from typing import Optional, Dict, List, Union, Sequence from timeit import default_timer as timer import srsly import tqdm from pydantic import BaseModel, FilePath from pathlib import Path from wasabi import msg import thinc import thinc.schedules from thinc.api import Model, use_pytorch_for_gpu_memory, require_gpu, fix_random_seed import random from ._app import app, Arg, Opt from ..gold import Corpus, Example from ..lookups import Lookups from .. import util from ..errors import Errors # Don't remove - required to load the built-in architectures from ..ml import models # noqa: F401 # from ..schemas import ConfigSchema # TODO: include? registry = util.registry CONFIG_STR = """ [training] patience = 10 eval_frequency = 10 dropout = 0.2 init_tok2vec = null max_epochs = 100 orth_variant_level = 0.0 gold_preproc = false max_length = 0 use_gpu = 0 scores = ["ents_p", "ents_r", "ents_f"] score_weights = {"ents_f": 1.0} limit = 0 [training.batch_size] @schedules = "compounding.v1" start = 100 stop = 1000 compound = 1.001 [optimizer] @optimizers = "Adam.v1" learn_rate = 0.001 beta1 = 0.9 beta2 = 0.999 [nlp] lang = "en" vectors = null [nlp.pipeline.tok2vec] factory = "tok2vec" [nlp.pipeline.ner] factory = "ner" [nlp.pipeline.ner.model] @architectures = "spacy.TransitionBasedParser.v1" nr_feature_tokens = 3 hidden_width = 64 maxout_pieces = 3 [nlp.pipeline.ner.model.tok2vec] @architectures = "spacy.Tok2VecTensors.v1" width = ${nlp.pipeline.tok2vec.model:width} [nlp.pipeline.tok2vec.model] @architectures = "spacy.HashEmbedCNN.v1" pretrained_vectors = ${nlp:vectors} width = 128 depth = 4 window_size = 1 embed_size = 10000 maxout_pieces = 3 subword_features = true """ class PipelineComponent(BaseModel): factory: str model: Model class Config: arbitrary_types_allowed = True class ConfigSchema(BaseModel): optimizer: Optional["Optimizer"] class training(BaseModel): patience: int = 10 eval_frequency: int = 100 dropout: float = 0.2 init_tok2vec: Optional[FilePath] = None max_epochs: int = 100 orth_variant_level: float = 0.0 gold_preproc: bool = False max_length: int = 0 use_gpu: int = 0 scores: List[str] = ["ents_p", "ents_r", "ents_f"] score_weights: Dict[str, Union[int, float]] = {"ents_f": 1.0} limit: int = 0 batch_size: Union[Sequence[int], int] class nlp(BaseModel): lang: str vectors: Optional[str] pipeline: Optional[Dict[str, PipelineComponent]] class Config: extra = "allow" @app.command("train") def train_cli( # fmt: off train_path: Path = Arg(..., help="Location of JSON-formatted training data", exists=True), dev_path: Path = Arg(..., help="Location of JSON-formatted development data", exists=True), config_path: Path = Arg(..., help="Path to config file", exists=True), output_path: Optional[Path] = Opt(None, "--output", "--output-path", "-o", help="Output directory to store model in"), code_path: Optional[Path] = Opt(None, "--code-path", "-c", help="Path to Python file with additional code (registered functions) to be imported"), init_tok2vec: Optional[Path] = Opt(None, "--init-tok2vec", "-t2v", help="Path to pretrained weights for the tok2vec components. See 'spacy pretrain'. Experimental."), raw_text: Optional[Path] = Opt(None, "--raw-text", "-rt", help="Path to jsonl file with unlabelled text documents."), verbose: bool = Opt(False, "--verbose", "-VV", help="Display more information for debugging purposes"), use_gpu: int = Opt(-1, "--use-gpu", "-g", help="Use GPU"), tag_map_path: Optional[Path] = Opt(None, "--tag-map-path", "-tm", help="Location of JSON-formatted tag map"), omit_extra_lookups: bool = Opt(False, "--omit-extra-lookups", "-OEL", help="Don't include extra lookups in model"), # fmt: on ): """ Train or update a spaCy model. Requires data to be formatted in spaCy's JSON format. To convert data from other formats, use the `spacy convert` command. """ util.set_env_log(verbose) verify_cli_args(**locals()) if raw_text is not None: raw_text = list(srsly.read_jsonl(raw_text)) tag_map = {} if tag_map_path is not None: tag_map = srsly.read_json(tag_map_path) weights_data = None if init_tok2vec is not None: with init_tok2vec.open("rb") as file_: weights_data = file_.read() if use_gpu >= 0: msg.info("Using GPU: {use_gpu}") require_gpu(use_gpu) else: msg.info("Using CPU") train( config_path, {"train": train_path, "dev": dev_path}, output_path=output_path, raw_text=raw_text, tag_map=tag_map, weights_data=weights_data, omit_extra_lookups=omit_extra_lookups, ) def train( config_path: Path, data_paths: Dict[str, Path], raw_text: Optional[Path] = None, output_path: Optional[Path] = None, tag_map: Optional[Path] = None, weights_data: Optional[bytes] = None, omit_extra_lookups: bool = False, ) -> None: msg.info(f"Loading config from: {config_path}") # Read the config first without creating objects, to get to the original nlp_config config = util.load_config(config_path, create_objects=False) fix_random_seed(config["training"]["seed"]) if config["training"].get("use_pytorch_for_gpu_memory"): # It feels kind of weird to not have a default for this. use_pytorch_for_gpu_memory() nlp_config = config["nlp"] config = util.load_config(config_path, create_objects=True) training = config["training"] msg.info("Creating nlp from config") nlp = util.load_model_from_config(nlp_config) optimizer = training["optimizer"] limit = training["limit"] corpus = Corpus(data_paths["train"], data_paths["dev"], limit=limit) if "textcat" in nlp_config["pipeline"]: verify_textcat_config(nlp, nlp_config) if training.get("resume", False): msg.info("Resuming training") nlp.resume_training() else: msg.info(f"Initializing the nlp pipeline: {nlp.pipe_names}") train_examples = list( corpus.train_dataset( nlp, shuffle=False, gold_preproc=training["gold_preproc"], max_length=training["max_length"] ) ) nlp.begin_training(lambda: train_examples) # Update tag map with provided mapping nlp.vocab.morphology.tag_map.update(tag_map) # Create empty extra lexeme tables so the data from spacy-lookups-data # isn't loaded if these features are accessed if omit_extra_lookups: nlp.vocab.lookups_extra = Lookups() nlp.vocab.lookups_extra.add_table("lexeme_cluster") nlp.vocab.lookups_extra.add_table("lexeme_prob") nlp.vocab.lookups_extra.add_table("lexeme_settings") # Load a pretrained tok2vec model - cf. CLI command 'pretrain' if weights_data is not None: tok2vec_path = config.get("pretraining", {}).get("tok2vec_model", None) if tok2vec_path is None: msg.fail( f"To use a pretrained tok2vec model, the config needs to specify which " f"tok2vec layer to load in the setting [pretraining.tok2vec_model].", exits=1, ) tok2vec = config for subpath in tok2vec_path.split("."): tok2vec = tok2vec.get(subpath) if not tok2vec: msg.fail( f"Could not locate the tok2vec model at {tok2vec_path}.", exits=1, ) tok2vec.from_bytes(weights_data) msg.info("Loading training corpus") train_batches = create_train_batches(nlp, corpus, training) evaluate = create_evaluation_callback(nlp, optimizer, corpus, training) # Create iterator, which yields out info after each optimization step. msg.info("Start training") training_step_iterator = train_while_improving( nlp, optimizer, train_batches, evaluate, dropout=training["dropout"], accumulate_gradient=training["accumulate_gradient"], patience=training.get("patience", 0), max_steps=training.get("max_steps", 0), eval_frequency=training["eval_frequency"], raw_text=raw_text, ) msg.info(f"Training. Initial learn rate: {optimizer.learn_rate}") print_row = setup_printer(training, nlp) try: progress = tqdm.tqdm(total=training["eval_frequency"], leave=False) for batch, info, is_best_checkpoint in training_step_iterator: progress.update(1) if is_best_checkpoint is not None: progress.close() print_row(info) if is_best_checkpoint and output_path is not None: update_meta(training, nlp, info) nlp.to_disk(output_path / "model-best") progress = tqdm.tqdm(total=training["eval_frequency"], leave=False) except Exception as e: if output_path is not None: msg.warn( f"Aborting and saving the final best model. " f"Encountered exception: {str(e)}", exits=1, ) else: raise e finally: if output_path is not None: final_model_path = output_path / "model-final" if optimizer.averages: with nlp.use_params(optimizer.averages): nlp.to_disk(final_model_path) else: nlp.to_disk(final_model_path) msg.good(f"Saved model to output directory {final_model_path}") def create_train_batches(nlp, corpus, cfg): max_epochs = cfg.get("max_epochs", 0) train_examples = list( corpus.train_dataset( nlp, shuffle=True, gold_preproc=cfg["gold_preproc"], max_length=cfg["max_length"], ) ) epoch = 0 batch_strategy = cfg.get("batch_by", "sequences") while True: if len(train_examples) == 0: raise ValueError(Errors.E988) epoch += 1 if batch_strategy == "padded": batches = util.minibatch_by_padded_size( train_examples, size=cfg["batch_size"], buffer=256, discard_oversize=cfg["discard_oversize"], ) elif batch_strategy == "words": batches = util.minibatch_by_words( train_examples, size=cfg["batch_size"], discard_oversize=cfg["discard_oversize"], ) else: batches = util.minibatch( train_examples, size=cfg["batch_size"], ) # make sure the minibatch_by_words result is not empty, or we'll have an infinite training loop try: first = next(batches) yield epoch, first except StopIteration: raise ValueError(Errors.E986) for batch in batches: yield epoch, batch if max_epochs >= 1 and epoch >= max_epochs: break random.shuffle(train_examples) def create_evaluation_callback(nlp, optimizer, corpus, cfg): def evaluate(): dev_examples = list( corpus.dev_dataset( nlp, gold_preproc=cfg["gold_preproc"], ignore_misaligned=True ) ) n_words = sum(len(ex.predicted) for ex in dev_examples) batch_size = cfg.get("evaluation_batch_size", 128) start_time = timer() if optimizer.averages: with nlp.use_params(optimizer.averages): scorer = nlp.evaluate(dev_examples, batch_size=batch_size) else: scorer = nlp.evaluate(dev_examples, batch_size=batch_size) end_time = timer() wps = n_words / (end_time - start_time) scores = scorer.scores # Calculate a weighted sum based on score_weights for the main score weights = cfg["score_weights"] try: weighted_score = sum(scores[s] * weights.get(s, 0.0) for s in weights) except KeyError as e: raise KeyError( Errors.E983.format( dict="score_weights", key=str(e), keys=list(scores.keys()) ) ) scores["speed"] = wps return weighted_score, scores return evaluate def train_while_improving( nlp, optimizer, train_data, evaluate, *, dropout, eval_frequency, accumulate_gradient=1, patience=0, max_steps=0, raw_text=None, ): """Train until an evaluation stops improving. Works as a generator, with each iteration yielding a tuple `(batch, info, is_best_checkpoint)`, where info is a dict, and is_best_checkpoint is in [True, False, None] -- None indicating that the iteration was not evaluated as a checkpoint. The evaluation is conducted by calling the evaluate callback, which should Positional arguments: nlp: The spaCy pipeline to evaluate. optimizer: The optimizer callable. train_data (Iterable[Batch]): A generator of batches, with the training data. Each batch should be a Sized[Tuple[Input, Annot]]. The training data iterable needs to take care of iterating over the epochs and shuffling. evaluate (Callable[[], Tuple[float, Any]]): A callback to perform evaluation. The callback should take no arguments and return a tuple `(main_score, other_scores)`. The main_score should be a float where higher is better. other_scores can be any object. Every iteration, the function yields out a tuple with: * batch: A list of Example objects. * info: A dict with various information about the last update (see below). * is_best_checkpoint: A value in None, False, True, indicating whether this was the best evaluation so far. You should use this to save the model checkpoints during training. If None, evaluation was not conducted on that iteration. False means evaluation was conducted, but a previous evaluation was better. The info dict provides the following information: epoch (int): How many passes over the data have been completed. step (int): How many steps have been completed. score (float): The main score form the last evaluation. other_scores: : The other scores from the last evaluation. loss: The accumulated losses throughout training. checkpoints: A list of previous results, where each result is a (score, step, epoch) tuple. """ if isinstance(dropout, float): dropouts = thinc.schedules.constant(dropout) else: dropouts = dropout results = [] losses = {} to_enable = [name for name, proc in nlp.pipeline if hasattr(proc, "model")] if raw_text: random.shuffle(raw_text) raw_examples = [Example.from_dict(nlp.make_doc(rt["text"]), {}) for rt in raw_text] raw_batches = util.minibatch(raw_examples, size=8) for step, (epoch, batch) in enumerate(train_data): dropout = next(dropouts) with nlp.select_pipes(enable=to_enable): for subbatch in subdivide_batch(batch, accumulate_gradient): nlp.update(subbatch, drop=dropout, losses=losses, sgd=False) if raw_text: # If raw text is available, perform 'rehearsal' updates, # which use unlabelled data to reduce overfitting. raw_batch = list(next(raw_batches)) nlp.rehearse(raw_batch, sgd=optimizer, losses=losses) for name, proc in nlp.pipeline: if hasattr(proc, "model"): proc.model.finish_update(optimizer) optimizer.step_schedules() if not (step % eval_frequency): score, other_scores = evaluate() results.append((score, step)) is_best_checkpoint = score == max(results)[0] else: score, other_scores = (None, None) is_best_checkpoint = None info = { "epoch": epoch, "step": step, "score": score, "other_scores": other_scores, "losses": losses, "checkpoints": results, } yield batch, info, is_best_checkpoint if is_best_checkpoint is not None: losses = {} # Stop if no improvement in `patience` updates (if specified) best_score, best_step = max(results) if patience and (step - best_step) >= patience: break # Stop if we've exhausted our max steps (if specified) if max_steps and step >= max_steps: break def subdivide_batch(batch, accumulate_gradient): batch = list(batch) batch.sort(key=lambda eg: len(eg.predicted)) sub_len = len(batch) // accumulate_gradient start = 0 for i in range(accumulate_gradient): subbatch = batch[start : start + sub_len] if subbatch: yield subbatch start += len(subbatch) subbatch = batch[start:] if subbatch: yield subbatch def setup_printer(training, nlp): score_cols = training["scores"] score_widths = [max(len(col), 6) for col in score_cols] loss_cols = [f"Loss {pipe}" for pipe in nlp.pipe_names] loss_widths = [max(len(col), 8) for col in loss_cols] table_header = ["E", "#"] + loss_cols + score_cols + ["Score"] table_header = [col.upper() for col in table_header] table_widths = [3, 6] + loss_widths + score_widths + [6] table_aligns = ["r" for _ in table_widths] msg.row(table_header, widths=table_widths) msg.row(["-" * width for width in table_widths]) def print_row(info): try: losses = [ "{0:.2f}".format(float(info["losses"][pipe_name])) for pipe_name in nlp.pipe_names ] except KeyError as e: raise KeyError( Errors.E983.format( dict="scores (losses)", key=str(e), keys=list(info["losses"].keys()) ) ) try: scores = [ "{0:.2f}".format(float(info["other_scores"][col])) for col in score_cols ] except KeyError as e: raise KeyError( Errors.E983.format( dict="scores (other)", key=str(e), keys=list(info["other_scores"].keys()), ) ) data = ( [info["epoch"], info["step"]] + losses + scores + ["{0:.2f}".format(float(info["score"]))] ) msg.row(data, widths=table_widths, aligns=table_aligns) return print_row def update_meta(training, nlp, info): score_cols = training["scores"] nlp.meta["performance"] = {} for metric in score_cols: nlp.meta["performance"][metric] = info["other_scores"][metric] for pipe_name in nlp.pipe_names: nlp.meta["performance"][f"{pipe_name}_loss"] = info["losses"][pipe_name] def verify_cli_args( train_path, dev_path, config_path, output_path=None, code_path=None, init_tok2vec=None, raw_text=None, verbose=False, use_gpu=-1, tag_map_path=None, omit_extra_lookups=False, ): # Make sure all files and paths exists if they are needed if not config_path or not config_path.exists(): msg.fail("Config file not found", config_path, exits=1) if not train_path or not train_path.exists(): msg.fail("Training data not found", train_path, exits=1) if not dev_path or not dev_path.exists(): msg.fail("Development data not found", dev_path, exits=1) if output_path is not None: if not output_path.exists(): output_path.mkdir() msg.good(f"Created output directory: {output_path}") elif output_path.exists() and [p for p in output_path.iterdir() if p.is_dir()]: msg.warn( "Output directory is not empty.", "This can lead to unintended side effects when saving the model. " "Please use an empty directory or a different path instead. If " "the specified output path doesn't exist, the directory will be " "created for you.", ) if code_path is not None: if not code_path.exists(): msg.fail("Path to Python code not found", code_path, exits=1) try: util.import_file("python_code", code_path) except Exception as e: msg.fail(f"Couldn't load Python code: {code_path}", e, exits=1) if init_tok2vec is not None and not init_tok2vec.exists(): msg.fail("Can't find pretrained tok2vec", init_tok2vec, exits=1) def verify_textcat_config(nlp, nlp_config): # if 'positive_label' is provided: double check whether it's in the data and # the task is binary if nlp_config["pipeline"]["textcat"].get("positive_label", None): textcat_labels = nlp.get_pipe("textcat").cfg.get("labels", []) pos_label = nlp_config["pipeline"]["textcat"]["positive_label"] if pos_label not in textcat_labels: msg.fail( f"The textcat's 'positive_label' config setting '{pos_label}' " f"does not match any label in the training data.", exits=1, ) if len(textcat_labels) != 2: msg.fail( f"A textcat 'positive_label' '{pos_label}' was " f"provided for training data that does not appear to be a " f"binary classification problem with two labels.", exits=1, )