I need to quickly save a re-ordered sequence back to my items' integer sortOrder columns.

The simple renumber-by-one approach can be slow - if last item moved to first, all N rows are modified. A multi-row update statement would let database do the work, but I'd like to explore smarter ways, like making sortOrder floating point except I don't have that option :(

The solution I imagine would take a renumbered list like this: (100,200,1700,300,400...1600,1800,...) and produce (100,200,250,300,400...1600,1800,...) (by modifying one row in this example). It seems simple at first, but I'm having a hard time expressing it in code...

Can someone help me with this logic? There could be sequences of adjacent items that need to be shifted for a new one to fit - I was hoping someone might have this already written? It has to be faster than what I have now, but still readable and simple to understand/maintain.

OK, after answer, posting back with resulting code I came up with (comments welcome):

```
/**
* Renumber list with minimal changes
*
* Given a list of SortOrderNumbers in the 'new' sequence they are to be saved in, determine the
* minimal set of changes (described by Change(i, newSortOrderNumber)) that can be saved that
* results in a properly ordered sequence.
*
* A simple answer would always be List(change<1,1>, change<2,2>, ...change<n,n>) which is of length N.
* This method returns a set of changes no larger than N (often much smaller for simple moves).
*
* @author Jim Pinkham
* @param s
* @return Set<Change>
*/
private Set<Change> renumber(int[] s) {
Set<Change> ret = new HashSet<Change>();
// pass1 goes from start forwards looking for decrease in numbering
for (int i=1; i<s.length; i++) {
// if predecessor of item is larger and it's large enough to renumber from start of list
if (s[i-1]>s[i] && s[i]>i) {
int beforeStart=0;
int beforeIndex=-1;
// go back towards start looking for anchor
for (int j=i-2; j>=0; --j) {
int diff = s[i]-s[j];
if (diff>(i-j)) {
beforeIndex=j;
beforeStart=s[beforeIndex];
break;
}
}
int diff = s[i]-beforeStart;
int stepsToDiff=i-beforeIndex;
int delta = diff/stepsToDiff;
// renumber from start of list or anchor thru decrease
int fixCnt=0;
for (int j=beforeIndex+1; j<i; ++j) {
s[j] = beforeStart + (delta*++fixCnt);
System.out.println("s["+j+"]="+s[j]);
ret.add(new Change(j, s[j]));
}
}
}
// pass1 could leave some decreases in sequence
// pass2 goes from end back to start
for (int i=s.length-1; i>0; i--) {
// if predecessor of item is larger
if (s[i-1] > s[i]) {
int afterIndex=s.length;
int delta=DEFAULT_RENUMBER_GAP;
// go back towards end looking for anchor
for (int j=i; j<s.length; ++j) {
int diff = s[j]-s[i-1];
if (diff>(j-(i-1))) {
afterIndex=j;
int afterEnd=s[afterIndex];
int stepsToDiff=afterIndex-(i-1);
int gap = afterEnd-s[i-1];
delta = gap/stepsToDiff;
break;
}
}
// renumber from decrease thru anchor or end of list
int fixCnt=0;
for (int j=i; j<afterIndex; ++j) {
s[j] = s[i-1] + (delta*++fixCnt);
System.out.println("s["+j+"]="+s[j]);
ret.add(new Change(j, s[j]));
}
}
}
return ret;
}
class Change {
int i;
int sortOrder;
Change(int i, int sortOrder) {
this.i=i; this.sortOrder=sortOrder;
}
public boolean equals(Change other) {
return Integer.valueOf(i).equals(Integer.valueOf(other.i));
}
public int hashCode() {
return Integer.valueOf(i).hashCode();
}
}
```