(), False),
StructField('normalized_score', FloatType(), False),
StructField('3-way-class', StringType(), False),
StructField('5-way-class', StringType(), False)
])
int_schema = StructType([
StructField('id', StringType(), False),
StructField('score', IntegerType(), False),
StructField('normalized_score', FloatType(), False),
StructField('3-way-class', StringType(), False),
StructField('5-way-class', StringType(), False)
])
# This schema concerns the output of the file
# containing the number of references of each doi
refs_schema = StructType([
StructField('id', StringType(), False),
StructField('num_refs', IntegerType(), False),
])
print("--- Initialization time: %s seconds ---" % (time.time() - start_time))
# --------------------------------------------------------------------------------------------- #
# Time the main program execution
start_time = time.time()
# The following is executed when the user requests the bip-update specific file
if mode == 'bip':
# Read the remaining input files
if len(sys.argv) < 8:
print ("\n\nInsufficient input for 'bip' mode.")
print ("File list required: <pagerank> <attrank> <citation count> <3-year citation count> <tar-ram> <number of references> <num_partitions>\n")
sys.exit(0)
# Read number of partitions:
num_partitions = int(sys.argv[-1])
pagerank_dir = sys.argv[2]
attrank_dir = sys.argv[3]
cc_dir = sys.argv[4]
impulse_dir = sys.argv[5]
ram_dir = sys.argv[6]
# NOTE: This was used initial, but @Serafeim told me to remove it since we don't get doi-doi referencew anymore
# In case of emergency, bring this back
# refs_dir = sys.argv[7]
# Score-specific dataframe
pagerank_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header',True).csv(pagerank_dir).repartition(num_partitions, 'id')
attrank_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header',True).csv(attrank_dir).repartition(num_partitions, 'id')
cc_df = spark.read.schema(int_schema).option('delimiter', '\t').option('header',True).csv(cc_dir).repartition(num_partitions, 'id')
impulse_df = spark.read.schema(int_schema).option('delimiter', '\t').option('header',True).csv(impulse_dir).repartition(num_partitions, 'id')
ram_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header', True).csv(ram_dir).repartition(num_partitions, 'id')
# refs_df = spark.read.schema(refs_schema).option('delimiter', '\t').option('header',True).csv(refs_dir).repartition(num_partitions, 'id')
# ----------- TESTING CODE --------------- #
# pagerank_entries = pagerank_df.count()
# attrank_entries = attrank_df.count()
# cc_entries = cc_df.count()
# impulse_entries = impulse_df.count()
# ram_entries = ram_df.count()
# refs_entries = refs_df.count()
# print ("Pagerank:" + str(pagerank_entries))
# print ("AttRank:" + str(attrank_entries))
# print ("CC entries: " + str(cc_entries))
# print ("Impulse entries: " + str(impulse_entries))
# print ("Refs: " + str(refs_entries))
# ---------------------------------------- #
# Create a new dataframe with the required data
results_df = pagerank_df.select('id', F.col('score').alias('pagerank'), F.col('normalized_score').alias('pagerank_normalized'))
# Add attrank dataframe
results_df = results_df.join(attrank_df.select('id', 'score', 'normalized_score'), ['id'])\
.select(results_df.id, 'pagerank', 'pagerank_normalized', F.col('score').alias('attrank'), F.col('normalized_score').alias('attrank_normalized'))
# Add citation count dataframe
results_df = results_df.join(cc_df.select('id', 'score', 'normalized_score'), ['id'])\
.select(results_df.id, 'pagerank', 'pagerank_normalized', 'attrank', 'attrank_normalized', F.col('score').alias('cc'), F.col('normalized_score').alias('cc_normalized'))
# Add 3-year df
results_df = results_df.join(impulse_df.select('id', 'score', 'normalized_score'), ['id'])\
.select(results_df.id, 'pagerank', 'pagerank_normalized', 'attrank', 'attrank_normalized', 'cc', 'cc_normalized', \
F.col('score').alias('3-cc'), F.col('normalized_score').alias('3-cc_normalized'))
# Add ram df
results_df = results_df.join(ram_df.select('id', 'score'), ['id'])\
.select(results_df.id, 'pagerank', 'pagerank_normalized', 'attrank', 'attrank_normalized', 'cc', 'cc_normalized',\
'3-cc', '3-cc_normalized', F.col('score').alias('ram'))
# Add references - THIS WAS REMOVED SINCE WE DON't GET DOI REFERENCES
# In case of emergency bring back
# results_df = results_df.join(refs_df, ['id']).select(results_df.id, 'pagerank', 'pagerank_normalized', 'attrank', 'attrank_normalized', \
# 'cc', 'cc_normalized', '3-cc', '3-cc_normalized', 'ram', 'num_refs')
# Write resulting dataframe to file
output_dir = "/".join(pagerank_dir.split('/')[:-1])
output_dir = output_dir + '/bip_update_data.txt.gz'
print("Writing to:" + output_dir)
results_df.write.mode('overwrite').option('delimiter','\t').option('header',True).csv(output_dir, compression='gzip')
# The following is executed when the user requests the zenodo-specific file
elif mode == 'zenodo':
# Read the remaining input files
if len(sys.argv) < 9:
print ("\n\nInsufficient input for 'zenodo' mode.")
print ("File list required: <pagerank> <attrank> <citation count> <3-year citation count> <tar-ram> <num_partitions> <graph_type>\n")
sys.exit(0)
# Read number of partitions:
num_partitions = int(sys.argv[-2])
graph_type = sys.argv[-1]
if graph_type not in ['bip', 'openaire']:
graph_type = 'bip'
pagerank_dir = sys.argv[2]
attrank_dir = sys.argv[3]
cc_dir = sys.argv[4]
impulse_dir = sys.argv[5]
ram_dir = sys.argv[6]
# Output directory is common for all files
output_dir_prefix = "/".join(pagerank_dir.split('/')[:-1])
# Method-specific outputs
pagerank_output = clean_directory_name(pagerank_dir.split('/')[-1])
attrank_output = clean_directory_name(attrank_dir.split('/')[-1])
cc_output = clean_directory_name(cc_dir.split('/')[-1])
impulse_output = clean_directory_name(impulse_dir.split('/')[-1])
ram_output = clean_directory_name(ram_dir.split('/')[-1])
# --------- PageRank ----------- #
# Get per file the doi - score - 6-way classes and write it to output
print("Writing to: " + output_dir_prefix + '/' + pagerank_output)
pagerank_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header',True).csv(pagerank_dir).repartition(num_partitions, 'id').select('id', 'score', '5-way-class')
# Replace dataframe class names
pagerank_df = pagerank_df.withColumn('class', F.lit('C6'))
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('E'), F.lit('C5')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.drop('5-way-class')
if graph_type == 'openaire':
pagerank_df = pagerank_df.where( ~F.col('id').like('10.%') )
# Write output
pagerank_df.write.mode('overwrite').option('delimiter','\t').option('header',False).csv(output_dir_prefix + '/' + pagerank_output, compression='gzip')
# --------- AttRank ----------- #
print("Writing to: " + output_dir_prefix + '/' + attrank_output)
attrank_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header',True).csv(attrank_dir).repartition(num_partitions, 'id').select('id', 'score', '5-way-class')
# Replace dataframe class names
attrank_df = attrank_df.withColumn('class', F.lit('C6'))
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('E'), F.lit('C5')).otherwise(F.col('class')) )
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
attrank_df = attrank_df.drop('5-way-class')
if graph_type == 'openaire':
attrank_df = attrank_df.where( ~F.col('id').like('10.%') )
# Write output
attrank_df.write.mode('overwrite').option('delimiter','\t').option('header',False).csv(output_dir_prefix + '/' + attrank_output, compression='gzip')
# --------- Citation Count ----------- #
print("Writing to: " + output_dir_prefix + '/' + cc_output)
cc_df = spark.read.schema(int_schema).option('delimiter', '\t').option('header',True).csv(cc_dir).repartition(num_partitions, 'id').select('id', 'score', '5-way-class')
# Replace dataframe class names
cc_df = cc_df.withColumn('class', F.lit('C5'))
# cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('E'), F.lit('C5')).otherwise(F.col('class')) )
cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
cc_df = cc_df.drop('5-way-class')
if graph_type == 'openaire':
cc_df = cc_df.where( ~F.col('id').like('10.%') )
# Write output
cc_df.write.mode('overwrite').option('delimiter','\t').option('header',False).csv(output_dir_prefix + '/' + cc_output, compression='gzip')
# --------- Impulse ----------- #
print("Writing to: " + output_dir_prefix + '/' + impulse_output)
impulse_df = spark.read.schema(int_schema).option('delimiter', '\t').option('header',True).csv(impulse_dir).repartition(num_partitions, 'id').select('id', 'score', '5-way-class')
# Replace dataframe class names
impulse_df = impulse_df.withColumn('class', F.lit('C5'))
# impulse_df = impulse_df.withColumn('class', F.when(F.col('6-way-class') == F.lit('E'), F.lit('C5')).otherwise(F.col('class')) )
impulse_df = impulse_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
impulse_df = impulse_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
impulse_df = impulse_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
impulse_df = impulse_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
impulse_df = impulse_df.drop('5-way-class')
if graph_type == 'openaire':
impulse_df = impulse_df.where( ~F.col('id').like('10.%') )
# Write output
impulse_df.write.mode('overwrite').option('delimiter','\t').option('header',False).csv(output_dir_prefix + '/' + impulse_output, compression='gzip')
# --------- RAM ----------- #
print("Writing to: " + output_dir_prefix + '/' + ram_output)
ram_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header', True).csv(ram_dir).repartition(num_partitions, 'id').select('id', 'score', '5-way-class')
# Replace dataframe class names
ram_df = ram_df.withColumn('class', F.lit('C5'))
# ram_df = ram_df.withColumn('class', F.when(F.col('6-way-class') == F.lit('E'), F.lit('C5')).otherwise(F.col('class')) )
ram_df = ram_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
ram_df = ram_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
ram_df = ram_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
ram_df = ram_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
ram_df = ram_df.drop('5-way-class')
if graph_type == 'openaire':
ram_df = ram_df.where( ~F.col('id').like('10.%') )
# Write output
ram_df.write.mode('overwrite').option('delimiter','\t').option('header',False).csv(output_dir_prefix + '/' + ram_output, compression='gzip')
# The following produces the json file required by openaire
elif mode == 'json':
# Read the remaining input files
if len(sys.argv) < 9:
print ("\n\nInsufficient input for 'json' mode.")
print ("File list required: <pagerank> <attrank> <citation count> <3-year citation count> <tar-ram> <num_partitions> <graph_type>\n")
sys.exit(0)
# Read number of partitions:
num_partitions = int(sys.argv[-2])
graph_type = sys.argv[-1]
if graph_type not in ['bip', 'openaire']:
graph_type = 'bip'
print ("Graph type: " + str(graph_type))
# File directories
pagerank_dir = sys.argv[2]
attrank_dir = sys.argv[3]
cc_dir = sys.argv[4]
impulse_dir = sys.argv[5]
ram_dir = sys.argv[6]
print ("Reading files:")
print (pagerank_dir)
print (attrank_dir)
print (cc_dir)
print (impulse_dir)
print (ram_dir)
# Score-specific dataframe - read inputs
pagerank_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header',True).csv(pagerank_dir).repartition(num_partitions, 'id')
attrank_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header',True).csv(attrank_dir).repartition(num_partitions, 'id')
cc_df = spark.read.schema(int_schema).option('delimiter', '\t').option('header',True).csv(cc_dir).repartition(num_partitions, 'id')
impulse_df = spark.read.schema(int_schema).option('delimiter', '\t').option('header',True).csv(impulse_dir).repartition(num_partitions, 'id')
ram_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header', True).csv(ram_dir).repartition(num_partitions, 'id')
# --- Join the data of the various scores --- #
# Create json data for pagerank
pagerank_df = pagerank_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('3-way-class'))).alias('class_map'))
pagerank_df = pagerank_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('influence_values') )
pagerank_df = pagerank_df.select('id', F.create_map(F.lit('id'), F.lit('influence')).alias('id_map'), F.col('influence_values'))
pagerank_df = pagerank_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('influence'))).alias('influence_key'), F.to_json(F.col('influence_values')).alias('influence_values') )
pagerank_df = pagerank_df.select('id', F.expr('substring(influence_key, 0, length(influence_key)-1)').alias('influence_key'), 'influence_values')
pagerank_df = pagerank_df.select('id', 'influence_key', F.expr('substring(influence_values, 2, length(influence_values))').alias('influence_values'))
pagerank_df = pagerank_df.select('id', F.concat_ws(', ', F.col('influence_key'), F.col('influence_values')).alias('influence_json'))
# Create json data for attrank
attrank_df = attrank_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('3-way-class'))).alias('class_map'))
attrank_df = attrank_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('popularity_values') )
attrank_df = attrank_df.select('id', F.create_map(F.lit('id'), F.lit('popularity')).alias('id_map'), F.col('popularity_values'))
attrank_df = attrank_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('popularity'))).alias('popularity_key'), F.to_json(F.col('popularity_values')).alias('popularity_values') )
attrank_df = attrank_df.select('id', F.expr('substring(popularity_key, 0, length(popularity_key)-1)').alias('popularity_key'), 'popularity_values')
attrank_df = attrank_df.select('id', 'popularity_key', F.expr('substring(popularity_values, 2, length(popularity_values))').alias('popularity_values'))
attrank_df = attrank_df.select('id', F.concat_ws(', ', F.col('popularity_key'), F.col('popularity_values')).alias('popularity_json'))
# Create json data for CC
cc_df = cc_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('3-way-class'))).alias('class_map'))
cc_df = cc_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('influence_alt_values') )
cc_df = cc_df.select('id', F.create_map(F.lit('id'), F.lit('influence_alt')).alias('id_map'), F.col('influence_alt_values'))
cc_df = cc_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('influence_alt'))).alias('influence_alt_key'), F.to_json(F.col('influence_alt_values')).alias('influence_alt_values') )
cc_df = cc_df.select('id', F.expr('substring(influence_alt_key, 0, length(influence_alt_key)-1)').alias('influence_alt_key'), 'influence_alt_values')
cc_df = cc_df.select('id', 'influence_alt_key', F.expr('substring(influence_alt_values, 2, length(influence_alt_values))').alias('influence_alt_values'))
cc_df = cc_df.select('id', F.concat_ws(', ', F.col('influence_alt_key'), F.col('influence_alt_values')).alias('influence_alt_json'))
# Create json data for RAM
ram_df = ram_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('3-way-class'))).alias('class_map'))
ram_df = ram_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('popularity_alt_values') )
ram_df = ram_df.select('id', F.create_map(F.lit('id'), F.lit('popularity_alt')).alias('id_map'), F.col('popularity_alt_values'))
ram_df = ram_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('popularity_alt'))).alias('popularity_alt_key'), F.to_json(F.col('popularity_alt_values')).alias('popularity_alt_values') )
ram_df = ram_df.select('id', F.expr('substring(popularity_alt_key, 0, length(popularity_alt_key)-1)').alias('popularity_alt_key'), 'popularity_alt_values')
ram_df = ram_df.select('id', 'popularity_alt_key', F.expr('substring(popularity_alt_values, 2, length(popularity_alt_values))').alias('popularity_alt_values'))
ram_df = ram_df.select('id', F.concat_ws(', ', F.col('popularity_alt_key'), F.col('popularity_alt_values')).alias('popularity_alt_json'))
# Create json data for impulse
impulse_df = impulse_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('3-way-class'))).alias('class_map'))
impulse_df = impulse_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('impulse_values') )
impulse_df = impulse_df.select('id', F.create_map(F.lit('id'), F.lit('impulse')).alias('id_map'), F.col('impulse_values'))
impulse_df = impulse_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('impulse'))).alias('impulse_key'), F.to_json(F.col('impulse_values')).alias('impulse_values') )
impulse_df = impulse_df.select('id', F.expr('substring(impulse_key, 0, length(impulse_key)-1)').alias('impulse_key'), 'impulse_values')
impulse_df = impulse_df.select('id', 'impulse_key', F.expr('substring(impulse_values, 2, length(impulse_values))').alias('impulse_values'))
impulse_df = impulse_df.select('id', F.concat_ws(', ', F.col('impulse_key'), F.col('impulse_values')).alias('impulse_json'))
#Join dataframes together
results_df = pagerank_df.join(attrank_df, ['id'])
results_df = results_df.join(cc_df, ['id'])
results_df = results_df.join(ram_df, ['id'])
results_df = results_df.join(impulse_df, ['id'])
print ("Json encoding DOI keys")
# Json encode doi strings
results_df = results_df.select(json_encode_key('id').alias('id'), 'influence_json', 'popularity_json', 'influence_alt_json', 'popularity_alt_json', 'impulse_json')
# Concatenate individual json columns
results_df = results_df.select('id', F.concat_ws(', ', F.col('influence_json'), F.col('popularity_json'), F.col('influence_alt_json'), F.col('popularity_alt_json'), F.col('impulse_json') ).alias('json_data'))
results_df = results_df.select('id', F.concat_ws('', F.lit('['), F.col('json_data'), F.lit(']')).alias('json_data') )
# Filter out non-openaire ids if need
if graph_type == 'openaire':
results_df = results_df.where( ~F.col('id').like('"10.%') )
# Concatenate paper id and add opening and ending brackets
results_df = results_df.select(F.concat_ws('', F.lit('{'), F.col('id'), F.lit(': '), F.col('json_data'), F.lit('}')).alias('json') )
# -------------------------------------------- #
# Write json output - set the directory here
output_dir = "/".join(pagerank_dir.split('/')[:-1])
if graph_type == 'bip':
output_dir = output_dir + '/bip_universe_doi_scores/'
else:
output_dir = output_dir + '/openaire_universe_scores/'
# Write the dataframe
print ("Writing output to: " + output_dir)
results_df.write.mode('overwrite').option('header', False).text(output_dir, compression='gzip')
# Rename the files to .json.gz now
sc = spark.sparkContext
URI = sc._gateway.jvm.java.net.URI
Path = sc._gateway.jvm.org.apache.hadoop.fs.Path
FileSystem = sc._gateway.jvm.org.apache.hadoop.fs.FileSystem
# Get master prefix from input file path
master_prefix = "/".join(pagerank_dir.split('/')[:5])
fs = FileSystem.get(URI(master_prefix), sc._jsc.hadoopConfiguration())
path = Path(output_dir)
print ("Path is:" + path.toString())
file_list = fs.listStatus(Path(output_dir))
print ("Renaming files:")
for f in file_list:
initial_filename = f.getPath().toString()
if "part" in initial_filename:
print (initial_filename + " => " + initial_filename.replace(".txt.gz", ".json.gz"))
fs.rename(Path(initial_filename), Path(initial_filename.replace(".txt.gz", ".json.gz")))
'''
DEPRECATED:
# -------------------------------------------- #
# Write json output
output_dir = "/".join(pagerank_dir.split('/')[:-1])
if graph_type == 'bip':
output_dir = output_dir + '/bip_universe_doi_scores_txt/'
else:
output_dir = output_dir + '/openaire_universe_scores_txt/'
print ("Writing output to: " + output_dir)
results_df.write.mode('overwrite').option('header', False).text(output_dir, compression='gzip')
print ("Done writing first results")
# Read results df as json and write it as json file
print ("Reading json input from: " + str(output_dir))
resulds_df_json = spark.read.json(output_dir).cache()
# Write json to different dir
print ("Writing json output to: " + output_dir.replace("_txt", ""))
resulds_df_json.write.mode('overwrite').json(output_dir.replace("_txt", ""), compression='gzip')
'''
# The following produces the json file required by openaire
elif mode == 'json-5-way':
# Read the remaining input files
if len(sys.argv) < 9:
print ("\n\nInsufficient input for 'json-5-way' mode.")
print ("File list required: <pagerank> <attrank> <citation count> <3-year citation count> <tar-ram> <num_partitions> <graph_type>\n")
sys.exit(0)
# Read number of partitions:
num_partitions = int(sys.argv[-2])
graph_type = sys.argv[-1]
if graph_type not in ['bip', 'openaire']:
graph_type = 'bip'
# File directories
pagerank_dir = sys.argv[2]
attrank_dir = sys.argv[3]
cc_dir = sys.argv[4]
impulse_dir = sys.argv[5]
ram_dir = sys.argv[6]
# Score-specific dataframe - read inputs
pagerank_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header',True).csv(pagerank_dir).repartition(num_partitions, 'id')
attrank_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header',True).csv(attrank_dir).repartition(num_partitions, 'id')
cc_df = spark.read.schema(int_schema).option('delimiter', '\t').option('header',True).csv(cc_dir).repartition(num_partitions, 'id')
impulse_df = spark.read.schema(int_schema).option('delimiter', '\t').option('header',True).csv(impulse_dir).repartition(num_partitions, 'id')
ram_df = spark.read.schema(float_schema).option('delimiter', '\t').option('header', True).csv(ram_dir).repartition(num_partitions, 'id')
# --- Join the data of the various scores --- #
# Replace 6-way classes with 5-way values
pagerank_df = pagerank_df.withColumn('class', F.lit('C5'))
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
pagerank_df = pagerank_df.drop('5-way-class').withColumnRenamed('class', '5-way-class')
# Create json data for pagerank
pagerank_df = pagerank_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('5-way-class'))).alias('class_map'))
pagerank_df = pagerank_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('influence_values') )
pagerank_df = pagerank_df.select('id', F.create_map(F.lit('id'), F.lit('influence')).alias('id_map'), F.col('influence_values'))
pagerank_df = pagerank_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('influence'))).alias('influence_key'), F.to_json(F.col('influence_values')).alias('influence_values') )
pagerank_df = pagerank_df.select('id', F.expr('substring(influence_key, 0, length(influence_key)-1)').alias('influence_key'), 'influence_values')
pagerank_df = pagerank_df.select('id', 'influence_key', F.expr('substring(influence_values, 2, length(influence_values))').alias('influence_values'))
pagerank_df = pagerank_df.select('id', F.concat_ws(', ', F.col('influence_key'), F.col('influence_values')).alias('influence_json'))
# Replace 6-way classes with 5 way classes for attrank
attrank_df = attrank_df.withColumn('class', F.lit('C5'))
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
attrank_df = attrank_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
attrank_df = attrank_df.drop('5-way-class').withColumnRenamed('class', '5-way-class')
# Create json data for attrank
attrank_df = attrank_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('5-way-class'))).alias('class_map'))
attrank_df = attrank_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('popularity_values') )
attrank_df = attrank_df.select('id', F.create_map(F.lit('id'), F.lit('popularity')).alias('id_map'), F.col('popularity_values'))
attrank_df = attrank_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('popularity'))).alias('popularity_key'), F.to_json(F.col('popularity_values')).alias('popularity_values') )
attrank_df = attrank_df.select('id', F.expr('substring(popularity_key, 0, length(popularity_key)-1)').alias('popularity_key'), 'popularity_values')
attrank_df = attrank_df.select('id', 'popularity_key', F.expr('substring(popularity_values, 2, length(popularity_values))').alias('popularity_values'))
attrank_df = attrank_df.select('id', F.concat_ws(', ', F.col('popularity_key'), F.col('popularity_values')).alias('popularity_json'))
# Replace 6-way classes with 5 way classes for attrank
cc_df = cc_df.withColumn('class', F.lit('C5'))
cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
cc_df = cc_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
cc_df = cc_df.drop('5-way-class').withColumnRenamed('class', '5-way-class')
# Create json data for CC
cc_df = cc_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('5-way-class'))).alias('class_map'))
cc_df = cc_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('influence_alt_values') )
cc_df = cc_df.select('id', F.create_map(F.lit('id'), F.lit('influence_alt')).alias('id_map'), F.col('influence_alt_values'))
cc_df = cc_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('influence_alt'))).alias('influence_alt_key'), F.to_json(F.col('influence_alt_values')).alias('influence_alt_values') )
cc_df = cc_df.select('id', F.expr('substring(influence_alt_key, 0, length(influence_alt_key)-1)').alias('influence_alt_key'), 'influence_alt_values')
cc_df = cc_df.select('id', 'influence_alt_key', F.expr('substring(influence_alt_values, 2, length(influence_alt_values))').alias('influence_alt_values'))
cc_df = cc_df.select('id', F.concat_ws(', ', F.col('influence_alt_key'), F.col('influence_alt_values')).alias('influence_alt_json'))
# Replace 6-way classes with 5 way classes for attrank
ram_df = ram_df.withColumn('class', F.lit('C5'))
ram_df = ram_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
ram_df = ram_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
ram_df = ram_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
ram_df = ram_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
ram_df = ram_df.drop('5-way-class').withColumnRenamed('class', '5-way-class')
# Create json data for RAM
ram_df = ram_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('5-way-class'))).alias('class_map'))
ram_df = ram_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('popularity_alt_values') )
ram_df = ram_df.select('id', F.create_map(F.lit('id'), F.lit('popularity_alt')).alias('id_map'), F.col('popularity_alt_values'))
ram_df = ram_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('popularity_alt'))).alias('popularity_alt_key'), F.to_json(F.col('popularity_alt_values')).alias('popularity_alt_values') )
ram_df = ram_df.select('id', F.expr('substring(popularity_alt_key, 0, length(popularity_alt_key)-1)').alias('popularity_alt_key'), 'popularity_alt_values')
ram_df = ram_df.select('id', 'popularity_alt_key', F.expr('substring(popularity_alt_values, 2, length(popularity_alt_values))').alias('popularity_alt_values'))
ram_df = ram_df.select('id', F.concat_ws(', ', F.col('popularity_alt_key'), F.col('popularity_alt_values')).alias('popularity_alt_json'))
# Replace 6-way classes with 5 way classes for attrank
impulse_df = impulse_df.withColumn('class', F.lit('C5'))
impulse_df = impulse_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('D'), F.lit('C4')).otherwise(F.col('class')) )
impulse_df = impulse_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('C'), F.lit('C3')).otherwise(F.col('class')) )
impulse_df = impulse_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('B'), F.lit('C2')).otherwise(F.col('class')) )
impulse_df = impulse_df.withColumn('class', F.when(F.col('5-way-class') == F.lit('A'), F.lit('C1')).otherwise(F.col('class')) )
impulse_df = impulse_df.drop('5-way-class').withColumnRenamed('class', '5-way-class')
# Create json data for impulse
impulse_df = impulse_df.select('id', F.map_concat(
F.create_map(F.lit('key'), F.lit('score')),
F.create_map(F.lit('value'), F.col('score'))).alias('score_map'),
F.map_concat(
F.create_map(F.lit('key'), F.lit('class')),
F.create_map(F.lit('value'), F.col('5-way-class'))).alias('class_map'))
impulse_df = impulse_df.select('id', F.create_map(F.lit('unit'), F.array([F.col('score_map'), F.col('class_map')]) ).alias('impulse_values') )
impulse_df = impulse_df.select('id', F.create_map(F.lit('id'), F.lit('impulse')).alias('id_map'), F.col('impulse_values'))
impulse_df = impulse_df.select('id', F.to_json(F.create_map(F.lit('id'), F.lit('impulse'))).alias('impulse_key'), F.to_json(F.col('impulse_values')).alias('impulse_values') )
impulse_df = impulse_df.select('id', F.expr('substring(impulse_key, 0, length(impulse_key)-1)').alias('impulse_key'), 'impulse_values')
impulse_df = impulse_df.select('id', 'impulse_key', F.expr('substring(impulse_values, 2, length(impulse_values))').alias('impulse_values'))
impulse_df = impulse_df.select('id', F.concat_ws(', ', F.col('impulse_key'), F.col('impulse_values')).alias('impulse_json'))
#Join dataframes together
results_df = pagerank_df.join(attrank_df, ['id'])
results_df = results_df.join(cc_df, ['id'])
results_df = results_df.join(ram_df, ['id'])
results_df = results_df.join(impulse_df, ['id'])
print ("Json encoding DOI keys")
# Json encode doi strings
results_df = results_df.select(json_encode_key('id').alias('id'), 'influence_json', 'popularity_json', 'influence_alt_json', 'popularity_alt_json', 'impulse_json')
# Concatenate individual json columns
results_df = results_df.select('id', F.concat_ws(', ', F.col('influence_json'), F.col('popularity_json'), F.col('influence_alt_json'), F.col('popularity_alt_json'), F.col('impulse_json') ).alias('json_data'))
results_df = results_df.select('id', F.concat_ws('', F.lit('['), F.col('json_data'), F.lit(']')).alias('json_data') )
# Filter out non-openaire ids if need
if graph_type == 'openaire':
results_df = results_df.where( ~F.col('id').like('10.%') )
# Concatenate paper id and add opening and ending brackets
results_df = results_df.select(F.concat_ws('', F.lit('{'), F.col('id'), F.lit(': '), F.col('json_data'), F.lit('}')).alias('json') )
# TEST output and count
# results_df.show(20, False)
# print ("Results #" + str(results_df.count()))
# -------------------------------------------- #
# Write json output
# -------------------------------------------- #
# Write json output - set the directory here
output_dir = "/".join(pagerank_dir.split('/')[:-1])
if graph_type == 'bip':
output_dir = output_dir + '/bip_universe_doi_scores/'
else:
output_dir = output_dir + '/openaire_universe_scores/'
# Write the dataframe
print ("Writing output to: " + output_dir)
results_df.write.mode('overwrite').option('header', False).text(output_dir, compression='gzip')
# Rename the files to .json.gz now
sc = spark.sparkContext
URI = sc._gateway.jvm.java.net.URI
Path = sc._gateway.jvm.org.apache.hadoop.fs.Path
FileSystem = sc._gateway.jvm.org.apache.hadoop.fs.FileSystem
# Get master prefix from input file path
master_prefix = "/".join(pagerank_dir.split('/')[:5])
fs = FileSystem.get(URI(master_prefix), sc._jsc.hadoopConfiguration())
path = Path(output_dir)
print ("Path is:" + path.toString())
file_list = fs.listStatus(Path(output_dir))
print ("Renaming files:")
for f in file_list:
initial_filename = f.getPath().toString()
if "part" in initial_filename:
print (initial_filename + " => " + initial_filename.replace(".txt.gz", ".json.gz"))
fs.rename(Path(initial_filename), Path(initial_filename.replace(".txt.gz", ".json.gz")))
# Close spark session
spark.stop()
print("--- Main program execution time: %s seconds ---" % (time.time() - start_time))
print("--- Finished --- \n\n")

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ranking_results_folder=$1;
pr_file=`hdfs dfs -ls ${ranking_results_folder}/ | grep "/PR_.*" | grep -o "PR.*"`;
attrank_file=`hdfs dfs -ls ${ranking_results_folder}/ | grep "/AttRank.*" | grep -o "AttRank.*"`;
cc_file=`hdfs dfs -ls ${ranking_results_folder}/ | grep "/CC_.*" | grep -o "CC.*"`;
impulse_file=`hdfs dfs -ls ${ranking_results_folder}/ | grep "/3-year_.*" | grep -o "3-year.*"`;
ram_file=`hdfs dfs -ls ${ranking_results_folder}/ | grep "/RAM_.*" | grep -o "RAM.*"`;
echo "pr_file=${pr_file}";
echo "attrank_file=${attrank_file}";
echo "cc_file=${cc_file}";
echo "impulse_file=${impulse_file}";
echo "ram_file=${ram_file}";
# echo "TEST=`hdfs dfs -ls ${ranking_results_folder}/`";

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#/usr/bin/bash
# Read log files from ranking scripts and create a two-line file
# with score limits for the various measures. To be used by Kleanthis
attrank_file=$(ls *attrank*.log);
pr_file=$(ls *pagerank*.log)
ram_file=$(ls *ram*.log);
cc_file=$(ls *cc*.log);
impulse_file=$(ls *impulse*.log);
echo
echo "-----------------------------"
echo "Attrank file:${attrank_file}";
echo "PageRank file:${pr_file}";
echo "RAM file:${ram_file}";
echo "CC file:${cc_file}";
echo "Impulse file:${impulse_file}";
echo "-----------------------------"
echo
echo
# output file will be called score_limits.csv
echo -e "influence_top001\tinfluence_top01\tinfluence_top1\tinfluence_top10\tpopularity_top001\tpopularity_top01\tpopularity_top1\tpopularity_top10\timpulse_top001\timpulse_top01\timpulse_top1\timpulse_top10\tcc_top001\tcc_top01\tcc_top1\tcc_top10" > score_limits.csv
# ---------------------------------------------------- #
# Get respective score limits (we don't need RAM)
inf_001=$(grep "^0.01%" ${pr_file} | cut -f 2);
inf_01=$(grep "^0.1%" ${pr_file} | cut -f 2);
inf_1=$(grep "^1%" ${pr_file} | cut -f 2);
inf_10=$(grep "^10%" ${pr_file} | cut -f 2);
echo "Influnence limits:"
echo -e "${inf_001}\t${inf_01}\t${inf_1}\t${inf_10}";
# ---------------------------------------------------- #
pop_001=$(grep "^0.01%" ${attrank_file} | cut -f 2);
pop_01=$(grep "^0.1%" ${attrank_file} | cut -f 2);
pop_1=$(grep "^1%" ${attrank_file} | cut -f 2);
pop_10=$(grep "^10%" ${attrank_file} | cut -f 2);
echo "Popularity limits:";
echo -e "${pop_001}\t${pop_01}\t${pop_1}\t${pop_10}";
# ---------------------------------------------------- #
imp_001=$(grep "^0.01%" ${impulse_file} | cut -f 2);
imp_01=$(grep "^0.1%" ${impulse_file} | cut -f 2);
imp_1=$(grep "^1%" ${impulse_file} | cut -f 2);
imp_10=$(grep "^10%" ${impulse_file} | cut -f 2);
echo "Popularity limits:";
echo -e "${imp_001}\t${imp_01}\t${imp_1}\t${imp_10}";
# ---------------------------------------------------- #
cc_001=$(grep "^0.01%" ${cc_file} | cut -f 2);
cc_01=$(grep "^0.1%" ${cc_file} | cut -f 2);
cc_1=$(grep "^1%" ${cc_file} | cut -f 2);
cc_10=$(grep "^10%" ${cc_file} | cut -f 2);
echo "Popularity limits:";
echo -e "${cc_001}\t${cc_01}\t${cc_1}\t${cc_10}";
# ---------------------------------------------------- #
echo -e "${inf_001}\t${inf_01}\t${inf_1}\t${inf_10}\t${pop_001}\t${pop_01}\t${pop_1}\t${pop_10}\t${imp_001}\t${imp_01}\t${imp_1}\t${imp_10}\t${cc_001}\t${cc_01}\t${cc_1}\t${cc_10}" >> score_limits.csv
echo
echo "score_limits.csv contents:"
cat score_limits.csv
echo;
echo;

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import json
import sys
from pyspark.sql import SparkSession
from pyspark import SparkConf, SparkContext
if len(sys.argv) != 3:
print("Usage: map_openaire_ids_to_dois.py <hdfs_src_dir> <hdfs_output_dir>")
sys.exit(-1)
conf = SparkConf().setAppName('BIP!: Map OpenAIRE IDs to DOIs')
sc = SparkContext(conf = conf)
spark = SparkSession.builder.appName('BIP!: Map OpenAIRE IDs to DOIs').getOrCreate()
sc.setLogLevel('OFF')
src_dir = sys.argv[1]
output = sys.argv[2]
# src_dir = "/tmp/beta_provision/graph/21_graph_cleaned/"
# output = '/tmp/openaireid_to_dois/'
def transform(doc):
# get publication year from 'doc.dateofacceptance.value'
dateofacceptance = doc.get('dateofacceptance', {}).get('value')
year = 0
if (dateofacceptance is not None):
year = dateofacceptance.split('-')[0]
# for each pid get 'pid.value' if 'pid.qualifier.classid' equals to 'doi'
dois = [ pid['value'] for pid in doc.get('pid', []) if (pid.get('qualifier', {}).get('classid') == 'doi' and pid['value'] is not None)]
num_dois = len(dois)
# exlcude openaire ids that do not correspond to DOIs
if (num_dois == 0):
return None
fields = [ doc['id'], str(num_dois), chr(0x02).join(dois), str(year) ]
return '\t'.join([ v.encode('utf-8') for v in fields ])
docs = None
for result_type in ["publication", "dataset", "software", "otherresearchproduct"]:
tmp = sc.textFile(src_dir + result_type).map(json.loads)
if (docs is None):
docs = tmp
else:
# append all result types in one RDD
docs = docs.union(tmp)
docs = docs.filter(lambda d: d.get('dataInfo', {}).get('deletedbyinference') == False and d.get('dataInfo', {}).get('invisible') == False)
docs = docs.map(transform).filter(lambda d: d is not None)
docs.saveAsTextFile(output)

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#!/usr/bin/python
# This program reads the openaire to doi mapping from the ${synonymFolder} of the workflow
# and uses this mapping to create doi-based score files in the format required by BiP! DB.
# This is done by reading each openaire-id based ranking file and joining the openaire based
# score and classes to all the corresponding dois.
#################################################################################################
# Imports
import sys
# Sparksession lib to communicate with cluster via session object
from pyspark.sql import SparkSession
# Import sql types to define schemas
from pyspark.sql.types import *
# Import sql functions with shorthand alias
import pyspark.sql.functions as F
from pyspark.sql.functions import max
# from pyspark.sql.functions import udf
#################################################################################################
#################################################################################################
# Clean up directory name - no longer needed in final workflow version
'''
def clean_directory_name(dir_name):
# We have a name with the form *_bip_universe<digits>_* or *_graph_universe<digits>_*
# and we need to keep the parts in *
dir_name_parts = dir_name.split('_')
dir_name_parts = [part for part in dir_name_parts if ('bip' not in part and 'graph' not in part and 'universe' not in part and 'from' not in part)]
dir_name = dir_name.replace("openaire_id_graph", "openaire_ids")
clean_name = dir_name + ".txt.gz"
# clean_name = '_'.join(dir_name_parts)
# if '_ids' not in clean_name:
# clean_name = clean_name.replace('id_', 'ids_')
# clean_name = clean_name.replace('.txt', '')
# clean_name = clean_name.replace('.gz', '')
# if 'openaire_ids_' in clean_name:
# clean_name = clean_name.replace('openaire_ids_', '')
# clean_name = clean_name + '.txt.gz'
# else:
# clean_name = clean_name + '.txt.gz'
return clean_name
'''
#################################################################################################
if len(sys.argv) < 3:
print ("Usage: ./map_scores_to_dois.py <synonym_folder> <num_partitions> <score_file_1> <score_file_2> <...etc...>")
sys.exit(-1)
# Read arguments
synonyms_folder = sys.argv[1]
num_partitions = int(sys.argv[2])
input_file_list = [argument.replace("_openaire_id_graph", "").replace("_openaire_id_graph_", "") + "_openaire_ids.txt.gz" for argument in sys.argv[3:]]
# input_file_list = [clean_directory_name(item) for item in input_file_list]
# Prepare output specific variables
output_file_list = [item.replace("_openaire_ids", "") for item in input_file_list]
output_file_list = [item + ".txt.gz" if not item.endswith(".txt.gz") else item for item in output_file_list]
# --- INFO MESSAGES --- #
print ("\n\n----------------------------")
print ("Mpping openaire ids to DOIs")
print ("Reading input from: " + synonyms_folder)
print ("Num partitions: " + str(num_partitions))
print ("Input files:" + " -- ".join(input_file_list))
print ("Output files: " + " -- ".join(output_file_list))
print ("----------------------------\n\n")
#######################################################################################
# We weill define the following schemas:
# --> the schema of the openaire - doi mapping file [string - int - doi_list] (the separator of the doi-list is a non printable character)
# --> a schema for floating point ranking scores [string - float - string] (the latter string is the class)
# --> a schema for integer ranking scores [string - int - string] (the latter string is the class)
float_schema = StructType([
StructField('id', StringType(), False),
StructField('score', FloatType(), False),
StructField('class', StringType(), False)
])
int_schema = StructType([
StructField('id', StringType(), False),
StructField('score', IntegerType(), False),
StructField('class', StringType(), False)
])
# This schema concerns the output of the file
# containing the number of references of each doi
synonyms_schema = StructType([
StructField('id', StringType(), False),
StructField('num_synonyms', IntegerType(), False),
StructField('doi_list', StringType(), False),
])
#######################################################################################
# Start spark session
spark = SparkSession.builder.appName('Map openaire scores to DOIs').getOrCreate()
# Set Log Level for spark session
spark.sparkContext.setLogLevel('WARN')
#######################################################################################
# MAIN Program
# Read and repartition the synonym folder - also cache it since we will need to perform multiple joins
synonym_df = spark.read.schema(synonyms_schema).option('delimiter', '\t').csv(synonyms_folder)
synonym_df = synonym_df.select('id', F.split(F.col('doi_list'), chr(0x02)).alias('doi_list'))
synonym_df = synonym_df.select('id', F.explode('doi_list').alias('doi')).repartition(num_partitions, 'id').cache()
# TESTING
# print ("Synonyms: " + str(synonym_df.count()))
# print ("DF looks like this:" )
# synonym_df.show(1000, False)
print ("\n\n-----------------------------")
# Now we need to join the score files on the openaire-id with the synonyms and then keep
# only doi - score - class and write this to the output
for offset, input_file in enumerate(input_file_list):
print ("Mapping scores from " + input_file)
# Select correct schema
schema = int_schema
if "attrank" in input_file.lower() or "pr" in input_file.lower() or "ram" in input_file.lower():
schema = float_schema
# Load file to dataframe
ranking_df = spark.read.schema(schema).option('delimiter', '\t').csv(input_file).repartition(num_partitions, 'id')
# Get max score
max_score = ranking_df.select(max('score').alias('max')).collect()[0]['max']
print ("Max Score for " + str(input_file) + " is " + str(max_score))
# TESTING
# print ("Loaded df sample:")
# ranking_df.show(1000, False)
# Join scores to synonyms and keep required fields
doi_score_df = synonym_df.join(ranking_df, ['id']).select('doi', 'score', 'class').repartition(num_partitions, 'doi').cache()
# Write output
output_file = output_file_list[offset]
print ("Writing to: " + output_file)
doi_score_df.write.mode('overwrite').option('delimiter','\t').option('header',False).csv(output_file, compression='gzip')
# Creata another file for the bip update process
ranking_df = ranking_df.select('id', 'score', F.lit(F.col('score')/max_score).alias('normalized_score'), 'class', F.col('class').alias('class_dup'))
doi_score_df = synonym_df.join(ranking_df, ['id']).select('doi', 'score', 'normalized_score', 'class', 'class_dup').repartition(num_partitions, 'doi').cache()
output_file = output_file.replace(".txt.gz", "_for_bip_update.txt.gz")
print ("Writing bip update to: " + output_file)
doi_score_df.write.mode('overwrite').option('delimiter','\t').option('header',False).csv(output_file, compression='gzip')
# Free memory?
ranking_df.unpersist(True)
print ("-----------------------------")
print ("\n\nFinished!\n\n")

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import sys
from pyspark.sql import SparkSession
from pyspark import SparkConf, SparkContext
import pyspark.sql.functions as F
from pyspark.sql.types import StringType, IntegerType, StructType, StructField
if len(sys.argv) < 8:
print("Usage: projects_impact.py <relations_folder> <influence_file> <popularity_file> <cc_file> <impulse_file> <num_partitions> <output_dir>")
sys.exit(-1)
appName = 'Project Impact Indicators'
conf = SparkConf().setAppName(appName)
sc = SparkContext(conf = conf)
spark = SparkSession.builder.appName(appName).getOrCreate()
sc.setLogLevel('OFF')
# input parameters
relations_fd = sys.argv[1]
influence_fd = sys.argv[2]
popularity_fd = sys.argv[3]
cc_fd = sys.argv[4]
impulse_fd = sys.argv[5]
num_partitions = int(sys.argv[6])
output_dir = sys.argv[7]
# schema for impact indicator files
impact_files_schema = StructType([
StructField('resultId', StringType(), False),
StructField('score', IntegerType(), False),
StructField('class', StringType(), False),
])
# list of impact indicators
impact_indicators = [
('influence', influence_fd, 'class'),
('popularity', popularity_fd, 'class'),
('impulse', impulse_fd, 'score'),
('citation_count', cc_fd, 'score')
]
'''
* Read impact indicator file and return a dataframe with the following schema:
* resultId: String
* indicator_name: Integer
'''
def read_df(fd, indicator_name, column_name):
return spark.read.schema(impact_files_schema)\
.option('delimiter', '\t')\
.option('header', False)\
.csv(fd)\
.select('resultId', F.col(column_name).alias(indicator_name))\
.repartition(num_partitions, 'resultId')
# Print dataframe schema, first 5 rows, and count
def print_df(df):
df.show(50)
df.printSchema()
print(df.count())
# Sets a null value to the column if the value is equal to the given value
def set_class_value_to_null(column, value):
return F.when(column != value, column).otherwise(F.lit(None))
# load and filter Project-to-Result relations
print("Reading relations")
relations = spark.read.json(relations_fd)\
.select(F.col('source').alias('projectId'), F.col('target').alias('resultId'), 'relClass', 'dataInfo.deletedbyinference', 'dataInfo.invisible')\
.where( (F.col('relClass') == 'produces') \
& (F.col('deletedbyinference') == "false")\
& (F.col('invisible') == "false"))\
.drop('deletedbyinference')\
.drop('invisible')\
.drop('relClass')\
.repartition(num_partitions, 'resultId')
for indicator_name, fd, column_name in impact_indicators:
print("Reading {} '{}' field from file".format(indicator_name, column_name))
df = read_df(fd, indicator_name, column_name)
# sets a zero value to the indicator column if the value is C5
if (column_name == 'class'):
df = df.withColumn(indicator_name, F.when(F.col(indicator_name).isin("C5"), 0).otherwise(1))
# print_df(df)
print("Joining {} to relations".format(indicator_name))
# NOTE: we use inner join because we want to keep only the results that have an impact score
# also note that all impact scores have the same set of results
relations = relations.join(df, 'resultId', 'inner')\
.repartition(num_partitions, 'resultId')
# uncomment to print non-null values count for each indicator
# for indicator_name, fd, column_name in impact_indicators:
# print("Counting non null values for {}".format(indicator_name))
# print(relations.filter(F.col(indicator_name).isNotNull()).count())
# sum the impact indicator values for each project
relations.groupBy('projectId')\
.agg(\
F.sum('influence').alias('numOfInfluentialResults'),\
F.sum('popularity').alias('numOfPopularResults'),\
F.sum('impulse').alias('totalImpulse'),\
F.sum('citation_count').alias('totalCitationCount')\
)\
.write.mode("overwrite")\
.json(output_dir, compression="gzip")

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@ -0,0 +1,602 @@
<workflow-app xmlns="uri:oozie:workflow:0.5" name="ranking-wf">
<!-- Global params -->
<global>
<job-tracker>${jobTracker}</job-tracker>
<name-node>${nameNode}</name-node>
<configuration>
<property>
<name>oozie.action.sharelib.for.spark</name>
<value>${oozieActionShareLibForSpark2}</value>
</property>
</configuration>
</global>
<!-- start using a decision node, so as to determine from which point onwards a job will continue -->
<start to="entry-point-decision" />
<decision name="entry-point-decision">
<switch>
<!-- The default will be set as the normal start, a.k.a. get-doi-synonyms -->
<!-- If any different condition is set, go to the corresponding start -->
<case to="non-iterative-rankings">${wf:conf('resume') eq "rankings-start"}</case>
<case to="spark-impulse">${wf:conf('resume') eq "impulse"}</case>
<case to="spark-pagerank">${wf:conf('resume') eq "pagerank"}</case>
<case to="spark-attrank">${wf:conf('resume') eq "attrank"}</case>
<!-- <case to="iterative-rankings">${wf:conf('resume') eq "rankings-iterative"}</case> -->
<case to="get-file-names">${wf:conf('resume') eq "format-results"}</case>
<case to="map-openaire-to-doi">${wf:conf('resume') eq "map-ids"}</case>
<case to="map-scores-to-dois">${wf:conf('resume') eq "map-scores"}</case>
<case to="create-openaire-ranking-graph">${wf:conf('resume') eq "start"}</case>
<!-- Aggregation of impact scores on the project level -->
<case to="project-impact-indicators">${wf:conf('resume') eq "projects-impact"}</case>
<case to="create-actionset">${wf:conf('resume') eq "create-actionset"}</case>
<default to="create-openaire-ranking-graph" />
</switch>
</decision>
<!-- initial step: create citation network -->
<action name="create-openaire-ranking-graph">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>OpenAIRE Ranking Graph Creation</name>
<jar>create_openaire_ranking_graph.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkHighDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<!-- The openaire graph data from which to read relations and objects -->
<arg>${openaireDataInput}</arg>
<!-- Year for filtering entries w/ larger values / empty -->
<arg>${currentYear}</arg>
<!-- number of partitions to be used on joins -->
<arg>${sparkShufflePartitions}</arg>
<!-- The output of the graph should be the openaire input graph for ranking-->
<arg>${openaireGraphInputPath}</arg>
<file>${wfAppPath}/create_openaire_ranking_graph.py#create_openaire_ranking_graph.py</file>
</spark>
<ok to="non-iterative-rankings" />
<error to="openaire-graph-error" />
</action>
<!-- Citation Count and RAM are calculated in parallel-->
<fork name="non-iterative-rankings">
<path start="spark-cc"/>
<!-- <path start="spark-impulse"/> -->
<path start="spark-ram"/>
</fork>
<!-- Run Citation Count calculation -->
<action name="spark-cc">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>Citation Count calculation</name>
<jar>CC.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>${openaireGraphInputPath}</arg>
<!-- number of partitions to be used on joins -->
<arg>${sparkShufflePartitions}</arg>
<file>${wfAppPath}/bip-ranker/CC.py#CC.py</file>
</spark>
<ok to="join-non-iterative-rankings" />
<error to="cc-fail" />
</action>
<!-- RAM calculation -->
<action name="spark-ram">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>RAM calculation</name>
<jar>TAR.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>${openaireGraphInputPath}</arg>
<arg>${ramGamma}</arg>
<arg>${currentYear}</arg>
<arg>RAM</arg>
<arg>${sparkShufflePartitions}</arg>
<arg>${checkpointDir}</arg>
<file>${wfAppPath}/bip-ranker/TAR.py#TAR.py</file>
</spark>
<ok to="join-non-iterative-rankings" />
<error to="ram-fail" />
</action>
<!-- Join non-iterative methods -->
<join name="join-non-iterative-rankings" to="spark-impulse"/>
<action name="spark-impulse">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>Impulse calculation</name>
<jar>CC.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>${openaireGraphInputPath}</arg>
<!-- number of partitions to be used on joins -->
<arg>${sparkShufflePartitions}</arg>
<arg>3</arg>
<file>${wfAppPath}/bip-ranker/CC.py#CC.py</file>
</spark>
<ok to="spark-pagerank" />
<error to="impulse-fail" />
</action>
<action name="spark-pagerank">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>Pagerank calculation</name>
<jar>PageRank.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>${openaireGraphInputPath}</arg>
<arg>${pageRankAlpha}</arg>
<arg>${convergenceError}</arg>
<arg>${checkpointDir}</arg>
<!-- number of partitions to be used on joins -->
<arg>${sparkShufflePartitions}</arg>
<arg>dfs</arg>
<file>${wfAppPath}/bip-ranker/PageRank.py#PageRank.py</file>
</spark>
<ok to="spark-attrank" />
<error to="pagerank-fail" />
</action>
<action name="spark-attrank">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>AttRank calculation</name>
<jar>AttRank.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>${openaireGraphInputPath}</arg>
<arg>${attrankAlpha}</arg>
<arg>${attrankBeta}</arg>
<arg>${attrankGamma}</arg>
<arg>${attrankRho}</arg>
<arg>${currentYear}</arg>
<arg>${attrankStartYear}</arg>
<arg>${convergenceError}</arg>
<arg>${checkpointDir}</arg>
<!-- number of partitions to be used on joins -->
<arg>${sparkShufflePartitions}</arg>
<arg>dfs</arg>
<file>${wfAppPath}/bip-ranker/AttRank.py#AttRank.py</file>
</spark>
<ok to="get-file-names" />
<error to="attrank-fail" />
</action>
<action name="get-file-names">
<shell xmlns="uri:oozie:shell-action:0.3">
<!-- Exec is needed for shell commands - points to type of shell command -->
<exec>/usr/bin/bash</exec>
<!-- name of script to run -->
<argument>get_ranking_files.sh</argument>
<!-- We only pass the directory where we expect to find the rankings -->
<argument>${workingDir}</argument>
<file>${wfAppPath}/get_ranking_files.sh#get_ranking_files.sh</file>
<!-- Get the output in order to be usable by following actions -->
<capture-output/>
</shell>
<ok to="format-result-files" />
<error to="filename-getting-error" />
</action>
<!-- Now we will run in parallel the formatting of ranking files for BiP! DB and openaire (json files) -->
<fork name="format-result-files">
<path start="format-bip-files"/>
<path start="format-json-files"/>
</fork>
<!-- Format json files -->
<!-- Two parts: a) format files b) make the file endings .json.gz -->
<action name="format-json-files">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>Format Ranking Results JSON</name>
<jar>format_ranking_results.py</jar>
<spark-opts>
--executor-memory=${sparkNormalExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>json-5-way</arg>
<!-- Input files must be identified dynamically -->
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['pr_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['attrank_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['cc_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['impulse_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['ram_file']}</arg>
<!-- Num partitions -->
<arg>${sparkShufflePartitions}</arg>
<!-- Type of data to be produced [bip (dois) / openaire (openaire-ids) ] -->
<arg>openaire</arg>
<file>${wfAppPath}/format_ranking_results.py#format_ranking_results.py</file>
</spark>
<ok to="join-file-formatting" />
<error to="json-formatting-fail" />
</action>
<!-- This is the second line of parallel workflow execution where we create the BiP! DB files -->
<action name="format-bip-files">
<!-- This is required as a tag for spark jobs, regardless of programming language -->
<spark xmlns="uri:oozie:spark-action:0.2">
<!-- using configs from an example on openaire -->
<master>yarn-cluster</master>
<mode>cluster</mode>
<!-- This is the name of our job -->
<name>Format Ranking Results BiP! DB</name>
<!-- Script name goes here -->
<jar>format_ranking_results.py</jar>
<!-- spark configuration options: I've taken most of them from an example from dhp workflows / Master value stolen from sandro -->
<spark-opts>
--executor-memory=${sparkNormalExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>zenodo</arg>
<!-- Input files must be identified dynamically -->
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['pr_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['attrank_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['cc_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['impulse_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['ram_file']}</arg>
<!-- Num partitions -->
<arg>${sparkShufflePartitions}</arg>
<!-- Type of data to be produced [bip (dois) / openaire (openaire-ids) ] -->
<arg>openaire</arg>
<!-- This needs to point to the file on the hdfs i think -->
<file>${wfAppPath}/format_ranking_results.py#format_ranking_results.py</file>
</spark>
<ok to="join-file-formatting" />
<error to="bip-formatting-fail" />
</action>
<!-- Finish formatting jobs -->
<join name="join-file-formatting" to="map-openaire-to-doi"/>
<!-- maps openaire ids to DOIs -->
<action name="map-openaire-to-doi">
<spark xmlns="uri:oozie:spark-action:0.2">
<!-- Delete previously created doi synonym folder -->
<prepare>
<delete path="${synonymFolder}"/>
</prepare>
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>Openaire-DOI synonym collection</name>
<jar>map_openaire_ids_to_dois.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkHighDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>${openaireDataInput}/</arg>
<!-- number of partitions to be used on joins -->
<arg>${synonymFolder}</arg>
<file>${wfAppPath}/map_openaire_ids_to_dois.py#map_openaire_ids_to_dois.py</file>
</spark>
<ok to="map-scores-to-dois" />
<error to="synonym-collection-fail" />
</action>
<!-- mapping openaire scores to DOIs -->
<action name="map-scores-to-dois">
<!-- This is required as a tag for spark jobs, regardless of programming language -->
<spark xmlns="uri:oozie:spark-action:0.2">
<!-- using configs from an example on openaire -->
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>Mapping Openaire Scores to DOIs</name>
<jar>map_scores_to_dois.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkHighDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<arg>${synonymFolder}</arg>
<!-- Number of partitions -->
<arg>${sparkShufflePartitions}</arg>
<!-- The remaining input are the ranking files fproduced for bip db-->
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['pr_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['attrank_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['cc_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['impulse_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['ram_file']}</arg>
<file>${wfAppPath}/map_scores_to_dois.py#map_scores_to_dois.py</file>
</spark>
<ok to="project-impact-indicators" />
<error to="map-scores-fail" />
</action>
<action name="project-impact-indicators">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>Project Impact Indicators calculation</name>
<jar>projects_impact.py</jar>
<spark-opts>
--executor-memory=${sparkHighExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.sql.shuffle.partitions=${sparkShufflePartitions}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
</spark-opts>
<!-- Script arguments here -->
<!-- graph data folder from which to read relations -->
<arg>${openaireDataInput}/relation</arg>
<!-- input files with impact indicators for results -->
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['pr_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['attrank_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['cc_file']}</arg>
<arg>${nameNode}/${workingDir}/${wf:actionData('get-file-names')['impulse_file']}</arg>
<!-- number of partitions to be used on joins -->
<arg>${sparkShufflePartitions}</arg>
<arg>${projectImpactIndicatorsOutput}</arg>
<file>${wfAppPath}/projects_impact.py#projects_impact.py</file>
</spark>
<ok to="delete-output-path-for-actionset" />
<error to="project-impact-indicators-fail" />
</action>
<!-- Re-create folder for actionsets -->
<action name="delete-output-path-for-actionset">
<fs>
<delete path="${actionSetOutputPath}"/>
<mkdir path="${actionSetOutputPath}"/>
</fs>
<ok to="create-actionset"/>
<error to="actionset-delete-fail"/>
</action>
<action name="create-actionset">
<spark xmlns="uri:oozie:spark-action:0.2">
<master>yarn-cluster</master>
<mode>cluster</mode>
<name>Produces the atomic action with the bip finder scores</name>
<class>eu.dnetlib.dhp.actionmanager.bipfinder.SparkAtomicActionScoreJob</class>
<jar>dhp-aggregation-${projectVersion}.jar</jar>
<spark-opts>
--executor-memory=${sparkNormalExecutorMemory}
--executor-cores=${sparkExecutorCores}
--driver-memory=${sparkNormalDriverMemory}
--conf spark.extraListeners=${spark2ExtraListeners}
--conf spark.sql.queryExecutionListeners=${spark2SqlQueryExecutionListeners}
--conf spark.yarn.historyServer.address=${spark2YarnHistoryServerAddress}
--conf spark.eventLog.dir=${nameNode}${spark2EventLogDir}
--conf spark.sql.warehouse.dir=${sparkSqlWarehouseDir}
</spark-opts>
<arg>--resultsInputPath</arg><arg>${bipScorePath}</arg>
<arg>--projectsInputPath</arg><arg>${projectImpactIndicatorsOutput}</arg>
<arg>--outputPath</arg><arg>${actionSetOutputPath}</arg>
</spark>
<ok to="end"/>
<error to="actionset-creation-fail"/>
</action>
<!-- Definitions of failure messages -->
<kill name="openaire-graph-error">
<message>Creation of openaire-graph failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="cc-fail">
<message>CC failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="ram-fail">
<message>RAM failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="impulse-fail">
<message>Impulse failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="pagerank-fail">
<message>PageRank failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="attrank-fail">
<message>AttRank failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="filename-getting-error">
<message>Error getting key-value pairs for output files, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="json-formatting-fail">
<message>Error formatting json files, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="bip-formatting-fail">
<message>Error formatting BIP files, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="synonym-collection-fail">
<message>Synonym collection failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="map-scores-fail">
<message>Mapping scores to DOIs failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="actionset-delete-fail">
<message>Deleting output path for actionsets failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="actionset-creation-fail">
<message>ActionSet creation for results failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<kill name="project-impact-indicators-fail">
<message>Calculating project impact indicators failed, error message[${wf:errorMessage(wf:lastErrorNode())}]</message>
</kill>
<!-- Define ending node -->
<end name="end" />
</workflow-app>

View File

@ -38,6 +38,7 @@
<module>dhp-usage-raw-data-update</module>
<module>dhp-broker-events</module>
<module>dhp-doiboost</module>
<module>dhp-impact-indicators</module>
</modules>
<pluginRepositories>