diffusers/scripts/convert_mochi_to_diffusers.py

import argparse
from contextlib import nullcontext

import torch
from accelerate import init_empty_weights
from safetensors.torch import load_file
from transformers import T5EncoderModel, T5Tokenizer

from diffusers import AutoencoderKLMochi, FlowMatchEulerDiscreteScheduler, MochiPipeline, MochiTransformer3DModel
from diffusers.utils.import_utils import is_accelerate_available


CTX = init_empty_weights if is_accelerate_available() else nullcontext

TOKENIZER_MAX_LENGTH = 256

parser = argparse.ArgumentParser()
parser.add_argument("--transformer_checkpoint_path", default=None, type=str)
parser.add_argument("--vae_encoder_checkpoint_path", default=None, type=str)
parser.add_argument("--vae_decoder_checkpoint_path", default=None, type=str)
parser.add_argument("--output_path", required=True, type=str)
parser.add_argument("--push_to_hub", action="store_true", default=False, help="Whether to push to HF Hub after saving")
parser.add_argument("--text_encoder_cache_dir", type=str, default=None, help="Path to text encoder cache directory")
parser.add_argument("--dtype", type=str, default=None)

args = parser.parse_args()


# This is specific to `AdaLayerNormContinuous`:
# Diffusers implementation split the linear projection into the scale, shift while Mochi split it into shift, scale
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 swap_proj_gate(weight):
    proj, gate = weight.chunk(2, dim=0)
    new_weight = torch.cat([gate, proj], dim=0)
    return new_weight


def convert_mochi_transformer_checkpoint_to_diffusers(ckpt_path):
    original_state_dict = load_file(ckpt_path, device="cpu")
    new_state_dict = {}

    # Convert patch_embed
    new_state_dict["patch_embed.proj.weight"] = original_state_dict.pop("x_embedder.proj.weight")
    new_state_dict["patch_embed.proj.bias"] = original_state_dict.pop("x_embedder.proj.bias")

    # Convert time_embed
    new_state_dict["time_embed.timestep_embedder.linear_1.weight"] = original_state_dict.pop("t_embedder.mlp.0.weight")
    new_state_dict["time_embed.timestep_embedder.linear_1.bias"] = original_state_dict.pop("t_embedder.mlp.0.bias")
    new_state_dict["time_embed.timestep_embedder.linear_2.weight"] = original_state_dict.pop("t_embedder.mlp.2.weight")
    new_state_dict["time_embed.timestep_embedder.linear_2.bias"] = original_state_dict.pop("t_embedder.mlp.2.bias")
    new_state_dict["time_embed.pooler.to_kv.weight"] = original_state_dict.pop("t5_y_embedder.to_kv.weight")
    new_state_dict["time_embed.pooler.to_kv.bias"] = original_state_dict.pop("t5_y_embedder.to_kv.bias")
    new_state_dict["time_embed.pooler.to_q.weight"] = original_state_dict.pop("t5_y_embedder.to_q.weight")
    new_state_dict["time_embed.pooler.to_q.bias"] = original_state_dict.pop("t5_y_embedder.to_q.bias")
    new_state_dict["time_embed.pooler.to_out.weight"] = original_state_dict.pop("t5_y_embedder.to_out.weight")
    new_state_dict["time_embed.pooler.to_out.bias"] = original_state_dict.pop("t5_y_embedder.to_out.bias")
    new_state_dict["time_embed.caption_proj.weight"] = original_state_dict.pop("t5_yproj.weight")
    new_state_dict["time_embed.caption_proj.bias"] = original_state_dict.pop("t5_yproj.bias")

    # Convert transformer blocks
    num_layers = 48
    for i in range(num_layers):
        block_prefix = f"transformer_blocks.{i}."
        old_prefix = f"blocks.{i}."

        # norm1
        new_state_dict[block_prefix + "norm1.linear.weight"] = original_state_dict.pop(old_prefix + "mod_x.weight")
        new_state_dict[block_prefix + "norm1.linear.bias"] = original_state_dict.pop(old_prefix + "mod_x.bias")
        if i < num_layers - 1:
            new_state_dict[block_prefix + "norm1_context.linear.weight"] = original_state_dict.pop(
                old_prefix + "mod_y.weight"
            )
            new_state_dict[block_prefix + "norm1_context.linear.bias"] = original_state_dict.pop(
                old_prefix + "mod_y.bias"
            )
        else:
            new_state_dict[block_prefix + "norm1_context.linear_1.weight"] = original_state_dict.pop(
                old_prefix + "mod_y.weight"
            )
            new_state_dict[block_prefix + "norm1_context.linear_1.bias"] = original_state_dict.pop(
                old_prefix + "mod_y.bias"
            )

        # Visual attention
        qkv_weight = original_state_dict.pop(old_prefix + "attn.qkv_x.weight")
        q, k, v = qkv_weight.chunk(3, dim=0)

        new_state_dict[block_prefix + "attn1.to_q.weight"] = q
        new_state_dict[block_prefix + "attn1.to_k.weight"] = k
        new_state_dict[block_prefix + "attn1.to_v.weight"] = v
        new_state_dict[block_prefix + "attn1.norm_q.weight"] = original_state_dict.pop(
            old_prefix + "attn.q_norm_x.weight"
        )
        new_state_dict[block_prefix + "attn1.norm_k.weight"] = original_state_dict.pop(
            old_prefix + "attn.k_norm_x.weight"
        )
        new_state_dict[block_prefix + "attn1.to_out.0.weight"] = original_state_dict.pop(
            old_prefix + "attn.proj_x.weight"
        )
        new_state_dict[block_prefix + "attn1.to_out.0.bias"] = original_state_dict.pop(old_prefix + "attn.proj_x.bias")

        # Context attention
        qkv_weight = original_state_dict.pop(old_prefix + "attn.qkv_y.weight")
        q, k, v = qkv_weight.chunk(3, dim=0)

        new_state_dict[block_prefix + "attn1.add_q_proj.weight"] = q
        new_state_dict[block_prefix + "attn1.add_k_proj.weight"] = k
        new_state_dict[block_prefix + "attn1.add_v_proj.weight"] = v
        new_state_dict[block_prefix + "attn1.norm_added_q.weight"] = original_state_dict.pop(
            old_prefix + "attn.q_norm_y.weight"
        )
        new_state_dict[block_prefix + "attn1.norm_added_k.weight"] = original_state_dict.pop(
            old_prefix + "attn.k_norm_y.weight"
        )
        if i < num_layers - 1:
            new_state_dict[block_prefix + "attn1.to_add_out.weight"] = original_state_dict.pop(
                old_prefix + "attn.proj_y.weight"
            )
            new_state_dict[block_prefix + "attn1.to_add_out.bias"] = original_state_dict.pop(
                old_prefix + "attn.proj_y.bias"
            )

        # MLP
        new_state_dict[block_prefix + "ff.net.0.proj.weight"] = swap_proj_gate(
            original_state_dict.pop(old_prefix + "mlp_x.w1.weight")
        )
        new_state_dict[block_prefix + "ff.net.2.weight"] = original_state_dict.pop(old_prefix + "mlp_x.w2.weight")
        if i < num_layers - 1:
            new_state_dict[block_prefix + "ff_context.net.0.proj.weight"] = swap_proj_gate(
                original_state_dict.pop(old_prefix + "mlp_y.w1.weight")
            )
            new_state_dict[block_prefix + "ff_context.net.2.weight"] = original_state_dict.pop(
                old_prefix + "mlp_y.w2.weight"
            )

    # Output layers
    new_state_dict["norm_out.linear.weight"] = swap_scale_shift(
        original_state_dict.pop("final_layer.mod.weight"), dim=0
    )
    new_state_dict["norm_out.linear.bias"] = swap_scale_shift(original_state_dict.pop("final_layer.mod.bias"), dim=0)
    new_state_dict["proj_out.weight"] = original_state_dict.pop("final_layer.linear.weight")
    new_state_dict["proj_out.bias"] = original_state_dict.pop("final_layer.linear.bias")

    new_state_dict["pos_frequencies"] = original_state_dict.pop("pos_frequencies")

    print("Remaining Keys:", original_state_dict.keys())

    return new_state_dict


def convert_mochi_vae_state_dict_to_diffusers(encoder_ckpt_path, decoder_ckpt_path):
    encoder_state_dict = load_file(encoder_ckpt_path, device="cpu")
    decoder_state_dict = load_file(decoder_ckpt_path, device="cpu")
    new_state_dict = {}

    # ==== Decoder =====
    prefix = "decoder."

    # Convert conv_in
    new_state_dict[f"{prefix}conv_in.weight"] = decoder_state_dict.pop("blocks.0.0.weight")
    new_state_dict[f"{prefix}conv_in.bias"] = decoder_state_dict.pop("blocks.0.0.bias")

    # Convert block_in (MochiMidBlock3D)
    for i in range(3):  # layers_per_block[-1] = 3
        new_state_dict[f"{prefix}block_in.resnets.{i}.norm1.norm_layer.weight"] = decoder_state_dict.pop(
            f"blocks.0.{i+1}.stack.0.weight"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.norm1.norm_layer.bias"] = decoder_state_dict.pop(
            f"blocks.0.{i+1}.stack.0.bias"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.conv1.conv.weight"] = decoder_state_dict.pop(
            f"blocks.0.{i+1}.stack.2.weight"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.conv1.conv.bias"] = decoder_state_dict.pop(
            f"blocks.0.{i+1}.stack.2.bias"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.norm2.norm_layer.weight"] = decoder_state_dict.pop(
            f"blocks.0.{i+1}.stack.3.weight"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.norm2.norm_layer.bias"] = decoder_state_dict.pop(
            f"blocks.0.{i+1}.stack.3.bias"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.conv2.conv.weight"] = decoder_state_dict.pop(
            f"blocks.0.{i+1}.stack.5.weight"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.conv2.conv.bias"] = decoder_state_dict.pop(
            f"blocks.0.{i+1}.stack.5.bias"
        )

    # Convert up_blocks (MochiUpBlock3D)
    down_block_layers = [6, 4, 3]  # layers_per_block[-2], layers_per_block[-3], layers_per_block[-4]
    for block in range(3):
        for i in range(down_block_layers[block]):
            new_state_dict[f"{prefix}up_blocks.{block}.resnets.{i}.norm1.norm_layer.weight"] = decoder_state_dict.pop(
                f"blocks.{block+1}.blocks.{i}.stack.0.weight"
            )
            new_state_dict[f"{prefix}up_blocks.{block}.resnets.{i}.norm1.norm_layer.bias"] = decoder_state_dict.pop(
                f"blocks.{block+1}.blocks.{i}.stack.0.bias"
            )
            new_state_dict[f"{prefix}up_blocks.{block}.resnets.{i}.conv1.conv.weight"] = decoder_state_dict.pop(
                f"blocks.{block+1}.blocks.{i}.stack.2.weight"
            )
            new_state_dict[f"{prefix}up_blocks.{block}.resnets.{i}.conv1.conv.bias"] = decoder_state_dict.pop(
                f"blocks.{block+1}.blocks.{i}.stack.2.bias"
            )
            new_state_dict[f"{prefix}up_blocks.{block}.resnets.{i}.norm2.norm_layer.weight"] = decoder_state_dict.pop(
                f"blocks.{block+1}.blocks.{i}.stack.3.weight"
            )
            new_state_dict[f"{prefix}up_blocks.{block}.resnets.{i}.norm2.norm_layer.bias"] = decoder_state_dict.pop(
                f"blocks.{block+1}.blocks.{i}.stack.3.bias"
            )
            new_state_dict[f"{prefix}up_blocks.{block}.resnets.{i}.conv2.conv.weight"] = decoder_state_dict.pop(
                f"blocks.{block+1}.blocks.{i}.stack.5.weight"
            )
            new_state_dict[f"{prefix}up_blocks.{block}.resnets.{i}.conv2.conv.bias"] = decoder_state_dict.pop(
                f"blocks.{block+1}.blocks.{i}.stack.5.bias"
            )
        new_state_dict[f"{prefix}up_blocks.{block}.proj.weight"] = decoder_state_dict.pop(
            f"blocks.{block+1}.proj.weight"
        )
        new_state_dict[f"{prefix}up_blocks.{block}.proj.bias"] = decoder_state_dict.pop(f"blocks.{block+1}.proj.bias")

    # Convert block_out (MochiMidBlock3D)
    for i in range(3):  # layers_per_block[0] = 3
        new_state_dict[f"{prefix}block_out.resnets.{i}.norm1.norm_layer.weight"] = decoder_state_dict.pop(
            f"blocks.4.{i}.stack.0.weight"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.norm1.norm_layer.bias"] = decoder_state_dict.pop(
            f"blocks.4.{i}.stack.0.bias"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.conv1.conv.weight"] = decoder_state_dict.pop(
            f"blocks.4.{i}.stack.2.weight"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.conv1.conv.bias"] = decoder_state_dict.pop(
            f"blocks.4.{i}.stack.2.bias"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.norm2.norm_layer.weight"] = decoder_state_dict.pop(
            f"blocks.4.{i}.stack.3.weight"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.norm2.norm_layer.bias"] = decoder_state_dict.pop(
            f"blocks.4.{i}.stack.3.bias"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.conv2.conv.weight"] = decoder_state_dict.pop(
            f"blocks.4.{i}.stack.5.weight"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.conv2.conv.bias"] = decoder_state_dict.pop(
            f"blocks.4.{i}.stack.5.bias"
        )

    # Convert proj_out (Conv1x1 ~= nn.Linear)
    new_state_dict[f"{prefix}proj_out.weight"] = decoder_state_dict.pop("output_proj.weight")
    new_state_dict[f"{prefix}proj_out.bias"] = decoder_state_dict.pop("output_proj.bias")

    print("Remaining Decoder Keys:", decoder_state_dict.keys())

    # ==== Encoder =====
    prefix = "encoder."

    new_state_dict[f"{prefix}proj_in.weight"] = encoder_state_dict.pop("layers.0.weight")
    new_state_dict[f"{prefix}proj_in.bias"] = encoder_state_dict.pop("layers.0.bias")

    # Convert block_in (MochiMidBlock3D)
    for i in range(3):  # layers_per_block[0] = 3
        new_state_dict[f"{prefix}block_in.resnets.{i}.norm1.norm_layer.weight"] = encoder_state_dict.pop(
            f"layers.{i+1}.stack.0.weight"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.norm1.norm_layer.bias"] = encoder_state_dict.pop(
            f"layers.{i+1}.stack.0.bias"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.conv1.conv.weight"] = encoder_state_dict.pop(
            f"layers.{i+1}.stack.2.weight"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.conv1.conv.bias"] = encoder_state_dict.pop(
            f"layers.{i+1}.stack.2.bias"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.norm2.norm_layer.weight"] = encoder_state_dict.pop(
            f"layers.{i+1}.stack.3.weight"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.norm2.norm_layer.bias"] = encoder_state_dict.pop(
            f"layers.{i+1}.stack.3.bias"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.conv2.conv.weight"] = encoder_state_dict.pop(
            f"layers.{i+1}.stack.5.weight"
        )
        new_state_dict[f"{prefix}block_in.resnets.{i}.conv2.conv.bias"] = encoder_state_dict.pop(
            f"layers.{i+1}.stack.5.bias"
        )

    # Convert down_blocks (MochiDownBlock3D)
    down_block_layers = [3, 4, 6]  # layers_per_block[1], layers_per_block[2], layers_per_block[3]
    for block in range(3):
        new_state_dict[f"{prefix}down_blocks.{block}.conv_in.conv.weight"] = encoder_state_dict.pop(
            f"layers.{block+4}.layers.0.weight"
        )
        new_state_dict[f"{prefix}down_blocks.{block}.conv_in.conv.bias"] = encoder_state_dict.pop(
            f"layers.{block+4}.layers.0.bias"
        )

        for i in range(down_block_layers[block]):
            # Convert resnets
            new_state_dict[
                f"{prefix}down_blocks.{block}.resnets.{i}.norm1.norm_layer.weight"
            ] = encoder_state_dict.pop(f"layers.{block+4}.layers.{i+1}.stack.0.weight")
            new_state_dict[f"{prefix}down_blocks.{block}.resnets.{i}.norm1.norm_layer.bias"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.stack.0.bias"
            )
            new_state_dict[f"{prefix}down_blocks.{block}.resnets.{i}.conv1.conv.weight"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.stack.2.weight"
            )
            new_state_dict[f"{prefix}down_blocks.{block}.resnets.{i}.conv1.conv.bias"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.stack.2.bias"
            )
            new_state_dict[
                f"{prefix}down_blocks.{block}.resnets.{i}.norm2.norm_layer.weight"
            ] = encoder_state_dict.pop(f"layers.{block+4}.layers.{i+1}.stack.3.weight")
            new_state_dict[f"{prefix}down_blocks.{block}.resnets.{i}.norm2.norm_layer.bias"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.stack.3.bias"
            )
            new_state_dict[f"{prefix}down_blocks.{block}.resnets.{i}.conv2.conv.weight"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.stack.5.weight"
            )
            new_state_dict[f"{prefix}down_blocks.{block}.resnets.{i}.conv2.conv.bias"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.stack.5.bias"
            )

            # Convert attentions
            qkv_weight = encoder_state_dict.pop(f"layers.{block+4}.layers.{i+1}.attn_block.attn.qkv.weight")
            q, k, v = qkv_weight.chunk(3, dim=0)

            new_state_dict[f"{prefix}down_blocks.{block}.attentions.{i}.to_q.weight"] = q
            new_state_dict[f"{prefix}down_blocks.{block}.attentions.{i}.to_k.weight"] = k
            new_state_dict[f"{prefix}down_blocks.{block}.attentions.{i}.to_v.weight"] = v
            new_state_dict[f"{prefix}down_blocks.{block}.attentions.{i}.to_out.0.weight"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.attn_block.attn.out.weight"
            )
            new_state_dict[f"{prefix}down_blocks.{block}.attentions.{i}.to_out.0.bias"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.attn_block.attn.out.bias"
            )
            new_state_dict[f"{prefix}down_blocks.{block}.norms.{i}.norm_layer.weight"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.attn_block.norm.weight"
            )
            new_state_dict[f"{prefix}down_blocks.{block}.norms.{i}.norm_layer.bias"] = encoder_state_dict.pop(
                f"layers.{block+4}.layers.{i+1}.attn_block.norm.bias"
            )

    # Convert block_out (MochiMidBlock3D)
    for i in range(3):  # layers_per_block[-1] = 3
        # Convert resnets
        new_state_dict[f"{prefix}block_out.resnets.{i}.norm1.norm_layer.weight"] = encoder_state_dict.pop(
            f"layers.{i+7}.stack.0.weight"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.norm1.norm_layer.bias"] = encoder_state_dict.pop(
            f"layers.{i+7}.stack.0.bias"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.conv1.conv.weight"] = encoder_state_dict.pop(
            f"layers.{i+7}.stack.2.weight"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.conv1.conv.bias"] = encoder_state_dict.pop(
            f"layers.{i+7}.stack.2.bias"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.norm2.norm_layer.weight"] = encoder_state_dict.pop(
            f"layers.{i+7}.stack.3.weight"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.norm2.norm_layer.bias"] = encoder_state_dict.pop(
            f"layers.{i+7}.stack.3.bias"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.conv2.conv.weight"] = encoder_state_dict.pop(
            f"layers.{i+7}.stack.5.weight"
        )
        new_state_dict[f"{prefix}block_out.resnets.{i}.conv2.conv.bias"] = encoder_state_dict.pop(
            f"layers.{i+7}.stack.5.bias"
        )

        # Convert attentions
        qkv_weight = encoder_state_dict.pop(f"layers.{i+7}.attn_block.attn.qkv.weight")
        q, k, v = qkv_weight.chunk(3, dim=0)

        new_state_dict[f"{prefix}block_out.attentions.{i}.to_q.weight"] = q
        new_state_dict[f"{prefix}block_out.attentions.{i}.to_k.weight"] = k
        new_state_dict[f"{prefix}block_out.attentions.{i}.to_v.weight"] = v
        new_state_dict[f"{prefix}block_out.attentions.{i}.to_out.0.weight"] = encoder_state_dict.pop(
            f"layers.{i+7}.attn_block.attn.out.weight"
        )
        new_state_dict[f"{prefix}block_out.attentions.{i}.to_out.0.bias"] = encoder_state_dict.pop(
            f"layers.{i+7}.attn_block.attn.out.bias"
        )
        new_state_dict[f"{prefix}block_out.norms.{i}.norm_layer.weight"] = encoder_state_dict.pop(
            f"layers.{i+7}.attn_block.norm.weight"
        )
        new_state_dict[f"{prefix}block_out.norms.{i}.norm_layer.bias"] = encoder_state_dict.pop(
            f"layers.{i+7}.attn_block.norm.bias"
        )

    # Convert output layers
    new_state_dict[f"{prefix}norm_out.norm_layer.weight"] = encoder_state_dict.pop("output_norm.weight")
    new_state_dict[f"{prefix}norm_out.norm_layer.bias"] = encoder_state_dict.pop("output_norm.bias")
    new_state_dict[f"{prefix}proj_out.weight"] = encoder_state_dict.pop("output_proj.weight")

    print("Remaining Encoder Keys:", encoder_state_dict.keys())

    return new_state_dict


def main(args):
    if args.dtype is None:
        dtype = None
    if args.dtype == "fp16":
        dtype = torch.float16
    elif args.dtype == "bf16":
        dtype = torch.bfloat16
    elif args.dtype == "fp32":
        dtype = torch.float32
    else:
        raise ValueError(f"Unsupported dtype: {args.dtype}")

    transformer = None
    vae = None

    if args.transformer_checkpoint_path is not None:
        converted_transformer_state_dict = convert_mochi_transformer_checkpoint_to_diffusers(
            args.transformer_checkpoint_path
        )
        transformer = MochiTransformer3DModel()
        transformer.load_state_dict(converted_transformer_state_dict, strict=True)
        if dtype is not None:
            transformer = transformer.to(dtype=dtype)

    if args.vae_encoder_checkpoint_path is not None and args.vae_decoder_checkpoint_path is not None:
        vae = AutoencoderKLMochi(latent_channels=12, out_channels=3)
        converted_vae_state_dict = convert_mochi_vae_state_dict_to_diffusers(
            args.vae_encoder_checkpoint_path, args.vae_decoder_checkpoint_path
        )
        vae.load_state_dict(converted_vae_state_dict, strict=True)
        if dtype is not None:
            vae = vae.to(dtype=dtype)

    text_encoder_id = "google/t5-v1_1-xxl"
    tokenizer = T5Tokenizer.from_pretrained(text_encoder_id, model_max_length=TOKENIZER_MAX_LENGTH)
    text_encoder = T5EncoderModel.from_pretrained(text_encoder_id, cache_dir=args.text_encoder_cache_dir)

    # Apparently, the conversion does not work anymore without this :shrug:
    for param in text_encoder.parameters():
        param.data = param.data.contiguous()

    pipe = MochiPipeline(
        scheduler=FlowMatchEulerDiscreteScheduler(invert_sigmas=True),
        vae=vae,
        text_encoder=text_encoder,
        tokenizer=tokenizer,
        transformer=transformer,
    )
    pipe.save_pretrained(args.output_path, safe_serialization=True, max_shard_size="5GB", push_to_hub=args.push_to_hub)


if __name__ == "__main__":
    main(args)