StellarGraph - Machine Learning on Graphs

Overview

StellarGraph Machine Learning library logo

pypi downloads

StellarGraph Machine Learning Library

StellarGraph is a Python library for machine learning on graphs and networks.

Table of Contents

Introduction

The StellarGraph library offers state-of-the-art algorithms for graph machine learning, making it easy to discover patterns and answer questions about graph-structured data. It can solve many machine learning tasks:

Graph-structured data represent entities as nodes (or vertices) and relationships between them as edges (or links), and can include data associated with either as attributes. For example, a graph can contain people as nodes and friendships between them as links, with data like a person's age and the date a friendship was established. StellarGraph supports analysis of many kinds of graphs:

  • homogeneous (with nodes and links of one type),
  • heterogeneous (with more than one type of nodes and/or links)
  • knowledge graphs (extreme heterogeneous graphs with thousands of types of edges)
  • graphs with or without data associated with nodes
  • graphs with edge weights

StellarGraph is built on TensorFlow 2 and its Keras high-level API, as well as Pandas and NumPy. It is thus user-friendly, modular and extensible. It interoperates smoothly with code that builds on these, such as the standard Keras layers and scikit-learn, so it is easy to augment the core graph machine learning algorithms provided by StellarGraph. It is thus also easy to install with pip or Anaconda.

Getting Started

The numerous detailed and narrated examples are a good way to get started with StellarGraph. There is likely to be one that is similar to your data or your problem (if not, let us know).

You can start working with the examples immediately in Google Colab or Binder by clicking the and badges within each Jupyter notebook.

Alternatively, you can run download a local copy of the demos and run them using jupyter. The demos can be downloaded by cloning the master branch of this repository, or by using the curl command below:

curl -L https://github.com/stellargraph/stellargraph/archive/master.zip | tar -xz --strip=1 stellargraph-master/demos

The dependencies required to run most of our demo notebooks locally can be installed using one of the following:

  • Using pip: pip install stellargraph[demos]
  • Using conda: conda install -c stellargraph stellargraph

(See Installation section for more details and more options.)

Getting Help

If you get stuck or have a problem, there are many ways to make progress and get help or support:

Example: GCN

One of the earliest deep machine learning algorithms for graphs is a Graph Convolution Network (GCN) [6]. The following example uses it for node classification: predicting the class from which a node comes. It shows how easy it is to apply using StellarGraph, and shows how StellarGraph integrates smoothly with Pandas and TensorFlow and libraries built on them.

Data preparation

Data for StellarGraph can be prepared using common libraries like Pandas and scikit-learn.

import pandas as pd
from sklearn import model_selection

def load_my_data():
    # your own code to load data into Pandas DataFrames, e.g. from CSV files or a database
    ...

nodes, edges, targets = load_my_data()

# Use scikit-learn to compute training and test sets
train_targets, test_targets = model_selection.train_test_split(targets, train_size=0.5)

Graph machine learning model

This is the only part that is specific to StellarGraph. The machine learning model consists of some graph convolution layers followed by a layer to compute the actual predictions as a TensorFlow tensor. StellarGraph makes it easy to construct all of these layers via the GCN model class. It also makes it easy to get input data in the right format via the StellarGraph graph data type and a data generator.

import stellargraph as sg
import tensorflow as tf

# convert the raw data into StellarGraph's graph format for faster operations
graph = sg.StellarGraph(nodes, edges)

generator = sg.mapper.FullBatchNodeGenerator(graph, method="gcn")

# two layers of GCN, each with hidden dimension 16
gcn = sg.layer.GCN(layer_sizes=[16, 16], generator=generator)
x_inp, x_out = gcn.in_out_tensors() # create the input and output TensorFlow tensors

# use TensorFlow Keras to add a layer to compute the (one-hot) predictions
predictions = tf.keras.layers.Dense(units=len(ground_truth_targets.columns), activation="softmax")(x_out)

# use the input and output tensors to create a TensorFlow Keras model
model = tf.keras.Model(inputs=x_inp, outputs=predictions)

Training and evaluation

The model is a conventional TensorFlow Keras model, and so tasks such as training and evaluation can use the functions offered by Keras. StellarGraph's data generators make it simple to construct the required Keras Sequences for input data.

# prepare the model for training with the Adam optimiser and an appropriate loss function
model.compile("adam", loss="categorical_crossentropy", metrics=["accuracy"])

# train the model on the train set
model.fit(generator.flow(train_targets.index, train_targets), epochs=5)

# check model generalisation on the test set
(loss, accuracy) = model.evaluate(generator.flow(test_targets.index, test_targets))
print(f"Test set: loss = {loss}, accuracy = {accuracy}")

This algorithm is spelled out in more detail in its extended narrated notebook. We provide many more algorithms, each with a detailed example.

Algorithms

The StellarGraph library currently includes the following algorithms for graph machine learning:

Algorithm Description
GraphSAGE [1] Supports supervised as well as unsupervised representation learning, node classification/regression, and link prediction for homogeneous networks. The current implementation supports multiple aggregation methods, including mean, maxpool, meanpool, and attentional aggregators.
HinSAGE Extension of GraphSAGE algorithm to heterogeneous networks. Supports representation learning, node classification/regression, and link prediction/regression for heterogeneous graphs. The current implementation supports mean aggregation of neighbour nodes, taking into account their types and the types of links between them.
attri2vec [4] Supports node representation learning, node classification, and out-of-sample node link prediction for homogeneous graphs with node attributes.
Graph ATtention Network (GAT) [5] The GAT algorithm supports representation learning and node classification for homogeneous graphs. There are versions of the graph attention layer that support both sparse and dense adjacency matrices.
Graph Convolutional Network (GCN) [6] The GCN algorithm supports representation learning and node classification for homogeneous graphs. There are versions of the graph convolutional layer that support both sparse and dense adjacency matrices.
Cluster Graph Convolutional Network (Cluster-GCN) [10] An extension of the GCN algorithm supporting representation learning and node classification for homogeneous graphs. Cluster-GCN scales to larger graphs and can be used to train deeper GCN models using Stochastic Gradient Descent.
Simplified Graph Convolutional network (SGC) [7] The SGC network algorithm supports representation learning and node classification for homogeneous graphs. It is an extension of the GCN algorithm that smooths the graph to bring in more distant neighbours of nodes without using multiple layers.
(Approximate) Personalized Propagation of Neural Predictions (PPNP/APPNP) [9] The (A)PPNP algorithm supports fast and scalable representation learning and node classification for attributed homogeneous graphs. In a semi-supervised setting, first a multilayer neural network is trained using the node attributes as input. The predictions from the latter network are then diffused across the graph using a method based on Personalized PageRank.
Node2Vec [2] The Node2Vec and Deepwalk algorithms perform unsupervised representation learning for homogeneous networks, taking into account network structure while ignoring node attributes. The node2vec algorithm is implemented by combining StellarGraph's random walk generator with the word2vec algorithm from Gensim. Learned node representations can be used in downstream machine learning models implemented using Scikit-learn, Keras, TensorFlow or any other Python machine learning library.
Metapath2Vec [3] The metapath2vec algorithm performs unsupervised, metapath-guided representation learning for heterogeneous networks, taking into account network structure while ignoring node attributes. The implementation combines StellarGraph's metapath-guided random walk generator and Gensim word2vec algorithm. As with node2vec, the learned node representations (node embeddings) can be used in downstream machine learning models to solve tasks such as node classification, link prediction, etc, for heterogeneous networks.
Relational Graph Convolutional Network [11] The RGCN algorithm performs semi-supervised learning for node representation and node classification on knowledge graphs. RGCN extends GCN to directed graphs with multiple edge types and works with both sparse and dense adjacency matrices.
ComplEx[12] The ComplEx algorithm computes embeddings for nodes (entities) and edge types (relations) in knowledge graphs, and can use these for link prediction
GraphWave [13] GraphWave calculates unsupervised structural embeddings via wavelet diffusion through the graph.
Supervised Graph Classification A model for supervised graph classification based on GCN [6] layers and mean pooling readout.
Watch Your Step [14] The Watch Your Step algorithm computes node embeddings by using adjacency powers to simulate expected random walks.
Deep Graph Infomax [15] Deep Graph Infomax trains unsupervised GNNs to maximize the shared information between node level and graph level features.
Continuous-Time Dynamic Network Embeddings (CTDNE) [16] Supports time-respecting random walks which can be used in a similar way as in Node2Vec for unsupervised representation learning.
DistMult [17] The DistMult algorithm computes embeddings for nodes (entities) and edge types (relations) in knowledge graphs, and can use these for link prediction
DGCNN [18] The Deep Graph Convolutional Neural Network (DGCNN) algorithm for supervised graph classification.
TGCN [19] The GCN_LSTM model in StellarGraph follows the Temporal Graph Convolutional Network architecture proposed in the TGCN paper with a few enhancements in the layers architecture.

Installation

StellarGraph is a Python 3 library and we recommend using Python version 3.6. The required Python version can be downloaded and installed from python.org. Alternatively, use the Anaconda Python environment, available from anaconda.com.

The StellarGraph library can be installed from PyPI, from Anaconda Cloud, or directly from GitHub, as described below.

Install StellarGraph using PyPI:

To install StellarGraph library from PyPI using pip, execute the following command:

pip install stellargraph

Some of the examples require installing additional dependencies as well as stellargraph. To install these dependencies as well as StellarGraph using pip execute the following command:

pip install stellargraph[demos]

The community detection demos require python-igraph which is only available on some platforms. To install this in addition to the other demo requirements:

pip install stellargraph[demos,igraph]

Install StellarGraph in Anaconda Python:

The StellarGraph library is available an Anaconda Cloud and can be installed in Anaconda Python using the command line conda tool, execute the following command:

conda install -c stellargraph stellargraph

Install StellarGraph from GitHub source:

First, clone the StellarGraph repository using git:

git clone https://github.com/stellargraph/stellargraph.git

Then, cd to the StellarGraph folder, and install the library by executing the following commands:

cd stellargraph
pip install .

Some of the examples in the demos directory require installing additional dependencies as well as stellargraph. To install these dependencies as well as StellarGraph using pip execute the following command:

pip install .[demos]

Citing

StellarGraph is designed, developed and supported by CSIRO's Data61. If you use any part of this library in your research, please cite it using the following BibTex entry

@misc{StellarGraph,
  author = {CSIRO's Data61},
  title = {StellarGraph Machine Learning Library},
  year = {2018},
  publisher = {GitHub},
  journal = {GitHub Repository},
  howpublished = {\url{https://github.com/stellargraph/stellargraph}},
}

References

  1. Inductive Representation Learning on Large Graphs. W.L. Hamilton, R. Ying, and J. Leskovec. Neural Information Processing Systems (NIPS), 2017, (link webpage)

  2. Node2Vec: Scalable Feature Learning for Networks. A. Grover, J. Leskovec. ACM SIGKDD International Conference on Knowledge Discovery and Data Mining (KDD), 2016, (link)

  3. Metapath2Vec: Scalable Representation Learning for Heterogeneous Networks. Yuxiao Dong, Nitesh V. Chawla, and Ananthram Swami. ACM SIGKDD International Conference on Knowledge Discovery and Data Mining (KDD), 135–144, 2017, (link)

  4. Attributed Network Embedding via Subspace Discovery. D. Zhang, Y. Jie, X. Zhu and C. Zhang, Data Mining and Knowledge Discovery, 2019, (link)

  5. Graph Attention Networks. P. Veličković et al. International Conference on Learning Representations (ICLR), 2018, (link)

  6. Graph Convolutional Networks (GCN): Semi-Supervised Classification with Graph Convolutional Networks. Thomas N. Kipf, Max Welling. International Conference on Learning Representations (ICLR), 2017, (link)

  7. Simplifying Graph Convolutional Networks. F. Wu, T. Zhang, A. H. de Souza, C. Fifty, T. Yu, and K. Q. Weinberger. International Conference on Machine Learning (ICML), 2019, (link)

  8. Adversarial Examples on Graph Data: Deep Insights into Attack and Defense. H. Wu, C. Wang, Y. Tyshetskiy, A. Docherty, K. Lu, and L. Zhu. IJCAI 2019, (link)

  9. Predict then propagate: Graph neural networks meet personalized PageRank. J. Klicpera, A. Bojchevski, A., and S. Günnemann, ICLR, 2019, arXiv:1810.05997.(link)

  10. Cluster-GCN: An Efficient Algorithm for Training Deep and Large Graph Convolutional Networks. W. Chiang, X. Liu, S. Si, Y. Li, S. Bengio, and C. Hsiej, KDD, 2019, arXiv:1905.07953.(link)

  11. Modeling relational data with graph convolutional networks. M. Schlichtkrull, T. N. Kipf, P. Bloem, R. Van Den Berg, I. Titov, and M. Welling, European Semantic Web Conference, 2018, arXiv:1609.02907 (link).

  12. Complex Embeddings for Simple Link Prediction. T. Trouillon, J. Welbl, S. Riedel, É. Gaussier and G. Bouchard, ICML, 2016. (link)

  13. Learning Structural Node Embeddings via Diffusion Wavelets. C. Donnat, M. Zitnik, D. Hallac, and J. Leskovec, SIGKDD, 2018, arXiv:1710.10321 (link)

  14. Watch Your Step: Learning Node Embeddings via Graph Attention. S. Abu-El-Haija, B. Perozzi, R. Al-Rfou and A. Alemi, NIPS, 2018, arXiv:1710.09599 (link)

  15. Deep Graph Infomax. P. Veličković, W. Fedus, W. L. Hamilton, P. Lio, Y. Bengio, R. D. Hjelm. International Conference on Learning Representations (ICLR), 2019, arXiv:1809.10341, (link).

  16. Continuous-Time Dynamic Network Embeddings. Giang Hoang Nguyen, John Boaz Lee, Ryan A. Rossi, Nesreen K. Ahmed, Eunyee Koh, and Sungchul Kim. Proceedings of the 3rd International Workshop on Learning Representations for Big Networks (WWW BigNet) 2018. (link)

  17. Embedding Entities and Relations for Learning and Inference in Knowledge Bases. Bishan Yang, Wen-tau Yih, Xiaodong He, Jianfeng Gao, and Li Deng, ICLR, 2015. arXiv:1412.6575 (link)

  18. An End-to-End Deep Learning Architecture for Graph Classification. Muhan Zhang, Zhicheng Cui, Marion Neumann, and Yixin Chen, AAAI, 2018. (link)

  19. T-GCN: A Temporal Graph Convolutional Network for Traffic Prediction. Ling Zhao, Yujiao Song, Chao Zhang, Yu Liu, Pu Wang, Tao Lin, Min Deng, and Haifeng Li. IEEE Transactions on Intelligent Transportation Systems, 2019. (link)

Comments
  • Move tensorflow to extras

    Move tensorflow to extras

    Part of #546

    I'm not sure if we would land this as is, since this feels like a big breaking change, so I'm open to suggestions for how to make migration easier.

    I'm hoping to figure out a way to print a warning if tensorflow is not installed with stellargraph as @adocherty has suggested in #546 but let me know if you have ideas.

    I also didn't add a stellargraph[gpu] option for now since we're not verifying it in CI currently, although the user would have the option to try use their own gpu tensorflow installation regardless.

    opened by kjun9 35
  • Feature/node2vec for issue Word2Vec in StellarGraph #255

    Feature/node2vec for issue Word2Vec in StellarGraph #255

    This is the pull request for adding Keras Node2Vec layer to StellarGraph library.

    I mainly made the following changes:

    1. Add the Node2Vec layer.
    2. Add the Node2VecNodeGenerator and Node2VecLinkGenerator mapper.
    3. Change the interface for the __init__ and run function of BiasedRandomWalk to make UnSupervisedSampler support BiasedRandomWalk
    4. Write the Keras-node2vec notebook examples for embedding learning and node classification
    5. Add the unit test for the added node2vec layer and mappers
    opened by daokunzhang 26
  • Replace inheritance of NetworkX by encapsulation

    Replace inheritance of NetworkX by encapsulation

    Under this revision, StellarGraph is no longer also a NetworkX - it now has its own interface. The NetworkXStellarGraph implementation class (formerly StellarGraphBase) now wraps the supplied NetworkX object.

    opened by geoffj-d61 20
  • Feature/144 new stellargraph

    Feature/144 new stellargraph

    Notes:

    • The code in this branch does not yet comprise a complete replacement for all uses of StellarGraph.
    • The particular aim was to sufficiently capture the efficient handling of node and edge data in the form of Pandas data-frames and/or type-specific maps.
    • The short-term goal was to document and implement enough of the StellarGraph interface to permit the node classification of the Cora dataset using GraphSAGE.
    • Further work is required to finish capturing and implementing the full StellarGraph interface.
    • However, the current work should serve as an example for review of the techniques used, in order to see if this approach is viable in regards to memory usage and speed of access.
    sg-library 
    opened by geoffj-d61 17
  • How to train node classification using custom dataset

    How to train node classification using custom dataset

    HI, thanks for the great library, I have seen the loading pandas jupyter to generate the node classification dataset, but I confused with the train example of node classification (gat and graphsage). For my understanding CORA network dataset has only single graph input. So how can I train multiple input graph Let's say I have 10 invoice or id card image, So using OCR I able to get the bounding box of text Now I want to classify the bounding box whether it is a company name, address, etc. based on the location of structure so that's why I planned to use GCN technique. This is my dataset look like: invoice_1: source | target | distance feature | isalpha feature | label 0 1 xxx 1 header 0 2 xxx 0 bill no 0 3 xxx 1 company_name 3 7 xxx 0 date invoice_2: source | target | distance feature | isalpha feature | label 0 1 xxx 1 header 0 2 xxx 0 bill no 0 4 xxx 1 company_name 4 5 xxx 1 company_name

    and so on first two invoice_2 is the same billing but ocr bounding box will differ if invoice image varies like first invoice photo taken near so the ocr detect the company service as a single bounding box but in second invoice photo taken far so, the ocr detect the company separate and service as a separate bounding box. So How can I train the gat or graphsage with this dataset which as a separate CSV file for each invoice image?

    I inspired by this https://github.com/dhavalpotdar/Graph-Convolution-on-Structured-Documents GitHub link to write a code for invoice and id card to my use case and your loading pandas homogenous graph example to generate above file CSV. I hope that the above explanation will be understandable. Thanks @huonw

    external sg-library 
    opened by vigneshgig 16
  • Creating embedding is not reproducible

    Creating embedding is not reproducible

    I am using StellarGraph to create embeddings for a particular graph/feature set. Unfortunately, the embeddings are different each time I create/train the graph despite providing identical information each time.

    Is this bug, or am I using StellarGraph incorrectly?

    Below is the code that demonstrates the issue:

    import networkx as nx
    import random
    import numpy as np
    import pandas as pd
    import keras
    import stellargraph as sg
    from stellargraph.mapper import GraphSAGELinkGenerator, GraphSAGENodeGenerator
    from stellargraph.layer import GraphSAGE, link_classification
    from stellargraph.data import UnsupervisedSampler
    
    # Establish random seed
    RANDOM_SEED = 42
    random.seed(RANDOM_SEED)
    
    # Create a graph from well-known karate club data
    print(f"Creating graph")
    graph = nx.karate_club_graph()
    
    # Create features for each node
    print(f"Creating features")
    features = []
    nodes = list(graph.nodes)
    columns = ["c-" + str(x) for x in range(10)]
    nodes.sort()
    for node in nodes:
        f = {c: random.random() for c in columns}
        features.append(f)
    
    features_df = pd.DataFrame(features)
    print(f"features_df: \n{features_df}")
    
    for i in range(2):
        print(f"----- Iteration: {i} -----")
    
        # Create the model and generators
        print(f"Creating the model and generators")
        Gs = sg.StellarGraph(graph, node_features=features_df)
        unsupervisedSamples = UnsupervisedSampler(Gs, nodes=graph.nodes(), length=5, number_of_walks=3, seed=RANDOM_SEED)
        train_gen = GraphSAGELinkGenerator(Gs, 50, [5, 5], seed=RANDOM_SEED).flow(unsupervisedSamples)
        graphsage = GraphSAGE(layer_sizes=[100, 100], generator=train_gen, bias=True, dropout=0.0, normalize="l2")
        x_inp_src, x_out_src = graphsage.node_model(flatten_output=False)
        x_inp_dst, x_out_dst = graphsage.node_model(flatten_output=False)
    
        x_inp = [x for ab in zip(x_inp_src, x_inp_dst) for x in ab]
        x_out = [x_out_src, x_out_dst]
        edge_embedding_method = "l2"
        prediction = link_classification(output_dim=1, output_act="sigmoid", edge_embedding_method=edge_embedding_method)(x_out)
    
        # Create and train the Keras model
        model = keras.Model(inputs=x_inp, outputs=prediction)
        learning_rate = 1e-2
        model.compile(
            optimizer=keras.optimizers.Adam(lr=learning_rate),
            loss=keras.losses.binary_crossentropy,
            metrics=[keras.metrics.binary_accuracy])
    
        _ = model.fit_generator(train_gen, epochs=5, verbose=2, use_multiprocessing=False, workers=1, shuffle=False)
    
        # Create the embeddings
        print(f"Creating the embeddings")
        nodes = list(graph.nodes)
        nodes.sort()
        print(f"Nodes: {nodes}")
    
        # Create a generator that serves up nodes for use in embedding prediction / creation
        node_gen = GraphSAGENodeGenerator(Gs, 50, [5, 5], seed=RANDOM_SEED).flow(nodes)
    
        embedding_model = keras.Model(inputs=x_inp_src, outputs=x_out_src)
        embeddings = embedding_model.predict_generator(node_gen, workers=4, verbose=1)
        embeddings = embeddings[:, 0, :]
    
        np.set_printoptions(threshold=10)
        print(f"embeddings: {embeddings.shape} \n{embeddings}")
    

    There are a number of debug (print output) statements when the code is executed. (sample output is shown below). Note that the embeddings are different despite the identical inputs, graph configuration, model configuration, and random see values.

    ----- Iteration: 0 -----
    :
    :
    1/1 [==============================] - 0s 58ms/step
    embeddings: (34, 100) 
    [[-0.10566715  0.02253576 -0.18743701 ... -0.1028127   0.03689012
      -0.02482301]
     [-0.03171733  0.01606975 -0.08616363 ... -0.11775644  0.0429472
      -0.02371055]
     [-0.05802531  0.03910012 -0.10229243 ... -0.15050544  0.06637941
      -0.01950052]
     ...
     [ 0.03011296  0.08852117 -0.01836969 ... -0.154132    0.03844732
      -0.08643046]
     [ 0.01052345 -0.0123206   0.08913474 ... -0.11741614  0.03202919
      -0.04432516]
     [ 0.01951274  0.06263477  0.07959272 ... -0.10350229  0.05735112
      -0.0368157 ]]
    :
    :
    ----- Iteration: 1 -----
    embeddings: (34, 100) 
    [[ 0.11182436 -0.02642134  0.01168384 ...  0.10322241 -0.01680471
      -0.03918815]
     [ 0.02391489  0.02674667 -0.00091334 ...  0.12946768 -0.02389602
      -0.01414653]
     [ 0.08718258 -0.01711811 -0.05704292 ...  0.13477756 -0.00658288
      -0.05889895]
     ...
     [ 0.06843725 -0.13134597 -0.10870655 ...  0.11091235 -0.05146989
      -0.06138216]
     [-0.00593233 -0.05901312 -0.02113489 ... -0.01590953 -0.02516254
      -0.02280537]
     [ 0.00871993 -0.04059998 -0.07237951 ... -0.01590569 -0.00954109
      -0.01116194]]
    
    bug external sg-library 
    opened by ericbroda 16
  • Problem in GCN link prediction example

    Problem in GCN link prediction example

    Describe the bug

    It seems that the GCN link prediction example doesn't perform the same performance in the doc. And the GCN seems didn't learn something from the data, I am not sure why this happen.

    To Reproduce

    Steps to reproduce the behavior:

    1. Go to the colab example code https://colab.research.google.com/github/stellargraph/stellargraph/blob/master/demos/link-prediction/gcn-link-prediction.ipynb#scrollTo=cW8U-jvPKdob.
    2. Just run all the commands.
    3. Can't get the same performance in https://stellargraph.readthedocs.io/en/stable/demos/link-prediction/gcn-link-prediction.html, the acc is close to 0 in the reproduction of example.

    I just run the code w/o any modification.

    Environment

    Operating system: 1. Ubuntu 2. colab

    Python version: 1. python3.6.9 2. colab example default

    Package versions: 1. stellargraph==1.2.1, tensorflow==2.2.0 2. colab example default

    <IPython.core.display.HTML object>
    StellarGraph: Undirected multigraph
     Nodes: 2708, Edges: 5429
    
     Node types:
      paper: [2708]
        Features: float32 vector, length 1440
        Edge types: paper-cites->paper
    
     Edge types:
        paper-cites->paper: [5429]
            Weights: all 1 (default)
            Features: none
    ** Sampled 542 positive and 542 negative edges. **
    ** Sampled 488 positive and 488 negative edges. **
    Using GCN (local pooling) filters...
    Using GCN (local pooling) filters...
    2020-07-08 02:02:51.125100: I tensorflow/stream_executor/platform/default/dso_loader.cc:44] Successfully opened dynamic library libcublas.so.10
    1/1 [==============================] - 0s 261us/step - loss: 1.7441 - acc: 0.0000e+00
    1/1 [==============================] - 0s 372us/step - loss: 1.7190 - acc: 0.0000e+00
    
    Train Set Metrics of the initial (untrained) model:
            loss: 1.7441
            acc: 0.0000
    
    Test Set Metrics of the initial (untrained) model:
            loss: 1.7190
            acc: 0.0000
    Epoch 1/50
    1/1 - 0s - loss: 1.7230 - acc: 0.0000e+00 - val_loss: 1.6174 - val_acc: 0.0000e+00
    Epoch 2/50
    1/1 - 0s - loss: 1.8744 - acc: 0.0000e+00 - val_loss: 0.6929 - val_acc: 0.0000e+00
    Epoch 3/50
    1/1 - 0s - loss: 0.7559 - acc: 0.0000e+00 - val_loss: 0.8678 - val_acc: 0.0000e+00
    Epoch 4/50
    1/1 - 0s - loss: 0.8746 - acc: 0.0000e+00 - val_loss: 0.9703 - val_acc: 0.0000e+00
    Epoch 5/50
    1/1 - 0s - loss: 0.9689 - acc: 0.0000e+00 - val_loss: 0.9082 - val_acc: 0.0000e+00
    Epoch 6/50
    1/1 - 0s - loss: 0.8899 - acc: 0.0000e+00 - val_loss: 0.7689 - val_acc: 0.0000e+00
    Epoch 7/50
    1/1 - 0s - loss: 0.7362 - acc: 0.0000e+00 - val_loss: 0.6734 - val_acc: 0.0000e+00
    Epoch 8/50
    1/1 - 0s - loss: 0.6950 - acc: 0.0000e+00 - val_loss: 0.7262 - val_acc: 0.0000e+00
    Epoch 9/50
    1/1 - 0s - loss: 0.7597 - acc: 0.0000e+00 - val_loss: 0.9009 - val_acc: 0.0000e+00
    Epoch 10/50
    1/1 - 0s - loss: 1.0559 - acc: 0.0000e+00 - val_loss: 0.8252 - val_acc: 0.0000e+00
    Epoch 11/50
    1/1 - 0s - loss: 0.9358 - acc: 0.0000e+00 - val_loss: 0.6823 - val_acc: 0.0000e+00
    Epoch 12/50
    1/1 - 0s - loss: 0.7335 - acc: 0.0000e+00 - val_loss: 0.6319 - val_acc: 0.0000e+00
    Epoch 13/50
    1/1 - 0s - loss: 0.5645 - acc: 0.0000e+00 - val_loss: 0.6511 - val_acc: 0.0000e+00
    Epoch 14/50
    1/1 - 0s - loss: 0.6124 - acc: 0.0000e+00 - val_loss: 0.6859 - val_acc: 0.0000e+00
    Epoch 15/50
    1/1 - 0s - loss: 0.6148 - acc: 0.0000e+00 - val_loss: 0.7000 - val_acc: 0.0000e+00
    Epoch 16/50
    1/1 - 0s - loss: 0.6342 - acc: 0.0000e+00 - val_loss: 0.6994 - val_acc: 0.0000e+00
    Epoch 17/50
    1/1 - 0s - loss: 0.6002 - acc: 0.0000e+00 - val_loss: 0.6820 - val_acc: 0.0000e+00
    Epoch 18/50
    1/1 - 0s - loss: 0.5741 - acc: 0.0000e+00 - val_loss: 0.6816 - val_acc: 0.0000e+00
    Epoch 19/50
    1/1 - 0s - loss: 0.5270 - acc: 0.0000e+00 - val_loss: 0.6888 - val_acc: 0.0000e+00
    Epoch 20/50
    1/1 - 0s - loss: 0.5358 - acc: 0.0000e+00 - val_loss: 0.7120 - val_acc: 0.0000e+00
    Epoch 21/50
    1/1 - 0s - loss: 0.5582 - acc: 0.0000e+00 - val_loss: 0.7397 - val_acc: 0.0000e+00
    Epoch 22/50
    1/1 - 0s - loss: 0.6449 - acc: 0.0000e+00 - val_loss: 0.7800 - val_acc: 0.0000e+00
    Epoch 23/50
    1/1 - 0s - loss: 0.5558 - acc: 0.0000e+00 - val_loss: 0.6514 - val_acc: 0.0000e+00
    Epoch 24/50
    1/1 - 0s - loss: 0.5180 - acc: 0.0000e+00 - val_loss: 0.6666 - val_acc: 0.0000e+00
    Epoch 25/50
    1/1 - 0s - loss: 0.5070 - acc: 0.0000e+00 - val_loss: 0.6780 - val_acc: 0.0000e+00
    Epoch 26/50
    1/1 - 0s - loss: 0.5492 - acc: 0.0000e+00 - val_loss: 0.7167 - val_acc: 0.0000e+00
    Epoch 27/50
    1/1 - 0s - loss: 0.5637 - acc: 0.0000e+00 - val_loss: 0.7343 - val_acc: 0.0000e+00
    Epoch 28/50
    1/1 - 0s - loss: 0.6122 - acc: 0.0000e+00 - val_loss: 0.7493 - val_acc: 0.0000e+00
    Epoch 29/50
    1/1 - 0s - loss: 0.6122 - acc: 0.0000e+00 - val_loss: 0.7420 - val_acc: 0.0000e+00
    Epoch 30/50
    1/1 - 0s - loss: 0.5376 - acc: 0.0000e+00 - val_loss: 0.7160 - val_acc: 0.0000e+00
    Epoch 31/50
    1/1 - 0s - loss: 0.5866 - acc: 0.0000e+00 - val_loss: 0.6874 - val_acc: 0.0000e+00
    Epoch 32/50
    1/1 - 0s - loss: 0.5429 - acc: 0.0000e+00 - val_loss: 0.6786 - val_acc: 0.0000e+00
    Epoch 33/50
    1/1 - 0s - loss: 0.6190 - acc: 0.0000e+00 - val_loss: 0.6995 - val_acc: 0.0000e+00
    Epoch 34/50
    1/1 - 0s - loss: 0.5032 - acc: 0.0000e+00 - val_loss: 0.7124 - val_acc: 0.0000e+00
    Epoch 35/50
    1/1 - 0s - loss: 0.5199 - acc: 0.0000e+00 - val_loss: 0.7479 - val_acc: 0.0000e+00
    Epoch 36/50
    1/1 - 0s - loss: 0.5283 - acc: 0.0000e+00 - val_loss: 0.7146 - val_acc: 0.0000e+00
    Epoch 37/50
    1/1 - 0s - loss: 0.5227 - acc: 0.0000e+00 - val_loss: 0.6946 - val_acc: 0.0000e+00
    Epoch 38/50
    1/1 - 0s - loss: 0.4818 - acc: 0.0000e+00 - val_loss: 0.6404 - val_acc: 0.0000e+00
    Epoch 39/50
    1/1 - 0s - loss: 0.4635 - acc: 0.0000e+00 - val_loss: 0.6060 - val_acc: 0.0000e+00
    Epoch 40/50
    1/1 - 0s - loss: 0.4405 - acc: 0.0000e+00 - val_loss: 0.6063 - val_acc: 0.0000e+00
    Epoch 41/50
    1/1 - 0s - loss: 0.4395 - acc: 0.0000e+00 - val_loss: 0.6093 - val_acc: 0.0000e+00
    Epoch 42/50
    1/1 - 0s - loss: 0.4369 - acc: 0.0000e+00 - val_loss: 0.6352 - val_acc: 0.0000e+00
    Epoch 43/50
    1/1 - 0s - loss: 0.4165 - acc: 0.0000e+00 - val_loss: 0.6561 - val_acc: 0.0000e+00
    Epoch 44/50
    1/1 - 0s - loss: 0.3748 - acc: 0.0000e+00 - val_loss: 0.6558 - val_acc: 0.0000e+00
    Epoch 45/50
    1/1 - 0s - loss: 0.3929 - acc: 0.0000e+00 - val_loss: 0.6668 - val_acc: 0.0000e+00
    Epoch 46/50
    1/1 - 0s - loss: 0.3927 - acc: 0.0000e+00 - val_loss: 0.6897 - val_acc: 0.0000e+00
    Epoch 47/50
    1/1 - 0s - loss: 0.3800 - acc: 0.0000e+00 - val_loss: 0.7172 - val_acc: 0.0000e+00
    Epoch 48/50
    1/1 - 0s - loss: 0.3637 - acc: 0.0000e+00 - val_loss: 0.7382 - val_acc: 0.0000e+00
    Epoch 49/50
    1/1 - 0s - loss: 0.3720 - acc: 0.0000e+00 - val_loss: 0.7558 - val_acc: 0.0000e+00
    Epoch 50/50
    1/1 - 0s - loss: 0.3790 - acc: 0.0000e+00 - val_loss: 0.8127 - val_acc: 0.0000e+00
    1/1 [==============================] - 0s 487us/step - loss: 0.3245 - acc: 0.0000e+00
    1/1 [==============================] - 0s 266us/step - loss: 0.8127 - acc: 0.0000e+00
    
    Train Set Metrics of the trained model:
            loss: 0.3245
            acc: 0.0000
    
    Test Set Metrics of the trained model:
            loss: 0.8127
            acc: 0.0000
    
    bug sg-library doc 
    opened by davidho27941 14
  • Link prediction comparison demo between Node2Vec, Attri2Vec, GraphSAGE and GCN

    Link prediction comparison demo between Node2Vec, Attri2Vec, GraphSAGE and GCN

    Following @huonw 's advice, I add a link prediction demo to compare the link prediction permanence on the Cora dataset under the same edge train-test-split setting.

    The results show that Attri2Vec performs best, while GraphSAGE and Node2Vec perform comparably.

    sg-library 
    opened by daokunzhang 14
  • Store adj dictionaries as one contiguous np array

    Store adj dictionaries as one contiguous np array

    This PR stored adj lists in one contiguous numpy array.

    For each adj dict, this PR instead stores the edge ilocs in one contiguous numpy array sorted by the index (source/target node for in/out dicts). The edge ilocs associated with a node are then accessed by:

    • mapping a node_iloc -> start_index, stop_index
    • lookup up flat array: -> flat[start_index:stop_index]

    ====== Memory

    Measuring the memory of FB15k in MiB for develop and this PR for different adj caches:

    | Ajd Lists | Develop | PR | | ----------- |:--------:| -----:| | None | 7.3 | 7.3 | | Directed | 14.2 | 11.9 | | Undirected | 16.7 | 12.1 |

    For directed graphs the adj lists are 1.4x smaller, and 1.2x smaller for undirected graphs.

    A nice property of this PR is that undirected adj lists, directed adj lists, and the edge lists now all use approximately the same amount of memory. (this doesn't apply if the node_ilocs and edge_ilocs are different types).

    ====== Neighbour lookup

    PR benchmark

    --------------------------------------------------------------------------------------- benchmark 'StellarGraph neighbours': 2 tests --------------------------------------------------------------------------------------
    Name (time in us)                               Min                   Max                  Mean              StdDev                Median                 IQR            Outliers         OPS            Rounds  Iterations
    ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
    test_benchmark_get_neighbours[True]        649.1660 (1.0)      2,333.2520 (1.0)        727.6934 (1.0)       86.5430 (1.0)        692.0295 (1.0)       41.2615 (1.0)       198;236  1,374.2051 (1.0)        1352           1
    test_benchmark_get_neighbours[False]     7,630.3470 (11.75)    8,945.7340 (3.83)     8,079.2179 (11.10)    256.9341 (2.97)     8,024.1330 (11.60)    275.9956 (6.69)         26;8    123.7744 (0.09)        116           1
    ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
    

    Develop benchmark

    --------------------------------------------------------------------------------------- benchmark 'StellarGraph neighbours': 2 tests ---------------------------------------------------------------------------------------
    Name (time in us)                               Min                    Max                  Mean              StdDev                Median                 IQR            Outliers         OPS            Rounds  Iterations
    ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
    test_benchmark_get_neighbours[True]        694.8380 (1.0)       2,825.8630 (1.0)        746.4933 (1.0)      113.9017 (1.0)        716.6200 (1.0)       28.2870 (1.0)        84;182  1,339.5968 (1.0)        1058           1
    test_benchmark_get_neighbours[False]     6,867.9860 (9.88)     10,783.6280 (3.82)     7,280.8026 (9.75)     521.6676 (4.58)     7,174.2410 (10.01)    251.7290 (8.90)          7;9    137.3475 (0.10)        129           1
    ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
    

    The lack of difference in get_neighbours benchmarks is unsurprising because the the adj list lookup only accounts for a small fraction of the time in .neighbors.

    ====== Adj list lookup

    Running:

    import stellargraph as sg
    
    graph, *_ = sg.datasets.FB15k().load()
    _ = graph.neighbors(0, use_ilocs=True)
    %timeit -n 5 -r 5 _ = [graph._edges._edges_dict[i] for i in range(len(graph.nodes()))]
    

    Yields:

    • 19.6 ms ± 1.06 ms per loop (mean ± std. dev. of 5 runs, 5 loops each) on develop
    • 12.2 ms ± 853 µs per loop (mean ± std. dev. of 5 runs, 5 loops each) on this PR

    Surprisingly, (to me at least!), this PR is twice as fast for neighbour lookups.

    ====== Construction Time

    Comparing construction time of test_benchmark_creation[both-100-1000-5000] shows that this PR is ~2x as fast.

    PR

    test_benchmark_creation[both-100-1000-5000]            11.9162 (1.76)     16.6076 (1.75)     13.3288 (1.70)     0.8721 (2.24)     13.2245 (1.73)     0.9719 (3.23)         20;3   75.0255 (0.59)         69           1
    

    Develop

    test_benchmark_creation[both-100-1000-5000]            19.6726 (2.79)     25.4567 (2.70)     22.1017 (2.82)     1.6570 (4.12)     22.2158 (2.87)     2.8661 (8.46)         20;0   45.2454 (0.35)         49           1
    

    For reference, on this PR the minimal construction of the above graph takes:

    test_benchmark_creation[None-100-1000-5000]             9.8109 (1.41)     12.3400 (1.34)     10.4754 (1.43)     0.5610 (1.76)     10.2614 (1.42)     0.5045 (2.31)         13;6   95.4618 (0.70)         80           1
    

    Suggesting that the average time for creating all 3 adj caches went from ~12s to ~3s, a ~4x speedup

    opened by kieranricardo 14
  • Create an explicit API for handling node ilocs

    Create an explicit API for handling node ilocs

    This PR makes a number of changes to support iloc usage:

    • the nodes are stored as ilocs in StellarGraph._edges instead of node ids
    • where possible StellarGraph functions now have a use_ilocs=False argument which specifies that any nodes input to the function are ilocs and node ilocs should be returned.
    • StellarGraph_get_index_for_nodes will be made public
    • tests for use_ilocs=True

    To keep the scope of this PR small, this PR does not change any samplers/generators. Many of these could be updated to natively use ilocs by passing use_ilocs=True to StellarGraph functions.

    See #870

    opened by kieranricardo 14
  • Store features as TensorFlow tensors, not NumPy arrays

    Store features as TensorFlow tensors, not NumPy arrays

    This PR stores features as a dictionary of Tensors instead of a dictionary of np.arrays, and uses tf.nn.embedding_lookup to access the features.

    Testing with GraphSAGE on CORA using my machine (MacOS + 9th gen quad core i7) and the following hyperparameters the training time decreases from 10s to 3s per epoch.

    batch_size = 200
    num_samples = [20, 20]
    generator = GraphSAGENodeGenerator(G, batch_size, num_samples)
    train_gen = generator.flow(node_subjects.index, targets, shuffle=True)
    graphsage = GraphSAGE(
    generator=generator, layer_sizes=[32, 32], activations=["relu", "relu"]
    

    ~See #1168~ See: #1228

    opened by kieranricardo 14
  • Bump setuptools from 46.1.3 to 65.5.1 in /docs

    Bump setuptools from 46.1.3 to 65.5.1 in /docs

    Bumps setuptools from 46.1.3 to 65.5.1.

    Release notes

    Sourced from setuptools's releases.

    v65.5.1

    No release notes provided.

    v65.5.0

    No release notes provided.

    v65.4.1

    No release notes provided.

    v65.4.0

    No release notes provided.

    v65.3.0

    No release notes provided.

    v65.2.0

    No release notes provided.

    v65.1.1

    No release notes provided.

    v65.1.0

    No release notes provided.

    v65.0.2

    No release notes provided.

    v65.0.1

    No release notes provided.

    v65.0.0

    No release notes provided.

    v64.0.3

    No release notes provided.

    v64.0.2

    No release notes provided.

    v64.0.1

    No release notes provided.

    v64.0.0

    No release notes provided.

    v63.4.3

    No release notes provided.

    v63.4.2

    No release notes provided.

    ... (truncated)

    Changelog

    Sourced from setuptools's changelog.

    v65.5.1

    Misc ^^^^

    • #3638: Drop a test dependency on the mock package, always use :external+python:py:mod:unittest.mock -- by :user:hroncok
    • #3659: Fixed REDoS vector in package_index.

    v65.5.0

    Changes ^^^^^^^

    • #3624: Fixed editable install for multi-module/no-package src-layout projects.
    • #3626: Minor refactorings to support distutils using stdlib logging module.

    Documentation changes ^^^^^^^^^^^^^^^^^^^^^

    • #3419: Updated the example version numbers to be compliant with PEP-440 on the "Specifying Your Project’s Version" page of the user guide.

    Misc ^^^^

    • #3569: Improved information about conflicting entries in the current working directory and editable install (in documentation and as an informational warning).
    • #3576: Updated version of validate_pyproject.

    v65.4.1

    Misc ^^^^

    v65.4.0

    Changes ^^^^^^^

    v65.3.0

    ... (truncated)

    Commits

    Dependabot compatibility score

    Dependabot will resolve any conflicts with this PR as long as you don't alter it yourself. You can also trigger a rebase manually by commenting @dependabot rebase.


    Dependabot commands and options

    You can trigger Dependabot actions by commenting on this PR:

    • @dependabot rebase will rebase this PR
    • @dependabot recreate will recreate this PR, overwriting any edits that have been made to it
    • @dependabot merge will merge this PR after your CI passes on it
    • @dependabot squash and merge will squash and merge this PR after your CI passes on it
    • @dependabot cancel merge will cancel a previously requested merge and block automerging
    • @dependabot reopen will reopen this PR if it is closed
    • @dependabot close will close this PR and stop Dependabot recreating it. You can achieve the same result by closing it manually
    • @dependabot ignore this major version will close this PR and stop Dependabot creating any more for this major version (unless you reopen the PR or upgrade to it yourself)
    • @dependabot ignore this minor version will close this PR and stop Dependabot creating any more for this minor version (unless you reopen the PR or upgrade to it yourself)
    • @dependabot ignore this dependency will close this PR and stop Dependabot creating any more for this dependency (unless you reopen the PR or upgrade to it yourself)
    • @dependabot use these labels will set the current labels as the default for future PRs for this repo and language
    • @dependabot use these reviewers will set the current reviewers as the default for future PRs for this repo and language
    • @dependabot use these assignees will set the current assignees as the default for future PRs for this repo and language
    • @dependabot use this milestone will set the current milestone as the default for future PRs for this repo and language

    You can disable automated security fix PRs for this repo from the Security Alerts page.

    dependencies 
    opened by dependabot[bot] 2
  • The first half of the embeddings learned have small variances using the unsupervised GraphSAGE model

    The first half of the embeddings learned have small variances using the unsupervised GraphSAGE model

    Hi everyone,

    I followed this excellent tutorial Node representation learning with GraphSAGE and UnsupervisedSampler on a couple of my own data sets to learn the embeddings for the all nodes in the graph.

    When I used the MeanAggregator, I noticed that the variances of the first half embeddings obtained from the model were really low compared to the rest of the embeddings.

    image

    I'm wondering if anyone else has observed this ( I observed the same thing across multiple datasets) and if this is an expected behaviour of the model.

    Thanks all, Ruqian

    opened by ruqianl 0
  • On stable version a documentation page is broken

    On stable version a documentation page is broken

    Describe the bug

    The stable version of documentation does not provide StellarGraph API information.

    To Reproduce

    Steps to reproduce the behavior:

    1. Go to StellarGraph API
    2. The page provides no information

    Observed behavior

    No information provided on API page

    Expected behavior

    API information showcase, like on any other version, (e.g., on the dev version https://stellargraph.readthedocs.io/en/latest/api.html)

    Environment

    Operating system: Windows10

    Additional context

    Screenshots: https://ctrl.vi/i/h0bDdPUig

    bug sg-library 
    opened by AmadeusZhang 0
  • Interpretability options, supervised graph classification

    Interpretability options, supervised graph classification

    Hi, thanks for the constantly expanding stellargraph library!

    Description

    I am looking for wa feature to obtain node/link/subgraph importance for stellargraph-based supervised graph classification tasks. stellargraph.interpretability.saliency_maps does not seem to be compatible with the PaddedGraphGenerator function yet. Also GNNexplainer or SubgraphX are all available for pytorch models only.

    User Story

    I am working in the biomedical field and I trained molecular graph structures of two different classes with the DeepGraphCNN model. I achieve promising prediction results but have no option to further interpret the classification of disease-relevant molecular structures. I would hence greatly appreciate if the interpretability feature can be implemented into the stellargraph library for supervised graph classification models. Thanks!

    Done Checklist

    • [ ] Produced code for required functionality
    • [ ] Tests written and coverage checked
    • [ ] Code review performed
    • [ ] Documentation on Google Docs (if applicable)
    • [ ] Documentation in repo
    • [ ] Version number reflects new status
    • [ ] CHANGELOG.md updated
    • [ ] Team demo
    enhancement sg-library 
    opened by mmpust 0
  • Bump pillow from 7.1.2 to 9.3.0 in /docs

    Bump pillow from 7.1.2 to 9.3.0 in /docs

    Bumps pillow from 7.1.2 to 9.3.0.

    Release notes

    Sourced from pillow's releases.

    9.3.0

    https://pillow.readthedocs.io/en/stable/releasenotes/9.3.0.html

    Changes

    ... (truncated)

    Changelog

    Sourced from pillow's changelog.

    9.3.0 (2022-10-29)

    • Limit SAMPLESPERPIXEL to avoid runtime DOS #6700 [wiredfool]

    • Initialize libtiff buffer when saving #6699 [radarhere]

    • Inline fname2char to fix memory leak #6329 [nulano]

    • Fix memory leaks related to text features #6330 [nulano]

    • Use double quotes for version check on old CPython on Windows #6695 [hugovk]

    • Remove backup implementation of Round for Windows platforms #6693 [cgohlke]

    • Fixed set_variation_by_name offset #6445 [radarhere]

    • Fix malloc in _imagingft.c:font_setvaraxes #6690 [cgohlke]

    • Release Python GIL when converting images using matrix operations #6418 [hmaarrfk]

    • Added ExifTags enums #6630 [radarhere]

    • Do not modify previous frame when calculating delta in PNG #6683 [radarhere]

    • Added support for reading BMP images with RLE4 compression #6674 [npjg, radarhere]

    • Decode JPEG compressed BLP1 data in original mode #6678 [radarhere]

    • Added GPS TIFF tag info #6661 [radarhere]

    • Added conversion between RGB/RGBA/RGBX and LAB #6647 [radarhere]

    • Do not attempt normalization if mode is already normal #6644 [radarhere]

    ... (truncated)

    Commits

    Dependabot compatibility score

    Dependabot will resolve any conflicts with this PR as long as you don't alter it yourself. You can also trigger a rebase manually by commenting @dependabot rebase.


    Dependabot commands and options

    You can trigger Dependabot actions by commenting on this PR:

    • @dependabot rebase will rebase this PR
    • @dependabot recreate will recreate this PR, overwriting any edits that have been made to it
    • @dependabot merge will merge this PR after your CI passes on it
    • @dependabot squash and merge will squash and merge this PR after your CI passes on it
    • @dependabot cancel merge will cancel a previously requested merge and block automerging
    • @dependabot reopen will reopen this PR if it is closed
    • @dependabot close will close this PR and stop Dependabot recreating it. You can achieve the same result by closing it manually
    • @dependabot ignore this major version will close this PR and stop Dependabot creating any more for this major version (unless you reopen the PR or upgrade to it yourself)
    • @dependabot ignore this minor version will close this PR and stop Dependabot creating any more for this minor version (unless you reopen the PR or upgrade to it yourself)
    • @dependabot ignore this dependency will close this PR and stop Dependabot creating any more for this dependency (unless you reopen the PR or upgrade to it yourself)
    • @dependabot use these labels will set the current labels as the default for future PRs for this repo and language
    • @dependabot use these reviewers will set the current reviewers as the default for future PRs for this repo and language
    • @dependabot use these assignees will set the current assignees as the default for future PRs for this repo and language
    • @dependabot use this milestone will set the current milestone as the default for future PRs for this repo and language

    You can disable automated security fix PRs for this repo from the Security Alerts page.

    dependencies 
    opened by dependabot[bot] 2
  • Pandas object type cannot be represented as a node feature

    Pandas object type cannot be represented as a node feature

    Describe the bug

    I created a DataFrame which has a series that is object type. I cannot use the row of this object type as a feature of single node. I'm initiating stellar graph with following code by using my custom dataset that i attached as a screenshot below.

    square_node_data = pd.DataFrame(
        {'of': nf_obj, 'nf': nf_num}, index=from_node_ids
    )
    square_node_features = StellarGraph(square_node_data, square_edges)
    

    Stellar graph initialization gives an error as:

    ValueError: could not convert string to float: 'object_feature_A'
    

    Screen Shot 2022-11-19 at 02 02 05 Screen Shot 2022-11-19 at 02 02 32

    It seems that there is no support for the feature as numpy object type. I want to ensure it because I couldn't find the answer in the documentation. Maybe there is an another way of giving that feature type 🤔

    bug sg-library 
    opened by nevzatseferoglu 0
Releases(v1.2.1)
  • v1.2.1(Jun 30, 2020)

    StellarGraph is a Python library for machine learning on graphs and networks. It offers state-of-the-art algorithms for graph machine learning, making it easy to discover patterns and answer questions about graph-structured data.

    Get started with StellarGraph's newest graph machine learning features with pip install stellargraph.

    This release is a small bug fix release on top of 1.2.0.

    Bug fixes and other changes

    • Update the URLs of some datasets (Cora, PubMedDiabetes, CiteSeer) for upstream changes #1738, #1759
    • Add two missing layers to the stellargraph.custom_keras_layers dictionary #1757
    • Experimental changes: rename RotHEScoring to RotHEScore #1756
    • DevOps:

    Full Changelog

    Source code(tar.gz)
    Source code(zip)
  • v1.2.0(Jun 25, 2020)

    StellarGraph is a Python library for machine learning on graphs and networks. It offers state-of-the-art algorithms for graph machine learning, making it easy to discover patterns and answer questions about graph-structured data.

    Get started with StellarGraph's newest graph machine learning features with pip install stellargraph.

    Jump in to this release, with the new and improved demos and examples:

    Major features and improvements

    • Better Windows support: StellarGraph's existing ability to run on Windows has been improved, with all tests running on CI (#1696) and several small fixes (#1671, #1704, #1705).
    • Edge weights are supported in GraphSAGE (#1667) and Watch Your Step (#1604). This is in addition to the existing support for edge weights in GCN, GAT, APPNP, PPNP, RGCN, GCN graph classification, DeepGraphCNN and Node2Vec sampling.
    • Better and more demonstration notebooks and documentation to make the library more accessible to new and existing users:
      • A demo notebook for a comparison of link prediction with random walks based node embedding, showing Node2Vec, Attri2Vec, GraphSAGE and GCN #1658
      • The demo notebook for unsupervised training with Deep Graph Infomax has been expanded with more explanation and links #1257
      • The documentation for models, generators and other elements now has many more links to other relevant items in a "See also" box, making it easier to fit pieces together (examples: GraphSAGE, GraphSAGENodeGenerator, BiasedRandomWalk) #1718
    • The Cluster-GCN training procedure supports unsupervised training via Deep Graph Infomax; this allows for scalable training of GCN, APPNP and GAT models, and includes connecting to Neo4j for large graphs demo (#1257)
    • KGTripleGenerator now supports the self-adversarial negative sampling training procedure for knowledge graph algorithms (from RotatE), via generator.flow(..., sample_strategy="self-adversarial") docs

    Deprecations

    • The ClusterGCN model has been replaced with the GCN class. In the previous 1.1.0 release, GCN, APPNP and GAT were generalised to support the Cluster-GCN training procedure via ClusterNodeGenerator (which includes Neo4j support). The ClusterGCN model is now redundant and thus is deprecated: however, it still works without behaviour change.

    Experimental features

    Some new algorithms and features are still under active development, and are available as an experimental preview. However, they may not be easy to use: their documentation or testing may be incomplete, and they may change dramatically from release to release. The experimental status is noted in the documentation and at runtime via prominent warnings.

    • RotE, RotH: knowledge graph link prediction algorithms that combine TransE and RotatE in Euclidean or hyperbolic space, respectively #1539

    Bug fixes and other changes


    Full Changelog

    Source code(tar.gz)
    Source code(zip)
  • v1.1.0(Jun 2, 2020)

    StellarGraph is a Python library for machine learning on graphs and networks. It offers state-of-the-art algorithms for graph machine learning, making it easy to discover patterns and answer questions about graph-structured data.

    Get started with StellarGraph's newest graph machine learning features with pip install stellargraph.

    Jump in to this release, with the new and improved demos and examples:

    Major features and improvements

    • Support for the Neo4j graph database has been significantly improved:
      • There is now a Neo4jStellarGraph class that packages up a connection to a Neo4j instance, and allows it to be used for machine learning algorithms including the existing Neo4j and GraphSAGE functionality demo, #1595, #1598.
      • The ClusterNodeGenerator class now supports Neo4jStellarGraph in addition to the in-memory StellarGraph class, allowing it to be used to train models like GCN and GAT with data stored entirely in Neo4j demo (#1561, #1594, #1613)
    • Better and more demonstration notebooks and documentation to make the library more accessible to new and existing users:
    • New algorithms:
    • The StellarGraph class continues to get smaller, faster and more flexible:
      • Node features can now be specified as NumPy arrays or the newly added thin IndexedArray wrapper, which does no copies and has minimal runtime overhead demo (#1535, #1556, #1599). They can also now be multidimensional for each node #1561.
      • Edges can now have features, taken as any extra/unused columns in the input DataFrames demo (#1574)
      • Adjacency lists used for random walks and GraphSAGE/HinSAGE are constructed with NumPy and stored as contiguous arrays instead of dictionaries, cutting the time and memory or construction by an order of magnitude #1296
      • The peak memory usage of construction and adjacency list building is now monitored to ensure that there are not large spikes for large graphs, that exceed available memory #1546. This peak usage has thus been optimised: #1551,
      • Other optimisations: the edge_arrays, neighbor_arrays, in_node_arrays and out_node_arrays methods have been added, reducing time and memory overhead by leaving data as its underlying NumPy array #1253; the node_type method now supports multiple nodes as input, making algorithms like HinSAGE and Metapath2Vec much faster #1452; the default edge weight of 1 no longer consumes significant memory #1610.
    • Overall performance and memory usage improvements since 1.0.0, in numbers:
      • A reddit graph has 233 thousand nodes and 11.6 million edges:
        • construction without node features is now 2.3× faster, uses 31% less memory and has a memory peak 57% smaller.
        • construction with node features from NumPy arrays is 6.8× faster, uses 6.5% less memory overall and 85% less new memory (the majority of the memory is shared with the original NumPy arrays), and has a memory peak (above the raw data set) 70% smaller, compared to Pandas DataFrames in 1.0.0.
        • adjacency lists are 4.7-5.0× faster to construct, use 28% less memory and have a memory peak 60% smaller.
      • Various random walkers are faster: BiasedRandomWalk is up to 30× faster with weights and 5× faster without weights on MovieLens and up to 100× faster on some synthetic datasets, UniformRandomMetapathWalk is up to 17× faster (on MovieLens), UniformRandomWalk is up to 1.4× (on MovieLens).
    • Tensorflow 2.2 and thus Python 3.8 are now supported #1278

    Experimental features

    Some new algorithms and features are still under active development, and are available as an experimental preview. However, they may not be easy to use: their documentation or testing may be incomplete, and they may change dramatically from release to release. The experimental status is noted in the documentation and at runtime via prominent warnings.

    • RotatE: a knowledge graph link prediction algorithm that uses complex rotations (|z| = 1) to encode relations #1522
    • GCN_LSTM (renamed from GraphConvolutionLSTM): time series prediction on spatio-temporal data. It is still experimental, but has been improved since last release:
      • the SlidingFeaturesNodeGenerator class has been added to yield data appropriate for the model, straight from a StellarGraph instance containing time series data as node features #1564
      • the hidden graph convolution layers can now have a custom output size #1555
      • the model now supports multivariate input and output, including via the SlidingFeaturesNodeGenerator class (with multidimensional node features) #1580
      • unit tests have been added #1560
    • Neo4j support: some classes have been renamed from Neo4J... (uppercase J) to Neo4j... (lowercase j).

    Bug fixes and other changes

    • Edge weights are supported in methods using FullBatchNodeGenerator (GCN, GAT, APPNP, PPNP), RelationalFullBatchNodeGenerator (RGCN) and PaddedGraphGenerator (GCN graph classification, DeepGraphCNN), via the weighted=True parameter #1600
    • The StellarGraph class now supports conversion between node type and edge type names and equivalent ilocs #1366, which allows optimising some algorithms (#1367 optimises ranking with the DistMult algorithm from 42.6s to 20.7s on the FB15k dataset)
    • EdgeSplitter no longer prints progress updates #1619
    • The info method now merges edge types triples like A-[r]->B and B-[r]->A in undirected graphs #1650
    • There is now a notebook capturing time and memory resource usage on non-synthetic datasets, designed to help StellarGraph contributors understand and optimise the StellarGraph class #1547
    • Various documentation, demo and error message fixes and improvements: #1516 (thanks @thatlittleboy), #1519, #1520, #1537, #1541, #1542, #1577, #1605, #1606, #1608, #1624, #1628, #1632, #1634, #1636, #1643, #1645, #1649, #1652
    • DevOps changes:

    Full Changelog

    Source code(tar.gz)
    Source code(zip)
  • v1.0.0(May 5, 2020)

    This 1.0 release of StellarGraph is the culmination of three years of active research and engineering to deliver an open-source, user-friendly library for machine learning (ML) on graphs and networks.

    Jump in to this release, with the new demos and examples:

    Major features and improvements

    • Better demonstration notebooks and documentation to make the library more accessible to new and existing users:
    • New algorithms:
      • GCNSupervisedGraphClassification: supervised graph classification model based on Graph Convolutional layers (GCN) #929, demo.
      • DeepGraphCNN (DGCNN): supervised graph classification using a stack of graph convolutional layers followed by SortPooling, and standard convolutional and pooling (such as Conv1D and MaxPool1D) #1212 #1265, demo
      • SortPooling layer: the node pooling layer introduced in Zhang et al #1210
    • DeepGraphInfomax can be used to train almost any model in an unsupervised way, via the corrupt_index_groups parameter to CorruptedGenerator #1243, demo. Additionally, many algorithms provide defaults and so can be used with DeepGraphInfomax without specifying this parameter:
      • any model using FullBatchNodeGenerator, including models supported in StellarGraph 0.11: GCN, GAT, PPNP and APPNP
      • GraphSAGE #1162
      • HinSAGE for heterogeneous graphs with node features #1254
    • UnsupervisedSampler supports a walker parameter to use other random walking algorithms such as BiasedRandomWalk, in addition to the default UniformRandomWalk. #1187
    • The StellarGraph class is now smaller, faster and easier to construct and use:
      • The StellarGraph(..., edge_type_column=...) parameter can be used to construct a heterogeneous graph from a single flat DataFrame, containing a column of the edge types #1284. This avoids the need to build separate DataFrames for each type, and is significantly faster when there are many types. Using edge_type_column gives a 2.6× speedup for loading the stellargraph.datasets.FB15k dataset (with almost 600 thousand edges across 1345 types).
      • StellarGraph's internal cache of node adjacencies is now computed lazily #1291 and takes into account whether the graph is directed or not #1463, and they now use the smallest integer type they can #1289
      • StellarGraph's internal list of source and target nodes are now stored using integer "ilocs" #1267, reducing memory use and making some functionality significantly faster #1444 #1446)
      • Functions like graph.node_features() no longer needs node_type specified if graph has only one node type (this includes classes like HinSAGENodeGenerator, which no longer needs head_node_type if there is only one node type) #1375
    • Overall performance and memory usage improvements since 0.11, in numbers:
      • The FB15k graph has 15 thousand nodes and 483 thousand edges: it is now 7× faster and 4× smaller to construct (without adjacency lists). It is still about 2× smaller when directed or undirected adjacency lists are computed.
      • Directed adjacency matrix construction is up to 2× faster
      • Various samplers and random walkers are faster: HinSAGENodeGenerator is 3× faster (on MovieLens), Attri2VecNodeGenerator is 4× faster (on CiteSeer), weighted BiasedRandomWalk is up to 3× faster, UniformRandomMetapathWalk is up to 7× faster

    Breaking changes

    • The stellargraph/stellargraph docker image wasn't being published in an optimal way, so we have stopped updating it for now #1455
    • Edge weights are now validated to be numeric when creating a StellarGraph. Previously edge weights could be any type, but all algorithms that use them would fail with non-numeric types. #1191
    • Full batch layers no longer support an "output indices" tensor to filter the output rows to a selected set of nodes #1204 (this does not affect models like GCN, only the layers within them: APPNPPropagationLayer, ClusterGraphConvolution, GraphConvolution, GraphAttention, GraphAttentionSparse, PPNPPropagationLayer, RelationalGraphConvolution). Migration: post-process the output using tf.gather manually or the new sg.layer.misc.GatherIndices layer.
    • GraphConvolution has been generalised to work with batch size > 1, subsuming the functionality of the now-deprecated ClusterGraphConvolution (and GraphClassificationConvolution) #1205. Migration: replace stellargraph.layer.ClusterGraphConvolution with stellargraph.layer.GraphConvolution.
    • BiasedRandomWalk now takes multi-edges into consideration instead of collapsing them when traversing the graph. It previously required all multi-edges had to same weight and only counted one of them when considering where to walk, but now a multi-edge is equivalent to having an edge whose weight is the sum of the weights of all edges in the multi-edge #1444

    Experimental features

    Some new algorithms and features are still under active development, and are available as an experimental preview. However, they may not be easy to use: their documentation or testing may be incomplete, and they may change dramatically from release to release. The experimental status is noted in the documentation and at runtime via prominent warnings.

    • GraphConvolutionLSTM: time series prediction on spatio-temporal data, combining GCN with a LSTM model to augment the conventional time-series model with information from nearby data points #1085, demo

    Bug fixes and other changes

    • Random walk classes like UniformRandomWalk and BiasedRandomWalk can have their hyperparameters set on construction, in addition to in each call to run #1179
    • Node feature sampling was made ~4× faster by ensuring a better data layout, this makes some configurations of GraphSAGE (and HinSAGE) noticably faster #1225
    • The PROTEINS dataset has been added to stellargraph.datasets, for graph classification #1282
    • The BlogCatalog3 dataset can now be successfully downloaded again #1283
    • Knowledge graph model evaluation via rank_edges_against_all_nodes now defaults to the random strategy for breaking ties, and supports top (previous default) and bottom as alternatives #1223
    • Creating a RelationalFullBatchNodeGenerator is now significantly faster and requires much less memory (18× speedup and 560× smaller for the stellargraph.datasets.AIFB dataset) #1274
    • Creating a FullBatchNodeGenerator or FullBatchLinkGenerator is now significantly faster and requires much less memory (3× speedup and 480× smaller for the stellargraph.datasets.PubMedDiabetes dataset) #1277
    • StellarGraph.info now shows a summary of the edge weights for each edge type #1240
    • The plot_history function accepts a return_figure parameter to return the matplotlib.figure.Figure value, for further manipulation #1309 (Thanks @LarsNeR)
    • Tests now pass against the TensorFlow 2.2.0 release candidates, in preparation for the full 2.2.0 release #1175
    • Some functions no longer fail for some particular cases of empty graphs: StellarGraph.to_adjacency_matrix #1378, StellarGraph.from_networkx #1401
    • CorruptedGenerator on a FullBatchNodeGenerator can be used to train DeepGraphInfomax on a subset of the nodes in a graph, instead of all of them #1415
    • The stellargraph.custom_keras_layers dictionary for use when loading a Keras model now includes all of StellarGraph's layers #1280
    • PaddedGraphGenerator.flow now also accepts a list of StellarGraph objects as input #1458
    • Supervised Graph Classification demo now prints progress update messages during training #1485
    • Explicit contributors file has been removed to avoid inconsistent acknowledgement #1484. Please refer to the Github display for contributors instead.
    • Various documentation, demo and error message fixes and improvements: #1141, #1219, #1246, #1260, #1266, #1361, #1362, #1385, #1386, #1363, #1376, #1405 (thanks @thatlittleboy), #1408, #1393, #1403, #1401, #1397, #1396, #1391, #1394, #1434 (thanks @thatlittleboy), #1442, #1438 (thanks @thatlittleboy), #1413, #1450, #1440, #1453, #1447, #1467, #1465 (thanks @thatlittleboy), #1470, #1475, #1480, #1468, #1472, #1474
    • DevOps changes:
    Source code(tar.gz)
    Source code(zip)
  • v1.0.0rc1(Apr 22, 2020)

    This is the first release candidate for StellarGraph 1.0. The 1.0 release will be the culmination of 2 years of activate development, and this release candidate is the first milestone for that release.

    Jump in to this release, with the new demos and examples:

    Major features and improvements

    • Better demonstration notebooks and documentation to make the library more accessible to new and existing users:
    • New algorithms:
      • GCNSupervisedGraphClassification: supervised graph classification model based on Graph Convolutional layers (GCN) #929, demo.
    • DeepGraphInfomax can be used to train almost any model in an unsupervised way, via the corrupt_index_groups parameter to CorruptedGenerator #1243, demo. Additionally, many algorithms provide defaults and so can be used with DeepGraphInfomax without specifying this parameter:
      • any model using FullBatchNodeGenerator, including models supported in StellarGraph 0.11: GCN, GAT, PPNP and APPNP
      • GraphSAGE #1162
      • HinSAGE for heterogeneous graphs with node features #1254
    • UnsupervisedSampler supports a walker parameter to use other random walking algorithms such as BiasedRandomWalk, in addition to the default UniformRandomWalk. #1187
    • The StellarGraph class is now smaller, faster and easier to construct:
      • The StellarGraph(..., edge_type_column=...) parameter can be used to construct a heterogeneous graph from a single flat DataFrame, containing a column of the edge types #1284. This avoids the need to build separate DataFrames for each type, and is significantly faster when there are many types. Using edge_type_column gives a 2.6× speedup for loading the stellargraph.datasets.FB15k dataset (with almost 600 thousand edges across 1345 types).
      • StellarGraph's internal cache of node adjacencies now uses the smallest integer type it can #1289. This reduces memory use by 31% on the FB15k dataset, and 36% on a reddit dataset (with 11.6 million edges).

    Breaking changes

    • Edge weights are now validated to be numeric when creating a StellarGraph, previously edge weights could be any type, but all algorithms that use them would fail. #1191
    • Full batch layers no longer support an "output indices" tensor to filter the output rows to a selected set of nodes #1204 (this does not affect models like GCN, only the layers within them: APPNPPropagationLayer, ClusterGraphConvolution, GraphConvolution, GraphAttention, GraphAttentionSparse, PPNPPropagationLayer, RelationalGraphConvolution). Migration: post-process the output using tf.gather manually or the new sg.layer.misc.GatherIndices layer.
    • GraphConvolution has been generalised to work with batch size > 1, subsuming the functionality of the now-deprecated ClusterGraphConvolution (and GraphClassificationConvolution) #1205. Migration: replace stellargraph.layer.ClusterGraphConvolution with stellargraph.layer.GraphConvolution.

    Experimental features

    Some new algorithms and features are still under active development, and are available as an experimental preview. However, they may not be easy to use: their documentation or testing may be incomplete, and they may change dramatically from release to release. The experimental status is noted in the documentation and at runtime via prominent warnings.

    • SortPooling layer: the node pooling layer introduced in Zhang et al #1210
    • DeepGraphConvolutionalNeuralNetwork (DGCNN): supervised graph classification using a stack of graph convolutional layers followed by SortPooling, and standard convolutional and pooling (such as Conv1D and MaxPool1D) #1212 #1265
    • GraphConvolutionLSTM: time series prediction on spatio-temporal data, combining GCN with a LSTM model to augment the conventional time-series model with information from nearby data points #1085, demo

    Bug fixes and other changes

    • Random walk classes like UniformRandomWalk and BiasedRandomWalk can have their hyperparameters set on construction, in addition to in each call to run #1179
    • Node feature sampling was made ~4× faster by ensuring a better data layout, this makes some configurations of GraphSAGE (and HinSAGE) noticably faster #1225
    • The PROTEINS dataset has been added to stellargraph.datasets, for graph classification #1282
    • The BlogCatalog3 dataset can now be successfully downloaded again #1283
    • Knowledge graph model evaluation via rank_edges_against_all_nodes now defaults to the random strategy for breaking ties, and supports top (previous default) and bottom as alternatives #1223
    • Creating a RelationalFullBatchNodeGenerator is now significantly faster and requires much less memory (18× speedup and 560× smaller for the stellargraph.datasets.AIFB dataset) #1274
    • StellarGraph.info now shows a summary of the edge weights for each edge type #1240
    • Various documentation, demo and error message fixes and improvements: #1141, #1219, #1246, #1260, #1266
    • DevOps changes:
    Source code(tar.gz)
    Source code(zip)
  • v0.11.1(Mar 31, 2020)

    StellarGraph is a Python library for machine learning on graphs and networks. It offers state-of-the-art algorithms for graph machine learning, making it easy to discover patterns and answer questions about graph-structured data.

    Get started with StellarGraph's newest graph machine learning features with pip install stellargraph.

    This bugfix release contains the same code as 0.11.0, and just fixes the metadata in the Anaconda package so that it can be installed successfully.

    Bug fixes and other changes

    Source code(tar.gz)
    Source code(zip)
  • v0.11.0(Mar 25, 2020)

    StellarGraph is a Python library for machine learning on graphs and networks. It offers state-of-the-art algorithms for graph machine learning, making it easy to discover patterns and answer questions about graph-structured data.

    Get started with StellarGraph's newest graph machine learning features with pip install stellargraph.

    Major features and improvements

    • The onboarding/getting-started process has been optimised and improved:
    • New algorithms:
      • Watch Your Step: computes node embeddings by simulating the effect of random walks, rather than doing them. #750.
      • Deep Graph Infomax: performs unsupervised node representation learning #978.
      • Temporal Random Walks (Continuous-Time Dynamic Network Embeddings): random walks that respect the time that each edge occurred (stored as edge weights) #1120.
      • ComplEx: computes multiplicative complex-number embeddings for entities and relationships (edge types) in knowledge graphs, which can be used for link prediction. #901 #1080
      • DistMult: computes multiplicative real-number embeddings for entities and relationships (edge types) in knowledge graphs, which can be used for link prediction. #755 #865 #1136

    Breaking changes

    • StellarGraph now requires TensorFlow 2.1 or greater, TensorFlow 2.0 is no longer supported #1008
    • The legacy constructor using NetworkX graphs has been deprecated #1027. Migration: replace StellarGraph(some_networkx_graph) with StellarGraph.from_networkx(some_networkx_graph), and similarly for StellarDiGraph.
    • The build method on model classes (such as GCN) has been renamed to in_out_tensors #1140. Migration: replace model.build() with model.in_out_tensors().
    • The node_model and link_model methods on model classes has been replaced by in_out_tensors #1140 (see that PR for the exact list of types). Migration: replace model.node_model() with model.in_out_tensors() or model.in_out_tensors(multiplicity=1), and model.node_model() with model.in_out_tensors() or model.in_out_tensors(multiplicity=2).
    • Re-exports of calibration and ensembling functionality from the top-level of the stellargraph module were deprecated, in favour of importing from the stellargraph.calibration or stellargraph.ensemble submodules directly #1107. Migration: replace uses of stellargraph.Ensemble with stellargraph.ensemble.Ensemble, and similarly for the other names (see #1107 for all replacements).
    • StellarGraph.to_networkx parameters now use attr to refer to NetworkX attributes, not name or label #973. Migration: for any named parameters in graph.to_networkx(...), change node_type_name=... to node_type_attr=... and similarly edge_type_name to edge_type_attr, edge_weight_label to edge_weight_attr, feature_name to feature_attr.
    • StellarGraph.nodes_of_type is deprecated in favour of the nodes method #1111. Migration: replace some_graph.nodes_of_type(some_type) with some_graph.nodes(node_type=some_type).
    • StellarGraph.info parameters show_attributes and sample were deprecated #1110
    • Some more layers and models had many parameters move from **kwargs to real arguments: Attri2Vec (#1128), ClusterGCN (#1129), GraphAttention & GAT (#1130), GraphSAGE & its aggregators (#1142), HinSAGE & its aggregators (#1143), RelationalGraphConvolution & RGCN (#1148). Invalid (e.g. incorrectly spelled) arguments would have been ignored previously, but now may fail with a TypeError; to fix, remove or correct the arguments.
    • The method="chebyshev" option to FullBatchNodeGenerator, FullBatchLinkGenerator and GCN_Aadj_feats_op has been removed for now, because it needed significant revision to be correctly implemented #1028
    • The fit_generator, evaluate_generator and predict_generator methods on Ensemble and BaggingEnsemble have been renamed to fit, evaluate and predict, to match the deprecation in TensorFlow 2.1 of the tensorflow.keras.Model methods of the same name #1065. Migration: remove the _generator suffix on these methods.
    • The default_model method on Attri2Vec, GraphSAGE and HinSAGE has been deprecated, in favour of in_out_tensors #1145. Migration: replace model.default_model() with model.in_out_tensors().

    Experimental features

    Some new algorithms and features are still under active development, and are available as an experimental preview. However, they may not be easy to use: their documentation or testing may be incomplete, and they may change dramatically from release to release. The experimental status is noted in the documentation and at runtime via prominent warnings.

    • GCNSupervisedGraphClassification: supervised graph classification model based on Graph Convolutional layers (GCN) #929.

    Bug fixes and other changes

    • StellarGraph.to_adjacency_matrix is at least 15× faster on undirected graphs #932
    • ClusterNodeGenerator is now noticably faster, which makes training and predicting with a ClusterGCN model faster #1095. On a random graph with 1000 nodes and 5000 edges and 10 clusters, iterating over an epoch with q=1 (each clusters individually) is 2× faster, and is even faster for larger q. The model in the Cluster-GCN demo notebook using Cora trains 2× faster overall.
    • The node_features=... parameter to StellarGraph.from_networkx now only needs to mention the node types that have features, when passing a dictionary of Pandas DataFrames. Node types that aren't mentioned will automatically have no features (zero-length feature vectors). #1082
    • A subgraph method was added to StellarGraph for computing a node-induced subgraph #958
    • A connected_components method was added to StellarGraph for computing the nodes involved in each connected component in a StellarGraph #958
    • The info method on StellarGraph now shows only 20 node and edge types by default to be more useful for graphs with many types #993. This behaviour can be customized with the truncate=... parameter.
    • The info method on StellarGraph now shows information about the size and type of each node type's feature vectors #979
    • The EdgeSplitter class supports StellarGraph input (and will output StellarGraphs in this case), in addition to NetworkX graphs #1032
    • The Attri2Vec model class stores its weights statefully, so they are shared between all tensors computed by build #1101
    • The GCN model defaults for some parameters now match the GraphConvolution layer's defaults: specifically kernel_initializer (glorot_uniform) and bias_initializer (zeros) #1147
    • The datasets submodule is now accessible as stellargraph.datasets, after just import stellargraph #1113
    • All datasets in stellargraph.datasets now support a load method to create a StellarGraph object (and other information): AIFB (#982), CiteSeer (#989), Cora (#913), MovieLens (#947), PubMedDiabetes (#986). The demo notebooks using these datasets are now cleaner.
    • Some new datasets were added to stellargraph.datasets:
      • MUTAG: a collection of graphs representing chemical compounds #960
      • WN18, WN18RR: knowledge graphs based on the WordNet linguistics data #977
      • FB15k, FB15k_237: knowledge graphs based on the FreeBase knowledge base #977
      • IAEnronEmployees: a small set of employees of Enron, and the many emails between them #1058
    • Warnings now point to the call site of the function causing the warning, not the warnings.warn call inside StellarGraph; this means DeprecationWarnings will be visible in Jupyter notebooks and scripts run with Python 3.7 #1144
    • Some code that triggered warnings from other libraries was fixed or removed #995 #1008, #1051, #1064, #1066
    • Some demo notebooks have been updated or fixed: demos/use-cases/hateful-twitters.ipynb (#1019), rgcn-aifb-node-classification-example.ipynb (#983)
    • The documentation "quick start" guide duplicated a lot of the information in the README, and so has been replaced with the latter #1096
    • API documentation now lists items under their recommended import path, not their definition. For instance, stellargraph.StellarGraph instead of stellargraph.core.StellarGraph (#1127), stellargraph.layer.GCN instead of stellargraph.layer.gcn.GCN (#1150) and stellargraph.datasets.Cora instead of stellargraph.datasets.datasets.Cora (#1157)
    • Some API documentation is now formatted better #1061, #1068, #1070, #1071
    • DevOps changes:
    Source code(tar.gz)
    Source code(zip)
  • v0.10.0(Feb 26, 2020)

    Major features and improvements

    • The StellarGraph and StellarDiGraph classes are now backed by NumPy and Pandas #752. The StellarGraph(...) and StellarDiGraph(...) constructors now consume Pandas DataFrames representing node features and the edge list. This significantly reduces the memory use and construction time for these StellarGraph objects.

      The following table shows some measurements of the memory use of g = StellarGraph(...), and the time required for that constructor call, for several real-world datasets of different sizes, for both the old form backed by NetworkX code and the new form backed by NumPy and Pandas (both old and new store node features similarly, using 2D NumPy arrays, so the measurements in this table include only graph structure: the edges and nodes themselves):

      | dataset | nodes | edges | size old (MiB) | size new (MiB) | size change | time old (s) | time new (s) | time change | |---------|-------:|---------:|---------------:|---------------:|------------:|-------------:|-------------:|------------:| | Cora | 2708 | 5429 | 4.1 | 1.3 | -69% | 0.069 | 0.034 | -50% | | FB15k | 14951 | 592213 | 148 | 28 | -81% | 5.5 | 1.2 | -77% | | Reddit | 231443 | 11606919 | 6611 | 493 | -93% | 154 | 33 | -82% |

      The old backend has been removed, and conversion from a NetworkX graph should be performed via the StellarGraph.from_networkx function (the existing form StellarGraph(networkx_graph) is supported in this release but is deprecated, and may be removed in a future release).

    • More detailed information about Heterogeneous GraphSAGE (HinSAGE) has been added to StellarGraph's readthedocs documentation #839.

    • New algorithms:

      • Link prediction with directed GraphSAGE, via DirectedGraphSAGELinkGenerator #871
      • GraphWave: computes structural node embeddings by using wavelet transforms on the graph Laplacian #822

    Breaking changes

    • Some layers and models had many parameters move from **kwargs to real arguments: GraphConvolution, GCN. #801 Invalid (e.g. incorrectly spelled) arguments would have been ignored previously, but now may fail with a TypeError; to fix, remove or correct the arguments.
    • The stellargraph.data.load_dataset_BlogCatalog3 function has been replaced by the load method on stellargraph.datasets.BlogCatalog3 #888. Migration: replace load_dataset_BlogCatalog3(location) with BlogCatalog3().load(); code required to find the location or download the dataset can be removed, as load now does this automatically.
    • stellargraph.data.train_test_val_split and stellargraph.data.NodeSplitter have been removed. #887 Migration: this functionality should be replaced with pandas and sklearn (for instance, sklearn.model_selection.train_test_split).
    • Most of the submodules in stellargraph.utils have been moved to top-level modules: stellargraph.calibration, stellargraph.ensemble, stellargraph.losses and stellargraph.interpretability #938. Imports from the old location are now deprecated, and may stop working in future releases. See the linked issue for the full list of changes.

    Experimental features

    Some new algorithms and features are still under active development, and are available as an experimental preview. However, they may not be easy to use: their documentation or testing may be incomplete, and they may change dramatically from release to release. The experimental status is noted in the documentation and at runtime via prominent warnings.

    • Temporal Random Walks: random walks that respect the time that each edge occurred (stored as edge weights) #787. The implementation does not have an example or thorough testing and documentation.
    • Watch Your Step: computes node embeddings by simulating the effect of random walks, rather than doing them. #750. The implementation is not fully tested.
    • ComplEx: computes embeddings for nodes and edge types in knowledge graphs, and use these to perform link prediction #756. The implementation hasn't been validated to match the paper.
    • Neo4j connector: the GraphSAGE algorithm can execute doing neighbourhood sampling in a Neo4j database, so that the edges of a graph do not have to fit entirely into memory #799. The implementation is not automatically tested, and doesn't support functionality like loading node feature vectors from Neo4j.

    Bug fixes and other changes

    • StellarGraph now supports TensorFlow 2.1, which includes GPU support by default: #875
    • Demos now focus on Jupyter notebooks, and demo scripts that duplicate notebooks have been removed: #889
    • The following algorithms are now reproducible:
      • Supervised GraphSAGE Node Attribute Inference #844
    • Randomness can be more easily controlled using stellargraph.random.set_seed #806
    • StellarGraph.edges() can return edge weights as a separate NumPy array with include_edge_weights=True #754
    • StellarGraph.to_networkx supports ignoring node features (and thus being a little more efficient) with feature_name=None #841
    • StellarGraph.to_adjacency_matrix now ignores edge weights (that is, defaults every weight to 1) by default, unless weighted=True is specified #857
    • stellargraph.utils.plot_history visualises the model training history as a plot for each metric (such as loss) #902
    • the saliency maps/interpretability code has been refactored to have more sharing as well as to make it cleaner and easier to extend #855
    • DevOps changes:
    Source code(tar.gz)
    Source code(zip)
  • v0.9.0(Jan 29, 2020)

    Major features and improvements

    • StellarGraph is now available as a conda package on Anaconda Cloud #516
    • New algorithms:
      • Cluster-GCN: an extension of GCN that can be trained using SGD, with demo #487
      • Relational-GCN (RGCN): a generalisation of GCN to relational/multi edge type graphs, with demo #490
      • Link prediction for full-batch models: FullBatchLinkGenerator allows doing link prediction with algorithms like GCN, GAT, APPNP and PPNP #543
    • Unsupervised GraphSAGE has now been updated and tested for reproducibility. Ensuring all seeds are set, running the same pipeline should give reproducible embeddings. #620
    • A datasets subpackage provides easier access to sample datasets with inbuilt downloading. #690

    Breaking changes

    • The stellargraph library now only supports tensorflow version 2.0 #518, #732. Backward compatibility with earlier versions of tensorflow is not guaranteed.
    • The stellargraph library now only supports Python versions 3.6 and above #641. Backward compatibility with earlier versions of Python is not guaranteed.
    • The StellarGraph class no longer exposes NetworkX internals, only required functionality. In particular, calls like list(G) will no longer return a list of nodes; use G.nodes() instead. #297 If NetworkX functionality is required, use the new .to_networkx() method to convert to a normal networkx.MultiGraph or networkx.MultiDiGraph.
    • Passing a NodeSequence or LinkSequence object to GraphSAGE and HinSAGE classes is now deprecated and no longer supported #498. Users might need to update their calls of GraphSAGE and HinSAGE classes by passing generator objects instead of generator.flow() objects.
    • Various methods on StellarGraph have been renamed to be more succinct and uniform:
      • get_feature_for_nodes is now node_features
      • type_for_node is now node_type
    • Neighbourhood methods in StellarGraph class (neighbors, in_nodes, out_nodes) now return a list of neighbours instead of a set. This addresses #653. This means multi-edges are no longer collapsed into one in the return value. There will be an implicit change in behaviour for explorer classes used for algorithms like GraphSAGE, Node2Vec, since a neighbour connected via multiple edges will now be more likely to be sampled. If this doesn't sound like the desired behaviour, consider pruning the graph of multi-edges before running the algorithm.
    • GraphSchema has been simplified to remove type look-ups for individual nodes and edges #702 #703. Migration: for nodes, use StellarGraph.node_type; for edges, use the triple argument to the edges method, or filter when doing neighbour queries using the edge_types argument.
    • NodeAttributeSpecification and the supporting Converter classes have been removed #707. Migration: use the more powerful and flexible preprocessing tools from pandas and sklearn (see the linked PR for specifics)

    Experimental features

    Some new algorithms and features are still under active development, and are available as an experimental preview. However, they may not be easy to use: their documentation or testing may be incomplete, and they may change dramatically from release to release. The experimental status is noted in the documentation and at runtime via prominent warnings.

    • The StellarGraph and StellarDiGraph classes supports using a backend based on NumPy and Pandas that uses dramatically less memory for large graphs than the existing NetworkX-based backend #668. The new backend can be enabled by constructing with StellarGraph(nodes=..., edges=...) using Pandas DataFrames, instead of a NetworkX graph.

    Bug fixes and other changes

    • Documentation for every relased version is published under a permanent URL, in addition to the stable alias for the latest release, e.g. https://stellargraph.readthedocs.io/en/v0.8.4/ for v0.8.4 #612
    • Neighbourhood methods in StellarGraph class (neighbors, in_nodes, out_nodes) now support additional parameters to include edge weights in the results or filter by a set of edge types. #646
    • Changed GraphSAGE and HinSAGE class API to accept generator objects the same as GCN/GAT models. Passing a NodeSequence or LinkSequence object is now deprecated. #498
    • SampledBreadthFirstWalk, SampledHeterogeneousBreadthFirstWalk and DirectedBreadthFirstNeighbours have been made 1.2-1.5× faster #628
    • UniformRandomWalk has been made 2× faster #625
    • FullBatchNodeGenerator.flow has been reduced from O(n^2) quadratic complexity to O(n), where n is the number of nodes in the graph, making it orders of magnitude faster for large graphs #513
    • The dependencies required for demos and testing have been included as "extras" in the main package: demos and igraph for demos, and test for testing. For example, pip install stellargraph[demos,igraph] will install the dependencies required to run every demo. #661
    • The StellarGraph and StellarDiGraph constructors now list their arguments explicitly for clearer documentation (rather than using *arg and **kwargs splats) #659
    • sys.exit(0) is no longer called on failure in load_dataset_BlogCatalog3 #648
    • Warnings are printed using the Python warnings module #583
    • Numerous DevOps changes:
    Source code(tar.gz)
    Source code(zip)
  • v0.8.4(Jan 20, 2020)

  • v0.8.3(Dec 12, 2019)

    Fixed bugs:

    • Fixed the issue in the APPNP class that causes appnp to propagate excessive dropout layers. #525
    • Added a fix into the PPNP node classification demo so that the softmax layer is no longer propagated. #525
    Source code(tar.gz)
    Source code(zip)
  • v0.8.2(Nov 8, 2019)

    Fixed bugs:

    • Updated requirements to Tensorflow>=1.14, as tensorflow with lower versions causes errors with sparse full batch node methods: GCN, APPNP, and GAT. #519
    Source code(tar.gz)
    Source code(zip)
  • v0.8.1(Oct 29, 2019)

  • v0.8.0(Oct 25, 2019)

    We are excited to announce the 0.8.0 release of the library. This release extends stellargraph by adding new algorithms and demos, enhancing interpretability via saliency maps for GAT, and further simplifying graph ML workflows through standardised model APIs and arguments. More details on new features and enhancements are listed below.

    New algorithms:

    • Directed GraphSAGE algorithm (a generalisation of GraphSAGE to directed graphs) + demo #479
    • Attri2vec algorithm + demo #470 #455
    • PPNP and APPNP algorithms + demos #485
    • GAT saliency maps for interpreting node classification with Graph Attention Networks + demo #435

    Implemented enhancements:

    • New demo of node classification on Twitter hateful users \430
    • New demo of graph saliency on Twitter hateful users #448
    • Added Directed SampledBFS walks on directed graphs #464
    • Unified API of GCN, GAT, GraphSAGE, and HinSAGE classses by adding build() method to GCN and GAT classes #439
    • Added activations argument to GraphSAGE and HinSAGE classes #381
    • Unified activations for GraphSAGE, HinSAGE, GCN and GAT #493 #381
    • Added optional regularisation on the weights for GCN, GraphSage, and HinSage #172 #469
    • Unified regularisation of GraphSAGE, HinSAGE, GCN and GAT #494 (geoffj-d61)
    • Unsupervised GraphSage speed up via multithreading #474 #477
    • Support of sparse generators in the GCN saliency map implementation. #432

    Refactoring:

    • Refactored Ensemble class into Ensemble and BaggingEnsemble. The former implements naive ensembles and the latter bagging ensembles. #459
    • Changed from using keras to use tensorflow.keras #471
    • Removed flatten_output arguments for all models #447

    Fixed bugs:

    • Updated Yelp example to support new dataset version #442
    • Fixed bug where some nodes and edges did not get a default type #451
    • Inconsistency in Ensemble.fit_generator() argument #461
    • Fixed source--target node designations for code using Cora dataset #444
    • IndexError: index 1 is out of bounds for axis 1 with size 1 in: demos/node-classification/hinsage #434
    • GraphSAGE and GAT/GCN predictions have different shapes #425
    Source code(tar.gz)
    Source code(zip)
  • v0.7.3(Oct 18, 2019)

    Limited NetworkX version to <2.4 and Tensorflow version to <1.15 in installation requirements, to avoid errors due to API changes in the recent versions of NetworkX and Tensorflow.

    Source code(tar.gz)
    Source code(zip)
  • v0.7.2(Sep 20, 2019)

    Limited Keras version to <2.2.5 and Tensorflow version to <2.0 in installation requirements, to avoid errors due to API changes in the recent versions of Keras and Tensorflow.

    Source code(tar.gz)
    Source code(zip)
  • v0.7.1(Jun 25, 2019)

    Fixed bugs:

    • Removed igraph and mplleaflet from demos requirements in setup.py. Python-igraph doesn't install on many systems and is only required for the clustering notebook. See the README.md in that directory for requirements and installation directions.
    • Updated GCN interpretability notebook to work with new FullBatchGenerator API #429
    Source code(tar.gz)
    Source code(zip)
  • v0.7.0(Jun 25, 2019)

    New features and enhancements:

    • SGC Implementation #361
    • Updated to support Python 3.7 #348
    • FullBatchNodeGenerator now supports a simpler interface to apply different adjacency matrix pre-processing options #405
    • Full-batch models (GCN, GAT, and SGC) now return predictions for only those nodes provided to the generator in the same order #417
    • GAT now supports using a sparse adjacency matrix making execution faster #420
    • Added interpretability of GCN models and a demo of finding important edges for a node prediction #383
    • Added a demo showing inductive classification with the PubMed dataset #372

    Refactoring:

    • Added build() method for GraphSAGE and HinSAGE model classes #385 This replaces the node_model() and link_model() methods, which will be deprecated in future versions (deprecation warnings added).
    • Changed the FullBatchNodeGenerator to accept simpler method and transform arguments #405

    Fixed bugs:

    • Removed label from features for pubmed dataset. #362
    • Python igraph requirement fixed #392
    • Simplified random walks to not require passing a graph #408
    Source code(tar.gz)
    Source code(zip)
  • v0.6.1(Apr 1, 2019)

    Fixed bugs:

    • a bug in passing graph adjacency matrix to the optional func_opt function in FullBatchNodeGenerator class
    • a bug in demos/node-classification/gcn/gcn-cora-example.py:144: incorrect argument was used to pass the optional function to the generator for GCN

    Enhancements:

    • separate treatment of gcn and gat models in demos/ensembles/ensemble-node-classification-example.ipynb
    Source code(tar.gz)
    Source code(zip)
  • v0.6.0(Mar 14, 2019)

    New features and enhancements:

    • Graph Attention (GAT) layer and model (stack of GAT layers), with demos #216, #315
    • Unsupervised GraphSAGE #331 with a demo #335
    • Model Ensembles #343
    • Community detection based on unsupervised graph representation learning #354
    • Saliency maps and integrated gradients for model interpretability #345
    • Shuffling of head nodes/edges in node and link generators at each epoch #298

    Fixed bugs:

    • a bug where seed was not passed to sampler in GraphSAGELinkGenerator constructor #337
    • UniformRandomMetaPathWalk doesn't update the current node neighbors #340
    • seed value for link mapper #336
    Source code(tar.gz)
    Source code(zip)
  • v0.5.0(Feb 11, 2019)

    Implemented new features and enhancements:

    • Added model calibration #326
    • Added GraphConvolution layer, GCN class for a stack of GraphConvolution layers, and FullBatchNodeGenerator class for feeding data into GCN models #318
    • Added GraphSAGE attention aggregator #317
    • Added GraphSAGE MaxPoolAggregator and MeanPoolAggregator #278
    • Added shuffle option to all flow methods for GraphSAGE and HinSAGE generators #328
    • GraphSAGE and HinSAGE: ensure that a MLP can be created by using zero samples #301
    • Handle isolated nodes in GraphSAGE #294
    • Ensure isolated nodes are handled correctly by GraphSAGENodeMapper and GraphSAGELinkMapper #182
    • EdgeSplitter: introduce a switch for keeping the reduced graph connected #285
    • Node2vec for weighted graphs #241
    • Fix edge types in demos #237
    • Add docstrings to StellarGraphBase class #175
    • Make L2-normalisation of the final embeddings in GraphSAGE and HinSAGE optional #115
    • Check/change the GraphSAGE mapper's behaviour for isolated nodes #100
    • Added GraphSAGE node embedding extraction and visualisation #290

    Fixed bugs:

    • Fixed the bug in running demos when no options given #271
    • Fixed the bug in LinkSequence that threw an error when no link targets were given #273

    Refactoring:

    • Refactored link inference classes to use edge_embedding_method instead of edge_feature_method #327
    Source code(tar.gz)
    Source code(zip)
  • 0.4.1(Oct 4, 2018)

  • v0.4.0(Sep 14, 2018)

    Features of this release:

    • The library is refactored for better structure and more intuitive use;
    • /demos populated with examples covering representation learning, node attribute inference, and link prediction/inference for both homogeneous and heterogeneous networks;
    • Usage of StellarGraph class is simplified;
    • Documentation improved;
    • Various bugs fixed.
    Source code(tar.gz)
    Source code(zip)
  • v0.3.0(Jul 16, 2018)

    What's new in this release:

    • UniformRandomMetaPathWalk class added to /stellar/data/explorer.py, enabling metapath-driven uniform random walks on heterogeneous graphs with multiple node types (but currently limited to one edge type per pair of nodes)
    • Added GraphSAGELinkMapper class to /stellar/mapper/link_mapper.py, for feeding minibatches of links into the GraphSAGE layer, for link prediction/classification/attribute inference workflows.
    • A demo of link prediction using GraphSAGE is added in /demos/link-prediction_graphsage/, showing how to use GraphSAGELinkMapper to build an end-to-end link prediction/classification workflow with GraphSAGE.
    • StellarGraph base class is introduced in /stellar/data/stellargraph.py. This class is intended to be the default class for graph objects in this library.
    • A convenience graph loader function, from_epgm(), is added to /stellar/data/loader.py
    • Some bugs are fixed
    • Code documentation is improved
    Source code(tar.gz)
    Source code(zip)
  • v0.2.0(Jul 4, 2018)

    What's new in this release:

    • UniformRandomWalk class added to /stellar/data/explorer.py
    • SampledBreadthFirstWalk class added, to be used with GraphSAGENodeMapper class
    • GraphSAGENodeMapper class added, to feed minibatches of sampled subgraphs to GraphSAGE layer
    • a demo added /demos/node-classification/epgm-example.py showing how to use GraphSAGENodeMapper with SampledBreadthFirstWalk sampler to build an end-to-end node classification workflow with GraphSAGE.
    Source code(tar.gz)
    Source code(zip)
Convert BART models to ONNX with quantization. 3X reduction in size, and upto 3X boost in inference speed

fast-Bart Reduction of BART model size by 3X, and boost in inference speed up to 3X BART implementation of the fastT5 library (https://github.com/Ki6a

Siddharth Sharma 19 Dec 09, 2022
Accelerated Multi-Modal MR Imaging with Transformers

Accelerated Multi-Modal MR Imaging with Transformers Dependencies numpy==1.18.5 scikit_image==0.16.2 torchvision==0.8.1 torch==1.7.0 runstats==1.8.0 p

54 Dec 16, 2022
Only valid pull requests will be allowed. Use python only and readme changes will not be accepted.

❌ This repo is excluded from hacktoberfest This repo is for python beginners and contains lot of beginner python projects for practice. You can also s

Prajjwal Pathak 50 Dec 28, 2022
AtlasNet: A Papier-Mâché Approach to Learning 3D Surface Generation

AtlasNet [Project Page] [Paper] [Talk] AtlasNet: A Papier-Mâché Approach to Learning 3D Surface Generation Thibault Groueix, Matthew Fisher, Vladimir

577 Dec 17, 2022
利用python脚本实现微信、支付宝账单的合并,并保存到excel文件实现自动记账,可查看可视化图表。

KeepAccounts_v2.0 KeepAccounts.exe和其配套表格能够实现微信、支付宝官方导出账单的读取合并,为每笔帐标记类型,并按月份和类型生成可视化图表。再也不用消费一笔记一笔,每月仅需10分钟,记好所有的帐。 作者: MickLife Bilibili: https://spac

159 Jan 01, 2023
A configurable, tunable, and reproducible library for CTR prediction

FuxiCTR This repo is the community dev version of the official release at huawei-noah/benchmark/FuxiCTR. Click-through rate (CTR) prediction is an cri

XUEPAI 397 Dec 30, 2022
The official project of SimSwap (ACM MM 2020)

SimSwap: An Efficient Framework For High Fidelity Face Swapping Proceedings of the 28th ACM International Conference on Multimedia The official reposi

Six_God 2.6k Jan 08, 2023
Este conversor criará a medida exata para sua receita de capuccino gelado da grandiosa Rafaella Ballerini!

ConversorDeMedidas_CapuccinoGelado Este conversor criará a medida exata para sua receita de capuccino gelado da grandiosa Rafaella Ballerini! Requirem

Arthur Ottoni Ribeiro 48 Nov 15, 2022
Neural-Pull: Learning Signed Distance Functions from Point Clouds by Learning to Pull Space onto Surfaces(ICML 2021)

Neural-Pull: Learning Signed Distance Functions from Point Clouds by Learning to Pull Space onto Surfaces(ICML 2021) This repository contains the code

149 Dec 15, 2022
Official implementation of "Motif-based Graph Self-Supervised Learning forMolecular Property Prediction"

Motif-based Graph Self-Supervised Learning for Molecular Property Prediction Official Pytorch implementation of NeurIPS'21 paper "Motif-based Graph Se

zaixi 71 Dec 20, 2022
Official code repository for the EMNLP 2021 paper

Integrating Visuospatial, Linguistic and Commonsense Structure into Story Visualization PyTorch code for the EMNLP 2021 paper "Integrating Visuospatia

Adyasha Maharana 23 Dec 19, 2022
Defocus Map Estimation and Deblurring from a Single Dual-Pixel Image

Defocus Map Estimation and Deblurring from a Single Dual-Pixel Image This repository is an implementation of the method described in the following pap

21 Dec 15, 2022
PyTorch implementation for the Neuro-Symbolic Sudoku Solver leveraging the power of Neural Logic Machines (NLM)

Neuro-Symbolic Sudoku Solver PyTorch implementation for the Neuro-Symbolic Sudoku Solver leveraging the power of Neural Logic Machines (NLM). Please n

Ashutosh Hathidara 60 Dec 10, 2022
Real-Time SLAM for Monocular, Stereo and RGB-D Cameras, with Loop Detection and Relocalization Capabilities

ORB-SLAM2 Authors: Raul Mur-Artal, Juan D. Tardos, J. M. M. Montiel and Dorian Galvez-Lopez (DBoW2) 13 Jan 2017: OpenCV 3 and Eigen 3.3 are now suppor

Raul Mur-Artal 7.8k Dec 30, 2022
Code for Transformers Solve Limited Receptive Field for Monocular Depth Prediction

Official PyTorch code for Transformers Solve Limited Receptive Field for Monocular Depth Prediction. Guanglei Yang, Hao Tang, Mingli Ding, Nicu Sebe,

stanley 152 Dec 16, 2022
Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition

Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition

107 Dec 02, 2022
Official Implementation of Swapping Autoencoder for Deep Image Manipulation (NeurIPS 2020)

Swapping Autoencoder for Deep Image Manipulation Taesung Park, Jun-Yan Zhu, Oliver Wang, Jingwan Lu, Eli Shechtman, Alexei A. Efros, Richard Zhang UC

449 Dec 27, 2022
Neuron class provides LNU (Linear Neural Unit), QNU (Quadratic Neural Unit), RBF (Radial Basis Function), MLP (Multi Layer Perceptron), MLP-ELM (Multi Layer Perceptron - Extreme Learning Machine) neurons learned with Gradient descent or LeLevenberg–Marquardt algorithm

Neuron class provides LNU (Linear Neural Unit), QNU (Quadratic Neural Unit), RBF (Radial Basis Function), MLP (Multi Layer Perceptron), MLP-ELM (Multi Layer Perceptron - Extreme Learning Machine) neu

Filip Molcik 38 Dec 17, 2022
PyTorch implementation of paper "StarEnhancer: Learning Real-Time and Style-Aware Image Enhancement" (ICCV 2021 Oral)

StarEnhancer StarEnhancer: Learning Real-Time and Style-Aware Image Enhancement (ICCV 2021 Oral) Abstract: Image enhancement is a subjective process w

IDKiro 133 Dec 28, 2022
Image-to-image regression with uncertainty quantification in PyTorch

Image-to-image regression with uncertainty quantification in PyTorch. Take any dataset and train a model to regress images to images with rigorous, distribution-free uncertainty quantification.

Anastasios Angelopoulos 25 Dec 26, 2022