#pragma once #include "llama-arch.h" #include "llama-batch.h" #include "llama-hparams.h" #include "llama-adapter.h" #include #include #include #include #include #include struct ggml_cgraph; struct ggml_context; struct ggml_tensor; struct llama_cparams; struct llama_memory_context_i; class llama_kv_cache_context; class llama_kv_cache_iswa_context; class llama_memory_recurrent_context; class llama_memory_hybrid_context; class llama_memory_hybrid_iswa_context; // certain models (typically multi-modal) can produce different types of graphs enum llm_graph_type { LLM_GRAPH_TYPE_DEFAULT, LLM_GRAPH_TYPE_ENCODER, LLM_GRAPH_TYPE_DECODER, }; enum llm_ffn_op_type { LLM_FFN_SILU, LLM_FFN_GELU, LLM_FFN_RELU, LLM_FFN_RELU_SQR, LLM_FFN_SWIGLU, LLM_FFN_GEGLU, LLM_FFN_REGLU, LLM_FFN_SWIGLU_OAI_MOE, }; enum llm_ffn_gate_type { LLM_FFN_SEQ, LLM_FFN_PAR, // ffn_gate is parallel to ffn_up }; enum llm_norm_type { LLM_NORM, LLM_NORM_RMS, LLM_NORM_GROUP, }; // TODO: tmp - need something better to pass the data from the encoder to the decoder struct llama_cross { // the output embeddings from the encoder as a ggml tensor // TODO: this needs more work to be correct, for now copy the embeddings data to host memory // ref: https://github.com/ggml-org/llama.cpp/pull/11213#discussion_r1969892524 //ggml_tensor * t_embd = nullptr; int64_t n_embd = 0; int64_t n_enc = 0; // embeddings data copied to host memory (tmp) std::vector v_embd; // needed to construct the cross-attention mask in the decoder std::vector> seq_ids_enc; }; struct llm_graph_params; // // llm_graph_input // class llm_graph_input_i { public: llm_graph_input_i() { const char * LLAMA_GRAPH_INPUT_DEBUG = getenv("LLAMA_GRAPH_INPUT_DEBUG"); debug = LLAMA_GRAPH_INPUT_DEBUG ? atoi(LLAMA_GRAPH_INPUT_DEBUG) : 0; } virtual ~llm_graph_input_i() = default; virtual void set_input(const llama_ubatch * ubatch) = 0; // return true if the resulting input tensors using the provided graph parameters would be // the same as the previous input tensors that we have currently stored in the object virtual bool can_reuse(const llm_graph_params & params) { // returning false here by default will prevent from reusing the graph if the check // for the input type has not been implemented yet GGML_UNUSED(params); return false; } protected: // env: LLAMA_GRAPH_INPUT_DEBUG int debug = 0; }; using llm_graph_input_ptr = std::unique_ptr; class llm_graph_input_embd : public llm_graph_input_i { public: llm_graph_input_embd(int64_t n_embd) : n_embd(n_embd) {} virtual ~llm_graph_input_embd() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; ggml_tensor * tokens = nullptr; // I32 [n_batch] ggml_tensor * embd = nullptr; // F32 [n_embd, n_batch] const int64_t n_embd = 0; }; class llm_graph_input_pos : public llm_graph_input_i { public: llm_graph_input_pos(uint32_t n_pos_per_embd) : n_pos_per_embd(n_pos_per_embd) {} virtual ~llm_graph_input_pos() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; ggml_tensor * pos = nullptr; // I32 [n_batch] const uint32_t n_pos_per_embd = 1; }; // temperature tuning, used by llama4 class llm_graph_input_attn_temp : public llm_graph_input_i { public: llm_graph_input_attn_temp(uint32_t n_attn_temp_floor_scale, float f_attn_temp_scale, float f_attn_temp_offset) : n_attn_temp_floor_scale(n_attn_temp_floor_scale), f_attn_temp_scale(f_attn_temp_scale), f_attn_temp_offset(f_attn_temp_offset) {} virtual ~llm_graph_input_attn_temp() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * attn_scale = nullptr; // F32 [n_batch] const uint32_t n_attn_temp_floor_scale; const float f_attn_temp_scale; const float f_attn_temp_offset; }; class llm_graph_input_pos_bucket : public llm_graph_input_i { public: llm_graph_input_pos_bucket(const llama_hparams & hparams) : hparams(hparams) {} virtual ~llm_graph_input_pos_bucket() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * pos_bucket = nullptr; // I32 [n_batch, n_batch] const llama_hparams hparams; }; class llm_graph_input_pos_bucket_kv : public llm_graph_input_i { public: llm_graph_input_pos_bucket_kv( const llama_hparams & hparams, const llama_kv_cache_context * mctx) : hparams(hparams), mctx(mctx) {} virtual ~llm_graph_input_pos_bucket_kv() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * pos_bucket = nullptr; // I32 [n_kv, n_batch] const llama_hparams hparams; const llama_kv_cache_context * mctx; }; class llm_graph_input_out_ids : public llm_graph_input_i { public: llm_graph_input_out_ids( const llama_hparams & hparams, const llama_cparams & cparams, uint32_t n_outputs) : hparams(hparams), cparams(cparams), n_outputs(n_outputs) {} virtual ~llm_graph_input_out_ids() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; ggml_tensor * out_ids; // I32 [n_outputs] const llama_hparams hparams; const llama_cparams cparams; const uint32_t n_outputs; }; class llm_graph_input_mean : public llm_graph_input_i { public: llm_graph_input_mean(const llama_cparams & cparams) : cparams(cparams) {} virtual ~llm_graph_input_mean() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * mean; // F32 [n_batch, n_batch] const llama_cparams cparams; }; class llm_graph_input_cls : public llm_graph_input_i { public: llm_graph_input_cls(const llama_cparams & cparams, const llm_arch arch) : cparams(cparams), arch(arch) {} virtual ~llm_graph_input_cls() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * cls; // I32 [n_batch] const llama_cparams cparams; const llm_arch arch; }; class llm_graph_input_rs : public llm_graph_input_i { public: llm_graph_input_rs(const llama_memory_recurrent_context * mctx) : mctx(mctx) {} virtual ~llm_graph_input_rs() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; ggml_tensor * s_copy; // I32 [n_rs] // views of s_copy, computed once per graph // and shared across layers which use build_rs ggml_tensor * s_copy_main; // I32 [n_seqs] ggml_tensor * s_copy_extra; // I32 [n_rs - n_seqs] const llama_memory_recurrent_context * mctx; // used in view offsets, need to match for valid graph reuse uint32_t head; int32_t rs_z; }; class llm_graph_input_cross_embd : public llm_graph_input_i { public: llm_graph_input_cross_embd( const llama_cross * cross) : cross(cross) {} virtual ~llm_graph_input_cross_embd() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * cross_embd; // F32 [n_embd, n_outputs_enc] const llama_cross * cross; }; class llm_graph_input_attn_no_cache : public llm_graph_input_i { public: llm_graph_input_attn_no_cache(const llama_hparams & hparams, const llama_cparams & cparams) : hparams(hparams), cparams(cparams) { } ~llm_graph_input_attn_no_cache() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * get_kq_mask() const { return self_kq_mask_cnv; } ggml_tensor * get_kq_mask_swa() const { return self_kq_mask_swa_cnv; } // n_tokens == n_batch ggml_tensor * self_kq_mask = nullptr; // F32 [n_tokens, n_batch/n_stream, 1, n_stream] ggml_tensor * self_kq_mask_cnv = nullptr; // [n_tokens, n_batch/n_stream, 1, n_stream] ggml_tensor * self_kq_mask_swa = nullptr; // F32 [n_tokens, n_batch/n_stream, 1, n_stream] ggml_tensor * self_kq_mask_swa_cnv = nullptr; // [n_tokens, n_batch/n_stream, 1, n_stream] const llama_hparams hparams; const llama_cparams cparams; }; class llm_graph_input_attn_kv : public llm_graph_input_i { public: llm_graph_input_attn_kv( const llama_hparams & hparams, const llama_cparams & cparams, const llama_kv_cache_context * mctx) : hparams(hparams), cparams(cparams), mctx(mctx) { } ~llm_graph_input_attn_kv() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; ggml_tensor * get_k_idxs() const { return self_k_idxs; } ggml_tensor * get_v_idxs() const { return self_v_idxs; } ggml_tensor * get_kq_mask() const { return self_kq_mask_cnv; } ggml_tensor * self_k_idxs = nullptr; // I64 [n_batch] ggml_tensor * self_v_idxs = nullptr; // I64 [n_batch] or [n_batch*n_embd_v_gqa] ggml_tensor * self_kq_mask = nullptr; // F32 [n_kv, n_batch/n_stream, 1, n_stream] ggml_tensor * self_kq_mask_cnv = nullptr; // [n_kv, n_batch/n_stream, 1, n_stream] // note: assumes v_rot^ == I ggml_tensor * self_k_rot = nullptr; ggml_tensor * self_v_rot = nullptr; // note: these have to be copies because in order to be able to reuse a graph, its inputs // need to carry these parameters with them. otherwise, they can point to freed // llm_graph_params from a previous batch, causing stack-use-after-return const llama_hparams hparams; const llama_cparams cparams; const llama_kv_cache_context * mctx; }; // V-less input for the KV cache // ref: https://github.com/ggml-org/llama.cpp/pull/19067 class llm_graph_input_attn_k : public llm_graph_input_i { public: llm_graph_input_attn_k( const llama_hparams & hparams, const llama_cparams & cparams, const llama_kv_cache_context * mctx) : hparams(hparams), cparams(cparams), mctx(mctx) { } ~llm_graph_input_attn_k() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; ggml_tensor * get_k_idxs() const { return self_k_idxs; } ggml_tensor * get_kq_mask() const { return self_kq_mask_cnv; } ggml_tensor * self_k_idxs = nullptr; // I64 [n_batch] ggml_tensor * self_kq_mask = nullptr; // F32 [n_kv, n_batch/n_stream, 1, n_stream] ggml_tensor * self_kq_mask_cnv = nullptr; // [n_kv, n_batch/n_stream, 1, n_stream] const llama_hparams hparams; const llama_cparams cparams; const llama_kv_cache_context * mctx; }; class llm_graph_input_attn_kv_iswa : public llm_graph_input_i { public: llm_graph_input_attn_kv_iswa( const llama_hparams & hparams, const llama_cparams & cparams, const llama_kv_cache_iswa_context * mctx) : hparams(hparams), cparams(cparams), mctx(mctx) { } ~llm_graph_input_attn_kv_iswa() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; ggml_tensor * get_k_idxs() const { return self_k_idxs; } ggml_tensor * get_v_idxs() const { return self_v_idxs; } ggml_tensor * get_k_idxs_swa() const { return self_k_idxs_swa; } ggml_tensor * get_v_idxs_swa() const { return self_v_idxs_swa; } ggml_tensor * get_kq_mask() const { return self_kq_mask_cnv; } ggml_tensor * get_kq_mask_swa() const { return self_kq_mask_swa_cnv; } ggml_tensor * self_k_idxs = nullptr; // I64 [n_batch] ggml_tensor * self_v_idxs = nullptr; // I64 [n_batch] or [n_batch*n_embd_v_gqa] ggml_tensor * self_k_idxs_swa = nullptr; // I64 [n_batch] ggml_tensor * self_v_idxs_swa = nullptr; // I64 [n_batch] or [n_batch*n_embd_v_gqa] ggml_tensor * self_kq_mask = nullptr; // F32 [n_kv, n_batch/n_stream, 1, n_stream] ggml_tensor * self_kq_mask_cnv = nullptr; // [n_kv, n_batch/n_stream, 1, n_stream] ggml_tensor * self_kq_mask_swa = nullptr; // F32 [n_kv, n_batch/n_stream, 1, n_stream] ggml_tensor * self_kq_mask_swa_cnv = nullptr; // [n_kv, n_batch/n_stream, 1, n_stream] // note: using same rotation matrices for both base and swa cache ggml_tensor * self_k_rot = nullptr; ggml_tensor * self_v_rot = nullptr; const llama_hparams hparams; const llama_cparams cparams; const llama_kv_cache_iswa_context * mctx; }; class llm_graph_input_attn_cross : public llm_graph_input_i { public: llm_graph_input_attn_cross(const llama_cross * cross) : cross(cross) {} ~llm_graph_input_attn_cross() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * get_kq_mask_cross() const { return cross_kq_mask_cnv; } ggml_tensor * cross_kq_mask = nullptr; // F32 [n_outputs_enc, n_batch, 1, 1] ggml_tensor * cross_kq_mask_cnv = nullptr; // F32 [n_outputs_enc, n_batch, 1, 1] const llama_cross * cross = nullptr; }; class llm_graph_input_mem_hybrid : public llm_graph_input_i { public: llm_graph_input_mem_hybrid( const llama_cparams & cparams, std::unique_ptr inp_attn, std::unique_ptr inp_rs, const llama_memory_hybrid_context * mctx) : inp_attn(std::move(inp_attn)), inp_rs(std::move(inp_rs)), cparams(cparams), mctx(mctx) { } virtual ~llm_graph_input_mem_hybrid() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; std::unique_ptr inp_attn; std::unique_ptr inp_rs; llm_graph_input_attn_kv * get_attn() const { return inp_attn.get(); } llm_graph_input_rs * get_recr() const { return inp_rs.get(); } const llama_cparams cparams; const llama_memory_hybrid_context * mctx; }; class llm_graph_input_mem_hybrid_k : public llm_graph_input_i { public: llm_graph_input_mem_hybrid_k( const llama_cparams & cparams, std::unique_ptr inp_attn, std::unique_ptr inp_rs, const llama_memory_hybrid_context * mctx) : inp_attn(std::move(inp_attn)), inp_rs(std::move(inp_rs)), cparams(cparams), mctx(mctx) { } virtual ~llm_graph_input_mem_hybrid_k() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; std::unique_ptr inp_attn; std::unique_ptr inp_rs; llm_graph_input_attn_k * get_attn() const { return inp_attn.get(); } llm_graph_input_rs * get_recr() const { return inp_rs.get(); } const llama_cparams cparams; const llama_memory_hybrid_context * mctx; }; class llm_graph_input_mem_hybrid_iswa : public llm_graph_input_i { public: llm_graph_input_mem_hybrid_iswa( const llama_cparams & cparams, std::unique_ptr inp_attn, std::unique_ptr inp_rs, const llama_memory_hybrid_iswa_context * mctx) : inp_attn(std::move(inp_attn)), inp_rs(std::move(inp_rs)), cparams(cparams), mctx(mctx) { } virtual ~llm_graph_input_mem_hybrid_iswa() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; std::unique_ptr inp_attn; std::unique_ptr inp_rs; llm_graph_input_attn_kv_iswa * get_attn() const { return inp_attn.get(); } llm_graph_input_rs * get_recr() const { return inp_rs.get(); } const llama_cparams cparams; const llama_memory_hybrid_iswa_context * mctx; }; class llm_graph_input_sampling : public llm_graph_input_i { public: llm_graph_input_sampling(std::map samplers) : samplers(std::move(samplers)) { } virtual ~llm_graph_input_sampling() = default; void set_input(const llama_ubatch * ubatch) override; bool can_reuse(const llm_graph_params & params) override; std::map samplers; }; // // llm_graph_result // // these objects deliver the result from the graph build process back to the llama_context // note that the input tensors created for the graph are referenced here - the goal is to be able to populate their // specific data, by calling the set_inputs() method // along with the input tensors, the object also provides commonly used outputs tensors, such as logits, embeddings, etc. // these are used by the llama_context to extact the relevant data, based on the compute parameters // callback that allows us to apply custom logic to each tensor (e.g. ggml-alloc, offloading, etc.) using llm_graph_cb = std::function; class llm_graph_result; struct llm_graph_params { llm_arch arch = LLM_ARCH_UNKNOWN; llama_hparams hparams; llama_cparams cparams; llama_ubatch ubatch; // note: intentionally make a copy llm_graph_type gtype; ggml_backend_sched_t sched; ggml_backend_t backend_cpu; const llama_adapter_cvec * cvec; const llama_adapter_loras * loras; const llama_memory_context_i * mctx; const llama_cross * cross; std::map samplers; static bool samplers_equal( const std::map & lhs, const std::map & rhs) { if (lhs.size() != rhs.size()) { return false; } for (const auto & [seq_id, sampler] : lhs) { auto it = rhs.find(seq_id); if (it == rhs.end() || it->second != sampler) { return false; } } return true; } uint32_t n_outputs; llm_graph_cb cb; llm_graph_result * res; // return true if the "other" params would result in a graph with the same topology as with the current params // having the same topology allows us to reuse the graph in some cases bool allow_reuse(const llm_graph_params & other) const { // first check the ubatch bool can_reuse_ubatch = ubatch.equal_seqs() == other.ubatch.equal_seqs() && ubatch.n_tokens == other.ubatch.n_tokens && ubatch.n_seq_tokens == other.ubatch.n_seq_tokens && ubatch.n_seqs == other.ubatch.n_seqs && ubatch.n_seqs_unq == other.ubatch.n_seqs_unq && ( (!ubatch.token && !other.ubatch.token) || (!ubatch.embd && !other.ubatch.embd) ); // when we split the batch using "equal_seqs" we have to verify that the participating sequences are the same // the reason is because the set of attention streams would be different for different sequences if (can_reuse_ubatch && ubatch.equal_seqs()) { if (!ubatch.data) { // if the old ubatch does not own it's data, then we cannot guarantee that it is still alive, and // therefore we cannot perform the sequence id check. normally should never happen can_reuse_ubatch = false; } else { for (uint32_t s = 0; s < ubatch.n_seqs_unq; ++s) { can_reuse_ubatch &= ubatch.seq_id_unq[s] == other.ubatch.seq_id_unq[s]; } } } if (!can_reuse_ubatch) { return false; } if (n_outputs != other.n_outputs) { return false; } if (!samplers_equal(samplers, other.samplers)) { return false; } if (samplers.size() > 0) { if (!ubatch.data || !other.ubatch.data) { return false; } // check that the outputs are the same for all samplers for (uint32_t i = 0; i < ubatch.n_tokens; ++i) { if (ubatch.output[i] != other.ubatch.output[i] || ubatch.seq_id[i][0] != other.ubatch.seq_id[i][0]) { return false; } } } return cparams.embeddings == other.cparams.embeddings && cparams.causal_attn == other.cparams.causal_attn && arch == other.arch && gtype == other.gtype && cvec == other.cvec && loras == other.loras && cross == other.cross; } }; class llm_graph_result { public: llm_graph_result(int64_t max_nodes); virtual ~llm_graph_result() = default; ggml_tensor * get_inp_tokens() const { return t_inp_tokens; } ggml_tensor * get_logits() const { return t_logits; } ggml_tensor * get_embd() const { return t_embd; } ggml_tensor * get_embd_pooled() const { return t_embd_pooled; } ggml_cgraph * get_gf() const { return gf; } ggml_context * get_ctx() const { return ctx_compute.get(); } int64_t get_max_nodes() const; void reset(); void set_inputs(const llama_ubatch * ubatch); void set_outputs(); // try to update the existing graph result using the new graph parameters in order to reuse it // this can only be done if we determine that the resulting graph using the new graph parameters // would be identical to the existing graph. in that case, we simply have to update the memory // contexts of the input tensors of the graph and we can reuse it for another computation // return true if the graph was updated and can be reused bool can_reuse(const llm_graph_params & params); llm_graph_input_i * add_input(llm_graph_input_ptr input); void set_params(const llm_graph_params & params); // important graph nodes ggml_tensor * t_inp_tokens = nullptr; ggml_tensor * t_inp_embd = nullptr; // [n_embd_inp, n_tokens] ggml_tensor * t_logits = nullptr; ggml_tensor * t_embd = nullptr; ggml_tensor * t_embd_pooled = nullptr; std::map t_sampled_logits; std::map t_candidates; std::map t_sampled; std::map t_sampled_probs; std::vector inputs; ggml_context_ptr ctx_compute; // memory buffers used to evaluate the model std::vector buf_compute_meta; ggml_cgraph * gf; int64_t max_nodes; private: // keep a copy of the previous graph parameters // we will use this to determine whether the graph can be reused by comparing them with the new parameters // note: these are updated after constructing the new graph llm_graph_params params; // env: LLAMA_GRAPH_RESULT_DEBUG int debug = 0; }; using llm_graph_result_ptr = std::unique_ptr; // // llm_graph_context // // used in build_rs to properly order writes and avoid unnecessary copies using llm_graph_get_rows_fn = std::function; struct llm_graph_context { const llm_arch arch; const llama_hparams & hparams; const llama_cparams & cparams; const llama_ubatch & ubatch; const int64_t n_embd; const int64_t n_layer; const int64_t n_rot; const int64_t n_ctx; // user-specified context size (can be different from n_ctx_train) const int64_t n_head; const int64_t n_head_kv; const int64_t n_embd_head_k; const int64_t n_embd_k_gqa; const int64_t n_embd_head_v; const int64_t n_embd_v_gqa; const int64_t n_expert; const int64_t n_expert_used; const float freq_base; const float freq_scale; const float ext_factor; const float attn_factor; const float beta_fast; const float beta_slow; const float norm_eps; const float norm_rms_eps; const int64_t n_tokens; const int64_t n_outputs; const int32_t n_ctx_orig; // yarn const enum llama_pooling_type pooling_type; const enum llama_rope_type rope_type; ggml_backend_sched_t sched; ggml_backend_t backend_cpu; // TODO: needed by build_attn_mha, figure out a way to remove? const llama_adapter_cvec * cvec; const llama_adapter_loras * loras; const llama_memory_context_i * mctx; const llama_cross * cross; std::map samplers; const llm_graph_cb & cb_func; llm_graph_result * res; ggml_context * ctx0 = nullptr; ggml_cgraph * gf = nullptr; llm_graph_context(const llm_graph_params & params); virtual ~llm_graph_context() = default; void cb(ggml_tensor * cur, const char * name, int il) const; // // common // ggml_tensor * build_cvec( ggml_tensor * cur, int il) const; // do mat_mul, while optionally apply lora and per-tensor scale ggml_tensor * build_lora_mm( ggml_tensor * w, ggml_tensor * cur, ggml_tensor * w_s = nullptr) const; // do mat_mul_id, while optionally apply lora ggml_tensor * build_lora_mm_id( ggml_tensor * w, // ggml_tensor * as ggml_tensor * cur, // ggml_tensor * b ggml_tensor * ids) const; ggml_tensor * build_norm( ggml_tensor * cur, ggml_tensor * mw, ggml_tensor * mb, llm_norm_type type, int il) const; ggml_tensor * build_ffn( ggml_tensor * cur, ggml_tensor * up, ggml_tensor * up_b, ggml_tensor * up_s, ggml_tensor * gate, ggml_tensor * gate_b, ggml_tensor * gate_s, ggml_tensor * down, ggml_tensor * down_b, ggml_tensor * down_s, ggml_tensor * act_scales, llm_ffn_op_type type_op, llm_ffn_gate_type type_gate, int il) const; // build MoE FFN without bias tensors ggml_tensor * build_moe_ffn( ggml_tensor * cur, ggml_tensor * gate_inp, ggml_tensor * up_exps, ggml_tensor * gate_exps, ggml_tensor * down_exps, ggml_tensor * exp_probs_b, int64_t n_expert, int64_t n_expert_used, llm_ffn_op_type type_op, bool norm_w, float w_scale, llama_expert_gating_func_type gating_op, int il, ggml_tensor * probs_in = nullptr, ggml_tensor * gate_up_exps = nullptr, ggml_tensor * up_exps_s = nullptr, ggml_tensor * gate_exps_s = nullptr, ggml_tensor * down_exps_s = nullptr) const; ggml_tensor * build_moe_ffn( ggml_tensor * cur, ggml_tensor * gate_inp, ggml_tensor * gate_inp_b, ggml_tensor * up_exps, ggml_tensor * up_exps_b, ggml_tensor * gate_exps, ggml_tensor * gate_exps_b, ggml_tensor * down_exps, ggml_tensor * down_exps_b, ggml_tensor * exp_probs_b, int64_t n_expert, int64_t n_expert_used, llm_ffn_op_type type_op, bool norm_w, float w_scale, llama_expert_gating_func_type gating_op, int il, ggml_tensor * probs_in = nullptr, ggml_tensor * gate_up_exps = nullptr, ggml_tensor * gate_up_exps_b = nullptr, ggml_tensor * up_exps_s = nullptr, ggml_tensor * gate_exps_s = nullptr, ggml_tensor * down_exps_s = nullptr) const; // // inputs // ggml_tensor * build_inp_embd(ggml_tensor * tok_embd) const; ggml_tensor * build_inp_pos() const; ggml_tensor * build_inp_attn_scale() const; ggml_tensor * build_inp_out_ids() const; ggml_tensor * build_inp_mean() const; ggml_tensor * build_inp_cls() const; ggml_tensor * build_inp_cross_embd() const; ggml_tensor * build_inp_pos_bucket_enc() const; ggml_tensor * build_inp_pos_bucket_dec() const; ggml_tensor * build_pos_bias(ggml_tensor * pos_bucket, ggml_tensor * attn_rel_b) const; // // attention // ggml_tensor * build_attn_mha( ggml_tensor * q, // [n_embd_head_q, n_head_q, n_tokens] ggml_tensor * k, // [n_embd_head_k, n_head_k, n_tokens] ggml_tensor * v, // [n_embd_head_v, n_head_v, n_tokens] (v_trans == false) ggml_tensor * kq_b, ggml_tensor * kq_mask, ggml_tensor * sinks, // [n_head_q] ggml_tensor * v_mla, // [n_embd_head_v_mla, n_embd_head_v, n_head_v] float kq_scale, int il) const; llm_graph_input_attn_no_cache * build_attn_inp_no_cache() const; ggml_tensor * build_attn( llm_graph_input_attn_no_cache * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, // [n_embd_head_q, n_head_q, n_tokens] ggml_tensor * k_cur, // [n_embd_head_k, n_head_k, n_tokens] ggml_tensor * v_cur, // [n_embd_head_v, n_head_v, n_tokens] ggml_tensor * kq_b, ggml_tensor * sinks, // [n_head_q] ggml_tensor * v_mla, // [n_embd_head_v_mla, n_embd_head_v, n_head_v] float kq_scale, int il) const; llm_graph_input_attn_kv * build_attn_inp_kv() const; ggml_tensor * build_attn( llm_graph_input_attn_kv * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, // [n_embd_head_q, n_head_q, n_tokens] ggml_tensor * k_cur, // [n_embd_head_k, n_head_k, n_tokens] ggml_tensor * v_cur, // [n_embd_head_v, n_head_v, n_tokens] ggml_tensor * kq_b, ggml_tensor * sinks, // [n_head_q] ggml_tensor * v_mla, // [n_embd_head_v_mla, n_embd_head_v, n_head_v] // TODO: remove float kq_scale, int il) const; llm_graph_input_attn_k * build_attn_inp_k() const; ggml_tensor * build_attn( llm_graph_input_attn_k * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, // [n_embd_head_q, n_head_q, n_tokens] ggml_tensor * k_cur, // [n_embd_head_k, n_head_k, n_tokens] ggml_tensor * v_cur, // [n_embd_head_v, n_head_v, n_tokens] ggml_tensor * kq_b, ggml_tensor * sinks, // [n_head_q] ggml_tensor * v_mla, // [n_embd_head_v_mla, n_embd_head_v, n_head_v] float kq_scale, int il) const; llm_graph_input_attn_kv_iswa * build_attn_inp_kv_iswa() const; // note: if k_cur or v_cur are not provided, they will not be stored in the memory ggml_tensor * build_attn( llm_graph_input_attn_kv_iswa * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, // [n_embd_head_q, n_head_q, n_tokens] ggml_tensor * k_cur, // [n_embd_head_k, n_head_k, n_tokens] optional ggml_tensor * v_cur, // [n_embd_head_v, n_head_v, n_tokens] optional ggml_tensor * kq_b, ggml_tensor * sinks, // [n_head_q] ggml_tensor * v_mla, // [n_embd_head_v_mla, n_embd_head_v, n_head_v] float kq_scale, int il) const; llm_graph_input_attn_cross * build_attn_inp_cross() const; ggml_tensor * build_attn( llm_graph_input_attn_cross * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, // [n_embd_head_q, n_head_q, n_tokens] ggml_tensor * k_cur, // [n_embd_head_k, n_head_k, n_tokens] ggml_tensor * v_cur, // [n_embd_head_v, n_head_v, n_tokens] ggml_tensor * kq_b, ggml_tensor * sinks, // [n_head_q] ggml_tensor * v_mla, // [n_embd_head_v_mla, n_embd_head_v, n_head_v] float kq_scale, int il) const; // // recurrent // // TODO: move this implementation to llama_memory_recurrent. // this is analogous to llama_kv_cache::cpy_k / cpy_v // when moving, avoid passing `ggml_cgraph` - only pass `ggml_context`. would likely need to split the // implementation in 2 separate methods. the goal is to avoid calling `ggml_build_forward_expand` in // `llama_memory_recurrent` ggml_tensor * build_rs( ggml_tensor * s, ggml_tensor * state_copy_main, ggml_tensor * state_copy_extra, int32_t state_size, int32_t n_seqs, uint32_t n_rs, uint32_t rs_head, uint32_t rs_size, int32_t rs_zero, const llm_graph_get_rows_fn & get_state_rows = ggml_get_rows) const; llm_graph_input_rs * build_rs_inp() const; ggml_tensor * build_rs( llm_graph_input_rs * inp, ggml_tensor * s, int32_t state_size, int32_t n_seqs, const llm_graph_get_rows_fn & get_state_rows = ggml_get_rows) const; ggml_tensor * build_rwkv_token_shift_load( llm_graph_input_rs * inp, const llama_ubatch & ubatch, int il) const; ggml_tensor * build_rwkv_token_shift_store( ggml_tensor * token_shift, const llama_ubatch & ubatch, int il) const; // // hybrid // llm_graph_input_mem_hybrid * build_inp_mem_hybrid() const; llm_graph_input_mem_hybrid_k * build_inp_mem_hybrid_k() const; llm_graph_input_mem_hybrid_iswa * build_inp_mem_hybrid_iswa() const; // // pooling // void build_pooling( ggml_tensor * cls, ggml_tensor * cls_b, ggml_tensor * cls_out, ggml_tensor * cls_out_b, ggml_tensor * cls_norm) const; // // sampling (backend sampling) // void build_sampling() const; // // dense (out) // void build_dense_out( ggml_tensor * dense_2, ggml_tensor * dense_2_b, ggml_tensor * dense_3) const; }; // TODO: better name int32_t llama_relative_position_bucket(llama_pos x, llama_pos y, uint64_t n_buckets, bool bidirectional);