DETR¶
Overview¶
The DETR model was proposed in End-to-End Object Detection with Transformers by Nicolas Carion, Francisco Massa, Gabriel Synnaeve, Nicolas Usunier, Alexander Kirillov and Sergey Zagoruyko. DETR consists of a convolutional backbone followed by an encoder-decoder Transformer which can be trained end-to-end for object detection. It greatly simplifies a lot of the complexity of models like Faster-R-CNN and Mask-R-CNN, which use things like region proposals, non-maximum suppression procedure and anchor generation. Moreover, DETR can also be naturally extended to perform panoptic segmentation, by simply adding a mask head on top of the decoder outputs.
The abstract from the paper is the following:
We present a new method that views object detection as a direct set prediction problem. Our approach streamlines the detection pipeline, effectively removing the need for many hand-designed components like a non-maximum suppression procedure or anchor generation that explicitly encode our prior knowledge about the task. The main ingredients of the new framework, called DEtection TRansformer or DETR, are a set-based global loss that forces unique predictions via bipartite matching, and a transformer encoder-decoder architecture. Given a fixed small set of learned object queries, DETR reasons about the relations of the objects and the global image context to directly output the final set of predictions in parallel. The new model is conceptually simple and does not require a specialized library, unlike many other modern detectors. DETR demonstrates accuracy and run-time performance on par with the well-established and highly-optimized Faster RCNN baseline on the challenging COCO object detection dataset. Moreover, DETR can be easily generalized to produce panoptic segmentation in a unified manner. We show that it significantly outperforms competitive baselines.
This model was contributed by nielsr. The original code can be found here.
The quickest way to get started with DETR is by checking the example notebooks (which showcase both inference and fine-tuning on custom data).
Here’s a TLDR explaining how DetrForObjectDetection
works:
First, an image is sent through a pre-trained convolutional backbone (in the paper, the authors use
ResNet-50/ResNet-101). Let’s assume we also add a batch dimension. This means that the input to the backbone is a
tensor of shape (batch_size, 3, height, width)
, assuming the image has 3 color channels (RGB). The CNN backbone
outputs a new lower-resolution feature map, typically of shape (batch_size, 2048, height/32, width/32)
. This is
then projected to match the hidden dimension of the Transformer of DETR, which is 256
by default, using a
nn.Conv2D
layer. So now, we have a tensor of shape (batch_size, 256, height/32, width/32).
Next, the
feature map is flattened and transposed to obtain a tensor of shape (batch_size, seq_len, d_model)
=
(batch_size, width/32*height/32, 256)
. So a difference with NLP models is that the sequence length is actually
longer than usual, but with a smaller d_model
(which in NLP is typically 768 or higher).
Next, this is sent through the encoder, outputting encoder_hidden_states
of the same shape (you can consider
these as image features). Next, so-called object queries are sent through the decoder. This is a tensor of shape
(batch_size, num_queries, d_model)
, with num_queries
typically set to 100 and initialized with zeros.
These input embeddings are learnt positional encodings that the authors refer to as object queries, and similarly to
the encoder, they are added to the input of each attention layer. Each object query will look for a particular object
in the image. The decoder updates these embeddings through multiple self-attention and encoder-decoder attention layers
to output decoder_hidden_states
of the same shape: (batch_size, num_queries, d_model)
. Next, two heads
are added on top for object detection: a linear layer for classifying each object query into one of the objects or “no
object”, and a MLP to predict bounding boxes for each query.
The model is trained using a bipartite matching loss: so what we actually do is compare the predicted classes + bounding boxes of each of the N = 100 object queries to the ground truth annotations, padded up to the same length N (so if an image only contains 4 objects, 96 annotations will just have a “no object” as class and “no bounding box” as bounding box). The Hungarian matching algorithm is used to find an optimal one-to-one mapping of each of the N queries to each of the N annotations. Next, standard cross-entropy (for the classes) and a linear combination of the L1 and generalized IoU loss (for the bounding boxes) are used to optimize the parameters of the model.
DETR can be naturally extended to perform panoptic segmentation (which unifies semantic segmentation and instance
segmentation). DetrForSegmentation
adds a segmentation mask head on top of
DetrForObjectDetection
. The mask head can be trained either jointly, or in a two steps process,
where one first trains a DetrForObjectDetection
model to detect bounding boxes around both
“things” (instances) and “stuff” (background things like trees, roads, sky), then freeze all the weights and train only
the mask head for 25 epochs. Experimentally, these two approaches give similar results. Note that predicting boxes is
required for the training to be possible, since the Hungarian matching is computed using distances between boxes.
Tips:
DETR uses so-called object queries to detect objects in an image. The number of queries determines the maximum number of objects that can be detected in a single image, and is set to 100 by default (see parameter
num_queries
ofDetrConfig
). Note that it’s good to have some slack (in COCO, the authors used 100, while the maximum number of objects in a COCO image is ~70).The decoder of DETR updates the query embeddings in parallel. This is different from language models like GPT-2, which use autoregressive decoding instead of parallel. Hence, no causal attention mask is used.
DETR adds position embeddings to the hidden states at each self-attention and cross-attention layer before projecting to queries and keys. For the position embeddings of the image, one can choose between fixed sinusoidal or learned absolute position embeddings. By default, the parameter
position_embedding_type
ofDetrConfig
is set to"sine"
.During training, the authors of DETR did find it helpful to use auxiliary losses in the decoder, especially to help the model output the correct number of objects of each class. If you set the parameter
auxiliary_loss
ofDetrConfig
toTrue
, then prediction feedforward neural networks and Hungarian losses are added after each decoder layer (with the FFNs sharing parameters).If you want to train the model in a distributed environment across multiple nodes, then one should update the num_boxes variable in the DetrLoss class of modeling_detr.py. When training on multiple nodes, this should be set to the average number of target boxes across all nodes, as can be seen in the original implementation here.
DetrForObjectDetection
andDetrForSegmentation
can be initialized with any convolutional backbone available in the timm library. Initializing with a MobileNet backbone for example can be done by setting thebackbone
attribute ofDetrConfig
to"tf_mobilenetv3_small_075"
, and then initializing the model with that config.DETR resizes the input images such that the shortest side is at least a certain amount of pixels while the longest is at most 1333 pixels. At training time, scale augmentation is used such that the shortest side is randomly set to at least 480 and at most 800 pixels. At inference time, the shortest side is set to 800. One can use
DetrFeatureExtractor
to prepare images (and optional annotations in COCO format) for the model. Due to this resizing, images in a batch can have different sizes. DETR solves this by padding images up to the largest size in a batch, and by creating a pixel mask that indicates which pixels are real/which are padding. Alternatively, one can also define a customcollate_fn
in order to batch images together, usingpad_and_create_pixel_mask()
.The size of the images will determine the amount of memory being used, and will thus determine the
batch_size
. It is advised to use a batch size of 2 per GPU. See this Github thread for more info.
As a summary, consider the following table:
Task |
Object detection |
Instance segmentation |
Panoptic segmentation |
Description |
Predicting bounding boxes and class labels around objects in an image |
Predicting masks around objects (i.e. instances) in an image |
Predicting masks around both objects (i.e. instances) as well as “stuff” (i.e. background things like trees and roads) in an image |
Model |
|||
Example dataset |
COCO detection |
COCO detection, COCO panoptic |
COCO panoptic |
Format of annotations to provide to
|
{‘image_id’: int, ‘annotations’: List[Dict]}, each Dict being a COCO object annotation |
{‘image_id’: int, ‘annotations’: [List[Dict]] } (in case of COCO detection) or {‘file_name’: str, ‘image_id’: int, ‘segments_info’: List[Dict]} (in case of COCO panoptic) |
{‘file_name: str, ‘image_id: int, ‘segments_info’: List[Dict] } and masks_path (path to directory containing PNG files of the masks) |
Postprocessing (i.e. converting the output of the model to COCO API) |
|||
evaluators |
|
|
|
In short, one should prepare the data either in COCO detection or COCO panoptic format, then use
DetrFeatureExtractor
to create pixel_values
, pixel_mask
and optional
labels
, which can then be used to train (or fine-tune) a model. For evaluation, one should first convert the
outputs of the model using one of the postprocessing methods of DetrFeatureExtractor
. These can
be be provided to either CocoEvaluator
or PanopticEvaluator
, which allow you to calculate metrics like
mean Average Precision (mAP) and Panoptic Quality (PQ). The latter objects are implemented in the original repository. See the example notebooks for more info regarding evaluation.
DETR specific outputs¶
-
class
transformers.models.detr.modeling_detr.
DetrModelOutput
(last_hidden_state: Optional[torch.FloatTensor] = None, past_key_values: Optional[Tuple[Tuple[torch.FloatTensor]]] = None, decoder_hidden_states: Optional[Tuple[torch.FloatTensor]] = None, decoder_attentions: Optional[Tuple[torch.FloatTensor]] = None, cross_attentions: Optional[Tuple[torch.FloatTensor]] = None, encoder_last_hidden_state: Optional[torch.FloatTensor] = None, encoder_hidden_states: Optional[Tuple[torch.FloatTensor]] = None, encoder_attentions: Optional[Tuple[torch.FloatTensor]] = None, intermediate_hidden_states: Optional[torch.FloatTensor] = None)[source]¶ Base class for outputs of the DETR encoder-decoder model. This class adds one attribute to Seq2SeqModelOutput, namely an optional stack of intermediate decoder activations, i.e. the output of each decoder layer, each of them gone through a layernorm. This is useful when training the model with auxiliary decoding losses.
- Parameters
last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
) – Sequence of hidden-states at the output of the last layer of the decoder of the model.decoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the decoder at the output of each layer plus the initial embedding outputs.decoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder, after the attention softmax, used to compute the weighted average in the self-attention heads.cross_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder’s cross-attention layer, after the attention softmax, used to compute the weighted average in the cross-attention heads.encoder_last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the encoder of the model.encoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the encoder at the output of each layer plus the initial embedding outputs.encoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the encoder, after the attention softmax, used to compute the weighted average in the self-attention heads.intermediate_hidden_states (
torch.FloatTensor
of shape(config.decoder_layers, batch_size, sequence_length, hidden_size)
, optional, returned whenconfig.auxiliary_loss=True
) – Intermediate decoder activations, i.e. the output of each decoder layer, each of them gone through a layernorm.
-
class
transformers.models.detr.modeling_detr.
DetrObjectDetectionOutput
(loss: Optional[torch.FloatTensor] = None, loss_dict: Optional[Dict] = None, logits: Optional[torch.FloatTensor] = None, pred_boxes: Optional[torch.FloatTensor] = None, auxiliary_outputs: Optional[List[Dict]] = None, last_hidden_state: Optional[torch.FloatTensor] = None, decoder_hidden_states: Optional[Tuple[torch.FloatTensor]] = None, decoder_attentions: Optional[Tuple[torch.FloatTensor]] = None, cross_attentions: Optional[Tuple[torch.FloatTensor]] = None, encoder_last_hidden_state: Optional[torch.FloatTensor] = None, encoder_hidden_states: Optional[Tuple[torch.FloatTensor]] = None, encoder_attentions: Optional[Tuple[torch.FloatTensor]] = None)[source]¶ Output type of
DetrForObjectDetection
.- Parameters
loss (
torch.FloatTensor
of shape(1,)
, optional, returned whenlabels
are provided)) – Total loss as a linear combination of a negative log-likehood (cross-entropy) for class prediction and a bounding box loss. The latter is defined as a linear combination of the L1 loss and the generalized scale-invariant IoU loss.loss_dict (
Dict
, optional) – A dictionary containing the individual losses. Useful for logging.logits (
torch.FloatTensor
of shape(batch_size, num_queries, num_classes + 1)
) – Classification logits (including no-object) for all queries.pred_boxes (
torch.FloatTensor
of shape(batch_size, num_queries, 4)
) – Normalized boxes coordinates for all queries, represented as (center_x, center_y, width, height). These values are normalized in [0, 1], relative to the size of each individual image in the batch (disregarding possible padding). You can usepost_process()
to retrieve the unnormalized bounding boxes.auxiliary_outputs (
list[Dict]
, optional) – Optional, only returned when auxilary losses are activated (i.e.config.auxiliary_loss
is set to True) and labels are provided. It is a list of dictionnaries containing the two above keys (logits
andpred_boxes
) for each decoder layer.last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the decoder of the model.decoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the decoder at the output of each layer plus the initial embedding outputs.decoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder, after the attention softmax, used to compute the weighted average in the self-attention heads.cross_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder’s cross-attention layer, after the attention softmax, used to compute the weighted average in the cross-attention heads.encoder_last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the encoder of the model.encoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the encoder at the output of each layer plus the initial embedding outputs.encoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the encoder, after the attention softmax, used to compute the weighted average in the self-attention heads.
-
class
transformers.models.detr.modeling_detr.
DetrSegmentationOutput
(loss: Optional[torch.FloatTensor] = None, loss_dict: Optional[Dict] = None, logits: Optional[torch.FloatTensor] = None, pred_boxes: Optional[torch.FloatTensor] = None, pred_masks: Optional[torch.FloatTensor] = None, auxiliary_outputs: Optional[List[Dict]] = None, last_hidden_state: Optional[torch.FloatTensor] = None, decoder_hidden_states: Optional[Tuple[torch.FloatTensor]] = None, decoder_attentions: Optional[Tuple[torch.FloatTensor]] = None, cross_attentions: Optional[Tuple[torch.FloatTensor]] = None, encoder_last_hidden_state: Optional[torch.FloatTensor] = None, encoder_hidden_states: Optional[Tuple[torch.FloatTensor]] = None, encoder_attentions: Optional[Tuple[torch.FloatTensor]] = None)[source]¶ Output type of
DetrForSegmentation
.- Parameters
loss (
torch.FloatTensor
of shape(1,)
, optional, returned whenlabels
are provided)) – Total loss as a linear combination of a negative log-likehood (cross-entropy) for class prediction and a bounding box loss. The latter is defined as a linear combination of the L1 loss and the generalized scale-invariant IoU loss.loss_dict (
Dict
, optional) – A dictionary containing the individual losses. Useful for logging.logits (
torch.FloatTensor
of shape(batch_size, num_queries, num_classes + 1)
) – Classification logits (including no-object) for all queries.pred_boxes (
torch.FloatTensor
of shape(batch_size, num_queries, 4)
) – Normalized boxes coordinates for all queries, represented as (center_x, center_y, width, height). These values are normalized in [0, 1], relative to the size of each individual image in the batch (disregarding possible padding). You can usepost_process()
to retrieve the unnormalized bounding boxes.pred_masks (
torch.FloatTensor
of shape(batch_size, num_queries, height/4, width/4)
) – Segmentation masks logits for all queries. See alsopost_process_segmentation()
orpost_process_panoptic()
to evaluate instance and panoptic segmentation masks respectively.auxiliary_outputs (
list[Dict]
, optional) – Optional, only returned when auxilary losses are activated (i.e.config.auxiliary_loss
is set to True) and labels are provided. It is a list of dictionnaries containing the two above keys (logits
andpred_boxes
) for each decoder layer.last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the decoder of the model.decoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the decoder at the output of each layer plus the initial embedding outputs.decoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder, after the attention softmax, used to compute the weighted average in the self-attention heads.cross_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder’s cross-attention layer, after the attention softmax, used to compute the weighted average in the cross-attention heads.encoder_last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the encoder of the model.encoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the encoder at the output of each layer plus the initial embedding outputs.encoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the encoder, after the attention softmax, used to compute the weighted average in the self-attention heads.
DetrConfig¶
-
class
transformers.
DetrConfig
(num_queries=100, max_position_embeddings=1024, encoder_layers=6, encoder_ffn_dim=2048, encoder_attention_heads=8, decoder_layers=6, decoder_ffn_dim=2048, decoder_attention_heads=8, encoder_layerdrop=0.0, decoder_layerdrop=0.0, is_encoder_decoder=True, activation_function='relu', d_model=256, dropout=0.1, attention_dropout=0.0, activation_dropout=0.0, init_std=0.02, init_xavier_std=1.0, classifier_dropout=0.0, scale_embedding=False, auxiliary_loss=False, position_embedding_type='sine', backbone='resnet50', dilation=False, class_cost=1, bbox_cost=5, giou_cost=2, mask_loss_coefficient=1, dice_loss_coefficient=1, bbox_loss_coefficient=5, giou_loss_coefficient=2, eos_coefficient=0.1, **kwargs)[source]¶ This is the configuration class to store the configuration of a
DetrModel
. It is used to instantiate a DETR model according to the specified arguments, defining the model architecture. Instantiating a configuration with the defaults will yield a similar configuration to that of the DETR facebook/detr-resnet-50 architecture.Configuration objects inherit from
PretrainedConfig
and can be used to control the model outputs. Read the documentation fromPretrainedConfig
for more information.- Parameters
num_queries (
int
, optional, defaults to 100) – Number of object queries, i.e. detection slots. This is the maximal number of objectsDetrModel
can detect in a single image. For COCO, we recommend 100 queries.d_model (
int
, optional, defaults to 256) – Dimension of the layers.encoder_layers (
int
, optional, defaults to 6) – Number of encoder layers.decoder_layers (
int
, optional, defaults to 6) – Number of decoder layers.encoder_attention_heads (
int
, optional, defaults to 8) – Number of attention heads for each attention layer in the Transformer encoder.decoder_attention_heads (
int
, optional, defaults to 8) – Number of attention heads for each attention layer in the Transformer decoder.decoder_ffn_dim (
int
, optional, defaults to 2048) – Dimension of the “intermediate” (often named feed-forward) layer in decoder.encoder_ffn_dim (
int
, optional, defaults to 2048) – Dimension of the “intermediate” (often named feed-forward) layer in decoder.activation_function (
str
orfunction
, optional, defaults to"relu"
) – The non-linear activation function (function or string) in the encoder and pooler. If string,"gelu"
,"relu"
,"silu"
and"gelu_new"
are supported.dropout (
float
, optional, defaults to 0.1) – The dropout probability for all fully connected layers in the embeddings, encoder, and pooler.attention_dropout (
float
, optional, defaults to 0.0) – The dropout ratio for the attention probabilities.activation_dropout (
float
, optional, defaults to 0.0) – The dropout ratio for activations inside the fully connected layer.init_std (
float
, optional, defaults to 0.02) – The standard deviation of the truncated_normal_initializer for initializing all weight matrices.init_xavier_std (
float
, optional, defaults to 1) – The scaling factor used for the Xavier initialization gain in the HM Attention map module.encoder_layerdrop – (
float
, optional, defaults to 0.0): The LayerDrop probability for the encoder. See the LayerDrop paper for more details.decoder_layerdrop – (
float
, optional, defaults to 0.0): The LayerDrop probability for the decoder. See the LayerDrop paper for more details.auxiliary_loss (
bool
, optional, defaults toFalse
) – Whether auxiliary decoding losses (loss at each decoder layer) are to be used.position_embedding_type (
str
, optional, defaults to"sine"
) – Type of position embeddings to be used on top of the image features. One of"sine"
or"learned"
.backbone (
str
, optional, defaults to"resnet50"
) – Name of convolutional backbone to use. Supports any convolutional backbone from the timm package. For a list of all available models, see this page.dilation (
bool
, optional, defaults toFalse
) – Whether to replace stride with dilation in the last convolutional block (DC5).class_cost (
float
, optional, defaults to 1) – Relative weight of the classification error in the Hungarian matching cost.bbox_cost (
float
, optional, defaults to 5) – Relative weight of the L1 error of the bounding box coordinates in the Hungarian matching cost.giou_cost (
float
, optional, defaults to 2) – Relative weight of the generalized IoU loss of the bounding box in the Hungarian matching cost.mask_loss_coefficient (
float
, optional, defaults to 1) – Relative weight of the Focal loss in the panoptic segmentation loss.dice_loss_coefficient (
float
, optional, defaults to 1) – Relative weight of the DICE/F-1 loss in the panoptic segmentation loss.bbox_loss_coefficient (
float
, optional, defaults to 5) – Relative weight of the L1 bounding box loss in the object detection loss.giou_loss_coefficient (
float
, optional, defaults to 2) – Relative weight of the generalized IoU loss in the object detection loss.eos_coefficient (
float
, optional, defaults to 0.1) – Relative classification weight of the ‘no-object’ class in the object detection loss.
Examples:
>>> from transformers import DetrModel, DetrConfig >>> # Initializing a DETR facebook/detr-resnet-50 style configuration >>> configuration = DetrConfig() >>> # Initializing a model from the facebook/detr-resnet-50 style configuration >>> model = DetrModel(configuration) >>> # Accessing the model configuration >>> configuration = model.config
DetrFeatureExtractor¶
-
class
transformers.
DetrFeatureExtractor
(format='coco_detection', do_resize=True, size=800, max_size=1333, do_normalize=True, image_mean=None, image_std=None, **kwargs)[source]¶ Constructs a DETR feature extractor.
This feature extractor inherits from
FeatureExtractionMixin
which contains most of the main methods. Users should refer to this superclass for more information regarding those methods.- Parameters
format (
str
, optional, defaults to"coco_detection"
) – Data format of the annotations. One of “coco_detection” or “coco_panoptic”.do_resize (
bool
, optional, defaults toTrue
) – Whether to resize the input to a certainsize
.size (
int
, optional, defaults to 800) – Resize the input to the given size. Only has an effect ifdo_resize
is set toTrue
. If size is a sequence like(width, height)
, output size will be matched to this. If size is an int, smaller edge of the image will be matched to this number. i.e, ifheight > width
, then image will be rescaled to(size * height / width, size)
.max_size (
int
, optional, defaults to1333
) – The largest size an image dimension can have (otherwise it’s capped). Only has an effect ifdo_resize
is set toTrue
.do_normalize (
bool
, optional, defaults toTrue
) – Whether or not to normalize the input with mean and standard deviation.image_mean (
int
, optional, defaults to[0.485, 0.456, 0.406]
) – The sequence of means for each channel, to be used when normalizing images. Defaults to the ImageNet mean.image_std (
int
, optional, defaults to[0.229, 0.224, 0.225]
) – The sequence of standard deviations for each channel, to be used when normalizing images. Defaults to the ImageNet std.
-
__call__
(images: Union[PIL.Image.Image, numpy.ndarray, torch.Tensor, List[PIL.Image.Image], List[numpy.ndarray], List[torch.Tensor]], annotations: Optional[Union[List[Dict], List[List[Dict]]]] = None, return_segmentation_masks: Optional[bool] = False, masks_path: Optional[pathlib.Path] = None, pad_and_return_pixel_mask: Optional[bool] = True, return_tensors: Optional[Union[str, transformers.file_utils.TensorType]] = None, **kwargs) → transformers.feature_extraction_utils.BatchFeature[source]¶ Main method to prepare for the model one or several image(s) and optional annotations. Images are by default padded up to the largest image in a batch, and a pixel mask is created that indicates which pixels are real/which are padding.
Warning
NumPy arrays and PyTorch tensors are converted to PIL images when resizing, so the most efficient is to pass PIL images.
- Parameters
images (
PIL.Image.Image
,np.ndarray
,torch.Tensor
,List[PIL.Image.Image]
,List[np.ndarray]
,List[torch.Tensor]
) – The image or batch of images to be prepared. Each image can be a PIL image, NumPy array or PyTorch tensor. In case of a NumPy array/PyTorch tensor, each image should be of shape (C, H, W), where C is a number of channels, H and W are image height and width.annotations (
Dict
,List[Dict]
, optional) –The corresponding annotations in COCO format.
In case
DetrFeatureExtractor
was initialized withformat = "coco_detection"
, the annotations for each image should have the following format: {‘image_id’: int, ‘annotations’: [annotation]}, with the annotations being a list of COCO object annotations.In case
DetrFeatureExtractor
was initialized withformat = "coco_panoptic"
, the annotations for each image should have the following format: {‘image_id’: int, ‘file_name’: str, ‘segments_info’: [segment_info]} with segments_info being a list of COCO panoptic annotations.return_segmentation_masks (
Dict
,List[Dict]
, optional, defaults toFalse
) – Whether to also include instance segmentation masks as part of the labels in caseformat = "coco_detection"
.masks_path (
pathlib.Path
, optional) – Path to the directory containing the PNG files that store the class-agnostic image segmentations. Only relevant in caseDetrFeatureExtractor
was initialized withformat = "coco_panoptic"
.pad_and_return_pixel_mask (
bool
, optional, defaults toTrue
) –Whether or not to pad images up to the largest image in a batch and create a pixel mask.
If left to the default, will return a pixel mask that is:
1 for pixels that are real (i.e. not masked),
0 for pixels that are padding (i.e. masked).
return_tensors (
str
orTensorType
, optional) – If set, will return tensors instead of NumPy arrays. If set to'pt'
, return PyTorchtorch.Tensor
objects.
- Returns
A
BatchFeature
with the following fields:pixel_values – Pixel values to be fed to a model.
pixel_mask – Pixel mask to be fed to a model (when
pad_and_return_pixel_mask=True
or if “pixel_mask” is inself.model_input_names
).labels – Optional labels to be fed to a model (when
annotations
are provided)
- Return type
-
pad_and_create_pixel_mask
(pixel_values_list: List[torch.Tensor], return_tensors: Optional[Union[str, transformers.file_utils.TensorType]] = None)[source]¶ Pad images up to the largest image in a batch and create a corresponding
pixel_mask
.- Parameters
pixel_values_list (
List[torch.Tensor]
) – List of images (pixel values) to be padded. Each image should be a tensor of shape (C, H, W).return_tensors (
str
orTensorType
, optional) – If set, will return tensors instead of NumPy arrays. If set to'pt'
, return PyTorchtorch.Tensor
objects.
- Returns
A
BatchFeature
with the following fields:pixel_values – Pixel values to be fed to a model.
pixel_mask – Pixel mask to be fed to a model (when
pad_and_return_pixel_mask=True
or if “pixel_mask” is inself.model_input_names
).
- Return type
-
post_process
(outputs, target_sizes)[source]¶ Converts the output of
DetrForObjectDetection
into the format expected by the COCO api. Only supports PyTorch.- Parameters
outputs (
DetrObjectDetectionOutput
) – Raw outputs of the model.target_sizes (
torch.Tensor
of shape(batch_size, 2)
, optional) – Tensor containing the size (h, w) of each image of the batch. For evaluation, this must be the original image size (before any data augmentation). For visualization, this should be the image size after data augment, but before padding.
- Returns
A list of dictionaries, each dictionary containing the scores, labels and boxes for an image in the batch as predicted by the model.
- Return type
List[Dict]
-
post_process_panoptic
(outputs, processed_sizes, target_sizes=None, is_thing_map=None, threshold=0.85)[source]¶ Converts the output of
DetrForSegmentation
into actual panoptic predictions. Only supports PyTorch.- Parameters
outputs (
DetrSegmentationOutput
) – Raw outputs of the model.processed_sizes (
torch.Tensor
of shape(batch_size, 2)
orList[Tuple]
of lengthbatch_size
) – Torch Tensor (or list) containing the size (h, w) of each image of the batch, i.e. the size after data augmentation but before batching.target_sizes (
torch.Tensor
of shape(batch_size, 2)
orList[Tuple]
of lengthbatch_size
, optional) – Torch Tensor (or list) corresponding to the requested final size (h, w) of each prediction. If left to None, it will default to theprocessed_sizes
.is_thing_map (
torch.Tensor
of shape(batch_size, 2)
, optional) – Dictionary mapping class indices to either True or False, depending on whether or not they are a thing. If not set, defaults to theis_thing_map
of COCO panoptic.threshold (
float
, optional, defaults to 0.85) – Threshold to use to filter out queries.
- Returns
A list of dictionaries, each dictionary containing a PNG string and segments_info values for an image in the batch as predicted by the model.
- Return type
List[Dict]
-
post_process_segmentation
(results, outputs, orig_target_sizes, max_target_sizes, threshold=0.5)[source]¶ Converts the output of
DetrForSegmentation
into actual instance segmentation predictions. Only supports PyTorch.- Parameters
results (
List[Dict]
) – Results list obtained bypost_process()
, to which “masks” results will be added.outputs (
DetrSegmentationOutput
) – Raw outputs of the model.orig_target_sizes (
torch.Tensor
of shape(batch_size, 2)
) – Tensor containing the size (h, w) of each image of the batch. For evaluation, this must be the original image size (before any data augmentation).max_target_sizes (
torch.Tensor
of shape(batch_size, 2)
) – Tensor containing the maximum size (h, w) of each image of the batch. For evaluation, this must be the original image size (before any data augmentation).threshold (
float
, optional, defaults to 0.5) – Threshold to use when turning the predicted masks into binary values.
- Returns
A list of dictionaries, each dictionary containing the scores, labels, boxes and masks for an image in the batch as predicted by the model.
- Return type
List[Dict]
DetrModel¶
-
class
transformers.
DetrModel
(config: transformers.models.detr.configuration_detr.DetrConfig)[source]¶ The bare DETR Model (consisting of a backbone and encoder-decoder Transformer) outputting raw hidden-states without any specific head on top.
This model inherits from
PreTrainedModel
. Check the superclass documentation for the generic methods the library implements for all its model (such as downloading or saving, resizing the input embeddings, pruning heads etc.)This model is also a PyTorch torch.nn.Module subclass. Use it as a regular PyTorch Module and refer to the PyTorch documentation for all matter related to general usage and behavior.
- Parameters
config (
DetrConfig
) – Model configuration class with all the parameters of the model. Initializing with a config file does not load the weights associated with the model, only the configuration. Check out thefrom_pretrained()
method to load the model weights.
-
forward
(pixel_values, pixel_mask=None, decoder_attention_mask=None, encoder_outputs=None, inputs_embeds=None, decoder_inputs_embeds=None, output_attentions=None, output_hidden_states=None, return_dict=None)[source]¶ The
DetrModel
forward method, overrides the__call__()
special method.Note
Although the recipe for forward pass needs to be defined within this function, one should call the
Module
instance afterwards instead of this since the former takes care of running the pre and post processing steps while the latter silently ignores them.- Parameters
pixel_values (
torch.FloatTensor
of shape(batch_size, num_channels, height, width)
) –Pixel values. Padding will be ignored by default should you provide it.
Pixel values can be obtained using
DetrFeatureExtractor
. Seetransformers.DetrFeatureExtractor.__call__()
for details.pixel_mask (
torch.LongTensor
of shape(batch_size, height, width)
, optional) –Mask to avoid performing attention on padding pixel values. Mask values selected in
[0, 1]
:1 for pixels that are real (i.e. not masked),
0 for pixels that are padding (i.e. masked).
decoder_attention_mask (
torch.LongTensor
of shape(batch_size, num_queries)
, optional) – Not used by default. Can be used to mask object queries.encoder_outputs (
tuple(tuple(torch.FloatTensor)
, optional) – Tuple consists of (last_hidden_state
, optional:hidden_states
, optional:attentions
)last_hidden_state
of shape(batch_size, sequence_length, hidden_size)
, optional) is a sequence of hidden-states at the output of the last layer of the encoder. Used in the cross-attention of the decoder.inputs_embeds (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Optionally, instead of passing the flattened feature map (output of the backbone + projection layer), you can choose to directly pass a flattened representation of an image.decoder_inputs_embeds (
torch.FloatTensor
of shape(batch_size, num_queries, hidden_size)
, optional) – Optionally, instead of initializing the queries with a tensor of zeros, you can choose to directly pass an embedded representation.output_attentions (
bool
, optional) – Whether or not to return the attentions tensors of all attention layers. Seeattentions
under returned tensors for more detail.output_hidden_states (
bool
, optional) – Whether or not to return the hidden states of all layers. Seehidden_states
under returned tensors for more detail.return_dict (
bool
, optional) – Whether or not to return aModelOutput
instead of a plain tuple.
- Returns
A
DetrModelOutput
or a tuple oftorch.FloatTensor
(ifreturn_dict=False
is passed or whenconfig.return_dict=False
) comprising various elements depending on the configuration (DetrConfig
) and inputs.last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
) – Sequence of hidden-states at the output of the last layer of the decoder of the model.decoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the decoder at the output of each layer plus the initial embedding outputs.decoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder, after the attention softmax, used to compute the weighted average in the self-attention heads.cross_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder’s cross-attention layer, after the attention softmax, used to compute the weighted average in the cross-attention heads.encoder_last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the encoder of the model.encoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the encoder at the output of each layer plus the initial embedding outputs.encoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the encoder, after the attention softmax, used to compute the weighted average in the self-attention heads.intermediate_hidden_states (
torch.FloatTensor
of shape(config.decoder_layers, batch_size, sequence_length, hidden_size)
, optional, returned whenconfig.auxiliary_loss=True
) – Intermediate decoder activations, i.e. the output of each decoder layer, each of them gone through a layernorm.
Examples:
>>> from transformers import DetrFeatureExtractor, DetrModel >>> from PIL import Image >>> import requests >>> url = 'http://images.cocodataset.org/val2017/000000039769.jpg' >>> image = Image.open(requests.get(url, stream=True).raw) >>> feature_extractor = DetrFeatureExtractor.from_pretrained('facebook/detr-resnet-50') >>> model = DetrModel.from_pretrained('facebook/detr-resnet-50') >>> inputs = feature_extractor(images=image, return_tensors="pt") >>> outputs = model(**inputs) >>> last_hidden_states = outputs.last_hidden_state
- Return type
DetrModelOutput
ortuple(torch.FloatTensor)
DetrForObjectDetection¶
-
class
transformers.
DetrForObjectDetection
(config: transformers.models.detr.configuration_detr.DetrConfig)[source]¶ DETR Model (consisting of a backbone and encoder-decoder Transformer) with object detection heads on top, for tasks such as COCO detection.
This model inherits from
PreTrainedModel
. Check the superclass documentation for the generic methods the library implements for all its model (such as downloading or saving, resizing the input embeddings, pruning heads etc.)This model is also a PyTorch torch.nn.Module subclass. Use it as a regular PyTorch Module and refer to the PyTorch documentation for all matter related to general usage and behavior.
- Parameters
config (
DetrConfig
) – Model configuration class with all the parameters of the model. Initializing with a config file does not load the weights associated with the model, only the configuration. Check out thefrom_pretrained()
method to load the model weights.
-
forward
(pixel_values, pixel_mask=None, decoder_attention_mask=None, encoder_outputs=None, inputs_embeds=None, decoder_inputs_embeds=None, labels=None, output_attentions=None, output_hidden_states=None, return_dict=None)[source]¶ The
DetrForObjectDetection
forward method, overrides the__call__()
special method.Note
Although the recipe for forward pass needs to be defined within this function, one should call the
Module
instance afterwards instead of this since the former takes care of running the pre and post processing steps while the latter silently ignores them.- Parameters
pixel_values (
torch.FloatTensor
of shape(batch_size, num_channels, height, width)
) –Pixel values. Padding will be ignored by default should you provide it.
Pixel values can be obtained using
DetrFeatureExtractor
. Seetransformers.DetrFeatureExtractor.__call__()
for details.pixel_mask (
torch.LongTensor
of shape(batch_size, height, width)
, optional) –Mask to avoid performing attention on padding pixel values. Mask values selected in
[0, 1]
:1 for pixels that are real (i.e. not masked),
0 for pixels that are padding (i.e. masked).
decoder_attention_mask (
torch.LongTensor
of shape(batch_size, num_queries)
, optional) – Not used by default. Can be used to mask object queries.encoder_outputs (
tuple(tuple(torch.FloatTensor)
, optional) – Tuple consists of (last_hidden_state
, optional:hidden_states
, optional:attentions
)last_hidden_state
of shape(batch_size, sequence_length, hidden_size)
, optional) is a sequence of hidden-states at the output of the last layer of the encoder. Used in the cross-attention of the decoder.inputs_embeds (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Optionally, instead of passing the flattened feature map (output of the backbone + projection layer), you can choose to directly pass a flattened representation of an image.decoder_inputs_embeds (
torch.FloatTensor
of shape(batch_size, num_queries, hidden_size)
, optional) – Optionally, instead of initializing the queries with a tensor of zeros, you can choose to directly pass an embedded representation.output_attentions (
bool
, optional) – Whether or not to return the attentions tensors of all attention layers. Seeattentions
under returned tensors for more detail.output_hidden_states (
bool
, optional) – Whether or not to return the hidden states of all layers. Seehidden_states
under returned tensors for more detail.return_dict (
bool
, optional) – Whether or not to return aModelOutput
instead of a plain tuple.labels (
List[Dict]
of len(batch_size,)
, optional) – Labels for computing the bipartite matching loss. List of dicts, each dictionary containing at least the following 2 keys: ‘class_labels’ and ‘boxes’ (the class labels and bounding boxes of an image in the batch respectively). The class labels themselves should be atorch.LongTensor
of len(number of bounding boxes in the image,)
and the boxes atorch.FloatTensor
of shape(number of bounding boxes in the image, 4)
.
- Returns
A
DetrObjectDetectionOutput
or a tuple oftorch.FloatTensor
(ifreturn_dict=False
is passed or whenconfig.return_dict=False
) comprising various elements depending on the configuration (DetrConfig
) and inputs.loss (
torch.FloatTensor
of shape(1,)
, optional, returned whenlabels
are provided)) – Total loss as a linear combination of a negative log-likehood (cross-entropy) for class prediction and a bounding box loss. The latter is defined as a linear combination of the L1 loss and the generalized scale-invariant IoU loss.loss_dict (
Dict
, optional) – A dictionary containing the individual losses. Useful for logging.logits (
torch.FloatTensor
of shape(batch_size, num_queries, num_classes + 1)
) – Classification logits (including no-object) for all queries.pred_boxes (
torch.FloatTensor
of shape(batch_size, num_queries, 4)
) – Normalized boxes coordinates for all queries, represented as (center_x, center_y, width, height). These values are normalized in [0, 1], relative to the size of each individual image in the batch (disregarding possible padding). You can usepost_process()
to retrieve the unnormalized bounding boxes.auxiliary_outputs (
list[Dict]
, optional) – Optional, only returned when auxilary losses are activated (i.e.config.auxiliary_loss
is set to True) and labels are provided. It is a list of dictionnaries containing the two above keys (logits
andpred_boxes
) for each decoder layer.last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the decoder of the model.decoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the decoder at the output of each layer plus the initial embedding outputs.decoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder, after the attention softmax, used to compute the weighted average in the self-attention heads.cross_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder’s cross-attention layer, after the attention softmax, used to compute the weighted average in the cross-attention heads.encoder_last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the encoder of the model.encoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the encoder at the output of each layer plus the initial embedding outputs.encoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the encoder, after the attention softmax, used to compute the weighted average in the self-attention heads.
Examples:
>>> from transformers import DetrFeatureExtractor, DetrForObjectDetection >>> from PIL import Image >>> import requests >>> url = 'http://images.cocodataset.org/val2017/000000039769.jpg' >>> image = Image.open(requests.get(url, stream=True).raw) >>> feature_extractor = DetrFeatureExtractor.from_pretrained('facebook/detr-resnet-50') >>> model = DetrForObjectDetection.from_pretrained('facebook/detr-resnet-50') >>> inputs = feature_extractor(images=image, return_tensors="pt") >>> outputs = model(**inputs) >>> # model predicts bounding boxes and corresponding COCO classes >>> logits = outputs.logits >>> bboxes = outputs.pred_boxes
- Return type
DetrObjectDetectionOutput
ortuple(torch.FloatTensor)
DetrForSegmentation¶
-
class
transformers.
DetrForSegmentation
(config: transformers.models.detr.configuration_detr.DetrConfig)[source]¶ DETR Model (consisting of a backbone and encoder-decoder Transformer) with a segmentation head on top, for tasks such as COCO panoptic.
This model inherits from
PreTrainedModel
. Check the superclass documentation for the generic methods the library implements for all its model (such as downloading or saving, resizing the input embeddings, pruning heads etc.)This model is also a PyTorch torch.nn.Module subclass. Use it as a regular PyTorch Module and refer to the PyTorch documentation for all matter related to general usage and behavior.
- Parameters
config (
DetrConfig
) – Model configuration class with all the parameters of the model. Initializing with a config file does not load the weights associated with the model, only the configuration. Check out thefrom_pretrained()
method to load the model weights.
-
forward
(pixel_values, pixel_mask=None, decoder_attention_mask=None, encoder_outputs=None, inputs_embeds=None, decoder_inputs_embeds=None, labels=None, output_attentions=None, output_hidden_states=None, return_dict=None)[source]¶ The
DetrForSegmentation
forward method, overrides the__call__()
special method.Note
Although the recipe for forward pass needs to be defined within this function, one should call the
Module
instance afterwards instead of this since the former takes care of running the pre and post processing steps while the latter silently ignores them.- Parameters
pixel_values (
torch.FloatTensor
of shape(batch_size, num_channels, height, width)
) –Pixel values. Padding will be ignored by default should you provide it.
Pixel values can be obtained using
DetrFeatureExtractor
. Seetransformers.DetrFeatureExtractor.__call__()
for details.pixel_mask (
torch.LongTensor
of shape(batch_size, height, width)
, optional) –Mask to avoid performing attention on padding pixel values. Mask values selected in
[0, 1]
:1 for pixels that are real (i.e. not masked),
0 for pixels that are padding (i.e. masked).
decoder_attention_mask (
torch.LongTensor
of shape(batch_size, num_queries)
, optional) – Not used by default. Can be used to mask object queries.encoder_outputs (
tuple(tuple(torch.FloatTensor)
, optional) – Tuple consists of (last_hidden_state
, optional:hidden_states
, optional:attentions
)last_hidden_state
of shape(batch_size, sequence_length, hidden_size)
, optional) is a sequence of hidden-states at the output of the last layer of the encoder. Used in the cross-attention of the decoder.inputs_embeds (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Optionally, instead of passing the flattened feature map (output of the backbone + projection layer), you can choose to directly pass a flattened representation of an image.decoder_inputs_embeds (
torch.FloatTensor
of shape(batch_size, num_queries, hidden_size)
, optional) – Optionally, instead of initializing the queries with a tensor of zeros, you can choose to directly pass an embedded representation.output_attentions (
bool
, optional) – Whether or not to return the attentions tensors of all attention layers. Seeattentions
under returned tensors for more detail.output_hidden_states (
bool
, optional) – Whether or not to return the hidden states of all layers. Seehidden_states
under returned tensors for more detail.return_dict (
bool
, optional) – Whether or not to return aModelOutput
instead of a plain tuple.labels (
List[Dict]
of len(batch_size,)
, optional) – Labels for computing the bipartite matching loss, DICE/F-1 loss and Focal loss. List of dicts, each dictionary containing at least the following 3 keys: ‘class_labels’, ‘boxes’ and ‘masks’ (the class labels, bounding boxes and segmentation masks of an image in the batch respectively). The class labels themselves should be atorch.LongTensor
of len(number of bounding boxes in the image,)
, the boxes atorch.FloatTensor
of shape(number of bounding boxes in the image, 4)
and the masks atorch.FloatTensor
of shape(number of bounding boxes in the image, height, width)
.
- Returns
A
DetrSegmentationOutput
or a tuple oftorch.FloatTensor
(ifreturn_dict=False
is passed or whenconfig.return_dict=False
) comprising various elements depending on the configuration (DetrConfig
) and inputs.loss (
torch.FloatTensor
of shape(1,)
, optional, returned whenlabels
are provided)) – Total loss as a linear combination of a negative log-likehood (cross-entropy) for class prediction and a bounding box loss. The latter is defined as a linear combination of the L1 loss and the generalized scale-invariant IoU loss.loss_dict (
Dict
, optional) – A dictionary containing the individual losses. Useful for logging.logits (
torch.FloatTensor
of shape(batch_size, num_queries, num_classes + 1)
) – Classification logits (including no-object) for all queries.pred_boxes (
torch.FloatTensor
of shape(batch_size, num_queries, 4)
) – Normalized boxes coordinates for all queries, represented as (center_x, center_y, width, height). These values are normalized in [0, 1], relative to the size of each individual image in the batch (disregarding possible padding). You can usepost_process()
to retrieve the unnormalized bounding boxes.pred_masks (
torch.FloatTensor
of shape(batch_size, num_queries, height/4, width/4)
) – Segmentation masks logits for all queries. See alsopost_process_segmentation()
orpost_process_panoptic()
to evaluate instance and panoptic segmentation masks respectively.auxiliary_outputs (
list[Dict]
, optional) – Optional, only returned when auxilary losses are activated (i.e.config.auxiliary_loss
is set to True) and labels are provided. It is a list of dictionnaries containing the two above keys (logits
andpred_boxes
) for each decoder layer.last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the decoder of the model.decoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the decoder at the output of each layer plus the initial embedding outputs.decoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder, after the attention softmax, used to compute the weighted average in the self-attention heads.cross_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the decoder’s cross-attention layer, after the attention softmax, used to compute the weighted average in the cross-attention heads.encoder_last_hidden_state (
torch.FloatTensor
of shape(batch_size, sequence_length, hidden_size)
, optional) – Sequence of hidden-states at the output of the last layer of the encoder of the model.encoder_hidden_states (
tuple(torch.FloatTensor)
, optional, returned whenoutput_hidden_states=True
is passed or whenconfig.output_hidden_states=True
) – Tuple oftorch.FloatTensor
(one for the output of the embeddings + one for the output of each layer) of shape(batch_size, sequence_length, hidden_size)
. Hidden-states of the encoder at the output of each layer plus the initial embedding outputs.encoder_attentions (
tuple(torch.FloatTensor)
, optional, returned whenoutput_attentions=True
is passed or whenconfig.output_attentions=True
) – Tuple oftorch.FloatTensor
(one for each layer) of shape(batch_size, num_heads, sequence_length, sequence_length)
. Attentions weights of the encoder, after the attention softmax, used to compute the weighted average in the self-attention heads.
Examples:
>>> from transformers import DetrFeatureExtractor, DetrForSegmentation >>> from PIL import Image >>> import requests >>> url = 'http://images.cocodataset.org/val2017/000000039769.jpg' >>> image = Image.open(requests.get(url, stream=True).raw) >>> feature_extractor = DetrFeatureExtractor.from_pretrained('facebook/detr-resnet-50-panoptic') >>> model = DetrForSegmentation.from_pretrained('facebook/detr-resnet-50-panoptic') >>> inputs = feature_extractor(images=image, return_tensors="pt") >>> outputs = model(**inputs) >>> # model predicts COCO classes, bounding boxes, and masks >>> logits = outputs.logits >>> bboxes = outputs.pred_boxes >>> masks = outputs.pred_masks
- Return type
DetrSegmentationOutput
ortuple(torch.FloatTensor)