static PyObject*
cshockCapturingCalculateNumericalDiffusionJaffre(PyObject* self,
PyObject* args)
{
double shockCapturingFactor,beta;
PyObject *elementDiameter,*strongResidual,*grad_u,*numDiff;
if(!PyArg_ParseTuple(args,"ddOOOO",
&shockCapturingFactor,
&beta,
&elementDiameter,
&strongResidual,
&grad_u,
&numDiff))
return NULL;
calculateNumericalDiffusionJaffre(SHAPE(grad_u)[0],
SHAPE(grad_u)[1],
SHAPE(grad_u)[2],
shockCapturingFactor,
beta,
DDATA(elementDiameter),
DDATA(strongResidual),
DDATA(grad_u),
DDATA(numDiff));
Py_INCREF(Py_None);
return Py_None;
}
static PyObject*
cshockCapturingCalculateNumericalDiffusion_A_1(PyObject* self,
PyObject* args)
{
double shockCapturingFactor;
PyObject *elementDiameter,*strongResidual,*mt,*df,*numDiff;
if(!PyArg_ParseTuple(args,"dOOOOO",
&shockCapturingFactor,
&elementDiameter,
&strongResidual,
&mt,
&df,
&numDiff))
return NULL;
calculateNumericalDiffusion_A_1(SHAPE(df)[0],
SHAPE(df)[1],
SHAPE(df)[2],
shockCapturingFactor,
DDATA(elementDiameter),
DDATA(strongResidual),
DDATA(mt),
DDATA(df),
DDATA(numDiff));
Py_INCREF(Py_None);
return Py_None;
}
static PyObject* ctracking_getOuterNormals_affineSimplex(PyObject* self,
PyObject* args)
{
int nSpace;
PyObject *boundaryNormals,
*jacobianInverseArray,
*unitNormalArray;
if (!PyArg_ParseTuple(args,
"OOO",
&boundaryNormals,
&jacobianInverseArray,
&unitNormalArray))
return NULL;
nSpace = SHAPE(boundaryNormals)[0] -1;
if (nSpace == 1)
{
getOuterNormals_affineSimplex_1d(SHAPE(jacobianInverseArray)[0],
SHAPE(unitNormalArray)[1],
SHAPE(jacobianInverseArray)[1],
DDATA(boundaryNormals),
DDATA(jacobianInverseArray),
DDATA(unitNormalArray));
}
else if (nSpace == 2)
{
getOuterNormals_affineSimplex_2d(SHAPE(jacobianInverseArray)[0],
SHAPE(unitNormalArray)[1],
SHAPE(jacobianInverseArray)[1],
DDATA(boundaryNormals),
DDATA(jacobianInverseArray),
DDATA(unitNormalArray));
}
else
{
assert(nSpace == 3);
getOuterNormals_affineSimplex_3d(SHAPE(jacobianInverseArray)[0],
SHAPE(unitNormalArray)[1],
SHAPE(jacobianInverseArray)[1],
DDATA(boundaryNormals),
DDATA(jacobianInverseArray),
DDATA(unitNormalArray));
}
Py_INCREF(Py_None);
return Py_None;
}
static VALUE
rb_cpShapeSetLayers(VALUE self, VALUE layers)
{
SHAPE(self)->layers = NUM2UINT(layers);
return layers;
}
static VALUE
rb_cpShapeGetBB(VALUE self)
{
cpBB *bb = malloc(sizeof(cpBB));
*bb = SHAPE(self)->bb;
return Data_Wrap_Struct(c_cpBB, NULL, free, bb);
}
static VALUE
rb_cpShapeCacheBB(VALUE self)
{
cpShape *shape = SHAPE(self);
cpShapeCacheBB(shape);
return rb_cpShapeGetBB(self);
}
static VALUE
rb_cpShapeSetBody(VALUE self, VALUE body)
{
SHAPE(self)->body = BODY(body);
rb_ivar_set(self, id_body, body);
return body;
}
static VALUE
rb_cpShapeSetCollType(VALUE self, VALUE val)
{
VALUE col_type = rb_obj_id(val);
rb_iv_set(self, "collType", val);
SHAPE(self)->collision_type = NUM2UINT(col_type);
return val;
}
static VALUE
rb_cpShapeSetGroup(VALUE self, VALUE val)
{
VALUE col_type = rb_obj_id(val);
rb_iv_set(self, "group", val);
SHAPE(self)->group = NUM2UINT(col_type);
return val;
}
Recursor::Recursor(Vector2 pos, int c) : oldPos(pos), GameObject(pos,SHAPE(baseShape)) {
parent = NULL;
if (c > 0) {
child = new Recursor(pos + (Vector2(15,15) * (float)c * 1.7f), c - 1);
child->parent = this;
scale += (c*1.25f);
} else {
child = NULL;
}
}
static VALUE
rb_cpCircleInitialize(VALUE self, VALUE body, VALUE radius, VALUE offset)
{
cpCircleShape *circle = (cpCircleShape *)SHAPE(self);
cpCircleShapeInit(circle, BODY(body), NUM2DBL(radius), *VGET(offset));
circle->shape.data = (void *)self;
circle->shape.collision_type = Qnil;
rb_ivar_set(self, id_body, body);
return self;
}
static PyObject* ctracking_setNodeOnBoundaryArray(PyObject* self,
PyObject* args)
{
PyObject *exteriorElementBoundariesArray,
*elementBoundaryNodesArray,
*nodeOnBoundaryArray;
if (!PyArg_ParseTuple(args,
"OOO",
&exteriorElementBoundariesArray,
&elementBoundaryNodesArray,
&nodeOnBoundaryArray))
return NULL;
setNodeOnBoundaryArray(SHAPE(exteriorElementBoundariesArray)[0],
SHAPE(elementBoundaryNodesArray)[1],
IDATA(exteriorElementBoundariesArray),
IDATA(elementBoundaryNodesArray),
IDATA(nodeOnBoundaryArray));
Py_INCREF(Py_None);
return Py_None;
}
static VALUE
rb_cpSegmentInitialize(VALUE self, VALUE body, VALUE a, VALUE b, VALUE r)
{
cpSegmentShape *seg = (cpSegmentShape *)SHAPE(self);
cpSegmentShapeInit(seg, BODY(body), *VGET(a), *VGET(b), NUM2DBL(r));
seg->shape.data = (void *)self;
seg->shape.collision_type = Qnil;
rb_ivar_set(self, id_body, body);
return self;
}
static VALUE
rb_cpPolyInitialize(VALUE self, VALUE body, VALUE arr, VALUE offset)
{
cpPolyShape *poly = (cpPolyShape *)SHAPE(self);
Check_Type(arr, T_ARRAY);
int numVerts = RARRAY_LEN(arr);
VALUE *ary_ptr = RARRAY_PTR(arr);
cpVect verts[numVerts];
for(int i=0; i<numVerts; i++)
verts[i] = *VGET(ary_ptr[i]);
cpPolyShapeInit(poly, BODY(body), numVerts, verts, *VGET(offset));
poly->shape.data = (void *)self;
poly->shape.collision_type = Qnil;
rb_ivar_set(self, id_body, body);
return self;
}
static VALUE
rb_cpShapeGetElasticity(VALUE self)
{
return rb_float_new(SHAPE(self)->e);
}
static VALUE
rb_cpShapeGetFriction(VALUE self)
{
return rb_float_new(SHAPE(self)->u);
}
static VALUE
rb_cpShapeSetElasticity(VALUE self, VALUE val)
{
SHAPE(self)->e = NUM2DBL(val);
return val;
}
static VALUE
rb_cpShapeSetFriction(VALUE self, VALUE val)
{
SHAPE(self)->u = NUM2DBL(val);
return val;
}
static VALUE
rb_cpShapeGetLayers(VALUE self)
{
return UINT2NUM(SHAPE(self)->layers);
}
static VALUE
rb_cpShapeGetSurfaceV(VALUE self)
{
return VWRAP(self, &SHAPE(self)->surface_v);
}
static VALUE
rb_cpShapeSetSurfaceV(VALUE self, VALUE val)
{
SHAPE(self)->surface_v = *VGET(val);
return val;
}
