Lambda has a much-discussed feature: cold starts. It’s the “price” sometimes paid for the on-demand model from subchapter 14.1. In this subchapter, you’ll understand what they are, why they happen, and what you can do to reduce their impact.
What is a cold start
Remember how Lambda works: your code is not always running, but AWS starts it up when an event arrives. Well, that startup has two scenarios:
-
Cold start: it’s the first time the function is invoked (or after a while without use). AWS has to prepare the environment from scratch: reserve resources, load your code, initialize the runtime (Python, Java...), load libraries. This adds an extra delay, usually a few hundred milliseconds to a couple of seconds.
-
Warm start: if the function was used recently, AWS reuses the environment that was already prepared. Here there’s no preparation delay: the function responds instantly.
First invocation (cold): [prepare environment]──[load code and libraries]──[execute] └──── extra delay (cold start) ────┘ Subsequent invocations (warm): [execute] ← environment already ready, no delay
Analogy: a cold start is like starting a car on a winter morning: the cold engine takes a bit to get going. Once it’s running (warm), you start and accelerate instantly. If you leave it parked for a while, it cools down again.
Why it matters (and when it doesn’t)
The impact of cold starts depends on the type of application:
- It matters in interactive applications where the user expects a quick response (an API responding to a mobile app). A 1-2 second delay on the first request can be noticeable.
- It doesn’t matter for background or asynchronous tasks (processing an uploaded file, draining a queue). If the task takes a few extra seconds to start, nobody is affected.
It also depends on the language: lightweight runtimes like Python or Node.js have short cold starts; heavier runtimes like Java or .NET start up more slowly (though there are techniques to improve this).
Strategies to reduce cold starts
- Provisioned Concurrency
This is the most direct solution: you tell AWS to keep a number of environments always warm and ready, waiting for requests. Thus, those invocations never suffer a cold start.
Provisioned Concurrency = 5 → AWS keeps 5 environments always warm → the first 5 simultaneous requests respond instantly
It’s like having several cars with the engine already running in the parking lot, ready to go. The trade-off: you pay to keep them warm (even if unused), so it’s used when first-request latency is critical.
- Keep the function “warm” with periodic invocations
A simple technique: schedule an invocation every few minutes (with CloudWatch, see subchapter 14.2) so the environment doesn’t cool down. It’s a cheap trick, though less reliable than provisioned concurrency, especially if there are many simultaneous requests.
- Reduce package size
The less code and libraries AWS has to load, the faster the startup. So it’s advisable to:
- Include only the libraries you actually use (see subchapter 14.3).
- Use layers to avoid inflating the package.
- Avoid unnecessary heavy dependencies.
- Choose a lightweight runtime
If cold start is critical and you can choose the language, Python or Node.js usually start up faster than Java or .NET. (For Java there are specific optimizations, but by default it’s heavier.)
- Properly initialize code
What you put outside the handler (connections, configuration) runs only once per environment and is reused in warm starts. Using this well avoids repeating costly work on every invocation:
import boto3
# This runs ONCE when preparing the environment (reused when warm)
client = boto3.client("dynamodb")
def handler(event, context):
# This runs on EVERY invocation
return client.get_item(...)Summary table
| Strategy | What it does | Trade-off |
|---|---|---|
| Provisioned Concurrency | Keeps environments always warm | You pay to keep them, even if unused |
| Periodic invocations | “Wakes up” the function every X minutes | Cheap trick, less reliable |
| Reduce package size | Less code/libraries to load | Requires discipline with dependencies |
| Lightweight runtime | Python/Node start up faster | Depends on your language choice |
| Initialize outside handler | Reuses connections between invocations | Good practice, no cost |
Should I obsess over this?
Not at first. For most applications, occasional cold starts are perfectly manageable, and runtimes like Python or Node make them very bearable. Worry about them only if you have an interactive application sensitive to latency and you measure that cold starts bother users. Then apply provisioned concurrency and the other strategies. Remember: optimizing before you have a measured problem is usually wasted time.
What you should remember
- A cold start is the extra delay the first time a Lambda is invoked (or after a while without use), because AWS prepares the environment from scratch. In warm starts that environment is reused and there’s no delay.
- It matters in interactive applications sensitive to latency; it doesn’t matter in background tasks. Lightweight runtimes (Python, Node) start up faster.
- Strategies: Provisioned Concurrency (environments always warm), periodic invocations, reduce package size, lightweight runtime, and initialize connections outside the handler to reuse them.
- Don’t obsess at first: optimize cold starts only if you measure that they truly affect your users.
In the last subchapter of the chapter, we’ll look at Lambda’s limits and antipatterns: when Lambda is not the right tool.
Cloud, AWS & Terraform — From Zero to Expert
Chapter 1 · What is cloud computing
- 1.1 The traditional client-server model
- 1.2 Problems the cloud came to solve
- 1.3 On-premise vs cloud vs hybrid
- 1.4 The three service models: IaaS, PaaS, SaaS
- 1.5 The five pillars of cloud (according to NIST)
- 1.6 Real advantages: elasticity, pay-as-you-go, global availability
Chapter 2 · The cloud market and major providers
- 2.1 AWS, Azure and GCP: differences and market share
- 2.2 Why learn AWS first
- 2.3 Concepts that are universal among providers
Chapter 3 · Regions, availability zones and edge
- 3.1 What is an AWS region and how to choose it
- 3.2 Availability Zones: high availability by design
- 3.3 Edge locations and CloudFront
- 3.4 Latency, resilience and data sovereignty
Chapter 4 · Compute: EC2
- 4.1 Instances: types, families and when to choose each
- 4.2 AMIs, key pairs and Security Groups
- 4.3 Instance lifecycle
- 4.4 Elastic IPs and Placement Groups
- 4.5 Savings Plans vs Reserved vs On-Demand vs Spot
Chapter 5 · Storage: S3
- 5.1 Buckets, objects and keys
- 5.2 Storage classes (Standard, IA, Glacier…)
- 5.3 Versioning and object lifecycle
- 5.4 Bucket policies and ACLs
- 5.5 Static website hosting
Chapter 6 · Networking: VPC
- 6.1 What is a VPC and why you need it
- 6.2 Public and private subnets
- 6.3 Internet Gateway and NAT Gateway
- 6.4 Route Tables and Network ACLs
- 6.5 VPC Peering and endpoints
Chapter 7 · Identity and access: IAM
- 7.1 Users, groups, roles and policies
- 7.2 The principle of least privilege
- 7.3 Identity-based vs resource-based policies
- 7.4 MFA and temporary credentials (STS)
- 7.5 IAM security best practices
Chapter 8 · Managed databases
- 8.1 RDS: engines, Multi-AZ and read replicas
- 8.2 Aurora and its advantages over vanilla RDS
- 8.3 DynamoDB: key-value / document model
- 8.4 ElastiCache for in-memory cache
- 8.5 When to use each type of database
Chapter 9 · Why Infrastructure as Code
- 9.1 Problems with manual provisioning
- 9.2 Declarative vs imperative IaC
- 9.3 Terraform vs CloudFormation vs Pulumi vs CDK
- 9.4 The plan → apply → destroy cycle
Chapter 10 · HCL: the Terraform language
- 10.1 Resource, variable, output, locals blocks
- 10.2 Data types: string, number, bool, list, map, object
- 10.3 Expressions, references and built-in functions
- 10.4 Conditionals and loops (count, for_each, for)
Chapter 11 · Providers and state
- 11.1 How the AWS provider works
- 11.2 The terraform.tfstate file and its importance
- 11.3 Local state vs remote state (S3 + DynamoDB)
- 11.4 Essential commands: init, plan, apply, destroy, fmt, validate
Chapter 12 · Your first real infrastructure in Terraform
- 12.1 Create a VPC with subnets from scratch
- 12.2 Launch a public EC2 instance
- 12.3 Associate a Security Group and an Elastic IP
- 12.4 Outputs and references between resources
- 12.5 Team workflow: PR review of plans
Chapter 13 · Load balancing and auto scaling
- 13.1 Application Load Balancer vs Network Load Balancer
- 13.2 Target Groups, listeners and rules
- 13.3 Auto Scaling Groups: policies and metrics
- 13.4 Warm pools and lifecycle hooks
Chapter 14 · Serverless with Lambda
- 14.1 The Lambda execution model
- 14.2 Triggers: API Gateway, S3, DynamoDB Streams, SQS
- 14.3 Dependency management and layers
- 14.4 Cold starts and strategies to reduce them
- 14.5 Limits and anti-patterns
Chapter 15 · Messaging and events
- 15.1 SQS: standard vs FIFO queues, DLQ
- 15.2 SNS: topics, subscriptions, fan-out
- 15.3 EventBridge: event buses and rules
- 15.4 Patterns: pub/sub, decoupling, saga
Chapter 16 · Content delivery and DNS
- 16.1 Route 53: record types and routing policies
- 16.2 CloudFront: distributions, caches and origins
- 16.3 ACM: free SSL/TLS certificates
- 16.4 WAF integrated with CloudFront
Chapter 17 · Containers on AWS
- 17.1 Docker: quick review of key concepts
- 17.2 ECR: private image registry
- 17.3 ECS: task definitions, services, Fargate vs EC2
- 17.4 EKS: when Kubernetes and when not
Chapter 18 · Modules: reuse and composition
- 18.1 Anatomy of a Terraform module
- 18.2 Input variables, outputs and dependencies
- 18.3 Local modules vs Terraform Registry modules
- 18.4 Module versioning with Git tags
- 18.5 Design of generic vs domain-specific modules
Chapter 19 · Workspaces and environment management
- 19.1 Terraform workspaces: use cases and limitations
- 19.2 Directory strategy per environment (dev/stg/prod)
- 19.3 Terragrunt: DRY for environment configurations
- 19.4 Environment variables and .tfvars files
Chapter 20 · Remote backends and locking
- 20.1 Configure S3 + DynamoDB as backend
- 20.2 State locking: avoiding team corruption
- 20.3 State migration between backends
- 20.4 terraform import: bring existing resources into state
Chapter 21 · Infrastructure testing
- 21.1 Terraform validate and fmt in CI
- 21.2 Checkov and tfsec: static security analysis
- 21.3 Terratest: integration tests in Go
- 21.4 Contract testing between modules
Chapter 22 · Terraform in CI/CD
- 22.1 Basic pipeline: lint → plan → apply in GitHub Actions
- 22.2 Atlantis: GitOps for Terraform
- 22.3 Terraform Cloud / HCP Terraform
- 22.4 Drift detection and automatic reconciliation
Chapter 23 · Defense in depth
- 23.1 AWS Organizations and Service Control Policies
- 23.2 AWS Config: continuous compliance
- 23.3 GuardDuty: threat detection
- 23.4 Security Hub: centralized view
- 23.5 KMS: key management and rotation
- 23.6 Secrets Manager vs Parameter Store
Chapter 24 · Observability: logs, metrics and traces
- 24.1 CloudWatch Logs, metrics and alarms
- 24.2 CloudWatch Dashboards and Contributor Insights
- 24.3 X-Ray: distributed tracing
- 24.4 OpenTelemetry on AWS
- 24.5 Managed Grafana and Managed Prometheus
Chapter 25 · Cost optimization
- 25.1 AWS Cost Explorer and budgets with alerts
- 25.2 Trusted Advisor and Compute Optimizer
- 25.3 Rightsizing: how to detect overprovisioning
- 25.4 Savings Plans vs Reserved Instances: strategic decision
- 25.5 FinOps: culture and processes to control spending
Chapter 26 · High availability and disaster recovery
- 26.1 RTO and RPO: defining objectives
- 26.2 Strategies: backup/restore, pilot light, warm standby, multi-site
- 26.3 Route 53 health checks and automatic failover
- 26.4 AWS Backup: centralized backup policy
Chapter 27 · AWS Well-Architected Framework
- 27.1 The six pillars: operational excellence, security, reliability, performance efficiency, cost optimization, sustainability
- 27.2 Well-Architected Tool: formal reviews
- 27.3 How to apply the framework in design decisions
Chapter 28 · Serverless architectures at scale
- 28.1 Event-driven architecture with Lambda + EventBridge
- 28.2 Saga pattern for distributed transactions
- 28.3 Step Functions: orchestration of complex workflows
- 28.4 Lambda@Edge and CloudFront Functions
Chapter 29 · Data platforms on AWS
- 29.1 Data Lake with S3, Glue and Athena
- 29.2 Kinesis Data Streams and Firehose for streaming
- 29.3 Redshift: data warehousing at scale
- 29.4 Lake Formation: data governance
Chapter 30 · Multi-account and landing zones
- 30.1 Why separate workloads into different accounts
- 30.2 AWS Control Tower and Account Factory
- 30.3 Centralized log and security management
- 30.4 Terraform at multi-account scale with shared modules
Chapter 31 · Platform Engineering and Internal Developer Platform
- 31.1 Golden paths and abstractions over Terraform
- 31.2 AWS Service Catalog
- 31.3 Backstage as a developer portal
- 31.4 Terraform modules as internal product
Chapter 32 · Relevant AWS certifications
- 32.1 Cloud Practitioner: is it worth it?
- 32.2 Solutions Architect Associate → Professional
- 32.3 DevOps Engineer Professional
- 32.4 Specialty: Security, Database, Networking
- 32.5 HashiCorp Terraform Associate
Chapter 33 · Projects to consolidate what you've learned
- 33.1 Project 1: serverless blog (S3 + CloudFront + Lambda + DynamoDB)
- 33.2 Project 2: REST API with ECS Fargate + RDS + ALB
- 33.3 Project 3: data platform with Glue + Athena + Redshift
- 33.4 Project 4: multi-account landing zone with Terraform and Control Tower