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#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import json
import math
from pathlib import Path
from typing import List, Optional, Tuple, Union
import numpy as np
import torch
import torchvision.transforms.functional as TF
from diffusers.models.autoencoders.autoencoder_kl_wan import AutoencoderKLWan
from diffusers.pipelines.pipeline_utils import DiffusionPipeline
from diffusers.schedulers import UniPCMultistepScheduler
from diffusers.utils.torch_utils import randn_tensor
from einops import rearrange
from tqdm import tqdm
from transformers import AutoTokenizer
from diffusers_cosmos3.sequence_packing import (
GenerationDataClean,
SequencePlan,
build_packed_sequence,
build_sequence_plans_from_data_batch,
get_all_seq,
pack_input_sequence,
)
from diffusers_cosmos3.transformer import (
Cosmos3OmniTransformer,
)
_SYSTEM_PROMPT_IMAGE = "You are a helpful assistant who will generate images from a give prompt."
_SYSTEM_PROMPT_VIDEO = "You are a helpful assistant who will generate videos from a give prompt."
def save_img_or_video(sample, save_fp_wo_ext, fps=24, quality=10, ffmpeg_params=None, **kwargs):
# TODO: remove this function and use diffusers-style vidoe processor
# However, it may cause numerical differences in the saved video, so we keep it for now for exact reproducibility of saved videos.
import imageio
from PIL import Image as PILImage
assert sample.ndim == 4, "Only support 4D tensor"
if torch.is_floating_point(sample):
sample = sample.clamp(0, 1)
else:
assert sample.dtype == torch.uint8, "Only support uint8 tensor"
sample = sample.float().div(255)
if sample.shape[1] == 1:
save_obj = PILImage.fromarray(
rearrange((sample.cpu().float().numpy() * 255), "c 1 h w -> h w c").astype(np.uint8),
mode="RGB",
)
save_obj.save(f"{save_fp_wo_ext}.jpg", format="JPEG", quality=85 if quality is None else quality)
else:
frames = rearrange((sample.cpu().float().numpy() * 255), "c t h w -> t h w c").astype(np.uint8)
h, w = frames.shape[1], frames.shape[2]
out_ffmpeg_params = ffmpeg_params if ffmpeg_params is not None else ["-s", f"{w}x{h}"]
imageio.mimsave(
f"{save_fp_wo_ext}.mp4",
frames,
fps=fps,
quality=quality,
macro_block_size=1,
ffmpeg_params=out_ffmpeg_params,
output_params=["-f", "mp4"],
)
class DiffusersWan22VAE:
"""
Drop-in replacement for Wan2pt2VAEInterface, backed by AutoencoderKLWan.
Bridges the following interface differences:
1. encode – AutoencoderKLWan returns AutoencoderKLOutput(latent_dist=
DiagonalGaussianDistribution); we extract .mode() and apply the same
(μ - mean) * inv_std normalization that WanVAE does internally.
2. decode – AutoencoderKLWan expects un-normalized z and returns
DecoderOutput(sample=…); we invert the normalization before calling
decode and unwrap the result to a plain tensor.
3. spatial/temporal_compression_factor properties – AutoencoderKLWan
stores these as config.scale_factor_spatial / scale_factor_temporal
and exposes spatial_compression_ratio (not *_factor).
Note: AutoencoderKLWan._decode() clamps the output to [-1, 1];
Wan2pt2VAEInterface does not. The pipeline applies .clamp(0, 1) after
decode so this difference does not affect saved videos.
Numerical equivalence requirements (needed for bitwise-identical output
vs Wan2pt2VAEInterface):
- No torch.amp.autocast: Wan2pt2VAEInterface constructs WanVAE with
is_amp=False, so the encoder/decoder run as pure bfloat16 with no
autocast context. Wrapping calls in autocast changes how ops such as
F.normalize accumulate internally and breaks the match.
- mean / inv_std must be initialised directly in `dtype` (bfloat16).
WanVAE.__init__ does:
self.std = torch.tensor(std, dtype=bfloat16)
self.scale = [self.mean, 1.0 / self.std] # division in bfloat16
Computing 1/std in float32 and then casting to bfloat16 can yield
different bit patterns, so we must perform the division in bfloat16
from the start.
"""
def __init__(self, vae: AutoencoderKLWan, dtype: torch.dtype = torch.bfloat16):
self.vae = vae
self.dtype = dtype
# Initialise in `dtype` so 1/std is computed in bfloat16, matching WanVAE.
mean = torch.tensor(vae.config.latents_mean, dtype=dtype)
std = torch.tensor(vae.config.latents_std, dtype=dtype)
self._mean = mean # [z_dim]
self._inv_std = 1.0 / std # [z_dim]
@torch.no_grad()
def encode(self, x: torch.Tensor) -> torch.Tensor:
"""[B,3,T,H,W] -> [B,z_dim,T//4,H//16,W//16] (normalized μ, matching Wan2pt2VAEInterface)"""
in_dtype = x.dtype
device = x.device
mean = self._mean.to(device=device, dtype=self.dtype)
inv_std = self._inv_std.to(device=device, dtype=self.dtype)
# No autocast — mirrors WanVAE(is_amp=False), pure bfloat16 forward pass.
raw_mu = self.vae.encode(x.to(self.dtype)).latent_dist.mode()
normalized = (raw_mu - mean.view(1, -1, 1, 1, 1)) * inv_std.view(1, -1, 1, 1, 1)
return normalized.to(in_dtype)
@torch.no_grad()
def decode(self, z: torch.Tensor) -> torch.Tensor:
"""[B,z_dim,T_lat,H_lat,W_lat] -> [B,3,T,H,W]"""
in_dtype = z.dtype
device = z.device
mean = self._mean.to(device=device, dtype=self.dtype)
inv_std = self._inv_std.to(device=device, dtype=self.dtype)
z_raw = z.to(self.dtype) / inv_std.view(1, -1, 1, 1, 1) + mean.view(1, -1, 1, 1, 1)
# No autocast — mirrors WanVAE(is_amp=False), pure bfloat16 forward pass.
out = self.vae.decode(z_raw).sample
return out.to(in_dtype)
@property
def spatial_compression_factor(self) -> int:
return self.vae.config.scale_factor_spatial
@property
def temporal_compression_factor(self) -> int:
return self.vae.config.scale_factor_temporal
class Cosmos3OmniDiffusersPipeline(DiffusionPipeline):
_optional_components = ["vision_encoder"]
model_cpu_offload_seq = "transformer"
def __init__(
self,
transformer: Cosmos3OmniTransformer,
text_tokenizer: AutoTokenizer,
vae: AutoencoderKLWan,
scheduler: UniPCMultistepScheduler,
vision_encoder=None,
):
super().__init__()
self.register_modules(
transformer=transformer,
text_tokenizer=text_tokenizer,
vae=vae,
scheduler=scheduler,
vision_encoder=vision_encoder,
)
# Plain attribute (not registered): registering the wrapper would cause save_pretrained to call
# wrapper.save_pretrained(), which fails since DiffusersWan22VAE has no such method.
self.vision_tokenizer = DiffusersWan22VAE(vae)
self.llm_special_tokens = {
"start_of_generation": text_tokenizer.convert_tokens_to_ids("<|vision_start|>"),
"end_of_generation": text_tokenizer.convert_tokens_to_ids("<|vision_end|>"),
"eos_token_id": text_tokenizer.eos_token_id,
}
def tokenize_caption(
self,
caption: str,
is_video: bool = False,
use_system_prompt: bool = False,
) -> list[int]:
"""Tokenize a text caption into token IDs using the Qwen2 chat template.
Returns:
List of token IDs representing the full chat-formatted caption.
"""
conversations = []
# Optionally prepend a system prompt that tells the model whether it is generating
# an image or a video. This changes the conditioning context for the LLM.
if use_system_prompt:
_system_prompt = _SYSTEM_PROMPT_VIDEO if is_video else _SYSTEM_PROMPT_IMAGE
conversations.append({"role": "system", "content": _system_prompt})
conversations.append({"role": "user", "content": caption})
tokenizer_output = self.text_tokenizer.apply_chat_template(
conversations,
tokenize=True,
add_generation_prompt=True,
add_vision_id=False,
)
return tokenizer_output
def apply_timestep_embeds_to_noisy_tokens(
self,
packed_tokens: torch.Tensor,
packed_timestep_embeds: torch.Tensor,
noisy_frame_indexes: List[torch.Tensor],
token_shapes: list[tuple[int, ...]],
) -> torch.Tensor:
start_noisy_index = 0
flattened_noisy_frame_indexes = []
for noisy_indexes_i, token_shape_i in zip(noisy_frame_indexes, token_shapes):
assert noisy_indexes_i.numel() <= token_shape_i[0]
spatial_numel_i = math.prod(token_shape_i[1:])
spatial_indexes_i = torch.arange(spatial_numel_i, device=packed_tokens.device)
noisy_indexes_i = (noisy_indexes_i * spatial_numel_i).unsqueeze(-1).expand(-1, spatial_numel_i)
noisy_indexes_i = noisy_indexes_i.clone() + spatial_indexes_i + start_noisy_index
flattened_noisy_frame_indexes.append(noisy_indexes_i.flatten())
start_noisy_index += math.prod(token_shape_i)
flattened_noisy_frame_indexes = torch.cat(flattened_noisy_frame_indexes, dim=0)
assert packed_tokens.dim() == 2
assert packed_timestep_embeds.dim() == 2
assert packed_timestep_embeds.shape[1] == packed_tokens.shape[1]
assert packed_timestep_embeds.shape[0] <= packed_tokens.shape[0]
assert flattened_noisy_frame_indexes.dim() == 1
assert flattened_noisy_frame_indexes.shape[0] == packed_timestep_embeds.shape[0]
flattened_noisy_frame_indexes = flattened_noisy_frame_indexes.unsqueeze(-1).expand(
-1,
packed_tokens.shape[1],
)
return packed_tokens.scatter_add(
dim=0,
index=flattened_noisy_frame_indexes,
src=packed_timestep_embeds,
)
def patchify_and_pack_latents(
self,
latent_patch_size: int,
latent_channel: int,
tokens_vision: torch.Tensor,
token_shapes_vision: List[Tuple[int, int, int]],
) -> tuple[torch.Tensor, List[Tuple[int, int, int]]]:
p = latent_patch_size
packed_latent = []
original_latent_shapes = []
for latent, (t, h, w) in zip(tokens_vision, token_shapes_vision):
latent = latent.squeeze(0) # [C,T,H,W]
_, t_actual, h_actual, w_actual = latent.shape
original_latent_shapes.append((t_actual, h_actual, w_actual))
h_padded = ((h_actual + p - 1) // p) * p
w_padded = ((w_actual + p - 1) // p) * p
if h_padded != h_actual or w_padded != w_actual:
padded = torch.zeros(
(latent_channel, t_actual, h_padded, w_padded),
device=latent.device,
dtype=latent.dtype,
)
padded[:, :, :h_actual, :w_actual] = latent
latent = padded
h_patches = h_padded // p
w_patches = w_padded // p
latent = latent.reshape(latent_channel, t_actual, h_patches, p, w_patches, p)
latent = torch.einsum("cthpwq->thwpqc", latent).reshape(-1, p * p * latent_channel)
packed_latent.append(latent)
return torch.cat(packed_latent, dim=0), original_latent_shapes
def unpatchify_and_unpack_latents(
self,
latent_patch_size: int,
latent_channel: int,
packed_mse_preds: torch.Tensor,
token_shapes_vision: List[Tuple[int, int, int]],
noisy_frame_indexes_vision: list[torch.Tensor],
original_latent_shapes: List[Tuple[int, int, int]] | None = None,
) -> list[torch.Tensor]:
p = latent_patch_size
unpatchified_latents = []
start_idx = 0
for i, (t_c, h_c, w_c) in enumerate(token_shapes_vision):
if original_latent_shapes is not None:
t_orig, h_orig, w_orig = original_latent_shapes[i]
h_padded = ((h_orig + p - 1) // p) * p
w_padded = ((w_orig + p - 1) // p) * p
h_patches = h_padded // p
w_patches = w_padded // p
else:
t_orig, h_orig, w_orig = t_c, h_c * p, w_c * p
h_patches, w_patches = h_c, w_c
noisy_frame_indexes = noisy_frame_indexes_vision[i]
t_n = len(noisy_frame_indexes)
output_tensor = torch.zeros(
(latent_channel, t_c, h_orig, w_orig),
device=packed_mse_preds.device,
dtype=packed_mse_preds.dtype,
)
num_patches = t_n * h_patches * w_patches
if num_patches > 0:
end_idx = start_idx + num_patches
latent_patches = packed_mse_preds[start_idx:end_idx]
latent_patches = latent_patches.reshape(t_n, h_patches, w_patches, p, p, latent_channel)
latent = torch.einsum("thwpqc->cthpwq", latent_patches)
latent = latent.reshape(latent_channel, t_n, h_patches * p, w_patches * p)
latent = latent[:, :, :h_orig, :w_orig]
output_tensor[:, noisy_frame_indexes] = latent
start_idx = end_idx
unpatchified_latents.append(output_tensor.unsqueeze(0))
return unpatchified_latents
def decode_vision(
self,
patch_latent_dim: int,
latent_patch_size: int,
latent_channel: int,
packed_seq,
last_hidden_state: torch.Tensor,
original_latent_shapes: List[Tuple[int, int, int]] | None = None,
) -> list[torch.Tensor]:
"""Decode vision predictions from last_hidden_state. Returns preds_vision list."""
vision = packed_seq.vision
has_noisy_vision = (
vision is not None
and vision.tokens is not None
and isinstance(vision.mse_loss_indexes, torch.Tensor)
and vision.mse_loss_indexes.numel() > 0
)
if not has_noisy_vision:
preds_vision = torch.zeros(
[1, patch_latent_dim], device=last_hidden_state.device, dtype=last_hidden_state.dtype
)
preds_vision = self.transformer.proj_in(preds_vision)
preds_vision = self.transformer.proj_out(preds_vision)
if vision is not None and vision.tokens is not None:
preds_vision_list = [torch.zeros_like(tok) for tok in vision.tokens]
preds_vision_list[0] = preds_vision_list[0] + 0.0 * preds_vision.sum()
else:
preds_vision_list = [preds_vision]
else:
assert vision is not None
assert isinstance(vision.mse_loss_indexes, torch.Tensor)
assert vision.noisy_frame_indexes is not None
preds_vision = self.transformer.proj_out(last_hidden_state[vision.mse_loss_indexes])
preds_vision_list = self.unpatchify_and_unpack_latents(
latent_patch_size,
latent_channel,
preds_vision,
token_shapes_vision=vision.token_shapes,
noisy_frame_indexes_vision=vision.noisy_frame_indexes,
original_latent_shapes=original_latent_shapes,
)
return preds_vision_list
def normalize_video_databatch_inplace(
self,
input_video_key: str,
data_batch: dict,
input_key: str | None = None,
device: str = "cuda",
dtype: torch.dtype = torch.bfloat16,
) -> None:
input_key = input_video_key if input_key is None else input_key
if input_key in data_batch:
if data_batch.get("is_preprocessed", False) is True:
for i in range(len(data_batch[input_key])):
assert torch.is_floating_point(data_batch[input_key][i])
assert torch.all((data_batch[input_key][i] >= -1.0001) & (data_batch[input_key][i] <= 1.0001))
else:
for i in range(len(data_batch[input_key])):
item = data_batch[input_key][i]
if isinstance(item, torch.Tensor):
item = [item]
assert item[0].dtype == torch.uint8
data_batch[input_key][i] = torch.stack(item).to(device=device, dtype=dtype) / 127.5 - 1.0
data_batch["is_preprocessed"] = True
def augment_image_dim_inplace(
self,
input_image_key: str,
data_batch: dict,
input_key: str | None = None,
device: str = "cuda",
dtype: torch.dtype = torch.bfloat16,
) -> None:
input_key = input_image_key if input_key is None else input_key
if input_key in data_batch:
if data_batch.get("is_preprocessed", False) is True:
for i in range(len(data_batch[input_key])):
assert data_batch[input_key][i].shape[2] == 1
return
else:
new_image_tensor_list = []
for i in range(len(data_batch[input_key])):
for img_tensor in data_batch[input_key][i]:
img_tensor = rearrange(img_tensor, "c h w -> 1 c 1 h w").contiguous()
if img_tensor.dtype == torch.uint8:
img_tensor = img_tensor.to(device=device, dtype=dtype) / 127.5 - 1.0
new_image_tensor_list.append(img_tensor)
data_batch[input_key] = new_image_tensor_list
data_batch["is_preprocessed"] = True
def remove_padding_from_latent(
self,
spatial_compression_factor: int,
x0_tokens_vision: list[torch.Tensor],
frame_size: list[torch.Tensor],
) -> list[torch.Tensor]:
cropped_latents = []
for i in range(len(x0_tokens_vision)):
fs = frame_size[i]
if fs.dim() == 2:
fs = fs[0]
orig_h = int(fs[2].item())
orig_w = int(fs[3].item())
orig_h_latent = orig_h // spatial_compression_factor
orig_w_latent = orig_w // spatial_compression_factor
cropped_latents.append(x0_tokens_vision[i][:, :, :, :orig_h_latent, :orig_w_latent].contiguous())
return cropped_latents
def get_data_and_condition(
self,
input_image_key: str,
input_video_key: str,
data_batch: dict,
device: str = "cuda",
dtype: torch.dtype = torch.bfloat16,
) -> GenerationDataClean:
assert (input_image_key in data_batch) != (input_video_key in data_batch)
is_img = input_image_key in data_batch
sample_vision_list = data_batch[input_image_key if is_img else input_video_key]
if "num_vision_items_per_sample" not in data_batch:
has_multiple_vision_per_sample = any(
isinstance(v, (list, tuple)) and len(v) > 1 for v in sample_vision_list
)
num_vision_items_per_sample: list[int] | None = (
[len(v) for v in sample_vision_list] if has_multiple_vision_per_sample else None
)
data_batch["num_vision_items_per_sample"] = num_vision_items_per_sample
if has_multiple_vision_per_sample:
media_key = input_video_key if not is_img else input_image_key
data_batch[media_key] = [item.unsqueeze(0) for sublist in sample_vision_list for item in sublist]
if data_batch[media_key][0].dtype == torch.float32 and not is_img:
data_batch["is_preprocessed"] = True
else:
num_vision_items_per_sample = data_batch["num_vision_items_per_sample"]
batch_size = (
len(sample_vision_list) if num_vision_items_per_sample is None else len(num_vision_items_per_sample)
)
self.normalize_video_databatch_inplace(input_video_key, data_batch, device=device, dtype=dtype)
self.augment_image_dim_inplace(input_image_key, data_batch, device=device, dtype=dtype)
raw_state_vision = data_batch[input_image_key if is_img else input_video_key]
x0_tokens_vision = [
self.vision_tokenizer.encode(raw_state_vision_i).contiguous().float()
for raw_state_vision_i in raw_state_vision
]
frame_size = data_batch.get("image_size", None)
if frame_size is not None:
x0_tokens_vision = self.remove_padding_from_latent(
self.vision_tokenizer.spatial_compression_factor, x0_tokens_vision, frame_size
)
fps_raw = data_batch.get("conditioning_fps", None)
if isinstance(fps_raw, list):
fps_raw = torch.stack(fps_raw).flatten()
fps_vision = fps_raw.to(device=device, dtype=dtype) if fps_raw is not None else None
return GenerationDataClean(
batch_size=batch_size,
is_image_batch=is_img,
raw_state_vision=raw_state_vision,
x0_tokens_vision=x0_tokens_vision,
fps_vision=fps_vision,
num_vision_items_per_sample=num_vision_items_per_sample,
)
def get_inference_text_tokens(
self, use_system_prompt: bool, input_caption_key: str, data_batch: dict, has_negative_prompt: bool
) -> tuple[list[list[int]], list[list[int]]]:
cond_tokens = [
self.tokenize_caption(c, is_video=False, use_system_prompt=use_system_prompt)
for c in data_batch[input_caption_key]
]
if has_negative_prompt:
neg_key = "neg_" + input_caption_key
assert neg_key in data_batch, f"Negative prompt ({neg_key}) not found"
uncond_captions = data_batch[neg_key]
else:
uncond_captions = [""] * len(cond_tokens)
uncond_tokens = [
self.tokenize_caption(c, is_video=False, use_system_prompt=use_system_prompt) for c in uncond_captions
]
return cond_tokens, uncond_tokens
def derive_include_end_of_generation_token(self, joint_attn_implementation: str) -> bool:
assert joint_attn_implementation in ("flex", "two_way", "three_way")
return joint_attn_implementation == "flex"
def prepare_inference_data(
self,
use_system_prompt: bool,
prompt: Union[str, List[str]],
negative_prompt: Optional[Union[str, List[str]]] = None,
image=None,
num_frames: int = 189,
height: int = 720,
width: int = 1280,
fps: float = 24.0,
condition_frame_indexes: Optional[List[int]] = None,
noises: Optional[List[torch.Tensor]] = None,
generator: Optional[torch.Generator] = None,
input_caption_key: str = "ai_caption",
input_video_key: str = "video",
input_image_key: str = "images",
device: str = "cuda",
dtype: torch.dtype = torch.bfloat16,
) -> tuple[
list[SequencePlan],
GenerationDataClean,
list[list[int]],
list[list[int]],
torch.Tensor,
]:
# Build data_batch
prompts = [prompt] if isinstance(prompt, str) else list(prompt)
batch_size = len(prompts)
is_image = num_frames == 1
conditioning_frames = None
if image is not None:
conditioning_frames = self._load_image_as_tensor(image, height, width)
image_size = [
torch.tensor([[height, width, height, width]], dtype=torch.float32, device=device)
for _ in range(batch_size)
]
if is_image:
img_tensor = (
conditioning_frames.unsqueeze(0).to(device=device, dtype=dtype)
if conditioning_frames is not None
else torch.zeros(1, 3, 1, height, width, dtype=dtype, device=device)
)
seq_plans = [
SequencePlan(has_text=True, has_vision=True, condition_frame_indexes_vision=[])
for _ in range(batch_size)
]
data_batch = {
input_image_key: [img_tensor] * batch_size,
"image_size": image_size,
"is_preprocessed": True,
"fps": torch.full((batch_size,), float(fps), device=device),
"conditioning_fps": torch.full((batch_size,), float(fps), device=device),
"num_frames": torch.full((batch_size,), num_frames, device=device),
"sequence_plan": seq_plans,
input_caption_key: prompts,
}
else:
cond_indexes = (
condition_frame_indexes
if condition_frame_indexes is not None
else ([0] if conditioning_frames is not None else [])
)
if conditioning_frames is not None:
video_data = torch.zeros(1, 3, num_frames, height, width, dtype=dtype)
t_fill = min(conditioning_frames.shape[1], num_frames)
video_data[0, :, :t_fill] = conditioning_frames[:, :t_fill].to(dtype=dtype)
if t_fill < num_frames:
video_data[0, :, t_fill:] = video_data[0, :, t_fill - 1 : t_fill].expand(
-1, num_frames - t_fill, -1, -1
)
video_tensor = video_data.to(device=device)
else:
video_tensor = torch.zeros(1, 3, num_frames, height, width, dtype=dtype, device=device)
seq_plans = [
SequencePlan(has_text=True, has_vision=True, condition_frame_indexes_vision=list(cond_indexes))
for _ in range(batch_size)
]
data_batch = {
input_video_key: [video_tensor] * batch_size,
"image_size": image_size,
"is_preprocessed": True,
"fps": torch.full((batch_size,), float(fps), device=device),
"conditioning_fps": torch.full((batch_size,), float(fps), device=device),
"num_frames": torch.full((batch_size,), num_frames, device=device),
"sequence_plan": seq_plans,
input_caption_key: prompts,
}
has_negative_prompt = negative_prompt is not None
if has_negative_prompt:
neg_prompts = [negative_prompt] if isinstance(negative_prompt, str) else list(negative_prompt)
data_batch["neg_" + input_caption_key] = neg_prompts
sequence_plans = build_sequence_plans_from_data_batch(
data_batch=data_batch,
input_video_key=input_video_key,
input_image_key=input_image_key,
)
gen_data_clean = self.get_data_and_condition(
input_image_key, input_video_key, data_batch, device=device, dtype=dtype
)
num_items_per_sample = gen_data_clean.num_vision_items_per_sample
cond_text_tokens, uncond_text_tokens = self.get_inference_text_tokens(
use_system_prompt, input_caption_key, data_batch, has_negative_prompt
)
mask_timesteps = torch.zeros((gen_data_clean.batch_size,), dtype=torch.float32)
packed_seq = pack_input_sequence(
sequence_plans=sequence_plans,
input_text_indexes=cond_text_tokens,
gen_data_clean=gen_data_clean,
input_timesteps=mask_timesteps,
special_tokens=self.llm_special_tokens,
latent_patch_size=self.transformer.config.latent_patch_size,
include_end_of_generation_token=self.derive_include_end_of_generation_token(
self.transformer.config.joint_attn_implementation
),
position_embedding_type=self.transformer.config.position_embedding_type,
unified_3d_mrope_reset_spatial_ids=self.transformer.config.unified_3d_mrope_reset_spatial_ids,
unified_3d_mrope_temporal_modality_margin=self.transformer.config.unified_3d_mrope_temporal_modality_margin,
enable_fps_modulation=self.transformer.config.enable_fps_modulation,
base_fps=float(self.transformer.config.base_fps),
temporal_compression_factor=self.vision_tokenizer.temporal_compression_factor,
video_temporal_causal=self.transformer.config.video_temporal_causal,
action_dim=self.transformer.config.max_action_dim,
)
assert packed_seq.vision is not None
assert packed_seq.vision.condition_mask is not None
assert isinstance(packed_seq.vision.condition_mask, list)
assert gen_data_clean.x0_tokens_vision is not None
noise_vision_list: list[torch.Tensor] = []
for i, (x0_token, cond_mask) in enumerate(
zip(gen_data_clean.x0_tokens_vision, packed_seq.vision.condition_mask, strict=True)
):
if noises is not None:
pure_noise = noises[i].to(device=device, dtype=dtype)
else:
pure_noise = randn_tensor(tuple(x0_token.shape), generator=generator, device=device, dtype=dtype)
noise_vision_list.append(
cond_mask * x0_token.to(device=device, dtype=dtype) + (1.0 - cond_mask) * pure_noise
)
initial_noise = torch.cat([t.reshape(-1) for t in noise_vision_list])
return sequence_plans, gen_data_clean, cond_text_tokens, uncond_text_tokens, initial_noise
def encode_text(
self,
hidden_size: int,
packed_seq,
) -> tuple[torch.Tensor, torch.dtype]:
"""Embed text tokens. Returns (hidden_states [N_total, H], target_dtype)."""
packed_text_embedding = self.transformer.embed_tokens(packed_seq.text_ids) # [N_text,H]
hidden_states = packed_text_embedding.new_zeros(size=(packed_seq.sequence_length, hidden_size))
hidden_states[packed_seq.text_indexes] = packed_text_embedding
return hidden_states, packed_text_embedding.dtype
def encode_vision(
self,
timestep_scale: float,
latent_patch_size: int,
latent_channel: int,
packed_seq,
hidden_states: torch.Tensor,
target_dtype: torch.dtype,
fps: Optional[torch.Tensor] = None,
) -> List[Tuple[int, int, int]] | None:
"""Project vision tokens into hidden_states in-place. Returns original_latent_shapes."""
if packed_seq.vision is None or packed_seq.vision.tokens is None:
return None
vision = packed_seq.vision
assert vision.tokens is not None
assert vision.token_shapes is not None
assert isinstance(vision.sequence_indexes, torch.Tensor)
assert isinstance(vision.timesteps, torch.Tensor)
assert isinstance(vision.mse_loss_indexes, torch.Tensor)
packed_tokens_vision, original_latent_shapes = self.patchify_and_pack_latents(
latent_patch_size, latent_channel, vision.tokens, vision.token_shapes
)
packed_tokens_vision = self.transformer.proj_in(packed_tokens_vision)
if vision.mse_loss_indexes.numel() > 0:
timesteps_vision = vision.timesteps * timestep_scale
with torch.autocast("cuda", enabled=True, dtype=torch.float32):
packed_timestep_embeds_vision = self.transformer.time_embedder(timesteps_vision)
packed_timestep_embeds_vision = packed_timestep_embeds_vision.to(target_dtype)
packed_tokens_vision = self.apply_timestep_embeds_to_noisy_tokens(
packed_tokens=packed_tokens_vision,
packed_timestep_embeds=packed_timestep_embeds_vision,
noisy_frame_indexes=vision.noisy_frame_indexes,
token_shapes=vision.token_shapes,
)
hidden_states[vision.sequence_indexes] = packed_tokens_vision
return original_latent_shapes
@torch.no_grad()
def run_single(
self,
packed_seq,
noise_x_vision: list[torch.Tensor],
hidden_size: int,
latent_patch_size: int,
latent_channel: int,
patch_latent_dim: int,
timestep_scale: float,
num_heads: int,
head_dim: int,
num_hidden_layers: int,
use_moe: bool,
joint_attn_implementation: str,
fps_vision: Optional[torch.Tensor],
device: str = "cuda",
dtype: torch.dtype = torch.bfloat16,
) -> list[torch.Tensor]:
"""Inlined forward pass from Cosmos3VFMNetworkSimple.forward()."""
if packed_seq.vision is not None:
packed_seq.vision.tokens = [x.to(device=device, dtype=dtype) for x in noise_x_vision]
packed_seq.to_cuda()
# 1. Encode text
hidden_states, target_dtype = self.encode_text(hidden_size, packed_seq)
# 2. Encode vision
original_latent_shapes = self.encode_vision(
timestep_scale,
latent_patch_size,
latent_channel,
packed_seq,
hidden_states,
target_dtype,
fps=fps_vision,
)
# 3. Build attention metadata
assert use_moe
assert packed_seq.attn_modes is not None
assert packed_seq.split_lens is not None
all_gen_indexes = []
if packed_seq.vision is not None:
assert packed_seq.vision.token_shapes is not None
assert isinstance(packed_seq.vision.sequence_indexes, torch.Tensor)
all_gen_indexes.append(packed_seq.vision.sequence_indexes)
vision_sequence_indexes = torch.cat(all_gen_indexes, dim=0) if all_gen_indexes else None
input_pack, attention_meta, _ = build_packed_sequence(
joint_attn_implementation,
packed_sequence=hidden_states,
attn_modes=packed_seq.attn_modes,
split_lens=packed_seq.split_lens,
sample_lens=packed_seq.sample_lens,
packed_und_token_indexes=packed_seq.text_indexes,
packed_gen_token_indexes=vision_sequence_indexes,
num_heads=num_heads,
is_image_batch=packed_seq.is_image_batch,
head_dim=head_dim,
num_layers=num_hidden_layers,
token_shapes=packed_seq.vision.token_shapes,
natten_parameter_list=None,
cp_world_size=1,
video_temporal_causal=False,
vision_token_shapes=packed_seq.vision.token_shapes if packed_seq.vision else None,
action_token_shapes=None,
temporal_compression_factor_vision=self.vision_tokenizer.temporal_compression_factor,
null_action_supertokens=packed_seq.null_action_supertokens,
pad_for_cuda_graphs=False,
)
# 4. Run transformer
packed_outputs, _ = self.transformer(
input_pack,
attention_mask=attention_meta,
position_ids=packed_seq.position_ids,
dual_kv_cache=None,
frame_idx=None,
natten_metadata_list=None,
)
last_hidden_state = get_all_seq(packed_outputs)
# 5. Decode vision
return self.decode_vision(
patch_latent_dim,
latent_patch_size,
latent_channel,
packed_seq,
last_hidden_state,
original_latent_shapes,
)
@torch.no_grad()
def get_cfg_velocity(
self,
noise_x: torch.Tensor,
timestep: torch.Tensor,
guidance: float,
gen_data_clean: GenerationDataClean,
sequence_plans: list[SequencePlan],
cond_tokens: list[list[int]],
uncond_tokens: list[list[int]],
include_eog: bool,
hidden_size: int,
latent_patch_size: int,
latent_channel: int,
patch_latent_dim: int,
timestep_scale: float,
num_heads: int,
head_dim: int,
num_hidden_layers: int,
use_moe: bool,
joint_attn_implementation: str,
skip_text_tokens_for_cfg: bool = False,
normalize_cfg: bool = False,
device: str = "cuda",
dtype: torch.dtype = torch.bfloat16,
) -> torch.Tensor:
torch.compiler.cudagraph_mark_step_begin()
assert timestep.ndim == 2 and timestep.shape == (1, 1)
num_items = gen_data_clean.num_vision_items_per_sample
num_vis = num_items[0] if num_items is not None else 1
noise_x_vision: list[torch.Tensor] = []
offset = 0
for j in range(num_vis):
vision_shape = gen_data_clean.x0_tokens_vision[j].shape
vision_dim = int(torch.prod(torch.tensor(vision_shape)))
noise_x_vision.append(noise_x[offset : offset + vision_dim].reshape(vision_shape))
offset += vision_dim
gen_data_for_packing = GenerationDataClean(
batch_size=1,
is_image_batch=gen_data_clean.is_image_batch,
raw_state_vision=gen_data_clean.raw_state_vision,
x0_tokens_vision=noise_x_vision,
fps_vision=gen_data_clean.fps_vision,
num_vision_items_per_sample=num_items,
)
def _run_cond(text_tokens: list[list[int]], skip_text: bool) -> torch.Tensor:
packed_seq = pack_input_sequence(
sequence_plans=sequence_plans,
input_text_indexes=text_tokens,
gen_data_clean=gen_data_for_packing,
input_timesteps=timestep.cpu(),
special_tokens=self.llm_special_tokens,
latent_patch_size=self.transformer.config.latent_patch_size,
include_end_of_generation_token=include_eog,
skip_text_tokens=skip_text,
position_embedding_type=self.transformer.config.position_embedding_type,
unified_3d_mrope_reset_spatial_ids=self.transformer.config.unified_3d_mrope_reset_spatial_ids,
unified_3d_mrope_temporal_modality_margin=self.transformer.config.unified_3d_mrope_temporal_modality_margin,
enable_fps_modulation=self.transformer.config.enable_fps_modulation,
base_fps=float(self.transformer.config.base_fps),
temporal_compression_factor=self.vision_tokenizer.temporal_compression_factor,
video_temporal_causal=self.transformer.config.video_temporal_causal,
action_dim=self.transformer.config.max_action_dim,
)
preds = self.run_single(
packed_seq,
noise_x_vision,
hidden_size,
latent_patch_size,
latent_channel,
patch_latent_dim,
timestep_scale,
num_heads,
head_dim,
num_hidden_layers,
use_moe,
joint_attn_implementation,
fps_vision=gen_data_clean.fps_vision,
device=device,
dtype=dtype,
)
assert packed_seq.vision is not None
assert packed_seq.vision.condition_mask is not None
assert isinstance(packed_seq.vision.condition_mask, list)
velocity_vision = [
pred * (1.0 - m).to(dtype=pred.dtype, device=pred.device)
if (1.0 - m).sum() > 0
else torch.zeros_like(pred)
for pred, m in zip(preds, packed_seq.vision.condition_mask)
]
return torch.cat([v.reshape(-1) for v in velocity_vision])
cond_v = _run_cond(cond_tokens, False)
uncond_v = _run_cond(uncond_tokens, skip_text_tokens_for_cfg)
v_pred = uncond_v + guidance * (cond_v - uncond_v)
if normalize_cfg:
v_pred = v_pred * (torch.norm(cond_v) / (torch.norm(v_pred) + 1e-8)).clamp(min=0.0, max=1.0)
return v_pred
def _load_image_as_tensor(self, image, target_h: int, target_w: int) -> torch.Tensor:
"""Load image from PIL, path, URL, or tensor; returns [3, 1, H, W] in [-1, 1]."""
from PIL import Image as PILImage
if isinstance(image, (str, Path)):
image_str = str(image)
if image_str.startswith("http://") or image_str.startswith("https://"):
import io
import urllib.request
with urllib.request.urlopen(image_str) as resp:
img_bytes = resp.read()
pil_img = PILImage.open(io.BytesIO(img_bytes)).convert("RGB")
else:
with open(image_str, "rb") as f:
pil_img = PILImage.open(f).convert("RGB")
img_t = torch.from_numpy(np.array(pil_img)).permute(2, 0, 1).float()
elif hasattr(image, "convert"): # PIL.Image
img_t = torch.from_numpy(np.array(image.convert("RGB"))).permute(2, 0, 1).float()
elif isinstance(image, torch.Tensor):
img_t = image.float()
if img_t.dim() == 4:
img_t = img_t.squeeze(0)
# if already normalized to [-1, 1], skip the /127.5-1 step below
if img_t.max() <= 1.1:
img_4d = img_t.unsqueeze(0)
orig_h, orig_w = img_4d.shape[2], img_4d.shape[3]
scale = max(target_w / orig_w, target_h / orig_h)
resize_h = int(math.ceil(scale * orig_h))
resize_w = int(math.ceil(scale * orig_w))
img_4d = TF.resize(img_4d, [resize_h, resize_w])
img_4d = TF.center_crop(img_4d, [target_h, target_w])
return img_4d.squeeze(0).unsqueeze(1)
else:
raise TypeError(f"Unsupported image type: {type(image)}")
img_4d = img_t.unsqueeze(0) # [1, 3, H, W] (uint8-range [0, 255])
orig_h, orig_w = img_4d.shape[2], img_4d.shape[3]
scale = max(target_w / orig_w, target_h / orig_h)
resize_h = int(math.ceil(scale * orig_h))
resize_w = int(math.ceil(scale * orig_w))
img_4d = TF.resize(img_4d, [resize_h, resize_w])
img_4d = TF.center_crop(img_4d, [target_h, target_w])
img_4d = img_4d / 127.5 - 1.0 # normalize after resize, matching load_conditioning_image
return img_4d.squeeze(0).unsqueeze(1) # [3, 1, H, W]
def _resolve_defaults_and_prompts(
self,
prompt: Union[str, List[str]],
negative_prompt: Optional[Union[str, List[str]]],
image,
num_frames: int,
fps: float,
height: int,
width: int,
) -> tuple[float, int, float, Union[str, List[str]], Union[str, List[str]]]:
"""Load modality defaults and apply duration/resolution templates to prompts.
Returns (guidance, num_steps, shift, formatted_prompt, formatted_negative_prompt).
"""
model_mode = "image2video" if image is not None else "text2video"
defaults = json.loads((Path(__file__).parent / f"sample_args/{model_mode}.json").read_text())
guidance = float(defaults["guidance"])
num_steps = int(defaults["num_steps"])
shift = float(defaults["shift"])
print(f"model_mode={model_mode!r}: guidance={guidance}, num_steps={num_steps}, shift={shift}")
duration_template = defaults.get("duration_template")
resolution_template = defaults.get("resolution_template")
negative_prompt_base = defaults.get("negative_prompt", "")
keep_metadata = defaults.get("negative_prompt_keep_metadata", False)
def _apply_templates(text: str) -> str:
if duration_template and num_frames > 1:
text = text.rstrip(".") + ". " + duration_template.format(duration=num_frames / fps, fps=fps)
if resolution_template:
text = text.rstrip(".") + ". " + resolution_template.format(height=height, width=width)
return text
if isinstance(prompt, str):
prompt = _apply_templates(prompt)
else:
prompt = [_apply_templates(p) for p in prompt]
if negative_prompt is None:
negative_prompt = _apply_templates(negative_prompt_base) if keep_metadata else negative_prompt_base
return guidance, num_steps, shift, prompt, negative_prompt
@torch.no_grad()
def decode_latents(self, vision_list: list[torch.Tensor]) -> list[torch.Tensor]:
"""Decode latents to pixel tensors of shape [C, T, H, W] in [0, 1]."""
frames = []
for vision_latent in vision_list:
vision = self.vision_tokenizer.decode(vision_latent.cuda()) # [1, C, T, H, W]
frames.append(((1.0 + vision) / 2).clamp(0, 1).squeeze(0))
return frames
@torch.no_grad()
def __call__(
self,
prompt: Union[str, List[str]],
negative_prompt: Optional[Union[str, List[str]]] = None,
image=None,
num_frames: int = 189,
height: int = 720,
width: int = 1280,
fps: float = 24.0,
condition_frame_indexes: Optional[List[int]] = None,
noises: Optional[List[torch.Tensor]] = None,
generator: Optional[torch.Generator] = None,
use_system_prompt: bool = False,
device: str = "cuda",
dtype: torch.dtype = torch.bfloat16,
output_type: str = "video",
):
latent_patch_size = self.transformer.config.latent_patch_size
latent_channel = self.transformer.config.latent_channel
patch_latent_dim = self.transformer.config.patch_latent_dim
timestep_scale = self.transformer.config.timestep_scale
hidden_size = self.transformer.config.hidden_size
num_heads = self.transformer.config.num_attention_heads
head_dim = self.transformer.config.head_dim
num_hidden_layers = self.transformer.config.num_hidden_layers
use_moe = self.transformer.config.use_moe
joint_attn_implementation = self.transformer.config.joint_attn_implementation
guidance, num_steps, shift, prompt, negative_prompt = self._resolve_defaults_and_prompts(
prompt, negative_prompt, image, num_frames, fps, height, width
)
sequence_plans, gen_data_clean, cond_tokens, uncond_tokens, initial_noise = self.prepare_inference_data(
use_system_prompt,
prompt=prompt,
negative_prompt=negative_prompt,
image=image,
num_frames=num_frames,
height=height,
width=width,
fps=fps,
condition_frame_indexes=condition_frame_indexes,
noises=noises,
generator=generator,
device=device,
dtype=dtype,
)
assert guidance != 1.0, "Guidance weight must be != 1.0"
device = initial_noise.device
self.scheduler.set_timesteps(num_steps, device=device)
timesteps = self.scheduler.timesteps
# print(f"sigmas: first={self.scheduler.sigmas[0].item():.4f} last={self.scheduler.sigmas[-2].item():.4f}")
# print(f"timesteps: first={timesteps[0].item():.2f} last={timesteps[-1].item():.2f}")
# print(f"timestep_scale: {timestep_scale}")
# breakpoint()
latent = initial_noise
include_eog = self.derive_include_end_of_generation_token(joint_attn_implementation)
# --- Denoising loop ---
print("Running generate_samples_from_batch …")
for timestep in tqdm(timesteps, desc="Denoising"):
velocity_pred = self.get_cfg_velocity(
latent,
timestep.reshape(1, 1),
guidance,
gen_data_clean,
sequence_plans,
cond_tokens,
uncond_tokens,
include_eog,
hidden_size,
latent_patch_size,
latent_channel,
patch_latent_dim,
timestep_scale,
num_heads,
head_dim,
num_hidden_layers,
use_moe,
joint_attn_implementation,
device=device,
dtype=dtype,
)
latent = self.scheduler.step(
model_output=velocity_pred,
timestep=timestep,
sample=latent.unsqueeze(0),
return_dict=False,
)[0].squeeze(0)
# --- Extract vision results ---
num_vision_items = gen_data_clean.num_vision_items_per_sample
n_vis = num_vision_items[0] if num_vision_items is not None else 1
result_vision: list[torch.Tensor] = []
offset = 0
for j in range(n_vis):
vision_shape = gen_data_clean.x0_tokens_vision[j].shape
vision_dim = int(torch.prod(torch.tensor(vision_shape)))
if j == n_vis - 1:
result_vision.append(latent[offset : offset + vision_dim].reshape(vision_shape))
offset += vision_dim
if output_type == "latent":
return result_vision
return self.decode_latents(result_vision)
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