detecting-cryptomining-in-cloud▌
mukul975/Anthropic-Cybersecurity-Skills · updated May 25, 2026
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This skill teaches security teams how to detect and respond to unauthorized cryptocurrency mining operations in cloud environments. It covers identifying cryptomining indicators through compute usage anomalies, network traffic patterns to mining pools, GuardDuty CryptoCurrency findings, and runtime process monitoring on EC2, ECS, EKS, and Azure Automation workloads.
| name | detecting-cryptomining-in-cloud |
| description | 'This skill teaches security teams how to detect and respond to unauthorized cryptocurrency mining operations in cloud environments. It covers identifying cryptomining indicators through compute usage anomalies, network traffic patterns to mining pools, GuardDuty CryptoCurrency findings, and runtime process monitoring on EC2, ECS, EKS, and Azure Automation workloads. ' |
| domain | cybersecurity |
| subdomain | cloud-security |
| tags | - cryptomining-detection - cloud-abuse - resource-hijacking - guardduty-crypto - cost-anomaly |
| version | 1.0.0 |
| author | mahipal |
| license | Apache-2.0 |
| nist_csf | - PR.IR-01 - ID.AM-08 - GV.SC-06 - DE.CM-01 |
Detecting Cryptomining in Cloud
When to Use
- When cloud billing alerts indicate unexpected compute cost spikes
- When GuardDuty generates CryptoCurrency or Impact finding types
- When investigating compromised IAM credentials that may be used to launch mining instances
- When monitoring container workloads for unauthorized process execution
- When establishing proactive detection controls against resource hijacking attacks
Do not use for legitimate cryptocurrency mining operations, for non-cloud mining detection on physical hardware, or for general malware analysis unrelated to mining activity.
Prerequisites
- Amazon GuardDuty enabled with Runtime Monitoring for EC2, ECS, and EKS
- CloudWatch or Azure Monitor configured for compute utilization alerting
- VPC Flow Logs enabled for network traffic analysis to mining pool IPs
- AWS Cost Anomaly Detection or Azure Cost Management alerts configured
Workflow
Step 1: Establish Detection Through Multiple Signals
Deploy detection across four signal categories: cost anomalies, compute utilization, network traffic, and runtime processes.
# AWS Cost Anomaly Detection
aws ce create-anomaly-monitor \
--anomaly-monitor '{
"MonitorName": "EC2CostSpike",
"MonitorType": "DIMENSIONAL",
"MonitorDimension": "SERVICE"
}'
aws ce create-anomaly-subscription \
--anomaly-subscription '{
"SubscriptionName": "CryptoMiningAlert",
"MonitorArnList": ["arn:aws:ce::123456789012:anomalymonitor/monitor-id"],
"Subscribers": [{"Address": "[email protected]", "Type": "EMAIL"}],
"Threshold": 50.0,
"Frequency": "IMMEDIATE"
}'
# CloudWatch alarm for CPU utilization spike
aws cloudwatch put-metric-alarm \
--alarm-name HighCPUUtilization \
--namespace AWS/EC2 \
--metric-name CPUUtilization \
--statistic Average \
--period 300 \
--threshold 90 \
--comparison-operator GreaterThanThreshold \
--evaluation-periods 3 \
--alarm-actions "arn:aws:sns:us-east-1:123456789012:security-alerts"
Step 2: Monitor GuardDuty CryptoCurrency Findings
Configure alerting for GuardDuty findings specific to cryptocurrency mining activity on EC2, ECS, and EKS workloads.
Key GuardDuty finding types for cryptomining:
CryptoCurrency:EC2/BitcoinTool.B- Network connections to crypto-related domainsCryptoCurrency:Runtime/BitcoinTool.B- Runtime detection of mining process executionImpact:EC2/BitcoinTool.B- EC2 instance communicating with known Bitcoin mining poolsImpact:Runtime/CryptoMinerExecuted- Crypto mining binary execution detected by runtime agent
# EventBridge rule for cryptocurrency findings
aws events put-rule \
--name CryptoMiningDetection \
--event-pattern '{
"source": ["aws.guardduty"],
"detail-type": ["GuardDuty Finding"],
"detail": {
"type": [
{"prefix": "CryptoCurrency:"},
{"prefix": "Impact:EC2/BitcoinTool"},
{"prefix": "Impact:Runtime/CryptoMiner"}
]
}
}'
# Auto-remediation Lambda for crypto findings
aws events put-targets \
--rule CryptoMiningDetection \
--targets '[{
"Id": "CryptoAutoRemediate",
"Arn": "arn:aws:lambda:us-east-1:123456789012:function/crypto-remediate"
}]'
Step 3: Analyze Network Traffic for Mining Pool Connections
Monitor VPC Flow Logs and DNS queries for connections to known cryptocurrency mining pools operating on common ports (3333, 4444, 5555, 8333, 9999, 14444).
// Sentinel KQL query for mining pool connections
AzureNetworkAnalytics_CL
| where TimeGenerated > ago(24h)
| where DestPort_d in (3333, 4444, 5555, 8333, 9999, 14444, 14433, 45700)
| summarize ConnectionCount = count(), BytesSent = sum(BytesSent_d)
by SrcIP_s, DestIP_s, DestPort_d, bin(TimeGenerated, 1h)
| where ConnectionCount > 10
| project TimeGenerated, SrcIP_s, DestIP_s, DestPort_d, ConnectionCount, BytesSent
# AWS Athena query for VPC Flow Logs mining pool detection
cat << 'EOF' > mining-detection.sql
SELECT srcaddr, dstaddr, dstport, protocol,
COUNT(*) as connection_count,
SUM(bytes) as total_bytes
FROM vpc_flow_logs
WHERE dstport IN (3333, 4444, 5555, 8333, 9999, 14444)
AND action = 'ACCEPT'
AND start >= date_add('hour', -24, now())
GROUP BY srcaddr, dstaddr, dstport, protocol
HAVING COUNT(*) > 10
ORDER BY connection_count DESC
EOF
Step 4: Detect Mining in Container Environments
Monitor ECS task definitions and EKS pod deployments for known mining container images and suspicious process execution.
# Check for recently registered ECS task definitions with suspicious images
aws ecs list-task-definitions --sort DESC --max-items 50 | \
jq -r '.taskDefinitionArns[]' | while read arn; do
aws ecs describe-task-definition --task-definition "$arn" \
--query 'taskDefinition.containerDefinitions[*].[name,image]' --output text
done
# Known malicious mining images to watch for:
# - Images with high pull counts from unknown registries
# - Images containing xmrig, cpuminer, minergate, or ccminer binaries
# - Images with entrypoint pointing to /tmp/.hidden or /dev/shm paths
# Monitor CloudTrail for suspicious ECS/EKS activity
aws cloudtrail lookup-events \
--lookup-attributes AttributeKey=EventName,AttributeValue=RegisterTaskDefinition \
--start-time $(date -d '-24 hours' +%Y-%m-%dT%H:%M:%S) \
--query 'Events[*].[EventName,Username,EventTime]'
Step 5: Respond and Contain Mining Activity
Execute immediate containment actions when mining is confirmed, preserving forensic evidence before terminating the malicious workloads.
# Auto-remediation Lambda for cryptomining incidents
import boto3
import json
def lambda_handler(event, context):
finding = event['detail']
resource_type = finding['resource']['resourceType']
if resource_type == 'Instance':
instance_id = finding['resource']['instanceDetails']['instanceId']
ec2 = boto3.client('ec2')
# Snapshot EBS volumes for forensics before isolation
volumes = ec2.describe_instances(InstanceIds=[instance_id])
for reservation in volumes['Reservations']:
for instance in reservation['Instances']:
for vol in instance['BlockDeviceMappings']:
volume_id = vol['Ebs']['VolumeId']
ec2.create_snapshot(
VolumeId=volume_id,
Description=f'Forensic snapshot - crypto mining - {instance_id}',
TagSpecifications=[{
'ResourceType': 'snapshot',
'Tags': [{'Key': 'Incident', 'Value': 'CryptoMining'},
{'Key': 'SourceInstance', 'Value': instance_id}]
}]
)
# Disable API termination protection if set by attacker
ec2.modify_instance_attribute(
InstanceId=instance_id,
DisableApiTermination={'Value': False}
)
# Isolate instance with empty security group
vpc_id = finding['resource']['instanceDetails']['networkInterfaces'][0]['vpcId']
isolation_sg = ec2.create_security_group(
GroupName=f'crypto-isolation-{instance_id}',
Description='Cryptomining isolation - no traffic allowed',
VpcId=vpc_id
)
# Revoke default egress rule
ec2.revoke_security_group_egress(
GroupId=isolation_sg['GroupId'],
IpPermissions=[{'IpProtocol': '-1', 'IpRanges': [{'CidrIp': '0.0.0.0/0'}]}]
)
ec2.modify_instance_attribute(
InstanceId=instance_id,
Groups=[isolation_sg['GroupId']]
)
return {'status': 'contained', 'instance': instance_id}
Step 6: Trace Initial Access Vector
Investigate CloudTrail logs to determine how the attacker gained access to deploy mining workloads. Common vectors include compromised IAM credentials, exposed access keys, and supply chain attacks through container images.
# Trace the initial access for the compromised identity
aws cloudtrail lookup-events \
--lookup-attributes AttributeKey=Username,AttributeValue=compromised-user \
--start-time 2025-02-01T00:00:00Z \
--query 'Events[?EventName==`ConsoleLogin` || EventName==`GetSessionToken`].[EventTime,SourceIPAddress,EventName]' \
--output table
# Check for RunInstances calls in unusual regions
for region in $(aws ec2 describe-regions --query 'Regions[*].RegionName' --output text); do
count=$(aws cloudtrail lookup-events \
--region $region \
--lookup-attributes AttributeKey=EventName,AttributeValue=RunInstances \
--start-time $(date -d '-7 days' +%Y-%m-%dT%H:%M:%S) \
--query 'Events | length(@)')
if [ "$count" -gt 0 ]; then
echo "Region: $region - RunInstances calls: $count"
fi
done
Key Concepts
| Term | Definition |
|---|---|
| Cryptojacking | Unauthorized use of cloud compute resources to mine cryptocurrency, typically Monero (XMR) due to its CPU-friendly algorithm |
| Stratum Protocol | Mining pool communication protocol operating on TCP ports 3333, 4444, or custom ports, identifiable in network flow logs |
| XMRig | Open-source Monero mining software commonly found in cryptojacking attacks, often deployed as a hidden binary in containers |
| API Termination Protection | EC2 attribute that attackers enable to prevent security teams from quickly terminating compromised mining instances |
| Cost Anomaly Detection | AWS service that uses machine learning to identify unusual spending patterns that may indicate unauthorized resource usage |
| Runtime Monitoring | GuardDuty capability that deploys agents to detect process-level activity including crypto mining binary execution |
| Attack Sequence | GuardDuty Extended Threat Detection finding correlating credential theft, infrastructure deployment, and mining execution into a single Critical event |
Tools & Systems
- Amazon GuardDuty: Detects cryptocurrency mining through network traffic analysis, DNS queries, and runtime process monitoring
- AWS Cost Anomaly Detection: Machine learning-based service identifying unexpected cost increases from mining instance deployment
- VPC Flow Logs: Network traffic metadata showing connections to mining pool IP addresses and ports
- Falco: Open-source runtime security tool for detecting crypto mining process execution in containers
- Amazon Detective: Graph-based investigation tool for tracing the attack path from initial access to mining deployment
Common Scenarios
Scenario: Compromised IAM Credentials Used for Large-Scale EC2 Mining
Context: Exposed IAM credentials from a public GitHub repository are used to launch 200 GPU instances across 8 AWS regions within 10 minutes. The attacker enables API termination protection and disables CloudTrail in each region.
Approach:
- AWS Cost Anomaly Detection triggers an immediate alert for $15,000+ hourly EC2 spend
- GuardDuty generates Stealth:IAMUser/CloudTrailLoggingDisabled and CryptoCurrency:EC2/BitcoinTool.B findings
- Immediately deactivate the compromised IAM access key
- Re-enable CloudTrail in all affected regions to restore visibility
- Disable API termination protection on all 200 instances and terminate them
- Create forensic snapshots of representative instances before termination
- Review the GitHub commit history to identify and remove the exposed credentials
- Deploy AWS Config rules preventing CloudTrail disabling and enforcing IMDSv2
Pitfalls: Failing to check all AWS regions for mining instances leaves active miners running in overlooked regions. Not disabling API termination protection before attempting to stop instances wastes response time.
Output Format
Cryptomining Incident Response Report
=======================================
Incident ID: INC-2025-0223-CRYPTO
Detection Time: 2025-02-23T14:23:00Z
Containment Time: 2025-02-23T14:41:00Z (18 minutes)
INITIAL ACCESS:
Vector: Exposed IAM access key in public GitHub repository
Credential: AKIAIOSFODNN7EXAMPLE (user: ci-deploy)
First Malicious Activity: 2025-02-23T14:12:00Z
IMPACT:
Instances Launched: 200 (p3.2xlarge GPU instances)
Regions Affected: 8 (us-east-1, us-west-2, eu-west-1, eu-central-1, ...)
Estimated Cost: $4,200 (18 minutes at $15,400/hour)
Mining Pool: stratum+tcp://pool.supportxmr.com:3333
Cryptocurrency: Monero (XMR)
DETECTION SIGNALS:
[14:15] GuardDuty: Stealth:IAMUser/CloudTrailLoggingDisabled (HIGH)
[14:18] Cost Anomaly: EC2 spend 4,200% above baseline
[14:23] GuardDuty: CryptoCurrency:EC2/BitcoinTool.B (HIGH) x 200
CONTAINMENT ACTIONS:
[14:25] IAM access key AKIAIOSFODNN7EXAMPLE deactivated
[14:30] CloudTrail re-enabled in all 8 regions
[14:35] API termination protection disabled on 200 instances
[14:41] All 200 instances terminated
REMEDIATION:
- Compromised access key deleted
- GitHub repository secret scanning enabled
- AWS Config rule deployed: cloudtrail-enabled (auto-remediate)
- SCP deployed: deny ec2:RunInstances for GPU instance types without approval
How to use detecting-cryptomining-in-cloud on Cursor
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Prerequisites
Before installing skills in Cursor, ensure your development environment meets these requirements:
- ›Cursor installed and configured on your development machine
- ›Node.js version 16.0+ with npm package manager (verify with
node --version) - ›Active project directory or workspace where you want to add detecting-cryptomining-in-cloud
Execute installation command
Execute the skills CLI command in your project's root directory to begin installation:
The skills CLI fetches detecting-cryptomining-in-cloud from GitHub repository mukul975/Anthropic-Cybersecurity-Skills and configures it for Cursor.
Select Cursor when prompted
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Verify installation
Confirm successful installation by checking the skill directory location:
Reload or restart Cursor to activate detecting-cryptomining-in-cloud. Access the skill through slash commands (e.g., /detecting-cryptomining-in-cloud) or your agent's skill management interface.
Security & Verification Notice
We perform automated surface-level scans (Gen AI Scanner, Socket, Snyk) during installation. These checks detect common vulnerabilities but do not guarantee complete security. Always review skill source code and verify the publisher's reputation before production use.
Skills execute code in your development environment. Always verify the publisher's identity, review recent commits, and test in isolated environments before production deployment.
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Use Cases▌
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Knowledge Enhancement
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Example
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Accelerate learning and skill development by 2x
Quality Improvement
Enhance output quality through reviews, suggestions, and refinements
Example
Review drafts, suggest improvements, catch errors
Improve work quality by 30-40% with less effort
Implementation Guide▌
Prerequisites
- ›Claude Desktop or compatible AI client with skill support
- ›Clear understanding of task or problem to solve
- ›Willingness to iterate and refine outputs
Time Estimate
15-45 minutes depending on use case complexity
Installation Steps
- 1.Install skill using provided installation command
- 2.Test with simple use case relevant to your work
- 3.Evaluate output quality and relevance
- 4.Iterate on prompts to improve results
- 5.Integrate into regular workflow if valuable
Common Pitfalls
- ⚠Expecting perfect results without iteration
- ⚠Not providing enough context in prompts
- ⚠Using skill for tasks outside its intended scope
- ⚠Accepting outputs without review and validation
Best Practices▌
✓ Do
- +Start with clear, specific prompts
- +Provide relevant context and constraints
- +Review and refine all outputs before using
- +Iterate to improve output quality
- +Document successful prompt patterns
✗ Don't
- −Don't use without understanding skill limitations
- −Don't skip validation of outputs
- −Don't share sensitive information in prompts
- −Don't expect skill to replace human judgment
💡 Pro Tips
- ★Be specific about desired format and style
- ★Ask for multiple options to choose from
- ★Request explanations to understand reasoning
- ★Combine AI efficiency with human expertise
When to Use This▌
✓ Use When
Use when skill capabilities match your task, clear ROI on time saved, and you can validate outputs. Best for repetitive tasks, learning, and quality improvement.
✗ Avoid When
Avoid when task requires deep expertise you can't validate, involves sensitive decisions, or when learning process is more valuable than speed of completion.
Learning Path▌
- 1Familiarize yourself with skill capabilities and limitations
- 2Start with low-risk, non-critical tasks
- 3Progress to more complex and valuable use cases
- 4Build expertise through regular use and experimentation
Discussion
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Ratings
4.5★★★★★65 reviews- ★★★★★Harper Gill· Dec 28, 2024
detecting-cryptomining-in-cloud reduced setup friction for our internal harness; good balance of opinion and flexibility.
- ★★★★★Mei Perez· Dec 24, 2024
detecting-cryptomining-in-cloud fits our agent workflows well — practical, well scoped, and easy to wire into existing repos.
- ★★★★★Mei Mensah· Dec 16, 2024
detecting-cryptomining-in-cloud has been reliable in day-to-day use. Documentation quality is above average for community skills.
- ★★★★★Valentina Mehta· Dec 12, 2024
We added detecting-cryptomining-in-cloud from the explainx registry; install was straightforward and the SKILL.md answered most questions upfront.
- ★★★★★Aisha Torres· Dec 12, 2024
Registry listing for detecting-cryptomining-in-cloud matched our evaluation — installs cleanly and behaves as described in the markdown.
- ★★★★★Pratham Ware· Dec 8, 2024
detecting-cryptomining-in-cloud fits our agent workflows well — practical, well scoped, and easy to wire into existing repos.
- ★★★★★Sakshi Patil· Nov 27, 2024
detecting-cryptomining-in-cloud is among the better-maintained entries we tried; worth keeping pinned for repeat workflows.
- ★★★★★Carlos Gonzalez· Nov 19, 2024
I recommend detecting-cryptomining-in-cloud for anyone iterating fast on agent tooling; clear intent and a small, reviewable surface area.
- ★★★★★Mei Robinson· Nov 15, 2024
detecting-cryptomining-in-cloud is among the better-maintained entries we tried; worth keeping pinned for repeat workflows.
- ★★★★★Mateo Desai· Nov 3, 2024
Keeps context tight: detecting-cryptomining-in-cloud is the kind of skill you can hand to a new teammate without a long onboarding doc.
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