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// file : cxx/tree/complex/ctor/driver.cxx
// license : GNU GPL v2 + exceptions; see accompanying LICENSE file
// Test generation of varous complex type constructors.
//
#include <memory>
#include "test.hxx"
#ifdef XSD_CXX11
# include <utility> // std::move
# define XSD_MOVE(x) std::move(x)
#else
# define XSD_MOVE(x) x
#endif
#undef NDEBUG
#include <cassert>
using namespace std;
using namespace test;
int
main ()
{
// Test case A.
//
{
a_base b1;
a_base b2 ("abc"); // empty ultimate base + required
a_base b3 ("abc", "foo"); // ultimate base + required
a_derived a1;
a_derived a2 ("foo", "bar"); // empty ultimate base + required
a_derived a3 (b3, "bar"); // base + required
a_derived a4 ("abc", "foo", "bar"); // ultimate base + required
}
// Test case B.
//
{
b_simple s ("base");
b_base b ("base", "foo");
b_derived d ("base", "foo", "bar");
b_type t ("base");
}
// Test case C.
//
{
c_simple s (c_enum::a);
c_base b (c_enum::a, "foo");
c_derived d (c_enum::a, "foo", "bar");
c_type t (c_enum::a);
}
// Test case D.
//
{
d_simple s (1);
d_base b (1, "foo");
d_derived d (1, "foo", "bar");
d_type t (1);
}
// Test case E.
//
{
// e_base
//
e_base b1 (1, "foo", e_complex_type ("bar"));
XSD_AUTO_PTR<e_complex_type> c2 (new e_complex_type ("bar"));
e_base b2 (1, "foo", XSD_MOVE (c2));
XSD_AUTO_PTR<e_simple_type> s3 (new e_simple_type ("foo"));
XSD_AUTO_PTR<e_complex_type> c3 (new e_complex_type ("bar"));
e_base b3 (1, XSD_MOVE (s3), XSD_MOVE (c3));
assert (b1 == b2);
assert (b1 == b3);
// e_derived
//
e_derived d1 (1, "foo", e_complex_type ("bar"),
true, "baz", e_complex_type ("biz"));
XSD_AUTO_PTR<e_complex_type> c2a (new e_complex_type ("bar"));
XSD_AUTO_PTR<e_complex_type> c2b (new e_complex_type ("biz"));
e_derived d2 (1, "foo", XSD_MOVE (c2a), true, "baz", XSD_MOVE (c2b));
XSD_AUTO_PTR<e_simple_type> s3a (new e_simple_type ("foo"));
XSD_AUTO_PTR<xml_schema::string> s3b (new xml_schema::string ("baz"));
XSD_AUTO_PTR<e_complex_type> c3a (new e_complex_type ("bar"));
XSD_AUTO_PTR<e_complex_type> c3b (new e_complex_type ("biz"));
e_derived d3 (1,
XSD_MOVE (s3a),
XSD_MOVE (c3a),
true,
XSD_MOVE (s3b),
XSD_MOVE (c3b));
assert (d1 == d2);
assert (d1 == d3);
}
// Test case F.
//
{
f_type f1 (xml_schema::type (), 1, "foo", f_complex_type ("bar"));
XSD_AUTO_PTR<f_complex_type> c2 (new f_complex_type ("bar"));
f_type f2 (1, "foo", XSD_MOVE (c2));
XSD_AUTO_PTR<f_simple_type> s3 (new f_simple_type ("foo"));
XSD_AUTO_PTR<f_complex_type> c3 (new f_complex_type ("bar"));
f_type f3 (1, XSD_MOVE (s3), XSD_MOVE (c3));
assert (f1 == f2);
assert (f1 == f3);
}
}
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