implement-diffusion-network
О программе
Этот навык реализует полную генеративную диффузионную модель (DDPM/score-based), включая планировщик шума, архитектуру U-Net и циклы обучения/сэмплирования. Используйте его, когда вам необходимо создать пользовательскую диффузионную модель для синтеза изображений или аудио, реализовать научную статью или создать прототип перед масштабированием с использованием промышленных фреймворков. Он предоставляет ключевые компоненты, такие как DDIM-ускорение, и поддерживает пользовательские условия или расписания шума.
Быстрая установка
Claude Code
Рекомендуетсяnpx skills add pjt222/agent-almanac -a claude-code/plugin add https://github.com/pjt222/agent-almanacgit clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/implement-diffusion-networkСкопируйте и вставьте эту команду в Claude Code для установки этого навыка
Документация
Diffusionsnetzwerk implementieren
Erstellen a denoising diffusion probabilistic model (DDPM) or score-based generative model from scratch, einschliesslich the forward noising process, U-Net denoiser, training objective, reverse sampling procedure, and accelerated inference via DDIM or DPM-Solver.
Wann verwenden
- Building a generative model for image, audio, or molecular synthesis
- Implementing DDPM or score-based diffusion from a research paper
- Adding a custom noise schedule or conditioning mechanism to a diffusion pipeline
- Replacing a GAN-based generator with a diffusion-based alternative
- Prototyping a diffusion model vor scaling to production with frameworks like diffusers
Eingaben
- Erforderlich: Training dataset (images, spectrograms, point clouds, or other continuous data)
- Erforderlich: Target resolution and number of channels
- Erforderlich: Berechnen budget (GPU type and count, training time limit)
- Optional: Noise schedule type (default: cosine)
- Optional: Number of diffusion timesteps T (default: 1000)
- Optional: Conditioning signal (class labels, text embeddings, or other guidance)
- Optional: Sampling acceleration method (default: DDIM with 50 steps)
Vorgehensweise
Schritt 1: Definieren the Forward Verarbeiten (Noise Schedule)
Konfigurieren the variance schedule that controls how data is progressively noised.
- Definieren the beta schedule (linear, cosine, or learned):
import torch
import numpy as np
def cosine_beta_schedule(timesteps, s=0.008):
"""Cosine schedule from Nichol & Dhariwal (2021)."""
steps = timesteps + 1
t = torch.linspace(0, timesteps, steps) / timesteps
alphas_cumprod = torch.cos((t + s) / (1 + s) * np.pi / 2) ** 2
alphas_cumprod = alphas_cumprod / alphas_cumprod[0]
betas = 1 - (alphas_cumprod[1:] / alphas_cumprod[:-1])
return torch.clip(betas, 0.0001, 0.9999)
def linear_beta_schedule(timesteps, beta_start=1e-4, beta_end=0.02):
"""Original DDPM linear schedule."""
return torch.linspace(beta_start, beta_end, timesteps)
- Pre-compute the derived quantities used waehrend training and sampling:
class DiffusionSchedule:
def __init__(self, betas):
self.betas = betas
self.alphas = 1.0 - betas
self.alphas_cumprod = torch.cumprod(self.alphas, dim=0)
self.alphas_cumprod_prev = torch.cat([torch.tensor([1.0]), self.alphas_cumprod[:-1]])
self.sqrt_alphas_cumprod = torch.sqrt(self.alphas_cumprod)
self.sqrt_one_minus_alphas_cumprod = torch.sqrt(1.0 - self.alphas_cumprod)
self.posterior_variance = (
betas * (1.0 - self.alphas_cumprod_prev) / (1.0 - self.alphas_cumprod)
)
- Implementieren the forward noising function (q-sample):
def q_sample(self, x_0, t, noise=None):
"""Add noise to x_0 at timestep t: q(x_t | x_0)."""
if noise is None:
noise = torch.randn_like(x_0)
sqrt_alpha = self.sqrt_alphas_cumprod[t].reshape(-1, 1, 1, 1)
sqrt_one_minus_alpha = self.sqrt_one_minus_alphas_cumprod[t].reshape(-1, 1, 1, 1)
return sqrt_alpha * x_0 + sqrt_one_minus_alpha * noise
- Verifizieren the schedule visually:
schedule = DiffusionSchedule(cosine_beta_schedule(1000))
print(f"alpha_cumprod at t=0: {schedule.alphas_cumprod[0]:.4f}") # ~1.0 (clean)
print(f"alpha_cumprod at t=500: {schedule.alphas_cumprod[500]:.4f}") # ~0.5 (half noise)
print(f"alpha_cumprod at t=999: {schedule.alphas_cumprod[999]:.4f}") # ~0.0 (pure noise)
Erwartet: alphas_cumprod decreases monotonically from near 1.0 to near 0.0. The cosine schedule should decrease more gradually than linear in the middle timesteps.
Bei Fehler: If alphas_cumprod nicht reach near zero at t=T, das Modell will not learn to generate from pure noise. Increase T or adjust the schedule. If values go negative, check the clipping bounds on betas.
Schritt 2: Entwerfen the Denoising Network Architecture
Erstellen a U-Net with time conditioning that predicts noise given a noisy input.
- Definieren the time embedding module:
import torch.nn as nn
import math
class SinusoidalTimeEmbedding(nn.Module):
def __init__(self, dim):
super().__init__()
self.dim = dim
def forward(self, t):
half_dim = self.dim // 2
emb = math.log(10000) / (half_dim - 1)
emb = torch.exp(torch.arange(half_dim, device=t.device) * -emb)
emb = t[:, None].float() * emb[None, :]
return torch.cat([emb.sin(), emb.cos()], dim=-1)
- Definieren a residual block with time conditioning:
class ResBlock(nn.Module):
def __init__(self, in_ch, out_ch, time_dim):
super().__init__()
self.conv1 = nn.Conv2d(in_ch, out_ch, 3, padding=1)
self.conv2 = nn.Conv2d(out_ch, out_ch, 3, padding=1)
self.time_mlp = nn.Linear(time_dim, out_ch)
self.norm1 = nn.GroupNorm(8, out_ch)
self.norm2 = nn.GroupNorm(8, out_ch)
self.skip = nn.Conv2d(in_ch, out_ch, 1) if in_ch != out_ch else nn.Identity()
def forward(self, x, t_emb):
h = self.norm1(torch.nn.functional.silu(self.conv1(x)))
h = h + self.time_mlp(torch.nn.functional.silu(t_emb))[:, :, None, None]
h = self.norm2(torch.nn.functional.silu(self.conv2(h)))
return h + self.skip(x)
- Assemble the U-Net with encoder, bottleneck, and decoder:
class UNet(nn.Module):
def __init__(self, in_channels=3, base_channels=64, channel_mults=(1, 2, 4, 8)):
super().__init__()
time_dim = base_channels * 4
self.time_embed = nn.Sequential(
SinusoidalTimeEmbedding(base_channels),
nn.Linear(base_channels, time_dim),
nn.SiLU(),
nn.Linear(time_dim, time_dim)
)
# Encoder, bottleneck, and decoder built from ResBlocks
# with skip connections between encoder and decoder stages
# (full implementation depends on resolution and channel config)
- Verifizieren the architecture accepts inputs of das Ziel resolution:
model = UNet(in_channels=3, base_channels=64)
x_test = torch.randn(2, 3, 64, 64)
t_test = torch.randint(0, 1000, (2,))
out = model(x_test, t_test)
assert out.shape == x_test.shape, f"Output shape {out.shape} != input shape {x_test.shape}"
print(f"Model parameters: {sum(p.numel() for p in model.parameters()):,}")
Erwartet: The model outputs a tensor with the same shape as die Eingabe (predicting noise of matching dimensions). Parameter count sollte proportional to resolution: ungefaehr 30-60M for 64x64, 100-300M for 256x256.
Bei Fehler: Shape mismatches normalerweise indicate incorrect downsampling/upsampling ratios. Sicherstellen, dass each encoder stage halves spatial dimensions and each decoder stage doubles them. GroupNorm requires channels to be divisible by the group count.
Schritt 3: Implementieren the Training Loop
Trainieren the denoiser to predict the noise added at each timestep.
- Einrichten the training objective (simplified DDPM loss):
def training_loss(model, schedule, x_0):
batch_size = x_0.shape[0]
t = torch.randint(0, len(schedule.betas), (batch_size,), device=x_0.device)
noise = torch.randn_like(x_0)
x_t = schedule.q_sample(x_0, t, noise)
predicted_noise = model(x_t, t)
loss = torch.nn.functional.mse_loss(predicted_noise, noise)
return loss
- Konfigurieren the optimizer and learning rate schedule:
optimizer = torch.optim.AdamW(model.parameters(), lr=1e-4, weight_decay=0.01)
scheduler = torch.optim.lr_scheduler.CosineAnnealingLR(optimizer, T_max=100000)
- Ausfuehren the training loop with logging:
from torch.utils.data import DataLoader
dataloader = DataLoader(dataset, batch_size=64, shuffle=True, num_workers=4, pin_memory=True)
for epoch in range(num_epochs):
model.train()
epoch_loss = 0.0
for batch_idx, x_0 in enumerate(dataloader):
x_0 = x_0.to(device)
loss = training_loss(model, schedule, x_0)
optimizer.zero_grad()
loss.backward()
torch.nn.utils.clip_grad_norm_(model.parameters(), 1.0)
optimizer.step()
scheduler.step()
epoch_loss += loss.item()
avg_loss = epoch_loss / len(dataloader)
print(f"Epoch {epoch}: loss={avg_loss:.4f}, lr={scheduler.get_last_lr()[0]:.6f}")
- Speichern checkpoints periodically:
if (epoch + 1) % 10 == 0:
torch.save({
"epoch": epoch,
"model_state": model.state_dict(),
"optimizer_state": optimizer.state_dict(),
"loss": avg_loss
}, f"checkpoint_epoch_{epoch+1}.pt")
Erwartet: Loss decreases steadily over training. For image data normalized to [-1, 1], initial loss sollte near 1.0 (predicting random noise). After convergence, loss sollte in the range 0.01-0.10 abhaengig von data complexity.
Bei Fehler: If loss plateaus early (> 0.5), check: (a) data normalization (muss [-1, 1] or [0, 1] with matching final activation), (b) learning rate (try 3e-4 or 5e-5), (c) gradient clipping (1.0 is standard). If loss is NaN, reduce learning rate and check for division by zero in the schedule.
Schritt 4: Implementieren Sampling (Reverse Process)
Generieren new samples by iteratively denoising from pure Gaussian noise.
- Implementieren the standard DDPM sampling loop:
@torch.no_grad()
def ddpm_sample(model, schedule, shape, device):
"""Sample via the full DDPM reverse process (T steps)."""
x = torch.randn(shape, device=device)
T = len(schedule.betas)
for t in reversed(range(T)):
t_batch = torch.full((shape[0],), t, device=device, dtype=torch.long)
predicted_noise = model(x, t_batch)
alpha = schedule.alphas[t]
alpha_cumprod = schedule.alphas_cumprod[t]
beta = schedule.betas[t]
mean = (1 / torch.sqrt(alpha)) * (
x - (beta / torch.sqrt(1 - alpha_cumprod)) * predicted_noise
)
if t > 0:
noise = torch.randn_like(x)
sigma = torch.sqrt(schedule.posterior_variance[t])
x = mean + sigma * noise
else:
x = mean
return x
- Generieren and visualize samples:
samples = ddpm_sample(model, schedule, shape=(16, 3, 64, 64), device=device)
samples = (samples.clamp(-1, 1) + 1) / 2 # rescale to [0, 1]
Erwartet: Generated samples show recognizable structure (not pure noise or uniform color). At 64x64 resolution with 100K+ training steps, outputs should visually resemble the training distribution.
Bei Fehler: If samples are blurry, train longer or increase model capacity. If samples are noisy, the reverse process may have a bug -- verify that the schedule indexing matches training. If all samples look identical, check for mode collapse (try different random seeds).
Schritt 5: Hinzufuegen Sampling Acceleration
Reduzieren the number of sampling steps using DDIM or DPM-Solver.
- Implementieren DDIM sampling (deterministic, fewer steps):
@torch.no_grad()
def ddim_sample(model, schedule, shape, device, num_steps=50, eta=0.0):
"""DDIM sampling with configurable step count and stochasticity."""
T = len(schedule.betas)
step_indices = torch.linspace(0, T - 1, num_steps, dtype=torch.long)
x = torch.randn(shape, device=device)
for i in reversed(range(len(step_indices))):
t = step_indices[i]
t_batch = torch.full((shape[0],), t, device=device, dtype=torch.long)
predicted_noise = model(x, t_batch)
alpha_t = schedule.alphas_cumprod[t]
alpha_prev = schedule.alphas_cumprod[step_indices[i - 1]] if i > 0 else torch.tensor(1.0)
predicted_x0 = (x - torch.sqrt(1 - alpha_t) * predicted_noise) / torch.sqrt(alpha_t)
predicted_x0 = predicted_x0.clamp(-1, 1)
sigma = eta * torch.sqrt((1 - alpha_prev) / (1 - alpha_t) * (1 - alpha_t / alpha_prev))
direction = torch.sqrt(1 - alpha_prev - sigma**2) * predicted_noise
x = torch.sqrt(alpha_prev) * predicted_x0 + direction
if i > 0 and eta > 0:
x = x + sigma * torch.randn_like(x)
return x
- Vergleichen sample quality across step counts:
for n_steps in [10, 25, 50, 100, 250]:
samples = ddim_sample(model, schedule, shape=(16, 3, 64, 64), device=device, num_steps=n_steps)
print(f"DDIM {n_steps} steps: generated {samples.shape[0]} samples")
# Save grid for visual comparison
- Benchmark sampling speed:
import time
for method, n_steps in [("DDPM", 1000), ("DDIM-50", 50), ("DDIM-25", 25)]:
start = time.time()
_ = ddim_sample(model, schedule, (1, 3, 64, 64), device, num_steps=n_steps if "DDIM" in method else 1000)
elapsed = time.time() - start
print(f"{method}: {elapsed:.2f}s per sample")
Erwartet: DDIM with 50 steps produces samples visually comparable to DDPM with 1000 steps at 20x speed improvement. Quality degrades gracefully down to ungefaehr 20-25 steps.
Bei Fehler: If DDIM samples are worse than DDPM at the same step count, verify the alpha indexing. DDIM uses alphas_cumprod directly, not alphas. If samples at low step counts are very noisy, try eta=0.0 (fully deterministic) first.
Schritt 6: Bewerten Sample Quality
Quantify generation quality using standard metrics.
- Berechnen FID (Frechet Inception Distance):
from torchmetrics.image.fid import FrechetInceptionDistance
fid_metric = FrechetInceptionDistance(feature=2048, normalize=True)
# Add real images
for batch in real_dataloader:
fid_metric.update(batch.to(device), real=True)
# Add generated images
n_generated = 0
while n_generated < 10000:
samples = ddim_sample(model, schedule, (64, 3, 64, 64), device, num_steps=50)
samples = ((samples.clamp(-1, 1) + 1) / 2 * 255).byte()
fid_metric.update(samples, real=False)
n_generated += samples.shape[0]
fid_score = fid_metric.compute()
print(f"FID: {fid_score:.2f}")
- Bewerten sample diversity (check for mode collapse):
# Compute pairwise LPIPS distances among generated samples
from torchmetrics.image.lpip import LearnedPerceptualImagePatchSimilarity
lpips = LearnedPerceptualImagePatchSimilarity(net_type="alex")
n_pairs = 50
diversity_scores = []
for i in range(n_pairs):
s1 = ddim_sample(model, schedule, (1, 3, 64, 64), device, num_steps=50)
s2 = ddim_sample(model, schedule, (1, 3, 64, 64), device, num_steps=50)
score = lpips(s1.clamp(-1, 1), s2.clamp(-1, 1))
diversity_scores.append(score.item())
print(f"Mean pairwise LPIPS: {np.mean(diversity_scores):.4f} (higher = more diverse)")
- Log results:
results = {
"fid": fid_score.item(),
"mean_lpips_diversity": float(np.mean(diversity_scores)),
"sampling_method": "DDIM-50",
"training_epochs": num_epochs,
"model_params": sum(p.numel() for p in model.parameters())
}
print("Evaluation results:", results)
Erwartet: FID unter 50 for a well-trained model on standard benchmarks (CIFAR-10, CelebA). LPIPS diversity ueber 0.4 indicates no mode collapse. State-of-the-art models achieve FID 2-10 on CIFAR-10.
Bei Fehler: High FID (>100) indicates training issues or insufficient epochs. Low diversity (LPIPS < 0.2) suggests mode collapse -- increase model capacity, check data augmentation, or train longer. Berechnen FID on mindestens 10K samples for stable estimates.
Validierung
- Forward process produces pure noise at t=T (visual check and numeric: mean near 0, std near 1)
- U-Net output shape matches input shape for all target resolutions
- Training loss decreases monotonically over the first 1000 steps
- DDPM sampling produces recognizable outputs nach sufficient training
- DDIM with 50 steps produces quality comparable to DDPM with 1000 steps
- FID score is unter 50 on das Ziel dataset (adjust threshold for domain)
- Sample diversity (LPIPS) confirms no mode collapse
- Checkpoints are saved and loadable ohne errors
Haeufige Stolperfallen
- Wrong data normalization: DDPM assumes data in [-1, 1]. If your images are in [0, 255], the loss wird enormous and training will diverge. Normalize vor training and denormalize nach sampling.
- Planen indexing off by one: The forward process uses
alphas_cumprod[t]for the noised sample at step t. Off-by-one errors in sampling (using t+1 or t-1) produce visibly degraded samples. - Forgetting gradient clipping: Without
clip_grad_norm_(1.0), training is unstable for large models. This is besonders critical in the early epochs. - Too few sampling steps for DDIM: Below 20 steps, DDIM quality degrades rapidly. Use mindestens 25 steps for acceptable results; 50 steps for near-DDPM quality.
- Evaluating FID on too few samples: FID estimates are biased with small sample sizes. Use mindestens 10,000 generated images and 10,000 real images for stable FID computation.
- Ignoring EMA: Exponential moving average of model weights erheblich improves sample quality. Use a decay rate of 0.9999 and sample from the EMA model, not the training model.
Verwandte Skills
analyze-diffusion-dynamics- mathematical foundations of the diffusion SDE that DDPM discretizesfit-drift-diffusion-model- a different application of diffusion processes to cognitive modelingsetup-gpu-training- configuring GPU environments for diffusion model trainingcontainerize-application- packaging diffusion inference pipelines in Docker
GitHub репозиторий
Frequently asked questions
What is the implement-diffusion-network skill?
implement-diffusion-network is a Claude Skill by pjt222. Skills package instructions and resources that Claude loads on demand, so Claude can perform implement-diffusion-network-related tasks without extra prompting.
How do I install implement-diffusion-network?
Use the install commands on this page: add implement-diffusion-network to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does implement-diffusion-network belong to?
implement-diffusion-network is in the Meta category, tagged ai and design.
Is implement-diffusion-network free to use?
Yes. implement-diffusion-network is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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