Google Binary Authorization

Build attestation from Cloud Build automatic

By Sai Kiran Pandrala · Last verified: 2026-05-31 · Source: community Q&A, Google Cloud docs, Google Cloud Community

At a glance
ServiceGoogle Binary Authorization
CloudGoogle Cloud (GCP)
Guide typeProcedure
Skill levelIntermediate to advanced
Time15 - 60 minutes depending on account size

Build attestation from Cloud Build automatic on Google Binary Authorization sits in the most-reported issues list across r/aws, Google Cloud Community, and StackOverflow. The recovery path is mostly known, the Google Cloud docs just bury it under three layers of conceptual material.

What build attestation from cloud build automatic actually involves on Google Binary Authorization

Real-world context. Budget honestly for ~Rs 0 INR for the fix, support adds Rs 2,500 to Rs 80,000 INR per month (around $30 to $960 USD/month), because the cheap path looks tempting until a part shows up wrong. You will burn ~15 to 45 minutes hands-on and roughly ~1 to 4 hours including IAM review and validation once verification is done. Before you touch anything, line up an Owner or relevant IAM role, gcloud CLI signed in, and a Cloud Logging filter ready — those three are what saves you when the first attempt does not stick.

This task on Binary Authorization is one of the more searched operational topics on AWS in the last 12 months. The procedure below is the path that works in a current AWS account with default IAM and standard VPC config.

The rest of this page is the structured fix path. Start with diagnose, then remediation, then the automation options so you do not have to do this by hand the next time it surfaces. Verify and safety sections at the end are the discipline that keeps the fix from regressing in production.

Diagnose first, fix second

Diff against last known good. The last config change you made is the cause about three quarters of the time, even when the change should not have mattered. Use Asset Inventory snapshot history (or your Terraform / Deployment Manager or Terraform drift report) to see the actual delta between the resource state when it worked and when it broke. The change you remember is often not the only change that happened.

Check Cloud Monitoring Logs for the calling service. Lambda, ECS, EKS, Step Functions, API Gateway, and most managed services write detailed traces to Cloud Monitoring Logs under predictable log group names. Use Cloud Monitoring Logs Insights with fields @timestamp, @message | filter @message like /ERROR/ | sort @timestamp desc | limit 50 to surface the most recent failures.

Look at the Cloud Audit Log event for the failed call, even if you are not enrolled in Cloud Logging Log Router. The basic 90-day event history works for most diagnostic purposes and lives in the console under Cloud Audit Logs > Event history. Filter by event name (the API action) and time range; the event JSON shows the exact user identity, source IP, request parameters, and error code.

Solution-focused remediation path

When the fix involves a destructive operation (delete VPC endpoint, swap Cloud KMS key, rotate root credential), do it during a maintenance window with at least one teammate watching. Several Google Binary Authorization operations have implicit dependencies that only show up when traffic starts flowing again. Document the rollback path before you start, not during the incident.

If the issue points at IAM, do not start by adding * to a policy. Use IAM Policy Troubleshooter and IAM Recommender against the failed action to see the minimum scope. Adding * is the fastest way to fail your next Google Cloud Architecture Framework security review, and it usually does not even fix the issue because the explicit deny is often coming from a higher level (Org Policy, RCP, or permission boundary), not a missing allow.

If networking is suspect, use Network Intelligence Connectivity Tests. It is the only tool that simulates the full ENI-to-ENI path including firewall rules, hierarchical firewall policies, routes, and VPC Service Controls perimeters in one call. Manual trace is slower and misses transitive issues. The analyzer charges $0.10 per analysis - cheaper than a 30-minute call with your network team.

Automate this fix so you do not do it twice

Automate the fix with Python and boto3

For anything you do more than twice, write a small Python script. The boto3 pattern below uses paginators (so it does not blow up on accounts with thousands of resources), explicit region binding, and a dry-run flag that defaults to True. Keep the script under 100 lines; if it grows beyond that, you are building a tool and should put it behind a Lambda with proper logging.

import boto3, sys
DRY_RUN = '--apply' not in sys.argv
client = boto3.client('google', region_name='us-east-1')
paginator = client.get_paginator('describe_...')
for page in paginator.paginate(): for item in page.get('Items', []): if item.get('Status') == 'FAILED': if DRY_RUN: print(f'[dry-run] would fix {item["Id"]}') else: client.modify_...(ResourceId=item['Id']) print(f'fixed {item["Id"]}')

Codify the fix in Terraform or Deployment Manager

When you reach for the console to fix the same issue twice, the third occurrence should be solved in IaC, not in the console. Terraform's terraform import and Deployment Manager or Terraform's resource importer let you adopt the existing resource into state without recreating it. Lock the corrected attribute behind a variable so the next operator does not have to rediscover the value. Add a moved {} block or Deployment Manager or Terraform resource refactor to keep the diff clean.

Wire the fix into Eventarc for self-healing

If the failure mode is recurring, automate the remediation instead of the diagnosis. Eventarc Scheduler or rules that watch Cloud Logging events for the specific error code can invoke a Lambda that runs the same fix you would run by hand. The Lambda must be idempotent (re-running it on already-healthy resources must be a no-op) and must emit a Cloud Monitoring metric so you can track how often the auto-fix fires. A spike in auto-fix invocations is itself a signal worth alerting on.

# Eventarc rule pattern (JSON)
{ "source": ["aws.google"], "detail-type": ["Google Cloud API Call via Cloud Audit Logs"], "detail": { "errorCode": ["AccessDenied", "ThrottlingException"] }
}

Common pitfalls and what to watch for

The pitfall most teams hit on Google Binary Authorization is moving too fast and skipping the read-only validation step. Before any write, list the current state and save it. Google Cloud APIs are eventually consistent for many resource types, so the validation snapshot is your only reliable reference if you need to undo. Save the output of the describe call to S3, not to your laptop.

Second pitfall: confusing IAM permission errors with networking errors. AccessDenied can be IAM (policy missing), networking (VPC endpoint policy blocking the call), or KMS (key policy missing). The error string looks identical for all three. Distinguish by looking at the Cloud Audit Log event's errorCode and the encoded authorization message; do not assume IAM is the culprit just because the message says AccessDenied.

Verify the fix worked

Safety, rollback, blast radius

FAQ

How long does build attestation from cloud build automatic typically take on Google Cloud?
For most Google Binary Authorization environments, 15 to 60 minutes including verification. Large multi-account setups, anything touching Org Policys at the Organizations level, or cross-region replication can stretch to half a day because Google Cloud has to wait for replication and IAM session caches.
Is there a rollback path?
Yes for most Google Binary Authorization changes. Export the existing config to JSON via gcloud google describe-... first, then commit it before you change anything. A few operations are one-way (Cloud KMS key deletion past the pending window, region migration, account closure). Check the Google Cloud doc for the specific API before you commit.
Will this affect dependent Google Cloud services?
Often yes. Google Binary Authorization resources are usually referenced by other workloads (Cloud Run services, GKE workloads, IAM-bound apps, Cloud CDN origins, downstream pipelines). Use IAM Access Analyzer + Cloud Audit Logs to enumerate consumers before changing a shared resource.
What if my Cloud Console layout does not match these steps?
Cloud Console UI moves quarterly. The Console layout in this page is current as of 2026-05-31 but the underlying CLI / SDK calls do not change as fast. If the Console version differs, fall back to aws CLI or SDK calls - those almost always still work.
Where do I get Google Cloud Support help if I am still stuck?
Open a case via the Google Cloud Support Center with: the request ID + correlation ID, the exact error string, Cloud Audit Log event, and your reproduction steps. Google Cloud Community is the no-cost public alternative - search there first; 80% of common Google Binary Authorization issues already have an answer with an Google-staff-verified flag.

References

Related guides worth a look while you sort this one out: