#include "arg.h" #include "common.h" #include "sampling.h" #include "speculative.h" #include "log.h" #include "llama.h" #include #include #include #include #include #include #include struct spec_checkpoint { int64_t n_tokens = 0; std::vector data; size_t size() const { return data.size(); } bool empty() const { return data.empty(); } }; int main(int argc, char ** argv) { std::setlocale(LC_NUMERIC, "C"); common_params params; common_init(); if (!common_params_parse(argc, argv, params, LLAMA_EXAMPLE_SPECULATIVE)) { return 1; } if (params.n_predict < -1) { LOG_ERR("%s: --n-predict must be >= -1\n", __func__); return 1; } if (params.speculative.draft.mparams.path.empty()) { LOG_ERR("%s: --model-draft is required\n", __func__); return 1; } // init llama.cpp llama_backend_init(); llama_numa_init(params.numa); llama_model * model_tgt = NULL; llama_context * ctx_tgt = NULL; // load the target model auto llama_init_tgt = common_init_from_params(params); model_tgt = llama_init_tgt->model(); ctx_tgt = llama_init_tgt->context(); // check if the context supports partial sequence removal const auto ctx_seq_rm = common_context_can_seq_rm(ctx_tgt); const bool use_ckpt = (ctx_seq_rm == COMMON_CONTEXT_SEQ_RM_TYPE_FULL); if (use_ckpt) { LOG_INF("speculative decoding will use checkpoints (context does not support partial sequence removal)\n"); } const llama_vocab * vocab = llama_model_get_vocab(model_tgt); // load the draft model llama_model_ptr model_dft; // TODO: simplify this logic { const auto & params_spec = params.speculative.draft; auto params_dft = params; params_dft.n_parallel = 1; params_dft.n_ctx = params_spec.n_ctx; params_dft.n_batch = llama_n_ctx_seq(ctx_tgt); params_dft.devices = params_spec.devices; params_dft.model = params_spec.mparams; params_dft.n_gpu_layers = params_spec.n_gpu_layers; if (params_spec.cpuparams.n_threads > 0) { params_dft.cpuparams.n_threads = params.speculative.draft.cpuparams.n_threads; params_dft.cpuparams_batch.n_threads = params.speculative.draft.cpuparams_batch.n_threads; } params_dft.tensor_buft_overrides = params.speculative.draft.tensor_buft_overrides; auto mparams_dft = common_model_params_to_llama(params_dft); model_dft.reset(llama_model_load_from_file(params_dft.model.path.c_str(), mparams_dft)); if (model_dft == nullptr) { LOG_ERR("failed to load draft model, '%s'\n", params_dft.model.path.c_str()); return 1; } params.speculative.draft.model = model_dft.get(); params.speculative.draft.cparams = common_context_params_to_llama(params_dft); } // Tokenize the prompt std::vector inp; inp = common_tokenize(ctx_tgt, params.prompt, true, true); if (llama_n_ctx(ctx_tgt) < (uint32_t) inp.size()) { LOG_ERR("%s: the prompt exceeds the context size (%d tokens, ctx %d)\n", __func__, (int) inp.size(), llama_n_ctx(ctx_tgt)); return 1; } if (llama_n_batch(ctx_tgt) < (uint32_t) inp.size()) { LOG_ERR("%s: the prompt exceeds the batch size (%d tokens, batch %d)\n", __func__, (int) inp.size(), llama_n_batch(ctx_tgt)); return 1; } LOG("\n\n"); for (auto id : inp) { LOG("%s", common_token_to_piece(ctx_tgt, id).c_str()); } int n_predict = 0; int n_drafted = 0; int n_accept = 0; // used to determine end of generation bool has_eos = false; // ================================================ // everything until here is standard initialization // the relevant stuff for speculative decoding starts here const auto t_enc_start = ggml_time_us(); // target model sampling context common_sampler_ptr smpl(common_sampler_init(model_tgt, params.sampling)); // eval the prompt llama_decode(ctx_tgt, llama_batch_get_one(inp.data(), inp.size() - 1)); // note: keep the last token separate! llama_token id_last = inp.back(); // all tokens currently in the target context llama_tokens prompt_tgt(inp.begin(), inp.end() - 1); prompt_tgt.reserve(llama_n_ctx(ctx_tgt)); int n_past = inp.size() - 1; // init the speculator const auto & params_spec = params.speculative; struct common_speculative * spec = common_speculative_init(params.speculative, ctx_tgt); common_speculative_begin(spec, prompt_tgt); llama_batch batch_tgt = llama_batch_init(llama_n_batch(ctx_tgt), 0, 1); size_t n_draft = 0; llama_tokens draft; spec_checkpoint spec_ckpt; const auto t_enc_end = ggml_time_us(); const auto t_dec_start = ggml_time_us(); while (true) { // generate or reuse draft tokens // // this is the most important part of the speculation. the more probable tokens that are provided here // the better the performance will be. in theory, this computation can be performed asynchronously and even // offloaded to a remote device. it doesn't even have to be based on an LLM. instead, it can provide tokens // from a cache or lookup tables. // if (draft.empty()) { // generate a new draft draft = common_speculative_draft(spec, params_spec, prompt_tgt, id_last); // save the original draft size n_draft = draft.size(); // save a checkpoint of the target context before evaluating the draft // this allows us to restore the state if partial draft acceptance occurs if (!draft.empty() && use_ckpt) { const size_t ckpt_size = llama_state_seq_get_size_ext(ctx_tgt, 0, LLAMA_STATE_SEQ_FLAGS_PARTIAL_ONLY); spec_ckpt.data.resize(ckpt_size); const size_t n = llama_state_seq_get_data_ext(ctx_tgt, spec_ckpt.data.data(), ckpt_size, 0, LLAMA_STATE_SEQ_FLAGS_PARTIAL_ONLY); GGML_ASSERT(n == ckpt_size); spec_ckpt.n_tokens = (int64_t) prompt_tgt.size(); LOG_DBG("created speculative checkpoint (n_tokens = %" PRId64 ", size = %.3f MiB)\n", spec_ckpt.n_tokens, (float) spec_ckpt.data.size() / 1024 / 1024); } } else { // we have a previous (partial) draft to reuse from checkpoint restoration if (use_ckpt) { GGML_ASSERT(!spec_ckpt.empty()); } } // always have a token to evaluate from before - id_last common_batch_clear(batch_tgt); common_batch_add (batch_tgt, id_last, n_past++, { 0 }, true); // evaluate the target model on [id_last, draft0, draft1, ..., draftN-1] { for (size_t i = 0; i < draft.size(); ++i) { common_batch_add(batch_tgt, draft[i], n_past + i, { 0 }, true); } //LOG_DBG("target batch: %s\n", string_from(ctx_tgt, batch_tgt).c_str()); llama_decode(ctx_tgt, batch_tgt); } // only save the sampler sampler state if we use checkpoints common_sampler_ptr smpl_save; if (use_ckpt) { smpl_save.reset(common_sampler_clone(smpl.get())); } // sample from the full target batch and return the accepted tokens based on the target sampler // // for each token to be accepted, the sampler would have to sample that same token // in such cases, instead of decoding the sampled token as we normally do, we simply continue with the // available logits from the batch and sample the next token until we run out of logits or the sampler // disagrees with the draft // auto ids = common_sampler_sample_and_accept_n(smpl.get(), ctx_tgt, draft); //LOG_DBG("ids: %s\n", string_from(ctx_tgt, ids).c_str()); GGML_ASSERT(ids.size() > 0); // there will always be at least one accepted token // check for partial draft acceptance: // if the context doesn't support partial sequence removal, restore the checkpoint // and make the accepted tokens the new partial draft for the next iteration if (use_ckpt && ids.size() - 1 < draft.size()) { LOG_DBG("partial acceptance: %zu < %zu, restoring checkpoint\n", ids.size() - 1, draft.size()); draft = std::move(ids); const size_t n = llama_state_seq_set_data_ext(ctx_tgt, spec_ckpt.data.data(), spec_ckpt.size(), 0, LLAMA_STATE_SEQ_FLAGS_PARTIAL_ONLY); GGML_ASSERT(n == spec_ckpt.size()); llama_memory_seq_rm(llama_get_memory(ctx_tgt), 0, spec_ckpt.n_tokens, -1); prompt_tgt.resize(spec_ckpt.n_tokens); smpl = std::move(smpl_save); n_past = (int) prompt_tgt.size(); continue; } common_speculative_accept(spec, ids.size() - 1); // full acceptance: consume the draft and commit accepted tokens n_past += ids.size() - 1; n_drafted += n_draft; // note: we ignore the discarded small drafts n_accept += ids.size() - 1; n_predict += ids.size(); // process the accepted tokens and update contexts // // this is the standard token post-processing that we normally do // in this case, we do it for a group of accepted tokens at once // for (size_t i = 0; i < ids.size(); ++i) { prompt_tgt.push_back(id_last); id_last = ids[i]; if (llama_vocab_is_eog(vocab, id_last)) { has_eos = true; break; } const std::string token_str = common_token_to_piece(ctx_tgt, id_last); if (params.use_color && i + 1 < ids.size()) { LOG("\u001b[%dm%s\u001b[37m", (36 - 0 % 6), token_str.c_str()); } else { LOG("%s", token_str.c_str()); } } LOG_DBG("accepted %d/%d draft tokens, the last target token is: (%d)\n", (int) ids.size() - 1, (int) draft.size(), id_last); // clear the draft since it has been consumed draft.clear(); { LOG_DBG("clear kv cache from any extra tokens, n_past = %d\n", n_past); llama_memory_seq_rm(llama_get_memory(ctx_tgt), 0, n_past, -1); } if ((params.n_predict >= 0 && n_predict > params.n_predict) || has_eos) { break; } } auto t_dec_end = ggml_time_us(); const int n_input = inp.size(); LOG("\n\n"); LOG_INF("encoded %4d tokens in %8.3f seconds, speed: %8.3f t/s\n", n_input, (t_enc_end - t_enc_start) / 1e6f, inp.size() / ((t_enc_end - t_enc_start) / 1e6f)); LOG_INF("decoded %4d tokens in %8.3f seconds, speed: %8.3f t/s\n", n_predict, (t_dec_end - t_dec_start) / 1e6f, n_predict / ((t_dec_end - t_dec_start) / 1e6f)); LOG_INF("\n"); LOG_INF("n_draft = %d\n", params_spec.draft.n_max); LOG_INF("n_predict = %d\n", n_predict); LOG_INF("n_drafted = %d\n", n_drafted); LOG_INF("n_accept = %d\n", n_accept); LOG_INF("accept = %.3f%%\n", 100.0f * n_accept / n_drafted); LOG_INF("\n"); LOG_INF("draft:\n\n"); LOG_INF("\n"); LOG_INF("target:\n\n"); common_perf_print(ctx_tgt, smpl.get()); llama_batch_free(batch_tgt); common_speculative_free(spec); llama_backend_free(); LOG("\n\n"); return 0; }