feat(reliability): fd-leak rails — self-watchdog, poll-overlap guard, fd tests
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Guardrails so the fd-leak class of bug (Errno 24 lockup; recent SNMP + UniFi
fixes) surfaces early or can't compound, instead of silently killing the app.

- Self-fd watchdog (steward/core/self_monitor.py): records open_fds and
  open_fds_pct (% of soft RLIMIT_NOFILE) as "steward"/"process" metrics each
  minute through the normal alert pipeline, so the operator can alert on them
  via the existing alert-rules UI. Built-in WARNING floor at 80% gives a
  zero-config early signal. Stdlib-only (/proc + resource); degrades to a no-op
  off Linux. Registered as a core ScheduledTask in app.py.

- Poll-overlap guard (steward/core/scheduler.py): extract a pure _DueTracker
  that skips a tick while a task's prior run is still in flight, so a hung poll
  can't stack overlapping runs (which amplify per-poll resource/fd use). A
  skipped task isn't penalised — it retries the next tick after it completes.

- fd-stability tests (tests/core/): _DueTracker overlap policy, the watchdog
  metric/warning/degradation paths, and a real-fd canary that hammers tcp_check
  and asserts /proc/self/fd doesn't grow.

Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
This commit is contained in:
2026-06-24 10:36:53 -04:00
parent 0c5a1573da
commit f40063a74d
6 changed files with 395 additions and 10 deletions
+13
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@@ -268,6 +268,10 @@ def _register_core_tasks(app: Quart) -> None:
from .core.reports import check_and_send
await check_and_send(app)
async def run_self_monitor():
from .core.self_monitor import record_self_metrics
await record_self_metrics(app)
app._task_registry.extend([
ScheduledTask(
name="weekly_report_check",
@@ -275,6 +279,15 @@ def _register_core_tasks(app: Quart) -> None:
interval_seconds=3600,
run_on_startup=False,
),
# Watch our own fd usage so a descriptor leak surfaces as a metric/alert
# instead of a silent Errno 24 lockup. Cheap; plugin_metrics roll up
# hourly so the 60s cadence is storage-bounded.
ScheduledTask(
name="self_monitor",
coro_factory=run_self_monitor,
interval_seconds=60,
run_on_startup=True,
),
ScheduledTask(
name="monitor_check",
coro_factory=run_monitor_checks,
+47 -10
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@@ -1,7 +1,7 @@
from __future__ import annotations
import asyncio
import logging
from dataclasses import dataclass
from dataclasses import dataclass, field
from typing import Callable, Coroutine
logger = logging.getLogger(__name__)
@@ -15,28 +15,65 @@ class ScheduledTask:
run_on_startup: bool = False
@dataclass
class _DueTracker:
"""Decides which scheduled tasks are due, with a self-overlap guard.
Pure (no asyncio, no clock of its own — `now` is passed in) so the
scheduling policy is unit-testable without timing races. A task whose prior
run is still in flight is NOT re-fired: overlapping poll runs stack up open
connections/subprocesses and amplify any per-poll resource use — the same
failure mode behind the fd-leak lockups. The skipped task is retried on the
next tick once it completes (its last_run isn't advanced while skipped).
"""
last_run: dict[str, float] = field(default_factory=dict)
in_flight: set[str] = field(default_factory=set)
def due(self, tasks: list[ScheduledTask], now: float) -> list[ScheduledTask]:
ready: list[ScheduledTask] = []
for task in tasks:
if now - self.last_run.get(task.name, 0) < task.interval_seconds:
continue
if task.name in self.in_flight:
logger.warning(
"Scheduled task %r still running — skipping this tick",
task.name)
continue
ready.append(task)
return ready
def mark_started(self, task: ScheduledTask, now: float) -> None:
self.in_flight.add(task.name)
self.last_run[task.name] = now
def mark_done(self, name: str) -> None:
self.in_flight.discard(name)
async def start_scheduler(tasks: list[ScheduledTask]) -> None:
"""Run scheduled tasks in a loop. Call with asyncio.create_task()."""
last_run: dict[str, float] = {}
tracker = _DueTracker()
def _spawn(task: ScheduledTask, now: float) -> None:
tracker.mark_started(task, now)
asyncio.create_task(_run_task(task, tracker))
for task in tasks:
if task.run_on_startup:
logger.info(f"Startup task: {task.name}")
asyncio.create_task(_run_task(task))
last_run[task.name] = asyncio.get_event_loop().time()
_spawn(task, asyncio.get_event_loop().time())
while True:
now = asyncio.get_event_loop().time()
for task in tasks:
last = last_run.get(task.name, 0)
if now - last >= task.interval_seconds:
asyncio.create_task(_run_task(task))
last_run[task.name] = now
for task in tracker.due(tasks, now):
_spawn(task, now)
await asyncio.sleep(1)
async def _run_task(task: ScheduledTask) -> None:
async def _run_task(task: ScheduledTask, tracker: _DueTracker) -> None:
try:
await task.coro_factory()
except Exception:
logger.exception(f"Scheduled task {task.name!r} raised an exception")
finally:
tracker.mark_done(task.name)
+116
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@@ -0,0 +1,116 @@
"""Self-monitoring: record Steward's own open file-descriptor usage.
A leaked socket/file handle in a poll loop (see the SNMP and UniFi fd-leak
issues) used to fail silently until the process hit its fd ceiling and
`socket.accept()` started raising `OSError: [Errno 24] Too many open files` —
taking the whole app down with no early warning.
This turns that failure mode into an observable signal. Steward monitors other
things; it should monitor itself. We record two metrics each tick under
`source_module="steward"`:
• ``open_fds`` — raw count of open descriptors
• ``open_fds_pct`` — that count as a percentage of the soft RLIMIT_NOFILE
Both flow through the normal alert pipeline, so the operator can attach an alert
rule to either via the existing alert-rules UI. As a zero-config floor we also
log a WARNING once usage crosses ``FD_WARN_PCT`` — a leak becomes visible even
before any rule is set up.
"""
from __future__ import annotations
import logging
import os
logger = logging.getLogger(__name__)
# Stdlib-only fd counting via /proc keeps this dependency-free. resource is
# POSIX-only but always present on the Linux runtime image; guard anyway so
# imports never explode on a dev machine.
try:
import resource
except ImportError: # pragma: no cover - non-POSIX
resource = None # type: ignore[assignment]
# Warn (without needing a configured alert rule) once we're using this fraction
# of the soft fd limit. 80% leaves headroom to act before accepts start failing.
FD_WARN_PCT = 80.0
_warned = False # de-dupe the WARNING so a sustained leak doesn't spam the log
def count_open_fds() -> int | None:
"""Number of open file descriptors for this process, or None if unknown.
Reads ``/proc/self/fd`` (Linux). Returns None where /proc isn't available
(e.g. a macOS dev box) so callers degrade to a no-op rather than guessing.
"""
try:
return len(os.listdir("/proc/self/fd"))
except OSError:
return None
def fd_soft_limit() -> int | None:
"""Soft RLIMIT_NOFILE for this process, or None if it can't be read.
None when the limit is unknown or 'unlimited' (RLIM_INFINITY) — a percentage
against an unbounded ceiling is meaningless, so we skip the pct metric then.
"""
if resource is None:
return None
try:
soft, _hard = resource.getrlimit(resource.RLIMIT_NOFILE)
except (ValueError, OSError):
return None
if soft <= 0 or soft == resource.RLIM_INFINITY:
return None
return soft
async def record_self_metrics(app) -> None:
"""Record open-fd usage as Steward's own metrics; warn past the floor.
No-op (logged at debug) when fd accounting isn't available on this platform,
so it's safe to schedule unconditionally.
"""
global _warned
fds = count_open_fds()
if fds is None:
logger.debug("self_monitor: /proc/self/fd unavailable — skipping fd metrics")
return
from .alerts import record_metric
soft = fd_soft_limit()
pct = (fds / soft * 100.0) if soft else None
async with app.db_sessionmaker() as session:
async with session.begin():
await record_metric(
session=session,
source_module="steward",
resource_name="process",
metric_name="open_fds",
value=float(fds),
)
if pct is not None:
await record_metric(
session=session,
source_module="steward",
resource_name="process",
metric_name="open_fds_pct",
value=pct,
)
if pct is not None and pct >= FD_WARN_PCT:
if not _warned:
logger.warning(
"Open file descriptors at %.0f%% of the soft limit (%d/%d) — "
"possible descriptor leak; the app will stop accepting "
"connections if this reaches 100%%.", pct, fds, soft)
_warned = True
else:
_warned = False # recovered — re-arm the warning for the next breach
logger.debug("self_monitor: open_fds=%d soft_limit=%s pct=%s", fds, soft, pct)
+46
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@@ -0,0 +1,46 @@
"""Real-fd regression canary.
Drives a real socket code path (the TCP reachability probe) in a tight loop and
asserts the process's open-fd count doesn't grow. If someone reintroduces a
socket leak in the probe path — the class of bug behind the Errno 24 lockups —
this fails in CI instead of in production. Uses real descriptors, not fakes, so
the assertion has teeth.
"""
import asyncio
import os
import pytest
from steward.monitors.ping import tcp_check
_ITERATIONS = 100
def _fd_count() -> int | None:
try:
return len(os.listdir("/proc/self/fd"))
except OSError:
return None
async def _hammer_tcp_check() -> None:
# 127.0.0.1:1 has no listener → connection refused immediately. Each call must
# fully release its socket; a leak would add ~one fd per iteration.
for _ in range(_ITERATIONS):
await tcp_check("127.0.0.1", 1)
def test_tcp_check_does_not_leak_fds():
if _fd_count() is None:
pytest.skip("/proc/self/fd unavailable on this platform")
asyncio.run(_hammer_tcp_check()) # warm up (lazy imports, caches)
before = _fd_count()
asyncio.run(_hammer_tcp_check())
after = _fd_count()
# Small slack for interpreter-internal fds; a genuine leak over 100 iterations
# would be far larger than this.
assert after - before <= 5, (
f"open fds grew {before}->{after} over {_ITERATIONS} tcp_check calls "
"— possible socket leak")
+58
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@@ -0,0 +1,58 @@
"""Unit tests for the scheduler's poll-overlap guard (_DueTracker).
The tracker is pure (clock passed in) so we can assert the overlap policy
deterministically: a task whose prior run is still in flight is never re-fired,
and a skipped task isn't penalised — it runs on the next tick once it finishes.
This is the rail that stops a hung poll from stacking overlapping runs (which
would amplify any per-poll resource/fd use).
"""
from steward.core.scheduler import ScheduledTask, _DueTracker
def _task(name: str, interval: int) -> ScheduledTask:
return ScheduledTask(name=name, coro_factory=lambda: None, interval_seconds=interval)
def test_due_only_after_interval_elapses():
t = _task("a", 60)
tr = _DueTracker()
assert tr.due([t], now=59) == [] # 59 < 60
assert tr.due([t], now=60) == [t] # interval elapsed
def test_in_flight_task_is_skipped_even_when_due():
t = _task("a", 0) # due every tick
tr = _DueTracker()
tr.mark_started(t, now=0)
assert tr.due([t], now=100) == [] # still running → skipped
tr.mark_done("a")
assert tr.due([t], now=100) == [t] # finished → eligible again
def test_skip_does_not_advance_last_run_so_it_retries():
t = _task("a", 10)
tr = _DueTracker()
tr.mark_started(t, now=0)
assert tr.due([t], now=100) == [] # due but in flight
assert tr.last_run["a"] == 0 # not advanced by the skip
tr.mark_done("a")
assert tr.due([t], now=100) == [t] # retried promptly after completion
def test_mark_started_advances_last_run_and_marks_in_flight():
t = _task("a", 10)
tr = _DueTracker()
tr.mark_started(t, now=50)
assert tr.last_run["a"] == 50
assert tr.in_flight == {"a"}
assert tr.due([t], now=55) == [] # 5 < 10 (not yet due)
assert tr.due([t], now=61) == [] # due by interval, but still in flight
tr.mark_done("a")
assert tr.due([t], now=61) == [t]
def test_independent_tasks_do_not_block_each_other():
a, b = _task("a", 0), _task("b", 0)
tr = _DueTracker()
tr.mark_started(a, now=0) # a hangs
assert tr.due([a, b], now=10) == [b] # b still fires
+115
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@@ -0,0 +1,115 @@
"""Unit tests for the self-fd watchdog (no DB, no network).
Exercises the fd accounting, the percentage/warning floor, and that the
recorder degrades to a no-op where fd accounting isn't available. The DB session
and the alert pipeline are faked — we only assert that the right metrics get
handed to record_metric.
"""
import asyncio
import logging
import steward.core.alerts as alerts
import steward.core.self_monitor as sm
# ── fd accounting ────────────────────────────────────────────────────────────
def test_count_open_fds_sane_or_none():
n = sm.count_open_fds()
# On the Linux CI image /proc exists; stdin/stdout/stderr are always open.
assert n is None or n >= 3
def test_fd_soft_limit_positive_or_none():
soft = sm.fd_soft_limit()
assert soft is None or soft > 0
# ── fake session / app plumbing ──────────────────────────────────────────────
class _Ctx:
async def __aenter__(self):
return self
async def __aexit__(self, *_):
return False
class _FakeSession(_Ctx):
def begin(self):
return _Ctx()
class _FakeApp:
def db_sessionmaker(self):
return _FakeSession()
def _patch_recorder(monkeypatch):
recorded: list[tuple] = []
async def fake_record_metric(session, source_module, resource_name, metric_name, value):
recorded.append((source_module, resource_name, metric_name, value))
monkeypatch.setattr(alerts, "record_metric", fake_record_metric)
return recorded
# ── record_self_metrics ──────────────────────────────────────────────────────
def test_records_both_fd_metrics(monkeypatch):
recorded = _patch_recorder(monkeypatch)
monkeypatch.setattr(sm, "count_open_fds", lambda: 50)
monkeypatch.setattr(sm, "fd_soft_limit", lambda: 1000)
asyncio.run(sm.record_self_metrics(_FakeApp()))
assert ("steward", "process", "open_fds", 50.0) in recorded
assert ("steward", "process", "open_fds_pct", 5.0) in recorded
def test_no_pct_metric_when_limit_unknown(monkeypatch):
recorded = _patch_recorder(monkeypatch)
monkeypatch.setattr(sm, "count_open_fds", lambda: 50)
monkeypatch.setattr(sm, "fd_soft_limit", lambda: None)
asyncio.run(sm.record_self_metrics(_FakeApp()))
metric_names = [m for (_s, _r, m, _v) in recorded]
assert "open_fds" in metric_names
assert "open_fds_pct" not in metric_names # meaningless without a ceiling
def test_warns_past_floor(monkeypatch, caplog):
_patch_recorder(monkeypatch)
monkeypatch.setattr(sm, "count_open_fds", lambda: 900)
monkeypatch.setattr(sm, "fd_soft_limit", lambda: 1000) # 90% ≥ FD_WARN_PCT
monkeypatch.setattr(sm, "_warned", False)
with caplog.at_level(logging.WARNING, logger=sm.logger.name):
asyncio.run(sm.record_self_metrics(_FakeApp()))
assert any("soft limit" in r.message for r in caplog.records)
def test_no_warning_below_floor(monkeypatch, caplog):
_patch_recorder(monkeypatch)
monkeypatch.setattr(sm, "count_open_fds", lambda: 100)
monkeypatch.setattr(sm, "fd_soft_limit", lambda: 1000) # 10%
monkeypatch.setattr(sm, "_warned", False)
with caplog.at_level(logging.WARNING, logger=sm.logger.name):
asyncio.run(sm.record_self_metrics(_FakeApp()))
assert not any("soft limit" in r.message for r in caplog.records)
def test_noop_when_fd_count_unavailable(monkeypatch):
# /proc absent → must return before touching the DB.
monkeypatch.setattr(sm, "count_open_fds", lambda: None)
class _Boom:
def db_sessionmaker(self):
raise AssertionError("must not open a session when fds are unknown")
asyncio.run(sm.record_self_metrics(_Boom())) # no raise