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Establishing a convention for scripts is beneficial for various tools. However, we do not install scripts on anyones PATH - instead they go to a self contained (dyn *syspath*) /bin folder which could be added to path, or symlinks could be added. |
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.builds | ||
.github | ||
assets | ||
examples | ||
src | ||
test | ||
tools | ||
.gitattributes | ||
.gitignore | ||
build_win.bat | ||
CHANGELOG.md | ||
CONTRIBUTING.md | ||
janet_win.rc | ||
janet.1 | ||
LICENSE | ||
Makefile | ||
meson_options.txt | ||
meson.build | ||
README.md |
Janet is a programming language for system scripting, expressive automation, and extending programs written in C or C++ with user scripting capabilities.
Janet makes a good system scripting language, or a language to embed in other programs. It's like Lua and GNU Guile in that regard. It has more built-in functionality and a richer core language than Lua, but smaller than GNU Guile or Python. However, it is much easier to embed and port than Python or Guile.
There is a REPL for trying out the language, as well as the ability to run script files. This client program is separate from the core runtime, so Janet can be embedded in other programs. Try Janet in your browser at https://janet-lang.org.
If you'd like to financially support the ongoing development of Janet, consider sponsoring its primary author through GitHub.
Examples
See the examples directory for all provided example programs.
Game of Life
# John Conway's Game of Life
(def- window
(seq [x :range [-1 2]
y :range [-1 2]
:when (not (and (zero? x) (zero? y)))]
[x y]))
(defn- neighbors
[[x y]]
(map (fn [[x1 y1]] [(+ x x1) (+ y y1)]) window))
(defn tick
"Get the next state in the Game Of Life."
[state]
(def cell-set (frequencies state))
(def neighbor-set (frequencies (mapcat neighbors state)))
(seq [coord :keys neighbor-set
:let [count (get neighbor-set coord)]
:when (or (= count 3) (and (get cell-set coord) (= count 2)))]
coord))
(defn draw
"Draw cells in the game of life from (x1, y1) to (x2, y2)"
[state x1 y1 x2 y2]
(def cellset @{})
(each cell state (put cellset cell true))
(loop [x :range [x1 (+ 1 x2)]
:after (print)
y :range [y1 (+ 1 y2)]]
(file/write stdout (if (get cellset [x y]) "X " ". ")))
(print))
# Print the first 20 generations of a glider
(var *state* '[(0 0) (-1 0) (1 0) (1 1) (0 2)])
(for i 0 20
(print "generation " i)
(draw *state* -7 -7 7 7)
(set *state* (tick *state*)))
TCP Echo Server
# A simple TCP echo server using the built-in socket networking and event loop.
(defn handler
"Simple handler for connections."
[stream]
(defer (:close stream)
(def id (gensym))
(def b @"")
(print "Connection " id "!")
(while (:read stream 1024 b)
(printf " %v -> %v" id b)
(:write stream b)
(buffer/clear b))
(printf "Done %v!" id)
(ev/sleep 0.5)))
(net/server "127.0.0.1" "8000" handler)
Windows FFI Hello, World!
# Use the FFI to popup a Windows message box - no C required
(ffi/context "user32.dll")
(ffi/defbind MessageBoxA :int
[w :ptr text :string cap :string typ :int])
(MessageBoxA nil "Hello, World!" "Test" 0)
Language Features
- 600+ functions and macros in the core library
- Built-in socket networking, threading, subprocesses, and file system functions.
- Parsing Expression Grammars (PEG) engine as a more robust Regex alternative
- Macros and compile-time computation
- Per-thread event loop for efficient IO (epoll/IOCP/kqueue)
- First-class green threads (continuations) as well as OS threads
- Erlang-style supervision trees that integrate with the event loop
- First-class closures
- Garbage collection
- Distributed as janet.c and janet.h for embedding into a larger program.
- Python-style generators (implemented as a plain macro)
- Mutable and immutable arrays (array/tuple)
- Mutable and immutable hashtables (table/struct)
- Mutable and immutable strings (buffer/string)
- Tail recursion
- Interface with C functions and dynamically load plugins ("natives").
- Built-in C FFI for when the native bindings are too much work
- REPL development with debugger and inspectable runtime
Documentation
- For a quick tutorial, see the introduction for more details.
- For the full API for all functions in the core library, see the core API doc.
Documentation is also available locally in the REPL.
Use the (doc symbol-name)
macro to get API
documentation for symbols in the core library. For example,
(doc apply)
shows documentation for the apply
function.
To get a list of all bindings in the default
environment, use the (all-bindings)
function. You
can also use the (doc)
macro with no arguments if you are in the REPL
to show bound symbols.
Source
You can get the source on GitHub or SourceHut. While the GitHub repo is the official repo, the SourceHut mirror is actively maintained.
Building
macOS and Unix-like
The Makefile is non-portable and requires GNU-flavored make.
cd somewhere/my/projects/janet
make
make test
make repl
make install
make install-jpm-git
Find out more about the available make targets by running make help
.
32-bit Haiku
32-bit Haiku build instructions are the same as the UNIX-like build instructions,
but you need to specify an alternative compiler, such as gcc-x86
.
cd somewhere/my/projects/janet
make CC=gcc-x86
make test
make repl
make install
make install-jpm-git
FreeBSD
FreeBSD build instructions are the same as the UNIX-like build instructions,
but you need gmake
to compile. Alternatively, install the package directly with pkg install lang/janet
.
cd somewhere/my/projects/janet
gmake
gmake test
gmake repl
gmake install
gmake install-jpm-git
NetBSD
NetBSD build instructions are the same as the FreeBSD build instructions.
Alternatively, install the package directly with pkgin install janet
.
Windows
- Install Visual Studio or Visual Studio Build Tools.
- Run a Visual Studio Command Prompt (
cl.exe
andlink.exe
need to be on your PATH) andcd
to the directory with Janet. - Run
build_win
to compile Janet. - Run
build_win test
to make sure everything is working.
To build an .msi
installer executable, in addition to the above steps, you will have to:
- Install, or otherwise add to your PATH the WiX 3.11 Toolset.
- Run
build_win dist
.
Now you should have an .msi
. You can run build_win install
to install the .msi
, or execute the file itself.
Meson
Janet also has a build file for Meson, a cross-platform build system. Although Meson has a Python dependency, Meson is a very complete build system that is maybe more convenient and flexible for integrating into existing pipelines. Meson also provides much better IDE integration than Make or batch files, as well as support for cross-compilation.
For the impatient, building with Meson is as follows. The options provided to
meson setup
below emulate Janet's Makefile.
git clone https://github.com/janet-lang/janet.git
cd janet
meson setup build \
--buildtype release \
--optimization 2 \
--libdir /usr/local/lib \
-Dgit_hash=$(git log --pretty=format:'%h' -n 1)
ninja -C build
# Run the binary
build/janet
# Installation
ninja -C build install
Development
Janet can be hacked on with pretty much any environment you like, but for IDE lovers, Gnome Builder is probably the best option, as it has excellent Meson integration. It also offers code completion for Janet's C API right out of the box, which is very useful for exploring. VSCode, Vim, Emacs, and Atom each have syntax packages for the Janet language, though.
Installation
See the Introduction for more details. If you just want
to try out the language, you don't need to install anything. You can also move the janet
executable wherever you want on your system and run it.
Usage
A REPL is launched when the binary is invoked with no arguments. Pass the -h
flag
to display the usage information. Individual scripts can be run with ./janet myscript.janet
.
If you are looking to explore, you can print a list of all available macros, functions, and constants
by entering the command (all-bindings)
into the REPL.
$ janet
Janet 1.7.1-dev-951e10f Copyright (C) 2017-2020 Calvin Rose
janet:1:> (+ 1 2 3)
6
janet:2:> (print "Hello, World!")
Hello, World!
nil
janet:3:> (os/exit)
$ janet -h
usage: janet [options] script args...
Options are:
-h : Show this help
-v : Print the version string
-s : Use raw stdin instead of getline like functionality
-e code : Execute a string of janet
-E code arguments... : Evaluate an expression as a short-fn with arguments
-d : Set the debug flag in the REPL
-r : Enter the REPL after running all scripts
-R : Disables loading profile.janet when JANET_PROFILE is present
-p : Keep on executing if there is a top-level error (persistent)
-q : Hide logo (quiet)
-k : Compile scripts but do not execute (flycheck)
-m syspath : Set system path for loading global modules
-c source output : Compile janet source code into an image
-i : Load the script argument as an image file instead of source code
-n : Disable ANSI color output in the REPL
-l lib : Use a module before processing more arguments
-w level : Set the lint warning level - default is "normal"
-x level : Set the lint error level - default is "none"
-- : Stop handling options
If installed, you can also run man janet
to get usage information.
Embedding
Janet can be embedded in a host program very easily. The normal build
will create a file build/janet.c
, which is a single C file
that contains all the source to Janet. This file, along with
src/include/janet.h
and src/conf/janetconf.h
, can be dragged into any C
project and compiled into it. Janet should be compiled with -std=c99
on most compilers, and will need to be linked to the math library, -lm
, and
the dynamic linker, -ldl
, if one wants to be able to load dynamic modules. If
there is no need for dynamic modules, add the define
-DJANET_NO_DYNAMIC_MODULES
to the compiler options.
See the Embedding Section on the website for more information.
Discussion
Feel free to ask questions and join the discussion on the Janet Zulip Instance
FAQ
How fast is it?
It is about the same speed as most interpreted languages without a JIT compiler. Tight, critical loops should probably be written in C or C++ . Programs tend to be a bit faster than they would be in a language like Python due to the discouragement of slow Object-Oriented abstraction with lots of hash-table lookups, and making late-binding explicit. All values are boxed in an 8-byte representation by default and allocated on the heap, with the exception of numbers, nils and booleans. The PEG engine is a specialized interpreter that can efficiently process string and buffer data.
The GC is simple and stop-the-world, but GC knobs are exposed in the core library and separate threads have isolated heaps and garbage collectors. Data that is shared between threads is reference counted.
YMMV.
Where is (favorite feature from other language)?
It may exist, it may not. If you want to propose a major language feature, go ahead and open an issue, but it will likely be closed as "will not implement". Often, such features make one usecase simpler at the expense of 5 others by making the language more complicated.
Is there a language spec?
There is not currently a spec besides the documentation at https://janet-lang.org.
Is this Scheme/Common Lisp? Where are the cons cells?
Nope. There are no cons cells here.
Is this a Clojure port?
No. It's similar to Clojure superficially because I like Lisps and I like the aesthetics. Internally, Janet is not at all like Clojure, Scheme, or Common Lisp.
Are the immutable data structures (tuples and structs) implemented as hash tries?
No. They are immutable arrays and hash tables. Don't try and use them like Clojure's vectors and maps, instead they work well as table keys or other identifiers.
Can I do object-oriented programming with Janet?
To some extent, yes. However, it is not the recommended method of abstraction, and performance may suffer. That said, tables can be used to make mutable objects with inheritance and polymorphism, where object methods are implemented with keywords.
(def Car @{:honk (fn [self msg] (print "car " self " goes " msg)) })
(def my-car (table/setproto @{} Car))
(:honk my-car "Beep!")
Why can't we add (feature from Clojure) into the core?
Usually, one of a few reasons:
- Often, it already exists in a different form and the Clojure port would be redundant.
- Clojure programs often generate a lot of garbage and rely on the JVM to clean it up. Janet does not run on the JVM and has a more primitive garbage collector.
- We want to keep the Janet core small. With Lisps, a feature can usually be added as a library without feeling "bolted on", especially when compared to ALGOL-like languages. Adding features to the core also makes it a bit more difficult to keep Janet maximally portable.
Can I bind to Rust/Zig/Go/Java/Nim/C++/D/Pascal/Fortran/Odin/Jai/(Some new "Systems" Programming Language)?
Probably, if that language has a good interface with C. But the programmer may need to do
some extra work to map Janet's internal memory model to that of the bound language. Janet
also uses setjmp
/longjmp
for non-local returns internally. This
approach is out of favor with many programmers now and doesn't always play well with other languages
that have exceptions or stack-unwinding.
Why is my terminal spitting out junk when I run the REPL?
Make sure your terminal supports ANSI escape codes. Most modern terminals will
support these, but some older terminals, Windows consoles, or embedded terminals
will not. If your terminal does not support ANSI escape codes, run the REPL with
the -n
flag, which disables color output. You can also try the -s
flag if further issues
ensue.
Why is it called "Janet"?
Janet is named after the almost omniscient and friendly artificial being in The Good Place.