// file : common/inverse/test.hxx // copyright : Copyright (c) 2009-2015 Code Synthesis Tools CC // license : GNU GPL v2; see accompanying LICENSE file #ifndef TEST_HXX #define TEST_HXX #include // HAVE_CXX11, HAVE_TR1_MEMORY #include #include #include #include #include #if !defined(HAVE_CXX11) && defined(HAVE_TR1_MEMORY) # include #endif // Test raw pointers. // #pragma db namespace table("t1_") namespace test1 { struct obj1; struct obj2; struct obj3; struct obj4; struct obj5; typedef obj1* obj1_ptr; typedef obj2* obj2_ptr; typedef obj3* obj3_ptr; typedef obj4* obj4_ptr; typedef obj5* obj5_ptr; typedef std::set obj1_ptr_set; typedef std::set obj3_ptr_set; typedef std::set obj5_ptr_set; #pragma db object struct obj1 { obj1 (): o2 (0), o4 (0) {} ~obj1 (); #pragma db id std::string id; obj2_ptr o2; #pragma db id_column("obj1_id") value_column("obj3_id") obj3_ptr_set o3; obj4_ptr o4; obj5_ptr_set o5; }; #pragma db object struct obj2 { #pragma db id auto int id; // one-to-one // #pragma db inverse(o2) obj1_ptr o1; std::string str; }; #pragma db object struct obj3 { std::string str; // one(i)-to-many // #pragma db inverse (o3) obj1_ptr o1; #pragma db id auto int id; }; #pragma db object struct obj4 { #pragma db id auto int id; std::string str; // many(i)-to-one // #pragma db inverse (o4) obj1_ptr_set o1; }; #pragma db object struct obj5 { #pragma db id auto int id; std::string str; // many(i)-to-many // #pragma db inverse (o5) obj1_ptr_set o1; }; inline obj1:: ~obj1 () { delete o2; for (obj3_ptr_set::iterator i (o3.begin ()); i != o3.end (); ++i) delete *i; delete o4; for (obj5_ptr_set::iterator i (o5.begin ()); i != o5.end (); ++i) delete *i; } } // Test shared_ptr/weak_ptr. // #if defined(HAVE_CXX11) || defined(HAVE_TR1_MEMORY) #pragma db namespace table("t2_") namespace test2 { #ifdef HAVE_CXX11 using std::shared_ptr; using std::weak_ptr; #else using std::tr1::shared_ptr; using std::tr1::weak_ptr; #endif struct obj1; struct obj2; struct obj3; struct obj4; struct obj5; typedef shared_ptr obj1_ptr; typedef shared_ptr obj2_ptr; typedef shared_ptr obj3_ptr; typedef shared_ptr obj4_ptr; typedef shared_ptr obj5_ptr; typedef weak_ptr obj1_wptr; typedef std::vector obj1_wptr_vec; typedef std::vector obj3_ptr_vec; typedef std::vector obj5_ptr_vec; #pragma db object pointer(obj1_ptr) struct obj1 { #pragma db id std::string id; obj2_ptr o2; #pragma db id_column("obj1_id") value_column("obj3_id") obj3_ptr_vec o3; obj4_ptr o4; obj5_ptr_vec o5; }; #pragma db object pointer(obj2_ptr) struct obj2 { #pragma db id auto int id; std::string str; // one(i)-to-one // #pragma db inverse(o2) obj1_wptr o1; }; #pragma db object pointer(obj3_ptr) struct obj3 { #pragma db id auto int id; std::string str; // one(i)-to-many // #pragma db inverse (o3) obj1_wptr o1; }; #pragma db object pointer(obj4_ptr) struct obj4 { #pragma db id auto int id; std::string str; // many(i)-to-one // #pragma db inverse (o4) obj1_wptr_vec o1; }; #pragma db object pointer(obj5_ptr) struct obj5 { #pragma db id auto int id; std::string str; // many(i)-to-many // #pragma db inverse (o5) obj1_wptr_vec o1; }; } #endif // Test inverse based on points_to. // #pragma db namespace table("t3_") namespace test3 { // Inverse pointer. // #pragma db value struct comp { int i; int j; }; inline bool operator< (comp x, comp y) {return x.i < y.i || (x.i == y.i && x.j < y.j);} struct obj2; #pragma db object struct obj1 { #pragma db id comp id; #pragma db inverse(o1) obj2* o2; obj1 (int i = 0, int j = 0): o2 (0) {id.i = i; id.j = j;} ~obj1 (); }; #pragma db object struct obj2 { #pragma db id auto int id; #pragma db points_to(obj1) comp o1; #ifndef ODB_DATABASE_MYSQL #pragma db member(o1) on_delete(cascade) #endif }; inline obj1:: ~obj1 () {delete o2;} // Inverse container of pointers. // struct obj4; #pragma db object struct obj3 { #pragma db id auto int id; #pragma db inverse(o3) std::vector o4; ~obj3 (); }; #pragma db object struct obj4 { #pragma db id auto int id; #pragma db points_to(obj3) int o3; }; inline obj3:: ~obj3 () { for (std::vector::iterator i (o4.begin ()); i != o4.end (); ++i) delete *i; } }; // Test inverse with nested data members. // #pragma db namespace table("t4_") namespace test4 { // Inverse pointer. // struct obj1; struct obj2; #pragma db value struct obj2_id { #pragma db points_to(obj1) int i; int j; }; inline bool operator< (obj2_id x, obj2_id y) {return x.i < y.i || (x.i == y.i && x.j < y.j);} #pragma db object struct obj1 { #pragma db id auto int id; #pragma db inverse(id.i) obj2* o2; obj1 (): o2 (0) {} ~obj1 (); }; #pragma db object struct obj2 { #pragma db id obj2_id id; }; inline obj1:: ~obj1 () {delete o2;} // Inverse container of pointers. // struct obj3; struct obj4; #pragma db value struct obj4_id { #pragma db points_to(obj3) int i; int j; }; inline bool operator< (obj4_id x, obj4_id y) {return x.i < y.i || (x.i == y.i && x.j < y.j);} #pragma db object struct obj3 { #pragma db id auto int id; #pragma db inverse(id.i) std::vector o4; ~obj3 (); }; #pragma db object struct obj4 { #pragma db id obj4_id id; }; inline obj3:: ~obj3 () { for (std::vector::iterator i (o4.begin ()); i != o4.end (); ++i) delete *i; } }; #endif // TEST_HXX