liangchengyou / wow_english

  //
  // Copyright (c) 2009-2010 Mikko Mononen memon@inside.org
  //
  // This software is provided 'as-is', without any express or implied
  // warranty.  In no event will the authors be held liable for any damages
  // arising from the use of this software.
  // Permission is granted to anyone to use this software for any purpose,
  // including commercial applications, and to alter it and redistribute it
  // freely, subject to the following restrictions:
  // 1. The origin of this software must not be misrepresented; you must not
  //    claim that you wrote the original software. If you use this software
  //    in a product, an acknowledgment in the product documentation would be
  //    appreciated but is not required.
  // 2. Altered source versions must be plainly marked as such, and must not be
  //    misrepresented as being the original software.
  // 3. This notice may not be removed or altered from any source distribution.
  //
  
  #include "DebugDraw.h"
  #include "DetourDebugDraw.h"
  #include "recast/Detour/DetourNavMesh.h"
  #include "recast/Detour/DetourCommon.h"
  #include "recast/Detour/DetourNode.h"
  
  
  static float distancePtLine2d(const float* pt, const float* p, const float* q)
  {
  	float pqx = q[0] - p[0];
  	float pqz = q[2] - p[2];
  	float dx = pt[0] - p[0];
  	float dz = pt[2] - p[2];
  	float d = pqx*pqx + pqz*pqz;
  	float t = pqx*dx + pqz*dz;
  	if (d != 0) t /= d;
  	dx = p[0] + t*pqx - pt[0];
  	dz = p[2] + t*pqz - pt[2];
  	return dx*dx + dz*dz;
  }
  
  static void drawPolyBoundaries(duDebugDraw* dd, const dtMeshTile* tile,
  							   const unsigned int col, const float linew,
  							   bool inner)
  {
  	static const float thr = 0.01f*0.01f;
  
  	dd->begin(DU_DRAW_LINES, linew);
  
  	for (int i = 0; i < tile->header->polyCount; ++i)
  	{
  		const dtPoly* p = &tile->polys[i];
  		
  		if (p->getType() == DT_POLYTYPE_OFFMESH_CONNECTION) continue;
  		
  		const dtPolyDetail* pd = &tile->detailMeshes[i];
  		
  		for (int j = 0, nj = (int)p->vertCount; j < nj; ++j)
  		{
  			unsigned int c = col;
  			if (inner)
  			{
  				if (p->neis[j] == 0) continue;
  				if (p->neis[j] & DT_EXT_LINK)
  				{
  					bool con = false;
  					for (unsigned int k = p->firstLink; k != DT_NULL_LINK; k = tile->links[k].next)
  					{
  						if (tile->links[k].edge == j)
  						{
  							con = true;
  							break;
  						}
  					}
  					if (con)
  						c = duRGBA(255,255,255,48);
  					else
  						c = duRGBA(0,0,0,48);
  				}
  				else
  					c = duRGBA(0,48,64,32);
  			}
  			else
  			{
  				if (p->neis[j] != 0) continue;
  			}
  			
  			const float* v0 = &tile->verts[p->verts[j]*3];
  			const float* v1 = &tile->verts[p->verts[(j+1) % nj]*3];
  			
  			// Draw detail mesh edges which align with the actual poly edge.
  			// This is really slow.
  			for (int k = 0; k < pd->triCount; ++k)
  			{
  				const unsigned char* t = &tile->detailTris[(pd->triBase+k)*4];
  				const float* tv[3];
  				for (int m = 0; m < 3; ++m)
  				{
  					if (t[m] < p->vertCount)
  						tv[m] = &tile->verts[p->verts[t[m]]*3];
  					else
  						tv[m] = &tile->detailVerts[(pd->vertBase+(t[m]-p->vertCount))*3];
  				}
  				for (int m = 0, n = 2; m < 3; n=m++)
  				{
  					if (((t[3] >> (n*2)) & 0x3) == 0) continue;	// Skip inner detail edges.
  					if (distancePtLine2d(tv[n],v0,v1) < thr &&
  						distancePtLine2d(tv[m],v0,v1) < thr)
  					{
  						dd->vertex(tv[n], c);
  						dd->vertex(tv[m], c);
  					}
  				}
  			}
  		}
  	}
  	dd->end();
  }
  
  static void drawMeshTile(duDebugDraw* dd, const dtNavMesh& mesh, const dtNavMeshQuery* query,
  						 const dtMeshTile* tile, unsigned char flags)
  {
  	dtPolyRef base = mesh.getPolyRefBase(tile);
  
  	int tileNum = mesh.decodePolyIdTile(base);
  	
  	dd->depthMask(false);
  
  	dd->begin(DU_DRAW_TRIS);
  	for (int i = 0; i < tile->header->polyCount; ++i)
  	{
  		const dtPoly* p = &tile->polys[i];
  		if (p->getType() == DT_POLYTYPE_OFFMESH_CONNECTION)	// Skip off-mesh links.
  			continue;
  			
  		const dtPolyDetail* pd = &tile->detailMeshes[i];
  
  		unsigned int col;
  		if (query && query->isInClosedList(base | (dtPolyRef)i))
  			col = duRGBA(255,196,0,64);
  		else
  		{
  			if (flags & DU_DRAWNAVMESH_COLOR_TILES)
  			{
  				col = duIntToCol(tileNum, 128);
  			}
  			else
  			{
  				if (p->getArea() == 0) // Treat zero area type as default.
  					col = duRGBA(0,192,255,64);
  				else
  					col = duIntToCol(p->getArea(), 64);
  			}
  		}
  		
  		for (int j = 0; j < pd->triCount; ++j)
  		{
  			const unsigned char* t = &tile->detailTris[(pd->triBase+j)*4];
  			for (int k = 0; k < 3; ++k)
  			{
  				if (t[k] < p->vertCount)
  					dd->vertex(&tile->verts[p->verts[t[k]]*3], col);
  				else
  					dd->vertex(&tile->detailVerts[(pd->vertBase+t[k]-p->vertCount)*3], col);
  			}
  		}
  	}
  	dd->end();
  	
  	// Draw inter poly boundaries
  	drawPolyBoundaries(dd, tile, duRGBA(0,48,64,32), 1.5f, true);
  	
  	// Draw outer poly boundaries
  	drawPolyBoundaries(dd, tile, duRGBA(0,48,64,220), 2.5f, false);
  
  	if (flags & DU_DRAWNAVMESH_OFFMESHCONS)
  	{
  		dd->begin(DU_DRAW_LINES, 2.0f);
  		for (int i = 0; i < tile->header->polyCount; ++i)
  		{
  			const dtPoly* p = &tile->polys[i];
  			if (p->getType() != DT_POLYTYPE_OFFMESH_CONNECTION)	// Skip regular polys.
  				continue;
  			
  			unsigned int col, col2;
  			if (query && query->isInClosedList(base | (dtPolyRef)i))
  				col = duRGBA(255,196,0,220);
  			else
  				col = duDarkenCol(duIntToCol(p->getArea(), 220));
  			
  			const dtOffMeshConnection* con = &tile->offMeshCons[i - tile->header->offMeshBase];
  			const float* va = &tile->verts[p->verts[0]*3];
  			const float* vb = &tile->verts[p->verts[1]*3];
  
  			// Check to see if start and end end-points have links.
  			bool startSet = false;
  			bool endSet = false;
  			for (unsigned int k = p->firstLink; k != DT_NULL_LINK; k = tile->links[k].next)
  			{
  				if (tile->links[k].edge == 0)
  					startSet = true;
  				if (tile->links[k].edge == 1)
  					endSet = true;
  			}
  			
  			// End points and their on-mesh locations.
  			dd->vertex(va[0],va[1],va[2], col);
  			dd->vertex(con->pos[0],con->pos[1],con->pos[2], col);
  			col2 = startSet ? col : duRGBA(220,32,16,196);
  			duAppendCircle(dd, con->pos[0],con->pos[1]+0.1f,con->pos[2], con->rad, col2);
  
  			dd->vertex(vb[0],vb[1],vb[2], col);
  			dd->vertex(con->pos[3],con->pos[4],con->pos[5], col);
  			col2 = endSet ? col : duRGBA(220,32,16,196);
  			duAppendCircle(dd, con->pos[3],con->pos[4]+0.1f,con->pos[5], con->rad, col2);
  			
  			// End point vertices.
  			dd->vertex(con->pos[0],con->pos[1],con->pos[2], duRGBA(0,48,64,196));
  			dd->vertex(con->pos[0],con->pos[1]+0.2f,con->pos[2], duRGBA(0,48,64,196));
  			
  			dd->vertex(con->pos[3],con->pos[4],con->pos[5], duRGBA(0,48,64,196));
  			dd->vertex(con->pos[3],con->pos[4]+0.2f,con->pos[5], duRGBA(0,48,64,196));
  			
  			// Connection arc.
  			duAppendArc(dd, con->pos[0],con->pos[1],con->pos[2], con->pos[3],con->pos[4],con->pos[5], 0.25f,
  						(con->flags & 1) ? 0.6f : 0, 0.6f, col);
  		}
  		dd->end();
  	}
  	
  	const unsigned int vcol = duRGBA(0,0,0,196);
  	dd->begin(DU_DRAW_POINTS, 3.0f);
  	for (int i = 0; i < tile->header->vertCount; ++i)
  	{
  		const float* v = &tile->verts[i*3];
  		dd->vertex(v[0], v[1], v[2], vcol);
  	}
  	dd->end();
  
  	dd->depthMask(true);
  }
  
  void duDebugDrawNavMesh(duDebugDraw* dd, const dtNavMesh& mesh, unsigned char flags)
  {
  	if (!dd) return;
  	
  	for (int i = 0; i < mesh.getMaxTiles(); ++i)
  	{
  		const dtMeshTile* tile = mesh.getTile(i);
  		if (!tile->header) continue;
  		drawMeshTile(dd, mesh, 0, tile, flags);
  	}
  }
  
  void duDebugDrawNavMeshWithClosedList(struct duDebugDraw* dd, const dtNavMesh& mesh, const dtNavMeshQuery& query, unsigned char flags)
  {
  	if (!dd) return;
  
  	const dtNavMeshQuery* q = (flags & DU_DRAWNAVMESH_CLOSEDLIST) ? &query : 0;
  	
  	for (int i = 0; i < mesh.getMaxTiles(); ++i)
  	{
  		const dtMeshTile* tile = mesh.getTile(i);
  		if (!tile->header) continue;
  		drawMeshTile(dd, mesh, q, tile, flags);
  	}
  }
  
  void duDebugDrawNavMeshNodes(struct duDebugDraw* dd, const dtNavMeshQuery& query)
  {
  	if (!dd) return;
  	
  	const dtNodePool* pool = query.getNodePool();
  	if (pool)
  	{
  		const float off = 0.5f;
  		dd->begin(DU_DRAW_POINTS, 4.0f);
  		for (int i = 0; i < pool->getHashSize(); ++i)
  		{
  			for (dtNodeIndex j = pool->getFirst(i); j != DT_NULL_IDX; j = pool->getNext(j))
  			{
  				const dtNode* node = pool->getNodeAtIdx(j+1);
  				if (!node) continue;
  				dd->vertex(node->pos[0],node->pos[1]+off,node->pos[2], duRGBA(255,192,0,255));
  			}
  		}
  		dd->end();
  		
  		dd->begin(DU_DRAW_LINES, 2.0f);
  		for (int i = 0; i < pool->getHashSize(); ++i)
  		{
  			for (dtNodeIndex j = pool->getFirst(i); j != DT_NULL_IDX; j = pool->getNext(j))
  			{
  				const dtNode* node = pool->getNodeAtIdx(j+1);
  				if (!node) continue;
  				if (!node->pidx) continue;
  				const dtNode* parent = pool->getNodeAtIdx(node->pidx);
  				if (!parent) continue;
  				dd->vertex(node->pos[0],node->pos[1]+off,node->pos[2], duRGBA(255,192,0,128));
  				dd->vertex(parent->pos[0],parent->pos[1]+off,parent->pos[2], duRGBA(255,192,0,128));
  			}
  		}
  		dd->end();
  	}
  }
  
  
  static void drawMeshTileBVTree(duDebugDraw* dd, const dtMeshTile* tile)
  {
  	// Draw BV nodes.
  	const float cs = 1.0f / tile->header->bvQuantFactor;
  	dd->begin(DU_DRAW_LINES, 1.0f);
  	for (int i = 0; i < tile->header->bvNodeCount; ++i)
  	{
  		const dtBVNode* n = &tile->bvTree[i];
  		if (n->i < 0) // Leaf indices are positive.
  			continue;
  		duAppendBoxWire(dd, tile->header->bmin[0] + n->bmin[0]*cs,
  						tile->header->bmin[1] + n->bmin[1]*cs,
  						tile->header->bmin[2] + n->bmin[2]*cs,
  						tile->header->bmin[0] + n->bmax[0]*cs,
  						tile->header->bmin[1] + n->bmax[1]*cs,
  						tile->header->bmin[2] + n->bmax[2]*cs,
  						duRGBA(255,255,255,128));
  	}
  	dd->end();
  }
  
  void duDebugDrawNavMeshBVTree(duDebugDraw* dd, const dtNavMesh& mesh)
  {
  	if (!dd) return;
  	
  	for (int i = 0; i < mesh.getMaxTiles(); ++i)
  	{
  		const dtMeshTile* tile = mesh.getTile(i);
  		if (!tile->header) continue;
  		drawMeshTileBVTree(dd, tile);
  	}
  }
  
  static void drawMeshTilePortal(duDebugDraw* dd, const dtMeshTile* tile)
  {
  	// Draw portals
  	const float padx = 0.04f;
  	const float pady = tile->header->walkableClimb;
  
  	dd->begin(DU_DRAW_LINES, 2.0f);
  
  	for (int side = 0; side < 8; ++side)
  	{
  		unsigned short m = DT_EXT_LINK | (unsigned short)side;
  		
  		for (int i = 0; i < tile->header->polyCount; ++i)
  		{
  			dtPoly* poly = &tile->polys[i];
  			
  			// Create new links.
  			const int nv = poly->vertCount;
  			for (int j = 0; j < nv; ++j)
  			{
  				// Skip edges which do not point to the right side.
  				if (poly->neis[j] != m)
  					continue;
  				
  				// Create new links
  				const float* va = &tile->verts[poly->verts[j]*3];
  				const float* vb = &tile->verts[poly->verts[(j+1) % nv]*3];
  				
  				if (side == 0 || side == 4)
  				{
  					unsigned int col = side == 0 ? duRGBA(128,0,0,128) : duRGBA(128,0,128,128);
  
  					const float x = va[0] + ((side == 0) ? -padx : padx);
  					
  					dd->vertex(x,va[1]-pady,va[2], col);
  					dd->vertex(x,va[1]+pady,va[2], col);
  
  					dd->vertex(x,va[1]+pady,va[2], col);
  					dd->vertex(x,vb[1]+pady,vb[2], col);
  
  					dd->vertex(x,vb[1]+pady,vb[2], col);
  					dd->vertex(x,vb[1]-pady,vb[2], col);
  
  					dd->vertex(x,vb[1]-pady,vb[2], col);
  					dd->vertex(x,va[1]-pady,va[2], col);
  				}
  				else if (side == 2 || side == 6)
  				{
  					unsigned int col = side == 2 ? duRGBA(0,128,0,128) : duRGBA(0,128,128,128);
  
  					const float z = va[2] + ((side == 2) ? -padx : padx);
  					
  					dd->vertex(va[0],va[1]-pady,z, col);
  					dd->vertex(va[0],va[1]+pady,z, col);
  					
  					dd->vertex(va[0],va[1]+pady,z, col);
  					dd->vertex(vb[0],vb[1]+pady,z, col);
  					
  					dd->vertex(vb[0],vb[1]+pady,z, col);
  					dd->vertex(vb[0],vb[1]-pady,z, col);
  					
  					dd->vertex(vb[0],vb[1]-pady,z, col);
  					dd->vertex(va[0],va[1]-pady,z, col);
  				}
  
  			}
  		}
  	}
  	
  	dd->end();
  }
  
  void duDebugDrawNavMeshPortals(duDebugDraw* dd, const dtNavMesh& mesh)
  {
  	if (!dd) return;
  	
  	for (int i = 0; i < mesh.getMaxTiles(); ++i)
  	{
  		const dtMeshTile* tile = mesh.getTile(i);
  		if (!tile->header) continue;
  		drawMeshTilePortal(dd, tile);
  	}
  }
  
  void duDebugDrawNavMeshPolysWithFlags(struct duDebugDraw* dd, const dtNavMesh& mesh,
  									  const unsigned short polyFlags, const unsigned int col)
  {
  	if (!dd) return;
  	
  	for (int i = 0; i < mesh.getMaxTiles(); ++i)
  	{
  		const dtMeshTile* tile = mesh.getTile(i);
  		if (!tile->header) continue;
  		dtPolyRef base = mesh.getPolyRefBase(tile);
  
  		for (int j = 0; j < tile->header->polyCount; ++j)
  		{
  			const dtPoly* p = &tile->polys[j];
  			if ((p->flags & polyFlags) == 0) continue;
  			duDebugDrawNavMeshPoly(dd, mesh, base|(dtPolyRef)j, col);
  		}
  	}
  }
  
  void duDebugDrawNavMeshPoly(duDebugDraw* dd, const dtNavMesh& mesh, dtPolyRef ref, const unsigned int col)
  {
  	if (!dd) return;
  	
  	const dtMeshTile* tile = 0;
  	const dtPoly* poly = 0;
  	if (dtStatusFailed(mesh.getTileAndPolyByRef(ref, &tile, &poly)))
  		return;
  	
  	dd->depthMask(false);
  	
  	const unsigned int c = (col & 0x00ffffff) | (64 << 24);
  	const unsigned int ip = (unsigned int)(poly - tile->polys);
  
  	if (poly->getType() == DT_POLYTYPE_OFFMESH_CONNECTION)
  	{
  		dtOffMeshConnection* con = &tile->offMeshCons[ip - tile->header->offMeshBase];
  
  		dd->begin(DU_DRAW_LINES, 2.0f);
  
  		// Connection arc.
  		duAppendArc(dd, con->pos[0],con->pos[1],con->pos[2], con->pos[3],con->pos[4],con->pos[5], 0.25f,
  					(con->flags & 1) ? 0.6f : 0, 0.6f, c);
  		
  		dd->end();
  	}
  	else
  	{
  		const dtPolyDetail* pd = &tile->detailMeshes[ip];
  
  		dd->begin(DU_DRAW_TRIS);
  		for (int i = 0; i < pd->triCount; ++i)
  		{
  			const unsigned char* t = &tile->detailTris[(pd->triBase+i)*4];
  			for (int j = 0; j < 3; ++j)
  			{
  				if (t[j] < poly->vertCount)
  					dd->vertex(&tile->verts[poly->verts[t[j]]*3], c);
  				else
  					dd->vertex(&tile->detailVerts[(pd->vertBase+t[j]-poly->vertCount)*3], c);
  			}
  		}
  		dd->end();
  	}
  	
  	dd->depthMask(true);
  
  }
  
  static void debugDrawTileCachePortals(struct duDebugDraw* dd, const dtTileCacheLayer& layer, const float cs, const float ch)
  {
  	const int w = (int)layer.header->width;
  	const int h = (int)layer.header->height;
  	const float* bmin = layer.header->bmin;
  
  	// Portals
  	unsigned int pcol = duRGBA(255,255,255,255);
  	
  	const int segs[4*4] = {0,0,0,1, 0,1,1,1, 1,1,1,0, 1,0,0,0};
  	
  	// Layer portals
  	dd->begin(DU_DRAW_LINES, 2.0f);
  	for (int y = 0; y < h; ++y)
  	{
  		for (int x = 0; x < w; ++x)
  		{
  			const int idx = x+y*w;
  			const int lh = (int)layer.heights[idx];
  			if (lh == 0xff) continue;
  			
  			for (int dir = 0; dir < 4; ++dir)
  			{
  				if (layer.cons[idx] & (1<<(dir+4)))
  				{
  					const int* seg = &segs[dir*4];
  					const float ax = bmin[0] + (x+seg[0])*cs;
  					const float ay = bmin[1] + (lh+2)*ch;
  					const float az = bmin[2] + (y+seg[1])*cs;
  					const float bx = bmin[0] + (x+seg[2])*cs;
  					const float by = bmin[1] + (lh+2)*ch;
  					const float bz = bmin[2] + (y+seg[3])*cs;
  					dd->vertex(ax, ay, az, pcol);
  					dd->vertex(bx, by, bz, pcol);
  				}
  			}
  		}
  	}
  	dd->end();
  }
  
  void duDebugDrawTileCacheLayerAreas(struct duDebugDraw* dd, const dtTileCacheLayer& layer, const float cs, const float ch)
  {
  	const int w = (int)layer.header->width;
  	const int h = (int)layer.header->height;
  	const float* bmin = layer.header->bmin;
  	const float* bmax = layer.header->bmax;
  	const int idx = layer.header->tlayer;
  	
  	unsigned int color = duIntToCol(idx+1, 255);
  	
  	// Layer bounds
  	float lbmin[3], lbmax[3];
  	lbmin[0] = bmin[0] + layer.header->minx*cs;
  	lbmin[1] = bmin[1];
  	lbmin[2] = bmin[2] + layer.header->miny*cs;
  	lbmax[0] = bmin[0] + (layer.header->maxx+1)*cs;
  	lbmax[1] = bmax[1];
  	lbmax[2] = bmin[2] + (layer.header->maxy+1)*cs;
  	duDebugDrawBoxWire(dd, lbmin[0],lbmin[1],lbmin[2], lbmax[0],lbmax[1],lbmax[2], duTransCol(color,128), 2.0f);
  	
  	// Layer height
  	dd->begin(DU_DRAW_QUADS);
  	for (int y = 0; y < h; ++y)
  	{
  		for (int x = 0; x < w; ++x)
  		{
  			const int lidx = x+y*w;
  			const int lh = (int)layer.heights[lidx];
  			if (lh == 0xff) continue;
  			const unsigned char area = layer.areas[lidx];
  			
  			unsigned int col;
  			if (area == 63)
  				col = duLerpCol(color, duRGBA(0,192,255,64), 32);
  			else if (area == 0)
  				col = duLerpCol(color, duRGBA(0,0,0,64), 32);
  			else
  				col = duLerpCol(color, duIntToCol(area, 255), 32);
  			
  			const float fx = bmin[0] + x*cs;
  			const float fy = bmin[1] + (lh+1)*ch;
  			const float fz = bmin[2] + y*cs;
  			
  			dd->vertex(fx, fy, fz, col);
  			dd->vertex(fx, fy, fz+cs, col);
  			dd->vertex(fx+cs, fy, fz+cs, col);
  			dd->vertex(fx+cs, fy, fz, col);
  		}
  	}
  	dd->end();
  	
  	debugDrawTileCachePortals(dd, layer, cs, ch);
  }
  
  void duDebugDrawTileCacheLayerRegions(struct duDebugDraw* dd, const dtTileCacheLayer& layer, const float cs, const float ch)
  {
  	const int w = (int)layer.header->width;
  	const int h = (int)layer.header->height;
  	const float* bmin = layer.header->bmin;
  	const float* bmax = layer.header->bmax;
  	const int idx = layer.header->tlayer;
  	
  	unsigned int color = duIntToCol(idx+1, 255);
  	
  	// Layer bounds
  	float lbmin[3], lbmax[3];
  	lbmin[0] = bmin[0] + layer.header->minx*cs;
  	lbmin[1] = bmin[1];
  	lbmin[2] = bmin[2] + layer.header->miny*cs;
  	lbmax[0] = bmin[0] + (layer.header->maxx+1)*cs;
  	lbmax[1] = bmax[1];
  	lbmax[2] = bmin[2] + (layer.header->maxy+1)*cs;
  	duDebugDrawBoxWire(dd, lbmin[0],lbmin[1],lbmin[2], lbmax[0],lbmax[1],lbmax[2], duTransCol(color,128), 2.0f);
  	
  	// Layer height
  	dd->begin(DU_DRAW_QUADS);
  	for (int y = 0; y < h; ++y)
  	{
  		for (int x = 0; x < w; ++x)
  		{
  			const int lidx = x+y*w;
  			const int lh = (int)layer.heights[lidx];
  			if (lh == 0xff) continue;
  			const unsigned char reg = layer.regs[lidx];
  			
  			unsigned int col = duLerpCol(color, duIntToCol(reg, 255), 192);
  			
  			const float fx = bmin[0] + x*cs;
  			const float fy = bmin[1] + (lh+1)*ch;
  			const float fz = bmin[2] + y*cs;
  			
  			dd->vertex(fx, fy, fz, col);
  			dd->vertex(fx, fy, fz+cs, col);
  			dd->vertex(fx+cs, fy, fz+cs, col);
  			dd->vertex(fx+cs, fy, fz, col);
  		}
  	}
  	dd->end();
  	
  	debugDrawTileCachePortals(dd, layer, cs, ch);
  }
  
  
  
  
  /*struct dtTileCacheContour
  {
  	int nverts;
  	unsigned char* verts;
  	unsigned char reg;
  	unsigned char area;
  };
  
  struct dtTileCacheContourSet
  {
  	int nconts;
  	dtTileCacheContour* conts;
  };*/
  
  void duDebugDrawTileCacheContours(duDebugDraw* dd, const struct dtTileCacheContourSet& lcset,
  								  const float* orig, const float cs, const float ch)
  {
  	if (!dd) return;
  	
  	const unsigned char a = 255;// (unsigned char)(alpha*255.0f);
  	
  	const int offs[2*4] = {-1,0, 0,1, 1,0, 0,-1};
  	
  	dd->begin(DU_DRAW_LINES, 2.0f);
  	
  	for (int i = 0; i < lcset.nconts; ++i)
  	{
  		const dtTileCacheContour& c = lcset.conts[i];
  		unsigned int color = 0;
  		
  		color = duIntToCol(i, a);
  		
  		for (int j = 0; j < c.nverts; ++j)
  		{
  			const int k = (j+1) % c.nverts;
  			const unsigned char* va = &c.verts[j*4];
  			const unsigned char* vb = &c.verts[k*4];
  			const float ax = orig[0] + va[0]*cs;
  			const float ay = orig[1] + (va[1]+1+(i&1))*ch;
  			const float az = orig[2] + va[2]*cs;
  			const float bx = orig[0] + vb[0]*cs;
  			const float by = orig[1] + (vb[1]+1+(i&1))*ch;
  			const float bz = orig[2] + vb[2]*cs;
  			unsigned int col = color;
  			if ((va[3] & 0xf) != 0xf)
  			{
  				// Portal segment
  				col = duRGBA(255,255,255,128);
  				int d = va[3] & 0xf;
  				
  				const float cx = (ax+bx)*0.5f;
  				const float cy = (ay+by)*0.5f;
  				const float cz = (az+bz)*0.5f;
  				
  				const float dx = cx + offs[d*2+0]*2*cs;
  				const float dy = cy;
  				const float dz = cz + offs[d*2+1]*2*cs;
  				
  				dd->vertex(cx,cy,cz,duRGBA(255,0,0,255));
  				dd->vertex(dx,dy,dz,duRGBA(255,0,0,255));
  			}
  			
  			duAppendArrow(dd, ax,ay,az, bx,by,bz, 0.0f, cs*0.5f, col);
  		}
  	}
  	dd->end();
  	
  	dd->begin(DU_DRAW_POINTS, 4.0f);	
  	
  	for (int i = 0; i < lcset.nconts; ++i)
  	{
  		const dtTileCacheContour& c = lcset.conts[i];
  		unsigned int color = 0;
  		
  		for (int j = 0; j < c.nverts; ++j)
  		{
  			const unsigned char* va = &c.verts[j*4];
  			
  			color = duDarkenCol(duIntToCol(i, a));
  			if (va[3] & 0x80)
  			{
  				// Border vertex
  				color = duRGBA(255,0,0,255);
  			}
  			
  			float fx = orig[0] + va[0]*cs;
  			float fy = orig[1] + (va[1]+1+(i&1))*ch;
  			float fz = orig[2] + va[2]*cs;
  			dd->vertex(fx,fy,fz, color);
  		}
  	}
  	dd->end();
  }
  
  void duDebugDrawTileCachePolyMesh(duDebugDraw* dd, const struct dtTileCachePolyMesh& lmesh,
  								  const float* orig, const float cs, const float ch)
  {
  	if (!dd) return;
  	
  	const int nvp = lmesh.nvp;
  	
  	const int offs[2*4] = {-1,0, 0,1, 1,0, 0,-1};
  	
  	dd->begin(DU_DRAW_TRIS);
  	
  	for (int i = 0; i < lmesh.npolys; ++i)
  	{
  		const unsigned short* p = &lmesh.polys[i*nvp*2];
  		
  		unsigned int color;
  		if (lmesh.areas[i] == DT_TILECACHE_WALKABLE_AREA)
  			color = duRGBA(0,192,255,64);
  		else if (lmesh.areas[i] == DT_TILECACHE_NULL_AREA)
  			color = duRGBA(0,0,0,64);
  		else
  			color = duIntToCol(lmesh.areas[i], 255);
  		
  		unsigned short vi[3];
  		for (int j = 2; j < nvp; ++j)
  		{
  			if (p[j] == DT_TILECACHE_NULL_IDX) break;
  			vi[0] = p[0];
  			vi[1] = p[j-1];
  			vi[2] = p[j];
  			for (int k = 0; k < 3; ++k)
  			{
  				const unsigned short* v = &lmesh.verts[vi[k]*3];
  				const float x = orig[0] + v[0]*cs;
  				const float y = orig[1] + (v[1]+1)*ch;
  				const float z = orig[2] + v[2]*cs;
  				dd->vertex(x,y,z, color);
  			}
  		}
  	}
  	dd->end();
  	
  	// Draw neighbours edges
  	const unsigned int coln = duRGBA(0,48,64,32);
  	dd->begin(DU_DRAW_LINES, 1.5f);
  	for (int i = 0; i < lmesh.npolys; ++i)
  	{
  		const unsigned short* p = &lmesh.polys[i*nvp*2];
  		for (int j = 0; j < nvp; ++j)
  		{
  			if (p[j] == DT_TILECACHE_NULL_IDX) break;
  			if (p[nvp+j] & 0x8000) continue;
  			const int nj = (j+1 >= nvp || p[j+1] == DT_TILECACHE_NULL_IDX) ? 0 : j+1; 
  			int vi[2] = {p[j], p[nj]};
  			
  			for (int k = 0; k < 2; ++k)
  			{
  				const unsigned short* v = &lmesh.verts[vi[k]*3];
  				const float x = orig[0] + v[0]*cs;
  				const float y = orig[1] + (v[1]+1)*ch + 0.1f;
  				const float z = orig[2] + v[2]*cs;
  				dd->vertex(x, y, z, coln);
  			}
  		}
  	}
  	dd->end();
  	
  	// Draw boundary edges
  	const unsigned int colb = duRGBA(0,48,64,220);
  	dd->begin(DU_DRAW_LINES, 2.5f);
  	for (int i = 0; i < lmesh.npolys; ++i)
  	{
  		const unsigned short* p = &lmesh.polys[i*nvp*2];
  		for (int j = 0; j < nvp; ++j)
  		{
  			if (p[j] == DT_TILECACHE_NULL_IDX) break;
  			if ((p[nvp+j] & 0x8000) == 0) continue;
  			const int nj = (j+1 >= nvp || p[j+1] == DT_TILECACHE_NULL_IDX) ? 0 : j+1; 
  			int vi[2] = {p[j], p[nj]};
  			
  			unsigned int col = colb;
  			if ((p[nvp+j] & 0xf) != 0xf)
  			{
  				const unsigned short* va = &lmesh.verts[vi[0]*3];
  				const unsigned short* vb = &lmesh.verts[vi[1]*3];
  				
  				const float ax = orig[0] + va[0]*cs;
  				const float ay = orig[1] + (va[1]+1+(i&1))*ch;
  				const float az = orig[2] + va[2]*cs;
  				const float bx = orig[0] + vb[0]*cs;
  				const float by = orig[1] + (vb[1]+1+(i&1))*ch;
  				const float bz = orig[2] + vb[2]*cs;
  				
  				const float cx = (ax+bx)*0.5f;
  				const float cy = (ay+by)*0.5f;
  				const float cz = (az+bz)*0.5f;
  				
  				int d = p[nvp+j] & 0xf;
  				
  				const float dx = cx + offs[d*2+0]*2*cs;
  				const float dy = cy;
  				const float dz = cz + offs[d*2+1]*2*cs;
  				
  				dd->vertex(cx,cy,cz,duRGBA(255,0,0,255));
  				dd->vertex(dx,dy,dz,duRGBA(255,0,0,255));
  				
  				col = duRGBA(255,255,255,128);
  			}
  			
  			for (int k = 0; k < 2; ++k)
  			{
  				const unsigned short* v = &lmesh.verts[vi[k]*3];
  				const float x = orig[0] + v[0]*cs;
  				const float y = orig[1] + (v[1]+1)*ch + 0.1f;
  				const float z = orig[2] + v[2]*cs;
  				dd->vertex(x, y, z, col);
  			}
  		}
  	}
  	dd->end();
  	
  	dd->begin(DU_DRAW_POINTS, 3.0f);
  	const unsigned int colv = duRGBA(0,0,0,220);
  	for (int i = 0; i < lmesh.nverts; ++i)
  	{
  		const unsigned short* v = &lmesh.verts[i*3];
  		const float x = orig[0] + v[0]*cs;
  		const float y = orig[1] + (v[1]+1)*ch + 0.1f;
  		const float z = orig[2] + v[2]*cs;
  		dd->vertex(x,y,z, colv);
  	}
  	dd->end();
  }