tests/debuginfo/unique-enum.rs - toolchain/rustc - Git at Google

 //@ min-lldb-version: 1800

 //@ compile-flags:-g

 // === GDB TESTS ===================================================================================

 // gdb-command:run

 // gdb-command:print *the_a
 // gdb-check:$1 = unique_enum::ABC::TheA{x: 0, y: 8970181431921507452}

 // gdb-command:print *the_b
 // gdb-check:$2 = unique_enum::ABC::TheB(0, 286331153, 286331153)

 // gdb-command:print *univariant
 // gdb-check:$3 = unique_enum::Univariant::TheOnlyCase(123234)


 // === LLDB TESTS ==================================================================================

 // lldb-command:run

 // lldb-command:v *the_a
 // lldb-check:(unique_enum::ABC) *the_a = { value = { x = 0 y = 8970181431921507452 } $discr$ = 0 }

 // lldb-command:v *the_b
 // lldb-check:(unique_enum::ABC) *the_b = { value = { 0 = 0 1 = 286331153 2 = 286331153 } $discr$ = 1 }

 // lldb-command:v *univariant
 // lldb-check:(unique_enum::Univariant) *univariant = { value = { 0 = 123234 } }

 #![allow(unused_variables)]
 #![feature(omit_gdb_pretty_printer_section)]
 #![omit_gdb_pretty_printer_section]

 // 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 ABC {
     TheA { x: i64, y: i64 },
     TheB (i64, i32, i32),
 }

 // This is a special case since it does not have the implicit discriminant field.
 enum Univariant {
     TheOnlyCase(i64)
 }

 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 the_a: Box<_> = Box::new(ABC::TheA { x: 0, y: 8970181431921507452 });

     // 0b0001000100010001000100010001000100010001000100010001000100010001 = 1229782938247303441
     // 0b00010001000100010001000100010001 = 286331153
     // 0b0001000100010001 = 4369
     // 0b00010001 = 17
     let the_b: Box<_> = Box::new(ABC::TheB (0, 286331153, 286331153));

     let univariant: Box<_> = Box::new(Univariant::TheOnlyCase(123234));

     zzz(); // #break
 }

 fn zzz() {()}
	//@ min-lldb-version: 1800

	//@ compile-flags:-g

	// === GDB TESTS ===================================================================================

	// gdb-command:run

	// gdb-command:print *the_a
	// gdb-check:$1 = unique_enum::ABC::TheA{x: 0, y: 8970181431921507452}

	// gdb-command:print *the_b
	// gdb-check:$2 = unique_enum::ABC::TheB(0, 286331153, 286331153)

	// gdb-command:print *univariant
	// gdb-check:$3 = unique_enum::Univariant::TheOnlyCase(123234)


	// === LLDB TESTS ==================================================================================

	// lldb-command:run

	// lldb-command:v *the_a
	// lldb-check:(unique_enum::ABC) *the_a = { value = { x = 0 y = 8970181431921507452 } $discr$ = 0 }

	// lldb-command:v *the_b
	// lldb-check:(unique_enum::ABC) *the_b = { value = { 0 = 0 1 = 286331153 2 = 286331153 } $discr$ = 1 }

	// lldb-command:v *univariant
	// lldb-check:(unique_enum::Univariant) *univariant = { value = { 0 = 123234 } }

	#![allow(unused_variables)]
	#![feature(omit_gdb_pretty_printer_section)]
	#![omit_gdb_pretty_printer_section]

	// 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 ABC {
	TheA { x: i64, y: i64 },
	TheB (i64, i32, i32),
	}

	// This is a special case since it does not have the implicit discriminant field.
	enum Univariant {
	TheOnlyCase(i64)
	}

	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 the_a: Box<_> = Box::new(ABC::TheA { x: 0, y: 8970181431921507452 });

	// 0b0001000100010001000100010001000100010001000100010001000100010001 = 1229782938247303441
	// 0b00010001000100010001000100010001 = 286331153
	// 0b0001000100010001 = 4369
	// 0b00010001 = 17
	let the_b: Box<_> = Box::new(ABC::TheB (0, 286331153, 286331153));

	let univariant: Box<_> = Box::new(Univariant::TheOnlyCase(123234));

	zzz(); // #break
	}

	fn zzz() {()}