#include "llama-kv-cache.h" #include "llama-impl.h" #include "llama-io.h" #include "llama-model.h" #include "llama-context.h" #include #include #include #include #include #include #include static bool ggml_is_power_of_2(int n) { return (n & (n - 1)) == 0; } // orthonormal Walsh-Hadamard rotation matrix // note: res^2 == I static void ggml_gen_hadamard(ggml_tensor * tensor) { assert(tensor->type == GGML_TYPE_F32); const int n = tensor->ne[0]; assert(ggml_is_power_of_2(n)); assert(tensor->ne[1] == n); assert(tensor->ne[2] == 1); assert(tensor->ne[3] == 1); std::vector data_f32; float * data = (float *) tensor->data; if (tensor->type != GGML_TYPE_F32) { data_f32.resize(n*n); data = data_f32.data(); } data[0*n + 0] = 1.0 / sqrtf(n); for (int s = 1; s < n; s *= 2) { for (int i = 0; i < s; i++) { for (int j = 0; j < s; j++) { const float val = data[i*n + j]; data[(i + s)*n + (j )] = val; data[(i )*n + (j + s)] = val; data[(i + s)*n + (j + s)] = -val; } } } if (tensor->type != GGML_TYPE_F32) { ggml_quantize_chunk(tensor->type, data, tensor->data, 0, 1, n*n, nullptr); } } 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; } // // llama_kv_cache // llama_kv_cache::llama_kv_cache( const llama_model & model, ggml_type type_k, ggml_type type_v, bool v_trans, bool offload, bool unified, uint32_t kv_size, uint32_t n_seq_max, uint32_t n_pad, uint32_t n_swa, llama_swa_type swa_type, const layer_filter_cb & filter, const layer_reuse_cb & reuse) : model(model), hparams(model.hparams), v_trans(v_trans), n_seq_max(n_seq_max), n_stream(unified ? 1 : n_seq_max), n_pad(n_pad), n_swa(n_swa), swa_type(swa_type) { GGML_ASSERT(kv_size % n_pad == 0); const uint32_t n_layer_kv = hparams.n_layer_kv(); // define a comparator for the buft -> ctx map to ensure that the order is well-defined: struct ggml_backend_buft_comparator { bool operator()(const ggml_backend_buffer_type_t & lhs, const ggml_backend_buffer_type_t & rhs) const { return strcmp(ggml_backend_buft_name(lhs), ggml_backend_buft_name(rhs)) < 0; } }; std::map ctx_map; // create a context for each buffer type auto ctx_for_buft = [&](ggml_backend_buffer_type_t buft) -> ggml_context * { auto it = ctx_map.find(buft); if (it == ctx_map.end()) { ggml_init_params params = { /*.mem_size =*/ size_t(2u*(1 + n_stream)*n_layer_kv*ggml_tensor_overhead()), /*.mem_buffer =*/ NULL, /*.no_alloc =*/ true, }; ggml_context * ctx = ggml_init(params); if (!ctx) { return nullptr; } ctx_map.emplace(buft, ctx); return ctx; } return it->second.get(); }; GGML_ASSERT(n_stream == 1 || n_stream == n_seq_max); v_heads.resize(n_stream); for (uint32_t s = 0; s < n_stream; ++s) { v_heads[s] = 0; } v_cells.resize(n_stream); for (uint32_t s = 0; s < n_stream; ++s) { v_cells[s].resize(kv_size); } // by default, all sequence ids are mapped to the 0th stream seq_to_stream.resize(LLAMA_MAX_SEQ, 0); if (n_stream > 1) { seq_to_stream.resize(n_stream, 0); for (uint32_t s = 0; s < n_stream; ++s) { seq_to_stream[s] = s; } } // [TAG_V_CACHE_VARIABLE] if (v_trans && hparams.is_n_embd_v_gqa_variable()) { LLAMA_LOG_WARN("%s: the V embeddings have different sizes across layers and FA is not enabled - padding V cache to %d\n", __func__, hparams.n_embd_v_gqa_max()); } const bool is_mla = hparams.is_mla(); for (uint32_t il = 0; il < hparams.n_layer; il++) { if (!hparams.has_kv(il)) { LLAMA_LOG_DEBUG("%s: layer %3d: does not have KV cache\n", __func__, il); continue; } if (filter && !filter(il)) { LLAMA_LOG_DEBUG("%s: layer %3d: filtered\n", __func__, il); continue; } // [TAG_V_CACHE_VARIABLE] const uint32_t n_embd_k_gqa = hparams.n_embd_k_gqa(il); const uint32_t n_embd_v_gqa = !v_trans ? hparams.n_embd_v_gqa(il) : hparams.n_embd_v_gqa_max(); const char * dev_name = "CPU"; ggml_backend_buffer_type_t buft = ggml_backend_cpu_buffer_type(); if (offload) { auto * dev = model.dev_layer(il); buft = ggml_backend_dev_buffer_type(dev); dev_name = ggml_backend_dev_name(dev); } LLAMA_LOG_DEBUG("%s: layer %3d: dev = %s\n", __func__, il, dev_name); ggml_context * ctx = ctx_for_buft(buft); if (!ctx) { throw std::runtime_error("failed to create ggml context for kv cache"); } const bool has_k = true; const bool has_v = !is_mla; ggml_tensor * k = has_k ? ggml_new_tensor_3d(ctx, type_k, n_embd_k_gqa, kv_size, n_stream) : nullptr; ggml_tensor * v = has_v ? ggml_new_tensor_3d(ctx, type_v, n_embd_v_gqa, kv_size, n_stream) : nullptr; has_k && ggml_format_name(k, "cache_k_l%d", il); has_v && ggml_format_name(v, "cache_v_l%d", il); std::vector k_stream; std::vector v_stream; for (uint32_t s = 0; s < n_stream; ++s) { k_stream.push_back(has_k ? ggml_view_2d(ctx, k, n_embd_k_gqa, kv_size, k->nb[1], s*k->nb[2]) : nullptr); v_stream.push_back(has_v ? ggml_view_2d(ctx, v, n_embd_v_gqa, kv_size, v->nb[1], s*v->nb[2]) : nullptr); } map_layer_ids[il] = layers.size(); layers.push_back({ il, k, v, k_stream, v_stream, }); } if (reuse) { LLAMA_LOG_DEBUG("%s: reusing layers:\n", __func__); for (uint32_t il = 0; il < hparams.n_layer; il++) { const int32_t il_reuse = reuse(il); if (il_reuse < 0) { LLAMA_LOG_DEBUG("%s: - layer %3d: no reuse\n", __func__, il); continue; } if (filter && !filter(il)) { LLAMA_LOG_DEBUG("%s: - layer %3d: filtered\n", __func__, il); continue; } GGML_ASSERT(map_layer_ids.find(il_reuse) != map_layer_ids.end()); map_layer_ids[il] = map_layer_ids[il_reuse]; LLAMA_LOG_DEBUG("%s: - layer %3d: reuse layer %d, is_swa = %d\n", __func__, il, il_reuse, hparams.is_swa(il)); } } // allocate tensors and initialize the buffers to avoid NaNs in the padding for (auto & [buft, ctx] : ctx_map) { ggml_backend_buffer_t buf; if (model.hparams.no_alloc) { buf = ggml_backend_buft_alloc_buffer(buft, /*size =*/ 0); // dummy buffer for (ggml_tensor * t = ggml_get_first_tensor(ctx.get()); t != nullptr; t = ggml_get_next_tensor(ctx.get(), t)) { t->buffer = buf; // set dummy buffer for KV cache so that the backend scheduler won't try to allocate it } } else { buf = ggml_backend_alloc_ctx_tensors_from_buft(ctx.get(), buft); // real buffer } if (!buf) { throw std::runtime_error("failed to allocate buffer for kv cache"); } LLAMA_LOG_INFO("%s: %10s KV buffer size = %8.2f MiB\n", __func__, ggml_backend_buffer_name(buf), ggml_backend_buffer_get_size(buf)/1024.0/1024.0); ggml_backend_buffer_clear(buf, 0); ctxs_bufs.emplace_back(std::move(ctx), buf); } { const size_t memory_size_k = size_k_bytes(); const size_t memory_size_v = size_v_bytes(); LLAMA_LOG_INFO("%s: size = %7.2f MiB (%6u cells, %3d layers, %2u/%u seqs), K (%s): %7.2f MiB, V (%s): %7.2f MiB\n", __func__, (float)(memory_size_k + memory_size_v) / (1024.0f * 1024.0f), kv_size, (int) layers.size(), n_seq_max, n_stream, ggml_type_name(type_k), (float)memory_size_k / (1024.0f * 1024.0f), ggml_type_name(type_v), (float)memory_size_v / (1024.0f * 1024.0f)); } const char * LLAMA_ATTN_ROT_DISABLE = getenv("LLAMA_ATTN_ROT_DISABLE"); const bool attn_rot_disable = LLAMA_ATTN_ROT_DISABLE ? atoi(LLAMA_ATTN_ROT_DISABLE) : false; if (attn_rot_disable) { LLAMA_LOG_WARN("%s: attention rotation force disabled (LLAMA_ATTN_ROT_DISABLE)\n", __func__); } attn_rot_k = !attn_rot_disable && ggml_is_quantized(type_k) && !hparams.is_n_embd_k_gqa_variable() && hparams.n_embd_head_k() % 64 == 0; attn_rot_v = !attn_rot_disable && ggml_is_quantized(type_v) && !hparams.is_n_embd_v_gqa_variable() && hparams.n_embd_head_v() % 64 == 0; LLAMA_LOG_INFO("%s: attn_rot_k = %d\n", __func__, attn_rot_k); LLAMA_LOG_INFO("%s: attn_rot_v = %d\n", __func__, attn_rot_v); // pre-compute the haramard matrices and keep them in host memory // TODO: in the future, we can make copies in the backend buffers to avoid host -> device transfers if (attn_rot_k || attn_rot_v) { for (int64_t n = 64; n <= std::max(hparams.n_embd_head_k(), hparams.n_embd_head_v()); n *= 2) { attn_rot_hadamard[n] = std::vector(n*n); ggml_init_params params = { /* .mem_size = */ 1*ggml_tensor_overhead(), /* .mem_buffer = */ nullptr, /* .no_alloc = */ true, }; ggml_context_ptr ctx { ggml_init(params) }; ggml_tensor * tmp = ggml_new_tensor_2d(ctx.get(), GGML_TYPE_F32, n, n); tmp->data = attn_rot_hadamard[n].data(); ggml_gen_hadamard(tmp); } } const char * LLAMA_KV_CACHE_DEBUG = getenv("LLAMA_KV_CACHE_DEBUG"); debug = LLAMA_KV_CACHE_DEBUG ? atoi(LLAMA_KV_CACHE_DEBUG) : 0; } void llama_kv_cache::clear(bool data) { for (uint32_t s = 0; s < n_stream; ++s) { v_cells[s].reset(); v_heads[s] = 0; } if (data) { for (auto & [_, buf] : ctxs_bufs) { ggml_backend_buffer_clear(buf.get(), 0); } } } bool llama_kv_cache::seq_rm(llama_seq_id seq_id, llama_pos p0, llama_pos p1) { GGML_ASSERT(seq_id == -1 || (seq_id >= 0 && (size_t) seq_id < seq_to_stream.size())); if (p0 < 0) { p0 = 0; } if (p1 < 0) { p1 = std::numeric_limits::max(); } if (seq_id >= 0) { auto & cells = v_cells[seq_to_stream[seq_id]]; auto & head = v_heads[seq_to_stream[seq_id]]; uint32_t new_head = cells.size(); for (uint32_t i = 0; i < cells.size(); ++i) { if (!cells.pos_in(i, p0, p1)) { continue; } if (cells.seq_has(i, seq_id) && cells.seq_rm(i, seq_id)) { if (new_head == cells.size()) { new_head = i; } } } // If we freed up a slot, set head to it so searching can start there. if (new_head != cells.size() && new_head < head) { head = new_head; } } else { // match any sequence for (uint32_t s = 0; s < n_stream; ++s) { auto & cells = v_cells[s]; auto & head = v_heads[s]; uint32_t new_head = cells.size(); for (uint32_t i = 0; i < cells.size(); ++i) { if (!cells.pos_in(i, p0, p1)) { continue; } cells.rm(i); if (new_head == cells.size()) { new_head = i; } } // If we freed up a slot, set head to it so searching can start there. if (new_head != cells.size() && new_head < head) { head = new_head; } } } return true; } void llama_kv_cache::seq_cp(llama_seq_id seq_id_src, llama_seq_id seq_id_dst, llama_pos p0, llama_pos p1) { GGML_ASSERT(seq_id_src >= 0 && (size_t) seq_id_src < seq_to_stream.size()); GGML_ASSERT(seq_id_dst >= 0 && (size_t) seq_id_dst < seq_to_stream.size()); const auto s0 = seq_to_stream[seq_id_src]; const auto s1 = seq_to_stream[seq_id_dst]; if (s0 == s1) { // since both sequences are in the same stream, no data copy is necessary // we just have to update the cells meta data auto & cells = v_cells[s0]; if (seq_id_src == seq_id_dst) { return; } if (p0 < 0) { p0 = 0; } if (p1 < 0) { p1 = std::numeric_limits::max(); } for (uint32_t i = 0; i < cells.size(); ++i) { if (!cells.pos_in(i, p0, p1)) { continue; } if (cells.seq_has(i, seq_id_src)) { cells.seq_add(i, seq_id_dst); } } return; } // cross-stream sequence copies require to copy the actual buffer data bool is_full = true; if (p0 > 0 && p0 + 1 < (int) get_size()) { is_full = false; } if (p1 > 0 && p1 + 1 < (int) get_size()) { is_full = false; } GGML_ASSERT(is_full && "seq_cp() is only supported for full KV buffers"); // enqueue the copy operation - the buffer copy will be performed during the next update sc_info.ssrc.push_back(s0); sc_info.sdst.push_back(s1); v_cells[s1].reset(); for (uint32_t i = 0; i < v_cells[s0].size(); ++i) { if (v_cells[s0].seq_has(i, seq_id_src)) { llama_pos pos = v_cells[s0].pos_get(i); llama_pos shift = v_cells[s0].get_shift(i); llama_kv_cell_ext ext = v_cells[s0].ext_get(i); if (shift != 0) { pos -= shift; assert(pos >= 0); } v_cells[s1].pos_set(i, pos); v_cells[s1].seq_add(i, seq_id_dst); if (shift != 0) { v_cells[s1].pos_add(i, shift); } v_cells[s1].ext_set(i, ext); } } v_heads[s1] = v_heads[s0]; //for (uint32_t s = 0; s < n_stream; ++s) { // LLAMA_LOG_WARN("%s: seq %d: min = %d, max = %d\n", __func__, s, v_cells[s].seq_pos_min(s), v_cells[s].seq_pos_max(s)); //} } void llama_kv_cache::seq_keep(llama_seq_id seq_id) { GGML_ASSERT(seq_id >= 0 && (size_t) seq_id < seq_to_stream.size()); auto & cells = v_cells[seq_to_stream[seq_id]]; auto & head = v_heads[seq_to_stream[seq_id]]; uint32_t new_head = cells.size(); for (uint32_t i = 0; i < cells.size(); ++i) { if (cells.seq_keep(i, seq_id)) { if (new_head == cells.size()) { new_head = i; } } } // If we freed up a slot, set head to it so searching can start there. if (new_head != cells.size() && new_head < head) { head = new_head; } } void llama_kv_cache::seq_add(llama_seq_id seq_id, llama_pos p0, llama_pos p1, llama_pos shift) { GGML_ASSERT(seq_id >= 0 && (size_t) seq_id < seq_to_stream.size()); GGML_ASSERT(hparams.n_pos_per_embd() == 1 && "seq_add() is only supported for n_pos_per_embd() == 1"); auto & cells = v_cells[seq_to_stream[seq_id]]; auto & head = v_heads[seq_to_stream[seq_id]]; if (shift == 0) { return; } uint32_t new_head = cells.size(); if (p0 < 0) { p0 = 0; } if (p1 < 0) { p1 = std::numeric_limits::max(); } // If there is no range then return early to avoid looping over all cells. if (p0 == p1) { return; } for (uint32_t i = 0; i < cells.size(); ++i) { if (!cells.pos_in(i, p0, p1)) { continue; } if (cells.seq_has(i, seq_id)) { if (cells.pos_add(i, shift)) { if (new_head == cells.size()) { new_head = i; } } } } // If we freed up a slot, set head to it so searching can start there. // Otherwise we just start the next search from the beginning. head = new_head != cells.size() ? new_head : 0; } void llama_kv_cache::seq_div(llama_seq_id seq_id, llama_pos p0, llama_pos p1, int d) { GGML_ASSERT(seq_id >= 0 && (size_t) seq_id < seq_to_stream.size()); GGML_ASSERT(hparams.n_pos_per_embd() == 1 && "seq_div() is only supported for n_pos_per_embd() == 1"); auto & cells = v_cells[seq_to_stream[seq_id]]; if (d == 1) { return; } if (p0 < 0) { p0 = 0; } if (p1 < 0) { p1 = std::numeric_limits::max(); } // If there is no range then return early to avoid looping over the cache. if (p0 == p1) { return; } for (uint32_t i = 0; i < cells.size(); ++i) { if (!cells.pos_in(i, p0, p1)) { continue; } if (cells.seq_has(i, seq_id)) { cells.pos_div(i, d); } } } llama_pos llama_kv_cache::seq_pos_min(llama_seq_id seq_id) const { GGML_ASSERT(seq_id >= 0 && (size_t) seq_id < seq_to_stream.size()); const auto & cells = v_cells[seq_to_stream[seq_id]]; return cells.seq_pos_min(seq_id); } llama_pos llama_kv_cache::seq_pos_max(llama_seq_id seq_id) const { GGML_ASSERT(seq_id >= 0 && (size_t) seq_id < seq_to_stream.size()); const auto & cells = v_cells[seq_to_stream[seq_id]]; return cells.seq_pos_max(seq_id); } std::map llama_kv_cache::memory_breakdown() const { std::map ret; for (const auto & [ctx, buf] : ctxs_bufs) { ggml_backend_buffer_type_t buft = ggml_backend_buffer_get_type(buf.get()); if (hparams.no_alloc) { GGML_ASSERT(ggml_backend_buffer_get_base(buf.get()) == nullptr); ret[buft] += ggml_backend_alloc_ctx_tensors_from_buft_size(ctx.get(), buft); } else { // GGML_ASSERT(ggml_backend_buffer_get_base(buf.get()) != nullptr); // multi_buffer does not have a defined base ret[buft] += ggml_backend_buffer_get_size(buf.get()); } } return ret; } llama_memory_context_ptr llama_kv_cache::init_batch( llama_batch_allocr & balloc, uint32_t n_ubatch, bool embd_all) { GGML_UNUSED(embd_all); do { balloc.split_reset(); std::vector ubatches; while (true) { auto ubatch = n_stream == 1 ? balloc.split_simple(n_ubatch) : balloc.split_equal(n_ubatch, true); if (ubatch.n_tokens == 0) { break; } ubatches.push_back(std::move(ubatch)); // NOLINT } if (balloc.get_n_used() < balloc.get_n_tokens()) { // failed to find a suitable split break; } auto sinfos = prepare(ubatches); if (sinfos.empty()) { break; } return std::make_unique( this, std::move(sinfos), std::move(ubatches)); } while (false); return std::make_unique(LLAMA_MEMORY_STATUS_FAILED_PREPARE); } llama_memory_context_ptr llama_kv_cache::init_full() { return std::make_unique(this); } llama_memory_context_ptr llama_kv_cache::init_update(llama_context * lctx, bool optimize) { GGML_UNUSED(optimize); bool do_shift = get_has_shift(); return std::make_unique(this, lctx, do_shift, std::move(sc_info)); } llama_kv_cache::slot_info_vec_t llama_kv_cache::prepare(const std::vector & ubatches) { llama_kv_cache::slot_info_vec_t res; struct state_t { slot_info sinfo; // slot info for the ubatch std::vector v_heads_old; // old positions of the heads, before placing the ubatch std::vector v_cells; // copy of the old cells, before placing the ubatch }; // remember the old state of the cells so we can restore it in the end std::vector states; bool success = true; for (const auto & ubatch : ubatches) { // only find a suitable slot for the ubatch. don't modify the cells yet const auto sinfo_new = find_slot(ubatch, false); if (sinfo_new.empty()) { success = false; break; } // remember the position that we found res.push_back(sinfo_new); // store the old state of the cells in the recovery stack { state_t state = { sinfo_new, v_heads, {} }; for (uint32_t s = 0; s < sinfo_new.n_stream(); ++s) { auto & cells = v_cells[sinfo_new.strm[s]]; state.v_cells.push_back(cells.cp(sinfo_new.idxs[s])); } states.push_back(std::move(state)); } // now emplace the ubatch apply_ubatch(sinfo_new, ubatch); } GGML_ASSERT(!states.empty() || !success); // iterate backwards and restore the cells to their original state for (auto it = states.rbegin(); it != states.rend(); ++it) { const auto & sinfo = it->sinfo; for (uint32_t s = 0; s < sinfo.n_stream(); ++s) { auto & cells = v_cells[sinfo.strm[s]]; auto & head = v_heads[sinfo.strm[s]]; cells.set(sinfo.idxs[s], it->v_cells[s]); head = it->v_heads_old[s]; } } if (!success) { return {}; } return res; } bool llama_kv_cache::update(llama_context * lctx, bool do_shift, const stream_copy_info & sc_info) { bool updated = false; auto * sched = lctx->get_sched(); if (!sc_info.empty()) { assert(n_stream > 1 && "stream copy should never happen with a single stream"); llama_synchronize(lctx); const size_t n_copy = sc_info.ssrc.size(); for (size_t i = 0; i < n_copy; ++i) { const auto ssrc = sc_info.ssrc[i]; const auto sdst = sc_info.sdst[i]; assert(ssrc < n_stream); assert(sdst < n_stream); LLAMA_LOG_DEBUG("%s: copying KV buffer: stream %d to stream %d\n", __func__, ssrc, sdst); assert(ssrc != sdst); for (uint32_t il = 0; il < layers.size(); ++il) { const auto & layer = layers[il]; ggml_backend_tensor_copy(layer.k_stream[ssrc], layer.k_stream[sdst]); if (layer.v_stream[ssrc]) { ggml_backend_tensor_copy(layer.v_stream[ssrc], layer.v_stream[sdst]); } } } } if (do_shift) { if (!get_can_shift()) { GGML_ABORT("The current KV cache / model configuration does not support K-shift"); } LLAMA_LOG_DEBUG("%s: applying K-shift\n", __func__); // apply K-shift if needed if (hparams.rope_type != LLAMA_ROPE_TYPE_NONE) { ggml_backend_sched_reset(sched); auto * res = lctx->get_gf_res_reserve(); res->reset(); auto * gf = build_graph_shift(res, lctx); if (!ggml_backend_sched_alloc_graph(sched, gf)) { LLAMA_LOG_ERROR("%s: failed to allocate compute graph for K-shift\n", __func__); return updated; } res->set_inputs(nullptr); if (lctx->graph_compute(gf, false) != GGML_STATUS_SUCCESS) { LLAMA_LOG_ERROR("%s: failed to compute K-shift\n", __func__); return updated; } updated = true; } for (uint32_t s = 0; s < n_stream; ++s) { auto & cells = v_cells[s]; cells.reset_shift(); } } return updated; } llama_kv_cache::slot_info llama_kv_cache::find_slot(const llama_ubatch & ubatch, bool cont) const { if (debug > 0) { for (uint32_t s = 0; s < ubatch.n_seqs_unq; ++s) { const auto seq_id = ubatch.seq_id_unq[s]; const auto stream_id = seq_to_stream[seq_id]; const auto & cells = v_cells[stream_id]; const uint32_t head_cur = v_heads[stream_id]; LLAMA_LOG_DEBUG("%s: stream[%d], n = %5d, used = %5d, head = %5d, size = %5d, n_swa = %5d\n", __func__, stream_id, cells.used_max_p1(), cells.get_used(), head_cur, get_size(), n_swa); if ((debug == 2 && n_swa > 0) || debug > 2) { std::string ss; for (uint32_t i = 0; i < cells.size(); ++i) { if (cells.is_empty(i)) { ss += '.'; } else { assert(cells.seq_count(i) >= 1); if (cells.seq_count(i) == 1) { ss += std::to_string(cells.seq_get(i)); } else { ss += 'M'; } } if (i%256 == 255) { ss += " *"; ss += '\n'; } } LLAMA_LOG_DEBUG("\n%s\n", ss.c_str()); } if ((debug == 2 && n_swa > 0) || debug > 2) { std::string ss; for (uint32_t i = 0; i < cells.size(); ++i) { std::string cur; if (cells.is_empty(i)) { cur = '.'; } else { cur = std::to_string(cells.pos_get(i)); } const int n = cur.size(); for (int j = 0; j < 5 - n; ++j) { cur += ' '; } ss += cur; if (i%256 == 255) { ss += " *"; } if (i%64 == 63) { ss += '\n'; } } LLAMA_LOG_DEBUG("\n%s\n", ss.c_str()); } for (int s = 0; s < LLAMA_MAX_SEQ; ++s) { if (cells.seq_pos_min(s) < 0) { continue; } LLAMA_LOG_DEBUG("%s: stream[%d] min[%d] = %5d, max[%d] = %5d\n", __func__, stream_id, s, cells.seq_pos_min(s), s, cells.seq_pos_max(s)); } } } uint32_t n_tokens = ubatch.n_tokens; uint32_t n_seqs = 1; if (n_stream > 1) { GGML_ASSERT(n_tokens % ubatch.n_seqs_unq == 0); n_seqs = ubatch.n_seqs_unq; n_tokens = n_tokens / n_seqs; } slot_info res = { /*.s0 =*/ LLAMA_MAX_SEQ, /*.s1 =*/ 0, /*.strm =*/ { }, /*.idxs =*/ { }, }; res.resize(n_seqs); for (uint32_t s = 0; s < n_seqs; ++s) { const auto seq_id = ubatch.seq_id_unq[s]; if (n_stream > 1) { GGML_ASSERT(ubatch.n_seq_id[s*n_tokens] == 1); GGML_ASSERT(ubatch.seq_id [s*n_tokens][0] == seq_id); } res.s0 = std::min(res.s0, seq_to_stream[seq_id]); res.s1 = std::max(res.s1, seq_to_stream[seq_id]); res.strm[s] = seq_to_stream[seq_id]; res.idxs[s].reserve(n_tokens); const auto & cells = v_cells[seq_to_stream[seq_id]]; uint32_t head_cur = v_heads[seq_to_stream[seq_id]]; // if we have enough unused cells before the current head -> // better to start searching from the beginning of the cache, hoping to fill it if (head_cur > cells.get_used() + 2*n_tokens) { head_cur = 0; } if (n_tokens > cells.size()) { LLAMA_LOG_ERROR("%s: n_tokens = %d > size = %u\n", __func__, n_tokens, cells.size()); return { }; } uint32_t n_tested = 0; // for continuous slots, we test that all tokens in the ubatch fit, starting from the current head // for non-continuous slots, we test the tokens one by one const uint32_t n_test = cont ? n_tokens : 1; while (true) { if (head_cur + n_test > cells.size()) { n_tested += cells.size() - head_cur; head_cur = 0; continue; } for (uint32_t i = 0; i < n_test; i++) { const auto idx = head_cur; head_cur++; n_tested++; //const llama_pos pos = ubatch.pos[i]; //const llama_seq_id seq_id = ubatch.seq_id[i][0]; // can we use this cell? either: // - the cell is empty // - the cell is occupied only by one sequence: // - (disabled) mask causally, if the sequence is the same as the one we are inserting // - mask SWA, using current max pos for that sequence in the cache // always insert in the cell with minimum pos bool can_use = cells.is_empty(idx); if (!can_use && cells.seq_count(idx) == 1) { const llama_pos pos_cell = cells.pos_get(idx); // (disabled) causal mask // note: it's better to purge any "future" tokens beforehand //if (cells.seq_has(idx, seq_id)) { // can_use = pos_cell >= pos; //} if (!can_use) { const llama_seq_id seq_id_cell = cells.seq_get(idx); // SWA mask if (llama_hparams::is_masked_swa(n_swa, swa_type, pos_cell, cells.seq_pos_max(seq_id_cell) + 1)) { can_use = true; } } } if (can_use) { res.idxs[s].push_back(idx); } else { if (cont) { break; } } } if (res.idxs[s].size() == n_tokens) { break; } if (cont) { res.idxs[s].clear(); } if (n_tested >= cells.size()) { //LLAMA_LOG_ERROR("%s: failed to find a slot for %d tokens\n", __func__, n_tokens); return { }; } } // we didn't find a suitable slot - return empty result if (res.idxs[s].size() < n_tokens) { return { }; } } assert(res.s1 >= res.s0); return res; } void llama_kv_cache::apply_ubatch(const slot_info & sinfo, const llama_ubatch & ubatch) { // keep track of the max sequence position that we would overwrite with this ubatch // for non-SWA cache, this would be always empty llama_seq_id seq_pos_max_rm[LLAMA_MAX_SEQ]; for (uint32_t s = 0; s < LLAMA_MAX_SEQ; ++s) { seq_pos_max_rm[s] = -1; } assert(ubatch.n_tokens == sinfo.n_stream()*sinfo.size()); for (uint32_t s = 0; s < sinfo.n_stream(); ++s) { for (uint32_t ii = 0; ii < sinfo.size(); ++ii) { const uint32_t i = s*sinfo.size() + ii; auto & cells = v_cells[sinfo.strm[s]]; const auto idx = sinfo.idxs[s][ii]; if (!cells.is_empty(idx)) { assert(cells.seq_count(idx) == 1); const llama_seq_id seq_id = cells.seq_get(idx); const llama_pos pos = cells.pos_get(idx); seq_pos_max_rm[seq_id] = std::max(seq_pos_max_rm[seq_id], pos); cells.rm(idx); } cells.pos_set(idx, ubatch.pos[i]); if (ubatch.is_pos_2d()) { llama_kv_cell_ext ext { /*.x =*/ ubatch.pos[i + ubatch.n_tokens*2], /*.y =*/ ubatch.pos[i + ubatch.n_tokens], }; cells.ext_set(idx, ext); } for (int32_t s = 0; s < ubatch.n_seq_id[i]; s++) { cells.seq_add(idx, ubatch.seq_id[i][s]); } } } // note: we want to preserve the invariant that all positions between [pos_min, pos_max] for each sequence // will be present in the cache. so we have to purge any position which is less than those we would overwrite // ref: https://github.com/ggml-org/llama.cpp/pull/13746#issuecomment-2916057092 for (uint32_t s = 0; s < LLAMA_MAX_SEQ; ++s) { if (seq_pos_max_rm[s] == -1) { continue; } GGML_ASSERT(s < seq_to_stream.size()); auto & cells = v_cells[seq_to_stream[s]]; if (cells.seq_pos_min(s) <= seq_pos_max_rm[s]) { LLAMA_LOG_DEBUG("%s: purging positions [%d, %d] of sequence %d from KV cache\n", __func__, cells.seq_pos_min(s), seq_pos_max_rm[s], s); seq_rm(s, cells.seq_pos_min(s), seq_pos_max_rm[s] + 1); } } // move the head at the end of the slot for (uint32_t s = 0; s < sinfo.n_stream(); ++s) { auto & head = v_heads[sinfo.strm[s]]; head = sinfo.idxs[s].back() + 1; } } bool llama_kv_cache::get_can_shift() const { // Step35 uses per-layer RoPE dims; K-shift assumes a single global n_rot. if (model.arch == LLM_ARCH_STEP35) { return false; } if (hparams.n_pos_per_embd() > 1) { return false; } return true; } uint32_t llama_kv_cache::get_size() const { const auto & cells = v_cells[seq_to_stream[0]]; return cells.size(); } uint32_t llama_kv_cache::get_n_stream() const { return n_stream; } bool llama_kv_cache::get_has_shift() const { bool result = false; for (uint32_t s = 0; s < n_stream; ++s) { result |= v_cells[s].get_has_shift(); } return result; } ggml_type llama_kv_cache::type_k() const { return layers[0].k->type; } ggml_type llama_kv_cache::type_v() const { return layers[0].v->type; } uint32_t llama_kv_cache::get_n_kv(const slot_info & sinfo) const { uint32_t result = 0; // pad the n_kv value so that the graph remains constant across batches and can be reused // note: this also helps some backends with performance (f.ex https://github.com/ggml-org/llama.cpp/pull/16812#issuecomment-3455112220) const uint32_t n_pad_cur = std::max(n_pad, 256u); for (uint32_t s = 0; s < sinfo.n_stream(); ++s) { const auto & cells = v_cells[sinfo.strm[s]]; result = std::max(std::min(cells.size(), std::max(n_pad_cur, GGML_PAD(cells.used_max_p1(), n_pad_cur))), result); } return result; } ggml_tensor * llama_kv_cache::get_k(ggml_context * ctx, int32_t il, uint32_t n_kv, const slot_info & sinfo) const { const int32_t ikv = map_layer_ids.at(il); auto * k = layers[ikv].k; const uint64_t kv_size = get_size(); const uint64_t n_embd_k_gqa = k->ne[0]; assert(n_embd_k_gqa == hparams.n_embd_k_gqa(il)); const uint32_t ns = sinfo.s1 - sinfo.s0 + 1; return ggml_view_4d(ctx, k, hparams.n_embd_head_k(il), hparams.n_head_kv(il), n_kv, ns, ggml_row_size(k->type, hparams.n_embd_head_k(il)), ggml_row_size(k->type, n_embd_k_gqa), ggml_row_size(k->type, n_embd_k_gqa*kv_size), ggml_row_size(k->type, n_embd_k_gqa*kv_size)*sinfo.s0); } ggml_tensor * llama_kv_cache::get_v(ggml_context * ctx, int32_t il, uint32_t n_kv, const slot_info & sinfo) const { const int32_t ikv = map_layer_ids.at(il); auto * v = layers[ikv].v; const uint64_t kv_size = get_size(); const uint64_t n_embd_v_gqa = v->ne[0]; // [TAG_V_CACHE_VARIABLE] assert(n_embd_v_gqa >= hparams.n_embd_v_gqa(il)); const uint32_t ns = sinfo.s1 - sinfo.s0 + 1; if (!v_trans) { // note: v->nb[1] <= v->nb[2] return ggml_view_4d(ctx, v, hparams.n_embd_head_v(il), hparams.n_head_kv(il), n_kv, ns, ggml_row_size(v->type, hparams.n_embd_head_v(il)), // v->nb[1] ggml_row_size(v->type, n_embd_v_gqa), // v->nb[2] ggml_row_size(v->type, n_embd_v_gqa*kv_size), // v->nb[3] ggml_row_size(v->type, n_embd_v_gqa*kv_size)*sinfo.s0); } // note: v->nb[1] > v->nb[2] return ggml_view_4d(ctx, v, n_kv, hparams.n_head_kv(il), hparams.n_embd_head_v(il), ns, ggml_row_size(v->type, kv_size*hparams.n_embd_head_v(il)), // v->nb[1] ggml_row_size(v->type, kv_size), // v->nb[2] ggml_row_size(v->type, kv_size*n_embd_v_gqa), // v->nb[3] ggml_row_size(v->type, kv_size*n_embd_v_gqa)*sinfo.s0); } ggml_tensor * llama_kv_cache::cpy_k(ggml_context * ctx, ggml_tensor * k_cur, ggml_tensor * k_idxs, int32_t il, const slot_info & sinfo) const { GGML_UNUSED(sinfo); const int32_t ikv = map_layer_ids.at(il); ggml_tensor * k = layers[ikv].k; const int64_t n_embd_head = k_cur->ne[0]; const int64_t n_head = k_cur->ne[1]; const int64_t n_tokens = k_cur->ne[2]; const int64_t n_embd_gqa = n_embd_head*n_head; // we can merge dims 0 and 1 // TODO: add ggml helper function for this? GGML_ASSERT(ggml_row_size(k_cur->type, n_embd_head) == k_cur->nb[1]); k_cur = ggml_view_2d(ctx, k_cur, n_embd_gqa, n_tokens, k_cur->nb[2], 0); const int64_t n_stream = k->ne[2]; if (n_stream > 1) { const int64_t kv_size = get_size(); assert(n_embd_gqa == k->ne[0]); assert(kv_size == k->ne[1]); // merge the buffer across all streams because the idxs are global k = ggml_reshape_2d(ctx, k, n_embd_gqa, kv_size*n_stream); } // store the current K values into the cache return ggml_set_rows(ctx, k, k_cur, k_idxs); } ggml_tensor * llama_kv_cache::cpy_v(ggml_context * ctx, ggml_tensor * v_cur, ggml_tensor * v_idxs, int32_t il, const slot_info & sinfo) const { GGML_UNUSED(sinfo); const int32_t ikv = map_layer_ids.at(il); auto * v = layers[ikv].v; const int64_t n_embd_head = v_cur->ne[0]; const int64_t n_head = v_cur->ne[1]; const int64_t n_tokens = v_cur->ne[2]; const int64_t n_embd_gqa = n_embd_head*n_head; // we can merge dims 0 and 1 GGML_ASSERT(ggml_row_size(v_cur->type, n_embd_head) == v_cur->nb[1]); const int64_t n_stream = v->ne[2]; // take this branch when FA is enabled (the V cache is not transposed) if (!v_trans) { v_cur = ggml_view_2d(ctx, v_cur, n_embd_gqa, n_tokens, v_cur->nb[2], 0); if (n_stream > 1) { const int64_t kv_size = get_size(); assert(n_embd_gqa == v->ne[0]); assert(kv_size == v->ne[1]); // merge the buffer across all streams because the idxs are global v = ggml_reshape_2d(ctx, v, n_embd_gqa, kv_size*n_stream); } return ggml_set_rows(ctx, v, v_cur, v_idxs); } if (ggml_row_size(v_cur->type, n_embd_gqa) == v_cur->nb[2]) { // we can merge dims 0, 1 and 2 v_cur = ggml_reshape_2d(ctx, v_cur, n_embd_gqa, n_tokens); } else { // otherwise -> make a copy to get contiguous data v_cur = ggml_cont_2d (ctx, v_cur, n_embd_gqa, n_tokens); } // [TAG_V_CACHE_VARIABLE] if (n_embd_gqa < v->ne[0]) { v_cur = ggml_pad(ctx, v_cur, v->ne[0] - n_embd_gqa, 0, 0, 0); } // in this branch the v_idxs are constructed in such a way that each row is a single head element ggml_tensor * v_view = ggml_reshape_2d(ctx, v, 1, ggml_nelements(v)); v_cur = ggml_reshape_2d(ctx, v_cur, 1, ggml_nelements(v_cur)); return ggml_set_rows(ctx, v_view, v_cur, v_idxs); } ggml_tensor * llama_kv_cache::build_input_k_idxs(ggml_context * ctx, const llama_ubatch & ubatch) const { const uint32_t n_tokens = ubatch.n_tokens; ggml_tensor * k_idxs = ggml_new_tensor_1d(ctx, GGML_TYPE_I64, n_tokens); ggml_set_input(k_idxs); return k_idxs; } ggml_tensor * llama_kv_cache::build_input_v_idxs(ggml_context * ctx, const llama_ubatch & ubatch) const { const uint32_t n_tokens = ubatch.n_tokens; ggml_tensor * v_idxs; if (!v_trans) { v_idxs = ggml_new_tensor_1d(ctx, GGML_TYPE_I64, n_tokens); } else { v_idxs = ggml_new_tensor_1d(ctx, GGML_TYPE_I64, n_tokens*hparams.n_embd_v_gqa_max()); } ggml_set_input(v_idxs); return v_idxs; } ggml_tensor * llama_kv_cache::build_input_k_rot(ggml_context * ctx) const { ggml_tensor * res = nullptr; if (attn_rot_k) { int nrot = 64; // TODO: investigate if using the smallest rotation matrix is beneficial also for K (similar as for V) // ref: https://github.com/ggml-org/llama.cpp/pull/21038#issuecomment-4141323088 do { nrot *= 2; } while (hparams.n_embd_head_k() % nrot == 0); nrot /= 2; res = ggml_new_tensor_2d(ctx, GGML_TYPE_F32, nrot, nrot); ggml_set_input(res); ggml_set_name(res, "attn_inp_k_rot"); } return res; } ggml_tensor * llama_kv_cache::build_input_v_rot(ggml_context * ctx) const { ggml_tensor * res = nullptr; if (attn_rot_v) { int nrot = 64; // using smaller rotation matrices for V seems beneficial // ref: https://github.com/ggml-org/llama.cpp/pull/21038#issuecomment-4146397570 //do { // nrot *= 2; //} while (hparams.n_embd_head_v() % nrot == 0); //nrot /= 2; res = ggml_new_tensor_2d(ctx, GGML_TYPE_F32, nrot, nrot); ggml_set_input(res); ggml_set_name(res, "attn_inp_v_rot"); } return res; } void llama_kv_cache::set_input_k_idxs(ggml_tensor * dst, const llama_ubatch * ubatch, const slot_info & sinfo) const { const uint32_t n_tokens = ubatch->n_tokens; GGML_ASSERT(n_tokens == (int64_t) sinfo.size()*sinfo.n_stream()); GGML_ASSERT(ggml_backend_buffer_is_host(dst->buffer)); int64_t * data = (int64_t *) dst->data; for (uint32_t s = 0; s < sinfo.n_stream(); ++s) { const int64_t offs = sinfo.strm[s]*get_size(); for (uint32_t i = 0; i < sinfo.size(); ++i) { data[s*sinfo.size() + i] = offs + sinfo.idxs[s][i]; } } } void llama_kv_cache::set_input_v_idxs(ggml_tensor * dst, const llama_ubatch * ubatch, const slot_info & sinfo) const { const uint32_t n_tokens = ubatch->n_tokens; GGML_ASSERT(n_tokens == (int64_t) sinfo.size()*sinfo.n_stream()); GGML_ASSERT(ggml_backend_buffer_is_host(dst->buffer)); int64_t * data = (int64_t *) dst->data; if (!v_trans) { for (uint32_t s = 0; s < sinfo.n_stream(); ++s) { const int64_t offs = sinfo.strm[s]*get_size(); for (uint32_t i = 0; i < sinfo.size(); ++i) { data[s*sinfo.size() + i] = offs + sinfo.idxs[s][i]; } } } else { // note: the V cache is transposed when not using flash attention const int64_t kv_size = get_size(); const int64_t n_embd_v_gqa = hparams.n_embd_v_gqa_max(); for (uint32_t s = 0; s < sinfo.n_stream(); ++s) { const int64_t offs = sinfo.strm[s]*kv_size*n_embd_v_gqa; for (uint32_t i = 0; i < sinfo.size(); ++i) { for (uint32_t j = 0; j < n_embd_v_gqa; ++j) { data[s*sinfo.size()*n_embd_v_gqa + i*n_embd_v_gqa + j] = offs + j*kv_size + sinfo.idxs[s][i]; } } } } } void llama_kv_cache::set_input_k_shift(ggml_tensor * dst) const { GGML_ASSERT(ggml_backend_buffer_is_host(dst->buffer)); int32_t * data = (int32_t *) dst->data; for (uint32_t s = 0; s < n_stream; ++s) { const auto & cells = v_cells[s]; for (uint32_t i = 0; i < cells.size(); ++i) { data[s*cells.size() + i] = cells.is_empty(i) ? 0 : cells.get_shift(i); } } } struct args_set_input_kq_mask { const llama_hparams & hparams; const llama_ubatch * ubatch; const std::vector & v_cells; const std::vector & seq_to_stream; uint32_t n_swa; llama_swa_type swa_type; int64_t n_kv; int64_t n_stream; int64_t n_tps; }; template static void set_input_kq_mask_impl(const args_set_input_kq_mask & args, float * data) { //const auto & hparams = args.hparams; const auto & ubatch = args.ubatch; const auto & v_cells = args.v_cells; const auto & seq_to_stream = args.seq_to_stream; const uint32_t n_swa = args.n_swa; const llama_swa_type swa_type = args.swa_type; const int64_t n_kv = args.n_kv; const int64_t n_stream = args.n_stream; const int64_t n_tps = args.n_tps; // the min position in the batch for each sequence llama_pos seq_pos_min[LLAMA_MAX_SEQ]; std::fill(seq_pos_min, seq_pos_min + LLAMA_MAX_SEQ, INT32_MAX); for (uint32_t i = 0; i < ubatch->n_tokens; ++i) { const llama_seq_id seq_id = ubatch->seq_id[i][0]; seq_pos_min[seq_id] = std::min(seq_pos_min[seq_id], ubatch->pos[i]); } for (uint32_t s = 0; s < n_stream; ++s) { // bookkeeping of the KQ mask cells that could change for other tokens of the same sequence std::unordered_map seq_srct; std::unordered_map> seq_idxs; for (uint32_t ii = 0; ii < n_tps; ++ii) { const uint32_t i = s*n_tps + ii; const llama_seq_id seq_id = ubatch->seq_id[i][0]; const auto & cells = v_cells.at(seq_to_stream[seq_id]); llama_pos p0 = -1; const llama_pos p1 = ubatch->pos[i]; // for M-RoPE const llama_pos p1_x = is_2d ? ubatch->pos[i + ubatch->n_tokens*2] : 0; const llama_pos p1_y = is_2d ? ubatch->pos[i + ubatch->n_tokens] : 0; const uint64_t idst = n_kv*i; // for tokens of the same sequence, the mask is mostly the same, so we can reuse it // the only cells that could change are the ones that are with similar positions as the // ones in the batch (i.e. due to causal masking, SWA, etc.) // keep track of those cells and shortcut the loop to save time // note: this optimization is not compatible with Alibi position encoding // ref: https://github.com/ggml-org/llama.cpp/pull/18842 bool prev = false; auto & idxs = seq_idxs[seq_id]; if (!alibi) { if (seq_srct.find(seq_id) != seq_srct.end()) { const uint32_t srct = seq_srct[seq_id]; const uint64_t idst_prev = n_kv*srct; std::copy(data + idst_prev, data + idst_prev + n_kv, data + idst); prev = true; } else { idxs.clear(); idxs.reserve(ubatch->n_tokens + n_swa + 32); seq_srct[seq_id] = i; } } for (uint32_t jj = 0; jj < n_kv; ++jj) { uint32_t j = jj; // we have an exiting mask for this sequence -> update just seq_idxs if (!alibi) { if (prev) { if (jj >= idxs.size()) { break; } j = idxs[jj]; } } if (cells.is_empty(j)) { goto skip; } // mask the token if not the same sequence if (!cells.seq_has(j, seq_id)) { goto skip; } p0 = cells.pos_get(j); if (!alibi) { if (!prev) { // record all cells for which: p0 >= seq_pos_min[seq_id] - n_swa - 32 if (p0 + (int32_t) (n_swa + 32) >= seq_pos_min[seq_id]) { idxs.push_back(j); } } } if (causal) { // mask future tokens if (p0 > p1) { goto skip; } // M-RoPE causal mask if (is_2d) { if (p0 == p1) { const auto & p0_ext = cells.ext_get(j); if (p0_ext.is_2d_gt(p1_x, p1_y)) { goto skip; } } } } // apply SWA if any if (swa) { if (llama_hparams::is_masked_swa(n_swa, swa_type, p0, p1)) { goto skip; } } if (alibi) { data[idst + j] = -std::abs(p0 - p1); } else { data[idst + j] = 0.0f; } continue; skip: data[idst + j] = -INFINITY; } } } } template static void set_input_kq_mask_impl(const args_set_input_kq_mask & args, float * data) { const bool alibi = args.hparams.use_alibi; if (alibi) { set_input_kq_mask_impl (args, data); } else { set_input_kq_mask_impl(args, data); } } template static void set_input_kq_mask_impl(const args_set_input_kq_mask & args, float * data) { const bool is_2d = args.ubatch->is_pos_2d(); if (is_2d) { set_input_kq_mask_impl (args, data); } else { set_input_kq_mask_impl(args, data); } } template static void set_input_kq_mask_impl(const args_set_input_kq_mask & args, float * data) { const bool swa = args.swa_type != LLAMA_SWA_TYPE_NONE; if (swa) { set_input_kq_mask_impl (args, data); } else { set_input_kq_mask_impl(args, data); } } void llama_kv_cache::set_input_kq_mask(ggml_tensor * dst, const llama_ubatch * ubatch, bool causal_attn) const { const uint32_t n_tokens = ubatch->n_tokens; GGML_ASSERT(ggml_backend_buffer_is_host(dst->buffer)); float * data = (float *) dst->data; const int64_t n_kv = dst->ne[0]; const int64_t n_stream = dst->ne[3]; // num streams in the current ubatch GGML_ASSERT(n_tokens%n_stream == 0); // n_tps == n_tokens_per_stream const int64_t n_tps = n_tokens/n_stream; //const int64_t t_start = ggml_time_us(); const args_set_input_kq_mask args = { /*.hparams =*/ hparams, /*.ubatch =*/ ubatch, /*.v_cells =*/ v_cells, /*.seq_to_stream =*/ seq_to_stream, /*.n_swa =*/ n_swa, /*.swa_type =*/ swa_type, /*.n_kv =*/ n_kv, /*.n_stream =*/ n_stream, /*.n_tps =*/ n_tps, }; if (causal_attn) { set_input_kq_mask_impl (args, data); } else { set_input_kq_mask_impl(args, data); } //const int64_t t_end = ggml_time_us(); //LLAMA_LOG_ERROR("%s: kq mask time: %0.3f ms\n", __func__, (t_end - t_start)/1000.0); } void llama_kv_cache::set_input_pos_bucket(ggml_tensor * dst, const llama_ubatch * ubatch) const { const int64_t n_tokens = ubatch->n_tokens; GGML_ASSERT(n_stream == 1 && "TODO: support multiple streams"); const auto & cells = v_cells[0]; GGML_ASSERT(ggml_backend_buffer_is_host(dst->buffer)); GGML_ASSERT(!ubatch->equal_seqs()); // TODO: use ubatch->n_seqs instead of failing int32_t * data = (int32_t *) dst->data; const int32_t n_kv = dst->ne[0]; for (int h = 0; h < 1; ++h) { for (int i = 0; i < n_tokens; ++i) { for (int j = 0; j < n_kv; ++j) { // the position when the cells is empty is irrelevant - it will be masked out later in the attention const llama_pos p0 = cells.is_empty(j) ? -1 : cells.pos_get(j); data[h*(n_kv*n_tokens) + i*n_kv + j] = llama_relative_position_bucket(p0, ubatch->pos[i], hparams.n_rel_attn_bkts, false); } } } } void llama_kv_cache::set_input_k_rot(ggml_tensor * dst) const { GGML_ASSERT(ggml_backend_buffer_is_host(dst->buffer)); const auto n_rot = dst->ne[0]; GGML_ASSERT(attn_rot_hadamard.count(dst->ne[0])); memcpy(dst->data, attn_rot_hadamard.at(n_rot).data(), ggml_nbytes(dst)); } void llama_kv_cache::set_input_v_rot(ggml_tensor * dst) const { GGML_ASSERT(ggml_backend_buffer_is_host(dst->buffer)); const auto n_rot = dst->ne[0]; GGML_ASSERT(attn_rot_hadamard.count(dst->ne[0])); memcpy(dst->data, attn_rot_hadamard.at(n_rot).data(), ggml_nbytes(dst)); } size_t llama_kv_cache::total_size() const { size_t size = 0; for (const auto & [_, buf] : ctxs_bufs) { size += ggml_backend_buffer_get_size(buf.get()); } return size; } size_t llama_kv_cache::size_k_bytes() const { size_t size_k_bytes = 0; for (const auto & layer : layers) { size_k_bytes += ggml_nbytes(layer.k); } return size_k_bytes; } size_t llama_kv_cache::size_v_bytes() const { size_t size_v_bytes = 0; for (const auto & layer : layers) { size_v_bytes += layer.v ? ggml_nbytes(layer.v) : 0; } return size_v_bytes; } ggml_tensor * llama_kv_cache::build_rope_shift( const llama_cparams & cparams, ggml_context * ctx, ggml_tensor * cur, ggml_tensor * shift, ggml_tensor * rot, ggml_tensor * factors, float freq_base, float freq_scale, uint32_t il) const { const auto & n_ctx_orig = cparams.n_ctx_orig_yarn; const auto & yarn_ext_factor = cparams.yarn_ext_factor; const auto & yarn_beta_fast = cparams.yarn_beta_fast; const auto & yarn_beta_slow = cparams.yarn_beta_slow; const auto & yarn_attn_factor = cparams.yarn_attn_factor; const auto & n_rot = hparams.n_rot(il); const auto & rope_type = hparams.rope_type == LLAMA_ROPE_TYPE_MROPE || hparams.rope_type == LLAMA_ROPE_TYPE_IMROPE // @ngxson : this is a workaround // for M-RoPE, we want to rotate the whole vector when doing KV shift // a normal RoPE should work, we just need to use the correct ordering // ref: https://github.com/ggml-org/llama.cpp/pull/13870 ? LLAMA_ROPE_TYPE_NEOX : hparams.rope_type; ggml_tensor * tmp; if (ggml_is_quantized(cur->type)) { // dequantize to f32 -> RoPE -> quantize back tmp = ggml_cast(ctx, cur, GGML_TYPE_F32); // rotate back tmp = ggml_mul_mat_aux(ctx, tmp, rot); tmp = ggml_rope_ext(ctx, tmp, shift, factors, n_rot, rope_type, n_ctx_orig, freq_base, freq_scale, yarn_ext_factor, yarn_attn_factor, yarn_beta_fast, yarn_beta_slow); // rotate fwd tmp = ggml_mul_mat_aux(ctx, tmp, rot); tmp = ggml_cpy(ctx, tmp, cur); } else { // we rotate only the first n_rot dimensions tmp = ggml_rope_ext_inplace(ctx, cur, shift, factors, n_rot, rope_type, n_ctx_orig, freq_base, freq_scale, yarn_ext_factor, yarn_attn_factor, yarn_beta_fast, yarn_beta_slow); } return tmp; } class llm_graph_input_k_shift : public llm_graph_input_i { public: llm_graph_input_k_shift(const llama_kv_cache * kv_self) : kv_self(kv_self) {} virtual ~llm_graph_input_k_shift() = default; void set_input(const llama_ubatch * ubatch) override; ggml_tensor * k_shift; // I32 [kv_size*n_stream] // note: assumes k_rot^2 == I ggml_tensor * k_rot = nullptr; const llama_kv_cache * kv_self; }; void llm_graph_input_k_shift::set_input(const llama_ubatch * ubatch) { GGML_UNUSED(ubatch); if (k_shift) { kv_self->set_input_k_shift(k_shift); } if (k_rot) { kv_self->set_input_k_rot(k_rot); } } ggml_cgraph * llama_kv_cache::build_graph_shift(llm_graph_result * res, llama_context * lctx) const { auto * ctx = res->get_ctx(); auto * gf = res->get_gf(); auto inp = std::make_unique(this); inp->k_shift = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, (int64_t) get_size()*n_stream); ggml_set_input(inp->k_shift); inp->k_rot = build_input_k_rot(ctx); const auto & cparams = lctx->get_cparams(); for (const auto & layer : layers) { const uint32_t il = layer.il; const int64_t n_head_kv = hparams.n_head_kv(il); const int64_t n_embd_k_gqa = hparams.n_embd_k_gqa(il); const auto n_rot = hparams.n_rot(il); const auto n_embd_head_k = hparams.n_embd_head_k(il); const auto n_embd_nope = hparams.n_lora_kv > 0 ? n_embd_head_k - n_rot : 0; const float freq_base_l = model.get_rope_freq_base (cparams, il); const float freq_scale_l = model.get_rope_freq_scale(cparams, il); ggml_tensor * rope_factors = model.get_rope_factors(cparams, il); ggml_tensor * k = ggml_view_3d(ctx, layer.k, n_rot, n_head_kv, get_size()*n_stream, ggml_row_size(layer.k->type, n_embd_head_k), ggml_row_size(layer.k->type, n_embd_k_gqa), ggml_row_size(layer.k->type, n_embd_nope)); ggml_tensor * cur = build_rope_shift(cparams, ctx, k, inp->k_shift, inp->k_rot, rope_factors, freq_base_l, freq_scale_l, il); ggml_build_forward_expand(gf, cur); } res->add_input(std::move(inp)); return gf; } void llama_kv_cache::state_write(llama_io_write_i & io, llama_seq_id seq_id, llama_state_seq_flags flags) const { GGML_UNUSED(flags); io.write(&n_stream, sizeof(n_stream)); for (uint32_t s = 0; s < n_stream; ++s) { cell_ranges_t cr { s, {} }; uint32_t cell_count = 0; const auto & cells = v_cells[s]; // Count the number of cells with the specified seq_id // Find all the ranges of cells with this seq id (or all, when -1) uint32_t cell_range_begin = cells.size(); for (uint32_t i = 0; i < cells.size(); ++i) { if (!cells.is_empty(i) && (seq_id == -1 || cells.seq_has(i, seq_id))) { ++cell_count; if (cell_range_begin == cells.size()) { cell_range_begin = i; } } else { if (cell_range_begin != cells.size()) { cr.data.emplace_back(cell_range_begin, i); cell_range_begin = cells.size(); } } } if (cell_range_begin != cells.size()) { cr.data.emplace_back(cell_range_begin, cells.size()); } // DEBUG CHECK: Sum of cell counts in ranges should equal the total cell count uint32_t cell_count_check = 0; for (const auto & range : cr.data) { cell_count_check += range.second - range.first; } GGML_ASSERT(cell_count == cell_count_check); io.write(&cell_count, sizeof(cell_count)); // skip empty streams if (cell_count == 0) { continue; } state_write_meta(io, cr, seq_id); state_write_data(io, cr); } } void llama_kv_cache::state_read(llama_io_read_i & io, llama_seq_id seq_id, llama_state_seq_flags flags) { GGML_UNUSED(flags); GGML_ASSERT(seq_id == -1 || (seq_id >= 0 && (size_t) seq_id < seq_to_stream.size())); uint32_t n_stream_cur; io.read_to(&n_stream_cur, sizeof(n_stream_cur)); if (n_stream_cur != n_stream) { throw std::runtime_error("n_stream mismatch"); } for (uint32_t s = 0; s < n_stream; ++s) { uint32_t cell_count; io.read_to(&cell_count, sizeof(cell_count)); if (cell_count == 0) { continue; } const uint32_t strm = seq_id == -1 ? s : seq_to_stream[seq_id]; slot_info sinfo; bool res = true; res = res && state_read_meta(io, strm, cell_count, sinfo, seq_id); res = res && state_read_data(io, strm, cell_count, sinfo); if (!res) { if (seq_id == -1) { clear(true); } else { seq_rm(seq_id, -1, -1); } throw std::runtime_error("failed to restore kv cache"); } } } void llama_kv_cache::state_write_meta(llama_io_write_i & io, const cell_ranges_t & cr, llama_seq_id seq_id) const { const auto & cells = v_cells[cr.strm]; for (const auto & range : cr.data) { for (uint32_t i = range.first; i < range.second; ++i) { std::vector seq_ids; for (llama_seq_id cur = 0; cur < (int) n_seq_max; ++cur) { if (cur == seq_id || seq_id == -1) { if (cells.seq_has(i, cur)) { seq_ids.push_back(cur); } } } const llama_pos pos = cells.pos_get(i); const uint32_t n_seq_id = seq_ids.size(); io.write(&pos, sizeof(pos)); io.write(&n_seq_id, sizeof(n_seq_id)); if (hparams.n_pos_per_embd() > 1) { const llama_kv_cell_ext ext = cells.ext_get(i); io.write(&ext, sizeof(ext)); } for (const auto & seq_id : seq_ids) { io.write(&seq_id, sizeof(seq_id)); } } } } void llama_kv_cache::state_write_data(llama_io_write_i & io, const cell_ranges_t & cr) const { const auto & cells = v_cells[cr.strm]; const uint32_t v_trans = this->v_trans ? 1 : 0; const uint32_t n_layer = layers.size(); io.write(&v_trans, sizeof(v_trans)); io.write(&n_layer, sizeof(n_layer)); // Iterate and write all the keys first, each row is a cell // Get whole range at a time for (const auto & layer : layers) { const uint32_t il = layer.il; const uint32_t n_embd_k_gqa = hparams.n_embd_k_gqa(il); auto * k = layer.k_stream[cr.strm]; // Write key type const int32_t k_type_i = (int32_t) k->type; io.write(&k_type_i, sizeof(k_type_i)); // Write row size of key const uint64_t k_size_row = ggml_row_size(k->type, n_embd_k_gqa); io.write(&k_size_row, sizeof(k_size_row)); // Read each range of cells of k_size length and write out for (const auto & range : cr.data) { const size_t range_size = range.second - range.first; const size_t buf_size = range_size * k_size_row; io.write_tensor(k, range.first * k_size_row, buf_size); } } if (!v_trans) { for (const auto & layer : layers) { const uint32_t il = layer.il; const uint32_t n_embd_v_gqa = hparams.n_embd_v_gqa(il); auto * v = layer.v_stream[cr.strm]; if (!v) { continue; } // Write value type const int32_t v_type_i = (int32_t) v->type; io.write(&v_type_i, sizeof(v_type_i)); // Write row size of value const uint64_t v_size_row = ggml_row_size(v->type, n_embd_v_gqa); io.write(&v_size_row, sizeof(v_size_row)); // Read each range of cells of v_size length and write out for (const auto & range : cr.data) { const size_t range_size = range.second - range.first; const size_t buf_size = range_size * v_size_row; io.write_tensor(v, range.first * v_size_row, buf_size); } } } else { // When v is transposed, we also need the element size and get the element ranges from each row const uint32_t kv_size = cells.size(); for (const auto & layer : layers) { const uint32_t il = layer.il; const uint32_t n_embd_v_gqa = hparams.n_embd_v_gqa(il); auto * v = layer.v_stream[cr.strm]; if (!v) { continue; } // Write value type const int32_t v_type_i = (int32_t) v->type; io.write(&v_type_i, sizeof(v_type_i)); // Write element size const uint32_t v_size_el = ggml_type_size(v->type); io.write(&v_size_el, sizeof(v_size_el)); // Write GQA embedding size io.write(&n_embd_v_gqa, sizeof(n_embd_v_gqa)); // For each row, we get the element values of each cell for (uint32_t j = 0; j < n_embd_v_gqa; ++j) { // Read each range of cells of v_size_el length and write out for (const auto & range : cr.data) { const size_t range_size = range.second - range.first; const size_t src_offset = (range.first + j * kv_size) * v_size_el; const size_t buf_size = range_size * v_size_el; io.write_tensor(v, src_offset, buf_size); } } } } } bool llama_kv_cache::state_read_meta(llama_io_read_i & io, uint32_t strm, uint32_t cell_count, slot_info & sinfo, llama_seq_id dest_seq_id) { auto & cells = v_cells[strm]; auto & head = v_heads[strm]; if (dest_seq_id != -1) { // single sequence seq_rm(dest_seq_id, -1, -1); llama_batch_allocr balloc(hparams.n_pos_per_embd()); llama_ubatch ubatch = balloc.ubatch_reserve(cell_count, 1); ubatch.seq_id_unq[0] = dest_seq_id; for (uint32_t i = 0; i < cell_count; ++i) { llama_pos pos; uint32_t n_seq_id; io.read_to(&pos, sizeof(pos)); io.read_to(&n_seq_id, sizeof(n_seq_id)); if (n_seq_id != 1) { LLAMA_LOG_ERROR("%s: invalid seq_id-agnostic kv cell\n", __func__); return false; } if (hparams.n_pos_per_embd() > 1) { llama_kv_cell_ext ext; io.read_to(&ext, sizeof(ext)); ubatch.pos[i + ubatch.n_tokens] = ext.y; ubatch.pos[i + ubatch.n_tokens*2] = ext.x; } // read the sequence id, but directly discard it - we will use dest_seq_id instead { llama_seq_id seq_id; io.read_to(&seq_id, sizeof(seq_id)); } ubatch.pos[i] = pos; ubatch.n_seq_id[i] = n_seq_id; ubatch.seq_id[i] = &dest_seq_id; } sinfo = find_slot(ubatch, false); if (sinfo.empty()) { LLAMA_LOG_ERROR("%s: failed to find available cells in kv cache\n", __func__); return false; } // TODO: we cannot yet restore llama_kv_cell_ext as the apply_ubatch() does not support it yet // see: https://github.com/ggml-org/llama.cpp/pull/16825#issuecomment-3460868350 apply_ubatch(sinfo, ubatch); LLAMA_LOG_DEBUG("%s: cell_count = %d, dest_seq_id = %d\n", __func__, cell_count, dest_seq_id); // DEBUG CHECK: verify that all cells were allocated and have correct seq_id and pos values GGML_ASSERT(sinfo.n_stream() == 1); GGML_ASSERT(sinfo.idxs[0].size() == cell_count); for (uint32_t i = 0; i < cell_count; ++i) { const uint32_t idx = sinfo.idxs[0][i]; GGML_ASSERT(cells.pos_get(idx) == ubatch.pos[i]); GGML_ASSERT(cells.seq_has(idx, dest_seq_id)); } } else { // whole KV cache restore if (cell_count > cells.size()) { LLAMA_LOG_ERROR("%s: not enough cells in kv cache\n", __func__); return false; } clear(true); for (uint32_t i = 0; i < cell_count; ++i) { llama_pos pos; uint32_t n_seq_id; io.read_to(&pos, sizeof(pos)); io.read_to(&n_seq_id, sizeof(n_seq_id)); cells.pos_set(i, pos); if (hparams.n_pos_per_embd() > 1) { llama_kv_cell_ext ext; io.read_to(&ext, sizeof(ext)); cells.ext_set(i, ext); } for (uint32_t j = 0; j < n_seq_id; ++j) { llama_seq_id seq_id; io.read_to(&seq_id, sizeof(seq_id)); if (seq_id < 0 || (uint32_t) seq_id >= n_seq_max) { LLAMA_LOG_ERROR("%s: invalid seq_id, %d is out of range [0, %u)\n", __func__, seq_id, n_seq_max); return false; } cells.seq_add(i, seq_id); } } // Create contiguous slot_info for whole cache restore sinfo.s0 = strm; sinfo.s1 = strm; sinfo.resize(1); sinfo.strm[0] = strm; sinfo.idxs[0].resize(cell_count); for (uint32_t i = 0; i < cell_count; ++i) { sinfo.idxs[0][i] = i; } head = 0; } return true; } bool llama_kv_cache::state_read_data(llama_io_read_i & io, uint32_t strm, uint32_t cell_count, const slot_info & sinfo) { auto & cells = v_cells[strm]; uint32_t v_trans; uint32_t n_layer; io.read_to(&v_trans, sizeof(v_trans)); io.read_to(&n_layer, sizeof(n_layer)); if (n_layer != layers.size()) { LLAMA_LOG_ERROR("%s: mismatched layer count (%u instead of %u)\n", __func__, n_layer, (uint32_t) layers.size()); return false; } if (cell_count > cells.size()) { LLAMA_LOG_ERROR("%s: not enough cells in kv cache to restore state (%u > %u)\n", __func__, cell_count, cells.size()); return false; } if (this->v_trans != (bool) v_trans) { LLAMA_LOG_ERROR("%s: incompatible V transposition\n", __func__); return false; } // For each layer, read the keys for each cell, one row is one cell, read as one contiguous block for (const auto & layer : layers) { const uint32_t il = layer.il; const uint32_t n_embd_k_gqa = hparams.n_embd_k_gqa(il); auto * k = layer.k_stream[strm]; // Read type of key int32_t k_type_i_ref; io.read_to(&k_type_i_ref, sizeof(k_type_i_ref)); const int32_t k_type_i = (int32_t) k->type; if (k_type_i != k_type_i_ref) { LLAMA_LOG_ERROR("%s: mismatched key type (%d != %d, layer %d)\n", __func__, k_type_i, k_type_i_ref, il); return false; } // Read row size of key uint64_t k_size_row_ref; io.read_to(&k_size_row_ref, sizeof(k_size_row_ref)); const size_t k_size_row = ggml_row_size(k->type, n_embd_k_gqa); if (k_size_row != k_size_row_ref) { LLAMA_LOG_ERROR("%s: mismatched key row size (%zu != %zu, layer %d)\n", __func__, k_size_row, (size_t) k_size_row_ref, il); return false; } if (cell_count) { if (sinfo.is_contiguous()) { // Fast path: contiguous cells, single memcpy ggml_backend_tensor_set(k, io.read(cell_count * k_size_row), sinfo.head() * k_size_row, cell_count * k_size_row); } else { // Slow path: scatter to non-contiguous positions const void * src = io.read(cell_count * k_size_row); for (uint32_t i = 0; i < cell_count; ++i) { const size_t dst_offset = sinfo.idxs[0][i] * k_size_row; ggml_backend_tensor_set(k, (const char*)src + i * k_size_row, dst_offset, k_size_row); } } } } if (!this->v_trans) { for (const auto & layer : layers) { const uint32_t il = layer.il; const uint32_t n_embd_v_gqa = hparams.n_embd_v_gqa(il); auto * v = layer.v_stream[strm]; if (!v) { continue; } // Read type of value int32_t v_type_i_ref; io.read_to(&v_type_i_ref, sizeof(v_type_i_ref)); const int32_t v_type_i = (int32_t) v->type; if (v_type_i != v_type_i_ref) { LLAMA_LOG_ERROR("%s: mismatched value type (%d != %d, layer %d)\n", __func__, v_type_i, v_type_i_ref, il); return false; } // Read row size of value uint64_t v_size_row_ref; io.read_to(&v_size_row_ref, sizeof(v_size_row_ref)); const size_t v_size_row = ggml_row_size(v->type, n_embd_v_gqa); if (v_size_row != v_size_row_ref) { LLAMA_LOG_ERROR("%s: mismatched value row size (%zu != %zu, layer %d)\n", __func__, v_size_row, (size_t) v_size_row_ref, il); return false; } if (cell_count) { if (sinfo.is_contiguous()) { // Fast path: contiguous cells, single memcpy ggml_backend_tensor_set(v, io.read(cell_count * v_size_row), sinfo.head() * v_size_row, cell_count * v_size_row); } else { // Slow path: scatter to non-contiguous positions const void * src = io.read(cell_count * v_size_row); for (uint32_t i = 0; i < cell_count; ++i) { const size_t dst_offset = sinfo.idxs[0][i] * v_size_row; ggml_backend_tensor_set(v, (const char*)src + i * v_size_row, dst_offset, v_size_row); } } } } } else { // For each layer, read the values for each cell (transposed) for (const auto & layer : layers) { const uint32_t il = layer.il; const uint32_t n_embd_v_gqa = hparams.n_embd_v_gqa(il); auto * v = layer.v_stream[strm]; if (!v) { continue; } // Read type of value int32_t v_type_i_ref; io.read_to(&v_type_i_ref, sizeof(v_type_i_ref)); const int32_t v_type_i = (int32_t) v->type; if (v_type_i != v_type_i_ref) { LLAMA_LOG_ERROR("%s: mismatched value type (%d != %d, layer %d)\n", __func__, v_type_i, v_type_i_ref, il); return false; } // Read element size of value uint32_t v_size_el_ref; io.read_to(&v_size_el_ref, sizeof(v_size_el_ref)); const size_t v_size_el = ggml_type_size(v->type); if (v_size_el != v_size_el_ref) { LLAMA_LOG_ERROR("%s: mismatched value element size (%zu != %zu, layer %d)\n", __func__, v_size_el, (size_t) v_size_el_ref, il); return false; } // Read GQA embedding size uint32_t n_embd_v_gqa_ref; io.read_to(&n_embd_v_gqa_ref, sizeof(n_embd_v_gqa_ref)); if (n_embd_v_gqa != n_embd_v_gqa_ref) { LLAMA_LOG_ERROR("%s: mismatched GQA embedding size (%u != %u, layer %d)\n", __func__, n_embd_v_gqa, n_embd_v_gqa_ref, il); return false; } if (cell_count) { if (sinfo.is_contiguous()) { // Fast path: contiguous cells const uint32_t h = sinfo.head(); for (uint32_t j = 0; j < n_embd_v_gqa; ++j) { const size_t dst_offset = (h + j * cells.size()) * v_size_el; ggml_backend_tensor_set(v, io.read(cell_count * v_size_el), dst_offset, cell_count * v_size_el); } } else { // Slow path: scatter to non-contiguous positions for (uint32_t j = 0; j < n_embd_v_gqa; ++j) { const void * src = io.read(cell_count * v_size_el); for (uint32_t i = 0; i < cell_count; ++i) { const size_t dst_offset = (sinfo.idxs[0][i] + j * cells.size()) * v_size_el; ggml_backend_tensor_set(v, (const char*)src + i * v_size_el, dst_offset, v_size_el); } } } } } } return true; } // // llama_kv_cache_context // llama_kv_cache_context::llama_kv_cache_context(llama_memory_status status) : status(status) {} llama_kv_cache_context::llama_kv_cache_context( llama_kv_cache * kv) : status(LLAMA_MEMORY_STATUS_SUCCESS), kv(kv) { n_kv = kv->get_size(); const uint32_t n_stream = kv->get_n_stream(); // create a dummy slot info - the actual data is irrelevant. we just need to build the graph sinfos.resize(1); sinfos[0].s0 = 0; sinfos[0].s1 = n_stream - 1; sinfos[0].idxs.resize(n_stream); for (uint32_t s = 0; s < n_stream; ++s) { sinfos[0].strm.push_back(s); sinfos[0].idxs[s].resize(1, 0); } } llama_kv_cache_context::llama_kv_cache_context( llama_kv_cache * kv, llama_context * lctx, bool do_shift, stream_copy_info sc_info) : status(LLAMA_MEMORY_STATUS_SUCCESS), kv(kv), lctx(lctx), do_shift(do_shift), sc_info(std::move(sc_info)) { if (!do_shift && this->sc_info.empty()) { status = LLAMA_MEMORY_STATUS_NO_UPDATE; } } llama_kv_cache_context::llama_kv_cache_context( llama_kv_cache * kv, llama_kv_cache::slot_info_vec_t sinfos, std::vector ubatches) : status(LLAMA_MEMORY_STATUS_SUCCESS), kv(kv), sinfos(std::move(sinfos)), ubatches(std::move(ubatches)) { } llama_kv_cache_context::~llama_kv_cache_context() = default; bool llama_kv_cache_context::next() { assert(status == LLAMA_MEMORY_STATUS_SUCCESS); if (++i_cur >= ubatches.size()) { return false; } return true; } bool llama_kv_cache_context::apply() { assert(!llama_memory_status_is_fail(status)); // no ubatches -> this is a KV cache update if (ubatches.empty()) { kv->update(lctx, do_shift, sc_info); return true; } kv->apply_ubatch(sinfos[i_cur], ubatches[i_cur]); n_kv = kv->get_n_kv(sinfos[i_cur]); return true; } llama_memory_status llama_kv_cache_context::get_status() const { return status; } const llama_ubatch & llama_kv_cache_context::get_ubatch() const { assert(status == LLAMA_MEMORY_STATUS_SUCCESS); return ubatches[i_cur]; } uint32_t llama_kv_cache_context::get_n_kv() const { return n_kv; } ggml_type llama_kv_cache_context::type_k() const { return kv->type_k(); } ggml_type llama_kv_cache_context::type_v() const { return kv->type_v(); } ggml_tensor * llama_kv_cache_context::get_k(ggml_context * ctx, int32_t il) const { return kv->get_k(ctx, il, n_kv, sinfos[i_cur]); } ggml_tensor * llama_kv_cache_context::get_v(ggml_context * ctx, int32_t il) const { return kv->get_v(ctx, il, n_kv, sinfos[i_cur]); } ggml_tensor * llama_kv_cache_context::cpy_k(ggml_context * ctx, ggml_tensor * k_cur, ggml_tensor * k_idxs, int32_t il) const { return kv->cpy_k(ctx, k_cur, k_idxs, il, sinfos[i_cur]); } ggml_tensor * llama_kv_cache_context::cpy_v(ggml_context * ctx, ggml_tensor * v_cur, ggml_tensor * v_idxs, int32_t il) const { return kv->cpy_v(ctx, v_cur, v_idxs, il, sinfos[i_cur]); } ggml_tensor * llama_kv_cache_context::build_input_k_idxs(ggml_context * ctx, const llama_ubatch & ubatch) const { return kv->build_input_k_idxs(ctx, ubatch); } ggml_tensor * llama_kv_cache_context::build_input_v_idxs(ggml_context * ctx, const llama_ubatch & ubatch) const { return kv->build_input_v_idxs(ctx, ubatch); } ggml_tensor * llama_kv_cache_context::build_input_k_rot(ggml_context * ctx) const { return kv->build_input_k_rot(ctx); } ggml_tensor * llama_kv_cache_context::build_input_v_rot(ggml_context * ctx) const { return kv->build_input_v_rot(ctx); } void llama_kv_cache_context::set_input_k_shift(ggml_tensor * dst) const { kv->set_input_k_shift(dst); } void llama_kv_cache_context::set_input_k_idxs(ggml_tensor * dst, const llama_ubatch * ubatch) const { kv->set_input_k_idxs(dst, ubatch, sinfos[i_cur]); } void llama_kv_cache_context::set_input_v_idxs(ggml_tensor * dst, const llama_ubatch * ubatch) const { kv->set_input_v_idxs(dst, ubatch, sinfos[i_cur]); } void llama_kv_cache_context::set_input_kq_mask(ggml_tensor * dst, const llama_ubatch * ubatch, bool causal_attn) const { kv->set_input_kq_mask(dst, ubatch, causal_attn); } void llama_kv_cache_context::set_input_pos_bucket(ggml_tensor * dst, const llama_ubatch * ubatch) const { kv->set_input_pos_bucket(dst, ubatch); } void llama_kv_cache_context::set_input_k_rot(ggml_tensor * dst) const { kv->set_input_k_rot(dst); } void llama_kv_cache_context::set_input_v_rot(ggml_tensor * dst) const { kv->set_input_v_rot(dst); }