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Saturday, March 15, 2025

Architect fault-tolerant purposes with occasion fleets on Amazon EMR on EC2


Organizations depend on Amazon EMR on EC2 clusters to course of large-scale information workloads utilizing frameworks like Apache Spark, Apache Hive, and Trino. Occasions resembling TV commercials or unplanned promotions would possibly result in a rise in demand of compute capability, making efficient capability planning obligatory to verify your workloads don’t hit capability limits or job failures.

A typical state of affairs is to run every day Spark jobs on Amazon EMR utilizing constant Amazon Elastic Compute Cloud (Amazon EC2) occasion sorts (for instance, a single occasion dimension and household for the cluster). Though this would possibly work effectively to maintain the baseline, spikes can set off auto scaling, which narrows the probabilities of capability availability when making an attempt to cease and relaunch a bigger EMR cluster, as a result of the particular on-demand occasion pool would possibly lack capability to satisfy the demand.

On this publish, we present optimize capability by analyzing EMR workloads and implementing methods tailor-made to your workload patterns. We stroll by means of assessing the historic compute utilization of a workload and use a mix of methods to cut back the probability of InsufficientCapacityExceptions (ICE) when Amazon EMR launches particular EC2 occasion sorts. We implement versatile occasion fleet methods to cut back dependency on particular occasion sorts and use Amazon EC2 On-Demand Capability Reservation (ODCRs) for predictable, steady-state workloads. Following this strategy will help forestall job failures on account of capability limits whereas optimizing your cluster for value and efficiency.

Answer overview

Occasion fleets in Amazon EMR provide a versatile and sturdy solution to handle EC2 situations inside your cluster. This characteristic means that you can specify goal capacities for On-Demand and Spot Situations, choose as much as 5 EC2 occasion sorts per fleet (or 30 when utilizing the AWS Command Line Interface [AWS CLI] and API with an allocation technique), and use a number of subnets throughout totally different Availability Zones. Importantly, occasion fleets assist the usage of ODCRs, enabling you to align your EMR clusters with pre-purchased EC2 capability. You’ll be able to configure your occasion fleet to want or require capability reservations, ensuring that your EMR clusters use your reserved capability effectively.

EMR workload patterns sometimes fall into two classes: steady and variable (spiky). Within the following sections, we discover optimize for every sample utilizing numerous choices out there with occasion fleets, beginning with steady workloads after which addressing variable workloads.

Secure workloads are workloads with a predictable sample of useful resource utilization over time; for instance, a pharmaceutical supplier must course of 21 TB of analysis information, affected person information, and different info every day. The workload is constant and must run reliably on daily basis on long-running persistent clusters. For crucial enterprise operations requiring excessive reliability and assured capability, we suggest reserving the baseline capability as a part of your capability planning. We exhibit the next steps:

  1. Use AWS Price and Utilization Studies (AWS CUR) to estimate the baseline of present workloads.
  2. Reserve the baseline capability utilizing ODCR.
  3. Configure Amazon EMR to make use of the focused ODCR.

Spiky workloads are outlined by unpredictable and infrequently important fluctuations in processing calls for. These surges might be triggered by numerous components (resembling batch processing, real-time information streaming, or seasonal enterprise fluctuations) that set off Amazon EMR to request extra capability to match the demand. We deal with the useful resource allocation by utilizing occasion and Availability Zone flexibility, with the next steps:

  1. Introduce EC2 occasion flexibility with EMR occasion fleets.
  2. Obtain resiliency by means of clever subnet choice with EMR occasion fleets.
  3. Use managed scaling to routinely handle scaling out and in.

Secure workloads

On this part, we exhibit outline your baseline, configure AWS Identification and Entry Administration (IAM) permissions, create an ODCR, and affiliate your reservations to a capability group and configure Amazon EMR to make use of focused ODCRs. You’ll be able to go for a combined ODCR technique—for instance, one ODCR with a brief interval of period that helps the launch of your EMR cluster, and one other ODCR with an extended interval of period that helps your process nodes based mostly on the baseline capability reservation.

Estimate the baseline

Be certain to activate the AWS generated value allocation tag aws:elasticmapreduce:job-flow-id. This permits the sphere resource_tags_aws_elasticmapreduce_job_flow_id within the AWS CUR to be populated with the EMR cluster ID and is utilized by the SQL queries within the answer. To activate the price allocation tag from the AWS Billing Console, full the next steps:

  1. On the AWS Billing and Price Administration console, select Price allocation tags within the navigation pane.
  2. Below AWS generated value allocation tags, select the aws:elasticmapreduce:job-flow-id tag.
  3. Select Activate.

It could actually take as much as 24 hours for tags to activate. For extra info, see right here.

After the tags are activated, you need to use AWS CUR and carry out the next question on Amazon Athena to seek out the compute assets utilized by the EMR cluster ID vs. the timeline of utilization. For extra particulars, see Querying Price and Utilization Studies utilizing Amazon Athena. Replace the next question along with your CUR desk title, EMR cluster ID, desired timestamps, and AWS account ID, and run the question on Athena:

SELECT bill_payer_account_id as Payer,
    product_product_family as PFamily,
    product_product_name as PName,
    resource_tags_aws_elasticmapreduce_job_flow_id,
    line_item_usage_account_id as LinkedAccount,
    line_item_usage_start_date as UsageDate,
    bill_billing_period_start_date as BillingDate,
    SPLIT_PART(line_item_usage_type, ':', 2) AS InstanceType,
    line_item_availability_zone AS AvailabilityZone,
    COUNT(line_item_resource_id) as ResourceIDCount
FROM <YOUR_CUR_TABLE_NAME>
WHERE (
        line_item_usage_start_date BETWEEN TIMESTAMP 'YYYY-MM-DD 00:00:00'
        AND TIMESTAMP 'YYYY-MM-DD 23:59:59' 
    )
    AND line_item_operation LIKE '%%RunInstance%%'
    AND line_item_line_item_type LIKE '%%Utilization%%'
    AND product_product_family NOT IN ('Knowledge Switch')
    AND resource_tags_aws_elasticmapreduce_job_flow_id LIKE '%%<emr-cluster-id>%%'
    AND line_item_usage_account_id IN (
        '<aws_account_id>'
)
GROUP BY 1,2,3,4,5,6,7,8,9

For instance, the previous question filters situations utilization per hour for a given account and EMR cluster for the interval of 6 months, to generate the next determine. You’ll be able to export the ends in CSV format and analyze the info. Now that you’ve got a visible illustration of your workloads’ baseline and bursts, you’ll be able to outline the technique and configuration of your EMR cluster.

Create an ODCR to order the baseline capability

ODCRs might be both open or focused:

  • With an open ODCR, new situations and present situations which have matching attributes (resembling working system or occasion kind) will run utilizing the capability reservation attributes first.
  • With a focused ODCR, situations should match the attributes of the ODCR specification and the ODCR is particularly focused at launch. This strategy is really helpful when you have a number of concurrent EMR clusters consuming capability from the shared On-Demand pool of EC2 situations. EMR clusters bigger than the focused ODCR amount will fall again to On-Demand Situations which might be in the identical Availability Zone.

On this instance, we use a focused ODCR with an EMR occasion fleet within the us-east-1a Availability Zone. The next diagram illustrates the workflow.

Full the next steps:

  1. Use the create-capacity-reservation AWS CLI command to create the ODCR and make a remark of the CapacityReservationArn worth within the output:
aws ec2 create-capacity-reservation 
     --availability-zone <Enter Your Availability Zone> 
     --instance-type r8g.2xlarge 
     --instance-match-criteria focused 
     --instance-platform Linux/UNIX 
     --instance-count <enter the variety of situations out of your baseline estimation>

We get the next output:

{
     "CapacityReservation": {
         "CapacityReservationId": "cr-0123456f9907xxxxx",
         "OwnerId": "XXXX",
         "CapacityReservationArn": "arn:aws:ec2:us-east-1:XXXX:capacity-reservation/cr-0123456f9907xxxxx",
         "InstanceType": "r8g.2xlarge",
         "InstancePlatform": "Linux/UNIX",
         "AvailabilityZone": "us-east-1a"

 ....
     }
 }

You should utilize Amazon CloudWatch to observe ODCR utilization and set off an alert for unused capability. For extra particulars, see Monitor Capability Reservations utilization with CloudWatch metrics.

  1. Create a useful resource group named EMRSparkSteadyStateGroup and make a remark of GroupArn values within the output:
aws resource-groups create-group --name EMRSparkSteadyStateGroup 
--configuration '{"Sort":"AWS::EC2::CapacityReservationPool"}' '{"Sort":"AWS::ResourceGroups::Generic", "Parameters":[{"Name":"allowed-resource-types","Values":["AWS::EC2::CapacityReservation"]}]}'

We get the next output:

"Group": {
         "GroupArn": "arn:aws:resource-groups:us-east-1:XXXX:group/EMRSparkSteadyStateGroup",
         "Identify": "EMRSparkSteadyStateGroup"
     }, ...

  1. Use the next code to affiliate the capability reservation to the useful resource group. You’ll be able to have a number of capability reservations related to a useful resource group.
aws resource-groups group-resources --group EMRSparkSteadyStateGroup 
 --resource-arns arn:aws:ec2:us-east-1:XXXX:capacity-reservation/cr-0123456f9907xxxxx

  1. As a finest follow for efficient administration and cleanup, Create a tag Goal=EMR-Spark-Regular-State for the newly created ODCR and the useful resource group.
# Tag your Capability Reservation
 aws ec2 create-tags 
 --resources cr-0123456f9907xxxxx 
 --tags Key=Goal,Worth=EMR-Spark-Regular-State
# Tag your Useful resource Group
 aws resource-groups tag 
 --arn "arn:aws:resource-groups:us-east-1:XXXX:group/EMRSparkSteadyStateGroup" --tags Goal=EMR-Spark-Regular-State

Implement Amazon EMR with ODCR

Full the next steps to create an EMR cluster tagged with the particular focused ODCR:

  1. Add required permissions to the EMR service position earlier than utilizing capability reservations. With these permissions, you’ll be able to lock down the useful resource with the particular Amazon Useful resource Identify (ARN) of the group title to be created with the next code:
{
     "Model": "2012-10-17",
     "Assertion": [
         {
             "Effect": "Allow",
             "Resource": "*",
             "Action": [
                 "ec2:CreateFleet",
                 "ec2:RunInstances",
                 "ec2:CreateLaunchTemplate",
                 "ec2:CreateLaunchTemplateVersion",
                 "ec2:DeleteLaunchTemplateVersions",
                 "ec2:DescribeCapacityReservations",
                 "ec2:DescribeLaunchTemplateVersions",
                 "resource-groups:ListGroupResources"
             ]
         }
     ]
 }

  1. Configure the EMR cluster to make use of ODCR with occasion fleets. We use the CapacityReservationOptions parameter to configure the EMR cluster, as proven within the following instance:
  {
 ...
     "LaunchSpecifications": {
       "OnDemandSpecification": {
         "AllocationStrategy": "LOWEST_PRICE",
         "CapacityReservationOptions": {
           "UsageStrategy": "USE_CAPACITY_RESERVATIONS_FIRST",
           "CapacityReservationResourceGroupArn": "arn:aws:resource-groups:us-east-1:xxxxxx:group/EMRSparkSteadyStateGroup"
         }
       }
     }
   }

The next step-by-step breakdown illustrates the Amazon EMR decision-making course of when prioritizing focused capability reservations, from core node provisioning by means of process node allocation:

  • Cluster provisioning initiation:
    • The consumer chooses to override the lowest-price allocation technique.
    • The consumer specifies focused capability reservations within the launch request.
  • Core node provisioning:
    • Amazon EMR evaluates all EC2 occasion capability swimming pools with focused capability reservations, and selects the pool with the bottom worth that has adequate capability for all requested core nodes.
    • If no pool with focused reservations has adequate capability, Amazon EMR reevaluates all specified EC2 occasion capability swimming pools and selects the lowest-priced pool with adequate capability for core nodes. Obtainable open capability reservations are utilized routinely.
  • Availability Zone choice:
    • After the core capability is acquired, Amazon EMR locks within the Availability Zone to your cluster.
  • Major and process node provisioning:
    • Amazon EMR evaluates EC2 occasion capability swimming pools inside that Availability Zone for major and process fleets. First, Amazon EMR evaluates all of the swimming pools with focused ODCRs specified within the request, ordered by lowest worth by default.
    • From the ordered record, Amazon EMR launches as a lot capability as doable from the unused focused ODCRs of every occasion pool till the request is fulfilled.
    • If the unused focused ODCRs don’t fulfill the request but, Amazon EMR continues to launch the remaining capability into On-Demand swimming pools, within the lowest-price order by default.

For extra particulars concerning the allocation technique, check with Allocation technique as an example fleets or Amazon EMR Help for Focused ODCR.

Spiky workloads

Spiky workloads are outlined by unpredictable and infrequently important fluctuations in processing calls for, triggered by components resembling rare however resource-intensive periodic batch processing jobs. For instance, a geographic info system processes location information from tens of millions of customers in actual time to offer up-to-date site visitors info, calculate routes, and counsel factors of curiosity. Consumer location information is consistently being generated, however the quantity can spike dramatically throughout rush hour or particular occasions, as illustrated within the following determine. This graph exhibits the variety of used assets (Amazon EC2) by hour; it varies from 1 when the cluster scales in, ready for jobs, to spikes of 1,000 nodes.

If you happen to’re operating spiky workloads with restricted flexibility in occasion kind, household, and Availability Zone, you would possibly face ICE errors when the out there capability can’t meet the cluster’s scaling necessities. To deal with this, we discover a set of finest practices for EMR cluster creation to maximise availability and steadiness price-performance. Though spiky workloads current a singular problem in useful resource administration, configuring EMR occasion fleets presents a strong answer. By utilizing numerous occasion sorts, prioritized allocation methods, Availability Zone flexibility, and managed scaling, organizations can create a strong, cost-effective infrastructure able to dealing with unpredictable workload patterns. This configuration presents the next advantages:

  • Improved availability – By diversifying occasion sorts and utilizing a number of Availability Zones, the cluster mitigates inadequate capability points
  • Price financial savings – Allocation methods scale back prices whereas minimizing interruptions
  • Resilience for spiky workloads – Prioritizing occasion generations supplies seamless scaling beneath various calls for
  • Optimized efficiency – Managed scaling dynamically adjusts assets to satisfy workload calls for effectively

Introduce EC2 occasion flexibility and occasion fleets with a prioritized allocation technique

Amazon EMR helps occasion flexibility with occasion fleet deployment. Occasion fleets offer you a greater variety of choices and intelligence round occasion provisioning. Now you can present an inventory of as much as 30 occasion sorts with corresponding weighted capacities and spot bid costs (together with spot blocks) utilizing the AWS CLI or AWS CloudFormation. Amazon EMR will routinely provision On-Demand and Spot capability throughout these occasion sorts when creating your cluster. This may make it extra easy and more cost effective to shortly get hold of and preserve your required capability to your clusters. In August 2024, Amazon EMR launched the prioritized allocation technique to boost occasion flexibility with occasion fleets. This characteristic means that you can specify precedence ranges to your occasion sorts, enabling Amazon EMR to allocate capability to the highest-priority situations first. This technique helps enhance value financial savings and reduces the time required to launch clusters, even in eventualities with restricted capability. For extra particulars, see Amazon EMR assist prioritized and capacity-optimized-prioritized allocation methods for EC2 situations. To maximise cost-efficiency and availability for spiky workloads, mix the price-performance benefits of new-generation situations with the broader availability of previous-generation situations. For workloads with strict latency necessities, repair the occasion dimension to keep up constant efficiency. This strategy takes benefit of the strengths of each occasion generations, offering flexibility and reliability lowering the probability of capability constraints. For On-Demand nodes, select the prioritized allocation technique, so the cluster tries to make use of newer-generation situations first. Whereas configuring the occasion fleet, prepare situations in a prioritized order reflecting price-performance and availability trade-offs, for instance:

  • Major node – m8g.12xlarge > m8g.16xlarge > m7g.12xlarge > m7g.16xlarge
  • Core node – r8g.8xlarge > r8g.12xlarge > r7g.8xlarge > r6g.16xlarge > r5.16xlarge
  • Process Node – r8g.8xlarge > r8g.12xlarge > r7g.8xlarge > r6g.16xlarge > r5.16xlarge

For Spot Situations, be certain that the capacity-optimized prioritized allocation technique is chosen to cut back interruptions. See the next CloudFormation template snippet for instance:

...
       "Properties": {
         "Situations": {
          "MasterInstanceFleet": {
            "Identify": "cfnMaster",
            "InstanceTypeConfigs": [
               {
                 "BidPrice": "10.50",
                 "InstanceType": "m5.xlarge",
                 "Priority": "1",
 ...
             "LaunchSpecifications": {
               "SpotSpecification": {
                 "TimeoutAction": "SWITCH_TO_ON_DEMAND",
                 "TimeoutDurationMinutes": 20,
                 "AllocationStrategy": "CAPACITY_OPTIMIZED_PRIORITIZED"
               },
               "OnDemandSpecification": {
                "AllocationStrategy": "PRIORITIZED"
               }
 ...

Select subnets with EMR instance fleets

When creating a cluster, specify multiple EC2 subnets within a virtual private cloud (VPC), each corresponding to a different Availability Zone. Amazon EMR provides multiple subnet (Availability Zone) options by employing subnet filtering at cluster launch, and selects one of the subnets that has adequate available IP addresses to successfully launch all instance fleets. If Amazon EMR can’t find a subnet with sufficient IP addresses to launch the whole cluster, it will prioritize the subnet that can at least launch the core and primary instance fleets.

Use managed scaling

Managed scaling is another powerful feature of Amazon EMR that automatically adjusts the number of instances in your cluster based on workload demands. This makes sure that your cluster scales up during periods of high demand to meet processing requirements and scales down during idle times to save costs. With managed scaling, you can set minimum and maximum scaling limits, giving you control over costs while benefiting from an optimized and efficient cluster performance.

The following workflow illustrates Amazon EMR configured with instance fleets and managed scaling.

The workflow consists of the following steps:

  1. The user defines the EMR instance configurations and instance types, along with their launch priority.
  2. The user selects subnets for the Amazon EMR configuration to provide Availability Zone flexibility.
  3. Amazon EMR calls the Amazon EC2 Fleet API to provision instances based on the allocation strategy.
  4. The EMR instance fleet is launched.
  5. The cycle is repeated for scaling operations within the launched Availability Zone, providing optimized performance and scalability.

Conclusion

In this post, we demonstrated how to optimize capacity by analyzing EMR workloads and implementing strategies tailored to your workload patterns. As you implement any of the preceding strategies, remember to continuously monitor your cluster’s performance and adjust configurations based on your specific workload patterns and business needs. With the right approach, the challenges of spiky workloads can be transformed into opportunities for optimized performance and cost savings.

To effectively manage workloads with both baseline demands and unexpected spikes, consider implementing a hybrid approach in Amazon EMR. Use ODCRs for consistent baseline capacity and configure instance fleets with a strategic mix of ODCR, On-Demand, and Spot Instances prioritizing ODCR usage.

Try these strategies with your own use case, and leave your questions in the comments.


About the Authors

Deepmala Agarwal works as an AWS Data Specialist Solutions Architect. She is passionate about helping customers build out scalable, distributed, and data-driven solutions on AWS. When not at work, Deepmala likes spending time with family, walking, listening to music, watching movies, and cooking!

Suba Palanisamy is a Senior Technical Account Manager, helping customers achieve operational excellence on AWS. Suba is passionate about all things data and analytics. She enjoys traveling with her family and playing board games.

Flavio Torres is a Principal Technical Account Manager at AWS. Flavio helps Enterprise Support customers design, deploy, and scale resilient cloud applications. Outside of work, he enjoys hiking and barbecuing.

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