This page provides basic tutorials about the usage of MMDetection. For installation instructions, please see INSTALL.md.
We provide testing scripts to evaluate a whole dataset (COCO, PASCAL VOC, etc.), and also some high-level apis for easier integration to other projects.
- single GPU testing
- multiple GPU testing
- visualize detection results
You can use the following commands to test a dataset.
# single-gpu testing
python tools/test.py ${CONFIG_FILE} ${CHECKPOINT_FILE} [--out ${RESULT_FILE}] [--eval ${EVAL_METRICS}] [--show]
# multi-gpu testing
./tools/dist_test.sh ${CONFIG_FILE} ${CHECKPOINT_FILE} ${GPU_NUM} [--out ${RESULT_FILE}] [--eval ${EVAL_METRICS}]
Optional arguments:
RESULT_FILE
: Filename of the output results in pickle format. If not specified, the results will not be saved to a file.EVAL_METRICS
: Items to be evaluated on the results. Allowed values are:proposal_fast
,proposal
,bbox
,segm
,keypoints
.--show
: If specified, detection results will be plotted on the images and shown in a new window. It is only applicable to single GPU testing. Please make sure that GUI is available in your environment, otherwise you may encounter the error likecannot connect to X server
.
Examples:
Assume that you have already downloaded the checkpoints to checkpoints/
.
- Test Faster R-CNN and show the results.
python tools/test.py configs/faster_rcnn_r50_fpn_1x.py \
checkpoints/faster_rcnn_r50_fpn_1x_20181010-3d1b3351.pth \
--show
- Test Mask R-CNN and evaluate the bbox and mask AP.
python tools/test.py configs/mask_rcnn_r50_fpn_1x.py \
checkpoints/mask_rcnn_r50_fpn_1x_20181010-069fa190.pth \
--out results.pkl --eval bbox segm
- Test Mask R-CNN with 8 GPUs, and evaluate the bbox and mask AP.
./tools/dist_test.sh configs/mask_rcnn_r50_fpn_1x.py \
checkpoints/mask_rcnn_r50_fpn_1x_20181010-069fa190.pth \
8 --out results.pkl --eval bbox segm
We provide a webcam demo to illustrate the results.
python demo/webcam_demo.py ${CONFIG_FILE} ${CHECKPOINT_FILE} [--device ${GPU_ID}] [--camera-id ${CAMERA-ID}] [--score-thr ${SCORE_THR}]
Examples:
python demo/webcam_demo.py configs/faster_rcnn_r50_fpn_1x.py \
checkpoints/faster_rcnn_r50_fpn_1x_20181010-3d1b3351.pth
Here is an example of building the model and test given images.
from mmdet.apis import init_detector, inference_detector, show_result
import mmcv
config_file = 'configs/faster_rcnn_r50_fpn_1x.py'
checkpoint_file = 'checkpoints/faster_rcnn_r50_fpn_1x_20181010-3d1b3351.pth'
# build the model from a config file and a checkpoint file
model = init_detector(config_file, checkpoint_file, device='cuda:0')
# test a single image and show the results
img = 'test.jpg' # or img = mmcv.imread(img), which will only load it once
result = inference_detector(model, img)
# visualize the results in a new window
show_result(img, result, model.CLASSES)
# or save the visualization results to image files
show_result(img, result, model.CLASSES, out_file='result.jpg')
# test a video and show the results
video = mmcv.VideoReader('video.mp4')
for frame in video:
result = inference_detector(model, frame)
show_result(frame, result, model.CLASSES, wait_time=1)
A notebook demo can be found in demo/inference_demo.ipynb.
Async interface allows not to block CPU on GPU bound inference code and enables better CPU/GPU utilization for single threaded application. Inference can be done concurrently either between different input data samples or between different models of some inference pipeline.
See tests/async_benchmark.py
to compare the speed of synchronous and asynchronous interfaces.
import asyncio
import torch
from mmdet.apis import init_detector, async_inference_detector, show_result
from mmdet.utils.contextmanagers import concurrent
async def main():
config_file = 'configs/faster_rcnn_r50_fpn_1x.py'
checkpoint_file = 'checkpoints/faster_rcnn_r50_fpn_1x_20181010-3d1b3351.pth'
device = 'cuda:0'
model = init_detector(config_file, checkpoint=checkpoint_file, device=device)
# queue is used for concurrent inference of multiple images
streamqueue = asyncio.Queue()
# queue size defines concurrency level
streamqueue_size = 3
for _ in range(streamqueue_size):
streamqueue.put_nowait(torch.cuda.Stream(device=device))
# test a single image and show the results
img = 'test.jpg' # or img = mmcv.imread(img), which will only load it once
async with concurrent(streamqueue):
result = await async_inference_detector(model, img)
# visualize the results in a new window
show_result(img, result, model.CLASSES)
# or save the visualization results to image files
show_result(img, result, model.CLASSES, out_file='result.jpg')
asyncio.run(main())
MMDetection implements distributed training and non-distributed training,
which uses MMDistributedDataParallel
and MMDataParallel
respectively.
All outputs (log files and checkpoints) will be saved to the working directory,
which is specified by work_dir
in the config file.
By default we evaluate the model on the validation set after each epoch, you can change the evaluation interval by adding the interval argument in the training config.
evaluation = dict(interval=12) # This evaluate the model per 12 epoch.
*Important*: The default learning rate in config files is for 8 GPUs and 2 img/gpu (batch size = 8*2 = 16). According to the Linear Scaling Rule, you need to set the learning rate proportional to the batch size if you use different GPUs or images per GPU, e.g., lr=0.01 for 4 GPUs * 2 img/gpu and lr=0.08 for 16 GPUs * 4 img/gpu.
python tools/train.py ${CONFIG_FILE}
If you want to specify the working directory in the command, you can add an argument --work_dir ${YOUR_WORK_DIR}
.
./tools/dist_train.sh ${CONFIG_FILE} ${GPU_NUM} [optional arguments]
Optional arguments are:
--validate
(strongly recommended): Perform evaluation at every k (default value is 1, which can be modified like this) epochs during the training.--work_dir ${WORK_DIR}
: Override the working directory specified in the config file.--resume_from ${CHECKPOINT_FILE}
: Resume from a previous checkpoint file.
Difference between resume_from
and load_from
:
resume_from
loads both the model weights and optimizer status, and the epoch is also inherited from the specified checkpoint. It is usually used for resuming the training process that is interrupted accidentally.
load_from
only loads the model weights and the training epoch starts from 0. It is usually used for finetuning.
If you run MMDetection on a cluster managed with slurm, you can use the script slurm_train.sh
.
./tools/slurm_train.sh ${PARTITION} ${JOB_NAME} ${CONFIG_FILE} ${WORK_DIR} [${GPUS}]
Here is an example of using 16 GPUs to train Mask R-CNN on the dev partition.
./tools/slurm_train.sh dev mask_r50_1x configs/mask_rcnn_r50_fpn_1x.py /nfs/xxxx/mask_rcnn_r50_fpn_1x 16
You can check slurm_train.sh for full arguments and environment variables.
If you have just multiple machines connected with ethernet, you can refer to pytorch launch utility. Usually it is slow if you do not have high speed networking like infiniband.
If you launch multiple jobs on a single machine, e.g., 2 jobs of 4-GPU training on a machine with 8 GPUs, you need to specify different ports (29500 by default) for each job to avoid communication conflict.
If you use dist_train.sh
to launch training jobs, you can set the port in commands.
CUDA_VISIBLE_DEVICES=0,1,2,3 PORT=29500 ./tools/dist_train.sh ${CONFIG_FILE} 4
CUDA_VISIBLE_DEVICES=4,5,6,7 PORT=29501 ./tools/dist_train.sh ${CONFIG_FILE} 4
If you use launch training jobs with slurm, you need to modify the config files (usually the 6th line from the bottom in config files) to set different communication ports.
In config1.py
,
dist_params = dict(backend='nccl', port=29500)
In config2.py
,
dist_params = dict(backend='nccl', port=29501)
Then you can launch two jobs with config1.py
ang config2.py
.
CUDA_VISIBLE_DEVICES=0,1,2,3 ./tools/slurm_train.sh ${PARTITION} ${JOB_NAME} config1.py ${WORK_DIR} 4
CUDA_VISIBLE_DEVICES=4,5,6,7 ./tools/slurm_train.sh ${PARTITION} ${JOB_NAME} config2.py ${WORK_DIR} 4
You can plot loss/mAP curves given a training log file. Run pip install seaborn
first to install the dependency.
python tools/analyze_logs.py plot_curve [--keys ${KEYS}] [--title ${TITLE}] [--legend ${LEGEND}] [--backend ${BACKEND}] [--style ${STYLE}] [--out ${OUT_FILE}]
Examples:
- Plot the classification loss of some run.
python tools/analyze_logs.py plot_curve log.json --keys loss_cls --legend loss_cls
- Plot the classification and regression loss of some run, and save the figure to a pdf.
python tools/analyze_logs.py plot_curve log.json --keys loss_cls loss_reg --out losses.pdf
- Compare the bbox mAP of two runs in the same figure.
python tools/analyze_logs.py plot_curve log1.json log2.json --keys bbox_mAP --legend run1 run2
You can also compute the average training speed.
python tools/analyze_logs.py cal_train_time ${CONFIG_FILE} [--include-outliers]
The output is expected to be like the following.
-----Analyze train time of work_dirs/some_exp/20190611_192040.log.json-----
slowest epoch 11, average time is 1.2024
fastest epoch 1, average time is 1.1909
time std over epochs is 0.0028
average iter time: 1.1959 s/iter
You can analyse the class-wise mAP to have a more comprehensive understanding of the model.
python coco_eval.py ${RESULT} --ann ${ANNOTATION_PATH} --types bbox --classwise
Now we only support class-wise mAP for all the evaluation types, we will support class-wise mAR in the future.
We provide a script adapted from flops-counter.pytorch to compute the FLOPs and params of a given model.
python tools/get_flops.py ${CONFIG_FILE} [--shape ${INPUT_SHAPE}]
You will get the result like this.
==============================
Input shape: (3, 1280, 800)
Flops: 239.32 GMac
Params: 37.74 M
==============================
Note: This tool is still experimental and we do not guarantee that the number is correct. You may well use the result for simple comparisons, but double check it before you adopt it in technical reports or papers.
(1) FLOPs are related to the input shape while parameters are not. The default input shape is (1, 3, 1280, 800).
(2) Some operators are not counted into FLOPs like GN and custom operators.
You can add support for new operators by modifying mmdet/utils/flops_counter.py
.
(3) The FLOPs of two-stage detectors is dependent on the number of proposals.
Before you upload a model to AWS, you may want to (1) convert model weights to CPU tensors, (2) delete the optimizer states and (3) compute the hash of the checkpoint file and append the hash id to the filename.
python tools/publish_model.py ${INPUT_FILENAME} ${OUTPUT_FILENAME}
E.g.,
python tools/publish_model.py work_dirs/faster_rcnn/latest.pth faster_rcnn_r50_fpn_1x_20190801.pth
The final output filename will be faster_rcnn_r50_fpn_1x_20190801-{hash id}.pth
.
Please refer to ROBUSTNESS_BENCHMARKING.md.
The simplest way is to convert your dataset to existing dataset formats (COCO or PASCAL VOC).
Here we show an example of adding a custom dataset of 5 classes, assuming it is also in COCO format.
In mmdet/datasets/my_dataset.py
:
from .coco import CocoDataset
from .registry import DATASETS
@DATASETS.register_module
class MyDataset(CocoDataset):
CLASSES = ('a', 'b', 'c', 'd', 'e')
In mmdet/datasets/__init__.py
:
from .my_dataset import MyDataset
Then you can use MyDataset
in config files, with the same API as CocoDataset.
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
.
We basically categorize model components into 4 types.
- backbone: usually an FCN network to extract feature maps, e.g., ResNet, MobileNet.
- neck: the component between backbones and heads, e.g., FPN, PAFPN.
- head: the component for specific tasks, e.g., bbox prediction and mask prediction.
- roi extractor: the part for extracting RoI features from feature maps, e.g., RoI Align.
Here we show how to develop new components with an example of MobileNet.
- Create a new file
mmdet/models/backbones/mobilenet.py
.
import torch.nn as nn
from ..registry import BACKBONES
@BACKBONES.register_module
class MobileNet(nn.Module):
def __init__(self, arg1, arg2):
pass
def forward(self, x): # should return a tuple
pass
def init_weights(self, pretrained=None):
pass
- Import the module in
mmdet/models/backbones/__init__.py
.
from .mobilenet import MobileNet
- Use it in your config file.
model = dict(
...
backbone=dict(
type='MobileNet',
arg1=xxx,
arg2=xxx),
...
For more information on how it works, you can refer to TECHNICAL_DETAILS.md (TODO).