Why the fuzz about serverless (with CompassDigital)

Transcript

1. Why the fuzz about serverless?

2. 1. What is serverless and why you should care 2.

   Who’s using serverless? 3. Serverless- fi rst, not serverless-only 4. Patterns & Anti-Patterns 5. The case for GraphQL & AppSync 6. Q&A

3. Yan Cui http://theburningmonk.com @theburningmonk AWS user since 2010

4. Yan Cui http://theburningmonk.com @theburningmonk running serverless in production since 2016

5. Yan Cui http://theburningmonk.com @theburningmonk independent consultant

6. “What is serverless?”

7. None

8. Gojko Adzic It is serverless the same way WiFi is

   wireless. http://bit.ly/2yQgwwb

9. Serverless means… don’t need to worry about scaling don’t need

   to provision and manage servers

10. Serverless means… don’t need to worry about scaling don’t need

    to provision and manage servers don’t pay for it if no-one uses it

11. Lambda

12. Lambda S3 DynamoDB

13. Lambda S3 API Gateway DynamoDB AppSync

14. Lambda S3 API Gateway DynamoDB AppSync Cognito

15. Lambda S3 SQS SNS API Gateway DynamoDB AppSync EventBridge Cognito

16. Lambda S3 SQS SNS Step Functions API Gateway DynamoDB AppSync

    EventBridge Cognito

17. Lambda S3 SQS SNS Step Functions API Gateway DynamoDB AppSync

    Kinesis EventBridge Cognito

18. Lambda S3 SQS SNS Step Functions API Gateway DynamoDB AppSync

    Kinesis EventBridge Cognito You can build pretty much everything with serverless.

19. SCALABLE

20. https://www.vladionescu.me/posts/scaling-containers-on-aws-in-2022 Lambda

21. https://www.vladionescu.me/posts/scaling-containers-on-aws-in-2022 Lambda OUT-DATED!

22. None

23. Every function can scale by 1,000 concurrent executions every 10

    seconds, independently of each other.

24. RESILIENT

25. DynamoDB replicates data to 3 AZs

26. S3 has 99.999999999% (11 9s) durability

27. None

28. Lambda, API Gateway, AppSync, etc. all provide built-in multi-AZ redundancy

    out-of-the-box

29. Lambda Workers (microVMs) don’t share memory

30. Lambda Workers (microVMs) process one invocation request at a time

31. Lambda Failures are isolated, no more system crash!

32. Lambda Workers are garbage collected every x hours

33. Lambda No more memory leaks and memory fragmentation issues

34. SECURE

35. Lambda Your code Your dependencies The OS EC2 instance Networking

    Physical infrastructure
36. None

37. COST-EFFICIENT

38. User Tra ff i c Cost Serverless Cost per transaction

    is highly predictable Cost tracks usage closely

39. WASTE User Tra ff i c Cost Serverless Serverful Cost

    can be predictable, but you overpay Cost per transaction is highly predictable Cost tracks usage closely

40. aws.amazon.com/solutions/case-studies/finra-data-validation

41. “FinDev”

42. $0.0000035 $0.0000004083 $0.00000125 cost per transaction: $0.0000051583 Lambda API Gateway

    DynamoDB

43. Donald Knuth We should forget about small ef fi ciencies,

    say about 97% of the time: premature optimization is the root of all evil.

44. input output engineering time lower operational cost

45. None

46. cost of the conversation: ~$50 per dev per hour x

    8 = $400 potential saving: $10/month

47. cost of the conversation: ~$50 per dev per hour x

    8 = $400 potential saving: $10/month break-even time for conversation: $400 ÷ $10/month = 40 months!!!

48. Donald Knuth We should forget about small ef fi ciencies,

    say about 97% of the time: premature optimization is the root of all evil. Yet we should not pass up our opportunities in that critical 3%.
49. None

50. this is pretty $$$ input output engineering time lower operational

    cost

51. Knowing the cost of individual functions lets us optimise the

    right parts of our application
52. None
53. None
54. None
55. None

56. “I just want to get from A to B I

    don’t care how ”

57. Ownership Fuel Navigate To get there! Focus on getting there!

    uber

58. HW Ownership OS Runtime & Scale Code Physical Servers

59. HW Ownership OS Runtime & Scale Code Physical Servers Virtual

    Machines

60. HW Ownership OS Runtime & Scale Code Physical Servers Virtual

    Machines Containers

61. HW Ownership OS Runtime & Scale Code Focus on getting

    there! Physical Servers Virtual Machines Containers Serverless

62. leverage: do more with less

63. https://bit.ly/2Im61VK “Unless you’re an infrastructure company, infrastructure is basically overhead.”

    Matt Klein

64. bit.ly/social-network-in-4-weeks

65. leverage: do more with less

66. “Is serverless right for { insert industry }?”

67. None

68. Streaming live sporting events 2 million+ concurrent users at peak

69. Streaming live sporting events 2 million+ concurrent users at peak

    Mix of containers and serverless Serverless for APIs, event processing, etc.

70. www.youtube.com/watch?v=C0pA5eZkmFk

71. aws.amazon.com/solutions/case-studies/bustle

72. twitter.com/ben11kehoe/status/1187027628152115200

73. https://www.infoq.com/news/2021/01/bbc-serverless-scale

74. Workloads transcend industry boundaries

75. “Serverless-First”

76. Start with serverless Move to container when it makes more

    sense
77. None

78. “Amazon has abandoned serverless!”

79. “Amazon has abandoned serverless!” It’s one service, by one team,

    within one business area…

80. Evolution Architecture "an approach to building software that's designed to

    evolve over time as business priorities change, customer demands shift, and new technologies emerge."

81. serverless Fast time-to-market

82. serverless Fast time-to-market Gains traction

83. Gains traction serverless Fast time-to-market Optimize for efficiency

84. services that charge by uptime are order of magnitude cheaper

    when running at scale

85. container Optimize for efficiency Gains traction serverless Fast time-to-market

86. None

87. “We can solve any problem by introducing an extra level

    of indirection.” Fundamental Theorem of Software Engineering

88. Anti-Patterns Patterns &

89. None
90. None
91. None
92. None

93. Synchronous Lambda-to-Lambda are almost always a sign of bad design.

94. None

95. Service Boundary

96. Service Boundary

97. Service Boundary

98. AWS Lambda function !== lambda function in programming

99. ?

100. ? ?

101. None
102. None
103. None

104. Service Boundary Service Boundary

105. Service Boundary Service Boundary

106. Implementation detail Service Boundary Service Boundary

107. Not a stable interface Service Boundary Service Boundary Implementation detail

108. None

109. container Optimize for efficiency Gains traction serverless Fast time-to-market

110. container Optimize for efficiency Gains traction serverless Fast time-to-market Caller

     shouldn’t have to rewrite their app when you change an implementation detail

111. Service Boundary Service Boundary

112. Service Boundary Service Boundary

113. Service Boundary Service Boundary

114. “Use Lambda functions to transform data, NOT transport data.”

115. None

116. Basic CRUD operation No business logic

117. None
118. None

119. “But why you go functionless?”

120. No Lambda = no cold starts

121. No Lambda = no Lambda-related costs

122. EventBridge Pipes

123. EventBridge Pipes

124. 3rd party API EventBridge Pipes

125. 3rd party API EventBridge Pipes Transform

126. OpenSearch

127. No-Code ETL OpenSearch

128. AppSync EventBridge OpenSearch

129. Step Functions EventBridge OpenSearch

130. Consider the ROI on every moving part in your architecture

131. None
132. None

133. ?

134. ?

135. None

136. Function URL

137. Function URL Lambdalith

138. “Lambdalith”

139. Lambdalith: run web app (e.g. express.js) inside Lambda

140. https://github.com/awslabs/aws-lambda-web-adapter

141. https://github.com/CodeGenieApp/serverless-express

142. https://bref.sh

143. https://github.com/zappa/Zappa

144. “Is it a good idea?”

145. If you’re not using API Gateway features (e.g. Cognito authoriser,

     request models, direct integration)

146. or, if you’re facing API Gateway limits (e.g. 29s timeout,

     no response streaming)

147. No API Gateway = no API Gateway costs

148. No API Gateway = no API Gateway latency overhead

149. Lambdalith Pros & Cons

150. Lambdalith Pros & Cons Familiar web framework

151. Lambdalith Pros & Cons Familiar web framework Testing is easier

152. Lambdalith Pros & Cons Familiar web framework Testing is easier

     No per-endpoint metric & alert

153. Lambdalith Pros & Cons Familiar web framework Testing is easier

     No per-endpoint metric & alert Less fine-grained access control

154. Lambdalith Pros & Cons Familiar web framework Testing is easier

     No per-endpoint metric & alert Less fine-grained access control Limited auth support

155. Lambdalith Pros & Cons Familiar web framework Testing is easier

     No per-endpoint metric & alert Less fine-grained access control Limited auth support Large frameworks affect performance

156. Lambdalith Pros & Cons Familiar web framework Testing is easier

     No per-endpoint metric & alert Less fine-grained access control Limited auth support Large frameworks affect performance Custom app metric with EMF

157. Lambdalith Pros & Cons Familiar web framework Testing is easier

     No per-endpoint metric & alert Less fine-grained access control Limited auth support Large frameworks affect performance Custom app metric with EMF In-function authentication
158. None

159. Lambdalith Pros & Cons Familiar web framework Testing is easier

     No per-endpoint metric & alert Less fine-grained access control No per-endpoint auth Large frameworks affect performance Custom app metric with EMF In-function authentication YOU pay for unauthorised requests

160. Knowing the cost of individual functions lets us optimise the

     right parts of our application

161. Lambdalith Pros & Cons Familiar web framework Testing is easier

     No per-endpoint metric & alert Less fine-grained access control No per-endpoint auth Large frameworks affect performance Harder to tune performance & cost

162. “Is it a good idea?”

163. Consider the trade-offs before you go Lambdalith

164. Caching

165. Caching is a cheat code

166. Route53 CloudFront API Gateway Lambda DynamoDB

167. Route53 CloudFront API Gateway Lambda DynamoDB client-side caching

168. Route53 CloudFront API Gateway Lambda DynamoDB client-side caching edge caching

169. Route53 CloudFront API Gateway Lambda DynamoDB client-side caching edge caching

     application-level caching

170. Route53 CloudFront API Gateway Lambda DynamoDB client-side caching edge caching

     application-level caching ElastiCache

171. Route53 CloudFront API Gateway Lambda DynamoDB client-side caching edge caching

     application-level caching Momento

172. bit.ly/social-network-in-4-weeks

173. average 99% cache hit rate

174. None

175. Lambda DynamoDB AppSync

176. A Query Language for your APIs + runtime for fulfilling

     queries with your data

177. schema

178. schema server AppSync

179. Client Server

180. Client Server Validates the request

181. schema { query: Query mutation: Mutation }

182. schema { query: Query mutation: Mutation } type Query {

     getProfile(id: ID!): Profile }

183. schema { query: Query mutation: Mutation } type Query {

     getProfile(id: ID!): Profile } ! = required ID is a built-in type

184. Profile is a type schema { query: Query mutation: Mutation

     } type Query { getProfile(id: ID!): Profile }

185. schema { query: Query mutation: Mutation } type Query {

     getProfile(id: ID!): Profile } type Profile { id: ID! firstName: String! lastName: String! }

186. schema { query: Query mutation: Mutation } type Query {

     getProfile(id: ID!): Profile @aws_lambda } type Profile { id: ID! firstName: String! lastName: String! } type Mutation { createProfile( firstName: String! lastName: String! ): Profile }

187. schema server AppSync

188. schema server data sources DynamoDB RDS ElasticSearch AppSync

189. GET https://myapp.com/user/1234 REST API { “id”: “1234”, “firstName”: “Yan”, “lastName”:

     “Cui”, “dob”: “…”, … }

190. GET https://myapp.com/user/1234 REST API { “id”: “1234”, “firstName”: “Yan”, “lastName”:

     “Cui”, “dob”: “…”, … } Returns data we don’t need

191. GET https://myapp.com/user/1234 REST API { “id”: “1234”, “firstName”: “Yan”, “lastName”:

     “Cui”, “dob”: “…”, … } Returns data we don’t need Overfetching

192. GET https://myapp.com/user/1234 REST API { “id”: “1234”, “firstName”: “Yan”, “lastName”:

     “Cui”, “dob”: “…”, … } Doesn’t have everything we need

193. GET https://myapp.com/sports/football GET https://myapp.com/sports/squash … GET https://myapp.com/user/1234/activities REST API GET

     https://myapp.com/user/1234

194. GET https://myapp.com/sports/football GET https://myapp.com/sports/squash GET https://myapp.com/user/1234/activities REST API GET https://myapp.com/user/1234

     …

195. n+1 requests GET https://myapp.com/sports/football GET https://myapp.com/sports/squash GET https://myapp.com/user/1234/activities REST API

     GET https://myapp.com/user/1234 Underfetching …

196. GraphQL API POST https://myapp.com/graphql { getProfile (id: “1234”) { firstName

     lastName } }

197. GraphQL API POST https://myapp.com/graphql { getProfile (id: “1234”) { firstName

     lastName } } { “firstName”: “Yan”, “lastName”: “Cui” }

198. GraphQL API POST https://myapp.com/graphql { getProfile (id: “1234”) { friends

     { firstName lastName } } } { “friends”: [{ “firstName”: “Gerard”, “lastName”: “Sans” }, { “firstName”: “Ant”, “lastName”: “Stanley” }] }

199. GraphQL solves overfetching and underfetching

200. Strongly typed contract between client and server

201. Strongly typed contract between client and server Built-in request &

     response validation

202. Strongly typed contract between client and server Built-in request &

     response validation Mitigates data exfiltration risks

203. Implement “joins” with DynamoDB effortlessly

204. None

205. AppSync

206. AppSync Pro fi le

207. AppSync Pro fi le

208. Pro fi le

209. Pro fi le Sport

210. Pro fi le Sport

211. AppSync Pro fi le Sport

212. AppSync Pro fi le Sport

213. Activity

214. Activity

215. AppSync Pro fi le Sport Activity

216. Enables rapid product iterations on the frontend

217. AppSync has built-in caching support

218. aws.amazon.com/appsync/pricing

219. AppSync full request caching

220. AppSync full request caching $context.arguments & $context.identity

221. AppSync full request caching Shared, static data are fetched multiple

     times $context.arguments & $context.identity

222. Full-request caching is kinda meh…

223. AppSync per-resolver caching

224. AppSync per-resolver caching Shared data is fetched once and cached

225. AppSync per-resolver caching Can specify different TTL & cache key

     for each resolver Shared data is fetched once and cached

226. average 99% cache hit rate

227. average p99 latency of < 250ms

228. Caching is a cheat code!

229. AppSync Subscriptions simplifies real-time applications

230. None

231. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! }

232. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost: Post @aws_subscribe(mutations: [“addPost"]) }

233. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost: Post @aws_subscribe(mutations: [“addPost“]) }

234. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost: Post @aws_subscribe(mutations: [“addPost“]) } subscriber publisher subscriber subscriber

235. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost: Post @aws_subscribe(mutations: [“addPost“]) } publisher subscriber subscriber subscriber

236. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost: Post @aws_subscribe(mutations: [“addPost“]) } publisher subscriber subscriber subscriber
237. None

238. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost(author: String, title: String, publishYear: Int, publishMonth: Int) : Post @aws_subscribe(mutations: [“addPost“]) }

239. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost(author: String, title: String, publishYear: Int, publishMonth: Int) : Post @aws_subscribe(mutations: [“addPost“]) } subscriber subscriber subscriber

240. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost(author: String, title: String, publishYear: Int, publishMonth: Int) : Post @aws_subscribe(mutations: [“addPost“]) } subscriber publisher subscriber subscriber

241. type Mutation { addPost(id: ID! author: String! title: String content:

     String url: String): Post! } type Subscription { addedPost(author: String, title: String, publishYear: Int, publishMonth: Int) : Post @aws_subscribe(mutations: [“addPost“]) } subscriber publisher subscriber subscriber

242. AppSync + Lambda + DynamoDB is the most efficient way

     to build data-driven applications

243. Summary

244. Synchronous Lambda-to-Lambda calls

245. 🤔 Synchronous Lambda-to-Lambda calls Lambdalith

246. 🤔 Synchronous Lambda-to-Lambda calls Lambdalith Functionless

247. 🤔 Synchronous Lambda-to-Lambda calls Lambdalith Functionless GraphQL & AppSync

248. 🤔 Synchronous Lambda-to-Lambda calls Lambdalith Functionless GraphQL & AppSync Caching

249. Questions?