In this section, we will introduce the main units of training a detector: data loading, model and iteration pipeline.
Following typical conventions, we use Dataset
and DataLoader
for data loading
with multiple workers. Dataset
returns a dict of data items corresponding
the arguments of models' forward method.
Since the data in object detection may not be the same size (image size, gt bbox size, etc.),
we introduce a new DataContainer
type in mmcv
to help collect and distribute
data of different size.
See here for more details.
In mmdetection, model components are basically categorized as 4 types.
- backbone: usually a FCN network to extract feature maps, e.g., ResNet.
- neck: the part between backbones and heads, e.g., FPN, ASPP.
- head: the part for specific tasks, e.g., bbox prediction and mask prediction.
- roi extractor: the part for extracting features from feature maps, e.g., RoI Align.
We also write implement some general detection pipelines with the above components,
such as SingleStageDetector
and TwoStageDetector
.
Following some basic pipelines (e.g., two-stage detectors), the model structure can be customized through config files with no pains.
If we want to implement some new components, e.g, the path aggregation FPN structure in Path Aggregation Network for Instance Segmentation, there are two things to do.
-
create a new file in
mmdet/models/necks/pafpn.py
.from ..registry import NECKS @NECKS.register class PAFPN(nn.Module): def __init__(self, in_channels, out_channels, num_outs, start_level=0, end_level=-1, add_extra_convs=False): pass def forward(self, inputs): # implementation is ignored pass
-
modify the config file from
neck=dict( type='FPN', in_channels=[256, 512, 1024, 2048], out_channels=256, num_outs=5)
to
neck=dict( type='PAFPN', in_channels=[256, 512, 1024, 2048], out_channels=256, num_outs=5)
We will release more components (backbones, necks, heads) for research purpose.
To write a new detection pipeline, you need to inherit from BaseDetector
,
which defines the following abstract methods.
extract_feat()
: given an image batch of shape (n, c, h, w), extract the feature map(s).forward_train()
: forward method of the training modesimple_test()
: single scale testing without augmentationaug_test()
: testing with augmentation (multi-scale, flip, etc.)
TwoStageDetector is a good example which shows how to do that.
We adopt distributed training for both single machine and multiple machines. Supposing that the server has 8 GPUs, 8 processes will be started and each process runs on a single GPU.
Each process keeps an isolated model, data loader, and optimizer. Model parameters are only synchronized once at the beginning. After a forward and backward pass, gradients will be allreduced among all GPUs, and the optimizer will update model parameters. Since the gradients are allreduced, the model parameter stays the same for all processes after the iteration.
For more information, please refer to our technical report.