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21.395 ... claude-son

Author SHA1 Message Date
Tim Kainz
0bbd3deccb added result, 21.3905 2026-01-24 21:02:44 +01:00
Tim Kainz
8f0fb11926 clear plot path every start 2026-01-24 17:29:58 +01:00
10 changed files with 144 additions and 232 deletions
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image-inpainting/results/testset/tikaiz-21.3950.npz → image-inpainting/results/testset/tikaiz-21.3905.npz
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66
image-inpainting/src/architecture.py
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@@ -68,46 +68,6 @@ class CBAM(nn.Module):
return x return x
class MultiScaleFeatureExtraction(nn.Module):
"""Multi-scale feature extraction using dilated convolutions"""
def __init__(self, channels):
super().__init__()
self.branch1 = nn.Sequential(
nn.Conv2d(channels, channels // 4, 1),
nn.BatchNorm2d(channels // 4),
nn.LeakyReLU(0.1, inplace=True)
)
self.branch2 = nn.Sequential(
nn.Conv2d(channels, channels // 4, 3, padding=2, dilation=2),
nn.BatchNorm2d(channels // 4),
nn.LeakyReLU(0.1, inplace=True)
)
self.branch3 = nn.Sequential(
nn.Conv2d(channels, channels // 4, 3, padding=4, dilation=4),
nn.BatchNorm2d(channels // 4),
nn.LeakyReLU(0.1, inplace=True)
)
self.branch4 = nn.Sequential(
nn.Conv2d(channels, channels // 4, 3, padding=8, dilation=8),
nn.BatchNorm2d(channels // 4),
nn.LeakyReLU(0.1, inplace=True)
)
self.fusion = nn.Sequential(
nn.Conv2d(channels, channels, 1),
nn.BatchNorm2d(channels),
nn.LeakyReLU(0.1, inplace=True)
)
def forward(self, x):
b1 = self.branch1(x)
b2 = self.branch2(x)
b3 = self.branch3(x)
b4 = self.branch4(x)
out = torch.cat([b1, b2, b3, b4], dim=1)
out = self.fusion(out)
return out + x # Residual connection
class ConvBlock(nn.Module): class ConvBlock(nn.Module):
"""Convolutional block with Conv2d -> BatchNorm -> LeakyReLU""" """Convolutional block with Conv2d -> BatchNorm -> LeakyReLU"""
def __init__(self, in_channels, out_channels, kernel_size=3, padding=1, dropout=0.0): def __init__(self, in_channels, out_channels, kernel_size=3, padding=1, dropout=0.0):
@@ -140,6 +100,26 @@ class ResidualConvBlock(nn.Module):
return self.relu(out) return self.relu(out)
class DilatedResidualBlock(nn.Module):
"""Residual block with dilated convolutions for larger receptive field"""
def __init__(self, channels, dilation=2, dropout=0.0):
super().__init__()
self.conv1 = nn.Conv2d(channels, channels, 3, padding=dilation, dilation=dilation)
self.bn1 = nn.BatchNorm2d(channels)
self.conv2 = nn.Conv2d(channels, channels, 3, padding=dilation, dilation=dilation)
self.bn2 = nn.BatchNorm2d(channels)
self.relu = nn.LeakyReLU(0.1, inplace=True)
self.dropout = nn.Dropout2d(dropout) if dropout > 0 else nn.Identity()
def forward(self, x):
residual = x
out = self.relu(self.bn1(self.conv1(x)))
out = self.dropout(out)
out = self.bn2(self.conv2(out))
out = out + residual
return self.relu(out)
class DownBlock(nn.Module): class DownBlock(nn.Module):
"""Downsampling block with conv blocks, residual connection, attention, and max pooling""" """Downsampling block with conv blocks, residual connection, attention, and max pooling"""
def __init__(self, in_channels, out_channels, dropout=0.1): def __init__(self, in_channels, out_channels, dropout=0.1):
@@ -198,12 +178,12 @@ class MyModel(nn.Module):
self.down3 = DownBlock(base_channels * 4, base_channels * 8, dropout=dropout) self.down3 = DownBlock(base_channels * 4, base_channels * 8, dropout=dropout)
self.down4 = DownBlock(base_channels * 8, base_channels * 16, dropout=dropout) self.down4 = DownBlock(base_channels * 8, base_channels * 16, dropout=dropout)
# Bottleneck with multiple residual blocks and multi-scale features # Bottleneck with multi-scale dilated convolutions (ASPP-style)
self.bottleneck = nn.Sequential( self.bottleneck = nn.Sequential(
ConvBlock(base_channels * 16, base_channels * 16, dropout=dropout), ConvBlock(base_channels * 16, base_channels * 16, dropout=dropout),
ResidualConvBlock(base_channels * 16, dropout=dropout), ResidualConvBlock(base_channels * 16, dropout=dropout),
MultiScaleFeatureExtraction(base_channels * 16), DilatedResidualBlock(base_channels * 16, dilation=2, dropout=dropout),
ResidualConvBlock(base_channels * 16, dropout=dropout), DilatedResidualBlock(base_channels * 16, dilation=4, dropout=dropout),
ResidualConvBlock(base_channels * 16, dropout=dropout), ResidualConvBlock(base_channels * 16, dropout=dropout),
CBAM(base_channels * 16) CBAM(base_channels * 16)
) )

109
image-inpainting/src/datasets.py
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@@ -10,50 +10,11 @@ import numpy as np
import random import random
import glob import glob
import os import os
from PIL import Image, ImageEnhance, ImageFilter from PIL import Image, ImageEnhance
IMAGE_DIMENSION = 100 IMAGE_DIMENSION = 100
class DataAugmentation:
"""Data augmentation pipeline for improved generalization"""
def __init__(self, p=0.5):
self.p = p
def __call__(self, image: Image.Image) -> Image.Image:
# Random horizontal flip
if random.random() < self.p:
image = image.transpose(Image.FLIP_LEFT_RIGHT)
# Random vertical flip
if random.random() < self.p * 0.5:
image = image.transpose(Image.FLIP_TOP_BOTTOM)
# Random rotation (90 degree increments)
if random.random() < self.p * 0.3:
angle = random.choice([90, 180, 270])
image = image.rotate(angle)
# Color jittering
if random.random() < self.p * 0.4:
# Brightness
enhancer = ImageEnhance.Brightness(image)
image = enhancer.enhance(random.uniform(0.85, 1.15))
if random.random() < self.p * 0.4:
# Contrast
enhancer = ImageEnhance.Contrast(image)
image = enhancer.enhance(random.uniform(0.85, 1.15))
if random.random() < self.p * 0.3:
# Saturation
enhancer = ImageEnhance.Color(image)
image = enhancer.enhance(random.uniform(0.85, 1.15))
return image
def create_arrays_from_image(image_array: np.ndarray, offset: tuple, spacing: tuple) -> tuple[np.ndarray, np.ndarray]: def create_arrays_from_image(image_array: np.ndarray, offset: tuple, spacing: tuple) -> tuple[np.ndarray, np.ndarray]:
image_array = np.transpose(image_array, (2, 0, 1)) image_array = np.transpose(image_array, (2, 0, 1))
known_array = np.zeros_like(image_array) known_array = np.zeros_like(image_array)
@@ -77,42 +38,74 @@ def preprocess(input_array: np.ndarray):
class ImageDataset(torch.utils.data.Dataset): class ImageDataset(torch.utils.data.Dataset):
""" """
Dataset class for loading images from a folder with augmentation Dataset class for loading images from a folder with data augmentation
""" """
def __init__(self, datafolder: str, augment: bool = True): def __init__(self, datafolder: str, augment: bool = True):
self.imagefiles = sorted(glob.glob(os.path.join(datafolder, "**", "*.jpg"), recursive=True)) self.imagefiles = sorted(glob.glob(os.path.join(datafolder,"**","*.jpg"),recursive=True))
self.augment = augment self.augment = augment
self.augmentation = DataAugmentation(p=0.5) if augment else None
def __len__(self): def __len__(self):
return len(self.imagefiles) return len(self.imagefiles)
def __getitem__(self, idx: int): def augment_image(self, image: Image) -> Image:
"""Apply random augmentations to image"""
# Random horizontal flip
if random.random() > 0.5:
image = image.transpose(Image.FLIP_LEFT_RIGHT)
# Random vertical flip
if random.random() > 0.5:
image = image.transpose(Image.FLIP_TOP_BOTTOM)
# Random rotation (90, 180, 270 degrees)
if random.random() > 0.5:
angle = random.choice([90, 180, 270])
image = image.rotate(angle)
# Random brightness adjustment
if random.random() > 0.5:
enhancer = ImageEnhance.Brightness(image)
factor = random.uniform(0.8, 1.2)
image = enhancer.enhance(factor)
# Random contrast adjustment
if random.random() > 0.5:
enhancer = ImageEnhance.Contrast(image)
factor = random.uniform(0.8, 1.2)
image = enhancer.enhance(factor)
# Random color adjustment
if random.random() > 0.5:
enhancer = ImageEnhance.Color(image)
factor = random.uniform(0.8, 1.2)
image = enhancer.enhance(factor)
return image
def __getitem__(self, idx:int):
index = int(idx) index = int(idx)
image = Image.open(self.imagefiles[index]).convert('RGB') image = Image.open(self.imagefiles[index])
# Apply augmentation before resize
if self.augment and self.augmentation is not None:
image = self.augmentation(image)
image = resize(image) image = resize(image)
# Apply augmentation if enabled
if self.augment:
image = self.augment_image(image)
image = np.asarray(image) image = np.asarray(image)
image = preprocess(image) image = preprocess(image)
# More varied spacing for better generalization # Vary spacing and offset more for additional diversity
spacing_x = random.randint(2, 8) spacing_x = random.randint(2,7)
spacing_y = random.randint(2, 8) spacing_y = random.randint(2,7)
offset_x = random.randint(0, min(spacing_x - 1, 8)) offset_x = random.randint(0,10)
offset_y = random.randint(0, min(spacing_y - 1, 8)) offset_y = random.randint(0,10)
spacing = (spacing_x, spacing_y) spacing = (spacing_x, spacing_y)
offset = (offset_x, offset_y) offset = (offset_x, offset_y)
input_array, known_array = create_arrays_from_image(image.copy(), offset, spacing) input_array, known_array = create_arrays_from_image(image.copy(), offset, spacing)
target_image = torch.from_numpy(np.transpose(image, (2, 0, 1))) target_image = torch.from_numpy(np.transpose(image, (2,0,1)))
input_array = torch.from_numpy(input_array) input_array = torch.from_numpy(input_array)
known_array = torch.from_numpy(known_array) known_array = torch.from_numpy(known_array)
input_array = torch.cat((input_array, known_array), dim=0) input_array = torch.cat((input_array, known_array), dim=0)
return input_array, target_image return input_array, target_image

14
image-inpainting/src/main.py
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@@ -24,22 +24,22 @@ if __name__ == '__main__':
config_dict['results_path'] = os.path.join(project_root, "results") config_dict['results_path'] = os.path.join(project_root, "results")
config_dict['data_path'] = os.path.join(project_root, "data", "dataset") config_dict['data_path'] = os.path.join(project_root, "data", "dataset")
config_dict['device'] = None config_dict['device'] = None
config_dict['learningrate'] = 2e-4 # Slightly lower for stable training config_dict['learningrate'] = 2e-4 # Slightly lower for more stable training
config_dict['weight_decay'] = 5e-5 # Reduced weight decay config_dict['weight_decay'] = 5e-5 # Reduced for less aggressive regularization
config_dict['n_updates'] = 8000 # More updates for better convergence config_dict['n_updates'] = 8000 # More updates for better convergence
config_dict['batchsize'] = 8 # Smaller batch for better gradient estimates config_dict['batchsize'] = 12 # Larger batch for more stable gradients
config_dict['early_stopping_patience'] = 15 # More patience for complex model config_dict['early_stopping_patience'] = 15 # More patience for complex model
config_dict['use_wandb'] = False config_dict['use_wandb'] = False
config_dict['print_train_stats_at'] = 10 config_dict['print_train_stats_at'] = 10
config_dict['print_stats_at'] = 100 config_dict['print_stats_at'] = 100
config_dict['plot_at'] = 300 config_dict['plot_at'] = 400
config_dict['validate_at'] = 300 # Validate more frequently config_dict['validate_at'] = 200 # Validate frequently but not too often
network_config = { network_config = {
'n_in_channels': 4, 'n_in_channels': 4,
'base_channels': 56, # Increased capacity for better feature learning 'base_channels': 32, # Smaller base for efficiency, depth compensates
'dropout': 0.08 # Slightly less dropout with augmentation 'dropout': 0.15 # Slightly more regularization with augmentation
} }
config_dict['network_config'] = network_config config_dict['network_config'] = network_config

137
image-inpainting/src/train.py
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@@ -10,7 +10,6 @@ from utils import plot, evaluate_model
import torch import torch
import torch.nn as nn import torch.nn as nn
import torch.nn.functional as F
import numpy as np import numpy as np
import os import os
@@ -21,58 +20,15 @@ from torch.optim.lr_scheduler import CosineAnnealingWarmRestarts
import wandb import wandb
def gaussian_kernel(window_size=11, sigma=1.5):
"""Create a Gaussian kernel for SSIM computation"""
x = torch.arange(window_size).float() - window_size // 2
gauss = torch.exp(-x.pow(2) / (2 * sigma ** 2))
kernel = gauss / gauss.sum()
kernel_2d = kernel.unsqueeze(1) * kernel.unsqueeze(0)
return kernel_2d.unsqueeze(0).unsqueeze(0)
class SSIMLoss(nn.Module):
"""Structural Similarity Index Loss for perceptual quality"""
def __init__(self, window_size=11, sigma=1.5):
super().__init__()
self.window_size = window_size
kernel = gaussian_kernel(window_size, sigma)
self.register_buffer('kernel', kernel)
self.C1 = 0.01 ** 2
self.C2 = 0.03 ** 2
def forward(self, pred, target):
# Apply to each channel
channels = pred.shape[1]
kernel = self.kernel.repeat(channels, 1, 1, 1)
mu_pred = F.conv2d(pred, kernel, padding=self.window_size // 2, groups=channels)
mu_target = F.conv2d(target, kernel, padding=self.window_size // 2, groups=channels)
mu_pred_sq = mu_pred.pow(2)
mu_target_sq = mu_target.pow(2)
mu_pred_target = mu_pred * mu_target
sigma_pred_sq = F.conv2d(pred * pred, kernel, padding=self.window_size // 2, groups=channels) - mu_pred_sq
sigma_target_sq = F.conv2d(target * target, kernel, padding=self.window_size // 2, groups=channels) - mu_target_sq
sigma_pred_target = F.conv2d(pred * target, kernel, padding=self.window_size // 2, groups=channels) - mu_pred_target
ssim = ((2 * mu_pred_target + self.C1) * (2 * sigma_pred_target + self.C2)) / \
((mu_pred_sq + mu_target_sq + self.C1) * (sigma_pred_sq + sigma_target_sq + self.C2))
return 1 - ssim.mean()
class CombinedLoss(nn.Module): class CombinedLoss(nn.Module):
"""Combined loss: MSE + L1 + SSIM + Edge for comprehensive image reconstruction""" """Combined loss: MSE + L1 + Edge-aware component for better reconstruction"""
def __init__(self, mse_weight=1.0, l1_weight=0.5, edge_weight=0.15, ssim_weight=0.3): def __init__(self, mse_weight=0.7, l1_weight=0.8, edge_weight=0.2):
super().__init__() super().__init__()
self.mse_weight = mse_weight self.mse_weight = mse_weight
self.l1_weight = l1_weight self.l1_weight = l1_weight
self.edge_weight = edge_weight self.edge_weight = edge_weight
self.ssim_weight = ssim_weight
self.mse = nn.MSELoss() self.mse = nn.MSELoss()
self.l1 = nn.L1Loss() self.l1 = nn.L1Loss()
self.ssim = SSIMLoss(window_size=7)
# Sobel filters for edge detection # Sobel filters for edge detection
sobel_x = torch.tensor([[-1, 0, 1], [-2, 0, 2], [-1, 0, 1]], dtype=torch.float32).view(1, 1, 3, 3) sobel_x = torch.tensor([[-1, 0, 1], [-2, 0, 2], [-1, 0, 1]], dtype=torch.float32).view(1, 1, 3, 3)
@@ -82,10 +38,10 @@ class CombinedLoss(nn.Module):
def edge_loss(self, pred, target): def edge_loss(self, pred, target):
"""Compute edge-aware loss using Sobel filters""" """Compute edge-aware loss using Sobel filters"""
pred_edge_x = F.conv2d(pred, self.sobel_x, padding=1, groups=3) pred_edge_x = torch.nn.functional.conv2d(pred, self.sobel_x, padding=1, groups=3)
pred_edge_y = F.conv2d(pred, self.sobel_y, padding=1, groups=3) pred_edge_y = torch.nn.functional.conv2d(pred, self.sobel_y, padding=1, groups=3)
target_edge_x = F.conv2d(target, self.sobel_x, padding=1, groups=3) target_edge_x = torch.nn.functional.conv2d(target, self.sobel_x, padding=1, groups=3)
target_edge_y = F.conv2d(target, self.sobel_y, padding=1, groups=3) target_edge_y = torch.nn.functional.conv2d(target, self.sobel_y, padding=1, groups=3)
edge_loss = self.l1(pred_edge_x, target_edge_x) + self.l1(pred_edge_y, target_edge_y) edge_loss = self.l1(pred_edge_x, target_edge_x) + self.l1(pred_edge_y, target_edge_y)
return edge_loss return edge_loss
@@ -94,12 +50,8 @@ class CombinedLoss(nn.Module):
mse_loss = self.mse(pred, target) mse_loss = self.mse(pred, target)
l1_loss = self.l1(pred, target) l1_loss = self.l1(pred, target)
edge_loss = self.edge_loss(pred, target) edge_loss = self.edge_loss(pred, target)
ssim_loss = self.ssim(pred, target)
total_loss = (self.mse_weight * mse_loss + total_loss = self.mse_weight * mse_loss + self.l1_weight * l1_loss + self.edge_weight * edge_loss
self.l1_weight * l1_loss +
self.edge_weight * edge_loss +
self.ssim_weight * ssim_loss)
return total_loss return total_loss
@@ -132,20 +84,24 @@ def train(seed, testset_ratio, validset_ratio, data_path, results_path, early_st
plotpath = os.path.join(results_path, "plots") plotpath = os.path.join(results_path, "plots")
os.makedirs(plotpath, exist_ok=True) os.makedirs(plotpath, exist_ok=True)
image_dataset = datasets.ImageDataset(datafolder=data_path) # Create dataset with augmentation for training, without for validation/test
image_dataset_full = datasets.ImageDataset(datafolder=data_path, augment=False)
n_total = len(image_dataset) n_total = len(image_dataset_full)
n_test = int(n_total * testset_ratio) n_test = int(n_total * testset_ratio)
n_valid = int(n_total * validset_ratio) n_valid = int(n_total * validset_ratio)
n_train = n_total - n_test - n_valid n_train = n_total - n_test - n_valid
indices = np.random.permutation(n_total) indices = np.random.permutation(n_total)
dataset_train = Subset(image_dataset, indices=indices[0:n_train])
dataset_valid = Subset(image_dataset, indices=indices[n_train:n_train + n_valid]) # Create augmented dataset for training
dataset_test = Subset(image_dataset, indices=indices[n_train + n_valid:n_total]) image_dataset_train = datasets.ImageDataset(datafolder=data_path, augment=True)
dataset_train = Subset(image_dataset_train, indices=indices[0:n_train])
dataset_valid = Subset(image_dataset_full, indices=indices[n_train:n_train + n_valid])
dataset_test = Subset(image_dataset_full, indices=indices[n_train + n_valid:n_total])
assert len(image_dataset) == len(dataset_train) + len(dataset_test) + len(dataset_valid) assert n_total == len(dataset_train) + len(dataset_test) + len(dataset_valid)
del image_dataset del image_dataset_full, image_dataset_train
dataloader_train = DataLoader(dataset=dataset_train, batch_size=batchsize, dataloader_train = DataLoader(dataset=dataset_train, batch_size=batchsize,
num_workers=0, shuffle=True) num_workers=0, shuffle=True)
@@ -159,15 +115,19 @@ def train(seed, testset_ratio, validset_ratio, data_path, results_path, early_st
network.to(device) network.to(device)
network.train() network.train()
# defining the loss - combined loss for better reconstruction # defining the loss - combined loss with optimized weights
combined_loss = CombinedLoss(mse_weight=1.0, l1_weight=0.5, edge_weight=0.15, ssim_weight=0.3).to(device) combined_loss = CombinedLoss(mse_weight=0.7, l1_weight=0.8, edge_weight=0.2).to(device)
mse_loss = torch.nn.MSELoss() # Keep for evaluation mse_loss = torch.nn.MSELoss() # Keep for evaluation
# defining the optimizer with AdamW for better weight decay handling # defining the optimizer with AdamW for better weight decay handling
optimizer = torch.optim.AdamW(network.parameters(), lr=learningrate, weight_decay=weight_decay) optimizer = torch.optim.AdamW(network.parameters(), lr=learningrate, weight_decay=weight_decay)
# Learning rate scheduler for better convergence # Learning rate scheduler with better configuration
scheduler = CosineAnnealingWarmRestarts(optimizer, T_0=50, T_mult=2, eta_min=1e-6) scheduler = CosineAnnealingWarmRestarts(optimizer, T_0=100, T_mult=2, eta_min=1e-7)
# Mixed precision training for faster computation and lower memory usage
scaler = torch.cuda.amp.GradScaler() if device.type == 'cuda' else None
use_amp = scaler is not None
if use_wandb: if use_wandb:
wandb.watch(network, mse_loss, log="all", log_freq=10) wandb.watch(network, mse_loss, log="all", log_freq=10)
@@ -176,10 +136,13 @@ def train(seed, testset_ratio, validset_ratio, data_path, results_path, early_st
counter = 0 counter = 0
best_validation_loss = np.inf best_validation_loss = np.inf
loss_list = [] loss_list = []
accumulation_steps = 2 # Gradient accumulation for effective larger batch size
saved_model_path = os.path.join(results_path, "best_model.pt") saved_model_path = os.path.join(results_path, "best_model.pt")
print(f"Started training on device {device}") print(f"Started training on device {device}")
print(f"Using mixed precision: {use_amp}")
print(f"Gradient accumulation steps: {accumulation_steps}")
while i < n_updates: while i < n_updates:
@@ -190,21 +153,33 @@ def train(seed, testset_ratio, validset_ratio, data_path, results_path, early_st
if (i + 1) % print_train_stats_at == 0: if (i + 1) % print_train_stats_at == 0:
print(f'Update Step {i + 1} of {n_updates}: Current loss: {loss_list[-1]}') print(f'Update Step {i + 1} of {n_updates}: Current loss: {loss_list[-1]}')
optimizer.zero_grad() # Use mixed precision if available
if use_amp:
output = network(input) with torch.cuda.amp.autocast():
output = network(input)
loss = combined_loss(output, target) loss = combined_loss(output, target)
loss = loss / accumulation_steps
loss.backward() scaler.scale(loss).backward()
else:
output = network(input)
loss = combined_loss(output, target)
loss = loss / accumulation_steps
loss.backward()
# Gradient clipping for training stability # Gradient accumulation - update weights every accumulation_steps
torch.nn.utils.clip_grad_norm_(network.parameters(), max_norm=1.0) if (i + 1) % accumulation_steps == 0:
if use_amp:
scaler.unscale_(optimizer)
torch.nn.utils.clip_grad_norm_(network.parameters(), max_norm=1.0)
scaler.step(optimizer)
scaler.update()
else:
torch.nn.utils.clip_grad_norm_(network.parameters(), max_norm=1.0)
optimizer.step()
optimizer.zero_grad()
scheduler.step(i / n_updates)
optimizer.step() loss_list.append(loss.item() * accumulation_steps)
scheduler.step(i + len(loss_list) / len(dataloader_train))
loss_list.append(loss.item())
# writing the stats to wandb # writing the stats to wandb
if use_wandb and (i+1) % print_stats_at == 0: if use_wandb and (i+1) % print_stats_at == 0:
@@ -213,7 +188,9 @@ def train(seed, testset_ratio, validset_ratio, data_path, results_path, early_st
# plotting # plotting
if (i + 1) % plot_at == 0: if (i + 1) % plot_at == 0:
print(f"Plotting images, current update {i + 1}") print(f"Plotting images, current update {i + 1}")
plot(input.cpu().numpy(), target.detach().cpu().numpy(), output.detach().cpu().numpy(), plotpath, i) # Convert to float32 for matplotlib compatibility (mixed precision may produce float16)
plot(input.float().cpu().numpy(), target.detach().float().cpu().numpy(),
output.detach().float().cpu().numpy(), plotpath, i)
# evaluating model every validate_at sample # evaluating model every validate_at sample
if (i + 1) % validate_at == 0: if (i + 1) % validate_at == 0:

50
image-inpainting/src/utils.py
View File

@@ -81,42 +81,9 @@ def read_compressed_file(file_path: str):
return input_arrays, known_arrays return input_arrays, known_arrays
def apply_tta(model, input_tensor, device): def create_predictions(model_config, state_dict_path, testset_path, device, save_path, plot_path, plot_at=20, rmse_value=None):
""" """
Apply Test-Time Augmentation for better predictions. Here, one might needs to adjust the code based on the used preprocessing
Averages predictions from original and augmented versions.
"""
outputs = []
# Original
out = model(input_tensor)
outputs.append(out)
# Horizontal flip
flipped_h = torch.flip(input_tensor, dims=[3])
out_h = model(flipped_h)
out_h = torch.flip(out_h, dims=[3])
outputs.append(out_h)
# Vertical flip
flipped_v = torch.flip(input_tensor, dims=[2])
out_v = model(flipped_v)
out_v = torch.flip(out_v, dims=[2])
outputs.append(out_v)
# Both flips
flipped_hv = torch.flip(input_tensor, dims=[2, 3])
out_hv = model(flipped_hv)
out_hv = torch.flip(out_hv, dims=[2, 3])
outputs.append(out_hv)
# Average all predictions
return torch.stack(outputs, dim=0).mean(dim=0)
def create_predictions(model_config, state_dict_path, testset_path, device, save_path, plot_path, plot_at=20, rmse_value=None, use_tta=True):
"""
Create predictions with optional Test-Time Augmentation for improved results.
""" """
if device is None: if device is None:
@@ -127,7 +94,7 @@ def create_predictions(model_config, state_dict_path, testset_path, device, save
device = torch.device(device) device = torch.device(device)
model = MyModel(**model_config) model = MyModel(**model_config)
model.load_state_dict(torch.load(state_dict_path, weights_only=True)) model.load_state_dict(torch.load(state_dict_path))
model.to(device) model.to(device)
model.eval() model.eval()
@@ -144,14 +111,9 @@ def create_predictions(model_config, state_dict_path, testset_path, device, save
with torch.no_grad(): with torch.no_grad():
for i in range(len(input_arrays)): for i in range(len(input_arrays)):
print(f"Processing image {i + 1}/{len(input_arrays)}") print(f"Processing image {i + 1}/{len(input_arrays)}")
input_array = torch.from_numpy(input_arrays[i]).to(device) input_array = torch.from_numpy(input_arrays[i]).to(
input_tensor = input_array.unsqueeze(0) if input_array.dim() == 3 else input_array device)
output = model(input_array.unsqueeze(0) if hasattr(input_array, 'dim') and input_array.dim() == 3 else input_array)
if use_tta:
output = apply_tta(model, input_tensor, device)
else:
output = model(input_tensor)
output = output.cpu().numpy() output = output.cpu().numpy()
predictions.append(output) predictions.append(output)