Magic-Me / comfy /utils.py
Xue-She Wang
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import torch
import math
import struct
import comfy.checkpoint_pickle
import safetensors.torch
import numpy as np
from PIL import Image
def load_torch_file(ckpt, safe_load=False, device=None):
if device is None:
device = torch.device("cpu")
if ckpt.lower().endswith(".safetensors"):
sd = safetensors.torch.load_file(ckpt, device=device.type)
else:
if safe_load:
if not 'weights_only' in torch.load.__code__.co_varnames:
print("Warning torch.load doesn't support weights_only on this pytorch version, loading unsafely.")
safe_load = False
if safe_load:
pl_sd = torch.load(ckpt, map_location=device, weights_only=True)
else:
pl_sd = torch.load(ckpt, map_location=device, pickle_module=comfy.checkpoint_pickle)
if "global_step" in pl_sd:
print(f"Global Step: {pl_sd['global_step']}")
if "state_dict" in pl_sd:
sd = pl_sd["state_dict"]
else:
sd = pl_sd
return sd
def save_torch_file(sd, ckpt, metadata=None):
if metadata is not None:
safetensors.torch.save_file(sd, ckpt, metadata=metadata)
else:
safetensors.torch.save_file(sd, ckpt)
def calculate_parameters(sd, prefix=""):
params = 0
for k in sd.keys():
if k.startswith(prefix):
params += sd[k].nelement()
return params
def state_dict_key_replace(state_dict, keys_to_replace):
for x in keys_to_replace:
if x in state_dict:
state_dict[keys_to_replace[x]] = state_dict.pop(x)
return state_dict
def state_dict_prefix_replace(state_dict, replace_prefix, filter_keys=False):
if filter_keys:
out = {}
else:
out = state_dict
for rp in replace_prefix:
replace = list(map(lambda a: (a, "{}{}".format(replace_prefix[rp], a[len(rp):])), filter(lambda a: a.startswith(rp), state_dict.keys())))
for x in replace:
w = state_dict.pop(x[0])
out[x[1]] = w
return out
def transformers_convert(sd, prefix_from, prefix_to, number):
keys_to_replace = {
"{}positional_embedding": "{}embeddings.position_embedding.weight",
"{}token_embedding.weight": "{}embeddings.token_embedding.weight",
"{}ln_final.weight": "{}final_layer_norm.weight",
"{}ln_final.bias": "{}final_layer_norm.bias",
}
for k in keys_to_replace:
x = k.format(prefix_from)
if x in sd:
sd[keys_to_replace[k].format(prefix_to)] = sd.pop(x)
resblock_to_replace = {
"ln_1": "layer_norm1",
"ln_2": "layer_norm2",
"mlp.c_fc": "mlp.fc1",
"mlp.c_proj": "mlp.fc2",
"attn.out_proj": "self_attn.out_proj",
}
for resblock in range(number):
for x in resblock_to_replace:
for y in ["weight", "bias"]:
k = "{}transformer.resblocks.{}.{}.{}".format(prefix_from, resblock, x, y)
k_to = "{}encoder.layers.{}.{}.{}".format(prefix_to, resblock, resblock_to_replace[x], y)
if k in sd:
sd[k_to] = sd.pop(k)
for y in ["weight", "bias"]:
k_from = "{}transformer.resblocks.{}.attn.in_proj_{}".format(prefix_from, resblock, y)
if k_from in sd:
weights = sd.pop(k_from)
shape_from = weights.shape[0] // 3
for x in range(3):
p = ["self_attn.q_proj", "self_attn.k_proj", "self_attn.v_proj"]
k_to = "{}encoder.layers.{}.{}.{}".format(prefix_to, resblock, p[x], y)
sd[k_to] = weights[shape_from*x:shape_from*(x + 1)]
return sd
UNET_MAP_ATTENTIONS = {
"proj_in.weight",
"proj_in.bias",
"proj_out.weight",
"proj_out.bias",
"norm.weight",
"norm.bias",
}
TRANSFORMER_BLOCKS = {
"norm1.weight",
"norm1.bias",
"norm2.weight",
"norm2.bias",
"norm3.weight",
"norm3.bias",
"attn1.to_q.weight",
"attn1.to_k.weight",
"attn1.to_v.weight",
"attn1.to_out.0.weight",
"attn1.to_out.0.bias",
"attn2.to_q.weight",
"attn2.to_k.weight",
"attn2.to_v.weight",
"attn2.to_out.0.weight",
"attn2.to_out.0.bias",
"ff.net.0.proj.weight",
"ff.net.0.proj.bias",
"ff.net.2.weight",
"ff.net.2.bias",
}
UNET_MAP_RESNET = {
"in_layers.2.weight": "conv1.weight",
"in_layers.2.bias": "conv1.bias",
"emb_layers.1.weight": "time_emb_proj.weight",
"emb_layers.1.bias": "time_emb_proj.bias",
"out_layers.3.weight": "conv2.weight",
"out_layers.3.bias": "conv2.bias",
"skip_connection.weight": "conv_shortcut.weight",
"skip_connection.bias": "conv_shortcut.bias",
"in_layers.0.weight": "norm1.weight",
"in_layers.0.bias": "norm1.bias",
"out_layers.0.weight": "norm2.weight",
"out_layers.0.bias": "norm2.bias",
}
UNET_MAP_BASIC = {
("label_emb.0.0.weight", "class_embedding.linear_1.weight"),
("label_emb.0.0.bias", "class_embedding.linear_1.bias"),
("label_emb.0.2.weight", "class_embedding.linear_2.weight"),
("label_emb.0.2.bias", "class_embedding.linear_2.bias"),
("label_emb.0.0.weight", "add_embedding.linear_1.weight"),
("label_emb.0.0.bias", "add_embedding.linear_1.bias"),
("label_emb.0.2.weight", "add_embedding.linear_2.weight"),
("label_emb.0.2.bias", "add_embedding.linear_2.bias"),
("input_blocks.0.0.weight", "conv_in.weight"),
("input_blocks.0.0.bias", "conv_in.bias"),
("out.0.weight", "conv_norm_out.weight"),
("out.0.bias", "conv_norm_out.bias"),
("out.2.weight", "conv_out.weight"),
("out.2.bias", "conv_out.bias"),
("time_embed.0.weight", "time_embedding.linear_1.weight"),
("time_embed.0.bias", "time_embedding.linear_1.bias"),
("time_embed.2.weight", "time_embedding.linear_2.weight"),
("time_embed.2.bias", "time_embedding.linear_2.bias")
}
def unet_to_diffusers(unet_config):
num_res_blocks = unet_config["num_res_blocks"]
channel_mult = unet_config["channel_mult"]
transformer_depth = unet_config["transformer_depth"][:]
transformer_depth_output = unet_config["transformer_depth_output"][:]
num_blocks = len(channel_mult)
transformers_mid = unet_config.get("transformer_depth_middle", None)
diffusers_unet_map = {}
for x in range(num_blocks):
n = 1 + (num_res_blocks[x] + 1) * x
for i in range(num_res_blocks[x]):
for b in UNET_MAP_RESNET:
diffusers_unet_map["down_blocks.{}.resnets.{}.{}".format(x, i, UNET_MAP_RESNET[b])] = "input_blocks.{}.0.{}".format(n, b)
num_transformers = transformer_depth.pop(0)
if num_transformers > 0:
for b in UNET_MAP_ATTENTIONS:
diffusers_unet_map["down_blocks.{}.attentions.{}.{}".format(x, i, b)] = "input_blocks.{}.1.{}".format(n, b)
for t in range(num_transformers):
for b in TRANSFORMER_BLOCKS:
diffusers_unet_map["down_blocks.{}.attentions.{}.transformer_blocks.{}.{}".format(x, i, t, b)] = "input_blocks.{}.1.transformer_blocks.{}.{}".format(n, t, b)
n += 1
for k in ["weight", "bias"]:
diffusers_unet_map["down_blocks.{}.downsamplers.0.conv.{}".format(x, k)] = "input_blocks.{}.0.op.{}".format(n, k)
i = 0
for b in UNET_MAP_ATTENTIONS:
diffusers_unet_map["mid_block.attentions.{}.{}".format(i, b)] = "middle_block.1.{}".format(b)
for t in range(transformers_mid):
for b in TRANSFORMER_BLOCKS:
diffusers_unet_map["mid_block.attentions.{}.transformer_blocks.{}.{}".format(i, t, b)] = "middle_block.1.transformer_blocks.{}.{}".format(t, b)
for i, n in enumerate([0, 2]):
for b in UNET_MAP_RESNET:
diffusers_unet_map["mid_block.resnets.{}.{}".format(i, UNET_MAP_RESNET[b])] = "middle_block.{}.{}".format(n, b)
num_res_blocks = list(reversed(num_res_blocks))
for x in range(num_blocks):
n = (num_res_blocks[x] + 1) * x
l = num_res_blocks[x] + 1
for i in range(l):
c = 0
for b in UNET_MAP_RESNET:
diffusers_unet_map["up_blocks.{}.resnets.{}.{}".format(x, i, UNET_MAP_RESNET[b])] = "output_blocks.{}.0.{}".format(n, b)
c += 1
num_transformers = transformer_depth_output.pop()
if num_transformers > 0:
c += 1
for b in UNET_MAP_ATTENTIONS:
diffusers_unet_map["up_blocks.{}.attentions.{}.{}".format(x, i, b)] = "output_blocks.{}.1.{}".format(n, b)
for t in range(num_transformers):
for b in TRANSFORMER_BLOCKS:
diffusers_unet_map["up_blocks.{}.attentions.{}.transformer_blocks.{}.{}".format(x, i, t, b)] = "output_blocks.{}.1.transformer_blocks.{}.{}".format(n, t, b)
if i == l - 1:
for k in ["weight", "bias"]:
diffusers_unet_map["up_blocks.{}.upsamplers.0.conv.{}".format(x, k)] = "output_blocks.{}.{}.conv.{}".format(n, c, k)
n += 1
for k in UNET_MAP_BASIC:
diffusers_unet_map[k[1]] = k[0]
return diffusers_unet_map
def repeat_to_batch_size(tensor, batch_size):
if tensor.shape[0] > batch_size:
return tensor[:batch_size]
elif tensor.shape[0] < batch_size:
return tensor.repeat([math.ceil(batch_size / tensor.shape[0])] + [1] * (len(tensor.shape) - 1))[:batch_size]
return tensor
def resize_to_batch_size(tensor, batch_size):
in_batch_size = tensor.shape[0]
if in_batch_size == batch_size:
return tensor
if batch_size <= 1:
return tensor[:batch_size]
output = torch.empty([batch_size] + list(tensor.shape)[1:], dtype=tensor.dtype, device=tensor.device)
if batch_size < in_batch_size:
scale = (in_batch_size - 1) / (batch_size - 1)
for i in range(batch_size):
output[i] = tensor[min(round(i * scale), in_batch_size - 1)]
else:
scale = in_batch_size / batch_size
for i in range(batch_size):
output[i] = tensor[min(math.floor((i + 0.5) * scale), in_batch_size - 1)]
return output
def convert_sd_to(state_dict, dtype):
keys = list(state_dict.keys())
for k in keys:
state_dict[k] = state_dict[k].to(dtype)
return state_dict
def safetensors_header(safetensors_path, max_size=100*1024*1024):
with open(safetensors_path, "rb") as f:
header = f.read(8)
length_of_header = struct.unpack('<Q', header)[0]
if length_of_header > max_size:
return None
return f.read(length_of_header)
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, requires_grad=False))
del prev
def copy_to_param(obj, attr, value):
# inplace update tensor instead of replacing it
attrs = attr.split(".")
for name in attrs[:-1]:
obj = getattr(obj, name)
prev = getattr(obj, attrs[-1])
prev.data.copy_(value)
def get_attr(obj, attr):
attrs = attr.split(".")
for name in attrs:
obj = getattr(obj, name)
return obj
def bislerp(samples, width, height):
def slerp(b1, b2, r):
'''slerps batches b1, b2 according to ratio r, batches should be flat e.g. NxC'''
c = b1.shape[-1]
#norms
b1_norms = torch.norm(b1, dim=-1, keepdim=True)
b2_norms = torch.norm(b2, dim=-1, keepdim=True)
#normalize
b1_normalized = b1 / b1_norms
b2_normalized = b2 / b2_norms
#zero when norms are zero
b1_normalized[b1_norms.expand(-1,c) == 0.0] = 0.0
b2_normalized[b2_norms.expand(-1,c) == 0.0] = 0.0
#slerp
dot = (b1_normalized*b2_normalized).sum(1)
omega = torch.acos(dot)
so = torch.sin(omega)
#technically not mathematically correct, but more pleasing?
res = (torch.sin((1.0-r.squeeze(1))*omega)/so).unsqueeze(1)*b1_normalized + (torch.sin(r.squeeze(1)*omega)/so).unsqueeze(1) * b2_normalized
res *= (b1_norms * (1.0-r) + b2_norms * r).expand(-1,c)
#edge cases for same or polar opposites
res[dot > 1 - 1e-5] = b1[dot > 1 - 1e-5]
res[dot < 1e-5 - 1] = (b1 * (1.0-r) + b2 * r)[dot < 1e-5 - 1]
return res
def generate_bilinear_data(length_old, length_new, device):
coords_1 = torch.arange(length_old, dtype=torch.float32, device=device).reshape((1,1,1,-1))
coords_1 = torch.nn.functional.interpolate(coords_1, size=(1, length_new), mode="bilinear")
ratios = coords_1 - coords_1.floor()
coords_1 = coords_1.to(torch.int64)
coords_2 = torch.arange(length_old, dtype=torch.float32, device=device).reshape((1,1,1,-1)) + 1
coords_2[:,:,:,-1] -= 1
coords_2 = torch.nn.functional.interpolate(coords_2, size=(1, length_new), mode="bilinear")
coords_2 = coords_2.to(torch.int64)
return ratios, coords_1, coords_2
orig_dtype = samples.dtype
samples = samples.float()
n,c,h,w = samples.shape
h_new, w_new = (height, width)
#linear w
ratios, coords_1, coords_2 = generate_bilinear_data(w, w_new, samples.device)
coords_1 = coords_1.expand((n, c, h, -1))
coords_2 = coords_2.expand((n, c, h, -1))
ratios = ratios.expand((n, 1, h, -1))
pass_1 = samples.gather(-1,coords_1).movedim(1, -1).reshape((-1,c))
pass_2 = samples.gather(-1,coords_2).movedim(1, -1).reshape((-1,c))
ratios = ratios.movedim(1, -1).reshape((-1,1))
result = slerp(pass_1, pass_2, ratios)
result = result.reshape(n, h, w_new, c).movedim(-1, 1)
#linear h
ratios, coords_1, coords_2 = generate_bilinear_data(h, h_new, samples.device)
coords_1 = coords_1.reshape((1,1,-1,1)).expand((n, c, -1, w_new))
coords_2 = coords_2.reshape((1,1,-1,1)).expand((n, c, -1, w_new))
ratios = ratios.reshape((1,1,-1,1)).expand((n, 1, -1, w_new))
pass_1 = result.gather(-2,coords_1).movedim(1, -1).reshape((-1,c))
pass_2 = result.gather(-2,coords_2).movedim(1, -1).reshape((-1,c))
ratios = ratios.movedim(1, -1).reshape((-1,1))
result = slerp(pass_1, pass_2, ratios)
result = result.reshape(n, h_new, w_new, c).movedim(-1, 1)
return result.to(orig_dtype)
def lanczos(samples, width, height):
images = [Image.fromarray(np.clip(255. * image.movedim(0, -1).cpu().numpy(), 0, 255).astype(np.uint8)) for image in samples]
images = [image.resize((width, height), resample=Image.Resampling.LANCZOS) for image in images]
images = [torch.from_numpy(np.array(image).astype(np.float32) / 255.0).movedim(-1, 0) for image in images]
result = torch.stack(images)
return result.to(samples.device, samples.dtype)
def common_upscale(samples, width, height, upscale_method, crop):
if crop == "center":
old_width = samples.shape[3]
old_height = samples.shape[2]
old_aspect = old_width / old_height
new_aspect = width / height
x = 0
y = 0
if old_aspect > new_aspect:
x = round((old_width - old_width * (new_aspect / old_aspect)) / 2)
elif old_aspect < new_aspect:
y = round((old_height - old_height * (old_aspect / new_aspect)) / 2)
s = samples[:,:,y:old_height-y,x:old_width-x]
else:
s = samples
if upscale_method == "bislerp":
return bislerp(s, width, height)
elif upscale_method == "lanczos":
return lanczos(s, width, height)
else:
return torch.nn.functional.interpolate(s, size=(height, width), mode=upscale_method)
def get_tiled_scale_steps(width, height, tile_x, tile_y, overlap):
return math.ceil((height / (tile_y - overlap))) * math.ceil((width / (tile_x - overlap)))
@torch.inference_mode()
def tiled_scale(samples, function, tile_x=64, tile_y=64, overlap = 8, upscale_amount = 4, out_channels = 3, output_device="cpu", pbar = None):
output = torch.empty((samples.shape[0], out_channels, round(samples.shape[2] * upscale_amount), round(samples.shape[3] * upscale_amount)), device=output_device)
for b in range(samples.shape[0]):
s = samples[b:b+1]
out = torch.zeros((s.shape[0], out_channels, round(s.shape[2] * upscale_amount), round(s.shape[3] * upscale_amount)), device=output_device)
out_div = torch.zeros((s.shape[0], out_channels, round(s.shape[2] * upscale_amount), round(s.shape[3] * upscale_amount)), device=output_device)
for y in range(0, s.shape[2], tile_y - overlap):
for x in range(0, s.shape[3], tile_x - overlap):
x = max(0, min(s.shape[-1] - overlap, x))
y = max(0, min(s.shape[-2] - overlap, y))
s_in = s[:,:,y:y+tile_y,x:x+tile_x]
ps = function(s_in).to(output_device)
mask = torch.ones_like(ps)
feather = round(overlap * upscale_amount)
for t in range(feather):
mask[:,:,t:1+t,:] *= ((1.0/feather) * (t + 1))
mask[:,:,mask.shape[2] -1 -t: mask.shape[2]-t,:] *= ((1.0/feather) * (t + 1))
mask[:,:,:,t:1+t] *= ((1.0/feather) * (t + 1))
mask[:,:,:,mask.shape[3]- 1 - t: mask.shape[3]- t] *= ((1.0/feather) * (t + 1))
out[:,:,round(y*upscale_amount):round((y+tile_y)*upscale_amount),round(x*upscale_amount):round((x+tile_x)*upscale_amount)] += ps * mask
out_div[:,:,round(y*upscale_amount):round((y+tile_y)*upscale_amount),round(x*upscale_amount):round((x+tile_x)*upscale_amount)] += mask
if pbar is not None:
pbar.update(1)
output[b:b+1] = out/out_div
return output
PROGRESS_BAR_ENABLED = True
def set_progress_bar_enabled(enabled):
global PROGRESS_BAR_ENABLED
PROGRESS_BAR_ENABLED = enabled
PROGRESS_BAR_HOOK = None
def set_progress_bar_global_hook(function):
global PROGRESS_BAR_HOOK
PROGRESS_BAR_HOOK = function
class ProgressBar:
def __init__(self, total):
global PROGRESS_BAR_HOOK
self.total = total
self.current = 0
self.hook = PROGRESS_BAR_HOOK
def update_absolute(self, value, total=None, preview=None):
if total is not None:
self.total = total
if value > self.total:
value = self.total
self.current = value
if self.hook is not None:
self.hook(self.current, self.total, preview)
def update(self, value):
self.update_absolute(self.current + value)