| name | sharded-counters |
| description | This skill should be used when the user needs a "sharded counter", "distributed counter", to "count likes / views at scale", handles a "high-write counter" or "hot counter contention", asks about "approximate counting", "real-time counts", or "HyperLogLog". It gives the recipe for absorbing write-heavy counting without a single hot row. Use it whenever one row/key takes concurrent increments faster than it can serialize them, even if the user doesn't say "sharded counter". |
Sharded counters
Count a thing that is incremented far faster than a single row, key, or
partition can serialize writes — likes, views, votes, rate tallies, inventory
decrements. The trap is the hot counter: every writer contends on one
record, so latency climbs and throughput plateaus no matter how big the box is.
Getting it wrong turns a trivial +1 into the bottleneck of the whole feature.
When to reach for this
Concurrent increments to a single logical count exceed what one row/key can
absorb — a viral post's like count, a live-event view counter, a global
rate tally. The symptom is write contention (lock waits, CAS retries, partition
hot-spotting) on one record while the rest of the store is idle. Reaching for
this means the write side is the problem, and an exact-to-the-millisecond
total is not required.
When NOT to
Low write rate (a single atomic INCR handles thousands/sec — don't shard a
counter nobody is hammering; YAGNI). Counts that must be transactionally exact
and read-after-write consistent at every instant (bank balances, seat
inventory at sell-out) — that's a transactional decrement, see
consistency-coordination, not a fan-out tally. Counting distinct items
exactly (unique visitors) where you also need the member list — that's a set in
the store, not a counter. If reads dominate and writes are cheap, you need a
cached aggregate, not sharding.
Clarify first
- Write rate to the hottest single count — peak increments/sec on one
logical counter, not the aggregate (→
back-of-the-envelope).
- Exact or approximate — is an off-by-a-few total acceptable, and for how
long may shards disagree (eventual)? Drives shard count and read path.
- Counting occurrences or distinct items — a running total vs. unique-count
(likes vs. unique viewers) decides plain shards vs. HyperLogLog.
- Read rate and freshness — how often is the total read, and how stale may
the served number be (sub-second? minutes?).
- Time-windowed or lifetime — "views in the last hour" needs bucketed keys
and expiry; a lifetime total does not.
The options
- Single atomic counter — one row/key with atomic
INCR/UPDATE +1. Use
when peak write rate on the hottest count is well within one node's serialized
write throughput. The default; don't outgrow it prematurely.
- Write-sharded (striped) counter — split one logical count into N physical
shards (
counter:{id}:shard:{0..N-1}); each write increments a random/hashed
shard, reads sum all N. Use when single-key contention is the bottleneck
and the total may be eventually consistent.
- Approximate distinct count (HyperLogLog) — a fixed-size probabilistic
sketch (~12 KB) that counts unique items with ~2% error. Use for uniques at
scale where exact membership isn't needed (unique visitors, distinct search
terms).
- Time-windowed (bucketed) counters — key the counter by time bucket
(
views:{id}:2026-06-01T14), increment the current bucket, sum recent buckets
on read, expire old ones. Use for "last N minutes/hours" rate-style counts.
- Aggregate-on-read + cached total — sum shards (or roll up) periodically and
serve the cached number. Use when reads vastly outnumber writes and a slightly
stale total is fine (pairs with
caching).
Trade-offs
| Option | What it solves | What it worsens | Change it when |
|---|
| Single atomic counter | Simplest; exact; read-after-write trivial | One hot record caps write throughput; contention under spikes | Increments on one count exceed one node → shard the writes |
| Write-sharded counter | Spreads write load N-way; removes the hot spot | Reads cost N lookups + sum; total is eventually consistent; pick N up front | Read cost of summing N grows painful → cache the aggregate / roll up |
| HyperLogLog | Counts uniques in fixed tiny memory at huge scale | ~2% error; can't list members or do exact counts | Exact uniques or the member set is required → use a stored set |
| Time-windowed buckets | Cheap rolling/rate counts; old data self-expires | More keys; window boundaries need care; cross-bucket reads sum many keys | You need an exact lifetime total → keep a separate lifetime counter |
| Aggregate-on-read + cache | Cheap reads of a heavy-write count | Served total lags writes by the refresh interval | Reads must be fresh-to-the-write → read shards live (eat the N-sum) |
Behavior under stress
A counter is a tiny thing that punches above its weight in an outage.
- Hot-shard skew: if writes pick shards by
hash(userId) instead of random,
one viral actor or a bad hash can still pile onto one shard. Mitigate: pick
the shard at random per write; size N to peak contention, not average.
- Read amplification on spikes: when a count goes viral, reads of the total
multiply the N-shard sum across the read fan-out and can overload the store.
Mitigate: cache the aggregate and refresh on an interval, not per read
(→
caching).
- Lost increments: fire-and-forget increments (or a crash before flush in a
buffered/write-back path) silently undercount. Mitigate: use the store's
atomic increment, accept the eventual-consistency window explicitly, and
reconcile from a source of truth if exactness later matters.
- Window-boundary stampede: time-bucketed counters all roll to a new key at
the top of the hour — a synchronized cold bucket plus a flood of reads. Mitigate:
pre-create buckets and jitter rollups.
- Mass expiry: bucketed counters expiring together can spike the store.
Mitigate: stagger TTLs.
Monitor: per-shard write distribution (skew), increments/sec vs. node
ceiling, read-path latency for the N-sum, sketch error budget (HLL), and
under/over-count drift against any source of truth.
How to apply
- Clarify the inputs — peak increments/sec on the hottest single count,
exact-vs-approximate tolerance, occurrence-vs-distinct, read rate, and
freshness budget (see Clarify first). If no number shows one count is too
hot, stay on a single atomic counter (YAGNI).
- Pick from the trade-off table — single atomic if it fits one node;
write-sharded if single-key contention is the wall; HyperLogLog for uniques;
time-buckets for rolling windows. Combine (e.g. sharded + cached aggregate).
- Set the key knobs — choose N (shard count) from peak contention, the
shard-selection rule (random, not user-hashed), the read aggregation method,
bucket granularity + TTL for windows, and the cache refresh interval.
- Stress-test the choice — walk Behavior under stress: confirm shard
skew, read amplification, lost increments, and window boundaries each have a
mitigation the traffic profile actually needs.
- Size it with numbers — N ≥ peak increments/sec ÷ per-shard write ceiling;
confirm the N-sum read cost and any HLL error fit the budget
(→
back-of-the-envelope).
- Pick a provider — default to the generic recipe; open a provider file
only if the user named a cloud (see Choosing a provider).
Dos and don'ts
Do
- Start with a single atomic counter; shard only when a number shows one count
is the bottleneck.
- Pick the write shard at random so load spreads evenly regardless of the
actor.
- Cache the summed aggregate and refresh on an interval when reads dominate.
- Use HyperLogLog for uniques-at-scale and state the ~2% error as a known cost.
- Expire time-bucket keys with staggered TTLs and pre-create the next bucket.
- State the eventual-consistency window out loud — sharding trades exact-now for
throughput.
Don't
- Don't shard a counter that a single
INCR already handles (premature
sharding adds read cost for nothing).
- Don't hash the shard by user/entity ID — a hot actor reconcentrates the load.
- Don't sum N shards on every read of a viral count — cache the aggregate.
- Don't use a sharded/eventual counter where the number must be transactionally
exact (money, sell-out inventory) →
consistency-coordination.
- Don't reach for HyperLogLog when you also need the member list or an exact
count.
Numbers that matter
The deciding figure is peak increments/sec on the single hottest count vs. a
node's serialized write ceiling — that ratio sets N. A HyperLogLog sketch is
~12 KB for billions of uniques at ~2% standard error, regardless of cardinality
— the reason it beats a stored set at scale. Reading a sharded total costs N
lookups, so N trades write headroom for read cost. For QPS rates, per-node write
ceilings, and storage sizing, don't restate them here — see back-of-the-envelope.
Interface sketch
A sharded counter is a key contract, not one value:
- Write:
INCR counter:{id}:shard:{rand(0..N-1)} (atomic, fire to one shard).
- Read:
sum(GET counter:{id}:shard:{0..N-1}) — or read the cached aggregate
count:{id} refreshed every T seconds.
- Distinct:
PFADD uniq:{id} {member} then PFCOUNT uniq:{id} (HLL sketch).
- Windowed:
INCR views:{id}:{bucket} with a TTL; read sums the recent
buckets.
Decide N, the shard-selection rule, the aggregation/refresh policy, and the
window granularity up front — they are the contract, not implementation details.
Choosing a provider
Default to the generic recipe above. If the user names a cloud, read
references/providers/<provider>.md for the managed-service mapping,
quotas/limits, and provider-specific trade-offs. If no file exists for that
provider, the generic recipe is the answer.
Diagram
To visualize the fan-out write path (writer → random shard) and the
aggregate-on-read sum (read → N shards → cached total), use the in-plugin
architecture-diagram skill — shards share the store color, the read fan-out is
a dashed sum arrow, and the cached aggregate sits in the cache color.
Related building blocks
data-storage — depends on this for where the shards physically live;
sharding/partitioning theory and key design are owned there.
caching — pairs with this to serve the cached aggregate so a viral count's
reads don't re-sum N shards every time.
consistency-coordination — depends on this for the exact-vs-eventual count
decision; transactional/atomic semantics and quorum are owned there.
back-of-the-envelope — feeds into this: it supplies the per-count write
rate and per-node ceiling that justify sharding and set N.
system-design — owned-concept lives in the orchestrator: the reasoning
loop, the trade-off method, and the ten failure modes.
References
references/deep-dive.md — shard-count math, random vs. hashed selection,
HyperLogLog mechanics and error, time-bucket layout, roll-up/aggregation
patterns, and reconciliation. Read when designing the counter in detail.
references/providers/{generic,aws,azure,gcp}.md — service mappings,
atomicity/contention limits, and pitfalls per environment.