examples
IPv6 Allowlist Gap examples
These examples show how IPv6 Allowlist Gap problems ship in real apps — and what fixes actually work when tested via direct API access.
Why IPv6 Allowlist Gap examples matter
Partial network policy creates false confidence and complicates incident investigations. Ensuring parity across address families makes access control deterministic and prevents quiet bypasses tied to infrastructure defaults.
Examples about IPv6 Allowlist Gap
| Example | Summary | URL |
|---|---|---|
| IPv6 Allowlist Gap: direct API bypass | A production-like scenario where IPv6 Allowlist Gap is exploited through direct requests that bypass frontend assumptions. | /examples/ipv6-allowlist-gap/direct-api-bypass-ipv6-allowlist-gap |
| IPv6 Allowlist Gap: migration drift regression | A release regression where migration drift silently reintroduces ipv6 allowlist gap after an earlier fix. | /examples/ipv6-allowlist-gap/migration-drift-ipv6-allowlist-gap |
Root cause → fix pattern analysis for IPv6 Allowlist Gap
Examples are most useful when you can translate them into a repeatable fix pattern. This table highlights the “why” behind each fix:
| Example | Root cause | Fix pattern | URL |
|---|---|---|---|
| IPv6 Allowlist Gap: direct API bypass | Security controls depended on frontend behavior and partial configuration checks. The underlying grants, schema exposure, or policy predicates still allowed direct access patterns that untrusted clients could reproduce. | The team removed direct sensitive paths from client reach, tightened role grants and policy predicates, and added endpoint-level verification tests that run in CI after each migration. | /examples/ipv6-allowlist-gap/direct-api-bypass-ipv6-allowlist-gap |
| IPv6 Allowlist Gap: migration drift regression | Migrations were treated as schema-only changes without mandatory security gates. No automated checks validated grants, exposed schema settings, or authorization behavior before deployment. | The team added migration-time policy/grant diff checks, blocked deploys on drift findings, and required post-deploy direct-access verification for each changed surface. | /examples/ipv6-allowlist-gap/migration-drift-ipv6-allowlist-gap |
How IPv6 Allowlist Gap failures typically happen
- Copying only legacy IPv4 CIDRs into restrictions while production traffic also uses IPv6 routes.
- Testing connectivity from one office network and assuming global enforcement is equivalent.
- Changing infrastructure providers without re-validating network policy behavior on both stacks.
Fix patterns that tend to work for IPv6 Allowlist Gap
Across these examples, the highest-leverage fixes share a theme: remove direct client access and make verification repeatable.
- Backend-only access for sensitive operations (server endpoints enforce authorization).
- Least-privilege grants: revoke broad privileges from anon/authenticated.
- Small, testable policies if you intentionally keep client access — avoid complex conditions.
- A verification step that proves direct access fails (not just that the UI hides data).
How to spot IPv6 Allowlist Gap in your own project (signals)
- A direct API call returns rows/files even when the UI is supposed to restrict them.
- RLS/policies exist, but access still succeeds (often because RLS is disabled or policies are too broad).
- Permissions depend on the client behaving “nicely” (UI checks) rather than the database enforcing access.
- After a migration, access behavior changes unexpectedly (drift).
How to use these examples to fix your own app
- Match the scenario to your table/bucket/function setup.
- Identify the root cause (not just the symptom).
- Apply the relevant template or conversion guide.
- Verify direct access fails for client credentials.
- Document the rule so it doesn’t regress.
Verification checklist for IPv6 Allowlist Gap fixes
- Reproduce the issue once using direct API access (anon/authenticated) so you know it’s real.
- Apply the fix pattern (backend-only access + least privilege) using a template.
- Repeat the same direct access call and confirm it now fails.
- Confirm the app still works via backend endpoints for authorized users.
- Re-scan after the fix and add a drift guard for the next migration.
Preventing IPv6 Allowlist Gap regressions (drift guard)
- Re-run the same direct access test after every migration that touches auth, policies, grants, Storage, or functions.
- Keep a short inventory of sensitive resources and treat them as server-only by default.
- Review new tables/buckets/functions in code review with an access-control checklist.
- If you intentionally allow client access, document the policy rationale and add tests for it.
Optional SQL checks for IPv6 Allowlist Gap (extra confidence)
If you like having a repeatable “proof”, add a small set of SQL checks to your process.
- Confirm RLS status for tables involved (enabled/forced where appropriate).
- List policies and read them as plain language: who can do what under what condition?
- Audit grants to anon/authenticated and PUBLIC for tables, views, and functions tied to this topic.
- If Storage/RPC is involved, explicitly audit bucket settings and EXECUTE grants.
These checks complement (not replace) the direct access tests shown in the examples.
Decision guide for IPv6 Allowlist Gap: template vs conversion vs integration
If you’re here because you found this topic in a scan, the fastest path depends on whether the fix is a small config change or a workflow change.
- Choose a template when you need a copy/paste change plus verification (tighten a policy/grant/bucket setting).
- Choose a conversion when you need to change an access model end-to-end (unsafe → backend-only) with example transformations.
- Choose an integration when the fix is a workflow pattern you’ll repeat (signed URLs, server-only RPC, backend endpoints).
If you’re unsure, start with the smallest template that removes direct client access, then add integrations for durability.
Evidence to keep after fixing IPv6 Allowlist Gap (makes reviews faster)
Teams often “fix” a topic but can’t prove it later. Save a few small artifacts so you can re-verify after migrations:
- The direct access request you used before the fix (and the expected denial after).
- A short boundary statement (who can access what, through which server endpoint).
- The change you applied (policy/grant/bucket setting/EXECUTE revoke) and why.
- The drift guard you’ll run after migrations (scan, checklist query, or release checklist item).
Related pages
- Glossary: IPv6 Allowlist Gap →
/glossary/ipv6-allowlist-gap - Template: Lock down a public table (backend-only access) →
/templates/access-control/lock-down-public-table
What to do after you fix one example (so it stays fixed)
One fixed example is great — but the real win is preventing drift.
- Write a one-sentence boundary statement (who can access what, through which server path).
- Keep the one direct access test you used before the fix (and expect it to fail after).
- Re-run the same test after migrations that touch policies, grants, buckets, or functions.
If you can re-run the test and it still fails, you’ve turned a one-time fix into a durable control.
FAQ
What’s the fastest fix pattern when IPv6 Allowlist Gap shows up in a scan?
Prefer backend-only access and remove direct client privileges. Then add verification checks that prove direct access fails.
Can I fix IPv6 Allowlist Gap with policies alone?
Sometimes, but it’s easy to get subtly wrong. Use these examples to learn the failure modes, and verify with direct API tests.
How do I choose between examples, templates, and conversions?
Examples explain the pattern, templates show concrete implementation, and conversions describe the whole transformation from unsafe to safe.
Next step
Want to know if your project matches any of these scenarios? Run a Mockly scan and compare your findings to the examples here.