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V4: Test-Time Self-Consistency.
For each validation image:
1. S(I) -> P_direct (standard segmentation)
2. Binarize P_direct -> M0
3. G(M0, z_1..z_N) -> generate N views
4. S(view_i) -> P_i for each view
5. P_ensemble = mean(sigmoid(P_i))
6. P_combined = alpha * P_direct + (1-alpha) * P_ensemble
Compares: direct, ensemble, combined strategies.
Usage:
python scripts/v4_test_time.py --condition cycle_consist --seed 42
python scripts/v4_test_time.py --condition baseline --seed 42
"""
import sys
sys.path.insert(0, "/data/sichengli/Code/PixelGen")
import argparse
import os
import json
import random
import numpy as np
import torch
import torch.nn.functional as F
from torch.utils.data import Dataset, DataLoader
from PIL import Image
import torchvision.transforms as transforms
import torchvision.transforms.functional as TF
import segmentation_models_pytorch as smp
from src.models.transformer.JiT_medical import JiTMedical
from segmentation.metrics import compute_dice_iou_binary, MetricTracker
# βββ Config βββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
KVASIR_ROOT = "/data2/sichengli/Data/test/Segmentation/Kvasir-SEG/Kvasir-SEG"
WORK_DIR = "/data/sichengli/Code/PixelGen/synergy_v4_workdir"
PIXELGEN_CKPT = "/data/sichengli/Code/PixelGen/medical_workdirs/exp_PixelGen_Medical_Kvasir/epoch=12499-step=100000.ckpt"
RESOLUTION = 256
TRAIN_RATIO = 0.9
SPLIT_SEED = 42
IMAGENET_MEAN = [0.485, 0.456, 0.406]
IMAGENET_STD = [0.229, 0.224, 0.225]
MODEL_KWARGS = dict(
input_size=256, patch_size=16, in_channels=3,
hidden_size=768, depth=12, num_heads=12, mlp_ratio=4.0,
attn_drop=0.0, proj_drop=0.1, num_classes=1,
use_bottleneck=True, bottleneck_dim=128,
in_context_len=32, in_context_start=4, mask_in_channels=1,
mask_mode="spatial"
)
NUM_STEPS = 50
CFG_SCALE = 2.0
# βββ Dataset ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
class KvasirValDataset(Dataset):
"""Kvasir validation set (100 images)."""
def __init__(self):
self.normalize = transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
img_dir = os.path.join(KVASIR_ROOT, "images")
mask_dir = os.path.join(KVASIR_ROOT, "masks")
all_files = sorted([
f for f in os.listdir(img_dir)
if f.endswith((".jpg", ".png", ".jpeg"))
])
random.seed(SPLIT_SEED)
indices = list(range(len(all_files)))
random.shuffle(indices)
split_idx = int(len(indices) * TRAIN_RATIO)
val_indices = indices[split_idx:]
self.files = [all_files[i] for i in sorted(val_indices)]
self.img_dir = img_dir
self.mask_dir = mask_dir
print(f"[KvasirValDataset] {len(self.files)} validation samples")
def __len__(self):
return len(self.files)
def __getitem__(self, idx):
fname = self.files[idx]
image = Image.open(os.path.join(self.img_dir, fname)).convert("RGB")
mask = Image.open(os.path.join(self.mask_dir, fname)).convert("L")
image = TF.resize(image, (RESOLUTION, RESOLUTION),
interpolation=transforms.InterpolationMode.BILINEAR)
mask = TF.resize(mask, (RESOLUTION, RESOLUTION),
interpolation=transforms.InterpolationMode.NEAREST)
image_tensor = self.normalize(TF.to_tensor(image))
mask_np = np.array(mask)
mask_np = (mask_np > 127).astype(np.float32)
mask_tensor = torch.from_numpy(mask_np).unsqueeze(0)
return image_tensor, mask_tensor
# βββ PixelGen Sampling ββββββββββββββββββββββββββββββββββββββββββββββββ
def shift_respace_fn(t, shift=1.0):
return t / (t + (1 - t) * shift)
@torch.no_grad()
def sample_batch_cfg(model, noise, mask, num_steps=50, cfg_scale=2.0, t_eps=0.05):
"""Euler ODE sampler with CFG."""
batch_size = noise.shape[0]
timesteps = torch.linspace(0.0, 1 - 1.0 / num_steps, num_steps)
timesteps = torch.cat([timesteps, torch.tensor([1.0])], dim=0)
timesteps = shift_respace_fn(timesteps, 1.0).to(noise.device)
y = torch.zeros(batch_size, dtype=torch.long, device=noise.device)
x = noise
for i in range(len(timesteps) - 1):
t_cur = timesteps[i]
t_next = timesteps[i + 1]
dt = t_next - t_cur
t_batch = t_cur.repeat(batch_size)
cfg_x = torch.cat([x, x], dim=0)
cfg_t = t_batch.repeat(2)
cfg_y = torch.cat([y, y], dim=0)
cfg_mask = torch.cat([torch.zeros_like(mask), mask], dim=0)
pred = model(cfg_x, cfg_t, cfg_y, mask=cfg_mask)
pred_v = (pred - cfg_x) / (1.0 - cfg_t.view(-1, 1, 1, 1)).clamp_min(t_eps)
v_uncond, v_cond = pred_v.chunk(2)
v = v_uncond + cfg_scale * (v_cond - v_uncond)
x = x + v * dt
return x
def load_pixelgen(ckpt_path, device):
ckpt = torch.load(ckpt_path, map_location="cpu", weights_only=False)
state_dict = ckpt["state_dict"]
ema_state = {}
for k, v in state_dict.items():
if k.startswith("ema_denoiser."):
new_k = k.replace("ema_denoiser.", "").replace("_orig_mod.", "")
ema_state[new_k] = v
model = JiTMedical(**MODEL_KWARGS)
result = model.load_state_dict(ema_state, strict=False)
print(f"PixelGen loaded ({len(ema_state)} keys), missing: {result.missing_keys}, unexpected: {result.unexpected_keys}")
model = model.to(device).eval().to(torch.float32)
return model
def load_segmentor(condition, seed, device):
ckpt_path = os.path.join(WORK_DIR, "checkpoints", f"{condition}_seed{seed}", "best.pth")
model = smp.Unet(
encoder_name="resnet34",
encoder_weights="imagenet",
in_channels=3,
classes=1,
)
ckpt = torch.load(ckpt_path, map_location="cpu", weights_only=False)
model.load_state_dict(ckpt["model_state_dict"])
model = model.to(device).eval()
print(f"Segmentor loaded: {ckpt_path} (best_dice={ckpt['best_dice']:.4f})")
return model
# βββ Test-Time Self-Consistency βββββββββββββββββββββββββββββββββββββββ
@torch.no_grad()
def test_time_consistency(segmentor, pixelgen, val_loader, device,
n_views=5, alpha=0.5):
"""
For each val image:
direct: S(I)
ensemble: mean(S(G(S(I)->M0, z_i))) for i=1..n_views
combined: alpha * direct + (1-alpha) * ensemble
"""
normalize = transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
tracker_direct = MetricTracker()
tracker_ensemble = MetricTracker()
tracker_combined = MetricTracker()
for batch_idx, (images, gt_masks) in enumerate(val_loader):
images = images.to(device)
gt_masks = gt_masks.to(device)
bs = images.shape[0]
# Step 1: Direct prediction
logits_direct = segmentor(images)
p_direct = torch.sigmoid(logits_direct) # [B, 1, H, W]
dice_d, iou_d = compute_dice_iou_binary(logits_direct, gt_masks)
tracker_direct.update(dice_d, iou_d, bs)
# Step 2: Binarize -> M0 (for PixelGen, mask in [0, 1])
m0 = (p_direct > 0.5).float() # [B, 1, H, W]
# Step 3: Generate N views and re-segment
ensemble_probs = torch.zeros_like(p_direct) # [B, 1, H, W]
for v in range(n_views):
noise = torch.randn(bs, 3, RESOLUTION, RESOLUTION, device=device)
gen_images = sample_batch_cfg(pixelgen, noise, m0, NUM_STEPS, CFG_SCALE)
gen_images = gen_images.clamp(-1, 1) * 0.5 + 0.5 # [-1,1] -> [0,1]
# Normalize for segmentor
gen_normalized = torch.stack([normalize(img) for img in gen_images])
logits_v = segmentor(gen_normalized)
p_v = torch.sigmoid(logits_v)
ensemble_probs += p_v
ensemble_probs /= n_views # [B, 1, H, W]
# Evaluate ensemble
ensemble_preds = (ensemble_probs > 0.5).float()
smooth = 1e-6
inter_e = (ensemble_preds.view(bs, -1) * gt_masks.view(bs, -1)).sum(1)
pred_sum_e = ensemble_preds.view(bs, -1).sum(1)
gt_sum_e = gt_masks.view(bs, -1).sum(1)
dice_e = ((2 * inter_e + smooth) / (pred_sum_e + gt_sum_e + smooth)).mean().item()
iou_e = ((inter_e + smooth) / (pred_sum_e + gt_sum_e - inter_e + smooth)).mean().item()
tracker_ensemble.update(dice_e, iou_e, bs)
# Combined
p_combined = alpha * p_direct + (1 - alpha) * ensemble_probs
combined_preds = (p_combined > 0.5).float()
inter_c = (combined_preds.view(bs, -1) * gt_masks.view(bs, -1)).sum(1)
pred_sum_c = combined_preds.view(bs, -1).sum(1)
gt_sum_c = gt_masks.view(bs, -1).sum(1)
dice_c = ((2 * inter_c + smooth) / (pred_sum_c + gt_sum_c + smooth)).mean().item()
iou_c = ((inter_c + smooth) / (pred_sum_c + gt_sum_c - inter_c + smooth)).mean().item()
tracker_combined.update(dice_c, iou_c, bs)
print(f" Batch {batch_idx+1}/{len(val_loader)} | "
f"Direct: {dice_d:.4f} | Ensemble: {dice_e:.4f} | Combined: {dice_c:.4f}")
return {
"direct": {"dice": tracker_direct.avg_dice, "iou": tracker_direct.avg_iou},
"ensemble": {"dice": tracker_ensemble.avg_dice, "iou": tracker_ensemble.avg_iou},
"combined": {"dice": tracker_combined.avg_dice, "iou": tracker_combined.avg_iou},
}
# βββ Main βββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
def main():
parser = argparse.ArgumentParser()
parser.add_argument("--condition", type=str, default="cycle_consist",
choices=["no_aug", "baseline", "cycle", "consist", "cycle_consist"])
parser.add_argument("--seed", type=int, default=42)
parser.add_argument("--n_views", type=int, default=5)
parser.add_argument("--alpha", type=float, default=0.5)
parser.add_argument("--gpu", type=int, default=0)
args = parser.parse_args()
device = torch.device(f"cuda:{args.gpu}")
print(f"\n{'='*60}")
print(f" V4 Test-Time Self-Consistency")
print(f" Condition: {args.condition}, Seed: {args.seed}")
print(f" N_views: {args.n_views}, Alpha: {args.alpha}")
print(f"{'='*60}\n")
# Load models
segmentor = load_segmentor(args.condition, args.seed, device)
pixelgen = load_pixelgen(PIXELGEN_CKPT, device)
# Load validation set
val_dataset = KvasirValDataset()
val_loader = DataLoader(val_dataset, batch_size=4, shuffle=False,
num_workers=4, pin_memory=True)
# Run test-time consistency
results = test_time_consistency(
segmentor, pixelgen, val_loader, device,
n_views=args.n_views, alpha=args.alpha
)
# Print results
print(f"\n{'='*60}")
print(f" TEST-TIME SELF-CONSISTENCY RESULTS")
print(f" Condition: {args.condition}, Seed: {args.seed}")
print(f"{'='*60}")
print(f"{'Strategy':<12s} | {'Dice':>8s} | {'IoU':>8s}")
print("-" * 35)
for strategy in ["direct", "ensemble", "combined"]:
r = results[strategy]
print(f"{strategy:<12s} | {r['dice']:>8.4f} | {r['iou']:>8.4f}")
print("=" * 35)
# Save results
output = {
"condition": args.condition,
"seed": args.seed,
"n_views": args.n_views,
"alpha": args.alpha,
"results": results,
}
out_path = os.path.join(WORK_DIR, "test_time_results.json")
# Merge with existing
all_results = {}
if os.path.exists(out_path):
with open(out_path, "r") as f:
all_results = json.load(f)
key = f"{args.condition}_seed{args.seed}"
all_results[key] = output
with open(out_path, "w") as f:
json.dump(all_results, f, indent=2)
print(f"\nResults saved: {out_path}")
if __name__ == "__main__":
main()
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