This C++ toolbox is aimed at representing and solving common AI problems, implementing an easy-to-use interface which should be hopefully extensible to many problems, while keeping code readable.
Current development includes MDPs, POMDPs and related algorithms. This toolbox
has been developed taking inspiration from the Matlab MDPToolbox, which you
can find here, and from the
pomdp-solve software written by A. R. Cassandra, which you can find
here.
This toolbox is aimed at Decision Theoretic Control algorithms. The general idea is to create algorithms that are able to interact with an environment in order to obtain some reward using actions, and to find the best policy of actions to use to do so.
The field divides itself into planning and reinforcement learning: planning focuses into solving problems that we know how to model: think chess, or 2048. Reinforcement learning focuses on exploring an unknown environment and learning the best policy for it. An excellent introduction to the basics can be found freely online in this book.
There are many variants of these problems, with single agent worlds, multi agent, multi objective, competitive, cooperative, partially observable and so on. This framework is a work in progress that tries to implement many DTC algorithms in one place, much like OpenCV is for Computer Vision algorithms.
Please note that the API may change over time (although most things at this point are stable) since at every algorithm I add I may decide to alter the API a bit, to offer a more consistent interface throughout the library.
Decision Theoretic Control is a field which is in rapid development. There are incredibly many methods to solve problems, each with a huge number of variants. This framework only tries to implement the most influential methods, and in their vanilla form (or the form that is most widely used in the research community to my knowledge), trying to keep the code as simple as possible.
If you need any of the variants, the code is structured so that it is easy to read it and modify it to your requirements, versus providing an endless list of parameters and include all the variants. Some toolboxes do this, but my opinion is that this makes the code very hard to digest, which makes it also hard to find out what parameters to set to get the algorithm variant you want.
Since Python does not allow templates, the classes are binded with as many as possible instantiations. This toolbox does lose quite a bit of power in terms of efficient customization when used from Python, but it allows to rapidly iterate in order to find out what works and what doesn't.
Policies:
Algorithms:
- Policy Evaluation
- Policy Iteration
- Value Iteration
- Win or Learn Fast Policy Iteration (WoLF)
- Q-Learning
- Hysteretic Q-Learning
- SARSA
- Expected SARSA
- SARSA(λ)
- Dyna-Q
- Dyna2
- Prioritized Sweeping
- Monte Carlo Tree Search (MCTS)
Policies:
- Normal Policy
- Epsilon-Greedy Policy
- Softmax Policy
- Q-Greedy Policy
- WoLF Policy
Algorithms:
- Witness
- Incremental Pruning
- Point Based Value Iteration (PBVI)
- POMCP with UCB1
- rPOMCP
- QMDP
- Real-Time Belief State Search (RTBSS)
- Augmented MDP (AMDP)
- PERSEUS
Policies:
- Normal Policy
Not in Python yet.
Algorithms:
- Variable Elimination
- Multi-Objective Variable Elimination
- Sparse Cooperative QLearning
- Learning with Linear Rewards (LLR)
- FactoredLP
Policies:
- SingleAction Policy
- Epsilon-Greedy Policy
- Q-Greedy Policy
To build the library you need:
- cmake
- the boost library >= 1.62
- the Eigen 3.3 library.
In addition, full C++17 support is now required (this means at least g++-7)
If you want to build the POMDP or Factored MDP part of the library you will also need:
- the lp_solve library (a shared library must be available to compile the Python wrapper).
Once you have all required dependencies, you can simply execute the following commands from the project's main folder:
mkdir build
cd build/
cmake ..
makecmake can be called with a series of flags in order to customize the output,
if building everything is not desirable. The following flags are available:
CMAKE_BUILD_TYPE # Defines the build type
MAKE_ALL # Builds all there is to build in the project
MAKE_LIB # Builds the whole core C++ library (MDP, POMDP, etc..)
MAKE_MDP # Builds only the core C++ MDP library
MAKE_FMDP # Builds only the core C++ Factored MDP and MDP library
MAKE_POMDP # Builds only the core C++ POMDP and MDP library
MAKE_PYTHON # Builds Python bindings for the compiled core library
MAKE_TESTS # Builds the library's tests for the compiled core library
MAKE_EXAMPLES # Builds the library's examples using the compiled core libraryThese flags can be combined as needed. For example:
# Will build MDP and MDP Python bindings
cmake -DCMAKE_BUILD_TYPE=Debug -DMAKE_MDP=1 -DMAKE_PYTHON=1 ..The default flags when nothing is specified are MAKE_ALL and
CMAKE_BUILD_TYPE=Release.
The static library files will be available directly in the build directory.
Three separate libraries are built: AIToolboxMDP, AIToolboxPOMDP and
AIToolboxFMDP. In case you want to link against either the POMDP library or
the Factored MDP library, you will also need to link against the MDP one, since
both of them use MDP functionality.
A number of small tests are included which you can find in the test/ folder.
You can execute them after building the project using the following command
directly from the build directory, just after you finish make:
ctestThe tests also offer a brief introduction for the framework, waiting for a more complete descriptive write-up. Only the tests for the parts of the library that you compiled are going to be built.
To compile the library's documentation you need the Doxygen tool. To use it it is sufficient to execute the following command from the project's root folder:
doxygenAfter that the documentation will be generated into an html folder in the
main directory.
To compile a program that uses this library, simply link it against the compiled
libraries you need, and possibly to the lp_solve libraries (if using POMDP or
FMDP).
Please note that since both POMDP and FMDP libraries rely on the MDP code, you
MUST specify those libraries before the MDP library when linking,
otherwise it may result in undefined reference errors. The POMDP and Factored
MDP libraries are not currently dependent on each other so their order does not
matter.
For Python, you just need to import the MDP.so and POMDP.so modules, and
you'll be able to use the classes as exported to Python. All classes are
documented, and you can run in the Python CLI
help(MDP)
help(POMDP)
to see the documentation for each specific class.
The latest documentation is available here. Keep in mind that it may not always be 100% up to date with the latest commits, while the one you compile yourself will of course be.
For Python docs you can find them by typing help(MDP) or help(MDP.SomeMDPClass)
from the interpreter. It should show the exported API for each class, along with
any differences in input/output.