venice-h1 / train.py
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#!/usr/bin/env python3
"""
Train Venice-H1 re-ranker on pre-extracted DeRIS feature caches.
Matches paper Section 3.5 exactly:
- Loss: L = L_gate + λ·L_gain (λ=5)
- L_gate: focal BCE (γ=2, auto w_pos)
- L_gain: smooth-L1 IoU regression on ALL samples
- AdamW (lr=5e-4, wd=1e-4), cosine + 3-epoch warmup
- 20 epochs, batch 512, FP16
- Training time: ~3 min on single RTX 3090
Usage:
python train.py --config venice_h1/configs/default.yaml
python train.py --config venice_h1/configs/default.yaml --no_grid
"""
import argparse
import os
import random
from pathlib import Path
import numpy as np
import torch
import torch.nn as nn
import torch.nn.functional as F
from torch.utils.data import DataLoader, Dataset, ConcatDataset
from torch.cuda.amp import GradScaler, autocast
try:
from torch.utils.tensorboard import SummaryWriter
_HAS_TB = True
except ImportError:
_HAS_TB = False
try:
import yaml
except ImportError:
raise SystemExit("pip install pyyaml")
try:
from sklearn.metrics import roc_auc_score
_HAS_SKLEARN = True
except ImportError:
_HAS_SKLEARN = False
from venice_h1.model.reranker import VeniceH1Reranker
def set_seed(seed: int):
random.seed(seed)
np.random.seed(seed)
torch.manual_seed(seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(seed)
def load_config(path: str) -> dict:
with open(path) as f:
return yaml.safe_load(f)
# ---------------------------------------------------------------------------
# Dataset
# ---------------------------------------------------------------------------
class FeatureCacheDataset(Dataset):
"""Loads a pre-extracted .pt feature cache from extract_features.py."""
def __init__(self, path: str, use_grid: bool = True):
data = torch.load(path, map_location="cpu")
self.use_grid = use_grid
self.query_feat = data["query_feat"].float()
self.det_scores = data["det_scores"].float()
self.query_ious = data["query_ious"].float()
self.oracle_idx = data["oracle_idx"].long()
self.mask_mean = data["mask_mean"].float()
self.mask_max = data["mask_max"].float()
self.mask_area = data["mask_area"].float()
self.mask_std = data["mask_std"].float()
if use_grid:
self.grid_mean_4 = data["grid_mean_4"].float()
self.grid_max_4 = data["grid_max_4"].float()
self.boundary_4 = data["boundary_4"].float()
self.grid_mean_8 = data["grid_mean_8"].float()
self.grid_max_8 = data["grid_max_8"].float()
self.boundary_8 = data["boundary_8"].float()
self.grid_mean_16 = data["grid_mean_16"].float()
self.grid_max_16 = data["grid_max_16"].float()
self.boundary_16 = data["boundary_16"].float()
self.failure_flag = (self.oracle_idx != 0).float()
def __len__(self):
return len(self.oracle_idx)
def __getitem__(self, idx):
N = self.query_feat.shape[1]
qf = self.query_feat[idx] # [N, D]
ds = self.det_scores[idx].unsqueeze(-1) # [N, 1]
mm = self.mask_mean[idx].unsqueeze(-1) # [N, 1]
mx = self.mask_max[idx].unsqueeze(-1) # [N, 1]
ma = self.mask_area[idx].unsqueeze(-1) # [N, 1]
ms = self.mask_std[idx].unsqueeze(-1) # [N, 1]
parts = [qf, ds, mm, mx, ma, ms] # [N, D+5]
if self.use_grid:
gm4 = self.grid_mean_4[idx] # [N, 16]
gx4 = self.grid_max_4[idx] # [N, 16]
b4 = self.boundary_4[idx].unsqueeze(-1) # [N, 1]
gm8 = self.grid_mean_8[idx] # [N, 64]
gx8 = self.grid_max_8[idx] # [N, 64]
b8 = self.boundary_8[idx].unsqueeze(-1) # [N, 1]
gm16 = self.grid_mean_16[idx] # [N, 256]
gx16 = self.grid_max_16[idx] # [N, 256]
b16 = self.boundary_16[idx].unsqueeze(-1) # [N, 1]
parts += [gm4, gx4, b4, gm8, gx8, b8, gm16, gx16, b16]
features = torch.cat(parts, dim=-1) # [N, 936]
return {
"features": features,
"det_scores": self.det_scores[idx],
"mask_means": self.mask_mean[idx],
"oracle_idx": self.oracle_idx[idx],
"failure_flag": self.failure_flag[idx],
"query_ious": self.query_ious[idx],
}
# ---------------------------------------------------------------------------
# Loss (Section 3.5)
# ---------------------------------------------------------------------------
def focal_bce_loss(pred: torch.Tensor, target: torch.Tensor,
gamma: float = 2.0, pos_weight: float | None = None):
"""Focal binary cross-entropy (Eq. in Section 3.5)."""
if pos_weight is not None:
weight = torch.where(target > 0.5, pos_weight, 1.0)
else:
weight = None
bce = F.binary_cross_entropy(pred, target, reduction='none')
pt = pred * target + (1 - pred) * (1 - target)
focal = ((1 - pt) ** gamma) * bce
if weight is not None:
focal = focal * weight
return focal.mean()
def compute_loss(out: dict, batch: dict, cfg: dict) -> dict:
"""L = L_gate + λ·L_gain (Section 3.5)."""
device = out["p_fail"].device
tcfg = cfg["training"]
failure_flag = batch["failure_flag"].to(device)
query_ious = batch["query_ious"].to(device)
# Auto positive weight for focal BCE
n_pos = failure_flag.sum().clamp(min=1)
n_neg = (1 - failure_flag).sum().clamp(min=1)
wpos = (n_neg / n_pos).clamp(max=50.0) if tcfg.get("auto_wpos") else None
# L_gate: focal BCE
loss_gate = focal_bce_loss(
out["p_fail"], failure_flag,
gamma=tcfg["focal_gamma"], pos_weight=wpos)
# L_gain: smooth-L1 on IoU gain (all samples, dense supervision)
gain_target = query_ious - query_ious[:, 0:1] # relative to Q0
loss_gain = F.smooth_l1_loss(out["gain_logits"], gain_target)
# Total loss
total = loss_gate + tcfg["lambda_gain"] * loss_gain
return {"total": total, "gate": loss_gate, "gain": loss_gain}
# ---------------------------------------------------------------------------
# Evaluation
# ---------------------------------------------------------------------------
@torch.no_grad()
def evaluate(model, loader, device, tau: float = 0.05) -> dict:
model.eval()
total = failures = reranked_count = correct = harmful = 0
all_pfail, all_flag = [], []
for batch in loader:
features = batch["features"].to(device)
det_scores = batch["det_scores"].to(device)
mask_means = batch["mask_means"].to(device)
oracle_idx = batch["oracle_idx"].to(device)
failure_flag = batch["failure_flag"].to(device)
query_ious = batch["query_ious"].to(device)
out = model(features, det_scores, mask_means)
selected = model.rerank(features, det_scores, mask_means, tau=tau)
B = len(oracle_idx)
total += B
fail_mask = failure_flag.bool()
failures += fail_mask.sum().item()
reranked_mask = selected != 0
reranked_count += reranked_mask.sum().item()
correct += (selected[fail_mask] == oracle_idx[fail_mask]).sum().item()
q0_iou = query_ious[:, 0]
sel_iou = query_ious.gather(1, selected.unsqueeze(1)).squeeze(1)
harmful += (reranked_mask & (sel_iou < q0_iou - 0.01)).sum().item()
all_pfail.append(out["p_fail"].cpu())
all_flag.append(failure_flag.cpu())
all_pfail = torch.cat(all_pfail).numpy()
all_flag = torch.cat(all_flag).numpy()
auc = roc_auc_score(all_flag, all_pfail) if _HAS_SKLEARN and all_flag.sum() > 0 else 0.0
return {
"failure_rate": failures / max(total, 1),
"rerank_rate": reranked_count / max(total, 1),
"correct_rerank": correct / max(failures, 1),
"harmful_switch": harmful / max(total, 1),
"gate_auc": auc,
}
# ---------------------------------------------------------------------------
# Main
# ---------------------------------------------------------------------------
def main():
parser = argparse.ArgumentParser(description="Train Venice-H1 re-ranker")
parser.add_argument("--config", default="venice_h1/configs/default.yaml")
parser.add_argument("--no_grid", action="store_true",
help="Ablation: BASE features only (Df=261)")
parser.add_argument("--tau", type=float, default=None)
args = parser.parse_args()
cfg = load_config(args.config)
if args.no_grid:
cfg["model"]["use_grid"] = False
set_seed(cfg["training"]["seed"])
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
print(f"Device: {device}")
use_grid = cfg["model"]["use_grid"]
tau = args.tau if args.tau is not None else cfg["model"]["tau"]
# ---- Data ----
train_paths = [p for p in cfg["data"]["train_splits"] if Path(p).exists()]
val_paths = [p for p in cfg["data"]["val_splits"] if Path(p).exists()]
if not train_paths:
print("ERROR: No training data found. Run extract_features.py first.")
print("Expected paths:", cfg["data"]["train_splits"])
return
train_ds = ConcatDataset([FeatureCacheDataset(p, use_grid) for p in train_paths])
val_ds = ConcatDataset([FeatureCacheDataset(p, use_grid) for p in val_paths]) \
if val_paths else None
bs = cfg["training"]["batch_size"]
train_loader = DataLoader(train_ds, batch_size=bs, shuffle=True,
num_workers=4, pin_memory=True, drop_last=True)
val_loader = DataLoader(val_ds, batch_size=bs, shuffle=False,
num_workers=4, pin_memory=True) if val_ds else None
print(f"Train: {len(train_ds):,} samples | "
f"Val: {len(val_ds) if val_ds else 0:,} samples")
print(f"Feature set: {'BASE+GRID (Df=936)' if use_grid else 'BASE (Df=261)'}")
# ---- Model ----
model = VeniceH1Reranker(**cfg["model"]).to(device)
print(f"Venice-H1: {model.num_parameters():,} parameters (~11.3M)")
# ---- Optimizer (Section 3.5: AdamW, lr=5e-4, wd=1e-4) ----
optimizer = torch.optim.AdamW(
model.parameters(),
lr=cfg["training"]["lr"],
weight_decay=cfg["training"]["weight_decay"])
epochs = cfg["training"]["epochs"]
warmup = cfg["training"]["warmup_epochs"]
def lr_lambda(epoch):
if epoch < warmup:
return epoch / warmup
progress = (epoch - warmup) / (epochs - warmup)
return 0.5 * (1 + np.cos(np.pi * progress))
scheduler = torch.optim.lr_scheduler.LambdaLR(optimizer, lr_lambda)
# FP16
scaler = GradScaler() if cfg["training"].get("fp16") else None
# Logging
writer = SummaryWriter(cfg["output"]["log_dir"]) if _HAS_TB else None
ckpt_dir = cfg["output"]["checkpoint_dir"]
os.makedirs(ckpt_dir, exist_ok=True)
best_auc = 0.0
# ---- Training Loop ----
print(f"\nTraining for {epochs} epochs (batch={bs}, lr={cfg['training']['lr']})")
print("-" * 70)
for epoch in range(1, epochs + 1):
model.train()
epoch_loss = 0.0
for batch in train_loader:
features = batch["features"].to(device)
det_scores = batch["det_scores"].to(device)
mask_means = batch["mask_means"].to(device)
optimizer.zero_grad()
if scaler:
with autocast():
out = model(features, det_scores, mask_means)
losses = compute_loss(out, batch, cfg)
scaler.scale(losses["total"]).backward()
scaler.unscale_(optimizer)
nn.utils.clip_grad_norm_(model.parameters(), 1.0)
scaler.step(optimizer)
scaler.update()
else:
out = model(features, det_scores, mask_means)
losses = compute_loss(out, batch, cfg)
losses["total"].backward()
nn.utils.clip_grad_norm_(model.parameters(), 1.0)
optimizer.step()
epoch_loss += losses["total"].item()
scheduler.step()
avg_loss = epoch_loss / len(train_loader)
# Validation
metrics = evaluate(model, val_loader, device, tau=tau) if val_loader else {}
if writer:
writer.add_scalar("train/loss", avg_loss, epoch)
for k, v in metrics.items():
writer.add_scalar(f"val/{k}", v, epoch)
auc = metrics.get("gate_auc", 0)
harm = metrics.get("harmful_switch", 0) * 100
print(f" Epoch {epoch:2d}/{epochs} | loss={avg_loss:.4f} | "
f"AUC={auc:.3f} | harmful={harm:.2f}%")
if auc > best_auc:
best_auc = auc
torch.save(
{"epoch": epoch, "model": model.state_dict(),
"config": cfg, "metrics": metrics},
os.path.join(ckpt_dir, "best.pt"))
if writer:
writer.close()
print(f"\nDone. Best Gate AUC: {best_auc:.4f}")
print(f"Checkpoint: {os.path.join(ckpt_dir, 'best.pt')}")
if __name__ == "__main__":
main()