import copy import torch from ldm_patched.modules.model_patcher import ModelPatcher from ldm_patched.modules.sample import convert_cond from ldm_patched.modules.samplers import encode_model_conds class UnetPatcher(ModelPatcher): def __init__(self, *args, **kwargs): super().__init__(*args, **kwargs) self.controlnet_linked_list = None self.extra_preserved_memory_during_sampling = 0 self.extra_model_patchers_during_sampling = [] self.extra_concat_condition = None def clone(self): n = UnetPatcher(self.model, self.load_device, self.offload_device, self.size, self.current_device, weight_inplace_update=self.weight_inplace_update) n.patches = {} for k in self.patches: n.patches[k] = self.patches[k][:] n.object_patches = self.object_patches.copy() n.model_options = copy.deepcopy(self.model_options) n.model_keys = self.model_keys n.controlnet_linked_list = self.controlnet_linked_list n.extra_preserved_memory_during_sampling = self.extra_preserved_memory_during_sampling n.extra_model_patchers_during_sampling = self.extra_model_patchers_during_sampling.copy() n.extra_concat_condition = self.extra_concat_condition return n def add_extra_preserved_memory_during_sampling(self, memory_in_bytes: int): # Use this to ask Forge to preserve a certain amount of memory during sampling. # If GPU VRAM is 8 GB, and memory_in_bytes is 2GB, i.e., memory_in_bytes = 2 * 1024 * 1024 * 1024 # Then the sampling will always use less than 6GB memory by dynamically offload modules to CPU RAM. # You can estimate this using model_management.module_size(any_pytorch_model) to get size of any pytorch models. self.extra_preserved_memory_during_sampling += memory_in_bytes return def add_extra_model_patcher_during_sampling(self, model_patcher: ModelPatcher): # Use this to ask Forge to move extra model patchers to GPU during sampling. # This method will manage GPU memory perfectly. self.extra_model_patchers_during_sampling.append(model_patcher) return def add_extra_torch_module_during_sampling(self, m: torch.nn.Module, cast_to_unet_dtype: bool = True): # Use this method to bind an extra torch.nn.Module to this UNet during sampling. # This model `m` will be delegated to Forge memory management system. # `m` will be loaded to GPU everytime when sampling starts. # `m` will be unloaded if necessary. # `m` will influence Forge's judgement about use GPU memory or # capacity and decide whether to use module offload to make user's batch size larger. # Use cast_to_unet_dtype if you want `m` to have same dtype with unet during sampling. if cast_to_unet_dtype: m.to(self.model.diffusion_model.dtype) patcher = ModelPatcher(model=m, load_device=self.load_device, offload_device=self.offload_device) self.add_extra_model_patcher_during_sampling(patcher) return patcher def add_patched_controlnet(self, cnet): cnet.set_previous_controlnet(self.controlnet_linked_list) self.controlnet_linked_list = cnet return def list_controlnets(self): results = [] pointer = self.controlnet_linked_list while pointer is not None: results.append(pointer) pointer = pointer.previous_controlnet return results def append_model_option(self, k, v, ensure_uniqueness=False): if k not in self.model_options: self.model_options[k] = [] if ensure_uniqueness and v in self.model_options[k]: return self.model_options[k].append(v) return def append_transformer_option(self, k, v, ensure_uniqueness=False): if 'transformer_options' not in self.model_options: self.model_options['transformer_options'] = {} to = self.model_options['transformer_options'] if k not in to: to[k] = [] if ensure_uniqueness and v in to[k]: return to[k].append(v) return def set_transformer_option(self, k, v): if 'transformer_options' not in self.model_options: self.model_options['transformer_options'] = {} self.model_options['transformer_options'][k] = v return def add_conditioning_modifier(self, modifier, ensure_uniqueness=False): self.append_model_option('conditioning_modifiers', modifier, ensure_uniqueness) return def add_sampler_pre_cfg_function(self, modifier, ensure_uniqueness=False): self.append_model_option('sampler_pre_cfg_function', modifier, ensure_uniqueness) return def set_memory_peak_estimation_modifier(self, modifier): self.model_options['memory_peak_estimation_modifier'] = modifier return def add_alphas_cumprod_modifier(self, modifier, ensure_uniqueness=False): """ For some reasons, this function only works in A1111's Script.process_batch(self, p, *args, **kwargs) For example, below is a worked modification: class ExampleScript(scripts.Script): def process_batch(self, p, *args, **kwargs): unet = p.sd_model.forge_objects.unet.clone() def modifier(x): return x ** 0.5 unet.add_alphas_cumprod_modifier(modifier) p.sd_model.forge_objects.unet = unet return This add_alphas_cumprod_modifier is the only patch option that should be used in process_batch() All other patch options should be called in process_before_every_sampling() """ self.append_model_option('alphas_cumprod_modifiers', modifier, ensure_uniqueness) return def add_block_modifier(self, modifier, ensure_uniqueness=False): self.append_transformer_option('block_modifiers', modifier, ensure_uniqueness) return def add_block_inner_modifier(self, modifier, ensure_uniqueness=False): self.append_transformer_option('block_inner_modifiers', modifier, ensure_uniqueness) return def add_controlnet_conditioning_modifier(self, modifier, ensure_uniqueness=False): self.append_transformer_option('controlnet_conditioning_modifiers', modifier, ensure_uniqueness) return def set_controlnet_model_function_wrapper(self, wrapper): self.set_transformer_option('controlnet_model_function_wrapper', wrapper) return def set_model_replace_all(self, patch, target="attn1"): for block_name in ['input', 'middle', 'output']: for number in range(16): for transformer_index in range(16): self.set_model_patch_replace(patch, target, block_name, number, transformer_index) return def encode_conds_after_clip(self, conds, noise, prompt_type="positive"): return encode_model_conds( model_function=self.model.extra_conds, conds=convert_cond(conds), noise=noise, device=noise.device, prompt_type=prompt_type ) def load_frozen_patcher(self, state_dict, strength): patch_dict = {} for k, w in state_dict.items(): model_key, patch_type, weight_index = k.split('::') if model_key not in patch_dict: patch_dict[model_key] = {} if patch_type not in patch_dict[model_key]: patch_dict[model_key][patch_type] = [None] * 16 patch_dict[model_key][patch_type][int(weight_index)] = w patch_flat = {} for model_key, v in patch_dict.items(): for patch_type, weight_list in v.items(): patch_flat[model_key] = (patch_type, weight_list) self.add_patches(patches=patch_flat, strength_patch=float(strength), strength_model=1.0) return