def profile(model, inputs=None, n_texts=10000):
"""
Profile a spaCy pipeline, to find out which functions take the most time.
Input should be formatted as one JSON object per line with a key "text".
It can either be provided as a JSONL file, or be read from sys.sytdin.
If no input file is specified, the IMDB dataset is loaded via Thinc.
"""
msg = Printer()
if inputs is not None:
inputs = _read_inputs(inputs, msg)
if inputs is None:
n_inputs = 25000
with msg.loading("Loading IMDB dataset via Thinc..."):
imdb_train, _ = thinc.extra.datasets.imdb()
inputs, _ = zip(*imdb_train)
msg.info("Loaded IMDB dataset and using {} examples".format(n_inputs))
inputs = inputs[:n_inputs]
with msg.loading("Loading model '{}'...".format(model)):
nlp = load_model(model)
msg.good("Loaded model '{}'".format(model))
texts = list(itertools.islice(inputs, n_texts))
cProfile.runctx("parse_texts(nlp, texts)", globals(), locals(), "Profile.prof")
s = pstats.Stats("Profile.prof")
msg.divider("Profile stats")
s.strip_dirs().sort_stats("time").print_stats()
def download_file(url: str, dest_filename: str) -> None:
""" Download a file from the given url
Parameters
----------
url : str
The url from which the file will be downloaded
dest_filename : str
The destination filename
"""
# NOTE the stream=True parameter below
msg_printer = Printer()
block_size = 65536
r = requests.get(url, stream=True)
total_size = int(r.headers.get("content-length", 0))
written = 0
with open(dest_filename, "wb") as f:
for chunk in tqdm(
r.iter_content(chunk_size=block_size),
total=math.ceil(total_size // block_size),
desc=f"Downloading from {url}",
):
if chunk: # filter out keep-alive new chunks
written = written + len(chunk)
f.write(chunk)
msg_printer.good(f"Finished downloading {url} to {dest_filename}")
def print_summary(nlp, pretty=True, no_print=False):
"""Print a formatted summary for the current nlp object's pipeline. Shows
a table with the pipeline components and why they assign and require, as
well as any problems if available.
nlp (Language): The nlp object.
pretty (bool): Pretty-print the results (color etc).
no_print (bool): Don't print anything, just return the data.
RETURNS (dict): A dict with "overview" and "problems".
"""
msg = Printer(pretty=pretty, no_print=no_print)
overview = []
problems = {}
for i, (name, pipe) in enumerate(nlp.pipeline):
requires = getattr(pipe, "requires", [])
assigns = getattr(pipe, "assigns", [])
retok = getattr(pipe, "retokenizes", False)
overview.append((i, name, requires, assigns, retok))
problems[name] = analyze_pipes(nlp.pipeline, name, pipe, i, warn=False)
msg.divider("Pipeline Overview")
header = ("#", "Component", "Requires", "Assigns", "Retokenizes")
msg.table(overview, header=header, divider=True, multiline=True)
n_problems = sum(len(p) for p in problems.values())
if any(p for p in problems.values()):
msg.divider("Problems ({})".format(n_problems))
for name, problem in problems.items():
if problem:
problem = ", ".join(problem)
msg.warn("'{}' requirements not met: {}".format(name, problem))
else:
msg.good("No problems found.")
if no_print:
return {"overview": overview, "problems": problems}
def spinner(text='Loading...', clean=False):
printer = Printer()
spinchars = '⠙⠹⠸⠼⠴⠦⠧⠇⠏'
def spin(s):
for char in itertools.cycle(spinchars):
sys.stdout.write("\r\033[96m{} {}".format(char, s))
sys.stdout.flush()
time.sleep(0.1)
stime = time.time()
t = Process(target=spin, args=(text, ))
t.start()
try:
yield
except Exception as e:
t.terminate()
printer.fail(text + ' failed.')
raise e
t.terminate()
sys.stdout.write("\r")
if clean:
for _ in range(len(text) // 4 + 1):
sys.stdout.write("\x1b[2K")
else:
time_used = strfsec(int(time.time() - stime))
printer.good(f'{text} succeed in {time_used}.')
sys.stdout.flush()
def main(uri, table_path, schema, write_mode):
msg = Printer()
project_id, dataset_id, _ = table_path.split(".")
config = Config(project_id=project_id, dataset_id=dataset_id)
client = config.client()
table_ref = str_to_bq_ref(table_path)
load_job_config = bq.LoadJobConfig()
load_job_config.schema = client.schema_from_json(schema)
load_job_config.source_format = bq.SourceFormat.NEWLINE_DELIMITED_JSON
load_job_config.ignore_unknown_values = True
load_job_config.write_disposition = "WRITE_APPEND"
load_job_config.max_bad_records = 100
assert write_mode in ["CREATE_NEW", "WRITE_APPEND"]
table_id = table_path.split(".")[-1]
exists = any([
table_id == table.table_id
for table in client.list_tables(client.dataset(dataset_id))
])
if exists and write_mode == "CREATE_NEW":
msg.info(f"{table_path} already exists. Write_mode: {write_mode}")
client.delete_table(table_ref)
table = bq.Table(table_ref, schema=client.schema_from_json(schema))
client.create_table(table)
load_job = client.load_table_from_uri(uri,
table_ref,
job_config=load_job_config)
with msg.loading("Loading data..."):
load_job.result()
msg.good("Data succesfully loaded!")
def op_iter(
data: List[Example],
pre: List[PreProcessor],
verbose: bool = True) -> Iterator[Tuple[int, Example, Dict[str, Any]]]:
"""Iterate over list of examples for an operation
yielding tuples of (example hash, example)
Args:
data (List[Example]): List of examples to iterate
pre (List[PreProcessor]): List of preprocessors to run
verbose (bool, optional): Show verbose output.
Yields:
Iterator[Tuple[int, Example]]: Tuples of (example hash, example)
"""
msg = Printer(no_print=verbose == False, hide_animation=verbose == False)
preprocessed_outputs: Dict[Example, Dict[str, Any]] = defaultdict(dict)
for processor in pre:
with msg.loading(f"\t=> Running preprocessor {processor.name}..."):
processor_outputs = list(processor(data))
msg.good("Done")
for i, (example, output) in enumerate(zip(data, processor_outputs)):
preprocessed_outputs[example][
processor.name] = processor_outputs[i]
for example in data:
yield hash(example), example.copy(
deep=True), preprocessed_outputs[example]
def evaluate(
model,
data_path,
gpu_id=-1,
gold_preproc=False,
displacy_path=None,
displacy_limit=25,
return_scores=False,
):
"""
Evaluate a model. To render a sample of parses in a HTML file, set an
output directory as the displacy_path argument.
"""
msg = Printer()
util.fix_random_seed()
if gpu_id >= 0:
util.use_gpu(gpu_id)
util.set_env_log(False)
data_path = util.ensure_path(data_path)
displacy_path = util.ensure_path(displacy_path)
if not data_path.exists():
msg.fail("Evaluation data not found", data_path, exits=1)
if displacy_path and not displacy_path.exists():
msg.fail("Visualization output directory not found", displacy_path, exits=1)
corpus = GoldCorpus(data_path, data_path)
nlp = util.load_model(model)
dev_docs = list(corpus.dev_docs(nlp, gold_preproc=gold_preproc))
begin = timer()
scorer = nlp.evaluate(dev_docs, verbose=False)
end = timer()
nwords = sum(len(doc_gold[0]) for doc_gold in dev_docs)
results = {
"Time": "%.2f s" % (end - begin),
"Words": nwords,
"Words/s": "%.0f" % (nwords / (end - begin)),
"TOK": "%.2f" % scorer.token_acc,
"POS": "%.2f" % scorer.tags_acc,
"UAS": "%.2f" % scorer.uas,
"LAS": "%.2f" % scorer.las,
"NER P": "%.2f" % scorer.ents_p,
"NER R": "%.2f" % scorer.ents_r,
"NER F": "%.2f" % scorer.ents_f,
}
msg.table(results, title="Results")
if displacy_path:
docs, golds = zip(*dev_docs)
render_deps = "parser" in nlp.meta.get("pipeline", [])
render_ents = "ner" in nlp.meta.get("pipeline", [])
render_parses(
docs,
displacy_path,
model_name=model,
limit=displacy_limit,
deps=render_deps,
ents=render_ents,
)
msg.good("Generated {} parses as HTML".format(displacy_limit), displacy_path)
if return_scores:
return scorer.scores
def extract_tar(filename: str, destination_dir: str, mode="r"):
""" Extracts tar, targz and other files
Parameters
----------
filename : str
The tar zipped file
destination_dir : str
The destination directory in which the files should be placed
mode : str
A valid tar mode. You can refer to https://docs.python.org/3/library/tarfile.html
for the different modes.
Returns
-------
"""
msg_printer = Printer()
try:
with msg_printer.loading(
f"Unzipping file {filename} to {destination_dir}"):
stdout.flush()
with tarfile.open(filename, mode) as t:
t.extractall(destination_dir)
msg_printer.good(
f"Finished extraction {filename} to {destination_dir}")
except tarfile.ExtractError:
msg_printer.fail("Couldnot extract {filename} to {destination}")
def convert(
input_file,
output_dir="-",
file_type="jsonl",
n_sents=1,
morphology=False,
converter="auto",
lang=None,
):
"""
Convert files into JSON format for use with train command and other
experiment management functions. If no output_dir is specified, the data
is written to stdout, so you can pipe them forward to a JSONL file:
$ spacy convert some_file.conllu > some_file.jsonl
"""
msg = Printer()
input_path = Path(input_file)
if file_type not in FILE_TYPES:
msg.fail(
"Unknown file type: '{}'".format(file_type),
"Supported file types: '{}'".format(", ".join(FILE_TYPES)),
exits=1,
)
if file_type not in FILE_TYPES_STDOUT and output_dir == "-":
# TODO: support msgpack via stdout in srsly?
msg.fail(
"Can't write .{} data to stdout.".format(file_type),
"Please specify an output directory.",
exits=1,
)
if not input_path.exists():
msg.fail("Input file not found", input_path, exits=1)
if output_dir != "-" and not Path(output_dir).exists():
msg.fail("Output directory not found", output_dir, exits=1)
if converter == "auto":
converter = input_path.suffix[1:]
if converter not in CONVERTERS:
msg.fail("Can't find converter for {}".format(converter), exits=1)
# Use converter function to convert data
func = CONVERTERS[converter]
input_data = input_path.open("r", encoding="utf-8").read()
data = func(input_data, n_sents=n_sents, use_morphology=morphology, lang=lang)
if output_dir != "-":
# Export data to a file
suffix = ".{}".format(file_type)
output_file = Path(output_dir) / Path(input_path.parts[-1]).with_suffix(suffix)
if file_type == "json":
srsly.write_json(output_file, data)
elif file_type == "jsonl":
srsly.write_jsonl(output_file, data)
elif file_type == "msg":
srsly.write_msgpack(output_file, data)
msg.good("Generated output file ({} documents)".format(len(data)), output_file)
else:
# Print to stdout
if file_type == "json":
srsly.write_json("-", data)
elif file_type == "jsonl":
srsly.write_jsonl("-", data)
def package(input_dir, output_dir, meta_path=None, create_meta=False, force=False):
"""
Generate Python package for model data, including meta and required
installation files. A new directory will be created in the specified
output directory, and model data will be copied over. If --create-meta is
set and a meta.json already exists in the output directory, the existing
values will be used as the defaults in the command-line prompt.
"""
msg = Printer()
input_path = util.ensure_path(input_dir)
output_path = util.ensure_path(output_dir)
meta_path = util.ensure_path(meta_path)
if not input_path or not input_path.exists():
msg.fail("Can't locate model data", input_path, exits=1)
if not output_path or not output_path.exists():
msg.fail("Output directory not found", output_path, exits=1)
if meta_path and not meta_path.exists():
msg.fail("Can't find model meta.json", meta_path, exits=1)
meta_path = meta_path or input_path / "meta.json"
if meta_path.is_file():
meta = srsly.read_json(meta_path)
if not create_meta: # only print if user doesn't want to overwrite
msg.good("Loaded meta.json from file", meta_path)
else:
meta = generate_meta(input_dir, meta, msg)
for key in ("lang", "name", "version"):
if key not in meta or meta[key] == "":
msg.fail(
"No '{}' setting found in meta.json".format(key),
"This setting is required to build your package.",
exits=1,
)
model_name = meta["lang"] + "_" + meta["name"]
model_name_v = model_name + "-" + meta["version"]
main_path = output_path / model_name_v
package_path = main_path / model_name
if package_path.exists():
if force:
shutil.rmtree(path2str(package_path))
else:
msg.fail(
"Package directory already exists",
"Please delete the directory and try again, or use the "
"`--force` flag to overwrite existing "
"directories.".format(path=path2str(package_path)),
exits=1,
)
Path.mkdir(package_path, parents=True)
shutil.copytree(path2str(input_path), path2str(package_path / model_name_v))
create_file(main_path / "meta.json", srsly.json_dumps(meta, indent=2))
create_file(main_path / "setup.py", TEMPLATE_SETUP)
create_file(main_path / "MANIFEST.in", TEMPLATE_MANIFEST)
create_file(package_path / "__init__.py", TEMPLATE_INIT)
msg.good("Successfully created package '{}'".format(model_name_v), main_path)
msg.text("To build the package, run `python setup.py sdist` in this directory.")
def convert_sectlabel_to_json(filename: str) -> Dict:
""" Converts the secthead file into more readable json format
Parameters
----------
filename : str
The sectlabel file name available at WING-NUS website
Returns
-------
Dict[str, Any]
text
The text of the line
label
The label of the file
file_no
A unique file number
line_count
A line count within the file
"""
file_count = 1
line_count = 1
output_json = {"parse_sect": []}
msg_printer = Printer()
with open(filename) as fp:
for line in tqdm(fp, desc="Converting SectLabel File to JSON"):
line = line.replace("\n", "")
# if the line is empty then the next line is the beginning of the
if not line:
file_count += 1
continue
# new file
fields = line.split()
line_content = fields[0] # first column contains the content text
line_content = line_content.replace(
"|||", " "
) # every word in the line is sepearted by |||
label = fields[-1] # the last column contains the field marked
line_json = {
"text": line_content,
"label": label,
"file_no": file_count,
"line_count": line_count,
}
line_count += 1
output_json["parse_sect"].append(line_json)
msg_printer.good("Finished converting sect label file to JSON")
return output_json
def main(path, name="bert-base-uncased", lang="en"):
msg = Printer()
msg.info(f"Creating model for '{name}' ({lang})")
with msg.loading(f"Setting up the pipeline..."):
nlp = PyTT_Language(pytt_name=name, meta={"lang": lang})
nlp.add_pipe(nlp.create_pipe("sentencizer"))
nlp.add_pipe(PyTT_WordPiecer.from_pretrained(nlp.vocab, name))
nlp.add_pipe(PyTT_TokenVectorEncoder.from_pretrained(nlp.vocab, name))
msg.good("Initialized the model pipeline")
nlp.to_disk(path)
msg.good(f"Saved '{name}' ({lang})")
msg.text(f"Pipeline: {nlp.pipe_names}")
msg.text(f"Location: {path}")
def fill_config(
output_file: Path,
base_path: Path,
*,
pretraining: bool = False,
diff: bool = False,
silent: bool = False,
) -> Tuple[Config, Config]:
is_stdout = str(output_file) == "-"
no_print = is_stdout or silent
msg = Printer(no_print=no_print)
with show_validation_error(hint_fill=False):
config = util.load_config(base_path)
nlp = util.load_model_from_config(config,
auto_fill=True,
validate=False)
# Load a second time with validation to be extra sure that the produced
# config result is a valid config
nlp = util.load_model_from_config(nlp.config)
filled = nlp.config
# If we have sourced components in the base config, those will have been
# replaced with their actual config after loading, so we have to re-add them
sourced = util.get_sourced_components(config)
filled["components"].update(sourced)
if pretraining:
validate_config_for_pretrain(filled, msg)
pretrain_config = util.load_config(DEFAULT_CONFIG_PRETRAIN_PATH)
filled = pretrain_config.merge(filled)
before = config.to_str()
after = filled.to_str()
if before == after:
msg.warn("Nothing to auto-fill: base config is already complete")
else:
msg.good("Auto-filled config with all values")
if diff and not no_print:
if before == after:
msg.warn("No diff to show: nothing was auto-filled")
else:
msg.divider("START CONFIG DIFF")
print("")
print(diff_strings(before, after))
msg.divider("END CONFIG DIFF")
print("")
save_config(filled, output_file, is_stdout=is_stdout, silent=silent)
return config, filled
def convert_parscit_to_conll(
parscit_train_filepath: pathlib.Path, ) -> List[Dict[str, Any]]:
""" Convert the parscit data available at
"https://github.com/knmnyn/ParsCit/blob/master/crfpp/traindata/parsCit.train.data"
to a CONLL dummy version
This is done so that we can use it with AllenNLPs built in data reader called
conll2013 dataset reader
Parameters
----------------
parscit_train_filepath: pathlib.Path
The path where the train file path is stored
"""
printer = Printer()
citation_string = []
word_tags = []
output_list = []
with printer.loading(
f"Converting {parscit_train_filepath.name} to conll format"):
with open(str(parscit_train_filepath), "r", encoding="latin-1") as fp:
for line in fp:
if bool(line.strip()):
fields = line.strip().split()
word = fields[0]
tag = fields[-1]
word = word.strip()
tag = f"{tag.strip()}"
word_tag = " ".join([word] + [tag] * 3)
citation_string.append(word)
word_tags.append(word_tag)
else:
citation_string = " ".join(citation_string)
output_list.append({
"word_tags": word_tags,
"citation_string": citation_string
})
citation_string = []
word_tags = []
printer.good(
f"Successfully converted {parscit_train_filepath.name} to conll format"
)
return output_list
def save_config(config: Config,
output_file: Path,
is_stdout: bool = False,
silent: bool = False) -> None:
no_print = is_stdout or silent
msg = Printer(no_print=no_print)
if is_stdout:
print(config.to_str())
else:
if not output_file.parent.exists():
output_file.parent.mkdir(parents=True)
config.to_disk(output_file, interpolate=False)
msg.good("Saved config", output_file)
msg.text("You can now add your data and train your pipeline:")
variables = ["--paths.train ./train.spacy", "--paths.dev ./dev.spacy"]
if not no_print:
print(
f"{COMMAND} train {output_file.parts[-1]} {' '.join(variables)}"
)
def extract_zip(filename: str, destination_dir: str):
""" Extracts a zipped file
Parameters
----------
filename : str
The zipped filename
destination_dir : str
The directory where the zipped will be placed
"""
msg_printer = Printer()
try:
with msg_printer.loading(f"Unzipping file {filename} to {destination_dir}"):
stdout.flush()
with zipfile.ZipFile(filename, "r") as z:
z.extractall(destination_dir)
msg_printer.good(f"Finished extraction {filename} to {destination_dir}")
except zipfile.BadZipFile:
msg_printer.fail("Couldnot extract {filename} to {destination}")
def apply_(
self,
operation: Union[str, Callable[[Any], OperationResult]],
*args: Any,
initial_state: OperationState = None,
**kwargs: Any,
) -> None:
"""Apply an operation to all data inplace.
Args:
operation (Callable[[Any], OperationResult]): Any operation that
changes data in place. See recon.operations.registry.operations
"""
if isinstance(operation, str):
operation = registry.operations.get(operation)
if operation:
operation = cast(Callable, operation)
name = getattr(operation, "name", None)
if name is None or name not in registry.operations:
raise ValueError(
"This function is not an operation. Ensure your function is registered in the operations registry."
)
msg = Printer(no_print=self.verbose == False)
msg.text(f"=> Applying operation '{name}' inplace")
result: OperationResult = operation(self, *args, initial_state=initial_state, verbose=self.verbose, **kwargs) # type: ignore
msg.good(f"Completed operation '{name}'")
self.operations.append(result.state)
dataset_changed = any(
(
result.state.examples_added,
result.state.examples_removed,
result.state.examples_changed,
)
)
if dataset_changed:
self.data = result.data
def main(path, name="bert-base-uncased", lang="en"):
msg = Printer()
msg.info(f"Creating model for '{name}' ({lang})")
with msg.loading(f"Setting up the pipeline..."):
nlp = TransformersLanguage(trf_name=name, meta={"lang": lang})
nlp.add_pipe(nlp.create_pipe("sentencizer"))
nlp.add_pipe(TransformersWordPiecer.from_pretrained(nlp.vocab, name))
nlp.add_pipe(TransformersTok2Vec.from_pretrained(nlp.vocab, name))
msg.good("Initialized the model pipeline")
nlp.to_disk(path)
msg.good(f"Saved '{name}' ({lang})")
msg.text(f"Pipeline: {nlp.pipe_names}")
msg.text(f"Location: {path}")
with msg.loading("Verifying model loads..."):
nlp.from_disk(path)
msg.good("Model loads!")
def package(
input_dir: Path,
output_dir: Path,
meta_path: Optional[Path] = None,
code_paths: List[Path] = [],
name: Optional[str] = None,
version: Optional[str] = None,
create_meta: bool = False,
create_sdist: bool = True,
create_wheel: bool = False,
force: bool = False,
silent: bool = True,
) -> None:
msg = Printer(no_print=silent, pretty=not silent)
input_path = util.ensure_path(input_dir)
output_path = util.ensure_path(output_dir)
meta_path = util.ensure_path(meta_path)
if create_wheel and not has_wheel():
err = "Generating a binary .whl file requires wheel to be installed"
msg.fail(err, "pip install wheel", exits=1)
if not input_path or not input_path.exists():
msg.fail("Can't locate pipeline data", input_path, exits=1)
if not output_path or not output_path.exists():
msg.fail("Output directory not found", output_path, exits=1)
if create_sdist or create_wheel:
opts = [
"sdist" if create_sdist else "", "wheel" if create_wheel else ""
]
msg.info(
f"Building package artifacts: {', '.join(opt for opt in opts if opt)}"
)
for code_path in code_paths:
if not code_path.exists():
msg.fail("Can't find code file", code_path, exits=1)
# Import the code here so it's available when model is loaded (via
# get_meta helper). Also verifies that everything works
util.import_file(code_path.stem, code_path)
if code_paths:
msg.good(
f"Including {len(code_paths)} Python module(s) with custom code")
if meta_path and not meta_path.exists():
msg.fail("Can't find pipeline meta.json", meta_path, exits=1)
meta_path = meta_path or input_dir / "meta.json"
if not meta_path.exists() or not meta_path.is_file():
msg.fail("Can't load pipeline meta.json", meta_path, exits=1)
meta = srsly.read_json(meta_path)
meta = get_meta(input_dir, meta)
if name is not None:
meta["name"] = name
if version is not None:
meta["version"] = version
if not create_meta: # only print if user doesn't want to overwrite
msg.good("Loaded meta.json from file", meta_path)
else:
meta = generate_meta(meta, msg)
errors = validate(ModelMetaSchema, meta)
if errors:
msg.fail("Invalid pipeline meta.json")
print("\n".join(errors))
sys.exit(1)
model_name = meta["lang"] + "_" + meta["name"]
model_name_v = model_name + "-" + meta["version"]
main_path = output_dir / model_name_v
package_path = main_path / model_name
if package_path.exists():
if force:
shutil.rmtree(str(package_path))
else:
msg.fail(
"Package directory already exists",
"Please delete the directory and try again, or use the "
"`--force` flag to overwrite existing directories.",
exits=1,
)
Path.mkdir(package_path, parents=True)
shutil.copytree(str(input_dir), str(package_path / model_name_v))
license_path = package_path / model_name_v / "LICENSE"
if license_path.exists():
shutil.move(str(license_path), str(main_path))
imports = []
for code_path in code_paths:
imports.append(code_path.stem)
shutil.copy(str(code_path), str(package_path))
create_file(main_path / "meta.json", srsly.json_dumps(meta, indent=2))
create_file(main_path / "setup.py", TEMPLATE_SETUP)
create_file(main_path / "MANIFEST.in", TEMPLATE_MANIFEST)
init_py = TEMPLATE_INIT.format(imports="\n".join(f"from . import {m}"
for m in imports))
create_file(package_path / "__init__.py", init_py)
msg.good(f"Successfully created package '{model_name_v}'", main_path)
if create_sdist:
with util.working_dir(main_path):
util.run_command([sys.executable, "setup.py", "sdist"],
capture=False)
zip_file = main_path / "dist" / f"{model_name_v}{SDIST_SUFFIX}"
msg.good(f"Successfully created zipped Python package", zip_file)
if create_wheel:
with util.working_dir(main_path):
util.run_command([sys.executable, "setup.py", "bdist_wheel"],
capture=False)
wheel = main_path / "dist" / f"{model_name_v}{WHEEL_SUFFIX}"
msg.good(f"Successfully created binary wheel", wheel)
def validate():
"""
Validate that the currently installed version of spaCy is compatible
with the installed models. Should be run after `pip install -U spacy`.
"""
msg = Printer()
with msg.loading("Loading compatibility table..."):
r = requests.get(about.__compatibility__)
if r.status_code != 200:
msg.fail(
"Server error ({})".format(r.status_code),
"Couldn't fetch compatibility table.",
exits=1,
)
msg.good("Loaded compatibility table")
compat = r.json()["spacy"]
version = about.__version__
version = version.rsplit(".dev", 1)[0]
current_compat = compat.get(version)
if not current_compat:
msg.fail(
"Can't find spaCy v{} in compatibility table".format(version),
about.__compatibility__,
exits=1,
)
all_models = set()
for spacy_v, models in dict(compat).items():
all_models.update(models.keys())
for model, model_vs in models.items():
compat[spacy_v][model] = [reformat_version(v) for v in model_vs]
model_links = get_model_links(current_compat)
model_pkgs = get_model_pkgs(current_compat, all_models)
incompat_links = {l for l, d in model_links.items() if not d["compat"]}
incompat_models = {
d["name"]
for _, d in model_pkgs.items() if not d["compat"]
}
incompat_models.update(
[d["name"] for _, d in model_links.items() if not d["compat"]])
na_models = [m for m in incompat_models if m not in current_compat]
update_models = [m for m in incompat_models if m in current_compat]
spacy_dir = Path(__file__).parent.parent
msg.divider("Installed models (spaCy v{})".format(about.__version__))
msg.info("spaCy installation: {}".format(path2str(spacy_dir)))
if model_links or model_pkgs:
header = ("TYPE", "NAME", "MODEL", "VERSION", "")
rows = []
for name, data in model_pkgs.items():
rows.append(get_model_row(current_compat, name, data, msg))
for name, data in model_links.items():
rows.append(get_model_row(current_compat, name, data, msg, "link"))
msg.table(rows, header=header)
else:
msg.text("No models found in your current environment.", exits=0)
if update_models:
msg.divider("Install updates")
msg.text("Use the following commands to update the model packages:")
cmd = "python -m spacy download {}"
print("\n".join([cmd.format(pkg) for pkg in update_models]) + "\n")
if na_models:
msg.text("The following models are not available for spaCy "
"v{}: {}".format(about.__version__, ", ".join(na_models)))
if incompat_links:
msg.text(
"You may also want to overwrite the incompatible links using the "
"`python -m spacy link` command with `--force`, or remove them "
"from the data directory. "
"Data path: {path}".format(path=path2str(get_data_path())))
if incompat_models or incompat_links:
sys.exit(1)
def init_config(
*,
lang: str,
pipeline: List[str],
optimize: str,
gpu: bool,
pretraining: bool = False,
silent: bool = True,
) -> Config:
msg = Printer(no_print=silent)
with TEMPLATE_PATH.open("r") as f:
template = Template(f.read())
# Filter out duplicates since tok2vec and transformer are added by template
pipeline = [
pipe for pipe in pipeline if pipe not in ("tok2vec", "transformer")
]
defaults = RECOMMENDATIONS["__default__"]
reco = RecommendationSchema(**RECOMMENDATIONS.get(lang, defaults)).dict()
variables = {
"lang": lang,
"components": pipeline,
"optimize": optimize,
"hardware": "gpu" if gpu else "cpu",
"transformer_data": reco["transformer"],
"word_vectors": reco["word_vectors"],
"has_letters": reco["has_letters"],
}
if variables["transformer_data"] and not has_spacy_transformers():
msg.warn(
"To generate a more effective transformer-based config (GPU-only), "
"install the spacy-transformers package and re-run this command. "
"The config generated now does not use transformers.")
variables["transformer_data"] = None
base_template = template.render(variables).strip()
# Giving up on getting the newlines right in jinja for now
base_template = re.sub(r"\n\n\n+", "\n\n", base_template)
# Access variables declared in templates
template_vars = template.make_module(variables)
use_case = {
"Language":
lang,
"Pipeline":
", ".join(pipeline),
"Optimize for":
optimize,
"Hardware":
variables["hardware"].upper(),
"Transformer":
template_vars.transformer.get("name") # type: ignore[attr-defined]
if template_vars.use_transformer # type: ignore[attr-defined]
else None,
}
msg.info("Generated config template specific for your use case")
for label, value in use_case.items():
msg.text(f"- {label}: {value}")
with show_validation_error(hint_fill=False):
config = util.load_config_from_str(base_template)
nlp = util.load_model_from_config(config, auto_fill=True)
config = nlp.config
if pretraining:
validate_config_for_pretrain(config, msg)
pretrain_config = util.load_config(DEFAULT_CONFIG_PRETRAIN_PATH)
config = pretrain_config.merge(config)
msg.good("Auto-filled config with all values")
return config
def train(
lang,
output_path,
train_path,
dev_path,
raw_text=None,
base_model=None,
pipeline="tagger,parser,ner",
vectors=None,
n_iter=30,
n_early_stopping=None,
n_examples=0,
use_gpu=-1,
version="0.0.0",
meta_path=None,
init_tok2vec=None,
parser_multitasks="",
entity_multitasks="",
noise_level=0.0,
orth_variant_level=0.0,
eval_beam_widths="",
gold_preproc=False,
learn_tokens=False,
textcat_multilabel=False,
textcat_arch="bow",
textcat_positive_label=None,
verbose=False,
debug=False,
):
"""
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.
"""
# temp fix to avoid import issues cf https://github.com/explosion/spaCy/issues/4200
import tqdm
msg = Printer()
util.fix_random_seed()
util.set_env_log(verbose)
# Make sure all files and paths exists if they are needed
train_path = util.ensure_path(train_path)
dev_path = util.ensure_path(dev_path)
meta_path = util.ensure_path(meta_path)
output_path = util.ensure_path(output_path)
if raw_text is not None:
raw_text = list(srsly.read_jsonl(raw_text))
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 meta_path is not None and not meta_path.exists():
msg.fail("Can't find model meta.json", meta_path, exits=1)
meta = srsly.read_json(meta_path) if meta_path else {}
if 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 not output_path.exists():
output_path.mkdir()
# Take dropout and batch size as generators of values -- dropout
# starts high and decays sharply, to force the optimizer to explore.
# Batch size starts at 1 and grows, so that we make updates quickly
# at the beginning of training.
dropout_rates = util.decaying(
util.env_opt("dropout_from", 0.2),
util.env_opt("dropout_to", 0.2),
util.env_opt("dropout_decay", 0.0),
)
batch_sizes = util.compounding(
util.env_opt("batch_from", 100.0),
util.env_opt("batch_to", 1000.0),
util.env_opt("batch_compound", 1.001),
)
if not eval_beam_widths:
eval_beam_widths = [1]
else:
eval_beam_widths = [int(bw) for bw in eval_beam_widths.split(",")]
if 1 not in eval_beam_widths:
eval_beam_widths.append(1)
eval_beam_widths.sort()
has_beam_widths = eval_beam_widths != [1]
# Set up the base model and pipeline. If a base model is specified, load
# the model and make sure the pipeline matches the pipeline setting. If
# training starts from a blank model, intitalize the language class.
pipeline = [p.strip() for p in pipeline.split(",")]
msg.text("Training pipeline: {}".format(pipeline))
if base_model:
msg.text("Starting with base model '{}'".format(base_model))
nlp = util.load_model(base_model)
if nlp.lang != lang:
msg.fail(
"Model language ('{}') doesn't match language specified as "
"`lang` argument ('{}') ".format(nlp.lang, lang),
exits=1,
)
nlp.disable_pipes([p for p in nlp.pipe_names if p not in pipeline])
for pipe in pipeline:
if pipe not in nlp.pipe_names:
if pipe == "parser":
pipe_cfg = {"learn_tokens": learn_tokens}
elif pipe == "textcat":
pipe_cfg = {
"exclusive_classes": not textcat_multilabel,
"architecture": textcat_arch,
"positive_label": textcat_positive_label,
}
else:
pipe_cfg = {}
nlp.add_pipe(nlp.create_pipe(pipe, config=pipe_cfg))
else:
if pipe == "textcat":
textcat_cfg = nlp.get_pipe("textcat").cfg
base_cfg = {
"exclusive_classes": textcat_cfg["exclusive_classes"],
"architecture": textcat_cfg["architecture"],
"positive_label": textcat_cfg["positive_label"],
}
pipe_cfg = {
"exclusive_classes": not textcat_multilabel,
"architecture": textcat_arch,
"positive_label": textcat_positive_label,
}
if base_cfg != pipe_cfg:
msg.fail(
"The base textcat model configuration does"
"not match the provided training options. "
"Existing cfg: {}, provided cfg: {}".format(
base_cfg, pipe_cfg),
exits=1,
)
else:
msg.text("Starting with blank model '{}'".format(lang))
lang_cls = util.get_lang_class(lang)
nlp = lang_cls()
for pipe in pipeline:
if pipe == "parser":
pipe_cfg = {"learn_tokens": learn_tokens}
elif pipe == "textcat":
pipe_cfg = {
"exclusive_classes": not textcat_multilabel,
"architecture": textcat_arch,
"positive_label": textcat_positive_label,
}
else:
pipe_cfg = {}
nlp.add_pipe(nlp.create_pipe(pipe, config=pipe_cfg))
if vectors:
msg.text("Loading vector from model '{}'".format(vectors))
_load_vectors(nlp, vectors)
# Multitask objectives
multitask_options = [("parser", parser_multitasks),
("ner", entity_multitasks)]
for pipe_name, multitasks in multitask_options:
if multitasks:
if pipe_name not in pipeline:
msg.fail("Can't use multitask objective without '{}' in the "
"pipeline".format(pipe_name))
pipe = nlp.get_pipe(pipe_name)
for objective in multitasks.split(","):
pipe.add_multitask_objective(objective)
# Prepare training corpus
msg.text("Counting training words (limit={})".format(n_examples))
corpus = GoldCorpus(train_path, dev_path, limit=n_examples)
n_train_words = corpus.count_train()
if base_model:
# Start with an existing model, use default optimizer
optimizer = create_default_optimizer(Model.ops)
else:
# Start with a blank model, call begin_training
optimizer = nlp.begin_training(lambda: corpus.train_tuples,
device=use_gpu)
nlp._optimizer = None
# Load in pretrained weights
if init_tok2vec is not None:
components = _load_pretrained_tok2vec(nlp, init_tok2vec)
msg.text("Loaded pretrained tok2vec for: {}".format(components))
# Verify textcat config
if "textcat" in pipeline:
textcat_labels = nlp.get_pipe("textcat").cfg["labels"]
if textcat_positive_label and textcat_positive_label not in textcat_labels:
msg.fail(
"The textcat_positive_label (tpl) '{}' does not match any "
"label in the training data.".format(textcat_positive_label),
exits=1,
)
if textcat_positive_label and len(textcat_labels) != 2:
msg.fail(
"A textcat_positive_label (tpl) '{}' was provided for training "
"data that does not appear to be a binary classification "
"problem with two labels.".format(textcat_positive_label),
exits=1,
)
train_docs = corpus.train_docs(nlp,
noise_level=noise_level,
gold_preproc=gold_preproc,
max_length=0)
train_labels = set()
if textcat_multilabel:
multilabel_found = False
for text, gold in train_docs:
train_labels.update(gold.cats.keys())
if list(gold.cats.values()).count(1.0) != 1:
multilabel_found = True
if not multilabel_found and not base_model:
msg.warn("The textcat training instances look like they have "
"mutually-exclusive classes. Remove the flag "
"'--textcat-multilabel' to train a classifier with "
"mutually-exclusive classes.")
if not textcat_multilabel:
for text, gold in train_docs:
train_labels.update(gold.cats.keys())
if list(gold.cats.values()).count(1.0) != 1 and not base_model:
msg.warn(
"Some textcat training instances do not have exactly "
"one positive label. Modifying training options to "
"include the flag '--textcat-multilabel' for classes "
"that are not mutually exclusive.")
nlp.get_pipe("textcat").cfg["exclusive_classes"] = False
textcat_multilabel = True
break
if base_model and set(textcat_labels) != train_labels:
msg.fail(
"Cannot extend textcat model using data with different "
"labels. Base model labels: {}, training data labels: "
"{}.".format(textcat_labels, list(train_labels)),
exits=1,
)
if textcat_multilabel:
msg.text(
"Textcat evaluation score: ROC AUC score macro-averaged across "
"the labels '{}'".format(", ".join(textcat_labels)))
elif textcat_positive_label and len(textcat_labels) == 2:
msg.text("Textcat evaluation score: F1-score for the "
"label '{}'".format(textcat_positive_label))
elif len(textcat_labels) > 1:
if len(textcat_labels) == 2:
msg.warn(
"If the textcat component is a binary classifier with "
"exclusive classes, provide '--textcat_positive_label' for "
"an evaluation on the positive class.")
msg.text(
"Textcat evaluation score: F1-score macro-averaged across "
"the labels '{}'".format(", ".join(textcat_labels)))
else:
msg.fail(
"Unsupported textcat configuration. Use `spacy debug-data` "
"for more information.")
# fmt: off
row_head, output_stats = _configure_training_output(
pipeline, use_gpu, has_beam_widths)
row_widths = [len(w) for w in row_head]
row_settings = {
"widths": row_widths,
"aligns": tuple(["r" for i in row_head]),
"spacing": 2
}
# fmt: on
print("")
msg.row(row_head, **row_settings)
msg.row(["-" * width for width in row_settings["widths"]], **row_settings)
try:
iter_since_best = 0
best_score = 0.0
for i in range(n_iter):
train_docs = corpus.train_docs(
nlp,
noise_level=noise_level,
orth_variant_level=orth_variant_level,
gold_preproc=gold_preproc,
max_length=0,
)
if raw_text:
random.shuffle(raw_text)
raw_batches = util.minibatch(
(nlp.make_doc(rt["text"]) for rt in raw_text), size=8)
words_seen = 0
with tqdm.tqdm(total=n_train_words, leave=False) as pbar:
losses = {}
for batch in util.minibatch_by_words(train_docs,
size=batch_sizes):
if not batch:
continue
docs, golds = zip(*batch)
nlp.update(
docs,
golds,
sgd=optimizer,
drop=next(dropout_rates),
losses=losses,
)
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)
if not int(os.environ.get("LOG_FRIENDLY", 0)):
pbar.update(sum(len(doc) for doc in docs))
words_seen += sum(len(doc) for doc in docs)
with nlp.use_params(optimizer.averages):
util.set_env_log(False)
epoch_model_path = output_path / ("model%d" % i)
nlp.to_disk(epoch_model_path)
nlp_loaded = util.load_model_from_path(epoch_model_path)
for beam_width in eval_beam_widths:
for name, component in nlp_loaded.pipeline:
if hasattr(component, "cfg"):
component.cfg["beam_width"] = beam_width
dev_docs = list(
corpus.dev_docs(nlp_loaded, gold_preproc=gold_preproc))
nwords = sum(len(doc_gold[0]) for doc_gold in dev_docs)
start_time = timer()
scorer = nlp_loaded.evaluate(dev_docs, verbose=verbose)
end_time = timer()
if use_gpu < 0:
gpu_wps = None
cpu_wps = nwords / (end_time - start_time)
else:
gpu_wps = nwords / (end_time - start_time)
with Model.use_device("cpu"):
nlp_loaded = util.load_model_from_path(
epoch_model_path)
for name, component in nlp_loaded.pipeline:
if hasattr(component, "cfg"):
component.cfg["beam_width"] = beam_width
dev_docs = list(
corpus.dev_docs(nlp_loaded,
gold_preproc=gold_preproc))
start_time = timer()
scorer = nlp_loaded.evaluate(dev_docs,
verbose=verbose)
end_time = timer()
cpu_wps = nwords / (end_time - start_time)
acc_loc = output_path / ("model%d" % i) / "accuracy.json"
srsly.write_json(acc_loc, scorer.scores)
# Update model meta.json
meta["lang"] = nlp.lang
meta["pipeline"] = nlp.pipe_names
meta["spacy_version"] = ">=%s" % about.__version__
if beam_width == 1:
meta["speed"] = {
"nwords": nwords,
"cpu": cpu_wps,
"gpu": gpu_wps,
}
meta["accuracy"] = scorer.scores
else:
meta.setdefault("beam_accuracy", {})
meta.setdefault("beam_speed", {})
meta["beam_accuracy"][beam_width] = scorer.scores
meta["beam_speed"][beam_width] = {
"nwords": nwords,
"cpu": cpu_wps,
"gpu": gpu_wps,
}
meta["vectors"] = {
"width": nlp.vocab.vectors_length,
"vectors": len(nlp.vocab.vectors),
"keys": nlp.vocab.vectors.n_keys,
"name": nlp.vocab.vectors.name,
}
meta.setdefault("name", "model%d" % i)
meta.setdefault("version", version)
meta["labels"] = nlp.meta["labels"]
meta_loc = output_path / ("model%d" % i) / "meta.json"
srsly.write_json(meta_loc, meta)
util.set_env_log(verbose)
progress = _get_progress(
i,
losses,
scorer.scores,
output_stats,
beam_width=beam_width if has_beam_widths else None,
cpu_wps=cpu_wps,
gpu_wps=gpu_wps,
)
if i == 0 and "textcat" in pipeline:
textcats_per_cat = scorer.scores.get(
"textcats_per_cat", {})
for cat, cat_score in textcats_per_cat.items():
if cat_score.get("roc_auc_score", 0) < 0:
msg.warn(
"Textcat ROC AUC score is undefined due to "
"only one value in label '{}'.".format(
cat))
msg.row(progress, **row_settings)
# Early stopping
if n_early_stopping is not None:
current_score = _score_for_model(meta)
if current_score < best_score:
iter_since_best += 1
else:
iter_since_best = 0
best_score = current_score
if iter_since_best >= n_early_stopping:
msg.text("Early stopping, best iteration "
"is: {}".format(i - iter_since_best))
msg.text("Best score = {}; Final iteration "
"score = {}".format(best_score,
current_score))
break
finally:
with nlp.use_params(optimizer.averages):
final_model_path = output_path / "model-final"
nlp.to_disk(final_model_path)
msg.good("Saved model to output directory", final_model_path)
with msg.loading("Creating best model..."):
best_model_path = _collate_best_model(meta, output_path,
nlp.pipe_names)
msg.good("Created best model", best_model_path)
def debug_data(
lang,
train_path,
dev_path,
base_model=None,
pipeline="tagger,parser,ner",
ignore_warnings=False,
ignore_validation=False,
verbose=False,
no_format=False,
):
msg = Printer(pretty=not no_format, ignore_warnings=ignore_warnings)
# Make sure all files and paths exists if they are needed
if not train_path.exists():
msg.fail("Training data not found", train_path, exits=1)
if not dev_path.exists():
msg.fail("Development data not found", dev_path, exits=1)
# Initialize the model and pipeline
pipeline = [p.strip() for p in pipeline.split(",")]
if base_model:
nlp = load_model(base_model)
else:
lang_cls = get_lang_class(lang)
nlp = lang_cls()
msg.divider("Data format validation")
# Load the data in one – might take a while but okay in this case
train_data = _load_file(train_path, msg)
dev_data = _load_file(dev_path, msg)
# Validate data format using the JSON schema
# TODO: update once the new format is ready
train_data_errors = [] # TODO: validate_json
dev_data_errors = [] # TODO: validate_json
if not train_data_errors:
msg.good("Training data JSON format is valid")
if not dev_data_errors:
msg.good("Development data JSON format is valid")
for error in train_data_errors:
msg.fail("Training data: {}".format(error))
for error in dev_data_errors:
msg.fail("Develoment data: {}".format(error))
if (train_data_errors or dev_data_errors) and not ignore_validation:
sys.exit(1)
# Create the gold corpus to be able to better analyze data
with msg.loading("Analyzing corpus..."):
train_data = read_json_object(train_data)
dev_data = read_json_object(dev_data)
corpus = GoldCorpus(train_data, dev_data)
train_docs = list(corpus.train_docs(nlp))
dev_docs = list(corpus.dev_docs(nlp))
msg.good("Corpus is loadable")
# Create all gold data here to avoid iterating over the train_docs constantly
gold_data = _compile_gold(train_docs, pipeline)
train_texts = gold_data["texts"]
dev_texts = set([doc.text for doc, gold in dev_docs])
msg.divider("Training stats")
msg.text("Training pipeline: {}".format(", ".join(pipeline)))
for pipe in [p for p in pipeline if p not in nlp.factories]:
msg.fail("Pipeline component '{}' not available in factories".format(pipe))
if base_model:
msg.text("Starting with base model '{}'".format(base_model))
else:
msg.text("Starting with blank model '{}'".format(lang))
msg.text("{} training docs".format(len(train_docs)))
msg.text("{} evaluation docs".format(len(dev_docs)))
overlap = len(train_texts.intersection(dev_texts))
if overlap:
msg.warn("{} training examples also in evaluation data".format(overlap))
else:
msg.good("No overlap between training and evaluation data")
if not base_model and len(train_docs) < BLANK_MODEL_THRESHOLD:
text = "Low number of examples to train from a blank model ({})".format(
len(train_docs)
)
if len(train_docs) < BLANK_MODEL_MIN_THRESHOLD:
msg.fail(text)
else:
msg.warn(text)
msg.text(
"It's recommended to use at least {} examples (minimum {})".format(
BLANK_MODEL_THRESHOLD, BLANK_MODEL_MIN_THRESHOLD
),
show=verbose,
)
msg.divider("Vocab & Vectors")
n_words = gold_data["n_words"]
msg.info(
"{} total {} in the data ({} unique)".format(
n_words, "word" if n_words == 1 else "words", len(gold_data["words"])
)
)
most_common_words = gold_data["words"].most_common(10)
msg.text(
"10 most common words: {}".format(
_format_labels(most_common_words, counts=True)
),
show=verbose,
)
if len(nlp.vocab.vectors):
msg.info(
"{} vectors ({} unique keys, {} dimensions)".format(
len(nlp.vocab.vectors),
nlp.vocab.vectors.n_keys,
nlp.vocab.vectors_length,
)
)
else:
msg.info("No word vectors present in the model")
if "ner" in pipeline:
# Get all unique NER labels present in the data
labels = set(label for label in gold_data["ner"] if label not in ("O", "-"))
label_counts = gold_data["ner"]
model_labels = _get_labels_from_model(nlp, "ner")
new_labels = [l for l in labels if l not in model_labels]
existing_labels = [l for l in labels if l in model_labels]
has_low_data_warning = False
has_no_neg_warning = False
has_ws_ents_error = False
msg.divider("Named Entity Recognition")
msg.info(
"{} new {}, {} existing {}".format(
len(new_labels),
"label" if len(new_labels) == 1 else "labels",
len(existing_labels),
"label" if len(existing_labels) == 1 else "labels",
)
)
missing_values = label_counts["-"]
msg.text(
"{} missing {} (tokens with '-' label)".format(
missing_values, "value" if missing_values == 1 else "values"
)
)
if new_labels:
labels_with_counts = [
(label, count)
for label, count in label_counts.most_common()
if label != "-"
]
labels_with_counts = _format_labels(labels_with_counts, counts=True)
msg.text("New: {}".format(labels_with_counts), show=verbose)
if existing_labels:
msg.text(
"Existing: {}".format(_format_labels(existing_labels)), show=verbose
)
if gold_data["ws_ents"]:
msg.fail("{} invalid whitespace entity spans".format(gold_data["ws_ents"]))
has_ws_ents_error = True
for label in new_labels:
if label_counts[label] <= NEW_LABEL_THRESHOLD:
msg.warn(
"Low number of examples for new label '{}' ({})".format(
label, label_counts[label]
)
)
has_low_data_warning = True
with msg.loading("Analyzing label distribution..."):
neg_docs = _get_examples_without_label(train_docs, label)
if neg_docs == 0:
msg.warn(
"No examples for texts WITHOUT new label '{}'".format(label)
)
has_no_neg_warning = True
if not has_low_data_warning:
msg.good("Good amount of examples for all labels")
if not has_no_neg_warning:
msg.good("Examples without occurences available for all labels")
if not has_ws_ents_error:
msg.good("No entities consisting of or starting/ending with whitespace")
if has_low_data_warning:
msg.text(
"To train a new entity type, your data should include at "
"least {} insteances of the new label".format(NEW_LABEL_THRESHOLD),
show=verbose,
)
if has_no_neg_warning:
msg.text(
"Training data should always include examples of entities "
"in context, as well as examples without a given entity "
"type.",
show=verbose,
)
if has_ws_ents_error:
msg.text(
"As of spaCy v2.1.0, entity spans consisting of or starting/ending "
"with whitespace characters are considered invalid."
)
if "textcat" in pipeline:
msg.divider("Text Classification")
labels = [label for label in gold_data["textcat"]]
model_labels = _get_labels_from_model(nlp, "textcat")
new_labels = [l for l in labels if l not in model_labels]
existing_labels = [l for l in labels if l in model_labels]
msg.info(
"Text Classification: {} new label(s), {} existing label(s)".format(
len(new_labels), len(existing_labels)
)
)
if new_labels:
labels_with_counts = _format_labels(
gold_data["textcat"].most_common(), counts=True
)
msg.text("New: {}".format(labels_with_counts), show=verbose)
if existing_labels:
msg.text(
"Existing: {}".format(_format_labels(existing_labels)), show=verbose
)
if "tagger" in pipeline:
msg.divider("Part-of-speech Tagging")
labels = [label for label in gold_data["tags"]]
tag_map = nlp.Defaults.tag_map
msg.info(
"{} {} in data ({} {} in tag map)".format(
len(labels),
"label" if len(labels) == 1 else "labels",
len(tag_map),
"label" if len(tag_map) == 1 else "labels",
)
)
labels_with_counts = _format_labels(
gold_data["tags"].most_common(), counts=True
)
msg.text(labels_with_counts, show=verbose)
non_tagmap = [l for l in labels if l not in tag_map]
if not non_tagmap:
msg.good("All labels present in tag map for language '{}'".format(nlp.lang))
for label in non_tagmap:
msg.fail(
"Label '{}' not found in tag map for language '{}'".format(
label, nlp.lang
)
)
if "parser" in pipeline:
msg.divider("Dependency Parsing")
labels = [label for label in gold_data["deps"]]
msg.info(
"{} {} in data".format(
len(labels), "label" if len(labels) == 1 else "labels"
)
)
labels_with_counts = _format_labels(
gold_data["deps"].most_common(), counts=True
)
msg.text(labels_with_counts, show=verbose)
msg.divider("Summary")
good_counts = msg.counts[MESSAGES.GOOD]
warn_counts = msg.counts[MESSAGES.WARN]
fail_counts = msg.counts[MESSAGES.FAIL]
if good_counts:
msg.good(
"{} {} passed".format(
good_counts, "check" if good_counts == 1 else "checks"
)
)
if warn_counts:
msg.warn(
"{} {}".format(warn_counts, "warning" if warn_counts == 1 else "warnings")
)
if fail_counts:
msg.fail("{} {}".format(fail_counts, "error" if fail_counts == 1 else "errors"))
if fail_counts:
sys.exit(1)
def validate():
"""
Validate that the currently installed version of spaCy is compatible
with the installed models. Should be run after `pip install -U spacy`.
"""
msg = Printer()
with msg.loading("Loading compatibility table..."):
r = requests.get(about.__compatibility__)
if r.status_code != 200:
msg.fail(
"Server error ({})".format(r.status_code),
"Couldn't fetch compatibility table.",
exits=1,
)
msg.good("Loaded compatibility table")
compat = r.json()["spacy"]
version = about.__version__
version = version.rsplit(".dev", 1)[0]
current_compat = compat.get(version)
if not current_compat:
msg.fail(
"Can't find spaCy v{} in compatibility table".format(version),
about.__compatibility__,
exits=1,
)
all_models = set()
for spacy_v, models in dict(compat).items():
all_models.update(models.keys())
for model, model_vs in models.items():
compat[spacy_v][model] = [reformat_version(v) for v in model_vs]
model_links = get_model_links(current_compat)
model_pkgs = get_model_pkgs(current_compat, all_models)
incompat_links = {l for l, d in model_links.items() if not d["compat"]}
incompat_models = {d["name"] for _, d in model_pkgs.items() if not d["compat"]}
incompat_models.update(
[d["name"] for _, d in model_links.items() if not d["compat"]]
)
na_models = [m for m in incompat_models if m not in current_compat]
update_models = [m for m in incompat_models if m in current_compat]
spacy_dir = Path(__file__).parent.parent
msg.divider("Installed models (spaCy v{})".format(about.__version__))
msg.info("spaCy installation: {}".format(path2str(spacy_dir)))
if model_links or model_pkgs:
header = ("TYPE", "NAME", "MODEL", "VERSION", "")
rows = []
for name, data in model_pkgs.items():
rows.append(get_model_row(current_compat, name, data, msg))
for name, data in model_links.items():
rows.append(get_model_row(current_compat, name, data, msg, "link"))
msg.table(rows, header=header)
else:
msg.text("No models found in your current environment.", exits=0)
if update_models:
msg.divider("Install updates")
msg.text("Use the following commands to update the model packages:")
cmd = "python -m spacy download {}"
print("\n".join([cmd.format(pkg) for pkg in update_models]) + "\n")
if na_models:
msg.text(
"The following models are not available for spaCy "
"v{}: {}".format(about.__version__, ", ".join(na_models))
)
if incompat_links:
msg.text(
"You may also want to overwrite the incompatible links using the "
"`python -m spacy link` command with `--force`, or remove them "
"from the data directory. "
"Data path: {path}".format(path=path2str(get_data_path()))
)
if incompat_models or incompat_links:
sys.exit(1)
import numpy as np
from tqdm import tqdm
from typer import Option, Typer
from wasabi import Printer
from src.elastic import ES
from src.lsh_encoder import LSHEncoder
msg = Printer()
es = ES()
msg.warn("loading features and ids...")
feature_vectors = np.load("/data/feature_vectors.npy")
document_ids = np.load("/data/ids.npy")
msg.good("data loaded successfully")
# populate exact index with dense vectors
msg.warn("indexing exact features...")
def gendata_exact(document_ids, feature_vectors):
loop = tqdm(
zip(document_ids, feature_vectors),
total=len(document_ids)
)
for (document_id, feature_vector) in loop:
features_1, features_2 = feature_vector.reshape(2, 2048)
yield {
"_index": "feature_vectors",
"_id": document_id,
def pretrain(
texts_loc,
vectors_model,
output_dir,
width=96,
depth=4,
embed_rows=2000,
loss_func="cosine",
use_vectors=False,
dropout=0.2,
n_iter=1000,
batch_size=3000,
max_length=500,
min_length=5,
seed=0,
n_save_every=None,
):
"""
Pre-train the 'token-to-vector' (tok2vec) layer of pipeline components,
using an approximate language-modelling objective. Specifically, we load
pre-trained vectors, and train a component like a CNN, BiLSTM, etc to predict
vectors which match the pre-trained ones. The weights are saved to a directory
after each epoch. You can then pass a path to one of these pre-trained weights
files to the 'spacy train' command.
This technique may be especially helpful if you have little labelled data.
However, it's still quite experimental, so your mileage may vary.
To load the weights back in during 'spacy train', you need to ensure
all settings are the same between pretraining and training. The API and
errors around this need some improvement.
"""
config = dict(locals())
msg = Printer()
util.fix_random_seed(seed)
has_gpu = prefer_gpu()
msg.info("Using GPU" if has_gpu else "Not using GPU")
output_dir = Path(output_dir)
if not output_dir.exists():
output_dir.mkdir()
msg.good("Created output directory")
srsly.write_json(output_dir / "config.json", config)
msg.good("Saved settings to config.json")
# Load texts from file or stdin
if texts_loc != "-": # reading from a file
texts_loc = Path(texts_loc)
if not texts_loc.exists():
msg.fail("Input text file doesn't exist", texts_loc, exits=1)
with msg.loading("Loading input texts..."):
texts = list(srsly.read_jsonl(texts_loc))
msg.good("Loaded input texts")
random.shuffle(texts)
else: # reading from stdin
msg.text("Reading input text from stdin...")
texts = srsly.read_jsonl("-")
with msg.loading("Loading model '{}'...".format(vectors_model)):
nlp = util.load_model(vectors_model)
msg.good("Loaded model '{}'".format(vectors_model))
pretrained_vectors = None if not use_vectors else nlp.vocab.vectors.name
model = create_pretraining_model(
nlp,
Tok2Vec(
width,
embed_rows,
conv_depth=depth,
pretrained_vectors=pretrained_vectors,
bilstm_depth=0, # Requires PyTorch. Experimental.
cnn_maxout_pieces=3, # You can try setting this higher
subword_features=True, # Set to False for Chinese etc
),
)
optimizer = create_default_optimizer(model.ops)
tracker = ProgressTracker(frequency=10000)
msg.divider("Pre-training tok2vec layer")
row_settings = {"widths": (3, 10, 10, 6, 4), "aligns": ("r", "r", "r", "r", "r")}
msg.row(("#", "# Words", "Total Loss", "Loss", "w/s"), **row_settings)
def _save_model(epoch, is_temp=False):
is_temp_str = ".temp" if is_temp else ""
with model.use_params(optimizer.averages):
with (output_dir / ("model%d%s.bin" % (epoch, is_temp_str))).open(
"wb"
) as file_:
file_.write(model.tok2vec.to_bytes())
log = {
"nr_word": tracker.nr_word,
"loss": tracker.loss,
"epoch_loss": tracker.epoch_loss,
"epoch": epoch,
}
with (output_dir / "log.jsonl").open("a") as file_:
file_.write(srsly.json_dumps(log) + "\n")
for epoch in range(n_iter):
for batch_id, batch in enumerate(
util.minibatch_by_words(((text, None) for text in texts), size=batch_size)
):
docs = make_docs(
nlp,
[text for (text, _) in batch],
max_length=max_length,
min_length=min_length,
)
loss = make_update(
model, docs, optimizer, objective=loss_func, drop=dropout
)
progress = tracker.update(epoch, loss, docs)
if progress:
msg.row(progress, **row_settings)
if texts_loc == "-" and tracker.words_per_epoch[epoch] >= 10 ** 7:
break
if n_save_every and (batch_id % n_save_every == 0):
_save_model(epoch, is_temp=True)
_save_model(epoch)
tracker.epoch_loss = 0.0
if texts_loc != "-":
# Reshuffle the texts if texts were loaded from a file
random.shuffle(texts)
def pretrain(
texts_loc,
vectors_model,
output_dir,
width=96,
depth=4,
embed_rows=2000,
loss_func="cosine",
use_vectors=False,
dropout=0.2,
n_iter=1000,
batch_size=3000,
max_length=500,
min_length=5,
seed=0,
n_save_every=None,
):
"""
Pre-train the 'token-to-vector' (tok2vec) layer of pipeline components,
using an approximate language-modelling objective. Specifically, we load
pre-trained vectors, and train a component like a CNN, BiLSTM, etc to predict
vectors which match the pre-trained ones. The weights are saved to a directory
after each epoch. You can then pass a path to one of these pre-trained weights
files to the 'spacy train' command.
This technique may be especially helpful if you have little labelled data.
However, it's still quite experimental, so your mileage may vary.
To load the weights back in during 'spacy train', you need to ensure
all settings are the same between pretraining and training. The API and
errors around this need some improvement.
"""
config = dict(locals())
msg = Printer()
util.fix_random_seed(seed)
has_gpu = prefer_gpu()
msg.info("Using GPU" if has_gpu else "Not using GPU")
output_dir = Path(output_dir)
if not output_dir.exists():
output_dir.mkdir()
msg.good("Created output directory")
srsly.write_json(output_dir / "config.json", config)
msg.good("Saved settings to config.json")
# Load texts from file or stdin
if texts_loc != "-": # reading from a file
texts_loc = Path(texts_loc)
if not texts_loc.exists():
msg.fail("Input text file doesn't exist", texts_loc, exits=1)
with msg.loading("Loading input texts..."):
texts = list(srsly.read_jsonl(texts_loc))
msg.good("Loaded input texts")
random.shuffle(texts)
else: # reading from stdin
msg.text("Reading input text from stdin...")
texts = srsly.read_jsonl("-")
with msg.loading("Loading model '{}'...".format(vectors_model)):
nlp = util.load_model(vectors_model)
msg.good("Loaded model '{}'".format(vectors_model))
pretrained_vectors = None if not use_vectors else nlp.vocab.vectors.name
model = create_pretraining_model(
nlp,
Tok2Vec(
width,
embed_rows,
conv_depth=depth,
pretrained_vectors=pretrained_vectors,
bilstm_depth=0, # Requires PyTorch. Experimental.
cnn_maxout_pieces=3, # You can try setting this higher
subword_features=True, # Set to False for Chinese etc
),
)
optimizer = create_default_optimizer(model.ops)
tracker = ProgressTracker(frequency=10000)
msg.divider("Pre-training tok2vec layer")
row_settings = {
"widths": (3, 10, 10, 6, 4),
"aligns": ("r", "r", "r", "r", "r")
}
msg.row(("#", "# Words", "Total Loss", "Loss", "w/s"), **row_settings)
def _save_model(epoch, is_temp=False):
is_temp_str = ".temp" if is_temp else ""
with model.use_params(optimizer.averages):
with (output_dir / ("model%d%s.bin" %
(epoch, is_temp_str))).open("wb") as file_:
file_.write(model.tok2vec.to_bytes())
log = {
"nr_word": tracker.nr_word,
"loss": tracker.loss,
"epoch_loss": tracker.epoch_loss,
"epoch": epoch,
}
with (output_dir / "log.jsonl").open("a") as file_:
file_.write(srsly.json_dumps(log) + "\n")
for epoch in range(n_iter):
for batch_id, batch in enumerate(
util.minibatch_by_words(((text, None) for text in texts),
size=batch_size)):
docs = make_docs(
nlp,
[text for (text, _) in batch],
max_length=max_length,
min_length=min_length,
)
loss = make_update(model,
docs,
optimizer,
objective=loss_func,
drop=dropout)
progress = tracker.update(epoch, loss, docs)
if progress:
msg.row(progress, **row_settings)
if texts_loc == "-" and tracker.words_per_epoch[epoch] >= 10**7:
break
if n_save_every and (batch_id % n_save_every == 0):
_save_model(epoch, is_temp=True)
_save_model(epoch)
tracker.epoch_loss = 0.0
if texts_loc != "-":
# Reshuffle the texts if texts were loaded from a file
random.shuffle(texts)
def evaluate(
model: str,
data_path: Path,
output: Optional[Path] = None,
use_gpu: int = -1,
gold_preproc: bool = False,
displacy_path: Optional[Path] = None,
displacy_limit: int = 25,
silent: bool = True,
spans_key: str = "sc",
) -> Dict[str, Any]:
msg = Printer(no_print=silent, pretty=not silent)
fix_random_seed()
setup_gpu(use_gpu, silent=silent)
data_path = util.ensure_path(data_path)
output_path = util.ensure_path(output)
displacy_path = util.ensure_path(displacy_path)
if not data_path.exists():
msg.fail("Evaluation data not found", data_path, exits=1)
if displacy_path and not displacy_path.exists():
msg.fail("Visualization output directory not found", displacy_path, exits=1)
corpus = Corpus(data_path, gold_preproc=gold_preproc)
nlp = util.load_model(model)
dev_dataset = list(corpus(nlp))
scores = nlp.evaluate(dev_dataset)
metrics = {
"TOK": "token_acc",
"TAG": "tag_acc",
"POS": "pos_acc",
"MORPH": "morph_acc",
"LEMMA": "lemma_acc",
"UAS": "dep_uas",
"LAS": "dep_las",
"NER P": "ents_p",
"NER R": "ents_r",
"NER F": "ents_f",
"TEXTCAT": "cats_score",
"SENT P": "sents_p",
"SENT R": "sents_r",
"SENT F": "sents_f",
"SPAN P": f"spans_{spans_key}_p",
"SPAN R": f"spans_{spans_key}_r",
"SPAN F": f"spans_{spans_key}_f",
"SPEED": "speed",
}
results = {}
data = {}
for metric, key in metrics.items():
if key in scores:
if key == "cats_score":
metric = metric + " (" + scores.get("cats_score_desc", "unk") + ")"
if isinstance(scores[key], (int, float)):
if key == "speed":
results[metric] = f"{scores[key]:.0f}"
else:
results[metric] = f"{scores[key]*100:.2f}"
else:
results[metric] = "-"
data[re.sub(r"[\s/]", "_", key.lower())] = scores[key]
msg.table(results, title="Results")
data = handle_scores_per_type(scores, data, spans_key=spans_key, silent=silent)
if displacy_path:
factory_names = [nlp.get_pipe_meta(pipe).factory for pipe in nlp.pipe_names]
docs = list(nlp.pipe(ex.reference.text for ex in dev_dataset[:displacy_limit]))
render_deps = "parser" in factory_names
render_ents = "ner" in factory_names
render_parses(
docs,
displacy_path,
model_name=model,
limit=displacy_limit,
deps=render_deps,
ents=render_ents,
)
msg.good(f"Generated {displacy_limit} parses as HTML", displacy_path)
if output_path is not None:
srsly.write_json(output_path, data)
msg.good(f"Saved results to {output_path}")
return data
def debug_data(
lang,
train_path,
dev_path,
base_model=None,
pipeline="tagger,parser,ner",
ignore_warnings=False,
ignore_validation=False,
verbose=False,
no_format=False,
):
msg = Printer(pretty=not no_format, ignore_warnings=ignore_warnings)
# Make sure all files and paths exists if they are needed
if not train_path.exists():
msg.fail("Training data not found", train_path, exits=1)
if not dev_path.exists():
msg.fail("Development data not found", dev_path, exits=1)
# Initialize the model and pipeline
pipeline = [p.strip() for p in pipeline.split(",")]
if base_model:
nlp = load_model(base_model)
else:
lang_cls = get_lang_class(lang)
nlp = lang_cls()
msg.divider("Data format validation")
# Validate data format using the JSON schema
# TODO: update once the new format is ready
# TODO: move validation to GoldCorpus in order to be able to load from dir
train_data_errors = [] # TODO: validate_json
dev_data_errors = [] # TODO: validate_json
if not train_data_errors:
msg.good("Training data JSON format is valid")
if not dev_data_errors:
msg.good("Development data JSON format is valid")
for error in train_data_errors:
msg.fail("Training data: {}".format(error))
for error in dev_data_errors:
msg.fail("Develoment data: {}".format(error))
if (train_data_errors or dev_data_errors) and not ignore_validation:
sys.exit(1)
# Create the gold corpus to be able to better analyze data
loading_train_error_message = ""
loading_dev_error_message = ""
with msg.loading("Loading corpus..."):
corpus = GoldCorpus(train_path, dev_path)
try:
train_docs = list(corpus.train_docs(nlp))
train_docs_unpreprocessed = list(
corpus.train_docs_without_preprocessing(nlp))
except ValueError as e:
loading_train_error_message = "Training data cannot be loaded: {}".format(
str(e))
try:
dev_docs = list(corpus.dev_docs(nlp))
except ValueError as e:
loading_dev_error_message = "Development data cannot be loaded: {}".format(
str(e))
if loading_train_error_message or loading_dev_error_message:
if loading_train_error_message:
msg.fail(loading_train_error_message)
if loading_dev_error_message:
msg.fail(loading_dev_error_message)
sys.exit(1)
msg.good("Corpus is loadable")
# Create all gold data here to avoid iterating over the train_docs constantly
gold_train_data = _compile_gold(train_docs, pipeline)
gold_train_unpreprocessed_data = _compile_gold(train_docs_unpreprocessed,
pipeline)
gold_dev_data = _compile_gold(dev_docs, pipeline)
train_texts = gold_train_data["texts"]
dev_texts = gold_dev_data["texts"]
msg.divider("Training stats")
msg.text("Training pipeline: {}".format(", ".join(pipeline)))
for pipe in [p for p in pipeline if p not in nlp.factories]:
msg.fail(
"Pipeline component '{}' not available in factories".format(pipe))
if base_model:
msg.text("Starting with base model '{}'".format(base_model))
else:
msg.text("Starting with blank model '{}'".format(lang))
msg.text("{} training docs".format(len(train_docs)))
msg.text("{} evaluation docs".format(len(dev_docs)))
overlap = len(train_texts.intersection(dev_texts))
if overlap:
msg.warn(
"{} training examples also in evaluation data".format(overlap))
else:
msg.good("No overlap between training and evaluation data")
if not base_model and len(train_docs) < BLANK_MODEL_THRESHOLD:
text = "Low number of examples to train from a blank model ({})".format(
len(train_docs))
if len(train_docs) < BLANK_MODEL_MIN_THRESHOLD:
msg.fail(text)
else:
msg.warn(text)
msg.text(
"It's recommended to use at least {} examples (minimum {})".format(
BLANK_MODEL_THRESHOLD, BLANK_MODEL_MIN_THRESHOLD),
show=verbose,
)
msg.divider("Vocab & Vectors")
n_words = gold_train_data["n_words"]
msg.info("{} total {} in the data ({} unique)".format(
n_words, "word" if n_words == 1 else "words",
len(gold_train_data["words"])))
if gold_train_data["n_misaligned_words"] > 0:
msg.warn("{} misaligned tokens in the training data".format(
gold_train_data["n_misaligned_words"]))
if gold_dev_data["n_misaligned_words"] > 0:
msg.warn("{} misaligned tokens in the dev data".format(
gold_dev_data["n_misaligned_words"]))
most_common_words = gold_train_data["words"].most_common(10)
msg.text(
"10 most common words: {}".format(
_format_labels(most_common_words, counts=True)),
show=verbose,
)
if len(nlp.vocab.vectors):
msg.info("{} vectors ({} unique keys, {} dimensions)".format(
len(nlp.vocab.vectors),
nlp.vocab.vectors.n_keys,
nlp.vocab.vectors_length,
))
else:
msg.info("No word vectors present in the model")
if "ner" in pipeline:
# Get all unique NER labels present in the data
labels = set(label for label in gold_train_data["ner"]
if label not in ("O", "-"))
label_counts = gold_train_data["ner"]
model_labels = _get_labels_from_model(nlp, "ner")
new_labels = [l for l in labels if l not in model_labels]
existing_labels = [l for l in labels if l in model_labels]
has_low_data_warning = False
has_no_neg_warning = False
has_ws_ents_error = False
msg.divider("Named Entity Recognition")
msg.info("{} new {}, {} existing {}".format(
len(new_labels),
"label" if len(new_labels) == 1 else "labels",
len(existing_labels),
"label" if len(existing_labels) == 1 else "labels",
))
missing_values = label_counts["-"]
msg.text("{} missing {} (tokens with '-' label)".format(
missing_values, "value" if missing_values == 1 else "values"))
if new_labels:
labels_with_counts = [
(label, count) for label, count in label_counts.most_common()
if label != "-"
]
labels_with_counts = _format_labels(labels_with_counts,
counts=True)
msg.text("New: {}".format(labels_with_counts), show=verbose)
if existing_labels:
msg.text("Existing: {}".format(_format_labels(existing_labels)),
show=verbose)
if gold_train_data["ws_ents"]:
msg.fail("{} invalid whitespace entity spans".format(
gold_train_data["ws_ents"]))
has_ws_ents_error = True
for label in new_labels:
if label_counts[label] <= NEW_LABEL_THRESHOLD:
msg.warn(
"Low number of examples for new label '{}' ({})".format(
label, label_counts[label]))
has_low_data_warning = True
with msg.loading("Analyzing label distribution..."):
neg_docs = _get_examples_without_label(train_docs, label)
if neg_docs == 0:
msg.warn(
"No examples for texts WITHOUT new label '{}'".format(
label))
has_no_neg_warning = True
if not has_low_data_warning:
msg.good("Good amount of examples for all labels")
if not has_no_neg_warning:
msg.good("Examples without occurrences available for all labels")
if not has_ws_ents_error:
msg.good(
"No entities consisting of or starting/ending with whitespace")
if has_low_data_warning:
msg.text(
"To train a new entity type, your data should include at "
"least {} instances of the new label".format(
NEW_LABEL_THRESHOLD),
show=verbose,
)
if has_no_neg_warning:
msg.text(
"Training data should always include examples of entities "
"in context, as well as examples without a given entity "
"type.",
show=verbose,
)
if has_ws_ents_error:
msg.text(
"As of spaCy v2.1.0, entity spans consisting of or starting/ending "
"with whitespace characters are considered invalid.")
if "textcat" in pipeline:
msg.divider("Text Classification")
labels = [label for label in gold_train_data["textcat"]]
model_labels = _get_labels_from_model(nlp, "textcat")
new_labels = [l for l in labels if l not in model_labels]
existing_labels = [l for l in labels if l in model_labels]
msg.info("Text Classification: {} new label(s), {} existing label(s)".
format(len(new_labels), len(existing_labels)))
if new_labels:
labels_with_counts = _format_labels(
gold_train_data["textcat"].most_common(), counts=True)
msg.text("New: {}".format(labels_with_counts), show=verbose)
if existing_labels:
msg.text("Existing: {}".format(_format_labels(existing_labels)),
show=verbose)
if "tagger" in pipeline:
msg.divider("Part-of-speech Tagging")
labels = [label for label in gold_train_data["tags"]]
tag_map = nlp.Defaults.tag_map
msg.info("{} {} in data ({} {} in tag map)".format(
len(labels),
"label" if len(labels) == 1 else "labels",
len(tag_map),
"label" if len(tag_map) == 1 else "labels",
))
labels_with_counts = _format_labels(
gold_train_data["tags"].most_common(), counts=True)
msg.text(labels_with_counts, show=verbose)
non_tagmap = [l for l in labels if l not in tag_map]
if not non_tagmap:
msg.good("All labels present in tag map for language '{}'".format(
nlp.lang))
for label in non_tagmap:
msg.fail(
"Label '{}' not found in tag map for language '{}'".format(
label, nlp.lang))
if "parser" in pipeline:
msg.divider("Dependency Parsing")
# profile sentence length
msg.info("Found {} sentence{} with an average length of {:.1f} words.".
format(
gold_train_data["n_sents"],
"s" if len(train_docs) > 1 else "",
gold_train_data["n_words"] / gold_train_data["n_sents"]))
# profile labels
labels_train = [label for label in gold_train_data["deps"]]
labels_train_unpreprocessed = [
label for label in gold_train_unpreprocessed_data["deps"]
]
labels_dev = [label for label in gold_dev_data["deps"]]
if gold_train_unpreprocessed_data["n_nonproj"] > 0:
msg.info("Found {} nonprojective train sentence{}".format(
gold_train_unpreprocessed_data["n_nonproj"], "s"
if gold_train_unpreprocessed_data["n_nonproj"] > 1 else ""))
if gold_dev_data["n_nonproj"] > 0:
msg.info("Found {} nonprojective dev sentence{}".format(
gold_dev_data["n_nonproj"],
"s" if gold_dev_data["n_nonproj"] > 1 else ""))
msg.info("{} {} in train data".format(
len(labels_train_unpreprocessed),
"label" if len(labels_train) == 1 else "labels"))
msg.info("{} {} in projectivized train data".format(
len(labels_train),
"label" if len(labels_train) == 1 else "labels"))
labels_with_counts = _format_labels(
gold_train_unpreprocessed_data["deps"].most_common(), counts=True)
msg.text(labels_with_counts, show=verbose)
# rare labels in train
for label in gold_train_unpreprocessed_data["deps"]:
if gold_train_unpreprocessed_data["deps"][
label] <= DEP_LABEL_THRESHOLD:
msg.warn("Low number of examples for label '{}' ({})".format(
label, gold_train_unpreprocessed_data["deps"][label]))
has_low_data_warning = True
# rare labels in projectivized train
rare_projectivized_labels = []
for label in gold_train_data["deps"]:
if gold_train_data["deps"][
label] <= DEP_LABEL_THRESHOLD and "||" in label:
rare_projectivized_labels.append("{}: {}".format(
label, str(gold_train_data["deps"][label])))
if len(rare_projectivized_labels) > 0:
msg.warn(
"Low number of examples for {} label{} in the "
"projectivized dependency trees used for training. You may "
"want to projectivize labels such as punct before "
"training in order to improve parser performance.".format(
len(rare_projectivized_labels),
"s" if len(rare_projectivized_labels) > 1 else ""))
msg.warn("Projectivized labels with low numbers of examples: "
"{}".format("\n".join(rare_projectivized_labels)),
show=verbose)
has_low_data_warning = True
# labels only in train
if set(labels_train) - set(labels_dev):
msg.warn("The following labels were found only in the train data: "
"{}".format(
", ".join(set(labels_train) - set(labels_dev))),
show=verbose)
# labels only in dev
if set(labels_dev) - set(labels_train):
msg.warn("The following labels were found only in the dev data: " +
", ".join(set(labels_dev) - set(labels_train)),
show=verbose)
if has_low_data_warning:
msg.text(
"To train a parser, your data should include at "
"least {} instances of each label.".format(
DEP_LABEL_THRESHOLD),
show=verbose,
)
# multiple root labels
if len(gold_train_unpreprocessed_data["roots"]) > 1:
msg.warn(
"Multiple root labels ({}) ".format(", ".join(
gold_train_unpreprocessed_data["roots"])) +
"found in training data. spaCy's parser uses a single root "
"label ROOT so this distinction will not be available.")
# these should not happen, but just in case
if gold_train_data["n_nonproj"] > 0:
msg.fail(
"Found {} nonprojective projectivized train sentence{}".format(
gold_train_data["n_nonproj"],
"s" if gold_train_data["n_nonproj"] > 1 else ""))
if gold_train_data["n_cycles"] > 0:
msg.fail(
"Found {} projectivized train sentence{} with cycles".format(
gold_train_data["n_cycles"],
"s" if gold_train_data["n_cycles"] > 1 else ""))
msg.divider("Summary")
good_counts = msg.counts[MESSAGES.GOOD]
warn_counts = msg.counts[MESSAGES.WARN]
fail_counts = msg.counts[MESSAGES.FAIL]
if good_counts:
msg.good("{} {} passed".format(
good_counts, "check" if good_counts == 1 else "checks"))
if warn_counts:
msg.warn("{} {}".format(warn_counts,
"warning" if warn_counts == 1 else "warnings"))
if fail_counts:
msg.fail("{} {}".format(fail_counts,
"error" if fail_counts == 1 else "errors"))
if fail_counts:
sys.exit(1)
def train(
nlp: "Language",
output_path: Optional[Path] = None,
*,
use_gpu: int = -1,
stdout: IO = sys.stdout,
stderr: IO = sys.stderr,
) -> Tuple["Language", Optional[Path]]:
"""Train a pipeline.
nlp (Language): The initialized nlp object with the full config.
output_path (Path): Optional output path to save trained model to.
use_gpu (int): Whether to train on GPU. Make sure to call require_gpu
before calling this function.
stdout (file): A file-like object to write output messages. To disable
printing, set to io.StringIO.
stderr (file): A second file-like object to write output messages. To disable
printing, set to io.StringIO.
RETURNS (tuple): The final nlp object and the path to the exported model.
"""
# We use no_print here so we can respect the stdout/stderr options.
msg = Printer(no_print=True)
# Create iterator, which yields out info after each optimization step.
config = nlp.config.interpolate()
if config["training"]["seed"] is not None:
fix_random_seed(config["training"]["seed"])
allocator = config["training"]["gpu_allocator"]
if use_gpu >= 0 and allocator:
set_gpu_allocator(allocator)
T = registry.resolve(config["training"], schema=ConfigSchemaTraining)
dot_names = [T["train_corpus"], T["dev_corpus"]]
train_corpus, dev_corpus = resolve_dot_names(config, dot_names)
optimizer = T["optimizer"]
score_weights = T["score_weights"]
batcher = T["batcher"]
train_logger = T["logger"]
before_to_disk = create_before_to_disk_callback(T["before_to_disk"])
# Helper function to save checkpoints. This is a closure for convenience,
# to avoid passing in all the args all the time.
def save_checkpoint(is_best):
with nlp.use_params(optimizer.averages):
before_to_disk(nlp).to_disk(output_path / DIR_MODEL_LAST)
if is_best:
# Avoid saving twice (saving will be more expensive than
# the dir copy)
if (output_path / DIR_MODEL_BEST).exists():
shutil.rmtree(output_path / DIR_MODEL_BEST)
shutil.copytree(output_path / DIR_MODEL_LAST,
output_path / DIR_MODEL_BEST)
# Components that shouldn't be updated during training
frozen_components = T["frozen_components"]
# Components that should set annotations on update
annotating_components = T["annotating_components"]
# Create iterator, which yields out info after each optimization step.
training_step_iterator = train_while_improving(
nlp,
optimizer,
create_train_batches(nlp, train_corpus, batcher, T["max_epochs"]),
create_evaluation_callback(nlp, dev_corpus, score_weights),
dropout=T["dropout"],
accumulate_gradient=T["accumulate_gradient"],
patience=T["patience"],
max_steps=T["max_steps"],
eval_frequency=T["eval_frequency"],
exclude=frozen_components,
annotating_components=annotating_components,
)
clean_output_dir(output_path)
stdout.write(msg.info(f"Pipeline: {nlp.pipe_names}") + "\n")
if frozen_components:
stdout.write(
msg.info(f"Frozen components: {frozen_components}") + "\n")
if annotating_components:
stdout.write(
msg.info(f"Set annotations on update for: {annotating_components}")
+ "\n")
stdout.write(
msg.info(f"Initial learn rate: {optimizer.learn_rate}") + "\n")
with nlp.select_pipes(disable=frozen_components):
log_step, finalize_logger = train_logger(nlp, stdout, stderr)
try:
for batch, info, is_best_checkpoint in training_step_iterator:
if is_best_checkpoint is not None:
with nlp.select_pipes(disable=frozen_components):
update_meta(T, nlp, info)
if output_path is not None:
save_checkpoint(is_best_checkpoint)
info["output_path"] = str(output_path / DIR_MODEL_LAST)
log_step(info if is_best_checkpoint is not None else None)
except Exception as e:
if output_path is not None:
stdout.write(
msg.warn(f"Aborting and saving the final best model. "
f"Encountered exception: {repr(e)}") + "\n")
raise e
finally:
finalize_logger()
if output_path is not None:
save_checkpoint(False)
# This will only run if we did't hit an error
if optimizer.averages:
nlp.use_params(optimizer.averages)
if output_path is not None:
stdout.write(
msg.good("Saved pipeline to output directory", output_path /
DIR_MODEL_LAST) + "\n")
return (nlp, output_path / DIR_MODEL_LAST)
else:
return (nlp, None)
def train(
lang,
output_path,
train_path,
dev_path,
raw_text=None,
base_model=None,
pipeline="tagger,parser,ner",
vectors=None,
n_iter=30,
n_early_stopping=None,
n_examples=0,
use_gpu=-1,
version="0.0.0",
meta_path=None,
init_tok2vec=None,
parser_multitasks="",
entity_multitasks="",
noise_level=0.0,
eval_beam_widths="",
gold_preproc=False,
learn_tokens=False,
verbose=False,
debug=False,
):
"""
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.
"""
msg = Printer()
util.fix_random_seed()
util.set_env_log(verbose)
# Make sure all files and paths exists if they are needed
train_path = util.ensure_path(train_path)
dev_path = util.ensure_path(dev_path)
meta_path = util.ensure_path(meta_path)
output_path = util.ensure_path(output_path)
if raw_text is not None:
raw_text = list(srsly.read_jsonl(raw_text))
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 meta_path is not None and not meta_path.exists():
msg.fail("Can't find model meta.json", meta_path, exits=1)
meta = srsly.read_json(meta_path) if meta_path else {}
if 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 not output_path.exists():
output_path.mkdir()
# Take dropout and batch size as generators of values -- dropout
# starts high and decays sharply, to force the optimizer to explore.
# Batch size starts at 1 and grows, so that we make updates quickly
# at the beginning of training.
dropout_rates = util.decaying(
util.env_opt("dropout_from", 0.2),
util.env_opt("dropout_to", 0.2),
util.env_opt("dropout_decay", 0.0),
)
batch_sizes = util.compounding(
util.env_opt("batch_from", 100.0),
util.env_opt("batch_to", 1000.0),
util.env_opt("batch_compound", 1.001),
)
if not eval_beam_widths:
eval_beam_widths = [1]
else:
eval_beam_widths = [int(bw) for bw in eval_beam_widths.split(",")]
if 1 not in eval_beam_widths:
eval_beam_widths.append(1)
eval_beam_widths.sort()
has_beam_widths = eval_beam_widths != [1]
# Set up the base model and pipeline. If a base model is specified, load
# the model and make sure the pipeline matches the pipeline setting. If
# training starts from a blank model, intitalize the language class.
pipeline = [p.strip() for p in pipeline.split(",")]
msg.text("Training pipeline: {}".format(pipeline))
if base_model:
msg.text("Starting with base model '{}'".format(base_model))
nlp = util.load_model(base_model)
if nlp.lang != lang:
msg.fail(
"Model language ('{}') doesn't match language specified as "
"`lang` argument ('{}') ".format(nlp.lang, lang),
exits=1,
)
other_pipes = [pipe for pipe in nlp.pipe_names if pipe not in pipeline]
nlp.disable_pipes(*other_pipes)
for pipe in pipeline:
if pipe not in nlp.pipe_names:
nlp.add_pipe(nlp.create_pipe(pipe))
else:
msg.text("Starting with blank model '{}'".format(lang))
lang_cls = util.get_lang_class(lang)
nlp = lang_cls()
for pipe in pipeline:
nlp.add_pipe(nlp.create_pipe(pipe))
if learn_tokens:
nlp.add_pipe(nlp.create_pipe("merge_subtokens"))
if vectors:
msg.text("Loading vector from model '{}'".format(vectors))
_load_vectors(nlp, vectors)
# Multitask objectives
multitask_options = [("parser", parser_multitasks), ("ner", entity_multitasks)]
for pipe_name, multitasks in multitask_options:
if multitasks:
if pipe_name not in pipeline:
msg.fail(
"Can't use multitask objective without '{}' in the "
"pipeline".format(pipe_name)
)
pipe = nlp.get_pipe(pipe_name)
for objective in multitasks.split(","):
pipe.add_multitask_objective(objective)
# Prepare training corpus
msg.text("Counting training words (limit={})".format(n_examples))
corpus = GoldCorpus(train_path, dev_path, limit=n_examples)
n_train_words = corpus.count_train()
if base_model:
# Start with an existing model, use default optimizer
optimizer = create_default_optimizer(Model.ops)
else:
# Start with a blank model, call begin_training
optimizer = nlp.begin_training(lambda: corpus.train_tuples, device=use_gpu)
nlp._optimizer = None
# Load in pre-trained weights
if init_tok2vec is not None:
components = _load_pretrained_tok2vec(nlp, init_tok2vec)
msg.text("Loaded pretrained tok2vec for: {}".format(components))
# fmt: off
row_head = ["Itn", "Dep Loss", "NER Loss", "UAS", "NER P", "NER R", "NER F", "Tag %", "Token %", "CPU WPS", "GPU WPS"]
row_widths = [3, 10, 10, 7, 7, 7, 7, 7, 7, 7, 7]
if has_beam_widths:
row_head.insert(1, "Beam W.")
row_widths.insert(1, 7)
row_settings = {"widths": row_widths, "aligns": tuple(["r" for i in row_head]), "spacing": 2}
# fmt: on
print("")
msg.row(row_head, **row_settings)
msg.row(["-" * width for width in row_settings["widths"]], **row_settings)
try:
iter_since_best = 0
best_score = 0.0
for i in range(n_iter):
train_docs = corpus.train_docs(
nlp, noise_level=noise_level, gold_preproc=gold_preproc, max_length=0
)
if raw_text:
random.shuffle(raw_text)
raw_batches = util.minibatch(
(nlp.make_doc(rt["text"]) for rt in raw_text), size=8
)
words_seen = 0
with tqdm.tqdm(total=n_train_words, leave=False) as pbar:
losses = {}
for batch in util.minibatch_by_words(train_docs, size=batch_sizes):
if not batch:
continue
docs, golds = zip(*batch)
nlp.update(
docs,
golds,
sgd=optimizer,
drop=next(dropout_rates),
losses=losses,
)
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)
if not int(os.environ.get("LOG_FRIENDLY", 0)):
pbar.update(sum(len(doc) for doc in docs))
words_seen += sum(len(doc) for doc in docs)
with nlp.use_params(optimizer.averages):
util.set_env_log(False)
epoch_model_path = output_path / ("model%d" % i)
nlp.to_disk(epoch_model_path)
nlp_loaded = util.load_model_from_path(epoch_model_path)
for beam_width in eval_beam_widths:
for name, component in nlp_loaded.pipeline:
if hasattr(component, "cfg"):
component.cfg["beam_width"] = beam_width
dev_docs = list(
corpus.dev_docs(nlp_loaded, gold_preproc=gold_preproc)
)
nwords = sum(len(doc_gold[0]) for doc_gold in dev_docs)
start_time = timer()
scorer = nlp_loaded.evaluate(dev_docs, debug)
end_time = timer()
if use_gpu < 0:
gpu_wps = None
cpu_wps = nwords / (end_time - start_time)
else:
gpu_wps = nwords / (end_time - start_time)
with Model.use_device("cpu"):
nlp_loaded = util.load_model_from_path(epoch_model_path)
for name, component in nlp_loaded.pipeline:
if hasattr(component, "cfg"):
component.cfg["beam_width"] = beam_width
dev_docs = list(
corpus.dev_docs(nlp_loaded, gold_preproc=gold_preproc)
)
start_time = timer()
scorer = nlp_loaded.evaluate(dev_docs)
end_time = timer()
cpu_wps = nwords / (end_time - start_time)
acc_loc = output_path / ("model%d" % i) / "accuracy.json"
srsly.write_json(acc_loc, scorer.scores)
# Update model meta.json
meta["lang"] = nlp.lang
meta["pipeline"] = nlp.pipe_names
meta["spacy_version"] = ">=%s" % about.__version__
if beam_width == 1:
meta["speed"] = {
"nwords": nwords,
"cpu": cpu_wps,
"gpu": gpu_wps,
}
meta["accuracy"] = scorer.scores
else:
meta.setdefault("beam_accuracy", {})
meta.setdefault("beam_speed", {})
meta["beam_accuracy"][beam_width] = scorer.scores
meta["beam_speed"][beam_width] = {
"nwords": nwords,
"cpu": cpu_wps,
"gpu": gpu_wps,
}
meta["vectors"] = {
"width": nlp.vocab.vectors_length,
"vectors": len(nlp.vocab.vectors),
"keys": nlp.vocab.vectors.n_keys,
"name": nlp.vocab.vectors.name,
}
meta.setdefault("name", "model%d" % i)
meta.setdefault("version", version)
meta_loc = output_path / ("model%d" % i) / "meta.json"
srsly.write_json(meta_loc, meta)
util.set_env_log(verbose)
progress = _get_progress(
i,
losses,
scorer.scores,
beam_width=beam_width if has_beam_widths else None,
cpu_wps=cpu_wps,
gpu_wps=gpu_wps,
)
msg.row(progress, **row_settings)
# Early stopping
if n_early_stopping is not None:
current_score = _score_for_model(meta)
if current_score < best_score:
iter_since_best += 1
else:
iter_since_best = 0
best_score = current_score
if iter_since_best >= n_early_stopping:
msg.text(
"Early stopping, best iteration "
"is: {}".format(i - iter_since_best)
)
msg.text(
"Best score = {}; Final iteration "
"score = {}".format(best_score, current_score)
)
break
finally:
with nlp.use_params(optimizer.averages):
final_model_path = output_path / "model-final"
nlp.to_disk(final_model_path)
msg.good("Saved model to output directory", final_model_path)
with msg.loading("Creating best model..."):
best_model_path = _collate_best_model(meta, output_path, nlp.pipe_names)
msg.good("Created best model", best_model_path)
def pretrain(
texts_loc,
vectors_model,
output_dir,
width=96,
depth=4,
bilstm_depth=2,
embed_rows=2000,
loss_func="cosine",
use_vectors=False,
dropout=0.2,
n_iter=1000,
batch_size=3000,
max_length=500,
min_length=5,
seed=0,
n_save_every=None,
init_tok2vec=None,
epoch_start=None,
):
"""
Pre-train the 'token-to-vector' (tok2vec) layer of pipeline components,
using an approximate language-modelling objective. Specifically, we load
pretrained vectors, and train a component like a CNN, BiLSTM, etc to predict
vectors which match the pretrained ones. The weights are saved to a directory
after each epoch. You can then pass a path to one of these pretrained weights
files to the 'spacy train' command.
This technique may be especially helpful if you have little labelled data.
However, it's still quite experimental, so your mileage may vary.
To load the weights back in during 'spacy train', you need to ensure
all settings are the same between pretraining and training. The API and
errors around this need some improvement.
"""
config = dict(locals())
for key in config:
if isinstance(config[key], Path):
config[key] = str(config[key])
msg = Printer()
util.fix_random_seed(seed)
has_gpu = prefer_gpu()
if has_gpu:
import torch
torch.set_default_tensor_type("torch.cuda.FloatTensor")
msg.info("Using GPU" if has_gpu else "Not using GPU")
output_dir = Path(output_dir)
if not output_dir.exists():
output_dir.mkdir()
msg.good("Created output directory")
srsly.write_json(output_dir / "config.json", config)
msg.good("Saved settings to config.json")
# Load texts from file or stdin
if texts_loc != "-": # reading from a file
texts_loc = Path(texts_loc)
if not texts_loc.exists():
msg.fail("Input text file doesn't exist", texts_loc, exits=1)
with msg.loading("Loading input texts..."):
texts = list(srsly.read_jsonl(texts_loc))
if not texts:
msg.fail("Input file is empty", texts_loc, exits=1)
msg.good("Loaded input texts")
random.shuffle(texts)
else: # reading from stdin
msg.text("Reading input text from stdin...")
texts = srsly.read_jsonl("-")
with msg.loading("Loading model '{}'...".format(vectors_model)):
nlp = util.load_model(vectors_model)
msg.good("Loaded model '{}'".format(vectors_model))
pretrained_vectors = None if not use_vectors else nlp.vocab.vectors.name
model = create_pretraining_model(
nlp,
Tok2Vec(
width,
embed_rows,
conv_depth=depth,
pretrained_vectors=pretrained_vectors,
bilstm_depth=bilstm_depth, # Requires PyTorch. Experimental.
cnn_maxout_pieces=3, # You can try setting this higher
subword_features=True, # Set to False for Chinese etc
),
)
# Load in pretrained weights
if init_tok2vec is not None:
components = _load_pretrained_tok2vec(nlp, init_tok2vec)
msg.text("Loaded pretrained tok2vec for: {}".format(components))
# Parse the epoch number from the given weight file
model_name = re.search(r"model\d+\.bin", str(init_tok2vec))
if model_name:
# Default weight file name so read epoch_start from it by cutting off 'model' and '.bin'
epoch_start = int(model_name.group(0)[5:][:-4]) + 1
else:
if not epoch_start:
msg.fail(
"You have to use the '--epoch-start' argument when using a renamed weight file for "
"'--init-tok2vec'",
exits=True,
)
elif epoch_start < 0:
msg.fail(
"The argument '--epoch-start' has to be greater or equal to 0. '%d' is invalid"
% epoch_start,
exits=True,
)
else:
# Without '--init-tok2vec' the '--epoch-start' argument is ignored
epoch_start = 0
optimizer = create_default_optimizer(model.ops)
tracker = ProgressTracker(frequency=10000)
msg.divider("Pre-training tok2vec layer - starting at epoch %d" %
epoch_start)
row_settings = {
"widths": (3, 10, 10, 6, 4),
"aligns": ("r", "r", "r", "r", "r")
}
msg.row(("#", "# Words", "Total Loss", "Loss", "w/s"), **row_settings)
def _save_model(epoch, is_temp=False):
is_temp_str = ".temp" if is_temp else ""
with model.use_params(optimizer.averages):
with (output_dir / ("model%d%s.bin" %
(epoch, is_temp_str))).open("wb") as file_:
file_.write(model.tok2vec.to_bytes())
log = {
"nr_word": tracker.nr_word,
"loss": tracker.loss,
"epoch_loss": tracker.epoch_loss,
"epoch": epoch,
}
with (output_dir / "log.jsonl").open("a") as file_:
file_.write(srsly.json_dumps(log) + "\n")
skip_counter = 0
for epoch in range(epoch_start, n_iter + epoch_start):
for batch_id, batch in enumerate(
util.minibatch_by_words(((text, None) for text in texts),
size=batch_size)):
docs, count = make_docs(
nlp,
[text for (text, _) in batch],
max_length=max_length,
min_length=min_length,
)
skip_counter += count
loss = make_update(model,
docs,
optimizer,
objective=loss_func,
drop=dropout)
progress = tracker.update(epoch, loss, docs)
if progress:
msg.row(progress, **row_settings)
if texts_loc == "-" and tracker.words_per_epoch[epoch] >= 10**7:
break
if n_save_every and (batch_id % n_save_every == 0):
_save_model(epoch, is_temp=True)
_save_model(epoch)
tracker.epoch_loss = 0.0
if texts_loc != "-":
# Reshuffle the texts if texts were loaded from a file
random.shuffle(texts)
if skip_counter > 0:
msg.warn(
"Skipped {count} empty values".format(count=str(skip_counter)))
msg.good("Successfully finished pretrain")
def example_data(output_dir: Path, verbose: bool = False):
"""Download Example Data from Github
output_dir (Path): path to output_dir for entities.jsonl and aliases.jsonl
"""
msg = Printer(hide_animation=not verbose)
msg.divider("Example Data")
with msg.loading(f"Writing Example data to {output_dir}"):
aliases_data = [
{
"alias": "ML",
"entities": ["a1", "a2"],
"probabilities": [0.5, 0.5]
},
{
"alias": "Machine learning",
"entities": ["a1"],
"probabilities": [1.0]
},
{
"alias": "Meta Language",
"entities": ["a2"],
"probabilities": [1.0]
},
{
"alias": "NLP",
"entities": ["a3", "a4"],
"probabilities": [0.5, 0.5]
},
{
"alias": "Natural language processing",
"entities": ["a3"],
"probabilities": [1.0],
},
{
"alias": "Neuro-linguistic programming",
"entities": ["a4"],
"probabilities": [1.0],
},
{
"alias": "Operating system",
"entities": ["a5"],
"probabilities": [1.0]
},
{
"alias": "OS",
"entities": ["a5"],
"probabilities": [1.0]
},
{
"alias": "Statistics",
"entities": ["a6"],
"probabilities": [1.0]
},
{
"alias": "Audience segmentation",
"entities": ["a7"],
"probabilities": [1.0],
},
{
"alias": "Decision analysis",
"entities": ["a8"],
"probabilities": [1.0]
},
{
"alias": "Computer science",
"entities": ["a9"],
"probabilities": [1.0]
},
{
"alias": "Photochemistry",
"entities": ["a10"],
"probabilities": [1.0]
},
{
"alias": "Mineralogy",
"entities": ["a11"],
"probabilities": [1.0]
},
{
"alias": "Stereochemistry",
"entities": ["a12"],
"probabilities": [1.0]
},
{
"alias": "Environmental chemistry",
"entities": ["a13"],
"probabilities": [1.0],
},
{
"alias": "Agronomy",
"entities": ["a14"],
"probabilities": [1.0]
},
{
"alias": "Research",
"entities": ["a15"],
"probabilities": [1.0]
},
]
entities_data = [
{
"id":
"a1",
"name":
"Machine learning (ML)",
"description":
"Machine learning (ML) is the scientific study of algorithms and statistical models...",
},
{
"id":
"a2",
"name":
'ML ("Meta Language")',
"description":
'ML ("Meta Language") is a general-purpose functional programming language. It has roots in Lisp, and has been characterized as "Lisp with types".',
},
{
"id":
"a3",
"name":
"Natural language processing (NLP)",
"description":
"Natural language processing (NLP) is a subfield of linguistics, computer science, information engineering, and artificial intelligence concerned with the interactions between computers and human (natural) languages, in particular how to program computers to process and analyze large amounts of natural language data.",
},
{
"id":
"a4",
"name":
"Neuro-linguistic programming (NLP)",
"description":
"Neuro-linguistic programming (NLP) is a pseudoscientific approach to communication, personal development, and psychotherapy created by Richard Bandler and John Grinder in California, United States in the 1970s.",
},
{
"id": "a5",
"name": "Operating system",
"description":
"Operating Systems consists of building system software that provides common services for other types of computer programs.",
"label": "SKILL",
},
{
"id": "a6",
"name": "Statistics",
"description":
"Statistics deals with all aspects of data collection, organization, analysis, interpretation, and presentation.",
"label": "SKILL",
},
{
"id": "a7",
"name": "Audience segmentation",
"description":
"Audience segmentation is a process of dividing people into homogeneous subgroups based upon defined criterion such as product usage, demographics, psychographics, communication behaviors and media use. Audience segmentation is used in commercial marketing so advertisers can design and tailor products and services that satisfy the targeted groups. In social marketing, audiences are segmented into subgroups and assumed to have similar interests, needs and behavioral patterns and this assumption allows social marketers to design relevant health or social messages that influence the people to adopt recommended behaviors. Audience segmentation is widely accepted as a fundamental strategy in communication campaigns to influence health and social change. Audience segmentation makes campaign efforts more effective when messages are tailored to the distinct subgroups and more efficient when the target audience is selected based on their susceptibility and receptivity.",
"label": "SKILL",
},
{
"id": "a8",
"name": "Decision analysis",
"description":
"Decision analysis (DA) is the discipline comprising the philosophy, methodology, and professional practice necessary to address important decisions in a formal manner. Decision analysis includes many procedures, methods, and tools for identifying, clearly representing, and formally assessing important aspects of a decision, for prescribing a recommended course of action by applying the maximum expected utility action axiom to a well-formed representation of the decision, and for translating the formal representation of a decision and its corresponding recommendation into insight for the decision maker and other stakeholders.",
"label": "SKILL",
},
{
"id":
"a9",
"name":
"Computer science",
"description":
"Computer science is the study of processes that interact with data and that can be represented as data in the form of programs. It enables the use of algorithms to manipulate, store, and communicate digital information. A computer scientist studies the theory of computation and the practice of designing software systems.",
},
{
"id": "a10",
"name": "Photochemistry",
"description":
"Photochemistry is the branch of chemistry concerned with the chemical effects of light. Generally, this term is used to describe a chemical reaction caused by absorption of ultraviolet (wavelength from 100 to 400 nm), visible light (400\u2013750 nm) or infrared radiation (750\u20132500 nm).",
"label": "SKILL",
},
{
"id": "a11",
"name": "Mineralogy",
"description":
"Mineralogy is a subject of geology specializing in the scientific study of the chemistry, crystal structure, and physical (including optical) properties of minerals and mineralized artifacts. Specific studies within mineralogy include the processes of mineral origin and formation, classification of minerals, their geographical distribution, as well as their utilization.",
"label": "SKILL",
},
{
"id": "a12",
"name": "Stereochemistry",
"description":
'Stereochemistry, a subdiscipline of chemistry, involves the study of the relative spatial arrangement of atoms that form the structure of molecules and their manipulation. The study of stereochemistry focuses on stereoisomers, which by definition have the same molecular formula and sequence of bonded atoms (constitution), but differ in the three-dimensional orientations of their atoms in space. For this reason, it is also known as 3D chemistry\u2014the prefix "stereo-" means "three-dimensionality".',
"label": "SKILL",
},
{
"id": "a13",
"name": "Environmental chemistry",
"description":
"Environmental chemistry is the scientific study of the chemical and biochemical phenomena that occur in natural places. It should not be confused with green chemistry, which seeks to reduce potential pollution at its source. It can be defined as the study of the sources, reactions, transport, effects, and fates of chemical species in the air, soil, and water environments; and the effect of human activity and biological activity on these. Environmental chemistry is an interdisciplinary science that includes atmospheric, aquatic and soil chemistry, as well as heavily relying on analytical chemistry and being related to environmental and other areas of science.",
"label": "SKILL",
},
{
"id": "a14",
"name": "Agronomy",
"description":
"Agronomy is the science and technology of producing and using plants for food, fuel, fiber, and land restoration. Agronomy has come to encompass work in the areas of plant genetics, plant physiology, meteorology, and soil science. It is the application of a combination of sciences like biology, chemistry, economics, ecology, earth science, and genetics. Agronomists of today are involved with many issues, including producing food, creating healthier food, managing the environmental impact of agriculture, and extracting energy from plants. Agronomists often specialise in areas such as crop rotation, irrigation and drainage, plant breeding, plant physiology, soil classification, soil fertility, weed control, and insect and pest control.",
"label": "SKILL",
},
{
"id": "a15",
"name": "Research",
"description":
'Research is "creative and systematic work undertaken to increase the stock of knowledge, including knowledge of humans, culture and society, and the use of this stock of knowledge to devise new applications." or in other hand Research is a process of steps used to collect and analyze information to increase our understanding of a topic or issue. At a general level, research consists of three steps: 1. Pose a question. 2. Collect data to answer the question. 3. Present an answer to the question. This should be a familiar process. You engage in solving problems every day and you start with a question, collect some information, and then form an answer\nResearch is important for three reasons.1. Research adds to our knowledge: Adding to knowledge means that educators undertake research to contribute to existing information about issues 2.Research improves practice: Research is also important because it suggests improvements for practice. Armed with research results, teachers and other educators become more effective professionals. 3. Research informs policy debates: research also provides information to policy makers when they research and debate educational topics.',
"label": "SKILL",
},
]
if not output_dir.exists():
output_dir.mkdir(parents=True)
srsly.write_jsonl(output_dir / "entities.jsonl", entities_data)
srsly.write_jsonl(output_dir / "aliases.jsonl", aliases_data)
msg.good("Done.")
class Engine(ClassNursery):
def __init__(
self,
model: nn.Module,
datasets_manager: DatasetsManager,
optimizer: optim,
batch_size: int,
save_dir: str,
num_epochs: int,
save_every: int,
log_train_metrics_every: int,
train_metric: BaseMetric,
validation_metric: BaseMetric,
test_metric: BaseMetric,
experiment_name: Optional[str] = None,
experiment_hyperparams: Optional[Dict[str, Any]] = None,
tensorboard_logdir: str = None,
track_for_best: str = "loss",
collate_fn=list,
device: Union[torch.device, str] = torch.device("cpu"),
gradient_norm_clip_value: Optional[float] = 5.0,
lr_scheduler: Optional[torch.optim.lr_scheduler._LRScheduler] = None,
use_wandb: bool = False,
sample_proportion: float = 1.0,
seeds: Dict[str, int] = None,
):
""" Engine runs the models end to end. It iterates through the train dataset and passes
it through the model. During training it helps in tracking a lot of parameters for the run
and saving the parameters. It also reports validation and test parameters from time to time.
Many utilities required for end-end running of the model is here.
Parameters
----------
model : nn.Module
A pytorch module defining a model to be run
datasets_manager : DatasetsManager
A datasets manager that handles all the different datasets
optimizer : torch.optim
Any Optimizer object instantiated using ``torch.optim``
batch_size : int
Batch size for the dataset. The same batch size is used for ``train``, ``valid``
and ``test`` dataset
save_dir : int
The experiments are saved in ``save_dir``. We save checkpoints, the best model,
logs and other information into the save dir
num_epochs : int
The number of epochs to run the training
save_every : int
The model will be checkpointed every ``save_every`` number of iterations
log_train_metrics_every : int
The train metrics will be reported every ``log_train_metrics_every`` iterations
during training
train_metric : BaseMetric
Anything that is an instance of ``BaseMetric`` for calculating training metrics
validation_metric : BaseMetric
Anything that is an instance of ``BaseMetric`` for calculating validation metrics
test_metric : BaseMetric
Anything that is an instance of ``BaseMetric`` for calculating test metrics
experiment_name : str
The experiment should be given a name for ease of tracking. Instead experiment
name is not given, we generate a unique 10 digit sha for the experiment.
experiment_hyperparams : Dict[str, Any]
This is mostly used for tracking the different hyper-params of the experiment
being run. This may be used by ``wandb`` to save the hyper-params
tensorboard_logdir : str
The directory where all the tensorboard runs are stored. If ``None`` is passed
then it defaults to the tensorboard default of storing the log in the current directory.
track_for_best : str
Which metric should be tracked for deciding the best model?. Anything that
the metric emits and is a single value can be used for tracking. The defauly value
is ``loss``. If its loss, then the best value will be the lowest one. For some
other metrics like ``macro_fscore``, the best metric might be the one that has the highest
value
collate_fn : Callable[[List[Any]], List[Any]]
Collates the different examples into a single batch of examples.
This is the same terminology adopted from ``pytorch``. There is no different
device : torch.device
The device on which the model will be placed. If this is "cpu", then the model
and the tensors will all be on cpu. If this is "cuda:0", then the model and
the tensors will be placed on cuda device 0. You can mention any other cuda
device that is suitable for your environment
gradient_norm_clip_value : float
To avoid gradient explosion, the gradients of the norm will be clipped
if the gradient norm exceeds this value
lr_scheduler : torch.optim.lr_scheduler
Any pytorch ``lr_scheduler`` can be used for reducing the learning rate
if the performance on the validation set reduces.
use_wandb : bool
wandb or weights and biases is a tool that is used to track experiments
online. Sciwing comes with inbuilt functionality to track experiments
on weights and biases
seeds: Dict[str, int]
The dict of seeds to be set.
Set the random_seed, pytorch_seed and numpy_seed
Found in
https://github.com/allenai/allennlp/blob/master/allennlp/common/util.py
"""
if isinstance(device, str):
device = torch.device(device)
if seeds is None:
seeds = {}
self.seeds = seeds
self._set_seeds()
self.model = model
self.datasets_manager = datasets_manager
self.train_dataset = self.datasets_manager.train_dataset
self.validation_dataset = self.datasets_manager.dev_dataset
self.test_dataset = self.datasets_manager.test_dataset
self.optimizer = optimizer
self.batch_size = batch_size
self.save_dir = pathlib.Path(save_dir)
self.num_epochs = num_epochs
self.msg_printer = Printer()
self.save_every = save_every
self.log_train_metrics_every = log_train_metrics_every
self.tensorboard_logdir = tensorboard_logdir
self.train_metric_calc = train_metric
self.validation_metric_calc = validation_metric
self.test_metric_calc = test_metric
self.summaryWriter = SummaryWriter(log_dir=tensorboard_logdir)
self.track_for_best = track_for_best
self.collate_fn = collate_fn
self.device = device
self.best_track_value = None
self.set_best_track_value(self.best_track_value)
self.gradient_norm_clip_value = gradient_norm_clip_value
self.lr_scheduler = lr_scheduler
self.lr_scheduler_is_plateau = isinstance(
self.lr_scheduler, torch.optim.lr_scheduler.ReduceLROnPlateau)
self.use_wandb = wandb and use_wandb
self.sample_proportion = sample_proportion
self.label_namespaces = self.datasets_manager.label_namespaces
self.datasets_manager.print_stats()
if experiment_name is None:
hash_ = hashlib.sha1()
hash_.update(str(time.time()).encode("utf-8"))
digest = hash_.hexdigest()
experiment_name = digest[:10]
self.experiment_name = experiment_name
self.experiment_hyperparams = experiment_hyperparams or {}
if self.use_wandb:
wandb.init(
project="project-scwing",
name=self.experiment_name,
config=self.experiment_hyperparams,
)
if not self.save_dir.is_dir():
self.save_dir.mkdir(parents=True)
with open(self.save_dir.joinpath("hyperparams.json"), "w") as fp:
json.dump(self.experiment_hyperparams, fp)
self.num_workers = 1
self.model.to(self.device)
self.train_loader = self.get_loader(self.train_dataset)
self.validation_loader = self.get_loader(self.validation_dataset)
self.test_loader = self.get_loader(self.test_dataset)
# refresh the iters at the beginning of every epoch
self.train_iter = None
self.validation_iter = None
self.test_iter = None
# initializing loss meters
self.train_loss_meter = LossMeter()
self.validation_loss_meter = LossMeter()
self.msg_printer.divider("ENGINE STARTING")
time.sleep(3)
# get the loggers ready
self.train_log_filename = self.save_dir.joinpath("train.log")
self.validation_log_filename = self.save_dir.joinpath("validation.log")
self.test_log_filename = self.save_dir.joinpath("test.log")
self.train_logger = logzero.setup_logger(
name="train-logger",
logfile=self.train_log_filename,
level=logging.INFO)
self.validation_logger = logzero.setup_logger(
name="valid-logger",
logfile=self.validation_log_filename,
level=logging.INFO,
)
self.test_logger = logzero.setup_logger(name="test-logger",
logfile=self.test_log_filename,
level=logging.INFO)
if self.lr_scheduler_is_plateau:
if self.best_track_value == "loss" and self.lr_scheduler.mode == "max":
self.msg_printer.warn(
"You are optimizing loss and lr schedule mode is max instead of min"
)
if (self.best_track_value == "macro_fscore"
or self.best_track_value == "fscore"
and self.lr_scheduler.mode == "min"):
self.msg_printer.warn(
f"You are optimizing for macro_fscore and lr scheduler mode is min instead of max"
)
if (self.best_track_value == "micro_fscore"
and self.lr_scheduler.mode == "min"):
self.msg_printer.warn(
f"You are optimizing for micro_fscore and lr scheduler mode is min instead of max"
)
def get_loader(self, dataset: Dataset) -> DataLoader:
""" Returns the DataLoader for the Dataset
Parameters
----------
dataset : Dataset
Returns
-------
DataLoader
A pytorch DataLoader
"""
dataset_size = len(dataset)
sample_size = int(np.floor(dataset_size * self.sample_proportion))
indices = np.random.choice(range(dataset_size),
size=sample_size,
replace=False)
sampler = SubsetRandomSampler(indices=indices)
loader = DataLoader(
dataset=dataset,
batch_size=self.batch_size,
num_workers=self.num_workers,
collate_fn=self.collate_fn,
pin_memory=True,
sampler=sampler,
)
return loader
def is_best_lower(self, current_best=None):
""" Returns True if the current value of the metric is lower than the best metric.
This is useful for tracking metrics like loss where, lower the value, the better it is
Parameters
----------
current_best : float
The current value for the metric that is being tracked
Returns
-------
bool
"""
return True if current_best < self.best_track_value else False
def is_best_higher(self, current_best=None):
""" Returns ``True`` if the current value of the metric is HIGHER than the best metric.
This is useful for tracking metrics like FSCORE where, higher the value, the better it is
Parameters
----------
current_best : float
The current value for the metric that is being tracked
Returns
-------
bool
"""
return True if current_best >= self.best_track_value else False
def set_best_track_value(self, current_best=None):
""" Set the best value of the value being tracked
Parameters
----------
current_best : float
The current value that is best
Returns
-------
"""
if self.track_for_best == "loss":
self.best_track_value = np.inf if current_best is None else current_best
elif self.track_for_best == "macro_fscore" or self.track_for_best == "fscore":
self.best_track_value = 0 if current_best is None else current_best
elif self.track_for_best == "micro_fscore":
self.best_track_value = 0 if current_best is None else current_best
def run(self):
"""
Run the engine
:return:
"""
for epoch_num in range(self.num_epochs):
self.train_epoch(epoch_num)
self.validation_epoch(epoch_num)
self.test_epoch(epoch_num)
def train_epoch(self, epoch_num: int):
"""
Run the training for one epoch
:param epoch_num: type: int
The current epoch number
"""
# refresh everything necessary before training begins
num_iterations = 0
train_iter = self.get_iter(self.train_loader)
self.train_loss_meter.reset()
self.train_metric_calc.reset()
self.model.train()
self.msg_printer.info(
f"Starting Training Epoch: {epoch_num+1}/{self.num_epochs}")
while True:
try:
# N*T, N * 1, N * 1
lines_labels = next(train_iter)
lines_labels = list(zip(*lines_labels))
lines = lines_labels[0]
labels = lines_labels[1]
batch_size = len(lines)
model_forward_out = self.model(
lines=lines,
labels=labels,
is_training=True,
is_validation=False,
is_test=False,
)
self.train_metric_calc.calc_metric(
lines=lines,
labels=labels,
model_forward_dict=model_forward_out)
try:
self.optimizer.zero_grad()
loss = model_forward_out["loss"]
loss.backward()
torch.nn.utils.clip_grad_norm_(
self.model.parameters(),
max_norm=self.gradient_norm_clip_value)
self.optimizer.step()
self.train_loss_meter.add_loss(loss.item(), batch_size)
except KeyError:
self.msg_printer.fail(
"The model output dictionary does not have "
"a key called loss. Please check to have "
"loss in the model output")
num_iterations += 1
if (num_iterations + 1) % self.log_train_metrics_every == 0:
metrics = self.train_metric_calc.report_metrics()
for label_namespace, table in metrics.items():
self.msg_printer.divider(
text=f"Train Metrics for {label_namespace.upper()}"
)
print(table)
except StopIteration:
self.train_epoch_end(epoch_num)
break
def train_epoch_end(self, epoch_num: int):
""" Performs house-keeping at the end of a training epoch
At the end of the training epoch, it does some house-keeping. It reports the average loss, the
average metric and other information.
Parameters
----------
epoch_num : int
The current epoch number (0 based)
"""
self.msg_printer.divider(f"Training end @ Epoch {epoch_num + 1}")
average_loss = self.train_loss_meter.get_average()
self.msg_printer.text("Average Loss: {0}".format(average_loss))
self.train_logger.info(
f"Average loss @ Epoch {epoch_num+1} - {average_loss}")
metric = self.train_metric_calc.get_metric()
if self.use_wandb:
wandb.log({"train_loss": average_loss}, step=epoch_num + 1)
if self.track_for_best != "loss":
for label_namespace in self.label_namespaces:
wandb.log(
{
f"train_{self.track_for_best}_{label_namespace}":
metric[label_namespace][self.track_for_best]
},
step=epoch_num + 1,
)
# save the model after every `self.save_every` epochs
if (epoch_num + 1) % self.save_every == 0:
torch.save(
{
"epoch_num": epoch_num,
"optimizer_state": self.optimizer.state_dict(),
"model_state": self.model.state_dict(),
"loss": average_loss,
},
self.save_dir.joinpath(f"model_epoch_{epoch_num+1}.pt"),
)
# log loss to tensor board
self.summaryWriter.add_scalars(
"train_validation_loss",
{"train_loss": average_loss or np.inf},
epoch_num + 1,
)
def validation_epoch(self, epoch_num: int):
""" Runs one validation epoch on the validation dataset
Parameters
----------
epoch_num : int
0-based epoch number
"""
self.model.eval()
valid_iter = iter(self.validation_loader)
self.validation_loss_meter.reset()
self.validation_metric_calc.reset()
self.msg_printer.info(
f"Starting Validation Epoch: {epoch_num + 1}/{self.num_epochs}")
while True:
try:
lines_labels = next(valid_iter)
lines_labels = list(zip(*lines_labels))
lines = lines_labels[0]
labels = lines_labels[1]
batch_size = len(lines)
with torch.no_grad():
model_forward_out = self.model(
lines=lines,
labels=labels,
is_training=False,
is_validation=True,
is_test=False,
)
loss = model_forward_out["loss"]
self.validation_loss_meter.add_loss(loss, batch_size)
self.validation_metric_calc.calc_metric(
lines=lines,
labels=labels,
model_forward_dict=model_forward_out)
except StopIteration:
self.validation_epoch_end(epoch_num)
break
def validation_epoch_end(self, epoch_num: int):
"""Performs house-keeping at the end of validation epoch
Parameters
----------
epoch_num : int
The current epoch number
"""
self.msg_printer.divider(f"Validation @ Epoch {epoch_num+1}")
metric_report = self.validation_metric_calc.report_metrics()
average_loss = self.validation_loss_meter.get_average()
for label_namespace, table in metric_report.items():
self.msg_printer.divider(
text=f"Validation Metrics for {label_namespace.upper()}")
print(table)
self.msg_printer.text(f"Average Loss: {average_loss}")
self.validation_logger.info(
f"Validation Loss @ Epoch {epoch_num+1} - {average_loss}")
if self.use_wandb:
wandb.log({"validation_loss": average_loss}, step=epoch_num + 1)
metric = self.validation_metric_calc.get_metric()
if self.track_for_best != "loss":
for label_namespace in self.label_namespaces:
wandb.log(
{
f"validation_{self.track_for_best}_{label_namespace}":
metric[label_namespace][self.track_for_best]
},
step=epoch_num + 1,
)
self.summaryWriter.add_scalars(
"train_validation_loss",
{"validation_loss": average_loss or np.inf},
epoch_num + 1,
)
is_best: bool = None
value_tracked: str = None
if self.track_for_best == "loss":
value_tracked = average_loss
is_best = self.is_best_lower(average_loss)
elif (self.track_for_best == "micro_fscore"
or self.track_for_best == "macro_fscore"
or self.track_for_best == "fscore"):
# If there are multiple namespaces for the metric
# we decide the best model based on the average score
values_tracked = []
metrics = self.validation_metric_calc.get_metric()
for label_namespace in self.label_namespaces:
value_tracked = metrics[label_namespace][self.track_for_best]
values_tracked.append(value_tracked)
value_tracked = sum(values_tracked) / len(values_tracked)
is_best = self.is_best_higher(current_best=value_tracked)
if self.lr_scheduler is not None:
self.lr_scheduler.step(value_tracked)
if is_best:
self.set_best_track_value(current_best=value_tracked)
self.msg_printer.good(f"Found Best Model @ epoch {epoch_num + 1}")
torch.save(
{
"epoch_num": epoch_num,
"optimizer_state": self.optimizer.state_dict(),
"model_state": self.model.state_dict(),
"loss": average_loss,
},
self.save_dir.joinpath("best_model.pt"),
)
def test_epoch(self, epoch_num: int):
"""Runs the test epoch for ``epoch_num``
Loads the best model that is saved during the training
and runs the test dataset.
Parameters
----------
epoch_num : int
zero based epoch number for which the test dataset is run
This is after the last training epoch.
"""
self.msg_printer.divider("Running on Test Batch")
self.load_model_from_file(self.save_dir.joinpath("best_model.pt"))
self.model.eval()
test_iter = iter(self.test_loader)
while True:
try:
lines_labels = next(test_iter)
lines_labels = list(zip(*lines_labels))
lines = lines_labels[0]
labels = lines_labels[1]
with torch.no_grad():
model_forward_out = self.model(
lines=lines,
labels=labels,
is_training=False,
is_validation=False,
is_test=True,
)
self.test_metric_calc.calc_metric(
lines=lines,
labels=labels,
model_forward_dict=model_forward_out)
except StopIteration:
self.test_epoch_end(epoch_num)
break
def test_epoch_end(self, epoch_num: int):
""" Performs house-keeping at the end of the test epoch
It reports the metric that is being traced at the end
of the test epoch
Parameters
----------
epoch_num : int
Epoch num after which the test dataset is run
"""
metric_report = self.test_metric_calc.report_metrics()
for label_namespace, table in metric_report.items():
self.msg_printer.divider(
text=f"Test Metrics for {label_namespace.upper()}")
print(table)
precision_recall_fmeasure = self.test_metric_calc.get_metric()
self.msg_printer.divider(f"Test @ Epoch {epoch_num+1}")
self.test_logger.info(
f"Test Metrics @ Epoch {epoch_num+1} - {precision_recall_fmeasure}"
)
if self.use_wandb:
wandb.log({"test_metrics": str(precision_recall_fmeasure)})
self.summaryWriter.close()
def get_train_dataset(self):
""" Returns the train dataset of the experiment
Returns
-------
Dataset
Anything that conforms to the pytorch style dataset.
"""
return self.train_dataset
def get_validation_dataset(self):
""" Returns the validation dataset of the experiment
Returns
-------
Dataset
Anything that conforms to the pytorch style dataset.
"""
return self.validation_dataset
def get_test_dataset(self):
""" Returns the test dataset of the experiment
Returns
-------
Dataset
Anything that conforms to the pytorch style dataset.
"""
return self.test_dataset
@staticmethod
def get_iter(loader: DataLoader) -> Iterator:
""" Returns the iterator for a pytorch data loader.
The ``loader`` is a pytorch DataLoader that iterates
over the dataset in batches and employs many strategies to do
so. We want an iterator that returns the dataset in batches.
The end of the iterator would signify the end of an epoch
and then we can use that information to perform house-keeping.
Parameters
----------
loader : DataLoader
a pytorch data loader
Returns
-------
Iterator
An iterator over the data loader
"""
iterator = iter(loader)
return iterator
def load_model_from_file(self, filename: str):
self.msg_printer.divider("LOADING MODEL FROM FILE")
with self.msg_printer.loading(
f"Loading Pytorch Model from file {filename}"):
model_chkpoint = torch.load(filename)
self.msg_printer.good("Finished Loading the Model")
model_state = model_chkpoint["model_state"]
self.model.load_state_dict(model_state)
def _set_seeds(self):
seed = self.seeds.get("random_seed", 17290)
numpy_seed = self.seeds.get("numpy_seed", 1729)
torch_seed = self.seeds.get("pytorch_seed", 172)
if seed is not None:
random.seed(seed)
if numpy_seed is not None:
np.random.seed(numpy_seed)
if torch_seed is not None:
torch.manual_seed(torch_seed)
# Seed all GPUs with the same seed if available.
if torch.cuda.is_available():
torch.cuda.manual_seed_all(torch_seed)
def link(origin, link_name, force=False, model_path=None):
"""
Create a symlink for models within the spacy/data directory. Accepts
either the name of a pip package, or the local path to the model data
directory. Linking models allows loading them via spacy.load(link_name).
"""
msg = Printer()
if util.is_package(origin):
model_path = util.get_package_path(origin)
else:
model_path = Path(origin) if model_path is None else Path(model_path)
if not model_path.exists():
msg.fail(
"Can't locate model data",
"The data should be located in {}".format(path2str(model_path)),
exits=1,
)
data_path = util.get_data_path()
if not data_path or not data_path.exists():
spacy_loc = Path(__file__).parent.parent
msg.fail(
"Can't find the spaCy data path to create model symlink",
"Make sure a directory `/data` exists within your spaCy "
"installation and try again. The data directory should be located "
"here:".format(path=spacy_loc),
exits=1,
)
link_path = util.get_data_path() / link_name
if link_path.is_symlink() and not force:
msg.fail(
"Link '{}' already exists".format(link_name),
"To overwrite an existing link, use the --force flag",
exits=1,
)
elif link_path.is_symlink(): # does a symlink exist?
# NB: It's important to check for is_symlink here and not for exists,
# because invalid/outdated symlinks would return False otherwise.
link_path.unlink()
elif link_path.exists(): # does it exist otherwise?
# NB: Check this last because valid symlinks also "exist".
msg.fail(
"Can't overwrite symlink '{}'".format(link_name),
"This can happen if your data directory contains a directory or "
"file of the same name.",
exits=1,
)
details = "%s --> %s" % (path2str(model_path), path2str(link_path))
try:
symlink_to(link_path, model_path)
except: # noqa: E722
# This is quite dirty, but just making sure other errors are caught.
msg.fail(
"Couldn't link model to '{}'".format(link_name),
"Creating a symlink in spacy/data failed. Make sure you have the "
"required permissions and try re-running the command as admin, or "
"use a virtualenv. You can still import the model as a module and "
"call its load() method, or create the symlink manually.",
)
msg.text(details)
raise
msg.good("Linking successful", details)
msg.text("You can now load the model via spacy.load('{}')".format(link_name))
