mirror of
https://github.com/adambard/learnxinyminutes-docs.git
synced 2024-12-24 10:01:38 +00:00
c3b9173466
[hy] Updating, elaborating and cleaning some rust
213 lines
6.2 KiB
Markdown
213 lines
6.2 KiB
Markdown
---
|
|
language: hy
|
|
filename: learnhy.hy
|
|
contributors:
|
|
- ["Abhishek L", "http://twitter.com/abhishekl"]
|
|
- ["Zirak", "http://zirak.me"]
|
|
---
|
|
|
|
Hy is a lisp dialect built on top of python. This is achieved by
|
|
converting hy code to python's abstract syntax tree (ast). This allows
|
|
hy to call native python code or python to call native hy code as well
|
|
|
|
This tutorial works for hy ≥ 0.9.12, with some corrections for hy 0.11.
|
|
|
|
```clojure
|
|
;; this gives an gentle introduction to hy for a quick trial head to
|
|
;; http://try-hy.appspot.com
|
|
;;
|
|
; Semicolon comments, like other LISPS
|
|
|
|
;; s-expression basics
|
|
; lisp programs are made of symbolic expressions or sexps which
|
|
; resemble
|
|
(some-function args)
|
|
; now the quintessential hello world
|
|
(print "hello world")
|
|
|
|
;; simple data types
|
|
; All simple data types are exactly similar to their python counterparts
|
|
; which
|
|
42 ; => 42
|
|
3.14 ; => 3.14
|
|
True ; => True
|
|
4+10j ; => (4+10j) a complex number
|
|
|
|
; lets start with some really simple arithmetic
|
|
(+ 4 1) ;=> 5
|
|
; the operator is applied to all arguments, like other lisps
|
|
(+ 4 1 2 3) ;=> 10
|
|
(- 2 1) ;=> 1
|
|
(* 4 2) ;=> 8
|
|
(/ 4 1) ;=> 4
|
|
(% 4 2) ;=> 0 the modulo operator
|
|
; power is represented by ** operator like python
|
|
(** 3 2) ;=> 9
|
|
; nesting forms will do the expected thing
|
|
(+ 2 (* 4 2)) ;=> 10
|
|
; also logical operators and or not and equal to etc. do as expected
|
|
(= 5 4) ;=> False
|
|
(not (= 5 4)) ;=> True
|
|
|
|
;; variables
|
|
; variables are set using setv, variable names can use utf-8 except
|
|
; for ()[]{}",'`;#|
|
|
(setv a 42)
|
|
(setv π 3.14159)
|
|
(def *foo* 42)
|
|
;; other container data types
|
|
; strings, lists, tuples & dicts
|
|
; these are exactly same as python's container types
|
|
"hello world" ;=> "hello world"
|
|
; string operations work similar to python
|
|
(+ "hello " "world") ;=> "hello world"
|
|
; lists are created using [], indexing starts at 0
|
|
(setv mylist [1 2 3 4])
|
|
; tuples are immutable data structures
|
|
(setv mytuple (, 1 2))
|
|
; dictionaries are key value pairs
|
|
(setv dict1 {"key1" 42 "key2" 21})
|
|
; :name can be used to define keywords in hy which can be used for keys
|
|
(setv dict2 {:key1 41 :key2 20})
|
|
; use `get' to get the element at an index/key
|
|
(get mylist 1) ;=> 2
|
|
(get dict1 "key1") ;=> 42
|
|
; Alternatively if keywords were used they can directly be called
|
|
(:key1 dict2) ;=> 41
|
|
|
|
;; functions and other program constructs
|
|
; functions are defined using defn, the last sexp is returned by default
|
|
(defn greet [name]
|
|
"A simple greeting" ; an optional docstring
|
|
(print "hello " name))
|
|
|
|
(greet "bilbo") ;=> "hello bilbo"
|
|
|
|
; functions can take optional arguments as well as keyword arguments
|
|
(defn foolists [arg1 &optional [arg2 2]]
|
|
[arg1 arg2])
|
|
|
|
(foolists 3) ;=> [3 2]
|
|
(foolists 10 3) ;=> [10 3]
|
|
|
|
; you can use rest arguments and kwargs too:
|
|
(defn something-fancy [wow &rest descriptions &kwargs props]
|
|
(print "Look at" wow)
|
|
(print "It's" descriptions)
|
|
(print "And it also has:" props))
|
|
|
|
(something-fancy "My horse" "amazing" :mane "spectacular")
|
|
|
|
; you use apply instead of the splat operators:
|
|
(apply something-fancy ["My horse" "amazing"] { "mane" "spectacular" })
|
|
|
|
; anonymous functions are created using `fn' or `lambda' constructs
|
|
; which are similiar to `defn'
|
|
(map (fn [x] (* x x)) [1 2 3 4]) ;=> [1 4 9 16]
|
|
|
|
;; Sequence operations
|
|
; hy has some builtin utils for sequence operations etc.
|
|
; retrieve the first element using `first' or `car'
|
|
(setv mylist [1 2 3 4])
|
|
(setv mydict {"a" 1 "b" 2})
|
|
(first mylist) ;=> 1
|
|
|
|
; slice lists using slice
|
|
(slice mylist 1 3) ;=> [2 3]
|
|
; or, in hy 0.11, use cut instead:
|
|
(cut mylist 1 3) ;=> [2 3]
|
|
|
|
; get elements from a list or dict using `get'
|
|
(get mylist 1) ;=> 2
|
|
(get mydict "b") ;=> 2
|
|
; list indexing starts from 0 same as python
|
|
; assoc can set elements at keys/indexes
|
|
(assoc mylist 2 10) ; makes mylist [1 2 10 4]
|
|
(assoc mydict "c" 3) ; makes mydict {"a" 1 "b" 2 "c" 3}
|
|
; there are a whole lot of other core functions which makes working with
|
|
; sequences fun
|
|
|
|
;; Python interop
|
|
;; import works just like in python
|
|
(import datetime)
|
|
(import [functools [partial reduce]]) ; imports fun1 and fun2 from module1
|
|
(import [matplotlib.pyplot :as plt]) ; doing an import foo as bar
|
|
; all builtin python methods etc. are accessible from hy
|
|
; a.foo(arg) is called as (.foo a arg)
|
|
(.split (.strip "hello world ")) ;=> ["hello" "world"]
|
|
|
|
; there is a shortcut for executing multiple functions on a value called the
|
|
; "threading macro", denoted by an arrow:
|
|
(-> "hello world " (.strip) (.split)) ;=> ["hello" "world]
|
|
; the arrow passes the value along the calls as the first argument, for instance:
|
|
(-> 4 (* 3) (+ 2))
|
|
; is the same as:
|
|
(+ (* 4 3) 2)
|
|
|
|
; there is also a "threading tail macro", which instead passes the value as the
|
|
; second argument. compare:
|
|
(-> 4 (- 2) (+ 1)) ;=> 3
|
|
(+ (- 4 2) 1) ;=> 3
|
|
; to:
|
|
(->> 4 (- 2) (+ 1)) ;=> -1
|
|
(+ 1 (- 2 4)) ;=> -1
|
|
|
|
;; Conditionals
|
|
; (if condition (body-if-true) (body-if-false)
|
|
(if (= passcode "moria")
|
|
(print "welcome")
|
|
(print "Speak friend, and Enter!"))
|
|
|
|
; nest multiple if else if clauses with cond
|
|
(cond
|
|
[(= someval 42)
|
|
(print "Life, universe and everything else!")]
|
|
[(> someval 42)
|
|
(print "val too large")]
|
|
[(< someval 42)
|
|
(print "val too small")])
|
|
|
|
; group statements with do, these are executed sequentially
|
|
; forms like defn have an implicit do
|
|
(do
|
|
(setv someval 10)
|
|
(print "someval is set to " someval)) ;=> 10
|
|
|
|
; create lexical bindings with `let', all variables defined thusly
|
|
; have local scope
|
|
(let [[nemesis {"superman" "lex luther"
|
|
"sherlock" "moriarty"
|
|
"seinfeld" "newman"}]]
|
|
(for [(, h v) (.items nemesis)]
|
|
(print (.format "{0}'s nemesis was {1}" h v))))
|
|
|
|
;; classes
|
|
; classes are defined in the following way
|
|
(defclass Wizard [object]
|
|
[[--init-- (fn [self spell]
|
|
(setv self.spell spell) ; init the spell attr
|
|
None)]
|
|
[get-spell (fn [self]
|
|
self.spell)]])
|
|
|
|
; or, in hy 0.11:
|
|
(defclass Wizard [object]
|
|
(defn --init-- [self spell]
|
|
(setv self.spell spell))
|
|
|
|
(defn get-spell [self]
|
|
self.spell))
|
|
|
|
;; do checkout hylang.org
|
|
```
|
|
|
|
### Further Reading
|
|
|
|
This tutorial is just a very basic introduction to hy/lisp/python.
|
|
|
|
Hy docs are here: [http://hy.readthedocs.org](http://hy.readthedocs.org)
|
|
|
|
Hy's GitHub repo: [http://github.com/hylang/hy](http://github.com/hylang/hy)
|
|
|
|
On freenode irc #hy, twitter hashtag #hylang
|