Follow-up to Microbench 3 that finally tests H5 (cache-size
dependence) and instruments worker-side connector callbacks the
original patch missed.
Patch v2 (apply_step_timing_v2.py) adds:
scheduler: `cache_size` field in engine_step.jsonl
worker: `get_finished_us` + `start_load_kv_us` in worker_step.r0.jsonl
uses BLOCK_BEGIN/END sentinels for safe multi-line revert
(the original v1 patch survives this v2's apply/revert cycle)
Driver: continuous open-loop (1.5 req/s, 4096x256 random per req)
that lets APC fill from 0 → ceiling within one vLLM lifetime so a
single run produces the full cache_size sweep. Decode-only steps
are filtered post-hoc to remove prefill-mix variance.
Findings (H20 96GB, ceiling reached ~17.5k blocks; n=15-18k decode
steps per config):
config | slope (μs / 1k blocks) | step_dur p50 @ |cache|=16.6k
---------------|------------------------|-----------------------------
mooncake_both | +85.6 | 1528 μs (build_meta=1442, 94%)
noop_connector | -0.8 (≈0) | 79 μs
plain | +1.0 (≈0) | 84 μs
Worker-side get_finished p50/p90/p99 (μs/step):
mooncake_both: 180 / 257 / 333
noop_connector: 0 / 0 / 2
H5 PASSES. mooncake_both step_duration scales linearly with |cache|
because build_connector_meta walks set(cache.keys()) every step
(`mooncake_connector.py:434-450`). plain and noop are flat.
The previously-uninstrumented get_finished() adds a constant
180 μs/step on top — two `run_coroutine_threadsafe(...).result()`
blocking waits in kv_both mode (`mooncake_connector.py:1107-1137`)
fire every step even when no transfer is pending.
Trace-replay reconciliation (APC ≈ 79% → |cache| ≈ 13k blocks):
build_meta @ 13k ≈ 1060 μs + get_finished ≈ 180 μs = 1.24 ms/step
On ~7 ms decode forward → +15-20% TPOT per step.
This explains most of the trace-replay +25% TPOT p90 gap from
single-instance per-step cost alone, leaving a smaller residual
for multi-instance coupling than originally assumed.
Two clear fixes pointed out in REPORT.md:
1. replace O(|cache|) per-step walk with incremental delta
listener using block_pool's add/remove callbacks
2. short-circuit get_finished() when both producer/consumer
queues are empty in kv_both
Heavy raw artifacts (engine_step.jsonl, vllm_stdout/stderr,
.vllm.pid) are .gitignored — they re-derive from `bash run_all.sh`
and SUMMARY.md / per_config.json fully capture the conclusions.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
4.3 KiB
Cache-size Sweep — testing H5 from connector_tax DESIGN.md
Hypothesis under test
H5: MooncakeConnectorScheduler.build_connector_meta() walks
set(self._block_pool.cached_block_hash_to_block._cache.keys()) every
scheduler step, so step_duration_us and build_meta_us should
grow linearly with |cache| (= the number of cached block-hash
entries in the block pool). The +45 % trace-replay tax is hypothesised
to come from running this O(|cache|) loop at APC ≈ 79 %, which the
prior microbench never tested (random content → cache stays small).
What we instrument
The original apply_step_timing.py only recorded
step_duration_us and build_meta_us. This sweep adds:
| Field | Source | Why |
|---|---|---|
cache_size |
len(scheduler.kv_cache_manager.block_pool.cached_block_hash_to_block._cache) |
The exact dict that set(...) walks |
get_finished_us |
wraps kv_connector.get_finished(...) in worker mixin |
The other suspected cost (two run_coroutine_threadsafe(...).result() blocking waits for kv_both) |
start_load_kv_us |
wraps kv_connector.start_load_kv(...) in worker mixin |
Mostly fast for kv_both w/o transfers, but include for completeness |
Scheduler-side fields go to engine_step.jsonl (existing channel).
Worker-side timings go to worker_step.jsonl (one file per worker
process).
Method
For each config in {plain, noop_connector, mooncake_both}:
- Launch one fresh vLLM (TP=1, H20, max_model_len=200000, gpu-memory-utilization=0.9, enable_prefix_caching).
- Read /metrics once to record
kv_cache_max_blocks(the dict ceiling). - Drive an open-loop stream:
- shape = 4096 in / 256 out
- rate = 2 req/s (kept below saturation to keep step duration dominated by scheduler-not-queueing)
- content random per request (UUID + hash), zero prefix-cache
hit ⇒
|cache|grows monotonically until hit by LRU eviction - duration = until cache fills (≤ 12 min)
- Collect
engine_step.jsonl+worker_step.jsonl+ the per-request metrics frombench_loop.py. - Tear down vLLM, wait for GPU release.
After all three configs:
- Apply LWESS-style binning on (
cache_size,step_duration_us) to show the curve per config. - Compute linear fit per config:
step_duration_us ≈ a + b · cache_size. - Connector-attributable per-step tax at a given |cache|:
tax_us(cache_size) = mc_step(cache_size) − plain_step(cache_size). - Same decomposition for
build_meta_us(only mooncake / noop have non-zero values; plain is 0 by construction). - For worker side:
get_finished_usdistribution per config; inkv_bothmode this should be non-zero even when no transfer fires.
What "passes" or "fails" H5
- PASS:
step_duration_us(mooncake_both) grows roughly linearly with |cache|, with slope > 5 μs / 1 000 blocks so that at |cache| ≈ 200 k it is ≥ 1 ms of per-step overhead.plainshows no slope. This matches the source code reading. - FAIL: no measurable slope, or slope is similar for plain and
mooncake_both → the O(|cache|) walk is not the actual cost driver
and we should look elsewhere (e.g.
get_finishedblocking waits, delay_free overhead).
Either outcome is informative.
What this sweep does not answer
- Multi-instance coupling (8 schedulers running the walk concurrently vs proxy load-balancing).
- Agentic session structure (long prefix reuse + short uncached tail).
- The 8-instance trace-replay 45 % figure can only be reconciled once we know the slope and combine with concurrency / coupling measurements. This sweep is a necessary input, not the full reconciliation.
Files
cache_sweep/
├── DESIGN.md # this file
├── apply_step_timing_v2.py # extends apply_step_timing.py with cache_size + worker timings
├── run_cache_sweep.py # bench driver: per-config continuous open-loop
├── analyze.py # join engine_step + worker_step, plot, fit
├── run_all.sh # orchestrator (apply patch → run 3 configs → revert → analyze)
└── results/<date>/ # one subdir per run
└── <config>/
├── engine_step.jsonl
├── worker_step.jsonl
├── requests.jsonl
├── summary.json
├── vllm_stdout.log
└── vllm_stderr.log