from llama_cpp import * from ctypes import POINTER, c_size_t from llama_cpp._internals import ( _LlamaModel, # type: ignore _LlamaContext, # type: ignore _LlamaBatch, # type: ignore _LlamaTokenDataArray, # type: ignore ) from KMP_list import kmp_search, compute_lps_array from Turbo_Colormap import map_value_to_color, NOCOLOR, LEGEND, BACK_WHITE class LLMGenerate: def __init__( self, model, n_keep, n_discard: int = 256, im_start=None, top_k: int = 40, top_p: float = 0.95, min_p: float = 0.05, typical_p: float = 1.0, temp: float = 0.80, repeat_penalty: float = 1.1, repeat_last_n: int = 64, frequency_penalty: float = 0.0, presence_penalty: float = 0.0, tfs_z: float = 1.0, mirostat_mode: int = 0, mirostat_tau: float = 5.0, mirostat_eta: float = 0.1 ): def _eval_t(tokens): return model.eval_t( tokens=tokens, n_keep=n_keep, n_discard=n_discard, im_start=im_start ) def _sample_t(logits_processor): return model.sample_t( top_k=top_k, top_p=top_p, min_p=min_p, typical_p=typical_p, temp=temp, repeat_penalty=repeat_penalty, repeat_last_n=repeat_last_n, frequency_penalty=frequency_penalty, presence_penalty=presence_penalty, tfs_z=tfs_z, mirostat_mode=mirostat_mode, mirostat_tau=mirostat_tau, mirostat_eta=mirostat_eta, logits_processor=logits_processor ) self._eval_t = _eval_t self._sample_t = _sample_t self.str_detokenize = model.str_detokenize self.venv_pop_token = model.venv_pop_token # ========== 保存输出 ========== self.t_bot = [] self.completion_tokens = [] self.history = '' self.token = None def eval_t(self, tokens): # ========== 避免不完整的utf-8编码 ========== self.completion_tokens.extend(tokens) all_text = self.str_detokenize(self.completion_tokens) if all_text: self.t_bot.extend(self.completion_tokens) self.history += all_text self.completion_tokens = [] return self._eval_t(tokens) def sample_t(self, logits_processor): self.token = self._sample_t(logits_processor) return self.token def detokenize_sample_t(self): self.completion_tokens.append(self.token) all_text = self.str_detokenize(self.completion_tokens) if not all_text: return False self.t_bot.extend(self.completion_tokens) self.history += all_text self.completion_tokens = [] return True def eval_sample_t(self): return self._eval_t([self.token]) def endswith_t(self, token_list): return self.token in token_list def endswith_s(self, start_func, str_list, com_func=str.rstrip): if self.completion_tokens: # 不完整 return False history = self.history t_bot = self.t_bot if start_func(history): history = com_func(history) for x in str_list: if history.endswith(x): n = len(t_bot) for i in range(1, n): # 找出需要弃置的tokens长度 tmp = self.str_detokenize(t_bot[n - i:]) tmp = com_func(tmp) if tmp.endswith(x): if i > 1: # 最后一个token并未进入kv_cache self.venv_pop_token(i - 1) if history.endswith(tmp): self.history = history[:-len(tmp)] # 移除末尾的tmp return True return False kv_cache_type = { 'f32': 0, 'f16': 1, 'q8_0': 8, 'q4_0': 2, 'q4_1': 3, 'iq4_nl': 20, 'q5_0': 6, 'q5_1': 7 } class StreamingLLM(Llama): __backend_initialized = False def __init__( self, model_path: str, *, # Model Params n_gpu_layers: int = 0, split_mode: int = llama_cpp.LLAMA_SPLIT_MODE_LAYER, main_gpu: int = 0, tensor_split: Optional[List[float]] = None, vocab_only: bool = False, use_mmap: bool = True, use_mlock: bool = False, kv_overrides: Optional[Dict[str, Union[bool, int, float]]] = None, # Context Params seed: int = llama_cpp.LLAMA_DEFAULT_SEED, n_ctx: int = 512, n_batch: int = 512, n_threads: Optional[int] = None, n_threads_batch: Optional[int] = None, rope_scaling_type: Optional[int] = llama_cpp.LLAMA_ROPE_SCALING_TYPE_UNSPECIFIED, pooling_type: int = llama_cpp.LLAMA_POOLING_TYPE_UNSPECIFIED, rope_freq_base: float = 0.0, rope_freq_scale: float = 0.0, yarn_ext_factor: float = -1.0, yarn_attn_factor: float = 1.0, yarn_beta_fast: float = 32.0, yarn_beta_slow: float = 1.0, yarn_orig_ctx: int = 0, logits_all: bool = False, embedding: bool = False, offload_kqv: bool = True, # Sampling Params last_n_tokens_size: int = 64, # LoRA Params lora_base: Optional[str] = None, lora_scale: float = 1.0, lora_path: Optional[str] = None, # Backend Params numa: Union[bool, int] = False, # Chat Format Params chat_format: Optional[str] = None, chat_handler: Optional[llama_chat_format.LlamaChatCompletionHandler] = None, # Speculative Decoding draft_model: Optional[LlamaDraftModel] = None, # Tokenizer Override tokenizer: Optional[BaseLlamaTokenizer] = None, # Misc verbose: bool = True, # Extra Params type_k: str = 'f16', type_v: str = 'f16', **kwargs, # type: ignore ): """Load a llama.cpp model from `model_path`. Examples: Basic usage >>> import llama_cpp >>> model = llama_cpp.Llama( ... model_path="path/to/model", ... ) >>> print(model("The quick brown fox jumps ", stop=["."])["choices"][0]["text"]) the lazy dog Loading a chat model >>> import llama_cpp >>> model = llama_cpp.Llama( ... model_path="path/to/model", ... chat_format="llama-2", ... ) >>> print(model.create_chat_completion( ... messages=[{ ... "role": "user", ... "content": "what is the meaning of life?" ... }] ... )) Args: model_path: Path to the model. n_gpu_layers: Number of layers to offload to GPU (-ngl). If -1, all layers are offloaded. split_mode: How to split the model across GPUs. See llama_cpp.LLAMA_SPLIT_* for options. main_gpu: main_gpu interpretation depends on split_mode: LLAMA_SPLIT_NONE: the GPU that is used for the entire model. LLAMA_SPLIT_ROW: the GPU that is used for small tensors and intermediate results. LLAMA_SPLIT_LAYER: ignored tensor_split: How split tensors should be distributed across GPUs. If None, the model is not split. vocab_only: Only load the vocabulary no weights. use_mmap: Use mmap if possible. use_mlock: Force the system to keep the model in RAM. kv_overrides: Key-value overrides for the model. seed: RNG seed, -1 for random n_ctx: Text context, 0 = from model n_batch: Prompt processing maximum batch size n_threads: Number of threads to use for generation n_threads_batch: Number of threads to use for batch processing rope_scaling_type: RoPE scaling type, from `enum llama_rope_scaling_type`. ref: https://github.com/ggerganov/llama.cpp/pull/2054 pooling_type: Pooling type, from `enum llama_pooling_type`. rope_freq_base: RoPE base frequency, 0 = from model rope_freq_scale: RoPE frequency scaling factor, 0 = from model yarn_ext_factor: YaRN extrapolation mix factor, negative = from model yarn_attn_factor: YaRN magnitude scaling factor yarn_beta_fast: YaRN low correction dim yarn_beta_slow: YaRN high correction dim yarn_orig_ctx: YaRN original context size logits_all: Return logits for all tokens, not just the last token. Must be True for completion to return logprobs. embedding: Embedding mode only. offload_kqv: Offload K, Q, V to GPU. last_n_tokens_size: Maximum number of tokens to keep in the last_n_tokens deque. lora_base: Optional path to base model, useful if using a quantized base model and you want to apply LoRA to an f16 model. lora_path: Path to a LoRA file to apply to the model. numa: numa policy chat_format: String specifying the chat format to use when calling create_chat_completion. chat_handler: Optional chat handler to use when calling create_chat_completion. draft_model: Optional draft model to use for speculative decoding. tokenizer: Optional tokenizer to override the default tokenizer from llama.cpp. verbose: Print verbose output to stderr. Raises: ValueError: If the model path does not exist. Returns: A Llama instance. """ self.verbose = verbose set_verbose(verbose) if not StreamingLLM.__backend_initialized: with suppress_stdout_stderr(disable=verbose): llama_cpp.llama_backend_init() StreamingLLM.__backend_initialized = True if isinstance(numa, bool): self.numa = ( llama_cpp.GGML_NUMA_STRATEGY_DISTRIBUTE if numa else llama_cpp.GGML_NUMA_STRATEGY_DISABLED ) else: self.numa = numa if self.numa != llama_cpp.GGML_NUMA_STRATEGY_DISABLED: with suppress_stdout_stderr(disable=verbose): llama_cpp.llama_numa_init(self.numa) self.model_path = model_path # Model Params self.model_params = llama_cpp.llama_model_default_params() self.model_params.n_gpu_layers = ( 0x7FFFFFFF if n_gpu_layers == -1 else n_gpu_layers ) # 0x7FFFFFFF is INT32 max, will be auto set to all layers self.model_params.split_mode = split_mode self.model_params.main_gpu = main_gpu self.tensor_split = tensor_split self._c_tensor_split = None if self.tensor_split is not None: if len(self.tensor_split) > llama_cpp.LLAMA_MAX_DEVICES: raise ValueError( f"Attempt to split tensors that exceed maximum supported devices. Current LLAMA_MAX_DEVICES={llama_cpp.LLAMA_MAX_DEVICES}" ) # Type conversion and expand the list to the length of LLAMA_MAX_DEVICES FloatArray = ctypes.c_float * llama_cpp.LLAMA_MAX_DEVICES self._c_tensor_split = FloatArray( *tensor_split # type: ignore ) # keep a reference to the array so it is not gc'd self.model_params.tensor_split = self._c_tensor_split self.model_params.vocab_only = vocab_only self.model_params.use_mmap = use_mmap if lora_path is None else False self.model_params.use_mlock = use_mlock # kv_overrides is the original python dict self.kv_overrides = kv_overrides if kv_overrides is not None: # _kv_overrides_array is a ctypes.Array of llama_model_kv_override Structs kvo_array_len = len(kv_overrides) + 1 # for sentinel element self._kv_overrides_array = ( llama_cpp.llama_model_kv_override * kvo_array_len )() for i, (k, v) in enumerate(kv_overrides.items()): self._kv_overrides_array[i].key = k.encode("utf-8") if isinstance(v, bool): self._kv_overrides_array[i].tag = llama_cpp.LLAMA_KV_OVERRIDE_TYPE_BOOL self._kv_overrides_array[i].value.bool_value = v elif isinstance(v, int): self._kv_overrides_array[i].tag = llama_cpp.LLAMA_KV_OVERRIDE_TYPE_INT self._kv_overrides_array[i].value.int_value = v elif isinstance(v, float): self._kv_overrides_array[i].tag = llama_cpp.LLAMA_KV_OVERRIDE_TYPE_FLOAT self._kv_overrides_array[i].value.float_value = v else: raise ValueError(f"Unknown value type for {k}: {v}") self._kv_overrides_array[-1].key = ( b"\0" # ensure sentinel element is zeroed ) self.model_params.kv_overrides = self._kv_overrides_array self.n_batch = min(n_ctx, n_batch) # ??? self.n_threads = n_threads or max(multiprocessing.cpu_count() // 2, 1) self.n_threads_batch = n_threads_batch or max( multiprocessing.cpu_count() // 2, 1 ) # Context Params self.context_params = llama_cpp.llama_context_default_params() self.context_params.seed = seed self.context_params.n_ctx = n_ctx self.context_params.n_batch = self.n_batch self.context_params.n_threads = self.n_threads self.context_params.n_threads_batch = self.n_threads_batch self.context_params.rope_scaling_type = ( rope_scaling_type if rope_scaling_type is not None else llama_cpp.LLAMA_ROPE_SCALING_TYPE_UNSPECIFIED ) self.context_params.pooling_type = pooling_type self.context_params.rope_freq_base = ( rope_freq_base if rope_freq_base != 0.0 else 0 ) self.context_params.rope_freq_scale = ( rope_freq_scale if rope_freq_scale != 0.0 else 0 ) self.context_params.yarn_ext_factor = ( yarn_ext_factor if yarn_ext_factor != 0.0 else 0 ) self.context_params.yarn_attn_factor = ( yarn_attn_factor if yarn_attn_factor != 0.0 else 0 ) self.context_params.yarn_beta_fast = ( yarn_beta_fast if yarn_beta_fast != 0.0 else 0 ) self.context_params.yarn_beta_slow = ( yarn_beta_slow if yarn_beta_slow != 0.0 else 0 ) self.context_params.yarn_orig_ctx = yarn_orig_ctx if yarn_orig_ctx != 0 else 0 self.context_params.logits_all = ( logits_all if draft_model is None else True ) # Must be set to True for speculative decoding self.context_params.embeddings = embedding # TODO: Rename to embeddings # KV cache quantization print(self.context_params.type_k, self.context_params.type_v) self.context_params.type_k = kv_cache_type[type_k] self.context_params.type_v = kv_cache_type[type_v] self.context_params.offload_kqv = offload_kqv # Sampling Params self.last_n_tokens_size = last_n_tokens_size self.cache: Optional[BaseLlamaCache] = None self.lora_base = lora_base self.lora_scale = lora_scale self.lora_path = lora_path if not os.path.exists(model_path): raise ValueError(f"Model path does not exist: {model_path}") self._model = _LlamaModel( path_model=self.model_path, params=self.model_params, verbose=self.verbose ) # Override tokenizer self.tokenizer_ = tokenizer or LlamaTokenizer(self) # Set the default value for the context and correct the batch if n_ctx == 0: n_ctx = self._model.n_ctx_train() self.n_batch = min(n_ctx, n_batch) self.context_params.n_ctx = self._model.n_ctx_train() self.context_params.n_batch = self.n_batch self._ctx = _LlamaContext( model=self._model, params=self.context_params, verbose=self.verbose, ) self._batch = _LlamaBatch( n_tokens=self.n_batch, embd=0, n_seq_max=self.context_params.n_ctx, verbose=self.verbose, ) if self.lora_path: if self._model.apply_lora_from_file( self.lora_path, self.lora_scale, self.lora_base, self.n_threads, ): raise RuntimeError( f"Failed to apply LoRA from lora path: {self.lora_path} to base path: {self.lora_base}" ) if self.verbose: print(llama_cpp.llama_print_system_info().decode("utf-8"), file=sys.stderr) self.chat_format = chat_format self.chat_handler = chat_handler self.draft_model = draft_model self._n_vocab = self.n_vocab() self._n_ctx = self.n_ctx() self._token_nl = self.token_nl() self._token_eos = self.token_eos() self._candidates = _LlamaTokenDataArray(n_vocab=self._n_vocab) self.n_tokens = 0 self.input_ids: npt.NDArray[np.intc] = np.ndarray((n_ctx,), dtype=np.intc) self.scores: npt.NDArray[np.single] = np.ndarray( (n_ctx, self._n_vocab), dtype=np.single ) self._mirostat_mu = ctypes.c_float( 2.0 * 5.0 ) # TODO: Move this to sampling context try: self.metadata = self._model.metadata() except Exception as e: self.metadata = {} if self.verbose: print(f"Failed to load metadata: {e}", file=sys.stderr) if self.verbose: print(f"Model metadata: {self.metadata}", file=sys.stderr) if ( self.chat_format is None and self.chat_handler is None and "tokenizer.chat_template" in self.metadata ): chat_format = llama_chat_format.guess_chat_format_from_gguf_metadata( self.metadata ) if chat_format is not None: self.chat_format = chat_format if self.verbose: print(f"Guessed chat format: {chat_format}", file=sys.stderr) else: template = self.metadata["tokenizer.chat_template"] try: eos_token_id = int(self.metadata["tokenizer.ggml.eos_token_id"]) except: eos_token_id = self.token_eos() try: bos_token_id = int(self.metadata["tokenizer.ggml.bos_token_id"]) except: bos_token_id = self.token_bos() eos_token = self._model.token_get_text(eos_token_id) bos_token = self._model.token_get_text(bos_token_id) if self.verbose: print(f"Using gguf chat template: {template}", file=sys.stderr) print(f"Using chat eos_token: {eos_token}", file=sys.stderr) print(f"Using chat bos_token: {bos_token}", file=sys.stderr) self.chat_handler = llama_chat_format.Jinja2ChatFormatter( template=template, eos_token=eos_token, bos_token=bos_token ).to_chat_handler() if self.chat_format is None and self.chat_handler is None: self.chat_format = "llama-2" if self.verbose: print(f"Using fallback chat format: {chat_format}", file=sys.stderr) self._venv_init() def str_detokenize(self, tokens) -> str: return self.detokenize(tokens).decode('utf-8', errors='ignore') def kv_cache_seq_trim(self): self._ctx.kv_cache_seq_rm(-1, self.n_tokens, -1) def _venv_init(self): self.venv = [0] self.venv_idx_map = [] def venv_create(self, name: str): self.venv.append(0) self.venv_idx_map.append(name) return name def venv_disband(self, name_set): if len(self.venv) <= 1: return False name_set = {x for x in name_set if x in self.venv_idx_map} if not name_set: return False while self.venv_idx_map: if self.venv_idx_map[0] in name_set: self.venv_idx_map.pop(0) # 删除 tmp = self.venv.pop(1) # 对应的 venv 移入上一层 self.venv[0] += tmp else: break return True def venv_revision(self, name: str): if len(self.venv) <= 1: return False if name not in self.venv_idx_map: return False _s = 0 while self.venv_idx_map: if self.venv_idx_map[-1] == name: break self.venv_idx_map.pop() # 删除 _s += self.venv.pop() if _s: self.n_tokens -= min(_s, self.n_tokens) self.kv_cache_seq_trim() return True def venv_remove(self, name: str, keep_last=0): if len(self.venv) <= 1: return False if name not in self.venv_idx_map: return False venv_idx = self.venv_idx_map.index(name) + 1 count_name = self.venv_idx_map.count(name) if keep_last else 0 while self.venv_idx_map: if keep_last and count_name <= keep_last: break # 保留最后n个 self.venv_idx_map.pop(venv_idx - 1) # 删除 if venv_idx == len(self.venv) - 1: # 最后一层 self.n_tokens -= min(self.venv.pop(), self.n_tokens) self.kv_cache_seq_trim() break else: # 非最后一层 n_keep = self.n_tokens - sum(self.venv[i] for i in range(venv_idx, len(self.venv))) n_discard = self.venv.pop(venv_idx) self.kv_cache_seq_ltrim(n_keep, n_discard) try: venv_idx = self.venv_idx_map.index(name, venv_idx - 1) + 1 except ValueError: # 没有了 break count_name -= 1 # 计数减一 return True def venv_pop_token(self, n=1): self.n_tokens -= n self.venv[-1] -= n self.kv_cache_seq_trim() @property def venv_info(self): return str((self.n_tokens, self.venv, self.venv_idx_map)) def venv_viz(self): completion_tokens = [] history = LEGEND + '\n' text_color = NOCOLOR for i in range(self.venv[-1]): idx = self.n_tokens - self.venv[-1] + i token = self._input_ids[idx] if not completion_tokens: # 不完整则是第一个token # ========== 获取对应token的概率 ========== score = self.scores[idx-1: idx, :].ravel() # 第i个token的分数是前i-1个token预测的,所以减一 score = np.exp(score) # 空白则全1,但无所谓了 sum_score = np.sum(score) probabilities = score[token] / sum_score if probabilities < 0.001: text_color = NOCOLOR else: if text_color is NOCOLOR: text_color = BACK_WHITE + map_value_to_color(probabilities) else: text_color = map_value_to_color(probabilities) history += text_color # ========== 避免不完整的utf-8编码 ========== completion_tokens.append(token) all_text = self.str_detokenize(completion_tokens) if not all_text: continue completion_tokens = [] # 完整则清空缓存 history += repr(all_text)[1:-1] return history + NOCOLOR def kv_cache_seq_ltrim(self, n_keep, n_discard=256, n_past=-1, im_start=None): if n_keep < 0: return if n_past < 0: n_past = self.n_tokens if im_start is not None: # [<|im_start|>, name, nl] lps = compute_lps_array(im_start) _idx = kmp_search(self.input_ids, im_start, n_keep + n_discard, n_past, lps) if _idx >= n_keep: # 其实是大于等于 n_keep + n_discard n_discard = _idx - n_keep # 截断到最近的 im_start 序列结构 else: _idx = kmp_search(self.input_ids, im_start, n_keep, n_past, lps) if _idx >= n_keep: n_keep = _idx + len(im_start) # 至少保留一个 im_start 序列结构 print(im_start, n_keep, n_discard, _idx) self._ctx.kv_cache_seq_rm(-1, n_keep, n_keep + n_discard) self._ctx.kv_cache_seq_shift(0, n_keep + n_discard, n_past, -n_discard) self.input_ids[n_keep:n_past - n_discard] = self.input_ids[n_keep + n_discard:n_past] self.n_tokens = n_past - n_discard def eval_t(self, tokens, n_keep=4, n_discard=256, im_start=None): if self._n_ctx < self.n_tokens + len(tokens): tmp_n_discard = max(n_discard, self.n_tokens + len(tokens) - self._n_ctx) self.kv_cache_seq_ltrim(n_keep, tmp_n_discard, im_start=im_start) for i in range(0, len(tokens), self.n_batch): batch = tokens[i: i + self.n_batch] n_past = self.n_tokens n_tokens = len(batch) self._batch.set_batch( batch=batch, n_past=n_past, logits_all=self.context_params.logits_all ) self._ctx.decode(self._batch) # Save tokens self.input_ids[n_past: n_past + n_tokens] = batch # Save logits rows = n_tokens cols = self._n_vocab offset = ( 0 if self.context_params.logits_all else n_tokens - 1 ) # NOTE: Only save the last token logits if logits_all is False self.scores[n_past + offset: n_past + n_tokens, :].reshape(-1)[ : ] = self._ctx.get_logits()[offset * cols: rows * cols] # Update n_tokens self.n_tokens += n_tokens self.venv[-1] += n_tokens return self.n_tokens def sample_t( self, top_k: int = 40, top_p: float = 0.95, min_p: float = 0.05, typical_p: float = 1.0, temp: float = 0.80, repeat_penalty: float = 1.1, repeat_last_n: int = 64, frequency_penalty: float = 0.0, presence_penalty: float = 0.0, tfs_z: float = 1.0, mirostat_mode: int = 0, mirostat_eta: float = 0.1, mirostat_tau: float = 5.0, penalize_nl: bool = True, logits_processor=None, grammar: Optional[LlamaGrammar] = None, ): last_n_tokens_data = [llama_cpp.llama_token(0)] * max( 0, repeat_last_n - self.n_tokens ) + self._input_ids[-repeat_last_n:].tolist() last_n_tokens_size = len(last_n_tokens_data) n_vocab = self._n_vocab n_ctx = self._n_ctx top_k = n_vocab if top_k <= 0 else top_k last_n_tokens_size = n_ctx if last_n_tokens_size < 0 else last_n_tokens_size last_n_tokens_data_c = (llama_cpp.llama_token * last_n_tokens_size)( *last_n_tokens_data ) logits: npt.NDArray[np.single] = self.scores[self.n_tokens - 1: self.n_tokens, :].ravel() if logits_processor is not None: logits[:] = logits_processor(self._input_ids, logits) self._candidates.copy_logits(logits) self._ctx.sample_repetition_penalties( candidates=self._candidates, last_tokens_data=last_n_tokens_data_c, penalty_last_n=last_n_tokens_size, penalty_repeat=repeat_penalty, penalty_freq=frequency_penalty, penalty_present=presence_penalty, ) if not penalize_nl: nl_logit = logits[self._token_nl] self._candidates.candidates.data[self._token_nl].logit = llama_cpp.c_float( nl_logit ) if grammar is not None: self._ctx.sample_grammar( candidates=self._candidates, grammar=grammar, ) if temp < 0.0: self._ctx.sample_softmax(candidates=self._candidates) id_ = self._candidates.candidates.data[0].id elif temp == 0.0: id_ = self._ctx.sample_token_greedy(candidates=self._candidates) elif mirostat_mode == 1: self._ctx.sample_temp(candidates=self._candidates, temp=temp) id_ = self._ctx.sample_token_mirostat( candidates=self._candidates, tau=mirostat_tau, eta=mirostat_eta, mu=2.0 * mirostat_tau, m=100, ) elif mirostat_mode == 2: self._ctx.sample_temp(candidates=self._candidates, temp=temp) id_ = self._ctx.sample_token_mirostat_v2( candidates=self._candidates, tau=mirostat_tau, eta=mirostat_eta, mu=2.0 * mirostat_tau, ) else: self._ctx.sample_top_k(candidates=self._candidates, k=top_k, min_keep=1) self._ctx.sample_tail_free(candidates=self._candidates, z=tfs_z, min_keep=1) self._ctx.sample_typical( candidates=self._candidates, p=typical_p, min_keep=1 ) self._ctx.sample_top_p(candidates=self._candidates, p=top_p, min_keep=1) self._ctx.sample_min_p(candidates=self._candidates, p=min_p, min_keep=1) self._ctx.sample_temp(candidates=self._candidates, temp=temp) id_ = self._ctx.sample_token(candidates=self._candidates) if grammar is not None: self._ctx.grammar_accept_token(grammar=grammar, token=id_) return id_ def generate_t( self, tokens: Sequence[int], n_keep, n_discard: int = 256, im_start=None, top_k: int = 40, top_p: float = 0.95, min_p: float = 0.05, typical_p: float = 1.0, temp: float = 0.80, repeat_penalty: float = 1.1, repeat_last_n: int = 64, frequency_penalty: float = 0.0, presence_penalty: float = 0.0, tfs_z: float = 1.0, mirostat_mode: int = 0, mirostat_tau: float = 5.0, mirostat_eta: float = 0.1, logits_processor: Optional[LogitsProcessorList] = None, stopping_criteria: Optional[StoppingCriteriaList] = None, grammar: Optional[LlamaGrammar] = None, ) -> Generator[int, Optional[Sequence[int]], None]: typical_p = float(typical_p) frequency_penalty = float(frequency_penalty) presence_penalty = float(presence_penalty) tfs_z = float(tfs_z) mirostat_tau = float(mirostat_tau) while True: self.eval_t(tokens, n_keep, n_discard, im_start=im_start) token = self.sample_t( top_k=top_k, top_p=top_p, min_p=min_p, typical_p=typical_p, temp=temp, repeat_penalty=repeat_penalty, repeat_last_n=repeat_last_n, frequency_penalty=frequency_penalty, presence_penalty=presence_penalty, tfs_z=tfs_z, mirostat_mode=mirostat_mode, mirostat_tau=mirostat_tau, mirostat_eta=mirostat_eta, logits_processor=logits_processor, grammar=grammar, ) if stopping_criteria is not None and stopping_criteria( self._input_ids, self._scores[-1, :] ): return tokens = yield token if tokens is None: tokens = [token] def load_session(self, filepath: str): n_tokens = POINTER(c_size_t)(c_size_t(0)) tokens = (llama_cpp.llama_token * self.n_ctx())() retn = llama_cpp.llama_load_session_file(self._ctx.ctx, filepath.encode('utf-8'), tokens, self.n_ctx(), n_tokens) self.n_tokens = n_tokens.contents.value self.input_ids[:self.n_tokens] = tokens[:self.n_tokens] self._venv_init() return retn def save_session(self, filepath: str): tokens = self._input_ids.tolist() tokens = (llama_cpp.llama_token * len(tokens))(*tokens) return llama_cpp.llama_save_session_file(self._ctx.ctx, filepath.encode('utf-8'), tokens, self.n_tokens)