4 experiments: baseline vs elastic × linear vs lmetric Using corrected trace (w600_r0.0015_st30, 70% multi-turn, APC~76%) and fixed elastic PS (D accounting, offload cap, cache sync). Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
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4.0 KiB
Elastic PS Evaluation Plan
Goal
Compare baseline (PD-combined) vs elastic PS (selective prefill offload) under production-realistic trace on 8×H20.
Context
The baseline (baseline_r0015_st30, 912 req) shows:
- TPOT p90=0.175s (vs 0.073s at 1 req/GPU) — prefill-decode interference is real
- APC=67.5% with per-instance range 46–84%
- 58% of requests are HEAVY (≥20k), consuming 89% of input tokens
Elastic PS offloads HEAVY prefills to a different GPU via Mooncake RDMA, isolating decode from prefill interference. Recent bug fixes:
- D instance now accounted during prefill phase (prevents D overload)
- MAX_OFFLOAD_INFLIGHT=4 cap prevents runaway offloads
- D's proxy cache updated after decode (preserves session cache locality)
Machine
dash0: 8×H20 96GB, NVLink, 4×CX7 200Gbps RDMA. SSH: ssh dash0.
Trace
traces/w600_r0.0015_st30.jsonl on dash0 (1214 requests, 688 sessions, 70% multi-turn).
Use --requests 850 for ~13 min wall clock.
Experiments
Experiment 1: Baseline (Linear, PD-combined)
cd ~/agentic-kv && source .venv/bin/activate
bash scripts/bench.sh \
--tag eval_baseline_linear \
--mode baseline --policy linear \
--trace traces/w600_r0.0015_st30.jsonl \
--requests 850
Experiment 2: Elastic PS (Linear, kv_both + offload)
bash scripts/bench.sh \
--tag eval_elastic_linear \
--mode elastic --policy linear \
--trace traces/w600_r0.0015_st30.jsonl \
--requests 850
Experiment 3: Baseline (LMetric, PD-combined)
bash scripts/bench.sh \
--tag eval_baseline_lmetric \
--mode baseline --policy lmetric \
--trace traces/w600_r0.0015_st30.jsonl \
--requests 850
Experiment 4: Elastic PS (LMetric, kv_both + offload)
bash scripts/bench.sh \
--tag eval_elastic_lmetric \
--mode elastic --policy lmetric \
--trace traces/w600_r0.0015_st30.jsonl \
--requests 850
What to Measure
For each experiment, collect from outputs/<tag>/:
metrics.summary.json: TTFT (mean/p50/p90), TPOT (mean/p50/p90), E2E, success rateapc.txt: per-instance prefix cache hit ratebreakdown.json: per-request routing class (WARM/MEDIUM/HEAVY_COLO/HEAVY_OFFLOAD/HEAVY_COLO_FALLBACK)stats.json: per-instance load at end
Analysis
After all 4 experiments, compare:
import json
def summarize(path):
s = json.load(open(path))
return {
"ok": "%d/%d" % (s["success_count"], s["request_count"]),
"ttft_mean": "%.2f" % s["ttft_stats_s"]["mean"],
"ttft_p50": "%.2f" % s["ttft_stats_s"]["p50"],
"ttft_p90": "%.2f" % s["ttft_stats_s"]["p90"],
"tpot_mean": "%.4f" % s["tpot_stats_s"]["mean"],
"tpot_p50": "%.4f" % s["tpot_stats_s"]["p50"],
"tpot_p90": "%.4f" % s["tpot_stats_s"]["p90"],
"e2e_p50": "%.2f" % s["latency_stats_s"]["p50"],
}
for tag in ["eval_baseline_linear", "eval_elastic_linear",
"eval_baseline_lmetric", "eval_elastic_lmetric"]:
path = "outputs/%s/metrics.summary.json" % tag
print("%-30s %s" % (tag, summarize(path)))
Key questions:
- Does elastic PS reduce TPOT? (expect: yes, by isolating heavy prefills from decode)
- Does elastic PS hurt TTFT? (expect: some increase from RDMA overhead on offloaded requests)
- What's the net E2E impact? (TPOT improvement vs TTFT overhead)
- How many requests actually get offloaded? (check breakdown.json HEAVY_OFFLOAD count)
- Does the offload cap (MAX_OFFLOAD=4) get hit? (check breakdown for "cap_reached")
- Per-instance APC: does D maintain cache after migration? (compare APC spread)
Expected Results
Based on analysis:
- HEAVY requests: 58% of total, 89% of tokens
- TPOT reduction potential: ~66% for WARM/MEDIUM (from 0.11 to 0.038)
- RDMA overhead: ~1-15s per offloaded request (bimodal)
- Net: TPOT should improve if offload successfully isolates prefill
- Risk: Mooncake kv_both memory overhead may negate gains (was +11% TPOT in prior experiment at low concurrency)