Clafer, the Language
v0.4.0
Clafer is a general-purpose lightweight structural modeling language developed by
GSD Lab, University of Waterloo, and
MODELS group at IT University of Copenhagen.
Clafer can be used for modeling of static hierarchical structures but has no support for modeling the change of the structures over time (behavior).
The main goal of Clafer is to make modeling more accessible to a wider range of users and domains.
There are many possible applications of Clafer; however, three are prominent:
-
Product-Line Modeling - aims at representing and managing commonality and variability of assets in product lines and creating and verifying product configurations.
Clafer naturally supports multi-staged configuration.
-
Multi-Objective Product Optimization - aims at finding a set of products in a given product line that are optimal with respect to a set of objectives.
Clafer multi-objective optimizer generates a Pareto front of optimal product configurations.
-
Domain Modeling - aims at improving the understanding of the problem domain in the early stages of software development and determining the requirements with fewer defects.
This is also known as Concept Modeling or Ontology Modeling.
Clafer, the Compiler
Clafer compiler provides a reference implementation of Clafer, the language.
It translates models in Clafer to other formats (e.g., Alloy, JSON, Python, JS, HTML, DOT) to allow for reasoning and processing with existing tools (Alloy Analyzer, Choco3, and Z3 SMT solver, GraphViz).
Currently, the compiler is used by
Contributors
Getting the Clafer Compiler
Clafer can be installed from a binary distribution (preferred), from Hackage, and from the source code.
Dependencies for running
Regardless of the installation method, the following are
Optional:
- Java Platform (JDK) v8+, 32bit on Windows, 64bit otherwise
- needed only for running Alloy validation
- Alloy4.2
- needed only for Alloy output validation
- GraphViz
- the program
dot
is needed only in the html
mode for SVG graph generation
Installation from binaries
Binary distributions of the release 0.4.0 of Clafer Tools for Windows, Mac, and Linux,
can be downloaded from
Clafer Tools - Binary Distributions.
- download the binaries and unpack
<target directory>
of your choice
- add the
<target directory>
to your system path so that the executables can be found
Installation from Hackage
Dependencies
Clafer is now available on Hackage and it can be installed using
cabal update
cabal install clafer
- on Windows
cd C:\Users\<user>\AppData\Roaming\cabal\i386-windows-ghc-7.10.1\clafer-0.4.0
- on Linux
ca ~/.cabal/share/x86_64-linux-ghc-7.10.1/clafer-0.4.0/
- to automatically download Alloy jars, execute
Installation from the source code
Dependencies
On Windows
- MSYS2
- download MSYS2 installer
- in MSYS2 console, execute
pacman -Syu
pacman -S make wget unzip diffutils
Important: Branches must correspond
All related projects are following the simultaneous release model.
The branch master
contains releases, whereas the branch develop
contains code under development.
When building the tools, the branches should match.
Releases from branches 'masterare guaranteed to work well together.
Development versions from branches
develop` should work well together but this might not always be the case.
Building
- install the dependencies
- open the command line terminal. On Windows, open MSYS2 terminal.
- in some
<source directory>
of your choice, execute
git clone git://github.com/gsdlab/clafer.git
- in
<source directory>/clafer
, execute
cabal update
make init
make
Installation
- Execute
make install to=<target directory>
Note:
On Windows, use /
with the make
command instead of \
.
Integration with Sublime Text 2/3
See ClaferToolsST
Integration with VIM
See clafer-vim
Usage
Clafer Compiler
(As printed by clafer --help
)
Clafer 0.4.0
clafer [OPTIONS] [FILE]
Common flags:
-m --mode=CLAFERMODE Generated output type. Available
CLAFERMODEs are: 'alloy' (default,
Alloy 4.2); 'json' (intermediate
representation of Clafer model);
'clafer' (analyzed and desugared
clafer model); 'html' (original model
in HTML); 'graph' (graphical
representation written in DOT
language); 'cvlgraph' (cvl notation
representation written in DOT
language); 'python' (generates IR in
python); 'choco' (Choco constraint
programming solver). Multiple modes
can be specified at the same time,
e.g., '-m alloy -m html'.
-o --console-output Output code on console.
-i --flatten-inheritance Flatten inheritance ('alloy' mode
only).
--timeout-analysis=INT Timeout for analysis.
-l --no-layout Don't resolve off-side rule layout.
-n --nl --new-layout Use new fast layout resolver
(experimental).
-c --check-duplicates Check duplicated clafer names in
the entire model.
-f --skip-resolver Skip name resolution.
-k --keep-unused Keep uninstantated abstract clafers
('alloy' mode only).
-s --no-stats Don't print statistics.
-v --validate Validate outputs of all modes. Uses
'tools/alloy4.2.jar' for Alloy
models, and Clafer translator for
desugared Clafer models. Use
'--tooldir' to override the default
location of these tools.
--tooldir=DIR Specify the tools directory
('validate' only). Default: 'tools/'.
-a --alloy-mapping Generate mapping to Alloy source
code ('alloy' mode only).
--self-contained Generate a self-contained html
document ('html' mode only).
--add-graph Add a graph to the generated html
model ('html' mode only). Requires
the "dot" executable to be on the
system path.
--sr --show-references Whether the links for references
should be rendered. ('html' and
'graph' modes only).
--add-comments Include comments from the source
file in the html output ('html' mode
only).
-e --ecore2clafer Translate an ECore model into
Clafer.
--ss=SCOPESTRATEGY --scope-strategy Use scope computation strategy:
none or simple (default).
--check-afm --afm Throws an error if the cardinality
of any of the clafers is above 1.
--meta-data Generate a 'fully qualified
name'-'least-partially-qualified
name'-'unique ID' map ('.cfr-map').
In Alloy and Choco modes, generate
the scopes map ('.cfr-scope').
-? --help Display help message
-V --version Print version information
--numeric-version Print just the version number
The dependencies among the command line arguments are described on the model wiki.
Multiple modes can be used at the same time. For example,
clafer model.cfr -m alloy -m json -m html -m graph --self-contained --show-references --no-stats
The mode -m alloy
is only the default mode if no other modes are given. When other modes are given, the mode -m alloy
must be added explicitly if needed.
Additionally, [OPTIONS]
can also be specified directly in the model file by inserting the following compiler directive as the first line of the file:
//# [OPTIONS]
for example
//# --keep-unused -m=alloy
Options given at command line override the options given in the file using //#
which, in turn, override the defaults.
Using compiler directives
Compiler directives are comments of the form
//# <directive name>
The following directives are markers of locations in the input files for different purposes:
//# FRAGMENT
- marks the beginning of the new module fragment.
//# GRAPH
- marks the insertion point for a graph rendering. The graph is only produced in HTML mode with the argument --add-graph
.
//# STATS
- marks the insertion point for module statistics. The statistics can be omitted using the argument --no-stats
.
//# SUMMARY
- shorthand for //# GRAPH
and //# STATS
He is some information about the development of the clafer compiler.
Branching
We are following the simplified version of the successful Git branching model.
The branch master
is for releases and hot fixes only.
The branch develop
is for minor development and for integration of features from feature branches.
For any substantial work, branch off from develop
and create a pull request back into develop
after the work is completed.
We do testing and code review before merging into develop.
If the develop
is ahead, merge it into the feature branch and perform integration testing there.
To make a release, we create a pull request from develop
into master
.
We tag master
with version numbers after each release merge.
Testing
We have both automated tests and regression tests.
To run the automated tests (including both unit tests and doctests), execute
cabal test
To only run unit tests, execute cabal test test-suite
.
To only run doctests, execute cabal test doctests
.
For instructions for adding new modules to the doctest suite, see cabal integration.
To run all the automated tests and the regression tests, execute
make test
We do test-driven development in the following way:
- create a test case Clafer model in either
test/positive
or test/negative
depending on whether a test case should compile successfully or return an error. For example, see a positive test case test/positive/redefinition.cfr.
- produce the intended compiler output automatically if possible and manually fix the output. Save the intended output as a regression test case. For example, see test/regression/redefinition.cfr.reg.
- implement the feature to reproduce the intended output: compiler the test case and execute
cd test
make diffRegressions
this will show you how the current output diverges from the intended output.
Modifying the grammar
We are using a customized version of BNCF.
Clone the repository and install a binary of bnfc
so that it's visible in your PATH
.
After changing the grammar, execute
make grammar
Need help?