/******************************************************************************
*
*
*
*
* Copyright (C) 1997-2008 by Dimitri van Heesch.
*
* Permission to use, copy, modify, and distribute this software and its
* documentation under the terms of the GNU General Public License is hereby
* granted. No representations are made about the suitability of this software
* for any purpose. It is provided "as is" without express or implied warranty.
* See the GNU General Public License for more details.
*
* Documents produced by Doxygen are derivative works derived from the
* input used in their production; they are not affected by this license.
*
*/
#include "qtbc.h"
#include <stdio.h>
#include <stdlib.h>
#include <qlist.h>
#include <qarray.h>
#include <qtextstream.h>
#include <qfile.h>
#include "diagram.h"
#include "image.h"
#include "classdef.h"
#include "config.h"
#include "message.h"
#include "util.h"
#include "doxygen.h"
#include "portable.h"
#include "index.h"
//-----------------------------------------------------------------------------
const uint maxTreeWidth = 8;
const int gridWidth = 100;
const int gridHeight = 100;
const uint labelHorSpacing = 10; // horizontal distance between labels
const uint labelVertSpacing = 32; // vertical distance between labels
const uint labelHorMargin = 6; // horiz. spacing between label and box
const uint fontHeight = 12; // height of a character
//static QCString escapeLatex(const char *s)
//{
// QCString result;
// char c;
// while ((c=*s++))
// {
// if (c=='_') result+="\\_";
// else result+=c;
// }
// return result;
//}
static uint protToMask(Protection p)
{
switch(p)
{
case Public: return 0xffffffff;
case Package: // package is not possible!
case Protected: return 0xcccccccc;
case Private: return 0xaaaaaaaa;
}
return 0;
}
static uint protToColor(Protection p)
{
switch(p)
{
case Public: return 6;
case Package: // package is not possible!
case Protected: return 5;
case Private: return 4;
}
return 0;
}
static QCString protToString(Protection p)
{
switch(p)
{
case Public: return "solid";
case Package: // package is not possible!
case Protected: return "dashed";
case Private: return "dotted";
}
return 0;
}
static uint virtToMask(Specifier p)
{
switch(p)
{
case Normal: return 0xffffffff;
case Virtual: return 0xf0f0f0f0;
default: return 0;
}
return 0;
}
// pre: dil is not empty
static Protection getMinProtectionLevel(DiagramItemList *dil)
{
DiagramItem *di=dil->first();
Protection result=di->protection();
di=dil->next();
while (di)
{
Protection p=di->protection();
if (p!=result)
{
if (result==Protected && p==Public) result=p;
else if (result==Private) result=p;
}
di=dil->next();
}
return result;
}
static void writeBitmapBox(DiagramItem *di,Image *image,
int x,int y,int w,int h,bool firstRow,
bool hasDocs,bool children=FALSE)
{
int colFill = hasDocs ? (firstRow ? 0 : 2) : 7;
int colBorder = (firstRow || !hasDocs) ? 1 : 3;
int l = Image::stringLength(di->label());
uint mask=virtToMask(di->virtualness());
image->fillRect(x+1,y+1,w-2,h-2,colFill,mask);
image->drawRect(x,y,w,h,colBorder,mask);
image->writeString(x+(w-l)/2, y+(h-fontHeight)/2, di->label(),1);
if (children)
{
int i;
for (i=0;i<5;i++)
image->drawHorzLine(y+h+i-6,x+w-2-i,x+w-2,firstRow?1:3,0xffffffff);
}
}
static void writeVectorBox(QTextStream &t,DiagramItem *di,
float x,float y,bool children=FALSE)
{
if (di->virtualness()==Virtual) t << "dashed\n";
t << " (" << di->label() << ") " << x << " " << y << " box\n";
if (children) t << x << " " << y << " mark\n";
if (di->virtualness()==Virtual) t << "solid\n";
}
static void writeMapArea(QTextStream &t,ClassDef *cd,QCString relPath,
int x,int y,int w,int h)
{
if (cd->isLinkable())
{
QCString *dest;
QCString ref=cd->getReference();
t << "<area ";
if (!ref.isEmpty())
{
t << "doxygen=\"" << ref << ":";
if ((dest=Doxygen::tagDestinationDict[ref])) t << *dest << "/";
t << "\" ";
}
t << "href=\"";
if (!ref.isEmpty())
{
if ((dest=Doxygen::tagDestinationDict[ref])) t << *dest << "/";
}
else
{
t << relPath;
}
t << cd->getOutputFileBase() << Doxygen::htmlFileExtension << "\" ";
t << "alt=\"" << convertToXML(cd->displayName());
t << "\" shape=\"rect\" coords=\"" << x << "," << y << ",";
t << (x+w) << "," << (y+h) << "\"/>" << endl;
}
}
//-----------------------------------------------------------------------------
DiagramItem::DiagramItem(DiagramItem *p,int number,ClassDef *cd,
Protection pr,Specifier vi,const char *ts)
{
parent=p;
x=y=0;
//name=n;
num=number;
children = new DiagramItemList;
prot=pr;
virt=vi;
inList=FALSE;
classDef=cd;
templSpec=ts;
}
DiagramItem::~DiagramItem()
{
delete children;
}
QCString DiagramItem::label() const
{
QCString result;
if (!templSpec.isEmpty())
{
// we use classDef->name() here and not diplayName() in order
// to get the name used in the inheritance relation.
result=insertTemplateSpecifierInScope(classDef->name(),templSpec);
}
else
{
result=classDef->displayName();
}
if (Config_getBool("HIDE_SCOPE_NAMES")) result=stripScope(result);
return result;
}
QCString DiagramItem::fileName() const
{
return classDef->getOutputFileBase();
}
int DiagramItem::avgChildPos() const
{
DiagramItem *di;
int c=children->count();
if (c==0) // no children -> don't move
return xPos();
if ((di=children->getFirst())->isInList()) // children should be in a list
return di->xPos();
if (c&1) // odd number of children -> get pos of middle child
return children->at(c/2)->xPos();
else // even number of children -> get middle of most middle children
return (children->at(c/2-1)->xPos()+children->at(c/2)->xPos())/2;
}
int DiagramItem::numChildren() const
{
return children->count();
}
void DiagramItem::addChild(DiagramItem *di)
{
children->append(di);
}
void DiagramRow::insertClass(DiagramItem *parent,ClassDef *cd,bool doBases,
Protection prot,Specifier virt,const char *ts)
{
//if (cd->visited) return; // the visit check does not work in case of
// multiple inheritance of the same class!
DiagramItem *di=new DiagramItem(parent, diagram->at(level)->count(),
cd,prot,virt,ts);
//cd->visited=TRUE;
if (parent) parent->addChild(di);
di->move(count()*gridWidth,level*gridHeight);
append(di);
BaseClassList *bcl=doBases ? cd->baseClasses() : cd->subClasses();
int count=0;
if (bcl)
{
/* there are base/sub classes */
BaseClassDef *bcd=bcl->first();
while (bcd)
{
ClassDef *ccd=bcd->classDef;
if (ccd && ccd->isVisibleInHierarchy() /*&& !ccd->visited*/) count++;
bcd=bcl->next();
}
}
if (count>0 && (prot!=Private || !doBases))
{
DiagramRow *row=0;
if (diagram->count()<=level+1) /* add new row */
{
row = new DiagramRow(diagram,level+1);
diagram->append(row);
}
else /* get next row */
{
row=diagram->at(level+1);
}
/* insert base classes in the next row */
BaseClassDef *bcd=bcl->first();
while (bcd)
{
ClassDef *ccd=bcd->classDef;
if (ccd && ccd->isVisibleInHierarchy() /*&& !ccd->visited*/)
{
row->insertClass(di,ccd,doBases,bcd->prot,
doBases?bcd->virt:Normal,
doBases?bcd->templSpecifiers.data():"");
}
bcd=bcl->next();
}
}
}
TreeDiagram::TreeDiagram(ClassDef *root,bool doBases)
{
setAutoDelete(TRUE);
DiagramRow *row=new DiagramRow(this,0);
append(row);
row->insertClass(0,root,doBases,Public,Normal,0);
}
TreeDiagram::~TreeDiagram()
{
}
void TreeDiagram::moveChildren(DiagramItem *root,int dx)
{
DiagramItemList *dil=root->getChildren();
DiagramItem *di=dil->first();
while (di)
{
di->move(dx,0);
moveChildren(di,dx);
di=dil->next();
}
}
bool TreeDiagram::layoutTree(DiagramItem *root,int r)
{
bool moved=FALSE;
//printf("layoutTree(%s,%d)\n",root->label().data(),r);
DiagramItemList *dil=root->getChildren();
if (dil->count()>0)
{
uint k;
int pPos=root->xPos();
int cPos=root->avgChildPos();
if (pPos>cPos) // move children
{
DiagramRow *row=at(r+1);
//printf("Moving children %d-%d in row %d\n",
// dil->getFirst()->number(),row->count()-1,r+1);
for (k=dil->getFirst()->number();k<row->count();k++)
row->at(k)->move(pPos-cPos,0);
moved=TRUE;
}
else if (pPos<cPos) // move parent
{
DiagramRow *row=at(r);
//printf("Moving parents %d-%d in row %d\n",
// root->number(),row->count()-1,r);
for (k=root->number();k<row->count();k++)
row->at(k)->move(cPos-pPos,0);
moved=TRUE;
}
// recurse to children
DiagramItem *di=dil->first();
while (di && !moved && !di->isInList())
{
moved = moved || layoutTree(di,r+1);
di=dil->next();
}
}
return moved;
}
void TreeDiagram::computeLayout()
{
DiagramRow *row=first();
while (row && row->count()<maxTreeWidth) row=next();
if (row)
{
//printf("computeLayout() list row at %d\n",row->number());
DiagramItem *di=row->first();
DiagramItem *opi=0;
int delta=0;
bool first=TRUE;
while (di)
{
DiagramItem *pi=di->parentItem();
if (pi==opi && !first) { delta-=gridWidth; }
first = pi!=opi;
opi=pi;
di->move(delta,0); // collapse all items in the same
// list (except the first)
di->putInList();
di=row->next();
}
}
// re-organize the diagram items
DiagramItem *root=getFirst()->getFirst();
while (layoutTree(root,0)) { }
// move first items of the lists
if (row)
{
DiagramItem *di=row->first();
while (di)
{
DiagramItem *pi=di->parentItem();
if (pi->getChildren()->count()>1)
{
di->move(gridWidth,0);
while (di && di->parentItem()==pi) di=row->next();
}
else
{
di=row->next();
}
}
}
}
uint TreeDiagram::computeRows()
{
//printf("TreeDiagram::computeRows()=%d\n",count());
int count=0;
DiagramRow *row=first();
while (row && !row->getFirst()->isInList())
{
count++;
row=next();
}
//printf("count=%d row=%p\n",count,row);
if (row)
{
int maxListLen=0;
int curListLen=0;
DiagramItem *di=row->first(),*opi=0;
while (di)
{
if (di->parentItem()!=opi) curListLen=1; else curListLen++;
if (curListLen>maxListLen) maxListLen=curListLen;
opi=di->parentItem();
di=row->next();
}
//printf("maxListLen=%d\n",maxListLen);
count+=maxListLen;
}
return count;
}
#if 0
uint TreeDiagram::computeCols()
{
uint count=0;
DiagramRow *row=first();
while (row && !row->getFirst()->isInList())
{
if (row->count()>count) count=row->count();
row=next();
}
if (row)
{
row=prev();
uint cols=row->count();
if (row->getLast()->getChildren()->count()>1) cols++;
if (cols>count) count=cols;
}
return count;
};
#endif
void TreeDiagram::computeExtremes(uint *maxLabelLen,uint *maxXPos)
{
uint ml=0,mx=0;
DiagramRow *dr=first();
bool done=FALSE;
while (dr && !done)
{
DiagramItem *di=dr->first();
while (di)
{
if (di->isInList()) done=TRUE;
if (maxXPos) mx=QMAX(mx,(uint)di->xPos());
if (maxLabelLen) ml=QMAX(ml,Image::stringLength(di->label()));
di=dr->next();
}
dr=next();
}
if (maxLabelLen) *maxLabelLen=ml;
if (maxXPos) *maxXPos=mx;
}
void TreeDiagram::drawBoxes(QTextStream &t,Image *image,
bool doBase,bool bitmap,
uint baseRows,uint superRows,
uint cellWidth,uint cellHeight,
QCString relPath,
bool generateMap)
{
DiagramRow *dr=first();
if (!doBase) dr=next();
bool done=FALSE;
bool firstRow = doBase;
while (dr && !done)
{
int x=0,y=0;
float xf=0.0,yf=0.0;
DiagramItem *di=dr->first();
if (di->isInList()) // put boxes in a list
{
DiagramItem *opi=0;
if (doBase) di=dr->last();
while (di)
{
if (di->parentItem()==opi)
{
if (bitmap)
{
if (doBase) y -= cellHeight+labelVertSpacing;
else y += cellHeight+labelVertSpacing;
}
else
{
if (doBase) yf += 1.0;
else yf -= 1.0;
}
}
else
{
if (bitmap)
{
x = di->xPos()*(cellWidth+labelHorSpacing)/gridWidth;
if (doBase)
{
y = image->getHeight()-
superRows*cellHeight-
(superRows-1)*labelVertSpacing-
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
}
else
{
y = (baseRows-1)*(cellHeight+labelVertSpacing)+
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
}
}
else
{
xf = di->xPos()/(float)gridWidth;
if (doBase)
{
yf = di->yPos()/(float)gridHeight+superRows-1;
}
else
{
yf = superRows-1-di->yPos()/(float)gridHeight;
}
}
}
opi=di->parentItem();
if (bitmap)
{
bool hasDocs=di->getClassDef()->isLinkable();
writeBitmapBox(di,image,x,y,cellWidth,cellHeight,firstRow,
hasDocs,di->getChildren()->count()>0);
if (!firstRow && generateMap)
writeMapArea(t,di->getClassDef(),relPath,x,y,cellWidth,cellHeight);
}
else
{
writeVectorBox(t,di,xf,yf,di->getChildren()->count()>0);
}
if (doBase) di=dr->prev(); else di=dr->next();
}
done=TRUE;
}
else // draw a tree of boxes
{
while (di)
{
if (bitmap)
{
x = di->xPos()*(cellWidth+labelHorSpacing)/gridWidth;
if (doBase)
{
y = image->getHeight()-
superRows*cellHeight-
(superRows-1)*labelVertSpacing-
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
}
else
{
y = (baseRows-1)*(cellHeight+labelVertSpacing)+
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
}
bool hasDocs=di->getClassDef()->isLinkable();
writeBitmapBox(di,image,x,y,cellWidth,cellHeight,firstRow,hasDocs);
if (!firstRow && generateMap)
writeMapArea(t,di->getClassDef(),relPath,x,y,cellWidth,cellHeight);
}
else
{
xf=di->xPos()/(float)gridWidth;
if (doBase)
{
yf = di->yPos()/(float)gridHeight+superRows-1;
}
else
{
yf = superRows-1-di->yPos()/(float)gridHeight;
}
writeVectorBox(t,di,xf,yf);
}
di=dr->next();
}
}
dr=next();
firstRow=FALSE;
}
}
void TreeDiagram::drawConnectors(QTextStream &t,Image *image,
bool doBase,bool bitmap,
uint baseRows,uint superRows,
uint cellWidth,uint cellHeight)
{
DiagramRow *dr=first();
bool done=FALSE;
while (dr && !done) // for each row
{
DiagramItem *di=dr->first();
if (di->isInList()) // row consists of list connectors
{
int x=0,y=0,ys=0;
float xf=0.0,yf=0.0,ysf=0.0;
while (di)
{
DiagramItem *pi=di->parentItem();
DiagramItemList *dil=pi->getChildren();
DiagramItem *last=dil->getLast();
if (di==last) // single child
{
if (bitmap) // draw pixels
{
x = di->xPos()*(cellWidth+labelHorSpacing)/gridWidth + cellWidth/2;
if (doBase) // base classes
{
y = image->getHeight()-
(superRows-1)*(cellHeight+labelVertSpacing)-
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
image->drawVertArrow(x,y,y+labelVertSpacing/2,
protToColor(di->protection()),
protToMask(di->protection()));
}
else // super classes
{
y = (baseRows-1)*(cellHeight+labelVertSpacing)-
labelVertSpacing/2+
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
image->drawVertLine(x,y,y+labelVertSpacing/2,
protToColor(di->protection()),
protToMask(di->protection()));
}
}
else // draw vectors
{
t << protToString(di->protection()) << endl;
if (doBase)
{
t << "1 " << (di->xPos()/(float)gridWidth) << " "
<< (di->yPos()/(float)gridHeight+superRows-1) << " in\n";
}
else
{
t << "0 " << (di->xPos()/(float)gridWidth) << " "
<< ((float)superRows-0.25-di->yPos()/(float)gridHeight)
<< " in\n";
}
}
}
else // multiple children, put them in a vertical list
{
if (bitmap)
{
x = di->parentItem()->xPos()*
(cellWidth+labelHorSpacing)/gridWidth+cellWidth/2;
if (doBase) // base classes
{
ys = image->getHeight()-
(superRows-1)*(cellHeight+labelVertSpacing)-
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
y = ys - cellHeight/2;
}
else // super classes
{
ys = (baseRows-1)*(cellHeight+labelVertSpacing)+
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
y = ys + cellHeight/2;
}
}
else
{
xf = di->parentItem()->xPos()/(float)gridWidth;
if (doBase)
{
ysf = di->yPos()/(float)gridHeight+superRows-1;
yf = ysf + 0.5;
}
else
{
ysf = (float)superRows-0.25-di->yPos()/(float)gridHeight;
yf = ysf - 0.25;
}
}
while (di!=last) // more children to add
{
if (bitmap)
{
if (doBase) // base classes
{
image->drawHorzArrow(y,x,x+cellWidth/2+labelHorSpacing,
protToColor(di->protection()),
protToMask(di->protection()));
y -= cellHeight+labelVertSpacing;
}
else // super classes
{
image->drawHorzLine(y,x,x+cellWidth/2+labelHorSpacing,
protToColor(di->protection()),
protToMask(di->protection()));
y += cellHeight+labelVertSpacing;
}
}
else
{
t << protToString(di->protection()) << endl;
if (doBase)
{
t << "1 " << xf << " " << yf << " hedge\n";
yf += 1.0;
}
else
{
t << "0 " << xf << " " << yf << " hedge\n";
yf -= 1.0;
}
}
di=dr->next();
}
// add last horizonal line and a vertical connection line
if (bitmap)
{
if (doBase) // base classes
{
image->drawHorzArrow(y,x,x+cellWidth/2+labelHorSpacing,
protToColor(di->protection()),
protToMask(di->protection()));
image->drawVertLine(x,y,ys+labelVertSpacing/2,
protToColor(getMinProtectionLevel(dil)),
protToMask(getMinProtectionLevel(dil)));
}
else // super classes
{
image->drawHorzLine(y,x,x+cellWidth/2+labelHorSpacing,
protToColor(di->protection()),
protToMask(di->protection()));
image->drawVertLine(x,ys-labelVertSpacing/2,y,
protToColor(getMinProtectionLevel(dil)),
protToMask(getMinProtectionLevel(dil)));
}
}
else
{
t << protToString(di->protection()) << endl;
if (doBase)
{
t << "1 " << xf << " " << yf << " hedge\n";
}
else
{
t << "0 " << xf << " " << yf << " hedge\n";
}
t << protToString(getMinProtectionLevel(dil)) << endl;
if (doBase)
{
t << xf << " " << ysf << " " << yf << " vedge\n";
}
else
{
t << xf << " " << (ysf + 0.25) << " " << yf << " vedge\n";
}
}
}
di=dr->next();
}
done=TRUE; // the tree is drawn now
}
else // normal tree connector
{
while (di)
{
int x=0,y=0;
DiagramItemList *dil = di->getChildren();
DiagramItem *parent = di->parentItem();
if (parent) // item has a parent -> connect to it
{
if (bitmap) // draw pixels
{
x = di->xPos()*(cellWidth+labelHorSpacing)/gridWidth + cellWidth/2;
if (doBase) // base classes
{
y = image->getHeight()-
(superRows-1)*(cellHeight+labelVertSpacing)-
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
/* write input line */
image->drawVertArrow(x,y,y+labelVertSpacing/2,
protToColor(di->protection()),
protToMask(di->protection()));
}
else // super classes
{
y = (baseRows-1)*(cellHeight+labelVertSpacing)-
labelVertSpacing/2+
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
/* write output line */
image->drawVertLine(x,y,y+labelVertSpacing/2,
protToColor(di->protection()),
protToMask(di->protection()));
}
}
else // draw pixels
{
t << protToString(di->protection()) << endl;
if (doBase)
{
t << "1 " << di->xPos()/(float)gridWidth << " "
<< (di->yPos()/(float)gridHeight+superRows-1) << " in\n";
}
else
{
t << "0 " << di->xPos()/(float)gridWidth << " "
<< ((float)superRows-0.25-di->yPos()/(float)gridHeight)
<< " in\n";
}
}
}
if (dil->count()>0)
{
Protection p=getMinProtectionLevel(dil);
uint mask=protToMask(p);
uint col=protToColor(p);
if (bitmap)
{
x = di->xPos()*(cellWidth+labelHorSpacing)/gridWidth + cellWidth/2;
if (doBase) // base classes
{
y = image->getHeight()-
(superRows-1)*(cellHeight+labelVertSpacing)-
cellHeight-labelVertSpacing/2-
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
image->drawVertLine(x,y,y+labelVertSpacing/2-1,col,mask);
}
else // super classes
{
y = (baseRows-1)*(cellHeight+labelVertSpacing)+
cellHeight+
di->yPos()*(cellHeight+labelVertSpacing)/gridHeight;
image->drawVertArrow(x,y,y+labelVertSpacing/2-1,col,mask);
}
}
else
{
t << protToString(p) << endl;
if (doBase)
{
t << "0 " << di->xPos()/(float)gridWidth << " "
<< (di->yPos()/(float)gridHeight+superRows-1) << " out\n";
}
else
{
t << "1 " << di->xPos()/(float)gridWidth << " "
<< ((float)superRows-1.75-di->yPos()/(float)gridHeight)
<< " out\n";
}
}
/* write input line */
DiagramItem *first = dil->first();
DiagramItem *last = dil->last();
if (first!=last && !first->isInList()) /* connect with all base classes */
{
if (bitmap)
{
int xs = first->xPos()*(cellWidth+labelHorSpacing)/gridWidth
+ cellWidth/2;
int xe = last->xPos()*(cellWidth+labelHorSpacing)/gridWidth
+ cellWidth/2;
if (doBase) // base classes
{
image->drawHorzLine(y,xs,xe,col,mask);
}
else // super classes
{
image->drawHorzLine(y+labelVertSpacing/2,xs,xe,col,mask);
}
}
else
{
t << protToString(p) << endl;
if (doBase)
{
t << first->xPos()/(float)gridWidth << " "
<< last->xPos()/(float)gridWidth << " "
<< (first->yPos()/(float)gridHeight+superRows-1)
<< " conn\n";
}
else
{
t << first->xPos()/(float)gridWidth << " "
<< last->xPos()/(float)gridWidth << " "
<< ((float)superRows-first->yPos()/(float)gridHeight)
<< " conn\n";
}
}
}
}
di=dr->next();
}
dr=next();
}
}
}
void clearVisitFlags()
{
ClassSDict::Iterator cli(*Doxygen::classSDict);
ClassDef *cd;
for (;(cd=cli.current());++cli)
{
cd->visited=FALSE;
}
}
ClassDiagram::ClassDiagram(ClassDef *root)
{
clearVisitFlags();
base = new TreeDiagram(root,TRUE);
base->computeLayout();
clearVisitFlags();
super = new TreeDiagram(root,FALSE);
super->computeLayout();
DiagramItem *baseItem = base->first()->first();
DiagramItem *superItem = super->first()->first();
int xbase = baseItem->xPos();
int xsuper = superItem->xPos();
if (xbase>xsuper)
{
superItem->move(xbase-xsuper,0);
super->moveChildren(superItem,xbase-xsuper);
}
else if (xbase<xsuper)
{
baseItem->move(xsuper-xbase,0);
base->moveChildren(baseItem,xsuper-xbase);
}
}
ClassDiagram::~ClassDiagram()
{
delete base;
delete super;
}
void ClassDiagram::writeFigure(QTextStream &output,const char *path,
const char *fileName) const
{
uint baseRows=base->computeRows();
uint superRows=super->computeRows();
uint baseMaxX, baseMaxLabelWidth, superMaxX, superMaxLabelWidth;
base->computeExtremes(&baseMaxLabelWidth,&baseMaxX);
super->computeExtremes(&superMaxLabelWidth,&superMaxX);
uint rows=baseRows+superRows-1;
uint cols=(QMAX(baseMaxX,superMaxX)+gridWidth*2-1)/gridWidth;
// Estimate the image aspect width and height in pixels.
uint estHeight = rows*40;
uint estWidth = cols*(20+QMAX(baseMaxLabelWidth,superMaxLabelWidth));
//printf("Estimated size %d x %d\n",estWidth,estHeight);
const float pageWidth = 14.0; // estimated page width in cm.
// Somewhat lower to deal with estimation
// errors.
// compute the image height in centimeters based on the estimates
float realHeight = QMIN(rows,12); // real height in cm
float realWidth = realHeight * estWidth/(float)estHeight;
if (realWidth>pageWidth) // assume that the page width is about 15 cm
{
realHeight*=pageWidth/realWidth;
realWidth=pageWidth;
}
//output << "}\n";
output << ":\\begin{figure}[H]\n"
"\\begin{center}\n"
"\\leavevmode\n";
output << "\\includegraphics[height=" << realHeight << "cm]{"
<< fileName << "}" << endl;
output << "\\end{center}\n"
"\\end{figure}\n";
//printf("writeFigure rows=%d cols=%d\n",rows,cols);
QCString epsBaseName=(QCString)path+"/"+fileName;
QCString epsName=epsBaseName+".eps";
QFile f1;
f1.setName(epsName.data());
if (!f1.open(IO_WriteOnly))
{
err("Could not open file %s for writing\n",convertToQCString(f1.name()).data());
exit(1);
}
QTextStream t(&f1);
//printf("writeEPS() rows=%d cols=%d\n",rows,cols);
// generate EPS header and postscript variables and procedures
t << "%!PS-Adobe-2.0 EPSF-2.0\n";
t << "%%Title: ClassName\n";
t << "%%Creator: Doxygen\n";
t << "%%CreationDate: Time\n";
t << "%%For: \n";
t << "%Magnification: 1.00\n";
t << "%%Orientation: Portrait\n";
t << "%%BoundingBox: 0 0 500 " << estHeight*500.0/(float)estWidth << "\n";
t << "%%Pages: 0\n";
t << "%%BeginSetup\n";
t << "%%EndSetup\n";
t << "%%EndComments\n";
t << "\n";
t << "% ----- variables -----\n";
t << "\n";
t << "/boxwidth 0 def\n";
t << "/boxheight 40 def\n";
t << "/fontheight 24 def\n";
t << "/marginwidth 10 def\n";
t << "/distx 20 def\n";
t << "/disty 40 def\n";
t << "/boundaspect " << estWidth/(float)estHeight << " def % aspect ratio of the BoundingBox (width/height)\n";
t << "/boundx 500 def\n";
t << "/boundy boundx boundaspect div def\n";
t << "/xspacing 0 def\n";
t << "/yspacing 0 def\n";
t << "/rows " << rows << " def\n";
t << "/cols " << cols << " def\n";
t << "/scalefactor 0 def\n";
t << "/boxfont /Times-Roman findfont fontheight scalefont def\n";
t << "\n";
t << "% ----- procedures -----\n";
t << "\n";
t << "/dotted { [1 4] 0 setdash } def\n";
t << "/dashed { [5] 0 setdash } def\n";
t << "/solid { [] 0 setdash } def\n";
t << "\n";
t << "/max % result = MAX(arg1,arg2)\n";
t << "{\n";
t << " /a exch def\n";
t << " /b exch def\n";
t << " a b gt {a} {b} ifelse\n";
t << "} def\n";
t << "\n";
t << "/xoffset % result = MAX(0,(scalefactor-(boxwidth*cols+distx*(cols-1)))/2)\n";
t << "{\n";
t << " 0 scalefactor boxwidth cols mul distx cols 1 sub mul add sub 2 div max\n";
t << "} def\n";
t << "\n";
t << "/cw % boxwidth = MAX(boxwidth, stringwidth(arg1))\n";
t << "{\n";
t << " /str exch def\n";
t << " /boxwidth boxwidth str stringwidth pop max def\n";
t << "} def\n";
t << "\n";
t << "/box % draws a box with text `arg1' at grid pos (arg2,arg3)\n";
t << "{ gsave\n";
t << " 2 setlinewidth\n";
t << " newpath\n";
t << " exch xspacing mul xoffset add\n";
t << " exch yspacing mul\n";
t << " moveto\n";
t << " boxwidth 0 rlineto \n";
t << " 0 boxheight rlineto \n";
t << " boxwidth neg 0 rlineto \n";
t << " 0 boxheight neg rlineto \n";
t << " closepath\n";
t << " dup stringwidth pop neg boxwidth add 2 div\n";
t << " boxheight fontheight 2 div sub 2 div\n";
t << " rmoveto show stroke\n";
t << " grestore\n";
t << "} def \n";
t << "\n";
t << "/mark\n";
t << "{ newpath\n";
t << " exch xspacing mul xoffset add boxwidth add\n";
t << " exch yspacing mul\n";
t << " moveto\n";
t << " 0 boxheight 4 div rlineto\n";
t << " boxheight neg 4 div boxheight neg 4 div rlineto\n";
t << " closepath\n";
t << " eofill\n";
t << " stroke\n";
t << "} def\n";
t << "\n";
t << "/arrow\n";
t << "{ newpath\n";
t << " moveto\n";
t << " 3 -8 rlineto\n";
t << " -6 0 rlineto\n";
t << " 3 8 rlineto\n";
t << " closepath\n";
t << " eofill\n";
t << " stroke\n";
t << "} def\n";
t << "\n";
t << "/out % draws an output connector for the block at (arg1,arg2)\n";
t << "{\n";
t << " newpath\n";
t << " exch xspacing mul xoffset add boxwidth 2 div add\n";
t << " exch yspacing mul boxheight add\n";
t << " /y exch def\n";
t << " /x exch def\n";
t << " x y moveto\n";
t << " 0 disty 2 div rlineto \n";
t << " stroke\n";
t << " 1 eq { x y disty 2 div add arrow } if\n";
t << "} def\n";
t << "\n";
t << "/in % draws an input connector for the block at (arg1,arg2)\n";
t << "{\n";
t << " newpath\n";
t << " exch xspacing mul xoffset add boxwidth 2 div add\n";
t << " exch yspacing mul disty 2 div sub\n";
t << " /y exch def\n";
t << " /x exch def\n";
t << " x y moveto\n";
t << " 0 disty 2 div rlineto\n";
t << " stroke\n";
t << " 1 eq { x y disty 2 div add arrow } if\n";
t << "} def\n";
t << "\n";
t << "/hedge\n";
t << "{\n";
t << " exch xspacing mul xoffset add boxwidth 2 div add\n";
t << " exch yspacing mul boxheight 2 div sub\n";
t << " /y exch def\n";
t << " /x exch def\n";
t << " newpath\n";
t << " x y moveto\n";
t << " boxwidth 2 div distx add 0 rlineto\n";
t << " stroke\n";
t << " 1 eq\n";
t << " { newpath x boxwidth 2 div distx add add y moveto\n";
t << " -8 3 rlineto\n";
t << " 0 -6 rlineto\n";
t << " 8 3 rlineto\n";
t << " closepath\n";
t << " eofill\n";
t << " stroke\n";
t << " } if\n";
t << "} def\n";
t << "\n";
t << "/vedge\n";
t << "{\n";
t << " /ye exch def\n";
t << " /ys exch def\n";
t << " /xs exch def\n";
t << " newpath\n";
t << " xs xspacing mul xoffset add boxwidth 2 div add dup\n";
t << " ys yspacing mul boxheight 2 div sub\n";
t << " moveto\n";
t << " ye yspacing mul boxheight 2 div sub\n";
t << " lineto\n";
t << " stroke\n";
t << "} def\n";
t << "\n";
t << "/conn % connections the blocks from col `arg1' to `arg2' of row `arg3'\n";
t << "{\n";
t << " /ys exch def\n";
t << " /xe exch def\n";
t << " /xs exch def\n";
t << " newpath\n";
t << " xs xspacing mul xoffset add boxwidth 2 div add\n";
t << " ys yspacing mul disty 2 div sub\n";
t << " moveto\n";
t << " xspacing xe xs sub mul 0\n";
t << " rlineto\n";
t << " stroke\n";
t << "} def\n";
t << "\n";
t << "% ----- main ------\n";
t << "\n";
t << "boxfont setfont\n";
t << "1 boundaspect scale\n";
bool done=FALSE;
DiagramRow *dr=base->first();
while (dr && !done)
{
DiagramItem *di=dr->first();
while (di)
{
done=di->isInList();
t << "(" << di->label() << ") cw\n";
di=dr->next();
}
dr=base->next();
}
dr=super->first();
dr=super->next();
done=FALSE;
while (dr && !done)
{
DiagramItem *di=dr->first();
while (di)
{
done=di->isInList();
t << "(" << di->label() << ") cw\n";
di=dr->next();
}
dr=super->next();
}
t << "/boxwidth boxwidth marginwidth 2 mul add def\n"
<< "/xspacing boxwidth distx add def\n"
<< "/yspacing boxheight disty add def\n"
<< "/scalefactor \n"
<< " boxwidth cols mul distx cols 1 sub mul add\n"
<< " boxheight rows mul disty rows 1 sub mul add boundaspect mul \n"
<< " max def\n"
<< "boundx scalefactor div boundy scalefactor div scale\n";
t << "\n% ----- classes -----\n\n";
base->drawBoxes(t,0,TRUE,FALSE,baseRows,superRows,0,0);
super->drawBoxes(t,0,FALSE,FALSE,baseRows,superRows,0,0);
t << "\n% ----- relations -----\n\n";
base->drawConnectors(t,0,TRUE,FALSE,baseRows,superRows,0,0);
super->drawConnectors(t,0,FALSE,FALSE,baseRows,superRows,0,0);
f1.close();
if (Config_getBool("USE_PDFLATEX"))
{
QCString epstopdfArgs(4096);
epstopdfArgs.sprintf("\"%s.eps\" --outfile=\"%s.pdf\"",
epsBaseName.data(),epsBaseName.data());
//printf("Converting eps using `%s'\n",epstopdfCmd.data());
if (portable_system("epstopdf",epstopdfArgs)!=0)
{
err("Error: Problems running epstopdf. Check your TeX installation!\n");
return;
}
}
}
void ClassDiagram::writeImage(QTextStream &t,const char *path,
const char *relPath,const char *fileName,
bool generateMap) const
{
uint baseRows=base->computeRows();
uint superRows=super->computeRows();
uint rows=baseRows+superRows-1;
uint lb,ls,xb,xs;
base->computeExtremes(&lb,&xb);
super->computeExtremes(&ls,&xs);
uint cellWidth = QMAX(lb,ls)+labelHorMargin*2;
uint maxXPos = QMAX(xb,xs);
uint labelVertMargin = 6; //QMAX(6,(cellWidth-fontHeight)/6); // aspect at least 1:3
uint cellHeight = labelVertMargin*2+fontHeight;
uint imageWidth = (maxXPos+gridWidth)*cellWidth/gridWidth+
(maxXPos*labelHorSpacing)/gridWidth;
uint imageHeight = rows*cellHeight+(rows-1)*labelVertSpacing;
Image image(imageWidth,imageHeight);
base->drawBoxes(t,&image,TRUE,TRUE,baseRows,superRows,cellWidth,cellHeight,relPath,generateMap);
super->drawBoxes(t,&image,FALSE,TRUE,baseRows,superRows,cellWidth,cellHeight,relPath,generateMap);
base->drawConnectors(t,&image,TRUE,TRUE,baseRows,superRows,cellWidth,cellHeight);
super->drawConnectors(t,&image,FALSE,TRUE,baseRows,superRows,cellWidth,cellHeight);
#define IMAGE_EXT ".png"
image.save((QCString)path+"/"+fileName+IMAGE_EXT);
Doxygen::indexList.addImageFile(QCString(fileName)+IMAGE_EXT);
if (generateMap) t << "</map>" << endl;
}