#include "llama-graph.h" #include "llama-impl.h" #include "llama-batch.h" #include "llama-cparams.h" #include "llama-kv-cache.h" #include "llama-kv-cache-iswa.h" #include "llama-memory-hybrid.h" #include "llama-memory-hybrid-iswa.h" #include "llama-memory-recurrent.h" #include #include #include #include #include #include // dedup helpers static ggml_tensor * build_attn_inp_kq_mask( ggml_context * ctx, const llama_kv_cache_context * mctx, const llama_ubatch & ubatch, const llama_cparams & cparams) { const auto n_kv = mctx->get_n_kv(); const auto n_tokens = ubatch.n_tokens; const auto n_stream = cparams.kv_unified ? 1 : ubatch.n_seqs_unq; ggml_tensor * res = ggml_new_tensor_4d(ctx, GGML_TYPE_F32, n_kv, n_tokens/n_stream, 1, n_stream); ggml_set_input(res); ggml_set_name(res, "attn_inp_kq_mask"); return res; } static bool can_reuse_kq_mask( ggml_tensor * kq_mask, const llama_kv_cache_context * mctx, const llama_ubatch & ubatch, const llama_cparams & cparams) { const auto n_kv = mctx->get_n_kv(); const auto n_tokens = ubatch.n_tokens; const auto n_stream = cparams.kv_unified ? 1 : ubatch.n_seqs_unq; bool res = true; res &= (kq_mask->ne[0] == n_kv); res &= (kq_mask->ne[1] == n_tokens/n_stream); res &= (kq_mask->ne[2] == 1); res &= (kq_mask->ne[3] == n_stream); return res; } // impl static ggml_tensor * ggml_mul_mat_aux( ggml_context * ctx, ggml_tensor * cur, ggml_tensor * rot) { const auto n = rot->ne[0]; ggml_tensor * res; res = ggml_reshape_2d(ctx, cur, n, ggml_nelements(cur)/n); res = ggml_mul_mat (ctx, rot, res); res = ggml_reshape_4d(ctx, res, cur->ne[0], cur->ne[1], cur->ne[2], cur->ne[3]); return res; } void llm_graph_input_embd::set_input(const llama_ubatch * ubatch) { if (ubatch->token) { const int64_t n_tokens = ubatch->n_tokens; ggml_backend_tensor_set(tokens, ubatch->token, 0, n_tokens*ggml_element_size(tokens)); } if (ubatch->embd) { GGML_ASSERT(n_embd == embd->ne[0]); const int64_t n_tokens = ubatch->n_tokens; ggml_backend_tensor_set(embd, ubatch->embd, 0, n_tokens*n_embd*ggml_element_size(embd)); } } bool llm_graph_input_embd::can_reuse(const llm_graph_params & params) { bool res = true; res &= (!params.ubatch.token) || (tokens && tokens->ne[0] == params.ubatch.n_tokens); res &= (!params.ubatch.embd) || (embd && embd->ne[1] == params.ubatch.n_tokens); return res; } void llm_graph_input_pos::set_input(const llama_ubatch * ubatch) { if (ubatch->pos && pos) { const int64_t n_tokens = ubatch->n_tokens; if (ubatch->token && n_pos_per_embd == 4) { // in case we're using M-RoPE with text tokens, convert the 1D positions to 4D // the 3 first dims are the same, and 4th dim is all 0 std::vector pos_data(n_tokens*n_pos_per_embd); // copy the first dimension for (int i = 0; i < n_tokens; ++i) { pos_data[ i] = ubatch->pos[i]; pos_data[ n_tokens + i] = ubatch->pos[i]; pos_data[2 * n_tokens + i] = ubatch->pos[i]; pos_data[3 * n_tokens + i] = 0; // 4th dim is 0 } ggml_backend_tensor_set(pos, pos_data.data(), 0, pos_data.size()*ggml_element_size(pos)); } else { ggml_backend_tensor_set(pos, ubatch->pos, 0, n_tokens*n_pos_per_embd*ggml_element_size(pos)); } } } bool llm_graph_input_pos::can_reuse(const llm_graph_params & params) { bool res = true; res &= pos->ne[0] == params.ubatch.n_tokens*n_pos_per_embd; return res; } void llm_graph_input_attn_temp::set_input(const llama_ubatch * ubatch) { if (ubatch->pos && attn_scale) { const int64_t n_tokens = ubatch->n_tokens; GGML_ASSERT(f_attn_temp_scale != 0.0f); GGML_ASSERT(n_attn_temp_floor_scale != 0); std::vector attn_scale_data(n_tokens, 0.0f); for (int i = 0; i < n_tokens; ++i) { const float pos = ubatch->pos[i]; attn_scale_data[i] = std::log( std::floor((pos + f_attn_temp_offset) / n_attn_temp_floor_scale) + 1.0 ) * f_attn_temp_scale + 1.0; } ggml_backend_tensor_set(attn_scale, attn_scale_data.data(), 0, n_tokens*ggml_element_size(attn_scale)); } } void llm_graph_input_pos_bucket::set_input(const llama_ubatch * ubatch) { if (pos_bucket) { const int64_t n_tokens = ubatch->n_tokens; GGML_ASSERT(ggml_backend_buffer_is_host(pos_bucket->buffer)); GGML_ASSERT(!ubatch->equal_seqs()); // TODO: use ubatch->n_seqs instead of failing int32_t * data = (int32_t *) pos_bucket->data; for (int j = 0; j < n_tokens; ++j) { for (int i = 0; i < n_tokens; ++i) { data[j*n_tokens + i] = llama_relative_position_bucket(ubatch->pos[i], ubatch->pos[j], hparams.n_rel_attn_bkts, true); } } } } void llm_graph_input_pos_bucket_kv::set_input(const llama_ubatch * ubatch) { if (pos_bucket) { mctx->set_input_pos_bucket(pos_bucket, ubatch); } } void llm_graph_input_out_ids::set_input(const llama_ubatch * ubatch) { GGML_ASSERT(out_ids); const int64_t n_tokens = ubatch->n_tokens; GGML_ASSERT(ggml_backend_buffer_is_host(out_ids->buffer)); int32_t * data = (int32_t *) out_ids->data; if (n_outputs == n_tokens) { for (int i = 0; i < n_tokens; ++i) { data[i] = i; } return; } GGML_ASSERT(ubatch->output); int n_outputs = 0; for (int i = 0; i < n_tokens; ++i) { if (ubatch->output[i]) { data[n_outputs++] = i; } } } bool llm_graph_input_out_ids::can_reuse(const llm_graph_params & params) { bool res = true; res &= n_outputs == params.n_outputs; return res; } void llm_graph_input_mean::set_input(const llama_ubatch * ubatch) { if (cparams.embeddings && (cparams.pooling_type == LLAMA_POOLING_TYPE_MEAN || cparams.pooling_type == LLAMA_POOLING_TYPE_RANK )) { const int64_t n_tokens = ubatch->n_tokens; const int64_t n_seq_tokens = ubatch->n_seq_tokens; const int64_t n_seqs_unq = ubatch->n_seqs_unq; GGML_ASSERT(mean); GGML_ASSERT(ggml_backend_buffer_is_host(mean->buffer)); float * data = (float *) mean->data; memset(mean->data, 0, n_tokens*n_seqs_unq*ggml_element_size(mean)); std::vector sums(n_seqs_unq, 0); for (int i = 0; i < n_tokens; i += n_seq_tokens) { for (int s = 0; s < ubatch->n_seq_id[i]; ++s) { const llama_seq_id seq_id = ubatch->seq_id[i][s]; const int32_t seq_idx = ubatch->seq_idx[seq_id]; sums[seq_idx] += ubatch->n_seq_tokens; } } std::vector div(n_seqs_unq, 0.0f); for (int s = 0; s < n_seqs_unq; ++s) { const uint64_t sum = sums[s]; if (sum > 0) { div[s] = 1.0f/float(sum); } } for (int i = 0; i < n_tokens; i += n_seq_tokens) { for (int s = 0; s < ubatch->n_seq_id[i]; ++s) { const llama_seq_id seq_id = ubatch->seq_id[i][s]; const int32_t seq_idx = ubatch->seq_idx[seq_id]; for (int j = 0; j < n_seq_tokens; ++j) { data[seq_idx*n_tokens + i + j] = div[seq_idx]; } } } } } void llm_graph_input_cls::set_input(const llama_ubatch * ubatch) { const int64_t n_tokens = ubatch->n_tokens; const int64_t n_seqs_unq = ubatch->n_seqs_unq; if (cparams.embeddings && ( cparams.pooling_type == LLAMA_POOLING_TYPE_CLS || cparams.pooling_type == LLAMA_POOLING_TYPE_RANK || cparams.pooling_type == LLAMA_POOLING_TYPE_LAST )) { GGML_ASSERT(cls); GGML_ASSERT(ggml_backend_buffer_is_host(cls->buffer)); uint32_t * data = (uint32_t *) cls->data; memset(cls->data, 0, n_seqs_unq*ggml_element_size(cls)); std::vector target_pos(n_seqs_unq, -1); std::vector target_row(n_seqs_unq, -1); const bool last = ( cparams.pooling_type == LLAMA_POOLING_TYPE_LAST || (cparams.pooling_type == LLAMA_POOLING_TYPE_RANK && (arch == LLM_ARCH_QWEN3 || arch == LLM_ARCH_QWEN3VL)) // qwen3 reranking & embedding models use last token ); for (int i = 0; i < n_tokens; ++i) { const llama_pos pos = ubatch->pos[i]; for (int s = 0; s < ubatch->n_seq_id[i]; ++s) { const llama_seq_id seq_id = ubatch->seq_id[i][s]; const int32_t seq_idx = ubatch->seq_idx[seq_id]; if ( (target_pos[seq_idx] == -1) || ( last && pos >= target_pos[seq_idx]) || (!last && pos < target_pos[seq_idx]) ) { target_pos[seq_idx] = pos; target_row[seq_idx] = i; } } } for (int s = 0; s < n_seqs_unq; ++s) { if (target_row[s] >= 0) { data[s] = target_row[s]; } } } } void llm_graph_input_rs::set_input(const llama_ubatch * ubatch) { GGML_UNUSED(ubatch); const int64_t n_rs = mctx->get_n_rs(); if (s_copy) { GGML_ASSERT(ggml_backend_buffer_is_host(s_copy->buffer)); int32_t * data = (int32_t *) s_copy->data; // assuming copy destinations ALWAYS happen ONLY on the cells between head and head+n for (uint32_t i = 0; i < n_rs; ++i) { data[i] = mctx->s_copy(i); } } } bool llm_graph_input_rs::can_reuse(const llm_graph_params & params) { const auto * mctx = static_cast(params.mctx); this->mctx = mctx; bool res = true; res &= s_copy->ne[0] == mctx->get_n_rs(); res &= s_copy_main->ne[0] == params.ubatch.n_seqs; res &= s_copy_extra->ne[0] == mctx->get_n_rs() - params.ubatch.n_seqs; res &= head == mctx->get_head(); res &= rs_z == mctx->get_rs_z(); return res; } void llm_graph_input_cross_embd::set_input(const llama_ubatch * ubatch) { GGML_UNUSED(ubatch); if (cross_embd && !cross->v_embd.empty()) { assert(cross_embd->type == GGML_TYPE_F32); ggml_backend_tensor_set(cross_embd, cross->v_embd.data(), 0, ggml_nbytes(cross_embd)); } } static void print_mask(const float * data, int64_t n_tokens, int64_t n_kv, int64_t n_swa, llama_swa_type swa_type) { LLAMA_LOG_DEBUG("%s: === Attention mask ===\n", __func__); const char * swa_type_str = "unknown"; switch (swa_type) { case LLAMA_SWA_TYPE_NONE: swa_type_str = "LLAMA_SWA_TYPE_NONE"; break; case LLAMA_SWA_TYPE_STANDARD: swa_type_str = "LLAMA_SWA_TYPE_STANDARD"; break; case LLAMA_SWA_TYPE_CHUNKED: swa_type_str = "LLAMA_SWA_TYPE_CHUNKED"; break; case LLAMA_SWA_TYPE_SYMMETRIC: swa_type_str = "LLAMA_SWA_TYPE_SYMMETRIC"; break; }; LLAMA_LOG_DEBUG("%s: n_swa : %d, n_kv: %d, swq_type: %s\n", __func__, (int)n_swa, (int)n_kv, swa_type_str); LLAMA_LOG_DEBUG("%s: '0' = can attend, '∞' = masked\n", __func__); LLAMA_LOG_DEBUG("%s: Rows = query tokens, Columns = key/value tokens\n\n", __func__); LLAMA_LOG_DEBUG(" "); for (int j = 0; j < std::min((int64_t)20, n_kv); ++j) { LLAMA_LOG_DEBUG("%2d", j); } LLAMA_LOG_DEBUG("\n"); for (int i = 0; i < std::min((int64_t)20, n_tokens); ++i) { LLAMA_LOG_DEBUG(" %2d ", i); for (int j = 0; j < std::min((int64_t)20, n_kv); ++j) { float val = data[i * n_kv + j]; if (val == -INFINITY) { LLAMA_LOG_DEBUG(" ∞"); } else { LLAMA_LOG_DEBUG(" 0"); } } LLAMA_LOG_DEBUG("\n"); } } void llm_graph_input_attn_no_cache::set_input(const llama_ubatch * ubatch) { const int64_t n_kv = ubatch->n_tokens; const int64_t n_tokens = ubatch->n_tokens; const auto fill_mask = [&](float * data, int n_swa, llama_swa_type swa_type) { for (int i1 = 0; i1 < n_tokens; ++i1) { const llama_seq_id s1 = ubatch->seq_id[i1][0]; const llama_pos p1 = ubatch->pos[i1]; const uint64_t idst = i1*n_kv; for (int i0 = 0; i0 < n_tokens; ++i0) { const llama_seq_id s0 = ubatch->seq_id[i0][0]; const llama_pos p0 = ubatch->pos[i0]; // mask different sequences if (s0 != s1) { continue; } // mask future tokens if (cparams.causal_attn && p0 > p1) { continue; } // apply SWA if any if (llama_hparams::is_masked_swa(n_swa, swa_type, p0, p1)) { continue; } data[idst + i0] = hparams.use_alibi ? -std::abs(p0 - p1) : 0.0f; } } }; { GGML_ASSERT(self_kq_mask); GGML_ASSERT(ggml_backend_buffer_is_host(self_kq_mask->buffer)); float * data = (float *) self_kq_mask->data; std::fill(data, data + ggml_nelements(self_kq_mask), -INFINITY); fill_mask(data, 0, LLAMA_SWA_TYPE_NONE); if (debug) { print_mask(data, n_tokens, n_kv, 0, LLAMA_SWA_TYPE_NONE); } } if (hparams.swa_type != LLAMA_SWA_TYPE_NONE) { GGML_ASSERT(self_kq_mask_swa); GGML_ASSERT(ggml_backend_buffer_is_host(self_kq_mask_swa->buffer)); float * data = (float *) self_kq_mask_swa->data; std::fill(data, data + ggml_nelements(self_kq_mask_swa), -INFINITY); fill_mask(data, hparams.n_swa, hparams.swa_type); if (debug) { print_mask(data, n_tokens, n_kv, hparams.n_swa, hparams.swa_type); } } } void llm_graph_input_attn_kv::set_input(const llama_ubatch * ubatch) { mctx->set_input_k_idxs(self_k_idxs, ubatch); mctx->set_input_v_idxs(self_v_idxs, ubatch); mctx->set_input_kq_mask(self_kq_mask, ubatch, cparams.causal_attn); if (self_k_rot) { mctx->set_input_k_rot(self_k_rot); } if (self_v_rot) { mctx->set_input_v_rot(self_v_rot); } } bool llm_graph_input_attn_kv::can_reuse(const llm_graph_params & params) { const auto * mctx = static_cast(params.mctx); this->mctx = mctx; bool res = true; res &= self_k_idxs->ne[0] == params.ubatch.n_tokens; //res &= self_v_idxs->ne[0] == params.ubatch.n_tokens; // TODO: need to move this to the unified cache and check there res &= can_reuse_kq_mask(self_kq_mask, mctx, params.ubatch, params.cparams); return res; } void llm_graph_input_attn_k::set_input(const llama_ubatch * ubatch) { mctx->set_input_k_idxs(self_k_idxs, ubatch); mctx->set_input_kq_mask(self_kq_mask, ubatch, cparams.causal_attn); } bool llm_graph_input_attn_k::can_reuse(const llm_graph_params & params) { const auto * mctx = static_cast(params.mctx); this->mctx = mctx; bool res = true; res &= self_k_idxs->ne[0] == params.ubatch.n_tokens; res &= can_reuse_kq_mask(self_kq_mask, mctx, params.ubatch, params.cparams); return res; } void llm_graph_input_attn_kv_iswa::set_input(const llama_ubatch * ubatch) { mctx->get_base()->set_input_k_idxs(self_k_idxs, ubatch); mctx->get_base()->set_input_v_idxs(self_v_idxs, ubatch); mctx->get_base()->set_input_kq_mask(self_kq_mask, ubatch, cparams.causal_attn); mctx->get_swa()->set_input_k_idxs(self_k_idxs_swa, ubatch); mctx->get_swa()->set_input_v_idxs(self_v_idxs_swa, ubatch); mctx->get_swa()->set_input_kq_mask(self_kq_mask_swa, ubatch, cparams.causal_attn); if (self_k_rot) { mctx->get_base()->set_input_k_rot(self_k_rot); } if (self_v_rot) { mctx->get_base()->set_input_v_rot(self_v_rot); } } bool llm_graph_input_attn_kv_iswa::can_reuse(const llm_graph_params & params) { const auto * mctx = static_cast(params.mctx); this->mctx = mctx; bool res = true; res &= self_k_idxs->ne[0] == params.ubatch.n_tokens; //res &= self_v_idxs->ne[0] == params.ubatch.n_tokens; // TODO: need to move this to the unified cache and check there res &= self_k_idxs_swa->ne[0] == params.ubatch.n_tokens; //res &= self_v_idxs_swa->ne[0] == params.ubatch.n_tokens; // TODO: need to move this to the unified cache and check there res &= can_reuse_kq_mask(self_kq_mask, mctx->get_base(), params.ubatch, params.cparams); res &= can_reuse_kq_mask(self_kq_mask_swa, mctx->get_swa(), params.ubatch, params.cparams); return res; } void llm_graph_input_attn_cross::set_input(const llama_ubatch * ubatch) { GGML_ASSERT(cross_kq_mask); const int64_t n_enc = cross_kq_mask->ne[0]; const int64_t n_tokens = ubatch->n_tokens; GGML_ASSERT(ggml_backend_buffer_is_host(cross_kq_mask->buffer)); GGML_ASSERT(!ubatch->equal_seqs()); // TODO: use ubatch->n_seqs instead of failing float * data = (float *) cross_kq_mask->data; for (int i = 0; i < n_tokens; ++i) { GGML_ASSERT(!cross->seq_ids_enc.empty() && "llama_encode must be called first"); for (int j = 0; j < n_enc; ++j) { float f = -INFINITY; for (int s = 0; s < ubatch->n_seq_id[i]; ++s) { const llama_seq_id seq_id = ubatch->seq_id[i][s]; if (cross->seq_ids_enc[j].find(seq_id) != cross->seq_ids_enc[j].end()) { f = 0.0f; } } data[i*n_enc + j] = f; } } } void llm_graph_input_mem_hybrid::set_input(const llama_ubatch * ubatch) { mctx->get_attn()->set_input_k_idxs(inp_attn->self_k_idxs, ubatch); mctx->get_attn()->set_input_v_idxs(inp_attn->self_v_idxs, ubatch); mctx->get_attn()->set_input_kq_mask(inp_attn->self_kq_mask, ubatch, cparams.causal_attn); if (inp_attn->self_k_rot) { mctx->get_attn()->set_input_k_rot(inp_attn->self_k_rot); } if (inp_attn->self_v_rot) { mctx->get_attn()->set_input_v_rot(inp_attn->self_v_rot); } const int64_t n_rs = mctx->get_recr()->get_n_rs(); if (inp_rs->s_copy) { GGML_ASSERT(ggml_backend_buffer_is_host(inp_rs->s_copy->buffer)); int32_t * data = (int32_t *) inp_rs->s_copy->data; // assuming copy destinations ALWAYS happen ONLY on the cells between head and head+n for (uint32_t i = 0; i < n_rs; ++i) { data[i] = mctx->get_recr()->s_copy(i); } } } bool llm_graph_input_mem_hybrid::can_reuse(const llm_graph_params & params) { const auto * mctx = static_cast(params.mctx); this->mctx = mctx; bool res = true; res &= inp_attn->self_k_idxs->ne[0] == params.ubatch.n_tokens; //res &= inp_attn->self_v_idxs->ne[0] == params.ubatch.n_tokens; // TODO: need to move this to the unified cache and check there res &= can_reuse_kq_mask(inp_attn->self_kq_mask, mctx->get_attn(), params.ubatch, params.cparams); res &= inp_rs->s_copy->ne[0] == mctx->get_recr()->get_n_rs(); res &= inp_rs->s_copy_main->ne[0] == params.ubatch.n_seqs; res &= inp_rs->s_copy_extra->ne[0] == mctx->get_recr()->get_n_rs() - params.ubatch.n_seqs; res &= inp_rs->head == mctx->get_recr()->get_head(); res &= inp_rs->rs_z == mctx->get_recr()->get_rs_z(); return res; } // TODO: Hybrid input classes are a bit redundant. // Instead of creating a hybrid input, the graph can simply create 2 separate inputs. // Refactoring is required in the future. void llm_graph_input_mem_hybrid_k::set_input(const llama_ubatch * ubatch) { mctx->get_attn()->set_input_k_idxs(inp_attn->self_k_idxs, ubatch); mctx->get_attn()->set_input_kq_mask(inp_attn->self_kq_mask, ubatch, cparams.causal_attn); const int64_t n_rs = mctx->get_recr()->get_n_rs(); if (inp_rs->s_copy) { GGML_ASSERT(ggml_backend_buffer_is_host(inp_rs->s_copy->buffer)); int32_t * data = (int32_t *) inp_rs->s_copy->data; // assuming copy destinations ALWAYS happen ONLY on the cells between head and head+n for (uint32_t i = 0; i < n_rs; ++i) { data[i] = mctx->get_recr()->s_copy(i); } } } bool llm_graph_input_mem_hybrid_k::can_reuse(const llm_graph_params & params) { const auto * mctx = static_cast(params.mctx); this->mctx = mctx; bool res = true; res &= inp_attn->self_k_idxs->ne[0] == params.ubatch.n_tokens; res &= can_reuse_kq_mask(inp_attn->self_kq_mask, mctx->get_attn(), params.ubatch, params.cparams); res &= inp_rs->s_copy->ne[0] == mctx->get_recr()->get_n_rs(); res &= inp_rs->s_copy_main->ne[0] == params.ubatch.n_seqs; res &= inp_rs->s_copy_extra->ne[0] == mctx->get_recr()->get_n_rs() - params.ubatch.n_seqs; res &= inp_rs->head == mctx->get_recr()->get_head(); res &= inp_rs->rs_z == mctx->get_recr()->get_rs_z(); return res; } void llm_graph_input_mem_hybrid_iswa::set_input(const llama_ubatch * ubatch) { const auto * attn_ctx = mctx->get_attn(); // base tensors may not be allocated if there are no non-SWA attention layers if (inp_attn->self_k_idxs && inp_attn->self_k_idxs->buffer) { attn_ctx->get_base()->set_input_k_idxs(inp_attn->self_k_idxs, ubatch); attn_ctx->get_base()->set_input_v_idxs(inp_attn->self_v_idxs, ubatch); attn_ctx->get_base()->set_input_kq_mask(inp_attn->self_kq_mask, ubatch, cparams.causal_attn); } // swa tensors may not be allocated if there are no SWA attention layers if (inp_attn->self_k_idxs_swa && inp_attn->self_k_idxs_swa->buffer) { attn_ctx->get_swa()->set_input_k_idxs(inp_attn->self_k_idxs_swa, ubatch); attn_ctx->get_swa()->set_input_v_idxs(inp_attn->self_v_idxs_swa, ubatch); attn_ctx->get_swa()->set_input_kq_mask(inp_attn->self_kq_mask_swa, ubatch, cparams.causal_attn); } if (inp_attn->self_k_rot) { attn_ctx->get_base()->set_input_k_rot(inp_attn->self_k_rot); } if (inp_attn->self_v_rot) { attn_ctx->get_base()->set_input_v_rot(inp_attn->self_v_rot); } const int64_t n_rs = mctx->get_recr()->get_n_rs(); if (inp_rs->s_copy) { GGML_ASSERT(ggml_backend_buffer_is_host(inp_rs->s_copy->buffer)); int32_t * data = (int32_t *) inp_rs->s_copy->data; // assuming copy destinations ALWAYS happen ONLY on the cells between head and head+n for (uint32_t i = 0; i < n_rs; ++i) { data[i] = mctx->get_recr()->s_copy(i); } } } bool llm_graph_input_mem_hybrid_iswa::can_reuse(const llm_graph_params & params) { const auto * mctx = static_cast(params.mctx); this->mctx = mctx; bool res = true; const auto * attn_ctx = mctx->get_attn(); // base tensors may not be allocated if there are no non-SWA attention layers if (inp_attn->self_k_idxs && inp_attn->self_k_idxs->buffer) { res &= inp_attn->self_k_idxs->ne[0] == params.ubatch.n_tokens; //res &= inp_attn->self_v_idxs->ne[0] == params.ubatch.n_tokens; // TODO: need to move this to the unified cache and check there res &= can_reuse_kq_mask(inp_attn->self_kq_mask, attn_ctx->get_base(), params.ubatch, params.cparams); } // swa tensors may not be allocated if there are no SWA attention layers if (inp_attn->self_k_idxs_swa && inp_attn->self_k_idxs_swa->buffer) { res &= inp_attn->self_k_idxs_swa->ne[0] == params.ubatch.n_tokens; //res &= inp_attn->self_v_idxs_swa->ne[0] == params.ubatch.n_tokens; // TODO: need to move this to the unified cache and check there res &= can_reuse_kq_mask(inp_attn->self_kq_mask_swa, attn_ctx->get_swa(), params.ubatch, params.cparams); } res &= inp_rs->s_copy->ne[0] == mctx->get_recr()->get_n_rs(); res &= inp_rs->s_copy_main->ne[0] == params.ubatch.n_seqs; res &= inp_rs->s_copy_extra->ne[0] == mctx->get_recr()->get_n_rs() - params.ubatch.n_seqs; res &= inp_rs->head == mctx->get_recr()->get_head(); res &= inp_rs->rs_z == mctx->get_recr()->get_rs_z(); return res; } void llm_graph_input_sampling::set_input(const llama_ubatch * ubatch) { // set the inputs only for the active samplers in the current ubatch std::unordered_set active_samplers; for (uint32_t i = 0; i < ubatch->n_tokens; i++) { if (ubatch->output[i]) { llama_seq_id seq_id = ubatch->seq_id[i][0]; active_samplers.insert(seq_id); } } for (auto seq_id : active_samplers) { if (samplers.find(seq_id) == samplers.end()) { continue; } auto & sampler = samplers[seq_id]; if (sampler->iface->backend_set_input) { sampler->iface->backend_set_input(sampler); } } } bool llm_graph_input_sampling::can_reuse(const llm_graph_params & params) { if (samplers.size() != params.samplers.size()) { return false; } for (const auto & [seq_id, sampler] : params.samplers) { if (samplers[seq_id] != sampler) { return false; } } return true; } // // llm_graph_result // llm_graph_result::llm_graph_result(int64_t max_nodes) : max_nodes(max_nodes) { reset(); const char * LLAMA_GRAPH_RESULT_DEBUG = getenv("LLAMA_GRAPH_RESULT_DEBUG"); debug = LLAMA_GRAPH_RESULT_DEBUG ? atoi(LLAMA_GRAPH_RESULT_DEBUG) : 0; } int64_t llm_graph_result::get_max_nodes() const { return max_nodes; } void llm_graph_result::reset() { t_inp_tokens = nullptr; t_inp_embd = nullptr; t_logits = nullptr; t_embd = nullptr; t_embd_pooled = nullptr; t_sampled.clear(); t_sampled_probs.clear(); t_sampled_logits.clear(); t_candidates.clear(); params = {}; inputs.clear(); buf_compute_meta.resize(ggml_tensor_overhead()*max_nodes + ggml_graph_overhead_custom(max_nodes, false)); ggml_init_params params = { /*.mem_size =*/ buf_compute_meta.size(), /*.mem_buffer =*/ buf_compute_meta.data(), /*.no_alloc =*/ true, }; ctx_compute.reset(ggml_init(params)); gf = ggml_new_graph_custom(ctx_compute.get(), max_nodes, false); } void llm_graph_result::set_inputs(const llama_ubatch * ubatch) { for (auto & input : inputs) { input->set_input(ubatch); } } void llm_graph_result::set_outputs() { if (t_logits != nullptr) { ggml_set_output(t_logits); } if (t_embd != nullptr) { ggml_set_output(t_embd); } if (t_embd_pooled != nullptr) { ggml_set_output(t_embd_pooled); } for (auto & [seq_id, t] : t_sampled) { if (t != nullptr) { ggml_set_output(t); } } for (auto & [seq_id, t] : t_sampled_probs) { if (t != nullptr) { ggml_set_output(t); } } for (auto & [seq_id, t] : t_sampled_logits) { if (t != nullptr) { ggml_set_output(t); } } for (auto & [seq_id, t] : t_candidates) { if (t != nullptr) { ggml_set_output(t); } } } bool llm_graph_result::can_reuse(const llm_graph_params & params) { if (!this->params.allow_reuse(params)) { if (debug > 1) { LLAMA_LOG_DEBUG("%s: cannot reuse graph due to incompatible graph parameters\n", __func__); } return false; } if (debug > 1) { LLAMA_LOG_DEBUG("%s: checking compatibility of %d inputs:\n", __func__, (int) inputs.size()); } bool res = true; for (auto & input : inputs) { const bool cur = input->can_reuse(params); if (debug > 1) { LLAMA_LOG_DEBUG("%s: can_reuse = %d\n", "placeholder", cur); } res = res && cur; } if (debug > 0) { LLAMA_LOG_DEBUG("%s: can reuse graph = %d\n", __func__, res); } return res; } llm_graph_input_i * llm_graph_result::add_input(llm_graph_input_ptr input) { inputs.emplace_back(std::move(input)); return inputs.back().get(); } void llm_graph_result::set_params(const llm_graph_params & params) { this->params = params; } // // llm_graph_context // llm_graph_context::llm_graph_context(const llm_graph_params & params) : arch (params.arch), hparams (params.hparams), cparams (params.cparams), ubatch (params.ubatch), n_embd (hparams.n_embd), n_layer (hparams.n_layer), n_rot (hparams.n_rot()), n_ctx (cparams.n_ctx), n_head (hparams.n_head()), n_head_kv (hparams.n_head_kv()), n_embd_head_k (hparams.n_embd_head_k()), n_embd_k_gqa (hparams.n_embd_k_gqa()), n_embd_head_v (hparams.n_embd_head_v()), n_embd_v_gqa (hparams.n_embd_v_gqa()), n_expert (hparams.n_expert), n_expert_used (cparams.warmup ? hparams.n_expert : hparams.n_expert_used), freq_base (cparams.rope_freq_base), freq_scale (cparams.rope_freq_scale), ext_factor (cparams.yarn_ext_factor), attn_factor (cparams.yarn_attn_factor), beta_fast (cparams.yarn_beta_fast), beta_slow (cparams.yarn_beta_slow), norm_eps (hparams.f_norm_eps), norm_rms_eps (hparams.f_norm_rms_eps), n_tokens (ubatch.n_tokens), n_outputs (params.n_outputs), n_ctx_orig (cparams.n_ctx_orig_yarn), pooling_type (cparams.pooling_type), rope_type (hparams.rope_type), sched (params.sched), backend_cpu (params.backend_cpu), cvec (params.cvec), loras (params.loras), mctx (params.mctx), cross (params.cross), samplers (params.samplers), cb_func (params.cb), res (params.res), ctx0 (res->get_ctx()), gf (res->get_gf()) { res->set_params(params); } void llm_graph_context::cb(ggml_tensor * cur, const char * name, int il) const { if (cb_func) { cb_func(ubatch, cur, name, il); } } ggml_tensor * llm_graph_context::build_cvec( ggml_tensor * cur, int il) const { return cvec->apply_to(ctx0, cur, il); } ggml_tensor * llm_graph_context::build_lora_mm( ggml_tensor * w, ggml_tensor * cur, ggml_tensor * w_s) const { ggml_tensor * res = ggml_mul_mat(ctx0, w, cur); for (const auto & lora : *loras) { llama_adapter_lora_weight * lw = lora.first->get_weight(w); if (lw == nullptr) { continue; } const float adapter_scale = lora.second; const float scale = lw->get_scale(lora.first->alpha, adapter_scale); ggml_tensor * ab_cur = ggml_mul_mat( ctx0, lw->b, ggml_mul_mat(ctx0, lw->a, cur) ); ab_cur = ggml_scale(ctx0, ab_cur, scale); res = ggml_add(ctx0, res, ab_cur); } if (w_s) { res = ggml_mul(ctx0, res, w_s); } return res; } ggml_tensor * llm_graph_context::build_lora_mm_id( ggml_tensor * w, // ggml_tensor * as ggml_tensor * cur, // ggml_tensor * b ggml_tensor * ids) const { ggml_tensor * res = ggml_mul_mat_id(ctx0, w, cur, ids); for (const auto & lora : *loras) { llama_adapter_lora_weight * lw = lora.first->get_weight(w); if (lw == nullptr) { continue; } const float alpha = lora.first->alpha; const float rank = (float) lw->b->ne[0]; const float scale = alpha ? lora.second * alpha / rank : lora.second; ggml_tensor * ab_cur = ggml_mul_mat_id( ctx0, lw->b, ggml_mul_mat_id(ctx0, lw->a, cur, ids), ids ); ab_cur = ggml_scale(ctx0, ab_cur, scale); res = ggml_add(ctx0, res, ab_cur); } return res; } ggml_tensor * llm_graph_context::build_norm( ggml_tensor * cur, ggml_tensor * mw, ggml_tensor * mb, llm_norm_type type, int il) const { switch (type) { case LLM_NORM: cur = ggml_norm (ctx0, cur, hparams.f_norm_eps); break; case LLM_NORM_RMS: cur = ggml_rms_norm(ctx0, cur, hparams.f_norm_rms_eps); break; case LLM_NORM_GROUP: { cur = ggml_reshape_3d(ctx0, cur, cur->ne[0], 1, cur->ne[1]); cur = ggml_group_norm(ctx0, cur, hparams.n_norm_groups, hparams.f_norm_group_eps); cur = ggml_reshape_2d(ctx0, cur, cur->ne[0], cur->ne[2]); } break; } if (mw || mb) { cb(cur, "norm", il); } if (mw) { cur = ggml_mul(ctx0, cur, mw); if (mb) { cb(cur, "norm_w", il); } } if (mb) { cur = ggml_add(ctx0, cur, mb); } return cur; } ggml_tensor * llm_graph_context::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 { ggml_tensor * tmp = up ? build_lora_mm(up, cur) : cur; cb(tmp, "ffn_up", il); if (up_b) { tmp = ggml_add(ctx0, tmp, up_b); cb(tmp, "ffn_up_b", il); } if (up_s) { tmp = ggml_mul(ctx0, tmp, up_s); cb(tmp, "ffn_up_s", il); } if (gate) { switch (type_gate) { case LLM_FFN_SEQ: { cur = build_lora_mm(gate, tmp); cb(cur, "ffn_gate", il); } break; case LLM_FFN_PAR: { cur = build_lora_mm(gate, cur); cb(cur, "ffn_gate", il); } break; } if (gate_b) { cur = ggml_add(ctx0, cur, gate_b); cb(cur, "ffn_gate_b", il); } if (gate_s) { cur = ggml_mul(ctx0, cur, gate_s); cb(cur, "ffn_gate_s", il); } } else { cur = tmp; } switch (type_op) { case LLM_FFN_SILU: if (gate && type_gate == LLM_FFN_PAR) { // Step35: HF clamps gate (after SiLU) and up before multiplication if (arch == LLM_ARCH_STEP35 && il >= 0) { const float limit = hparams.swiglu_clamp_shexp[il]; constexpr float eps = 1e-6f; if (limit > eps) { ggml_tensor * gate_act = ggml_silu(ctx0, cur); cb(gate_act, "ffn_silu", il); gate_act = ggml_clamp(ctx0, gate_act, -INFINITY, limit); cb(gate_act, "ffn_silu_clamped", il); tmp = ggml_clamp(ctx0, tmp, -limit, limit); cb(tmp, "ffn_up_clamped", il); cur = ggml_mul(ctx0, gate_act, tmp); cb(cur, "ffn_swiglu_limited", il); type_gate = LLM_FFN_SEQ; break; } } cur = ggml_swiglu_split(ctx0, cur, tmp); cb(cur, "ffn_swiglu", il); type_gate = LLM_FFN_SEQ; } else { cur = ggml_silu(ctx0, cur); cb(cur, "ffn_silu", il); } break; case LLM_FFN_GELU: if (gate && type_gate == LLM_FFN_PAR) { cur = ggml_geglu_split(ctx0, cur, tmp); cb(cur, "ffn_geglu", il); type_gate = LLM_FFN_SEQ; } else { cur = ggml_gelu(ctx0, cur); cb(cur, "ffn_gelu", il); if (act_scales != NULL) { cur = ggml_div(ctx0, cur, act_scales); cb(cur, "ffn_act", il); } } break; case LLM_FFN_RELU: if (gate && type_gate == LLM_FFN_PAR) { cur = ggml_reglu_split(ctx0, cur, tmp); cb(cur, "ffn_reglu", il); type_gate = LLM_FFN_SEQ; } else { cur = ggml_relu(ctx0, cur); cb(cur, "ffn_relu", il); } break; case LLM_FFN_RELU_SQR: { cur = ggml_relu(ctx0, cur); cb(cur, "ffn_relu", il); cur = ggml_sqr(ctx0, cur); cb(cur, "ffn_sqr(relu)", il); } break; case LLM_FFN_SWIGLU: { cur = ggml_swiglu(ctx0, cur); cb(cur, "ffn_swiglu", il); } break; case LLM_FFN_GEGLU: { cur = ggml_geglu(ctx0, cur); cb(cur, "ffn_geglu", il); } break; case LLM_FFN_REGLU: { cur = ggml_reglu(ctx0, cur); cb(cur, "ffn_reglu", il); } break; default: GGML_ABORT("fatal error"); } if (gate && type_gate == LLM_FFN_PAR) { cur = ggml_mul(ctx0, cur, tmp); cb(cur, "ffn_gate_par", il); } if (down) { cur = build_lora_mm(down, cur); if (arch == LLM_ARCH_GLM4 || arch == LLM_ARCH_GLM4_MOE || arch == LLM_ARCH_JAIS2) { // GLM4, GLM4_MOE, and JAIS2 seem to have numerical issues with half-precision accumulators ggml_mul_mat_set_prec(cur, GGML_PREC_F32); } } if (down_b) { cb(cur, "ffn_down", il); } if (down_b) { cur = ggml_add(ctx0, cur, down_b); } if (down_s) { cur = ggml_mul(ctx0, cur, down_s); cb(cur, "ffn_down_s", il); } return cur; } ggml_tensor * llm_graph_context::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, ggml_tensor * gate_up_exps, ggml_tensor * up_exps_s, ggml_tensor * gate_exps_s, ggml_tensor * down_exps_s) const { return build_moe_ffn( cur, gate_inp, /* gate_inp_b */ nullptr, up_exps, /* up_exps_b */ nullptr, gate_exps, /* gate_exps_b */ nullptr, down_exps, /* down_exps_b */ nullptr, exp_probs_b, n_expert, n_expert_used, type_op, norm_w, w_scale, gating_op, il, probs_in, gate_up_exps, /* gate_up_exps_b */ nullptr, up_exps_s, gate_exps_s, down_exps_s ); } ggml_tensor * llm_graph_context::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, ggml_tensor * gate_up_exps, ggml_tensor * gate_up_exps_b, ggml_tensor * up_exps_s, ggml_tensor * gate_exps_s, ggml_tensor * down_exps_s) const { const int64_t n_embd = cur->ne[0]; const int64_t n_tokens = cur->ne[1]; const bool weight_before_ffn = arch == LLM_ARCH_LLAMA4; // for llama4, we apply the sigmoid-ed weights before the FFN ggml_tensor * logits = nullptr; if (probs_in == nullptr) { logits = build_lora_mm(gate_inp, cur); // [n_expert, n_tokens] cb(logits, "ffn_moe_logits", il); } else { logits = probs_in; } if (gate_inp_b) { logits = ggml_add(ctx0, logits, gate_inp_b); cb(logits, "ffn_moe_logits_biased", il); } ggml_tensor * probs = nullptr; switch (gating_op) { case LLAMA_EXPERT_GATING_FUNC_TYPE_SOFTMAX: { probs = ggml_soft_max(ctx0, logits); // [n_expert, n_tokens] } break; case LLAMA_EXPERT_GATING_FUNC_TYPE_SIGMOID: { probs = ggml_sigmoid(ctx0, logits); // [n_expert, n_tokens] } break; case LLAMA_EXPERT_GATING_FUNC_TYPE_SOFTMAX_WEIGHT: { probs = logits; // [n_expert, n_tokens] } break; default: GGML_ABORT("fatal error"); } cb(probs, "ffn_moe_probs", il); // add experts selection bias - introduced in DeepSeek V3 // leave probs unbiased as it's later used to get expert weights ggml_tensor * selection_probs = probs; if (exp_probs_b != nullptr) { selection_probs = ggml_add(ctx0, probs, exp_probs_b); cb(selection_probs, "ffn_moe_probs_biased", il); } // llama4 doesn't have exp_probs_b, and sigmoid is only used after top_k // see: https://github.com/meta-llama/llama-models/blob/699a02993512fb36936b1b0741e13c06790bcf98/models/llama4/moe.py#L183-L198 if (arch == LLM_ARCH_LLAMA4) { selection_probs = logits; } if (arch == LLM_ARCH_GROVEMOE) { selection_probs = ggml_sigmoid(ctx0, logits); // [n_expert, n_tokens] cb(selection_probs, "ffn_moe_probs_biased", il); } // select top n_group_used expert groups // https://huggingface.co/deepseek-ai/DeepSeek-V3/blob/e815299b0bcbac849fa540c768ef21845365c9eb/modeling_deepseek.py#L440-L457 if (hparams.n_expert_groups > 1 && n_tokens > 0) { const int64_t n_exp_per_group = n_expert / hparams.n_expert_groups; // organize experts into n_expert_groups ggml_tensor * selection_groups = ggml_reshape_3d(ctx0, selection_probs, n_exp_per_group, hparams.n_expert_groups, n_tokens); // [n_exp_per_group, n_expert_groups, n_tokens] ggml_tensor * group_scores = ggml_argsort_top_k(ctx0, selection_groups, 2); // [2, n_expert_groups, n_tokens] group_scores = ggml_get_rows(ctx0, ggml_reshape_4d(ctx0, selection_groups, 1, selection_groups->ne[0], selection_groups->ne[1], selection_groups->ne[2]), group_scores); // [1, 2, n_expert_groups, n_tokens] // get top n_group_used expert groups group_scores = ggml_sum_rows(ctx0, ggml_reshape_3d(ctx0, group_scores, group_scores->ne[1], group_scores->ne[2], group_scores->ne[3])); // [1, n_expert_groups, n_tokens] group_scores = ggml_reshape_2d(ctx0, group_scores, group_scores->ne[1], group_scores->ne[2]); // [n_expert_groups, n_tokens] ggml_tensor * expert_groups = ggml_argsort_top_k(ctx0, group_scores, hparams.n_group_used); // [n_group_used, n_tokens] cb(expert_groups, "ffn_moe_group_topk", il); // mask out the other groups selection_probs = ggml_get_rows(ctx0, selection_groups, expert_groups); // [n_exp_per_group, n_group_used, n_tokens] selection_probs = ggml_set_rows(ctx0, ggml_fill(ctx0, selection_groups, -INFINITY), selection_probs, expert_groups); // [n_exp_per_group, n_expert_groups, n_tokens] selection_probs = ggml_reshape_2d(ctx0, selection_probs, n_expert, n_tokens); // [n_expert, n_tokens] cb(selection_probs, "ffn_moe_probs_masked", il); } // select experts ggml_tensor * selected_experts = ggml_argsort_top_k(ctx0, selection_probs, n_expert_used); // [n_expert_used, n_tokens] cb(selected_experts->src[0], "ffn_moe_argsort", il); cb(selected_experts, "ffn_moe_topk", il); if (arch == LLM_ARCH_GROVEMOE && n_expert != hparams.n_expert) { // TODO: Use scalar div instead when/if implemented ggml_tensor * f_sel = ggml_cast(ctx0, selected_experts, GGML_TYPE_F32); selected_experts = ggml_cast(ctx0, ggml_scale(ctx0, f_sel, 1.0f / float(hparams.n_group_experts)), GGML_TYPE_I32); probs = ggml_reshape_3d(ctx0, probs, 1, hparams.n_expert, n_tokens); } else { probs = ggml_reshape_3d(ctx0, probs, 1, n_expert, n_tokens); } ggml_tensor * weights = ggml_get_rows(ctx0, probs, selected_experts); // [1, n_expert_used, n_tokens] cb(weights, "ffn_moe_weights", il); if (gating_op == LLAMA_EXPERT_GATING_FUNC_TYPE_SOFTMAX_WEIGHT) { weights = ggml_reshape_2d(ctx0, weights, n_expert_used, n_tokens); weights = ggml_soft_max(ctx0, weights); // [n_expert_used, n_tokens] weights = ggml_reshape_3d(ctx0, weights, 1, n_expert_used, n_tokens); cb(weights, "ffn_moe_weights_softmax", il); } if (norm_w) { weights = ggml_reshape_2d(ctx0, weights, n_expert_used, n_tokens); ggml_tensor * weights_sum = ggml_sum_rows(ctx0, weights); // [1, n_tokens] cb(weights_sum, "ffn_moe_weights_sum", il); // Avoid division by zero, clamp to smallest number representable by F16 weights_sum = ggml_clamp(ctx0, weights_sum, 6.103515625e-5, INFINITY); cb(weights_sum, "ffn_moe_weights_sum_clamped", il); weights = ggml_div(ctx0, weights, weights_sum); // [n_expert_used, n_tokens] cb(weights, "ffn_moe_weights_norm", il); weights = ggml_reshape_3d(ctx0, weights, 1, n_expert_used, n_tokens); } if (w_scale != 0.0f && w_scale != 1.0f) { weights = ggml_scale(ctx0, weights, w_scale); cb(weights, "ffn_moe_weights_scaled", il); } //call early so that topk-moe can be used ggml_build_forward_expand(gf, weights); cur = ggml_reshape_3d(ctx0, cur, n_embd, 1, n_tokens); if (weight_before_ffn) { // repeat cur to [n_embd, n_expert_used, n_tokens] ggml_tensor * repeated = ggml_repeat_4d(ctx0, cur, n_embd, n_expert_used, n_tokens, 1); cur = ggml_mul(ctx0, repeated, weights); cb(cur, "ffn_moe_weighted", il); } ggml_tensor * up = nullptr; ggml_tensor * experts = nullptr; if (gate_up_exps) { // merged gate_up path: one mul_mat_id, then split into gate and up views ggml_tensor * gate_up = build_lora_mm_id(gate_up_exps, cur, selected_experts); // [n_ff*2, n_expert_used, n_tokens] cb(gate_up, "ffn_moe_gate_up", il); if (gate_up_exps_b) { gate_up = ggml_add_id(ctx0, gate_up, gate_up_exps_b, selected_experts); cb(gate_up, "ffn_moe_gate_up_biased", il); } // apply per-expert scale2 to merged gate_up (use up_exps_s since gate and up are fused) if (up_exps_s) { ggml_tensor * s = ggml_reshape_3d(ctx0, up_exps_s, 1, n_expert, 1); s = ggml_repeat_4d(ctx0, s, 1, n_expert, n_tokens, 1); s = ggml_get_rows(ctx0, s, selected_experts); // [1, n_expert_used, n_tokens] gate_up = ggml_mul(ctx0, gate_up, s); cb(gate_up, "ffn_moe_gate_up_scaled", il); } const int64_t n_ff = gate_up->ne[0] / 2; cur = ggml_view_3d(ctx0, gate_up, n_ff, gate_up->ne[1], gate_up->ne[2], gate_up->nb[1], gate_up->nb[2], 0); cb(cur, "ffn_moe_gate", il); up = ggml_view_3d(ctx0, gate_up, n_ff, gate_up->ne[1], gate_up->ne[2], gate_up->nb[1], gate_up->nb[2], n_ff * gate_up->nb[0]); cb(up, "ffn_moe_up", il); } else { // separate gate and up path up = build_lora_mm_id(up_exps, cur, selected_experts); // [n_ff, n_expert_used, n_tokens] cb(up, "ffn_moe_up", il); if (up_exps_b) { up = ggml_add_id(ctx0, up, up_exps_b, selected_experts); cb(up, "ffn_moe_up_biased", il); } // apply per-expert scale2 to up if (up_exps_s) { ggml_tensor * s = ggml_reshape_3d(ctx0, up_exps_s, 1, n_expert, 1); s = ggml_repeat_4d(ctx0, s, 1, n_expert, n_tokens, 1); s = ggml_get_rows(ctx0, s, selected_experts); // [1, n_expert_used, n_tokens] up = ggml_mul(ctx0, up, s); cb(up, "ffn_moe_up_scaled", il); } if (gate_exps) { cur = build_lora_mm_id(gate_exps, cur, selected_experts); // [n_ff, n_expert_used, n_tokens] cb(cur, "ffn_moe_gate", il); } else { cur = up; } if (gate_exps_b) { cur = ggml_add_id(ctx0, cur, gate_exps_b, selected_experts); cb(cur, "ffn_moe_gate_biased", il); } // apply per-expert scale2 to gate if (gate_exps_s) { ggml_tensor * s = ggml_reshape_3d(ctx0, gate_exps_s, 1, n_expert, 1); s = ggml_repeat_4d(ctx0, s, 1, n_expert, n_tokens, 1); s = ggml_get_rows(ctx0, s, selected_experts); // [1, n_expert_used, n_tokens] cur = ggml_mul(ctx0, cur, s); cb(cur, "ffn_moe_gate_scaled", il); } } const bool has_gate = gate_exps || gate_up_exps; switch (type_op) { case LLM_FFN_SILU: if (gate_exps) { // Step35: per-layer clamp for routed experts if (arch == LLM_ARCH_STEP35 && il >= 0) { const float limit = hparams.swiglu_clamp_exp[il]; constexpr float eps = 1e-6f; if (limit > eps) { ggml_tensor * gate_act = ggml_silu(ctx0, cur); cb(gate_act, "ffn_moe_silu", il); gate_act = ggml_clamp(ctx0, gate_act, -INFINITY, limit); cb(gate_act, "ffn_moe_silu_clamped", il); up = ggml_clamp(ctx0, up, -limit, limit); cb(up, "ffn_moe_up_clamped", il); cur = ggml_mul(ctx0, gate_act, up); cb(cur, "ffn_moe_swiglu_limited", il); break; } } } if (has_gate) { cur = ggml_swiglu_split(ctx0, cur, up); cb(cur, "ffn_moe_swiglu", il); } else { cur = ggml_silu(ctx0, cur); cb(cur, "ffn_moe_silu", il); } break; case LLM_FFN_GELU: if (has_gate) { cur = ggml_geglu_split(ctx0, cur, up); cb(cur, "ffn_moe_geglu", il); } else { cur = ggml_gelu(ctx0, cur); cb(cur, "ffn_moe_gelu", il); } break; case LLM_FFN_SWIGLU_OAI_MOE: { // TODO: move to hparams? constexpr float alpha = 1.702f; constexpr float limit = 7.0f; cur = ggml_swiglu_oai(ctx0, cur, up, alpha, limit); cb(cur, "ffn_moe_swiglu_oai", il); } break; case LLM_FFN_RELU: if (has_gate) { cur = ggml_reglu_split(ctx0, cur, up); cb(cur, "ffn_moe_reglu", il); } else { cur = ggml_relu(ctx0, cur); cb(cur, "ffn_moe_relu", il); } break; case LLM_FFN_RELU_SQR: if (has_gate) { // TODO: add support for gated squared relu GGML_ABORT("fatal error: gated squared relu not implemented"); } else { cur = ggml_relu(ctx0, cur); cur = ggml_sqr(ctx0, cur); cb(cur, "ffn_moe_relu_sqr", il); } break; default: GGML_ABORT("fatal error"); } experts = build_lora_mm_id(down_exps, cur, selected_experts); // [n_embd, n_expert_used, n_tokens] cb(experts, "ffn_moe_down", il); if (down_exps_b) { experts = ggml_add_id(ctx0, experts, down_exps_b, selected_experts); cb(experts, "ffn_moe_down_biased", il); } // apply per-expert scale2 to down if (down_exps_s) { ggml_tensor * s = ggml_reshape_3d(ctx0, down_exps_s, 1, n_expert, 1); s = ggml_repeat_4d(ctx0, s, 1, n_expert, n_tokens, 1); s = ggml_get_rows(ctx0, s, selected_experts); // [1, n_expert_used, n_tokens] experts = ggml_mul(ctx0, experts, s); cb(experts, "ffn_moe_down_scaled", il); } if (!weight_before_ffn) { experts = ggml_mul(ctx0, experts, weights); cb(experts, "ffn_moe_weighted", il); } ggml_tensor * cur_experts[LLAMA_MAX_EXPERTS] = { nullptr }; assert(n_expert_used > 0); // order the views before the adds for (uint32_t i = 0; i < hparams.n_expert_used; ++i) { cur_experts[i] = ggml_view_2d(ctx0, experts, n_embd, n_tokens, experts->nb[2], i*experts->nb[1]); ggml_build_forward_expand(gf, cur_experts[i]); } // aggregate experts // note: here we explicitly use hparams.n_expert_used instead of n_expert_used // to avoid potentially a large number of add nodes during warmup // ref: https://github.com/ggml-org/llama.cpp/pull/14753 ggml_tensor * moe_out = cur_experts[0]; for (uint32_t i = 1; i < hparams.n_expert_used; ++i) { moe_out = ggml_add(ctx0, moe_out, cur_experts[i]); } if (hparams.n_expert_used == 1) { // avoid returning a non-contiguous tensor moe_out = ggml_cont(ctx0, moe_out); } cb(moe_out, "ffn_moe_out", il); return moe_out; } // input embeddings with optional lora ggml_tensor * llm_graph_context::build_inp_embd(ggml_tensor * tok_embd) const { const int64_t n_embd_inp = hparams.n_embd_inp(); const int64_t n_embd = hparams.n_embd; assert(n_embd_inp >= n_embd); auto inp = std::make_unique(n_embd_inp); inp->tokens = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, ubatch.n_tokens); cb(inp->tokens, "inp_tokens", -1); ggml_set_input(inp->tokens); res->t_inp_tokens = inp->tokens; inp->embd = ggml_new_tensor_2d(ctx0, GGML_TYPE_F32, n_embd_inp, ubatch.n_tokens); cb(inp->embd, "inp_embd", -1); ggml_set_input(inp->embd); // select one of the 2 inputs, based on the batch contents // ref: https://github.com/ggml-org/llama.cpp/pull/18550 std::array inps; // token embeddings path (ubatch.token != nullptr) { auto & cur = inps[0]; cur = ggml_get_rows(ctx0, tok_embd, inp->tokens); // apply lora for embedding tokens if needed for (const auto & lora : *loras) { llama_adapter_lora_weight * lw = lora.first->get_weight(tok_embd); if (lw == nullptr) { continue; } const float adapter_scale = lora.second; const float scale = lw->get_scale(lora.first->alpha, adapter_scale); ggml_tensor * inpL_delta = ggml_scale(ctx0, ggml_mul_mat( ctx0, lw->b, // non-transposed lora_b ggml_get_rows(ctx0, lw->a, inp->tokens) ), scale); cur = ggml_add(ctx0, cur, inpL_delta); } if (n_embd_inp != n_embd) { cur = ggml_pad(ctx0, cur, hparams.n_embd_inp() - n_embd, 0, 0, 0); } } // vector embeddings path (ubatch.embd != nullptr) { auto & cur = inps[1]; cur = inp->embd; } assert(ggml_are_same_shape (inps[0], inps[1])); assert(ggml_are_same_stride(inps[0], inps[1])); ggml_tensor * cur = ggml_build_forward_select(gf, inps.data(), inps.size(), ubatch.token ? 0 : 1); if (n_embd_inp != n_embd) { cur = ggml_view_2d(ctx0, cur, n_embd, n_tokens, cur->nb[1], 0); } res->t_inp_embd = cur; // For Granite architecture if (hparams.f_embedding_scale != 0.0f) { cur = ggml_scale(ctx0, cur, hparams.f_embedding_scale); } cb(cur, "embd", -1); res->add_input(std::move(inp)); // make sure the produced embeddings are immediately materialized in the ggml graph // ref: https://github.com/ggml-org/llama.cpp/pull/18599 ggml_build_forward_expand(gf, cur); return cur; } ggml_tensor * llm_graph_context::build_inp_pos() const { auto inp = std::make_unique(hparams.n_pos_per_embd()); auto & cur = inp->pos; cur = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, (int64_t)n_tokens*hparams.n_pos_per_embd()); ggml_set_input(cur); res->add_input(std::move(inp)); return cur; } ggml_tensor * llm_graph_context::build_inp_attn_scale() const { auto inp = std::make_unique(hparams.n_attn_temp_floor_scale, hparams.f_attn_temp_scale, hparams.f_attn_temp_offset); auto & cur = inp->attn_scale; // this need to be 1x1xN for broadcasting cur = ggml_new_tensor_3d(ctx0, GGML_TYPE_F32, 1, 1, n_tokens); ggml_set_input(cur); ggml_set_name(cur, "attn_scale"); res->add_input(std::move(inp)); return cur; } ggml_tensor * llm_graph_context::build_inp_out_ids() const { // note: when all tokens are output, we could skip this optimization to spare the ggml_get_rows() calls, // but this would make the graph topology depend on the number of output tokens, which can interfere with // features that require constant topology such as pipeline parallelism // ref: https://github.com/ggml-org/llama.cpp/pull/14275#issuecomment-2987424471 //if (n_outputs < n_tokens) { // return nullptr; //} auto inp = std::make_unique(hparams, cparams, n_outputs); auto & cur = inp->out_ids; cur = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, n_outputs); ggml_set_input(cur); res->add_input(std::move(inp)); return cur; } ggml_tensor * llm_graph_context::build_inp_mean() const { auto inp = std::make_unique(cparams); auto & cur = inp->mean; cur = ggml_new_tensor_2d(ctx0, GGML_TYPE_F32, n_tokens, ubatch.n_seqs_unq); ggml_set_input(cur); res->add_input(std::move(inp)); return cur; } ggml_tensor * llm_graph_context::build_inp_cls() const { auto inp = std::make_unique(cparams, arch); auto & cur = inp->cls; cur = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, ubatch.n_seqs_unq); ggml_set_input(cur); res->add_input(std::move(inp)); return cur; } ggml_tensor * llm_graph_context::build_inp_cross_embd() const { auto inp = std::make_unique(cross); auto & cur = inp->cross_embd; // if we have the output embeddings from the encoder, use them directly // TODO: needs more work to be correct, for now just use the tensor shape //if (cross->t_embd) { // cur = ggml_view_tensor(ctx0, cross->t_embd); // return cur; //} const auto n_embd = !cross->v_embd.empty() ? cross->n_embd : hparams.n_embd_inp(); const auto n_enc = !cross->v_embd.empty() ? cross->n_enc : hparams.n_ctx_train; cur = ggml_new_tensor_2d(ctx0, GGML_TYPE_F32, n_embd, n_enc); ggml_set_input(cur); res->add_input(std::move(inp)); return cur; } ggml_tensor * llm_graph_context::build_inp_pos_bucket_enc() const { auto inp = std::make_unique(hparams); auto & cur = inp->pos_bucket; cur = ggml_new_tensor_2d(ctx0, GGML_TYPE_I32, n_tokens, n_tokens); ggml_set_input(cur); res->add_input(std::move(inp)); return cur; } ggml_tensor * llm_graph_context::build_inp_pos_bucket_dec() const { const auto * mctx_cur = static_cast(mctx); auto inp = std::make_unique(hparams, mctx_cur); const auto n_kv = mctx_cur->get_n_kv(); auto & cur = inp->pos_bucket; cur = ggml_new_tensor_2d(ctx0, GGML_TYPE_I32, n_kv, n_tokens); ggml_set_input(cur); res->add_input(std::move(inp)); return cur; } ggml_tensor * llm_graph_context::build_pos_bias(ggml_tensor * pos_bucket, ggml_tensor * attn_rel_b) const { ggml_tensor * pos_bucket_1d = ggml_reshape_1d(ctx0, pos_bucket, pos_bucket->ne[0] * pos_bucket->ne[1]); cb(pos_bucket_1d, "pos_bucket_1d", -1); ggml_tensor * pos_bias = ggml_get_rows(ctx0, attn_rel_b, pos_bucket_1d); pos_bias = ggml_reshape_3d(ctx0, pos_bias, pos_bias->ne[0], pos_bucket->ne[0], pos_bucket->ne[1]); pos_bias = ggml_permute (ctx0, pos_bias, 2, 0, 1, 3); pos_bias = ggml_cont (ctx0, pos_bias); cb(pos_bias, "pos_bias", -1); return pos_bias; } ggml_tensor * llm_graph_context::build_attn_mha( ggml_tensor * q, ggml_tensor * k, ggml_tensor * v, ggml_tensor * kq_b, ggml_tensor * kq_mask, ggml_tensor * sinks, ggml_tensor * v_mla, float kq_scale, int il) const { const bool v_trans = v->nb[1] > v->nb[2]; // split the batch into streams if needed const auto n_stream = k->ne[3]; q = ggml_view_4d(ctx0, q, q->ne[0], q->ne[1], q->ne[2]/n_stream, n_stream, q->nb[1], q->nb[2], q->nb[3]/n_stream, 0); q = ggml_permute(ctx0, q, 0, 2, 1, 3); k = ggml_permute(ctx0, k, 0, 2, 1, 3); v = ggml_permute(ctx0, v, 0, 2, 1, 3); ggml_tensor * cur; const bool use_flash_attn = cparams.flash_attn && kq_b == nullptr; if (use_flash_attn) { GGML_ASSERT(kq_b == nullptr && "Flash attention does not support KQ bias yet"); if (v_trans) { v = ggml_transpose(ctx0, v); } // this can happen when KV cache is not used (e.g. an embedding model with non-causal attn) if (k->type == GGML_TYPE_F32) { k = ggml_cast(ctx0, k, GGML_TYPE_F16); } if (v->type == GGML_TYPE_F32) { v = ggml_cast(ctx0, v, GGML_TYPE_F16); } cur = ggml_flash_attn_ext(ctx0, q, k, v, kq_mask, kq_scale, hparams.f_max_alibi_bias, hparams.attn_soft_cap ? hparams.f_attn_logit_softcapping : 0.0f); cb(cur, LLAMA_TENSOR_NAME_FATTN, il); ggml_flash_attn_ext_add_sinks(cur, sinks); ggml_flash_attn_ext_set_prec (cur, GGML_PREC_F32); if (v_mla) { #if 0 // v_mla can be applied as a matrix-vector multiplication with broadcasting across dimension 3 == n_tokens. // However, the code is optimized for dimensions 0 and 1 being large, so this is inefficient. cur = ggml_reshape_4d(ctx0, cur, v_mla->ne[0], 1, n_head, n_tokens); cur = ggml_mul_mat(ctx0, v_mla, cur); #else // It's preferable to do the calculation as a matrix-matrix multiplication with n_tokens in dimension 1. // The permutations are noops and only change how the tensor data is interpreted. cur = ggml_permute(ctx0, cur, 0, 2, 1, 3); cur = ggml_mul_mat(ctx0, v_mla, cur); cb(cur, "fattn_mla", il); cur = ggml_permute(ctx0, cur, 0, 2, 1, 3); cur = ggml_cont(ctx0, cur); // Needed because ggml_reshape_2d expects contiguous inputs. #endif } cur = ggml_reshape_2d(ctx0, cur, cur->ne[0]*cur->ne[1], cur->ne[2]*cur->ne[3]); } else { ggml_tensor * kq = ggml_mul_mat(ctx0, k, q); cb(kq, "kq", il); // note: this op tends to require high floating point range // while for some models F16 is enough, for others it is not, so we default to F32 here ggml_mul_mat_set_prec(kq, GGML_PREC_F32); if (arch == LLM_ARCH_GROK) { // need to do the following: // multiply by attn_output_multiplier // and then : // kq = 30 * tanh(kq / 30) // before the softmax below kq = ggml_tanh(ctx0, ggml_scale(ctx0, kq, hparams.f_attn_out_scale / hparams.f_attn_logit_softcapping)); cb(kq, "kq_tanh", il); kq = ggml_scale(ctx0, kq, hparams.f_attn_logit_softcapping); cb(kq, "kq_scaled", il); } if (hparams.attn_soft_cap) { kq = ggml_scale(ctx0, kq, 1.0f / hparams.f_attn_logit_softcapping); cb(kq, "kq_scaled_1", il); kq = ggml_tanh (ctx0, kq); cb(kq, "kq_tanh", il); kq = ggml_scale(ctx0, kq, hparams.f_attn_logit_softcapping); cb(kq, "kq_scaled_2", il); } if (kq_b) { kq = ggml_add(ctx0, kq, kq_b); cb(kq, "kq_plus_kq_b", il); } kq = ggml_soft_max_ext(ctx0, kq, kq_mask, kq_scale, hparams.f_max_alibi_bias); ggml_soft_max_add_sinks(kq, sinks); cb(kq, "kq_soft_max", il); if (!v_trans) { // note: avoid this branch v = ggml_cont(ctx0, ggml_transpose(ctx0, v)); cb(v, "v_cont", il); } ggml_tensor * kqv = ggml_mul_mat(ctx0, v, kq); cb(kqv, "kqv", il); // for MLA with the absorption optimization, we need to "decompress" from MQA back to MHA if (v_mla) { kqv = ggml_mul_mat(ctx0, v_mla, kqv); cb(kqv, "kqv_mla", il); } cur = ggml_permute(ctx0, kqv, 0, 2, 1, 3); // recombine streams cur = ggml_cont_2d(ctx0, cur, cur->ne[0]*cur->ne[1], cur->ne[2]*cur->ne[3]); if (!cparams.offload_kqv) { // all nodes between the KV store and the attention output are run on the CPU ggml_backend_sched_set_tensor_backend(sched, cur, backend_cpu); } } ggml_build_forward_expand(gf, cur); return cur; } llm_graph_input_attn_no_cache * llm_graph_context::build_attn_inp_no_cache() const { auto inp = std::make_unique(hparams, cparams); // note: there is no KV cache, so the number of KV values is equal to the number of tokens in the batch inp->self_kq_mask = ggml_new_tensor_4d(ctx0, GGML_TYPE_F32, n_tokens, n_tokens, 1, 1); ggml_set_input(inp->self_kq_mask); inp->self_kq_mask_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp->self_kq_mask, GGML_TYPE_F16) : inp->self_kq_mask; if (hparams.swa_type != LLAMA_SWA_TYPE_NONE) { inp->self_kq_mask_swa = ggml_new_tensor_4d(ctx0, GGML_TYPE_F32, n_tokens, n_tokens, 1, 1); ggml_set_input(inp->self_kq_mask_swa); inp->self_kq_mask_swa_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp->self_kq_mask_swa, GGML_TYPE_F16) : inp->self_kq_mask_swa; } else { inp->self_kq_mask_swa = nullptr; inp->self_kq_mask_swa_cnv = nullptr; } return (llm_graph_input_attn_no_cache *) res->add_input(std::move(inp)); } ggml_tensor * llm_graph_context::build_attn( llm_graph_input_attn_no_cache * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, ggml_tensor * k_cur, ggml_tensor * v_cur, ggml_tensor * kq_b, ggml_tensor * sinks, ggml_tensor * v_mla, float kq_scale, int il) const { GGML_UNUSED(n_tokens); // these nodes are added to the graph together so that they are not reordered // by doing so, the number of splits in the graph is reduced ggml_build_forward_expand(gf, q_cur); ggml_build_forward_expand(gf, k_cur); ggml_build_forward_expand(gf, v_cur); const bool is_swa = hparams.is_swa(il); const auto & kq_mask = is_swa ? inp->get_kq_mask_swa() : inp->get_kq_mask(); // [TAG_NO_CACHE_PAD] // TODO: if ubatch.equal_seqs() == true, we can split the three tensors below into ubatch.n_seqs_unq streams // but it might not be worth it: https://github.com/ggml-org/llama.cpp/pull/15636 //assert(!ubatch.equal_seqs() || (k_cur->ne[3] == 1 && k_cur->ne[3] == ubatch.n_seqs_unq)); ggml_tensor * q = q_cur; ggml_tensor * k = k_cur; ggml_tensor * v = v_cur; ggml_tensor * cur = build_attn_mha(q, k, v, kq_b, kq_mask, sinks, v_mla, kq_scale, il); cb(cur, "kqv_out", il); if (wo) { cur = build_lora_mm(wo, cur); } if (wo_b) { //cb(cur, "kqv_wo", il); } if (wo_b) { cur = ggml_add(ctx0, cur, wo_b); } return cur; } static std::unique_ptr build_attn_inp_kv_impl( ggml_context * ctx0, const llama_ubatch & ubatch, const llama_hparams & hparams, const llama_cparams & cparams, const llama_kv_cache_context * mctx_cur) { auto inp = std::make_unique(hparams, cparams, mctx_cur); { GGML_ASSERT(hparams.swa_type == LLAMA_SWA_TYPE_NONE && "Use llama_kv_cache_iswa for SWA"); inp->self_k_idxs = mctx_cur->build_input_k_idxs(ctx0, ubatch); inp->self_v_idxs = mctx_cur->build_input_v_idxs(ctx0, ubatch); inp->self_kq_mask = build_attn_inp_kq_mask(ctx0, mctx_cur, ubatch, cparams); inp->self_kq_mask_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp->self_kq_mask, GGML_TYPE_F16) : inp->self_kq_mask; } inp->self_k_rot = mctx_cur->build_input_k_rot(ctx0); inp->self_v_rot = mctx_cur->build_input_v_rot(ctx0); return inp; } llm_graph_input_attn_kv * llm_graph_context::build_attn_inp_kv() const { const auto * mctx_cur = static_cast(mctx); auto inp = build_attn_inp_kv_impl(ctx0, ubatch, hparams, cparams, mctx_cur); return (llm_graph_input_attn_kv *) res->add_input(std::move(inp)); } ggml_tensor * llm_graph_context::build_attn( llm_graph_input_attn_kv * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, ggml_tensor * k_cur, ggml_tensor * v_cur, ggml_tensor * kq_b, ggml_tensor * sinks, ggml_tensor * v_mla, // TODO: remove float kq_scale, int il) const { GGML_ASSERT(v_mla == nullptr); if (inp->self_k_rot) { q_cur = ggml_mul_mat_aux(ctx0, q_cur, inp->self_k_rot); k_cur = ggml_mul_mat_aux(ctx0, k_cur, inp->self_k_rot); } if (inp->self_v_rot) { v_cur = ggml_mul_mat_aux(ctx0, v_cur, inp->self_v_rot); } // these nodes are added to the graph together so that they are not reordered // by doing so, the number of splits in the graph is reduced // expand k later to enable rope fusion which directly writes into k-v cache ggml_build_forward_expand(gf, q_cur); ggml_build_forward_expand(gf, v_cur); ggml_build_forward_expand(gf, k_cur); const auto * mctx_cur = inp->mctx; // store to KV cache { const auto & k_idxs = inp->get_k_idxs(); const auto & v_idxs = inp->get_v_idxs(); ggml_build_forward_expand(gf, mctx_cur->cpy_k(ctx0, k_cur, k_idxs, il)); ggml_build_forward_expand(gf, mctx_cur->cpy_v(ctx0, v_cur, v_idxs, il)); } const auto & kq_mask = inp->get_kq_mask(); ggml_tensor * q = q_cur; ggml_tensor * k = mctx_cur->get_k(ctx0, il); ggml_tensor * v = mctx_cur->get_v(ctx0, il); ggml_tensor * cur = build_attn_mha(q, k, v, kq_b, kq_mask, sinks, v_mla, kq_scale, il); cb(cur, "kqv_out", il); if (inp->self_v_rot) { cur = ggml_mul_mat_aux(ctx0, cur, inp->self_v_rot); } if (wo) { cur = build_lora_mm(wo, cur); if (arch == LLM_ARCH_GLM4 || arch == LLM_ARCH_GLM4_MOE || arch == LLM_ARCH_JAIS2) { // GLM4, GLM4_MOE, and JAIS2 seem to have numerical issues with half-precision accumulators ggml_mul_mat_set_prec(cur, GGML_PREC_F32); } } if (wo_b) { cur = ggml_add(ctx0, cur, wo_b); } return cur; } static std::unique_ptr build_attn_inp_k_impl( ggml_context * ctx0, const llama_ubatch & ubatch, const llama_hparams & hparams, const llama_cparams & cparams, const llama_kv_cache_context * mctx_cur) { auto inp = std::make_unique(hparams, cparams, mctx_cur); { GGML_ASSERT(hparams.swa_type == LLAMA_SWA_TYPE_NONE && "Use llama_kv_cache_iswa for SWA"); inp->self_k_idxs = mctx_cur->build_input_k_idxs(ctx0, ubatch); inp->self_kq_mask = build_attn_inp_kq_mask(ctx0, mctx_cur, ubatch, cparams); inp->self_kq_mask_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp->self_kq_mask, GGML_TYPE_F16) : inp->self_kq_mask; } return inp; } llm_graph_input_attn_k * llm_graph_context::build_attn_inp_k() const { const auto * mctx_cur = static_cast(mctx); auto inp = build_attn_inp_k_impl(ctx0, ubatch, hparams, cparams, mctx_cur); return (llm_graph_input_attn_k *) res->add_input(std::move(inp)); } ggml_tensor * llm_graph_context::build_attn( llm_graph_input_attn_k * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, ggml_tensor * k_cur, ggml_tensor * v_cur, ggml_tensor * kq_b, ggml_tensor * sinks, ggml_tensor * v_mla, float kq_scale, int il) const { // these nodes are added to the graph together so that they are not reordered // by doing so, the number of splits in the graph is reduced // expand k later to enable rope fusion which directly writes into k-v cache ggml_build_forward_expand(gf, q_cur); ggml_build_forward_expand(gf, v_cur); ggml_build_forward_expand(gf, k_cur); const auto * mctx_cur = inp->mctx; // store to KV cache { const auto & k_idxs = inp->get_k_idxs(); ggml_build_forward_expand(gf, mctx_cur->cpy_k(ctx0, k_cur, k_idxs, il)); } const auto & kq_mask = inp->get_kq_mask(); ggml_tensor * q = q_cur; ggml_tensor * k = mctx_cur->get_k(ctx0, il); ggml_tensor * v = ggml_view_4d(ctx0, k, v_cur->ne[0], k->ne[1], k->ne[2], k->ne[3], k->nb[1], k->nb[2], k->nb[3], 0); ggml_tensor * cur = build_attn_mha(q, k, v, kq_b, kq_mask, sinks, v_mla, kq_scale, il); cb(cur, "kqv_out", il); if (wo) { cur = build_lora_mm(wo, cur); if (arch == LLM_ARCH_GLM4 || arch == LLM_ARCH_GLM4_MOE) { // GLM4 and GLM4_MOE seem to have numerical issues with half-precision accumulators ggml_mul_mat_set_prec(cur, GGML_PREC_F32); } } if (wo_b) { cur = ggml_add(ctx0, cur, wo_b); } return cur; } ggml_tensor * llm_graph_context::build_attn( llm_graph_input_attn_kv_iswa * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, ggml_tensor * k_cur, ggml_tensor * v_cur, ggml_tensor * kq_b, ggml_tensor * sinks, ggml_tensor * v_mla, float kq_scale, int il) const { if (inp->self_k_rot) { q_cur = ggml_mul_mat_aux(ctx0, q_cur, inp->self_k_rot); if (k_cur) { k_cur = ggml_mul_mat_aux(ctx0, k_cur, inp->self_k_rot); } } if (inp->self_v_rot) { if (v_cur) { v_cur = ggml_mul_mat_aux(ctx0, v_cur, inp->self_v_rot); } } // these nodes are added to the graph together so that they are not reordered // by doing so, the number of splits in the graph is reduced ggml_build_forward_expand(gf, q_cur); if (k_cur) { ggml_build_forward_expand(gf, k_cur); } if (v_cur) { ggml_build_forward_expand(gf, v_cur); } const auto * mctx_iswa = inp->mctx; const bool is_swa = hparams.is_swa(il); const auto * mctx_cur = is_swa ? mctx_iswa->get_swa() : mctx_iswa->get_base(); // optionally store to KV cache if (k_cur) { const auto & k_idxs = is_swa ? inp->get_k_idxs_swa() : inp->get_k_idxs(); ggml_build_forward_expand(gf, mctx_cur->cpy_k(ctx0, k_cur, k_idxs, il)); } if (v_cur) { const auto & v_idxs = is_swa ? inp->get_v_idxs_swa() : inp->get_v_idxs(); ggml_build_forward_expand(gf, mctx_cur->cpy_v(ctx0, v_cur, v_idxs, il)); } const auto & kq_mask = is_swa ? inp->get_kq_mask_swa() : inp->get_kq_mask(); ggml_tensor * q = q_cur; ggml_tensor * k = mctx_cur->get_k(ctx0, il); ggml_tensor * v = mctx_cur->get_v(ctx0, il); ggml_tensor * cur = build_attn_mha(q, k, v, kq_b, kq_mask, sinks, v_mla, kq_scale, il); cb(cur, "kqv_out", il); if (inp->self_v_rot) { cur = ggml_mul_mat_aux(ctx0, cur, inp->self_v_rot); } if (wo) { cur = build_lora_mm(wo, cur); } if (wo_b) { //cb(cur, "kqv_wo", il); } if (wo_b) { cur = ggml_add(ctx0, cur, wo_b); } return cur; } llm_graph_input_attn_cross * llm_graph_context::build_attn_inp_cross() const { auto inp = std::make_unique(cross); const int32_t n_enc = !cross->v_embd.empty() ? cross->n_enc : hparams.n_ctx_train; inp->cross_kq_mask = ggml_new_tensor_4d(ctx0, GGML_TYPE_F32, n_enc, n_tokens, 1, 1); ggml_set_input(inp->cross_kq_mask); inp->cross_kq_mask_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp->cross_kq_mask, GGML_TYPE_F16) : inp->cross_kq_mask; return (llm_graph_input_attn_cross *) res->add_input(std::move(inp)); } ggml_tensor * llm_graph_context::build_attn( llm_graph_input_attn_cross * inp, ggml_tensor * wo, ggml_tensor * wo_b, ggml_tensor * q_cur, ggml_tensor * k_cur, ggml_tensor * v_cur, ggml_tensor * kq_b, ggml_tensor * sinks, ggml_tensor * v_mla, float kq_scale, int il) const { // these nodes are added to the graph together so that they are not reordered // by doing so, the number of splits in the graph is reduced ggml_build_forward_expand(gf, q_cur); ggml_build_forward_expand(gf, k_cur); ggml_build_forward_expand(gf, v_cur); const auto & kq_mask = inp->get_kq_mask_cross(); ggml_tensor * q = q_cur; ggml_tensor * k = k_cur; ggml_tensor * v = v_cur; ggml_tensor * cur = build_attn_mha(q, k, v, kq_b, kq_mask, sinks, v_mla, kq_scale, il); cb(cur, "kqv_out", il); if (wo) { cur = build_lora_mm(wo, cur); } if (wo_b) { //cb(cur, "kqv_wo", il); } if (wo_b) { cur = ggml_add(ctx0, cur, wo_b); } return cur; } // TODO: maybe separate the inner implementation into a separate function // like with the non-sliding window equivalent // once sliding-window hybrid caches are a thing. llm_graph_input_attn_kv_iswa * llm_graph_context::build_attn_inp_kv_iswa() const { const auto * mctx_cur = static_cast(mctx); auto inp = std::make_unique(hparams, cparams, mctx_cur); { inp->self_k_idxs = mctx_cur->get_base()->build_input_k_idxs(ctx0, ubatch); inp->self_v_idxs = mctx_cur->get_base()->build_input_v_idxs(ctx0, ubatch); inp->self_kq_mask = build_attn_inp_kq_mask(ctx0, mctx_cur->get_base(), ubatch, cparams); inp->self_kq_mask_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp->self_kq_mask, GGML_TYPE_F16) : inp->self_kq_mask; } { GGML_ASSERT(hparams.swa_type != LLAMA_SWA_TYPE_NONE && "Use llama_kv_cache for non-SWA"); inp->self_k_idxs_swa = mctx_cur->get_swa()->build_input_k_idxs(ctx0, ubatch); inp->self_v_idxs_swa = mctx_cur->get_swa()->build_input_v_idxs(ctx0, ubatch); inp->self_kq_mask_swa = build_attn_inp_kq_mask(ctx0, mctx_cur->get_swa(), ubatch, cparams); inp->self_kq_mask_swa_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp->self_kq_mask_swa, GGML_TYPE_F16) : inp->self_kq_mask_swa; } inp->self_k_rot = mctx_cur->get_base()->build_input_k_rot(ctx0); inp->self_v_rot = mctx_cur->get_base()->build_input_v_rot(ctx0); return (llm_graph_input_attn_kv_iswa *) res->add_input(std::move(inp)); } ggml_tensor * llm_graph_context::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) const { ggml_tensor * states = ggml_reshape_2d(ctx0, s, state_size, rs_size); // Clear a single state which will then be copied to the other cleared states. // Note that this is a no-op when the view is zero-sized. ggml_tensor * state_zero = ggml_view_1d(ctx0, states, state_size*(rs_zero >= 0), rs_zero*states->nb[1]*(rs_zero >= 0)); ggml_build_forward_expand(gf, ggml_scale_inplace(ctx0, state_zero, 0)); // copy states // NOTE: assuming the copy destinations are ALL contained between rs_head and rs_head + n_rs // {state_size, rs_size} -> {state_size, n_seqs} ggml_tensor * output_states = get_state_rows(ctx0, states, state_copy_main); ggml_build_forward_expand(gf, output_states); // copy extra states which won't be changed further (between n_seqs and n_rs) ggml_tensor * states_extra = ggml_get_rows(ctx0, states, state_copy_extra); ggml_build_forward_expand(gf, ggml_cpy(ctx0, states_extra, ggml_view_1d(ctx0, s, state_size*(n_rs - n_seqs), (rs_head + n_seqs)*state_size*ggml_element_size(s)))); return output_states; } static std::unique_ptr build_rs_inp_impl( ggml_context * ctx0, const llama_ubatch & ubatch, const llama_memory_recurrent_context * mctx_cur) { auto inp = std::make_unique(mctx_cur); const int64_t n_rs = mctx_cur->get_n_rs(); const int64_t n_seqs = ubatch.n_seqs; inp->s_copy = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, n_rs); ggml_set_input(inp->s_copy); inp->s_copy_main = ggml_view_1d(ctx0, inp->s_copy, n_seqs, 0); inp->s_copy_extra = ggml_view_1d(ctx0, inp->s_copy, n_rs - n_seqs, n_seqs * inp->s_copy->nb[0]); inp->head = mctx_cur->get_head(); inp->rs_z = mctx_cur->get_rs_z(); return inp; } llm_graph_input_rs * llm_graph_context::build_rs_inp() const { const auto * mctx_cur = static_cast(mctx); auto inp = build_rs_inp_impl(ctx0, ubatch, mctx_cur); return (llm_graph_input_rs *) res->add_input(std::move(inp)); } ggml_tensor * llm_graph_context::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) const { const auto * kv_state = inp->mctx; return build_rs(s, inp->s_copy_main, inp->s_copy_extra, state_size, n_seqs, kv_state->get_n_rs(), kv_state->get_head(), kv_state->get_size(), kv_state->get_rs_z(), get_state_rows); } ggml_tensor * llm_graph_context::build_rwkv_token_shift_load( llm_graph_input_rs * inp, const llama_ubatch & ubatch, int il) const { const auto * mctx_cur = static_cast(mctx); const auto token_shift_count = hparams.token_shift_count; const int64_t n_seqs = ubatch.n_seqs; ggml_tensor * token_shift_all = mctx_cur->get_r_l(il); ggml_tensor * token_shift = build_rs( inp, token_shift_all, hparams.n_embd_r(), n_seqs); token_shift = ggml_reshape_3d(ctx0, token_shift, hparams.n_embd, token_shift_count, n_seqs); return token_shift; } ggml_tensor * llm_graph_context::build_rwkv_token_shift_store( ggml_tensor * token_shift, const llama_ubatch & ubatch, int il) const { const auto * mctx_cur = static_cast(mctx); const auto token_shift_count = hparams.token_shift_count; const auto n_embd = hparams.n_embd; const int64_t n_seqs = ubatch.n_seqs; const auto kv_head = mctx_cur->get_head(); return ggml_cpy( ctx0, ggml_view_1d(ctx0, token_shift, n_embd * n_seqs * token_shift_count, 0), ggml_view_1d(ctx0, mctx_cur->get_r_l(il), hparams.n_embd_r()*n_seqs, hparams.n_embd_r()*kv_head*ggml_element_size(mctx_cur->get_r_l(il))) ); } llm_graph_input_mem_hybrid * llm_graph_context::build_inp_mem_hybrid() const { const auto * mctx_cur = static_cast(mctx); auto inp_rs = build_rs_inp_impl (ctx0, ubatch, mctx_cur->get_recr()); auto inp_attn = build_attn_inp_kv_impl(ctx0, ubatch, hparams, cparams, mctx_cur->get_attn()); auto inp = std::make_unique(cparams, std::move(inp_attn), std::move(inp_rs), mctx_cur); return (llm_graph_input_mem_hybrid *) res->add_input(std::move(inp)); } llm_graph_input_mem_hybrid_k * llm_graph_context::build_inp_mem_hybrid_k() const { const auto * mctx_cur = static_cast(mctx); auto inp_rs = build_rs_inp_impl (ctx0, ubatch, mctx_cur->get_recr()); auto inp_attn = build_attn_inp_k_impl(ctx0, ubatch, hparams, cparams, mctx_cur->get_attn()); auto inp = std::make_unique(cparams, std::move(inp_attn), std::move(inp_rs), mctx_cur); return (llm_graph_input_mem_hybrid_k *) res->add_input(std::move(inp)); } llm_graph_input_mem_hybrid_iswa * llm_graph_context::build_inp_mem_hybrid_iswa() const { const auto * mctx_cur = static_cast(mctx); auto inp_rs = build_rs_inp_impl(ctx0, ubatch, mctx_cur->get_recr()); // build iswa attention input const auto * attn_ctx = mctx_cur->get_attn(); auto inp_attn = std::make_unique(hparams, cparams, attn_ctx); { inp_attn->self_k_idxs = attn_ctx->get_base()->build_input_k_idxs(ctx0, ubatch); inp_attn->self_v_idxs = attn_ctx->get_base()->build_input_v_idxs(ctx0, ubatch); inp_attn->self_kq_mask = build_attn_inp_kq_mask(ctx0, attn_ctx->get_base(), ubatch, cparams); inp_attn->self_kq_mask_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp_attn->self_kq_mask, GGML_TYPE_F16) : inp_attn->self_kq_mask; } { inp_attn->self_k_idxs_swa = attn_ctx->get_swa()->build_input_k_idxs(ctx0, ubatch); inp_attn->self_v_idxs_swa = attn_ctx->get_swa()->build_input_v_idxs(ctx0, ubatch); inp_attn->self_kq_mask_swa = build_attn_inp_kq_mask(ctx0, attn_ctx->get_swa(), ubatch, cparams); inp_attn->self_kq_mask_swa_cnv = cparams.flash_attn ? ggml_cast(ctx0, inp_attn->self_kq_mask_swa, GGML_TYPE_F16) : inp_attn->self_kq_mask_swa; } auto inp = std::make_unique(cparams, std::move(inp_attn), std::move(inp_rs), mctx_cur); return (llm_graph_input_mem_hybrid_iswa *) res->add_input(std::move(inp)); } void llm_graph_context::build_dense_out( ggml_tensor * dense_2, ggml_tensor * dense_2_b, ggml_tensor * dense_3) const { if (!cparams.embeddings || !(dense_2 || dense_2_b || dense_3)) { return; } ggml_tensor * cur = res->t_embd_pooled != nullptr ? res->t_embd_pooled : res->t_embd; GGML_ASSERT(cur != nullptr && "missing t_embd_pooled/t_embd"); if (dense_2) { cur = ggml_mul_mat(ctx0, dense_2, cur); } if (dense_2_b) { cur = ggml_add(ctx0, cur, dense_2_b); } if (dense_3) { cur = ggml_mul_mat(ctx0, dense_3, cur); } cb(cur, "result_embd_pooled", -1); res->t_embd_pooled = cur; ggml_build_forward_expand(gf, cur); } void llm_graph_context::build_pooling( ggml_tensor * cls, ggml_tensor * cls_b, ggml_tensor * cls_out, ggml_tensor * cls_out_b, ggml_tensor * cls_norm) const { if (!cparams.embeddings) { return; } ggml_tensor * inp = res->t_embd; //// find result_norm tensor for input //for (int i = ggml_graph_n_nodes(gf) - 1; i >= 0; --i) { // inp = ggml_graph_node(gf, i); // if (strcmp(inp->name, "result_norm") == 0 || strcmp(inp->name, "result_embd") == 0) { // break; // } // inp = nullptr; //} GGML_ASSERT(inp != nullptr && "missing result_norm/result_embd tensor"); ggml_tensor * cur; switch (pooling_type) { case LLAMA_POOLING_TYPE_NONE: { cur = inp; } break; case LLAMA_POOLING_TYPE_MEAN: { ggml_tensor * inp_mean = build_inp_mean(); cur = ggml_mul_mat(ctx0, ggml_cont(ctx0, ggml_transpose(ctx0, inp)), inp_mean); } break; case LLAMA_POOLING_TYPE_CLS: case LLAMA_POOLING_TYPE_LAST: { ggml_tensor * inp_cls = build_inp_cls(); cur = ggml_get_rows(ctx0, inp, inp_cls); } break; case LLAMA_POOLING_TYPE_RANK: { if (arch == LLM_ARCH_MODERN_BERT) { // modern bert gte reranker builds mean first then applies prediction head and classifier // https://github.com/huggingface/transformers/blob/main/src/transformers/models/modernbert/modular_modernbert.py#L1404-1411 ggml_tensor * inp_mean = build_inp_mean(); cur = ggml_mul_mat(ctx0, ggml_cont(ctx0, ggml_transpose(ctx0, inp)), inp_mean); } else { ggml_tensor * inp_cls = build_inp_cls(); cur = ggml_get_rows(ctx0, inp, inp_cls); } // classification head // https://github.com/huggingface/transformers/blob/5af7d41e49bbfc8319f462eb45253dcb3863dfb7/src/transformers/models/roberta/modeling_roberta.py#L1566 if (cls) { cur = ggml_mul_mat(ctx0, cls, cur); if (cls_b) { cur = ggml_add(ctx0, cur, cls_b); } if (arch == LLM_ARCH_MODERN_BERT) { cur = ggml_gelu(ctx0, cur); } else { cur = ggml_tanh(ctx0, cur); } if (cls_norm) { // head norm cur = build_norm(cur, cls_norm, NULL, LLM_NORM, -1); } } // some models don't have `cls_out`, for example: https://huggingface.co/jinaai/jina-reranker-v1-tiny-en // https://huggingface.co/jinaai/jina-reranker-v1-tiny-en/blob/cb5347e43979c3084a890e3f99491952603ae1b7/modeling_bert.py#L884-L896 // Single layer classification head (direct projection) // https://github.com/huggingface/transformers/blob/f4fc42216cd56ab6b68270bf80d811614d8d59e4/src/transformers/models/bert/modeling_bert.py#L1476 if (cls_out) { cur = ggml_mul_mat(ctx0, cls_out, cur); if (cls_out_b) { cur = ggml_add(ctx0, cur, cls_out_b); } } // softmax for qwen3 reranker if (arch == LLM_ARCH_QWEN3 || arch == LLM_ARCH_QWEN3VL) { cur = ggml_soft_max(ctx0, cur); } } break; default: { GGML_ABORT("unknown pooling type"); } } cb(cur, "result_embd_pooled", -1); res->t_embd_pooled = cur; ggml_build_forward_expand(gf, cur); } void llm_graph_context::build_sampling() const { if (samplers.empty() || !res->t_logits) { return; } std::array outs; outs[0] = res->t_logits; auto inp_sampling = std::make_unique(samplers); res->add_input(std::move(inp_sampling)); std::map seq_to_logit_row; int32_t logit_row_idx = 0; for (uint32_t i = 0; i < ubatch.n_tokens; i++) { if (ubatch.output[i]) { llama_seq_id seq_id = ubatch.seq_id[i][0]; seq_to_logit_row[seq_id] = logit_row_idx; logit_row_idx++; } } // res->t_logits will contain logits for all tokens that want the logits calculated (logits=1 or output=1) GGML_ASSERT(res->t_logits != nullptr && "missing t_logits tensor"); // add a dummy row of logits // this trick makes the graph static, regardless of which samplers are activated // this is important in order to minimize graph reallocations ggml_tensor * logits_t = ggml_pad(ctx0, res->t_logits, 0, 1, 0, 0); for (const auto & [seq_id, sampler] : samplers) { const auto it = seq_to_logit_row.find(seq_id); // inactive samplers always work on the first row const auto row_idx = it != seq_to_logit_row.end() ? it->second : 0; const int i_out = it != seq_to_logit_row.end() ? 1 : 0; ggml_tensor * logits_seq = ggml_view_1d(ctx0, logits_t, logits_t->ne[0], row_idx * logits_t->nb[1]); ggml_format_name(logits_seq, "logits_seq_%d", seq_id); struct llama_sampler_data data = { /*.logits =*/ logits_seq, /*.probs =*/ nullptr, /*.sampled =*/ nullptr, /*.candidates =*/ nullptr, }; assert(sampler->iface->backend_apply); sampler->iface->backend_apply(sampler, ctx0, gf, &data); if (data.sampled != nullptr) { res->t_sampled[seq_id] = data.sampled; outs[1] = data.sampled; ggml_build_forward_select(gf, outs.data(), outs.size(), i_out); } if (data.probs != nullptr) { res->t_sampled_probs[seq_id] = data.probs; outs[1] = data.probs; ggml_build_forward_select(gf, outs.data(), outs.size(), i_out); } if (data.logits != nullptr) { res->t_sampled_logits[seq_id] = data.logits; outs[1] = data.logits; ggml_build_forward_select(gf, outs.data(), outs.size(), i_out); } if (data.candidates != nullptr) { res->t_candidates[seq_id] = data.candidates; outs[1] = data.candidates; ggml_build_forward_select(gf, outs.data(), outs.size(), i_out); } } // TODO: Call llama_sampler_accept_ggml after all samplers have been applied. /* for (const auto & [seq_id, sampler] : samplers) { if (auto it = res->t_sampled.find(seq_id); it != res->t_sampled.end()) { ggml_tensor * selected_token = it->second; if (selected_token != nullptr) { llama_sampler_accept_ggml(sampler, ctx0, gf, selected_token); } } } */ } int32_t llama_relative_position_bucket(llama_pos x, llama_pos y, uint64_t n_buckets, bool bidirectional) { // TODO move to hparams if a T5 variant appears that uses a different value const int64_t max_distance = 128; if (bidirectional) { n_buckets >>= 1; } const int64_t max_exact = n_buckets >> 1; int32_t relative_position = x - y; int32_t relative_bucket = 0; if (bidirectional) { relative_bucket += (relative_position > 0) * n_buckets; relative_position = std::abs(relative_position); } else { relative_position = -std::min(relative_position, 0); } int32_t relative_position_if_large = floorf(max_exact + logf(1.0 * relative_position / max_exact) * (n_buckets - max_exact) / log(1.0 * max_distance / max_exact)); relative_position_if_large = std::min(relative_position_if_large, n_buckets - 1); relative_bucket += (relative_position < max_exact ? relative_position : relative_position_if_large); return relative_bucket; }