const std = @import("std"); const builtin = @import("builtin"); const tests = @import("tests.zig"); const CrossTarget = std.zig.CrossTarget; pub fn addCases(cases: *tests.TranslateCContext) void { const default_enum_type = if (builtin.abi == .msvc) "c_int" else "c_uint"; cases.add("do while with breaks", \\void foo(int a) { \\ do { \\ if (a) break; \\ } while (4); \\ do { \\ if (a) break; \\ } while (0); \\ do { \\ if (a) break; \\ } while (a); \\ do { \\ break; \\ } while (3); \\ do { \\ break; \\ } while (0); \\ do { \\ break; \\ } while (a); \\} , &[_][]const u8{ \\pub export fn foo(arg_a: c_int) void { \\ var a = arg_a; \\ while (true) { \\ if (a != 0) break; \\ } \\ while (true) { \\ if (a != 0) break; \\ if (!false) break; \\ } \\ while (true) { \\ if (a != 0) break; \\ if (!(a != 0)) break; \\ } \\ while (true) { \\ break; \\ } \\ while (true) { \\ break; \\ } \\ while (true) { \\ break; \\ } \\} }); cases.add("variables check for opaque demotion", \\struct A { \\ _Atomic int a; \\} a; \\int main(void) { \\ struct A a; \\} , &[_][]const u8{ \\pub const struct_A = opaque {}; \\pub const a = @compileError("non-extern variable has opaque type"); , \\pub extern fn main() c_int; }); cases.add("field access is grouped if necessary", \\unsigned long foo(unsigned long x) { \\ return ((union{unsigned long _x}){x})._x; \\} , &[_][]const u8{ \\pub export fn foo(arg_x: c_ulong) c_ulong { \\ var x = arg_x; \\ const union_unnamed_1 = extern union { \\ _x: c_ulong, \\ }; \\ return (union_unnamed_1{ \\ ._x = x, \\ })._x; \\} }); cases.add("unnamed child types of typedef receive typedef's name", \\typedef enum { \\ FooA, \\ FooB, \\} Foo; \\typedef struct { \\ int a, b; \\} Bar; , &[_][]const u8{ \\pub const FooA: c_int = 0; \\pub const FooB: c_int = 1; \\pub const Foo = ++ " " ++ default_enum_type ++ \\; \\pub const Bar = extern struct { \\ a: c_int, \\ b: c_int, \\}; }); cases.add("if as while stmt has semicolon", \\void foo() { \\ while (1) if (1) { \\ int a = 1; \\ } else { \\ int b = 2; \\ } \\ if (1) if (1) {} \\} , &[_][]const u8{ \\pub export fn foo() void { \\ while (true) if (true) { \\ var a: c_int = 1; \\ _ = @TypeOf(a); \\ } else { \\ var b: c_int = 2; \\ _ = @TypeOf(b); \\ }; \\ if (true) if (true) {}; \\} }); cases.add("conditional operator cast to void", \\int bar(); \\void foo() { \\ int a; \\ a ? a = 2 : bar(); \\} , &[_][]const u8{ \\pub extern fn bar(...) c_int; \\pub export fn foo() void { \\ var a: c_int = undefined; \\ if (a != 0) a = 2 else _ = bar(); \\} }); cases.add("struct in struct init to zero", \\struct Foo { \\ int a; \\ struct Bar { \\ int a; \\ } b; \\} a = {}; \\#define PTR void * , &[_][]const u8{ \\pub const struct_Bar = extern struct { \\ a: c_int, \\}; \\pub const struct_Foo = extern struct { \\ a: c_int, \\ b: struct_Bar, \\}; \\pub export var a: struct_Foo = struct_Foo{ \\ .a = 0, \\ .b = @import("std").mem.zeroes(struct_Bar), \\}; , \\pub const PTR = ?*anyopaque; }); cases.add("scoped record", \\void foo() { \\ struct Foo { \\ int A; \\ int B; \\ int C; \\ }; \\ struct Foo a = {0}; \\ { \\ struct Foo { \\ int A; \\ int B; \\ int C; \\ }; \\ struct Foo a = {0}; \\ } \\} , &[_][]const u8{ \\pub export fn foo() void { \\ const struct_Foo = extern struct { \\ A: c_int, \\ B: c_int, \\ C: c_int, \\ }; \\ var a: struct_Foo = struct_Foo{ \\ .A = @as(c_int, 0), \\ .B = 0, \\ .C = 0, \\ }; \\ _ = @TypeOf(a); \\ { \\ const struct_Foo_1 = extern struct { \\ A: c_int, \\ B: c_int, \\ C: c_int, \\ }; \\ var a_2: struct_Foo_1 = struct_Foo_1{ \\ .A = @as(c_int, 0), \\ .B = 0, \\ .C = 0, \\ }; \\ _ = @TypeOf(a_2); \\ } \\} }); cases.add("scoped typedef", \\void foo() { \\ typedef union { \\ int A; \\ int B; \\ int C; \\ } Foo; \\ Foo a = {0}; \\ { \\ typedef union { \\ int A; \\ int B; \\ int C; \\ } Foo; \\ Foo a = {0}; \\ } \\} , &[_][]const u8{ \\pub export fn foo() void { \\ const union_unnamed_1 = extern union { \\ A: c_int, \\ B: c_int, \\ C: c_int, \\ }; \\ _ = @TypeOf(union_unnamed_1); \\ const Foo = union_unnamed_1; \\ var a: Foo = Foo{ \\ .A = @as(c_int, 0), \\ }; \\ _ = @TypeOf(a); \\ { \\ const union_unnamed_2 = extern union { \\ A: c_int, \\ B: c_int, \\ C: c_int, \\ }; \\ _ = @TypeOf(union_unnamed_2); \\ const Foo_1 = union_unnamed_2; \\ var a_2: Foo_1 = Foo_1{ \\ .A = @as(c_int, 0), \\ }; \\ _ = @TypeOf(a_2); \\ } \\} }); cases.add("use cast param as macro fn return type", \\#include \\#define SYS_BASE_CACHED 0 \\#define MEM_PHYSICAL_TO_K0(x) (void*)((uint32_t)(x) + SYS_BASE_CACHED) , &[_][]const u8{ \\pub inline fn MEM_PHYSICAL_TO_K0(x: anytype) ?*anyopaque { \\ return @import("std").zig.c_translation.cast(?*anyopaque, @import("std").zig.c_translation.cast(u32, x) + SYS_BASE_CACHED); \\} }); cases.add("variadic function demoted to extern", \\int foo(int bar, ...) { \\ return 1; \\} , &[_][]const u8{ \\warning: TODO unable to translate variadic function, demoted to extern \\pub extern fn foo(bar: c_int, ...) c_int; }); cases.add("pointer to opaque demoted struct", \\typedef struct { \\ _Atomic int foo; \\} Foo; \\ \\typedef struct { \\ Foo *bar; \\} Bar; , &[_][]const u8{ \\source.h:1:9: warning: struct demoted to opaque type - unable to translate type of field foo \\pub const Foo = opaque {}; \\pub const Bar = extern struct { \\ bar: ?*Foo, \\}; }); cases.add("macro expressions respect C operator precedence", \\int *foo = 0; \\#define FOO *((foo) + 2) \\#define VALUE (1 + 2 * 3 + 4 * 5 + 6 << 7 | 8 == 9) \\#define _AL_READ3BYTES(p) ((*(unsigned char *)(p)) \ \\ | (*((unsigned char *)(p) + 1) << 8) \ \\ | (*((unsigned char *)(p) + 2) << 16)) , &[_][]const u8{ \\pub const FOO = (foo + @as(c_int, 2)).*; , \\pub const VALUE = ((((@as(c_int, 1) + (@as(c_int, 2) * @as(c_int, 3))) + (@as(c_int, 4) * @as(c_int, 5))) + @as(c_int, 6)) << @as(c_int, 7)) | @boolToInt(@as(c_int, 8) == @as(c_int, 9)); , \\pub inline fn _AL_READ3BYTES(p: anytype) @TypeOf((@import("std").zig.c_translation.cast([*c]u8, p).* | ((@import("std").zig.c_translation.cast([*c]u8, p) + @as(c_int, 1)).* << @as(c_int, 8))) | ((@import("std").zig.c_translation.cast([*c]u8, p) + @as(c_int, 2)).* << @as(c_int, 16))) { \\ return (@import("std").zig.c_translation.cast([*c]u8, p).* | ((@import("std").zig.c_translation.cast([*c]u8, p) + @as(c_int, 1)).* << @as(c_int, 8))) | ((@import("std").zig.c_translation.cast([*c]u8, p) + @as(c_int, 2)).* << @as(c_int, 16)); \\} }); cases.add("static variable in block scope", \\float bar; \\int foo() { \\ _Thread_local static int bar = 2; \\} , &[_][]const u8{ \\pub export var bar: f32 = @import("std").mem.zeroes(f32); \\pub export fn foo() c_int { \\ const bar_1 = struct { \\ threadlocal var static: c_int = 2; \\ }; \\ _ = @TypeOf(bar_1); \\ return 0; \\} }); cases.add("missing return stmt", \\int foo() {} \\int bar() { \\ int a = 2; \\} \\int baz() { \\ return 0; \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ return 0; \\} \\pub export fn bar() c_int { \\ var a: c_int = 2; \\ _ = @TypeOf(a); \\ return 0; \\} \\pub export fn baz() c_int { \\ return 0; \\} }); cases.add("alignof", \\void main() { \\ int a = _Alignof(int); \\} , &[_][]const u8{ \\pub export fn main() void { \\ var a: c_int = @bitCast(c_int, @truncate(c_uint, @alignOf(c_int))); \\ _ = @TypeOf(a); \\} }); cases.add("initializer list macro", \\typedef struct Color { \\ unsigned char r; \\ unsigned char g; \\ unsigned char b; \\ unsigned char a; \\} Color; \\#define CLITERAL(type) (type) \\#define LIGHTGRAY CLITERAL(Color){ 200, 200, 200, 255 } // Light Gray \\typedef struct boom_t \\{ \\ int i1; \\} boom_t; \\#define FOO ((boom_t){1}) \\typedef struct { float x; } MyCStruct; \\#define A(_x) (MyCStruct) { .x = (_x) } \\#define B A(0.f) , &[_][]const u8{ \\pub const struct_Color = extern struct { \\ r: u8, \\ g: u8, \\ b: u8, \\ a: u8, \\}; \\pub const Color = struct_Color; , \\pub inline fn CLITERAL(@"type": anytype) @TypeOf(@"type") { \\ return @"type"; \\} , \\pub const LIGHTGRAY = @import("std").mem.zeroInit(CLITERAL(Color), .{ @as(c_int, 200), @as(c_int, 200), @as(c_int, 200), @as(c_int, 255) }); , \\pub const struct_boom_t = extern struct { \\ i1: c_int, \\}; \\pub const boom_t = struct_boom_t; , \\pub const FOO = @import("std").mem.zeroInit(boom_t, .{@as(c_int, 1)}); , \\pub const MyCStruct = extern struct { \\ x: f32, \\}; , \\pub inline fn A(_x: anytype) MyCStruct { \\ return @import("std").mem.zeroInit(MyCStruct, .{ \\ .x = _x, \\ }); \\} , \\pub const B = A(@as(f32, 0.0)); }); cases.add("complex switch", \\int main() { \\ int i = 2; \\ switch (i) { \\ case 0: { \\ case 2:{ \\ i += 2;} \\ i += 1; \\ } \\ } \\} , &[_][]const u8{ // TODO properly translate this \\source.h:5:13: warning: TODO complex switch , \\source.h:1:5: warning: unable to translate function, demoted to extern \\pub extern fn main() c_int; }); cases.add("correct semicolon after infixop", \\#define _IO_ERR_SEEN 0 \\#define __ferror_unlocked_body(_fp) (((_fp)->_flags & _IO_ERR_SEEN) != 0) , &[_][]const u8{ \\pub inline fn __ferror_unlocked_body(_fp: anytype) @TypeOf((_fp.*._flags & _IO_ERR_SEEN) != @as(c_int, 0)) { \\ return (_fp.*._flags & _IO_ERR_SEEN) != @as(c_int, 0); \\} }); cases.add("c booleans are just ints", \\#define FOO(x) ((x >= 0) + (x >= 0)) \\#define BAR 1 && 2 > 4 , &[_][]const u8{ \\pub inline fn FOO(x: anytype) @TypeOf(@boolToInt(x >= @as(c_int, 0)) + @boolToInt(x >= @as(c_int, 0))) { \\ return @boolToInt(x >= @as(c_int, 0)) + @boolToInt(x >= @as(c_int, 0)); \\} , \\pub const BAR = (@as(c_int, 1) != 0) and (@as(c_int, 2) > @as(c_int, 4)); }); cases.add("struct with aligned fields", \\struct foo { \\ __attribute__((aligned(1))) short bar; \\}; , &[_][]const u8{ \\pub const struct_foo = extern struct { \\ bar: c_short align(1), \\}; }); cases.add("struct with flexible array", \\struct foo { int x; int y[]; }; \\struct bar { int x; int y[0]; }; , &[_][]const u8{ \\pub const struct_foo = extern struct { \\ x: c_int align(4), \\ pub fn y(self: anytype) @import("std").zig.c_translation.FlexibleArrayType(@TypeOf(self), c_int) { \\ const Intermediate = @import("std").zig.c_translation.FlexibleArrayType(@TypeOf(self), u8); \\ const ReturnType = @import("std").zig.c_translation.FlexibleArrayType(@TypeOf(self), c_int); \\ return @ptrCast(ReturnType, @alignCast(@alignOf(c_int), @ptrCast(Intermediate, self) + 4)); \\ } \\}; \\pub const struct_bar = extern struct { \\ x: c_int align(4), \\ pub fn y(self: anytype) @import("std").zig.c_translation.FlexibleArrayType(@TypeOf(self), c_int) { \\ const Intermediate = @import("std").zig.c_translation.FlexibleArrayType(@TypeOf(self), u8); \\ const ReturnType = @import("std").zig.c_translation.FlexibleArrayType(@TypeOf(self), c_int); \\ return @ptrCast(ReturnType, @alignCast(@alignOf(c_int), @ptrCast(Intermediate, self) + 4)); \\ } \\}; }); cases.add("nested loops without blocks", \\void foo() { \\ while (0) while (0) {} \\ for (;;) while (0); \\ for (;;) do {} while (0); \\} , &[_][]const u8{ \\pub export fn foo() void { \\ while (false) while (false) {}; \\ while (true) while (false) {}; \\ while (true) while (true) { \\ if (!false) break; \\ }; \\} }); cases.add("macro comma operator", \\#define foo (foo, bar) \\int baz(int x, int y) { return 0; } \\#define bar(x) (&x, +3, 4 == 4, 5 * 6, baz(1, 2), 2 % 2, baz(1,2)) , &[_][]const u8{ \\pub const foo = blk_1: { \\ _ = @TypeOf(foo); \\ break :blk_1 bar; \\}; , \\pub inline fn bar(x: anytype) @TypeOf(baz(@as(c_int, 1), @as(c_int, 2))) { \\ return blk_1: { \\ _ = &x; \\ _ = @as(c_int, 3); \\ _ = @as(c_int, 4) == @as(c_int, 4); \\ _ = @as(c_int, 5) * @as(c_int, 6); \\ _ = baz(@as(c_int, 1), @as(c_int, 2)); \\ _ = @import("std").zig.c_translation.MacroArithmetic.rem(@as(c_int, 2), @as(c_int, 2)); \\ break :blk_1 baz(@as(c_int, 1), @as(c_int, 2)); \\ }; \\} }); cases.add("macro keyword define", \\#define foo 1 \\#define inline 2 , &[_][]const u8{ \\pub const foo = @as(c_int, 1); , \\pub const @"inline" = @as(c_int, 2); }); cases.add("macro line continuation", \\int BAR = 0; \\#define FOO -\ \\BAR , &[_][]const u8{ \\pub const FOO = -BAR; }); cases.add("struct with atomic field", \\struct arcan_shmif_cont { \\ struct arcan_shmif_page* addr; \\}; \\struct arcan_shmif_page { \\ volatile _Atomic int abufused[12]; \\}; , &[_][]const u8{ \\source.h:4:8: warning: struct demoted to opaque type - unable to translate type of field abufused \\pub const struct_arcan_shmif_page = opaque {}; \\pub const struct_arcan_shmif_cont = extern struct { \\ addr: ?*struct_arcan_shmif_page, \\}; }); if (builtin.zig_backend != .stage1) { cases.add("function prototype translated as optional", \\typedef void (*fnptr_ty)(void); \\typedef __attribute__((cdecl)) void (*fnptr_attr_ty)(void); \\struct foo { \\ __attribute__((cdecl)) void (*foo)(void); \\ void (*bar)(void); \\ fnptr_ty baz; \\ fnptr_attr_ty qux; \\}; , &[_][]const u8{ \\pub const fnptr_ty = ?*const fn () callconv(.C) void; \\pub const fnptr_attr_ty = ?*const fn () callconv(.C) void; \\pub const struct_foo = extern struct { \\ foo: ?*const fn () callconv(.C) void, \\ bar: ?*const fn () callconv(.C) void, \\ baz: fnptr_ty, \\ qux: fnptr_attr_ty, \\}; }); } cases.add("function prototype with parenthesis", \\void (f0) (void *L); \\void ((f1)) (void *L); \\void (((f2))) (void *L); , &[_][]const u8{ \\pub extern fn f0(L: ?*anyopaque) void; \\pub extern fn f1(L: ?*anyopaque) void; \\pub extern fn f2(L: ?*anyopaque) void; }); cases.add("array initializer w/ typedef", \\typedef unsigned char uuid_t[16]; \\static const uuid_t UUID_NULL __attribute__ ((unused)) = {0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0}; , &[_][]const u8{ \\pub const uuid_t = [16]u8; \\pub const UUID_NULL: uuid_t = [16]u8{ \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\ 0, \\}; }); cases.add("empty declaration", \\; , &[_][]const u8{""}); cases.add("#define hex literal with capital X", \\#define VAL 0XF00D , &[_][]const u8{ \\pub const VAL = @import("std").zig.c_translation.promoteIntLiteral(c_int, 0xF00D, .hexadecimal); }); cases.add("anonymous struct & unions", \\typedef struct { \\ union { \\ char x; \\ struct { int y; }; \\ }; \\} outer; \\void foo(outer *x) { x->y = x->x; } , &[_][]const u8{ \\const struct_unnamed_2 = extern struct { \\ y: c_int, \\}; \\const union_unnamed_1 = extern union { \\ x: u8, \\ unnamed_0: struct_unnamed_2, \\}; \\pub const outer = extern struct { \\ unnamed_0: union_unnamed_1, \\}; \\pub export fn foo(arg_x: [*c]outer) void { \\ var x = arg_x; \\ x.*.unnamed_0.unnamed_0.y = @bitCast(c_int, @as(c_uint, x.*.unnamed_0.x)); \\} }); cases.add("union initializer", \\union { int x; char c[4]; } \\ ua = {1}, \\ ub = {.c={'a','b','b','a'}}; , &[_][]const u8{ \\const union_unnamed_1 = extern union { \\ x: c_int, \\ c: [4]u8, \\}; \\pub export var ua: union_unnamed_1 = union_unnamed_1{ \\ .x = @as(c_int, 1), \\}; \\pub export var ub: union_unnamed_1 = union_unnamed_1{ \\ .c = [4]u8{ \\ 'a', \\ 'b', \\ 'b', \\ 'a', \\ }, \\}; }); cases.add("struct initializer - simple", \\typedef struct { int x; } foo; \\struct {double x,y,z;} s0 = {1.2, 1.3}; \\struct {int sec,min,hour,day,mon,year;} s1 = {.day=31,12,2014,.sec=30,15,17}; \\struct {int x,y;} s2 = {.y = 2, .x=1}; \\foo s3 = { 123 }; , &[_][]const u8{ \\pub const foo = extern struct { \\ x: c_int, \\}; \\const struct_unnamed_1 = extern struct { \\ x: f64, \\ y: f64, \\ z: f64, \\}; \\pub export var s0: struct_unnamed_1 = struct_unnamed_1{ \\ .x = 1.2, \\ .y = 1.3, \\ .z = 0, \\}; \\const struct_unnamed_2 = extern struct { \\ sec: c_int, \\ min: c_int, \\ hour: c_int, \\ day: c_int, \\ mon: c_int, \\ year: c_int, \\}; \\pub export var s1: struct_unnamed_2 = struct_unnamed_2{ \\ .sec = @as(c_int, 30), \\ .min = @as(c_int, 15), \\ .hour = @as(c_int, 17), \\ .day = @as(c_int, 31), \\ .mon = @as(c_int, 12), \\ .year = @as(c_int, 2014), \\}; \\const struct_unnamed_3 = extern struct { \\ x: c_int, \\ y: c_int, \\}; \\pub export var s2: struct_unnamed_3 = struct_unnamed_3{ \\ .x = @as(c_int, 1), \\ .y = @as(c_int, 2), \\}; \\pub export var s3: foo = foo{ \\ .x = @as(c_int, 123), \\}; }); cases.add("simple ptrCast for casts between opaque types", \\struct opaque; \\struct opaque_2; \\void function(struct opaque *opaque) { \\ struct opaque_2 *cast = (struct opaque_2 *)opaque; \\} , &[_][]const u8{ \\pub const struct_opaque = opaque {}; \\pub const struct_opaque_2 = opaque {}; \\pub export fn function(arg_opaque_1: ?*struct_opaque) void { \\ var opaque_1 = arg_opaque_1; \\ var cast: ?*struct_opaque_2 = @ptrCast(?*struct_opaque_2, opaque_1); \\ _ = @TypeOf(cast); \\} }); cases.add("struct initializer - packed", \\struct {int x,y,z;} __attribute__((packed)) s0 = {1, 2}; , &[_][]const u8{ \\const struct_unnamed_1 = extern struct { \\ x: c_int align(1), \\ y: c_int align(1), \\ z: c_int align(1), \\}; \\pub export var s0: struct_unnamed_1 = struct_unnamed_1{ \\ .x = @as(c_int, 1), \\ .y = @as(c_int, 2), \\ .z = 0, \\}; }); // Test case temporarily disabled: // https://github.com/ziglang/zig/issues/12055 if (false) { cases.add("align() attribute", \\__attribute__ ((aligned(128))) \\extern char my_array[16]; \\__attribute__ ((aligned(128))) \\void my_fn(void) { } \\void other_fn(void) { \\ char ARR[16] __attribute__ ((aligned (16))); \\} , &[_][]const u8{ \\pub extern var my_array: [16]u8 align(128); \\pub export fn my_fn() align(128) void {} \\pub export fn other_fn() void { \\ var ARR: [16]u8 align(16) = undefined; \\ _ = @TypeOf(ARR); \\} }); } cases.add("linksection() attribute", \\// Use the "segment,section" format to make this test pass when \\// targeting the mach-o binary format \\__attribute__ ((__section__("NEAR,.data"))) \\extern char my_array[16]; \\__attribute__ ((__section__("NEAR,.data"))) \\void my_fn(void) { } , &[_][]const u8{ \\pub extern var my_array: [16]u8 linksection("NEAR,.data"); \\pub export fn my_fn() linksection("NEAR,.data") void {} }); cases.add("simple function prototypes", \\void __attribute__((noreturn)) foo(void); \\int bar(void); , &[_][]const u8{ \\pub extern fn foo() noreturn; \\pub extern fn bar() c_int; }); cases.add("simple var decls", \\void foo(void) { \\ int a; \\ char b = 123; \\ const int c; \\ const unsigned d = 440; \\ int e = 10; \\ unsigned int f = 10u; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: c_int = undefined; \\ _ = @TypeOf(a); \\ var b: u8 = 123; \\ _ = @TypeOf(b); \\ const c: c_int = undefined; \\ _ = @TypeOf(c); \\ const d: c_uint = @bitCast(c_uint, @as(c_int, 440)); \\ _ = @TypeOf(d); \\ var e: c_int = 10; \\ _ = @TypeOf(e); \\ var f: c_uint = 10; \\ _ = @TypeOf(f); \\} }); cases.add("ignore result, explicit function arguments", \\void foo(void) { \\ int a; \\ 1; \\ "hey"; \\ 1 + 1; \\ 1 - 1; \\ a = 1; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: c_int = undefined; \\ _ = @as(c_int, 1); \\ _ = "hey"; \\ _ = @as(c_int, 1) + @as(c_int, 1); \\ _ = @as(c_int, 1) - @as(c_int, 1); \\ a = 1; \\} }); cases.add("function with no prototype", \\int foo() { \\ return 5; \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ return 5; \\} }); cases.add("variables", \\extern int extern_var; \\static const int int_var = 13; \\int foo; , &[_][]const u8{ \\pub extern var extern_var: c_int; \\pub const int_var: c_int = 13; \\pub export var foo: c_int = @import("std").mem.zeroes(c_int); }); cases.add("const ptr initializer", \\static const char *v0 = "0.0.0"; , &[_][]const u8{ \\pub var v0: [*c]const u8 = "0.0.0"; }); cases.add("static incomplete array inside function", \\void foo(void) { \\ static const char v2[] = "2.2.2"; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ const v2 = struct { \\ const static: [5:0]u8 = "2.2.2".*; \\ }; \\ _ = @TypeOf(v2); \\} }); cases.add("simple function definition", \\void foo(void) {} \\static void bar(void) {} , &[_][]const u8{ \\pub export fn foo() void {} \\pub fn bar() callconv(.C) void {} }); cases.add("typedef void", \\typedef void Foo; \\Foo fun(Foo *a); , &[_][]const u8{ \\pub const Foo = anyopaque; , \\pub extern fn fun(a: ?*Foo) void; }); cases.add("duplicate typedef", \\typedef long foo; \\typedef int bar; \\typedef long foo; \\typedef int baz; , &[_][]const u8{ \\pub const foo = c_long; \\pub const bar = c_int; \\pub const baz = c_int; }); if (builtin.zig_backend != .stage1) { cases.add("casting pointers to ints and ints to pointers", \\void foo(void); \\void bar(void) { \\ void *func_ptr = foo; \\ void (*typed_func_ptr)(void) = (void (*)(void)) (unsigned long) func_ptr; \\} , &[_][]const u8{ \\pub extern fn foo() void; \\pub export fn bar() void { \\ var func_ptr: ?*anyopaque = @ptrCast(?*anyopaque, &foo); \\ var typed_func_ptr: ?*const fn () callconv(.C) void = @intToPtr(?*const fn () callconv(.C) void, @intCast(c_ulong, @ptrToInt(func_ptr))); \\ _ = @TypeOf(typed_func_ptr); \\} }); } cases.add("noreturn attribute", \\void foo(void) __attribute__((noreturn)); , &[_][]const u8{ \\pub extern fn foo() noreturn; }); cases.add("always_inline attribute", \\__attribute__((always_inline)) int foo() { \\ return 5; \\} , &[_][]const u8{ \\pub inline fn foo() c_int { \\ return 5; \\} }); cases.add("add, sub, mul, div, rem", \\int s() { \\ int a, b, c; \\ c = a + b; \\ c = a - b; \\ c = a * b; \\ c = a / b; \\ c = a % b; \\} \\unsigned u() { \\ unsigned a, b, c; \\ c = a + b; \\ c = a - b; \\ c = a * b; \\ c = a / b; \\ c = a % b; \\} , &[_][]const u8{ \\pub export fn s() c_int { \\ var a: c_int = undefined; \\ var b: c_int = undefined; \\ var c: c_int = undefined; \\ c = a + b; \\ c = a - b; \\ c = a * b; \\ c = @divTrunc(a, b); \\ c = @import("std").zig.c_translation.signedRemainder(a, b); \\ return 0; \\} \\pub export fn u() c_uint { \\ var a: c_uint = undefined; \\ var b: c_uint = undefined; \\ var c: c_uint = undefined; \\ c = a +% b; \\ c = a -% b; \\ c = a *% b; \\ c = a / b; \\ c = a % b; \\ return 0; \\} }); if (builtin.zig_backend != .stage1) { cases.add("typedef of function in struct field", \\typedef void lws_callback_function(void); \\struct Foo { \\ void (*func)(void); \\ lws_callback_function *callback_http; \\}; , &[_][]const u8{ \\pub const lws_callback_function = fn () callconv(.C) void; \\pub const struct_Foo = extern struct { \\ func: ?*const fn () callconv(.C) void, \\ callback_http: ?*const lws_callback_function, \\}; }); } cases.add("pointer to struct demoted to opaque due to bit fields", \\struct Foo { \\ unsigned int: 1; \\}; \\struct Bar { \\ struct Foo *foo; \\}; , &[_][]const u8{ \\pub const struct_Foo = opaque {}; , \\pub const struct_Bar = extern struct { \\ foo: ?*struct_Foo, \\}; }); cases.add("macro with left shift", \\#define REDISMODULE_READ (1<<0) , &[_][]const u8{ \\pub const REDISMODULE_READ = @as(c_int, 1) << @as(c_int, 0); }); cases.add("macro with right shift", \\#define FLASH_SIZE 0x200000UL /* 2 MB */ \\#define FLASH_BANK_SIZE (FLASH_SIZE >> 1) /* 1 MB */ , &[_][]const u8{ \\pub const FLASH_SIZE = @as(c_ulong, 0x200000); , \\pub const FLASH_BANK_SIZE = FLASH_SIZE >> @as(c_int, 1); }); cases.add("double define struct", \\typedef struct Bar Bar; \\typedef struct Foo Foo; \\ \\struct Foo { \\ Foo *a; \\}; \\ \\struct Bar { \\ Foo *a; \\}; , &[_][]const u8{ \\pub const struct_Foo = extern struct { \\ a: [*c]Foo, \\}; , \\pub const Foo = struct_Foo; , \\pub const struct_Bar = extern struct { \\ a: [*c]Foo, \\}; , \\pub const Bar = struct_Bar; }); cases.add("simple struct", \\struct Foo { \\ int x; \\ char *y; \\}; , &[_][]const u8{ \\const struct_Foo = extern struct { \\ x: c_int, \\ y: [*c]u8, \\}; , \\pub const Foo = struct_Foo; }); if (builtin.zig_backend != .stage1) { cases.add("self referential struct with function pointer", \\struct Foo { \\ void (*derp)(struct Foo *foo); \\}; , &[_][]const u8{ \\pub const struct_Foo = extern struct { \\ derp: ?*const fn ([*c]struct_Foo) callconv(.C) void, \\}; , \\pub const Foo = struct_Foo; }); } cases.add("struct prototype used in func", \\struct Foo; \\struct Foo *some_func(struct Foo *foo, int x); , &[_][]const u8{ \\pub const struct_Foo = opaque {}; , \\pub extern fn some_func(foo: ?*struct_Foo, x: c_int) ?*struct_Foo; , \\pub const Foo = struct_Foo; }); cases.add("#define an unsigned integer literal", \\#define CHANNEL_COUNT 24 , &[_][]const u8{ \\pub const CHANNEL_COUNT = @as(c_int, 24); }); cases.add("#define referencing another #define", \\#define THING2 THING1 \\#define THING1 1234 , &[_][]const u8{ \\pub const THING1 = @as(c_int, 1234); , \\pub const THING2 = THING1; }); cases.add("circular struct definitions", \\struct Bar; \\ \\struct Foo { \\ struct Bar *next; \\}; \\ \\struct Bar { \\ struct Foo *next; \\}; , &[_][]const u8{ \\pub const struct_Bar = extern struct { \\ next: [*c]struct_Foo, \\}; , \\pub const struct_Foo = extern struct { \\ next: [*c]struct_Bar, \\}; }); cases.add("#define string", \\#define foo "a string" , &[_][]const u8{ \\pub const foo = "a string"; }); cases.add("zig keywords in C code", \\struct comptime { \\ int defer; \\}; , &[_][]const u8{ \\pub const struct_comptime = extern struct { \\ @"defer": c_int, \\}; , \\pub const @"comptime" = struct_comptime; }); cases.add("macro with parens around negative number", \\#define LUA_GLOBALSINDEX (-10002) , &[_][]const u8{ \\pub const LUA_GLOBALSINDEX = -@as(c_int, 10002); }); cases.add( "u integer suffix after 0 (zero) in macro definition", "#define ZERO 0U", &[_][]const u8{ "pub const ZERO = @as(c_uint, 0);", }, ); cases.add( "l integer suffix after 0 (zero) in macro definition", "#define ZERO 0L", &[_][]const u8{ "pub const ZERO = @as(c_long, 0);", }, ); cases.add( "ul integer suffix after 0 (zero) in macro definition", "#define ZERO 0UL", &[_][]const u8{ "pub const ZERO = @as(c_ulong, 0);", }, ); cases.add( "lu integer suffix after 0 (zero) in macro definition", "#define ZERO 0LU", &[_][]const u8{ "pub const ZERO = @as(c_ulong, 0);", }, ); cases.add( "ll integer suffix after 0 (zero) in macro definition", "#define ZERO 0LL", &[_][]const u8{ "pub const ZERO = @as(c_longlong, 0);", }, ); cases.add( "ull integer suffix after 0 (zero) in macro definition", "#define ZERO 0ULL", &[_][]const u8{ "pub const ZERO = @as(c_ulonglong, 0);", }, ); cases.add( "llu integer suffix after 0 (zero) in macro definition", "#define ZERO 0LLU", &[_][]const u8{ "pub const ZERO = @as(c_ulonglong, 0);", }, ); cases.add( "bitwise not on u-suffixed 0 (zero) in macro definition", "#define NOT_ZERO (~0U)", &[_][]const u8{ "pub const NOT_ZERO = ~@as(c_uint, 0);", }, ); cases.add("float suffixes", \\#define foo 3.14f \\#define bar 16.e-2l \\#define FOO 0.12345 \\#define BAR .12345 \\#define baz 1e1 \\#define BAZ 42e-3f \\#define foobar -73.L , &[_][]const u8{ "pub const foo = @as(f32, 3.14);", "pub const bar = @as(c_longdouble, 16.0e-2);", "pub const FOO = @as(f64, 0.12345);", "pub const BAR = @as(f64, 0.12345);", "pub const baz = @as(f64, 1e1);", "pub const BAZ = @as(f32, 42e-3);", "pub const foobar = -@as(c_longdouble, 73.0);", }); cases.add("macro defines hexadecimal float", \\#define FOO 0xf7p38 \\#define BAR -0X8F.BP5F \\#define FOOBAR 0X0P+0 \\#define BAZ -0x.0a5dp+12 \\#define FOOBAZ 0xfE.P-1l , &[_][]const u8{ "pub const FOO = @as(f64, 0xf7p38);", "pub const BAR = -@as(f32, 0x8F.BP5);", "pub const FOOBAR = @as(f64, 0x0P+0);", "pub const BAZ = -@as(f64, 0x0.0a5dp+12);", "pub const FOOBAZ = @as(c_longdouble, 0xfE.0P-1);", }); cases.add("comments", \\#define foo 1 //foo \\#define bar /* bar */ 2 , &[_][]const u8{ "pub const foo = @as(c_int, 1);", "pub const bar = @as(c_int, 2);", }); cases.add("string prefix", \\#define foo L"hello" , &[_][]const u8{ "pub const foo = \"hello\";", }); cases.add("null statements", \\void foo(void) { \\ ;;;;; \\} , &[_][]const u8{ \\pub export fn foo() void {} }); if (builtin.os.tag != .windows) { // Windows treats this as an enum with type c_int cases.add("big negative enum init values when C ABI supports long long enums", \\enum EnumWithInits { \\ VAL01 = 0, \\ VAL02 = 1, \\ VAL03 = 2, \\ VAL04 = 3, \\ VAL05 = -1, \\ VAL06 = -2, \\ VAL07 = -3, \\ VAL08 = -4, \\ VAL09 = VAL02 + VAL08, \\ VAL10 = -1000012000, \\ VAL11 = -1000161000, \\ VAL12 = -1000174001, \\ VAL13 = VAL09, \\ VAL14 = VAL10, \\ VAL15 = VAL11, \\ VAL16 = VAL13, \\ VAL17 = (VAL16 - VAL10 + 1), \\ VAL18 = 0x1000000000000000L, \\ VAL19 = VAL18 + VAL18 + VAL18 - 1, \\ VAL20 = VAL19 + VAL19, \\ VAL21 = VAL20 + 0xFFFFFFFFFFFFFFFF, \\ VAL22 = 0xFFFFFFFFFFFFFFFF + 1, \\ VAL23 = 0xFFFFFFFFFFFFFFFF, \\}; , &[_][]const u8{ \\pub const VAL01: c_int = 0; \\pub const VAL02: c_int = 1; \\pub const VAL03: c_int = 2; \\pub const VAL04: c_int = 3; \\pub const VAL05: c_int = -1; \\pub const VAL06: c_int = -2; \\pub const VAL07: c_int = -3; \\pub const VAL08: c_int = -4; \\pub const VAL09: c_int = -3; \\pub const VAL10: c_int = -1000012000; \\pub const VAL11: c_int = -1000161000; \\pub const VAL12: c_int = -1000174001; \\pub const VAL13: c_int = -3; \\pub const VAL14: c_int = -1000012000; \\pub const VAL15: c_int = -1000161000; \\pub const VAL16: c_int = -3; \\pub const VAL17: c_int = 1000011998; \\pub const VAL18: c_longlong = 1152921504606846976; \\pub const VAL19: c_longlong = 3458764513820540927; \\pub const VAL20: c_longlong = 6917529027641081854; \\pub const VAL21: c_longlong = 6917529027641081853; \\pub const VAL22: c_int = 0; \\pub const VAL23: c_longlong = -1; \\pub const enum_EnumWithInits = c_longlong; }); } cases.add("predefined expressions", \\void foo(void) { \\ __func__; \\ __FUNCTION__; \\ __PRETTY_FUNCTION__; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ _ = "foo"; \\ _ = "foo"; \\ _ = "void foo(void)"; \\} }); cases.add("constant size array", \\void func(int array[20]); , &[_][]const u8{ \\pub extern fn func(array: [*c]c_int) void; }); if (builtin.zig_backend != .stage1) { cases.add("__cdecl doesn't mess up function pointers", \\void foo(void (__cdecl *fn_ptr)(void)); , &[_][]const u8{ \\pub extern fn foo(fn_ptr: ?*const fn () callconv(.C) void) void; }); } cases.add("void cast", \\void foo() { \\ int a; \\ (void) a; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: c_int = undefined; \\ _ = @TypeOf(a); \\} }); cases.add("implicit cast to void *", \\void *foo() { \\ unsigned short *x; \\ return x; \\} , &[_][]const u8{ \\pub export fn foo() ?*anyopaque { \\ var x: [*c]c_ushort = undefined; \\ return @ptrCast(?*anyopaque, x); \\} }); cases.add("null pointer implicit cast", \\int* foo(void) { \\ return 0; \\} , &[_][]const u8{ \\pub export fn foo() [*c]c_int { \\ return null; \\} }); cases.add("simple union", \\union Foo { \\ int x; \\ double y; \\}; , &[_][]const u8{ \\pub const union_Foo = extern union { \\ x: c_int, \\ y: f64, \\}; , \\pub const Foo = union_Foo; }); cases.add("packed union - simple", \\union Foo { \\ char x; \\ double y; \\} __attribute__((packed)); , &[_][]const u8{ \\pub const union_Foo = extern union { \\ x: u8 align(1), \\ y: f64 align(1), \\}; , \\pub const Foo = union_Foo; }); cases.add("packed union - nested unpacked", \\union Foo{ \\ char x; \\ double y; \\ struct { \\ char a; \\ int b; \\ } z; \\} __attribute__((packed)); , &[_][]const u8{ // NOTE: The nested struct is *not* packed/aligned, // even though the parent struct is // this is consistent with GCC docs \\const struct_unnamed_1 = extern struct { \\ a: u8, \\ b: c_int, \\}; , \\pub const union_Foo = extern union { \\ x: u8 align(1), \\ y: f64 align(1), \\ z: struct_unnamed_1 align(1), \\}; , \\pub const Foo = union_Foo; }); cases.add("packed union - nested packed", \\union Foo{ \\ char x; \\ double y; \\ struct { \\ char a; \\ int b; \\ } __attribute__((packed)) z; \\} __attribute__((packed)); , &[_][]const u8{ // in order for the nested struct to be packed, it must // have an independent packed declaration on // the nested type (see GCC docs for details) \\const struct_unnamed_1 = extern struct { \\ a: u8 align(1), \\ b: c_int align(1), \\}; , \\pub const union_Foo = extern union { \\ x: u8 align(1), \\ y: f64 align(1), \\ z: struct_unnamed_1 align(1), \\}; , \\pub const Foo = union_Foo; }); cases.add("string literal", \\const char *foo(void) { \\ return "bar"; \\} , &[_][]const u8{ \\pub export fn foo() [*c]const u8 { \\ return "bar"; \\} }); cases.add("return void", \\void foo(void) { \\ return; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ return; \\} }); cases.add("for loop", \\void foo(void) { \\ for (int i = 0; i; i++) { } \\} , &[_][]const u8{ \\pub export fn foo() void { \\ { \\ var i: c_int = 0; \\ while (i != 0) : (i += 1) {} \\ } \\} }); cases.add("empty for loop", \\void foo(void) { \\ for (;;) { } \\} , &[_][]const u8{ \\pub export fn foo() void { \\ while (true) {} \\} }); cases.add("for loop with simple init expression", \\void foo(void) { \\ int i; \\ for (i = 3; i; i--) { } \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var i: c_int = undefined; \\ { \\ i = 3; \\ while (i != 0) : (i -= 1) {} \\ } \\} }); cases.add("break statement", \\void foo(void) { \\ for (;;) { \\ break; \\ } \\} , &[_][]const u8{ \\pub export fn foo() void { \\ while (true) { \\ break; \\ } \\} }); cases.add("continue statement", \\void foo(void) { \\ for (;;) { \\ continue; \\ } \\} , &[_][]const u8{ \\pub export fn foo() void { \\ while (true) { \\ continue; \\ } \\} }); cases.add("pointer casting", \\float *ptrcast() { \\ int *a; \\ return (float *)a; \\} , &[_][]const u8{ \\pub export fn ptrcast() [*c]f32 { \\ var a: [*c]c_int = undefined; \\ return @ptrCast([*c]f32, @alignCast(@import("std").meta.alignment([*c]f32), a)); \\} }); cases.add("casting pointer to pointer", \\float **ptrptrcast() { \\ int **a; \\ return (float **)a; \\} , &[_][]const u8{ \\pub export fn ptrptrcast() [*c][*c]f32 { \\ var a: [*c][*c]c_int = undefined; \\ return @ptrCast([*c][*c]f32, @alignCast(@import("std").meta.alignment([*c][*c]f32), a)); \\} }); cases.add("pointer conversion with different alignment", \\void test_ptr_cast() { \\ void *p; \\ { \\ char *to_char = (char *)p; \\ short *to_short = (short *)p; \\ int *to_int = (int *)p; \\ long long *to_longlong = (long long *)p; \\ } \\ { \\ char *to_char = p; \\ short *to_short = p; \\ int *to_int = p; \\ long long *to_longlong = p; \\ } \\} , &[_][]const u8{ \\pub export fn test_ptr_cast() void { \\ var p: ?*anyopaque = undefined; \\ { \\ var to_char: [*c]u8 = @ptrCast([*c]u8, @alignCast(@import("std").meta.alignment([*c]u8), p)); \\ _ = @TypeOf(to_char); \\ var to_short: [*c]c_short = @ptrCast([*c]c_short, @alignCast(@import("std").meta.alignment([*c]c_short), p)); \\ _ = @TypeOf(to_short); \\ var to_int: [*c]c_int = @ptrCast([*c]c_int, @alignCast(@import("std").meta.alignment([*c]c_int), p)); \\ _ = @TypeOf(to_int); \\ var to_longlong: [*c]c_longlong = @ptrCast([*c]c_longlong, @alignCast(@import("std").meta.alignment([*c]c_longlong), p)); \\ _ = @TypeOf(to_longlong); \\ } \\ { \\ var to_char: [*c]u8 = @ptrCast([*c]u8, @alignCast(@import("std").meta.alignment([*c]u8), p)); \\ _ = @TypeOf(to_char); \\ var to_short: [*c]c_short = @ptrCast([*c]c_short, @alignCast(@import("std").meta.alignment([*c]c_short), p)); \\ _ = @TypeOf(to_short); \\ var to_int: [*c]c_int = @ptrCast([*c]c_int, @alignCast(@import("std").meta.alignment([*c]c_int), p)); \\ _ = @TypeOf(to_int); \\ var to_longlong: [*c]c_longlong = @ptrCast([*c]c_longlong, @alignCast(@import("std").meta.alignment([*c]c_longlong), p)); \\ _ = @TypeOf(to_longlong); \\ } \\} }); cases.add("while on non-bool", \\int while_none_bool() { \\ int a; \\ float b; \\ void *c; \\ while (a) return 0; \\ while (b) return 1; \\ while (c) return 2; \\ return 3; \\} , &[_][]const u8{ \\pub export fn while_none_bool() c_int { \\ var a: c_int = undefined; \\ var b: f32 = undefined; \\ var c: ?*anyopaque = undefined; \\ while (a != 0) return 0; \\ while (b != 0) return 1; \\ while (c != null) return 2; \\ return 3; \\} }); cases.add("for on non-bool", \\int for_none_bool() { \\ int a; \\ float b; \\ void *c; \\ for (;a;) return 0; \\ for (;b;) return 1; \\ for (;c;) return 2; \\ return 3; \\} , &[_][]const u8{ \\pub export fn for_none_bool() c_int { \\ var a: c_int = undefined; \\ var b: f32 = undefined; \\ var c: ?*anyopaque = undefined; \\ while (a != 0) return 0; \\ while (b != 0) return 1; \\ while (c != null) return 2; \\ return 3; \\} }); cases.add("bitshift", \\int foo(void) { \\ return (1 << 2) >> 1; \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ return (@as(c_int, 1) << @intCast(@import("std").math.Log2Int(c_int), 2)) >> @intCast(@import("std").math.Log2Int(c_int), 1); \\} }); cases.add("sizeof", \\#include \\size_t size_of(void) { \\ return sizeof(int); \\} , &[_][]const u8{ \\pub export fn size_of() usize { \\ return @sizeOf(c_int); \\} }); cases.add("normal deref", \\void foo() { \\ int *x; \\ *x = 1; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var x: [*c]c_int = undefined; \\ x.* = 1; \\} }); cases.add("address of operator", \\int foo(void) { \\ int x = 1234; \\ int *ptr = &x; \\ return *ptr; \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ var x: c_int = 1234; \\ var ptr: [*c]c_int = &x; \\ return ptr.*; \\} }); cases.add("bin not", \\int foo() { \\ int x; \\ return ~x; \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ var x: c_int = undefined; \\ return ~x; \\} }); cases.add("bool not", \\int foo() { \\ int a; \\ float b; \\ void *c; \\ return !(a == 0); \\ return !a; \\ return !b; \\ return !c; \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ var a: c_int = undefined; \\ var b: f32 = undefined; \\ var c: ?*anyopaque = undefined; \\ return @boolToInt(!(a == @as(c_int, 0))); \\ return @boolToInt(!(a != 0)); \\ return @boolToInt(!(b != 0)); \\ return @boolToInt(!(c != null)); \\} }); cases.add("__extension__ cast", \\int foo(void) { \\ return __extension__ 1; \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ return 1; \\} }); if (builtin.os.tag != .windows) { // sysv_abi not currently supported on windows cases.add("Macro qualified functions", \\void __attribute__((sysv_abi)) foo(void); , &[_][]const u8{ \\pub extern fn foo() void; }); } cases.add("Forward-declared enum", \\extern enum enum_ty my_enum; \\enum enum_ty { FOO }; , &[_][]const u8{ \\pub const FOO: c_int = 0; \\pub const enum_enum_ty = c_int; \\pub extern var my_enum: enum_enum_ty; }); if (builtin.zig_backend != .stage1) { cases.add("Parameterless function pointers", \\typedef void (*fn0)(); \\typedef void (*fn1)(char); , &[_][]const u8{ \\pub const fn0 = ?*const fn (...) callconv(.C) void; \\pub const fn1 = ?*const fn (u8) callconv(.C) void; }); } cases.addWithTarget("Calling convention", .{ .cpu_arch = .x86, .os_tag = .linux, .abi = .none, }, \\void __attribute__((fastcall)) foo1(float *a); \\void __attribute__((stdcall)) foo2(float *a); \\void __attribute__((vectorcall)) foo3(float *a); \\void __attribute__((cdecl)) foo4(float *a); \\void __attribute__((thiscall)) foo5(float *a); , &[_][]const u8{ \\pub extern fn foo1(a: [*c]f32) callconv(.Fastcall) void; \\pub extern fn foo2(a: [*c]f32) callconv(.Stdcall) void; \\pub extern fn foo3(a: [*c]f32) callconv(.Vectorcall) void; \\pub extern fn foo4(a: [*c]f32) void; \\pub extern fn foo5(a: [*c]f32) callconv(.Thiscall) void; }); cases.addWithTarget("Calling convention", CrossTarget.parse(.{ .arch_os_abi = "arm-linux-none", .cpu_features = "generic+v8_5a", }) catch unreachable, \\void __attribute__((pcs("aapcs"))) foo1(float *a); \\void __attribute__((pcs("aapcs-vfp"))) foo2(float *a); , &[_][]const u8{ \\pub extern fn foo1(a: [*c]f32) callconv(.AAPCS) void; \\pub extern fn foo2(a: [*c]f32) callconv(.AAPCSVFP) void; }); cases.addWithTarget("Calling convention", CrossTarget.parse(.{ .arch_os_abi = "aarch64-linux-none", .cpu_features = "generic+v8_5a", }) catch unreachable, \\void __attribute__((aarch64_vector_pcs)) foo1(float *a); , &[_][]const u8{ \\pub extern fn foo1(a: [*c]f32) callconv(.Vectorcall) void; }); cases.add("Parameterless function prototypes", \\void a() {} \\void b(void) {} \\void c(); \\void d(void); \\static void e() {} \\static void f(void) {} \\static void g(); \\static void h(void); , &[_][]const u8{ \\pub export fn a() void {} \\pub export fn b() void {} \\pub extern fn c(...) void; \\pub extern fn d() void; \\pub fn e() callconv(.C) void {} \\pub fn f() callconv(.C) void {} \\pub extern fn g() void; \\pub extern fn h() void; }); cases.add("variable declarations", \\extern char arr0[] = "hello"; \\static char arr1[] = "hello"; \\char arr2[] = "hello"; , &[_][]const u8{ \\pub export var arr0: [5:0]u8 = "hello".*; \\pub var arr1: [5:0]u8 = "hello".*; \\pub export var arr2: [5:0]u8 = "hello".*; }); cases.add("array initializer expr", \\static void foo(void){ \\ char arr[10] ={1}; \\ char *arr1[10] ={0}; \\} , &[_][]const u8{ \\pub fn foo() callconv(.C) void { \\ var arr: [10]u8 = [1]u8{ \\ 1, \\ } ++ [1]u8{0} ** 9; \\ _ = @TypeOf(arr); \\ var arr1: [10][*c]u8 = [1][*c]u8{ \\ null, \\ } ++ [1][*c]u8{null} ** 9; \\ _ = @TypeOf(arr1); \\} }); cases.add("enums", \\typedef enum { \\ a, \\ b, \\ c, \\} d; \\enum { \\ e, \\ f = 4, \\ g, \\} h = e; \\struct Baz { \\ enum { \\ i, \\ j, \\ k, \\ } l; \\ d m; \\}; \\enum i { \\ n, \\ o, \\ p, \\}; , &[_][]const u8{ \\pub const a: c_int = 0; \\pub const b: c_int = 1; \\pub const c: c_int = 2; \\pub const d = ++ " " ++ default_enum_type ++ \\; \\pub const e: c_int = 0; \\pub const f: c_int = 4; \\pub const g: c_int = 5; \\const enum_unnamed_1 = ++ " " ++ default_enum_type ++ \\; \\pub export var h: enum_unnamed_1 = @bitCast(c_uint, e); \\pub const i: c_int = 0; \\pub const j: c_int = 1; \\pub const k: c_int = 2; \\const enum_unnamed_2 = ++ " " ++ default_enum_type ++ \\; \\pub const struct_Baz = extern struct { \\ l: enum_unnamed_2, \\ m: d, \\}; \\pub const n: c_int = 0; \\pub const o: c_int = 1; \\pub const p: c_int = 2; \\pub const enum_i = ++ " " ++ default_enum_type ++ \\; , "pub const Baz = struct_Baz;", }); cases.add("#define a char literal", \\#define A_CHAR 'a' , &[_][]const u8{ \\pub const A_CHAR = 'a'; }); cases.add("comment after integer literal", \\#define SDL_INIT_VIDEO 0x00000020 /**< SDL_INIT_VIDEO implies SDL_INIT_EVENTS */ , &[_][]const u8{ \\pub const SDL_INIT_VIDEO = @as(c_int, 0x00000020); }); cases.add("u integer suffix after hex literal", \\#define SDL_INIT_VIDEO 0x00000020u /**< SDL_INIT_VIDEO implies SDL_INIT_EVENTS */ , &[_][]const u8{ \\pub const SDL_INIT_VIDEO = @as(c_uint, 0x00000020); }); cases.add("l integer suffix after hex literal", \\#define SDL_INIT_VIDEO 0x00000020l /**< SDL_INIT_VIDEO implies SDL_INIT_EVENTS */ , &[_][]const u8{ \\pub const SDL_INIT_VIDEO = @as(c_long, 0x00000020); }); cases.add("ul integer suffix after hex literal", \\#define SDL_INIT_VIDEO 0x00000020ul /**< SDL_INIT_VIDEO implies SDL_INIT_EVENTS */ , &[_][]const u8{ \\pub const SDL_INIT_VIDEO = @as(c_ulong, 0x00000020); }); cases.add("lu integer suffix after hex literal", \\#define SDL_INIT_VIDEO 0x00000020lu /**< SDL_INIT_VIDEO implies SDL_INIT_EVENTS */ , &[_][]const u8{ \\pub const SDL_INIT_VIDEO = @as(c_ulong, 0x00000020); }); cases.add("ll integer suffix after hex literal", \\#define SDL_INIT_VIDEO 0x00000020ll /**< SDL_INIT_VIDEO implies SDL_INIT_EVENTS */ , &[_][]const u8{ \\pub const SDL_INIT_VIDEO = @as(c_longlong, 0x00000020); }); cases.add("ull integer suffix after hex literal", \\#define SDL_INIT_VIDEO 0x00000020ull /**< SDL_INIT_VIDEO implies SDL_INIT_EVENTS */ , &[_][]const u8{ \\pub const SDL_INIT_VIDEO = @as(c_ulonglong, 0x00000020); }); cases.add("llu integer suffix after hex literal", \\#define SDL_INIT_VIDEO 0x00000020llu /**< SDL_INIT_VIDEO implies SDL_INIT_EVENTS */ , &[_][]const u8{ \\pub const SDL_INIT_VIDEO = @as(c_ulonglong, 0x00000020); }); if (builtin.zig_backend != .stage1) { cases.add("generate inline func for #define global extern fn", \\extern void (*fn_ptr)(void); \\#define foo fn_ptr \\ \\extern char (*fn_ptr2)(int, float); \\#define bar fn_ptr2 , &[_][]const u8{ \\pub extern var fn_ptr: ?*const fn () callconv(.C) void; , \\pub inline fn foo() void { \\ return fn_ptr.?(); \\} , \\pub extern var fn_ptr2: ?*const fn (c_int, f32) callconv(.C) u8; , \\pub inline fn bar(arg_1: c_int, arg_2: f32) u8 { \\ return fn_ptr2.?(arg_1, arg_2); \\} }); } if (builtin.zig_backend != .stage1) { cases.add("macros with field targets", \\typedef unsigned int GLbitfield; \\typedef void (*PFNGLCLEARPROC) (GLbitfield mask); \\typedef void(*OpenGLProc)(void); \\union OpenGLProcs { \\ OpenGLProc ptr[1]; \\ struct { \\ PFNGLCLEARPROC Clear; \\ } gl; \\}; \\extern union OpenGLProcs glProcs; \\#define glClearUnion glProcs.gl.Clear \\#define glClearPFN PFNGLCLEARPROC , &[_][]const u8{ \\pub const GLbitfield = c_uint; \\pub const PFNGLCLEARPROC = ?*const fn (GLbitfield) callconv(.C) void; \\pub const OpenGLProc = ?*const fn () callconv(.C) void; \\const struct_unnamed_1 = extern struct { \\ Clear: PFNGLCLEARPROC, \\}; \\pub const union_OpenGLProcs = extern union { \\ ptr: [1]OpenGLProc, \\ gl: struct_unnamed_1, \\}; \\pub extern var glProcs: union_OpenGLProcs; , \\pub const glClearPFN = PFNGLCLEARPROC; , \\pub inline fn glClearUnion(arg_2: GLbitfield) void { \\ return glProcs.gl.Clear.?(arg_2); \\} , \\pub const OpenGLProcs = union_OpenGLProcs; }); } cases.add("macro pointer cast", \\#define NRF_GPIO_BASE 0 \\typedef struct { int dummy; } NRF_GPIO_Type; \\#define NRF_GPIO ((NRF_GPIO_Type *) NRF_GPIO_BASE) , &[_][]const u8{ \\pub const NRF_GPIO = @import("std").zig.c_translation.cast([*c]NRF_GPIO_Type, NRF_GPIO_BASE); }); cases.add("basic macro function", \\extern int c; \\#define BASIC(c) (c*2) \\#define FOO(L,b) (L + b) \\#define BAR() (c*c) , &[_][]const u8{ \\pub extern var c: c_int; , \\pub inline fn BASIC(c_1: anytype) @TypeOf(c_1 * @as(c_int, 2)) { \\ return c_1 * @as(c_int, 2); \\} , \\pub inline fn FOO(L: anytype, b: anytype) @TypeOf(L + b) { \\ return L + b; \\} , \\pub inline fn BAR() @TypeOf(c * c) { \\ return c * c; \\} }); cases.add("macro defines string literal with hex", \\#define FOO "aoeu\xab derp" \\#define FOO2 "aoeu\x0007a derp" \\#define FOO_CHAR '\xfF' , &[_][]const u8{ \\pub const FOO = "aoeu\xab derp"; , \\pub const FOO2 = "aoeu\x7a derp"; , \\pub const FOO_CHAR = '\xff'; }); cases.add("macro add", \\#define D3_AHB1PERIPH_BASE 0 \\#define PERIPH_BASE (0x40000000UL) /*!< Base address of : AHB/APB Peripherals */ \\#define D3_APB1PERIPH_BASE (PERIPH_BASE + 0x18000000UL) \\#define RCC_BASE (D3_AHB1PERIPH_BASE + 0x4400UL) , &[_][]const u8{ \\pub const PERIPH_BASE = @as(c_ulong, 0x40000000); , \\pub const D3_APB1PERIPH_BASE = PERIPH_BASE + @as(c_ulong, 0x18000000); , \\pub const RCC_BASE = D3_AHB1PERIPH_BASE + @as(c_ulong, 0x4400); }); cases.add("variable aliasing", \\static long a = 2; \\static long b = 2; \\static int c = 4; \\void foo(char c) { \\ int a; \\ char b = 123; \\ b = (char) a; \\ { \\ int d = 5; \\ } \\ unsigned d = 440; \\} , &[_][]const u8{ \\pub var a: c_long = 2; \\pub var b: c_long = 2; \\pub var c: c_int = 4; \\pub export fn foo(arg_c_1: u8) void { \\ var c_1 = arg_c_1; \\ _ = @TypeOf(c_1); \\ var a_2: c_int = undefined; \\ var b_3: u8 = 123; \\ b_3 = @bitCast(u8, @truncate(i8, a_2)); \\ { \\ var d: c_int = 5; \\ _ = @TypeOf(d); \\ } \\ var d: c_uint = @bitCast(c_uint, @as(c_int, 440)); \\ _ = @TypeOf(d); \\} }); cases.add("comma operator", \\int foo() { \\ 2, 4; \\ return 2, 4, 6; \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ _ = blk: { \\ _ = @as(c_int, 2); \\ break :blk @as(c_int, 4); \\ }; \\ return blk: { \\ _ = blk_1: { \\ _ = @as(c_int, 2); \\ break :blk_1 @as(c_int, 4); \\ }; \\ break :blk @as(c_int, 6); \\ }; \\} }); cases.add("worst-case assign", \\void foo() { \\ int a; \\ int b; \\ a = b = 2; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: c_int = undefined; \\ var b: c_int = undefined; \\ a = blk: { \\ const tmp = @as(c_int, 2); \\ b = tmp; \\ break :blk tmp; \\ }; \\} }); cases.add("while loops", \\int foo() { \\ int a = 5; \\ while (2) \\ a = 2; \\ while (4) { \\ int a = 4; \\ a = 9; \\ return 6, a; \\ } \\ do { \\ int a = 2; \\ a = 12; \\ } while (4); \\ do \\ a = 7; \\ while (4); \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ var a: c_int = 5; \\ while (true) { \\ a = 2; \\ } \\ while (true) { \\ var a_1: c_int = 4; \\ a_1 = 9; \\ return blk: { \\ _ = @as(c_int, 6); \\ break :blk a_1; \\ }; \\ } \\ while (true) { \\ var a_1: c_int = 2; \\ a_1 = 12; \\ } \\ while (true) { \\ a = 7; \\ } \\ return 0; \\} }); cases.add("for loops", \\void foo() { \\ for (int i = 2, b = 4; i + 2; i = 2) { \\ int a = 2; \\ a = 6, 5, 7; \\ } \\ char i = 2; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ { \\ var i: c_int = 2; \\ var b: c_int = 4; \\ _ = @TypeOf(b); \\ while ((i + @as(c_int, 2)) != 0) : (i = 2) { \\ var a: c_int = 2; \\ _ = blk: { \\ _ = blk_1: { \\ a = 6; \\ break :blk_1 @as(c_int, 5); \\ }; \\ break :blk @as(c_int, 7); \\ }; \\ } \\ } \\ var i: u8 = 2; \\ _ = @TypeOf(i); \\} }); cases.add("shadowing primitive types", \\unsigned anyerror = 2; \\#define noreturn _Noreturn \\typedef enum { \\ f32, \\ u32, \\} BadEnum; , &[_][]const u8{ \\pub export var @"anyerror": c_uint = 2; , \\pub const @"noreturn" = @compileError("unable to translate C expr: unexpected token '_Noreturn'"); , \\pub const @"f32": c_int = 0; \\pub const @"u32": c_int = 1; \\pub const BadEnum = c_uint; }); cases.add("floats", \\float a = 3.1415; \\double b = 3.1415; \\int c = 3.1415; \\double d = 3; , &[_][]const u8{ \\pub export var a: f32 = @floatCast(f32, 3.1415); \\pub export var b: f64 = 3.1415; \\pub export var c: c_int = @floatToInt(c_int, 3.1415); \\pub export var d: f64 = 3; }); cases.add("conditional operator", \\int bar(void) { \\ if (2 ? 5 : 5 ? 4 : 6) 2; \\ return 2 ? 5 : 5 ? 4 : 6; \\} , &[_][]const u8{ \\pub export fn bar() c_int { \\ if ((if (true) @as(c_int, 5) else if (true) @as(c_int, 4) else @as(c_int, 6)) != 0) { \\ _ = @as(c_int, 2); \\ } \\ return if (true) @as(c_int, 5) else if (true) @as(c_int, 4) else @as(c_int, 6); \\} }); cases.add("switch on int", \\void switch_fn(int i) { \\ int res = 0; \\ switch (i) { \\ case 0: \\ res = 1; \\ case 1 ... 3: \\ res = 2; \\ default: \\ res = 3 * i; \\ break; \\ break; \\ case 7: { \\ res = 7; \\ break; \\ } \\ case 4: \\ case 5: \\ res = 69; \\ { \\ res = 5; \\ return; \\ } \\ case 6: \\ switch (res) { \\ case 9: break; \\ } \\ res = 1; \\ return; \\ } \\} , &[_][]const u8{ \\pub export fn switch_fn(arg_i: c_int) void { \\ var i = arg_i; \\ var res: c_int = 0; \\ while (true) { \\ switch (i) { \\ @as(c_int, 0) => { \\ res = 1; \\ res = 2; \\ res = @as(c_int, 3) * i; \\ break; \\ }, \\ @as(c_int, 1)...@as(c_int, 3) => { \\ res = 2; \\ res = @as(c_int, 3) * i; \\ break; \\ }, \\ else => { \\ res = @as(c_int, 3) * i; \\ break; \\ }, \\ @as(c_int, 7) => { \\ { \\ res = 7; \\ break; \\ } \\ }, \\ @as(c_int, 4), @as(c_int, 5) => { \\ res = 69; \\ { \\ res = 5; \\ return; \\ } \\ }, \\ @as(c_int, 6) => { \\ while (true) { \\ switch (res) { \\ @as(c_int, 9) => break, \\ else => {}, \\ } \\ break; \\ } \\ res = 1; \\ return; \\ }, \\ } \\ break; \\ } \\} }); if (builtin.os.tag != .windows) { // When clang uses the -windows-none triple it behaves as MSVC and // interprets the inner `struct Bar` as an anonymous structure cases.add("type referenced struct", \\struct Foo { \\ struct Bar{ \\ int b; \\ }; \\ struct Bar c; \\}; , &[_][]const u8{ \\pub const struct_Bar = extern struct { \\ b: c_int, \\}; \\pub const struct_Foo = extern struct { \\ c: struct_Bar, \\}; }); } cases.add("undefined array global", \\int array[100] = {}; , &[_][]const u8{ \\pub export var array: [100]c_int = [1]c_int{0} ** 100; }); cases.add("restrict -> noalias", \\void foo(void *restrict bar, void *restrict); , &[_][]const u8{ \\pub extern fn foo(noalias bar: ?*anyopaque, noalias ?*anyopaque) void; }); cases.add("assign", \\void max(int a) { \\ int tmp; \\ tmp = a; \\ a = tmp; \\} , &[_][]const u8{ \\pub export fn max(arg_a: c_int) void { \\ var a = arg_a; \\ var tmp: c_int = undefined; \\ tmp = a; \\ a = tmp; \\} }); cases.add("chaining assign", \\void max(int a) { \\ int b, c; \\ c = b = a; \\} , &[_][]const u8{ \\pub export fn max(arg_a: c_int) void { \\ var a = arg_a; \\ var b: c_int = undefined; \\ var c: c_int = undefined; \\ c = blk: { \\ const tmp = a; \\ b = tmp; \\ break :blk tmp; \\ }; \\} }); cases.add("anonymous enum", \\enum { \\ One, \\ Two, \\}; , &[_][]const u8{ \\pub const One: c_int = 0; \\pub const Two: c_int = 1; \\const enum_unnamed_1 = ++ " " ++ default_enum_type ++ \\; }); cases.add("c style cast", \\int float_to_int(float a) { \\ return (int)a; \\} , &[_][]const u8{ \\pub export fn float_to_int(arg_a: f32) c_int { \\ var a = arg_a; \\ return @floatToInt(c_int, a); \\} }); cases.add("escape sequences", \\const char *escapes() { \\char a = '\'', \\ b = '\\', \\ c = '\a', \\ d = '\b', \\ e = '\f', \\ f = '\n', \\ g = '\r', \\ h = '\t', \\ i = '\v', \\ j = '\0', \\ k = '\"'; \\ return "\'\\\a\b\f\n\r\t\v\0\""; \\} \\ , &[_][]const u8{ \\pub export fn escapes() [*c]const u8 { \\ var a: u8 = '\''; \\ _ = @TypeOf(a); \\ var b: u8 = '\\'; \\ _ = @TypeOf(b); \\ var c: u8 = '\x07'; \\ _ = @TypeOf(c); \\ var d: u8 = '\x08'; \\ _ = @TypeOf(d); \\ var e: u8 = '\x0c'; \\ _ = @TypeOf(e); \\ var f: u8 = '\n'; \\ _ = @TypeOf(f); \\ var g: u8 = '\r'; \\ _ = @TypeOf(g); \\ var h: u8 = '\t'; \\ _ = @TypeOf(h); \\ var i: u8 = '\x0b'; \\ _ = @TypeOf(i); \\ var j: u8 = '\x00'; \\ _ = @TypeOf(j); \\ var k: u8 = '"'; \\ _ = @TypeOf(k); \\ return "'\\\x07\x08\x0c\n\r\t\x0b\x00\""; \\} }); cases.add("do loop", \\void foo(void) { \\ int a = 2; \\ do { \\ a = a - 1; \\ } while (a); \\ \\ int b = 2; \\ do \\ b = b -1; \\ while (b); \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: c_int = 2; \\ while (true) { \\ a = a - @as(c_int, 1); \\ if (!(a != 0)) break; \\ } \\ var b: c_int = 2; \\ while (true) { \\ b = b - @as(c_int, 1); \\ if (!(b != 0)) break; \\ } \\} }); cases.add("logical and, logical or, on non-bool values, extra parens", \\enum Foo { \\ FooA, \\ FooB, \\ FooC, \\}; \\typedef int SomeTypedef; \\int and_or_non_bool(int a, float b, void *c) { \\ enum Foo d = FooA; \\ int e = (a && b); \\ int f = (b && c); \\ int g = (a && c); \\ int h = (a || b); \\ int i = (b || c); \\ int j = (a || c); \\ int k = (a || (int)d); \\ int l = ((int)d && b); \\ int m = (c || (unsigned int)d); \\ SomeTypedef td = 44; \\ int o = (td || b); \\ int p = (c && td); \\ return ((((((((((e + f) + g) + h) + i) + j) + k) + l) + m) + o) + p); \\} , &[_][]const u8{ \\pub const FooA: c_int = 0; \\pub const FooB: c_int = 1; \\pub const FooC: c_int = 2; \\pub const enum_Foo = ++ " " ++ default_enum_type ++ \\; \\pub const SomeTypedef = c_int; \\pub export fn and_or_non_bool(arg_a: c_int, arg_b: f32, arg_c: ?*anyopaque) c_int { \\ var a = arg_a; \\ var b = arg_b; \\ var c = arg_c; \\ var d: enum_Foo = @bitCast(c_uint, FooA); \\ var e: c_int = @boolToInt((a != 0) and (b != 0)); \\ var f: c_int = @boolToInt((b != 0) and (c != null)); \\ var g: c_int = @boolToInt((a != 0) and (c != null)); \\ var h: c_int = @boolToInt((a != 0) or (b != 0)); \\ var i: c_int = @boolToInt((b != 0) or (c != null)); \\ var j: c_int = @boolToInt((a != 0) or (c != null)); \\ var k: c_int = @boolToInt((a != 0) or (@bitCast(c_int, d) != 0)); \\ var l: c_int = @boolToInt((@bitCast(c_int, d) != 0) and (b != 0)); \\ var m: c_int = @boolToInt((c != null) or (d != 0)); \\ var td: SomeTypedef = 44; \\ var o: c_int = @boolToInt((td != 0) or (b != 0)); \\ var p: c_int = @boolToInt((c != null) and (td != 0)); \\ return (((((((((e + f) + g) + h) + i) + j) + k) + l) + m) + o) + p; \\} , \\pub const Foo = enum_Foo; }); cases.add("qualified struct and enum", \\struct Foo { \\ int x; \\ int y; \\}; \\enum Bar { \\ BarA, \\ BarB, \\}; \\void func(struct Foo *a, enum Bar **b); , &[_][]const u8{ \\pub const struct_Foo = extern struct { \\ x: c_int, \\ y: c_int, \\}; \\pub const BarA: c_int = 0; \\pub const BarB: c_int = 1; \\pub const enum_Bar = ++ " " ++ default_enum_type ++ \\; \\pub extern fn func(a: [*c]struct_Foo, b: [*c][*c]enum_Bar) void; , \\pub const Foo = struct_Foo; \\pub const Bar = enum_Bar; }); cases.add("bitwise binary operators, simpler parens", \\int max(int a, int b) { \\ return (a & b) ^ (a | b); \\} , &[_][]const u8{ \\pub export fn max(arg_a: c_int, arg_b: c_int) c_int { \\ var a = arg_a; \\ var b = arg_b; \\ return (a & b) ^ (a | b); \\} }); cases.add("comparison operators (no if)", // TODO Come up with less contrived tests? Make sure to cover all these comparisons. \\int test_comparisons(int a, int b) { \\ int c = (a < b); \\ int d = (a > b); \\ int e = (a <= b); \\ int f = (a >= b); \\ int g = (c < d); \\ int h = (e < f); \\ int i = (g < h); \\ return i; \\} , &[_][]const u8{ \\pub export fn test_comparisons(arg_a: c_int, arg_b: c_int) c_int { \\ var a = arg_a; \\ var b = arg_b; \\ var c: c_int = @boolToInt(a < b); \\ var d: c_int = @boolToInt(a > b); \\ var e: c_int = @boolToInt(a <= b); \\ var f: c_int = @boolToInt(a >= b); \\ var g: c_int = @boolToInt(c < d); \\ var h: c_int = @boolToInt(e < f); \\ var i: c_int = @boolToInt(g < h); \\ return i; \\} }); cases.add("==, !=", \\int max(int a, int b) { \\ if (a == b) \\ return a; \\ if (a != b) \\ return b; \\ return a; \\} , &[_][]const u8{ \\pub export fn max(arg_a: c_int, arg_b: c_int) c_int { \\ var a = arg_a; \\ var b = arg_b; \\ if (a == b) return a; \\ if (a != b) return b; \\ return a; \\} }); cases.add("typedeffed bool expression", \\typedef char* yes; \\void foo(void) { \\ yes a; \\ if (a) 2; \\} , &[_][]const u8{ \\pub const yes = [*c]u8; \\pub export fn foo() void { \\ var a: yes = undefined; \\ if (a != null) { \\ _ = @as(c_int, 2); \\ } \\} }); cases.add("statement expression", \\int foo(void) { \\ return ({ \\ int a = 1; \\ a; \\ a; \\ }); \\} , &[_][]const u8{ \\pub export fn foo() c_int { \\ return blk: { \\ var a: c_int = 1; \\ _ = @TypeOf(a); \\ break :blk a; \\ }; \\} }); cases.add("field access expression", \\#define ARROW a->b \\#define DOT a.b \\extern struct Foo { \\ int b; \\}a; \\float b = 2.0f; \\void foo(void) { \\ struct Foo *c; \\ a.b; \\ c->b; \\} , &[_][]const u8{ \\pub const struct_Foo = extern struct { \\ b: c_int, \\}; \\pub extern var a: struct_Foo; \\pub export var b: f32 = 2.0; \\pub export fn foo() void { \\ var c: [*c]struct_Foo = undefined; \\ _ = a.b; \\ _ = c.*.b; \\} , \\pub const DOT = a.b; , \\pub const ARROW = a.*.b; }); cases.add("array access", \\#define ACCESS array[2] \\int array[100] = {}; \\int foo(int index) { \\ return array[index]; \\} , &[_][]const u8{ \\pub export var array: [100]c_int = [1]c_int{0} ** 100; \\pub export fn foo(arg_index: c_int) c_int { \\ var index = arg_index; \\ return array[@intCast(c_uint, index)]; \\} , \\pub const ACCESS = array[@intCast(usize, @as(c_int, 2))]; }); cases.add("cast signed array index to unsigned", \\void foo() { \\ int a[10], i = 0; \\ a[i] = 0; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: [10]c_int = undefined; \\ var i: c_int = 0; \\ a[@intCast(c_uint, i)] = 0; \\} }); cases.add("long long array index cast to usize", \\void foo() { \\ long long a[10], i = 0; \\ a[i] = 0; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: [10]c_longlong = undefined; \\ var i: c_longlong = 0; \\ a[@intCast(usize, i)] = 0; \\} }); cases.add("unsigned array index skips cast", \\void foo() { \\ unsigned int a[10], i = 0; \\ a[i] = 0; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: [10]c_uint = undefined; \\ var i: c_uint = 0; \\ a[i] = 0; \\} }); cases.add("macro call", \\#define CALL(arg) bar(arg) \\int bar(int x) { return x; } , &[_][]const u8{ \\pub inline fn CALL(arg: anytype) @TypeOf(bar(arg)) { \\ return bar(arg); \\} }); cases.add("macro call with no args", \\#define CALL(arg) bar() \\int bar(void) { return 0; } , &[_][]const u8{ \\pub inline fn CALL(arg: anytype) @TypeOf(bar()) { \\ _ = @TypeOf(arg); \\ return bar(); \\} }); cases.add("logical and, logical or", \\int max(int a, int b) { \\ if (a < b || a == b) \\ return b; \\ if (a >= b && a == b) \\ return a; \\ return a; \\} , &[_][]const u8{ \\pub export fn max(arg_a: c_int, arg_b: c_int) c_int { \\ var a = arg_a; \\ var b = arg_b; \\ if ((a < b) or (a == b)) return b; \\ if ((a >= b) and (a == b)) return a; \\ return a; \\} }); cases.add("simple if statement", \\int max(int a, int b) { \\ if (a < b) \\ return b; \\ \\ if (a < b) \\ return b; \\ else \\ return a; \\ \\ if (a < b) ; else ; \\} , &[_][]const u8{ \\pub export fn max(arg_a: c_int, arg_b: c_int) c_int { \\ var a = arg_a; \\ var b = arg_b; \\ if (a < b) return b; \\ if (a < b) return b else return a; \\ if (a < b) {} else {} \\ return 0; \\} }); cases.add("if statements", \\void foo() { \\ if (2) { \\ int a = 2; \\ } \\ if (2, 5) { \\ int a = 2; \\ } \\} , &[_][]const u8{ \\pub export fn foo() void { \\ if (true) { \\ var a: c_int = 2; \\ _ = @TypeOf(a); \\ } \\ if ((blk: { \\ _ = @as(c_int, 2); \\ break :blk @as(c_int, 5); \\ }) != 0) { \\ var a: c_int = 2; \\ _ = @TypeOf(a); \\ } \\} }); cases.add("if on non-bool", \\enum SomeEnum { A, B, C }; \\int if_none_bool(int a, float b, void *c, enum SomeEnum d) { \\ if (a) return 0; \\ if (b) return 1; \\ if (c) return 2; \\ if (d) return 3; \\ return 4; \\} , &[_][]const u8{ \\pub const A: c_int = 0; \\pub const B: c_int = 1; \\pub const C: c_int = 2; \\pub const enum_SomeEnum = ++ " " ++ default_enum_type ++ \\; \\pub export fn if_none_bool(arg_a: c_int, arg_b: f32, arg_c: ?*anyopaque, arg_d: enum_SomeEnum) c_int { \\ var a = arg_a; \\ var b = arg_b; \\ var c = arg_c; \\ var d = arg_d; \\ if (a != 0) return 0; \\ if (b != 0) return 1; \\ if (c != null) return 2; \\ if (d != 0) return 3; \\ return 4; \\} }); cases.add("simple data types", \\#include \\int foo(char a, unsigned char b, signed char c); \\int foo(char a, unsigned char b, signed char c); // test a duplicate prototype \\void bar(uint8_t a, uint16_t b, uint32_t c, uint64_t d); \\void baz(int8_t a, int16_t b, int32_t c, int64_t d); , &[_][]const u8{ \\pub extern fn foo(a: u8, b: u8, c: i8) c_int; \\pub extern fn bar(a: u8, b: u16, c: u32, d: u64) void; \\pub extern fn baz(a: i8, b: i16, c: i32, d: i64) void; }); cases.add("simple function", \\int abs(int a) { \\ return a < 0 ? -a : a; \\} , &[_][]const u8{ \\pub export fn abs(arg_a: c_int) c_int { \\ var a = arg_a; \\ return if (a < @as(c_int, 0)) -a else a; \\} }); cases.add("post increment", \\unsigned foo1(unsigned a) { \\ a++; \\ return a; \\} \\int foo2(int a) { \\ a++; \\ return a; \\} \\int *foo3(int *a) { \\ a++; \\ return a; \\} , &[_][]const u8{ \\pub export fn foo1(arg_a: c_uint) c_uint { \\ var a = arg_a; \\ a +%= 1; \\ return a; \\} \\pub export fn foo2(arg_a: c_int) c_int { \\ var a = arg_a; \\ a += 1; \\ return a; \\} \\pub export fn foo3(arg_a: [*c]c_int) [*c]c_int { \\ var a = arg_a; \\ a += 1; \\ return a; \\} }); if (builtin.zig_backend != .stage1) { cases.add("deref function pointer", \\void foo(void) {} \\int baz(void) { return 0; } \\void bar(void) { \\ void(*f)(void) = foo; \\ int(*b)(void) = baz; \\ f(); \\ (*(f))(); \\ foo(); \\ b(); \\ (*(b))(); \\ baz(); \\} , &[_][]const u8{ \\pub export fn foo() void {} \\pub export fn baz() c_int { \\ return 0; \\} \\pub export fn bar() void { \\ var f: ?*const fn () callconv(.C) void = &foo; \\ var b: ?*const fn () callconv(.C) c_int = &baz; \\ f.?(); \\ f.?(); \\ foo(); \\ _ = b.?(); \\ _ = b.?(); \\ _ = baz(); \\} }); } cases.add("pre increment/decrement", \\void foo(void) { \\ int i = 0; \\ unsigned u = 0; \\ ++i; \\ --i; \\ ++u; \\ --u; \\ i = ++i; \\ i = --i; \\ u = ++u; \\ u = --u; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var i: c_int = 0; \\ var u: c_uint = 0; \\ i += 1; \\ i -= 1; \\ u +%= 1; \\ u -%= 1; \\ i = blk: { \\ const ref = &i; \\ ref.* += 1; \\ break :blk ref.*; \\ }; \\ i = blk: { \\ const ref = &i; \\ ref.* -= 1; \\ break :blk ref.*; \\ }; \\ u = blk: { \\ const ref = &u; \\ ref.* +%= 1; \\ break :blk ref.*; \\ }; \\ u = blk: { \\ const ref = &u; \\ ref.* -%= 1; \\ break :blk ref.*; \\ }; \\} }); cases.add("shift right assign", \\int log2(unsigned a) { \\ int i = 0; \\ while (a > 0) { \\ a >>= 1; \\ } \\ return i; \\} , &[_][]const u8{ \\pub export fn log2(arg_a: c_uint) c_int { \\ var a = arg_a; \\ var i: c_int = 0; \\ while (a > @bitCast(c_uint, @as(c_int, 0))) { \\ a >>= @intCast(@import("std").math.Log2Int(c_int), @as(c_int, 1)); \\ } \\ return i; \\} }); cases.add("shift right assign with a fixed size type", \\#include \\int log2(uint32_t a) { \\ int i = 0; \\ while (a > 0) { \\ a >>= 1; \\ } \\ return i; \\} , &[_][]const u8{ \\pub export fn log2(arg_a: u32) c_int { \\ var a = arg_a; \\ var i: c_int = 0; \\ while (a > @bitCast(c_uint, @as(c_int, 0))) { \\ a >>= @intCast(@import("std").math.Log2Int(c_int), @as(c_int, 1)); \\ } \\ return i; \\} }); cases.add("compound assignment operators", \\void foo(void) { \\ int a = 0; \\ unsigned b = 0; \\ a += (a += 1); \\ a -= (a -= 1); \\ a *= (a *= 1); \\ a &= (a &= 1); \\ a |= (a |= 1); \\ a ^= (a ^= 1); \\ a >>= (a >>= 1); \\ a <<= (a <<= 1); \\ a /= (a /= 1); \\ a %= (a %= 1); \\ b /= (b /= 1); \\ b %= (b %= 1); \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: c_int = 0; \\ var b: c_uint = 0; \\ a += blk: { \\ const ref = &a; \\ ref.* += @as(c_int, 1); \\ break :blk ref.*; \\ }; \\ a -= blk: { \\ const ref = &a; \\ ref.* -= @as(c_int, 1); \\ break :blk ref.*; \\ }; \\ a *= blk: { \\ const ref = &a; \\ ref.* *= @as(c_int, 1); \\ break :blk ref.*; \\ }; \\ a &= blk: { \\ const ref = &a; \\ ref.* &= @as(c_int, 1); \\ break :blk ref.*; \\ }; \\ a |= blk: { \\ const ref = &a; \\ ref.* |= @as(c_int, 1); \\ break :blk ref.*; \\ }; \\ a ^= blk: { \\ const ref = &a; \\ ref.* ^= @as(c_int, 1); \\ break :blk ref.*; \\ }; \\ a >>= @intCast(@import("std").math.Log2Int(c_int), blk: { \\ const ref = &a; \\ ref.* >>= @intCast(@import("std").math.Log2Int(c_int), @as(c_int, 1)); \\ break :blk ref.*; \\ }); \\ a <<= @intCast(@import("std").math.Log2Int(c_int), blk: { \\ const ref = &a; \\ ref.* <<= @intCast(@import("std").math.Log2Int(c_int), @as(c_int, 1)); \\ break :blk ref.*; \\ }); \\ a = @divTrunc(a, blk: { \\ const ref = &a; \\ ref.* = @divTrunc(ref.*, @as(c_int, 1)); \\ break :blk ref.*; \\ }); \\ a = @import("std").zig.c_translation.signedRemainder(a, blk: { \\ const ref = &a; \\ ref.* = @import("std").zig.c_translation.signedRemainder(ref.*, @as(c_int, 1)); \\ break :blk ref.*; \\ }); \\ b /= blk: { \\ const ref = &b; \\ ref.* /= @bitCast(c_uint, @as(c_int, 1)); \\ break :blk ref.*; \\ }; \\ b %= blk: { \\ const ref = &b; \\ ref.* %= @bitCast(c_uint, @as(c_int, 1)); \\ break :blk ref.*; \\ }; \\} }); cases.add("compound assignment operators unsigned", \\void foo(void) { \\ unsigned a = 0; \\ a += (a += 1); \\ a -= (a -= 1); \\ a *= (a *= 1); \\ a &= (a &= 1); \\ a |= (a |= 1); \\ a ^= (a ^= 1); \\ a >>= (a >>= 1); \\ a <<= (a <<= 1); \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var a: c_uint = 0; \\ a +%= blk: { \\ const ref = &a; \\ ref.* +%= @bitCast(c_uint, @as(c_int, 1)); \\ break :blk ref.*; \\ }; \\ a -%= blk: { \\ const ref = &a; \\ ref.* -%= @bitCast(c_uint, @as(c_int, 1)); \\ break :blk ref.*; \\ }; \\ a *%= blk: { \\ const ref = &a; \\ ref.* *%= @bitCast(c_uint, @as(c_int, 1)); \\ break :blk ref.*; \\ }; \\ a &= blk: { \\ const ref = &a; \\ ref.* &= @bitCast(c_uint, @as(c_int, 1)); \\ break :blk ref.*; \\ }; \\ a |= blk: { \\ const ref = &a; \\ ref.* |= @bitCast(c_uint, @as(c_int, 1)); \\ break :blk ref.*; \\ }; \\ a ^= blk: { \\ const ref = &a; \\ ref.* ^= @bitCast(c_uint, @as(c_int, 1)); \\ break :blk ref.*; \\ }; \\ a >>= @intCast(@import("std").math.Log2Int(c_uint), blk: { \\ const ref = &a; \\ ref.* >>= @intCast(@import("std").math.Log2Int(c_int), @as(c_int, 1)); \\ break :blk ref.*; \\ }); \\ a <<= @intCast(@import("std").math.Log2Int(c_uint), blk: { \\ const ref = &a; \\ ref.* <<= @intCast(@import("std").math.Log2Int(c_int), @as(c_int, 1)); \\ break :blk ref.*; \\ }); \\} }); cases.add("post increment/decrement", \\void foo(void) { \\ int i = 0; \\ unsigned u = 0; \\ i++; \\ i--; \\ u++; \\ u--; \\ i = i++; \\ i = i--; \\ u = u++; \\ u = u--; \\} , &[_][]const u8{ \\pub export fn foo() void { \\ var i: c_int = 0; \\ var u: c_uint = 0; \\ i += 1; \\ i -= 1; \\ u +%= 1; \\ u -%= 1; \\ i = blk: { \\ const ref = &i; \\ const tmp = ref.*; \\ ref.* += 1; \\ break :blk tmp; \\ }; \\ i = blk: { \\ const ref = &i; \\ const tmp = ref.*; \\ ref.* -= 1; \\ break :blk tmp; \\ }; \\ u = blk: { \\ const ref = &u; \\ const tmp = ref.*; \\ ref.* +%= 1; \\ break :blk tmp; \\ }; \\ u = blk: { \\ const ref = &u; \\ const tmp = ref.*; \\ ref.* -%= 1; \\ break :blk tmp; \\ }; \\} }); if (builtin.zig_backend != .stage1) { cases.add("implicit casts", \\#include \\ \\void fn_int(int x); \\void fn_f32(float x); \\void fn_f64(double x); \\void fn_char(char x); \\void fn_bool(bool x); \\void fn_ptr(void *x); \\ \\void call() { \\ fn_int(3.0f); \\ fn_int(3.0); \\ fn_int('ABCD'); \\ fn_f32(3); \\ fn_f64(3); \\ fn_char('3'); \\ fn_char('\x1'); \\ fn_char(0); \\ fn_f32(3.0f); \\ fn_f64(3.0); \\ fn_bool(123); \\ fn_bool(0); \\ fn_bool(&fn_int); \\ fn_int((int)&fn_int); \\ fn_ptr((void *)42); \\} , &[_][]const u8{ \\pub extern fn fn_int(x: c_int) void; \\pub extern fn fn_f32(x: f32) void; \\pub extern fn fn_f64(x: f64) void; \\pub extern fn fn_char(x: u8) void; \\pub extern fn fn_bool(x: bool) void; \\pub extern fn fn_ptr(x: ?*anyopaque) void; \\pub export fn call() void { \\ fn_int(@floatToInt(c_int, 3.0)); \\ fn_int(@floatToInt(c_int, 3.0)); \\ fn_int(@as(c_int, 1094861636)); \\ fn_f32(@intToFloat(f32, @as(c_int, 3))); \\ fn_f64(@intToFloat(f64, @as(c_int, 3))); \\ fn_char(@bitCast(u8, @truncate(i8, @as(c_int, '3')))); \\ fn_char(@bitCast(u8, @truncate(i8, @as(c_int, '\x01')))); \\ fn_char(@bitCast(u8, @truncate(i8, @as(c_int, 0)))); \\ fn_f32(3.0); \\ fn_f64(3.0); \\ fn_bool(@as(c_int, 123) != 0); \\ fn_bool(@as(c_int, 0) != 0); \\ fn_bool(@ptrToInt(&fn_int) != 0); \\ fn_int(@intCast(c_int, @ptrToInt(&fn_int))); \\ fn_ptr(@intToPtr(?*anyopaque, @as(c_int, 42))); \\} }); } if (builtin.zig_backend != .stage1) { cases.add("function call", \\static void bar(void) { } \\void foo(int *(baz)(void)) { \\ bar(); \\ baz(); \\} , &[_][]const u8{ \\pub fn bar() callconv(.C) void {} \\pub export fn foo(arg_baz: ?*const fn () callconv(.C) [*c]c_int) void { \\ var baz = arg_baz; \\ bar(); \\ _ = baz.?(); \\} }); } cases.add("macro defines string literal with octal", \\#define FOO "aoeu\023 derp" \\#define FOO2 "aoeu\0234 derp" \\#define FOO_CHAR '\077' , &[_][]const u8{ \\pub const FOO = "aoeu\x13 derp"; , \\pub const FOO2 = "aoeu\x134 derp"; , \\pub const FOO_CHAR = '\x3f'; }); cases.add("enums", \\enum Foo { \\ FooA = 2, \\ FooB = 5, \\ Foo1, \\}; , &[_][]const u8{ \\pub const FooA: c_int = 2; \\pub const FooB: c_int = 5; \\pub const Foo1: c_int = 6; \\pub const enum_Foo = ++ " " ++ default_enum_type ++ \\; , \\pub const Foo = enum_Foo; }); cases.add("macro cast", \\#include \\int baz(void *arg) { return 0; } \\#define FOO(bar) baz((void *)(baz)) \\#define BAR (void*) a \\#define BAZ (uint32_t)(2) \\#define a 2 , &[_][]const u8{ \\pub inline fn FOO(bar: anytype) @TypeOf(baz(@import("std").zig.c_translation.cast(?*anyopaque, baz))) { \\ _ = @TypeOf(bar); \\ return baz(@import("std").zig.c_translation.cast(?*anyopaque, baz)); \\} , \\pub const BAR = @import("std").zig.c_translation.cast(?*anyopaque, a); , \\pub const BAZ = @import("std").zig.c_translation.cast(u32, @as(c_int, 2)); }); cases.add("macro with cast to unsigned short, long, and long long", \\#define CURLAUTH_BASIC_BUT_USHORT ((unsigned short) 1) \\#define CURLAUTH_BASIC ((unsigned long) 1) \\#define CURLAUTH_BASIC_BUT_ULONGLONG ((unsigned long long) 1) , &[_][]const u8{ \\pub const CURLAUTH_BASIC_BUT_USHORT = @import("std").zig.c_translation.cast(c_ushort, @as(c_int, 1)); \\pub const CURLAUTH_BASIC = @import("std").zig.c_translation.cast(c_ulong, @as(c_int, 1)); \\pub const CURLAUTH_BASIC_BUT_ULONGLONG = @import("std").zig.c_translation.cast(c_ulonglong, @as(c_int, 1)); }); cases.add("macro conditional operator", \\ int a, b, c; \\#define FOO a ? b : c , &[_][]const u8{ \\pub const FOO = if (a) b else c; }); cases.add("do while as expr", \\static void foo(void) { \\ if (1) \\ do {} while (0); \\} , &[_][]const u8{ \\pub fn foo() callconv(.C) void { \\ if (true) while (true) { \\ if (!false) break; \\ }; \\} }); cases.add("macro comparisons", \\#define MIN(a, b) ((b) < (a) ? (b) : (a)) \\#define MAX(a, b) ((b) > (a) ? (b) : (a)) , &[_][]const u8{ \\pub inline fn MIN(a: anytype, b: anytype) @TypeOf(if (b < a) b else a) { \\ return if (b < a) b else a; \\} , \\pub inline fn MAX(a: anytype, b: anytype) @TypeOf(if (b > a) b else a) { \\ return if (b > a) b else a; \\} }); cases.add("nested assignment", \\int foo(int *p, int x) { \\ return *p++ = x; \\} , &[_][]const u8{ \\pub export fn foo(arg_p: [*c]c_int, arg_x: c_int) c_int { \\ var p = arg_p; \\ var x = arg_x; \\ return blk: { \\ const tmp = x; \\ (blk_1: { \\ const ref = &p; \\ const tmp_2 = ref.*; \\ ref.* += 1; \\ break :blk_1 tmp_2; \\ }).* = tmp; \\ break :blk tmp; \\ }; \\} }); cases.add("widening and truncating integer casting to different signedness", \\unsigned long foo(void) { \\ return -1; \\} \\unsigned short bar(long x) { \\ return x; \\} , &[_][]const u8{ \\pub export fn foo() c_ulong { \\ return @bitCast(c_ulong, @as(c_long, -@as(c_int, 1))); \\} \\pub export fn bar(arg_x: c_long) c_ushort { \\ var x = arg_x; \\ return @bitCast(c_ushort, @truncate(c_short, x)); \\} }); cases.add("arg name aliasing decl which comes after", \\void foo(int bar) { \\ bar = 2; \\} \\int bar = 4; , &[_][]const u8{ \\pub export fn foo(arg_bar_1: c_int) void { \\ var bar_1 = arg_bar_1; \\ bar_1 = 2; \\} \\pub export var bar: c_int = 4; }); cases.add("arg name aliasing macro which comes after", \\void foo(int bar) { \\ bar = 2; \\} \\#define bar 4 , &[_][]const u8{ \\pub export fn foo(arg_bar_1: c_int) void { \\ var bar_1 = arg_bar_1; \\ bar_1 = 2; \\} , \\pub const bar = @as(c_int, 4); }); cases.add("don't export inline functions", \\inline void a(void) {} \\static void b(void) {} \\void c(void) {} \\static void foo() {} , &[_][]const u8{ \\pub fn a() callconv(.C) void {} \\pub fn b() callconv(.C) void {} \\pub export fn c() void {} \\pub fn foo() callconv(.C) void {} }); cases.add("casting away const and volatile", \\void foo(int *a) {} \\void bar(const int *a) { \\ foo((int *)a); \\} \\void baz(volatile int *a) { \\ foo((int *)a); \\} , &[_][]const u8{ \\pub export fn foo(arg_a: [*c]c_int) void { \\ var a = arg_a; \\ _ = @TypeOf(a); \\} \\pub export fn bar(arg_a: [*c]const c_int) void { \\ var a = arg_a; \\ foo(@intToPtr([*c]c_int, @ptrToInt(a))); \\} \\pub export fn baz(arg_a: [*c]volatile c_int) void { \\ var a = arg_a; \\ foo(@intToPtr([*c]c_int, @ptrToInt(a))); \\} }); cases.add("handling of _Bool type", \\_Bool foo(_Bool x) { \\ _Bool a = x != 1; \\ _Bool b = a != 0; \\ _Bool c = foo; \\ return foo(c != b); \\} , &[_][]const u8{ \\pub export fn foo(arg_x: bool) bool { \\ var x = arg_x; \\ var a: bool = @as(c_int, @boolToInt(x)) != @as(c_int, 1); \\ var b: bool = @as(c_int, @boolToInt(a)) != @as(c_int, 0); \\ var c: bool = @ptrToInt(&foo) != 0; \\ return foo(@as(c_int, @boolToInt(c)) != @as(c_int, @boolToInt(b))); \\} }); cases.add("Don't make const parameters mutable", \\int max(const int x, int y) { \\ return (x > y) ? x : y; \\} , &[_][]const u8{ \\pub export fn max(x: c_int, arg_y: c_int) c_int { \\ var y = arg_y; \\ return if (x > y) x else y; \\} }); cases.add("string concatenation in macros", \\#define FOO "hello" \\#define BAR FOO " world" \\#define BAZ "oh, " FOO , &[_][]const u8{ \\pub const FOO = "hello"; , \\pub const BAR = FOO ++ " world"; , \\pub const BAZ = "oh, " ++ FOO; }); cases.add("string concatenation in macros: two defines", \\#define FOO "hello" \\#define BAZ " world" \\#define BAR FOO BAZ , &[_][]const u8{ \\pub const FOO = "hello"; , \\pub const BAZ = " world"; , \\pub const BAR = FOO ++ BAZ; }); cases.add("string concatenation in macros: two strings", \\#define FOO "a" "b" \\#define BAR FOO "c" , &[_][]const u8{ \\pub const FOO = "a" ++ "b"; , \\pub const BAR = FOO ++ "c"; }); cases.add("string concatenation in macros: three strings", \\#define FOO "a" "b" "c" , &[_][]const u8{ \\pub const FOO = "a" ++ "b" ++ "c"; }); cases.add("multibyte character literals", \\#define FOO 'abcd' , &[_][]const u8{ \\pub const FOO = 0x61626364; }); cases.add("Make sure casts are grouped", \\typedef struct \\{ \\ int i; \\} \\*_XPrivDisplay; \\typedef struct _XDisplay Display; \\#define DefaultScreen(dpy) (((_XPrivDisplay)(dpy))->default_screen) \\ , &[_][]const u8{ \\pub inline fn DefaultScreen(dpy: anytype) @TypeOf(@import("std").zig.c_translation.cast(_XPrivDisplay, dpy).*.default_screen) { \\ return @import("std").zig.c_translation.cast(_XPrivDisplay, dpy).*.default_screen; \\} }); cases.add("macro integer literal casts", \\#define NULL ((void*)0) \\#define FOO ((int)0x8000) , &[_][]const u8{ \\pub const NULL = @import("std").zig.c_translation.cast(?*anyopaque, @as(c_int, 0)); , \\pub const FOO = @import("std").zig.c_translation.cast(c_int, @import("std").zig.c_translation.promoteIntLiteral(c_int, 0x8000, .hexadecimal)); }); if (builtin.abi == .msvc) { cases.add("nameless struct fields", \\typedef struct NAMED \\{ \\ long name; \\} NAMED; \\ \\typedef struct ONENAMEWITHSTRUCT \\{ \\ NAMED; \\ long b; \\} ONENAMEWITHSTRUCT; , &[_][]const u8{ \\pub const struct_NAMED = extern struct { \\ name: c_long, \\}; \\pub const NAMED = struct_NAMED; \\pub const struct_ONENAMEWITHSTRUCT = extern struct { \\ unnamed_0: struct_NAMED, \\ b: c_long, \\}; }); } else { cases.add("nameless struct fields", \\typedef struct NAMED \\{ \\ long name; \\} NAMED; \\ \\typedef struct ONENAMEWITHSTRUCT \\{ \\ NAMED; \\ long b; \\} ONENAMEWITHSTRUCT; , &[_][]const u8{ \\pub const struct_NAMED = extern struct { \\ name: c_long, \\}; \\pub const NAMED = struct_NAMED; \\pub const struct_ONENAMEWITHSTRUCT = extern struct { \\ b: c_long, \\}; }); } cases.add("unnamed fields have predictable names", \\struct a { \\ struct {}; \\}; \\struct b { \\ struct {}; \\}; , &[_][]const u8{ \\const struct_unnamed_1 = extern struct {}; \\pub const struct_a = extern struct { \\ unnamed_0: struct_unnamed_1, \\}; \\const struct_unnamed_2 = extern struct {}; \\pub const struct_b = extern struct { \\ unnamed_0: struct_unnamed_2, \\}; }); cases.add("integer literal promotion", \\#define GUARANTEED_TO_FIT_1 1024 \\#define GUARANTEED_TO_FIT_2 10241024L \\#define GUARANTEED_TO_FIT_3 20482048LU \\#define MAY_NEED_PROMOTION_1 10241024 \\#define MAY_NEED_PROMOTION_2 307230723072L \\#define MAY_NEED_PROMOTION_3 819281928192LU \\#define MAY_NEED_PROMOTION_HEX 0x80000000 \\#define MAY_NEED_PROMOTION_OCT 020000000000 , &[_][]const u8{ \\pub const GUARANTEED_TO_FIT_1 = @as(c_int, 1024); \\pub const GUARANTEED_TO_FIT_2 = @as(c_long, 10241024); \\pub const GUARANTEED_TO_FIT_3 = @as(c_ulong, 20482048); \\pub const MAY_NEED_PROMOTION_1 = @import("std").zig.c_translation.promoteIntLiteral(c_int, 10241024, .decimal); \\pub const MAY_NEED_PROMOTION_2 = @import("std").zig.c_translation.promoteIntLiteral(c_long, 307230723072, .decimal); \\pub const MAY_NEED_PROMOTION_3 = @import("std").zig.c_translation.promoteIntLiteral(c_ulong, 819281928192, .decimal); \\pub const MAY_NEED_PROMOTION_HEX = @import("std").zig.c_translation.promoteIntLiteral(c_int, 0x80000000, .hexadecimal); \\pub const MAY_NEED_PROMOTION_OCT = @import("std").zig.c_translation.promoteIntLiteral(c_int, 0o20000000000, .octal); }); cases.add("demote un-implemented builtins", \\#define FOO(X) __builtin_alloca_with_align((X), 8) , &[_][]const u8{ \\pub const FOO = @compileError("unable to translate macro: undefined identifier `__builtin_alloca_with_align`"); }); cases.add("null sentinel arrays when initialized from string literal. Issue #8256", \\#include \\char zero[0] = "abc"; \\uint32_t zero_w[0] = U"💯💯💯"; \\char empty_incomplete[] = ""; \\uint32_t empty_incomplete_w[] = U""; \\char empty_constant[100] = ""; \\uint32_t empty_constant_w[100] = U""; \\char incomplete[] = "abc"; \\uint32_t incomplete_w[] = U"💯💯💯"; \\char truncated[1] = "abc"; \\uint32_t truncated_w[1] = U"💯💯💯"; \\char extend[5] = "a"; \\uint32_t extend_w[5] = U"💯"; \\char no_null[3] = "abc"; \\uint32_t no_null_w[3] = U"💯💯💯"; , &[_][]const u8{ \\pub export var zero: [0]u8 = [0]u8{}; \\pub export var zero_w: [0]u32 = [0]u32{}; \\pub export var empty_incomplete: [1]u8 = [1]u8{0} ** 1; \\pub export var empty_incomplete_w: [1]u32 = [1]u32{0} ** 1; \\pub export var empty_constant: [100]u8 = [1]u8{0} ** 100; \\pub export var empty_constant_w: [100]u32 = [1]u32{0} ** 100; \\pub export var incomplete: [3:0]u8 = "abc".*; \\pub export var incomplete_w: [3:0]u32 = [3:0]u32{ \\ '\u{1f4af}', \\ '\u{1f4af}', \\ '\u{1f4af}', \\}; \\pub export var truncated: [1]u8 = "abc"[0..1].*; \\pub export var truncated_w: [1]u32 = [1]u32{ \\ '\u{1f4af}', \\}; \\pub export var extend: [5]u8 = "a"[0..1].* ++ [1]u8{0} ** 4; \\pub export var extend_w: [5]u32 = [1]u32{ \\ '\u{1f4af}', \\} ++ [1]u32{0} ** 4; \\pub export var no_null: [3]u8 = "abc".*; \\pub export var no_null_w: [3]u32 = [3]u32{ \\ '\u{1f4af}', \\ '\u{1f4af}', \\ '\u{1f4af}', \\}; }); cases.add("global assembly", \\__asm__(".globl func\n\t" \\ ".type func, @function\n\t" \\ "func:\n\t" \\ ".cfi_startproc\n\t" \\ "movl $42, %eax\n\t" \\ "ret\n\t" \\ ".cfi_endproc"); , &[_][]const u8{ \\comptime { \\ asm (".globl func\n\t.type func, @function\n\tfunc:\n\t.cfi_startproc\n\tmovl $42, %eax\n\tret\n\t.cfi_endproc"); \\} }); cases.add("Demote function that initializes opaque struct", \\struct my_struct { \\ unsigned a: 15; \\ unsigned: 2; \\ unsigned b: 15; \\}; \\void initialize(void) { \\ struct my_struct S = {.a = 1, .b = 2}; \\} , &[_][]const u8{ \\warning: local variable has opaque type , \\warning: unable to translate function, demoted to extern \\pub extern fn initialize() void; }); cases.add("Demote function that dereferences opaque type", \\struct my_struct { \\ unsigned a: 1; \\}; \\void deref(struct my_struct *s) { \\ *s; \\} , &[_][]const u8{ \\warning: cannot dereference opaque type , \\warning: unable to translate function, demoted to extern \\pub extern fn deref(arg_s: ?*struct_my_struct) void; }); cases.add("Demote function that dereference types that contain opaque type", \\struct inner { \\ _Atomic int a; \\}; \\struct outer { \\ int thing; \\ struct inner sub_struct; \\}; \\void deref(struct outer *s) { \\ *s; \\} , &[_][]const u8{ \\pub const struct_inner = opaque {}; , \\pub const struct_outer = extern struct { \\ thing: c_int, \\ sub_struct: struct_inner, \\}; , \\warning: unable to translate function, demoted to extern , \\pub extern fn deref(arg_s: ?*struct_outer) void; }); cases.add("Function prototype declared within function", \\int foo(void) { \\ extern int bar(int, int); \\ return bar(1, 2); \\} , &[_][]const u8{ \\pub extern fn bar(c_int, c_int) c_int; \\pub export fn foo() c_int { \\ return bar(@as(c_int, 1), @as(c_int, 2)); \\} }); cases.add("static local variable zero-initialized if no initializer", \\struct FOO {int x; int y;}; \\int bar(void) { \\ static struct FOO foo; \\ return foo.x; \\} , &[_][]const u8{ \\pub const struct_FOO = extern struct { \\ x: c_int, \\ y: c_int, \\}; \\pub export fn bar() c_int { \\ const foo = struct { \\ var static: struct_FOO = @import("std").mem.zeroes(struct_FOO); \\ }; \\ return foo.static.x; \\} }); cases.add("macro with nontrivial cast", \\#define MAP_FAILED ((void *) -1) \\typedef long long LONG_PTR; \\#define INVALID_HANDLE_VALUE ((void *)(LONG_PTR)-1) , &[_][]const u8{ \\pub const MAP_FAILED = @import("std").zig.c_translation.cast(?*anyopaque, -@as(c_int, 1)); \\pub const INVALID_HANDLE_VALUE = @import("std").zig.c_translation.cast(?*anyopaque, @import("std").zig.c_translation.cast(LONG_PTR, -@as(c_int, 1))); }); cases.add("discard unused local variables and function parameters", \\#define FOO(A, B) (A) \\int bar(int x, int y) { \\ return x; \\} , &[_][]const u8{ \\pub export fn bar(arg_x: c_int, arg_y: c_int) c_int { \\ var x = arg_x; \\ var y = arg_y; \\ _ = @TypeOf(y); \\ return x; \\} , \\pub inline fn FOO(A: anytype, B: anytype) @TypeOf(A) { \\ _ = @TypeOf(B); \\ return A; \\} }); cases.add("Use @ syntax for bare underscore identifier in macro or public symbol", \\#define FOO _ \\int _ = 42; , &[_][]const u8{ \\pub const FOO = @"_"; , \\pub export var @"_": c_int = 42; }); cases.add("Macro matching", \\#define FOO(X) (X ## U) , &[_][]const u8{ \\pub const FOO = @import("std").zig.c_translation.Macros.U_SUFFIX; }); cases.add("Simple array access of pointer with non-negative integer constant", \\void foo(int *p) { \\ p[0]; \\ p[1]; \\} , &[_][]const u8{ \\_ = p[@intCast(c_uint, @as(c_int, 0))]; , \\_ = p[@intCast(c_uint, @as(c_int, 1))]; }); cases.add("Undefined macro identifier", \\#define FOO BAR , &[_][]const u8{ \\pub const FOO = @compileError("unable to translate macro: undefined identifier `BAR`"); }); cases.add("Macro redefines builtin", \\#define FOO __builtin_popcount , &[_][]const u8{ \\pub const FOO = __builtin_popcount; }); cases.add("Only consider public decls in `isBuiltinDefined`", \\#define FOO std , &[_][]const u8{ \\pub const FOO = @compileError("unable to translate macro: undefined identifier `std`"); }); cases.add("Macro without a value", \\#define FOO , &[_][]const u8{ \\pub const FOO = ""; }); cases.add("leading zeroes", \\#define O_RDONLY 00 \\#define HELLO 000 \\#define ZERO 0 \\#define WORLD 00000123 , &[_][]const u8{ \\pub const O_RDONLY = @as(c_int, 0o0); \\pub const HELLO = @as(c_int, 0o00); \\pub const ZERO = @as(c_int, 0); \\pub const WORLD = @as(c_int, 0o0000123); }); }