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#include "muscle.h"
#include "diaglist.h"
#include "pwpath.h"
#define MAX(x, y) ((x) > (y) ? (x) : (y))
#define MIN(x, y) ((x) < (y) ? (x) : (y))
void DiagList::Add(const Diag &d)
{
if (m_uCount == MAX_DIAGS)
Quit("DiagList::Add, overflow %u", m_uCount);
m_Diags[m_uCount] = d;
++m_uCount;
}
void DiagList::Add(unsigned uStartPosA, unsigned uStartPosB, unsigned uLength)
{
Diag d;
d.m_uStartPosA = uStartPosA;
d.m_uStartPosB = uStartPosB;
d.m_uLength = uLength;
Add(d);
}
const Diag &DiagList::Get(unsigned uIndex) const
{
if (uIndex >= m_uCount)
Quit("DiagList::Get(%u), count=%u", uIndex, m_uCount);
return m_Diags[uIndex];
}
void DiagList::LogMe() const
{
Log("DiagList::LogMe, count=%u\n", m_uCount);
Log(" n StartA StartB Length\n");
Log("--- ------ ------ ------\n");
for (unsigned n = 0; n < m_uCount; ++n)
{
const Diag &d = m_Diags[n];
Log("%3u %6u %6u %6u\n",
n, d.m_uStartPosA, d.m_uStartPosB, d.m_uLength);
}
}
void DiagList::FromPath(const PWPath &Path)
{
Clear();
const unsigned uEdgeCount = Path.GetEdgeCount();
unsigned uLength = 0;
unsigned uStartPosA;
unsigned uStartPosB;
for (unsigned uEdgeIndex = 0; uEdgeIndex < uEdgeCount; ++uEdgeIndex)
{
const PWEdge &Edge = Path.GetEdge(uEdgeIndex);
// Typical cases
if (Edge.cType == 'M')
{
if (0 == uLength)
{
uStartPosA = Edge.uPrefixLengthA - 1;
uStartPosB = Edge.uPrefixLengthB - 1;
}
++uLength;
}
else
{
if (uLength >= g_uMinDiagLength)
Add(uStartPosA, uStartPosB, uLength);
uLength = 0;
}
}
// Special case for last edge
if (uLength >= g_uMinDiagLength)
Add(uStartPosA, uStartPosB, uLength);
}
bool DiagList::NonZeroIntersection(const Diag &d) const
{
for (unsigned n = 0; n < m_uCount; ++n)
{
const Diag &d2 = m_Diags[n];
if (DiagOverlap(d, d2) > 0)
return true;
}
return false;
}
// DialogOverlap returns the length of the overlapping
// section of the two diagonals along the diagonals
// themselves; in other words, the length of
// the intersection of the two sets of cells in
// the matrix.
unsigned DiagOverlap(const Diag &d1, const Diag &d2)
{
// Determine where the diagonals intersect the A
// axis (extending them if required). If they
// intersect at different points, they do not
// overlap. Coordinates on a diagonal are
// given by B = A + c where c is the value of
// A at the intersection with the A axis.
// Hence, c = B - A for any point on the diagonal.
int c1 = (int) d1.m_uStartPosB - (int) d1.m_uStartPosA;
int c2 = (int) d2.m_uStartPosB - (int) d2.m_uStartPosA;
if (c1 != c2)
return 0;
assert(DiagOverlapA(d1, d2) == DiagOverlapB(d1, d2));
return DiagOverlapA(d1, d2);
}
// DialogOverlapA returns the length of the overlapping
// section of the projection of the two diagonals onto
// the A axis.
unsigned DiagOverlapA(const Diag &d1, const Diag &d2)
{
unsigned uMaxStart = MAX(d1.m_uStartPosA, d2.m_uStartPosA);
unsigned uMinEnd = MIN(d1.m_uStartPosA + d1.m_uLength - 1,
d2.m_uStartPosA + d2.m_uLength - 1);
int iLength = (int) uMinEnd - (int) uMaxStart + 1;
if (iLength < 0)
return 0;
return (unsigned) iLength;
}
// DialogOverlapB returns the length of the overlapping
// section of the projection of the two diagonals onto
// the B axis.
unsigned DiagOverlapB(const Diag &d1, const Diag &d2)
{
unsigned uMaxStart = MAX(d1.m_uStartPosB, d2.m_uStartPosB);
unsigned uMinEnd = MIN(d1.m_uStartPosB + d1.m_uLength - 1,
d2.m_uStartPosB + d2.m_uLength - 1);
int iLength = (int) uMinEnd - (int) uMaxStart + 1;
if (iLength < 0)
return 0;
return (unsigned) iLength;
}
// Returns true if the two diagonals can be on the
// same path through the DP matrix. If DiagCompatible
// returns false, they cannot be in the same path
// and hence "contradict" each other.
bool DiagCompatible(const Diag &d1, const Diag &d2)
{
if (DiagOverlap(d1, d2) > 0)
return true;
return 0 == DiagOverlapA(d1, d2) && 0 == DiagOverlapB(d1, d2);
}
// Returns the length of the "break" between two diagonals.
unsigned DiagBreak(const Diag &d1, const Diag &d2)
{
int c1 = (int) d1.m_uStartPosB - (int) d1.m_uStartPosA;
int c2 = (int) d2.m_uStartPosB - (int) d2.m_uStartPosA;
if (c1 != c2)
return 0;
int iMaxStart = MAX(d1.m_uStartPosA, d2.m_uStartPosA);
int iMinEnd = MIN(d1.m_uStartPosA + d1.m_uLength - 1,
d2.m_uStartPosA + d1.m_uLength - 1);
int iBreak = iMaxStart - iMinEnd - 1;
if (iBreak < 0)
return 0;
return (unsigned) iBreak;
}
// Merge diagonals that are continuations of each other with
// short breaks of up to length g_uMaxDiagBreak.
// In a sorted list of diagonals, we only have to check
// consecutive entries.
void MergeDiags(DiagList &DL)
{
return;
#if DEBUG
if (!DL.IsSorted())
Quit("MergeDiags: !IsSorted");
#endif
// TODO: Fix this!
// Breaks must be with no offset (no gaps)
const unsigned uCount = DL.GetCount();
if (uCount <= 1)
return;
DiagList NewList;
Diag MergedDiag;
const Diag *ptrPrev = &DL.Get(0);
for (unsigned i = 1; i < uCount; ++i)
{
const Diag *ptrDiag = &DL.Get(i);
unsigned uBreakLength = DiagBreak(*ptrPrev, *ptrDiag);
if (uBreakLength <= g_uMaxDiagBreak)
{
MergedDiag.m_uStartPosA = ptrPrev->m_uStartPosA;
MergedDiag.m_uStartPosB = ptrPrev->m_uStartPosB;
MergedDiag.m_uLength = ptrPrev->m_uLength + ptrDiag->m_uLength
+ uBreakLength;
ptrPrev = &MergedDiag;
}
else
{
NewList.Add(*ptrPrev);
ptrPrev = ptrDiag;
}
}
NewList.Add(*ptrPrev);
DL.Copy(NewList);
}
void DiagList::DeleteIncompatible()
{
assert(IsSorted());
if (m_uCount < 2)
return;
bool *bFlagForDeletion = new bool[m_uCount];
for (unsigned i = 0; i < m_uCount; ++i)
bFlagForDeletion[i] = false;
for (unsigned i = 0; i < m_uCount; ++i)
{
const Diag &di = m_Diags[i];
for (unsigned j = i + 1; j < m_uCount; ++j)
{
const Diag &dj = m_Diags[j];
// Verify sorted correctly
assert(di.m_uStartPosA <= dj.m_uStartPosA);
// If two diagonals are incompatible and
// one is is much longer than the other,
// keep the longer one.
if (!DiagCompatible(di, dj))
{
if (di.m_uLength > dj.m_uLength*4)
bFlagForDeletion[j] = true;
else if (dj.m_uLength > di.m_uLength*4)
bFlagForDeletion[i] = true;
else
{
bFlagForDeletion[i] = true;
bFlagForDeletion[j] = true;
}
}
}
}
for (unsigned i = 0; i < m_uCount; ++i)
{
const Diag &di = m_Diags[i];
if (bFlagForDeletion[i])
continue;
for (unsigned j = i + 1; j < m_uCount; ++j)
{
const Diag &dj = m_Diags[j];
if (bFlagForDeletion[j])
continue;
// Verify sorted correctly
assert(di.m_uStartPosA <= dj.m_uStartPosA);
// If sort order in B different from sorted order in A,
// either diags are incompatible or we detected a repeat
// or permutation.
if (di.m_uStartPosB >= dj.m_uStartPosB || !DiagCompatible(di, dj))
{
bFlagForDeletion[i] = true;
bFlagForDeletion[j] = true;
}
}
}
unsigned uNewCount = 0;
Diag *NewDiags = new Diag[m_uCount];
for (unsigned i = 0; i < m_uCount; ++i)
{
if (bFlagForDeletion[i])
continue;
const Diag &d = m_Diags[i];
NewDiags[uNewCount] = d;
++uNewCount;
}
memcpy(m_Diags, NewDiags, uNewCount*sizeof(Diag));
m_uCount = uNewCount;
delete[] NewDiags;
}
void DiagList::Copy(const DiagList &DL)
{
Clear();
unsigned uCount = DL.GetCount();
for (unsigned i = 0; i < uCount; ++i)
Add(DL.Get(i));
}
// Check if sorted in increasing order of m_uStartPosA
bool DiagList::IsSorted() const
{
return true;
unsigned uCount = GetCount();
for (unsigned i = 1; i < uCount; ++i)
if (m_Diags[i-1].m_uStartPosA > m_Diags[i].m_uStartPosA)
return false;
return true;
}
// Sort in increasing order of m_uStartPosA
// Dumb bubble sort, but don't care about speed
// because don't get long lists.
void DiagList::Sort()
{
if (m_uCount < 2)
return;
bool bContinue = true;
while (bContinue)
{
bContinue = false;
for (unsigned i = 0; i < m_uCount - 1; ++i)
{
if (m_Diags[i].m_uStartPosA > m_Diags[i+1].m_uStartPosA)
{
Diag Tmp = m_Diags[i];
m_Diags[i] = m_Diags[i+1];
m_Diags[i+1] = Tmp;
bContinue = true;
}
}
}
}
//void TestDiag()
// {
// Diag d1;
// Diag d2;
// Diag d3;
//
// d1.m_uStartPosA = 0;
// d1.m_uStartPosB = 1;
// d1.m_uLength = 32;
//
// d2.m_uStartPosA = 55;
// d2.m_uStartPosB = 70;
// d2.m_uLength = 36;
//
// d3.m_uStartPosA = 102;
// d3.m_uStartPosB = 122;
// d3.m_uLength = 50;
//
// DiagList DL;
// DL.Add(d1);
// DL.Add(d2);
// DL.Add(d3);
//
// Log("Before DeleteIncompatible:\n");
// DL.LogMe();
// DL.DeleteIncompatible();
//
// Log("After DeleteIncompatible:\n");
// DL.LogMe();
//
// MergeDiags(DL);
// Log("After Merge:\n");
// DL.LogMe();
//
// DPRegionList RL;
// DiagListToDPRegionList(DL, RL, 200, 200);
// RL.LogMe();
// }
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