const std = @import("../../std.zig"); const maxInt = std.math.maxInt; const linux = std.os.linux; const SYS = linux.SYS; const socklen_t = linux.socklen_t; const iovec = std.os.iovec; const iovec_const = std.os.iovec_const; const uid_t = linux.uid_t; const gid_t = linux.gid_t; const pid_t = linux.pid_t; const stack_t = linux.stack_t; const sigset_t = linux.sigset_t; const sockaddr = linux.sockaddr; const timespec = linux.timespec; pub fn syscall0(number: SYS) usize { return asm volatile ("int $0x80" : [ret] "={eax}" (-> usize), : [number] "{eax}" (@enumToInt(number)), : "memory" ); } pub fn syscall1(number: SYS, arg1: usize) usize { return asm volatile ("int $0x80" : [ret] "={eax}" (-> usize), : [number] "{eax}" (@enumToInt(number)), [arg1] "{ebx}" (arg1), : "memory" ); } pub fn syscall2(number: SYS, arg1: usize, arg2: usize) usize { return asm volatile ("int $0x80" : [ret] "={eax}" (-> usize), : [number] "{eax}" (@enumToInt(number)), [arg1] "{ebx}" (arg1), [arg2] "{ecx}" (arg2), : "memory" ); } pub fn syscall3(number: SYS, arg1: usize, arg2: usize, arg3: usize) usize { return asm volatile ("int $0x80" : [ret] "={eax}" (-> usize), : [number] "{eax}" (@enumToInt(number)), [arg1] "{ebx}" (arg1), [arg2] "{ecx}" (arg2), [arg3] "{edx}" (arg3), : "memory" ); } pub fn syscall4(number: SYS, arg1: usize, arg2: usize, arg3: usize, arg4: usize) usize { return asm volatile ("int $0x80" : [ret] "={eax}" (-> usize), : [number] "{eax}" (@enumToInt(number)), [arg1] "{ebx}" (arg1), [arg2] "{ecx}" (arg2), [arg3] "{edx}" (arg3), [arg4] "{esi}" (arg4), : "memory" ); } pub fn syscall5(number: SYS, arg1: usize, arg2: usize, arg3: usize, arg4: usize, arg5: usize) usize { return asm volatile ("int $0x80" : [ret] "={eax}" (-> usize), : [number] "{eax}" (@enumToInt(number)), [arg1] "{ebx}" (arg1), [arg2] "{ecx}" (arg2), [arg3] "{edx}" (arg3), [arg4] "{esi}" (arg4), [arg5] "{edi}" (arg5), : "memory" ); } pub fn syscall6( number: SYS, arg1: usize, arg2: usize, arg3: usize, arg4: usize, arg5: usize, arg6: usize, ) usize { // The 6th argument is passed via memory as we're out of registers if ebp is // used as frame pointer. We push arg6 value on the stack before changing // ebp or esp as the compiler may reference it as an offset relative to one // of those two registers. return asm volatile ( \\ push %[arg6] \\ push %%ebp \\ mov 4(%%esp), %%ebp \\ int $0x80 \\ pop %%ebp \\ add $4, %%esp : [ret] "={eax}" (-> usize), : [number] "{eax}" (@enumToInt(number)), [arg1] "{ebx}" (arg1), [arg2] "{ecx}" (arg2), [arg3] "{edx}" (arg3), [arg4] "{esi}" (arg4), [arg5] "{edi}" (arg5), [arg6] "rm" (arg6), : "memory" ); } pub fn socketcall(call: usize, args: [*]usize) usize { return asm volatile ("int $0x80" : [ret] "={eax}" (-> usize), : [number] "{eax}" (@enumToInt(SYS.socketcall)), [arg1] "{ebx}" (call), [arg2] "{ecx}" (@ptrToInt(args)), : "memory" ); } const CloneFn = std.meta.FnPtr(fn (arg: usize) callconv(.C) u8); /// This matches the libc clone function. pub extern fn clone(func: CloneFn, stack: usize, flags: u32, arg: usize, ptid: *i32, tls: usize, ctid: *i32) usize; pub fn restore() callconv(.Naked) void { switch (@import("builtin").zig_backend) { .stage2_c => return asm volatile ( \\ movl %[number], %%eax \\ int $0x80 : : [number] "i" (@enumToInt(SYS.sigreturn)), : "memory" ), else => return asm volatile ("int $0x80" : : [number] "{eax}" (@enumToInt(SYS.sigreturn)), : "memory" ), } } pub fn restore_rt() callconv(.Naked) void { switch (@import("builtin").zig_backend) { .stage2_c => return asm volatile ( \\ movl %[number], %%eax \\ int $0x80 : : [number] "i" (@enumToInt(SYS.rt_sigreturn)), : "memory" ), else => return asm volatile ("int $0x80" : : [number] "{eax}" (@enumToInt(SYS.rt_sigreturn)), : "memory" ), } } pub const O = struct { pub const CREAT = 0o100; pub const EXCL = 0o200; pub const NOCTTY = 0o400; pub const TRUNC = 0o1000; pub const APPEND = 0o2000; pub const NONBLOCK = 0o4000; pub const DSYNC = 0o10000; pub const SYNC = 0o4010000; pub const RSYNC = 0o4010000; pub const DIRECTORY = 0o200000; pub const NOFOLLOW = 0o400000; pub const CLOEXEC = 0o2000000; pub const ASYNC = 0o20000; pub const DIRECT = 0o40000; pub const LARGEFILE = 0o100000; pub const NOATIME = 0o1000000; pub const PATH = 0o10000000; pub const TMPFILE = 0o20200000; pub const NDELAY = NONBLOCK; }; pub const F = struct { pub const DUPFD = 0; pub const GETFD = 1; pub const SETFD = 2; pub const GETFL = 3; pub const SETFL = 4; pub const SETOWN = 8; pub const GETOWN = 9; pub const SETSIG = 10; pub const GETSIG = 11; pub const GETLK = 12; pub const SETLK = 13; pub const SETLKW = 14; pub const SETOWN_EX = 15; pub const GETOWN_EX = 16; pub const GETOWNER_UIDS = 17; pub const RDLCK = 0; pub const WRLCK = 1; pub const UNLCK = 2; }; pub const LOCK = struct { pub const SH = 1; pub const EX = 2; pub const NB = 4; pub const UN = 8; }; pub const MAP = struct { pub const NORESERVE = 0x4000; pub const GROWSDOWN = 0x0100; pub const DENYWRITE = 0x0800; pub const EXECUTABLE = 0x1000; pub const LOCKED = 0x2000; pub const @"32BIT" = 0x40; }; pub const MMAP2_UNIT = 4096; pub const VDSO = struct { pub const CGT_SYM = "__vdso_clock_gettime"; pub const CGT_VER = "LINUX_2.6"; }; pub const ARCH = struct {}; pub const Flock = extern struct { type: i16, whence: i16, start: off_t, len: off_t, pid: pid_t, }; pub const msghdr = extern struct { name: ?*sockaddr, namelen: socklen_t, iov: [*]iovec, iovlen: i32, control: ?*anyopaque, controllen: socklen_t, flags: i32, }; pub const msghdr_const = extern struct { name: ?*const sockaddr, namelen: socklen_t, iov: [*]const iovec_const, iovlen: i32, control: ?*const anyopaque, controllen: socklen_t, flags: i32, }; pub const blksize_t = i32; pub const nlink_t = u32; pub const time_t = isize; 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, __dev_padding: u32, __ino_truncated: u32, mode: mode_t, nlink: nlink_t, uid: uid_t, gid: gid_t, rdev: dev_t, __rdev_padding: u32, size: off_t, blksize: blksize_t, blocks: blkcnt_t, atim: timespec, mtim: timespec, ctim: timespec, ino: ino_t, pub fn atime(self: @This()) timespec { return self.atim; } pub fn mtime(self: @This()) timespec { return self.mtim; } pub fn ctime(self: @This()) timespec { return self.ctim; } }; pub const timeval = extern struct { tv_sec: i32, tv_usec: i32, }; pub const timezone = extern struct { tz_minuteswest: i32, tz_dsttime: i32, }; pub const mcontext_t = extern struct { gregs: [19]usize, fpregs: [*]u8, oldmask: usize, cr2: usize, }; pub const REG = struct { pub const GS = 0; pub const FS = 1; pub const ES = 2; pub const DS = 3; pub const EDI = 4; pub const ESI = 5; pub const EBP = 6; pub const ESP = 7; pub const EBX = 8; pub const EDX = 9; pub const ECX = 10; pub const EAX = 11; pub const TRAPNO = 12; pub const ERR = 13; pub const EIP = 14; pub const CS = 15; pub const EFL = 16; pub const UESP = 17; pub const SS = 18; }; pub const ucontext_t = extern struct { flags: usize, link: ?*ucontext_t, stack: stack_t, mcontext: mcontext_t, sigmask: sigset_t, regspace: [64]u64, }; pub const Elf_Symndx = u32; pub const user_desc = packed struct { entry_number: u32, base_addr: u32, limit: u32, seg_32bit: u1, contents: u2, read_exec_only: u1, limit_in_pages: u1, seg_not_present: u1, useable: u1, }; /// socketcall() call numbers pub const SC = struct { pub const socket = 1; pub const bind = 2; pub const connect = 3; pub const listen = 4; pub const accept = 5; pub const getsockname = 6; pub const getpeername = 7; pub const socketpair = 8; pub const send = 9; pub const recv = 10; pub const sendto = 11; pub const recvfrom = 12; pub const shutdown = 13; pub const setsockopt = 14; pub const getsockopt = 15; pub const sendmsg = 16; pub const recvmsg = 17; pub const accept4 = 18; pub const recvmmsg = 19; pub const sendmmsg = 20; };