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Compare feature part 3: Implement the find_middle_snake algorithm.

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The feature should now be up and running, although it might have some performance issues. Please test with small changes :S as it scales quadratic with the size of a single change. 

git-svn-id: svn://svn.lyx.org/lyx/lyx-devel/trunk@32930 a592a061-630c-0410-9148-cb99ea01b6c8
This commit is contained in:
Vincent van Ravesteijn 2010-01-10 00:09:48 +00:00
parent 1fe4ff8ef3
commit 9cfebdb969
1 changed files with 193 additions and 3 deletions
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196
src/Compare.cpp
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@ -275,6 +275,26 @@ private:
/// shortest edit script. /// shortest edit script.
int find_middle_snake(DocRangePair const & rp, DocPair & middle_snake); int find_middle_snake(DocRangePair const & rp, DocPair & middle_snake);
enum SnakeResult {
NoSnake,
SingleSnake,
NormalSnake
};
/// Retrieve the middle snake when there is overlap between
/// the forward and backward path.
SnakeResult retrieve_middle_snake(int k, int D, Direction direction,
DocPair & middle_snake);
/// Find the the furthest reaching D-path (number of horizontal
/// and vertical steps; differences between the old and new
/// document) in the k-diagonal (vertical minus horizontal steps).
void furthest_Dpath_kdiagonal(int D, int k,
DocRangePair const & rp, Direction direction);
/// Is there overlap between the forward and backward path
bool overlap(int k, int D);
/// This function is called recursively by a divide and conquer /// This function is called recursively by a divide and conquer
/// algorithm. Each time, the string is divided into two split /// algorithm. Each time, the string is divided into two split
/// around the middle snake. /// around the middle snake.
@ -303,6 +323,11 @@ private:
int N_; int N_;
/// The length of the new chunk currently processed /// The length of the new chunk currently processed
int M_; int M_;
/// The offset diagonal of the reverse path of the
/// currently processed chunk
int offset_reverse_diagonal_;
/// Is the offset odd or even ?
bool odd_offset_;
/// The thread object, used to emit signals to the GUI /// The thread object, used to emit signals to the GUI
Compare const & compare_; Compare const & compare_;
@ -322,6 +347,17 @@ private:
/// The number of nested insets at this level /// The number of nested insets at this level
int nested_inset_level_; int nested_inset_level_;
/// The position/snake in the old/new document
/// of the forward/reverse search
compl_vector<DocIterator> ofp;
compl_vector<DocIterator> nfp;
compl_vector<DocIterator> ofs;
compl_vector<DocIterator> nfs;
compl_vector<DocIterator> orp;
compl_vector<DocIterator> nrp;
compl_vector<DocIterator> ors;
compl_vector<DocIterator> nrs;
}; };
///////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////
@ -477,12 +513,166 @@ static bool traverse_snake(DocPair & p, DocRangePair const & range,
// //
///////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////
int Compare::Impl::find_middle_snake(DocRangePair const & rp,
DocPair &) void Compare::Impl::furthest_Dpath_kdiagonal(int D, int k,
DocRangePair const & rp, Direction direction)
{ {
++furthest_Dpath_kdiagonal_count;
compl_vector<DocIterator> * op = direction == Forward ? &ofp : &orp;
compl_vector<DocIterator> * np = direction == Forward ? &nfp : &nrp;
compl_vector<DocIterator> * os = direction == Forward ? &ofs : &ors;
compl_vector<DocIterator> * ns = direction == Forward ? &nfs : &nrs;
// A vertical step means stepping one character in the new document.
bool vertical_step = k == -D;
if (!vertical_step && k != D) {
vertical_step = direction == Forward
? op->get(k - 1) < op->get(k + 1)
: op->get(k - 1) > op->get(k + 1);
}
// Where do we take the step from ?
int const kk = vertical_step ? k + 1 : k - 1;
DocPair p(op->get(kk), np->get(kk));
// If D==0 we simulate a vertical step from (0,-1) by doing nothing.
if (D != 0) {
// Take a step
if (vertical_step && direction == Forward)
step(p.n, rp.n.to, direction);
else if (vertical_step && direction == Backward)
step(p.n, rp.n.from, direction);
else if (!vertical_step && direction == Forward)
step(p.o, rp.o.to, direction);
else if (!vertical_step && direction == Backward)
step(p.o, rp.o.from, direction);
}
// Traverse snake
if (traverse_snake(p, rp, direction)) {
// Record last snake
os->set(k, p.o);
ns->set(k, p.n);
} else {
// Copy last snake from the previous step
os->set(k, os->get(kk));
ns->set(k, ns->get(kk));
}
//Record new position
op->set(k, p.o);
np->set(k, p.n);
}
bool Compare::Impl::overlap(int k, int D)
{
++overlap_count;
// To generalize for the forward and reverse checks
int kk = offset_reverse_diagonal_ - k;
// Can we have overlap ?
if (kk <= D && kk >= -D) {
// Do we have overlap ?
if (odd_offset_)
return ofp.get(k) >= orp.get(kk) && nfp.get(k) >= nrp.get(kk);
else
return ofp.get(kk) >= orp.get(k) && nfp.get(kk) >= nrp.get(k);
}
return false;
}
Compare::Impl::SnakeResult Compare::Impl::retrieve_middle_snake(
int k, int D, Direction direction, DocPair & middle_snake)
{
++middle_snake_count;
compl_vector<DocIterator> * os = direction == Forward ? &ofs : &ors;
compl_vector<DocIterator> * ns = direction == Forward ? &nfs : &nrs;
compl_vector<DocIterator> * os_r = direction == Forward ? &ors : &ofs;
compl_vector<DocIterator> * ns_r = direction == Forward ? &nrs : &nfs;
// The diagonal while doing the backward search
int kk = -k + offset_reverse_diagonal_;
// Did we find a snake ?
if (os->get(k).empty() && os_r->get(kk).empty()) {
// No, there is no snake at all, in which case
// the length of the shortest edit script is M+N.
LASSERT(2 * D - odd_offset_ == M_ + N_, /**/);
return NoSnake;
}
if (os->get(k).empty()) {
// Yes, but there is only 1 snake and we found it in the
// reverse path.
middle_snake.o = os_r->get(kk);
middle_snake.n = ns_r->get(kk);
return SingleSnake;
}
middle_snake.o = os->get(k);
middle_snake.n = ns->get(k);
return NormalSnake;
}
int Compare::Impl::find_middle_snake(DocRangePair const & rp,
DocPair & middle_snake)
{
// The lengths of the old and new chunks.
N_ = rp.o.length(); N_ = rp.o.length();
M_ = rp.n.length(); M_ = rp.n.length();
return M_ + N_;
// Forward paths are centered around the 0-diagonal; reverse paths
// are centered around the diagonal N - M. (Delta in the article)
offset_reverse_diagonal_ = N_ - M_;
// If the offset is odd, only check for overlap while extending forward
// paths, otherwise only check while extending reverse paths.
odd_offset_ = (offset_reverse_diagonal_ % 2 != 0);
ofp.reset(rp.o.from);
nfp.reset(rp.n.from);
ofs.reset(DocIterator());
nfs.reset(DocIterator());
orp.reset(rp.o.to);
nrp.reset(rp.n.to);
ors.reset(DocIterator());
nrs.reset(DocIterator());
// D is the number of horizontal and vertical steps, i.e.
// different characters in the old and new chunk.
int const D_max = ceil(((double)M_ + N_)/2);
for (int D = 0; D <= D_max; ++D) {
// Forward and reverse paths
for (int f = 0; f < 2; ++f) {
Direction direction = f == 0 ? Forward : Backward;
// Diagonals between -D and D can be reached by a D-path
for (int k = -D; k <= D; k += 2) {
// Find the furthest reaching D-path on this diagonal
furthest_Dpath_kdiagonal(D, k, rp, direction);
// Only check for overlap for forward paths if the offset is odd
// and only for reverse paths if the offset is even.
if (odd_offset_ == (direction == Forward)) {
// Do the forward and backward paths overlap ?
if (overlap(k, D - odd_offset_)) {
retrieve_middle_snake(k, D, direction, middle_snake);
LYXERR0("overlap_count " << overlap_count);
LYXERR0("middle_snake_count " << middle_snake_count);
LYXERR0("furthest_Dpath_kdiagonal_count " << furthest_Dpath_kdiagonal_count);
return 2 * D - odd_offset_;
}
}
}
}
}
// This should never be reached
return -2;
} }