import argparse from typing import Any, Dict, Tuple import torch from accelerate import init_empty_weights from transformers import AutoProcessor, AutoTokenizer, Qwen3VLForConditionalGeneration from diffusers import ( AutoencoderKLWan, JoyImageEditPipeline, JoyImageEditTransformer3DModel, ) from diffusers.schedulers.scheduling_flow_match_euler_discrete import ( FlowMatchEulerDiscreteScheduler, ) # This code is modified from convert_wan_to_diffusers.py to support input ckpt path def convert_vae(vae_ckpt_path): old_state_dict = torch.load(vae_ckpt_path, weights_only=True) new_state_dict = {} # Create mappings for specific components middle_key_mapping = { # Encoder middle block "encoder.middle.0.residual.0.gamma": "encoder.mid_block.resnets.0.norm1.gamma", "encoder.middle.0.residual.2.bias": "encoder.mid_block.resnets.0.conv1.bias", "encoder.middle.0.residual.2.weight": "encoder.mid_block.resnets.0.conv1.weight", "encoder.middle.0.residual.3.gamma": "encoder.mid_block.resnets.0.norm2.gamma", "encoder.middle.0.residual.6.bias": "encoder.mid_block.resnets.0.conv2.bias", "encoder.middle.0.residual.6.weight": "encoder.mid_block.resnets.0.conv2.weight", "encoder.middle.2.residual.0.gamma": "encoder.mid_block.resnets.1.norm1.gamma", "encoder.middle.2.residual.2.bias": "encoder.mid_block.resnets.1.conv1.bias", "encoder.middle.2.residual.2.weight": "encoder.mid_block.resnets.1.conv1.weight", "encoder.middle.2.residual.3.gamma": "encoder.mid_block.resnets.1.norm2.gamma", "encoder.middle.2.residual.6.bias": "encoder.mid_block.resnets.1.conv2.bias", "encoder.middle.2.residual.6.weight": "encoder.mid_block.resnets.1.conv2.weight", # Decoder middle block "decoder.middle.0.residual.0.gamma": "decoder.mid_block.resnets.0.norm1.gamma", "decoder.middle.0.residual.2.bias": "decoder.mid_block.resnets.0.conv1.bias", "decoder.middle.0.residual.2.weight": "decoder.mid_block.resnets.0.conv1.weight", "decoder.middle.0.residual.3.gamma": "decoder.mid_block.resnets.0.norm2.gamma", "decoder.middle.0.residual.6.bias": "decoder.mid_block.resnets.0.conv2.bias", "decoder.middle.0.residual.6.weight": "decoder.mid_block.resnets.0.conv2.weight", "decoder.middle.2.residual.0.gamma": "decoder.mid_block.resnets.1.norm1.gamma", "decoder.middle.2.residual.2.bias": "decoder.mid_block.resnets.1.conv1.bias", "decoder.middle.2.residual.2.weight": "decoder.mid_block.resnets.1.conv1.weight", "decoder.middle.2.residual.3.gamma": "decoder.mid_block.resnets.1.norm2.gamma", "decoder.middle.2.residual.6.bias": "decoder.mid_block.resnets.1.conv2.bias", "decoder.middle.2.residual.6.weight": "decoder.mid_block.resnets.1.conv2.weight", } # Create a mapping for attention blocks attention_mapping = { # Encoder middle attention "encoder.middle.1.norm.gamma": "encoder.mid_block.attentions.0.norm.gamma", "encoder.middle.1.to_qkv.weight": "encoder.mid_block.attentions.0.to_qkv.weight", "encoder.middle.1.to_qkv.bias": "encoder.mid_block.attentions.0.to_qkv.bias", "encoder.middle.1.proj.weight": "encoder.mid_block.attentions.0.proj.weight", "encoder.middle.1.proj.bias": "encoder.mid_block.attentions.0.proj.bias", # Decoder middle attention "decoder.middle.1.norm.gamma": "decoder.mid_block.attentions.0.norm.gamma", "decoder.middle.1.to_qkv.weight": "decoder.mid_block.attentions.0.to_qkv.weight", "decoder.middle.1.to_qkv.bias": "decoder.mid_block.attentions.0.to_qkv.bias", "decoder.middle.1.proj.weight": "decoder.mid_block.attentions.0.proj.weight", "decoder.middle.1.proj.bias": "decoder.mid_block.attentions.0.proj.bias", } # Create a mapping for the head components head_mapping = { # Encoder head "encoder.head.0.gamma": "encoder.norm_out.gamma", "encoder.head.2.bias": "encoder.conv_out.bias", "encoder.head.2.weight": "encoder.conv_out.weight", # Decoder head "decoder.head.0.gamma": "decoder.norm_out.gamma", "decoder.head.2.bias": "decoder.conv_out.bias", "decoder.head.2.weight": "decoder.conv_out.weight", } # Create a mapping for the quant components quant_mapping = { "conv1.weight": "quant_conv.weight", "conv1.bias": "quant_conv.bias", "conv2.weight": "post_quant_conv.weight", "conv2.bias": "post_quant_conv.bias", } # Process each key in the state dict for key, value in old_state_dict.items(): # Handle middle block keys using the mapping if key in middle_key_mapping: new_key = middle_key_mapping[key] new_state_dict[new_key] = value # Handle attention blocks using the mapping elif key in attention_mapping: new_key = attention_mapping[key] new_state_dict[new_key] = value # Handle head keys using the mapping elif key in head_mapping: new_key = head_mapping[key] new_state_dict[new_key] = value # Handle quant keys using the mapping elif key in quant_mapping: new_key = quant_mapping[key] new_state_dict[new_key] = value # Handle encoder conv1 elif key == "encoder.conv1.weight": new_state_dict["encoder.conv_in.weight"] = value elif key == "encoder.conv1.bias": new_state_dict["encoder.conv_in.bias"] = value # Handle decoder conv1 elif key == "decoder.conv1.weight": new_state_dict["decoder.conv_in.weight"] = value elif key == "decoder.conv1.bias": new_state_dict["decoder.conv_in.bias"] = value # Handle encoder downsamples elif key.startswith("encoder.downsamples."): # Convert to down_blocks new_key = key.replace("encoder.downsamples.", "encoder.down_blocks.") # Convert residual block naming but keep the original structure if ".residual.0.gamma" in new_key: new_key = new_key.replace(".residual.0.gamma", ".norm1.gamma") elif ".residual.2.bias" in new_key: new_key = new_key.replace(".residual.2.bias", ".conv1.bias") elif ".residual.2.weight" in new_key: new_key = new_key.replace(".residual.2.weight", ".conv1.weight") elif ".residual.3.gamma" in new_key: new_key = new_key.replace(".residual.3.gamma", ".norm2.gamma") elif ".residual.6.bias" in new_key: new_key = new_key.replace(".residual.6.bias", ".conv2.bias") elif ".residual.6.weight" in new_key: new_key = new_key.replace(".residual.6.weight", ".conv2.weight") elif ".shortcut.bias" in new_key: new_key = new_key.replace(".shortcut.bias", ".conv_shortcut.bias") elif ".shortcut.weight" in new_key: new_key = new_key.replace(".shortcut.weight", ".conv_shortcut.weight") new_state_dict[new_key] = value # Handle decoder upsamples elif key.startswith("decoder.upsamples."): # Convert to up_blocks parts = key.split(".") block_idx = int(parts[2]) # Group residual blocks if "residual" in key: if block_idx in [0, 1, 2]: new_block_idx = 0 resnet_idx = block_idx elif block_idx in [4, 5, 6]: new_block_idx = 1 resnet_idx = block_idx - 4 elif block_idx in [8, 9, 10]: new_block_idx = 2 resnet_idx = block_idx - 8 elif block_idx in [12, 13, 14]: new_block_idx = 3 resnet_idx = block_idx - 12 else: # Keep as is for other blocks new_state_dict[key] = value continue # Convert residual block naming if ".residual.0.gamma" in key: new_key = f"decoder.up_blocks.{new_block_idx}.resnets.{resnet_idx}.norm1.gamma" elif ".residual.2.bias" in key: new_key = f"decoder.up_blocks.{new_block_idx}.resnets.{resnet_idx}.conv1.bias" elif ".residual.2.weight" in key: new_key = f"decoder.up_blocks.{new_block_idx}.resnets.{resnet_idx}.conv1.weight" elif ".residual.3.gamma" in key: new_key = f"decoder.up_blocks.{new_block_idx}.resnets.{resnet_idx}.norm2.gamma" elif ".residual.6.bias" in key: new_key = f"decoder.up_blocks.{new_block_idx}.resnets.{resnet_idx}.conv2.bias" elif ".residual.6.weight" in key: new_key = f"decoder.up_blocks.{new_block_idx}.resnets.{resnet_idx}.conv2.weight" else: new_key = key new_state_dict[new_key] = value # Handle shortcut connections elif ".shortcut." in key: if block_idx == 4: new_key = key.replace(".shortcut.", ".resnets.0.conv_shortcut.") new_key = new_key.replace("decoder.upsamples.4", "decoder.up_blocks.1") else: new_key = key.replace("decoder.upsamples.", "decoder.up_blocks.") new_key = new_key.replace(".shortcut.", ".conv_shortcut.") new_state_dict[new_key] = value # Handle upsamplers elif ".resample." in key or ".time_conv." in key: if block_idx == 3: new_key = key.replace( f"decoder.upsamples.{block_idx}", "decoder.up_blocks.0.upsamplers.0", ) elif block_idx == 7: new_key = key.replace( f"decoder.upsamples.{block_idx}", "decoder.up_blocks.1.upsamplers.0", ) elif block_idx == 11: new_key = key.replace( f"decoder.upsamples.{block_idx}", "decoder.up_blocks.2.upsamplers.0", ) else: new_key = key.replace("decoder.upsamples.", "decoder.up_blocks.") new_state_dict[new_key] = value else: new_key = key.replace("decoder.upsamples.", "decoder.up_blocks.") new_state_dict[new_key] = value else: # Keep other keys unchanged new_state_dict[key] = value with init_empty_weights(): vae = AutoencoderKLWan() vae.load_state_dict(new_state_dict, strict=True, assign=True) return vae def get_transformer_config() -> Tuple[Dict[str, Any], ...]: config = { "diffusers_config": { "hidden_size": 4096, "in_channels": 16, "num_attention_heads": 32, "num_layers": 40, "out_channels": 16, "patch_size": [1, 2, 2], "rope_dim_list": [16, 56, 56], "text_dim": 4096, "rope_type": "rope", "theta": 10000, }, } return config def convert_transformer(ckpt_path: str): checkpoint = torch.load(ckpt_path, weights_only=True) if "model" in checkpoint: original_state_dict = checkpoint["model"] else: original_state_dict = checkpoint # Attention weights moved from block to block.attn submodule attn_suffixes = ( "img_attn_qkv.", "img_attn_q_norm.", "img_attn_k_norm.", "img_attn_proj.", "txt_attn_qkv.", "txt_attn_q_norm.", "txt_attn_k_norm.", "txt_attn_proj.", ) remapped = {} for key, value in original_state_dict.items(): new_key = key if key.startswith("double_blocks."): for suffix in attn_suffixes: # double_blocks.0.img_attn_qkv.weight -> double_blocks.0.attn.img_attn_qkv.weight if "." + suffix in key and ".attn." + suffix not in key: new_key = key.replace("." + suffix, ".attn." + suffix) break remapped[new_key] = value config = get_transformer_config() with init_empty_weights(): transformer = JoyImageEditTransformer3DModel(**config["diffusers_config"]) transformer.load_state_dict(remapped, strict=True, assign=True) return transformer def get_args(): parser = argparse.ArgumentParser() parser.add_argument( "--transformer_ckpt_path", type=str, default=None, help="Path to original transformer checkpoint", ) parser.add_argument( "--vae_ckpt_path", type=str, default=None, help="Path to original VAE checkpoint", ) parser.add_argument( "--text_encoder_path", type=str, default=None, help="Path to original llama checkpoint", ) parser.add_argument( "--tokenizer_path", type=str, default=None, help="Path to original llama tokenizer", ) parser.add_argument("--save_pipeline", action="store_true") parser.add_argument( "--output_path", type=str, required=True, help="Path where converted model should be saved", ) parser.add_argument("--dtype", default="bf16", help="Torch dtype to save the transformer in.") parser.add_argument("--flow_shift", type=float, default=7.0) return parser.parse_args() DTYPE_MAPPING = { "fp32": torch.float32, "fp16": torch.float16, "bf16": torch.bfloat16, } if __name__ == "__main__": args = get_args() transformer = None vae = None dtype = DTYPE_MAPPING[args.dtype] if args.save_pipeline: assert args.transformer_ckpt_path is not None and args.vae_ckpt_path is not None assert args.text_encoder_path is not None # assert args.tokenizer_path is not None if args.transformer_ckpt_path is not None: transformer = convert_transformer(args.transformer_ckpt_path) transformer = transformer.to(dtype=dtype) if not args.save_pipeline: transformer.save_pretrained(args.output_path, safe_serialization=True, max_shard_size="5GB") if args.vae_ckpt_path is not None: vae = convert_vae(args.vae_ckpt_path) vae = vae.to(dtype=dtype) if not args.save_pipeline: vae.save_pretrained(args.output_path, safe_serialization=True, max_shard_size="5GB") if args.save_pipeline: processor = AutoProcessor.from_pretrained(args.text_encoder_path) text_encoder = Qwen3VLForConditionalGeneration.from_pretrained( args.text_encoder_path, torch_dtype=torch.bfloat16 ).to("cuda") tokenizer = AutoTokenizer.from_pretrained(args.text_encoder_path) flow_shift = 1.5 scheduler = FlowMatchEulerDiscreteScheduler(num_train_timesteps=1000, shift=flow_shift) transformer = transformer.to("cuda") vae = vae.to("cuda") pipe = JoyImageEditPipeline( processor=processor, transformer=transformer, text_encoder=text_encoder, tokenizer=tokenizer, vae=vae, scheduler=scheduler, ).to("cuda") pipe.save_pretrained(args.output_path, safe_serialization=True, max_shard_size="5GB") processor.save_pretrained(f"{args.output_path}/processor")