# SPDX-License-Identifier: Apache-2.0 # SPDX-FileCopyrightText: Copyright contributors to the vLLM project # pylint: disable=unused-argument import math from dataclasses import dataclass from typing import TYPE_CHECKING, Optional, Union, cast import torch import torch.nn as nn import torch.nn.functional as F from transformers import PretrainedConfig from vllm.adapter_commons.layers import AdapterMapping from vllm.config import LoRAConfig from vllm.distributed import (get_tensor_model_parallel_rank, get_tensor_model_parallel_world_size, split_tensor_along_last_dim, tensor_model_parallel_all_gather, tensor_model_parallel_all_reduce) from vllm.distributed.utils import divide # yapf: disable from vllm.model_executor.layers.linear import (ColumnParallelLinear, LinearBase, MergedColumnParallelLinear, QKVParallelLinear, ReplicatedLinear, RowParallelLinear) # yapf: enable from vllm.model_executor.layers.logits_processor import LogitsProcessor from vllm.model_executor.layers.vocab_parallel_embedding import ( VocabParallelEmbedding) from vllm.platforms import current_platform if TYPE_CHECKING: from vllm.lora.punica_wrapper import PunicaWrapperBase def _get_lora_device(base_layer: nn.Module) -> torch.device: # code borrowed from https://github.com/fmmoret/vllm/blob/fm-support-lora-on-quantized-models/vllm/lora/layers.py#L34 """Returns the device for where to place the LoRA tensors.""" # unquantizedLinear if hasattr(base_layer, "weight"): return base_layer.weight.device # Compressed Tensor elif hasattr(base_layer, "weight_packed"): return base_layer.weight_packed.device # GPTQ/AWQ elif hasattr(base_layer, "qweight"): return base_layer.qweight.device # marlin elif hasattr(base_layer, "B"): return base_layer.B.device # HQQ marlin elif hasattr(base_layer, "W_q"): return base_layer.W_q.device else: raise ValueError(f"Unsupported base layer: {base_layer}") def _not_fully_sharded_can_replace(can_replace): """ decorator which adds the condition of not using fully sharded loras intended to wrap can_replace_layer() """ def dec(*args, **kwargs): decorate = kwargs.pop("decorate") if "decorate" in kwargs else True condition = (not kwargs["lora_config"].fully_sharded_loras if decorate else True) return can_replace(*args, **kwargs) and condition return dec @dataclass class LoRAMapping(AdapterMapping): is_prefill: bool = False class BaseLayerWithLoRA(nn.Module): def slice_lora_a( self, lora_a: Union[torch.Tensor, list[Union[torch.Tensor, None]]] ) -> Union[torch.Tensor, list[Union[torch.Tensor, None]]]: """Slice lora a if splitting for tensor parallelism.""" ... def slice_lora_b( self, lora_b: Union[torch.Tensor, list[Union[torch.Tensor, None]]] ) -> Union[torch.Tensor, list[Union[torch.Tensor, None]]]: """Slice lora b if splitting with tensor parallelism.""" ... def create_lora_weights( self, max_loras: int, lora_config: LoRAConfig, model_config: Optional[PretrainedConfig] = None, ) -> None: """Initializes lora matrices.""" ... def reset_lora(self, index: int): """Resets the lora weights at index back to 0.""" ... def set_lora( self, index: int, lora_a: torch.Tensor, lora_b: torch.Tensor, embeddings_tensor: Optional[torch.Tensor], bias: Optional[torch.Tensor] = None, ): """Overwrites lora tensors at index.""" ... def set_mapping( self, punica_wrapper, ): self.punica_wrapper: PunicaWrapperBase = punica_wrapper @classmethod def can_replace_layer( cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig], ) -> bool: """Returns True if the layer can be replaced by this LoRA layer.""" raise NotImplementedError class VocabParallelEmbeddingWithLoRA(BaseLayerWithLoRA): def __init__(self, base_layer: VocabParallelEmbedding) -> None: super().__init__() self.base_layer = base_layer self.embeddings_slice: Optional[tuple[int, int]] self.embeddings_weights: Optional[torch.Tensor] def create_lora_weights( self, max_loras: int, lora_config: LoRAConfig, model_config: Optional[PretrainedConfig] = None) -> None: if self.base_layer.num_added_embeddings_per_partition > 0: # We can start adding lora weights self.embeddings_weights = self.base_layer.weight.data[ self.base_layer.num_org_embeddings_per_partition:self. base_layer.num_org_embeddings_per_partition + self.base_layer.num_added_embeddings_per_partition] self.embeddings_slice = ( self.base_layer.shard_indices.added_vocab_start_index - self.base_layer.org_vocab_size, self.base_layer.shard_indices.added_vocab_end_index - self.base_layer.org_vocab_size) self.base_layer.weight.data[ self.base_layer.num_org_embeddings_per_partition:].fill_(0) else: self.embeddings_slice = None self.embeddings_weights = None self.embeddings_tensors = torch.zeros( ( max_loras, lora_config.lora_extra_vocab_size, self.base_layer.embedding_dim, ), dtype=self.base_layer.weight.dtype, device=self.base_layer.weight.device, ) self.lora_a_stacked = torch.zeros( ( max_loras, self.base_layer.org_vocab_size + lora_config.lora_extra_vocab_size, lora_config.max_lora_rank, ), dtype=lora_config.lora_dtype, device=self.base_layer.weight.device, ) self.lora_b_stacked = torch.zeros( ( max_loras, 1, self.base_layer.embedding_dim, lora_config.max_lora_rank, ), dtype=lora_config.lora_dtype, device=self.base_layer.weight.device, ) self.lora_a_stacked_2d = self.lora_a_stacked.view( self.lora_a_stacked.shape[0] * self.lora_a_stacked.shape[1], self.lora_a_stacked.shape[2], ) def reset_lora(self, index: int): self.lora_a_stacked[index] = 0 self.lora_b_stacked[index] = 0 self.embeddings_tensors[index] = 0 def set_lora( self, index: int, lora_a: torch.Tensor, lora_b: torch.Tensor, embeddings_tensor: Optional[torch.Tensor], bias: Optional[torch.Tensor] = None, ): self.reset_lora(index) self.lora_a_stacked[index, :lora_a.shape[0], :lora_a.shape[1]].copy_( lora_a, non_blocking=True) self.lora_b_stacked[index, 0, :lora_b.shape[1], :lora_b.shape[0]].copy_( lora_b.T, non_blocking=True) if embeddings_tensor is not None: self.embeddings_tensors[ index, :embeddings_tensor.shape[0], :embeddings_tensor.shape[1], ].copy_(embeddings_tensor, non_blocking=True) if self.embeddings_slice is not None: # TODO(yard1): Optimize this copy, we don't need to copy # everything, just the modified part embeddings = self.embeddings_tensors.view( self.embeddings_tensors.shape[0] * self.embeddings_tensors.shape[1], self.embeddings_tensors.shape[2], )[self.embeddings_slice[0]:self.embeddings_slice[1]] assert self.embeddings_weights is not None self.embeddings_weights[:embeddings.shape[0]].copy_(embeddings) def forward(self, x: torch.Tensor) -> torch.Tensor: added_tokens_mask = torch.where(x > self.base_layer.org_vocab_size - 1, 1, 0) # NB: Don't use torch.narrow here. torch.narrow triggers some # Dynamic Shape specialization in torch.compile num_tokens = x.shape[0] indices_1 = self.punica_wrapper._embeddings_indices[1][:num_tokens] indices_0 = self.punica_wrapper._embeddings_indices[0][:num_tokens] full_lora_a_embeddings = F.embedding( x + indices_1, self.lora_a_stacked_2d, ) full_output = self.base_layer.forward(x + (indices_0 * added_tokens_mask)) full_output_org = full_output if full_output.ndim == 3: full_output = full_output.view( full_output.shape[0] * full_output.shape[1], -1) if full_lora_a_embeddings.ndim == 3: full_lora_a_embeddings = full_lora_a_embeddings.view( full_lora_a_embeddings.shape[0] * full_lora_a_embeddings.shape[1], -1, ) lora_output: Optional[ torch.Tensor] = self.punica_wrapper.add_lora_embedding( full_output, full_lora_a_embeddings, self.lora_b_stacked, add_input=True) if not current_platform.can_update_inplace(): full_output = lora_output return full_output.view_as(full_output_org) @classmethod def can_replace_layer( cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig], ) -> bool: return type(source_layer) is VocabParallelEmbedding @property def weight(self): return self.base_layer.weight class BaseLinearLayerWithLoRA(BaseLayerWithLoRA): def __init__(self, base_layer: LinearBase): super().__init__() self.base_layer = base_layer self.input_size = self.base_layer.input_size self.device = _get_lora_device(self.base_layer) self.lora_bias_stacked: Optional[tuple[torch.Tensor, ...]] = None self.output_slices: tuple[int, ...] self.tp_size: int self.output_size: int self.n_slices: int def create_lora_weights( self, max_loras: int, lora_config: LoRAConfig, model_config: Optional[PretrainedConfig] = None, ) -> None: self.lora_config = lora_config # if isinstance(self.base_layer, ReplicatedLinear): lora_a_out_size = lora_config.max_lora_rank lora_b_out_size = self.output_size elif isinstance(self.base_layer, ColumnParallelLinear): lora_a_out_size = (lora_config.max_lora_rank if not lora_config.fully_sharded_loras else divide( lora_config.max_lora_rank, self.tp_size)) lora_b_out_size = self.output_size elif isinstance(self.base_layer, RowParallelLinear): lora_a_out_size = lora_config.max_lora_rank lora_b_out_size = (self.output_size if not lora_config.fully_sharded_loras else divide( self.output_size, self.tp_size)) else: raise NotImplementedError self.lora_a_stacked = tuple( torch.zeros( max_loras, 1, lora_a_out_size, self.input_size, dtype=lora_config.lora_dtype, device=self.device, ) for _ in range(self.n_slices)) self.lora_b_stacked = tuple( torch.zeros( max_loras, 1, lora_b_out_size, lora_config.max_lora_rank, dtype=lora_config.lora_dtype, device=self.device, ) for _ in range(self.n_slices)) if lora_config.bias_enabled: lora_bias_out_size = lora_b_out_size self.lora_bias_stacked = tuple( torch.zeros( max_loras, 1, lora_bias_out_size, dtype=lora_config.lora_dtype, device=self.device, ) for _ in range(self.n_slices)) self.output_slices = (self.lora_b_stacked[0].shape[2], ) def reset_lora(self, index: int): for s_index in range(self.n_slices): self.lora_a_stacked[s_index][index] = 0 self.lora_b_stacked[s_index][index] = 0 if self.lora_config.bias_enabled: # Make mypy happy self.lora_bias_stacked = cast(tuple[torch.Tensor, ...], self.lora_bias_stacked) self.lora_bias_stacked[s_index][index] = 0 def set_lora( self, index: int, lora_a: torch.Tensor, lora_b: torch.Tensor, embeddings_tensor: Optional[torch.Tensor], lora_bias: Optional[torch.Tensor] = None, ): # Except for QKVParallelLinearWithLoRA and # MergedColumnParallelLinearWithLoRA, all other linear LoRA layers # store weights in a tuple of size 1. These two layers will # override this function. assert (len(self.lora_a_stacked) == len(self.lora_b_stacked) == self.n_slices == 1) self.reset_lora(index) if self.tp_size > 1: lora_a = self.slice_lora_a(lora_a) lora_b = self.slice_lora_b(lora_b) if lora_bias is not None: lora_bias = self.slice_bias(lora_bias) self.lora_a_stacked[0][index, 0, :lora_a.shape[1], :lora_a.shape[0]].copy_( lora_a.T, non_blocking=True) self.lora_b_stacked[0][index, 0, :lora_b.shape[1], :lora_b.shape[0]].copy_( lora_b.T, non_blocking=True) if lora_bias is not None: self.lora_bias_stacked = cast(tuple[torch.Tensor, ...], self.lora_bias_stacked) assert len(self.lora_bias_stacked) self.lora_bias_stacked[0][index, 0, :lora_bias.shape[0]].copy_( lora_bias.T, non_blocking=True) def apply(self, x: torch.Tensor, bias: Optional[torch.Tensor] = None) -> torch.Tensor: output = self.base_layer.quant_method.apply(self.base_layer, x, bias) # In transformers backend, x and output have extra batch dimension like # (1, seq_len, hidden_dim), while punica expects (seq_len, hidden_dim), # therefore we need to flatten the batch dimensions. if x.ndim == 3 and output.ndim == 3: output = output.flatten(0, 1) x = x.flatten(0, 1) lora_output: Optional[ torch.Tensor] = self.punica_wrapper.add_lora_linear( output, x, self.lora_a_stacked, self.lora_b_stacked, self.lora_bias_stacked, 1.0, self.output_slices) if not current_platform.can_update_inplace(): output = lora_output return output @property def weight(self) -> torch.Tensor: # unquantizedLinear if hasattr(self.base_layer, "weight"): return self.base_layer.weight # Compressed Tensor elif hasattr(self.base_layer, "weight_packed"): return self.base_layer.weight_packed # GPTQ/AWQ elif hasattr(self.base_layer, "qweight"): return self.base_layer.qweight # marlin elif hasattr(self.base_layer, "B"): return self.base_layer.B # HQQ marlin elif hasattr(self.base_layer, "W_q"): return self.base_layer.W_q else: raise ValueError(f"Unsupported base layer: {self.base_layer}") @property def bias(self) -> Optional[torch.Tensor]: if hasattr(self.base_layer, "bias"): return self.base_layer.bias else: return None class ReplicatedLinearWithLoRA(BaseLinearLayerWithLoRA): def __init__(self, base_layer: ReplicatedLinear) -> None: super().__init__(base_layer, ) # To ensure interface compatibility, set to 1 always. self.tp_size = 1 self.output_size = self.base_layer.output_size self.n_slices = 1 def forward( self, input_: torch.Tensor ) -> Union[torch.Tensor, tuple[torch.Tensor, Optional[torch.Tensor]]]: """Forward of ReplicatedLinearWithLoRA Args: input_: Tensor whose last dimension is `input_size`. Returns: - output - bias """ bias = (self.base_layer.bias if not self.base_layer.skip_bias_add else None) # Matrix multiply. output = self.apply(input_, bias) output_bias = (self.base_layer.bias if self.base_layer.skip_bias_add else None) if not self.base_layer.return_bias: return output return output, output_bias # ReplicatedLinear should always be replaced, regardless of the fully # sharded LoRAs setting, because it is, by definition, copied per GPU. @classmethod def can_replace_layer( cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig], ) -> bool: return type(source_layer) is ReplicatedLinear class ColumnParallelLinearWithLoRA(BaseLinearLayerWithLoRA): """ LoRA on top of ColumnParallelLinear layer. LoRA B is sliced for tensor parallelism. There are two types for the `base_layer`: 1. ColumnParallelLinear, e.g.`dense_h_to_4h` in `FalconForCausalLM`. 2. MergedColumnParallelLinear, e.g.`gate_up_proj` in `Phi3ForCausalLM`. """ def __init__(self, base_layer: ColumnParallelLinear) -> None: super().__init__(base_layer) # The base_layer type is ColumnParallelLinear or # MergedColumnParallelLinear, their weight sharding logic is # inconsistent when TP is greater than 1. self.is_merged_col_linear = type( base_layer) is MergedColumnParallelLinear self.tp_size = get_tensor_model_parallel_world_size() self.output_size = self.base_layer.output_size_per_partition # There is only one LoRA layer self.n_slices = 1 def slice_lora_a(self, lora_a: torch.Tensor) -> torch.Tensor: return lora_a def slice_lora_b(self, lora_b: torch.Tensor) -> torch.Tensor: # Applicable to cases where the base_layer is # MergedColumnParallelLinear. if self.is_merged_col_linear: tp_rank = get_tensor_model_parallel_rank() shard_size = self.output_size // 2 offset = lora_b.shape[-1] // 2 left_weight = lora_b[:, tp_rank * shard_size:(tp_rank + 1) * shard_size] right_weight = lora_b[:, offset + tp_rank * shard_size:offset + (tp_rank + 1) * shard_size] lora_b = torch.cat([left_weight, right_weight], dim=1) # Applicable to cases where the base_layer is # ColumnParallelLinear. else: tensor_model_parallel_rank = get_tensor_model_parallel_rank() shard_size = self.output_size start_idx = tensor_model_parallel_rank * shard_size end_idx = (tensor_model_parallel_rank + 1) * shard_size lora_b = lora_b[:, start_idx:end_idx] return lora_b def slice_bias(self, bias: torch.Tensor) -> torch.Tensor: # TODO: Fix the slicing logic of bias. if bias is None: return bias tensor_model_parallel_rank = get_tensor_model_parallel_rank() shard_size = self.output_size start_idx = tensor_model_parallel_rank * shard_size end_idx = (tensor_model_parallel_rank + 1) * shard_size bias = bias[start_idx:end_idx] return bias def forward( self, input_: torch.Tensor ) -> Union[torch.Tensor, tuple[torch.Tensor, Optional[torch.Tensor]]]: """Forward of ColumnParallelLinear Args: input_: Tensor whose last dimension is `input_size`. Returns: - output - bias """ bias = (self.base_layer.bias if not self.base_layer.skip_bias_add else None) # Matrix multiply. output_parallel = self.apply(input_, bias) if self.base_layer.gather_output: # All-gather across the partitions. output = tensor_model_parallel_all_gather(output_parallel) else: output = output_parallel if not self.base_layer.return_bias: return output output_bias = (self.base_layer.bias if self.base_layer.skip_bias_add else None) return output, output_bias @classmethod @_not_fully_sharded_can_replace def can_replace_layer( cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig], ) -> bool: return type(source_layer) is ColumnParallelLinear or ( type(source_layer) is MergedColumnParallelLinear and len(packed_modules_list) == 1) class MergedColumnParallelLinearWithLoRA(ColumnParallelLinearWithLoRA): """ColumnParallelLinear layer that is composed of 2 sublayers (slices) packed together (eg. gate_proj + up_proj -> gate_up_proj). This means we have 2 LoRAs, each applied to one half of the layer. Both slices must have the same size. """ def __init__( self, base_layer: Union[MergedColumnParallelLinear, QKVParallelLinear]) -> None: super().__init__(base_layer) # There are two LoRA layers self.tp_size = get_tensor_model_parallel_world_size() self.tp_rank = get_tensor_model_parallel_rank() # the output_sizes in MergedColumnParallelLinear is not sharded by tp # we need to divide it by the tp_size to get correct slices size output_sizes = self.base_layer.output_sizes self.output_slices = tuple( divide(output_size, self.tp_size) for output_size in output_sizes) self.n_slices = len(self.output_slices) self.output_ids = (self.tp_rank, ) * self.n_slices def create_lora_weights( self, max_loras: int, lora_config: LoRAConfig, model_config: Optional[PretrainedConfig] = None, ) -> None: """ The main reason for overriding this function is to enhance code maintainability. """ self.lora_config = lora_config lora_a_output_size_per_partition = ( lora_config.max_lora_rank if not lora_config.fully_sharded_loras else divide(lora_config.max_lora_rank, self.tp_size)) self.lora_a_stacked = tuple( torch.zeros( max_loras, 1, lora_a_output_size_per_partition, self.input_size, dtype=lora_config.lora_dtype, device=self.device, ) for _ in range(self.n_slices)) self.lora_b_stacked = tuple( torch.zeros( max_loras, 1, output_size, lora_config.max_lora_rank, dtype=lora_config.lora_dtype, device=self.device, ) for output_size in self.output_slices) if lora_config.bias_enabled: self.lora_bias_stacked = tuple( torch.zeros( max_loras, 1, output_size, dtype=lora_config.lora_dtype, device=self.device, ) for output_size in self.output_slices) def slice_lora_a( self, lora_a: list[Union[torch.Tensor, None]] ) -> list[Union[torch.Tensor, None]]: return lora_a def slice_lora_b( self, lora_b: list[Union[torch.Tensor, None]] ) -> list[Union[torch.Tensor, None]]: sliced_lora_b = [None] * self.n_slices for i, (shard_id, shard_size) in enumerate( zip(self.output_ids, self.output_slices)): if (lora_b_i := lora_b[i]) is not None: sliced_lora_b[i] = lora_b_i[:, shard_size * shard_id:shard_size * (shard_id + 1)] return sliced_lora_b def slice_bias( self, bias: list[Union[torch.Tensor, None]]) -> list[Union[torch.Tensor, None]]: for i, (shard_id, shard_size) in enumerate( zip(self.output_ids, self.output_slices)): if (bias_i := bias[i]) is not None: bias[i] = bias_i[shard_size * shard_id:shard_size * (shard_id + 1)] return bias def set_lora( self, index: int, lora_a: torch.Tensor, lora_b: torch.Tensor, embeddings_tensor: Optional[torch.Tensor], lora_bias: Optional[torch.Tensor] = None, ): self.reset_lora(index) if self.tp_size > 1: lora_a = self.slice_lora_a(lora_a) lora_b = self.slice_lora_b(lora_b) if lora_bias is not None: lora_bias = self.slice_bias(lora_bias) for i in range(self.n_slices): if (lora_a_i := lora_a[i]) is not None: self.lora_a_stacked[i][ index, 0, :lora_a_i.shape[1], :lora_a_i.shape[0]].copy_( lora_a_i.T, non_blocking=True) if (lora_b_i := lora_b[i]) is not None: self.lora_b_stacked[i][ index, 0, :lora_b_i.shape[1], :lora_b_i.shape[0]].copy_( lora_b_i.T, non_blocking=True) if lora_bias is not None: self.lora_bias_stacked = cast(tuple[torch.Tensor, ...], self.lora_bias_stacked) for i in range(self.n_slices): if (lora_bias_i := lora_bias[i]) is not None: self.lora_bias_stacked[i][index, 0, :lora_bias_i.shape[0]].copy_( lora_bias_i.T, non_blocking=True) @classmethod @_not_fully_sharded_can_replace def can_replace_layer( cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig], ) -> bool: return (type(source_layer) is MergedColumnParallelLinear and len(packed_modules_list) == 2) class QKVParallelLinearWithLoRA(ColumnParallelLinearWithLoRA): """ ColumnParallelLinear layer that is specifically designed for qkv_proj. Certain models, such as chatglm3 and baichuan-7b, only contains a single LoRA within their qkv_proj layer. During inference with Tensor Parallel, the weights of lora_b must be accurately partitioned according to the respective ranks. Q slice may have different shape than K and V slices (which both have the same shape). """ def __init__(self, base_layer: QKVParallelLinear) -> None: super().__init__(base_layer) self.q_proj_total_size = (self.base_layer.total_num_heads * self.base_layer.head_size) self.q_proj_shard_size = (self.base_layer.num_heads * self.base_layer.head_size) self.kv_proj_shard_size = (self.base_layer.num_kv_heads * self.base_layer.head_size) self.kv_proj_total_size = (self.base_layer.total_num_kv_heads * self.base_layer.head_size) # There is only one LoRA layer self.n_slices = 1 def slice_lora_b(self, lora_b: torch.Tensor) -> torch.Tensor: tp_rank = get_tensor_model_parallel_rank() self.q_shard_id = tp_rank self.kv_shard_id = tp_rank // self.base_layer.num_kv_head_replicas lora_b_q = lora_b[:, self.q_proj_shard_size * self.q_shard_id:self.q_proj_shard_size * (self.q_shard_id + 1)] k_offset = self.q_proj_total_size lora_b_k = lora_b[:, k_offset + self.kv_proj_shard_size * self.kv_shard_id:k_offset + self.kv_proj_shard_size * (self.kv_shard_id + 1)] v_offset = k_offset + self.kv_proj_total_size lora_b_v = lora_b[:, v_offset + self.kv_proj_shard_size * self.kv_shard_id:v_offset + self.kv_proj_shard_size * (self.kv_shard_id + 1)] lora_b = torch.cat([lora_b_q, lora_b_k, lora_b_v], dim=1) return lora_b def slice_bias(self, bias: torch.Tensor) -> torch.Tensor: bias_q = bias[self.q_proj_shard_size * self.q_shard_id:self.q_proj_shard_size * (self.q_shard_id + 1)] k_offset = self.q_proj_total_size bias_k = bias[k_offset + self.kv_proj_shard_size * self.kv_shard_id:k_offset + self.kv_proj_shard_size * (self.kv_shard_id + 1)] v_offset = k_offset + self.kv_proj_total_size bias_v = bias[v_offset + self.kv_proj_shard_size * self.kv_shard_id:v_offset + self.kv_proj_shard_size * (self.kv_shard_id + 1)] bias = torch.cat([bias_q, bias_k, bias_v], dim=1) return bias @classmethod @_not_fully_sharded_can_replace def can_replace_layer(cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig]) -> bool: return type(source_layer) is QKVParallelLinear and len( packed_modules_list) == 1 class MergedQKVParallelLinearWithLoRA(MergedColumnParallelLinearWithLoRA): """MergedColumnParallelLinear layer that is composed of 3 sublayers (slices) packed together in qkv proj fashion (q_proj + k_proj + v_proj -> qkv_proj). This means we have 3 LoRAs, each applied to one slice of the layer. Q slice may have different shape than K and V slices (which both have the same shape). """ def __init__(self, base_layer: QKVParallelLinear) -> None: super().__init__(base_layer) # There are three LoRA layer. self.n_slices = len(self.base_layer.output_sizes) self.tp_size = get_tensor_model_parallel_world_size() self.tp_rank = get_tensor_model_parallel_rank() self.q_proj_shard_size = (self.base_layer.num_heads * self.base_layer.head_size) self.kv_proj_shard_size = (self.base_layer.num_kv_heads * self.base_layer.head_size) self.q_shard_id = self.tp_rank self.kv_shard_id = self.tp_rank // self.base_layer.num_kv_head_replicas self.output_slices = ( self.q_proj_shard_size, self.kv_proj_shard_size, self.kv_proj_shard_size, ) self.output_ids = ( self.q_shard_id, self.kv_shard_id, self.kv_shard_id, ) def create_lora_weights( self, max_loras: int, lora_config: LoRAConfig, model_config: Optional[PretrainedConfig] = None, ) -> None: """ The main reason for overloading this function is to handle inconsistent weight dimensions in qkv lora. """ super().create_lora_weights(max_loras, lora_config, model_config) @classmethod @_not_fully_sharded_can_replace def can_replace_layer( cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig], ) -> bool: return (type(source_layer) is QKVParallelLinear and len(packed_modules_list) == 3) #TODO: Implement this class QKVCrossParallelLinearWithLoRA(BaseLayerWithLoRA): pass class RowParallelLinearWithLoRA(BaseLinearLayerWithLoRA): def __init__(self, base_layer: RowParallelLinear) -> None: super().__init__(base_layer) self.tp_size = get_tensor_model_parallel_world_size() # reset input_size self.input_size = self.base_layer.input_size_per_partition self.output_size = self.base_layer.output_size self.tp_rank = get_tensor_model_parallel_rank() # There is only one LoRA layer. self.n_slices = 1 def slice_lora_a(self, lora_a: torch.Tensor) -> torch.Tensor: shard_size = self.input_size start_idx = self.tp_rank * shard_size end_idx = (self.tp_rank + 1) * shard_size lora_a = lora_a[start_idx:end_idx, :] return lora_a def slice_lora_b(self, lora_b: torch.Tensor) -> torch.Tensor: return lora_b def slice_bias(self, bias: torch.Tensor) -> torch.Tensor: return bias def forward( self, input_: torch.Tensor ) -> Union[torch.Tensor, tuple[torch.Tensor, Optional[torch.Tensor]]]: """Forward of RowParallelLinear Args: input_: tensor whose last dimension is `input_size`. If `input_is_parallel` is set, then the last dimension is `input_size // tp_size`. Returns: - output - bias """ # set up backprop all-reduce. if self.base_layer.input_is_parallel: input_parallel = input_ else: # TODO: simplify code below splitted_input = split_tensor_along_last_dim( input_, num_partitions=self.base_layer.tp_size) input_parallel = splitted_input[self.tp_rank].contiguous() # Matrix multiply. output_parallel = self.apply(input_parallel) if self.base_layer.reduce_results and self.base_layer.tp_size > 1: output_ = tensor_model_parallel_all_reduce(output_parallel) else: output_ = output_parallel if not self.base_layer.skip_bias_add: output = (output_ + self.base_layer.bias if self.base_layer.bias is not None else output_) output_bias = None else: output = output_ output_bias = self.base_layer.bias if not self.base_layer.return_bias: return output return output, output_bias @classmethod @_not_fully_sharded_can_replace def can_replace_layer( cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig], ) -> bool: return type(source_layer) is RowParallelLinear class LogitsProcessorWithLoRA(BaseLayerWithLoRA): """ LoRA wrapper for LogitsProcessor, with extra logic to handle the application of the LoRA adapter and added LoRA vocabulary. Args: base_layer: LogitsProcessor layer hidden_size: hidden size of the model dtype: data type of the model device: device of the model sharded_to_full_mapping: index mapping from sharded vocab to full vocab received from base_layer.get_sharded_to_full_mapping(). If None, no reindexing will be done. """ def __init__(self, base_layer: LogitsProcessor, hidden_size: int, dtype: torch.dtype, device: torch.device, sharded_to_full_mapping: Optional[list[int]]) -> None: super().__init__() self.base_layer = base_layer self.hidden_size = hidden_size self.dtype = dtype self.device = device self.tp_size = get_tensor_model_parallel_world_size() self.tp_rank = get_tensor_model_parallel_rank() self.sharded_to_full_mapping = sharded_to_full_mapping @property def logits_as_input(self): return self.base_layer.logits_as_input @property def vocab_size(self): return self.base_layer.vocab_size @property def scale(self): return self.base_layer.scale @property def soft_cap(self): return self.base_layer.soft_cap @property def use_all_gather(self): return self.base_layer.use_all_gather @property def org_vocab_size(self): return self.base_layer.org_vocab_size @property def include_gpu_probs_tensor(self): return self.base_layer.include_gpu_probs_tensor @property def should_modify_greedy_probs_inplace(self): return self.base_layer.should_modify_greedy_probs_inplace def create_lora_weights( self, max_loras: int, lora_config: LoRAConfig, model_config: Optional[PretrainedConfig] = None, ) -> None: # TODO: Verify if this condition can be further relaxed if 32000 < self.base_layer.vocab_size > 257024: raise ValueError("When using LoRA, vocab size must be " "32000 >= vocab_size <= 257024") self.lora_a_stacked = torch.zeros( ( max_loras, 1, lora_config.max_lora_rank, self.hidden_size, ), dtype=lora_config.lora_dtype, device=self.device, ) self.lora_b_stacked = torch.zeros( ( max_loras, 1, # Pad for kernel compatibility math.ceil(self.base_layer.vocab_size / lora_config.lora_vocab_padding_size) * lora_config.lora_vocab_padding_size, lora_config.max_lora_rank, ), dtype=lora_config.lora_dtype, device=self.device, ) self.embeddings_tensors = torch.full( (max_loras, lora_config.lora_extra_vocab_size, self.hidden_size), fill_value=float("-inf"), dtype=self.dtype, device=self.device, ) if self.sharded_to_full_mapping is not None: self.sharded_to_full_mapping_gpu = torch.tensor( self.sharded_to_full_mapping, device=self.device, dtype=torch.long) else: self.sharded_to_full_mapping_gpu = None def reset_lora(self, index: int): self.lora_a_stacked[index] = 0 self.lora_b_stacked[index] = 0 self.embeddings_tensors[index] = float("-inf") def set_lora( self, index: int, lora_a: torch.Tensor, lora_b: torch.Tensor, embeddings_tensor: Optional[torch.Tensor], bias: Optional[torch.Tensor] = None, ): self.reset_lora(index) self.lora_a_stacked[index, 0, :lora_a.shape[1], :lora_a.shape[0]].copy_( lora_a.T, non_blocking=True) self.lora_b_stacked[index, 0, :lora_b.shape[1], :lora_b.shape[0]].copy_( lora_b.T, non_blocking=True) if embeddings_tensor is not None: self.embeddings_tensors[ index, :embeddings_tensor.shape[0], :embeddings_tensor.shape[1], ] = embeddings_tensor def _get_logits( self, hidden_states: torch.Tensor, lm_head: VocabParallelEmbedding, embedding_bias: Optional[torch.Tensor] = None, ) -> Optional[torch.Tensor]: # Get the logits for the next tokens. logits = lm_head.quant_method.apply(lm_head, hidden_states) if embedding_bias is not None: logits += embedding_bias # Gather logits for TP logits = self.base_layer._gather_logits(logits) if logits is None: return None if self.sharded_to_full_mapping_gpu is not None: # Reindex full logits tensor to ensure 1:1 mapping between # index and token_id # Example for: # org_vocab_size = 4 # added_vocab_size = 2 # pad_to_size = 8 # tp_size = 2 # indices: [0, 1, 2, 3, 4, 5, 6, 7] # token_id: [0, 1, 4, -1, 2, 3, 5, -1] # Therefore, the mapping is expected to be: # [0, 1, 4, 6, 2, 3, 5, 7] so that when we reindex, # we get: # indices: [0, 1, 2, 3, 4, 5, 6, 7] # token_id: [0, 1, 2, 3, 4, 5, -1, -1] logits = logits[:, self.sharded_to_full_mapping_gpu] lora_logits = torch.empty( self.embeddings_tensors.shape[0] + 1, self.embeddings_tensors.shape[1], hidden_states.shape[0], dtype=self.embeddings_tensors.dtype, device=self.embeddings_tensors.device, ) torch.matmul(self.embeddings_tensors, hidden_states.T, out=lora_logits[:-1]) neg_inf, pos_inf = current_platform.get_infinity_values( lora_logits.dtype) lora_logits[-1] = neg_inf lora_logits = lora_logits.mT indices_padded = self.punica_wrapper.sampler_indices_padded if current_platform.is_tpu(): indices_padded = indices_padded[:logits.size(0)] lora_logits = (lora_logits.reshape( lora_logits.shape[0] * lora_logits.shape[1], lora_logits.shape[2], ).index_select(0, indices_padded).nan_to_num_(nan=neg_inf, posinf=pos_inf, neginf=neg_inf)) logits[:, self.base_layer.org_vocab_size:self.base_layer.org_vocab_size + lora_logits.shape[1]] = lora_logits lora_output: Optional[ torch.Tensor] = self.punica_wrapper.add_lora_logits( logits, hidden_states, self.lora_a_stacked, self.lora_b_stacked, 1.0) if not current_platform.can_update_inplace(): logits = lora_output # Remove paddings in vocab (if any). logits = logits[:, :self.base_layer.vocab_size] return logits def forward(self, *args, **kwargs): return type(self.base_layer).forward(self, *args, **kwargs) @classmethod def can_replace_layer( cls, source_layer: nn.Module, lora_config: LoRAConfig, packed_modules_list: list, model_config: Optional[PretrainedConfig], ) -> bool: # Special handling for the LogitsProcessor. return False