Tag Archives: Analytics

Amazon QuickSight Update – Geospatial Visualization, Private VPC Access, and More

Post Syndicated from Jeff Barr original https://aws.amazon.com/blogs/aws/amazon-quicksight-update-geospatial-visualization-private-vpc-access-and-more/

We don’t often recognize or celebrate anniversaries at AWS. With nearly 100 services on our list, we’d be eating cake and drinking champagne several times a week. While that might sound like fun, we’d rather spend our working hours listening to customers and innovating. With that said, Amazon QuickSight has now been generally available for a little over a year and I would like to give you a quick update!

QuickSight in Action
Today, tens of thousands of customers (from startups to enterprises, in industries as varied as transportation, legal, mining, and healthcare) are using QuickSight to analyze and report on their business data.

Here are a couple of examples:

Gemini provides legal evidence procurement for California attorneys who represent injured workers. They have gone from creating custom reports and running one-off queries to creating and sharing dynamic QuickSight dashboards with drill-downs and filtering. QuickSight is used to track sales pipeline, measure order throughput, and to locate bottlenecks in the order processing pipeline.

Jivochat provides a real-time messaging platform to connect visitors to website owners. QuickSight lets them create and share interactive dashboards while also providing access to the underlying datasets. This has allowed them to move beyond the sharing of static spreadsheets, ensuring that everyone is looking at the same and is empowered to make timely decisions based on current data.

Transfix is a tech-powered freight marketplace that matches loads and increases visibility into logistics for Fortune 500 shippers in retail, food and beverage, manufacturing, and other industries. QuickSight has made analytics accessible to both BI engineers and non-technical business users. They scrutinize key business and operational metrics including shipping routes, carrier efficient, and process automation.

Looking Back / Looking Ahead
The feedback on QuickSight has been incredibly helpful. Customers tell us that their employees are using QuickSight to connect to their data, perform analytics, and make high-velocity, data-driven decisions, all without setting up or running their own BI infrastructure. We love all of the feedback that we get, and use it to drive our roadmap, leading to the introduction of over 40 new features in just a year. Here’s a summary:

Looking forward, we are watching an interesting trend develop within our customer base. As these customers take a close look at how they analyze and report on data, they are realizing that a serverless approach offers some tangible benefits. They use Amazon Simple Storage Service (S3) as a data lake and query it using a combination of QuickSight and Amazon Athena, giving them agility and flexibility without static infrastructure. They also make great use of QuickSight’s dashboards feature, monitoring business results and operational metrics, then sharing their insights with hundreds of users. You can read Building a Serverless Analytics Solution for Cleaner Cities and review Serverless Big Data Analytics using Amazon Athena and Amazon QuickSight if you are interested in this approach.

New Features and Enhancements
We’re still doing our best to listen and to learn, and to make sure that QuickSight continues to meet your needs. I’m happy to announce that we are making seven big additions today:

Geospatial Visualization – You can now create geospatial visuals on geographical data sets.

Private VPC Access – You can now sign up to access a preview of a new feature that allows you to securely connect to data within VPCs or on-premises, without the need for public endpoints.

Flat Table Support – In addition to pivot tables, you can now use flat tables for tabular reporting. To learn more, read about Using Tabular Reports.

Calculated SPICE Fields – You can now perform run-time calculations on SPICE data as part of your analysis. Read Adding a Calculated Field to an Analysis for more information.

Wide Table Support – You can now use tables with up to 1000 columns.

Other Buckets – You can summarize the long tail of high-cardinality data into buckets, as described in Working with Visual Types in Amazon QuickSight.

HIPAA Compliance – You can now run HIPAA-compliant workloads on QuickSight.

Geospatial Visualization
Everyone seems to want this feature! You can now take data that contains a geographic identifier (country, city, state, or zip code) and create beautiful visualizations with just a few clicks. QuickSight will geocode the identifier that you supply, and can also accept lat/long map coordinates. You can use this feature to visualize sales by state, map stores to shipping destinations, and so forth. Here’s a sample visualization:

To learn more about this feature, read Using Geospatial Charts (Maps), and Adding Geospatial Data.

Private VPC Access Preview
If you have data in AWS (perhaps in Amazon Redshift, Amazon Relational Database Service (RDS), or on EC2) or on-premises in Teradata or SQL Server on servers without public connectivity, this feature is for you. Private VPC Access for QuickSight uses an Elastic Network Interface (ENI) for secure, private communication with data sources in a VPC. It also allows you to use AWS Direct Connect to create a secure, private link with your on-premises resources. Here’s what it looks like:

If you are ready to join the preview, you can sign up today.

Jeff;

 

Cross-Account Integration with Amazon SNS

Post Syndicated from Christie Gifrin original https://aws.amazon.com/blogs/compute/cross-account-integration-with-amazon-sns/

Contributed by Zak Islam, Senior Manager, Software Development, AWS Messaging

 

Amazon Simple Notification Service (Amazon SNS) is a fully managed AWS service that makes it easy to decouple your application components and fan-out messages. SNS provides topics (similar to topics in message brokers such as RabbitMQ or ActiveMQ) that you can use to create 1:1, 1:N, or N:N producer/consumer design patterns. For more information about how to send messages from SNS to Amazon SQS, AWS Lambda, or HTTP(S) endpoints in the same account, see Sending Amazon SNS Messages to Amazon SQS Queues.

SNS can be used to send messages within a single account or to resources in different accounts to create administrative isolation. This enables administrators to grant only the minimum level of permissions required to process a workload (for example, limiting the scope of your application account to only send messages and to deny deletes). This approach is commonly known as the “principle of least privilege.” If you are interested, read more about AWS’s multi-account security strategy.

This is great from a security perspective, but why would you want to share messages between accounts? It may sound scary, but it’s a common practice to isolate application components (such as producer and consumer) to operate using different AWS accounts to lock down privileges in case credentials are exposed. In this post, I go slightly deeper and explore how to set up your SNS topic so that it can route messages to SQS queues that are owned by a separate AWS account.

Potential use cases

First, look at a common order processing design pattern:

This is a simple architecture. A web server submits an order directly to an SNS topic, which then fans out messages to two SQS queues. One SQS queue is used to track all incoming orders for audits (such as anti-entropy, comparing the data of all replicas and updating each replica to the newest version). The other is used to pass the request to the order processing systems.

Imagine now that a few years have passed, and your downstream processes no longer scale, so you are kicking around the idea of a re-architecture project. To thoroughly test your system, you need a way to replay your production messages in your development system. Sure, you can build a system to replicate and replay orders from your production environment in your development environment. Wouldn’t it be easier to subscribe your development queues to the production SNS topic so you can test your new system in real time? That’s exactly what you can do here.

Here’s another use case. As your business grows, you recognize the need for more metrics from your order processing pipeline. The analytics team at your company has built a metrics aggregation service and ingests data via a central SQS queue. Their architecture is as follows:

Again, it’s a fairly simple architecture. All data is ingested via SQS queues (master_ingest_queue, in this case). You subscribe the master_ingest_queue, running under the analytics team’s AWS account, to the topic that is in the order management team’s account.

Making it work

Now that you’ve seen a few scenarios, let’s dig into the details. There are a couple of ways to link an SQS queue to an SNS topic (subscribe a queue to a topic):

  1. The queue owner can create a subscription to the topic.
  2. The topic owner can subscribe a queue in another account to the topic.

Queue owner subscription

What happens when the queue owner subscribes to a topic? In this case, assume that the topic owner has given permission to the subscriber’s account to call the Subscribe API action using the topic ARN (Amazon Resource Name). For the examples below, also assume the following:

  •  Topic_Owner is the identifier for the account that owns the topic MainTopic
  • Queue_Owner is the identifier for the account that owns the queue subscribed to the main topic

To enable the subscriber to subscribe to a topic, the topic owner must add the sns:Subscribe and topic ARN to the topic policy via the AWS Management Console, as follows:

{
  "Version":"2012-10-17",
  "Id":"MyTopicSubscribePolicy",
  "Statement":[{
      "Sid":"Allow-other-account-to-subscribe-to-topic",
      "Effect":"Allow",
      "Principal":{
        "AWS":"Topic_Owner"
      },
      "Action":"sns:Subscribe",
      "Resource":"arn:aws:sns:us-east-1:Queue_Owner:MainTopic"
    }
  ]
}

After this has been set up, the subscriber (using account Queue_Owner) can call Subscribe to link the queue to the topic. After the queue has been successfully subscribed, SNS starts to publish notifications. In this case, neither the topic owner nor the subscriber have had to process any kind of confirmation message.

Topic owner subscription

The second way to subscribe an SQS queue to an SNS topic is to have the Topic_Owner account initiate the subscription for the queue from account Queue_Owner. In this case, SNS first sends a confirmation message to the queue. To confirm the subscription, a user who can read messages from the queue must visit the URL specified in the SubscribeURL value in the message. Until the subscription is confirmed, no notifications published to the topic are sent to the queue. To confirm a subscription, you can use the SQS console or the ReceiveMessage API action.

What’s next?

In this post, I covered a few simple use cases but the principles can be extended to complex systems as well. As you architect new systems and refactor existing ones, think about where you can leverage queues (SQS) and topics (SNS) to build a loosely coupled system that can be quickly and easily extended to meet your business need.

For step by step instructions, see Sending Amazon SNS messages to an Amazon SQS queue in a different account. You can also visit the following resources to get started working with message queues and topics:

The Decision on Transparency

Post Syndicated from Gleb Budman original https://www.backblaze.com/blog/transparency-in-business/

Backblaze transparency

This post by Backblaze’s CEO and co-founder Gleb Budman is the seventh in a series about entrepreneurship. You can choose posts in the series from the list below:

  1. How Backblaze got Started: The Problem, The Solution, and the Stuff In-Between
  2. Building a Competitive Moat: Turning Challenges Into Advantages
  3. From Idea to Launch: Getting Your First Customers
  4. How to Get Your First 1,000 Customers
  5. Surviving Your First Year
  6. How to Compete with Giants
  7. The Decision on Transparency

Use the Join button above to receive notification of new posts in this series.

“Are you crazy?” “Why would you do that?!” “You shouldn’t share that!”

These are just a few of the common questions and comments we heard after posting some of the information we have shared over the years. So was it crazy? Misguided? Should you do it?

With that background I’d like to dig into the decision to become so transparent, from releasing stats on hard drive failures, to storage pod specs, to publishing our cloud storage costs, and open sourcing the Reed-Solomon code. What was the thought process behind becoming so transparent when most companies work so hard to hide their inner workings, especially information such as the Storage Pod specs that would normally be considered a proprietary advantage? Most importantly I’d like to explore the positives and negatives of being so transparent.

Sharing Intellectual Property

The first “transparency” that garnered a flurry of “why would you share that?!” came as a result of us deciding to open source our Storage Pod design: publishing the specs, parts, prices, and how to build it yourself. The Storage Pod was a key component of our infrastructure, gave us a cost (and thus competitive) advantage, took significant effort to develop, and had a fair bit of intellectual property: the “IP.”

The negatives of sharing this are obvious: it allows our competitors to use the design to reduce our cost advantage, and it gives away the IP, which could be patentable or have value as a trade secret.

The positives were certainly less obvious, and at the time we couldn’t have guessed how massive they would be.

We wrestled with the decision: prospective users and others online didn’t believe we could offer our service for such a low price, thinking that we would burn through some cash hoard and then go out of business. We wanted to reassure them, but how?

This is how our response evolved:

We’ve built a lower cost storage platform.
But why would anyone believe us?
Because, we’ve designed our own servers and they’re less expensive.
But why would anyone believe they were so low cost and efficient?
Because here’s how much they cost versus others.
But why would anyone believe they cost that little and still enabled us to efficiently store data?
Because here are all the components they’re made of, this is how to build them, and this is how they work.
Ok, you can’t argue with that.

Great — so that would reassure people. But should we do this? Is it worth it?

This was 2009, we were a tiny company of seven people working from our co-founder’s one-bedroom apartment. We decided that the risk of not having potential customers trust us was more impactful than the risk of our competitors possibly deciding to use our server architecture. The former might kill the company in short order; the latter might make it harder for us to compete in the future. Moreover, we figured that most competitors were established on their own platforms and were unlikely to switch to ours, even if it were better.

Takeaway: Build your brand today. There are no assurances you will make it to tomorrow if you can’t make people believe in you today.

A Sharing Success Story — The Backblaze Storage Pod

So with that, we decided to publish everything about the Storage Pod. As for deciding to actually open source it? That was a ‘thank you’ to the open source community upon whose shoulders we stood as we used software such as Linux, Tomcat, etc.

With eight years of hindsight, here’s what happened:

As best as I can tell, none of our direct competitors ever used our Storage Pod design, opting instead to continue paying more for commercial solutions.

  • Hundreds of press articles have been written about Backblaze as a direct result of sharing the Storage Pod design.
  • Millions of people have read press articles or our blog posts about the Storage Pods.
  • Backblaze was established as a storage tech thought leader, and a resource for those looking for information in the space.
  • Our blog became viewed as a resource, not a corporate mouthpiece.
  • Recruiting has been made easier through the awareness of Backblaze, the appreciation for us taking on challenging tech problems in interesting ways, and for our openness.
  • Sourcing for our Storage Pods has become easier because we can point potential vendors to our blog posts and say, “here’s what we need.”

And those are just the direct benefits for us. One of the things that warms my heart is that doing this has helped others:

  • Several companies have started selling servers based on our Storage Pod designs.
  • Netflix credits Backblaze with being the inspiration behind their CDN servers.
  • Many schools, labs, and others have shared that they’ve been able to do what they didn’t think was possible because using our Storage Pod designs provided lower-cost storage.
  • And I want to believe that in general we pushed forward the development of low-cost storage servers in the industry.

So overall, the decision on being transparent and sharing our Storage Pod designs was a clear win.

Takeaway: Never underestimate the value of goodwill. It can help build new markets that fuel your future growth and create new ecosystems.

Sharing An “Almost Acquisition”

Acquisition announcements are par for the course. No company, however, talks about the acquisition that fell through. If rumors appear in the press, the company’s response is always, “no comment.” But in 2010, when Backblaze was almost, but not acquired, we wrote about it in detail. Crazy?

The negatives of sharing this are slightly less obvious, but the two issues most people worried about were, 1) the fact that the company could be acquired would spook customers, and 2) the fact that it wasn’t would signal to potential acquirers that something was wrong.

So, why share this at all? No one was asking “did you almost get acquired?”

First, we had established a culture of transparency and this was a significant event that occurred for us, thus we defaulted to assuming we would share. Second, we learned that acquisitions fall through all the time, not just during the early fishing stage, but even after term sheets are signed, diligence is done, and all the paperwork is complete. I felt we had learned some things about the process that would be valuable to others that were going through it.

As it turned out, we received emails from startup founders saying they saved the post for the future, and from lawyers, VCs, and advisors saying they shared them with their portfolio companies. Among the most touching emails I received was from a founder who said that after an acquisition fell through she felt so alone that she became incredibly depressed, and that reading our post helped her see that this happens and that things could be OK after. Being transparent about almost getting acquired was worth it just to help that one founder.

And what about the concerns? As for spooking customers, maybe some were — but our sign-ups went up, not down, afterward. Any company can be acquired, and many of the world’s largest have been. That we were being both thoughtful about where to go with it, and open about it, I believe gave customers a sense that we would do the right thing if it happened. And as for signaling to potential acquirers? The ones I’ve spoken with all knew this happens regularly enough that it’s not a factor.

Takeaway: Being open and transparent is also a form of giving back to others.

Sharing Strategic Data

For years people have been desperate to know how reliable are hard drives. They could go to Amazon for individual reviews, but someone saying “this drive died for me” doesn’t provide statistical insight. Google published a study that showed annualized drive failure rates, but didn’t break down the results by manufacturer or model. Since Backblaze has deployed about 100,000 hard drives to store customer data, we have been able to collect a wealth of data on the reliability of the drives by make, model, and size. Was Backblaze the only one with this data? Of course not — Google, Amazon, Microsoft, and any other cloud-scale storage provider tracked it. Yet none would publish. Should Backblaze?

Again, starting with the main negatives: 1) sharing which drives we liked could increase demand for them, thus reducing availability or increasing prices, and 2) publishing the data might make the drive vendors unhappy with us, thereby making it difficult for us to buy drives.

But we felt that the largest drive purchasers (Amazon, Google, etc.) already had their own stats and would buy the drives they chose, and if individuals or smaller companies used our stats, they wouldn’t sufficiently move the overall market demand. Also, we hoped that the drive companies would see that we were being fair in our analysis and, if anything, would leverage our data to make drives even better.

Again, publishing the data resulted in tremendous value for Backblaze, with millions of people having read the analysis that we put out quarterly. Also, becoming known as the place to go for drive reliability information is a natural fit with being a backup and storage provider. In addition, in a twist from many people’s expectations, some of the drive companies actually started working closer with us, seeing that we could be a good source of data for them as feedback. We’ve also seen many individuals and companies make more data-based decisions on which drives to buy, and researchers have used the data for a variety of analyses.

traffic spike from hard drive reliability post

Backblaze blog analytics showing spike in readership after a hard drive stats post

Takeaway: Being open and transparent is rarely as risky as it seems.

Sharing Revenue (And Other Metrics)

Journalists always want to publish company revenue and other metrics, and private companies always shy away from sharing. For a long time we did, too. Then, we opened up about that, as well.

The negatives of sharing these numbers are: 1) external parties may otherwise perceive you’re doing better than you are, 2) if you share numbers often, you may show that growth has slowed or worse, 3) it gives your competitors info to compare their own business too.

We decided that, while some may have perceived we were bigger, our scale was plenty significant. Since we choose what we share and when, it’s up to us whether to disclose at any point. And if our competitors compare, what will they actually change that would affect us?

I did wait to share revenue until I felt I had the right person to write about it. At one point a journalist said she wouldn’t write about us unless I disclosed revenue. I suggested we had a lot to offer for the story, but didn’t want to share revenue yet. She refused to budge and I walked away from the article. Several year later, I reached out to a journalist who had covered Backblaze before and I felt understood our business and offered to share revenue with him. He wrote a deep-dive about the company, with revenue being one of the components of the story.

Sharing these metrics showed that we were at scale and running a real business, one with positive unit economics and margins, but not one where we were gouging customers.

Takeaway: Being open with the press about items typically not shared can be uncomfortable, but the press can amplify your story.

Should You Share?

For Backblaze, I believe the results of transparency have been staggering. However, it’s not for everyone. Apple has, clearly, been wildly successful taking secrecy to the extreme. In their case, early disclosure combined with the long cycle of hardware releases could significantly impact sales of current products.

“For Backblaze, I believe the results of transparency have been staggering.” — Gleb Budman

I will argue, however, that for most startups transparency wins. Most startups need to establish credibility and trust, build awareness and a fan base, show that they understand what their customers need and be useful to them, and show the soul and passion behind the company. Some startup companies try to buy these virtues with investor money, and sometimes amplifying your brand via paid marketing helps. But, authentic transparency can build awareness and trust not only less expensively, but more deeply than money can buy.

Backblaze was open from the beginning. With no outside investors, as founders we were able to express ourselves and make our decisions. And it’s easier to be a company that shares if you do it from the start, but for any company, here are a few suggestions:

  1. Ask about sharing: If something significant happens — good or bad — ask “should we share this?” If you made a tough decision, ask “should we share the thinking behind the decision and why it was tough?”
  2. Default to yes: It’s often scary to share, but look for the reasons to say ‘yes,’ not the reasons to say ‘no.’ That doesn’t mean you won’t sometimes decide not to, but make that the high bar.
  3. Minimize reviews: Press releases tend to be sanitized and boring because they’ve been endlessly wordsmithed by committee. Establish the few things you don’t want shared, but minimize the number of people that have to see anything else before it can go out. Teach, then trust.
  4. Engage: Sharing will result in comments on your blog, social, articles, etc. Reply to people’s questions and engage. It’ll make the readers more engaged and give you a better understanding of what they’re looking for.
  5. Accept mistakes: Things will become public that aren’t perfectly sanitized. Accept that and don’t punish people for oversharing.

Building a culture of a company that is open to sharing takes time, but continuous practice will build that, and over time the company will navigate its voice and approach to sharing.

The post The Decision on Transparency appeared first on Backblaze Blog | Cloud Storage & Cloud Backup.

Google: Netflix Searches Outweigh Those For Pirate Alternatives

Post Syndicated from Andy original https://torrentfreak.com/google-netflix-searches-outweigh-those-for-pirate-alternatives-171112/

When large-scale access to online pirated content began to flourish at the turn of the decade, entertainment industry groups claimed that if left to run riot, it could mean the end of their businesses.

More than seventeen years later that doomsday scenario hasn’t come to pass, not because piracy has been defeated – far from it – but because the music, movie and related industries have come to the market with their own offers.

The music industry were the quickest to respond, with services like iTunes and later Spotify making serious progress against pirate alternatives. It took the video industry far longer to attack the market but today, with platforms such as Netflix and Amazon Video, they have a real chance at scooping up what might otherwise be pirate consumption.

While there’s still a long way to go, it’s interesting to hear the progress that’s being made not only in the West but also piracy hotspots further afield. This week, Brazil’s Exame reported on a new study published by Google.

Focused on movies, one of its key findings is that local consumer interest in Netflix is now greater than pirate alternatives including torrents, streaming, and apps. As illustrated in the image below, the tipping point took place early November 2016, when searches for Netflix overtook those for unauthorized platforms.

Netflix vs Pirates (via Exame)

While the stats above don’t necessarily point to a reduction in piracy of movies and TV shows in Brazil, they show that Netflix’s library and ease of use is rewarded by widespread awareness among those seeking such content locally.

“We’re not lowering piracy but this does show how relevant the [Netflix] brand is when it comes to offering content online,” Google Brazil’s market intelligence chief Sérgio Tejido told Exame.

For Debora Bona, a director specializing in media and entertainment at Google Brazil, the success of Netflix is comparable to the rise of Spotify. In part thanks to The Pirate Bay, Sweden had a serious piracy problem in the middle of the last decade but by providing a viable alternative, the streaming service has become part of the solution.

“The event is interesting,” Bona says. “Since the launch of streaming solutions such as Netflix and Spotify, they have become alternatives to piracy. Sweden had many problems with music piracy and the arrival of Spotify reversed this curve.”

Netflix launched in Brazil back in 2011, but Exame notes that the largest increase in searches for the platform took place between 2013 and 2016, demonstrating a boost of 284%. Even more evidence of Netflix’s popularity was revealed in recent surveys which indicate that 77% of surveyed Brazilians had watched Netflix, up from 71% in 2016.

Importantly, nine out of ten users in Brazil said they were “extremely satisfied” or “very satisfied” with the service, up from 79% in the previous year. An impressive 66% of subscribers said that they were “not at all likely to cancel”, a welcome statistics for a company pumping billions into making its own content and increasingly protecting it (1,2), in the face of persistent pirate competition.

Source: TF, for the latest info on copyright, file-sharing, torrent sites and more. We also have VPN discounts, offers and coupons

Visualize AWS Cloudtrail Logs using AWS Glue and Amazon Quicksight

Post Syndicated from Luis Caro Perez original https://aws.amazon.com/blogs/big-data/streamline-aws-cloudtrail-log-visualization-using-aws-glue-and-amazon-quicksight/

Being able to easily visualize AWS CloudTrail logs gives you a better understanding of how your AWS infrastructure is being used. It can also help you audit and review AWS API calls and detect security anomalies inside your AWS account. To do this, you must be able to perform analytics based on your CloudTrail logs.

In this post, I walk through using AWS Glue and AWS Lambda to convert AWS CloudTrail logs from JSON to a query-optimized format dataset in Amazon S3. I then use Amazon Athena and Amazon QuickSight to query and visualize the data.

Solution overview

To process CloudTrail logs, you must implement the following architecture:

CloudTrail delivers log files in an Amazon S3 bucket folder. To correctly crawl these logs, you modify the file contents and folder structure using an Amazon S3-triggered Lambda function that stores the transformed files in an S3 bucket single folder. When the files are in a single folder, AWS Glue scans the data, converts it into Apache Parquet format, and catalogs it to allow for querying and visualization using Amazon Athena and Amazon QuickSight.

Walkthrough

Let’s look at the steps that are required to build the solution.

Set up CloudTrail logs

First, you need to set up a trail that delivers log files to an S3 bucket. To create a trail in CloudTrail, follow the instructions in Creating a Trail.

When you finish, the trail settings page should look like the following screenshot:

In this example, I set up log files to be delivered to the cloudtraillfcaro bucket.

Consolidate CloudTrail reports into a single folder using Lambda

AWS CloudTrail delivers log files using the following folder structure inside the configured Amazon S3 bucket:

AWSLogs/ACCOUNTID/CloudTrail/REGION/YEAR/MONTH/HOUR/filename.json.gz

Additionally, log files have the following structure:

{
    "Records": [{
        "eventVersion": "1.01",
        "userIdentity": {
            "type": "IAMUser",
            "principalId": "AIDAJDPLRKLG7UEXAMPLE",
            "arn": "arn:aws:iam::123456789012:user/Alice",
            "accountId": "123456789012",
            "accessKeyId": "AKIAIOSFODNN7EXAMPLE",
            "userName": "Alice",
            "sessionContext": {
                "attributes": {
                    "mfaAuthenticated": "false",
                    "creationDate": "2014-03-18T14:29:23Z"
                }
            }
        },
        "eventTime": "2014-03-18T14:30:07Z",
        "eventSource": "cloudtrail.amazonaws.com",
        "eventName": "StartLogging",
        "awsRegion": "us-west-2",
        "sourceIPAddress": "72.21.198.64",
        "userAgent": "signin.amazonaws.com",
        "requestParameters": {
            "name": "Default"
        },
        "responseElements": null,
        "requestID": "cdc73f9d-aea9-11e3-9d5a-835b769c0d9c",
        "eventID": "3074414d-c626-42aa-984b-68ff152d6ab7"
    },
    ... additional entries ...
    ]

If AWS Glue crawlers are used to catalog these files as they are written, the following obstacles arise:

  1. AWS Glue identifies different tables per different folders because they don’t follow a traditional partition format.
  2. Based on the structure of the file content, AWS Glue identifies the tables as having a single column of type array.
  3. CloudTrail logs have JSON attributes that use uppercase letters. According to the Best Practices When Using Athena with AWS Glue, it is recommended that you convert these to lowercase.

To have AWS Glue catalog all log files in a single table with all the columns describing each event, implement the following Lambda function:

from __future__ import print_function
import json
import urllib
import boto3
import gzip

s3 = boto3.resource('s3')
client = boto3.client('s3')

def convertColumntoLowwerCaps(obj):
    for key in obj.keys():
        new_key = key.lower()
        if new_key != key:
            obj[new_key] = obj[key]
            del obj[key]
    return obj


def lambda_handler(event, context):

    bucket = event['Records'][0]['s3']['bucket']['name']
    key = urllib.unquote_plus(event['Records'][0]['s3']['object']['key'].encode('utf8'))
    print(bucket)
    print(key)
    try:
        newKey = 'flatfiles/' + key.replace("/", "")
        client.download_file(bucket, key, '/tmp/file.json.gz')
        with gzip.open('/tmp/out.json.gz', 'w') as output, gzip.open('/tmp/file.json.gz', 'rb') as file:
            i = 0
            for line in file: 
                for record in json.loads(line,object_hook=convertColumntoLowwerCaps)['records']:
            		if i != 0:
            		    output.write("\n")
            		output.write(json.dumps(record))
            		i += 1
        client.upload_file('/tmp/out.json.gz', bucket,newKey)
        return "success"
    except Exception as e:
        print(e)
        print('Error processing object {} from bucket {}. Make sure they exist and your bucket is in the same region as this function.'.format(key, bucket))
        raise e

The function goes over each element of the records array, changes uppercase letters to lowercase in column names, and inserts each element of the array as a single line of a new file. The new file is saved inside a flatfiles folder created by the function without any subfolders in the S3 bucket.

The function should have a role containing a policy with at least the following permissions:

{
    "Version": "2012-10-17",
    "Statement": [
        {
            "Action": [
                "s3:*"
            ],
            "Resource": [
                "arn:aws:s3:::cloudtraillfcaro/*",
                "arn:aws:s3:::cloudtraillfcaro"
            ],
            "Effect": "Allow"
        }
    ]
}

In this example, CloudTrail delivers logs to the cloudtraillfcaro bucket. Make sure that you replace this name with your bucket name in the policy. For more information about how to work with inline policies, see Working with Inline Policies.

After the Lambda function is created, you can set up the following trigger using the Triggers tab on the AWS Lambda console.

Choose Add trigger, and choose S3 as a source of the trigger.

After choosing the source, configure the following settings:

In the trigger, any file that is written to the path for the log files—which in this case is AWSLogs/119582755581/CloudTrail/—is processed. Make sure that the Enable trigger check box is selected and that the bucket and prefix parameters match your use case.

After you set up the function and receive log files, the bucket (in this case cloudtraillfcaro) should contain the processed files inside the flatfiles folder.

Catalog source data

Once the files are processed by the Lambda function, set up a crawler named cloudtrail to catalog them.

The crawler must point to the flatfiles folder.

All the crawlers and AWS Glue jobs created for this solution must have a role with the AWSGlueServiceRole managed policy and an inline policy with permissions to modify the S3 buckets used on the Lambda function. For more information, see Working with Managed Policies.

The role should look like the following:

In this example, the inline policy named s3perms contains the permissions to modify the S3 buckets.

After you choose the role, you can schedule the crawler to run on demand.

A new database is created, and the crawler is set to use it. In this case, the cloudtrail database is used for all the tables.

After the crawler runs, a single table should be created in the catalog with the following structure:

The table should contain the following columns:

Create and run the AWS Glue job

To convert all the CloudTrail logs to a columnar store in Parquet, set up an AWS Glue job by following these steps.

Upload the following script into a bucket in Amazon S3:

import sys
from awsglue.transforms import *
from awsglue.utils import getResolvedOptions
from pyspark.context import SparkContext
from awsglue.context import GlueContext
from awsglue.job import Job
import boto3
import time

## @params: [JOB_NAME]
args = getResolvedOptions(sys.argv, ['JOB_NAME'])

sc = SparkContext()
glueContext = GlueContext(sc)
spark = glueContext.spark_session
job = Job(glueContext)
job.init(args['JOB_NAME'], args)

datasource0 = glueContext.create_dynamic_frame.from_catalog(database = "cloudtrail", table_name = "flatfiles", transformation_ctx = "datasource0")
resolvechoice1 = ResolveChoice.apply(frame = datasource0, choice = "make_struct", transformation_ctx = "resolvechoice1")
relationalized1 = resolvechoice1.relationalize("trail", args["TempDir"]).select("trail")
datasink = glueContext.write_dynamic_frame.from_options(frame = relationalized1, connection_type = "s3", connection_options = {"path": "s3://cloudtraillfcaro/parquettrails"}, format = "parquet", transformation_ctx = "datasink4")
job.commit()

In the example, you load the script as a file named cloudtrailtoparquet.py. Make sure that you modify the script and update the “{"path": "s3://cloudtraillfcaro/parquettrails"}” with the destination in which you want to store your results.

After uploading the script, add a new AWS Glue job. Choose a name and role for the job, and choose the option of running the job from An existing script that you provide.

To avoid processing the same data twice, enable the Job bookmark setting in the Advanced properties section of the job properties.

Choose Next twice, and then choose Finish.

If logs are already in the flatfiles folder, you can run the job on demand to generate the first set of results.

Once the job starts running, wait for it to complete.

When the job is finished, its Run status should be Succeeded. After that, you can verify that the Parquet files are written to the Amazon S3 location.

Catalog results

To be able to process results from Athena, you can use an AWS Glue crawler to catalog the results of the AWS Glue job.

In this example, the crawler is set to use the same database as the source named cloudtrail.

You can run the crawler using the console. When the crawler finishes running and has processed the Parquet results, a new table should be created in the AWS Glue Data Catalog. In this example, it’s named parquettrails.

The table should have the classification set to parquet.

It should have the same columns as the flatfiles table, with the exception of the struct type columns, which should be relationalized into several columns:

In this example, notice how the requestparameters column, which was a struct in the original table (flatfiles), was transformed to several columns—one for each key value inside it. This is done using a transformation native to AWS Glue called relationalize.

Query results with Athena

After crawling the results, you can query them using Athena. For example, to query what events took place in the time frame between 2017-10-23t12:00:00 and 2017-10-23t13:00, use the following select statement:

select *
from cloudtrail.parquettrails
where eventtime > '2017-10-23T12:00:00Z' AND eventtime < '2017-10-23T13:00:00Z'
order by eventtime asc;

Be sure to replace cloudtrail.parquettrails with the names of your database and table that references the Parquet results. Replace the datetimes with an hour when your account had activity and was processed by the AWS Glue job.

Visualize results using Amazon QuickSight

Once you can query the data using Athena, you can visualize it using Amazon QuickSight. Before connecting Amazon QuickSight to Athena, be sure to grant QuickSight access to Athena and the associated S3 buckets in your account. For more information, see Managing Amazon QuickSight Permissions to AWS Resources. You can then create a new data set in Amazon QuickSight based on the Athena table that you created.

After setting up permissions, you can create a new analysis in Amazon QuickSight by choosing New analysis.

Then add a new data set.

Choose Athena as the source.

Give the data source a name (in this case, I named it cloudtrail).

Choose the name of the database and the table referencing the Parquet results.

Then choose Visualize.

After that, you should see the following screen:

Now you can create some visualizations. First, search for the sourceipaddress column, and drag it to the AutoGraph section.

You can see a list of the IP addresses that you have used to interact with AWS. To review whether these IP addresses have been used from IAM users, internal AWS services, or roles, use the type value that is inside the useridentity field of the original log files. Thanks to the relationalize transformation, this value is available as the useridentity.type column. After the column is added into the Group/Color box, the visualization should look like the following:

You can now see and distinguish the most used IPs and whether they are used from roles, AWS services, or IAM users.

After following all these steps, you can use Amazon QuickSight to add different columns from CloudTrail and perform different types of visualizations. You can build operational dashboards that continuously monitor AWS infrastructure usage and access. You can share those dashboards with others in your organization who might need to see this data.

Summary

In this post, you saw how you can use a simple Lambda function and an AWS Glue script to convert text files into Parquet to improve Athena query performance and data compression. The post also demonstrated how to use AWS Lambda to preprocess files in Amazon S3 and transform them into a format that is recognizable by AWS Glue crawlers.

This example, used AWS CloudTrail logs, but you can apply the proposed solution to any set of files that after preprocessing, can be cataloged by AWS Glue.


Additional Reading

Learn how to Harmonize, Query, and Visualize Data from Various Providers using AWS Glue, Amazon Athena, and Amazon QuickSight.


About the Authors

Luis Caro is a Big Data Consultant for AWS Professional Services. He works with our customers to provide guidance and technical assistance on big data projects, helping them improving the value of their solutions when using AWS.

 

 

 

Amazon ElastiCache Update – Online Resizing for Redis Clusters

Post Syndicated from Jeff Barr original https://aws.amazon.com/blogs/aws/amazon-elasticache-update-online-resizing-for-redis-clusters/

Amazon ElastiCache makes it easy to for you to set up a fast, in-memory data store and cache. With support for the two most popular open source offerings (Redis and Memcached), ElastiCache supports the demanding needs of game leaderboards, in-memory analytics, and large-scale messaging.

Today I would like to tell you about an important addition to Amazon ElastiCache for Redis. You can already create clusters with up to 15 shards, each responsible for storing keys and values for a specific set of slots (each cluster has exactly 16,384 slots). A single cluster can expand to store 3.55 terabytes of in-memory data while supporting up to 20 million reads and 4.5 million writes per second.

Now with Online Resizing
You can now adjust the number of shards in a running ElastiCache for Redis cluster while the cluster remains online and responding to requests. This gives you the power to respond to changes in traffic and data volume without having to take the cluster offline or to start with an empty cache. You can also rebalance a running cluster to uniformly redistribute slot space without changing the number of shards.

When you initiate a resharding or rebalancing operation, ElastiCache for Redis starts by preparing a plan that will result in an even distribution of slots across the shards in the cluster. Then it transfers slots across shards, moving many in parallel for efficiency. This all happens while the cluster continues to respond to requests, with a modest impact on write throughput for writes to a slot that is in motion. The migration rate is dependent on the instance type, network speed, read/write traffic to the slots, and is generally about 1 gigabyte per minute.

The resharding and rebalancing operations apply to Redis clusters that were created with Cluster Mode enabled:

Resharding a Cluster
In general, you will know that it is time to expand a cluster via resharding when it starts to face significant memory pressure or when individual nodes are becoming bottlenecks. You can watch the cluster’s CloudWatch metrics to identify each situation:

Memory Pressure – FreeableMemory, SwapUsage, BytesUsedForCache.

CPU Bottleneck – CPUUtilization, CurrConnections, NewConnections.

Network Bottleneck – NetworkBytesIn, NetworkBytesOut.

You can use CloudWatch Dashboards to monitor these metrics, and CloudWatch Alarms to automate the resharding process.

To reshard a Redis cluster from the ElastiCache Dashboard, click on the cluster to visit the detail page, and then click on the Add shards button:

Enter the number of shards to add and (optionally) the desired Availability Zones, then click on Add:

The status of the cluster will change to modifying and the resharding process will begin. It can take anywhere from a few minutes to several hours, as indicated above. You can track the progress on the detail page for the cluster:

You can see the slots moving from shard to shard:

You can also watch the Events for the cluster:

During the resharding you should avoid the use of the KEYS and SMEMBERS commands, as well as compute-intensive Lua scripts in order to moderate the load on the cluster shards. You should avoid the FLUSHDB and FLUSHALL commands entirely; using them will interrupt and then abort the resharding process.

The status of each shard will return to available when the process is complete:

The same process takes place when you delete shards.

Rebalancing Slots
You can perform this operation by heading to the cluster’s detail page and clicking on Rebalance Slot Distribution:

Things to Know
Here are a couple of things to keep in mind about this new feature:

Engine Version – Your cluster must be running version 3.2.10 of the Redis engine.

Migration Size – Slots that contain items that are larger than 256 megabytes after serialization are not migrated.

Cluster Endpoint – The cluster endpoint does not change as a result of a resharding or rebalancing.

Available Now
This feature is available now and you can start using it today.

Jeff;

 

Now Available – Compute-Intensive C5 Instances for Amazon EC2

Post Syndicated from Jeff Barr original https://aws.amazon.com/blogs/aws/now-available-compute-intensive-c5-instances-for-amazon-ec2/

I’m thrilled to announce that the new compute-intensive C5 instances are available today in six sizes for launch in three AWS regions!

These instances designed for compute-heavy applications like batch processing, distributed analytics, high-performance computing (HPC), ad serving, highly scalable multiplayer gaming, and video encoding. The new instances offer a 25% price/performance improvement over the C4 instances, with over 50% for some workloads. They also have additional memory per vCPU, and (for code that can make use of the new AVX-512 instructions), twice the performance for vector and floating point workloads.

Over the years we have been working non-stop to provide our customers with the best possible networking, storage, and compute performance, with a long-term focus on offloading many types of work to dedicated hardware designed and built by AWS. The C5 instance type incorporates the latest generation of our hardware offloads, and also takes another big step forward with the addition of a new hypervisor that runs hand-in-glove with our hardware. The new hypervisor allows us to give you access to all of the processing power provided by the host hardware, while also making performance even more consistent and further raising the bar on security. We’ll be sharing many technical details about it at AWS re:Invent.

The New Instances
The C5 instances are available in six sizes:

Instance Name vCPUs
RAM
EBS Bandwidth Network Bandwidth
c5.large 2 4 GiB Up to 2.25 Gbps Up to 10 Gbps
c5.xlarge 4 8 GiB Up to 2.25 Gbps Up to 10 Gbps
c5.2xlarge 8 16 GiB Up to 2.25 Gbps Up to 10 Gbps
c5.4xlarge 16 32 GiB 2.25 Gbps Up to 10 Gbps
c5.9xlarge 36 72 GiB 4.5 Gbps 10 Gbps
c5.18xlarge 72 144 GiB 9 Gbps 25 Gbps

Each vCPU is a hardware hyperthread on a 3.0 GHz Intel Xeon Platinum 8000-series processor. This custom processor, optimized for EC2, allows you have full control over the C-states on the two largest sizes, allowing you to run a single core at up to 3.5 GHz using Intel Turbo Boost Technology.

As you can see from the table, the four smallest instance sizes offer substantially more EBS and network bandwidth than the previous generation of compute-intensive instances.

Because all networking and storage functionality is implemented in hardware, C5 instances require HVM AMIs that include drivers for the Elastic Network Adapter (ENA) and NVMe. The latest Amazon Linux, Microsoft Windows, Ubuntu, RHEL, CentOS, SLES, Debian, and FreeBSD AMIs all support C5 instances. If you are doing machine learning inferencing, or other compute-intensive work, be sure to check out the most recent version of the Intel Math Kernel Library. It has been optimized for the Intel® Xeon® Platinum processor and has the potential to greatly accelerate your work.

In order to remain compatible with instances that use the Xen hypervisor, the device names for EBS volumes will continue to use the existing /dev/sd and /dev/xvd prefixes. The device name that you provide when you attach a volume to an instance is not used because the NVMe driver assigns its own device name (read Amazon EBS and NVMe to learn more):

The nvme command displays additional information about each volume (install it using sudo yum -y install nvme-cli if necessary):

The SN field in the output can be mapped to an EBS volume ID by inserting a “-” after the “vol” prefix (sadly, the NVMe SN field is not long enough to store the entire ID). Here’s a simple script that uses this information to create an EBS snapshot of each attached volume:

$ sudo nvme list | \
  awk '/dev/ {print(gensub("vol", "vol-", 1, $2))}' | \
  xargs -n 1 aws ec2 create-snapshot --volume-id

With a little more work (and a lot of testing), you could create a script that expands EBS volumes that are getting full.

Getting to C5
As I mentioned earlier, our effort to offload work to hardware accelerators has been underway for quite some time. Here’s a recap:

CC1 – Launched in 2010, the CC1 was designed to support scale-out HPC applications. It was the first EC2 instance to support 10 Gbps networking and one of the first to support HVM virtualization. The network fabric that we designed for the CC1 (based on our own switch hardware) has become the standard for all AWS data centers.

C3 – Launched in 2013, the C3 introduced Enhanced Networking and uses dedicated hardware accelerators to support the software defined network inside of each Virtual Private Cloud (VPC). Hardware virtualization removes the I/O stack from the hypervisor in favor of direct access by the guest OS, resulting in higher performance and reduced variability.

C4 – Launched in 2015, the C4 instances are EBS Optimized by default via a dedicated network connection, and also offload EBS processing (including CPU-intensive crypto operations for encrypted EBS volumes) to a hardware accelerator.

C5 – Launched today, the hypervisor that powers the C5 instances allow practically all of the resources of the host CPU to be devoted to customer instances. The ENA networking and the NVMe interface to EBS are both powered by hardware accelerators. The instances do not require (or support) the Xen paravirtual networking or block device drivers, both of which have been removed in order to increase efficiency.

Going forward, we’ll use this hypervisor to power other instance types and plan to share additional technical details in a set of AWS re:Invent sessions.

Launch a C5 Today
You can launch C5 instances today in the US East (Northern Virginia), US West (Oregon), and EU (Ireland) Regions in On-Demand and Spot form (Reserved Instances are also available), with additional Regions in the works.

One quick note before I go: The current NVMe driver is not optimized for high-performance sequential workloads and we don’t recommend the use of C5 instances in conjunction with sc1 or st1 volumes. We are aware of this issue and have been working to optimize the driver for this important use case.

Jeff;

MPAA: Almost 70% of 38 Million Kodi Users Are Pirates

Post Syndicated from Andy original https://torrentfreak.com/mpaa-almost-70-of-38-million-kodi-users-are-pirates-171104/

As torrents and other forms of file-sharing resolutely simmer away in the background, it is the streaming phenomenon that’s taking the Internet by storm.

This Tuesday, in a report by Canadian broadband management company Sandvine, it was revealed that IPTV traffic has grown to massive proportions.

Sandvine found that 6.5% of households in North American are now communicating with known TV piracy services. This translates to seven million subscribers and many more potential viewers. There’s little doubt that IPTV and all its variants, Kodi streaming included, are definitely here to stay.

The topic was raised again Wednesday during a panel discussion hosted by the Copyright Alliance in conjunction with the Creative Rights Caucus. Titled “Copyright Pirates’ New Strategies”, the discussion’s promotional graphic indicates some of the industry heavyweights in attendance.

The Copyright Alliance tweeted points from the discussion throughout the day and soon the conversation turned to the streaming phenomenon that has transformed piracy in recent times.

Previously dubbed Piracy 3.0 by the MPAA, Senior Vice President, Government and Regulatory Affairs Neil Fried was present to describe streaming devices and apps as the latest development in TV and movie piracy.

Like many before him, Fried explained that the Kodi platform in its basic form is legal. However, he noted that many of the add-ons for the media player provide access to pirated content, a point proven in a big screen demo.

Kodi demo by the MPAA via Copyright Alliance

According to the Copyright Alliance, Fried then delivered some interesting stats. The MPAA believes that there are around 38 million users of Kodi in the world, which sounds like a reasonable figure given that the system has been around for 15 years in various guises, including during its XBMC branding.

However, he also claimed that of those 38 million, a substantial 26 million users have piracy addons installed. That suggests around 68.5% or seven out of ten of all Kodi users are pirates of movies, TV shows, and other media. Taking the MPAA statement to its conclusion, only 12 million Kodi users are operating the software legitimately.

TorrentFreak contacted XBMC Foundation President Nathan Betzen for his stance on the figures but he couldn’t shine much light on usage.

“Unfortunately I do not have an up to date number on users, and because we don’t watch what our users are doing, we have no way of knowing how many do what with regards to streaming. [The MPAA’s] numbers could be completely correct or totally made up. We have no real way to know,” Betzen said.

That being said, the team does have the capability to monitor overall Kodi usage, even if they don’t publish the stats. This was revealed back in June 2011 when Kodi was still called XBMC.

“The addon system gives us the opportunity to measure the popularity of addons, measure user base, estimate the frequency that people update their systems, and even, ultimately, help users find the more popular addons,” the team wrote.

“Most interestingly, for the purposes of this post, is that we can get a pretty good picture of how many active XBMC installs there are without having to track what each individual user does.”

Using this system, the team concluded there were roughly 435,000 active XBMC instances around the globe in April 2011, but that figure was to swell dramatically. Just three months later, 789,000 XBMC installations had been active in the previous six weeks.

What’s staggering is that in 2017, the MPAA claims that there are now 38 million users of Kodi, of which 26 million are pirates. In the absence of any figures from the Kodi team, TF asked Kodi addon repository TVAddons what they thought of the MPAA’s stats.

“We’ve always banned the use of analytics within Kodi addons, so it’s really impossible to make such an estimate. It seems like the MPAA is throwing around numbers without much statistical evidence while mislabelling Kodi users as ‘pirate’ in the same way that they have mislabelled legitimate services like CloudFlare,” a spokesperson said.

“As far as general addon use goes, before our repository server (which contained hundreds of legitimate addons) was unlawfully seized, it had about 39 million active users per month, but even we don’t know how many users downloaded which addons. We never allowed for addon statistics for users because they are invasive to privacy and breed unhealthy competition.”

So, it seems that while there is some dispute over the number of potential pirates, there does at least appear to be some consensus on the number of users overall. The big question, however, is how groups like the MPAA will deal with this kind of unauthorized infringement in future.

At the moment the big push is to paint pirate platforms as dangerous places to be. Indeed, during the discussion this week, Copyright Alliance CEO Keith Kupferschmid claimed that users of pirate services are “28 times more likely” to be infected with malware.

Whether that strategy will pay off remains unclear but it’s obvious that at least for now, Piracy 3.0 is a massive deal, one that few people saw coming half a decade ago but is destined to keep growing.

Source: TF, for the latest info on copyright, file-sharing, torrent sites and ANONYMOUS VPN services.

Tableau 10.4 Supports Amazon Redshift Spectrum with External Amazon S3 Tables

Post Syndicated from Robin Cottiss original https://aws.amazon.com/blogs/big-data/tableau-10-4-supports-amazon-redshift-spectrum-with-external-amazon-s3-tables/

This is a guest post by Robin Cottiss, strategic customer consultant, Russell Christopher, staff product manager, and Vaidy Krishnan, senior manager of product marketing, at Tableau. Tableau, in their own words, “helps anyone quickly analyze, visualize, and share information. More than 61,000 customer accounts get rapid results with Tableau in the office and on the go. Over 300,000 people use Tableau Public to share public data in their blogs and websites.”

We’re excited to announce today an update to our Amazon Redshift connector with support for Amazon Redshift Spectrum to analyze data in external Amazon S3 tables. This feature, the direct result of joint engineering and testing work performed by the teams at Tableau and AWS, was released as part of Tableau 10.3.3 and will be available broadly in Tableau 10.4.1. With this update, you can quickly and directly connect Tableau to data in Amazon Redshift and analyze it in conjunction with data in Amazon S3—all with drag-and-drop ease.

This connector is yet another in a series of market-leading integrations of Tableau with AWS’s analytics platform, with services such as Amazon Redshift, Amazon EMR, and Amazon Athena. These integrations have allowed Tableau to become the natural choice of tool for analyzing data stored on AWS. Beyond this, Tableau Server runs seamlessly in the AWS Cloud infrastructure. If you prefer to deploy all your applications inside AWS, you have a complete solution offering from Tableau.

How does support for Amazon Redshift Spectrum help you?

If you’re like many Tableau customers, you have large buckets of data stored in Amazon S3. You might need to access this data frequently and store it in a consistent, highly structured format. If so, you can provision it to a data warehouse like Amazon Redshift. You might also want to explore this S3 data on an ad hoc basis. For example, you might want to determine whether or not to provision the data, and where—options might be Hadoop, Impala, Amazon EMR, or Amazon Redshift. To do so, you can use Amazon Athena, a serverless interactive query service from AWS that requires no infrastructure setup and management.

But what if you want to analyze both the frequently accessed data stored locally in Amazon Redshift AND your full datasets stored cost-effectively in Amazon S3? What if you want the throughput of disk and sophisticated query optimization of Amazon Redshift AND a service that combines a serverless scale-out processing capability with the massively reliable and scalable S3 infrastructure? What if you want the super-fast performance of Amazon Redshift AND support for open storage formats (for example, Parquet or ORC) in S3?

To enable these AND and resolve the tyranny of ORs, AWS launched Amazon Redshift Spectrum earlier this year.

Amazon Redshift Spectrum gives you the freedom to store your data where you want, in the format you want, and have it available for processing when you need it. Since the Amazon Redshift Spectrum launch, Tableau has worked tirelessly to provide best-in-class support for this new service. With Tableau and Redshift Spectrum, you can extend your Amazon Redshift analyses out to the entire universe of data in your S3 data lakes.

This latest update has been tested by many customers with very positive feedback. One such customer is the world’s largest food product distributor, Sysco—you can watch their session referencing the Amazon Spectrum integration at Tableau Conference 2017. Sysco also plans to reprise its “Tableau on AWS” story again in a month’s time at AWS re:Invent.

Now, I’d like to use a concrete example to demonstrate how Tableau works with Amazon Redshift Spectrum. In this example, I also show you how and why you might want to connect to your AWS data in different ways.

The setup

I use the pipeline described following to ingest, process, and analyze data with Tableau on an AWS stack. The source data is the New York City Taxi dataset, which has 9 years’ worth of taxi rides activity (including pick-up and drop-off location, amount paid, payment type, and so on) captured in 1.2 billion records.

In this pipeline, this data lands in S3, is cleansed and partitioned by using Amazon EMR, and is then converted to a columnar Parquet format that is analytically optimized. You can point Tableau to the raw data in S3 by using Amazon Athena. You can also access the cleansed data with Tableau using Presto through your Amazon EMR cluster.

Why use Tableau this early in the pipeline? Because sometimes you want to understand what’s there and what questions are worth asking before you even start the analysis.

After you find out what those questions are and determine if this sort of analysis has long-term usefulness, you can automate and optimize that pipeline. You do this to add new data as soon as possible as it arrives, to get it to the processes and people that need it. You might also want to provision this data to a highly performant “hotter” layer (Amazon Redshift or Tableau Extract) for repeated access.

In the illustration preceding, S3 contains the raw denormalized ride data at the timestamp level of granularity. This S3 data is the fact table. Amazon Redshift has the time dimensions broken out by date, month, and year, and also has the taxi zone information.

Now imagine I want to know where and when taxi pickups happen on a certain date in a certain borough. With support for Amazon Redshift Spectrum, I can now join the S3 tables with the Amazon Redshift dimensions, as shown following.

I can next analyze the data in Tableau to produce a borough-by-borough view of New York City ride density on Christmas Day 2015.

Or I can hone in on just Manhattan and identify pickup hotspots, with ride charges way above the average!

With Amazon Redshift Spectrum, you now have a fast, cost-effective engine that minimizes data processed with dynamic partition pruning. You can further improve query performance by reducing the data scanned. You do this by partitioning and compressing data and by using a columnar format for storage.

At the end of the day, which engine you use behind Tableau is a function of what you want to optimize for. Some possible engines are Amazon Athena, Amazon Redshift, and Redshift Spectrum, or you can bring a subset of data into Tableau Extract. Factors in planning optimization include these:

  • Are you comfortable with the serverless cost model of Amazon Athena and potential full scans? Or do you prefer the advantages of no setup?
  • Do you want the throughput of local disk?
  • Effort and time of setup. Are you okay with the lead-time of an Amazon Redshift cluster setup, as opposed to just bringing everything into Tableau Extract?

To meet the many needs of our customers, Tableau’s approach is simple: It’s all about choice. The choice of how you want to connect to and analyze your data. Throughout the history of our product and into the future, we have and will continue to empower choice for customers.

For more on how to deal with choice, as you go about making architecture decisions for your enterprise, watch this big data strategy session my friend Robin Cottiss and I delivered at Tableau Conference 2017. This session includes several customer examples leveraging the Tableau on AWS platform, and also a run-through of the aforementioned demonstration.

If you’re curious to learn more about analyzing data with Tableau on Amazon Redshift we encourage you to check out the following resources:

Bringing Datacenter-Scale Hardware-Software Co-design to the Cloud with FireSim and Amazon EC2 F1 Instances

Post Syndicated from Mia Champion original https://aws.amazon.com/blogs/compute/bringing-datacenter-scale-hardware-software-co-design-to-the-cloud-with-firesim-and-amazon-ec2-f1-instances/

The recent addition of Xilinx FPGAs to AWS Cloud compute offerings is one way that AWS is enabling global growth in the areas of advanced analytics, deep learning and AI. The customized F1 servers use pooled accelerators, enabling interconnectivity of up to 8 FPGAs, each one including 64 GiB DDR4 ECC protected memory, with a dedicated PCIe x16 connection. That makes this a powerful engine with the capacity to process advanced analytical applications at scale, at a significantly faster rate. For example, AWS commercial partner Edico Genome is able to achieve an approximately 30X speedup in analyzing whole genome sequencing datasets using their DRAGEN platform powered with F1 instances.

While the availability of FPGA F1 compute on-demand provides clear accessibility and cost advantages, many mainstream users are still finding that the “threshold to entry” in developing or running FPGA-accelerated simulations is too high. Researchers at the UC Berkeley RISE Lab have developed “FireSim”, powered by Amazon FPGA F1 instances as an open-source resource, FireSim lowers that entry bar and makes it easier for everyone to leverage the power of an FPGA-accelerated compute environment. Whether you are part of a small start-up development team or working at a large datacenter scale, hardware-software co-design enables faster time-to-deployment, lower costs, and more predictable performance. We are excited to feature FireSim in this post from Sagar Karandikar and his colleagues at UC-Berkeley.

―Mia Champion, Sr. Data Scientist, AWS

Mapping an 8-node FireSim cluster simulation to Amazon EC2 F1

As traditional hardware scaling nears its end, the data centers of tomorrow are trending towards heterogeneity, employing custom hardware accelerators and increasingly high-performance interconnects. Prototyping new hardware at scale has traditionally been either extremely expensive, or very slow. In this post, I introduce FireSim, a new hardware simulation platform under development in the computer architecture research group at UC Berkeley that enables fast, scalable hardware simulation using Amazon EC2 F1 instances.

FireSim benefits both hardware and software developers working on new rack-scale systems: software developers can use the simulated nodes with new hardware features as they would use a real machine, while hardware developers have full control over the hardware being simulated and can run real software stacks while hardware is still under development. In conjunction with this post, we’re releasing the first public demo of FireSim, which lets you deploy your own 8-node simulated cluster on an F1 Instance and run benchmarks against it. This demo simulates a pre-built “vanilla” cluster, but demonstrates FireSim’s high performance and usability.

Why FireSim + F1?

FPGA-accelerated hardware simulation is by no means a new concept. However, previous attempts to use FPGAs for simulation have been fraught with usability, scalability, and cost issues. FireSim takes advantage of EC2 F1 and open-source hardware to address the traditional problems with FPGA-accelerated simulation:
Problem #1: FPGA-based simulations have traditionally been expensive, difficult to deploy, and difficult to reproduce.
FireSim uses public-cloud infrastructure like F1, which means no upfront cost to purchase and deploy FPGAs. Developers and researchers can distribute pre-built AMIs and AFIs, as in this public demo (more details later in this post), to make experiments easy to reproduce. FireSim also automates most of the work involved in deploying an FPGA simulation, essentially enabling one-click conversion from new RTL to deploying on an FPGA cluster.

Problem #2: FPGA-based simulations have traditionally been difficult (and expensive) to scale.
Because FireSim uses F1, users can scale out experiments by spinning up additional EC2 instances, rather than spending hundreds of thousands of dollars on large FPGA clusters.

Problem #3: Finding open hardware to simulate has traditionally been difficult. Finding open hardware that can run real software stacks is even harder.
FireSim simulates RocketChip, an open, silicon-proven, RISC-V-based processor platform, and adds peripherals like a NIC and disk device to build up a realistic system. Processors that implement RISC-V automatically support real operating systems (such as Linux) and even support applications like Apache and Memcached. We provide a custom Buildroot-based FireSim Linux distribution that runs on our simulated nodes and includes many popular developer tools.

Problem #4: Writing hardware in traditional HDLs is time-consuming.
Both FireSim and RocketChip use the Chisel HDL, which brings modern programming paradigms to hardware description languages. Chisel greatly simplifies the process of building large, highly parameterized hardware components.

How to use FireSim for hardware/software co-design

FireSim drastically improves the process of co-designing hardware and software by acting as a push-button interface for collaboration between hardware developers and systems software developers. The following diagram describes the workflows that hardware and software developers use when working with FireSim.

Figure 2. The FireSim custom hardware development workflow.

The hardware developer’s view:

  1. Write custom RTL for your accelerator, peripheral, or processor modification in a productive language like Chisel.
  2. Run a software simulation of your hardware design in standard gate-level simulation tools for early-stage debugging.
  3. Run FireSim build scripts, which automatically build your simulation, run it through the Vivado toolchain/AWS shell scripts, and publish an AFI.
  4. Deploy your simulation on EC2 F1 using the generated simulation driver and AFI
  5. Run real software builds released by software developers to benchmark your hardware

The software developer’s view:

  1. Deploy the AMI/AFI generated by the hardware developer on an F1 instance to simulate a cluster of nodes (or scale out to many F1 nodes for larger simulated core-counts).
  2. Connect using SSH into the simulated nodes in the cluster and boot the Linux distribution included with FireSim. This distribution is easy to customize, and already supports many standard software packages.
  3. Directly prototype your software using the same exact interfaces that the software will see when deployed on the real future system you’re prototyping, with the same performance characteristics as observed from software, even at scale.

FireSim demo v1.0

Figure 3. Cluster topology simulated by FireSim demo v1.0.

This first public demo of FireSim focuses on the aforementioned “software-developer’s view” of the custom hardware development cycle. The demo simulates a cluster of 1 to 8 RocketChip-based nodes, interconnected by a functional network simulation. The simulated nodes work just like “real” machines:  they boot Linux, you can connect to them using SSH, and you can run real applications on top. The nodes can see each other (and the EC2 F1 instance on which they’re deployed) on the network and communicate with one another. While the demo currently simulates a pre-built “vanilla” cluster, the entire hardware configuration of these simulated nodes can be modified after FireSim is open-sourced.

In this post, I walk through bringing up a single-node FireSim simulation for experienced EC2 F1 users. For more detailed instructions for new users and instructions for running a larger 8-node simulation, see FireSim Demo v1.0 on Amazon EC2 F1. Both demos walk you through setting up an instance from a demo AMI/AFI and booting Linux on the simulated nodes. The full demo instructions also walk you through an example workload, running Memcached on the simulated nodes, with YCSB as a load generator to demonstrate network functionality.

Deploying the demo on F1

In this release, we provide pre-built binaries for driving simulation from the host and a pre-built AFI that contains the FPGA infrastructure necessary to simulate a RocketChip-based node.

Starting your F1 instances

First, launch an instance using the free FireSim Demo v1.0 product available on the AWS Marketplace on an f1.2xlarge instance. After your instance has booted, log in using the user name centos. On the first login, you should see the message “FireSim network config completed.” This sets up the necessary tap interfaces and bridge on the EC2 instance to enable communicating with the simulated nodes.

AMI contents

The AMI contains a variety of tools to help you run simulations and build software for RISC-V systems, including the riscv64 toolchain, a Buildroot-based Linux distribution that runs on the simulated nodes, and the simulation driver program. For more details, see the AMI Contents section on the FireSim website.

Single-node demo

First, you need to flash the FPGA with the FireSim AFI. To do so, run:

[[email protected]_ADDR ~]$ sudo fpga-load-local-image -S 0 -I agfi-00a74c2d615134b21

To start a simulation, run the following at the command line:

[[email protected]_ADDR ~]$ boot-firesim-singlenode

This automatically calls the simulation driver, telling it to load the Linux kernel image and root filesystem for the Linux distro. This produces output similar to the following:

Simulations Started. You can use the UART console of each simulated node by attaching to the following screens:

There is a screen on:

2492.fsim0      (Detached)

1 Socket in /var/run/screen/S-centos.

You could connect to the simulated UART console by connecting to this screen, but instead opt to use SSH to access the node instead.

First, ping the node to make sure it has come online. This is currently required because nodes may get stuck at Linux boot if the NIC does not receive any network traffic. For more information, see Troubleshooting/Errata. The node is always assigned the IP address 192.168.1.10:

[[email protected]_ADDR ~]$ ping 192.168.1.10

This should eventually produce the following output:

PING 192.168.1.10 (192.168.1.10) 56(84) bytes of data.

From 192.168.1.1 icmp_seq=1 Destination Host Unreachable

64 bytes from 192.168.1.10: icmp_seq=1 ttl=64 time=2017 ms

64 bytes from 192.168.1.10: icmp_seq=2 ttl=64 time=1018 ms

64 bytes from 192.168.1.10: icmp_seq=3 ttl=64 time=19.0 ms

At this point, you know that the simulated node is online. You can connect to it using SSH with the user name root and password firesim. It is also convenient to make sure that your TERM variable is set correctly. In this case, the simulation expects TERM=linux, so provide that:

[[email protected]_ADDR ~]$ TERM=linux ssh [email protected]

The authenticity of host ‘192.168.1.10 (192.168.1.10)’ can’t be established.

ECDSA key fingerprint is 63:e9:66:d0:5c:06:2c:1d:5c:95:33:c8:36:92:30:49.

Are you sure you want to continue connecting (yes/no)? yes

Warning: Permanently added ‘192.168.1.10’ (ECDSA) to the list of known hosts.

[email protected]’s password:

#

At this point, you’re connected to the simulated node. Run uname -a as an example. You should see the following output, indicating that you’re connected to a RISC-V system:

# uname -a

Linux buildroot 4.12.0-rc2 #1 Fri Aug 4 03:44:55 UTC 2017 riscv64 GNU/Linux

Now you can run programs on the simulated node, as you would with a real machine. For an example workload (running YCSB against Memcached on the simulated node) or to run a larger 8-node simulation, see the full FireSim Demo v1.0 on Amazon EC2 F1 demo instructions.

Finally, when you are finished, you can shut down the simulated node by running the following command from within the simulated node:

# poweroff

You can confirm that the simulation has ended by running screen -ls, which should now report that there are no detached screens.

Future plans

At Berkeley, we’re planning to keep improving the FireSim platform to enable our own research in future data center architectures, like FireBox. The FireSim platform will eventually support more sophisticated processors, custom accelerators (such as Hwacha), network models, and peripherals, in addition to scaling to larger numbers of FPGAs. In the future, we’ll open source the entire platform, including Midas, the tool used to transform RTL into FPGA simulators, allowing users to modify any part of the hardware/software stack. Follow @firesimproject on Twitter to stay tuned to future FireSim updates.

Acknowledgements

FireSim is the joint work of many students and faculty at Berkeley: Sagar Karandikar, Donggyu Kim, Howard Mao, David Biancolin, Jack Koenig, Jonathan Bachrach, and Krste Asanović. This work is partially funded by AWS through the RISE Lab, by the Intel Science and Technology Center for Agile HW Design, and by ASPIRE Lab sponsors and affiliates Intel, Google, HPE, Huawei, NVIDIA, and SK hynix.

Linux Foundation debuts Community Data License Agreement

Post Syndicated from jake original https://lwn.net/Articles/737212/rss

The Linux Foundation has announced a pair of licenses for data that are modeled on the two broad categories of free-software licenses: permissive and copyleft. The Community Data License Agreement (CDLA) comes in two flavors: Sharing that “encourages contributions of data back to the data community” and Permissive that allows the data to be used without any further requirements.

Inspired by the collaborative software development models of open source software, the CDLA licenses are designed to enable individuals and organizations of all types to share data as easily as they currently share open source software code. Soundly drafted licensing models can help people form communities to assemble, curate and maintain vast amounts of data, measured in petabytes and exabytes, to bring new value to communities of all types, to build new business opportunities and to power new applications that promise to enhance safety and services.
The growth of big data analytics, machine learning and artificial intelligence (AI) technologies has allowed people to extract unprecedented levels of insight from data. Now the challenge is to assemble the critical mass of data for those tools to analyze. The CDLA licenses are designed to help governments, academic institutions, businesses and other organizations open up and share data, with the goal of creating communities that curate and share data openly.

Federate Database User Authentication Easily with IAM and Amazon Redshift

Post Syndicated from Thiyagarajan Arumugam original https://aws.amazon.com/blogs/big-data/federate-database-user-authentication-easily-with-iam-and-amazon-redshift/

Managing database users though federation allows you to manage authentication and authorization procedures centrally. Amazon Redshift now supports database authentication with IAM, enabling user authentication though enterprise federation. No need to manage separate database users and passwords to further ease the database administration. You can now manage users outside of AWS and authenticate them for access to an Amazon Redshift data warehouse. Do this by integrating IAM authentication and a third-party SAML-2.0 identity provider (IdP), such as AD FS, PingFederate, or Okta. In addition, database users can also be automatically created at their first login based on corporate permissions.

In this post, I demonstrate how you can extend the federation to enable single sign-on (SSO) to the Amazon Redshift data warehouse.

SAML and Amazon Redshift

AWS supports Security Assertion Markup Language (SAML) 2.0, which is an open standard for identity federation used by many IdPs. SAML enables federated SSO, which enables your users to sign in to the AWS Management Console. Users can also make programmatic calls to AWS API actions by using assertions from a SAML-compliant IdP. For example, if you use Microsoft Active Directory for corporate directories, you may be familiar with how Active Directory and AD FS work together to enable federation. For more information, see the Enabling Federation to AWS Using Windows Active Directory, AD FS, and SAML 2.0 AWS Security Blog post.

Amazon Redshift now provides the GetClusterCredentials API operation that allows you to generate temporary database user credentials for authentication. You can set up an IAM permissions policy that generates these credentials for connecting to Amazon Redshift. Extending the IAM authentication, you can configure the federation of AWS access though a SAML 2.0–compliant IdP. An IAM role can be configured to permit the federated users call the GetClusterCredentials action and generate temporary credentials to log in to Amazon Redshift databases. You can also set up policies to restrict access to Amazon Redshift clusters, databases, database user names, and user group.

Amazon Redshift federation workflow

In this post, I demonstrate how you can use a JDBC– or ODBC-based SQL client to log in to the Amazon Redshift cluster using this feature. The SQL clients used with Amazon Redshift JDBC or ODBC drivers automatically manage the process of calling the GetClusterCredentials action, retrieving the database user credentials, and establishing a connection to your Amazon Redshift database. You can also use your database application to programmatically call the GetClusterCredentials action, retrieve database user credentials, and connect to the database. I demonstrate these features using an example company to show how different database users accounts can be managed easily using federation.

The following diagram shows how the SSO process works:

  1. JDBC/ODBC
  2. Authenticate using Corp Username/Password
  3. IdP sends SAML assertion
  4. Call STS to assume role with SAML
  5. STS Returns Temp Credentials
  6. Use Temp Credentials to get Temp cluster credentials
  7. Connect to Amazon Redshift using temp credentials

Walkthrough

Example Corp. is using Active Directory (idp host:demo.examplecorp.com) to manage federated access for users in its organization. It has an AWS account: 123456789012 and currently manages an Amazon Redshift cluster with the cluster ID “examplecorp-dw”, database “analytics” in us-west-2 region for its Sales and Data Science teams. It wants the following access:

  • Sales users can access the examplecorp-dw cluster using the sales_grp database group
  • Sales users access examplecorp-dw through a JDBC-based SQL client
  • Sales users access examplecorp-dw through an ODBC connection, for their reporting tools
  • Data Science users access the examplecorp-dw cluster using the data_science_grp database group.
  • Partners access the examplecorp-dw cluster and query using the partner_grp database group.
  • Partners are not federated through Active Directory and are provided with separate IAM user credentials (with IAM user name examplecorpsalespartner).
  • Partners can connect to the examplecorp-dw cluster programmatically, using language such as Python.
  • All users are automatically created in Amazon Redshift when they log in for the first time.
  • (Optional) Internal users do not specify database user or group information in their connection string. It is automatically assigned.
  • Data warehouse users can use SSO for the Amazon Redshift data warehouse using the preceding permissions.

Step 1:  Set up IdPs and federation

The Enabling Federation to AWS Using Windows Active Directory post demonstrated how to prepare Active Directory and enable federation to AWS. Using those instructions, you can establish trust between your AWS account and the IdP and enable user access to AWS using SSO.  For more information, see Identity Providers and Federation.

For this walkthrough, assume that this company has already configured SSO to their AWS account: 123456789012 for their Active Directory domain demo.examplecorp.com. The Sales and Data Science teams are not required to specify database user and group information in the connection string. The connection string can be configured by adding SAML Attribute elements to your IdP. Configuring these optional attributes enables internal users to conveniently avoid providing the DbUser and DbGroup parameters when they log in to Amazon Redshift.

The user-name attribute can be set up as follows, with a user ID (for example, nancy) or an email address (for example. [email protected]):

<Attribute Name="https://redshift.amazon.com/SAML/Attributes/DbUser">  
  <AttributeValue>user-name</AttributeValue>
</Attribute>

The AutoCreate attribute can be defined as follows:

<Attribute Name="https://redshift.amazon.com/SAML/Attributes/AutoCreate">
    <AttributeValue>true</AttributeValue>
</Attribute>

The sales_grp database group can be included as follows:

<Attribute Name="https://redshift.amazon.com/SAML/Attributes/DbGroups">
    <AttributeValue>sales_grp</AttributeValue>
</Attribute>

For more information about attribute element configuration, see Configure SAML Assertions for Your IdP.

Step 2: Create IAM roles for access to the Amazon Redshift cluster

The next step is to create IAM policies with permissions to call GetClusterCredentials and provide authorization for Amazon Redshift resources. To grant a SQL client the ability to retrieve the cluster endpoint, region, and port automatically, include the redshift:DescribeClusters action with the Amazon Redshift cluster resource in the IAM role.  For example, users can connect to the Amazon Redshift cluster using a JDBC URL without the need to hardcode the Amazon Redshift endpoint:

Previous:  jdbc:redshift://endpoint:port/database

Current:  jdbc:redshift:iam://clustername:region/dbname

Use IAM to create the following policies. You can also use an existing user or role and assign these policies. For example, if you already created an IAM role for IdP access, you can attach the necessary policies to that role. Here is the policy created for sales users for this example:

Sales_DW_IAM_Policy

{
    "Version": "2012-10-17",
    "Statement": [
        {
            "Effect": "Allow",
            "Action": [
                "redshift:DescribeClusters"
            ],
            "Resource": [
                "arn:aws:redshift:us-west-2:123456789012:cluster:examplecorp-dw"
            ]
        },
        {
            "Effect": "Allow",
            "Action": [
                "redshift:GetClusterCredentials"
            ],
            "Resource": [
                "arn:aws:redshift:us-west-2:123456789012:cluster:examplecorp-dw",
                "arn:aws:redshift:us-west-2:123456789012:dbuser:examplecorp-dw/${redshift:DbUser}"
            ],
            "Condition": {
                "StringEquals": {
                    "aws:userid": "AIDIODR4TAW7CSEXAMPLE:${redshift:DbUser}@examplecorp.com"
                }
            }
        },
        {
            "Effect": "Allow",
            "Action": [
                "redshift:CreateClusterUser"
            ],
            "Resource": [
                "arn:aws:redshift:us-west-2:123456789012:dbuser:examplecorp-dw/${redshift:DbUser}"
            ]
        },
        {
            "Effect": "Allow",
            "Action": [
                "redshift:JoinGroup"
            ],
            "Resource": [
                "arn:aws:redshift:us-west-2:123456789012:dbgroup:examplecorp-dw/sales_grp"
            ]
        }
    ]
}

The policy uses the following parameter values:

  • Region: us-west-2
  • AWS Account: 123456789012
  • Cluster name: examplecorp-dw
  • Database group: sales_grp
  • IAM role: AIDIODR4TAW7CSEXAMPLE
Policy Statement Description
{
"Effect":"Allow",
"Action":[
"redshift:DescribeClusters"
],
"Resource":[
"arn:aws:redshift:us-west-2:123456789012:cluster:examplecorp-dw"
]
}

Allow users to retrieve the cluster endpoint, region, and port automatically for the Amazon Redshift cluster examplecorp-dw. This specification uses the resource format arn:aws:redshift:region:account-id:cluster:clustername. For example, the SQL client JDBC can be specified in the format jdbc:redshift:iam://clustername:region/dbname.

For more information, see Amazon Resource Names.

{
"Effect":"Allow",
"Action":[
"redshift:GetClusterCredentials"
],
"Resource":[
"arn:aws:redshift:us-west-2:123456789012:cluster:examplecorp-dw",
"arn:aws:redshift:us-west-2:123456789012:dbuser:examplecorp-dw/${redshift:DbUser}"
],
"Condition":{
"StringEquals":{
"aws:userid":"AIDIODR4TAW7CSEXAMPLE:${redshift:DbUser}@examplecorp.com"
}
}
}

Generates a temporary token to authenticate into the examplecorp-dw cluster. “arn:aws:redshift:us-west-2:123456789012:dbuser:examplecorp-dw/${redshift:DbUser}” restricts the corporate user name to the database user name for that user. This resource is specified using the format: arn:aws:redshift:region:account-id:dbuser:clustername/dbusername.

The Condition block enforces that the AWS user ID should match “AIDIODR4TAW7CSEXAMPLE:${redshift:DbUser}@examplecorp.com”, so that individual users can authenticate only as themselves. The AIDIODR4TAW7CSEXAMPLE role has the Sales_DW_IAM_Policy policy attached.

{
"Effect":"Allow",
"Action":[
"redshift:CreateClusterUser"
],
"Resource":[
"arn:aws:redshift:us-west-2:123456789012:dbuser:examplecorp-dw/${redshift:DbUser}"
]
}
Automatically creates database users in examplecorp-dw, when they log in for the first time. Subsequent logins reuse the existing database user.
{
"Effect":"Allow",
"Action":[
"redshift:JoinGroup"
],
"Resource":[
"arn:aws:redshift:us-west-2:123456789012:dbgroup:examplecorp-dw/sales_grp"
]
}
Allows sales users to join the sales_grp database group through the resource “arn:aws:redshift:us-west-2:123456789012:dbgroup:examplecorp-dw/sales_grp” that is specified in the format arn:aws:redshift:region:account-id:dbgroup:clustername/dbgroupname.

Similar policies can be created for Data Science users with access to join the data_science_grp group in examplecorp-dw. You can now attach the Sales_DW_IAM_Policy policy to the role that is mapped to IdP application for SSO.
 For more information about how to define the claim rules, see Configuring SAML Assertions for the Authentication Response.

Because partners are not authorized using Active Directory, they are provided with IAM credentials and added to the partner_grp database group. The Partner_DW_IAM_Policy is attached to the IAM users for partners. The following policy allows partners to log in using the IAM user name as the database user name.

Partner_DW_IAM_Policy

{
    "Version": "2012-10-17",
    "Statement": [
        {
            "Effect": "Allow",
            "Action": [
                "redshift:DescribeClusters"
            ],
            "Resource": [
                "arn:aws:redshift:us-west-2:123456789012:cluster:examplecorp-dw"
            ]
        },
        {
            "Effect": "Allow",
            "Action": [
                "redshift:GetClusterCredentials"
            ],
            "Resource": [
                "arn:aws:redshift:us-west-2:123456789012:cluster:examplecorp-dw",
                "arn:aws:redshift:us-west-2:123456789012:dbuser:examplecorp-dw/${redshift:DbUser}"
            ],
            "Condition": {
                "StringEquals": {
                    "redshift:DbUser": "${aws:username}"
                }
            }
        },
        {
            "Effect": "Allow",
            "Action": [
                "redshift:CreateClusterUser"
            ],
            "Resource": [
                "arn:aws:redshift:us-west-2:123456789012:dbuser:examplecorp-dw/${redshift:DbUser}"
            ]
        },
        {
            "Effect": "Allow",
            "Action": [
                "redshift:JoinGroup"
            ],
            "Resource": [
                "arn:aws:redshift:us-west-2:123456789012:dbgroup:examplecorp-dw/partner_grp"
            ]
        }
    ]
}

redshift:DbUser“: “${aws:username}” forces an IAM user to use the IAM user name as the database user name.

With the previous steps configured, you can now establish the connection to Amazon Redshift through JDBC– or ODBC-supported clients.

Step 3: Set up database user access

Before you start connecting to Amazon Redshift using the SQL client, set up the database groups for appropriate data access. Log in to your Amazon Redshift database as superuser to create a database group, using CREATE GROUP.

Log in to examplecorp-dw/analytics as superuser and create the following groups and users:

CREATE GROUP sales_grp;
CREATE GROUP datascience_grp;
CREATE GROUP partner_grp;

Use the GRANT command to define access permissions to database objects (tables/views) for the preceding groups.

Step 4: Connect to Amazon Redshift using the JDBC SQL client

Assume that sales user “nancy” is using the SQL Workbench client and JDBC driver to log in to the Amazon Redshift data warehouse. The following steps help set up the client and establish the connection:

  1. Download the latest Amazon Redshift JDBC driver from the Configure a JDBC Connection page
  2. Build the JDBC URL with the IAM option in the following format:
    jdbc:redshift:iam://examplecorp-dw:us-west-2/sales_db

Because the redshift:DescribeClusters action is assigned to the preceding IAM roles, it automatically resolves the cluster endpoints and the port. Otherwise, you can specify the endpoint and port information in the JDBC URL, as described in Configure a JDBC Connection.

Identify the following JDBC options for providing the IAM credentials (see the “Prepare your environment” section) and configure in the SQL Workbench Connection Profile:

plugin_name=com.amazon.redshift.plugin.AdfsCredentialsProvider 
idp_host=demo.examplecorp.com (The name of the corporate identity provider host)
idp_port=443  (The port of the corporate identity provider host)
user=examplecorp\nancy(corporate user name)
password=***(corporate user password)

The SQL workbench configuration looks similar to the following screenshot:

Now, “nancy” can connect to examplecorp-dw by authenticating using the corporate Active Directory. Because the SAML attributes elements are already configured for nancy, she logs in as database user nancy and is assigned the sales_grp. Similarly, other Sales and Data Science users can connect to the examplecorp-dw cluster. A custom Amazon Redshift ODBC driver can also be used to connect using a SQL client. For more information, see Configure an ODBC Connection.

Step 5: Connecting to Amazon Redshift using JDBC SQL Client and IAM Credentials

This optional step is necessary only when you want to enable users that are not authenticated with Active Directory. Partners are provided with IAM credentials that they can use to connect to the examplecorp-dw Amazon Redshift clusters. These IAM users are attached to Partner_DW_IAM_Policy that assigns them to be assigned to the public database group in Amazon Redshift. The following JDBC URLs enable them to connect to the Amazon Redshift cluster:

jdbc:redshift:iam//examplecorp-dw/analytics?AccessKeyID=XXX&SecretAccessKey=YYY&DbUser=examplecorpsalespartner&DbGroup= partner_grp&AutoCreate=true

The AutoCreate option automatically creates a new database user the first time the partner logs in. There are several other options available to conveniently specify the IAM user credentials. For more information, see Options for providing IAM credentials.

Step 6: Connecting to Amazon Redshift using an ODBC client for Microsoft Windows

Assume that another sales user “uma” is using an ODBC-based client to log in to the Amazon Redshift data warehouse using Example Corp Active Directory. The following steps help set up the ODBC client and establish the Amazon Redshift connection in a Microsoft Windows operating system connected to your corporate network:

  1. Download and install the latest Amazon Redshift ODBC driver.
  2. Create a system DSN entry.
    1. In the Start menu, locate the driver folder or folders:
      • Amazon Redshift ODBC Driver (32-bit)
      • Amazon Redshift ODBC Driver (64-bit)
      • If you installed both drivers, you have a folder for each driver.
    2. Choose ODBC Administrator, and then type your administrator credentials.
    3. To configure the driver for all users on the computer, choose System DSN. To configure the driver for your user account only, choose User DSN.
    4. Choose Add.
  3. Select the Amazon Redshift ODBC driver, and choose Finish. Configure the following attributes:
    Data Source Name =any friendly name to identify the ODBC connection 
    Database=analytics
    user=uma(corporate user name)
    Auth Type-Identity Provider: AD FS
    password=leave blank (Windows automatically authenticates)
    Cluster ID: examplecorp-dw
    idp_host=demo.examplecorp.com (The name of the corporate IdP host)

This configuration looks like the following:

  1. Choose OK to save the ODBC connection.
  2. Verify that uma is set up with the SAML attributes, as described in the “Set up IdPs and federation” section.

The user uma can now use this ODBC connection to establish the connection to the Amazon Redshift cluster using any ODBC-based tools or reporting tools such as Tableau. Internally, uma authenticates using the Sales_DW_IAM_Policy  IAM role and is assigned the sales_grp database group.

Step 7: Connecting to Amazon Redshift using Python and IAM credentials

To enable partners, connect to the examplecorp-dw cluster programmatically, using Python on a computer such as Amazon EC2 instance. Reuse the IAM users that are attached to the Partner_DW_IAM_Policy policy defined in Step 2.

The following steps show this set up on an EC2 instance:

  1. Launch a new EC2 instance with the Partner_DW_IAM_Policy role, as described in Using an IAM Role to Grant Permissions to Applications Running on Amazon EC2 Instances. Alternatively, you can attach an existing IAM role to an EC2 instance.
  2. This example uses Python PostgreSQL Driver (PyGreSQL) to connect to your Amazon Redshift clusters. To install PyGreSQL on Amazon Linux, use the following command as the ec2-user:
    sudo easy_install pip
    sudo yum install postgresql postgresql-devel gcc python-devel
    sudo pip install PyGreSQL

  1. The following code snippet demonstrates programmatic access to Amazon Redshift for partner users:
    #!/usr/bin/env python
    """
    Usage:
    python redshift-unload-copy.py <config file> <region>
    
    * Copyright 2014, Amazon.com, Inc. or its affiliates. All Rights Reserved.
    *
    * Licensed under the Amazon Software License (the "License").
    * You may not use this file except in compliance with the License.
    * A copy of the License is located at
    *
    * http://aws.amazon.com/asl/
    *
    * or in the "license" file accompanying this file. This file is distributed
    * on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either
    * express or implied. See the License for the specific language governing
    * permissions and limitations under the License.
    """
    
    import sys
    import pg
    import boto3
    
    REGION = 'us-west-2'
    CLUSTER_IDENTIFIER = 'examplecorp-dw'
    DB_NAME = 'sales_db'
    DB_USER = 'examplecorpsalespartner'
    
    options = """keepalives=1 keepalives_idle=200 keepalives_interval=200
                 keepalives_count=6"""
    
    set_timeout_stmt = "set statement_timeout = 1200000"
    
    def conn_to_rs(host, port, db, usr, pwd, opt=options, timeout=set_timeout_stmt):
        rs_conn_string = """host=%s port=%s dbname=%s user=%s password=%s
                             %s""" % (host, port, db, usr, pwd, opt)
        print "Connecting to %s:%s:%s as %s" % (host, port, db, usr)
        rs_conn = pg.connect(dbname=rs_conn_string)
        rs_conn.query(timeout)
        return rs_conn
    
    def main():
        # describe the cluster and fetch the IAM temporary credentials
        global redshift_client
        redshift_client = boto3.client('redshift', region_name=REGION)
        response_cluster_details = redshift_client.describe_clusters(ClusterIdentifier=CLUSTER_IDENTIFIER)
        response_credentials = redshift_client.get_cluster_credentials(DbUser=DB_USER,DbName=DB_NAME,ClusterIdentifier=CLUSTER_IDENTIFIER,DurationSeconds=3600)
        rs_host = response_cluster_details['Clusters'][0]['Endpoint']['Address']
        rs_port = response_cluster_details['Clusters'][0]['Endpoint']['Port']
        rs_db = DB_NAME
        rs_iam_user = response_credentials['DbUser']
        rs_iam_pwd = response_credentials['DbPassword']
        # connect to the Amazon Redshift cluster
        conn = conn_to_rs(rs_host, rs_port, rs_db, rs_iam_user,rs_iam_pwd)
        # execute a query
        result = conn.query("SELECT sysdate as dt")
        # fetch results from the query
        for dt_val in result.getresult() :
            print dt_val
        # close the Amazon Redshift connection
        conn.close()
    
    if __name__ == "__main__":
        main()

You can save this Python program in a file (redshiftscript.py) and execute it at the command line as ec2-user:

python redshiftscript.py

Now partners can connect to the Amazon Redshift cluster using the Python script, and authentication is federated through the IAM user.

Summary

In this post, I demonstrated how to use federated access using Active Directory and IAM roles to enable single sign-on to an Amazon Redshift cluster. I also showed how partners outside an organization can be managed easily using IAM credentials.  Using the GetClusterCredentials API action, now supported by Amazon Redshift, lets you manage a large number of database users and have them use corporate credentials to log in. You don’t have to maintain separate database user accounts.

Although this post demonstrated the integration of IAM with AD FS and Active Directory, you can replicate this solution across with your choice of SAML 2.0 third-party identity providers (IdP), such as PingFederate or Okta. For the different supported federation options, see Configure SAML Assertions for Your IdP.

If you have questions or suggestions, please comment below.


Additional Reading

Learn how to establish federated access to your AWS resources by using Active Directory user attributes.


About the Author

Thiyagarajan Arumugam is a Big Data Solutions Architect at Amazon Web Services and designs customer architectures to process data at scale. Prior to AWS, he built data warehouse solutions at Amazon.com. In his free time, he enjoys all outdoor sports and practices the Indian classical drum mridangam.

 

Getting Ready for AWS re:Invent 2017

Post Syndicated from Jeff Barr original https://aws.amazon.com/blogs/aws/getting-ready-for-aws-reinvent-2017/

With just 40 days remaining before AWS re:Invent begins, my colleagues and I want to share some tips that will help you to make the most of your time in Las Vegas. As always, our focus is on training and education, mixed in with some after-hours fun and recreation for balance.

Locations, Locations, Locations
The re:Invent Campus will span the length of the Las Vegas strip, with events taking place at the MGM Grand, Aria, Mirage, Venetian, Palazzo, the Sands Expo Hall, the Linq Lot, and the Encore. Each venue will host tracks devoted to specific topics:

MGM Grand – Business Apps, Enterprise, Security, Compliance, Identity, Windows.

Aria – Analytics & Big Data, Alexa, Container, IoT, AI & Machine Learning, and Serverless.

Mirage – Bootcamps, Certifications & Certification Exams.

Venetian / Palazzo / Sands Expo Hall – Architecture, AWS Marketplace & Service Catalog, Compute, Content Delivery, Database, DevOps, Mobile, Networking, and Storage.

Linq Lot – Alexa Hackathons, Gameday, Jam Sessions, re:Play Party, Speaker Meet & Greets.

EncoreBookable meeting space.

If your interests span more than one topic, plan to take advantage of the re:Invent shuttles that will be making the rounds between the venues.

Lots of Content
The re:Invent Session Catalog is now live and you should start to choose the sessions of interest to you now.

With more than 1100 sessions on the agenda, planning is essential! Some of the most popular “deep dive” sessions will be run more than once and others will be streamed to overflow rooms at other venues. We’ve analyzed a lot of data, run some simulations, and are doing our best to provide you with multiple opportunities to build an action-packed schedule.

We’re just about ready to let you reserve seats for your sessions (follow me and/or @awscloud on Twitter for a heads-up). Based on feedback from earlier years, we have fine-tuned our seat reservation model. This year, 75% of the seats for each session will be reserved and the other 25% are for walk-up attendees. We’ll start to admit walk-in attendees 10 minutes before the start of the session.

Las Vegas never sleeps and neither should you! This year we have a host of late-night sessions, workshops, chalk talks, and hands-on labs to keep you busy after dark.

To learn more about our plans for sessions and content, watch the Get Ready for re:Invent 2017 Content Overview video.

Have Fun
After you’ve had enough training and learning for the day, plan to attend the Pub Crawl, the re:Play party, the Tatonka Challenge (two locations this year), our Hands-On LEGO Activities, and the Harley Ride. Stay fit with our 4K Run, Spinning Challenge, Fitness Bootcamps, and Broomball (a longstanding Amazon tradition).

See You in Vegas
As always, I am looking forward to meeting as many AWS users and blog readers as possible. Never hesitate to stop me and to say hello!

Jeff;

 

 

What’s new in HiveMQ 3.3

Post Syndicated from The HiveMQ Team original https://www.hivemq.com/whats-new-in-hivemq-3-3

We are pleased to announce the release of HiveMQ 3.3. This version of HiveMQ is the most advanced and user friendly version of HiveMQ ever. A broker is the heart of every MQTT deployment and it’s key to monitor and understand how healthy your system and your connected clients are. Version 3.3 of HiveMQ focuses on observability, usability and advanced administration features and introduces a brand new Web UI. This version is a drop-in replacement for HiveMQ 3.2 and of course supports rolling upgrades for zero-downtime.

HiveMQ 3.3 brings many features that your users, administrators and plugin developers are going to love. These are the highlights:

Web UI

Web UI
The new HiveMQ version has a built-in Web UI for advanced analysis and administrative tasks. A powerful dashboard shows important data about the health of the broker cluster and an overview of the whole MQTT deployment.
With the new Web UI, administrators are able to drill down to specific client information and can perform administrative actions like disconnecting a client. Advanced analytics functionality allows indetifying clients with irregular behavior. It’s easy to identify message-dropping clients as HiveMQ shows detailed statistics of such misbehaving MQTT participants.
Of course all Web UI features work at scale with more than a million connected MQTT clients. Learn more about the Web UI in the documentation.

Time To Live

TTL
HiveMQ introduces Time to Live (TTL) on various levels of the MQTT lifecycle. Automatic cleanup of expired messages is as well supported as the wiping of abandoned persistent MQTT sessions. In particular, version 3.3 implements the following TTL features:

  • MQTT client session expiration
  • Retained Message expiration
  • MQTT PUBLISH message expiration

Configuring a TTL for MQTT client sessions and retained messages allows freeing system resources without manual administrative intervention as soon as the data is not needed anymore.
Beside global configuration, MQTT PUBLISHES can have individual TTLs based on application specific characteristics. It’s a breeze to change the TTL of particular messages with the HiveMQ plugin system. As soon as a message TTL expires, the broker won’t send out the message anymore, even if the message was previously queued or in-flight. This can save precious bandwidth for mobile connections as unnecessary traffic is avoided for expired messages.

Trace Recordings

Trace Recordings
Debugging specific MQTT clients or groups of MQTT clients can be challenging at scale. HiveMQ 3.3 introduces an innovative Trace Recording mechanism that allows creating detailed recordings of all client interactions with given filters.
It’s possible to filter based on client identifiers, MQTT message types and topics. And the best of all: You can use regular expressions to select multiple MQTT clients at once as well as topics with complex structures. Getting detailed information about the behavior of specific MQTT clients for debugging complex issues was never easier.

Native SSL

Native SSL
The new native SSL integration of HiveMQ brings a performance boost of more than 40% for SSL Handshakes (in terms of CPU usage) by utilizing an integration with BoringSSL. BoringSSL is Google’s fork of OpenSSL which is also used in Google Chrome and Android. Besides the compute and huge memory optimizations (saves up to 60% Java Heap), additional secure state-of-the-art cipher suites are supported by HiveMQ which are not directly available for Java (like ChaCha20-Poly1305).
Most HiveMQ deployments on Linux systems are expected to see decreased CPU load on TLS handshakes with the native SSL integration and huge memory improvements.

New Plugin System Features

New Plugin System Features
The popular and powerful plugin system has received additional services and callbacks which are useful for many existing and future plugins.
Plugin developers can now use a ConnectionAttributeStore and a SessionAttributeStore for storing arbitrary data for the lifetime of a single MQTT connection of a client or for the whole session of a client. The new ClientGroupService allows grouping different MQTT client identifiers by the same key, so it’s easy to address multiple MQTT clients (with the same group) at once.

A new callback was introduced which notifies a plugin when a HiveMQ instance is ready, which means the instance is part of the cluster and all listeners were started successfully. Developers can now react when a MQTT client session is ready and usable in the cluster with a dedicated callback.

Some use cases require modifying a MQTT PUBLISH packet before it’s sent out to a client. This is now possible with a new callback that was introduced for modifying a PUBLISH before sending it out to a individual client.
The offline queue size for persistent clients is now also configurable for individual clients as well as the queue discard strategy.

Additional Features

Additional Features
HiveMQ 3.3 has many additional features designed for power users and professional MQTT deployments. The new version also has the following highlights:

  • OCSP Stapling
  • Event Log for MQTT client connects, disconnects and unusual events (e.g. discarded message due to slow consumption on the client side
  • Throttling of concurrent TLS handshakes
  • Connect Packet overload protection
  • Configuration of Socket send and receive buffer sizes
  • Global System Information like the HiveMQ Home folder can now be set via Environment Variables without changing the run script
  • The internal HTTP server of HiveMQ is now exposed to the holistic monitoring subsystem
  • Many additional useful metrics were exposed to HiveMQ’s monitoring subsystem

 

In order to upgrade to HiveMQ 3.3 from HiveMQ 3.2 or older versions, take a look at our Upgrade Guide.
Don’t forget to learn more about all the new features with our HiveMQ User Guide.

Download HiveMQ 3.3 now

Amazon Redshift Dense Compute (DC2) Nodes Deliver Twice the Performance as DC1 at the Same Price

Post Syndicated from Quaseer Mujawar original https://aws.amazon.com/blogs/big-data/amazon-redshift-dense-compute-dc2-nodes-deliver-twice-the-performance-as-dc1-at-the-same-price/

Amazon Redshift makes analyzing exabyte-scale data fast, simple, and cost-effective. It delivers advanced data warehousing capabilities, including parallel execution, compressed columnar storage, and end-to-end encryption as a fully managed service, for less than $1,000/TB/year. With Amazon Redshift Spectrum, you can run SQL queries directly against exabytes of unstructured data in Amazon S3 for $5/TB scanned.

Today, we are making our Dense Compute (DC) family faster and more cost-effective with new second-generation Dense Compute (DC2) nodes at the same price as our previous generation DC1. DC2 is designed for demanding data warehousing workloads that require low latency and high throughput. DC2 features powerful Intel E5-2686 v4 (Broadwell) CPUs, fast DDR4 memory, and NVMe-based solid state disks.

We’ve tuned Amazon Redshift to take advantage of the better CPU, network, and disk on DC2 nodes, providing up to twice the performance of DC1 at the same price. Our DC2.8xlarge instances now provide twice the memory per slice of data and an optimized storage layout with 30 percent better storage utilization.

Customer successes

Several flagship customers, ranging from fast growing startups to large Fortune 100 companies, previewed the new DC2 node type. In their tests, DC2 provided up to twice the performance as DC1. Our preview customers saw faster ETL (extract, transform, and load) jobs, higher query throughput, better concurrency, faster reports, and shorter data-to-insights—all at the same cost as DC1. DC2.8xlarge customers also noted that their databases used up to 30 percent less disk space due to our optimized storage format, reducing their costs.

4Cite Marketing, one of America’s fastest growing private companies, uses Amazon Redshift to analyze customer data and determine personalized product recommendations for retailers. “Amazon Redshift’s new DC2 node is giving us a 100 percent performance increase, allowing us to provide faster insights for our retailers, more cost-effectively, to drive incremental revenue,” said Jim Finnerty, 4Cite’s senior vice president of product.

BrandVerity, a Seattle-based brand protection and compliance‎ company, provides solutions to monitor, detect, and mitigate online brand, trademark, and compliance abuse. “We saw a 70 percent performance boost with the DC2 nodes for running Redshift Spectrum queries. As a result, we can analyze far more data for our customers and deliver results much faster,” said Hyung-Joon Kim, principal software engineer at BrandVerity.

“Amazon Redshift is at the core of our operations and our marketing automation tools,” said Jarno Kartela, head of analytics and chief data scientist at DNA Plc, one of the leading Finnish telecommunications groups and Finland’s largest cable operator and pay TV provider. “We saw a 52 percent performance gain in moving to Amazon Redshift’s DC2 nodes. We can now run queries in half the time, allowing us to provide more analytics power and reduce time-to-insight for our analytics and marketing automation users.”

You can read about their experiences on our Customer Success page.

Get started

You can try the new node type using our getting started guide. Just choose dc2.large or dc2.8xlarge in the Amazon Redshift console:

If you have a DC1.large Amazon Redshift cluster, you can restore to a new DC2.large cluster using an existing snapshot. To migrate from DS2.xlarge, DS2.8xlarge, or DC1.8xlarge Amazon Redshift clusters, you can use the resize operation to move data to your new DC2 cluster. For more information, see Clusters and Nodes in Amazon Redshift.

To get the latest Amazon Redshift feature announcements, check out our What’s New page, and subscribe to the RSS feed.

Predict Billboard Top 10 Hits Using RStudio, H2O and Amazon Athena

Post Syndicated from Gopal Wunnava original https://aws.amazon.com/blogs/big-data/predict-billboard-top-10-hits-using-rstudio-h2o-and-amazon-athena/

Success in the popular music industry is typically measured in terms of the number of Top 10 hits artists have to their credit. The music industry is a highly competitive multi-billion dollar business, and record labels incur various costs in exchange for a percentage of the profits from sales and concert tickets.

Predicting the success of an artist’s release in the popular music industry can be difficult. One release may be extremely popular, resulting in widespread play on TV, radio and social media, while another single may turn out quite unpopular, and therefore unprofitable. Record labels need to be selective in their decision making, and predictive analytics can help them with decision making around the type of songs and artists they need to promote.

In this walkthrough, you leverage H2O.ai, Amazon Athena, and RStudio to make predictions on whether a song might make it to the Top 10 Billboard charts. You explore the GLM, GBM, and deep learning modeling techniques using H2O’s rapid, distributed and easy-to-use open source parallel processing engine. RStudio is a popular IDE, licensed either commercially or under AGPLv3, for working with R. This is ideal if you don’t want to connect to a server via SSH and use code editors such as vi to do analytics. RStudio is available in a desktop version, or a server version that allows you to access R via a web browser. RStudio’s Notebooks feature is used to demonstrate the execution of code and output. In addition, this post showcases how you can leverage Athena for query and interactive analysis during the modeling phase. A working knowledge of statistics and machine learning would be helpful to interpret the analysis being performed in this post.

Walkthrough

Your goal is to predict whether a song will make it to the Top 10 Billboard charts. For this purpose, you will be using multiple modeling techniques―namely GLM, GBM and deep learning―and choose the model that is the best fit.

This solution involves the following steps:

  • Install and configure RStudio with Athena
  • Log in to RStudio
  • Install R packages
  • Connect to Athena
  • Create a dataset
  • Create models

Install and configure RStudio with Athena

Use the following AWS CloudFormation stack to install, configure, and connect RStudio on an Amazon EC2 instance with Athena.

Launching this stack creates all required resources and prerequisites:

  • Amazon EC2 instance with Amazon Linux (minimum size of t2.large is recommended)
  • Provisioning of the EC2 instance in an existing VPC and public subnet
  • Installation of Java 8
  • Assignment of an IAM role to the EC2 instance with the required permissions for accessing Athena and Amazon S3
  • Security group allowing access to the RStudio and SSH ports from the internet (I recommend restricting access to these ports)
  • S3 staging bucket required for Athena (referenced within RStudio as ATHENABUCKET)
  • RStudio username and password
  • Setup logs in Amazon CloudWatch Logs (if needed for additional troubleshooting)
  • Amazon EC2 Systems Manager agent, which makes it easy to manage and patch

All AWS resources are created in the US-East-1 Region. To avoid cross-region data transfer fees, launch the CloudFormation stack in the same region. To check the availability of Athena in other regions, see Region Table.

Log in to RStudio

The instance security group has been automatically configured to allow incoming connections on the RStudio port 8787 from any source internet address. You can edit the security group to restrict source IP access. If you have trouble connecting, ensure that port 8787 isn’t blocked by subnet network ACLS or by your outgoing proxy/firewall.

  1. In the CloudFormation stack, choose Outputs, Value, and then open the RStudio URL. You might need to wait for a few minutes until the instance has been launched.
  2. Log in to RStudio with the and password you provided during setup.

Install R packages

Next, install the required R packages from the RStudio console. You can download the R notebook file containing just the code.

#install pacman – a handy package manager for managing installs
if("pacman" %in% rownames(installed.packages()) == FALSE)
{install.packages("pacman")}  
library(pacman)
p_load(h2o,rJava,RJDBC,awsjavasdk)
h2o.init(nthreads = -1)
##  Connection successful!
## 
## R is connected to the H2O cluster: 
##     H2O cluster uptime:         2 hours 42 minutes 
##     H2O cluster version:        3.10.4.6 
##     H2O cluster version age:    4 months and 4 days !!! 
##     H2O cluster name:           H2O_started_from_R_rstudio_hjx881 
##     H2O cluster total nodes:    1 
##     H2O cluster total memory:   3.30 GB 
##     H2O cluster total cores:    4 
##     H2O cluster allowed cores:  4 
##     H2O cluster healthy:        TRUE 
##     H2O Connection ip:          localhost 
##     H2O Connection port:        54321 
##     H2O Connection proxy:       NA 
##     H2O Internal Security:      FALSE 
##     R Version:                  R version 3.3.3 (2017-03-06)
## Warning in h2o.clusterInfo(): 
## Your H2O cluster version is too old (4 months and 4 days)!
## Please download and install the latest version from http://h2o.ai/download/
#install aws sdk if not present (pre-requisite for using Athena with an IAM role)
if (!aws_sdk_present()) {
  install_aws_sdk()
}

load_sdk()
## NULL

Connect to Athena

Next, establish a connection to Athena from RStudio, using an IAM role associated with your EC2 instance. Use ATHENABUCKET to specify the S3 staging directory.

URL <- 'https://s3.amazonaws.com/athena-downloads/drivers/AthenaJDBC41-1.0.1.jar'
fil <- basename(URL)
#download the file into current working directory
if (!file.exists(fil)) download.file(URL, fil)
#verify that the file has been downloaded successfully
list.files()
## [1] "AthenaJDBC41-1.0.1.jar"
drv <- JDBC(driverClass="com.amazonaws.athena.jdbc.AthenaDriver", fil, identifier.quote="'")

con <- jdbcConnection <- dbConnect(drv, 'jdbc:awsathena://athena.us-east-1.amazonaws.com:443/',
                                   s3_staging_dir=Sys.getenv("ATHENABUCKET"),
                                   aws_credentials_provider_class="com.amazonaws.auth.DefaultAWSCredentialsProviderChain")

Verify the connection. The results returned depend on your specific Athena setup.

con
## <JDBCConnection>
dbListTables(con)
##  [1] "gdelt"               "wikistats"           "elb_logs_raw_native"
##  [4] "twitter"             "twitter2"            "usermovieratings"   
##  [7] "eventcodes"          "events"              "billboard"          
## [10] "billboardtop10"      "elb_logs"            "gdelthist"          
## [13] "gdeltmaster"         "twitter"             "twitter3"

Create a dataset

For this analysis, you use a sample dataset combining information from Billboard and Wikipedia with Echo Nest data in the Million Songs Dataset. Upload this dataset into your own S3 bucket. The table below provides a description of the fields used in this dataset.

Field Description
year Year that song was released
songtitle Title of the song
artistname Name of the song artist
songid Unique identifier for the song
artistid Unique identifier for the song artist
timesignature Variable estimating the time signature of the song
timesignature_confidence Confidence in the estimate for the timesignature
loudness Continuous variable indicating the average amplitude of the audio in decibels
tempo Variable indicating the estimated beats per minute of the song
tempo_confidence Confidence in the estimate for tempo
key Variable with twelve levels indicating the estimated key of the song (C, C#, B)
key_confidence Confidence in the estimate for key
energy Variable that represents the overall acoustic energy of the song, using a mix of features such as loudness
pitch Continuous variable that indicates the pitch of the song
timbre_0_min thru timbre_11_min Variables that indicate the minimum values over all segments for each of the twelve values in the timbre vector
timbre_0_max thru timbre_11_max Variables that indicate the maximum values over all segments for each of the twelve values in the timbre vector
top10 Indicator for whether or not the song made it to the Top 10 of the Billboard charts (1 if it was in the top 10, and 0 if not)

Create an Athena table based on the dataset

In the Athena console, select the default database, sampled, or create a new database.

Run the following create table statement.

create external table if not exists billboard
(
year int,
songtitle string,
artistname string,
songID string,
artistID string,
timesignature int,
timesignature_confidence double,
loudness double,
tempo double,
tempo_confidence double,
key int,
key_confidence double,
energy double,
pitch double,
timbre_0_min double,
timbre_0_max double,
timbre_1_min double,
timbre_1_max double,
timbre_2_min double,
timbre_2_max double,
timbre_3_min double,
timbre_3_max double,
timbre_4_min double,
timbre_4_max double,
timbre_5_min double,
timbre_5_max double,
timbre_6_min double,
timbre_6_max double,
timbre_7_min double,
timbre_7_max double,
timbre_8_min double,
timbre_8_max double,
timbre_9_min double,
timbre_9_max double,
timbre_10_min double,
timbre_10_max double,
timbre_11_min double,
timbre_11_max double,
Top10 int
)
ROW FORMAT DELIMITED
FIELDS TERMINATED BY ','
STORED AS TEXTFILE
LOCATION 's3://aws-bigdata-blog/artifacts/predict-billboard/data'
;

Inspect the table definition for the ‘billboard’ table that you have created. If you chose a database other than sampledb, replace that value with your choice.

dbGetQuery(con, "show create table sampledb.billboard")
##                                      createtab_stmt
## 1       CREATE EXTERNAL TABLE `sampledb.billboard`(
## 2                                       `year` int,
## 3                               `songtitle` string,
## 4                              `artistname` string,
## 5                                  `songid` string,
## 6                                `artistid` string,
## 7                              `timesignature` int,
## 8                `timesignature_confidence` double,
## 9                                `loudness` double,
## 10                                  `tempo` double,
## 11                       `tempo_confidence` double,
## 12                                       `key` int,
## 13                         `key_confidence` double,
## 14                                 `energy` double,
## 15                                  `pitch` double,
## 16                           `timbre_0_min` double,
## 17                           `timbre_0_max` double,
## 18                           `timbre_1_min` double,
## 19                           `timbre_1_max` double,
## 20                           `timbre_2_min` double,
## 21                           `timbre_2_max` double,
## 22                           `timbre_3_min` double,
## 23                           `timbre_3_max` double,
## 24                           `timbre_4_min` double,
## 25                           `timbre_4_max` double,
## 26                           `timbre_5_min` double,
## 27                           `timbre_5_max` double,
## 28                           `timbre_6_min` double,
## 29                           `timbre_6_max` double,
## 30                           `timbre_7_min` double,
## 31                           `timbre_7_max` double,
## 32                           `timbre_8_min` double,
## 33                           `timbre_8_max` double,
## 34                           `timbre_9_min` double,
## 35                           `timbre_9_max` double,
## 36                          `timbre_10_min` double,
## 37                          `timbre_10_max` double,
## 38                          `timbre_11_min` double,
## 39                          `timbre_11_max` double,
## 40                                     `top10` int)
## 41                             ROW FORMAT DELIMITED 
## 42                         FIELDS TERMINATED BY ',' 
## 43                            STORED AS INPUTFORMAT 
## 44       'org.apache.hadoop.mapred.TextInputFormat' 
## 45                                     OUTPUTFORMAT 
## 46  'org.apache.hadoop.hive.ql.io.HiveIgnoreKeyTextOutputFormat'
## 47                                        LOCATION
## 48    's3://aws-bigdata-blog/artifacts/predict-billboard/data'
## 49                                  TBLPROPERTIES (
## 50            'transient_lastDdlTime'='1505484133')

Run a sample query

Next, run a sample query to obtain a list of all songs from Janet Jackson that made it to the Billboard Top 10 charts.

dbGetQuery(con, " SELECT songtitle,artistname,top10   FROM sampledb.billboard WHERE lower(artistname) =     'janet jackson' AND top10 = 1")
##                       songtitle    artistname top10
## 1                       Runaway Janet Jackson     1
## 2               Because Of Love Janet Jackson     1
## 3                         Again Janet Jackson     1
## 4                            If Janet Jackson     1
## 5  Love Will Never Do (Without You) Janet Jackson 1
## 6                     Black Cat Janet Jackson     1
## 7               Come Back To Me Janet Jackson     1
## 8                       Alright Janet Jackson     1
## 9                      Escapade Janet Jackson     1
## 10                Rhythm Nation Janet Jackson     1

Determine how many songs in this dataset are specifically from the year 2010.

dbGetQuery(con, " SELECT count(*)   FROM sampledb.billboard WHERE year = 2010")
##   _col0
## 1   373

The sample dataset provides certain song properties of interest that can be analyzed to gauge the impact to the song’s overall popularity. Look at one such property, timesignature, and determine the value that is the most frequent among songs in the database. Timesignature is a measure of the number of beats and the type of note involved.

Running the query directly may result in an error, as shown in the commented lines below. This error is a result of trying to retrieve a large result set over a JDBC connection, which can cause out-of-memory issues at the client level. To address this, reduce the fetch size and run again.

#t<-dbGetQuery(con, " SELECT timesignature FROM sampledb.billboard")
#Note:  Running the preceding query results in the following error: 
#Error in .jcall(rp, "I", "fetch", stride, block): java.sql.SQLException: The requested #fetchSize is more than the allowed value in Athena. Please reduce the fetchSize and try #again. Refer to the Athena documentation for valid fetchSize values.
# Use the dbSendQuery function, reduce the fetch size, and run again
r <- dbSendQuery(con, " SELECT timesignature     FROM sampledb.billboard")
dftimesignature<- fetch(r, n=-1, block=100)
dbClearResult(r)
## [1] TRUE
table(dftimesignature)
## dftimesignature
##    0    1    3    4    5    7 
##   10  143  503 6787  112   19
nrow(dftimesignature)
## [1] 7574

From the results, observe that 6787 songs have a timesignature of 4.

Next, determine the song with the highest tempo.

dbGetQuery(con, " SELECT songtitle,artistname,tempo   FROM sampledb.billboard WHERE tempo = (SELECT max(tempo) FROM sampledb.billboard) ")
##                   songtitle      artistname   tempo
## 1 Wanna Be Startin' Somethin' Michael Jackson 244.307

Create the training dataset

Your model needs to be trained such that it can learn and make accurate predictions. Split the data into training and test datasets, and create the training dataset first.  This dataset contains all observations from the year 2009 and earlier. You may face the same JDBC connection issue pointed out earlier, so this query uses a fetch size.

#BillboardTrain <- dbGetQuery(con, "SELECT * FROM sampledb.billboard WHERE year <= 2009")
#Running the preceding query results in the following error:-
#Error in .verify.JDBC.result(r, "Unable to retrieve JDBC result set for ", : Unable to retrieve #JDBC result set for SELECT * FROM sampledb.billboard WHERE year <= 2009 (Internal error)
#Follow the same approach as before to address this issue.

r <- dbSendQuery(con, "SELECT * FROM sampledb.billboard WHERE year <= 2009")
BillboardTrain <- fetch(r, n=-1, block=100)
dbClearResult(r)
## [1] TRUE
BillboardTrain[1:2,c(1:3,6:10)]
##   year           songtitle artistname timesignature
## 1 2009 The Awkward Goodbye    Athlete             3
## 2 2009        Rubik's Cube    Athlete             3
##   timesignature_confidence loudness   tempo tempo_confidence
## 1                    0.732   -6.320  89.614   0.652
## 2                    0.906   -9.541 117.742   0.542
nrow(BillboardTrain)
## [1] 7201

Create the test dataset

BillboardTest <- dbGetQuery(con, "SELECT * FROM sampledb.billboard where year = 2010")
BillboardTest[1:2,c(1:3,11:15)]
##   year              songtitle        artistname key
## 1 2010 This Is the House That Doubt Built A Day to Remember  11
## 2 2010        Sticks & Bricks A Day to Remember  10
##   key_confidence    energy pitch timbre_0_min
## 1          0.453 0.9666556 0.024        0.002
## 2          0.469 0.9847095 0.025        0.000
nrow(BillboardTest)
## [1] 373

Convert the training and test datasets into H2O dataframes

train.h2o <- as.h2o(BillboardTrain)
## 
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test.h2o <- as.h2o(BillboardTest)
## 
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  |=================================================================| 100%

Inspect the column names in your H2O dataframes.

colnames(train.h2o)
##  [1] "year"                     "songtitle"               
##  [3] "artistname"               "songid"                  
##  [5] "artistid"                 "timesignature"           
##  [7] "timesignature_confidence" "loudness"                
##  [9] "tempo"                    "tempo_confidence"        
## [11] "key"                      "key_confidence"          
## [13] "energy"                   "pitch"                   
## [15] "timbre_0_min"             "timbre_0_max"            
## [17] "timbre_1_min"             "timbre_1_max"            
## [19] "timbre_2_min"             "timbre_2_max"            
## [21] "timbre_3_min"             "timbre_3_max"            
## [23] "timbre_4_min"             "timbre_4_max"            
## [25] "timbre_5_min"             "timbre_5_max"            
## [27] "timbre_6_min"             "timbre_6_max"            
## [29] "timbre_7_min"             "timbre_7_max"            
## [31] "timbre_8_min"             "timbre_8_max"            
## [33] "timbre_9_min"             "timbre_9_max"            
## [35] "timbre_10_min"            "timbre_10_max"           
## [37] "timbre_11_min"            "timbre_11_max"           
## [39] "top10"

Create models

You need to designate the independent and dependent variables prior to applying your modeling algorithms. Because you’re trying to predict the ‘top10’ field, this would be your dependent variable and everything else would be independent.

Create your first model using GLM. Because GLM works best with numeric data, you create your model by dropping non-numeric variables. You only use the variables in the dataset that describe the numerical attributes of the song in the logistic regression model. You won’t use these variables:  “year”, “songtitle”, “artistname”, “songid”, or “artistid”.

y.dep <- 39
x.indep <- c(6:38)
x.indep
##  [1]  6  7  8  9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28
## [24] 29 30 31 32 33 34 35 36 37 38

Create Model 1: All numeric variables

Create Model 1 with the training dataset, using GLM as the modeling algorithm and H2O’s built-in h2o.glm function.

modelh1 <- h2o.glm( y = y.dep, x = x.indep, training_frame = train.h2o, family = "binomial")
## 
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Measure the performance of Model 1, using H2O’s built-in performance function.

h2o.performance(model=modelh1,newdata=test.h2o)
## H2OBinomialMetrics: glm
## 
## MSE:  0.09924684
## RMSE:  0.3150347
## LogLoss:  0.3220267
## Mean Per-Class Error:  0.2380168
## AUC:  0.8431394
## Gini:  0.6862787
## R^2:  0.254663
## Null Deviance:  326.0801
## Residual Deviance:  240.2319
## AIC:  308.2319
## 
## Confusion Matrix (vertical: actual; across: predicted) for F1-optimal threshold:
##          0   1    Error     Rate
## 0      255  59 0.187898  =59/314
## 1       17  42 0.288136   =17/59
## Totals 272 101 0.203753  =76/373
## 
## Maximum Metrics: Maximum metrics at their respective thresholds
##                         metric threshold    value idx
## 1                       max f1  0.192772 0.525000 100
## 2                       max f2  0.124912 0.650510 155
## 3                 max f0point5  0.416258 0.612903  23
## 4                 max accuracy  0.416258 0.879357  23
## 5                max precision  0.813396 1.000000   0
## 6                   max recall  0.037579 1.000000 282
## 7              max specificity  0.813396 1.000000   0
## 8             max absolute_mcc  0.416258 0.455251  23
## 9   max min_per_class_accuracy  0.161402 0.738854 125
## 10 max mean_per_class_accuracy  0.124912 0.765006 155
## 
## Gains/Lift Table: Extract with `h2o.gainsLift(<model>, <data>)` or ` 
h2o.auc(h2o.performance(modelh1,test.h2o)) 
## [1] 0.8431394

The AUC metric provides insight into how well the classifier is able to separate the two classes. In this case, the value of 0.8431394 indicates that the classification is good. (A value of 0.5 indicates a worthless test, while a value of 1.0 indicates a perfect test.)

Next, inspect the coefficients of the variables in the dataset.

dfmodelh1 <- as.data.frame(h2o.varimp(modelh1))
dfmodelh1
##                       names coefficients sign
## 1              timbre_0_max  1.290938663  NEG
## 2                  loudness  1.262941934  POS
## 3                     pitch  0.616995941  NEG
## 4              timbre_1_min  0.422323735  POS
## 5              timbre_6_min  0.349016024  NEG
## 6                    energy  0.348092062  NEG
## 7             timbre_11_min  0.307331997  NEG
## 8              timbre_3_max  0.302225619  NEG
## 9             timbre_11_max  0.243632060  POS
## 10             timbre_4_min  0.224233951  POS
## 11             timbre_4_max  0.204134342  POS
## 12             timbre_5_min  0.199149324  NEG
## 13             timbre_0_min  0.195147119  POS
## 14 timesignature_confidence  0.179973904  POS
## 15         tempo_confidence  0.144242598  POS
## 16            timbre_10_max  0.137644568  POS
## 17             timbre_7_min  0.126995955  NEG
## 18            timbre_10_min  0.123851179  POS
## 19             timbre_7_max  0.100031481  NEG
## 20             timbre_2_min  0.096127636  NEG
## 21           key_confidence  0.083115820  POS
## 22             timbre_6_max  0.073712419  POS
## 23            timesignature  0.067241917  POS
## 24             timbre_8_min  0.061301881  POS
## 25             timbre_8_max  0.060041698  POS
## 26                      key  0.056158445  POS
## 27             timbre_3_min  0.050825116  POS
## 28             timbre_9_max  0.033733561  POS
## 29             timbre_2_max  0.030939072  POS
## 30             timbre_9_min  0.020708113  POS
## 31             timbre_1_max  0.014228818  NEG
## 32                    tempo  0.008199861  POS
## 33             timbre_5_max  0.004837870  POS
## 34                                    NA <NA>

Typically, songs with heavier instrumentation tend to be louder (have higher values in the variable “loudness”) and more energetic (have higher values in the variable “energy”). This knowledge is helpful for interpreting the modeling results.

You can make the following observations from the results:

  • The coefficient estimates for the confidence values associated with the time signature, key, and tempo variables are positive. This suggests that higher confidence leads to a higher predicted probability of a Top 10 hit.
  • The coefficient estimate for loudness is positive, meaning that mainstream listeners prefer louder songs with heavier instrumentation.
  • The coefficient estimate for energy is negative, meaning that mainstream listeners prefer songs that are less energetic, which are those songs with light instrumentation.

These coefficients lead to contradictory conclusions for Model 1. This could be due to multicollinearity issues. Inspect the correlation between the variables “loudness” and “energy” in the training set.

cor(train.h2o$loudness,train.h2o$energy)
## [1] 0.7399067

This number indicates that these two variables are highly correlated, and Model 1 does indeed suffer from multicollinearity. Typically, you associate a value of -1.0 to -0.5 or 1.0 to 0.5 to indicate strong correlation, and a value of 0.1 to 0.1 to indicate weak correlation. To avoid this correlation issue, omit one of these two variables and re-create the models.

You build two variations of the original model:

  • Model 2, in which you keep “energy” and omit “loudness”
  • Model 3, in which you keep “loudness” and omit “energy”

You compare these two models and choose the model with a better fit for this use case.

Create Model 2: Keep energy and omit loudness

colnames(train.h2o)
##  [1] "year"                     "songtitle"               
##  [3] "artistname"               "songid"                  
##  [5] "artistid"                 "timesignature"           
##  [7] "timesignature_confidence" "loudness"                
##  [9] "tempo"                    "tempo_confidence"        
## [11] "key"                      "key_confidence"          
## [13] "energy"                   "pitch"                   
## [15] "timbre_0_min"             "timbre_0_max"            
## [17] "timbre_1_min"             "timbre_1_max"            
## [19] "timbre_2_min"             "timbre_2_max"            
## [21] "timbre_3_min"             "timbre_3_max"            
## [23] "timbre_4_min"             "timbre_4_max"            
## [25] "timbre_5_min"             "timbre_5_max"            
## [27] "timbre_6_min"             "timbre_6_max"            
## [29] "timbre_7_min"             "timbre_7_max"            
## [31] "timbre_8_min"             "timbre_8_max"            
## [33] "timbre_9_min"             "timbre_9_max"            
## [35] "timbre_10_min"            "timbre_10_max"           
## [37] "timbre_11_min"            "timbre_11_max"           
## [39] "top10"
y.dep <- 39
x.indep <- c(6:7,9:38)
x.indep
##  [1]  6  7  9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29
## [24] 30 31 32 33 34 35 36 37 38
modelh2 <- h2o.glm( y = y.dep, x = x.indep, training_frame = train.h2o, family = "binomial")
## 
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  |=================================================================| 100%

Measure the performance of Model 2.

h2o.performance(model=modelh2,newdata=test.h2o)
## H2OBinomialMetrics: glm
## 
## MSE:  0.09922606
## RMSE:  0.3150017
## LogLoss:  0.3228213
## Mean Per-Class Error:  0.2490554
## AUC:  0.8431933
## Gini:  0.6863867
## R^2:  0.2548191
## Null Deviance:  326.0801
## Residual Deviance:  240.8247
## AIC:  306.8247
## 
## Confusion Matrix (vertical: actual; across: predicted) for F1-optimal threshold:
##          0  1    Error     Rate
## 0      280 34 0.108280  =34/314
## 1       23 36 0.389831   =23/59
## Totals 303 70 0.152815  =57/373
## 
## Maximum Metrics: Maximum metrics at their respective thresholds
##                         metric threshold    value idx
## 1                       max f1  0.254391 0.558140  69
## 2                       max f2  0.113031 0.647208 157
## 3                 max f0point5  0.413999 0.596026  22
## 4                 max accuracy  0.446250 0.876676  18
## 5                max precision  0.811739 1.000000   0
## 6                   max recall  0.037682 1.000000 283
## 7              max specificity  0.811739 1.000000   0
## 8             max absolute_mcc  0.254391 0.469060  69
## 9   max min_per_class_accuracy  0.141051 0.716561 131
## 10 max mean_per_class_accuracy  0.113031 0.761821 157
## 
## Gains/Lift Table: Extract with `h2o.gainsLift(<model>, <data>)` or `h2o.gainsLift(<model>, valid=<T/F>, xval=<T/F>)`
dfmodelh2 <- as.data.frame(h2o.varimp(modelh2))
dfmodelh2
##                       names coefficients sign
## 1                     pitch  0.700331511  NEG
## 2              timbre_1_min  0.510270513  POS
## 3              timbre_0_max  0.402059546  NEG
## 4              timbre_6_min  0.333316236  NEG
## 5             timbre_11_min  0.331647383  NEG
## 6              timbre_3_max  0.252425901  NEG
## 7             timbre_11_max  0.227500308  POS
## 8              timbre_4_max  0.210663865  POS
## 9              timbre_0_min  0.208516163  POS
## 10             timbre_5_min  0.202748055  NEG
## 11             timbre_4_min  0.197246582  POS
## 12            timbre_10_max  0.172729619  POS
## 13         tempo_confidence  0.167523934  POS
## 14 timesignature_confidence  0.167398830  POS
## 15             timbre_7_min  0.142450727  NEG
## 16             timbre_8_max  0.093377516  POS
## 17            timbre_10_min  0.090333426  POS
## 18            timesignature  0.085851625  POS
## 19             timbre_7_max  0.083948442  NEG
## 20           key_confidence  0.079657073  POS
## 21             timbre_6_max  0.076426046  POS
## 22             timbre_2_min  0.071957831  NEG
## 23             timbre_9_max  0.071393189  POS
## 24             timbre_8_min  0.070225578  POS
## 25                      key  0.061394702  POS
## 26             timbre_3_min  0.048384697  POS
## 27             timbre_1_max  0.044721121  NEG
## 28                   energy  0.039698433  POS
## 29             timbre_5_max  0.039469064  POS
## 30             timbre_2_max  0.018461133  POS
## 31                    tempo  0.013279926  POS
## 32             timbre_9_min  0.005282143  NEG
## 33                                    NA <NA>

h2o.auc(h2o.performance(modelh2,test.h2o)) 
## [1] 0.8431933

You can make the following observations:

  • The AUC metric is 0.8431933.
  • Inspecting the coefficient of the variable energy, Model 2 suggests that songs with high energy levels tend to be more popular. This is as per expectation.
  • As H2O orders variables by significance, the variable energy is not significant in this model.

You can conclude that Model 2 is not ideal for this use , as energy is not significant.

CreateModel 3: Keep loudness but omit energy

colnames(train.h2o)
##  [1] "year"                     "songtitle"               
##  [3] "artistname"               "songid"                  
##  [5] "artistid"                 "timesignature"           
##  [7] "timesignature_confidence" "loudness"                
##  [9] "tempo"                    "tempo_confidence"        
## [11] "key"                      "key_confidence"          
## [13] "energy"                   "pitch"                   
## [15] "timbre_0_min"             "timbre_0_max"            
## [17] "timbre_1_min"             "timbre_1_max"            
## [19] "timbre_2_min"             "timbre_2_max"            
## [21] "timbre_3_min"             "timbre_3_max"            
## [23] "timbre_4_min"             "timbre_4_max"            
## [25] "timbre_5_min"             "timbre_5_max"            
## [27] "timbre_6_min"             "timbre_6_max"            
## [29] "timbre_7_min"             "timbre_7_max"            
## [31] "timbre_8_min"             "timbre_8_max"            
## [33] "timbre_9_min"             "timbre_9_max"            
## [35] "timbre_10_min"            "timbre_10_max"           
## [37] "timbre_11_min"            "timbre_11_max"           
## [39] "top10"
y.dep <- 39
x.indep <- c(6:12,14:38)
x.indep
##  [1]  6  7  8  9 10 11 12 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29
## [24] 30 31 32 33 34 35 36 37 38
modelh3 <- h2o.glm( y = y.dep, x = x.indep, training_frame = train.h2o, family = "binomial")
## 
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  |                                                                       
  |========                                                         |  12%
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perfh3<-h2o.performance(model=modelh3,newdata=test.h2o)
perfh3
## H2OBinomialMetrics: glm
## 
## MSE:  0.0978859
## RMSE:  0.3128672
## LogLoss:  0.3178367
## Mean Per-Class Error:  0.264925
## AUC:  0.8492389
## Gini:  0.6984778
## R^2:  0.2648836
## Null Deviance:  326.0801
## Residual Deviance:  237.1062
## AIC:  303.1062
## 
## Confusion Matrix (vertical: actual; across: predicted) for F1-optimal threshold:
##          0  1    Error     Rate
## 0      286 28 0.089172  =28/314
## 1       26 33 0.440678   =26/59
## Totals 312 61 0.144772  =54/373
## 
## Maximum Metrics: Maximum metrics at their respective thresholds
##                         metric threshold    value idx
## 1                       max f1  0.273799 0.550000  60
## 2                       max f2  0.125503 0.663265 155
## 3                 max f0point5  0.435479 0.628931  24
## 4                 max accuracy  0.435479 0.882038  24
## 5                max precision  0.821606 1.000000   0
## 6                   max recall  0.038328 1.000000 280
## 7              max specificity  0.821606 1.000000   0
## 8             max absolute_mcc  0.435479 0.471426  24
## 9   max min_per_class_accuracy  0.173693 0.745763 120
## 10 max mean_per_class_accuracy  0.125503 0.775073 155
## 
## Gains/Lift Table: Extract with `h2o.gainsLift(<model>, <data>)` or `h2o.gainsLift(<model>, valid=<T/F>, xval=<T/F>)`
dfmodelh3 <- as.data.frame(h2o.varimp(modelh3))
dfmodelh3
##                       names coefficients sign
## 1              timbre_0_max 1.216621e+00  NEG
## 2                  loudness 9.780973e-01  POS
## 3                     pitch 7.249788e-01  NEG
## 4              timbre_1_min 3.891197e-01  POS
## 5              timbre_6_min 3.689193e-01  NEG
## 6             timbre_11_min 3.086673e-01  NEG
## 7              timbre_3_max 3.025593e-01  NEG
## 8             timbre_11_max 2.459081e-01  POS
## 9              timbre_4_min 2.379749e-01  POS
## 10             timbre_4_max 2.157627e-01  POS
## 11             timbre_0_min 1.859531e-01  POS
## 12             timbre_5_min 1.846128e-01  NEG
## 13 timesignature_confidence 1.729658e-01  POS
## 14             timbre_7_min 1.431871e-01  NEG
## 15            timbre_10_max 1.366703e-01  POS
## 16            timbre_10_min 1.215954e-01  POS
## 17         tempo_confidence 1.183698e-01  POS
## 18             timbre_2_min 1.019149e-01  NEG
## 19           key_confidence 9.109701e-02  POS
## 20             timbre_7_max 8.987908e-02  NEG
## 21             timbre_6_max 6.935132e-02  POS
## 22             timbre_8_max 6.878241e-02  POS
## 23            timesignature 6.120105e-02  POS
## 24                      key 5.814805e-02  POS
## 25             timbre_8_min 5.759228e-02  POS
## 26             timbre_1_max 2.930285e-02  NEG
## 27             timbre_9_max 2.843755e-02  POS
## 28             timbre_3_min 2.380245e-02  POS
## 29             timbre_2_max 1.917035e-02  POS
## 30             timbre_5_max 1.715813e-02  POS
## 31                    tempo 1.364418e-02  NEG
## 32             timbre_9_min 8.463143e-05  NEG
## 33                                    NA <NA>
h2o.sensitivity(perfh3,0.5)
## Warning in h2o.find_row_by_threshold(object, t): Could not find exact
## threshold: 0.5 for this set of metrics; using closest threshold found:
## 0.501855569251422. Run `h2o.predict` and apply your desired threshold on a
## probability column.
## [[1]]
## [1] 0.2033898
h2o.auc(perfh3)
## [1] 0.8492389

You can make the following observations:

  • The AUC metric is 0.8492389.
  • From the confusion matrix, the model correctly predicts that 33 songs will be top 10 hits (true positives). However, it has 26 false positives (songs that the model predicted would be Top 10 hits, but ended up not being Top 10 hits).
  • Loudness has a positive coefficient estimate, meaning that this model predicts that songs with heavier instrumentation tend to be more popular. This is the same conclusion from Model 2.
  • Loudness is significant in this model.

Overall, Model 3 predicts a higher number of top 10 hits with an accuracy rate that is acceptable. To choose the best fit for production runs, record labels should consider the following factors:

  • Desired model accuracy at a given threshold
  • Number of correct predictions for top10 hits
  • Tolerable number of false positives or false negatives

Next, make predictions using Model 3 on the test dataset.

predict.regh <- h2o.predict(modelh3, test.h2o)
## 
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print(predict.regh)
##   predict        p0          p1
## 1       0 0.9654739 0.034526052
## 2       0 0.9654748 0.034525236
## 3       0 0.9635547 0.036445318
## 4       0 0.9343579 0.065642149
## 5       0 0.9978334 0.002166601
## 6       0 0.9779949 0.022005078
## 
## [373 rows x 3 columns]
predict.regh$predict
##   predict
## 1       0
## 2       0
## 3       0
## 4       0
## 5       0
## 6       0
## 
## [373 rows x 1 column]
dpr<-as.data.frame(predict.regh)
#Rename the predicted column 
colnames(dpr)[colnames(dpr) == 'predict'] <- 'predict_top10'
table(dpr$predict_top10)
## 
##   0   1 
## 312  61

The first set of output results specifies the probabilities associated with each predicted observation.  For example, observation 1 is 96.54739% likely to not be a Top 10 hit, and 3.4526052% likely to be a Top 10 hit (predict=1 indicates Top 10 hit and predict=0 indicates not a Top 10 hit).  The second set of results list the actual predictions made.  From the third set of results, this model predicts that 61 songs will be top 10 hits.

Compute the baseline accuracy, by assuming that the baseline predicts the most frequent outcome, which is that most songs are not Top 10 hits.

table(BillboardTest$top10)
## 
##   0   1 
## 314  59

Now observe that the baseline model would get 314 observations correct, and 59 wrong, for an accuracy of 314/(314+59) = 0.8418231.

It seems that Model 3, with an accuracy of 0.8552, provides you with a small improvement over the baseline model. But is this model useful for record labels?

View the two models from an investment perspective:

  • A production company is interested in investing in songs that are more likely to make it to the Top 10. The company’s objective is to minimize the risk of financial losses attributed to investing in songs that end up unpopular.
  • How many songs does Model 3 correctly predict as a Top 10 hit in 2010? Looking at the confusion matrix, you see that it predicts 33 top 10 hits correctly at an optimal threshold, which is more than half the number
  • It will be more useful to the record label if you can provide the production company with a list of songs that are highly likely to end up in the Top 10.
  • The baseline model is not useful, as it simply does not label any song as a hit.

Considering the three models built so far, you can conclude that Model 3 proves to be the best investment choice for the record label.

GBM model

H2O provides you with the ability to explore other learning models, such as GBM and deep learning. Explore building a model using the GBM technique, using the built-in h2o.gbm function.

Before you do this, you need to convert the target variable to a factor for multinomial classification techniques.

train.h2o$top10=as.factor(train.h2o$top10)
gbm.modelh <- h2o.gbm(y=y.dep, x=x.indep, training_frame = train.h2o, ntrees = 500, max_depth = 4, learn_rate = 0.01, seed = 1122,distribution="multinomial")
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perf.gbmh<-h2o.performance(gbm.modelh,test.h2o)
perf.gbmh
## H2OBinomialMetrics: gbm
## 
## MSE:  0.09860778
## RMSE:  0.3140188
## LogLoss:  0.3206876
## Mean Per-Class Error:  0.2120263
## AUC:  0.8630573
## Gini:  0.7261146
## 
## Confusion Matrix (vertical: actual; across: predicted) for F1-optimal threshold:
##          0  1    Error     Rate
## 0      266 48 0.152866  =48/314
## 1       16 43 0.271186   =16/59
## Totals 282 91 0.171582  =64/373
## 
## Maximum Metrics: Maximum metrics at their respective thresholds
##                       metric threshold    value idx
## 1                     max f1  0.189757 0.573333  90
## 2                     max f2  0.130895 0.693717 145
## 3               max f0point5  0.327346 0.598802  26
## 4               max accuracy  0.442757 0.876676  14
## 5              max precision  0.802184 1.000000   0
## 6                 max recall  0.049990 1.000000 284
## 7            max specificity  0.802184 1.000000   0
## 8           max absolute_mcc  0.169135 0.496486 104
## 9 max min_per_class_accuracy  0.169135 0.796610 104
## 10 max mean_per_class_accuracy  0.169135 0.805948 104
## 
## Gains/Lift Table: Extract with `h2o.gainsLift(<model>, <data>)` or `
h2o.sensitivity(perf.gbmh,0.5)
## Warning in h2o.find_row_by_threshold(object, t): Could not find exact
## threshold: 0.5 for this set of metrics; using closest threshold found:
## 0.501205344484314. Run `h2o.predict` and apply your desired threshold on a
## probability column.
## [[1]]
## [1] 0.1355932
h2o.auc(perf.gbmh)
## [1] 0.8630573

This model correctly predicts 43 top 10 hits, which is 10 more than the number predicted by Model 3. Moreover, the AUC metric is higher than the one obtained from Model 3.

As seen above, H2O’s API provides the ability to obtain key statistical measures required to analyze the models easily, using several built-in functions. The record label can experiment with different parameters to arrive at the model that predicts the maximum number of Top 10 hits at the desired level of accuracy and threshold.

H2O also allows you to experiment with deep learning models. Deep learning models have the ability to learn features implicitly, but can be more expensive computationally.

Now, create a deep learning model with the h2o.deeplearning function, using the same training and test datasets created before. The time taken to run this model depends on the type of EC2 instance chosen for this purpose.  For models that require more computation, consider using accelerated computing instances such as the P2 instance type.

system.time(
  dlearning.modelh <- h2o.deeplearning(y = y.dep,
                                      x = x.indep,
                                      training_frame = train.h2o,
                                      epoch = 250,
                                      hidden = c(250,250),
                                      activation = "Rectifier",
                                      seed = 1122,
                                      distribution="multinomial"
  )
)
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##    user  system elapsed 
##   1.216   0.020 166.508
perf.dl<-h2o.performance(model=dlearning.modelh,newdata=test.h2o)
perf.dl
## H2OBinomialMetrics: deeplearning
## 
## MSE:  0.1678359
## RMSE:  0.4096778
## LogLoss:  1.86509
## Mean Per-Class Error:  0.3433013
## AUC:  0.7568822
## Gini:  0.5137644
## 
## Confusion Matrix (vertical: actual; across: predicted) for F1-optimal threshold:
##          0  1    Error     Rate
## 0      290 24 0.076433  =24/314
## 1       36 23 0.610169   =36/59
## Totals 326 47 0.160858  =60/373
## 
## Maximum Metrics: Maximum metrics at their respective thresholds
##                       metric threshold    value idx
## 1                     max f1  0.826267 0.433962  46
## 2                     max f2  0.000000 0.588235 239
## 3               max f0point5  0.999929 0.511811  16
## 4               max accuracy  0.999999 0.865952  10
## 5              max precision  1.000000 1.000000   0
## 6                 max recall  0.000000 1.000000 326
## 7            max specificity  1.000000 1.000000   0
## 8           max absolute_mcc  0.999929 0.363219  16
## 9 max min_per_class_accuracy  0.000004 0.662420 145
## 10 max mean_per_class_accuracy  0.000000 0.685334 224
## 
## Gains/Lift Table: Extract with `h2o.gainsLift(<model>, <data>)` or `h2o.gainsLift(<model>, valid=<T/F>, xval=<T/F>)`
h2o.sensitivity(perf.dl,0.5)
## Warning in h2o.find_row_by_threshold(object, t): Could not find exact
## threshold: 0.5 for this set of metrics; using closest threshold found:
## 0.496293348880151. Run `h2o.predict` and apply your desired threshold on a
## probability column.
## [[1]]
## [1] 0.3898305
h2o.auc(perf.dl)
## [1] 0.7568822

The AUC metric for this model is 0.7568822, which is less than what you got from the earlier models. I recommend further experimentation using different hyper parameters, such as the learning rate, epoch or the number of hidden layers.

H2O’s built-in functions provide many key statistical measures that can help measure model performance. Here are some of these key terms.

Metric Description
Sensitivity Measures the proportion of positives that have been correctly identified. It is also called the true positive rate, or recall.
Specificity Measures the proportion of negatives that have been correctly identified. It is also called the true negative rate.
Threshold Cutoff point that maximizes specificity and sensitivity. While the model may not provide the highest prediction at this point, it would not be biased towards positives or negatives.
Precision The fraction of the documents retrieved that are relevant to the information needed, for example, how many of the positively classified are relevant
AUC

Provides insight into how well the classifier is able to separate the two classes. The implicit goal is to deal with situations where the sample distribution is highly skewed, with a tendency to overfit to a single class.

0.90 – 1 = excellent (A)

0.8 – 0.9 = good (B)

0.7 – 0.8 = fair (C)

.6 – 0.7 = poor (D)

0.5 – 0.5 = fail (F)

Here’s a summary of the metrics generated from H2O’s built-in functions for the three models that produced useful results.

Metric Model 3 GBM Model Deep Learning Model

Accuracy

(max)

0.882038

(t=0.435479)

0.876676

(t=0.442757)

0.865952

(t=0.999999)

Precision

(max)

1.0

(t=0.821606)

1.0

(t=0802184)

1.0

(t=1.0)

Recall

(max)

1.0 1.0

1.0

(t=0)

Specificity

(max)

1.0 1.0

1.0

(t=1)

Sensitivity

 

0.2033898 0.1355932

0.3898305

(t=0.5)

AUC 0.8492389 0.8630573 0.756882

Note: ‘t’ denotes threshold.

Your options at this point could be narrowed down to Model 3 and the GBM model, based on the AUC and accuracy metrics observed earlier.  If the slightly lower accuracy of the GBM model is deemed acceptable, the record label can choose to go to production with the GBM model, as it can predict a higher number of Top 10 hits.  The AUC metric for the GBM model is also higher than that of Model 3.

Record labels can experiment with different learning techniques and parameters before arriving at a model that proves to be the best fit for their business. Because deep learning models can be computationally expensive, record labels can choose more powerful EC2 instances on AWS to run their experiments faster.

Conclusion

In this post, I showed how the popular music industry can use analytics to predict the type of songs that make the Top 10 Billboard charts. By running H2O’s scalable machine learning platform on AWS, data scientists can easily experiment with multiple modeling techniques and interactively query the data using Amazon Athena, without having to manage the underlying infrastructure. This helps record labels make critical decisions on the type of artists and songs to promote in a timely fashion, thereby increasing sales and revenue.

If you have questions or suggestions, please comment below.


Additional Reading

Learn how to build and explore a simple geospita simple GEOINT application using SparkR.


About the Authors

gopalGopal Wunnava is a Partner Solution Architect with the AWS GSI Team. He works with partners and customers on big data engagements, and is passionate about building analytical solutions that drive business capabilities and decision making. In his spare time, he loves all things sports and movies related and is fond of old classics like Asterix, Obelix comics and Hitchcock movies.

 

 

Bob Strahan, a Senior Consultant with AWS Professional Services, contributed to this post.