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TensorFlow Eager implementation of NEAT and Adaptive HyperNEAT

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TensorFlow NEAT

Background

NEAT (NeuroEvolution of Augmenting Topologies) is a popular neuroevolution algorithm, one of the few such algorithms that evolves the architectures of its networks in addition to the weights. For more information, see this research paper: http://nn.cs.utexas.edu/downloads/papers/stanley.ec02.pdf.

HyperNEAT is an extension to NEAT that indirectly encodes the weights of the network (called the substrate) with a separate network (called a CPPN, for compositional pattern-producing network). For more information on HyperNEAT, see this website: http://eplex.cs.ucf.edu/hyperNEATpage/.

Adaptive HyperNEAT is an extension to HyperNEAT which indirectly encodes both the initial weights and an update rule for the weights such that some learning can occur during a network's "lifetime." For more information, see this research paper: http://eplex.cs.ucf.edu/papers/risi_sab10.pdf.

About

Because TensorFlow did not support dynamic computation graphs, there was no mature TensorFlow implementation of NEAT. This project makes use of the dynamic computation graphs introduced with TensorFlow Eager. TensorFlow NEAT builds upon PyTorch-NEAT and NEAT-Python by providing some functions which can turn a NEAT-Python genome into either a recurrent TensorFlow network or a TensorFlow CPPN for use in HyperNEAT or Adaptive HyperNEAT. We also provide some environments in which to test NEAT and Adaptive HyperNEAT, and a more involved example using the CPPN infrastructure with Adaptive HyperNEAT on a T-maze.

Examples

The following snippet turns a NEAT-Python genome into a recurrent TensorFlow network:

from tf_neat.recurrent_net import RecurrentNet

net = RecurrentNet.create(genome, config, bs)
outputs = net.activate(some_array)

You can also turn a NEAT-Python genome into a CPPN:

from tf_neat.cppn import create_cppn

cppn_nodes = create_cppn(genome, config)

A CPPN is represented as a graph structure. For easy evaluation, a CPPN's input and output nodes may be named:

from tf_neat.cppn import create_cppn

[delta_w_node] = create_cppn(
    genome,
    config,
    ["x_in", "y_in", "x_out", "y_out", "pre", "post", "w"],
    ["delta_w"],
)

delta_w = delta_w_node(x_in=some_array, y_in=other_array, ...)

We also provide some infrastructure for running networks in Gym environments:

from tf_neat.multi_env_eval import MultiEnvEvaluator
from tf_neat.recurrent_net import RecurrentNet

def make_net(genome, config, batch_size):
    return RecurrentNet.create(genome, config, batch_size)


def activate_net(net, states):
    outputs = net.activate(states).numpy()
    return outputs[:, 0] > 0.5

def make_env():
    return gym.make("CartPole-v0")

evaluator = MultiEnvEvaluator(
    make_net, activate_net, make_env=make_env, max_env_steps=max_env_steps, batch_size=batch_size,
)

fitness = evaluator.eval_genome(genome)

This allows multiple environments to run in parallel for efficiency.

A simple example using NEAT to solve the Cartpole can be run like this:

python3 -m examples.simple.main

And a simple example using Adaptive HyperNEAT to partially solve a T-maze can be run like this:

python3 -m examples.adaptive.main

To run the tests run from the root directory:

pytest 

Author / Support

TensorFlow NEAT is extended by Cristian Bodnar from PyTorch NEAT from Uber Research and Python NEAT by Alex Gajewsky.

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