Linuxcent

Network Flow Observability — What Every Connection Reveals

May 3, 2026 by Vamshi Krishna Santhapuri

Reading Time: 9 minutes

eBPF: From Kernel to Cloud, Episode 10
What Is eBPF? · The BPF Verifier · eBPF vs Kernel Modules · eBPF Program Types · eBPF Maps · CO-RE and libbpf · XDP · TC eBPF · bpftrace · Network Flow Observability · DNS Observability

TL;DR

Network flow observability with eBPF attaches persistent programs to TC hooks and records every connection attempt, retransmit, reset, and drop — continuously, with no sampling
(TC hook = Traffic Control hook: the point in the Linux network stack where eBPF programs intercept packets after ingress or before egress, tied to a specific network interface)
APM tools and service mesh telemetry are interpretations of what happened; kernel-level flow data from TC hooks is the raw event stream they all derive from
Retransmit counters at the kernel level reveal congestion, half-open connections, and remote endpoint failures that application logs never surface
Cilium’s Hubble and similar tools (Pixie, Retina) are eBPF flow exporters — they run TC programs, collect perf_event or ringbuf events, and expose them over an API
You can verify what flow data a tool is actually collecting with four bpftool commands — without reading documentation
Production caution: flow maps grow with the number of active connections; pin and bound your maps, and account for the per-packet overhead on high-throughput interfaces

EP09 showed bpftrace as an on-demand kernel query tool — compile a question, get an answer, clean up. Network flow observability with eBPF is the persistent version: programs that stay attached to TC hooks across your entire fleet, recording every connection without waiting for you to ask. When a client reports intermittent failures that appear nowhere in application logs, that persistent record is what you query. This episode covers how that layer works and how to read it.

Quick Check: What Flow Data Is Your Cluster Already Collecting?

Before building anything new, check what’s already running. If you have Cilium, Pixie, or Retina on your cluster, eBPF flow programs are already attached:

# SSH into a worker node, then:

# What TC programs are attached to cluster interfaces?
bpftool net list

# Expected output on a Cilium node:
# xdp:
#
# tc:
# eth0(2) clsact/ingress prog_id 38 prio 1 handle 0x1 direct-action
# eth0(2) clsact/egress  prog_id 39 prio 1 handle 0x1 direct-action
# lxc12a3(15) clsact/ingress prog_id 41 prio 1 handle 0x1 direct-action
# lxc12a3(15) clsact/egress  prog_id 42 prio 1 handle 0x1 direct-action

# What maps are those programs holding state in?
bpftool map list | grep -E "flow|conn|sock|nat"

# Sample output:
# 24: hash  name cilium_ct4_global  flags 0x0
#     key 24B  value 56B  max_entries 65536  memlock 4718592B
# 25: hash  name cilium_ct4_local   flags 0x0
#     key 24B  value 56B  max_entries 8192   memlock 589824B

Each lxcXXXX interface is a pod’s veth pair. The TC programs on those interfaces are what Cilium uses to enforce NetworkPolicy and collect flow telemetry. If you see prog_id values on pod interfaces, your cluster is already doing kernel-level flow collection.

Not running Cilium? On a plain kubeadm or EKS node without a CNI that uses eBPF, bpftool net list will show no TC programs on pod interfaces — just whatever kube-proxy or the CNI plugin installed. You can still attach your own flow programs with tc qdisc add dev eth0 clsact — that’s the starting point this episode covers.

The client opened a ticket on a Tuesday afternoon. “Intermittent connection failures to the payment gateway. Started around 11 AM. Application logs say timeout. Retry logic is masking it for most users but the error rate is up 0.3%.”

I looked at the APM dashboard. The service showed elevated latency — p99 at 850ms versus a normal 120ms — but no hard errors at the application layer. The service mesh metrics showed the downstream call succeeding from the mesh’s perspective. The payment gateway team said their side looked clean.

Three tools. Three different answers. All of them interpreting the network. None of them were the network.

I ran:

bpftool map dump id 24 | grep -A5 "payment-gateway-ip"

The connection tracking map showed retransmit count 14 for a specific (src_ip, dst_ip, src_port, dst_port) tuple — the same 5-tuple, every 30 seconds, for 2 hours. The kernel was retransmitting. The TCP stack was compensating. The application was seeing sporadic success because retransmits eventually got through. The APM dashboard averaged that latency into a p99 and called it “elevated.”

The kernel had the truth. Everything above it was rounding.

Why Application-Level Metrics Miss What the Kernel Sees

Application metrics — APM spans, service mesh telemetry, load balancer health checks — operate at Layer 7. They measure round-trip time for complete requests, error codes returned, bytes transferred. They answer “did this request succeed?” not “what did the network do to make it succeed?”

The TCP stack underneath those requests handles retransmits, congestion window adjustments, RST packets, and half-open connections silently. From an application’s perspective, a request that required 3 retransmits before the ACK arrived looks identical to one that succeeded on the first attempt — slightly slower, but successful.

This is structural, not a tooling gap. Application-layer observability tools cannot see below their own protocol boundary. The kernel’s TCP implementation does not report upward when it retransmits. It just retransmits.

eBPF flow observability closes this gap by attaching programs directly to the network path — at the TC hook, which fires on every packet crossing a network interface — and recording what the kernel actually does.

How TC Hook Flow Programs Work

EP08 covered TC eBPF programs for pod network policy. Flow observability uses the same attachment point with a different purpose: instead of allowing or dropping packets, the program reads packet metadata and writes it to a map or ring buffer.

Pod sends packet
      ↓
veth interface (lxcXXXX)
      ↓
TC clsact/egress hook fires
      ↓
eBPF program reads:
  - src IP, dst IP
  - src port, dst port
  - protocol
  - packet size
  - TCP flags (SYN, ACK, FIN, RST, retransmit bit)
      ↓
Writes event to ringbuf (or perf_event_array)
      ↓
Userspace consumer reads ringbuf
      ↓
Aggregates to flow record
      ↓
Exports to Hubble/Prometheus/flow store

ringbuf — a BPF ring buffer: a lock-free, memory-efficient queue shared between a kernel eBPF program and a userspace consumer. The kernel program writes events; the userspace reader drains them. Used instead of perf_event_array in kernel 5.8+ because it avoids per-CPU memory waste and supports variable-length records. When you see Hubble exporting flows, it’s reading from a ringbuf that the TC program writes to.

The key structural property: the TC hook fires on every packet. Not sampled. Not throttled by default. Every SYN, every ACK, every RST, every retransmit. For flow observability, you typically aggregate at the program level — count packets and bytes per 5-tuple per second, rather than emitting an event per packet — but the raw visibility is there if you need it.

What Retransmit Telemetry Actually Reveals

Most flow observability implementations track TCP retransmits specifically because they are the clearest signal of network-layer trouble invisible to applications.

A TCP retransmit happens when a sender doesn’t receive an ACK within the retransmission timeout (RTO). The kernel resends the segment and doubles the timeout (exponential backoff). From the application’s perspective, the call takes longer. If retransmits keep clearing, the application sees success — just slow success.

perf_event — a kernel mechanism for collecting performance data. In eBPF, BPF_MAP_TYPE_PERF_EVENT_ARRAY lets kernel programs push variable-length records to userspace readers via a ring buffer per CPU. Older tools use perf_event_array; newer ones use BPF_MAP_TYPE_RINGBUF (single shared ring, more efficient). If you inspect an older version of Cilium’s flow exporter, you’ll see perf_event writes; newer versions use ringbuf.

To observe retransmits directly with bpftrace:

# Count retransmit events per destination IP — run for 60 seconds
bpftrace -e '
kprobe:tcp_retransmit_skb {
    $sk = (struct sock *)arg0;
    $daddr = ntop(AF_INET, $sk->__sk_common.skc_daddr);
    @retransmits[$daddr] = count();
}
interval:s:60 { print(@retransmits); clear(@retransmits); exit(); }
'

Sample output:

Attaching 2 probes...
@retransmits[10.96.0.10]:   2       # DNS service — normal
@retransmits[172.16.4.23]:  847     # payment gateway endpoint ← problem here
@retransmits[10.244.1.5]:   1       # normal pod-to-pod traffic

847 retransmits to a single endpoint in 60 seconds. That’s not noise. That’s a congested or half-open connection being retried 14 times per second by the TCP stack while the application layer averages it into “elevated latency.”

How Cilium Hubble Collects Flow Data

Hubble is the flow observability layer built into Cilium. Understanding how it works makes you able to reason about what it can and cannot see — and how to verify what it’s actually collecting.

Hubble’s architecture:

Kernel (per node)
├── TC eBPF programs on all pod veth interfaces
│     write flow events → BPF ringbuf
│
└── Hubble node agent (userspace)
      reads ringbuf
      enriches with pod metadata (Kubernetes API)
      exposes gRPC API

Cluster level
└── Hubble Relay
      aggregates per-node gRPC streams
      exposes single cluster-wide API

User tooling
└── hubble observe  /  Hubble UI  /  Prometheus exporter

The TC programs are writing raw packet events. The Hubble agent is the consumer that translates those events into Kubernetes-aware flow records — adding pod name, namespace, label, and policy verdict on top of the 5-tuple and TCP metadata the kernel provides.

To see what Hubble’s TC programs have attached:

# On any Cilium node
bpftool net list | grep lxc

# lxce4a1(23) clsact/ingress prog_id 61  ← Hubble flow program on pod interface ingress
# lxce4a1(23) clsact/egress  prog_id 62  ← Hubble flow program on pod interface egress
# lxcf7b2(31) clsact/ingress prog_id 63
# lxcf7b2(31) clsact/egress  prog_id 64

# Inspect one of those programs to confirm it's reading flow metadata
bpftool prog show id 61

# Output:
# 61: sched_cls  name tail_handle_nat  tag 3a8e2f1b4c7d9e0a  gpl
#     loaded_at 2026-04-22T09:13:45+0530  uid 0
#     xlated 2144B  jited 1382B  memlock 4096B  map_ids 24,31,38
#     btf_id 142

sched_cls is the BPF program type for TC — confirming these are TC-attached flow programs. map_ids 24,31,38 — those are the maps this program reads from and writes to. You can dump any of them:

bpftool map dump id 24 | head -40

# Output (connection tracking entry):
# [{
#     "key": {
#         "saddr": "10.244.1.5",        # ← source pod IP
#         "daddr": "172.16.4.23",        # ← destination IP
#         "sport": 48291,                # ← source port
#         "dport": 443,                  # ← destination port
#         "nexthdr": 6,                  # ← protocol: TCP
#         "flags": 3                     # ← CT_EGRESS | CT_ESTABLISHED
#     },
#     "value": {
#         "rx_packets": 14832,           # ← packets received
#         "tx_packets": 14831,           # ← packets sent
#         "rx_bytes": 3841024,           # ← bytes received
#         "tx_bytes": 3756288,           # ← bytes sent
#         "lifetime": 21600,             # ← seconds until entry expires
#         "rx_closing": 0,
#         "tx_closing": 0
#     }
# }]

That’s the ground truth. Not an APM span. Not a service mesh metric. The actual per-connection counters the kernel is maintaining for that 5-tuple.

Writing a Minimal Flow Observer with bpftrace

You don’t need Cilium or Hubble to get flow telemetry. bpftrace can produce it directly on any node with BTF:

# Persistent flow table: connections + packet counts for 2 minutes
bpftrace -e '
kprobe:tcp_sendmsg {
    $sk = (struct sock *)arg0;
    $daddr = ntop(AF_INET, $sk->__sk_common.skc_daddr);
    $dport = $sk->__sk_common.skc_dport >> 8;
    @flows[comm, $daddr, $dport] = count();
}
interval:s:30 { print(@flows); clear(@flows); }
' --timeout 120

Sample output (every 30 seconds):

@flows[curl, 93.184.216.34, 443]:         12    # curl → example.com:443
@flows[coredns, 10.96.0.10, 53]:          341   # CoreDNS upstream queries
@flows[payment-svc, 172.16.4.23, 443]:   1204   # payment service → gateway
@flows[nginx, 10.244.2.3, 8080]:          89    # nginx → upstream pod

For retransmit tracking specifically:

# Combined flow + retransmit watcher — runs until Ctrl-C
bpftrace -e '
kprobe:tcp_retransmit_skb {
    $sk = (struct sock *)arg0;
    $daddr = ntop(AF_INET, $sk->__sk_common.skc_daddr);
    @retx[comm, $daddr] = count();
}
kprobe:tcp_sendmsg {
    $sk = (struct sock *)arg0;
    $daddr = ntop(AF_INET, $sk->__sk_common.skc_daddr);
    @sends[comm, $daddr] = count();
}
interval:s:10 {
    printf("=== Retransmit ratio (last 10s) ===\n");
    print(@retx);
    print(@sends);
    clear(@retx);
    clear(@sends);
}
'

This gives you both the volume of sends and the retransmit count side by side — the ratio tells you whether retransmits are a rounding error (0.01%) or a signal (5%+).

⚠ Production Gotchas

Map size bounds matter. Connection tracking maps default to tens of thousands of entries. On nodes with high connection churn (serverless, short-lived batch jobs), maps can fill and start dropping new entries silently. Check bpftool map show id N for max_entries and monitor map utilization. Cilium exposes this as cilium_bpf_map_pressure in Prometheus.

Per-packet overhead on high-throughput interfaces. A TC program that fires on every packet on a 10Gbps interface processes millions of packets per second. Aggregating at the program level (count per 5-tuple rather than emit per packet) keeps overhead manageable — Cilium does this. A naive bpftrace one-liner that emits a perf event per packet will saturate the perf ring buffer under real load. Use ringbuf write paths or aggregate before emitting.

TC hook placement and direction confusion. Ingress TC on a pod’s veth (lxcXXXX) sees egress traffic from the pod’s perspective — because the host sees the packet arriving on the veth after the pod sent it. This reversal is consistent but confusing when you’re reading direction labels in flow records. EP08 covered this in detail for policy enforcement; the same asymmetry applies to flow data.

Retransmit counters reset on connection close. If you’re tracking retransmit totals for a long-lived connection, the count is stored in the kernel’s socket state and is cleared when the socket closes. For persistent tracking across reconnects, aggregate at the flow level in userspace before the connection closes.

Hubble flow visibility requires pod interfaces. Hubble only sees traffic that crosses a pod’s veth interface. Node-to-node traffic that doesn’t involve a pod (e.g., node SSH, kubelet-to-API-server on the node IP) is not captured by default. For host-level network observability, you need a TC program on the physical interface (eth0, ens3), not just on pod veth pairs.

Quick Reference

What you want to see	Command
What TC programs are attached	`bpftool net list`
Which maps a program uses	`bpftool prog show id N` (check `map_ids`)
Connection tracking entries	`bpftool map dump id N`
Retransmits per destination	`bpftrace -e 'kprobe:tcp_retransmit_skb { ... }'`
Flow counts per process	`bpftrace -e 'kprobe:tcp_sendmsg { @[comm, daddr] = count(); }'`
Hubble flow stream (Cilium)	`hubble observe --follow`
Hubble flows for one pod	`hubble observe --pod mynamespace/mypod --follow`
Verify map pressure	`bpftool map show id N` (check `max_entries` vs entries)

Kernel function	What it marks
`tcp_sendmsg`	Data being sent on a TCP socket
`tcp_recvmsg`	Data being received on a TCP socket
`tcp_retransmit_skb`	A segment being retransmitted
`tcp_send_reset`	RST being sent
`tcp_fin`	Connection teardown initiated
`tcp_connect`	New outbound TCP connection attempt

Key Takeaways

Network flow observability with eBPF attaches TC programs that record every connection event continuously — not sampled, not throttled, not filtered by what the application reports
Retransmit telemetry from tcp_retransmit_skb reveals congestion and endpoint failures that are structurally invisible to application-layer monitoring tools
Cilium Hubble, Pixie, and Retina are all eBPF flow exporters — they run TC programs, drain a ringbuf, enrich with Kubernetes metadata, and expose the result over an API
You can verify what any flow tool is actually collecting with bpftool net list, bpftool prog show, and bpftool map dump — four commands, no documentation needed
Map sizing and per-packet overhead are the two production concerns; aggregate at the kernel level, bound your maps, and monitor map pressure
The kernel’s connection tracking map is the ground truth. APM dashboards, service mesh metrics, and load balancer health checks are all interpretations of what that map contains

What’s Next

Flow observability tells you what connections exist. EP11 goes one level deeper: what names your pods are resolving those connections to. DNS is where a compromised workload first reveals itself — it queries a domain that has no business being queried from a production pod, and if you’re not watching the kernel-level DNS path, you won’t see it until after the damage.

DNS observability at the kernel level uses tracepoint hooks on the DNS syscall path — the same ground-truth approach as flow telemetry, but for name resolution: every query, every response, tied to the pod that made it, without deploying a sidecar.

Next: DNS observability at the kernel level — what your pods are actually resolving

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The Pipeline Gate — Hardened Images as a CI/CD Build Constraint

May 3, 2026 by Vamshi Krishna Santhapuri

Reading Time: 6 minutes

OS Hardening as Code, Episode 5
Cloud AMI Security Risks · Linux Hardening as Code · Multi-Cloud OS Hardening · Automated OpenSCAP Compliance · CI/CD Compliance Gate**

Focus Keyphrase: CI/CD compliance gate
Search Intent: Investigational
Meta Description: A compliance grade no one checks before deploying is decoration. The Pipeline API makes grade a build constraint — unhardened images never reach production. (158 chars)

TL;DR

A CI/CD compliance gate turns an OS hardening grade from a report into a build constraint — unhardened images fail the pipeline before they can be deployed
POST /api/pipeline/scan returns pass/fail against a minimum grade threshold — integrates into any CI/CD system that can make an HTTP request
Failed gate output tells engineers exactly which controls failed and what to fix — not just “blocked”
The gate works on both build-time grades (new images) and runtime grades (existing instances)
GitHub Actions, GitLab CI, Jenkins, and Tekton integrations are one curl command
The structural guarantee: an image that doesn’t pass the gate doesn’t exist in the deployment pipeline

The Problem: A Grade No One Checks Is Decoration

Pipeline without compliance gate:
  Build → Test → Security scan (results to dashboard) → Deploy

What actually happens:
  Build → Test → Security scan → "C grade, but we need to ship" → Deploy anyway
                                           │
                                           └─ Dashboard shows C grade
                                              Nobody is paged
                                              Deployment succeeds

A CI/CD compliance gate means the pipeline can’t continue if the grade is below threshold.

EP04 showed that automated OpenSCAP compliance gives every image a verified, reproducible grade before deployment. What it assumed is that someone checks the grade before deploying. They don’t — not under deadline pressure, not when the image has been “working fine for months,” not at 2am.

The same problem that made hardening runbooks skippable applies to compliance grades: if checking the grade is a discretionary step, it will be skipped.

A new microservice was deployed from an unhardened base image. The team had built it quickly during a sprint, used a community AMI as the base, and planned to harden it “in the next sprint.”

Three weeks later, a penetration test found it. SSH password authentication enabled. Three unnecessary services running — one of them with a known CVE. The finding: the instance had full inbound access from the VPC and was reachable from a compromised adjacent instance.

The deployment had gone through the normal CI/CD pipeline. Unit tests passed. Integration tests passed. A vulnerability scan ran. The scan produced a report that went to a dashboard. Nobody had a gate set up to fail the build if the image was unhardened.

The hardening work from the “next sprint” plan would have taken four hours. The pentest remediation took a week, plus the time to investigate what had been exposed during the three weeks the instance was running.

The CI/CD pipeline had every check except the one that would have caught the base image problem before the first deployment.

The Pipeline API

The Pipeline API is a single HTTP endpoint that takes an image or instance ID, checks it against a minimum grade, and returns pass or fail:

# Fail the pipeline if the image grade is below B
curl -sf -X POST https://stratum.yourdomain.com/api/pipeline/scan \
  -H "Authorization: Bearer ${STRATUM_TOKEN}" \
  -H "Content-Type: application/json" \
  -d '{
    "image_id": "ami-0a7f3c9e82d1b4c05",
    "min_grade": "B"
  }'

# Pass response (grade A):
# HTTP 200
# {
#   "result": "pass",
#   "image_id": "ami-0a7f3c9e82d1b4c05",
#   "grade": "A",
#   "score": 94,
#   "controls_passing": 94,
#   "controls_total": 100,
#   "scanned_at": "2026-04-19T15:54:10Z"
# }

# Fail response (grade C):
# HTTP 422
# {
#   "result": "fail",
#   "image_id": "ami-0c9d5e3f81a2b6e07",
#   "grade": "C",
#   "score": 72,
#   "min_grade_required": "B",
#   "failing_controls": [
#     { "id": "1.1.7", "title": "Separate partition for /var/log/audit", "severity": "medium" },
#     { "id": "3.3.2", "title": "TCP SYN cookies enabled", "severity": "low" },
#     ...
#   ]
# }

A non-200 response fails the pipeline. The || exit 1 in the shell integration handles this — if the API returns 422, the pipeline step exits non-zero and the job fails.

GitHub Actions Integration

# .github/workflows/deploy.yml

jobs:
  build-image:
    runs-on: ubuntu-latest
    outputs:
      ami_id: ${{ steps.build.outputs.ami_id }}
    steps:
      - name: Build hardened AMI
        id: build
        run: |
          AMI_ID=$(stratum build \
            --blueprint ubuntu22-cis-l1.yaml \
            --provider aws \
            --output json | jq -r '.image_id')
          echo "ami_id=${AMI_ID}" >> $GITHUB_OUTPUT

  compliance-gate:
    runs-on: ubuntu-latest
    needs: build-image
    steps:
      - name: Stratum compliance gate
        run: |
          curl -sf -X POST ${{ vars.STRATUM_URL }}/api/pipeline/scan \
            -H "Authorization: Bearer ${{ secrets.STRATUM_TOKEN }}" \
            -H "Content-Type: application/json" \
            -d "{\"image_id\": \"${{ needs.build-image.outputs.ami_id }}\", \"min_grade\": \"B\"}" \
            || { echo "Compliance gate failed — image does not meet minimum grade B"; exit 1; }

  deploy:
    runs-on: ubuntu-latest
    needs: [build-image, compliance-gate]
    steps:
      - name: Deploy to staging
        run: |
          aws autoscaling update-auto-scaling-group \
            --auto-scaling-group-name my-asg \
            --launch-template "ImageId=${{ needs.build-image.outputs.ami_id }}"

The deploy job only runs if compliance-gate passes. The AMI doesn’t reach the autoscaling group if it doesn’t meet the grade threshold.

GitLab CI Integration

# .gitlab-ci.yml

stages:
  - build
  - compliance
  - deploy

build-image:
  stage: build
  script:
    - |
      AMI_ID=$(stratum build \
        --blueprint ubuntu22-cis-l1.yaml \
        --provider aws \
        --output json | jq -r '.image_id')
      echo "AMI_ID=${AMI_ID}" >> build.env
  artifacts:
    reports:
      dotenv: build.env

compliance-gate:
  stage: compliance
  needs: [build-image]
  script:
    - |
      curl -sf -X POST ${STRATUM_URL}/api/pipeline/scan \
        -H "Authorization: Bearer ${STRATUM_TOKEN}" \
        -H "Content-Type: application/json" \
        -d "{\"image_id\": \"${AMI_ID}\", \"min_grade\": \"B\"}"

deploy:
  stage: deploy
  needs: [build-image, compliance-gate]
  script:
    - ./deploy.sh ${AMI_ID}

What the Failed Gate Tells You

The value of the CI/CD compliance gate is not just that it blocks bad images — it’s that the failure output tells engineers what to fix.

A gate failure in CI shows:

Compliance gate failed.

Image: ami-0c9d5e3f81a2b6e07
Grade: C (72/100)
Required: B (85/100)
Gap: 13 controls failing

Failing controls:
  HIGH   1.1.7   Separate partition for /var/log/audit
                 Fix: Provision /var/log/audit on a separate EBS volume
  MEDIUM 1.6.1.3 AppArmor enabled in bootloader
                 Fix: Update GRUB_CMDLINE_LINUX, run update-grub, reboot
  MEDIUM 3.3.2   TCP SYN cookies
                 Fix: echo "net.ipv4.tcp_syncookies=1" > /etc/sysctl.d/60-cis.conf
  LOW    5.2.21  SSH MaxStartups
                 Fix: Add "MaxStartups 10:30:60" to /etc/ssh/sshd_config
  ...

View full scan report: https://stratum.yourdomain.com/scans/ami-0c9d5e3f81a2b6e07

This is not a wall — it’s a list of exactly what to fix. The engineer running the pipeline sees the gap, fixes the blueprint or the Ansible role, rebuilds, and the gate passes. The gap is closed before any instance is deployed.

Runtime Gate: Checking Existing Instances

The Pipeline API also works against running instances, not just images:

# Gate on a running instance's current compliance state
curl -sf -X POST https://stratum.yourdomain.com/api/pipeline/scan \
  -H "Authorization: Bearer ${STRATUM_TOKEN}" \
  -H "Content-Type: application/json" \
  -d '{
    "instance_id": "i-0abc123",
    "min_grade": "B",
    "scan_type": "runtime"
  }'

This is useful in deployment pipelines that don’t build custom AMIs — they launch instances and configure them after launch. The runtime gate runs after configuration is complete and before the instance is registered with the load balancer.

It also integrates into scheduled compliance jobs — scan your fleet on a schedule and alert when any instance drifts below grade threshold.

Grade Thresholds by Environment

Not all environments need the same threshold. A common pattern:

# Environment-specific minimum grades
environments:
  production: A      # 95%+ passing — no exceptions
  staging:    B      # 85%+ passing — minor gaps acceptable
  development: C     # 70%+ passing — experimental OK

# Production deploy gate
curl -sf -X POST .../api/pipeline/scan \
  -d '{"image_id": "ami-...", "min_grade": "A"}'

# Staging deploy gate
curl -sf -X POST .../api/pipeline/scan \
  -d '{"image_id": "ami-...", "min_grade": "B"}'

This lets development move fast with a lower bar while enforcing the highest standard at the production gate.

Production Gotchas

Gate latency on first scan: If the image hasn’t been scanned yet, the Pipeline API triggers a scan on demand. This takes 2–3 minutes. For build pipelines that want instant gate results, use stratum build --blueprint ... --scan-on-build to ensure the scan runs during the build step and the result is cached for the gate call.

Token rotation: The STRATUM_TOKEN used for API authentication should be rotated on the same schedule as other service credentials. Use environment-specific tokens so a compromised staging token doesn’t bypass a production gate.

Webhook notifications on gate failure: The Pipeline API can send a webhook to Slack, PagerDuty, or any endpoint when a gate fails. Configure this for production pipelines so failures are visible beyond the CI log.

# In the Stratum config
notifications:
  pipeline_failures:
    - type: slack
      webhook: ${SLACK_WEBHOOK}
      channel: "#platform-security"
    - type: webhook
      url: ${PAGERDUTY_WEBHOOK}
      min_grade: D     # only page on D/F, not B/C failures

Key Takeaways

A CI/CD compliance gate turns a compliance grade from a dashboard metric into a pipeline constraint — the image doesn’t deploy if it doesn’t pass
POST /api/pipeline/scan is a single HTTP call that any CI/CD system can make — no agent, no plugin, no SDK required
Failed gate output is actionable: every failing control includes the specific fix, not just the control ID
Runtime gates check instances after configuration, not just at image build time
Environment-specific thresholds let development move faster while enforcing the highest standard at production

What’s Next

The CI/CD compliance gate closes the final gap: even if an unhardened image gets built, it can’t deploy. EP05 is the bookmark episode — this is the point where OS hardening becomes structurally enforced rather than procedurally expected.

EP06 is the series closer. For five episodes, you’ve been using Stratum as a user. What does it look like to run it yourself — extend it with a custom control, add a provider, deploy the platform in your own infrastructure?

Stratum is open-core (Apache 2.0). EP06 is the architecture reveal, the GitHub release, and the extension guide for everything the series taught.

Next: Stratum — open-source OS hardening platform for multi-cloud infrastructure

Get EP06 in your inbox when it publishes → linuxcent.com/subscribe

How Active Directory Works: LDAP, Kerberos, and Group Policy Under the Hood

May 3, 2026 by Vamshi Krishna Santhapuri

Reading Time: 6 minutes

The Identity Stack, Episode 9
EP08: FreeIPA → EP09 → EP10: SAML/OIDC → …

Focus Keyphrase: Active Directory LDAP
Search Intent: Informational
Meta Description: Active Directory is LDAP + Kerberos + DNS + Group Policy — all tightly integrated. Here’s how AD replication, Sites, GPO, and Linux domain join actually work. (160 chars)

TL;DR

Active Directory is not a product that happens to use LDAP — it is an LDAP directory with a Microsoft-extended schema, a built-in Kerberos KDC, and DNS tightly integrated
Replication uses USNs (Update Sequence Numbers) and GUIDs — the Knowledge Consistency Checker (KCC) automatically builds the replication topology
Sites and site links tell AD which DCs are physically close — AD prefers to authenticate users against a DC in the same site to minimize WAN latency
Group Policy Objects (GPOs) are stored as LDAP entries (in the CN=Policies container) and Sysvol files — LDAP tells clients which GPOs apply; Sysvol delivers the policy files
Linux joins AD via realm join (uses adcli + SSSD) or net ads join (Samba + winbind) — both register a machine account in AD and get a Kerberos keytab
The difference between Linux in AD and Linux in FreeIPA: AD is optimized for Windows; FreeIPA is optimized for Linux — both interoperate

The Big Picture: What AD Actually Is

Active Directory Domain: corp.com
┌────────────────────────────────────────────────────────────┐
│                                                            │
│  LDAP directory          Kerberos KDC                      │
│  ─────────────           ──────────                        │
│  Schema: 1000+ classes   Realm: CORP.COM                   │
│  Objects: users, groups, Issues TGTs + service tickets     │
│  computers, GPOs, OUs    Uses LDAP as the account DB       │
│                                                            │
│  DNS                     Sysvol (DFS share)                │
│  ────                    ────────────────                  │
│  SRV records for KDC     GPO templates                     │
│  and LDAP discovery      Login scripts                     │
│                          Replicated via DFSR               │
│                                                            │
│  Replication engine: USN + GUID + KCC                      │
└────────────────────────────────────────────────────────────┘
          │ replicates to          │ replicates to
          ▼                        ▼
   DC: dc02.corp.com        DC: dc03.corp.com

EP08 showed FreeIPA as the Linux-native answer to enterprise identity. AD is the Microsoft answer — and because most enterprises run Windows clients, understanding AD is unavoidable for Linux infrastructure engineers. This episode goes behind the LDAP and Kerberos protocols to explain what makes AD specifically work.

The AD Schema: LDAP With 1000+ Object Classes

AD’s schema extends the base LDAP schema with Microsoft-specific classes and attributes. Every user object is a user class (which extends organizationalPerson which extends person which extends top) with additional attributes like:

sAMAccountName   ← the pre-Windows 2000 login name (vamshi)
userPrincipalName ← the modern UPN ([email protected])
objectGUID       ← a globally unique 128-bit identifier (never changes, even if DN changes)
objectSid        ← Windows Security Identifier (used for ACL enforcement on Windows)
whenCreated      ← creation timestamp
pwdLastSet       ← password change timestamp
userAccountControl ← bitmask: disabled, locked, password never expires, etc.
memberOf         ← back-link: groups this user belongs to

objectGUID is the authoritative identifier in AD — not the DN. When a user is renamed or moved to a different OU, the GUID stays the same. Applications that store a user’s DN will break on rename; applications that store the GUID won’t.

userAccountControl is the bitmask that controls account state:

Flag          Value   Meaning
ACCOUNTDISABLE  2     Account disabled
LOCKOUT         16    Account locked out
PASSWD_NOTREQD  32    Password not required
NORMAL_ACCOUNT  512   Normal user account (set on almost all accounts)
DONT_EXPIRE_PASSWD 65536  Password never expires

# Query AD from a Linux machine
ldapsearch -x -H ldap://dc.corp.com \
  -D "[email protected]" -w password \
  -b "dc=corp,dc=com" \
  "(sAMAccountName=vamshi)" \
  sAMAccountName userPrincipalName objectGUID memberOf userAccountControl

Replication: USN + GUID + KCC

AD replication is multi-master — every DC accepts writes. The replication engine uses:

USN (Update Sequence Number) — a per-DC counter that increments on every local write. Each attribute in the directory stores the USN at which it was last modified (uSNChanged, uSNCreated). When DC-A replicates to DC-B, DC-B asks: “give me everything you’ve changed since the last USN I saw from you.”

GUID — each object has a globally unique identifier. If the same attribute is modified on two DCs before replication (a conflict), the conflict is resolved: last-writer-wins at the attribute level, based on the modification timestamp. If timestamps are equal, the attribute value from the DC with the lexicographically higher GUID wins.

KCC (Knowledge Consistency Checker) — a component that runs on every DC and automatically constructs the replication topology. You don’t configure which DCs replicate to which — the KCC builds a minimum spanning tree that ensures every DC is connected to every other within a set number of hops. You configure Sites and site links; the KCC does the rest.

# Check replication status from a Linux machine (requires rpcclient or adcli)
# Or on the DC: repadmin /showrepl (Windows tool)

# Simulate: query the highestCommittedUSN from a DC
ldapsearch -x -H ldap://dc.corp.com \
  -D "[email protected]" -w password \
  -b "" -s base highestCommittedUSN

Sites and Site Links

Sites are AD’s concept of physical network topology. A site is a set of IP subnets with high-bandwidth connectivity between them. Site links represent the WAN connections between sites.

Site: Mumbai              Site: Hyderabad
┌────────────────┐        ┌────────────────┐
│ DC: dc-mum-01  │        │ DC: dc-hyd-01  │
│ DC: dc-mum-02  │        │ DC: dc-hyd-02  │
│ subnet: 10.1/16│        │ subnet: 10.2/16│
└───────┬────────┘        └────────┬───────┘
        │                          │
        └──── Site Link ───────────┘
              Cost: 100
              Replication interval: 15 min

When a user in Mumbai authenticates, AD’s KDC locates a DC in the same site using DNS SRV records. The SRV records include the site name in the service name: _ldap._tcp.Mumbai._sites.dc._msdcs.corp.com. SSSD and Windows clients query site-local SRV records first.

If no DC is available in the local site, authentication falls back to a DC in another site across the WAN link. Configuring sites correctly prevents remote authentication failures from killing local operations.

Group Policy: LDAP + Sysvol

GPOs are stored in two places:

LDAP — the CN=Policies,CN=System,DC=corp,DC=com container holds GPO metadata objects. Each GPO has a GUID, a display name, and version numbers. The gPLink attribute on OUs and the domain root links GPOs to where they apply.

Sysvol — the actual policy templates and scripts live in \\corp.com\SYSVOL\corp.com\Policies\{GPO-GUID}\. Sysvol is a DFS-R (Distributed File System Replication) share replicated to every DC.

When a Windows client applies Group Policy:
1. LDAP query: what GPOs are linked to my OU chain?
2. Sysvol fetch: download the policy templates from the GPO’s Sysvol path
3. Apply: process Registry settings, Security settings, Scripts

Linux clients don’t process GPOs natively. The adcli and sssd tools interpret a small subset of AD policy (password policy, account lockout) via LDAP. Full GPO processing on Linux requires Samba’s samba-gpupdate or third-party tools.

Joining Linux to AD

realm join (recommended)

# Install required packages
dnf install -y realmd sssd adcli samba-common

# Discover the domain
realm discover corp.com
# corp.com
#   type: kerberos
#   realm-name: CORP.COM
#   domain-name: corp.com
#   configured: no
#   server-software: active-directory
#   client-software: sssd

# Join
realm join corp.com -U Administrator
# Prompts for Administrator password
# Creates machine account in AD
# Configures sssd.conf, krb5.conf, nsswitch.conf, pam.d automatically

# Verify
realm list
id [email protected]

What the join does:

Creates a machine account HOSTNAME$ in CN=Computers,DC=corp,DC=com
Sets a machine password (rotated automatically by SSSD)
Retrieves a Kerberos keytab to /etc/krb5.keytab
Configures SSSD with id_provider = ad, auth_provider = ad
Updates /etc/nsswitch.conf to include sss
Updates /etc/pam.d/ to include pam_sss

After joining, SSSD uses the machine’s Kerberos keytab to authenticate to the DC and query LDAP — no hardcoded service account credentials required.

LDAP Queries Against AD from Linux

# Find a user (after kinit or with -w password)
ldapsearch -Y GSSAPI -H ldap://dc.corp.com \
  -b "dc=corp,dc=com" \
  "(sAMAccountName=vamshi)" \
  sAMAccountName mail memberOf

# Find all members of a group
ldapsearch -Y GSSAPI -H ldap://dc.corp.com \
  -b "dc=corp,dc=com" \
  "(cn=engineers)" \
  member

# Find all AD-joined Linux machines
ldapsearch -Y GSSAPI -H ldap://dc.corp.com \
  -b "dc=corp,dc=com" \
  "(&(objectClass=computer)(operatingSystem=*Linux*))" \
  cn operatingSystem lastLogonTimestamp

# Find disabled accounts
ldapsearch -Y GSSAPI -H ldap://dc.corp.com \
  -b "dc=corp,dc=com" \
  "(userAccountControl:1.2.840.113556.1.4.803:=2)" \
  sAMAccountName

The last filter uses an LDAP extensible match (1.2.840.113556.1.4.803 is the OID for bitwise AND). userAccountControl:1.2.840.113556.1.4.803:=2 means “entries where userAccountControl AND 2 equals 2” — i.e., the ACCOUNTDISABLE bit is set. This is a Microsoft AD extension not in standard LDAP.

⚠ Common Misconceptions

“AD is just Microsoft’s LDAP.” AD is LDAP + Kerberos + DNS + DFS-R + GPO, all tightly integrated and with a schema that the Microsoft ecosystem depends on. You can query AD with standard ldapsearch. You cannot replace it with OpenLDAP without breaking every Windows client.

“Linux machines in AD get GPO.” Linux machines appear in AD and can be organized into OUs. Standard GPOs don’t apply to them. Samba’s samba-gpupdate can process a subset of AD policy for Linux — mostly Registry and Security settings mapped to Linux equivalents.

“realm leave removes the machine cleanly.” realm leave removes local configuration but does not delete the machine account from AD. The stale computer object stays in CN=Computers until an AD admin deletes it. Always run realm leave && adcli delete-computer -U Administrator for a clean removal.

Framework Alignment

Domain	Relevance
CISSP Domain 5: Identity and Access Management	AD is the dominant enterprise identity store — understanding its LDAP structure, Kerberos realm, and GPO model is essential for IAM in mixed environments
CISSP Domain 4: Communications and Network Security	AD replication traffic (RPC, LDAP, Kerberos) is a significant portion of enterprise WAN traffic — Sites and site links are a network security and performance design decision
CISSP Domain 3: Security Architecture and Engineering	AD forest/domain/OU hierarchy is an architectural decision with long-term security consequences — getting OU structure wrong constrains GPO delegation for years

Key Takeaways

AD is LDAP + Kerberos + DNS + GPO + DFS-R — not a product that “uses” these; they’re the implementation
Replication is multi-master via USN + GUID; the KCC builds the topology automatically from Sites configuration
objectGUID is the stable identifier — not the DN, which changes on rename/move
realm join is the correct way to join Linux to AD — it configures SSSD, Kerberos, PAM, and NSS correctly in one command
userAccountControl is the bitmask that controls account state — (userAccountControl:1.2.840.113556.1.4.803:=2) finds disabled accounts

What’s Next

EP09 covered AD — LDAP and Kerberos inside the corporate network. EP10 covers what happens when identity needs to work across the internet, where Kerberos doesn’t reach: SAML, OAuth2, and OIDC — the protocols that let identity leave the building.

Next: SAML vs OIDC vs OAuth2: Which Protocol Handles Which Identity Problem

Get EP10 in your inbox when it publishes → linuxcent.com/subscribe

FreeIPA: LDAP + Kerberos + PKI in a Single Linux Identity Stack

May 2, 2026 by Vamshi Krishna Santhapuri

Reading Time: 5 minutes

The Identity Stack, Episode 8
EP07: LDAP HA → EP08 → EP09: Active Directory → …

Focus Keyphrase: FreeIPA setup
Search Intent: Investigational
Meta Description: FreeIPA integrates 389-DS, MIT Kerberos, Dogtag PKI, and SSSD into one Linux identity stack. Here’s what it gives you and how to use it effectively. (153 chars)

TL;DR

FreeIPA is 389-DS (LDAP) + MIT Kerberos + Dogtag PKI + Bind DNS + SSSD — one ipa-server-install command gets you an enterprise identity platform
Host-Based Access Control (HBAC) lets you define centrally: which users can SSH to which hosts — no more managing /etc/security/access.conf per machine
Sudo rules from the directory: define sudo policy centrally, have every machine pull it — no /etc/sudoers.d/ files scattered across the fleet
ipa CLI is the management interface — ipa user-add, ipa group-add, ipa hbacrule-add — everything that took five LDAP commands takes one ipa command
FreeIPA trusts with Active Directory let Linux machines authenticate AD users without joining the AD domain
The right choice for Linux-centric environments; AD is the right choice when Windows clients dominate

The Big Picture: What FreeIPA Integrates

┌─────────────────────────────────────────────────────────┐
│                    FreeIPA Server                        │
│                                                         │
│  389-DS (LDAP)    MIT Kerberos    Dogtag PKI            │
│  ─────────────    ───────────     ─────────             │
│  User/group       TGT + service   Machine certs         │
│  storage          ticket issuing  User certs             │
│                                   OCSP / CRL            │
│  Bind DNS         SSSD (client)   Apache (WebUI)        │
│  ──────────       ────────────    ──────────────        │
│  SRV records      Enrollment      Management UI         │
│  for KDC/LDAP     automation      REST API              │
└─────────────────────────────────────────────────────────┘
              ▲                  ▲
              │ enrollment       │ SSH + sudo rules
   ┌──────────┴──────────┐  ┌───┴──────────────────┐
   │  Linux client        │  │  Linux client         │
   │  (ipa-client-install)│  │  (ipa-client-install) │
   └─────────────────────┘  └──────────────────────┘

EP06 and EP07 built OpenLDAP from components. FreeIPA gives you all of that plus Kerberos, PKI, DNS, and HBAC — opinionated, integrated, and managed through a single CLI and WebUI. This episode shows what you actually get from it.

Why FreeIPA Instead of Bare OpenLDAP

Running bare OpenLDAP requires you to:
– Configure schema for POSIX accounts, SSH keys, sudo rules, HBAC manually
– Set up MIT Kerberos separately and integrate it with LDAP
– Build your own PKI for machine certificates
– Maintain DNS SRV records for Kerberos discovery
– Write client enrollment scripts
– Build a management interface (or live in LDIF)

FreeIPA does all of this in one installer, with a consistent data model across all components. The trade-off is opacity — FreeIPA makes decisions for you (schema, replication topology, Kerberos realm name) that bare OpenLDAP leaves to you.

Installing FreeIPA Server

# RHEL / Rocky / AlmaLinux
dnf install -y freeipa-server freeipa-server-dns

# Run the installer (interactive)
ipa-server-install

# Or non-interactive:
ipa-server-install \
  --realm=CORP.COM \
  --domain=corp.com \
  --ds-password=DM_password \
  --admin-password=Admin_password \
  --setup-dns \
  --forwarder=8.8.8.8 \
  --unattended

# After install: get an admin Kerberos ticket
kinit admin

The installer creates:
– 389-DS instance with the FreeIPA schema
– MIT KDC with realm CORP.COM
– Dogtag CA and all certificate infrastructure
– Bind DNS with SRV records for the KDC and LDAP server
– Apache WebUI at https://ipa.corp.com/ipa/ui/
– SSSD configured on the server itself

Time: 5–10 minutes. What used to take a week of manual configuration.

The ipa CLI

Every management action goes through ipa. It talks to the IPA server’s REST API and handles Kerberos authentication transparently (it uses your kinit session).

# Users
ipa user-add vamshi \
  --first=Vamshi --last=Krishna \
  [email protected] \
  --password

ipa user-show vamshi
ipa user-find --all              # search all users
ipa user-disable vamshi          # lock account without deleting
ipa user-mod vamshi --shell=/bin/zsh

# Groups
ipa group-add engineers --desc "Engineering team"
ipa group-add-member engineers --users=vamshi,alice

# Password policy
ipa pwpolicy-mod --minlength=12 --maxlife=90 --history=10

# SSH public keys — stored centrally, pushed to every host
ipa user-mod vamshi --sshpubkey="ssh-ed25519 AAAA..."
# SSSD on enrolled hosts will use this key for SSH login — no authorized_keys file needed

Host-Based Access Control (HBAC)

HBAC is the feature that justifies FreeIPA for most Linux shops. It lets you define centrally: which users (or groups) can log in to which hosts (or host groups), using which services (SSH, sudo, FTP).

Without HBAC, access control is per-machine: /etc/security/access.conf or PAM pam_access rules, replicated across every server, managed inconsistently.

With HBAC: one rule, enforced everywhere.

# Create host groups
ipa hostgroup-add production-servers --desc "Production Linux hosts"
ipa hostgroup-add-member production-servers --hosts=web01.corp.com,db01.corp.com

# Create user groups
ipa group-add sre-team
ipa group-add-member sre-team --users=vamshi,alice

# Create an HBAC rule
ipa hbacrule-add allow-sre-to-prod \
  --desc "SRE team can SSH to production"
ipa hbacrule-add-user allow-sre-to-prod --groups=sre-team
ipa hbacrule-add-host allow-sre-to-prod --hostgroups=production-servers
ipa hbacrule-add-service allow-sre-to-prod --hbacsvcs=sshd

# Test the rule before applying
ipa hbactest \
  --user=vamshi \
  --host=web01.corp.com \
  --service=sshd
# Access granted: True
# Matched rules: allow-sre-to-prod

SSSD on each enrolled host enforces the HBAC rules at login time by querying the IPA server. No per-machine configuration. Add a new server to the production-servers host group and the HBAC rules apply immediately.

Sudo Rules from the Directory

# Create a sudo rule
ipa sudorule-add allow-sre-sudo \
  --cmdcat=all \
  --desc "SRE team gets full sudo on production"
ipa sudorule-add-user allow-sre-sudo --groups=sre-team
ipa sudorule-add-host allow-sre-sudo --hostgroups=production-servers

# Or a scoped rule — only specific commands
ipa sudorule-add allow-service-restart
ipa sudocmdgroup-add service-commands
ipa sudocmd-add /usr/bin/systemctl
ipa sudocmdgroup-add-member service-commands --sudocmds="/usr/bin/systemctl"
ipa sudorule-add-allow-command allow-service-restart --sudocmdgroups=service-commands

On enrolled hosts, SSSD’s sssd_sudo responder pulls these rules and the sudo command evaluates them locally. No /etc/sudoers.d/ files. Central policy, local enforcement.

Enrolling a Client

# On the client machine
dnf install -y freeipa-client

ipa-client-install \
  --domain=corp.com \
  --server=ipa.corp.com \
  --realm=CORP.COM \
  --principal=admin \
  --password=Admin_password \
  --unattended

# What this does:
# 1. Registers the host in IPA as a machine principal
# 2. Retrieves a host Kerberos keytab (/etc/krb5.keytab)
# 3. Configures SSSD (sssd.conf, nsswitch.conf, pam.d)
# 4. Configures Kerberos (/etc/krb5.conf)
# 5. Optionally configures NTP and DNS

After enrollment: getent passwd vamshi returns the IPA user. SSH with an IPA password works. HBAC rules are enforced. Sudo rules from the directory apply. SSH public keys from the user’s IPA profile work without authorized_keys files.

FreeIPA Trust with Active Directory

In mixed environments (Linux servers + Windows clients), you can establish a trust between FreeIPA and AD without joining the Linux servers to the AD domain directly.

# On the IPA server (after installing ipa-server-trust-ad)
ipa-adtrust-install --netbios-name=CORP

# Establish the trust
ipa trust-add ad.corp.com \
  --admin=Administrator \
  --password \
  --type=ad

# AD users can now log in to IPA-enrolled Linux hosts
# They appear as: CORP.COM\username or [email protected]

Under the hood: FreeIPA acts as an SSSD-enabled Samba DC for the trust relationship. AD users’ Kerberos tickets from the AD KDC are accepted by the FreeIPA KDC, which maps them to POSIX attributes stored in IPA (or automatically generated via ID mapping).

⚠ Common Misconceptions

“FreeIPA is just OpenLDAP with a UI.” FreeIPA uses 389-DS (not OpenLDAP), adds a full Kerberos KDC, a certificate authority, DNS, HBAC enforcement, and sudo management — all with a consistent schema designed for these use cases. It’s an integrated identity platform, not a wrapper.

“HBAC rules replace firewall rules.” HBAC controls who can log in to a host at the authentication layer — not network access. A blocked HBAC rule means the SSH session is rejected after TCP connection. You still need firewall rules to block TCP access.

“FreeIPA replicas are identical.” FreeIPA uses 389-DS Multi-Supplier replication. All replicas accept reads and writes. But the CA is separate — only the initial server (and explicitly designated CA replicas) run the CA. If the CA goes down, certificate operations stop; authentication does not.

Framework Alignment

Domain	Relevance
CISSP Domain 5: Identity and Access Management	FreeIPA is an enterprise IAM platform — HBAC, sudo policy, SSH key management, and certificate-based authentication are all IAM controls
CISSP Domain 3: Security Architecture and Engineering	FreeIPA’s integrated CA enables certificate-based authentication for machines and users — a stronger authentication factor than passwords
CISSP Domain 1: Security and Risk Management	Centralized HBAC and sudo policy reduces the attack surface of privilege escalation — no more inconsistent sudoers files that drift across the fleet

Key Takeaways

FreeIPA = 389-DS + MIT Kerberos + Dogtag PKI + Bind DNS — one installer, one management interface
HBAC rules define centrally who can SSH to which host groups — enforced by SSSD on every enrolled client, no per-machine config
Sudo rules from the directory replace scattered /etc/sudoers.d/ files — central policy, SSSD-enforced locally
ipa hbactest lets you verify access rules before a user hits a blocked login — use it before every policy change
For Linux-centric environments: FreeIPA. For Windows-dominant environments: AD. For mixed: FreeIPA trust with AD.

What’s Next

FreeIPA is the Linux answer to enterprise identity. EP09 covers the Microsoft answer — Active Directory — which extended LDAP and Kerberos into a complete enterprise platform with Group Policy, Sites, and a replication model built for global scale.

Next: How Active Directory Works: LDAP, Kerberos, and Group Policy Under the Hood

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LDAP High Availability: Load Balancing and Production Architecture

May 1, 2026 by Vamshi Krishna Santhapuri

Reading Time: 6 minutes

The Identity Stack, Episode 7
EP06: OpenLDAP → EP07 → EP08: FreeIPA → …

Focus Keyphrase: LDAP high availability
Search Intent: Informational
Meta Description: Design LDAP high availability for production: HAProxy load balancing, read/write split, connection pooling, monitoring with cn=monitor, and 389-DS at scale. (157 chars)

TL;DR

LDAP HA means multiple directory servers behind a load balancer — clients connect to a VIP, not to individual servers
Read/write split: all writes go to the provider, reads are distributed across consumers — the load balancer enforces this by routing on port or backend check
SSSD handles multi-server failover natively (ldap_uri accepts a comma-separated list) — for apps without built-in failover, HAProxy with health checks does the work
Connection pooling is critical at scale — nss_ldap and pam_ldap opened a new connection per login; SSSD maintains a pool; apps that use libldap directly must implement their own
cn=monitor is the built-in monitoring endpoint — exposes connection counts, operation rates, and backend stats readable via ldapsearch
389-DS (Red Hat Directory Server) is the production choice for >1M entries — purpose-built for large directories with a dedicated replication engine

The Big Picture: Production LDAP Topology

         Clients (SSSD, apps, VPN concentrators)
                      │
              ┌───────▼───────┐
              │   HAProxy VIP  │   ← single endpoint, port 389/636
              │  10.0.0.10     │
              └───────┬───────┘
                      │
          ┌───────────┼───────────┐
          ▼           ▼           ▼
   ldap1.corp.com  ldap2.corp.com  ldap3.corp.com
   (Provider)      (Consumer)      (Consumer)
   Reads + Writes  Reads only      Reads only
          │           ▲               ▲
          └───────────┴───────────────┘
               SyncRepl replication

EP06 built a two-node replicated directory. This episode covers what happens when the directory becomes infrastructure — when it needs to survive a node failure, handle thousands of connections, and be monitored like any other critical service.

HAProxy for LDAP

HAProxy is the standard choice for LDAP load balancing. Unlike HTTP, LDAP is a stateful protocol — once a client binds, subsequent operations on that connection share the authenticated session. The load balancer must use connection persistence, not per-request routing.

# /etc/haproxy/haproxy.cfg

global
    log /dev/log local0
    maxconn 50000

defaults
    mode tcp                  # LDAP is TCP, not HTTP
    timeout connect 5s
    timeout client  30s
    timeout server  30s
    option tcplog

# ── LDAP read/write split ─────────────────────────────────────────────

# Writes → provider only
frontend ldap-write
    bind *:389
    default_backend ldap-provider

backend ldap-provider
    balance first                   # always use first available (provider)
    option tcp-check
    tcp-check connect
    server ldap1 ldap1.corp.com:389 check inter 5s rise 2 fall 3
    server ldap2 ldap2.corp.com:389 check inter 5s rise 2 fall 3 backup

# Reads → all nodes round-robin
frontend ldap-read
    bind *:3389                     # internal read port
    default_backend ldap-consumers

backend ldap-consumers
    balance roundrobin
    option tcp-check
    tcp-check connect
    server ldap1 ldap1.corp.com:389 check inter 5s
    server ldap2 ldap2.corp.com:389 check inter 5s
    server ldap3 ldap3.corp.com:389 check inter 5s

# LDAPS (TLS)
frontend ldaps
    bind *:636
    default_backend ldap-consumers-tls

backend ldap-consumers-tls
    balance roundrobin
    server ldap1 ldap1.corp.com:636 check inter 5s ssl verify required ca-file /etc/ssl/certs/ca.pem
    server ldap2 ldap2.corp.com:636 check inter 5s ssl verify required ca-file /etc/ssl/certs/ca.pem

The health check (tcp-check connect) just verifies TCP connectivity. For a more precise check — verifying that slapd is actually responding to LDAP requests — use a custom script that runs ldapsearch and checks the result code.

SSSD Multi-Server Failover

SSSD has native failover — no load balancer required for SSSD-based clients:

# /etc/sssd/sssd.conf
[domain/corp.com]
ldap_uri = ldap://ldap1.corp.com, ldap://ldap2.corp.com, ldap://ldap3.corp.com
# SSSD tries them in order; switches to next on failure
# Switches back to primary after ldap_recovery_interval (default: 30s)

# For AD, discovery via DNS SRV records is even better:
ad_server = _srv_
# SSSD queries _ldap._tcp.corp.com SRV records and gets all DCs automatically

SSSD monitors the connection health. If the current server becomes unreachable, it switches to the next in the list within seconds. Existing cached data keeps serving during the switchover. Clients using SSSD don’t need a load balancer for basic HA.

Connection Pooling

Every LDAP bind creates an authenticated session on the server. A server with connection limits (olcConnMaxPending, olcConnMaxPendingAuth in OLC) will reject new connections when those limits are hit.

The problem: applications that use libldap directly tend to open a new connection per operation. At 500 requests/second, that’s 500 new TCP connections, 500 binds, 500 TLS handshakes per second — a directory that can handle 5000 concurrent connections starts refusing new ones.

The solutions:

SSSD — handles this automatically. SSSD maintains one or a small number of persistent connections per domain and multiplexes all PAM/NSS queries through them.

Application-level pooling — frameworks like python-ldap with connection pooling, ldap3 with connection strategies, or dedicated middleware like 389-DS‘s Directory Proxy Server.

ldap_maxconnections in OpenLDAP — sets a hard limit. When hit, new connections block until existing ones close. Set this to something reasonable (olcConnMaxPending: 100 in OLC) so you get a controlled failure mode instead of unbounded queuing.

Monitoring with cn=monitor

OpenLDAP exposes live operational statistics via the cn=monitor database — a virtual LDAP subtree that reflects the server’s current state. Enable it:

# enable-monitor.ldif
dn: cn=module,cn=config
objectClass: olcModuleList
cn: module
olcModulePath: /usr/lib/ldap
olcModuleLoad: back_monitor

dn: olcDatabase=monitor,cn=config
objectClass: olcDatabaseConfig
olcDatabase: monitor
olcAccess: to *
  by dn="cn=admin,dc=corp,dc=com" read
  by * none

Query it:

# Overall statistics
ldapsearch -x -H ldap://localhost \
  -D "cn=admin,dc=corp,dc=com" -w password \
  -b "cn=monitor" -s sub "(objectClass=*)" \
  monitorOpInitiated monitorOpCompleted

# Connection counts
ldapsearch -x -H ldap://localhost \
  -D "cn=admin,dc=corp,dc=com" -w password \
  -b "cn=Connections,cn=monitor" -s one \
  monitorConnectionNumber

# Operations by type
ldapsearch -x -H ldap://localhost \
  -D "cn=admin,dc=corp,dc=com" -w password \
  -b "cn=Operations,cn=monitor" -s one \
  monitorOpInitiated monitorOpCompleted

Useful metrics to export to Prometheus (via prometheus-openldap-exporter or similar):
– monitorOpCompleted per operation type (bind, search, modify)
– monitorConnectionNumber — current connection count
– Backend-specific: olmMDBEntries, olmMDBPagesMax, olmMDBPagesUsed

389-DS: LDAP at Scale

OpenLDAP is excellent for directories up to a few million entries. When you need:
– 10M+ entries
– High write throughput (more than a few hundred writes/second)
– Fine-grained replication filtering
– A dedicated web-based admin UI

…389-DS (Red Hat Directory Server, community edition) is the production answer. It’s what FreeIPA uses under the hood.

Key architectural differences from OpenLDAP:

Multi-supplier replication — 389-DS’s replication engine uses a dedicated changelog (stored in LMDB) and Change Sequence Numbers (CSNs) for conflict resolution. Multi-supplier (multi-master) replication is first-class, not a bolted-on feature.

Changelog — every change is written to a persistent changelog before being applied. This enables precise replication: a consumer can reconnect after a network partition and get exactly the changes it missed, rather than doing a full resync.

Plugin architecture — 389-DS functionality (replication, managed entries, DNA for automatic UID allocation, memberOf, password policy) is all implemented as plugins that can be enabled/disabled per directory instance.

# Install 389-DS
dnf install -y 389-ds-base

# Create a new instance
dscreate interactive
# — or use a template:
dscreate from-file /path/to/instance.inf

# Manage with dsctl
dsctl slapd-corp status
dsctl slapd-corp start
dsctl slapd-corp stop

# Admin with dsconf
dsconf slapd-corp backend suffix list
dsconf slapd-corp replication status -suffix "dc=corp,dc=com"

The dsconf replication status command gives a live view of replication lag across all suppliers and consumers — something OpenLDAP requires you to compute manually from contextCSN comparisons.

Global Catalog: Cross-Domain Search in AD

When your directory spans multiple AD domains in a forest, the Global Catalog solves a specific problem: a user in emea.corp.com needs to be found by an app that only knows corp.com.

Forest: corp.com
  ├── corp.com       → DC port 389    full directory: 500K entries
  ├── emea.corp.com  → DC port 389    full directory: 200K entries
  └── Global Catalog → GC port 3268  partial replica: 700K entries
                                       (not all attributes — just the most queried ones)

The GC replicates a subset of attributes from every domain in the forest. By default: cn, mail, sAMAccountName, userPrincipalName, memberOf, and about 150 others. Attributes marked with isMemberOfPartialAttributeSet in the schema are replicated to the GC.

If an application is configured to use port 3268 instead of 389, it’s using the GC — and it won’t see attributes not included in the partial attribute set. This surprises teams that add a custom attribute to AD and then wonder why their application can’t see it on 3268 but can on 389.

⚠ Production Gotchas

HAProxy TCP health checks don’t verify LDAP is responsive. A server can accept TCP connections but have slapd in a degraded state (database corruption, out-of-memory). Build a proper LDAP health check: a script that binds and searches a known entry and checks the result.

replication lag under write load. SyncRepl consumers can fall behind under sustained write load. Monitor the contextCSN difference between provider and consumers. If consumers are more than a few seconds behind, investigate the provider’s write throughput and the consumer’s processing speed.

Directory size and the MDB mapsize. LMDB requires a pre-configured maximum database size (olcDbMaxSize). If the database grows beyond this, slapd starts failing writes. Set it to 2–4x your expected data size and monitor olmMDBPagesUsed / olmMDBPagesMax.

Key Takeaways

HAProxy in TCP mode provides LDAP load balancing — use balance first for write routing (provider only), balance roundrobin for reads
SSSD has native failover via ldap_uri — for SSSD clients, a load balancer adds HA but isn’t strictly required
cn=monitor is the built-in OpenLDAP monitoring endpoint — export its counters to Prometheus for operational visibility
389-DS is the right choice for >1M entries, high write throughput, or multi-supplier replication as a first-class feature
Global Catalog (port 3268/3269) is a partial replica of all AD domains — useful for forest-wide searches, but missing non-replicated attributes

What’s Next

EP07 covers the infrastructure layer. EP08 zooms out to FreeIPA — what you get when LDAP, Kerberos, DNS, PKI, and HBAC are integrated into a single Linux-native identity stack, and why most Linux shops running their own directory should be running FreeIPA instead of bare OpenLDAP.

Next: FreeIPA: LDAP + Kerberos + PKI in a Single Linux Identity Stack

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bpftrace — Kernel Answers in One Line

May 3, 2026May 1, 2026 by Vamshi Krishna Santhapuri

Reading Time: 8 minutes

eBPF: From Kernel to Cloud, Episode 9
What Is eBPF? · The BPF Verifier · eBPF vs Kernel Modules · eBPF Program Types · eBPF Maps · CO-RE and libbpf · XDP · TC eBPF · bpftrace**

TL;DR

bpftrace is an eBPF compiler, not a monitoring agent — every one-liner compiles, loads, runs, and cleans up a complete kernel program
(think of it like kubectl exec — but for asking the kernel a direct question, with no agent, no sidecar, no prior setup)
kretprobe and tracepoint cover most production debugging needs; use tracepoints for stability across kernel versions
The security use cases are unique: kernel-level observation that an attacker inside a container cannot suppress
Every connection, every file open, every process spawn — observable in real time with a single command, no prior instrumentation
Production caution: high-frequency probes on hot paths add overhead; filter by pid/comm, use --timeout, watch %si
Container PIDs are host-namespace PIDs in bpftrace — use curtask->real_parent->tgid to correlate to container activity

bpftrace turns any kernel question into a one-liner — compiling, loading, and attaching a complete eBPF program in seconds, with no agents, no restarts, and no prior instrumentation on the node. When something is wrong on a node right now and you don’t know where to look, it’s how you ask the kernel a direct question. That’s what EP09 is about.

Quick Check: Is bpftrace Available on Your Node?

Before the one-liner toolkit — verify bpftrace is installed and working on a cluster node:

# SSH into a worker node, then:
bpftrace --version
# bpftrace v0.19.0   ← any version ≥ 0.16 supports the patterns in this episode

# Verify BTF is available (required for struct access one-liners)
ls /sys/kernel/btf/vmlinux && echo "BTF available"

# The simplest possible one-liner — count syscalls for 5 seconds
bpftrace -e 'tracepoint:raw_syscalls:sys_enter { @[comm] = count(); }' --timeout 5

Expected output (abridged):

Attaching 1 probe...

@[containerd]: 312
@[kubelet]:    841
@[node_exporter]: 203
@[sshd]:       47

Each line is a process name and how many syscalls it made in 5 seconds. If this runs and produces output, everything in this episode will work on your node.

Not on a self-managed node? EKS managed nodes and GKE nodes don’t have bpftrace pre-installed, but you can run it from a privileged debug pod: kubectl debug node/<node-name> -it --image=quay.io/iovisor/bpftrace. The tool runs on the host kernel — you get full kernel visibility even from a pod.

A node in production started showing elevated TCP latency — p99 at 180ms, where p99 was normally under 10ms. The application logs were clean. The APM dashboard showed nothing unusual at the service level. CPU, memory, disk: all normal. The load balancer health checks were passing.

I had 12 minutes before the on-call escalation would have gone to the application team and started a war room.

I ran one command:

bpftrace -e 'kretprobe:tcp_recvmsg { @bytes[comm] = hist(retval); }' --timeout 10

Ten seconds of sampling. The histogram output showed a single process — backup-agent — receiving 4MB chunks at irregular intervals. Not the application. Not the service mesh. A backup agent that runs at the infrastructure layer, saturating the receive path with large reads during its scheduled window.

Found in 9 seconds. War room averted.

What made that possible is something most engineers don’t know about bpftrace: that one-liner is not a monitoring query. It’s a complete eBPF program — compiled, loaded into the kernel, attached to the tcp_recvmsg kernel return probe, run, and cleaned up — all in ten seconds. bpftrace is a compiler that happens to have a very convenient command-line interface.

What bpftrace Actually Is

bpftrace is not a monitoring tool. It’s an eBPF compiler with a high-level scripting language designed for one-shot investigation.

When you run bpftrace -e 'kretprobe:tcp_recvmsg { ... }', this is what happens:

Your one-liner
      ↓
bpftrace's built-in LLVM/Clang frontend
      ↓
eBPF bytecode (.bpf.o in memory)
      ↓
Kernel verifier validates the program
      ↓
JIT compiler compiles to native machine code
      ↓
Program attaches to tcp_recvmsg kretprobe
      ↓
Runs until Ctrl-C or --timeout
      ↓
Output printed, maps freed, program detached

The kernel doesn’t know bpftrace wrote the program. It’s the same path as Falco, Cilium, Tetragon — kernel program loaded via the BPF syscall, verified, JIT-compiled, attached to a probe. bpftrace just wraps that entire process in a scripting language that takes 30 seconds to write instead of an afternoon.

This is why bpftrace can answer questions that no other tool can: it compiles to a kernel-level observer that fires on any event in the kernel, on any process, on any container — without any prior instrumentation.

The Four Probe Types You’ll Use Most

bpftrace supports 20+ probe types. These four cover 90% of production debugging:

kprobe / kretprobe — Kernel Functions

Attaches to the entry (kprobe) or return (kretprobe) of any kernel function. The most powerful probes for understanding what the kernel is actually doing.

# Fire on every call to tcp_connect — who's making new TCP connections?
bpftrace -e 'kprobe:tcp_connect { printf("%s PID %d connecting\n", comm, pid); }'

# On return from tcp_recvmsg — how large are the reads per process?
bpftrace -e 'kretprobe:tcp_recvmsg { @[comm] = hist(retval); }'

# Count calls to vfs_write per process (file write activity)
bpftrace -e 'kprobe:vfs_write { @[comm] = count(); }'

Limitation: kernel functions are internal and can change between kernel versions. Use tracepoints (below) for stability when you can.

kprobe instability: A function targeted by a kprobe can be inlined by the kernel compiler — the compiler embeds the function’s code at its call sites with no separate entry point. When that happens, the kprobe silently fires on nothing. Verify before relying on one: bpftrace -l 'kprobe:function_name' — empty response means it was inlined. Use a tracepoint equivalent instead.

tracepoint — Stable Kernel Trace Points

Tracepoints are stable, versioned hooks explicitly placed in the kernel source. Unlike kprobes, they are part of the kernel’s public interface and guaranteed not to disappear between versions. Use these for anything you need to work reliably across a fleet with mixed kernel versions.

# Every file open — process name + filename
bpftrace -e 'tracepoint:syscalls:sys_enter_openat {
    printf("%s %s\n", comm, str(args->filename));
}'

# Every outbound connect — process, destination IP and port
bpftrace -e 'tracepoint:syscalls:sys_enter_connect {
    printf("%-16s %-6d\n", comm, pid);
}'

# List all available tracepoints (hundreds)
bpftrace -l 'tracepoint:syscalls:*' | head -30

uprobe — Userspace Function Probes

Attaches to a specific function in a userspace binary or library. Useful for observing application behaviour without recompiling.

# What bash commands are being typed on this node?
bpftrace -e 'uprobe:/bin/bash:readline { printf("%s\n", str(arg0)); }'

# Python function calls
bpftrace -e 'uprobe:/usr/bin/python3:PyObject_Call { printf("Python call: pid %d\n", pid); }'

From a security standpoint: this is how you observe what an attacker is typing in an interactive shell they’ve obtained on your node — in real time, from the kernel, without touching the terminal session.

interval — Periodic Sampling

Runs a block of code on a fixed interval. Used for aggregation and periodic stats.

# Print the top file-opening processes every 5 seconds
bpftrace -e '
kprobe:vfs_open { @[comm] = count(); }
interval:s:5  { print(@); clear(@); }
'

The One-Liner Toolkit: Runnable Right Now

These run on any Linux node with BTF (kernel 5.8+, Ubuntu 20.04+, most managed K8s nodes):

# What files is every process opening right now? (30-second view)
bpftrace -e 'tracepoint:syscalls:sys_enter_openat {
    printf("%-16s %s\n", comm, str(args->filename));
}' --timeout 30

# Who is making DNS queries? (catches queries from any container, no sidecar needed)
bpftrace -e 'tracepoint:net:net_dev_xmit {
    if (args->skbaddr->protocol == 0x0800) printf("%s\n", comm);
}'

# Latency histogram for all read() syscalls — find the slow process
bpftrace -e '
tracepoint:syscalls:sys_enter_read { @start[tid] = nsecs; }
tracepoint:syscalls:sys_exit_read  {
    $latency = nsecs - @start[tid];
    @latency[comm] = hist($latency);
    delete(@start[tid]);
}' --timeout 15

# Which process is using the most CPU right now? (99Hz sampling)
bpftrace -e 'profile:hz:99 { @[comm] = count(); }' --timeout 10

# Real-time syscall frequency — find unusual process activity
bpftrace -e 'tracepoint:raw_syscalls:sys_enter { @[comm, args->id] = count(); }' --timeout 10 \
  | sort -k3 -rn | head -20

# New TCP connections in the last 30 seconds — source and dest
bpftrace -e 'kprobe:tcp_connect {
    $sk = (struct sock *)arg0;
    printf("%-16s → %s:%d\n", comm,
           ntop(AF_INET, $sk->__sk_common.skc_daddr),
           $sk->__sk_common.skc_dport >> 8);
}' --timeout 30

# What is a specific PID doing? (replace 12345)
bpftrace -e 'tracepoint:syscalls:sys_enter_openat /pid == 12345/ {
    printf("%s\n", str(args->filename));
}'

Each of these compiles and loads in under 2 seconds. They leave no persistent state. When they exit, the kernel reverts to exactly the state it was in before.

The Security Use Cases

Watching an Active Session

If you suspect a process is running commands you didn’t deploy:

# See every bash command on this node in real time
bpftrace -e 'uprobe:/bin/bash:readline { printf("%s %s\n", comm, str(arg0)); }'

# Every process spawn — PID, parent, command
bpftrace -e 'tracepoint:syscalls:sys_enter_execve {
    printf("%-6d %-6d %s\n", pid, curtask->real_parent->tgid, str(args->filename));
}'

This is the kernel-level version of watching /var/log/auth.log — except it can’t be suppressed by an attacker who has root, because the probe runs in kernel space. An attacker who has compromised a container with root inside the container cannot prevent a bpftrace program on the host from observing their syscalls.

Detecting Unexpected Network Activity

# Any process making a connection to a non-standard port
bpftrace -e 'kprobe:tcp_connect {
    $sk = (struct sock *)arg0;
    $port = $sk->__sk_common.skc_dport >> 8;
    if ($port != 80 && $port != 443 && $port != 53) {
        printf("%-16s port %d\n", comm, $port);
    }
}'

# DNS queries to non-standard resolvers (anything not on port 53)
bpftrace -e 'tracepoint:syscalls:sys_enter_sendto {
    if (args->addr->sa_family == 2) {
        printf("%-16s → %s\n", comm, str(args->addr));
    }
}'

Watching File Access on Sensitive Paths

# Any access to /etc/passwd, /etc/shadow, /root/
bpftrace -e 'tracepoint:syscalls:sys_enter_openat {
    if (str(args->filename) == "/etc/passwd" ||
        str(args->filename) == "/etc/shadow") {
        printf("%-16s PID %-6d opened %s\n", comm, pid, str(args->filename));
    }
}'

Production Gotchas

CPU overhead: bpftrace probes fire synchronously in the traced context. High-frequency probes on hot kernel paths (vfs_read, sys_enter_* without filtering) can add 10–20% overhead. Always test with --timeout and watch %si before running on a production node.

Maps grow unbounded by default: @[comm] = count() will accumulate an entry per unique comm value forever in the current session. Use clear(@) in an interval block, or set a key limit: @[comm] = count(); if (@[comm] > 100) { clear(@comm); }.

kprobe instability: Functions targeted by kprobes can be inlined by the compiler between kernel versions, making the probe silently ineffective. If a kprobe isn’t firing, verify the function exists: bpftrace -l 'kprobe:function_name'. If it returns nothing, the function was inlined. Use a tracepoint equivalent instead.

Container PIDs: PIDs inside a container are different from host PIDs. pid in bpftrace is the host namespace PID.

Container PID semantics: When a container shows PID 1 internally, the host kernel sees it as PID 8432 (or whatever was assigned). bpftrace’s pid built-in always gives you the host-namespace PID. To map a container’s PID to the host PID: cat /proc/<host-pid>/status | grep NSpid — the second value is the PID inside the container. Or use curtask->real_parent->tgid in your probe to walk the process tree. This matters when you filter by pid in a one-liner and get no output — you may be filtering on the container-namespace PID instead of the host one.

BTF requirement: bpftrace requires BTF for struct field access ($sk->__sk_common.skc_daddr). If BTF is unavailable, struct access fails. Check /sys/kernel/btf/vmlinux exists before running struct-access one-liners.

Quick Reference

Probe type	Syntax	Use for
kernel function entry	`kprobe:function_name`	Function arguments
kernel function return	`kretprobe:function_name`	Return value, latency
kernel tracepoint	`tracepoint:subsys:name`	Stable, versioned hooks
userspace function	`uprobe:/path/to/bin:function`	App-level observation
CPU sampling	`profile:hz:99`	Flamegraphs, hot code
interval	`interval:s:N`	Periodic aggregation
process start	`tracepoint:syscalls:sys_enter_execve`	New process detection

Built-in variable	Value
`pid`	Process ID (host namespace)
`tid`	Thread ID
`comm`	Process name (15 chars)
`nsecs`	Nanoseconds since boot
`curtask`	Pointer to `task_struct`
`retval`	Return value (kretprobe/tracepoint exit)
`args`	Probe arguments struct

Key Takeaways

bpftrace is an eBPF compiler, not a monitoring agent — every one-liner compiles, loads, runs, and cleans up a complete kernel program
kretprobe and tracepoint cover most production debugging needs; use tracepoints for stability across kernel versions
The security use cases are unique: kernel-level observation that an attacker inside a container cannot suppress, because the probe runs on the host in kernel space
Every connection, every file open, every process spawn — observable in real time with a single command, no prior instrumentation
Production caution: high-frequency probes on hot paths add overhead; filter by pid/comm, use --timeout, watch %si

What’s Next

bpftrace answers questions you ask in the moment. EP10 covers what happens when you need those answers continuously — not as a one-shot investigation tool, but as persistent telemetry recording every network connection across your entire cluster.

Flow observability from TC hooks is the always-on version: a persistent eBPF program recording every connection attempt, every retransmit, every dropped packet — the ground truth layer that everything above it interprets. When your APM says “timeout” and the kernel says “retransmit storm to one specific endpoint,” the kernel is right.

Next: network flow observability at the kernel level

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OpenLDAP Setup and Replication: Running Your Own Directory

April 30, 2026 by Vamshi Krishna Santhapuri

Reading Time: 5 minutes

The Identity Stack, Episode 6
EP01 → … → EP05: Kerberos → EP06 → EP07: LDAP HA → …

Focus Keyphrase: OpenLDAP setup
Search Intent: Navigational
Meta Description: Set up OpenLDAP with the MDB backend, configure it via cn=config (OLC), and wire up SyncRepl replication — a complete walkthrough for running your own directory. (162 chars)

TL;DR

OpenLDAP’s server process is slapd — the backend that stores data is MDB (LMDB), a memory-mapped B-tree that replaced the old Berkeley DB backend
Configuration lives in the directory itself: cn=config (OLC — Online Configuration) lets you modify slapd at runtime without restarting
SyncRepl is the replication protocol: a consumer subscribes to a provider and stays in sync via either polling (refreshOnly) or a persistent connection (refreshAndPersist)
Multi-Provider (formerly Multi-Master) lets multiple nodes accept writes — conflict resolution uses CSN (Change Sequence Number), last-writer-wins
The essential tools: slapd, ldapadd, ldapmodify, ldapsearch, slapcat, slaptest
Always build indexes on the attributes you search most — uid, cn, memberOf — or every search is a full scan

The Big Picture: slapd Architecture

ldapsearch / ldapadd / SSSD / any LDAP client
              │ TCP 389 / 636
              ▼
         ┌─────────────────────────────────┐
         │  slapd (OpenLDAP server)         │
         │                                 │
         │  Frontend (protocol layer)       │
         │    • parse BER requests          │
         │    • ACL enforcement             │
         │    • schema validation           │
         │                                 │
         │  Backend (storage layer)         │
         │    • MDB (LMDB) — default       │
         │    • memory-mapped file I/O      │
         │    • ACID transactions           │
         └────────────┬────────────────────┘
                      │
              /var/lib/ldap/
              data.mdb   (the directory data)
              lock.mdb   (LMDB lock file)

EP05 showed Kerberos in isolation. OpenLDAP is where you run the identity store that Kerberos references — and where SSSD looks up user and group attributes. This episode builds a working two-node replicated directory from scratch.

Installation

# Ubuntu / Debian
apt-get install -y slapd ldap-utils

# RHEL / Rocky / AlmaLinux
dnf install -y openldap-servers openldap-clients

# After install — Ubuntu runs a configuration wizard
# Skip it: dpkg-reconfigure slapd
# Or answer it and then switch to OLC management

On RHEL-family systems, slapd is not configured after install — you work entirely through OLC from the start.

OLC: The Directory Configures Itself

The old way was slapd.conf — a static file that required a full restart on every change. OLC (Online Configuration) replaced it: slapd‘s own configuration is stored as LDAP entries under cn=config. You modify configuration the same way you modify data — with ldapmodify. Changes take effect immediately.

cn=config                        ← root config entry
├── cn=schema,cn=config          ← schema definitions
│     ├── cn={0}core             ← core schema
│     ├── cn={1}cosine           ← RFC 1274 attributes
│     └── cn={2}inetorgperson    ← inetOrgPerson object class
├── olcDatabase={-1}frontend     ← default settings for all databases
├── olcDatabase={0}config        ← the config database itself
└── olcDatabase={1}mdb           ← your actual directory data
      ├── olcAccess              ← ACLs
      ├── olcSuffix              ← base DN (e.g., dc=corp,dc=com)
      └── olcDbIndex             ← search indexes

Everything under cn=config has attributes prefixed with olc (OpenLDAP Configuration). You query and modify it just like any other LDAP subtree — with one restriction: only the cn=config admin (usually gidNumber=0+uidNumber=0,cn=peercred,cn=external,cn=auth — the local root via SASL EXTERNAL) can write to it.

Bootstrapping a Directory

The quickest way to get a working directory is a set of LDIF files applied in order.

1. Load schemas

# Apply the schemas OpenLDAP ships with
ldapadd -Y EXTERNAL -H ldapi:/// \
  -f /etc/ldap/schema/cosine.ldif
ldapadd -Y EXTERNAL -H ldapi:/// \
  -f /etc/ldap/schema/inetorgperson.ldif
ldapadd -Y EXTERNAL -H ldapi:/// \
  -f /etc/ldap/schema/nis.ldif       # adds posixAccount, posixGroup

2. Configure the MDB database

# mdb-config.ldif
dn: olcDatabase={1}mdb,cn=config
changetype: modify
replace: olcSuffix
olcSuffix: dc=corp,dc=com
-
replace: olcRootDN
olcRootDN: cn=admin,dc=corp,dc=com
-
replace: olcRootPW
olcRootPW: {SSHA}hashed_password_here

Generate the hash: slappasswd -s yourpassword

ldapmodify -Y EXTERNAL -H ldapi:/// -f mdb-config.ldif

3. Add indexes

# indexes.ldif
dn: olcDatabase={1}mdb,cn=config
changetype: modify
add: olcDbIndex
olcDbIndex: uid eq,pres
olcDbIndex: cn eq,sub
olcDbIndex: sn eq,sub
olcDbIndex: mail eq
olcDbIndex: memberOf eq
olcDbIndex: entryCSN eq
olcDbIndex: entryUUID eq

The last two (entryCSN, entryUUID) are required for SyncRepl replication to work efficiently.

4. Load initial data

# base.ldif
dn: dc=corp,dc=com
objectClass: top
objectClass: dcObject
objectClass: organization
o: Corp
dc: corp

dn: ou=people,dc=corp,dc=com
objectClass: organizationalUnit
ou: people

dn: ou=groups,dc=corp,dc=com
objectClass: organizationalUnit
ou: groups

dn: uid=vamshi,ou=people,dc=corp,dc=com
objectClass: inetOrgPerson
objectClass: posixAccount
objectClass: shadowAccount
cn: Vamshi Krishna
sn: Krishna
uid: vamshi
uidNumber: 1001
gidNumber: 1001
homeDirectory: /home/vamshi
loginShell: /bin/bash
mail: [email protected]
userPassword: {SSHA}hashed_password_here

ldapadd -x -H ldap://localhost \
  -D "cn=admin,dc=corp,dc=com" \
  -w adminpassword \
  -f base.ldif

ACLs: Who Can Read What

OpenLDAP ACLs are evaluated top-to-bottom; first match wins.

# acls.ldif — set via OLC
dn: olcDatabase={1}mdb,cn=config
changetype: modify
replace: olcAccess
# Users can change their own passwords
olcAccess: to attrs=userPassword
  by self write
  by anonymous auth
  by * none
# Users can read their own entry
olcAccess: to dn.base="ou=people,dc=corp,dc=com"
  by self read
  by users read
  by * none
# Service accounts can read everything (for SSSD)
olcAccess: to *
  by dn="cn=svc-ldap,ou=services,dc=corp,dc=com" read
  by self read
  by * none

A service account (cn=svc-ldap) that SSSD uses to search the directory needs read access to ou=people and ou=groups. Never give SSSD admin (write) access.

SyncRepl Replication

SyncRepl is a pull-based replication protocol built on the LDAP Sync operation (RFC 4533). A consumer connects to a provider and requests changes. The provider sends them. The consumer stays in sync.

On the Provider: Enable the syncprov overlay

# syncprov.ldif
dn: olcOverlay=syncprov,olcDatabase={1}mdb,cn=config
objectClass: olcOverlayConfig
objectClass: olcSyncProvConfig
olcOverlay: syncprov
olcSpCheckpoint: 100 10     # checkpoint every 100 ops or 10 minutes
olcSpSessionLog: 100        # keep last 100 changes for delta-sync

ldapadd -Y EXTERNAL -H ldapi:/// -f syncprov.ldif

On the Consumer: Configure syncrepl

# consumer-config.ldif
dn: olcDatabase={1}mdb,cn=config
changetype: modify
add: olcSyncrepl
olcSyncrepl: rid=001
  provider=ldap://ldap1.corp.com:389
  bindmethod=simple
  binddn="cn=repl-svc,dc=corp,dc=com"
  credentials=replication-password
  searchbase="dc=corp,dc=com"
  scope=sub
  schemachecking=on
  type=refreshAndPersist    # persistent connection (vs refreshOnly = polling)
  retry="5 5 60 +"          # retry: 5 times every 5s, then every 60s forever
  interval=00:00:05:00      # (for refreshOnly) sync every 5 minutes
-
add: olcUpdateRef
olcUpdateRef: ldap://ldap1.corp.com   # redirect writes to provider

refreshAndPersist keeps a persistent connection open. Changes replicate within milliseconds. refreshOnly polls on an interval — simpler, but adds latency.

Verify Replication

# On provider: check the contextCSN (the sync state token)
ldapsearch -x -H ldap://ldap1.corp.com \
  -D "cn=admin,dc=corp,dc=com" -w password \
  -b "dc=corp,dc=com" -s base contextCSN
# contextCSN: 20260427010000.000000Z#000000#000#000000

# On consumer: should match after sync
ldapsearch -x -H ldap://ldap2.corp.com \
  -D "cn=admin,dc=corp,dc=com" -w password \
  -b "dc=corp,dc=com" -s base contextCSN
# Same CSN = in sync

Multi-Provider: Accepting Writes on Both Nodes

Standard SyncRepl has one provider and one or more consumers — only the provider accepts writes. Multi-Provider (formerly Multi-Master) lets every node accept writes.

# On each node — add mirrormode to the database config
dn: olcDatabase={1}mdb,cn=config
changetype: modify
add: olcMirrorMode
olcMirrorMode: TRUE

With mirrormode enabled and each node configured as both provider and consumer of the other, writes on either node replicate to the other. Conflict resolution is CSN-based (Change Sequence Number) — a monotonically increasing timestamp. Last write wins at the attribute level.

Multi-Provider does not prevent split-brain conflicts — if two clients write the same attribute on two different nodes during a network partition, the higher CSN wins when the partition heals. For most directory use cases (user passwords, group memberships), this is acceptable. For others, it requires careful thought.

⚠ Production Gotchas

MDB data file grows monotonically. LMDB never shrinks the data file automatically. Deleted entries leave free space inside the file that gets reused, but the file on disk doesn’t shrink. Use slapcat to export and slapadd to reimport if you need to reclaim disk space.

slapcat is the only safe backup. slapcat reads the MDB database directly and exports LDIF — it does not go through slapd. Run it while slapd is running (LMDB is MVCC-safe for readers), but never copy the raw MDB files while slapd is running.

Schema changes on a replicated directory require coordination. Load the new schema on the provider first. SyncRepl will propagate it to consumers — but if a consumer gets a new entry using the new schema before the schema itself is replicated, the import will fail. Load schemas manually on all nodes before adding entries that use them.

Key Takeaways

OpenLDAP uses LMDB (MDB backend) — a memory-mapped, ACID-compliant storage engine with no external dependency
OLC (cn=config) is the right way to configure slapd — changes apply without restarts
SyncRepl pulls changes from a provider to a consumer — refreshAndPersist for near-real-time, refreshOnly for poll-based
Always index uid, cn, entryCSN, and entryUUID — unindexed searches are full scans
Multi-Provider allows writes on all nodes with CSN-based last-write-wins conflict resolution

What’s Next

A single OpenLDAP server works. Two nodes with SyncRepl work better. EP07 goes further: how you put multiple LDAP servers behind a load balancer, how connection pooling works, what to monitor, and how 389-DS handles directories with tens of millions of entries.

Next: LDAP High Availability: Load Balancing and Production Architecture

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Compliance Grading — Automated OpenSCAP with A-F Scores Before Deployment

May 3, 2026April 29, 2026 by Vamshi Krishna Santhapuri

Reading Time: 6 minutes

OS Hardening as Code, Episode 4
Cloud AMI Security Risks · Linux Hardening as Code · Multi-Cloud OS Hardening · Automated OpenSCAP Compliance**

Focus Keyphrase: automated OpenSCAP compliance
Search Intent: Navigational
Meta Description: Get an A-F compliance grade on every AMI before it deploys — automated OpenSCAP scanning, SARIF export, and drift detection built into the image build process. (158 chars)

TL;DR

“We use CIS L1” means nothing without a verified grade — automated OpenSCAP compliance provides one before any instance is deployed
Stratum runs OpenSCAP after every build and attaches the grade to the image metadata: cis-l1-A-98
Grades are A through F based on percentage of controls passing, with explicit accounting for documented overrides
SARIF output is machine-readable — importable directly into GitHub Advanced Security, Jira, or any SIEM
Drift detection: rescan any running instance against the original blueprint and see exactly which controls changed since the image was built
An image that scores below your minimum grade threshold doesn’t get snapshotted — it doesn’t exist

The Problem: A Grade That’s Never Been Verified Is Not a Grade

Security audit request:
"Provide CIS L1 compliance evidence for all production instances"

Team response:
  Instance A: "CIS L1 hardened" — OpenSCAP last run: 4 months ago
  Instance B: "CIS L1 hardened" — OpenSCAP last run: never
  Instance C: "CIS L1 hardened" — OpenSCAP version: 1.2 (current: 1.3.8)
  Instance D: "CIS L1 hardened" — manual scan output: "87% passing"
  Instance E: "CIS L1 hardened" — manual scan output: "91% passing"

"Which profile was used for D and E? Are they comparable?"
"Were they scanned before or after a recent kernel update?"
"Why is C running an old OpenSCAP version?"

Automated OpenSCAP compliance means the grade is generated the same way, on every image, every time, before the image is ever deployed.

EP03 showed that the same HardeningBlueprint YAML builds consistent OS images across six cloud providers. What it left open is the question every auditor eventually asks: how do you know the Ansible hardening actually did what you think it did? Running Ansible-Lockdown successfully means the tasks ran. It does not mean every CIS control is satisfied — some controls can’t be applied by Ansible alone, some require manual verification, and some interact with the environment in unexpected ways.

A compliance team requested CIS L2 evidence for a SOC 2 Type II audit. The security team had been running OpenSCAP scans — but manually, on-demand, using slightly different profiles across teams, with no standard for how to store or compare results.

The audit found four problems:
1. Two instances had been scanned with CIS L1, not L2, despite being labeled “CIS L2”
2. Three instances hadn’t been scanned in over six months
3. The scan outputs from different teams were in different formats (HTML vs XML vs text)
4. Two instances showed “91% passing” and “89% passing” — with no documentation of whether those were acceptable thresholds or what the failing controls were

The audit took two weeks to resolve. The finding wasn’t a security failure — it was a documentation and process failure. But it consumed two weeks of engineering time and appeared in the audit report as a gap.

The root cause: compliance scanning was a manual step that produced inconsistent output in an inconsistent format.

How Automated OpenSCAP Compliance Works

Every Stratum build ends with an automated OpenSCAP scan:

stratum build --blueprint ubuntu22-cis-l1.yaml --provider aws
      │
      ├─ Provisions build instance
      │
      ├─ Runs Ansible-Lockdown (144 tasks)
      │
      ├─ Runs post-build OpenSCAP scan
      │    ├── Profile: CIS Ubuntu 22.04 L1 (from blueprint)
      │    ├── OpenSCAP version: pinned in blueprint (default: latest)
      │    └── 100 controls checked
      │
      ├─ Calculates grade
      │    ├── Passing:   92 controls
      │    ├── Failing:   6 controls
      │    ├── Overrides: 2 (documented in blueprint)
      │    └── Grade: A (94/100 effective, 98% pass rate)
      │
      ├─ Writes to image metadata:
      │    compliance_grade=cis-l1-A-94
      │    compliance_scan_date=2026-04-19
      │    [email protected]
      │
      └─ Snapshots AMI (or fails if grade < min_grade)

The grade is written into the AMI (or GCP/Azure image) metadata at creation time. It travels with the image. Any instance launched from this AMI carries the provenance of what was applied and what grade was achieved.

The A-F Grade Calculation

The grade is not a simple percentage. It accounts for documented overrides and applies a threshold-based letter scale:

Total CIS controls:    100
Passing:               92
Failing:               6 (genuine failures)
Overrides (compliant): 2 (documented in blueprint, counted as passing)

Effective passing:     94 / 100
Grade:                 A

Grade thresholds (configurable per blueprint):

Grade	Default threshold	Meaning
A	≥ 95% effective	Production-ready, minimal exceptions
B	85–94%	Acceptable with documented exceptions
C	70–84%	Below standard — deploy with caution
D	55–69%	Significant gaps — do not deploy to production
F	< 55%	Hardening failed — image not snapshotted

The thresholds are configurable in the blueprint:

compliance:
  benchmark: cis-l1
  controls: all
  min_grade: B          # Build fails if grade < B
  grade_thresholds:
    A: 95
    B: 85
    C: 70
    D: 55

If the build produces a grade below min_grade, the instance is terminated and no image is created. The failure is logged with the full list of controls that blocked the grade.

Reading the Scan Output

# Show the last build's scan results
stratum scan --show-last --blueprint ubuntu22-cis-l1.yaml

# Output:
# Build: ubuntu22-cis-l1 @ 2026-04-19T15:42:01Z
# Provider: aws (ap-south-1)
# Grade: A (94/100 effective controls)
#
# Passing controls: 92
# Failing controls: 6
# ──────────────────────────────────────────────
# FAIL  1.1.7   Ensure separate partition for /var/log/audit
#       Reason: tmpfs used — separate block device not configured
#       Remediation: Add /var/log/audit to separate EBS volume
#
# FAIL  1.6.1.3 Ensure AppArmor is enabled in bootloader config
#       Reason: GRUB_CMDLINE_LINUX missing apparmor=1 security=apparmor
#       Remediation: Update /etc/default/grub, run update-grub, reboot
#
# FAIL  3.1.1   Ensure IPv6 is disabled if not needed
#       Reason: net.ipv6.conf.all.disable_ipv6=0
#       Remediation: Set in /etc/sysctl.d/60-kernel-hardening.conf
# ...
#
# Overrides (compliant): 2
# ──────────────────────────────────────────────
# OVERRIDE  1.1.2   tmpfs /tmp via systemd unit — equivalent control
# OVERRIDE  5.2.4   SSH timeout managed by session manager policy

The failing controls tell you exactly what to fix and how to fix it. This is the difference between “87% passing” as a number and “87% passing” as an actionable gap list.

SARIF Export

Every scan produces a SARIF (Static Analysis Results Interchange Format) file:

# Export scan results to SARIF
stratum scan \
  --instance i-0abc123 \
  --benchmark cis-l1 \
  --output sarif \
  --out-file scan-results/i-0abc123-cis-l1.sarif

SARIF is the standard format for security scan results. It’s directly importable into:

GitHub Advanced Security — upload via actions/upload-sarif, results appear in the Security tab
Jira — import as security findings, linked to the image or instance ID
Splunk / SIEM — structured JSON, parseable as events
AWS Security Hub — importable as findings via the Security Hub API

For audit purposes, the SARIF file is the evidence artifact. It contains the full scan profile, every control result, the OpenSCAP version, the scan timestamp, and the machine it was run against.

# Upload to GitHub Advanced Security
stratum scan \
  --instance i-0abc123 \
  --benchmark cis-l1 \
  --output sarif \
  --github-upload \
  --github-ref $GITHUB_REF \
  --github-sha $GITHUB_SHA

Drift Detection

The grade at build time is the baseline. Any instance can be rescanned against the blueprint that built it:

# Rescan a running instance
stratum scan --instance i-0abc123 --blueprint ubuntu22-cis-l1.yaml

# Output:
# Instance: i-0abc123 (launched from ami-0a7f3c9e82d1b4c05)
# Original grade (build):  A (94/100) — 2026-01-15
# Current grade (rescan):  B (87/100) — 2026-04-19
#
# Drifted controls (7):
#   3.3.2  TCP SYN cookies: FAIL — net.ipv4.tcp_syncookies=0
#           Last passing: 2026-01-15 (build)
#           Current value: 0 (expected: 1)
#
#   5.3.2  sudo log_input: FAIL — rule removed from /etc/sudoers.d/
#           Last passing: 2026-01-15 (build)
#           Current value: [rule absent] (expected: Defaults log_input)

Drift detection is how you find the instances that were “temporarily” modified and never reverted. The scan compares the current state against the baseline — not against a generic CIS profile, but against the specific blueprint version that built the image.

Scanning Without a Build: Assessing Existing Instances

For instances not built with Stratum, you can run a standalone scan:

# Assess an existing instance against CIS L1
stratum scan --instance i-0legacy123 --benchmark cis-l1

# No blueprint comparison — just the raw CIS grade
# Output:
# Grade: C (72/100)
# 28 controls failing
# ...

This is useful for assessing the state of instances built before Stratum was in use, or for comparing a manual hardening approach against the benchmark.

What Controls Typically Block an A Grade

For Ubuntu 22.04 CIS L1 builds in most cloud environments, these are the controls that most commonly prevent an A grade:

Control	Why it often fails	Fix
1.1.7 `/var/log/audit` separate partition	Cloud images don’t have separate volumes at build time	Add EBS volume, configure at launch
1.6.1 AppArmor bootloader config	GRUB parameters not set correctly	Update `/etc/default/grub`, run `update-grub`
3.1.1 Disable IPv6	Cloud networking sometimes requires IPv6	Override with documented reason if intentional
5.2.21 SSH MaxStartups	Default sshd_config not updated	Add `MaxStartups 10:30:60` to sshd_config
6.1.10 World-writable files	Some package installations leave world-writable files	Post-install cleanup in Ansible role

The first two (separate audit partition, AppArmor bootloader) are the most common A→B blockers and often require architecture decisions about how volumes are provisioned at launch versus build time.

Key Takeaways

Automated OpenSCAP compliance means every image has a verified, reproducible grade generated by the same scanner with the same profile, before it’s ever deployed
The A-F grade accounts for documented overrides from the blueprint — the failing controls in the output are genuine gaps, not known exceptions
SARIF export makes scan results importable into GitHub Advanced Security, Jira, SIEM, and audit tooling
Drift detection catches configuration changes that happen after the image is deployed — the grade at build time is the baseline
Images that score below min_grade don’t get snapshotted — the failed build tells you exactly which controls to fix

What’s Next

Automated OpenSCAP compliance gives every image a verified grade before deployment. What EP04 left open is what happens after the grade is known — specifically, what prevents an engineer from deploying a C-grade image to production “just this once.”

The Pipeline API is the answer. EP05 covers the CI/CD compliance gate: POST /api/pipeline/scan fails the build if the image grade is below threshold. The unhardened image never reaches production — not because engineers are disciplined, but because the pipeline won’t let it through.

Next: CI/CD compliance gate — block unhardened images before they reach production

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How Kerberos Works: Tickets, KDC, and Why Enterprises Use It With LDAP

April 30, 2026April 29, 2026 by Vamshi Krishna Santhapuri

Reading Time: 7 minutes

The Identity Stack, Episode 5
EP01 → EP02 → EP03 → EP04: SSSD → EP05 → EP06: OpenLDAP → …

Focus Keyphrase: how Kerberos works
Search Intent: Informational
Meta Description: How Kerberos works: the KDC, ticket-granting tickets, and the three-step flow that lets enterprises authenticate without sending passwords on the wire. (157 chars)

TL;DR

Kerberos is a network authentication protocol — it proves identity without sending passwords over the network, using time-limited cryptographic tickets
Three actors: the client, the KDC (Key Distribution Center), and the service — the KDC issues tickets; clients use tickets to authenticate to services
The ticket flow: AS-REQ (get a TGT) → TGS-REQ (exchange TGT for a service ticket) → AP-REQ (present service ticket to the target service)
A TGT (Ticket-Granting Ticket) is a session credential — it lets you request service tickets without re-entering your password for the lifetime of the ticket (default 10 hours)
LDAP + Kerberos together: LDAP stores identity (who you are), Kerberos authenticates it (proves you are who you say you are) — Active Directory is exactly this combination
kinit, klist, kdestroy are the hands-on tools — run them and read the ticket output

The Big Picture: Three Actors, Three Steps

         1. AS-REQ / AS-REP
Client ◄────────────────────► AS (Authentication Server)
  │                                     │
  │    (part of KDC)                    │
  │                                     ▼
  │         2. TGS-REQ / TGS-REP   TGS (Ticket-Granting Server)
  ├───────────────────────────────────►│
  │         (part of KDC)              │
  │                                    │
  │    3. AP-REQ / AP-REP              │
  └─────────────────────────────► Service (SSH, LDAP, NFS, HTTP...)

KDC = AS + TGS (usually the same process, same machine)

EP04 mentioned Kerberos tickets and clock skew requirements without explaining the protocol. This episode explains why Kerberos was invented, what a ticket actually is, and how the three-step flow works — so that when SSSD says “KDC unreachable” or kinit fails with “pre-authentication required,” you know exactly what’s happening.

The Problem Kerberos Was Built to Solve

MIT’s Project Athena started in 1983 — a campus-wide computing initiative giving students access to thousands of workstations. The problem: how do you authenticate a student at workstation 847 to a file server across campus without sending their password over the network?

In 1988, Steve Miller and Clifford Neuman published Kerberos version 4. The core insight: a trusted third party (the KDC) can issue cryptographic proof that a user has authenticated, and that proof can be presented to any service on the network without the service ever seeing the user’s password.

The password never leaves the client machine after the initial authentication. Every subsequent authentication — to a different service, to the same service again — uses a ticket. The KDC knows both the client and the service. The client and service only need to trust the KDC.

Keys, Tickets, and Sessions

Before the protocol, the primitives:

Long-term keys — derived from passwords. When you set a password in Kerberos, it’s hashed into a key stored in the KDC database (in the krbtgt account on AD, in /var/lib/krb5kdc/principal on MIT Kerberos). The client also derives this key from the password at authentication time. Neither ever sends the raw password.

Session keys — temporary symmetric keys created by the KDC for a specific session. They’re valid for the ticket’s lifetime. After the ticket expires, the session key is useless.

Tickets — encrypted blobs issued by the KDC. A ticket contains the session key, the client identity, the expiry time, and optional flags. It’s encrypted with the target service’s long-term key — only the service can decrypt it. The client carries the ticket but can’t read the contents.

The Three-Step Flow

Step 1: AS-REQ / AS-REP — Getting a TGT

Client                        KDC (AS component)
  │                                │
  │── AS-REQ ──────────────────────►
  │   {username, timestamp}         │
  │   (timestamp encrypted with     │
  │    client's long-term key)       │
  │                                 │
  │   KDC verifies: decrypts        │
  │   timestamp with stored key.    │
  │   If valid → issues TGT         │
  │                                 │
  ◄── AS-REP ──────────────────────│
      {session_key_enc_with_client, │
       TGT_enc_with_krbtgt_key}     │

The client decrypts the session key using its long-term key (derived from the password). The TGT is encrypted with the KDC’s own key (krbtgt) — the client can’t read it, but carries it.

This is the step that requires the password. After this, the TGT is what the client uses for everything else.

Step 2: TGS-REQ / TGS-REP — Getting a Service Ticket

Client                        KDC (TGS component)
  │                                │
  │── TGS-REQ ─────────────────────►
  │   {TGT, authenticator,         │
  │    target_service_name}        │
  │   (authenticator encrypted      │
  │    with TGT session key)        │
  │                                 │
  │   KDC: decrypts TGT,           │
  │   verifies authenticator,       │
  │   issues service ticket         │
  │                                 │
  ◄── TGS-REP ────────────────────│
      {service_session_key_enc,    │
       service_ticket_enc_with_    │
       service_long_term_key}      │

No password involved. The client proves its identity by presenting the TGT (which only the KDC can issue) and an authenticator (a timestamp encrypted with the TGT’s session key, proving the client holds the session key without revealing it).

Step 3: AP-REQ / AP-REP — Authenticating to the Service

Client                        Service (sshd, LDAP, NFS...)
  │                                │
  │── AP-REQ ──────────────────────►
  │   {service_ticket,             │
  │    authenticator_enc_with_      │
  │    service_session_key}        │
  │                                 │
  │   Service: decrypts ticket      │
  │   with its long-term key,       │
  │   verifies authenticator        │
  │                                 │
  ◄── AP-REP (optional) ───────────│
      {mutual authentication}       │

The service decrypts the ticket using its own key. It extracts the client identity and session key. It verifies the authenticator. No communication with the KDC required — the service trusts what the KDC signed.

Why Clock Skew Matters

Every Kerberos authenticator contains a timestamp. The service rejects authenticators older than 5 minutes (by default) — this prevents replay attacks where an attacker captures an authenticator and replays it later.

This is why clock skew over 5 minutes breaks Kerberos authentication entirely. If your machine’s clock drifts 6 minutes from the KDC, every authenticator you generate is rejected as too old or too far in the future. No tickets. No AD logins. No SSSD authentication.

# Check time sync status
timedatectl status
chronyc tracking        # if using chrony
ntpq -p                 # if using ntpd

# If clock is off: force a sync
chronyc makestep        # immediate step correction (chrony)

Hands-On: kinit, klist, kdestroy

# Get a TGT (will prompt for password)
kinit [email protected]

# Show current tickets
klist
# Credentials cache: FILE:/tmp/krb5cc_1001
# Principal: [email protected]
#
# Valid starting     Expires            Service principal
# 04/27/26 01:00:00  04/27/26 11:00:00  krbtgt/[email protected]
#   renew until 05/04/26 01:00:00

# Show encryption types used (the -e flag)
klist -e
# 04/27/26 01:00:00  04/27/26 11:00:00  krbtgt/[email protected]
#         Etype: aes256-cts-hmac-sha1-96, aes256-cts-hmac-sha1-96

# Get a service ticket for a specific service
kvno host/[email protected]
# host/[email protected]: kvno = 3

# Show all tickets including service tickets
klist -f
# Flags: F=forwardable, f=forwarded, P=proxiable, p=proxy, D=postdated,
#        d=postdated, R=renewable, I=initial, i=invalid, H=hardware auth

# Destroy all tickets
kdestroy

The Valid starting and Expires fields are the ticket lifetime. After expiry, you need to re-authenticate (or renew the ticket if it’s within the renew until window). The renew until date is when even renewal stops working.

/etc/krb5.conf

[libdefaults]
    default_realm = CORP.COM
    dns_lookup_realm = false
    dns_lookup_kdc = true         # find KDCs via DNS SRV records
    ticket_lifetime = 10h
    renew_lifetime = 7d
    forwardable = true            # tickets can be forwarded to remote hosts (needed for SSH forwarding)
    rdns = false

[realms]
    CORP.COM = {
        kdc = dc01.corp.com
        kdc = dc02.corp.com       # failover KDC
        admin_server = dc01.corp.com
    }

[domain_realm]
    .corp.com = CORP.COM
    corp.com = CORP.COM

With dns_lookup_kdc = true, Kerberos finds KDCs by querying DNS SRV records (_kerberos._tcp.corp.com). AD sets these up automatically. On MIT Kerberos, you add them manually. DNS-based discovery is the recommended approach for AD environments — it picks up new DCs automatically.

Kerberos + LDAP: Why Enterprises Run Both

LDAP and Kerberos solve different problems and are almost always deployed together:

LDAP answers:  "Who is vamshi? What groups is he in? What's his home directory?"
Kerberos answers: "Is this really vamshi? Prove it without sending a password."

Active Directory is exactly this combination — the directory is LDAP-based, the authentication is Kerberos. When a Linux machine joins an AD domain via realm join or adcli, it gets:
– LDAP access to the AD directory (for NSS: user and group lookups)
– A Kerberos principal registered in AD (for PAM: ticket-based authentication)
– A machine account (the machine’s identity in the directory)

When you SSH into an AD-joined Linux machine:
1. SSSD issues a Kerberos AS-REQ for the user’s TGT
2. SSSD uses the TGT to get a service ticket for the Linux machine’s PAM service
3. Authentication is verified via the service ticket — no LDAP Bind with a password
4. SSSD does an LDAP Search to get POSIX attributes (UID, GID, home dir)

Password-based LDAP Bind is the fallback when Kerberos isn’t available. Kerberos is the default on AD-joined systems — and it’s more secure because the password never leaves the client.

⚠ Common Misconceptions

“Kerberos sends your password to the KDC.” It doesn’t. The client derives a key from the password locally and uses that key to encrypt a timestamp (the pre-authentication data). The KDC verifies the timestamp using the stored key. The raw password never travels.

“Kerberos is an authorization protocol.” Kerberos authenticates — it proves who you are. Authorization (what you can do) is a separate decision, usually handled by ACLs on the service or directory group membership.

“Once you have a TGT, you’re authenticated to everything.” A TGT only proves your identity to the KDC. Each service requires a separate service ticket. The TGT is what lets you get those service tickets without re-entering your password.

“Kerberos requires AD.” MIT Kerberos 5 is a standalone implementation. FreeIPA (EP08) runs MIT Kerberos. Heimdal is another implementation. AD uses a Microsoft-extended version of Kerberos 5, but the core protocol is the same RFC.

Framework Alignment

Domain	Relevance
CISSP Domain 5: Identity and Access Management	Kerberos is the de facto enterprise authentication protocol — SSO, delegation, and service account authentication all depend on it
CISSP Domain 4: Communications and Network Security	Kerberos prevents credential sniffing and replay attacks — two of the core network authentication threat categories
CISSP Domain 3: Security Architecture and Engineering	The KDC is a critical single point of trust — its availability, key management, and account (`krbtgt`) rotation are architectural security decisions

Key Takeaways

Kerberos is a ticket-based protocol — the password is used once to get a TGT; from then on, tickets prove identity without the password
The three-step flow: get a TGT from the AS, exchange it for a service ticket at the TGS, present the service ticket to the target service
Clock skew over 5 minutes breaks Kerberos — time synchronization is a hard dependency
LDAP stores identity; Kerberos authenticates it — Active Directory is exactly this combination, and so is FreeIPA
klist -e shows the encryption types in use — aes256-cts-hmac-sha1-96 is what you want to see; arcfour-hmac (RC4) is legacy and should be disabled

What’s Next

EP05 covered Kerberos as a protocol. EP06 goes hands-on: building a real LDAP directory with OpenLDAP, configuring replication, and understanding how the server-side components — slapd, the MDB backend, SyncRepl — fit together.

Next: OpenLDAP Setup and Replication: Running Your Own Directory

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SSSD: The Caching Daemon That Powers Every Enterprise Linux Login

April 29, 2026 by Vamshi Krishna Santhapuri

Reading Time: 7 minutes

The Identity Stack, Episode 4
EP01: What Is LDAP → EP02: LDAP Internals → EP03: LDAP Auth on Linux → EP04 → EP05: Kerberos → …

Focus Keyphrase: SSSD Linux
Search Intent: Informational
Meta Description: SSSD powers every enterprise Linux login — but most engineers only interact with it when it breaks. Here’s the architecture, the config knobs that matter, and how to debug it. (185 chars — trim to: SSSD powers every enterprise Linux login. Here’s the architecture, the sssd.conf knobs that matter, and how to debug it when it breaks. (137 chars))
Meta Description (final): SSSD powers every enterprise Linux login. Here’s the architecture, the sssd.conf knobs that matter, and how to debug it when it breaks. (137 chars)

TL;DR

SSSD (System Security Services Daemon) is the caching and brokering layer between Linux and directory services — it handles LDAP, Kerberos, and AD so PAM and NSS don’t have to
Architecture: three tiers — responders (answer PAM/NSS queries), providers (talk to AD/LDAP/Kerberos), and a shared cache (LDB database on disk)
Credential caching means offline logins work — a user who authenticated yesterday can log in today even if the domain controller is unreachable
Key config: sssd.conf — the [domain] section is where almost all tuning happens
Debugging toolkit: sssctl, sss_cache, id, getent, journalctl -u sssd
The most common failure modes are: SSSD not running, stale cache, misconfigured ldap_search_base, and clock skew breaking Kerberos

The Big Picture: SSSD as the Identity Broker

PAM (pam_sss)         NSS (sss module)
      │                      │
      └──────────┬───────────┘
                 ▼
          SSSD Responders
          ┌────────────────────────────────────┐
          │  PAM responder   NSS responder      │
          │  (auth, account, (passwd, group,    │
          │   session)        shadow lookups)   │
          └────────────┬───────────────────────┘
                       │  shared cache (LDB)
                       ▼
          SSSD Providers
          ┌────────────────────────────────────┐
          │  identity provider  auth provider   │
          │  (user/group attrs) (credentials)   │
          └────────────┬───────────────────────┘
                       │
          ┌────────────┼────────────┐
          ▼            ▼            ▼
       LDAP          Kerberos    Local files
    (AD / OpenLDAP)  (KDC / AD)

EP03 showed that SSSD sits between PAM and LDAP. This episode goes inside it — the architecture, the config, and how to tell exactly what it’s doing on any given login attempt.

Why SSSD Exists

The problem before SSSD: nss_ldap and pam_ldap made direct LDAP connections for every query. No caching, no connection pooling, no failover, no offline support. On a system that makes dozens of getpwuid() calls per second (every ls -l, every process spawn), this meant dozens of LDAP roundtrips per second hitting the domain controller.

SSSD solved this with a single daemon that:
– Maintains a persistent connection pool to the directory
– Caches identity and credential data in an LDB (LDAP-like) database on disk
– Handles failover across multiple directory servers
– Satisfies PAM and NSS queries from cache when the directory is unreachable

The credential cache is the key insight. When you authenticate successfully, SSSD stores a hash of your credentials locally. If the domain controller is unreachable on your next login — network outage, laptop offline, VPN not connected — SSSD can verify your credentials against the local cache. You log in. You never knew the DC was down.

SSSD Architecture

SSSD is a set of cooperating processes sharing a cache:

Monitor — the parent process. Starts and restarts all other SSSD processes. If a responder or provider crashes, the monitor restarts it.

Responders — answer queries from PAM and NSS. Each responder handles a specific interface:
– sssd_nss — answers getpwnam(), getpwuid(), getgrnam(), initgroups() calls
– sssd_pam — handles PAM authentication, account checks, and session management
– sssd_autofs, sssd_ssh, sssd_sudo — optional responders for specific services

Providers — the backend processes that talk to the actual directory:
– Each domain gets its own provider process (sssd_be[domain_name])
– The provider connects to LDAP/Kerberos/AD, fetches data, and writes it to the shared cache
– If the provider crashes or loses connectivity, responders fall back to serving from cache

Cache — LDB files in /var/lib/sss/db/. One database per configured domain, plus a cache for negative results (lookups that returned “not found”). The cache is an LDAP-like directory stored on disk — SSSD uses the same hierarchical structure for local storage as the remote directory uses.

# See the cache files
ls -la /var/lib/sss/db/
# cache_corp.com.ldb         ← user/group data for domain corp.com
# ccache_corp.com            ← Kerberos credential cache
# timestamps_corp.com.ldb   ← when entries were last refreshed

sssd.conf: The Config That Matters

/etc/sssd/sssd.conf has a [sssd] section (global) and one [domain/name] section per directory. The domain section is where almost all tuning happens.

[sssd]
services = nss, pam, sudo
domains = corp.com
config_file_version = 2

[domain/corp.com]
# What type of directory this is
id_provider = ad               # or: ldap, ipa, files
auth_provider = ad             # or: ldap, krb5, none
access_provider = ad           # controls who can log in

# The AD/LDAP server (can be a list for failover)
ad_domain = corp.com
ad_server = dc01.corp.com, dc02.corp.com

# Where to look for users and groups
ldap_search_base = dc=corp,dc=com

# Cache behavior
cache_credentials = true       # enable offline login
entry_cache_timeout = 5400     # how long before re-querying (seconds)
offline_credentials_expiration = 1  # days cached credentials stay valid offline

# What uid/gid range belongs to this domain (prevents UID conflicts)
ldap_id_mapping = true         # auto-map AD SIDs to UIDs (no uidNumber needed)
# OR for classical POSIX LDAP:
# ldap_id_mapping = false      # use uidNumber/gidNumber from directory

# Restrict logins to specific AD groups
# access_provider = simple
# simple_allow_groups = linux-admins, sre-team

# Home directory and shell defaults
override_homedir = /home/%u
default_shell = /bin/bash
fallback_homedir = /home/%u

# Enumerate all users (expensive on large dirs — disable unless needed)
enumerate = false

The two most commonly wrong settings:

ldap_search_base — if this doesn’t include the OU where your users live, SSSD won’t find them. On AD, the default searches the entire domain, which is usually correct. On OpenLDAP, you may need ou=people,dc=corp,dc=com.

ldap_id_mapping — on AD, users typically don’t have uidNumber attributes. Setting ldap_id_mapping = true tells SSSD to derive a UID from the user’s SID algorithmically. This produces consistent UIDs across machines. Setting it to false requires actual uidNumber attributes in the directory.

Credential Caching and Offline Logins

The cache is what separates SSSD from a simple proxy. When cache_credentials = true:

On successful authentication, SSSD stores a hash of the credential in the LDB cache
On the next authentication attempt, SSSD first tries the domain controller
If the DC is unreachable, SSSD falls back to the local credential hash
If the hash matches, login succeeds — even with no network

The credential hash is not the cleartext password — it’s a salted hash stored in /var/lib/sss/db/cache_corp.com.ldb. The security model is the same as /etc/shadow: someone with root access to the machine can access the hashes.

offline_credentials_expiration controls how long cached credentials stay valid when the DC is unreachable. 0 means forever (not recommended for high-security environments). 1 means one day — after 24 hours offline, even cached credentials expire and the user must authenticate online.

The Debugging Toolkit

# 1. Is SSSD running?
systemctl status sssd
pgrep -a sssd    # shows all SSSD processes (monitor + responders + providers)

# 2. Domain connectivity status
sssctl domain-status corp.com
# Domain: corp.com
# Active servers:
#   LDAP: dc01.corp.com
#   KDC: dc01.corp.com
# Discovered servers:
#   LDAP: dc01.corp.com, dc02.corp.com

# 3. Can SSSD find a specific user?
sssctl user-checks vamshi
# user: vamshi
# user name: [email protected]
# POSIX attributes: UID=1001, GID=1001, ...
# Authentication: success (uses actual PAM auth stack)

# 4. What does NSS see?
getent passwd vamshi          # full passwd entry
id vamshi                     # uid, gid, groups

# 5. Flush stale cache entries
sss_cache -u vamshi           # invalidate one user
sss_cache -G engineers        # invalidate one group
sss_cache -E                  # invalidate everything (nuclear option)

# 6. Live logs
journalctl -u sssd -f         # tail all SSSD logs
# Then attempt login in another terminal — watch the auth flow in real time

# 7. Increase log verbosity temporarily
sssctl config-check            # validate sssd.conf syntax
# Edit sssd.conf: add debug_level = 6 under [domain/corp.com]
systemctl restart sssd
journalctl -u sssd -f          # now shows LDAP queries, cache hits/misses

The single most useful command is sssctl user-checks <username>. It runs the full NSS + PAM auth stack internally and prints what SSSD would do on a real login — without creating a session or touching the running system.

Breaking SSSD (and What Each Failure Looks Like)

SSSD not running:

ssh vamshi@server
# Permission denied (publickey,gssapi-keyex,gssapi-with-mic,password)
# getent passwd vamshi → (empty)
# Fix: systemctl start sssd

Stale cache after AD password change:

# User changed password in AD but SSSD still has old credential hash
ssh vamshi@server  # password accepted (wrong!) — cache hit with old hash
# Fix: sss_cache -u vamshi, then attempt login again

Clock skew > 5 minutes (breaks Kerberos):

journalctl -u sssd | grep -i "clock skew\|KDC\|kinit"
# sssd_be[corp.com]: Kerberos authentication failed: Clock skew too great
# Fix: systemctl restart chronyd (or ntpd), verify time sync

ldap_search_base wrong:

getent passwd vamshi  # empty, but user exists in AD
sssctl user-checks vamshi  # "User not found"
# Check: ldap_search_base must include the OU containing users
# Test: ldapsearch -x -H ldap://dc -b "ou=engineers,dc=corp,dc=com" "(uid=vamshi)"

⚠ Common Misconceptions

“Restarting SSSD logs everyone out.” Restarting SSSD doesn’t affect existing authenticated sessions. Active shell sessions, running processes — all unaffected. Only new authentication attempts are disrupted during the restart window, which takes a few seconds.

“sss_cache -E fixes everything.” Flushing the entire cache forces SSSD to re-fetch all entries from the domain controller on the next lookup. On a system with many users or enumeration enabled, this can cause a brief spike in LDAP traffic and slow lookups. Use targeted flushes (-u username, -G group) when possible.

“debug_level should always be high.” SSSD at debug_level = 9 logs every LDAP packet. On a production system with active logins, this generates gigabytes of logs quickly. Set it temporarily for debugging, then remove it and restart.

Framework Alignment

Domain	Relevance
CISSP Domain 5: Identity and Access Management	SSSD is the runtime implementation of enterprise identity integration on Linux — understanding its caching model, failover behavior, and credential storage is foundational to IAM operations
CISSP Domain 3: Security Architecture and Engineering	The credential cache design (`/var/lib/sss/db/`) creates a local credential store with specific security properties — architects need to understand the offline login trade-off
CISSP Domain 7: Security Operations	SSSD is a critical security service — monitoring it, understanding its failure modes, and knowing how to recover it quickly are operational security skills

Key Takeaways

SSSD is a three-tier system: responders (serve PAM/NSS), providers (talk to AD/LDAP), and a shared LDB cache — each tier is independently restartable
Credential caching enables offline logins — the security trade-off is a local hash store in /var/lib/sss/db/
sssctl user-checks is the first tool to reach for when a login fails — it simulates the full auth flow and shows exactly where it breaks
ldap_id_mapping = true is the right choice for AD environments without POSIX attributes; false requires actual uidNumber/gidNumber in the directory
Clock skew over 5 minutes silently breaks Kerberos authentication — time sync is a hard dependency

What’s Next

EP04 showed SSSD’s role as the caching and brokering layer. What it referenced repeatedly — “Kerberos ticket”, “KDC”, “GSSAPI” — is the authentication protocol that sits underneath AD-joined Linux logins. SSSD uses Kerberos to authenticate. LDAP carries the identity data. EP05 explains how Kerberos works.

Next: How Kerberos Works: Tickets, KDC, and Why Enterprises Use It With LDAP

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How LDAP Authentication Works on Linux: PAM, NSS, and the Login Stack

April 29, 2026April 27, 2026 by Vamshi Krishna Santhapuri

Reading Time: 9 minutes

The Identity Stack, Episode 3
EP01: What Is LDAP → EP02: LDAP Internals → EP03 → EP04: SSSD → …

Focus Keyphrase: LDAP authentication Linux
Search Intent: Informational
Meta Description: Trace a Linux SSH login through PAM, NSS, and LDAP step by step — and understand why LDAP alone is not an authentication protocol. (144 chars)

TL;DR

LDAP is a directory protocol — it stores identity information and can verify a password via Bind, but authentication on Linux runs through PAM, not directly through LDAP
NSS (/etc/nsswitch.conf) answers “who is this user?” — it resolves UIDs, group memberships, and home directories by querying LDAP (or the local files, or SSSD)
PAM (/etc/pam.d/) answers “are they allowed in?” — it enforces authentication, account validity, session setup, and password policy
pam_ldap (the old way) opened a direct LDAP connection on every login — fragile, no caching, broken when the LDAP server was unreachable
pam_sss (the modern way) delegates to SSSD, which caches credentials and handles failover — SSSD is the layer between Linux and the directory
Tracing a single SSH login: sshd → PAM → pam_sss → SSSD → LDAP Bind + Search → session created

You type: ssh [email protected]

  sshd
    │
    ▼
  PAM  (/etc/pam.d/sshd)          ← "Is this user allowed in?"
    │
    ├── pam_sss    (auth)          ← sends credentials to SSSD
    ├── pam_sss    (account)       ← checks account not expired/locked
    ├── pam_sss    (session)       ← logs the session open/close
    └── pam_mkhomedir (session)    ← creates /home/vamshi if it doesn't exist
    │
    ▼
  SSSD  (/etc/sssd/sssd.conf)     ← "Let me check the directory"
    │
    ├── NSS responder              ← answers getent, id, getpwnam
    └── LDAP/Kerberos provider     ← talks to the actual directory
    │
    ▼
  LDAP Server (AD / OpenLDAP)
    │
    ├── Bind: uid=vamshi + password (or Kerberos ticket)
    └── Search: posixAccount attrs for uid=vamshi
    │
    ▼
  Linux session created
  UID=1001, GID=1001, HOME=/home/vamshi, SHELL=/bin/bash

EP02 showed what the directory contains and what travels on the wire. What it left open is how Linux uses that to grant a login — and why LDAP is not, by itself, an authentication protocol.

Why LDAP Is Not an Authentication Protocol

This is the confusion that trips people most. LDAP can verify a password — the Bind operation does exactly that. But authentication on Linux means something broader: checking credentials, checking account validity, enforcing password policy, setting up a session, creating a home directory. LDAP handles one piece of that. PAM handles the rest.

More precisely: LDAP doesn’t know what a Linux session is. It doesn’t know about /etc/pam.d/. It doesn’t enforce login hours, account expiry, or concurrent session limits. It returns directory entries and verifies binds. The intelligence about what to do with those results lives in the Linux authentication stack.

When you run ssh vamshi@server, the OS doesn’t open an LDAP connection and ask “can this user log in?” It calls PAM. PAM consults its configuration, and PAM decides whether to call LDAP (directly or via SSSD), whether to check the shadow file, whether to enforce MFA. LDAP is one possible backend. It’s not the gatekeeper.

NSS: The Traffic Controller

Before PAM runs, Linux needs to know if the user exists at all. That’s NSS’s job.

/etc/nsswitch.conf is a routing table for name resolution. It tells the OS where to look when something asks “who is UID 1001?” or “what groups is vamshi in?”:

# /etc/nsswitch.conf

passwd:     files sss        ← user lookups: check /etc/passwd first, then SSSD
group:      files sss        ← group lookups: check /etc/group first, then SSSD
shadow:     files sss        ← shadow password lookups
hosts:      files dns        ← hostname lookups (not identity-related)
netgroup:   sss              ← NIS netgroups from SSSD only
automount:  sss              ← autofs maps from SSSD

Every call to getpwnam(), getpwuid(), getgrnam(), getgrgid() in any process — including sshd — goes through NSS. The entries in nsswitch.conf control which backends are tried in order.

With passwd: files sss, a lookup for user vamshi:
1. Checks /etc/passwd — not found (vamshi is a domain user, not in local files)
2. Queries SSSD — SSSD checks its cache, or queries LDAP, and returns the posixAccount attributes

Without the sss entry in passwd:, domain users don’t exist on the system — getent passwd vamshi returns nothing, id vamshi fails, SSH login never gets to PAM’s authentication step.

# Verify NSS is routing to SSSD correctly
getent passwd vamshi
# vamshi:*:1001:1001:Vamshi K:/home/vamshi:/bin/bash

# If this returns nothing, NSS isn't reaching SSSD
# Check: systemctl status sssd && grep passwd /etc/nsswitch.conf

# See what groups the user is in (NSS group lookup)
id vamshi
# uid=1001(vamshi) gid=1001(engineers) groups=1001(engineers),1002(ops)

PAM: The Real Gatekeeper

PAM (Pluggable Authentication Modules) is the framework that lets Linux swap authentication backends without recompiling anything. Every service that needs to authenticate users — sshd, sudo, login, su, gdm — has a PAM configuration file in /etc/pam.d/.

Each PAM config defines four stacks:

auth        ← verify credentials (password, key, MFA)
account     ← check if the account is valid (not expired, not locked, login hours)
password    ← password change policy
session     ← set up/tear down the session (home dir, limits, logging)

A typical /etc/pam.d/sshd on a system joined to AD via SSSD:

# /etc/pam.d/sshd

# auth stack — verify the user's credentials
auth    required      pam_sepermit.so
auth    substack      password-auth   ← usually includes pam_sss.so

# account stack — check account validity
account required      pam_nologin.so
account include       password-auth

# password stack — handle password changes
password include      password-auth

# session stack — set up the session
session required      pam_selinux.so close
session required      pam_loginuid.so
session optional      pam_keyinit.so force revoke
session include       password-auth
session optional      pam_motd.so
session optional      pam_mkhomedir.so skel=/etc/skel/ umask=0077
session required      pam_selinux.so open

The include and substack directives pull in shared stacks from other files (like /etc/pam.d/password-auth). On a system with SSSD, password-auth contains:

auth    required      pam_env.so
auth    sufficient    pam_sss.so      ← try SSSD first
auth    required      pam_deny.so     ← if pam_sss fails, deny

account required      pam_unix.so
account sufficient    pam_localuser.so
account sufficient    pam_sss.so      ← SSSD account check
account required      pam_permit.so

session optional      pam_sss.so      ← SSSD session tracking

The sufficient flag means: if this module succeeds, stop checking this stack and consider it passed. required means: this must pass (but continue checking other modules and report failure at the end). requisite means: if this fails, stop immediately.

PAM Control Flags at a Glance

required   — must succeed; failure reported after remaining modules run
requisite  — must succeed; failure reported immediately, stack stops
sufficient — if success, stop stack (ignore remaining); failure continues
optional   — result ignored unless it's the only module in the stack

This matters for debugging. If pam_sss.so is sufficient and SSSD is down, PAM falls through to pam_deny.so — login denied. If it were optional, the login would proceed to the next module. The control flag is the policy decision.

The Old Way: pam_ldap

Before SSSD, Linux systems used pam_ldap and nss_ldap directly:

# Old /etc/pam.d/common-auth (Ubuntu pre-SSSD era)
auth    sufficient    pam_ldap.so    ← direct LDAP connection per login
auth    required      pam_unix.so nullok_secure

# Old /etc/nsswitch.conf
passwd: files ldap    ← nss_ldap for user lookups
group:  files ldap

pam_ldap opened a fresh LDAP connection on every login attempt. No caching. If the LDAP server was unreachable for 3 seconds, the login hung for 3 seconds — sometimes much longer. If the LDAP server was down, all domain logins failed immediately. Previously logged-in users with active sessions were fine; new logins simply didn’t work.

nss_ldap had the same problem for NSS lookups: every getpwnam() call hit the LDAP server directly. On a busy system with many processes doing user lookups, this meant hundreds of LDAP queries per second, no connection reuse, and no way to survive a brief network blip.

The problems were structural:
– No credential caching — offline logins impossible
– No connection pooling — LDAP server saw one connection per login attempt
– No failover logic — one LDAP server down meant all logins down
– Slow timeouts that blocked login sessions

SSSD was built to fix all of this.

The Modern Way: pam_sss + SSSD

pam_sss doesn’t talk to LDAP directly. It’s a thin client that passes authentication requests to SSSD over a Unix domain socket. SSSD manages the LDAP connection, the credential cache, and the failover logic.

sshd  →  PAM (pam_sss)  →  SSSD (Unix socket)  →  LDAP server
                                   │
                                   └── credential cache
                                       (survives brief LDAP outages)

When pam_sss sends a credential to SSSD:
1. SSSD checks its in-memory cache — if the credential hash matches a recent successful auth, it can satisfy the request without hitting LDAP
2. If not cached (or cache expired), SSSD sends a Bind to the LDAP server
3. On success, SSSD caches the result and returns success to pam_sss
4. pam_sss returns PAM_SUCCESS, and the auth stack continues

The credential cache is what enables offline logins. If the LDAP server is unreachable and a user has authenticated successfully within the cache TTL (default: 1 day for credentials, configurable via cache_credentials = True in sssd.conf), SSSD satisfies the auth from cache and the login succeeds. The user never knows the LDAP server was down.

Here’s every step of an SSH login for a domain user, in order:

1.  sshd accepts the TCP connection
2.  sshd calls PAM: pam_start("sshd", "vamshi", ...)

3.  PAM auth stack runs pam_sss:
      pam_sss sends credentials to SSSD via /var/lib/sss/pipes/pam

4.  SSSD auth provider:
      a. Check credential cache — miss (first login)
      b. Resolve user: NSS lookup for uid=vamshi
         → SSSD LDAP provider searches dc=corp,dc=com for (uid=vamshi)
         → Returns: uidNumber=1001, gidNumber=1001, homeDirectory=/home/vamshi
      c. Authenticate: LDAP Simple Bind as uid=vamshi,ou=engineers,dc=corp,dc=com
         → Server returns: success
      d. Cache the credential hash + POSIX attrs

5.  SSSD returns PAM_SUCCESS to pam_sss

6.  PAM account stack runs pam_sss:
      SSSD checks: account not expired, not locked, login permitted
      → PAM_ACCT_MGMT success

7.  PAM session stack:
      pam_loginuid sets /proc/self/loginuid = 1001
      pam_mkhomedir creates /home/vamshi if missing
      pam_sss opens session (records in SSSD session tracking)

8.  sshd creates the shell, sets environment:
      USER=vamshi, HOME=/home/vamshi, SHELL=/bin/bash, LOGNAME=vamshi

9.  Shell prompt appears

Steps 4b and 4c are the only two LDAP operations in the entire login flow: one Search to resolve the user’s attributes, one Bind to verify the password. Everything else is PAM and SSSD.

Debugging the Stack

When a login fails, the failure could be in any layer. Work top-down:

# 1. Does NSS resolve the user at all?
getent passwd vamshi
# If empty: NSS isn't reaching SSSD, or SSSD isn't finding the user in LDAP

# 2. Is SSSD running and healthy?
systemctl status sssd
sssctl domain-status corp.com      # shows SSSD's view of domain connectivity

# 3. What does SSSD think about the user?
sssctl user-checks vamshi          # runs auth + account checks internally
id vamshi                          # forces NSS resolution and shows group memberships

# 4. What does SSSD's log say?
journalctl -u sssd -f              # tail SSSD logs live, then attempt login

# 5. Can you reach the LDAP server at all?
ldapsearch -x -H ldap://dc.corp.com \
  -D "cn=svc-ldap,ou=services,dc=corp,dc=com" \
  -w "password" \
  -b "dc=corp,dc=com" \
  "(uid=vamshi)" dn

# 6. Force a cache flush if entries are stale
sss_cache -u vamshi                # invalidate this user's cache entry
sss_cache -G engineers             # invalidate a group

The sssctl user-checks command is the single most useful diagnostic — it simulates the full PAM auth + account check flow without actually creating a session, and prints exactly what SSSD would do on a real login attempt.

⚠ Common Misconceptions

“If ldapsearch works, SSH login should work.” Not necessarily. ldapsearch tests the LDAP layer. An SSH login requires NSS to resolve the user, PAM to authenticate, SSSD to be running and configured correctly, and pam_mkhomedir to create the home directory if it’s the first login. Any of these can fail independently.

“pam_ldap and pam_sss do the same thing.” They have the same job (authenticate via LDAP) but completely different architectures. pam_ldap is a direct-connect, no-cache module. pam_sss is a client of SSSD, which provides caching, connection pooling, failover, and offline support. On any modern system, you want pam_sss.

“nsswitch.conf order doesn’t matter much.” It matters exactly as much as the order suggests. passwd: files sss means local /etc/passwd is always checked first — if a domain username collides with a local user, the local account wins. This is the intended behavior (local accounts should always be reachable), but it means you’ll never override a local account with a directory entry.

“SSSD cache = security risk.” The cache stores a credential hash, not the cleartext password. An attacker with access to the SSSD cache database (/var/lib/sss/db/) would see hashed credentials — the same situation as /etc/shadow. The real concern is whether offline authentication is appropriate for your security posture; it can be disabled with offline_credentials_expiration = 0.

Framework Alignment

Domain	Relevance
CISSP Domain 5: Identity and Access Management	PAM is the enforcement layer for authentication policy on Linux — understanding its stack is foundational to any Linux IAM deployment
CISSP Domain 3: Security Architecture and Engineering	The separation between NSS (resolution) and PAM (authentication) is an architectural boundary — misunderstanding it leads to misconfigured systems where account checks are bypassed
CISSP Domain 4: Communications and Network Security	pam_ldap vs pam_sss affects whether credentials travel over a direct LDAP connection (one socket per login, no TLS guarantee) or through SSSD’s managed, pooled connection

Key Takeaways

LDAP alone is not an authentication protocol for Linux — authentication flows through PAM, and LDAP is one of PAM’s possible backends
NSS (/etc/nsswitch.conf) resolves user identity (who is UID 1001?); PAM enforces it (are they allowed in?)
pam_ldap talks to LDAP directly — no cache, no failover, login blocked when LDAP is unreachable
pam_sss delegates to SSSD — credential caching, connection pooling, offline login, and failover are all built in
A full SSH login touches LDAP exactly twice: one Search for POSIX attributes, one Bind to verify the password
When login fails, debug top-down: NSS resolution → SSSD status → LDAP reachability → PAM config

What’s Next

EP03 showed how authentication reaches LDAP — through PAM, through SSSD, through a Bind. What it assumed is that SSSD is healthy and the LDAP server is reachable. The moment either goes wrong, the behavior depends entirely on how SSSD is configured — its cache TTLs, its failover order, its offline credential policy.

EP04 goes inside SSSD: the architecture, the sssd.conf knobs that matter, how to read the logs, and how to break it intentionally and fix it.

Next: SSSD: The Caching Daemon That Powers Every Enterprise Linux Login

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