SAPL
SAPL is a purely functional, intermediate language and related infrastructure for supporting cross-compilation of lazy functional languages to different target platforms. It currently supports Clean and Haskell/GHC as source languages and provides JavaScript as target platform, however a DART and Java target is under development. SAPL is extensively used in the ITasks project, furthermore various GHC based projects are experimenting with SAPL. OverviewSAPL infrastructure consists of a few main parts built around the SAPL Language. Source filtersSource filters convert the source language to the SAPL language. Currently we have source filters for Clean and Haskell/GHC. For Clean, the filter is integrated into the compiler. As for Haskell/GHC, a separate compiler is provided based on the original one. Detailed instructions for their usages can be found at SAPL/Clean and SAPL/GHC, respectively. SAPL linkerSAPL has hierarchical module support based on directory layout. Prior to the target compilation a linking step is required to collect and combine, based on arbitrary root expressions, the necessary functions recursively from the separate modules into one SAPL file which will be the input of the target compilers. As the SAPL language is designed for easy parsing, linking is very fast and straightforward compared to the linking of the target languages (e.g. JavaScript) and helps with minimizing the size of the output code. FlavoursA flavour is a kind of configuration file used by the target compilers. It provides information about how to compile the built-in functions of a given source language to a given target language. It must be in sync with the source filter and source language dependent part of the run-time system. Flavours are provided for all the combinations of source and target languages. Target compilersA target compiler transforms SAPL code into a given target language. The compilation must be aided by a flavour for the correct compilation of the built-in functions. The SAPL library supports the development of target languages by providing a lexer and parser for the SAPL language along with language transformation functions (e.g. Topological ordering of let definitions), and other support functions (e.g. strictness propagation, type inference etc). Currently JavaScript is the only target language supported, however DART and Java targets are under development. Target run-timeRun-time functions are necessary to execute the target code. Some of these are independent of the source language and cope with e.g. lazy evaluation, while some are dependent of the source language and must be in sync with the source filter and the supporting flavour. Some language features must be supported by the run-time system, for the current state of/features supported by the run-times please consult with the appropriate page: Tutorial (Clean)The SAPL compiler and linker is fully integrated into the upcoming version of the Clean compiler. Until that becomes available, please contact me for instructions by dlacko@gmail.com. Tutorial (GHC)As for GHC a carefully adjusted environment must be used for the SAPL compilation (e.g. 32bit compiler must be used, for more explanation please consult to Sapl/GHC). We use [www.vagrantup.com Vagrant] to provide this environment by virtualisation. However, you don't need any knowledge on Vagrant, all you have to do is to install Vagrant in one easy step, check out the following SVN URL https://svn.cs.ru.nl/repos/clean-sapl/trunk/platforms/GHC/vagrant and in directory where you checked out type $ vagrant up followed by $ vagrant ssh and you find yourself using a shell where all the SAPL components are available precompiled. The current directory outside the virtual machine can be accessed at the directory /vagrant. Now, create a hello.hs with the well knows "Hello, World!" example: $ mkdir hello $ cd hello $ cat > hello.hs $ main = putStrLn "Hello, World!"^D First step, compile it to SAPL: $ ghcsapl hello.hs It creates a Main.sapl, as SAPL file names are the names of the modules rather than the original file names. If you are brave enough, have a look at the generated SAPL source code. It consists of three simple lines only, with references to functions located in other modules, e.g. System.IO. For proper compilation you need to collect the necessary functions from these modules. Precompiled SAPL files can be found in ~/sapl/packages, the base system modules are in core/base and core/ghc-prim within that. Use the sl command for linking: $ sl -I ~/sapl/packages/core/base -I ~/sapl/packages/core/ghc-prim -i Main.sapl -e Main.main hello.sapl This command produces a hello.sapl file which is already self-contained. Finally the $ sapl2js -f ghc hello.sapl produces JavaScript output of approximately 1300 bytes as hello.js. Please note the usage of the "ghc" flavour. I recommend one optimal step, the utilization of closure compiler to reduce code size and execution time: $ java -jar ~/sapl/tools/closure-compiler.jar --js_output_file hello_opt.js hello.js For the execution check out the necessary run-time from the following URLs:
It contains a template HTML file named client.html for the execution of a function placed in a file main.js. So all you need is to copy all the files of the run-time and either hello.js or hello_opt.js (renamed to main.js) into one common directory. For more elaborated projects I also recommend to create a Makefile. For this simplistic case it could be like this: SL=sl --include-dir=~/sapl/packages/core/base \ --include-dir=~/sapl/packages/core/ghc-prim S2JS=sapl2js -f ghc GHCSAPL=ghcsapl -O2 CC=java -jar ~/sapl/tools/closure-compiler.jar all: create hello_opt.js hello_opt.js: $(GHCSAPL) --make hello.hs $(SL) -i Main.sapl -e Main.main hello.sapl $(SAPL2JS) hello.sapl $(CC) --js_output_file hello_opt.js hello.js PublicationsThere are two publications that are closely related to the current form of SAPL, however, both of them are slightly outdated. The SAPL language described in the first paper is already modified several times for various reasons, but the compilation scheme is still basically the same. As for the second paper, most of the shortcomings listed there are solved after the publication (some of them by adjusting the SAPL language itself) and currently the transformation scheme support all of the Haskell/GHC language features.
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