# Copyright The 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 List, Optional, Union import torch from torch import Tensor, tensor from typing_extensions import Literal from torchmetrics.functional.classification.precision_recall_curve import ( _binary_precision_recall_curve_arg_validation, _binary_precision_recall_curve_format, _binary_precision_recall_curve_tensor_validation, _binary_precision_recall_curve_update, _multiclass_precision_recall_curve_arg_validation, _multiclass_precision_recall_curve_format, _multiclass_precision_recall_curve_tensor_validation, _multiclass_precision_recall_curve_update, _multilabel_precision_recall_curve_arg_validation, _multilabel_precision_recall_curve_format, _multilabel_precision_recall_curve_tensor_validation, _multilabel_precision_recall_curve_update, ) from torchmetrics.functional.classification.roc import ( _binary_roc_compute, _multiclass_roc_compute, _multilabel_roc_compute, ) from torchmetrics.utilities.compute import _auc_compute_without_check, _safe_divide from torchmetrics.utilities.data import _bincount from torchmetrics.utilities.enums import ClassificationTask from torchmetrics.utilities.prints import rank_zero_warn def _reduce_auroc( fpr: Union[Tensor, List[Tensor]], tpr: Union[Tensor, List[Tensor]], average: Optional[Literal["macro", "weighted", "none"]] = "macro", weights: Optional[Tensor] = None, direction: float = 1.0, ) -> Tensor: """Reduce multiple average precision score into one number.""" if isinstance(fpr, Tensor) and isinstance(tpr, Tensor): res = _auc_compute_without_check(fpr, tpr, direction=direction, axis=1) else: res = torch.stack([_auc_compute_without_check(x, y, direction=direction) for x, y in zip(fpr, tpr)]) if average is None or average == "none": return res if torch.isnan(res).any(): rank_zero_warn( f"Average precision score for one or more classes was `nan`. Ignoring these classes in {average}-average", UserWarning, ) idx = ~torch.isnan(res) if average == "macro": return res[idx].mean() if average == "weighted" and weights is not None: weights = _safe_divide(weights[idx], weights[idx].sum()) return (res[idx] * weights).sum() raise ValueError("Received an incompatible combinations of inputs to make reduction.") def _binary_auroc_arg_validation( max_fpr: Optional[float] = None, thresholds: Optional[Union[int, list[float], Tensor]] = None, ignore_index: Optional[int] = None, ) -> None: _binary_precision_recall_curve_arg_validation(thresholds, ignore_index) if max_fpr is not None and not isinstance(max_fpr, float) and 0 < max_fpr <= 1: raise ValueError(f"Arguments `max_fpr` should be a float in range (0, 1], but got: {max_fpr}") def _binary_auroc_compute( state: Union[Tensor, tuple[Tensor, Tensor]], thresholds: Optional[Tensor], max_fpr: Optional[float] = None, pos_label: int = 1, ) -> Tensor: fpr, tpr, _ = _binary_roc_compute(state, thresholds, pos_label) if max_fpr is None or max_fpr == 1 or fpr.sum() == 0 or tpr.sum() == 0: return _auc_compute_without_check(fpr, tpr, 1.0) _device = fpr.device if isinstance(fpr, Tensor) else fpr[0].device max_area: Tensor = tensor(max_fpr, device=_device) # Add a single point at max_fpr and interpolate its tpr value stop = torch.bucketize(max_area, fpr, out_int32=True, right=True) weight = (max_area - fpr[stop - 1]) / (fpr[stop] - fpr[stop - 1]) interp_tpr: Tensor = torch.lerp(tpr[stop - 1], tpr[stop], weight) tpr = torch.cat([tpr[:stop], interp_tpr.view(1)]) fpr = torch.cat([fpr[:stop], max_area.view(1)]) # Compute partial AUC partial_auc = _auc_compute_without_check(fpr, tpr, 1.0) # McClish correction: standardize result to be 0.5 if non-discriminant and 1 if maximal min_area: Tensor = 0.5 * max_area**2 return 0.5 * (1 + (partial_auc - min_area) / (max_area - min_area)) def binary_auroc( preds: Tensor, target: Tensor, max_fpr: Optional[float] = None, thresholds: Optional[Union[int, list[float], Tensor]] = None, ignore_index: Optional[int] = None, validate_args: bool = True, ) -> Tensor: r"""Compute Area Under the Receiver Operating Characteristic Curve (`ROC AUC`_) for binary tasks. The AUROC score summarizes the ROC curve into an single number that describes the performance of a model for multiple thresholds at the same time. Notably, an AUROC score of 1 is a perfect score and an AUROC score of 0.5 corresponds to random guessing. Accepts the following input tensors: - ``preds`` (float tensor): ``(N, ...)``. Preds should be a tensor containing probabilities or logits for each observation. If preds has values outside [0,1] range we consider the input to be logits and will auto apply sigmoid per element. - ``target`` (int tensor): ``(N, ...)``. Target should be a tensor containing ground truth labels, and therefore only contain {0,1} values (except if `ignore_index` is specified). The value 1 always encodes the positive class. Additional dimension ``...`` will be flattened into the batch dimension. The implementation both supports calculating the metric in a non-binned but accurate version and a binned version that is less accurate but more memory efficient. Setting the `thresholds` argument to `None` will activate the non-binned version that uses memory of size :math:`\mathcal{O}(n_{samples})` whereas setting the `thresholds` argument to either an integer, list or a 1d tensor will use a binned version that uses memory of size :math:`\mathcal{O}(n_{thresholds})` (constant memory). Args: preds: Tensor with predictions target: Tensor with true labels max_fpr: If not ``None``, calculates standardized partial AUC over the range ``[0, max_fpr]``. thresholds: Can be one of: - If set to `None`, will use a non-binned approach where thresholds are dynamically calculated from all the data. Most accurate but also most memory consuming approach. - If set to an `int` (larger than 1), will use that number of thresholds linearly spaced from 0 to 1 as bins for the calculation. - If set to an `list` of floats, will use the indicated thresholds in the list as bins for the calculation - If set to an 1d `tensor` of floats, will use the indicated thresholds in the tensor as bins for the calculation. ignore_index: Specifies a target value that is ignored and does not contribute to the metric calculation validate_args: bool indicating if input arguments and tensors should be validated for correctness. Set to ``False`` for faster computations. Returns: A single scalar with the auroc score Example: >>> from torchmetrics.functional.classification import binary_auroc >>> preds = torch.tensor([0, 0.5, 0.7, 0.8]) >>> target = torch.tensor([0, 1, 1, 0]) >>> binary_auroc(preds, target, thresholds=None) tensor(0.5000) >>> binary_auroc(preds, target, thresholds=5) tensor(0.5000) """ if validate_args: _binary_auroc_arg_validation(max_fpr, thresholds, ignore_index) _binary_precision_recall_curve_tensor_validation(preds, target, ignore_index) preds, target, thresholds = _binary_precision_recall_curve_format(preds, target, thresholds, ignore_index) state = _binary_precision_recall_curve_update(preds, target, thresholds) return _binary_auroc_compute(state, thresholds, max_fpr) def _multiclass_auroc_arg_validation( num_classes: int, average: Optional[Literal["macro", "weighted", "none"]] = "macro", thresholds: Optional[Union[int, list[float], Tensor]] = None, ignore_index: Optional[int] = None, ) -> None: _multiclass_precision_recall_curve_arg_validation(num_classes, thresholds, ignore_index) allowed_average = ("macro", "weighted", "none", None) if average not in allowed_average: raise ValueError(f"Expected argument `average` to be one of {allowed_average} but got {average}") def _multiclass_auroc_compute( state: Union[Tensor, tuple[Tensor, Tensor]], num_classes: int, average: Optional[Literal["macro", "weighted", "none"]] = "macro", thresholds: Optional[Tensor] = None, ) -> Tensor: fpr, tpr, _ = _multiclass_roc_compute(state, num_classes, thresholds) return _reduce_auroc( fpr, tpr, average, weights=_bincount(state[1], minlength=num_classes).float() if thresholds is None else state[0][:, 1, :].sum(-1), ) def multiclass_auroc( preds: Tensor, target: Tensor, num_classes: int, average: Optional[Literal["macro", "weighted", "none"]] = "macro", thresholds: Optional[Union[int, list[float], Tensor]] = None, ignore_index: Optional[int] = None, validate_args: bool = True, ) -> Tensor: r"""Compute Area Under the Receiver Operating Characteristic Curve (`ROC AUC`_) for multiclass tasks. The AUROC score summarizes the ROC curve into an single number that describes the performance of a model for multiple thresholds at the same time. Notably, an AUROC score of 1 is a perfect score and an AUROC score of 0.5 corresponds to random guessing. Accepts the following input tensors: - ``preds`` (float tensor): ``(N, C, ...)``. Preds should be a tensor containing probabilities or logits for each observation. If preds has values outside [0,1] range we consider the input to be logits and will auto apply softmax per sample. - ``target`` (int tensor): ``(N, ...)``. Target should be a tensor containing ground truth labels, and therefore only contain values in the [0, n_classes-1] range (except if `ignore_index` is specified). Additional dimension ``...`` will be flattened into the batch dimension. The implementation both supports calculating the metric in a non-binned but accurate version and a binned version that is less accurate but more memory efficient. Setting the `thresholds` argument to `None` will activate the non-binned version that uses memory of size :math:`\mathcal{O}(n_{samples})` whereas setting the `thresholds` argument to either an integer, list or a 1d tensor will use a binned version that uses memory of size :math:`\mathcal{O}(n_{thresholds} \times n_{classes})` (constant memory). Args: preds: Tensor with predictions target: Tensor with true labels num_classes: Integer specifying the number of classes average: Defines the reduction that is applied over classes. Should be one of the following: - ``macro``: Calculate score for each class and average them - ``weighted``: calculates score for each class and computes weighted average using their support - ``"none"`` or ``None``: calculates score for each class and applies no reduction thresholds: Can be one of: - If set to `None`, will use a non-binned approach where thresholds are dynamically calculated from all the data. Most accurate but also most memory consuming approach. - If set to an `int` (larger than 1), will use that number of thresholds linearly spaced from 0 to 1 as bins for the calculation. - If set to an `list` of floats, will use the indicated thresholds in the list as bins for the calculation - If set to an 1d `tensor` of floats, will use the indicated thresholds in the tensor as bins for the calculation. ignore_index: Specifies a target value that is ignored and does not contribute to the metric calculation validate_args: bool indicating if input arguments and tensors should be validated for correctness. Set to ``False`` for faster computations. Returns: If `average=None|"none"` then a 1d tensor of shape (n_classes, ) will be returned with auroc score per class. If `average="macro"|"weighted"` then a single scalar is returned. Example: >>> from torchmetrics.functional.classification import multiclass_auroc >>> preds = torch.tensor([[0.75, 0.05, 0.05, 0.05, 0.05], ... [0.05, 0.75, 0.05, 0.05, 0.05], ... [0.05, 0.05, 0.75, 0.05, 0.05], ... [0.05, 0.05, 0.05, 0.75, 0.05]]) >>> target = torch.tensor([0, 1, 3, 2]) >>> multiclass_auroc(preds, target, num_classes=5, average="macro", thresholds=None) tensor(0.5333) >>> multiclass_auroc(preds, target, num_classes=5, average=None, thresholds=None) tensor([1.0000, 1.0000, 0.3333, 0.3333, 0.0000]) >>> multiclass_auroc(preds, target, num_classes=5, average="macro", thresholds=5) tensor(0.5333) >>> multiclass_auroc(preds, target, num_classes=5, average=None, thresholds=5) tensor([1.0000, 1.0000, 0.3333, 0.3333, 0.0000]) """ if validate_args: _multiclass_auroc_arg_validation(num_classes, average, thresholds, ignore_index) _multiclass_precision_recall_curve_tensor_validation(preds, target, num_classes, ignore_index) preds, target, thresholds = _multiclass_precision_recall_curve_format( preds, target, num_classes, thresholds, ignore_index ) state = _multiclass_precision_recall_curve_update(preds, target, num_classes, thresholds) return _multiclass_auroc_compute(state, num_classes, average, thresholds) def _multilabel_auroc_arg_validation( num_labels: int, average: Optional[Literal["micro", "macro", "weighted", "none"]], thresholds: Optional[Union[int, list[float], Tensor]] = None, ignore_index: Optional[int] = None, ) -> None: _multilabel_precision_recall_curve_arg_validation(num_labels, thresholds, ignore_index) allowed_average = ("micro", "macro", "weighted", "none", None) if average not in allowed_average: raise ValueError(f"Expected argument `average` to be one of {allowed_average} but got {average}") def _multilabel_auroc_compute( state: Union[Tensor, tuple[Tensor, Tensor]], num_labels: int, average: Optional[Literal["micro", "macro", "weighted", "none"]], thresholds: Optional[Tensor], ignore_index: Optional[int] = None, ) -> Tensor: if average == "micro": if isinstance(state, Tensor) and thresholds is not None: return _binary_auroc_compute(state.sum(1), thresholds, max_fpr=None) preds = state[0].flatten() target = state[1].flatten() if ignore_index is not None: idx = target == ignore_index preds = preds[~idx] target = target[~idx] return _binary_auroc_compute((preds, target), thresholds, max_fpr=None) fpr, tpr, _ = _multilabel_roc_compute(state, num_labels, thresholds, ignore_index) return _reduce_auroc( fpr, tpr, average, weights=(state[1] == 1).sum(dim=0).float() if thresholds is None else state[0][:, 1, :].sum(-1), ) def multilabel_auroc( preds: Tensor, target: Tensor, num_labels: int, average: Optional[Literal["micro", "macro", "weighted", "none"]] = "macro", thresholds: Optional[Union[int, list[float], Tensor]] = None, ignore_index: Optional[int] = None, validate_args: bool = True, ) -> Tensor: r"""Compute Area Under the Receiver Operating Characteristic Curve (`ROC AUC`_) for multilabel tasks. The AUROC score summarizes the ROC curve into an single number that describes the performance of a model for multiple thresholds at the same time. Notably, an AUROC score of 1 is a perfect score and an AUROC score of 0.5 corresponds to random guessing. Accepts the following input tensors: - ``preds`` (float tensor): ``(N, C, ...)``. Preds should be a tensor containing probabilities or logits for each observation. If preds has values outside [0,1] range we consider the input to be logits and will auto apply sigmoid per element. - ``target`` (int tensor): ``(N, C, ...)``. Target should be a tensor containing ground truth labels, and therefore only contain {0,1} values (except if `ignore_index` is specified). Additional dimension ``...`` will be flattened into the batch dimension. The implementation both supports calculating the metric in a non-binned but accurate version and a binned version that is less accurate but more memory efficient. Setting the `thresholds` argument to `None` will activate the non-binned version that uses memory of size :math:`\mathcal{O}(n_{samples})` whereas setting the `thresholds` argument to either an integer, list or a 1d tensor will use a binned version that uses memory of size :math:`\mathcal{O}(n_{thresholds} \times n_{labels})` (constant memory). Args: preds: Tensor with predictions target: Tensor with true labels num_labels: Integer specifying the number of labels average: Defines the reduction that is applied over labels. Should be one of the following: - ``micro``: Sum score over all labels - ``macro``: Calculate score for each label and average them - ``weighted``: calculates score for each label and computes weighted average using their support - ``"none"`` or ``None``: calculates score for each label and applies no reduction thresholds: Can be one of: - If set to `None`, will use a non-binned approach where thresholds are dynamically calculated from all the data. Most accurate but also most memory consuming approach. - If set to an `int` (larger than 1), will use that number of thresholds linearly spaced from 0 to 1 as bins for the calculation. - If set to an `list` of floats, will use the indicated thresholds in the list as bins for the calculation - If set to an 1d `tensor` of floats, will use the indicated thresholds in the tensor as bins for the calculation. ignore_index: Specifies a target value that is ignored and does not contribute to the metric calculation validate_args: bool indicating if input arguments and tensors should be validated for correctness. Set to ``False`` for faster computations. Returns: If `average=None|"none"` then a 1d tensor of shape (n_classes, ) will be returned with auroc score per class. If `average="micro|macro"|"weighted"` then a single scalar is returned. Example: >>> from torchmetrics.functional.classification import multilabel_auroc >>> preds = torch.tensor([[0.75, 0.05, 0.35], ... [0.45, 0.75, 0.05], ... [0.05, 0.55, 0.75], ... [0.05, 0.65, 0.05]]) >>> target = torch.tensor([[1, 0, 1], ... [0, 0, 0], ... [0, 1, 1], ... [1, 1, 1]]) >>> multilabel_auroc(preds, target, num_labels=3, average="macro", thresholds=None) tensor(0.6528) >>> multilabel_auroc(preds, target, num_labels=3, average=None, thresholds=None) tensor([0.6250, 0.5000, 0.8333]) >>> multilabel_auroc(preds, target, num_labels=3, average="macro", thresholds=5) tensor(0.6528) >>> multilabel_auroc(preds, target, num_labels=3, average=None, thresholds=5) tensor([0.6250, 0.5000, 0.8333]) """ if validate_args: _multilabel_auroc_arg_validation(num_labels, average, thresholds, ignore_index) _multilabel_precision_recall_curve_tensor_validation(preds, target, num_labels, ignore_index) preds, target, thresholds = _multilabel_precision_recall_curve_format( preds, target, num_labels, thresholds, ignore_index ) state = _multilabel_precision_recall_curve_update(preds, target, num_labels, thresholds) return _multilabel_auroc_compute(state, num_labels, average, thresholds, ignore_index) def auroc( preds: Tensor, target: Tensor, task: Literal["binary", "multiclass", "multilabel"], thresholds: Optional[Union[int, list[float], Tensor]] = None, num_classes: Optional[int] = None, num_labels: Optional[int] = None, average: Optional[Literal["macro", "weighted", "none"]] = "macro", max_fpr: Optional[float] = None, ignore_index: Optional[int] = None, validate_args: bool = True, ) -> Optional[Tensor]: r"""Compute Area Under the Receiver Operating Characteristic Curve (`ROC AUC`_). The AUROC score summarizes the ROC curve into an single number that describes the performance of a model for multiple thresholds at the same time. Notably, an AUROC score of 1 is a perfect score and an AUROC score of 0.5 corresponds to random guessing. This function is a simple wrapper to get the task specific versions of this metric, which is done by setting the ``task`` argument to either ``'binary'``, ``'multiclass'`` or ``'multilabel'``. See the documentation of :func:`~torchmetrics.functional.classification.binary_auroc`, :func:`~torchmetrics.functional.classification.multiclass_auroc` and :func:`~torchmetrics.functional.classification.multilabel_auroc` for the specific details of each argument influence and examples. Legacy Example: >>> preds = torch.tensor([0.13, 0.26, 0.08, 0.19, 0.34]) >>> target = torch.tensor([0, 0, 1, 1, 1]) >>> auroc(preds, target, task='binary') tensor(0.5000) >>> preds = torch.tensor([[0.90, 0.05, 0.05], ... [0.05, 0.90, 0.05], ... [0.05, 0.05, 0.90], ... [0.85, 0.05, 0.10], ... [0.10, 0.10, 0.80]]) >>> target = torch.tensor([0, 1, 1, 2, 2]) >>> auroc(preds, target, task='multiclass', num_classes=3) tensor(0.7778) """ task = ClassificationTask.from_str(task) if task == ClassificationTask.BINARY: return binary_auroc(preds, target, max_fpr, thresholds, ignore_index, validate_args) if task == ClassificationTask.MULTICLASS: if not isinstance(num_classes, int): raise ValueError(f"`num_classes` is expected to be `int` but `{type(num_classes)} was passed.`") return multiclass_auroc(preds, target, num_classes, average, thresholds, ignore_index, validate_args) if task == ClassificationTask.MULTILABEL: if not isinstance(num_labels, int): raise ValueError(f"`num_labels` is expected to be `int` but `{type(num_labels)} was passed.`") return multilabel_auroc(preds, target, num_labels, average, thresholds, ignore_index, validate_args) return None