#!/usr/bin/env python3 """Audit MILK10k imbalance, plan paired SD augmentation, and optionally materialize a capped dataset.""" from __future__ import annotations import argparse import json import math import os import shutil from pathlib import Path os.environ.setdefault("MPLCONFIGDIR", "/tmp/matplotlib-cache") import matplotlib.pyplot as plt import numpy as np import pandas as pd try: import seaborn as sns except ModuleNotFoundError: # Matplotlib fallback keeps audit usable in minimal environments. sns = None LABEL_COLUMNS = ["AKIEC", "BCC", "BEN_OTH", "BKL", "DF", "INF", "MAL_OTH", "MEL", "NV", "SCCKA", "VASC"] MODALITIES = {"clinical: close-up", "dermoscopic"} def parse_args(argv=None): p = argparse.ArgumentParser(description="Audit and materialize a safely balanced paired MILK10k dataset.") p.add_argument("--base-data-dir", type=Path, required=True) p.add_argument("--base-input-dir", type=Path, default=None) p.add_argument("--augmented-groundtruth", type=Path, default=None) p.add_argument("--augmented-metadata", type=Path, default=None) p.add_argument("--synthetic-input-dir", type=Path, default=None) p.add_argument("--qc-summary", type=Path, default=None) p.add_argument("--fresh-start", action="store_true", help="Ignore every existing synthetic CSV and plan from base real data only.") p.add_argument("--report-dir", type=Path, required=True) p.add_argument("--scripts-dir", type=Path, default=None, help="Command output folder; defaults to Stable_diffusion_augmentation/.") p.add_argument("--materialize-dir", type=Path, default=None) p.add_argument("--bcc-cap-ratio", type=float, default=1.5) p.add_argument("--tail-floor", type=int, default=150) p.add_argument("--max-synthetic-real-ratio", type=float, default=2.0) p.add_argument("--max-synthetic-per-source", type=int, default=3) p.add_argument("--min-target-prob", type=float, default=0.4) p.add_argument("--require-target-pred", action="store_true") p.add_argument("--seed", type=int, default=42) p.add_argument("--num-variants", type=int, default=1) p.add_argument("--link-mode", choices=["hardlink", "copy", "symlink"], default="hardlink") p.add_argument("--overwrite", action="store_true") return p.parse_args(argv) def resolve_paths(args): base = args.base_data_dir.expanduser().resolve() gt = base / "MILK10k_Training_GroundTruth.csv" meta = base / "MILK10k_Training_Metadata.csv" input_dir = (args.base_input_dir or base / "MILK10k_Training_Input").expanduser().resolve() if not input_dir.exists() and args.base_input_dir is None: input_dir = (base.parent / "MILK10k_Training_Input").resolve() info = base / "augmented_info" aug_gt = args.augmented_groundtruth or info / "MILK10k_Training_GroundTruth(2).csv" aug_meta = args.augmented_metadata or info / "MILK10k_Training_Metadata(3).csv" required = [gt, meta, input_dir] + ([] if args.fresh_start else [aug_gt, aug_meta]) missing = [str(path) for path in required if not path.exists()] if missing: raise FileNotFoundError("Missing inputs: " + ", ".join(missing)) return gt, meta, input_dir, aug_gt.expanduser().resolve(), aug_meta.expanduser().resolve() def attach_labels(gt): missing = set(LABEL_COLUMNS) - set(gt.columns) if missing: raise ValueError(f"Ground truth missing labels: {sorted(missing)}") result = gt.copy(); result["label"] = result[LABEL_COLUMNS].idxmax(axis=1) if result.lesion_id.duplicated().any(): raise ValueError("Duplicate lesion_id in ground truth.") return result def source_id(lesion_id): return str(lesion_id).split("__sdpair_", 1)[0] def load_inventory(args): gt_path, meta_path, input_dir, aug_gt_path, aug_meta_path = resolve_paths(args) base_gt_raw = pd.read_csv(gt_path); base_meta = pd.read_csv(meta_path); base_gt = attach_labels(base_gt_raw) base_ids = set(base_gt.lesion_id.astype(str)) if args.fresh_start: synth_gt = pd.DataFrame(columns=[*base_gt.columns, "source_lesion_id", "pair_metadata_complete"]) synth_meta = pd.DataFrame(columns=base_meta.columns) return base_gt_raw, base_gt, base_meta, synth_gt, synth_meta, input_dir aug_gt_raw = pd.read_csv(aug_gt_path); aug_meta = pd.read_csv(aug_meta_path); aug_gt = attach_labels(aug_gt_raw) synth_gt = aug_gt[~aug_gt.lesion_id.astype(str).isin(base_ids)].copy() synth_meta = aug_meta[aug_meta.lesion_id.astype(str).isin(set(synth_gt.lesion_id.astype(str)))].copy() if base_ids - set(aug_gt.lesion_id.astype(str)): raise ValueError("Augmented ground truth omits base lesions.") if synth_gt.lesion_id.duplicated().any(): raise ValueError("Duplicate synthetic lesion IDs.") synth_gt["source_lesion_id"] = synth_gt.lesion_id.map(source_id) modality_counts = synth_meta.groupby("lesion_id").image_type.agg(lambda values: set(map(str, values))) synth_gt["pair_metadata_complete"] = synth_gt.lesion_id.map(lambda x: modality_counts.get(x, set()) == MODALITIES) return base_gt_raw, base_gt, base_meta, synth_gt, synth_meta, input_dir def add_file_and_qc_status(args, synth, synth_meta): result = synth.copy(); qc = None if args.qc_summary: qc = pd.read_csv(args.qc_summary.expanduser().resolve()).drop_duplicates("synthetic_lesion_id").set_index("synthetic_lesion_id") if args.synthetic_input_dir: image_root = args.synthetic_input_dir.expanduser().resolve() paths = synth_meta.assign(path=synth_meta.apply(lambda row: image_root / str(row.lesion_id) / f"{row.isic_id}.jpg", axis=1)) file_counts = paths.groupby("lesion_id").path.agg(lambda values: sum(Path(x).exists() for x in values)) result["existing_image_files"] = result.lesion_id.map(lambda x: int(file_counts.get(x, 0))) result["pair_files_complete"] = result.lesion_id.map(lambda x: file_counts.get(x, 0) == 2) else: result["existing_image_files"] = 0 result["pair_files_complete"] = False result["qc_available"] = result.lesion_id.isin(set(qc.index)) if qc is not None else False result["target_probability"] = result.lesion_id.map(qc.target_class_probability) if qc is not None and "target_class_probability" in qc else np.nan result["is_target_predicted"] = result.lesion_id.map(qc.is_target_predicted).astype(str).eq("True") if qc is not None and "is_target_predicted" in qc else False result["qc_pass"] = result.qc_available & (pd.to_numeric(result.target_probability, errors="coerce").fillna(0) >= args.min_target_prob) if args.require_target_pred: result["qc_pass"] &= result.is_target_predicted result["usable"] = result.pair_metadata_complete & result.pair_files_complete & result.qc_pass return result def capped_synthetic(synth, real_counts, args, usable_only): candidates = synth[synth.usable].copy() if usable_only else synth.copy() candidates = candidates.sort_values(["label", "is_target_predicted", "target_probability", "lesion_id"], ascending=[True, False, False, True]) candidates["source_rank"] = candidates.groupby(["label", "source_lesion_id"]).cumcount() + 1 candidates = candidates[candidates.source_rank <= args.max_synthetic_per_source] selected = [] for label, group in candidates.groupby("label", sort=True): cap = int(math.floor(real_counts.get(label, 0) * args.max_synthetic_real_ratio)) selected.append(group.head(cap)) return pd.concat(selected, ignore_index=True) if selected else candidates.iloc[:0] def plan_counts(base, synth, inventory_selected, usable_selected, args): real = base.label.value_counts().reindex(LABEL_COLUMNS, fill_value=0).astype(int) raw = synth.label.value_counts().reindex(LABEL_COLUMNS, fill_value=0).astype(int) inventory = inventory_selected.label.value_counts().reindex(LABEL_COLUMNS, fill_value=0).astype(int) usable = usable_selected.label.value_counts().reindex(LABEL_COLUMNS, fill_value=0).astype(int) second = int(real.drop("BCC").max()); bcc_cap = min(int(real.BCC), int(math.floor(second * args.bcc_cap_ratio))) rows = [] for label in LABEL_COLUMNS: target = int(real[label]) if label in {"BEN_OTH", "DF", "INF", "MAL_OTH", "VASC"}: target = min(args.tail_floor, int(math.floor(real[label] * (1 + args.max_synthetic_real_ratio)))) kept_real = bcc_cap if label == "BCC" else int(real[label]) rows.append({"class": label, "real_count": int(real[label]), "raw_synthetic_inventory": int(raw[label]), "capped_inventory": int(inventory[label]), "verified_usable": int(usable[label]), "target_total": target, "kept_real": kept_real, "final_inventory_total": kept_real + int(inventory[label]), "final_verified_total": kept_real + int(usable[label]), "additional_needed_inventory": max(0, target - int(real[label]) - int(inventory[label])), "additional_needed_verified": max(0, target - int(real[label]) - int(usable[label]))}) return pd.DataFrame(rows), bcc_cap def bcc_strata(base_meta, base, cap, seed): bcc = base[base.label.eq("BCC")][["lesion_id"]].merge(base_meta.drop_duplicates("lesion_id"), on="lesion_id", how="left") age = pd.to_numeric(bcc.age_approx, errors="coerce"); bcc["age_bin"] = pd.cut(age, [-np.inf,29,49,69,np.inf], labels=["<30","30-49","50-69","70+"]).astype(str) for column in ("sex", "site", "skin_tone_class", "age_bin"): bcc[column] = bcc[column].fillna("unknown").astype(str) bcc["stratum"] = bcc[["sex","site","skin_tone_class","age_bin"]].agg("|".join, axis=1) counts = bcc.stratum.value_counts().sort_index(); exact = counts / len(bcc) * cap; quota = np.floor(exact).astype(int) for key in (exact-quota).sort_values(ascending=False).index: if quota.sum() >= cap: break if quota[key] < counts[key]: quota[key] += 1 chosen=[]; rng=np.random.default_rng(seed) for key in counts.index: ids=bcc.loc[bcc.stratum.eq(key),"lesion_id"].to_numpy();rng.shuffle(ids);chosen.extend(ids[:quota[key]]) if len(chosen)0)&~plan["class"].eq("MAL_OTH")] classes=" ".join(needed_rows["class"].astype(str));per_source=args.max_synthetic_per_source max_sources=max([math.ceil(int(value)/per_source) for value in needed_rows.additional_needed_verified] or [1]) base_data=args.base_data_dir.expanduser().resolve();base_input=(args.base_input_dir.expanduser().resolve() if args.base_input_dir else base_data/"MILK10k_Training_Input") if not base_input.exists():base_input=base_data.parent/"MILK10k_Training_Input" header=["#!/usr/bin/env bash","set -euo pipefail","","# Generated commands. Review paths before running.", f'BASE_DATA="{base_data}"',f'BASE_INPUT="{base_input}"',f'REPORT_DIR="{report_dir}"','CHECKPOINT_DIR="/path/to/convnext_5fold_run"', 'GEN_DIR="$REPORT_DIR/generated_balance_pairs"','CANDIDATE_DIR="$REPORT_DIR/candidate_augmented"','FINAL_DIR="/path/to/milk10k_balanced"',""] generate=[] if classes: generate += [f"# Planned classes: {classes}; planner applies exact caps after QC.", f"python Stable_diffusion_augmentation/generate_milk10k_sd_pairs.py --data-dir \"$BASE_DATA\" --input-dir \"$BASE_INPUT\" --output-dir \"$GEN_DIR\" --class-names {classes} --num-per-lesion {per_source} --max-source-lesions {max_sources} --shuffle --skip-existing",""] qc_materialize=["# QC outputs: $GEN_DIR/effb2_qc_predictions.csv and effb2_qc_summary.csv.", "python Stable_diffusion_augmentation/run_effb2_qc.py --checkpoint-dir \"$CHECKPOINT_DIR\" --output-dir \"$GEN_DIR\"", "", "python Stable_diffusion_augmentation/filter_paired_augmentation_by_qc.py --manifest \"$GEN_DIR/paired_augmentation_manifest.csv\" --qc-summary \"$GEN_DIR/effb2_qc_summary.csv\" --output \"$GEN_DIR/filtered_manifest.csv\" --min-target-prob 0.4 --require-target-pred", "", "# Build a temporary complete MILK10k dataset from QC-passed pairs.", "python Stable_diffusion_augmentation/materialize_augmented_milk10k_dataset.py --input-dir \"$BASE_INPUT\" --metadata-csv \"$BASE_DATA/MILK10k_Training_Metadata.csv\" --groundtruth-csv \"$BASE_DATA/MILK10k_Training_GroundTruth.csv\" --augmentation-manifest \"$GEN_DIR/filtered_manifest.csv\" --output-dir \"$CANDIDATE_DIR\" --symlink --synthetic-metadata neutral --overwrite", "", "# Apply BCC stratified cap and final source/class caps into a separate dataset.", "python Stable_diffusion_augmentation/plan_and_materialize_balanced_milk10k.py --base-data-dir \"$BASE_DATA\" --augmented-groundtruth \"$CANDIDATE_DIR/MILK10k_Training_GroundTruth.csv\" --augmented-metadata \"$CANDIDATE_DIR/MILK10k_Training_Metadata.csv\" --synthetic-input-dir \"$CANDIDATE_DIR/MILK10k_Training_Input\" --qc-summary \"$GEN_DIR/effb2_qc_summary.csv\" --report-dir \"$REPORT_DIR/final_audit\" --materialize-dir \"$FINAL_DIR\" --require-target-pred --overwrite", "", "# Train safely: synthetic IDs stay train-only.", "# python milk10k_effb2_dermoscopic_metadata/train_milk10k_effb2_dermoscopic_metadata.py --data-dir \"$FINAL_DIR\" --output-dir /path/to/run --split-manifest /path/to/run/split_v2.json --synthetic-train-only --metadata-mode none --loss ldam", ""] code_dir=(args.scripts_dir.expanduser().resolve() if args.scripts_dir else Path(__file__).resolve().parent) code_dir.mkdir(parents=True,exist_ok=True) exported={"run_fresh_balance_01_generate.sh":header+generate, "run_fresh_balance_02_qc_materialize.sh":header+qc_materialize} for name,lines in exported.items(): path=code_dir/name;path.write_text("\n".join(lines),encoding="utf-8");path.chmod(0o755) def report_markdown(args, plan, sources, manifest, bcc_cap, usable_count, missing_pairs, missing_image_files): warnings=[] if args.qc_summary is None:warnings.append("QC summary was not provided; no synthetic row is considered verified usable.") if args.synthetic_input_dir is None:warnings.append("Synthetic image root was not provided; materialization is disabled.") if missing_pairs:warnings.append(f"Synthetic images missing: {missing_image_files} files across {missing_pairs} incomplete inventory pairs.") warnings.append("MAL_OTH should use external/manual-reviewed data; do not scale SD from only a few source lesions.") lines=["# MILK10k Balance Report","",f"- BCC static cap: {bcc_cap}",f"- verified usable synthetic lesions: {usable_count}",f"- source cap: {args.max_synthetic_per_source}",f"- synthetic/real cap: {args.max_synthetic_real_ratio}x","","## Warnings",""]+[f"- {x}" for x in warnings] lines += ["","## Augmentation plan","","```",plan.to_string(index=False),"```","","## Source diversity","","```",sources.to_string(index=False),"```","","## Selection reasons","",manifest.selection_reason.value_counts().to_string(),""] return "\n".join(lines) def run(args): if args.num_variants<1 or args.max_synthetic_per_source<1:raise ValueError("num variants and source cap must be positive.") report_dir=args.report_dir.expanduser().resolve();report_dir.mkdir(parents=True,exist_ok=True) base_gt_raw,base,base_meta,synth_gt,synth_meta,base_input=load_inventory(args) synth=add_file_and_qc_status(args,synth_gt,synth_meta);real_counts=base.label.value_counts().to_dict() inventory_selected=capped_synthetic(synth,real_counts,args,False);usable_selected=capped_synthetic(synth,real_counts,args,True) plan,bcc_cap=plan_counts(base,synth,inventory_selected,usable_selected,args) manifest=selection_manifest(synth,set(inventory_selected.lesion_id),set(usable_selected.lesion_id));sources=source_diversity(synth,inventory_selected) variants=[];drifts=[] materialize_error = None if args.materialize_dir and len(inventory_selected) and not len(usable_selected): materialize_error = ValueError( "Materialization refused: synthetic inventory exists but no pair passed image/QC validation. " "Check --synthetic-input-dir and --qc-summary; audit reports are still written." ) for index in range(args.num_variants): ids,bcc=bcc_strata(base_meta,base,bcc_cap,args.seed+index);selected_base=set(base.loc[~base.label.eq("BCC"),"lesion_id"].astype(str))|ids variants.append(selected_base);drift=drift_table(bcc,ids);drift["variant"]=index;drifts.append(drift) base[["lesion_id","label"]].assign(selected=lambda frame:frame.lesion_id.astype(str).isin(selected_base),variant=index).to_csv(report_dir/f"selected_base_manifest_variant_{index:02d}.csv",index=False) if args.materialize_dir and materialize_error is None: root=args.materialize_dir.expanduser().resolve();destination=root if args.num_variants==1 else root/f"variant_{index:02d}" materialize_variant(destination,base_gt_raw,base_meta,selected_base,synth_gt,synth_meta,set(usable_selected.lesion_id),base_input,args.synthetic_input_dir.expanduser().resolve() if args.synthetic_input_dir else None,args) plan.to_csv(report_dir/"augmentation_plan.csv",index=False);sources.to_csv(report_dir/"source_diversity.csv",index=False);manifest.to_csv(report_dir/"selected_synthetic_manifest.csv",index=False) pd.concat(drifts,ignore_index=True).to_csv(report_dir/"bcc_distribution_drift.csv",index=False) distribution=plan.copy();distribution.to_csv(report_dir/"class_distribution.csv",index=False);plot_reports(report_dir,distribution,sources) missing_pairs=int((~synth.pair_files_complete).sum());missing_image_files=int((2-synth.existing_image_files.clip(upper=2)).sum()) payload={"policy":vars(args),"bcc_cap":bcc_cap,"inventory_lesions":len(synth),"usable_synthetic_lesions":len(usable_selected),"missing_image_pairs":missing_pairs,"missing_image_files":missing_image_files,"plan":plan.to_dict("records")} payload["policy"]={k:str(v) if isinstance(v,Path) else v for k,v in payload["policy"].items()};(report_dir/"balance_plan.json").write_text(json.dumps(payload,indent=2),encoding="utf-8") (report_dir/"balance_report.md").write_text(report_markdown(args,plan,sources,manifest,bcc_cap,len(usable_selected),missing_pairs,missing_image_files),encoding="utf-8") command_script(args,plan,report_dir) print(f"Base lesions: {len(base)}; synthetic inventory: {len(synth)}; verified usable: {len(usable_selected)}") print(f"BCC cap: {bcc_cap}; reports: {report_dir}") if materialize_error is not None:raise materialize_error if args.materialize_dir:print(f"Materialized dataset: {args.materialize_dir.expanduser().resolve()}") return {"plan":plan,"manifest":manifest,"bcc_cap":bcc_cap,"usable":usable_selected} def main():run(parse_args()) if __name__=="__main__":main()