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/**************************************************************************\
* ** Copyright (c) 1998 Microsoft Corporation ** ** Module Name: ** ** Region to Path Conversion class. ** ** Abstract: ** ** Code from Kirk Olynyk [kirko] created 14-Sep-1993. This code will ** convert rectangular regions to a path by analyzing the DDA pattern. ** ** Discussion: ** ** Input ** ** The input to the diagonalization routing is a rectangular ** path whose vertices have integer endpoints. Moreover it ** is required that the path always has the region on its ** left and that successive lines are mutually orthogonal. ** ** All paths are in device 28.4 coordinates. (Since all of ** the input coordinates are integers, the fractional part of all ** coordinates is zero.) ** ** Output ** ** A path that contains the same pixels as the originl path. ** ** Filling Convention ** ** Any region bounded by two non-horizontal lines is closed ** on the left and open on the right. If the region is bounded ** by two horizontal lines, it is closed on the top and open on ** bottom. ** ** Definition ** ** A CORNER is subsequence of two lines from the orignal axial path. ** It is convenient to partition the set of corners into two classes; ** HORIZONTAL-VERTIAL and VERTICAL-HORIZONTAL. ** ** A corner is "diagonalizable" the original two lines can be replaced ** by a single diagonal line such that same pixels would be rendered ** (using the filling convention defined above). ** ** ** Nomenclature ** ** S ::= "SOUTH" ::= one pixel move in +y-direction ** N ::= "NORTH" ::= one pixel move in -y-direction ** E ::= "EAST" ::= one pixel move in +x direction ** W ::= "WEST" ::= one pixel move in -x direction ** ** The set of diagonalizable corners are described by ** the following regular expressions: ** ** DIAGONALIZABLE CORNERS ** ** S(E+|W+) a one pixel move in the +y-direction ** followed by at least one pixel in any horizontal ** direction ** ** S+W an arbitary number of pixels in the +y-direction ** followed by a single pixel move in the ** negative x-direction. ** ** EN+ a one pixel move in the positive x-direction ** followed by at least one pixel move in the negative ** x-direction ** ** (E+|W+)N at least one-pixel move in the horizontal followed ** by a single pixel move in the negative ** y-direction. ** ** Algorithm ** ** BEGIN ** <For each corner in the orginal path> ** BEGIN ** <if the corner is diagonalizable> THEN ** ** <just draw a single diagonal line> ** ELSE ** <draw both legs of the original corner> ** END ** ** <Go around the path once again, merging successive ** identical moves into single lines> ** END ** ** In the code, both of these steps are done in parallel ** ** Further Improvements ** ** The output path the I generate with this algorithm will contain only ** points that were vertices of the original axial path. A larger of ** regular expressions could be searched for if I were willing to ** consider using new vertices for the output path. For example ** the regular exprssios N+WN and S+ES describe two "chicane turns" that ** can be diagonalized. The price to be paid is the a more complex ** code path. ** *\**************************************************************************/
#include "precomp.hpp"
/******************************Public*Routine******************************\
* RegionToPath::ConvertRegionToPath ** ** Takes an enumerable clip region as input and outputs a path ** ** Assumptions ** ** 0. *this is the original path which will not be changed. ** 1. All points on the path lie on integers ** 2. All subpaths have the inside on the left ** 3. All subpaths are closed ** ** History: ** Mon 13-Sep-1993 15:53:50 by Kirk Olynyk [kirko] ** Wrote it. *\**************************************************************************/
BOOL RegionToPath::ConvertRegionToPath(const DpRegion* inRegion, DynPointArray& newPoints, DynByteArray& newTypes){ BOOL result;
curIndex = 0; // initialize array to reasonable no. of points + types
points = &newPoints; types = &newTypes; newPoints.Reset(); newTypes.Reset(); region = inRegion;
if (region->IsSimple()) { GpRect bounds;
region->GetBounds(&bounds);
newPoints.Add(GpPoint(bounds.X, bounds.Y)); newPoints.Add(GpPoint(bounds.X + bounds.Width, bounds.Y)); newPoints.Add(GpPoint(bounds.X + bounds.Width, bounds.Y + bounds.Height)); newPoints.Add(GpPoint(bounds.X, bounds.Y + bounds.Height)); newTypes.Add(PathPointTypeStart); newTypes.Add(PathPointTypeLine); newTypes.Add(PathPointTypeLine); newTypes.Add(PathPointTypeLine | PathPointTypeCloseSubpath);
return TRUE; } inPoints.Reset(); inTypes.Reset();
// convert region to right angle piecewise line segments
if (region->GetOutlinePoints(inPoints, inTypes) == TRUE) { curPoint = (GpPoint*) inPoints.GetDataBuffer(); curType = (BYTE*) inTypes.GetDataBuffer();
BOOL result = TRUE; lastPoint = &inPoints.Last();
while (curPoint<=lastPoint && result) { endSubpath = FALSE; firstPoint = curPoint; result = DiagonalizePath(); }
return result; } else return FALSE;}
/******************************Public*Routine******************************\
* RTP_PATHMEMOBJ::bWritePoint ** ** This routine takes as input a candidate point for writing. However ** this routine is smart in that it analyzes the stream of candidate ** points looking for consecutive sub-sets of points that all lie on the ** same line. When such a case is recognized, then only the endpoints of ** the interpolating line are actually added to the output path. ** ** I do not go to a great deal of trouble to determine if a candidate ** point is on a line. All that I do is to see if the vector increment ** to the new point is the same as the increment between prior points ** in the input path. ** ** History: ** Mon 13-Sep-1993 15:53:35 by Kirk Olynyk [kirko] ** Wrote it. *\**************************************************************************/
BOOL RegionToPath::WritePoint(){ GpPoint NewAB; BOOL result = TRUE; int jA = curIndex;
if (outPts == 2) { NewAB.X = pts[jA].X - writePts[1].X; NewAB.Y = pts[jA].Y - writePts[1].Y; if (NewAB.X != AB.X || NewAB.Y != AB.Y) { points->Add(writePts[0]); types->Add(PathPointTypeLine); writePts[0] = writePts[1]; AB = NewAB; }
writePts[1] = pts[jA]; } else if (outPts == 0) { writePts[0] = pts[jA]; outPts += 1; } else if (outPts == 1) { writePts[1] = pts[jA]; AB.X = writePts[1].X - writePts[0].X; AB.Y = writePts[1].Y - writePts[0].Y; outPts += 1; } else { RIP(("RegionToPath::WritePoint -- point count is bad")); result = FALSE; } return(result);}
/******************************Public*Routine******************************\
* bFetchNextPoint ... in sub-path ** ** History: ** Tue 14-Sep-1993 14:13:01 by Kirk Olynyk [kirko] ** Wrote it. *\**************************************************************************/
BOOL RegionToPath::FetchNextPoint(){ INT oldIndex = curIndex;
curIndex = (curIndex + 1) % 3;
// only output the first point if at end of a subpath
if (endSubpath) { // end of subpath, add first point on end of new path
flags[oldIndex] = 0; pts[oldIndex] = *firstPoint; return TRUE; } pts[oldIndex] = *curPoint;
// check for end subpath only?
if (*curType & PathPointTypeCloseSubpath) { endSubpath = TRUE; flags[oldIndex] = LastPointFlag; } else { flags[oldIndex] = 0; } curPoint++; curType++;
return TRUE;}
/******************************Public*Routine******************************\
* Path2Region::bDiagonalizeSubPathRTP_PATHMEMOBJ::bDiagonalizeSubPath ** ** History: ** Tue 14-Sep-1993 12:47:49 by Kirk Olynyk [kirko] ** Wrote it. *\**************************************************************************/
inline VOID RotateBackward(INT& x, INT& y, INT& z){ INT temp;
temp = x; x = z; z = y; y = temp;}
inline VOID RotateForward(INT& x, INT& y, INT& z){ INT temp;
temp = x; x = y; y = z; z = temp;}
BOOL RegionToPath::DiagonalizePath(){ INT AB; // Length of leg A->B
INT BC; // Length of second leg B->C
INT bH; // set to 1 if second leg is horizontal
INT jA,jB,jC; register BOOL bRet = TRUE; // if FALSE then return immediately
// otherwise keep processing.
outPts = 0; // no points so far in the write buffer
curIndex = 0; // set the start of the circular buffer
lastCount = 0;
// Fill the circular buffer with the first three points of the
// path. The three member buffer, defines two successive lines, or
// one corner (the path is guaranteed to be composed of alternating
// lines along the x-axis and y-axis). I shall label the three vertices
// of the corner A,B, and C. The point A always resides at ax[j],
// point B resides at ax[iMod3[j+1]], and point C resides at
// ax[iMod3[j+2]] where j can have one of the values 0, 1, 2.
if (bRet = FetchNextPoint() && FetchNextPoint() && FetchNextPoint()) { ASSERTMSG(curIndex == 0, ("RegionToPath::DiagonalizeSubPath()" " -- curIndex != 0"));
// bH ::= <is the second leg of the corner horizontal?>
//
// if the second leg of the corner is horizontal set bH=1 otherwise
// set bH=0. Calculate the length of the first leg of the corner
// and save it in fxAB. Note that I do not need to use the iMod3
// modulus operation since j==0.
if (pts[2].Y == pts[1].Y) { bH = 1; AB = pts[1].Y - pts[0].Y; } else { bH = 0; AB = pts[1].X - pts[0].X; }
// Start a new subpath at the first point of the subpath.
points->Add(pts[0]); types->Add(PathPointTypeStart); jA = 0; jB = 1; jC = 2; }
while (bRet) { if (!(flags[jA] & LastPointFlag)) { // Assert that the the legs of the corner are along
// the axes, and that the two legs are mutually
// orthogonal
ASSERTMSG(pts[jC].X == pts[jB].X || pts[jC].Y == pts[jB].Y, ("Bad Path :: C-B is not axial")); ASSERTMSG(pts[jA].X == pts[jB].X || pts[jA].Y == pts[jB].Y, ("Bad Path :: B-A is not axial")); ASSERTMSG( (pts[jC].X - pts[jB].X) * (pts[jB].X - pts[jA].X) + (pts[jC].Y - pts[jB].Y) * (pts[jB].Y - pts[jA].Y) == 0, ("Bad Path :: B-A is not orthogonal to C-B") ); } // If the first vertex of the corner is the last point in the
// original subpath then we terminate the processing. This point
// has either been recorded with PATHMEMOBJ::bMoveTo or
// PATHMEMOBJ::bPolyLineTo. All that remains is to close the
// subpath which is done outside the while loop
if (flags[jA] & LastPointFlag) break;
// There are two paths through the following if-else clause
// They are for VERTICAL-HORIZONTAL and HORIZONTAL-VERTICAL
// corners respectively. These two clauses are identical
// except for the interchange of ".x" with ".y". It might be
// a good idea to have macros or subrouines for these sections
// in order that they be guranteed to be identical.
// Is the second leg of the corner horizontal?
if (bH) { // Yes, the second leg of the corner is horizontal
BC = pts[jC].X - pts[jB].X;
// Is the corner diagonalizable?
if ((AB > 0) && ((AB == 1) || (BC == -1))) { // Yes, the corner is diagonalizable
//
// If the middle of the corner was the last point in the
// original path then the last point in the output path
// is the first point in the corner. This is because the
// last line in the output path is this diagonalized
// corner which will be produced automatically by the
// CloseFigure() call after this while-loop. Thus, in
// this case we would just break out of the loop.
if (flags[jB] & LastPointFlag) break;
// The corner is diagonalizable. This means that we are no
// longer interested in the first two points of this corner.
// We therefore fetch the next two points of the path
// an place them in our circular corner-buffer.
if (!(bRet = FetchNextPoint() && FetchNextPoint())) break;
// under modulo 3 arithmetic, incrementing by 2 is
// equivalent to decrementing by 1
RotateBackward(jA,jB,jC);
// fxAB is set to the length of the first leg of the new
// corner.
AB = pts[jB].Y - pts[jA].Y; } else { // No, the corner is not diagonalizable
//
// The corner cannot be diagonalized. Advance the corner
// to the next point in the original path. The orientation
// of the second leg of the corner will change. The length
// of the first leg of the new corner is set equal to the
// length of the second leg of the previous corner.
if (!(bRet = FetchNextPoint())) break;
RotateForward(jA,jB,jC); bH ^= 1; AB = BC; } } else { // Diagonalize the HORIZONTAL->VERTICAL corner
BC = pts[jC].Y - pts[jB].Y; if ((BC < 0) && ((AB == 1) || (BC == -1))) { if (flags[jB] & LastPointFlag) break; if (!(bRet = FetchNextPoint() && FetchNextPoint())) break; RotateBackward(jA,jB,jC); AB = pts[jB].X - pts[jA].X; } else { if (!(bRet = FetchNextPoint())) break; RotateForward(jA,jB,jC); bH ^= 1; AB = BC; } } if (!(bRet = WritePoint())) break; }
if (bRet) { ASSERTMSG(outPts == 2, ("GDI Region To Path -- numPts is not 2"));
points->Add(writePts[0]); points->Add(writePts[1]); types->Add(PathPointTypeLine); types->Add(PathPointTypeLine | PathPointTypeCloseSubpath); }
return(bRet);}
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