txlyre
5ca7bda377
opt
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2 tuần trước cách đây | |
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| .gitignore | 3 tuần trước cách đây | |
| build.sh | 2 tuần trước cách đây | |
| jk.c | 2 tuần trước cách đây | |
| readme.md | 2 tuần trước cách đây |
readme.md
jk
jk is a recreational tacit array programming language inspired by J and K (so j + k = jk).
this is an implementation of the jk interpreter in C. Requires libgc (a.k.a. bdwgc) to build.
Examples
Compute factorial
fac:*/!. / analytic
fac 5
120
facr:<.;1?.(]*(s.<)),:(:1) / recursive
facr 5
120
/ or simply use *.
*.5
120
Compute Nth fibonacci
fib:*x?:(+\|)!2 / iterative
fib 10
55
fib"!.10
1 1 2 3 5 8 13 21 34 55
fibr:<.;1?.((s.<)+(s.(<<))),:] / recursive
fibr"!.10
1 1 2 3 5 8 13 21 34 55
/ or just +.
+.!.10
1 1 2 3 5 8 13 21 34 55
Remove consecutive duplicates
rcd:]&.(1~:".)
rcd 'abobaabuuss'
abobabus
Check if an array is palindrome
ispal:]=:|
ispal 'aboba'
1
ispal 'hi'
0
Count occurences
occs:?,"(#"]@#:)
occs 'abracadabra'
a 5
b 2
r 2
c 1
d 1
occs 'Hello World!'
H 1
e 1
l 3
o 2
1
W 1
r 1
d 1
! 1
*it@<:{."it / get most frequent
l 3
Make multiplication table
*\.;.!.9
1 2 3 4 5 6 7 8 9
2 4 6 8 10 12 14 16 18
3 6 9 12 15 18 21 24 27
4 8 12 16 20 24 28 32 36
5 10 15 20 25 30 35 40 45
6 12 18 24 30 36 42 48 54
7 14 21 28 35 42 49 56 63
8 16 24 32 40 48 56 64 72
9 18 27 36 45 54 63 72 81
Duplicate zeroes keeping the same shape
dzks:##]#.(>0=)
dzks 1 0 2 3 0 4 5 0
1 0 0 2 3 0 0 4
Quick reference (also available in the interpreter itself)
/ comment
5+5 / also comment
5+5/not comment (no whitespace before /)
nil udf / special, nil and undefined
'a'%2 / = nan, nan used to denote illegal numeric operation
+1 2 3 / = udf, attempt to transpose flat vector, udf/undefined used to denote illegal operation
5 5.5 -5 42 / number (double-precision floats)
1`000 1`000`000 /
.5 .429 /
0xff 0o4 0b0101 /
nan inf /
'a' 'b' 'g' / chars (bytes)
4t.0 / 0 NUL byte
(4t.0),:(4t.16),:(4t.22) /
1 2 3 / numbers array
'hello world!' 'bla''bla' / quote, array of chars
,'a' / 1-char string
,1 / 1-elt array
() / unit, empty array
1,:(5+5),:1 2 3 / strand, mixed array literal
-1 / negative num literal
- 1 / application of - negate to 1
-1 -2 -3 / array of negative nums
- 1 2 3 / application of - negate to an array of nums
5-5 / array of numbers 5 and -5
5- 5 / 5 minus 5
+ / verb
5+5 / dyadic expr
#1 2 3 / monadic expr (no left side)
+/ *;. / adverb
+;1 -;* +^:^. / conjunction
:x+y / function literal
:1 / function that always yields 1
x:123 / bind name
sq:*;. /
fac:*/1+! / bind function
f:x+y /
f:-x / overload function by arity
f 5 / = -5
5 f 5 / = 10
*/!. / hook, fgx -> f(g(x)), xfgy -> f(g(x, y))
+/%# / fork, fghx -> g(f(x), h(x)), xfghy -> g(f(x), h(y))
1+! / over, nfgx -> f(n, g(x)), xnfgy -> f(n, g(x, y))
1+ / bond, nfx -> f(n, x), xnfy -> f(n, f(x, y))
: monadic const create a function that always yields x
: dyadic bind bind y to symbol x
:: monadic unbind unbind symbol x
:: dyadic obverse insert inverse for x
+ monadic flip transpose matrix
+ dyadic plus add numbers
+. monadic fibonacci compute xth fibonacci number
+. dyadic gcd compute gcd(x, y)
+: monadic sin compute sin(x)
+: dyadic combine combine digits of x and y, same as 10_.(10_:),(10_:)
- monadic negate negate number
- dyadic minus subtract numbers
* monadic first yield first element of x
* dyadic times multiply numbers
*. monadic factorial x!
*. dyadic lcm compute lcm(x, y)
*: monadic double x * 2
*: dyadic replicate repeat y x times
% monadic reciprocal 1 / x
% dyadic divide divide numbers
%. monadic sqrt compute square root of x
%. dyadic root compute xth root of y
%: monadic halve x % 2
%: dyadic idivide same as % divide, but result is always integer
! monadic enum [0, x)
! dyadic mod modulo of numbers
!. monadic iota [1, x]
!. dyadic range [x, y] (also works for chars and even if x > y)
!: monadic odometer !:10 10 is 0 0,:0 1,: ... 1 0,:1 1,: ... 9 8,:9 9
!: dyadic chunks split y into x-sized chunks
^ monadic exp e^x
^ dyadic power raise number to a power
^. monadic nlog ln(x)
^. dyadic log log(y)/log(x)
= monadic permute generate permutations of x
= dyadic equals test whether x and y are equal
=. monadic occurences count occurences of elts, =.'Hello World!' is 0 0 0 1 0 0 0 1 0 2 0 0
=. dyadic mask mask one array in another, 'abxyzabayxxyabxyk'=.'xy' is 0 0 1 1 0 0 0 0 0 0 2 2 0 0 3 3 0
=: monadic classify assign unique index to each unique elt, =:'Hello World!' is 0 1 2 2 3 4 5 3 6 2 7 8
=: dyadic match same as = equals, but rank 0, so compares x and y as whole
~ monadic not logical not, nil udf () 0 4t.0 are not truthy, everything else is truthy
~ dyadic notequals test whether x and y are not equal
~. monadic sign sign of x, -1 for negative, 0 for 0, 1 for positive
~. dyadic insert insert x between elts of y, 0~.1 2 3 is 1 0 2 0 3
~: dyadic notmatch rank 0 version of ~ notequals
< monadic pred x - 1
< dyadic less test whether x is lesser than y
<. monadic floor round x down
<. dyadic lesseq test whether x is equal or lesser than y
<: monadic gradedown indices of array sorted descending
<: dyadic nudgeleft shift elts of y to the left filling gap with x
> monadic succ x + 1
> dyadic greater test whether x is greater than y
>. monadic ceil round x up
>. dyadic greatereq test whether x is equal or greater than y
>: monadic gradeup indices of array sorted ascending
>: dyadic nudgeright shift elts of y to the right filling gap with x
, monadic enlist put x into 1-elt array
, dyadic join concat x and y
,. monadic enfile same as , enlist but with infinite rank, ,.1 2 3 is (,1),:(,2),:(,3)
,. dyadic enpair put x and y into 2-elt array
# monadic count yield count of elts of x
# dyadic take take x first elts of y (or last if x < 0)
#. monadic where #.0 0 1 0 1 0 is 2 4
#. dyadic copy repeat each elt of x by corresponding number in y, 5 2 3 3#.0 2 2 1 is 2 2 3 3 3
#: monadic group #:'mississippi' is (,0),:1 4 7 10,:2 3 5 6,:8 9
#: dyadic buckets group elts of y into buckets according to x, e.g. 0 -1 -1 2 0#:a b c d e is (a,.e),:(),:(,d)
_ monadic nub mark all unique elts of x, e.g. _'abracadabra' yields 1 1 1 0 1 0 1 0 0 0 0
_ dyadic drop remove first x elts of y (or last if x < 0)
_. monadic unbits _.1 0 1 is 5
_. dyadic unbase 10_.4 5 6 is 456
_: monadic bits _:5 is 1 0 1
_: dyadic base 10_:4242 is 4 2 4 2
? monadic unique distinct elts of x, same as ]#._
? dyadic find find all indices of x in y
& monadic flatten flatten an array, same as ,//.
& dyadic minand get min of two numbers (logical and for 0/1s)
| monadic reverse reverse an array
| dyadic maxor get max of two numbers (for 0/1s is same as logical or)
|. monadic round round x
|. dyadic rotate rotate array x times clockwise (-x for counterclockwise)
|: monadic depth find max depth of x, |:,,,y yields 3
|: dyadic windows yields all contiguous x-sized subarrays of y
@ monadic abs |x|
@ dyadic at pick elts from x by indices from y
@. monadic shuffle shuffle elts of x
@. dyadic member check whether x is in y
@: dyadic indexof yield index of x in y or #y if x not in y
{ monadic head first two elts of x, same as 2#
{ dyadic bin bin search, e.g. 1 3 5 7 9{8 9 0 yields 3 4 -1
{. monadic tail last elt of x
{: monadic prefixes prefixes of x, same as |}.\.
{: dyadic shl x << y
} monadic behead all elts of x except first, same as 1_
} dyadic xor x ^ y
}. monadic curtail all elts of x except last, same as -1_
}: monadic suffixes suffixes of x, same as }.\.
}: dyadic shr x >> y
[ monadic factors compute prime factors of x
[ dyadic left yield x
[. monadic bnot ~x
[. dyadic bor x | y
[: monadic primes find primes in range [2, x]
[: dyadic parts split y into x parts
] monadic same yield x (i.e. identity)
] dyadic right yield y (i.e. right argument)
]. monadic sort sort x ascending, shortcut for ]@>:
]. dyadic outof the number of ways of picking x balls from a bag of y balls, e.g. 5].10 is 252
]: monadic unsort sort x descending, shortcut for ]@<:
]: dyadic explode split y by delim x
`. monadic symbol cast x to a symbol
`. dyadic apply1 apply x to y
`: monadic square x ^ 2
`: dyadic apply2 apply x to y (y is 2-elt array of args)
$ monadic shape yield shape of x
$ dyadic reshape reshape y to shape x
$. monadic repr yield string repr of x
$. dyadic format format y by template x, e.g. '{0}+{1}*{-1}+_'$.1 2 3 4 is 1+2*4+1
$: monadic eye identity matrix of size x
$: dyadic implode join y inserting x between
p. monadic print print x
P. monadic println print x and a \n
s. monadic selfref1 monadic reference to current function or rhs of bind or top-most train
s. dyadic selfref2 dyadic reference to current function or rhs of bind or top-most train
F. monadic read read file (x=0 to read stdin)
F. dyadic write write file (y=0 to write to stderr)
t. monadic type type of x, array=0, verb=1, symbol=2, number=3, char=4, nil=5, udf=6
r. monadic deal yield random elt of x
r. dyadic roll roll xdy (note: y is 0-based, so >xr.y for 1-based)
e. monadic eval eval expression, yields udf on parse error
i. monadic import load and eval source file
i. dyadic foreign call external function (lhs is array of arguments), e.g. .5i.'libm.so:dd:sin'
y. monadic system exec system command (yields output)
y. dyadic system2 exec system command with input
E. monadic exit exit with exit code
L. dyadic tackleft prepend x to y
R. dyadic tackright append x to y
f" each >"1 2 3 yields 2 3 4
xf" merge 1 2 3,"a b c yields (1,.a),:(2,.b),:(3,.c)
f". eachprior -".1 2 2 3 5 6 yields 1 0 1 2 1
xf". eachpriorwith 0-".1 2 2 3 5 6 yields 1 1 0 1 2 1
f/ fold +/1 2 3 yields 6
xf/ foldwith 1+/1 2 3 yields 7
f\ scan +\1 2 3 yields 1 3 6
xf\ scanwith 1+\1 2 3 yields 1 2 4 7
f/. converge 1;_/.1 2 3 yields ()
f\. converges 1;_\.1 2 3 yields 1 2 3,:2 3,:(,3),:()
xf/. eachright 1-/.1 2 3 yields 0 1 2
xf\. eachleft 1-\.1 2 3 yields 0 -1 -2
f": rank #":1 2 3$1 yields 3 3, #":inf 2 3$1 yields 1 1 1,:1 1 1
xf": rank2 1 2 3 *:":1 1 2 3 yields (,1),:2 2,:3 3 3
n` amend 'gw'0 3`'cross' yields 'grows'
f&. filter >;0&.-2!.2 yields 1 2, basically shortcut for ]#.f
f/: span =;' '/:'x y z' yields (,'x'),:(,'y'),:(,'z')
xf/: stencil 3+//:!10 yields 3 6 9 12 15 18 21 24, shortcut for f"x|:
f;. reflex *;.5 yields 25, 5%;.2 yields 0.4
f;g bond */;!.5 yields 120, +;1 5 yields 6, 5;- 1 yields 4
f?.x pick >;5?.((2*),:<)"3 6 yields 6 5
f?:F while <;5?:>0 yields 5
n?:f repeat 5?:*;2 1 yields 32
f&:F if 1+&:+2 yields 2
f;:F monaddyad -;:+5 yields -5, 1-;:+5 yields 6
inverse of a function f is a function ~f that undoes the effect of f
f::~f obverse define inverse ~f for f
f-:x inverse ~fx
xf-:y inverse2 (~fx)~f~fx
f^:Fx under ~FfFx
xf^:Fx under2 ~F(Fx)f(Fx)
Prebuilt binaries
There is prebuilt ELF executables with statically linked libgc for x86-64 and aarch64 Linux: