# 🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨 # This file was automatically generated from src/transformers/models/zamba2/modular_zamba2.py. # Do NOT edit this file manually as any edits will be overwritten by the generation of # the file from the modular. If any change should be done, please apply the change to the # modular_zamba2.py file directly. One of our CI enforces this. # 🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨🚨 # Copyright 2024 Zyphra Technologies and the HuggingFace Inc. team. All rights reserved. # # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import math from collections.abc import Callable from itertools import cycle from typing import Optional import torch from torch import nn from ... import initialization as init from ...activations import ACT2FN from ...cache_utils import Cache, DynamicCache from ...generation import GenerationMixin from ...integrations import use_kernel_func_from_hub from ...integrations.hub_kernels import lazy_load_kernel from ...masking_utils import create_causal_mask from ...modeling_layers import GradientCheckpointingLayer from ...modeling_outputs import BaseModelOutputWithPast, CausalLMOutputWithPast, SequenceClassifierOutputWithPast from ...modeling_rope_utils import ROPE_INIT_FUNCTIONS, dynamic_rope_update from ...modeling_utils import ALL_ATTENTION_FUNCTIONS, PreTrainedModel from ...processing_utils import Unpack from ...utils import TransformersKwargs, auto_docstring, can_return_tuple, is_torchdynamo_compiling, logging from ...utils.generic import maybe_autocast, merge_with_config_defaults from ...utils.import_utils import resolve_internal_import from ...utils.output_capturing import capture_outputs from .configuration_zamba2 import Zamba2Config logger = logging.get_logger(__name__) class Zamba2RMSNormGated(torch.nn.Module): def __init__(self, hidden_size, group_size, eps=1e-6): super().__init__() self.weight = nn.Parameter(torch.ones(hidden_size)) self.variance_epsilon = eps self.group_size = group_size def forward(self, hidden_states, gate=None): input_dtype = hidden_states.dtype hidden_states = hidden_states.to(torch.float32) if gate is not None: hidden_states = hidden_states * nn.functional.silu(gate.to(torch.float32)) *prefix_dims, last_dim = hidden_states.shape group_count = last_dim // self.group_size hidden_states_group = hidden_states.view(*prefix_dims, group_count, self.group_size) variance = hidden_states_group.pow(2).mean(-1, keepdim=True) hidden_states_group = hidden_states_group * torch.rsqrt(variance + self.variance_epsilon) hidden_states = hidden_states_group.view(*prefix_dims, group_count * self.group_size) return self.weight * hidden_states.to(input_dtype) class Zamba2RMSNorm(nn.Module): def __init__(self, hidden_size, eps: float = 1e-6) -> None: """ Zamba2RMSNorm is equivalent to T5LayerNorm """ super().__init__() self.weight = nn.Parameter(torch.ones(hidden_size)) self.variance_epsilon = eps def forward(self, hidden_states: torch.Tensor) -> torch.Tensor: input_dtype = hidden_states.dtype hidden_states = hidden_states.to(torch.float32) variance = hidden_states.pow(2).mean(-1, keepdim=True) hidden_states = hidden_states * torch.rsqrt(variance + self.variance_epsilon) return self.weight * hidden_states.to(input_dtype) def extra_repr(self): return f"{tuple(self.weight.shape)}, eps={self.variance_epsilon}" class Zamba2RotaryEmbedding(nn.Module): inv_freq: torch.Tensor # fix linting for `register_buffer` def __init__(self, config: Zamba2Config, device=None): super().__init__() self.max_seq_len_cached = config.max_position_embeddings self.original_max_seq_len = config.max_position_embeddings self.config = config self.rope_type = self.config.rope_parameters["rope_type"] rope_init_fn: Callable = self.compute_default_rope_parameters if self.rope_type != "default": rope_init_fn = ROPE_INIT_FUNCTIONS[self.rope_type] inv_freq, self.attention_scaling = rope_init_fn(self.config, device) self.register_buffer("inv_freq", inv_freq, persistent=False) self.register_buffer("original_inv_freq", inv_freq.clone(), persistent=False) @staticmethod def compute_default_rope_parameters( config: Zamba2Config | None = None, device: Optional["torch.device"] = None, seq_len: int | None = None, ) -> tuple["torch.Tensor", float]: """ Computes the inverse frequencies according to the original RoPE implementation Args: config ([`~transformers.PreTrainedConfig`]): The model configuration. device (`torch.device`): The device to use for initialization of the inverse frequencies. seq_len (`int`, *optional*): The current sequence length. Unused for this type of RoPE. Returns: Tuple of (`torch.Tensor`, `float`), containing the inverse frequencies for the RoPE embeddings and the post-processing scaling factor applied to the computed cos/sin (unused in this type of RoPE). """ base = config.rope_parameters["rope_theta"] dim = getattr(config, "head_dim", None) or config.hidden_size // config.num_attention_heads attention_factor = 1.0 # Unused in this type of RoPE # Compute the inverse frequencies inv_freq = 1.0 / ( base ** (torch.arange(0, dim, 2, dtype=torch.int64).to(device=device, dtype=torch.float) / dim) ) return inv_freq, attention_factor @torch.no_grad() @dynamic_rope_update # power user: used with advanced RoPE types (e.g. dynamic rope) def forward(self, x, position_ids): inv_freq_expanded = self.inv_freq[None, :, None].float().expand(position_ids.shape[0], -1, 1).to(x.device) position_ids_expanded = position_ids[:, None, :].float() device_type = x.device.type if isinstance(x.device.type, str) and x.device.type != "mps" else "cpu" with maybe_autocast(device_type=device_type, enabled=False): # Force float32 freqs = (inv_freq_expanded.float() @ position_ids_expanded.float()).transpose(1, 2) emb = torch.cat((freqs, freqs), dim=-1) cos = emb.cos() * self.attention_scaling sin = emb.sin() * self.attention_scaling return cos.to(dtype=x.dtype), sin.to(dtype=x.dtype) def repeat_kv(hidden_states: torch.Tensor, n_rep: int) -> torch.Tensor: """ This is the equivalent of torch.repeat_interleave(x, dim=1, repeats=n_rep). The hidden states go from (batch, num_key_value_heads, seqlen, head_dim) to (batch, num_attention_heads, seqlen, head_dim) """ batch, num_key_value_heads, slen, head_dim = hidden_states.shape if n_rep == 1: return hidden_states hidden_states = hidden_states[:, :, None, :, :].expand(batch, num_key_value_heads, n_rep, slen, head_dim) return hidden_states.reshape(batch, num_key_value_heads * n_rep, slen, head_dim) def eager_attention_forward( module: nn.Module, query: torch.Tensor, key: torch.Tensor, value: torch.Tensor, attention_mask: torch.Tensor | None, scaling: float, dropout: float = 0.0, **kwargs, ): key_states = repeat_kv(key, module.num_key_value_groups) value_states = repeat_kv(value, module.num_key_value_groups) attn_weights = torch.matmul(query, key_states.transpose(2, 3)) * scaling if attention_mask is not None: attn_weights = attn_weights + attention_mask attn_weights = nn.functional.softmax(attn_weights, dim=-1, dtype=torch.float32).to(query.dtype) attn_weights = nn.functional.dropout(attn_weights, p=dropout, training=module.training) attn_output = torch.matmul(attn_weights, value_states) attn_output = attn_output.transpose(1, 2).contiguous() return attn_output, attn_weights def rotate_half(x): """Rotates half the hidden dims of the input.""" x1 = x[..., : x.shape[-1] // 2] x2 = x[..., x.shape[-1] // 2 :] return torch.cat((-x2, x1), dim=-1) @use_kernel_func_from_hub("rotary_pos_emb") def apply_rotary_pos_emb(q, k, cos, sin, unsqueeze_dim=1): """Applies Rotary Position Embedding to the query and key tensors. Args: q (`torch.Tensor`): The query tensor. k (`torch.Tensor`): The key tensor. cos (`torch.Tensor`): The cosine part of the rotary embedding. sin (`torch.Tensor`): The sine part of the rotary embedding. unsqueeze_dim (`int`, *optional*, defaults to 1): The 'unsqueeze_dim' argument specifies the dimension along which to unsqueeze cos[position_ids] and sin[position_ids] so that they can be properly broadcasted to the dimensions of q and k. For example, note that cos[position_ids] and sin[position_ids] have the shape [batch_size, seq_len, head_dim]. Then, if q and k have the shape [batch_size, heads, seq_len, head_dim], then setting unsqueeze_dim=1 makes cos[position_ids] and sin[position_ids] broadcastable to the shapes of q and k. Similarly, if q and k have the shape [batch_size, seq_len, heads, head_dim], then set unsqueeze_dim=2. Returns: `tuple(torch.Tensor)` comprising of the query and key tensors rotated using the Rotary Position Embedding. """ cos = cos.unsqueeze(unsqueeze_dim) sin = sin.unsqueeze(unsqueeze_dim) q_embed = (q * cos) + (rotate_half(q) * sin) k_embed = (k * cos) + (rotate_half(k) * sin) return q_embed, k_embed class Zamba2Attention(nn.Module): """ Multi-headed attention from 'Attention Is All You Need' paper. Adapted from transformers.models.mistral.modeling_mistral.MistralAttention: The input dimension here is attention_hidden_size = 2 * hidden_size, and head_dim = attention_hidden_size // num_heads. The extra factor of 2 comes from the input being the concatenation of original_hidden_states with the output of the previous (mamba) layer (see fig. 2 in https://huggingface.co/papers/2405.16712). Additionally, replaced attn_weights = torch.matmul(query_states, key_states.transpose(2, 3)) / math.sqrt(self.head_dim) with attn_weights = torch.matmul(query_states, key_states.transpose(2, 3)) / math.sqrt(self.head_dim/2) Finally, this attention layer contributes to tied transformer blocks aimed to increasing compute without increasing model size. Because this layer is tied, un-tied adapters (formally the same as LoRA but used in the base model) modules are added to the q, k, v projectors to increase expressivity with a small memory overhead (see Fig. 2 of https://huggingface.co/papers/2411.15242). """ def __init__( self, config: Zamba2Config, layer_idx: int | None = None, num_fwd_mem_blocks: int | None = None, block_id: int | None = None, ): super().__init__() self.config = config self.layer_idx = layer_idx self.attention_hidden_size = config.attention_hidden_size self.head_dim = config.attention_head_dim self.num_key_value_groups = config.num_attention_heads // config.num_key_value_heads self.max_position_embeddings = config.max_position_embeddings self.scaling = (self.head_dim / 2) ** -0.5 self.is_causal = True self.attention_dropout = config.attention_dropout self.q_proj = nn.Linear(config.attention_hidden_size, config.num_attention_heads * self.head_dim, bias=False) self.k_proj = nn.Linear(config.attention_hidden_size, config.num_key_value_heads * self.head_dim, bias=False) self.v_proj = nn.Linear(config.attention_hidden_size, config.num_key_value_heads * self.head_dim, bias=False) self.o_proj = nn.Linear(config.num_attention_heads * self.head_dim, config.hidden_size, bias=False) self.num_fwd_mem_blocks = num_fwd_mem_blocks self.layer_block_map = config.hybrid_layer_ids self.block_id = block_id if config.use_shared_attention_adapter: self.linear_q_adapter_list = nn.ModuleList([]) self.linear_k_adapter_list = nn.ModuleList([]) self.linear_v_adapter_list = nn.ModuleList([]) for i in range(self.num_fwd_mem_blocks): if i % config.num_mem_blocks == block_id: linear_q_adapter = nn.Sequential( nn.Linear(self.attention_hidden_size, self.config.adapter_rank, bias=False), nn.Linear(self.config.adapter_rank, self.attention_hidden_size, bias=False), ) linear_k_adapter = nn.Sequential( nn.Linear(self.attention_hidden_size, self.config.adapter_rank, bias=False), nn.Linear(self.config.adapter_rank, self.attention_hidden_size, bias=False), ) linear_v_adapter = nn.Sequential( nn.Linear(self.attention_hidden_size, self.config.adapter_rank, bias=False), nn.Linear(self.config.adapter_rank, self.attention_hidden_size, bias=False), ) else: linear_q_adapter = nn.Identity() linear_k_adapter = nn.Identity() linear_v_adapter = nn.Identity() self.linear_q_adapter_list.append(linear_q_adapter) self.linear_k_adapter_list.append(linear_k_adapter) self.linear_v_adapter_list.append(linear_v_adapter) self.layer_dic = {value: index for index, value in enumerate(self.layer_block_map)} def forward( self, hidden_states: torch.Tensor, layer_idx: int, attention_mask: torch.Tensor | None = None, past_key_values: Cache | None = None, position_embeddings: tuple[torch.Tensor, torch.Tensor] | None = None, **kwargs: Unpack[TransformersKwargs], ) -> tuple[torch.Tensor, torch.Tensor | None, tuple[torch.Tensor] | None]: input_shape = hidden_states.shape[:-1] hidden_shape = (*input_shape, -1, self.head_dim) query_states = self.q_proj(hidden_states) key_states = self.k_proj(hidden_states) value_states = self.v_proj(hidden_states) if self.config.use_shared_attention_adapter: adapter_layer_idx = self.layer_dic[layer_idx] query_states = query_states + self.linear_q_adapter_list[adapter_layer_idx](hidden_states) key_states = key_states + self.linear_k_adapter_list[adapter_layer_idx](hidden_states) value_states = value_states + self.linear_v_adapter_list[adapter_layer_idx](hidden_states) query_states = query_states.view(hidden_shape).transpose(1, 2) key_states = key_states.view(hidden_shape).transpose(1, 2) value_states = value_states.view(hidden_shape).transpose(1, 2) if self.config.use_mem_rope: cos, sin = position_embeddings query_states, key_states = apply_rotary_pos_emb(query_states, key_states, cos, sin) if past_key_values is not None: key_states, value_states = past_key_values.update(key_states, value_states, layer_idx) attention_interface: Callable = ALL_ATTENTION_FUNCTIONS.get_interface( self.config._attn_implementation, eager_attention_forward ) attn_output, attn_weights = attention_interface( self, query_states, key_states, value_states, attention_mask, dropout=0.0 if not self.training else self.attention_dropout, scaling=self.scaling, **kwargs, ) attn_output = attn_output.reshape(*input_shape, -1).contiguous() attn_output = self.o_proj(attn_output) return attn_output, attn_weights # Helper methods for segment sum computation def pad_tensor_by_size(input_tensor: torch.Tensor, pad_size: int): """ Padding x tensor with `pad_size` on the seq_len dim (dim=1) Assumes that we only have tensors of either size 4 or 3 """ pad_shape = (0, 0, 0, 0, 0, pad_size, 0, 0) if len(input_tensor.shape) == 4 else (0, 0, 0, pad_size, 0, 0) return torch.nn.functional.pad(input_tensor, pad_shape, mode="constant", value=0) def reshape_into_chunks(input_tensor, pad_size, chunk_size): """ Padding input_tensor with `pad_size` on the seq_len dim (dim=1) and simultaneously splitting it into chunk sequences. Assumes that we only have tensors of either size 4 or 3 """ # [bsz, seq_len, ...] -> [bsz, seq_len multiple of chunk_size, ...] input_tensor = pad_tensor_by_size(input_tensor, pad_size) if len(input_tensor.shape) == 3: # [bsz, seq_len multiple of chunk_size, num_heads] -> [bsz, -1, chunk_size, num_heads] return input_tensor.reshape(input_tensor.shape[0], -1, chunk_size, input_tensor.shape[2]) else: # [bsz, seq_len multiple of chunk_size, num_heads, head_dim or state_size] -> [bsz, -1, chunk_size, num_heads, head_dim or state_size] return input_tensor.reshape( input_tensor.shape[0], -1, chunk_size, input_tensor.shape[2], input_tensor.shape[3] ) def segment_sum(input_tensor): """ More stable segment sum calculation. Uses cumulative sums and masking instead of direct subtractions. """ chunk_size = input_tensor.size(-1) # 1. expand input tensor to have an additional dimension and repeat along that dimension # [..., chunk_size] -> [..., chunk_size, chunk_size] input_tensor = input_tensor[..., None].expand(*input_tensor.size(), chunk_size) # 2. create a lower triangular mask with the diagonal set to 0 to 0 out elements above diag mask = torch.tril(torch.ones(chunk_size, chunk_size, device=input_tensor.device, dtype=torch.bool), diagonal=-1) input_tensor = input_tensor.masked_fill(~mask, 0) # 3. compute actual cumsum tensor_segsum = torch.cumsum(input_tensor, dim=-2) # 4. apply mask to keep only the lower triangular part of the cumulative sum result (incl diagonal this time) mask = torch.tril(torch.ones(chunk_size, chunk_size, device=input_tensor.device, dtype=torch.bool), diagonal=0) tensor_segsum = tensor_segsum.masked_fill(~mask, -torch.inf) return tensor_segsum class Zamba2MambaMixer(nn.Module): """ Compute ∆, A, B, C, and D the state space parameters and compute the `contextualized_states`. A, D are input independent (see Mamba paper [1] Section 3.5.2 "Interpretation of A" for why A isn't selective) ∆, B, C are input-dependent (this is a key difference between Mamba and the linear time invariant S4, and is why Mamba is called **selective** state spaces) """ def __init__(self, config: Zamba2Config, layer_idx: int | None = None): super().__init__() self.config = config self.hidden_size = config.hidden_size self.ssm_state_size = config.mamba_d_state self.conv_kernel_size = config.mamba_d_conv self.intermediate_size = int(config.mamba_expand * self.hidden_size) self.layer_idx = layer_idx self.use_conv_bias = config.use_conv_bias self.activation = "silu" self.act = nn.SiLU() self.use_mem_eff_path = config.use_mem_eff_path self.n_groups = config.mamba_ngroups self.head_dim = config.mamba_headdim self.num_heads = self.config.n_mamba_heads self.chunk_size = config.chunk_size self.time_step_limit = config.time_step_limit self.time_step_min = config.time_step_min self.time_step_max = config.time_step_max self.conv_dim = self.intermediate_size + 2 * self.n_groups * self.ssm_state_size self.conv1d = nn.Conv1d( in_channels=self.conv_dim, out_channels=self.conv_dim, bias=True, kernel_size=config.mamba_d_conv, groups=self.conv_dim, padding=config.mamba_d_conv - 1, ) # projection of the input hidden states projection_size = self.intermediate_size + self.conv_dim + self.num_heads self.in_proj = nn.Linear( self.hidden_size, projection_size, bias=config.add_bias_linear, ) # selective projection used to make dt, B and C input dependent # time step projection (discretization) # instantiate once and copy inv_dt in init_weights of PretrainedModel self.dt_bias = nn.Parameter(torch.ones(self.num_heads)) # S4D real initialization. These are not discretized! # The core is to load them, compute the discrete states, then write the updated state. Keeps the memory bounded A = torch.arange(1, self.num_heads + 1) self.A_log = nn.Parameter(torch.log(A)) self.norm = Zamba2RMSNormGated( self.intermediate_size, group_size=self.intermediate_size // self.n_groups, eps=1e-5 ) self.D = nn.Parameter(torch.ones(self.num_heads)) self.out_proj = nn.Linear(self.intermediate_size, self.hidden_size, bias=config.add_bias_linear) global causal_conv1d_update, causal_conv1d_fn causal_conv1d = lazy_load_kernel("causal-conv1d") causal_conv1d_update = getattr(causal_conv1d, "causal_conv1d_update", None) causal_conv1d_fn = getattr(causal_conv1d, "causal_conv1d_fn", None) global selective_state_update, mamba_chunk_scan_combined, mamba_split_conv1d_scan_combined mamba_ssm = lazy_load_kernel("mamba-ssm") selective_state_update = resolve_internal_import( mamba_ssm, chained_path="ops.triton.selective_state_update.selective_state_update" ) mamba_chunk_scan_combined = resolve_internal_import( mamba_ssm, chained_path="ops.triton.ssd_combined.mamba_chunk_scan_combined" ) mamba_split_conv1d_scan_combined = resolve_internal_import( mamba_ssm, chained_path="ops.triton.ssd_combined.mamba_split_conv1d_scan_combined" ) global is_fast_path_available is_fast_path_available = all( ( selective_state_update, mamba_chunk_scan_combined, mamba_split_conv1d_scan_combined, causal_conv1d_fn, causal_conv1d_update, ) ) if not is_fast_path_available: logger.warning_once( "The fast path is not available because one of `(selective_state_update, causal_conv1d_fn, causal_conv1d_update)`" " is None. Falling back to the naive implementation. To install follow https://github.com/state-spaces/mamba/#installation and" " https://github.com/Dao-AILab/causal-conv1d" ) def cuda_kernels_forward( self, hidden_states: torch.Tensor, cache_params: Cache | None = None, attention_mask: torch.Tensor | None = None, ): # set up dimensions for reshapes later batch_size, seq_len, _ = hidden_states.shape groups_time_state_size = self.n_groups * self.ssm_state_size d_to_remove = 2 * self.intermediate_size + 2 * self.n_groups * self.ssm_state_size + self.num_heads # getting projected states from cache if it exists if cache_params is not None and cache_params.has_previous_state(self.layer_idx): in_projected_states = self.in_proj(hidden_states.squeeze(1)) # (B 2D) d_mlp = (in_projected_states.shape[-1] - d_to_remove) // 2 split_projection_dim = [d_mlp, d_mlp, self.intermediate_size, self.conv_dim, self.num_heads] _, _, gate, hidden_states_B_C, dt = torch.split(in_projected_states, split_projection_dim, dim=-1) hidden_states_B_C = causal_conv1d_update( hidden_states_B_C, cache_params.layers[self.layer_idx].conv_states, self.conv1d.weight.squeeze(1), self.conv1d.bias, self.activation, ) hidden_states, B, C = torch.split( hidden_states_B_C, [self.intermediate_size, groups_time_state_size, groups_time_state_size], dim=-1, ) A = -torch.exp(self.A_log.float()) # (nheads,) A = A[:, None, ...][:, :, None].expand(-1, self.head_dim, self.ssm_state_size).to(dtype=torch.float32) dt = dt[:, :, None].expand(-1, -1, self.head_dim) dt_bias = self.dt_bias[:, None, ...].expand(-1, self.head_dim) D = self.D[:, None, ...].expand(-1, self.head_dim) B = B.view(batch_size, self.n_groups, B.shape[1] // self.n_groups) C = C.view(batch_size, self.n_groups, C.shape[1] // self.n_groups) hidden_states_reshaped = hidden_states.view(batch_size, self.num_heads, self.head_dim) hidden_states = selective_state_update( cache_params.layers[self.layer_idx].recurrent_states, hidden_states_reshaped, dt, A, B, C, D, z=None, dt_bias=dt_bias, dt_softplus=True, ) hidden_states = hidden_states.view(batch_size, self.num_heads * self.head_dim) hidden_states = self.norm(hidden_states, gate) out = self.out_proj(hidden_states)[:, None, ...] # if no cache is found, calling the kernel else: if attention_mask is not None and not torch.all(attention_mask == 1): # tune out hidden states for pad tokens, see https://github.com/state-spaces/mamba/issues/66 dtype = hidden_states.dtype hidden_states = (hidden_states * attention_mask[:, :, None]).to(dtype) # 1. Gated MLP's linear projection projected_states = self.in_proj(hidden_states) A = -torch.exp(self.A_log.float()) # (num_heads) or (intermediate_size, state_size) dt_limit_kwargs = {} if self.time_step_limit is None else {"dt_limit": self.time_step_limit} if attention_mask is not None: input_not_masked = torch.all(attention_mask == 1) else: input_not_masked = True if self.use_mem_eff_path and self.training and cache_params is None and input_not_masked: out, ssm_state = mamba_split_conv1d_scan_combined( projected_states, self.conv1d.weight.squeeze(1), self.conv1d.bias, self.dt_bias, A, D=self.D, chunk_size=self.chunk_size, seq_idx=None, activation=self.activation, rmsnorm_weight=self.norm.weight, rmsnorm_eps=self.norm.variance_epsilon, outproj_weight=self.out_proj.weight, outproj_bias=self.out_proj.bias, headdim=self.head_dim, ngroups=self.n_groups, norm_before_gate=False, return_final_states=True, **dt_limit_kwargs, ) else: gate, hidden_states_B_C, time_step = torch.split( projected_states, [self.intermediate_size, self.conv_dim, self.num_heads], dim=-1, ) # 1D Convolution if cache_params is not None: hidden_states_B_C_t = hidden_states_B_C.transpose(1, 2) conv_state = nn.functional.pad( hidden_states_B_C_t, (self.conv_kernel_size - hidden_states_B_C_t.shape[-1], 0) ) conv_state = cache_params.update_conv_state(conv_state, self.layer_idx) if causal_conv1d_fn is None or self.activation not in ["silu", "swish"]: hidden_states_B_C = self.act( self.conv1d(hidden_states_B_C.transpose(1, 2)).transpose(1, 2)[:, :seq_len] ) # (B, L, self.d_inner + 2 * ngroups * d_state) else: hidden_states_B_C = causal_conv1d_fn( x=hidden_states_B_C.transpose(1, 2), weight=self.conv1d.weight.squeeze(1), bias=self.conv1d.bias, activation=self.activation, ).transpose(1, 2)[:, :seq_len] hidden_states, B, C = torch.split( hidden_states_B_C, [self.intermediate_size, groups_time_state_size, groups_time_state_size], dim=-1, ) if attention_mask is not None and not torch.all(attention_mask == 1): # tune out hidden states for pad tokens, see https://github.com/state-spaces/mamba/issues/66 dtype = hidden_states.dtype hidden_states = (hidden_states * attention_mask[:, :, None]).to(dtype) scan_output, ssm_state = mamba_chunk_scan_combined( hidden_states.view(batch_size, seq_len, -1, self.head_dim), time_step, A, B.view(batch_size, seq_len, self.n_groups, -1), C.view(batch_size, seq_len, self.n_groups, -1), chunk_size=self.chunk_size, D=self.D, z=None, seq_idx=None, return_final_states=True, dt_bias=self.dt_bias, dt_softplus=True, **dt_limit_kwargs, ) if ssm_state is not None and cache_params is not None: cache_params.update_recurrent_state(ssm_state, self.layer_idx) scan_output = scan_output.view(batch_size, seq_len, -1) # Multiply "gate" branch and apply extra normalization layer scan_output = self.norm(scan_output, gate) out = self.out_proj(scan_output) return out # fmt: off def torch_forward(self, input_states, cache_params: Cache | None=None, attention_mask: torch.Tensor | None = None): batch_size, seq_len, _ = input_states.shape dtype = input_states.dtype # Gated MLP's linear projection if cache_params is not None and cache_params.has_previous_state(self.layer_idx): projected_states = self.in_proj(input_states) else: if attention_mask is not None: # tune out hidden states for pad tokens, see https://github.com/state-spaces/mamba/issues/66 input_states = (input_states * attention_mask[:, :, None]).to(dtype) projected_states = self.in_proj(input_states) d_mlp = (projected_states.shape[-1] - 2 * self.intermediate_size - 2 * self.n_groups * self.ssm_state_size- self.num_heads) // 2 _, _, gate, hidden_states, dt = projected_states.split( [d_mlp, d_mlp, self.intermediate_size, self.conv_dim, self.num_heads], dim=-1 ) hidden_states = hidden_states.transpose(1, 2) use_precomputed_state = cache_params is not None and cache_params.has_previous_state(self.layer_idx) # Convolution sequence transformation if use_precomputed_state: conv_state = cache_params.update_conv_state(hidden_states, self.layer_idx) hidden_states = torch.sum(conv_state * self.conv1d.weight[:, 0, :], dim=-1) if self.use_conv_bias: hidden_states += self.conv1d.bias hidden_states = self.act(hidden_states).to(dtype)[:, None, ...] # [batch, 1, intermediate_size] : decoding else: if cache_params is not None: conv_state = nn.functional.pad( hidden_states, (self.conv_kernel_size - hidden_states.shape[-1], 0) ) conv_state = cache_params.update_conv_state(conv_state, self.layer_idx) hidden_states = self.act(self.conv1d(hidden_states)[..., :seq_len].transpose(1, 2)) if attention_mask is not None: dtype = hidden_states.dtype # tune out hidden states for pad tokens, see https://github.com/state-spaces/mamba/issues/66 hidden_states = (hidden_states * attention_mask[:, :, None]).to(dtype) hidden_states, B, C = torch.split(hidden_states, [self.intermediate_size, self.n_groups * self.ssm_state_size, self.n_groups * self.ssm_state_size], dim=-1) A = -torch.exp(self.A_log.float()) # [num_heads] if use_precomputed_state: # Note: there is no need to pad parameter matrices here, as there is just one new token # for batched generation dt = dt[:, None, ...] if dt.ndim == 2 else dt[:, 0, :][:, None, ...] dt = dt.transpose(1, 2).expand(batch_size, dt.shape[-1], self.head_dim) # [num_heads] -> [num_heads, head_dim] dt_bias = self.dt_bias[..., None].expand(self.dt_bias.shape[0], self.head_dim) dt = torch.nn.functional.softplus(dt + dt_bias.to(dt.dtype)) dt = torch.clamp(dt, self.time_step_min) #, self.time_step_max) A = A[..., None, None].expand(self.num_heads, self.head_dim, self.ssm_state_size).to(dtype=torch.float32) # [bsz, num_heads, head_dim, state_size] dA = torch.exp(dt[..., None] * A) # Discretize B # [bsz, n_groups * state_size] -> [bsz, n_groups, 1, state_size] -> # -> [bsz, n_groups, group to head repetition factor, state_size] -> [bsz, num_heads, state_size] B = B.reshape(batch_size, self.n_groups, -1)[..., None, :] B = B.expand(batch_size, self.n_groups, self.num_heads // self.n_groups, B.shape[-1]).contiguous() B = B.reshape(batch_size, -1, B.shape[-1]) # [bsz, num_heads, head_dim, state_size] dB = dt[..., None] * B[..., None, :] # Discretize x into dB # [bsz, intermediate_size] -> [bsz, num_heads, head_dim] hidden_states = hidden_states.reshape(batch_size, -1, self.head_dim) dBx = dB * hidden_states[..., None] # State calculation ssm_states = cache_params.layers[self.layer_idx].recurrent_states.clone() ssm_states = ssm_states * dA + dBx ssm_states = cache_params.update_recurrent_state(ssm_states, self.layer_idx) # Subsequent output # [bsz, n_groups * state_size] -> [bsz, num_heads, state_size] C = C.reshape(batch_size, self.n_groups, -1)[..., None, :] C = C.expand(batch_size, self.n_groups, self.num_heads // self.n_groups, C.shape[-1]).contiguous() C = C.reshape(batch_size, -1, C.shape[-1]) # [bsz, num_heads, head_dim] ssm_states = ssm_states.to(C.dtype) # Shape: [b, h, d, n] # Reshape ssm_states to merge the first two dimensions ssm_states_reshaped = ssm_states.view(batch_size * self.num_heads, self.head_dim, self.ssm_state_size) # Shape: [b*h, d, n] C_reshaped = C.view(batch_size * self.num_heads, self.ssm_state_size, 1) # Shape: [b*h, n, 1] y = torch.bmm(ssm_states_reshaped, C_reshaped) y = y.view(batch_size, self.num_heads, self.head_dim) # D skip connection # [num_heads] -> [num_heads, head_dim] D = self.D[..., None].expand(self.D.shape[0], self.head_dim) y = (y + hidden_states * D).to(y.dtype) # [bsz, num_heads, head_dim] -> [bsz, 1, intermediate_size] y = y.reshape(batch_size, -1)[:, None, ...] else: # begin ssd naive implementation without einsums dt = nn.functional.softplus(dt + self.dt_bias) dt = torch.clamp(dt, self.time_step_min) hidden_states = hidden_states.reshape(batch_size, seq_len, -1, self.head_dim).float() B = B.reshape(batch_size, seq_len, -1, self.ssm_state_size).float() C = C.reshape(batch_size, seq_len, -1, self.ssm_state_size).float() B = B.repeat_interleave(self.num_heads // self.n_groups, dim=2, output_size=self.num_heads) C = C.repeat_interleave(self.num_heads // self.n_groups, dim=2, output_size=self.num_heads) pad_size = (self.chunk_size - seq_len % self.chunk_size) % self.chunk_size D_residual = self.D[..., None] * pad_tensor_by_size(hidden_states, pad_size) # Discretize x and A hidden_states = hidden_states * dt[..., None] A = A.to(hidden_states.dtype) * dt # Rearrange into blocks/chunks hidden_states, A, B, C = [reshape_into_chunks(t, pad_size, self.chunk_size) for t in (hidden_states, A, B, C)] # [bsz, -1, chunk_size, num_heads] -> [bsz, num_heads, -1, chunk_size] A = A.permute(0, 3, 1, 2) A_cumsum = torch.cumsum(A, dim=-1) # 1. Compute the output for each intra-chunk (diagonal blocks) # This is the analog of a causal mask L = torch.exp(segment_sum(A)) # First, contraction of C and B to get G (attention-weights like) G_intermediate = C[:, :, :, None, :, :] * B[:, :, None, :, : ,:] # shape: (b, c, l, s, h, n) G = G_intermediate.sum(dim=-1) # shape: (b, c, l, s, h) # Step 2: Compute M, equivalent to applying attention mask to weights M_intermediate = G[..., None] * L.permute(0, 2, 3, 4, 1)[..., None] M = M_intermediate.sum(dim=-1) # Step 3: Compute Y_diag (apply to values) Y_diag = (M[..., None] * hidden_states[:, :, None]).sum(3) # (right term of low-rank factorization of off-diagonal blocks; B terms) decay_states = torch.exp(A_cumsum[:, :, :, -1:] - A_cumsum) B_decay_contraction = B * decay_states.permute(0, 2, 3, 1)[..., None] # permute back B * decay states states = (B_decay_contraction.permute(0, 1, 3, 2, 4)[..., None] * hidden_states.permute(0, 1, 3, 2, 4)[..., None, :]).sum(dim=3).permute(0, 1, 2, 4, 3) previous_states = torch.zeros_like(states[:, :1]) states = torch.cat([previous_states, states], dim=1) decay_chunk = torch.exp(segment_sum(nn.functional.pad(A_cumsum[:, :, :, -1], (1, 0)))) states_permuted = states.permute(0, 2, 1, 3, 4) result = (decay_chunk[..., None, None] * states_permuted[:, :, None, ...]).sum(dim=2) new_states = result.permute(0, 2, 1, 3, 4) states, ssm_state = new_states[:, :-1], new_states[:, -1] # Compute state -> output conversion per chunk # (left term of low-rank factorization of off-diagonal blocks; C terms) state_decay_out = torch.exp(A_cumsum) # compute Yoff C_times_states = (C[..., None, :] * states[:, :, None, ...]) state_decay_out_permuted = state_decay_out.permute(0, 2, 3, 1) Y_off = (C_times_states.sum(-1) * state_decay_out_permuted[..., None]) # Add output of intra-chunk and inter-chunk terms (diagonal and off-diagonal blocks) y = Y_diag + Y_off # [bsz, -1, self.chunk_size, num_heads, head_dim] -> [bsz, (padded) seq_len, num_heads, head_dim] y = y.reshape(batch_size, -1, self.num_heads, self.head_dim) y = y + D_residual # Cutting off padded chunks if pad_size > 0: y = y[:, :seq_len, :, :] y = y.reshape(batch_size, seq_len, -1) if ssm_state is not None and cache_params is not None: cache_params.update_recurrent_state(ssm_state, self.layer_idx) scan_output = self.norm(y, gate) # end ssd naive # 4. Final linear projection contextualized_states = self.out_proj(scan_output.to(dtype)) # [batch, seq_len, hidden_size] return contextualized_states # fmt: on def forward( self, hidden_states, cache_params: Cache | None = None, attention_mask: torch.Tensor | None = None, **kwargs, ): if is_fast_path_available and "cuda" in self.in_proj.weight.device.type and not is_torchdynamo_compiling(): return self.cuda_kernels_forward(hidden_states, cache_params, attention_mask) return self.torch_forward(hidden_states, cache_params, attention_mask) class Zamba2MLP(nn.Module): def __init__(self, config: Zamba2Config, num_fwd_mem_blocks=None, block_id: int | None = None): """ This MLP layer contributes to tied transformer blocks aimed to increasing compute without increasing model size. Because this layer is tied, un-tied adapter modules (formally same as LoRA, but used in the base model) are added to the up and gate projectors to increase expressivity with a small memory overhead. """ super().__init__() self.config = config self.hidden_size = config.hidden_size self.intermediate_size = config.intermediate_size self.num_fwd_mem_blocks = num_fwd_mem_blocks self.block_id = block_id self.gate_up_proj = nn.Linear(self.hidden_size, 2 * self.intermediate_size, bias=config.add_bias_linear) self.down_proj = nn.Linear(self.intermediate_size, self.hidden_size, bias=config.add_bias_linear) self.act_fn = ACT2FN[config.hidden_act] self.gate_up_proj_adapter_list = nn.ModuleList([]) for i in range(self.num_fwd_mem_blocks): if i % config.num_mem_blocks == block_id: gate_up_proj_adapter = nn.Sequential( nn.Linear(self.config.hidden_size, self.config.adapter_rank, bias=False), nn.Linear(self.config.adapter_rank, 2 * self.intermediate_size, bias=False), ) else: gate_up_proj_adapter = nn.Identity() self.gate_up_proj_adapter_list.append(gate_up_proj_adapter) layer_block_map = config.hybrid_layer_ids self.layer_dic = {value: index for index, value in enumerate(layer_block_map)} def forward(self, hidden_state, layer_idx=None): gate_up_state = self.gate_up_proj(hidden_state) layer_idx = self.layer_dic[layer_idx] gate_up_state = gate_up_state + self.gate_up_proj_adapter_list[layer_idx](hidden_state) gate_up_state = torch.chunk(gate_up_state, 2, dim=-1) hidden_state = self.act_fn(gate_up_state[0]) * gate_up_state[1] output = self.down_proj(hidden_state) return output class Zamba2AttentionDecoderLayer(nn.Module): def __init__(self, config: Zamba2Config, block_id: int | None = None, layer_idx: int | None = None): super().__init__() self.block_id = block_id num_gs = len(config.hybrid_layer_ids) self.self_attn = Zamba2Attention(config, layer_idx=-1, num_fwd_mem_blocks=num_gs, block_id=block_id) self.feed_forward = Zamba2MLP(config, num_fwd_mem_blocks=num_gs, block_id=block_id) self.input_layernorm = Zamba2RMSNorm(config.attention_hidden_size, eps=config.rms_norm_eps) self.pre_ff_layernorm = Zamba2RMSNorm(config.hidden_size, eps=config.rms_norm_eps) def forward( self, hidden_states: torch.Tensor, original_hidden_states: torch.Tensor, layer_idx: int, attention_mask: torch.Tensor | None = None, past_key_values: Cache | None = None, position_embeddings: torch.LongTensor | None = None, **kwargs: Unpack[TransformersKwargs], ) -> tuple[torch.FloatTensor]: """ Args: hidden_states (`torch.FloatTensor`): output of previous Mamba layer of shape `(batch, seq_len, embed_dim)` original_hidden_states (`torch.FloatTensor`): word embedding output of shape `(batch, seq_len, embed_dim)`. This is concatenated with `hidden_states` (which is the output of the previous (mamba) layer). The concatenated tensor is then used as input of the pre-attention RMSNorm (see fig. 2 in https://huggingface.co/papers/2405.16712). attention_mask (`torch.FloatTensor`, *optional*): attention mask of size `(batch, sequence_length)` where padding elements are indicated by 0. past_key_values (`Cache`, *optional*): cached past key and value projection states use_cache (`bool`, *optional*): If set to `True`, `past_key_values` key value states are returned and can be used to speed up decoding (see `past_key_values`). position_embeddings (`tuple[torch.FloatTensor, torch.FloatTensor]`, *optional*): Tuple containing the cosine and sine positional embeddings of shape `(batch_size, seq_len, head_dim)`, with `head_dim` being the embedding dimension of each attention head. """ hidden_states = torch.concatenate([hidden_states, original_hidden_states], dim=-1) hidden_states = self.input_layernorm(hidden_states) hidden_states, _ = self.self_attn( hidden_states=hidden_states, layer_idx=layer_idx, attention_mask=attention_mask, past_key_values=past_key_values, position_embeddings=position_embeddings, **kwargs, ) hidden_states = self.pre_ff_layernorm(hidden_states) hidden_states = self.feed_forward(hidden_states, layer_idx) return hidden_states class Zamba2MambaDecoderLayer(GradientCheckpointingLayer): def __init__(self, config: Zamba2Config, layer_idx: int): super().__init__() self.mamba = Zamba2MambaMixer(config=config, layer_idx=layer_idx) self.input_layernorm = Zamba2RMSNorm(config.hidden_size, eps=config.rms_norm_eps) self.layer_idx = layer_idx def forward( self, hidden_states: torch.Tensor, original_hidden_states: torch.Tensor | None = None, layer_idx: int | None = None, attention_mask: torch.Tensor | None = None, causal_mask: torch.Tensor | None = None, past_key_values: Cache | None = None, use_cache: bool | None = False, position_ids: torch.LongTensor | None = None, transformer_hidden_states: torch.Tensor | None = None, **kwargs: Unpack[TransformersKwargs], ) -> tuple[torch.FloatTensor, tuple[torch.FloatTensor, torch.FloatTensor] | None]: """ Args: hidden_states (`torch.FloatTensor`): input to the layer of shape `(batch, seq_len, embed_dim)` attention_mask (`torch.FloatTensor`, *optional*): attention mask of size `(batch, sequence_length)` where padding elements are indicated by 0. past_key_values (`Cache`, *optional*): cached past key and value projection states use_cache (`bool`, *optional*): If set to `True`, `past_key_values` key value states are returned and can be used to speed up decoding (see `past_key_values`). """ residual = hidden_states # `transformer_hidden_states` is the output from shared transformer + linear layer (see fig. 2 in https://huggingface.co/papers/2405.16712). # `transformer_hidden_states` is then added to the input to the mamba layer below (as described in eq. (6) of https://huggingface.co/papers/2405.16712). hidden_states = ( hidden_states + transformer_hidden_states if transformer_hidden_states is not None else hidden_states ) hidden_states = self.input_layernorm(hidden_states) hidden_states = self.mamba( hidden_states=hidden_states, cache_params=past_key_values, attention_mask=attention_mask, **kwargs, ) # residual connection after mamba hidden_states = residual + hidden_states return hidden_states class Zamba2HybridLayer(GradientCheckpointingLayer): def __init__( self, shared_transformer: Zamba2AttentionDecoderLayer, linear: nn.Linear, mamba: Zamba2MambaDecoderLayer ): super().__init__() self.linear = linear self.mamba_decoder = mamba self.shared_transformer = shared_transformer def forward( self, hidden_states: torch.Tensor, original_hidden_states: torch.Tensor | None = None, layer_idx: int | None = None, attention_mask: torch.Tensor | None = None, causal_mask: torch.Tensor | None = None, past_key_values: Cache | None = None, use_cache: bool | None = False, position_embeddings: torch.LongTensor | None = None, position_ids: torch.LongTensor | None = None, **kwargs: Unpack[TransformersKwargs], ) -> tuple[torch.FloatTensor, tuple[torch.FloatTensor, torch.FloatTensor] | None]: """ Args: hidden_states (`torch.FloatTensor`): input to the layer of shape `(batch, seq_len, embed_dim)` original_hidden_states (`torch.FloatTensor`): word embedding output that will be concatenated with hidden activations to form the input of the shared transformer layer. layer_idx (`int`): layer number. attention_mask (`torch.FloatTensor`, *optional*): attention mask of size `(batch, sequence_length)` where padding elements are indicated by 0. past_key_values (`Cache`, *optional*): cached past key and value projection states use_cache (`bool`, *optional*): If set to `True`, `past_key_values` key value states are returned and can be used to speed up decoding (see `past_key_values`). position_embeddings (`tuple[torch.FloatTensor, torch.FloatTensor]`, *optional*): Tuple containing the cosine and sine positional embeddings of shape `(batch_size, seq_len, head_dim)`, with `head_dim` being the embedding dimension of each attention head. """ transformer_hidden_states = self.shared_transformer( hidden_states, original_hidden_states=original_hidden_states, layer_idx=layer_idx, attention_mask=causal_mask, past_key_values=past_key_values, position_embeddings=position_embeddings, position_ids=position_ids, **kwargs, ) transformer_hidden_states = self.linear(transformer_hidden_states) hidden_states = self.mamba_decoder( hidden_states, transformer_hidden_states=transformer_hidden_states, attention_mask=attention_mask, past_key_values=past_key_values, use_cache=use_cache, position_embeddings=position_embeddings, **kwargs, ) return hidden_states @auto_docstring class Zamba2PreTrainedModel(PreTrainedModel): config: Zamba2Config base_model_prefix = "model" supports_gradient_checkpointing = True _no_split_modules = ["Zamba2HybridLayer", "Zamba2MambaDecoderLayer"] _skip_keys_device_placement = "past_key_values" _supports_flash_attn = True _supports_flex_attn = True _supports_sdpa = True _is_stateful = True _can_record_outputs = { "hidden_states": Zamba2MambaDecoderLayer, "attentions": Zamba2Attention, } @torch.no_grad() def _init_weights(self, module): super()._init_weights(module) if isinstance(module, Zamba2MambaMixer): dt = torch.exp( torch.rand(self.config.n_mamba_heads) * (math.log(self.config.time_step_max) - math.log(self.config.time_step_min)) + math.log(self.config.time_step_min) ).clamp(min=self.config.time_step_floor) # # Inverse of softplus: https://github.com/pytorch/pytorch/issues/72759 inv_dt = dt + torch.log(-torch.expm1(-dt)) init.copy_(module.dt_bias, inv_dt) A = torch.arange(1, module.num_heads + 1) init.copy_(module.A_log, torch.log(A)) init.ones_(module.D) @auto_docstring class Zamba2Model(Zamba2PreTrainedModel): """ Model consisting of *config.num_hidden_layers* layers. Args: config: Zamba2Config """ def __init__(self, config: Zamba2Config): super().__init__(config) self.config = config self.padding_idx = config.pad_token_id self.vocab_size = config.vocab_size self.embed_tokens = nn.Embedding(config.vocab_size, config.hidden_size, self.padding_idx) self.layers_block_type = config.layers_block_type self.layers = self.get_layers() self._attn_implementation = config._attn_implementation self.final_layernorm = Zamba2RMSNorm(config.hidden_size, eps=config.rms_norm_eps) if config.use_mem_rope: if config.use_long_context: logger.warning_once( "`use_long_context` set to `True`: using rescaled `rope_theta` and extended `max_position_embeddings`." ) self.rotary_emb = Zamba2RotaryEmbedding(config) self.gradient_checkpointing = False # Initialize weights and apply final processing self.post_init() @merge_with_config_defaults @capture_outputs @auto_docstring def forward( self, input_ids: torch.LongTensor | None = None, attention_mask: torch.Tensor | None = None, position_ids: torch.LongTensor | None = None, past_key_values: Cache | None = None, inputs_embeds: torch.FloatTensor | None = None, use_cache: bool | None = None, **kwargs: Unpack[TransformersKwargs], ) -> tuple | BaseModelOutputWithPast: if (input_ids is None) ^ (inputs_embeds is not None): raise ValueError( "You cannot specify both input_ids and inputs_embeds at the same time, and must specify either one" ) if inputs_embeds is None: inputs_embeds = self.embed_tokens(input_ids) hidden_states = inputs_embeds original_hidden_states = torch.clone(inputs_embeds) # original_hidden_states: word embedding output that will be concatenated with hidden activations to form the input of the shared transformer layer if use_cache and past_key_values is None: past_key_values = DynamicCache(config=self.config) if position_ids is None: past_seen_tokens = past_key_values.get_seq_length() if past_key_values is not None else 0 position_ids = torch.arange(inputs_embeds.shape[1], device=inputs_embeds.device) + past_seen_tokens position_ids = position_ids.unsqueeze(0) causal_mask = create_causal_mask( config=self.config, inputs_embeds=inputs_embeds, attention_mask=attention_mask, past_key_values=past_key_values, position_ids=position_ids, ) # create position embeddings to be shared across the decoder layers if self.config.use_mem_rope: position_embeddings = self.rotary_emb(hidden_states, position_ids=position_ids) else: position_embeddings = None for layer_idx, layer in enumerate(self.layers): hidden_states = layer( hidden_states, original_hidden_states, layer_idx, attention_mask, causal_mask, past_key_values=past_key_values, use_cache=use_cache, position_embeddings=position_embeddings, position_ids=position_ids, **kwargs, ) hidden_states = self.final_layernorm(hidden_states) return BaseModelOutputWithPast( last_hidden_state=hidden_states, past_key_values=past_key_values if use_cache else None, ) def get_layers(self): layers = [] self._tied_weights_keys = {} self.first_transformer_layer_id = 0 unique_hybrid_blocks = [] for layer_id, layer_type in enumerate(self.layers_block_type): mamba_layer = Zamba2MambaDecoderLayer(self.config, layer_idx=layer_id) if layer_type == "hybrid": prefix_pattern = f"layers.{layer_id}.shared_transformer" # Zamba ties Hybrid module weights by repeating blocks after every # `num_mem_blocks`. So if `num_mem_blocks=2`, the blocks looks like # [1, 2, 1, 2, 1, 2] where all "ones" share the same set of weights. if ( not isinstance(unique_hybrid_blocks, list) or len(unique_hybrid_blocks) >= self.config.num_mem_blocks ): if isinstance(unique_hybrid_blocks, list): unique_hybrid_blocks = cycle(unique_hybrid_blocks) target_pattern = next(unique_hybrid_blocks) self._tied_weights_keys.update({prefix_pattern: target_pattern}) else: # Store source patterns to which the subsequent modules will be tied unique_hybrid_blocks.append(prefix_pattern) block_id = layer_id % self.config.num_mem_blocks attn_block = Zamba2AttentionDecoderLayer(self.config, block_id=block_id) linear_layer = nn.Linear(self.config.hidden_size, self.config.hidden_size, bias=False) layers.append(Zamba2HybridLayer(attn_block, linear_layer, mamba_layer)) else: layers.append(mamba_layer) return nn.ModuleList(layers) # Adapted from transformers.models.jamba.modeling_jamba.JambaForCausalLM with Jamba->Zamba2, JAMBA->ZAMBA2 class Zamba2ForCausalLM(Zamba2PreTrainedModel, GenerationMixin): _tied_weights_keys = {"lm_head.weight": "model.embed_tokens.weight"} def __init__(self, config: Zamba2Config): super().__init__(config) self.model = Zamba2Model(config) self.vocab_size = config.vocab_size self.lm_head = nn.Linear(config.hidden_size, config.vocab_size, bias=False) # Initialize weights and apply final processing self.post_init() @can_return_tuple @auto_docstring def forward( self, input_ids: torch.LongTensor | None = None, attention_mask: torch.Tensor | None = None, position_ids: torch.LongTensor | None = None, past_key_values: Cache | None = None, inputs_embeds: torch.FloatTensor | None = None, labels: torch.LongTensor | None = None, use_cache: bool | None = None, logits_to_keep: int | torch.Tensor = 0, **kwargs: Unpack[TransformersKwargs], ) -> tuple | CausalLMOutputWithPast: r""" labels (`torch.LongTensor` of shape `(batch_size, sequence_length)`, *optional*): Labels for computing the masked language modeling loss. Indices should either be in `[0, ..., config.vocab_size]` or -100 (see `input_ids` docstring). Tokens with indices set to `-100` are ignored (masked), the loss is only computed for the tokens with labels in `[0, ..., config.vocab_size]`. Example: ```python >>> from transformers import AutoTokenizer, Zamba2ForCausalLM >>> model = Zamba2ForCausalLM.from_pretrained("Zyphra/Zamba2-7B-v1") >>> tokenizer = AutoTokenizer.from_pretrained("Zyphra/Zamba2-7B-v1") >>> prompt = "Hey, are you conscious? Can you talk to me?" >>> inputs = tokenizer(prompt, return_tensors="pt") >>> # Generate >>> generate_ids = model.generate(inputs.input_ids, max_length=30) >>> tokenizer.batch_decode(generate_ids, skip_special_tokens=True, clean_up_tokenization_spaces=False)[0] "Hey, are you conscious? Can you talk to me?\nI'm not conscious, but I can talk to you." ```""" outputs: BaseModelOutputWithPast = self.model( input_ids=input_ids, attention_mask=attention_mask, position_ids=position_ids, past_key_values=past_key_values, inputs_embeds=inputs_embeds, use_cache=use_cache, **kwargs, ) hidden_states = outputs.last_hidden_state # Only compute necessary logits, and do not upcast them to float if we are not computing the loss slice_indices = slice(-logits_to_keep, None) if isinstance(logits_to_keep, int) else logits_to_keep logits = self.lm_head(hidden_states[:, slice_indices, :]) loss = None if labels is not None: loss = self.loss_function( logits, labels, self.vocab_size, **kwargs, ) return CausalLMOutputWithPast( loss=loss, logits=logits, past_key_values=outputs.past_key_values, hidden_states=outputs.hidden_states, attentions=outputs.attentions, ) def prepare_inputs_for_generation( self, input_ids, past_key_values=None, attention_mask=None, inputs_embeds=None, position_ids=None, use_cache=True, is_first_iteration=False, **kwargs, ): kwargs["logits_to_keep"] = self.config.num_logits_to_keep model_inputs = super().prepare_inputs_for_generation( input_ids, past_key_values=past_key_values, attention_mask=attention_mask, inputs_embeds=inputs_embeds, position_ids=position_ids, use_cache=use_cache, is_first_iteration=is_first_iteration, **kwargs, ) return model_inputs @auto_docstring( custom_intro=""" The Zamba2 Model with a sequence classification head on top (linear layer). [`Zamba2ForSequenceClassification`] uses the last token in order to do the classification, as other causal models (e.g. GPT-2) do. Since it does classification on the last token, it requires to know the position of the last token. If a `pad_token_id` is defined in the configuration, it finds the last token that is not a padding token in each row. If no `pad_token_id` is defined, it simply takes the last value in each row of the batch. Since it cannot guess the padding tokens when `inputs_embeds` are passed instead of `input_ids`, it does the same (take the last value in each row of the batch). """ ) class Zamba2ForSequenceClassification(Zamba2PreTrainedModel): def __init__(self, config: Zamba2Config): super().__init__(config) self.num_labels = config.num_labels self.model = Zamba2Model(config) self.score = nn.Linear(config.hidden_size, self.num_labels, bias=False) # Initialize weights and apply final processing self.post_init() @can_return_tuple @auto_docstring def forward( self, input_ids: torch.LongTensor | None = None, attention_mask: torch.Tensor | None = None, position_ids: torch.LongTensor | None = None, past_key_values: Cache | None = None, inputs_embeds: torch.FloatTensor | None = None, labels: torch.LongTensor | None = None, use_cache: bool | None = None, logits_to_keep: int | torch.Tensor = 0, **kwargs: Unpack[TransformersKwargs], ) -> tuple | SequenceClassifierOutputWithPast: r""" labels (`torch.LongTensor` of shape `(batch_size,)`, *optional*): Labels for computing the sequence classification/regression loss. Indices should be in `[0, ..., config.num_labels - 1]`. If `config.num_labels == 1` a regression loss is computed (Mean-Square loss), If `config.num_labels > 1` a classification loss is computed (Cross-Entropy). """ transformer_outputs: BaseModelOutputWithPast = self.model( input_ids, attention_mask=attention_mask, position_ids=position_ids, past_key_values=past_key_values, inputs_embeds=inputs_embeds, use_cache=use_cache, **kwargs, ) hidden_states = transformer_outputs[0] logits = self.score(hidden_states) if input_ids is not None: batch_size = input_ids.shape[0] else: batch_size = inputs_embeds.shape[0] if self.config.pad_token_id is None and batch_size != 1: raise ValueError("Cannot handle batch sizes > 1 if no padding token is defined.") if self.config.pad_token_id is None: last_non_pad_token = -1 elif input_ids is not None: non_pad_mask = (input_ids != self.config.pad_token_id).to(logits.device, torch.int32) token_indices = torch.arange(input_ids.shape[-1], device=logits.device, dtype=torch.int32) last_non_pad_token = (token_indices * non_pad_mask).argmax(-1) else: last_non_pad_token = -1 logger.warning_once( f"{self.__class__.__name__} will not detect padding tokens in `inputs_embeds`. Results may be " "unexpected if using padding tokens in conjunction with `inputs_embeds.`" ) pooled_logits = logits[torch.arange(batch_size, device=logits.device), last_non_pad_token] loss = None if labels is not None: loss = self.loss_function( logits=pooled_logits, labels=labels, pooled_logits=pooled_logits, config=self.config, **kwargs ) return SequenceClassifierOutputWithPast( loss=loss, logits=pooled_logits, past_key_values=transformer_outputs.past_key_values, hidden_states=transformer_outputs.hidden_states, attentions=transformer_outputs.attentions, ) __all__ = ["Zamba2ForCausalLM", "Zamba2ForSequenceClassification", "Zamba2Model", "Zamba2PreTrainedModel"]