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FiloDB

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High-performance distributed analytical database + Spark SQL queries + built for streaming.

filodb-announce google group and filodb-discuss google group

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Columnar, versioned layers of data wrapped in a yummy high-performance analytical database engine.

See architecture and datasets and reading for more information. Also see the Spark Notebooks under doc... there is one for time-series/geo analysis of the NYC Taxi dataset, and one for interactive charting of the GDELT dataset!

Table of Contents generated with DocToc

Overview

FiloDB is a new open-source distributed, versioned, and columnar analytical database designed for modern streaming workloads.

  • High performance - competitive with Parquet scan speeds, plus filtering along two or more dimensions
    • Very flexible filtering: filter on only part of a partition key, much more flexible than allowed in Cassandra
    • Much faster bulk ingestion than raw Cassandra tables
  • Compact storage - within 35% of Parquet for CassandraColumnStore
  • Idempotent writes - primary-key based appends and updates; easy exactly-once ingestion from streaming sources
  • Distributed - pluggable storage engine includes Apache Cassandra and in-memory
  • Low-latency - minimal SQL query latency of 15ms on one node; sub-second easily achievable with filtering and easy to use concurrency control
  • SQL queries - plug in Tableau or any tool using JDBC/ODBC drivers
  • Ingest from Spark/Spark Streaming from any supported Spark data source

Overview presentation -- see the docs folder for design docs.

To compile the .mermaid source files to .png's, install the Mermaid CLI.

Use Cases

  • Storage and analysis of streaming event / time series data
  • Data warehousing
  • In-memory database for Spark Streaming analytics
  • Low-latency in-memory SQL database engine

Anti-use-cases

  • Heavily transactional, update-oriented workflows

Roadmap

Your input is appreciated!

NOTE: Please beware that significant storage-layer changes are taking place. For a stable version, please use the v0.4 release/tag. At the next release, the storage layer should be stable for production use.

  • Kafka input API / connector (without needing Spark)
  • In-memory caching for significant query speedup
  • True columnar querying and execution, using late materialization and vectorization techniques. GPU/SIMD.
  • Projections. Often-repeated queries can be sped up significantly with projections.

Pre-requisites

  1. Java 8
  2. SBT to build
  3. Apache Cassandra 2.x or 3.x (We prefer using CCM for local testing) (Optional if you are using the in-memory column store)
  4. Apache Spark (2.0)

NOTE: Please check out the spark1.6 branch for Spark 1.6 version.

Getting Started

  1. Clone the project and cd into the project directory,

    $ git clone https://github.com/filodb/FiloDB.git
    $ cd FiloDB
    
    • It is recommended you use the last stable released version.
    • To build, run filo-cli (see below) and also sbt spark/assembly.
  2. Choose either the Cassandra column store (default) or the in-memory column store.

    • Start a Cassandra Cluster.
    • Copy core/src/main/resources/filodb-defaults.conf and modify the Cassandra settings for your cluster. This step and passing in a custom config may be skipped for a localhost Cassandra cluster with no auth.
    • Or, use FiloDB's in-memory column store with Spark (does not work with CLI). Pass the --conf spark.filodb.store=in-memory to spark-submit / spark-shell. This is a great option to test things out, and is really really fast!
  3. For Cassandra, update the keyspace-replication-options config, then run filo-cli -Dconfig.file=/path/to/my/filo.conf --command init to initialize the default filodb_admin keyspace. In addition, you should use CQLSH to create any additional keyspaces you desire to store FiloDB datasets in.

  4. Dataset creation can be done using filo-cli or using Spark Shell / Scala/Java API.

  5. Inserting data can be done using filo-cli (CSV only), using Spark SQL/JDBC (INSERT INTO), or the Spark Shell / Scala / Java API.

  6. Querying is done using Spark SQL/JDBC or Scala/Java API.

  7. Listing/deleting/maintenance can be done using filo-cli. If using Cassandra, cqlsh can also be used to inspect metadata.

Note: There is at least one release out now, tagged via Git and also located in the "Releases" tab on Github.

Introduction to FiloDB Data Modelling

Perhaps it's easiest by starting with a diagram of how FiloDB stores data.

Column A Column B
Partition key 1 Chunk 1 Chunk 2 Chunk 1 Chunk 2
Partition key 2 Chunk 1 Chunk 2 Chunk 1 Chunk 2

Data is modeled and ingested using the two different parts of a record's primary key: the partition key and the row key.

  1. partition key - decides how data is going to be distributed across the cluster. All data within one partition key is guaranteed to fit on one node. Similar to the partition key in Cassandra. May consist of multiple columns with computed columns.
  2. row key - acts as a primary key within each partition. Records with the same row key will replace previous ones. Within each chunkset, records are sorted by row key. Row keys also facilitate range scans within a partition.

The PRIMARY KEY for FiloDB consists of (partition key, row key). When choosing the above values you must make sure the combination of the two are unique. If any component of a primary key contains a null value, then a default value will be substituted.

Specifying the partition key is optional. If a partition key is not specified, FiloDB will create a default one with a fixed value, which means everything will be thrown into one node, and is only suitable for small amounts of data. The usual strategy is to find partition keys that distribute data in the cluster and over time.

For examples of data modeling and choosing keys, see the examples below as well as datasets.

For additional information refer to Data Modeling and Performance Considerations.

Computed Columns

You may specify a function, or computed column, for use with partition keys. This is especially useful for hashing values or time bucketing.

Name Description Example
string returns a constant string value :string /0
getOrElse returns default value if column value is null. This is not needed most of the time as FiloDB will use a default value in case of null, though :getOrElse may help with key uniqueness. NOTE: do not use the default value null for strings. :getOrElse columnA ---
round rounds down a numeric column. Useful for bucketing by time or bucketing numeric IDs. :round timestamp 10000
stringPrefix takes the first N chars of a string; good for partitioning :stringPrefix token 4
hash hashes keys of any type to an int between 0 and N :hash customerID 400
timeslice bucketizes a Long (millisecond) or Timestamp column using duration strings - 500ms, 5s, 10m, 3h, etc. :timeslice arrivalTime 30s
monthOfYear return 1 to 12 (IntColumn) for the month number of a Long (millisecond) or Timestamp column :monthOfYear pickup_datetime

FiloDB vs Cassandra Data Modelling

  • Like Cassandra, partitions (physical rows) distribute data
  • Like Cassandra, a single partition is the smallest unit of parallelism when querying from Spark
  • Row keys are like Cassandra clustering keys -- they act as primary key within a partition, but sorting works differently due to chunks
  • Wider rows work better for FiloDB (bigger chunk/segment size)
  • FiloDB does not have Cassandra's restrictions for partition key filtering. You can filter by any partition keys with most operators. This means less tables in FiloDB can match more query patterns.
  • Cassandra range scans within a partition is available via row keys

Data Modelling and Performance Considerations

Choosing Partition Keys.

  • A good start for a partition key is a hash of an ID or columns that distribute well, plus a time bucket. This spreads data around but also prevents too much data from piling up in a single partition.
  • Partition keys are the most efficient way to filter data. Remember that, unlike Cassandra, FiloDB is able to efficiently filter any column in a partition key -- even string contains, IN on only one column. It can do this because FiloDB pre-scans a much smaller table ahead of scanning the main columnar chunk table. This flexibility means that there is no need to populate different tables with different orders of partition keys just to optimize for different queries.
  • Target between 10-100 active partitions per node in a cluster during ingestion. This leads to big chunk sizes that are efficient for reading. This does not mean that there can only be 100 partitions total; rather that at any one time during ingestion the number of active partitions are limited (another reason why time bucketing is important).
  • If the numer of rows in each partition is too few, then the storage will not be efficient.
  • Consider picking a column or group of columns with low cardinality, and has good distribution so that data is distributed across the cluster.
  • Consider only those columns that do not get updated. Since partition key is part of primary key, partition key columns cannot get updated.
  • For Cassandra, each partition cannot be too big, target 500MB-1GB as a maximum size

Row Keys and Chunk Size.

Within a partition, data is divided into chunks. The relationship between partitions, chunks, and row keys are as follows:

  • During ingestion, all the rows for a partition are sorted by row key in a memtable, then chunked (with the max chunk size configurable). Thus all chunks are internally in row key sorted order.
  • Filtering within a partition by row key ranges is available. This results in only chunks that intersect with the row key range being read.
  • The choice of row key does not affect chunk size, but does affect row key range scanning. Choose a row key according to how you want to filter partition data -- put the most important filtering key first in the row key.

Bigger chunks are better. The chunk size can be predicted as follows:

Math.min(`chunk_size`, MemtableSize / (AverageActiveNumberOfPartitions))

For example, with the default max-rows-per-table of 200000, and 100 active partitions (let's say the time bucket is a day, and on average the other partition keys are hashed into 100 buckets), then the average chunk size will be 200000/100 = 2000 rows per chunk.

Chunk size distribution may be checked by the CLI analyze command. In addition, the following configuration affects chunk size:

  • memtable.max-rows-per-table, memtable.flush-trigger-rows affects how many rows are kept in the MemTable at a time, and this along with how many partitions are in the MemTable directly leads to the chunk size upon flushing.
  • chunk_size option when creating a dataset caps the size of a single chunk. Smaller chunk sizes lead to slower reads, but more even distribution of chunks (ie better range scanning)
  • Row keys are immutable. Don't pick columns that might change.
  • Consider moving one of the partition keys as a part of a row key if your chunk sizes/partitions are too small. Use the analyze filo-cli command to discover partition size.
  • Less partitions and smaller chunk sizes leads to more chunks being written with each flush, which leads to better range scanning

Predicate Pushdowns

To help with planning, here is an exact list of the predicate pushdowns (in Spark) that help with reducing I/O and query times:

  • Partition key column(s): =, IN on any partition key column
    • = on every partition key results in a single-partition query
    • = or IN on every partition key results in a multi-partition query, still faster than full table scan
    • Otherwise, a filtered full table scan results - partitions not matching predicates will not be scanned
  • Rowkey Range Scan:
    • Range scans are available for matching either the entire row key or the first N components of the row key
    • The last component compared must be either = or a range, and all other components must be = comparison
    • For example, if a row key consists of colA, colB, colC, then the following predicates are valid for push down:
      • colA = value
      • colA >/>= value AND colA </<= value
      • colA = value AND colB = val2
      • colA = value AND (colB >/>= val1 AND colB </<= val2)
      • colA = valA AND colB = valB AND colC = valC
      • colA = valA AND colB = valB AND (colC >/>= val1 AND colC </<= val2)

Note: You can see predicate pushdown filters in application logs by setting logging level to INFO.

Example FiloDB Schema for machine metrics

This is one way I would recommend setting things up to take advantage of FiloDB.

The metric names are the column names. This lets you select on just one metric and effectively take advantage of columnar layout.

  • Partition key = :hash hostname 100,:timeslice timestamp 1d
  • Row key = timestamp,hostname
  • Columns: hostname, timestamp, CPU, load_avg, disk_usage, etc.

You can add more metrics/columns over time, but storing each metric in its own column is FAR FAR more efficient, at least in FiloDB. For example, disk usage metrics are likely to have very different numbers than load_avg, and so Filo can optimize the storage of each one independently. Right now I would store them as ints and longs if possible.

Queries that would work well for the above layout:

  • SELECT avg(load_avg), min(load_avg), max(load_avg) FROM metrics WHERE timestamp > t1 AND timestamp < t2
  • The above with filter on a specific hostname (would be single partition read)

Distributed Partitioning

FiloDB will automatically form a cluster (via Akka Cluster), divide the range of partition keys amongst the nodes using a consistent-hashing algorithm, and re-route incoming records to the right ingestion node. Thus, users no longer need to sort their incoming data in Spark.

Using FiloDB Data Source with Spark

FiloDB has a Spark data-source module - filodb.spark. So, you can use the Spark Dataframes read and write APIs with FiloDB. To use it, follow the steps below

  1. Start Cassandra and update project configuration if required.
  2. From the FiloDB project directory, execute,
    $ sbt clean
    $ ./filo-cli --command init
    $ sbt spark/assembly
    
  3. Use the jar FiloDB/spark/target/scala-2.10/filodb-spark-assembly-0.4.jar with Spark 1.6.x.

The options to use with the data-source api are:

option value command optional
dataset name of the dataset read/write No
database name of the database to use for the dataset. For Cassandra, defaults to filodb.cassandra.keyspace config. read/write Yes
row_keys comma-separated list of column name(s) to use for the row primary key within each partition. Computed columns are not allowed. May be used for range queries within partitions and chunks are sorted by row keys. write No if mode is OverWrite or creating dataset for first time
partition_keys comma-separated list of column name(s) or computed column functions to use for the partition key. If not specified, defaults to :string /0 (a single partition). write Yes
splits_per_node number of read threads per node, defaults to 4 read Yes
reset_schema If true, allows dataset schema (eg partition keys) to be redefined for an existing dataset when SaveMode.Overwrite is used. Defaults to false. write Yes
chunk_size Max number of rows to put into one chunk. Note that this only has an effect if the dataset is created for the first time. write Yes
flush_after_write initiates a memtable flush after Spark INSERT / DataFrame.write; this ensures all the rows are flushed to ColumnStore. Might want to be turned off for streaming write yes - default true
version numeric version of data to write, defaults to 0 read/write Yes

Partitioning columns could be created using an expression on the original column in Spark:

val newDF = df.withColumn("partition", df("someCol") % 100)

or even UDFs:

val idHash = sqlContext.udf.register("hashCode", (s: String) => s.hashCode())
val newDF = df.withColumn("partition", idHash(df("id")) % 100) 

However, note that the above methods will lead to a physical column being created, so use of computed columns is probably preferable.

Configuring FiloDB

Some options must be configured before starting the Spark Shell or Spark application. FiloDB executables are invoked by spark application. These configuration settings can be tuned as per the needs of individual application invoking filoDB executables. There are two methods:

  1. Modify the application.conf and rebuild, or repackage a new configuration.
  2. Override the built in defaults by setting SparkConf configuration values, preceding the filo settings with spark.filodb. For example, to change the default keyspace, pass --conf spark.filodb.cassandra.keyspace=mykeyspace to Spark Shell/Submit. To use the fast in-memory column store instead of Cassandra, pass --conf spark.filodb.store=in-memory.
  3. It might be easier to pass in an entire configuration file to FiloDB. Pass the java option -Dfilodb.config.file=/path/to/my-filodb.conf, for example using --java-driver-options.

Note that if Cassandra is kept as the default column store, the keyspace can be changed on each transaction by specifying the database option in the data source API, or the database parameter in the Scala API.

For a list of all configuration params as well as a template for a config file, see the filodb_defaults.conf file included in the source and packaged with the jar as defaults.

For metrics system configuration, see the metrics section below.

Passing Cassandra Authentication Settings

Typically, you have per-environment configuration files, and you do not want to check in username and password information. Here are ways to pass in authentication settings:

  • Pass in the credentials on the command line.

    • For Spark, --conf spark.filodb.cassandra.username=XYZ etc.
    • For CLI, other apps, pass in JVM args: -Dfilodb.cassandra.username=XYZ
  • Put the credentials in a local file on the host, and refer to it from your config file. In your config file, do include "/usr/local/filodb-cass-auth.properties". The properties file would look like:

      filodb.cassandra.username=XYZ
      filodb.cassandra.password=AABBCC
    

Spark Data Source API Example (spark-shell)

You can follow along using the Spark Notebook... launch the notebook using EXTRA_CLASSPATH=$FILO_JAR ADD_JARS=$FILO_JAR ./bin/spark-notebook & where FILO_JAR is the path to filodb-spark-assembly jar. See the FiloDB_GDELT notebook to follow the GDELT examples below, or the NYC Taxi notebook for some really neat time series/geo analysis!

Or you can start a spark-shell locally,

bin/spark-shell --jars ../FiloDB/spark/target/scala-2.11/filodb-spark-assembly-0.7.0.spark20-SNAPSHOT.jar --packages com.databricks:spark-csv_2.11:1.4.0 --driver-memory 3G --executor-memory 3G

Loading CSV file from Spark:

scala> val csvDF = spark.read.format("com.databricks.spark.csv").
           option("header", "true").option("inferSchema", "true").
           load("../FiloDB/GDELT-1979-1984-100000.csv")

Creating a dataset from a Spark DataFrame,

scala> import org.apache.spark.sql.SaveMode
import org.apache.spark.sql.SaveMode

scala> csvDF.write.format("filodb.spark").
             option("dataset", "gdelt").
             option("row_keys", "GLOBALEVENTID").
             option("partition_keys", "MonthYear").
             mode(SaveMode.Overwrite).save()

Above, we partition the GDELT dataset by MonthYear, creating roughly 72 partitions for 1979-1984, with the unique GLOBALEVENTID used as a row key. You could use multiple columns for the partition or row keys, of course. For example, to partition by country code and year instead:

scala> csvDF.write.format("filodb.spark").
             option("dataset", "gdelt_by_country_year").
             option("row_keys", "GLOBALEVENTID").
             option("partition_keys", "Actor2CountryCode,Year").
             mode(SaveMode.Overwrite).save()

In both cases, the use of GLOBALEVENTID as a row key would allow for range queries within partitions by the GLOBALEVENTID.

The key definitions can be left out for appends:

sourceDataFrame.write.format("filodb.spark").
                option("dataset", "gdelt").
                mode(SaveMode.Append).save()

Note that for efficient columnar encoding, wide rows with fewer partition keys are better for performance.

By default, data is written to replace existing records with the same primary key. To turn this primary key replacement off for faster ingestion, set filodb.reprojector.bulk-write-mode to true.

Reading the dataset,

val df = spark.read.format("filodb.spark").option("dataset", "gdelt").load()

The dataset can be queried using the DataFrame DSL. See the section Querying Datasets for examples.

Spark/Scala/Java API

There is a more typesafe API than the Spark Data Source API.

import filodb.spark._
spark.saveAsFilo(df, "gdelt",
                      rowKeys = Seq("GLOBALEVENTID"),
                      partitionKeys = Seq("MonthYear"))

The above creates the gdelt table based on the keys above, and also inserts data from the dataframe df.

NOTE: If you are running Spark Shell in DSE, you might need to do import _root_.filodb.spark._.

Please see the ScalaDoc for the method for more details -- there is a database option for specifying the Cassandra keyspace, and a mode option for specifying the Spark SQL SaveMode.

There is also an API purely for inserting data... after all, specifying the keys is not needed when inserting into an existing table.

import filodb.spark._
spark.insertIntoFilo(df, "gdelt")

The API for creating a DataFrame is also much more concise:

val df = spark.filoDataset("gdelt")
val df2 = spark.filoDataset("gdelt", database = Some("keyspace2"))

The above method calls rely on an implicit conversion. From Java, you would need to create a new FiloContext first:

FiloContext fc = new filodb.spark.FiloContext(sparkSession.sqlContext);
fc.insertIntoFilo(df, "gdelt");

Spark Streaming Example

It's not difficult to ingest data into FiloDB using Spark Streaming. Simple use foreachRDD on your DStream and then transform each RDD into a DataFrame.

For an example, see the StreamingTest.

SQL/Hive Example

Start Spark-SQL:

  bin/spark-sql --jars path/to/FiloDB/spark/target/scala-2.10/filodb-spark-assembly-0.4.jar

(NOTE: if you want to connect with a real Hive Metastore, you should probably instead start the thrift server, also adding the --jars above, and then start the spark-beeline client)

Create a temporary table using an existing dataset,

  create temporary table gdelt
  using filodb.spark
  options (
   dataset "gdelt"
 );

Then, start running SQL queries!

You probably want to create a permanent Hive Metastore entry so you don't have to run create temporary table every single time at startup:

  CREATE TABLE gdelt using filodb.spark options (dataset "gdelt");

Once this is done, you could insert data using SQL syntax:

  INSERT INTO TABLE gdelt SELECT * FROM othertable;

Of course, this assumes othertable has a similar schema.

Querying Datasets

Now do some queries, using the DataFrame DSL:

scala> df.select(count(df("MonthYear"))).show()
...
COUNT(MonthYear)
4037998

or SQL, to find the top 15 events with the highest tone:

scala> df.registerTempTable("gdelt")

scala> sqlContext.sql("SELECT Actor1Name, Actor2Name, AvgTone FROM gdelt ORDER BY AvgTone DESC LIMIT 15").collect()
res13: Array[org.apache.spark.sql.Row] = Array([208077.29634561483])

Now, how about something uniquely Spark .. feed SQL query results to MLLib to compute a correlation:

scala> import org.apache.spark.mllib.stat.Statistics

scala> val numMentions = df.select("NumMentions").map(row => row.getInt(0).toDouble)
numMentions: org.apache.spark.rdd.RDD[Double] = MapPartitionsRDD[100] at map at DataFrame.scala:848

scala> val numArticles = df.select("NumArticles").map(row => row.getInt(0).toDouble)
numArticles: org.apache.spark.rdd.RDD[Double] = MapPartitionsRDD[104] at map at DataFrame.scala:848

scala> val correlation = Statistics.corr(numMentions, numArticles, "pearson")

Notes: You can also query filoDB tables using Spark thrift server. Refer to SQL/Hive Example for additional information regarding thrift server.

FiloDB logs can be viewed in corresponding spark application logs by setting appropriate settings in log4j.properties, or logback.xml for DSE.

Using the CLI

The filo-cli accepts arguments as key-value pairs. The following keys are supported:

key purpose
dataset It is required for all the operations. Its value should be the name of the dataset
database Specifies the "database" the dataset should operate in. For Cassandra, this is the keyspace. If not specified, uses config value.
limit This is optional key to be used with select. Its value should be the number of rows required.
columns This is required for defining the schema of a dataset. Its value should be a comma-separated string of the format, column1:typeOfColumn1,column2:typeOfColumn2 where column1 and column2 are the names of the columns and typeOfColumn1 and typeOfColumn2 are one of int,long,double,string,bool
rowKeys This is required for defining the row keys. Its value should be a comma-separated list of column names to make up the row key
partitionKeys Comma-separated list of column names or computed columns to make up the partition key
command Its value can be either of init, create, importcsv, analyze, delete, truncate or list.

The init command is used to create the FiloDB schema.

The create command is used to define new a dataset. For example,
./filo-cli --command create --dataset playlist --columns id:int,album:string,artist:string,title:string --rowKeys id --segmentKey ':string /0'
Note: The sort column is not optional.

The list command can be used to view the schema of a dataset. For example,
./filo-cli --command list --dataset playlist

The importcsv command can be used to load data from a CSV file into a dataset. For example,
./filo-cli --command importcsv --dataset playlist --filename playlist.csv
Note: The CSV file should be delimited with comma and have a header row. The column names must match those specified when creating the schema for that dataset.
The delete command is used to delete datasets, like a drop.
truncate truncates data for an existing dataset to 0.
select Its value should be a comma-separated string of the columns to be selected,
./filo-cli --dataset playlist --select album,title
The result from select is printed in the console by default. An output file can be specified with the key --outfile. For example,
./filo-cli --dataset playlist --select album,title --outfile playlist.csv
delimiter This is optional key to be used with importcsv command. Its value should be the field delimiter character. Default value is comma.
numPartitions The maximum number of partitions to analyze for the analyze command. Prevents analyze of large tables from taking too long. Defaults to 1000.
timeoutSeconds The number of seconds for timeout for initialization, table creation, other quick things

Running the CLI

You may want to customize a configuration to point at your Cassandra cluster, or change other configuration parameters. The easiest is to pass in a customized config file:

./filo-cli -Dfilodb.config.file=/path/to/myfilo.conf --command init

You may also set the FILO_CONFIG_FILE environment var instead, but any -Dfilodb.config.file args passed in takes precedence.

Individual configuration params may also be changed by passing them on the command line. They must be the first arguments passed in. For example:

./filo-cli -Dfilodb.columnstore.segment-cache-size=10000 --command ingestcsv ....

All -D config options must be passed before any other arguments.

You may also configure CLI logging by copying cli/src/main/resources/logback.xml to your deploy folder, customizing it, and passing on the command line -Dlogback.configurationFile=/path/to/filo-cli-logback.xml.

You can also change the logging directory by setting the FILO_LOG_DIR environment variable before calling the CLI.

NOTE: The CLI currently only operates on the Cassandra column store. The --database option may be used to specify which keyspace to operate on. If the keyspace is not initialized, then FiloDB code will automatically create one for you, but you may want to create it yourself to control the options that you want.

CLI Example

The following examples use the GDELT public dataset and can be run from the project directory.

Create a dataset with all the columns :

./filo-cli --command create --dataset gdelt --columns GLOBALEVENTID:int,SQLDATE:string,MonthYear:int,Year:int,FractionDate:double,Actor1Code:string,Actor1Name:string,Actor1CountryCode:string,Actor1KnownGroupCode:string,Actor1EthnicCode:string,Actor1Religion1Code:string,Actor1Religion2Code:string,Actor1Type1Code:string,Actor1Type2Code:string,Actor1Type3Code:string,Actor2Code:string,Actor2Name:string,Actor2CountryCode:string,Actor2KnownGroupCode:string,Actor2EthnicCode:string,Actor2Religion1Code:string,Actor2Religion2Code:string,Actor2Type1Code:string,Actor2Type2Code:string,Actor2Type3Code:string,IsRootEvent:int,EventCode:string,EventBaseCode:string,EventRootCode:string,QuadClass:int,GoldsteinScale:double,NumMentions:int,NumSources:int,NumArticles:int,AvgTone:double,Actor1Geo_Type:int,Actor1Geo_FullName:string,Actor1Geo_CountryCode:string,Actor1Geo_ADM1Code:string,Actor1Geo_Lat:double,Actor1Geo_Long:double,Actor1Geo_FeatureID:int,Actor2Geo_Type:int,Actor2Geo_FullName:string,Actor2Geo_CountryCode:string,Actor2Geo_ADM1Code:string,Actor2Geo_Lat:double,Actor2Geo_Long:double,Actor2Geo_FeatureID:int,ActionGeo_Type:int,ActionGeo_FullName:string,ActionGeo_CountryCode:string,ActionGeo_ADM1Code:string,ActionGeo_Lat:double,ActionGeo_Long:double,ActionGeo_FeatureID:int,DATEADDED:string,Actor1Geo_FullLocation:string,Actor2Geo_FullLocation:string,ActionGeo_FullLocation:string --rowKeys GLOBALEVENTID

Verify the dataset metadata:

./filo-cli --command list --dataset gdelt

Import data from a CSV file:

./filo-cli --command importcsv --dataset gdelt --filename GDELT-1979-1984-100000.csv

Query/export some columns:

./filo-cli --dataset gdelt --select MonthYear,Actor2Code --limit 5 --outfile out.csv

Current Status

Version 0.4 is the stable, latest released version. It has been tested on a cluster for a different variety of schemas, has a stable data model and ingestion, and features a huge number of improvements over the previous version.

Upcoming version 0.7 changes:

  • ALL NEW segmentless data model, much simpler to ingest data efficiently without as much guesswork (no need to determine segment key), especially for streaming apps
  • Range scans over one or more row keys, instead of over segment keys
  • Completely revised, more efficient read path
  • NEW storage layout with incremental indices, provides much better ingestion for large partitions and skewed data
  • Spark 2.0 and Scala 2.11 (master branch)
  • Automatic routing of ingestion records across the network - no need to sort your DataFrame in Spark
  • creating a function for checking java and another to check sbt (@jenaiz)

Version 0.4 change list:

  • Defaults to Spark 1.6.1
  • New metrics and monitoring framework based on Kamon.io, with built in stats logging and statsd output, and tracing of write path
  • Replaced Phantom with direct usage of Java C* driver. Bonus: use prepared statements, should result in better performance all around especially on ingest; plus supports C* 3.0+
  • WHERE clauses specifying multiple partition keys now get pushed down. Should result in much better read performance in those cases.
  • New :hash function makes it easier to hash partition key components into smaller cardinality (but specify the full key in WHERE clauses)
  • New config filodb.cassandra.keyspace-replication-options allows any CQL replication option to be set when FiloDB keyspaces are created with CLI --command init
  • A few new configs for Cassandra CQL / chunk / sstable compression; can help improve remote read performance
  • CLI log directory can be easily changed with FILO_LOG_DIR env var
  • CLI analyze command can now analyze segments from multiple partitions up to a configurable maximum # of segments
  • Allow comma-separated list of hosts for filodb.cassandra.hosts
  • Fix missing data on read issue with wrapping token ranges in C*
  • Fix actor path uniqueness issue on ingestion

Deploying

  • sbt spark/assembly
  • sbt cli/assembly
  • Copy core/src/main/resources/application.conf and modify as needed for your own config file
  • Set FILO_CONFIG_FILE to the path to your custom config
  • Run the cli jar as the filo CLI command line tool and initialize keyspaces if using Cassandra: filo-cli-*.jar --command init

Note that if you are using DSE or have vnodes enabled, a lower number of vnodes (16 or less) is STRONGLY recommended as higher numbers of vnodes slows down queries substantially and basically prevents subsecond queries from happening.

If you are using DSE 5.0, you need to shade the hdrhistogram jar when building the FiloDB assembly due to a version conflict.

By default, FiloDB nodes (basically all the Spark executors) talk to each other using a random port and locally assigned hostname. You may wish to set filodb.spark.driver.port, filodb.spark.executor.port to assign specific ports (for AWS, for example) or possibly use a different config file on each host and set akka.remote.netty.tcp.hostname on each host's config file.

Monitoring and Metrics

FiloDB uses Kamon for metrics and Akka/Futures/async tracing. Not only does this give us summary statistics, but this also gives us Zipkin-style tracing of the ingestion write path in production, which can give a much richer picture than just stats.

Metrics Sinks

  • statsd sink - this is packaged into FiloDB's spark module (but not the CLI module) by default. All you need to do is stand up statsd, Statsite, or equivalent daemon. See the Kamon Statsd module guide for configuration.
  • Kamon metrics logger - this is part of the coordinator module and will log all metrics (including segment trace metrics) at every Kamon tick interval, which defaults to 10 seconds. It is disabled by default but could be enabled with --conf spark.filodb.metrics-logger.enabled=true or changing filodb.metrics-logger.enabled in your conf file. Also, which metrics to log including pattern matching on names can be configured.
  • Kamon trace logger - this logs detailed trace information on segment appends and is always on if detailed tracing is on.

Metrics Configuration

Kamon has many configurable options. To get more detailed traces on the write / segment append path, for example, here is how you might pass to spark-submit or spark-shell options to set detailed tracing on and to trace 3% of all segment appends:

--driver-java-options '-XX:+UseG1GC -XX:MaxGCPauseMillis=500 -Dkamon.trace.level-of-detail=simple-trace -Dkamon.trace.random-sampler.chance=3'

To change the metrics flush interval, you can set kamon.metric.tick-interval and kamon.statsd.flush-interval. The statsd flush-interval must be equal to or greater than the tick-interval.

Methods of configuring Kamon (except for the metrics logger):

  • The best way to configure Kamon is to pass this Java property: -Dkamon.config-provider=filodb.coordinator.KamonConfigProvider. This lets you configure Kamon through the same mechanisms as the rest of FiloDB: -Dfilo.config.file for example, and the configuration is automatically passed to each executor/worker. Otherwise:
  • Passing Java options on the command line with -D, or for Spark, --driver-java-options and --executor-java-options
  • Passing options in a config file and using -Dconfig.file. NOTE: -Dfilo.config.file will not work because Kamon uses a different initialization stack. Need to be done for both drivers and executors.

Code Walkthrough

Please go to the architecture doc.

Building and Testing

Run the tests with sbt test, or for continuous development, sbt ~test. Noisy cassandra logs can be seen in filodb-test.log.

To run benchmarks, from within SBT:

cd jmh
jmh:run -i 5 -wi 5 -f3

You can get the huge variety of JMH options by running jmh:run -help. For stack profiling, do this:

jmh:run -i 5 -wi 5 -f3 -prof stack -jvmArgsAppend -Djmh.stack.lines=3

There are also stress tests in the stress module. See the Stress README.

You can help!

Contributions are welcome!

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