# mal - Make a Lisp [![Build Status](https://travis-ci.org/kanaka/mal.svg?branch=master)](https://travis-ci.org/kanaka/mal) ## Description **1. Mal is a Clojure inspired Lisp interpreter** **2. Mal is implemented in 75 languages** | Language | Creator | | -------- | ------- | | [Ada](#ada) | [Chris Moore](https://github.com/zmower) | | [GNU Awk](#gnu-awk) | [Miutsuru Kariya](https://github.com/kariya-mitsuru) | | [Bash 4](#bash-4) | [Joel Martin](https://github.com/kanaka) | | [BASIC](#basic-c64-and-qbasic) (C64 & QBasic) | [Joel Martin](https://github.com/kanaka) | | [C](#c) | [Joel Martin](https://github.com/kanaka) | | [C++](#c-1) | [Stephen Thirlwall](https://github.com/sdt) | | [C#](#c-2) | [Joel Martin](https://github.com/kanaka) | | [ChucK](#chuck) | [Vasilij Schneidermann](https://github.com/wasamasa) | | [Clojure](#clojure) (Clojure & ClojureScript) | [Joel Martin](https://github.com/kanaka) | | [CoffeeScript](#coffeescript) | [Joel Martin](https://github.com/kanaka) | | [Common Lisp](#common-lisp) | [Iqbal Ansari](https://github.com/iqbalansari) | | [Crystal](#crystal) | [Linda_pp](https://github.com/rhysd) | | [D](#d) | [Dov Murik](https://github.com/dubek) | | [Dart](#dart) | [Harry Terkelsen](https://github.com/hterkelsen) | | [Elixir](#elixir) | [Martin Ek](https://github.com/ekmartin) | | [Elm](#elm) | [Jos van Bakel](https://github.com/c0deaddict) | | [Emacs Lisp](#emacs-lisp) | [Vasilij Schneidermann](https://github.com/wasamasa) | | [Erlang](#erlang) | [Nathan Fiedler](https://github.com/nlfiedler) | | [ES6](#es6-ecmascript-2015) (ECMAScript 2015) | [Joel Martin](https://github.com/kanaka) | | [F#](#f) | [Peter Stephens](https://github.com/pstephens) | | [Factor](#factor) | [Jordan Lewis](https://github.com/jordanlewis) | | [Fantom](#fantom) | [Dov Murik](https://github.com/dubek) | | [Forth](#forth) | [Chris Houser](https://github.com/chouser) | | [GNU Guile](#gnu-guile-21) | [Mu Lei](https://github.com/NalaGinrut) | | [GNU Smalltalk](#gnu-smalltalk) | [Vasilij Schneidermann](https://github.com/wasamasa) | | [Go](#go) | [Joel Martin](https://github.com/kanaka) | | [Groovy](#groovy) | [Joel Martin](https://github.com/kanaka) | | [Haskell](#haskell) | [Joel Martin](https://github.com/kanaka) | | [Haxe](#haxe-neko-python-c-and-javascript) (Neko, Python, C++, & JS) | [Joel Martin](https://github.com/kanaka) | | [Hy](#hy) | [Joel Martin](https://github.com/kanaka) | | [Io](#io) | [Dov Murik](https://github.com/dubek) | | [Java](#java-17) | [Joel Martin](https://github.com/kanaka) | | [JavaScript](#javascriptnode) ([Demo](http://kanaka.github.io/mal)) | [Joel Martin](https://github.com/kanaka) | | [Julia](#julia) | [Joel Martin](https://github.com/kanaka) | | [Kotlin](#kotlin) | [Javier Fernandez-Ivern](https://github.com/ivern) | | [LiveScript](#livescript) | [Jos van Bakel](https://github.com/c0deaddict) | | [Logo](#logo) | [Dov Murik](https://github.com/dubek) | | [Lua](#lua) | [Joel Martin](https://github.com/kanaka) | | [GNU Make](#gnu-make-381) | [Joel Martin](https://github.com/kanaka) | | [mal itself](#mal) | [Joel Martin](https://github.com/kanaka) | | [MATLAB](#matlab-gnu-octave-and-matlab) (GNU Octave & MATLAB) | [Joel Martin](https://github.com/kanaka) | | [miniMAL](#minimal) ([Repo](https://github.com/kanaka/miniMAL), [Demo](https://kanaka.github.io/miniMAL/)) | [Joel Martin](https://github.com/kanaka) | | [NASM](#nasm) | [Ben Dudson](https://github.com/bendudson) | | [Nim](#nim-0170) | [Dennis Felsing](https://github.com/def-) | | [Object Pascal](#object-pascal) | [Joel Martin](https://github.com/kanaka) | | [Objective C](#objective-c) | [Joel Martin](https://github.com/kanaka) | | [OCaml](#ocaml-4010) | [Chris Houser](https://github.com/chouser) | | [Perl](#perl-58) | [Joel Martin](https://github.com/kanaka) | | [Perl 6](#perl-6) | [Hinrik Örn Sigurðsson](https://github.com/hinrik) | | [PHP](#php-53) | [Joel Martin](https://github.com/kanaka) | | [Picolisp](#picolisp) | [Vasilij Schneidermann](https://github.com/wasamasa) | | [PL/pgSQL](#plpgsql-postgres-sql-procedural-language) (Postgres) | [Joel Martin](https://github.com/kanaka) | | [PL/SQL](#plsql-oracle-sql-procedural-language) (Oracle) | [Joel Martin](https://github.com/kanaka) | | [PostScript](#postscript-level-23) | [Joel Martin](https://github.com/kanaka) | | [PowerShell](#powershell) | [Joel Martin](https://github.com/kanaka) | | [Python](#python-2x-and-3x) (2.X & 3.X) | [Joel Martin](https://github.com/kanaka) | | [RPython](#rpython) | [Joel Martin](https://github.com/kanaka) | | [R](#r) | [Joel Martin](https://github.com/kanaka) | | [Racket](#racket-53) | [Joel Martin](https://github.com/kanaka) | | [Rexx](#rexx) | [Dov Murik](https://github.com/dubek) | | [Ruby](#ruby-19) | [Joel Martin](https://github.com/kanaka) | | [Rust](#rust-100-nightly) | [Joel Martin](https://github.com/kanaka) | | [Scala](#scala) | [Joel Martin](https://github.com/kanaka) | | [Scheme (R7RS)](#scheme-r7rs) | [Vasilij Schneidermann](https://github.com/wasamasa) | | [Skew](#skew) | [Dov Murik](https://github.com/dubek) | | [Swift 2](#swift) | [Keith Rollin](https://github.com/keith-rollin) | | [Swift 3](#swift-3) | [Joel Martin](https://github.com/kanaka) | | [Swift 4](#swift-4) | [陆遥](https://github.com/LispLY) | | [Tcl](#tcl-86) | [Dov Murik](https://github.com/dubek) | | [TypeScript](#typescript) | [Masahiro Wakame](https://github.com/vvakame) | | [VHDL](#vhdl) | [Dov Murik](https://github.com/dubek) | | [Vimscript](#vimscript) | [Dov Murik](https://github.com/dubek) | | [Visual Basic.NET](#visual-basicnet) | [Joel Martin](https://github.com/kanaka) | | [WebAssembly](#webassembly-wasm) (wasm) | [Joel Martin](https://github.com/kanaka) | | [Yorick](#yorick) | [Dov Murik](https://github.com/dubek) | **3. Mal is a learning tool** Each implementation of mal is separated into 11 incremental, self-contained (and testable) steps that demonstrate core concepts of Lisp. The last step is capable of self-hosting (running the mal implementation of mal). See the [make-a-lisp process guide](process/guide.md). The make-a-lisp steps are: * [step0_repl](process/guide.md#step0) * [step1_read_print](process/guide.md#step1) * [step2_eval](process/guide.md#step2) * [step3_env](process/guide.md#step3) * [step4_if_fn_do](process/guide.md#step4) * [step5_tco](process/guide.md#step5) * [step6_file](process/guide.md#step6) * [step7_quote](process/guide.md#step7) * [step8_macros](process/guide.md#step8) * [step9_try](process/guide.md#step9) * [stepA_mal](process/guide.md#stepA) Each make-a-lisp step has an associated architectural diagram. That elements that are new for that step are highlighted in red. Here is the final diagram for [step A](process/guide.md#stepA): ![stepA_mal architecture](process/stepA_mal.png) If you are interesting in creating a mal implementation (or just interested in using mal for something), please drop by the #mal channel on freenode. In addition to the [make-a-lisp process guide](process/guide.md) there is also a [mal/make-a-lisp FAQ](docs/FAQ.md) where I attempt to answer some common questions. ## Presentations Mal was presented publicly for the first time in a lightning talk at Clojure West 2014 (unfortunately there is no video). See examples/clojurewest2014.mal for the presentation that was given at the conference (yes, the presentation is a mal program). At Midwest.io 2015, Joel Martin gave a presentation on Mal titled "Achievement Unlocked: A Better Path to Language Learning". [Video](https://www.youtube.com/watch?v=lgyOAiRtZGw), [Slides](http://kanaka.github.io/midwest.io.mal/). More recently Joel gave a presentation on "Make Your Own Lisp Interpreter in 10 Incremental Steps" at LambdaConf 2016: [Part 1](https://www.youtube.com/watch?v=jVhupfthTEk), [Part 2](https://www.youtube.com/watch?v=X5OQBMGpaTU), [Part 3](https://www.youtube.com/watch?v=6mARZzGgX4U), [Part 4](https://www.youtube.com/watch?v=dCO1SYR5kDU), [Slides](http://kanaka.github.io/lambdaconf/). ## Building/running implementations The simplest way to run any given implementation is to use docker. Every implementation has a docker image pre-built with language dependencies installed. You can launch the REPL using a convenient target in the top level Makefile (where IMPL is the implementation directory name and stepX is the step to run): ``` make DOCKERIZE=1 "repl^IMPL^stepX" # OR stepA is the default step: make DOCKERIZE=1 "repl^IMPL" ``` ### Ada The Ada implementation was developed with GNAT 4.9 on debian. It also compiles unchanged on windows if you have windows versions of git, GNAT and (optionally) make. There are no external dependencies (readline not implemented). ``` cd ada make ./stepX_YYY ``` ### GNU awk The GNU awk implementation of mal has been tested with GNU awk 4.1.1. ``` cd gawk gawk -O -f stepX_YYY.awk ``` ### Bash 4 ``` cd bash bash stepX_YYY.sh ``` ### BASIC (C64 and QBasic) The BASIC implementation uses a preprocessor that can generate BASIC code that is compatible with both C64 BASIC (CBM v2) and QBasic. The C64 mode has been tested with [cbmbasic](https://github.com/kanaka/cbmbasic) (the patched version is currently required to fix issues with line input) and the QBasic mode has been tested with [qb64](http://www.qb64.net/). Generate C64 code and run it using cbmbasic: ``` cd basic make stepX_YYY.bas STEP=stepX_YYY ./run ``` Generate QBasic code and load it into qb64: ``` cd basic make MODE=qbasic stepX_YYY.bas ./qb64 stepX_YYY.bas ``` Thanks to [Steven Syrek](https://github.com/sjsyrek) for the original inspiration for this implementation. ### C The C implementation of mal requires the following libraries (lib and header packages): glib, libffi6, libgc, and either the libedit or GNU readline library. ``` cd c make ./stepX_YYY ``` ### C++ The C++ implementation of mal requires g++-4.9 or clang++-3.5 and a readline compatible library to build. See the `cpp/README.md` for more details: ``` cd cpp make # OR make CXX=clang++-3.5 ./stepX_YYY ``` ### C# ### The C# implementation of mal has been tested on Linux using the Mono C# compiler (mcs) and the Mono runtime (version 2.10.8.1). Both are required to build and run the C# implementation. ``` cd cs make mono ./stepX_YYY.exe ``` ### ChucK The ChucK implementation has been tested with ChucK 1.3.5.2. ``` cd chuck ./run ``` ### Clojure For the most part the Clojure implementation requires Clojure 1.5, however, to pass all tests, Clojure 1.8.0-RC4 is required. ``` cd clojure lein with-profile +stepX trampoline run ``` ### CoffeeScript ``` sudo npm install -g coffee-script cd coffee coffee ./stepX_YYY ``` ### Common Lisp The implementation has been tested with SBCL, CCL, CMUCL, GNU CLISP, ECL and Allegro CL on Ubuntu 16.04 and Ubuntu 12.04, see the [README](common-lisp/README.org) for more details. Provided you have the dependencies mentioned installed, do the following to run the implementation ``` cd common-lisp make ./run ``` ### Crystal The Crystal implementation of mal has been tested with Crystal 0.26.1. ``` cd crystal crystal run ./stepX_YYY.cr # OR make # needed to run tests ./stepX_YYY ``` ### D The D implementation of mal was tested with GDC 4.8. It requires the GNU readline library. ``` cd d make ./stepX_YYY ``` ### Dart The Dart implementation has been tested with Dart 1.20. ``` cd dart dart ./stepX_YYY ``` ### Emacs Lisp The Emacs Lisp implementation of mal has been tested with Emacs 24.3 and 24.5. While there is very basic readline editing (`` and `C-d` work, `C-c` cancels the process), it is recommended to use `rlwrap`. ``` cd elisp emacs -Q --batch --load stepX_YYY.el # with full readline support rlwrap emacs -Q --batch --load stepX_YYY.el ``` ### Elixir The Elixir implementation of mal has been tested with Elixir 1.0.5. ``` cd elixir mix stepX_YYY # Or with readline/line editing functionality: iex -S mix stepX_YYY ``` ### Elm The Elm implementation of mal has been tested with Elm 0.18.0 ``` cd elm make stepX_YYY.js STEP=stepX_YYY ./run ``` ### Erlang The Erlang implementation of mal requires [Erlang/OTP R17](http://www.erlang.org/download.html) and [rebar](https://github.com/rebar/rebar) to build. ``` cd erlang make # OR MAL_STEP=stepX_YYY rebar compile escriptize # build individual step ./stepX_YYY ``` ### ES6 (ECMAScript 2015) The ES6 / ECMAScript 2015 implementation uses the [babel](https://babeljs.io) compiler to generate ES5 compatible JavaScript. The generated code has been tested with Node 0.12.4. ``` cd es6 make node build/stepX_YYY.js ``` ### F# ### The F# implementation of mal has been tested on Linux using the Mono F# compiler (fsharpc) and the Mono runtime (version 3.12.1). The mono C# compiler (mcs) is also necessary to compile the readline dependency. All are required to build and run the F# implementation. ``` cd fsharp make mono ./stepX_YYY.exe ``` ### Factor The Factor implementation of mal has been tested with Factor 0.97 ([factorcode.org](http://factorcode.org)). ``` cd factor FACTOR_ROOTS=. factor -run=stepX_YYY ``` ### Fantom The Fantom implementation of mal has been tested with Fantom 1.0.70. ``` cd fantom make lib/fan/stepX_YYY.pod STEP=stepX_YYY ./run ``` ### Forth ``` cd forth gforth stepX_YYY.fs ``` ### GNU Guile 2.1+ ``` cd guile guile -L ./ stepX_YYY.scm ``` ### GNU Smalltalk The Smalltalk implementation of mal has been tested with GNU Smalltalk 3.2.91. ``` cd gnu-smalltalk ./run ``` ### Go The Go implementation of mal requires that go is installed on on the path. The implementation has been tested with Go 1.3.1. ``` cd go make ./stepX_YYY ``` ### Groovy The Groovy implementation of mal requires Groovy to run and has been tested with Groovy 1.8.6. ``` cd groovy make groovy ./stepX_YYY.groovy ``` ### Haskell The Haskell implementation requires the ghc compiler version 7.10.1 or later and also the Haskell parsec and readline (or editline) packages. ``` cd haskell make ./stepX_YYY ``` ### Haxe (Neko, Python, C++ and JavaScript) The Haxe implementation of mal requires Haxe version 3.2 to compile. Four different Haxe targets are supported: Neko, Python, C++, and JavaScript. ``` cd haxe # Neko make all-neko neko ./stepX_YYY.n # Python make all-python python3 ./stepX_YYY.py # C++ make all-cpp ./cpp/stepX_YYY # JavaScript make all-js node ./stepX_YYY.js ``` ### Hy The Hy implementation of mal has been tested with Hy 0.13.0. ``` cd hy ./stepX_YYY.hy ``` ### Io The Io implementation of mal has been tested with Io version 20110905. ``` cd io io ./stepX_YYY.io ``` ### Java 1.7 The Java implementation of mal requires maven2 to build. ``` cd java mvn compile mvn -quiet exec:java -Dexec.mainClass=mal.stepX_YYY # OR mvn -quiet exec:java -Dexec.mainClass=mal.stepX_YYY -Dexec.args="CMDLINE_ARGS" ``` ### JavaScript/Node ``` cd js npm update node stepX_YYY.js ``` ### Julia The Julia implementation of mal requires Julia 0.4. ``` cd julia julia stepX_YYY.jl ``` ### Kotlin The Kotlin implementation of mal has been tested with Kotlin 1.0. ``` cd kotlin make java -jar stepX_YYY.jar ``` ### LiveScript The LiveScript implementation of mal has been tested with LiveScript 1.5. ``` cd livescript make node_modules/.bin/lsc stepX_YYY.ls ``` ### Logo The Logo implementation of mal has been tested with UCBLogo 6.0. ``` cd logo logo stepX_YYY.lg ``` ### Lua The Lua implementation of mal has been tested with Lua 5.2. The implementation requires that luarocks and the lua-rex-pcre library are installed. ``` cd lua make # to build and link linenoise.so ./stepX_YYY.lua ``` ### Mal Running the mal implementation of mal involves running stepA of one of the other implementations and passing the mal step to run as a command line argument. ``` cd IMPL IMPL_STEPA_CMD ../mal/stepX_YYY.mal ``` ### GNU Make 3.81 ``` cd make make -f stepX_YYY.mk ``` ### NASM The NASM implementation of mal is written for x86-64 Linux, and has been tested with Linux 3.16.0-4-amd64 and NASM version 2.11.05. ``` cd nasm make ./stepX_YYY ``` ### Nim 0.17.0 The Nim implementation of mal has been tested with Nim 0.17.0. ``` cd nim make # OR nimble build ./stepX_YYY ``` ### Object Pascal The Object Pascal implementation of mal has been built and tested on Linux using the Free Pascal compiler version 2.6.2 and 2.6.4. ``` cd objpascal make ./stepX_YYY ``` ### Objective C The Objective C implementation of mal has been built and tested on Linux using clang/LLVM 3.6. It has also been built and tested on OS X using XCode 7. ``` cd objc make ./stepX_YYY ``` ### OCaml 4.01.0 ``` cd ocaml make ./stepX_YYY ``` ### MATLAB (GNU Octave and MATLAB) The MatLab implementation has been tested with GNU Octave 4.2.1. It has also been tested with MATLAB version R2014a on Linux. Note that MATLAB is a commercial product. ``` cd matlab ./stepX_YYY octave -q --no-gui --no-history --eval "stepX_YYY();quit;" matlab -nodisplay -nosplash -nodesktop -nojvm -r "stepX_YYY();quit;" # OR with command line arguments octave -q --no-gui --no-history --eval "stepX_YYY('arg1','arg2');quit;" matlab -nodisplay -nosplash -nodesktop -nojvm -r "stepX_YYY('arg1','arg2');quit;" ``` ### miniMAL [miniMAL](https://github.com/kanaka/miniMAL) is small Lisp interpreter implemented in less than 1024 bytes of JavaScript. To run the miniMAL implementation of mal you need to download/install the miniMAL interpreter (which requires Node.js). ``` cd miniMAL # Download miniMAL and dependencies npm install export PATH=`pwd`/node_modules/minimal-lisp/:$PATH # Now run mal implementation in miniMAL miniMAL ./stepX_YYY ``` ### Perl 5.8 For readline line editing support, install Term::ReadLine::Perl or Term::ReadLine::Gnu from CPAN. ``` cd perl perl stepX_YYY.pl ``` ### Perl 6 The Perl 6 implementation was tested on Rakudo Perl 6 2016.04. ``` cd perl6 perl6 stepX_YYY.pl ``` ### PHP 5.3 The PHP implementation of mal requires the php command line interface to run. ``` cd php php stepX_YYY.php ``` ### Picolisp The Picolisp implementation requires libreadline and Picolisp 3.1.11 or later. ``` cd picolisp ./run ``` ### PL/pgSQL (Postgres SQL Procedural Language) The PL/pgSQL implementation of mal requires a running Postgres server (the "kanaka/mal-test-plpgsql" docker image automatically starts a Postgres server). The implementation connects to the Postgres server and create a database named "mal" to store tables and stored procedures. The wrapper script uses the psql command to connect to the server and defaults to the user "postgres" but this can be overridden with the PSQL_USER environment variable. A password can be specified using the PGPASSWORD environment variable. The implementation has been tested with Postgres 9.4. ``` cd plpgsql ./wrap.sh stepX_YYY.sql # OR PSQL_USER=myuser PGPASSWORD=mypass ./wrap.sh stepX_YYY.sql ``` ### PL/SQL (Oracle SQL Procedural Language) The PL/pgSQL implementation of mal requires a running Oracle DB server (the "kanaka/mal-test-plsql" docker image automatically starts an Oracle Express server). The implementation connects to the Oracle server to create types, tables and stored procedures. The default SQL*Plus logon value (username/password@connect_identifier) is "system/oracle" but this can be overridden with the ORACLE_LOGON environment variable. The implementation has been tested with Oracle Express Edition 11g Release 2. Note that any SQL*Plus connection warnings (user password expiration, etc) will interfere with the ability of the wrapper script to communicate with the DB. ``` cd plsql ./wrap.sh stepX_YYY.sql # OR ORACLE_LOGON=myuser/mypass@ORCL ./wrap.sh stepX_YYY.sql ``` ### Postscript Level 2/3 The Postscript implementation of mal requires ghostscript to run. It has been tested with ghostscript 9.10. ``` cd ps gs -q -dNODISPLAY -I./ stepX_YYY.ps ``` ### PowerShell The PowerShell implementation of mal requires the PowerShell script language. It has been tested with PowerShell 6.0.0 Alpha 9 on Linux. ``` cd powershell powershell ./stepX_YYY.ps1 ``` ### Python (2.X and 3.X) ``` cd python python stepX_YYY.py ``` ### RPython You must have [rpython](https://rpython.readthedocs.org/) on your path (included with [pypy](https://bitbucket.org/pypy/pypy/)). ``` cd rpython make # this takes a very long time ./stepX_YYY ``` ### R The R implementation of mal requires R (r-base-core) to run. ``` cd r make libs # to download and build rdyncall Rscript stepX_YYY.r ``` ### Racket (5.3) The Racket implementation of mal requires the Racket compiler/interpreter to run. ``` cd racket ./stepX_YYY.rkt ``` ### Rexx The Rexx implementation of mal has been tested with Regina Rexx 3.6. ``` cd rexx make rexx -a ./stepX_YYY.rexxpp ``` ### Ruby (1.9+) ``` cd ruby ruby stepX_YYY.rb ``` ### Rust (1.0.0 nightly) The rust implementation of mal requires the rust compiler and build tool (cargo) to build. ``` cd rust cargo run --release --bin stepX_YYY ``` ### Scala ### Install scala and sbt (http://www.scala-sbt.org/0.13/tutorial/Installing-sbt-on-Linux.html): ``` cd scala sbt 'run-main stepX_YYY' # OR sbt compile scala -classpath target/scala*/classes stepX_YYY ``` ### Scheme (R7RS) ### The Scheme implementation of mal has been tested with Chibi-Scheme 0.7.3, Kawa 2.4, Gauche 0.9.5, CHICKEN 4.11.0, Sagittarius 0.8.3, Cyclone 0.6.3 (Git version) and Foment 0.4 (Git version). You should be able to get it running on other conforming R7RS implementations after figuring out how libraries are loaded and adjusting the `Makefile` and `run` script accordingly. ``` cd scheme make symlinks # chibi scheme_MODE=chibi ./run # kawa make kawa scheme_MODE=kawa ./run # gauche scheme_MODE=gauche ./run # chicken make chicken scheme_MODE=chicken ./run # sagittarius scheme_MODE=sagittarius ./run # cyclone make cyclone scheme_MODE=cyclone ./run # foment scheme_MODE=foment ./run ``` ### Skew ### The Skew implementation of mal has been tested with Skew 0.7.42. ``` cd skew make node stepX_YYY.js ``` ### Swift The Swift implementation of mal requires the Swift 2.0 compiler (XCode 7.0) to build. Older versions will not work due to changes in the language and standard library. ``` cd swift make ./stepX_YYY ``` ### Swift 3 The Swift 3 implementation of mal requires the Swift 3.0 compiler. It has been tested with Swift 3 Preview 3. ``` cd swift3 make ./stepX_YYY ``` ### Swift 4 The Swift 4 implementation of mal requires the Swift 4.0 compiler. It has been tested with Swift 4.2.3 release. ``` cd swift4 make ./stepX_YYY ``` ### Tcl 8.6 The Tcl implementation of mal requires Tcl 8.6 to run. For readline line editing support, install tclreadline. ``` cd tcl tclsh ./stepX_YYY.tcl ``` ### TypeScript The TypeScript implementation of mal requires the TypeScript 2.2 compiler. It has been tested with Node.js v6. ``` cd ts make node ./stepX_YYY.js ``` ### VHDL The VHDL implementation of mal has been tested with GHDL 0.29. ``` cd vhdl make ./run_vhdl.sh ./stepX_YYY ``` ### Vimscript The Vimscript implementation of mal requires Vim 8.0 to run. ``` cd vimscript ./run_vimscript.sh ./stepX_YYY.vim ``` ### Visual Basic.NET ### The VB.NET implementation of mal has been tested on Linux using the Mono VB compiler (vbnc) and the Mono runtime (version 2.10.8.1). Both are required to build and run the VB.NET implementation. ``` cd vb make mono ./stepX_YYY.exe ``` ### WebAssembly (wasm) ### The WebAssembly implementation is written in [Wam](https://github.com/kanaka/wam) (WebAssembly Macro language) and runs under the [wac/wace](https://github.com/kanaka/wac) WebAssembly runtime. ``` cd wasm make wace ./stepX_YYY.wasm ``` ### Yorick The Yorick implementation of mal was tested on Yorick 2.2.04. ``` cd yorick yorick -batch ./stepX_YYY.i ``` ## Running tests The top level Makefile has a number of useful targets to assist with implementation development and testing. The `help` target provides a list of the targets and options: ``` make help ``` ### Functional tests The are over 600 generic functional tests (for all implementations) in the `tests/` directory. Each step has a corresponding test file containing tests specific to that step. The `runtest.py` test harness launches a Mal step implementation and then feeds the tests one at a time to the implementation and compares the output/return value to the expected output/return value. * To run all the tests across all implementations (be prepared to wait): ``` make test ``` * To run all tests against a single implementation: ``` make "test^IMPL" # e.g. make "test^clojure" make "test^js" ``` * To run tests for a single step against all implementations: ``` make "test^stepX" # e.g. make "test^step2" make "test^step7" ``` * To run tests for a specific step against a single implementation: ``` make "test^IMPL^stepX" # e.g make "test^ruby^step3" make "test^ps^step4" ``` ### Self-hosted functional tests * To run the functional tests in self-hosted mode, you specify `mal` as the test implementation and use the `MAL_IMPL` make variable to change the underlying host language (default is JavaScript): ``` make MAL_IMPL=IMPL "test^mal^step2" # e.g. make "test^mal^step2" # js is default make MAL_IMPL=ruby "test^mal^step2" make MAL_IMPL=python "test^mal^step2" ``` ### Starting the REPL * To start the REPL of an implementation in a specific step: ``` make "repl^IMPL^stepX" # e.g make "repl^ruby^step3" make "repl^ps^step4" ``` * If you omit the step, then `stepA` is used: ``` make "repl^IMPL" # e.g make "repl^ruby" make "repl^ps" ``` * To start the REPL of the self-hosted implementation, specify `mal` as the REPL implementation and use the `MAL_IMPL` make variable to change the underlying host language (default is JavaScript): ``` make MAL_IMPL=IMPL "repl^mal^stepX" # e.g. make "repl^mal^step2" # js is default make MAL_IMPL=ruby "repl^mal^step2" make MAL_IMPL=python "repl^mal" ``` ### Performance tests Warning: These performance tests are neither statistically valid nor comprehensive; runtime performance is a not a primary goal of mal. If you draw any serious conclusions from these performance tests, then please contact me about some amazing oceanfront property in Kansas that I'm willing to sell you for cheap. * To run performance tests against a single implementation: ``` make "perf^IMPL" # e.g. make "perf^js" ``` * To run performance tests against all implementations: ``` make "perf" ``` ### Generating language statistics * To report line and byte statistics for a single implementation: ``` make "stats^IMPL" # e.g. make "stats^js" ``` * To report line and bytes statistics for general Lisp code (env, core and stepA): ``` make "stats-lisp^IMPL" # e.g. make "stats-lisp^js" ``` ## Dockerized testing Every implementation directory contains a Dockerfile to create a docker image containing all the dependencies for that implementation. In addition, the top-level Makefile contains support for running the tests target (and perf, stats, repl, etc) within a docker container for that implementation by passing *"DOCKERIZE=1"* on the make command line. For example: ``` make DOCKERIZE=1 "test^js^step3" ``` Existing implementations already have docker images built and pushed to the docker registry. However, if you wish to build or rebuild a docker image locally, the toplevel Makefile provides a rule for building docker images: ``` make "docker-build^IMPL" ``` **Notes**: * Docker images are named *"kanaka/mal-test-IMPL"* * JVM-based language implementations (Groovy, Java, Clojure, Scala): you will probably need to run this command once manually first `make DOCKERIZE=1 "repl^IMPL"` before you can run tests because runtime dependencies need to be downloaded to avoid the tests timing out. These dependencies are downloaded to dot-files in the /mal directory so they will persist between runs. ## External Implementations The following implementations are maintained as separate projects: ### HolyC * [by Alexander Bagnalla](https://github.com/bagnalla/holyc_mal) ### Rust * [by Tim Morgan](https://github.com/seven1m/mal-rust) * [by vi](https://github.com/vi/mal-rust-vi) - using [Pest](https://pest.rs/) grammar, not using typical Mal infrastructure (cargo-ized steps and built-in converted tests). ## Other mal Projects * [malc](https://github.com/dubek/malc) - Mal (Make A Lisp) compiler. Compiles a Mal program to LLVM assembly language, then binary. * [malcc](https://git.sr.ht/~tim/malcc) (@seven1m) - malcc is an incremental compiler implementation for the Mal language. It uses the Tiny C Compiler as the compiler backend and has full support for the Mal language, including macros, tail-call elimination, and even run-time eval. * [frock](https://github.com/chr15m/frock) - Clojure-flavoured PHP. Uses mal/php to run programs. ## License Mal (make-a-lisp) is licensed under the MPL 2.0 (Mozilla Public License 2.0). See LICENSE.txt for more details.