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Domain Adaptation for Semantic Segmentation via Class-Balanced Self-Training

By Yang Zou*, Zhiding Yu*, Vijayakumar Bhagavatula, Jinsong Wang (* indicates equal contribution).

Update

  • 2019.10.10: check out our new paper "Confidence Regularized Self-Training" (ICCV 2019, Oral), which investigates confidence regularization in self-training systematically. The pytorch code based on CBST are released.
  • 2018.11.11: source domain training code for GTA-5 and SYNTHIA uploaded
  • 2018.10.14: code release for GTA-5 to Cityscapes and SYNTHIA to Cityscapes

Contents

  1. Introduction
  2. Citation and license
  3. Requirements
  4. Setup
  5. Usage
  6. Results
  7. Note

Introduction

This repository contains the self-training based methods described in the ECCV 2018 paper "Domain Adaptation for Semantic Segmentation via Class-Balanced Self-Training". Self-training (ST), Class-balanced self-training (CBST) with Spatial Priors (CBST-SP) are implemented. CBST is the core algorithm for the 1st and 3rd winner of Domain Adaptation of Semantic Segmentation Challenge in CVPR 2018 Workshop on Autonomous Driving (WAD).

Requirements:

The code is tested in Ubuntu 16.04. It is implemented based on MXNet 1.3.0 and Python 2.7.12. For GPU usage, the maximum GPU memory consumption is about 7GB in a single NVIDIA TiTan Xp.

Citation

If you use this code, please cite:

@inproceedings{zou2018unsupervised,
  title={Unsupervised Domain Adaptation for Semantic Segmentation via Class-Balanced Self-Training},
  author={Zou, Yang and Yu, Zhiding and Kumar, BVK Vijaya and Wang, Jinsong},
  booktitle={Proceedings of the European Conference on Computer Vision (ECCV)},
  pages={289--305},
  year={2018}
}


@InProceedings{Zou_2019_ICCV,
author = {Zou, Yang and Yu, Zhiding and Liu, Xiaofeng and Kumar, B.V.K. Vijaya and Wang, Jinsong},
title = {Confidence Regularized Self-Training},
booktitle = {The IEEE International Conference on Computer Vision (ICCV)},
month = {October},
year = {2019}
}

The model and code are available for non-commercial (NC) research purposes only. If you modify the code and want to redistribute, please include the CC-BY-NC-SA-4.0 license.

Results:

  1. GTA2city:

    Case mIoU Road Sidewalk Build Wall Fence Pole Traffic Light Traffic Sign Veg. Terrain Sky Person Rider Car Truck Bus Train Motor Bike
    Source 35.4 70.0 23.7 67.8 15.4 18.1 40.2 41.9 25.3 78.8 11.7 31.4 62.9 29.8 60.1 21.5 26.8 7.7 28.1 12.0
    ST 41.5 88.0 20.4 80.4 25.5 19.7 41.3 42.6 20.2 86.0 3.5 64.6 65.4 25.4 83.3 31.7 44.3 0.6 13.4 3.7
    CBST 45.2 86.8 46.7 76.9 26.3 24.8 42.0 46.0 38.6 80.7 15.7 48.0 57.3 27.9 78.2 24.5 49.6 17.7 25.5 45.1
    CBST-SP 46.2 88.0 56.2 77.0 27.4 22.4 40.7 47.3 40.9 82.4 21.6 60.3 50.2 20.4 83.8 35.0 51.0 15.2 20.6 37.0
  2. SYNTHIA2City:

    Case mIoU Road Sidewalk Build Wall Fence Pole Traffic Light Traffic Sign Veg. Sky Person Rider Car Bus Motor Bike
    Source 29.2 32.6 21.5 46.5 4.8 0.1 26.5 14.8 13.1 70.8 60.3 56.6 3.5 74.1 20.4 8.9 13.1
    ST 32.2 38.2 19.6 70.2 3.9 0.0 31.9 17.6 17.2 82.4 68.3 63.1 5.3 78.4 11.2 0.8 7.5
    CBST 42.5 53.6 23.7 75.0 12.5 0.3 36.4 23.5 26.3 84.8 74.7 67.2 17.5 84.5 28.4 15.2 55.8

Setup

We assume you are working in cbst-master folder.

  1. Datasets:
  • Download GTA-5 dataset. Since GTA-5 contains images with different resolutions, we recommend resize all images to 1052x1914.
  • Download Cityscapes.
  • Download SYNTHIA-RAND-CITYSCAPES.
  • Put downloaded data in "data" folder.
  1. Source pretrained models:
  1. Spatial priors
  • Download Spatial priors from GTA-5. Spatial priors are only used in GTA2Cityscapes. Put the prior_array.mat in "spatial_prior/gta/" folder.

Usage

  1. Set the PYTHONPATH environment variable:
cd cbst-master
export PYTHONPATH=PYTHONPATH:./
  1. Self-training for GTA2Cityscapes:
  • CBST-SP:
python issegm/solve_AO.py --num-round 6 --test-scales 1850 --scale-rate-range 0.7,1.3 --dataset gta --dataset-tgt cityscapes --split train --split-tgt train --data-root DATA_ROOT_GTA5 --data-root-tgt DATA_ROOT_CITYSCAPES --output gta2city/cbst-sp --model cityscapes_rna-a1_cls19_s8 --weights models/gta_rna-a1_cls19_s8_ep-0000.params --batch-images 2 --crop-size 500 --origin-size-tgt 2048 --init-tgt-port 0.15 --init-src-port 0.03 --seed-int 0 --mine-port 0.8 --mine-id-number 3 --mine-thresh 0.001 --base-lr 1e-4 --to-epoch 2 --source-sample-policy cumulative --self-training-script issegm/solve_ST.py --kc-policy cb --prefetch-threads 2 --gpus 0 --with-prior True
  1. Self-training for SYNTHIA2City:
  • CBST:
python issegm/solve_AO.py --num-round 6 --test-scales 1850 --scale-rate-range 0.7,1.3 --dataset synthia --dataset-tgt cityscapes --split train --split-tgt train --data-root DATA_ROOT_SYNTHIA --data-root-tgt DATA_ROOT_CITYSCAPES --output syn2city/cbst --model cityscapes_rna-a1_cls16_s8 --weights models/synthia_rna-a1_cls16_s8_ep-0000.params --batch-images 2 --crop-size 500 --origin-size 1280 --origin-size-tgt 2048 --init-tgt-port 0.2 --init-src-port 0.02 --max-src-port 0.06 --seed-int 0 --mine-port 0.8 --mine-id-number 3 --mine-thresh 0.001 --base-lr 1e-4 --to-epoch 2 --source-sample-policy cumulative --self-training-script issegm/solve_ST.py --kc-policy cb --prefetch-threads 2 --gpus 0 --with-prior False
  • To run the code, you need to set the data paths of source data (data-root) and target data (data-root-tgt) by yourself. Besides that, you can keep other argument setting as default.
  • For CBST, set "--kc-policy cb" and "--with-prior False". For ST, set "--kc-policy global" and "--with-prior False".
  • We use a small class patch mining strategy to mine the patches including small classes. To turn off small class mining, set "--mine-port 0.0".
  1. Evaluation
  • Test in Cityscapes for model compatible with GTA-5 (Initial source trained model as example)
python issegm/evaluate.py --data-root DATA_ROOT_CITYSCAPES --output val/gta-city --dataset cityscapes --phase val --weights models/gta_rna-a1_cls19_s8_ep-0000.params --split val --test-scales 2048 --test-flipping --gpus 0 --no-cudnn
  • Test in Cityscapes for model compatible with SYNTHIA (Initial source trained model as example)
python issegm/evaluate.py --data-root DATA_ROOT_CITYSCAPES --output val/syn-city --dataset cityscapes16 --phase val --weights models/synthia_rna-a1_cls16_s8_ep-0000.params --split val --test-scales 2048 --test-flipping --gpus 0 --no-cudnn
  • Test in GTA-5
python issegm/evaluate.py --data-root DATA_ROOT_GTA --output val/gta --dataset gta --phase val --weights models/gta_rna-a1_cls19_s8_ep-0000.params --split train --test-scales 1914 --test-flipping --gpus 0 --no-cudnn
  • Test in SYNTHIA
python issegm/evaluate.py --data-root DATA_ROOT_SYNTHIA --output val/synthia --dataset synthia --phase val --weights models/synthia_rna-a1_cls16_s8_ep-0000.params --split train --test-scales 1280 --test-flipping --gpus 0 --no-cudnn
  1. Train in source domain
  • Train in GTA-5
python issegm/train_src.py --gpus 0,1,2,3 --split train --data-root DATA_ROOT_GTA --output gta_train --model gta_rna-a1_cls19_s8 --batch-images 16 --crop-size 500 --scale-rate-range 0.7,1.3 --weights models/ilsvrc-cls_rna-a1_cls1000_ep-0001.params --lr-type fixed --base-lr 0.0016 --to-epoch 30 --kvstore local --prefetch-threads 16 --prefetcher process --cache-images 0 --backward-do-mirror --origin-size 1914
  • Train in SYNTHIA
python issegm/train_src.py --gpus 0,1,2,3 --split train --data-root DATA_ROOT_SYNTHIA --output synthia_train --model synthia_rna-a1_cls16_s8 --batch-images 16 --crop-size 500 --scale-rate-range 0.7,1.3 --weights models/ilsvrc-cls_rna-a1_cls1000_ep-0001.params --lr-type fixed --base-lr 0.0016 --to-epoch 50 --kvstore local --prefetch-threads 16 --prefetcher process --cache-images 0 --backward-do-mirror --origin-size 1280

Note

  • This code is based on ResNet-38.
  • Due to the randomness, the self-training results may slightly vary in each run. Usually the best results will be obtained in 2nd/3rd round. For training in source domain, the best model usually appears during the first 30 epoches. Optimal model appearing in initial stage is also possible.

Contact: [email protected]