# Langford sequence implementation Haskell or C

In combinatorial mathematics, a Langford pairing, also called a Langford sequence, is a permutation of the sequence of `2n` numbers `1, 1, 2, 2, ..., n,`n in which the two ones are one unit apart, the two twos are two units apart, and more generally the two copies of each number k are k units apart.

For example:

Langford pairing for `n = 3` is given by the sequence `2,3,1,2,1,3.`

• What is a good method to solve this in `haskell` or `C`
• Can you suggest an algorithm to solve it (Do not want to use brute force)?

--------------------------EDIT----------------------
How could we define the mathematical rules to put @Rafe's code in haskell

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The algorithm should be relatively independent of the language in use. (And besides, if this is more than an educational exercise, you're propably better off just using readily-calculated solutions) – delnan Apr 27 '11 at 19:50
According to wikipedia, this is an exact cover problem, which are NP complete in general. I am not sure if that result applies to this particular problem. – luqui Apr 27 '11 at 20:22
Here's a Perl program that you might want to study: legacy.lclark.edu/~miller/langford/ROD.pl – larsmans Apr 27 '11 at 20:31
Integer programming might be useful here. – Aryabhatta Apr 27 '11 at 20:39
When trying to solve this problem, I wrote this correctness checker. Hard problem. – luqui Apr 27 '11 at 20:54

You want to find an assignment to the variables {p1, p2, ..., pn} (where pi is the position of the first occurrence of 'i') with the following constraints holding for each pi:

• pi in 1..(1+n-i)
• if pi = k then forall pj where j != i
• pj != k
• pj != k + i
• pj != k - j
• pj != k + i - j

You need a sensible search strategy here. A good choice is to at each choice point choose the pi with the smallest remaining set of possible values.

Cheers!

This is a "mostly functional" version of the imperative version I first wrote (see first addendum below). It's mostly functional in the sense that the state associated with each vertex in the search tree is independent of all other state, hence there's no need for a trail or machinery of that kind. However, I have used imperative code to implement the construction of each new domain set from a copy of the parent domain set.

``````using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace MostlyFunctionalLangford
{
class Program
{
// An (effectively functional) program to compute Langford sequences.
static void Main(string[] args)
{
var n = 7;
var DInit = InitLangford(n);
var DSoln = Search(DInit);
if (DSoln != null)
{
Console.WriteLine();
Console.WriteLine("Solution for n = {0}:", n);
WriteSolution(DSoln);
}
else
{
Console.WriteLine();
Console.WriteLine("No solution for n = {0}.", n);
}
}

// The largest integer in the Langford sequence we are looking for.
// [I could infer N from the size of the domain array, but this is neater.]
static int N;

// ---- Integer domain manipulation. ----

// Find the least bit in a domain; return 0 if the domain is empty.
private static long LeastBitInDomain(long d)
{
return d & ~(d - 1);
}

// Remove a bit from a domain.
private static long RemoveBitFromDomain(long d, long b)
{
return d & ~b;
}

private static bool DomainIsEmpty(long d)
{
return d == 0;
}

private static bool DomainIsSingleton(long d)
{
return (d == LeastBitInDomain(d));
}

// Return the size of a domain.
private static int DomainSize(long d)
{
var size = 0;
while (!DomainIsEmpty(d))
{
d = RemoveBitFromDomain(d, LeastBitInDomain(d));
size++;
}
return size;
}

// Find the k with the smallest non-singleton domain D[k].
// Returns zero if none exists.
private static int SmallestUndecidedDomainIndex(long[] D)
{
var bestK = 0;
var bestKSize = int.MaxValue;
for (var k = 1; k <= N && 2 < bestKSize; k++)
{
var kSize = DomainSize(D[k]);
if (2 <= kSize && kSize < bestKSize)
{
bestK = k;
bestKSize = kSize;
}
}
return bestK;
}

// Obtain a copy of a domain.
private static long[] CopyOfDomain(long[] D)
{
var DCopy = new long[N + 1];
for (var i = 1; i <= N; i++) DCopy[i] = D[i];
return DCopy;
}

// Destructively prune a domain by setting D[k] = {b}.
// Returns false iff this exhausts some domain.
private static bool Prune(long[] D, int k, long b)
{
for (var j = 1; j <= N; j++)
{
if (j == k)
{
D[j] = b;
}
else
{
var dj = D[j];
dj = RemoveBitFromDomain(dj, b);
dj = RemoveBitFromDomain(dj, b << (k + 1));
dj = RemoveBitFromDomain(dj, b >> (j + 1));
dj = RemoveBitFromDomain(dj, (b << (k + 1)) >> (j + 1));
if (DomainIsEmpty(dj)) return false;
if (dj != D[j] && DomainIsSingleton(dj) && !Prune(D, j, dj)) return false;
}
}
return true;
}

// Search for a solution from a given set of domains.
// Returns the solution domain on success.
// Returns null on failure.
private static long[] Search(long[] D)
{
var k = SmallestUndecidedDomainIndex(D);
if (k == 0) return D;

// Branch on k, trying each possible assignment.
var dk = D[k];
while (!DomainIsEmpty(dk))
{
var b = LeastBitInDomain(dk);
dk = RemoveBitFromDomain(dk, b);
var DKeqB = CopyOfDomain(D);
if (Prune(DKeqB, k, b))
{
var DSoln = Search(DKeqB);
if (DSoln != null) return DSoln;
}
}

// Search failed.
return null;
}

// Set up the problem.
private static long[] InitLangford(int n)
{
N = n;
var D = new long[N + 1];
var bs = (1L << (N + N - 1)) - 1;
for (var k = 1; k <= N; k++)
{
D[k] = bs & ~1;
bs >>= 1;
}
return D;
}

// Print out a solution.
private static void WriteSolution(long[] D)
{
var l = new int[N + N + 1];
for (var k = 1; k <= N; k++)
{
for (var i = 1; i <= N + N; i++)
{
if (D[k] == 1L << i)
{
l[i] = k;
l[i + k + 1] = k;
}
}
}
for (var i = 1; i < l.Length; i++)
{
Console.Write("{0} ", l[i]);
}
Console.WriteLine();
}
}
}
``````

I decided to write a C# program to solve Langford problems. It runs very quickly up to n = 16, but thereafter you need to change it to use longs since it represents domains as bit patterns.

``````using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace Langford
{
// Compute Langford sequences.  A Langford sequence L(n) is a permutation of [1, 1, 2, 2, ..., n, n] such
// that the pair of 1s is separated by 1 place, the pair of 2s is separated by 2 places, and so forth.
//
class Program
{
static void Main(string[] args)
{
var n = 16;
InitLangford(n);
WriteDomains();
if (FindSolution())
{
Console.WriteLine();
Console.WriteLine("Solution for n = {0}:", n);
WriteDomains();
}
else
{
Console.WriteLine();
Console.WriteLine("No solution for n = {0}.", n);
}
}

// The n in L(n).
private static int N;

// D[k] is the set of unexcluded possible positions in the solution of the first k for each pair of ks.
// Each domain is represented as a bit pattern, where bit i is set iff i is in D[k].
private static int[] D;

// The trail records domain changes to undo on backtracking.  T[2k] gives the element in D to undo;
// T[2k+1] gives the value to which it must be restored.
private static List<int> T = new List<int> { };

// This is the index of the next unused entry in the trail.
private static int TTop;

// Extend the trail to restore D[k] on backtracking.
private static void TrailDomainValue(int k)
{
if (TTop == T.Count)
{
}
T[TTop++] = k;
T[TTop++] = D[k];
}

// Undo the trail to some earlier point.
private static void UntrailTo(int checkPoint)
{
//Console.WriteLine("Backtracking...");

while (TTop != checkPoint)
{
var d = T[--TTop];
var k = T[--TTop];
D[k] = d;
}
}

// Find the least bit in a domain; return 0 if the domain is empty.
private static int LeastBitInDomain(int d)
{
return d & ~(d - 1);
}

// Remove a bit from a domain.
private static int RemoveBitFromDomain(int d, int b)
{
return d & ~b;
}

private static bool DomainIsEmpty(int d)
{
return d == 0;
}

private static bool DomainIsSingleton(int d)
{
return (d == LeastBitInDomain(d));
}

// Return the size of a domain.
private static int DomainSize(int d)
{
var size = 0;
while (!DomainIsEmpty(d))
{
d = RemoveBitFromDomain(d, LeastBitInDomain(d));
size++;
}
return size;
}

// Find the k with the smallest non-singleton domain D[k].
// Returns zero if none exists.
private static int SmallestUndecidedDomainIndex()
{
var bestK = 0;
var bestKSize = int.MaxValue;
for (var k = 1; k <= N && 2 < bestKSize; k++)
{
var kSize = DomainSize(D[k]);
if (2 <= kSize && kSize < bestKSize)
{
bestK = k;
bestKSize = kSize;
}
}
return bestK;
}

// Prune the other domains when domain k is reduced to a singleton.
// Return false iff this exhausts some domain.
private static bool Prune(int k)
{
var newSingletons = new Queue<int>();
newSingletons.Enqueue(k);

while (newSingletons.Count != 0)
{
k = newSingletons.Dequeue();

//Console.WriteLine("Pruning from domain {0}.", k);

var b = D[k];
for (var j = 1; j <= N; j++)
{
if (j == k) continue;
var dOrig = D[j];
var d = dOrig;
d = RemoveBitFromDomain(d, b);
d = RemoveBitFromDomain(d, b << (k + 1));
d = RemoveBitFromDomain(d, b >> (j + 1));
d = RemoveBitFromDomain(d, (b << (k + 1)) >> (j + 1));
if (DomainIsEmpty(d)) return false;
if (d != dOrig)
{
TrailDomainValue(j);
D[j] = d;
if (DomainIsSingleton(d)) newSingletons.Enqueue(j);
}
}

//WriteDomains();
}
return true;
}

// Search for a solution.  Return false iff one is not found.
private static bool FindSolution() {
var k = SmallestUndecidedDomainIndex();
if (k == 0) return true;

// Branch on k, trying each possible assignment.
var dOrig = D[k];
var d = dOrig;
var checkPoint = TTop;
while (!DomainIsEmpty(d))
{
var b = LeastBitInDomain(d);
d = RemoveBitFromDomain(d, b);
D[k] = b;

//Console.WriteLine();
//Console.WriteLine("Branching on domain {0}.", k);

if (Prune(k) && FindSolution()) return true;
UntrailTo(checkPoint);
}
D[k] = dOrig;
return false;
}

// Print out a representation of the domains.
private static void WriteDomains()
{
for (var k = 1; k <= N; k++)
{
Console.Write("D[{0,3}] = {{", k);
for (var i = 1; i <= N + N; i++)
{
Console.Write("{0, 3}", ( (1 << i) & D[k]) != 0 ? i.ToString()
: DomainIsSingleton(D[k]) && (1 << i) == (D[k] << (k + 1)) ? "x"
: "");
}
Console.WriteLine(" }");
}
}

// Set up the problem.
private static void InitLangford(int n)
{
N = n;
D = new int[N + 1];
var bs = (1 << (N + N - 1)) - 1;
for (var k = 1; k <= N; k++)
{
D[k] = bs & ~1;
bs >>= 1;
}
}
}
}
``````
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could you give a hint in how would be a haskell solution?, I am reading your code, is really cool. – cMinor May 6 '11 at 18:46
@darkcminor, sure. In Haskell, the solution is even easier. You write your code to generate the search tree explicitly; you don't need a trail since you never backtrack - each branch of the tree keeps its own assignment. Laziness means you only manifest the part of the tree you are currently examining. Let me know if you need more help on this one. Cheers! – Rafe May 7 '11 at 11:12
@darkcminor, check out the new C# version. That should be trivial to recode in Haskell! – Rafe May 8 '11 at 7:13
Thanks Is a great answer and a great code – cMinor May 8 '11 at 16:03

I couldn't resist. Here's my port of Rafe's code to Haskell:

``````module Langford where

import Control.Applicative
import Data.Array
import Data.List
import Data.Ord
import Data.Tuple
import qualified Data.IntSet as S

langford :: Int -> [[Int]]
langford n
| mod n 4 `elem` [0, 3] = map (pairingToList n) . search \$ initial n
| otherwise             = []

type Variable = (Int, S.IntSet)
type Assignment = (Int, Int)
type Pairing = [Assignment]

initial :: Int -> [Variable]
initial n = [(i, S.fromList [1..(2*n-i-1)]) | i <- [1..n]]

search :: [Variable] -> [Pairing]
search [] = return []
search vs = do
let (v, vs') = choose vs
a <- assignments v
case prune a vs' of
Just vs'' -> (a :) <\$> search vs''
Nothing   -> mzero

choose :: [Variable] -> (Variable, [Variable])
choose vs = (v, filter (\(j, _) -> i /= j) vs)
where v@(i, _) = minimumBy (comparing (S.size . snd)) vs

assignments :: Variable -> [Assignment]
assignments (i, d) = [(i, k) | k <- S.toList d]

prune :: Assignment -> [Variable] -> Maybe [Variable]
prune a = mapM (prune' a)

prune' :: Assignment -> Variable -> Maybe Variable
prune' (i, k) (j, d)
| S.null d' = Nothing
| otherwise = Just (j, d')
where d' = S.filter (`notElem` [k, k+i+1, k-j-1, k+i-j]) d

pairingToList :: Int -> Pairing -> [Int]
pairingToList n = elems . array (1, 2*n) . concatMap positions
where positions (i, k) = [(k, i), (k+i+1, i)]
``````

It seems to work quite well. Here are some timings from GHCi:

``````Prelude Langford> :set +s
Prelude Langford> head \$ langford 4
[4,1,3,1,2,4,3,2]
(0.03 secs, 6857080 bytes)
Prelude Langford> head \$ langford 32
[32,28,31,23,26,29,22,24,27,15,17,11,25,10,30,5,20,2,21,19,2,5,18,11,10, ...]
(0.05 secs, 15795632 bytes)
Prelude Langford> head \$ langford 100
[100,96,99,91,94,97,90,92,95,83,85,82,93,78,76,73,88,70,89,87,69,64,86, ...]
(0.57 secs, 626084984 bytes)
``````
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Wow, here is a great code! – cMinor May 14 '11 at 7:05
Seconded - I really miss declarative languages! Still, have to pay the mortgage these days. – Rafe May 14 '11 at 9:46

Since the Langford sequences are usually generated for a small integer n, I use bogosort for this program and include a check everytime it is bogosorted. When the check completes, I'm done.

For example, with n=3:

• Create an array for 2n numbers. The array would be something like this: `1 2 3 1 2 3`
• Employ a simple loop for bogosort and include a check every time which is quite easy.
• If the check is successful, the array would give you the Langford sequence.

This will work fast for small integers only since the number of permutaions possible is n!, here: 3*2*1=6.

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