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DNS Tool
Engineer's DNS Intelligence Report
Generated 2026-04-20T00:08:49Z
Duration 2.6s
Version v26.48.08
Integrity de4a56eaef265550383c7efb89f0c80cf3167f864c8d9418ae851d7adadfd63662072467ac627a9e42f541b1c16d2a229021cef5ad0509096155e51f01d70d9f
Subject Domain
932.moe

Engineer's DNS Intelligence Report

932.moe
2026-04-20T00:08:49Z · 2.6s ·v26.48.08 · SHA-3-512: de4a✱✱✱✱ Verify ·Cross-Referenced
Executive Topology
Recon Mode Snapshot Re-analyze New Domain
Footprint
DNS Security & Trust Posture
Risk Level: Low Risk
6 protocols configured, 3 not configured Domain appears to be in deliberate DMARC deployment phase — quarantine fully enforced with reporting, consider upgrading to reject Why we go beyond letter grades
1 recommendation
Currentness Excellent TTL Compliance Excellent Completeness Degraded Source Credibility Excellent TTL Relevance Degraded
ICuAE Details
DNS data shows some aging or gaps — consider re-scanning for critical decisions

The following DNS record TTLs deviate from recommended values. Incorrect TTLs can cause caching issues, slow propagation, or unnecessary DNS traffic.

Record Type Observed TTL Typical TTL Severity Context
A 5 minutes (300s) 1 hour (3600s) high A TTL is below typical — observed 5 minutes (300s), typical value is 1 hour (3600s). Short TTLs increase DNS query volume but enable faster propagation. If you are preparing for a migration or need rapid failover, this may be intentional (RFC 1035 §3.2.1). For steady-state production, consider 3600 seconds per NIST SP 800-53 SI-7 relevance guidance. Use the TTL Tuner for profile-specific recommendations.
Provider Note: This TTL (5 minutes (300s)) matches Cloudflare's fixed proxied-record TTL. If this record is proxied (orange cloud), the TTL is enforced by Cloudflare and cannot be changed. Disable proxying (gray cloud) to regain TTL control, at the cost of losing Cloudflare's DDoS protection and CDN.
MX 5 minutes (300s) 1 hour (3600s) high MX TTL is below typical — observed 5 minutes (300s), typical value is 1 hour (3600s). Short TTLs increase DNS query volume but enable faster propagation. If you are preparing for a migration or need rapid failover, this may be intentional (RFC 1035 §3.2.1). For steady-state production, consider 3600 seconds per NIST SP 800-53 SI-7 relevance guidance. Use the TTL Tuner for profile-specific recommendations.
TXT 5 minutes (300s) 1 hour (3600s) high TXT TTL is below typical — observed 5 minutes (300s), typical value is 1 hour (3600s). Short TTLs increase DNS query volume but enable faster propagation. If you are preparing for a migration or need rapid failover, this may be intentional (RFC 1035 §3.2.1). For steady-state production, consider 3600 seconds per NIST SP 800-53 SI-7 relevance guidance. Use the TTL Tuner for profile-specific recommendations.
AAAA 5 minutes (300s) 1 hour (3600s) high AAAA TTL is below typical — observed 5 minutes (300s), typical value is 1 hour (3600s). Short TTLs increase DNS query volume but enable faster propagation. If you are preparing for a migration or need rapid failover, this may be intentional (RFC 1035 §3.2.1). For steady-state production, consider 3600 seconds per NIST SP 800-53 SI-7 relevance guidance. Use the TTL Tuner for profile-specific recommendations.
Provider Note: This TTL (5 minutes (300s)) matches Cloudflare's fixed proxied-record TTL. If this record is proxied (orange cloud), the TTL is enforced by Cloudflare and cannot be changed. Disable proxying (gray cloud) to regain TTL control, at the cost of losing Cloudflare's DDoS protection and CDN.
NS 21007s 1 day (86400s) medium NS TTL is below typical — observed 21007s, typical value is 1 day (86400s). Short TTLs increase DNS query volume but enable faster propagation. If you are preparing for a migration or need rapid failover, this may be intentional (RFC 1035 §3.2.1). For steady-state production, consider 86400 seconds per NIST SP 800-53 SI-7 relevance guidance. Use the TTL Tuner for profile-specific recommendations.
SOA 1207s 1 hour (3600s) medium SOA TTL is below typical — observed 1207s, typical value is 1 hour (3600s). Short TTLs increase DNS query volume but enable faster propagation. If you are preparing for a migration or need rapid failover, this may be intentional (RFC 1035 §3.2.1). For steady-state production, consider 3600 seconds per NIST SP 800-53 SI-7 relevance guidance. Use the TTL Tuner for profile-specific recommendations.
Provider Note: Cloudflare manages SOA timers automatically. Free/Pro/Business plans cannot modify SOA values. Observed TTL (1207s) is set by Cloudflare, not the zone administrator. See RFC 1912 §2.2 for recommended SOA timer values.

Big Picture Questions

  • How often do you actually change this record? If it hasn’t changed in months, a short TTL is generating unnecessary DNS queries without any benefit.
  • Are you preparing for a migration or IP change? Short TTLs make sense temporarily — but should be raised back to 1 hour (3600s) once the change is complete.
  • Every DNS lookup adds 20–150ms of latency. With a 60s TTL, returning visitors trigger a fresh lookup every minute. With 3600s, they get cached responses for an hour — faster page loads, no extra infrastructure needed.
  • Google runs A records at ~30s because they operate a global anycast network and need to steer traffic dynamically. For a typical website without that infrastructure, copying those TTLs increases query volume with zero upside.
Tune TTL for 932.moe
Reference: NIST SP 800-53 SI-7 (Information Integrity) · RFC 8767 (Serve Stale) · RFC 1035 §3.2.1 (TTL semantics) DNS provider detected: Cloudflare — provider-specific RFC compliance notes are shown inline above where applicable.
Primary NS dane.ns.cloudflare.com
Serial 2401858659
Admin dns.cloudflare.com
Provider Cloudflare
Timer Value RFC 1912 Range
Refresh10000s1,200–43,200s (20 min – 12 hrs)
Retry2400sFraction of Refresh
Expire604800s1,209,600–2,419,200s (14–28 days)
Minimum (Neg. Cache)1800s300–86,400s (5 min – 1 day)
Expire: SOA Expire is 7 days (604800s). RFC 1912 §2.2 recommends 1,209,600–2,419,200 seconds (14–28 days). If the primary nameserver becomes unreachable, secondary nameservers will stop serving this zone after only 7 days (604800s). Cloudflare's anycast architecture reduces the practical risk, but this value departs from the RFC recommendation.
RFC 1912 §2.2

Independent RFC compliance assessment for Cloudflare. Each finding cites the specific RFC section and reports what the engineering community consensus is. We report honestly — if a provider deviates from standards, we explain what they did differently and what the RFCs actually say.

SOA Expire below RFC 1912 recommendation RFC 1912 §2.2

Cloudflare sets SOA Expire to 604,800 seconds (7 days). RFC 1912 §2.2 recommends 1,209,600–2,419,200 seconds (14–28 days). This means secondary nameservers stop serving the zone sooner if the primary becomes unreachable. Cloudflare's position is that their anycast architecture makes traditional zone transfer semantics less relevant. SOA timers are not editable on Free, Pro, or Business plans.

Below RFC recommendation
Proxied record TTLs fixed at 300s RFC 2181 §5.2

Cloudflare overrides the zone administrator's TTL to 300 seconds for all proxied (orange-cloud) records. RFC 2181 §5.2 requires TTL uniformity within an RRset but does not mandate a specific value. As the authoritative server, Cloudflare is technically within its rights, but the administrator loses TTL control. This can affect ACME DNS-01 challenges and automation workflows that depend on rapid propagation.

Technically compliant, but overrides administrator intent
Non-standard SOA serial format RFC 1912 §2.2

RFC 1912 recommends YYYYMMDDNN format for SOA serial numbers (e.g., 2026022501). Cloudflare uses a proprietary serial number format that does not encode the date. RFC 1035 only requires the serial to increment on changes, so this is compliant with the mandatory standard but breaks the convention relied on by monitoring tools.

Compliant with RFC 1035, deviates from RFC 1912 convention
Negative cache TTL delays new records RFC 2308 §5

Cloudflare's SOA MINIMUM (negative cache TTL) is 1,800–3,600 seconds (30–60 minutes). This controls how long resolvers cache NXDOMAIN responses. Newly created DNS records — including ACME DNS-01 challenge TXT records for Let's Encrypt — may be invisible for up to 1 hour even after creation. This causes certificate issuance failures for automation tools like cert-manager and Traefik. Workaround: pre-create placeholder records before they're needed. This is RFC-compliant but aggressive compared to the 300–900 seconds common at other providers.

RFC-compliant, but causes real-world automation failures
Historical RFC 2181 §5.2 violation: TTL mismatch in CNAME RRsets RFC 2181 §5.2

In February 2022, Cloudflare's resolver (1.1.1.1) returned CNAME responses with mismatched TTLs within the same RRset — including cases where one TTL was zero and another was non-zero. RFC 2181 §5.2 explicitly states: 'the TTLs of all RRs in an RRSet must be the same.' systemd-resolved (used by Arch Linux, Ubuntu, Fedora, and most modern Linux distributions) correctly rejected these responses per the RFC, causing widespread DNS resolution failures. Cloudflare acknowledged the issue and it appears to have been fixed, but it demonstrated that Cloudflare's DNS infrastructure can deviate from RFC requirements in ways that break compliant resolver implementations.

Was a documented RFC violation — appears resolved
This assessment is based on RFC specifications, provider documentation, and documented incidents from DNS engineering communities. DNS Tool does not have a commercial relationship with any provider listed.
Email Spoofing
Protected
Brand Impersonation
Not Setup
DNS Tampering
Protected
Certificate Control
Configured
Recommended
Upgrade DMARC policy from quarantine to reject (p=reject) for maximum spoofing protection
Configured
SPF, DMARC (quarantine, 100%), DKIM, DANE, DNSSEC, CAA
Not Configured
MTA-STS, TLS-RPT, BIMI
Priority Actions Achievable posture: Secure
Medium Upgrade DMARC to Reject

Your DMARC policy is set to quarantine. Upgrade to p=reject for maximum protection — reject instructs receivers to discard spoofed mail entirely rather than quarantining it.

A reject policy provides the strongest protection against domain spoofing.
TypeTXT
Host_dmarc.932.moe (update existing DMARC record)
Valuev=DMARC1; p=reject; rua=mailto:dmarc-reports@932.moe
RFC 7489 §6.3
Low Add TLS-RPT Reporting

Your domain has DNSSEC + DANE — the strongest email transport security available. TLS-RPT (TLS Reporting) sends you reports about TLS connection failures when other servers try to deliver mail to your domain.

TLS-RPT sends you reports about TLS connection failures to your mail servers.
TypeTXT
Host_smtp._tls.932.moe (SMTP TLS reporting record)
Valuev=TLSRPTv1; rua=mailto:tls-reports@932.moe
RFC 8460
Low Deploy MTA-STS

MTA-STS enforces TLS encryption for inbound mail delivery, preventing downgrade attacks on your mail transport.

MTA-STS tells sending servers to require TLS when delivering mail to your domain.
TypeTXT
Host_mta-sts.932.moe (MTA-STS policy record)
Valuev=STSv1; id=932.moe
RFC 8461
Open Remediation Workspace — Copy-Paste Ready Records
Registrar (RDAP) OBSERVED LIVE
NameSilo, LLC
Where domain was purchased
Email Service Provider INFERRED
Cloudflare Email
Moderately Protected
Web Hosting
Unknown
Where website is hosted
DNS Hosting OBSERVED
Cloudflare
Where DNS records are edited
Email Security Methodology Can this domain be impersonated by email? Unlikely SPF and DMARC quarantine policy enforced

SPF Record RFC 7208 §4 Consistent

Does this domain declare who may send email on its behalf? Yes
Success ~all 2/10 lookups

SPF valid with industry-standard soft fail (~all), 2/10 lookups

v=spf1 include:spf1.dm.aliyun.com include:_spf.mx.cloudflare.net ~all
RFC 7208 Conformant — This SPF record conforms to the syntax and semantics defined in RFC 7208 §4.
RFC Failure Mode: Unlike DMARC (where unknown tags are silently ignored per RFC 7489 §6.3), SPF with unrecognized mechanisms produces a PermError per RFC 7208 §4.6 — the record fails loudly rather than silently.
Related CVEs: CVE-2024-7208 (multi-tenant domain spoofing), CVE-2024-7209 (shared SPF exploitation), CVE-2023-51764 (SMTP smuggling bypasses SPF)
~all is the industry standard. Google, Apple, and most providers default to soft fail. CISA (BOD 18-01) and RFC 7489 confirm that DMARC policy — not SPF alone — is the primary enforcement control. Using ~all allows DKIM to be evaluated before a DMARC decision is made. This domain uses ~all + DMARC quarantine — good protection. Moving to p=reject would achieve the strongest stance.

DMARC Policy RFC 7489 §6.3 Consistent

Are spoofed emails rejected or quarantined? Quarantined, not rejected
Success p=quarantine

DMARC policy quarantine (100%) - good protection

v=DMARC1;p=quarantine;rua=mailto:e562106005c14c55ba7023150c409399@dmarc-reports.cloudflare.net
Alignment: SPF relaxed DKIM relaxed
No np= tag (DMARCbis) — non-existent subdomains inherit p= policy but adding np=reject provides explicit protection against subdomain spoofing
No forensic reporting (ruf) tag — this is correct. The absence of ruf= is not a gap. RFC 7489 §7.3 warns that forensic reports can expose PII (full message headers or bodies). Google, Microsoft, and Yahoo do not honour ruf= requests regardless. The DMARCbis draft (draft-ietf-dmarc-dmarcbis) has formally removed ruf= from the specification, confirming its deprecation. Omitting ruf= is the recommended modern practice. RFC 7489 §7.3 — Forensic Reports
Advanced cryptographic posture detected. Domain appears to be in deliberate DMARC deployment phase — quarantine fully enforced with reporting, consider upgrading to reject
RFC 7489 Present — DMARC record published per RFC 7489 §6.3.
Monitoring Posture Note: Quarantine sequesters authentication failures while preserving full DMARC forensic telemetry (RFC 7489 §7). Some organizations maintain quarantine rather than reject as a deliberate monitoring strategy — failed messages are processed and reported but sequestered from the inbox. See NIST SP 800-177 Rev. 1 for enforcement tradeoffs.
DMARCbis (Pending): draft-ietf-dmarc-dmarcbis will elevate DMARC to Standards Track, obsolete RFC 7489, replace pct= with t= (testing flag), add np= (non-existent subdomain policy), and mandate DNS tree walk for policy discovery instead of the Public Suffix List.
Related CVEs: CVE-2024-49040 (Exchange sender spoofing), CVE-2024-7208 (multi-tenant DMARC bypass)

DKIM Records RFC 6376 §3.6 Consistent

Are outbound emails cryptographically signed? Yes — verified
Found 2048-bit

Found DKIM for 2 selector(s) with strong keys (2048-bit)

dkim._domainkey Cloudflare Email (inferred) 2048-bit Adequate
v=DKIM1; k=rsa; p=MIIBIjANBgkqhkiG9w0BAQEFAAOCAQ8AMIIBCgKCAQEAwUg0OKgkJ+7PGh5eBXmSSquQErVx3bejzp2jTjn6EP0rof6sDxPBFhqQyKCLHDLs9gxJ4QyVFxXvhZ1CqMdELS8zvCA2gnYCGZmPWN61ELg+f7ZVk/45UIRYt+dp3TcI0LZoOAbe1kZtMYjeI9XXkLiMd+sFW/ym9xLFziWPeLu67WeCqBcdW0RxV5u95Ksw0MxsvC3IDE/ADL/AocxaLJ758iKDlrnkiYkLhxmCxZu5E3qZxtg8C9tbM8bieBNKqp0Wziu0RUlexeQqWBXSV5KuNqGvD31qVs3gQlzqArHWjeVrQr/WNtecshmE/5Sbt/T61BGRZeoF334yhcB7zwIDAQAB
mail._domainkey Cloudflare Email (inferred) 2048-bit Adequate
v=DKIM1; k=rsa; p=MIIBIjANBgkqhkiG9w0BAQEFAAOCAQ8AMIIBCgKCAQEAwUg0OKgkJ+7PGh5eBXmSSquQErVx3bejzp2jTjn6EP0rof6sDxPBFhqQyKCLHDLs9gxJ4QyVFxXvhZ1CqMdELS8zvCA2gnYCGZmPWN61ELg+f7ZVk/45UIRYt+dp3TcI0LZoOAbe1kZtMYjeI9XXkLiMd+sFW/ym9xLFziWPeLu67WeCqBcdW0RxV5u95Ksw0MxsvC3IDE/ADL/AocxaLJ758iKDlrnkiYkLhxmCxZu5E3qZxtg8C9tbM8bieBNKqp0Wziu0RUlexeQqWBXSV5KuNqGvD31qVs3gQlzqArHWjeVrQr/WNtecshmE/5Sbt/T61BGRZeoF334yhcB7zwIDAQAB
RFC 6376 Conformant — DKIM keys and signatures conform to RFC 6376 §3.6 (Internet Standard).
Known Vulnerabilities: DKIM l= tag body length vulnerability (attacker appends unsigned content to signed mail), weak key exploitation (keys below 1024-bit are cryptographically breakable per RFC 6376 §3.3.3), DKIM replay attacks (re-sending legitimately signed messages at scale)

MTA-STS RFC 8461 §3 Consistent

Can attackers downgrade SMTP to intercept mail? Not prevented
Warning

No MTA-STS record found

MTA-STS policy enforcement is evaluated in Mail Transport Security below.

TLS-RPT RFC 8460 §3 Consistent

Will failures in TLS delivery be reported? No reporting
Warning

No TLS-RPT record found

DMARC External Reporting Authorization RFC 7489 §7.1

Are external report receivers authorized? Yes — all authorized
Success

All 1 external reporting domains properly authorized

External Domain Authorization Auth Record
dmarc-reports.cloudflare.net Authorized v=DMARC1;
DANE / TLSA Consistent Recon Methodology Can mail servers establish identity without a public CA? Yes
RFC 7672 §3 RFC 6698 §2 3/3 MX

DANE configured — TLSA records found for all 3 MX hosts

MX Host Usage Selector Match Certificate Data
route1.mx.cloudflare.net 2 DANE-TA (Trust anchor) Public key only (SubjectPublicKeyInfo) SHA-256 59e738e674221702af1edb87c5200c1a4b75f64fae3d2c3d265124c61bd83c79
route1.mx.cloudflare.net 3 DANE-EE (Domain-issued certificate) Public key only (SubjectPublicKeyInfo) SHA-256 0f0c6c164a36f97e7b4c5a5b69d6f4f239d422fc3ec2592072ecfab8c271c452
route1.mx.cloudflare.net 3 DANE-EE (Domain-issued certificate) Public key only (SubjectPublicKeyInfo) SHA-256 9be5b7d47f9eff930c11eb04d27cae6bddd0d375cdfbccf68b26efe676d1d0db
route2.mx.cloudflare.net 2 DANE-TA (Trust anchor) Public key only (SubjectPublicKeyInfo) SHA-256 59e738e674221702af1edb87c5200c1a4b75f64fae3d2c3d265124c61bd83c79
route2.mx.cloudflare.net 3 DANE-EE (Domain-issued certificate) Public key only (SubjectPublicKeyInfo) SHA-256 9be5b7d47f9eff930c11eb04d27cae6bddd0d375cdfbccf68b26efe676d1d0db
route2.mx.cloudflare.net 3 DANE-EE (Domain-issued certificate) Public key only (SubjectPublicKeyInfo) SHA-256 0f0c6c164a36f97e7b4c5a5b69d6f4f239d422fc3ec2592072ecfab8c271c452
route3.mx.cloudflare.net 3 DANE-EE (Domain-issued certificate) Public key only (SubjectPublicKeyInfo) SHA-256 0f0c6c164a36f97e7b4c5a5b69d6f4f239d422fc3ec2592072ecfab8c271c452
route3.mx.cloudflare.net 3 DANE-EE (Domain-issued certificate) Public key only (SubjectPublicKeyInfo) SHA-256 9be5b7d47f9eff930c11eb04d27cae6bddd0d375cdfbccf68b26efe676d1d0db
route3.mx.cloudflare.net 2 DANE-TA (Trust anchor) Public key only (SubjectPublicKeyInfo) SHA-256 59e738e674221702af1edb87c5200c1a4b75f64fae3d2c3d265124c61bd83c79
Email Transport Security

Two mechanisms protect email in transit. DANE is the primary standard; MTA-STS is the alternative for domains that cannot deploy DNSSEC:

  • DNSSEC + DANE (RFC 7672) — Cryptographic chain of trust from DNS root to mail server certificate. Eliminates reliance on certificate authorities. No trust-on-first-use weakness. Requires DNSSEC.
  • MTA-STS (RFC 8461) — HTTPS-based policy requiring TLS for mail delivery. Works without DNSSEC but relies on CA trust and is vulnerable on first use (§10). Created for domains where “deploying DNSSEC is undesirable or impractical” (§2).
This domain uses DNSSEC + DANE — the strongest cryptographic transport security. DANE binds TLS certificates to DNSSEC-signed DNS records, creating a verifiable chain of trust from root to mail server (RFC 7672 §1.3). MTA-STS could complement this for senders that don't validate DNSSEC, but DANE alone provides the highest level of protection available.

Industry trend: Microsoft Exchange Online enforces inbound DANE with DNSSEC (GA October 2024), and providers like Proton Mail and Fastmail also support DANE. Google Workspace does not support DANE and relies on MTA-STS. Both mechanisms coexist because DANE is backward-compatible — senders skip the check if the domain isn't DNSSEC-signed (RFC 7672 §1.3).

Brand Security Can this brand be convincingly faked? Likely DMARC quarantine flags but does not reject spoofed mail (RFC 7489 §6.3), and no BIMI brand verification — lookalike domains display identically in inboxes; CAA restricts certificate issuance (RFC 8659 §4) but visual brand faking remains open

BIMI BIMI Spec Consistent Warning

Is the brand identity verified and displayed in inboxes? No

No BIMI record found

CAA RFC 8659 §4 Consistent Success

Does this domain restrict who can issue TLS certificates? Yes

CAA configured - only Let's Encrypt, cansignhttpexchanges=yes, ssl.com, DigiCert, Sectigo can issue certificates (wildcard issuance: Sectigo, Let's Encrypt, cansignhttpexchanges=yes, ssl.com, DigiCert per RFC 8659 §4.3)

Authorized CAs: Let's Encrypt cansignhttpexchanges=yes ssl.com DigiCert Sectigo
0 issuewild "ssl.com"
0 issuewild "digicert.com; cansignhttpexchanges=yes"
0 issuewild "comodoca.com"
0 issue "digicert.com; cansignhttpexchanges=yes"
0 issue "comodoca.com"
0 issuewild "letsencrypt.org"
0 issue "letsencrypt.org"
0 issue "pki.goog; cansignhttpexchanges=yes"
0 issuewild "pki.goog; cansignhttpexchanges=yes"
0 issue "ssl.com"
Since September 2025, all public CAs must verify domain control from multiple geographic locations (Multi-Perspective Issuance Corroboration, CA/B Forum Ballot SC-067). CAA records are now checked from multiple network perspectives before certificate issuance.
Vulnerability Disclosure Policy (security.txt) Is there a verified way to report security issues? No RFC 9116

No security.txt found

A security.txt file at /.well-known/security.txt provides security researchers with a standardized way to report vulnerabilities. See securitytxt.org for a generator.
AI Surface Scanner Beta Is this domain discoverable by AI — and protected from abuse? No

No AI governance measures detected

llms.txt llmstxt.org
Is this domain publishing AI-readable brand context? No
No llms.txt found
No llms-full.txt found
AI Crawler Governance (robots.txt) RFC 9309 IETF Draft
Are AI crawlers explicitly allowed or blocked? Not blocked
No AI crawler blocking observed — no blocking directives found in robots.txt View robots.txt
Content-Usage Directive IETF Draft
Does the site express AI content-usage preferences? Not Configured
No Content-Usage directive detected. The IETF AI Preferences working group is developing a Content-Usage: directive for robots.txt that lets site owners declare whether their content may be used for AI training and inference. This is an active draft, not yet a ratified standard.
Example: Add Content-Usage: ai=no to robots.txt to deny AI training, or Content-Usage: ai=allow to explicitly permit it. Without this directive, AI crawler behavior depends on individual crawler policies and User-agent rules.
AI Recommendation Poisoning
Is this site trying to manipulate AI recommendations? No
No AI recommendation poisoning indicators found
Hidden Prompt Artifacts
Is hidden prompt-injection text present in the source? No
No hidden prompt-like artifacts detected
Evidence Log (1 item)
TypeDetailSeverityConfidence
robots_txt_no_ai_blocks robots.txt found but no AI-specific blocking directives low Observed
Public Exposure Checks Are sensitive files or secrets exposed? No

No exposed secrets detected in public page source — same-origin, non-intrusive scan of publicly visible page source and scripts.

No exposed secrets, API keys, or credentials were detected in publicly accessible page source or scripts.
Sources scanned (2)
  • https://932.moe/
  • https://932.moe/cdn-cgi/scripts/5c5dd728/cloudflare-static/email-decode.min.js
What type of scan is this?

This is OSINT (Open Source Intelligence) collection — we check the same publicly accessible URLs that any web browser could visit. No authentication is bypassed, no ports are probed, no vulnerabilities are exploited.

Is this a PCI compliance scan? No. PCI DSS requires scans performed by an Approved Scanning Vendor (ASV) certified by the PCI Security Standards Council. DNS Tool is not an ASV. If you need PCI compliance scanning, engage a certified ASV such as Qualys, Tenable, or Trustwave.

Is this a penetration test? No. Penetration testing involves active exploitation attempts against systems with authorization. Our checks are passive observation of publicly accessible resources — the same methodology used by Shodan, Mozilla Observatory, and other OSINT platforms.

DNS Server Security Hardened

No DNS server misconfigurations found on dane.ns.cloudflare.com — Nmap NSE probes for zone transfer (AXFR), open recursion (RFC 5358), nameserver identity disclosure, and DNS cache snooping.

Check Result Detail
Zone Transfer (AXFR) Denied Zone transfer denied (correct configuration)
Open Recursion Disabled Recursion disabled (correct configuration)
Nameserver Identity Hidden No nameserver identity information disclosed
Cache Snooping Protected Cache snooping not possible (correct configuration)

Tested nameservers: dane.ns.cloudflare.com, melany.ns.cloudflare.com

Delegation Consistency 1 Issue

Delegation consistency: 1 issue(s) found — Parent/child NS delegation alignment: DS↔DNSKEY, glue records, TTL drift, SOA serial sync.

Findings:
  • Could not retrieve NS TTL from parent zone

DS ↔ DNSKEY Alignment Aligned

DS Key TagDS AlgorithmDNSKEY Key TagDNSKEY Algorithm
2371 13 2371 13

Glue Record Completeness Complete

NameserverIn-BailiwickIPv4 GlueIPv6 GlueStatus
dane.ns.cloudflare.com No N/A N/A OK
melany.ns.cloudflare.com No N/A N/A OK

NS TTL Comparison Drift

Child TTL: 86400s Drift: 0s

SOA Serial Consistency Consistent

dane.ns.cloudflare.com: 2.401858659e+09
melany.ns.cloudflare.com: 2.401858659e+09
Nameserver Fleet Matrix Healthy

Analyzed 2 nameserver(s) for 932.moe — Per-nameserver reachability, ASN diversity, SOA serial sync, and lame delegation checks.

Nameserver IPv4 IPv6 ASN / Operator UDP TCP AA SOA Serial
melany.ns.cloudflare.com 162.159.38.138
172.64.34.138
108.162.194.138 		2606:4700:50::a29f:268a
2a06:98c1:50::ac40:228a
2803:f800:50::6ca2:c28a 		AS13335
Cloudflare, Inc. 		2401858659
dane.ns.cloudflare.com 172.64.33.97
173.245.59.97
108.162.193.97 		2803:f800:50::6ca2:c161
2a06:98c1:50::ac40:2161
2606:4700:58::adf5:3b61 		AS13335
Cloudflare, Inc. 		2401858659
Unique ASNs
1
Unique Operators
1
Unique /24 Prefixes
6
Diversity Score
Fair

1 ASN(s), 6 /24 prefix(es) — consider adding diversity

DNSSEC Operations Deep Dive 1 Issue

DNSSEC operational notes: 1 item(s) to review — KSK/ZSK differentiation, RRSIG expiry windows, NSEC/NSEC3 analysis, and rollover readiness.

Findings:
  • CDS/CDNSKEY automation present but only single KSK — pre-publish second KSK before rollover

DNSKEY Inventory 2 Keys

RoleKey TagAlgorithmKey Size
ZSK 34505 ECDSA P-256/SHA-256 256 bits
KSK 2371 ECDSA P-256/SHA-256 256 bits

RRSIG Signatures 0 Signatures

No RRSIG records found.

Denial of Existence NSEC

NSEC records expose zone contents via ordered names (zone walking). Consider NSEC3 for zone enumeration protection.

Rollover Readiness Partial

Multiple KSKs:
CDS Published:
CDNSKEY Published:
Automation: full
Mail Transport Security Beta Is mail transport encrypted and verified? Yes DANE/TLSA provides cryptographic transport verification

All 3 server(s) verified: encrypted transport confirmed via direct SMTP probe and DNS policy

Policy Assessment Primary
  • DANE/TLSA records published — mail servers pin TLS certificates via DNSSEC (RFC 7672)
Telemetry
TLS-RPT not configured — domain has no visibility into TLS delivery failures from real senders
Live Probe Supplementary
MX Host STARTTLS TLS Version Cipher Certificate
route3.mx.cloudflare.net TLSv1.2 TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256 Valid
Expires: 2026-12-08 (232 days)
Issuer: DigiCert Inc
route1.mx.cloudflare.net TLSv1.2 TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256 Valid
Expires: 2026-12-08 (232 days)
Issuer: DigiCert Inc
route2.mx.cloudflare.net TLSv1.2 TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256 Valid
Expires: 2026-12-08 (232 days)
Issuer: DigiCert Inc
Multi-Vantage Probe Results
Unanimous: TLS verified 2 probes, 2 responded
US-East (Boston) observed
All servers support TLS
France - EU observed
All servers support TLS
0.634127712s
Infrastructure Intelligence Who hosts this domain and what services power it? Direct

ASN / Network Success

Resolved 1 unique ASN(s) across 4 IP address(es)

ASNNameCountry
AS13335 Cloudflare, Inc. US
IPv4 Mappings:
104.21.75.162AS13335 (104.21.64.0/20)
172.67.178.188AS13335 (172.67.176.0/20)
IPv6 Mappings:
2606:4700:3030::ac43:b2bcAS13335 (2606:4700:3030::/48)
2606:4700:3034::6815:4ba2AS13335 (2606:4700:3034::/48)

Edge / CDN Success

Domain appears to use direct origin hosting

SaaS TXT Footprint Success

No SaaS services detected

Detects SaaS services that leave DNS TXT verification records (e.g., domain ownership proofs). Does not detect all SaaS platforms — only those indicated by DNS.

Domain Security Methodology Can DNS responses be tampered with in transit? No DNSSEC signed and validated, cryptographic chain of trust verified

DNSSEC RFC 4033 §2 Consistent Signed ECDSA P-256/SHA-256 Modern

DNSSEC fully configured and validated — AD (Authenticated Data) flag set by resolver 8.8.8.8 confirming cryptographic chain of trust from root to zone (RFC 4035 §3.2.3)

Algorithm Observation: ECDSA P-256/SHA-256 — MUST implement, recommended default (RFC 8624 §3.1)
All current DNSSEC algorithms use classical cryptography. Post-quantum DNSSEC standards are in active IETF development (draft-sheth-pqc-dnssec-strategy) but no PQC algorithms have been standardized for DNSSEC yet.
Chain of trust: Root → TLD → Domain. DNS responses are cryptographically authenticated and tamper-evident.
AD Flag: Validated - Resolver (8.8.8.8) confirmed cryptographic signatures
DS Record (at registrar):
2371 13 2 63EE0C7D0D31D1828E38C287C1539C72F15BBD08CB7FE7E436396F98E47C8F18

NS Delegation Verified

2 nameserver(s) configured

Nameservers: dane.ns.cloudflare.com melany.ns.cloudflare.com
Managed DNS
All 2 nameservers hosted by Cloudflare. Managed DNS provides reliable resolution with provider-maintained infrastructure.
DNS provider(s): Cloudflare
Multi-Resolver Verification Recon: Discrepancy detected - Some resolvers returned different results (1 difference found)
Resolver Differences:
A: DNS4EU returned different results: [188.114.96.0 188.114.97.0]
This may indicate DNS propagation in progress or geo-based DNS routing.

HTTPS / SVCB Records RFC 9460 Success HTTPS HTTP/3 ECH

HTTPS records found, HTTP/3 supported, ECH (Encrypted Client Hello) enabled

PriorityTargetALPNECHRaw
1 . h3, h2 Yes 932.moe. 300 IN HTTPS 1 . alpn="h3,h2" ipv4hint="104.21.75.162,172.67.178.188" ech="AEX+DQBBAAAgACBtRbnnswGK/1juhzVv2FUinWTsQBBfkqpERxx4PxDqXwAEAAEAAQASY2xvdWRmbGFyZS1lY2guY29tAAA=" ipv6hint="2606:4700:3030::ac43:b2bc,2606:4700:3034::6815:4ba2"

CDS / CDNSKEY (DNSSEC Automation) RFC 7344 Success CDS CDNSKEY

Full RFC 8078 automated DNSSEC key rollover signaling detected (CDS + CDNSKEY)

Key TagAlgorithmDigest TypeDigest
2371 ECDSAP256SHA256 2
CDNSKEY Records:
FlagsProtocolAlgorithmPublic Key
257 3 ECDSAP256SHA256
Traffic & Routing Where does this domain's traffic actually terminate?

AIPv4 Address

104.21.75.162
172.67.178.188
Where the domain points for web traffic

AAAAIPv6 Address

2606:4700:3030::ac43:b2bc
2606:4700:3034::6815:4ba2
IPv6 ready

MXMail Servers

1 route1.mx.cloudflare.net.
30 route2.mx.cloudflare.net.
60 route3.mx.cloudflare.net.
Priority + mail server for email delivery
Cloudflare Email

SRVServices

No SRV records
No service-specific routing configured
Web: Reachable (2 IPv4, 2 IPv6) Mail: 3 servers Services: None
Subdomain Discovery RFC 6962 Recon LIVE What subdomains and infrastructure are exposed in certificate logs? 12 subdomains discovered
How did we find these?
CT logs unavailable 12 current 0 expired Source: Certificate Transparency + DNS Intelligence
Subdomains discovered via CT logs (RFC 6962), DNS probing of common service names, and CNAME chain traversal.
Subdomain Source Status Provider / CNAME Certificates First Seen Issuer(s)
bj.mefrp.932.moe CT Log Current 2 2026-02-15T00:00:00 ZeroSSL
cname.932.moe DNS Current 4 2026-02-12 Google Trust Services, Let's Encrypt
encrypted.client.hello.932.moe CT Log Current 2 2026-03-19T20:27:00 Let's Encrypt
gm.932.moe CT Log Current 3 2026-03-13T18:54:22 Google Trust Services
hk.mefrp.932.moe CT Log Current 2 2026-03-03T03:16:42 Let's Encrypt
home.932.moe CT Log Current 8 2026-03-25T00:00:00 ZeroSSL, Let's Encrypt
home4.932.moe CT Log Current 6 2026-03-25T00:00:00 ZeroSSL, Let's Encrypt
home6.932.moe CT Log Current 6 2026-03-25T00:00:00 ZeroSSL, Let's Encrypt
http.932.moe CT Log Current 6 2026-03-27T11:35:15 Google Trust Services
ip.932.moe CT Log Current
storage.932.moe DNS Current 4 2026-02-12 Google Trust Services, Let's Encrypt
www.932.moe CT Log Current 3 2026-02-13T12:45:46 Google Trust Services
Export Recon (CSV)
Δ No Propagation Issues: All DNS records are synchronized between resolver and authoritative nameserver.
DNS Intelligence What does DNS look like right now — and what changed over time?
DNS Evidence Diff Side-by-side comparison
Resolver Records (Public DNS cache)
Authoritative Records (Source of truth)
A Synchronized 2 / 2 records
104.21.75.162
172.67.178.188
172.67.178.188
104.21.75.162
AAAA Synchronized 2 / 2 records
2606:4700:3030::ac43:b2bc
2606:4700:3030::ac43:b2bc
2606:4700:3034::6815:4ba2
2606:4700:3034::6815:4ba2
CAA RFC 8659 §4 Synchronized 10 / 10 records
0 issuewild "digicert.com; cansignhttpexchanges=yes"
0 issue "comodoca.com"
0 issue "letsencrypt.org"
0 issue "digicert.com; cansignhttpexchanges=yes"
0 issue "ssl.com"
0 issue "letsencrypt.org"
0 issue "pki.goog; cansignhttpexchanges=yes"
0 issue "pki.goog; cansignhttpexchanges=yes"
0 issuewild "letsencrypt.org"
0 issue "ssl.com"
0 issuewild "pki.goog; cansignhttpexchanges=yes"
0 issuewild "comodoca.com"
0 issuewild "comodoca.com"
0 issuewild "digicert.com; cansignhttpexchanges=yes"
0 issue "comodoca.com"
0 issuewild "letsencrypt.org"
0 issuewild "ssl.com"
0 issuewild "pki.goog; cansignhttpexchanges=yes"
0 issue "digicert.com; cansignhttpexchanges=yes"
0 issuewild "ssl.com"
DMARC _dmarc.932.moe RFC 7489 §6.3 Synchronized 1 / 1 records
v=DMARC1;p=quarantine;rua=mailto:e562106005c14c55ba7023150c409399@dmarc-reports.cloudflare.net
v=DMARC1;p=quarantine;rua=mailto:e562106005c14c55ba7023150c409399@dmarc-reports.cloudflare.net
MX RFC 5321 Synchronized 3 / 3 records
1 route1.mx.cloudflare.net.
1 route1.mx.cloudflare.net.
30 route2.mx.cloudflare.net.
30 route2.mx.cloudflare.net.
60 route3.mx.cloudflare.net.
60 route3.mx.cloudflare.net.
NS RFC 1035 Synchronized 2 / 2 records
dane.ns.cloudflare.com.
dane.ns.cloudflare.com.
melany.ns.cloudflare.com.
melany.ns.cloudflare.com.
SOA RFC 1035 Synchronized 1 / 1 records
dane.ns.cloudflare.com. dns.cloudflare.com. 2401858659 10000 2400 604800 1800
dane.ns.cloudflare.com. dns.cloudflare.com. 2401858659 10000 2400 604800 1800
TXT RFC 7208 §4 Synchronized 1 / 1 records
v=spf1 include:spf1.dm.aliyun.com include:_spf.mx.cloudflare.net ~all
v=spf1 include:spf1.dm.aliyun.com include:_spf.mx.cloudflare.net ~all
DNS History Timeline BETA
Your key is sent directly to SecurityTrails and is never stored on our servers. Get an API key
DNS History Timeline BETA

When was a record added, removed, or changed — and could that change be the problem?

Analyze Another Domain

Confirm Your Email Configuration

This tool analyzes DNS records, but to verify actual email delivery, send a test email to Red Sift Investigate. Their tool shows exactly how your emails arrive, including SPF/DKIM/DMARC pass/fail results in the headers.

DATA FRESHNESS & METHODOLOGY

All security-critical records (SPF, DMARC, DKIM, DANE/TLSA, DNSSEC, MTA-STS, TLS-RPT, BIMI, CAA) are queried live from authoritative nameservers and cross-referenced against 5 independent public DNS resolvers (Cloudflare, Google, Quad9, OpenDNS, DNS4EU) at the time of each analysis. No security verdict uses cached data.

Registrar data (RDAP) is cached for up to 24 hours because domain ownership and registration details change infrequently. Certificate Transparency logs (subdomain discovery via RFC 6962) are cached for 1 hour because CT entries are append-only historical records. Sections using cached data are marked with a CACHED badge; live queries show LIVE.

Intelligence Sources

This analysis used 4 DNS resolvers (consensus), reverse DNS (PTR), Team Cymru (ASN attribution), IANA RDAP (registrar), crt.sh (CT logs), and SMTP probing (transport). All using open-standard protocols.

Full List
Verify Report Integrity SHA-3-512 Has this report been altered since generation? Verify below

This cryptographic hash seals the analysis data, domain, timestamp, and tool version into a tamper-evident fingerprint. Any modification to the report data will produce a different hash. This is distinct from the posture hash (used for drift detection) — the integrity hash uniquely identifies this specific report instance.

de4a56eaef265550383c7efb89f0c80cf3167f864c8d9418ae851d7adadfd63662072467ac627a9e42f541b1c16d2a229021cef5ad0509096155e51f01d70d9f
Evaluations reference 12 RFCs. Methods are reproducible using the verification commands provided. Results reflect DNS state at 2026-04-20T00:08:49Z.
Download Raw Intelligence Download Checksum (.sha3) Cross-Reference Verification

Download the intelligence dump and verify its integrity, like you would a Kali ISO or any critical artifact. The SHA-3-512 checksum covers every byte of the download — deterministic serialization ensures identical hashes across downloads.

After downloading, verify with any of these commands:

Tip: cd ~/Downloads first (or wherever you saved the files).

OpenSSL + Sidecar (macOS, Linux, WSL) 
cat dns-intelligence-932.moe.json.sha3 && echo '---' && openssl dgst -sha3-512 dns-intelligence-932.moe.json
Python 3 (cross-platform) 
python3 -c "import hashlib; print(hashlib.sha3_512(open('dns-intelligence-932.moe.json','rb').read()).hexdigest())"
sha3sum (coreutils 9+) 
sha3sum -a 512 dns-intelligence-932.moe.json
Compare the output against the .sha3 file or the checksum API at /api/analysis/14368/checksum. Hash algorithm: SHA-3-512 (Keccak, NIST FIPS 202).

Every finding in this report is backed by DNS queries you can run yourself. These vetted one-liners reproduce the exact checks used to build this report for 932.moe. Our analysis adds multi-resolver consensus, RFC-based evaluation, and cross-referencing — but the underlying data is always independently verifiable. We are intelligence analysts, not gatekeepers.

DNS Records

Query A records (IPv4) RFC 1035 
dig +noall +answer 932.moe A
Query AAAA records (IPv6) RFC 1035 
dig +noall +answer 932.moe AAAA
Query MX records (mail servers) RFC 1035 
dig +noall +answer 932.moe MX
Query NS records (nameservers) RFC 1035 
dig +noall +answer 932.moe NS
Query TXT records RFC 1035 
dig +noall +answer 932.moe TXT

Email Authentication

Check SPF record RFC 7208 
dig +short 932.moe TXT | grep -i spf
Check DMARC policy RFC 7489 
dig +short _dmarc.932.moe TXT
Check DKIM key for selector 'dkim' RFC 6376 
dig +short dkim._domainkey.932.moe TXT
Check DKIM key for selector 'mail' RFC 6376 
dig +short mail._domainkey.932.moe TXT

Domain Security

Check DNSSEC DNSKEY records RFC 4035 
dig +dnssec +noall +answer 932.moe DNSKEY
Check DNSSEC DS records RFC 4035 
dig +noall +answer 932.moe DS
Validate DNSSEC chain (requires DNSSEC-validating resolver) RFC 4035 
dig +dnssec +cd 932.moe A @1.1.1.1

Transport Security

Check TLSA record for route1.mx.cloudflare.net RFC 7672 
dig +noall +answer _25._tcp.route1.mx.cloudflare.net TLSA
Check TLSA record for route2.mx.cloudflare.net RFC 7672 
dig +noall +answer _25._tcp.route2.mx.cloudflare.net TLSA
Check TLSA record for route3.mx.cloudflare.net RFC 7672 
dig +noall +answer _25._tcp.route3.mx.cloudflare.net TLSA
Verify TLS certificate on primary MX (route1.mx.cloudflare.net) RFC 6698 
openssl s_client -starttls smtp -connect route1.mx.cloudflare.net:25 -servername route1.mx.cloudflare.net 2>/dev/null | openssl x509 -noout -subject -dates
Check MTA-STS DNS record RFC 8461 
dig +short _mta-sts.932.moe TXT
Fetch MTA-STS policy file RFC 8461 
curl -sL https://mta-sts.932.moe/.well-known/mta-sts.txt
Check TLS-RPT record RFC 8460 
dig +short _smtp._tls.932.moe TXT

Brand & Trust

Check BIMI record BIMI Draft 
dig +short default._bimi.932.moe TXT
Check CAA records (certificate authority authorization) RFC 8659 
dig +noall +answer 932.moe CAA

DNS Records

Check HTTPS/SVCB records RFC 9460 
dig +noall +answer 932.moe HTTPS

Domain Security

Check CDS/CDNSKEY automation records RFC 7344 
dig +noall +answer 932.moe CDS

Infrastructure Intelligence

RDAP domain registration lookup RFC 9083 
curl -sL 'https://rdap.org/domain/932.moe' | python3 -m json.tool | head -50

Transport Security

Test STARTTLS on primary MX (route1.mx.cloudflare.net) RFC 3207 
openssl s_client -starttls smtp -connect route1.mx.cloudflare.net:25 -servername route1.mx.cloudflare.net </dev/null 2>/dev/null | head -5

Infrastructure Intelligence

Search Certificate Transparency logs RFC 6962 
curl -s 'https://crt.sh/?q=%25.932.moe&output=json' | python3 -c "import json,sys; [print(e['name_value']) for e in json.load(sys.stdin)]" | sort -u | head -20
Check security.txt RFC 9116 
curl -sL https://932.moe/.well-known/security.txt | head -20

AI Surface

Check for llms.txt 
curl -sI https://932.moe/llms.txt | head -5
Check robots.txt for AI crawler rules 
curl -s https://932.moe/robots.txt | grep -i -E 'GPTBot|ChatGPT|Claude|Anthropic|Google-Extended|CCBot|PerplexityBot'

Infrastructure Intelligence

ASN lookup for 104.21.75.162 (Team Cymru) 
dig +short 162.75.21.104.origin.asn.cymru.com TXT
ASN lookup for 172.67.178.188 (Team Cymru) 
dig +short 188.178.67.172.origin.asn.cymru.com TXT
Commands use dig, openssl, and curl — standard tools available on macOS, Linux, and WSL. Results may vary slightly due to DNS propagation timing and resolver caching.
Intelligence Confidence Audit Engine Consistent · 9/9 Evaluated
How confident are these results? Each protocol is independently verified against RFC standards. No self-awarded badges.
SPF
Consistent 15107 runs
DKIM
Consistent 14884 runs
DMARC
Consistent 15088 runs
DANE/TLSA
Consistent 14866 runs
DNSSEC
Consistent 15065 runs
BIMI
Consistent 14881 runs
MTA-STS
Consistent 14902 runs
TLS-RPT
Consistent 14917 runs
CAA
Consistent 14914 runs
Maturity: Development Verified Consistent Gold Gold Master

Appendix: Verification Commands

The core DNS queries behind this report can be independently verified using these standard terminal commands (dig, openssl, curl). DNS Tool adds multi-resolver consensus, RFC-based evaluation, and cross-referencing on top of the raw data shown here.

DNS Records

Query A records (IPv4) (RFC 1035) 
dig +noall +answer 932.moe A
Query AAAA records (IPv6) (RFC 1035) 
dig +noall +answer 932.moe AAAA
Query MX records (mail servers) (RFC 1035) 
dig +noall +answer 932.moe MX
Query NS records (nameservers) (RFC 1035) 
dig +noall +answer 932.moe NS
Query TXT records (RFC 1035) 
dig +noall +answer 932.moe TXT

Email Authentication

Check SPF record (RFC 7208) 
dig +short 932.moe TXT | grep -i spf
Check DMARC policy (RFC 7489) 
dig +short _dmarc.932.moe TXT
Check DKIM key for selector 'dkim' (RFC 6376) 
dig +short dkim._domainkey.932.moe TXT
Check DKIM key for selector 'mail' (RFC 6376) 
dig +short mail._domainkey.932.moe TXT

Domain Security

Check DNSSEC DNSKEY records (RFC 4035) 
dig +dnssec +noall +answer 932.moe DNSKEY
Check DNSSEC DS records (RFC 4035) 
dig +noall +answer 932.moe DS
Validate DNSSEC chain (requires DNSSEC-validating resolver) (RFC 4035) 
dig +dnssec +cd 932.moe A @1.1.1.1

Transport Security

Check TLSA record for route1.mx.cloudflare.net (RFC 7672) 
dig +noall +answer _25._tcp.route1.mx.cloudflare.net TLSA
Check TLSA record for route2.mx.cloudflare.net (RFC 7672) 
dig +noall +answer _25._tcp.route2.mx.cloudflare.net TLSA
Check TLSA record for route3.mx.cloudflare.net (RFC 7672) 
dig +noall +answer _25._tcp.route3.mx.cloudflare.net TLSA
Verify TLS certificate on primary MX (route1.mx.cloudflare.net) (RFC 6698) 
openssl s_client -starttls smtp -connect route1.mx.cloudflare.net:25 -servername route1.mx.cloudflare.net 2>/dev/null | openssl x509 -noout -subject -dates
Check MTA-STS DNS record (RFC 8461) 
dig +short _mta-sts.932.moe TXT
Fetch MTA-STS policy file (RFC 8461) 
curl -sL https://mta-sts.932.moe/.well-known/mta-sts.txt
Check TLS-RPT record (RFC 8460) 
dig +short _smtp._tls.932.moe TXT

Brand & Trust

Check BIMI record (BIMI Draft) 
dig +short default._bimi.932.moe TXT
Check CAA records (certificate authority authorization) (RFC 8659) 
dig +noall +answer 932.moe CAA

DNS Records

Check HTTPS/SVCB records (RFC 9460) 
dig +noall +answer 932.moe HTTPS

Domain Security

Check CDS/CDNSKEY automation records (RFC 7344) 
dig +noall +answer 932.moe CDS

Infrastructure Intelligence

RDAP domain registration lookup (RFC 9083) 
curl -sL 'https://rdap.org/domain/932.moe' | python3 -m json.tool | head -50

Transport Security

Test STARTTLS on primary MX (route1.mx.cloudflare.net) (RFC 3207) 
openssl s_client -starttls smtp -connect route1.mx.cloudflare.net:25 -servername route1.mx.cloudflare.net </dev/null 2>/dev/null | head -5

Infrastructure Intelligence

Search Certificate Transparency logs (RFC 6962) 
curl -s 'https://crt.sh/?q=%25.932.moe&output=json' | python3 -c "import json,sys; [print(e['name_value']) for e in json.load(sys.stdin)]" | sort -u | head -20
Check security.txt (RFC 9116) 
curl -sL https://932.moe/.well-known/security.txt | head -20

AI Surface

Check for llms.txt 
curl -sI https://932.moe/llms.txt | head -5
Check robots.txt for AI crawler rules 
curl -s https://932.moe/robots.txt | grep -i -E 'GPTBot|ChatGPT|Claude|Anthropic|Google-Extended|CCBot|PerplexityBot'

Infrastructure Intelligence

ASN lookup for 104.21.75.162 (Team Cymru) 
dig +short 162.75.21.104.origin.asn.cymru.com TXT
ASN lookup for 172.67.178.188 (Team Cymru) 
dig +short 188.178.67.172.origin.asn.cymru.com TXT

0s

Running Real-Time Scan Telemetry

Most scans complete in less than one minute. Some may take longer.

Markers represent known resolver locations. Anycast routing selects the nearest node — exact routing is internal to each provider.

Pipeline nodes reflect live data as each analysis phase completes.

Telemetry Log 0 polls