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#
# Copyright 2023 The HuggingFace Inc. team.
# SPDX-FileCopyrightText: Copyright (c) 1993-2023 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 gc
import os
from collections import OrderedDict
from copy import copy
from typing import List, Optional, Union
import numpy as np
import onnx
import onnx_graphsurgeon as gs
import PIL
import tensorrt as trt
import torch
from huggingface_hub import snapshot_download
from onnx import shape_inference
from polygraphy import cuda
from polygraphy.backend.common import bytes_from_path
from polygraphy.backend.onnx.loader import fold_constants
from polygraphy.backend.trt import (
CreateConfig,
Profile,
engine_from_bytes,
engine_from_network,
network_from_onnx_path,
save_engine,
)
from polygraphy.backend.trt import util as trt_util
from transformers import CLIPFeatureExtractor, CLIPTextModel, CLIPTokenizer
from diffusers.models import AutoencoderKL, UNet2DConditionModel
from diffusers.pipelines.stable_diffusion import (
StableDiffusionInpaintPipeline,
StableDiffusionPipelineOutput,
StableDiffusionSafetyChecker,
)
from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion_inpaint import prepare_mask_and_masked_image
from diffusers.schedulers import DDIMScheduler
from diffusers.utils import DIFFUSERS_CACHE, logging
"""
Installation instructions
python3 -m pip install --upgrade transformers diffusers>=0.16.0
python3 -m pip install --upgrade tensorrt>=8.6.1
python3 -m pip install --upgrade polygraphy>=0.47.0 onnx-graphsurgeon --extra-index-url https://pypi.ngc.nvidia.com
python3 -m pip install onnxruntime
"""
TRT_LOGGER = trt.Logger(trt.Logger.ERROR)
logger = logging.get_logger(__name__) # pylint: disable=invalid-name
# Map of numpy dtype -> torch dtype
numpy_to_torch_dtype_dict = {
np.uint8: torch.uint8,
np.int8: torch.int8,
np.int16: torch.int16,
np.int32: torch.int32,
np.int64: torch.int64,
np.float16: torch.float16,
np.float32: torch.float32,
np.float64: torch.float64,
np.complex64: torch.complex64,
np.complex128: torch.complex128,
}
if np.version.full_version >= "1.24.0":
numpy_to_torch_dtype_dict[np.bool_] = torch.bool
else:
numpy_to_torch_dtype_dict[np.bool] = torch.bool
# Map of torch dtype -> numpy dtype
torch_to_numpy_dtype_dict = {value: key for (key, value) in numpy_to_torch_dtype_dict.items()}
def device_view(t):
return cuda.DeviceView(ptr=t.data_ptr(), shape=t.shape, dtype=torch_to_numpy_dtype_dict[t.dtype])
def preprocess_image(image):
"""
image: torch.Tensor
"""
w, h = image.size
w, h = (x - x % 32 for x in (w, h)) # resize to integer multiple of 32
image = image.resize((w, h))
image = np.array(image).astype(np.float32) / 255.0
image = image[None].transpose(0, 3, 1, 2)
image = torch.from_numpy(image).contiguous()
return 2.0 * image - 1.0
class Engine:
def __init__(self, engine_path):
self.engine_path = engine_path
self.engine = None
self.context = None
self.buffers = OrderedDict()
self.tensors = OrderedDict()
def __del__(self):
[buf.free() for buf in self.buffers.values() if isinstance(buf, cuda.DeviceArray)]
del self.engine
del self.context
del self.buffers
del self.tensors
def build(
self,
onnx_path,
fp16,
input_profile=None,
enable_preview=False,
enable_all_tactics=False,
timing_cache=None,
workspace_size=0,
):
logger.warning(f"Building TensorRT engine for {onnx_path}: {self.engine_path}")
p = Profile()
if input_profile:
for name, dims in input_profile.items():
assert len(dims) == 3
p.add(name, min=dims[0], opt=dims[1], max=dims[2])
config_kwargs = {}
config_kwargs["preview_features"] = [trt.PreviewFeature.DISABLE_EXTERNAL_TACTIC_SOURCES_FOR_CORE_0805]
if enable_preview:
# Faster dynamic shapes made optional since it increases engine build time.
config_kwargs["preview_features"].append(trt.PreviewFeature.FASTER_DYNAMIC_SHAPES_0805)
if workspace_size > 0:
config_kwargs["memory_pool_limits"] = {trt.MemoryPoolType.WORKSPACE: workspace_size}
if not enable_all_tactics:
config_kwargs["tactic_sources"] = []
engine = engine_from_network(
network_from_onnx_path(onnx_path, flags=[trt.OnnxParserFlag.NATIVE_INSTANCENORM]),
config=CreateConfig(fp16=fp16, profiles=[p], load_timing_cache=timing_cache, **config_kwargs),
save_timing_cache=timing_cache,
)
save_engine(engine, path=self.engine_path)
def load(self):
logger.warning(f"Loading TensorRT engine: {self.engine_path}")
self.engine = engine_from_bytes(bytes_from_path(self.engine_path))
def activate(self):
self.context = self.engine.create_execution_context()
def allocate_buffers(self, shape_dict=None, device="cuda"):
for idx in range(trt_util.get_bindings_per_profile(self.engine)):
binding = self.engine[idx]
if shape_dict and binding in shape_dict:
shape = shape_dict[binding]
else:
shape = self.engine.get_binding_shape(binding)
dtype = trt.nptype(self.engine.get_binding_dtype(binding))
if self.engine.binding_is_input(binding):
self.context.set_binding_shape(idx, shape)
tensor = torch.empty(tuple(shape), dtype=numpy_to_torch_dtype_dict[dtype]).to(device=device)
self.tensors[binding] = tensor
self.buffers[binding] = cuda.DeviceView(ptr=tensor.data_ptr(), shape=shape, dtype=dtype)
def infer(self, feed_dict, stream):
start_binding, end_binding = trt_util.get_active_profile_bindings(self.context)
# shallow copy of ordered dict
device_buffers = copy(self.buffers)
for name, buf in feed_dict.items():
assert isinstance(buf, cuda.DeviceView)
device_buffers[name] = buf
bindings = [0] * start_binding + [buf.ptr for buf in device_buffers.values()]
noerror = self.context.execute_async_v2(bindings=bindings, stream_handle=stream.ptr)
if not noerror:
raise ValueError("ERROR: inference failed.")
return self.tensors
class Optimizer:
def __init__(self, onnx_graph):
self.graph = gs.import_onnx(onnx_graph)
def cleanup(self, return_onnx=False):
self.graph.cleanup().toposort()
if return_onnx:
return gs.export_onnx(self.graph)
def select_outputs(self, keep, names=None):
self.graph.outputs = [self.graph.outputs[o] for o in keep]
if names:
for i, name in enumerate(names):
self.graph.outputs[i].name = name
def fold_constants(self, return_onnx=False):
onnx_graph = fold_constants(gs.export_onnx(self.graph), allow_onnxruntime_shape_inference=True)
self.graph = gs.import_onnx(onnx_graph)
if return_onnx:
return onnx_graph
def infer_shapes(self, return_onnx=False):
onnx_graph = gs.export_onnx(self.graph)
if onnx_graph.ByteSize() > 2147483648:
raise TypeError("ERROR: model size exceeds supported 2GB limit")
else:
onnx_graph = shape_inference.infer_shapes(onnx_graph)
self.graph = gs.import_onnx(onnx_graph)
if return_onnx:
return onnx_graph
class BaseModel:
def __init__(self, model, fp16=False, device="cuda", max_batch_size=16, embedding_dim=768, text_maxlen=77):
self.model = model
self.name = "SD Model"
self.fp16 = fp16
self.device = device
self.min_batch = 1
self.max_batch = max_batch_size
self.min_image_shape = 256 # min image resolution: 256x256
self.max_image_shape = 1024 # max image resolution: 1024x1024
self.min_latent_shape = self.min_image_shape // 8
self.max_latent_shape = self.max_image_shape // 8
self.embedding_dim = embedding_dim
self.text_maxlen = text_maxlen
def get_model(self):
return self.model
def get_input_names(self):
pass
def get_output_names(self):
pass
def get_dynamic_axes(self):
return None
def get_sample_input(self, batch_size, image_height, image_width):
pass
def get_input_profile(self, batch_size, image_height, image_width, static_batch, static_shape):
return None
def get_shape_dict(self, batch_size, image_height, image_width):
return None
def optimize(self, onnx_graph):
opt = Optimizer(onnx_graph)
opt.cleanup()
opt.fold_constants()
opt.infer_shapes()
onnx_opt_graph = opt.cleanup(return_onnx=True)
return onnx_opt_graph
def check_dims(self, batch_size, image_height, image_width):
assert batch_size >= self.min_batch and batch_size <= self.max_batch
assert image_height % 8 == 0 or image_width % 8 == 0
latent_height = image_height // 8
latent_width = image_width // 8
assert latent_height >= self.min_latent_shape and latent_height <= self.max_latent_shape
assert latent_width >= self.min_latent_shape and latent_width <= self.max_latent_shape
return (latent_height, latent_width)
def get_minmax_dims(self, batch_size, image_height, image_width, static_batch, static_shape):
min_batch = batch_size if static_batch else self.min_batch
max_batch = batch_size if static_batch else self.max_batch
latent_height = image_height // 8
latent_width = image_width // 8
min_image_height = image_height if static_shape else self.min_image_shape
max_image_height = image_height if static_shape else self.max_image_shape
min_image_width = image_width if static_shape else self.min_image_shape
max_image_width = image_width if static_shape else self.max_image_shape
min_latent_height = latent_height if static_shape else self.min_latent_shape
max_latent_height = latent_height if static_shape else self.max_latent_shape
min_latent_width = latent_width if static_shape else self.min_latent_shape
max_latent_width = latent_width if static_shape else self.max_latent_shape
return (
min_batch,
max_batch,
min_image_height,
max_image_height,
min_image_width,
max_image_width,
min_latent_height,
max_latent_height,
min_latent_width,
max_latent_width,
)
def getOnnxPath(model_name, onnx_dir, opt=True):
return os.path.join(onnx_dir, model_name + (".opt" if opt else "") + ".onnx")
def getEnginePath(model_name, engine_dir):
return os.path.join(engine_dir, model_name + ".plan")
def build_engines(
models: dict,
engine_dir,
onnx_dir,
onnx_opset,
opt_image_height,
opt_image_width,
opt_batch_size=1,
force_engine_rebuild=False,
static_batch=False,
static_shape=True,
enable_preview=False,
enable_all_tactics=False,
timing_cache=None,
max_workspace_size=0,
):
built_engines = {}
if not os.path.isdir(onnx_dir):
os.makedirs(onnx_dir)
if not os.path.isdir(engine_dir):
os.makedirs(engine_dir)
# Export models to ONNX
for model_name, model_obj in models.items():
engine_path = getEnginePath(model_name, engine_dir)
if force_engine_rebuild or not os.path.exists(engine_path):
logger.warning("Building Engines...")
logger.warning("Engine build can take a while to complete")
onnx_path = getOnnxPath(model_name, onnx_dir, opt=False)
onnx_opt_path = getOnnxPath(model_name, onnx_dir)
if force_engine_rebuild or not os.path.exists(onnx_opt_path):
if force_engine_rebuild or not os.path.exists(onnx_path):
logger.warning(f"Exporting model: {onnx_path}")
model = model_obj.get_model()
with torch.inference_mode(), torch.autocast("cuda"):
inputs = model_obj.get_sample_input(opt_batch_size, opt_image_height, opt_image_width)
torch.onnx.export(
model,
inputs,
onnx_path,
export_params=True,
opset_version=onnx_opset,
do_constant_folding=True,
input_names=model_obj.get_input_names(),
output_names=model_obj.get_output_names(),
dynamic_axes=model_obj.get_dynamic_axes(),
)
del model
torch.cuda.empty_cache()
gc.collect()
else:
logger.warning(f"Found cached model: {onnx_path}")
# Optimize onnx
if force_engine_rebuild or not os.path.exists(onnx_opt_path):
logger.warning(f"Generating optimizing model: {onnx_opt_path}")
onnx_opt_graph = model_obj.optimize(onnx.load(onnx_path))
onnx.save(onnx_opt_graph, onnx_opt_path)
else:
logger.warning(f"Found cached optimized model: {onnx_opt_path} ")
# Build TensorRT engines
for model_name, model_obj in models.items():
engine_path = getEnginePath(model_name, engine_dir)
engine = Engine(engine_path)
onnx_path = getOnnxPath(model_name, onnx_dir, opt=False)
onnx_opt_path = getOnnxPath(model_name, onnx_dir)
if force_engine_rebuild or not os.path.exists(engine.engine_path):
engine.build(
onnx_opt_path,
fp16=True,
input_profile=model_obj.get_input_profile(
opt_batch_size,
opt_image_height,
opt_image_width,
static_batch=static_batch,
static_shape=static_shape,
),
enable_preview=enable_preview,
timing_cache=timing_cache,
workspace_size=max_workspace_size,
)
built_engines[model_name] = engine
# Load and activate TensorRT engines
for model_name, model_obj in models.items():
engine = built_engines[model_name]
engine.load()
engine.activate()
return built_engines
def runEngine(engine, feed_dict, stream):
return engine.infer(feed_dict, stream)
class CLIP(BaseModel):
def __init__(self, model, device, max_batch_size, embedding_dim):
super(CLIP, self).__init__(
model=model, device=device, max_batch_size=max_batch_size, embedding_dim=embedding_dim
)
self.name = "CLIP"
def get_input_names(self):
return ["input_ids"]
def get_output_names(self):
return ["text_embeddings", "pooler_output"]
def get_dynamic_axes(self):
return {"input_ids": {0: "B"}, "text_embeddings": {0: "B"}}
def get_input_profile(self, batch_size, image_height, image_width, static_batch, static_shape):
self.check_dims(batch_size, image_height, image_width)
min_batch, max_batch, _, _, _, _, _, _, _, _ = self.get_minmax_dims(
batch_size, image_height, image_width, static_batch, static_shape
)
return {
"input_ids": [(min_batch, self.text_maxlen), (batch_size, self.text_maxlen), (max_batch, self.text_maxlen)]
}
def get_shape_dict(self, batch_size, image_height, image_width):
self.check_dims(batch_size, image_height, image_width)
return {
"input_ids": (batch_size, self.text_maxlen),
"text_embeddings": (batch_size, self.text_maxlen, self.embedding_dim),
}
def get_sample_input(self, batch_size, image_height, image_width):
self.check_dims(batch_size, image_height, image_width)
return torch.zeros(batch_size, self.text_maxlen, dtype=torch.int32, device=self.device)
def optimize(self, onnx_graph):
opt = Optimizer(onnx_graph)
opt.select_outputs([0]) # delete graph output#1
opt.cleanup()
opt.fold_constants()
opt.infer_shapes()
opt.select_outputs([0], names=["text_embeddings"]) # rename network output
opt_onnx_graph = opt.cleanup(return_onnx=True)
return opt_onnx_graph
def make_CLIP(model, device, max_batch_size, embedding_dim, inpaint=False):
return CLIP(model, device=device, max_batch_size=max_batch_size, embedding_dim=embedding_dim)
class UNet(BaseModel):
def __init__(
self, model, fp16=False, device="cuda", max_batch_size=16, embedding_dim=768, text_maxlen=77, unet_dim=4
):
super(UNet, self).__init__(
model=model,
fp16=fp16,
device=device,
max_batch_size=max_batch_size,
embedding_dim=embedding_dim,
text_maxlen=text_maxlen,
)
self.unet_dim = unet_dim
self.name = "UNet"
def get_input_names(self):
return ["sample", "timestep", "encoder_hidden_states"]
def get_output_names(self):
return ["latent"]
def get_dynamic_axes(self):
return {
"sample": {0: "2B", 2: "H", 3: "W"},
"encoder_hidden_states": {0: "2B"},
"latent": {0: "2B", 2: "H", 3: "W"},
}
def get_input_profile(self, batch_size, image_height, image_width, static_batch, static_shape):
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)
return {
"sample": [
(2 * min_batch, self.unet_dim, min_latent_height, min_latent_width),
(2 * batch_size, self.unet_dim, latent_height, latent_width),
(2 * max_batch, self.unet_dim, max_latent_height, max_latent_width),
],
"encoder_hidden_states": [
(2 * min_batch, self.text_maxlen, self.embedding_dim),
(2 * batch_size, self.text_maxlen, self.embedding_dim),
(2 * max_batch, self.text_maxlen, self.embedding_dim),
],
}
def get_shape_dict(self, batch_size, image_height, image_width):
latent_height, latent_width = self.check_dims(batch_size, image_height, image_width)
return {
"sample": (2 * batch_size, self.unet_dim, latent_height, latent_width),
"encoder_hidden_states": (2 * batch_size, self.text_maxlen, self.embedding_dim),
"latent": (2 * batch_size, 4, latent_height, latent_width),
}
def get_sample_input(self, batch_size, image_height, image_width):
latent_height, latent_width = self.check_dims(batch_size, image_height, image_width)
dtype = torch.float16 if self.fp16 else torch.float32
return (
torch.randn(
2 * batch_size, self.unet_dim, latent_height, latent_width, dtype=torch.float32, device=self.device
),
torch.tensor([1.0], dtype=torch.float32, device=self.device),
torch.randn(2 * batch_size, self.text_maxlen, self.embedding_dim, dtype=dtype, device=self.device),
)
def make_UNet(model, device, max_batch_size, embedding_dim, inpaint=False, unet_dim=4):
return UNet(
model,
fp16=True,
device=device,
max_batch_size=max_batch_size,
embedding_dim=embedding_dim,
unet_dim=unet_dim,
)
class VAE(BaseModel):
def __init__(self, model, device, max_batch_size, embedding_dim):
super(VAE, self).__init__(
model=model, device=device, max_batch_size=max_batch_size, embedding_dim=embedding_dim
)
self.name = "VAE decoder"
def get_input_names(self):
return ["latent"]
def get_output_names(self):
return ["images"]
def get_dynamic_axes(self):
return {"latent": {0: "B", 2: "H", 3: "W"}, "images": {0: "B", 2: "8H", 3: "8W"}}
def get_input_profile(self, batch_size, image_height, image_width, static_batch, static_shape):
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)
return {
"latent": [
(min_batch, 4, min_latent_height, min_latent_width),
(batch_size, 4, latent_height, latent_width),
(max_batch, 4, max_latent_height, max_latent_width),
]
}
def get_shape_dict(self, batch_size, image_height, image_width):
latent_height, latent_width = self.check_dims(batch_size, image_height, image_width)
return {
"latent": (batch_size, 4, latent_height, latent_width),
"images": (batch_size, 3, image_height, image_width),
}
def get_sample_input(self, batch_size, image_height, image_width):
latent_height, latent_width = self.check_dims(batch_size, image_height, image_width)
return torch.randn(batch_size, 4, latent_height, latent_width, dtype=torch.float32, device=self.device)
def make_VAE(model, device, max_batch_size, embedding_dim, inpaint=False):
return VAE(model, device=device, max_batch_size=max_batch_size, embedding_dim=embedding_dim)
class TorchVAEEncoder(torch.nn.Module):
def __init__(self, model):
super().__init__()
self.vae_encoder = model
def forward(self, x):
return self.vae_encoder.encode(x).latent_dist.sample()
class VAEEncoder(BaseModel):
def __init__(self, model, device, max_batch_size, embedding_dim):
super(VAEEncoder, self).__init__(
model=model, device=device, max_batch_size=max_batch_size, embedding_dim=embedding_dim
)
self.name = "VAE encoder"
def get_model(self):
vae_encoder = TorchVAEEncoder(self.model)
return vae_encoder
def get_input_names(self):
return ["images"]
def get_output_names(self):
return ["latent"]
def get_dynamic_axes(self):
return {"images": {0: "B", 2: "8H", 3: "8W"}, "latent": {0: "B", 2: "H", 3: "W"}}
def get_input_profile(self, batch_size, image_height, image_width, static_batch, static_shape):
assert batch_size >= self.min_batch and batch_size <= self.max_batch
min_batch = batch_size if static_batch else self.min_batch
max_batch = batch_size if static_batch else self.max_batch
self.check_dims(batch_size, image_height, image_width)
(
min_batch,
max_batch,
min_image_height,
max_image_height,
min_image_width,
max_image_width,
_,
_,
_,
_,
) = self.get_minmax_dims(batch_size, image_height, image_width, static_batch, static_shape)
return {
"images": [
(min_batch, 3, min_image_height, min_image_width),
(batch_size, 3, image_height, image_width),
(max_batch, 3, max_image_height, max_image_width),
]
}
def get_shape_dict(self, batch_size, image_height, image_width):
latent_height, latent_width = self.check_dims(batch_size, image_height, image_width)
return {
"images": (batch_size, 3, image_height, image_width),
"latent": (batch_size, 4, latent_height, latent_width),
}
def get_sample_input(self, batch_size, image_height, image_width):
self.check_dims(batch_size, image_height, image_width)
return torch.randn(batch_size, 3, image_height, image_width, dtype=torch.float32, device=self.device)
def make_VAEEncoder(model, device, max_batch_size, embedding_dim, inpaint=False):
return VAEEncoder(model, device=device, max_batch_size=max_batch_size, embedding_dim=embedding_dim)
class TensorRTStableDiffusionInpaintPipeline(StableDiffusionInpaintPipeline):
r"""
Pipeline for inpainting using TensorRT accelerated Stable Diffusion.
This model inherits from [`StableDiffusionInpaintPipeline`]. Check the superclass documentation for the generic methods the
library implements for all the pipelines (such as downloading or saving, running on a particular device, etc.)
Args:
vae ([`AutoencoderKL`]):
Variational Auto-Encoder (VAE) Model to encode and decode images to and from latent representations.
text_encoder ([`CLIPTextModel`]):
Frozen text-encoder. Stable Diffusion uses the text portion of
[CLIP](https://huggingface.co/docs/transformers/model_doc/clip#transformers.CLIPTextModel), specifically
the [clip-vit-large-patch14](https://huggingface.co/openai/clip-vit-large-patch14) variant.
tokenizer (`CLIPTokenizer`):
Tokenizer of class
[CLIPTokenizer](https://huggingface.co/docs/transformers/v4.21.0/en/model_doc/clip#transformers.CLIPTokenizer).
unet ([`UNet2DConditionModel`]): Conditional U-Net architecture to denoise the encoded image latents.
scheduler ([`SchedulerMixin`]):
A scheduler to be used in combination with `unet` to denoise the encoded image latents. Can be one of
[`DDIMScheduler`], [`LMSDiscreteScheduler`], or [`PNDMScheduler`].
safety_checker ([`StableDiffusionSafetyChecker`]):
Classification module that estimates whether generated images could be considered offensive or harmful.
Please, refer to the [model card](https://huggingface.co/runwayml/stable-diffusion-v1-5) for details.
feature_extractor ([`CLIPFeatureExtractor`]):
Model that extracts features from generated images to be used as inputs for the `safety_checker`.
"""
def __init__(
self,
vae: AutoencoderKL,
text_encoder: CLIPTextModel,
tokenizer: CLIPTokenizer,
unet: UNet2DConditionModel,
scheduler: DDIMScheduler,
safety_checker: StableDiffusionSafetyChecker,
feature_extractor: CLIPFeatureExtractor,
requires_safety_checker: bool = True,
stages=["clip", "unet", "vae", "vae_encoder"],
image_height: int = 512,
image_width: int = 512,
max_batch_size: int = 16,
# ONNX export parameters
onnx_opset: int = 17,
onnx_dir: str = "onnx",
# TensorRT engine build parameters
engine_dir: str = "engine",
build_preview_features: bool = True,
force_engine_rebuild: bool = False,
timing_cache: str = "timing_cache",
):
super().__init__(
vae, text_encoder, tokenizer, unet, scheduler, safety_checker, feature_extractor, requires_safety_checker
)
self.vae.forward = self.vae.decode
self.stages = stages
self.image_height, self.image_width = image_height, image_width
self.inpaint = True
self.onnx_opset = onnx_opset
self.onnx_dir = onnx_dir
self.engine_dir = engine_dir
self.force_engine_rebuild = force_engine_rebuild
self.timing_cache = timing_cache
self.build_static_batch = False
self.build_dynamic_shape = False
self.build_preview_features = build_preview_features
self.max_batch_size = max_batch_size
# TODO: Restrict batch size to 4 for larger image dimensions as a WAR for TensorRT limitation.
if self.build_dynamic_shape or self.image_height > 512 or self.image_width > 512:
self.max_batch_size = 4
self.stream = None # loaded in loadResources()
self.models = {} # loaded in __loadModels()
self.engine = {} # loaded in build_engines()
def __loadModels(self):
# Load pipeline models
self.embedding_dim = self.text_encoder.config.hidden_size
models_args = {
"device": self.torch_device,
"max_batch_size": self.max_batch_size,
"embedding_dim": self.embedding_dim,
"inpaint": self.inpaint,
}
if "clip" in self.stages:
self.models["clip"] = make_CLIP(self.text_encoder, **models_args)
if "unet" in self.stages:
self.models["unet"] = make_UNet(self.unet, **models_args, unet_dim=self.unet.config.in_channels)
if "vae" in self.stages:
self.models["vae"] = make_VAE(self.vae, **models_args)
if "vae_encoder" in self.stages:
self.models["vae_encoder"] = make_VAEEncoder(self.vae, **models_args)
@classmethod
def set_cached_folder(cls, pretrained_model_name_or_path: Optional[Union[str, os.PathLike]], **kwargs):
cache_dir = kwargs.pop("cache_dir", DIFFUSERS_CACHE)
resume_download = kwargs.pop("resume_download", False)
proxies = kwargs.pop("proxies", None)
local_files_only = kwargs.pop("local_files_only", False)
use_auth_token = kwargs.pop("use_auth_token", None)
revision = kwargs.pop("revision", None)
cls.cached_folder = (
pretrained_model_name_or_path
if os.path.isdir(pretrained_model_name_or_path)
else snapshot_download(
pretrained_model_name_or_path,
cache_dir=cache_dir,
resume_download=resume_download,
proxies=proxies,
local_files_only=local_files_only,
use_auth_token=use_auth_token,
revision=revision,
)
)
def to(self, torch_device: Optional[Union[str, torch.device]] = None, silence_dtype_warnings: bool = False):
super().to(torch_device, silence_dtype_warnings=silence_dtype_warnings)
self.onnx_dir = os.path.join(self.cached_folder, self.onnx_dir)
self.engine_dir = os.path.join(self.cached_folder, self.engine_dir)
self.timing_cache = os.path.join(self.cached_folder, self.timing_cache)
# set device
self.torch_device = self._execution_device
logger.warning(f"Running inference on device: {self.torch_device}")
# load models
self.__loadModels()
# build engines
self.engine = build_engines(
self.models,
self.engine_dir,
self.onnx_dir,
self.onnx_opset,
opt_image_height=self.image_height,
opt_image_width=self.image_width,
force_engine_rebuild=self.force_engine_rebuild,
static_batch=self.build_static_batch,
static_shape=not self.build_dynamic_shape,
enable_preview=self.build_preview_features,
timing_cache=self.timing_cache,
)
return self
def __initialize_timesteps(self, num_inference_steps, strength):
self.scheduler.set_timesteps(num_inference_steps)
offset = self.scheduler.config.steps_offset if hasattr(self.scheduler, "steps_offset") else 0
init_timestep = int(num_inference_steps * strength) + offset
init_timestep = min(init_timestep, num_inference_steps)
t_start = max(num_inference_steps - init_timestep + offset, 0)
timesteps = self.scheduler.timesteps[t_start * self.scheduler.order :].to(self.torch_device)
return timesteps, num_inference_steps - t_start
def __preprocess_images(self, batch_size, images=()):
init_images = []
for image in images:
image = image.to(self.torch_device).float()
image = image.repeat(batch_size, 1, 1, 1)
init_images.append(image)
return tuple(init_images)
def __encode_image(self, init_image):
init_latents = runEngine(self.engine["vae_encoder"], {"images": device_view(init_image)}, self.stream)[
"latent"
]
init_latents = 0.18215 * init_latents
return init_latents
def __encode_prompt(self, prompt, negative_prompt):
r"""
Encodes the prompt into text encoder hidden states.
Args:
prompt (`str` or `List[str]`, *optional*):
prompt to be encoded
negative_prompt (`str` or `List[str]`, *optional*):
The prompt or prompts not to guide the image generation. If not defined, one has to pass
`negative_prompt_embeds`. instead. If not defined, one has to pass `negative_prompt_embeds`. instead.
Ignored when not using guidance (i.e., ignored if `guidance_scale` is less than `1`).
"""
# Tokenize prompt
text_input_ids = (
self.tokenizer(
prompt,
padding="max_length",
max_length=self.tokenizer.model_max_length,
truncation=True,
return_tensors="pt",
)
.input_ids.type(torch.int32)
.to(self.torch_device)
)
text_input_ids_inp = device_view(text_input_ids)
# NOTE: output tensor for CLIP must be cloned because it will be overwritten when called again for negative prompt
text_embeddings = runEngine(self.engine["clip"], {"input_ids": text_input_ids_inp}, self.stream)[
"text_embeddings"
].clone()
# Tokenize negative prompt
uncond_input_ids = (
self.tokenizer(
negative_prompt,
padding="max_length",
max_length=self.tokenizer.model_max_length,
truncation=True,
return_tensors="pt",
)
.input_ids.type(torch.int32)
.to(self.torch_device)
)
uncond_input_ids_inp = device_view(uncond_input_ids)
uncond_embeddings = runEngine(self.engine["clip"], {"input_ids": uncond_input_ids_inp}, self.stream)[
"text_embeddings"
]
# Concatenate the unconditional and text embeddings into a single batch to avoid doing two forward passes for classifier free guidance
text_embeddings = torch.cat([uncond_embeddings, text_embeddings]).to(dtype=torch.float16)
return text_embeddings
def __denoise_latent(
self, latents, text_embeddings, timesteps=None, step_offset=0, mask=None, masked_image_latents=None
):
if not isinstance(timesteps, torch.Tensor):
timesteps = self.scheduler.timesteps
for step_index, timestep in enumerate(timesteps):
# Expand the latents if we are doing classifier free guidance
latent_model_input = torch.cat([latents] * 2)
latent_model_input = self.scheduler.scale_model_input(latent_model_input, timestep)
if isinstance(mask, torch.Tensor):
latent_model_input = torch.cat([latent_model_input, mask, masked_image_latents], dim=1)
# Predict the noise residual
timestep_float = timestep.float() if timestep.dtype != torch.float32 else timestep
sample_inp = device_view(latent_model_input)
timestep_inp = device_view(timestep_float)
embeddings_inp = device_view(text_embeddings)
noise_pred = runEngine(
self.engine["unet"],
{"sample": sample_inp, "timestep": timestep_inp, "encoder_hidden_states": embeddings_inp},
self.stream,
)["latent"]
# Perform guidance
noise_pred_uncond, noise_pred_text = noise_pred.chunk(2)
noise_pred = noise_pred_uncond + self.guidance_scale * (noise_pred_text - noise_pred_uncond)
latents = self.scheduler.step(noise_pred, timestep, latents).prev_sample
latents = 1.0 / 0.18215 * latents
return latents
def __decode_latent(self, latents):
images = runEngine(self.engine["vae"], {"latent": device_view(latents)}, self.stream)["images"]
images = (images / 2 + 0.5).clamp(0, 1)
return images.cpu().permute(0, 2, 3, 1).float().numpy()
def __loadResources(self, image_height, image_width, batch_size):
self.stream = cuda.Stream()
# Allocate buffers for TensorRT engine bindings
for model_name, obj in self.models.items():
self.engine[model_name].allocate_buffers(
shape_dict=obj.get_shape_dict(batch_size, image_height, image_width), device=self.torch_device
)
@torch.no_grad()
def __call__(
self,
prompt: Union[str, List[str]] = None,
image: Union[torch.FloatTensor, PIL.Image.Image] = None,
mask_image: Union[torch.FloatTensor, PIL.Image.Image] = None,
strength: float = 1.0,
num_inference_steps: int = 50,
guidance_scale: float = 7.5,
negative_prompt: Optional[Union[str, List[str]]] = None,
generator: Optional[Union[torch.Generator, List[torch.Generator]]] = None,
):
r"""
Function invoked when calling the pipeline for generation.
Args:
prompt (`str` or `List[str]`, *optional*):
The prompt or prompts to guide the image generation. If not defined, one has to pass `prompt_embeds`.
instead.
image (`PIL.Image.Image`):
`Image`, or tensor representing an image batch which will be inpainted, *i.e.* parts of the image will
be masked out with `mask_image` and repainted according to `prompt`.
mask_image (`PIL.Image.Image`):
`Image`, or tensor representing an image batch, to mask `image`. White pixels in the mask will be
repainted, while black pixels will be preserved. If `mask_image` is a PIL image, it will be converted
to a single channel (luminance) before use. If it's a tensor, it should contain one color channel (L)
instead of 3, so the expected shape would be `(B, H, W, 1)`.
strength (`float`, *optional*, defaults to 0.8):
Conceptually, indicates how much to transform the reference `image`. Must be between 0 and 1. `image`
will be used as a starting point, adding more noise to it the larger the `strength`. The number of
denoising steps depends on the amount of noise initially added. When `strength` is 1, added noise will
be maximum and the denoising process will run for the full number of iterations specified in
`num_inference_steps`. A value of 1, therefore, essentially ignores `image`.
num_inference_steps (`int`, *optional*, defaults to 50):
The number of denoising steps. More denoising steps usually lead to a higher quality image at the
expense of slower inference.
guidance_scale (`float`, *optional*, defaults to 7.5):
Guidance scale as defined in [Classifier-Free Diffusion Guidance](https://arxiv.org/abs/2207.12598).
`guidance_scale` is defined as `w` of equation 2. of [Imagen
Paper](https://arxiv.org/pdf/2205.11487.pdf). Guidance scale is enabled by setting `guidance_scale >
1`. Higher guidance scale encourages to generate images that are closely linked to the text `prompt`,
usually at the expense of lower image quality.
negative_prompt (`str` or `List[str]`, *optional*):
The prompt or prompts not to guide the image generation. If not defined, one has to pass
`negative_prompt_embeds`. instead. If not defined, one has to pass `negative_prompt_embeds`. instead.
Ignored when not using guidance (i.e., ignored if `guidance_scale` is less than `1`).
generator (`torch.Generator` or `List[torch.Generator]`, *optional*):
One or a list of [torch generator(s)](https://pytorch.org/docs/stable/generated/torch.Generator.html)
to make generation deterministic.
"""
self.generator = generator
self.denoising_steps = num_inference_steps
self.guidance_scale = guidance_scale
# Pre-compute latent input scales and linear multistep coefficients
self.scheduler.set_timesteps(self.denoising_steps, device=self.torch_device)
# Define call parameters
if prompt is not None and isinstance(prompt, str):
batch_size = 1
prompt = [prompt]
elif prompt is not None and isinstance(prompt, list):
batch_size = len(prompt)
else:
raise ValueError(f"Expected prompt to be of type list or str but got {type(prompt)}")
if negative_prompt is None:
negative_prompt = [""] * batch_size
if negative_prompt is not None and isinstance(negative_prompt, str):
negative_prompt = [negative_prompt]
assert len(prompt) == len(negative_prompt)
if batch_size > self.max_batch_size:
raise ValueError(
f"Batch size {len(prompt)} is larger than allowed {self.max_batch_size}. If dynamic shape is used, then maximum batch size is 4"
)
# Validate image dimensions
mask_width, mask_height = mask_image.size
if mask_height != self.image_height or mask_width != self.image_width:
raise ValueError(
f"Input image height and width {self.image_height} and {self.image_width} are not equal to "
f"the respective dimensions of the mask image {mask_height} and {mask_width}"
)
# load resources
self.__loadResources(self.image_height, self.image_width, batch_size)
with torch.inference_mode(), torch.autocast("cuda"), trt.Runtime(TRT_LOGGER):
# Spatial dimensions of latent tensor
latent_height = self.image_height // 8
latent_width = self.image_width // 8
# Pre-process input images
mask, masked_image, init_image = self.__preprocess_images(
batch_size,
prepare_mask_and_masked_image(
image,
mask_image,
self.image_height,
self.image_width,
return_image=True,
),
)
mask = torch.nn.functional.interpolate(mask, size=(latent_height, latent_width))
mask = torch.cat([mask] * 2)
# Initialize timesteps
timesteps, t_start = self.__initialize_timesteps(self.denoising_steps, strength)
# at which timestep to set the initial noise (n.b. 50% if strength is 0.5)
latent_timestep = timesteps[:1].repeat(batch_size)
# create a boolean to check if the strength is set to 1. if so then initialise the latents with pure noise
is_strength_max = strength == 1.0
# Pre-initialize latents
num_channels_latents = self.vae.config.latent_channels
latents_outputs = self.prepare_latents(
batch_size,
num_channels_latents,
self.image_height,
self.image_width,
torch.float32,
self.torch_device,
generator,
image=init_image,
timestep=latent_timestep,
is_strength_max=is_strength_max,
)
latents = latents_outputs[0]
# VAE encode masked image
masked_latents = self.__encode_image(masked_image)
masked_latents = torch.cat([masked_latents] * 2)
# CLIP text encoder
text_embeddings = self.__encode_prompt(prompt, negative_prompt)
# UNet denoiser
latents = self.__denoise_latent(
latents,
text_embeddings,
timesteps=timesteps,
step_offset=t_start,
mask=mask,
masked_image_latents=masked_latents,
)
# VAE decode latent
images = self.__decode_latent(latents)
images = self.numpy_to_pil(images)
return StableDiffusionPipelineOutput(images=images, nsfw_content_detected=None)
|