private void init()
{
this.cdif = this.compact_diff(this.left, this.right);
this._Same = true;
if ((this.cdif[2] == 0) && (this.cdif[3] == 0))
{
this._Same = false;
this.cdif.RemoveAt(0);
this.cdif.RemoveAt(0);
}
this._End = (1 + this.cdif.Count) / 2;
}
void init()
{
cdif = compact_diff(left, right);
_Same = true;
if (0 == (int)cdif[2] && 0 == (int)cdif[3])
{
_Same = false;
cdif.RemoveAt(0);
cdif.RemoveAt(0);
}
_End = (1 + cdif.Count) / 2;
}
void init()
{
compactDiff = compact_diff(left, right);
same = true;
if (0 == compactDiff[2] && 0 == compactDiff[3])
{
same = false;
compactDiff.RemoveAt(0);
compactDiff.RemoveAt(0);
}
end = (1 + compactDiff.Count) / 2;
}
/*void prepare(IList list) {
* prepared = _withPositionsOfInInterval(list, 0, list.Count-1);
* preparedlist = list;
* }*/
void LongestCommonSubsequenceIndex(IList a, IList b, out IntList am, out IntList bm)
{
IntList match = LongestCommonSubsequence(a, b);
am = new IntList();
for (int i = 0; i < match.Count; i++)
{
if (match[i] != -1)
{
am.Add(i);
}
}
bm = new IntList();
for (int vi = 0; vi < am.Count; vi++)
{
bm.Add(match[am[vi]]);
}
}
private void LCSidx(IList a, IList b, out IntList am, out IntList bm)
{
IntList list = this._longestCommonSubsequence(a, b);
am = new IntList();
for (int i = 0; i < list.Count; i++)
{
if (list[i] != -1)
{
am.Add(i);
}
}
bm = new IntList();
for (int j = 0; j < am.Count; j++)
{
bm.Add(list[am[j]]);
}
}
/*
# Find the place at which aValue would normally be inserted into the
# array. If that place is already occupied by aValue, do nothing, and
# return undef. If the place does not exist (i.e., it is off the end of
# the array), add it to the end, otherwise replace the element at that
# point with aValue. It is assumed that the array's values are numeric.
# This is where the bulk (75%) of the time is spent in this module, so
# try to make it fast!
*/
// NOTE: Instead of returning undef, it returns -1.
int ReplaceNextLargerWith(IntList array, int value, int high)
{
if (high <= 0)
{
high = array.Count - 1;
}
// off the end?
if (high == -1 || value > array[array.Count - 1])
{
array.Add(value);
return(array.Count - 1);
}
// binary search for insertion point...
int low = 0;
while (low <= high)
{
int index = (high + low) / 2;
int found = array[index];
if (value == found)
{
return(-1);
}
if (value > found)
{
low = index + 1;
}
else
{
high = index - 1;
}
}
// # now insertion point is in $low.
array[low] = value; // overwrite next larger
return(low);
}
IntList compact_diff(IList a, IList b)
{
IntList am, bm;
LongestCommonSubsequenceIndex(a, b, out am, out bm);
IntList newCompactDiff = new IntList();
int ai = 0, bi = 0;
newCompactDiff.Add(ai);
newCompactDiff.Add(bi);
while (true)
{
while (am.Count > 0 && ai == am[0] && bi == bm[0])
{
am.RemoveAt(0);
bm.RemoveAt(0);
++ai;
++bi;
}
newCompactDiff.Add(ai);
newCompactDiff.Add(bi);
if (am.Count == 0)
{
break;
}
ai = am[0];
bi = bm[0];
newCompactDiff.Add(ai);
newCompactDiff.Add(bi);
}
if (ai < a.Count || bi < b.Count)
{
newCompactDiff.Add(a.Count);
newCompactDiff.Add(b.Count);
}
return(newCompactDiff);
}
IntList compact_diff(IList a, IList b)
{
IntList am, bm, cdiff;
LCSidx(a, b, out am, out bm);
cdiff = new IntList();
int ai = 0, bi = 0;
cdiff.Add(ai);
cdiff.Add(bi);
while (true)
{
while (am.Count > 0 && ai == (int)am[0] && bi == (int)bm[0])
{
am.RemoveAt(0);
bm.RemoveAt(0);
++ai;
++bi;
}
cdiff.Add(ai);
cdiff.Add(bi);
if (am.Count == 0)
{
break;
}
ai = (int)am[0];
bi = (int)bm[0];
cdiff.Add(ai);
cdiff.Add(bi);
}
if (ai < a.Count || bi < b.Count)
{
cdiff.Add(a.Count);
cdiff.Add(b.Count);
}
return(cdiff);
}
private IntList compact_diff(IList a, IList b)
{
IntList am;
IntList bm;
this.LCSidx(a, b, out am, out bm);
IntList list3 = new IntList();
int num = 0;
int num2 = 0;
list3.Add(num);
list3.Add(num2);
while (true)
{
while (((am.Count > 0) && (num == am[0])) && (num2 == bm[0]))
{
am.RemoveAt(0);
bm.RemoveAt(0);
num++;
num2++;
}
list3.Add(num);
list3.Add(num2);
if (am.Count == 0)
{
break;
}
num = am[0];
num2 = bm[0];
list3.Add(num);
list3.Add(num2);
}
if ((num < a.Count) || (num2 < b.Count))
{
list3.Add(a.Count);
list3.Add(b.Count);
}
return(list3);
}
private Hashtable _withPositionsOfInInterval(IList aCollection, int start, int end)
{
Hashtable hashtable = new Hashtable(this.hashcoder);
for (int i = start; i <= end; i++)
{
object key = aCollection[i];
if (hashtable.ContainsKey(key))
{
((IntList)hashtable[key]).Add(i);
}
else
{
IntList list2 = new IntList();
list2.Add(i);
hashtable[key] = list2;
}
}
foreach (IntList list3 in hashtable.Values)
{
list3.Reverse();
}
return(hashtable);
}
IntList _longestCommonSubsequence(IList a, IList b)
{
int aStart = 0;
int aFinish = a.Count-1;
IntList matchVector = new IntList();
Hashtable bMatches;
// initialize matchVector to length of a
for (int i = 0; i < a.Count; i++)
matchVector.Add(-1);
if (!IsPrepared(out bMatches)) {
int bStart = 0;
int bFinish = b.Count-1;
// First we prune off any common elements at the beginning
while (aStart <= aFinish && bStart <= bFinish && compare(a[aStart], b[bStart]))
matchVector[aStart++] = bStart++;
// now the end
while (aStart <= aFinish && bStart <= bFinish && compare(a[aFinish], b[bFinish]))
matchVector[aFinish--] = bFinish--;
// Now compute the equivalence classes of positions of elements
bMatches =
_withPositionsOfInInterval(b, bStart, bFinish);
}
IntList thresh = new IntList();
TrioList links = new TrioList();
for (int i = aStart; i <= aFinish; i++) {
IntList aimatches = (IntList)bMatches[a[i]];
if (aimatches != null) {
int k = 0;
for (int ji = 0; ji < aimatches.Count; ji++) {
int j = aimatches[ji];
// # optimization: most of the time this will be true
if (k>0 && (int)thresh[k] > j && (int)thresh[k-1] < j)
thresh[k] = j;
else
k = _replaceNextLargerWith(thresh, j, k);
// oddly, it's faster to always test this (CPU cache?).
if (k != -1) {
Trio t = new Trio( (Trio)( k>0 ? links[k-1] : null ), i, j );
if (k == links.Count)
links.Add( t );
else
links[k] = t;
}
}
}
}
if (thresh.Count > 0) {
for (Trio link = (Trio)links[thresh.Count-1]; link != null; link = link.a)
matchVector[link.b] = link.c;
}
return matchVector;
}
void init()
{
cdif = compact_diff(left, right);
_Same = true;
if (0 == (int)cdif[2] && 0 == (int)cdif[3]) {
_Same = false;
cdif.RemoveAt(0);
cdif.RemoveAt(0);
}
_End = (1+cdif.Count)/2;
}
/*void prepare(IList list) {
prepared = _withPositionsOfInInterval(list, 0, list.Count-1);
preparedlist = list;
}*/
void LCSidx(IList a, IList b, out IntList am, out IntList bm)
{
IntList match = _longestCommonSubsequence(a, b);
am = new IntList();
for (int i = 0; i < match.Count; i++)
if ((int)match[i] != -1)
am.Add(i);
bm = new IntList();
for (int vi = 0; vi < am.Count; vi++)
bm.Add(match[am[vi]]);
}
IntList compact_diff(IList a, IList b)
{
IntList am, bm, cdiff;
LCSidx(a, b, out am, out bm);
cdiff = new IntList();
int ai = 0, bi = 0;
cdiff.Add(ai);
cdiff.Add(bi);
while (true) {
while(am.Count > 0 && ai == (int)am[0] && bi == (int)bm[0]) {
am.RemoveAt(0);
bm.RemoveAt(0);
++ai;
++bi;
}
cdiff.Add(ai);
cdiff.Add(bi);
if (am.Count == 0) break;
ai = (int)am[0];
bi = (int)bm[0];
cdiff.Add(ai);
cdiff.Add(bi);
}
if (ai < a.Count || bi < b.Count) {
cdiff.Add(a.Count);
cdiff.Add(b.Count);
}
return cdiff;
}
private IntList _longestCommonSubsequence(IList a, IList b)
{
Hashtable bMatches;
int num = 0;
int num2 = a.Count - 1;
IntList list = new IntList();
for (int i = 0; i < a.Count; i++)
{
list.Add(-1);
}
if (!this.IsPrepared(out bMatches))
{
int start = 0;
int end = b.Count - 1;
while (((num <= num2) && (start <= end)) && this.compare(a[num], b[start]))
{
list[num++] = start++;
}
while (((num <= num2) && (start <= end)) && this.compare(a[num2], b[end]))
{
list[num2--] = end--;
}
bMatches = this._withPositionsOfInInterval(b, start, end);
}
IntList array = new IntList();
ArrayList list3 = new ArrayList();
for (int j = num; j <= num2; j++)
{
IntList list4 = (IntList)bMatches[a[j]];
if (list4 != null)
{
int high = 0;
for (int k = 0; k < list4.Count; k++)
{
int num9 = list4[k];
if (((high > 0) && (array[high] > num9)) && (array[high - 1] < num9))
{
array[high] = num9;
}
else
{
high = this._replaceNextLargerWith(array, num9, high);
}
if (high != -1)
{
Trio trio = new Trio((high > 0) ? ((Trio)list3[high - 1]) : null, j, num9);
if (high == list3.Count)
{
list3.Add(trio);
}
else
{
list3[high] = trio;
}
}
}
}
}
if (array.Count > 0)
{
for (Trio trio2 = (Trio)list3[array.Count - 1]; trio2 != null; trio2 = trio2.a)
{
list[trio2.b] = trio2.c;
}
}
return(list);
}
IntList compact_diff(IList a, IList b)
{
IntList am, bm;
LongestCommonSubsequenceIndex(a, b, out am, out bm);
IntList newCompactDiff = new IntList();
int ai = 0, bi = 0;
newCompactDiff.Add(ai);
newCompactDiff.Add(bi);
while (true)
{
while (am.Count > 0 && ai == am[0] && bi == bm[0])
{
am.RemoveAt(0);
bm.RemoveAt(0);
++ai;
++bi;
}
newCompactDiff.Add(ai);
newCompactDiff.Add(bi);
if (am.Count == 0) break;
ai = am[0];
bi = bm[0];
newCompactDiff.Add(ai);
newCompactDiff.Add(bi);
}
if (ai < a.Count || bi < b.Count)
{
newCompactDiff.Add(a.Count);
newCompactDiff.Add(b.Count);
}
return newCompactDiff;
}
void init()
{
compactDiff = compact_diff(left, right);
same = true;
if (0 == compactDiff[2] && 0 == compactDiff[3])
{
same = false;
compactDiff.RemoveAt(0);
compactDiff.RemoveAt(0);
}
end = (1 + compactDiff.Count) / 2;
}
/*
# Find the place at which aValue would normally be inserted into the
# array. If that place is already occupied by aValue, do nothing, and
# return undef. If the place does not exist (i.e., it is off the end of
# the array), add it to the end, otherwise replace the element at that
# point with aValue. It is assumed that the array's values are numeric.
# This is where the bulk (75%) of the time is spent in this module, so
# try to make it fast!
*/
// NOTE: Instead of returning undef, it returns -1.
int _replaceNextLargerWith(IntList array, int value, int high)
{
if (high <= 0)
high = array.Count-1;
// off the end?
if (high == -1 || value > (int)array[array.Count-1]) {
array.Add(value);
return array.Count-1;
}
// binary search for insertion point...
int low = 0;
int index, found;
while (low <= high) {
index = (high + low) / 2;
found = (int)array[index];
if (value == found)
return -1;
else if (value > found)
low = index + 1;
else
high = index - 1;
}
// # now insertion point is in $low.
array[low] = value; // overwrite next larger
return low;
}
/*
# McIlroy-Hunt diff algorithm
# Adapted from the Smalltalk code of Mario I. Wolczko, <*****@*****.**>
# by Ned Konz, [email protected]
# Updates by Tye McQueen, http://perlmonks.org/?node=tye
# Create a hash that maps each element of $aCollection to the set of
# positions it occupies in $aCollection, restricted to the elements
# within the range of indexes specified by $start and $end.
# The fourth parameter is a subroutine reference that will be called to
# generate a string to use as a key.
# Additional parameters, if any, will be passed to this subroutine.
#
# my $hashRef = _withPositionsOfInInterval( \@array, $start, $end, $keyGen );
*/
Hashtable _withPositionsOfInInterval(IList aCollection, int start, int end)
{
Hashtable d = new Hashtable(hashcoder, comparer);
for (int index = start; index <= end; index++) {
object element = aCollection[index];
if (d.ContainsKey(element)) {
IntList list = (IntList)d[element];
list.Add(index);
} else {
IntList list = new IntList();
list.Add(index);
d[element] = list;
}
}
foreach (IntList list in d.Values)
list.Reverse();
return d;
}
IntList LongestCommonSubsequence(IList a, IList b)
{
int aStart = 0;
int aFinish = a.Count - 1;
IntList matchVector = new IntList();
Hashtable bMatches;
// initialize matchVector to length of a
for (int i = 0; i < a.Count; i++)
{
matchVector.Add(-1);
}
if (!IsPrepared(out bMatches))
{
int bStart = 0;
int bFinish = b.Count - 1;
// First we prune off any common elements at the beginning
while (aStart <= aFinish && bStart <= bFinish && compare(a[aStart], b[bStart]))
{
matchVector[aStart++] = bStart++;
}
// now the end
while (aStart <= aFinish && bStart <= bFinish && compare(a[aFinish], b[bFinish]))
{
matchVector[aFinish--] = bFinish--;
}
// Now compute the equivalence classes of positions of elements
bMatches =
WithPositionsOfInInterval(b, bStart, bFinish);
}
IntList thresh = new IntList();
TrioList links = new TrioList();
for (int i = aStart; i <= aFinish; i++)
{
IntList aimatches = (IntList)bMatches[a[i]];
if (aimatches != null)
{
int k = 0;
for (int ji = 0; ji < aimatches.Count; ji++)
{
int j = aimatches[ji];
// # optimization: most of the time this will be true
if (k > 0 && thresh[k] > j && thresh[k - 1] < j)
{
thresh[k] = j;
}
else
{
k = ReplaceNextLargerWith(thresh, j, k);
}
// oddly, it's faster to always test this (CPU cache?).
if (k != -1)
{
Trio t = new Trio((Trio)(k > 0 ? links[k - 1] : null), i, j);
if (k == links.Count)
{
links.Add(t);
}
else
{
links[k] = t;
}
}
}
}
}
if (thresh.Count > 0)
{
for (Trio link = (Trio)links[thresh.Count - 1]; link != null; link = link.a)
{
matchVector[link.b] = link.c;
}
}
return(matchVector);
}
