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diff --git a/makima/src/tts/qwen3/code_predictor.rs b/makima/src/tts/qwen3/code_predictor.rs
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+//! Multi-Token Prediction (MTP) code predictor.
+//!
+//! After the main LM predicts the zeroth codebook token, this module
+//! predicts the remaining 15 codebook layers in parallel from the
+//! LM's hidden states.
+//!
+//! Architecture:
+//! - 5 transformer layers (same structure as main LM layers)
+//! - 16 output heads, one per codebook (vocab 2048 each)
+//! - Input: last hidden state from main LM + zeroth codebook embedding
+//! - Output: 16 codebook token predictions
+
+use candle_core::{Device, Module, Result, Tensor, D};
+use candle_nn::{embedding, linear_no_bias, rms_norm, Embedding, Linear, RmsNorm, VarBuilder};
+
+use super::config::{CodePredictorConfig, Qwen3LmConfig};
+use super::model::{KvCache, Qwen3Attention, Qwen3Mlp, RotaryEmbedding};
+
+/// A single code predictor transformer layer.
+///
+/// Uses the same pre-norm residual structure as the main LM layers.
+pub struct CodePredictorLayer {
+    self_attn: Qwen3Attention,
+    mlp: Qwen3Mlp,
+    input_layernorm: RmsNorm,
+    post_attention_layernorm: RmsNorm,
+}
+
+impl CodePredictorLayer {
+    pub fn new(config: &CodePredictorConfig, vb: VarBuilder) -> Result<Self> {
+        // Construct a Qwen3LmConfig-like view for the attention/MLP constructors
+        let lm_config = Qwen3LmConfig {
+            hidden_size: config.hidden_size,
+            num_hidden_layers: config.num_layers,
+            num_attention_heads: config.num_attention_heads,
+            num_key_value_heads: config.num_attention_heads, // No GQA in predictor
+            intermediate_size: config.hidden_size * 3, // 3072 for hidden=1024
+            head_dim: config.hidden_size / config.num_attention_heads,
+            rms_norm_eps: config.rms_norm_eps,
+            ..Qwen3LmConfig::default()
+        };
+
+        let self_attn = Qwen3Attention::new(&lm_config, vb.pp("self_attn"))?;
+        let mlp = Qwen3Mlp::new(&lm_config, vb.pp("mlp"))?;
+        let input_layernorm = rms_norm(
+            config.hidden_size,
+            config.rms_norm_eps,
+            vb.pp("input_layernorm"),
+        )?;
+        let post_attention_layernorm = rms_norm(
+            config.hidden_size,
+            config.rms_norm_eps,
+            vb.pp("post_attention_layernorm"),
+        )?;
+
+        Ok(Self {
+            self_attn,
+            mlp,
+            input_layernorm,
+            post_attention_layernorm,
+        })
+    }
+
+    pub fn forward(
+        &self,
+        hidden_states: &Tensor,
+        rope: &RotaryEmbedding,
+        kv_cache: &mut KvCache,
+        attention_mask: Option<&Tensor>,
+    ) -> Result<Tensor> {
+        let residual = hidden_states;
+        let hidden_states = self.input_layernorm.forward(hidden_states)?;
+        let hidden_states =
+            self.self_attn
+                .forward(&hidden_states, rope, kv_cache, attention_mask)?;
+        let hidden_states = (residual + hidden_states)?;
+
+        let residual = &hidden_states;
+        let hidden_states = self.post_attention_layernorm.forward(&hidden_states)?;
+        let hidden_states = self.mlp.forward(&hidden_states)?;
+        let output = (residual + hidden_states)?;
+
+        Ok(output)
+    }
+}
+
+/// Multi-token prediction code predictor.
+///
+/// Takes the hidden states from the main LM and predicts all 16 codebook
+/// tokens. The zeroth codebook is predicted by the main LM head; this
+/// module predicts the remaining 15 residual codebooks.
+pub struct CodePredictor {
+    /// Embedding layer for codebook tokens (shared across groups).
+    code_embeddings: Vec<Embedding>,
+    /// Projection from LM hidden + code embedding to predictor hidden.
+    input_proj: Linear,
+    /// 5 transformer layers.
+    layers: Vec<CodePredictorLayer>,
+    /// Final normalization.
+    norm: RmsNorm,
+    /// Per-codebook output heads (16 heads, each projecting to codebook_vocab_size).
+    output_heads: Vec<Linear>,
+    /// RoPE for the predictor's attention layers.
+    rope: RotaryEmbedding,
+    config: CodePredictorConfig,
+}
+
+impl CodePredictor {
+    pub fn new(
+        config: &CodePredictorConfig,
+        lm_config: &Qwen3LmConfig,
+        vb: VarBuilder,
+    ) -> Result<Self> {
+        let predictor_vb = vb.pp("code_predictor");
+
+        // Code embeddings for each codebook group
+        let mut code_embeddings = Vec::with_capacity(config.num_code_groups);
+        for i in 0..config.num_code_groups {
+            let emb = embedding(
+                config.codebook_vocab_size,
+                config.hidden_size,
+                predictor_vb.pp(format!("code_embeddings.{i}")),
+            )?;
+            code_embeddings.push(emb);
+        }
+
+        // Input projection: LM hidden (1024) + code embedding (1024) -> predictor hidden (1024)
+        let input_proj = linear_no_bias(
+            config.hidden_size * 2,
+            config.hidden_size,
+            predictor_vb.pp("input_proj"),
+        )?;
+
+        // Transformer layers
+        let mut layers = Vec::with_capacity(config.num_layers);
+        for i in 0..config.num_layers {
+            let layer =
+                CodePredictorLayer::new(config, predictor_vb.pp(format!("layers.{i}")))?;
+            layers.push(layer);
+        }
+
+        let norm = rms_norm(
+            config.hidden_size,
+            config.rms_norm_eps,
+            predictor_vb.pp("norm"),
+        )?;
+
+        // Output heads for each codebook
+        let mut output_heads = Vec::with_capacity(config.num_code_groups);
+        for i in 0..config.num_code_groups {
+            let head = linear_no_bias(
+                config.hidden_size,
+                config.codebook_vocab_size,
+                predictor_vb.pp(format!("output_heads.{i}")),
+            )?;
+            output_heads.push(head);
+        }
+
+        // RoPE for predictor attention (uses same theta/dim as main LM but with predictor head_dim)
+        let predictor_head_dim = config.hidden_size / config.num_attention_heads;
+        let rope_config = Qwen3LmConfig {
+            head_dim: predictor_head_dim,
+            rope_theta: lm_config.rope_theta,
+            max_position_embeddings: lm_config.max_position_embeddings,
+            ..Qwen3LmConfig::default()
+        };
+        let rope = RotaryEmbedding::new(&rope_config, vb.dtype(), vb.device())?;
+
+        Ok(Self {
+            code_embeddings,
+            input_proj,
+            layers,
+            norm,
+            output_heads,
+            rope,
+            config: config.clone(),
+        })
+    }
+
+    /// Predict all 16 codebook tokens from the LM hidden state.
+    ///
+    /// `lm_hidden`: [batch, 1, hidden_size] — last hidden state from main LM
+    /// `zeroth_code`: the token predicted by the main LM head (zeroth codebook)
+    ///
+    /// Returns: Vec of 16 token indices (one per codebook), starting with zeroth_code.
+    pub fn predict(
+        &self,
+        lm_hidden: &Tensor,
+        zeroth_code: u32,
+        device: &Device,
+    ) -> Result<Vec<u32>> {
+        let mut all_codes = Vec::with_capacity(self.config.num_code_groups);
+        all_codes.push(zeroth_code);
+
+        // The code predictor iterates through codebook groups.
+        // For each group i (1..16), it:
+        //   1. Embeds the previous codebook token
+        //   2. Concatenates with LM hidden state
+        //   3. Projects through the predictor layers
+        //   4. Predicts the next codebook token via output_head[i]
+        let mut prev_code = zeroth_code;
+
+        for group_idx in 1..self.config.num_code_groups {
+            // Embed the previous codebook token
+            let code_tensor = Tensor::from_vec(
+                vec![prev_code],
+                (1, 1),
+                device,
+            )?;
+            let code_emb = self.code_embeddings[group_idx - 1].forward(&code_tensor)?;
+
+            // Concatenate LM hidden state with code embedding
+            let combined = Tensor::cat(&[lm_hidden, &code_emb], D::Minus1)?;
+
+            // Project to predictor hidden size
+            let mut hidden = self.input_proj.forward(&combined)?;
+
+            // Run through predictor transformer layers (no KV cache needed — single step)
+            let mut kv_caches: Vec<KvCache> =
+                (0..self.config.num_layers).map(|_| KvCache::new()).collect();
+            for (i, layer) in self.layers.iter().enumerate() {
+                hidden = layer.forward(&hidden, &self.rope, &mut kv_caches[i], None)?;
+            }
+
+            hidden = self.norm.forward(&hidden)?;
+
+            // Predict codebook token
+            let logits = self.output_heads[group_idx].forward(&hidden)?;
+
+            // Greedy decode: argmax
+            let logits_flat = logits.squeeze(0)?.squeeze(0)?; // [codebook_vocab_size]
+            let next_code = logits_flat
+                .argmax(0)?
+                .to_scalar::<u32>()?;
+
+            all_codes.push(next_code);
+            prev_code = next_code;
+        }
+
+        Ok(all_codes)
+    }
+
+    /// Number of codebook groups.
+    pub fn num_code_groups(&self) -> usize {
+        self.config.num_code_groups
+    }
+}
+
+#[cfg(test)]
+mod tests {
+    use super::*;
+
+    #[test]
+    fn test_code_predictor_config() {
+        let config = CodePredictorConfig::default();
+        assert_eq!(config.num_layers, 5);
+        assert_eq!(config.num_code_groups, 16);
+        assert_eq!(config.codebook_vocab_size, 2048);
+        assert_eq!(config.hidden_size, 1024);
+    }
+}