- Author: Umberto Griffo
- Twitter: @UmbertoGriffo
This Python script is a command line tool for visualizing, checking and deleting near-duplicate images from the target directory. In order to find similar images this script hashes the images using pHash from ImageHash library, adding the hash into a KDTree and perform a nearest neighbours search. In addition, near-duplicate images can be visualized generating a t-SNE (t-distributed Stochastic Neighbor Embedding) using a feature vector for each image derived from the pHash function.
I take no responsibility for bugs in this script or accidentally deleted pictures. Use at your own risk. Make sure you back up your pictures before using. This algorithm is intended to find nearly duplicate images. It is NOT intended to find images that are conceptually similar.
- pHash definition
- KDTree definition
- Search
- Deletion
- Installation
- How to use the Makefile
- Usage
- Todo
- References
Features in the image are used to generate a distinct (but not unique) fingerprint, and these fingerprints are comparable. Perceptual hashes are a different concept compared to cryptographic hash functions like MD5 and SHA1.
With cryptographic hashes, the hash values are random. The data used to generate the hash acts like a random seed, so the same data will generate the same result, but different data will create different results. Comparing two SHA1 hash values really only tells you two things. If the hashes are different, then the data is different. And if the hashes are the same, then the data is likely the same. (Since there is a possibility of a hash collision, having the same hash values does not guarantee the same data.) In contrast, perceptual hashes can be compared giving you a sense of similarity between the two data sets. Using pHash images can be scaled larger or smaller, have different aspect ratios, and even minor coloring differences (contrast, brightness, etc.) and they will still match similar images.
A KDTree(short for k-dimensional tree) is a space-partitioning data structure for organizing points in a k-dimensional space. In particular, KDTree helps organize and partition the data points based on specific conditions. KDTree is a useful for several applications, such as searches involving a multidimensional search key (e.g. range searches and nearest neighbor searches).
Scape | Search | Insert | Delete |
---|---|---|---|
O(n) | O(log n) | O(log n) | O(log n) |
where n is the number of points.
Check INSTALL.md for installation instructions.
Install Python3
and virtualenv
see Option 2
in INSTALL.md
- All-in-one:
make all
- Setup, test and package.
- Setup:
make setup-env
- Installs all dependencies.
- Export dependencies of the environment:
make export_env
- Export a requirements.txt file containing the detailed dependencies of the environment.
- Test:
make test
- Runs all tests.
- Using pytest
- Clean:
make clean
- Removes the environment.
- Removes all cached files.
- Check:
make check
- Use It to check that
which pip3
andwhich python3
points to the right path.
- Use It to check that
- Lint:
make lint
- Checks PEP8 conformance and code smells using pylint.
- Package:
make package
- Creates a bundle of software to be installed.
Note: Run Setup
as your init command (or after Clean
)
<command> delete or show or search.
--images-path /path/to/images/
The Directory containing images.
--output-path /path/to/output/
The Directory containing results.
-q /path/to/image/, --query /path/to/image/
Path to the query image
--tree-type {KDTree,cKDTree}
--leaf-size LEAF_SIZE
Leaf size of the tree.
--hash-algorithm {average_hash,dhash,phash,whash}
Hash algorithm to use.
--hash-size HASH_SIZE
Hash size to use.
-d {euclidean,l2,minkowski,p,manhattan,cityblock,l1,chebyshev,infinity}, --distance-metric {euclidean,l2,minkowski,p,manhattan,cityblock,l1,chebyshev,infinity}
Distance metric to use
--nearest-neighbors NEAREST_NEIGHBORS
# of nearest neighbors.
--threshold THRESHOLD
Threshold.
--parallel [parallel]
Whether to parallelize the computation.
--batch-size BATCH_SIZE
The batch size is used when parallel is set to true.
--backup-keep [BACKUP_KEEP]
Whether to save the image to keep into a folder.
--backup-duplicate [BACKUP_DUPLICATE]
Whether to save the duplicates into a folder.
--safe-deletion [SAFE_DELETION]
Whether to execute the deletion without really
deleting nothing.
--image-w IMAGE_W The source image is resized down to or up to the
specified size.
--image-h IMAGE_H The source image is resized down to or up to the
specified size.
$ deduplication delete --images_path <target_dir> --output_path <output_dir> --tree_type KDTree
For example:
delete \
--images-path datasets/potatoes_multi_folder \
--output-path outputs \
--tree-type KDTree \
--threshold 40 \
--parallel y \
--nearest-neighbors 5 \
--hash-algorithm phash \
--hash-size 8 \
--distance-metric manhattan \
--backup-keep y \
--backup-duplicate y \
--safe-deletion y \
Building the dataset...
Parallel mode has been enabled...
CPU: 16
delegate work...
100%|██████████| 1/1 [00:00<00:00, 2231.01it/s]
get the results...
100%|██████████| 1/1 [00:00<00:00, 773.57it/s]
Building the KDTree...
Finding duplicates and/or near duplicates...
Max distance: 33.0
Min distance: 0.0
number of files to remove: 28
number of files to keep: 4
28 duplicates or near duplicates has been founded in 0.0027272701263427734 seconds
We have found 28/32 duplicates in folder
Backuping images...
100%|██████████| 28/28 [00:00<00:00, 4087.45it/s]
$ deduplication search \
--images_path <target_dir> \
--output_path <output_dir> \
--query <specify a query image file>
For example:
$ deduplication search \
--images-path datasets/potatoes \
--output-path outputs \
--tree-type KDTree \
--threshold 40 \
--parallel f \
--nearest-neighbors 5 \
--hash-algorithm phash \
--hash-size 8 \
--distance-metric manhattan \
--query datasets/potatoes/2018-12-11-15-031193.png
$ deduplication show --images_path <target_dir> --output_path <output_dir>
For example:
$ show
--images-path datasets/potatoes \
--output-path outputs \
--parallel y \
--image-w 32 \
--image-h 32
- Using t-SNE in order to visualize a clusters of near-duplicate images:
- Looking for inspiration from:
- Trying to use Parallel t-SNE implementation with Python and Torch wrappers.
- Trying to use Fast Fourier Transform-accelerated Interpolation-based t-SNE (FIt-SNE)
- Trying to use Extensible, parallel implementations of t-SNE
- Trying to use pykdtree instead of KDTree.
- Trying to use Locality Sensitive Hashing instead of KDTree.
- Trying to use BK-trees instead of KDTree.
- You could also use k-means to cluster the images and only search within clusters that are similar to the query.
- ImageHash
- ImageHash - Official Github repository
- KDTree - Wikipedia
- Introductory guide to Information Retrieval using kNN and KDTree
- Perceptual Hash computation
- The complete guide to building an image search engine with Python and OpenCV
- Visualizing Embeddings With t-SNE
- t-SNE visualization of CNN codes
- Benchmarking Nearest Neighbor Searches in Python
- Fingerprinting Images for Near-Duplicate Detection
- Image dataset - Caltech 101