POLYGLOT PERSISTENCE AND MULTI-CLOUD DATA MANAGEMENT SOLUTIONS
GENOVEVA VARGAS SOLAR FRENCH COUNCIL OF SCIENTIFIC RESEARCH, LIG-LAFMIA, FRANCE
http://www.vargas-‐solar.com
DATA ALL AROUND
2
30 billion pieces of content are shared on Facebook every month
40 billion+ hours video are watched on YouTube each month
As of 2011 the global size Data in healthcare was estimated to be 150 Exabytes (161 billion of Gigabytes)
40 million Tweets are sent per day about 200 monthly active users
By 2014 it is anticipated there will be 400 million wearable wireless health monitors
Web 2.0 sites where millions of users may both read and write data, scalability for simple database operations has become important
Data collections available through front ends managed through public/private organization, available through the Web, e.g., Sloan Sky Server
STORING AND ACCESSING HUGE AMOUNTS OF DATA
Peta 1015
Exa 1018
Zetta 1021
Yota 1024
RAID
Disk
Cloud
3
• Data formats • Data collection sizes
• Data storage supports • Data delivery mechanisms
4
THIS TALK IS NOT ABOUT
5
http://nosql-‐database.org
Debate on whether NoSQL stores and relational systems are better or worse … that is not the point
Of course we can surf on these waves at the end of the talk and during EDBT School!
THIS TALK IS ABOUT
6
alternative for managing multiform and multimedia data collections according to different properties and requirements
AGENDA
¡ Dealing with multiform and multimedia data collections:
it’s all about management requirements
¡ Polyglot persistence general principle
¡ The NoSQL plethora
¡ Polyglot database
¡ Design
¡ Deployment
¡ Querying, update and maintenance
¡ Conclusions and outlook
7
8
POLYGLOT PERSISTENCE
¡ Polyglot Programming: applications should be written in a mix of languages to take advantage of different languages are suitable for tackling different problems
¡ Polyglot persistence: any decent sized enterprise will have a variety of different data storage technologies for different kinds of data
¡ a new strategic enterprise application should no longer be built assuming a relational persistence support
¡ the relational option might be the right one - but you should seriously look at other alternatives
9
M. Fowler and P. Sadalage. NoSQL Distilled: A Brief Guide to the Emerging World of Polyglot Persistence. Pearson Education, Limited, 2012
(Katsov-2012)
Use the right tool for the right job…
How do I know which is the right tool for the right job?
10
SCALING DATABASE SYSTEMS
¡ A system is scalable if increasing its resources (CPU, memory, disk) results in increased performance proportionally to the added resources
¡ Improving performance means serving more units of work for handling larger units of work like when data sets grow
¡ Database systems have been scaled by buying bigger faster and more expensive machines
11
¡ Vertically (SCALE UP) ¡ Add resources (CPU, memory) to a single node in a system
¡ Horizontally (SCALE OUT) ¡ Add more nodes to a system
NOSQL STORES CHARACTERISTICS
¡ Simple operations ¡ Key lookups reads and writes of one record or a small number of records
¡ No complex queries or joins
¡ Ability to dynamically add new attributes to data records
¡ Horizontal scalability ¡ Distribute data and operations over many servers
¡ Replicate and distribute data over many servers
¡ No shared memory or disk
¡ High performance ¡ Efficient use of distributed indexes and RAM for data storage
¡ Weak consistency model
¡ Limited transactions
12
Next generation databases mostly addressing some of the points: being non-relational, distributed, open-source and horizontally scalable [http://nosql-‐database.org]
DEALING WITH HUGE AMOUNTS OF DATA
13
Peta 1015
Exa 1018
Zetta 1021
Yota 1024
RAID
Disk
Cloud
Concurrency
Consistency
Atomicity
Relational
Graph
Key value
Columns
DATA MANAGEMENT SYSTEMS ARCHITECTURES
Physical model
Logic model
External model
ANSI/SPARC
Storage Manager
Schema Manager
Query Engine
Transaction Manager
DBMS
Customisable points
Custom components
Glue code
Data services
Access services
Storage services
Additional Extension services
Other services
Extension services Streaming, XML, procedures, queries, replication
Physical model
Logic model
External model
Physical model
Logic model External model
14
15
Data stores designed to scale simple OLTP-‐style applica7on loads
• Data model • Consistency • Storage • Durability
• Availability • Query support
Read/Write operations by thousands/millions of users
PROBLEM STATEMENT: HOW MUCH TO GIVE UP?
¡ CAP theorem1: a system can have two of the three properties
¡ NoSQL systems sacrifice consistency
16
Consistency Availability
Fault-‐tolerant partitioning
1 Eric Brewer, "Towards robust distributed systems." PODC. 2000 http://www.cs.berkeley.edu/~brewer/cs262b-‐2004/PODC-‐keynote.pdf
NOSQL STORES: AVAILABILITY AND PERFORMANCE
¡ Replication
¡ Copy data across multiple servers (each bit of data can be found in multiple servers)
¡ Increase data availability
¡ Faster query evaluation
¡ Sharding
¡ Distribute different data across multiple servers
¡ Each server acts as the single source of a data subset
¡ Orthogonal techniques
17
REPLICATION: PROS & CONS
¡ Data is more available
¡ Failure of a site containing E does not result in unavailability of E if replicas exist
¡ Performance
¡ Parallelism: queries processed in parallel on several nodes
¡ Reduce data transfer for local data
¡ Increased updates cost
¡ Synchronisation: each replica must be updated
¡ Increased complexity of concurrency control
¡ Concurrent updates to distinct replicas may lead to inconsistent data unless special concurrency control mechanisms are implemented
18
SHARDING: WHY IS IT USEFUL?
¡ Scaling applications by reducing data sets in any single databases
¡ Segregating data
¡ Sharing application data
¡ Securing sensitive data by isolating it
¡ Improve read and write performance ¡ Smaller amount of data in each user group implies faster querying
¡ Isolating data into smaller shards accessed data is more likely to stay on cache
¡ More write bandwidth: writing can be done in parallel
¡ Smaller data sets are easier to backup, restore and manage
¡ Massively work done ¡ Parallel work: scale out across more nodes
¡ Parallel backend: handling higher user loads
¡ Share nothing: very few bottlenecks
¡ Decrease resilience improve availability ¡ If a box goes down others still operate
¡ But: Part of the data missing
19
Load%balancer%
Cache%1%
Cache%2%
Cache%3%
MySQL%Master%
MySQL%Master%
Web%1%
Web%2%
Web%3%
Site%database%
Resume%database%
SHARDING AND REPLICATION
¡ Sharding with no replication: unique copy, distributed data sets
¡ (+) Better concurrency levels (shards are accessed independently)
¡ (-) Cost of checking constraints, rebuilding aggregates
¡ Ensure that queries and updates are distributed across shards
¡ Replication of shards
¡ (+) Query performance (availability)
¡ (-) Cost of updating, of checking constraints, complexity of concurrency control
¡ Partial replication (most of the times)
¡ Only some shards are duplicated
20
NOSQL STORES: DATA MANAGEMENT PROPERTIES
¡ Indexing
¡ Distributed hashing like Memcached open source cache
¡ In-memory indexes are scalable when distributing and replicating objects over multiple nodes
¡ Partitioned tables
¡ High availability and scalability: eventual consistency
¡ Data fetched are not guaranteed to be up-to-date
¡ Updates are guaranteed to be propagated to all nodes eventually
¡ Shared nothing horizontal scaling
¡ Replicating and partitioning data over many servers
¡ Support large number of simple read/write operations per second (OLTP)
¡ No ACID guarantees
¡ Updates eventually propagated but limited guarantees on reads consistency
¡ BASE: basically available; soft state, eventually consistent
¡ Multi-version concurrency control
21
COMPARING NOSQL & NEWSQL SYSTEMS
SYSTEM CONCURRENCY CONTROL
DATA STORAGE
REPLICATION TRANSACTION
Redis Locks RAM Asynchronous No
Scalaris Locks RAM Synchronous Local
Tokyo Locks RAM/Disk Asynchronous Local
Voldemort MVCC RAM/BDB Asynchronous No
Riak MVCC Plug in Asynchronous No
Membrain Locks Flash+Disk Synchronous Local
Membase Locks Disk Synchronous Local
Dynamo MVCC Plug in Asynchronous No
SimpleDB Non S3 Asynchronous No
MongoDB Locks Disk Asynchronous No
CouchDB MVCC Disk Asynchronous No
22
SYSTEM CONCURRENCY CONTROL
DATA STORAGE
REPLICATION TRANSACTION
Terrastore Locks RAM+ Synchronous L
Hbase Locks HADOOP Asynchronous L
HyperTable Locks Files Synchronous L
Cassandra MVCC Disk Asynchronous L
BigTable Locs+stamps GFS Both L
PNuts MVCC Disk Asynchronous L
MySQL-C ACID Disk Synchronous Y
VoltDB ACID/no Lock RAM Synchronous Y
Clustrix ACID/no Lock Disk Synchronous Y
ScaleDB ACID Disk Synchronous Y
ScaleBase ACID Disk Asynchronous Y
NimbusDB ACID/no Lock Disk Synchronous Y
Key-‐Value
Document
Extended records
Relational
Cattell, Rick. "Scalable SQL and NoSQL data stores." ACM SIGMOD Record 39.4 (2011): 12-‐27
AGENDA
ü Dealing with multiform and multimedia data collections:
ü it’s all about management requirements
ü Polyglot persistence general principle
ü The NoSQL plethora
¡ Polyglot database
¡ Design
¡ Deployment
¡ Querying, update and maintenance
¡ Conclusions and outlook
23
DESIGNING AND BUILDING A POLYGLOT DATABASE
24
25
OBJECTIVE
¡ Build a MyNet app based on a polyglot database for building an integrated directory of my contacts including their status and posts from several social networks
MyNet DB MyNet App Social network
26
Analysis on contacts networks, overlapping according to interests, posts topics Top 10 most popular contacts
User sessions in different Social networks
Integrating posts from all networks
Contact graph traversal For building groups out of Common characteristics
Synchronizing posts to all SN Friends network
User accounts activity In different social networks
Directory synchronisation Integrating contacts’ information From all SN
NOSQL DESIGN AND CONSTRUCTION PROCESS
¡ Data reside in RAM (memcached) and is eventually replicated and stored
¡ Querying = designing a database according to the type of queries / map reduce model
¡ “On demand” data management: the database is virtually organized per view (external schema) on cache and some view are made persistent
¡ An elastic easy to evolve and explicitly configurable architecture 27
Database querying
Database population
Database organization
INDEX Memcached
Replicated Stored
GENERATING NOSQL PROGRAMS FROM HIGH LEVEL ABSTRACTIONS
28
UML class diagram application classes
Spring Roo
Java web App Spring Data
Graph database Relational database
High-level abstractions
Low-level abstractions
http://code.google.com/p/model2roo/
DEPLOYING A POLYGLOT DATABASE
29
DEPLOYING A DATABASE APPLICATION ON THE CLOUD
Have a first experience on
¡ creating a database on a relational DBMS deployed on the cloud,
¡ building a simple database application exported as a service,
¡ deploying the service on the cloud and implement an interface. 30
MyNet DB
MyNet App
Contact'
idContact:"Integer"firstName:"String"lastName:"String"
Service
App
SHARDING AND DEPLOYING SHARDS ON THE CLOUD
Have a first experience on
¡ sharding a relational DBMS
¡ dealing with shards synchronization
¡ deploying the service on the cloud and implement an interface 31
MyNet DB
MyNet Service
webSite:(URI(socialNetworkID:(URI(((
Basic(Info(Contact'
idContact:(Integer(lastName:(String(givenName:(String(society:(String( <<'hasBasicInfo'>>'
1' *'
postID:(Integer(timeStamp:(Date(geoStamp:(String(
Post'
contentID:(Integer(text:(String(
Content'
<<'hasContent'>>'
<<publishesPost>>'*'
1'
1' 1'
street:(String,((number:(Integer,(City:(Sting,((Zipcode:(Integer(
Address'
*'
email:(String(type:({pers,(prof}(
Email'
<<'hasAddress'>>'
*'
1' <<'hasEmail'>>'
ID:(Integer,(Lang:(String(
Language'*'
<<'speaksLanguage'>>'
Français
Español
English
Others
REST
JSON documents
MyNet
MULTI-CLOUD POLYGLOT DATABASE
MyNetContacts
webSite:(URI(socialNetworkID:(URI(((
Basic(Info(Contact'
idContact:(Integer(lastName:(String(givenName:(String(society:(String(
<<'hasBasicInfo'>>'
<<'isContactof'>>'
groupName:(String(
Group'
<<'isComposedof'>>'
1' *'
1'
*'1'
*'
postID:(Integer(timeStamp:(Date(geoStamp:(String(
Post'
contentID:(Integer(text:(String(image:(Jpeg(video:(Avi(
Content'
<<'hasContent'>>'
<<'publishesPost'>>'*'
1'
1' 1'
street:(String,((number:(Integer,(City:(Sting,((Zipcode:(Integer(
Address'
1'
*'
number:(String(type:({pers,(prof}(
Phone'
email:(String(type:({pers,(prof}(
Email'<<'hasAddress'
>>'
<<'hasOtherPhones'
>>'
1'
*'
1'
*'
*'
<<'hasMobilePhones
'>>'
1'
<<'hasEmail'>>'
webSite:(URI(socialNetworkID:(URI(((
Basic(Info(Contact'
idContact:(Integer(lastName:(String(givenName:(String(society:(String(
<<'hasBasicInfo'>>'
<<'isContactof'>>'
groupName:(String(
Group'
<<'isComposedof'>>'
1' *'
1'
*'1'
*'
postID:(Integer(timeStamp:(Date(geoStamp:(String(
Post'
contentID:(Integer(text:(String(image:(Jpeg(video:(Avi(
Content'
<<'hasContent'>>'
<<'publishesPost'>>'*'
1'
1' 1'
street:(String,((number:(Integer,(City:(Sting,((Zipcode:(Integer(
Address'
1'
*'
number:(String(type:({pers,(prof}(
Phone'
email:(String(type:({pers,(prof}(
Email'<<'hasAddress'>>'
<<'hasOtherPhones'>>'
1'
*'
1'
*'
*'
<<'hasMobilePhones'>>'
1'
<<'hasEmail'>>'
webSite:(URI(socialNetworkID:(URI(((
Basic(Info(Contact'
idContact:(Integer(lastName:(String(givenName:(String(society:(String(
<<'hasBasicInfo'>>'
<<'isContactof'>>'
groupName:(String(
Group'
<<'isComposedof'>>'
1' *'
1'
*'1'
*'
postID:(Integer(timeStamp:(Date(geoStamp:(String(
Post'
contentID:(Integer(text:(String(image:(Jpeg(video:(Avi(
Content'
<<'hasContent'>>'
<<'publishesPost'>>'*'
1'
1' 1'
street:(String,((number:(Integer,(City:(Sting,((Zipcode:(Integer(
Address'
1'
*'
number:(String(type:({pers,(prof}(
Phone'
email:(String(type:({pers,(prof}(
Email'<<'hasAddress'>>'
<<'hasOtherPhones'>>'
1'
*'
1'
*'
*'
<<'hasMobilePhones'>>'
1'
<<'hasEmail'>>'
MANAGING A POLYGLOT DATABASE QUERYING, INSERTING, MAINTAINING
33
CRUD OPERATIONS
34
Contact
Group
Content
Post
Id FirstName LastName Society
Consistent view of data
EXAMPLE 1: SYNCHRONIZING REDIS+MYSQL
35
https://oracleus.activeevents.com/connect/sessionDetail.ww?SESSION_ID=4775
Updating REDIS #FAIL
begin MySQL transaction update MySQL update Redis
rollback MySQL transaction
begin MySQL transaction update MySQL
commit MySQL transaction << system crashes >> update Redis
Redis has updated MySQL does not
MySQL has updated Redis does not
EXAMPLE 1: UPDATING REDIS RELIABLY
Step I Step 2
36
begin MySQL transaction update MySQL queue CRUD event in MySQL
commit transaction
Event Id Operation: Create, Update, Delete queue CRUD event in MySQL
New entity state, e.g. JSON
ACID for each CRUD event in MySQL queue
get next CRUD event from MySQL queue if CRUD event is not duplicate then
update Redis (incl. eventID) end if
begin MySQL transaction
mark CRUD event processed commit transaction
end for each
EXAMPLE 1: UPDATING REDIS RELIABLY
37
EntityCRUDEvent Repository
EntityCRUDEvent Processor Redis updater
ID JSON Processed?
INSERT INTO .. SELECT … FROM..
apply(event)
Timer Step 1 Step 2
EXAMPLE 1: TRACKING CHANGES (HIBERNATE)
38
POLYGLOT DATABASE EVOLUTION
¡ Problem statement: ¡ Evolution of the application: modification of classes, new
classes, new relationships among classes
¡ Evolution of the “entities” managed in the polyglot database
¡ Some change structure, change values, …
¡ The content of the stores start deriving from the application data structures
¡ Which is the current structure of the entities stored?
¡ Are there elements that are not being accessed because they do not longer correspond to the application data structures?
39
Contact'
idContact:"Integer"firstName:"String"lastName:"String"
webSite:(URI(socialNetworkID:(URI(((
Basic(Info(Contact'
idContact:(Integer(lastName:(String(givenName:(String(society:(String( <<'hasBasicInfo'>>'
1' *'
postID:(Integer(timeStamp:(Date(geoStamp:(String(
Post'
contentID:(Integer(text:(String(
Content'
<<'hasContent'>>'
<<publishesPost>>'*'
1'
1' 1'
street:(String,((number:(Integer,(City:(Sting,((Zipcode:(Integer(
Address'
*'
email:(String(type:({pers,(prof}(
Email'
<<'h
asAddres
s'>>'
*'
1' <<'hasEmail'>>'
ID:(Integer,(Lang:(String(
Language'*'
<<'speaksLanguage'>>'
EXTRACTING SCHEMATA FROM NOSQL PROGRAMS CODE
http://code.google.com/p/exschema/ 40
Metalayer(
Struct( Relationship(
Attribute(Set(
*( *(
*(*(
*( *(
*(*(*(
*(
*(
*(
*(
*(
Declarations analyzer
Updates analyzer
Repositories analyzer
Schema1 Schema2 Schema3
Set
Attribute implementation : Spring Repository Set
Attribute name : fr.imag.twitter.domain.UserInfo Struct
Attribute name : userId
Attribute name : firstName
Attribute name : lastName
Set
Attribute implementation : Spring Repository Set
Attribute name : fr.imag.twitter.domain.Tweet Struct
Attribute name : text
Attribute name : userId
Set
Attribute implementation : Neo4j Struct
Attribute name : fr.imag.twitter.domain.User Struct
Attribute name : nodeId
Attribute name : userName
Attribute name : userId
Attribute name : password
Relationship
start end
Attribute name : followers
Schema1 Schema2 Schema3
Set
Attribute implementation : Spring Repository Set
Attribute name : fr.imag.twitter.domain.UserInfo Struct
Attribute name : userId
Attribute name : firstName
Attribute name : lastName
Set
Attribute implementation : Spring Repository Set
Attribute name : fr.imag.twitter.domain.Tweet Struct
Attribute name : text
Attribute name : userId
Set
Attribute implementation : Neo4j Struct
Attribute name : fr.imag.twitter.domain.User Struct
Attribute name : nodeId
Attribute name : userName
Attribute name : userId
Attribute name : password
Relationship
start end
Attribute name : followers
Schema1 Schema2 Schema3
Set
Attribute implementation : Spring Repository Set
Attribute name : fr.imag.twitter.domain.UserInfo Struct
Attribute name : userId
Attribute name : firstName
Attribute name : lastName
Set
Attribute implementation : Spring Repository Set
Attribute name : fr.imag.twitter.domain.Tweet Struct
Attribute name : text
Attribute name : userId
Set
Attribute implementation : Neo4j Struct
Attribute name : fr.imag.twitter.domain.User Struct
Attribute name : nodeId
Attribute name : userName
Attribute name : userId
Attribute name : password
Relationship
start end
Attribute name : followers
Spring Data
EXTRACTING SCHEMATA FROM A POLYGLOT DATABASE
41
Application source code
Metalayer(
Struct( Relationship(
Attribute(Set(
*( *(
*(*(
*( *(
*(*(*(
*(
*(
*(
*(
*(
Declarations Analyzer
Updates Analyzer
Annotations Analyzer
Repositories Analyzer
ExSchema
Variables/Methods Graph Store
Annotations/Variables Relational & document stores
AGENDA
ü Dealing with multiform and multimedia data collections:
ü it’s all about management requirements
ü Polyglot persistence general principle
ü The NoSQL plethora
ü Polyglot database
ü Design
ü Deployment
ü Querying, update and maintenance
¡ Conclusions and outlook
42
CHALLENGE: POLYGLOT MEETS XPERANTO
Given a data collection coming from different social networks stored on NoSQL systems (Neo4J and Mongo) [possibly according to a strategy combining sharding and replication techniques], extend the UnQL pivot query language considering
¡ Data processing operators adapted to query different data models (graph, document). Example query Neo + Mongo and what about Join, Union …
¡ Assuming concurrent CRUD operations to the stores can you expect query results to be consistent ? How can you tag your results or implement a sharding strategy in order to determine whether results are consistent?
¡ Querying data represented on different models: How can you exploit the structure of the different stores for expressing queries ? Provide adapted operators? Give generic operators and then rewrite queries?
¡ Normally, Polyglot solutions tend to solve some data processing issues in the application code. This can be penalizing. Discuss the challenges to address for ensuring that your queries will be able to scale as the collection grows.
43
CHALLENGE: EXPECTED RESULTS
¡ Give the principle of your proposal through a partial programming solution, of the operators of your UnQL extension, detail the query evaluation process if U want your solution to scale
¡ We ask U to sketch the solution on the polyglot database that we provide consisting of mongo, Neo4J stores
¡ https://github.com/jccastrejon/edbt-unql
¡ Technical requirements: VMware player 5
44
WHEN IS POLYGLOT PERSISTENCE PERTINENT?
¡ Application essentially composing and serving web pages
¡ They only looked up page elements by ID, they had different needs or availability, concurrency and no need to share all their data
¡ A problem like this is much better suited to a NoSQL store than the corporate relational DBMS
¡ Scaling to lots of traffic gets harder and harder to do with vertical scaling
¡ Many NoSQL databases are designed to operate over clusters
¡ They can tackle larger volumes of traffic and data than is realistic with a single server
45
CONCLUSIONS
¡ Data are growing big and more heterogeneous and they need new adapted ways to be managed thus the NoSQL movement is gaining momentum
¡ Data heterogeneity implies different management requirements this is where polyglot persistence comes up
¡ Consistency – Availability – Fault tolerance theorem: find the balance !
¡ Which data store according to its data model?
¡ A lot of programming implied …
46
Open opportunities if you’re interested in this topic!
Contact: Genoveva Vargas-Solar, CNRS, LIG-LAFMIA [email protected] http://www.vargas-‐solar.com/teaching/
http://code.google.com/p/exschema/
47 http://code.google.com/p/model2roo/
Open source polyglot persistence tools
Prof. Dr. Christine Collet Grenoble INP France
Juan Carlos Castrejón University of Grenoble France
Javier Espinosa University of Grenoble France
Dr. Genoveva Vargas-‐Solar CNRS, LIG-‐LAFMIA France
REFERENCES
¡ Eric A., Brewer "Towards robust distributed systems." PODC. 2000
¡ Rick, Cattell "Scalable SQL and NoSQL data stores." ACM SIGMOD Record 39.4 (2011): 12-‐27
¡ Juan Castrejon, Genoveva Vargas-‐Solar, Christine Collet, and Rafael Lozano, ExSchema: Discovering and Maintaining Schemas from Polyglot Persistence Applications, In Proceedings of the International Conference on Software Maintenance, Demo Paper, IEEE, 2013
¡ M. Fowler and P. Sadalage. NoSQL Distilled: A Brief Guide to the Emerging World of Polyglot Persistence. Pearson Education, Limited, 2012
¡ C. Richardson, Developing polyglot persistence applications, http://fr.slideshare.net/chris.e.richardson/developing-‐polyglotpersistenceapplications-‐gluecon2013
49
NOSQL PLETHORA
50
DATA MODELS
¡ Tuple
¡ Row in a relational table, where attributes are pre-defined in a schema, and the values are scalar
¡ Document
¡ Allows values to be nested documents or lists, as well as scalar values.
¡ Attributes are not defined in a global schema
¡ Extensible record
¡ Hybrid between tuple and document, where families of attributes are defined in a schema, but new attributes can be added on a per-record basis
51
DATA STORES
¡ Key-value ¡ Systems that store values and an index to find them, based on a key
¡ Document ¡ Systems that store documents, providing index and simple query mechanisms
¡ Extensible record ¡ Systems that store extensible records that can be partitioned vertically and horizontally across nodes
¡ Graph ¡ Systems that store model data as graphs where nodes can represent content modelled as document or key-value structures and arcs
represent a relation between the data modelled by the node
¡ Relational ¡ Systems that store, index and query tuples
52
KEY-VALUE STORES
¡ “Simplest data stores” use a data model similar to the memcached distributed in-memory cache
¡ Single key-value index for all data
¡ Provide a persistence mechanism
¡ Replication, versioning, locking, transactions, sorting
¡ API: inserts, deletes, index lookups
¡ No secondary indices or keys
53
SYSTEM ADDRESS
Redis code.google.com/p/redis
Scalaris code.google.com/p/scalaris
Tokyo tokyocabinet.sourceforge.net
Voldemort project-‐voldemort.com
Riak riak.basho.com
Membrain schoonerinfotech.com/products
Membase membase.com
SELECT name FROM group WHERE gid IN ( SELECT gid FROM group_member WHERE uid = me() )
54
SELECT name, pic, profile_url FROM user WHERE uid = me()
SELECT name, pic FROM user WHERE online_presence = "active" AND uid IN ( SELECT uid2 FROM friend WHERE uid1 = me() )
SELECT name FROM friendlist WHERE owner = me()
SELECT message, attachment FROM stream WHERE source_id = me() AND type = 80
https://developers.facebook.com/docs/reference/fql/
55
<805114856,
>
DOCUMENT STORES
¡ Support more complex data: pointerless objects, i.e., documents
¡ Secondary indexes, multiple types of documents (objects) per database, nested documents and lists, e.g. B-trees
¡ Automatic sharding (scale writes), no explicit locks, weaker concurrency (eventual for scaling reads) and atomicity properties
¡ API: select, delete, getAttributes, putAttributes on documents
¡ Queries can be distributed in parallel over multiple nodes using a map-reduce mechanism
56
SYSTEM ADDRESS
SimpleDB amazon.com/simpledb
Couch DB couchdb.apache.org
Mongo DB mongodb.org
Terrastore code.google.com/terrastore
57
DOCUMENT STORES
EXTENSIBLE RECORD STORES
¡ Basic data model is rows and columns
¡ Basic scalability model is splitting rows and columns over multiple nodes ¡ Rows split across nodes through sharding on the primary key
¡ Split by range rather than hash function
¡ Rows analogous to documents: variable number of attributes, attribute names must be unique
¡ Grouped into collections (tables)
¡ Queries on ranges of values do not go to every node
¡ Columns are distributed over multiple nodes using “column groups” ¡ Which columns are best stored together
¡ Column groups must be pre-defined with the extensible record stores
58
SYSTEM ADDRESS
HBase hbase.apache.com
HyperTable hypertable.org
Cassandra incubator.apache.org/cassandra
SCALABLE RELATIONAL SYSTEMS
¡ SQL: rich declarative query language
¡ Databases reinforce referential integrity
¡ ACID semantics
¡ Well understood operations: ¡ Configuration, Care and feeding, Backups, Tuning, Failure and recovery,
Performance characteristics
¡ Use small-scope operations ¡ Challenge: joins that do not scale with sharding
¡ Use small-scope transactions ¡ ACID transactions inefficient with communication and 2PC overhead
¡ Shared nothing architecture for scalability
¡ Avoid cross-node operations
59
SYSTEM ADDRESS
MySQL C mysql.com/cluster
Volt DB voltdb.com
Clustrix clustrix.com
ScaleDB scaledb.com
Scale Base scalebase.com
Nimbus DB nimbusdb.com
NOSQL STORES: AVAILABILITY AND PERFORMANCE
60
REPLICATION MASTER - SLAVE
¡ Makes one node the authoritative copy/replica that handles writes while replica synchronize with the master and may handle reeds
¡ All replicas have the same weight ¡ Replicas can all accept writes
¡ The lose of one of them does not prevent access to the data store
¡ Helps with read scalability but does not help with write scalability
¡ Read resilience: should the master fail, slaves can still handle read requests
¡ Master failure eliminates the ability to handle writes until either the master is restored or a new master is appointed
¡ Biggest complication is consistency ¡ Possible write – write conflict
¡ Attempt to update the same record at the same time from to different places
¡ Master is a bottle-neck and a point of failure
61
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Master'
Slaves'
all'updates'made'to'the'master'
changes'propagate''To'slaves'
reads'can'be'done'from'master'or'slaves'
MASTER-SLAVE REPLICATION MANAGEMENT
¡ Masters can be appointed ¡ Manually when configuring the nodes cluster
¡ Automatically: when configuring a nodes cluster one of them elected as master. The master can appoint a new master when the master fails reducing downtime
¡ Read resilience
¡ Read and write paths have to be managed separately to handle failure in the write path and still reads can occur
¡ Reads and writes are put in different database connections if the database library accepts it
¡ Replication comes inevitably with a dark side: inconsistency ¡ Different clients reading different slaves will see different values if changes have not been propagated to all slaves
¡ In the worst case a client cannot read a write it just made
¡ Even if master-slave is used for hot backups, if the master fails any updates on to the backup are lost
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REPLICATION: PEER-TO-PEER
¡ Allows writes to any node; the nodes coordinate to synchronize their copies
¡ The replicas have equal weight
¡ Deals with inconsistencies
¡ Replicas coordinate to avoid conflict
¡ Network traffic cost for coordinating writes
¡ Unnecessary to make all replicas agree to write, only the majority
¡ Survival to the loss of the minority of replicas nodes
¡ Policy to merge inconsistent writes
¡ Full performance on writing to any replica
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Master'
nodes'communicate'their'writes'
all'nodes'read'and'write'all'data'
SHARDING
¡ Ability to distribute both data and load of simple operations over many servers, with no RAM or disk shared among servers
¡ A way to horizontally scale writes ¡ Improve read performance
¡ Application/data store support
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¡ Puts different data on separate nodes
¡ Each user only talks to one servicer so she gets rapid responses
¡ The load should be balanced out nicely between servers
¡ Ensure that
¡ data that is accessed together is clumped together on the same node
¡ that clumps are arranged on the nodes to provide best data access
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SHARDING
Database laws
¡ Small databases are fast
¡ Big databases are slow
¡ Keep databases small
Principle
¡ Start with a big monolithic database
¡ Break into smaller databases
¡ Across many clusters
¡ Using a key value
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Instead of having one million customers information on a single big machine ….
100 000 customers on smaller and different machines
SHARDING CRITERIA
¡ Partitioning
¡ Relational: handled by the DBMS (homogeneous DBMS)
¡ NoSQL: based on ranging of the k-value
¡ Federation
¡ Relational
¡ Combine tables stored in different physical databases
¡ Easier with denormalized data
¡ NoSQL:
¡ Store together data that are accessed together
¡ Aggregates unit of distribution
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SHARDING
Architecture
¡ Each application server (AS) is running DBS/client
¡ Each shard server is running
¡ a database server
¡ replication agents and query agents for supporting parallel query functionality
Process
¡ Pick a dimension that helps sharding easily (customers, countries, addresses)
¡ Pick strategies that will last a long time as repartition/re-sharding of data is operationally difficult
¡ This is done according to two different principles ¡ Partitioning: a partition is a structure that divides a space
into tow parts
¡ Federation: a set of things that together compose a centralized unit but each individually maintains some aspect of autonomy
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Customers data is partitioned by ID in shards using an algorithm d to determine which shard a customer ID belongs to
REPLICATION: ASPECTS TO CONSIDER
¡ Conditioning
¡ Important elements to consider
¡ Data to duplicate
¡ Copies location
¡ Duplication model (master – slave / P2P)
¡ Consistency model (global – copies)
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Fault tolerance
Availability Transparency levels
Performance
à Find a compromise !
PARTITIONING A PARTITION IS A STRUCTURE THAT DIVIDES A SPACE INTO TOW PARTS
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BACKGROUND: DISTRIBUTED RELATIONAL DATABASES
¡ External schemas (views) are often subsets of relations (contacts in Europe and America)
¡ Access defined on subsets of relations: 80% of the queries issued in a region have to do with contacts of that region
¡ Relations partition ¡ Better concurrency level
¡ Fragments accessed independently
¡ Implications ¡ Check integrity constraints
¡ Rebuild relations
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FRAGMENTATION
¡ Horizontal
¡ Groups of tuples of the same relation
¡ Budget < 300 000 or >= 150 000
¡ Not disjoint are more difficult to manage
¡ Vertical
¡ Groups attributes of the same relation
¡ Separate budget from loc and pname of the relation project
¡ Hybrid
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FRAGMENTATION: RULES
Vertical
¡ Clustering
¡ Grouping elementary fragments
¡ Budget and location information in two relations
¡ Splitting
¡ Decomposing a relation according to affinity relationships among attributes
Horizontal
¡ Tuples of the same fragment must be statistically homogeneous ¡ If t1 and t2 are tuples of the same fragment then t1 and t2 have
the same probability of being selected by a query
¡ Keep important conditions ¡ Complete
¡ Every tuple (attribute) belongs to a fragment (without information loss)
¡ If tuples where budget >= 150 000 are more likely to be selected then it is a good candidate
¡ Minimum
¡ If no application distinguishes between budget >= 150 000 and budget < 150 000 then these conditions are unnecessary
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SHARDING: HORIZONTAL PARTITIONING
¡ The entities of a database are split into two or more sets (by row)
¡ In relational: same schema several physical bases/servers ¡ Partition contacts in Europe and America shards where
they zip code indicates where the will be found
¡ Efficient if there exists some robust and implicit way to identify in which partition to find a particular entity
¡ Last resort shard ¡ Needs to find a sharding function: modulo, round robin,
hash – partition, range - partition
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Load%balancer%
Cache%1%
Cache%2%
Cache%3%
MySQL%Master%
MySQL%Master%
Web%1%
Web%2%
Web%3%
Even%IDs%
Odd%IDs%MySQL%Slave%1% MySQL%
Slave%2%
MySQL%Slave%n%
MySQL%Slave%1% MySQL%
Slave%2%
MySQL%Slave%n%
FEDERATION A FEDERATION IS A SET OF THINGS THAT TOGETHER COMPOSE A CENTRALIZED UNIT BUT EACH INDIVIDUALLY MAINTAINS SOME ASPECT OF AUTONOMY
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FEDERATION: VERTICAL SHARDING
¡ Principle
¡ Partition data according to their logical affiliation
¡ Put together data that are commonly accessed
¡ The search load for the large partitioned entity can be split across multiple servers (logical and physical) and not only according to multiple indexes in the same logical server
¡ Different schemas, systems, and physical bases/servers
¡ Shards the components of a site and not only data
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Load%balancer%
Cache%1%
Cache%2%
Cache%3%
MySQL%Master%
MySQL%Master%
Web%1%
Web%2%
Web%3%
Site%database%
Resume%database%MySQL%Slave%1% MySQL%
Slave%2%
MySQL%Slave%n%
MySQL%Slave%1%
Internal%user%
NOSQL STORES: PERSISTENCY MANAGEMENT
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«MEMCACHED»
¡ «memcached» is a memory management protocol based on a cache: ¡ Uses the key-value notion ¡ Information is completly stored in RAM
¡ «memcached» protocol for: ¡ Creating, retrieving, updating, and deleting information from the database ¡ Applications with their own «memcached» manager (Google, Facebook,
YouTube, FarmVille, Twitter, Wikipedia)
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STORAGE ON DISC (1)
¡ For efficiency reasons, information is stored using the RAM:
¡ Work information is in RAM in order to answer to low latency requests
¡ Yet, this is not always possible and desirable
Ø The process of moving data from RAM to disc is called "eviction”; this process is configured automatically for every bucket
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STORAGE ON DISC (2)
¡ NoSQL servers support the storage of key-value pairs on disc:
¡ Persistency–can be executed by loading data, closing and reinitializing it without having to load data from another source
¡ Hot backups– loaded data are sotred on disc so that it can be reinitialized in case of failures
¡ Storage on disc– the disc is used when the quantity of data is higher thant the physical size of the RAM, frequently used information is maintained in RAM and the rest es stored on disc
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STORAGE ON DISC (3)
¡ Strategies for ensuring:
¡ Each node maintains in RAM information on the key-value pairs it stores. Keys:
¡ may not be found, or
¡ they can be stored in memory or on disc
¡ The process of moving information from RAM to disc is asynchronous:
¡ The server can continue processing new requests
¡ A queue manages requests to disc
Ø In periods with a lot of writing requests, clients can be notified that the server is termporaly out of memory until information is evicted
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NOSQL STORES: CONCURRENCY CONTROL
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MULTI VERSION CONCURRENCY CONTROL (MVCC)
¡ Objective: Provide concurrent access to the database and in programming languages to implement transactional memory
¡ Problem: If someone is reading from a database at the same time as someone else is writing to it, the reader could see a half-written or inconsistent piece of data.
¡ Lock: readers wait until the writer is done
¡ MVCC: ¡ Each user connected to the database sees a snapshot of the database at a particular instant in time
¡ Any changes made by a writer will not be seen by other users until the changes have been completed (until the transaction has been committed
¡ When an MVCC database needs to update an item of data it marks the old data as obsolete and adds the newer version elsewhere à multiple versions stored, but only one is the latest
¡ Writes can be isolated by virtue of the old versions being maintained
¡ Requires (generally) the system to periodically sweep through and delete the old, obsolete data objects
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