NOTE:
This is just an example of extending the Reader -
it's not meant to be practical.
String
interpolation is a convenient language feature which makes creating
human-readable strings that contain variables easier. The classical approach
to this in languages without string interpolation is something like printf
- a function which accepts a format string and a variable number of
arguments. The format string contains special sequences of characters which
get replaced with the values of passed arguments, like this:
printf("An error occured at %s:%d.","file-name.c",42);// Displays: An error occured at file-name.c:42.
This has various problems, for example the possibility to supply more (or
fewer) arguments than expected. String interpolation allows you to embed
variables directly into the format string:
LINE=42FILE="file-name.c"echo"An error occured at $FILE:$LINE."
As with many features, some languages provide string interpolation and some
don't. In the dark and troubled past of JavaScript, for example, some people
switched to CoffeeScript for its string interpolation support (among other
things.) More recently, string interpolation came to Python in the form of
f-strings (PEP-498)
and to plain JavaScript in the form
of template
literals (supported
by Babel
and other transpilers). While the feature is most often associated with
dynamic, dynamically typed languages, some statically typed ones, for
example C#
and Swift,
also support it, so it's not exclusive to the former.
Help! No string interpolation in Racket!
Racket - like JS at one point - lacks the string interpolation support. If
Racket was JS, the only options would be to either write a transpiler, or
switch to another language. Both choices normally require a lot of work, so
developers tend to learn to live without the feature instead and move on.
But Racket is not JS, it's a Lisp. All Lisps
are programmable programming languages[1], but Racket takes it up to eleven
with the multidute of tools for language extension (and creation)[2]. How
much work would it be to make Racket interpolate strings?
How Racket processes code
To process any code, Racket performs these steps:
reading - accomplished by two functions, read and
read-syntax, reading means taking a string and returning an
AST[3] (which
happens to be a normal list with normal symbols, strings, numbers, etc.
Such a list can be wrapped with a syntax object, which adds some
meta-data to the raw list. You can always get a raw list out of syntax
object with syntax->datum).
expansion - all the special forms and macros in the read
code are expanded until only the most basic forms (modules, function
applications, value literals) are left.
compilation - Racket performs byte-code compilation on the expanded
code. This is where most of the optimizations are applied.
execution - compiled byte-code is handed to the VM for execution. At this
stage, on some architectures, further JIT compilation happens, turning
(possibly portions of) bytecode into native code.
The first two steps are completely customizable: code expansion
with macros,
and code reading via hooks into the
Racket parser
(you can also write a new parser from scratch (or generate it) if you want,
but frequently it's not necessary). Symbolically, what happens during
reading and expansion can be presented[4]
like this:
Extending the parser
The Racket parser is a simple, recursive-descent one and it works by
utilizing a readtable - a mapping from characters to functions responsible
for parsing what follows the given character. The read and read-syntax
functions utilize current-readtable, which is
a parameter
you can override. Adding a new syntax to the reader requires just three
steps:
create a function for parsing the new syntax into valid Racket forms
get the current-readtable and add your function to it
make that expanded readtable from the prev step the new current-readtable
Interpolated string syntax
We'll get to writing the parsing function in a minute, but first we need to
know what is it we're going to parse and what the results of the parsing
should be. The exact syntax I have in mind would look like this (with #@
distinguishing interpolated strings from normal ones):
"An error occured at #{file}:#{line}."# would be compiled to:"An error occured at "+file+":"+line+"."
In Racket we have no + operator for concatenating the strings and even if
we did have it, the prefix notation and resulting nesting wouldn't be
pretty. The easier and more natural way is to use a string-append
procedure, which - conveniently - accepts any number of arguments. The
syntax introduced in the previous section would compile down to something
like this:
(define(parsestr);; Assume that @{} cannot be nested and that the braces are always matched.;; Obviously, in a real parsing function, these assumptions would need to be validated.(definelst(regexp-split#rx"@{"str));; After splitting we have a list like this: '("An error occured at " "file}: " "line}.");; We'll go over it, building a list of expressions to be passed to string-append as we go.(definechunks(for/fold([result'()])([chunk(restlst)]); we don't need the first element here(let*;; convert a string into a port([is(open-input-stringchunk)];; call original read to get the expression from inside brackets[form(readis)];; read what remains in the port back into a string[after-form(port->stringis)];; drop the closing brace[after-brace(substringafter-form(add1(s-index-ofafter-form"}")))]);; ~a is a generic "toString" function in Racket(appendresult`((~a,form),after-brace)))));; chunks now looks like this: ((~a file) ":" (~a line) ".")`(string-append,(firstlst),@chunks))
It's dead simple - just a couple of lines - and it glosses over important
details, like the possibility of nesting the @{} expressions and syntax
errors handling, but it works for the simple cases. We can easily test it,
like this:
(parse"An error occured at @{file}:@{line}.");; Returns:'(string-append"An error occured at "(~afile)":"(~aline)".");; which is exactly what we wanted!
The boilerplate code
The hard part ends here - the rest is just some boilerplate we need to make
Racket aware of our extension to its reader. In Racket, this is often done
by defining a new language - working with #lang lang-name syntax, but in
our case we don't need (or want) to create a whole language (it's simpler
than it sounds, but it's still a bit more work) - we just change the reader
and can reuse everything else from some other language.
For situations like these, Racket supports a special syntax to
its #lang line, which looks like this:
#lang reader<reader-implementation-module><language-the-reader-will-be-used-with>;; for example:#lang reader"reader.rkt"racket
Generating a reader module
Let's first define reader.rkt. Writing a whole new reader is of course
an option but it's a lot of unnecessary work, as the generic read and
read-syntax[5] need to handle some more complex things, like
module declarations, which we don't care about. Instead, we can use a
special language for defining readers, which will generate appropriate
read and read-syntax implementations for us provided we supply a single
function to it:
The #:language option takes a function which accepts a string (of what
remains after the reader module name on the #lang line) and returns a
language name to use. A simple read happens to work here.
The #:wrapper1 option takes a function, which takes another function as
input and returns the parsed code. The passed in function, when invoked,
performs normal read.
Extending and installing a readtable
With #:wrapper1 option, in conjunction with parameterize, it's very easy
to install our readtable[6]:
(define(wrap-readdo-read)(definert(make-readtable(current-readtable);; register our function to be called when #@ is encountered#\@'dispatch-macro;; name of the function to be calledread-str))(parameterize([current-readtablert])(do-read)))
Wrapping parse so that it works inside readtable
The only part missing is a read-str function, which is a bit more
complicated. The function passed to make-readtable may be called in two
different ways, depending on whether it's used from inside read or
read-syntax. The function distinguishes the cases based on a number of
arguments it gets, and returns either syntax object or a simple list
depending on the case. Here's its implementation:
(defineread-str(case-lambda[(chinsrclinecolpos);; The caller wants a syntax object. The current position of the `in` port;; is just after the #@ characters, before the opening quote.(let*;; Here we read the next expression (which we assume is a string)([literal-string(readin)]);; then we parse the contents of the string and return the result,;; wrapped in a new syntax object. The `in` port is now just after the;; closing quote and the parser continues from there.(datum->syntax#f(parseliteral-string)))][(chin);; The caller wants a simple list. Let's parse the input into syntax and;; transform to a list (this saves as writing the same code twice).(syntax->datum(read-syntax#fin))]))))
#lang reader"reader.rkt"racket(defineline42)(definefile"file-name.rkt")(displayln#@"An error occured at @{file}:@{line}.");; Displays: An error occured at file-name.rkt:42.
It also works for more complex expressions out of the box:
#lang reader"reader.rkt"racket(requireracket/date)(displayln#@"Current date&time: @{(date->string (current-date) #t)}");; Displays: Current date&time: Friday, April 28th, 2017 7:57:11pm
This is of course a pretty basic as far as string interpolation features go,
but it took thirty (34 to be precise) lines of code (excluding comments) to
build it. Adding another twenty lines would be enough to implement error
checking, and using one of the parser generators could even shorten the
code.
That's it!
Aside from how easy it is to extend Racket syntax one thing deserves a
mention. That is, such syntax extensions are easily composable (as long as
they don't want to install extensions to the same entry in the readtable) -
you can load them one by one, each extending the readtable.
The language extension and creation tools of Racket don't end there. Robust
module system with support for exporting syntax extensions, powerful
syntax-parse,
traditional syntax-rules and syntax-case,
many tools for generating parsers
and lexers -
all these features are geared towards meta-lingustic programming. Racket is
a programming language laboratory and allows you to bend it to better suit
your needs safely (ie. ensuring that only your code will be affected). Very
few languages or transpilers offer that much freedom with that kind of
safety guarantees.
It's an ideal environment for people who know what they need from their
language - with Racket you're never stuck, waiting for the
next release to support some feature. On the other hand, despite there being
a great many helpers and libraries, you need to know at least some basics of
programming language creation to do this yourself. The good news is that the
extensions written by others are easily installable with a single command of
a Racket package manager.
Addendum: doing the same without messing with the reader
A commenter on Hacker News provided an interesting solution using normal
macros only. Turns out there's a special macro, called #%datum, which gets
wrapped around every literal in the code (when the code is read). By default
it's a noop, but we can override it with arbitrary logic. In this solution
there's no need for marking strings for interpolation: all strings are
interpolate-able by default. Here's the implementation:
I don't have the time to go over this line by line and explain it right now,
but it's possible I'll write another post featuring this solution in the
future.
The quote comes from Paul
Graham's famous book and
is attributed to John Foderaro. ↵
A good
starting point for learning more would be Racket
is ... article by Matthias Felleisen. At least I assume it's his -
it's not signed, but clearly in Matthias home directory ;) ↵
Any module, which exports these two functions, can be used
as a reader. ↵
In the actual source code the (make-readtable ...)
part is extracted into separate procedure, which makes it easier to compose
this syntax extension with others. ↵
Most programming languages are created with some goals in mind, which the new language tries to meet. Over time, the goals may (but don't have to) shift as languages evolve. Either way, knowing current goals and history of a language should make understanding the bad and good sides of the language easier. I prepared a short introduction to both Clojure and Racket, before getting to the main issue in the following posts.
Racket: in the beginning, there was (PLT) Scheme
Racket started its life in 1994, as an implementation of Scheme language[1]. Scheme is a rather minimal Lisp-1[2] dialect popular with Programming Languages researchers, Computer Science professors, and teachers because of its simplicity and elegance.
Matthias Felleisen initially created a research group with a goal of providing better teaching material for novice programmers. The group was called PLT, and after deciding to write a new language as part of their efforts, they decided to base it on Scheme, creating first versions of PLT Scheme. The initial goal was consequently pursued for many years, resulting in a couple of books and many papers, but there were other groups of users of the Scheme - the language proved to be a good platform for implementing novel PL concepts, so researchers took a liking to it. From that point, the design and implementation of what would become Racket tried to meet the two goals: to be a beginner-friendly pedagogical environment and to be a powerful, easily extendable general purpose language.
On the one hand, Racket included delimited continuations[3], more powerful macro systems[4] and soft typing and eventually statically typed dialect[5] were implemented in Racket, improving both the language and the state of research. On the other hand, the need for more beginner-friendly language features focused on making teaching and learning on different levels easier, resulted in a graphical IDE and support for restricted and contracted[6] subsets of the primary language. Between the two extremes was the often overlooked rest - a natively-looking, cross-platform GUI toolkit (used to write Racket's IDE), a lot of utility libraries distributed via a central repository[7] and the infrastructure like the JIT compiler, garbage collector and so on.
PLT Scheme changed its name to Racket sometime around 2010, when it became apparent that it evolved way past the Scheme specification and showed no signs of stopping its further development and evolution. Current Racket is a product of seven more years of cutting-edge language research, teaching material preparation[8], adding requested features and abstractions and implementing even more libraries.
If it sounds like a kitchen sink, that's because it is. Some parts of Racket are explicitly designed, but some others evolved on their own. When meeting all the challenges during the years Racket not only added tools for dealing with them but also perfected the meta-tools to create the tools, which made it into a perfect kitchen sink: one where implementing new linguistic features is not only possible but easy by design.
Clojure: quite a different story
Rich Hickey wanted a simple, powerful and successful Lisp for a long time. During the 00's such a Lisp arguably didn't exist. Common Lisp was in a decline which started a decade earlier[9]. Scheme was impractical (because of problems with portability between implementations, also Scheme's minimalist approach to stdlib didn't help). Other Lisps - other than the embedded ones, like Emacs Lisp or a dialect used in AutoCAD - hardly had any following at all.
Before writing Clojure, Rich was familiar with Common Lisp and tried integrating CL with Java on a couple of occasions, but ultimately decided to create an entirely new Lisp, using JVM as a runtime environment. His goals were: symbiotic relation with the hosting platform, Functional Programming, and concurrency. FP and concurrency implied immutability: almost all native data structures in Clojure are immutable and persistent[10], and the mutable ones only allow mutation in certain, safeguarded contexts. The desire for expressive power resulted in an extended syntax, used for data structure literals and pattern matching[11] and dereferencing shortcuts. The standard library is not too big because Clojure can use all of the Java stdlib directly; the largest part of the library are functions for dealing with collections, which are an abstraction similar to iterable in Python. The four basic data structures - string, vector, set and map - are all collections and may be operated by the same set of functions.
In the first couple of years after launch, Clojure marketing was focused on Java interop and concurrency. Clojure indeed offered a lot of options for safe concurrency and safe parallelism (leveraging JVM threads and other constructs, but hiding them behind novel APIs) and was definitely more productive than Java (but comparable to Groovy or Jython, I think). It was quickly recognized as a language well suited for server-side web development. Later, when ClojureScript appeared[12], Clojure steered even more towards web development, now promising performant servers and almost effort-free (i.e., reusing the server-side code) frontend. It didn't work that well at first: ClojureScript was lacking features and Clojure to ClojureScript interop wasn't easy to setup. Things improved over the years, and in 2015, according to Wikipedia, 66% of surveyed Clojure users also used ClojureScript.
Over the years, the language became one driven by the community, with Rich serving as its BDFL, analogous to Python's Guido van Rossum. The community produces new versions of the language in 1-2 year spans; the new features are generally few in number, but powerful, with a broad impact on how the code is supposed to be written[13]. The tooling and library ecosystem, initially dependent on Java, also improved and matured over the years, resulting - among other things - in a good build tool and package manager[14]. The core language remained relatively small and focused, but its expressivity allowed for many features to be added as libraries.
Cross-pollination and differences
As both languages were rapidly evolving around the same time (and still being developed), some features from one language were implemented in the other. For example, in Clojure, core.typed is based on TypedRacket, while Racket sequences idea is suspiciously similar to Clojure's collections (especially when using a helper library, because in stdlib support for sequences is very basic).
That doesn't really make the languages similar, though - they are based on completely different philosophies and were developed very differently. Honestly, I'm tempted to say that Lispiness-1 of the dialects is the only thing they have in common (I'm exaggerating a bit): they offer similar functionality but deliver it in different ways, and the general feel of using them is very different.
Of course, how the language feels when used is entirely subjective, but language designers and developers often optimize languages to "feel natural" or "feel right," and language users often evaluate them based on this vague notion. That is to say: even if two languages are technically equivalent, if they "feel" different, they attract different users, cover different use-cases and specialize in different things.
The differences between Racket and Clojure are just enough to make it worth learning both of them, I think... But, well, as a programming languages nerd I may be a bit biased. Still, it's worth seeing at least some of the capabilities and features they provide - I plan to present a few of them in the third post in the series. But before that, in the next post, I'll tell you how and why my work on a Clojure-based project was a nightmare.
See RnRS for an official definition of Scheme. The newest Report is in this document↵
See this document for an in-depth explanation of what that means. ↵
Apparently, I can't directly upgrade to whichever version I choose, I need
to go one by one, doing fedora-upgrade and rebooting in a loop as needed.
I realize that my case is somewhat extreme, but watching the same set of
packages getting downloaded five times (~640MB each time) feels wrong
somehow.
The good news are that the upgrade took its time, but in the end finished
successfully. Quite a feat for that large defference in versions: default
package manager and system upgrade tools changed in the meantime, but still
managed to produce a working system with minimal fuss.
Damn, I'm getting back to Linux as fast as I find a decent laptop; working
on Mac OS - although, with effort, made vaguely ok - is tiring as I need to
cope with all the "oh, it doesn't work that way here" moments...
As you can probably guess with a quick glance, this blog is self-hosted by
me and is a result of "static page generation", which means there's a bunch
of files and a few scripts which output all the needed HTML/CSS/JS to run
the site, you just upload it to the server and you're done. This approach is
very popular lately and many bloggers do the same.
One - slightly - unusual bit is that I wrote all of the generators and
scripts myself, from scratch (using mainly Python). This means,
among other things, that I have no pile of already written plugins or
modules I could resort to in case I found my generator lacks an important
feature...
For a long time I was pretty much the only user of both the generator and
the blog, so I didn't mind. Recently, though, quite a few people who
said they'd like to read my next post (my prospective
readers! Finally, after four years, I have a chance to get my very own
readers! ...err, sorry, got a bit too happy there for a moment...) suggested
adding RSS feed to the blog.
I had known nothing about RSS and it took a couple of hours, but I finally
added RSS feed generation to my scripts. Now every time I publish a post, a
new /statics/feed.xml gets
generated and, hopefuly, every subscriber will be notified![1] Even better, you will be even notified
about post updates (probably)!
Thank you! (Or: Rkt vs. Clj is comming!)
Ok, so I know simply adding RSS feed is hardly important enough to write a
post about it, so here is the other part: thank you very much! All of you
who upvoted my comment on Hacker News or even sent
me an email - only to encourage me to write the promised post,
thank you. It's thanks to you that I got motivated enough to finally start
writing that post about Clojure and Racket comparison.
Please stay tuned and be patient: it's a lot of work, especially
because I want to stay as fair as possible and give as many
detailed examples as possible (without copyright-related problems).
So, once again, thank you for expressing your interest in my future post and
please stay patient while waiting for me to finish; I'll try my best, on my
part, to write it all well and on time!
Let me know if
it doesn't work for you or your reader! I don't know much about RSS and
could have messed up). ↵
I worked on a Web project in Clojure and saw how frontend/JS devs
had a hard time adjusting to the syntax. Here is a breakdown of which
tools I find essential for editing lisps as well as a list of possible
tool suites (IDEs with plugins, standalone editors, etc.).
NOTE:
When first starting to use Clojure,
get Nightcode. The experience
is going to be much better.
It's normal, I think, to get overwhelmed by the sheer amount of parens you
need to manage when learning a Lisp. When taken on its own, the syntax
really is simple, but introducing another strange thing on top of already
unfamiliar concepts doesn't help learning.
Some people will tell you that you will "get used to it" soon enough and
that it's just a matter of practice. While there is some truth to these
claims, I'm a pragmatist and so I prefer another approach: simply set up a
decent environment for working with Lisp before you begin. There are many
tools which make reading and writing Lisp code much easier: you need to
either configure your editor to enable them or change the editor. There are
some Clojure-specific editors out there, you can simply use one of them (my
thoughts on them below).
Main things/features useful when working with Lisps:
syntax highlighting for your Lisp (obviously!)
automatic indentation (and re-indent) for your Lisp
ability to highlight matching paren
ability to jump to matching paren
configurable syntax coloring and/or rainbow-style coloring of parens
"Go to definition..." is good to have, but you can usually make do with
grep or "Find in files..." editor command
See the screenshots and a video for visual demonstration of what I'm talking
about (click on the image to get a bigger version):
Also see here for a
very good general introduction to editing Lisp along with explanation of
what Parinfer is.
Clojure specific editors
After writing the above I realized that it would be good to give a couple of
examples of beginner-friendly editors, which implement the features
mentioned above. To my surprise there are some editors which target Clojure,
some of them even maintained. Here's a short summary of what I found out:
Nightcode
- I only played with it a little but I'm impressed at what it can do. I
tried using parinfer some time back and it is much friendlier and easier to
use than Paredit[2]. In short: you never need to worry about parens when
using Nightcode. Place a cursor where you need it and start typing: the
parens will magically appear. It worked out of the box for me on Mac,
however it refused to run on Fedora.
Clooj
- inactive since 2012, has nearly none of the useful features, looks ugly
and is slow. Forget it.
LightTable - supports
many things mentioned above as plugins, but they tend to be disabled by
default and enabling them is not as easy as it should be. The plugin-based
architecture makes it interesting for polyglot projects, but it needs some
configuration to get started and Nightcode needs none.
Cursive - a Clojure
plugin for IntelliJ IDEA from JetBrains. I don't have any of their IDEs
installed and so I didn't try it. Its feature list looks decent, though, so
if you like IntelliJ this may be the best option for you.
Emacs
and CIDER
- that's what I use. I'd recommend you to only try this route if you already
know some Emacs, otherwise it's going to be frustrating for a good while
until you internalize all the strange names and such. CIDER itself is great,
though, and integgrates with Leiningen, offers inline code evaluation,
auto-completion, connecting to a running REPL and so on.
In short: give Nightcode a try if you can, otherwise use a Lisp/Clojure
plugins for your current editor, like Sublime, IntelliJ or Eclipse. Come
over to Emacs side once you get bored with those.
A full "IntelliSense" - context
aware auto-completion - is always nice to have, but you can live without
it. For a while. ↵
I stick with Paredit because I already got used
to it and am efficient enough with it; I'd go for parienfer had I started
learning about Lisps now. ↵
I gave a talk on 15.03 about polyglot programming, based on the example
project I wrote some time before. The project was a web scraper, with
downloading part written in Elixir and processing part written in Python.
One thing I'd like to add is that I don't trust OpenRESTY as an app platform
yet. The project is being actively developed and the author writes tons of
good code, but he is but a single man. This means there is severe lack of
tools and libraries in the ecosystem: they simply don't exist yet.
On the other hand, OpenRESTY is a painless way to script Nginx with Lua and
that's something you can do with just the modules provided by OpenRESTY.
Being able to communicate asynchronously with anything (literally: anything
that wants to talk over sockets), including databases, external services and
so on, is very nice thing indeed.
There's one caveat though, which is that you can't use any blocking
(non-async) constructs, which includes using normal Lua sockets. This is not
the problem in your code, but if you happen to need a Lua library which
comes as a C extension, and if the functions in the library block, you will
probably need to fix the C code. At this point it's purely theoretical,
because I didn't encounter any such library yet.
In short: it's about me exploring - or at least getting into contact with -
a couple of interesting things:
X Window System APIs via Xlib bindings
low-level Linux APIs for elevating privilages, checking passwords
GCC options and some C
and of course the Nim language
Introduction
At my work we strongly discourage leaving logged-in accounts and/or unlocked
screens of computers. I happen to agree that locking your computer is a good
habit to have, so I've had no problems with this rule... Up to the point when I
switched from KDE to StumpWM (I wrote about it some time ago,
in this,
this
and this posts) and my
trusty Ctrl + Alt + L stopped working.
The only idea that came to my mind was to use the
venerable xscreensaver, but:
a) I didn't really need any of the 200+ animations (I just
wanted a blank screen) and b) I didn't like how the unlock
dialog looked like[1].
XScreenSaver and its dialog straight from the 80ties.
I needed something more lightweight (xscreensaver is ~30k loc of C[2]), simpler and either better looking or without any
UI altogether.
slock to the rescue
There's a site called suckless.org where
you can find some impressively clean and simple tools, implemented mostly in
C. You can read more about their philosophy
here, which I recommend as an
eye opening experience. Anyway, among the tools being developed there, there
is also slock - a very simple
and basic screen locker for X. It's 310 lines of code long and it's all
pretty straightforward C.
The program suited my needs very well: minimal, fast, and good looking.
Well, the last part it got through cheating, as slock simply has no
interface at all - but this means there's no ugly unlock dialog, so it's all
good.
Why Nim?
As I used slock I read through its code a couple of times. It seemed simple
and learnable, despite the fact that I knew nothing about X and didn't use C
seriously in 15 years. Fast forward to last week and I finally found some
free time and decided to learn some Xlib stuff. Re-implementing slock in
Nim looked like a good way of learning it: this may sound a bit extreme, but
it allowed me to gain exp points in two stats
simultaneously[3] - in Xlib
usage and Nim knowledge!
Nim is a very interesting language. I'd call it "unorthodox" - not yet
radical, like Lisp or Smalltalk, but also not exactly aligned with Java and
the like. For one tiny example: return statement in functions is optional
and if omitted, a function returns its last expression's value. That's
rather normal way to go about it; hovewer, in Nim you can also use a special
variable name result and assign to it to have the assigned thing returned.
It looks like this:
It's practically an idiom, a very common construct. Nim takes this idiom,
adds some sugar, adapts it to the world of static typing and includes in the
language itself. We can translate the above Python to Nim with very minor
changes[4]:
As I said, it's not a groundbreaking feature, but it is nice and
good to have, and it shows that Nim doesn't hesitate much when
choosing language features to include. In effect Nim includes many such
conveniences, which may be seen both as a strength and as a weakness. While
it makes common tasks very easy, it also makes Nim a larger language than
some others. It's not bad in itself, rather, depending on how well the
features fit together it's harder or easier to remember and use them all.
Nim manages well in this area, and also it most definitely is not
like C++ with its backwards compatibility problem, so I think even
Pythonistas with taste for minimalism will be able to work with Nim.
Being Nimble - the project setup
Many modern languages include some kind of task runner and package manager
either as part of stadard distribution or as downloadable packages. Nim
has Nimble, which takes
care of installing, creating and publishing Nim packages. Assumming that you
have Nim already installed[5], you can
install Nimble with:
$ git clone https://github.com/nim-lang/nimble.git
$ cd nimble
$ git clone -b v0.13.0 --depth 1 https://github.com/nim-lang/nim vendor/nim
$ nim c -r src/nimble install
$ exportPATH="$PATH:~/.nimble/bin/"
Note the addition to the PATH variable: ~/.nimble/bin/ is where Nimble
installed itself and where it will place other binaries it installs. Make
sure to have this directory in your PATH before working with nimble.
$ mkdir slock
$ cd slock
$ nimble init
In order to initialise a new Nimble package, I will need to ask you
some questions. Default values are shown in square brackets, press
enter to use them.
Enter package name [slock]:
Enter intial version of package [0.1.0]:
Enter your name [Piotr Klibert]:
Enter package description: Simplest possible screen locker for X
Enter package license [MIT]:
Enter lowest supported Nim version [0.13.0]:
$ ls
total 4.0K
-rw-rw-r--. 1 cji cji 18813/02/2016 01:02 slock.nimble
$ cat slock.nimble
# Packageversion="0.1.0"author="Piotr Klibert"description="Simplest possible screen locker for X"license="MIT"# Dependencies requires "nim >= 0.13.0" $ mkdir src
$ touch src/slock.nim
The generated slock.nimble is a configuration file
for Nimble; it's written in a
NimScript, which looks like
a very recent development in Nim and it replaces the
previous INI-style config files. This means that many examples and tutorials
on the Internet won't work with this format. The most important
difference is the format of dependencies list for your app: it now has to be
a seq. For example, to add x11
library to the project:
The dependencies should be downloaded by Nimble automatically, but you can
also dowload them manually, like in the example below. You'll notice that I
also install a c2nim package
- I will say more about it later.
$ nimble install c2nim x11
Searching in "official" package list...
Downloading https://github.com/nim-lang/c2nim into /tmp/nimble_18934/githubcom_nimlangc2nim using git...
Cloning into '/tmp/nimble_18934/githubcom_nimlangc2nim'...
...etc, etc, etc...
Workflow and tooling
Nim is a compiled language, but working with it proved to be comparable to
working with a dynamic language, mainly thanks to type inference and
blazingly fast compiler. You dcan ommit type declarations where they are
obvious from the context and Nim will deduce the correct type for you. It's
not a full program type inference like in OCaml, but rather a local type
inference as used in Scala or modern C++ or Java. Even with this limitation
it's immensely useful and reduces code verbosity by a lot.
Compiler speed is important, because it encourages frequent testing. If
compilation is going to take a long time you tend to "batch" changes in your
code together and only compile and run once in a while instead of after
every single change. This, in turn, makes it harder to find and fix
regressions if they appear. Dynamic languages work around this issue by
rejecting compilation step completely, at the cost of run-time safety and
performance. Nim - which is similar to Go in this respect - makes
compilation effortless and nearly invisible. The command for compile-and-run
looks like this:
$ nimble build && sudo ./slock
# or, if you need to pass some additional parameters to Nim compiler: $ nimble c --dynlibOverride:crypt --opt:size --passL:"-lcrypt" -d:release src/slock.nim -o:./slock && sudo ./slock
While Nim's compiler and Nimble are very good tools, they're not enough to
work comfortably on more complex codebases. Nim acknowledges this and
provides a couple of additional tools for working with code,
like nimsuggest.
However, nimsuggest is rather new and it SEGFAULTed on me a
couple of times[6]. I used it via - of course - Emacs
with nim-mode, and again,
I encountered a couple of irritating bugs, frequent "Mismatched parens"
errors when trying to jump a word or expression forward. However,
when nimsuggest works, it does a good job, particularly its "Go
to definition" feature works and is very helpful.
Nim's definitive source of documentation is The Index, which does a
surprisingly well as a reference. Ctrl + f works just as well as search
boxes other documentation sites provide. Nim docs are also nice in that they
link to the source: you get a link to the function implementation beside its
documentation. I like this trend and I'm happy that more documentation is
like this - a quick peek at the source can sometimes save hours of unneeded
work.
In this project, I had to work with Xlib and turns out its
documented in man pages, and the pages were already installed on my system.
I don't remember installing them, so maybe they come with X by default on
Fedora. Anyway, for Xlib tutorial I used Xlib Programming Manual and for
reference I simply used the man pages: just type, for example, man
XFreePixmap and you get XCreatePixmap (3) man
page. The same is true for Linux/POSIX functions - try, for example,
man getpwuid.
That's it, for now
In the next part I'm going to show some Nim code, translated - both manually
and automatically - from C. I'll focus on Nim's language features that C
doesn't have and I'll show how they can be used to write shorter, safer and
more readable code. In the later, last part I'm going to write about Nim's
interop with C and various ways of connecting the two, using
Xlib as an example.
And it seems that JWZ doesn't like people modifying the
looks of this dialog, so I didn't even try. ↵
Every power
gamer will understand how nice this is! ↵
But note the lack of unnecessary return statement in Nim. ↵
I recommend installing from GitHub - it's always
good to have the sources for your compiler and stdlib around, and you won't
get it if you install just the binaries. And master branch is stable:
checkout devel branch for the in-development code. ↵
This might be because of my own incompetence, of course. ↵
Recently I was writing a little set of scripts for downloading and
analyzing manga meta-data, for use with my Machine Learning pet project.
True to a polyglot style, the scripts were written in two languages:
Python and Elixir. Elixir is a language that works on Erlang VM (see my
previous blog post on
it, Weekend with Elixir)
and Python doesn't need any introductions I think. I used Elixir for
network related stuff, and Python with pandas for analysis.
The biggest problem with such a setup (and with polyglot approach) is
passing the data around between the languages. At first I just used a
couple of temporary JSON files, but then I remembered a project I once
saw, called ErlPort, which is a Python
implementation of the Slang's external term protocol. In short, it
enables seamless integration between Python and Erlang and - by
extension - Elixir. ErlPort not only lets you serialize data, but lets
you also call functions across language boundaries. It also supports
Ruby besides Python.
In general, using ErlPort was a success in my case, but it's limited as
it can only connect three languages. I'd normally say it's good
enough and leave it, but a couple of days later, in "the best of
Python lib of 2015" thread on HN, I discovered another project called
python-bond,
which provides similar interoperability features for Python
and three more languages: PHP, Perl, JavaScript. The
two libraries - ErlPort and python-bond - make it embarrassingly easy to
integrate a couple of different languages in a Python project. Along
with Cython, which lets you easily call C-level functions, it makes
Python a very good base language for Polyglot projects.
The hardest part with polyglot style, and in particular architecture, is
deciding which language should be a base one, the one which runs and
integrates the rest of the languages. In my case, I ended up with most
of the control flow inside Elixir, because of the very neat supervision
tree feature it provides (thanks to Erlang/OTP). It remains to be seen
if Elixir is capable of filling the role of a main implementation
language in a polyglot project. I'll make sure to write a post about it
in the future.
For a very long time I used normal search to get to a next occurence of
something. However, it wasn't very comfortable. For this to work, I need to:
move point (cursor) to the beginning of a word I'd like to jump to
press C-s
press C-w, more than once if necessary, to copy current word into search box
keep pressing C-s to search for occurences
I found a better way.
iedit is a mode for
Emacs for editing all the occurences of something at once. I alternate
between iedit and multiple-cursors mode when I need to do
something simple to a word in many places in the code. However, iedit
also provides an iedit-next-occurence, which by default is bound to
TAB.
Using iedit I only need to:
move point to anywhere inside a word
press C-; for iedit
press TAB to jump to next and S-TAB (shift + tab) to jump to
previous occurence
One more feature of iedit I find useful sometimes is a
toggle-unmatched-lines-visible command. It duplicates occur mode
functionality a bit, but it hides unmatched lines in your current
buffer. This makes it easy to quickly switch between a
global occurences list and a local occurence context.
So I was playing with Elixir in the last couple of days. I didn't write anything
significant, but I scribbled enough code, I think, to get a feel of the
language. I know Erlang rather well, so I suppose most "pain points" of Elixir
were non-issues for me. I already mastered things like async message passing,
OTP behaviors, as well as pattern matching, recursion as iteration and the like.
Thanks to this I was able to concentrate on Elixir itself, instead of learning
many unfamiliar concepts.
The syntax
One difference from Erlang which is highly visible is syntax. I don't hate
Erlang's syntax; it's small and clean, probably owing to its Prolog roots.
However, it's not like it couldn't be improved. Elixir has completely different
syntax, closer to Ruby than to anything else I know of, but it turns out it
works well.
For Erlangers, some interesting points are:
Dedicated alist syntax. With strict arity enforcement it's common for
functions to accept a list of two-tuples (pairs) as an options list. First
element of the tuple is a key, and the second is its value. It's natural to
recurse and pattern-match over such a structure, so it's used a lot. Elixir
comes with a special syntax for creating these, as long as the key is an atom
(which it almost always is). It looks like this:
[key: val,
key2: val2,
...]
It's just a bit of syntactic sugar, you could equivalently write:
[{:key, val},
{:key2, val},
...]
and it would look similarly in Erlang. The sugared version is easier to read
thanks to reduced number of parentheses, which clutter a non-sugared version.
Elixir syntax is also very consistent, with only a couple of pitfalls you need
to look out for (mainly, a comma before do in statements in alist style).
Every block and every instruction (macro call or special form) follow the same
rules. For example, you can use both abbreviated and normal block syntax
everywhere there is a block required. The syntaxe look like this:
def fun() do
...
end
or you can write it like this:
def fun(), do: (...)
You may get suspicious, as I did, seeing the second form. As it turns out, it's
exactly as you think it is: it's the same syntax sugar that alists use. So, you
can equivalently write:
def fun(), [{:do, val}]
It's nice, because it works uniformly, for every call, as long as the alist is
the last parameter of the call. No matter if it was a macro or function call.
Ruby has this in the form of hashes sugar.
Other syntactic features are much less interesting. For example, in Erlang all
the variables has to begin with upper-case letter, while Elixir reverses this
and makes variables begin with only lower-case letters. This means that atoms
need a : prefix. What's fun is that capitalized identifiers are also special
in Elixir and they are read as atoms (with Elixir. prefix). Things like this
are very easy to get used to. Also, in most situations it's optional to enclose
function arguments in parentheses. You can call zero-arity functions by just
mentioning their name. To get a reference to a function you need to "capture" it
with a &[mod.]func_name/arity construct. It's also easy to get used to, and not that
different from Erlang fun [mod:]func_name/arity.
The module system
Erlang includes a module system for code organization. In Erlang, a module is
always a single file, and the file name must match the module name. Also, the
namespace for modules is flat, which means you can have conflicts if you're not
careful. Elixir does away with the first restriction entirely and works around
the second with a clever hack. You can define many modules inside a single file
and you can nest the modules. It looks like this:
defmodule A do
defmodule B do
...
end
end
Inside the A module you can refer to B simply, but on the outside you have
to use A.B (which is still just a single atom!). Moreover, you can unnest the
modules, too (order of modules doesn't matter):
defmodule A do
end
defmodule A.B do
end
So, the modules are still identified by a simple atom in a flat namespace, but
they give an illusion of being namespaced with a convenient convention. By the
way, it makes calling Elixir code from Erlang not too hard:
'Elixir.A.B':func()
It's not that pretty, but it works well.
The other part of the module system is an ability to export and import
identifiers to the module scope. In Erlang you can do both, but it's limited,
because there is no import ... as ... equivalent, like in Python. Elixir, on
the other hand, provides both an import and alias macros. Import works by
injecting other module function names directly to the current lexical scope
(this is another difference from Erlang, where you can only import at module
level) and alias lets you rename a module you'd like to use. For example:
alias HTTPoison.Response, as: Resp
makes it easy to refer to the nested module without the need to write the long
name every time. It also works in the current lexical environment. There's also
require form, meant for importing macros (similar to how -include is used in
Erlang).
These two features make modules in Elixir cheap. You're likely to create heaps
more of modules in Elixir than you would in Erlang. That's a good thing, as it
makes organizing the code-base easier.
There is more to the module system, like compile-time constants and a use
directive, which make it even more powerful (and sometimes a bit too magical).
The tooling
Elixir comes with Mix, a task runner similar to Grunt or Gulp in the
JS/Node.js-land. Every library can extend the list of available tasks by just
defining appropriate module. One of such task providers is Hex, a package
manager, also built-in.
The two work together to make pulling the dependencies (locally, like npm or
virtualenv do) easier than most other solutions I've seen. You can install
packages from central Hex repository or directly from GitHub. No manual fiddling
involved. In Erlang this is also possible, but it's not as streamlined or
convenient. Starting a new project, installing dependencies and running a REPL
is ridiculously easy:
$ mix new dir
...edit dir/mix.exs, deps section...
$ iex -S mix
You can do mix run instead to run the project itself without a REPL. Every
time your deps change, the change is automatically picked up and your deps get
synced. Also, mix automatically compiles all your source code if it changes; in
Erlang I was more than once wondering why the heck my changes aren't visible in
the REPL, only to realize I didn't compile and load it. Of course, in the
REPL you have both compile and load commands available, along with reload,
which compiles and loads a module in one go. Mix is also used for running tests,
and unit-test support is built into the language with ExUnit library, by the
way.
The REPL itself is... colorful. That's the first difference I noticed compared
to Erlang REPL. It supports tab-completion for modules and functions, which is
the same for Erlang, but it also supports a help command, which displays
docstrings for various things. This is useful, especially because the Elixir
devs seem to like annotating modules and functions with docstrings. Everything
else works just as in Erlang, I think.
The standard library
The library is not that big, and it doesn't have to, because there's Erlang
underneath it. Instead it focuses on delivering a set of convenient wrappers
which follow consistent conventions. There's and Enum module, which groups most
collection-related operations, String module for working with binaries (strings
in Elixir are binaries by default) and so on.
I said they follow consistent conventions. It's linked to the use of a threading
macro (known as thread-first or -> in Clojure and |> in F#) - wherever
possible, functions take the subject of their operations as a first argument,
with other arguments following. This makes it easy to chain calls with the
macro, which lets you unnest calls:
Nothing fancy, and it has it's limitations , but it does make a difference in
practice. It's a macro, so it's not as elegant as it would be in some ML, but it
still works, so who cares? Of course, the problem is that not every function
follows the convention, which makes you break the chain of calls for it. It also
doesn't work with lambdas, which is a pain in the ass, because it doesn't let
you (easily) do something like flip(&Mod.func/2). You could do it with macros,
but that's the direction I have yet to explore.
Overall, Elixir standard library is rather compact, but provides most of the
tools you'd expect, along with convenient OTP wrappers. And if you find that
something is missing, calling Erlang functions is really easy (tab-completion in
the shell works here, too):
> :erlang.now()
{1448, 491309, 304608}
The macros
Elixir sports a macro system based on quasiquote and unquote, known from Lisps.
They are hygienic by default, work at compile time and can expand to any (valid)
code you want. A lot of Elixir itself is implemented with macros.
You can treat macros simply as functions which take unevaluated code as
arguments and return the final piece of code that's going to be run. I didn't
investigate much, but one macro I found useful was a tap macro:
https://github.com/mgwidmann/elixir-pattern_tap
You can read its code, it's less than 40 lines of code, with quite a bunch of
whitespace thrown in. This is also the reason why I believe that flip-like
macro should be possible and easy to make.
I will probably expand on macros and other meta-programming features of Elixir
after I play with it some more.
Structures and protocols
In Erlang you have records, but they are just a bit of (not that well looking,
by the way) syntactic sugar on top of tuples. From what I understand, records
(called structures) in Elixir are a syntactic sugar over Maps (the ones added in
Erlang/OTP 17), however they act as a building block for protocols, which
provide easy polymorphism to the language. Actually, it's still the same as in
Erlang, where you can pass a module name along with some value, to have a
function from that module called on the value. The difference is that in Erlang
you need to do this explicitly, while protocols in Elixir hide all this from the
programmer.
First, you need to define a protocol itself. It has to have a name and a couple
of functions. Then you implement the functions for a structure of your choosing
(built-in types, like Lists or even Functions, are included too). Then you can
call the protocol functions (treating protocol name as module name) on all the
structures which implement required functions. I think the protocols are
nominative and not structural, so it's not enough to implement the functions in
the same module as the structure, you need to explicitly declare them as an
implementation for some protocol.
Protocols are used for a Dict module, for example, which allows you to treat
maps, hashes, alists and other things like simple dictionaries, letting you
manipulate them without worrying about the concrete type. However, the dispatch
happens at run-time, so it's better to use implementation-specific functions if
there's no need for polymorphism.
That's it
I mean, I only played with Elixir over a single weekend; I still have quite a
few corners to explore. This is why I refrain from putting my perceived "cons"
in this post - I still need to get used to the Elixir way of doing things some
more.
I already decided, however, to use Elixir for programming Erlang in my next
project. At a glance Elixir looks like it improves on Erlang in some areas,
while not making it much worse at other places. I have a high expectations for
macros which are actually usable (you have parse transforms in Erlang, but...).
I have no idea how it happened, but somehow for the last 3 years I missed a
very useful command, called finder-by-keyword.
The command is almost undocumented, there's only a short explanation of what
the module (finder.el) does:
;; This mode uses the Keywords library header to provide code-finding
;; services by keyword.
By default it's bound to C-h p. It let's you browse built-in packages by
keyword, like "abbrev", "convenience", "tools" and so on. It's great for
discovering packages you didn't know existed!
The module seems to come from 1992 though, which makes it ignore all the
libraries installed via package.el. It shouldn't be that hard to make it
search all the package directories too. Actually, that's my main problem with
package.el - it only provides a simple, flat list view of the package. This
little tool is much better for browsing packages lists, and it's even already
written.
After
reading Lenses
in Pictures I felt rather dumb. I understood what is the
problem, but couldn't understand why all the ceremony around the
solution. I looked at
OCaml Lens
library and became enilghtened: it was because Haskell! Simple.
z = require"lodash"# `_` is a syntactic construct in LS{reverse,fold1,map}=require"prelude-ls"pass-thru = (f, v) -->(fv);vabstract-method = ->thrownewError("Abstract method")## LensProto - a prototype of all lens objects.#LensProto =# essential methods which need to be implemented on all lens instancesget: abstract-method(obj) ->set: abstract-method(obj, val) ->update: (obj, update_func) ->(@getobj)|>update_func|>@setobj,_# convenience functionsadd: (obj, val) ->@updateobj,(+val)## Lens constructors#make-lens = (name) ->LensProtowithget: (.[name])set: (obj, val) ->(switchtypeof!obj|\Object=>^^obj<<<obj|\Array=>obj.slice0)|>pass-thru(.[name]=val)make-lenses = (...lenses) ->mapmake-lens,lenses## Lenses composition#comp-lens = (L1, L2) ->LensProtowithget: L2.get>>L1.getset: (obj, val) ->L2.updateobj,(obj2) ->L1.setobj2,val# Lensable is a base class (or a mix-in), which can be used with any object and# which provides two methods for obtaining lenses for given names. The lens# returned is bound to the object, which allows us to write:## obj.l("...").get()# obj.l("...").set new_val## instead of## make-lens("...").get obj# make-lens("...").set obj, new_value#Lensable =# at - convenience function for creating and binding a lens from a string# path, with components separated by slash; for example: "a/f/z"at: (str) ->@l(...str.split("/"))l: (...names) -># create lenses for the names and compose them all into a single lenslens = reversenames|>mapmake-lens|>fold1comp-lens# bind the lens to *this* objectlenswithget: ~>lens.getthisset: (val) ~>lens.setthis,valto-lensable = (obj) ->Lensablewithobj
This showcases many of the ways you can use lenses in LiveScript. LS has
many ways of creating functions and it has syntax for pipe'ing and
composing functions, so it's a natural fit for everything FP-looking.
LS does not do "curried by default" like Haskell or OCaml, but it gives
you a partial application syntax and allows defining curried functions.
It's much like Scala in this regard.
Anyway, this is what lenses are supposed to do - they should support
functional updates over data sctructures. They should offer get, set and
update methods, and also there should be a compose operator for them.
And that's all - you can read the linked OCaml implementation to see
that it's really that simple. Most of that implementation are
convenience methods for creating lenses for various OCaml structures;
the core code is really short.
The first day of the conference is nearing an end right now, I don't
have much time, but I decided to at least enumerate the talks I
attended. I'll probably try expending on them later in the evening.
Reducing the Slippery Surface of Failure with Dependent Types - a
talk about dependent types in Scala, and their applications. Examples
given were: command line parsing, string internationalization.
Concurrency + Distribution = Scalability + Availability, a Journey
architecting Erlang Systems - very interesting talk about the
higher-level things you need to think about when desigining any kind
of distributed system.
The Pendulum - batch processing vs. interactive computing in the
eyes of Bruce Tate. Some interesting anecdotes about the history of
computing, Java and scalability.
Function-Passing, A New Model for Typed, Asynchronous and
Distributed Programming - another Scala-themed talk, this time about
a "new" model of distributed programming. If I understand the
concept correctly it's not exactly new, for example PicoLisp uses
something rather similar. But, this being Scala, this approach
guarantees static, compile-time checking for functions which are not
suitable for passing around.
Working with TXR without syntax highlighting was getting frustrating, so
I finally decided to write a mode for Emacs. It's very simple and offers
syntax highlighting only - ie. it scratches my own itch. It may be
useful for others anyway.
I will probably expand it as I work with TXR. TXR proves to be a really
nice language - its matching rules have some quirks, but once you learn
them you can parse nearly anything without much hassle.
I've been programming since forever, continuously learning and
improving for as long as 15 years
(see here).
I'm passionate about polyglot programming and original,
experimental programming languages. I try to apply knowledge of
both to production quality systems in real life.
