import argparse from contextlib import nullcontext import safetensors.torch import torch from accelerate import init_empty_weights from diffusers import AutoencoderKL, SD3Transformer2DModel from diffusers.loaders.single_file_utils import convert_ldm_vae_checkpoint from diffusers.models.modeling_utils import load_model_dict_into_meta from diffusers.utils.import_utils import is_accelerate_available CTX = init_empty_weights if is_accelerate_available else nullcontext parser = argparse.ArgumentParser() parser.add_argument("--checkpoint_path", type=str) parser.add_argument("--output_path", type=str) parser.add_argument("--dtype", type=str, default="fp16") args = parser.parse_args() dtype = torch.float16 if args.dtype == "fp16" else torch.float32 def load_original_checkpoint(ckpt_path): original_state_dict = safetensors.torch.load_file(ckpt_path) keys = list(original_state_dict.keys()) for k in keys: if "model.diffusion_model." in k: original_state_dict[k.replace("model.diffusion_model.", "")] = original_state_dict.pop(k) return original_state_dict # in SD3 original implementation of AdaLayerNormContinuous, it split linear projection output into shift, scale; # while in diffusers it split into scale, shift. Here we swap the linear projection weights in order to be able to use diffusers implementation def swap_scale_shift(weight, dim): shift, scale = weight.chunk(2, dim=0) new_weight = torch.cat([scale, shift], dim=0) return new_weight def convert_sd3_transformer_checkpoint_to_diffusers(original_state_dict, num_layers, caption_projection_dim): converted_state_dict = {} # Positional and patch embeddings. converted_state_dict["pos_embed.pos_embed"] = original_state_dict.pop("pos_embed") converted_state_dict["pos_embed.proj.weight"] = original_state_dict.pop("x_embedder.proj.weight") converted_state_dict["pos_embed.proj.bias"] = original_state_dict.pop("x_embedder.proj.bias") # Timestep embeddings. converted_state_dict["time_text_embed.timestep_embedder.linear_1.weight"] = original_state_dict.pop( "t_embedder.mlp.0.weight" ) converted_state_dict["time_text_embed.timestep_embedder.linear_1.bias"] = original_state_dict.pop( "t_embedder.mlp.0.bias" ) converted_state_dict["time_text_embed.timestep_embedder.linear_2.weight"] = original_state_dict.pop( "t_embedder.mlp.2.weight" ) converted_state_dict["time_text_embed.timestep_embedder.linear_2.bias"] = original_state_dict.pop( "t_embedder.mlp.2.bias" ) # Context projections. converted_state_dict["context_embedder.weight"] = original_state_dict.pop("context_embedder.weight") converted_state_dict["context_embedder.bias"] = original_state_dict.pop("context_embedder.bias") # Pooled context projection. converted_state_dict["time_text_embed.text_embedder.linear_1.weight"] = original_state_dict.pop( "y_embedder.mlp.0.weight" ) converted_state_dict["time_text_embed.text_embedder.linear_1.bias"] = original_state_dict.pop( "y_embedder.mlp.0.bias" ) converted_state_dict["time_text_embed.text_embedder.linear_2.weight"] = original_state_dict.pop( "y_embedder.mlp.2.weight" ) converted_state_dict["time_text_embed.text_embedder.linear_2.bias"] = original_state_dict.pop( "y_embedder.mlp.2.bias" ) # Transformer blocks 🎸. for i in range(num_layers): # Q, K, V sample_q, sample_k, sample_v = torch.chunk( original_state_dict.pop(f"joint_blocks.{i}.x_block.attn.qkv.weight"), 3, dim=0 ) context_q, context_k, context_v = torch.chunk( original_state_dict.pop(f"joint_blocks.{i}.context_block.attn.qkv.weight"), 3, dim=0 ) sample_q_bias, sample_k_bias, sample_v_bias = torch.chunk( original_state_dict.pop(f"joint_blocks.{i}.x_block.attn.qkv.bias"), 3, dim=0 ) context_q_bias, context_k_bias, context_v_bias = torch.chunk( original_state_dict.pop(f"joint_blocks.{i}.context_block.attn.qkv.bias"), 3, dim=0 ) converted_state_dict[f"transformer_blocks.{i}.attn.to_q.weight"] = torch.cat([sample_q]) converted_state_dict[f"transformer_blocks.{i}.attn.to_q.bias"] = torch.cat([sample_q_bias]) converted_state_dict[f"transformer_blocks.{i}.attn.to_k.weight"] = torch.cat([sample_k]) converted_state_dict[f"transformer_blocks.{i}.attn.to_k.bias"] = torch.cat([sample_k_bias]) converted_state_dict[f"transformer_blocks.{i}.attn.to_v.weight"] = torch.cat([sample_v]) converted_state_dict[f"transformer_blocks.{i}.attn.to_v.bias"] = torch.cat([sample_v_bias]) converted_state_dict[f"transformer_blocks.{i}.attn.add_q_proj.weight"] = torch.cat([context_q]) converted_state_dict[f"transformer_blocks.{i}.attn.add_q_proj.bias"] = torch.cat([context_q_bias]) converted_state_dict[f"transformer_blocks.{i}.attn.add_k_proj.weight"] = torch.cat([context_k]) converted_state_dict[f"transformer_blocks.{i}.attn.add_k_proj.bias"] = torch.cat([context_k_bias]) converted_state_dict[f"transformer_blocks.{i}.attn.add_v_proj.weight"] = torch.cat([context_v]) converted_state_dict[f"transformer_blocks.{i}.attn.add_v_proj.bias"] = torch.cat([context_v_bias]) # output projections. converted_state_dict[f"transformer_blocks.{i}.attn.to_out.0.weight"] = original_state_dict.pop( f"joint_blocks.{i}.x_block.attn.proj.weight" ) converted_state_dict[f"transformer_blocks.{i}.attn.to_out.0.bias"] = original_state_dict.pop( f"joint_blocks.{i}.x_block.attn.proj.bias" ) if not (i == num_layers - 1): converted_state_dict[f"transformer_blocks.{i}.attn.to_add_out.weight"] = original_state_dict.pop( f"joint_blocks.{i}.context_block.attn.proj.weight" ) converted_state_dict[f"transformer_blocks.{i}.attn.to_add_out.bias"] = original_state_dict.pop( f"joint_blocks.{i}.context_block.attn.proj.bias" ) # norms. converted_state_dict[f"transformer_blocks.{i}.norm1.linear.weight"] = original_state_dict.pop( f"joint_blocks.{i}.x_block.adaLN_modulation.1.weight" ) converted_state_dict[f"transformer_blocks.{i}.norm1.linear.bias"] = original_state_dict.pop( f"joint_blocks.{i}.x_block.adaLN_modulation.1.bias" ) if not (i == num_layers - 1): converted_state_dict[f"transformer_blocks.{i}.norm1_context.linear.weight"] = original_state_dict.pop( f"joint_blocks.{i}.context_block.adaLN_modulation.1.weight" ) converted_state_dict[f"transformer_blocks.{i}.norm1_context.linear.bias"] = original_state_dict.pop( f"joint_blocks.{i}.context_block.adaLN_modulation.1.bias" ) else: converted_state_dict[f"transformer_blocks.{i}.norm1_context.linear.weight"] = swap_scale_shift( original_state_dict.pop(f"joint_blocks.{i}.context_block.adaLN_modulation.1.weight"), dim=caption_projection_dim, ) converted_state_dict[f"transformer_blocks.{i}.norm1_context.linear.bias"] = swap_scale_shift( original_state_dict.pop(f"joint_blocks.{i}.context_block.adaLN_modulation.1.bias"), dim=caption_projection_dim, ) # ffs. converted_state_dict[f"transformer_blocks.{i}.ff.net.0.proj.weight"] = original_state_dict.pop( f"joint_blocks.{i}.x_block.mlp.fc1.weight" ) converted_state_dict[f"transformer_blocks.{i}.ff.net.0.proj.bias"] = original_state_dict.pop( f"joint_blocks.{i}.x_block.mlp.fc1.bias" ) converted_state_dict[f"transformer_blocks.{i}.ff.net.2.weight"] = original_state_dict.pop( f"joint_blocks.{i}.x_block.mlp.fc2.weight" ) converted_state_dict[f"transformer_blocks.{i}.ff.net.2.bias"] = original_state_dict.pop( f"joint_blocks.{i}.x_block.mlp.fc2.bias" ) if not (i == num_layers - 1): converted_state_dict[f"transformer_blocks.{i}.ff_context.net.0.proj.weight"] = original_state_dict.pop( f"joint_blocks.{i}.context_block.mlp.fc1.weight" ) converted_state_dict[f"transformer_blocks.{i}.ff_context.net.0.proj.bias"] = original_state_dict.pop( f"joint_blocks.{i}.context_block.mlp.fc1.bias" ) converted_state_dict[f"transformer_blocks.{i}.ff_context.net.2.weight"] = original_state_dict.pop( f"joint_blocks.{i}.context_block.mlp.fc2.weight" ) converted_state_dict[f"transformer_blocks.{i}.ff_context.net.2.bias"] = original_state_dict.pop( f"joint_blocks.{i}.context_block.mlp.fc2.bias" ) # Final blocks. converted_state_dict["proj_out.weight"] = original_state_dict.pop("final_layer.linear.weight") converted_state_dict["proj_out.bias"] = original_state_dict.pop("final_layer.linear.bias") converted_state_dict["norm_out.linear.weight"] = swap_scale_shift( original_state_dict.pop("final_layer.adaLN_modulation.1.weight"), dim=caption_projection_dim ) converted_state_dict["norm_out.linear.bias"] = swap_scale_shift( original_state_dict.pop("final_layer.adaLN_modulation.1.bias"), dim=caption_projection_dim ) return converted_state_dict def is_vae_in_checkpoint(original_state_dict): return ("first_stage_model.decoder.conv_in.weight" in original_state_dict) and ( "first_stage_model.encoder.conv_in.weight" in original_state_dict ) def main(args): original_ckpt = load_original_checkpoint(args.checkpoint_path) num_layers = list(set(int(k.split(".", 2)[1]) for k in original_ckpt if "joint_blocks" in k))[-1] + 1 # noqa: C401 caption_projection_dim = 1536 converted_transformer_state_dict = convert_sd3_transformer_checkpoint_to_diffusers( original_ckpt, num_layers, caption_projection_dim ) with CTX(): transformer = SD3Transformer2DModel( sample_size=64, patch_size=2, in_channels=16, joint_attention_dim=4096, num_layers=num_layers, caption_projection_dim=caption_projection_dim, num_attention_heads=24, pos_embed_max_size=192, ) if is_accelerate_available(): load_model_dict_into_meta(transformer, converted_transformer_state_dict) else: transformer.load_state_dict(converted_transformer_state_dict, strict=True) print("Saving SD3 Transformer in Diffusers format.") transformer.to(dtype).save_pretrained(f"{args.output_path}/transformer") if is_vae_in_checkpoint(original_ckpt): with CTX(): vae = AutoencoderKL.from_config( "stabilityai/stable-diffusion-xl-base-1.0", subfolder="vae", latent_channels=16, use_post_quant_conv=False, use_quant_conv=False, scaling_factor=1.5305, shift_factor=0.0609, ) converted_vae_state_dict = convert_ldm_vae_checkpoint(original_ckpt, vae.config) if is_accelerate_available(): load_model_dict_into_meta(vae, converted_vae_state_dict) else: vae.load_state_dict(converted_vae_state_dict, strict=True) print("Saving SD3 Autoencoder in Diffusers format.") vae.to(dtype).save_pretrained(f"{args.output_path}/vae") if __name__ == "__main__": main(args)