Presentation is loading. Please wait.

Presentation is loading. Please wait.

Jimmy Narang 1. A service in the cloud has to: Be able to handle arbitrary node failures Be available all the time Be able to scale up or down on demand.

Similar presentations


Presentation on theme: "Jimmy Narang 1. A service in the cloud has to: Be able to handle arbitrary node failures Be available all the time Be able to scale up or down on demand."— Presentation transcript:

1 Jimmy Narang 1

2 A service in the cloud has to: Be able to handle arbitrary node failures Be available all the time Be able to scale up or down on demand without the need to re-write the code Handle platform or software upgrades 2

3 The service design must be: Loosely coupled Such that node failures do not affect functionality Nodes can be initialized and added easily State of the service is decoupled from nodes Scale can be achieved through quantity (scale out) 3

4 Cloud: thousands of connected servers Azure: an operating system for the cloud Abstracts away hardware – switches, servers, disks, routers, load- balancers Manages deployment, so that developer can upload code and hit ‘run’ Provides reliable common storage that can be accessed from any mode Provides a familiar development platform 4

5 A service boundary Roles Each role has a number of identical instances Two types of roles: web roles and worker role Storage Accessible from any instance Blobs, tables, queues Endpoints External: communicate outside the service boundary Internal: communicate within the service boundary 5

6 Web Role Cloud Storage LB n role instances Worker Role Web Role Worker Role Web Role Worker Role 6 External endpoint Service Boundary Internal endpoints External endpoint m role instances

7 Developers write their code and describe a service model Service model includes role definitions, VM Size, instance counts, endpoints, etc. code + service model is packed and uploaded to Azure, which deploys the service in Microsoft Datacenters 7

8 Two types: web roles and worker roles No Admin access; cannot install applications Choose a particular VM capacity for each role Specify number of instances per role Azure starts a fresh instance if an existing one crashes Code: Extend RoleEntryPoint class for worker roles; optional for web roles. Asp.Net for web roles 8

9 Each service runs in an isolated boundary The service deployment is assigned a Virtual IP address (VIP) The service is reachable externally via ‘external endpoints’ on this VIP External endpoints: ports selected to be exposed to the outside world for in-coming connections to the service Usually http and https on web roles (i.e., port no. 80 and 81) Can be TCP endpoints on worker roles Both web and worker roles can make outbound connections to Internet resources via HTTP or HTTPS and via Microsoft.NET APIs for TCP/IP sockets. 9

10 Azure provides APIs to obtain internal IPs of each instance in each role Roles can define ‘internal endpoints’ (ports exposed within the service) to communicate between instances 10

11 Accessed from anywhere using account name and storage key Exposed in the form of URIs: http://.queue.core.windows.net/ http://.blob.core.windows.net/ / http://.table.core.windows.net/ 11

12 Queues: often the best way to communicate between roles Messages can be 8kb max use messages as pointers to blobs/tables for larger data Can create several queues per account Not guaranteed Fifo; no priority queues either. Guaranteed each message will be seen at least once 12

13 Create / Delete queue Get / Put message Peek message (queueName, n) Delete message (queueName, msgId, popreceipt) ‘get message’ does not lead to deletion! Clear Queue 13

14 MessageID: A GUID associated with each msg VisibilityTimeOut: default 30 seconds, max: 2 hours. Messages not deleted within this interval will return to the queue PopReceipt: A string retrieved with every get-msg. PopReceipt+MsgID required to delete a msg MessageTTl: (7 days) messages not deleted within this interval are garbage collected 14

15 2 2 1 1 C1C1 C1C1 C2C2 C2C2 1 1 2 2 3 3 Producers Consumers P P 3 3 1 1 2 2 C1: GetMsg (returns 1) C2: GetMsg (returns 2) C2: DeleteMsg #2 C1 dies C2: GetMsg (returns 3) Visibility Timeout on Msg#1 C2: DeleteMsg #3 C2: GetMsg (returns 1) 15

16 A large chunk of (raw binary) data Blob Operations: Create / Delete Read / Write: byte range (page blob) or blocks (block blob) Lease the blob Create a Snapshot Create a copy Mount as Drive (page blob) 16

17 Hierarchy: accounts, containers, blobs http://.blob.core.windows.net/ / An account can contain multiple containers A container can contain blobs or other containers Fine grained access control can be granted to containers/blobs (grant permissions for individual operations such as read, write, delete, list, take snapshot etc.) 17

18 A blob as a sequential list of blocks Each block has an ID Blocks are immutable Upload blocks out of order / in parallel PutBlock to upload block PutBlockList to stitch uploaded blocks into blob Order of upload doesn’t matter; order in Putblocklist matters. Putblocklist: First commit wins (all uncommitted blocks are garbage collected) 18

19 Block Id 1Block Id 3Block Id 2 Block Id 4 Block Id 2Block Id 3 Block Id 4 PutBlob (name); PutBlock(BlockId1); PutBlock(BlockId3); PutBlock(BlockId4); PutBlock(BlockId2); PutBlock(BlockId4); PutBlockList(BlockId2, BlockId3, BlockId4); 19

20 Page blobs: A collection of pages Specify blob size at creation time. Entire range initialized to 0 at creation Read/Write specific byte ranges, no ‘commit’ required (unlike block blobs) 512 Byte alignment required for write operations; not required for read 20

21 A lease is a timed (1 min) lock on a block Acquire lease: create a lease for a blob without one Renew: request to hold the existing lease Release Break: to end the lease but ensure that another instance cannot acquire it until the current lease has expired 21

22 Can scale up to billions of entries and terabytes of data Contain set of ‘entities’ (rows) with ‘properties’ (columns) (Partition Key, Row Key) defines the primary key Partition key is used to partition the table into storage nodes Row key uniquely identifies an entity within a partition 22

23 No Fixed schema, except for Partition Key, Row Key, and Timestamp Properties are stored as Two entities can have very different properties Common data types – int, string, guid, timestamp etc. – supported. Limits on the size of an entity (1MB), and # of properties(255, including keys & timestamp) 23

24 Queries: always return whole entities, no projections Only ‘From’, ‘Take’ (max 1000), ‘where’ operators supported – no select, sort, group-by, join, etc. Normal Boolean and comparison operators supported. For good performance, ‘where’ should have the partition key Insert / Delete Update: Replaces the original entity Merge: modifies properties in place 24

25 ACID guaranteed for transactions involving a single entity. Group Transactions have restrictions, such as: Only possible for entities in the same partition Entity needs to be identified by primary key Max 100 operations per ‘batch’ Snapshot isolation: there will be no dirty reads Application needs to ensure cross-table consistency 25

26 A partition (i.e. all entities with the same partition key) are served by the same ‘node’ ‘node’ here should not be thought of as a single server, but a single ‘place’. Entity locality: Entities within the same partition are stored together Tradeoffs in choosing the partition key: large partitions: efficient group queries small partitions: spread across more nodes => greater scalability 26

27 Updating an entity is a multi-step process: Get the entity from the server Update it locally, and submit to server Entity can get changed in that time Use E-tags (“version numbers”) stored in the header associated with each entity Update only if version number matches with the one you were expecting Or use If-Match * to unconditionally update 27

28 Use for debugging, performance monitoring, traffic analysis etc. Based on logging: no remote desktop access to instances Choose the required Log sources: Azure, IIS logs, Windows event logs, Perf counters, Crash dumps (and others) Then dump the logs locally or store them in Azure storage (at scheduled intervals or on-demand) 28

29 X Drive Mount a page blob as a VHD (per instance) SQL Azure Complete relational SQL storage in the cloud Azure appliance A container of pre-configured hardware with Azure installed Content Delivery Network Mark public blobs to be copied to edge locations across a region 29

30 30


Download ppt "Jimmy Narang 1. A service in the cloud has to: Be able to handle arbitrary node failures Be available all the time Be able to scale up or down on demand."

Similar presentations


Ads by Google