bool ModelClass::CalculateBNT(ID3D11Device* device)
{
if(!m_vertexBuffer)
{
return false;
}
for(int i=0; i < m_vertexCount; i+=3)
{
CalculateTangentBinormal(i, i+1, i+2);
CalculateNormal(i, i+1, i+2);
}
InitializeBuffers(device);
return true;
}
void ModelClass::CalculateModelVectors() {
int faceCount, index;
TempVertexType vertex[3];
XMFLOAT3 tangent, binormal, normal;
faceCount = mVertexCount / 3;
index = 0;
for (int i = 0; i < faceCount; ++i)
{
for (int z = 0; z < 3; ++z)
{
vertex[z].x = mModel[index].x;
vertex[z].y = mModel[index].y;
vertex[z].z = mModel[index].z;
vertex[z].tu = mModel[index].tu;
vertex[z].tv = mModel[index].tv;
vertex[z].nx = mModel[index].nx;
vertex[z].ny = mModel[index].ny;
vertex[z].nz = mModel[index].nz;
++index;
}
CalculateTangentBinormal(vertex[0], vertex[1], vertex[2], tangent, binormal);
CalculateNormal(tangent, binormal, normal);
for (int z = 0; z < 3; ++z)
{
mModel[index - 1 - z].nx = normal.x;
mModel[index - 1 - z].ny = normal.y;
mModel[index - 1 - z].nz = normal.z;
mModel[index - 1 - z].tx = tangent.x;
mModel[index - 1 - z].ty = tangent.y;
mModel[index - 1 - z].tz = tangent.z;
mModel[index - 1 - z].bx = binormal.x;
mModel[index - 1 - z].by = binormal.y;
mModel[index - 1 - z].bz = binormal.z;
}
}
}
void ModelClass::CalculateModelVectors()
{
int faceCount, i, index;
TempVertexType vertex1, vertex2, vertex3;
VectorType tangent, binormal, normal;
faceCount = m_vertexCount / 3;
index = 0;
for (i = 0; i != faceCount; ++i)
{
loadStruct(vertex1, m_Model, index++);
loadStruct(vertex2, m_Model, index++);
loadStruct(vertex3, m_Model, index++);
CalculateTangentBinormal(vertex1, vertex2, vertex3, tangent, binormal);
CalculateNormal(tangent, binormal, normal);
loadModel(m_Model, index, tangent, binormal, normal);
}
}
void SuperEllipsoid::create(int samples, float n1, float n2, const Ogre::Vector3& scale)
{
float phi = 0.0, beta = 0.0;
Ogre::Vector3 p1, p2, p3;
float dB = Ogre::Math::TWO_PI/samples;
float dP = Ogre::Math::TWO_PI/samples;
phi = -Ogre::Math::HALF_PI;
manual_object_->clear();
manual_object_->begin( material_name_, Ogre::RenderOperation::OT_TRIANGLE_LIST );
float scale_x = scale.x / 2.0f;
float scale_y = scale.y / 2.0f;
float scale_z = scale.z / 2.0f;
for(int j=0; j<=samples/2; j++)
{
beta = -Ogre::Math::PI;
for(int i=0; i<=samples; i++)
{
//Triangle #1
manual_object_->position(Sample(phi+dP, beta, n1, n2, scale_x, scale_y, scale_z));
manual_object_->normal(CalculateNormal(phi+dP, beta, n1, n2, scale_x, scale_y, scale_z));
manual_object_->position(Sample(phi, beta, n1, n2, scale_x, scale_y, scale_z));
manual_object_->normal(CalculateNormal(phi, beta, n1, n2, scale_x, scale_y, scale_z));
manual_object_->position(Sample(phi+dP, beta+dB, n1, n2, scale_x, scale_y, scale_z));
manual_object_->normal(CalculateNormal(phi+dP, beta+dB, n1, n2, scale_x, scale_y, scale_z));
//Triangle #2
manual_object_->position(Sample(phi+dP, beta+dB, n1, n2, scale_x, scale_y, scale_z));
manual_object_->normal(CalculateNormal(phi+dP, beta+dB, n1, n2, scale_x, scale_y, scale_z));
manual_object_->position(Sample(phi, beta, n1, n2, scale_x, scale_y, scale_z));
manual_object_->normal(CalculateNormal(phi, beta, n1, n2, scale_x, scale_y, scale_z));
manual_object_->position(Sample(phi, beta+dB, n1, n2, scale_x, scale_y, scale_z));
manual_object_->normal(CalculateNormal(phi, beta+dB, n1, n2, scale_x, scale_y, scale_z));
beta += dB;
}
phi += dP;
}
manual_object_->end();
}
void CalculateBoundaryVertexNormal3D(vector3& nOut, Grid& grid, Vertex* vrt,
TAAPosVRT& aaPos)
{
// The algorithm is a little cumbersome. However, through this setup, we
// make sure that the orientation of the normal indeed points outwards,
// based only on the topology.
// set nOut to 0
VecSet(nOut, 0);
// iterate over associated volumes
std::vector<Volume*> vols;
CollectAssociated(vols, grid, vrt);
FaceDescriptor fd;
for(size_t i_vol = 0; i_vol < vols.size(); ++i_vol){
Volume* v = vols[i_vol];
// check for each side of f whether it is a boundary edge
for(size_t i_side = 0; i_side < v->num_sides(); ++i_side){
if(IsBoundaryFace3D(grid, grid.get_face(v, i_side))){
v->face_desc(i_side, fd);
// make sure that fd contains the given vertex
if(!FaceContains(&fd, vrt))
continue;
// the normal pointing outwards is clearly defined from the
// orientation of the face descriptor
vector3 n;
CalculateNormal(n, &fd, aaPos);
VecAdd(nOut, nOut, n);
}
}
}
VecNormalize(nOut, nOut);
}
glm::dvec2 CollisionCircle::CalculateNormal(double relativePositionX, double relativePositionY)
{
return CalculateNormal(glm::dvec2(relativePositionX, relativePositionY));
}
void Cube::CalculateModelVectors()
{
int faceCount, i, index;
TempVertexType vertex1, vertex2, vertex3;
VectorType tangent, binormal, normal;
// Calculate the number of faces in the model.
faceCount = m_VertexCount / 3;
// Initialize the index to the model data.
index = 0;
// Go through all the faces and calculate the the tangent, binormal, and normal vectors.
for (i=0; i < faceCount; i++)
{
// Get the three vertices for this face from the model.
vertex1.x = pModelVertex[index].x;
vertex1.y = pModelVertex[index].y;
vertex1.z = pModelVertex[index].z;
vertex1.tu = pModelVertex[index].tu;
vertex1.tv = pModelVertex[index].tv;
vertex1.nx = pModelVertex[index].nx;
vertex1.ny = pModelVertex[index].ny;
vertex1.nz = pModelVertex[index].nz;
index++;
vertex2.x = pModelVertex[index].x;
vertex2.y = pModelVertex[index].y;
vertex2.z = pModelVertex[index].z;
vertex2.tu = pModelVertex[index].tu;
vertex2.tv = pModelVertex[index].tv;
vertex2.nx = pModelVertex[index].nx;
vertex2.ny = pModelVertex[index].ny;
vertex2.nz = pModelVertex[index].nz;
index++;
vertex3.x = pModelVertex[index].x;
vertex3.y = pModelVertex[index].y;
vertex3.z = pModelVertex[index].z;
vertex3.tu = pModelVertex[index].tu;
vertex3.tv = pModelVertex[index].tv;
vertex3.nx = pModelVertex[index].nx;
vertex3.ny = pModelVertex[index].ny;
vertex3.nz = pModelVertex[index].nz;
index++;
// Calculate the tangent and binormal of that face.
CalculateTangentBinormal(vertex1, vertex2, vertex3, tangent, binormal);
// Calculate the new normal using the tangent and binormal.
CalculateNormal(tangent, binormal, normal);
// Store the normal, tangent, and binormal for this face back in the model structure.
pModelVertex[index - 1].nx = normal.x;
pModelVertex[index - 1].ny = normal.y;
pModelVertex[index - 1].nz = normal.z;
pModelVertex[index - 1].tx = tangent.x;
pModelVertex[index - 1].ty = tangent.y;
pModelVertex[index - 1].tz = tangent.z;
pModelVertex[index - 1].bx = binormal.x;
pModelVertex[index - 1].by = binormal.y;
pModelVertex[index - 1].bz = binormal.z;
pModelVertex[index - 2].nx = normal.x;
pModelVertex[index - 2].ny = normal.y;
pModelVertex[index - 2].nz = normal.z;
pModelVertex[index - 2].tx = tangent.x;
pModelVertex[index - 2].ty = tangent.y;
pModelVertex[index - 2].tz = tangent.z;
pModelVertex[index - 2].bx = binormal.x;
pModelVertex[index - 2].by = binormal.y;
pModelVertex[index - 2].bz = binormal.z;
pModelVertex[index - 3].nx = normal.x;
pModelVertex[index - 3].ny = normal.y;
pModelVertex[index - 3].nz = normal.z;
pModelVertex[index - 3].tx = tangent.x;
pModelVertex[index - 3].ty = tangent.y;
pModelVertex[index - 3].tz = tangent.z;
pModelVertex[index - 3].bx = binormal.x;
pModelVertex[index - 3].by = binormal.y;
pModelVertex[index - 3].bz = binormal.z;
}
return;
}
//----------------------------------------------------------------------------
void BouncingTetrahedra::Reposition (int t0, int t1, Contact& contact)
{
RigidTetra& tetra0 = *mTetras[t0];
RigidTetra& tetra1 = *mTetras[t1];
// Compute the centroids of the tetrahedra.
Vector3f vertices0[4], vertices1[4];
tetra0.GetVertices(vertices0);
tetra1.GetVertices(vertices1);
Vector3f centroid0 = Vector3f::ZERO;
Vector3f centroid1 = Vector3f::ZERO;
int i;
for (i = 0; i < 4; ++i)
{
centroid0 += vertices0[i];
centroid1 += vertices1[i];
}
centroid0 *= 0.25f;
centroid1 *= 0.25f;
// Randomly perturb the tetrahedra vertices by a small amount. This is
// done to help prevent the LCP solver from getting into cycles and
// degenerate cases.
const float reduction = 0.95f;
float reduceI = reduction*Mathf::IntervalRandom(0.9999f, 1.0001f);
float reduceJ = reduction*Mathf::IntervalRandom(0.9999f, 1.0001f);
for (i = 0; i < 4; ++i)
{
vertices0[i] = centroid0 + (vertices0[i] - centroid0)*reduceI;
vertices1[i] = centroid1 + (vertices1[i] - centroid1)*reduceJ;
}
// Compute the distance between the tetrahedra.
float dist = 1.0f;
int statusCode = 0;
Vector3f closest[2];
LCPPolyDist3(4, vertices0, 4, mFaces, 4, vertices1, 4, mFaces,
statusCode, dist, closest);
++mLCPCount;
// In theory, LCPPolyDist<3> should always find a valid distance, but just
// in case numerical round-off errors cause problems, let us trap it.
assertion(dist >= 0.0f, "LCP polyhedron distance calculator failed.\n");
// Reposition the tetrahedra to the theoretical points of contact.
closest[0] = centroid0 + (closest[0] - centroid0)/reduceI;
closest[1] = centroid1 + (closest[1] - centroid1)/reduceJ;
for (i = 0; i < 4; ++i)
{
vertices0[i] = centroid0 + (vertices0[i] - centroid0)/reduceI;
vertices1[i] = centroid1 + (vertices1[i] - centroid1)/reduceJ;
}
// Numerical round-off errors can cause interpenetration. Move the
// tetrahedra to back out of this situation. The length of diff
// estimates the depth of penetration when dist > 0 was reported.
Vector3f diff = closest[0] - closest[1];
// Apply the separation distance along the line containing the centroids
// of the tetrahedra.
Vector3f diff2 = centroid1 - centroid0;
diff = diff2/diff2.Length()*diff.Length();
// Move each tetrahedron by half of kDiff when the distance was large,
// but move each by twice kDiff when the distance is really small.
float mult = (dist >= mTolerance ? 0.5f : 1.0f);
Vector3f delta = mult*diff;
// Undo the interpenetration.
if (tetra0.Moved && !tetra1.Moved)
{
// Tetra t0 has moved but tetra t1 has not moved.
tetra1.SetPosition(tetra1.GetPosition() + 2.0f*delta);
tetra1.Moved = true;
}
else if (!tetra0.Moved && tetra1.Moved)
{
// Tetra t1 has moved but tetra t0 has not moved.
tetra0.SetPosition(tetra0.GetPosition() - 2.0f*delta);
tetra0.Moved = true;
}
else
{
// Both tetras moved or both tetras did not move.
tetra0.SetPosition(tetra0.GetPosition() - delta);
tetra0.Moved = true;
tetra1.SetPosition(tetra1.GetPosition() + delta);
tetra1.Moved = true;
}
// Test whether the two tetrahedra intersect in a vertex-face
// configuration.
contact.IsVFContact = IsVertex(vertices0, closest[0]);
if (contact.IsVFContact)
{
contact.A = mTetras[t1];
contact.B = mTetras[t0];
CalculateNormal(vertices1, closest[1], contact);
}
else
{
contact.IsVFContact = IsVertex(vertices1, closest[1]);
if (contact.IsVFContact)
{
contact.A = mTetras[t0];
contact.B = mTetras[t1];
CalculateNormal(vertices0, closest[0], contact);
}
}
// Test whether the two tetrahedra intersect in an edge-edge
// configuration.
if (!contact.IsVFContact)
{
contact.A = mTetras[t0];
contact.B = mTetras[t1];
Vector3f otherVertexA = Vector3f::UNIT_X;
Vector3f otherVertexB = Vector3f::ZERO;
contact.EA = ClosestEdge(vertices0, closest[0], otherVertexA);
contact.EB = ClosestEdge(vertices1, closest[1], otherVertexB);
Vector3f normal = contact.EA.UnitCross(contact.EB);
if (normal.Dot(otherVertexA - closest[0]) < 0.0f)
{
contact.N = normal;
}
else
{
contact.N = -normal;
}
}
// Reposition results to correspond to relocaton of tetra.
contact.PA = closest[0] - delta;
contact.PB = closest[1] + delta;
}
void Wall2D::SetTo(const cocos2d::CCPoint &v)
{
m_vB = v;
CalculateNormal();
}
void Wall2D::SetFrom(const cocos2d::CCPoint &v)
{
m_vA = v;
CalculateNormal();
}
// 以插值方式绘制模型,从而生成动画
// 成功返回0,失败返回-1
int CMD2Model::Animate(int startFrame, int endFrame, float percent)
{
// 当前帧的顶点
vector_t* vList;
// 下一帧的顶点
vector_t* nextVList;
// 当前帧顶点的坐标值
float x1, y1, z1;
// 下一帧顶点的坐标值
float x2, y2, z2;
vector_t vertex[3];
if (startFrame > currentFrame)
{
currentFrame = startFrame;
}
if ((startFrame < 0) || (endFrame < 0))
{
return -1;
}
if ((startFrame >= numFrames) || (endFrame >= numFrames))
{
return -1;
}
if (interpol >= 1.0f)
{
interpol = 0.0f;
currentFrame++;
if (currentFrame >= endFrame)
{
currentFrame = startFrame;
}
nextFrame = currentFrame + 1;
if (nextFrame >= endFrame)
{
nextFrame = startFrame;
}
}
vList = &vertexList[numVertices * currentFrame];
nextVList = &vertexList[numVertices * nextFrame];
glBindTexture(GL_TEXTURE_2D, modelTex->texID);
glBegin(GL_TRIANGLES);
for (int i = 0; i < numTriangles; i++)
{
// 获取每一关键帧中三角形的第一个顶点
x1 = vList[triIndex[i].meshIndex[0]].point[0];
y1 = vList[triIndex[i].meshIndex[0]].point[1];
z1 = vList[triIndex[i].meshIndex[0]].point[2];
x2 = nextVList[triIndex[i].meshIndex[0]].point[0];
y2 = nextVList[triIndex[i].meshIndex[0]].point[1];
z2 = nextVList[triIndex[i].meshIndex[0]].point[2];
// 存储三角形第一个顶点的插值
vertex[0].point[0] = x1 + interpol * (x2 - x1);
vertex[0].point[1] = y1 + interpol * (y2 - y1);
vertex[0].point[2] = z1 + interpol * (z2 - z1);
// 获取每一关键帧中三角形的第二个顶点
x1 = vList[triIndex[i].meshIndex[2]].point[0];
y1 = vList[triIndex[i].meshIndex[2]].point[1];
z1 = vList[triIndex[i].meshIndex[2]].point[2];
x2 = nextVList[triIndex[i].meshIndex[2]].point[0];
y2 = nextVList[triIndex[i].meshIndex[2]].point[1];
z2 = nextVList[triIndex[i].meshIndex[2]].point[2];
// 存储三角形第二个顶点的插值
vertex[2].point[0] = x1 + interpol * (x2 - x1);
vertex[2].point[1] = y1 + interpol * (y2 - y1);
vertex[2].point[2] = z1 + interpol * (z2 - z1);
// 获取每一关键帧中三角形的第三个顶点
x1 = vList[triIndex[i].meshIndex[1]].point[0];
y1 = vList[triIndex[i].meshIndex[1]].point[1];
z1 = vList[triIndex[i].meshIndex[1]].point[2];
x2 = nextVList[triIndex[i].meshIndex[1]].point[0];
y2 = nextVList[triIndex[i].meshIndex[1]].point[1];
z2 = nextVList[triIndex[i].meshIndex[1]].point[2];
// 存储三角形第三个顶点的插值
vertex[1].point[0] = x1 + interpol * (x2 - x1);
vertex[1].point[1] = y1 + interpol * (y2 - y1);
vertex[1].point[2] = z1 + interpol * (z2 - z1);
// 计算三角形的法线
CalculateNormal(vertex[0].point,
vertex[2].point, vertex[1].point);
// 绘制正确的纹理三角形
glTexCoord2f(st[triIndex[i].stIndex[0]].s,
st[triIndex[i].stIndex[0]].t);
glVertex3fv(vertex[0].point);
glTexCoord2f(st[triIndex[i].stIndex[2]].s,
st[triIndex[i].stIndex[2]].t);
glVertex3fv(vertex[2].point);
glTexCoord2f(st[triIndex[i].stIndex[1]].s,
st[triIndex[i].stIndex[1]].t);
glVertex3fv(vertex[1].point);
}
glEnd();
interpol += percent;
return 0;
} // End of Animate()
void Decepticon :: DrawLowerLeg()
{
if (anti_aliasing)
{
glEnable (GL_LINE_SMOOTH);
glEnable (GL_BLEND);
glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
glHint (GL_LINE_SMOOTH_HINT, GL_DONT_CARE);
glLineWidth (1.5);
} // if statement
glScalef(1.1, 1.1, 1.1);
ChangeColor(0.0, 0.0, 1.0, 1.0, 0.0, 0.0, 0.8, 1.0);
glBegin(display_mode); // lower leg back left edge
glNormal3f(0, 0, -1);
glVertex3f(-12.5, 5, -10);
glVertex3f(-7.5, 5, -10);
glVertex3f(-7.5, -10, -10);
glVertex3f(-12.5, -10, -10);
glEnd();
glBegin(display_mode); // lower leg top left edge
glNormal3f(0, 1, 0);
glVertex3f(-12.5, 5, -10);
glVertex3f(-7.5, 5, -10);
glVertex3f(-7.5, 5, 10);
glVertex3f(-12.5, 5, 10);
glEnd();
glBegin(display_mode); // lower leg front left edge
CalculateNormal(5, -15, 5, 5, 0, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-12.5, 5, 10);
glVertex3f(-7.5, 5, 10);
glVertex3f(-7.5, -10, 17.5);
glVertex3f(-12.5, -10, 17.5);
glEnd();
glBegin(display_mode); // lower leg bottom left edge
glNormal3f(0, -1, 0);
glVertex3f(-7.5, -10, 17.5);
glVertex3f(-12.5, -10, 17.5);
glVertex3f(-12.5, -10, -10);
glVertex3f(-7.5, -10, -10);
glEnd();
glBegin(display_mode); // lower leg back right edge
glNormal3f(0, 0, -1);
glVertex3f(12.5, 5, -10);
glVertex3f(7.5, 5, -10);
glVertex3f(7.5, -10, -10);
glVertex3f(12.5, -10, -10);
glEnd();
glBegin(display_mode); // lower leg top right edge
glNormal3f(0, 1, 0);
glVertex3f(12.5, 5, -10);
glVertex3f(7.5, 5, -10);
glVertex3f(7.5, 5, 10);
glVertex3f(12.5, 5, 10);
glEnd();
glBegin(display_mode); // lower leg front right edge
CalculateNormal(-5, 0, 0, -5, -15, 5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(12.5, 5, 10);
glVertex3f(7.5, 5, 10);
glVertex3f(7.5, -10, 17.5);
glVertex3f(12.5, -10, 17.5);
glEnd();
//glBegin(display_mode); // lower leg bottom right edge
// glVertex3f(7.5, -10, 15); // no normal needed
// glVertex3f(12.5, -10, 15);
// glVertex3f(12.5, -10, -10);
// glVertex3f(7.5, -10, -10);
//glEnd();
glBegin(display_mode); // lower leg shin plate back face
glNormal3f(0, 0, -1);
glVertex3f(-10, -10, -10);
glVertex3f(-10, -45, -10);
glVertex3f(12.5, -45, -10);
glVertex3f(12.5, -10, -10);
glEnd();
glBegin(display_mode); // lower leg shin plate front face
glNormal3f(0, 0, 1);
glVertex3f(-10, -10, 25);
glVertex3f(-10, -30, 25);
glVertex3f(12.5, -30, 25);
glVertex3f(12.5, -10, 25);
glEnd();
glBegin(display_mode); // lower leg shin plate top face
glNormal3f(0, 1, 0);
glVertex3f(-10, -10, -10);
glVertex3f(-10, -10, 25);
glVertex3f(12.5, -10, 25);
glVertex3f(12.5, -10, -10);
glEnd();
glBegin(display_mode); // lower leg shin plate slanted face
CalculateNormal(22.5, -7.5, -5, 22.5, 0, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-10, -30, 25);
glVertex3f(12.5, -30, 25);
glVertex3f(12.5, -42.5, 17.5);
glVertex3f(-10, -42.5, 17.5);
glEnd();
glBegin(display_mode); // lower leg inside plate top edge
glNormal3f(0, 1, 0);
glVertex3f(-12.5, -30, -10);
glVertex3f(-12.5, -30, 17.5);
glVertex3f(-10, -30, 17.5);
glVertex3f(-10, -30, -10);
glEnd();
glBegin(display_mode); // lower leg inside plate front edge
glNormal3f(0, 0, 1);
glVertex3f(-10, -30, 17.5);
glVertex3f(-12.5, -30, 17.5);
glVertex3f(-12.5, -70, 17.5);
glVertex3f(-10, -70, 17.5);
glEnd();
glBegin(display_mode); // lower leg inside plate back edge
glNormal3f(0, 0, -1);
glVertex3f(-10, -30, -10);
glVertex3f(-12.5, -30, -10);
glVertex3f(-12.5, -70, -10);
glVertex3f(-10, -70, -10);
glEnd();
glBegin(display_mode); // lower leg inside plate inner edge
glNormal3f(1, 0, 0);
glVertex3f(-10, -30, 17.5);
glVertex3f(-10, -30, -10);
glVertex3f(-10, -70, -10);
glVertex3f(-10, -70, 17.5);
glEnd();
glBegin(display_mode); // lower leg inside plate outer edge
glNormal3f(-1, 0, 0);
glVertex3f(-12.5, -30, 17.5);
glVertex3f(-12.5, -30, -10);
glVertex3f(-12.5, -70, -10);
glVertex3f(-12.5, -70, 17.5);
glEnd();
glBegin(display_mode); // lower leg inside plate bottom edge
glNormal3f(0, -1, 0);
glVertex3f(-12.5, -70, -10);
glVertex3f(-12.5, -70, 17.5);
glVertex3f(-10, -70, 17.5);
glVertex3f(-10, -70, -10);
glEnd();
glBegin(display_mode); // lower leg flat front face
glNormal3f(0, 0, 1);
glVertex3f(-10, -42.5, 17.5);
glVertex3f(-10, -45, 17.5);
glVertex3f(12.5, -45, 17.5);
glVertex3f(12.5, -42.5, 17.5);
glEnd();
glBegin(display_mode); // lower leg flat bottom face
glNormal3f(0, -1, 0);
glVertex3f(12.5, -45, 17.5);
glVertex3f(12.5, -45, -10);
glVertex3f(-10, -45, -10);
glVertex3f(-10, -45, 17.5);
glEnd();
glBegin(display_mode); // lower leg right plate inside face
glNormal3f(-1, 0, 0);
glVertex3f(10, -45, -10);
glVertex3f(10, -70, -10);
glVertex3f(10, -70, 15);
glVertex3f(10, -45, 15);
glEnd();
glBegin(display_mode); // lower leg right plate outside face
glNormal3f(1, 0, 0);
glVertex3f(12.5, -45, -10);
glVertex3f(12.5, -70, -10);
glVertex3f(12.5, -70, 17.5);
glVertex3f(12.5, -45, 17.5);
glEnd();
glBegin(display_mode); // lower leg right plate bottom edge
glNormal3f(0, -1, 0);
glVertex3f(10, -70, -10);
glVertex3f(10, -70, 17.5);
glVertex3f(12.5, -70, 17.5);
glVertex3f(12.5, -70, -10);
glEnd();
glBegin(display_mode); // lower leg right face
glNormal3f(1, 0, 0);
glVertex3f(12.5, -10, -10);
glVertex3f(12.5, -10, 25);
glVertex3f(12.5, -30, 25);
glVertex3f(12.5, -42.5, 17.5);
glVertex3f(12.5, -70, 17.5);
glVertex3f(12.5, -70, -10);
glEnd();
glBegin(display_mode); // lower leg left face
glNormal3f(-1, 0, 0);
glVertex3f(-10, -10, -10);
glVertex3f(-10, -10, 25);
glVertex3f(-10, -30, 25);
glVertex3f(-10, -42.5, 17.5);
glVertex3f(-10, -70, 17.5);
glVertex3f(-10, -70, -10);
glEnd();
glBegin(display_mode); // lower leg right place front edge
glNormal3f(0, 0, 1);
glVertex3f(10, -45, 17.5);
glVertex3f(12.5, -45, 17.5);
glVertex3f(12.5, -70, 17.5);
glVertex3f(10, -70, 17.5);
glEnd();
glBegin(display_mode); // lower leg right place back edge
glNormal3f(0, 0, -1);
glVertex3f(10, -45, -10);
glVertex3f(12.5, -45, -10);
glVertex3f(12.5, -70, -10);
glVertex3f(10, -70, -10);
glEnd();
glBegin(display_mode); // lower leg hip joint left plate left face
glNormal3f(-1, 0, 0);
glVertex3f(-12.5, 5, -10);
glVertex3f(-12.5, 5, 10);
glVertex3f(-12.5, -10, 17.5);
glVertex3f(-12.5, -10, -10);
glEnd();
glBegin(display_mode); // lower leg hip joint left plate right face
glNormal3f(1, 0, 0);
glVertex3f(-7.5, 5, -10);
glVertex3f(-7.5, 5, 10);
glVertex3f(-7.5, -10, 17.5);
glVertex3f(-7.5, -10, -10);
glEnd();
glBegin(display_mode); // lower leg hip joint right plate left face
glNormal3f(-1, 0, 0);
glVertex3f(7.5, 5, -10);
glVertex3f(7.5, 5, 10);
glVertex3f(7.5, -10, 17.5);
glVertex3f(7.5, -10, -10);
glEnd();
glBegin(display_mode); // lower leg hip joint right plate right face
glNormal3f(1, 0, 0);
glVertex3f(12.5, 5, -10);
glVertex3f(12.5, 5, 10);
glVertex3f(12.5, -10, 17.5);
glVertex3f(12.5, -10, -10);
glEnd();
} // DrawLowerLeg
void Decepticon :: DrawShoulder()
{
if (anti_aliasing)
{
glEnable (GL_LINE_SMOOTH);
glEnable (GL_BLEND);
glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
glHint (GL_LINE_SMOOTH_HINT, GL_DONT_CARE);
glLineWidth (1.5);
} // if statement
glTranslatef (0, -20, -15);
ChangeColor(0.0, 0.0, 1.0, 1.0, 0.0, 0.0, 0.8, 1.0);
glBegin(display_mode); // shoulder back
glNormal3f(0, 0, -1);
glVertex3f(0, 0, -12.5);
glVertex3f(0, 22.5, -12.5);
glVertex3f(5, 27.5, -12.5);
glVertex3f(20, 27.5, -12.5);
glVertex3f(20, 10, -12.5);
glVertex3f(7.5, 0, -12.5);
glEnd();
glBegin(display_mode); // shoulder front
glNormal3f(0, 0, 1);
glVertex3f(0, 0, 12.5);
glVertex3f(0, 22.5, 12.5);
glVertex3f(5, 27.5, 12.5);
glVertex3f(20, 27.5, 12.5);
glVertex3f(20, 10, 12.5);
glVertex3f(7.5, 0, 12.5);
glEnd();
glBegin(display_mode); // back inner shoulder edge
glNormal3f(-1, 0, 0);
glVertex3f(0, 0, -12.5);
glVertex3f(0, 22.5, -12.5);
glVertex3f(0, 20, -10.5);
glVertex3f(0, 0, -10.5);
glEnd();
glBegin(display_mode); // front inner shoulder edge
glNormal3f(-1, 0, 0);
glVertex3f(0, 0, 12.5);
glVertex3f(0, 22.5, 12.5);
glVertex3f(0, 20, 10.5);
glVertex3f(0, 0, 10.5);
glEnd();
glBegin(display_mode); // top inner shoulder edge
glNormal3f(-1, 0, 0);
glVertex3f(0, 22.5, -12.5);
glVertex3f(0, 20, -10);
glVertex3f(0, 20, 10);
glVertex3f(0, 22.5, 12.5);
glEnd();
glBegin(display_mode); // shoulder top left edge
CalculateNormal(5, 5, 25, 5, 5, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(0, 22.5, -12.5);
glVertex3f(5, 27.5, -12.5);
glVertex3f(5, 27.5, 12.5);
glVertex3f(0, 22.5, 12.5);
glEnd();
glBegin(display_mode); // shoulder top edge
glNormal3f(0, 1, 0);
glVertex3f(5, 27.5, -12.5);
glVertex3f(20, 27.5, -12.5);
glVertex3f(20, 27.5, 12.5);
glVertex3f(5, 27.5, 12.5);
glEnd();
glBegin(display_mode); // shoulder right edge
glNormal3f(1, 0, 0);
glVertex3f(20, 27.5, -12.5);
glVertex3f(20, 10, -12.5);
glVertex3f(20, 10, 12.5);
glVertex3f(20, 27.5, 12.5);
glEnd();
glBegin(display_mode);
CalculateNormal(-1.95, -1.66, 25, -1.95, -1.66, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(20, 10, -12.5);
glVertex3f(18.05, 8.34, -12.5); // 18.05 = 10 - (2.5 * 12.5) / sqrt(256.25)
glVertex3f(18.05, 8.34, 12.5); // 8.34 = 10 - (2.5 *10) / sqrt(256.25)
glVertex3f(20, 10, 12.5);
glEnd();
glBegin(display_mode);
CalculateNormal(12.5, 10, 2.5, 12.5, 10, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(7.5, 0, -12.5);
glVertex3f(20, 10, -12.5);
glVertex3f(20, 10, -10.5);
glVertex3f(7.5, 0, -10.5);
glEnd();
glBegin(display_mode); // same normal as last calculation
glVertex3f(7.5, 0, 12.5);
glVertex3f(20, 10, 12.5);
glVertex3f(20, 10, 10.5);
glVertex3f(7.5, 0, 10.5);
glEnd();
glBegin(display_mode);
glNormal3f(-1, 0, 0);
glVertex3f(0, 0, -12.5);
glVertex3f(7.5, 0, -12.5);
glVertex3f(7.5, 0, -10);
glVertex3f(0, 0, -10);
glEnd();
glBegin(display_mode); // same normal as last calculation
glVertex3f(0, 0, 12.5);
glVertex3f(7.5, 0, 12.5);
glVertex3f(7.5, 0, 10);
glVertex3f(0, 0, 10);
glEnd();
glBegin(display_mode); // shoulder plate back face
glNormal3f(0, 0, 1);
glVertex3f(0, 0, 12.5);
glVertex3f(0, 22.5, 12.5);
glVertex3f(15, 22.5, 12.5);
glVertex3f(15, 6, 12.5);
glVertex3f(7.5, 0, 12.5);
glEnd();
glBegin(display_mode); // shoulder plate front face
glVertex3f(0, 0, 15); // same normal as last calculation
glVertex3f(0, 22.5, 15);
glVertex3f(15, 22.5, 15);
glVertex3f(15, 6, 15);
glVertex3f(7.5, 0, 15);
glEnd();
glBegin(display_mode); // shoulder plate left edge
glNormal3f(-1, 0, 0);
glVertex3f(0, 0, 12.5);
glVertex3f(0, 22.5, 12.5);
glVertex3f(0, 22.5, 15);
glVertex3f(0, 0, 15);
glEnd();
glBegin(display_mode); // shoulder plate top edge
glNormal3f(0, 1, 0);
glVertex3f(0, 22.5, 12.5);
glVertex3f(15, 22.5, 12.5);
glVertex3f(15, 22.5, 15);
glVertex3f(0, 22.5, 15);
glEnd();
glBegin(display_mode); // shoulder plate right edge
glNormal3f(1, 0, 0);
glVertex3f(15, 22.5, 12.5);
glVertex3f(15, 6, 12.5);
glVertex3f(15, 6, 15);
glVertex3f(15, 22.5, 15);
glEnd();
glBegin(display_mode); // shoulder plate bottom right edge
CalculateNormal(-7.5, -6, 2.5, -7.5, -6, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(15, 6, 12.5);
glVertex3f(7.5, 0, 12.5);
glVertex3f(7.5, 0, 15);
glVertex3f(15, 6, 15);
glEnd();
glBegin(display_mode); // shoulder plate bottom edge
glNormal3f(0, -1, 0);
glVertex3f(0, 0, 12.5);
glVertex3f(7.5, 0, 12.5);
glVertex3f(7.5, 0, 15);
glVertex3f(0, 0, 15);
glEnd();
} // DrawShoulder
void Decepticon :: DrawTorso()
{
if (anti_aliasing)
{
glEnable (GL_LINE_SMOOTH);
glEnable (GL_BLEND);
glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
glHint (GL_LINE_SMOOTH_HINT, GL_DONT_CARE);
glLineWidth (1.5);
} // if statement
ChangeColor(0.0, 0.0, 0.8, 1.0, 0.0, 0.0, 0.5, 1.0);
glBegin(display_mode); // torso back face
glVertex3f(-32.5, 0, -12.5); // no normal needed (not visible - hidden behind 'torso back raised face')
glVertex3f(32.5, 0, -12.5);
glVertex3f(27.5, -20, -7.5);
glVertex3f(-27.5, -20, -7.5);
glEnd();
glBegin(display_mode); // torso front face
glVertex3f(-32.5, 0, 12.5); // no normal needed (not visible - hidden behind 'torso front raised face')
glVertex3f(32.5, 0, 12.5);
glVertex3f(27.5, -20, 7.5);
glVertex3f(-27.5, -20, 7.5);
glEnd();
glBegin(display_mode); // torso back raised face
CalculateNormal(50, 0, 0, 55, -20, 5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-27.5, 0, -15);
glVertex3f(27.5, 0, -15);
glVertex3f(22.5, -20, -10);
glVertex3f(-22.5, -20, -10);
glEnd();
glBegin(display_mode); // torso front raised face
CalculateNormal(55, -20, -5, 50, 0, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-27.5, 0, 15);
glVertex3f(27.5, 0, 15);
glVertex3f(22.5, -20, 10);
glVertex3f(-22.5, -20, 10);
glEnd();
glBegin(display_mode); // torso back left edge
CalculateNormal(0, -20, 7.5, -5, 0, 2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-27.5, 0, -15);
glVertex3f(-32.5, 0, -12.5);
glVertex3f(-27.5, -20, -7.5);
glVertex3f(-22.5, -20, -10);
glEnd();
glBegin(display_mode); // torso front left edge
CalculateNormal(-5, 0, -2.5, 0, -20, -7.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-27.5, 0, 15);
glVertex3f(-32.5, 0, 12.5);
glVertex3f(-27.5, -20, 7.5);
glVertex3f(-22.5, -20, 10);
glEnd();
glBegin(display_mode); // torso back right edge
CalculateNormal(5, 0, 2.5, 0, -20, 7.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(27.5, 0, -15);
glVertex3f(32.5, 0, -12.5);
glVertex3f(27.5, -20, -7.5);
glVertex3f(22.5, -20, -10);
glEnd();
glBegin(display_mode); // torso front right edge
CalculateNormal(0, -20, -7.5, 5, 0, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(27.5, 0, 15);
glVertex3f(32.5, 0, 12.5);
glVertex3f(27.5, -20, 7.5);
glVertex3f(22.5, -20, 10);
glEnd();
glBegin(display_mode); // torso left face
CalculateNormal(5, -20, 5, 0, 0, 25);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-32.5, 0, -12.5);
glVertex3f(-32.5, 0, 12.5);
glVertex3f(-27.5, -20, 7.5);
glVertex3f(-27.5, -20, -7.5);
glEnd();
glBegin(display_mode); // torso right face
CalculateNormal(0, 0, 25, -5, -20, 5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(32.5, 0, -12.5);
glVertex3f(32.5, 0, 12.5);
glVertex3f(27.5, -20, 7.5);
glVertex3f(27.5, -20, -7.5);
glEnd();
ChangeColor(0.0, 0.0, 1.0, 1.0, 0.0, 0.0, 0.8, 1.0);
} // DrawTorso
void Decepticon :: DrawUpperArm()
{
if (anti_aliasing)
{
glEnable (GL_LINE_SMOOTH);
glEnable (GL_BLEND);
glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
glHint (GL_LINE_SMOOTH_HINT, GL_DONT_CARE);
glLineWidth (1.5);
} // if statement
glBegin(display_mode); // upper arm back face
glNormal3f(0, 0, -1);
glVertex3f(0, 0, -8);
glVertex3f(0, -40, -8);
glVertex3f(7, -40, -8);
glVertex3f(7, -30, -8);
glVertex3f(11, -30, -8);
glVertex3f(11, -40, -8);
glVertex3f(18, -40, -8);
glVertex3f(18, 0, -8);
glEnd();
glBegin(display_mode); // upper arm front face
glNormal3f(0, 0, 1);
glVertex3f(0, 0, 8);
glVertex3f(0, -40, 8);
glVertex3f(7, -40, 8);
glVertex3f(7, -30, 8);
glVertex3f(11, -30, 8);
glVertex3f(11, -40, 8);
glVertex3f(18, -40, 8);
glVertex3f(18, 0, 8);
glEnd();
glBegin(display_mode); // upper arm left face
glNormal3f(-1, 0, 0);
glVertex3f(0, 0, -8);
glVertex3f(0, -40, -8);
glVertex3f(0, -40, 8);
glVertex3f(0, 0, 8);
glEnd();
glBegin(display_mode); // upper arm right face
glNormal3f(1, 0, 0);
glVertex3f(18, 0, -8);
glVertex3f(18, -40, -8);
glVertex3f(18, -40, 8);
glVertex3f(18, 0, 8);
glEnd();
glBegin(display_mode); // upper arm back raised face
glNormal3f(0, 0, -1);
glVertex3f(2, 0, -10);
glVertex3f(2, -37, -10);
glVertex3f(7, -37, -10);
glVertex3f(7, -30, -10);
glVertex3f(11, -30, -10);
glVertex3f(11, -37, -10);
glVertex3f(16, -37, -10);
glVertex3f(16, 0, -10);
glEnd();
glBegin(display_mode); // upper arm front raised face
glNormal3f(0, 0, 1);
glVertex3f(2, 0, 10);
glVertex3f(2, -37, 10);
glVertex3f(7, -37, 10);
glVertex3f(7, -30, 10);
glVertex3f(11, -30, 10);
glVertex3f(11, -37, 10);
glVertex3f(16, -37, 10);
glVertex3f(16, 0, 10);
glEnd();
glBegin(display_mode); // upper arm front left edge
CalculateNormal(2, -37, 2, 0, -40, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(0, 0, 8);
glVertex3f(0, -40, 8);
glVertex3f(2, -37, 10);
glVertex3f(2, 0, 10);
glEnd();
glBegin(display_mode); // upper arm back left edge
CalculateNormal(2, -37, -2, 0, -40, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(0, 0, -8);
glVertex3f(0, -40, -8);
glVertex3f(2, -37, -10);
glVertex3f(2, 0, -10);
glEnd();
glBegin(display_mode); // upper arm front right edge
CalculateNormal(-2, -37, 2, 0, -40, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(18, 0, 8);
glVertex3f(18, -40, 8);
glVertex3f(16, -37, 10);
glVertex3f(16, 0, 10);
glEnd();
glBegin(display_mode); // upper arm back right edge
CalculateNormal(-2, -37, 8, 0, -40, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(18, 0, -8);
glVertex3f(18, -40, -8);
glVertex3f(16, -37, -10);
glVertex3f(16, 0, -10);
glEnd();
glBegin(display_mode); // upper arm lower front left edge
CalculateNormal(7, 3, 2, 2, 3, 2);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(0, -40, 8);
glVertex3f(2, -37, 10);
glVertex3f(7, -37, 10);
glVertex3f(7, -40, 8);
glEnd();
glBegin(display_mode); // upper arm lower front right edge
CalculateNormal(-7, 3, 2, -2, 3, 2);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(18, -40, 8);
glVertex3f(16, -37, 10);
glVertex3f(11, -37, 10);
glVertex3f(11, -40, 8);
glEnd();
glBegin(display_mode); // upper arm lower back left edge
CalculateNormal(7, 3, -2, 2, 3, -2);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(0, -40, -8);
glVertex3f(2, -37, -10);
glVertex3f(7, -37, -10);
glVertex3f(7, -40, -8);
glEnd();
glBegin(display_mode); // upper arm lower back right edge
CalculateNormal(-7, 3, -2, -2, 3, -2);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(18, -40, -8);
glVertex3f(16, -37, -10);
glVertex3f(11, -37, -10);
glVertex3f(11, -40, -8);
glEnd();
glBegin(display_mode); // upper arm inside left edge
glNormal3f(1, 0, 0);
glVertex3f(7, -30, -10);
glVertex3f(7, -37, -10);
glVertex3f(7, -40, -8);
glVertex3f(7, -40, 8);
glVertex3f(7, -37, 10);
glVertex3f(7, -30, 10);
glEnd();
glBegin(display_mode); // upper arm inside right edge
glNormal3f(1, 0, 0);
glVertex3f(11, -30, -10);
glVertex3f(11, -37, -10);
glVertex3f(11, -40, -8);
glVertex3f(11, -40, 8);
glVertex3f(11, -37, 10);
glVertex3f(11, -30, 10);
glEnd();
glBegin(display_mode); // upper arm inside upper edge
glNormal3f(0, -1, 0);
glVertex3f(7, -30, -10);
glVertex3f(7, -30, 10);
glVertex3f(11, -30, 10);
glVertex3f(11, -30, -10);
glEnd();
glBegin(display_mode); // upper arm bottom edge
glNormal3f(0, -1, 0);
glVertex3f(0, -40, -8);
glVertex3f(7, -40, -8);
glVertex3f(7, -40, 8);
glVertex3f(0, -40, 8);
glEnd();
glBegin(display_mode); // same normal as last
glVertex3f(11, -40, -8);
glVertex3f(18, -40, -8);
glVertex3f(18, -40, 8);
glVertex3f(11, -40, 8);
glEnd();
} // DrawUpperArm
CDoubleArray* GetMrGrayCurvature(vtkPolyData* p)
{
// Params: p is a vtkPolyData mesh
// Should have ONLY TRIANGLES!
// No other primitive is checked. Don't send in a stripped mesh.
// Normals is an array of floats that the normals will be written to.
// Should have 3*n elements. (n is obtained from p)
// Grays is an array of BYTEs that the colours will be written to.
// n elements. 1 byte per vertex, 0-255 grayscale
// This routine gray-codes each vertex according to the local curvature
// Also calculates an area-weighted set of Normals
// The "curvature" is approximated by the following formula:
// C = R / (fabs(R) + sqrt(A)/4)
// Where R is the signed distance between a point and the
// average plane of its connected neighbours, and A is the
// area of all the triangles featuring the point.
// The plane is defined by the averages of all triangle normals
// and centers (area weighted averages)
int nVerticies = p->GetNumberOfPoints();
//int nTriangles = p->GetNumberOfPolys();
vtkDoubleArray *pArrayNormals = NULL;
double *Normals = NULL;
CDoubleArray *pCurvatures = NULL;
// Zero Normals and Colours if we have any.. note we'll need
// a temp normal store even if they don't want it returned
/* Normals = new float[nVerticies*3];
memset(Normals, 0, sizeof(float)*nVerticies*3);
*/
pArrayNormals = vtkDoubleArray::New();
if (!pArrayNormals)
return NULL;
pArrayNormals->SetNumberOfComponents(3);
pArrayNormals->SetNumberOfTuples(nVerticies);
Normals = pArrayNormals->GetPointer(0);
if (!Normals)
{
pArrayNormals->Delete();
return NULL;
}
// 2003.09.24 RFD: trying this as a fix for sporatic linux curvature noise bug.
memset(Normals, 0, sizeof(double)*nVerticies*3);
pCurvatures = new CDoubleArray;
if (!pCurvatures || !pCurvatures->Create(1, nVerticies))
{
// delete[] Normals;
pArrayNormals->Delete();
return NULL;
}
p->BuildLinks();
double fMax = 0.0,
fSum = 0.0;
//for (int i=0;i<nVerticies;i++)
for (vtkIdType i=0;i<nVerticies;i++)
{
// For each vertex, calculate an average plane and normal
double A=0; // Total area of all triangles using this vertex
double P[3]={0,0,0}; // Mean of centers of all triangles using this vertex
// Find out which triangles use this vertex
unsigned short nTris;
//int *pp;
vtkIdType *pp;
//p->GetPointCells(i,nTris,pp);
p->GetPointCells(i,nTris,pp);
for (int j=0;j<nTris;j++,pp++)
{
// This triangle uses this point.
//int nVerts;
vtkIdType nVerts;
//int *Verts;
vtkIdType *Verts;
//p->GetCellPoints(*pp,nVerts,Verts);
p->GetCellPoints(*pp,nVerts,Verts);
if (nVerts!=3)
continue;
static double p1[3];
static double p2[3];
static double p3[3];
p->GetPoint(Verts[0], p1);
//printf("%lf %lf %lf\n",p1[0],p1[1],p1[2]);
p->GetPoint(Verts[1], p2);
p->GetPoint(Verts[2], p3);
//printf("%lf %lf %lf %lf %lf %lf %lf %lf %lf\n",p1[0],p1[1],p1[2],p2[0],p2[1],p2[2],p3[0],p3[1],p3[2]);
// Get its normal and area at the same time
double n[3],dA;
CalculateNormal(p1,p2,p3,n,&dA);
// Store area weighted normal
Normals[i*3]+=n[0]*dA;
Normals[i*3+1]+=n[1]*dA;
Normals[i*3+2]+=n[2]*dA;
// Add it's weighted center
P[0]+= (p1[0]+p2[0]+p3[0])*dA;
P[1]+= (p1[1]+p2[1]+p3[1])*dA;
P[2]+= (p1[2]+p2[2]+p3[2])*dA;
// Add the area to the running total
A+=dA;
} // Next triangle on this vertex
// Average out all the normals
if (A)
{
double RecipA = 1.0/A;
Normals[i*3]*=RecipA;
Normals[i*3+1]*=RecipA;
Normals[i*3+2]*=RecipA;
RecipA*=1.0/3.0;
P[0]*=RecipA;
P[1]*=RecipA;
P[2]*=RecipA;
}
// Find the signed distance to the average plane
double *x= p->GetPoint(i);
double *n=&(Normals[i*3]);
double R = n[0]*(x[0]-P[0]) + n[1]*(x[1]-P[1]) + n[2]*(x[2]-P[2]);
// Now encode the curvature
// C = R / (fabs(R) + sqrt(A)/4)
double C = R / (fabsf(R) + sqrtf(A)*0.25);
/*
// Convert to a byte value
BYTE gray=(BYTE)((255.9*(C+1.0))*0.5);
// Assign as the vertex colour
if (Grays) Grays[i]=gray;
*/
pCurvatures->SetAtAbsoluteIndex(C, i);
fSum += fabsf(C);
if (fabsf(C) > fMax)
fMax = fabsf(C);
} // Next vertex
// delete[] Normals; // Was temp in that case.
// p->GetPointData()->SetNormals(pArrayNormals);
pArrayNormals->Delete();
return pCurvatures;
}
T MapRangeValue(T sX, T xMin, T xMax, T yMin, T yMax)
{
return( Lerp( yMin, yMax, CalculateNormal(sX,xMin,xMax)) );
}
//-------------------------------------------------------------------------------------------------
// render a single frame of a MD2 model
void JMD2Model::Render(int frameNum)
{
Vector3D *pointList;
int i;
// create a pointer to the frame we want to show
pointList = &mModel->pointList[mModel->numPoints * frameNum];
// set the texture
mRenderer->BindTexture(mModel->modelTex);
#if !defined (PSP)
// display the textured model with proper lighting normals
#if (defined GL_ES_VERSION_2_0) || (defined GL_VERSION_2_0)
#elif (defined GL_ES_VERSION_1_1) || (defined GL_VERSION_1_1) || (defined GL_VERSION_ES_CM_1_1) || (defined GL_OES_VERSION_1_1)
glEnableClientState(GL_VERTEX_ARRAY);
glEnableClientState(GL_TEXTURE_COORD_ARRAY);
#else
glBegin(GL_TRIANGLES);
#endif //(defined GL_ES_VERSION_2_0) || (defined GL_VERSION_2_0)
for(i = 0; i < mModel->numTriangles; i++)
{
CalculateNormal(pointList[mModel->triIndex[i].meshIndex[0]].v,
pointList[mModel->triIndex[i].meshIndex[2]].v,
pointList[mModel->triIndex[i].meshIndex[1]].v);
#if (defined GL_ES_VERSION_2_0) || (defined GL_VERSION_2_0)
#elif (defined GL_ES_VERSION_1_1) || (defined GL_VERSION_1_1)|| (defined GL_VERSION_ES_CM_1_1) || (defined GL_OES_VERSION_1_1)
float vertex_data[]={
pointList[mModel->triIndex[i].meshIndex[0]].x, pointList[mModel->triIndex[i].meshIndex[0]].y, pointList[mModel->triIndex[i].meshIndex[0]].z,
pointList[mModel->triIndex[i].meshIndex[2]].x, pointList[mModel->triIndex[i].meshIndex[2]].y, pointList[mModel->triIndex[i].meshIndex[2]].z,
pointList[mModel->triIndex[i].meshIndex[1]].x, pointList[mModel->triIndex[i].meshIndex[1]].y, pointList[mModel->triIndex[i].meshIndex[1]].z,
};
float texcoord_data[] = {
mModel->st[mModel->triIndex[i].stIndex[0]].s,
mModel->st[mModel->triIndex[i].stIndex[0]].t,
mModel->st[mModel->triIndex[i].stIndex[2]].s,
mModel->st[mModel->triIndex[i].stIndex[2]].t,
mModel->st[mModel->triIndex[i].stIndex[1]].s,
mModel->st[mModel->triIndex[i].stIndex[1]].t,
};
glVertexPointer(3,GL_FLOAT,0,vertex_data);
glTexCoordPointer(2,GL_FLOAT,0,texcoord_data);
#else
glTexCoord2f(mModel->st[mModel->triIndex[i].stIndex[0]].s,
mModel->st[mModel->triIndex[i].stIndex[0]].t);
glVertex3fv(pointList[mModel->triIndex[i].meshIndex[0]].v);
glTexCoord2f(mModel->st[mModel->triIndex[i].stIndex[2]].s ,
mModel->st[mModel->triIndex[i].stIndex[2]].t);
glVertex3fv(pointList[mModel->triIndex[i].meshIndex[2]].v);
glTexCoord2f(mModel->st[mModel->triIndex[i].stIndex[1]].s,
mModel->st[mModel->triIndex[i].stIndex[1]].t);
glVertex3fv(pointList[mModel->triIndex[i].meshIndex[1]].v);
#endif //#if (!defined GL_ES_VERSION_2_0) && (!defined GL_VERSION_2_0)
}
#if (defined GL_ES_VERSION_2_0) || (defined GL_VERSION_2_0)
#elif (defined GL_ES_VERSION_1_1) || (defined GL_VERSION_1_1) || (defined GL_VERSION_ES_CM_1_1) || (defined GL_OES_VERSION_1_1)
glDrawArrays(GL_TRIANGLES,0,3); // seems suspicious to put that here, should probably be in the loop
#else
glEnd();
#endif //(defined GL_ES_VERSION_2_0) || (defined GL_VERSION_2_0)
#else
PSPVertex3D* vertices = (PSPVertex3D*) sceGuGetMemory(mModel->numTriangles * 3 * sizeof(PSPVertex3D));
int n = 0;
for(i = 0; i < mModel->numTriangles; i++)
{
//CalculateNormal(&vertices[n].normal,
// pointList[mModel->triIndex[i].meshIndex[0]].v,
// pointList[mModel->triIndex[i].meshIndex[2]].v,
// pointList[mModel->triIndex[i].meshIndex[1]].v);
vertices[n].texture.x = mModel->st[mModel->triIndex[i].stIndex[0]].s;
vertices[n].texture.y = mModel->st[mModel->triIndex[i].stIndex[0]].t;
vertices[n].pos.x = pointList[mModel->triIndex[i].meshIndex[0]].x;
vertices[n].pos.y = pointList[mModel->triIndex[i].meshIndex[0]].y;
vertices[n].pos.z = pointList[mModel->triIndex[i].meshIndex[0]].z;
n++;
//vertices[n].normal.x = vertices[n-1].normal.x;
//vertices[n].normal.y = vertices[n-1].normal.y;
//vertices[n].normal.z = vertices[n-1].normal.z;
vertices[n].texture.x = mModel->st[mModel->triIndex[i].stIndex[2]].s;
vertices[n].texture.y = mModel->st[mModel->triIndex[i].stIndex[2]].t;
vertices[n].pos.x = pointList[mModel->triIndex[i].meshIndex[2]].x;
vertices[n].pos.y = pointList[mModel->triIndex[i].meshIndex[2]].y;
vertices[n].pos.z = pointList[mModel->triIndex[i].meshIndex[2]].z;
n++;
//vertices[n].normal.x = vertices[n-1].normal.x;
//vertices[n].normal.y = vertices[n-1].normal.y;
//vertices[n].normal.z = vertices[n-1].normal.z;
vertices[n].texture.x = mModel->st[mModel->triIndex[i].stIndex[1]].s;
vertices[n].texture.y = mModel->st[mModel->triIndex[i].stIndex[1]].t;
vertices[n].pos.x = pointList[mModel->triIndex[i].meshIndex[1]].x;
vertices[n].pos.y = pointList[mModel->triIndex[i].meshIndex[1]].y;
vertices[n].pos.z = pointList[mModel->triIndex[i].meshIndex[1]].z;
n++;
}
sceGuColor(0xff000000);
sceGumDrawArray(GU_TRIANGLES,GU_TEXTURE_32BITF|GU_NORMAL_32BITF|GU_VERTEX_32BITF|GU_TRANSFORM_3D,mModel->numTriangles*3,0,vertices);
#endif
}
BRUSH* ConvertXModelToBrushFormat ( char* szFilename, BRUSH* pBrush, int* piCount, LPDIRECT3DDEVICE8 lpDevice )
{
// takes an x model and converts it into brushes
// check the pointers are valid
if ( !szFilename || !piCount )
return NULL;
// used to access vertex data
struct sMeshData
{
float x, y, z;
float nx, ny, nz;
float tu, tv;
};
// variable declarations
tagModelData* ptr; // model data
LPDIRECT3DVERTEXBUFFER8 pMeshVertexBuffer; // vertex buffer
LPDIRECT3DINDEXBUFFER8 pMeshIndexBuffer; // index buffer
sMeshData* pMeshVertices; // mesh vertices
WORD* pMeshIndices; // mesh indices
sMesh* pMesh; // mesh data
int iCount;
// load the model
Constructor ( lpDevice );
ptr = Load ( 1, szFilename );
pMesh = ptr->m_Object.m_Meshes;
// count the number of brushes so we can allocate enough memory for them
iCount = 0;
while ( pMesh )
{
pMesh = pMesh->m_Next;
iCount++;
}
// store the number of models in the brush count pointer
*piCount = iCount;
// now setup the brushes
pBrush = new BRUSH [ iCount ]; // allocate memory
// set the mesh pointer back to the original mesh
pMesh = ptr->m_Object.m_Meshes;
// run through all meshes and store the brush data
// first off set iCount to 0 so we know which brush
// we are dealing with
iCount = 0;
while ( pMesh )
{
int iInd = 0;
DWORD dwNumVertices = pMesh->m_Mesh->GetNumVertices ( );
DWORD dwNumFaces = pMesh->m_Mesh->GetNumFaces ( );
pBrush [ iCount ].Faces = new POLYGON [ dwNumFaces ];
pBrush [ iCount ].FaceCount = dwNumFaces;
pBrush [ iCount ].Bounds.Max = D3DXVECTOR3 ( 150.0f, 150.0f, 150.0f );
pBrush [ iCount ].Bounds.Min = D3DXVECTOR3 ( -150.0f, -150.0f, -150.0f );
pBrush [ iCount ].BSPTree = NULL;
pMesh->m_Mesh->GetVertexBuffer ( &pMeshVertexBuffer );
pMesh->m_Mesh->GetIndexBuffer ( &pMeshIndexBuffer );
DWORD dwFVF = pMesh->m_Mesh->GetFVF ( );
pMeshVertexBuffer->Lock ( 0, pMesh->m_Mesh->GetNumVertices ( ) * sizeof ( sMeshData ), ( BYTE** ) &pMeshVertices, 0 );
pMeshIndexBuffer->Lock ( 0, 3 * pMesh->m_Mesh->GetNumFaces ( ) * sizeof ( WORD ), ( BYTE** ) &pMeshIndices, 0 );
for ( int iTemp = 0; iTemp < dwNumFaces; iTemp++ )
{
char szX [ 256 ];
char szY [ 256 ];
char szZ [ 256 ];
int iA = pMeshIndices [ iInd + 0 ];
int iB = pMeshIndices [ iInd + 1 ];
int iC = pMeshIndices [ iInd + 2 ];
WORD wIndices [ ] = { 0, 1, 2 };
pBrush [ iCount ].Faces [ iTemp ].IndexCount = 3;
pBrush [ iCount ].Faces [ iTemp ].TextureIndex = 0;
pBrush [ iCount ].Faces [ iTemp ].VertexCount = 3;
pBrush [ iCount ].Faces [ iTemp ].Indices = new WORD [ 3 ];
pBrush [ iCount ].Faces [ iTemp ].Vertices = new D3DVERTEX [ 3 ];
pBrush [ iCount ].Faces [ iTemp ].Vertices [ 0 ] = SetupVertex ( pMeshVertices [ iA ].x, pMeshVertices [ iA ].y, pMeshVertices [ iA ].z, pMeshVertices [ iA ].tu, pMeshVertices [ iA ].tv );
pBrush [ iCount ].Faces [ iTemp ].Vertices [ 1 ] = SetupVertex ( pMeshVertices [ iB ].x, pMeshVertices [ iB ].y, pMeshVertices [ iB ].z, pMeshVertices [ iB ].tu, pMeshVertices [ iB ].tv );
pBrush [ iCount ].Faces [ iTemp ].Vertices [ 2 ] = SetupVertex ( pMeshVertices [ iC ].x, pMeshVertices [ iC ].y, pMeshVertices [ iC ].z, pMeshVertices [ iC ].tu, pMeshVertices [ iC ].tv );
for ( int iChar = 0; iChar < 3; iChar++ )
{
sprintf ( szX, "%.1f", pBrush [ iCount ].Faces [ iTemp ].Vertices [ iChar ].x );
sprintf ( szY, "%.1f", pBrush [ iCount ].Faces [ iTemp ].Vertices [ iChar ].y );
sprintf ( szZ, "%.1f", pBrush [ iCount ].Faces [ iTemp ].Vertices [ iChar ].z );
pBrush [ iCount ].Faces [ iTemp ].Vertices [ iChar ].x = atof ( szX );
pBrush [ iCount ].Faces [ iTemp ].Vertices [ iChar ].y = atof ( szY );
pBrush [ iCount ].Faces [ iTemp ].Vertices [ iChar ].z = atof ( szZ );
}
memcpy ( pBrush [ iCount ].Faces [ iTemp ].Indices, wIndices, sizeof ( wIndices ) );
CalculateNormal ( &pBrush [ iCount ].Faces [ iTemp ] );
iInd += 3;
}
SetBlockPosition ( &pBrush [ iCount ], 0.0f, 0.0f, 0.0f, 1.0f );
pMeshVertexBuffer->Unlock ( );
pMeshIndexBuffer->Unlock ( );
iCount++;
pMesh = pMesh->m_Next;
}
iCount = 0;
pMesh = ptr->m_Object.m_Meshes;
for ( int iTemp = ptr->m_Object.m_NumFrames; iTemp > 0; iTemp-- )
{
sFrame* pFrame = ptr->m_Object.m_Frames->FindFrame ( iTemp );
if ( pFrame )
{
pBrush [ iCount ].Matrix._41 = pFrame->m_matOriginal._41;
pBrush [ iCount ].Matrix._42 = pFrame->m_matOriginal._42;
pBrush [ iCount ].Matrix._43 = pFrame->m_matOriginal._43;
iCount++;
}
}
return pBrush;
}
/* This function is designed to create vertex and index buffers according to a heightmap that has already been set.
* @PARAM ID3D11Device* device - ptr to a direct x 11 device, can usually be retrieved from the graphics class.
*/
bool CTerrain::InitialiseBuffers(ID3D11Device * device)
{
VertexType* vertices;
unsigned long* indices;
int index;
int vertex;
D3D11_BUFFER_DESC vertexBufferDesc;
D3D11_BUFFER_DESC indexBufferDesc;
D3D11_SUBRESOURCE_DATA vertexData;
D3D11_SUBRESOURCE_DATA indexData;
HRESULT result;
const int kNumIndicesInSquare = 6;
int numberOfNormals;
/////////////////////////////
// Terrain tiles setup.
/////////////////////////////
if (mpTerrainTiles == nullptr)
{
mpTerrainTiles = new CTerrainTile*[mHeight];
for (int y = 0; y < mHeight; y++)
{
mpTerrainTiles[y] = new CTerrainTile[mWidth];
}
}
// Calculate the number of vertices in the terrain mesh.
mVertexCount = (mWidth * mHeight);
mIndexCount = (mWidth - 1) * (mHeight - 1) * kNumIndicesInSquare;
numberOfNormals = ((mWidth - 1) * (mHeight - 1)) * 2;
// Create the vertex array.
vertices = new VertexType[mVertexCount];
// Output the allocation message to the log.
logger->GetInstance().MemoryAllocWriteLine(typeid(vertices).name());
// If we failed to allocate memory to the vertices array.
if (!vertices)
{
// Output error message to the debug log.
logger->GetInstance().WriteLine("Failed to create the vertex array in InitialiseBuffers function, Terrain.cpp.");
// Don't continue any more.
return false;
}
// Create the index array.
indices = new unsigned long[mIndexCount];
// Output allocation message to the debug log.
logger->GetInstance().MemoryAllocWriteLine(typeid(indices).name());
// If we failed to allocate memory to the indices array.
if (!indices)
{
// Output failure message to the debug log.
logger->GetInstance().WriteLine("Failed to create the index array in InitialiseBuffers function, Terrain.cpp.");
// Don't continue any further.
return false;
}
// Reset the index and vertex we're starting from to 0.
index = 0;
vertex = 0;
// Define the position in world space which we should decide on the terrain type.
const float changeInHeight = mHighestPoint - mLowestPoint;
float onePerc = changeInHeight / 100.0f;
mRockHeight = mLowestPoint + (onePerc * 60) - mLowestPoint; // 60% and upwards will be rock.
mGrassHeight = mLowestPoint + (onePerc * 30) - mLowestPoint; // 30% and upwards will be grass.
mSandHeight = mLowestPoint + (onePerc * 10) - mLowestPoint; // 10% and upwards will be sand.
mDirtHeight = mLowestPoint + (onePerc * 15) - mLowestPoint; // 15% and upwards will be dirt.
/// Plot the vertices of the grid.
float U = 0.0f;
float V = 0.0f;
// For the height of our height map.
for (int heightCount = 0; heightCount < mHeight; heightCount++)
{
// For the width of our height map.
for (int widthCount = 0; widthCount < mWidth; widthCount++)
{
// Calculate the positions the X and Z of this vertex (Only the height varies for now).
float posX = static_cast<float>(widthCount);
float posZ = static_cast<float>(heightCount);
// If we've loaded in a height map.
if (mHeightMapLoaded)
{
// Set the height to whatever we found in this coordinate of our array.
vertices[vertex].position = D3DXVECTOR3{ posX, static_cast<float>(mpHeightMap[heightCount][widthCount]), posZ };
}
else
{
// Set the position to a default of 0.0f.
vertices[vertex].position = D3DXVECTOR3{ posX, 0.0f, posZ };
}
U = static_cast<float>(widthCount);
V = static_cast<float>(heightCount);
vertices[vertex].UV = { U, V };
// Onto the next vertex.
vertex++;
}
V += 1.0f;
}
vertex = 0;
/// Calculate indices.
// Iterate through the height ( - 1 because we'll draw a triangle which uses the vertex above current point, don't want to cause issues when we hit the boundary).
for (int heightCount = 0; heightCount < mHeight - 1; heightCount++)
{
// Iterate through the width ( - 1 because we'll draw a triangle which uses the vertex to the right of the current point, don't want to cause issue's at the boundary).
for (int widthCount = 0; widthCount < mWidth - 1; widthCount++)
{
/// Calculate indices.
/// Triangle 1.
// Starting point.
indices[index] = vertex;
// Directly above.
indices[index + 1] = vertex + mWidth;
// Directly to the right.
indices[index + 2] = vertex + 1;
/// Triangle 2.
// Directly to the right.
indices[index + 3] = vertex + 1;
// Directly above.
indices[index + 4] = vertex + mWidth;
// Above and to the right.
indices[index + 5] = vertex + mWidth + 1;
// We've added 6 indices so increment the count by 6.
index += 6;
/// Calculate normals.
PrioEngine::Math::VEC3 face1Vec = CalculateNormal(vertices, vertex);
float length = PrioEngine::Math::GetLength(face1Vec);
// Normalise the normal.
vertices[vertex].normal = D3DXVECTOR3{ face1Vec.x / length, face1Vec.y / length, face1Vec.z / length };
// Increase the vertex which is our primary point.
vertex++;
}
PrioEngine::Math::VEC3 face1Vec = CalculateNormal(vertices, vertex);
float length = PrioEngine::Math::GetLength(face1Vec);
// Normalise the normal.
vertices[vertex].normal = D3DXVECTOR3{ face1Vec.x / length, face1Vec.y / length, face1Vec.z / length };
// We missed 1 off of the width count so auto adjust the vertex count here.
vertex++;
}
// Add the final top row.
for (int widthCount = 0; widthCount < mWidth; widthCount++)
{
// Bottom left
PrioEngine::Math::VEC3 point1 = { vertices[vertex].position.x, vertices[vertex].position.y, vertices[vertex].position.z };
// Bottom right
PrioEngine::Math::VEC3 point2 = { vertices[vertex - 1].position.x, vertices[vertex - 1].position.y, vertices[vertex - 1].position.z };
// Upper right
PrioEngine::Math::VEC3 point3 = { vertices[vertex - mWidth - 1].position.x, vertices[vertex - mWidth - 1].position.y, vertices[vertex - mWidth - 1].position.z };
// Upper left
PrioEngine::Math::VEC3 U = PrioEngine::Math::Subtract(point2, point1);
PrioEngine::Math::VEC3 V = PrioEngine::Math::Subtract(point3, point1);
PrioEngine::Math::VEC3 face1Vec = PrioEngine::Math::CrossProduct(U, V);
float length = PrioEngine::Math::GetLength(face1Vec);
// Normalise the normal.
vertices[vertex].normal = D3DXVECTOR3{ face1Vec.x / length, face1Vec.y / length, face1Vec.z / length };
// Next vertex.
vertex++;
}
// Reset vertex one more time, so we can use it in this function.
vertex = 0;
index = 0;
/// Calculate average normals..
// Iterate through the height.
for (int heightCount = 0; heightCount < mHeight; heightCount++)
{
// Iterate through the width.
for (int widthCount = 0; widthCount < mWidth; widthCount++)
{
PrioEngine::Math::VEC3 averageNormal;
averageNormal.x = 0.0f;
averageNormal.y = 0.0f;
averageNormal.z = 0.0f;
// Directly above.
if (heightCount < mHeight - 1)
{
int north = vertex + mWidth;
averageNormal.x += vertices[north].normal.x;
averageNormal.y += vertices[north].normal.y;
averageNormal.z += vertices[north].normal.z;
}
// Directly to the right.
if (widthCount < mWidth - 1)
{
int east = vertex + 1;
averageNormal.x += vertices[east].normal.x;
averageNormal.y += vertices[east].normal.y;
averageNormal.z += vertices[east].normal.z;
}
// Directly to the left.
if (widthCount > 0)
{
int west = vertex - 1;
averageNormal.x += vertices[west].normal.x;
averageNormal.y += vertices[west].normal.y;
averageNormal.z += vertices[west].normal.z;
}
// Below
if (heightCount > 0)
{
int south = vertex - mWidth;
averageNormal.x += vertices[south].normal.x;
averageNormal.y += vertices[south].normal.y;
averageNormal.z += vertices[south].normal.z;
}
float length = PrioEngine::Math::GetLength(averageNormal);
vertices[vertex].normal.x = averageNormal.x / length;
vertices[vertex].normal.y = averageNormal.y / length;
vertices[vertex].normal.z = averageNormal.z / length;
vertex++;
}
}
vertex = 0;
// Want to start again so clear both of these lists.
mTreesInfo.clear();
mPlantsInfo.clear();
for (int heightCount = 0; heightCount < mHeight; heightCount++)
{
for (int widthCount = 0; widthCount < mWidth; widthCount++)
{
CTerrain::VertexAreaType areaType = FindAreaType(vertices[vertex].position.y);
if (areaType == CTerrain::VertexAreaType::Grass)
{
CreateTree(vertices[vertex].position, vertices[vertex].normal);
CreatePlant(vertices[vertex].position, vertices[vertex].normal);
}
vertex++;
}
}
vertex = 0;
///////////////////////////////
// Set up the terrain tiles.
///////////////////////////////
for (int y = 0; y < mHeight; y++)
{
for (int x = 0; x < mWidth; x++)
{
D3DXVECTOR3 LL, LR, UL, UR;
// Pass in the surrounding tiles.
if (y > 0)
{
mpTerrainTiles[y][x].SetDownTile(&mpTerrainTiles[y - 1][x]);
}
else
{
mpTerrainTiles[y][x].SetDownTile(&mpTerrainTiles[y][x]);
}
if (x > 0)
{
mpTerrainTiles[y][x].SetLeftTile(&mpTerrainTiles[y][x - 1]);
}
else
{
mpTerrainTiles[y][x].SetLeftTile(&mpTerrainTiles[y][x]);
}
if (y < mHeight - 1)
{
mpTerrainTiles[y][x].SetUpTile(&mpTerrainTiles[y + 1][x]);
}
else
{
mpTerrainTiles[y][x].SetUpTile(&mpTerrainTiles[y][x]);
}
if (x < mWidth - 1)
{
mpTerrainTiles[y][x].SetRightTile(&mpTerrainTiles[y][x + 1]);
}
else
{
mpTerrainTiles[y][x].SetRightTile(&mpTerrainTiles[y][x]);
}
/////////////////////////////////
// Calculate vertices of surrounding grids.
////////////////////////////////
LL = vertices[vertex].position;
if (x < mWidth - 1)
{
LR = vertices[vertex + 1].position;
}
else
{
LR = vertices[vertex].position;
}
if (y < mHeight - 1)
{
UL = vertices[vertex + mWidth].position;
}
else
{
UL = vertices[vertex].position;
}
if (y < mHeight - 1)
{
if (x < mWidth - 1)
{
UR = vertices[vertex + mWidth + 1].position;
}
else
{
UR = vertices[vertex].position;
}
}
else
{
if (x < mWidth - 1)
{
UR = vertices[vertex - mWidth + 1].position;
}
else
{
UR = vertices[vertex].position;
}
}
D3DXVECTOR3 centrePos = (LL + LR + UL + UR) / 4;
mpTerrainTiles[y][x].SetCentrePosition(centrePos);
mpTerrainTiles[y][x].SetLowerLeftVertexPosition(LL);
mpTerrainTiles[y][x].SetLowerRightVertexPosition(LR);
mpTerrainTiles[y][x].SetUpperLeftVertexPosition(UL);
mpTerrainTiles[y][x].SetUpperRightVertexPosition(UR);
VertexAreaType areatype = FindAreaType(centrePos.y);
switch (areatype)
{
case VertexAreaType::Snow:
mpTerrainTiles[y][x].SetTileType(CTerrainTile::TileType::Rock);
break;
case VertexAreaType::Grass:
mpTerrainTiles[y][x].SetTileType(CTerrainTile::TileType::Grass);
break;
case VertexAreaType::Dirt:
mpTerrainTiles[y][x].SetTileType(CTerrainTile::TileType::Dirt);
break;
case VertexAreaType::Sand:
mpTerrainTiles[y][x].SetTileType(CTerrainTile::TileType::Sand);
break;
default:
mpTerrainTiles[y][x].SetTileType(CTerrainTile::TileType::Rock);
break;
}
vertex++;
}
}
//////////////////////////
// Generate foliage
// TODO:
// Remove all of this creation from the terrain. Let the engine do it, give the user control.
// Also allows seperation of objects.
/////////////////////////
//if (!GenerateFoliage(device, vertices))
//{
// logger->GetInstance().WriteLine("Failed to generate the foliage for terrain.");
// return false;
//}
// Set up the descriptor of the static vertex buffer.
vertexBufferDesc.Usage = D3D11_USAGE_DEFAULT;
vertexBufferDesc.ByteWidth = sizeof(VertexType) * mVertexCount;
vertexBufferDesc.BindFlags = D3D11_BIND_VERTEX_BUFFER;
vertexBufferDesc.CPUAccessFlags = 0;
vertexBufferDesc.MiscFlags = 0;
vertexBufferDesc.StructureByteStride = 0;
// Give the subresource structure a pointer to the vertex data.
vertexData.pSysMem = vertices;
vertexData.SysMemPitch = 0;
vertexData.SysMemSlicePitch = 0;
// Create the vertex buffer.
result = device->CreateBuffer(&vertexBufferDesc, &vertexData, &mpVertexBuffer);
if (FAILED(result))
{
logger->GetInstance().WriteLine("Failed to create the vertex buffer from the buffer description.");
return false;
}
// Set up the description of the static index buffer.
indexBufferDesc.Usage = D3D11_USAGE_DEFAULT;
indexBufferDesc.ByteWidth = sizeof(unsigned long) * mIndexCount;
indexBufferDesc.BindFlags = D3D11_BIND_INDEX_BUFFER;
indexBufferDesc.CPUAccessFlags = 0;
indexBufferDesc.MiscFlags = 0;
indexBufferDesc.StructureByteStride = 0;
// Give the subresource structure a pointer to the index data.
indexData.pSysMem = indices;
indexData.SysMemPitch = 0;
indexData.SysMemSlicePitch = 0;
// Create the index buffer.
result = device->CreateBuffer(&indexBufferDesc, &indexData, &mpIndexBuffer);
if (FAILED(result))
{
logger->GetInstance().WriteLine("Failed to create the index buffer from the buffer description.");
return false;
}
// Clean up the memory allocated to arrays.
delete[] vertices;
logger->GetInstance().MemoryDeallocWriteLine(typeid(vertices).name());
vertices = nullptr;
delete[] indices;
logger->GetInstance().MemoryDeallocWriteLine(typeid(indices).name());
indices = nullptr;
if (mpWater != nullptr)
{
mpWater->SetXPos(GetPosX());
mpWater->SetZPos(GetPosY());
}
return true;
}
void Coloring(Model& integ)
{
//CalculateDistance(integ);
CalculateDistance_AllVoxel(integ);
cout << "CalculateNormal: " << endl;
//
CalculateNormal(integ);
//
vector<cv::Mat> UpSilhouette(ImageNum);
ReadSilhouette(ImageNum, directory[1], model, pose[0], UpSilhouette);
vector<cv::Mat> DownSilhouette(ImageNum);
ReadSilhouette(ImageNum, directory[1], model, pose[1], DownSilhouette);
vector<cv::Mat> UpImage(ImageNum);
ReadColorImage(ImageNum, directory[0], model, pose[0], UpImage);
vector<cv::Mat> DownImage(ImageNum);
ReadColorImage(ImageNum, directory[0], model, pose[1], DownImage);
cv::Point temp;
int R, G, B;
int step = UpImage[0].step;
int width = UpSilhouette[0].cols;
int height = UpSilhouette[0].rows;
CColor tempColor(0.0, 0.0, 0.0);
Color_hue tempColorH;
vector<Color_hue> VoxColor;
CVector3d Point_Image;
short templum;
//short thre(50);
short thre(123);
Color_hue tempBackColor;
tempBackColor.r = integ.BackColor.r;
tempBackColor.g = integ.BackColor.g;
tempBackColor.b = integ.BackColor.b;
tempBackColor.CalcHue();
integ.SurfColors.reserve(integ.SurfNum); //
int ring1[][2] = { {0, 0}, {-1, -1}, {-1, 0},
{-1, 1}, {0, -1}, {0, 1},
{1, -1}, {1, 0}, {1, 1}
};
//
//
//
integ.Voxel_colors = new CColor **[integ.num[0]];
for (int i(0); i < integ.num[0]; i++) {
integ.Voxel_colors[i] = new CColor *[integ.num[1]];
for (int k(0); k < integ.num[1]; k++)
integ.Voxel_colors[i][k] = new CColor[integ.num[2]];
}
cout << "\nCheck visable voxels which can be seen\n" << endl;
for (int x = 1; x < integ.num[0] - 1; x++) {
for (int y = 1; y < integ.num[1] - 1; y++) {
for (int z = 1; z < integ.num[2] - 1; z++) {
//
if (integ.Voxels[x][y][z].surf) {
//
VoxColor.clear();
for (int i = 0; i < ImageNum; i++)
{
CanSee(integ, x, y, z, CameraPosUp[i], "UP"); //true(UP)
//UP
if (integ.Flags[x][y][z].upCan)
{
integ.Voxels[x][y][z].line.push_back(CameraPosUp[i] - integ.Voxels[x][y][z].center);
temp = integ.Voxels[x][y][z].CalcImageCoordofCenter(ART[i]);
//�
//
for (int n = 0; n < 9; n++) {
templum = (short)(UpSilhouette[i].data[width * (temp.y + ring1[n][1]) + temp.x + ring1[n][0]]);
if (templum < thre)
continue;
//opencv
tempColorH.Clear();
B = UpImage[i].data[step * (temp.y + ring1[n][1]) + (temp.x + ring1[n][0]) * 3];
G = UpImage[i].data[step * (temp.y + ring1[n][1]) + (temp.x + ring1[n][0]) * 3 + 1];
R = UpImage[i].data[step * (temp.y + ring1[n][1]) + (temp.x + ring1[n][0]) * 3 + 2];
tempColorH.b = B / 255.0;
tempColorH.g = G / 255.0;
tempColorH.r = R / 255.0;
tempColorH.CalcHue();
tempColorH.CalcLuminance();
//if( fabs(tempBackColor.GetHue() - tempColorH.GetHue()) < HueGap_Thres ) //�w�i�F�̐F���ɋ߂��F�͎g�p���Ȃ�
// continue;
// //�V�}�E�}��p
//if(tempColorH.luminance>0.5){
// tempColorH.Set(1.0,1.0,1.0);
//}
//else{
// tempColorH.Set(0.0,0.0,0.0);
//}
VoxColor.push_back(tempColorH);
}
}
CanSee(integ, x, y, z, CameraPosDown[i], "DOWN"); //false(DOWN)
//DOWN
if (integ.Flags[x][y][z].downCan)
{
integ.Voxels[x][y][z].line.push_back(CameraPosDown[i] - integ.Voxels[x][y][z].center);
temp = integ.Voxels[x][y][z].CalcImageCoordofCenter(ARTRTinv[i]);
//�
//
for (int n = 0; n < 9; n++) {
templum = (short)(DownSilhouette[i].data[width * (temp.y + ring1[n][1]) + temp.x + ring1[n][0]]);
if (templum < thre) //
continue;
//opencv�
tempColorH.Clear();
B = DownImage[i].data[step * (temp.y + ring1[n][1]) + (temp.x + ring1[n][0]) * 3];
G = DownImage[i].data[step * (temp.y + ring1[n][1]) + (temp.x + ring1[n][0]) * 3 + 1];
R = DownImage[i].data[step * (temp.y + ring1[n][1]) + (temp.x + ring1[n][0]) * 3 + 2];
tempColorH.b = B / 255.0;
tempColorH.g = G / 255.0;
tempColorH.r = R / 255.0;
tempColorH.CalcHue();
tempColorH.CalcLuminance();
//if( fabs(tempBackColor.GetHue() - tempColorH.GetHue()) < HueGap_Thres )
// continue;
//
//if(tempColorH.luminance>0.5){
// tempColorH.Set(1.0,1.0,1.0);
//}
//else{
// tempColorH.Set(0.0,0.0,0.0);
//}
VoxColor.push_back(tempColorH);
}
}
}
if (!VoxColor.empty()) {
tempColor = GetVoxelColor_hue_mode(VoxColor);
//tempColor = GetVoxelColor_lumi_mode(VoxColor);
//cout<<tempColor.r <<" "<<tempColor.g<<" "<<tempColor.b<<endl;
integ.Voxel_colors[x][y][z] = tempColor;
integ.SurfColors.push_back(tempColor);
}
else {
integ.Voxel_colors[x][y][z] = tempColor;
integ.SurfColors.push_back(tempColor); //0.0.0.0.0.0
}
}
}
}
}
//
UpSilhouette.clear();
UpSilhouette.shrink_to_fit();
DownSilhouette.clear();
DownSilhouette.shrink_to_fit();
UpImage.clear();
UpImage.shrink_to_fit();
DownImage.clear();
DownImage.shrink_to_fit();
}
void Decepticon :: DrawFoot()
{
if (anti_aliasing)
{
glEnable (GL_LINE_SMOOTH);
glEnable (GL_BLEND);
glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
glHint (GL_LINE_SMOOTH_HINT, GL_DONT_CARE);
glLineWidth (1.5);
} // if statement
glScalef(1, 1, 0.85);
ChangeColor(1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0);
glBegin(display_mode); // foot toe plate
CalculateNormal(20, 5, -2.5, 0, 5, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-10, 0, 40);
glVertex3f(-10, 5, 37.5);
glVertex3f(10, 5, 37.5);
glVertex3f(10, 0, 40);
glEnd();
glBegin(display_mode); // foot top ramp
CalculateNormal(20, 5, -27.5, 0, 5, -27.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-10, 5, 37.5);
glVertex3f(-10, 10, 10);
glVertex3f(10, 10, 10);
glVertex3f(10, 5, 37.5);
glEnd();
glBegin(display_mode); // foot top face
glNormal3f(0, 1, 0);
glVertex3f(-10, 10, 10);
glVertex3f(-10, 10, -15);
glVertex3f(10, 10, -15);
glVertex3f(10, 10, 10);
glEnd();
glBegin(display_mode); // foot back face
CalculateNormal(20, 0, 0, 20, -10, -5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-10, 10, -15);
glVertex3f(10, 10, -15);
glVertex3f(10, 0, -20);
glVertex3f(-10, 0, -20);
glEnd();
glBegin(display_mode); // foot left face
glNormal3f(-1, 0, 0);
glVertex3f(-10, 0, 40);
glVertex3f(-10, 5, 37.5);
glVertex3f(-10, 10, 10);
glVertex3f(-10, 10, -15);
glVertex3f(-10, 0, -20);
glEnd();
glBegin(display_mode); // foot right face
glNormal3f(1, 0, 0);
glVertex3f(10, 0, 40);
glVertex3f(10, 5, 37.5);
glVertex3f(10, 10, 10);
glVertex3f(10, 10, -15);
glVertex3f(10, 0, -20);
glEnd();
glBegin(display_mode); // foot bottom face
glNormal3f(0, -1, 0);
glVertex3f(-10, 0, 40);
glVertex3f(10, 0, 40);
glVertex3f(10, 0, -20);
glVertex3f(-10, 0, -20);
glEnd();
glBegin(display_mode); // foot top piece top slanted plate
CalculateNormal(10, 0, 0, 10, 7.5, -15);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-5, 7.5, 25);
glVertex3f(5, 7.5, 25);
glVertex3f(5, 15, 10);
glVertex3f(-5, 15, 10);
glEnd();
glBegin(display_mode); // foot top piece top plate
glNormal3f(0, 1, 0);
glVertex3f(-5, 15, 10);
glVertex3f(5, 15, 10);
glVertex3f(5, 15, -5);
glVertex3f(-5, 15, -5);
glEnd();
glBegin(display_mode); // foot top piece left face
glNormal3f(-1, 0, 0);
glVertex3f(-5, 7.5, 25);
glVertex3f(-5, 15, 10);
glVertex3f(-5, 15, -5);
glVertex3f(-5, 10, -10);
glEnd();
glBegin(display_mode); // foot top piece right face
glNormal3f(1, 0, 0);
glVertex3f(5, 7.5, 25);
glVertex3f(5, 15, 10);
glVertex3f(5, 15, -5);
glVertex3f(5, 10, -10);
glEnd();
glBegin(display_mode); // foot top piece back face
CalculateNormal(10, 5, 5, 10, 0, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-5, 10, -10);
glVertex3f(5, 10, -10);
glVertex3f(5, 15, -5);
glVertex3f(-5, 15, -5);
glEnd();
} // DrawFoot
//=================================================================================================
void Terrain::Build(bool smooth)
{
assert(state == 1);
HRESULT hr = D3DXCreateMeshFVF(n_tris, n_verts, D3DXMESH_MANAGED | D3DXMESH_32BIT, VTerrain::fvf, device, &mesh);
if(FAILED(hr))
throw Format("Failed to create new terrain mesh (%d)!", hr);
VTerrain* v;
//word* idx;
uint* idx;
uint n = 0;
//uint index = 0;
V(mesh->LockVertexBuffer(0, (void**)&v));
V(mesh->LockIndexBuffer(0, (void**)&idx));
#define TRI(xx,zz,uu,vv) v[n++] = VTerrain((x+xx)*tile_size, h[x+xx+(z+zz)*hszer], (z+zz)*tile_size, float(uu)/uv_mod, float(vv)/uv_mod,\
((float)(x+xx)) / n_tiles, ((float)(z+zz)) / n_tiles)
for(uint z = 0; z < n_tiles; ++z)
{
for(uint x = 0; x < n_tiles; ++x)
{
int u1 = (x%uv_mod);
int u2 = ((x + 1) % uv_mod);
if(u2 == 0)
u2 = uv_mod;
int v1 = (z%uv_mod);
int v2 = ((z + 1) % uv_mod);
if(v2 == 0)
v2 = uv_mod;
TRI(0, 0, u1, v1);
TRI(0, 1, u1, v2);
TRI(1, 0, u2, v1);
CalculateNormal(v[n - 3], v[n - 2], v[n - 1]);
TRI(0, 1, u1, v2);
TRI(1, 1, u2, v2);
TRI(1, 0, u2, v1);
CalculateNormal(v[n - 3], v[n - 2], v[n - 1]);
}
}
#undef TRI
for(uint z = 0; z < n_parts; ++z)
{
for(uint x = 0; x < n_parts; ++x)
{
const uint z_start = z*tiles_per_part,
z_end = z_start + tiles_per_part,
x_start = x*tiles_per_part,
x_end = x_start + tiles_per_part;
for(uint zz = z_start; zz < z_end; ++zz)
{
for(uint xx = x_start; xx < x_end; ++xx)
{
for(uint j = 0; j < 6; ++j)
{
*idx = (xx + zz*n_tiles) * 6 + j;
++idx;
}
}
}
}
}
V(mesh->UnlockIndexBuffer());
state = 2;
if(smooth)
SmoothNormals(v);
V(mesh->UnlockVertexBuffer());
}
//매번 리셋가능하도록 수정해야함
bool Ground::_SetBuffer() {
mVertices.clear();
mIndices.clear();
UINT col = mData->col - 1;
UINT row = mData->row - 1;
mVertexCount = (col + 1) * (row + 1);
mIndexCount = col * row * 2;
GROUND_CUSTOM_VERTEX* vertex = new GROUND_CUSTOM_VERTEX[mVertexCount];
UINT nIndex = 0;
//int imageSize = (col + 1) * (row + 1) * 3 - 3;
for (UINT z = 0; z < row + 1; ++z) {
for (UINT x = 0; x < col + 1; ++x) {
// Z축 반전 구현해야함.
nIndex = (z * (col + 1)) + x;
//int nIndex2 = (row - z) * (col + 1) + x;
vertex[nIndex].position.x = mPolygonSize * x;
vertex[nIndex].position.z = mPolygonSize * z;
//vertex[nIndex].position.y = (float)bitmapImage[nIndex * 3] * 0.005f;
vertex[nIndex].position.y = mData->GetHeight(x, z) * mData->amp;
vertex[nIndex].tu0 = (float)z * 40.0f /(float)(row - 1);
vertex[nIndex].tv0 = (float)x * 40.0f /(float)(col - 1);
vertex[nIndex].tu1 = (float)z / (float)(row - 1);
vertex[nIndex].tv1 = (float)x / (float)(col - 1);
vertex[nIndex].tu2 = (float)z * 40.0f / (float)(row - 1);
vertex[nIndex].tv2 = (float)x * 40.0f / (float)(col - 1);
//mVertices.push_back(vertex[nIndex].position);
vertex[nIndex].color = D3DCOLOR_RGBA(255, 255, 255, 255);
}
}
nIndex = 0;
for (UINT z = 1; z < row; ++z) {
for (UINT x = 1; x < col; ++x) {
int nVtxT = col + 1;
nIndex = z * nVtxT + x;
D3DXVECTOR3 normal = D3DXVECTOR3(0, 0, 0);
int nearVertices[6][3] = {
{ nIndex, nIndex - 1, nIndex - nVtxT },
{ nIndex, nIndex - nVtxT, nIndex - nVtxT + 1 },
{ nIndex, nIndex - nVtxT + 1, nIndex + 1 },
{ nIndex, nIndex + 1, nIndex + nVtxT },
{ nIndex, nIndex + nVtxT, nIndex + nVtxT - 1 },
{ nIndex, nIndex + nVtxT - 1, nIndex - 1 }
};
for (int k = 0; k < 6; ++k) {
D3DXVECTOR3 v0 = vertex[nearVertices[k][0]].position;
D3DXVECTOR3 v1 = vertex[nearVertices[k][1]].position;
D3DXVECTOR3 v2 = vertex[nearVertices[k][2]].position;
D3DXVECTOR3 temp = D3DXVECTOR3(0, 0, 0);
CalculateNormal(&temp, &v0, &v1, &v2);
normal += temp;
}
D3DXVec3Normalize(&normal, &normal);
vertex[nIndex].normal = normal;
}
}
GROUND_CUSTOM_INDEX* Index = new GROUND_CUSTOM_INDEX[mIndexCount];
nIndex = 0;
for (UINT z = 0; z < row; z++) {
for (UINT x = 0; x < col; x++) {
Index[nIndex].w2 = UINT(z * (col + 1) + x);
Index[nIndex].w1 = UINT((z + 1)*(col + 1) + x + 1);
Index[nIndex].w0 = UINT((z + 1)*(col + 1) + x);
//mIndices.push_back(D3DXVECTOR3(Index[nIndex].w0, Index[nIndex].w1, Index[nIndex].w2));
++nIndex;
Index[nIndex].w2 = UINT(z * (col + 1) + x);
Index[nIndex].w1 = UINT(z * (col + 1) + x + 1);
Index[nIndex].w0 = UINT((z + 1)*(col + 1) + x + 1);
//mIndices.push_back(D3DXVECTOR3(Index[nIndex].w0, Index[nIndex].w1, Index[nIndex].w2));
++nIndex;
}
}
// mVertexBuffer->Release();
// mIndexBuffer->Release();
//버택스 버퍼 생성
if (GetDevice()->CreateVertexBuffer(mVertexCount*sizeof(GROUND_CUSTOM_VERTEX),
0, D3DFVF_GROUNDCUSTOMVERTEX,
D3DPOOL_DEFAULT, &mVertexBuffer, NULL) < 0)
{
return false;
}
//락과 언락을 최대한 출일 수 있는 방법을 연구해야함
VOID* pVertices;
if (mVertexBuffer->Lock(0, mVertexCount*sizeof(GROUND_CUSTOM_VERTEX), (void**)&pVertices, 0) < 0)
return false;
memcpy(pVertices, vertex, mVertexCount*sizeof(GROUND_CUSTOM_VERTEX));
mVertexBuffer->Unlock();
//인덱스 버퍼 생성
if (GetDevice()->CreateIndexBuffer(mIndexCount*sizeof(GROUND_CUSTOM_INDEX), 0, D3DFMT_INDEX32,
D3DPOOL_DEFAULT, &mIndexBuffer, NULL) < 0)
{
return false;
}
/// 인덱스버퍼를 값으로 채운다.
/// 인덱스버퍼의 Lock()함수를 호출하여 포인터를 얻어온다.
VOID* pIndices;
if (mIndexBuffer->Lock(0, mIndexCount*sizeof(GROUND_CUSTOM_INDEX), (void**)&pIndices, 0) < 0)
return false;
memcpy(pIndices, Index, mIndexCount*sizeof(GROUND_CUSTOM_INDEX));
mIndexBuffer->Unlock();
delete[] vertex;
delete[] Index;
return true;
}
void Decepticon :: DrawBody()
{
if (anti_aliasing)
{
glEnable (GL_LINE_SMOOTH);
glEnable (GL_BLEND);
glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
glHint (GL_LINE_SMOOTH_HINT, GL_DONT_CARE);
glLineWidth (1.5);
} // if statement
GLfloat mat_ambient[] = {0.0, 0.0, 1.0, 1.0};
GLfloat mat_diffuse[] = {0.0, 0.0, 0.8, 1.0};
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
glBegin(display_mode); // bottom left edge
CalculateNormal(10, 10, -2.5, -2.5, 0, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-35, 0, 20);
glVertex3f(-37.5, 0, 17.5);
glVertex3f(-45, 10, 17.5);
glVertex3f(-42.5, 10, 20);
glEnd();
glBegin(display_mode); // bottom right edge
CalculateNormal(2.5, 0, -2.5, 5, 10, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(35, 0, 20);
glVertex3f(37.5, 0, 17.5);
glVertex3f(45, 10, 17.5);
glVertex3f(42.5, 10, 20);
glEnd();
glBegin(display_mode); // left edge
CalculateNormal(-2.5, 40, -2.5, -2.5, 0, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-42.5, 10, 20);
glVertex3f(-45, 10, 17.5);
glVertex3f(-45, 50, 17.5);
glVertex3f(-42.5, 47.5, 20);
glEnd();
glBegin(display_mode); // right edge
CalculateNormal(2.5, 0, -2.5, 2.5, 40, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(42.5, 10, 20);
glVertex3f(45, 10, 17.5);
glVertex3f(45, 50, 17.5);
glVertex3f(42.5, 47.5, 20);
glEnd();
glBegin(display_mode); // top left edge
CalculateNormal(30, 2.5, -2.5, 27.5, 2.5, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-42.5, 47.5, 20);
glVertex3f(-45, 50, 17.5);
glVertex3f(-15, 50, 17.5);
glVertex3f(-15, 47.5, 20);
glEnd();
glBegin(display_mode); // top right edge
CalculateNormal(2.5, 2.5, -2.5, -27.5, 2.5, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(42.5, 47.5, 20);
glVertex3f(45, 50, 17.5);
glVertex3f(15, 50, 17.5);
glVertex3f(15, 47.5, 20);
glEnd();
glBegin(display_mode); // left inner wall
glNormal3f(0, 0, 1);
glVertex3f(-15, 50, 15);
glVertex3f(-15, 50, 17.5);
glVertex3f(-15, 47.5, 20);
glVertex3f(-15, 45, 20);
glVertex3f(-15, 45, 17.5);
glEnd();
glBegin(display_mode); // right inner wall
glNormal3f(0, 0, 1);
glVertex3f(15, 50, 15);
glVertex3f(15, 50, 17.5);
glVertex3f(15, 47.5, 20);
glVertex3f(15, 45, 20);
glVertex3f(15, 45, 17.5);
glEnd();
glBegin(display_mode); // middle flat wall
glNormal3f(0, 1, 0);
glVertex3f(-15, 45, 17.5);
glVertex3f(-15, 45, 20);
glVertex3f(15, 45, 20);
glVertex3f(15, 45, 17.5);
glEnd();
glBegin(display_mode); // middle slanted edge
CalculateNormal(30, 5, -2.5, 0, 5, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-15, 45, 17.5);
glVertex3f(-15, 50, 15);
glVertex3f(15, 50, 15);
glVertex3f(15, 45, 17.5);
glEnd();
glBegin(display_mode); // bottom edge
CalculateNormal(-2.5, 0, -2.5, 72.5, 0, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-35, 0, 20);
glVertex3f(-37.5, 0, 17.5);
glVertex3f(37.5, 0, 17.5);
glVertex3f(35, 0, 20);
glEnd();
glBegin(display_mode); // back face
glNormal3f(0, 0, -1);
glVertex3f(-37.5, 0, -17.5);
glVertex3f(-45, 10, -17.5);
glVertex3f(-45, 50, -17.5);
glVertex3f(45, 50, -17.5);
glVertex3f(45, 10, -17.5);
glVertex3f(37.5, 0, -17.5);
glEnd();
glBegin(display_mode); // front bevelled left face
glNormal3f(0, 0, 1);
glVertex3f(-35, 0, 20);
glVertex3f(-42.5, 10, 20);
glVertex3f(-42.5, 47.5, 20);
glVertex3f(-30, 40, 20);
glVertex3f(-30, 15, 20);
glVertex3f(-27.5, 12.5, 20);
glEnd();
glBegin(display_mode); // front bevelled left edge
glNormal3f(1, 0, 0);
glVertex3f(-30, 40, 20);
glVertex3f(-30, 15, 20);
glVertex3f(-30, 15, 17.5);
glVertex3f(-30, 40, 17.5);
glEnd();
glBegin(display_mode); // front bevelled right face
glNormal3f(0, 0, 1);
glVertex3f(35, 0, 20);
glVertex3f(42.5, 10, 20);
glVertex3f(42.5, 47.5, 20);
glVertex3f(30, 40, 20);
glVertex3f(30, 15, 20);
glVertex3f(27.5, 12.5, 20);
glEnd();
glBegin(display_mode); // front bevelled right edge
glNormal3f(-1, 0, 0);
glVertex3f(30, 40, 20);
glVertex3f(30, 15, 20);
glVertex3f(30, 15, 17.5);
glVertex3f(30, 40, 17.5);
glEnd();
glBegin(display_mode); // front bevelled bottom face
glNormal3f(0, 0, 1);
glVertex3f(-35, 0, 20);
glVertex3f(-27.5, 12.5, 20);
glVertex3f(27.5, 12.5, 20);
glVertex3f(35, 0, 20);
glEnd();
glBegin(display_mode); // front bevelled bottom edge
glNormal3f(0, 1, 0);
glVertex3f(-27.5, 12.5, 20);
glVertex3f(27.5, 12.5, 20);
glVertex3f(27.5, 12.5, 17.5);
glVertex3f(-27.5, 12.5, 17.5);
glEnd();
glBegin(display_mode); // front bevelled bottom left edge
CalculateNormal(-2.5, 2.5, -2.5, -2.5, 2.5, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-27.5, 12.5, 20);
glVertex3f(-30, 15, 20);
glVertex3f(-30, 15, 17.5);
glVertex3f(-27.5, 12.5, 17.5);
glEnd();
glBegin(display_mode); // front bevelled bottom right edge
CalculateNormal(2.5, 2.5, 0, 2.5, 2.5, -2.5);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(27.5, 12.5, 20);
glVertex3f(30, 15, 20);
glVertex3f(30, 15, 17.5);
glVertex3f(27.5, 12.5, 17.5);
glEnd();
glBegin(display_mode); // front bevelled top left face
glNormal3f(0, 0, 1);
glVertex3f(-30, 40, 20);
glVertex3f(-42.5, 47.5, 20);
glVertex3f(-15, 47.5, 20);
glVertex3f(-15, 40, 20);
glEnd();
glBegin(display_mode); // front bevelled top right face
glNormal3f(0, 0, 1);
glVertex3f(30, 40, 20);
glVertex3f(42.5, 47.5, 20);
glVertex3f(15, 47.5, 20);
glVertex3f(15, 40, 20);
glEnd();
glBegin(display_mode); // front bevelled top middle face
glNormal3f(0, 0, 1);
glVertex3f(-15, 45, 20);
glVertex3f(-15, 40, 20);
glVertex3f(15, 40, 20);
glVertex3f(15, 45, 20);
glEnd();
glBegin(display_mode); // front bevelled top edge
glNormal3f(0, 1, 0);
glVertex3f(-30, 40, 20);
glVertex3f(30, 40, 20);
glVertex3f(30, 40, 17.5);
glVertex3f(-30, 40, 17.5);
glEnd();
glBegin(display_mode); // bottom face
glNormal3f(0, -1, 0);
glVertex3f(-37.5, 0, 17.5);
glVertex3f(-37.5, 0, -17.5);
glVertex3f(37.5, 0, -17.5);
glVertex3f(37.5, 0, 17.5);
glEnd();
glBegin(display_mode); // bottom left face
CalculateNormal(-7.5, 10, 35, -7.5, 10, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-37.5, 0, 17.5);
glVertex3f(-45, 10, 17.5);
glVertex3f(-45, 10, -17.5);
glVertex3f(-37.5, 0, -17.5);
glEnd();
glBegin(display_mode); // bottom right face
CalculateNormal(7.5, 10, 0, 7.5, 10, 35);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(37.5, 0, 17.5);
glVertex3f(45, 10, 17.5);
glVertex3f(45, 10, -17.5);
glVertex3f(37.5, 0, -17.5);
glEnd();
glBegin(display_mode); // left face
glNormal3f(-1, 0, 0);
glVertex3f(-45, 10, 17.5);
glVertex3f(-45, 50, 17.5);
glVertex3f(-45, 50, -17.5);
glVertex3f(-45, 10, -17.5);
glEnd();
glBegin(display_mode); // right face
glNormal3f(1, 0, 0);
glVertex3f(45, 10, 17.5);
glVertex3f(45, 50, 17.5);
glVertex3f(45, 50, -17.5);
glVertex3f(45, 10, -17.5);
glEnd();
glBegin(display_mode); // top face
glNormal3f(0, 1, 0);
glVertex3f(-45, 50, 17.5);
glVertex3f(-15, 50, 17.5);
glVertex3f(-15, 50, 15);
glVertex3f(15, 50, 15);
glVertex3f(15, 50, 17.5);
glVertex3f(45, 50, 17.5);
glVertex3f(45, 50, -17.5);
glVertex3f(-45, 50, -17.5);
glEnd();
mat_ambient[0] = 1.0;
mat_ambient[1] = 1.0;
mat_ambient[2] = 0.0;
mat_diffuse[0] = 0.8;
mat_diffuse[1] = 0.8;
mat_diffuse[2] = 0.0;
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
glBegin(display_mode); // left upper stripe face
glNormal3f(0, 0, 1);
glVertex3f(-42.5, 35, 21);
glVertex3f(-42.5, 31, 21);
glVertex3f(-32.5, 31, 21);
glVertex3f(-32.5, 35, 21);
glEnd();
glBegin(display_mode); // right upper stripe face
glNormal3f(0, 0, 1);
glVertex3f(42.5, 35, 21);
glVertex3f(42.5, 31, 21);
glVertex3f(32.5, 31, 21);
glVertex3f(32.5, 35, 21);
glEnd();
glBegin(display_mode); // left lower stripe face
glNormal3f(0, 0, 1);
glVertex3f(-42.5, 29, 21);
glVertex3f(-42.5, 25, 21);
glVertex3f(-32.5, 25, 21);
glVertex3f(-32.5, 29, 21);
glEnd();
glBegin(display_mode); // right lower stripe face
glNormal3f(0, 0, 1);
glVertex3f(42.5, 29, 21);
glVertex3f(42.5, 25, 21);
glVertex3f(32.5, 25, 21);
glVertex3f(32.5, 29, 21);
glEnd();
glBegin(display_mode); // left upper stripe left rise
glNormal3f(-1, 0, 0);
glVertex3f(-42.5, 35, 21);
glVertex3f(-42.5, 31, 21);
glVertex3f(-42.5, 31, 20);
glVertex3f(-42.5, 35, 20);
glEnd();
glBegin(display_mode); // right upper stripe right rise
glNormal3f(1, 0, 0);
glVertex3f(42.5, 35, 21);
glVertex3f(42.5, 31, 21);
glVertex3f(42.5, 31, 20);
glVertex3f(42.5, 35, 20);
glEnd();
glBegin(display_mode); // left upper stripe upper rise
glNormal3f(0, 1, 0);
glVertex3f(-42.5, 35, 21);
glVertex3f(-32.5, 35, 21);
glVertex3f(-32.5, 35, 20);
glVertex3f(-42.5, 35, 20);
glEnd();
glBegin(display_mode); // right upper stripe upper rise
glNormal3f(0, 1, 0);
glVertex3f(42.5, 35, 21);
glVertex3f(32.5, 35, 21);
glVertex3f(32.5, 35, 20);
glVertex3f(42.5, 35, 20);
glEnd();
glBegin(display_mode); // left upper stripe right rise
glNormal3f(1, 0, 0);
glVertex3f(-32.5, 35, 21);
glVertex3f(-32.5, 31, 21);
glVertex3f(-32.5, 31, 20);
glVertex3f(-32.5, 35, 20);
glEnd();
glBegin(display_mode); // right upper stripe left rise
glNormal3f(-1, 0, 0);
glVertex3f(32.5, 35, 21);
glVertex3f(32.5, 31, 21);
glVertex3f(32.5, 31, 20);
glVertex3f(32.5, 35, 20);
glEnd();
glBegin(display_mode); // left upper stripe lower rise
glNormal3f(0, -1, 0);
glVertex3f(-42.5, 31, 21);
glVertex3f(-32.5, 31, 21);
glVertex3f(-32.5, 31, 20);
glVertex3f(-42.5, 31, 20);
glEnd();
glBegin(display_mode); // right upper stripe lower rise
glNormal3f(0, -1, 0);
glVertex3f(42.5, 31, 21);
glVertex3f(32.5, 31, 21);
glVertex3f(32.5, 31, 20);
glVertex3f(42.5, 31, 20);
glEnd();
glBegin(display_mode); // left lower stripe left rise
glNormal3f(-1, 0, 0);
glVertex3f(-42.5, 29, 21);
glVertex3f(-42.5, 25, 21);
glVertex3f(-42.5, 25, 20);
glVertex3f(-42.5, 29, 20);
glEnd();
glBegin(display_mode); // right lower stripe right rise
glNormal3f(1, 0, 0);
glVertex3f(42.5, 29, 21);
glVertex3f(42.5, 25, 21);
glVertex3f(42.5, 25, 20);
glVertex3f(42.5, 29, 20);
glEnd();
glBegin(display_mode); // left lower stripe upper rise
glNormal3f(0, 1, 0);
glVertex3f(-42.5, 29, 21);
glVertex3f(-32.5, 29, 21);
glVertex3f(-32.5, 29, 20);
glVertex3f(-42.5, 29, 20);
glEnd();
glBegin(display_mode); // right lower stripe upper rise
glNormal3f(0, 1, 0);
glVertex3f(42.5, 29, 21);
glVertex3f(32.5, 29, 21);
glVertex3f(32.5, 29, 20);
glVertex3f(42.5, 29, 20);
glEnd();
glBegin(display_mode); // left lower stripe right rise
glNormal3f(1, 0, 0);
glVertex3f(-32.5, 29, 21);
glVertex3f(-32.5, 25, 21);
glVertex3f(-32.5, 25, 20);
glVertex3f(-32.5, 29, 21);
glEnd();
glBegin(display_mode); // right lower stripe left rise
glNormal3f(-1, 0, 0);
glVertex3f(32.5, 29, 21);
glVertex3f(32.5, 25, 21);
glVertex3f(32.5, 25, 20);
glVertex3f(32.5, 29, 21);
glEnd();
glBegin(display_mode); // left lower stripe lower rise
glNormal3f(0, -1, 0);
glVertex3f(-42.5, 25, 21);
glVertex3f(-32.5, 25, 21);
glVertex3f(-32.5, 25, 20);
glVertex3f(-42.5, 25, 20);
glEnd();
glBegin(display_mode); // right lower stripe lower rise
glNormal3f(0, 0, -1);
glVertex3f(42.5, 25, 21);
glVertex3f(32.5, 25, 21);
glVertex3f(32.5, 25, 20);
glVertex3f(42.5, 25, 20);
glEnd();
mat_ambient[0] = 0.0;
mat_ambient[1] = 0.0;
mat_ambient[2] = 0.8;
mat_diffuse[0] = 0.0;
mat_diffuse[1] = 0.0;
mat_diffuse[2] = 0.5;
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
glBegin(display_mode); // back brace back left face
glNormal3f(0, 0, -1);
glVertex3f(-45, 20, -15);
glVertex3f(-50, 25, -15);
glVertex3f(-50, 50, -15);
glVertex3f(-45, 50, -15);
glEnd();
glBegin(display_mode); // back brace back right face
glNormal3f(0, 0, -1);
glVertex3f(45, 20, -15);
glVertex3f(50, 25, -15);
glVertex3f(50, 50, -15);
glVertex3f(45, 50, -15);
glEnd();
glBegin(display_mode); // back brace back top face
glNormal3f(0, 0, -1);
glVertex3f(-50, 50, -15);
glVertex3f(-45, 55, -15);
glVertex3f(45, 55, -15);
glVertex3f(50, 50, -15);
glEnd();
glBegin(display_mode); // back brace front left face
glNormal3f(0, 0, 1);
glVertex3f(-45, 20, -5);
glVertex3f(-50, 25, -5);
glVertex3f(-50, 50, -5);
glVertex3f(-45, 50, -5);
glEnd();
glBegin(display_mode); // back brace front right face
glNormal3f(0, 0, 1);
glVertex3f(45, 20, -5);
glVertex3f(50, 25, -5);
glVertex3f(50, 50, -5);
glVertex3f(45, 50, -5);
glEnd();
glBegin(display_mode); // back brace front top face
glNormal3f(0, 0, 1);
glVertex3f(-50, 50, -5);
glVertex3f(-45, 55, -5);
glVertex3f(45, 55, -5);
glVertex3f(50, 50, -5);
glEnd();
glBegin(display_mode); // front brace back left face
glNormal3f(0, 0, -1);
glVertex3f(-45, 20, 5);
glVertex3f(-50, 25, 5);
glVertex3f(-50, 50, 5);
glVertex3f(-45, 50, 5);
glEnd();
glBegin(display_mode); // front brace back right face
glNormal3f(0, 0, -1);
glVertex3f(45, 20, 5);
glVertex3f(50, 25, 5);
glVertex3f(50, 50, 5);
glVertex3f(45, 50, 5);
glEnd();
glBegin(display_mode); // front brace back top face
glNormal3f(0, 0, 1);
glVertex3f(-50, 50, 15);
glVertex3f(-45, 55, 15);
glVertex3f(45, 55, 15);
glVertex3f(50, 50, 15);
glEnd();
glBegin(display_mode); // front brace back left face
glNormal3f(0, 0, 1);
glVertex3f(-45, 20, 15);
glVertex3f(-50, 25, 15);
glVertex3f(-50, 50, 15);
glVertex3f(-45, 50, 15);
glEnd();
glBegin(display_mode); // front brace back right face
glNormal3f(0, 0, 1);
glVertex3f(45, 20, 15);
glVertex3f(50, 25, 15);
glVertex3f(50, 50, 15);
glVertex3f(45, 50, 15);
glEnd();
glBegin(display_mode); // front brace back top face
glNormal3f(0, 0, 1);
glVertex3f(-50, 50, 15);
glVertex3f(-45, 55, 15);
glVertex3f(45, 55, 15);
glVertex3f(50, 50, 15);
glEnd();
glBegin(display_mode); // back brace lower left edge
CalculateNormal(-5, 5, 0, -5, 5, -10);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-45, 20, -5);
glVertex3f(-50, 25, -5);
glVertex3f(-50, 25, -15);
glVertex3f(-45, 20, -15);
glEnd();
glBegin(display_mode); // front brace lower left edge
CalculateNormal(-5, 5, 10, -5, 5, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-45, 20, 5);
glVertex3f(-50, 25, 5);
glVertex3f(-50, 25, 15);
glVertex3f(-45, 20, 15);
glEnd();
glBegin(display_mode); // back brace lower right edge
CalculateNormal(5, 5, -10, 5, 5, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(45, 20, -5);
glVertex3f(50, 25, -5);
glVertex3f(50, 25, -15);
glVertex3f(45, 20, -15);
glEnd();
glBegin(display_mode); // front brace lower right edge
CalculateNormal(5, 5, 0, 5, 5, 10);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(45, 20, 5);
glVertex3f(50, 25, 5);
glVertex3f(50, 25, 15);
glVertex3f(45, 20, 15);
glEnd();
glBegin(display_mode); // back brace left edge
glNormal3f(-1, 0, 0);
glVertex3f(-50, 25, -5);
glVertex3f(-50, 50, -5);
glVertex3f(-50, 50, -15);
glVertex3f(-50, 25, -15);
glEnd();
glBegin(display_mode); // front brace left edge
glNormal3f(-1, 0, 0);
glVertex3f(-50, 25, 5);
glVertex3f(-50, 50, 5);
glVertex3f(-50, 50, 15);
glVertex3f(-50, 25, 15);
glEnd();
glBegin(display_mode); // back brace right edge
glNormal3f(1, 0, 0);
glVertex3f(50, 25, -5);
glVertex3f(50, 50, -5);
glVertex3f(50, 50, -15);
glVertex3f(50, 25, -15);
glEnd();
glBegin(display_mode); // front brace right edge
glNormal3f(1, 0, 0);
glVertex3f(50, 25, 5);
glVertex3f(50, 50, 5);
glVertex3f(50, 50, 15);
glVertex3f(50, 25, 15);
glEnd();
glBegin(display_mode); // back brace top left edge
CalculateNormal(5, 5, 0, 5, 5, -10);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-50, 50, -5);
glVertex3f(-45, 55, -5);
glVertex3f(-45, 55, -15);
glVertex3f(-50, 50, -15);
glEnd();
glBegin(display_mode); // back brace top right edge
CalculateNormal(-5, 5, -10, -5, 5, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(50, 50, -5);
glVertex3f(45, 55, -5);
glVertex3f(45, 55, -15);
glVertex3f(50, 50, -15);
glEnd();
glBegin(display_mode); // front brace top left edge
CalculateNormal(5, 5, 10, 5, 5, 0);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(-50, 50, 5);
glVertex3f(-45, 55, 5);
glVertex3f(-45, 55, 15);
glVertex3f(-50, 50, 15);
glEnd();
glBegin(display_mode); // front brace top right edge
CalculateNormal(5, 5, 0, -5, 5, 10);
glNormal3f(normal_vector[0], normal_vector[1], normal_vector[2]);
glVertex3f(50, 50, 5);
glVertex3f(45, 55, 5);
glVertex3f(45, 55, 15);
glVertex3f(50, 50, 15);
glEnd();
glBegin(display_mode); // back brace top edge
glNormal3f(0, 1, 0);
glVertex3f(-45, 55, -5);
glVertex3f(45, 55, -5);
glVertex3f(45, 55, -15);
glVertex3f(-45, 55, -15);
glEnd();
glBegin(display_mode); // front brace top edge
glNormal3f(0, 1, 0);
glVertex3f(-45, 55, 5);
glVertex3f(45, 55, 5);
glVertex3f(45, 55, 15);
glVertex3f(-45, 55, 15);
glEnd();
mat_ambient[0] = 1.0;
mat_ambient[1] = 1.0;
mat_ambient[2] = 1.0;
mat_diffuse[0] = 1.0;
mat_diffuse[1] = 1.0;
mat_diffuse[2] = 1.0;
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
glBegin(display_mode); // gun-mount front face
glNormal3f(0, 0, 1);
glVertex3f(22, 55, 12.5);
glVertex3f(22, 60, 12.5);
glVertex3f(32, 60, 12.5);
glVertex3f(32, 55, 12.5);
glEnd();
glBegin(display_mode); // gun-mount back face
glNormal3f(0, 0, -1);
glVertex3f(22, 55, 7.5);
glVertex3f(22, 60, 7.5);
glVertex3f(32, 60, 7.5);
glVertex3f(32, 55, 7.5);
glEnd();
glBegin(display_mode); // gun-mount left face
glNormal3f(-1, 0, 0);
glVertex3f(22, 55, 12.5);
glVertex3f(22, 60, 12.5);
glVertex3f(22, 60, 7.5);
glVertex3f(22, 55, 7.5);
glEnd();
glBegin(display_mode); // gun-mount right face
glNormal3f(1, 0, 0);
glVertex3f(32, 55, 12.5);
glVertex3f(32, 60, 12.5);
glVertex3f(32, 60, 7.5);
glVertex3f(32, 55, 7.5);
glEnd();
glBegin(display_mode); // gun-mount top face
glNormal3f(0, 1, 0);
glVertex3f(22, 60, 12.5);
glVertex3f(22, 60, 7.5);
glVertex3f(32, 60, 7.5);
glVertex3f(32, 60, 12.5);
glEnd();
mat_ambient[0] = 0.0;
mat_ambient[1] = 0.0;
mat_ambient[2] = 1.0;
mat_diffuse[0] = 0.0;
mat_diffuse[1] = 0.0;
mat_diffuse[2] = 0.8;
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
if (display_mode == GL_LINE_LOOP)
{
glPushMatrix();
glTranslatef(-30, 67.5, -32.5);
glRotatef(90, 1, 0, 0);
TaperedWireCylinder(0, 12.5, 0, 20);
TaperedWireCylinder(15, 12.5, 12.5, 20);
glTranslatef(0, 15, 0);
TaperedWireCylinder(0, 12.5, 9.5, 20);
TaperedWireCylinder(3, 9.5, 9.5, 20);
glTranslatef(0, 3, 0);
TaperedWireCylinder(0, 9.5, 12.5, 20);
TaperedWireCylinder(30, 12.5, 12.5, 20);
glTranslatef(0, 30, 0);
TaperedWireCylinder(0, 12.5, 9.5, 20);
TaperedWireCylinder(2, 9.5, 9.5, 20);
glTranslatef(0, 2, 0);
TaperedWireCylinder(0, 9.5, 12.5, 20);
TaperedWireCylinder(4, 12.5, 12.5, 20);
glTranslatef(0, 4, 0);
TaperedWireCylinder(0, 12.5, 9.5, 20);
TaperedWireCylinder(5, 9.5, 9.5, 20);
glTranslatef(0, 5, 0);
TaperedWireCylinder(0, 9.5, 12.5, 20);
TaperedWireCylinder(4, 12.5, 12.5, 20);
glTranslatef(0, 4, 0);
TaperedWireCylinder(0, 12.5, 9.5, 20);
TaperedWireCylinder(2, 9.5, 9.5, 20);
glTranslatef(0, 2, 0);
TaperedWireCylinder(0, 9.5, 12.5, 20);
glPushMatrix();
glTranslatef(0, 5, 0);
mat_ambient[0] = 1.0;
mat_ambient[1] = 0.0;
mat_ambient[2] = 0.0;
mat_diffuse[0] = 0.8;
mat_diffuse[1] = 0.0;
mat_diffuse[2] = 0.0;
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
TaperedWireCylinder(5, 12.5, 12.5, 20);
mat_ambient[0] = 0.0;
mat_ambient[1] = 0.0;
mat_ambient[2] = 1.0;
mat_diffuse[0] = 0.0;
mat_diffuse[1] = 0.0;
mat_diffuse[2] = 1.0;
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
glPopMatrix();
TaperedWireCylinder(15, 12.5, 12.5, 20);
glTranslatef(0, 15, 0);
TaperedWireCylinder(0, 12.5, 9.5, 20);
glTranslatef(0, -2, 0);
TaperedWireCylinder(0, 9.5, 0, 20);
TaperedWireCylinder(2, 9.5, 9.5, 20);
glPopMatrix();
} // if statement
else if (display_mode == GL_POLYGON)
{
glPushMatrix();
glTranslatef(-30, 67.5, -32.5);
glRotatef(90, 1, 0, 0);
TaperedCylinder(0, 12.5, 0, 20);
TaperedCylinder(15, 12.5, 12.5, 20);
glTranslatef(0, 15, 0);
TaperedCylinder(0, 12.5, 9.5, 20);
TaperedCylinder(3, 9.5, 9.5, 20);
glTranslatef(0, 3, 0);
TaperedCylinder(0, 9.5, 12.5, 20);
TaperedCylinder(30, 12.5, 12.5, 20);
glTranslatef(0, 30, 0);
TaperedCylinder(0, 12.5, 9.5, 20);
TaperedCylinder(2, 9.5, 9.5, 20);
glTranslatef(0, 2, 0);
TaperedCylinder(0, 9.5, 12.5, 20);
TaperedCylinder(4, 12.5, 12.5, 20);
glTranslatef(0, 4, 0);
TaperedCylinder(0, 12.5, 9.5, 20);
TaperedCylinder(5, 9.5, 9.5, 20);
glTranslatef(0, 5, 0);
TaperedCylinder(0, 9.5, 12.5, 20);
TaperedCylinder(4, 12.5, 12.5, 20);
glTranslatef(0, 4, 0);
TaperedCylinder(0, 12.5, 9.5, 20);
TaperedCylinder(2, 9.5, 9.5, 20);
glTranslatef(0, 2, 0);
TaperedCylinder(0, 9.5, 12.5, 20);
glPushMatrix();
glTranslatef(0, 5, 0);
mat_ambient[0] = 1.0;
mat_ambient[1] = 0.0;
mat_ambient[2] = 0.0;
mat_diffuse[0] = 0.8;
mat_diffuse[1] = 0.0;
mat_diffuse[2] = 0.0;
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
TaperedCylinder(5, 12.6, 12.6, 20);
mat_ambient[0] = 0.0;
mat_ambient[1] = 0.0;
mat_ambient[2] = 1.0;
mat_diffuse[0] = 0.0;
mat_diffuse[1] = 0.0;
mat_diffuse[2] = 1.0;
glMaterialfv(GL_FRONT, GL_AMBIENT, mat_ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, mat_diffuse);
glPopMatrix();
TaperedCylinder(15, 12.5, 12.5, 20);
glTranslatef(0, 15, 0);
TaperedCylinder(0, 12.5, 9.5, 20);
glTranslatef(0, -2, 0);
TaperedCylinder(0, 9.5, 0, 20);
TaperedCylinder(2, 9.5, 9.5, 20);
glPopMatrix();
} // else statement
} // DrawBody