Crates.io | adf-bdd-bin |
lib.rs | adf-bdd-bin |
version | 0.3.0 |
source | src |
created_at | 2022-08-02 13:33:34.381088 |
updated_at | 2022-08-02 13:33:34.381088 |
description | Solver for ADFs grounded, complete, and stable semantics by utilising OBDDs - ordered binary decision diagrams |
homepage | https://ellmau.github.io/adf-obdd |
repository | https://github.com/ellmau/adf-obdd |
max_upload_size | |
id | 637339 |
size | 66,284 |
This is the readme for the executable solver.
An abstract dialectical framework (ADF) consists of abstract statements. Each statement has an unique label and might be related to other statements (s) in the ADF. This relation is defined by a so-called acceptance condition (ac), which intuitively is a propositional formula, where the variable symbols are the labels of the statements. An interpretation is a three valued function which maps to each statement a truth value (true, false, undecided). We call such an interpretation a model, if each acceptance condition agrees to the interpration.
An ordered binary decision diagram is a normalised representation of binary functions, where satisfiability- and validity checks can be done relatively cheap.
USAGE:
adf-bdd [OPTIONS] <INPUT>
ARGS:
<INPUT> Input filename
OPTIONS:
--an Sorts variables in an alphanumeric manner
--com Compute the complete models
--counter <COUNTER> Set if the (counter-)models shall be computed and printed,
possible values are 'nai' and 'mem' for naive and memoization
repectively (only works in hybrid and naive mode)
--export <EXPORT> Export the adf-bdd state after parsing and BDD instantiation to
the given filename
--grd Compute the grounded model
-h, --help Print help information
--heu <HEU> Choose which heuristics shall be used by the nogood-learning
approach [possible values: Simple, MinModMinPathsMaxVarImp,
MinModMaxVarImpMinPaths]
--import Import an adf- bdd state instead of an adf
--lib <IMPLEMENTATION> Choose the bdd implementation of either 'biodivine', 'naive', or
hybrid [default: hybrid]
--lx Sorts variables in an lexicographic manner
-q Sets log verbosity to only errors
--rust_log <RUST_LOG> Sets the verbosity to 'warn', 'info', 'debug' or 'trace' if -v and
-q are not use [env: RUST_LOG=debug]
--stm Compute the stable models
--stmca Compute the stable models with the help of modelcounting using
heuristics a
--stmcb Compute the stable models with the help of modelcounting using
heuristics b
--stmng Compute the stable models with the nogood-learning based approach
--stmpre Compute the stable models with a pre-filter (only hybrid lib-mode)
--stmrew Compute the stable models with a single-formula rewriting (only
hybrid lib-mode)
--stmrew2 Compute the stable models with a single-formula rewriting on
internal representation(only hybrid lib-mode)
--twoval Compute the two valued models with the nogood-learning based
approach
-v Sets log verbosity (multiple times means more verbose)
-V, --version Print version information
Note that import and export only works if the naive library is chosen
Right now there is no additional information to the computed models, so if you use --com --grd --stm the borders between the results are not obviously communicated. They can be easily identified though:
The computation is always in the same order
We know that there is always exactly one grounded model
We know that there always exist at least one complete model (i.e. the grounded one)
We know that there does not need to exist a stable model
We know that every stable model is a complete model too
Each statement is defined by an ASP-style unary predicate s, where the enclosed term represents the label of the statement. The binary predicate ac relates each statement to one propositional formula in prefix notation, with the logical operations and constants as follows:
To build the binary, you need to run
$> cargo build --workspace --release
To build the binary with debug-symbols, run
$> cargo build --workspace
To run all the tests placed in the submodule you need to run
$> git submodule init
at the first time. Afterwards you need to update the content of the submodule to be on the currently used revision by
$> git submodule update
The tests can be started by using the test-framework of cargo, i.e.
$> cargo test
Note that some of the instances are quite big and it might take some time to finish all the tests. If you do not initialise the submodule, tests will "only" run on the other unit-tests and (possibly forthcoming) other integration tests. Due to the way of the generated test-modules you need to call
$> cargo clean
if you change some of your test-cases.
To remove the tests just type
$> git submodule deinit res/adf-instances
or
$> git submodule deinit --all
This work is partly supported by Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) in projects number 389792660 (TRR 248, Center for Perspicuous Systems), the Bundesministerium für Bildung und Forschung (BMBF, Federal Ministry of Education and Research) in the Center for Scalable Data Analytics and Artificial Intelligence (ScaDS.AI), and by the Center for Advancing Electronics Dresden (cfaed).
This work has been partly developed by the Knowledge-Based Systems Group, Faculty of Computer Science of TU Dresden.
Hosting content here does not establish any formal or legal relation to TU Dresden.