#include "speculative.h" #include "common.h" #include "ggml.h" #include "llama.h" #include "log.h" #include "ngram-cache.h" #include "ngram-map.h" #include "ngram-mod.h" #include "sampling.h" #include #include #include #include #include #define SPEC_VOCAB_MAX_SIZE_DIFFERENCE 128 #define SPEC_VOCAB_CHECK_START_TOKEN_ID 5 const std::vector common_speculative_types = { COMMON_SPECULATIVE_TYPE_NONE, COMMON_SPECULATIVE_TYPE_DRAFT, COMMON_SPECULATIVE_TYPE_EAGLE3, COMMON_SPECULATIVE_TYPE_NGRAM_SIMPLE, COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K, COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K4V, COMMON_SPECULATIVE_TYPE_NGRAM_MOD, COMMON_SPECULATIVE_TYPE_NGRAM_CACHE }; const std::map common_speculative_type_from_name_map = { {"none", COMMON_SPECULATIVE_TYPE_NONE}, {"draft", COMMON_SPECULATIVE_TYPE_DRAFT}, {"eagle3", COMMON_SPECULATIVE_TYPE_EAGLE3}, {"ngram_simple", COMMON_SPECULATIVE_TYPE_NGRAM_SIMPLE}, {"ngram_map_k", COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K}, {"ngram_map_k4v", COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K4V}, {"ngram_mod", COMMON_SPECULATIVE_TYPE_NGRAM_MOD}, {"ngram_cache", COMMON_SPECULATIVE_TYPE_NGRAM_CACHE} }; struct common_speculative_config { common_speculative_type type; common_params_speculative params; common_speculative_config(common_speculative_type t, const common_params_speculative & p = common_params_speculative{}) : type(t), params(p) {} }; static bool common_speculative_are_compatible( const llama_model * model_tgt, const llama_model * model_dft) { const llama_vocab * vocab_tgt = llama_model_get_vocab(model_tgt); const llama_vocab * vocab_dft = llama_model_get_vocab(model_dft); const bool vocab_type_tgt = llama_vocab_type(vocab_tgt); LOG_DBG("%s: vocab_type tgt: %d\n", __func__, vocab_type_tgt); const bool vocab_type_dft = llama_vocab_type(vocab_dft); LOG_DBG("%s: vocab_type dft: %d\n", __func__, vocab_type_dft); if (vocab_type_tgt != vocab_type_dft) { LOG_WRN("%s: draft model vocab type must match target model to use speculation but " "vocab_type_dft = %d while vocab_type_tgt = %d\n", __func__, vocab_type_dft, vocab_type_tgt); return false; } if (llama_vocab_get_add_bos(vocab_tgt) != llama_vocab_get_add_bos(vocab_dft) || (llama_vocab_get_add_bos(vocab_tgt) && llama_vocab_bos(vocab_tgt) != llama_vocab_bos(vocab_dft))) { LOG_WRN("%s: draft model bos tokens must match target model to use speculation. add: %d - %d, id: %d - %d)\n", __func__, llama_vocab_get_add_bos(vocab_tgt), llama_vocab_get_add_bos(vocab_dft), llama_vocab_bos(vocab_tgt), llama_vocab_bos(vocab_dft)); return false; } if (llama_vocab_get_add_eos(vocab_tgt) != llama_vocab_get_add_eos(vocab_dft) || (llama_vocab_get_add_eos(vocab_tgt) && llama_vocab_eos(vocab_tgt) != llama_vocab_eos(vocab_dft))) { LOG_WRN("%s: draft model eos tokens must match target model to use speculation. add: %d - %d, id: %d - %d)\n", __func__, llama_vocab_get_add_eos(vocab_tgt), llama_vocab_get_add_eos(vocab_dft), llama_vocab_eos(vocab_tgt), llama_vocab_eos(vocab_dft)); return false; } { const int n_vocab_tgt = llama_vocab_n_tokens(vocab_tgt); const int n_vocab_dft = llama_vocab_n_tokens(vocab_dft); const int vocab_diff = n_vocab_tgt > n_vocab_dft ? n_vocab_tgt - n_vocab_dft : n_vocab_dft - n_vocab_tgt; if (vocab_diff > SPEC_VOCAB_MAX_SIZE_DIFFERENCE) { LOG_DBG("%s: draft model vocab must closely match target model to use speculation but ", __func__); LOG_DBG("target vocab size %d does not match draft vocab size %d - difference %d, max allowed %d\n", n_vocab_tgt, llama_vocab_n_tokens(vocab_dft), vocab_diff, SPEC_VOCAB_MAX_SIZE_DIFFERENCE); return false; } for (int i = SPEC_VOCAB_CHECK_START_TOKEN_ID; i < std::min(n_vocab_tgt, n_vocab_dft); ++i) { const char * token_text_tgt = llama_vocab_get_text(vocab_tgt, i); const char * token_text_dft = llama_vocab_get_text(vocab_dft, i); if (std::strcmp(token_text_tgt, token_text_dft) != 0) { LOG_DBG("%s: draft model vocab must match target model to use speculation but ", __func__); LOG_DBG("token %d content differs - target '%s', draft '%s'\n", i, common_token_to_piece(vocab_tgt, i).c_str(), common_token_to_piece(vocab_dft, i).c_str()); return false; } } } return true; } // state of an implementation of speculative decoding // // each implementation has a unique type and a state that is implementation-specific // in a subclass of common_speculative_state struct common_speculative_state { const enum common_speculative_type type; size_t n_call_begin = 0; // number of times this implementation was called for refresh. size_t n_call_draft = 0; // number of times this implementation was called for generation. size_t n_call_accept = 0; // number of times this implementation was called for accumulation. size_t n_gen_drafts = 0; // number of times a draft or part was generated by this implementation. size_t n_acc_drafts = 0; // number of times a draft or part was accepted by the target model. size_t n_gen_tokens = 0; // number of tokens generated by this implementation. size_t n_acc_tokens = 0; // number of tokens accepted by the target model. // TODO: track performance of most recent calls const bool gen_perf = true; // whether to generate performance stats. int64_t t_begin_us = 0; // total time spent in refresh of this implementation in microseconds. int64_t t_draft_us = 0; // total time spent in generating drafts in this implementation in microseconds. int64_t t_accept_us = 0; // total time spent in accumulation of this implementation in microseconds. common_speculative_state(enum common_speculative_type type) : type(type) {} virtual ~common_speculative_state() = default; virtual void begin(const llama_tokens & prompt) = 0; virtual void draft( const common_params_speculative & params, const llama_tokens & prompt_tgt, llama_token id_last, llama_tokens & result) = 0; virtual void accept(uint16_t n_accepted) = 0; virtual int32_t n_max(const common_params_speculative & params) const = 0; virtual int32_t n_min(const common_params_speculative & params) const = 0; }; struct common_speculative_checkpoint { llama_pos pos_min = 0; llama_pos pos_max = 0; int64_t n_tokens = 0; std::vector data; size_t size() const { return data.size(); } }; struct common_speculative_state_draft : public common_speculative_state { llama_context * ctx_tgt; // only used for retokenizing from ctx_dft llama_context * ctx_dft; bool use_ckpt = false; common_speculative_checkpoint ckpt; common_sampler * smpl; llama_batch batch; llama_tokens prompt_dft; bool vocab_cmpt = true; // whether retokenization is needed std::unordered_map vocab_map; common_speculative_state_draft( enum common_speculative_type type, llama_context * ctx_tgt, llama_context * ctx_dft, const std::vector> & replacements, bool use_ckpt) : common_speculative_state(type) , ctx_tgt(ctx_tgt) , ctx_dft(ctx_dft) , use_ckpt(use_ckpt) { batch = llama_batch_init(llama_n_batch(ctx_dft), 0, 1); smpl = nullptr; // TODO: optimize or pass from outside? // { // common_params_sampling params; // params.no_perf = false; // // params.top_k = 40; // params.top_p = 0.9; // // params.samplers = { // COMMON_SAMPLER_TYPE_TOP_K, // COMMON_SAMPLER_TYPE_TOP_P, // COMMON_SAMPLER_TYPE_INFILL, // }; // // result->smpl = common_sampler_init(llama_get_model(ctx_dft), params); // } { common_params_sampling params; params.no_perf = false; params.top_k = 10; params.samplers = { COMMON_SAMPLER_TYPE_TOP_K, }; smpl = common_sampler_init(llama_get_model(ctx_dft), params); } vocab_cmpt = common_speculative_are_compatible(llama_get_model(ctx_tgt), llama_get_model(ctx_dft)); LOG_DBG("vocab_cmpt = %d\n", vocab_cmpt); if (!vocab_cmpt) { LOG_WRN("the target and draft vocabs are not compatible - tokens will be translated between the two\n"); for (const auto & pair : replacements) { vocab_map[pair.first] = pair.second; } } } ~common_speculative_state_draft() override { llama_perf_context_print(ctx_dft); llama_free(ctx_dft); common_sampler_free(smpl); llama_batch_free(batch); } void begin(const llama_tokens & /*prompt*/) override { } size_t create_checkpoint(int n_tokens_prompt) { int slot_id = 0; const size_t checkpoint_size = llama_state_seq_get_size_ext(ctx_dft, slot_id, LLAMA_STATE_SEQ_FLAGS_PARTIAL_ONLY); ckpt.pos_min = llama_memory_seq_pos_min(llama_get_memory(ctx_dft), slot_id); ckpt.pos_max = llama_memory_seq_pos_max(llama_get_memory(ctx_dft), slot_id); ckpt.n_tokens = n_tokens_prompt; ckpt.data.resize(checkpoint_size); const size_t n = llama_state_seq_get_data_ext(ctx_dft, ckpt.data.data(), checkpoint_size, slot_id, LLAMA_STATE_SEQ_FLAGS_PARTIAL_ONLY); if (n != checkpoint_size) { GGML_ABORT("checkpoint size mismatch: expected %zu, got %zu\n", checkpoint_size, n); } LOG_DBG("%s: pos_min = %d, pos_max = %d, size = %.3f MiB\n", __func__, ckpt.pos_min, ckpt.pos_max, (float) ckpt.data.size() / 1024 / 1024); return n; } size_t restore_checkpoint() { int slot_id = 0; LOG_DBG("%s: pos_min = %d, pos_max = %d\n", __func__, ckpt.pos_min, ckpt.pos_max); const size_t n = llama_state_seq_set_data_ext(ctx_dft, ckpt.data.data(), ckpt.size(), slot_id, LLAMA_STATE_SEQ_FLAGS_PARTIAL_ONLY); if (n != ckpt.size()) { GGML_ABORT("%s: failed to restore context checkpoint (pos_min=%d, pos_max=%d, size=%zu", __func__, ckpt.pos_min, ckpt.pos_max, ckpt.size()); } llama_memory_seq_rm(llama_get_memory(ctx_dft), slot_id, ckpt.pos_max + 1, -1); return n; } void draft( const common_params_speculative & params, const llama_tokens & prompt_tgt, llama_token id_last, llama_tokens & result) override { const auto & sparams = params.draft; auto * spec = this; auto & batch = spec->batch; auto & ctx_tgt = spec->ctx_tgt; auto & ctx_dft = spec->ctx_dft; auto & smpl = spec->smpl; auto & prompt_dft = spec->prompt_dft; auto * mem_dft = llama_get_memory(ctx_dft); int reuse_i = 0; // index of part to be reused in prompt_dft int reuse_n = 0; // length of part to be reused in prompt_dft const int n_ctx = llama_n_ctx(ctx_dft) - sparams.n_max; llama_tokens prompt_cnv; if (!spec->vocab_cmpt) { std::string text; text = common_detokenize(ctx_tgt, prompt_tgt, true); text = replace_to_dft(text); LOG_DBG("%s: main->draft detokenized string: '%s'\n", __func__, text.c_str()); prompt_cnv = common_tokenize(ctx_dft, text, false, true); // convert id_last to draft vocab. llama_detokenize is called directly to avoid an allocation const auto * model_tgt = llama_get_model(ctx_tgt); const auto * vocab_tgt = llama_model_get_vocab(model_tgt); int32_t n_chars = llama_detokenize(vocab_tgt, &id_last, 1, nullptr, 0, false, false); GGML_ASSERT(n_chars < 0 && "failed to detokenize id_last"); text.resize(-n_chars); llama_detokenize(vocab_tgt, &id_last, 1, text.data(), text.size(), false, false); text = replace_to_dft(text); LOG_DBG("main->draft detokenized id_last(%d): '%s'\n", id_last, text.c_str()); id_last = common_tokenize(ctx_dft, text, false, true)[0]; } const llama_tokens & prompt_cur = spec->vocab_cmpt ? prompt_tgt : prompt_cnv; const int i_start = std::max(0, (int) prompt_cur.size() - n_ctx); if (use_ckpt && i_start > 0) { LOG_WRN("%s: context shift is not supported with checkpoint-based contexts - skipping\n", __func__); return; } // reuse as much as possible from the old draft context // ideally, the draft context should be as big as the target context and we will always reuse the entire prompt for (int i = 0; i < (int) prompt_dft.size(); ++i) { int cur = 0; while (i_start + cur < (int) prompt_cur.size() && i + cur < (int) prompt_dft.size() && prompt_cur[i_start + cur] == prompt_dft[i + cur]) { cur++; } if ((cur >= 256 || n_ctx >= (int) prompt_cur.size()) && cur > reuse_n) { reuse_i = i; reuse_n = cur; } if (use_ckpt) { break; } } LOG_DBG("%s: reuse_i = %d, reuse_n = %d, #prompt_dft = %zu, #prompt_cur = %zu\n", __func__, reuse_i, reuse_n, prompt_dft.size(), prompt_cur.size()); if (use_ckpt && ckpt.n_tokens > reuse_n) { LOG_DBG("%s: checkpoint (n_tokens = %d) is outdated -> delete it\n", __func__, (int) ckpt.n_tokens); reuse_i = 0; reuse_n = 0; ckpt = {}; } result.clear(); result.reserve(sparams.n_max); if (reuse_n == 0 || (use_ckpt && reuse_i > 0)) { llama_memory_clear(mem_dft, false); prompt_dft.clear(); } else { // this happens when a previous draft has been discarded (for example, due to being too small), but the // target model agreed with it. in this case, we simply pass back the previous results to save compute if (reuse_i + reuse_n < (int64_t) prompt_dft.size() && prompt_dft[reuse_i + reuse_n] == id_last) { for (int i = reuse_i + reuse_n + 1; i < (int) prompt_dft.size(); ++i) { result.push_back(prompt_dft[i]); if (sparams.n_max <= (int) result.size()) { break; } } return; } if (reuse_i > 0) { GGML_ASSERT(!use_ckpt); bool is_removed = llama_memory_seq_rm (mem_dft, 0, 0, reuse_i); if (!is_removed) { LOG_ERR("%s: llama_memory_seq_rm failed, reuse_i=%d\n", __func__, reuse_i); return; } llama_memory_seq_add(mem_dft, 0, reuse_i, -1, -reuse_i); prompt_dft.erase(prompt_dft.begin(), prompt_dft.begin() + reuse_i); } if (reuse_n < (int) prompt_dft.size()) { if (use_ckpt) { if (ckpt.n_tokens > 0) { LOG_DBG("%s: restoring checkpoint, reuse_n=%d, prompt_dft.size=%zu\n", __func__, reuse_n, prompt_dft.size()); restore_checkpoint(); reuse_n = ckpt.n_tokens; prompt_dft.resize(reuse_n); } } else { const bool is_removed = llama_memory_seq_rm(mem_dft, 0, reuse_n, -1); if (!is_removed) { LOG_ERR("%s: llama_memory_seq_rm failed, reuse_n=%d, prompt_dft.size=%zu\n", __func__, reuse_n, prompt_dft.size()); return; } prompt_dft.erase(prompt_dft.begin() + reuse_n, prompt_dft.end()); } } } // prepare a batch to evaluate any new tokens in the prompt common_batch_clear(batch); for (size_t i = i_start + reuse_n; i < prompt_cur.size(); ++i) { //LOG_DBG("i = %d, i_start = %d, reuse_n = %d, i - i_start = %d, id = %6d\n", i, i_start, reuse_n, i - i_start, prompt_cur[i]); common_batch_add(batch, prompt_cur[i], i - i_start, { 0 }, false); prompt_dft.push_back(prompt_cur[i]); } // we should rarely end-up here during normal decoding if (batch.n_tokens > 0) { //LOG_DBG("%s: draft prompt batch: %s\n", __func__, string_from(ctx, batch).c_str()); LOG_DBG("%s: draft prompt batch: %d tokens\n", __func__, batch.n_tokens); int ret = llama_decode(ctx_dft, batch); if (ret != 0 && ret != 1) { LOG_WRN("%s: llama_decode returned %d, prompt_cur.size=%zu\n", __func__, ret, prompt_cur.size()); } if (use_ckpt) { create_checkpoint(prompt_dft.size()); } } const llama_pos n_past = prompt_dft.size(); LOG_DBG("%s: n_past = %d\n", __func__, n_past); common_batch_clear(batch); common_batch_add (batch, id_last, n_past, { 0 }, true); prompt_dft.push_back(id_last); //LOG_DBG("%s: draft prompt: %s\n", __func__, string_from(ctx_dft, prompt_dft).c_str()); int ret = llama_decode(ctx_dft, batch); if (ret != 0 && ret != 1) { LOG_WRN("%s: llama_decode returned %d, prompt_cur.size=%zu, prompt_dft.size=%zu\n", __func__, ret, prompt_cur.size(), prompt_dft.size()); } common_sampler_reset(smpl); // sample n_draft tokens from the draft model for (int i = 0; i < sparams.n_max; ++i) { common_batch_clear(batch); common_sampler_sample(smpl, ctx_dft, 0, true); const auto * cur_p = common_sampler_get_candidates(smpl, true); for (int k = 0; k < std::min(3, (int) cur_p->size); ++k) { LOG_DBG(" - draft candidate %3d, pos %3d: %6d (%8.3f) '%s'\n", k, i, cur_p->data[k].id, cur_p->data[k].p, common_token_to_piece(ctx_dft, cur_p->data[k].id).c_str()); } // add drafted token for each sequence const llama_token id = cur_p->data[0].id; common_sampler_accept(smpl, id, true); // only collect very high-confidence draft tokens if (cur_p->data[0].p < sparams.p_min) { break; } result.push_back(id); if (sparams.n_max <= (int) result.size()) { break; } common_batch_add(batch, id, n_past + i + 1, { 0 }, true); // evaluate the drafted tokens on the draft model ret = llama_decode(ctx_dft, batch); if (ret != 0) { LOG_WRN("%s: llama_decode[%d] returned %d, prompt_cur.size=%zu, prompt_dft.size=%zu\n", __func__, i, ret, prompt_cur.size(), prompt_dft.size()); } prompt_dft.push_back(id); } if (!spec->vocab_cmpt) { std::string detokenized = common_detokenize(ctx_dft, result, true); detokenized = replace_to_tgt(detokenized); LOG_DBG("draft->main detokenized string: '%s'\n", detokenized.c_str()); result = common_tokenize(ctx_tgt, detokenized, false, true); if (result.size() > (size_t) sparams.n_max) { result.resize(sparams.n_max); } } if (result.size() < (size_t) sparams.n_min) { result.clear(); } } void accept(uint16_t n_accepted) override { // noop GGML_UNUSED(n_accepted); } int32_t n_max(const common_params_speculative & params) const override { return params.draft.n_max; } int32_t n_min(const common_params_speculative & params) const override { return params.draft.n_min; } std::string replace_to_dft(const std::string & input) const { std::string result = input; for (const auto & pair : this->vocab_map) { size_t pos = result.find(pair.first); while (pos != std::string::npos) { result.replace(pos, pair.first.length(), pair.second); pos = result.find(pair.first, pos + pair.second.length()); } } return result; } std::string replace_to_tgt(const std::string & input) const { std::string result = input; for (const auto & pair : this->vocab_map) { size_t pos = result.find(pair.second); while (pos != std::string::npos) { result.replace(pos, pair.second.length(), pair.first); pos = result.find(pair.second, pos + pair.first.length()); } } return result; } }; struct common_speculative_state_eagle3 : public common_speculative_state { common_speculative_state_eagle3(enum common_speculative_type type) : common_speculative_state(type) {} void begin(const llama_tokens & prompt) override { GGML_UNUSED(prompt); } void draft( const common_params_speculative & params, const llama_tokens & prompt_tgt, llama_token id_last, llama_tokens & draft_tokens) override { // TODO: implement GGML_UNUSED(params); GGML_UNUSED(prompt_tgt); GGML_UNUSED(id_last); GGML_UNUSED(draft_tokens); } void accept(uint16_t n_accepted) override { // noop GGML_UNUSED(n_accepted); } int32_t n_max(const common_params_speculative & params) const override { return params.draft.n_max; } int32_t n_min(const common_params_speculative & params) const override { return params.draft.n_min; } }; // state of self-speculation (simple implementation, not ngram-map) struct common_speculative_state_ngram_simple : public common_speculative_state { common_ngram_simple_config config; common_speculative_state_ngram_simple( enum common_speculative_type type, common_ngram_simple_config config) : common_speculative_state(type), config(config) {} void begin(const llama_tokens & prompt) override { GGML_UNUSED(prompt); } void draft( const common_params_speculative & params, const llama_tokens & prompt_tgt, llama_token id_last, llama_tokens & result) override { result = common_ngram_simple_draft(config, prompt_tgt, id_last); GGML_UNUSED(params); } void accept(uint16_t n_accepted) override { // noop GGML_UNUSED(n_accepted); } int32_t n_max(const common_params_speculative & /*params*/) const override { return config.size_mgram; } int32_t n_min(const common_params_speculative & /*params*/) const override { return config.size_mgram; } }; struct common_speculative_state_ngram_map_k : public common_speculative_state { // draft ngram map for speculative decoding without draft model common_ngram_map config; common_speculative_state_ngram_map_k( enum common_speculative_type type, common_ngram_map config) : common_speculative_state(type), config(std::move(config)) {} void begin(const llama_tokens & prompt) override { common_ngram_map_begin(config, prompt); } void draft( const common_params_speculative & params, const llama_tokens & prompt_tgt, llama_token id_last, llama_tokens & result) override { common_ngram_map_draft(config, prompt_tgt, id_last, result); GGML_UNUSED(params); } void accept(uint16_t n_accepted) override { common_ngram_map_accept(config, n_accepted); } int32_t n_max(const common_params_speculative & /*params*/) const override { return config.size_value; } int32_t n_min(const common_params_speculative & /*params*/) const override { return config.size_value; } }; struct common_speculative_state_ngram_mod : public common_speculative_state { common_ngram_mod & mod; // the last position in the prompt that was added to the ngram container size_t i_last = 0; // length of the last drafted n‑gram (number of tokens returned by draft) size_t n_draft_last = 0; // consecutive accept rounds with low acceptance fraction (< 0.5) int n_low = 0; // enable trace logging if LLAMA_TRACE is set const bool verbose; common_speculative_state_ngram_mod(enum common_speculative_type type, common_ngram_mod & mod) : common_speculative_state(type), mod(mod), verbose(std::getenv("LLAMA_TRACE") != nullptr) { static_assert(sizeof(llama_token) == sizeof(common_ngram_mod::entry_t)); } void begin(const llama_tokens & prompt) override { i_last = 0; n_draft_last = 0; const size_t n = mod.get_n(); if (prompt.size() < n) { return; } for (size_t i = 0; i < prompt.size() - n; ++i) { mod.add(prompt.data() + i); } i_last = prompt.size() - n; const double f = (double)mod.get_used() / (double)mod.size(); LOG_INF("%s: ngram_mod occupancy = %zu/%zu (%.2f)\n", __func__, mod.get_used(), mod.size(), f); constexpr double f_thold = 0.25; if (f > f_thold) { LOG_WRN("%s: ngram_mod occupancy %.2f exceeds threshold (%.2f) - resetting\n", __func__, f, f_thold); mod.reset(); } } void draft( const common_params_speculative & params, const llama_tokens & prompt_tgt, llama_token id_last, llama_tokens & result) override { const auto & sparams = params.ngram_mod; n_draft_last = 0; const size_t cur_len = prompt_tgt.size(); if (cur_len < mod.get_n()) { return; } const size_t n = mod.get_n(); // add new ngrams in chunks if (i_last + 32 < cur_len) { for (size_t i = i_last; i < cur_len - n; ++i) { mod.add(prompt_tgt.data() + i); } i_last = cur_len - n; } result.resize(n + sparams.n_max); for (size_t i = 0; i < n - 1; ++i) { result[i] = prompt_tgt[cur_len - n + 1 + i]; } result[n - 1] = id_last; for (int i = 0; i < sparams.n_max; ++i) { const llama_token token = mod.get(result.data() + i); if (token == common_ngram_mod::EMPTY) { if (i < sparams.n_min) { result.clear(); return; } result.resize(n + i); break; } result[n + i] = token; } // only return the m tokens that were drafted for (size_t i = 0; n + i < result.size(); ++i) { result[i] = result[n + i]; } result.resize(result.size() - n); // store length of drafted n‑gram for later acceptance analysis n_draft_last = result.size(); } void accept(uint16_t n_accepted) override { // compute acceptance fraction if we have a recorded draft length if (n_draft_last > 0) { const double f_acc = (double)n_accepted / (double)n_draft_last; if (f_acc < 0.5) { n_low++; if (n_low >= 3) { if (verbose) { LOG_WRN("%s: low acceptance streak (%d) – resetting ngram_mod\n", __func__, n_low); } mod.reset(); n_low = 0; i_last = 0; } } else { n_low = 0; } } } int32_t n_max(const common_params_speculative & params) const override { return params.ngram_mod.n_max; } int32_t n_min(const common_params_speculative & params) const override { return params.ngram_mod.n_min; } }; struct common_speculative_state_ngram_cache : public common_speculative_state { uint16_t n_draft; bool save_dynamic; bool save_static; common_ngram_cache ngram_cache_context; common_ngram_cache ngram_cache_dynamic; common_ngram_cache ngram_cache_static; size_t cache_size = 0; // number of tokens in n-gram cache common_speculative_state_ngram_cache( const enum common_speculative_type type, const std::string & path_static, const std::string & path_dynamic, uint16_t n_draft, bool save_dynamic, bool save_static) : common_speculative_state(type) , n_draft(n_draft) , save_dynamic(save_dynamic) , save_static(save_static) { if (!path_static.empty()) { try { ngram_cache_static = common_ngram_cache_load(path_static); } catch (...) { LOG_ERR("failed to open static lookup cache: %s", path_static.c_str()); GGML_ABORT("Couldn't read static lookup cache"); } } if (!path_dynamic.empty()) { try { ngram_cache_dynamic = common_ngram_cache_load(path_dynamic); } catch (...) { LOG_ERR("failed to open dynamic lookup cache: %s", path_dynamic.c_str()); GGML_ABORT("Couldn't read dynamic lookup cache"); } } } void begin(const llama_tokens & prompt) override { GGML_UNUSED(prompt); } void draft( const common_params_speculative & params, const llama_tokens & prompt_tgt, llama_token id_last, llama_tokens & result) override { GGML_UNUSED(params); if (cache_size < prompt_tgt.size() + 1) { llama_tokens tokens_new; tokens_new.reserve(prompt_tgt.size() + 1 - cache_size); for (size_t j = cache_size; j < prompt_tgt.size(); ++j) { tokens_new.push_back(prompt_tgt[j]); } tokens_new.push_back(id_last); // add the last token // Update context ngram cache with new prompt_tgt: common_ngram_cache_update(ngram_cache_context, LLAMA_NGRAM_MIN, LLAMA_NGRAM_MAX, tokens_new, tokens_new.size(), false); cache_size = prompt_tgt.size() + 1; } llama_tokens inp; inp.reserve(prompt_tgt.size() + 1); for (size_t j = 0; j < prompt_tgt.size(); ++j) { inp.push_back(prompt_tgt[j]); } inp.push_back(id_last); result.push_back(id_last); common_ngram_cache_draft(inp, result, n_draft, LLAMA_NGRAM_MIN, LLAMA_NGRAM_MAX, ngram_cache_context, ngram_cache_dynamic, ngram_cache_static); if (result.size() > 0) { // delete first token in result (which is the id_last token) result.erase(result.begin()); } } void accept(uint16_t n_accepted) override { // TODO: noop GGML_UNUSED(n_accepted); } int32_t n_max(const common_params_speculative & /*params*/) const override { return n_draft; } int32_t n_min(const common_params_speculative & /*params*/) const override { return 0; } }; struct common_speculative { std::vector> impls; // list of implementations to use and their states common_speculative_state * curr_impl = nullptr; // current implementation in use (for stats) }; static common_ngram_map get_common_ngram_map( common_speculative_type type, const common_params_speculative_ngram_map & config) { uint16_t size_key = config.size_n; uint16_t size_value = config.size_m; bool key_only = type == COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K; uint16_t min_hits = config.min_hits; return common_ngram_map(size_key, size_value, key_only, min_hits); } static common_speculative_state_ngram_cache create_state_ngram_cache( const std::string & path_static, const std::string & path_dynamic, const common_speculative_config & config) { uint16_t n_draft = 8; // TODO get from config? // TODO bool param in common/common.h to set save_static/save_dynamic? bool save_static = false; bool save_dynamic = false; common_speculative_state_ngram_cache state(config.type, path_static, path_dynamic, n_draft, save_static, save_dynamic); return state; } std::string common_speculative_type_name_str() { std::string result; for (size_t i = 0; i < common_speculative_types.size(); i++) { if (i > 0) { result += ", "; } result += common_speculative_type_to_str(common_speculative_types[i]); } return result; } std::string common_speculative_type_to_str(enum common_speculative_type type) { switch (type) { case COMMON_SPECULATIVE_TYPE_NONE: return "none"; case COMMON_SPECULATIVE_TYPE_DRAFT: return "draft"; case COMMON_SPECULATIVE_TYPE_EAGLE3: return "eagle3"; case COMMON_SPECULATIVE_TYPE_NGRAM_SIMPLE: return "ngram_simple"; case COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K: return "ngram_map_k"; case COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K4V: return "ngram_map_k4v"; case COMMON_SPECULATIVE_TYPE_NGRAM_MOD: return "ngram_mod"; case COMMON_SPECULATIVE_TYPE_NGRAM_CACHE: return "ngram_cache"; default: return "unknown"; } } enum common_speculative_type common_speculative_type_from_name(const std::string & name) { const auto it = common_speculative_type_from_name_map.find(name); if (it == common_speculative_type_from_name_map.end()) { return COMMON_SPECULATIVE_TYPE_COUNT; } return it->second; } // initialization of the speculative decoding system // common_speculative * common_speculative_init( common_params_speculative & params, llama_context * ctx_tgt) { llama_context * ctx_dft = nullptr; if (params.draft.model) { ctx_dft = llama_init_from_model(params.draft.model, params.draft.cparams); if (ctx_dft == nullptr) { LOG_ERR("%s", "failed to create draft context\n"); return nullptr; } } // Compute the implementations to use based on the config and their order of preference std::vector configs = {}; // list of speculative configs to try { bool has_draft = !params.draft.mparams.path.empty(); bool has_draft_eagle3 = false; // TODO PR-18039: if params.speculative.eagle3 bool has_ngram_cache = (params.type == COMMON_SPECULATIVE_TYPE_NGRAM_CACHE); bool has_ngram_simple = (params.type == COMMON_SPECULATIVE_TYPE_NGRAM_SIMPLE); bool has_ngram_map_k = (params.type == COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K); bool has_ngram_map_k4v = (params.type == COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K4V); bool has_ngram_mod = (params.type == COMMON_SPECULATIVE_TYPE_NGRAM_MOD); // In a more complex implementation we could use the same implementation but with different parameters. // This was initially used in PR-18471 but removed to simplify the code. if (has_ngram_simple) { // This implementation can guess a lot of tokens without any draft model. configs.push_back(common_speculative_config(COMMON_SPECULATIVE_TYPE_NGRAM_SIMPLE, params)); } if (has_ngram_map_k) { configs.push_back(common_speculative_config(COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K, params)); } if (has_ngram_map_k4v) { // This implementation can guess tokens with high acceptance rate but is more expensive. configs.push_back(common_speculative_config(COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K4V, params)); } if (has_ngram_mod) { auto & sparams = params.ngram_mod; if (!sparams.obj) { sparams.obj = std::make_shared(sparams.n_match, 4*1024*1024); LOG_INF("%s: initialized ngram_mod with n_match=%d, size=%zu (%.3f MB)\n", __func__, sparams.n_match, sparams.obj->size(), (float)(sparams.obj->size_bytes())/1024/1024); if (sparams.n_match < 16) { LOG_WRN("%s: ngram_mod n_match=%d is too small - poor quality is possible, " "see: https://github.com/ggml-org/llama.cpp/pull/19164\n", __func__, sparams.n_match); } } configs.push_back(common_speculative_config(COMMON_SPECULATIVE_TYPE_NGRAM_MOD, params)); } if (has_ngram_cache) { configs.push_back(common_speculative_config(COMMON_SPECULATIVE_TYPE_NGRAM_CACHE, params)); } if (has_draft) { configs.push_back(common_speculative_config(COMMON_SPECULATIVE_TYPE_DRAFT, params)); } if (has_draft_eagle3) { configs.push_back(common_speculative_config(COMMON_SPECULATIVE_TYPE_EAGLE3, params)); } } std::vector> impls = {}; for (const common_speculative_config & config : configs) { LOG_DBG("%s: adding implementation %s\n", __func__, common_speculative_type_to_str(config.type).c_str()); switch (config.type) { case COMMON_SPECULATIVE_TYPE_NONE: break; case COMMON_SPECULATIVE_TYPE_DRAFT: { const bool use_ckpt = common_context_can_seq_rm(ctx_dft) == COMMON_CONTEXT_SEQ_RM_TYPE_FULL; impls.push_back(std::make_unique(config.type, /* .ctx_tgt = */ ctx_tgt, /* .ctx_dft = */ ctx_dft, /* .replacements = */ params.draft.replacements, /* .use_ckpt = */ use_ckpt )); break; } case COMMON_SPECULATIVE_TYPE_EAGLE3: { impls.push_back(std::make_unique(config.type)); break; } case COMMON_SPECULATIVE_TYPE_NGRAM_SIMPLE: { common_ngram_map ngram_map = get_common_ngram_map(config.type, config.params.ngram_simple); uint16_t ngram_size_key = ngram_map.size_key; uint16_t mgram_size_value = ngram_map.size_value; auto config_simple = common_ngram_simple_config { /* .size_ngram = */ ngram_size_key, /* .size_mgram = */ mgram_size_value }; auto state = std::make_unique( /* .type = */ config.type, /* .state = */ config_simple ); impls.push_back(std::move(state)); break; } case COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K: case COMMON_SPECULATIVE_TYPE_NGRAM_MAP_K4V: { impls.push_back(std::make_unique( (config.type), get_common_ngram_map(config.type, config.params.ngram_map_k) )); break; } case COMMON_SPECULATIVE_TYPE_NGRAM_MOD: { GGML_ASSERT(config.params.ngram_mod.obj); impls.push_back(std::make_unique(config.type, *config.params.ngram_mod.obj)); break; } case COMMON_SPECULATIVE_TYPE_NGRAM_CACHE: { auto state = create_state_ngram_cache(params.ngram_cache.lookup_cache_static, params.ngram_cache.lookup_cache_dynamic, config); impls.push_back(std::make_unique(state)); break; } default: break; } } if (impls.empty()) { LOG_WRN("%s", "no implementations specified for speculative decoding\n"); return nullptr; } auto * result = new common_speculative { /* .impls = */ std::move(impls), /* .curr_impl = */ nullptr, }; return result; } void common_speculative_free(common_speculative * spec) { if (spec == nullptr) { return; } delete spec; } void common_speculative_begin(common_speculative * spec, const llama_tokens & prompt) { if (spec == nullptr) { return; } for (auto & impl : spec->impls) { common_time_meas tm(impl->t_begin_us, !impl->gen_perf); impl->begin(prompt); impl->n_call_begin++; } } llama_tokens common_speculative_draft( common_speculative * spec, const common_params_speculative & params, const llama_tokens & prompt_tgt, // specified in target model vocab llama_token id_last) { llama_tokens result; spec->curr_impl = nullptr; // reset current implementation for (auto & impl : spec->impls) { { common_time_meas tm(impl->t_draft_us, !impl->gen_perf); impl->draft(params, prompt_tgt, id_last, result); impl->n_call_draft++; } { const int n_min = impl->n_min(params); if (!result.empty() && (int) result.size() < n_min) { LOG_DBG("%s: ignoring small draft: %d < %d\n", __func__, (int) result.size(), n_min); result.clear(); } } if (!result.empty()) { LOG_DBG("%s: called impl %s, hist size = %zu, call_count = %zu, gen = %zu\n", __func__, common_speculative_type_to_str(impl.get()->type).c_str(), prompt_tgt.size(), impl.get()->n_call_draft, result.size()); spec->curr_impl = impl.get(); // set current implementation for stats impl->n_gen_drafts++; impl->n_gen_tokens += result.size(); break; // we have a draft, so break out of the loop and return it. } } return result; } void common_speculative_accept(common_speculative * spec, uint16_t n_accepted) { if (n_accepted == 0) { return; } common_speculative_state * impl = spec->curr_impl; GGML_ASSERT(impl); { common_time_meas tm(impl->t_accept_us, !impl->gen_perf); if (n_accepted > 0) { impl->n_acc_drafts++; impl->n_acc_tokens += n_accepted; } impl->accept(n_accepted); impl->n_call_accept++; } } int32_t common_speculative_n_max(const common_speculative * spec, const common_params_speculative & params) { if (spec == nullptr) { return 0; } int32_t n_max = 0; for (const auto & impl : spec->impls) { n_max = std::max(n_max, impl->n_max(params)); } return n_max; } int32_t common_speculative_n_min(const common_speculative * spec, const common_params_speculative & params) { if (spec == nullptr) { return 0; } int32_t n_min = 0; for (const auto & impl : spec->impls) { n_min = std::max(n_min, impl->n_min(params)); } return n_min; } void common_speculative_print_stats(const common_speculative * spec) { if (spec == nullptr) { return; } for (const auto & impl : spec->impls) { std::string str_perf; if (impl->gen_perf) { std::ostringstream oss; oss << std::fixed << std::setprecision(3) << impl->t_begin_us / 1000.0 << ", "; oss << std::fixed << std::setprecision(3) << impl->t_draft_us / 1000.0 << ", "; oss << std::fixed << std::setprecision(3) << impl->t_accept_us / 1000.0; str_perf = ", dur(b,g,a) = " + oss.str() + " ms"; } else { str_perf = ""; } LOG_INF("statistics %s: #calls(b,g,a) = %zu %zu %zu, #gen drafts = %zu, #acc drafts = %zu, #gen tokens = %zu, #acc tokens = %zu%s\n", common_speculative_type_to_str(impl->type).c_str(), impl->n_call_begin, impl->n_call_draft, impl->n_call_accept, impl->n_gen_drafts, impl->n_acc_drafts, impl->n_gen_tokens, impl->n_acc_tokens, str_perf.c_str()); } }