- Add Progress Snapshot table to the intern TODO so per-batch status (DONE / partial / blocked-on-instrumentation) is visible at a glance. - New analysis/claude_characterization_work_plan.md scopes the Phase A instrumentation tasks (A1-A5) plus Window 1 (B1'+B2+B3) and Window 2 (B4+B5) on dash0, with locked decisions for model, topology, trace, SLO style, and GPU phasing. Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
361 lines
14 KiB
Markdown
361 lines
14 KiB
Markdown
# Claude Characterization Work Plan
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Status: planning, awaiting dash0 idle
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Date: 2026-05-25
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Owner: Claude (not interns)
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Source of requirements: `analysis/characterization_todo_for_interns.md`
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## Scope
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This plan covers the four hard gates and the B2–B5 GPU experiments that the
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intern TODO marks as `NOT DONE` / `protocol DONE`. The B0 analyzer, the
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B1 trace-shape statistics, and the B6 audit scaffold are already done; this
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plan does **not** re-do them, only refreshes their inputs.
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The work is split into:
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- **Phase A (CPU-only)** — instrumentation + analyzer extensions. Can run
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on the local dev box; does **not** need dash0. Must finish before any
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GPU run.
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- **Phase B (dash0 GPU)** — controlled microbench + routing sweep + SRR
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sweep + failure attribution.
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- **Phase C (CPU-only)** — final audit package refresh.
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## Phase A: Instrumentation + Analyzer (CPU-only, before dash0)
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### A1. Replayer instrumentation — close Gate 1 + Gate 2
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File: `replayer/metrics.py`, `replayer/replay.py`
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Add these fields to `RequestMetrics`:
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```text
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t_dispatch_unix float # absolute wall-clock when POST starts
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t_first_token_unix float # absolute wall-clock at first stream chunk
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t_finish_unix float # absolute wall-clock at stream done or error
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proxy_request_id str # value sent in X-Request-Id (matches breakdown)
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endpoint_url str # which proxy/instance the request hit
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trace_hash_ids list[int] # carried from trace for reuse joins
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```
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Change `_dispatch_request` to:
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- send a deterministic `X-Request-Id: <session_id>:<turn_id>` header (so
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proxy breakdown can be joined to metrics by exact key);
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- record `time.time()` (unix) at dispatch, first token, finish; keep
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`perf_counter` for the latency arithmetic.
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Acceptance: a 30-request smoke run produces `metrics.jsonl` where every
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row has those fields; `breakdown.json` rows from the proxy have the same
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`request_id` keys.
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Effort: 1 small PR. Pure CPU.
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### A2. Proxy instrumentation — close Gate 1 + Gate 3 + Gate 4
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File: `scripts/cache_aware_proxy.py`
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Changes:
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1. Honor incoming `X-Request-Id`: if header present, use it instead of
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generating a new uuid. Falls back to uuid otherwise.
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2. Record on every breakdown row:
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- `session_id` (already on header, not currently stored)
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- `input_length`
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- `estimated_new_tokens` (already produced by router)
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- `candidate_scores` (list of `{url, p_tokens_score, cache_score, bs,
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occupancy}`)
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- `chosen_score`
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3. At route decision time, snapshot per-worker state:
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- `pending_prefill_tokens` per worker
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- `running_decode_requests` per worker
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- `kv_blocks_used` / `kv_blocks_total` per worker
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- `apc_hits` / `apc_queries` cumulative per worker
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Write to a separate `worker_state.jsonl` (one line per route decision)
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with `(t_decision_unix, request_id, per_worker_state)`.
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4. New endpoint `GET /worker_state` returns the latest snapshot per worker
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(for sanity / live debugging).
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Acceptance: smoke run produces `breakdown.json` with new fields and a
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non-empty `worker_state.jsonl` that joins to breakdown by `request_id`.
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Effort: 1 medium PR. Pure CPU + light proxy work.
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### A3. Engine-side step timestamps — close Gate 3 for B2
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vLLM 0.18.1 already exposes:
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- `vllm:request_prefill_time_seconds` (histogram, per-request)
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- `vllm:request_decode_time_seconds`
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- `vllm:time_per_output_token_seconds`
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- step-level scheduler stats via `engine.async_step` logging
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For B2 we need decode-step and prefill-chunk timestamps with worker id.
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Plan:
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1. Inspect whether the vLLM proxy can be polled at high rate (e.g.
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100 Hz) for per-engine scheduler counters
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(`num_running`, `num_waiting`, `gpu_cache_usage`,
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`prefix_cache_queries`, `prefix_cache_hits`). If yes, sample
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into `engine_state.jsonl` during runs.
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2. If finer step-level data is needed, patch one vLLM file
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(`vllm/engine/async_llm_engine.py` step loop or
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`vllm/v1/core/sched/scheduler.py`) to emit a JSONL line per
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scheduler step with `(t_unix, worker_id, num_prefill_tokens_scheduled,
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num_decode_steps, running_request_ids)`. Patch goes under `patches/`
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so it can be applied/reverted cleanly.
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3. Worker id mapping: when running TP1xDP8 or similar, each engine
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listens on a distinct port; `worker_id == endpoint_url`.
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Acceptance: a single 10-minute run produces `engine_state.jsonl` from
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which a decode step at time T on worker W can be classified as
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"overlapping a same-worker prefill chunk" or not.
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Effort: 1 medium investigation (decide poll vs patch) + 1 medium PR.
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### A4. Open-loop session-causal loadgen for B4
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File: `replayer/replay.py` (new mode) or new `replayer/srr_loadgen.py`
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Current replayer dispatches by trace timestamps. SRR sweep needs:
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- pool of session templates (each = ordered list of turns from the
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trace);
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- Poisson arrivals of new sessions at rate `lambda`;
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- within a session: strict sequentiality (turn N+1 waits for turn N
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finish);
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- per-run warmup window (e.g. 60s) + steady-state window (e.g. 300s);
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- attempted / completed / error counters per window.
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Add a new mode `--mode srr --arrival-rate <lambda>
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--warmup-s 60 --steady-s 300 --session-pool-size N`. The trace
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file becomes the pool; sessions are drawn with replacement.
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Acceptance: at `lambda = 0.5 sess/s`, the run shows exponential inter-
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arrival times and per-session sequentiality in `metrics.jsonl`. A
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`window_summary.json` lists warmup vs steady-state attempted/completed.
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Effort: 1 medium PR.
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### A5. Analyzer extensions
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File: `analysis/characterization/analyze.py` (extend, do not rewrite)
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Add:
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1. **Joined-record builder.** Given `--metrics metrics.jsonl
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--breakdown breakdown.json --worker-state worker_state.jsonl
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--engine-state engine_state.jsonl`, produce
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`joined.jsonl` keyed on `request_id` with all fields merged.
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2. **Reuse decomposition (real).** Using joined records that carry
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`session_id` + `hash_ids` + `cached_tokens`, compute
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`intra_session` / `cross_session` / `shared_prefix` /
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`unclassified` cached-token mass. Replaces the current
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`status: unavailable` placeholder when fields are present.
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3. **Interference index.** Per decode step, label "overlap same-
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worker prefill" using `engine_state.jsonl`. Compute
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`TPOT_p90(overlap) / TPOT_p90(no_overlap)`.
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4. **Hotspot index.** Per worker queue delay p90, output
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`max_worker_q_p90 / median_worker_q_p90`.
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5. **Failure label.** For each slow / SLO-violating request, assign
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one of: `same_worker_prefill_overlap`, `hot_worker_queue`,
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`high_kv_occupancy`, `cache_miss_large_append`, `transfer_wait`,
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`p_queue_wait`, `d_admission_wait`, `unknown`.
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6. **Window summary.** For SRR runs, compute attempted/completed/
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error/goodput plus latency percentiles on the steady-state
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window only.
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Acceptance: re-run analyzer on smoke output and confirm `reuse_decomposition`
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no longer says `unavailable`; `interference_index.json` produced when
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engine state present; `failure_breakdown.json` populated when
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labels assigned.
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Effort: 1 large PR. CPU-only.
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## Phase B: GPU experiments (needs dash0)
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### B1' Workload characterization closure
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Inputs: instrumented replayer + small smoke trace (≤500 req).
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Steps:
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1. Pick `kv_bytes_per_token` for the production model. For
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Qwen3-Coder TP1 the value depends on layer/head config; compute
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from `vllm.config` once at run start and record in manifest.
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2. Re-run analyzer on full GLM-5.1 trace with `--kv-bytes-per-token`.
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Output: KV footprint p50/p90/p99 in `kv_footprint_summary.json`.
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3. Run a 1k-request session-causal smoke replay with instrumented
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proxy. Use the joined records to populate real reuse decomposition
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for the small sample. (Full-trace replay is too expensive; sample
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is acceptable for the decomposition claim.)
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Wall-clock: ~30 min GPU. Produces 2 figures: KV footprint CDF, reuse
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decomposition stacked bar.
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### B2 PD-colo interference microbench
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Setup: 1 combined instance on TP1. Two synthetic load generators:
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1. **Decode-only steady load** — short-prompt sessions at fixed
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per-second arrival, designed to saturate decode without prefill
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contention.
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2. **Prefill injector** — single-shot long-prompt requests at
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controlled cadence; same worker (target the decode worker) vs
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different worker (route to a paired idle instance).
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Sweep `uncached_prefill_tokens ∈ {2k, 8k, 16k, 32k, 64k}` × `{same,
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different} worker`.
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Outputs: `interference_microbench_summary.json`,
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`decode_step_timeseries.csv` (from `engine_state.jsonl`),
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`prefill_overlap_events.jsonl`, `interference_index.json`,
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TPOT-with-overlay figure, interference-index-vs-prefill-size figure.
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Wall-clock: ~2–3 h GPU including warm-up between sweeps.
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### B3 Routing sweep on session-causal trace
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Setup: 8 combined instances (TP1 × DP8) with the cache-aware proxy.
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Run the same session-causal trace (e.g. r=0.0015 st=30 850-req config
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from auto-mem `feedback-bench-config.md`) under five policies:
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1. corrected LMetric / cache-aware (`--policy lmetric`)
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2. load-only (new policy `--policy load_only` — picks min running)
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3. hard sticky (new policy `--policy sticky` — once a session lands
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on a worker, never moves)
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4. current Unified hybrid (`--policy unified`)
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5. session-mass capped replay (filter the trace so no session exceeds
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`cap_turns` or `cap_input_tokens`; rerun policy 1)
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Per run, collect: replayer metrics, proxy breakdown, worker_state,
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engine_state. Compute per-worker queue delay, GPU util, KV occupancy,
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APC, session-to-worker map.
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Outputs: `worker_balance_summary.json`, `session_to_worker_map.json`,
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`session_mass_summary.json`, `routing_policy_comparison.json`,
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`hotspot_index.json`, `capped_session_replay_summary.json`,
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8 figures from the TODO list (§5.figures).
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Wall-clock: 5 runs × ~13 min ≈ 1.5 h GPU.
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Implementation note: `load_only` and `sticky` are small additions to
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`scripts/cache_aware_proxy.py` — they reuse existing affinity / score
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machinery.
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### B4 Sustainable Request Rate sweep
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Setup: same 8 instances. Use Phase-A `--mode srr` loadgen.
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SLO (locked per-class):
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```text
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TTFT_p90 <= 2.0 s
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TPOT_p90 <= 0.15 s
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error_rate <= 0.5%
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queue length stable (no monotone growth over steady window)
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KV occupancy stable
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E2E_p90 <= T_class[c] for each output-length decile c
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```
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`T_class[c]` is derived from a low-load reference run as
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`E2E_p90_low_load(c) * 2` (factor configurable). The reference run
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is done once and cached as `analysis/characterization/srr/slo_classes.json`.
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Per policy sweep `lambda` from low (clearly safe) to high (clearly
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broken) using a bisection-ish search:
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```
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λ_low = 0.1 sess/s
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λ_high = doubling until first SLO violation
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binary-search λ_low .. λ_high for max sustainable λ
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```
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Policies covered: LMetric, static PD-disagg, Unified, hard sticky,
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load-only.
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Outputs: `srr_curve.json`, `lambda_runs/<lambda>/summary.json`,
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`slo_violation_reason.json`, `goodput_vs_arrival_rate.json`,
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`stability_summary.json`, all 8 figures from §6.figures.
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Wall-clock: this is the most expensive batch. With binary search,
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~6 lambda points × 5 policies × ~8 min (warmup + steady) ≈ 4 h GPU.
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### B5 Failure attribution near SRR boundary
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For each policy: pick `λ ∈ {0.9, 1.0, 1.1} × SRR`, run with full
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instrumentation, then run the analyzer's failure-label step.
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Outputs: `slow_request_attribution.jsonl`, `failure_breakdown.json`,
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`case_studies.md`, `worker_failure_windows.json`, 5 figures from §7.
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Wall-clock: 3 lambdas × 5 policies × 8 min ≈ 2 h GPU.
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## Phase C: Audit package refresh (CPU)
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Re-run `summarize_runs.py` and `plot_current_results.py` after each
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GPU batch. Final pass after B5: refresh `claim_matrix`, `risk_register`,
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`allowed_runs`, regenerate all figures, update
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`reproduction_commands.sh`.
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Effort: ~1 h CPU.
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## Sequencing & rough timeline
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```text
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Phase A (CPU, before dash0):
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A1 + A2 (parallel) ~half day CPU
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A3 patch (scheduler.py) ~half day CPU
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A4 SRR loadgen ~half day CPU
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A5 analyzer extensions ~1 day CPU
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Window 1 on dash0 (B2 + B3 only, ~5 h GPU):
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smoke validation of A1–A4 ~30 min GPU
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B1' KV footprint + reuse decomp ~30 min GPU
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B2 interference microbench ~3 h GPU
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B3 routing sweep (5 policies) ~1.5 h GPU
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Phase C partial refresh ~30 min CPU
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── HARD STOP, hand results back ──
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Window 2 on dash0 (B4 + B5, ~6 h GPU, only after review):
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B4 SRR sweep (5 policies × bisect) ~4 h GPU
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B5 failure attribution ~2 h GPU
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Phase C final refresh ~1 h CPU
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```
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## Decisions (locked 2026-05-25)
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1. **Target model**: Qwen3-Coder-30B-A3B. Compute
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`kv_bytes_per_token` from this model's config at manifest time.
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2. **GPU topology**: TP1 × 8 vLLM instances (DP8). All proxies and
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sweeps assume 8 worker endpoints.
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3. **Trace for B3/B4**: `traces/w600_r0.0015_st30.jsonl` (~850
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requests). No resampling.
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4. **E2E SLO**: per-class. Split requests by `requested_output_tokens`
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decile, set separate E2E thresholds per class. No normalized-E2E
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headline.
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5. **vLLM scheduler patch**: accepted. Step-level JSONL log goes
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through a patch under `patches/`. Polling falls back to per-engine
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`/metrics` for sanity only.
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6. **GPU phasing**: hard stop after B2 and B3. Hand results back for
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review before committing to B4 SRR sweep or B5 attribution.
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## What stays with the interns
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- Re-running `summarize_runs.py` after each GPU batch (mechanical).
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- Reviewing the auto-generated `current_results.md` for typos.
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- Maintaining `main_claim_allowed_runs.md` if new traces are added.
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- Anything reading the audit package — not extending it.
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## Out of scope for this plan
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- New routing policy design (Unified-v2 / PUSH variants).
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- Production-grade KV transfer engineering.
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- Any change to the production paper figures in
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`analysis/pd_sep_paper_section/`.
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- vLLM upstream contributions.
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These are downstream of characterization; once B2/B3/B5 attribution is
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in, we decide separately.
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