zju-eye-pretrain / code /build_oct_public.py
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#!/usr/bin/env python3
"""
Adapter for 19 OCT public datasets → 41-col manifest (matching private/fundus schema).
19 cohorts:
17 A-class (enumerated via existing unified_metadata.csv):
public_oct_kermany, public_oct_octid, public_oct_aroi, public_oct_neh_ut_2021,
public_oct_areds2, public_oct_glaucoma, public_oct_nyu_poag, public_oct_olives,
public_oct_chiu_dme_2015, public_oct_srinivasan_2014, public_oct_sparsity_sdoct_2012,
public_oct_oimhs, public_oct_retouch, public_oct_thoct1800, public_oct_octdl,
public_oct_amd_sd, public_oct_c8
+ 2 enumerated from source layout:
public_oct_octa500, public_oct_uestc
Output layout (under {output_root}):
extracted/{cohort}/{hash[:2]}/{hash}/{bscan.png|bscan_NNN.png}{+meta.json}{+masks}
manifest/{cohort}_images.parquet
manifest/{cohort}_sidecar.parquet (where applicable)
captions/{cohort}_captions.parquet
Notes:
- Most cohorts use file-level study_id (1 bscan = 1 study). patient_hash is shared
across bscans of same patient when patient_id is known.
- OLIVES uses study_id = hash(patient_eye_visit), patient_hash = hash(patient).
- OCTA500 and UESTC use file-level study_id (volume info preserved in source_basename).
- Masks (where present) are copied to study_dir as auxiliary files; not in manifest rows.
"""
import argparse
import os
import re
from collections import defaultdict
from pathlib import Path
import pandas as pd
from public_common import (
default_base_fields, study_hash_for, rel_file_path,
)
from oct_public_common import (
caption_l1_oct, caption_l3_oct, device_phrase,
save_mask_preserve, run_cohort,
)
# ============================================================
# Disease label → (diagnosis_group, severity)
# ============================================================
DR_SEVERITY = {0: "none", 1: "mild", 2: "moderate", 3: "severe", 4: "proliferative"}
DISEASE_MAP = {
# Normal variants
"NORMAL": ([], "none"),
"Normal": ([], "none"),
"NOR": ([], "none"),
"NO": ([], "none"),
"Control": ([], "none"),
"CONTROL": ([], "none"),
# Disease classes
"CNV": (["CNV"], "unknown"),
"DME": (["DME"], "unknown"),
"DRUSEN": (["DRUSEN"], "unknown"),
"DR": (["DR"], "unknown"),
"AMD": (["AMD"], "unknown"),
"wet_AMD": (["wet_AMD"], "unknown"),
"nAMD": (["nAMD"], "unknown"),
"AMD/RVO": (["AMD", "RVO"], "unknown"),
"CSR": (["CSR"], "unknown"),
"MH": (["MH"], "unknown"),
"MH_Stage1": (["MH"], "mild"),
"MH_Stage2": (["MH"], "moderate"),
"MH_Stage3": (["MH"], "severe"),
"MH_Stage4": (["MH"], "severe"),
"Glaucoma": (["glaucoma"], "unknown"),
"POAG": (["glaucoma"], "unknown"),
"ERM": (["ERM"], "unknown"),
"RVO": (["RVO"], "unknown"),
"RAO": (["RAO"], "unknown"),
"VID": (["VID"], "unknown"),
# Unknown / fallback
"Unknown": ([], "unknown"),
}
def map_disease(label):
return DISEASE_MAP.get(str(label).strip(), (["unknown_disease"], "unknown"))
# ============================================================
# Per-cohort static config (device, anatomy, scan_protocol, ethnicity)
# ============================================================
COHORT_CONFIG = {
"public_oct_kermany": dict(
phrase="Kermany 2018 OCT classification dataset (UCSD / Cell)",
vendor="heidelberg", model="spectralis", tech="sd_oct",
anatomy="macula", scan_protocol="single_shot",
ethnicity="Mixed", hospital_domain="kermany_ucsd_v1"),
"public_oct_octid": dict(
phrase="OCTID Indian retinal OCT classification dataset",
vendor="zeiss", model="cirrus_hd_oct_5000", tech="sd_oct",
anatomy="macula", scan_protocol="single_shot",
ethnicity="South Asian", hospital_domain="octid_sankara_v1"),
"public_oct_aroi": dict(
phrase="AROI nAMD layer segmentation dataset (Croatia)",
vendor="zeiss", model="cirrus_hd_oct_4000", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="European", hospital_domain="aroi_zagreb_v1"),
"public_oct_neh_ut_2021": dict(
phrase="NEH-UT-2021 Iranian retinal OCT dataset",
vendor="heidelberg", model="spectralis_sd_oct", tech="sd_oct",
anatomy="macula", scan_protocol="single_shot",
ethnicity="Middle Eastern", hospital_domain="neh_ut_2021_v1"),
"public_oct_areds2": dict(
phrase="AREDS2 ancillary SD-OCT AMD dataset (NEI)",
vendor="bioptigen", model="bioptigen_sd_oct", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="Mixed", hospital_domain="areds2_nei_v1"),
"public_oct_glaucoma": dict(
phrase="Glaucoma OCT and fundus dataset (TD-OCT)",
vendor="zeiss", model="stratus_oct", tech="td_oct",
anatomy="optic_disc", scan_protocol="single_shot",
ethnicity="unknown", hospital_domain="glaucoma_oct_v1"),
"public_oct_nyu_poag": dict(
phrase="NYU POAG retinal OCT dataset",
vendor="unknown", model="unknown", tech="unknown",
anatomy="optic_disc", scan_protocol="volume_3d_macula",
ethnicity="unknown", hospital_domain="nyu_poag_v1"),
"public_oct_olives": dict(
phrase="OLIVES longitudinal DR and DME OCT dataset",
vendor="heidelberg", model="spectralis_hra_oct", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="unknown", hospital_domain="olives_v1"),
"public_oct_chiu_dme_2015": dict(
phrase="Chiu et al. 2015 DME 8-layer segmentation dataset (Duke)",
vendor="heidelberg", model="spectralis", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="unknown", hospital_domain="chiu_duke_2015_v1"),
"public_oct_srinivasan_2014": dict(
phrase="Srinivasan et al. 2014 AMD-DME-Normal OCT dataset (Duke/Harvard/Michigan)",
vendor="heidelberg", model="spectralis", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="unknown", hospital_domain="srinivasan_2014_v1"),
"public_oct_sparsity_sdoct_2012": dict(
phrase="Sparsity SDOCT 2012 AMD vs control dataset",
vendor="bioptigen", model="bioptigen_sd_oct", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="unknown", hospital_domain="sparsity_sdoct_2012_v1"),
"public_oct_oimhs": dict(
phrase="OIMHS macular hole staging and layer segmentation dataset",
vendor="heidelberg", model="spectralis_sd_oct", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="Asian", hospital_domain="oimhs_china_v1"),
"public_oct_retouch": dict(
phrase="RETOUCH 2017 retinal fluid segmentation challenge dataset",
vendor="varies", model="varies", tech="sd_oct", # 3 sub-vendors
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="European", hospital_domain="retouch_v1"),
"public_oct_thoct1800": dict(
phrase="THOCT1800 Tsinghua AMD-DME-Normal OCT dataset",
vendor="zeiss", model="cirrus_hd_oct", tech="sd_oct",
anatomy="macula", scan_protocol="single_shot",
ethnicity="Asian", hospital_domain="thoct1800_tsinghua_v1"),
"public_oct_octdl": dict(
phrase="OCTDL Russian 7-class retinal OCT dataset",
vendor="optovue", model="rtvue_xr_avanti", tech="sd_oct",
anatomy="macula", scan_protocol="single_shot",
ethnicity="European", hospital_domain="octdl_russia_v1"),
"public_oct_amd_sd": dict(
phrase="AMD-SD wet AMD multi-class segmentation dataset (China)",
vendor="zeiss", model="cirrus_hd_oct_5000", tech="sd_oct",
anatomy="macula", scan_protocol="single_shot",
ethnicity="Asian", hospital_domain="amd_sd_nanchang_v1"),
"public_oct_c8": dict(
phrase="C8 compiled 8-class retinal OCT classification dataset (Kaggle)",
vendor="unknown", model="unknown", tech="unknown",
anatomy="macula", scan_protocol="single_shot",
ethnicity="unknown", hospital_domain="c8_kaggle_v1"),
"public_oct_octa500": dict(
phrase="OCTA-500 multi-modal OCT-A and OCT structural retinal dataset",
vendor="optovue", model="rtvue_xr_avanti", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="Asian", hospital_domain="octa500_njust_v1"),
"public_oct_uestc": dict(
phrase="UESTC despeckling 3D OCT dataset (BMizar + Spectralis)",
vendor="varies", model="varies", tech="sd_oct",
anatomy="macula", scan_protocol="volume_3d_macula",
ethnicity="Asian", hospital_domain="uestc_sichuan_v1"),
}
# ============================================================
# Shared row+caps builder for "standard" cohorts
# ============================================================
def _shared_build_row_caps(meta, cohort, cohort_phrase,
has_segmentation_fn=None,
l3_extras_fn=None,
scan_protocol_override=None):
"""Default row/caps builder. Returns (list_of_rows, list_of_captions).
Multi-slice studies emit one row per slice; all share study_id + patient_hash."""
cfg = COHORT_CONFIG[cohort]
sh = meta["study_hash"]
ph = meta["patient_hash"]
eye = meta.get("eye", "unknown")
disease_label = meta.get("disease_label", "Unknown")
dx, sev = map_disease(disease_label)
base = default_base_fields(
cohort, sh, patient_hash=ph, eye=eye,
ethnicity=cfg["ethnicity"], hospital_domain=cfg["hospital_domain"])
base["device_vendor"] = meta.get("device_vendor", cfg["vendor"])
base["device_model"] = meta.get("device_model", cfg["model"])
base["diagnosis_group"] = dx
base["severity"] = sev
if disease_label and disease_label != "Unknown":
base["diagnosis_source"] = meta.get("diagnosis_source", "expert_label")
rows, caps = [], []
n_slices = meta["n_slices"]
for slc in meta["slices"]:
idx = slc["idx"]
if idx is None:
image_id = f"{cohort}_{sh}_bscan"
file_path = rel_file_path(cohort, sh, "bscan.png")
else:
image_id = f"{cohort}_{sh}_bscan_{idx:03d}"
file_path = rel_file_path(cohort, sh, slc["fname"])
row = dict(base)
has_seg = has_segmentation_fn(meta, slc) if has_segmentation_fn else bool(
meta.get("has_segmentation_mask"))
row.update({
"image_id": image_id,
"file_path": file_path,
"file_format": "png",
"modality": "oct_bscan",
"anatomy": cfg["anatomy"],
"device_technology": cfg["tech"],
"scan_protocol": scan_protocol_override or cfg["scan_protocol"],
"bscan_index": idx,
"image_height_px": slc["h"],
"image_width_px": slc["w"],
"has_segmentation": has_seg,
"n_layers_visible": 0,
"is_valid": True,
})
rows.append(row)
# 把 row 中的 device 传给 L1 caption (per-row, RETOUCH/UESTC 多设备 cohort 也对)
caps.extend(caption_l1_oct(image_id, cohort_phrase, eye,
device_vendor=row["device_vendor"],
device_model=row["device_model"]))
# L3 也把设备短语 prepend (若已知)
dev = device_phrase(row["device_vendor"], row["device_model"])
if dev:
l3_parts = [f"An OCT B-scan from {dev}, {cohort_phrase}"]
else:
l3_parts = [f"An OCT B-scan from the {cohort_phrase}"]
if disease_label and disease_label not in ("Unknown",):
l3_parts.append(f"label: {disease_label}")
if idx is not None and n_slices > 1:
l3_parts.append(f"slice {idx+1} of {n_slices}")
if l3_extras_fn:
l3_parts.extend(l3_extras_fn(meta, slc))
caps.append(caption_l3_oct(image_id, ", ".join(l3_parts) + ".",
"manifest_fields+csv_labels"))
return rows, caps
# ============================================================
# 17 A-class enumerators (read from unified_metadata.csv)
# ============================================================
def enum_from_csv_simple(ds_df, in_root, csv_dataset_name):
"""File-level studies, patient_hash from patient_id when present.
study_basename = relative path with separators normalized to ensure uniqueness
across train/test/disease subdirs."""
in_root = Path(in_root)
items = []
seen_basenames = set()
for _, r in ds_df.iterrows():
src = r["image_path"]
if not os.path.exists(src):
continue
# Build unique basename from path relative to in_root
try:
rel = str(Path(src).relative_to(in_root))
except ValueError:
rel = src
# Sanitize: replace path separators + spaces + non-ascii safely
study_basename = re.sub(r"[^A-Za-z0-9._-]", "_", rel)
if study_basename in seen_basenames:
# Should not happen given uniqueness of file paths, but defensive
continue
seen_basenames.add(study_basename)
pid = str(r.get("patient_id", "")).strip()
patient_basename = f"patient_{pid}" if pid and pid not in ("Unknown", "nan", "") else study_basename
items.append({
"study_basename": study_basename,
"patient_basename": patient_basename,
"study_meta": {
"disease_label": r.get("disease_label", "Unknown"),
"eye": str(r.get("eye", "unknown")) if str(r.get("eye", "unknown")) != "Unknown" else "unknown",
"patient_id": pid if pid and pid != "Unknown" else None,
"device_csv": r.get("device", "unknown"),
"label_granularity": r.get("label_granularity", "b-scan"),
"notes": r.get("notes", ""),
},
"slices": [{"src_path": src, "slice_idx": None}],
})
return items
def enum_olives(ds_df, in_root):
"""Special: study_id = hash(patient_eye_visit), patient_hash = hash(patient).
Multiple bscans of the same (patient, eye, visit) share study_id with slice_idx."""
visit_path_re = re.compile(r"/W(\d+)/")
# TREX flat filename: 11-01-001_W100_OD_0.tif → patient=01-001, visit=W100, eye=OD, slc=0
visit_fname_re = re.compile(r"_W(\d+)_(O[DS])_(\d+)\b")
groups = defaultdict(list)
for _, r in ds_df.iterrows():
src = r["image_path"]
if not os.path.exists(src):
continue
pid = str(r.get("patient_id", "Unknown"))
eye = str(r.get("eye", "Unknown"))
stem = Path(src).stem
slc = None
# Prefer path-based extraction (Prime_FULL: XX-YYY/Wn/OD/N.png)
m_path = visit_path_re.search(src)
if m_path:
visit = m_path.group(1)
# slice = stem (numeric)
if stem.isdigit():
slc = int(stem)
else:
# TREX flat name
m_fn = visit_fname_re.search(stem)
if m_fn:
visit = m_fn.group(1)
if eye == "Unknown":
eye = m_fn.group(2)
slc = int(m_fn.group(3))
# Patient ID from TREX flat name: 11-XX-YYY_... → pid = XX-YYY
if pid in ("Unknown", "nan", ""):
pid_m = re.match(r"\d+-(\d{2}-\d{3})_", stem)
if pid_m:
pid = pid_m.group(1)
else:
visit = "unknown"
groups[(pid, eye, visit)].append((src, slc, r.get("disease_label", "Unknown"), r.get("notes", "")))
items = []
for (pid, eye, visit), files in groups.items():
# Order by slice index
files.sort(key=lambda x: (x[1] if x[1] is not None else 0))
slices = [{"src_path": src, "slice_idx": i} for i, (src, _, _, _) in enumerate(files)]
# disease_label: take majority (should be uniform within group)
diseases = [f[2] for f in files]
disease = max(set(diseases), key=diseases.count)
items.append({
"study_basename": f"{pid}_{eye}_W{visit}",
"patient_basename": f"patient_{pid}",
"study_meta": {
"disease_label": disease,
"eye": eye if eye in ("OD", "OS") else "unknown",
"patient_id": pid,
"visit": f"W{visit}",
"label_granularity": "visit",
"notes": files[0][3],
},
"slices": slices,
})
return items
def enum_retouch(ds_df, in_root):
"""RETOUCH 3 device sub-cohorts encoded in CSV 'notes' field.
CSV image_path filenames are flat numerics (1.png, 1000.png, ...) — original
volume grouping is LOST in the user's flat enumeration. We thus use file-level
studies, but preserve device subset → device_vendor/model in the row."""
items = []
in_root = Path(in_root)
for _, r in ds_df.iterrows():
src = r["image_path"]
if not os.path.exists(src):
continue
stem = Path(src).stem
notes = str(r.get("notes", ""))
dev_m = re.search(r"TrainingSet-(\w+)", notes)
dev = dev_m.group(1) if dev_m else "Unknown"
dev_model = {"Cirrus": "cirrus_hd_oct", "Spectralis": "spectralis",
"Topcon": "topcon_3d_oct"}.get(dev, "unknown")
dev_vendor = {"Cirrus": "zeiss", "Spectralis": "heidelberg",
"Topcon": "topcon"}.get(dev, "unknown")
# Include device in basename to avoid collision across 3 subsets (Spectralis/1.png
# and Cirrus/1.png both exist as separate volumes)
study_basename = f"retouch_{dev}_{stem}"
items.append({
"study_basename": study_basename,
"patient_basename": study_basename, # no patient grouping recoverable from CSV
"study_meta": {
"disease_label": r.get("disease_label", "AMD/RVO"),
"eye": "unknown",
"patient_id": None,
"device_vendor": dev_vendor,
"device_model": dev_model,
"subset": dev,
"label_granularity": "b-scan", # downgraded from volume since we lost grouping
"has_segmentation_mask": True,
},
"slices": [{"src_path": src, "slice_idx": None}],
})
return items
def enum_oimhs_with_demographics(ds_df, in_root):
"""Items + sidecar. One patient has two eyes (two eye_ids in Images/), each with
its own copy of files named 1.png, 2.png, etc. → must include eye_id in basename
to disambiguate same-patient same-filename collisions."""
items = []
for _, r in ds_df.iterrows():
src = r["image_path"]
if not os.path.exists(src):
continue
stem = Path(src).stem
# path is Images/<eye_id>/<stem>.png → eye_id is parent dir name
eye_id = Path(src).parent.name
pid = str(r.get("patient_id", "Unknown"))
items.append({
"study_basename": f"oimhs_p{pid}_e{eye_id}_{stem}",
"patient_basename": f"patient_{pid}",
"study_meta": {
"disease_label": r.get("disease_label", "MH"),
"eye": str(r.get("eye", "unknown")) if str(r.get("eye", "Unknown")) != "Unknown" else "unknown",
"patient_id": pid,
"eye_id": eye_id,
"age": str(r.get("age", "Unknown")),
"gender": str(r.get("gender", "Unknown")),
"stage": r.get("disease_label", "").replace("MH_Stage", "") if "Stage" in str(r.get("disease_label", "")) else "Unknown",
"label_granularity": "eye",
},
"slices": [{"src_path": src, "slice_idx": None}],
})
return items
def enum_octdl_with_demographics(ds_df, in_root):
"""OCTDL with sex/year(→age)/subcategory/condition sidecar.
Note: CSV's image_path lacks the .jpg extension and disease subfolder. We have
to reconstruct the real path: {OCTDL_root}/OCTDL/{disease}/{stem}.jpg."""
items = []
# Find OCTDL root by walking disk
octdl_root = None
for p in Path(in_root / "23" if not isinstance(in_root, Path) else Path(in_root) / "23").rglob("OCTDL"):
if p.is_dir() and (p / "AMD").exists():
octdl_root = p
break
if octdl_root is None:
print("[octdl] ERROR: cannot find OCTDL root with AMD subdir")
return []
for _, r in ds_df.iterrows():
src_csv = r["image_path"]
disease = r.get("disease_label", "AMD")
stem = Path(src_csv).name # CSV path's last segment = file stem (no ext)
# Try .jpg under disease subdir first
for ext in (".jpg", ".jpeg", ".png", ".JPG", ".JPEG"):
candidate = octdl_root / disease / f"{stem}{ext}"
if candidate.exists():
src = str(candidate)
break
else:
continue # file truly missing
pid = str(r.get("patient_id", "Unknown"))
items.append({
"study_basename": f"octdl_{disease}_{stem}",
"patient_basename": f"patient_{pid}" if pid not in ("Unknown", "nan", "", "0") else f"octdl_{disease}_{stem}",
"study_meta": {
"disease_label": disease,
"eye": str(r.get("eye", "unknown")) if str(r.get("eye", "Unknown")) not in ("Unknown", "0") else "unknown",
"patient_id": pid,
"age": str(r.get("age", "Unknown")),
"gender": str(r.get("gender", "Unknown")),
"notes": r.get("notes", ""),
"label_granularity": "b-scan",
},
"slices": [{"src_path": src, "slice_idx": None}],
})
return items
# ============================================================
# OCTA500 enumerator (filename = volID-sliceID, 300 vol × 400)
# ============================================================
def enum_octa500(in_root, octa500_subdir="OCTA500"):
base = Path(in_root) / octa500_subdir
images_dir = base / "images"
labels_xlsx = base / "Text labels.xlsx"
labels = {}
if labels_xlsx.exists():
df = pd.read_excel(labels_xlsx)
for _, r in df.iterrows():
labels[str(int(r["ID"]))] = {
"disease": str(r["Disease"]).strip(),
"sex": str(r["Sex"]).strip(),
"eye": str(r["OS/OD"]).strip(),
"age": str(r["Age"]).strip(),
}
# Group files by volume ID
groups = defaultdict(list)
for f in sorted(images_dir.glob("*.png")):
m = re.match(r"^(\d+)-(\d+)\.png$", f.name)
if not m:
continue
vol, slc = m.group(1), int(m.group(2))
groups[vol].append((slc, f))
items = []
for vol, files in groups.items():
files.sort()
lab = labels.get(vol, {})
slices = [{"src_path": str(f), "slice_idx": i} for i, (_, f) in enumerate(files)]
items.append({
"study_basename": f"vol_{vol}",
"patient_basename": f"vol_{vol}", # 1 vol = 1 patient (no cross-vol patient ID)
"study_meta": {
"disease_label": lab.get("disease", "Unknown"),
"eye": lab.get("eye", "unknown"),
"patient_id": vol,
"age": lab.get("age", "Unknown"),
"gender": "M" if lab.get("sex") == "M" else ("F" if lab.get("sex") == "F" else "Unknown"),
"label_granularity": "volume",
"has_dc_mask": True, # OCTA500 has B-scan-level 6-class masks
},
"slices": slices,
})
return items
def octa500_post_artifact(meta, sdir):
"""Copy 6-class B-scan masks for OCTA500."""
if not meta.get("has_dc_mask"):
return
mask_root = Path("/mnt/new/OCT Retinal B-scan数据集汇总/OCTA500/masks")
for slc in meta["slices"]:
idx = slc["idx"]
src_fname = Path(slc["src_path"]).name # 10001-0001.png
src_mask = mask_root / src_fname
if src_mask.exists():
dst_mask = sdir / f"mask_{idx:03d}.png"
save_mask_preserve(src_mask, dst_mask, force=False)
def has_segmentation_octa500(meta, slc):
idx = slc["idx"]
sdir_parts = Path(meta["slices"][0]["src_path"]).parent # not used
# The mask is saved post-hoc with mask_{idx:03d}.png inside study_dir.
# has_segmentation is True if the corresponding mask file existed at source.
src_fname = Path(slc["src_path"]).name
mask_root = Path("/mnt/new/OCT Retinal B-scan数据集汇总/OCTA500/masks")
return (mask_root / src_fname).exists()
# ============================================================
# UESTC enumerator (3 sub-protocols)
# ============================================================
def enum_uestc(in_root, uestc_subdir="UESTC天池"):
base = Path(in_root) / uestc_subdir
items = []
sub_to_protocol = {
"Dataset_speckle_OCT_3D_6x6_split": ("BMizar 6x6mm", "uestc_bmizar_6x6"),
"Dataset_speckle_OCT_3D_20x24_split": ("BMizar 20x24mm", "uestc_bmizar_20x24"),
"Dataset_speckle_OCT_3D_Spectralis_split": ("Spectralis", "uestc_spectralis"),
}
for sub, (subset_name, subset_id) in sub_to_protocol.items():
sub_dir = base / sub
if not sub_dir.exists():
continue
files = sorted(sub_dir.glob("*.tif"))
for f in files:
stem = f.stem # e.g. 000000
dev_vendor = "spectralis_bmizar" if "bmizar" in subset_id else "heidelberg"
dev_model = "bm_400k_bmizar" if "bmizar" in subset_id else "spectralis"
items.append({
"study_basename": f"{subset_id}_{stem}",
"patient_basename": f"{subset_id}_{stem}", # no patient grouping info
"study_meta": {
"disease_label": "Unknown",
"eye": "unknown",
"patient_id": None,
"subset": subset_name,
"subset_id": subset_id,
"device_vendor": dev_vendor,
"device_model": dev_model,
"label_granularity": "b-scan",
},
"slices": [{"src_path": str(f), "slice_idx": None}],
})
return items
def build_row_caps_uestc(meta, cohort, cohort_phrase):
"""UESTC override: scan_protocol per subset, severity always unknown."""
cfg = COHORT_CONFIG[cohort]
sh = meta["study_hash"]; ph = meta["patient_hash"]
eye = meta.get("eye", "unknown")
subset = meta.get("subset_id", "")
subset_label = meta.get("subset", "unknown")
base = default_base_fields(
cohort, sh, patient_hash=ph, eye=eye,
ethnicity="Asian", hospital_domain="uestc_sichuan_v1")
base["device_vendor"] = meta.get("device_vendor", "varies")
base["device_model"] = meta.get("device_model", "varies")
base["severity"] = "unknown"
base["diagnosis_source"] = "none"
# scan_protocol distinguishes subsets
scan_protocol = {
"uestc_bmizar_6x6": "volume_3d_macula_6x6mm",
"uestc_bmizar_20x24": "volume_3d_macula_20x24mm",
"uestc_spectralis": "volume_3d_macula_spectralis",
}.get(subset, "volume_3d_macula")
rows, caps = [], []
for slc in meta["slices"]:
idx = slc["idx"]
image_id = f"{cohort}_{sh}_bscan"
file_path = rel_file_path(cohort, sh, "bscan.png")
row = dict(base)
row.update({
"image_id": image_id, "file_path": file_path,
"file_format": "png", "modality": "oct_bscan",
"anatomy": "macula", "device_technology": "sd_oct",
"scan_protocol": scan_protocol, "bscan_index": idx,
"image_height_px": slc["h"], "image_width_px": slc["w"],
"has_segmentation": False, "n_layers_visible": 0,
"is_valid": True,
})
rows.append(row)
caps.extend(caption_l1_oct(image_id, cohort_phrase, eye,
device_vendor=row["device_vendor"],
device_model=row["device_model"]))
dev = device_phrase(row["device_vendor"], row["device_model"])
if dev:
l3 = f"An OCT B-scan from {dev}, {cohort_phrase}, {subset_label} subset."
else:
l3 = f"An OCT B-scan from the {cohort_phrase}, {subset_label} subset."
caps.append(caption_l3_oct(image_id, l3, "manifest_fields+subset"))
return rows, caps
# ============================================================
# Sidecar builders
# ============================================================
def sidecar_demographics(meta):
age = meta.get("age", "Unknown")
gender = meta.get("gender", "Unknown")
if age in (None, "Unknown", "", "nan") and gender in (None, "Unknown", "", "nan"):
return None
return {
"study_id": meta["study_hash"],
"patient_hash": meta["patient_hash"],
"image_id_pattern": f"{meta['cohort']}_{meta['study_hash']}_bscan",
"age": str(age),
"gender": str(gender),
"eye": meta.get("eye", "unknown"),
"disease_label": meta.get("disease_label", "Unknown"),
}
# ============================================================
# Mask post-artifact helpers for datasets that have masks
# ============================================================
def aroi_post_artifact(meta, sdir):
"""AROI mask: 6/AROI/AROI - online/24 patient/patientN/mask/<filename>"""
src = Path(meta["slices"][0]["src_path"])
stem = src.stem # e.g. 6-patient1_raw0001
pid_m = re.match(r"6-(patient\d+)_raw(\d+)", stem)
if not pid_m:
return
pid, raw_idx = pid_m.group(1), pid_m.group(2)
mask_src = Path("/mnt/new/OCT Retinal B-scan数据集汇总/6/AROI/AROI - online/24 patient") / pid / "mask" / f"raw{raw_idx}.png"
if mask_src.exists():
save_mask_preserve(mask_src, sdir / "layer_mask.png")
def oimhs_post_artifact(meta, sdir):
"""OIMHS mask: 16/OIMHS dataset/output_layer/16-patient{eye_id}-{img_stem}_layer.png"""
src = Path(meta["slices"][0]["src_path"])
eye_id = src.parent.name # Images/{eye_id}/file.png
mask_src = Path(f"/mnt/new/OCT Retinal B-scan数据集汇总/16/OIMHS dataset/output_layer/16-patient{eye_id}-{src.stem}_layer.png")
if mask_src.exists():
save_mask_preserve(mask_src, sdir / "layer_mask.png")
def retouch_post_artifact(meta, sdir):
"""RETOUCH mask in parallel masks/ dir."""
for slc in meta["slices"]:
src = Path(slc["src_path"])
mask_src = src.parent.parent / "masks" / src.name
if mask_src.exists():
dst_name = "fluid_mask.png" if slc["idx"] is None else f"fluid_mask_{slc['idx']:03d}.png"
save_mask_preserve(mask_src, sdir / dst_name)
def amd_sd_post_artifact(meta, sdir):
"""AMD-SD mask: AMD-SD/masks/{filename}"""
src = Path(meta["slices"][0]["src_path"])
mask_src = src.parent.parent / "masks" / src.name
if mask_src.exists():
save_mask_preserve(mask_src, sdir / "lesion_mask.png")
def chiu_post_artifact(meta, sdir):
"""Chiu DME masks (8 layers + fluid) — masks are in parallel dir if extracted by user."""
src = Path(meta["slices"][0]["src_path"])
mask_src = src.parent.parent / "masks" / src.name
if mask_src.exists():
save_mask_preserve(mask_src, sdir / "layer_mask.png")
# ============================================================
# Main dispatcher
# ============================================================
CSV_NAME_TO_COHORT = {
"Kermany": ("public_oct_kermany", None, None, None),
"OCTID": ("public_oct_octid", None, None, None),
"AROI": ("public_oct_aroi", None, None, aroi_post_artifact),
"NEH_UT_2021": ("public_oct_neh_ut_2021", None, None, None),
"AREDS2": ("public_oct_areds2", None, None, None),
"Glaucoma_OCT": ("public_oct_glaucoma", None, None, None),
"NYU_POAG": ("public_oct_nyu_poag", None, None, None),
"OLIVES": ("public_oct_olives", enum_olives, None, None),
"Chiu_DME_2015": ("public_oct_chiu_dme_2015", None, None, chiu_post_artifact),
"Srinivasan_2014": ("public_oct_srinivasan_2014", None, None, None),
"Sparsity_SDOCT_2012": ("public_oct_sparsity_sdoct_2012", None, None, None),
"OIMHS": ("public_oct_oimhs", enum_oimhs_with_demographics, sidecar_demographics, oimhs_post_artifact),
"RETOUCH": ("public_oct_retouch", enum_retouch, None, retouch_post_artifact),
"THOCT1800": ("public_oct_thoct1800", None, None, None),
"OCTDL": ("public_oct_octdl", enum_octdl_with_demographics, sidecar_demographics, None),
"AMD-SD": ("public_oct_amd_sd", None, None, amd_sd_post_artifact),
"C8": ("public_oct_c8", None, None, None),
}
def main():
ap = argparse.ArgumentParser()
ap.add_argument("--input-root", required=True,
help="Path to '/mnt/new/OCT Retinal B-scan数据集汇总'")
ap.add_argument("--output-root", required=True,
help="Output root (will create extracted/, manifest/, captions/)")
ap.add_argument("--csv", default=None,
help="Path to unified_metadata.csv (default: <input-root>/数据分类整理汇总/unified_metadata.csv)")
ap.add_argument("--cohorts", default="all",
help="comma-separated cohort names (full or short like 'kermany,octa500'), or 'all'")
ap.add_argument("--num-workers", type=int, default=8)
ap.add_argument("--force", action="store_true")
ap.add_argument("--limit-per-cohort", type=int, default=None,
help="for testing: process only first N studies per cohort")
args = ap.parse_args()
in_root = Path(args.input_root)
out_root = Path(args.output_root)
csv_path = Path(args.csv) if args.csv else (in_root / "数据分类整理汇总" / "unified_metadata.csv")
all_cohort_names = list(set(v[0] for v in CSV_NAME_TO_COHORT.values())) + [
"public_oct_octa500", "public_oct_uestc"]
if args.cohorts == "all":
cohorts_to_run = set(all_cohort_names)
else:
requested = [c.strip() for c in args.cohorts.split(",")]
cohorts_to_run = set()
for r in requested:
for full in all_cohort_names:
if full == r or full.endswith(f"_{r}") or r in full:
cohorts_to_run.add(full)
print(f"Will process {len(cohorts_to_run)} cohorts:")
for c in sorted(cohorts_to_run):
print(f" {c}")
print()
# CSV-driven A-class cohorts
if any(v[0] in cohorts_to_run for v in CSV_NAME_TO_COHORT.values()):
print(f"Loading CSV: {csv_path}")
csv_df = pd.read_csv(csv_path, low_memory=False)
print(f" {len(csv_df)} rows")
for csv_name, (cohort, enum_fn, sidecar_fn, post_fn) in CSV_NAME_TO_COHORT.items():
if cohort not in cohorts_to_run:
continue
ds_df = csv_df[csv_df["dataset_name"] == csv_name]
if len(ds_df) == 0:
print(f"[{cohort}] no CSV rows for dataset {csv_name}, skipping")
continue
if enum_fn is None:
items = enum_from_csv_simple(ds_df, in_root, csv_name)
else:
items = enum_fn(ds_df, in_root)
if args.limit_per_cohort:
items = items[:args.limit_per_cohort]
run_cohort(cohort, items, _shared_build_row_caps, out_root,
num_workers=args.num_workers, force=args.force,
sidecar_fn=sidecar_fn, cohort_phrase=COHORT_CONFIG[cohort]["phrase"],
post_artifact_fn=post_fn)
# OCTA500
if "public_oct_octa500" in cohorts_to_run:
items = enum_octa500(in_root)
if args.limit_per_cohort:
items = items[:args.limit_per_cohort]
def build_octa500(meta, cohort, cohort_phrase):
return _shared_build_row_caps(
meta, cohort, cohort_phrase,
has_segmentation_fn=has_segmentation_octa500,
l3_extras_fn=lambda m, s: ["with B-scan-level 6-class segmentation mask"]
if has_segmentation_octa500(m, s) else [],
)
run_cohort("public_oct_octa500", items, build_octa500, out_root,
num_workers=args.num_workers, force=args.force,
sidecar_fn=sidecar_demographics,
cohort_phrase=COHORT_CONFIG["public_oct_octa500"]["phrase"],
post_artifact_fn=octa500_post_artifact)
# UESTC
if "public_oct_uestc" in cohorts_to_run:
items = enum_uestc(in_root)
if args.limit_per_cohort:
items = items[:args.limit_per_cohort]
run_cohort("public_oct_uestc", items, build_row_caps_uestc, out_root,
num_workers=args.num_workers, force=args.force,
sidecar_fn=None,
cohort_phrase=COHORT_CONFIG["public_oct_uestc"]["phrase"],
post_artifact_fn=None)
print("\n[main] all done.")
if __name__ == "__main__":
main()