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accuracy.py
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accuracy.py
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# Copyright The PyTorch Lightning team.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from typing import Optional, Tuple
import torch
from torch import Tensor, tensor
from torchmetrics.functional.classification.stat_scores import _reduce_stat_scores, _stat_scores_update
from torchmetrics.utilities.checks import _check_classification_inputs, _input_format_classification, _input_squeeze
from torchmetrics.utilities.enums import AverageMethod, DataType, MDMCAverageMethod
def _check_subset_validity(mode: DataType) -> bool:
return mode in (DataType.MULTILABEL, DataType.MULTIDIM_MULTICLASS)
def _mode(
preds: Tensor,
target: Tensor,
threshold: float,
top_k: Optional[int],
num_classes: Optional[int],
multiclass: Optional[bool],
) -> DataType:
mode = _check_classification_inputs(
preds, target, threshold=threshold, top_k=top_k, num_classes=num_classes, multiclass=multiclass
)
return mode
def _accuracy_update(
preds: Tensor,
target: Tensor,
reduce: Optional[str],
mdmc_reduce: Optional[str],
threshold: float,
num_classes: Optional[int],
top_k: Optional[int],
multiclass: Optional[bool],
ignore_index: Optional[int],
mode: DataType,
) -> Tuple[Tensor, Tensor, Tensor, Tensor]:
if mode == DataType.MULTILABEL and top_k:
raise ValueError("You can not use the `top_k` parameter to calculate accuracy for multi-label inputs.")
preds, target = _input_squeeze(preds, target)
tp, fp, tn, fn = _stat_scores_update(
preds,
target,
reduce=reduce,
mdmc_reduce=mdmc_reduce,
threshold=threshold,
num_classes=num_classes,
top_k=top_k,
multiclass=multiclass,
ignore_index=ignore_index,
)
return tp, fp, tn, fn
def _accuracy_compute(
tp: Tensor,
fp: Tensor,
tn: Tensor,
fn: Tensor,
average: Optional[str],
mdmc_average: Optional[str],
mode: DataType,
) -> Tensor:
simple_average = [AverageMethod.MICRO, AverageMethod.SAMPLES]
if (mode == DataType.BINARY and average in simple_average) or mode == DataType.MULTILABEL:
numerator = tp + tn
denominator = tp + tn + fp + fn
else:
numerator = tp
denominator = tp + fn
if average == AverageMethod.NONE and mdmc_average != MDMCAverageMethod.SAMPLEWISE:
# a class is not present if there exists no TPs, no FPs, and no FNs
meaningless_indeces = torch.nonzero((tp | fn | fp) == 0).cpu()
numerator[meaningless_indeces, ...] = -1
denominator[meaningless_indeces, ...] = -1
return _reduce_stat_scores(
numerator=numerator,
denominator=denominator,
weights=None if average != AverageMethod.WEIGHTED else tp + fn,
average=average,
mdmc_average=mdmc_average,
)
def _subset_accuracy_update(
preds: Tensor,
target: Tensor,
threshold: float,
top_k: Optional[int],
) -> Tuple[Tensor, Tensor]:
preds, target = _input_squeeze(preds, target)
preds, target, mode = _input_format_classification(preds, target, threshold=threshold, top_k=top_k)
if mode == DataType.MULTILABEL and top_k:
raise ValueError("You can not use the `top_k` parameter to calculate accuracy for multi-label inputs.")
if mode == DataType.MULTILABEL:
correct = (preds == target).all(dim=1).sum()
total = tensor(target.shape[0], device=target.device)
elif mode == DataType.MULTICLASS:
correct = (preds * target).sum()
total = target.sum()
elif mode == DataType.MULTIDIM_MULTICLASS:
sample_correct = (preds * target).sum(dim=(1, 2))
correct = (sample_correct == target.shape[2]).sum()
total = tensor(target.shape[0], device=target.device)
return correct, total
def _subset_accuracy_compute(correct: Tensor, total: Tensor) -> Tensor:
return correct.float() / total
def accuracy(
preds: Tensor,
target: Tensor,
average: str = "micro",
mdmc_average: Optional[str] = "global",
threshold: float = 0.5,
top_k: Optional[int] = None,
subset_accuracy: bool = False,
num_classes: Optional[int] = None,
multiclass: Optional[bool] = None,
ignore_index: Optional[int] = None,
) -> Tensor:
r"""Computes `Accuracy <https://en.wikipedia.org/wiki/Accuracy_and_precision>`_:
.. math::
\text{Accuracy} = \frac{1}{N}\sum_i^N 1(y_i = \hat{y}_i)
Where :math:`y` is a tensor of target values, and :math:`\hat{y}` is a
tensor of predictions.
For multi-class and multi-dimensional multi-class data with probability or logits predictions, the
parameter ``top_k`` generalizes this metric to a Top-K accuracy metric: for each sample the
top-K highest probability or logits items are considered to find the correct label.
For multi-label and multi-dimensional multi-class inputs, this metric computes the "global"
accuracy by default, which counts all labels or sub-samples separately. This can be
changed to subset accuracy (which requires all labels or sub-samples in the sample to
be correctly predicted) by setting ``subset_accuracy=True``.
Accepts all input types listed in :ref:`references/modules:input types`.
Args:
preds: Predictions from model (probabilities, logits or labels)
target: Ground truth labels
average:
Defines the reduction that is applied. Should be one of the following:
- ``'micro'`` [default]: Calculate the metric globally, across all samples and classes.
- ``'macro'``: Calculate the metric for each class separately, and average the
metrics across classes (with equal weights for each class).
- ``'weighted'``: Calculate the metric for each class separately, and average the
metrics across classes, weighting each class by its support (``tp + fn``).
- ``'none'`` or ``None``: Calculate the metric for each class separately, and return
the metric for every class.
- ``'samples'``: Calculate the metric for each sample, and average the metrics
across samples (with equal weights for each sample).
.. note:: What is considered a sample in the multi-dimensional multi-class case
depends on the value of ``mdmc_average``.
.. note:: If ``'none'`` and a given class doesn't occur in the `preds` or `target`,
the value for the class will be ``nan``.
mdmc_average:
Defines how averaging is done for multi-dimensional multi-class inputs (on top of the
``average`` parameter). Should be one of the following:
- ``None`` [default]: Should be left unchanged if your data is not multi-dimensional
multi-class.
- ``'samplewise'``: In this case, the statistics are computed separately for each
sample on the ``N`` axis, and then averaged over samples.
The computation for each sample is done by treating the flattened extra axes ``...``
(see :ref:`references/modules:input types`) as the ``N`` dimension within the sample,
and computing the metric for the sample based on that.
- ``'global'``: In this case the ``N`` and ``...`` dimensions of the inputs
(see :ref:`references/modules:input types`)
are flattened into a new ``N_X`` sample axis, i.e. the inputs are treated as if they
were ``(N_X, C)``. From here on the ``average`` parameter applies as usual.
num_classes:
Number of classes. Necessary for ``'macro'``, ``'weighted'`` and ``None`` average methods.
threshold:
Threshold for transforming probability or logit predictions to binary (0,1) predictions, in the case
of binary or multi-label inputs. Default value of 0.5 corresponds to input being probabilities.
top_k:
Number of highest probability or logit score predictions considered to find the correct label,
relevant only for (multi-dimensional) multi-class inputs. The
default value (``None``) will be interpreted as 1 for these inputs.
Should be left at default (``None``) for all other types of inputs.
multiclass:
Used only in certain special cases, where you want to treat inputs as a different type
than what they appear to be. See the parameter's
:ref:`documentation section <references/modules:using the multiclass parameter>`
for a more detailed explanation and examples.
ignore_index:
Integer specifying a target class to ignore. If given, this class index does not contribute
to the returned score, regardless of reduction method. If an index is ignored, and ``average=None``
or ``'none'``, the score for the ignored class will be returned as ``nan``.
subset_accuracy:
Whether to compute subset accuracy for multi-label and multi-dimensional
multi-class inputs (has no effect for other input types).
- For multi-label inputs, if the parameter is set to ``True``, then all labels for
each sample must be correctly predicted for the sample to count as correct. If it
is set to ``False``, then all labels are counted separately - this is equivalent to
flattening inputs beforehand (i.e. ``preds = preds.flatten()`` and same for ``target``).
- For multi-dimensional multi-class inputs, if the parameter is set to ``True``, then all
sub-sample (on the extra axis) must be correct for the sample to be counted as correct.
If it is set to ``False``, then all sub-samples are counter separately - this is equivalent,
in the case of label predictions, to flattening the inputs beforehand (i.e.
``preds = preds.flatten()`` and same for ``target``). Note that the ``top_k`` parameter
still applies in both cases, if set.
Raises:
ValueError:
If ``threshold`` is not a ``float`` between ``0`` and ``1``.
ValueError:
If ``top_k`` parameter is set for ``multi-label`` inputs.
ValueError:
If ``average`` is none of ``"micro"``, ``"macro"``, ``"weighted"``, ``"samples"``, ``"none"``, ``None``.
ValueError:
If ``mdmc_average`` is not one of ``None``, ``"samplewise"``, ``"global"``.
ValueError:
If ``average`` is set but ``num_classes`` is not provided.
ValueError:
If ``num_classes`` is set
and ``ignore_index`` is not in the range ``[0, num_classes)``.
ValueError:
If ``top_k`` is not an ``integer`` larger than ``0``.
Example:
>>> import torch
>>> from torchmetrics.functional import accuracy
>>> target = torch.tensor([0, 1, 2, 3])
>>> preds = torch.tensor([0, 2, 1, 3])
>>> accuracy(preds, target)
tensor(0.5000)
>>> target = torch.tensor([0, 1, 2])
>>> preds = torch.tensor([[0.1, 0.9, 0], [0.3, 0.1, 0.6], [0.2, 0.5, 0.3]])
>>> accuracy(preds, target, top_k=2)
tensor(0.6667)
"""
if not 0 < threshold < 1:
raise ValueError(f"The `threshold` should be a float in the (0,1) interval, got {threshold}")
allowed_average = ["micro", "macro", "weighted", "samples", "none", None]
if average not in allowed_average:
raise ValueError(f"The `average` has to be one of {allowed_average}, got {average}.")
if average in ["macro", "weighted", "none", None] and (not num_classes or num_classes < 1):
raise ValueError(f"When you set `average` as {average}, you have to provide the number of classes.")
allowed_mdmc_average = [None, "samplewise", "global"]
if mdmc_average not in allowed_mdmc_average:
raise ValueError(f"The `mdmc_average` has to be one of {allowed_mdmc_average}, got {mdmc_average}.")
if num_classes and ignore_index is not None and (not 0 <= ignore_index < num_classes or num_classes == 1):
raise ValueError(f"The `ignore_index` {ignore_index} is not valid for inputs with {num_classes} classes")
if top_k is not None and (not isinstance(top_k, int) or top_k <= 0):
raise ValueError(f"The `top_k` should be an integer larger than 0, got {top_k}")
preds, target = _input_squeeze(preds, target)
mode = _mode(preds, target, threshold, top_k, num_classes, multiclass)
reduce = "macro" if average in ["weighted", "none", None] else average
if subset_accuracy and _check_subset_validity(mode):
correct, total = _subset_accuracy_update(preds, target, threshold, top_k)
return _subset_accuracy_compute(correct, total)
tp, fp, tn, fn = _accuracy_update(
preds, target, reduce, mdmc_average, threshold, num_classes, top_k, multiclass, ignore_index, mode
)
return _accuracy_compute(tp, fp, tn, fn, average, mdmc_average, mode)