Seamless, type-safe single program framework for client-server communication
Support for modern web technologies such as WebSockets, WebStorage and Canvas
Simple JavaScript interoperability
Generates small, fast programs
Supports all GHC extensions except Template Haskell
Uses standard Haskell libraries
Cabal integration
Simple, one-step build; no need for error prone Rube Goldberg machines of
Vagrant, VirtualBox, GHC sources and other black magic
Concurrency and MVars with Haste.Concurrent
Unboxed arrays, ByteArrays, StableNames and other low level features
Low-level DOM base library
Easy integration with Google's Closure compiler
Works on Windows, GNU/Linux and Mac OS X
Installation
You have three options for getting Haste: installing from Hackage, from
Github or from one of the pre-built
binary packages.
In the first two cases, you need to add add Cabal's bin directory, usually
~/.cabal/bin, to your $PATH if you haven't already done so.
When installing from the Mac, portable Windows or generic Linux package,
you may want to add path/to/haste-compiler/bin to your $PATH.
The Debian package as well as the Windows installer and the optional
install script included in the generic Linux package
take care of this automatically.
Or, you can install the latest stable version from Hackage:
$ cabal install haste-compiler
$ haste-boot
Building from Github source is equally easy. After checking out the source,
cd to the source tree and run:
$ cabal install
$ haste-boot --force --local
Alternatively, you may also build from Github source using Stack:
$ stack install
$ haste-boot --force --local
See doc/building.md for more information about build requirements and
procedures for the various platforms.
If you are having problems with the haste-cabal installed by haste-boot,
you can try building it from scratch and then passing the --no-haste-cabal
flag to haste-boot:
$ git clone https://github.com/valderman/cabal.git
$ cd cabal && git checkout haste-cabal
$ cd Cabal && cabal install
$ cd ../cabal-install && cabal install
When installing Haste from GitHub, you should probably run the test suite first,
to verify that everything is working. To do that, execute
./runtests.sh in the Haste root directory. You may also run only a particular
test by executing ./runtests.sh NameOfTest. The test suite uses the nodejs
interpreter by default, but this may be modified by setting the JS environment
variable as such: JS=other-js-interpreter ./runtests.sh. Other JavaScript
interpreters may or may not work. runtests.sh isn’t downloaded when installing
from Hackage. You would have to download it from GitHub.
To build the patched Closure compiler used when compiling using --opt-minify,
get the Closure source, apply patches/closure-argument-removal.patch and
build it as you normally would. This is not usually necessary however,
as haste-boot fetches a pre-compiled Closure binary when run.
For more detailed build instructions, see doc/building.md.
Haste has been tested to work on Windows and OSX platforms, but is primarily
developed on GNU/Linux. As such, running on a GNU/Linux platform will likely
get you less bugs.
Usage
To compile your Haskell program to a JavaScript blob ready to be included in an
HTML document or run using a command line interpreter:
$ hastec myprog.hs
This is equivalent to calling ghc --make myprog.hs; Main.main will be called
as soon as the JS blob has finished loading.
You can pass the same flags to hastec as you'd normally pass to GHC:
$ hastec -O2 -fglasgow-exts myprog.hs
Haste also has its own set of command line arguments. Invoke it with --help
to read more about them. In particular --opt-all, --opt-minify,
--start and --with-js should be fairly interesting.
If you want your package to compile with both Haste and, say, GHC, you might
want to use the CPP extension for conditional compilation. Haste defines the
preprocessor symbol __HASTE__ in all modules it compiles. This symbol may
also be used to differentiate between Haste versions, since it is defined
as an integer representation of the current Haste version. Its format is
MAJOR*10 000 + MINOR*100 + MICRO. Version 1.2.3 would thus be represented as
10203, and 0.4.3 as 403.
Haste also comes with wrappers for cabal and ghc-pkg, named haste-cabal and
haste-pkg respectively. You can use them to install packages just as you would
with vanilla GHC and cabal:
$ haste-cabal install mtl
Finally, you can interact with JavaScript code using the Haste.Foreign
module in the bundled haste-lib library.
See doc/js-externals.txt for more information about that.
This library also contains all sorts of functionality for DOM manipulation,
event handling, preemptive multitasking, canvas graphics, native JS
string manipulation, etc.
For more information on how Haste works, see
the Haste Report,
though beware that parts of Haste may have changed quite a bit.
You should also have a look at the documentation and/or source code for
haste-lib, which resides in the libraries/haste-lib directory, and the
small programs in the examples directory, to get started.
Interfacing with JavaScript
When writing programs you will probably want to use some native JavaScript
in your program; bindings to native libraries, for instance.
The preferred way of doing this is the Haste.Foreign module:
{-# LANGUAGE OverloadedStrings #-}
import Haste.Foreign
addTwo :: Int -> Int -> IO Int
addTwo = ffi "(function(x, y) {return x + y;})"
The ffi function is a little bit safer than the GHC FFI in that it enforces
some type invariants on values returned from JS, and is more convenient.
Performance-wise, it is roughly as fast as the GHC FFI except for complex types
(lists, records, etc.) where it is an order of magnitude faster.
If you do not feel comfortable throwing out your entire legacy JavaScript
code base, you can export selected functions from your Haste program and call
them from JavaScript:
fun.hs:
{-# LANGUAGE OverloadedStrings #-}
import Haste.Foreign
import Haste.Prim (toJSStr)
fun :: Int -> String -> IO String
fun n s = return $ "The number is " ++ show n ++ " and the string is " ++ s
main = do
export "fun" fun
legacy.js:
function mymain() {
console.log(Haste.fun(42, "hello"));
}
fun.hs will export the function fun when its main function is run.
Our JavaScript obviously needs to run after that, so we create our "real" main
function in legacy.js. Finally, we tell the compiler to start the program by
first executing Haste's main function (the $HASTE_MAIN gets replaced by
whatever name the compiler chooses for the Haste main) and then executing
our own mymain.
The mechanics of Haste.Foreign are described in detail in this
paper.
Effortless type-safe client-server communication
Using the framework from the Haste.App module hierarchy, you can easily write
web applications that communicate with a server without having to write a
single line of AJAX/WebSockets/whatever. Best of all: it's completely type
safe.
In essence, you write your web application as a single program - no more forced
separation of your client and server code. You then compile your program once
using Haste and once using GHC, and the two compilers will magically generate
client and server code respectively.
You will need to have the same libraries installed with both Haste and vanilla
GHC (unless you use conditional compilation to get around this).
haste-compiler comes bundled with all of haste-lib, so you
only need to concern yourself with this if you're using third party libraries.
You will also need a web server, to serve your HTML and JS files; the binary
generated by the native compilation pass only communicates with the client part
using WebSockets and does not serve any files on its own.
Examples of Haste.App in action is available in examples/haste-app and
examples/chatbox.
For more information about how exactly this works, see this
paper.
Base library and documentation
You can build your own set of docs for haste-lib by running
cabal haddock in the Haste base directory as with any other package.
Haste is able to use standard Haskell libraries. However, some primitive
operations are still not implemented which means that any code making use
of them will give you a compiler warning, then die at runtime with an angry
error. Some libraries also depend on external C code - if you wish to use such
a library, you will need to port the C bits to JavaScript yourself (perhaps
using Emscripten) and link them into your program using --with-js.
Known issues
Not all GHC primops are implemented; if you encounter an unimplemented
primop, please report it together with a small test case that demonstrates
the problem.
Template Haskell is still broken.
Generated code is not compatible with the vanilla Closure compiler's
ADVANCED_OPTIMIZATIONS, as it is not guaranteed to preserve
Function.length.
haste-boot bundles a compatibility patched version of Closure which does
preserve this property. Invoking hastec with the --opt-minify option
will use this patched version to minify the generated code with advanced
optimizations.
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