const builtin = @import("builtin"); const std = @import("../../std.zig"); const SYS = std.os.linux.SYS; pub fn syscall0(number: SYS) u32 { return asm volatile ("trap0(#1)" : [ret] "={r0}" (-> u32), : [number] "{r6}" (@intFromEnum(number)), : .{ .memory = true }); } pub fn syscall1(number: SYS, arg1: u32) u32 { return asm volatile ("trap0(#1)" : [ret] "={r0}" (-> u32), : [number] "{r6}" (@intFromEnum(number)), [arg1] "{r0}" (arg1), : .{ .memory = true }); } pub fn syscall2(number: SYS, arg1: u32, arg2: u32) u32 { return asm volatile ("trap0(#1)" : [ret] "={r0}" (-> u32), : [number] "{r6}" (@intFromEnum(number)), [arg1] "{r0}" (arg1), [arg2] "{r1}" (arg2), : .{ .memory = true }); } pub fn syscall3(number: SYS, arg1: u32, arg2: u32, arg3: u32) u32 { return asm volatile ("trap0(#1)" : [ret] "={r0}" (-> u32), : [number] "{r6}" (@intFromEnum(number)), [arg1] "{r0}" (arg1), [arg2] "{r1}" (arg2), [arg3] "{r2}" (arg3), : .{ .memory = true }); } pub fn syscall4(number: SYS, arg1: u32, arg2: u32, arg3: u32, arg4: u32) u32 { return asm volatile ("trap0(#1)" : [ret] "={r0}" (-> u32), : [number] "{r6}" (@intFromEnum(number)), [arg1] "{r0}" (arg1), [arg2] "{r1}" (arg2), [arg3] "{r2}" (arg3), [arg4] "{r3}" (arg4), : .{ .memory = true }); } pub fn syscall5(number: SYS, arg1: u32, arg2: u32, arg3: u32, arg4: u32, arg5: u32) u32 { return asm volatile ("trap0(#1)" : [ret] "={r0}" (-> u32), : [number] "{r6}" (@intFromEnum(number)), [arg1] "{r0}" (arg1), [arg2] "{r1}" (arg2), [arg3] "{r2}" (arg3), [arg4] "{r3}" (arg4), [arg5] "{r4}" (arg5), : .{ .memory = true }); } pub fn syscall6( number: SYS, arg1: u32, arg2: u32, arg3: u32, arg4: u32, arg5: u32, arg6: u32, ) u32 { return asm volatile ("trap0(#1)" : [ret] "={r0}" (-> u32), : [number] "{r6}" (@intFromEnum(number)), [arg1] "{r0}" (arg1), [arg2] "{r1}" (arg2), [arg3] "{r2}" (arg3), [arg4] "{r3}" (arg4), [arg5] "{r4}" (arg5), [arg6] "{r5}" (arg6), : .{ .memory = true }); } pub fn clone() callconv(.naked) u32 { // __clone(func, stack, flags, arg, ptid, tls, ctid) // r0, r1, r2, r3, r4, r5, +0 // // syscall(SYS_clone, flags, stack, ptid, ctid, tls) // r6 r0, r1, r2, r3, r4 asm volatile ( \\ allocframe(#8) \\ \\ r11 = r0 \\ r10 = r3 \\ \\ r6 = #220 // SYS_clone \\ r0 = r2 \\ r1 = and(r1, #-8) \\ r2 = r4 \\ r3 = memw(r30 + #8) \\ r4 = r5 \\ trap0(#1) \\ \\ p0 = cmp.eq(r0, #0) \\ if (!p0) dealloc_return ); if (builtin.unwind_tables != .none or !builtin.strip_debug_info) asm volatile ( \\ .cfi_undefined r31 ); asm volatile ( \\ r30 = #0 \\ r31 = #0 \\ \\ r0 = r10 \\ callr r11 \\ \\ r6 = #93 // SYS_exit \\ r0 = #0 \\ trap0(#1) ); } pub const blksize_t = i32; pub const nlink_t = u32; pub const time_t = i64; pub const mode_t = u32; pub const off_t = i64; pub const ino_t = u64; pub const dev_t = u64; pub const blkcnt_t = i64; // The `stat` definition used by the Linux kernel. pub const Stat = extern struct { dev: dev_t, ino: ino_t, mode: mode_t, nlink: nlink_t, uid: std.os.linux.uid_t, gid: std.os.linux.gid_t, rdev: dev_t, __pad: u32, size: off_t, blksize: blksize_t, __pad2: i32, blocks: blkcnt_t, atim: std.os.linux.timespec, mtim: std.os.linux.timespec, ctim: std.os.linux.timespec, __unused: [2]u32, pub fn atime(self: @This()) std.os.linux.timespec { return self.atim; } pub fn mtime(self: @This()) std.os.linux.timespec { return self.mtim; } pub fn ctime(self: @This()) std.os.linux.timespec { return self.ctim; } }; pub const VDSO = void;