webapp/seed/Lib/site-packages/transformers/models/sam/processing_sam.py

# Copyright 2023 The HuggingFace Inc. 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.
"""
Processor class for SAM.
"""

from copy import deepcopy
from typing import Union

import numpy as np

from ...image_utils import ImageInput
from ...processing_utils import ImagesKwargs, ProcessingKwargs, ProcessorMixin
from ...tokenization_utils_base import BatchEncoding, PreTokenizedInput, TextInput
from ...utils import auto_docstring, is_torch_available


if is_torch_available():
    import torch

NestedList = list[Union[float | int | None, "NestedList"]]


class SamImagesKwargs(ImagesKwargs, total=False):
    """
    segmentation_maps (`ImageInput`, *optional*):
        Ground truth segmentation maps to process alongside the input images. These maps are used for training
        or evaluation purposes and are resized and normalized to match the processed image dimensions.
    input_points (`NestedList`, *optional*):
        Input points for prompt-based segmentation. Should be a nested list with structure
        `[image_level, object_level, point_level, [x, y]]` where each point is specified as `[x, y]` coordinates
        in the original image space. Points are normalized to the target image size before being passed to the model.
    input_labels (`NestedList`, *optional*):
        Labels for the input points, indicating whether each point is a foreground (1) or background (0) point.
        Should be a nested list with structure `[image_level, object_level, point_level]`. Must have the same
        structure as `input_points` (excluding the coordinate dimension).
    input_boxes (`NestedList`, *optional*):
        Bounding boxes for prompt-based segmentation. Should be a nested list with structure
        `[image_level, box_level, [x1, y1, x2, y2]]` where each box is specified as `[x1, y1, x2, y2]` coordinates
        in the original image space. Boxes are normalized to the target image size before being passed to the model.
    point_pad_value (`int`, *optional*, defaults to `-10`):
        The value used for padding input points when batching sequences of different lengths. This value marks
        padded positions and is preserved during coordinate normalization to distinguish real points from padding.
    mask_size (`dict[str, int]`, *optional*):
        Dictionary specifying the target mask size with keys `"height"` and `"width"`. This determines the
        resolution of the output segmentation masks generated by the model.
    mask_pad_size (`dict[str, int]`, *optional*):
        Dictionary specifying the padding size for masks with keys `"height"` and `"width"`. This is used when
        batching masks of different sizes to ensure consistent dimensions.
    """

    segmentation_maps: ImageInput | None
    input_points: "NestedList | torch.Tensor | None"
    input_labels: "NestedList | int | torch.Tensor | None"
    input_boxes: "NestedList | torch.Tensor | None"
    point_pad_value: int | None
    mask_size: dict[str, int]
    mask_pad_size: dict[str, int]


class SamProcessorKwargs(ProcessingKwargs, total=False):
    images_kwargs: SamImagesKwargs
    _defaults = {
        "images_kwargs": {
            "point_pad_value": -10,
        }
    }


@auto_docstring
class SamProcessor(ProcessorMixin):
    def __init__(self, image_processor):
        super().__init__(image_processor)
        self.target_size = self.image_processor.size["longest_edge"]

    @auto_docstring
    def __call__(
        self,
        images: ImageInput | None = None,
        text: TextInput | PreTokenizedInput | list[TextInput] | list[PreTokenizedInput] | None = None,
        **kwargs,
    ) -> BatchEncoding:
        output_kwargs = self._merge_kwargs(
            SamProcessorKwargs,
            tokenizer_init_kwargs={},
            **kwargs,
        )
        input_points = output_kwargs["images_kwargs"].pop("input_points", None)
        input_labels = output_kwargs["images_kwargs"].pop("input_labels", None)
        input_boxes = output_kwargs["images_kwargs"].pop("input_boxes", None)
        point_pad_value = output_kwargs["images_kwargs"].pop("point_pad_value", None)

        encoding_image_processor = self.image_processor(
            images,
            **output_kwargs["images_kwargs"],
        )

        # pop arguments that are not used in the forward but used nevertheless
        original_sizes = encoding_image_processor["original_sizes"]

        if hasattr(original_sizes, "numpy"):
            original_sizes = original_sizes.numpy()

        input_points, input_labels, input_boxes = self._check_and_preprocess_points(
            input_points=input_points,
            input_labels=input_labels,
            input_boxes=input_boxes,
        )

        encoding_image_processor = self._normalize_and_convert(
            encoding_image_processor,
            original_sizes,
            input_points=input_points,
            input_labels=input_labels,
            input_boxes=input_boxes,
            return_tensors=output_kwargs["images_kwargs"].get("return_tensors"),
            point_pad_value=point_pad_value,
        )

        return encoding_image_processor

    def _normalize_and_convert(
        self,
        encoding_image_processor,
        original_sizes,
        input_points=None,
        input_labels=None,
        input_boxes=None,
        return_tensors="pt",
        point_pad_value=-10,
    ):
        if input_points is not None:
            if len(original_sizes) != len(input_points):
                input_points = [
                    self._normalize_coordinates(self.target_size, point, original_sizes[0]) for point in input_points
                ]
            else:
                input_points = [
                    self._normalize_coordinates(self.target_size, point, original_size)
                    for point, original_size in zip(input_points, original_sizes)
                ]
            # check that all arrays have the same shape
            if not all(point.shape == input_points[0].shape for point in input_points):
                if input_labels is not None:
                    input_points, input_labels = self._pad_points_and_labels(
                        input_points, input_labels, point_pad_value
                    )

            input_points = np.array(input_points)

        if input_labels is not None:
            input_labels = np.array(input_labels)

        if input_boxes is not None:
            if len(original_sizes) != len(input_boxes):
                input_boxes = [
                    self._normalize_coordinates(self.target_size, box, original_sizes[0], is_bounding_box=True)
                    for box in input_boxes
                ]
            else:
                input_boxes = [
                    self._normalize_coordinates(self.target_size, box, original_size, is_bounding_box=True)
                    for box, original_size in zip(input_boxes, original_sizes)
                ]
            input_boxes = np.array(input_boxes)

        if input_boxes is not None:
            if return_tensors == "pt":
                input_boxes = torch.from_numpy(input_boxes)
                # boxes batch size of 1 by default
                input_boxes = input_boxes.unsqueeze(1) if len(input_boxes.shape) != 3 else input_boxes
            encoding_image_processor.update({"input_boxes": input_boxes})
        if input_points is not None:
            if return_tensors == "pt":
                input_points = torch.from_numpy(input_points)
                # point batch size of 1 by default
                input_points = input_points.unsqueeze(1) if len(input_points.shape) != 4 else input_points
            encoding_image_processor.update({"input_points": input_points})
        if input_labels is not None:
            if return_tensors == "pt":
                input_labels = torch.from_numpy(input_labels)
                # point batch size of 1 by default
                input_labels = input_labels.unsqueeze(1) if len(input_labels.shape) != 3 else input_labels
            encoding_image_processor.update({"input_labels": input_labels})

        return encoding_image_processor

    def _pad_points_and_labels(self, input_points, input_labels, point_pad_value):
        r"""
        The method pads the 2D points and labels to the maximum number of points in the batch.
        """
        expected_nb_points = max(point.shape[0] for point in input_points)
        processed_input_points = []
        for i, point in enumerate(input_points):
            if point.shape[0] != expected_nb_points:
                point = np.concatenate(
                    [point, np.zeros((expected_nb_points - point.shape[0], 2)) + point_pad_value], axis=0
                )
                input_labels[i] = np.append(input_labels[i], [point_pad_value])
            processed_input_points.append(point)
        input_points = processed_input_points
        return input_points, input_labels

    def _normalize_coordinates(
        self, target_size: int, coords: np.ndarray, original_size, is_bounding_box=False
    ) -> np.ndarray:
        """
        Expects a numpy array of length 2 in the final dimension. Requires the original image size in (H, W) format.
        """
        old_h, old_w = original_size
        new_h, new_w = self.image_processor._get_preprocess_shape(original_size, longest_edge=target_size)
        coords = deepcopy(coords).astype(float)

        if is_bounding_box:
            coords = coords.reshape(-1, 2, 2)

        coords[..., 0] = coords[..., 0] * (new_w / old_w)
        coords[..., 1] = coords[..., 1] * (new_h / old_h)

        if is_bounding_box:
            coords = coords.reshape(-1, 4)

        return coords

    def _check_and_preprocess_points(
        self,
        input_points=None,
        input_labels=None,
        input_boxes=None,
    ):
        r"""
        Check and preprocesses the 2D points, labels and bounding boxes. It checks if the input is valid and if they
        are, it converts the coordinates of the points and bounding boxes. If a user passes directly a `torch.Tensor`,
        it is converted to a `numpy.ndarray` and then to a `list`.
        """
        if input_points is not None:
            if hasattr(input_points, "numpy"):
                input_points = input_points.numpy().tolist()

            if not isinstance(input_points, list) or not isinstance(input_points[0], list):
                raise ValueError("Input points must be a list of list of floating points.")
            input_points = [np.array(input_point) for input_point in input_points]
        else:
            input_points = None

        if input_labels is not None:
            if hasattr(input_labels, "numpy"):
                input_labels = input_labels.numpy().tolist()

            if not isinstance(input_labels, list) or not isinstance(input_labels[0], list):
                raise ValueError("Input labels must be a list of list integers.")
            input_labels = [np.array(label) for label in input_labels]
        else:
            input_labels = None

        if input_boxes is not None:
            if hasattr(input_boxes, "numpy"):
                input_boxes = input_boxes.numpy().tolist()

            if (
                not isinstance(input_boxes, list)
                or not isinstance(input_boxes[0], list)
                or not isinstance(input_boxes[0][0], list)
            ):
                raise ValueError("Input boxes must be a list of list of list of floating points.")
            input_boxes = [np.array(box).astype(np.float32) for box in input_boxes]
        else:
            input_boxes = None

        return input_points, input_labels, input_boxes

    @property
    def model_input_names(self):
        image_processor_input_names = self.image_processor.model_input_names
        return list(image_processor_input_names + ["original_sizes", "reshaped_input_sizes"])

    def post_process_masks(self, *args, **kwargs):
        return self.image_processor.post_process_masks(*args, **kwargs)


__all__ = ["SamProcessor"]
Initial commit 4 days ago			`# Copyright 2023 The HuggingFace Inc. 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.`
			`"""`
			`Processor class for SAM.`
			`"""`

			`from copy import deepcopy`
			`from typing import Union`

			`import numpy as np`

			`from ...image_utils import ImageInput`
			`from ...processing_utils import ImagesKwargs, ProcessingKwargs, ProcessorMixin`
			`from ...tokenization_utils_base import BatchEncoding, PreTokenizedInput, TextInput`
			`from ...utils import auto_docstring, is_torch_available`


			`if is_torch_available():`
			`import torch`

			`NestedList = list[Union[float \| int \| None, "NestedList"]]`


			`class SamImagesKwargs(ImagesKwargs, total=False):`
			`"""`
			segmentation_maps (`ImageInput`, optional):
			`Ground truth segmentation maps to process alongside the input images. These maps are used for training`
			`or evaluation purposes and are resized and normalized to match the processed image dimensions.`
			input_points (`NestedList`, optional):
			`Input points for prompt-based segmentation. Should be a nested list with structure`
			`[image_level, object_level, point_level, [x, y]]` where each point is specified as `[x, y]` coordinates
			`in the original image space. Points are normalized to the target image size before being passed to the model.`
			input_labels (`NestedList`, optional):
			`Labels for the input points, indicating whether each point is a foreground (1) or background (0) point.`
			Should be a nested list with structure `[image_level, object_level, point_level]`. Must have the same
			structure as `input_points` (excluding the coordinate dimension).
			input_boxes (`NestedList`, optional):
			`Bounding boxes for prompt-based segmentation. Should be a nested list with structure`
			`[image_level, box_level, [x1, y1, x2, y2]]` where each box is specified as `[x1, y1, x2, y2]` coordinates
			`in the original image space. Boxes are normalized to the target image size before being passed to the model.`
			point_pad_value (`int`, optional, defaults to `-10`):
			`The value used for padding input points when batching sequences of different lengths. This value marks`
			`padded positions and is preserved during coordinate normalization to distinguish real points from padding.`
			mask_size (`dict[str, int]`, optional):
			Dictionary specifying the target mask size with keys `"height"` and `"width"`. This determines the
			`resolution of the output segmentation masks generated by the model.`
			mask_pad_size (`dict[str, int]`, optional):
			Dictionary specifying the padding size for masks with keys `"height"` and `"width"`. This is used when
			`batching masks of different sizes to ensure consistent dimensions.`
			`"""`

			`segmentation_maps: ImageInput \| None`
			`input_points: "NestedList \| torch.Tensor \| None"`
			`input_labels: "NestedList \| int \| torch.Tensor \| None"`
			`input_boxes: "NestedList \| torch.Tensor \| None"`
			`point_pad_value: int \| None`
			`mask_size: dict[str, int]`
			`mask_pad_size: dict[str, int]`


			`class SamProcessorKwargs(ProcessingKwargs, total=False):`
			`images_kwargs: SamImagesKwargs`
			`_defaults = {`
			`"images_kwargs": {`
			`"point_pad_value": -10,`
			`}`
			`}`


			`@auto_docstring`
			`class SamProcessor(ProcessorMixin):`
			`def __init__(self, image_processor):`
			`super().__init__(image_processor)`
			`self.target_size = self.image_processor.size["longest_edge"]`

			`@auto_docstring`
			`def __call__(`
			`self,`
			`images: ImageInput \| None = None,`
			`text: TextInput \| PreTokenizedInput \| list[TextInput] \| list[PreTokenizedInput] \| None = None,`
			`**kwargs,`
			`) -> BatchEncoding:`
			`output_kwargs = self._merge_kwargs(`
			`SamProcessorKwargs,`
			`tokenizer_init_kwargs={},`
			`**kwargs,`
			`)`
			`input_points = output_kwargs["images_kwargs"].pop("input_points", None)`
			`input_labels = output_kwargs["images_kwargs"].pop("input_labels", None)`
			`input_boxes = output_kwargs["images_kwargs"].pop("input_boxes", None)`
			`point_pad_value = output_kwargs["images_kwargs"].pop("point_pad_value", None)`

			`encoding_image_processor = self.image_processor(`
			`images,`
			`**output_kwargs["images_kwargs"],`
			`)`

			`# pop arguments that are not used in the forward but used nevertheless`
			`original_sizes = encoding_image_processor["original_sizes"]`

			`if hasattr(original_sizes, "numpy"):`
			`original_sizes = original_sizes.numpy()`

			`input_points, input_labels, input_boxes = self._check_and_preprocess_points(`
			`input_points=input_points,`
			`input_labels=input_labels,`
			`input_boxes=input_boxes,`
			`)`

			`encoding_image_processor = self._normalize_and_convert(`
			`encoding_image_processor,`
			`original_sizes,`
			`input_points=input_points,`
			`input_labels=input_labels,`
			`input_boxes=input_boxes,`
			`return_tensors=output_kwargs["images_kwargs"].get("return_tensors"),`
			`point_pad_value=point_pad_value,`
			`)`

			`return encoding_image_processor`

			`def _normalize_and_convert(`
			`self,`
			`encoding_image_processor,`
			`original_sizes,`
			`input_points=None,`
			`input_labels=None,`
			`input_boxes=None,`
			`return_tensors="pt",`
			`point_pad_value=-10,`
			`):`
			`if input_points is not None:`
			`if len(original_sizes) != len(input_points):`
			`input_points = [`
			`self._normalize_coordinates(self.target_size, point, original_sizes[0]) for point in input_points`
			`]`
			`else:`
			`input_points = [`
			`self._normalize_coordinates(self.target_size, point, original_size)`
			`for point, original_size in zip(input_points, original_sizes)`
			`]`
			`# check that all arrays have the same shape`
			`if not all(point.shape == input_points[0].shape for point in input_points):`
			`if input_labels is not None:`
			`input_points, input_labels = self._pad_points_and_labels(`
			`input_points, input_labels, point_pad_value`
			`)`

			`input_points = np.array(input_points)`

			`if input_labels is not None:`
			`input_labels = np.array(input_labels)`

			`if input_boxes is not None:`
			`if len(original_sizes) != len(input_boxes):`
			`input_boxes = [`
			`self._normalize_coordinates(self.target_size, box, original_sizes[0], is_bounding_box=True)`
			`for box in input_boxes`
			`]`
			`else:`
			`input_boxes = [`
			`self._normalize_coordinates(self.target_size, box, original_size, is_bounding_box=True)`
			`for box, original_size in zip(input_boxes, original_sizes)`
			`]`
			`input_boxes = np.array(input_boxes)`

			`if input_boxes is not None:`
			`if return_tensors == "pt":`
			`input_boxes = torch.from_numpy(input_boxes)`
			`# boxes batch size of 1 by default`
			`input_boxes = input_boxes.unsqueeze(1) if len(input_boxes.shape) != 3 else input_boxes`
			`encoding_image_processor.update({"input_boxes": input_boxes})`
			`if input_points is not None:`
			`if return_tensors == "pt":`
			`input_points = torch.from_numpy(input_points)`
			`# point batch size of 1 by default`
			`input_points = input_points.unsqueeze(1) if len(input_points.shape) != 4 else input_points`
			`encoding_image_processor.update({"input_points": input_points})`
			`if input_labels is not None:`
			`if return_tensors == "pt":`
			`input_labels = torch.from_numpy(input_labels)`
			`# point batch size of 1 by default`
			`input_labels = input_labels.unsqueeze(1) if len(input_labels.shape) != 3 else input_labels`
			`encoding_image_processor.update({"input_labels": input_labels})`

			`return encoding_image_processor`

			`def _pad_points_and_labels(self, input_points, input_labels, point_pad_value):`
			`r"""`
			`The method pads the 2D points and labels to the maximum number of points in the batch.`
			`"""`
			`expected_nb_points = max(point.shape[0] for point in input_points)`
			`processed_input_points = []`
			`for i, point in enumerate(input_points):`
			`if point.shape[0] != expected_nb_points:`
			`point = np.concatenate(`
			`[point, np.zeros((expected_nb_points - point.shape[0], 2)) + point_pad_value], axis=0`
			`)`
			`input_labels[i] = np.append(input_labels[i], [point_pad_value])`
			`processed_input_points.append(point)`
			`input_points = processed_input_points`
			`return input_points, input_labels`

			`def _normalize_coordinates(`
			`self, target_size: int, coords: np.ndarray, original_size, is_bounding_box=False`
			`) -> np.ndarray:`
			`"""`
			`Expects a numpy array of length 2 in the final dimension. Requires the original image size in (H, W) format.`
			`"""`
			`old_h, old_w = original_size`
			`new_h, new_w = self.image_processor._get_preprocess_shape(original_size, longest_edge=target_size)`
			`coords = deepcopy(coords).astype(float)`

			`if is_bounding_box:`
			`coords = coords.reshape(-1, 2, 2)`

			`coords[..., 0] = coords[..., 0] * (new_w / old_w)`
			`coords[..., 1] = coords[..., 1] * (new_h / old_h)`

			`if is_bounding_box:`
			`coords = coords.reshape(-1, 4)`

			`return coords`

			`def _check_and_preprocess_points(`
			`self,`
			`input_points=None,`
			`input_labels=None,`
			`input_boxes=None,`
			`):`
			`r"""`
			`Check and preprocesses the 2D points, labels and bounding boxes. It checks if the input is valid and if they`
			are, it converts the coordinates of the points and bounding boxes. If a user passes directly a `torch.Tensor`,
			it is converted to a `numpy.ndarray` and then to a `list`.
			`"""`
			`if input_points is not None:`
			`if hasattr(input_points, "numpy"):`
			`input_points = input_points.numpy().tolist()`

			`if not isinstance(input_points, list) or not isinstance(input_points[0], list):`
			`raise ValueError("Input points must be a list of list of floating points.")`
			`input_points = [np.array(input_point) for input_point in input_points]`
			`else:`
			`input_points = None`

			`if input_labels is not None:`
			`if hasattr(input_labels, "numpy"):`
			`input_labels = input_labels.numpy().tolist()`

			`if not isinstance(input_labels, list) or not isinstance(input_labels[0], list):`
			`raise ValueError("Input labels must be a list of list integers.")`
			`input_labels = [np.array(label) for label in input_labels]`
			`else:`
			`input_labels = None`

			`if input_boxes is not None:`
			`if hasattr(input_boxes, "numpy"):`
			`input_boxes = input_boxes.numpy().tolist()`

			`if (`
			`not isinstance(input_boxes, list)`
			`or not isinstance(input_boxes[0], list)`
			`or not isinstance(input_boxes[0][0], list)`
			`):`
			`raise ValueError("Input boxes must be a list of list of list of floating points.")`
			`input_boxes = [np.array(box).astype(np.float32) for box in input_boxes]`
			`else:`
			`input_boxes = None`

			`return input_points, input_labels, input_boxes`

			`@property`
			`def model_input_names(self):`
			`image_processor_input_names = self.image_processor.model_input_names`
			`return list(image_processor_input_names + ["original_sizes", "reshaped_input_sizes"])`

			`def post_process_masks(self, args, *kwargs):`
			`return self.image_processor.post_process_masks(args, *kwargs)`


			`__all__ = ["SamProcessor"]`