Given a strictly positive integer, return the shortest possible Roman numeral using only the additive rule. Output must consist of zero or more of each of the characters MDCLXVI in that order. The number 14 must therefore give XIIII rather than XIV.
The characters' numeric values are M=1000, D=500, C=100, L=50, X=10, V=5, I=1.
3 → III
4 → IIII
9 → VIIII
42 → XXXXII
796 → DCCLXXXXVI
2017 → MMXVII
16807 → MMMMMMMMMMMMMMMMDCCCVII
Saved 34 bytes by removing an error trap. Then saved 384 bytes by golfing. Then saved 190 bytes by combining the division operation with the append operation ("z") into a new operation ("p"). Then saved 52 bytes by golfing.
A s is a string.
To p a r remainder a s a x string a n number:
If the x is "", exit.
Divide the r by the n giving a q quotient and the r.
Fill a t s with the x's first's target given the q.
Append the t to the s.
To convert a r number to a s:
p the r the s "M" 1000.
p the r the s "D" 500.
p the r the s "C" 100.
p the r the s "L" 50.
p the r the s "X" 10.
p the r the s "V" 5.
p the r the s "I" 1.
Here is the ungolfed version of the final code, plus an error trap for a negative number:
A roman numeral is a string.
To process a remainder given a roman numeral and a letter string is a number:
If the letter is "", exit.
Divide the remainder by the number giving a quotient and the remainder.
Fill a temp string with the letter's first's target given the quotient.
Append the temp string to the roman numeral.
To convert a number to a roman numeral:
If the number is negative, exit.
Put the number in a remainder.
Process the remainder given the roman numeral and "M" is 1000.
Process the remainder given the roman numeral and "D" is 500.
Process the remainder given the roman numeral and "C" is 100.
Process the remainder given the roman numeral and "L" is 50.
Process the remainder given the roman numeral and "X" is 10.
Process the remainder given the roman numeral and "V" is 5.
Process the remainder given the roman numeral and "I" is 1.
/) instead of reshape (⍴) so you can cut out the each and the catenate-reduction (¨ and ,/).
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⎕) and use commute (⍨) to remove the parens and compose (∘).
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Converts to unary, then greedily replaces bunches of Is with the higher denominations in order.
.*
$*I
I{5}
V
VV
X
X{5}
L
LL
C
C{5}
D
DD
M
Saved 15 bytes thanks to Martin
I as unit?
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f=lambda n,d=5,r='IVXLCD':r and f(n/d,7-d,r[1:])+n%d*r[0]or'M'*n
Rather than creating the output string from the start by greedily taking the largest part, this creates it from the end. For instance, the number of I's is n%5, then the number of V's is n/5%2, and so on. This is mixed base conversion with successive ratios of 5 and 2 alternating.
Here's an iterative equivalent:
Python 2, 68 bytes
n=input();s='';d=5
for c in'IVXLCD':s=n%d*c+s;n/=d;d^=7
print'M'*n+s
The M's need to be handled separately because any number of them could be present as there's no larger digit. So, after the other place values have been assigned, the value remaining is converted to M's.
For comparison, a greedy strategy (69 bytes):
Python 2, 69 bytes
f=lambda n,d=1000,r='MDCLXVI':r and n/d*r[0]+f(n%d,d/(d%3*3-1),r[1:])
The current digit value d is divided by either 2 or 5 to produce the next digit. The value of d%3 tell us which one: if d%3==1, divide by 2; and if d%3==2, divide by 5.
Table@@@Thread@{r=Characters@"MDCLXVI",#~NumberDecompose~FromRomanNumeral@r}<>""&
Explicitly using the values and deriving the corresponding numerals seems to be one byte longer:
Table@@@Thread@{RomanNumeral[n={1000,500,100,50,10,5,1}],#~NumberDecompose~n}<>""&
43 bytes saved thanks to @BradC
At this point, the answer really belongs totally to @BradC. Another 32 bytes saved.
=REPT("M",A1/1E3)&REPT("D",MOD(A1,1E3)/500)&REPT("C",MOD(A1,500)/100)&REPT("L",MOD(A1,100)/50)&REPT("X",MOD(A1,50)/10)&REPT("V",MOD(A1,10)/5)&REPT("I",MOD(A1,5))
Formatted:
=REPT("M",A1/1E3)
&REPT("D",MOD(A1,1E3)/500)
&REPT("C",MOD(A1,500)/100)
&REPT("L",MOD(A1,100)/50)
&REPT("X",MOD(A1,50)/10)
&REPT("V",MOD(A1,10)/5)
&REPT("I",MOD(A1,5))
CONCATENATE with & between each element, and QUOTIENT with INT(A/B).
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REPT already truncates the number if it isn't an integer, so you can save 30 more bytes by removing each INT(). Save 2 more by replacing both 1000 with 1E3 (although Excel doesn't seem to want to keep it that way once you hit enter).
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1E3 behaviour. Answer updated.
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65 bytes of code + -p flag.
$s=1e3;for$@(MDCLXVI=~/./g){$\.=$@x($_/$s);$_%=$s;$s/=--$|?2:5}}{
Without changing the byte count, MDCLXVI=~/./g can be replaced by M,D,C,L,X,V,I; and --$|?2:5 by $|--*3+2.
Much longer (99 bytes), there is:
$_=M x($_/1e3).D x($_%1e3/500).C x($_%500/100).L x($_%100/50).X x($_%50/10).V x($_%10/5).I x($_%5)
-7 bytes thanks to Martin Ender
q~{5md\2md\}3*]W%"MDCLXVI".*
q~ e# Read and eval input (push the input as an integer).
{ e# Open a block:
5md\ e# Divmod the top value by 5, and bring the quotient to the top.
2md\ e# Divmod that by 2, and bring the quotient to the top.
}3* e# Run this block 3 times.
]W% e# Wrap the stack in an array and reverse it. Now we've performed the mixed-base
e# conversion.
"MDCLXVI" e# Push this string.
.* e# Element-wise repetition of each character by the numbers in the other array.
e# Implicitly join and print.
f=n=>n>999?"M"+f(n-1000):n>499?"D"+f(n-500):n>99?"C"+f(n-100):n>49?"L"+f(n-50):n>9?"X"+f(n-10):n>4?"V"+f(n-5):n>0?"I"+f(n-1):""
A purely hard coded ternary statement using recursion.
Full/Formatted version:
using System;
class P
{
static void Main()
{
Func<int, string> f = null;
f = n => n > 999 ? "M" + f(n - 1000)
: n > 499 ? "D" + f(n - 500)
: n > 99 ? "C" + f(n - 100)
: n > 49 ? "L" + f(n - 50)
: n > 9 ? "X" + f(n - 10)
: n > 4 ? "V" + f(n - 5)
: n > 0 ? "I" + f(n - 1)
: "";
Console.WriteLine(f(3));
Console.WriteLine(f(4));
Console.WriteLine(f(42));
Console.WriteLine(f(796));
Console.WriteLine(f(2017));
Console.WriteLine(f(16807));
Console.ReadLine();
}
}
int can't be implicitly cast to a bool.
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Jun 29, 2017 at 8:30
¸5n3×Rvćy‰ì}"MDCLXVI"Ss×J
Explanation
¸ # wrap input in a list
5n # push 5**2
3× # repeat it 3 times
Rv # for each digit y in its reverse
ć # extract the head of the list
# (div result of the previous iteration, initially input)
y‰ # divmod with y
ì # prepend to the list
} # end loop
"MDCLXVI"S # push a list of roman numerals
s× # repeat each a number of times corresponding to the result
# of the modulus operations
J # join to string
Saved 6 bytes thanks to @Neil for porting @Jörg Hülsermann's answer
Saved 6 bytes thanks to @Shaggy
n=>'MDCLXVI'.replace(/./g,(c,i)=>c.repeat(n/a,n%=a,a/=i%2?5:2),a=1e3)
Test cases:
f=
n=>'MDCLXVI'.replace(/./g,(c,i)=>c.repeat(n/a,n%=a,a/=i%2?5:2),a=1e3)
const testCases = [3, 4, 42, 796, 2017, 16807]
testCases.forEach(testCase => console.log(f(testCase)))
n%=x within the repeat method to save a few bytes.
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n=>'MDCLXVI'.replace(/./g,(c,i)=>c.repeat(n/a,n%=a,a/=i%2?5:2),a=1e3)
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/1/I//IIIII/V//VV/X//XXXXX/L//LL/C//CCCCC/D//DD/M/
Takes input in unary, and I'm (ab)using the footer field on TIO for input so output is preceded by a newline.
def; array as default parameter reduced an indentation space; unwanted variable declaration removeda%= shorthand(a//i) got removed[] at the cost of one indentation space, thus saving 1 byte.def f(a):
b=1000,500,100,50,10,5,1
for i in b:print(end=a//i*'MDCLXVI'[b.index(i)]);a%=i
b as a variable within the function. That removes the necessity of brackets - b=1000,500,100,50,10,5,1
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Jun 27, 2017 at 21:10
/.UI,..N&..0\0&/52"IVXLCDM"U,r%ws;rr3tu;pw..u;qrUosv!s.u\psq,!@Us(0;U
/ . U I
, . . N
& . . 0
\ 0 & /
5 2 " I V X L C D M " U , r % w
s ; r r 3 t u ; p w . . u ; q r
U o s v ! s . u \ p s q , ! @ U
s ( 0 ; U . . . . . . . . . . .
. . . .
. . . .
. . . .
. . . .
I have managed to compress it a bit more, but there is still some pesky no-ops, especially on the top face.
52"IVXLCDM"U put the necessary divisors and characters on the stack. The 5 and 2 will be used to reduce the div/mod value and the characters will be discarded after use.UIN0/&0\&,/U u-turns onto the top face and starts a long tour to get the input and push 1000 onto the stack. An initial divide is done and a u-turn onto the r of the next snippet. This was an area I was looking at to make some savings.,r%ws;rr beginning of the divmod loop. integer divide, rotate the result away mod, then rearrange top of stack to be reduced input, current divisor and divide result.3tus bring the current character to the top and swap it with the divide result.!vsoUs(0;U this is the print loop. while the div result is more than 0, swap with character output, swap back, decrement, push a 0 and drop it. On 0 redirect over the pop stack (remove divide result) and around the cube.\u;pwpsq,!@Urq;u with a bit of redirection, this removes the character from the stack, brings the 5 and 2 to the top, swaps them and pushes one back down. The remaining is used to reduce the divisor. Halt if it reduces to 0, otherwise push the 5 or 2 to the bottom and re-enter the loop.
(f=#~NumberDecompose~{1000,500,100,50,10,5,1};""<>{Flatten@Table[Table[{"M","D","C","L","X","V","I"}[[i]],f[[i]]],{i,Length@f}]})&
lambda n,r=[1000,500,100,50,10,5,1]:''.join(n%a/b*c for a,b,c in zip([n+1]+r,r,'MDCLXVI'))
1000 can be 1e3 (if you don't mind it being a float which shouldn't be a problem)
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Jun 27, 2017 at 15:09
float, and you can't multiply a string by a float :c
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SELECT REPLICATE('M',n/1000)+IIF(n%1000>499,'D','')
+REPLICATE('C',n%500/100)+IIF(n%100>49,'L','')
+REPLICATE('X',n%50/10)+IIF(n%10>4,'V','')
+REPLICATE('I',n%5)
FROM t
Line breaks added for readability only.
This version is a lot longer (230 characters), but feels much more "SQL-like":
DECLARE @ INT,@r varchar(99)=''SELECT @=n FROM t
SELECT'I's,1v INTO m
INSERT m VALUES('V',5),('X',10),('L',50),('C',100),('D',500),('M',1000)
L:
SELECT @-=v,@r+=s
FROM m WHERE v=(SELECT MAX(v)FROM m WHERE v<=@)
IF @>0GOTO L
SELECT @r
Makes a table m with all the char-value mappings, and then loops through finding the largest value <= the number, concatenating the matching character.
"IVXLCD"£%(U/=Y=v *3+2Y)îXÃw i'MpU
"IVXLCD"£ %(U/=Y=v *3+2Y )îXÃ w i'MpU
"IVXLCD"mXY{U%(U/=Y=Yv *3+2,Y)îX} w i'MpU : Ungolfed
: Implicit: U = input number
"IVXLCD"mXY{ } : Map each char X and its index Y in this string to:
Y=Yv *3+2 : Set Y to 5 for even indexes, 2 for odd.
U/= : Divide U by this amount.
U%( ,Y) : Modulate the old value of U by 5.
îX : Repeat the character that many times.
: This returns e.g. "IIVCCCD" for 16807.
w : Reverse the entire string.
i'MpU : Prepend U copies of 'M' (remember U is now the input / 1000).
: Implicit: output result of last expression
A recursive function.
f=(n,a=(i=0,1e3))=>n?a>n?f(n,a/=i++&1?5:2):'MDCLXVI'[i]+f(n-a):''
The second recursive call f(n-a) really should be f(n-a,a). By omitting the 2nd parameter, a and i are reinitialized (to 1000 and 0 respectively) each time a new Roman digit is appended to the final result. This causes more recursion than needed but doesn't alter the outcome of the function and saves 2 bytes.
f=(n,a=(i=0,1e3))=>n?a>n?f(n,a/=i++&1?5:2):'MDCLXVI'[i]+f(n-a):''
console.log(f(3))
console.log(f(4))
console.log(f(9))
console.log(f(42))
console.log(f(796))
console.log(f(2017))
console.log(f(16807))3 bytes saved thanks to Adám.
'MDCLXVI'#~(_,6$2 5)&#:
Similar to the APL answer basically the same thing.
'MDCLXVI'#~(_,6$2 5)&#:
( )&#: mixed base conversion from decimal
6$2 5 2 5 2 5 2 5
_, infinity 2 5 2 5 2 5
this gives us e.g. `0 0 0 0 1 0 4` for input `14`
'MDCLXVI'#~ shape each according to the number of times on the right
this is greedy roman numeral base conversion
#.inv instead of #:?
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#.inv instead of #:, since something like 2 #: 4 is 0, whilst 2 #.inv 4 is 1 0 0
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Jun 27, 2017 at 22:29
# is /; ~ is ⍨; $ is ⍴; & is ∘; #: is ⊤. The only difference is that you use infinity _ while you could use 0 like the APL answer.
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@set/pn=
@set s=
@for %%a in (1000.M 500.D 100.C 50.L 10.X 5.V 1.I)do @call:c %%~na %%~xa
@echo %s:.=%
@exit/b
:c
@if %n% geq %1 set s=%s%%2&set/an-=%1&goto c
Takes input on STDIN.
select listagg((select listagg(l)within group(order by 1)from dual start with trunc((n-nvl(n-mod(n,p),0))/v)>0 connect by level<=trunc((n-nvl(n-mod(n,p),0))/v)))within group(order by v desc)from (select 2849n from dual)cross join(select 1000v,null p,'m'l from dual union select 500,1000,'d'from dual union select 100,500,'c'from dual union select 50,100,'l'from dual union select 10,50,'x'from dual union select 5,10,'v'from dual union select 1,5,'i'from dual)
Outputs:
mmdcccxxxxviiii
Please note the actual size of the line is 460bytes, because it includes the input number (2849).
Ungolfed:
select listagg(
(select listagg(l, '') within group(order by 1)
from dual
start with trunc((n-nvl(p*trunc(n/p),0))/v) > 0
connect by level <= trunc((n-nvl(p*trunc(n/p),0))/v) )
) within group(order by v desc)
from (select 2348 n
from dual
) cross join (
select 1000v, null p, 'm' l from dual union
select 500, 1000, 'd' from dual union
select 100, 500, 'c' from dual union
select 50, 100, 'l' from dual union
select 10, 50, 'x' from dual union
select 5, 10, 'v' from dual union
select 1, 5, 'i' from dual
)
How it works: I calculate how many of each letter I need, by calculating the most I can get to with the higher value one (infinity for M), and then doing an integer division between the current letter's value and the result of that.
E.g. 2348, how many Cs do I need? trunc((2348-mod(2348,500))/100) = 3.
Then, I listagg that letter together 3 times (exploiting CONNECT BY to generate the 3 rows I need).
Finally, I listagg everything together.
Kinda bulky, but most of it is the select from duals in the conversion table and I can't really do much about that...
n->{String s="";for(int v[]={1,5,10,50,100,500,1000},i=7;i-->0;)for(;n>=v[i];n-=v[i])s+="IVXLCDM".charAt(i);return s;}
Saved a byte thanks to @TheLethalCoder
v and i in the first for loop to save a byte?
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Jun 27, 2017 at 15:05
NνA⁰χWφ«W¬‹νφ«§MDCLXVIχA⁻νφν»A⁺¹χχA÷φ⎇﹪χ²¦²¦⁵φ
Explanation:
Nν Take input as number and assign it to ν
A⁰χ Let χ=0
Wφ« While φ>0 (φ has a predefined value of 1000)
W¬‹νφ« While v>=φ
§MDCLXVIχ Take the char from string "MDCLXVI" at position χ
A⁻νφν» Let ν=ν-φ
A⁺¹χχ Increment χ
A÷φ⎇﹪χ²¦²¦⁵φ If χ is odd, divide φ by 5, else divide φ by 2
Nν is one byte shorter than ANν, ¬‹ is one byte shorter than subtracting 1, and if you use ÷ (IntDivide) instead of ∕ (Divide) then you can use φ as the outer loop condition. However, I think you can get it down to 40 bytes by looping over MDCLXVI directly instead.
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#include <cstdio>
#include <map>
std::map<int,char> m = {{1000,'M'},{500,'D'},{100,'C'},{50,'L'},{10,'X'},{5,'V'},{1,'I'}};
int main(){unsigned long x;scanf("%d",&x);for(auto i=m.rbegin();i!=m.rend();++i)while(x>=i->first){printf("%c", i->second);x=x-i->first;}return 0;}
#include <stdio.h>
int v[]={1000,500,100,50,10,5,1};
char*c="MDCLXVI";
int main(){int x;scanf("%d",&x);for(int i=0;i<sizeof v/sizeof(int);i++)for(;x>=v[i];x-=v[i])putc(c[i],stdout);}
Same algorithm as before, just using plain c arrays instead of an std::map, partially inspired by @xnor's answer and using a string to store the letters.
This is an anonymous function, returning the result as a string.
(lambda(value)(setf(values a b)(floor v 1000))(concatenate 'string(format()"~v,,,v<~>"a #\M)(format nil"~@:r"b)))
Ungolfed, with descriptive variable names and comments:
(defun format-roman (value)
;; Get "value integer-divided by 1000" and "value mod 1000"
(setf (values n_thousands remainder) (floor value 1000))
(concatenate 'string
;; Pad the empty string n_thousands times, using "M" as the
;; padding character
(format () "~v,,,v<~>" n_thousands #\M)
;; Format the remainder using "old-style" Roman numerals, i.e.
;; numerals with "IIII" instead of "IV"
(format nil "~@:r" remainder)))
CL has built-in Roman numeral formatter. Sadly it doesn't work for numbers larger than 3999.
NςA²ξFMDCLXVI«×ι÷ςφA﹪ςφςA÷φξφA÷χξξ
Originally based on @CarlosAlego's answer. A port of @xnor's Python solution is also 34 bytes:
NθA⁵ξFIVXLCD«←×ι﹪θξA÷θξθA÷χξξ»←×Mθ
Edit: A port of @xnor's other Python solution turns out to be 33 bytes!
NθFMDCLXVI«×ι÷θφA﹪θφθA÷φ⁺׳﹪φ³±¹φ
Try it online! Link is to verbose version of code. Note that I've used ⁺׳﹪φ³±¹ instead of ⁻׳﹪φ³¦¹ because the deverbosifier is currently failing to insert the separator.
4 -> IIIIis9 -> VIIIIas well instead ofIX? \$\endgroup\$VIIIIis the only allowed output for 9. \$\endgroup\$