The §3.2 cost-vs-benefit math in commits029821c(MB1 plot + pd_cost_vs_benefit.png) andabde010(RESULTS_SUMMARY.md) was wrong. What was wrong: I framed PD-disagg's max phase-isolation benefit as "≤ decode duration of the new request (~50–200 ms)" — implicitly treating the benefit as per-request and bounded by that request's own decode. The correct accounting is per-prefill-event across all stalled streams: benefit_per_prefill = D × T_prefill × (1 − TPOT_baseline/TPOT_during) ≈ D × T_prefill which follows from the chunked-prefill math (each of L/N chunks slows D ongoing decode steps from ~10 ms to t ms, summing to D × T_prefill). Plug MB1 + MB2 numbers in: prefill size | T_prefill | T_transfer | D=8 benefit | cost/benefit 2k tok | 0.14 s | 8 ms | 1.1 s | 0.7 % 33k tok | 4.5 s | 320 ms | 36 s | 0.9 % 125k tok | 57 s | 1.9 s | 456 s | 0.4 % On the phase-isolation axis alone, PD-disagg WINS by 100×–250× — the opposite of what the deleted figure showed. The actual dominant reason static PD-disagg fails in agentic is the D-side KV pool capacity wall (figs/f4b_pdsep_kv_wall.png) — p99 single-request KV is 11.5 GiB, per-D-instance pool is 38 GiB, so 4P+4D halves system decode capacity. Colleague's 4P+4D experiment showed TTFT p50 62× worse and success rate 99.5% → 52%, driven by pool overflow + queueing, not by transfer latency. Changes (all touched files explicitly listed; no `git add -u`): - figs/pd_cost_vs_benefit.png : DELETED (figure built on wrong math) - microbench/fresh_setup/plot_mb1.py : drop the pd_cost_vs_benefit function; keep mb1_interference.png and update its title to note per-prefill aggregate stall = D × T_prefill (not capped by decode) - figs/mb1_interference.png : regenerated, no misleading band annotation - analysis/mb1/README.md : Summary block rewritten ("what MB1 measures"; no more "max benefit = decode duration" claim); §3.2 implications section replaced with the corrected per-prefill-event table; explicit ⚠ Correction note documents what was wrong - analysis/mb2/README.md : Summary block + §3.2 implications section rewritten the same way; ⚠ Correction note links to RESULTS_SUMMARY §4 - RESULTS_SUMMARY.md §4 + §6 : §4 reordered to lead with the D-side capacity argument (the real failure mode), MB1/MB2 demoted from "kill-shot for PD-disagg" to "supporting context inputs to a cost-benefit table that actually favors PD-disagg on this axis"; §6 paper-claims list reordered to remove the wrong "PD-disagg loses on cost-vs-benefit" claim and replace with the corrected ones PAPER_OUTLINE.md and MEETING.md were checked and never picked up this specific wrong claim — they already (correctly) frame §3.2 around the D-side KV memory wall. Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
194 lines
9.1 KiB
Markdown
194 lines
9.1 KiB
Markdown
# MB1 — Prefill–Decode Interference (chunked-prefill on, vLLM 0.18.1 default)
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Persistent record of the phase-interference microbench used to put a
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quantitative upper bound on **what PD-disaggregation can buy** under the
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chunked-prefill-on baseline. Re-runs append a dated section at the
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bottom; the **Summary** block is what gets cited.
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---
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## Summary (latest)
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| Headline | Value |
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|---|---|
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| Baseline single-stream TPOT (D=1, idle GPU) | **4.8 ms** |
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| Effective per-stream TPOT during **8k-token** prefill burst (D=8) | **114 ms (≈15× baseline)** |
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| Effective per-stream TPOT during **32k-token** prefill burst (D=8) | **388 ms (≈52×)** |
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| Effective per-stream TPOT during **131k-token** prefill burst (D=8) | **1419 ms (≈183×)** |
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**What MB1 actually measures**:
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> During a prefill burst, every ongoing decode stream is essentially
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> halted (per-stream effective TPOT is 15×–2000× baseline, scaling with
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> prefill size). The **total decode time lost per prefill event is
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> `D × T_prefill`** (D concurrent decodes each lose ~T_prefill of useful
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> work). For the trace mean (P ≈ 33k tokens, T_prefill ≈ 4.5 s) at D=8
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> that's **~36 seconds of decode-equivalent work lost per request**.
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> This is the **upper bound on what PD-disaggregation's phase isolation
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> could recover** on the decode side.
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**⚠ Correction (2026-05-27)**: an earlier version of this README framed
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the §3.2 PD-disagg argument as "phase-isolation benefit is capped at
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the decode duration of the new request (~50–200 ms), so MB2 transfer
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cost dominates". That framing was wrong. The correct accounting is
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benefit-per-prefill-event = D × T_prefill (aggregate decode time saved
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across all stalled streams), which is **much larger than per-request
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transfer cost**. The actual reason static PD-disagg fails in agentic
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is **D-side KV pool capacity** (`figs/f4b_pdsep_kv_wall.png`), not a
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cost-vs-benefit imbalance on phase isolation. See `RESULTS_SUMMARY.md`
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section 4 for the corrected framing.
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## Setup
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| Component | Value |
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|---|---|
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| Host | dash1, H20 96 GiB, driver 570.133.20 |
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| Venv | `/home/admin/cpfs/wjh/agentic-kv-fresh/.venv` |
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| vLLM | 0.18.1 official wheel (chunked-prefill default-on, V1 engine) |
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| Model | `/home/admin/cpfs/wjh/models/Qwen/Qwen3-Coder-30B-A3B-Instruct` |
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| Launch flags | `--tensor-parallel-size 1 --enable-prefix-caching --gpu-memory-utilization 0.9 --max-model-len 200000 --max-num-batched-tokens 8192` |
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| kv_connector | **none** (this measures pure single-GPU phase interference; PD-disagg cost lives in MB2) |
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## Method
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Adapted from `microbench/interference/driver.py`:
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1. Start D streaming decode requests on `/v1/chat/completions` with a
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long max_tokens cap. Discard the first 32 tokens as warmup.
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2. After 1 s, inject one prefill-only request with `max_tokens=1` and
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an input of `P` synthetic tokens (uuid-seeded for zero prefix-cache
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reuse). Measure the prefill's TTFT.
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3. Bin the *during-prefill* tokens from each decode stream by whether
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their wall-clock falls inside `[prefill_inject_ts, prefill_inject_ts +
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prefill_ttft]`. Report inter-token p50 / p90.
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4. Bin a baseline run (D streams, no prefill injection) the same way.
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We additionally compute the **effective per-stream TPOT during the
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prefill burst** as the single most informative summary:
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```
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eff_TPOT_during = prefill_ttft_ms / (num_tokens_during_prefill / D)
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```
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This is the average rate at which each decode stream produces tokens
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while a prefill is in flight. Compared to baseline TPOT it gives the
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real per-stream throughput penalty (chunked-prefill p50 looks deceptively
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fine because most decode-token intervals during the burst are at normal
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speed; p90 sees the stall but is itself noisy; the effective TPOT is
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the cleanest "average over the whole burst window" number).
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## Results — 2026-05-27, dash1 GPU 0, chunk_tokens=8192
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3 D × 5 P × 3 reps. Aggregated by `analyze_mb1.py`.
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| D | P (tok) | base TPOT (ms) | prefill_ttft (ms) | per-stream tokens during | effective TPOT during (ms) | penalty | max PD-disagg benefit per stream (ms) |
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|--:|--:|--:|--:|--:|--:|--:|--:|
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| 1 | 2 048 | 4.79 | 163 | 4.0 | 41 | 8× | 144 |
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| 1 | 8 192 | 4.78 | 584 | 5.0 | 117 | 24× | 560 |
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| 1 | 32 768 | 4.78 | 4 515 | 5.0 | 903 | 189× | 4 491 |
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| 1 | 65 536 | 4.78 | 15 568 | 5.3 | 2 919 | 610× | 15 542 |
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| 1 | 131 072 | 4.78 | 56 765 | 5.7 | 10 017 | 2 094× | 56 738 |
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| 4 | 2 048 | 5.62 | 138 | 3.9 | 36 | 6× | 117 |
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| 4 | 8 192 | 6.08 | 574 | 4.5 | 128 | 21× | 547 |
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| 4 | 32 768 | 6.09 | 4 529 | 11.9 | 381 | 63× | 4 457 |
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| 4 | 65 536 | 5.85 | 15 587 | 19.8 | 789 | 135× | 15 471 |
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| 4 | 131 072 | 6.27 | 56 697 | 37.4 | 1 517 | 242× | 56 463 |
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| 8 | 2 048 | 7.71 | 143 | 4.5 | 32 | 4× | 109 |
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| 8 | 8 192 | 7.69 | 583 | 5.1 | 114 | 15× | 544 |
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| 8 | 32 768 | 7.42 | 4 520 | 11.7 | 387 | 52× | 4 434 |
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| 8 | 65 536 | 7.67 | 15 615 | 20.6 | 757 | 99× | 15 457 |
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| 8 | 131 072 | 7.74 | 56 991 | 40.2 | 1 419 | 183× | 56 680 |
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**Reading the table**:
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- *Baseline TPOT* grows mildly with D (4.8 ms → 7.7 ms as D goes 1 → 8).
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Multi-stream decoding has small but nonzero contention even without
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prefill.
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- *Effective TPOT during* grows mostly with P: a single 8k prefill stalls
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decode for ~580 ms regardless of D, so each stream emits only a handful
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of tokens during that 580 ms window — effective per-stream TPOT
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collapses to 100–130 ms. Larger prefill = more chunks = larger stall.
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- *Penalty* is the eff/baseline ratio. Above 50× for P ≥ 32k. Above
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500× for D=1 at P ≥ 65k.
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- *Max PD-disagg benefit per stream* = `prefill_ttft − per_stream_tokens
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× baseline_TPOT` ≈ `prefill_ttft` (since interference essentially
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halts decode). This is the entire prefill duration's worth of decode
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time that could in principle be recovered.
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**Connecting to the §3.2 PD-disagg argument** (corrected):
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PD-disagg's promised phase-isolation benefit is **per prefill event**,
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not per request. When a new prefill arrives, it stalls every concurrent
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decode stream on the same GPU. The aggregate decode time lost across
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those D streams is `D × T_prefill`. PD-disagg moving prefill off-decode-GPU
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recovers all of it.
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Plugging numbers per prefill event:
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| Prefill size | T_prefill | PD-disagg cost (MB2 T_transfer) | PD-disagg benefit (D=8 × T_prefill) | Ratio |
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|---:|---:|---:|---:|---:|
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| 2k tok (trace lower) | 0.14 s | 8 ms | 1.1 s | 0.7 % |
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| 33k tok (trace mean) | 4.5 s | 320 ms | 36 s | 0.9 % |
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| 125k tok (~p99) | 57 s | 1.9 s | 456 s | 0.4 % |
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On the **phase-isolation axis alone**, PD-disagg wins by 100×–250×.
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The reason static PD-disagg nonetheless **fails in agentic** is a
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*different* failure mode: the D-side KV pool cannot fit p90+ requests
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(p99 = 11.5 GiB; D-instance pool ≈ 38 GiB; 4P+4D halves system-wide
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decode capacity → TTFT p50 62×, success rate 99.5% → 52% in colleague's
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4P+4D experiment). The structural problem is **capacity** (see
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`figs/f4b_pdsep_kv_wall.png`), not transfer-cost vs phase-isolation
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trade-off.
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## Reproduction
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```bash
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# vllm pair-free single-instance launch
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ssh dash1 'GPU=0 PORT=8000 CHUNK_TOKENS=8192 \
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bash /home/admin/cpfs/wjh/agentic-kv-fresh/scripts/mb1_launch.sh start'
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# sweep
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ssh dash1 'source /home/admin/cpfs/wjh/agentic-kv-fresh/.venv/bin/activate && \
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python /home/admin/cpfs/wjh/agentic-kv-fresh/scripts/mb1_driver.py \
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--host 127.0.0.1 --port 8000 \
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--model /home/admin/cpfs/wjh/models/Qwen/Qwen3-Coder-30B-A3B-Instruct \
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--decode-batch-sizes 1,4,8 --prefill-tokens 2048,8192,32768,65536,131072 \
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--reps 3 --output-dir /home/admin/cpfs/wjh/agentic-kv-fresh/mb1_results'
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# pull + analyze
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scp dash1:/home/admin/cpfs/wjh/agentic-kv-fresh/mb1_results/chunk8192/summary.csv \
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analysis/mb1/summary.csv
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.venv/bin/python microbench/fresh_setup/analyze_mb1.py \
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--summary analysis/mb1/summary.csv --out analysis/mb1/breakdown.json
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.venv/bin/python microbench/fresh_setup/plot_mb1.py \
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--mb1 analysis/mb1/breakdown.json \
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--mb2-intra analysis/mb2/intra_kvboth_breakdown.json \
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--mb2-inter analysis/mb2/inter_kvboth_breakdown.json
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# teardown
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ssh dash1 'bash /home/admin/cpfs/wjh/agentic-kv-fresh/scripts/mb1_launch.sh stop'
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```
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## Open questions / next runs
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- **Chunk size sensitivity**: this run uses `--max-num-batched-tokens
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8192`. Sarathi-Serve goes smaller (e.g. 1024) and recovers more
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decode interleaving inside each prefill burst. Worth running
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chunk_tokens ∈ {1024, 2048, 4096, 16384} to map the chunk-size axis.
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- **Higher D**: 12, 16 streams to see whether the penalty saturates or
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keeps shrinking per-stream.
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- **Cross-validate effective_TPOT_during with token-time-series plot**:
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raw per-token timestamps could reveal whether the stall is a few big
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spikes or many small ones (currently inferred from p50/p90 spread).
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## Run log
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### 2026-05-27 — dash1 GPU 0, chunk_tokens=8192
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3 × 5 × 3 sweep. CSV: `analysis/mb1/summary.csv`. Per-config JSONs on
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dash1 at `/home/admin/cpfs/wjh/agentic-kv-fresh/mb1_results/chunk8192/`.
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Figure: `figs/mb1_interference.png`. The figure
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`figs/pd_cost_vs_benefit.png` from the original commit `029821c` was
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based on the wrong "benefit ≤ decode duration" accounting; **deleted in
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the correction commit**.
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