コード例 #1
0
ファイル: MiniMap.cpp プロジェクト: stev47/0ad
void CMiniMap::SetCameraPos()
{
	CTerrain* terrain = g_Game->GetWorld()->GetTerrain();

	CVector3D target;
	GetMouseWorldCoordinates(target.X, target.Z);
	target.Y = terrain->GetExactGroundLevel(target.X, target.Z);
	g_Game->GetView()->MoveCameraTarget(target);
}
コード例 #2
0
ファイル: WaterManager.cpp プロジェクト: krichter722/0ad
// This requires m_DistanceHeightmap to be defined properly.
void WaterManager::CreateWaveMeshes()
{
	size_t SideSize = m_MapSize*2;
	CTerrain* terrain = g_Game->GetWorld()->GetTerrain();

	for (WaveObject* const& obj : m_ShoreWaves)
	{
		if (obj->m_VBvertices)
			g_VBMan.Release(obj->m_VBvertices);
		delete obj;
	}
	m_ShoreWaves.clear();

	if (m_ShoreWaves_VBIndices)
	{
		g_VBMan.Release(m_ShoreWaves_VBIndices);
		m_ShoreWaves_VBIndices = NULL;
	}

	if (m_Waviness < 5.0f && m_WaterType != L"ocean")
		return;
		
	// First step: get the points near the coast.
	std::set<int> CoastalPointsSet;
	for (size_t z = 1; z < SideSize-1; ++z)
		for (size_t x = 1; x < SideSize-1; ++x)
			if (fabs(m_DistanceHeightmap[z*SideSize + x]-1.0f) < 0.2f)
				CoastalPointsSet.insert(z*SideSize + x);
	
	// Second step: create chains out of those coastal points.
	static const int around[8][2] = { { -1,-1 }, { -1,0 }, { -1,1 }, { 0,1 }, { 1,1 }, { 1,0 }, { 1,-1 }, { 0,-1 } };

	std::vector<std::deque<CoastalPoint> > CoastalPointsChains;
	while (!CoastalPointsSet.empty())
	{
		int index = *(CoastalPointsSet.begin());
		int x = index % SideSize;
		int y = (index - x ) / SideSize;
		
		std::deque<CoastalPoint> Chain;
		
		Chain.push_front(CoastalPoint(index,CVector2D(x*2,y*2)));
		
		// Erase us.
		CoastalPointsSet.erase(CoastalPointsSet.begin());
		
		// We're our starter points. At most we can have 2 points close to us.
		// We'll pick the first one and look for its neighbors (he can only have one new)
		// Up until we either reach the end of the chain, or ourselves.
		// Then go down the other direction if there is any.
		int neighbours[2] = { -1, -1 };
		int nbNeighb = 0;
		for (int i = 0; i < 8; ++i)
		{
			if (CoastalPointsSet.count(x + around[i][0] + (y + around[i][1])*SideSize))
			{
				if (nbNeighb < 2)
					neighbours[nbNeighb] = x + around[i][0] + (y + around[i][1])*SideSize;
				++nbNeighb;
			}
		}
		if (nbNeighb > 2)
			continue;

		for (int i = 0; i < 2; ++i)
		{
			if (neighbours[i] == -1)
				continue;
			// Move to our neighboring point
			int xx = neighbours[i] % SideSize;
			int yy = (neighbours[i] - xx ) / SideSize;
			int indexx = xx + yy*SideSize;
			int endedChain = false;
			
			if (i == 0)
				Chain.push_back(CoastalPoint(indexx,CVector2D(xx*2,yy*2)));
			else
				Chain.push_front(CoastalPoint(indexx,CVector2D(xx*2,yy*2)));

			// If there's a loop we'll be the "other" neighboring point already so check for that.
			// We'll readd at the end/front the other one to have full squares.
			if (CoastalPointsSet.count(indexx) == 0)
				break;
						
			CoastalPointsSet.erase(indexx);

			// Start checking from there.
			while(!endedChain)
			{
				bool found = false;
				nbNeighb = 0;
				for (int p = 0; p < 8; ++p)
				{
					if (CoastalPointsSet.count(xx+around[p][0] + (yy + around[p][1])*SideSize))
					{
						if (nbNeighb >= 2)
						{
							CoastalPointsSet.erase(xx + yy*SideSize);
							continue;
						}
						++nbNeighb;
						// We've found a new point around us.
						// Move there
						xx = xx + around[p][0];
						yy = yy + around[p][1];
						indexx = xx + yy*SideSize;
						if (i == 0)
							Chain.push_back(CoastalPoint(indexx,CVector2D(xx*2,yy*2)));
						else
							Chain.push_front(CoastalPoint(indexx,CVector2D(xx*2,yy*2)));
						CoastalPointsSet.erase(xx + yy*SideSize);
						found = true;
						break;
					}
				}
				if (!found)
					endedChain = true;
			}
		}
		if (Chain.size() > 10)
			CoastalPointsChains.push_back(Chain);
	}
		
	// (optional) third step: Smooth chains out.
	// This is also really dumb.
	for (size_t i = 0; i < CoastalPointsChains.size(); ++i)
	{
		// Bump 1 for smoother.
		for (int p = 0; p < 3; ++p)
		{
			for (size_t j = 1; j < CoastalPointsChains[i].size()-1; ++j)
			{
				CVector2D realPos = CoastalPointsChains[i][j-1].position + CoastalPointsChains[i][j+1].position;
				
				CoastalPointsChains[i][j].position = (CoastalPointsChains[i][j].position + realPos/2.0f)/2.0f;
			}
		}
	}
	
	// Fourth step: create waves themselves, using those chains. We basically create subchains.
	size_t waveSizes = 14;	// maximal size in width.
	
	// Construct indices buffer (we can afford one for all of them)
	std::vector<GLushort> water_indices;
	for (size_t a = 0; a < waveSizes-1;++a)
	{
		for (size_t rect = 0; rect < 7; ++rect)
		{
			water_indices.push_back(a*9 + rect);
			water_indices.push_back(a*9 + 9 + rect);
			water_indices.push_back(a*9 + 1 + rect);
			water_indices.push_back(a*9 + 9 + rect);
			water_indices.push_back(a*9 + 10 + rect);
			water_indices.push_back(a*9 + 1 + rect);
		}
	}
	// Generic indexes, max-length
	m_ShoreWaves_VBIndices = g_VBMan.Allocate(sizeof(GLushort), water_indices.size(), GL_STATIC_DRAW, GL_ELEMENT_ARRAY_BUFFER);
	m_ShoreWaves_VBIndices->m_Owner->UpdateChunkVertices(m_ShoreWaves_VBIndices, &water_indices[0]);
	
	float diff = (rand() % 50) / 5.0f;
	
	for (size_t i = 0; i < CoastalPointsChains.size(); ++i)
	{
		for (size_t j = 0; j < CoastalPointsChains[i].size()-waveSizes; ++j)
		{
			if (CoastalPointsChains[i].size()- 1 - j < waveSizes)
				break;
			
			size_t width = waveSizes;
			
			// First pass to get some parameters out.
			float outmost = 0.0f;	// how far to move on the shore.
			float avgDepth = 0.0f;
			int sign = 1;
			CVector2D firstPerp(0,0), perp(0,0), lastPerp(0,0);
			for (size_t a = 0; a < waveSizes;++a)
			{
				lastPerp = perp;
				perp = CVector2D(0,0);
				int nb = 0;
				CVector2D pos = CoastalPointsChains[i][j+a].position;
				CVector2D posPlus;
				CVector2D posMinus;
				if (a > 0)
				{
					++nb;
					posMinus = CoastalPointsChains[i][j+a-1].position;
					perp += pos-posMinus;
				}
				if (a < waveSizes-1)
				{
					++nb;
					posPlus = CoastalPointsChains[i][j+a+1].position;
					perp += posPlus-pos;
				}
				perp /= nb;
				perp = CVector2D(-perp.Y,perp.X).Normalized();
				
				if (a == 0)
					firstPerp = perp;
				
				if ( a > 1 && perp.Dot(lastPerp) < 0.90f && perp.Dot(firstPerp) < 0.70f)
				{
					width = a+1;
					break;
				}
				
				if (m_BlurredNormalMap[ (int)(pos.X/4) + (int)(pos.Y/4)*m_MapSize].Y < 0.9)
				{
					width = a-1;
					break;
				}
				
				if (terrain->GetExactGroundLevel(pos.X+perp.X*1.5f, pos.Y+perp.Y*1.5f) > m_WaterHeight)
					sign = -1;
				
				avgDepth += terrain->GetExactGroundLevel(pos.X+sign*perp.X*20.0f, pos.Y+sign*perp.Y*20.0f) - m_WaterHeight;
				
				float localOutmost = -2.0f;
				while (localOutmost < 0.0f)
				{
					float depth = terrain->GetExactGroundLevel(pos.X+sign*perp.X*localOutmost, pos.Y+sign*perp.Y*localOutmost) - m_WaterHeight;
					if (depth < 0.0f || depth > 0.6f)
						localOutmost += 0.2f;
					else
						break;
				}

				outmost += localOutmost;
			}
			if (width < 5)
			{
				j += 6;
				continue;
			}

			outmost /= width;
			
			if (outmost > -0.5f)
			{
				j += 3;
				continue;
			}
			outmost = -0.5f + outmost * m_Waviness/10.0f;

			avgDepth /= width;

			if (avgDepth > -1.3f)
			{
				j += 3;
				continue;
			}
			// we passed the checks, we can create a wave of size "width".
			
			WaveObject* shoreWave = new WaveObject;
			std::vector<SWavesVertex> vertices;

			shoreWave->m_Width = width;
			shoreWave->m_TimeDiff = diff;
			diff += (rand() % 100) / 25.0f + 4.0f;

			for (size_t a = 0; a < width;++a)
			{
				CVector2D perp = CVector2D(0,0);
				int nb = 0;
				CVector2D pos = CoastalPointsChains[i][j+a].position;
				CVector2D posPlus;
				CVector2D posMinus;
				if (a > 0)
				{
					++nb;
					posMinus = CoastalPointsChains[i][j+a-1].position;
					perp += pos-posMinus;
				}
				if (a < waveSizes-1)
				{
					++nb;
					posPlus = CoastalPointsChains[i][j+a+1].position;
					perp += posPlus-pos;
				}
				perp /= nb;
				perp = CVector2D(-perp.Y,perp.X).Normalized();
				
				SWavesVertex point[9];
				
				float baseHeight = 0.04f;
				
				float halfWidth = (width-1.0f)/2.0f;
				float sideNess = sqrtf(clamp( (halfWidth - fabsf(a-halfWidth))/3.0f, 0.0f,1.0f));
				
				point[0].m_UV[0] = a; point[0].m_UV[1] = 8;
				point[1].m_UV[0] = a; point[1].m_UV[1] = 7;
				point[2].m_UV[0] = a; point[2].m_UV[1] = 6;
				point[3].m_UV[0] = a; point[3].m_UV[1] = 5;
				point[4].m_UV[0] = a; point[4].m_UV[1] = 4;
				point[5].m_UV[0] = a; point[5].m_UV[1] = 3;
				point[6].m_UV[0] = a; point[6].m_UV[1] = 2;
				point[7].m_UV[0] = a; point[7].m_UV[1] = 1;
				point[8].m_UV[0] = a; point[8].m_UV[1] = 0;
				
				point[0].m_PerpVect = perp;
				point[1].m_PerpVect = perp;
				point[2].m_PerpVect = perp;
				point[3].m_PerpVect = perp;
				point[4].m_PerpVect = perp;
				point[5].m_PerpVect = perp;
				point[6].m_PerpVect = perp;
				point[7].m_PerpVect = perp;
				point[8].m_PerpVect = perp;
				
				static const float perpT1[9] = { 6.0f, 6.05f, 6.1f, 6.2f, 6.3f, 6.4f, 6.5f, 6.6f, 9.7f };
				static const float perpT2[9] = { 2.0f, 2.1f,  2.2f, 2.3f, 2.4f, 3.0f, 3.3f, 3.6f, 9.5f };
				static const float perpT3[9] = { 1.1f, 0.7f, -0.2f, 0.0f, 0.6f, 1.3f, 2.2f, 3.6f, 9.0f };
				static const float perpT4[9] = { 2.0f, 2.1f,  1.2f, 1.5f, 1.7f, 1.9f, 2.7f, 3.8f, 9.0f };
				
				static const float heightT1[9] = { 0.0f, 0.2f, 0.5f, 0.8f, 0.9f, 0.85f, 0.6f, 0.2f, 0.0 };
				static const float heightT2[9] = { -0.8f, -0.4f, 0.0f, 0.1f, 0.1f, 0.03f, 0.0f, 0.0f, 0.0 };
				static const float heightT3[9] = { 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0 };

				for (size_t t = 0; t < 9; ++t)
				{
					float terrHeight = 0.05f + terrain->GetExactGroundLevel(pos.X+sign*perp.X*(perpT1[t]+outmost),
																			pos.Y+sign*perp.Y*(perpT1[t]+outmost));
					point[t].m_BasePosition = CVector3D(pos.X+sign*perp.X*(perpT1[t]+outmost), baseHeight + heightT1[t]*sideNess + std::max(m_WaterHeight,terrHeight),
														pos.Y+sign*perp.Y*(perpT1[t]+outmost));
				}
				for (size_t t = 0; t < 9; ++t)
				{
					float terrHeight = 0.05f + terrain->GetExactGroundLevel(pos.X+sign*perp.X*(perpT2[t]+outmost),
																			pos.Y+sign*perp.Y*(perpT2[t]+outmost));
					point[t].m_ApexPosition = CVector3D(pos.X+sign*perp.X*(perpT2[t]+outmost), baseHeight + heightT1[t]*sideNess + std::max(m_WaterHeight,terrHeight),
														pos.Y+sign*perp.Y*(perpT2[t]+outmost));
				}
				for (size_t t = 0; t < 9; ++t)
				{
					float terrHeight = 0.05f + terrain->GetExactGroundLevel(pos.X+sign*perp.X*(perpT3[t]+outmost*sideNess),
																			pos.Y+sign*perp.Y*(perpT3[t]+outmost*sideNess));
					point[t].m_SplashPosition = CVector3D(pos.X+sign*perp.X*(perpT3[t]+outmost*sideNess), baseHeight + heightT2[t]*sideNess + std::max(m_WaterHeight,terrHeight), pos.Y+sign*perp.Y*(perpT3[t]+outmost*sideNess));
				}
				for (size_t t = 0; t < 9; ++t)
				{
					float terrHeight = 0.05f + terrain->GetExactGroundLevel(pos.X+sign*perp.X*(perpT4[t]+outmost),
																			pos.Y+sign*perp.Y*(perpT4[t]+outmost));
					point[t].m_RetreatPosition = CVector3D(pos.X+sign*perp.X*(perpT4[t]+outmost), baseHeight + heightT3[t]*sideNess + std::max(m_WaterHeight,terrHeight),
														   pos.Y+sign*perp.Y*(perpT4[t]+outmost));
				}
				
				vertices.push_back(point[8]);
				vertices.push_back(point[7]);
				vertices.push_back(point[6]);
				vertices.push_back(point[5]);
				vertices.push_back(point[4]);
				vertices.push_back(point[3]);
				vertices.push_back(point[2]);
				vertices.push_back(point[1]);
				vertices.push_back(point[0]);
				
				shoreWave->m_AABB += point[8].m_SplashPosition;
				shoreWave->m_AABB += point[8].m_BasePosition;
				shoreWave->m_AABB += point[0].m_SplashPosition;
				shoreWave->m_AABB += point[0].m_BasePosition;
				shoreWave->m_AABB += point[4].m_ApexPosition;
			}

			if (sign == 1)
			{
				// Let's do some fancy reversing.
				std::vector<SWavesVertex> reversed;
				for (int a = width-1; a >= 0; --a)
				{
					for (size_t t = 0; t < 9; ++t)
						reversed.push_back(vertices[a*9+t]);
				}
				vertices = reversed;
			}
			j += width/2-1;
			
			shoreWave->m_VBvertices = g_VBMan.Allocate(sizeof(SWavesVertex), vertices.size(), GL_STATIC_DRAW, GL_ARRAY_BUFFER);
			shoreWave->m_VBvertices->m_Owner->UpdateChunkVertices(shoreWave->m_VBvertices, &vertices[0]);
			
			m_ShoreWaves.push_back(shoreWave);
		}
	}
}
コード例 #3
0
ファイル: WaterManager.cpp プロジェクト: krichter722/0ad
///////////////////////////////////////////////////////////////////
// Calculate our binary heightmap from the terrain heightmap.
void WaterManager::RecomputeDistanceHeightmap()
{
	size_t SideSize = m_MapSize*2;
	if (m_DistanceHeightmap == NULL)
		m_DistanceHeightmap = new float[SideSize*SideSize];
		
	CTerrain* terrain = g_Game->GetWorld()->GetTerrain();
	
	// Create a manhattan-distance heightmap.
	// This is currently upsampled by a factor of 2 to get more precision
	// This could be refined to only be done near the coast itself, but it's probably not necessary.
	
	for (size_t z = 0; z < SideSize; ++z)
	{
		float level = SideSize;
		for (size_t x = 0; x < SideSize; ++x)
			m_DistanceHeightmap[z*SideSize + x] = terrain->GetExactGroundLevel(x*2, z*2) >= m_WaterHeight ? level = 0.f : ++level;
		level = SideSize;
		for (size_t x = SideSize-1; x != (size_t)-1; --x)
		{
			if (terrain->GetExactGroundLevel(x*2, z*2) >= m_WaterHeight)
				level = 0.f;
			else
			{
				++level;
				if (level < m_DistanceHeightmap[z*SideSize + x])
					m_DistanceHeightmap[z*SideSize + x] = level;
			}
		}
	}
	for (size_t x = 0; x < SideSize; ++x)
	{
		float level = SideSize;
		for (size_t z = 0; z < SideSize; ++z)
		{
			if (terrain->GetExactGroundLevel(x*2, z*2) >= m_WaterHeight)
				level = 0.f;
			else if (level > m_DistanceHeightmap[z*SideSize + x])
				level = m_DistanceHeightmap[z*SideSize + x];
			else
			{
				++level;
				if (level < m_DistanceHeightmap[z*SideSize + x])
					m_DistanceHeightmap[z*SideSize + x] = level;
			}
		}
		level = SideSize;
		for (size_t z = SideSize-1; z != (size_t)-1; --z)
		{
			if (terrain->GetExactGroundLevel(x*2, z*2) >= m_WaterHeight)
				level = 0.f;
			else if (level > m_DistanceHeightmap[z*SideSize + x])
				level = m_DistanceHeightmap[z*SideSize + x];
			else
			{
				++level;
				if (level < m_DistanceHeightmap[z*SideSize + x])
					m_DistanceHeightmap[z*SideSize + x] = level;
			}
		}
	}
}
コード例 #4
0
ファイル: WaterManager.cpp プロジェクト: temirio/0ad
///////////////////////////////////////////////////////////////////
// Create information about the terrain and wave vertices.
void WaterManager::CreateSuperfancyInfo(CSimulation2* simulation)
{
	if (m_VBWaves)
	{
		g_VBMan.Release(m_VBWaves);
		m_VBWaves = NULL;
	}
	if (m_VBWavesIndices)
	{
		g_VBMan.Release(m_VBWavesIndices);
		m_VBWavesIndices = NULL;
	}

	CTerrain* terrain = g_Game->GetWorld()->GetTerrain();
	ssize_t mapSize = terrain->GetVerticesPerSide();
	
	CmpPtr<ICmpWaterManager> cmpWaterManager(*simulation, SYSTEM_ENTITY);
	if (!cmpWaterManager)
		return;	// REALLY shouldn't happen and will most likely crash.

	// Using this to get some more optimization on circular maps
	CmpPtr<ICmpRangeManager> cmpRangeManager(*simulation, SYSTEM_ENTITY);
	if (!cmpRangeManager)
		return;
	bool circular = cmpRangeManager->GetLosCircular();
	float mSize = mapSize*mapSize;
	float halfSize = (mapSize/2.0);

	// Warning: this won't work with multiple water planes
	m_WaterHeight = cmpWaterManager->GetExactWaterLevel(0,0);
	
	// TODO: change this whenever we incrementally update because it's def. not too efficient
	delete[] m_WaveX;
	delete[] m_WaveZ;
	delete[] m_DistanceToShore;
	delete[] m_FoamFactor;
	
	m_WaveX = new float[mapSize*mapSize];
	m_WaveZ = new float[mapSize*mapSize];
	m_DistanceToShore = new float[mapSize*mapSize];
	m_FoamFactor = new float[mapSize*mapSize];

	u16* heightmap = terrain->GetHeightMap();
	
	// some temporary stuff for wave intensity
	// not really used too much right now.
	u8* waveForceHQ = new u8[mapSize*mapSize];
	u16 waterHeightInu16 = m_WaterHeight/HEIGHT_SCALE;

	// used to cache terrain normals since otherwise we'd recalculate them a lot (I'm blurring the "normal" map).
	// this might be updated to actually cache in the terrain manager but that's not for now.
	CVector3D* normals = new CVector3D[mapSize*mapSize];

	// calculate wave force (not really used right now)
	// and puts into "normals" the terrain normal at that point
	// so as to avoid recalculating terrain normals too often.
	for (ssize_t i = 0; i < mapSize; ++i)
	{
		for (ssize_t j = 0; j < mapSize; ++j)
		{
			normals[j*mapSize + i] = terrain->CalcExactNormal(((float)i)*4.0f,((float)j)*4.0f);
			if (circular && (i-halfSize)*(i-halfSize)+(j-halfSize)*(j-halfSize) > mSize)
			{
				waveForceHQ[j*mapSize + i] = 255;
				continue;
			}
			u8 color = 0;
			for (int v = 0; v <= 18; v += 3){
				if (j-v >= 0 && i-v >= 0 && heightmap[(j-v)*mapSize + i-v] > waterHeightInu16)
				{
					if (color == 0)
						color = 5;
					else
						color++;
				}
			}
			waveForceHQ[j*mapSize + i] = 255 - color * 40;
		}
	}
	// this creates information for waves and stores it in float arrays. PatchRData then puts it in the vertex info for speed.
	for (ssize_t i = 0; i < mapSize; ++i)
	{
		for (ssize_t j = 0; j < mapSize; ++j)
		{
			if (circular && (i-halfSize)*(i-halfSize)+(j-halfSize)*(j-halfSize) > mSize)
			{
				m_WaveX[j*mapSize + i] = 0.0f;
				m_WaveZ[j*mapSize + i] = 0.0f;
				m_DistanceToShore[j*mapSize + i] = 100;
				m_FoamFactor[j*mapSize + i] = 0.0f;
				continue;
			}
			float depth = m_WaterHeight - heightmap[j*mapSize + i]*HEIGHT_SCALE;
			int distanceToShore = 10000;
			
			// calculation of the distance to the shore.
			// TODO: this is fairly dumb, though it returns a good result
			// Could be sped up a fair bit.
			if (depth >= 0)
			{
				// check in the square around.
				for (int xx = -5; xx <= 5; ++xx)
				{
					for (int yy = -5; yy <= 5; ++yy)
					{
						if (i+xx >= 0 && i + xx < mapSize)
							if (j + yy >= 0 && j + yy < mapSize)
							{
								float hereDepth = m_WaterHeight - heightmap[(j+yy)*mapSize + (i+xx)]*HEIGHT_SCALE;
								if (hereDepth < 0 && xx*xx + yy*yy < distanceToShore)
									distanceToShore = xx*xx + yy*yy;
							}
					}
				}
				// refine the calculation if we're close enough
				if (distanceToShore < 9)
				{
					for (float xx = -2.5f; xx <= 2.5f; ++xx)
					{
						for (float yy = -2.5f; yy <= 2.5f; ++yy)
						{
							float hereDepth = m_WaterHeight - terrain->GetExactGroundLevel( (i+xx)*4, (j+yy)*4 );
							if (hereDepth < 0 && xx*xx + yy*yy < distanceToShore)
								distanceToShore = xx*xx + yy*yy;
						}
					}
				}
			}
			else
			{
				for (int xx = -2; xx <= 2; ++xx)
				{
					for (int yy = -2; yy <= 2; ++yy)
					{
						float hereDepth = m_WaterHeight - terrain->GetVertexGroundLevel(i+xx, j+yy);
						if (hereDepth > 0)
							distanceToShore = 0;
					}
				}
				
			}
			// speedup with default values for land squares
			if (distanceToShore == 10000)
			{
				m_WaveX[j*mapSize + i] = 0.0f;
				m_WaveZ[j*mapSize + i] = 0.0f;
				m_DistanceToShore[j*mapSize + i] = 100;
				m_FoamFactor[j*mapSize + i] = 0.0f;
				continue;
			}
			// We'll compute the normals and the "water raise", to know about foam
			// Normals are a pretty good calculation but it's slow since we normalize so much.
			CVector3D normal;
			int waterRaise = 0;
			for (int xx = -4; xx <= 4; xx += 2)	// every 2 tile is good enough.
			{
				for (int yy = -4; yy <= 4; yy += 2)
				{
					if (j+yy < mapSize && i+xx < mapSize && i+xx >= 0 && j+yy >= 0)
						normal += normals[(j+yy)*mapSize + (i+xx)];
					if (terrain->GetVertexGroundLevel(i+xx,j+yy) < heightmap[j*mapSize + i]*HEIGHT_SCALE)
						waterRaise += heightmap[j*mapSize + i]*HEIGHT_SCALE - terrain->GetVertexGroundLevel(i+xx,j+yy);
				}
			}
			// normalizes the terrain info to avoid foam moving at too different speeds.
			normal *= 0.012345679f;
			normal[1] = 0.1f;
			normal = normal.Normalized();

			m_WaveX[j*mapSize + i] = normal[0];
			m_WaveZ[j*mapSize + i] = normal[2];
			// distance is /5.0 to be a [0,1] value.

			m_DistanceToShore[j*mapSize + i] = sqrtf(distanceToShore)/5.0f; // TODO: this can probably be cached as I'm integer here.

			// computing the amount of foam I want

			depth = clamp(depth,0.0f,10.0f);
			float foamAmount = (waterRaise/255.0f) * (1.0f - depth/10.0f) * (waveForceHQ[j*mapSize+i]/255.0f) * (m_Waviness/8.0f);
			foamAmount += clamp(m_Waviness/2.0f - distanceToShore,0.0f,m_Waviness/2.0f)/(m_Waviness/2.0f) * clamp(m_Waviness/9.0f,0.3f,1.0f);
			foamAmount = foamAmount > 1.0f ? 1.0f: foamAmount;
			
			m_FoamFactor[j*mapSize + i] = foamAmount;
		}
	}

	delete[] normals;
	delete[] waveForceHQ;
	
	// TODO: The rest should be cleaned up
	
	// okay let's create the waves squares. i'll divide the map in arbitrary squares
	// For each of these squares, check if waves are needed.
	// If yes, look for the best positionning (in order to have a nice blending with the shore)
	// Then clean-up: remove squares that are too close to each other
	
	std::vector<CVector2D> waveSquares;
	
	int size = 8;	// I think this is the size of the squares.
	for (int i = 0; i < mapSize/size; ++i)
	{
		for (int j = 0; j < mapSize/size; ++j)
		{
			
			int landTexel = 0;
			int waterTexel = 0;
			CVector3D avnormal (0.0f,0.0f,0.0f);
			CVector2D landPosition(0.0f,0.0f);
			CVector2D waterPosition(0.0f,0.0f);
			for (int xx = 0; xx < size; ++xx)
			{
				for (int yy = 0; yy < size; ++yy)
				{
					if (terrain->GetVertexGroundLevel(i*size+xx,j*size+yy) > m_WaterHeight)
					{
						landTexel++;
						landPosition += CVector2D(i*size+xx,j*size+yy);
					}
					else
					{
						waterPosition += CVector2D(i*size+xx,j*size+yy);
						waterTexel++;
						avnormal += terrain->CalcExactNormal( (i*size+xx)*4.0f,(j*size+yy)*4.0f);
					}
				}
			}
			if (landTexel < size/2)
				continue;

			landPosition /= landTexel;
			waterPosition /= waterTexel;
			
			avnormal[1] = 1.0f;
			avnormal.Normalize();
			avnormal[1] = 0.0f;
			
			// this should help ensure that the shore is pretty flat.
			if (avnormal.Length() <= 0.2f)
				continue;
			
			// To get the best position for squares, I start at the mean "ocean" position
			// And step by step go to the mean "land" position. I keep the position where I change from water to land.
			// If this never happens, the square is scrapped.
			if (terrain->GetExactGroundLevel(waterPosition.X*4.0f,waterPosition.Y*4.0f) > m_WaterHeight)
				continue;
			
			CVector2D squarePos(-1,-1);
			for (u8 i = 0; i < 40; i++)
			{
				squarePos = landPosition * (i/40.0f) + waterPosition * (1.0f-(i/40.0f));
				if (terrain->GetExactGroundLevel(squarePos.X*4.0f,squarePos.Y*4.0f) > m_WaterHeight)
					break;
			}
			if (squarePos.X == -1)
				continue;
			
			u8 enter = 1;
			// okaaaaaay. Got a square. Check for proximity.
			for (unsigned long i = 0; i < waveSquares.size(); i++)
			{
				if ( CVector2D(waveSquares[i]-squarePos).LengthSquared() < 80) {
					enter = 0;
					break;
				}
			}
			if (enter == 1)
				waveSquares.push_back(squarePos);
		}
	}
	
	// Actually create the waves' meshes.
	std::vector<SWavesVertex> waves_vertex_data;
	std::vector<GLushort> waves_indices;
	
	// loop through each square point. Look in the square around it, calculate the normal
	// create the square.
	for (unsigned long i = 0; i < waveSquares.size(); i++)
	{
		CVector2D pos(waveSquares[i]);
		
		CVector3D avgnorm(0.0f,0.0f,0.0f);
		for (int xx = -size/2; xx < size/2; ++xx)
		{
			for (int yy = -size/2; yy < size/2; ++yy)
			{
				avgnorm += terrain->CalcExactNormal((pos.X+xx)*4.0f,(pos.Y+yy)*4.0f);
			}
		}
		avgnorm[1] = 0.1f;
		// okay crank out a square.
		// we have the direction of the square. We'll get the perpendicular vector too
		CVector2D perp(-avgnorm[2],avgnorm[0]);
		perp = perp.Normalized();
		avgnorm = avgnorm.Normalized();
		
		SWavesVertex vertex[4];
		vertex[0].m_Position = CVector3D(pos.X + perp.X*(size/2.2f) - avgnorm[0]*1.0f, 0.0f,pos.Y + perp.Y*(size/2.2f) - avgnorm[2]*1.0f);
		vertex[0].m_Position *= 4.0f;
		vertex[0].m_Position.Y = m_WaterHeight + 1.0f;
		vertex[0].m_UV[1] = 1;
		vertex[0].m_UV[0] = 0;
		
		vertex[1].m_Position = CVector3D(pos.X - perp.X*(size/2.2f) - avgnorm[0]*1.0f, 0.0f,pos.Y - perp.Y*(size/2.2f) - avgnorm[2]*1.0f);
		vertex[1].m_Position *= 4.0f;
		vertex[1].m_Position.Y = m_WaterHeight + 1.0f;
		vertex[1].m_UV[1] = 1;
		vertex[1].m_UV[0] = 1;
		
		vertex[3].m_Position = CVector3D(pos.X + perp.X*(size/2.2f) + avgnorm[0]*(size/1.5f), 0.0f,pos.Y + perp.Y*(size/2.2f) + avgnorm[2]*(size/1.5f));
		vertex[3].m_Position *= 4.0f;
		vertex[3].m_Position.Y = m_WaterHeight + 1.0f;
		vertex[3].m_UV[1] = 0;
		vertex[3].m_UV[0] = 0;
		
		vertex[2].m_Position = CVector3D(pos.X - perp.X*(size/2.2f) + avgnorm[0]*(size/1.5f), 0.0f,pos.Y - perp.Y*(size/2.2f) + avgnorm[2]*(size/1.5f));
		vertex[2].m_Position *= 4.0f;
		vertex[2].m_Position.Y = m_WaterHeight + 1.0f;
		vertex[2].m_UV[1] = 0;
		vertex[2].m_UV[0] = 1;
		
		waves_indices.push_back(waves_vertex_data.size());
		waves_vertex_data.push_back(vertex[0]);
		waves_indices.push_back(waves_vertex_data.size());
		waves_vertex_data.push_back(vertex[1]);
		waves_indices.push_back(waves_vertex_data.size());
		waves_vertex_data.push_back(vertex[2]);
		waves_indices.push_back(waves_vertex_data.size());
		waves_vertex_data.push_back(vertex[3]);
	}

	// no vertex buffers if no data generated
	if (waves_indices.empty())
		return;

	// waves
	// allocate vertex buffer
	m_VBWaves = g_VBMan.Allocate(sizeof(SWavesVertex), waves_vertex_data.size(), GL_STATIC_DRAW, GL_ARRAY_BUFFER);
	m_VBWaves->m_Owner->UpdateChunkVertices(m_VBWaves, &waves_vertex_data[0]);

	// Construct indices buffer
	m_VBWavesIndices = g_VBMan.Allocate(sizeof(GLushort), waves_indices.size(), GL_STATIC_DRAW, GL_ELEMENT_ARRAY_BUFFER);
	m_VBWavesIndices->m_Owner->UpdateChunkVertices(m_VBWavesIndices, &waves_indices[0]);
}