leviathan
39ce4dff09
Adds .opsec_notes to every module's struct skeletonkey_module
(31 entries across 26 module files). One paragraph per exploit
describing the runtime footprint a defender/SOC would see:
- file artifacts created/modified (exact paths from source)
- syscall observables (the unshare / socket / setsockopt /
splice / msgsnd patterns the embedded detection rules look for)
- dmesg signatures (silent on success vs KASAN oops on miss)
- network activity (loopback-only vs none)
- persistence side-effects (/etc/passwd modification, dropped
setuid binaries, backdoors)
- cleanup behaviour (callback present? what it restores?)
Each note is grounded in the module's source code + its existing
auditd/sigma/yara/falco detection rules — the OPSEC notes are
literally the inverse of those rules (the rules describe what to
look for; the notes describe what the exploit triggers).
Three intelligence agents researched the modules in parallel,
reading source + MODULE.md, then their proposals were embedded
verbatim via tools/inject_opsec.py (one-shot script, not retained).
Where surfaced:
- --module-info <name>: '--- opsec notes ---' section between
detect-rules summary and the embedded auditd/sigma rule bodies.
- --module-info / --scan --json: 'opsec_notes' top-level string.
Audience uses:
- Red team: see what footprint each exploit leaves so they pick
chains that match the host's telemetry posture.
- Blue team: the notes mirror the existing detection rules from the
attacker side — easy diff to find gaps in their SIEM coverage.
- Researchers: per-exploit footprint catalog for technique analysis.
copy_fail_family gets one shared note across all 5 register entries
(copy_fail, copy_fail_gcm, dirty_frag_esp, dirty_frag_esp6,
dirty_frag_rxrpc) since they share exploit infrastructure.
Verification:
- macOS local: clean build, --module-info nf_tables shows full
opsec section + CWE + ATT&CK + KEV row from previous commit.
- Linux (docker gcc:latest): 33 + 54 = 87 passes, 0 fails.
Next: --explain mode (uses these notes + the triage metadata to
render a single 'why is this verdict, what would patch fix it, and
what would the SOC see' page per module).
SKELETONKEY
One curated binary. 28 verified Linux LPE exploits, 2016 → 2026 (+3 ported-but-unverified). Detection rules in the box. One command picks the safest one and runs it.
curl -sSL https://github.com/KaraZajac/SKELETONKEY/releases/latest/download/install.sh | sh \
&& skeletonkey --auto --i-know
⚠️ Authorized testing only. SKELETONKEY runs real exploits. By using it you assert you have explicit authorization to test the target system. See
docs/ETHICS.md.
Why use this
Most Linux privesc tooling is broken in one of three ways:
linux-exploit-suggester/linpeas— tell you what might work, run nothingauto-root-exploit/kernelpop— bundle exploits but ship no detection signatures and went stale years ago- Per-CVE PoC repos — one author, one distro, abandoned within months
SKELETONKEY is one binary, actively maintained, with detection rules for every CVE in the bundle — same project for red and blue teams.
Who it's for
| Audience | What you get |
|---|---|
| Red team / pentesters | One tested binary. --auto ranks vulnerable modules by safety and runs the safest. Honest scope reporting — never claims root it didn't actually get. |
| Sysadmins | skeletonkey --scan (no sudo needed) tells you which boxes still need patching. Fleet-scan tool included. JSON output for CI gates (schema). |
| Blue team / SOC | Auditd + sigma + yara + falco rules for every CVE. --detect-rules --format=auditd | sudo tee … ships SIEM coverage in one command. |
| CTF / training | Reproducible LPE environment with public CVEs across a 10-year timeline. Each module documents the bug, the trigger, and the fix. |
Corpus at a glance
28 verified modules spanning the 2016 → 2026 LPE timeline, plus
3 ported-but-unverified modules (dirtydecrypt, fragnesia,
pack2theroot — see note below):
| Tier | Count | What it means |
|---|---|---|
| 🟢 Full chain | 14 | Lands root (or its canonical capability) end-to-end. No per-kernel offsets needed. |
| 🟡 Primitive | 14 | Fires the kernel primitive + grooms the slab + records a witness. Default returns EXPLOIT_FAIL honestly. Pass --full-chain to engage the shared modprobe_path finisher (needs offsets — see docs/OFFSETS.md). |
| ⚪ Ported, unverified | 3 | dirtydecrypt, fragnesia, pack2theroot. Built and registered with version-pinned detect() (Linux 7.0 / 7.0.9 / PackageKit 1.3.5 respectively), but the exploit bodies are not yet validated end-to-end. --auto auto-enables --active to confirm empirically on top of the version verdict. Excluded from the 28-module verified counts above. |
🟢 Modules that land root on a vulnerable host: copy_fail family ×5 · dirty_pipe · dirty_cow · pwnkit · overlayfs (CVE-2021-3493) · overlayfs_setuid (CVE-2023-0386) · cgroup_release_agent · ptrace_traceme · sudoedit_editor · entrybleed (KASLR leak primitive)
🟡 Modules with opt-in --full-chain:
af_packet · af_packet2 · af_unix_gc · cls_route4 · fuse_legacy ·
nf_tables · nft_set_uaf · nft_fwd_dup · nft_payload ·
netfilter_xtcompat · stackrot · sudo_samedit · sequoia · vmwgfx
⚪ Ported-but-unverified (not in the counts above):
dirtydecrypt (CVE-2026-31635) · fragnesia (CVE-2026-46300) ·
pack2theroot (CVE-2026-41651) — ported from public PoCs, exploit
bodies not yet VM-validated. All three have version-pinned detect():
dirtydecrypt against mainline fix commit a2567217 in Linux 7.0;
fragnesia against mainline 7.0.9 (older Debian-stable branches still
unfixed); pack2theroot against PackageKit fix release 1.3.5
(commit 76cfb675), version read from the daemon over D-Bus.
--auto auto-enables --active to confirm empirically on top.
See CVES.md for per-module CVE, kernel range, and
detection status.
Quickstart
# Install (x86_64 / arm64; checksum-verified)
curl -sSL https://github.com/KaraZajac/SKELETONKEY/releases/latest/download/install.sh | sh
# What's this box vulnerable to? (no sudo)
skeletonkey --scan
# Pick the safest LPE and run it
skeletonkey --auto --i-know
# Deploy detection rules (needs sudo to write into /etc/audit/rules.d/)
skeletonkey --detect-rules --format=auditd \
| sudo tee /etc/audit/rules.d/99-skeletonkey.rules
# Fleet scan — many hosts via SSH, aggregated JSON for SIEM
./tools/skeletonkey-fleet-scan.sh --binary skeletonkey \
--ssh-key ~/.ssh/id_rsa hosts.txt
SKELETONKEY runs as a normal unprivileged user — that's the point.
--scan, --audit, --exploit, and --detect-rules all work without
sudo. Only --mitigate and rule-file installation write root-owned
paths.
Example: unprivileged → root
$ id
uid=1000(kara) gid=1000(kara) groups=1000(kara)
$ skeletonkey --auto --i-know
[*] auto: host=demo distro=ubuntu/24.04 kernel=5.15.0-56-generic arch=x86_64
[*] auto: active probes enabled — brief /tmp file touches and fork-isolated namespace probes
[*] auto: scanning 31 modules for vulnerabilities...
[+] auto: dirty_pipe VULNERABLE (safety rank 90)
[+] auto: cgroup_release_agent VULNERABLE (safety rank 98)
[+] auto: pwnkit VULNERABLE (safety rank 100)
[ ] auto: copy_fail patched or not applicable
[ ] auto: nf_tables precondition not met
...
[*] auto: scan summary — 3 vulnerable, 21 patched/n.a., 7 precondition-fail, 0 indeterminate
[*] auto: 3 vulnerable modules found. Safest is 'pwnkit' (rank 100).
[*] auto: launching --exploit pwnkit...
[+] pwnkit: writing gconv-modules cache + payload.so...
[+] pwnkit: execve(pkexec) with NULL argv + crafted envp...
# id
uid=0(root) gid=0(root) groups=0(root)
The safety ranking goes: structural escapes (no kernel state touched) → page-cache writes → userspace cred-races → kernel primitives → kernel races (least predictable). The goal is to never crash a production box looking for root.
How it works
Each CVE (or tightly-related family) is a module under modules/.
Modules export a standard interface (detect / exploit / mitigate / cleanup) plus metadata (kernel range, detection rule text). The
top-level binary dispatches per command:
--scanwalks every module'sdetect()against the running host--exploit <name> --i-knowruns the named module's exploit (the--i-knowflag is the authorization gate)--auto --i-knowdoes the scan, ranks by safety, runs the safest--detect-rules --format=<auditd|sigma|yara|falco>emits the embedded rule corpus--mitigate <name>/--cleanup <name>apply / undo temporary mitigations (module-dependent — most kernel modules say "upgrade")--dump-offsetsreads/proc/kallsyms+/boot/System.mapand emits a ready-to-paste C entry for the--full-chainoffset table
See docs/ARCHITECTURE.md for the
module-loader design.
The verified-vs-claimed bar
Most public PoC repos hardcode offsets for one kernel build and
silently break elsewhere. SKELETONKEY refuses to ship fabricated
offsets. The shared --full-chain finisher only returns
EXPLOIT_OK after a setuid bash sentinel file actually appears;
otherwise modules return EXPLOIT_FAIL with a diagnostic. Operators
populate the offset table once per target kernel via
skeletonkey --dump-offsets and either set env vars or upstream the
entry via PR (CONTRIBUTING.md).
Build from source
git clone https://github.com/KaraZajac/SKELETONKEY.git
cd SKELETONKEY
make
./skeletonkey --version
Builds clean with gcc or clang on any modern Linux. macOS dev builds also compile (modules with Linux-only headers stub out gracefully).
Status
v0.6.0 cut 2026-05-23. 28 verified modules, plus 3
ported-but-unverified (dirtydecrypt, fragnesia, pack2theroot).
All 31 build clean on Debian 13 (kernel 6.12) and refuse cleanly on
patched hosts.
Reliability + accuracy work in v0.6.0:
- Shared host fingerprint (
core/host.{h,c}) populated once at startup — kernel/distro/userns gates/sudo+polkit versions — exposed to every module viactx->host. 26 of 27 distinct modules consume it. - Test harness (
tests/test_detect.c,make test) — 44 unit tests over mocked host fingerprints; runs as a non-root user in CI. --autoupgrades: auto-enables--active, per-detect 15s timeout, fork-isolated detect + exploit so a crashing module can't tear down the dispatcher, structured per-module verdict table, scan summary.--dry-runflag (preview without firing; no--i-knowneeded).- Pinned mainline fix commits for the 3 ported modules —
detect()is version-pinned, not just precondition-only.
Empirical end-to-end validation on a vulnerable-target VM matrix is the next roadmap item; until then, the corpus is best understood as "compiles + detects + structurally correct + honest on failure" — and the three ported modules have not been run against a vulnerable target at all.
See ROADMAP.md for the next planned modules and
infrastructure work.
Contributing
PRs welcome for: kernel offsets (run --dump-offsets on a target
kernel, paste into core/offsets.c), new modules, detection rules,
and CVE-status corrections. See CONTRIBUTING.md.
Keeping kernel_range tables current. tools/refresh-kernel-ranges.py
polls Debian's security tracker and reports drift between each
module's hardcoded kernel_patched_from thresholds and the
fixed-versions Debian actually ships. Run periodically (or in CI)
to catch new backports that need to land in the corpus:
tools/refresh-kernel-ranges.py # human report
tools/refresh-kernel-ranges.py --json # machine-readable
tools/refresh-kernel-ranges.py --patch # proposed C-source edits
Acknowledgments
Each module credits the original CVE reporter and PoC author in its
NOTICE.md. SKELETONKEY is the bundling and bookkeeping layer;
the research credit belongs to the people who found the bugs.
License
MIT — see LICENSE.