const Kqueue = @This(); const builtin = @import("builtin"); const std = @import("../std.zig"); const Io = std.Io; const Dir = Io.Dir; const File = Io.File; const net = Io.net; const assert = std.debug.assert; const Allocator = std.mem.Allocator; const Alignment = std.mem.Alignment; const IpAddress = Io.net.IpAddress; const errnoBug = Io.Threaded.errnoBug; const closeFd = Io.Threaded.closeFd; const posix = std.posix; const posixSocketModeProtocol = Io.Threaded.posixSocketModeProtocol; /// Must be a thread-safe allocator. gpa: Allocator, mutex: Io.Mutex, main_fiber_buffer: [@sizeOf(Fiber) + Fiber.max_result_size]u8 align(@alignOf(Fiber)), threads: Thread.List, /// Empirically saw >128KB being used by the self-hosted backend to panic. const idle_stack_size = 256 * 1024; const max_idle_search = 4; const max_steal_ready_search = 4; const max_iovecs_len = 8; const changes_buffer_len = 64; const Thread = struct { thread: std.Thread, idle_context: Io.fiber.Context, current_context: *Io.fiber.Context, ready_queue: ?*Fiber, kq_fd: posix.fd_t, idle_search_index: u32, steal_ready_search_index: u32, /// For ensuring multiple fibers waiting on the same file descriptor and /// filter use the same kevent. wait_queues: std.AutoArrayHashMapUnmanaged(WaitQueueKey, *Fiber), const WaitQueueKey = struct { ident: usize, filter: i32, }; const canceling: ?*Thread = @ptrFromInt(@alignOf(Thread)); threadlocal var self: *Thread = undefined; fn current() *Thread { return self; } fn currentFiber(thread: *Thread) *Fiber { return @fieldParentPtr("context", thread.current_context); } const List = struct { allocated: []Thread, reserved: u32, active: u32, }; fn deinit(thread: *Thread, gpa: Allocator) void { closeFd(thread.kq_fd); assert(thread.wait_queues.count() == 0); thread.wait_queues.deinit(gpa); thread.* = undefined; } }; const Fiber = struct { required_align: void align(4), context: Io.fiber.Context, awaiter: ?*Fiber, queue_next: ?*Fiber, cancel_thread: ?*Thread, awaiting_completions: std.StaticBitSet(3), const finished: ?*Fiber = @ptrFromInt(@alignOf(Thread)); const max_result_align: Alignment = .@"16"; const max_result_size = max_result_align.forward(64); /// This includes any stack realignments that need to happen, and also the /// initial frame return address slot and argument frame, depending on target. const min_stack_size = 4 * 1024 * 1024; const max_context_align: Alignment = .@"16"; const max_context_size = max_context_align.forward(1024); const max_closure_size: usize = @sizeOf(AsyncClosure); const max_closure_align: Alignment = .of(AsyncClosure); const allocation_size = std.mem.alignForward( usize, max_closure_align.max(max_context_align).forward( max_result_align.forward(@sizeOf(Fiber)) + max_result_size + min_stack_size, ) + max_closure_size + max_context_size, std.heap.page_size_max, ); fn allocate(k: *Kqueue) error{OutOfMemory}!*Fiber { return @ptrCast(try k.gpa.alignedAlloc(u8, .of(Fiber), allocation_size)); } fn allocatedSlice(f: *Fiber) []align(@alignOf(Fiber)) u8 { return @as([*]align(@alignOf(Fiber)) u8, @ptrCast(f))[0..allocation_size]; } fn allocatedEnd(f: *Fiber) [*]u8 { const allocated_slice = f.allocatedSlice(); return allocated_slice[allocated_slice.len..].ptr; } fn resultPointer(f: *Fiber, comptime Result: type) *Result { return @ptrCast(@alignCast(f.resultBytes(.of(Result)))); } fn resultBytes(f: *Fiber, alignment: Alignment) [*]u8 { return @ptrFromInt(alignment.forward(@intFromPtr(f) + @sizeOf(Fiber))); } fn enterCancelRegion(fiber: *Fiber, thread: *Thread) error{Canceled}!void { if (@cmpxchgStrong( ?*Thread, &fiber.cancel_thread, null, thread, .acq_rel, .acquire, )) |cancel_thread| { assert(cancel_thread == Thread.canceling); return error.Canceled; } } fn exitCancelRegion(fiber: *Fiber, thread: *Thread) void { if (@cmpxchgStrong( ?*Thread, &fiber.cancel_thread, thread, null, .acq_rel, .acquire, )) |cancel_thread| assert(cancel_thread == Thread.canceling); } const Queue = struct { head: *Fiber, tail: *Fiber }; }; fn recycle(k: *Kqueue, fiber: *Fiber) void { std.log.debug("recyling {*}", .{fiber}); assert(fiber.queue_next == null); k.gpa.free(fiber.allocatedSlice()); } pub const InitOptions = struct { n_threads: ?usize = null, }; pub const InitError = Allocator.Error || CreateFileDescriptorError; pub fn init(k: *Kqueue, gpa: Allocator, options: InitOptions) !void { assert(options.n_threads != 0); const n_threads = @max(1, options.n_threads orelse std.Thread.getCpuCount() catch 1); const threads_size = n_threads * @sizeOf(Thread); const idle_stack_end_offset = std.mem.alignForward(usize, threads_size + idle_stack_size, std.heap.page_size_max); const allocated_slice = try gpa.alignedAlloc(u8, .of(Thread), idle_stack_end_offset); errdefer gpa.free(allocated_slice); k.* = .{ .gpa = gpa, .mutex = .init, .main_fiber_buffer = undefined, .threads = .{ .allocated = @ptrCast(allocated_slice[0..threads_size]), .reserved = 1, .active = 1, }, }; const main_fiber: *Fiber = @ptrCast(&k.main_fiber_buffer); main_fiber.* = .{ .required_align = {}, .context = undefined, .awaiter = null, .queue_next = null, .cancel_thread = null, .awaiting_completions = .empty, }; const main_thread = &k.threads.allocated[0]; Thread.self = main_thread; const idle_stack_end: [*]align(16) usize = @ptrCast(@alignCast(allocated_slice[idle_stack_end_offset..].ptr)); (idle_stack_end - 1)[0..1].* = .{@intFromPtr(k)}; main_thread.* = .{ .thread = undefined, .idle_context = switch (builtin.cpu.arch) { .aarch64 => .{ .sp = @intFromPtr(idle_stack_end), .fp = 0, .pc = @intFromPtr(&mainIdleEntry), }, .x86_64 => .{ .rsp = @intFromPtr(idle_stack_end - 1), .rbp = 0, .rip = @intFromPtr(&mainIdleEntry), }, else => @compileError("unimplemented architecture"), }, .current_context = &main_fiber.context, .ready_queue = null, .kq_fd = try createFileDescriptor(), .idle_search_index = 1, .steal_ready_search_index = 1, .wait_queues = .empty, }; errdefer closeFd(main_thread.kq_fd); std.log.debug("created main idle {*}", .{&main_thread.idle_context}); std.log.debug("created main {*}", .{main_fiber}); } pub fn deinit(k: *Kqueue) void { const active_threads = @atomicLoad(u32, &k.threads.active, .acquire); for (k.threads.allocated[0..active_threads]) |*thread| { const ready_fiber = @atomicLoad(?*Fiber, &thread.ready_queue, .monotonic); assert(ready_fiber == null or ready_fiber == Fiber.finished); // pending async } k.yield(null, .exit); const main_thread = &k.threads.allocated[0]; const gpa = k.gpa; main_thread.deinit(gpa); const allocated_ptr: [*]align(@alignOf(Thread)) u8 = @ptrCast(@alignCast(k.threads.allocated.ptr)); const idle_stack_end_offset = std.mem.alignForward(usize, k.threads.allocated.len * @sizeOf(Thread) + idle_stack_size, std.heap.page_size_max); for (k.threads.allocated[1..active_threads]) |*thread| thread.thread.join(); gpa.free(allocated_ptr[0..idle_stack_end_offset]); k.* = undefined; } pub const CreateFileDescriptorError = error{ /// The per-process limit on the number of open file descriptors has been reached. ProcessFdQuotaExceeded, /// The system-wide limit on the total number of open files has been reached. SystemFdQuotaExceeded, } || Io.UnexpectedError; pub fn createFileDescriptor() CreateFileDescriptorError!posix.fd_t { const rc = posix.system.kqueue(); switch (posix.errno(rc)) { .SUCCESS => return @intCast(rc), .MFILE => return error.ProcessFdQuotaExceeded, .NFILE => return error.SystemFdQuotaExceeded, else => |err| return posix.unexpectedErrno(err), } } fn findReadyFiber(k: *Kqueue, thread: *Thread) ?*Fiber { if (@atomicRmw(?*Fiber, &thread.ready_queue, .Xchg, Fiber.finished, .acquire)) |ready_fiber| { @atomicStore(?*Fiber, &thread.ready_queue, ready_fiber.queue_next, .release); ready_fiber.queue_next = null; return ready_fiber; } const active_threads = @atomicLoad(u32, &k.threads.active, .acquire); for (0..@min(max_steal_ready_search, active_threads)) |_| { defer thread.steal_ready_search_index += 1; if (thread.steal_ready_search_index == active_threads) thread.steal_ready_search_index = 0; const steal_ready_search_thread = &k.threads.allocated[0..active_threads][thread.steal_ready_search_index]; if (steal_ready_search_thread == thread) continue; const ready_fiber = @atomicLoad(?*Fiber, &steal_ready_search_thread.ready_queue, .acquire) orelse continue; if (ready_fiber == Fiber.finished) continue; if (@cmpxchgWeak( ?*Fiber, &steal_ready_search_thread.ready_queue, ready_fiber, null, .acquire, .monotonic, )) |_| continue; @atomicStore(?*Fiber, &thread.ready_queue, ready_fiber.queue_next, .release); ready_fiber.queue_next = null; return ready_fiber; } // couldn't find anything to do, so we are now open for business @atomicStore(?*Fiber, &thread.ready_queue, null, .monotonic); return null; } fn yield(k: *Kqueue, maybe_ready_fiber: ?*Fiber, pending_task: SwitchMessage.PendingTask) void { const thread: *Thread = .current(); const ready_context = if (maybe_ready_fiber orelse k.findReadyFiber(thread)) |ready_fiber| &ready_fiber.context else &thread.idle_context; const message: SwitchMessage = .{ .contexts = .{ .old = thread.current_context, .new = ready_context, }, .pending_task = pending_task, }; std.log.debug("switching from {*} to {*}", .{ message.contexts.old, message.contexts.new }); contextSwitch(&message).handle(k); } fn schedule(k: *Kqueue, thread: *Thread, ready_queue: Fiber.Queue) void { { var fiber = ready_queue.head; while (true) { std.log.debug("scheduling {*}", .{fiber}); fiber = fiber.queue_next orelse break; } assert(fiber == ready_queue.tail); } // shared fields of previous `Thread` must be initialized before later ones are marked as active const new_thread_index = @atomicLoad(u32, &k.threads.active, .acquire); for (0..@min(max_idle_search, new_thread_index)) |_| { defer thread.idle_search_index += 1; if (thread.idle_search_index == new_thread_index) thread.idle_search_index = 0; const idle_search_thread = &k.threads.allocated[0..new_thread_index][thread.idle_search_index]; if (idle_search_thread == thread) continue; if (@cmpxchgWeak( ?*Fiber, &idle_search_thread.ready_queue, null, ready_queue.head, .release, .monotonic, )) |_| continue; const changes = [_]posix.Kevent{ .{ .ident = 0, .filter = std.c.EVFILT.USER, .flags = std.c.EV.ADD | std.c.EV.ONESHOT, .fflags = std.c.NOTE.TRIGGER, .data = 0, .udata = @intFromEnum(Completion.UserData.wakeup), }, }; // If an error occurs it only pessimises scheduling. _ = kevent(idle_search_thread.kq_fd, &changes, &.{}, null) catch |err| { // TODO handle EINTR for cancellation purposes @panic(@errorName(err)); // TODO }; return; } spawn_thread: { // previous failed reservations must have completed before retrying if (new_thread_index == k.threads.allocated.len or @cmpxchgWeak( u32, &k.threads.reserved, new_thread_index, new_thread_index + 1, .acquire, .monotonic, ) != null) break :spawn_thread; const new_thread = &k.threads.allocated[new_thread_index]; const next_thread_index = new_thread_index + 1; new_thread.* = .{ .thread = undefined, .idle_context = undefined, .current_context = &new_thread.idle_context, .ready_queue = ready_queue.head, .kq_fd = createFileDescriptor() catch |err| { @atomicStore(u32, &k.threads.reserved, new_thread_index, .release); // no more access to `thread` after giving up reservation std.log.warn("unable to create worker thread due to kqueue init failure: {t}", .{err}); break :spawn_thread; }, .idle_search_index = 0, .steal_ready_search_index = 0, .wait_queues = .empty, }; new_thread.thread = std.Thread.spawn(.{ .stack_size = idle_stack_size, .allocator = k.gpa, }, threadEntry, .{ k, new_thread_index }) catch |err| { closeFd(new_thread.kq_fd); @atomicStore(u32, &k.threads.reserved, new_thread_index, .release); // no more access to `thread` after giving up reservation std.log.warn("unable to create worker thread due spawn failure: {s}", .{@errorName(err)}); break :spawn_thread; }; // shared fields of `Thread` must be initialized before being marked active @atomicStore(u32, &k.threads.active, next_thread_index, .release); return; } // nobody wanted it, so just queue it on ourselves while (@cmpxchgWeak( ?*Fiber, &thread.ready_queue, ready_queue.tail.queue_next, ready_queue.head, .acq_rel, .acquire, )) |old_head| ready_queue.tail.queue_next = old_head; } fn mainIdle(k: *Kqueue, message: *const SwitchMessage) callconv(.withStackAlign(.c, @max(@alignOf(Thread), @alignOf(Io.fiber.Context)))) noreturn { message.handle(k); k.idle(&k.threads.allocated[0]); k.yield(@ptrCast(&k.main_fiber_buffer), .nothing); unreachable; // switched to dead fiber } fn threadEntry(k: *Kqueue, index: u32) void { const thread: *Thread = &k.threads.allocated[index]; Thread.self = thread; std.log.debug("created thread idle {*}", .{&thread.idle_context}); k.idle(thread); thread.deinit(k.gpa); } const Completion = struct { const UserData = enum(usize) { unused, wakeup, cleanup, exit, /// *Fiber _, }; /// Corresponds to Kevent field. flags: u16, /// Corresponds to Kevent field. fflags: u32, /// Corresponds to Kevent field. data: isize, }; fn idle(k: *Kqueue, thread: *Thread) void { var events_buffer: [changes_buffer_len]posix.Kevent = undefined; var maybe_ready_fiber: ?*Fiber = null; while (true) { while (maybe_ready_fiber orelse k.findReadyFiber(thread)) |ready_fiber| { k.yield(ready_fiber, .nothing); maybe_ready_fiber = null; } const n = kevent(thread.kq_fd, &.{}, &events_buffer, null) catch |err| { // TODO handle EINTR for cancellation purposes @panic(@errorName(err)); // TODO }; var maybe_ready_queue: ?Fiber.Queue = null; for (events_buffer[0..n]) |event| switch (@as(Completion.UserData, @enumFromInt(event.udata))) { .unused => unreachable, // bad submission queued? .wakeup => {}, .cleanup => @panic("failed to notify other threads that we are exiting"), .exit => { assert(maybe_ready_fiber == null and maybe_ready_queue == null); // pending async return; }, _ => { const event_head_fiber: *Fiber = @ptrFromInt(event.udata); const event_tail_fiber = thread.wait_queues.fetchSwapRemove(.{ .ident = event.ident, .filter = event.filter, }).?.value; assert(event_tail_fiber.queue_next == null); // TODO reevaluate this logic event_head_fiber.resultPointer(Completion).* = .{ .flags = event.flags, .fflags = event.fflags, .data = event.data, }; queue_ready: { const head: *Fiber = if (maybe_ready_fiber == null) f: { maybe_ready_fiber = event_head_fiber; const next = event_head_fiber.queue_next orelse break :queue_ready; event_head_fiber.queue_next = null; break :f next; } else event_head_fiber; if (maybe_ready_queue) |*ready_queue| { ready_queue.tail.queue_next = head; ready_queue.tail = event_tail_fiber; } else { maybe_ready_queue = .{ .head = head, .tail = event_tail_fiber }; } } }, }; if (maybe_ready_queue) |ready_queue| k.schedule(thread, ready_queue); } } const SwitchMessage = struct { contexts: Io.fiber.Switch, pending_task: PendingTask, const PendingTask = union(enum) { nothing, reschedule, recycle: *Fiber, register_awaiter: *?*Fiber, exit, }; fn handle(message: *const SwitchMessage, k: *Kqueue) void { const thread: *Thread = .current(); thread.current_context = message.contexts.new; switch (message.pending_task) { .nothing => {}, .reschedule => if (message.contexts.old != &thread.idle_context) { const prev_fiber: *Fiber = @alignCast(@fieldParentPtr("context", message.contexts.old)); assert(prev_fiber.queue_next == null); k.schedule(thread, .{ .head = prev_fiber, .tail = prev_fiber }); }, .recycle => |fiber| { k.recycle(fiber); }, .register_awaiter => |awaiter| { const prev_fiber: *Fiber = @alignCast(@fieldParentPtr("context", message.contexts.old)); assert(prev_fiber.queue_next == null); if (@atomicRmw(?*Fiber, awaiter, .Xchg, prev_fiber, .acq_rel) == Fiber.finished) k.schedule(thread, .{ .head = prev_fiber, .tail = prev_fiber }); }, .exit => for (k.threads.allocated[0..@atomicLoad(u32, &k.threads.active, .acquire)]) |*each_thread| { const changes = [_]posix.Kevent{ .{ .ident = 0, .filter = std.c.EVFILT.USER, .flags = std.c.EV.ADD | std.c.EV.ONESHOT, .fflags = std.c.NOTE.TRIGGER, .data = 0, .udata = @intFromEnum(Completion.UserData.exit), }, }; _ = kevent(each_thread.kq_fd, &changes, &.{}, null) catch |err| { // TODO handle EINTR for cancellation purposes @panic(@errorName(err)); // TODO }; }, } } }; inline fn contextSwitch(message: *const SwitchMessage) *const SwitchMessage { return @fieldParentPtr("contexts", Io.fiber.contextSwitch(&message.contexts)); } fn mainIdleEntry() callconv(.naked) void { switch (builtin.cpu.arch) { .x86_64 => asm volatile ( \\ movq (%%rsp), %%rdi \\ jmp %[mainIdle:P] : : [mainIdle] "X" (&mainIdle), ), .aarch64 => asm volatile ( \\ ldr x0, [sp, #-8] \\ b %[mainIdle] : : [mainIdle] "X" (&mainIdle), ), else => |arch| @compileError("unimplemented architecture: " ++ @tagName(arch)), } } fn fiberEntry() callconv(.naked) void { switch (builtin.cpu.arch) { .x86_64 => asm volatile ( \\ leaq 8(%%rsp), %%rdi \\ jmp %[AsyncClosure_call:P] : : [AsyncClosure_call] "X" (&AsyncClosure.call), ), .aarch64 => asm volatile ( \\ mov x0, sp \\ b %[AsyncClosure_call] : : [AsyncClosure_call] "X" (&AsyncClosure.call), ), else => |arch| @compileError("unimplemented architecture: " ++ @tagName(arch)), } } const AsyncClosure = struct { kqueue: *Kqueue, fiber: *Fiber, start: Io.AnyFuture.Start, result_align: Alignment, already_awaited: bool, fn contextPointer(closure: *AsyncClosure) [*]align(Fiber.max_context_align.toByteUnits()) u8 { return @alignCast(@as([*]u8, @ptrCast(closure)) + @sizeOf(AsyncClosure)); } fn call(closure: *AsyncClosure, message: *const SwitchMessage) callconv(.withStackAlign(.c, @alignOf(AsyncClosure))) noreturn { message.handle(closure.kqueue); const fiber = closure.fiber; std.log.debug("{*} performing async", .{fiber}); closure.start(closure.contextPointer(), fiber.resultBytes(closure.result_align)); const awaiter = @atomicRmw(?*Fiber, &fiber.awaiter, .Xchg, Fiber.finished, .acq_rel); const ready_awaiter = r: { const a = awaiter orelse break :r null; if (@atomicRmw(bool, &closure.already_awaited, .Xchg, true, .acq_rel)) break :r null; break :r a; }; closure.kqueue.yield(ready_awaiter, .nothing); unreachable; // switched to dead fiber } fn fromFiber(fiber: *Fiber) *AsyncClosure { return @ptrFromInt(Fiber.max_context_align.max(.of(AsyncClosure)).backward( @intFromPtr(fiber.allocatedEnd()) - Fiber.max_context_size, ) - @sizeOf(AsyncClosure)); } }; pub fn io(k: *Kqueue) Io { return .{ .userdata = k, .vtable = &.{ .async = async, .concurrent = concurrent, .await = await, .cancel = cancel, .groupAsync = groupAsync, .groupConcurrent = groupConcurrent, .groupAwait = groupAwait, .groupCancel = groupCancel, .dirCreateDir = dirCreateDir, .dirCreateDirPath = dirCreateDirPath, .dirCreateDirPathOpen = dirCreateDirPathOpen, .dirStat = dirStat, .dirStatFile = dirStatFile, .fileStat = fileStat, .dirAccess = dirAccess, .dirCreateFile = dirCreateFile, .dirOpenFile = dirOpenFile, .dirOpenDir = dirOpenDir, .dirClose = dirClose, .fileClose = fileClose, .fileWriteStreaming = fileWriteStreaming, .fileWritePositional = fileWritePositional, .fileReadStreaming = fileReadStreaming, .fileReadPositional = fileReadPositional, .fileSeekBy = fileSeekBy, .fileSeekTo = fileSeekTo, .now = now, .sleep = sleep, .netListenIp = netListenIp, .netListenUnix = netListenUnix, .netAccept = netAccept, .netBindIp = netBindIp, .netConnectIp = netConnectIp, .netConnectUnix = netConnectUnix, .netClose = netClose, .netShutdown = netShutdown, .netRead = netRead, .netWrite = netWrite, .netSend = netSend, .netReceive = netReceive, .netInterfaceNameResolve = netInterfaceNameResolve, .netInterfaceName = netInterfaceName, .netLookup = netLookup, }, }; } fn async( userdata: ?*anyopaque, result: []u8, result_alignment: std.mem.Alignment, context: []const u8, context_alignment: std.mem.Alignment, start: Io.AnyFuture.Start, ) ?*Io.AnyFuture { return concurrent(userdata, result.len, result_alignment, context, context_alignment, start) catch { start(context.ptr, result.ptr); return null; }; } fn concurrent( userdata: ?*anyopaque, result_len: usize, result_alignment: Alignment, context: []const u8, context_alignment: Alignment, start: Io.AnyFuture.Start, ) Io.ConcurrentError!*Io.AnyFuture { const k: *Kqueue = @ptrCast(@alignCast(userdata)); assert(result_alignment.compare(.lte, Fiber.max_result_align)); // TODO assert(context_alignment.compare(.lte, Fiber.max_context_align)); // TODO assert(result_len <= Fiber.max_result_size); // TODO assert(context.len <= Fiber.max_context_size); // TODO const fiber = Fiber.allocate(k) catch return error.ConcurrencyUnavailable; std.log.debug("allocated {*}", .{fiber}); const closure: *AsyncClosure = .fromFiber(fiber); fiber.* = .{ .required_align = {}, .context = switch (builtin.cpu.arch) { .x86_64 => .{ .rsp = @intFromPtr(closure) - @sizeOf(usize), .rbp = 0, .rip = @intFromPtr(&fiberEntry), }, .aarch64 => .{ .sp = @intFromPtr(closure), .fp = 0, .pc = @intFromPtr(&fiberEntry), }, else => |arch| @compileError("unimplemented architecture: " ++ @tagName(arch)), }, .awaiter = null, .queue_next = null, .cancel_thread = null, .awaiting_completions = .empty, }; closure.* = .{ .kqueue = k, .fiber = fiber, .start = start, .result_align = result_alignment, .already_awaited = false, }; @memcpy(closure.contextPointer(), context); k.schedule(.current(), .{ .head = fiber, .tail = fiber }); return @ptrCast(fiber); } fn await( userdata: ?*anyopaque, any_future: *Io.AnyFuture, result: []u8, result_alignment: std.mem.Alignment, ) void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); const future_fiber: *Fiber = @ptrCast(@alignCast(any_future)); if (@atomicLoad(?*Fiber, &future_fiber.awaiter, .acquire) != Fiber.finished) k.yield(null, .{ .register_awaiter = &future_fiber.awaiter }); @memcpy(result, future_fiber.resultBytes(result_alignment)); k.recycle(future_fiber); } fn cancel( userdata: ?*anyopaque, any_future: *Io.AnyFuture, result: []u8, result_alignment: std.mem.Alignment, ) void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = any_future; _ = result; _ = result_alignment; @panic("TODO"); } fn cancelRequested(userdata: ?*anyopaque) bool { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; return false; // TODO } fn groupAsync( userdata: ?*anyopaque, type_erased: *Io.Group, context: []const u8, context_alignment: Alignment, start: Io.Group.Start, ) void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = type_erased; _ = context; _ = context_alignment; _ = start; @panic("TODO"); } fn groupConcurrent( userdata: ?*anyopaque, type_erased: *Io.Group, context: []const u8, context_alignment: Alignment, start: Io.Group.Start, ) Io.ConcurrentError!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = type_erased; _ = context; _ = context_alignment; _ = start; @panic("TODO"); } fn groupAwait(userdata: ?*anyopaque, type_erased: *Io.Group, initial_token: *anyopaque) Io.Cancelable!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = type_erased; _ = initial_token; @panic("TODO"); } fn groupCancel(userdata: ?*anyopaque, group: *Io.Group, token: *anyopaque) void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = group; _ = token; @panic("TODO"); } fn dirCreateDir(userdata: ?*anyopaque, dir: Dir, sub_path: []const u8, permissions: Dir.Permissions) Dir.CreateDirError!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; _ = sub_path; _ = permissions; @panic("TODO"); } fn dirCreateDirPath( userdata: ?*anyopaque, dir: Dir, sub_path: []const u8, permissions: Dir.Permissions, ) Dir.CreateDirPathError!Dir.CreatePathStatus { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; _ = sub_path; _ = permissions; @panic("TODO"); } fn dirCreateDirPathOpen( userdata: ?*anyopaque, dir: Dir, sub_path: []const u8, permissions: Dir.Permissions, options: Dir.OpenOptions, ) Dir.CreateDirPathOpenError!Dir { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; _ = sub_path; _ = permissions; _ = options; @panic("TODO"); } fn dirStat(userdata: ?*anyopaque, dir: Dir) Dir.StatError!Dir.Stat { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; @panic("TODO"); } fn dirStatFile( userdata: ?*anyopaque, dir: Dir, sub_path: []const u8, options: Dir.StatFileOptions, ) Dir.StatFileError!File.Stat { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; _ = sub_path; _ = options; @panic("TODO"); } fn dirAccess(userdata: ?*anyopaque, dir: Dir, sub_path: []const u8, options: Dir.AccessOptions) Dir.AccessError!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; _ = sub_path; _ = options; @panic("TODO"); } fn dirCreateFile(userdata: ?*anyopaque, dir: Dir, sub_path: []const u8, flags: File.CreateFlags) File.OpenError!File { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; _ = sub_path; _ = flags; @panic("TODO"); } fn dirOpenFile(userdata: ?*anyopaque, dir: Dir, sub_path: []const u8, flags: File.OpenFlags) File.OpenError!File { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; _ = sub_path; _ = flags; @panic("TODO"); } fn dirOpenDir(userdata: ?*anyopaque, dir: Dir, sub_path: []const u8, options: Dir.OpenOptions) Dir.OpenError!Dir { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dir; _ = sub_path; _ = options; @panic("TODO"); } fn dirClose(userdata: ?*anyopaque, dirs: []const Dir) void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dirs; @panic("TODO"); } fn fileStat(userdata: ?*anyopaque, file: File) File.StatError!File.Stat { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = file; @panic("TODO"); } fn fileClose(userdata: ?*anyopaque, files: []const File) void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = files; @panic("TODO"); } fn fileWriteStreaming( userdata: ?*anyopaque, file: File, header: []const u8, data: []const []const u8, splat: usize, ) File.Writer.Error!usize { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = file; _ = header; _ = data; _ = splat; @panic("TODO"); } fn fileWritePositional( userdata: ?*anyopaque, file: File, header: []const u8, data: []const []const u8, splat: usize, offset: u64, ) File.WritePositionalError!usize { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = file; _ = header; _ = data; _ = splat; _ = offset; @panic("TODO"); } fn fileReadStreaming(userdata: ?*anyopaque, file: File, data: []const []u8) File.Reader.Error!usize { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = file; _ = data; @panic("TODO"); } fn fileReadPositional(userdata: ?*anyopaque, file: File, data: []const []u8, offset: u64) File.ReadPositionalError!usize { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = file; _ = data; _ = offset; @panic("TODO"); } fn fileSeekBy(userdata: ?*anyopaque, file: File, relative_offset: i64) File.SeekError!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = file; _ = relative_offset; @panic("TODO"); } fn fileSeekTo(userdata: ?*anyopaque, file: File, absolute_offset: u64) File.SeekError!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = file; _ = absolute_offset; @panic("TODO"); } fn now(userdata: ?*anyopaque, clock: Io.Clock) Io.Clock.Error!Io.Timestamp { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = clock; @panic("TODO"); } fn sleep(userdata: ?*anyopaque, timeout: Io.Timeout) Io.SleepError!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = timeout; @panic("TODO"); } fn netListenIp( userdata: ?*anyopaque, address: *const net.IpAddress, options: net.IpAddress.ListenOptions, ) net.IpAddress.ListenError!net.Socket { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = address; _ = options; @panic("TODO"); } fn netAccept(userdata: ?*anyopaque, server: net.Socket.Handle, options: net.Server.AcceptOptions) net.Server.AcceptError!net.Socket { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = server; _ = options; @panic("TODO"); } fn netBindIp( userdata: ?*anyopaque, address: *const net.IpAddress, options: net.IpAddress.BindOptions, ) net.IpAddress.BindError!net.Socket { const k: *Kqueue = @ptrCast(@alignCast(userdata)); const family = Io.Threaded.posixAddressFamily(address); const socket_fd = try openSocketPosix(k, family, options); errdefer closeFd(socket_fd); var storage: Io.Threaded.PosixAddress = undefined; var addr_len = Io.Threaded.addressToPosix(address, &storage); try posixBind(k, socket_fd, &storage.any, addr_len); if (options.allow_broadcast) try setSocketOption(k, socket_fd, posix.SOL.SOCKET, posix.SO.BROADCAST, 1); try posixGetSockName(k, socket_fd, &storage.any, &addr_len); return .{ .handle = socket_fd, .address = Io.Threaded.addressFromPosix(&storage) }; } fn netConnectIp(userdata: ?*anyopaque, address: *const net.IpAddress, options: net.IpAddress.ConnectOptions) net.IpAddress.ConnectError!net.Socket { if (options.timeout != .none) @panic("TODO"); const k: *Kqueue = @ptrCast(@alignCast(userdata)); const family = Io.Threaded.posixAddressFamily(address); const socket_fd = try openSocketPosix(k, family, .{ .mode = options.mode, .protocol = options.protocol, }); errdefer closeFd(socket_fd); var storage: Io.Threaded.PosixAddress = undefined; var addr_len = Io.Threaded.addressToPosix(address, &storage); try posixConnect(k, socket_fd, &storage.any, addr_len); try posixGetSockName(k, socket_fd, &storage.any, &addr_len); return .{ .handle = socket_fd, .address = Io.Threaded.addressFromPosix(&storage) }; } fn posixConnect(k: *Kqueue, socket_fd: posix.socket_t, addr: *const posix.sockaddr, addr_len: posix.socklen_t) !void { while (true) { try k.checkCancel(); switch (posix.errno(posix.system.connect(socket_fd, addr, addr_len))) { .SUCCESS => return, .INTR => continue, .CANCELED => return error.Canceled, .AGAIN => @panic("TODO"), .INPROGRESS => return, // Due to TCP fast open, we find out possible error later. .ADDRNOTAVAIL => return error.AddressUnavailable, .AFNOSUPPORT => return error.AddressFamilyUnsupported, .ALREADY => return error.ConnectionPending, .BADF => |err| return errnoBug(err), // File descriptor used after closed. .CONNREFUSED => return error.ConnectionRefused, .CONNRESET => return error.ConnectionResetByPeer, .FAULT => |err| return errnoBug(err), .ISCONN => |err| return errnoBug(err), .HOSTUNREACH => return error.HostUnreachable, .NETUNREACH => return error.NetworkUnreachable, .NOTSOCK => |err| return errnoBug(err), .PROTOTYPE => |err| return errnoBug(err), .TIMEDOUT => return error.Timeout, .CONNABORTED => |err| return errnoBug(err), .ACCES => return error.AccessDenied, .PERM => |err| return errnoBug(err), .NOENT => |err| return errnoBug(err), .NETDOWN => return error.NetworkDown, else => |err| return posix.unexpectedErrno(err), } } } fn netListenUnix( userdata: ?*anyopaque, unix_address: *const net.UnixAddress, options: net.UnixAddress.ListenOptions, ) net.UnixAddress.ListenError!net.Socket.Handle { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = unix_address; _ = options; @panic("TODO"); } fn netConnectUnix( userdata: ?*anyopaque, unix_address: *const net.UnixAddress, ) net.UnixAddress.ConnectError!net.Socket.Handle { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = unix_address; @panic("TODO"); } fn netSend( userdata: ?*anyopaque, handle: net.Socket.Handle, outgoing_messages: []net.OutgoingMessage, flags: net.SendFlags, ) struct { ?net.Socket.SendError, usize } { const k: *Kqueue = @ptrCast(@alignCast(userdata)); const posix_flags: u32 = @as(u32, if (@hasDecl(posix.MSG, "CONFIRM") and flags.confirm) posix.MSG.CONFIRM else 0) | @as(u32, if (@hasDecl(posix.MSG, "DONTROUTE") and flags.dont_route) posix.MSG.DONTROUTE else 0) | @as(u32, if (@hasDecl(posix.MSG, "EOR") and flags.eor) posix.MSG.EOR else 0) | @as(u32, if (@hasDecl(posix.MSG, "OOB") and flags.oob) posix.MSG.OOB else 0) | @as(u32, if (@hasDecl(posix.MSG, "FASTOPEN") and flags.fastopen) posix.MSG.FASTOPEN else 0) | posix.MSG.NOSIGNAL; for (outgoing_messages, 0..) |*msg, i| { netSendOne(k, handle, msg, posix_flags) catch |err| return .{ err, i }; } return .{ null, outgoing_messages.len }; } fn netSendOne( k: *Kqueue, handle: net.Socket.Handle, message: *net.OutgoingMessage, flags: u32, ) net.Socket.SendError!void { var addr: Io.Threaded.PosixAddress = undefined; var iovec: posix.iovec_const = .{ .base = @constCast(message.data_ptr), .len = message.data_len }; const msg: posix.msghdr_const = .{ .name = &addr.any, .namelen = Io.Threaded.addressToPosix(message.address, &addr), .iov = (&iovec)[0..1], .iovlen = 1, // OS returns EINVAL if this pointer is invalid even if controllen is zero. .control = if (message.control.len == 0) null else @constCast(message.control.ptr), .controllen = @intCast(message.control.len), .flags = 0, }; while (true) { try k.checkCancel(); const rc = posix.system.sendmsg(handle, &msg, flags); switch (posix.errno(rc)) { .SUCCESS => { message.data_len = @intCast(rc); return; }, .INTR => continue, .CANCELED => return error.Canceled, .AGAIN => @panic("TODO register kevent"), .ACCES => return error.AccessDenied, .ALREADY => return error.FastOpenAlreadyInProgress, .BADF => |err| return errnoBug(err), // File descriptor used after closed. .CONNRESET => return error.ConnectionResetByPeer, .DESTADDRREQ => |err| return errnoBug(err), .FAULT => |err| return errnoBug(err), .INVAL => |err| return errnoBug(err), .ISCONN => |err| return errnoBug(err), .MSGSIZE => return error.MessageOversize, .NOBUFS => return error.SystemResources, .NOMEM => return error.SystemResources, .NOTSOCK => |err| return errnoBug(err), .OPNOTSUPP => |err| return errnoBug(err), .PIPE => return error.SocketUnconnected, .AFNOSUPPORT => return error.AddressFamilyUnsupported, .HOSTUNREACH => return error.HostUnreachable, .NETUNREACH => return error.NetworkUnreachable, .NOTCONN => return error.SocketUnconnected, .NETDOWN => return error.NetworkDown, else => |err| return posix.unexpectedErrno(err), } } } fn netReceive( userdata: ?*anyopaque, handle: net.Socket.Handle, message_buffer: []net.IncomingMessage, data_buffer: []u8, flags: net.ReceiveFlags, timeout: Io.Timeout, ) struct { ?net.Socket.ReceiveTimeoutError, usize } { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = handle; _ = message_buffer; _ = data_buffer; _ = flags; _ = timeout; @panic("TODO"); } fn netRead(userdata: ?*anyopaque, fd: net.Socket.Handle, data: [][]u8) net.Stream.Reader.Error!usize { const k: *Kqueue = @ptrCast(@alignCast(userdata)); var iovecs_buffer: [max_iovecs_len]posix.iovec = undefined; var i: usize = 0; for (data) |buf| { if (iovecs_buffer.len - i == 0) break; if (buf.len != 0) { iovecs_buffer[i] = .{ .base = buf.ptr, .len = buf.len }; i += 1; } } const dest = iovecs_buffer[0..i]; assert(dest[0].len > 0); while (true) { try k.checkCancel(); const rc = posix.system.readv(fd, dest.ptr, @intCast(dest.len)); switch (posix.errno(rc)) { .SUCCESS => return @intCast(rc), .INTR => continue, .CANCELED => return error.Canceled, .AGAIN => { const thread: *Thread = .current(); const fiber = thread.currentFiber(); const ident: u32 = @bitCast(fd); const filter = std.c.EVFILT.READ; const gop = thread.wait_queues.getOrPut(k.gpa, .{ .ident = ident, .filter = filter, }) catch return error.SystemResources; if (gop.found_existing) { const tail_fiber = gop.value_ptr.*; assert(tail_fiber.queue_next == null); tail_fiber.queue_next = fiber; gop.value_ptr.* = fiber; } else { gop.value_ptr.* = fiber; const changes = [_]posix.Kevent{ .{ .ident = ident, .filter = filter, .flags = std.c.EV.ADD | std.c.EV.ONESHOT, .fflags = 0, .data = 0, .udata = @intFromPtr(fiber), }, }; assert(0 == (kevent(thread.kq_fd, &changes, &.{}, null) catch |err| { // TODO handle EINTR for cancellation purposes @panic(@errorName(err)); // TODO })); } yield(k, null, .nothing); continue; }, .INVAL => |err| return errnoBug(err), .FAULT => |err| return errnoBug(err), .BADF => |err| return errnoBug(err), // File descriptor used after closed. .NOBUFS => return error.SystemResources, .NOMEM => return error.SystemResources, .NOTCONN => return error.SocketUnconnected, .CONNRESET => return error.ConnectionResetByPeer, .TIMEDOUT => return error.Timeout, .PIPE => return error.SocketUnconnected, .NETDOWN => return error.NetworkDown, else => |err| return posix.unexpectedErrno(err), } } } fn netWrite(userdata: ?*anyopaque, dest: net.Socket.Handle, header: []const u8, data: []const []const u8, splat: usize) net.Stream.Writer.Error!usize { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = dest; _ = header; _ = data; _ = splat; @panic("TODO"); } fn netClose(userdata: ?*anyopaque, handles: []const net.Socket.Handle) void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = handles; @panic("TODO"); } fn netShutdown(userdata: ?*anyopaque, handle: net.Socket.Handle, how: net.ShutdownHow) net.ShutdownError!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = handle; _ = how; @panic("TODO"); } fn netInterfaceNameResolve( userdata: ?*anyopaque, name: *const net.Interface.Name, ) net.Interface.Name.ResolveError!net.Interface { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = name; @panic("TODO"); } fn netInterfaceName(userdata: ?*anyopaque, interface: net.Interface) net.Interface.NameError!net.Interface.Name { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = interface; @panic("TODO"); } fn netLookup( userdata: ?*anyopaque, host_name: net.HostName, resolved: *Io.Queue(net.HostName.LookupResult), options: net.HostName.LookupOptions, ) net.HostName.LookupError!void { const k: *Kqueue = @ptrCast(@alignCast(userdata)); _ = k; _ = host_name; _ = resolved; _ = options; @panic("TODO"); } fn openSocketPosix( k: *Kqueue, family: posix.sa_family_t, options: IpAddress.BindOptions, ) error{ AddressFamilyUnsupported, ProtocolUnsupportedBySystem, ProcessFdQuotaExceeded, SystemFdQuotaExceeded, SystemResources, ProtocolUnsupportedByAddressFamily, SocketModeUnsupported, OptionUnsupported, Unexpected, Canceled, }!posix.socket_t { const mode, const protocol = try posixSocketModeProtocol(family, options.mode, options.protocol); const socket_fd = while (true) { try k.checkCancel(); const flags: u32 = mode | if (Io.Threaded.socket_flags_unsupported) 0 else posix.SOCK.CLOEXEC; const socket_rc = posix.system.socket(family, flags, protocol); switch (posix.errno(socket_rc)) { .SUCCESS => { const fd: posix.fd_t = @intCast(socket_rc); errdefer closeFd(fd); if (Io.Threaded.socket_flags_unsupported) { while (true) { try k.checkCancel(); switch (posix.errno(posix.system.fcntl(fd, posix.F.SETFD, @as(usize, posix.FD_CLOEXEC)))) { .SUCCESS => break, .INTR => continue, .CANCELED => return error.Canceled, else => |err| return posix.unexpectedErrno(err), } } var fl_flags: usize = while (true) { try k.checkCancel(); const rc = posix.system.fcntl(fd, posix.F.GETFL, @as(usize, 0)); switch (posix.errno(rc)) { .SUCCESS => break @intCast(rc), .INTR => continue, .CANCELED => return error.Canceled, else => |err| return posix.unexpectedErrno(err), } }; fl_flags |= @as(usize, 1 << @bitOffsetOf(posix.O, "NONBLOCK")); while (true) { try k.checkCancel(); switch (posix.errno(posix.system.fcntl(fd, posix.F.SETFL, fl_flags))) { .SUCCESS => break, .INTR => continue, .CANCELED => return error.Canceled, else => |err| return posix.unexpectedErrno(err), } } } break fd; }, .INTR => continue, .CANCELED => return error.Canceled, .AFNOSUPPORT => return error.AddressFamilyUnsupported, .INVAL => return error.ProtocolUnsupportedBySystem, .MFILE => return error.ProcessFdQuotaExceeded, .NFILE => return error.SystemFdQuotaExceeded, .NOBUFS => return error.SystemResources, .NOMEM => return error.SystemResources, .PROTONOSUPPORT => return error.ProtocolUnsupportedByAddressFamily, .PROTOTYPE => return error.SocketModeUnsupported, else => |err| return posix.unexpectedErrno(err), } }; errdefer closeFd(socket_fd); if (options.ip6_only) { if (posix.IPV6 == void) return error.OptionUnsupported; try setSocketOption(k, socket_fd, posix.IPPROTO.IPV6, posix.IPV6.V6ONLY, 0); } return socket_fd; } fn posixBind( k: *Kqueue, socket_fd: posix.socket_t, addr: *const posix.sockaddr, addr_len: posix.socklen_t, ) !void { while (true) { try k.checkCancel(); switch (posix.errno(posix.system.bind(socket_fd, addr, addr_len))) { .SUCCESS => break, .INTR => continue, .CANCELED => return error.Canceled, .ADDRINUSE => return error.AddressInUse, .BADF => |err| return errnoBug(err), // File descriptor used after closed. .INVAL => |err| return errnoBug(err), // invalid parameters .NOTSOCK => |err| return errnoBug(err), // invalid `sockfd` .AFNOSUPPORT => return error.AddressFamilyUnsupported, .ADDRNOTAVAIL => return error.AddressUnavailable, .FAULT => |err| return errnoBug(err), // invalid `addr` pointer .NOMEM => return error.SystemResources, else => |err| return posix.unexpectedErrno(err), } } } fn posixGetSockName(k: *Kqueue, socket_fd: posix.fd_t, addr: *posix.sockaddr, addr_len: *posix.socklen_t) !void { while (true) { try k.checkCancel(); switch (posix.errno(posix.system.getsockname(socket_fd, addr, addr_len))) { .SUCCESS => break, .INTR => continue, .CANCELED => return error.Canceled, .BADF => |err| return errnoBug(err), // File descriptor used after closed. .FAULT => |err| return errnoBug(err), .INVAL => |err| return errnoBug(err), // invalid parameters .NOTSOCK => |err| return errnoBug(err), // always a race condition .NOBUFS => return error.SystemResources, else => |err| return posix.unexpectedErrno(err), } } } fn setSocketOption(k: *Kqueue, fd: posix.fd_t, level: i32, opt_name: u32, option: u32) !void { const o: []const u8 = @ptrCast(&option); while (true) { try k.checkCancel(); switch (posix.errno(posix.system.setsockopt(fd, level, opt_name, o.ptr, @intCast(o.len)))) { .SUCCESS => return, .INTR => continue, .CANCELED => return error.Canceled, .BADF => |err| return errnoBug(err), // File descriptor used after closed. .NOTSOCK => |err| return errnoBug(err), .INVAL => |err| return errnoBug(err), .FAULT => |err| return errnoBug(err), else => |err| return posix.unexpectedErrno(err), } } } fn checkCancel(k: *Kqueue) error{Canceled}!void { if (cancelRequested(k)) return error.Canceled; } pub const KEventError = error{ /// The process does not have permission to register a filter. AccessDenied, /// The event could not be found to be modified or deleted. EventNotFound, /// No memory was available to register the event. SystemResources, /// The specified process to attach to does not exist. ProcessNotFound, /// changelist or eventlist had too many items on it. /// TODO remove this possibility Overflow, }; pub fn kevent( kq: i32, changelist: []const posix.Kevent, eventlist: []posix.Kevent, timeout: ?*const posix.timespec, ) KEventError!usize { while (true) { const rc = posix.system.kevent( kq, changelist.ptr, std.math.cast(c_int, changelist.len) orelse return error.Overflow, eventlist.ptr, std.math.cast(c_int, eventlist.len) orelse return error.Overflow, timeout, ); switch (posix.errno(rc)) { .SUCCESS => return @intCast(rc), .ACCES => return error.AccessDenied, .FAULT => unreachable, // TODO use error.Unexpected for these .BADF => unreachable, // Always a race condition. .INTR => continue, // TODO handle cancelation .INVAL => unreachable, .NOENT => return error.EventNotFound, .NOMEM => return error.SystemResources, .SRCH => return error.ProcessNotFound, else => unreachable, } } }