Flow Logs for Amazon Virtual Private Cloud enables you to capture information about the IP traffic going to and from network interfaces in your VPC. Flow Logs data can be published to Amazon CloudWatch Logs or Amazon Simple Storage Service (S3).

Since we launched VPC Flow Logs in 2015, you have been using it for variety of use-cases like troubleshooting connectivity issues across your VPCs, intrusion detection, anomaly detection, or archival for compliance purposes. Until today, VPC Flow Logs provided information that included source IP, source port, destination IP, destination port, action (accept, reject) and status. Once enabled, a VPC Flow Log entry looks like the one below.

While this information was sufficient to understand most flows, it required additional computation and lookup to match IP addresses to instance IDs or to guess the directionality of the flow to come to meaningful conclusions.

Today we are announcing the availability of additional meta data to include in your Flow Logs records to better understand network flows. The enriched Flow Logs will allow you to simplify your scripts or remove the need for postprocessing altogether, by reducing the number of computations or lookups required to extract meaningful information from the log data.

When you create a new VPC Flow Log, in addition to existing fields, you can now choose to add the following meta-data:

• vpc-id : the ID of the VPC containing the source Elastic Network Interface (ENI).
• subnet-id : the ID of the subnet containing the source ENI.
• instance-id : the Amazon Elastic Compute Cloud (EC2) instance ID of the instance associated with the source interface. When the ENI is placed by AWS services (for example, AWS PrivateLink, NAT Gateway, Network Load Balancer etc) this field will be “-“
• tcp-flags : the bitmask for TCP Flags observed within the aggregation period. For example, FIN is 0x01 (1), SYN is 0x02 (2), ACK is 0x10 (16), SYN + ACK is 0x12 (18), etc. (the bits are specified in “Control Bits” section of RFC793 “Transmission Control Protocol Specification”).
  This allows to understand who initiated or terminated the connection. TCP uses a three way handshake to establish a connection. The connecting machine sends a SYN packet to the destination, the destination replies with a SYN + ACK and, finally, the connecting machine sends an ACK. In the Flow Logs, the handshake is shown as two lines, with tcp-flags values of 2 (SYN), 18 (SYN + ACK).  ACK is reported only when it is accompanied with SYN (otherwise it would be too much noise for you to filter out).
• type : the type of traffic : IPV4, IPV6 or Elastic Fabric Adapter.
• pkt-srcaddr : the packet-level IP address of the source. You typically use this field in conjunction with srcaddr to distinguish between the IP address of an intermediate layer through which traffic flows, such as a NAT gateway.
• pkt-dstaddr : the packet-level destination IP address, similar to the previous one, but for destination IP addresses.

To create a VPC Flow Log, you can use the AWS Management Console, the AWS Command Line Interface (CLI) or the CreateFlowLogs API and select which additional information and the order you want to consume the fields, for example:

Or using the AWS Command Line Interface (CLI) as below:

$ aws ec2 create-flow-logs --resource-type VPC 
                            --region eu-west-1 
                            --resource-ids vpc-12345678 
                            --traffic-type ALL  
                            --log-destination-type s3 
                            --log-destination arn:aws:s3:::sst-vpc-demo 
                            --log-format '${version} ${vpc-id} ${subnet-id} ${instance-id} ${interface-id} ${account-id} ${type} ${srcaddr} ${dstaddr} ${srcport} ${dstport} ${pkt-srcaddr} ${pkt-dstaddr} ${protocol} ${bytes} ${packets} ${start} ${end} ${action} ${tcp-flags} ${log-status}'

# be sure to replace the bucket name and VPC ID !

{
    "ClientToken": "1A....HoP=",
    "FlowLogIds": [
        "fl-12345678123456789"
    ],
    "Unsuccessful": [] 
}

Enriched VPC Flow Logs are delivered to S3. We will automatically add the required S3 Bucket Policy to authorize VPC Flow Logs to write to your S3 bucket. VPC Flow Logs does not capture real-time log streams for your network interface, it might take several minutes to begin collecting and publishing data to the chosen destinations. Your logs will eventually be available on S3 at s3://<bucket name>/AWSLogs/<account id>/vpcflowlogs/<region>/<year>/<month>/<day>/

An SSH connection from my laptop with IP address 90.90.0.200 to an EC2 instance would appear like this :

3 vpc-exxxxxx2 subnet-8xxxxf3 i-0bfxxxxxxaf eni-08xxxxxxa5 48xxxxxx93 IPv4 172.31.22.145 90.90.0.200 22 62897 172.31.22.145 90.90.0.200 6 5225 24 1566328660 1566328672 ACCEPT 18 OK
3 vpc-exxxxxx2 subnet-8xxxxf3 i-0bfxxxxxxaf eni-08xxxxxxa5 48xxxxxx93 IPv4 90.90.0.200 172.31.22.145 62897 22 90.90.0.200 172.31.22.145 6 4877 29 1566328660 1566328672 ACCEPT 2 OK

172.31.22.145 is the private IP address of the EC2 instance, the one you see when you type ifconfig on the instance.  All flags are “OR”ed during aggregation period. When connection is short, probably both SYN and FIN (3), as well as SYN+ACK and FIN (19) will be set for the same lines.

Once a Flow Log is created, you can not add additional fields or modify the structure of the log to ensure you will not accidently break scripts consuming this data. Any modification will require you to delete and recreate the VPC Flow Logs. There is no additional cost to capture the extra information in the VPC Flow Logs, normal VPC Flow Log pricing applies, remember that Enriched VPC Flow Log records might consume more storage when selecting all fields.  We do recommend to select only the fields relevant to your use-cases.

Enriched VPC Flow Logs is available in all regions where VPC Flow logs is available, you can start to use it today.

— seb

PS: I heard from the team they are working on adding additional meta-data to the logs, stay tuned for updates.

Given the wide range of data types, query models, indexing options, scaling expectations, and performance requirements, databases are definitely not one size fits all products. That’s why there are many different AWS database offerings, each one purpose-built to meet the needs of a different type of application.

Introducing QLDB
Today I would like to tell you about Amazon QLDB, the newest member of the AWS database family. First announced at AWS re:Invent 2018 and made available in preview form, it is now available in production form in five AWS regions.

As a ledger database, QLDB is designed to provide an authoritative data source (often known as a system of record) for stored data. It maintains a complete, immutable history of all committed changes to the data that cannot be updated, altered, or deleted. QLDB supports PartiQL SQL queries to the historical data, and also provides an API that allows you to cryptographically verify that the history is accurate and legitimate. These features make QLDB a great fit for banking & finance, ecommerce, transportation & logistics, HR & payroll, manufacturing, and government applications and many other use cases that need to maintain the integrity and history of stored data.

Important QLDB Concepts
Let’s review the most important QLDB concepts before diving in:

Ledger – A QLDB ledger consists of a set of QLDB tables and a journal that maintains the complete, immutable history of changes to the tables. Ledgers are named and can be tagged.

Journal – A journal consists of a sequence of blocks, each cryptographically chained to the previous block so that changes can be verified. Blocks, in turn, contain the actual changes that were made to the tables, indexed for efficient retrieval. This append-only model ensures that previous data cannot be edited or deleted, and makes the ledgers immutable. QLDB allows you to export all or part of a journal to S3.

Table – Tables exist within a ledger, and contain a collection of document revisions. Tables support optional indexes on document fields; the indexes can improve performance for queries that make use of the equality (=) predicate.

Documents – Documents exist within tables, and must be in Amazon Ion form. Ion is a superset of JSON that adds additional data types, type annotations, and comments. QLDB supports documents that contain nested JSON elements, and gives you the ability to write queries that reference and include these elements. Documents need not conform to any particular schema, giving you the flexibility to build applications that can easily adapt to changes.

PartiQL – PartiQL is a new open standard query language that supports SQL-compatible access to relational, semi-structured, and nested data while remaining independent of any particular data source. To learn more, read Announcing PartiQL: One Query Languge for All Your Data.

Serverless – You don’t have to worry about provisioning capacity or configuring read & write throughput. You create a ledger, define your tables, and QLDB will automatically scale to meet the needs of your application.

Using QLDB
You can create QLDB ledgers and tables from the AWS Management Console, AWS Command Line Interface (CLI), a CloudFormation template, or by making calls to the QLDB API. I’ll use the QLDB Console and I will follow the steps in Getting Started with Amazon QLDB. I open the console and click Start tutorial to get started:

The Getting Started page outlines the first three steps; I click Create ledger to proceed (this opens in a fresh browser tab):

I enter a name for my ledger (vehicle-registration), tag it, and (again) click Create ledger to proceed:

My ledger starts out in Creating status, and transitions to Active within a minute or two:

I return to the Getting Started page, refresh the list of ledgers, choose my new ledger, and click Load sample data:

This takes a second or so, and creates four tables & six indexes:

I could also use PartiQL statements such as CREATE TABLE, CREATE INDEX, and INSERT INTO to accomplish the same task.

With my tables, indexes, and sample data loaded, I click on Editor and run my first query (a single-table SELECT):

This returns a single row, and also benefits from the index on the VIN field. I can also run a more complex query that joins two tables:

I can obtain the ID of a document (using a query from here), and then update the document:

I can query the modification history of a table or a specific document in a table, with the ability to find modifications within a certain range and on a particular document (read Querying Revision History to learn more). Here’s a simple query that returns the history of modifications to all of the documents in the VehicleRegistration table that were made on the day that I wrote this post:

As you can see, each row is a structured JSON object. I can select any desired rows and click View JSON for further inspection:

Earlier, I mentioned that PartiQL can deal with nested data. The VehicleRegistration table contains ownership information that looks like this:

{
   "Owners":{
      "PrimaryOwner":{
         "PersonId":"6bs0SQs1QFx7qN1gL2SE5G"
      },
      "SecondaryOwners":[

      ]
  }

PartiQL lets me reference the nested data using “.” notation:

I can also verify the integrity of a document that is stored within my ledger’s journal. This is fully described in Verify a Document in a Ledger, and is a great example of the power (and value) of cryptographic verification. Each QLDB ledger has an associated digest. The digest is a 256-bit hash value that uniquely represents the ledger’s entire history of document revisions as of a point in time. To access the digest, I select a ledger and click Get digest:

When I click Save, the console provides me with a short file that contains all of the information needed to verify the ledger. I save this file in a safe place, for use when I want to verify a document in the ledger. When that time comes, I get the file, click on Verification in the left-navigation, and enter the values needed to perform the verification. This includes the block address of a document revision, and the ID of the document. I also choose the digest that I saved earlier, and click Verify:

QLDB recomputes the hashes to ensure that the document has not been surreptitiously changed, and displays the verification:

In a production environment, you would use the QLDB APIs to periodically download digests and to verify the integrity of your documents.

Building Applications with QLDB
You can use the Amazon QLDB Driver for Java to write code that accesses and manipulates your ledger database. This is a Java driver that allows you to create sessions, execute PartiQL commands within the scope of a transaction, and retrieve results. Drivers for other languages are in the works; stay tuned for more information.

Available Now
Amazon QLDB is available now in the US East (N. Virginia), US East (Ohio), US West (Oregon), Europe (Ireland), and Asia Pacific (Tokyo) Regions. Pricing is based on the following factors, and is detailed on the Amazon QLDB Pricing page, including some real-world examples:

• Write operations
• Read operations
• Journal storage
• Indexed storage
• Data transfer

— Jeff;

Leaders within the AWS technical community educate others about the latest AWS services in a variety of ways: some share knowledge in person by speaking at events or running workshops and Meetups; while others prefer to share their insights online via social media, blogs, or open source contributions.

The most prominent AWS community leaders worldwide are recognized as AWS Heroes, and today we are excited to introduce to you the latest members of the AWS Hero program:

Alex Schultz – Fort Wayne, USA

Machine Learning Hero Alex Schultz works in the Innovation Labs at Advanced Solutions where he develops machine learning enabled products and solutions for the biomedical and product distribution industries. After receiving a DeepLens at re:Invent 2017, he dove headfirst into machine learning where he used the device to win the AWS DeepLens challenge by building a project which can read books to children. As an active advocate for AWS, he runs the Fort Wayne AWS User Group and loves to share his knowledge and experience with other developers. He also regularly contributes to the online DeepRacer community where he has helped many people who are new to machine learning get started.

Chase Douglas – Portland, USA

Serverless Hero Chase Douglas is the CTO and co-founder at Stackery, where he steers engineering and technical architecture of development tools that enable individuals and teams of developers to successfully build and manage serverless applications. He is a deeply experienced software architect and a long-time engineering leader focused on building products that increase development efficiency while delighting users. Chase is also a frequent conference speaker on the topics of serverless, instrumentation, and software patterns. Most recently, he discussed the serverless development-to-production pipeline at the Chicago and New York AWS Summits, and provided insight into how the future of serverless may be functionless in his blog series.

Chris Williams – Portsmouth, USA

Community Hero Chris Williams is an Enterprise Cloud Consultant for GreenPages Technology Solutions—a digital transformation and cloud enablement company. There he helps customers design and deploy the next generation of public, private, and hybrid cloud solutions, specializing in AWS and VMware. Chris blogs about virtualization, technology, and design at Mistwire. He is an active community leader, co-organizing the AWS Portsmouth User Group, and both hosts and presents on vBrownBag.

Dave Stauffacher – Milwaukee, USA

Community Hero Dave Stauffacher is a Principal Platform Engineer focused on cloud engineering at Direct Supply where he has helped navigate a 30,000% data growth over the last 15 years. In his current role, Dave is focused on helping drive Direct Supply’s cloud migration, combining his storage background with cloud automation and standardization practices. Dave has published his automation work for deploying AWS Storage Gateway for use with SQL Server data protection. He is a participant in the Milwaukee AWS User Group and the Milwaukee Docker User Group and has showcased his cloud experience in presentations at the AWS Midwest Community Day, AWS re:Invent, HashiConf, the Milwaukee Big Data User Group and other industry events.

Gojko Adzic – London, United Kingdom

Serverless Hero Gojko Adzic is a partner at Neuri Consulting LLP and a co-founder of MindMup, a collaborative mind mapping application that has been running on AWS Lambda since 2016. He is the author of the book Running Serverless and co-author of Serverless Computing: Economic and Architectural Impact, one of the first academic papers about AWS Lambda. He is also a key contributor to Claudia.js, an open-source tool that simplifies Lambda application deployment, and is a minor contributor to the AWS SAM CLI. Gojko frequently blogs about serverless application development on Serverless.Pub and his personal blog, and he has authored numerous other books.

Liz Rice – Enfield, United Kingdom

Container Hero Liz Rice is VP Open Source Engineering with cloud native security specialists Aqua Security, where she and her team look after several container-related open source projects. She is chair of the CNCF’s Technical Oversight Committee, and was Co-Chair of the KubeCon + CloudNativeCon 2018 events in Copenhagen, Shanghai and Seattle. She is a regular speaker at conferences including re:Invent, Velocity, DockerCon and many more. Her talks usually feature live coding or demos, and she is known for making complex technical concepts accessible.

Lyndon Leggate – London, United Kingdom

Machine Learning Hero Lyndon Leggate is a senior technology leader with extensive experience of defining and delivering complex technical solutions on large, business critical projects for consumer facing brands. Lyndon is a keen participant in the AWS DeepRacer league. Racing as Etaggel, he has regularly positioned in the top 10, features in DeepRacer TV and in May 2019 established the AWS DeepRacer Community. This vibrant and rapidly growing community provides a space for new and experienced racers to seek advice and share tips. The Community has gone on to expand the DeepRacer toolsets, making the platform more accessible and pushing the bounds of the technology. He also organises the AWS DeepRacer London Meetup series.

Maciej Lelusz – Crakow, Poland

Community Hero Maciej Lelusz is Co-Founder of Chaos Gears, a company concentrated on serverless, automation, IaC and chaos engineering as a way for the improvement of system resiliency. He is focused on community development, blogging, company management, and Public/Hybrid/Private cloud design. He cares about enterprise technology, IT transformation, its culture and people involved in it. Maciej is Co-Leader of the AWS User Group Poland – Cracow Chapter, and the Founder and Leader of the InfraXstructure conference and Polish VMware User Group.

Nathan Glover – Perth, Australia

Community Hero Nathan Glover is a DevOps Consultant at Mechanical Rock in Perth, Western Australia. Prior to that he worked as a Hardware Systems Designer and Embedded Developer in the IoT space. He is passionate about Cloud Native architecture and loves sharing his successes and failures on his blog. A key focus for him is breaking down the learning barrier by building practical examples using cloud services. On top of these he has a number of online courses teaching people how to get started building with Amazon Alexa Skills and AWS IoT. In his spare time, he loves to dabble in all areas of technology; building cloud connected toasters, embedded systems vehicle tracking, and competing in online capture the flag security events.

Prashanth HN – Bengaluru, India

Serverless Hero Prashanth HN is the Chief Technology Officer at WheelsBox and one of the community leaders of the AWS Users Group, Bengaluru. He mentors and consults other startups to embrace a serverless approach, frequently blogs about serverless topics for all skill levels including topics for beginners and advanced users on his personal blog and Amplify-related topics on the AWS Amplify Community Blog, and delivers talks about building using microservices and serverless. In a recent talk, he demonstrated how microservices patterns can be implemented using serverless. Prashanth maintains the open-source project Lanyard, a serverless agenda app for event organizers and attendees, which was well received at AWS Community Day India.

Ran Ribenzaft – Tel Aviv, Israel

Serverless Hero Ran Ribenzaft is the Chief Technology Officer at Epsagon, an AWS Advanced Technology Partner that specializes in monitoring and tracing for serverless applications. Ran is a passionate developer that loves sharing open-source tools to make everyone’s lives easier and writing technical blog posts on the topics of serverless, microservices, cloud, and AWS on Medium and the Epsagon blog. Ran is also dedicated to educating and growing the community around serverless, organizing Serverless meetups in SF and TLV, delivering online webinars and workshops, and frequently giving talks at conferences.

Rolf Koski – Tampere, Finland

Community Hero Rolf Koski works at Cybercom, which is an AWS Premier Partner from the Nordics headquartered in Sweden. He works as the CTO at Cybercom AWS Business Group. In his role he is both technical as well as being the thought leader in the Cloud. Rolf has been one of the leading figures at the Nordic AWS Communities as one of the community leads in Helsinki and Stockholm user groups and he initially founded and organized the first ever AWS Community Days Nordics. Rolf is professionally certified and additionally works as Well-Architected Lead doing Well-Architected Reviews for customer workloads.

Learn more about AWS Heroes and connect with a Hero near you by checking out the Hero website.