class Fox::FXSphered
Spherical bounds
Public Class Methods
Source
SWIGINTERN VALUE _wrap_new_FXSphered(int nargs, VALUE *args, VALUE self) {
int argc;
VALUE argv[4];
int ii;
argc = nargs;
if (argc > 4) SWIG_fail;
for (ii = 0; (ii < argc); ++ii) {
argv[ii] = args[ii];
}
if (argc == 0) {
return _wrap_new_FXSphered__SWIG_0(nargs, args, self);
}
if (argc == 1) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_new_FXSphered__SWIG_1(nargs, args, self);
}
}
if ((argc >= 1) && (argc <= 2)) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXVec3d, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
if (argc <= 1) {
return _wrap_new_FXSphered__SWIG_2(nargs, args, self);
}
{
int res = SWIG_AsVal_double(argv[1], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
return _wrap_new_FXSphered__SWIG_2(nargs, args, self);
}
}
}
if (argc == 1) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXRanged, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_new_FXSphered__SWIG_4(nargs, args, self);
}
}
if ((argc >= 3) && (argc <= 4)) {
int _v = 0;
{
int res = SWIG_AsVal_double(argv[0], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
{
int res = SWIG_AsVal_double(argv[1], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
{
int res = SWIG_AsVal_double(argv[2], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
if (argc <= 3) {
return _wrap_new_FXSphered__SWIG_3(nargs, args, self);
}
{
int res = SWIG_AsVal_double(argv[3], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
return _wrap_new_FXSphered__SWIG_3(nargs, args, self);
}
}
}
}
}
fail:
Ruby_Format_OverloadedError( argc, 4, "FXSphered.new",
" FXSphered.new()\n"
" FXSphered.new(FXSphered const &sphere)\n"
" FXSphered.new(FXVec3d const &cen, FXdouble rad)\n"
" FXSphered.new(FXdouble x, FXdouble y, FXdouble z, FXdouble rad)\n"
" FXSphered.new(FXRanged const &bounds)\n");
return Qnil;
}
Public Instance Methods
Source
SWIGINTERN VALUE
_wrap_FXSphered_center_get(int argc, VALUE *argv, VALUE self) {
FXSphered *arg1 = (FXSphered *) 0 ;
void *argp1 = 0 ;
int res1 = 0 ;
FXVec3d *result = 0 ;
VALUE vresult = Qnil;
if ((argc < 0) || (argc > 0)) {
rb_raise(rb_eArgError, "wrong # of arguments(%d for 0)",argc); SWIG_fail;
}
res1 = SWIG_ConvertPtr(self, &argp1,SWIGTYPE_p_FXSphered, 0 | 0 );
if (!SWIG_IsOK(res1)) {
SWIG_exception_fail(SWIG_ArgError(res1), Ruby_Format_TypeError( "", "FXSphered *","center", 1, self ));
}
arg1 = reinterpret_cast< FXSphered * >(argp1);
result = (FXVec3d *) & ((arg1)->center);
vresult = SWIG_NewPointerObj(SWIG_as_voidptr(result), SWIGTYPE_p_FXVec3d, 0 | 0 );
return vresult;
fail:
return Qnil;
}
Sphere center {FXVec3d}
Source
SWIGINTERN VALUE
_wrap_FXSphered_center_set(int argc, VALUE *argv, VALUE self) {
FXSphered *arg1 = (FXSphered *) 0 ;
FXVec3d *arg2 = 0 ;
void *argp1 = 0 ;
int res1 = 0 ;
void *argp2 = 0 ;
int res2 = 0 ;
if ((argc < 1) || (argc > 1)) {
rb_raise(rb_eArgError, "wrong # of arguments(%d for 1)",argc); SWIG_fail;
}
res1 = SWIG_ConvertPtr(self, &argp1,SWIGTYPE_p_FXSphered, 0 | 0 );
if (!SWIG_IsOK(res1)) {
SWIG_exception_fail(SWIG_ArgError(res1), Ruby_Format_TypeError( "", "FXSphered *","center", 1, self ));
}
arg1 = reinterpret_cast< FXSphered * >(argp1);
res2 = SWIG_ConvertPtr(argv[0], &argp2, SWIGTYPE_p_FXVec3d, 0 );
if (!SWIG_IsOK(res2)) {
SWIG_exception_fail(SWIG_ArgError(res2), Ruby_Format_TypeError( "", "FXVec3d const &","center", 2, argv[0] ));
}
if (!argp2) {
SWIG_exception_fail(SWIG_ValueError, Ruby_Format_TypeError("invalid null reference ", "FXVec3d const &","center", 2, argv[0]));
}
arg2 = reinterpret_cast< FXVec3d * >(argp2);
if (arg1) (arg1)->center = *arg2;
return Qnil;
fail:
return Qnil;
}
Sphere center {FXVec3d}
Source
SWIGINTERN VALUE _wrap_FXSphered_containsq___(int nargs, VALUE *args, VALUE self) {
int argc;
VALUE argv[5];
int ii;
argc = nargs + 1;
argv[0] = self;
if (argc > 5) SWIG_fail;
for (ii = 1; (ii < argc); ++ii) {
argv[ii] = args[ii-1];
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXVec3d, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_containsq_____SWIG_1(nargs, args, self);
}
}
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXRanged, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_containsq_____SWIG_2(nargs, args, self);
}
}
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXSphered, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_containsq_____SWIG_3(nargs, args, self);
}
}
}
if (argc == 4) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
{
int res = SWIG_AsVal_double(argv[1], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
{
int res = SWIG_AsVal_double(argv[2], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
{
int res = SWIG_AsVal_double(argv[3], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
return _wrap_FXSphered_containsq_____SWIG_0(nargs, args, self);
}
}
}
}
}
fail:
Ruby_Format_OverloadedError( argc, 5, "FXSphered.contains?",
" bool FXSphered.contains?(FXdouble x, FXdouble y, FXdouble z)\n"
" bool FXSphered.contains?(FXVec3d const &p)\n"
" bool FXSphered.contains?(FXRanged const &box)\n"
" bool FXSphered.contains?(FXSphered const &sphere)\n");
return Qnil;
}
Source
SWIGINTERN VALUE
_wrap_FXSphered_diameter(int argc, VALUE *argv, VALUE self) {
FXSphered *arg1 = (FXSphered *) 0 ;
void *argp1 = 0 ;
int res1 = 0 ;
FXdouble result;
VALUE vresult = Qnil;
if ((argc < 0) || (argc > 0)) {
rb_raise(rb_eArgError, "wrong # of arguments(%d for 0)",argc); SWIG_fail;
}
res1 = SWIG_ConvertPtr(self, &argp1,SWIGTYPE_p_FXSphered, 0 | 0 );
if (!SWIG_IsOK(res1)) {
SWIG_exception_fail(SWIG_ArgError(res1), Ruby_Format_TypeError( "", "FXSphered const *","diameter", 1, self ));
}
arg1 = reinterpret_cast< FXSphered * >(argp1);
result = (FXdouble)((FXSphered const *)arg1)->diameter();
vresult = SWIG_From_double(static_cast< double >(result));
return vresult;
fail:
return Qnil;
}
Source
SWIGINTERN VALUE
_wrap_FXSphered_emptyq___(int argc, VALUE *argv, VALUE self) {
FXSphered *arg1 = (FXSphered *) 0 ;
void *argp1 = 0 ;
int res1 = 0 ;
bool result;
VALUE vresult = Qnil;
if ((argc < 0) || (argc > 0)) {
rb_raise(rb_eArgError, "wrong # of arguments(%d for 0)",argc); SWIG_fail;
}
res1 = SWIG_ConvertPtr(self, &argp1,SWIGTYPE_p_FXSphered, 0 | 0 );
if (!SWIG_IsOK(res1)) {
SWIG_exception_fail(SWIG_ArgError(res1), Ruby_Format_TypeError( "", "FXSphered const *","empty", 1, self ));
}
arg1 = reinterpret_cast< FXSphered * >(argp1);
result = (bool)((FXSphered const *)arg1)->empty();
vresult = SWIG_From_bool(static_cast< bool >(result));
return vresult;
fail:
return Qnil;
}
Check if FXSphered is empty.
Source
SWIGINTERN VALUE _wrap_FXSphered_includeN___(int nargs, VALUE *args, VALUE self) {
int argc;
VALUE argv[5];
int ii;
argc = nargs + 1;
argv[0] = self;
if (argc > 5) SWIG_fail;
for (ii = 1; (ii < argc); ++ii) {
argv[ii] = args[ii-1];
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXVec3d, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_includeN_____SWIG_1(nargs, args, self);
}
}
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXRanged, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_includeN_____SWIG_2(nargs, args, self);
}
}
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXSphered, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_includeN_____SWIG_3(nargs, args, self);
}
}
}
if (argc == 4) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
{
int res = SWIG_AsVal_double(argv[1], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
{
int res = SWIG_AsVal_double(argv[2], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
{
int res = SWIG_AsVal_double(argv[3], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
return _wrap_FXSphered_includeN_____SWIG_0(nargs, args, self);
}
}
}
}
}
fail:
Ruby_Format_OverloadedError( argc, 5, "FXSphered.include!",
" FXSphered FXSphered.include!(FXdouble x, FXdouble y, FXdouble z)\n"
" FXSphered FXSphered.include!(FXVec3d const &p)\n"
" FXSphered FXSphered.include!(FXRanged const &box)\n"
" FXSphered & FXSphered.include!(FXSphered const &sphere)\n");
return Qnil;
}
Source
SWIGINTERN VALUE _wrap_FXSphered_includeInRadiusN___(int nargs, VALUE *args, VALUE self) {
int argc;
VALUE argv[5];
int ii;
argc = nargs + 1;
argv[0] = self;
if (argc > 5) SWIG_fail;
for (ii = 1; (ii < argc); ++ii) {
argv[ii] = args[ii-1];
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXVec3d, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_includeInRadiusN_____SWIG_1(nargs, args, self);
}
}
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXRanged, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_includeInRadiusN_____SWIG_2(nargs, args, self);
}
}
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXSphered, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_includeInRadiusN_____SWIG_3(nargs, args, self);
}
}
}
if (argc == 4) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
{
int res = SWIG_AsVal_double(argv[1], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
{
int res = SWIG_AsVal_double(argv[2], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
{
int res = SWIG_AsVal_double(argv[3], NULL);
_v = SWIG_CheckState(res);
}
if (_v) {
return _wrap_FXSphered_includeInRadiusN_____SWIG_0(nargs, args, self);
}
}
}
}
}
fail:
Ruby_Format_OverloadedError( argc, 5, "FXSphered.includeInRadius!",
" FXSphered FXSphered.includeInRadius!(FXdouble x, FXdouble y, FXdouble z)\n"
" FXSphered FXSphered.includeInRadius!(FXVec3d const &p)\n"
" FXSphered FXSphered.includeInRadius!(FXRanged const &box)\n"
" FXSphered & FXSphered.includeInRadius!(FXSphered const &sphere)\n");
return Qnil;
}
Source
SWIGINTERN VALUE
_wrap_FXSphered_intersect(int argc, VALUE *argv, VALUE self) {
FXSphered *arg1 = (FXSphered *) 0 ;
FXVec4d *arg2 = 0 ;
void *argp1 = 0 ;
int res1 = 0 ;
void *argp2 = 0 ;
int res2 = 0 ;
FXint result;
VALUE vresult = Qnil;
if ((argc < 1) || (argc > 1)) {
rb_raise(rb_eArgError, "wrong # of arguments(%d for 1)",argc); SWIG_fail;
}
res1 = SWIG_ConvertPtr(self, &argp1,SWIGTYPE_p_FXSphered, 0 | 0 );
if (!SWIG_IsOK(res1)) {
SWIG_exception_fail(SWIG_ArgError(res1), Ruby_Format_TypeError( "", "FXSphered const *","intersect", 1, self ));
}
arg1 = reinterpret_cast< FXSphered * >(argp1);
res2 = SWIG_ConvertPtr(argv[0], &argp2, SWIGTYPE_p_FXVec4d, 0 );
if (!SWIG_IsOK(res2)) {
SWIG_exception_fail(SWIG_ArgError(res2), Ruby_Format_TypeError( "", "FXVec4d const &","intersect", 2, argv[0] ));
}
if (!argp2) {
SWIG_exception_fail(SWIG_ValueError, Ruby_Format_TypeError("invalid null reference ", "FXVec4d const &","intersect", 2, argv[0]));
}
arg2 = reinterpret_cast< FXVec4d * >(argp2);
result = (FXint)((FXSphered const *)arg1)->intersect((FXVec4d const &)*arg2);
vresult = SWIG_From_int(static_cast< int >(result));
return vresult;
fail:
return Qnil;
}
Source
SWIGINTERN VALUE
_wrap_FXSphered_intersectsq___(int argc, VALUE *argv, VALUE self) {
FXSphered *arg1 = (FXSphered *) 0 ;
FXVec3d *arg2 = 0 ;
FXVec3d *arg3 = 0 ;
void *argp1 = 0 ;
int res1 = 0 ;
void *argp2 = 0 ;
int res2 = 0 ;
void *argp3 = 0 ;
int res3 = 0 ;
bool result;
VALUE vresult = Qnil;
if ((argc < 2) || (argc > 2)) {
rb_raise(rb_eArgError, "wrong # of arguments(%d for 2)",argc); SWIG_fail;
}
res1 = SWIG_ConvertPtr(self, &argp1,SWIGTYPE_p_FXSphered, 0 | 0 );
if (!SWIG_IsOK(res1)) {
SWIG_exception_fail(SWIG_ArgError(res1), Ruby_Format_TypeError( "", "FXSphered const *","intersect", 1, self ));
}
arg1 = reinterpret_cast< FXSphered * >(argp1);
res2 = SWIG_ConvertPtr(argv[0], &argp2, SWIGTYPE_p_FXVec3d, 0 );
if (!SWIG_IsOK(res2)) {
SWIG_exception_fail(SWIG_ArgError(res2), Ruby_Format_TypeError( "", "FXVec3d const &","intersect", 2, argv[0] ));
}
if (!argp2) {
SWIG_exception_fail(SWIG_ValueError, Ruby_Format_TypeError("invalid null reference ", "FXVec3d const &","intersect", 2, argv[0]));
}
arg2 = reinterpret_cast< FXVec3d * >(argp2);
res3 = SWIG_ConvertPtr(argv[1], &argp3, SWIGTYPE_p_FXVec3d, 0 );
if (!SWIG_IsOK(res3)) {
SWIG_exception_fail(SWIG_ArgError(res3), Ruby_Format_TypeError( "", "FXVec3d const &","intersect", 3, argv[1] ));
}
if (!argp3) {
SWIG_exception_fail(SWIG_ValueError, Ruby_Format_TypeError("invalid null reference ", "FXVec3d const &","intersect", 3, argv[1]));
}
arg3 = reinterpret_cast< FXVec3d * >(argp3);
result = (bool)((FXSphered const *)arg1)->intersect((FXVec3d const &)*arg2,(FXVec3d const &)*arg3);
vresult = SWIG_From_bool(static_cast< bool >(result));
return vresult;
fail:
return Qnil;
}
Source
SWIGINTERN VALUE _wrap_FXSphered_overlapsq___(int nargs, VALUE *args, VALUE self) {
int argc;
VALUE argv[3];
int ii;
argc = nargs + 1;
argv[0] = self;
if (argc > 3) SWIG_fail;
for (ii = 1; (ii < argc); ++ii) {
argv[ii] = args[ii-1];
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXRanged, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_overlapsq_____SWIG_0(nargs, args, self);
}
}
}
if (argc == 2) {
int _v = 0;
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[0], &vptr, SWIGTYPE_p_FXSphered, 0);
_v = SWIG_CheckState(res);
if (_v) {
void *vptr = 0;
int res = SWIG_ConvertPtr(argv[1], &vptr, SWIGTYPE_p_FXSphered, SWIG_POINTER_NO_NULL);
_v = SWIG_CheckState(res);
if (_v) {
return _wrap_FXSphered_overlapsq_____SWIG_1(nargs, args, self);
}
}
}
fail:
Ruby_Format_OverloadedError( argc, 3, "overlaps?",
" bool overlaps?(FXRanged const &other)\n"
" bool overlaps?(FXSphered const &other)\n");
return Qnil;
}
Source
SWIGINTERN VALUE
_wrap_FXSphered_radius_get(int argc, VALUE *argv, VALUE self) {
FXSphered *arg1 = (FXSphered *) 0 ;
void *argp1 = 0 ;
int res1 = 0 ;
FXdouble result;
VALUE vresult = Qnil;
if ((argc < 0) || (argc > 0)) {
rb_raise(rb_eArgError, "wrong # of arguments(%d for 0)",argc); SWIG_fail;
}
res1 = SWIG_ConvertPtr(self, &argp1,SWIGTYPE_p_FXSphered, 0 | 0 );
if (!SWIG_IsOK(res1)) {
SWIG_exception_fail(SWIG_ArgError(res1), Ruby_Format_TypeError( "", "FXSphered *","radius", 1, self ));
}
arg1 = reinterpret_cast< FXSphered * >(argp1);
result = (FXdouble) ((arg1)->radius);
vresult = SWIG_From_double(static_cast< double >(result));
return vresult;
fail:
return Qnil;
}
Sphere radius [Float]
Source
SWIGINTERN VALUE
_wrap_FXSphered_radius_set(int argc, VALUE *argv, VALUE self) {
FXSphered *arg1 = (FXSphered *) 0 ;
FXdouble arg2 ;
void *argp1 = 0 ;
int res1 = 0 ;
double val2 ;
int ecode2 = 0 ;
if ((argc < 1) || (argc > 1)) {
rb_raise(rb_eArgError, "wrong # of arguments(%d for 1)",argc); SWIG_fail;
}
res1 = SWIG_ConvertPtr(self, &argp1,SWIGTYPE_p_FXSphered, 0 | 0 );
if (!SWIG_IsOK(res1)) {
SWIG_exception_fail(SWIG_ArgError(res1), Ruby_Format_TypeError( "", "FXSphered *","radius", 1, self ));
}
arg1 = reinterpret_cast< FXSphered * >(argp1);
ecode2 = SWIG_AsVal_double(argv[0], &val2);
if (!SWIG_IsOK(ecode2)) {
SWIG_exception_fail(SWIG_ArgError(ecode2), Ruby_Format_TypeError( "", "FXdouble","radius", 2, argv[0] ));
}
arg2 = static_cast< FXdouble >(val2);
if (arg1) (arg1)->radius = arg2;
return Qnil;
fail:
return Qnil;
}
Sphere radius [Float]