docs: add SelVA integration implementation plan

Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
This commit is contained in:
2026-04-04 15:11:26 +02:00
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# SelVA Integration Implementation Plan
> **For Claude:** REQUIRED SUB-SKILL: Use superpowers:executing-plans to implement this plan task-by-task.
**Goal:** Add three new ComfyUI nodes (SelvaModelLoader, SelvaFeatureExtractor, SelvaSampler) that run SelVA's text-conditioned V2A pipeline inline — no subprocess, no JAX, pure PyTorch.
**Architecture:** Vendor SelVA source into `selva_core/`, implement three nodes that mirror the PrismAudio pattern. `SelvaFeatureExtractor` takes `SELVA_MODEL` (needs TextSynchformer + CLIP/T5 from FeaturesUtils). `SelvaSampler` runs flow matching ODE with CFG and negative prompts.
**Tech Stack:** PyTorch, open_clip (already in ComfyUI), transformers (already in ComfyUI), torchaudio, einops, torchvision
---
## Design reference
`docs/plans/2026-04-04-selva-integration-design.md`
**Key facts from SelVA source:**
- CLIP input: `[B, T, C, 384, 384]` float32 `[0,1]` — normalization applied inside FeaturesUtils
- Sync input: `[B, T, C, 224, 224]` float32 `[-1,1]` — normalize with `mean=std=[0.5,0.5,0.5]` before passing
- CLIP frame rate: 8fps, Sync frame rate: 25fps
- CONFIG_16K: latent=250, clip=64, sync=192 at 8s
- CONFIG_44K: latent=345, clip=64, sync=192 at 8s
- Sync segments: 16-frame windows, 8-frame stride (overlapping, unlike PrismAudio's 8-frame non-overlapping)
- `net_generator.update_seq_lengths(latent_seq_len, clip_seq_len, sync_seq_len)` must be called before each generation when duration ≠ 8s
---
## Task 1: Create branch and vendor selva_core
**Files:**
- Create: `selva_core/` (full directory tree)
**Step 1: Create new branch off master (not off feature/lora-trainer)**
```bash
git checkout master
git checkout -b feature/selva-integration
```
**Step 2: Clone SelVA and copy source**
```bash
git clone https://github.com/jnwnlee/selva.git /tmp/selva_src
cp -r /tmp/selva_src/selva /media/p5/Comfyui-Prismaudio/selva_core
```
**Step 3: Rename all internal imports**
```bash
cd /media/p5/Comfyui-Prismaudio/selva_core
find . -name "*.py" -exec sed -i \
's/from selva\./from selva_core./g;
s/import selva\./import selva_core./g' {} \;
```
**Step 4: Record the pinned commit**
```bash
cd /tmp/selva_src && git rev-parse HEAD
# Paste the hash into a comment at the top of selva_core/__init__.py
```
Edit `selva_core/__init__.py` to add at the top:
```python
# Vendored from https://github.com/jnwnlee/selva
# Pinned commit: <PASTE_HASH_HERE>
# Imports rewritten from selva.* → selva_core.*
```
**Step 5: Verify imports work**
```bash
cd /media/p5/Comfyui-Prismaudio
python -c "
from selva_core.model.networks_generator import MMAudio, get_my_mmaudio
from selva_core.model.networks_video_enc import TextSynch, get_my_textsynch
from selva_core.model.utils.features_utils import FeaturesUtils
from selva_core.model.flow_matching import FlowMatching
from selva_core.model.sequence_config import CONFIG_16K, CONFIG_44K, SequenceConfig
print('selva_core imports OK')
print(f'CONFIG_16K: latent={CONFIG_16K.latent_seq_len} clip={CONFIG_16K.clip_seq_len} sync={CONFIG_16K.sync_seq_len}')
print(f'CONFIG_44K: latent={CONFIG_44K.latent_seq_len} clip={CONFIG_44K.clip_seq_len} sync={CONFIG_44K.sync_seq_len}')
"
```
Expected:
```
selva_core imports OK
CONFIG_16K: latent=250 clip=64 sync=192
CONFIG_44K: latent=345 clip=64 sync=192
```
**Step 6: Commit**
```bash
git add selva_core/
git commit -m "chore: vendor selva_core from jnwnlee/selva@<HASH>
Pure PyTorch SelVA source for SelvaModelLoader/FeatureExtractor/Sampler nodes.
Imports rewritten from selva.* to selva_core.*. No training code included."
```
---
## Task 2: Implement SelvaModelLoader
**Files:**
- Create: `nodes/selva_model_loader.py`
- Modify: `nodes/__init__.py`
**Step 1: Create `nodes/selva_model_loader.py`**
```python
import os
import torch
import folder_paths
from .utils import PRISMAUDIO_CATEGORY, get_offload_device, determine_offload_strategy
# Variant → (generator filename, mode, has_bigvgan)
_VARIANTS = {
"small_16k": ("generator_small_16k_sup_5.pth", "16k", True),
"small_44k": ("generator_small_44k_sup_5.pth", "44k", False),
"medium_44k": ("generator_medium_44k_sup_5.pth", "44k", False),
"large_44k": ("generator_large_44k_sup_5.pth", "44k", False),
}
_SELVA_DIR = os.path.join(folder_paths.models_dir, "selva")
def _selva_path(*parts):
return os.path.join(_SELVA_DIR, *parts)
def _require(path, hint):
if not os.path.exists(path):
raise RuntimeError(
f"[SelVA] Missing: {path}\n{hint}"
)
return path
class SelvaModelLoader:
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"variant": (list(_VARIANTS.keys()),),
"precision": (["bf16", "fp16", "fp32"],),
"offload_strategy": (["auto", "keep_in_vram", "offload_to_cpu"],),
}
}
RETURN_TYPES = ("SELVA_MODEL",)
RETURN_NAMES = ("model",)
FUNCTION = "load_model"
CATEGORY = PRISMAUDIO_CATEGORY
def load_model(self, variant, precision, offload_strategy):
from selva_core.model.networks_generator import get_my_mmaudio
from selva_core.model.networks_video_enc import get_my_textsynch
from selva_core.model.utils.features_utils import FeaturesUtils
from selva_core.model.sequence_config import CONFIG_16K, CONFIG_44K
gen_filename, mode, has_bigvgan = _VARIANTS[variant]
dtype = {"bf16": torch.bfloat16, "fp16": torch.float16, "fp32": torch.float32}[precision]
strategy = determine_offload_strategy(offload_strategy)
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
# Resolve weight paths
video_enc_path = _require(
_selva_path("video_enc_sup_5.pth"),
"Download from https://huggingface.co/jnwnlee/selva and place in models/selva/"
)
gen_path = _require(
_selva_path(gen_filename),
f"Download {gen_filename} from https://huggingface.co/jnwnlee/selva and place in models/selva/"
)
vae_path = _require(
_selva_path("ext", f"v1-{mode}.pth"),
f"Download v1-{mode}.pth from MMAudio/SelVA release and place in models/selva/ext/"
)
synch_path = _require(
os.path.join(folder_paths.models_dir, "prismaudio", "synchformer_state_dict.pth"),
"Synchformer checkpoint missing from models/prismaudio/ — download from FunAudioLLM/PrismAudio"
)
bigvgan_path = None
if has_bigvgan:
bigvgan_path = _require(
_selva_path("ext", "best_netG.pt"),
"Download best_netG.pt (BigVGAN 16k vocoder) from MMAudio release and place in models/selva/ext/"
)
print(f"[SelVA] Loading TextSynch from {video_enc_path}", flush=True)
net_video_enc = get_my_textsynch("depth1").to(device, dtype).eval()
net_video_enc.load_weights(
torch.load(video_enc_path, map_location="cpu", weights_only=True)
)
print(f"[SelVA] Loading MMAudio ({variant}) from {gen_path}", flush=True)
seq_cfg = CONFIG_16K if mode == "16k" else CONFIG_44K
net_generator = get_my_mmaudio(variant).to(device, dtype).eval()
net_generator.load_weights(
torch.load(gen_path, map_location="cpu", weights_only=True)
)
print(f"[SelVA] Loading FeaturesUtils (CLIP + T5 + Synchformer + VAE)...", flush=True)
feature_utils = FeaturesUtils(
tod_vae_ckpt=vae_path,
synchformer_ckpt=synch_path,
enable_conditions=True,
mode=mode,
bigvgan_vocoder_ckpt=bigvgan_path,
).to(device, dtype).eval()
if strategy == "offload_to_cpu":
net_generator.to(get_offload_device())
net_video_enc.to(get_offload_device())
feature_utils.to(get_offload_device())
print(f"[SelVA] Model ready: variant={variant} dtype={dtype} strategy={strategy}", flush=True)
return ({
"generator": net_generator,
"video_enc": net_video_enc,
"feature_utils": feature_utils,
"variant": variant,
"mode": mode,
"strategy": strategy,
"dtype": dtype,
"seq_cfg": seq_cfg,
},)
```
**Step 2: Register in `nodes/__init__.py`**
In the `NODE_CLASS_MAPPINGS` dict, add:
```python
"SelvaModelLoader": (".selva_model_loader", "SelvaModelLoader", "SelVA Model Loader"),
```
**Step 3: Verify node registers**
```bash
cd /media/p5/Comfyui-Prismaudio
python -c "
import sys; sys.path.insert(0, '.')
from nodes.selva_model_loader import SelvaModelLoader
print('inputs:', list(SelvaModelLoader.INPUT_TYPES()['required'].keys()))
print('outputs:', SelvaModelLoader.RETURN_TYPES)
"
```
Expected: `inputs: ['variant', 'precision', 'offload_strategy']`
**Step 4: Commit**
```bash
git add nodes/selva_model_loader.py nodes/__init__.py
git commit -m "feat: SelvaModelLoader node — loads TextSynch + MMAudio + FeaturesUtils"
```
---
## Task 3: Implement SelvaFeatureExtractor
**Files:**
- Create: `nodes/selva_feature_extractor.py`
- Modify: `nodes/__init__.py`
**Step 1: Create `nodes/selva_feature_extractor.py`**
```python
import os
import hashlib
import tempfile
import torch
import torch.nn.functional as F
import numpy as np
from .utils import PRISMAUDIO_CATEGORY, get_device, get_offload_device, soft_empty_cache
# SelVA video preprocessing constants (from selva/utils/eval_utils.py)
_CLIP_SIZE = 384
_SYNC_SIZE = 224
_CLIP_FPS = 8
_SYNC_FPS = 25
# Sync normalization: [-1, 1] (from selva/utils/eval_utils.py load_video)
_SYNC_MEAN = torch.tensor([0.5, 0.5, 0.5]).view(1, 3, 1, 1)
_SYNC_STD = torch.tensor([0.5, 0.5, 0.5]).view(1, 3, 1, 1)
def _sample_frames(video, source_fps, target_fps, duration):
"""Sample frames from [T,H,W,C] float32 [0,1] at target_fps."""
T = video.shape[0]
n_out = max(1, int(duration * target_fps))
indices = [min(int(i / target_fps * source_fps), T - 1) for i in range(n_out)]
return video[indices] # [N, H, W, C]
def _resize_frames(frames, size):
"""Resize [N,H,W,C] float32 [0,1] → [N,C,H,W] at target size."""
x = frames.permute(0, 3, 1, 2) # [N, C, H, W]
x = F.interpolate(x, size=(size, size), mode="bicubic", align_corners=False)
return x.clamp(0, 1) # [N, C, H, W] float32
def _hash_inputs(video_tensor, prompt, fps, variant):
h = hashlib.sha256()
h.update(video_tensor.cpu().numpy().tobytes()[:1024 * 1024])
h.update(prompt.encode())
h.update(str(fps).encode())
h.update(variant.encode())
return h.hexdigest()[:16]
class SelvaFeatureExtractor:
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"model": ("SELVA_MODEL",),
"video": ("IMAGE",),
"prompt": ("STRING", {"default": "", "multiline": True,
"tooltip": "Text prompt used by TextSynchformer to focus sync features on the relevant sound source. Should match the prompt used in SelvaSampler."}),
},
"optional": {
"video_info": ("VHS_VIDEOINFO", {"tooltip": "Connect VHS LoadVideo info to auto-set fps."}),
"fps": ("FLOAT", {"default": 30.0, "min": 1.0, "max": 120.0, "step": 0.001}),
"duration": ("FLOAT", {"default": 0.0, "min": 0.0, "max": 30.0, "step": 0.1,
"tooltip": "Override duration in seconds. 0 = infer from video length and fps."}),
"cache_dir": ("STRING", {"default": "", "tooltip": "Directory for cached .npz features. Empty = temp dir."}),
},
}
RETURN_TYPES = ("SELVA_FEATURES", "FLOAT")
RETURN_NAMES = ("features", "fps")
FUNCTION = "extract_features"
CATEGORY = PRISMAUDIO_CATEGORY
def extract_features(self, model, video, prompt, video_info=None, fps=30.0,
duration=0.0, cache_dir=""):
if video_info is not None:
fps = video_info["loaded_fps"]
T = video.shape[0]
if duration <= 0:
duration = T / fps
duration = min(duration, T / fps) # clamp to actual video length
if not prompt.strip():
print("[SelVA] Warning: empty prompt — TextSynchformer sync features will be unfocused.", flush=True)
# Cache
if not cache_dir:
cache_dir = os.path.join(tempfile.gettempdir(), "selva_features")
os.makedirs(cache_dir, exist_ok=True)
cache_key = _hash_inputs(video, prompt, fps, model["variant"])
cached_path = os.path.join(cache_dir, f"{cache_key}.npz")
if os.path.exists(cached_path):
print(f"[SelVA] Using cached features: {cached_path}", flush=True)
return (_load_cached(cached_path), float(fps))
device = get_device()
dtype = model["dtype"]
strategy = model["strategy"]
feature_utils = model["feature_utils"]
net_video_enc = model["video_enc"]
# Move feature models to device
if strategy == "offload_to_cpu":
feature_utils.to(device)
net_video_enc.to(device)
soft_empty_cache()
print(f"[SelVA] Extracting features: duration={duration:.2f}s fps={fps:.3f} prompt='{prompt[:60]}'", flush=True)
with torch.no_grad():
# --- CLIP frames: 384×384, [0,1], 8fps ---
clip_frames = _sample_frames(video, fps, _CLIP_FPS, duration) # [N, H, W, C]
clip_frames = _resize_frames(clip_frames, _CLIP_SIZE) # [N, C, 384, 384]
clip_input = clip_frames.unsqueeze(0).to(device, dtype) # [1, N, C, 384, 384]
print(f"[SelVA] CLIP frames: {clip_frames.shape[0]} @ {_CLIP_FPS}fps", flush=True)
clip_features = feature_utils.encode_video_with_clip(clip_input) # [1, N, 1024]
# --- Sync frames: 224×224, [-1,1], 25fps ---
n_sync = max(16, int(duration * _SYNC_FPS)) # minimum 16 for segmentation
sync_frames = _sample_frames(video, fps, _SYNC_FPS, duration)
if sync_frames.shape[0] < 16:
# Pad by repeating last frame to reach minimum 16
pad = 16 - sync_frames.shape[0]
sync_frames = torch.cat([sync_frames, sync_frames[-1:].expand(pad, -1, -1, -1)], dim=0)
sync_frames = _resize_frames(sync_frames, _SYNC_SIZE) # [N, C, 224, 224]
# Normalize to [-1, 1]
mean = _SYNC_MEAN.to(sync_frames.device)
std = _SYNC_STD.to(sync_frames.device)
sync_frames = (sync_frames - mean) / std
sync_input = sync_frames.unsqueeze(0).to(device, dtype) # [1, N, C, 224, 224]
print(f"[SelVA] Sync frames: {sync_frames.shape[0]} @ {_SYNC_FPS}fps", flush=True)
# Encode T5 text + prepend supplementary tokens → text-conditioned sync features
text_f_t5, text_mask = feature_utils.encode_text_t5([prompt]) # [1, L, 768], [1, L]
text_f_t5, text_mask = net_video_enc.prepend_sup_text_tokens(text_f_t5, text_mask)
sync_features = net_video_enc.encode_video_with_sync(
sync_input, text_f=text_f_t5, text_mask=text_mask
) # [1, T_sync, 768]
print(f"[SelVA] clip_features: {tuple(clip_features.shape)}", flush=True)
print(f"[SelVA] sync_features: {tuple(sync_features.shape)}", flush=True)
# Offload back if needed
if strategy == "offload_to_cpu":
feature_utils.to(get_offload_device())
net_video_enc.to(get_offload_device())
soft_empty_cache()
# Save cache
np.savez(
cached_path,
clip_features=clip_features.cpu().float().numpy(),
sync_features=sync_features.cpu().float().numpy(),
duration=duration,
)
print(f"[SelVA] Features cached: {cached_path}", flush=True)
features = {
"clip_features": clip_features.cpu(),
"sync_features": sync_features.cpu(),
"duration": duration,
}
return (features, float(fps))
def _load_cached(path):
data = np.load(path, allow_pickle=False)
return {
"clip_features": torch.from_numpy(data["clip_features"]),
"sync_features": torch.from_numpy(data["sync_features"]),
"duration": float(data["duration"]),
}
```
**Step 2: Register in `nodes/__init__.py`**
```python
"SelvaFeatureExtractor": (".selva_feature_extractor", "SelvaFeatureExtractor", "SelVA Feature Extractor"),
```
**Step 3: Verify node registers**
```bash
python -c "
import sys; sys.path.insert(0, '.')
from nodes.selva_feature_extractor import SelvaFeatureExtractor
inputs = SelvaFeatureExtractor.INPUT_TYPES()
print('required:', list(inputs['required'].keys()))
print('optional:', list(inputs['optional'].keys()))
print('outputs:', SelvaFeatureExtractor.RETURN_TYPES)
"
```
Expected: `required: ['model', 'video', 'prompt']`
**Step 4: Commit**
```bash
git add nodes/selva_feature_extractor.py nodes/__init__.py
git commit -m "feat: SelvaFeatureExtractor — inline CLIP + TextSynchformer feature extraction"
```
---
## Task 4: Implement SelvaSampler
**Files:**
- Create: `nodes/selva_sampler.py`
- Modify: `nodes/__init__.py`
**Step 1: Create `nodes/selva_sampler.py`**
```python
import math
import torch
import comfy.utils
from .utils import (
PRISMAUDIO_CATEGORY,
get_device, get_offload_device, soft_empty_cache,
)
def _make_seq_cfg(duration, mode):
"""Compute sequence lengths for a given duration and mode."""
from selva_core.model.sequence_config import SequenceConfig
if mode == "16k":
return SequenceConfig(duration=duration, sampling_rate=16000, spectrogram_frame_rate=256)
else:
return SequenceConfig(duration=duration, sampling_rate=44100, spectrogram_frame_rate=512)
class SelvaSampler:
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"model": ("SELVA_MODEL",),
"features": ("SELVA_FEATURES",),
"prompt": ("STRING", {"default": "", "multiline": True,
"tooltip": "Should match the prompt used in SelvaFeatureExtractor."}),
"negative_prompt": ("STRING", {"default": "", "multiline": True,
"tooltip": "Sounds to steer away from, e.g. 'wind noise, background music'."}),
"duration": ("FLOAT", {"default": 0.0, "min": 0.0, "max": 30.0, "step": 0.1,
"tooltip": "Audio duration in seconds. 0 = use duration from features."}),
"steps": ("INT", {"default": 25, "min": 1, "max": 200}),
"cfg_strength": ("FLOAT", {"default": 4.5, "min": 1.0, "max": 20.0, "step": 0.1}),
"seed": ("INT", {"default": 0, "min": 0, "max": 0xFFFFFFFF}),
},
}
RETURN_TYPES = ("AUDIO",)
RETURN_NAMES = ("audio",)
FUNCTION = "generate"
CATEGORY = PRISMAUDIO_CATEGORY
def generate(self, model, features, prompt, negative_prompt, duration, steps, cfg_strength, seed):
from selva_core.model.flow_matching import FlowMatching
device = get_device()
dtype = model["dtype"]
strategy = model["strategy"]
net_generator = model["generator"]
feature_utils = model["feature_utils"]
mode = model["mode"]
# Resolve duration
if duration <= 0:
if "duration" not in features:
raise ValueError("[SelVA] duration=0 but features contain no duration field.")
duration = features["duration"]
print(f"[SelVA] Using video duration from features: {duration:.2f}s", flush=True)
seq_cfg = _make_seq_cfg(duration, mode)
sample_rate = seq_cfg.sampling_rate
# Move models to device
if strategy == "offload_to_cpu":
net_generator.to(device)
feature_utils.to(device)
soft_empty_cache()
clip_f = features["clip_features"].to(device, dtype) # [1, T_clip, 1024]
sync_f = features["sync_features"].to(device, dtype) # [1, T_sync, 768]
print(f"[SelVA] clip_f={tuple(clip_f.shape)} sync_f={tuple(sync_f.shape)}", flush=True)
print(f"[SelVA] seq_cfg: latent={seq_cfg.latent_seq_len} clip={seq_cfg.clip_seq_len} sync={seq_cfg.sync_seq_len}", flush=True)
# Update model sequence lengths for this duration
net_generator.update_seq_lengths(
latent_seq_len=seq_cfg.latent_seq_len,
clip_seq_len=seq_cfg.clip_seq_len,
sync_seq_len=seq_cfg.sync_seq_len,
)
with torch.no_grad():
# Encode text
text_clip = feature_utils.encode_text_clip([prompt]) # [1, 77, D]
# Build empty (negative) conditions for CFG
neg_text_clip = feature_utils.encode_text_clip([negative_prompt]) \
if negative_prompt.strip() else None
conditions = net_generator.preprocess_conditions(clip_f, sync_f, text_clip)
empty_conditions = net_generator.get_empty_conditions(
bs=1, negative_text_features=neg_text_clip
)
# Sample initial noise
rng = torch.Generator(device=device).manual_seed(seed)
x0 = torch.randn(
1, seq_cfg.latent_seq_len, net_generator.latent_dim,
device=device, dtype=dtype, generator=rng
)
# Flow matching ODE (Euler)
fm = FlowMatching(min_sigma=0, inference_mode="euler", num_steps=steps)
pbar = comfy.utils.ProgressBar(steps)
_step_count = [0]
orig_to_data = fm.to_data
def tracked_to_data(fn, x0_):
# ProgressBar update via step counting in ode_wrapper
return orig_to_data(fn, x0_)
# Wrap ODE to update progress bar
def ode_wrapper_tracked(t, x):
_step_count[0] += 1
pbar.update(1)
return net_generator.ode_wrapper(t, x, conditions, empty_conditions, cfg_strength)
x1 = fm.to_data(ode_wrapper_tracked, x0)
print(f"[SelVA] latent stats: mean={x1.float().mean():.4f} std={x1.float().std():.4f}", flush=True)
# Decode: latent → mel → audio
if strategy == "offload_to_cpu":
feature_utils.to(device)
soft_empty_cache()
with torch.no_grad():
x1_unnorm = net_generator.unnormalize(x1)
spec = feature_utils.decode(x1_unnorm)
audio = feature_utils.vocode(spec) # [1, samples] or [1, 1, samples]
if strategy == "offload_to_cpu":
net_generator.to(get_offload_device())
feature_utils.to(get_offload_device())
soft_empty_cache()
# Normalise to [-1, 1]
audio = audio.float()
if audio.dim() == 2:
audio = audio.unsqueeze(1) # [1, 1, samples]
elif audio.dim() == 3 and audio.shape[1] != 1:
audio = audio.mean(dim=1, keepdim=True) # stereo → mono
peak = audio.abs().max().clamp(min=1e-8)
audio = (audio / peak).clamp(-1, 1)
print(f"[SelVA] audio: shape={tuple(audio.shape)} sr={sample_rate}", flush=True)
return ({"waveform": audio.cpu(), "sample_rate": sample_rate},)
```
**Step 2: Register in `nodes/__init__.py`**
```python
"SelvaSampler": (".selva_sampler", "SelvaSampler", "SelVA Sampler"),
```
**Step 3: Verify node registers**
```bash
python -c "
import sys; sys.path.insert(0, '.')
from nodes.selva_sampler import SelvaSampler
inputs = SelvaSampler.INPUT_TYPES()
print('inputs:', list(inputs['required'].keys()))
print('outputs:', SelvaSampler.RETURN_TYPES)
"
```
Expected: `inputs: ['model', 'features', 'prompt', 'negative_prompt', 'duration', 'steps', 'cfg_strength', 'seed']`
**Step 4: Commit**
```bash
git add nodes/selva_sampler.py nodes/__init__.py
git commit -m "feat: SelvaSampler — flow matching ODE with CFG + negative prompts"
```
---
## Task 5: Create example workflow and push
**Files:**
- Create: `workflows/selva_video_to_audio.json`
**Step 1: Create workflow JSON**
Create `workflows/selva_video_to_audio.json` with this node graph:
- LoadVideo (VHS) → IMAGE + VHS_VIDEOINFO
- SelvaModelLoader → SELVA_MODEL
- SelvaFeatureExtractor (takes IMAGE + VHS_VIDEOINFO + SELVA_MODEL, prompt) → SELVA_FEATURES
- SelvaSampler (takes SELVA_MODEL + SELVA_FEATURES, prompt, negative_prompt) → AUDIO
- PreviewAudio (takes AUDIO)
Set defaults: variant=medium_44k, precision=bf16, steps=25, cfg_strength=4.5, duration=0.
**Step 2: Push branch**
```bash
git push -u origin feature/selva-integration
```
---
## Task 6: Smoke test
**Step 1: Check all three nodes are importable from ComfyUI's perspective**
```bash
cd /media/p5/Comfyui-Prismaudio
python -c "
import sys; sys.path.insert(0, '.')
import nodes
m = nodes.NODE_CLASS_MAPPINGS
print('SelVA nodes:', [k for k in m if 'Selva' in k])
assert 'SelvaModelLoader' in m
assert 'SelvaFeatureExtractor' in m
assert 'SelvaSampler' in m
print('All SelVA nodes registered OK')
"
```
**Step 2: Verify no import errors in full node load**
```bash
python -c "
import sys; sys.path.insert(0, '.')
from nodes.selva_model_loader import SelvaModelLoader
from nodes.selva_feature_extractor import SelvaFeatureExtractor
from nodes.selva_sampler import SelvaSampler
print('All imports clean')
"
```
**Step 3: Final commit with any fixes**
```bash
git add -A
git commit -m "fix: selva integration smoke test fixes (if any)"
git push
```
---
## Notes
- The `FeaturesUtils.train()` is overridden to always call `super().train(False)` — SelVA models are always in eval mode
- `net_generator.update_seq_lengths` recalculates rotary position embeddings; call it before every generation when duration may vary
- ProgressBar tracking: `FlowMatching.to_data` calls `fn(t, x)` for each Euler step; wrapping `ode_wrapper` with a counter gives accurate progress
- The `feature_utils.vocode` returns audio at 16kHz for small_16k (uses BigVGAN) and 44.1kHz for 44k variants (uses VAE mel decoder directly)
- If `encode_text_t5` or `encode_text_clip` fail with missing model errors on first run, it's HuggingFace downloading `flan-t5-base` and `apple/DFN5B-CLIP-ViT-H-14-384` — this is expected and takes a few minutes once