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319eb508b5
* Add a `spacy evaluate speed` subcommand This subcommand reports the mean batch performance of a model on a data set with a 95% confidence interval. For reliability, it first performs some warmup rounds. Then it will measure performance on batches with randomly shuffled documents. To avoid having too many spaCy commands, `speed` is a subcommand of `evaluate` and accuracy evaluation is moved to its own `evaluate accuracy` subcommand. * Fix import cycle * Restore `spacy evaluate`, make `spacy benchmark speed` an alias * Add documentation for `spacy benchmark` * CREATES -> PRINTS * WPS -> words/s * Disable formatting of benchmark speed arguments * Fail with an error message when trying to speed bench empty corpus * Make it clearer that `benchmark accuracy` is a replacement for `evaluate` * Fix docstring webpage reference * tests: check `evaluate` output against `benchmark accuracy`
175 lines
5.1 KiB
Python
175 lines
5.1 KiB
Python
from typing import Iterable, List, Optional
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import random
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from itertools import islice
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import numpy
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from pathlib import Path
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import time
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from tqdm import tqdm
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import typer
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from wasabi import msg
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from .. import util
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from ..language import Language
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from ..tokens import Doc
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from ..training import Corpus
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from ._util import Arg, Opt, benchmark_cli, setup_gpu
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@benchmark_cli.command(
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"speed",
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context_settings={"allow_extra_args": True, "ignore_unknown_options": True},
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)
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def benchmark_speed_cli(
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# fmt: off
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ctx: typer.Context,
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model: str = Arg(..., help="Model name or path"),
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data_path: Path = Arg(..., help="Location of binary evaluation data in .spacy format", exists=True),
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batch_size: Optional[int] = Opt(None, "--batch-size", "-b", min=1, help="Override the pipeline batch size"),
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no_shuffle: bool = Opt(False, "--no-shuffle", help="Do not shuffle benchmark data"),
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use_gpu: int = Opt(-1, "--gpu-id", "-g", help="GPU ID or -1 for CPU"),
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n_batches: int = Opt(50, "--batches", help="Minimum number of batches to benchmark", min=30,),
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warmup_epochs: int = Opt(3, "--warmup", "-w", min=0, help="Number of iterations over the data for warmup"),
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# fmt: on
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):
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"""
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Benchmark a pipeline. Expects a loadable spaCy pipeline and benchmark
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data in the binary .spacy format.
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"""
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setup_gpu(use_gpu=use_gpu, silent=False)
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nlp = util.load_model(model)
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batch_size = batch_size if batch_size is not None else nlp.batch_size
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corpus = Corpus(data_path)
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docs = [eg.predicted for eg in corpus(nlp)]
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if len(docs) == 0:
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msg.fail("Cannot benchmark speed using an empty corpus.", exits=1)
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print(f"Warming up for {warmup_epochs} epochs...")
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warmup(nlp, docs, warmup_epochs, batch_size)
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print()
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print(f"Benchmarking {n_batches} batches...")
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wps = benchmark(nlp, docs, n_batches, batch_size, not no_shuffle)
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print()
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print_outliers(wps)
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print_mean_with_ci(wps)
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# Lowercased, behaves as a context manager function.
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class time_context:
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"""Register the running time of a context."""
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def __enter__(self):
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self.start = time.perf_counter()
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return self
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def __exit__(self, type, value, traceback):
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self.elapsed = time.perf_counter() - self.start
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class Quartiles:
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"""Calculate the q1, q2, q3 quartiles and the inter-quartile range (iqr)
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of a sample."""
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q1: float
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q2: float
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q3: float
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iqr: float
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def __init__(self, sample: numpy.ndarray) -> None:
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self.q1 = numpy.quantile(sample, 0.25)
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self.q2 = numpy.quantile(sample, 0.5)
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self.q3 = numpy.quantile(sample, 0.75)
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self.iqr = self.q3 - self.q1
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def annotate(
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nlp: Language, docs: List[Doc], batch_size: Optional[int]
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) -> numpy.ndarray:
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docs = nlp.pipe(tqdm(docs, unit="doc"), batch_size=batch_size)
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wps = []
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while True:
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with time_context() as elapsed:
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batch_docs = list(
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islice(docs, batch_size if batch_size else nlp.batch_size)
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)
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if len(batch_docs) == 0:
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break
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n_tokens = count_tokens(batch_docs)
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wps.append(n_tokens / elapsed.elapsed)
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return numpy.array(wps)
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def benchmark(
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nlp: Language,
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docs: List[Doc],
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n_batches: int,
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batch_size: int,
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shuffle: bool,
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) -> numpy.ndarray:
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if shuffle:
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bench_docs = [
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nlp.make_doc(random.choice(docs).text)
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for _ in range(n_batches * batch_size)
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]
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else:
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bench_docs = [
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nlp.make_doc(docs[i % len(docs)].text)
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for i in range(n_batches * batch_size)
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]
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return annotate(nlp, bench_docs, batch_size)
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def bootstrap(x, statistic=numpy.mean, iterations=10000) -> numpy.ndarray:
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"""Apply a statistic to repeated random samples of an array."""
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return numpy.fromiter(
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(
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statistic(numpy.random.choice(x, len(x), replace=True))
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for _ in range(iterations)
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),
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numpy.float64,
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)
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def count_tokens(docs: Iterable[Doc]) -> int:
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return sum(len(doc) for doc in docs)
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def print_mean_with_ci(sample: numpy.ndarray):
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mean = numpy.mean(sample)
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bootstrap_means = bootstrap(sample)
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bootstrap_means.sort()
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# 95% confidence interval
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low = bootstrap_means[int(len(bootstrap_means) * 0.025)]
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high = bootstrap_means[int(len(bootstrap_means) * 0.975)]
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print(f"Mean: {mean:.1f} words/s (95% CI: {low-mean:.1f} +{high-mean:.1f})")
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def print_outliers(sample: numpy.ndarray):
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quartiles = Quartiles(sample)
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n_outliers = numpy.sum(
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(sample < (quartiles.q1 - 1.5 * quartiles.iqr))
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| (sample > (quartiles.q3 + 1.5 * quartiles.iqr))
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)
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n_extreme_outliers = numpy.sum(
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(sample < (quartiles.q1 - 3.0 * quartiles.iqr))
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| (sample > (quartiles.q3 + 3.0 * quartiles.iqr))
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)
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print(
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f"Outliers: {(100 * n_outliers) / len(sample):.1f}%, extreme outliers: {(100 * n_extreme_outliers) / len(sample)}%"
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)
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def warmup(
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nlp: Language, docs: List[Doc], warmup_epochs: int, batch_size: Optional[int]
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) -> numpy.ndarray:
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docs = warmup_epochs * docs
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return annotate(nlp, docs, batch_size)
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