src/WinLibs/FTGL/src/FTVectoriser.cpp - vendor/opensource/projectM - Git at Google

 #include    "FTVectoriser.h"
 #include    "FTGL.h"

 #ifndef CALLBACK
 #define CALLBACK
 #endif

 #ifdef __APPLE_CC__
     typedef GLvoid (*GLUTesselatorFunction)(...);
 #elif defined( __mips ) || defined( __linux__ ) || defined( __FreeBSD__ ) || defined( __OpenBSD__ ) || defined( __sun ) || defined (__CYGWIN__)
     typedef GLvoid (*GLUTesselatorFunction)();
 #elif defined ( WIN32)
     typedef GLvoid (CALLBACK *GLUTesselatorFunction)( );
 #else
     #error "Error - need to define type GLUTesselatorFunction for this platform/compiler"
 #endif


 void CALLBACK ftglError( GLenum errCode, FTMesh* mesh)
 {
     mesh->Error( errCode);
 }


 void CALLBACK ftglVertex( void* data, FTMesh* mesh)
 {
     FTGL_DOUBLE* vertex = static_cast<FTGL_DOUBLE*>(data);
     mesh->AddPoint( vertex[0], vertex[1], vertex[2]);
 }


 void CALLBACK ftglCombine( FTGL_DOUBLE coords[3], void* vertex_data[4], GLfloat weight[4], void** outData, FTMesh* mesh)
 {
     const FTGL_DOUBLE* vertex = static_cast<const FTGL_DOUBLE*>(coords);
     *outData = const_cast<FTGL_DOUBLE*>(mesh->Combine( vertex[0], vertex[1], vertex[2]));
 }


 void CALLBACK ftglBegin( GLenum type, FTMesh* mesh)
 {
     mesh->Begin( type);
 }


 void CALLBACK ftglEnd( FTMesh* mesh)
 {
     mesh->End();
 }


 FTMesh::FTMesh()
 :	currentTesselation(0),
     err(0)
 {
     tesselationList.reserve( 16);
 }


 FTMesh::~FTMesh()
 {
     for( size_t t = 0; t < tesselationList.size(); ++t)
     {
         delete tesselationList[t];
     }

     tesselationList.clear();
 }


 void FTMesh::AddPoint( const FTGL_DOUBLE x, const FTGL_DOUBLE y, const FTGL_DOUBLE z)
 {
     currentTesselation->AddPoint( x, y, z);
 }


 const FTGL_DOUBLE* FTMesh::Combine( const FTGL_DOUBLE x, const FTGL_DOUBLE y, const FTGL_DOUBLE z)
 {
     tempPointList.push_back( FTPoint( x, y,z));
     return static_cast<const FTGL_DOUBLE*>(tempPointList.back());
 }


 void FTMesh::Begin( GLenum meshType)
 {
     currentTesselation = new FTTesselation( meshType);
 }


 void FTMesh::End()
 {
     tesselationList.push_back( currentTesselation);
 }


 const FTTesselation* const FTMesh::Tesselation( unsigned int index) const
 {
     return ( index < tesselationList.size()) ? tesselationList[index] : NULL;
 }


 FTVectoriser::FTVectoriser( const FT_GlyphSlot glyph)
 :   contourList(0),
     mesh(0),
     ftContourCount(0),
     contourFlag(0)
 {
     if( glyph)
     {
         outline = glyph->outline;

         ftContourCount = outline.n_contours;
         contourList = 0;
         contourFlag = outline.flags;

         ProcessContours();
     }
 }


 FTVectoriser::~FTVectoriser()
 {
     for( size_t c = 0; c < ContourCount(); ++c)
     {
         delete contourList[c];
     }

     delete [] contourList;
     delete mesh;
 }


 void FTVectoriser::ProcessContours()
 {
     short contourLength = 0;
     short startIndex = 0;
     short endIndex = 0;

     contourList = new FTContour*[ftContourCount];

     for( short contourIndex = 0; contourIndex < ftContourCount; ++contourIndex)
     {
         FT_Vector* pointList = &outline.points[startIndex];
         char* tagList = &outline.tags[startIndex];

         endIndex = outline.contours[contourIndex];
         contourLength =  ( endIndex - startIndex) + 1;

         FTContour* contour = new FTContour( pointList, tagList, contourLength);

         contourList[contourIndex] = contour;

         startIndex = endIndex + 1;
     }
 }


 size_t FTVectoriser::PointCount()
 {
     size_t s = 0;
     for( size_t c = 0; c < ContourCount(); ++c)
     {
         s += contourList[c]->PointCount();
     }

     return s;
 }


 const FTContour* const FTVectoriser::Contour( unsigned int index) const
 {
     return ( index < ContourCount()) ? contourList[index] : NULL;
 }


 void FTVectoriser::MakeMesh( FTGL_DOUBLE zNormal)
 {
     if( mesh)
     {
         delete mesh;
     }

     mesh = new FTMesh;

     GLUtesselator* tobj = gluNewTess();

     gluTessCallback( tobj, GLU_TESS_BEGIN_DATA,     (GLUTesselatorFunction)ftglBegin);
     gluTessCallback( tobj, GLU_TESS_VERTEX_DATA,    (GLUTesselatorFunction)ftglVertex);
     gluTessCallback( tobj, GLU_TESS_COMBINE_DATA,   (GLUTesselatorFunction)ftglCombine);
     gluTessCallback( tobj, GLU_TESS_END_DATA,       (GLUTesselatorFunction)ftglEnd);
     gluTessCallback( tobj, GLU_TESS_ERROR_DATA,     (GLUTesselatorFunction)ftglError);

     if( contourFlag & ft_outline_even_odd_fill) // ft_outline_reverse_fill
     {
         gluTessProperty( tobj, GLU_TESS_WINDING_RULE, GLU_TESS_WINDING_ODD);
     }
     else
     {
         gluTessProperty( tobj, GLU_TESS_WINDING_RULE, GLU_TESS_WINDING_NONZERO);
     }


     gluTessProperty( tobj, GLU_TESS_TOLERANCE, 0);
     gluTessNormal( tobj, 0.0f, 0.0f, zNormal);
     gluTessBeginPolygon( tobj, mesh);

         for( size_t c = 0; c < ContourCount(); ++c)
         {
             const FTContour* contour = contourList[c];

             gluTessBeginContour( tobj);

                 for( size_t p = 0; p < contour->PointCount(); ++p)
                 {
                     const FTGL_DOUBLE* d = contour->Point(p);
                     gluTessVertex( tobj, (GLdouble*)d, (GLdouble*)d);
                 }

             gluTessEndContour( tobj);
         }

     gluTessEndPolygon( tobj);

     gluDeleteTess( tobj);
 }
	#include "FTVectoriser.h"
	#include "FTGL.h"

	#ifndef CALLBACK
	#define CALLBACK
	#endif

	#ifdef __APPLE_CC__
	typedef GLvoid (*GLUTesselatorFunction)(...);
	#elif defined( __mips ) \|\| defined( __linux__ ) \|\| defined( __FreeBSD__ ) \|\| defined( __OpenBSD__ ) \|\| defined( __sun ) \|\| defined (__CYGWIN__)
	typedef GLvoid (*GLUTesselatorFunction)();
	#elif defined ( WIN32)
	typedef GLvoid (CALLBACK *GLUTesselatorFunction)( );
	#else
	#error "Error - need to define type GLUTesselatorFunction for this platform/compiler"
	#endif


	void CALLBACK ftglError( GLenum errCode, FTMesh* mesh)
	{
	mesh->Error( errCode);
	}


	void CALLBACK ftglVertex( void* data, FTMesh* mesh)
	{
	FTGL_DOUBLE* vertex = static_cast<FTGL_DOUBLE*>(data);
	mesh->AddPoint( vertex[0], vertex[1], vertex[2]);
	}


	void CALLBACK ftglCombine( FTGL_DOUBLE coords[3], void* vertex_data[4], GLfloat weight[4], void** outData, FTMesh* mesh)
	{
	const FTGL_DOUBLE* vertex = static_cast<const FTGL_DOUBLE*>(coords);
	outData = const_cast<FTGL_DOUBLE>(mesh->Combine( vertex[0], vertex[1], vertex[2]));
	}


	void CALLBACK ftglBegin( GLenum type, FTMesh* mesh)
	{
	mesh->Begin( type);
	}


	void CALLBACK ftglEnd( FTMesh* mesh)
	{
	mesh->End();
	}


	FTMesh::FTMesh()
	: currentTesselation(0),
	err(0)
	{
	tesselationList.reserve( 16);
	}


	FTMesh::~FTMesh()
	{
	for( size_t t = 0; t < tesselationList.size(); ++t)
	{
	delete tesselationList[t];
	}

	tesselationList.clear();
	}


	void FTMesh::AddPoint( const FTGL_DOUBLE x, const FTGL_DOUBLE y, const FTGL_DOUBLE z)
	{
	currentTesselation->AddPoint( x, y, z);
	}


	const FTGL_DOUBLE* FTMesh::Combine( const FTGL_DOUBLE x, const FTGL_DOUBLE y, const FTGL_DOUBLE z)
	{
	tempPointList.push_back( FTPoint( x, y,z));
	return static_cast<const FTGL_DOUBLE*>(tempPointList.back());
	}


	void FTMesh::Begin( GLenum meshType)
	{
	currentTesselation = new FTTesselation( meshType);
	}


	void FTMesh::End()
	{
	tesselationList.push_back( currentTesselation);
	}


	const FTTesselation* const FTMesh::Tesselation( unsigned int index) const
	{
	return ( index < tesselationList.size()) ? tesselationList[index] : NULL;
	}


	FTVectoriser::FTVectoriser( const FT_GlyphSlot glyph)
	: contourList(0),
	mesh(0),
	ftContourCount(0),
	contourFlag(0)
	{
	if( glyph)
	{
	outline = glyph->outline;

	ftContourCount = outline.n_contours;
	contourList = 0;
	contourFlag = outline.flags;

	ProcessContours();
	}
	}


	FTVectoriser::~FTVectoriser()
	{
	for( size_t c = 0; c < ContourCount(); ++c)
	{
	delete contourList[c];
	}

	delete [] contourList;
	delete mesh;
	}


	void FTVectoriser::ProcessContours()
	{
	short contourLength = 0;
	short startIndex = 0;
	short endIndex = 0;

	contourList = new FTContour*[ftContourCount];

	for( short contourIndex = 0; contourIndex < ftContourCount; ++contourIndex)
	{
	FT_Vector* pointList = &outline.points[startIndex];
	char* tagList = &outline.tags[startIndex];

	endIndex = outline.contours[contourIndex];
	contourLength = ( endIndex - startIndex) + 1;

	FTContour* contour = new FTContour( pointList, tagList, contourLength);

	contourList[contourIndex] = contour;

	startIndex = endIndex + 1;
	}
	}


	size_t FTVectoriser::PointCount()
	{
	size_t s = 0;
	for( size_t c = 0; c < ContourCount(); ++c)
	{
	s += contourList[c]->PointCount();
	}

	return s;
	}


	const FTContour* const FTVectoriser::Contour( unsigned int index) const
	{
	return ( index < ContourCount()) ? contourList[index] : NULL;
	}


	void FTVectoriser::MakeMesh( FTGL_DOUBLE zNormal)
	{
	if( mesh)
	{
	delete mesh;
	}

	mesh = new FTMesh;

	GLUtesselator* tobj = gluNewTess();

	gluTessCallback( tobj, GLU_TESS_BEGIN_DATA, (GLUTesselatorFunction)ftglBegin);
	gluTessCallback( tobj, GLU_TESS_VERTEX_DATA, (GLUTesselatorFunction)ftglVertex);
	gluTessCallback( tobj, GLU_TESS_COMBINE_DATA, (GLUTesselatorFunction)ftglCombine);
	gluTessCallback( tobj, GLU_TESS_END_DATA, (GLUTesselatorFunction)ftglEnd);
	gluTessCallback( tobj, GLU_TESS_ERROR_DATA, (GLUTesselatorFunction)ftglError);

	if( contourFlag & ft_outline_even_odd_fill) // ft_outline_reverse_fill
	{
	gluTessProperty( tobj, GLU_TESS_WINDING_RULE, GLU_TESS_WINDING_ODD);
	}
	else
	{
	gluTessProperty( tobj, GLU_TESS_WINDING_RULE, GLU_TESS_WINDING_NONZERO);
	}


	gluTessProperty( tobj, GLU_TESS_TOLERANCE, 0);
	gluTessNormal( tobj, 0.0f, 0.0f, zNormal);
	gluTessBeginPolygon( tobj, mesh);

	for( size_t c = 0; c < ContourCount(); ++c)
	{
	const FTContour* contour = contourList[c];

	gluTessBeginContour( tobj);

	for( size_t p = 0; p < contour->PointCount(); ++p)
	{
	const FTGL_DOUBLE* d = contour->Point(p);
	gluTessVertex( tobj, (GLdouble)d, (GLdouble)d);
	}

	gluTessEndContour( tobj);
	}

	gluTessEndPolygon( tobj);

	gluDeleteTess( tobj);
	}