import json import math from itertools import groupby import os from typing import Callable, Dict, List, Optional, Set, Tuple, Type, Union import numpy as np import PIL import torch import torch.nn as nn import torch.nn.functional as F try: from safetensors.torch import safe_open from safetensors.torch import save_file as safe_save safetensors_available = True except ImportError: from .safe_open import safe_open def safe_save( tensors: Dict[str, torch.Tensor], filename: str, metadata: Optional[Dict[str, str]] = None, ) -> None: raise EnvironmentError( "Saving safetensors requires the safetensors library. Please install with pip or similar." ) safetensors_available = False from diffusers.models.lora import LoRACompatibleLinear class LoraInjectedLinear(nn.Module): def __init__( self, in_features, out_features, bias=False, r=4, dropout_p=0.1, scale=1.0 ): super().__init__() if r > min(in_features, out_features): #raise ValueError( # f"LoRA rank {r} must be less or equal than {min(in_features, out_features)}" #) print(f"LoRA rank {r} is too large. setting to: {min(in_features, out_features)}") r = min(in_features, out_features) self.r = r self.linear = nn.Linear(in_features, out_features, bias) self.lora_down = nn.Linear(in_features, r, bias=False) self.dropout = nn.Dropout(dropout_p) self.lora_up = nn.Linear(r, out_features, bias=False) self.scale = scale self.selector = nn.Identity() nn.init.normal_(self.lora_down.weight, std=1 / r) nn.init.zeros_(self.lora_up.weight) def forward(self, hidden_states: torch.Tensor, scale: float = 1.0): return ( self.linear(hidden_states) + self.dropout(self.lora_up(self.selector(self.lora_down(hidden_states)))) * self.scale ) def realize_as_lora(self): return self.lora_up.weight.data * self.scale, self.lora_down.weight.data def set_selector_from_diag(self, diag: torch.Tensor): # diag is a 1D tensor of size (r,) assert diag.shape == (self.r,) self.selector = nn.Linear(self.r, self.r, bias=False) self.selector.weight.data = torch.diag(diag) self.selector.weight.data = self.selector.weight.data.to( self.lora_up.weight.device ).to(self.lora_up.weight.dtype) class MultiLoraInjectedLinear(nn.Module): def __init__( self, in_features, out_features, bias=False, r=4, dropout_p=0.1, lora_num=1, scales=[1.0] ): super().__init__() if r > min(in_features, out_features): #raise ValueError( # f"LoRA rank {r} must be less or equal than {min(in_features, out_features)}" #) print(f"LoRA rank {r} is too large. setting to: {min(in_features, out_features)}") r = min(in_features, out_features) self.r = r self.linear = nn.Linear(in_features, out_features, bias) for i in range(lora_num): if i==0: self.lora_down =[nn.Linear(in_features, r, bias=False)] self.dropout = [nn.Dropout(dropout_p)] self.lora_up = [nn.Linear(r, out_features, bias=False)] self.scale = scales[i] self.selector = [nn.Identity()] else: self.lora_down.append(nn.Linear(in_features, r, bias=False)) self.dropout.append( nn.Dropout(dropout_p)) self.lora_up.append( nn.Linear(r, out_features, bias=False)) self.scale.append(scales[i]) nn.init.normal_(self.lora_down.weight, std=1 / r) nn.init.zeros_(self.lora_up.weight) def forward(self, input): return ( self.linear(input) + self.dropout(self.lora_up(self.selector(self.lora_down(input)))) * self.scale ) def realize_as_lora(self): return self.lora_up.weight.data * self.scale, self.lora_down.weight.data def set_selector_from_diag(self, diag: torch.Tensor): # diag is a 1D tensor of size (r,) assert diag.shape == (self.r,) self.selector = nn.Linear(self.r, self.r, bias=False) self.selector.weight.data = torch.diag(diag) self.selector.weight.data = self.selector.weight.data.to( self.lora_up.weight.device ).to(self.lora_up.weight.dtype) class LoraInjectedConv2d(nn.Module): def __init__( self, in_channels: int, out_channels: int, kernel_size, stride=1, padding=0, dilation=1, groups: int = 1, bias: bool = True, r: int = 4, dropout_p: float = 0.1, scale: float = 1.0, ): super().__init__() if r > min(in_channels, out_channels): print(f"LoRA rank {r} is too large. setting to: {min(in_channels, out_channels)}") r = min(in_channels, out_channels) self.r = r self.conv = nn.Conv2d( in_channels=in_channels, out_channels=out_channels, kernel_size=kernel_size, stride=stride, padding=padding, dilation=dilation, groups=groups, bias=bias, ) self.lora_down = nn.Conv2d( in_channels=in_channels, out_channels=r, kernel_size=kernel_size, stride=stride, padding=padding, dilation=dilation, groups=groups, bias=False, ) self.dropout = nn.Dropout(dropout_p) self.lora_up = nn.Conv2d( in_channels=r, out_channels=out_channels, kernel_size=1, stride=1, padding=0, bias=False, ) self.selector = nn.Identity() self.scale = scale nn.init.normal_(self.lora_down.weight, std=1 / r) nn.init.zeros_(self.lora_up.weight) def forward(self, input): return ( self.conv(input) + self.dropout(self.lora_up(self.selector(self.lora_down(input)))) * self.scale ) def realize_as_lora(self): return self.lora_up.weight.data * self.scale, self.lora_down.weight.data def set_selector_from_diag(self, diag: torch.Tensor): # diag is a 1D tensor of size (r,) assert diag.shape == (self.r,) self.selector = nn.Conv2d( in_channels=self.r, out_channels=self.r, kernel_size=1, stride=1, padding=0, bias=False, ) self.selector.weight.data = torch.diag(diag) # same device + dtype as lora_up self.selector.weight.data = self.selector.weight.data.to( self.lora_up.weight.device ).to(self.lora_up.weight.dtype) class LoraInjectedConv3d(nn.Module): def __init__( self, in_channels: int, out_channels: int, kernel_size: (3, 1, 1), padding: (1, 0, 0), bias: bool = False, r: int = 4, dropout_p: float = 0, scale: float = 1.0, ): super().__init__() if r > min(in_channels, out_channels): print(f"LoRA rank {r} is too large. setting to: {min(in_channels, out_channels)}") r = min(in_channels, out_channels) self.r = r self.kernel_size = kernel_size self.padding = padding self.conv = nn.Conv3d( in_channels=in_channels, out_channels=out_channels, kernel_size=kernel_size, padding=padding, ) self.lora_down = nn.Conv3d( in_channels=in_channels, out_channels=r, kernel_size=kernel_size, bias=False, padding=padding ) self.dropout = nn.Dropout(dropout_p) self.lora_up = nn.Conv3d( in_channels=r, out_channels=out_channels, kernel_size=1, stride=1, padding=0, bias=False, ) self.selector = nn.Identity() self.scale = scale nn.init.normal_(self.lora_down.weight, std=1 / r) nn.init.zeros_(self.lora_up.weight) def forward(self, input): return ( self.conv(input) + self.dropout(self.lora_up(self.selector(self.lora_down(input)))) * self.scale ) def realize_as_lora(self): return self.lora_up.weight.data * self.scale, self.lora_down.weight.data def set_selector_from_diag(self, diag: torch.Tensor): # diag is a 1D tensor of size (r,) assert diag.shape == (self.r,) self.selector = nn.Conv3d( in_channels=self.r, out_channels=self.r, kernel_size=1, stride=1, padding=0, bias=False, ) self.selector.weight.data = torch.diag(diag) # same device + dtype as lora_up self.selector.weight.data = self.selector.weight.data.to( self.lora_up.weight.device ).to(self.lora_up.weight.dtype) UNET_DEFAULT_TARGET_REPLACE = {"CrossAttention", "Attention", "GEGLU"} UNET_EXTENDED_TARGET_REPLACE = {"ResnetBlock2D", "CrossAttention", "Attention", "GEGLU"} TEXT_ENCODER_DEFAULT_TARGET_REPLACE = {"CLIPAttention"} TEXT_ENCODER_EXTENDED_TARGET_REPLACE = {"CLIPAttention"} DEFAULT_TARGET_REPLACE = UNET_DEFAULT_TARGET_REPLACE EMBED_FLAG = "" def _find_children( model, search_class: List[Type[nn.Module]] = [nn.Linear], ): """ Find all modules of a certain class (or union of classes). Returns all matching modules, along with the parent of those moduless and the names they are referenced by. """ # For each target find every linear_class module that isn't a child of a LoraInjectedLinear for parent in model.modules(): for name, module in parent.named_children(): if any([isinstance(module, _class) for _class in search_class]): yield parent, name, module def _find_modules_v2( model, ancestor_class: Optional[Set[str]] = None, search_class: List[Type[nn.Module]] = [nn.Linear], exclude_children_of: Optional[List[Type[nn.Module]]] = None, # [ # LoraInjectedLinear, # LoraInjectedConv2d, # LoraInjectedConv3d # ], ): """ Find all modules of a certain class (or union of classes) that are direct or indirect descendants of other modules of a certain class (or union of classes). Returns all matching modules, along with the parent of those moduless and the names they are referenced by. """ # Get the targets we should replace all linears under if ancestor_class is not None: ancestors = ( module for name, module in model.named_modules() if module.__class__.__name__ in ancestor_class # and ('transformer_in' not in name) ) else: # this, incase you want to naively iterate over all modules. ancestors = [module for module in model.modules()] # For each target find every linear_class module that isn't a child of a LoraInjectedLinear for ancestor in ancestors: for fullname, module in ancestor.named_modules(): if any([isinstance(module, _class) for _class in search_class]): continue_flag = True if 'Transformer2DModel' in ancestor_class and ('attn1' in fullname or 'ff' in fullname): continue_flag = False if 'TransformerTemporalModel' in ancestor_class and ('attn1' in fullname or 'attn2' in fullname or 'ff' in fullname): continue_flag = False if continue_flag: continue # Find the direct parent if this is a descendant, not a child, of target *path, name = fullname.split(".") parent = ancestor while path: parent = parent.get_submodule(path.pop(0)) # Skip this linear if it's a child of a LoraInjectedLinear if exclude_children_of and any( [isinstance(parent, _class) for _class in exclude_children_of] ): continue if name in ['lora_up', 'dropout', 'lora_down']: continue # Otherwise, yield it yield parent, name, module def _find_modules_old( model, ancestor_class: Set[str] = DEFAULT_TARGET_REPLACE, search_class: List[Type[nn.Module]] = [nn.Linear], exclude_children_of: Optional[List[Type[nn.Module]]] = [LoraInjectedLinear], ): ret = [] for _module in model.modules(): if _module.__class__.__name__ in ancestor_class: for name, _child_module in _module.named_modules(): if _child_module.__class__ in search_class: ret.append((_module, name, _child_module)) print(ret) return ret _find_modules = _find_modules_v2 def inject_trainable_lora( model: nn.Module, target_replace_module: Set[str] = DEFAULT_TARGET_REPLACE, r: int = 4, loras=None, # path to lora .pt verbose: bool = False, dropout_p: float = 0.0, scale: float = 1.0, ): """ inject lora into model, and returns lora parameter groups. """ require_grad_params = [] names = [] if loras != None: loras = torch.load(loras) for _module, name, _child_module in _find_modules( model, target_replace_module, search_class=[nn.Linear] ): weight = _child_module.weight bias = _child_module.bias if verbose: print("LoRA Injection : injecting lora into ", name) print("LoRA Injection : weight shape", weight.shape) _tmp = LoraInjectedLinear( _child_module.in_features, _child_module.out_features, _child_module.bias is not None, r=r, dropout_p=dropout_p, scale=scale, ) _tmp.linear.weight = weight if bias is not None: _tmp.linear.bias = bias # switch the module _tmp.to(_child_module.weight.device).to(_child_module.weight.dtype) _module._modules[name] = _tmp require_grad_params.append(_module._modules[name].lora_up.parameters()) require_grad_params.append(_module._modules[name].lora_down.parameters()) if loras != None: _module._modules[name].lora_up.weight = loras.pop(0) _module._modules[name].lora_down.weight = loras.pop(0) _module._modules[name].lora_up.weight.requires_grad = True _module._modules[name].lora_down.weight.requires_grad = True names.append(name) return require_grad_params, names def inject_trainable_lora_extended( model: nn.Module, target_replace_module: Set[str] = UNET_EXTENDED_TARGET_REPLACE, r: int = 4, loras=None, # path to lora .pt dropout_p: float = 0.0, scale: float = 1.0, ): """ inject lora into model, and returns lora parameter groups. """ require_grad_params = [] names = [] if loras != None: loras = torch.load(loras) if True: for target_replace_module_i in target_replace_module: for _module, name, _child_module in _find_modules( model, [target_replace_module_i], search_class=[LoRACompatibleLinear, nn.Conv2d, nn.Conv3d] ): # if name == 'to_q': # continue if _child_module.__class__ == LoRACompatibleLinear: weight = _child_module.weight bias = _child_module.bias _tmp = LoraInjectedLinear( _child_module.in_features, _child_module.out_features, _child_module.bias is not None, r=r, dropout_p=dropout_p, scale=scale, ) _tmp.linear.weight = weight if bias is not None: _tmp.linear.bias = bias elif _child_module.__class__ == nn.Conv2d: weight = _child_module.weight bias = _child_module.bias _tmp = LoraInjectedConv2d( _child_module.in_channels, _child_module.out_channels, _child_module.kernel_size, _child_module.stride, _child_module.padding, _child_module.dilation, _child_module.groups, _child_module.bias is not None, r=r, dropout_p=dropout_p, scale=scale, ) _tmp.conv.weight = weight if bias is not None: _tmp.conv.bias = bias elif _child_module.__class__ == nn.Conv3d: weight = _child_module.weight bias = _child_module.bias _tmp = LoraInjectedConv3d( _child_module.in_channels, _child_module.out_channels, bias=_child_module.bias is not None, kernel_size=_child_module.kernel_size, padding=_child_module.padding, r=r, dropout_p=dropout_p, scale=scale, ) _tmp.conv.weight = weight if bias is not None: _tmp.conv.bias = bias # switch the module _tmp.to(_child_module.weight.device).to(_child_module.weight.dtype) if bias is not None: _tmp.to(_child_module.bias.device).to(_child_module.bias.dtype) _module._modules[name] = _tmp require_grad_params.append(_module._modules[name].lora_up.parameters()) require_grad_params.append(_module._modules[name].lora_down.parameters()) if loras != None: _module._modules[name].lora_up.weight = loras.pop(0) _module._modules[name].lora_down.weight = loras.pop(0) _module._modules[name].lora_up.weight.requires_grad = True _module._modules[name].lora_down.weight.requires_grad = True names.append(name) else: for _module, name, _child_module in _find_modules( model, target_replace_module, search_class=[nn.Linear, nn.Conv2d, nn.Conv3d] ): if _child_module.__class__ == nn.Linear: weight = _child_module.weight bias = _child_module.bias _tmp = LoraInjectedLinear( _child_module.in_features, _child_module.out_features, _child_module.bias is not None, r=r, dropout_p=dropout_p, scale=scale, ) _tmp.linear.weight = weight if bias is not None: _tmp.linear.bias = bias elif _child_module.__class__ == nn.Conv2d: weight = _child_module.weight bias = _child_module.bias _tmp = LoraInjectedConv2d( _child_module.in_channels, _child_module.out_channels, _child_module.kernel_size, _child_module.stride, _child_module.padding, _child_module.dilation, _child_module.groups, _child_module.bias is not None, r=r, dropout_p=dropout_p, scale=scale, ) _tmp.conv.weight = weight if bias is not None: _tmp.conv.bias = bias elif _child_module.__class__ == nn.Conv3d: weight = _child_module.weight bias = _child_module.bias _tmp = LoraInjectedConv3d( _child_module.in_channels, _child_module.out_channels, bias=_child_module.bias is not None, kernel_size=_child_module.kernel_size, padding=_child_module.padding, r=r, dropout_p=dropout_p, scale=scale, ) _tmp.conv.weight = weight if bias is not None: _tmp.conv.bias = bias # switch the module _tmp.to(_child_module.weight.device).to(_child_module.weight.dtype) if bias is not None: _tmp.to(_child_module.bias.device).to(_child_module.bias.dtype) _module._modules[name] = _tmp require_grad_params.append(_module._modules[name].lora_up.parameters()) require_grad_params.append(_module._modules[name].lora_down.parameters()) if loras != None: _module._modules[name].lora_up.weight = loras.pop(0) _module._modules[name].lora_down.weight = loras.pop(0) _module._modules[name].lora_up.weight.requires_grad = True _module._modules[name].lora_down.weight.requires_grad = True names.append(name) return require_grad_params, names def inject_inferable_lora( model, lora_path='', unet_replace_modules=["UNet3DConditionModel"], text_encoder_replace_modules=["CLIPEncoderLayer"], is_extended=False, r=16 ): from transformers.models.clip import CLIPTextModel from diffusers import UNet3DConditionModel def is_text_model(f): return 'text_encoder' in f and isinstance(model.text_encoder, CLIPTextModel) def is_unet(f): return 'unet' in f and model.unet.__class__.__name__ == "UNet3DConditionModel" if os.path.exists(lora_path): try: for f in os.listdir(lora_path): if f.endswith('.pt'): lora_file = os.path.join(lora_path, f) if is_text_model(f): monkeypatch_or_replace_lora( model.text_encoder, torch.load(lora_file), target_replace_module=text_encoder_replace_modules, r=r ) print("Successfully loaded Text Encoder LoRa.") continue if is_unet(f): monkeypatch_or_replace_lora_extended( model.unet, torch.load(lora_file), target_replace_module=unet_replace_modules, r=r ) print("Successfully loaded UNET LoRa.") continue print("Found a .pt file, but doesn't have the correct name format. (unet.pt, text_encoder.pt)") except Exception as e: print(e) print("Couldn't inject LoRA's due to an error.") def extract_lora_ups_down(model, target_replace_module=DEFAULT_TARGET_REPLACE): loras = [] for target_replace_module_i in target_replace_module: for _m, _n, _child_module in _find_modules( model, [target_replace_module_i], search_class=[LoraInjectedLinear, LoraInjectedConv2d, LoraInjectedConv3d], ): loras.append((_child_module.lora_up, _child_module.lora_down)) if len(loras) == 0: raise ValueError("No lora injected.") return loras def extract_lora_child_module(model, target_replace_module=DEFAULT_TARGET_REPLACE): loras = [] for target_replace_module_i in target_replace_module: for _m, _n, _child_module in _find_modules( model, [target_replace_module_i], search_class=[LoraInjectedLinear, LoraInjectedConv2d, LoraInjectedConv3d], ): loras.append(_child_module) return loras def extract_lora_as_tensor( model, target_replace_module=DEFAULT_TARGET_REPLACE, as_fp16=True ): loras = [] for _m, _n, _child_module in _find_modules( model, target_replace_module, search_class=[LoraInjectedLinear, LoraInjectedConv2d, LoraInjectedConv3d], ): up, down = _child_module.realize_as_lora() if as_fp16: up = up.to(torch.float16) down = down.to(torch.float16) loras.append((up, down)) if len(loras) == 0: raise ValueError("No lora injected.") return loras def save_lora_weight( model, path="./lora.pt", target_replace_module=DEFAULT_TARGET_REPLACE, flag=None ): weights = [] for _up, _down in extract_lora_ups_down( model, target_replace_module=target_replace_module ): weights.append(_up.weight.to("cpu").to(torch.float32)) weights.append(_down.weight.to("cpu").to(torch.float32)) if not flag: torch.save(weights, path) else: weights_new=[] for i in range(0, len(weights), 4): subset = weights[i+(flag-1)*2:i+(flag-1)*2+2] weights_new.extend(subset) torch.save(weights_new, path) def save_lora_as_json(model, path="./lora.json"): weights = [] for _up, _down in extract_lora_ups_down(model): weights.append(_up.weight.detach().cpu().numpy().tolist()) weights.append(_down.weight.detach().cpu().numpy().tolist()) import json with open(path, "w") as f: json.dump(weights, f) def save_safeloras_with_embeds( modelmap: Dict[str, Tuple[nn.Module, Set[str]]] = {}, embeds: Dict[str, torch.Tensor] = {}, outpath="./lora.safetensors", ): """ Saves the Lora from multiple modules in a single safetensor file. modelmap is a dictionary of { "module name": (module, target_replace_module) } """ weights = {} metadata = {} for name, (model, target_replace_module) in modelmap.items(): metadata[name] = json.dumps(list(target_replace_module)) for i, (_up, _down) in enumerate( extract_lora_as_tensor(model, target_replace_module) ): rank = _down.shape[0] metadata[f"{name}:{i}:rank"] = str(rank) weights[f"{name}:{i}:up"] = _up weights[f"{name}:{i}:down"] = _down for token, tensor in embeds.items(): metadata[token] = EMBED_FLAG weights[token] = tensor print(f"Saving weights to {outpath}") safe_save(weights, outpath, metadata) def save_safeloras( modelmap: Dict[str, Tuple[nn.Module, Set[str]]] = {}, outpath="./lora.safetensors", ): return save_safeloras_with_embeds(modelmap=modelmap, outpath=outpath) def convert_loras_to_safeloras_with_embeds( modelmap: Dict[str, Tuple[str, Set[str], int]] = {}, embeds: Dict[str, torch.Tensor] = {}, outpath="./lora.safetensors", ): """ Converts the Lora from multiple pytorch .pt files into a single safetensor file. modelmap is a dictionary of { "module name": (pytorch_model_path, target_replace_module, rank) } """ weights = {} metadata = {} for name, (path, target_replace_module, r) in modelmap.items(): metadata[name] = json.dumps(list(target_replace_module)) lora = torch.load(path) for i, weight in enumerate(lora): is_up = i % 2 == 0 i = i // 2 if is_up: metadata[f"{name}:{i}:rank"] = str(r) weights[f"{name}:{i}:up"] = weight else: weights[f"{name}:{i}:down"] = weight for token, tensor in embeds.items(): metadata[token] = EMBED_FLAG weights[token] = tensor print(f"Saving weights to {outpath}") safe_save(weights, outpath, metadata) def convert_loras_to_safeloras( modelmap: Dict[str, Tuple[str, Set[str], int]] = {}, outpath="./lora.safetensors", ): convert_loras_to_safeloras_with_embeds(modelmap=modelmap, outpath=outpath) def parse_safeloras( safeloras, ) -> Dict[str, Tuple[List[nn.parameter.Parameter], List[int], List[str]]]: """ Converts a loaded safetensor file that contains a set of module Loras into Parameters and other information Output is a dictionary of { "module name": ( [list of weights], [list of ranks], target_replacement_modules ) } """ loras = {} metadata = safeloras.metadata() get_name = lambda k: k.split(":")[0] keys = list(safeloras.keys()) keys.sort(key=get_name) for name, module_keys in groupby(keys, get_name): info = metadata.get(name) if not info: raise ValueError( f"Tensor {name} has no metadata - is this a Lora safetensor?" ) # Skip Textual Inversion embeds if info == EMBED_FLAG: continue # Handle Loras # Extract the targets target = json.loads(info) # Build the result lists - Python needs us to preallocate lists to insert into them module_keys = list(module_keys) ranks = [4] * (len(module_keys) // 2) weights = [None] * len(module_keys) for key in module_keys: # Split the model name and index out of the key _, idx, direction = key.split(":") idx = int(idx) # Add the rank ranks[idx] = int(metadata[f"{name}:{idx}:rank"]) # Insert the weight into the list idx = idx * 2 + (1 if direction == "down" else 0) weights[idx] = nn.parameter.Parameter(safeloras.get_tensor(key)) loras[name] = (weights, ranks, target) return loras def parse_safeloras_embeds( safeloras, ) -> Dict[str, torch.Tensor]: """ Converts a loaded safetensor file that contains Textual Inversion embeds into a dictionary of embed_token: Tensor """ embeds = {} metadata = safeloras.metadata() for key in safeloras.keys(): # Only handle Textual Inversion embeds meta = metadata.get(key) if not meta or meta != EMBED_FLAG: continue embeds[key] = safeloras.get_tensor(key) return embeds def load_safeloras(path, device="cpu"): safeloras = safe_open(path, framework="pt", device=device) return parse_safeloras(safeloras) def load_safeloras_embeds(path, device="cpu"): safeloras = safe_open(path, framework="pt", device=device) return parse_safeloras_embeds(safeloras) def load_safeloras_both(path, device="cpu"): safeloras = safe_open(path, framework="pt", device=device) return parse_safeloras(safeloras), parse_safeloras_embeds(safeloras) def collapse_lora(model, alpha=1.0): for _module, name, _child_module in _find_modules( model, UNET_EXTENDED_TARGET_REPLACE | TEXT_ENCODER_EXTENDED_TARGET_REPLACE, search_class=[LoraInjectedLinear, LoraInjectedConv2d, LoraInjectedConv3d], ): if isinstance(_child_module, LoraInjectedLinear): print("Collapsing Lin Lora in", name) _child_module.linear.weight = nn.Parameter( _child_module.linear.weight.data + alpha * ( _child_module.lora_up.weight.data @ _child_module.lora_down.weight.data ) .type(_child_module.linear.weight.dtype) .to(_child_module.linear.weight.device) ) else: print("Collapsing Conv Lora in", name) _child_module.conv.weight = nn.Parameter( _child_module.conv.weight.data + alpha * ( _child_module.lora_up.weight.data.flatten(start_dim=1) @ _child_module.lora_down.weight.data.flatten(start_dim=1) ) .reshape(_child_module.conv.weight.data.shape) .type(_child_module.conv.weight.dtype) .to(_child_module.conv.weight.device) ) def monkeypatch_or_replace_lora( model, loras, target_replace_module=DEFAULT_TARGET_REPLACE, r: Union[int, List[int]] = 4, ): for _module, name, _child_module in _find_modules( model, target_replace_module, search_class=[nn.Linear, LoraInjectedLinear] ): _source = ( _child_module.linear if isinstance(_child_module, LoraInjectedLinear) else _child_module ) weight = _source.weight bias = _source.bias _tmp = LoraInjectedLinear( _source.in_features, _source.out_features, _source.bias is not None, r=r.pop(0) if isinstance(r, list) else r, ) _tmp.linear.weight = weight if bias is not None: _tmp.linear.bias = bias # switch the module _module._modules[name] = _tmp up_weight = loras.pop(0) down_weight = loras.pop(0) _module._modules[name].lora_up.weight = nn.Parameter( up_weight.type(weight.dtype) ) _module._modules[name].lora_down.weight = nn.Parameter( down_weight.type(weight.dtype) ) _module._modules[name].to(weight.device) def monkeypatch_or_replace_lora_extended( model, loras, target_replace_module=DEFAULT_TARGET_REPLACE, r: Union[int, List[int]] = 4, ): for _module, name, _child_module in _find_modules( model, target_replace_module, search_class=[ nn.Linear, nn.Conv2d, nn.Conv3d, LoraInjectedLinear, LoraInjectedConv2d, LoraInjectedConv3d, ], ): if (_child_module.__class__ == nn.Linear) or ( _child_module.__class__ == LoraInjectedLinear ): if len(loras[0].shape) != 2: continue _source = ( _child_module.linear if isinstance(_child_module, LoraInjectedLinear) else _child_module ) weight = _source.weight bias = _source.bias _tmp = LoraInjectedLinear( _source.in_features, _source.out_features, _source.bias is not None, r=r.pop(0) if isinstance(r, list) else r, ) _tmp.linear.weight = weight if bias is not None: _tmp.linear.bias = bias elif (_child_module.__class__ == nn.Conv2d) or ( _child_module.__class__ == LoraInjectedConv2d ): if len(loras[0].shape) != 4: continue _source = ( _child_module.conv if isinstance(_child_module, LoraInjectedConv2d) else _child_module ) weight = _source.weight bias = _source.bias _tmp = LoraInjectedConv2d( _source.in_channels, _source.out_channels, _source.kernel_size, _source.stride, _source.padding, _source.dilation, _source.groups, _source.bias is not None, r=r.pop(0) if isinstance(r, list) else r, ) _tmp.conv.weight = weight if bias is not None: _tmp.conv.bias = bias elif _child_module.__class__ == nn.Conv3d or( _child_module.__class__ == LoraInjectedConv3d ): if len(loras[0].shape) != 5: continue _source = ( _child_module.conv if isinstance(_child_module, LoraInjectedConv3d) else _child_module ) weight = _source.weight bias = _source.bias _tmp = LoraInjectedConv3d( _source.in_channels, _source.out_channels, bias=_source.bias is not None, kernel_size=_source.kernel_size, padding=_source.padding, r=r.pop(0) if isinstance(r, list) else r, ) _tmp.conv.weight = weight if bias is not None: _tmp.conv.bias = bias # switch the module _module._modules[name] = _tmp up_weight = loras.pop(0) down_weight = loras.pop(0) _module._modules[name].lora_up.weight = nn.Parameter( up_weight.type(weight.dtype) ) _module._modules[name].lora_down.weight = nn.Parameter( down_weight.type(weight.dtype) ) _module._modules[name].to(weight.device) def monkeypatch_or_replace_safeloras(models, safeloras): loras = parse_safeloras(safeloras) for name, (lora, ranks, target) in loras.items(): model = getattr(models, name, None) if not model: print(f"No model provided for {name}, contained in Lora") continue monkeypatch_or_replace_lora_extended(model, lora, target, ranks) def monkeypatch_remove_lora(model): for _module, name, _child_module in _find_modules( model, search_class=[LoraInjectedLinear, LoraInjectedConv2d, LoraInjectedConv3d] ): if isinstance(_child_module, LoraInjectedLinear): _source = _child_module.linear weight, bias = _source.weight, _source.bias _tmp = nn.Linear( _source.in_features, _source.out_features, bias is not None ) _tmp.weight = weight if bias is not None: _tmp.bias = bias else: _source = _child_module.conv weight, bias = _source.weight, _source.bias if isinstance(_source, nn.Conv2d): _tmp = nn.Conv2d( in_channels=_source.in_channels, out_channels=_source.out_channels, kernel_size=_source.kernel_size, stride=_source.stride, padding=_source.padding, dilation=_source.dilation, groups=_source.groups, bias=bias is not None, ) _tmp.weight = weight if bias is not None: _tmp.bias = bias if isinstance(_source, nn.Conv3d): _tmp = nn.Conv3d( _source.in_channels, _source.out_channels, bias=_source.bias is not None, kernel_size=_source.kernel_size, padding=_source.padding, ) _tmp.weight = weight if bias is not None: _tmp.bias = bias _module._modules[name] = _tmp def monkeypatch_add_lora( model, loras, target_replace_module=DEFAULT_TARGET_REPLACE, alpha: float = 1.0, beta: float = 1.0, ): for _module, name, _child_module in _find_modules( model, target_replace_module, search_class=[LoraInjectedLinear] ): weight = _child_module.linear.weight up_weight = loras.pop(0) down_weight = loras.pop(0) _module._modules[name].lora_up.weight = nn.Parameter( up_weight.type(weight.dtype).to(weight.device) * alpha + _module._modules[name].lora_up.weight.to(weight.device) * beta ) _module._modules[name].lora_down.weight = nn.Parameter( down_weight.type(weight.dtype).to(weight.device) * alpha + _module._modules[name].lora_down.weight.to(weight.device) * beta ) _module._modules[name].to(weight.device) def tune_lora_scale(model, alpha: float = 1.0): for _module in model.modules(): if _module.__class__.__name__ in ["LoraInjectedLinear", "LoraInjectedConv2d", "LoraInjectedConv3d"]: _module.scale = alpha def set_lora_diag(model, diag: torch.Tensor): for _module in model.modules(): if _module.__class__.__name__ in ["LoraInjectedLinear", "LoraInjectedConv2d", "LoraInjectedConv3d"]: _module.set_selector_from_diag(diag) def _text_lora_path(path: str) -> str: assert path.endswith(".pt"), "Only .pt files are supported" return ".".join(path.split(".")[:-1] + ["text_encoder", "pt"]) def _ti_lora_path(path: str) -> str: assert path.endswith(".pt"), "Only .pt files are supported" return ".".join(path.split(".")[:-1] + ["ti", "pt"]) def apply_learned_embed_in_clip( learned_embeds, text_encoder, tokenizer, token: Optional[Union[str, List[str]]] = None, idempotent=False, ): if isinstance(token, str): trained_tokens = [token] elif isinstance(token, list): assert len(learned_embeds.keys()) == len( token ), "The number of tokens and the number of embeds should be the same" trained_tokens = token else: trained_tokens = list(learned_embeds.keys()) for token in trained_tokens: print(token) embeds = learned_embeds[token] # cast to dtype of text_encoder dtype = text_encoder.get_input_embeddings().weight.dtype num_added_tokens = tokenizer.add_tokens(token) i = 1 if not idempotent: while num_added_tokens == 0: print(f"The tokenizer already contains the token {token}.") token = f"{token[:-1]}-{i}>" print(f"Attempting to add the token {token}.") num_added_tokens = tokenizer.add_tokens(token) i += 1 elif num_added_tokens == 0 and idempotent: print(f"The tokenizer already contains the token {token}.") print(f"Replacing {token} embedding.") # resize the token embeddings text_encoder.resize_token_embeddings(len(tokenizer)) # get the id for the token and assign the embeds token_id = tokenizer.convert_tokens_to_ids(token) text_encoder.get_input_embeddings().weight.data[token_id] = embeds return token def load_learned_embed_in_clip( learned_embeds_path, text_encoder, tokenizer, token: Optional[Union[str, List[str]]] = None, idempotent=False, ): learned_embeds = torch.load(learned_embeds_path) apply_learned_embed_in_clip( learned_embeds, text_encoder, tokenizer, token, idempotent ) def patch_pipe( pipe, maybe_unet_path, token: Optional[str] = None, r: int = 4, patch_unet=True, patch_text=True, patch_ti=True, idempotent_token=True, unet_target_replace_module=DEFAULT_TARGET_REPLACE, text_target_replace_module=TEXT_ENCODER_DEFAULT_TARGET_REPLACE, ): if maybe_unet_path.endswith(".pt"): # torch format if maybe_unet_path.endswith(".ti.pt"): unet_path = maybe_unet_path[:-6] + ".pt" elif maybe_unet_path.endswith(".text_encoder.pt"): unet_path = maybe_unet_path[:-16] + ".pt" else: unet_path = maybe_unet_path ti_path = _ti_lora_path(unet_path) text_path = _text_lora_path(unet_path) if patch_unet: print("LoRA : Patching Unet") monkeypatch_or_replace_lora( pipe.unet, torch.load(unet_path), r=r, target_replace_module=unet_target_replace_module, ) if patch_text: print("LoRA : Patching text encoder") monkeypatch_or_replace_lora( pipe.text_encoder, torch.load(text_path), target_replace_module=text_target_replace_module, r=r, ) if patch_ti: print("LoRA : Patching token input") token = load_learned_embed_in_clip( ti_path, pipe.text_encoder, pipe.tokenizer, token=token, idempotent=idempotent_token, ) elif maybe_unet_path.endswith(".safetensors"): safeloras = safe_open(maybe_unet_path, framework="pt", device="cpu") monkeypatch_or_replace_safeloras(pipe, safeloras) tok_dict = parse_safeloras_embeds(safeloras) if patch_ti: apply_learned_embed_in_clip( tok_dict, pipe.text_encoder, pipe.tokenizer, token=token, idempotent=idempotent_token, ) return tok_dict def train_patch_pipe(pipe, patch_unet, patch_text): if patch_unet: print("LoRA : Patching Unet") collapse_lora(pipe.unet) monkeypatch_remove_lora(pipe.unet) if patch_text: print("LoRA : Patching text encoder") collapse_lora(pipe.text_encoder) monkeypatch_remove_lora(pipe.text_encoder) @torch.no_grad() def inspect_lora(model): moved = {} for name, _module in model.named_modules(): if _module.__class__.__name__ in ["LoraInjectedLinear", "LoraInjectedConv2d", "LoraInjectedConv3d"]: ups = _module.lora_up.weight.data.clone() downs = _module.lora_down.weight.data.clone() wght: torch.Tensor = ups.flatten(1) @ downs.flatten(1) dist = wght.flatten().abs().mean().item() if name in moved: moved[name].append(dist) else: moved[name] = [dist] return moved def save_all( unet, text_encoder, save_path, placeholder_token_ids=None, placeholder_tokens=None, save_lora=True, save_ti=True, target_replace_module_text=TEXT_ENCODER_DEFAULT_TARGET_REPLACE, target_replace_module_unet=DEFAULT_TARGET_REPLACE, safe_form=True, ): if not safe_form: # save ti if save_ti: ti_path = _ti_lora_path(save_path) learned_embeds_dict = {} for tok, tok_id in zip(placeholder_tokens, placeholder_token_ids): learned_embeds = text_encoder.get_input_embeddings().weight[tok_id] print( f"Current Learned Embeddings for {tok}:, id {tok_id} ", learned_embeds[:4], ) learned_embeds_dict[tok] = learned_embeds.detach().cpu() torch.save(learned_embeds_dict, ti_path) print("Ti saved to ", ti_path) # save text encoder if save_lora: save_lora_weight( unet, save_path, target_replace_module=target_replace_module_unet ) print("Unet saved to ", save_path) save_lora_weight( text_encoder, _text_lora_path(save_path), target_replace_module=target_replace_module_text, ) print("Text Encoder saved to ", _text_lora_path(save_path)) else: assert save_path.endswith( ".safetensors" ), f"Save path : {save_path} should end with .safetensors" loras = {} embeds = {} if save_lora: loras["unet"] = (unet, target_replace_module_unet) loras["text_encoder"] = (text_encoder, target_replace_module_text) if save_ti: for tok, tok_id in zip(placeholder_tokens, placeholder_token_ids): learned_embeds = text_encoder.get_input_embeddings().weight[tok_id] print( f"Current Learned Embeddings for {tok}:, id {tok_id} ", learned_embeds[:4], ) embeds[tok] = learned_embeds.detach().cpu() save_safeloras_with_embeds(loras, embeds, save_path)