const builtin = @import("builtin"); const std = @import("../../std.zig"); const SYS = std.os.linux.SYS; pub const syscall_arg_t = u32; pub fn syscall0( number: SYS, ) u32 { return asm volatile ( \\ t 0x10 \\ bcc 1f \\ nop \\ neg %%o0 \\1: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(number)), : .{ .memory = true, .xcc = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub fn syscall1( number: SYS, arg1: syscall_arg_t, ) u32 { return asm volatile ( \\ t 0x10 \\ bcc 1f \\ nop \\ neg %%o0 \\1: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(number)), [arg1] "{o0}" (arg1), : .{ .memory = true, .xcc = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub fn syscall2( number: SYS, arg1: syscall_arg_t, arg2: syscall_arg_t, ) u32 { return asm volatile ( \\ t 0x10 \\ bcc 1f \\ nop \\ neg %%o0 \\1: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(number)), [arg1] "{o0}" (arg1), [arg2] "{o1}" (arg2), : .{ .memory = true, .xcc = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub fn syscall3( number: SYS, arg1: syscall_arg_t, arg2: syscall_arg_t, arg3: syscall_arg_t, ) u32 { return asm volatile ( \\ t 0x10 \\ bcc 1f \\ nop \\ neg %%o0 \\1: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(number)), [arg1] "{o0}" (arg1), [arg2] "{o1}" (arg2), [arg3] "{o2}" (arg3), : .{ .memory = true, .xcc = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub fn syscall4( number: SYS, arg1: syscall_arg_t, arg2: syscall_arg_t, arg3: syscall_arg_t, arg4: syscall_arg_t, ) u32 { return asm volatile ( \\ t 0x10 \\ bcc 1f \\ nop \\ neg %%o0 \\1: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(number)), [arg1] "{o0}" (arg1), [arg2] "{o1}" (arg2), [arg3] "{o2}" (arg3), [arg4] "{o3}" (arg4), : .{ .memory = true, .xcc = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub fn syscall5( number: SYS, arg1: syscall_arg_t, arg2: syscall_arg_t, arg3: syscall_arg_t, arg4: syscall_arg_t, arg5: syscall_arg_t, ) u32 { return asm volatile ( \\ t 0x10 \\ bcc 1f \\ nop \\ neg %%o0 \\1: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(number)), [arg1] "{o0}" (arg1), [arg2] "{o1}" (arg2), [arg3] "{o2}" (arg3), [arg4] "{o3}" (arg4), [arg5] "{o4}" (arg5), : .{ .memory = true, .xcc = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub fn syscall6( number: SYS, arg1: syscall_arg_t, arg2: syscall_arg_t, arg3: syscall_arg_t, arg4: syscall_arg_t, arg5: syscall_arg_t, arg6: syscall_arg_t, ) u32 { return asm volatile ( \\ t 0x10 \\ bcc 1f \\ nop \\ neg %%o0 \\1: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(number)), [arg1] "{o0}" (arg1), [arg2] "{o1}" (arg2), [arg3] "{o2}" (arg3), [arg4] "{o3}" (arg4), [arg5] "{o4}" (arg5), [arg6] "{o5}" (arg6), : .{ .memory = true, .xcc = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub fn syscall_pipe( fd: *[2]std.os.linux.fd_t, ) u32 { return asm volatile ( \\ mov %[arg], %%g3 \\ t 0x10 \\ bcc 1f \\ nop \\ # Return the error code \\ ba 2f \\ neg %%o0 \\1: \\ st %%o0, [%%g3+0] \\ st %%o1, [%%g3+4] \\ clr %%o0 \\2: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(SYS.pipe)), [arg] "r" (fd), : .{ .memory = true, .g3 = true }); } pub fn syscall_fork() u32 { // Linux/sparc fork() returns two values in %o0 and %o1: // - On the parent's side, %o0 is the child's PID and %o1 is 0. // - On the child's side, %o0 is the parent's PID and %o1 is 1. // We need to clear the child's %o0 so that the return values // conform to the libc convention. return asm volatile ( \\ t 0x10 \\ bcc 1f \\ nop \\ ba 2f \\ neg %%o0 \\1: \\ # Clear the child's %%o0 \\ dec %%o1 \\ and %%o1, %%o0, %%o0 \\2: : [ret] "={o0}" (-> u32), : [number] "{g1}" (@intFromEnum(SYS.fork)), : .{ .memory = true, .xcc = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub fn clone() callconv(.naked) u32 { // __clone(func, stack, flags, arg, ptid, tls, ctid) // i0, i1, i2, i3, i4, i5, sp // // syscall(SYS_clone, flags, stack, ptid, tls, ctid) // g1 o0, o1, o2, o3, o4 asm volatile ( \\ save %%sp, -96, %%sp \\ \\ // clone() on SPARC can fail with EFAULT if %%sp points to uncommitted memory, so flush \\ // all register windows up to this point to ensure that the kernel has enough committed \\ // memory for its stack frame. \\ save %%sp, -96, %%sp \\ t 0x3 \\ restore \\ \\ # Save the func pointer and the arg pointer \\ mov %%i0, %%g2 \\ mov %%i3, %%g3 \\ \\ # Shuffle the arguments \\ mov 217, %%g1 // SYS_clone \\ mov %%i2, %%o0 \\ \\ # Align, and add some extra space for the initial frame \\ and %%i1, -8, %%i1 \\ sub %%i1, 96 + 2047, %%o1 \\ \\ mov %%i4, %%o2 \\ mov %%i5, %%o3 \\ ld [%%fp + 92 + 2047], %%o4 \\ t 0x10 \\ bcs 1f \\ nop \\ # The child pid is returned in o0 while o1 tells if this \\ # process is the child (=1) or the parent (=0). \\ tst %%o1 \\ bne 2f \\ nop \\ \\ # Parent process, return the child pid \\ mov %%o0, %%i0 \\ ret \\ restore \\ \\1: \\ # The syscall failed \\ sub %%g0, %%o0, %%i0 \\ ret \\ restore \\ \\2: \\ # Child process ); if (builtin.unwind_tables != .none or !builtin.strip_debug_info) asm volatile ( \\ .cfi_undefined %%i7 ); asm volatile ( \\ mov %%g0, %%fp \\ mov %%g0, %%i7 \\ \\ # call func(arg) \\ call %%g2 \\ mov %%g3, %%o0 \\ # Exit \\ mov 1, %%g1 // SYS_exit \\ t 0x10 ); } pub const restore = restore_rt; // Need to use C ABI here instead of naked // to prevent an infinite loop when calling rt_sigreturn. pub fn restore_rt() callconv(.c) void { return asm volatile ("t 0x10" : : [number] "{g1}" (@intFromEnum(SYS.rt_sigreturn)), : .{ .memory = true, .xcc = true, .o0 = true, .o1 = true, .o2 = true, .o3 = true, .o4 = true, .o5 = true, .o7 = true }); } pub const VDSO = struct { pub const CGT_SYM = "__vdso_clock_gettime"; pub const CGT_VER = "LINUX_2.6"; }; pub const time_t = i32;