ComfyUI/comfy/sd.py

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import torch
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import contextlib
import copy
import inspect
import math
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from comfy import model_management
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from .ldm.util import instantiate_from_config
from .ldm.models.autoencoder import AutoencoderKL
import yaml
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from .cldm import cldm
from .t2i_adapter import adapter
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from . import utils
from . import clip_vision
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from . import gligen
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from . import diffusers_convert
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from . import model_base
from . import model_detection
from . import sd1_clip
from . import sd2_clip
from . import sdxl_clip
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def load_model_weights(model, sd):
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m, u = model.load_state_dict(sd, strict=False)
m = set(m)
unexpected_keys = set(u)
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k = list(sd.keys())
for x in k:
if x not in unexpected_keys:
w = sd.pop(x)
del w
if len(m) > 0:
print("missing", m)
return model
def load_clip_weights(model, sd):
k = list(sd.keys())
for x in k:
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if x.startswith("cond_stage_model.transformer.") and not x.startswith("cond_stage_model.transformer.text_model."):
y = x.replace("cond_stage_model.transformer.", "cond_stage_model.transformer.text_model.")
sd[y] = sd.pop(x)
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if 'cond_stage_model.transformer.text_model.embeddings.position_ids' in sd:
ids = sd['cond_stage_model.transformer.text_model.embeddings.position_ids']
if ids.dtype == torch.float32:
sd['cond_stage_model.transformer.text_model.embeddings.position_ids'] = ids.round()
sd = utils.transformers_convert(sd, "cond_stage_model.model.", "cond_stage_model.transformer.text_model.", 24)
return load_model_weights(model, sd)
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LORA_CLIP_MAP = {
"mlp.fc1": "mlp_fc1",
"mlp.fc2": "mlp_fc2",
"self_attn.k_proj": "self_attn_k_proj",
"self_attn.q_proj": "self_attn_q_proj",
"self_attn.v_proj": "self_attn_v_proj",
"self_attn.out_proj": "self_attn_out_proj",
}
def load_lora(lora, to_load):
patch_dict = {}
loaded_keys = set()
for x in to_load:
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alpha_name = "{}.alpha".format(x)
alpha = None
if alpha_name in lora.keys():
alpha = lora[alpha_name].item()
loaded_keys.add(alpha_name)
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regular_lora = "{}.lora_up.weight".format(x)
diffusers_lora = "{}_lora.up.weight".format(x)
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transformers_lora = "{}.lora_linear_layer.up.weight".format(x)
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A_name = None
if regular_lora in lora.keys():
A_name = regular_lora
B_name = "{}.lora_down.weight".format(x)
mid_name = "{}.lora_mid.weight".format(x)
elif diffusers_lora in lora.keys():
A_name = diffusers_lora
B_name = "{}_lora.down.weight".format(x)
mid_name = None
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elif transformers_lora in lora.keys():
A_name = transformers_lora
B_name ="{}.lora_linear_layer.down.weight".format(x)
mid_name = None
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if A_name is not None:
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mid = None
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if mid_name is not None and mid_name in lora.keys():
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mid = lora[mid_name]
loaded_keys.add(mid_name)
patch_dict[to_load[x]] = (lora[A_name], lora[B_name], alpha, mid)
loaded_keys.add(A_name)
loaded_keys.add(B_name)
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######## loha
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hada_w1_a_name = "{}.hada_w1_a".format(x)
hada_w1_b_name = "{}.hada_w1_b".format(x)
hada_w2_a_name = "{}.hada_w2_a".format(x)
hada_w2_b_name = "{}.hada_w2_b".format(x)
hada_t1_name = "{}.hada_t1".format(x)
hada_t2_name = "{}.hada_t2".format(x)
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if hada_w1_a_name in lora.keys():
hada_t1 = None
hada_t2 = None
if hada_t1_name in lora.keys():
hada_t1 = lora[hada_t1_name]
hada_t2 = lora[hada_t2_name]
loaded_keys.add(hada_t1_name)
loaded_keys.add(hada_t2_name)
patch_dict[to_load[x]] = (lora[hada_w1_a_name], lora[hada_w1_b_name], alpha, lora[hada_w2_a_name], lora[hada_w2_b_name], hada_t1, hada_t2)
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loaded_keys.add(hada_w1_a_name)
loaded_keys.add(hada_w1_b_name)
loaded_keys.add(hada_w2_a_name)
loaded_keys.add(hada_w2_b_name)
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######## lokr
lokr_w1_name = "{}.lokr_w1".format(x)
lokr_w2_name = "{}.lokr_w2".format(x)
lokr_w1_a_name = "{}.lokr_w1_a".format(x)
lokr_w1_b_name = "{}.lokr_w1_b".format(x)
lokr_t2_name = "{}.lokr_t2".format(x)
lokr_w2_a_name = "{}.lokr_w2_a".format(x)
lokr_w2_b_name = "{}.lokr_w2_b".format(x)
lokr_w1 = None
if lokr_w1_name in lora.keys():
lokr_w1 = lora[lokr_w1_name]
loaded_keys.add(lokr_w1_name)
lokr_w2 = None
if lokr_w2_name in lora.keys():
lokr_w2 = lora[lokr_w2_name]
loaded_keys.add(lokr_w2_name)
lokr_w1_a = None
if lokr_w1_a_name in lora.keys():
lokr_w1_a = lora[lokr_w1_a_name]
loaded_keys.add(lokr_w1_a_name)
lokr_w1_b = None
if lokr_w1_b_name in lora.keys():
lokr_w1_b = lora[lokr_w1_b_name]
loaded_keys.add(lokr_w1_b_name)
lokr_w2_a = None
if lokr_w2_a_name in lora.keys():
lokr_w2_a = lora[lokr_w2_a_name]
loaded_keys.add(lokr_w2_a_name)
lokr_w2_b = None
if lokr_w2_b_name in lora.keys():
lokr_w2_b = lora[lokr_w2_b_name]
loaded_keys.add(lokr_w2_b_name)
lokr_t2 = None
if lokr_t2_name in lora.keys():
lokr_t2 = lora[lokr_t2_name]
loaded_keys.add(lokr_t2_name)
if (lokr_w1 is not None) or (lokr_w2 is not None) or (lokr_w1_a is not None) or (lokr_w2_a is not None):
patch_dict[to_load[x]] = (lokr_w1, lokr_w2, alpha, lokr_w1_a, lokr_w1_b, lokr_w2_a, lokr_w2_b, lokr_t2)
for x in lora.keys():
if x not in loaded_keys:
print("lora key not loaded", x)
return patch_dict
def model_lora_keys_clip(model, key_map={}):
sdk = model.state_dict().keys()
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text_model_lora_key = "lora_te_text_model_encoder_layers_{}_{}"
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clip_l_present = False
for b in range(32):
for c in LORA_CLIP_MAP:
k = "transformer.text_model.encoder.layers.{}.{}.weight".format(b, c)
if k in sdk:
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lora_key = text_model_lora_key.format(b, LORA_CLIP_MAP[c])
key_map[lora_key] = k
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lora_key = "lora_te1_text_model_encoder_layers_{}_{}".format(b, LORA_CLIP_MAP[c])
key_map[lora_key] = k
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lora_key = "text_encoder.text_model.encoder.layers.{}.{}".format(b, c) #diffusers lora
key_map[lora_key] = k
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k = "clip_l.transformer.text_model.encoder.layers.{}.{}.weight".format(b, c)
if k in sdk:
lora_key = "lora_te1_text_model_encoder_layers_{}_{}".format(b, LORA_CLIP_MAP[c]) #SDXL base
key_map[lora_key] = k
clip_l_present = True
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lora_key = "text_encoder.text_model.encoder.layers.{}.{}".format(b, c) #diffusers lora
key_map[lora_key] = k
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k = "clip_g.transformer.text_model.encoder.layers.{}.{}.weight".format(b, c)
if k in sdk:
if clip_l_present:
lora_key = "lora_te2_text_model_encoder_layers_{}_{}".format(b, LORA_CLIP_MAP[c]) #SDXL base
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key_map[lora_key] = k
lora_key = "text_encoder_2.text_model.encoder.layers.{}.{}".format(b, c) #diffusers lora
key_map[lora_key] = k
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else:
lora_key = "lora_te_text_model_encoder_layers_{}_{}".format(b, LORA_CLIP_MAP[c]) #TODO: test if this is correct for SDXL-Refiner
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key_map[lora_key] = k
lora_key = "text_encoder.text_model.encoder.layers.{}.{}".format(b, c) #diffusers lora
key_map[lora_key] = k
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return key_map
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def model_lora_keys_unet(model, key_map={}):
sdk = model.state_dict().keys()
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for k in sdk:
if k.startswith("diffusion_model.") and k.endswith(".weight"):
key_lora = k[len("diffusion_model."):-len(".weight")].replace(".", "_")
key_map["lora_unet_{}".format(key_lora)] = k
diffusers_keys = utils.unet_to_diffusers(model.model_config.unet_config)
for k in diffusers_keys:
if k.endswith(".weight"):
unet_key = "diffusion_model.{}".format(diffusers_keys[k])
key_lora = k[:-len(".weight")].replace(".", "_")
key_map["lora_unet_{}".format(key_lora)] = unet_key
diffusers_lora_prefix = ["", "unet."]
for p in diffusers_lora_prefix:
diffusers_lora_key = "{}{}".format(p, k[:-len(".weight")].replace(".to_", ".processor.to_"))
if diffusers_lora_key.endswith(".to_out.0"):
diffusers_lora_key = diffusers_lora_key[:-2]
key_map[diffusers_lora_key] = unet_key
return key_map
def set_attr(obj, attr, value):
attrs = attr.split(".")
for name in attrs[:-1]:
obj = getattr(obj, name)
prev = getattr(obj, attrs[-1])
setattr(obj, attrs[-1], torch.nn.Parameter(value))
del prev
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def get_attr(obj, attr):
attrs = attr.split(".")
for name in attrs:
obj = getattr(obj, name)
return obj
class ModelPatcher:
def __init__(self, model, load_device, offload_device, size=0, current_device=None):
self.size = size
self.model = model
self.patches = {}
self.backup = {}
self.model_options = {"transformer_options":{}}
self.model_size()
self.load_device = load_device
self.offload_device = offload_device
if current_device is None:
self.current_device = self.offload_device
else:
self.current_device = current_device
def model_size(self):
if self.size > 0:
return self.size
model_sd = self.model.state_dict()
size = 0
for k in model_sd:
t = model_sd[k]
size += t.nelement() * t.element_size()
self.size = size
self.model_keys = set(model_sd.keys())
return size
def clone(self):
n = ModelPatcher(self.model, self.load_device, self.offload_device, self.size, self.current_device)
n.patches = {}
for k in self.patches:
n.patches[k] = self.patches[k][:]
n.model_options = copy.deepcopy(self.model_options)
n.model_keys = self.model_keys
return n
def is_clone(self, other):
if hasattr(other, 'model') and self.model is other.model:
return True
return False
def set_model_sampler_cfg_function(self, sampler_cfg_function):
if len(inspect.signature(sampler_cfg_function).parameters) == 3:
self.model_options["sampler_cfg_function"] = lambda args: sampler_cfg_function(args["cond"], args["uncond"], args["cond_scale"]) #Old way
else:
self.model_options["sampler_cfg_function"] = sampler_cfg_function
def set_model_unet_function_wrapper(self, unet_wrapper_function):
self.model_options["model_function_wrapper"] = unet_wrapper_function
def set_model_patch(self, patch, name):
to = self.model_options["transformer_options"]
if "patches" not in to:
to["patches"] = {}
to["patches"][name] = to["patches"].get(name, []) + [patch]
def set_model_patch_replace(self, patch, name, block_name, number):
to = self.model_options["transformer_options"]
if "patches_replace" not in to:
to["patches_replace"] = {}
if name not in to["patches_replace"]:
to["patches_replace"][name] = {}
to["patches_replace"][name][(block_name, number)] = patch
def set_model_attn1_patch(self, patch):
self.set_model_patch(patch, "attn1_patch")
def set_model_attn2_patch(self, patch):
self.set_model_patch(patch, "attn2_patch")
def set_model_attn1_replace(self, patch, block_name, number):
self.set_model_patch_replace(patch, "attn1", block_name, number)
def set_model_attn2_replace(self, patch, block_name, number):
self.set_model_patch_replace(patch, "attn2", block_name, number)
def set_model_attn1_output_patch(self, patch):
self.set_model_patch(patch, "attn1_output_patch")
def set_model_attn2_output_patch(self, patch):
self.set_model_patch(patch, "attn2_output_patch")
def model_patches_to(self, device):
to = self.model_options["transformer_options"]
if "patches" in to:
patches = to["patches"]
for name in patches:
patch_list = patches[name]
for i in range(len(patch_list)):
if hasattr(patch_list[i], "to"):
patch_list[i] = patch_list[i].to(device)
if "patches_replace" in to:
patches = to["patches_replace"]
for name in patches:
patch_list = patches[name]
for k in patch_list:
if hasattr(patch_list[k], "to"):
patch_list[k] = patch_list[k].to(device)
def model_dtype(self):
if hasattr(self.model, "get_dtype"):
return self.model.get_dtype()
def add_patches(self, patches, strength_patch=1.0, strength_model=1.0):
p = set()
for k in patches:
if k in self.model_keys:
p.add(k)
current_patches = self.patches.get(k, [])
current_patches.append((strength_patch, patches[k], strength_model))
self.patches[k] = current_patches
return list(p)
def get_key_patches(self, filter_prefix=None):
model_sd = self.model_state_dict()
p = {}
for k in model_sd:
if filter_prefix is not None:
if not k.startswith(filter_prefix):
continue
if k in self.patches:
p[k] = [model_sd[k]] + self.patches[k]
else:
p[k] = (model_sd[k],)
return p
def model_state_dict(self, filter_prefix=None):
sd = self.model.state_dict()
keys = list(sd.keys())
if filter_prefix is not None:
for k in keys:
if not k.startswith(filter_prefix):
sd.pop(k)
return sd
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def patch_model(self, device_to=None):
model_sd = self.model_state_dict()
for key in self.patches:
if key not in model_sd:
print("could not patch. key doesn't exist in model:", k)
continue
weight = model_sd[key]
if key not in self.backup:
self.backup[key] = weight.to(self.offload_device)
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if device_to is not None:
temp_weight = weight.float().to(device_to, copy=True)
else:
temp_weight = weight.to(torch.float32, copy=True)
out_weight = self.calculate_weight(self.patches[key], temp_weight, key).to(weight.dtype)
set_attr(self.model, key, out_weight)
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del temp_weight
if device_to is not None:
self.model.to(device_to)
self.current_device = device_to
return self.model
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def calculate_weight(self, patches, weight, key):
for p in patches:
alpha = p[0]
v = p[1]
strength_model = p[2]
if strength_model != 1.0:
weight *= strength_model
if isinstance(v, list):
v = (self.calculate_weight(v[1:], v[0].clone(), key), )
if len(v) == 1:
w1 = v[0]
if alpha != 0.0:
if w1.shape != weight.shape:
print("WARNING SHAPE MISMATCH {} WEIGHT NOT MERGED {} != {}".format(key, w1.shape, weight.shape))
else:
weight += alpha * w1.type(weight.dtype).to(weight.device)
elif len(v) == 4: #lora/locon
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mat1 = v[0].float().to(weight.device)
mat2 = v[1].float().to(weight.device)
if v[2] is not None:
alpha *= v[2] / mat2.shape[0]
if v[3] is not None:
#locon mid weights, hopefully the math is fine because I didn't properly test it
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mat3 = v[3].float().to(weight.device)
final_shape = [mat2.shape[1], mat2.shape[0], mat3.shape[2], mat3.shape[3]]
mat2 = torch.mm(mat2.transpose(0, 1).flatten(start_dim=1), mat3.transpose(0, 1).flatten(start_dim=1)).reshape(final_shape).transpose(0, 1)
try:
weight += (alpha * torch.mm(mat1.flatten(start_dim=1), mat2.flatten(start_dim=1))).reshape(weight.shape).type(weight.dtype)
except Exception as e:
print("ERROR", key, e)
elif len(v) == 8: #lokr
w1 = v[0]
w2 = v[1]
w1_a = v[3]
w1_b = v[4]
w2_a = v[5]
w2_b = v[6]
t2 = v[7]
dim = None
if w1 is None:
dim = w1_b.shape[0]
w1 = torch.mm(w1_a.float(), w1_b.float())
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else:
w1 = w1.float().to(weight.device)
if w2 is None:
dim = w2_b.shape[0]
if t2 is None:
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w2 = torch.mm(w2_a.float().to(weight.device), w2_b.float().to(weight.device))
else:
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w2 = torch.einsum('i j k l, j r, i p -> p r k l', t2.float().to(weight.device), w2_b.float().to(weight.device), w2_a.float().to(weight.device))
else:
w2 = w2.float().to(weight.device)
if len(w2.shape) == 4:
w1 = w1.unsqueeze(2).unsqueeze(2)
if v[2] is not None and dim is not None:
alpha *= v[2] / dim
try:
weight += alpha * torch.kron(w1, w2).reshape(weight.shape).type(weight.dtype)
except Exception as e:
print("ERROR", key, e)
else: #loha
w1a = v[0]
w1b = v[1]
if v[2] is not None:
alpha *= v[2] / w1b.shape[0]
w2a = v[3]
w2b = v[4]
if v[5] is not None: #cp decomposition
t1 = v[5]
t2 = v[6]
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m1 = torch.einsum('i j k l, j r, i p -> p r k l', t1.float().to(weight.device), w1b.float().to(weight.device), w1a.float().to(weight.device))
m2 = torch.einsum('i j k l, j r, i p -> p r k l', t2.float().to(weight.device), w2b.float().to(weight.device), w2a.float().to(weight.device))
else:
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m1 = torch.mm(w1a.float().to(weight.device), w1b.float().to(weight.device))
m2 = torch.mm(w2a.float().to(weight.device), w2b.float().to(weight.device))
try:
weight += (alpha * m1 * m2).reshape(weight.shape).type(weight.dtype)
except Exception as e:
print("ERROR", key, e)
return weight
def unpatch_model(self, device_to=None):
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keys = list(self.backup.keys())
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for k in keys:
set_attr(self.model, k, self.backup[k])
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self.backup = {}
if device_to is not None:
self.model.to(device_to)
self.current_device = device_to
def load_lora_for_models(model, clip, lora, strength_model, strength_clip):
key_map = model_lora_keys_unet(model.model)
key_map = model_lora_keys_clip(clip.cond_stage_model, key_map)
loaded = load_lora(lora, key_map)
new_modelpatcher = model.clone()
k = new_modelpatcher.add_patches(loaded, strength_model)
new_clip = clip.clone()
k1 = new_clip.add_patches(loaded, strength_clip)
k = set(k)
k1 = set(k1)
for x in loaded:
if (x not in k) and (x not in k1):
print("NOT LOADED", x)
return (new_modelpatcher, new_clip)
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class CLIP:
def __init__(self, target=None, embedding_directory=None, no_init=False):
if no_init:
return
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params = target.params.copy()
clip = target.clip
tokenizer = target.tokenizer
load_device = model_management.text_encoder_device()
offload_device = model_management.text_encoder_offload_device()
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params['device'] = load_device
if model_management.should_use_fp16(load_device):
params['dtype'] = torch.float16
else:
params['dtype'] = torch.float32
self.cond_stage_model = clip(**(params))
self.tokenizer = tokenizer(embedding_directory=embedding_directory)
self.patcher = ModelPatcher(self.cond_stage_model, load_device=load_device, offload_device=offload_device)
self.layer_idx = None
def clone(self):
n = CLIP(no_init=True)
n.patcher = self.patcher.clone()
n.cond_stage_model = self.cond_stage_model
n.tokenizer = self.tokenizer
n.layer_idx = self.layer_idx
return n
def load_from_state_dict(self, sd):
self.cond_stage_model.load_sd(sd)
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def add_patches(self, patches, strength_patch=1.0, strength_model=1.0):
return self.patcher.add_patches(patches, strength_patch, strength_model)
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def clip_layer(self, layer_idx):
self.layer_idx = layer_idx
def tokenize(self, text, return_word_ids=False):
return self.tokenizer.tokenize_with_weights(text, return_word_ids)
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def encode_from_tokens(self, tokens, return_pooled=False):
if self.layer_idx is not None:
self.cond_stage_model.clip_layer(self.layer_idx)
else:
self.cond_stage_model.reset_clip_layer()
self.load_model()
cond, pooled = self.cond_stage_model.encode_token_weights(tokens)
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if return_pooled:
return cond, pooled
return cond
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def encode(self, text):
tokens = self.tokenize(text)
return self.encode_from_tokens(tokens)
def load_sd(self, sd):
return self.cond_stage_model.load_sd(sd)
def get_sd(self):
return self.cond_stage_model.state_dict()
def load_model(self):
model_management.load_model_gpu(self.patcher)
return self.patcher
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def get_key_patches(self):
return self.patcher.get_key_patches()
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class VAE:
def __init__(self, ckpt_path=None, device=None, config=None):
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if config is None:
#default SD1.x/SD2.x VAE parameters
ddconfig = {'double_z': True, 'z_channels': 4, 'resolution': 256, 'in_channels': 3, 'out_ch': 3, 'ch': 128, 'ch_mult': [1, 2, 4, 4], 'num_res_blocks': 2, 'attn_resolutions': [], 'dropout': 0.0}
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self.first_stage_model = AutoencoderKL(ddconfig, {'target': 'torch.nn.Identity'}, 4, monitor="val/rec_loss")
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else:
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self.first_stage_model = AutoencoderKL(**(config['params']))
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self.first_stage_model = self.first_stage_model.eval()
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if ckpt_path is not None:
sd = utils.load_torch_file(ckpt_path)
if 'decoder.up_blocks.0.resnets.0.norm1.weight' in sd.keys(): #diffusers format
sd = diffusers_convert.convert_vae_state_dict(sd)
self.first_stage_model.load_state_dict(sd, strict=False)
if device is None:
device = model_management.vae_device()
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self.device = device
self.offload_device = model_management.vae_offload_device()
self.vae_dtype = model_management.vae_dtype()
self.first_stage_model.to(self.vae_dtype)
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def decode_tiled_(self, samples, tile_x=64, tile_y=64, overlap = 16):
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steps = samples.shape[0] * utils.get_tiled_scale_steps(samples.shape[3], samples.shape[2], tile_x, tile_y, overlap)
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steps += samples.shape[0] * utils.get_tiled_scale_steps(samples.shape[3], samples.shape[2], tile_x // 2, tile_y * 2, overlap)
steps += samples.shape[0] * utils.get_tiled_scale_steps(samples.shape[3], samples.shape[2], tile_x * 2, tile_y // 2, overlap)
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pbar = utils.ProgressBar(steps)
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decode_fn = lambda a: (self.first_stage_model.decode(a.to(self.vae_dtype).to(self.device)) + 1.0).float()
output = torch.clamp((
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(utils.tiled_scale(samples, decode_fn, tile_x // 2, tile_y * 2, overlap, upscale_amount = 8, pbar = pbar) +
utils.tiled_scale(samples, decode_fn, tile_x * 2, tile_y // 2, overlap, upscale_amount = 8, pbar = pbar) +
utils.tiled_scale(samples, decode_fn, tile_x, tile_y, overlap, upscale_amount = 8, pbar = pbar))
/ 3.0) / 2.0, min=0.0, max=1.0)
return output
def encode_tiled_(self, pixel_samples, tile_x=512, tile_y=512, overlap = 64):
steps = pixel_samples.shape[0] * utils.get_tiled_scale_steps(pixel_samples.shape[3], pixel_samples.shape[2], tile_x, tile_y, overlap)
steps += pixel_samples.shape[0] * utils.get_tiled_scale_steps(pixel_samples.shape[3], pixel_samples.shape[2], tile_x // 2, tile_y * 2, overlap)
steps += pixel_samples.shape[0] * utils.get_tiled_scale_steps(pixel_samples.shape[3], pixel_samples.shape[2], tile_x * 2, tile_y // 2, overlap)
pbar = utils.ProgressBar(steps)
encode_fn = lambda a: self.first_stage_model.encode(2. * a.to(self.vae_dtype).to(self.device) - 1.).sample().float()
samples = utils.tiled_scale(pixel_samples, encode_fn, tile_x, tile_y, overlap, upscale_amount = (1/8), out_channels=4, pbar=pbar)
samples += utils.tiled_scale(pixel_samples, encode_fn, tile_x * 2, tile_y // 2, overlap, upscale_amount = (1/8), out_channels=4, pbar=pbar)
samples += utils.tiled_scale(pixel_samples, encode_fn, tile_x // 2, tile_y * 2, overlap, upscale_amount = (1/8), out_channels=4, pbar=pbar)
samples /= 3.0
return samples
def decode(self, samples_in):
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self.first_stage_model = self.first_stage_model.to(self.device)
try:
memory_used = (2562 * samples_in.shape[2] * samples_in.shape[3] * 64) * 1.7
model_management.free_memory(memory_used, self.device)
free_memory = model_management.get_free_memory(self.device)
batch_number = int(free_memory / memory_used)
batch_number = max(1, batch_number)
pixel_samples = torch.empty((samples_in.shape[0], 3, round(samples_in.shape[2] * 8), round(samples_in.shape[3] * 8)), device="cpu")
for x in range(0, samples_in.shape[0], batch_number):
samples = samples_in[x:x+batch_number].to(self.vae_dtype).to(self.device)
pixel_samples[x:x+batch_number] = torch.clamp((self.first_stage_model.decode(samples) + 1.0) / 2.0, min=0.0, max=1.0).cpu().float()
except model_management.OOM_EXCEPTION as e:
print("Warning: Ran out of memory when regular VAE decoding, retrying with tiled VAE decoding.")
pixel_samples = self.decode_tiled_(samples_in)
self.first_stage_model = self.first_stage_model.to(self.offload_device)
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pixel_samples = pixel_samples.cpu().movedim(1,-1)
return pixel_samples
def decode_tiled(self, samples, tile_x=64, tile_y=64, overlap = 16):
self.first_stage_model = self.first_stage_model.to(self.device)
output = self.decode_tiled_(samples, tile_x, tile_y, overlap)
self.first_stage_model = self.first_stage_model.to(self.offload_device)
return output.movedim(1,-1)
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def encode(self, pixel_samples):
self.first_stage_model = self.first_stage_model.to(self.device)
pixel_samples = pixel_samples.movedim(-1,1)
try:
memory_used = (2078 * pixel_samples.shape[2] * pixel_samples.shape[3]) * 1.7 #NOTE: this constant along with the one in the decode above are estimated from the mem usage for the VAE and could change.
model_management.free_memory(memory_used, self.device)
free_memory = model_management.get_free_memory(self.device)
batch_number = int(free_memory / memory_used)
batch_number = max(1, batch_number)
samples = torch.empty((pixel_samples.shape[0], 4, round(pixel_samples.shape[2] // 8), round(pixel_samples.shape[3] // 8)), device="cpu")
for x in range(0, pixel_samples.shape[0], batch_number):
pixels_in = (2. * pixel_samples[x:x+batch_number] - 1.).to(self.vae_dtype).to(self.device)
samples[x:x+batch_number] = self.first_stage_model.encode(pixels_in).sample().cpu().float()
except model_management.OOM_EXCEPTION as e:
print("Warning: Ran out of memory when regular VAE encoding, retrying with tiled VAE encoding.")
samples = self.encode_tiled_(pixel_samples)
self.first_stage_model = self.first_stage_model.to(self.offload_device)
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return samples
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def encode_tiled(self, pixel_samples, tile_x=512, tile_y=512, overlap = 64):
self.first_stage_model = self.first_stage_model.to(self.device)
pixel_samples = pixel_samples.movedim(-1,1)
samples = self.encode_tiled_(pixel_samples, tile_x=tile_x, tile_y=tile_y, overlap=overlap)
self.first_stage_model = self.first_stage_model.to(self.offload_device)
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return samples
def get_sd(self):
return self.first_stage_model.state_dict()
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def broadcast_image_to(tensor, target_batch_size, batched_number):
current_batch_size = tensor.shape[0]
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#print(current_batch_size, target_batch_size)
if current_batch_size == 1:
return tensor
per_batch = target_batch_size // batched_number
tensor = tensor[:per_batch]
if per_batch > tensor.shape[0]:
tensor = torch.cat([tensor] * (per_batch // tensor.shape[0]) + [tensor[:(per_batch % tensor.shape[0])]], dim=0)
current_batch_size = tensor.shape[0]
if current_batch_size == target_batch_size:
return tensor
else:
return torch.cat([tensor] * batched_number, dim=0)
class ControlBase:
def __init__(self, device=None):
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self.cond_hint_original = None
self.cond_hint = None
self.strength = 1.0
self.timestep_percent_range = (1.0, 0.0)
self.timestep_range = None
if device is None:
device = model_management.get_torch_device()
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self.device = device
self.previous_controlnet = None
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self.global_average_pooling = False
def set_cond_hint(self, cond_hint, strength=1.0, timestep_percent_range=(1.0, 0.0)):
self.cond_hint_original = cond_hint
self.strength = strength
self.timestep_percent_range = timestep_percent_range
return self
def pre_run(self, model, percent_to_timestep_function):
self.timestep_range = (percent_to_timestep_function(self.timestep_percent_range[0]), percent_to_timestep_function(self.timestep_percent_range[1]))
if self.previous_controlnet is not None:
self.previous_controlnet.pre_run(model, percent_to_timestep_function)
def set_previous_controlnet(self, controlnet):
self.previous_controlnet = controlnet
return self
def cleanup(self):
if self.previous_controlnet is not None:
self.previous_controlnet.cleanup()
if self.cond_hint is not None:
del self.cond_hint
self.cond_hint = None
self.timestep_range = None
def get_models(self):
out = []
if self.previous_controlnet is not None:
out += self.previous_controlnet.get_models()
return out
def copy_to(self, c):
c.cond_hint_original = self.cond_hint_original
c.strength = self.strength
c.timestep_percent_range = self.timestep_percent_range
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def control_merge(self, control_input, control_output, control_prev, output_dtype):
out = {'input':[], 'middle':[], 'output': []}
if control_input is not None:
for i in range(len(control_input)):
key = 'input'
x = control_input[i]
if x is not None:
x *= self.strength
if x.dtype != output_dtype:
x = x.to(output_dtype)
out[key].insert(0, x)
if control_output is not None:
for i in range(len(control_output)):
if i == (len(control_output) - 1):
key = 'middle'
index = 0
else:
key = 'output'
index = i
x = control_output[i]
if x is not None:
if self.global_average_pooling:
x = torch.mean(x, dim=(2, 3), keepdim=True).repeat(1, 1, x.shape[2], x.shape[3])
x *= self.strength
if x.dtype != output_dtype:
x = x.to(output_dtype)
out[key].append(x)
if control_prev is not None:
for x in ['input', 'middle', 'output']:
o = out[x]
for i in range(len(control_prev[x])):
prev_val = control_prev[x][i]
if i >= len(o):
o.append(prev_val)
elif prev_val is not None:
if o[i] is None:
o[i] = prev_val
else:
o[i] += prev_val
return out
class ControlNet(ControlBase):
def __init__(self, control_model, global_average_pooling=False, device=None):
super().__init__(device)
self.control_model = control_model
self.control_model_wrapped = ModelPatcher(self.control_model, load_device=model_management.get_torch_device(), offload_device=model_management.unet_offload_device())
self.global_average_pooling = global_average_pooling
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def get_control(self, x_noisy, t, cond, batched_number):
control_prev = None
if self.previous_controlnet is not None:
control_prev = self.previous_controlnet.get_control(x_noisy, t, cond, batched_number)
if self.timestep_range is not None:
if t[0] > self.timestep_range[0] or t[0] < self.timestep_range[1]:
if control_prev is not None:
return control_prev
else:
return {}
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output_dtype = x_noisy.dtype
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if self.cond_hint is None or x_noisy.shape[2] * 8 != self.cond_hint.shape[2] or x_noisy.shape[3] * 8 != self.cond_hint.shape[3]:
if self.cond_hint is not None:
del self.cond_hint
self.cond_hint = None
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self.cond_hint = utils.common_upscale(self.cond_hint_original, x_noisy.shape[3] * 8, x_noisy.shape[2] * 8, 'nearest-exact', "center").to(self.control_model.dtype).to(self.device)
if x_noisy.shape[0] != self.cond_hint.shape[0]:
self.cond_hint = broadcast_image_to(self.cond_hint, x_noisy.shape[0], batched_number)
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context = torch.cat(cond['c_crossattn'], 1)
y = cond.get('c_adm', None)
if y is not None:
y = y.to(self.control_model.dtype)
control = self.control_model(x=x_noisy.to(self.control_model.dtype), hint=self.cond_hint, timesteps=t, context=context.to(self.control_model.dtype), y=y)
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return self.control_merge(None, control, control_prev, output_dtype)
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def copy(self):
c = ControlNet(self.control_model, global_average_pooling=self.global_average_pooling)
self.copy_to(c)
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return c
def get_models(self):
out = super().get_models()
out.append(self.control_model_wrapped)
return out
class ControlLoraOps:
class Linear(torch.nn.Module):
def __init__(self, in_features: int, out_features: int, bias: bool = True,
device=None, dtype=None) -> None:
factory_kwargs = {'device': device, 'dtype': dtype}
super().__init__()
self.in_features = in_features
self.out_features = out_features
self.weight = None
self.up = None
self.down = None
self.bias = None
def forward(self, input):
if self.up is not None:
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return torch.nn.functional.linear(input, self.weight.to(input.device) + (torch.mm(self.up.flatten(start_dim=1), self.down.flatten(start_dim=1))).reshape(self.weight.shape).type(input.dtype), self.bias)
else:
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return torch.nn.functional.linear(input, self.weight.to(input.device), self.bias)
class Conv2d(torch.nn.Module):
def __init__(
self,
in_channels,
out_channels,
kernel_size,
stride=1,
padding=0,
dilation=1,
groups=1,
bias=True,
padding_mode='zeros',
device=None,
dtype=None
):
super().__init__()
self.in_channels = in_channels
self.out_channels = out_channels
self.kernel_size = kernel_size
self.stride = stride
self.padding = padding
self.dilation = dilation
self.transposed = False
self.output_padding = 0
self.groups = groups
self.padding_mode = padding_mode
self.weight = None
self.bias = None
self.up = None
self.down = None
def forward(self, input):
if self.up is not None:
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return torch.nn.functional.conv2d(input, self.weight.to(input.device) + (torch.mm(self.up.flatten(start_dim=1), self.down.flatten(start_dim=1))).reshape(self.weight.shape).type(input.dtype), self.bias, self.stride, self.padding, self.dilation, self.groups)
else:
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return torch.nn.functional.conv2d(input, self.weight.to(input.device), self.bias, self.stride, self.padding, self.dilation, self.groups)
def conv_nd(self, dims, *args, **kwargs):
if dims == 2:
return self.Conv2d(*args, **kwargs)
else:
raise ValueError(f"unsupported dimensions: {dims}")
class ControlLora(ControlNet):
def __init__(self, control_weights, global_average_pooling=False, device=None):
ControlBase.__init__(self, device)
self.control_weights = control_weights
self.global_average_pooling = global_average_pooling
def pre_run(self, model, percent_to_timestep_function):
super().pre_run(model, percent_to_timestep_function)
controlnet_config = model.model_config.unet_config.copy()
controlnet_config.pop("out_channels")
controlnet_config["hint_channels"] = self.control_weights["input_hint_block.0.weight"].shape[1]
controlnet_config["operations"] = ControlLoraOps()
self.control_model = cldm.ControlNet(**controlnet_config)
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dtype = model.get_dtype()
self.control_model.to(dtype)
self.control_model.to(model_management.get_torch_device())
diffusion_model = model.diffusion_model
sd = diffusion_model.state_dict()
cm = self.control_model.state_dict()
for k in sd:
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weight = sd[k]
if weight.device == torch.device("meta"): #lowvram NOTE: this depends on the inner working of the accelerate library so it might break.
key_split = k.split('.') # I have no idea why they don't just leave the weight there instead of using the meta device.
op = get_attr(diffusion_model, '.'.join(key_split[:-1]))
weight = op._hf_hook.weights_map[key_split[-1]]
try:
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set_attr(self.control_model, k, weight)
except:
pass
for k in self.control_weights:
if k not in {"lora_controlnet"}:
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set_attr(self.control_model, k, self.control_weights[k].to(dtype).to(model_management.get_torch_device()))
def copy(self):
c = ControlLora(self.control_weights, global_average_pooling=self.global_average_pooling)
self.copy_to(c)
return c
def cleanup(self):
del self.control_model
self.control_model = None
super().cleanup()
def get_models(self):
out = ControlBase.get_models(self)
return out
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def load_controlnet(ckpt_path, model=None):
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controlnet_data = utils.load_torch_file(ckpt_path, safe_load=True)
if "lora_controlnet" in controlnet_data:
return ControlLora(controlnet_data)
controlnet_config = None
if "controlnet_cond_embedding.conv_in.weight" in controlnet_data: #diffusers format
use_fp16 = model_management.should_use_fp16()
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controlnet_config = model_detection.unet_config_from_diffusers_unet(controlnet_data, use_fp16)
diffusers_keys = utils.unet_to_diffusers(controlnet_config)
diffusers_keys["controlnet_mid_block.weight"] = "middle_block_out.0.weight"
diffusers_keys["controlnet_mid_block.bias"] = "middle_block_out.0.bias"
count = 0
loop = True
while loop:
suffix = [".weight", ".bias"]
for s in suffix:
k_in = "controlnet_down_blocks.{}{}".format(count, s)
k_out = "zero_convs.{}.0{}".format(count, s)
if k_in not in controlnet_data:
loop = False
break
diffusers_keys[k_in] = k_out
count += 1
count = 0
loop = True
while loop:
suffix = [".weight", ".bias"]
for s in suffix:
if count == 0:
k_in = "controlnet_cond_embedding.conv_in{}".format(s)
else:
k_in = "controlnet_cond_embedding.blocks.{}{}".format(count - 1, s)
k_out = "input_hint_block.{}{}".format(count * 2, s)
if k_in not in controlnet_data:
k_in = "controlnet_cond_embedding.conv_out{}".format(s)
loop = False
diffusers_keys[k_in] = k_out
count += 1
new_sd = {}
for k in diffusers_keys:
if k in controlnet_data:
new_sd[diffusers_keys[k]] = controlnet_data.pop(k)
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leftover_keys = controlnet_data.keys()
if len(leftover_keys) > 0:
print("leftover keys:", leftover_keys)
controlnet_data = new_sd
pth_key = 'control_model.zero_convs.0.0.weight'
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pth = False
key = 'zero_convs.0.0.weight'
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if pth_key in controlnet_data:
pth = True
key = pth_key
prefix = "control_model."
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elif key in controlnet_data:
prefix = ""
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else:
net = load_t2i_adapter(controlnet_data)
if net is None:
print("error checkpoint does not contain controlnet or t2i adapter data", ckpt_path)
return net
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if controlnet_config is None:
use_fp16 = model_management.should_use_fp16()
controlnet_config = model_detection.model_config_from_unet(controlnet_data, prefix, use_fp16).unet_config
controlnet_config.pop("out_channels")
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controlnet_config["hint_channels"] = controlnet_data["{}input_hint_block.0.weight".format(prefix)].shape[1]
control_model = cldm.ControlNet(**controlnet_config)
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if pth:
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if 'difference' in controlnet_data:
if model is not None:
model_management.load_models_gpu([model])
model_sd = model.model_state_dict()
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for x in controlnet_data:
c_m = "control_model."
if x.startswith(c_m):
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sd_key = "diffusion_model.{}".format(x[len(c_m):])
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if sd_key in model_sd:
cd = controlnet_data[x]
cd += model_sd[sd_key].type(cd.dtype).to(cd.device)
else:
print("WARNING: Loaded a diff controlnet without a model. It will very likely not work.")
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class WeightsLoader(torch.nn.Module):
pass
w = WeightsLoader()
w.control_model = control_model
missing, unexpected = w.load_state_dict(controlnet_data, strict=False)
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else:
missing, unexpected = control_model.load_state_dict(controlnet_data, strict=False)
print(missing, unexpected)
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if use_fp16:
control_model = control_model.half()
global_average_pooling = False
if ckpt_path.endswith("_shuffle.pth") or ckpt_path.endswith("_shuffle.safetensors") or ckpt_path.endswith("_shuffle_fp16.safetensors"): #TODO: smarter way of enabling global_average_pooling
global_average_pooling = True
control = ControlNet(control_model, global_average_pooling=global_average_pooling)
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return control
class T2IAdapter(ControlBase):
def __init__(self, t2i_model, channels_in, device=None):
super().__init__(device)
self.t2i_model = t2i_model
self.channels_in = channels_in
self.control_input = None
def scale_image_to(self, width, height):
unshuffle_amount = self.t2i_model.unshuffle_amount
width = math.ceil(width / unshuffle_amount) * unshuffle_amount
height = math.ceil(height / unshuffle_amount) * unshuffle_amount
return width, height
def get_control(self, x_noisy, t, cond, batched_number):
control_prev = None
if self.previous_controlnet is not None:
control_prev = self.previous_controlnet.get_control(x_noisy, t, cond, batched_number)
if self.timestep_range is not None:
if t[0] > self.timestep_range[0] or t[0] < self.timestep_range[1]:
if control_prev is not None:
return control_prev
else:
return {}
if self.cond_hint is None or x_noisy.shape[2] * 8 != self.cond_hint.shape[2] or x_noisy.shape[3] * 8 != self.cond_hint.shape[3]:
if self.cond_hint is not None:
del self.cond_hint
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self.control_input = None
self.cond_hint = None
width, height = self.scale_image_to(x_noisy.shape[3] * 8, x_noisy.shape[2] * 8)
self.cond_hint = utils.common_upscale(self.cond_hint_original, width, height, 'nearest-exact', "center").float().to(self.device)
if self.channels_in == 1 and self.cond_hint.shape[1] > 1:
self.cond_hint = torch.mean(self.cond_hint, 1, keepdim=True)
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if x_noisy.shape[0] != self.cond_hint.shape[0]:
self.cond_hint = broadcast_image_to(self.cond_hint, x_noisy.shape[0], batched_number)
if self.control_input is None:
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self.t2i_model.to(x_noisy.dtype)
self.t2i_model.to(self.device)
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self.control_input = self.t2i_model(self.cond_hint.to(x_noisy.dtype))
self.t2i_model.cpu()
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control_input = list(map(lambda a: None if a is None else a.clone(), self.control_input))
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mid = None
if self.t2i_model.xl == True:
mid = control_input[-1:]
control_input = control_input[:-1]
return self.control_merge(control_input, mid, control_prev, x_noisy.dtype)
def copy(self):
c = T2IAdapter(self.t2i_model, self.channels_in)
self.copy_to(c)
return c
def load_t2i_adapter(t2i_data):
keys = t2i_data.keys()
if 'adapter' in keys:
t2i_data = t2i_data['adapter']
keys = t2i_data.keys()
if "body.0.in_conv.weight" in keys:
cin = t2i_data['body.0.in_conv.weight'].shape[1]
model_ad = adapter.Adapter_light(cin=cin, channels=[320, 640, 1280, 1280], nums_rb=4)
elif 'conv_in.weight' in keys:
cin = t2i_data['conv_in.weight'].shape[1]
channel = t2i_data['conv_in.weight'].shape[0]
ksize = t2i_data['body.0.block2.weight'].shape[2]
use_conv = False
down_opts = list(filter(lambda a: a.endswith("down_opt.op.weight"), keys))
if len(down_opts) > 0:
use_conv = True
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xl = False
if cin == 256:
xl = True
model_ad = adapter.Adapter(cin=cin, channels=[channel, channel*2, channel*4, channel*4][:4], nums_rb=2, ksize=ksize, sk=True, use_conv=use_conv, xl=xl)
else:
return None
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missing, unexpected = model_ad.load_state_dict(t2i_data)
if len(missing) > 0:
print("t2i missing", missing)
if len(unexpected) > 0:
print("t2i unexpected", unexpected)
return T2IAdapter(model_ad, model_ad.input_channels)
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class StyleModel:
def __init__(self, model, device="cpu"):
self.model = model
def get_cond(self, input):
return self.model(input.last_hidden_state)
def load_style_model(ckpt_path):
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model_data = utils.load_torch_file(ckpt_path, safe_load=True)
keys = model_data.keys()
if "style_embedding" in keys:
model = adapter.StyleAdapter(width=1024, context_dim=768, num_head=8, n_layes=3, num_token=8)
else:
raise Exception("invalid style model {}".format(ckpt_path))
model.load_state_dict(model_data)
return StyleModel(model)
def load_clip(ckpt_paths, embedding_directory=None):
clip_data = []
for p in ckpt_paths:
clip_data.append(utils.load_torch_file(p, safe_load=True))
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class EmptyClass:
pass
for i in range(len(clip_data)):
if "transformer.resblocks.0.ln_1.weight" in clip_data[i]:
clip_data[i] = utils.transformers_convert(clip_data[i], "", "text_model.", 32)
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clip_target = EmptyClass()
clip_target.params = {}
if len(clip_data) == 1:
if "text_model.encoder.layers.30.mlp.fc1.weight" in clip_data[0]:
clip_target.clip = sdxl_clip.SDXLRefinerClipModel
clip_target.tokenizer = sdxl_clip.SDXLTokenizer
elif "text_model.encoder.layers.22.mlp.fc1.weight" in clip_data[0]:
clip_target.clip = sd2_clip.SD2ClipModel
clip_target.tokenizer = sd2_clip.SD2Tokenizer
else:
clip_target.clip = sd1_clip.SD1ClipModel
clip_target.tokenizer = sd1_clip.SD1Tokenizer
else:
clip_target.clip = sdxl_clip.SDXLClipModel
clip_target.tokenizer = sdxl_clip.SDXLTokenizer
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clip = CLIP(clip_target, embedding_directory=embedding_directory)
for c in clip_data:
m, u = clip.load_sd(c)
if len(m) > 0:
print("clip missing:", m)
if len(u) > 0:
print("clip unexpected:", u)
return clip
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def load_gligen(ckpt_path):
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data = utils.load_torch_file(ckpt_path, safe_load=True)
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model = gligen.load_gligen(data)
if model_management.should_use_fp16():
model = model.half()
return ModelPatcher(model, load_device=model_management.get_torch_device(), offload_device=model_management.unet_offload_device())
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def load_checkpoint(config_path=None, ckpt_path=None, output_vae=True, output_clip=True, embedding_directory=None, state_dict=None, config=None):
#TODO: this function is a mess and should be removed eventually
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if config is None:
with open(config_path, 'r') as stream:
config = yaml.safe_load(stream)
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model_config_params = config['model']['params']
clip_config = model_config_params['cond_stage_config']
scale_factor = model_config_params['scale_factor']
vae_config = model_config_params['first_stage_config']
fp16 = False
if "unet_config" in model_config_params:
if "params" in model_config_params["unet_config"]:
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unet_config = model_config_params["unet_config"]["params"]
if "use_fp16" in unet_config:
fp16 = unet_config["use_fp16"]
noise_aug_config = None
if "noise_aug_config" in model_config_params:
noise_aug_config = model_config_params["noise_aug_config"]
model_type = model_base.ModelType.EPS
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if "parameterization" in model_config_params:
if model_config_params["parameterization"] == "v":
model_type = model_base.ModelType.V_PREDICTION
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clip = None
vae = None
class WeightsLoader(torch.nn.Module):
pass
if state_dict is None:
state_dict = utils.load_torch_file(ckpt_path)
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class EmptyClass:
pass
model_config = EmptyClass()
model_config.unet_config = unet_config
from . import latent_formats
model_config.latent_format = latent_formats.SD15(scale_factor=scale_factor)
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if config['model']["target"].endswith("LatentInpaintDiffusion"):
model = model_base.SDInpaint(model_config, model_type=model_type)
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elif config['model']["target"].endswith("ImageEmbeddingConditionedLatentDiffusion"):
model = model_base.SD21UNCLIP(model_config, noise_aug_config["params"], model_type=model_type)
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else:
model = model_base.BaseModel(model_config, model_type=model_type)
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if fp16:
model = model.half()
offload_device = model_management.unet_offload_device()
model = model.to(offload_device)
model.load_model_weights(state_dict, "model.diffusion_model.")
if output_vae:
w = WeightsLoader()
vae = VAE(config=vae_config)
w.first_stage_model = vae.first_stage_model
load_model_weights(w, state_dict)
if output_clip:
w = WeightsLoader()
clip_target = EmptyClass()
clip_target.params = clip_config.get("params", {})
if clip_config["target"].endswith("FrozenOpenCLIPEmbedder"):
clip_target.clip = sd2_clip.SD2ClipModel
clip_target.tokenizer = sd2_clip.SD2Tokenizer
elif clip_config["target"].endswith("FrozenCLIPEmbedder"):
clip_target.clip = sd1_clip.SD1ClipModel
clip_target.tokenizer = sd1_clip.SD1Tokenizer
clip = CLIP(clip_target, embedding_directory=embedding_directory)
w.cond_stage_model = clip.cond_stage_model
load_clip_weights(w, state_dict)
return (ModelPatcher(model, load_device=model_management.get_torch_device(), offload_device=offload_device), clip, vae)
def calculate_parameters(sd, prefix):
params = 0
for k in sd.keys():
if k.startswith(prefix):
params += sd[k].nelement()
return params
def load_checkpoint_guess_config(ckpt_path, output_vae=True, output_clip=True, output_clipvision=False, embedding_directory=None):
sd = utils.load_torch_file(ckpt_path)
sd_keys = sd.keys()
clip = None
clipvision = None
vae = None
model = None
clip_target = None
parameters = calculate_parameters(sd, "model.diffusion_model.")
fp16 = model_management.should_use_fp16(model_params=parameters)
class WeightsLoader(torch.nn.Module):
pass
model_config = model_detection.model_config_from_unet(sd, "model.diffusion_model.", fp16)
if model_config is None:
raise RuntimeError("ERROR: Could not detect model type of: {}".format(ckpt_path))
if model_config.clip_vision_prefix is not None:
if output_clipvision:
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clipvision = clip_vision.load_clipvision_from_sd(sd, model_config.clip_vision_prefix, True)
dtype = torch.float32
if fp16:
dtype = torch.float16
inital_load_device = model_management.unet_inital_load_device(parameters, dtype)
offload_device = model_management.unet_offload_device()
model = model_config.get_model(sd, "model.diffusion_model.", device=inital_load_device)
model.load_model_weights(sd, "model.diffusion_model.")
if output_vae:
vae = VAE()
w = WeightsLoader()
w.first_stage_model = vae.first_stage_model
load_model_weights(w, sd)
if output_clip:
w = WeightsLoader()
clip_target = model_config.clip_target()
clip = CLIP(clip_target, embedding_directory=embedding_directory)
w.cond_stage_model = clip.cond_stage_model
sd = model_config.process_clip_state_dict(sd)
load_model_weights(w, sd)
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left_over = sd.keys()
if len(left_over) > 0:
print("left over keys:", left_over)
model_patcher = ModelPatcher(model, load_device=model_management.get_torch_device(), offload_device=model_management.unet_offload_device(), current_device=inital_load_device)
if inital_load_device != torch.device("cpu"):
print("loaded straight to GPU")
model_management.load_model_gpu(model_patcher)
return (model_patcher, clip, vae, clipvision)
def load_unet(unet_path): #load unet in diffusers format
sd = utils.load_torch_file(unet_path)
parameters = calculate_parameters(sd, "")
fp16 = model_management.should_use_fp16(model_params=parameters)
model_config = model_detection.model_config_from_diffusers_unet(sd, fp16)
if model_config is None:
print("ERROR UNSUPPORTED UNET", unet_path)
return None
diffusers_keys = utils.unet_to_diffusers(model_config.unet_config)
new_sd = {}
for k in diffusers_keys:
if k in sd:
new_sd[diffusers_keys[k]] = sd.pop(k)
else:
print(diffusers_keys[k], k)
offload_device = model_management.unet_offload_device()
model = model_config.get_model(new_sd, "")
model = model.to(offload_device)
model.load_model_weights(new_sd, "")
return ModelPatcher(model, load_device=model_management.get_torch_device(), offload_device=offload_device)
def save_checkpoint(output_path, model, clip, vae, metadata=None):
model_management.load_models_gpu([model, clip.load_model()])
sd = model.model.state_dict_for_saving(clip.get_sd(), vae.get_sd())
utils.save_torch_file(sd, output_path, metadata=metadata)