zig/lib/std/os/linux/powerpc.zig

const builtin = @import("builtin");
const std = @import("../../std.zig");
const SYS = std.os.linux.SYS;

pub fn syscall0(number: SYS) u32 {
    // r0 is both an input register and a clobber. musl and glibc achieve this with
    // a "+" constraint, which isn't supported in Zig, so instead we separately list
    // r0 as both an input and an output. (Listing it as an input and a clobber would
    // cause the C backend to emit invalid code; see #25209.)
    var r0_out: u32 = undefined;
    return asm volatile (
        \\ sc
        \\ bns+ 1f
        \\ neg 3, 3
        \\ 1:
        : [ret] "={r3}" (-> u32),
          [r0_out] "={r0}" (r0_out),
        : [number] "{r0}" (@intFromEnum(number)),
        : .{ .memory = true, .cr0 = true, .r4 = true, .r5 = true, .r6 = true, .r7 = true, .r8 = true, .r9 = true, .r10 = true, .r11 = true, .r12 = true, .ctr = true, .xer = true });
}

pub fn syscall1(number: SYS, arg1: u32) u32 {
    // r0 is both an input and a clobber.
    var r0_out: u32 = undefined;
    return asm volatile (
        \\ sc
        \\ bns+ 1f
        \\ neg 3, 3
        \\ 1:
        : [ret] "={r3}" (-> u32),
          [r0_out] "={r0}" (r0_out),
        : [number] "{r0}" (@intFromEnum(number)),
          [arg1] "{r3}" (arg1),
        : .{ .memory = true, .cr0 = true, .r4 = true, .r5 = true, .r6 = true, .r7 = true, .r8 = true, .r9 = true, .r10 = true, .r11 = true, .r12 = true, .ctr = true, .xer = true });
}

pub fn syscall2(number: SYS, arg1: u32, arg2: u32) u32 {
    // These registers are both inputs and clobbers.
    var r0_out: u32 = undefined;
    var r4_out: u32 = undefined;
    return asm volatile (
        \\ sc
        \\ bns+ 1f
        \\ neg 3, 3
        \\ 1:
        : [ret] "={r3}" (-> u32),
          [r0_out] "={r0}" (r0_out),
          [r4_out] "={r4}" (r4_out),
        : [number] "{r0}" (@intFromEnum(number)),
          [arg1] "{r3}" (arg1),
          [arg2] "{r4}" (arg2),
        : .{ .memory = true, .cr0 = true, .r5 = true, .r6 = true, .r7 = true, .r8 = true, .r9 = true, .r10 = true, .r11 = true, .r12 = true, .ctr = true, .xer = true });
}

pub fn syscall3(number: SYS, arg1: u32, arg2: u32, arg3: u32) u32 {
    // These registers are both inputs and clobbers.
    var r0_out: u32 = undefined;
    var r4_out: u32 = undefined;
    var r5_out: u32 = undefined;
    return asm volatile (
        \\ sc
        \\ bns+ 1f
        \\ neg 3, 3
        \\ 1:
        : [ret] "={r3}" (-> u32),
          [r0_out] "={r0}" (r0_out),
          [r4_out] "={r4}" (r4_out),
          [r5_out] "={r5}" (r5_out),
        : [number] "{r0}" (@intFromEnum(number)),
          [arg1] "{r3}" (arg1),
          [arg2] "{r4}" (arg2),
          [arg3] "{r5}" (arg3),
        : .{ .memory = true, .cr0 = true, .r6 = true, .r7 = true, .r8 = true, .r9 = true, .r10 = true, .r11 = true, .r12 = true, .ctr = true, .xer = true });
}

pub fn syscall4(number: SYS, arg1: u32, arg2: u32, arg3: u32, arg4: u32) u32 {
    // These registers are both inputs and clobbers.
    var r0_out: u32 = undefined;
    var r4_out: u32 = undefined;
    var r5_out: u32 = undefined;
    var r6_out: u32 = undefined;
    return asm volatile (
        \\ sc
        \\ bns+ 1f
        \\ neg 3, 3
        \\ 1:
        : [ret] "={r3}" (-> u32),
          [r0_out] "={r0}" (r0_out),
          [r4_out] "={r4}" (r4_out),
          [r5_out] "={r5}" (r5_out),
          [r6_out] "={r6}" (r6_out),
        : [number] "{r0}" (@intFromEnum(number)),
          [arg1] "{r3}" (arg1),
          [arg2] "{r4}" (arg2),
          [arg3] "{r5}" (arg3),
          [arg4] "{r6}" (arg4),
        : .{ .memory = true, .cr0 = true, .r7 = true, .r8 = true, .r9 = true, .r10 = true, .r11 = true, .r12 = true, .ctr = true, .xer = true });
}

pub fn syscall5(number: SYS, arg1: u32, arg2: u32, arg3: u32, arg4: u32, arg5: u32) u32 {
    // These registers are both inputs and clobbers.
    var r0_out: u32 = undefined;
    var r4_out: u32 = undefined;
    var r5_out: u32 = undefined;
    var r6_out: u32 = undefined;
    var r7_out: u32 = undefined;
    return asm volatile (
        \\ sc
        \\ bns+ 1f
        \\ neg 3, 3
        \\ 1:
        : [ret] "={r3}" (-> u32),
          [r0_out] "={r0}" (r0_out),
          [r4_out] "={r4}" (r4_out),
          [r5_out] "={r5}" (r5_out),
          [r6_out] "={r6}" (r6_out),
          [r7_out] "={r7}" (r7_out),
        : [number] "{r0}" (@intFromEnum(number)),
          [arg1] "{r3}" (arg1),
          [arg2] "{r4}" (arg2),
          [arg3] "{r5}" (arg3),
          [arg4] "{r6}" (arg4),
          [arg5] "{r7}" (arg5),
        : .{ .memory = true, .cr0 = true, .r8 = true, .r9 = true, .r10 = true, .r11 = true, .r12 = true, .ctr = true, .xer = true });
}

pub fn syscall6(
    number: SYS,
    arg1: u32,
    arg2: u32,
    arg3: u32,
    arg4: u32,
    arg5: u32,
    arg6: u32,
) u32 {
    // These registers are both inputs and clobbers.
    var r0_out: u32 = undefined;
    var r4_out: u32 = undefined;
    var r5_out: u32 = undefined;
    var r6_out: u32 = undefined;
    var r7_out: u32 = undefined;
    var r8_out: u32 = undefined;
    return asm volatile (
        \\ sc
        \\ bns+ 1f
        \\ neg 3, 3
        \\ 1:
        : [ret] "={r3}" (-> u32),
          [r0_out] "={r0}" (r0_out),
          [r4_out] "={r4}" (r4_out),
          [r5_out] "={r5}" (r5_out),
          [r6_out] "={r6}" (r6_out),
          [r7_out] "={r7}" (r7_out),
          [r8_out] "={r8}" (r8_out),
        : [number] "{r0}" (@intFromEnum(number)),
          [arg1] "{r3}" (arg1),
          [arg2] "{r4}" (arg2),
          [arg3] "{r5}" (arg3),
          [arg4] "{r6}" (arg4),
          [arg5] "{r7}" (arg5),
          [arg6] "{r8}" (arg6),
        : .{ .memory = true, .cr0 = true, .r9 = true, .r10 = true, .r11 = true, .r12 = true, .ctr = true, .xer = true });
}

pub fn clone() callconv(.naked) u32 {
    // __clone(func, stack, flags, arg, ptid, tls, ctid)
    //         3,    4,     5,     6,   7,    8,   9
    //
    // syscall(SYS_clone, flags, stack, ptid, tls, ctid)
    //         0          3,     4,     5,    6,   7
    asm volatile (
        \\ # store non-volatile regs r29, r30 on stack in order to put our
        \\ # start func and its arg there
        \\ stwu 29, -16(1)
        \\ stw 30, 4(1)
        \\
        \\ # save r3 (func) into r29, and r6(arg) into r30
        \\ mr 29, 3
        \\ mr 30, 6
        \\
        \\ # create initial stack frame for new thread
        \\ clrrwi 4, 4, 4
        \\ li 0, 0
        \\ stwu 0, -16(4)
        \\
        \\ #move c into first arg
        \\ mr 3, 5
        \\ #mr 4, 4
        \\ mr 5, 7
        \\ mr 6, 8
        \\ mr 7, 9
        \\
        \\ # move syscall number into r0
        \\ li 0, 120 # SYS_clone
        \\
        \\ sc
        \\
        \\ # check for syscall error
        \\ bns+ 1f # jump to label 1 if no summary overflow.
        \\ #else
        \\ neg 3, 3 #negate the result (errno)
        \\ 1:
        \\ # compare sc result with 0
        \\ cmpwi cr7, 3, 0
        \\
        \\ # if not 0, restore stack and return
        \\ beq cr7, 2f
        \\ lwz 29, 0(1)
        \\ lwz 30, 4(1)
        \\ addi 1, 1, 16
        \\ blr
        \\
        \\ #else: we're the child
        \\ 2:
    );
    if (builtin.unwind_tables != .none or !builtin.strip_debug_info) asm volatile (
        \\ .cfi_undefined lr
    );
    asm volatile (
        \\ li 31, 0
        \\ mtlr 0
        \\
        \\ #call funcptr: move arg (d) into r3
        \\ mr 3, 30
        \\ #move r29 (funcptr) into CTR reg
        \\ mtctr 29
        \\ # call CTR reg
        \\ bctrl
        \\ # mov SYS_exit into r0 (the exit param is already in r3)
        \\ li 0, 1
        \\ sc
    );
}

pub const restore = restore_rt;

pub fn restore_rt() callconv(.naked) noreturn {
    switch (builtin.zig_backend) {
        .stage2_c => asm volatile (
            \\ li 0, %[number]
            \\ sc
            :
            : [number] "i" (@intFromEnum(SYS.rt_sigreturn)),
        ),
        else => asm volatile (
            \\ sc
            :
            : [number] "{r0}" (@intFromEnum(SYS.rt_sigreturn)),
        ),
    }
}

pub const VDSO = struct {
    pub const CGT_SYM = "__kernel_clock_gettime";
    pub const CGT_VER = "LINUX_2.6.15";
};

pub const blksize_t = i32;
pub const nlink_t = u32;
pub const time_t = i32;
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,
    __rdev_padding: i16,
    size: off_t,
    blksize: blksize_t,
    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;
    }
};