// taken from https://github.com/jeschke/water-wave-packets // Include the OS headers //----------------------- #include #include #include #include #include #include #include #include #include #include "Packets.h" #pragma warning( disable: 4996 ) inline float rational_tanh(float x) { if (x < -3.0f) return -1.0f; else if (x > 3.0f) return 1.0f; else return x*(27.0f + x*x) / (27.0f+9.0f*x*x); } float Packets::GetIntersectionDistance(Vector2f pos1, Vector2f dir1, Vector2f pos2, Vector2f dir2) { ParametrizedLine line1(pos1, dir1); Hyperplane line2 = Hyperplane::Through(pos2, pos2+dir2); float intPointDist = line1.intersectionParameter(line2); if (abs(intPointDist) > 10000.0f) intPointDist = 10000.0f; return intPointDist; } inline float Packets::GetGroundVal(Vector2f &p) { Vector2f pTex = Vector2f(p.x()/SCENE_EXTENT+0.5f,p.y()/SCENE_EXTENT+0.5f); // convert from world space to texture space float val1 = m_ground[(int)(max(0,min(m_groundSizeY-1,pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,pTex.x()*m_groundSizeX)))]; float val2 = m_ground[(int)(max(0,min(m_groundSizeY-1,pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,1+pTex.x()*m_groundSizeX)))]; float val3 = m_ground[(int)(max(0,min(m_groundSizeY-1,1+pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,pTex.x()*m_groundSizeX)))]; float val4 = m_ground[(int)(max(0,min(m_groundSizeY-1,1+pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,1+pTex.x()*m_groundSizeX)))]; float xOffs = (pTex.x()*m_groundSizeX) - (int)(pTex.x()*m_groundSizeX); float yOffs = (pTex.y()*m_groundSizeY) - (int)(pTex.y()*m_groundSizeY); float valH1 = (1.0f-xOffs)*val1 + xOffs*val2; float valH2 = (1.0f-xOffs)*val3 + xOffs*val4; return( (1.0f-yOffs)*valH1 + yOffs*valH2 ); } inline Vector2f Packets::GetGroundNormal(Vector2f &p) { Vector2f pTex = Vector2f(p.x()/SCENE_EXTENT+0.5f,p.y()/SCENE_EXTENT+0.5f); // convert from world space to texture space Vector2f val1 = m_gndDeriv[(int)(max(0,min(m_groundSizeY-1,pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,pTex.x()*m_groundSizeX)))]; Vector2f val2 = m_gndDeriv[(int)(max(0,min(m_groundSizeY-1,pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,1+pTex.x()*m_groundSizeX)))]; Vector2f val3 = m_gndDeriv[(int)(max(0,min(m_groundSizeY-1,1+pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,pTex.x()*m_groundSizeX)))]; Vector2f val4 = m_gndDeriv[(int)(max(0,min(m_groundSizeY-1,1+pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,1+pTex.x()*m_groundSizeX)))]; float xOffs = (pTex.x()*m_groundSizeX) - (int)(pTex.x()*m_groundSizeX); float yOffs = (pTex.y()*m_groundSizeY) - (int)(pTex.y()*m_groundSizeY); Vector2f valH1 = (1.0f-xOffs)*val1 + xOffs*val2; Vector2f valH2 = (1.0f-xOffs)*val3 + xOffs*val4; Vector2f res = (1.0f-yOffs)*valH1 + yOffs*valH2; Vector2f resN = Vector2f(0,1); if (abs(res.x()) + abs(res.y()) > 0.0) resN = res.normalized(); return( resN ); } inline float Packets::GetBoundaryDist(Vector2f &p) { Vector2f pTex = Vector2f(p.x()/SCENE_EXTENT+0.5f,p.y()/SCENE_EXTENT+0.5f); // convert from world space to texture space float val1 = m_distMap[(int)(max(0,min(m_groundSizeY-1,pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,pTex.x()*m_groundSizeX)))]; float val2 = m_distMap[(int)(max(0,min(m_groundSizeY-1,pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,1+pTex.x()*m_groundSizeX)))]; float val3 = m_distMap[(int)(max(0,min(m_groundSizeY-1,1+pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,pTex.x()*m_groundSizeX)))]; float val4 = m_distMap[(int)(max(0,min(m_groundSizeY-1,1+pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,1+pTex.x()*m_groundSizeX)))]; float xOffs = (pTex.x()*m_groundSizeX) - (int)(pTex.x()*m_groundSizeX); float yOffs = (pTex.y()*m_groundSizeY) - (int)(pTex.y()*m_groundSizeY); float valH1 = (1.0f-xOffs)*val1 + xOffs*val2; float valH2 = (1.0f-xOffs)*val3 + xOffs*val4; return( (1.0f-yOffs)*valH1 + yOffs*valH2 ); } inline Vector2f Packets::GetBoundaryNormal(Vector2f &p) { Vector2f pTex = Vector2f(p.x()/SCENE_EXTENT+0.5f,p.y()/SCENE_EXTENT+0.5f); // convert from world space to texture space Vector2f val1 = m_bndDeriv[(int)(max(0,min(m_groundSizeY-1,pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,pTex.x()*m_groundSizeX)))]; Vector2f val2 = m_bndDeriv[(int)(max(0,min(m_groundSizeY-1,pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,1+pTex.x()*m_groundSizeX)))]; Vector2f val3 = m_bndDeriv[(int)(max(0,min(m_groundSizeY-1,1+pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,pTex.x()*m_groundSizeX)))]; Vector2f val4 = m_bndDeriv[(int)(max(0,min(m_groundSizeY-1,1+pTex.y()*m_groundSizeY)))*m_groundSizeX + (int)(max(0,min(m_groundSizeX-1,1+pTex.x()*m_groundSizeX)))]; float xOffs = (pTex.x()*m_groundSizeX) - (int)(pTex.x()*m_groundSizeX); float yOffs = (pTex.y()*m_groundSizeY) - (int)(pTex.y()*m_groundSizeY); Vector2f valH1 = (1.0f-xOffs)*val1 + xOffs*val2; Vector2f valH2 = (1.0f-xOffs)*val3 + xOffs*val4; Vector2f res = (1.0f-yOffs)*valH1 + yOffs*valH2; Vector2f resN = Vector2f(0,1); if (abs(res.x())+abs(res.y()) > 0.0) resN = res.normalized(); return( resN ); } #pragma warning( push ) #pragma warning( disable : 4996) Packets::Packets(int packetBudget) { WCHAR wcInfo[512]; //load ground/boundary texture for CPU processing LPCWSTR groundTexFile = WATER_TERRAIN_FILE; tagBITMAPFILEHEADER bmpheader; tagBITMAPINFOHEADER bmpinfo; DWORD bytesread; HANDLE file = CreateFile( groundTexFile , GENERIC_READ, FILE_SHARE_READ, NULL, OPEN_EXISTING, FILE_FLAG_SEQUENTIAL_SCAN, NULL ); if (file == NULL) { throw std::exception("Media file not found"); return; } if ( (ReadFile ( file, &bmpheader, sizeof ( BITMAPFILEHEADER ), &bytesread, NULL ) == false) || (ReadFile(file, &bmpinfo, sizeof(BITMAPINFOHEADER), &bytesread, NULL) == false) || (bmpheader.bfType != 'MB') || (bmpinfo.biCompression != BI_RGB) || (bmpinfo.biBitCount != 24) ) { CloseHandle ( file ); throw std::exception("Error reading media file"); return; } m_groundSizeX = abs(bmpinfo.biWidth); m_groundSizeY = abs(bmpinfo.biHeight); long size = bmpheader.bfSize-bmpheader.bfOffBits; SetFilePointer ( file, bmpheader.bfOffBits, NULL, FILE_BEGIN ); BYTE* Buffer = new BYTE[size]; if ( ReadFile ( file, Buffer, size, &bytesread, NULL ) == false ) { delete[](Buffer); CloseHandle(file); throw std::exception("Media file not found"); return; } CloseHandle(file); // convert read buffer to our rgb datastructure int padding = 0; int scanlinebytes = m_groundSizeX*3; while ( ( scanlinebytes + padding ) % 4 != 0 ) padding++; int psw = scanlinebytes + padding; m_ground = new float[m_groundSizeX*m_groundSizeY]; float *bound = new float[m_groundSizeX*m_groundSizeY]; for (int y=0; y 11.1f/255.0f) bound[y*m_groundSizeX+x] = 1.0f; else bound[y*m_groundSizeX+x] = 0.0f; } delete[](Buffer); // boundary texture distance transform // init helper distance map (pMap) StringCchPrintf(wcInfo, 512, L"Computing boundary distance transform.."); OutputDebugString(wcInfo); int *pMap = new int[m_groundSizeX*m_groundSizeY]; #pragma omp parallel for for (int y = 0; y < m_groundSizeY; y++) for (int x = 0; x < m_groundSizeX; x++) { // if we are at the boundary, intialize the distance function with 0, otherwise with maximum value if ((bound[y*m_groundSizeX + x] > 0.5f) && ((bound[max(0, min(m_groundSizeY - 1, y + 1))*m_groundSizeX + max(0, min(m_groundSizeX - 1, x + 0))] <= 0.5f) || (bound[max(0, min(m_groundSizeY - 1, y + 0))*m_groundSizeX + max(0, min(m_groundSizeX - 1, x + 1))] <= 0.5f) || (bound[max(0, min(m_groundSizeY - 1, y - 1))*m_groundSizeX + max(0, min(m_groundSizeX - 1, x + 0))] <= 0.5f) || (bound[max(0, min(m_groundSizeY - 1, y + 0))*m_groundSizeX + max(0, min(m_groundSizeX - 1, x - 1))] <= 0.5f))) pMap[y*m_groundSizeX + x] = 0; // initialize with maximum x distance else if ((bound[y*m_groundSizeX + x] <= 0.5f) && ((bound[max(0, min(m_groundSizeY - 1, y + 1))*m_groundSizeX + max(0, min(m_groundSizeX - 1, x + 0))] > 0.5f) || (bound[max(0, min(m_groundSizeY - 1, y + 0))*m_groundSizeX + max(0, min(m_groundSizeX - 1, x + 1))] > 0.5f) || (bound[max(0, min(m_groundSizeY - 1, y - 1))*m_groundSizeX + max(0, min(m_groundSizeX - 1, x + 0))] > 0.5f) || (bound[max(0, min(m_groundSizeY - 1, y + 0))*m_groundSizeX + max(0, min(m_groundSizeX - 1, x - 1))] > 0.5f))) pMap[y*m_groundSizeX + x] = 0; // initialize with maximum x distance else pMap[y*m_groundSizeX + x] = m_groundSizeX*m_groundSizeX; // initialize with maximum x distance } m_distMap = new float[m_groundSizeX*m_groundSizeY]; #pragma omp parallel for for (int y=0; y=0; x--) { if (pMap[y*m_groundSizeX+x] == 0) lastBoundX = x; pMap[y*m_groundSizeX+x] = min(pMap[y*m_groundSizeX+x], (lastBoundX-x)*(lastBoundX-x)); } } #pragma omp parallel for for (int x=0; x=0; yd--) { minDist = min(minDist, yd*yd+pMap[(y+yd)*m_groundSizeX+x]); if (minDist < yd*yd) break; } m_distMap[y*m_groundSizeX+x] = (float)(minDist); } delete[](pMap); // m_distMap now contains the _squared_ euklidean distance to closest label boundary, so take the sqroot. And sign the distance #pragma omp parallel for for (int y=0; y 0.5f) m_distMap[y*m_groundSizeX+x] = -m_distMap[y*m_groundSizeX+x]; // negative distance INSIDE a boundary regions m_distMap[y*m_groundSizeX+x] = m_distMap[y*m_groundSizeX+x]*SCENE_EXTENT / m_groundSizeX; } StringCchPrintf(wcInfo, 512, L"done!\n"); OutputDebugString(wcInfo); // derivative (2D normal) of the boundary texture StringCchPrintf( wcInfo, 512, L"Computing boundary derivatives.."); OutputDebugString( wcInfo ); m_bndDeriv = new Vector2f[m_groundSizeX*m_groundSizeY]; #pragma omp parallel for for (int y=0; y m_packetNum) ExpandWavePacketMemory(max(m_usedPackets,m_usedGhosts) + PACKET_BUFFER_DELTA); float speedDummy, kDummy; int firstfree = GetFreePackedID(); m_packet[firstfree].pos1 = Vector2f(pos1x,pos1y); m_packet[firstfree].pOld1 = m_packet[firstfree].pos1; m_packet[firstfree].pos2 = Vector2f(pos2x,pos2y); m_packet[firstfree].pOld2 = m_packet[firstfree].pos2; m_packet[firstfree].dir1 = Vector2f(dir1x,dir1y); m_packet[firstfree].dOld1 = m_packet[firstfree].dir1; m_packet[firstfree].dir2 = Vector2f(dir2x,dir2y); m_packet[firstfree].dOld2 = m_packet[firstfree].dir2; m_packet[firstfree].phase = 0.0; m_packet[firstfree].phOld = 0.0; m_packet[firstfree].E = E; m_packet[firstfree].use3rd = false; m_packet[firstfree].bounced1 = false; m_packet[firstfree].bounced2 = false; m_packet[firstfree].bounced3 = false; m_packet[firstfree].sliding3 = false; // set the wavelength/freq interval m_packet[firstfree].k_L = k_L; float wd = GetWaterDepth(m_packet[firstfree].pos1); m_packet[firstfree].w0_L = sqrt((GRAVITY + k_L*k_L*SIGMA/DENSITY)*k_L*rational_tanh(k_L*wd)); // this take surface tension into account m_packet[firstfree].k_H = k_H; m_packet[firstfree].w0_H = sqrt((GRAVITY + k_H*k_H*SIGMA/DENSITY)*k_H*rational_tanh(k_H*wd)); // this take surface tension into account m_packet[firstfree].d_L = 0.0; m_packet[firstfree].d_H = 0.0; // set the representative wave as average of interval boundaries m_packet[firstfree].k = 0.5f*(m_packet[firstfree].k_L+m_packet[firstfree].k_H); m_packet[firstfree].w0 = sqrt((GRAVITY + m_packet[firstfree].k*m_packet[firstfree].k*SIGMA/DENSITY)*m_packet[firstfree].k*rational_tanh(m_packet[firstfree].k*wd)); // this takes surface tension into account GetWaveParameters(GetWaterDepth(m_packet[firstfree].pos1), m_packet[firstfree].w0, m_packet[firstfree].k, kDummy, m_packet[firstfree].speed1); m_packet[firstfree].sOld1 = m_packet[firstfree].speed1; GetWaveParameters(GetWaterDepth(m_packet[firstfree].pos2), m_packet[firstfree].w0, m_packet[firstfree].k, kDummy, m_packet[firstfree].speed2); m_packet[firstfree].sOld2 = m_packet[firstfree].speed2; m_packet[firstfree].envelope = min(PACKET_ENVELOPE_MAXSIZE, max(PACKET_ENVELOPE_MINSIZE, PACKET_ENVELOPE_SIZE_FACTOR*2.0f*M_PI/m_packet[firstfree].k)); // adjust envelope size to represented wavelength m_packet[firstfree].ampOld = 0.0; float a1 = min(MAX_SPEEDNESS*2.0f*M_PI / m_packet[firstfree].k, GetWaveAmplitude(m_packet[firstfree].envelope*(m_packet[firstfree].pos1 - m_packet[firstfree].pos2).norm(), m_packet[firstfree].E, m_packet[firstfree].k)); m_packet[firstfree].dAmp = 0.5f*(m_packet[firstfree].speed1+m_packet[firstfree].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[firstfree].envelope)*a1; // Test for wave number splitting -> if the packet interval crosses the slowest waves, divide so that each part has a monotonic speed function (assumed for travel spread/error calculation) int i1=firstfree; if ((m_packet[i1].w0_L>PACKET_SLOWAVE_W0) && (m_packet[i1].w0_H 45 degrees void Packets::CreateSpreadingPacket(float xPos, float yPos, float dirx, float diry, float spreadFactor, float crestlength, float lambda_L, float lambda_H, float E) { Vector2f dir = Vector2f(dirx,diry); dir.normalize(); Vector2f wfAlign = 0.5f*crestlength*Vector2f(dir.y(),-dir.x()); Vector2f dirSpread1 = dir - spreadFactor*Vector2f(dir.y(),-dir.x()); Vector2f dirSpread2 = dir + spreadFactor*Vector2f(dir.y(),-dir.x()); CreatePacket( xPos-wfAlign.x(), yPos-wfAlign.y(), xPos+wfAlign.x(), yPos+wfAlign.y(), dirSpread1.x(), dirSpread1.y(), dirSpread2.x(), dirSpread2.y(), 2.0f*M_PI/lambda_L, 2.0f*M_PI/lambda_H, E); } // adds a new circular wave at normalized position x,y with wavelength boundaries lambda_L and lambda_H (in meters) void Packets::CreateCircularWavefront(float xPos, float yPos, float radius, float lambda_L, float lambda_H, float E) { // adapt initial packet crestlength to impact radius and wavelength float dAng = min(24.0f, 360.0f * ((0.5f*lambda_L + 0.5f*lambda_H)*3.0f) / (2.0f*M_PI*radius)); for (float i = 0; i < 360.0f; i += dAng) CreatePacket( xPos + radius*sin(i*M_PI / 180.0f), yPos + radius*cos(i*M_PI / 180.0f), xPos + radius*sin((i + dAng)*M_PI / 180.0f), yPos + radius*cos((i + dAng)*M_PI / 180.0f), sin(i*M_PI / 180.0f), cos(i*M_PI / 180.0f), sin((i + dAng)*M_PI / 180.0), cos((i + dAng)*M_PI / 180.0f), 2.0f*M_PI / lambda_L, 2.0f*M_PI / lambda_H, E); } // update the simulation time void Packets::UpdateTime(float dTime) { if (m_oldTime < 0) // if we are entering the first time, set the current time as time m_oldTime = 0.0f; else m_oldTime = m_time; m_time = m_oldTime + dTime; // time stepping m_elapsedTime = abs(m_time - m_oldTime); } // returns water depth at position p float Packets::GetWaterDepth(Vector2f &p) { float v = 1.0f-GetGroundVal(p); return(MIN_WATER_DEPTH + (MAX_WATER_DEPTH-MIN_WATER_DEPTH)*v*v*v*v); } void Packets::GetWaveParameters(float waterDepth, float w_0, float kIn, float &k_out, float &speed_out) { float k = kIn; float dk = 1.0f; float kOld; int it = 0; while ((dk > 1.0e-04) && (it<6)) { kOld = k; k = w_0/sqrt((GRAVITY/k+k*SIGMA/DENSITY)*rational_tanh(k*waterDepth)); // this includes surface tension / capillary waves dk = abs(k-kOld); it++; } k_out = k; float t = rational_tanh(k*waterDepth); const float c = SIGMA/DENSITY; speed_out = ((c*k*k + GRAVITY)*(t + waterDepth*k*(1.0f-t*t)) + 2.0f*c*k*k*t) / (2.0f*sqrt(k*(c*k*k + GRAVITY)*t)); // this is group speed as dw/dk return; } float Packets::GetPhaseSpeed(float w_0, float kIn) { return( w_0/kIn ); } // area = surface area of the wave packet, E = Energy, k = wavenumber // computing the amplitude from energy flux for a wave packet float Packets::GetWaveAmplitude(float area, float E, float k) { return( sqrt(abs(E)/(abs(area)*0.5f*(DENSITY*GRAVITY+SIGMA*k*k))) ); } // advects a single packet vertex with groupspeed, returns 1 if boundary reflection occured bool Packets::AdvectPacketVertex(float elapsedTime, Vector2f &posIn, Vector2f &dirIn, float w0, float &kIn, float &speedIn, Vector2f &posOut, Vector2f &dirOut, float &speedOut) { bool bounced = false; // intialize the output with the input posOut = posIn; dirOut = dirIn; speedOut = speedIn; // compute new direction and speed based on snells law (depending on water depth) float speed1, k; GetWaveParameters(GetWaterDepth( posIn ), w0, kIn, k, speed1); speedOut = speed1; // the new speed is defined by the speed of this wave at this water depth, this is does not necessarily respect snells law! Vector2f nDir = GetGroundNormal( posIn ); if (abs(nDir.x())+abs(nDir.y()) > 0.1f) // if there is a change in water depth here, indicated by a non-zero ground normal { Vector2f pNext = posIn + elapsedTime*speed1*dirIn; float speed2; GetWaveParameters(GetWaterDepth(pNext), w0, kIn, k, speed2); float cos1 = nDir.dot(-dirIn); float cos2 = sqrt( max(0.0f, 1.0f - (speed2*speed2)/(speed1*speed1)*(1.0f - cos1*cos1) )); Vector2f nRefrac; if (cos1 <= 0.0f) nRefrac = speed2/speed1*dirIn + (speed2/speed1*cos1 + cos2)*nDir; else nRefrac = speed2/speed1*dirIn + (speed2/speed1*cos1 - cos2)*nDir; if (nRefrac.norm() > 0.000001f) dirOut = nRefrac.normalized(); } posOut = posIn + elapsedTime*speed1*dirOut; // advect wave vertex position // if we ran into a boundary -> step back and bounce off if (GetBoundaryDist(posOut)<0.0f) { Vector2f nor = GetBoundaryNormal(posOut); float a = nor.dot(dirOut); if (a <= -0.08f) // a wave reflects if it travels with >4.5 degrees towards a surface. Otherwise, it gets diffracted { bounced = true; // step back until we are outside the boundary Vector2f pD = posIn; Vector2f vD = elapsedTime*speedIn*dirOut; for (int j = 0; j < 16; j++) { Vector2f pDD = pD + vD; if (GetBoundaryDist(pDD) > 0.0f) pD = pDD; vD = 0.5f*vD; } Vector2f wayVec = pD - posIn; float lGone = wayVec.norm(); posOut = pD; // compute the traveling direction after the bounce dirOut = -dirOut; Vector2f nor2 = GetBoundaryNormal(posOut); float a2 = nor2.dot(dirOut); Vector2f bFrac = a2*nor2 - dirOut; Vector2f d0 = dirOut + 2.0f*bFrac; dirOut = d0.normalized(); posOut += (elapsedTime*speedOut - lGone)*dirOut; } } // if we got trapped in a boundary (again), just project onto the nearest surface (this approximates multiple bounces) if (GetBoundaryDist(posOut) < 0.0) for (int i2=0; i2<16; i2++) posOut += -0.5f*GetBoundaryDist(posOut)*GetBoundaryNormal(posOut); return(bounced); } // updates the wavefield using the movin wavefronts and generated an output image from the wavefield void Packets::AdvectWavePackets(float dTime) { UpdateTime(dTime); if (m_elapsedTime <= 0.0) // if there is no time advancement, do not update anything.. return; // compute the new packet vertex positions, directions and speeds based on snells law #pragma omp parallel for for (int uP=0; uP find new "has to bounce" point if no other vertex bounced { float s = 0.0f; float sD = 0.5f; Vector2f posOld = m_packet[i1].pOld1; Vector2f dirOld = m_packet[i1].dOld1; float speedOld = m_packet[i1].sOld1; Vector2f pos = m_packet[i1].pos1; Vector2f dir = m_packet[i1].dir1; float speed = m_packet[i1].speed1; float wN = m_packet[i1].k; float w0 = m_packet[i1].w0; for (int j=0; j<16; j++) { Vector2f p = (1.0f-(s+sD))*m_packet[i1].pOld1 + (s+sD)*m_packet[i1].pOld3; Vector2f d = (1.0f-(s+sD))*m_packet[i1].dOld1 + (s+sD)*m_packet[i1].dOld3; float sp = (1.0f-(s+sD))*m_packet[i1].sOld1 + (s+sD)*m_packet[i1].sOld3; Vector2f posD, dirD; float speedD; if (!AdvectPacketVertex(m_elapsedTime, p, d, w0, wN, sp, posD, dirD, speedD)) { s += sD; posOld = p; dirOld = d; speedOld = sp; pos = posD; dir = dirD; speed = speedD; } sD = 0.5f*sD; } m_packet[i1].pOld3 = posOld; m_packet[i1].dOld3 = dirOld.normalized(); m_packet[i1].sOld3 = speedOld; m_packet[i1].pos3 = pos; m_packet[i1].dir3 = dir; m_packet[i1].speed3 = speed; } } // first contact to a boundary -> sent a ghost packet, make packet invisible for now, add 3rd vertex if (m_usedGhosts + m_usedPackets > m_packetNum) ExpandWavePacketMemory(m_usedGhosts + m_usedPackets + PACKET_BUFFER_DELTA); #pragma omp parallel for for (int uP = m_usedPackets-1; uP>=0; uP--) if ((!m_packet[m_usedPacket[uP]].use3rd) && (m_packet[m_usedPacket[uP]].bounced1 || m_packet[m_usedPacket[uP]].bounced2)) { int i1 = m_usedPacket[uP]; int firstghost = GetFreeGhostID(); m_ghostPacket[firstghost].pos = 0.5f*(m_packet[i1].pOld1+m_packet[i1].pOld2); m_ghostPacket[firstghost].dir = (m_packet[i1].dOld1+m_packet[i1].dOld2).normalized(); // the new position is wrong after the reflection, so use the old direction instead m_ghostPacket[firstghost].speed = 0.5f*(m_packet[i1].sOld1+m_packet[i1].sOld2); m_ghostPacket[firstghost].envelope = m_packet[i1].envelope; m_ghostPacket[firstghost].ampOld = m_packet[i1].ampOld; m_ghostPacket[firstghost].dAmp = m_ghostPacket[firstghost].ampOld* m_ghostPacket[firstghost].speed*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_ghostPacket[firstghost].envelope); m_ghostPacket[firstghost].k = m_packet[i1].k; m_ghostPacket[firstghost].phase = m_packet[i1].phOld; m_ghostPacket[firstghost].dPhase = m_packet[i1].phase-m_packet[i1].phOld; m_ghostPacket[firstghost].bending = GetIntersectionDistance(m_ghostPacket[firstghost].pos, m_ghostPacket[firstghost].dir, m_packet[i1].pOld1, m_packet[i1].dOld1); // hide this packet from display m_packet[i1].ampOld = 0.0; m_packet[i1].dAmp = 0.0; // emit all (higher-)frequency waves after a bounce if ((PACKET_BOUNCE_FREQSPLIT) && (m_packet[i1].k_L < PACKET_BOUNCE_FREQSPLIT_K)) // split the frequency range if smallest wave is > 20cm { m_packet[i1].k_L = PACKET_BOUNCE_FREQSPLIT_K; m_packet[i1].w0_L = sqrt(GRAVITY/m_packet[i1].k_L)*m_packet[i1].k_L; // initial guess for angular frequency m_packet[i1].w0 = 0.5f*(m_packet[i1].w0_L+m_packet[i1].w0_H); // distribute the error according to current speed difference float dummySpeed; Vector2f pos = 0.5f*(m_packet[i1].pos1+m_packet[i1].pos2); float wd = GetWaterDepth(pos); GetWaveParameters(wd, m_packet[i1].w0_L, m_packet[i1].k_L, m_packet[i1].k_L, dummySpeed); GetWaveParameters(wd, m_packet[i1].w0_H, m_packet[i1].k_H, m_packet[i1].k_H, dummySpeed); GetWaveParameters(wd, m_packet[i1].w0, 0.5f*(m_packet[i1].k_L+m_packet[i1].k_H), m_packet[i1].k, dummySpeed); m_packet[i1].d_L = 0.0; m_packet[i1].d_H = 0.0; // reset the internally tracked error m_packet[i1].envelope = min(PACKET_ENVELOPE_MAXSIZE, max(PACKET_ENVELOPE_MINSIZE, PACKET_ENVELOPE_SIZE_FACTOR*2.0f*M_PI/m_packet[i1].k)); } //if both vertices bounced, the reflected wave needs to smoothly reappear if (m_packet[i1].bounced1==m_packet[i1].bounced2) { m_packet[i1].ampOld = 0.0; m_packet[i1].dAmp = 0.5f*(m_packet[i1].speed1+m_packet[i1].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[i1].envelope)*GetWaveAmplitude( m_packet[i1].envelope*(m_packet[i1].pos1-m_packet[i1].pos2).norm(), m_packet[i1].E, m_packet[i1].k); } if (m_packet[i1].bounced1 != m_packet[i1].bounced2) // only one vertex bounced -> insert 3rd "wait for bounce" vertex and reorder such that 1st is waiting for bounce { if (m_packet[i1].bounced1) // if the first bounced an the second did not -> exchange the two points, as we assume that the second bounced already and the 3rd will be "ahead" of the first.. { WAVE_PACKET *seg = &m_packet[i1]; // use the 3rd vertex as copy element seg->pos3 = seg->pos2; seg->pos2 = seg->pos1; seg->pos1 = seg->pos3; seg->pOld3 = seg->pOld2; seg->pOld2 = seg->pOld1; seg->pOld1 = seg->pOld3; seg->dir3 = seg->dir2; seg->dir2 = seg->dir1; seg->dir1 = seg->dir3; seg->dOld3 = seg->dOld2; seg->dOld2 = seg->dOld1; seg->dOld1 = seg->dOld3; seg->speed3 = seg->speed2; seg->speed2 = seg->speed1; seg->speed1 = seg->speed3; seg->sOld3 = seg->sOld2; seg->sOld2 = seg->sOld1; seg->sOld1 = seg->sOld3; seg->bounced3 = seg->bounced2; seg->bounced2 = seg->bounced1; seg->bounced1 = seg->bounced3; } float s = 0.0; float sD = 0.5f; Vector2f posOld = m_packet[i1].pOld1; Vector2f dirOld = m_packet[i1].dOld1; float speedOld = m_packet[i1].sOld1; Vector2f pos = m_packet[i1].pos1; Vector2f dir = m_packet[i1].dir1; float speed = m_packet[i1].speed1; float wN = m_packet[i1].k; float w0 = m_packet[i1].w0; for (int j=0; j<16; j++) // find the last point before the boundary that does not bounce in this timestep, it becomes the 3rd point { Vector2f p = (1.0f-(s+sD))*m_packet[i1].pOld1 + (s+sD)*m_packet[i1].pOld2; Vector2f d = (1.0f-(s+sD))*m_packet[i1].dOld1 + (s+sD)*m_packet[i1].dOld2; float sp = (1.0f-(s+sD))*m_packet[i1].sOld1 + (s+sD)*m_packet[i1].sOld2; Vector2f posD, dirD; float speedD; if (!AdvectPacketVertex(m_elapsedTime, p, d, w0, wN, sp, posD, dirD, speedD)) { s += sD; posOld = p; dirOld = d; speedOld = sp; pos = posD; dir = dirD; speed = speedD; } sD = 0.5f*sD; } // the new 3rd vertex has "has to bounce" state (not sliding yet) m_packet[i1].pOld3 = posOld; m_packet[i1].dOld3 = dirOld.normalized(); m_packet[i1].sOld3 = speedOld; m_packet[i1].pos3 = pos; m_packet[i1].dir3 = dir; m_packet[i1].speed3 = speed; } } // define new state based on current state and bouncings #pragma omp parallel for for (int uP = 0; uP case "intiate new 3rd vertex" { m_packet[i1].use3rd = true; m_packet[i1].bounced3 = false; m_packet[i1].sliding3 = false; } } else // 3rd vertex already present { if (!m_packet[i1].sliding3) // 3rd point was in "waiting for bounce" state { if (!m_packet[i1].bounced3) // case: 3rd "has to bounce" vertex did not bounce -> make it sliding in any case m_packet[i1].sliding3 = true; else if ((m_packet[i1].bounced1) || (m_packet[i1].bounced2)) // case: 3rd "has to bounce" and one other point bounced as well -> release 3rd vertex m_packet[i1].use3rd = false; } else // 3rd point was already in "sliding" state { if (m_packet[i1].bounced3) // if sliding 3rd point bounced, release it m_packet[i1].use3rd = false; } // if we released this wave from a boundary (3rd vertex released) -> blend it smoothly in again if (!m_packet[i1].use3rd) { m_packet[i1].ampOld = 0.0; m_packet[i1].dAmp = 0.5f*(m_packet[i1].speed1+m_packet[i1].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[i1].envelope)*GetWaveAmplitude( m_packet[i1].envelope*(m_packet[i1].pos1-m_packet[i1].pos2).norm(), m_packet[i1].E, m_packet[i1].k); } } } // wavenumber interval subdivision if travel distance between fastest and slowest wave packets differ more than PACKET_SPLIT_DISPERSION x envelope size if ( max(m_usedGhosts + m_usedPackets, 2*m_usedPackets) > m_packetNum) ExpandWavePacketMemory(max(m_usedGhosts + m_usedPackets, 2 * m_usedPackets) + PACKET_BUFFER_DELTA); #pragma omp parallel for for (int uP = m_usedPackets-1; uP>=0; uP--) if (!m_packet[m_usedPacket[uP]].use3rd) { int i1 = m_usedPacket[uP]; float speedDummy,kDummy; Vector2f pos = 0.5f*(m_packet[i1].pos1+m_packet[i1].pos2); float wd = GetWaterDepth(pos); GetWaveParameters(wd, m_packet[i1].w0, m_packet[i1].k, kDummy, speedDummy); float dist_Ref = m_elapsedTime*speedDummy; GetWaveParameters(wd, m_packet[i1].w0_L, m_packet[i1].k_L, kDummy, speedDummy); m_packet[i1].k_L = kDummy; m_packet[i1].d_L += fabs(m_elapsedTime*speedDummy-dist_Ref); // taking the abs augments any errors caused by waterdepth independent slowest wave assumption.. GetWaveParameters(wd, m_packet[i1].w0_H, m_packet[i1].k_H, kDummy, speedDummy); m_packet[i1].k_H = kDummy; m_packet[i1].d_H += fabs(m_elapsedTime*speedDummy-dist_Ref); if (m_packet[i1].d_L+m_packet[i1].d_H > PACKET_SPLIT_DISPERSION*m_packet[i1].envelope) // if fastest/slowest waves in this packet diverged too much -> subdivide { // first create a ghost for the old packet int firstghost = GetFreeGhostID(); m_ghostPacket[firstghost].pos = 0.5f*(m_packet[i1].pOld1+m_packet[i1].pOld2); m_ghostPacket[firstghost].dir = (0.5f*(m_packet[i1].pos1+m_packet[i1].pos2)-0.5f*(m_packet[i1].pOld1+m_packet[i1].pOld2)).normalized(); m_ghostPacket[firstghost].speed = 0.5f*(m_packet[i1].sOld1+m_packet[i1].sOld2); m_ghostPacket[firstghost].envelope = m_packet[i1].envelope; m_ghostPacket[firstghost].ampOld = m_packet[i1].ampOld; m_ghostPacket[firstghost].dAmp = m_ghostPacket[firstghost].ampOld* m_ghostPacket[firstghost].speed*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_ghostPacket[firstghost].envelope); m_ghostPacket[firstghost].k = m_packet[i1].k; m_ghostPacket[firstghost].phase = m_packet[i1].phOld; m_ghostPacket[firstghost].dPhase = m_packet[i1].phase-m_packet[i1].phOld; m_ghostPacket[firstghost].bending = GetIntersectionDistance(m_ghostPacket[firstghost].pos, m_ghostPacket[firstghost].dir, m_packet[i1].pOld1, m_packet[i1].dOld1); // create new packet and copy ALL parameters int firstfree = GetFreePackedID(); m_packet[firstfree] = m_packet[i1]; // split the frequency range m_packet[firstfree].k_H = m_packet[i1].k; m_packet[firstfree].w0_H = m_packet[i1].w0; m_packet[firstfree].w0 = 0.5f*(m_packet[firstfree].w0_L+m_packet[firstfree].w0_H); // distribute the error according to current speed difference float speed_L,speed_M,speed_H; GetWaveParameters( wd, m_packet[firstfree].w0_L, m_packet[firstfree].k_L, m_packet[firstfree].k_L, speed_L); GetWaveParameters( wd, m_packet[firstfree].w0_H, m_packet[firstfree].k_H, m_packet[firstfree].k_H, speed_H); GetWaveParameters( wd, m_packet[firstfree].w0, 0.5f*(m_packet[firstfree].k_L+m_packet[firstfree].k_H), m_packet[firstfree].k, speed_M); float dSL = abs(abs(speed_L)-abs(speed_M)); float dSH = abs(abs(speed_H)-abs(speed_M)); float d_All = m_packet[i1].d_L; m_packet[firstfree].d_L = dSL*d_All / (dSH + dSL); m_packet[firstfree].d_H = d_All - m_packet[firstfree].d_L; m_packet[firstfree].envelope = min(PACKET_ENVELOPE_MAXSIZE, max(PACKET_ENVELOPE_MINSIZE, PACKET_ENVELOPE_SIZE_FACTOR*2.0f*M_PI/m_packet[firstfree].k)); // set the new upper freq. boundary and representative freq. m_packet[i1].k_L = m_packet[i1].k; m_packet[i1].w0_L = m_packet[i1].w0; m_packet[i1].w0 = 0.5f*(m_packet[i1].w0_L+m_packet[i1].w0_H); // distribute the error according to current speed difference GetWaveParameters( wd, m_packet[i1].w0_L, m_packet[i1].k_L, m_packet[i1].k_L, speed_L); GetWaveParameters( wd, m_packet[i1].w0_H, m_packet[i1].k_H, m_packet[i1].k_H, speed_H); GetWaveParameters( wd, m_packet[i1].w0, 0.5f*(m_packet[i1].k_L+m_packet[i1].k_H), m_packet[i1].k, speed_M); dSL = abs(abs(speed_L)-abs(speed_M)); dSH = abs(abs(speed_H)-abs(speed_M)); d_All = m_packet[i1].d_H; m_packet[i1].d_L = dSL*d_All / (dSH + dSL); m_packet[i1].d_H = d_All - m_packet[i1].d_L; m_packet[i1].envelope = min(PACKET_ENVELOPE_MAXSIZE, max(PACKET_ENVELOPE_MINSIZE, PACKET_ENVELOPE_SIZE_FACTOR*2.0f*M_PI/m_packet[i1].k)); // distribute the energy such that both max. wave gradients are equal -> both get the same wave shape m_packet[firstfree].E = abs(m_packet[i1].E)/(1.0f + (m_packet[i1].envelope*m_packet[firstfree].k*m_packet[firstfree].k*(DENSITY*GRAVITY+SIGMA*m_packet[i1].k*m_packet[i1].k))/(m_packet[firstfree].envelope*m_packet[i1].k*m_packet[i1].k*(DENSITY*GRAVITY+SIGMA*m_packet[firstfree].k*m_packet[firstfree].k))); m_packet[i1].E = abs(m_packet[i1].E)-m_packet[firstfree].E; // smoothly ramp the new waves m_packet[i1].phase=0; m_packet[i1].ampOld = 0.0f; m_packet[i1].dAmp = 0.5f*(m_packet[i1].speed1+m_packet[i1].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[i1].envelope)*GetWaveAmplitude( m_packet[i1].envelope*(m_packet[i1].pos1-m_packet[i1].pos2).norm(), m_packet[i1].E, m_packet[i1].k); m_packet[firstfree].phase = 0.0f; m_packet[firstfree].ampOld = 0.0f; m_packet[firstfree].dAmp = 0.5f*(m_packet[firstfree].speed1+m_packet[firstfree].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[firstfree].envelope)*GetWaveAmplitude( m_packet[firstfree].envelope*(m_packet[firstfree].pos1-m_packet[firstfree].pos2).norm(), m_packet[firstfree].E, m_packet[firstfree].k); } } // crest-refinement of packets of regular packet (not at any boundary, i.e. having no 3rd vertex) if (max(m_usedGhosts + m_usedPackets, 2 * m_usedPackets) > m_packetNum) ExpandWavePacketMemory(max(m_usedGhosts + m_usedPackets, 2 * m_usedPackets) + PACKET_BUFFER_DELTA); #pragma omp parallel for for (int uP = m_usedPackets-1; uP>=0; uP--) if (!m_packet[m_usedPacket[uP]].use3rd) { int i1 = m_usedPacket[uP]; float sDiff = (m_packet[i1].pos2-m_packet[i1].pos1).norm(); float aDiff = m_packet[i1].dir1.dot(m_packet[i1].dir2); if ((sDiff > m_packet[i1].envelope) || (aDiff <= PACKET_SPLIT_ANGLE)) // if the two vertices move towards each other, do not subdivide { int firstghost = GetFreeGhostID(); m_ghostPacket[firstghost].pos = 0.5f*(m_packet[i1].pOld1+m_packet[i1].pOld2); m_ghostPacket[firstghost].dir = (m_packet[i1].dOld1+m_packet[i1].dOld2).normalized(); m_ghostPacket[firstghost].speed = 0.5f*(m_packet[i1].sOld1+m_packet[i1].sOld2); m_ghostPacket[firstghost].envelope = m_packet[i1].envelope; m_ghostPacket[firstghost].ampOld = m_packet[i1].ampOld; m_ghostPacket[firstghost].dAmp = m_ghostPacket[firstghost].ampOld* m_ghostPacket[firstghost].speed*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_ghostPacket[firstghost].envelope); m_ghostPacket[firstghost].k = m_packet[i1].k; m_ghostPacket[firstghost].phase = m_packet[i1].phOld; m_ghostPacket[firstghost].dPhase = m_packet[i1].phase-m_packet[i1].phOld; m_ghostPacket[firstghost].bending = GetIntersectionDistance(m_ghostPacket[firstghost].pos, m_ghostPacket[firstghost].dir, m_packet[i1].pOld1, m_packet[i1].dOld1); // create new vertex between existing packet vertices int firstfree = GetFreePackedID(); m_packet[firstfree] = m_packet[i1]; // first copy all data m_packet[firstfree].pOld1 = 0.5f*(m_packet[i1].pOld1 + m_packet[i1].pOld2); m_packet[firstfree].dOld1 = (m_packet[i1].dOld1 + m_packet[i1].dOld2).normalized(); m_packet[firstfree].sOld1 = 0.5f*(m_packet[i1].sOld1 + m_packet[i1].sOld2); m_packet[firstfree].pos1 = 0.5f*(m_packet[i1].pos1 + m_packet[i1].pos2); m_packet[firstfree].dir1 = (m_packet[i1].dir1 + m_packet[i1].dir2).normalized(); m_packet[firstfree].speed1 = 0.5f*(m_packet[i1].speed1 + m_packet[i1].speed2); m_packet[firstfree].E = 0.5f*m_packet[i1].E; m_packet[firstfree].ampOld = 0.0; m_packet[firstfree].dAmp = 0.5f*(m_packet[firstfree].speed1+m_packet[firstfree].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[firstfree].envelope)*GetWaveAmplitude( m_packet[firstfree].envelope*(m_packet[firstfree].pos1-m_packet[firstfree].pos2).norm(), m_packet[firstfree].E, m_packet[firstfree].k); // use the same new middle vertex here m_packet[i1].pOld2 = m_packet[firstfree].pOld1; m_packet[i1].dOld2 = m_packet[firstfree].dOld1; m_packet[i1].sOld2 = m_packet[firstfree].sOld1; m_packet[i1].pos2 = m_packet[firstfree].pos1; m_packet[i1].dir2 = m_packet[firstfree].dir1; m_packet[i1].speed2 = m_packet[firstfree].speed1; m_packet[i1].E *= 0.5f; m_packet[i1].ampOld = 0.0; m_packet[i1].dAmp = 0.5f*(m_packet[i1].speed1+m_packet[i1].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[i1].envelope)*GetWaveAmplitude( m_packet[i1].envelope*(m_packet[i1].pos1-m_packet[i1].pos2).norm(), m_packet[i1].E, m_packet[i1].k); } } // crest-refinement of packets with a sliding 3rd vertex if ( 3 * m_usedPackets > m_packetNum) ExpandWavePacketMemory(3 * m_usedPackets + PACKET_BUFFER_DELTA); #pragma omp parallel for for (int uP = m_usedPackets-1; uP>=0; uP--) if ((m_packet[m_usedPacket[uP]].use3rd) && (m_packet[m_usedPacket[uP]].sliding3)) { int i1 = m_usedPacket[uP]; float sDiff1 = (m_packet[i1].pos1-m_packet[i1].pos3).norm(); float aDiff1 = m_packet[i1].dir1.dot(m_packet[i1].dir3); if ((sDiff1 >= m_packet[i1].envelope))// || (aDiff1 <= PACKET_SPLIT_ANGLE)) // angle criterion is removed here because this would prevent diffraction { int firstfree = GetFreePackedID(); // first vertex becomes first in new wave packet, third one becomes second m_packet[firstfree] = m_packet[i1]; // first copy all data m_packet[firstfree].pOld2 = 0.5f*(m_packet[i1].pOld1 + m_packet[i1].pOld3); m_packet[firstfree].dOld2 = (m_packet[i1].dOld1 + m_packet[i1].dOld3).normalized(); m_packet[firstfree].sOld2 = 0.5f*(m_packet[i1].sOld1 + m_packet[i1].sOld3); m_packet[firstfree].pos2 = 0.5f*(m_packet[i1].pos1 + m_packet[i1].pos3); m_packet[firstfree].dir2 = (m_packet[i1].dir1 + m_packet[i1].dir3).normalized(); m_packet[firstfree].speed2 = 0.5f*(m_packet[i1].speed1 + m_packet[i1].speed3); m_packet[firstfree].ampOld = 0.0; m_packet[firstfree].dAmp = 0.5f*(m_packet[i1].speed1+m_packet[i1].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[i1].envelope)*GetWaveAmplitude( m_packet[i1].envelope*(m_packet[i1].pos1-m_packet[i1].pos2).norm(), m_packet[i1].E, m_packet[i1].k); m_packet[firstfree].bounced1 = false; m_packet[firstfree].bounced2 = false; m_packet[firstfree].bounced3 = false; m_packet[firstfree].use3rd = false; m_packet[firstfree].sliding3 = false; // use the same new middle vertex here m_packet[i1].pOld1 = m_packet[firstfree].pOld2; m_packet[i1].dOld1 = m_packet[firstfree].dOld2; m_packet[i1].sOld1 = m_packet[firstfree].sOld2; m_packet[i1].pos1 = m_packet[firstfree].pos2; m_packet[i1].dir1 = m_packet[firstfree].dir2; m_packet[i1].speed1 = m_packet[firstfree].speed2; // distribute the energy according to length of the two new packets float s = (m_packet[firstfree].pos1-m_packet[firstfree].pos2).norm()/((m_packet[firstfree].pos1-m_packet[firstfree].pos2).norm() + (m_packet[i1].pos1-m_packet[i1].pos3).norm() + (m_packet[i1].pos2-m_packet[i1].pos3).norm()); m_packet[firstfree].E = s*m_packet[i1].E; m_packet[i1].E *= (1.0f-s); } // same procedure for the other end of sliding vertex.. sDiff1 = (m_packet[i1].pos2-m_packet[i1].pos3).norm(); aDiff1 = m_packet[i1].dir2.dot(m_packet[i1].dir3); if ((sDiff1 >= m_packet[i1].envelope)/* || (aDiff1 <= PACKET_SPLIT_ANGLE)*/) // angle criterion is removed here because this would prevent diffraction { int firstfree = GetFreePackedID(); // first vertex becomes first in new packet, third one becomes second m_packet[firstfree] = m_packet[i1]; // first copy all data m_packet[firstfree].pOld1 = 0.5f*(m_packet[i1].pOld2 + m_packet[i1].pOld3); m_packet[firstfree].dOld1 = (m_packet[i1].dOld2 + m_packet[i1].dOld3).normalized(); m_packet[firstfree].sOld1 = 0.5f*(m_packet[i1].sOld2 + m_packet[i1].sOld3); m_packet[firstfree].pos1 = 0.5f*(m_packet[i1].pos2 + m_packet[i1].pos3); m_packet[firstfree].dir1 = (m_packet[i1].dir2 + m_packet[i1].dir3).normalized(); m_packet[firstfree].speed1 = 0.5f*(m_packet[i1].speed2 + m_packet[i1].speed3); m_packet[firstfree].ampOld = 0.0; m_packet[firstfree].dAmp = 0.5f*(m_packet[firstfree].speed1+m_packet[firstfree].speed2)*m_elapsedTime/(PACKET_BLEND_TRAVEL_FACTOR*m_packet[firstfree].envelope)*GetWaveAmplitude( m_packet[firstfree].envelope*(m_packet[firstfree].pos1-m_packet[firstfree].pos2).norm(), m_packet[firstfree].E, m_packet[firstfree].k); m_packet[firstfree].bounced1 = false; m_packet[firstfree].bounced2 = false; m_packet[firstfree].bounced3 = false; m_packet[firstfree].use3rd = false; m_packet[firstfree].sliding3 = false; // use the same new middle vertex m_packet[i1].pOld2 = m_packet[firstfree].pOld1; m_packet[i1].dOld2 = m_packet[firstfree].dOld1; m_packet[i1].sOld2 = m_packet[firstfree].sOld1; m_packet[i1].pos2 = m_packet[firstfree].pos1; m_packet[i1].dir2 = m_packet[firstfree].dir1; m_packet[i1].speed2 = m_packet[firstfree].speed1; // distribute the energy according to length of the two new packets float s = (m_packet[firstfree].pos1-m_packet[firstfree].pos2).norm()/((m_packet[firstfree].pos1-m_packet[firstfree].pos2).norm() + (m_packet[i1].pos1-m_packet[i1].pos3).norm() + (m_packet[i1].pos2-m_packet[i1].pos3).norm()); m_packet[firstfree].E = s*m_packet[i1].E; m_packet[i1].E *= (1.0f-s); } } // delete packets traveling outside the scene #pragma omp parallel for for (int uP = 0; uP < m_usedPackets; uP++) { int i1 = m_usedPacket[uP]; m_packet[i1].toDelete = false; if (!m_packet[i1].use3rd) { Vector2f dir = m_packet[i1].pos1 - m_packet[i1].pOld1; Vector2f dir2 = m_packet[i1].pos2 - m_packet[i1].pOld2; if ((((m_packet[i1].pos1.x() < -0.5f*SCENE_EXTENT) && (dir.x() < 0.0)) || ((m_packet[i1].pos1.x() > +0.5f*SCENE_EXTENT) && (dir.x() > 0.0)) || ((m_packet[i1].pos1.y() < -0.5f*SCENE_EXTENT) && (dir.y() < 0.0)) || ((m_packet[i1].pos1.y() > +0.5f*SCENE_EXTENT) && (dir.y() > 0.0))) && (((m_packet[i1].pos2.x() < -0.5f*SCENE_EXTENT) && (dir2.x() < 0.0)) || ((m_packet[i1].pos2.x() > +0.5f*SCENE_EXTENT) && (dir2.x() > 0.0)) || ((m_packet[i1].pos2.y() < -0.5f*SCENE_EXTENT) && (dir2.y() < 0.0)) || ((m_packet[i1].pos2.y() > +0.5f*SCENE_EXTENT) && (dir2.y() > 0.0)))) m_packet[i1].toDelete = true; } } // damping, insignificant packet removal (if too low amplitude), reduce energy of steep waves with too high gradient m_softDampFactor = 1.0f + 100.0f*pow(max(0.0f, (float)(m_usedPackets)/(float)(m_packetBudget) - 1.0f), 2.0f); #pragma omp parallel for for (int uP = 0; uP < m_usedPackets; uP++) if ((!m_packet[m_usedPacket[uP]].use3rd) && (!m_packet[m_usedPacket[uP]].toDelete)) { int i1 = m_usedPacket[uP]; float dampViscosity = -2.0f*m_packet[i1].k*m_packet[i1].k*KINEMATIC_VISCOSITY; float dampJunkfilm = -0.5f*m_packet[i1].k*sqrt(0.5f*KINEMATIC_VISCOSITY*m_packet[i1].w0); m_packet[i1].E *= exp((dampViscosity + dampJunkfilm)*m_elapsedTime*m_softDampFactor); // wavelength-dependent damping // amplitude computation: lower if too steep, delete if too low float area = m_packet[i1].envelope*(m_packet[i1].pos2 - m_packet[i1].pos1).norm(); float a1 = GetWaveAmplitude( area, m_packet[i1].E, m_packet[i1].k); if (a1*m_packet[i1].k < PACKET_KILL_AMPLITUDE_DERIV) m_packet[i1].toDelete = true; else { // get the biggest wave as reference for energy reduction (conservative but important to not remove too much energy in case of large k intervals) float a_L = GetWaveAmplitude(area, m_packet[i1].E, m_packet[i1].k_L); float a_H = GetWaveAmplitude(area, m_packet[i1].E, m_packet[i1].k_H); float k; if (a_L*m_packet[i1].k_L < a_H*m_packet[i1].k_H) // take the smallest wave steepness (=amplitude derivative) { a1 = a_L; k = m_packet[i1].k_L; } else { a1 = a_H; k = m_packet[i1].k_H; } if (a1 > MAX_SPEEDNESS*2.0f*M_PI / k) { a1 = MAX_SPEEDNESS*2.0f*M_PI / k; m_packet[i1].E = a1*a1*(area*0.5f*(DENSITY*GRAVITY + SIGMA*k*k)); } } m_packet[i1].ampOld = min(a1, m_packet[i1].ampOld + m_packet[i1].dAmp); // smoothly increase amplitude from last timestep // update variables needed for packet display Vector2f posMidNew = 0.5f*(m_packet[i1].pos1 + m_packet[i1].pos2); Vector2f posMidOld = 0.5f*(m_packet[i1].pOld1 + m_packet[i1].pOld2); Vector2f dirN = (posMidNew - posMidOld).normalized(); // vector in traveling direction m_packet[i1].midPos = posMidNew; m_packet[i1].travelDir = dirN; m_packet[i1].bending = GetIntersectionDistance(posMidNew, dirN, m_packet[i1].pos1, m_packet[i1].dir1); } // delete all packets identified to be deleted (important: NO parallelization here!) for (int uP = 0; uP < m_usedPackets; uP++) if (m_packet[m_usedPacket[uP]].toDelete) DeletePacket(uP); // advect ghost packets #pragma omp parallel for for (int uG = 0; uG < m_usedGhosts; uG++) { int i1 = m_usedGhost[uG]; m_ghostPacket[i1].pos += m_elapsedTime*m_ghostPacket[i1].speed*m_ghostPacket[i1].dir; m_ghostPacket[i1].phase += m_ghostPacket[i1].dPhase; m_ghostPacket[i1].ampOld = max(0.0f, m_ghostPacket[i1].ampOld - m_softDampFactor*m_ghostPacket[i1].dAmp); // decrease amplitude to let this wave disappear (take budget-based softdamping into account) } // delete all ghost packets if they traveled long enough (important: NO parallelization here!) for (int uG = 0; uG < m_usedGhosts; uG++) if (m_ghostPacket[m_usedGhost[uG]].ampOld <= 0.0) DeleteGhost(uG); }