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from collections import defaultdict | |
from typing import Optional | |
from ..image_utils import load_image | |
from ..utils import ( | |
add_end_docstrings, | |
is_torch_available, | |
logging, | |
requires_backends, | |
) | |
from .base import PIPELINE_INIT_ARGS, ChunkPipeline | |
if is_torch_available(): | |
import torch | |
from ..models.auto.modeling_auto import MODEL_FOR_MASK_GENERATION_MAPPING_NAMES | |
logger = logging.get_logger(__name__) | |
class MaskGenerationPipeline(ChunkPipeline): | |
""" | |
Automatic mask generation for images using `SamForMaskGeneration`. This pipeline predicts binary masks for an | |
image, given an image. It is a `ChunkPipeline` because you can seperate the points in a mini-batch in order to | |
avoid OOM issues. Use the `points_per_batch` argument to control the number of points that will be processed at the | |
same time. Default is `64`. | |
The pipeline works in 3 steps: | |
1. `preprocess`: A grid of 1024 points evenly separated is generated along with bounding boxes and point | |
labels. | |
For more details on how the points and bounding boxes are created, check the `_generate_crop_boxes` | |
function. The image is also preprocessed using the `image_processor`. This function `yields` a minibatch of | |
`points_per_batch`. | |
2. `forward`: feeds the outputs of `preprocess` to the model. The image embedding is computed only once. | |
Calls both `self.model.get_image_embeddings` and makes sure that the gradients are not computed, and the | |
tensors and models are on the same device. | |
3. `postprocess`: The most important part of the automatic mask generation happens here. Three steps | |
are induced: | |
- image_processor.postprocess_masks (run on each minibatch loop): takes in the raw output masks, | |
resizes them according | |
to the image size, and transforms there to binary masks. | |
- image_processor.filter_masks (on each minibatch loop): uses both `pred_iou_thresh` and | |
`stability_scores`. Also | |
applies a variety of filters based on non maximum suppression to remove bad masks. | |
- image_processor.postprocess_masks_for_amg applies the NSM on the mask to only keep relevant ones. | |
Arguments: | |
model ([`PreTrainedModel`] or [`TFPreTrainedModel`]): | |
The model that will be used by the pipeline to make predictions. This needs to be a model inheriting from | |
[`PreTrainedModel`] for PyTorch and [`TFPreTrainedModel`] for TensorFlow. | |
tokenizer ([`PreTrainedTokenizer`]): | |
The tokenizer that will be used by the pipeline to encode data for the model. This object inherits from | |
[`PreTrainedTokenizer`]. | |
feature_extractor ([`SequenceFeatureExtractor`]): | |
The feature extractor that will be used by the pipeline to encode the input. | |
points_per_batch (*optional*, int, default to 64): | |
Sets the number of points run simultaneously by the model. Higher numbers may be faster but use more GPU | |
memory. | |
output_bboxes_mask (`bool`, *optional*, default to `False`): | |
Whether or not to output the bounding box predictions. | |
output_rle_masks (`bool`, *optional*, default to `False`): | |
Whether or not to output the masks in `RLE` format | |
Example: | |
```python | |
>>> from transformers import pipeline | |
>>> generator = pipeline(model="facebook/sam-vit-base", task="mask-generation") | |
>>> outputs = generator( | |
... "http://images.cocodataset.org/val2017/000000039769.jpg", | |
... ) | |
>>> outputs = generator( | |
... "https://huggingface.co./datasets/Narsil/image_dummy/raw/main/parrots.png", points_per_batch=128 | |
... ) | |
``` | |
Learn more about the basics of using a pipeline in the [pipeline tutorial](../pipeline_tutorial) | |
This segmentation pipeline can currently be loaded from [`pipeline`] using the following task identifier: | |
`"mask-generation"`. | |
See the list of available models on [huggingface.co/models](https://huggingface.co./models?filter=mask-generation). | |
""" | |
def __init__(self, **kwargs): | |
super().__init__(**kwargs) | |
requires_backends(self, "vision") | |
requires_backends(self, "torch") | |
if self.framework != "pt": | |
raise ValueError(f"The {self.__class__} is only available in PyTorch.") | |
self.check_model_type(MODEL_FOR_MASK_GENERATION_MAPPING_NAMES) | |
def _sanitize_parameters(self, **kwargs): | |
preprocess_kwargs = {} | |
postprocess_kwargs = {} | |
forward_params = {} | |
# preprocess args | |
if "points_per_batch" in kwargs: | |
preprocess_kwargs["points_per_batch"] = kwargs["points_per_batch"] | |
if "points_per_crop" in kwargs: | |
preprocess_kwargs["points_per_crop"] = kwargs["points_per_crop"] | |
if "crops_n_layers" in kwargs: | |
preprocess_kwargs["crops_n_layers"] = kwargs["crops_n_layers"] | |
if "crop_overlap_ratio" in kwargs: | |
preprocess_kwargs["crop_overlap_ratio"] = kwargs["crop_overlap_ratio"] | |
if "crop_n_points_downscale_factor" in kwargs: | |
preprocess_kwargs["crop_n_points_downscale_factor"] = kwargs["crop_n_points_downscale_factor"] | |
if "timeout" in kwargs: | |
preprocess_kwargs["timeout"] = kwargs["timeout"] | |
# postprocess args | |
if "pred_iou_thresh" in kwargs: | |
forward_params["pred_iou_thresh"] = kwargs["pred_iou_thresh"] | |
if "stability_score_offset" in kwargs: | |
forward_params["stability_score_offset"] = kwargs["stability_score_offset"] | |
if "mask_threshold" in kwargs: | |
forward_params["mask_threshold"] = kwargs["mask_threshold"] | |
if "stability_score_thresh" in kwargs: | |
forward_params["stability_score_thresh"] = kwargs["stability_score_thresh"] | |
if "crops_nms_thresh" in kwargs: | |
postprocess_kwargs["crops_nms_thresh"] = kwargs["crops_nms_thresh"] | |
if "output_rle_mask" in kwargs: | |
postprocess_kwargs["output_rle_mask"] = kwargs["output_rle_mask"] | |
if "output_bboxes_mask" in kwargs: | |
postprocess_kwargs["output_bboxes_mask"] = kwargs["output_bboxes_mask"] | |
return preprocess_kwargs, forward_params, postprocess_kwargs | |
def __call__(self, image, *args, num_workers=None, batch_size=None, **kwargs): | |
""" | |
Generates binary segmentation masks | |
Args: | |
inputs (`np.ndarray` or `bytes` or `str` or `dict`): | |
Image or list of images. | |
mask_threshold (`float`, *optional*, defaults to 0.0): | |
Threshold to use when turning the predicted masks into binary values. | |
pred_iou_thresh (`float`, *optional*, defaults to 0.88): | |
A filtering threshold in `[0,1]` applied on the model's predicted mask quality. | |
stability_score_thresh (`float`, *optional*, defaults to 0.95): | |
A filtering threshold in `[0,1]`, using the stability of the mask under changes to the cutoff used to | |
binarize the model's mask predictions. | |
stability_score_offset (`int`, *optional*, defaults to 1): | |
The amount to shift the cutoff when calculated the stability score. | |
crops_nms_thresh (`float`, *optional*, defaults to 0.7): | |
The box IoU cutoff used by non-maximal suppression to filter duplicate masks. | |
crops_n_layers (`int`, *optional*, defaults to 0): | |
If `crops_n_layers>0`, mask prediction will be run again on crops of the image. Sets the number of | |
layers to run, where each layer has 2**i_layer number of image crops. | |
crop_overlap_ratio (`float`, *optional*, defaults to `512 / 1500`): | |
Sets the degree to which crops overlap. In the first crop layer, crops will overlap by this fraction of | |
the image length. Later layers with more crops scale down this overlap. | |
crop_n_points_downscale_factor (`int`, *optional*, defaults to `1`): | |
The number of points-per-side sampled in layer n is scaled down by crop_n_points_downscale_factor**n. | |
timeout (`float`, *optional*, defaults to None): | |
The maximum time in seconds to wait for fetching images from the web. If None, no timeout is set and | |
the call may block forever. | |
Return: | |
`Dict`: A dictionary with the following keys: | |
- **mask** (`PIL.Image`) -- A binary mask of the detected object as a PIL Image of shape `(width, | |
height)` of the original image. Returns a mask filled with zeros if no object is found. | |
- **score** (*optional* `float`) -- Optionally, when the model is capable of estimating a confidence of | |
the "object" described by the label and the mask. | |
""" | |
return super().__call__(image, *args, num_workers=num_workers, batch_size=batch_size, **kwargs) | |
def preprocess( | |
self, | |
image, | |
points_per_batch=64, | |
crops_n_layers: int = 0, | |
crop_overlap_ratio: float = 512 / 1500, | |
points_per_crop: Optional[int] = 32, | |
crop_n_points_downscale_factor: Optional[int] = 1, | |
timeout: Optional[float] = None, | |
): | |
image = load_image(image, timeout=timeout) | |
target_size = self.image_processor.size["longest_edge"] | |
crop_boxes, grid_points, cropped_images, input_labels = self.image_processor.generate_crop_boxes( | |
image, target_size, crops_n_layers, crop_overlap_ratio, points_per_crop, crop_n_points_downscale_factor | |
) | |
model_inputs = self.image_processor(images=cropped_images, return_tensors="pt") | |
with self.device_placement(): | |
if self.framework == "pt": | |
inference_context = self.get_inference_context() | |
with inference_context(): | |
model_inputs = self._ensure_tensor_on_device(model_inputs, device=self.device) | |
image_embeddings = self.model.get_image_embeddings(model_inputs.pop("pixel_values")) | |
model_inputs["image_embeddings"] = image_embeddings | |
n_points = grid_points.shape[1] | |
points_per_batch = points_per_batch if points_per_batch is not None else n_points | |
if points_per_batch <= 0: | |
raise ValueError( | |
"Cannot have points_per_batch<=0. Must be >=1 to returned batched outputs. " | |
"To return all points at once, set points_per_batch to None" | |
) | |
for i in range(0, n_points, points_per_batch): | |
batched_points = grid_points[:, i : i + points_per_batch, :, :] | |
labels = input_labels[:, i : i + points_per_batch] | |
is_last = i == n_points - points_per_batch | |
yield { | |
"input_points": batched_points, | |
"input_labels": labels, | |
"input_boxes": crop_boxes, | |
"is_last": is_last, | |
**model_inputs, | |
} | |
def _forward( | |
self, | |
model_inputs, | |
pred_iou_thresh=0.88, | |
stability_score_thresh=0.95, | |
mask_threshold=0, | |
stability_score_offset=1, | |
): | |
input_boxes = model_inputs.pop("input_boxes") | |
is_last = model_inputs.pop("is_last") | |
original_sizes = model_inputs.pop("original_sizes").tolist() | |
reshaped_input_sizes = model_inputs.pop("reshaped_input_sizes").tolist() | |
model_outputs = self.model(**model_inputs) | |
# post processing happens here in order to avoid CPU GPU copies of ALL the masks | |
low_resolution_masks = model_outputs["pred_masks"] | |
masks = self.image_processor.post_process_masks( | |
low_resolution_masks, original_sizes, reshaped_input_sizes, mask_threshold, binarize=False | |
) | |
iou_scores = model_outputs["iou_scores"] | |
masks, iou_scores, boxes = self.image_processor.filter_masks( | |
masks[0], | |
iou_scores[0], | |
original_sizes[0], | |
input_boxes[0], | |
pred_iou_thresh, | |
stability_score_thresh, | |
mask_threshold, | |
stability_score_offset, | |
) | |
return { | |
"masks": masks, | |
"is_last": is_last, | |
"boxes": boxes, | |
"iou_scores": iou_scores, | |
} | |
def postprocess( | |
self, | |
model_outputs, | |
output_rle_mask=False, | |
output_bboxes_mask=False, | |
crops_nms_thresh=0.7, | |
): | |
all_scores = [] | |
all_masks = [] | |
all_boxes = [] | |
for model_output in model_outputs: | |
all_scores.append(model_output.pop("iou_scores")) | |
all_masks.extend(model_output.pop("masks")) | |
all_boxes.append(model_output.pop("boxes")) | |
all_scores = torch.cat(all_scores) | |
all_boxes = torch.cat(all_boxes) | |
output_masks, iou_scores, rle_mask, bounding_boxes = self.image_processor.post_process_for_mask_generation( | |
all_masks, all_scores, all_boxes, crops_nms_thresh | |
) | |
extra = defaultdict(list) | |
for output in model_outputs: | |
for k, v in output.items(): | |
extra[k].append(v) | |
optional = {} | |
if output_rle_mask: | |
optional["rle_mask"] = rle_mask | |
if output_bboxes_mask: | |
optional["bounding_boxes"] = bounding_boxes | |
return {"masks": output_masks, "scores": iou_scores, **optional, **extra} | |