Files
T
mukul975 cb8d79e068 Map all 754 skills to MITRE ATT&CK v19.1
- Add validated mitre_attack frontmatter to all 754 skills (286 distinct
  techniques), verified against MITRE ATT&CK v19.1 via the official
  mitreattack-python library: 0 revoked, deprecated, or invalid IDs
- Curate precise per-skill technique IDs for forensics, malware-analysis,
  threat-intel, and red-team skills (e.g. DCSync -> T1003.006,
  Kerberoasting -> T1558.003, Pass-the-Ticket -> T1550.003)
- Reconcile v19.1 tactic restructuring: Defense Evasion split into
  Stealth (TA0005) and Defense Impairment (TA0112); revoked T1562.*
  family and T1070.001/.002 remapped to active equivalents (T1685.*)
- Normalize word-split tags across 35 skills (remove filename-derived
  stopword tags, add semantic cybersecurity tags)
- Add api-reference.md for 3 skills that were missing it
- Update README ATT&CK section with accurate v19.1 tactic distribution
2026-06-01 12:13:29 +02:00

6.9 KiB

name, description, domain, subdomain, tags, version, author, license, nist_csf, mitre_attack
name description domain subdomain tags version author license nist_csf mitre_attack
performing-kubernetes-etcd-security-assessment Assess the security posture of Kubernetes etcd clusters by evaluating encryption at rest, TLS configuration, access controls, backup encryption, and network isolation. cybersecurity container-security
kubernetes
etcd
encryption
tls
security-assessment
backup
secrets
control-plane
1.0 mahipal Apache-2.0
PR.PS-01
PR.IR-01
ID.AM-08
DE.CM-01
T1610
T1611
T1609
T1525
T1573

Performing Kubernetes etcd Security Assessment

Overview

etcd is the distributed key-value store that serves as Kubernetes' backing store for all cluster data, including Secrets, RBAC policies, ConfigMaps, and workload configurations. Without proper hardening, etcd exposes all cluster secrets in plaintext, making it the highest-value target for attackers who gain control plane access. A comprehensive security assessment covers encryption at rest, TLS for transport, access control, backup security, and network isolation.

When to Use

  • When conducting security assessments that involve performing kubernetes etcd security assessment
  • When following incident response procedures for related security events
  • When performing scheduled security testing or auditing activities
  • When validating security controls through hands-on testing

Prerequisites

  • Access to Kubernetes control plane nodes
  • SSH access to etcd cluster nodes (or etcdctl configured)
  • CIS Kubernetes Benchmark reference document
  • Understanding of TLS certificate management and EncryptionConfiguration

Assessment Areas

1. Encryption at Rest

Verify that Kubernetes encrypts Secret data stored in etcd:

# Check if EncryptionConfiguration is configured on API server
ps aux | grep kube-apiserver | grep encryption-provider-config

# View the encryption configuration
cat /etc/kubernetes/enc/encryption-config.yaml

Expected secure configuration:

apiVersion: apiserver.config.k8s.io/v1
kind: EncryptionConfiguration
resources:
  - resources:
      - secrets
      - configmaps
    providers:
      - aescbc:
          keys:
            - name: key1
              secret: <base64-encoded-32-byte-key>
      - identity: {}  # Fallback for reading unencrypted data

Verify secrets are actually encrypted in etcd:

# Read a secret directly from etcd
ETCDCTL_API=3 etcdctl \
  --endpoints=https://127.0.0.1:2379 \
  --cacert=/etc/kubernetes/pki/etcd/ca.crt \
  --cert=/etc/kubernetes/pki/etcd/server.crt \
  --key=/etc/kubernetes/pki/etcd/server.key \
  get /registry/secrets/default/my-secret | hexdump -C | head -20

# If encrypted, output starts with "k8s:enc:aescbc:v1:key1"
# If NOT encrypted, you'll see plaintext key-value pairs

2. TLS Transport Security

# Verify etcd uses TLS for client connections
ETCDCTL_API=3 etcdctl endpoint health \
  --endpoints=https://127.0.0.1:2379 \
  --cacert=/etc/kubernetes/pki/etcd/ca.crt \
  --cert=/etc/kubernetes/pki/etcd/server.crt \
  --key=/etc/kubernetes/pki/etcd/server.key

# Check peer TLS configuration
ps aux | grep etcd | tr ' ' '\n' | grep -E "peer-cert|peer-key|peer-trusted-ca"

# Verify certificate expiration
openssl x509 -in /etc/kubernetes/pki/etcd/server.crt -noout -enddate
openssl x509 -in /etc/kubernetes/pki/etcd/peer.crt -noout -enddate

Expected flags:

Flag Required Value Purpose
--cert-file Path to server cert Client-to-server TLS
--key-file Path to server key Client-to-server TLS
--trusted-ca-file Path to CA cert Client certificate validation
--peer-cert-file Path to peer cert Peer-to-peer TLS
--peer-key-file Path to peer key Peer-to-peer TLS
--peer-trusted-ca-file Path to peer CA Peer certificate validation
--client-cert-auth true Require client certificates
--peer-client-cert-auth true Require peer certificates

3. Access Control

# Verify etcd is not exposed on all interfaces
ps aux | grep etcd | tr ' ' '\n' | grep listen-client-urls
# Should be: https://127.0.0.1:2379 (not 0.0.0.0)

# Check who can access etcd certificates
ls -la /etc/kubernetes/pki/etcd/
# Should be readable only by root/etcd user

# Verify API server is the only etcd client
ss -tlnp | grep 2379
# Only kube-apiserver should have connections

4. Backup Security

# Create an encrypted etcd backup
ETCDCTL_API=3 etcdctl snapshot save /backup/etcd-snapshot.db \
  --endpoints=https://127.0.0.1:2379 \
  --cacert=/etc/kubernetes/pki/etcd/ca.crt \
  --cert=/etc/kubernetes/pki/etcd/server.crt \
  --key=/etc/kubernetes/pki/etcd/server.key

# Encrypt the backup file
gpg --symmetric --cipher-algo AES256 /backup/etcd-snapshot.db

# Verify backup integrity
ETCDCTL_API=3 etcdctl snapshot status /backup/etcd-snapshot.db --write-out=table

5. Network Isolation

# Verify etcd ports are firewalled
iptables -L -n | grep -E "2379|2380"

# Check if etcd is accessible from worker nodes (should NOT be)
# Run from a worker node:
curl -k https://<control-plane-ip>:2379/health
# Should be rejected/timeout

CIS Benchmark Checks

CIS Control Check Expected Result
2.1 etcd cert-file set TLS certificate configured
2.2 etcd client-cert-auth Client certificate authentication enabled
2.3 etcd auto-tls disabled auto-tls=false
2.4 etcd peer cert-file set Peer TLS configured
2.5 etcd peer client-cert-auth Peer authentication enabled
2.6 etcd peer auto-tls disabled peer-auto-tls=false
2.7 etcd unique CA Separate CA for etcd (not shared with cluster)

Key Rotation Procedure

# 1. Generate new encryption key
NEW_KEY=$(head -c 32 /dev/urandom | base64)

# 2. Update EncryptionConfiguration with new key first
cat > /etc/kubernetes/enc/encryption-config.yaml <<EOF
apiVersion: apiserver.config.k8s.io/v1
kind: EncryptionConfiguration
resources:
  - resources:
      - secrets
    providers:
      - aescbc:
          keys:
            - name: key2
              secret: ${NEW_KEY}
            - name: key1
              secret: <old-key>
      - identity: {}
EOF

# 3. Restart API server to pick up new config
# 4. Re-encrypt all secrets with new key
kubectl get secrets --all-namespaces -o json | \
  kubectl replace -f -

# 5. Remove old key from EncryptionConfiguration
# 6. Restart API server again

References