#include "models.h" #include "llama-memory-recurrent.h" void llama_model_qwen35moe::load_arch_hparams(llama_model_loader & ml) { ml.get_key(LLM_KV_EXPERT_FEED_FORWARD_LENGTH, hparams.n_ff_exp, false); ml.get_key(LLM_KV_EXPERT_SHARED_FEED_FORWARD_LENGTH, hparams.n_ff_shexp, false); ml.get_key(LLM_KV_ATTENTION_LAYERNORM_RMS_EPS, hparams.f_norm_rms_eps); ml.get_key_or_arr(LLM_KV_ROPE_DIMENSION_SECTIONS, hparams.rope_sections, 4, true); // Load linear attention (gated delta net) parameters ml.get_key(LLM_KV_SSM_CONV_KERNEL, hparams.ssm_d_conv); ml.get_key(LLM_KV_SSM_INNER_SIZE, hparams.ssm_d_inner); ml.get_key(LLM_KV_SSM_STATE_SIZE, hparams.ssm_d_state); ml.get_key(LLM_KV_SSM_TIME_STEP_RANK, hparams.ssm_dt_rank); ml.get_key(LLM_KV_SSM_GROUP_COUNT, hparams.ssm_n_group); // NextN/MTP (Qwen3.5/3.6): extra decoder block appended beyond the main stack ml.get_key(LLM_KV_NEXTN_PREDICT_LAYERS, hparams.nextn_predict_layers, false); GGML_ASSERT(hparams.nextn_predict_layers < hparams.n_layer && "nextn_predict_layers must be < n_layer"); // Mark recurrent layers (linear attention layers). MTP layers are dense // attention-only and must be flagged non-recurrent. { const uint32_t n_main = hparams.n_layer - hparams.nextn_predict_layers; uint32_t full_attn_interval = 4; ml.get_key(LLM_KV_FULL_ATTENTION_INTERVAL, full_attn_interval, false); for (uint32_t i = 0; i < hparams.n_layer; ++i) { hparams.recurrent_layer_arr[i] = (i < n_main) && ((i + 1) % full_attn_interval != 0); } } switch (hparams.n_layer - hparams.nextn_predict_layers) { case 40: type = LLM_TYPE_35B_A3B; break; case 48: type = LLM_TYPE_122B_A10B; break; case 60: type = LLM_TYPE_397B_A17B; break; default: type = LLM_TYPE_UNKNOWN; } } void llama_model_qwen35moe::load_arch_tensors(llama_model_loader & ml) { LLAMA_LOAD_LOCALS; const uint32_t n_main = n_layer - hparams.nextn_predict_layers; const bool mtp_only = (hparams.nextn_predict_layers > 0) && (ml.get_weight("blk.0.attn_norm.weight") == nullptr); const int trunk_flags = mtp_only ? TENSOR_NOT_REQUIRED : 0; tok_embd = create_tensor(tn(LLM_TENSOR_TOKEN_EMBD, "weight"), { n_embd, n_vocab }, 0); // output output_norm = create_tensor(tn(LLM_TENSOR_OUTPUT_NORM, "weight"), { n_embd }, 0); output = create_tensor(tn(LLM_TENSOR_OUTPUT, "weight"), { n_embd, n_vocab }, TENSOR_NOT_REQUIRED); // if output is NULL, init from the input tok embed if (output == NULL) { output = create_tensor(tn(LLM_TENSOR_TOKEN_EMBD, "weight"), { n_embd, n_vocab }, TENSOR_DUPLICATED); } auto load_block_trunk = [&](int il, int flags) { auto & layer = layers[il]; const int64_t n_ff_exp = hparams.n_ff_exp ? hparams.n_ff_exp : n_ff / n_expert_used; const int64_t n_ff_shexp = hparams.n_ff_shexp ? hparams.n_ff_shexp : n_ff; // Calculate dimensions from hyperparameters const int64_t head_k_dim = hparams.ssm_d_state; const int64_t head_v_dim = hparams.ssm_d_state; const int64_t n_k_heads = hparams.ssm_n_group; const int64_t n_v_heads = hparams.ssm_dt_rank; const int64_t key_dim = head_k_dim * n_k_heads; const int64_t value_dim = head_v_dim * n_v_heads; const int64_t conv_dim = key_dim * 2 + value_dim; layer.attn_norm = create_tensor(tn(LLM_TENSOR_ATTN_NORM, "weight", il), { n_embd }, flags); layer.attn_post_norm = create_tensor(tn(LLM_TENSOR_ATTN_POST_NORM, "weight", il), { n_embd }, flags); if (!hparams.is_recurrent(il)) { // Attention layers create_tensor_qkv(layer, il, n_embd, n_embd_head_k * n_head * 2, n_embd_k_gqa, n_embd_v_gqa, flags); layer.wo = create_tensor(tn(LLM_TENSOR_ATTN_OUT, "weight", il), { n_embd_head_k * n_head, n_embd }, flags); // Q/K normalization for attention layers layer.attn_q_norm = create_tensor(tn(LLM_TENSOR_ATTN_Q_NORM, "weight", il), { n_embd_head_k }, flags); layer.attn_k_norm = create_tensor(tn(LLM_TENSOR_ATTN_K_NORM, "weight", il), { n_embd_head_k }, flags); } else { // Linear attention (gated delta net) specific tensors // Create tensors with calculated dimensions layer.wqkv = create_tensor(tn(LLM_TENSOR_ATTN_QKV, "weight", il), { n_embd, key_dim * 2 + value_dim }, TENSOR_NOT_REQUIRED); layer.wqkv_gate = create_tensor(tn(LLM_TENSOR_ATTN_GATE, "weight", il), { n_embd, value_dim }, TENSOR_NOT_REQUIRED); layer.ssm_conv1d = create_tensor(tn(LLM_TENSOR_SSM_CONV1D, "weight", il), { hparams.ssm_d_conv, conv_dim }, flags); layer.ssm_dt = create_tensor(tn(LLM_TENSOR_SSM_DT, "bias", il), { hparams.ssm_dt_rank }, flags); layer.ssm_a = create_tensor(tn(LLM_TENSOR_SSM_A_NOSCAN, il), { hparams.ssm_dt_rank }, flags); layer.ssm_beta = create_tensor(tn(LLM_TENSOR_SSM_BETA, "weight", il), { n_embd, n_v_heads }, flags); layer.ssm_alpha = create_tensor(tn(LLM_TENSOR_SSM_ALPHA, "weight", il), { n_embd, n_v_heads }, flags); layer.ssm_norm = create_tensor(tn(LLM_TENSOR_SSM_NORM, "weight", il), { head_v_dim }, flags); layer.ssm_out = create_tensor(tn(LLM_TENSOR_SSM_OUT, "weight", il), { value_dim, n_embd }, flags); } // Routed experts layer.ffn_gate_inp = create_tensor(tn(LLM_TENSOR_FFN_GATE_INP, "weight", il), { n_embd, n_expert }, flags); layer.ffn_down_exps = create_tensor(tn(LLM_TENSOR_FFN_DOWN_EXPS, "weight", il), { n_ff_exp, n_embd, n_expert }, flags); create_tensor_gate_up_exps(layer, il, n_embd, n_ff_exp, n_expert, flags); // Shared experts layer.ffn_gate_inp_shexp = create_tensor(tn(LLM_TENSOR_FFN_GATE_INP_SHEXP, "weight", il), { n_embd }, flags); layer.ffn_gate_shexp = create_tensor(tn(LLM_TENSOR_FFN_GATE_SHEXP, "weight", il), { n_embd, n_ff_shexp }, flags); layer.ffn_up_shexp = create_tensor(tn(LLM_TENSOR_FFN_UP_SHEXP, "weight", il), { n_embd, n_ff_shexp }, flags); layer.ffn_down_shexp = create_tensor(tn(LLM_TENSOR_FFN_DOWN_SHEXP, "weight", il), { n_ff_shexp, n_embd }, flags); }; auto load_block_mtp = [&](int il) { auto & layer = layers[il]; const int64_t n_ff_exp = hparams.n_ff_exp ? hparams.n_ff_exp : n_ff / n_expert_used; const int64_t n_ff_shexp = hparams.n_ff_shexp ? hparams.n_ff_shexp : n_ff; // MTP block looks like a full-attention Qwen3.5 decoder block with MoE FFN. layer.attn_norm = create_tensor(tn(LLM_TENSOR_ATTN_NORM, "weight", il), { n_embd }, 0); layer.attn_post_norm = create_tensor(tn(LLM_TENSOR_ATTN_POST_NORM, "weight", il), { n_embd }, 0); create_tensor_qkv(layer, il, n_embd, n_embd_head_k * n_head * 2, n_embd_k_gqa, n_embd_v_gqa, 0); layer.wo = create_tensor(tn(LLM_TENSOR_ATTN_OUT, "weight", il), { n_embd_head_k * n_head, n_embd }, 0); layer.attn_q_norm = create_tensor(tn(LLM_TENSOR_ATTN_Q_NORM, "weight", il), { n_embd_head_k }, 0); layer.attn_k_norm = create_tensor(tn(LLM_TENSOR_ATTN_K_NORM, "weight", il), { n_embd_head_k }, 0); // Routed experts layer.ffn_gate_inp = create_tensor(tn(LLM_TENSOR_FFN_GATE_INP, "weight", il), { n_embd, n_expert }, 0); layer.ffn_down_exps = create_tensor(tn(LLM_TENSOR_FFN_DOWN_EXPS, "weight", il), { n_ff_exp, n_embd, n_expert }, 0); create_tensor_gate_up_exps(layer, il, n_embd, n_ff_exp, n_expert, 0); // Shared experts layer.ffn_gate_inp_shexp = create_tensor(tn(LLM_TENSOR_FFN_GATE_INP_SHEXP, "weight", il), { n_embd }, 0); layer.ffn_gate_shexp = create_tensor(tn(LLM_TENSOR_FFN_GATE_SHEXP, "weight", il), { n_embd, n_ff_shexp }, 0); layer.ffn_up_shexp = create_tensor(tn(LLM_TENSOR_FFN_UP_SHEXP, "weight", il), { n_embd, n_ff_shexp }, 0); layer.ffn_down_shexp = create_tensor(tn(LLM_TENSOR_FFN_DOWN_SHEXP, "weight", il), { n_ff_shexp, n_embd }, 0); // NextN-specific tensors that define the MTP block. layer.nextn.eh_proj = create_tensor(tn(LLM_TENSOR_NEXTN_EH_PROJ, "weight", il), { 2 * n_embd, n_embd }, 0); layer.nextn.enorm = create_tensor(tn(LLM_TENSOR_NEXTN_ENORM, "weight", il), { n_embd }, 0); layer.nextn.hnorm = create_tensor(tn(LLM_TENSOR_NEXTN_HNORM, "weight", il), { n_embd }, 0); layer.nextn.embed_tokens = create_tensor(tn(LLM_TENSOR_NEXTN_EMBED_TOKENS, "weight", il), { n_embd, n_vocab }, TENSOR_NOT_REQUIRED); layer.nextn.shared_head_head = create_tensor(tn(LLM_TENSOR_NEXTN_SHARED_HEAD_HEAD, "weight", il), { n_embd, n_vocab }, TENSOR_NOT_REQUIRED); layer.nextn.shared_head_norm = create_tensor(tn(LLM_TENSOR_NEXTN_SHARED_HEAD_NORM, "weight", il), { n_embd }, TENSOR_NOT_REQUIRED); }; for (int i = 0; i < (int) n_main; ++i) { load_block_trunk(i, trunk_flags); } for (int i = (int) n_main; i < n_layer; ++i) { load_block_mtp(i); } } std::unique_ptr llama_model_qwen35moe::build_arch_graph(const llm_graph_params & params) const { if (params.gtype == LLM_GRAPH_TYPE_DECODER_MTP) { return std::make_unique(*this, params); } return std::make_unique(*this, params); } llama_model_qwen35moe::graph::graph(const llama_model & model, const llm_graph_params & params) : llm_build_delta_net_base(params), model(model) { const int64_t n_embd_head = hparams.n_embd_head_v(); GGML_ASSERT(n_embd_head == hparams.n_embd_head_k()); int sections[4]; std::copy(std::begin(hparams.rope_sections), std::begin(hparams.rope_sections) + 4, sections); ggml_tensor * cur; ggml_tensor * inpL; inpL = build_inp_embd(model.tok_embd); cb(inpL, "model.input_embed", -1); auto * inp = build_inp_mem_hybrid(); ggml_tensor * inp_pos = build_inp_pos(); ggml_tensor * inp_out_ids = build_inp_out_ids(); // MTP/NextN layers are loaded as extra decoder blocks but not executed in the main pass. const int n_transformer_layers = n_layer - (int) hparams.nextn_predict_layers; for (int il = 0; il < n_transformer_layers; ++il) { ggml_tensor * inpSA = inpL; cur = build_norm(inpL, model.layers[il].attn_norm, nullptr, LLM_NORM_RMS, il); cb(cur, "attn_norm", il); ggml_build_forward_expand(gf, cur); // Determine layer type and build appropriate attention mechanism if (hparams.is_recurrent(il)) { // Linear attention layer (gated delta net) cur = build_layer_attn_linear(inp->get_recr(), cur, il); } else { // Full attention layer cur = build_layer_attn(inp->get_attn(), cur, inp_pos, sections, il); } if (il == n_transformer_layers - 1 && inp_out_ids && cparams.embeddings_pre_norm_masked) { cur = ggml_get_rows(ctx0, cur, inp_out_ids); inpSA = ggml_get_rows(ctx0, inpSA, inp_out_ids); } // Residual connection cur = ggml_add(ctx0, cur, inpSA); cb(cur, "attn_residual", il); // Save the tensor before post-attention norm for residual connection ggml_tensor * ffn_residual = cur; // Post-attention norm ggml_tensor * attn_post_norm = build_norm(cur, model.layers[il].attn_post_norm, nullptr, LLM_NORM_RMS, il); cb(attn_post_norm, "attn_post_norm", il); // MOE FFN layer cur = build_layer_ffn(attn_post_norm, il); cb(cur, "ffn_out", il); // Residual connection for FFN - add to the tensor from before post_attention_layernorm cur = ggml_add(ctx0, cur, ffn_residual); cb(cur, "post_moe", il); cur = build_cvec(cur, il); cb(cur, "l_out", il); // Input for next layer inpL = cur; } cur = inpL; cb(cur, "h_pre_norm", -1); res->t_h_pre_norm = cur; if (!cparams.embeddings_pre_norm_masked && inp_out_ids) { cur = ggml_get_rows(ctx0, cur, inp_out_ids); } // Final norm cur = build_norm(cur, model.output_norm, nullptr, LLM_NORM_RMS, -1); cb(cur, "result_norm", -1); res->t_embd = cur; // LM head cur = build_lora_mm(model.output, cur, model.output_s); cb(cur, "result_output", -1); res->t_logits = cur; ggml_build_forward_expand(gf, cur); } std::pair llama_model_qwen35moe::graph::build_qkvz( ggml_tensor * input, int il) { const int64_t n_seqs = ubatch.n_seqs; const int64_t n_seq_tokens = ubatch.n_seq_tokens; ggml_tensor * qkv_mixed = build_lora_mm(model.layers[il].wqkv, input, model.layers[il].wqkv_s); qkv_mixed = ggml_reshape_3d(ctx0, qkv_mixed, qkv_mixed->ne[0], n_seq_tokens, n_seqs); cb(qkv_mixed, "linear_attn_qkv_mixed", il); ggml_tensor * z = build_lora_mm(model.layers[il].wqkv_gate, input, model.layers[il].wqkv_gate_s); cb(z, "z", il); return { qkv_mixed, z }; } ggml_tensor * llama_model_qwen35moe::graph::build_norm_gated( ggml_tensor * input, ggml_tensor * weights, ggml_tensor * gate, int layer) { ggml_tensor * normalized = build_norm(input, weights, nullptr, LLM_NORM_RMS, layer); ggml_tensor * gated_silu = ggml_silu(ctx0, gate); return ggml_mul(ctx0, normalized, gated_silu); } ggml_tensor * llama_model_qwen35moe::graph::build_layer_attn( llm_graph_input_attn_kv * inp, ggml_tensor * cur, ggml_tensor * inp_pos, int * sections, int il) { const int64_t n_embd_head = hparams.n_embd_head_v(); GGML_ASSERT(n_embd_head == hparams.n_embd_head_k()); // Order: joint QG projection, QG split, Q norm, KV projection, K norm, RoPE, attention // Qwen3Next uses a single Q projection that outputs query + gate ggml_tensor * Qcur_full = build_lora_mm(model.layers[il].wq, cur, model.layers[il].wq_s); // [ (n_embd_head * 2) * n_head, n_tokens ] cb(Qcur_full, "Qcur_full", il); ggml_tensor * Qcur = ggml_view_3d(ctx0, Qcur_full, n_embd_head, n_head, n_tokens, ggml_element_size(Qcur_full) * n_embd_head * 2, ggml_element_size(Qcur_full) * n_embd_head * 2 * n_head, 0); cb(Qcur, "Qcur_reshaped", il); // Apply Q normalization Qcur = build_norm(Qcur, model.layers[il].attn_q_norm, nullptr, LLM_NORM_RMS, il); cb(Qcur, "Qcur_normed", il); ggml_tensor * Kcur = build_lora_mm(model.layers[il].wk, cur, model.layers[il].wk_s); cb(Kcur, "Kcur", il); ggml_tensor * Vcur = build_lora_mm(model.layers[il].wv, cur, model.layers[il].wv_s); cb(Vcur, "Vcur", il); // Apply K normalization Kcur = ggml_reshape_3d(ctx0, Kcur, n_embd_head, n_head_kv, n_tokens); Kcur = build_norm(Kcur, model.layers[il].attn_k_norm, nullptr, LLM_NORM_RMS, il); cb(Kcur, "Kcur_normed", il); ggml_tensor * gate = ggml_view_3d(ctx0, Qcur_full, n_embd_head, n_head, n_tokens, ggml_element_size(Qcur_full) * n_embd_head * 2, ggml_element_size(Qcur_full) * n_embd_head * 2 * n_head, ggml_element_size(Qcur_full) * n_embd_head); gate = ggml_cont_2d(ctx0, gate, n_embd_head * n_head, n_tokens); cb(gate, "gate_reshaped", il); Vcur = ggml_reshape_3d(ctx0, Vcur, n_embd_head, n_head_kv, n_tokens); // Apply IMRoPE Qcur = ggml_rope_multi( ctx0, Qcur, inp_pos, nullptr, n_rot, sections, rope_type, n_ctx_orig, freq_base, freq_scale, ext_factor, attn_factor, beta_fast, beta_slow ); Kcur = ggml_rope_multi( ctx0, Kcur, inp_pos, nullptr, n_rot, sections, rope_type, n_ctx_orig, freq_base, freq_scale, ext_factor, attn_factor, beta_fast, beta_slow ); cb(Qcur, "Qcur", il); cb(Kcur, "Kcur", il); cb(Vcur, "Vcur", il); // Attention computation const float kq_scale = hparams.f_attention_scale == 0.0f ? 1.0f / sqrtf(float(n_embd_head)) : hparams.f_attention_scale; cur = build_attn(inp, nullptr, nullptr, nullptr, Qcur, Kcur, Vcur, nullptr, nullptr, nullptr, kq_scale, il); cb(cur, "attn_pregate", il); ggml_tensor * gate_sigmoid = ggml_sigmoid(ctx0, gate); cb(gate_sigmoid, "gate_sigmoid", il); cur = ggml_mul(ctx0, cur, gate_sigmoid); cb(cur, "attn_gated", il); cur = build_lora_mm(model.layers[il].wo, cur, model.layers[il].wo_s); cb(cur, "attn_output", il); return cur; } ggml_tensor * llama_model_qwen35moe::graph::build_layer_attn_linear( llm_graph_input_rs * inp, ggml_tensor * cur, int il) { const auto * mctx_cur = inp->mctx; const int64_t d_inner = hparams.ssm_d_inner; const int64_t n_seqs = ubatch.n_seqs; const int64_t head_k_dim = hparams.ssm_d_state; const int64_t num_k_heads = hparams.ssm_n_group; const int64_t num_v_heads = hparams.ssm_dt_rank; const int64_t head_v_dim = d_inner / num_v_heads; const int64_t n_seq_tokens = ubatch.n_seq_tokens; GGML_ASSERT(n_seqs != 0); GGML_ASSERT(ubatch.equal_seqs()); GGML_ASSERT(ubatch.n_tokens == n_seq_tokens * n_seqs); // Input projections auto qkvz = build_qkvz(cur, il); ggml_tensor * qkv_mixed = qkvz.first; ggml_tensor * z = qkvz.second; ggml_tensor * beta = build_lora_mm(model.layers[il].ssm_beta, cur, model.layers[il].ssm_beta_s); beta = ggml_reshape_4d(ctx0, beta, 1, num_v_heads, n_seq_tokens, n_seqs); cb(beta, "beta", il); beta = ggml_sigmoid(ctx0, beta); cb(beta, "beta_sigmoid", il); ggml_tensor * alpha = build_lora_mm(model.layers[il].ssm_alpha, cur, model.layers[il].ssm_alpha_s); alpha = ggml_reshape_3d(ctx0, alpha, num_v_heads, n_seq_tokens, n_seqs); cb(alpha, "alpha", il); ggml_tensor * alpha_biased = ggml_add(ctx0, alpha, model.layers[il].ssm_dt); ggml_tensor * alpha_softplus = ggml_softplus(ctx0, alpha_biased); cb(alpha_softplus, "a_softplus", il); ggml_tensor * gate = ggml_mul(ctx0, alpha_softplus, model.layers[il].ssm_a); // -A_log.exp() * softplus cb(gate, "gate", il); gate = ggml_reshape_4d(ctx0, gate, 1, num_v_heads, n_seq_tokens, n_seqs); ggml_tensor * conv_states_all = mctx_cur->get_r_l(il); ggml_tensor * ssm_states_all = mctx_cur->get_s_l(il); ggml_tensor * conv_kernel = model.layers[il].ssm_conv1d; const int64_t conv_kernel_size = conv_kernel->ne[0]; const int64_t conv_channels = d_inner + 2 * hparams.ssm_n_group * hparams.ssm_d_state; ggml_tensor * conv_input = build_conv_state(inp, conv_states_all, qkv_mixed, conv_kernel_size, conv_channels, il); ggml_tensor * state = build_rs(inp, ssm_states_all, hparams.n_embd_s(), n_seqs); state = ggml_reshape_4d(ctx0, state, head_v_dim, head_v_dim, num_v_heads, n_seqs); cb(state, "state_predelta", il); ggml_tensor * conv_output_proper = ggml_ssm_conv(ctx0, conv_input, conv_kernel); cb(conv_output_proper, "conv_output_raw", il); ggml_tensor * conv_output_silu = ggml_silu(ctx0, conv_output_proper); cb(conv_output_silu, "conv_output_silu", il); ggml_tensor * conv_qkv_mix = conv_output_silu; // Calculate the total conv dimension int64_t qkv_dim = head_k_dim * num_k_heads * 2 + head_v_dim * num_v_heads; int64_t nb1_qkv = ggml_row_size(conv_qkv_mix->type, qkv_dim); // Extract the convolved Q, K, V from conv_output ggml_tensor * q_conv = ggml_view_4d(ctx0, conv_qkv_mix, head_k_dim, num_k_heads, n_seq_tokens, n_seqs, ggml_row_size(conv_qkv_mix->type, head_k_dim), nb1_qkv, nb1_qkv * n_seq_tokens, 0); ggml_tensor * k_conv = ggml_view_4d(ctx0, conv_qkv_mix, head_k_dim, num_k_heads, n_seq_tokens, n_seqs, ggml_row_size(conv_qkv_mix->type, head_k_dim), nb1_qkv, nb1_qkv * n_seq_tokens, head_k_dim * num_k_heads * ggml_element_size(conv_qkv_mix)); ggml_tensor * v_conv = ggml_view_4d(ctx0, conv_qkv_mix, head_v_dim, num_v_heads, n_seq_tokens, n_seqs, ggml_row_size(conv_qkv_mix->type, head_v_dim), nb1_qkv, nb1_qkv * n_seq_tokens, ggml_row_size(conv_qkv_mix->type, 2 * head_k_dim * num_k_heads)); cb(q_conv, "q_conv", il); cb(k_conv, "k_conv", il); cb(v_conv, "v_conv", il); const float eps_norm = hparams.f_norm_rms_eps; q_conv = ggml_l2_norm(ctx0, q_conv, eps_norm); k_conv = ggml_l2_norm(ctx0, k_conv, eps_norm); //q_conv = ggml_cont_4d(ctx0, q_conv, head_k_dim, num_k_heads, n_seq_tokens, n_seqs); //k_conv = ggml_cont_4d(ctx0, k_conv, head_k_dim, num_k_heads, n_seq_tokens, n_seqs); //v_conv = ggml_cont_4d(ctx0, v_conv, head_v_dim, num_v_heads, n_seq_tokens, n_seqs); // if head keys and value keys are different, repeat to force tensors into matching shapes // note: need explicit repeat only if we are not using the fused GDN. if (num_k_heads != num_v_heads && (!cparams.fused_gdn_ar || !cparams.fused_gdn_ch)) { GGML_ASSERT(num_v_heads % num_k_heads == 0); q_conv = ggml_repeat_4d(ctx0, q_conv, head_k_dim, num_v_heads, n_seq_tokens, n_seqs); k_conv = ggml_repeat_4d(ctx0, k_conv, head_k_dim, num_v_heads, n_seq_tokens, n_seqs); } cb(q_conv, "q_conv_predelta", il); cb(k_conv, "k_conv_predelta", il); cb(v_conv, "v_conv_predelta", il); ggml_tensor * output = build_recurrent_attn(inp, ssm_states_all, q_conv, k_conv, v_conv, gate, beta, state, il); // z: [head_dim, n_heads, n_tokens, n_seqs] -> [n_heads * n_tokens * n_seqs, head_dim] ggml_tensor * z_2d = ggml_reshape_4d(ctx0, z, head_v_dim, num_v_heads, n_seq_tokens, n_seqs); // Apply gated normalization: self.norm(core_attn_out, z) ggml_tensor * attn_out_norm = build_norm_gated(output, model.layers[il].ssm_norm, z_2d, il); // Final reshape: [head_dim, n_heads, n_tokens, n_seqs] -> [n_tokens, n_seqs, n_heads * head_dim] ggml_tensor * final_output = ggml_reshape_3d(ctx0, attn_out_norm, head_v_dim * num_v_heads, n_seq_tokens, n_seqs); cb(final_output, "final_output", il); // Output projection cur = build_lora_mm(model.layers[il].ssm_out, final_output, model.layers[il].ssm_out_s); cb(cur, "linear_attn_out", il); // Reshape back to original dimensions cur = ggml_reshape_2d(ctx0, cur, n_embd, n_seq_tokens * n_seqs); return cur; } ggml_tensor * llama_model_qwen35moe::graph::build_layer_ffn(ggml_tensor * cur, const int il) { // Check if this is an MoE layer GGML_ASSERT(model.layers[il].ffn_gate_inp != nullptr); ggml_tensor * moe_out = build_moe_ffn(cur, model.layers[il].ffn_gate_inp, model.layers[il].ffn_up_exps, model.layers[il].ffn_gate_exps, model.layers[il].ffn_down_exps, nullptr, n_expert, n_expert_used, LLM_FFN_SILU, true, hparams.expert_weights_scale, LLAMA_EXPERT_GATING_FUNC_TYPE_SOFTMAX, il, nullptr, model.layers[il].ffn_gate_up_exps, model.layers[il].ffn_up_exps_s, model.layers[il].ffn_gate_exps_s, model.layers[il].ffn_down_exps_s); cb(moe_out, "ffn_moe_out", il); // Add shared experts if present - following Qwen3Next reference implementation if (model.layers[il].ffn_up_shexp != nullptr) { ggml_tensor * ffn_shexp = build_ffn(cur, model.layers[il].ffn_up_shexp, NULL, model.layers[il].ffn_up_shexp_s, model.layers[il].ffn_gate_shexp, NULL, model.layers[il].ffn_gate_shexp_s, model.layers[il].ffn_down_shexp, NULL, model.layers[il].ffn_down_shexp_s, NULL, LLM_FFN_SILU, LLM_FFN_PAR, il); cb(ffn_shexp, "ffn_shexp", il); // Apply shared expert gating as in the reference implementation // The shared expert has its own gate that is sigmoided // Note: ffn_gate_inp_shexp is the shared expert gate (outputs 1 value per token) ggml_tensor * shared_gate = build_lora_mm(model.layers[il].ffn_gate_inp_shexp, cur); cb(shared_gate, "shared_expert_gate", il); // Apply sigmoid to the gate shared_gate = ggml_sigmoid(ctx0, shared_gate); cb(shared_gate, "shared_expert_gate_sigmoid", il); // Apply the gate to the shared expert output ffn_shexp = ggml_mul(ctx0, ffn_shexp, shared_gate); cb(ffn_shexp, "ffn_shexp_gated", il); cur = ggml_add(ctx0, moe_out, ffn_shexp); cb(cur, "ffn_out", il); } else { cur = moe_out; } return cur; } // LLM_GRAPH_TYPE_DECODER_MTP draft head for Qwen3.5/3.6 MoE llama_model_qwen35moe::graph_mtp::graph_mtp(const llama_model & model, const llm_graph_params & params) : llm_graph_context(params) { GGML_ASSERT(hparams.nextn_predict_layers > 0 && "QWEN35MOE MTP requires nextn_predict_layers > 0"); GGML_ASSERT(hparams.nextn_predict_layers == 1 && "QWEN35MOE MTP currently only supports a single MTP block"); const int64_t n_embd_head = hparams.n_embd_head_v(); GGML_ASSERT(n_embd_head == hparams.n_embd_head_k()); const int il = (int) hparams.n_layer - (int) hparams.nextn_predict_layers; const auto & layer = model.layers[il]; GGML_ASSERT(layer.nextn.eh_proj && "MTP block missing nextn.eh_proj"); GGML_ASSERT(layer.nextn.enorm && "MTP block missing nextn.enorm"); GGML_ASSERT(layer.nextn.hnorm && "MTP block missing nextn.hnorm"); GGML_ASSERT(layer.ffn_gate_inp && "MTP block missing ffn_gate_inp"); int sections[4]; std::copy(std::begin(hparams.rope_sections), std::begin(hparams.rope_sections) + 4, sections); auto inp = std::make_unique(hparams.n_embd); inp->tokens = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, n_tokens); ggml_set_input(inp->tokens); inp->embd = ggml_new_tensor_2d(ctx0, GGML_TYPE_F32, hparams.n_embd, n_tokens); ggml_set_input(inp->embd); ggml_set_name(inp->embd, "mtp_h_input"); ggml_tensor * tok_embd_w = layer.nextn.embed_tokens ? layer.nextn.embed_tokens : model.tok_embd; ggml_tensor * h_input = inp->embd; ggml_tensor * tok_embd = ggml_get_rows(ctx0, tok_embd_w, inp->tokens); cb(tok_embd, "mtp_tok_embd", il); res->add_input(std::move(inp)); ggml_tensor * inp_pos = build_inp_pos(); ggml_tensor * inp_out_ids = build_inp_out_ids(); auto * inp_attn = build_attn_inp_kv(); ggml_tensor * h_norm = build_norm(h_input, layer.nextn.hnorm, nullptr, LLM_NORM_RMS, il); cb(h_norm, "mtp_hnorm", il); ggml_tensor * e_norm = build_norm(tok_embd, layer.nextn.enorm, nullptr, LLM_NORM_RMS, il); cb(e_norm, "mtp_enorm", il); ggml_tensor * concat = ggml_concat(ctx0, e_norm, h_norm, /*dim=*/ 0); cb(concat, "mtp_concat", il); ggml_tensor * cur = build_lora_mm(layer.nextn.eh_proj, concat, layer.nextn.eh_proj_s); cb(cur, "mtp_eh_proj", il); ggml_tensor * inpSA = cur; cur = build_norm(cur, layer.attn_norm, nullptr, LLM_NORM_RMS, il); cb(cur, "mtp_attn_norm", il); ggml_tensor * Qcur_full = build_lora_mm(layer.wq, cur, layer.wq_s); cb(Qcur_full, "mtp_Qcur_full", il); ggml_tensor * Qcur = ggml_view_3d(ctx0, Qcur_full, n_embd_head, n_head, n_tokens, ggml_element_size(Qcur_full) * n_embd_head * 2, ggml_element_size(Qcur_full) * n_embd_head * 2 * n_head, 0); Qcur = build_norm(Qcur, layer.attn_q_norm, nullptr, LLM_NORM_RMS, il); cb(Qcur, "mtp_Qcur_normed", il); ggml_tensor * gate = ggml_view_3d(ctx0, Qcur_full, n_embd_head, n_head, n_tokens, ggml_element_size(Qcur_full) * n_embd_head * 2, ggml_element_size(Qcur_full) * n_embd_head * 2 * n_head, ggml_element_size(Qcur_full) * n_embd_head); gate = ggml_cont_2d(ctx0, gate, n_embd_head * n_head, n_tokens); cb(gate, "mtp_gate", il); ggml_tensor * Kcur = build_lora_mm(layer.wk, cur, layer.wk_s); Kcur = ggml_reshape_3d(ctx0, Kcur, n_embd_head, n_head_kv, n_tokens); Kcur = build_norm(Kcur, layer.attn_k_norm, nullptr, LLM_NORM_RMS, il); cb(Kcur, "mtp_Kcur_normed", il); ggml_tensor * Vcur = build_lora_mm(layer.wv, cur, layer.wv_s); Vcur = ggml_reshape_3d(ctx0, Vcur, n_embd_head, n_head_kv, n_tokens); cb(Vcur, "mtp_Vcur", il); Qcur = ggml_rope_multi(ctx0, Qcur, inp_pos, nullptr, n_rot, sections, rope_type, n_ctx_orig, freq_base, freq_scale, ext_factor, attn_factor, beta_fast, beta_slow); Kcur = ggml_rope_multi(ctx0, Kcur, inp_pos, nullptr, n_rot, sections, rope_type, n_ctx_orig, freq_base, freq_scale, ext_factor, attn_factor, beta_fast, beta_slow); const float kq_scale = hparams.f_attention_scale == 0.0f ? 1.0f / sqrtf(float(n_embd_head)) : hparams.f_attention_scale; cur = build_attn(inp_attn, nullptr, nullptr, nullptr, Qcur, Kcur, Vcur, nullptr, nullptr, nullptr, kq_scale, il); cb(cur, "mtp_attn_pregate", il); cur = ggml_mul(ctx0, cur, ggml_sigmoid(ctx0, gate)); cur = build_lora_mm(layer.wo, cur, layer.wo_s); cb(cur, "mtp_attn_out", il); cur = ggml_add(ctx0, cur, inpSA); cb(cur, "mtp_attn_residual", il); ggml_tensor * ffn_residual = cur; cur = build_norm(cur, layer.attn_post_norm, nullptr, LLM_NORM_RMS, il); cb(cur, "mtp_attn_post_norm", il); // MoE FFN — routed experts plus gated shared expert (mirrors qwen35moe). ggml_tensor * moe_out = build_moe_ffn(cur, layer.ffn_gate_inp, layer.ffn_up_exps, layer.ffn_gate_exps, layer.ffn_down_exps, nullptr, n_expert, n_expert_used, LLM_FFN_SILU, true, hparams.expert_weights_scale, LLAMA_EXPERT_GATING_FUNC_TYPE_SOFTMAX, il, nullptr, layer.ffn_gate_up_exps, layer.ffn_up_exps_s, layer.ffn_gate_exps_s, layer.ffn_down_exps_s); cb(moe_out, "mtp_ffn_moe_out", il); if (layer.ffn_up_shexp != nullptr) { ggml_tensor * ffn_shexp = build_ffn(cur, layer.ffn_up_shexp, nullptr, layer.ffn_up_shexp_s, layer.ffn_gate_shexp, nullptr, layer.ffn_gate_shexp_s, layer.ffn_down_shexp, nullptr, layer.ffn_down_shexp_s, nullptr, LLM_FFN_SILU, LLM_FFN_PAR, il); cb(ffn_shexp, "mtp_ffn_shexp", il); ggml_tensor * shared_gate = build_lora_mm(layer.ffn_gate_inp_shexp, cur); shared_gate = ggml_sigmoid(ctx0, shared_gate); cb(shared_gate, "mtp_shared_expert_gate_sigmoid", il); ffn_shexp = ggml_mul(ctx0, ffn_shexp, shared_gate); cb(ffn_shexp, "mtp_ffn_shexp_gated", il); cur = ggml_add(ctx0, moe_out, ffn_shexp); } else { cur = moe_out; } cb(cur, "mtp_ffn_out", il); cur = ggml_add(ctx0, cur, ffn_residual); cb(cur, "mtp_post_ffn", il); // Pre-norm hidden state: used by the AR draft loop to seed the next MTP step. cb(cur, "h_pre_norm", -1); res->t_h_pre_norm = cur; cur = ggml_get_rows(ctx0, cur, inp_out_ids); ggml_tensor * head_norm_w = layer.nextn.shared_head_norm ? layer.nextn.shared_head_norm : model.output_norm; GGML_ASSERT(head_norm_w && "QWEN35MOE MTP: missing both nextn.shared_head_norm and output_norm"); cur = build_norm(cur, head_norm_w, nullptr, LLM_NORM_RMS, -1); cb(cur, "mtp_shared_head_norm", -1); ggml_tensor * head_w = layer.nextn.shared_head_head ? layer.nextn.shared_head_head : model.output; ggml_tensor * head_s = layer.nextn.shared_head_head ? layer.nextn.shared_head_head_s : model.output_s; GGML_ASSERT(head_w && "QWEN35MOE MTP: missing LM head (nextn.shared_head_head or model.output)"); cur = build_lora_mm(head_w, cur, head_s); cb(cur, "result_output", -1); res->t_logits = cur; ggml_build_forward_expand(gf, cur); }