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Suppose I have a sorted list of things

{thing1, thing2, thing3, ...}

and a binary comparison function that says whether one thing should come before another in that sort order. (I say "things" because they need not be numbers; they can be arbitrary data structures.)

I now seek a function that takes

  • a sorted list of things,
  • a comparison function, and
  • a thing

and returns the first pair of adjacent things in the list that the new thing should be inserted between. That is, return the first adjacent pair {a,b} such that comp(a,x) and comp(x,b) are true, where comp() is the comparison function.

For example,

pigeon[{1,3,5,7}, Less, 4]

should return

{3,5}

(EDIT: If the given thing is less than the first element, a, of the list, then return {Null, a}. Likewise, if it's greater than the last element, z, then return {z, Null}. Additionally, we need to either assume that the comparison function returns true for two identical elements (ie, it's like LessEqual rather than Less) or that the list of things doesn't contain the thing being pigeoned. Thanks to High Performance Mark for catching that!)

My first thought was to use Split and then take the Last and First, respectively, of the resulting two sublists. I'll post that as an answer (or feel free to beat me to it) but I imagine there's a more efficient or elegant way.

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1  
binary search.. –  Gabi Purcaru Dec 19 '10 at 22:34
    
Are you assuming the list is sorted in order consistent with comparison function? –  Yaroslav Bulatov Dec 20 '10 at 3:44
    
@Yaroslav, yes. Feel free to edit the question to make that more clear. –  dreeves Dec 20 '10 at 6:01
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6 Answers

Using BinarySearch

Assumption: No repeated elements in list.

BinarySearch has an alternative form:

BinarySearch[l,k,f]
gives the position of k in the list obtained from l by applying f to 
each element in l.  

which may be used if your list is sorted by the results of the aforementioned "f".

Clear["Global`*"]; Needs["Combinatorica`"];
ret[list_, f_, elem_] := Module[{pos, last},
  pos[l_, e_, g_] := IntegerPart[BinarySearch[l, g[e], g]];
  {
   list[[pos[list, elem, f]]] /. List -> Null,
   If[(last = pos[list, elem, f] + 1) > Length@list, Null, list[[last]]]
  }
 ]  

a = {1, 2, 3, 4, 5};
b = SelectionSort[a, Cos[#1] < Cos[#2] &]

{3, 4, 2, 5, 1}  

Table[{x, N[Cos[x], 2], ret[b, Cos, x]}, 
     {x, 1, 6}]  

{{1,  0.54, {1, Null}}, 
 {2, -0.42, {2, 5}}, 
 {3, -0.99, {3, 4}}, 
 {4, -0.65, {4, 2}}, 
 {5,  0.28, {5, 1}}, 
 {6,  0.96, {1, Null}}
}  

ret[b, Cos, Pi]  
{Null, 3}
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Thanks so much for this answer, belisarius. Should everything above "Edit II" be ignored? If so, maybe delete it so the answer is more concise and since the edit history is preserved. –  dreeves Dec 20 '10 at 17:26
    
@dreeves Agree. Done. –  belisarius Dec 20 '10 at 19:04
    
Cool, thanks again! Nitpick: I meant the comparison function to be a binary function from things-cross-things to boolean. Also, are you sure you need the assumption about no repeated elements? –  dreeves Dec 20 '10 at 23:00
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I think this is a good solution:

Needs["Combinatorica`"]
pigeon[list_, func_, x_] := 
  Join[{Null}, list, {Null}]
    [[ {# - 1/2, # + 1/2}& @
     BinarySearch[list, 0.5, 
      Piecewise[{{0, func[#, x]}, {1, True}}] &] + 1 ]]

giving:

> pigeon[{1, 3, 5, 7}, LessEqual, 0]
{Null, 1}

> pigeon[{1, 3, 5, 7}, LessEqual, 3]
{3, 5}

> pigeon[{1, 3, 5, 7}, LessEqual, 4]
{3, 5}

> pigeon[{1, 3, 5, 7}, LessEqual, 9]
{7, Null}

Explanation: the Piecewise function is applied inside the BinarySearch to the list {1, 3, 5, 7}, to check which elements are LessEqual, the BinarySearch than finds the position of the end of this mark, and the relevant elements are returned. This implementation uses only BinarySearch, so it suppose to be quite efficient.

This function can be easily changed to return in the second case {1, 3} instead.
Alternatively, if 'x' can be an element of 'list', something like this:

Needs["Combinatorica`"]
pigeon[list_, func_, 
  x_] := (Join[{Null}, 
    list, {Null}])[[Select[{# - 1/2, #, # + 1/2} &@
      BinarySearch[list, 0, 
       Piecewise[{{0, # == x}, {-1, func[#, x]}, {1, True}}] &], 
     IntegerQ] + 1]]

will give:

> pigeon[{1, 3, 5, 7}, LessEqual, 3]
{3}
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It's late, so here's a partial solution to a partially specified function:

f[l_List, compFun_Symbol, el_] := 
 Sort[l, compFun] /. {a___, b_ /; compFun[b, el], 
    c_ /; compFun[el, c], d___} -> {b, c}

I've taken the liberty of not requiring that the list supplied to the function f be sorted, since the input arguments include the comparison function. This function works well as long as (a) the element el is not a member of l and (b) there are elements in l sorted to both left and right of el. It probably doesn't work for LessEqual or GreaterEqual either.

If you care to clarify what you'd like the function to return when either or both of (a) and (b) is not met, I'll be happy to have another look at this in the morning.

EDIT:

I think this satisfies the revised requirements. As before, it doesn't require that the input list be already sorted.

f2[l_List, compFun_, el_] := Sort[Append[l, el], compFun] /. 
{a___, el, b___} :> {If[{a}==={}, Null, Last@{a}], If[{b}==={}, Null, First@{b}]}

I'll leave it to others to judge the elegance and efficiency of this solution (I can see some obvious improvements in the latter respect). Now to get back to work.

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Ah, thanks for pointing out the underspecification! I clarified the question. –  dreeves Dec 20 '10 at 3:38
    
What happened to the comparison function in your second answer? (That was probably my fault if you misinterpreted my "assume it's a 'less than or equal' function". I clarified the clarification in the question.) See also my comment to belisarius. This is a cool approach; thanks! –  dreeves Dec 20 '10 at 17:43
    
Yes, I interpreted you original clarification in such a way that I discarded the comparison operator. Shouldn't be too difficult for you to put it back in. –  High Performance Mark Dec 20 '10 at 21:56
    
Cool, ok, I edited it to put compFun back in (and condensed it slightly while I was at it). –  dreeves Dec 20 '10 at 23:17
    
@dreeves: I'd upvote (y)our answer if I could. –  High Performance Mark Dec 21 '10 at 9:37
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One possible approach:

lst = {1, 3, 5, 7, 9, 11}

{Last@#1, First@#2} & @@ GatherBy[lst, Less[4, #] &]

Output = {3, 5}

Alternatively, SplitBy may be substituted for GatherBy.

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Nice! I think Split should be more efficient than Gather since Split only considers adjacent elements and thus only has to make a single pass. Of course even that's wasteful. We should stop walking through the list as soon as we find the adjacent pair we want to return. –  dreeves Dec 20 '10 at 3:42
    
@dreeves. Agreed, on both points. –  TomD Dec 20 '10 at 9:59
    
I'm now liking Select better, as far as O(n) algorithms go. Or maybe the pattern-matching solution; not sure yet. Nitpick: I'm not sure your answer is sufficiently general. Probably my fault. See my comment to High Performance Mark. –  dreeves Dec 20 '10 at 17:47
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Here's a solution using Select (note the third argument) that takes at most one pass through the list, stopping when it finds the pigeonhole:

pigeon[l_, f_, x_] := Module[{p, r},
  p = Null;
  r = Select[l, If[f[x,#], True, p = #; False]&, 1];
  If[r==={}, {Last@l, Null}, {p, First@r}]]

Examples:

> pigeon[{1,3,5,7}, LessEqual, 4]
{3, 5}

> pigeon[{1,3,5,7}, LessEqual, 0]
{Null, 1}

> pigeon[{1,3,5,7}, LessEqual, 9]
{7, Null}
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Here's another binary search answer:

(* Helper for pigeon. Additional arguments a and b give current bounds on the 
   indices of the pigeonhole. *)
pigeon0[l_, f_, x_, a_, b_] := Which[
  b-a==1,                    {l[[a]], l[[b]]},
  f[x, l[[Floor[(a+b)/2]]]], pigeon0[l, f, x, a, Floor[(a+b)/2]],
  True,                      pigeon0[l, f, x, Floor[(a+b)/2], b]]

pigeon[l_, f_, x_] := Which[
  f[x, First@l],                 {Null, First@l},
  f[Last@l, x] && !f[x, Last@l], {Last@l, Null},
  True,                          pigeon0[l, f, x, 1, Length@l]]

I tried it like this:

> l = Sort@RandomReal[{0,1}, {10^6}];
> pigeon[l, LessEqual, .5]
{0.4999991874459364, 0.5000000938493356}

That matches my other answer (the one with Select) but is much faster.

Other examples:

> pigeon[{1,3,5,7}, LessEqual, 4]
{3, 5}

> pigeon[{1,3,5,7}, LessEqual, 0]
{Null, 1}

> pigeon[{1,3,5,7}, LessEqual, 9]
{7, Null}
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