"""Audio projector modules for bridging encoder and decoder embeddings. This module contains all projector architectures: - MLPAudioProjector: Simple 2-layer MLP with conv downsampling - MoEAudioProjector: MOSA-style dense mixture of experts - SwiGLUAudioProjector: SwiGLU-based projector with temporal pooling - ResidualAudioProjector: Residual MLP blocks with linear projection - SharedMoEAudioProjector: Shared expert + sparse routed experts - QFormerAudioProjector: BLIP-2 QFormer with learnable queries (Granite-style) """ import math import torch import torch.nn as nn import torch.nn.functional as F # noqa: N812 from transformers import AutoModel, Blip2QFormerConfig from transformers.models.llama.modeling_llama import LlamaRMSNorm # ============================================================================= # MLP Projector # ============================================================================= class MLPAudioProjector(nn.Module): """2-layer MLP projector with conv-based 2x temporal downsampling.""" def __init__(self, config): super().__init__() encoder_dim = getattr(config, "encoder_dim", 768) llm_dim = getattr(config, "llm_dim", 2048) self.downsample = nn.Conv1d( encoder_dim, encoder_dim, kernel_size=3, stride=2, padding=1, bias=False ) self.linear_1 = nn.Linear(encoder_dim, llm_dim, bias=False) self.act = nn.GELU() self.linear_2 = nn.Linear(llm_dim, llm_dim, bias=False) self.apply(self._init_weights) def _init_weights(self, module): if isinstance(module, nn.Linear): nn.init.normal_(module.weight, mean=0.0, std=0.02) elif isinstance(module, nn.Conv1d): nn.init.normal_(module.weight, mean=0.0, std=0.02) if module.bias is not None: nn.init.zeros_(module.bias) def get_output_length(self, input_length: int) -> int: """Calculate output sequence length given input length.""" # Conv stride=2 halves the length (with padding=1, kernel=3) return (input_length + 1) // 2 def forward(self, x): """ x: [Batch, Seq_Len, Dim] Returns: [Batch, Seq_Len // 2, llm_dim] """ # Conv1d expects [Batch, Channels, Seq_Len] x = x.transpose(1, 2) x = self.downsample(x) x = x.transpose(1, 2) x = self.linear_1(x) x = self.act(x) return self.linear_2(x) # ============================================================================= # MoE Projector (MOSA-style) # ============================================================================= class SimpleAdapter(nn.Module): """Simple 2-layer ReLU adapter (from MOSA paper).""" def __init__(self, input_dim: int, hidden_dim: int, output_dim: int): super().__init__() self.fc1 = nn.Linear(input_dim, hidden_dim) self.act = nn.ReLU() self.fc2 = nn.Linear(hidden_dim, output_dim) def forward(self, x: torch.Tensor) -> torch.Tensor: return self.fc2(self.act(self.fc1(x))) class SwiGLUExpert(nn.Module): """SwiGLU expert (gated MLP with SiLU activation).""" def __init__(self, input_dim: int, hidden_dim: int, output_dim: int): super().__init__() self.gate_proj = nn.Linear(input_dim, hidden_dim, bias=False) self.up_proj = nn.Linear(input_dim, hidden_dim, bias=False) self.down_proj = nn.Linear(hidden_dim, output_dim, bias=False) def forward(self, x: torch.Tensor) -> torch.Tensor: return self.down_proj(F.silu(self.gate_proj(x)) * self.up_proj(x)) class MOSAProjector(nn.Module): def __init__(self, config): super().__init__() self.encoder_dim = getattr(config, "encoder_dim", None) or 1280 self.llm_dim = getattr(config, "llm_dim", None) or 2048 self.num_experts = getattr(config, "num_experts", None) or 8 adapter_hidden = getattr(config, "adapter_hidden_dim", None) or 4096 # Auxiliary loss coefficients (MOSA paper uses only cross-entropy, no aux losses) self.aux_loss_coef = getattr(config, "router_aux_loss_coef", 0.0) self.z_loss_coef = getattr(config, "router_z_loss_coef", 0.0) # Store router state for aux loss computation self.last_router_logits = None self.last_routing_weights = None # --- 1. Pre-Norms (CRITICAL for stability) --- self.in_norm = LlamaRMSNorm(self.encoder_dim, eps=1e-8) # --- 2. Convolutional Subsampling (Stride 4) --- self.conv = nn.Sequential( nn.Conv1d(self.encoder_dim, self.llm_dim, kernel_size=3, stride=2, padding=1), nn.SiLU(), nn.Conv1d(self.llm_dim, self.llm_dim, kernel_size=3, stride=2, padding=1), nn.SiLU(), ) # --- 3. Deep Router (ReLU per MOSA paper) --- self.router = nn.Sequential( nn.Linear(self.encoder_dim, 2560), nn.ReLU(), nn.Linear(2560, 5120), nn.ReLU(), nn.Linear(5120, 2560), nn.ReLU(), nn.Linear(2560, 1280), nn.ReLU(), nn.Linear(1280, self.num_experts), ) # --- 4. Experts (Simple 2-layer ReLU adapters per MOSA paper) --- self.experts = nn.ModuleList( [ SimpleAdapter(self.llm_dim, adapter_hidden, self.llm_dim) for _ in range(self.num_experts) ] ) # --- 5. Output Norm --- # Projects often drift in magnitude; this clamps them before the LLM. self.out_norm = LlamaRMSNorm(self.llm_dim, eps=1e-8) # Using PyTorch default initialization (like MOSA paper) def forward(self, x): # x: (B, S, 1280) batch_size, seq_len, _ = x.shape # Apply Input Norm x = self.in_norm(x) # --- 1. Conv Branch --- x_trans = x.permute(0, 2, 1) # (B, D, S) h_conv = self.conv(x_trans).permute(0, 2, 1) # (B, S//4, llm_dim) # --- 2. Router Branch --- pad_amt = (4 - (seq_len % 4)) % 4 x_padded = F.pad(x, (0, 0, 0, pad_amt)) if pad_amt > 0 else x # Mean pool to align receptive fields x_pooled = x_padded.view(batch_size, -1, 4, self.encoder_dim).mean(dim=2) # (B, S//4, D) # Router Logits router_logits = self.router(x_pooled) # (B, S//4, num_experts) # Softmax for Dense MoE (Soft Mixing) routing_weights = F.softmax(router_logits, dim=-1) # Store for aux loss computation self.last_router_logits = router_logits self.last_routing_weights = routing_weights # --- 3. Expert Mixture (Dense Execution) --- # Warning: High VRAM usage. Runs all experts. # h_conv: (B, S//4, llm_dim) # Stack approach is clean but memory hungry. # Checkpointing could be added here if OOM occurs. expert_outputs = torch.stack([expert(h_conv) for expert in self.experts]) # (E, B, S//4, D) # Weighted Sum # (Experts, Batch, Seq, Dim) * (Batch, Seq, Experts) -> (Batch, Seq, Dim) final_out = torch.einsum("ebsd, bse -> bsd", expert_outputs, routing_weights) return self.out_norm(final_out) def get_output_length(self, input_length: int) -> int: """Calculate output sequence length given input length.""" # Two conv layers with stride=2 each = stride 4 total padded = input_length + (4 - input_length % 4) % 4 return padded // 4 def get_aux_loss(self) -> torch.Tensor: """Compute auxiliary losses: load balancing + z-loss.""" if self.last_router_logits is None: return torch.tensor(0.0, device=self.conv[0].weight.device) # Flatten for loss computation: (B, S, E) -> (B*S, E) logits_flat = self.last_router_logits.view(-1, self.num_experts) probs_flat = self.last_routing_weights.view(-1, self.num_experts) balance = load_balancing_loss(probs_flat, self.num_experts, top_k=self.num_experts) z = z_loss(logits_flat) return self.aux_loss_coef * balance + self.z_loss_coef * z # ============================================================================= # SwiGLU Projector # ============================================================================= class SwiGLU(nn.Module): def __init__(self, in_features, hidden_features, out_features, bias=False, dropout=0.0): super().__init__() self.w1 = nn.Linear(in_features, hidden_features, bias=bias) self.w2 = nn.Linear(in_features, hidden_features, bias=bias) self.w3 = nn.Linear(hidden_features, out_features, bias=bias) self.act = nn.SiLU() self.dropout = nn.Dropout(dropout) def forward(self, x): x_gate = self.act(self.w1(x)) x_val = self.w2(x) x = x_gate * x_val x = self.dropout(x) return self.w3(x) class SwiGLUAudioProjector(nn.Module): """SwiGLU-based projector with temporal pooling.""" def __init__(self, config): super().__init__() self.k = getattr(config, "projector_pool_stride", 4) in_dim = config.encoder_dim * self.k out_dim = config.llm_dim hidden_dim = config.projector_hidden_dim if hidden_dim is None: hidden_dim = config.encoder_dim * 2 dropout_rate = getattr(config, "projector_dropout", 0.0) self.proj1 = SwiGLU(in_dim, hidden_dim, hidden_dim, dropout=dropout_rate) self.proj2 = SwiGLU(hidden_dim, hidden_dim, out_dim, dropout=dropout_rate) self.output_dropout = nn.Dropout(dropout_rate) with torch.no_grad(): std = getattr(config, "projector_init_std", 0.02) nn.init.normal_(self.proj1.w1.weight, mean=0.0, std=std) nn.init.normal_(self.proj1.w2.weight, mean=0.0, std=std) nn.init.normal_(self.proj1.w3.weight, mean=0.0, std=std) nn.init.normal_(self.proj2.w1.weight, mean=0.0, std=std) nn.init.normal_(self.proj2.w2.weight, mean=0.0, std=std) nn.init.normal_(self.proj2.w3.weight, mean=0.0, std=std) def get_output_length(self, input_length: int) -> int: """Calculate output sequence length given input length.""" # Temporal pooling with stride k remainder = input_length % self.k if remainder: input_length += self.k - remainder return input_length // self.k def forward(self, x): batch_size, seq_len, dim = x.size() target_dtype = self.proj1.w1.weight.dtype if x.dtype != target_dtype: x = x.to(target_dtype) remainder = seq_len % self.k if remainder: pad_len = self.k - remainder x = F.pad(x, (0, 0, 0, pad_len)) x = x.contiguous().view(batch_size, -1, dim * self.k) x = self.proj1(x) x = self.proj2(x) return self.output_dropout(x) # Alias for backwards compatibility AudioProjector = SwiGLUAudioProjector # ============================================================================= # Residual Projector # ============================================================================= class ResidualMLP(nn.Module): """MLP block with residual connection: Output = x + MLP(x).""" def __init__(self, dim, hidden_dim, dropout=0.0): super().__init__() self.fc1 = nn.Linear(dim, hidden_dim) self.fc2 = nn.Linear(hidden_dim, dim) self.act = nn.GELU() self.dropout = nn.Dropout(dropout) def forward(self, x): residual = x x = self.fc1(x) x = self.act(x) x = self.dropout(x) x = self.fc2(x) x = self.dropout(x) return residual + x class ResidualAudioProjector(nn.Module): """Residual MLP projector for audio-to-LLM feature translation.""" def __init__(self, config): super().__init__() self.k = getattr(config, "projector_pool_stride", 4) in_dim = config.encoder_dim * self.k out_dim = config.llm_dim hidden_dim = getattr(config, "projector_hidden_dim", None) or out_dim * 4 self.num_layers = getattr(config, "projector_num_layers", 2) dropout_rate = getattr(config, "projector_dropout", 0.0) self.input_proj = nn.Linear(in_dim, out_dim) self.ln_input = LlamaRMSNorm(out_dim, eps=1e-8) self.layers = nn.ModuleList( [ResidualMLP(out_dim, hidden_dim, dropout=dropout_rate) for _ in range(self.num_layers)] ) self.layer_norms = nn.ModuleList( [LlamaRMSNorm(out_dim, eps=1e-8) for _ in range(self.num_layers)] ) self.output_dropout = nn.Dropout(dropout_rate) self._init_weights(config) def _init_weights(self, config): std = getattr(config, "projector_init_std", 0.02) with torch.no_grad(): nn.init.normal_(self.input_proj.weight, mean=0.0, std=std) if self.input_proj.bias is not None: nn.init.zeros_(self.input_proj.bias) self.ln_input.weight.data.fill_(1.0) for ln in self.layer_norms: ln.weight.data.fill_(1.0) for layer in self.layers: nn.init.normal_(layer.fc1.weight, mean=0.0, std=std) nn.init.normal_(layer.fc2.weight, mean=0.0, std=std * 0.1) if layer.fc1.bias is not None: nn.init.zeros_(layer.fc1.bias) if layer.fc2.bias is not None: nn.init.zeros_(layer.fc2.bias) def get_output_length(self, input_length: int) -> int: """Calculate output sequence length given input length.""" # Temporal pooling with stride k remainder = input_length % self.k if remainder: input_length += self.k - remainder return input_length // self.k def forward(self, x): batch_size, seq_len, dim = x.size() target_dtype = self.input_proj.weight.dtype if x.dtype != target_dtype: x = x.to(target_dtype) remainder = seq_len % self.k if remainder: pad_len = self.k - remainder x = F.pad(x, (0, 0, 0, pad_len)) x = x.contiguous().view(batch_size, -1, dim * self.k) x = self.input_proj(x) x = self.ln_input(x) for layer, ln in zip(self.layers, self.layer_norms): x = layer(x) x = ln(x) return self.output_dropout(x) # ============================================================================= # Shared MoE Projector # ============================================================================= class SharedMoEBlock(nn.Module): """MoE block with Shared + Sigmoid-Routed Experts.""" def __init__( self, input_dim: int, hidden_dim: int, output_dim: int, num_experts: int = 4, top_k: int = 2, ): super().__init__() self.num_experts = num_experts self.top_k = top_k self.output_dim = output_dim # RMSNorm before routing self.norm = LlamaRMSNorm(input_dim, eps=1e-8) self.router = nn.Linear(input_dim, num_experts, bias=False) nn.init.normal_(self.router.weight, mean=0.0, std=0.02) self.shared_expert = SwiGLUExpert(input_dim, hidden_dim, output_dim) self.experts = nn.ModuleList( [SwiGLUExpert(input_dim, hidden_dim, output_dim) for _ in range(num_experts)] ) self.last_router_logits = None self.last_router_probs = None def forward(self, hidden_states: torch.Tensor) -> torch.Tensor: batch_size, seq_len, dim = hidden_states.shape # 1. Apply Shared Expert normed_states = self.norm(hidden_states) shared_out = self.shared_expert(normed_states) # 2. Router Logic (Sigmoid Style) flat_hidden = normed_states.view(-1, dim) router_logits = self.router(flat_hidden) # Sigmoid routing router_probs = torch.sigmoid(router_logits) self.last_router_logits = router_logits self.last_router_probs = router_probs # 3. Top-K Selection top_k_scores, top_k_indices = torch.topk(router_probs, self.top_k, dim=-1) # Normalize weights top_k_weights = top_k_scores / (top_k_scores.sum(dim=-1, keepdim=True) + 1e-6) top_k_weights = top_k_weights.to(hidden_states.dtype) # 4. Dispatch routed_out = self._dispatch_experts(flat_hidden, top_k_indices, top_k_weights) routed_out = routed_out.view(batch_size, seq_len, -1) return shared_out + routed_out def _dispatch_experts( self, hidden_states: torch.Tensor, top_k_indices: torch.Tensor, top_k_weights: torch.Tensor, ) -> torch.Tensor: num_tokens = hidden_states.shape[0] output = torch.zeros( num_tokens, self.output_dim, device=hidden_states.device, dtype=hidden_states.dtype ) for expert_idx, expert in enumerate(self.experts): expert_mask = top_k_indices == expert_idx if not expert_mask.any(): continue token_indices, slot_indices = torch.where(expert_mask) expert_input = hidden_states[token_indices] expert_output = expert(expert_input).to(output.dtype) weights = top_k_weights[token_indices, slot_indices].unsqueeze(-1) output.index_add_(0, token_indices, expert_output * weights) return output def load_balancing_loss(router_probs: torch.Tensor, num_experts: int, top_k: int) -> torch.Tensor: """Auxiliary loss to encourage balanced expert usage.""" prob_per_expert = router_probs.mean(dim=0) target_mean = prob_per_expert.mean() return (prob_per_expert - target_mean).square().sum() * num_experts def z_loss(router_logits: torch.Tensor) -> torch.Tensor: """Z-loss to prevent router logits from growing too large.""" return torch.logsumexp(router_logits.float(), dim=-1).square().mean() class SharedMoEAudioProjector(nn.Module): """Shared expert + sparse routed experts projector.""" def __init__(self, config): super().__init__() # Default stride is now 2 (was 4) self.k = getattr(config, "projector_pool_stride", 4) encoder_dim = config.encoder_dim # Depthwise Conv for temporal mixing self.temporal_conv = nn.Conv1d( encoder_dim, encoder_dim, kernel_size=3, padding=1, groups=encoder_dim ) in_dim = encoder_dim * self.k out_dim = config.llm_dim hidden_dim = getattr(config, "projector_hidden_dim", None) or in_dim self.num_experts = getattr(config, "num_experts", 4) self.top_k = getattr(config, "num_experts_per_tok", 2) self.aux_loss_coef = getattr(config, "router_aux_loss_coef", 0.02) self.z_loss_coef = getattr(config, "router_z_loss_coef", 0.001) self.moe = SharedMoEBlock(in_dim, hidden_dim, out_dim, self.num_experts, self.top_k) self._init_weights() def _init_weights(self): with torch.no_grad(): nn.init.orthogonal_(self.moe.shared_expert.gate_proj.weight) nn.init.orthogonal_(self.moe.shared_expert.up_proj.weight) nn.init.orthogonal_(self.moe.shared_expert.down_proj.weight, gain=0.5) for expert in self.moe.experts: nn.init.orthogonal_(expert.gate_proj.weight) nn.init.orthogonal_(expert.up_proj.weight) nn.init.orthogonal_(expert.down_proj.weight, gain=0.01) def get_output_length(self, input_length: int) -> int: """Calculate output sequence length given input length.""" # Temporal pooling with stride k if input_length % self.k: input_length += self.k - input_length % self.k return input_length // self.k def forward(self, x: torch.Tensor) -> torch.Tensor: batch_size, seq_len, dim = x.size() target_dtype = self.moe.shared_expert.gate_proj.weight.dtype if x.dtype != target_dtype: x = x.to(target_dtype) # Temporal Context Injection x_ctx = x.transpose(1, 2) x_ctx = self.temporal_conv(x_ctx) x = x + x_ctx.transpose(1, 2) if seq_len % self.k: x = F.pad(x, (0, 0, 0, self.k - seq_len % self.k)) x = x.view(batch_size, -1, dim * self.k) return self.moe(x) def get_aux_loss(self) -> torch.Tensor: if self.moe.last_router_logits is None: return torch.tensor(0.0, device=self.moe.router.weight.device) balance = load_balancing_loss(self.moe.last_router_probs, self.num_experts, self.top_k) z = z_loss(self.moe.last_router_logits) return self.aux_loss_coef * balance + self.z_loss_coef * z # ============================================================================= # QFormer Projector (Granite-style) # ============================================================================= class QFormerAudioProjector(nn.Module): """ BLIP-2 QFormer projector with learnable queries. Based on GraniteSpeechEncoderProjector - uses a QFormer model with learnable query embeddings to compress and project audio encoder outputs. The audio sequence is processed in windows and downsampled via cross-attention. """ def __init__(self, config): super().__init__() encoder_dim = config.encoder_dim llm_dim = config.llm_dim # Window and downsampling parameters (Granite defaults: window=15, downsample=5) self.window_size = getattr(config, "qformer_window_size", 15) self.downsample_rate = getattr(config, "downsample_rate", 5) self.num_queries = self.window_size // self.downsample_rate # QFormer hidden size (matches encoder for cross-attention) qformer_hidden = getattr(config, "qformer_hidden_size", None) or encoder_dim qformer_num_layers = getattr(config, "qformer_num_layers", 2) qformer_num_heads = getattr(config, "qformer_num_heads", 16) qformer_intermediate = getattr(config, "qformer_intermediate_size", None) or ( qformer_hidden * 4 ) # Learnable query embeddings (Granite uses std=1.0) self.query = nn.Parameter(torch.zeros(1, self.num_queries, qformer_hidden)) self.query.data.normal_(mean=0.0, std=1.0) # Optional projection if encoder dim != qformer hidden if encoder_dim != qformer_hidden: self.encoder_proj = nn.Linear(encoder_dim, qformer_hidden, bias=False) else: self.encoder_proj = None # Configure QFormer to match Granite's exact config qformer_config = Blip2QFormerConfig( hidden_size=qformer_hidden, num_hidden_layers=qformer_num_layers, num_attention_heads=qformer_num_heads, intermediate_size=qformer_intermediate, encoder_hidden_size=qformer_hidden, cross_attention_frequency=1, # Granite-specific settings hidden_act="gelu", attention_probs_dropout_prob=0.1, hidden_dropout_prob=0.1, layer_norm_eps=1e-12, initializer_range=0.02, ) self.qformer = AutoModel.from_config(qformer_config) # Final projection to LLM dimension (Granite uses bias=True) self.linear = nn.Linear(qformer_hidden, llm_dim) def get_output_length(self, input_length: int) -> int: """Calculate output sequence length given input length.""" # QFormer uses window-based processing with num_queries per window nblocks = math.ceil(input_length / self.window_size) return nblocks * self.num_queries def forward(self, hidden_states: torch.Tensor) -> torch.Tensor: """ Args: hidden_states: [batch_size, seq_len, encoder_dim] Returns: projected: [batch_size, num_output_tokens, llm_dim] """ batch_size, seq_len, dim = hidden_states.size() # Ensure float dtype for QFormer target_dtype = self.query.dtype if hidden_states.dtype != target_dtype: hidden_states = hidden_states.to(target_dtype) # Optional encoder projection if self.encoder_proj is not None: hidden_states = self.encoder_proj(hidden_states) # Compute number of windows and pad to fit nblocks = math.ceil(seq_len / self.window_size) pad = nblocks * self.window_size - seq_len if pad > 0: hidden_states = F.pad(hidden_states, (0, 0, 0, pad), "constant", 0) # Reshape to process each window: [batch*nblocks, window_size, dim] effective_batch = batch_size * nblocks hidden_states = hidden_states.view(effective_batch, self.window_size, -1) # Expand queries to match batch size query_embeds = self.query.expand(effective_batch, -1, -1) # QFormer cross-attention query_output = self.qformer( query_embeds=query_embeds, encoder_hidden_states=hidden_states, return_dict=True, ) # Reshape back: [batch, nblocks * num_queries, hidden] output_tokens = nblocks * self.num_queries query_proj = query_output.last_hidden_state.view(batch_size, output_tokens, -1) # Project to LLM dimension return self.linear(query_proj) # ============================================================================= # Projector Registry # ============================================================================= PROJECTOR_CLASSES = { "mlp": MLPAudioProjector, "mosa": MOSAProjector, "swiglu": SwiGLUAudioProjector, "residual": ResidualAudioProjector, "shared_moe": SharedMoEAudioProjector, "qformer": QFormerAudioProjector, }