# Downstream track — leaderboard substrate This directory holds the **per-method substrate** for the OpenMHC Track-1 (outcome prediction) leaderboard. Each method ships two files: ``` downstream/.parquet # per-user prediction pairs (method × task × subgroup × user) downstream/.meta.json # display + diagnostic sidecar ``` See `SCHEMA.md` for the exact column / field schema (including the `fallback_rate` diagnostic), and `bootstrap/` for the per-draw CI reference. Unlike Tracks 2/3 (per-user MAE), Track-1's headline metrics — binary AUPRC, ordinal Spearman, regression Pearson — are cohort-level ranking / correlation metrics that do not decompose into one error per user. The substrate therefore ships the raw per-user `(y_true, y_pred, y_proba)` pairs, and the leaderboard recomputes the paired metrics server-side against the `linear` baseline. ## What's it for The substrate parquets are the canonical inputs for: - The OpenMHC HF Space (`MyHeartCounts/OpenMHC`) — the live leaderboard table (skill / fair-skill / average-rank vs the `linear` baseline). The Space **reduces these substrates live on every page load** — point estimate vs the `linear` baseline — exactly like the imputation and forecasting tracks. So once your `.parquet` (+ `.meta.json`) is on the dataset, **it goes straight onto the board** — reduced live vs `linear`, with no precomputed rows file and no offline maintainer reduce (the board picks it up on the Space's next restart). (The paper's 95% confidence intervals come from the separate `downstream/bootstrap/` reference; the live board shows the point value.) - Independent re-aggregation (the reducers in `scripts/paper_results/downstream/`). - The cluster-bootstrap reference at `downstream/bootstrap/` (per-draw CIs) is reduced from these substrates, so any change here must be matched by a bootstrap refresh. ## Loading ```python from huggingface_hub import hf_hub_download import pandas as pd, json parquet = hf_hub_download( "MyHeartCounts/OpenMHC-leaderboard-data", "downstream/xgboost.parquet", repo_type="dataset", ) df = pd.read_parquet(parquet) print(df.shape, df.columns.tolist()) # Display + diagnostic sidecar (incl. fallback_rate) meta_p = hf_hub_download( "MyHeartCounts/OpenMHC-leaderboard-data", "downstream/xgboost.meta.json", repo_type="dataset", ) print(json.loads(open(meta_p).read())) # -> {"display_name": "XGBoost", "type": "Statistical", ..., "fallback_rate": 0.0} ``` ## Pooled substrate The pooled per-user frame across all methods is the concatenation of the per-method parquets (93,528 rows/method for the canonical 32-task config): ```python import glob, pandas as pd pooled = pd.concat( [pd.read_parquet(p) for p in glob.glob("downstream/*.parquet")], ignore_index=True, ) ``` ## `fallback_rate` Each sidecar carries `fallback_rate` — the fraction of the method's test predictions the harness left non-finite and substituted with the `linear` baseline before scoring. `wbm` is the only non-zero method (it embeds only participants with a full weekly window); the rest are `0.0`. A high rate means the headline scores partly reflect the baseline's performance on the substituted cells and should be read with caution. ## Refreshing The substrate is produced and uploaded from the OpenMHC code repo. It is pooled from saved eval predictions (no model re-run); the bootstrap reference is kept on the same predictions. Because the Space reduces the substrate live, **uploading it (step 5) is all it takes** — no precomputed rows file to regenerate and no offline reduce; the board picks it up on the Space's next restart. (You only touch the Space *code* when the reducer itself changes — see `docs/leaderboard-maintenance.md`.) ```bash # (1) Eval — run each method through the public API, saving per-(method, task) # test predictions + the shared _subgroups.json. METHOD=xgboost MHC_DATA_DIR= PREDICTIONS_DIR=results/eval/final/predictions \ python scripts/run_eval.py # repeat for the 8 methods # (2) Bootstrap-draws reference for the CIs (n_boot=1000, seed=42, baseline=linear). PYTHONPATH=src python scripts/paper_results/downstream/bootstrap_downstream_draws.py \ --predictions_dir results/eval/final/predictions --csvs_dir results/eval/final \ --methods linear multirocket xgboost lsm2 gru_d wbm toto chronos2 \ --output results/paper/bootstrap_draws.parquet # (3) Build the per-method substrate parquets (+ provenance sidecars). python scripts/paper_results/downstream/parity/produce_per_method_per_user_pairs.py \ --predictions-dir results/eval/final/predictions --out-dir results/leaderboard_downstream # (4) Parity gate — the substrate must equal the predictions, and a substrate-driven # bootstrap must reproduce results/paper/bootstrap_draws.parquet. python scripts/paper_results/downstream/parity/parity_substrate.py # (5) Upload the per-method substrates (HF auth required). for m in multirocket xgboost lsm2 gru_d wbm toto chronos2; do python tools/upload_leaderboard_substrate.py --dir results/leaderboard_downstream \ --method "$m" --track downstream --name "" --type "" \ --submitter "OpenMHC team" --subtrack static done # (6) Upload the bootstrap-draws reference (-> downstream/bootstrap/). python tools/upload_leaderboard_bootstrap.py --dir results/paper --track downstream ``` Steps (2) and (6) keep the bootstrap CIs on the same canonical predictions as the point numbers — run them together whenever the substrates change.