models.py

import copy
import json
import math
import os
import re
from dataclasses import dataclass, field
from typing import Callable, Dict, List, Optional, Tuple, Type, Union

import safetensors.torch
import torch
from torch import nn

from vllm.config import LoRAConfig
from vllm.logger import init_logger
from vllm.lora.layers import (BaseLayerWithLoRA,
                              LinearScalingRotaryEmbeddingWithLora,
                              LoRAMapping)
from vllm.lora.lora import LoRALayerWeights, PackedLoRALayerWeights
from vllm.lora.utils import (from_layer, from_layer_logits_processor,
                             parse_fine_tuned_lora_name, replace_submodule)
from vllm.utils import LRUCache, is_pin_memory_available

logger = init_logger(__name__)

_GLOBAL_LORA_ID = 0


@dataclass
class LongContextLoRAContext:
    """Context for lora adapters that support long context."""
    # The scaling factors to support long context lora fine tuned models.
    scaling_factors: List[float]
    # dimension to apply rotary embedding.
    rot_dim: int
    # offsets to the sin_cos_cache for each lora_id loaded.
    # This value is dynamically modified.
    offsets_by_lora_id: Dict[int, int] = field(default_factory=dict)


def convert_mapping(
    mapping: LoRAMapping,
    lora_index_to_id: List[Optional[int]],
    max_loras: int,
    vocab_size: int,
    extra_vocab_size: int,
    long_lora_context: Optional[LongContextLoRAContext] = None,
) -> Tuple[torch.Tensor, torch.Tensor, torch.Tensor, torch.Tensor,
           Optional[torch.Tensor], List[int]]:
    """Converts LoRAMapping to index tensors.

    Args:
        mapping: LoRAMapping mapping rows in a batch to LoRA ids.
        lora_index_to_id: List mapping LoRA ids to LoRA indices.
        max_loras: Maximum number of LoRAs.
        vocab_size: Model vocab size.
        extra_vocab_size: Extra vocab size each LoRA can have.
        long_lora_context: Passed if there are long context lora in a batch.

    Returns:
        A tuple of tensors:
            base_indices: Tensor of shape [batch_size] mapping batch rows to
                LoRA indices.
            sampler_indices: Tensor of shape [batch_size] mapping requests to
                LoRA indices for sampler. For generation, this will be the
                same as base_indicies. For prefill, this will map requests
                to LoRA indices.
            sampler_indices_padded: Tensor of shape [batch_size] mapping
                requests to LoRA indices for sampler with padding.
                Same as sampler_indicies, but -1 is replaced with
                max_loras.
            embeddings_indices: Tensor of shape [2, batch_size] mapping
                requests to embedding indices. First row is for embeddings
                added by the LoRAs, second row is for the LoRA.lora_a
                embeddings.
            long_lora_indices: Tensor of shape [batch_size] mapping
                requests to RoPE offsets and rot dims for long LoRAs.
                None if long context lora doesn't exist.
            indices_len: List of lengths of the above tensors.
                Used to index into each tensor. It contains length for
                (base_indices, sampler_indices, sampler_indices_padded,
                embeddings_indices, long_lora_indices). If long_lora doesn't
                exist, it only contains first 4 entries.
    """
    index_mapping_indices: List[int] = list(mapping.index_mapping).copy()
    embedding_indices = index_mapping_indices.copy()
    lora_indices = index_mapping_indices.copy()
    long_lora_offsets: Optional[torch.Tensor] = None
    if long_lora_context:
        long_lora_offsets = torch.zeros(len(index_mapping_indices),
                                        device="cuda",
                                        dtype=torch.long)
    prompt_mapping: List[int] = [
        lora_index_to_id.index(x) if x > 0 else -1
        for x in mapping.prompt_mapping
    ]
    lora_idx = None
    for i in range(len(index_mapping_indices)):
        # TODO index can be slow. optimize
        lora_idx = (lora_index_to_id.index(index_mapping_indices[i])
                    if index_mapping_indices[i] > 0 else -1)
        embedding_indices[i] = lora_idx if index_mapping_indices[i] > 0 else 0
        lora_indices[i] = lora_idx
        if long_lora_context:
            assert long_lora_offsets is not None
            lora_offset: int = long_lora_context.offsets_by_lora_id.get(
                index_mapping_indices[i], 0)
            long_lora_offsets[i] = lora_offset

    indices_list: List[Union[List[int], torch.Tensor]] = [
        index_mapping_indices, lora_indices, embedding_indices
    ]
    if long_lora_context:
        assert long_lora_offsets is not None
        indices_list.append(long_lora_offsets)
    indices = torch.tensor(indices_list, dtype=torch.long, device="cuda")
    prompt_mapping_tensor = torch.tensor(prompt_mapping,
                                         device="cuda",
                                         dtype=torch.long)
    embeddings_indices = torch.stack([
        indices[2] * extra_vocab_size,
        indices[2] * (vocab_size + extra_vocab_size)
    ])
    embeddings_indices[embeddings_indices == -1] = max_loras - 1
    base_indices = indices[1]
    sampler_indices = prompt_mapping_tensor
    sampler_indices_padded = sampler_indices.clone()
    sampler_indices_padded[sampler_indices_padded == -1] = max_loras - 1
    sampler_indices_padded = (
        torch.arange(
            0, len(sampler_indices_padded), device="cuda", dtype=torch.long) +
        (sampler_indices_padded * len(sampler_indices_padded)))
    long_lora_indices = None
    long_lora_indices_len: Optional[int] = None
    if long_lora_context:
        long_lora_indices = indices[3]
        long_lora_indices_len = long_lora_indices.shape[-1]
    # Contain length of indices tensors. Used to index into each tensor.
    indices_len = [
        base_indices.shape[-1], sampler_indices.shape[-1],
        sampler_indices_padded.shape[-1], embeddings_indices.shape[-1]
    ]
    if long_lora_indices_len is not None:
        indices_len.append(long_lora_indices_len)

    return (base_indices, sampler_indices, sampler_indices_padded,
            embeddings_indices, long_lora_indices, indices_len)


def get_lora_id():
    global _GLOBAL_LORA_ID
    _GLOBAL_LORA_ID += 1
    return _GLOBAL_LORA_ID


class LoRAModel:
    """A LoRA fine-tuned model."""

    def __init__(
        self,
        lora_model_id: int,
        rank: int,
        loras: Dict[str, LoRALayerWeights],
        scaling_factor: Optional[float] = None,
    ) -> None:
        """
        Args:
            lora_model_id: The integer id for the lora model.
            rank: lora rank.
            loras: module name -> weights for lora-replaced layers.
            scaling_factor: Scaling factor to support long context lora model.
                None if the lora is not tuned for long context support.
        """
        self.id = lora_model_id
        # Scaling factor for long context lora model. None if it is not
        # fine tuned for the long context.
        self.scaling_factor = scaling_factor
        assert (lora_model_id >
                0), f"a valid lora id should be greater than 0, got {self.id}"
        self.rank = rank
        self.loras: Dict[str, LoRALayerWeights] = loras

    def clone(self, lora_model_id: int) -> "LoRAModel":
        """Return a copy of the object with different ids.

        Will share the underlying tensors."""
        return self.__class__(
            lora_model_id,
            rank=self.rank,
            loras=self.loras.copy(),
        )

    @property
    def extra_vocab_size(self) -> int:
        return max(lora.extra_vocab_size
                   for lora in self.loras.values()) if self.loras else 0

    def get_lora(self, module_name: str) -> Optional[LoRALayerWeights]:
        """Get LoRA for a given module by name"""
        return self.loras.get(module_name, None)

    # (yard1): TODO see if we can derive target_embedding_padding automatically
    @classmethod
    def from_lora_tensors(
        cls,
        lora_model_id: int,
        rank: int,
        lora_alpha: int,
        tensors: Dict[str, torch.Tensor],
        device: str = "cuda",
        dtype: Optional[torch.dtype] = None,
        embeddings: Optional[Dict[str, torch.Tensor]] = None,
        target_embedding_padding: Optional[int] = None,
        scaling_factor: Optional[float] = None,
        embedding_modules: Optional[Dict[str, str]] = None,
        embedding_padding_modules: Optional[List[str]] = None,
    ) -> "LoRAModel":
        """Create a LoRAModel from a dictionary of tensors."""
        pin_memory = str(device) == "cpu" and is_pin_memory_available()
        loras: Dict[str, LoRALayerWeights] = {}
        for tensor_name, tensor in tensors.items():
            module_name, is_lora_a = parse_fine_tuned_lora_name(tensor_name)
            if module_name not in loras:
                lora_embeddings_tensor = None
                if embeddings:
                    assert embedding_modules is not None
                    embeddings_module = next(
                        (k for k in embedding_modules if k in module_name),
                        None)
                    if embeddings_module:
                        lora_embeddings_tensor = embeddings[
                            embedding_modules[embeddings_module]].to(
                                device=device, dtype=dtype)
                        if pin_memory:
                            lora_embeddings_tensor = (
                                lora_embeddings_tensor.pin_memory())
                loras[module_name] = LoRALayerWeights(module_name, rank,
                                                      lora_alpha, None, None,
                                                      lora_embeddings_tensor)
            if is_lora_a:
                loras[module_name].lora_a = tensor.to(device=device,
                                                      dtype=dtype).t()
                if pin_memory:
                    loras[module_name].lora_a = loras[
                        module_name].lora_a.pin_memory()
            else:
                loras[module_name].lora_b = tensor.to(device=device,
                                                      dtype=dtype).t()
                assert embedding_padding_modules is not None
                if any(name in module_name
                       for name in embedding_padding_modules
                       ) and target_embedding_padding is not None:
                    lora_b = loras[module_name].lora_b
                    assert target_embedding_padding >= lora_b.shape[1]
                    addition = target_embedding_padding - lora_b.shape[1]
                    loras[module_name].lora_b = torch.nn.functional.pad(
                        lora_b, (0, addition))
                if pin_memory:
                    loras[module_name].lora_b = loras[
                        module_name].lora_b.pin_memory()

        for lora in loras.values():
            lora.optimize()
        return cls(lora_model_id, rank, loras, scaling_factor=scaling_factor)

    @classmethod
    def from_local_checkpoint(
        cls,
        lora_dir: str,
        expected_lora_modules: List[str],
        *,
        max_position_embeddings: Optional[int] = None,
        lora_model_id: Optional[int] = None,
        device: str = "cuda",
        dtype: Optional[torch.dtype] = None,
        target_embedding_padding: Optional[int] = None,
        embedding_modules: Optional[Dict[str, str]] = None,
        embedding_padding_modules: Optional[List[str]] = None,
    ) -> "LoRAModel":
        """Create a LoRAModel from a local checkpoint.
        
        Args:
            lora_dir: The local path that has lora data.
            expected_lora_modules: Name of modules that are expected to be
                replaced by lora.
            max_position_embeddings: Max position embedding length. Used to
                scaling the largest context length. If None, the lora model's
                context length is not scaled.
            lora_model_id: Lora model id. If not given, automatically set by
                a global counter.
            device: Device where the lora model is loaded.
            dtype: dtype of the lora model weights.

        Returns:
            Loaded LoRA Model.
        """
        lora_config_path = os.path.join(lora_dir, "adapter_config.json")
        lora_tensor_path = os.path.join(lora_dir, "adapter_model.safetensors")
        lora_bin_file_path = os.path.join(lora_dir, "adapter_model.bin")
        new_embeddings_tensor_path = os.path.join(
            lora_dir, "new_embeddings.safetensors")
        new_embeddings_bin_file_path = os.path.join(lora_dir,
                                                    "new_embeddings.bin")
        with open(lora_config_path) as f:
            config = json.load(f)
        target_modules = config["target_modules"]
        unexpected_modules = []
        for module in target_modules:
            # Compatible with more modules, such as:layers.11.self_attn.k_proj
            part_name = module.split(".")[-1]
            if part_name not in expected_lora_modules:
                unexpected_modules.append(module)
        # loaded lora's target modules must be a subset of expected_lora_modules
        if unexpected_modules:
            raise ValueError(
                f"While loading {lora_dir}, expected"
                f" target modules in {expected_lora_modules}"
                f" but received {unexpected_modules}."
                f" Please verify that the loaded LoRA module is correct")
        if os.path.isfile(lora_tensor_path):
            tensors = safetensors.torch.load_file(lora_tensor_path)
        elif os.path.isfile(lora_bin_file_path):
            tensors = torch.load(lora_bin_file_path)
        else:
            raise ValueError(f"{lora_dir} doesn't contain tensors")

        embeddings = None
        if os.path.isfile(new_embeddings_tensor_path):
            embeddings = safetensors.torch.load_file(
                new_embeddings_tensor_path)
        elif os.path.isfile(new_embeddings_bin_file_path):
            embeddings = torch.load(new_embeddings_bin_file_path)

        rank = config["r"]
        lora_alpha = config["lora_alpha"]
        context_length = config.get("context_length", None)
        scaling_factor = None
        if context_length:
            if max_position_embeddings is None:
                max_position_embeddings = context_length
            scaling_factor = float(
                math.ceil(context_length / max_position_embeddings))

        return cls.from_lora_tensors(
            lora_model_id=get_lora_id()
            if lora_model_id is None else lora_model_id,
            rank=rank,
            lora_alpha=lora_alpha,
            tensors=tensors,
            device=device,
            dtype=dtype,
            embeddings=embeddings,
            target_embedding_padding=target_embedding_padding,
            scaling_factor=scaling_factor,
            embedding_modules=embedding_modules,
            embedding_padding_modules=embedding_padding_modules,
        )


class LoRAModelManager:
    """A manager that manages multiple LoRA-fine-tuned models."""

    def __init__(
        self,
        model: nn.Module,
        max_num_seqs: int,
        max_num_batched_tokens: int,
        vocab_size: int,
        lora_config: LoRAConfig,
    ):
        """Create a LoRAModelManager and adapter for a given model.

        Args:
            model: the model to be adapted.
            max_num_seqs: the maximum number of sequences model can run in a
                single batch.
            max_num_batched_tokens: the maximum number of tokens model can run
                in a single batch.
            vocab_size: the vocab size of the model.
            lora_config: the LoRA configuration.
        """
        self.lora_config = lora_config
        self.max_num_seqs = max_num_seqs
        assert self.capacity >= self.lora_slots
        self.max_num_batched_tokens = math.ceil(max_num_batched_tokens / 8) * 8
        self.lora_index_to_id: List[Optional[int]] = [None] * self.lora_slots
        self.vocab_size = vocab_size
        self.long_lora_context: Optional[LongContextLoRAContext] = None
        self.base_indices = torch.empty(self.max_num_batched_tokens,
                                        dtype=torch.long,
                                        device="cuda")
        self.sampler_indices = torch.empty(self.max_num_batched_tokens,
                                           dtype=torch.long,
                                           device="cuda")
        self.sampler_indices_padded = torch.empty(self.max_num_batched_tokens,
                                                  dtype=torch.long,
                                                  device="cuda")
        self.embeddings_indices = torch.empty(2,
                                              self.max_num_batched_tokens,
                                              dtype=torch.long,
                                              device="cuda")
        self.long_lora_indices = torch.empty(self.max_num_batched_tokens,
                                             dtype=torch.long,
                                             device="cuda")
        # Scaling factor -> offset to the sin_cos_cache to it.
        # Used for long context lora.
        self.scaling_factor_to_offset: Dict[float, int] = {}
        # 4 is the number of indicies tensors defined above
        # base_indices, sampler_indices, sampler_indices_padded,
        # embeddings_indices
        self.indices_len: List[Optional[int]] = [None] * 4

        self.model: nn.Module = model
        if hasattr(self.model, "supported_lora_modules"):
            self.supported_lora_modules = copy.deepcopy(
                self.model.supported_lora_modules)
            if lora_config.long_lora_scaling_factors:
                # We need to replace rotary emb layer to do batch computation
                # for long lora.
                self.supported_lora_modules.append("rotary_emb")
            self.packed_modules_mapping = copy.deepcopy(
                self.model.packed_modules_mapping)
        self.packed_modules: Dict[str, List[str]] = {}
        self.modules: Dict[str, "BaseLayerWithLoRA"] = {}
        self._registered_loras: Dict[int, LoRAModel] = {}
        # Dict instead of a Set for compatibility with LRUCache.
        self._active_loras: Dict[int, None] = {}
        self._last_mapping: Optional[LoRAMapping] = None
        self._create_lora_modules()
        self.model.lora_manager = self

    @property
    def capacity(self) -> int:
        return self.lora_config.max_cpu_loras

    @property
    def lora_slots(self) -> int:
        return self.lora_config.max_loras

    def __len__(self) -> int:
        return len(self._registered_loras)

    def activate_lora(
        self,
        lora_id: int,
    ) -> bool:
        """Move LoRA into a GPU buffer to be used in the forward pass."""
        if lora_id in self._active_loras:
            return False
        first_free_slot = next(
            ((i, lora_id) for i, lora_id in enumerate(self.lora_index_to_id)
             if lora_id is None), None)
        if first_free_slot is None:
            raise ValueError("No free lora slots")
        index, _ = first_free_slot
        self._active_loras[lora_id] = None
        lora_model = self._registered_loras[lora_id]
        logger.debug("Activating LoRA. int id: %d, slot index: %d",
                     lora_model.id, index)
        self.lora_index_to_id[index] = lora_model.id
        for module_name, module in self.modules.items():
            module_lora = lora_model.get_lora(module_name)
            if module_lora:
                module_lora.optimize()
                module.set_lora(index, module_lora.lora_a, module_lora.lora_b,
                                module_lora.embeddings_tensor)
            else:
                module.reset_lora(index)
        return True

    def _deactivate_lora(self, lora_id: int):
        try:
            index = self.lora_index_to_id.index(lora_id)
            self.lora_index_to_id[index] = None
        except ValueError:
            pass

    def deactivate_lora(self, lora_id: int) -> bool:
        """Remove a LoRA from a GPU buffer."""
        if lora_id in self._active_loras:
            self._deactivate_lora(lora_id)
            self._active_loras.pop(lora_id)
            return True
        return False

    def _set_long_lora_context(self, lora: LoRAModel):
        if self.long_lora_context is None:
            return

        if lora.scaling_factor is None:
            return

        if (lora.scaling_factor not in self.scaling_factor_to_offset):
            raise ValueError(f"Long LoRA scaling factor {lora.scaling_factor}"
                             " has not been initialized.")

        offsets = self.scaling_factor_to_offset.get(lora.scaling_factor)
        if offsets:
            self.long_lora_context.offsets_by_lora_id[lora.id] = offsets

    def _add_lora(self, lora: LoRAModel):
        self._create_merged_loras_inplace(lora)
        self._registered_loras[lora.id] = lora
        self._set_long_lora_context(lora)

    def add_lora(self, lora: LoRAModel) -> bool:
        """Add a LoRAModel to the manager CPU cache."""
        logger.debug(
            "Adding lora. Model id: %d, "
            "int id: %d, "
            "scaling factor: %s", lora.id, lora.id, lora.scaling_factor)
        if lora.id not in self._registered_loras:
            if len(self._registered_loras) >= self.capacity:
                raise RuntimeError("No free LoRA slots.")
            self._add_lora(lora)
            return True
        return False

    def remove_lora(self, lora_id: int) -> bool:
        """Remove a LoRAModel from the manager CPU cache."""
        # TODO: should we check active lora?
        self.deactivate_lora(lora_id)
        if self.long_lora_context:
            self.long_lora_context.offsets_by_lora_id.pop(lora_id, None)
        return bool(self._registered_loras.pop(lora_id, None))

    # TODO see if this can be vectorized
    def _set_lora_mapping(self, mapping: LoRAMapping) -> None:
        (base_indices, sampler_indices, sampler_indices_padded,
         embeddings_indices, long_lora_offsets_tensor,
         indices_len) = convert_mapping(mapping, self.lora_index_to_id,
                                        self.lora_slots + 1, self.vocab_size,
                                        self.lora_config.lora_extra_vocab_size,
                                        self.long_lora_context)
        self.base_indices[:base_indices.shape[0]].copy_(base_indices)
        self.sampler_indices[:sampler_indices.shape[0]].copy_(sampler_indices)
        self.sampler_indices_padded[:sampler_indices_padded.shape[0]].copy_(
            sampler_indices_padded)
        self.embeddings_indices[:embeddings_indices.
                                shape[0], :embeddings_indices.shape[1]].copy_(
                                    embeddings_indices)
        if long_lora_offsets_tensor is not None:
            self.long_lora_indices[:long_lora_offsets_tensor.shape[0]].copy_(
                long_lora_offsets_tensor)
        else:
            self.long_lora_indices.zero_()
        # Maintain the reference
        self.indices_len[:] = indices_len

    def set_lora_mapping(self, lora_mapping: LoRAMapping) -> None:
        if self._last_mapping != lora_mapping:
            self._set_lora_mapping(lora_mapping)
        self._last_mapping = lora_mapping

    def list_loras(self) -> Dict[int, LoRAModel]:
        """List all registered LoRAModels."""
        return dict(self._registered_loras)

    def get_lora(self, lora_id: int) -> Optional[LoRAModel]:
        return self._registered_loras.get(lora_id, None)

    def remove_all_loras(self):
        """Remove all LoRAModels from the manager."""
        self._registered_loras.clear()
        self.lora_index_to_id = [None] * self.lora_slots
        self._active_loras.clear()

    def _create_lora_modules(self):
        for module_name, module in self.model.named_modules(
                remove_duplicate=False):
            if not self._match_target_modules(module_name):
                continue
            parts = module_name.split(".")[-1]
            packed_moduled_lst = self.packed_modules_mapping.get(parts, [])
            new_module = replace_submodule(
                self.model, module_name,
                from_layer(module, self.lora_slots, self.lora_config,
                           packed_moduled_lst, self.model.config))
            # LinearScalingRotaryEmbeddingWithLora is used to handle
            # long context lora. Register relevant metadata.
            if isinstance(new_module, LinearScalingRotaryEmbeddingWithLora):
                self.long_lora_context = LongContextLoRAContext(
                    new_module.scaling_factors, new_module.rotary_dim)
                self.scaling_factor_to_offset = \
                    new_module.scaling_factor_to_offset
            # (yard1): TODO make this more robust
            if "lm_head" in module_name:
                logits_processor_module = self.model.get_submodule(
                    "logits_processor")
                new_module = replace_submodule(
                    self.model, "logits_processor",
                    from_layer_logits_processor(logits_processor_module,
                                                module, self.lora_slots,
                                                self.lora_config,
                                                self.model.config))
            self.register_module(module_name, new_module)
            self._register_packed_modules(module_name)
            new_module.set_mapping(self.base_indices, self.sampler_indices,
                                   self.sampler_indices_padded,
                                   self.embeddings_indices,
                                   self.long_lora_indices, self.indices_len)

    def register_module(self, module_name: str, module: "BaseLayerWithLoRA"):
        assert isinstance(module, BaseLayerWithLoRA)
        self.modules[module_name] = module

    def create_dummy_lora(
            self,
            lora_id: int,
            rank: int,
            scaling_factor: Optional[float],
            embedding_modules: Optional[Dict[str, str]] = None) -> LoRAModel:
        """Create zero-initialized LoRAModel for warmup."""
        model = LoRAModel(lora_id, rank, {}, scaling_factor)
        for module_name, module in self.model.named_modules():
            if not self._match_target_modules(module_name) or not isinstance(
                    module, BaseLayerWithLoRA) or isinstance(
                        module, LinearScalingRotaryEmbeddingWithLora):
                continue
            parts = module_name.split(".")
            if module_name not in self.packed_modules:
                assert embedding_modules is not None
                if parts[-1] in embedding_modules:
                    input_dim = (module.base_layer.org_vocab_size +
                                 self.lora_config.lora_extra_vocab_size if
                                 hasattr(module.base_layer, "org_vocab_size")
                                 else module.base_layer.weight.shape[1])
                    output_dim = module.base_layer.embedding_dim if hasattr(
                        module.base_layer,
                        "embedding_dim") else module.base_layer.weight.shape[0]
                    embeddings_tensor_dim = (module.base_layer.embedding_dim if
                                             hasattr(module.base_layer,
                                                     "embedding_dim") else
                                             module.base_layer.weight.shape[1])
                    lora = LoRALayerWeights.create_dummy_lora_weights(
                        module_name,
                        input_dim,
                        output_dim,
                        rank,
                        module.lora_a_stacked.dtype,
                        "cpu",
                        embeddings_tensor_dim=embeddings_tensor_dim)
                else:
                    lora = LoRALayerWeights.create_dummy_lora_weights(
                        module_name,
                        module.lora_a_stacked.shape[-1],
                        module.lora_b_stacked.shape[-2],
                        rank,
                        module.lora_a_stacked.dtype,
                        "cpu",
                    )
                lora.optimize()
            else:
                parts = module_name.split(".")
                replacements = self.packed_modules_mapping[parts[-1]]
                subloras: List[Optional["LoRALayerWeights"]] = []
                for i, r in enumerate(replacements):
                    lora = LoRALayerWeights.create_dummy_lora_weights(
                        module_name + "." + r,
                        module.lora_a_stacked[i].shape[-1],
                        module.lora_b_stacked[i].shape[-2],
                        rank,
                        module.lora_a_stacked[i].dtype,
                        "cpu",
                    )
                    lora.optimize()
                    subloras.append(lora)
                lora = PackedLoRALayerWeights.pack(subloras)
            model.loras[module_name] = lora
        return model

    def _match_target_modules(self, module_name: str):
        return any(
            re.match(
                r".*\.{target_module}$".format(target_module=target_module),
                module_name) or target_module == module_name
            for target_module in self.supported_lora_modules)

    def _register_packed_modules(self, module_full_name: str) -> None:
        parts = module_full_name.split(".")
        module_name = parts[-1]
        replacements = self.packed_modules_mapping.get(module_name, [])
        # When replacements is less than or equal to 1, it indicates that this
        # module is not a packed module.
        if len(replacements) <= 1:
            return
        prefix = ".".join(parts[:-1])
        self.packed_modules[module_full_name] = [
            prefix + "." + r if prefix else r for r in replacements
        ]

    def _create_merged_loras_inplace(self, lora_model: LoRAModel) -> None:
        for module_name, new_module_names in self.packed_modules.items():
            replacement_loras: List[Optional[LoRALayerWeights]] = []
            has_replacement = False
            for r in new_module_names:
                lora = lora_model.get_lora(r)
                replacement_loras.append(lora)
                if lora:
                    has_replacement = True
            if not has_replacement:
                continue
            for i in range(len(replacement_loras)):
                if replacement_loras[i]:
                    continue
                replacement_loras[i] = None
            lora_model.loras[module_name] = PackedLoRALayerWeights.pack(
                replacement_loras)


class LoRALRUCache(LRUCache[LoRAModel]):

    def __init__(self, capacity: int, deactivate_lora_fn: Callable[[int],
                                                                   bool]):
        super().__init__(capacity)
        self.deactivate_lora_fn = deactivate_lora_fn

    def _on_remove(self, key: int, value: LoRAModel):
        logger.debug("Removing LoRA. int id: %d", key)
        self.deactivate_lora_fn(key)
        return super()._on_remove(key, value)


class LRUCacheLoRAModelManager(LoRAModelManager):
    """A model manager that manages multiple LoRAs with LRU cache."""

    def __init__(
        self,
        model: nn.Module,
        max_num_seqs: int,
        max_num_batched_tokens: int,
        vocab_size: int,
        lora_config: LoRAConfig,
    ):
        super().__init__(model, max_num_seqs, max_num_batched_tokens,
                         vocab_size, lora_config)
        self._registered_loras: LoRALRUCache = LoRALRUCache(
            self.capacity, self.deactivate_lora)
        self._active_loras: LoRALRUCache = LoRALRUCache(
            self.lora_slots, self._deactivate_lora)

    def list_loras(self) -> Dict[int, LoRAModel]:
        """List all registered LoRAModels."""
        return dict(self._registered_loras.cache)

    def add_lora(self, lora: LoRAModel) -> bool:
        """Add a LoRAModel to the manager."""
        logger.debug(
            "Adding lora. Model id: %d, "
            "int id: %d, "
            "scaling factor: %s", lora.id, lora.id, lora.scaling_factor)
        if lora.id not in self._registered_loras:
            self._add_lora(lora)
            was_added = True
        else:
            # We always touch to update the LRU cache order
            self._registered_loras.touch(lora.id)
            was_added = False
        return was_added

    def activate_lora(
        self,
        lora_id: int,
    ) -> bool:
        if lora_id not in self._active_loras and len(
                self._active_loras) >= self.lora_slots:
            self._active_loras.remove_oldest()
        result = super().activate_lora(lora_id)
        # We always touch to update the LRU cache order
        self._active_loras.touch(lora_id)
        return result

    def remove_oldest_lora(self) -> bool:
        if len(self._registered_loras) > 0:
            self._registered_loras.remove_oldest()
            return True
        return False


def create_lora_manager(
        model: nn.Module,
        max_num_seqs: int,
        max_num_batched_tokens: int,
        vocab_size: int,
        lora_config: LoRAConfig,
        lora_manager_cls: Type[LoRAModelManager] = LoRAModelManager,
        **kwargs) -> LoRAModelManager:
    """Create a LoRA adapter for a given model."""
    if not hasattr(model, "supported_lora_modules"):
        raise ValueError(f"Model {type(model)} is not supported for LoRA.")
    lora_manager = lora_manager_cls(
        model=model,
        max_num_seqs=max_num_seqs,
        max_num_batched_tokens=max_num_batched_tokens,
        vocab_size=vocab_size,
        lora_config=lora_config,
        **kwargs)
    return lora_manager