netgen/libsrc/csg/brick.cpp

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2009-01-13 04:40:13 +05:00
#include <mystdlib.h>
#include <linalg.hpp>
#include <csg.hpp>
namespace netgen
{
Parallelogram3d :: Parallelogram3d (Point<3> ap1, Point<3> ap2, Point<3> ap3)
{
p1 = ap1;
p2 = ap2;
p3 = ap3;
CalcData();
}
Parallelogram3d ::~Parallelogram3d ()
{
;
}
void Parallelogram3d :: SetPoints (Point<3> ap1,
Point<3> ap2,
Point<3> ap3)
{
p1 = ap1;
p2 = ap2;
p3 = ap3;
CalcData();
}
void Parallelogram3d :: CalcData()
{
v12 = p2 - p1;
v13 = p3 - p1;
p4 = p2 + v13;
n = Cross (v12, v13);
n.Normalize();
}
int Parallelogram3d ::
IsIdentic (const Surface & s2, int & inv, double eps) const
{
int id =
(fabs (s2.CalcFunctionValue (p1)) <= eps) &&
(fabs (s2.CalcFunctionValue (p2)) <= eps) &&
(fabs (s2.CalcFunctionValue (p3)) <= eps);
if (id)
{
Vec<3> n2;
n2 = s2.GetNormalVector(p1);
inv = (n * n2) < 0;
}
return id;
}
double Parallelogram3d :: CalcFunctionValue (const Point<3> & point) const
{
return n * (point - p1);
}
void Parallelogram3d :: CalcGradient (const Point<3> & /* point */,
Vec<3> & grad) const
{
grad = n;
}
void Parallelogram3d :: CalcHesse (const Point<3> & /* point */, Mat<3> & hesse) const
{
hesse = 0;
}
double Parallelogram3d :: HesseNorm () const
{
return 0;
}
Point<3> Parallelogram3d :: GetSurfacePoint () const
{
return p1;
}
void Parallelogram3d :: Print (ostream & str) const
{
str << "Parallelogram3d " << p1 << " - " << p2 << " - " << p3 << endl;
}
void Parallelogram3d ::
GetTriangleApproximation (TriangleApproximation & tas,
const Box<3> & /* bbox */,
double /* facets */) const
{
tas.AddPoint (p1);
tas.AddPoint (p2);
tas.AddPoint (p3);
tas.AddPoint (p4);
tas.AddTriangle (TATriangle (0, 0, 1, 2));
tas.AddTriangle (TATriangle (0, 2, 1, 3));
}
Brick :: Brick (Point<3> ap1, Point<3> ap2,
Point<3> ap3, Point<3> ap4)
{
faces.SetSize (6);
surfaceids.SetSize (6);
surfaceactive.SetSize(6);
p1 = ap1; p2 = ap2;
p3 = ap3; p4 = ap4;
for (int i = 0; i < 6; i++)
{
faces[i] = new Plane (Point<3>(0,0,0), Vec<3> (0,0,1));
surfaceactive[i] = 1;
}
CalcData();
}
Brick :: ~Brick ()
{
for (int i = 0; i < 6; i++)
delete faces[i];
}
Primitive * Brick :: CreateDefault ()
{
return new Brick (Point<3> (0,0,0),
Point<3> (1,0,0),
Point<3> (0,1,0),
Point<3> (0,0,1));
}
Primitive * Brick :: Copy () const
{
return new Brick (p1, p2, p3, p4);
}
void Brick :: Transform (Transformation<3> & trans)
{
trans.Transform (p1);
trans.Transform (p2);
trans.Transform (p3);
trans.Transform (p4);
CalcData();
}
INSOLID_TYPE Brick :: BoxInSolid (const BoxSphere<3> & box) const
{
/*
int i;
double maxval;
for (i = 1; i <= 6; i++)
{
double val = faces.Get(i)->CalcFunctionValue (box.Center());
if (i == 1 || val > maxval)
maxval = val;
}
if (maxval > box.Diam()) return IS_OUTSIDE;
if (maxval < -box.Diam()) return IS_INSIDE;
return DOES_INTERSECT;
*/
bool inside = 1;
bool outside = 0;
Point<3> p[8];
for (int j = 0; j < 8; j++)
p[j] = box.GetPointNr(j);
for (int i = 0; i < 6; i++)
{
bool outsidei = 1;
for (int j = 0; j < 8; j++)
{
// Point<3> p = box.GetPointNr (j);
double val = faces[i]->Plane::CalcFunctionValue (p[j]);
if (val > 0) inside = 0;
if (val < 0) outsidei = 0;
}
if (outsidei) outside = 1;
}
if (outside) return IS_OUTSIDE;
if (inside) return IS_INSIDE;
return DOES_INTERSECT;
}
INSOLID_TYPE Brick :: PointInSolid (const Point<3> & p,
double eps) const
{
double maxval = faces[0] -> Plane::CalcFunctionValue (p);
for (int i = 1; i < 6; i++)
{
double val = faces[i] -> Plane::CalcFunctionValue (p);
if (val > maxval) maxval = val;
}
if (maxval > eps) return IS_OUTSIDE;
if (maxval < -eps) return IS_INSIDE;
return DOES_INTERSECT;
}
INSOLID_TYPE Brick :: VecInSolid (const Point<3> & p,
const Vec<3> & v,
double eps) const
{
INSOLID_TYPE result = IS_INSIDE;
for (int i = 0; i < faces.Size(); i++)
{
INSOLID_TYPE hres = faces[i]->VecInSolid(p, v, eps);
if (hres == IS_OUTSIDE || result == IS_OUTSIDE) result = IS_OUTSIDE;
else if (hres == DOES_INTERSECT || result == DOES_INTERSECT) result = DOES_INTERSECT;
else result = IS_INSIDE;
}
return result;
/*
INSOLID_TYPE is = IS_INSIDE;
Vec<3> grad;
double scal;
for (int i = 0; i < faces.Size(); i++)
{
if (faces[i] -> PointOnSurface (p, eps))
{
GetSurface(i).CalcGradient (p, grad);
scal = v * grad;
if (scal >= eps)
is = IS_OUTSIDE;
if (scal >= -eps && is == IS_INSIDE)
is = DOES_INTERSECT;
}
}
return is;
*/
/*
Point<3> p2 = p + 1e-2 * v;
return PointInSolid (p2, eps);
*/
}
INSOLID_TYPE Brick :: VecInSolid2 (const Point<3> & p,
const Vec<3> & v1,
const Vec<3> & v2,
double eps) const
{
INSOLID_TYPE result = IS_INSIDE;
for (int i = 0; i < faces.Size(); i++)
{
INSOLID_TYPE hres = faces[i]->VecInSolid2(p, v1, v2, eps);
if (hres == IS_OUTSIDE || result == IS_OUTSIDE) result = IS_OUTSIDE;
else if (hres == DOES_INTERSECT || result == DOES_INTERSECT) result = DOES_INTERSECT;
else result = IS_INSIDE;
}
return result;
}
INSOLID_TYPE Brick :: VecInSolid3 (const Point<3> & p,
const Vec<3> & v1,
const Vec<3> & v2,
double eps) const
{
INSOLID_TYPE result = IS_INSIDE;
for (int i = 0; i < faces.Size(); i++)
{
INSOLID_TYPE hres = faces[i]->VecInSolid3(p, v1, v2, eps);
if (hres == IS_OUTSIDE || result == IS_OUTSIDE) result = IS_OUTSIDE;
else if (hres == DOES_INTERSECT || result == DOES_INTERSECT) result = DOES_INTERSECT;
else result = IS_INSIDE;
}
return result;
}
INSOLID_TYPE Brick :: VecInSolid4 (const Point<3> & p,
const Vec<3> & v,
const Vec<3> & v2,
const Vec<3> & m,
double eps) const
{
INSOLID_TYPE result = IS_INSIDE;
for (int i = 0; i < faces.Size(); i++)
{
INSOLID_TYPE hres = faces[i]->VecInSolid4(p, v, v2, m, eps);
if (hres == IS_OUTSIDE || result == IS_OUTSIDE) result = IS_OUTSIDE;
else if (hres == DOES_INTERSECT || result == DOES_INTERSECT) result = DOES_INTERSECT;
else result = IS_INSIDE;
}
return result;
}
void Brick ::
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GetPrimitiveData (const char *& classname, Array<double> & coeffs) const
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{
classname = "brick";
coeffs.SetSize(12);
coeffs.Elem(1) = p1(0);
coeffs.Elem(2) = p1(1);
coeffs.Elem(3) = p1(2);
coeffs.Elem(4) = p2(0);
coeffs.Elem(5) = p2(1);
coeffs.Elem(6) = p2(2);
coeffs.Elem(7) = p3(0);
coeffs.Elem(8) = p3(1);
coeffs.Elem(9) = p3(2);
coeffs.Elem(10) = p4(0);
coeffs.Elem(11) = p4(1);
coeffs.Elem(12) = p4(2);
}
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void Brick :: SetPrimitiveData (Array<double> & coeffs)
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{
p1(0) = coeffs.Elem(1);
p1(1) = coeffs.Elem(2);
p1(2) = coeffs.Elem(3);
p2(0) = coeffs.Elem(4);
p2(1) = coeffs.Elem(5);
p2(2) = coeffs.Elem(6);
p3(0) = coeffs.Elem(7);
p3(1) = coeffs.Elem(8);
p3(2) = coeffs.Elem(9);
p4(0) = coeffs.Elem(10);
p4(1) = coeffs.Elem(11);
p4(2) = coeffs.Elem(12);
CalcData();
}
void Brick :: CalcData()
{
v12 = p2 - p1;
v13 = p3 - p1;
v14 = p4 - p1;
Point<3> pi[8];
int i1, i2, i3;
int i, j;
i = 0;
for (i3 = 0; i3 <= 1; i3++)
for (i2 = 0; i2 <= 1; i2++)
for (i1 = 0; i1 <= 1; i1++)
{
pi[i] = p1 + i1 * v12 + i2 * v13 + i3 * v14;
i++;
}
static int lface[6][4] =
{ { 1, 3, 2, 4 },
{ 5, 6, 7, 8 },
{ 1, 2, 5, 6 },
{ 3, 7, 4, 8 },
{ 1, 5, 3, 7 },
{ 2, 4, 6, 8 } };
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Array<double> data(6);
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for (i = 0; i < 6; i++)
{
const Point<3> lp1 = pi[lface[i][0]-1];
const Point<3> lp2 = pi[lface[i][1]-1];
const Point<3> lp3 = pi[lface[i][2]-1];
Vec<3> n = Cross ((lp2-lp1), (lp3-lp1));
n.Normalize();
for (j = 0; j < 3; j++)
{
data[j] = lp1(j);
data[j+3] = n(j);
}
faces[i] -> SetPrimitiveData (data);
/*
{
faces.Elem(i+1) -> SetPoints
(pi[lface[i][0]-1],
pi[lface[i][1]-1],
pi[lface[i][2]-1]);
}
*/
}
}
void Brick :: Reduce (const BoxSphere<3> & box)
{
double val;
// Point<3> p;
Point<3> p[8];
for(int j=0;j<8;j++)
p[j]=box.GetPointNr(j);
for (int i = 0; i < 6; i++)
{
bool hasout = 0;
bool hasin = 0;
for (int j = 0; j < 8; j++)
{
// p = box.GetPointNr (j);
val = faces[i]->Plane::CalcFunctionValue (p[j]);
if (val > 0) hasout = 1;
else if (val < 0) hasin = 1;
if (hasout && hasin) break;
}
surfaceactive[i] = hasout && hasin;
}
}
void Brick :: UnReduce ()
{
for (int i = 0; i < 6; i++)
surfaceactive[i] = 1;
}
OrthoBrick :: OrthoBrick (const Point<3> & ap1, const Point<3> & ap2)
: Brick (ap1,
Point<3> (ap2(0), ap1(1), ap1(2)),
Point<3> (ap1(0), ap2(1), ap1(2)),
Point<3> (ap1(0), ap1(1), ap2(2)))
{
pmin = ap1;
pmax = ap2;
}
INSOLID_TYPE OrthoBrick :: BoxInSolid (const BoxSphere<3> & box) const
{
if (pmin(0) > box.PMax()(0) ||
pmin(1) > box.PMax()(1) ||
pmin(2) > box.PMax()(2) ||
pmax(0) < box.PMin()(0) ||
pmax(1) < box.PMin()(1) ||
pmax(2) < box.PMin()(2))
return IS_OUTSIDE;
if (pmin(0) < box.PMin()(0) &&
pmin(1) < box.PMin()(1) &&
pmin(2) < box.PMin()(2) &&
pmax(0) > box.PMax()(0) &&
pmax(1) > box.PMax()(1) &&
pmax(2) > box.PMax()(2))
return IS_INSIDE;
return DOES_INTERSECT;
}
void OrthoBrick :: Reduce (const BoxSphere<3> & box)
{
surfaceactive.Elem(1) =
(box.PMin()(2) < pmin(2)) && (pmin(2) < box.PMax()(2));
surfaceactive.Elem(2) =
(box.PMin()(2) < pmax(2)) && (pmax(2) < box.PMax()(2));
surfaceactive.Elem(3) =
(box.PMin()(1) < pmin(1)) && (pmin(1) < box.PMax()(1));
surfaceactive.Elem(4) =
(box.PMin()(1) < pmax(1)) && (pmax(1) < box.PMax()(1));
surfaceactive.Elem(5) =
(box.PMin()(0) < pmin(0)) && (pmin(0) < box.PMax()(0));
surfaceactive.Elem(6) =
(box.PMin()(0) < pmax(0)) && (pmax(0) < box.PMax()(0));
}
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RegisterClassForArchive<Parallelogram3d, Surface> regpar;
RegisterClassForArchive<Brick, Primitive> regbrick;
RegisterClassForArchive<OrthoBrick, Brick> regob;
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}