scripts/b2_interference.py is the controlled microbench. It runs two
coroutines against the open proxy bypass (direct vLLM endpoints):
- decode_load: continuous short-prompt requests at fixed QPS into a
designated decode instance, to keep it decode-saturated.
- prefill_injections: N large one-token requests at fixed interval,
pointed at either the same instance (same-worker variant) or a
paired one (different-worker control).
Each cell (variant × prefill_size) gets its own metrics.jsonl plus a
run_window.json containing t_start_unix/t_end_unix. The shared
engine_*.jsonl from the scheduler patch is sliced by that window in
the aggregator.
analysis/characterization/b2_sweep_analysis.py walks the cell tree,
slices the per-worker step log by each cell's window, runs the A5
interference_index() against the slice, and emits a single
b2_sweep_summary.json with one row per cell. This is what feeds the
"interference vs uncached prefill size" figure.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Smoke validation on dash0 surfaced three real bugs that broke
interference and failure-attribution labels end-to-end:
1. endpoint_url in metrics is the proxy URL (e.g. http://h:9200);
the vLLM worker URL lives in breakdown's routed_to. The
interference index and label path were taking endpoint_url first,
so every request looked routed to a non-existent worker and the
overlap counter stayed at zero.
2. _normalize_worker hard-coded base port 8000, so a smoke run on
port 9100 resolved to engine_1100 instead of engine_0. Added a
--worker-map URL=engine_id CLI flag and _resolve_worker() that
prefers the explicit map and falls back to the heuristic.
3. vLLM rewrites the per-step rid as cmpl-<proxy_id>-<i>-<hash>, so
the str equality check between per_req rid and our proxy
request_id never matched -> every prefill step looked like
"other request prefill", which would have flipped overlap to
100%. Added _vllm_rid_matches() that strips the cmpl-/chatcmpl-
prefix.
After the fix, the same smoke run reports interference_index = 22.9
across 24 overlap / 6 clean requests on a single instance, which is
the expected shape for serial dispatch into a cold engine.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Captures 5 runs from the experiment matrix (combined-ca x3 seeds,
pdsep-4p4d seed1, pdsep-6p2d seed1) on traces/w600_r0.0015_st30.jsonl
with cuda graphs enabled. The headline:
combined-ca: TTFT p50 0.91s success 99.5%
pdsep-4p4d: TTFT p50 62.8s success 52% (69x worse, half dropped)
pdsep-6p2d: TTFT p50 51.1s success 68% (56x worse, third dropped)
C2 (fig_c2): headline bars per config with error bars.
C3 (fig_c3): per-instance KV utilization time-series. Both PD-sep
splits hit the memory wall, but the side differs by P:D ratio --
4P+4D pins the P-side, 6P+2D pins both sides (D-side back-pressures
P-side).
C4 (fig_c4): TTFT stacked breakdown. 99% of PD-sep TTFT is P-side
prefill compute; D-side wait + first token is <=1.2s. The bottleneck
is P-side prefill queueing, not D-side decode wait as the original
analytical model assumed.
system_analysis.md gains a Layer 5b that reconciles the analytical
KV-wall model (which considered D-side only) with the empirical
finding that the wall hits whichever side has fewer GPUs, and
co-saturates both at extreme splits via D-side back-pressure.
plot_pd_matrix.py ingests outputs/pd_matrix/* into all four figures.
bench.sh gained AGENTIC_STEP_LOG_DIR hooks for future runs (set during
this work but not used by the current matrix's data).
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
New analysis/characterization/joined_analysis.py joins replayer
metrics.jsonl + proxy breakdown.json + worker_state.jsonl by
request_id, plus engine_*.jsonl by worker_id, and emits:
- joined.jsonl per-request merged record
- reuse_decomposition.json real intra/cross/shared classification
using session_id + hash_ids + cached_tokens
- interference_index.json TPOT_p90(same-worker prefill overlap)
/ TPOT_p90(clean), per Batch 2
- hotspot_index.json max/median worker TTFT-p90, per Batch 3
- failure_label.jsonl per-slow-request cause label, per Batch 5
- failure_breakdown.json label histogram
- window_summary.json SRR warmup/steady/drain aggregates
Closes the analyzer side of Phase A; replaces the
status: unavailable placeholders the existing scaffold emits when
join sources are missing.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
- 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>
Adds the experiment harness that gates the empirical claims (C2/C3/C4/C5)
in the PD-sep paper section. Three pieces:
1. scripts/bench.sh: new --mode pdsep with --pd-ratio P:D, and an
--eager flag to re-enable --enforce-eager for the cuda-graph
ablation. pdsep reuses the elastic-mode Mooncake kv_both launch and
swaps the proxy command from --combined to --prefill/--decode.
baseline and elastic flows are unchanged.
2. analysis/pd_sep_paper_section/scripts/bench_pd_matrix.sh: matrix
driver that runs {combined-ca, pdsep-4p4d, pdsep-6p2d} x cudagraph
x 3 seeds by default (~2 h on dash0). --with-rr adds combined-rr;
--with-eager doubles to ~5 h with the cuda-graph ablation. Skips
completed runs, captures per-instance vLLM logs (needed for C3
step-level KV-utilization mining).
3. fig_kv_memory_wall.pdf: empirical anchor (star) at REPORT.md §3.3's
observed 6P+2D 97% KV utilization. The marker lands on the model's
predicted curve at p90 input, confirming the steady-state analysis.
README updated with the run command, output layout, and the followup
plotters that consume outputs/pd_matrix/.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Adds the system-level argument resolving the roofline/PD-sep paradox.
Even at 95% cache reuse prefill stays compute-bound (the C6 roofline
fact), yet PD separation regresses TTFT 72%. The new system_analysis.md
walks through six layers showing why the roofline claim is necessary
but not sufficient, with the falsifiable condition being decode-side
KV memory budget: concurrent_decode * KV_per_req / (N_D * HBM_pool).
For chatbot this ratio is << 1 at any layout; for agentic at p90+
context it goes >> 1 under 4P+4D and 6P+2D, predicting the empirical
97% decode KV occupancy. fig_kv_memory_wall.pdf visualizes the model
with audit-able constants; fig_c1a/b ground the per-request KV-size
inputs in the actual sampled trace (input p50=33.5k, p90=101k,
intra-session reuse 79.2%).
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Adds analysis/pd_sep_paper_section/ as the home for the "PD separation is
net negative under agentic workloads" paper section: plot scripts for C1
(workload chars), C6 (roofline), C7 (routing-vs-PD-sep lever), the C6/C7
PDFs already rendered, and a README mapping candidate claims to required
figures plus open re-run items.
Removes --enforce-eager from bench.sh and all active launch scripts so
cuda graphs are captured -- the prior methodology suppressed one of
PD-sep's structural advantages (D-node fixed-shape decode). Legacy
scripts under scripts/legacy/ are intentionally untouched as historical
records.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Per analysis/unified_routing_fix_review.md #2, several docs still
presented the retired single-argmin + PUSH-migration design as the
final algorithm. Mark them superseded and document the current hybrid
direction (commit 255c8e6).
- REPORT.md §1.1 / §3.9: add errata callout and section header noting
the "Final Design" framing was retired after cc6e562 / 4c583f2;
point readers to docs/migration-policy-design.md.
- docs/migration-policy-design.md: rewrite. Opens with the current
hybrid algorithm (LMetric base + cache_ratio>0.5 affinity gate +
tie-breaker), then a "What Was Retired" commit table, then the old
Approach A numbers preserved as "Historical Baseline-Mode Comparison".
- analysis/research_findings.md §2.2 / §5: correct the LMetric framing.
LMetric isn't "neutralized by affinity constraints" (pure --policy
lmetric has no affinity at all); it converges to similar placements
because P_tokens includes new_uncached_tokens, giving it implicit
soft affinity.
- analysis/elastic_hypotheses.md: same LMetric correction in the
"DOESN'T work" summary, plus a footer cross-referencing the current
routing direction.
- analysis/unified_routing_fix_review.md: track this file (was
untracked); it is the review handoff cited from the updated docs.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Key finding: at 16 concurrent sessions (2 per GPU), TPOT p90 degrades
from 0.073 to 0.106 (+45%), with MEDIUM TPOT at 0.197 (+149%).
This is the first time we've reproduced real prefill-decode interference
in controlled experiments.
Elastic RDMA at 16 sessions doesn't help: only 13/500 offloaded (cache-gate
correct for cold turn-1), kv_both adds ~16% TPOT overhead at high concurrency.
Load scaling: 1000req_ts20, 200req_ts10, 200req_ts5, 500req_ts10 all show
~30% GPU util at 8 sessions. The bottleneck is max_inflight_sessions, not
arrival rate.
Updated elastic_hypotheses.md with H8, H9, and comprehensive final analysis.
The real bottleneck is vLLM's chunked prefill scheduling, not routing or
PD disaggregation.
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
H7: Sweeping OVERLOAD_FACTOR (2.0/1.5/1.3/1.0) has no effect on GPU
imbalance (~3.5-4x across all settings). Root cause: imbalance is from
workload skew at session placement (turn 1), not from routing at turn 2+.
H4 GPU profiling confirms: GPU balance improvement IS real (4.0x→2.0x),
and it directly improves HEAVY_COLO TTFT by 10.5%. But RDMA-offloaded
requests have bimodal transfer times (0.6s or 18-31s) that negate the
routing benefit.
Updated elastic_hypotheses.md with H7 results and next directions:
higher load experiments where contention amplifies routing differences.
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
Tracks all hypotheses tested during elastic PD disaggregation research:
- H1 (kv_both overhead): REJECTED — zero overhead at idle
- H2 (PS cold prefill): REJECTED — PS slower than cached C
- H3 (C_s+flexD): PARTIALLY VALIDATED — E2E -9% but HEAVY p90 +117%
- H4 (cache-aware offload): TODO — only offload high-cache-hit HEAVY
- H5 (RDMA overhead): TODO — Mooncake lacks layerwise transfer
- H6 (session migration): TODO — verify D's APC after migration
Key insight: offload decision should be cache-aware (new_tokens),
not size-based (total_input). 80k request with 90% cache = 8k prefill.
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
Design: offload HEAVY prefill only when P instance is less loaded than D
AND P is not overloaded (< 1.5x avg). Preserves session-sticky on D
for future KV reuse. External KV correctly registered in prefix cache.
Result (67/200 processed, 75% success):
TTFT p50: 0.551s (-49% vs baseline 1.080s)
TTFT p90: 4.135s (vs baseline 9.410s, -56%)
TPOT p90: 0.074s (same as baseline)
E2E p50: 2.938s (-45% vs baseline 5.306s)
25% error rate from ReadTimeout on very large HEAVY requests queuing on P.
Needs stricter elastic gate or higher timeout. But successful requests
show significant improvement over both baseline and previous P2P.
Also: added external_prefix_cache metrics tracking to replayer summary.
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
Root cause of 10.1pp APC gap: multi-turn sessions' KV evicted between
turns by cold-start prefills (66% of loss). Inter-turn gap is only 2
requests p50, but LRU cache (550 blocks) can't protect 93 blocks/session
across 14-21 concurrent sessions.
Three approaches designed:
A. Session-sticky routing with KV reservation (proxy-only, no vLLM change)
B. Two-tier KV cache: GPU + DRAM offload via Mooncake
C. Prefill-aware eviction (LFU/ARC instead of LRU, vLLM patch)
Next: simulate LRU vs LFU vs "infinite-for-MT" to quantify upper bounds,
then implement Approach A (lowest effort, immediate benchmark).
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
All 8 GPUs stay PD-combined. Global scheduler classifies requests as
WARM/MEDIUM/HEAVY based on estimated new tokens after prefix cache.
Only HEAVY requests (20%, cold start >20k new tokens) get offloaded;
80% of requests are co-located with zero KV transfer.
This avoids the KV cache memory wall (no decode concentration) while
isolating heavy prefills from decode when needed.
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
Systematic study of prefill-decode disaggregation for agentic LLM workloads
using production GLM-5.1 coder trace (2.1M requests, 71B input tokens).
Key findings:
- Cache-aware routing improves TPOT p90 by 15% and APC from 20.8% to 44.7%
without PD separation, matching PD-Sep's decode isolation benefit
- PD separation adds +72% TTFT overhead (KV transfer) with no TPOT gain
when using the same cache-aware scheduler
- Prefill remains compute-bound even at 95% KV cache reuse (AI >1000x
vs decode AI <2), but absolute FLOPs drop 71% from cache hits
- For agentic MoE workloads, cache-aware routing > PD separation
Infrastructure:
- Trace sampler preserving session structure + hash_ids for prefix sharing
- Async trace replayer with streaming TTFT/TPOT/E2E measurement
- Unified cache-aware + token-level load-balanced global scheduler proxy
supporting both PD-colocated and PD-disaggregated (Mooncake/RDMA) modes
- vLLM 0.18.1 scheduler patch for KV transfer abort race condition
- Roofline analysis tool for prefill/decode compute characterization
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>