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When reading about forward_list in the FCD of C++11 and N2543 I stumbled over one specific overload of splice_after (slightly simplified and let cit be const_iterator):

void splice_after(cit pos, forward_list<T>& x, cit first, cit last);

The behavior is that after pos everything between (first,last) is moved to this. Thus:

  this: 1 2 3 4 5 6           x: 11 12 13 14 15 16
          ^pos                      ^first   ^last
will become:
  this: 1 2 13 14 3 4 5 6     x: 11 12       15 16
          ^pos                      ^first   ^last

The description includes the complexity:

Complexity: O(distance(first, last))

I can see that this is because one needs to adjust PREDECESSOR(last).next = pos.next, and the forward_list does not allow this to happen in O(1).

Ok, but isn't joining two singly linked lists in O(1) one of the strengths of this simple data structure? Therefore I wonder -- is there no operation on forward_list that splices/merges/joins an arbitrary number of elements in O(1)?

The algorithm would be quite simple, of course. One would just need a name for the operation (pseudocode): (Updated by integrating Kerreks answer)

temp_this  =   pos.next;
temp_that  =  last.next;
  pos.next = first.next;
 last.next =  temp_this;
first.next =  temp_that;

The result is a bit different, because not (first,last) is moved, but (first,last].

  this: 1 2 3 4 5 6 7               x: 11 12 13 14 15 16 17
          ^pos                            ^first      ^last
will become:
  this: 1 2 13 14 15 16 3 4 5 6 7   x: 11 12             17
          ^pos       ^last                ^first   

I would think this is an as reasonable operation like the former one, that people might would like to do -- especially if it has the benefit of being O(1).

  • Am I overlooking a operation that is O(1) on many elements?
  • Or is my assumption wrong that (first,last] might be useful as the moved range?
  • Or is there an error in the O(1) algorithm?
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The details of your solution are a bit off, but the question is good. +1 –  Kerrek SB Oct 10 '11 at 14:57
1  
because not (first,last) is moved, but (first,last]. This exactly is the point, all standard algorithms work with that assumption, having such an exception would confuse people. –  PlasmaHH Oct 10 '11 at 14:58
1  
@PlasmaHH Isn't splice_after already violating the the standard assumptions, as all other algorithms work with [first,last)? –  Christian Rau Oct 10 '11 at 15:10
    
If there were a before_end iterator, then it could indeed be done. –  Kerrek SB Oct 10 '11 at 15:11
    
@ChristianRau: Indeed. See how confusing this is? and how confusing would it be to have yet another deviating version. Standard containers are created for easy use, not for ultimate performance. –  PlasmaHH Oct 10 '11 at 15:24

3 Answers 3

up vote 1 down vote accepted

Your algorithm fails when you pass in end() as last because it will try to use the one-past-end node and relink it into the other list. It would be a strange exception to allow end() to be used in every algorithm except this one.

Also I think first.next = &last; needs to be first.next = last.next; because otherwise last will be in both lists.

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Ah! Of course! Very good point! –  towi Oct 10 '11 at 15:40

Let me first give a corrected version of your O(1) splicing algorithm, with an example:

temp_this  =   pos.next;
temp_that  =  last.next;

  pos.next = first.next;
 last.next =  temp_this;
first.next =  temp_that;

(A sanity check is to observe that every variable appears precisely twice, once set and once got.)

Example:

    pos.next                           last.next
    v                                  v
1 2 3 4 5 6 7        11 12 13 14 15 16 17 #    
  ^                     ^           ^     ^
  pos                   first       last  end             


becomes:

This:     1 2 13 14 15 16 3 4 5 6 7

That:   11 12             17

Now we see that in order to splice up to the end of that list, we need to provide an iterator to one before the end(). However, no such iterator exists in constant time. So basically the linear cost comes from discovering the final iterator, one way or another: Either you precompute it in O(n) time and use your algorithm, or you just splice one-by-one, also in linear time.

(Presumably you could implement your own singly-linked list that would store an additional iterator for before_end, which you'd have to keep updated during the relevant operations.)

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We do have "one before the end". It is last.next, isn't it? –  towi Oct 10 '11 at 15:40
    
I think I wasn't clear enough. The problem is that your proposed algorithm is only useful if one can sensibly obtain an iterator to the last element of the desired sequence, but that isn't possible in constant time in general. So the entire algorithm isn't deemed useful. In other words, how did you come by the last iterator in the first place? –  Kerrek SB Oct 10 '11 at 15:46
    
@towi: he means one before last. –  Dani Oct 10 '11 at 15:47
    
Yep. Got it from the other answers. –  towi Oct 10 '11 at 15:49
    
@Dani: No, not really. What I meant was that in general there isn't a constant-time operation that obtains a good end iterator. Coming to think of it, one could probably offer this algorithm as an alternative for situations in which you already obtained the iterator pair by other means. That sounds like something that would be situationally useful. –  Kerrek SB Oct 10 '11 at 15:49

There was considerable debate within the LWG over this issue. See LWG 897 for some of the documentation of this issue.

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