To support a new data format, you can either convert them to existing formats (COCO format or PASCAL format) or directly convert them to the middle format. You could also choose to convert them offline (before training by a script) or online (implement a new dataset and do the conversion at training). In MMDetection, we recommand to convert the data into COCO formats and do the conversion offline, thus you only need to modify the config's data annotation pathes and classes after the conversion to your data.
The simplest way is to convert your dataset to existing dataset formats (COCO or PASCAL VOC).
The annotation json files in COCO format has the following necessary keys:
'images': [
{
'file_name': 'COCO_val2014_000000001268.jpg',
'height': 427,
'width': 640,
'id': 1268
},
...
],
'annotations': [
{
'segmentation': [[192.81,
247.09,
...
219.03,
249.06]], # if you have mask labels
'area': 1035.749,
'iscrowd': 0,
'image_id': 1268,
'bbox': [192.81, 224.8, 74.73, 33.43],
'category_id': 16,
'id': 42986
},
...
],
'categories': [
{'id': 0, 'name': 'car'},
]
There are three necessary keys in the json file:
images
: contains a list of images with their informations likefile_name
,height
,width
, andid
.annotations
: contains the list of instance annotations.categories
: contains the list of categories names and their ID.
After the data pre-processing, there are two steps for users to train the customized new dataset with existing format (e.g. COCO format):
- Modify the config file for using the customized dataset.
- Check the annotations of the customized dataset.
Here we give an example to show the above two steps, which uses a customized dataset of 5 classes with COCO format to train an existing Cascade MaskRCNN R50 FPN detector.
There are two aspects involved in the modification of config file:
- The
data
field. Specifically, you need to explicitly add theclasses
fields indata.train
,data.val
anddata.test
. - The
num_classes
field in themodel
part. Explicitly over-write all thenum_classes
from default value (e.g. 80 in COCO) to your classes number.
In configs/my_custom_config.py
:
# the new config inherits the base configs to highlight the necessary modification
_base_ = './cascade_mask_rcnn_r50_fpn_1x_coco.py'
# 1. dataset settings
dataset_type = 'CocoDataset'
classes = ('a', 'b', 'c', 'd', 'e')
data = dict(
samples_per_gpu=2,
workers_per_gpu=2,
train=dict(
type=dataset_type,
# explicitly add your class names to the field `classes`
classes=classes,
ann_file='path/to/your/train/annotation_data',
img_prefix='path/to/your/train/image_data'),
val=dict(
type=dataset_type,
# explicitly add your class names to the field `classes`
classes=classes,
ann_file='path/to/your/val/annotation_data',
img_prefix='path/to/your/val/image_data'),
test=dict(
type=dataset_type,
# explicitly add your class names to the field `classes`
classes=classes,
ann_file='path/to/your/test/annotation_data',
img_prefix='path/to/your/test/image_data'))
# 2. model settings
# explicitly over-write all the `num_classes` field from default 80 to 5.
model = dict(
roi_head=dict(
bbox_head=[
dict(
type='Shared2FCBBoxHead',
# explicitly over-write all the `num_classes` field from default 80 to 5.
num_classes=5),
dict(
type='Shared2FCBBoxHead',
# explicitly over-write all the `num_classes` field from default 80 to 5.
num_classes=5),
dict(
type='Shared2FCBBoxHead',
# explicitly over-write all the `num_classes` field from default 80 to 5.
num_classes=5)],
# explicitly over-write all the `num_classes` field from default 80 to 5.
mask_head=dict(num_classes=5)))
Assuming your customized dataset is COCO format, make sure you have the correct annotations in the customized dataset:
- The length for
categories
field in annotations should exactly equal the tuple length ofclasses
fields in your config, meaning the number of classes (e.g. 5 in this example). - The
classes
fields in your config file should have exactly the same elements and the same order with thename
incategories
of annotations. MMDetection automatically maps the uncontinuousid
incategories
to the continuous label indices, so the string order ofname
incategories
field affects the order of label indices. Meanwhile, the string order ofclasses
in config affects the label text during visualization of predicted bounding boxes. - The
category_id
inannotations
field should be valid, i.e., all values incategory_id
should belong toid
incategories
.
Here is a valid example of annotations:
'annotations': [
{
'segmentation': [[192.81,
247.09,
...
219.03,
249.06]], # if you have mask labels
'area': 1035.749,
'iscrowd': 0,
'image_id': 1268,
'bbox': [192.81, 224.8, 74.73, 33.43],
'category_id': 16,
'id': 42986
},
...
],
# MMDetection automatically maps the uncontinuous `id` to the continuous label indices.
'categories': [
{'id': 1, 'name': 'a'}, {'id': 3, 'name': 'b'}, {'id': 4, 'name': 'c'}, {'id': 16, 'name': 'd'}, {'id': 17, 'name': 'e'},
]
We use this way to support CityScapes dataset. The script is in cityscapes.py and we also provide the finetuning configs.
Note
- For instance segmentation datasets, MMDetection only supports evaluating mask AP of dataset in COCO format for now.
- It is recommanded to convert the data offline before training, thus you can still use
CocoDataset
and only need to modify the path of annotations and the training classes.
It is also fine if you do not want to convert the annotation format to COCO or PASCAL format. Actually, we define a simple annotation format and all existing datasets are processed to be compatible with it, either online or offline.
The annotation of a dataset is a list of dict, each dict corresponds to an image.
There are 3 field filename
(relative path), width
, height
for testing,
and an additional field ann
for training. ann
is also a dict containing at least 2 fields:
bboxes
and labels
, both of which are numpy arrays. Some datasets may provide
annotations like crowd/difficult/ignored bboxes, we use bboxes_ignore
and labels_ignore
to cover them.
Here is an example.
[
{
'filename': 'a.jpg',
'width': 1280,
'height': 720,
'ann': {
'bboxes': <np.ndarray, float32> (n, 4),
'labels': <np.ndarray, int64> (n, ),
'bboxes_ignore': <np.ndarray, float32> (k, 4),
'labels_ignore': <np.ndarray, int64> (k, ) (optional field)
}
},
...
]
There are two ways to work with custom datasets.
-
online conversion
You can write a new Dataset class inherited from
CustomDataset
, and overwrite two methodsload_annotations(self, ann_file)
andget_ann_info(self, idx)
, like CocoDataset and VOCDataset. -
offline conversion
You can convert the annotation format to the expected format above and save it to a pickle or json file, like pascal_voc.py. Then you can simply use
CustomDataset
.
Assume the annotation is in a new format in text files.
The bounding boxes annotations are stored in text file annotation.txt
as the following
#
000001.jpg
1280 720
2
10 20 40 60 1
20 40 50 60 2
#
000002.jpg
1280 720
3
50 20 40 60 2
20 40 30 45 2
30 40 50 60 3
We can create a new dataset in mmdet/datasets/my_dataset.py
to load the data.
import mmcv
import numpy as np
from .builder import DATASETS
from .custom import CustomDataset
@DATASETS.register_module()
class MyDataset(CustomDataset):
CLASSES = ('person', 'bicycle', 'car', 'motorcycle')
def load_annotations(self, ann_file):
ann_list = mmcv.list_from_file(ann_file)
data_infos = []
for i, ann_line in enumerate(ann_list):
if ann_line != '#':
continue
img_shape = ann_list[i + 2].split(' ')
width = int(img_shape[0])
height = int(img_shape[1])
bbox_number = int(ann_list[i + 3])
anns = ann_line.split(' ')
bboxes = []
labels = []
for anns in ann_list[i + 4:i + 4 + bbox_number]:
bboxes.append([float(ann) for ann in anns[:4]])
labels.append(int(anns[4]))
data_infos.append(
dict(
filename=ann_list[i + 1],
width=width,
height=height,
ann=dict(
bboxes=np.array(bboxes).astype(np.float32),
labels=np.array(labels).astype(np.int64))
))
return data_infos
def get_ann_info(self, idx):
return self.data_infos[idx]['ann']
Then in the config, to use MyDataset
you can modify the config as the following
dataset_A_train = dict(
type='MyDataset',
ann_file = 'image_list.txt',
pipeline=train_pipeline
)
MMDetection also supports many dataset wrappers to mix the dataset or modify the dataset distribution for training. Currently it supports to three dataset wrappers as below:
RepeatDataset
: simply repeat the whole dataset.ClassBalancedDataset
: repeat dataset in a class balanced manner.ConcatDataset
: concat datasets.
We use RepeatDataset
as wrapper to repeat the dataset. For example, suppose the original dataset is Dataset_A
, to repeat it, the config looks like the following
dataset_A_train = dict(
type='RepeatDataset',
times=N,
dataset=dict( # This is the original config of Dataset_A
type='Dataset_A',
...
pipeline=train_pipeline
)
)
We use ClassBalancedDataset
as wrapper to repeat the dataset based on category
frequency. The dataset to repeat needs to instantiate function self.get_cat_ids(idx)
to support ClassBalancedDataset
.
For example, to repeat Dataset_A
with oversample_thr=1e-3
, the config looks like the following
dataset_A_train = dict(
type='ClassBalancedDataset',
oversample_thr=1e-3,
dataset=dict( # This is the original config of Dataset_A
type='Dataset_A',
...
pipeline=train_pipeline
)
)
You may refer to source code for details.
There are three ways to concatenate the dataset.
-
If the datasets you want to concatenate are in the same type with different annotation files, you can concatenate the dataset configs like the following.
dataset_A_train = dict( type='Dataset_A', ann_file = ['anno_file_1', 'anno_file_2'], pipeline=train_pipeline )
If the concatenated dataset is used for test or evaluation, this manner supports to evaluate each dataset separately. To test the concatenated datasets as a whole, you can set
separate_eval=False
as below.dataset_A_train = dict( type='Dataset_A', ann_file = ['anno_file_1', 'anno_file_2'], separate_eval=False, pipeline=train_pipeline )
-
In case the dataset you want to concatenate is different, you can concatenate the dataset configs like the following.
dataset_A_train = dict() dataset_B_train = dict() data = dict( imgs_per_gpu=2, workers_per_gpu=2, train = [ dataset_A_train, dataset_B_train ], val = dataset_A_val, test = dataset_A_test )
If the concatenated dataset is used for test or evaluation, this manner also supports to evaluate each dataset separately.
-
We also support to define
ConcatDataset
explicitly as the following.dataset_A_val = dict() dataset_B_val = dict() data = dict( imgs_per_gpu=2, workers_per_gpu=2, train=dataset_A_train, val=dict( type='ConcatDataset', datasets=[dataset_A_val, dataset_B_val], separate_eval=False))
This manner allows users to evaluate all the datasets as a single one by setting
separate_eval=False
.
Note:
- The option
separate_eval=False
assumes the datasets useself.data_infos
during evaluation. Therefore, COCO datasets do not support this behavior since COCO datasets do not fully rely onself.data_infos
for evaluation. Combining different types of datasets and evaluating them as a whole is not tested thus is not suggested. - Evaluating
ClassBalancedDataset
andRepeatDataset
is not supported thus evaluating concatenated datasets of these types is also not supported.
A more complex example that repeats Dataset_A
and Dataset_B
by N and M times, respectively, and then concatenates the repeated datasets is as the following.
dataset_A_train = dict(
type='RepeatDataset',
times=N,
dataset=dict(
type='Dataset_A',
...
pipeline=train_pipeline
)
)
dataset_A_val = dict(
...
pipeline=test_pipeline
)
dataset_A_test = dict(
...
pipeline=test_pipeline
)
dataset_B_train = dict(
type='RepeatDataset',
times=M,
dataset=dict(
type='Dataset_B',
...
pipeline=train_pipeline
)
)
data = dict(
imgs_per_gpu=2,
workers_per_gpu=2,
train = [
dataset_A_train,
dataset_B_train
],
val = dataset_A_val,
test = dataset_A_test
)
With existing dataset types, we can modify the class names of them to train subset of the annotations. For example, if you want to train only three classes of the current dataset, you can modify the classes of dataset. The dataset will filter out the ground truth boxes of other classes automatically.
classes = ('person', 'bicycle', 'car')
data = dict(
train=dict(classes=classes),
val=dict(classes=classes),
test=dict(classes=classes))
MMDetection V2.0 also supports to read the classes from a file, which is common in real applications.
For example, assume the classes.txt
contains the name of classes as the following.
person
bicycle
car
Users can set the classes as a file path, the dataset will load it and convert it to a list automatically.
classes = 'path/to/classes.txt'
data = dict(
train=dict(classes=classes),
val=dict(classes=classes),
test=dict(classes=classes))
Note:
- Before MMDetection v2.5.0, the dataset will filter out the empty GT images automatically if the classes are set and there is no way to disable that through config. This is an undesirable behavior and introduces confusion because if the classes are not set, the dataset only filter the empty GT images when
filter_empty_gt=True
andtest_mode=False
. After MMDetection v2.5.0, we decouple the image filtering process and the classes modification, i.e., the dataset will only filter empty GT images whenfilter_empty_gt=True
andtest_mode=False
, no matter whether the classes are set. Thus, setting the classes only influences the annotations of classes used for training and users could decide whether to filter empty GT images by themselves. - Since the middle format only has box labels and does not contain the class names, when using
CustomDataset
, users cannot filter out the empty GT images through configs but only do this offline. - Please remember to modify the
num_classes
in the head when specifyingclasses
in dataset. We implemented NumClassCheckHook to check whether the numbers are consistent since v2.9.0(after PR#4508). - The features for setting dataset classes and dataset filtering will be refactored to be more user-friendly in the future (depends on the progress).