We list some common troubles faced by many users and their corresponding solutions here. Feel free to enrich the list if you find any frequent issues and have ways to help others to solve them. If the contents here do not cover your issue, please create an issue using the provided templates and make sure you fill in all required information in the template.
-
Compatibility issue between MMCV and MMDetection; "ConvWS is already registered in conv layer"; "AssertionError: MMCV==xxx is used but incompatible. Please install mmcv>=xxx, <=xxx."
Please install the correct version of MMCV for the version of your MMDetection following the installation instruction.
-
"No module named 'mmcv.ops'"; "No module named 'mmcv._ext'".
- Uninstall existing mmcv in the environment using
pip uninstall mmcv
. - Install mmcv-full following the installation instruction.
- Uninstall existing mmcv in the environment using
-
"RTX 30 series card fails when building MMCV or MMDet"
- Temporary work-around: do
MMCV_WITH_OPS=1 MMCV_CUDA_ARGS='-gencode=arch=compute_80,code=sm_80' pip install -e .
. The common issue isnvcc fatal : Unsupported gpu architecture 'compute_86'
. This means that the compiler should optimize for sm_86, i.e., nvidia 30 series card, but such optimizations have not been supported by CUDA toolkit 11.0. This work-around modifies the compile flag by addingMMCV_CUDA_ARGS='-gencode=arch=compute_80,code=sm_80'
, which tellsnvcc
to optimize for sm_80, i.e., Nvidia A100. Although A100 is different from the 30 series card, they use similar ampere architecture. This may hurt the performance but it works. - PyTorch developers have updated that the default compiler flags should be fixed by pytorch/pytorch#47585. So using PyTorch-nightly may also be able to solve the problem, though we have not tested it yet.
- Temporary work-around: do
-
"invalid device function" or "no kernel image is available for execution".
- Check if your cuda runtime version (under
/usr/local/
),nvcc --version
andconda list cudatoolkit
version match. - Run
python mmdet/utils/collect_env.py
to check whether PyTorch, torchvision, and MMCV are built for the correct GPU architecture. You may need to setTORCH_CUDA_ARCH_LIST
to reinstall MMCV. The GPU arch table could be found here, i.e. runTORCH_CUDA_ARCH_LIST=7.0 pip install mmcv-full
to build MMCV for Volta GPUs. The compatibility issue could happen when using old GPUS, e.g., Tesla K80 (3.7) on colab. - Check whether the running environment is the same as that when mmcv/mmdet has compiled. For example, you may compile mmcv using CUDA 10.0 but run it on CUDA 9.0 environments.
- Check if your cuda runtime version (under
-
"undefined symbol" or "cannot open xxx.so".
- If those symbols are CUDA/C++ symbols (e.g., libcudart.so or GLIBCXX), check whether the CUDA/GCC runtimes are the same as those used for compiling mmcv,
i.e. run
python mmdet/utils/collect_env.py
to see if"MMCV Compiler"
/"MMCV CUDA Compiler"
is the same as"GCC"
/"CUDA_HOME"
. - If those symbols are PyTorch symbols (e.g., symbols containing caffe, aten, and TH), check whether the PyTorch version is the same as that used for compiling mmcv.
- Run
python mmdet/utils/collect_env.py
to check whether PyTorch, torchvision, and MMCV are built by and running on the same environment.
- If those symbols are CUDA/C++ symbols (e.g., libcudart.so or GLIBCXX), check whether the CUDA/GCC runtimes are the same as those used for compiling mmcv,
i.e. run
-
setuptools.sandbox.UnpickleableException: DistutilsSetupError("each element of 'ext_modules' option must be an Extension instance or 2-tuple")
- If you are using miniconda rather than anaconda, check whether Cython is installed as indicated in #3379.
You need to manually install Cython first and then run command
pip install -r requirements.txt
. - You may also need to check the compatibility between the
setuptools
,Cython
, andPyTorch
in your environment.
- If you are using miniconda rather than anaconda, check whether Cython is installed as indicated in #3379.
You need to manually install Cython first and then run command
-
"Segmentation fault".
-
Check you GCC version and use GCC 5.4. This usually caused by the incompatibility between PyTorch and the environment (e.g., GCC < 4.9 for PyTorch). We also recommand the users to avoid using GCC 5.5 because many feedbacks report that GCC 5.5 will cause "segmentation fault" and simply changing it to GCC 5.4 could solve the problem.
-
Check whether PyTorch is correctly installed and could use CUDA op, e.g. type the following command in your terminal.
python -c 'import torch; print(torch.cuda.is_available())'
And see whether they could correctly output results.
-
If Pytorch is correctly installed, check whether MMCV is correctly installed.
python -c 'import mmcv; import mmcv.ops'
If MMCV is correctly installed, then there will be no issue of the above two commands.
-
If MMCV and Pytorch is correctly installed, you man use
ipdb
,pdb
to set breakpoints or directly add 'print' in mmdetection code and see which part leads the segmentation fault.
-
-
"Loss goes Nan"
- Check if the dataset annotations are valid: zero-size bounding boxes will cause the regression loss to be Nan due to the commonly used transformation for box regression. Some small size (width or height are smaller than 1) boxes will also cause this problem after data augmentation (e.g., instaboost). So check the data and try to filter out those zero-size boxes and skip some risky augmentations on the small-size boxes when you face the problem.
- Reduce the learning rate: the learning rate might be too large due to some reasons, e.g., change of batch size. You can rescale them to the value that could stably train the model.
- Extend the warmup iterations: some models are sensitive to the learning rate at the start of the training. You can extend the warmup iterations, e.g., change the
warmup_iters
from 500 to 1000 or 2000. - Add gradient clipping: some models requires gradient clipping to stablize the training process. You can add gradient clippint to avoid gradients that are too large.
-
’GPU out of memory"
- There are some scenarios when there are large amount of ground truth boxes, which may cause OOM during target assignment. You can set
gpu_assign_thr=N
in the config of assigner thus the assigner will calculate box overlaps through CPU when there are more than N GT boxes. - Set
with_cp=True
in the backbone. This uses the sublinear strategy in PyTorch to reduce GPU memory cost in the backbone. - Try mixed precision training using following the examples in
config/fp16
. Theloss_scale
might need further tuning for different models.
- There are some scenarios when there are large amount of ground truth boxes, which may cause OOM during target assignment. You can set
-
"RuntimeError: Expected to have finished reduction in the prior iteration before starting a new one"
- This error indicates that your module has parameters that were not used in producing loss. This phenomenon may be caused by running different branches in your code in DDP mode.
- You can set
find_unused_parameters = True
in the config to solve the above problems or find those unused parameters manually.