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ComfyUI-Reactor-Fast-Face-Swap-Codeb-CPU / comfy /model_management.py

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	"""
	This file is part of ComfyUI.
	Copyright (C) 2024 Comfy

	This program is free software: you can redistribute it and/or modify
	it under the terms of the GNU General Public License as published by
	the Free Software Foundation, either version 3 of the License, or
	(at your option) any later version.

	This program is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program. If not, see <https://www.gnu.org/licenses/>.
	"""

	import psutil
	import logging
	from enum import Enum
	from comfy.cli_args import args, PerformanceFeature
	import torch
	import sys
	import importlib
	import platform
	import weakref
	import gc

	class VRAMState(Enum):
	DISABLED = 0 #No vram present: no need to move models to vram
	NO_VRAM = 1 #Very low vram: enable all the options to save vram
	LOW_VRAM = 2
	NORMAL_VRAM = 3
	HIGH_VRAM = 4
	SHARED = 5 #No dedicated vram: memory shared between CPU and GPU but models still need to be moved between both.

	class CPUState(Enum):
	GPU = 0
	CPU = 1
	MPS = 2

	# Determine VRAM State
	vram_state = VRAMState.NORMAL_VRAM
	set_vram_to = VRAMState.NORMAL_VRAM
	cpu_state = CPUState.GPU

	total_vram = 0

	def get_supported_float8_types():
	float8_types = []
	try:
	float8_types.append(torch.float8_e4m3fn)
	except:
	pass
	try:
	float8_types.append(torch.float8_e4m3fnuz)
	except:
	pass
	try:
	float8_types.append(torch.float8_e5m2)
	except:
	pass
	try:
	float8_types.append(torch.float8_e5m2fnuz)
	except:
	pass
	try:
	float8_types.append(torch.float8_e8m0fnu)
	except:
	pass
	return float8_types

	FLOAT8_TYPES = get_supported_float8_types()

	xpu_available = False
	torch_version = ""
	try:
	torch_version = torch.version.__version__
	temp = torch_version.split(".")
	torch_version_numeric = (int(temp[0]), int(temp[1]))
	except:
	pass

	lowvram_available = True
	if args.deterministic:
	logging.info("Using deterministic algorithms for pytorch")
	torch.use_deterministic_algorithms(True, warn_only=True)

	directml_enabled = False
	if args.directml is not None:
	import torch_directml
	directml_enabled = True
	device_index = args.directml
	if device_index < 0:
	directml_device = torch_directml.device()
	else:
	directml_device = torch_directml.device(device_index)
	logging.info("Using directml with device: {}".format(torch_directml.device_name(device_index)))
	# torch_directml.disable_tiled_resources(True)
	lowvram_available = False #TODO: need to find a way to get free memory in directml before this can be enabled by default.

	try:
	import intel_extension_for_pytorch as ipex # noqa: F401
	except:
	pass

	try:
	_ = torch.xpu.device_count()
	xpu_available = torch.xpu.is_available()
	except:
	xpu_available = False

	try:
	if torch.backends.mps.is_available():
	cpu_state = CPUState.MPS
	import torch.mps
	except:
	pass

	try:
	import torch_npu # noqa: F401
	_ = torch.npu.device_count()
	npu_available = torch.npu.is_available()
	except:
	npu_available = False

	try:
	import torch_mlu # noqa: F401
	_ = torch.mlu.device_count()
	mlu_available = torch.mlu.is_available()
	except:
	mlu_available = False

	try:
	ixuca_available = hasattr(torch, "corex")
	except:
	ixuca_available = False

	if args.cpu:
	cpu_state = CPUState.CPU

	def is_intel_xpu():
	global cpu_state
	global xpu_available
	if cpu_state == CPUState.GPU:
	if xpu_available:
	return True
	return False

	def is_ascend_npu():
	global npu_available
	if npu_available:
	return True
	return False

	def is_mlu():
	global mlu_available
	if mlu_available:
	return True
	return False

	def is_ixuca():
	global ixuca_available
	if ixuca_available:
	return True
	return False

	def get_torch_device():
	global directml_enabled
	global cpu_state
	if directml_enabled:
	global directml_device
	return directml_device
	if cpu_state == CPUState.MPS:
	return torch.device("mps")
	if cpu_state == CPUState.CPU:
	return torch.device("cpu")
	else:
	if torch.cuda.is_available(): # Добавьте эту проверку!
	if is_intel_xpu():
	return torch.device("xpu", torch.xpu.current_device())
	elif is_ascend_npu():
	return torch.device("npu", torch.npu.current_device())
	elif is_mlu():
	return torch.device("mlu", torch.mlu.current_device())
	else:
	return torch.device(torch.cuda.current_device())
	else:
	return torch.device("cpu") # Fallback на CPU, если CUDA недоступен

	def get_total_memory(dev=None, torch_total_too=False):
	global directml_enabled
	if dev is None:
	dev = get_torch_device()

	if hasattr(dev, 'type') and (dev.type == 'cpu' or dev.type == 'mps'):
	mem_total = psutil.virtual_memory().total
	mem_total_torch = mem_total
	else:
	if directml_enabled:
	mem_total = 1024 * 1024 * 1024 #TODO
	mem_total_torch = mem_total
	elif is_intel_xpu():
	stats = torch.xpu.memory_stats(dev)
	mem_reserved = stats['reserved_bytes.all.current']
	mem_total_xpu = torch.xpu.get_device_properties(dev).total_memory
	mem_total_torch = mem_reserved
	mem_total = mem_total_xpu
	elif is_ascend_npu():
	stats = torch.npu.memory_stats(dev)
	mem_reserved = stats['reserved_bytes.all.current']
	_, mem_total_npu = torch.npu.mem_get_info(dev)
	mem_total_torch = mem_reserved
	mem_total = mem_total_npu
	elif is_mlu():
	stats = torch.mlu.memory_stats(dev)
	mem_reserved = stats['reserved_bytes.all.current']
	_, mem_total_mlu = torch.mlu.mem_get_info(dev)
	mem_total_torch = mem_reserved
	mem_total = mem_total_mlu
	else:
	stats = torch.cuda.memory_stats(dev)
	mem_reserved = stats['reserved_bytes.all.current']
	_, mem_total_cuda = torch.cuda.mem_get_info(dev)
	mem_total_torch = mem_reserved
	mem_total = mem_total_cuda

	if torch_total_too:
	return (mem_total, mem_total_torch)
	else:
	return mem_total

	def mac_version():
	try:
	return tuple(int(n) for n in platform.mac_ver()[0].split("."))
	except:
	return None

	total_vram = get_total_memory(get_torch_device()) / (1024 * 1024)
	total_ram = psutil.virtual_memory().total / (1024 * 1024)
	logging.info("Total VRAM {:0.0f} MB, total RAM {:0.0f} MB".format(total_vram, total_ram))

	try:
	logging.info("pytorch version: {}".format(torch_version))
	mac_ver = mac_version()
	if mac_ver is not None:
	logging.info("Mac Version {}".format(mac_ver))
	except:
	pass

	try:
	OOM_EXCEPTION = torch.cuda.OutOfMemoryError
	except:
	OOM_EXCEPTION = Exception

	XFORMERS_VERSION = ""
	XFORMERS_ENABLED_VAE = True
	if args.disable_xformers:
	XFORMERS_IS_AVAILABLE = False
	else:
	try:
	import xformers
	import xformers.ops
	XFORMERS_IS_AVAILABLE = True
	try:
	XFORMERS_IS_AVAILABLE = xformers._has_cpp_library
	except:
	pass
	try:
	XFORMERS_VERSION = xformers.version.__version__
	logging.info("xformers version: {}".format(XFORMERS_VERSION))
	if XFORMERS_VERSION.startswith("0.0.18"):
	logging.warning("\nWARNING: This version of xformers has a major bug where you will get black images when generating high resolution images.")
	logging.warning("Please downgrade or upgrade xformers to a different version.\n")
	XFORMERS_ENABLED_VAE = False
	except:
	pass
	except:
	XFORMERS_IS_AVAILABLE = False

	def is_nvidia():
	global cpu_state
	if cpu_state == CPUState.GPU:
	if torch.version.cuda:
	return True
	return False

	def is_amd():
	global cpu_state
	if cpu_state == CPUState.GPU:
	if torch.version.hip:
	return True
	return False

	def amd_min_version(device=None, min_rdna_version=0):
	if not is_amd():
	return False

	if is_device_cpu(device):
	return False

	arch = torch.cuda.get_device_properties(device).gcnArchName
	if arch.startswith('gfx') and len(arch) == 7:
	try:
	cmp_rdna_version = int(arch[4]) + 2
	except:
	cmp_rdna_version = 0
	if cmp_rdna_version >= min_rdna_version:
	return True

	return False

	MIN_WEIGHT_MEMORY_RATIO = 0.4
	if is_nvidia():
	MIN_WEIGHT_MEMORY_RATIO = 0.0

	ENABLE_PYTORCH_ATTENTION = False
	if args.use_pytorch_cross_attention:
	ENABLE_PYTORCH_ATTENTION = True
	XFORMERS_IS_AVAILABLE = False

	try:
	if is_nvidia():
	if torch_version_numeric[0] >= 2:
	if ENABLE_PYTORCH_ATTENTION == False and args.use_split_cross_attention == False and args.use_quad_cross_attention == False:
	ENABLE_PYTORCH_ATTENTION = True
	if is_intel_xpu() or is_ascend_npu() or is_mlu() or is_ixuca():
	if args.use_split_cross_attention == False and args.use_quad_cross_attention == False:
	ENABLE_PYTORCH_ATTENTION = True
	except:
	pass


	SUPPORT_FP8_OPS = args.supports_fp8_compute
	try:
	if is_amd():
	try:
	rocm_version = tuple(map(int, str(torch.version.hip).split(".")[:2]))
	except:
	rocm_version = (6, -1)
	arch = torch.cuda.get_device_properties(get_torch_device()).gcnArchName
	logging.info("AMD arch: {}".format(arch))
	logging.info("ROCm version: {}".format(rocm_version))
	if args.use_split_cross_attention == False and args.use_quad_cross_attention == False:
	if importlib.util.find_spec('triton') is not None: # AMD efficient attention implementation depends on triton. TODO: better way of detecting if it's compiled in or not.
	if torch_version_numeric >= (2, 7): # works on 2.6 but doesn't actually seem to improve much
	if any((a in arch) for a in ["gfx90a", "gfx942", "gfx1100", "gfx1101", "gfx1151"]): # TODO: more arches, TODO: gfx950
	ENABLE_PYTORCH_ATTENTION = True
	# if torch_version_numeric >= (2, 8):
	# if any((a in arch) for a in ["gfx1201"]):
	# ENABLE_PYTORCH_ATTENTION = True
	if torch_version_numeric >= (2, 7) and rocm_version >= (6, 4):
	if any((a in arch) for a in ["gfx1201", "gfx942", "gfx950"]): # TODO: more arches
	SUPPORT_FP8_OPS = True

	except:
	pass


	if ENABLE_PYTORCH_ATTENTION:
	torch.backends.cuda.enable_math_sdp(True)
	torch.backends.cuda.enable_flash_sdp(True)
	torch.backends.cuda.enable_mem_efficient_sdp(True)


	PRIORITIZE_FP16 = False # TODO: remove and replace with something that shows exactly which dtype is faster than the other
	try:
	if (is_nvidia() or is_amd()) and PerformanceFeature.Fp16Accumulation in args.fast:
	torch.backends.cuda.matmul.allow_fp16_accumulation = True
	PRIORITIZE_FP16 = True # TODO: limit to cards where it actually boosts performance
	logging.info("Enabled fp16 accumulation.")
	except:
	pass

	try:
	if torch_version_numeric >= (2, 5):
	torch.backends.cuda.allow_fp16_bf16_reduction_math_sdp(True)
	except:
	logging.warning("Warning, could not set allow_fp16_bf16_reduction_math_sdp")

	if args.lowvram:
	set_vram_to = VRAMState.LOW_VRAM
	lowvram_available = True
	elif args.novram:
	set_vram_to = VRAMState.NO_VRAM
	elif args.highvram or args.gpu_only:
	vram_state = VRAMState.HIGH_VRAM

	FORCE_FP32 = False
	if args.force_fp32:
	logging.info("Forcing FP32, if this improves things please report it.")
	FORCE_FP32 = True

	if lowvram_available:
	if set_vram_to in (VRAMState.LOW_VRAM, VRAMState.NO_VRAM):
	vram_state = set_vram_to


	if cpu_state != CPUState.GPU:
	vram_state = VRAMState.DISABLED

	if cpu_state == CPUState.MPS:
	vram_state = VRAMState.SHARED

	logging.info(f"Set vram state to: {vram_state.name}")

	DISABLE_SMART_MEMORY = args.disable_smart_memory

	if DISABLE_SMART_MEMORY:
	logging.info("Disabling smart memory management")

	def get_torch_device_name(device):
	if hasattr(device, 'type'):
	if device.type == "cuda":
	try:
	allocator_backend = torch.cuda.get_allocator_backend()
	except:
	allocator_backend = ""
	return "{} {} : {}".format(device, torch.cuda.get_device_name(device), allocator_backend)
	elif device.type == "xpu":
	return "{} {}".format(device, torch.xpu.get_device_name(device))
	else:
	return "{}".format(device.type)
	elif is_intel_xpu():
	return "{} {}".format(device, torch.xpu.get_device_name(device))
	elif is_ascend_npu():
	return "{} {}".format(device, torch.npu.get_device_name(device))
	elif is_mlu():
	return "{} {}".format(device, torch.mlu.get_device_name(device))
	else:
	return "CUDA {}: {}".format(device, torch.cuda.get_device_name(device))

	try:
	logging.info("Device: {}".format(get_torch_device_name(get_torch_device())))
	except:
	logging.warning("Could not pick default device.")


	current_loaded_models = []

	def module_size(module):
	module_mem = 0
	sd = module.state_dict()
	for k in sd:
	t = sd[k]
	module_mem += t.nelement() * t.element_size()
	return module_mem

	class LoadedModel:
	def __init__(self, model):
	self._set_model(model)
	self.device = model.load_device
	self.real_model = None
	self.currently_used = True
	self.model_finalizer = None
	self._patcher_finalizer = None

	def _set_model(self, model):
	self._model = weakref.ref(model)
	if model.parent is not None:
	self._parent_model = weakref.ref(model.parent)
	self._patcher_finalizer = weakref.finalize(model, self._switch_parent)

	def _switch_parent(self):
	model = self._parent_model()
	if model is not None:
	self._set_model(model)

	@property
	def model(self):
	return self._model()

	def model_memory(self):
	return self.model.model_size()

	def model_loaded_memory(self):
	return self.model.loaded_size()

	def model_offloaded_memory(self):
	return self.model.model_size() - self.model.loaded_size()

	def model_memory_required(self, device):
	if device == self.model.current_loaded_device():
	return self.model_offloaded_memory()
	else:
	return self.model_memory()

	def model_load(self, lowvram_model_memory=0, force_patch_weights=False):
	self.model.model_patches_to(self.device)
	self.model.model_patches_to(self.model.model_dtype())

	# if self.model.loaded_size() > 0:
	use_more_vram = lowvram_model_memory
	if use_more_vram == 0:
	use_more_vram = 1e32
	self.model_use_more_vram(use_more_vram, force_patch_weights=force_patch_weights)
	real_model = self.model.model

	if is_intel_xpu() and not args.disable_ipex_optimize and 'ipex' in globals() and real_model is not None:
	with torch.no_grad():
	real_model = ipex.optimize(real_model.eval(), inplace=True, graph_mode=True, concat_linear=True)

	self.real_model = weakref.ref(real_model)
	self.model_finalizer = weakref.finalize(real_model, cleanup_models)
	return real_model

	def should_reload_model(self, force_patch_weights=False):
	if force_patch_weights and self.model.lowvram_patch_counter() > 0:
	return True
	return False

	def model_unload(self, memory_to_free=None, unpatch_weights=True):
	if memory_to_free is not None:
	if memory_to_free < self.model.loaded_size():
	freed = self.model.partially_unload(self.model.offload_device, memory_to_free)
	if freed >= memory_to_free:
	return False
	self.model.detach(unpatch_weights)
	self.model_finalizer.detach()
	self.model_finalizer = None
	self.real_model = None
	return True

	def model_use_more_vram(self, extra_memory, force_patch_weights=False):
	return self.model.partially_load(self.device, extra_memory, force_patch_weights=force_patch_weights)

	def __eq__(self, other):
	return self.model is other.model

	def __del__(self):
	if self._patcher_finalizer is not None:
	self._patcher_finalizer.detach()

	def is_dead(self):
	return self.real_model() is not None and self.model is None


	def use_more_memory(extra_memory, loaded_models, device):
	for m in loaded_models:
	if m.device == device:
	extra_memory -= m.model_use_more_vram(extra_memory)
	if extra_memory <= 0:
	break

	def offloaded_memory(loaded_models, device):
	offloaded_mem = 0
	for m in loaded_models:
	if m.device == device:
	offloaded_mem += m.model_offloaded_memory()
	return offloaded_mem

	WINDOWS = any(platform.win32_ver())

	EXTRA_RESERVED_VRAM = 400 * 1024 * 1024
	if WINDOWS:
	EXTRA_RESERVED_VRAM = 600 * 1024 * 1024 #Windows is higher because of the shared vram issue
	if total_vram > (15 * 1024): # more extra reserved vram on 16GB+ cards
	EXTRA_RESERVED_VRAM += 100 * 1024 * 1024

	if args.reserve_vram is not None:
	EXTRA_RESERVED_VRAM = args.reserve_vram * 1024 * 1024 * 1024
	logging.debug("Reserving {}MB vram for other applications.".format(EXTRA_RESERVED_VRAM / (1024 * 1024)))

	def extra_reserved_memory():
	return EXTRA_RESERVED_VRAM

	def minimum_inference_memory():
	return (1024 * 1024 * 1024) * 0.8 + extra_reserved_memory()

	def free_memory(memory_required, device, keep_loaded=[]):
	cleanup_models_gc()
	unloaded_model = []
	can_unload = []
	unloaded_models = []

	for i in range(len(current_loaded_models) -1, -1, -1):
	shift_model = current_loaded_models[i]
	if shift_model.device == device:
	if shift_model not in keep_loaded and not shift_model.is_dead():
	can_unload.append((-shift_model.model_offloaded_memory(), sys.getrefcount(shift_model.model), shift_model.model_memory(), i))
	shift_model.currently_used = False

	for x in sorted(can_unload):
	i = x[-1]
	memory_to_free = None
	if not DISABLE_SMART_MEMORY:
	free_mem = get_free_memory(device)
	if free_mem > memory_required:
	break
	memory_to_free = memory_required - free_mem
	logging.debug(f"Unloading {current_loaded_models[i].model.model.__class__.__name__}")
	if current_loaded_models[i].model_unload(memory_to_free):
	unloaded_model.append(i)

	for i in sorted(unloaded_model, reverse=True):
	unloaded_models.append(current_loaded_models.pop(i))

	if len(unloaded_model) > 0:
	soft_empty_cache()
	else:
	if vram_state != VRAMState.HIGH_VRAM:
	mem_free_total, mem_free_torch = get_free_memory(device, torch_free_too=True)
	if mem_free_torch > mem_free_total * 0.25:
	soft_empty_cache()
	return unloaded_models

	def load_models_gpu(models, memory_required=0, force_patch_weights=False, minimum_memory_required=None, force_full_load=False):
	cleanup_models_gc()
	global vram_state

	inference_memory = minimum_inference_memory()
	extra_mem = max(inference_memory, memory_required + extra_reserved_memory())
	if minimum_memory_required is None:
	minimum_memory_required = extra_mem
	else:
	minimum_memory_required = max(inference_memory, minimum_memory_required + extra_reserved_memory())

	models_temp = set()
	for m in models:
	models_temp.add(m)
	for mm in m.model_patches_models():
	models_temp.add(mm)

	models = models_temp

	models_to_load = []

	for x in models:
	loaded_model = LoadedModel(x)
	try:
	loaded_model_index = current_loaded_models.index(loaded_model)
	except:
	loaded_model_index = None

	if loaded_model_index is not None:
	loaded = current_loaded_models[loaded_model_index]
	loaded.currently_used = True
	models_to_load.append(loaded)
	else:
	if hasattr(x, "model"):
	logging.info(f"Requested to load {x.model.__class__.__name__}")
	models_to_load.append(loaded_model)

	for loaded_model in models_to_load:
	to_unload = []
	for i in range(len(current_loaded_models)):
	if loaded_model.model.is_clone(current_loaded_models[i].model):
	to_unload = [i] + to_unload
	for i in to_unload:
	current_loaded_models.pop(i).model.detach(unpatch_all=False)

	total_memory_required = {}
	for loaded_model in models_to_load:
	total_memory_required[loaded_model.device] = total_memory_required.get(loaded_model.device, 0) + loaded_model.model_memory_required(loaded_model.device)

	for device in total_memory_required:
	if device != torch.device("cpu"):
	free_memory(total_memory_required[device] * 1.1 + extra_mem, device)

	for device in total_memory_required:
	if device != torch.device("cpu"):
	free_mem = get_free_memory(device)
	if free_mem < minimum_memory_required:
	models_l = free_memory(minimum_memory_required, device)
	logging.info("{} models unloaded.".format(len(models_l)))

	for loaded_model in models_to_load:
	model = loaded_model.model
	torch_dev = model.load_device
	if is_device_cpu(torch_dev):
	vram_set_state = VRAMState.DISABLED
	else:
	vram_set_state = vram_state
	lowvram_model_memory = 0
	if lowvram_available and (vram_set_state == VRAMState.LOW_VRAM or vram_set_state == VRAMState.NORMAL_VRAM) and not force_full_load:
	loaded_memory = loaded_model.model_loaded_memory()
	current_free_mem = get_free_memory(torch_dev) + loaded_memory

	lowvram_model_memory = max(128 * 1024 * 1024, (current_free_mem - minimum_memory_required), min(current_free_mem * MIN_WEIGHT_MEMORY_RATIO, current_free_mem - minimum_inference_memory()))
	lowvram_model_memory = max(0.1, lowvram_model_memory - loaded_memory)

	if vram_set_state == VRAMState.NO_VRAM:
	lowvram_model_memory = 0.1

	loaded_model.model_load(lowvram_model_memory, force_patch_weights=force_patch_weights)
	current_loaded_models.insert(0, loaded_model)
	return

	def load_model_gpu(model):
	return load_models_gpu([model])

	def loaded_models(only_currently_used=False):
	output = []
	for m in current_loaded_models:
	if only_currently_used:
	if not m.currently_used:
	continue

	output.append(m.model)
	return output


	def cleanup_models_gc():
	do_gc = False
	for i in range(len(current_loaded_models)):
	cur = current_loaded_models[i]
	if cur.is_dead():
	logging.info("Potential memory leak detected with model {}, doing a full garbage collect, for maximum performance avoid circular references in the model code.".format(cur.real_model().__class__.__name__))
	do_gc = True
	break

	if do_gc:
	gc.collect()
	soft_empty_cache()

	for i in range(len(current_loaded_models)):
	cur = current_loaded_models[i]
	if cur.is_dead():
	logging.warning("WARNING, memory leak with model {}. Please make sure it is not being referenced from somewhere.".format(cur.real_model().__class__.__name__))



	def cleanup_models():
	to_delete = []
	for i in range(len(current_loaded_models)):
	if current_loaded_models[i].real_model() is None:
	to_delete = [i] + to_delete

	for i in to_delete:
	x = current_loaded_models.pop(i)
	del x

	def dtype_size(dtype):
	dtype_size = 4
	if dtype == torch.float16 or dtype == torch.bfloat16:
	dtype_size = 2
	elif dtype == torch.float32:
	dtype_size = 4
	else:
	try:
	dtype_size = dtype.itemsize
	except: #Old pytorch doesn't have .itemsize
	pass
	return dtype_size

	def unet_offload_device():
	if vram_state == VRAMState.HIGH_VRAM:
	return get_torch_device()
	else:
	return torch.device("cpu")

	def unet_inital_load_device(parameters, dtype):
	torch_dev = get_torch_device()
	if vram_state == VRAMState.HIGH_VRAM or vram_state == VRAMState.SHARED:
	return torch_dev

	cpu_dev = torch.device("cpu")
	if DISABLE_SMART_MEMORY or vram_state == VRAMState.NO_VRAM:
	return cpu_dev

	model_size = dtype_size(dtype) * parameters

	mem_dev = get_free_memory(torch_dev)
	mem_cpu = get_free_memory(cpu_dev)
	if mem_dev > mem_cpu and model_size < mem_dev:
	return torch_dev
	else:
	return cpu_dev

	def maximum_vram_for_weights(device=None):
	return (get_total_memory(device) * 0.88 - minimum_inference_memory())

	def unet_dtype(device=None, model_params=0, supported_dtypes=[torch.float16, torch.bfloat16, torch.float32], weight_dtype=None):
	if model_params < 0:
	model_params = 1000000000000000000000
	if args.fp32_unet:
	return torch.float32
	if args.fp64_unet:
	return torch.float64
	if args.bf16_unet:
	return torch.bfloat16
	if args.fp16_unet:
	return torch.float16
	if args.fp8_e4m3fn_unet:
	return torch.float8_e4m3fn
	if args.fp8_e5m2_unet:
	return torch.float8_e5m2
	if args.fp8_e8m0fnu_unet:
	return torch.float8_e8m0fnu

	fp8_dtype = None
	if weight_dtype in FLOAT8_TYPES:
	fp8_dtype = weight_dtype

	if fp8_dtype is not None:
	if supports_fp8_compute(device): #if fp8 compute is supported the casting is most likely not expensive
	return fp8_dtype

	free_model_memory = maximum_vram_for_weights(device)
	if model_params * 2 > free_model_memory:
	return fp8_dtype

	if PRIORITIZE_FP16 or weight_dtype == torch.float16:
	if torch.float16 in supported_dtypes and should_use_fp16(device=device, model_params=model_params):
	return torch.float16

	for dt in supported_dtypes:
	if dt == torch.float16 and should_use_fp16(device=device, model_params=model_params):
	if torch.float16 in supported_dtypes:
	return torch.float16
	if dt == torch.bfloat16 and should_use_bf16(device, model_params=model_params):
	if torch.bfloat16 in supported_dtypes:
	return torch.bfloat16

	for dt in supported_dtypes:
	if dt == torch.float16 and should_use_fp16(device=device, model_params=model_params, manual_cast=True):
	if torch.float16 in supported_dtypes:
	return torch.float16
	if dt == torch.bfloat16 and should_use_bf16(device, model_params=model_params, manual_cast=True):
	if torch.bfloat16 in supported_dtypes:
	return torch.bfloat16

	return torch.float32

	# None means no manual cast
	def unet_manual_cast(weight_dtype, inference_device, supported_dtypes=[torch.float16, torch.bfloat16, torch.float32]):
	if weight_dtype == torch.float32 or weight_dtype == torch.float64:
	return None

	fp16_supported = should_use_fp16(inference_device, prioritize_performance=False)
	if fp16_supported and weight_dtype == torch.float16:
	return None

	bf16_supported = should_use_bf16(inference_device)
	if bf16_supported and weight_dtype == torch.bfloat16:
	return None

	fp16_supported = should_use_fp16(inference_device, prioritize_performance=True)
	if PRIORITIZE_FP16 and fp16_supported and torch.float16 in supported_dtypes:
	return torch.float16

	for dt in supported_dtypes:
	if dt == torch.float16 and fp16_supported:
	return torch.float16
	if dt == torch.bfloat16 and bf16_supported:
	return torch.bfloat16

	return torch.float32

	def text_encoder_offload_device():
	if args.gpu_only:
	return get_torch_device()
	else:
	return torch.device("cpu")

	def text_encoder_device():
	if args.gpu_only:
	return get_torch_device()
	elif vram_state == VRAMState.HIGH_VRAM or vram_state == VRAMState.NORMAL_VRAM:
	if should_use_fp16(prioritize_performance=False):
	return get_torch_device()
	else:
	return torch.device("cpu")
	else:
	return torch.device("cpu")

	def text_encoder_initial_device(load_device, offload_device, model_size=0):
	if load_device == offload_device or model_size <= 1024 * 1024 * 1024:
	return offload_device

	if is_device_mps(load_device):
	return load_device

	mem_l = get_free_memory(load_device)
	mem_o = get_free_memory(offload_device)
	if mem_l > (mem_o * 0.5) and model_size * 1.2 < mem_l:
	return load_device
	else:
	return offload_device

	def text_encoder_dtype(device=None):
	if args.fp8_e4m3fn_text_enc:
	return torch.float8_e4m3fn
	elif args.fp8_e5m2_text_enc:
	return torch.float8_e5m2
	elif args.fp16_text_enc:
	return torch.float16
	elif args.bf16_text_enc:
	return torch.bfloat16
	elif args.fp32_text_enc:
	return torch.float32

	if is_device_cpu(device):
	return torch.float16

	return torch.float16


	def intermediate_device():
	if args.gpu_only:
	return get_torch_device()
	else:
	return torch.device("cpu")

	def vae_device():
	if args.cpu_vae:
	return torch.device("cpu")
	return get_torch_device()

	def vae_offload_device():
	if args.gpu_only:
	return get_torch_device()
	else:
	return torch.device("cpu")

	def vae_dtype(device=None, allowed_dtypes=[]):
	if args.fp16_vae:
	return torch.float16
	elif args.bf16_vae:
	return torch.bfloat16
	elif args.fp32_vae:
	return torch.float32

	for d in allowed_dtypes:
	if d == torch.float16 and should_use_fp16(device):
	return d

	# NOTE: bfloat16 seems to work on AMD for the VAE but is extremely slow in some cases compared to fp32
	# slowness still a problem on pytorch nightly 2.9.0.dev20250720+rocm6.4 tested on RDNA3
	# also a problem on RDNA4 except fp32 is also slow there.
	# This is due to large bf16 convolutions being extremely slow.
	if d == torch.bfloat16 and ((not is_amd()) or amd_min_version(device, min_rdna_version=4)) and should_use_bf16(device):
	return d

	return torch.float32

	def get_autocast_device(dev):
	if hasattr(dev, 'type'):
	return dev.type
	return "cuda"

	def supports_dtype(device, dtype): #TODO
	if dtype == torch.float32:
	return True
	if is_device_cpu(device):
	return False
	if dtype == torch.float16:
	return True
	if dtype == torch.bfloat16:
	return True
	return False

	def supports_cast(device, dtype): #TODO
	if dtype == torch.float32:
	return True
	if dtype == torch.float16:
	return True
	if directml_enabled: #TODO: test this
	return False
	if dtype == torch.bfloat16:
	return True
	if is_device_mps(device):
	return False
	if dtype == torch.float8_e4m3fn:
	return True
	if dtype == torch.float8_e5m2:
	return True
	return False

	def pick_weight_dtype(dtype, fallback_dtype, device=None):
	if dtype is None:
	dtype = fallback_dtype
	elif dtype_size(dtype) > dtype_size(fallback_dtype):
	dtype = fallback_dtype

	if not supports_cast(device, dtype):
	dtype = fallback_dtype

	return dtype

	def device_supports_non_blocking(device):
	if args.force_non_blocking:
	return True
	if is_device_mps(device):
	return False #pytorch bug? mps doesn't support non blocking
	if is_intel_xpu(): #xpu does support non blocking but it is slower on iGPUs for some reason so disable by default until situation changes
	return False
	if args.deterministic: #TODO: figure out why deterministic breaks non blocking from gpu to cpu (previews)
	return False
	if directml_enabled:
	return False
	return True

	def device_should_use_non_blocking(device):
	if not device_supports_non_blocking(device):
	return False
	return False
	# return True #TODO: figure out why this causes memory issues on Nvidia and possibly others

	def force_channels_last():
	if args.force_channels_last:
	return True

	#TODO
	return False


	STREAMS = {}
	NUM_STREAMS = 1
	if args.async_offload:
	NUM_STREAMS = 2
	logging.info("Using async weight offloading with {} streams".format(NUM_STREAMS))

	stream_counters = {}
	def get_offload_stream(device):
	stream_counter = stream_counters.get(device, 0)
	if NUM_STREAMS <= 1:
	return None

	if device in STREAMS:
	ss = STREAMS[device]
	s = ss[stream_counter]
	stream_counter = (stream_counter + 1) % len(ss)
	if is_device_cuda(device):
	ss[stream_counter].wait_stream(torch.cuda.current_stream())
	elif is_device_xpu(device):
	ss[stream_counter].wait_stream(torch.xpu.current_stream())
	stream_counters[device] = stream_counter
	return s
	elif is_device_cuda(device):
	ss = []
	for k in range(NUM_STREAMS):
	ss.append(torch.cuda.Stream(device=device, priority=0))
	STREAMS[device] = ss
	s = ss[stream_counter]
	stream_counter = (stream_counter + 1) % len(ss)
	stream_counters[device] = stream_counter
	return s
	elif is_device_xpu(device):
	ss = []
	for k in range(NUM_STREAMS):
	ss.append(torch.xpu.Stream(device=device, priority=0))
	STREAMS[device] = ss
	s = ss[stream_counter]
	stream_counter = (stream_counter + 1) % len(ss)
	stream_counters[device] = stream_counter
	return s
	return None

	def sync_stream(device, stream):
	if stream is None:
	return
	if is_device_cuda(device):
	torch.cuda.current_stream().wait_stream(stream)
	elif is_device_xpu(device):
	torch.xpu.current_stream().wait_stream(stream)

	def cast_to(weight, dtype=None, device=None, non_blocking=False, copy=False, stream=None):
	if device is None or weight.device == device:
	if not copy:
	if dtype is None or weight.dtype == dtype:
	return weight
	if stream is not None:
	with stream:
	return weight.to(dtype=dtype, copy=copy)
	return weight.to(dtype=dtype, copy=copy)

	if stream is not None:
	with stream:
	r = torch.empty_like(weight, dtype=dtype, device=device)
	r.copy_(weight, non_blocking=non_blocking)
	else:
	r = torch.empty_like(weight, dtype=dtype, device=device)
	r.copy_(weight, non_blocking=non_blocking)
	return r

	def cast_to_device(tensor, device, dtype, copy=False):
	non_blocking = device_supports_non_blocking(device)
	return cast_to(tensor, dtype=dtype, device=device, non_blocking=non_blocking, copy=copy)

	def sage_attention_enabled():
	return args.use_sage_attention

	def flash_attention_enabled():
	return args.use_flash_attention

	def xformers_enabled():
	global directml_enabled
	global cpu_state
	if cpu_state != CPUState.GPU:
	return False
	if is_intel_xpu():
	return False
	if is_ascend_npu():
	return False
	if is_mlu():
	return False
	if is_ixuca():
	return False
	if directml_enabled:
	return False
	return XFORMERS_IS_AVAILABLE


	def xformers_enabled_vae():
	enabled = xformers_enabled()
	if not enabled:
	return False

	return XFORMERS_ENABLED_VAE

	def pytorch_attention_enabled():
	global ENABLE_PYTORCH_ATTENTION
	return ENABLE_PYTORCH_ATTENTION

	def pytorch_attention_enabled_vae():
	if is_amd():
	return False # enabling pytorch attention on AMD currently causes crash when doing high res
	return pytorch_attention_enabled()

	def pytorch_attention_flash_attention():
	global ENABLE_PYTORCH_ATTENTION
	if ENABLE_PYTORCH_ATTENTION:
	#TODO: more reliable way of checking for flash attention?
	if is_nvidia():
	return True
	if is_intel_xpu():
	return True
	if is_ascend_npu():
	return True
	if is_mlu():
	return True
	if is_amd():
	return True #if you have pytorch attention enabled on AMD it probably supports at least mem efficient attention
	if is_ixuca():
	return True
	return False

	def force_upcast_attention_dtype():
	upcast = args.force_upcast_attention

	macos_version = mac_version()
	if macos_version is not None and ((14, 5) <= macos_version): # black image bug on recent versions of macOS, I don't think it's ever getting fixed
	upcast = True

	if upcast:
	return {torch.float16: torch.float32}
	else:
	return None

	def get_free_memory(dev=None, torch_free_too=False):
	global directml_enabled
	if dev is None:
	dev = get_torch_device()

	if hasattr(dev, 'type') and (dev.type == 'cpu' or dev.type == 'mps'):
	mem_free_total = psutil.virtual_memory().available
	mem_free_torch = mem_free_total
	else:
	if directml_enabled:
	mem_free_total = 1024 * 1024 * 1024 #TODO
	mem_free_torch = mem_free_total
	elif is_intel_xpu():
	stats = torch.xpu.memory_stats(dev)
	mem_active = stats['active_bytes.all.current']
	mem_reserved = stats['reserved_bytes.all.current']
	mem_free_xpu = torch.xpu.get_device_properties(dev).total_memory - mem_reserved
	mem_free_torch = mem_reserved - mem_active
	mem_free_total = mem_free_xpu + mem_free_torch
	elif is_ascend_npu():
	stats = torch.npu.memory_stats(dev)
	mem_active = stats['active_bytes.all.current']
	mem_reserved = stats['reserved_bytes.all.current']
	mem_free_npu, _ = torch.npu.mem_get_info(dev)
	mem_free_torch = mem_reserved - mem_active
	mem_free_total = mem_free_npu + mem_free_torch
	elif is_mlu():
	stats = torch.mlu.memory_stats(dev)
	mem_active = stats['active_bytes.all.current']
	mem_reserved = stats['reserved_bytes.all.current']
	mem_free_mlu, _ = torch.mlu.mem_get_info(dev)
	mem_free_torch = mem_reserved - mem_active
	mem_free_total = mem_free_mlu + mem_free_torch
	else:
	stats = torch.cuda.memory_stats(dev)
	mem_active = stats['active_bytes.all.current']
	mem_reserved = stats['reserved_bytes.all.current']
	mem_free_cuda, _ = torch.cuda.mem_get_info(dev)
	mem_free_torch = mem_reserved - mem_active
	mem_free_total = mem_free_cuda + mem_free_torch

	if torch_free_too:
	return (mem_free_total, mem_free_torch)
	else:
	return mem_free_total

	def cpu_mode():
	global cpu_state
	return cpu_state == CPUState.CPU

	def mps_mode():
	global cpu_state
	return cpu_state == CPUState.MPS

	def is_device_type(device, type):
	if hasattr(device, 'type'):
	if (device.type == type):
	return True
	return False

	def is_device_cpu(device):
	return is_device_type(device, 'cpu')

	def is_device_mps(device):
	return is_device_type(device, 'mps')

	def is_device_xpu(device):
	return is_device_type(device, 'xpu')

	def is_device_cuda(device):
	return is_device_type(device, 'cuda')

	def is_directml_enabled():
	global directml_enabled
	if directml_enabled:
	return True

	return False

	def should_use_fp16(device=None, model_params=0, prioritize_performance=True, manual_cast=False):
	if device is not None:
	if is_device_cpu(device):
	return False

	if args.force_fp16:
	return True

	if FORCE_FP32:
	return False

	if is_directml_enabled():
	return True

	if (device is not None and is_device_mps(device)) or mps_mode():
	return True

	if cpu_mode():
	return False

	if is_intel_xpu():
	if torch_version_numeric < (2, 3):
	return True
	else:
	return torch.xpu.get_device_properties(device).has_fp16

	if is_ascend_npu():
	return True

	if is_mlu():
	return True

	if is_ixuca():
	return True

	if torch.version.hip:
	return True

	props = torch.cuda.get_device_properties(device)
	if props.major >= 8:
	return True

	if props.major < 6:
	return False

	#FP16 is confirmed working on a 1080 (GP104) and on latest pytorch actually seems faster than fp32
	nvidia_10_series = ["1080", "1070", "titan x", "p3000", "p3200", "p4000", "p4200", "p5000", "p5200", "p6000", "1060", "1050", "p40", "p100", "p6", "p4"]
	for x in nvidia_10_series:
	if x in props.name.lower():
	if WINDOWS or manual_cast:
	return True
	else:
	return False #weird linux behavior where fp32 is faster

	if manual_cast:
	free_model_memory = maximum_vram_for_weights(device)
	if (not prioritize_performance) or model_params * 4 > free_model_memory:
	return True

	if props.major < 7:
	return False

	#FP16 is just broken on these cards
	nvidia_16_series = ["1660", "1650", "1630", "T500", "T550", "T600", "MX550", "MX450", "CMP 30HX", "T2000", "T1000", "T1200"]
	for x in nvidia_16_series:
	if x in props.name:
	return False

	return True

	def should_use_bf16(device=None, model_params=0, prioritize_performance=True, manual_cast=False):
	if device is not None:
	if is_device_cpu(device): #TODO ? bf16 works on CPU but is extremely slow
	return False

	if FORCE_FP32:
	return False

	if directml_enabled:
	return False

	if (device is not None and is_device_mps(device)) or mps_mode():
	if mac_version() < (14,):
	return False
	return True

	if cpu_mode():
	return False

	if is_intel_xpu():
	if torch_version_numeric < (2, 3):
	return True
	else:
	return torch.xpu.is_bf16_supported()

	if is_ascend_npu():
	return True

	if is_ixuca():
	return True

	if is_amd():
	arch = torch.cuda.get_device_properties(device).gcnArchName
	if any((a in arch) for a in ["gfx1030", "gfx1031", "gfx1010", "gfx1011", "gfx1012", "gfx906", "gfx900", "gfx803"]): # RDNA2 and older don't support bf16
	if manual_cast:
	return True
	return False

	props = torch.cuda.get_device_properties(device)

	if is_mlu():
	if props.major > 3:
	return True

	if props.major >= 8:
	return True

	bf16_works = torch.cuda.is_bf16_supported()

	if bf16_works and manual_cast:
	free_model_memory = maximum_vram_for_weights(device)
	if (not prioritize_performance) or model_params * 4 > free_model_memory:
	return True

	return False

	def supports_fp8_compute(device=None):
	if SUPPORT_FP8_OPS:
	return True

	if not is_nvidia():
	return False

	props = torch.cuda.get_device_properties(device)
	if props.major >= 9:
	return True
	if props.major < 8:
	return False
	if props.minor < 9:
	return False

	if torch_version_numeric < (2, 3):
	return False

	if WINDOWS:
	if torch_version_numeric < (2, 4):
	return False

	return True

	def extended_fp16_support():
	# TODO: check why some models work with fp16 on newer torch versions but not on older
	if torch_version_numeric < (2, 7):
	return False

	return True

	def soft_empty_cache(force=False):
	global cpu_state
	if cpu_state == CPUState.MPS:
	torch.mps.empty_cache()
	elif is_intel_xpu():
	torch.xpu.empty_cache()
	elif is_ascend_npu():
	torch.npu.empty_cache()
	elif is_mlu():
	torch.mlu.empty_cache()
	elif torch.cuda.is_available():
	torch.cuda.empty_cache()
	torch.cuda.ipc_collect()

	def unload_all_models():
	free_memory(1e30, get_torch_device())


	#TODO: might be cleaner to put this somewhere else
	import threading

	class InterruptProcessingException(Exception):
	pass

	interrupt_processing_mutex = threading.RLock()

	interrupt_processing = False
	def interrupt_current_processing(value=True):
	global interrupt_processing
	global interrupt_processing_mutex
	with interrupt_processing_mutex:
	interrupt_processing = value

	def processing_interrupted():
	global interrupt_processing
	global interrupt_processing_mutex
	with interrupt_processing_mutex:
	return interrupt_processing

	def throw_exception_if_processing_interrupted():
	global interrupt_processing
	global interrupt_processing_mutex
	with interrupt_processing_mutex:
	if interrupt_processing:
	interrupt_processing = False
	raise InterruptProcessingException()