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chore: import upstream snapshot with attribution
2026-07-13 13:36:55 +08:00

224 lines
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Python

#
# SPDX-FileCopyrightText: Copyright (c) 1993-2025 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
# SPDX-License-Identifier: Apache-2.0
#
# 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 os
import torch
from demo_diffusion.dynamic_import import import_from_diffusers
from demo_diffusion.model import base_model, load, optimizer
# List of models to import from diffusers.models
models_to_import = ["SD3Transformer2DModel", "SD3ControlNetModel"]
for model in models_to_import:
globals()[model] = import_from_diffusers(model, "diffusers.models")
class SD3ControlNetWrapper(torch.nn.Module):
def __init__(self, controlnet):
super().__init__()
self.controlnet = controlnet
def forward(self, hidden_states, controlnet_cond, conditioning_scale, pooled_projections, timestep):
params = {
"hidden_states": hidden_states,
"pooled_projections": pooled_projections,
"timestep": timestep,
"controlnet_cond": controlnet_cond,
"conditioning_scale": conditioning_scale,
}
out = self.controlnet(**params)["controlnet_block_samples"]
return torch.stack(out, dim=0)
class SD3ControlNet(base_model.BaseModel):
def __init__(
self,
version,
controlnet,
pipeline,
device,
hf_token,
verbose,
framework_model_dir,
fp16=False,
tf32=False,
bf16=False,
int8=False,
fp8=False,
max_batch_size=16,
do_classifier_free_guidance=False,
):
super(SD3ControlNet, self).__init__(
version,
pipeline,
device=device,
hf_token=hf_token,
verbose=verbose,
framework_model_dir=framework_model_dir,
fp16=fp16,
tf32=tf32,
bf16=bf16,
int8=int8,
fp8=fp8,
max_batch_size=max_batch_size,
)
self.path = load.get_path(version, pipeline, controlnet)
self.subfolder = "controlnet_{}".format(controlnet)
self.controlnet_model_dir = load.get_checkpoint_dir(
self.framework_model_dir, self.version, self.pipeline, self.subfolder
)
self.transformer_model_dir = load.get_checkpoint_dir(
self.framework_model_dir, self.version, self.pipeline, "transformer"
)
if not os.path.exists(self.controlnet_model_dir):
self.config = SD3ControlNetModel.load_config(self.path, token=self.hf_token)
else:
print(f"[I] Load SD3ControlNetModel config from: {self.controlnet_model_dir}")
self.config = SD3ControlNetModel.load_config(self.controlnet_model_dir)
self.xB = 2 if do_classifier_free_guidance else 1 # batch multiplier
def get_model(self, torch_inference=""):
model_opts = (
{"torch_dtype": torch.float16} if self.fp16 else {"torch_dtype": torch.bfloat16} if self.bf16 else {}
)
if not load.is_model_cached(self.controlnet_model_dir, model_opts, self.hf_safetensor):
model = SD3ControlNetModel.from_pretrained(self.path, **model_opts, use_safetensors=self.hf_safetensor).to(
self.device
)
model.save_pretrained(self.controlnet_model_dir, **model_opts)
else:
print(f"[I] Load SD3ControlNetModel model from: {self.controlnet_model_dir}")
model = SD3ControlNetModel.from_pretrained(self.controlnet_model_dir, **model_opts).to(self.device)
# Load transformer model for pos_embed
transformer = SD3Transformer2DModel.from_pretrained(self.transformer_model_dir, **model_opts).to(self.device)
if hasattr(model.config, "use_pos_embed") and model.config.use_pos_embed is False:
pos_embed = model._get_pos_embed_from_transformer(transformer)
model.pos_embed = pos_embed.to(model.dtype).to(model.device)
# Free transformer model
del transformer
model = optimizer.optimize_checkpoint(model, torch_inference)
model = SD3ControlNetWrapper(model)
return model
def get_input_names(self):
return ["hidden_states", "controlnet_cond", "conditioning_scale", "pooled_projections", "timestep"]
def get_output_names(self):
return ["controlnet_block_samples"]
def get_dynamic_axes(self):
xB = "2B" if self.xB == 2 else "B"
dynamic_axes = {
"hidden_states": {0: xB, 2: "H", 3: "W"},
"controlnet_cond": {0: xB, 2: "H", 3: "W"},
"pooled_projections": {0: xB},
"timestep": {0: xB},
}
return dynamic_axes
def get_input_profile(
self,
batch_size: int,
image_height: int,
image_width: int,
static_batch: bool,
static_shape: bool,
):
latent_height, latent_width = self.check_dims(batch_size, image_height, image_width)
(
min_batch,
max_batch,
_,
_,
_,
_,
min_latent_height,
max_latent_height,
min_latent_width,
max_latent_width,
) = self.get_minmax_dims(batch_size, image_height, image_width, static_batch, static_shape)
input_profile = {
"hidden_states": [
(self.xB * min_batch, self.config["in_channels"], min_latent_height, min_latent_width),
(self.xB * batch_size, self.config["in_channels"], latent_height, latent_width),
(self.xB * max_batch, self.config["in_channels"], max_latent_height, max_latent_width),
],
"timestep": [(self.xB * min_batch,), (self.xB * batch_size,), (self.xB * max_batch,)],
"pooled_projections": [
(self.xB * min_batch, self.config["pooled_projection_dim"]),
(self.xB * batch_size, self.config["pooled_projection_dim"]),
(self.xB * max_batch, self.config["pooled_projection_dim"]),
],
"controlnet_cond": [
(self.xB * min_batch, self.config["in_channels"], min_latent_height, min_latent_width),
(self.xB * batch_size, self.config["in_channels"], latent_height, latent_width),
(self.xB * max_batch, self.config["in_channels"], max_latent_height, max_latent_width),
],
}
return input_profile
def get_shape_dict(self, batch_size, image_height, image_width):
latent_height, latent_width = self.check_dims(batch_size, image_height, image_width)
shape_dict = {
"hidden_states": (self.xB * batch_size, self.config["in_channels"], latent_height, latent_width),
"timestep": (self.xB * batch_size,),
"pooled_projections": (self.xB * batch_size, self.config["pooled_projection_dim"]),
"controlnet_cond": (self.xB * batch_size, self.config["in_channels"], latent_height, latent_width),
"conditioning_scale": (),
"controlnet_block_samples": (
self.config["num_layers"],
self.xB * batch_size,
latent_height // 2 * latent_width // 2,
self.config["num_attention_heads"] * self.config["attention_head_dim"],
),
}
return shape_dict
def get_sample_input(self, batch_size, image_height, image_width, static_shape):
dtype = torch.float16 if self.fp16 else torch.bfloat16 if self.bf16 else torch.float32
latent_height, latent_width = self.check_dims(batch_size, image_height, image_width)
sample_input = (
torch.randn(
self.xB * batch_size,
self.config["in_channels"],
latent_height,
latent_width,
dtype=dtype,
device=self.device,
),
torch.randn(
self.xB * batch_size,
self.config["in_channels"],
latent_height,
latent_width,
dtype=dtype,
device=self.device,
),
torch.tensor(1.0, dtype=dtype, device=self.device),
torch.randn(self.xB * batch_size, self.config["pooled_projection_dim"], dtype=dtype, device=self.device),
torch.randn(self.xB * batch_size, dtype=torch.float32, device=self.device),
)
return sample_input