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Precise RoI Pooling with coordinate gradient support, proposed in the paper "Acquisition of Localization Confidence for Accurate Object Detection" (https://arxiv.org/abs/1807.11590).

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PreciseRoIPooling

This repo implements the Precise RoI Pooling (PrRoI Pooling), proposed in the paper Acquisition of Localization Confidence for Accurate Object Detection published at ECCV 2018 (Oral Presentation).

Acquisition of Localization Confidence for Accurate Object Detection

Borui Jiang*, Ruixuan Luo*, Jiayuan Mao*, Tete Xiao, Yuning Jiang (* indicates equal contribution.)

https://arxiv.org/abs/1807.11590

Causion: To install the library, please git clone the repository instead of downloading the zip file, since source files inside the folder ./pytorch/prroi_pool/src/ and tensorflow/prroi_pool/src/kernels/external are symbol-linked. Downloading the repository as a zip file will break these symbolic links. Also, there are reports indicating that Windows git versions also breaks the symbol links. See issues/58.

Brief

In short, Precise RoI Pooling is an integration-based (bilinear interpolation) average pooling method for RoI Pooling. It avoids any quantization and has a continuous gradient on bounding box coordinates. It is:

  • different from the original RoI Pooling proposed in Fast R-CNN. PrRoI Pooling uses average pooling instead of max pooling for each bin and has a continuous gradient on bounding box coordinates. That is, one can take the derivatives of some loss function w.r.t the coordinates of each RoI and optimize the RoI coordinates.
  • different from the RoI Align proposed in Mask R-CNN. PrRoI Pooling uses a full integration-based average pooling instead of sampling a constant number of points. This makes the gradient w.r.t. the coordinates continuous.

For a better illustration, we illustrate RoI Pooling, RoI Align and PrRoI Pooing in the following figure. More details including the gradient computation can be found in our paper.

Implementation

PrRoI Pooling was originally implemented by Tete Xiao based on MegBrain, an (internal) deep learning framework built by Megvii Inc. It was later adapted into open-source deep learning frameworks. Currently, we only support PyTorch. Unfortunately, we don't have any specific plan for the adaptation into other frameworks such as TensorFlow, but any contributions (pull requests) will be more than welcome.

Usage (PyTorch 1.0)

In the directory pytorch/, we provide a PyTorch-based implementation of PrRoI Pooling. It requires PyTorch 1.0+ and only supports CUDA (CPU mode is not implemented). Since we use PyTorch JIT for cxx/cuda code compilation, to use the module in your code, simply do:

from prroi_pool import PrRoIPool2D

avg_pool = PrRoIPool2D(window_height, window_width, spatial_scale)
roi_features = avg_pool(features, rois)

# for those who want to use the "functional"

from prroi_pool.functional import prroi_pool2d
roi_features = prroi_pool2d(features, rois, window_height, window_width, spatial_scale)

Usage (PyTorch 0.4)

!!! Please first checkout to the branch pytorch0.4.

In the directory pytorch/, we provide a PyTorch-based implementation of PrRoI Pooling. It requires PyTorch 0.4 and only supports CUDA (CPU mode is not implemented). To use the PrRoI Pooling module, first goto pytorch/prroi_pool and execute ./travis.sh to compile the essential components (you may need nvcc for this step). To use the module in your code, simply do:

from prroi_pool import PrRoIPool2D

avg_pool = PrRoIPool2D(window_height, window_width, spatial_scale)
roi_features = avg_pool(features, rois)

# for those who want to use the "functional"

from prroi_pool.functional import prroi_pool2d
roi_features = prroi_pool2d(features, rois, window_height, window_width, spatial_scale)

Here,

  • RoI is an m * 5 float tensor of format (batch_index, x0, y0, x1, y1), following the convention in the original Caffe implementation of RoI Pooling, although in some frameworks the batch indices are provided by an integer tensor.
  • spatial_scale is multiplied to the RoIs. For example, if your feature maps are down-sampled by a factor of 16 (w.r.t. the input image), you should use a spatial scale of 1/16.
  • The coordinates for RoI follows the [L, R) convension. That is, (0, 0, 4, 4) denotes a box of size 4x4.

Usage (TensorFlow)

In the directory tensorflow/, we provide a TensorFlow-based implementation of PrRoI Pooling. It tested TensorFlow 2.2 and only supports CUDA (CPU mode is not implemented). To compile the essential components, follow the instruction below

To use the PrRoI Pooling module, to compile the essential components (you may need nvcc for this step). To use the module in your code, simply do:

Requirements

  • CUDA compiler(NVCC)
  • Tensorflow-GPU 2.x
  • CMake
  • Microsoft Visual C++ Build Tools(For Windows Users)

Step-by-step instructions

For Ubuntu Users

CMake Configuration
mkdir tensorflow/prroi_pool/build
cd tensorflow/prroi_pool/build
cmake -DCMAKE_BUILD_TYPE="Release" ..

Build & Test PrRoI Pooling module

make

For Windows Users

MSVC Configuration
${MSVC_INSTALL_PATH}\VC\Auxiliary\Build\vcvars64.bat
CMake Configuration
mkdir tensorflow/prroi_pool/build
cd tensorflow/prroi_pool/build
cmake -DCMAKE_BUILD_TYPE="Release" -G "NMake Makefiles" ..
Build & Test Custom ops
nmake BUILD=release

To use the module in your code, simply do:

from prroi_pool import PreciseRoIPooling

avg_pool = PreciseRoIPooling(window_height, window_width, spatial_scale, data_format)
roi_features = avg_pool([features, rois])

Here,

  • RoI is an m * 5 float tensor of format (batch_index, x0, y0, x1, y1), following the convention in the original Caffe implementation of RoI Pooling, although in some frameworks the batch indices are provided by an integer tensor.
  • spatial_scale is multiplied to the RoIs. For example, if your feature maps are down-sampled by a factor of 16 (w.r.t. the input image), you should use a spatial scale of 1/16.
  • The coordinates for RoI follows the [L, R) convension. That is, (0, 0, 4, 4) denotes a box of size 4x4.

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Precise RoI Pooling with coordinate gradient support, proposed in the paper "Acquisition of Localization Confidence for Accurate Object Detection" (https://arxiv.org/abs/1807.11590).

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