#include "llama-memory-recurrent.h" #include "llama-impl.h" #include "llama-io.h" #include "llama-batch.h" #include "llama-model.h" #include #include #include #include #include #include // // llama_memory_recurrent // llama_memory_recurrent::llama_memory_recurrent( const llama_model & model, ggml_type type_r, ggml_type type_s, bool offload, uint32_t mem_size, uint32_t n_seq_max, const layer_filter_cb & filter) : hparams(model.hparams), n_seq_max(n_seq_max) { const int32_t n_layer = hparams.n_layer; head = 0; size = mem_size; used = 0; cells.clear(); cells.resize(mem_size); // 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*n_layer*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(); }; r_l.resize(n_layer); s_l.resize(n_layer); for (int i = 0; i < n_layer; i++) { if (filter && !filter(i)) { LLAMA_LOG_DEBUG("%s: layer %3d: skipped\n", __func__, i); continue; } const char * dev_name = "CPU"; ggml_backend_buffer_type_t buft = ggml_backend_cpu_buffer_type(); if (offload) { auto * dev = model.dev_layer(i); buft = ggml_backend_dev_buffer_type(dev); dev_name = ggml_backend_dev_name(dev); } LLAMA_LOG_DEBUG("%s, layer %3d: dev = %s\n", __func__, i, dev_name); ggml_context * ctx = ctx_for_buft(buft); if (!ctx) { throw std::runtime_error("failed to create ggml context for rs cache"); } ggml_tensor * r = ggml_new_tensor_1d(ctx, type_r, hparams.n_embd_r()*mem_size); ggml_tensor * s = ggml_new_tensor_1d(ctx, type_s, hparams.n_embd_s()*mem_size); ggml_format_name(r, "cache_r_l%d", i); ggml_format_name(s, "cache_s_l%d", i); r_l[i] = r; s_l[i] = s; } // allocate tensors and initialize the buffers to avoid NaNs in the padding for (auto & [buft, ctx] : ctx_map) { ggml_backend_buffer_t buf = ggml_backend_alloc_ctx_tensors_from_buft(ctx.get(), buft); if (!buf) { throw std::runtime_error("failed to allocate buffer for rs cache"); } ggml_backend_buffer_clear(buf, 0); LLAMA_LOG_INFO("%s: %10s RS buffer size = %8.2f MiB\n", __func__, ggml_backend_buffer_name(buf), ggml_backend_buffer_get_size(buf)/1024.0/1024.0); ctxs_bufs.emplace_back(std::move(ctx), buf); } { const size_t memory_size_r = size_r_bytes(); const size_t memory_size_s = size_s_bytes(); LLAMA_LOG_INFO("%s: size = %7.2f MiB (%6u cells, %3d layers, %2u seqs), R (%s): %7.2f MiB, S (%s): %7.2f MiB\n", __func__, (float)(memory_size_r + memory_size_s) / (1024.0f * 1024.0f), mem_size, n_layer, n_seq_max, ggml_type_name(type_r), (float)memory_size_r / (1024.0f * 1024.0f), ggml_type_name(type_s), (float)memory_size_s / (1024.0f * 1024.0f)); } } void llama_memory_recurrent::clear(bool data) { for (int32_t i = 0; i < (int32_t) size; ++i) { cells[i].pos = -1; cells[i].seq_id.clear(); cells[i].src = -1; cells[i].tail = -1; } head = 0; used = 0; if (data) { for (auto & [_, buf] : ctxs_bufs) { ggml_backend_buffer_clear(buf.get(), 0); } } } bool llama_memory_recurrent::seq_rm(llama_seq_id seq_id, llama_pos p0, llama_pos p1) { //printf("[DEBUG] calling llama_memory_recurrent::seq_rm` with `seq_id=%d, p0=%d, p1=%d`\n", seq_id, p0, p1); uint32_t new_head = size; if (p0 < 0) { p0 = 0; } if (p1 < 0) { p1 = std::numeric_limits::max(); } // models like Mamba or RWKV can't have a state partially erased at the end // of the sequence because their state isn't preserved for previous tokens if (seq_id >= (int64_t) size) { // could be fatal return false; } if (0 <= seq_id) { int32_t & tail_id = cells[seq_id].tail; if (tail_id >= 0) { const auto & cell = cells[tail_id]; // partial intersection is invalid if it includes the final pos if (0 < p0 && p0 <= cell.pos && p1 > cell.pos) { //printf("[DEBUG] inside `llama_memory_recurrent::seq_rm`: partial intersection is invalid, so returning false, p0 = %d, cell.pos = %d, p1 = %d\n", p0, cell.pos, p1); return false; } // invalidate tails which will be cleared if (p0 <= cell.pos && cell.pos < p1) { tail_id = -1; } } } else { // seq_id is negative, then the range should include everything or nothing if (p0 != p1 && (p0 != 0 || p1 != std::numeric_limits::max())) { //printf("[DEBUG] inside `llama_memory_recurrent::seq_rm`: `seq_id` is negative, so returning false\n"); return false; } } for (uint32_t i = 0; i < size; ++i) { if (cells[i].pos >= p0 && cells[i].pos < p1) { if (seq_id < 0) { cells[i].seq_id.clear(); } else if (cells[i].has_seq_id(seq_id)) { cells[i].seq_id.erase(seq_id); } else { continue; } if (cells[i].is_empty()) { // keep count of the number of used cells if (cells[i].pos >= 0) { used--; } cells[i].pos = -1; cells[i].src = -1; if (new_head == size) { new_head = i; } } } } // If we freed up a slot, set head to it so searching can start there. if (new_head != size && new_head < head) { head = new_head; } return true; } void llama_memory_recurrent::seq_cp(llama_seq_id seq_id_src, llama_seq_id seq_id_dst, llama_pos p0, llama_pos p1) { if (seq_id_src == seq_id_dst) { return; } if (p0 < 0) { p0 = 0; } if (p1 < 0) { p1 = std::numeric_limits::max(); } if ((uint32_t) seq_id_dst < size && (uint32_t) seq_id_src < size) { auto & tail_src = cells[seq_id_src]; auto & tail_dst = cells[seq_id_dst]; if (tail_dst.tail >= 0) { // clear destination seq_id if it wasn't empty auto & cell_dst = cells[tail_dst.tail]; cell_dst.seq_id.erase(seq_id_dst); tail_dst.tail = -1; if (cell_dst.seq_id.empty()) { cell_dst.pos = -1; cell_dst.src = -1; used -= 1; } } if (tail_src.tail >= 0) { auto & cell_src = cells[tail_src.tail]; cell_src.seq_id.insert(seq_id_dst); tail_dst.tail = tail_src.tail; } } } void llama_memory_recurrent::seq_keep(llama_seq_id seq_id) { uint32_t new_head = size; for (uint32_t i = 0; i < size; ++i) { if ((llama_seq_id) i != seq_id) { cells[i].tail = -1; } if (!cells[i].has_seq_id(seq_id)) { if (cells[i].pos >= 0) { used--; } cells[i].pos = -1; cells[i].src = -1; cells[i].seq_id.clear(); if (new_head == size){ new_head = i; } } else { cells[i].seq_id.clear(); cells[i].seq_id.insert(seq_id); } } // If we freed up a slot, set head to it so searching can start there. if (new_head != size && new_head < head) { head = new_head; } } void llama_memory_recurrent::seq_add(llama_seq_id seq_id, llama_pos p0, llama_pos p1, llama_pos shift) { if (shift == 0) { 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 if (p0 == p1) { return; } // for Mamba-like or RWKV models, only the pos needs to be shifted if (0 <= seq_id && seq_id < (int64_t) size) { const int32_t tail_id = cells[seq_id].tail; if (tail_id >= 0) { auto & cell = cells[tail_id]; if (cell.has_seq_id(seq_id) && p0 <= cell.pos && cell.pos < p1) { cell.pos += shift; } } } } void llama_memory_recurrent::seq_div(llama_seq_id seq_id, llama_pos p0, llama_pos p1, int d) { 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 Mamba-like or RWKV models, only the pos needs to be changed if (0 <= seq_id && seq_id < (int64_t) size) { const int32_t tail_id = cells[seq_id].tail; if (tail_id >= 0) { auto & cell = cells[tail_id]; if (cell.has_seq_id(seq_id) && p0 <= cell.pos && cell.pos < p1) { cell.pos /= d; } } } } llama_pos llama_memory_recurrent::seq_pos_min(llama_seq_id seq_id) const { llama_pos result = std::numeric_limits::max(); for (uint32_t i = 0; i < size; ++i) { if (cells[i].has_seq_id(seq_id)) { result = std::min(result, cells[i].pos); } } if (result == std::numeric_limits::max()) { result = -1; } return result; } llama_pos llama_memory_recurrent::seq_pos_max(llama_seq_id seq_id) const { llama_pos result = -1; for (uint32_t i = 0; i < size; ++i) { if (cells[i].has_seq_id(seq_id)) { result = std::max(result, cells[i].pos); } } return result; } std::map llama_memory_recurrent::memory_breakdown() const { std::map ret; for (const auto & [_, buf] : ctxs_bufs) { ret[ggml_backend_buffer_get_type(buf.get())] += ggml_backend_buffer_get_size(buf.get()); } return ret; } llama_memory_context_ptr llama_memory_recurrent::init_batch(llama_batch_allocr & balloc, uint32_t n_ubatch, bool embd_all) { do { balloc.split_reset(); std::vector ubatches; while (true) { llama_ubatch ubatch; if (embd_all) { // if all tokens are output, split by sequence ubatch = balloc.split_seq(n_ubatch); } else { // TODO: non-sequential equal split can be done if using unified KV cache // for simplicity, we always use sequential equal split for now 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; } if (!prepare(ubatches)) { break; } return std::make_unique(this, std::move(ubatches)); } while (false); return std::make_unique(LLAMA_MEMORY_STATUS_FAILED_PREPARE); } llama_memory_context_ptr llama_memory_recurrent::init_full() { return std::make_unique(this); } llama_memory_context_ptr llama_memory_recurrent::init_update(llama_context * lctx, bool optimize) { GGML_UNUSED(lctx); GGML_UNUSED(optimize); return std::make_unique(LLAMA_MEMORY_STATUS_NO_UPDATE); } bool llama_memory_recurrent::prepare(const std::vector & ubatches) { // simply remember the full state because it is very small for this type of cache // TODO: optimize auto org_cells = cells; auto org_used = used; auto org_head = head; bool success = true; for (const auto & ubatch : ubatches) { if (!find_slot(ubatch)) { success = false; break; } } // restore the original state cells = std::move(org_cells); used = org_used; head = org_head; return success; } bool llama_memory_recurrent::find_slot(const llama_ubatch & ubatch) { const uint32_t n_seq_tokens = ubatch.n_seq_tokens; const uint32_t n_seqs = ubatch.n_seqs; // 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 > used + 2*n_seqs) { head = 0; } // For recurrent state architectures (like Mamba or RWKV), // each cache cell can store the state for a whole sequence. // A slot should be always be contiguous. // can only process batches with an equal number of new tokens in each sequence GGML_ASSERT(ubatch.equal_seqs()); int32_t min = size - 1; int32_t max = 0; // everything should fit if all seq_ids are smaller than the max for (uint32_t s = 0; s < n_seqs; ++s) { const uint32_t i = s*n_seq_tokens; // first token of sequence set s const uint32_t n_seq_id = ubatch.n_seq_id[i]; for (uint32_t j = 0; j < n_seq_id; ++j) { const llama_seq_id seq_id = ubatch.seq_id[i][j]; if (seq_id < 0 || (uint32_t) seq_id >= size) { // too big seq_id // TODO: would it be possible to resize the cache instead? LLAMA_LOG_ERROR("%s: seq_id=%d >= n_seq_max=%u Try using a bigger --parallel value\n", __func__, seq_id, n_seq_max); return false; } if (j > 0) { auto & seq = cells[seq_id]; if (seq.tail >= 0) { auto & cell = cells[seq.tail]; // clear cells from seq_ids that become shared // (should not normally happen, but let's handle it anyway) cell.seq_id.erase(seq_id); seq.tail = -1; if (cell.seq_id.empty()) { cell.pos = -1; cell.src = -1; used -= 1; } } } } } #ifndef NDEBUG { std::vector tails_verif; tails_verif.assign(size, -1); for (uint32_t i = 0; i < size; ++i) { auto & cell = cells[i]; for (llama_seq_id seq_id : cell.seq_id) { if (tails_verif[seq_id] != -1) { LLAMA_LOG_ERROR("%s: duplicate tail for seq_id %d in cell %d and %d\n", __func__, seq_id, i, tails_verif[seq_id]); } tails_verif[seq_id] = i; } } for (uint32_t i = 0; i < size; ++i) { if (tails_verif[i] != cells[i].tail) { LLAMA_LOG_ERROR("%s: wrong tail for seq_id %d, (%d instead of %d)\n", __func__, i, cells[i].tail, tails_verif[i]); } } } #endif // find next empty cell uint32_t next_empty_cell = head; for (uint32_t i = 0; i < size; ++i) { if (next_empty_cell >= size) { next_empty_cell -= size; } auto & cell = cells[next_empty_cell]; if (cell.is_empty()) { break; } next_empty_cell += 1; } // find usable cell range for (uint32_t s = 0; s < n_seqs; ++s) { const uint32_t i = s*n_seq_tokens; const llama_seq_id seq_id = ubatch.seq_id[i][0]; auto & seq_meta = cells[seq_id]; bool has_cell = false; if (seq_meta.tail >= 0) { auto & cell = cells[seq_meta.tail]; GGML_ASSERT(cell.has_seq_id(seq_id)); // does this seq_id "own" the cell? if (cell.seq_id.size() == 1) { has_cell = true; } } if (!has_cell) { auto & empty_cell = cells[next_empty_cell]; GGML_ASSERT(empty_cell.is_empty()); // copy old tail into the empty cell if (seq_meta.tail >= 0) { auto & orig_cell = cells[seq_meta.tail]; empty_cell.pos = orig_cell.pos; empty_cell.src = orig_cell.src; orig_cell.seq_id.erase(seq_id); empty_cell.seq_id.insert(seq_id); // will be overwritten GGML_ASSERT(!orig_cell.is_empty()); // has at least one remaining seq_id } seq_meta.tail = next_empty_cell; // find next empty cell if (s + 1 < n_seqs) { for (uint32_t j = 0; j < size; ++j) { next_empty_cell += 1; if (next_empty_cell >= size) { next_empty_cell -= size; } auto & cell = cells[next_empty_cell]; if (cell.is_empty()) { break; } } } } if (min > seq_meta.tail) { min = seq_meta.tail; } if (max < seq_meta.tail) { max = seq_meta.tail; } } // gather and re-order for (uint32_t s = 0; s < n_seqs; ++s) { const uint32_t i = s*n_seq_tokens; const int32_t dst_id = s + min; const int32_t src_id = cells[ubatch.seq_id[i][0]].tail; if (dst_id != src_id) { auto & dst_cell = cells[dst_id]; auto & src_cell = cells[src_id]; std::swap(dst_cell.pos, src_cell.pos); std::swap(dst_cell.src, src_cell.src); std::swap(dst_cell.seq_id, src_cell.seq_id); // swap tails for (uint32_t j = 0; j < size; ++j) { int32_t & tail = cells[j].tail; if (tail == src_id) { tail = dst_id; } else if (tail == dst_id) { tail = src_id; } } } } // update the pos of the used seqs for (uint32_t s = 0; s < n_seqs; ++s) { const uint32_t i = s*n_seq_tokens; const llama_pos last_pos = ubatch.pos[i + n_seq_tokens - 1]; const int32_t cell_id = s + min; auto & cell = cells[cell_id]; if (cell.pos >= 0 && last_pos != cell.pos + (llama_pos) n_seq_tokens) { // What should happen when the pos backtracks or skips a value? // Clearing the state mid-batch would require special-casing which isn't done. LLAMA_LOG_WARN("%s: non-consecutive token position %d after %d for sequence %d with %u new tokens\n", __func__, last_pos, cell.pos, ubatch.seq_id[i][0], n_seq_tokens); } cell.pos = last_pos; cell.seq_id.clear(); for (int32_t j = 0; j < ubatch.n_seq_id[i]; ++j) { const llama_seq_id seq_id = ubatch.seq_id[i][j]; cell.seq_id.insert(seq_id); cells[seq_id].tail = cell_id; } } // Find first cell without src refs, to use as the zero-ed state { // TODO: bake-in src refcounts in the cell metadata std::vector refcounts(size, 0); for (size_t i = 0; i < size; ++i) { const int32_t src = cells[i].src; if (src >= 0) { refcounts[src] += 1; } } rs_z = -1; for (int i = min; i <= max; ++i) { if (refcounts[i] == 0) { rs_z = i; break; } } for (int i = min; i <= max; ++i) { if (cells[i].src < 0) { GGML_ASSERT(rs_z >= 0); cells[i].src0 = rs_z; } else { // Stage the source ids for all used cells to allow correct seq_* behavior // and still make these values available when setting the inputs cells[i].src0 = cells[i].src; } cells[i].src = i; // avoid moving or clearing twice } } // allow getting the range of used cells, from head to head + n head = min; n = max - min + 1; used = std::count_if(cells.begin(), cells.end(), [](const mem_cell & cell){ return !cell.is_empty(); }); // sanity check return n >= n_seqs; } bool llama_memory_recurrent::get_can_shift() const { // shifting the pos is trivial for recurrent models return true; } size_t llama_memory_recurrent::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_memory_recurrent::size_r_bytes() const { size_t size_r_bytes = 0; for (const auto & r : r_l) { if (r != nullptr) { size_r_bytes += ggml_nbytes(r); } } return size_r_bytes; } size_t llama_memory_recurrent::size_s_bytes() const { size_t size_s_bytes = 0; for (const auto & s : s_l) { if (s != nullptr) { size_s_bytes += ggml_nbytes(s); } } return size_s_bytes; } void llama_memory_recurrent::state_write(llama_io_write_i & io, llama_seq_id seq_id, llama_state_seq_flags flags) const { GGML_UNUSED(flags); std::vector> cell_ranges; // ranges, from inclusive, to exclusive uint32_t cell_count = 0; // 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 = size; for (uint32_t i = 0; i < size; ++i) { const auto & cell = cells[i]; if ((seq_id == -1 && !cell.is_empty()) || cell.has_seq_id(seq_id)) { ++cell_count; if (cell_range_begin == size) { cell_range_begin = i; } } else { if (cell_range_begin != size) { cell_ranges.emplace_back(cell_range_begin, i); cell_range_begin = size; } } } if (cell_range_begin != size) { cell_ranges.emplace_back(cell_range_begin, 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 : cell_ranges) { cell_count_check += range.second - range.first; } GGML_ASSERT(cell_count == cell_count_check); io.write(&cell_count, sizeof(cell_count)); state_write_meta(io, cell_ranges, seq_id); state_write_data(io, cell_ranges); } void llama_memory_recurrent::state_read(llama_io_read_i & io, llama_seq_id seq_id, llama_state_seq_flags flags) { GGML_UNUSED(flags); uint32_t cell_count; io.read_to(&cell_count, sizeof(cell_count)); bool res = true; res = res && state_read_meta(io, cell_count, seq_id); res = res && state_read_data(io, cell_count); 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_memory_recurrent::state_write_meta(llama_io_write_i & io, const std::vector> & cell_ranges, llama_seq_id seq_id) const { for (const auto & range : cell_ranges) { for (uint32_t i = range.first; i < range.second; ++i) { const auto & cell = cells[i]; const llama_pos pos = cell.pos; const uint32_t n_seq_id = seq_id == -1 ? cell.seq_id.size() : 0; io.write(&pos, sizeof(pos)); io.write(&n_seq_id, sizeof(n_seq_id)); if (n_seq_id) { for (auto seq_id : cell.seq_id) { io.write(&seq_id, sizeof(seq_id)); } } } } } void llama_memory_recurrent::state_write_data(llama_io_write_i & io, const std::vector> & cell_ranges) const { const uint32_t s_trans = 0; const uint32_t n_layer = hparams.n_layer; io.write(&s_trans, sizeof(s_trans)); io.write(&n_layer, sizeof(n_layer)); // Iterate and write all the R tensors first, each row is a cell // Get whole range at a time for (uint32_t il = 0; il < n_layer; ++il) { // skip null layers (read_data will handle this by checking "r_l" and "s_l" for null) if (r_l[il] == nullptr) continue; // Write R tensor type const int32_t r_type_i = (int32_t)r_l[il]->type; io.write(&r_type_i, sizeof(r_type_i)); // Write row size of R tensor const uint64_t r_size_row = ggml_row_size(r_l[il]->type, hparams.n_embd_r()); io.write(&r_size_row, sizeof(r_size_row)); // Write each range of cells of r_size_row length for (const auto & range : cell_ranges) { const size_t range_size = range.second - range.first; const size_t buf_size = range_size * r_size_row; io.write_tensor(r_l[il], range.first * r_size_row, buf_size); } } if (!s_trans) { for (uint32_t il = 0; il < n_layer; ++il) { // skip null layers (read_data will handle this by checking "r_l" and "s_l" for null) if (s_l[il] == nullptr) continue; // Write S tensor type const int32_t s_type_i = (int32_t)s_l[il]->type; io.write(&s_type_i, sizeof(s_type_i)); // Write row size of S tensor const uint64_t s_size_row = ggml_row_size(s_l[il]->type, hparams.n_embd_s()); io.write(&s_size_row, sizeof(s_size_row)); // Write each range of S tensor rows for (const auto & range : cell_ranges) { const size_t range_size = range.second - range.first; const size_t buf_size = range_size * s_size_row; io.write_tensor(s_l[il], range.first * s_size_row, buf_size); } } } else { // When S tensor is transposed, we also need the element size and get the element ranges from each row const uint32_t mem_size = size; for (uint32_t il = 0; il < n_layer; ++il) { // skip null layers (read_data will handle this by checking "r_l" and "s_l" for null) if (s_l[il] == nullptr) continue; const uint32_t n_embd_s = hparams.n_embd_s(); // Write S tensor type const int32_t s_type_i = (int32_t)s_l[il]->type; io.write(&s_type_i, sizeof(s_type_i)); // Write element size const uint32_t s_size_el = ggml_type_size(s_l[il]->type); io.write(&s_size_el, sizeof(s_size_el)); // Write GQA embedding size io.write(&n_embd_s, sizeof(n_embd_s)); // For each row, we get the element values of each cell for (uint32_t j = 0; j < n_embd_s; ++j) { // Write each range of cells of s_size_el length for (const auto & range : cell_ranges) { const size_t range_size = range.second - range.first; const size_t src_offset = (range.first + j * mem_size) * s_size_el; const size_t buf_size = range_size * s_size_el; io.write_tensor(s_l[il], src_offset, buf_size); } } } } } bool llama_memory_recurrent::state_read_meta(llama_io_read_i & io, uint32_t cell_count, llama_seq_id dest_seq_id) { if (dest_seq_id != -1) { // single sequence seq_rm(dest_seq_id, -1, -1); if (cell_count == 0) { return true; } llama_batch_allocr balloc(hparams.n_pos_per_embd()); llama_ubatch ubatch = balloc.ubatch_reserve(cell_count, 1); 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 != 0) { LLAMA_LOG_ERROR("%s: invalid seq_id-agnostic kv cell\n", __func__); return false; } ubatch.pos[i] = pos; } ubatch.n_seq_id[0] = 1; ubatch.seq_id[0] = &dest_seq_id; if (!find_slot(ubatch)) { LLAMA_LOG_ERROR("%s: failed to find available cells in kv cache\n", __func__); return false; } // DEBUG CHECK: kv.head should be our first cell, kv.head + cell_count - 1 should be our last cell (verify seq_id and pos values) // Assume that this is one contiguous block of cells GGML_ASSERT(head + cell_count <= size); GGML_ASSERT(cells[head].pos == ubatch.pos[0]); GGML_ASSERT(cells[head + cell_count - 1].pos == ubatch.pos[cell_count - 1]); GGML_ASSERT(cells[head].has_seq_id(dest_seq_id)); GGML_ASSERT(cells[head + cell_count - 1].has_seq_id(dest_seq_id)); } else { // whole KV cache restore if (cell_count > 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) { auto & cell = cells[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)); cell.pos = pos; 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 >= this->n_seq_max) { LLAMA_LOG_ERROR("%s: invalid seq_id, %d is out of range [0, %u)\n", __func__, seq_id, this->n_seq_max); return false; } cell.seq_id.insert(seq_id); int32_t & tail = cells[seq_id].tail; if (tail != -1) { LLAMA_LOG_ERROR("%s: duplicate tail for seq_id %d in cell %d and %d\n", __func__, seq_id, i, tail); return false; } tail = i; } } head = 0; used = cell_count; } for (uint32_t i = 0; i < cell_count; ++i) { uint32_t cell_id = head + i; // make sure the recurrent states will keep their restored state cells[cell_id].src = cell_id; } return true; } bool llama_memory_recurrent::state_read_data(llama_io_read_i & io, uint32_t cell_count) { uint32_t s_trans; uint32_t n_layer; io.read_to(&s_trans, sizeof(s_trans)); io.read_to(&n_layer, sizeof(n_layer)); if (n_layer != hparams.n_layer) { LLAMA_LOG_ERROR("%s: mismatched layer count (%u instead of %u)\n", __func__, n_layer, hparams.n_layer); return false; } if (cell_count > size) { LLAMA_LOG_ERROR("%s: not enough cells in kv cache to restore state (%u > %u)\n", __func__, cell_count, size); return false; } if (false != (bool) s_trans) { LLAMA_LOG_ERROR("%s: incompatible s 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 (uint32_t il = 0; il < n_layer; ++il) { // skip null layers if (r_l[il] == nullptr) continue; // Read type of key int32_t r_type_i_ref; io.read_to(&r_type_i_ref, sizeof(r_type_i_ref)); const int32_t r_type_i = (int32_t) r_l[il]->type; if (r_type_i != r_type_i_ref) { LLAMA_LOG_ERROR("%s: mismatched r type (%d != %d, layer %d)\n", __func__, r_type_i, r_type_i_ref, il); return false; } // Read row size of key uint64_t r_size_row_ref; io.read_to(&r_size_row_ref, sizeof(r_size_row_ref)); const size_t r_size_row = ggml_row_size(r_l[il]->type, hparams.n_embd_r()); if (r_size_row != r_size_row_ref) { LLAMA_LOG_ERROR("%s: mismatched r row size (%zu != %zu, layer %d)\n", __func__, r_size_row, (size_t) r_size_row_ref, il); return false; } if (cell_count) { // Read and set the keys for the whole cell range ggml_backend_tensor_set(r_l[il], io.read(cell_count * r_size_row), head * r_size_row, cell_count * r_size_row); } } if (!s_trans) { for (uint32_t il = 0; il < n_layer; ++il) { // skip null layers if (s_l[il] == nullptr) continue; // Read type of value int32_t s_type_i_ref; io.read_to(&s_type_i_ref, sizeof(s_type_i_ref)); const int32_t s_type_i = (int32_t)s_l[il]->type; if (s_type_i != s_type_i_ref) { LLAMA_LOG_ERROR("%s: mismatched s type (%d != %d, layer %d)\n", __func__, s_type_i, s_type_i_ref, il); return false; } // Read row size of value uint64_t s_size_row_ref; io.read_to(&s_size_row_ref, sizeof(s_size_row_ref)); const size_t s_size_row = ggml_row_size(s_l[il]->type, hparams.n_embd_s()); if (s_size_row != s_size_row_ref) { LLAMA_LOG_ERROR("%s: mismatched s row size (%zu != %zu, layer %d)\n", __func__, s_size_row, (size_t) s_size_row_ref, il); return false; } if (cell_count) { // Read and set the values for the whole cell range ggml_backend_tensor_set(s_l[il], io.read(cell_count * s_size_row), head * s_size_row, cell_count * s_size_row); } } } else { // For each layer, read the values for each cell (transposed) for (uint32_t il = 0; il < n_layer; ++il) { // skip null layers if (s_l[il] == nullptr) continue; const uint32_t n_embd_s = hparams.n_embd_s(); // Read type of value int32_t s_type_i_ref; io.read_to(&s_type_i_ref, sizeof(s_type_i_ref)); const int32_t s_type_i = (int32_t)s_l[il]->type; if (s_type_i != s_type_i_ref) { LLAMA_LOG_ERROR("%s: mismatched s type (%d != %d, layer %d)\n", __func__, s_type_i, s_type_i_ref, il); return false; } // Read element size of value uint32_t s_size_el_ref; io.read_to(&s_size_el_ref, sizeof(s_size_el_ref)); const size_t s_size_el = ggml_type_size(s_l[il]->type); if (s_size_el != s_size_el_ref) { LLAMA_LOG_ERROR("%s: mismatched s element size (%zu != %zu, layer %d)\n", __func__, s_size_el, (size_t) s_size_el_ref, il); return false; } // Read state embedding size uint32_t n_embd_s_ref; io.read_to(&n_embd_s_ref, sizeof(n_embd_s_ref)); if (n_embd_s != n_embd_s_ref) { LLAMA_LOG_ERROR("%s: mismatched s embedding size (%u != %u, layer %d)\n", __func__, n_embd_s, n_embd_s_ref, il); return false; } if (cell_count) { // For each row in the transposed matrix, read the values for the whole cell range for (uint32_t j = 0; j < n_embd_s; ++j) { const size_t dst_offset = (head + j * size) * s_size_el; ggml_backend_tensor_set(s_l[il], io.read(cell_count * s_size_el), dst_offset, cell_count * s_size_el); } } } } return true; } // // llama_memory_recurrent_context // llama_memory_recurrent_context::llama_memory_recurrent_context(llama_memory_status status) : status(status) {} llama_memory_recurrent_context::llama_memory_recurrent_context( llama_memory_recurrent * mem) : status(LLAMA_MEMORY_STATUS_SUCCESS), mem(mem), is_full(true) { } llama_memory_recurrent_context::llama_memory_recurrent_context( llama_memory_recurrent * mem, std::vector ubatches) : status(LLAMA_MEMORY_STATUS_SUCCESS), mem(mem), ubatches(std::move(ubatches)) {} llama_memory_recurrent_context::~llama_memory_recurrent_context() = default; bool llama_memory_recurrent_context::next() { assert(status == LLAMA_MEMORY_STATUS_SUCCESS); if (++i_next >= ubatches.size()) { return false; } return true; } bool llama_memory_recurrent_context::apply() { assert(!llama_memory_status_is_fail(status)); // no ubatches -> this is an update if (ubatches.empty()) { // recurrent cache never performs updates assert(status == LLAMA_MEMORY_STATUS_NO_UPDATE); return true; } mem->find_slot(ubatches[i_next]); return true; } llama_memory_status llama_memory_recurrent_context::get_status() const { return status; } const llama_ubatch & llama_memory_recurrent_context::get_ubatch() const { assert(status == LLAMA_MEMORY_STATUS_SUCCESS); return ubatches[i_next]; } uint32_t llama_memory_recurrent_context::get_n_rs() const { return is_full ? mem->size : mem->n; } uint32_t llama_memory_recurrent_context::get_head() const { return is_full ? 0 : mem->head; } int32_t llama_memory_recurrent_context::get_rs_z() const { return is_full ? 0 : mem->rs_z; } uint32_t llama_memory_recurrent_context::get_size() const { return mem->size; } ggml_tensor * llama_memory_recurrent_context::get_r_l(int32_t il) const { return mem->r_l[il]; } ggml_tensor * llama_memory_recurrent_context::get_s_l(int32_t il) const { return mem->s_l[il]; } int32_t llama_memory_recurrent_context::s_copy(int i) const { return mem->cells[i + mem->head].src0; }