GCP IAM Policy Inheritance: How the Resource Hierarchy Controls Access

April 15, 2026 by Vamshi Krishna Santhapuri

Introduction

I once inherited a GCP environment where the previous team had taken what they thought was a shortcut. They had a folder called Production with twelve projects in it. Rather than grant developers access to each project individually, they bound roles/editor at the folder level. One binding, twelve projects, all covered. Fast.

When I audited what roles/editor on that folder actually meant, I found it gave every developer in that binding write access to Cloud SQL databases they’d never heard of, BigQuery datasets from other teams, Pub/Sub topics in shared services, and Cloud Storage buckets that held data exports. Not because anyone intended that. Because permissions in GCP flow downward through the hierarchy, and a broad role at a high level means a broad role everywhere below it.

The developer who made that binding understood “Editor means edit access.” They didn’t think through what “edit access at the folder level” means across twelve projects. This is the GCP IAM trap that catches teams coming from AWS: the hierarchy feels like an organizational convenience feature, not an access control mechanism. It’s both.

This episode is about understanding GCP IAM through that lens — not as a system for granting access, but as a system where every grant propagates in ways you need to trace before you commit.

The Resource Hierarchy — Not Just Org Structure

GCP’s resource hierarchy is the backbone of its IAM model:

Organization  (e.g., company.com)
  └── Folder  (e.g., Production, Development, Shared-Services)
        └── Folder  (nested, optional — up to 10 levels)
              └── Project  (unit of resource ownership and billing)
                    └── Resource  (GCE instance, GCS bucket, Cloud SQL, BigQuery, etc.)

The critical rule: IAM bindings at any level inherit downward to every node below.

Org IAM binding:
  [email protected] → roles/viewer (org-level)
    ↓ inherited by
  Folder: Production
    ↓ inherited by
  Project: prod-web-app
    ↓ inherited by
  GCS bucket "prod-assets"

Result: alice can list and read resources across the ENTIRE org,
        across every folder, every project, every resource.
        Even if none of those resources have a direct binding for alice.

roles/viewer at the org level sounds benign — it’s just read access. But read access to everything in the organization, including infrastructure configurations, customer data exports in GCS, BigQuery analytics, Cloud SQL connection details, and Kubernetes cluster configs. Not benign.

Before making any binding above the project level, trace it down. Ask: what does this role grant, and at every project and resource below this folder, am I comfortable with that?

# Understand your org structure before making changes
gcloud organizations list

gcloud resource-manager folders list --organization=ORG_ID

gcloud projects list --filter="parent.id=FOLDER_ID"

# See all existing bindings at the org level — do this regularly
gcloud organizations get-iam-policy ORG_ID --format=json | jq '.bindings[]'

Member Types — Who Can Hold a Binding

GCP uses the term member (being renamed to principal) for the identity in a binding:

Member Type	Format	Notes
Google Account	`user:[email protected]`	Individual Google/Workspace account
Service Account	`serviceAccount:[email protected]`	Machine identity
Google Group	`group:[email protected]`	Workspace group
Workspace Domain	`domain:company.com`	All users in a Workspace domain
All Authenticated	`allAuthenticatedUsers`	Any authenticated Google identity — extremely broad
All Users	`allUsers`	Anonymous + authenticated — public access
Workload Identity	`principal://iam.googleapis.com/...`	External workloads via WIF

The ones that have caused data exposure incidents: allAuthenticatedUsers and allUsers. Any GCS bucket or GCP resource bound to allAuthenticatedUsers is accessible to any of the ~3 billion Google accounts in existence. I have seen production customer data exposed this way — a developer testing a public CDN pattern applied the binding to the wrong bucket.

Audit for these regularly:

# Find any project-level binding with allUsers or allAuthenticatedUsers
gcloud projects get-iam-policy my-project --format=json \
  | jq '.bindings[] | select(.members[] | contains("allUsers") or contains("allAuthenticatedUsers"))'

# Check all GCS buckets in a project for public access
gsutil iam get gs://BUCKET_NAME \
  | grep -E "(allUsers|allAuthenticatedUsers)"

Role Types — Choose the Right Granularity

Basic (Primitive) Roles — Don’t Use in Production

roles/viewer   → read access to most resources across the entire project
roles/editor   → read + write to most resources
roles/owner    → full access including IAM management

These are legacy roles from before GCP had service-specific roles. roles/editor is particularly dangerous because it grants write access across almost every GCP service in the project. Use it in production and you have no meaningful separation of duties between your services.

I’ve seen roles/editor granted to a data pipeline service account because “it needed access to BigQuery, Cloud Storage, and Pub/Sub.” All three of those have predefined roles. Three specific bindings. Instead: one broad role that also grants access to Cloud SQL, Kubernetes, Secret Manager, and Compute Engine — none of which the pipeline needed.

Predefined Roles — The Default Correct Choice

Service-specific roles managed and updated by Google. For most use cases, these are the right choice:

# Find predefined roles for Cloud Storage
gcloud iam roles list --filter="name:roles/storage" --format="table(name,title)"
# roles/storage.objectViewer   — read objects (not list buckets)
# roles/storage.objectCreator  — create objects, cannot read or delete
# roles/storage.objectAdmin    — full object control
# roles/storage.admin          — full bucket + object control (much broader)

# See exactly what permissions a predefined role includes
gcloud iam roles describe roles/storage.objectViewer

The distinction between roles/storage.objectViewer and roles/storage.admin is the difference between “can read objects” and “can read objects, create objects, delete objects, and modify bucket IAM policies.” Use the narrowest role that covers the actual need.

Custom Roles — When Predefined Is Still Too Broad

When you need finer control than any predefined role offers, create a custom role:

cat > custom-log-reader.yaml << 'EOF'
title: "Log Reader"
description: "Read application logs from Cloud Logging — nothing else"
stage: "GA"
includedPermissions:
  - logging.logEntries.list
  - logging.logs.list
  - logging.logMetrics.get
  - logging.logMetrics.list
EOF

# Create at project level (available within one project)
gcloud iam roles create LogReader \
  --project=my-project \
  --file=custom-log-reader.yaml

# Or at org level (reusable across projects in the org)
gcloud iam roles create LogReader \
  --organization=ORG_ID \
  --file=custom-log-reader.yaml

# Grant the custom role
gcloud projects add-iam-policy-binding my-project \
  --member="serviceAccount:[email protected]" \
  --role="projects/my-project/roles/LogReader"

Custom roles have an operational overhead: when Google adds new permissions to a service, predefined roles are updated automatically. Custom roles are not — you have to update them manually. For roles like “Log Reader” that are unlikely to need new permissions, this isn’t a concern. For roles like “App Admin” that span many services, it becomes a maintenance burden.

IAM Policy Bindings — How Access Is Actually Granted

The mechanism for granting access in GCP is adding a binding to a resource’s IAM policy. A binding is: member + role + (optional condition).

# Grant a role on a project (all resources in the project inherit this)
gcloud projects add-iam-policy-binding my-project \
  --member="user:[email protected]" \
  --role="roles/storage.objectViewer"

# Grant on a specific GCS bucket (narrower — only this bucket)
gcloud storage buckets add-iam-policy-binding gs://prod-assets \
  --member="serviceAccount:[email protected]" \
  --role="roles/storage.objectViewer"

# Grant on a specific BigQuery dataset
bq update --add_iam_policy_binding \
  --member="group:[email protected]" \
  --role="roles/bigquery.dataViewer" \
  my-project:analytics_dataset

# View the current IAM policy on a project
gcloud projects get-iam-policy my-project --format=json

# View a specific resource's policy
gcloud storage buckets get-iam-policy gs://prod-assets

The choice between project-level and resource-level binding has real consequences. A binding on the GCS bucket affects only that bucket. A binding at the project level affects the bucket AND every other resource in the project. Default to the most specific scope available. Only move up the hierarchy when the alternative is an unmanageable number of bindings.

Conditional Bindings — Time-Limited and Context-Scoped Access

Conditions scope when a binding applies. They use CEL (Common Expression Language):

# Temporary access for a contractor — automatically expires
gcloud projects add-iam-policy-binding my-project \
  --member="user:[email protected]" \
  --role="roles/storage.objectViewer" \
  --condition="expression=request.time < timestamp('2026-06-30T00:00:00Z'),title=Contractor access Q2 2026"

# Access only from corporate network
gcloud projects add-iam-policy-binding my-project \
  --member="user:[email protected]" \
  --role="roles/bigquery.admin" \
  --condition="expression=request.origin.ip.startsWith('10.0.'),title=Corp network only"

Temporary access that automatically expires is one of the most practical applications of conditional bindings. Instead of “I’ll grant access and remember to remove it,” you set an expiry and it removes itself. The cognitive overhead of tracking temporary grants doesn’t disappear — you still need to know the grant exists — but the risk of it outliving its purpose drops significantly.

Service Accounts — GCP’s Machine Identity

Service accounts are the machine identity in GCP. They should be used for every workload that needs to call GCP APIs — GCE instances, GKE pods, Cloud Functions, Cloud Run services.

# Create a service account
gcloud iam service-accounts create app-backend \
  --display-name="App Backend Service Account" \
  --project=my-project

SA_EMAIL="[email protected]"

# Grant it the specific role it needs — on the specific resource it needs
gcloud storage buckets add-iam-policy-binding gs://app-assets \
  --member="serviceAccount:${SA_EMAIL}" \
  --role="roles/storage.objectViewer"

# Attach to a GCE instance
gcloud compute instances create my-vm \
  --service-account="${SA_EMAIL}" \
  --scopes="cloud-platform" \
  --zone=us-central1-a

From inside the VM, Application Default Credentials (ADC) handles authentication automatically:

# From the VM — ADC uses the attached SA without any credential configuration
gcloud auth application-default print-access-token

# Or via the metadata server directly
curl -H "Metadata-Flavor: Google" \
  "http://metadata.google.internal/computeMetadata/v1/instance/service-accounts/default/token"

Service Account Keys — The Antipattern to Avoid

A service account key is a JSON file containing a private key. It’s long-lived, it doesn’t expire automatically, and if it leaks it gives an attacker persistent access as that service account until someone discovers and revokes it.

# Creating a key — only if there is genuinely no alternative
gcloud iam service-accounts keys create key.json --iam-account="${SA_EMAIL}"
# This generates a long-lived credential. It will exist until explicitly deleted.

# List all active keys — do this in every audit
gcloud iam service-accounts keys list --iam-account="${SA_EMAIL}"

# Delete a key
gcloud iam service-accounts keys delete KEY_ID --iam-account="${SA_EMAIL}"

In the GCP environment I mentioned earlier — the one with roles/editor at the folder level — I also found 23 service account key files downloaded across the team’s laptops over 18 months. Several were for accounts that no longer existed. Nobody had a complete list of which keys were still valid and where they were stored. That’s not a hypothetical attack surface: that’s a breach waiting for a laptop to be stolen.

Never create service account keys when:
– Code runs on GCE/GKE/Cloud Run/Cloud Functions — use the attached service account and ADC
– Code runs in GitHub Actions — use Workload Identity Federation
– Code runs on-premises with Kubernetes — use Workload Identity Federation with OIDC

Service Account Impersonation — The Right Alternative to Keys

Instead of downloading a key, grant a user or service account permission to impersonate the service account. They generate a short-lived token, not a permanent credential:

# Allow alice to impersonate the service account
gcloud iam service-accounts add-iam-policy-binding "${SA_EMAIL}" \
  --member="user:[email protected]" \
  --role="roles/iam.serviceAccountTokenCreator"

# Alice generates a token for the SA — no key file, short-lived
gcloud auth print-access-token --impersonate-service-account="${SA_EMAIL}"

# Or configure ADC to use impersonation
export GOOGLE_IMPERSONATE_SERVICE_ACCOUNT="${SA_EMAIL}"
gcloud storage ls gs://app-assets  # runs as the SA

This is the right model for humans who need to act as service accounts for debugging or deployment: impersonate, use, done. The token expires. No file to manage.

Workload Identity Federation — Credentials Eliminated

The cleanest solution for any workload running outside GCP that needs to call GCP APIs: Workload Identity Federation. The external workload authenticates with its native identity (a GitHub Actions OIDC JWT, an AWS IAM role, a Kubernetes service account token), exchanges it for a short-lived GCP access token, and never handles a service account key.

# Create a Workload Identity Pool
gcloud iam workload-identity-pools create "github-actions-pool" \
  --project=my-project \
  --location=global \
  --display-name="GitHub Actions WIF Pool"

# Create a provider (GitHub OIDC)
gcloud iam workload-identity-pools providers create-oidc "github-provider" \
  --project=my-project \
  --location=global \
  --workload-identity-pool="github-actions-pool" \
  --issuer-uri="https://token.actions.githubusercontent.com" \
  --attribute-mapping="google.subject=assertion.sub,attribute.repository=assertion.repository" \
  --attribute-condition="assertion.repository_owner == 'my-org'"

# Allow a specific GitHub repo to impersonate the SA
gcloud iam service-accounts add-iam-policy-binding "${SA_EMAIL}" \
  --role="roles/iam.workloadIdentityUser" \
  --member="principalSet://iam.googleapis.com/projects/PROJECT_NUM/locations/global/workloadIdentityPools/github-actions-pool/attribute.repository/my-org/my-repo"

GitHub Actions workflow — no key files, no secrets stored in GitHub:

jobs:
  deploy:
    permissions:
      id-token: write   # required for OIDC token request
      contents: read
    steps:
      - uses: google-github-actions/auth@v2
        with:
          workload_identity_provider: "projects/PROJECT_NUM/locations/global/workloadIdentityPools/github-actions-pool/providers/github-provider"
          service_account: "[email protected]"

      - run: gcloud storage cp dist/ gs://app-assets/ --recursive

The OIDC JWT from GitHub is presented to GCP, which verifies it against GitHub’s public keys, checks the attribute mapping and condition (only the specified repo can use this), and issues a short-lived GCP access token. The credential exists for the duration of the job and is then gone.

IAM Deny Policies — Org-Wide Guardrails

GCP added standalone deny policies separate from bindings. They override grants:

cat > deny-iam-escalation.json << 'EOF'
{
  "displayName": "Deny IAM escalation permissions to non-admins",
  "rules": [{
    "denyRule": {
      "deniedPrincipals": ["principalSet://goog/group/[email protected]"],
      "deniedPermissions": [
        "iam.googleapis.com/roles.create",
        "iam.googleapis.com/roles.update",
        "iam.googleapis.com/serviceAccounts.actAs"
      ]
    }
  }]
}
EOF

gcloud iam policies create deny-iam-escalation-policy \
  --attachment-point="cloudresourcemanager.googleapis.com/projects/my-project" \
  --policy-file=deny-iam-escalation.json

iam.serviceAccounts.actAs is worth calling out specifically. It’s the GCP equivalent of AWS’s iam:PassRole — it allows an identity to make a service act as a specified service account. If a developer can call actAs on a high-privileged service account, they can launch a GCE instance using that service account and then operate with its permissions. Same privilege escalation pattern as iam:PassRole, different name. Deny it for anyone who doesn’t explicitly need it.

Framework Alignment

Framework	Reference	What It Covers Here
CISSP	Domain 5 — Identity and Access Management	GCP’s hierarchical model and service account patterns are the primary IAM constructs for GCP environments
CISSP	Domain 3 — Security Architecture	Resource hierarchy design determines access inheritance — architectural decisions with direct security implications
ISO 27001:2022	5.15 Access control	GCP IAM bindings are the technical implementation of access control policy in GCP environments
ISO 27001:2022	5.18 Access rights	Service account provisioning, conditional bindings with expiry, and workload identity federation
ISO 27001:2022	8.2 Privileged access rights	Folder/org-level bindings and basic roles represent the highest-risk privilege grants in GCP
SOC 2	CC6.1	IAM bindings and Workload Identity Federation address machine identity controls for CC6.1
SOC 2	CC6.3	Conditional bindings with time-bound expiry directly satisfy access removal requirements

Key Takeaways

GCP IAM is hierarchical — bindings inherit downward; a binding at org or folder level has much larger scope than it appears
Basic roles (viewer/editor/owner) are too coarse for production; use predefined or custom roles and grant at the narrowest scope
Service account keys are a long-lived credential antipattern; use ADC on GCP infrastructure, impersonation for humans, and Workload Identity Federation for external workloads
allAuthenticatedUsers and allUsers bindings expose resources to the internet — audit for these in every environment
iam.serviceAccounts.actAs is a privilege escalation vector — treat it like iam:PassRole
Conditional bindings with expiry dates are better than “I’ll remember to remove this later”

What’s Next

EP06 covers Azure RBAC and Entra ID — the most directory-centric of the three models, where Active Directory’s 25 years of enterprise history shapes both the strengths and the complexity of Azure’s access control.

Next: EP06 — Azure RBAC and Entra ID Deep Dive

AWS IAM Deep Dive: Users, Groups, Roles, and Policies Explained

April 15, 2026April 14, 2026 by Vamshi Krishna Santhapuri

What Is Cloud IAM → Authentication vs Authorization → IAM Roles vs Policies → AWS IAM Deep Dive**

TL;DR

IAM users with long-lived access keys are legacy — use IAM Identity Center with federation; static keys are a security finding, not a feature
Roles issue temporary credentials via STS — the right identity model for every service (Lambda, EC2, ECS, CI/CD)
Every role has two required configs: trust policy (who can assume it) + permission policy (what it can do) — both must be correct
SCPs set the org-level ceiling; they cannot grant permissions and do not apply to the management account
Permissions boundaries set an identity-level ceiling — effective permissions are the intersection with identity-based policies, not the union
Cross-account trust without an ExternalId condition is vulnerable to the confused deputy attack — always include it with third-party trust
One role per service, never shared — a shared role’s blast radius is the union of what every consumer needs

The Big Picture

AWS IAM evaluates every API call through a specific chain. Understanding this chain is how you debug access issues and how you design guardrails that actually hold.

  AWS POLICY EVALUATION — every API call walks this chain top to bottom
  An explicit DENY at any step ends evaluation immediately.

         API call arrives
               │
               ▼
  ┌────────────────────────────┐
  │  Explicit DENY in any SCP? │── YES ──────────────────────────► DENIED
  └────────────────┬───────────┘     (cannot be overridden by anything)
                   │ NO
                   ▼
  ┌────────────────────────────┐
  │  SCP present with no ALLOW │── YES ──────────────────────────► DENIED
  └────────────────┬───────────┘
                   │ NO (or no SCP / management account)
                   ▼
  ┌────────────────────────────┐
  │  Explicit DENY in any      │── YES ──────────────────────────► DENIED
  │  identity or resource      │
  │  policy?                   │
  └────────────────┬───────────┘
                   │ NO
                   ▼
  ┌────────────────────────────┐
  │  Resource-based policy     │── YES (same-account principal) ──► ALLOWED*
  │  with ALLOW?               │
  └────────────────┬───────────┘   *unless denied above
                   │ NO
                   ▼
  ┌────────────────────────────┐
  │  Permissions boundary      │── YES, boundary has NO ALLOW ───► DENIED
  │  attached?                 │
  └────────────────┬───────────┘
                   │ NO boundary, or boundary ALLOWS
                   ▼
  ┌────────────────────────────┐
  │  Session policy attached   │── YES, session has NO ALLOW ────► DENIED
  │  (role assumption)?        │
  └────────────────┬───────────┘
                   │ NO session policy, or session ALLOWS
                   ▼
  ┌────────────────────────────┐
  │  Identity-based policy     │── YES ──────────────────────────► ALLOWED
  │  with ALLOW?               │
  └────────────────┬───────────┘
                   │ NO
                   ▼
                DENIED (default — nothing explicitly granted)

  Debugging AccessDenied: work bottom-up.
  Start with the identity-based policy. Then boundary. Then SCP.

Introduction

An AWS IAM deep dive reveals what most teams miss: the difference between an IAM model that works under deadline and one that survives scale, audits, and staff turnover. If you’ve read IAM roles vs policies and understand the three-layer stack, this is where it becomes specific to AWS — trust policies, SCPs, permissions boundaries, cross-account trust, and Identity Center.

In 2017 I was asked to help clean up an AWS account that had been running in production for two years. The team had built something real — a microservices application, a data pipeline, a CI/CD system. Competent engineers. But nobody had been specifically accountable for IAM.

When I pulled the configuration:

One IAM user with AdministratorAccess shared by the entire dev team. Password in a shared password manager. Access key three years old.
Six Lambda functions each carrying AWSLambdaFullAccess, AmazonS3FullAccess, and AmazonDynamoDBFullAccess — three broad managed policies each, instead of one custom policy with what each function actually needed.
A CI/CD pipeline role with iam:* on * because someone once needed to create a role during a deployment and found that the easiest path.
Three IAM users for contractors who had finished their engagements months earlier. Still active, access keys still valid.

None of this was malicious. All of it was the result of reaching for the broadest thing that works, under deadline, without a framework for IAM decisions.

AWS IAM is the most flexible cloud IAM system — and that flexibility is the problem. If you don’t know the full model, you default to broad grants because they’re easier to reason about. Broad things accumulate into exposure. This episode is the full model.

AWS IAM Identity Types: Users, Groups, and Roles Compared

IAM Users: Why Static Access Keys Are a Security Finding

An IAM user is a permanent identity with long-lived credentials: a password for console access, and optionally an access key pair. No expiry on the access key by default.

# Create a user
aws iam create-user --user-name alice

# Generate an access key — no expiry unless you set one
aws iam create-access-key --user-name alice

# Enforce MFA for console access
aws iam create-virtual-mfa-device \
  --virtual-mfa-device-name alice-mfa \
  --outfile /tmp/alice-mfa.png \
  --bootstrap-method QRCodePNG

aws iam enable-mfa-device \
  --user-name alice \
  --serial-number arn:aws:iam::123456789012:mfa/alice-mfa \
  --authentication-code1 123456 \
  --authentication-code2 654321

The access key exists the moment you create it. It survives team changes, org restructures, and offboarding unless someone explicitly deletes it. In every AWS account I’ve audited, access keys are where I find the oldest, most-forgotten credentials.

Current best practice: don’t create IAM users for human access. Use IAM Identity Center with federation. Static access keys are a finding, not a feature.

IAM groups — useful but limited

Groups are collections of users. Policies attached to a group apply to all members. Useful as a middle layer, but limited: you can’t add roles or services to a group, and if you’re moving toward Identity Center, groups in IAM become less relevant.

aws iam create-group --group-name Backend-Developers
aws iam attach-group-policy \
  --group-name Backend-Developers \
  --policy-arn arn:aws:iam::aws:policy/AmazonS3ReadOnlyAccess
aws iam add-user-to-group --group-name Backend-Developers --user-name alice

IAM Roles: How STS Temporary Credentials Work

A role is an identity without permanent credentials. It is assumed by entities — services, users, external systems — and STS issues temporary credentials. Those credentials expire. Nothing to rotate.

# Create a role that EC2 can assume
cat > ec2-trust-policy.json << 'EOF'
{
  "Version": "2012-10-17",
  "Statement": [{
    "Effect": "Allow",
    "Principal": { "Service": "ec2.amazonaws.com" },
    "Action": "sts:AssumeRole"
  }]
}
EOF

aws iam create-role \
  --role-name AppServerRole \
  --assume-role-policy-document file://ec2-trust-policy.json

aws iam attach-role-policy \
  --role-name AppServerRole \
  --policy-arn arn:aws:iam::aws:policy/AmazonS3ReadOnlyAccess

# EC2 needs an instance profile to carry the role
aws iam create-instance-profile --instance-profile-name AppServerProfile
aws iam add-role-to-instance-profile \
  --instance-profile-name AppServerProfile \
  --role-name AppServerRole

# Launch with the profile
aws ec2 run-instances \
  --image-id ami-0abcdef1234567890 \
  --instance-type t3.micro \
  --iam-instance-profile Name=AppServerProfile

From inside the instance — no credential files, no configuration:

curl http://169.254.169.254/latest/meta-data/iam/security-credentials/AppServerRole
# Returns: AccessKeyId, SecretAccessKey, Token, Expiration
# AWS refreshes these before they expire. The application never sees a rotation event.

Lambda, ECS, and other services use different attachment mechanisms but the same model.

AWS IAM Policy Types: Managed, Inline, SCP, and Boundaries

Managed vs inline policies

┌────────────────────┬──────────────────────────────────┬──────────────────────────────────────┐
│ Type               │ Description                      │ Use when                             │
├────────────────────┼──────────────────────────────────┼──────────────────────────────────────┤
│ AWS Managed        │ Created by AWS, read-only        │ Quick prototyping; never production  │
│ Customer Managed   │ Created by you, reusable         │ Standard production permissions      │
│ Inline             │ Embedded in user/group/role      │ Explicit 1:1 non-transferable binding│
└────────────────────┴──────────────────────────────────┴──────────────────────────────────────┘

AWS Managed policies like AmazonS3FullAccess are convenient and dangerous for the same reason: broad by design, meant to cover every use case. For a Lambda that reads one specific bucket, AmazonS3FullAccess grants approximately 30 permissions you didn’t need.

# Create a customer managed policy — scoped to what the Lambda actually does
cat > lambda-reader-policy.json << 'EOF'
{
  "Version": "2012-10-17",
  "Statement": [{
    "Sid": "ReadSpecificBucket",
    "Effect": "Allow",
    "Action": ["s3:GetObject", "s3:ListBucket"],
    "Resource": [
      "arn:aws:s3:::app-data-prod",
      "arn:aws:s3:::app-data-prod/*"
    ]
  }]
}
EOF

aws iam create-policy \
  --policy-name LambdaS3ReadPolicy \
  --policy-document file://lambda-reader-policy.json

aws iam attach-role-policy \
  --role-name lambda-image-processor-role \
  --policy-arn arn:aws:iam::123456789012:policy/LambdaS3ReadPolicy

Service Control Policies — org-wide guardrails

SCPs attach to AWS Organization OUs or accounts. They define the maximum permissions any identity in that scope can have. They cannot grant — only restrict.

Two SCPs I apply to every account from day one:

// Region restriction — blast radius control
{
  "Version": "2012-10-17",
  "Statement": [{
    "Effect": "Deny",
    "Action": "*",
    "Resource": "*",
    "Condition": {
      "StringNotEquals": {
        "aws:RequestedRegion": ["ap-south-1", "us-east-1", "eu-west-1"]
      }
    }
  }]
}

// Protect the audit trail — anti-forensics control
{
  "Version": "2012-10-17",
  "Statement": [{
    "Effect": "Deny",
    "Action": [
      "cloudtrail:StopLogging",
      "cloudtrail:DeleteTrail",
      "cloudtrail:UpdateTrail"
    ],
    "Resource": "*"
  }]
}

The region restriction limits where compromised credentials can operate. The CloudTrail restriction means even an AdministratorAccess compromise cannot erase the audit trail. The attacker knows they’re being logged and cannot stop it. This is the authorization layer — understanding authentication vs authorization makes clear why SCPs operate at Gate 2, not Gate 1.

Permissions boundaries — identity-level ceilings

A permissions boundary sets the maximum permissions for a specific user or role. Effective permissions are the intersection of what the boundary allows and what identity-based policies grant.

Boundary allows:  s3:*, dynamodb:*
Identity policy:  s3:*, ec2:*
──────────────────────────────────
Effective:        s3:*             ← the intersection only

// Boundary: this role can use at most S3 and DynamoDB
{
  "Version": "2012-10-17",
  "Statement": [{
    "Effect": "Allow",
    "Action": ["s3:*", "dynamodb:*"],
    "Resource": "*"
  }]
}

aws iam put-role-permissions-boundary \
  --role-name DevTeamRole \
  --permissions-boundary arn:aws:iam::123456789012:policy/DevTeamBoundary

I use permissions boundaries for safe IAM delegation. When a dev team needs to create their own roles for their services, I give them iam:CreateRole and iam:AttachRolePolicy — but require any role they create to have a specific boundary. They can self-service IAM without accidentally creating a role more powerful than their team should have.

How AWS Cross-Account IAM Trust Works

AWS accounts are IAM isolation boundaries. An identity in Account A has zero access to Account B by default. Cross-account access requires explicit trust in both directions.

Account B creates a role with a trust policy naming Account A's identity.
Account A's identity has permission to call sts:AssumeRole on that role.

// Account B: trust policy on the cross-account role
{
  "Version": "2012-10-17",
  "Statement": [{
    "Effect": "Allow",
    "Principal": {
      "AWS": "arn:aws:iam::ACCOUNT_A_ID:role/DeployPipelineRole"
    },
    "Action": "sts:AssumeRole",
    "Condition": {
      "StringEquals": { "sts:ExternalId": "unique-external-id-12345" }
    }
  }]
}

# Account A: the pipeline assumes the cross-account role
aws sts assume-role \
  --role-arn arn:aws:iam::ACCOUNT_B_ID:role/DeployTarget \
  --role-session-name pipeline-deploy \
  --external-id unique-external-id-12345

# Export the temporary credentials and operate in Account B
export AWS_ACCESS_KEY_ID=...
export AWS_SECRET_ACCESS_KEY=...
export AWS_SESSION_TOKEN=...
aws s3 ls s3://account-b-bucket/

The ExternalId condition prevents the confused deputy attack. Without it, if you operate a service that assumes roles on behalf of customers, an attacker who knows your service’s ARN can trick it into assuming their customer’s role. The ExternalId is a shared secret proving the party requesting assumption is the one who established the trust. Always include it for third-party cross-account trust.

AWS IAM Identity Center: Federated Human Access Without Static Keys

IAM Identity Center (formerly AWS SSO) is the modern answer to “how do engineers access AWS accounts?” It federates an external IdP and maps your organization’s groups to Permission Sets.

  Okta / Google Workspace / Entra ID
    ↓ SAML 2.0 or OIDC
  IAM Identity Center
    ↓ Permission Sets (collections of policies)
  Account Assignments (group → permission set → account)
    ↓
  Temporary credentials in each target account (no long-lived keys)

# Configure CLI access via Identity Center
aws configure sso
# Prompts: SSO start URL, region, account, role

# Login — browser opens for IdP auth
aws sso login --profile prod-admin

# Use normally — credentials are temporary and auto-refreshed
aws s3 ls --profile prod-admin
aws ec2 describe-instances --profile prod-admin

When someone leaves the organization: disable them in your IdP. Their SSO session expires, their temporary credentials expire, access is gone. No access key hunting across 20 accounts.

AWS IAM Patterns for Production: What Survives Scale

Every Lambda, ECS task, and EC2 application gets its own role. Even two Lambdas doing similar things. The moment you share a role, its permissions are the union of what each consumer needs — and a compromise of one consumer exposes the full union.

# Dedicated execution role — specific to this function's actual needs
aws iam create-role \
  --role-name lambda-invoice-processor-role \
  --assume-role-policy-document \
  '{"Version":"2012-10-17","Statement":[{"Effect":"Allow","Principal":{"Service":"lambda.amazonaws.com"},"Action":"sts:AssumeRole"}]}'

aws iam put-role-policy \
  --role-name lambda-invoice-processor-role \
  --policy-name InvoiceProcessorPolicy \
  --policy-document file://lambda-invoice-processor-policy.json

IAM escalation guardrail

Any role that isn’t an explicit IAM admin should have a guardrail blocking escalation actions:

{
  "Sid": "DenyIAMEscalation",
  "Effect": "Deny",
  "Action": [
    "iam:CreateUser", "iam:CreateRole", "iam:AttachRolePolicy",
    "iam:PutRolePolicy", "iam:PassRole", "iam:CreateAccessKey"
  ],
  "Resource": "*",
  "Condition": {
    "StringNotEquals": {
      "aws:PrincipalArn": "arn:aws:iam::123456789012:role/InfraAdminRole"
    }
  }
}

Even if a role gets over-permissioned, it cannot create users, escalate its own privileges, or pass roles to expand its access. Defense in depth against the privilege escalation paths covered in AWS IAM Privilege Escalation: How iam:PassRole Leads to Full Compromise.

Least privilege with tag conditions

{
  "Effect": "Allow",
  "Action": ["ec2:StartInstances", "ec2:StopInstances", "ec2:RebootInstances"],
  "Resource": "arn:aws:ec2:*:*:instance/*",
  "Condition": {
    "StringEquals": {
      "aws:ResourceTag/Environment": "dev",
      "aws:ResourceTag/Owner": "${aws:username}"
    }
  }
}

A developer can control EC2 instances in dev — specifically the ones tagged as theirs. Not prod. Not someone else’s instances. ABAC layered on a role, eliminating a class of privilege escalation through direct resource access.

⚠ Production Gotchas

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 1 — SCPs don't apply to the management account          ║
║                                                                      ║
║  SCPs are applied to member accounts and OUs — not to the org      ║
║  management account. Guardrails you apply to member accounts do    ║
║  not protect the management account itself.                         ║
║                                                                      ║
║  Fix: lock down the management account separately. Use it only for  ║
║  billing and org management. Never run workloads in it.             ║
╚══════════════════════════════════════════════════════════════════════╝

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 2 — Permissions boundary ≠ policy grant                 ║
║                                                                      ║
║  A boundary that allows s3:* does NOT grant S3 access. The         ║
║  boundary is a ceiling. Effective permissions are the intersection  ║
║  of boundary + identity policy. Both must explicitly Allow.         ║
║                                                                      ║
║  Fix: after setting a boundary, check effective permissions with:   ║
║  aws iam simulate-principal-policy                                  ║
╚══════════════════════════════════════════════════════════════════════╝

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 3 — Cross-account trust without ExternalId              ║
║                                                                      ║
║  A trust policy that names any principal from Account A without     ║
║  ExternalId can be exploited if you operate a multi-tenant service. ║
║  An attacker can craft a request that tricks your service into      ║
║  assuming a victim's role (confused deputy).                        ║
║                                                                      ║
║  Fix: always add ExternalId condition to third-party trust policies.║
╚══════════════════════════════════════════════════════════════════════╝

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 4 — iam:* on * in CI/CD role                           ║
║                                                                      ║
║  "The pipeline needs to create roles" is a legitimate requirement.  ║
║  Granting iam:* on * is not. It lets the pipeline create any role  ║
║  with any permissions — effectively full account access.            ║
║                                                                      ║
║  Fix: grant specific iam: actions, require all created roles to     ║
║  carry a permissions boundary. Delegate without escalating.         ║
╚══════════════════════════════════════════════════════════════════════╝

Quick Reference

┌───────────────────────────┬───────────────────────────────────────────────────────────┐
│ Term                      │ What it is                                                │
├───────────────────────────┼───────────────────────────────────────────────────────────┤
│ IAM User                  │ Permanent identity with long-lived credentials — legacy   │
│ IAM Role                  │ Assumable identity; STS issues temp creds — preferred     │
│ Trust policy              │ Who can assume this role (separate from permissions)      │
│ Instance profile          │ Container that attaches a role to an EC2 instance        │
│ AWS Managed policy        │ Broad, maintained by AWS — avoid in production           │
│ Customer Managed policy   │ You own it, you scope it — correct default               │
│ Inline policy             │ 1:1 binding, non-reusable — use only when intentional    │
│ SCP                       │ Org-level guardrail; constrains, does not grant          │
│ Permissions boundary      │ Identity-level ceiling; intersection with policy = effective│
│ Session policy            │ Restricts a specific role assumption session             │
│ ExternalId                │ Shared secret in cross-account trust — prevents confused deputy│
│ IAM Identity Center       │ Federated human access via SSO; no long-lived keys       │
│ Permission Set            │ Policy collection in Identity Center → becomes role in account│
└───────────────────────────┴───────────────────────────────────────────────────────────┘

Commands to know:
┌────────────────────────────────────────────────────────────────────────────────────────┐
│  # Simulate a policy before deploying — will this call succeed?                      │
│  aws iam simulate-principal-policy \                                                  │
│    --policy-source-arn arn:aws:iam::ACCOUNT:role/MyRole \                            │
│    --action-names s3:GetObject \                                                      │
│    --resource-arns arn:aws:s3:::my-bucket/*                                          │
│                                                                                        │
│  # Full IAM snapshot of the account — all users, roles, policies, groups            │
│  aws iam get-account-authorization-details --output json > iam-snapshot.json         │
│                                                                                        │
│  # Find unused permissions — what does this role actually call?                      │
│  aws iam generate-service-last-accessed-details \                                     │
│    --arn arn:aws:iam::ACCOUNT:role/MyRole                                            │
│  aws iam get-service-last-accessed-details --job-id JOB_ID                           │
│                                                                                        │
│  # List all access keys and their age                                                │
│  aws iam list-users --query 'Users[].UserName' --output text | \                    │
│    xargs -I{} aws iam list-access-keys --user-name {}                               │
│                                                                                        │
│  # Check effective permissions boundary on a role                                    │
│  aws iam get-role --role-name MyRole \                                               │
│    --query 'Role.PermissionsBoundary'                                                │
│                                                                                        │
│  # Assume a cross-account role                                                       │
│  aws sts assume-role \                                                                │
│    --role-arn arn:aws:iam::TARGET_ACCOUNT:role/CrossAccountRole \                   │
│    --role-session-name deploy-session \                                               │
│    --external-id your-external-id                                                    │
└────────────────────────────────────────────────────────────────────────────────────────┘

Framework Alignment

Framework	Reference	What It Covers Here
CISSP	Domain 5 — Identity and Access Management	AWS IAM is the most widely deployed cloud IAM system; this covers the full model
CISSP	Domain 6 — Security Assessment and Testing	Policy evaluation logic is the foundation for cloud security assessments
ISO 27001:2022	5.15 Access control	Access control policy in AWS — SCPs, identity-based policies, resource-based policies
ISO 27001:2022	5.18 Access rights	User and role provisioning, permission boundaries, Identity Center assignments
ISO 27001:2022	8.2 Privileged access rights	IAM Identity Center, SCPs as org-level guardrails, least-privilege role design
SOC 2	CC6.1	AWS IAM is the primary technical control for CC6.1 in AWS-hosted environments
SOC 2	CC6.3	Identity Center with federation enables auditable access provisioning and removal
SOC 2	CC6.6	Cross-account trust relationships and ExternalId address third-party access controls

Key Takeaways

IAM users with static access keys are legacy for human access — use IAM Identity Center with federation; static keys are a persistent finding
Roles issue temporary credentials and are the right identity for every service — Lambda, EC2, ECS, CI/CD, cross-account
Trust policy controls who can assume a role; permission policy controls what the role can do — debug both when access fails
SCPs cap maximum permissions at org level and cannot be overridden — use them for region restriction and audit trail protection; they do not apply to the management account
Permissions boundaries cap at identity level — effective permissions are the intersection with identity-based policies, not the union
Cross-account trust without ExternalId is vulnerable to confused deputy — always include it with third-party trust
One role per service; share nothing — a shared role’s blast radius is the union of every consumer’s required permissions

What’s Next

EP05 moves to GCP IAM — a fundamentally different model where the resource hierarchy drives access inheritance. A misconfiguration at the folder level affects every project below it. We’ll cover why roles/editor keeps appearing in production audits and how to build a GCP IAM structure that composes correctly up the hierarchy.

Get the GCP IAM deep dive in your inbox when it publishes → https://linuxcent.com/subscribe

Next: GCP IAM Policy Inheritance: How the Resource Hierarchy Controls Access

IAM Roles vs Policies: How Cloud Authorization Actually Works

April 15, 2026April 14, 2026 by Vamshi Krishna Santhapuri

What Is Cloud IAM → Authentication vs Authorization → IAM Roles vs Policies → AWS IAM Deep Dive

TL;DR

Every cloud permission is atomic: one action (s3:GetObject) on one resource class — the indivisible unit of access
Policies group permissions into documents with conditions; roles carry policies and are assigned to identities
Never attach policies directly to users — roles are the indirection layer that makes access auditable and revocable
AWS roles have two required configs: trust policy (who can assume) + permission policy (what they can do) — both must be right
GCP binds roles to resources; AWS attaches policies to identities — the mental models run in opposite directions
iam:PassRole in AWS and iam.serviceAccounts.actAs in GCP are privilege escalation vectors — always scope to specific ARNs, never *

The Big Picture

Three primitives underlie every cloud IAM system. Learn how they connect and any cloud access model becomes readable.

  THE THREE-LAYER STACK
  Build bottom-up. Assign top-down. Change one layer without touching the others.

  ┌──────────────────────────────────────────────────────────────────────┐
  │  LAYER 3 — IDENTITY                                                  │
  │  [email protected]  ·  backend-service  ·  ci-runner@proj           │
  │  "who is acting — a human, a service, or a machine"                 │
  ├──────────────────────────────────────────────────────────────────────┤
  │  LAYER 2 — ROLE                                                      │
  │  BackendDeveloper  ·  DataAnalyst  ·  DeployBot  ·  S3ReadOnly      │
  │  "what function does this identity serve — the job title"           │
  ├──────────────────────────────────────────────────────────────────────┤
  │  LAYER 1 — POLICY                                                    │
  │  AllowS3Read  ·  AllowECRPush  ·  DenyProdDelete  ·  RequireMFA    │
  │  "what is explicitly permitted or denied, under what conditions"    │
  ├──────────────────────────────────────────────────────────────────────┤
  │  LAYER 0 — PERMISSION                                                │
  │  s3:GetObject  ·  ecr:PutImage  ·  s3:DeleteObject  ·  iam:PassRole│
  │  "one verb on one class of resource — the atom of access control"  │
  └──────────────────────────────────────────────────────────────────────┘

  When alice joins the backend team → assign her the BackendDeveloper role
  When the S3 bucket changes → update the policy once; alice gets it automatically
  When alice leaves → remove the role assignment; policy and permissions are untouched

If this maps better to something physical:

  PHYSICAL WORLD            →    CLOUD IAM

  A specific door rule           Permission      s3:GetObject
  Keycard access profile    →    Policy          AllowS3Read
  Job title                 →    Role            BackendDeveloper
  The employee              →    Identity        [email protected]

  When the employee leaves: revoke the role assignment.
  The job title, the keycard profile, the door rules — all unchanged.
  Next hire gets the same role. Same access. No manual work.

Introduction

IAM roles vs policies is a distinction that defines how cloud authorization actually works — and getting it wrong is how access sprawl starts. Every authentication vs authorization failure at the authorization layer traces back to how these three primitives are — or aren’t — structured.

Every cloud IAM system — AWS, GCP, Azure — is built on the same three primitives: permissions, policies, and roles. Learn these well and any cloud provider becomes readable. Skip them and you spend years pattern-matching without understanding why anything is structured the way it is.

What Is Cloud IAM established the foundation: IAM is the system that governs who can access what in cloud infrastructure, and its default answer is always deny. Authentication vs Authorization: AWS AccessDenied Explained drew the line between authentication — proving identity — and authorization — proving you’re allowed to act. This episode is about the authorization layer specifically. These three building blocks are how authorization is expressed in practice.

Before walking through each one, here’s what access control looks like without any of this structure — because that’s the fastest way to understand why the layers exist.

In 2015 I inherited an AWS account from a 12-engineer team that had been building for 18 months. When I ran aws iam list-attached-user-policies across the 23 users, 17 had policies attached directly to the user object — not to groups, not to roles. Directly. One engineer had left six months earlier. His access key was still active. Three policies still attached: read access to prod S3, write to a DynamoDB table, ability to invoke Lambda functions. When I asked what the DynamoDB table was for, nobody could tell me. The Lambda functions no longer existed.

That account wasn’t built by negligent engineers. It was built by engineers reaching for whatever granted access fastest, under deadline, without a framework. Permissions scattered. Nothing tracked. Nothing removed.

Roles, policies, and permissions are the framework that prevents that. Understanding them is the difference between an IAM configuration you can audit in an afternoon and one that takes a week and still leaves you uncertain.

What Are IAM Permissions? The Atomic Unit of Access Control

A permission is a single action on a class of resources. It is the most granular thing you can grant or deny — the atom of access control.

Cloud providers express permissions differently, but the structure is consistent: a service, a resource type, and an action verb.

# AWS: service:Action
s3:GetObject               # read an object from S3
ec2:StartInstances         # start EC2 instances
iam:PassRole               # assign a role to an AWS service — one of the most dangerous
kms:Decrypt                # use a KMS key to decrypt

# GCP: service.resource.verb
storage.objects.get
compute.instances.start
iam.serviceAccounts.actAs  # impersonate a service account — equivalent risk to iam:PassRole
cloudkms.cryptoKeyVersions.useToDecrypt

# Azure: Provider/ResourceType/Action
Microsoft.Storage/storageAccounts/blobServices/containers/read
Microsoft.Compute/virtualMachines/start/action
Microsoft.Authorization/roleAssignments/write   # grant roles — highest risk
Microsoft.KeyVault/vaults/secrets/getSecret/action

You generally don’t assign individual permissions directly to identities — that’s like handing someone 47 keys with no labels and expecting the system to remain auditable. Permissions are grouped into policies.

What Are IAM Policies? Grouping Permissions with Conditions

A policy is a document that groups permissions and defines the conditions under which they apply.

AWS policy structure

An AWS policy document is JSON. Every field is a deliberate decision:

{
  "Version": "2012-10-17",
  "Statement": [
    {
      "Sid": "AllowReadS3Backups",
      "Effect": "Allow",
      "Action": ["s3:GetObject", "s3:ListBucket"],
      "Resource": [
        "arn:aws:s3:::company-backups",
        "arn:aws:s3:::company-backups/*"
      ],
      "Condition": {
        "StringEquals": { "s3:prefix": ["2024/", "2025/"] }
      }
    },
    {
      "Sid": "DenyDeleteEverywhere",
      "Effect": "Deny",
      "Action": "s3:DeleteObject",
      "Resource": "*"
    }
  ]
}

The Sid is a comment — use it. AllowReadS3Backups tells a future auditor why this statement exists. Statement1 is technical debt.

The Effect is either Allow or Deny. A Deny always wins — it cannot be overridden by any Allow anywhere in any policy on the same identity. If you have a Deny on s3:DeleteObject with "Resource": "*", nothing can grant delete access to that identity. This asymmetry is deliberate: it’s how guardrails work.

The Resource field is where access most often creeps wider than intended. "Resource": "*" on a write action means “every resource of this type in the account.” It works. It outlives the context that made it feel reasonable.

AWS policy types — which to reach for

┌──────────────────────────┬────────────────────────────┬────────────────────────────┐
│ Type                     │ Attached to                │ What it does               │
├──────────────────────────┼────────────────────────────┼────────────────────────────┤
│ Identity-based           │ User, Group, Role          │ What the identity can do   │
│ Resource-based           │ S3 bucket, KMS key, Lambda │ Who can touch this resource │
│ Permissions boundary     │ User or Role               │ Maximum possible — ceiling  │
│ Service Control Policy   │ AWS Org OU or Account      │ Org-level guardrail         │
│ Session policy           │ AssumeRole session         │ Restricts a specific session│
│ Resource Control Policy  │ AWS Org resources          │ Resource-level org guardrail│
└──────────────────────────┴────────────────────────────┴────────────────────────────┘

Critical: Permissions boundaries and SCPs do not grant permissions. They constrain them. A boundary that allows s3:* doesn’t mean the identity has S3 access — it means the identity can have at most S3 access, if an identity-based policy actually grants it. Many engineers set a boundary and expect it to work as a grant. It doesn’t.

GCP policy bindings

GCP doesn’t attach policy documents to identities. Each resource has an IAM policy — a set of bindings mapping roles to members:

{
  "bindings": [
    {
      "role": "roles/storage.objectViewer",
      "members": [
        "user:[email protected]",
        "serviceAccount:[email protected]"
      ]
    },
    {
      "role": "roles/storage.objectCreator",
      "members": ["serviceAccount:[email protected]"],
      "condition": {
        "title": "Business hours only",
        "expression": "request.time.getHours('America/New_York') >= 9 && request.time.getHours('America/New_York') < 18"
      }
    }
  ]
}

The mental model shift: in AWS you ask “what can this identity do?” by looking at the identity. In GCP you ask “who can access this resource?” by looking at the resource. The question runs in the opposite direction.

Azure role definitions

Azure separates what a role grants (role definition) from who gets it where (role assignment). Define once, assign at multiple scopes.

{
  "Name": "Custom Storage Reader",
  "IsCustom": true,
  "Actions": [
    "Microsoft.Storage/storageAccounts/blobServices/containers/read",
    "Microsoft.Storage/storageAccounts/blobServices/generateUserDelegationKey/action"
  ],
  "DataActions": [
    "Microsoft.Storage/storageAccounts/blobServices/containers/blobs/read"
  ],
  "AssignableScopes": ["/subscriptions/SUB_ID"]
}

Actions vs DataActions catches people. Actions are control plane — you can see the storage account exists. DataActions are data plane — you can read actual blob contents. A user with Actions can list the container but cannot read a single byte without a DataAction. Both planes must be covered for the access to be complete.

What Are IAM Roles? The Layer That Scales Access Control

A role is a collection of policies assigned to identities. It’s the indirection layer that makes access manageable at scale.

Going back to the 2015 account: the problem wasn’t that engineers had access — they needed it. The problem was that access was scattered across 23 individual user objects with no shared structure. This is what what is cloud IAM establishes as the core problem IAM exists to solve — and roles are the structural answer.

The role model solves this:

Policy: S3ReadAccess (s3:GetObject, s3:ListBucket on s3:::app-data/*)
  ↓ attached to
Role: BackendDeveloper
  ↓ assigned to
Users: alice, bob, charlie, dave (and six more)

When the bucket changes  → update one policy
When someone joins       → assign one role
When someone leaves      → remove one role
Access model stays coherent because it's structured.

AWS roles — the identity that issues temporary credentials

AWS roles are themselves IAM identities, not just permission containers. When something assumes a role, it gets temporary credentials from STS. Two things must be configured:

Trust policy — who can assume:

{
  "Version": "2012-10-17",
  "Statement": [{
    "Effect": "Allow",
    "Principal": { "Service": "ec2.amazonaws.com" },
    "Action": "sts:AssumeRole"
  }]
}

Without this, nobody can use the role regardless of its permissions. The trust policy is the gatekeeper.

Permission policy — what it can do:

aws iam create-role \
  --role-name AppServerRole \
  --assume-role-policy-document file://ec2-trust-policy.json

aws iam attach-role-policy \
  --role-name AppServerRole \
  --policy-arn arn:aws:iam::aws:policy/AmazonS3ReadOnlyAccess

When debugging “why can’t this Lambda/EC2/ECS task do X?”, the first thing I check is the trust policy. Many times the permission policy is correct — the service simply isn’t in the trust policy and cannot assume the role at all.

GCP role types

┌──────────────────┬──────────────────────────────┬──────────────────────────────────┐
│ Type             │ Example                      │ When to use                      │
├──────────────────┼──────────────────────────────┼──────────────────────────────────┤
│ Basic/Primitive  │ roles/editor, roles/owner    │ Never in production              │
│ Predefined       │ roles/storage.objectViewer   │ Default — service-specific       │
│ Custom           │ Your org defines             │ When predefined is too broad     │
└──────────────────┴──────────────────────────────┴──────────────────────────────────┘

roles/editor at the project level grants write access to almost every GCP service. I’ve seen it granted “temporarily” and found it attached six months later. Always use predefined roles.

# Find the right predefined role
gcloud iam roles list --filter="name:roles/storage" --format="table(name,title)"

# See exactly what permissions it includes
gcloud iam roles describe roles/storage.objectViewer

# Create a custom role when predefined is still too broad
cat > custom-log-reader.yaml << 'EOF'
title: "Log Reader"
description: "Read application logs — nothing else"
stage: "GA"
includedPermissions:
  - logging.logEntries.list
  - logging.logs.list
  - logging.logMetrics.get
EOF
gcloud iam roles create LogReader --project=my-project --file=custom-log-reader.yaml

Azure built-in and custom roles

# List built-in roles containing "Storage"
az role definition list --output table | grep Storage

# View what a built-in role grants
az role definition list --name "Storage Blob Data Reader"

# Create a custom role
az role definition create --role-definition custom-app-storage.json

# Assign at a specific scope
az role assignment create \
  --assignee [email protected] \
  --role "Storage Blob Data Reader" \
  --scope /subscriptions/SUB_ID/resourceGroups/rg-prod/providers/\
Microsoft.Storage/storageAccounts/prodstore

RBAC vs ABAC: Which Access Control Model to Use

RBAC — Role-Based Access Control

The dominant model. Access flows from role membership:

alice     ∈ BackendDeveloper  →  s3:GetObject on app-data/*
bob       ∈ DataAnalyst       →  athena:* on analytics-queries
ci-runner ∈ DeployRole        →  ecr:PutImage, ecs:UpdateService

RBAC degrades two ways: role explosion (200 roles, nobody can explain what they all do) and coarse roles (avoid explosion by making roles broad, now BackendDeveloper has prod access with no distinction from dev). Both look the same on a spreadsheet — lots of access, no clear principle.

ABAC — Attribute-Based Access Control

ABAC grants access based on attributes of the principal, resource, or environment — not role membership. This one policy replaced 12 team-specific policies in one account:

{
  "Effect": "Allow",
  "Action": "ec2:*",
  "Resource": "*",
  "Condition": {
    "StringEquals": {
      "aws:ResourceTag/Team": "${aws:PrincipalTag/Team}"
    }
  }
}

An engineer tagged Team=Platform can only act on EC2 resources tagged Team=Platform. Add a new team — tag their resources and their identity. No new policy. No new role.

The risk is tag drift. If someone tags a resource incorrectly, the access model breaks silently. I use ABAC for environment and team scoping, and explicit policies for sensitive services like KMS and IAM. How these primitives combine in a full AWS account is covered in the AWS IAM deep dive.

Conditions — when context determines access

// Require MFA for any IAM or Organizations action
{
  "Effect": "Deny",
  "Action": ["iam:*", "organizations:*"],
  "Resource": "*",
  "Condition": { "BoolIfExists": { "aws:MultiFactorAuthPresent": "false" } }
}

// Restrict to corporate IP range
{
  "Effect": "Deny",
  "Action": "*",
  "Resource": "*",
  "Condition": {
    "NotIpAddress": { "aws:SourceIp": ["10.0.0.0/8", "172.16.0.0/12"] }
  }
}

The MFA condition is in every account I manage. A compromised API key without an MFA session can’t escalate IAM privileges — the Deny blocks it at the condition level. This single statement meaningfully reduces the blast radius of a credential compromise.

⚠ Production Gotchas

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 1 — Policies attached directly to users                 ║
║                                                                      ║
║  Feels fast. Creates the exact problem from 2015: access scattered  ║
║  across individual user objects with no shared structure.            ║
║  When the user leaves, their policies don't follow — they stay.     ║
║                                                                      ║
║  Fix: always use roles. Attach policies to roles. Assign roles to   ║
║  users. The role outlives the person.                               ║
╚══════════════════════════════════════════════════════════════════════╝

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 2 — Using AWS managed policies in production            ║
║                                                                      ║
║  AmazonS3FullAccess grants s3:* on *. For a Lambda that reads one  ║
║  specific bucket, that's ~30 permissions you didn't need, all live. ║
║                                                                      ║
║  Fix: create customer managed policies scoped to the specific       ║
║  actions and ARNs the workload actually uses.                       ║
╚══════════════════════════════════════════════════════════════════════╝

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 3 — iam:PassRole with "Resource": "*"                   ║
║                                                                      ║
║  iam:PassRole lets an identity assign a role to an AWS service.     ║
║  With Resource: *, it can pass ANY role — including ones with more  ║
║  permissions than it currently has. That is a privilege escalation. ║
║                                                                      ║
║  Fix: always scope iam:PassRole to a specific role ARN:             ║
║  "Resource": "arn:aws:iam::ACCOUNT:role/SpecificRoleName"          ║
╚══════════════════════════════════════════════════════════════════════╝

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 4 — Permissions boundary ≠ policy grant                 ║
║                                                                      ║
║  Setting a boundary that allows s3:* does NOT grant S3 access.     ║
║  The boundary is a ceiling — it limits maximum possible permissions. ║
║  The identity-based policy still needs to explicitly Allow the      ║
║  action. Both must be present for the access to work.               ║
╚══════════════════════════════════════════════════════════════════════╝

Cross-Cloud Rosetta Stone

Same concepts, different names and different directions. Bookmark this table.

┌─────────────────────────┬──────────────────────────┬──────────────────────────┬──────────────────────────┐
│ Concept                 │ AWS                      │ GCP                      │ Azure                    │
├─────────────────────────┼──────────────────────────┼──────────────────────────┼──────────────────────────┤
│ Atomic permission       │ s3:GetObject             │ storage.objects.get      │ .../blobs/read           │
│ Permission document     │ Policy (JSON)            │ (built into role def)    │ Role Definition          │
│ Access grant            │ Policy attachment        │ IAM Binding              │ Role Assignment          │
│ Job-function identity   │ IAM Role                 │ Predefined Role          │ Built-in Role            │
│ Non-human identity      │ IAM Role (assumed)       │ Service Account          │ Managed Identity         │
│ Org-level guardrail     │ SCP                      │ Org Policy               │ Management Group Policy  │
│ Permission ceiling      │ Permissions Boundary     │ —                        │ —                        │
│ Session restriction     │ Session Policy           │ —                        │ —                        │
│ Attribute-based grant   │ Tag conditions in policy │ IAM Conditions           │ Conditions in assignment │
└─────────────────────────┴──────────────────────────┴──────────────────────────┴──────────────────────────┘

Quick Reference

┌──────────────────────────┬────────────────────────────────────────────────────────────┐
│ Term                     │ What it is                                                 │
├──────────────────────────┼────────────────────────────────────────────────────────────┤
│ Permission               │ Atomic: one action on one resource class                   │
│ Policy                   │ Document grouping permissions + conditions                 │
│ Role (AWS)               │ Assumable identity — carries policies, issues temp creds   │
│ Trust policy (AWS)       │ Who can assume this role — separate from permissions       │
│ Permissions boundary     │ Ceiling — limits max possible permissions; does not grant  │
│ SCP                      │ Org guardrail — constrains all identities in scope         │
│ IAM Binding (GCP)        │ Maps a role to a member on a specific resource             │
│ Role Assignment (Azure)  │ Grants a role definition at a specific scope               │
│ ABAC                     │ Access by tag/attribute — one policy replaces many roles   │
│ RBAC                     │ Access by role membership — clean until roles proliferate  │
│ iam:PassRole             │ Privilege escalation vector — always scope to specific ARN │
└──────────────────────────┴────────────────────────────────────────────────────────────┘

Commands to know:
┌────────────────────────────────────────────────────────────────────────────────┐
│  # AWS — list policies attached to a role                                     │
│  aws iam list-attached-role-policies --role-name MyRole                       │
│                                                                                │
│  # AWS — view what a managed policy actually grants                           │
│  aws iam get-policy-version \                                                  │
│    --policy-arn arn:aws:iam::aws:policy/AmazonS3ReadOnlyAccess \              │
│    --version-id v1                                                             │
│                                                                                │
│  # AWS — who can assume this role?                                            │
│  aws iam get-role --role-name MyRole --query 'Role.AssumeRolePolicyDocument'  │
│                                                                                │
│  # GCP — view the IAM policy on a project                                    │
│  gcloud projects get-iam-policy PROJECT_ID --format=json                      │
│                                                                                │
│  # GCP — list all roles and what permissions they include                    │
│  gcloud iam roles describe roles/storage.objectViewer                         │
│                                                                                │
│  # Azure — list role assignments in a subscription                           │
│  az role assignment list --all --output table                                 │
│                                                                                │
│  # Azure — view exactly what a built-in role grants                          │
│  az role definition list --name "Storage Blob Data Reader"                   │
└────────────────────────────────────────────────────────────────────────────────┘

Framework Alignment

Framework	Reference	What It Covers Here
CISSP	Domain 5 — Identity and Access Management	RBAC and ABAC are the implementation models for authorization at scale
CISSP	Domain 1 — Security & Risk Management	Role design implements separation of duties and least privilege
ISO 27001:2022	5.15 Access control	Access control policy — roles and policies are the mechanism
ISO 27001:2022	5.18 Access rights	Provisioning, review, and removal of access rights — roles make this auditable
ISO 27001:2022	8.2 Privileged access rights	Permissions boundaries and conditions applied to elevated access
SOC 2	CC6.1	Logical access security — policy documents are the technical implementation
SOC 2	CC6.3	Access revocation — role-based model makes removal consistent and auditable

Key Takeaways

Permissions are atomic — one action on one resource class. Policies group permissions. Roles carry policies for assignment
AWS roles have two required configs: trust policy (who can assume) and permission policy (what it can do) — both must be correct
GCP binds roles to resources; AWS attaches policies to identities — the mental model runs in opposite directions
Azure separates role definition (what) from role assignment (who, where) — define once, assign at multiple scopes
RBAC scales through role design; ABAC scales through tag/attribute conditions — use ABAC where roles would proliferate
iam:PassRole and iam.serviceAccounts.actAs are privilege escalation vectors — scope them to specific ARNs, never *
Conditions add context (MFA, IP, tags, time) to policies — the MFA condition on IAM actions is essential in every account

What’s Next

EP04 goes deep on AWS IAM — the most complex of the three cloud models. Policy evaluation order, cross-account trust, permissions boundaries in practice, SCPs, and IAM Identity Center for human access. We’ll work through the patterns that make AWS IAM maintainable at production scale.

Next: AWS IAM Deep Dive: Users, Groups, Roles, and Policies Explained

Get the AWS IAM deep dive in your inbox when it publishes → linuxcent.com/subscribe

Authentication vs Authorization: AWS AccessDenied Explained

April 15, 2026April 14, 2026 by Vamshi Krishna Santhapuri

What Is Cloud IAM → Authentication vs Authorization → IAM Roles vs Policies

TL;DR

Authentication asks are you who you claim to be? Authorization asks are you allowed to do this? — two separate gates, two separate failure modes
AWS AccessDenied is an authorization failure — the identity authenticated fine; fix the policy, not the credentials
Prefer short-lived credentials (STS temporary tokens, Managed Identities) over long-lived access keys — the difference is the blast radius window
MFA strengthens authentication; it does nothing for authorization — a hijacked session with broad permissions is just as dangerous with or without MFA on the original login
HTTP 401 = authentication failure; HTTP 403 = authorization failure — the code tells you which gate to debug
Both layers must enforce least privilege independently — application-layer authorization is not a substitute for tight cloud IAM

The Big Picture

Every API call in the cloud passes through two gates before it executes. Most engineers know the first one. The second is where most security failures live.

  THE TWO GATES — every cloud API call passes through both, in order

  ┌──────────────────────────────────────────────────────────────────┐
  │  GATE 1 — AUTHENTICATION                                         │
  │  "Are you who you claim to be?"                                  │
  │                                                                  │
  │  IAM user     →  Access Key + Secret (long-lived, rotatable)    │
  │  IAM role     →  Temporary STS token (expires automatically)    │
  │  Human        →  Password + MFA via console or IdP              │
  │  Service      →  Instance profile / Managed Identity / OIDC     │
  │                                                                  │
  │  Passes → move to Gate 2                                        │
  │  Fails  → stopped here, HTTP 401                                │
  └──────────────────────────────────────────────────────────────────┘
                                 │
                                 ▼
  ┌──────────────────────────────────────────────────────────────────┐
  │  GATE 2 — AUTHORIZATION                                          │
  │  "Are you allowed to do what you're trying to do?"               │
  │                                                                  │
  │  Evaluated against: identity-based policies · SCPs              │
  │                     resource-based policies · conditions         │
  │                     permissions boundaries · session policies    │
  │                                                                  │
  │  Default answer: DENY (explicit Allow required every time)      │
  │                                                                  │
  │  Passes → request executes                                      │
  │  Fails  → AccessDenied / HTTP 403                               │
  └──────────────────────────────────────────────────────────────────┘

  MFA hardens Gate 1. It has zero effect on Gate 2.
  A hijacked session with a valid token clears Gate 1 automatically.
  Gate 2 is your last line of defense — and the one that's most often misconfigured.

Introduction

The authentication vs authorization distinction is the most commonly confused boundary in cloud security — and the source of most misdirected debugging when an AWS AccessDenied error appears. These are two separate gates, two separate failure modes, and two entirely different fixes.

Early in my career I wrote an API endpoint I was proud of. Token validation. Rejection of unauthenticated requests. I called it “secured” in the code review.

A senior engineer asked one question: “What happens if I take a valid token from a regular user and call your /admin/delete-user endpoint?”

I ran the test. It worked. Any employee — with a perfectly valid, properly issued token — could delete any user account in the system.

The authentication was correct. The authorization didn’t exist.

That gap between proving who you are and proving you’re allowed to do this is where a surprising number of security incidents live. Not just in application code. In cloud IAM too. I’ve reviewed AWS environments where MFA was enforced on every human account, access keys were rotated quarterly, and yet a Lambda function had s3:* on * because whoever wrote the deployment script reached for AmazonS3FullAccess and moved on.

Gate 1 was solid. Gate 2 was wide open.

This episode draws the boundary cleanly — what each gate is, how each cloud implements it, and the specific failure modes that happen when the two get conflated.

How Authentication Works in Cloud IAM

Authentication answers: are you who you claim to be?

The three factor types

Authentication has not fundamentally changed in decades. What has changed is how cloud platforms implement it.

Factor	Type	Cloud Examples
Something you know	Knowledge	Password, access key secret, PIN
Something you have	Possession	TOTP app, FIDO2 hardware key, smart card
Something you are	Inherence	Biometrics — less common in cloud contexts

MFA requires two distinct factors. A password plus a username is not MFA — both are knowledge factors. A password plus a TOTP code is MFA. Worth stating clearly because I’ve seen internal documentation describe “username and password” as two-factor authentication.

SMS codes count as MFA, but they’re the weakest form. SIM-swapping attacks — convincing a carrier to port your number — have been used to defeat SMS MFA on high-value accounts. If TOTP or FIDO2 hardware keys are available, use them.

How AWS authenticates

AWS has two fundamentally different identity classes:

Human identities authenticate via console (password + optional MFA) or CLI/API (Access Key ID + Secret Access Key). The access key is a long-lived credential with no default expiry. Every .env file with an access key, every git commit that included one, every CI/CD log that printed one — that credential is live until someone explicitly rotates or deletes it.

Machine identities — EC2, Lambda, ECS tasks — authenticate via temporary credentials issued by STS:

# Assume a role — get temporary credentials that expire
aws sts assume-role \
  --role-arn arn:aws:iam::123456789012:role/DevRole \
  --role-session-name alice-session \
  --duration-seconds 3600
# Returns: AccessKeyId + SecretAccessKey + SessionToken
# All three expire together. Nothing to rotate.

# From inside an EC2 instance — credentials arrive automatically via IMDS
curl http://169.254.169.254/latest/meta-data/iam/security-credentials/MyAppRole
# Returns: AccessKeyId, SecretAccessKey, Token, Expiration
# AWS refreshes these before expiry. The application never sees a rotation event.

The IMDS model is the right one. The application never manages a credential — it appears, it’s used, it expires. If it leaks, it’s usable for hours at most, not years.

How GCP authenticates

GCP cleanly separates human and machine authentication.

Humans authenticate via Google Account or Workspace (OAuth2). The gcloud CLI handles the flow:

gcloud auth login                        # browser-based OAuth2 for humans
gcloud auth application-default login    # sets up Application Default Credentials for local dev

Machine identities use service accounts, ideally attached to the resource rather than using downloaded key files. Key files are GCP’s equivalent of long-lived AWS access keys — same problems, same risks.

# From inside a GCE VM — ADC uses the attached service account, no key file needed
gcloud auth print-access-token
# Use it: curl -H "Authorization: Bearer $(gcloud auth print-access-token)" ...

How Azure authenticates

Azure’s identity plane is Entra ID (formerly Azure Active Directory). Humans authenticate via Entra ID using OAuth2/OIDC. Machine identities use Managed Identities — Azure handles the entire credential lifecycle, nothing to configure or rotate.

az login                                  # browser-based OAuth2
az login --service-principal \            # service principal for automation
  -u APP_ID -p CERT_OR_SECRET \
  --tenant TENANT_ID

# From inside an Azure VM — get a token via IMDS, no credentials needed
curl 'http://169.254.169.254/metadata/identity/oauth2/token\
?api-version=2018-02-01&resource=https://management.azure.com/' \
  -H 'Metadata: true'

The credential failure modes that repeat everywhere

Across all three clouds, the same patterns appear in every audit:

Leaked credentials — access keys in git commits, .env files, Docker image layers, CI/CD logs. GitHub’s secret scanning finds thousands of these monthly on public repos alone.

Long-lived credentials — an access key from 2019 is still valid in 2026 unless someone explicitly rotated it. I’ve audited accounts where 30% of access keys had never been rotated, some five years old.

Shared credentials — one key used by three services. When you revoke it, three things break. When it leaks, you can’t tell which service was the source.

Credential sprawl — service account keys downloaded for “one quick test” and never deleted. I once found seventeen key files for a single GCP service account, created by different engineers over two years. None rotated. Five belonged to accounts that no longer existed.

The direction of travel in all three clouds is credential-less: workload identity federation, managed identities, instance profiles. We’ll cover this specifically in OIDC Workload Identity: Eliminate Cloud Access Keys Entirely.

How Authorization Evaluates Every API Call

Authorization happens after authentication. The system knows who you are — now it decides what you can do. This decision is enforced through IAM roles vs policies — the building blocks that express what each identity is allowed to do on which resources.

What the evaluation looks like

Every API call triggers an authorization check. You don’t notice when it succeeds. You notice when it fails:

REQUEST:
  Action:    s3:DeleteObject
  Resource:  arn:aws:s3:::prod-backups/2024-01-15.tar.gz
  Principal: arn:aws:iam::123456789012:role/DevEngineerRole
  Context:   { source_ip: "10.0.1.5", mfa: false, time: "14:32 UTC" }

EVALUATION:
  1. Explicit Deny anywhere? → none found
  2. Explicit Allow in any policy? → not granted
  3. Default → DENY

RESULT: AccessDenied

The engineer authenticated successfully. Valid credentials, valid session. But DevEngineerRole has no policy granting s3:DeleteObject on that bucket. Gate 1 passed. Gate 2 denied. They are evaluated independently.

Policy evaluation chains by cloud

AWS — evaluated in layers, explicit Deny wins at any layer:

1. Explicit Deny in any SCP?           → DENY (cannot be overridden anywhere)
2. No SCP Allow?                       → DENY
3. Explicit Deny in identity or resource policy? → DENY
4. Resource-based policy Allow?        → can ALLOW (same account)
5. Permissions boundary — no Allow?    → DENY
6. Session policy — no Allow?          → DENY
7. Identity-based policy Allow?        → ALLOW
Default (nothing granted):             → DENY

The default is always Deny. Every successful authorization is an explicit "Effect": "Allow" somewhere in the chain. This is the opposite of traditional Unix — in the cloud, if you didn’t explicitly grant it, it doesn’t exist.

GCP — additive, permissions accumulate up the hierarchy:

Permission granted if ANY binding grants it at:
  resource level → project level → folder level → organization level

IAM Deny Policies can override all grants (newer feature).
No binding at any level? → Denied.

Azure RBAC:

1. Explicit Deny Assignment?           → DENY (even Owner can't override)
2. Role Assignment with Allow?         → ALLOW
Default:                               → DENY

Why Confusing Authentication and Authorization Breaks Security

The token-as-authorization antipattern

An application checks for a valid JWT and if found, proceeds. The JWT proves the user authenticated with the IdP. It says nothing about what they’re allowed to do.

# This is authentication only — anyone with a valid token gets through
@app.route("/admin/delete-user", methods=["POST"])
def delete_user():
    token = request.headers.get("Authorization")
    if verify_token(token):           # asks: is this token real and unexpired?
        delete_user_from_db(...)      # executes for any valid token holder
        return "OK"
    return "Unauthorized", 401

# This separates the two correctly
@app.route("/admin/delete-user", methods=["POST"])
def delete_user():
    token = request.headers.get("Authorization")
    principal = verify_token(token)                    # Gate 1: authentication
    if not has_permission(principal, "users:delete"):  # Gate 2: authorization
        return "Forbidden", 403
    delete_user_from_db(...)
    return "OK"

The short-expiry principle

Credential type	Provider	Typical lifetime	Risk
Access Key + Secret	AWS	Permanent (until deleted)	Years of exposure if leaked
STS Temporary Token	AWS	15 min – 12 hours	Hours at most
OAuth2 Access Token	GCP / Azure	~1 hour	Short window
IMDS Token (VM)	All three	Minutes	Auto-refreshed by platform

A credential that expires in an hour has a one-hour exposure window if stolen. A credential that never expires has an unlimited window. This is the operational argument for managed identities and instance profiles, beyond just convenience.

# AWS — configure max session duration at role level
aws iam update-role \
  --role-name MyRole \
  --max-session-duration 3600   # 1 hour max

# GCP — access tokens expire in ~1 hour automatically
gcloud auth print-access-token
# Refresh: gcloud auth application-default print-access-token

# Azure — token lifetime configurable in Entra ID token policies
az account get-access-token --resource https://management.azure.com/

⚠ Production Gotchas

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 1 — "We have MFA, so permissions can be broad"          ║
║                                                                      ║
║  MFA protects Gate 1 only. If a session is hijacked after login    ║
║  (via malware, SSRF, or a stolen session cookie), the attacker has  ║
║  a valid, MFA-authenticated token. Gate 1 is already cleared.       ║
║  Broad permissions in Gate 2 are the full attack surface.           ║
║                                                                      ║
║  Fix: treat Gate 2 (IAM policy) as your primary blast-radius        ║
║  control. MFA buys time. Least privilege limits damage.             ║
╚══════════════════════════════════════════════════════════════════════╝

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 2 — Debugging AccessDenied by rotating credentials      ║
║                                                                      ║
║  AWS AccessDenied is an authorization failure. The identity         ║
║  authenticated successfully — there's no Allow in the policy.       ║
║  Rotating the access key does nothing.                              ║
║                                                                      ║
║  Fix: check the policy chain. Use simulate-principal-policy to      ║
║  confirm where the Allow is missing before touching credentials.    ║
╚══════════════════════════════════════════════════════════════════════╝

╔══════════════════════════════════════════════════════════════════════╗
║  ⚠  GOTCHA 3 — Application-layer authZ with broad cloud IAM        ║
║                                                                      ║
║  "The app controls access" is not a substitute for scoped cloud     ║
║  IAM. An SSRF vulnerability, exposed debug endpoint, or            ║
║  compromised dependency bypasses the application layer entirely.    ║
║  The cloud identity's permissions become the attacker's surface.    ║
║                                                                      ║
║  Fix: both layers enforce least privilege independently.            ║
╚══════════════════════════════════════════════════════════════════════╝

Authentication vs Authorization Audit Checklist

Split your IAM review along the authN/authZ boundary — they’re different problems with different fixes.

Authentication — Gate 1:
– Are there long-lived access keys that could be replaced with STS/Managed Identity?
– Is MFA enforced for all human identities with console or API access?
– Are service account key files present where workload identity is available?
– Are credentials stored in a secrets manager — not in code, .env files, or repos?
– When did each long-lived credential last rotate?

Authorization — Gate 2:
– Does every policy follow least privilege — only the permissions the workload actually uses?
– Are there wildcards (s3:*, "Resource": "*") that could be narrowed?
– Are write, delete, and IAM-modification actions scoped to specific resources?
– Are SCPs or permissions boundaries capping maximum permissions at org or account level?
– When were each role’s permissions last reviewed against actual usage (Access Analyzer)?

Quick Reference

┌────────────────────────────┬──────────────────────────────────────────────────┐
│ Term                       │ What it means                                    │
├────────────────────────────┼──────────────────────────────────────────────────┤
│ Authentication (AuthN)     │ Verifying identity — are you who you claim?      │
│ Authorization (AuthZ)      │ Verifying permission — are you allowed to act?   │
│ MFA                        │ Two distinct factors; strengthens Gate 1 only    │
│ STS (AWS)                  │ Security Token Service — issues temp credentials │
│ Access Key                 │ Long-lived AWS credential; avoid for services    │
│ Instance profile (AWS)     │ Container attaching a role to EC2                │
│ Managed Identity (Azure)   │ Credential-less identity for Azure services      │
│ Service Account (GCP)      │ Machine identity; prefer attached over key file  │
│ HTTP 401                   │ Authentication failure — prove who you are       │
│ HTTP 403 / AccessDenied    │ Authorization failure — fix the policy           │
└────────────────────────────┴──────────────────────────────────────────────────┘

Commands to know:
┌──────────────────────────────────────────────────────────────────────────────┐
│  # AWS — assume a role and get temporary credentials                        │
│  aws sts assume-role --role-arn arn:aws:iam::ACCOUNT:role/ROLE \            │
│    --role-session-name my-session --duration-seconds 3600                   │
│                                                                              │
│  # AWS — simulate a policy to debug AccessDenied before touching anything   │
│  aws iam simulate-principal-policy \                                         │
│    --policy-source-arn arn:aws:iam::ACCOUNT:role/MyRole \                   │
│    --action-names s3:GetObject \                                             │
│    --resource-arns arn:aws:s3:::my-bucket/*                                 │
│                                                                              │
│  # AWS — check what credentials your session is using                       │
│  aws sts get-caller-identity                                                 │
│                                                                              │
│  # GCP — print the current access token (expires in ~1 hour)                │
│  gcloud auth print-access-token                                              │
│                                                                              │
│  # GCP — show which account ADC is using                                    │
│  gcloud auth application-default print-access-token                         │
│                                                                              │
│  # Azure — get current token for ARM                                         │
│  az account get-access-token --resource https://management.azure.com/       │
│                                                                              │
│  # Azure — check who you're logged in as                                     │
│  az account show                                                             │
└──────────────────────────────────────────────────────────────────────────────┘

Framework Alignment

Framework	Reference	What It Covers Here
CISSP	Domain 5 — Identity and Access Management	AuthN and AuthZ are the two core mechanisms; this episode defines the boundary
CISSP	Domain 1 — Security & Risk Management	Conflating the two creates systematic, measurable risk with different attack surfaces
ISO 27001:2022	5.17 Authentication information	Managing credentials and authentication mechanisms across the identity lifecycle
ISO 27001:2022	8.5 Secure authentication	Technical controls — MFA, session management, credential policies
ISO 27001:2022	5.15 Access control	Policy requirements that depend on cleanly separating identity from permission
SOC 2	CC6.1	Logical access controls — this episode defines the two-gate model CC6.1 is built on
SOC 2	CC6.7	Access restrictions enforced at the authorization layer, not just authentication

Key Takeaways

Authentication proves identity; authorization proves permission — two gates, two separate failure modes, two separate fixes
AWS AccessDenied is a Gate 2 failure — the credential is valid, the policy is missing; fix the policy
Short-lived credentials (STS, Managed Identities, instance profiles) reduce the blast radius of a credential compromise from years to hours
MFA hardens Gate 1 — it has no effect on what an authenticated identity can do
HTTP 401 = Gate 1 failed; HTTP 403 = Gate 2 failed — the status code tells you where to look
Application-layer authorization and cloud IAM authorization are independent — both must enforce least privilege

What’s Next

You now know what the two gates are and where failures in each originate. IAM Roles vs Policies: How Cloud Authorization Actually Works goes into the mechanics of Gate 2 — the permissions, policies, and roles that implement authorization in practice, and the structural patterns that keep them from turning into an unmanageable sprawl.

Next: IAM Roles vs Policies: How Cloud Authorization Actually Works

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eBPF Program Types — What’s Actually Running on Your Nodes

April 12, 2026April 12, 2026 by Vamshi Krishna Santhapuri

eBPF: From Kernel to Cloud, Episode 4
Earlier in this series: What Is eBPF? · The BPF Verifier · eBPF vs Kernel Modules

By Episode 3, we’d covered what eBPF is, why the verifier makes it safe for production, and why it’s replaced kernel modules for observability workloads. What we hadn’t answered — and what a 2am incident eventually forced — is what kind of eBPF programs are actually running on your nodes, and why the difference matters when something breaks.

A pod in production was dropping roughly one in fifty outbound TCP connections. Not all of them — just enough to cause intermittent timeouts in the application logs. NetworkPolicy showed egress allowed. Cilium reported no violations. Running curl manually from inside the pod worked every time.

I spent the better part of three hours eliminating possibilities. DNS. MTU. Node-level conntrack table exhaustion. Upstream firewall rules. Nothing.

Eventually, almost as an afterthought, I ran this:

sudo bpftool prog list

There were two TC programs attached to that pod’s veth interface. One from the current Cilium version. One from the previous version — left behind by a rolling upgrade that hadn’t cleaned up properly. Two programs. Different policy state. One was occasionally dropping packets based on rules that no longer existed in the current policy model.

The answer had been sitting in the kernel the whole time. I just didn’t know where to look.

That incident forced me to actually understand something I’d been hand-waving for two years: eBPF isn’t a single hook. It’s a family of program types, each attached to a different location in the kernel, each seeing different data, each suited for different problems. Understanding the difference is what separates “I run Cilium and Falco” from “I understand what Cilium and Falco are actually doing on my nodes” — and that difference matters when something breaks at 2am.

The Command You Should Run on Your Cluster Right Now

Before getting into the theory, do this:

# See every eBPF program loaded on the node
sudo bpftool prog list

# See every eBPF program attached to a network interface
sudo bpftool net list

On a node running Cilium and Falco, you’ll see something like this:

42: xdp           name cil_xdp_entry       loaded_at 2026-04-01T09:23:41
43: sched_cls     name cil_from_netdev      loaded_at 2026-04-01T09:23:41
44: sched_cls     name cil_to_netdev        loaded_at 2026-04-01T09:23:41
51: cgroup_sock_addr  name cil_sock4_connect loaded_at 2026-04-01T09:23:41
88: raw_tracepoint  name sys_enter          loaded_at 2026-04-01T09:23:55
89: raw_tracepoint  name sys_exit           loaded_at 2026-04-01T09:23:55

Each line is a different program type. Each one fires at a different point in the kernel. The type column — xdp, sched_cls, raw_tracepoint, cgroup_sock_addr — tells you where in the kernel execution path that program is attached and therefore what it can and cannot see.

If you see more programs than you expect on a specific interface — like I did — that’s your first clue.

Why Program Types Exist

The Linux kernel isn’t a single pipeline. Network packets, system calls, file operations, process scheduling — these all run through different subsystems with different execution contexts and different available data.

eBPF lets you attach programs to specific points within those subsystems. The “program type” is the contract: it defines where the hook fires, what data the program receives, and what it’s allowed to do with it. A program designed to process network packets before they hit the kernel stack looks completely different from one designed to intercept system calls across all containers simultaneously.

Most of us will interact with four or five program types through the tools we already run. Understanding what each one actually is — where it sits, what it sees — is what makes you effective when those tools behave unexpectedly.

The Types Behind the Tools You Already Use

TC — Why Cilium Can Tell Which Pod Sent a Packet

TC stands for Traffic Control. It’s where Cilium enforces your NetworkPolicy, and it’s what caused my incident.

TC programs attach to network interfaces — specifically to the ingress and egress directions of the pod’s virtual interface (lxcXXXXX in Cilium’s naming). They fire after the kernel has already processed the packet enough to know its context: which socket created it, which cgroup that socket belongs to. Cgroup maps to container, container maps to pod.

This is the critical piece: TC is how Cilium knows which pod a packet belongs to. Without that cgroup context, per-pod policy enforcement isn’t possible.

# See TC programs on a pod's veth interface
sudo tc filter show dev lxc12345 ingress
sudo tc filter show dev lxc12345 egress

# If you see two entries on the same direction — that's the incident I described
# The priority number (pref 1, pref 2) tells you the order they run

When there are two TC programs on the same interface, the first one to return “drop” wins. The second program never runs. This is why the issue was intermittent rather than consistent — the stale program only matched specific connection patterns.

Fixing it is straightforward once you know what to look for:

# Remove a stale TC filter by its priority number
sudo tc filter del dev lxc12345 egress pref 2

Add this check to your post-upgrade runbook. Cilium upgrades are generally clean but not always.

XDP — Why Cilium Doesn’t Use TC for Everything

If TC is good enough for pod-level policy, why does Cilium also run an XDP program on the node’s main interface? Look at the bpftool prog list output again — there’s an xdp program loaded alongside the TC programs.

XDP fires earlier. Much earlier. Before the kernel allocates any memory for the packet. Before routing. Before connection tracking. Before anything.

The tradeoff is exactly what you’d expect: XDP is fast but context-poor. It sees raw packet bytes. It doesn’t know which pod the packet came from. It can’t read cgroup information because no socket buffer has been allocated yet.

Cilium uses XDP specifically for ClusterIP service load balancing — when a packet arrives at the node destined for a service VIP, XDP rewrites the destination to the actual pod IP in a single map lookup and sends it on its way. No iptables. No conntrack. The work is done before the kernel stack is involved.

There’s a silent failure mode worth knowing about here. XDP runs in one of two modes:

Native mode — runs inside the NIC driver itself, before any kernel allocation. This is where the performance comes from.
Generic mode — fallback when the NIC driver doesn’t support XDP. Runs later, after sk_buff allocation. No performance benefit over iptables.

If your NIC doesn’t support native XDP, Cilium silently falls back to generic mode. The policy still works — but the performance characteristics you assumed aren’t there.

# Check which XDP mode is active on your node's main interface
ip link show eth0 | grep xdp
# xdpdrv  ← native mode (fast)
# xdpgeneric ← generic mode (no perf benefit)

Most cloud provider instance types with modern Mellanox/Intel NICs support native mode. Worth verifying rather than assuming.

Tracepoints — How Falco Sees Every Container

Falco loads two programs: sys_enter and sys_exit. These are raw tracepoints — they fire on every single system call, from every process, in every container on the node.

Tracepoints are explicitly defined and maintained instrumentation points in the kernel. Unlike hooks that attach to specific internal function names (which can be renamed or inlined between kernel versions), tracepoints are stable interfaces. They’re part of the kernel’s public contract with tooling that wants to instrument it.

This matters operationally. When you patch your nodes — and cloud-managed nodes get patched frequently — tools built on tracepoints keep working. Tools built on kprobes (internal function hooks) may silently stop firing if the function they’re attached to gets renamed or inlined by the compiler in a new kernel build.

# Verify what Falco is actually using
sudo bpftool prog list | grep -E "kprobe|tracepoint"

# Falco's current eBPF driver should show raw_tracepoint entries
# If you see kprobe entries from Falco, you're on the older driver
# Check: falco --version and the driver being loaded at startup

If you’re running Falco on a cluster that gets regular OS patch upgrades and you haven’t verified the driver mode, check it. The older kprobe-based driver has a real failure mode on certain kernel versions.

LSM — How Tetragon Blocks Operations at the Kernel Level

LSM hooks run at the kernel’s security decision points: file opens, socket connections, process execution, capability checks. The defining characteristic is that they can deny an operation. Return an error from an LSM hook and the kernel refuses the syscall before it completes.

This is qualitatively different from observability hooks. kprobes and tracepoints watch. LSM hooks enforce.

When you see Tetragon configured to kill a process attempting a privileged operation, or block a container from writing to a specific path, that’s an LSM hook making the decision inside the kernel — not a sidecar watching traffic, not an admission webhook running before pod creation, not a userspace agent trying to act fast enough. The enforcement is in the kernel itself.

# See if any LSM eBPF programs are active on the node
sudo bpftool prog list | grep lsm

# Verify LSM eBPF support on your kernel (required for Tetragon enforcement mode)
grep CONFIG_BPF_LSM /boot/config-$(uname -r)
# CONFIG_BPF_LSM=y   ← required

The Practical Summary

What’s happening on your node	Program type	Where to look
Cilium service load balancing	XDP	`ip link show eth0 \\| grep xdp`
Cilium pod network policy	TC (`sched_cls`)	`tc filter show dev lxcXXXX egress`
Falco syscall monitoring	Tracepoint	`bpftool prog list \\| grep tracepoint`
Tetragon enforcement	LSM	`bpftool prog list \\| grep lsm`
Anything unexpected	All types	`bpftool prog list`, `bpftool net list`

The Incident, Revisited

Three hours of debugging. The answer was a stale TC program sitting at priority 2 on a pod’s veth interface, left behind by an incomplete Cilium upgrade.

# What I should have run first
sudo bpftool net list
sudo tc filter show dev lxc12345 egress

Two commands. Thirty seconds. If I’d known that TC programs can stack on the same interface, I’d have started there.

That’s the point of understanding program types — not to write eBPF programs yourself, but to know where to look when the tools you depend on don’t behave the way you expect. The programs are already there, running on your nodes right now. bpftool prog list shows you all of them.

Key Takeaways

bpftool prog list and bpftool net list show every eBPF program on a node — run these before anything else when debugging eBPF-based tool behavior
TC programs can stack on the same interface; stale programs from incomplete Cilium upgrades cause intermittent drops — check tc filter show after every Cilium upgrade
XDP runs before the kernel stack — fastest hook, but no pod identity; Cilium uses it for service load balancing, not pod policy
XDP silently falls back to generic mode on unsupported NICs — verify with ip link show | grep xdp
Tracepoints are stable across kernel versions; kprobe-based tools may silently break after node OS patches — verify your Falco driver mode
LSM hooks enforce at the kernel level — this is what makes Tetragon’s enforcement mode fundamentally different from sidecar-based approaches

What’s Next

Every eBPF program fires, does its work, and exits — but the work always involves data. Counting connections. Tracking processes. Streaming events to a detection engine. In EP05, I’ll cover eBPF maps: the persistent data layer that connects kernel programs to the tools consuming their output. Understanding maps explains a class of production issues — and makes bpftool map dump useful rather than cryptic.

What Is Cloud IAM — and Why Every API Call Depends on It

April 15, 2026April 11, 2026 by Vamshi Krishna Santhapuri

What Is Cloud IAM → Authentication vs Authorization → IAM Roles vs Policies

TL;DR

Cloud IAM is the system that decides whether any API call is allowed or denied — deny by default, explicit Allow required at every layer
Every API call answers four questions: Who? (Identity) What? (Action) On what? (Resource) Under what conditions? (Context)
Two identity types in every cloud account: human (engineers) and machine (Lambda, EC2, Kubernetes pods) — machine identities outnumber human by 10:1 in most production environments
AWS, GCP, and Azure share the same model: deny-by-default, policy-driven, principal-based — different syntax, same mental model
The gap between granted and used permissions is where attackers move — the average IAM entity uses under 5% of its granted permissions
IAM failure has two modes: over-permissioned (“it works”) and over-restricted (“it’s secure, engineers work around it”) — both end in incidents

The Big Picture

                        WHAT IS CLOUD IAM?

  Every API call in AWS, GCP, or Azure answers four questions:

  ┌─────────────┐   ┌─────────────┐   ┌─────────────┐   ┌─────────────┐
  │    WHO?     │   │   WHAT?     │   │  ON WHAT?   │   │  UNDER      │
  │             │   │             │   │             │   │  WHAT?      │
  │  Identity / │   │  Action /   │   │  Resource   │   │             │
  │  Principal  │   │  Permission │   │             │   │  Condition  │
  │             │   │             │   │             │   │             │
  │ IAM Role    │   │ s3:GetObject│   │ arn:aws:s3: │   │ MFA: true   │
  │ Svc Account │   │ ec2:Start   │   │ ::prod-data │   │ IP: 10.0/8  │
  │ Managed     │   │ iam:        │   │ /exports/*  │   │ Time: 09-17 │
  │ Identity    │   │   PassRole  │   │             │   │             │
  └─────────────┘   └─────────────┘   └─────────────┘   └─────────────┘
        └────────────────┴────────────────┴────────────────┘
                                  │
                     ┌────────────▼────────────┐
                     │    IAM Policy Engine    │
                     │    deny by default      │
                     │                         │
                     │  Explicit ALLOW?   ─────┼──→  PERMIT
                     │  Explicit DENY?    ─────┼──→  DENY (overrides Allow)
                     │  No matching rule? ─────┼──→  DENY (implicit)
                     └─────────────────────────┘

Cloud IAM is the answer to a question every growing infrastructure team hits: at scale, how do you know who can do what, why they can do it, and whether they still should?

Introduction

Cloud IAM (Identity and Access Management) is the control plane for access in every major cloud provider. Every API call — reading a file, starting an instance, invoking a function — goes through an IAM evaluation. The result is binary: explicit Allow or deny. There is no implicit access. Nothing is open by default. This is what makes cloud IAM fundamentally different from the access models that came before it.

Understanding why it works that way requires tracing how access control evolved — and what kept breaking at each stage.

A few years into my career managing Linux infrastructure, I was handed a production server audit. The task was straightforward: find out who had access to what. I pulled /etc/passwd, checked the sudoers file, reviewed SSH authorized_keys across the fleet.

Three days later, I had a spreadsheet nobody wanted to read.

The problem wasn’t that the access was wrong. Most of it was fine. The problem was that nobody — not the team lead, not the security team, not the engineers who’d been there five years — could tell me why a particular account had access to a particular server. It had accumulated. People joined, got access, changed teams, left. The access stayed.

That was a 40-server fleet in 2012.

Fast-forward to a cloud environment today: you might have 50 engineers, 300 Lambda functions, 20 microservices, CI/CD pipelines, third-party integrations, compliance scanners — all making API calls, all needing access to something. The identity sprawl problem I spent three days auditing manually on 40 servers now exists at a scale where manual auditing isn’t even a conversation.

This is the problem Identity and Access Management exists to solve. Not just in theory — in practice, at the scale cloud infrastructure demands.

How We Got Here — The Evolution of Access Control

To understand why cloud IAM works the way it does, you need to trace how access control evolved. The design decisions in AWS IAM, GCP, and Azure didn’t come out of nowhere — they’re answers to lessons learned the hard way across decades of broken systems.

The Unix Model (1970s–1990s): Simple and Sufficient

Unix got the fundamentals right early. Every resource (file, device, process) has an owner and a group. Every action is one of three: read, write, execute. Every user is either the owner, in the group, or everyone else.

-rw-r--r--  1 vamshi  engineers  4096 Apr 11 09:00 deploy.conf
# owner can read/write | group can read | others can read

For a single machine or a small network, this model is elegant. The permissions are visible in a ls -l. Reasoning about access is straightforward. Auditing means reading a few files.

The cracks started showing when organizations grew. You’d add sudo to give specific commands to specific users. Then sudoers files became 300 lines long. Then you’d have shared accounts because managing individual ones was “too much overhead.” Shared accounts mean no individual accountability. No accountability means no audit trail worth anything.

The Directory Era (1990s–2000s): Centralise or Collapse

As networks grew, every server managing its own /etc/passwd became untenable. Enter LDAP and Active Directory. Instead of distributing identity management across every machine, you centralised it: one directory, one place to add users, one place to disable them when someone left.

This was a significant step forward. Onboarding got faster. Offboarding became reliable. Group membership drove access to resources across the network.

But the permission model was still coarse. You were either in the Domain Admins group or you weren’t. “Read access to the file share” was a group. “Deploy to the staging web server” was a group. Managing fine-grained permissions at scale meant managing hundreds of groups, and the groups themselves became the audit nightmare.

I spent time in environments like this. The group named SG_Prod_App_ReadWrite_v2_FINAL that nobody could explain. The AD group from a project that ended three years ago but was still in twenty user accounts. The contractor whose AD account was disabled but whose service account was still running a nightly job.

The directory model centralised identity. It didn’t solve the permissions sprawl problem.

The Cloud Shift (2006–2014): Everything Changes

AWS launched EC2 in 2006. In 2011, AWS IAM went into general availability. That date matters — for the first five years of AWS, access control was primitive. Root accounts. Access keys. No roles.

Early AWS environments I’ve seen (and had to clean up) reflect this era: a single root account access key shared across a team, rotated manually on a shared spreadsheet. Static credentials in application config files. EC2 instances with AdministratorAccess because “it was easier at the time.”

The AWS team understood what they’d built was dangerous. IAM in 2011 introduced the model that all three major cloud providers now share: deny-by-default, policy-driven, principal-based access control. Not “who is in which group” but “which policy explicitly grants this specific action on this specific resource to this specific identity.”

GCP launched its IAM model with a different flavour in 2012 — hierarchical, additive, binding-based. Azure RBAC came to general availability in 2014, built on top of Active Directory’s identity model.

By 2015, the modern cloud IAM era was established. The primitives existed. The problem shifted from “does IAM exist?” to “are we using it correctly?” — and most teams were not.

The Problem IAM Actually Solves

Here’s the honest version of what IAM is for, based on what I’ve seen go wrong without it.

Without proper IAM, you get one of two outcomes:

The first is what I call the “it works” environment. Everything runs. The developers are happy. Access requests take five minutes because everyone gets the same broad policy. And then a Lambda function’s execution role — which had s3:* on * because someone once needed to debug something — gets its credentials exposed through an SSRF vulnerability in the app it runs. That role can now read every bucket in the account, including the one with the customer database exports.

The second is the “it’s secure” environment. Access is locked down. Every request goes through a ticket. The ticket goes to a security team that approves it in three to five business days. Engineers work around it by storing credentials locally. The workarounds become the real access model. The formal IAM posture and the actual access posture diverge. The audit finds the formal one. Attackers find the real one.

IAM, done right, is the discipline of walking the line between those two outcomes. It’s not a product you buy or a feature you turn on. It’s a practice — a continuous process of defining what access exists, why it exists, and whether it’s still needed.

The Core Concepts — Taught, Not Listed

Let me walk you through the vocabulary you need, grounded in what each concept means in practice.

Identity: Who Is Making This Request?

An identity is any entity that can hold a credential and make requests. In cloud environments, identities split into two types:

Human identities are engineers, operators, and developers. They authenticate via the console, CLI, or SDK. They should ideally authenticate through a central IdP (Okta, Google Workspace, Entra ID) using federation — more on that in SAML vs OIDC: Which Federation Protocol Belongs in Your Cloud?.

Machine identities are everything else: Lambda functions, EC2 instances, Kubernetes pods, CI/CD pipelines, monitoring agents, data pipelines. In most production environments, machine identities outnumber human identities by 10:1 or more.

This ratio matters. When your security model is designed primarily for human access, the 90% of identities that are machines become an afterthought. That’s where access keys end up in environment variables, where Lambda functions get broad permissions because nobody thought carefully about what they actually need, where the real attack surface lives.

Principal: The Authenticated Identity Making a Specific Request

A principal is an identity that has been authenticated and is currently making a request. The distinction from “identity” is subtle but important: the principal includes the context of how the identity authenticated.

In AWS, an IAM role assumed by EC2, assumed by a Lambda, and assumed by a developer’s CLI session are three different principals — even if they all assume the same role. The session context, source, and expiration differ.

{
  "Principal": {
    "AWS": "arn:aws:iam::123456789012:role/DataPipelineRole"
  }
}

In GCP, the equivalent term is member. In Azure, it’s security principal — a user, group, service principal, or managed identity.

Resource: What Is Being Accessed?

A resource is whatever is being acted upon. In AWS, every resource has an ARN (Amazon Resource Name) — a globally unique identifier.

arn:aws:s3:::customer-data-prod          # S3 bucket
arn:aws:s3:::customer-data-prod/*        # everything inside that bucket
arn:aws:ec2:ap-south-1:123456789012:instance/i-0abcdef1234567890
arn:aws:iam::123456789012:role/DataPipelineRole

The ARN structure tells you: service, region, account, resource type, resource name. Once you can read ARNs fluently, IAM policies become much less intimidating.

Action: What Is Being Done?

An action (AWS/Azure) or permission (GCP) is the operation being attempted. Cloud providers express these as service:Operation strings:

# AWS
s3:GetObject           # read a specific object
s3:PutObject           # write an object
s3:DeleteObject        # delete an object — treat differently than read
iam:PassRole           # assign a role to a service — one of the most dangerous permissions
ec2:DescribeInstances  # list instances — often overlooked, but reveals infrastructure

# GCP
storage.objects.get
storage.objects.create
iam.serviceAccounts.actAs   # impersonate a service account — equivalent to iam:PassRole danger

When I audit IAM configurations, I pay special attention to any policy that includes iam:*, iam:PassRole, or wildcards like "Action": "*". These are the permissions that let a compromised identity create new identities, assign itself more power, or impersonate other accounts. They’re the privilege escalation primitives — more on that in AWS IAM Privilege Escalation: How iam:PassRole Leads to Full Compromise.

Policy: The Document That Connects Everything

A policy is a document that says: this principal can perform these actions on these resources, under these conditions.

{
  "Version": "2012-10-17",
  "Statement": [
    {
      "Sid": "ReadCustomerDataBucket",
      "Effect": "Allow",
      "Action": [
        "s3:GetObject",
        "s3:ListBucket"
      ],
      "Resource": [
        "arn:aws:s3:::customer-data-prod",
        "arn:aws:s3:::customer-data-prod/*"
      ]
    }
  ]
}

Notice what’s explicit here: the effect (Allow), the exact actions (not s3:*), and the exact resource (not *). Every word in this document is a deliberate decision. The moment you start using wildcards to save typing, you’re writing technical debt that will come back as a security incident.

How IAM Actually Works — The Decision Flow

When any API call hits a cloud service, an IAM engine evaluates it. Understanding this flow is the foundation of debugging access issues, and more importantly, of understanding why your security posture is what it is.

Request arrives:
  Action:    s3:PutObject
  Resource:  arn:aws:s3:::customer-data-prod/exports/2026-04-11.csv
  Principal: arn:aws:iam::123456789012:role/DataPipelineRole
  Context:   { source_ip: "10.0.2.15", mfa: false, time: "02:30 UTC" }

IAM Engine evaluation (AWS):
  1. Is there an explicit Deny anywhere? → No
  2. Does the SCP (if any) allow this? → Yes
  3. Does the identity-based policy allow this? → Yes (via DataPipelinePolicy)
  4. Does the resource-based policy (bucket policy) allow or deny? → No explicit rule → implicit allow for same-account
  5. Is there a permissions boundary? → No
  Decision: ALLOW

The critical insight here: cloud IAM is deny-by-default. There is no implicit allow. If there is no policy that explicitly grants s3:PutObject to this role on this bucket, the request fails. The only way in is through an explicit "Effect": "Allow".

This is the opposite of how most traditional systems work. In a Unix permission model, if your file is world-readable (-r--r--r--), anyone can read it unless you actively restrict them. In cloud IAM, nothing is accessible unless you actively grant it.

When I’m debugging an AccessDenied error — and every engineer who works with cloud IAM spends significant time doing this — the mental model is always: “what is the chain of explicit Allows that should be granting this access, and at which layer is it missing?”

Why This Is Harder Than It Looks

Understanding the concepts is the easy part. The hard part is everything that happens at organisational scale over time.

Scale. A real AWS account in a growing company might have 600+ IAM roles, 300+ policies, and 40+ cross-account trust relationships. None of these were designed together. They evolved incrementally, each change made by someone who understood the context at the time and may have left the organisation since. The cumulative effect is an IAM configuration that no single person fully understands.

Drift. IAM configs don’t stay clean. An engineer needs to debug a production issue at 2 AM and grants themselves broad access temporarily. The temporary access never gets revoked. Multiply that by a team of 20 over three years. I’ve audited environments where 60% of the permissions in a role had never been used — not once — in the 90-day CloudTrail window. That unused 60% is pure attack surface.

The machine identity blind spot. Most IAM governance practices were built for human users. Service accounts, Lambda roles, and CI/CD pipeline identities get created rapidly and reviewed rarely. In my experience, these are the identities most likely to have excess permissions, least likely to be in the access review process, and most likely to be the initial foothold in a cloud breach.

The gap between granted and used. This one surprised me most when I first started doing cloud security work. AWS data from real customer accounts shows the average IAM entity uses less than 5% of its granted permissions. That 95% excess isn’t just waste — it’s attack surface. Every permission that exists but isn’t needed is a permission an attacker can use if they compromise that identity.

IAM Across AWS, GCP, and Azure — The Conceptual Map

The three major providers implement IAM differently in syntax, but the same model underlies all of them. Once you understand one deeply, the others become a translation exercise.

Concept	AWS	GCP	Azure
Identity store	IAM users / roles	Google accounts, Workspace	Entra ID
Machine identity	IAM Role (via instance profile or AssumeRole)	Service Account	Managed Identity
Access grant mechanism	Policy document attached to identity or resource	IAM binding on resource (member + role + condition)	Role Assignment (principal + role + scope)
Hierarchy	Account is the boundary; Org via SCPs	Org → Folder → Project → Resource	Tenant → Management Group → Subscription → Resource Group → Resource
Default stance	Deny	Deny	Deny
Wildcard risk	`"Action": ""` on `"Resource": ""`	Primitive roles (viewer/editor/owner)	`Owner` or `Contributor` assigned broadly

The hierarchy point is worth pausing on. AWS is relatively flat — the account is the primary security boundary. GCP’s hierarchy means a binding at the Organisation level propagates down to every project. Azure’s hierarchy means a role assignment at the Management Group level flows through every subscription beneath it. The blast radius of a misconfiguration scales with how high in the hierarchy it sits.

This will matter in GCP IAM Policy Inheritance and Azure RBAC Explained when we go deep on GCP and Azure specifically. For now, the takeaway is: understand where in the hierarchy a permission is granted, because the same permission granted at the wrong level has a very different security implication.

Framework Alignment

If you’re mapping this episode to a control framework — for a compliance audit, a certification study, or building a security program — here’s where it lands:

Framework	Reference	What It Covers Here
CISSP	Domain 1 — Security & Risk Management	IAM as a risk reduction control; blast radius is a risk variable
CISSP	Domain 5 — Identity and Access Management	Direct implementation: who can do what, to which resources, under what conditions
ISO 27001:2022	5.15 Access control	Policy requirements for restricting access to information and systems
ISO 27001:2022	5.16 Identity management	Managing the full lifecycle of identities in the organization
ISO 27001:2022	5.18 Access rights	Provisioning, review, and removal of access rights
SOC 2	CC6.1	Logical access security controls to protect against unauthorized access
SOC 2	CC6.3	Access removal and review processes to limit unauthorized access

Key Takeaways

IAM evolved from Unix file permissions → directory services → cloud policy engines, driven by scale and the failure modes of each prior model
Cloud IAM is deny-by-default: every access requires an explicit Allow somewhere in the policy chain
Identities are human or machine; in production, machines dominate — and they’re the under-governed majority
A policy binds a principal to actions on resources; every word is a deliberate security decision
The hardest IAM problems aren’t technical — they’re organisational: drift, unused permissions, machine identities nobody owns, and access reviews that never happen
The gap between granted and used permissions is where attackers find room to move

What’s Next

Now that you understand what IAM is and why it exists, the next question is the one that trips up even experienced engineers: what’s the difference between authentication and authorization, and why does conflating them cause security failures?

EP02 works through both — how cloud providers implement each, where the boundary sits, and why getting this boundary wrong creates exploitable gaps.

Next: Authentication vs Authorization: AWS AccessDenied Explained

eBPF vs Kernel Modules: An Honest Comparison for K8s Engineers

April 4, 2026 by Vamshi Krishna Santhapuri

~2,100 words · Reading time: 8 min · Series: eBPF: From Kernel to Cloud, Episode 3 of 18

In Episode 1 we covered what eBPF is. In Episode 2 we covered why it is safe. The question that comes next is the one most tutorials skip entirely:

If eBPF can do everything a kernel module does for observability, why do kernel modules still exist? And when should you still reach for one?

Most comparisons on this topic are written by people who have used one or the other. I have used both — device driver work from 2012 to 2014 and eBPF in production Kubernetes clusters for the last several years. This is the honest version of that comparison, including the cases where kernel modules are still the right answer.

What Kernel Modules Actually Are

A kernel module is a piece of compiled code that loads directly into the running Linux kernel. Once loaded, it operates with full kernel privileges — the same level of access as the kernel itself. There is no sandbox. There is no safety check. There is no verifier.

This is both the power and the problem.

Kernel modules can do things that nothing else in the Linux ecosystem can do: implement new filesystems, add hardware drivers, intercept and modify kernel data structures, hook into scheduler internals. They are how the kernel extends itself without requiring a recompile or a reboot.

But the operating model is unforgiving:

A bug in a kernel module causes an immediate kernel panic — no exceptions, no recovery
Modules must be compiled against the exact kernel headers of the running kernel
A module that works on RHEL 8 may refuse to load on RHEL 9 without recompilation
Loading a module requires root privileges and deliberate coordination in production
Debugging a module failure means kernel crash dumps, kdump analysis, and time

I experienced all of these during device driver work. The discipline that environment instils is real — you think very carefully before touching anything, because mistakes are instantaneous and complete.

What eBPF Does Differently

eBPF was not designed to replace kernel modules. It was designed to provide a safe, programmable interface to kernel internals for the specific use cases where modules had always been used but were too dangerous: observability, networking, and security monitoring.

The fundamental difference is the verifier, covered in depth in Episode 2. Before any eBPF program runs, the kernel proves it is safe. Before any kernel module runs, nothing checks anything.

That single architectural decision produces a completely different operational profile:

Property	Kernel module	eBPF program
Safety check before load	None	BPF verifier — mathematical proof of safety
A bug causes	Kernel panic, immediate	Program rejected at load time
Kernel version coupling	Compiled per kernel version	CO-RE: compile once, run on any kernel 5.4+
Hot load / unload	Risky, requires coordination	Safe, zero downtime, zero pod restarts
Access scope	Full kernel, unrestricted	Restricted, granted per program type
Debugging	Kernel crash dumps, kdump	bpftool, bpftrace, readable error messages
Portability	Recompile per distro per version	Single binary runs across distros and versions
Production risk	High — no safety net	Low — verifier enforced before execution

CO-RE: Why Portability Matters More Than Most Engineers Realise

The portability column in that table deserves more than a one-line entry, because it is the operational advantage that compounds over time.

A kernel module written for RHEL 8 ships compiled against 4.18.0-xxx.el8.x86_64 kernel headers. When RHEL 8 moves to a new minor version, the module may need recompilation. When you migrate to RHEL 9 — kernel 5.14 with a completely different ABI in places — the module almost certainly needs a full rewrite of any code that touches kernel internals that changed between versions.

If you are running Falco with its kernel module driver and you upgrade a node from Ubuntu 20.04 to 22.04, Falco needs a pre-built module for your exact new kernel or it needs to compile one. If the pre-built is not available and compilation fails — no runtime security monitoring until it is resolved.

eBPF with CO-RE works differently. CO-RE (Compile Once, Run Everywhere) uses the kernel’s embedded BTF (BPF Type Format) information to patch field offsets and data structure layouts at load time to match the running kernel. The eBPF program was compiled once, against a reference kernel. When it loads on a different kernel, libbpf reads the BTF data from /sys/kernel/btf/vmlinux and fixes up the relocations automatically.

The practical result: a Cilium or Falco binary built six months ago loads and runs correctly on a node you just upgraded to a newer kernel version — without any module rebuilding, without any intervention, without any downtime.

In a Kubernetes environment where node images update regularly — especially on managed services like EKS, GKE, and AKS — this is not a minor convenience. It is the difference between eBPF tooling that survives an upgrade cycle and kernel module tooling that breaks one.

Security Implications: Container Escape and Privilege Escalation

The security difference between the two approaches matters specifically for container environments, and it goes beyond the verifier’s protection of your own nodes.

Kernel modules as an attack surface

Historically, kernel module vulnerabilities have been a primary vector for container escape. The attack pattern is straightforward: exploit a vulnerability in a loaded kernel module to gain kernel-level code execution, then use that access to break out of the container namespace into the host. Several high-profile CVEs over the past decade have followed this pattern.

The risk is compounded in environments that load third-party kernel modules — hardware drivers, filesystem modules, observability agents using the kernel module approach — because each additional module is an additional attack surface at the highest privilege level on the system.

eBPF’s security boundaries

eBPF does not eliminate the attack surface entirely, but it constrains it in important ways.

First, eBPF programs cannot leak kernel memory addresses to userspace. This is verifier-enforced and closes the class of KASLR bypass attacks that kernel module vulnerabilities have historically enabled.

Second, eBPF programs are sandboxed by design. They cannot access arbitrary kernel memory, cannot call arbitrary kernel functions, and cannot modify kernel data structures they were not explicitly granted access to. A vulnerability in an eBPF program is contained within that sandbox.

Third, the program type system controls what each eBPF program can see and do. A kprobe program watching syscalls cannot suddenly start modifying network packets. The scope is fixed at load time by the program type and verified by the kernel.

For EKS specifically: Falco running in eBPF mode on your nodes is not a kernel module that could be exploited for container escape. It is a verifier-checked program with a constrained access scope. The tool designed to detect container escapes is not itself a container escape vector — which is the correct security architecture.

Audit and visibility

eBPF programs are auditable in ways that kernel modules are not. You can list every eBPF program currently loaded on a node:

$ bpftool prog list
14: kprobe  name sys_enter_execve  tag abc123...  gpl
    loaded_at 2025-03-01T07:30:00+0000  uid 0
    xlated 240B  jited 172B  memlock 4096B  map_ids 3,4

27: cgroup_skb  name egress_filter  tag def456...  gpl
    loaded_at 2025-03-01T07:30:01+0000  uid 0

Every program is listed with its load time, its type, its tag (a hash of the program), and the maps it accesses. You can audit exactly what is running in your kernel at any point. Kernel modules offer no equivalent — lsmod tells you what is loaded but nothing about what it is actually doing.

EKS and Managed Kubernetes: Where the Difference Is Most Visible

The eBPF vs kernel module distinction plays out most clearly in managed Kubernetes environments, because you do not control when nodes upgrade.

On EKS, when AWS releases a new optimised AMI for a node group and you update it, your nodes are replaced. Any kernel module-based tooling on those nodes needs pre-built modules for the new kernel, or it needs to compile them at node startup, or it fails. AWS does not provide the kernel source for EKS-optimised AMIs in the same way a standard distribution does, which makes module compilation at runtime unreliable.

This is precisely why the EKS 1.33 migration covered in the EKS 1.33 post was painful for Rocky Linux: it involved kernel-level networking behaviour that had been assumed stable. When the kernel networking stack changed, everything built on top of those assumptions broke.

eBPF-based tooling on EKS does not have this problem, provided the node OS ships with BTF enabled — which Amazon Linux 2023 and Ubuntu 22.04 EKS-optimised AMIs do. Cilium and Falco survive node replacements without any module rebuilding because CO-RE handles the kernel version differences automatically.

For GKE and AKS the story is similar. Both use node images with BTF enabled on current versions, and both upgrade nodes on a managed schedule that is difficult to predict precisely. eBPF tooling survives this. Kernel module tooling fights it.

When You Should Still Use Kernel Modules

eBPF is not the right answer for every use case. Kernel modules remain the correct tool when:

You are implementing hardware support. Device drivers for new hardware still require kernel modules. eBPF cannot provide the low-level hardware interrupt handling, DMA operations, or hardware register access that a device driver needs. If you are bringing up a new network interface card, storage controller, or GPU, you are writing a kernel module.

You need to modify kernel behaviour, not just observe it. eBPF can observe and filter. It can drop packets, block syscalls via LSM hooks, and redirect traffic. But it cannot fundamentally change how the kernel handles a syscall, implement a new scheduling algorithm from scratch, or add a new filesystem type. Those changes require kernel modules or upstream kernel patches.

You are on a kernel older than 5.4. Without BTF and CO-RE, eBPF programs must be compiled per kernel version — which largely eliminates the portability advantage. On RHEL 7 or very old Ubuntu LTS versions still in production, kernel modules may be the more practical path for instrumentation work, though migrating the underlying OS is a better long-term answer.

You need capabilities the eBPF verifier rejects. The verifier’s safety constraints occasionally reject programs that are logically safe but that the verifier cannot prove safe statically. Complex loops, large stack allocations, and certain pointer arithmetic patterns hit verifier limits. In these edge cases, a kernel module can do what the verifier would not allow. These situations are rare and becoming rarer as the verifier improves across kernel versions.

The Practical Decision Framework

For most engineers reading this — Linux admins, DevOps engineers, SREs managing Kubernetes clusters — the decision is straightforward:

Observability, security monitoring, network policy, performance profiling on Linux 5.4+ → eBPF
Hardware drivers, new kernel subsystems, or kernels older than 5.4 → kernel modules
Production Kubernetes on EKS, GKE, or AKS → eBPF, always, because CO-RE survives managed upgrades and kernel modules do not

The overlap between the two technologies — the use cases where both could work — has been shrinking for five years and continues to shrink as the verifier becomes more capable and CO-RE becomes more widely supported. The direction of travel is clear.

Kernel modules are a precision instrument for modifying kernel behaviour. eBPF is a safe, portable interface for observing and influencing it. In 2025, if you are reaching for a kernel module to instrument a production system, there is almost certainly a better path.

Up Next

Episode 4 covers the five things eBPF can observe that no other tool can — without agents, without sidecars, and without any changes to your application code. If you are running production Kubernetes and want to understand what true zero-instrumentation observability looks like, that is the post.

The full series is on LinkedIn — search #eBPFSeries — and all episodes are indexed on linuxcent.com under the eBPF Series tag.

BPF Verifier Explained: Why eBPF Is Safe for Production Kubernetes

March 25, 2026March 22, 2026 by Vamshi Krishna Santhapuri

~2,400 words · Reading time: 9 min · Series: eBPF: From Kernel to Cloud, Episode 2 of 18

In Episode 1, we established what eBPF is and why it gives Linux admins and DevOps engineers kernel-level visibility without sidecars or code changes. The obvious follow-up question is the one every experienced engineer should ask before running anything in kernel space:

Is it actually safe to run on production nodes?

The answer is yes — and the reason is one specific component of the Linux kernel called the BPF verifier. This post explains what the verifier is, what it protects your cluster from, and why it changes the risk calculus for eBPF-based tools entirely.

The Fear That Holds Most Teams Back

When I first explain eBPF to Linux admins and DevOps engineers, the reaction is almost always the same:

“So it runs code inside the kernel? On our production nodes? That sounds like a disaster waiting to happen.”

It is a completely reasonable concern. The Linux kernel is not a place where mistakes are tolerated. A buggy kernel module can take down a server instantly — no warning, no graceful shutdown, just a hard panic and a 3 AM phone call.

I know this from personal experience. During 2012–2014, I worked briefly with Linux device driver code. That period taught me one thing clearly: kernel space does not forgive careless code.

So when people started talking about running programs inside the kernel via eBPF, my instinct was scepticism too. Then I understood the BPF verifier. And everything changed.

What the Verifier Actually Is

Think of the BPF verifier as a strict safety gate that sits between your eBPF program and the kernel. Before your eBPF program is allowed to run — before it touches a single system call, network packet, or container event — the verifier reads through every line of it and asks one question:

“Could this program crash or compromise the kernel?”

If the answer is yes, or even maybe, the program is rejected. It does not load. Your cluster stays safe. If the answer is a provable no, the program loads and runs.

This is not a runtime check that catches problems after the fact. It is a load-time guarantee — the kernel proves the program is safe before it ever executes. Here is what that looks like when you deploy Cilium:

You run: kubectl apply -f cilium-daemonset.yaml
         └─► Cilium loads its eBPF programs onto each node
                   └─► Kernel verifier checks every program
                             ├─► SAFE   → program loads, starts observing
                             └─► UNSAFE → rejected, cluster untouched

This is why Cilium can replace kube-proxy on your nodes, why Falco can watch every syscall in every container, and why Tetragon can enforce security policy at the kernel level — all without putting your cluster at risk.

What the Verifier Protects You From

You do not need to know how the verifier works internally. What matters is what it prevents — and why each protection matters specifically in Kubernetes environments.

Infinite loops

An eBPF program that never terminates would freeze the kernel event it is attached to — potentially hanging every container on that node. The verifier rejects any program it cannot prove will finish executing within a bounded number of instructions.

Why this matters: Every eBPF-based tool on your K8s nodes — Cilium, Falco, Tetragon, Hubble — was verified to terminate correctly on every code path before it shipped. You are not trusting the vendor’s claim. The kernel enforced it.

Memory safety violations

An eBPF program cannot read or write memory outside the boundaries it is explicitly granted. No reaching into another container’s memory space. No accessing kernel data structures it was not given permission to touch.

Why this matters: This is the property that makes eBPF safe for multi-tenant clusters. A Falco rule monitoring one namespace cannot accidentally read data from another namespace’s containers. The verifier makes this impossible at the program level, not just at the policy level.

Kernel crashes

The verifier checks that every pointer is valid before it is dereferenced, that every function call uses correct arguments, and that the program cannot corrupt kernel data structures. Programs that could cause a kernel panic are rejected before they load.

Why this matters: Running Cilium or Tetragon on a production node is not the same risk as loading an untested kernel module. The verifier has already proven these programs cannot crash your nodes — before they ever ran on your infrastructure.

Privilege escalation and kernel pointer leaks

eBPF programs cannot leak kernel memory addresses to userspace. This closes a class of container escape and privilege escalation attacks that have historically been possible through kernel module vulnerabilities.

Why this matters: Security tools built on eBPF — like Tetragon, which detects and blocks container escape attempts in real time — are not themselves a vector for the attacks they protect against.

eBPF vs Traditional Observability Agents

To appreciate what the verifier gives you operationally, compare the two main approaches to K8s observability.

Traditional agent — DaemonSet sidecar approach

Your K8s cluster
└─► Node
    ├─► App Pod (your service)
    ├─► Sidecar container (injected into every pod)
    │   └─► Reads /proc, intercepts syscalls via ptrace
    │       └─► 15–30% CPU/memory overhead per pod
    └─► Agent DaemonSet Pod
        └─► Aggregates data from all sidecars

Problems with this model:

Sidecar injection requires modifying every pod spec and typically an admission webhook
ptrace-based interception adds 50–100% overhead to the traced process and is blocked in hardened containers
The agent runs in userspace with elevated privileges — a larger attack surface
Updating the agent requires pod restarts across your fleet

eBPF-based tool — Cilium / Falco / Tetragon

Your K8s cluster
└─► Node
    ├─► App Pod (your service — completely unmodified)
    ├─► App Pod (another service — also unmodified)
    └─► eBPF programs (inside the kernel, verifier-checked)
        └─► See every syscall, network packet, file access
            └─► Forward events to userspace agent via ring buffer

Benefits:

No sidecar injection — pod specs stay clean, no admission webhook required
Kernel-level visibility with near-zero overhead (typically 1–3%)
The verifier guarantees the eBPF programs cannot harm your nodes
Works identically with Docker, containerd, and CRI-O

Tools You Are Probably Already Running — All Verifier-Protected

You may already be running eBPF on your nodes without thinking about it explicitly. In each case below, the verifier ran before the tool ever touched your cluster.

Tool	How the verifier is involved
Cilium	Every network policy decision, service load-balancing operation, and Hubble flow log is handled by eBPF programs that passed the verifier at node startup.
Falco	Every Falco rule is enforced by a verifier-checked eBPF program attached to syscall hooks. Sub-millisecond detection is only possible because the program runs in kernel space.
AWS VPC CNI	On EKS, networking operations have progressively moved to eBPF for performance at scale. If you are on a recent EKS AMI, eBPF is already doing work on your nodes.
systemd	Modern systemd uses eBPF for cgroup-based resource accounting and network traffic control. Active on most current Ubuntu, RHEL, and Amazon Linux 2023 installations.

Questions to Ask When Evaluating eBPF Tools

When a vendor tells you their tool uses eBPF, these three questions will quickly tell you how mature their implementation is.

1. What kernel version do you require?

The verifier’s capabilities have expanded significantly across kernel versions. Tools targeting kernel 5.8+ can use more powerful features safely. Tools claiming to work on kernel 4.x are constrained by an older, more limited verifier. The table below shows exactly where each major distribution stands.

Distribution	Default kernel	eBPF support level	Notes
Ubuntu 16.04 LTS	4.4	Basic eBPF only	No BTF. kprobes and socket filters work but modern tooling like Cilium and Falco eBPF driver will not run. EOL — do not use for new deployments.
Ubuntu 18.04 LTS	4.15	eBPF, no BTF	No CO-RE. Tools must be compiled against the exact running kernel headers. The HWE kernel (5.4) improves this but BTF still varies by build.
Ubuntu 20.04 LTS	5.4	BTF available, verify before use	CO-RE capable on most deployments. `CONFIG_DEBUG_INFO_BTF` was absent on some early builds. Verify with `ls /sys/kernel/btf/vmlinux` before deploying eBPF tooling. Cloud images generally have it enabled.
Ubuntu 20.10+	5.8	Full BTF + CO-RE	First Ubuntu release where BTF was consistently enabled by default. Ring buffers available. Not an LTS release — use 22.04 for production.
Ubuntu 22.04 LTS	5.15	Full modern eBPF — production ready	BTF embedded. Ring buffers, global variables, LSM hooks. Default baseline for EKS-optimised Ubuntu AMIs. Recommended for new deployments.
Ubuntu 24.04 LTS	6.8	Full modern eBPF + latest features	Open-coded iterators, improved verifier precision, enhanced LSM support. Best Ubuntu option for cutting-edge eBPF tooling today.
Debian 10 (Buster)	4.19	Basic eBPF, no BTF	eBPF programs load but CO-RE is unavailable. Must compile against exact kernel headers. EOL — migrate to Debian 11 or 12.
Debian 11 (Bullseye)	5.10 LTS	Full BTF + CO-RE	BTF enabled. CO-RE works. Cilium, Falco, and Tetragon all fully supported. Solid production baseline for Debian environments through 2026.
Debian 12 (Bookworm)	6.1 LTS	Full modern eBPF — production ready	Same kernel generation as Amazon Linux 2023. LSM hooks, ring buffers, full CO-RE. Recommended Debian version for eBPF workloads today.
Debian 13 (Trixie)	6.12 LTS	Full modern eBPF + latest features	Released August 2025. Same kernel generation as RHEL 10 / Rocky 10 / AlmaLinux 10. Maximum eBPF feature availability across all program types.
RHEL 7.6	3.10 (backported)	Tech Preview only — not production safe	First RHEL release to enable eBPF but explicitly marked as Tech Preview. Limited to kprobes and tracepoints. No XDP, no socket filters, no BTF. Do not use for eBPF in production.
RHEL 8 / Rocky 8 / AlmaLinux 8	4.18 (heavily backported)	Full BPF + BTF — functionally 5.4-equivalent	Red Hat backports make RHEL 8 kernels functionally comparable to upstream 5.4 for most eBPF use cases. BTF enabled across all releases. CO-RE works. Cilium treats RHEL 8.6+ as its minimum supported RHEL-family version.
RHEL 9 / Rocky 9 / AlmaLinux 9	5.14 (heavily backported)	Full modern eBPF — production ready	BTF embedded. XDP, tc, kprobe, tracepoint, and LSM hooks all supported. Falco, Cilium, and Tetragon fully supported. Recommended RHEL-family version for eBPF deployments today. Supported until 2032.
RHEL 10 / Rocky 10 / AlmaLinux 10	6.12	Full modern eBPF + latest features	Same kernel generation as Debian 13 and upstream 6.12 LTS. Rocky 10 released June 2025, AlmaLinux 10 released May 2025. Enhanced eBPF functionality throughout.
Amazon Linux 2023	6.1+	Full modern eBPF — production ready	BTF embedded. Full CO-RE. Recommended for EKS. Also resolves the NetworkManager deprecation issues in EKS 1.33+ — see the EKS 1.33 post.

Quick check for any distro: Run ls /sys/kernel/btf/vmlinux on your node. If the file exists, your kernel has BTF enabled and CO-RE-based eBPF tools will work correctly. If it does not exist, you are limited to tools that compile against your specific kernel headers. Run uname -r to confirm the exact kernel version.

Rocky Linux and AlmaLinux note: Both distros rebuild directly from RHEL sources. Their kernel versions and eBPF capabilities are effectively identical to the corresponding RHEL release. When Cilium or Falco document “RHEL 9 support”, that applies equally to Rocky 9 and AlmaLinux 9 without any additional configuration.

2. Do you use CO-RE?

CO-RE (Compile Once, Run Everywhere) means the tool’s eBPF programs work correctly across different kernel versions without recompilation. Tools using CO-RE are more portable and significantly less likely to break after a routine node OS update. This is a reliable signal of engineering maturity in the vendor’s eBPF implementation.

3. What eBPF program types do you use?

Different program types have different privilege levels and access scopes. A tool that only needs kprobe access is asking for considerably less privilege than one requiring lsm hooks.

kprobe / tracepoint — observability and debugging
tc (traffic control) — network policy enforcement
xdp (eXpress Data Path) — high-performance packet processing
lsm (Linux Security Module) — security policy enforcement (used by Tetragon)

Understanding the program type tells you what the tool can and cannot see on your nodes, and how much kernel access you are granting it.

How Falco Uses the Verifier — A Step-by-Step Walkthrough

Here is exactly what happens when Falco starts on one of your K8s nodes, and where the verifier fits in:

1. Falco pod starts on the node (via DaemonSet)

2. Falco loads its eBPF programs into the kernel:
   └─► BPF verifier checks each program
       ├─► Can it crash the kernel?            No → continue
       ├─► Can it loop forever?                No → continue
       ├─► Can it access out-of-bounds memory? No → continue
       └─► PASS → program loads

3. Falco's eBPF programs attach to syscall hooks:
   └─► sys_enter_execve   (every process execution in every container)
   └─► sys_enter_openat   (every file open)
   └─► sys_enter_connect  (every outbound network connection)

4. A container runs an unexpected shell (potential attack):
   └─► execve() called inside the container
   └─► Falco's eBPF hook fires in kernel space
   └─► Event forwarded to Falco userspace via ring buffer
   └─► Falco rule matches: "shell spawned in container"
   └─► Alert fired in under 1 millisecond

5. Your container, your other pods, your node: completely unaffected

Step 2 is what the verifier makes safe. Without it, attaching eBPF hooks to every syscall on your production node would be an unacceptable risk. With it, Falco can offer this level of visibility with a mathematical safety guarantee.

The Bottom Line

You do not need to understand BPF bytecode, register states, or static analysis to use eBPF tools safely in production. What you do need to understand is this:

The BPF verifier is the reason eBPF is fundamentally different from kernel modules. It does not just make eBPF “safer” in a vague sense — it provides a mathematical proof that each program cannot crash your kernel before that program ever runs.

This is why eBPF-based tools can deliver deep kernel-level visibility into every container, every syscall, and every network flow — with near-zero overhead, no sidecar injection, and production safety that kernel modules could never guarantee.

The next time someone on your team hesitates about running Cilium, Falco, or Tetragon on production nodes because “it runs code in the kernel” — you now know what to tell them. The verifier already checked it. Before it ever touched your cluster.

What Is eBPF? A Plain-English Guide for Linux and Kubernetes Engineers

March 22, 2026March 19, 2026 by Vamshi Krishna Santhapuri

~1,900 words · Reading time: 7 min · Series: eBPF: From Kernel to Cloud, Episode 1 of 18

Your Linux kernel has had a technology built into it since 2014 that most engineers working with Linux every day have never looked at directly. You have almost certainly been using it — through Cilium, Falco, Datadog, or even systemd — without knowing it was there.

This post is the plain-English introduction to eBPF that I wished existed when I first encountered it. No kernel engineering background required. No bytecode, no BPF maps, no JIT compilation. Just a clear answer to the question every Linux admin and DevOps engineer eventually asks: what actually is eBPF, and why does it matter for the infrastructure I run every day?

First: Forget the Name

eBPF stands for extended Berkeley Packet Filter. It is one of the most misleading names in computing for what the technology actually does.

The original BPF was a 1992 mechanism for filtering network packets — the engine behind tcpdump. The extended version, introduced in Linux 3.18 (2014) and significantly matured through Linux 5.x, is a completely different technology. It is no longer just about packets. It is no longer just about filtering.

Forget the name. Here is what eBPF actually is:

eBPF lets you run small, safe programs directly inside the Linux kernel — without writing a kernel module, without rebooting, and without modifying your applications.

That is the complete definition. Everything else is implementation detail. The one-liner above is what matters for how you use it day to day.

What the Linux Kernel Can See That Nothing Else Can

To understand why eBPF is significant, you need to understand what the Linux kernel already sees on every server and every Kubernetes node you run.

The kernel is the lowest layer of software on your machine. Every action that happens — every file opened, every process started, every network packet sent — passes through the kernel. That means it has a complete, real-time view of everything:

Every syscall — every open(), execve(), connect(), write() from every process in every container on the node, in real time
Every network packet — source, destination, port, protocol, bytes, and latency for every pod-to-pod and pod-to-external connection
Every process event — every fork, exec, and exit, including processes spawned inside containers that your container runtime never reports
Every file access — which process opened which file, when, and with what permissions, across all workloads on the node simultaneously
CPU and memory usage — per-process CPU time, function-level latency, and memory allocation patterns without profiling agents

The kernel has always had this visibility. The problem was that there was no safe, practical way to access it without writing kernel modules — which are complex, kernel version-specific, and genuinely dangerous to run in production. eBPF is the safe, practical way to access it.

The Problem eBPF Solves — A Real Kubernetes Scenario

Here is a situation every Kubernetes engineer has faced. A production pod starts behaving strangely — elevated CPU, slow responses, occasional connection failures. You want to understand what is happening at a low level: what syscalls is it making, what network connections is it opening, is something spawning unexpected processes?

The old approaches and their problems

Restart the pod with a debug sidecar. You lose the current state immediately. The issue may not reproduce. You have modified the workload.

Run strace inside the container via kubectl exec. strace uses ptrace, which adds 50–100% CPU overhead to the traced process and is unavailable in hardened containers. You are tracing one process at a time with no cluster-wide view.

Poll /proc with a monitoring agent. Snapshot-based. Any event that happens between polls is invisible. A process that starts, does something, and exits between intervals is completely missed.

The eBPF approach

# Use a debug pod on the node — no changes to your workload
$ kubectl debug node/your-node -it --image=cilium/hubble-cli

# Real-time kernel events from every container on this node:
sys_enter_execve  pid=8821  comm=sh    args=["/bin/sh","-c","curl http://..."]
sys_enter_connect pid=8821  comm=curl  dst=203.0.113.42:443
sys_enter_openat  pid=8821  comm=curl  path=/etc/passwd

# Something inside the pod spawned a shell, made an outbound connection,
# and read /etc/passwd — all visible without touching the pod.

Real-time visibility. No overhead on your workload. Nothing restarted. Nothing modified. That is what eBPF makes possible.

Tools You Are Probably Already Running on eBPF

eBPF is not a standalone product — it is the foundation that many tools in the cloud-native ecosystem are built on. You may already be running eBPF on your nodes without thinking about it explicitly.

Tool	What eBPF does for it	Without eBPF
Cilium	Replaces kube-proxy and iptables with kernel-level packet routing. 2–3× faster at scale.	iptables rules — linear lookup, degrades with service count
Falco	Watches every syscall in every container for security rule violations. Sub-millisecond detection.	Kernel module (risky) or ptrace (high overhead)
Tetragon	Runtime security enforcement — can kill a process or drop a network packet at the kernel level.	No practical alternative at this detection speed
Datadog Agent	Network performance monitoring and universal service monitoring without application code changes.	Language-specific agents injected into application code
systemd	cgroup resource accounting and network traffic control on your Linux nodes.	Legacy cgroup v1 interfaces with limited visibility

eBPF vs the Old Ways

Before eBPF, getting deep visibility into a running Linux system meant choosing between three approaches, each with a significant trade-off:

Approach	Visibility	Cost	Production safe?
Kernel modules	Full kernel access	One bug = kernel panic. Version-specific, must recompile per kernel update.	No
ptrace / strace	One process at a time	50–100% CPU overhead on the traced process. Unusable in production.	No
Polling /proc	Snapshots only	Events between polls are invisible. Short-lived processes are missed entirely.	Partial
eBPF	Full kernel visibility	1–3% overhead. Verifier-guaranteed safety. Real-time stream, not polling.	Yes

Is It Safe to Run in Production?

This is always the first question from any experienced Linux admin, and it is exactly the right question to ask. The answer is yes — and the reason is the BPF verifier.

Before any eBPF program is allowed to run on your node, the Linux kernel runs it through a built-in static safety analyser. This analyser examines every possible execution path and asks: could this program crash the kernel, loop forever, or access memory it should not?

If the answer is yes — or even maybe — the program is rejected at load time. It never runs.

This is fundamentally different from kernel modules. A kernel module loads immediately with no safety check. If it has a bug, you find out at runtime — usually as a kernel panic. An eBPF program that would cause a panic is rejected before it ever loads. The safety guarantee is mathematical, not hopeful.

Episode 2 of this series covers the BPF verifier in full: what it checks, how it makes Cilium and Falco safe on your production nodes, and what questions to ask eBPF tool vendors about their implementation.

Common Misconceptions

eBPF is not a specific tool or product. It is a kernel technology — a platform. Cilium, Falco, Tetragon, and Pixie are tools built on top of it. When a vendor says “we use eBPF”, they mean they build on this kernel capability, not that they share a single implementation.

eBPF is not only for networking. The Berkeley Packet Filter name suggests networking, but modern eBPF covers security, observability, performance profiling, and tracing. The networking origin is historical, not a limitation.

eBPF is not only for Kubernetes. It works on any Linux system running kernel 4.9+, including bare metal servers, Docker hosts, and VMs. K8s is the most popular deployment target because of the observability challenges at scale, but it is not a requirement.

You do not need to write eBPF programs to benefit from eBPF. Most Linux admins and DevOps engineers will use eBPF through tools like Cilium, Falco, and Datadog — never writing a line of BPF code themselves. This series covers the writing side later. Understanding what eBPF is makes you a significantly better user of these tools today.

Kernel Version Requirements

eBPF is a Linux kernel feature. The capabilities available depend directly on the kernel version running on your nodes. Run uname -r on any node to check.

Kernel	What becomes available
`4.9+`	Basic eBPF support. Tracing, socket filtering. Most production systems today meet this minimum.
`5.4+`	BTF (BPF Type Format) and CO-RE — programs that adapt to different kernel versions without recompile. Recommended minimum for production tooling.
`5.8+`	Ring buffers for high-performance event streaming. Global variables. The target kernel for Cilium, Falco, and Tetragon full feature support.
`6.x`	Open-coded iterators, improved verifier, LSM security enforcement hooks. Amazon Linux 2023 and Ubuntu 22.04+ ship 5.15 or newer and are fully eBPF-ready.

EKS users: Amazon Linux 2023 AMIs ship with kernel 6.1+ and support the full modern eBPF feature set out of the box. If you are still on AL2, the migration also resolves the NetworkManager deprecation issues covered in the EKS 1.33 post.

The Bottom Line

eBPF is the answer to a question Linux engineers have been asking for years: how do I get deep visibility into what is happening on my servers and Kubernetes nodes — without adding massive overhead, injecting sidecars, or risking a kernel panic?

The answer is: run small, safe programs at the kernel level, where everything is already visible. Let the BPF verifier guarantee those programs are safe before they run. Stream the results to your observability tools through shared memory maps.

The tools you already use — Cilium for networking, Falco for security, Datadog for APM — are built on this foundation. Understanding eBPF means understanding why those tools work the way they do, what they can and cannot see, and how to evaluate new tools that claim to use it.

Every eBPF-based tool you run on your nodes passed through the BPF verifier before it touched your cluster. Episode 2 covers exactly what that means — and why it matters for your infrastructure decisions.

Cloud AMI Security Risks & How Custom OS Images Fix them and what’s wrong with defaults

March 22, 2026March 15, 2026 by Vamshi Krishna Santhapuri

~2,800 words · Reading time: 12 min · Series: OS Image Security, Post 1 of 6

When you launch an EC2 instance from an AWS Marketplace AMI, or spin up a VM from a cloud-provider base image on GCP or Azure, you’re trusting a decision someone else made months ago about what your server should contain. That decision was made for the widest possible audience — not for your workload, your threat model, or your compliance requirements.

This post tears open what’s actually inside a default cloud image, compares it against what a production-hardened image should contain, and explains why the calculus changes depending on whether you’re deploying to AWS, an on-prem KVM host, or a Nutanix AHV cluster.

What a cloud provider is actually optimising for

AWS, Canonical, Red Hat, and every other publisher shipping to cloud marketplaces are solving a distribution problem, not a security problem. Their images need to:

Boot successfully on any instance type in any region
Work for the first-time user running their first workload
Support every possible use case — web servers, databases, ML training jobs, bastion hosts, everything

That constraint produces images that are, by design, permissive. Permissive gets out of the way. Permissive doesn’t break anything on day one. Permissive is also the opposite of what you want on a production server.

Let’s look at what “permissive” actually means in concrete terms.

Dissecting a default AWS AMI

Take Amazon Linux 2023 (AL2023), one of the more intentionally stripped-down cloud images available. Even with Amazon’s effort to reduce its footprint compared to AL2, a fresh AL2023 instance ships with more than most workloads need.

Services running at boot that most workloads don’t need

chronyd.service            # Fine — you need NTP
systemd-resolved.service   # Fine
dbus-broker.service        # Fine
amazon-ssm-agent.service   # Arguably fine if you use SSM
NetworkManager.service     # Debatable — most cloud workloads don't need NM

On a RHEL 8/9 or Ubuntu 22.04 Marketplace image, the list is longer. You’ll find avahi-daemon (mDNS/DNS-SD service discovery — on a server), bluetooth.service in some configurations, cups on some RHEL variants, and on Ubuntu, snapd running and occupying memory along with its associated mount units.

Every running service is an attack surface. Every socket it opens is a listening endpoint you didn’t ask for.

SSH configuration out of the box

The default sshd_config on most Marketplace images is not hardened. You’ll typically find:

PermitRootLogin prohibit-password   # Better than 'yes', but not 'no'
PasswordAuthentication no           # Usually disabled by cloud-init — good
X11Forwarding yes                   # On a headless server. Why?
AllowAgentForwarding yes            # Unnecessary for most workloads
PrintLastLog yes                    # Minor, but generates audit noise
MaxAuthTries 6                      # CIS recommends 4 or fewer
ClientAliveInterval 0               # No idle timeout

CIS Benchmark Level 1 for RHEL 9 has 40+ SSH-specific controls. A default image satisfies perhaps a third of them.

Kernel parameters that aren’t tuned

# Not set, or not set correctly, on most default images:
net.ipv4.conf.all.send_redirects = 1        # Should be 0
net.ipv4.conf.default.accept_redirects = 1  # Should be 0
net.ipv4.ip_forward = 0                     # Correct if not a router, but often left unset
kernel.randomize_va_space = 2               # Usually correct — verify anyway
fs.suid_dumpable = 0                        # Often not set
kernel.dmesg_restrict = 1                   # Rarely set

These live in /etc/sysctl.d/ and need to be explicitly applied. In a default AMI, they are not.

No audit daemon configured

auditd is installed on most RHEL-family images. It is not configured. The default audit.rules file is essentially empty — the daemon runs but captures almost nothing. On Ubuntu, auditd isn’t even installed by default.

CIS Benchmark Level 2 for RHEL 9 specifies 30+ auditd rules covering file access, privilege escalation, user management changes, network configuration changes, and more. None of them are present in a default AMI.

Package surface

Run rpm -qa | wc -l or dpkg -l | grep -c ^ii on a fresh instance. AL2023 comes in around 350 packages. Ubuntu 22.04 Server minimal sits around 500. RHEL 9 from Marketplace — depending on the variant — lands between 400 and 600.

How many of those packages does your application actually need? For a Python web service: Python, your runtime dependencies, and a handful of system libraries. The rest is exposure.

The on-prem story is different — and often worse

Cloud images at least get regular updates from their publishers. On-prem KVM and Nutanix environments tell a different story.

The KVM / QCOW2 situation

Most teams running KVM get their base images one of three ways:

Download a cloud image (cloud-init enabled QCOW2) from the distro vendor and use it directly
Convert an existing VMware VMDK or OVA and hope for the best
Run a manual Kickstart/Preseed install once, then treat the result as the “golden image” forever

Option 1 gives you the same problems as the cloud image analysis above, plus you’re now responsible for handling cloud-init in an environment that might not have a metadata service — so you either ship a seed ISO with every VM, or you rip out cloud-init and manage first-boot differently.

Option 3 is the most common and the most dangerous. That “golden image” was created by someone who’s possibly no longer at the company, contains packages pinned to versions from 18 months ago, and has sshd configured however was convenient at the time. Worse, it gets cloned hundreds of times and none of those clones are ever individually updated at the image level.

The Nutanix AHV specifics

Nutanix AHV images have additional considerations that cloud images don’t deal with:

AHV uses a custom paravirtualised SCSI controller (virtio-scsi or the Nutanix variant). Images imported from VMware need pvscsi drivers removed and virtio_scsi added to the initramfs before the disk will be detected at boot.
The Nutanix guest tools agent (ngt) is separate from the kernel and needs to be installed inside the image for snapshot quiescence, VSS integration, and in-guest metrics.
cloud-init works on AHV but requires the ConfigDrive datasource — not the EC2 datasource that most cloud QCOW2 images default to. An unconfigured datasource means cloud-init times out at boot, costing 3–5 minutes on every first start.
NUMA topology on large AHV nodes affects memory allocation in ways that need kernel tuning (vm.zone_reclaim_mode, kernel.numa_balancing) — parameters no generic cloud image sets.

The result is that most Nutanix environments end up with a patchwork: partially converted images, manually applied guest tools, and hardening that was done once per environment rather than once per image.

What a hardened image actually looks like

A properly built hardened image isn’t just “a default image with some hardening applied at the end.” The hardening is architectural — decisions made at build time that change the fundamental shape of what’s inside the image.

Package set — minimal by design

Start from a minimal install group — @minimal-environment on RHEL/Rocky, --variant=minbase on Debian derivatives. Then add only what the image class requires. For a web server image: your runtime, a process supervisor, and nothing else. No man-db, no X11-common, no avahi.

Every package you don’t install is a CVE that can never affect you.

Filesystem hardening

Separate mount points with restrictive options prevent a class of privilege escalation attacks that depend on executing binaries from world-writable locations:

/tmp      nodev,nosuid,noexec
/var      nodev,nosuid
/var/tmp  nodev,nosuid,noexec
/home     nodev,nosuid
/dev/shm  nodev,nosuid,noexec

These are not applied by any default cloud image.

Kernel parameters — baked in at build time

# /etc/sysctl.d/99-hardening.conf

net.ipv4.conf.all.send_redirects = 0
net.ipv4.conf.default.send_redirects = 0
net.ipv4.conf.all.accept_redirects = 0
net.ipv4.conf.default.accept_redirects = 0
net.ipv4.conf.all.accept_source_route = 0
net.ipv4.conf.all.log_martians = 1
net.ipv6.conf.all.accept_redirects = 0
kernel.randomize_va_space = 2
fs.suid_dumpable = 0
kernel.dmesg_restrict = 1
kernel.kptr_restrict = 2
net.core.bpf_jit_harden = 2

Applied at image build time. Present on every instance, every time, before your application code runs.

SSH locked down

Protocol 2
PermitRootLogin no
MaxAuthTries 4
LoginGraceTime 60
X11Forwarding no
AllowAgentForwarding no
AllowTcpForwarding no
PermitUserEnvironment no
Ciphers [email protected],[email protected],aes256-ctr
MACs [email protected],[email protected]
KexAlgorithms curve25519-sha256,diffie-hellman-group16-sha512
ClientAliveInterval 300
ClientAliveCountMax 3
Banner /etc/issue.net

This is approximately CIS Level 1 SSH hardening. It lives in the image — not in a post-deploy playbook.

auditd rules embedded

# Privilege escalation
-a always,exit -F arch=b64 -S execve -C uid!=euid -F euid=0 -k setuid

# Sudo usage
-w /etc/sudoers -p wa -k sudoers

# User and group management
-w /etc/passwd -p wa -k identity
-w /etc/group  -p wa -k identity

# Kernel module loading
-a always,exit -F arch=b64 -S init_module -S delete_module -k modules

The full CIS L2 auditd ruleset runs to ~60 rules. They’re all committed to the image. Every instance generates audit logs from minute one of its existence.

Services disabled at build time

systemctl disable avahi-daemon
systemctl disable cups
systemctl disable postfix
systemctl disable bluetooth
systemctl disable rpcbind
systemctl mask debug-shell.service

The service list varies by distro. The principle is the same: if it’s not required by the image’s purpose, it doesn’t run.

The platform dimension: why you can’t use one image everywhere

This is where the complexity gets real. A CIS-hardened RHEL 9 image built for AWS doesn’t directly work on KVM, and it doesn’t directly work on Nutanix either. The security controls are the same — the platform-specific layer underneath them is not.

Here’s what needs to differ per target platform:

Concern	AWS (AMI)	KVM (QCOW2)	Nutanix AHV
Disk format	Raw / VMDK → AMI	QCOW2	QCOW2 / VMDK
Boot mechanism	GRUB2 + PVGRUB2 or UEFI	GRUB2	GRUB2 + UEFI
Network driver	ENA (ena kernel module)	virtio-net	virtio-net
Storage driver	NVMe or xen-blkfront	virtio-blk / virtio-scsi	virtio-scsi
cloud-init datasource	ec2	NoCloud / ConfigDrive	ConfigDrive
Guest agent	AWS SSM / CloudWatch	qemu-guest-agent	Nutanix Guest Tools
Metadata service	169.254.169.254	None (seed ISO) or local	Nutanix AOS

A single pipeline needs to produce platform-specific artefacts from a single hardened source. The hardening doesn’t change. The drivers, datasources, and agents do.

Where this sits relative to CIS and NIST

The controls described above aren’t arbitrary. They map directly to published frameworks.

CIS Benchmark Level 1 covers controls with low operational impact and high security return — SSH configuration, kernel parameters, filesystem mount options, service reduction. Almost everything in the “what a hardened image looks like” section above is CIS Level 1.

CIS Benchmark Level 2 adds auditd configuration, PAM controls, additional filesystem protections, and more aggressive service disablement. It trades some operational flexibility for a significantly smaller attack surface.

NIST SP 800-53 CM-6 (Configuration Settings) directly requires that systems be configured to the most restrictive settings consistent with operational requirements. Baking hardening into the image is a stronger implementation of CM-6 than applying it post-deploy — because it’s guaranteed, auditable at build time, and consistent across every instance regardless of how it was launched.

NIST SP 800-53 SI-2 (Flaw Remediation) maps to your image patching cadence. An image rebuilt monthly against the latest package repositories satisfies SI-2 more completely than runtime patching alone, because it also eliminates packages you don’t need — packages that would need patching if they were present.

The full CIS and NIST control mapping will be covered in depth later in this series.

The build-time vs runtime hardening distinction

This is the most important concept in the entire post.

Hardening applied at runtime — via Ansible, Chef, cloud-init user-data, or a shell script — is conditional. It runs if the automation runs. It applies if nothing fails. It’s consistent only if every deployment goes through exactly the same path.

Hardening embedded in the image is unconditional. It cannot be skipped. It doesn’t depend on connectivity to an Ansible control node. It doesn’t require cloud-init to succeed. It cannot be accidentally omitted by a new team member who doesn’t know the runbook.

This distinction matters most at incident response time. When you’re investigating a compromised instance, the first question you want to answer confidently is: was this instance ever in a known-good state?

If your hardening is in the image: yes, from boot.
If your hardening is applied post-deploy: it depends on whether everything went right on that specific instance’s first boot.

What comes next

The practical question this raises: how do you build these images in a repeatable, multi-platform way, with CIS scanning integrated into the build pipeline?

Packer covers most of the builder layer. OpenSCAP provides the scanning. Kickstart, cloud-init, and Nutanix AHV-specific tooling fill the gaps. But the orchestration between these — producing a consistent hardened image for three different target platforms from a single source of truth — is where most teams hit friction.

The next post in this series covers the platform-specific differences between AWS, KVM, and Nutanix in depth: what actually needs to change per target when your security baseline is shared.

Next in the series: Cloud vs KVM vs Nutanix — why one image doesn’t fit all →

Questions or corrections? Open an issue or reach me on LinkedIn. If this was useful, the series index has the full roadmap.

EKS 1.33 Upgrade Blocker: Fixing Dead Nodes & NetworkManager on Rocky Linux

February 28, 2026February 18, 2026 by Vamshi Krishna Santhapuri

The EKS 1.33+ NetworkManager Trap: A Complete systemd-networkd Migration Guide for Rocky & Alma Linux

TL;DR:

The Blocker: Upgrading to EKS 1.33+ is breaking worker nodes, especially on free community distributions like Rocky Linux and AlmaLinux. Boot times are spiking past 6 minutes, and nodes are failing to get IPs.
The Root Cause: AWS is deprecating NetworkManager in favor of systemd-networkd. However, ripping out NetworkManager can leave stale VPC IPs in /etc/resolv.conf. Combined with the systemd-resolved stub listener (127.0.0.53) and a few configuration missteps, it causes a total internal DNS collapse where CoreDNS pods crash and burn.
The Subtext: AWS is pushing this modern networking standard hard. Subtly, this acts as a major drawback for Rocky/Alma AMIs, silently steering frustrated engineers toward Amazon Linux 2023 (AL2023) as the “easy” way out.
The “Super Hack”: Automate the clean removal of NetworkManager, bypass the DNS stub listener by symlinking /etc/resolv.conf directly to the systemd uplink, and enforce strict state validation during the AMI build.

If you’ve been in the DevOps and SRE space long enough, you know that vendor upgrades rarely go exactly as planned. But lately, if you are running enterprise Linux distributions like Rocky Linux or AlmaLinux on AWS EKS, you might have noticed the ground silently shifting beneath your feet.

With the push to EKS 1.33+, AWS is mandating a shift toward modern, cloud-native networking standards. Specifically, they are phasing out the legacy NetworkManager in favor of systemd-networkd.

While this makes sense on paper, the transition for community distributions has been incredibly painful. AWS support couldn’t resolve our issues, and my SRE team had practically given up, officially halting our EKS upgrade process. It’s hard not to notice that this massive, undocumented friction in Rocky Linux and AlmaLinux conveniently positions AWS’s own Amazon Linux 2023 (AL2023) as the path of least resistance.

I’m hoping the incredible maintainers at free distributions like Rocky Linux and AlmaLinux take note of this architectural shift. But until the official AMIs catch up, we have to fix it ourselves. Here is the exact breakdown of the cascading failure that brought our clusters to their knees, and the “super hack” script we used to fix it.

The Investigation: A Cascading SRE Failure

When our EKS 1.33+ worker nodes started booting with 6+ minute latencies or outright failing to join the cluster, I pulled apart our Rocky Linux AMIs to monitor the network startup sequence. What I found was a classic cascading failure of services, stale data, and human error.

Step 1: The Race Condition

Initially, the problem was a violent tug-of-war. NetworkManager was not correctly disabled by default, and cloud-init was still trying to invoke it. This conflicted directly with systemd-networkd, paralyzing the network stack during boot. To fix this, we initially disabled the NetworkManager service and removed it from cloud-init.

Step 2: The Stale Data Landmine

Here is where the trap snapped shut. Because NetworkManager was historically the primary service responsible for dynamically generating and updating /etc/resolv.conf, completely disabling it stopped that file from being updated.

When we baked the new AMI via Packer, /etc/resolv.conf was orphaned and preserved the old configuration—specifically, a stale .2 VPC IP address from the temporary subnet where the AMI build ran.

Step 3: The Human Element

We’ve all been there: during a stressful outage, wires get crossed. While troubleshooting the dead nodes, one of our SREs mistakenly stopped the systemd-resolved service entirely, thinking it was conflicting with something else.

Step 4: Total DNS Collapse

When the new AMI booted up and joined the EKS node group, the environment was a disaster zone:

NetworkManager was dead (intentional).
systemd-resolved was stopped (accidental).
/etc/resolv.conf contained a dead, stale IP address from a completely different subnet.

When kubelet started, it dutifully read the host’s broken /etc/resolv.conf and passed it up to CoreDNS. CoreDNS attempted to route traffic to the stale IP, failed, and started crash-looping. Internal DNS resolution (pod.namespace.svc.cluster.local) totally collapsed. The cluster was dead in the water.

Flowchart showing the cascading DNS failure in EKS worker nodes — The perfect storm: How stale data and disabled services led to a total CoreDNS collapse.

Architecture diagram of systemd-networkd and systemd-resolved D-Bus communication — The perfect storm: How stale data and disabled services led to a total CoreDNS collapse.

Introduction

The Resource Hierarchy — Not Just Org Structure

Member Types — Who Can Hold a Binding

Role Types — Choose the Right Granularity

Basic (Primitive) Roles — Don’t Use in Production

Predefined Roles — The Default Correct Choice

Custom Roles — When Predefined Is Still Too Broad

IAM Policy Bindings — How Access Is Actually Granted

Conditional Bindings — Time-Limited and Context-Scoped Access

Service Accounts — GCP’s Machine Identity

Service Account Keys — The Antipattern to Avoid

Service Account Impersonation — The Right Alternative to Keys

Workload Identity Federation — Credentials Eliminated

IAM Deny Policies — Org-Wide Guardrails

Framework Alignment

Key Takeaways

What’s Next

TL;DR

The Big Picture

Introduction

AWS IAM Identity Types: Users, Groups, and Roles Compared

IAM Users: Why Static Access Keys Are a Security Finding

IAM groups — useful but limited

IAM Roles: How STS Temporary Credentials Work

AWS IAM Policy Types: Managed, Inline, SCP, and Boundaries

Managed vs inline policies

Service Control Policies — org-wide guardrails

Permissions boundaries — identity-level ceilings

How AWS Cross-Account IAM Trust Works

AWS IAM Identity Center: Federated Human Access Without Static Keys

AWS IAM Patterns for Production: What Survives Scale

One role per service — never share

IAM escalation guardrail

Least privilege with tag conditions

⚠ Production Gotchas

Quick Reference

Framework Alignment

Key Takeaways

What’s Next

TL;DR

The Big Picture

Introduction

What Are IAM Permissions? The Atomic Unit of Access Control

What Are IAM Policies? Grouping Permissions with Conditions

AWS policy structure

AWS policy types — which to reach for

GCP policy bindings

Azure role definitions

What Are IAM Roles? The Layer That Scales Access Control

AWS roles — the identity that issues temporary credentials

GCP role types

Azure built-in and custom roles

RBAC vs ABAC: Which Access Control Model to Use

RBAC — Role-Based Access Control

ABAC — Attribute-Based Access Control

Conditions — when context determines access

⚠ Production Gotchas

Cross-Cloud Rosetta Stone

Quick Reference

Framework Alignment

Key Takeaways

What’s Next

TL;DR

The Big Picture

Introduction

How Authentication Works in Cloud IAM

The three factor types

How AWS authenticates

How GCP authenticates

How Azure authenticates

The credential failure modes that repeat everywhere

How Authorization Evaluates Every API Call

What the evaluation looks like

Policy evaluation chains by cloud

Why Confusing Authentication and Authorization Breaks Security

The token-as-authorization antipattern

The short-expiry principle

⚠ Production Gotchas

Authentication vs Authorization Audit Checklist

Quick Reference