GoGP

Go Genetic Programing

A Go implementation of a 'DNA' based Genetic Programmer. Given up to ~50 data columns and n rows, a program can be generated that fits the dataset to an assigned threshold of accuracy.

** This software is VERY beta, keep that in mind. **

Usage

go get github.com/wmiller848/GoGP

GoGP learn -c 4 -p 20 -g 10 < some.dat > MyProgram.coffee

-c Count: The number of columns in the input data that should be learned.

Required: true

-p Population: The running population to keep around.

Default: 20

Required: false

-g Generations: The number of generations to iterate.

Default: ∞

Required: false

-a Auto: Run until a score of 90% or better is found.

Default: true

Required: false

-s Score: Float value for desired percentage score of program. 0.10 = 10%

Default: 0.90

Required: false

This will output the contents of a CoffeScript program that evolved to match the input to our desired output.

The contents of some.csv could look like this:

1.0,3.1,5.2,1.0,Iris-setosa
3.1,5.2,1.8,2.3,Iris-virginica

Included in examples/datasets are several datasets to test learning.

Running the plant example can be done like:

GoGP learn -c 4 -s 0.90 -v < examples/datasets/plants.csv > output.coffee

For examle a run that scored 90% or above in all categories:

Invocation

The last column in each row is the desired output, meaning GoGP will evolve a program that given the input 1.0,3.1,5.2,1.0 will output Iris-setosa.

Example: GoGP learn -c 4 -s 0.90 < some.csv > MyProgram.coffee

Invoking the program is easy coffee MyProgram.coffee < some.csv, you could then pipe that output into your tooling.

About

GoGP is a DNA inspired genetic programmer.

What does that mean? Lets break it down:

Initialization

GoGP is heavly inspired by nature, namely DNA sequencing, natural selection, and random mutation. At the start of a new learning session the specifed population size is generated. Each new program in this population is defined by its DNA. DNA is defined as []byte, the first generation programs just have random bytes for their DNA.

DNA

So DNA is a []byte, but how does it work? There are several steps involved in converting that []byte into a working math equation to operate on input.

The first step is to sequence the DNA, like real DNA, our digital DNA contains four bases with a block size of three, additonaly each DNA strand can be read in three frames. Giving us 4^3=64 possible encodings to work with. Each program contains two sequences of DNA, a yin and yang strand. Each DNA strand is sequenced togeather and produces a single reading of the genes encoded. The process looks at each of the three readings in each strand, and produces the gene sequence in order of index of each gene.

Bases are defined as:

* Note this may become configurable in the future

A = [0x00 to 0x40]
B = [0x40 to 0x80]
C = [0x80 to 0xc0]
D = [0xc0 to 0xff]

For example, lets look at these two strands:

yin = [0, 24, 200, 241, 3, 12, 33, 4, 132]

yang = [20, 51, 127, 9, 15, 198, 18, 10, 215]

We could read each strand in three ways:

Strand yin:

• [0, 24, 200], [241, 3, 12], [33, 4, 132]
• [24, 200, 241], [3, 12, 33], [4, 132, 0]
• [200, 241, 3], [12, 33, 4], [132, 0, 24]

Strand yang

• [20, 51, 127], [9, 15, 198], [18, 10, 215]
• [51, 127, 9], [15, 198, 18], [10, 215, 20]
• [127, 9, 15], [198, 18, 10], [215, 20, 51]

Between those three readings we look for the first one that contains the start block AAA. If no start block is found that means that strand doesnt sequence to any genes. If we do find a start block we start reading from the strand from that frame, we read until we hit an end block DDD or the strand ends. We do the same thing for both strands and then sequence the output together respecting index. Also note index for any given gene takes into account the offset of the frame it was read from.

For example, say strand yin has a gene that starts at index 2 and ends at index 20. Say strand yang has two genes, one that starts at index 5 and goes to 15, and the other that starts at index 25 and goes to index 30. We would produce the following gene sequence:

gene = yin[2:20] + yang[25:30]

Notice that yang[5:15] was not included, that is because strand yin gene sequence ran through those indexes. This works almost the same way in real DNA.

A visual maping might looke like this:

Ying = xxx=======xxxxxx=======xxx
Yang = =====xxxx=========xxxx====

Where the 'x' is the genes that were sequenced.

Remembering that we have 64 total encoding, and that the start and stop blocks take up 2 of those, this means we can define 62 additional encodings. Currently we define the following block encodings:

& | ^ + - * / 0 1 2 3 4 5 6 7 8 9 , and one block for each input column as additional encodings.

The net result is that after we sequence all the genes we could get something like this Program Expression:

programExpression = '+12,5,$a-10*2000,7/12,$b', where $a and $b refer to an input column.

Before we move onto Program Expression's lets talk about what this DNA gets us. First, several bases may encode to the same value, AAA and AAB may encode to same value for example. Second we can arbitrarily add, remove, and mutate (XOR) bytes in our DNA strands. Mutations, even a single bit, may lead to no change or completly change the gene sequence, this is important because of the way we sequence this gives a lot of power to easy to perform mutations.

Program Expressions and Trees

Now we enter the the standard Genetic Programming space.

We have a program expression we can validate and convert into a Program Tree. These expressions are read from right to left and produce a program tree. For example:

+12,5,$a-10,2

Would convert to the following tree:

    +
____|_______
|   |  |   |
12  5  $a  -
           |
         _____
         |   |
         10  2

Given a tree, we can then covert that into a valid program. The previous tree would convert to:

(12 + 5 + $a) + (10 - 2)

In order to support balanced trees the Program Expression supports arbitrarily nested { and } to establish scope. For example:

/{12,10-3,$a}{*21,5}

This expression will convert to:

          /
          |
    ______________
    |             |
_________         *
|   |    |        |
12  10   -       ____
         |       |   |
        ____     21  5
        |  |
        3  $a

The previous tree would convert to:

(12 / 10 / (3 - $a)) / (21 * 5)

Using these simple rules, we can evolve arbitrary program trees to estimate our desired output. Because the mutations occures on the meta level above the Program Expression we gain a lot of resilence to getting stuck in bad tree evolvotion cycles. Because the dual DNA strands encode based off the index we can preserve 'dominate genes' aka those with a lower index.

The Evolution Process

Currently we apply an asexual mutation pattern, however because we have DNA strands we could do sexual crossover, ie combind strands between parents and maybe mutate the strands. However additional strand base pairing rules probaly need to be developed to mimic nature for seuxal crossover to work at its best.

In anycase, the process currently works as follows:

1. Generate the base population with random DNA
2. Run the training data though the program population
3. Take the top 25% and their (asexual mutated) children as the next generation
4. Repeat steps 2. and 3. for n generations
5. Return the program with the best fitness score
6. Profit

Road Map

Some items that would be great to have and being worked on, in a rough order:

• Getting the Test Suite up to date
• Some parallelism for running the generations
• Network io support for generated programs so you can send them data via tcp
• Sexual crossover
• Support outputing programs in many different languages and binary
• Generating a lib file instead of a program
• More then just math genes, maybe syscall genes for fuzzing :)

Legal & Licences

This code is licenced under a general BSD Licences, basicaly use as you see fit commercialy or not, don't take credit for work you didn't do. Don't use me, anyone or any group affiliated with this software names, companies or orginizations to advertise for your company, software or projects.

Copyright (c) 2016, William C. Miller
All rights reserved.

Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:

1. Redistributions of source code must retain the above copyright notice, this
   list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright notice,
   this list of conditions and the following disclaimer in the documentation
   and/or other materials provided with the distribution.
3. Neither the names, companies, or orginizations of the copyright holders nor
   the names, companies, or orginizations of its contributors may be used to
   endorse or promote products derived from this software without specific
   prior written permission.

THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.