//@ compile-flags:-g // === GDB TESTS =================================================================================== // gdb-command:set print union on // gdb-command:run // gdb-command:print case1 // gdb-check:$1 = generic_tuple_style_enum::Regular::Case1(0, 31868, 31868, 31868, 31868) // gdb-command:print case2 // gdb-check:$2 = generic_tuple_style_enum::Regular::Case2(0, 286331153, 286331153) // gdb-command:print case3 // gdb-check:$3 = generic_tuple_style_enum::Regular::Case3(0, 6438275382588823897) // gdb-command:print univariant // gdb-check:$4 = generic_tuple_style_enum::Univariant::TheOnlyCase(-1) // === LLDB TESTS ================================================================================== // lldb-command:run // lldb-command:v case1 // lldb-command:v case2 // lldb-command:v case3 // lldb-command:v univariant #![feature(omit_gdb_pretty_printer_section)] #![omit_gdb_pretty_printer_section] use self::Regular::{Case1, Case2, Case3}; use self::Univariant::TheOnlyCase; // NOTE: This is a copy of the non-generic test case. The `Txx` type parameters have to be // substituted with something of size `xx` bits and the same alignment as an integer type of the // same size. // The first element is to ensure proper alignment, irrespective of the machines word size. Since // the size of the discriminant value is machine dependent, this has be taken into account when // datatype layout should be predictable as in this case. enum Regular { Case1(T64, T16, T16, T16, T16), Case2(T64, T32, T32), Case3(T64, T64) } enum Univariant { TheOnlyCase(T64) } fn main() { // In order to avoid endianness trouble all of the following test values consist of a single // repeated byte. This way each interpretation of the union should look the same, no matter if // this is a big or little endian machine. // 0b0111110001111100011111000111110001111100011111000111110001111100 = 8970181431921507452 // 0b01111100011111000111110001111100 = 2088533116 // 0b0111110001111100 = 31868 // 0b01111100 = 124 let case1: Regular = Case1(0_u64, 31868_u16, 31868_u16, 31868_u16, 31868_u16); // 0b0001000100010001000100010001000100010001000100010001000100010001 = 1229782938247303441 // 0b00010001000100010001000100010001 = 286331153 // 0b0001000100010001 = 4369 // 0b00010001 = 17 let case2: Regular = Case2(0_i64, 286331153_i32, 286331153_i32); // 0b0101100101011001010110010101100101011001010110010101100101011001 = 6438275382588823897 // 0b01011001010110010101100101011001 = 1499027801 // 0b0101100101011001 = 22873 // 0b01011001 = 89 let case3: Regular = Case3(0_i64, 6438275382588823897_i64); let univariant = TheOnlyCase(-1_i64); zzz(); // #break } fn zzz() { () }