struct Io [src]

Alias for std.Io

Members

Source

const builtin = @import("builtin"); const is_windows = builtin.os.tag == .windows; const std = @import("std.zig"); const windows = std.os.windows; const posix = std.posix; const math = std.math; const assert = std.debug.assert; const Allocator = std.mem.Allocator; const Alignment = std.mem.Alignment; pub const Limit = enum(usize) { nothing = 0, unlimited = std.math.maxInt(usize), _, /// `std.math.maxInt(usize)` is interpreted to mean `.unlimited`. pub fn limited(n: usize) Limit { return @enumFromInt(n); } /// Any value grater than `std.math.maxInt(usize)` is interpreted to mean /// `.unlimited`. pub fn limited64(n: u64) Limit { return @enumFromInt(@min(n, std.math.maxInt(usize))); } pub fn countVec(data: []const []const u8) Limit { var total: usize = 0; for (data) |d| total += d.len; return .limited(total); } pub fn min(a: Limit, b: Limit) Limit { return @enumFromInt(@min(@intFromEnum(a), @intFromEnum(b))); } pub fn minInt(l: Limit, n: usize) usize { return @min(n, @intFromEnum(l)); } pub fn minInt64(l: Limit, n: u64) usize { return @min(n, @intFromEnum(l)); } pub fn slice(l: Limit, s: []u8) []u8 { return s[0..l.minInt(s.len)]; } pub fn sliceConst(l: Limit, s: []const u8) []const u8 { return s[0..l.minInt(s.len)]; } pub fn toInt(l: Limit) ?usize { return switch (l) { else => @intFromEnum(l), .unlimited => null, }; } /// Reduces a slice to account for the limit, leaving room for one extra /// byte above the limit, allowing for the use case of differentiating /// between end-of-stream and reaching the limit. pub fn slice1(l: Limit, non_empty_buffer: []u8) []u8 { assert(non_empty_buffer.len >= 1); return non_empty_buffer[0..@min(@intFromEnum(l) +| 1, non_empty_buffer.len)]; } pub fn nonzero(l: Limit) bool { return @intFromEnum(l) > 0; } /// Return a new limit reduced by `amount` or return `null` indicating /// limit would be exceeded. pub fn subtract(l: Limit, amount: usize) ?Limit { if (l == .unlimited) return .unlimited; if (amount > @intFromEnum(l)) return null; return @enumFromInt(@intFromEnum(l) - amount); } }; pub const Reader = @import("Io/Reader.zig"); pub const Writer = @import("Io/Writer.zig"); pub const tty = @import("Io/tty.zig"); pub fn poll( gpa: Allocator, comptime StreamEnum: type, files: PollFiles(StreamEnum), ) Poller(StreamEnum) { const enum_fields = @typeInfo(StreamEnum).@"enum".fields; var result: Poller(StreamEnum) = .{ .gpa = gpa, .readers = @splat(.failing), .poll_fds = undefined, .windows = if (is_windows) .{ .first_read_done = false, .overlapped = [1]windows.OVERLAPPED{ std.mem.zeroes(windows.OVERLAPPED), } ** enum_fields.len, .small_bufs = undefined, .active = .{ .count = 0, .handles_buf = undefined, .stream_map = undefined, }, } else {}, }; inline for (enum_fields, 0..) |field, i| { if (is_windows) { result.windows.active.handles_buf[i] = @field(files, field.name).handle; } else { result.poll_fds[i] = .{ .fd = @field(files, field.name).handle, .events = posix.POLL.IN, .revents = undefined, }; } } return result; } pub fn Poller(comptime StreamEnum: type) type { return struct { const enum_fields = @typeInfo(StreamEnum).@"enum".fields; const PollFd = if (is_windows) void else posix.pollfd; gpa: Allocator, readers: [enum_fields.len]Reader, poll_fds: [enum_fields.len]PollFd, windows: if (is_windows) struct { first_read_done: bool, overlapped: [enum_fields.len]windows.OVERLAPPED, small_bufs: [enum_fields.len][128]u8, active: struct { count: math.IntFittingRange(0, enum_fields.len), handles_buf: [enum_fields.len]windows.HANDLE, stream_map: [enum_fields.len]StreamEnum, pub fn removeAt(self: *@This(), index: u32) void { assert(index < self.count); for (index + 1..self.count) |i| { self.handles_buf[i - 1] = self.handles_buf[i]; self.stream_map[i - 1] = self.stream_map[i]; } self.count -= 1; } }, } else void, const Self = @This(); pub fn deinit(self: *Self) void { const gpa = self.gpa; if (is_windows) { // cancel any pending IO to prevent clobbering OVERLAPPED value for (self.windows.active.handles_buf[0..self.windows.active.count]) |h| { _ = windows.kernel32.CancelIo(h); } } inline for (&self.readers) |*r| gpa.free(r.buffer); self.* = undefined; } pub fn poll(self: *Self) !bool { if (is_windows) { return pollWindows(self, null); } else { return pollPosix(self, null); } } pub fn pollTimeout(self: *Self, nanoseconds: u64) !bool { if (is_windows) { return pollWindows(self, nanoseconds); } else { return pollPosix(self, nanoseconds); } } pub fn reader(self: *Self, which: StreamEnum) *Reader { return &self.readers[@intFromEnum(which)]; } pub fn toOwnedSlice(self: *Self, which: StreamEnum) error{OutOfMemory}![]u8 { const gpa = self.gpa; const r = reader(self, which); if (r.seek == 0) { const new = try gpa.realloc(r.buffer, r.end); r.buffer = &.{}; r.end = 0; return new; } const new = try gpa.dupe(u8, r.buffered()); gpa.free(r.buffer); r.buffer = &.{}; r.seek = 0; r.end = 0; return new; } fn pollWindows(self: *Self, nanoseconds: ?u64) !bool { const bump_amt = 512; const gpa = self.gpa; if (!self.windows.first_read_done) { var already_read_data = false; for (0..enum_fields.len) |i| { const handle = self.windows.active.handles_buf[i]; switch (try windowsAsyncReadToFifoAndQueueSmallRead( gpa, handle, &self.windows.overlapped[i], &self.readers[i], &self.windows.small_bufs[i], bump_amt, )) { .populated, .empty => |state| { if (state == .populated) already_read_data = true; self.windows.active.handles_buf[self.windows.active.count] = handle; self.windows.active.stream_map[self.windows.active.count] = @as(StreamEnum, @enumFromInt(i)); self.windows.active.count += 1; }, .closed => {}, // don't add to the wait_objects list .closed_populated => { // don't add to the wait_objects list, but we did already get data already_read_data = true; }, } } self.windows.first_read_done = true; if (already_read_data) return true; } while (true) { if (self.windows.active.count == 0) return false; const status = windows.kernel32.WaitForMultipleObjects( self.windows.active.count, &self.windows.active.handles_buf, 0, if (nanoseconds) |ns| @min(std.math.cast(u32, ns / std.time.ns_per_ms) orelse (windows.INFINITE - 1), windows.INFINITE - 1) else windows.INFINITE, ); if (status == windows.WAIT_FAILED) return windows.unexpectedError(windows.GetLastError()); if (status == windows.WAIT_TIMEOUT) return true; if (status < windows.WAIT_OBJECT_0 or status > windows.WAIT_OBJECT_0 + enum_fields.len - 1) unreachable; const active_idx = status - windows.WAIT_OBJECT_0; const stream_idx = @intFromEnum(self.windows.active.stream_map[active_idx]); const handle = self.windows.active.handles_buf[active_idx]; const overlapped = &self.windows.overlapped[stream_idx]; const stream_reader = &self.readers[stream_idx]; const small_buf = &self.windows.small_bufs[stream_idx]; const num_bytes_read = switch (try windowsGetReadResult(handle, overlapped, false)) { .success => |n| n, .closed => { self.windows.active.removeAt(active_idx); continue; }, .aborted => unreachable, }; const buf = small_buf[0..num_bytes_read]; const dest = try writableSliceGreedyAlloc(stream_reader, gpa, buf.len); @memcpy(dest[0..buf.len], buf); advanceBufferEnd(stream_reader, buf.len); switch (try windowsAsyncReadToFifoAndQueueSmallRead( gpa, handle, overlapped, stream_reader, small_buf, bump_amt, )) { .empty => {}, // irrelevant, we already got data from the small buffer .populated => {}, .closed, .closed_populated, // identical, since we already got data from the small buffer => self.windows.active.removeAt(active_idx), } return true; } } fn pollPosix(self: *Self, nanoseconds: ?u64) !bool { const gpa = self.gpa; // We ask for ensureUnusedCapacity with this much extra space. This // has more of an effect on small reads because once the reads // start to get larger the amount of space an ArrayList will // allocate grows exponentially. const bump_amt = 512; const err_mask = posix.POLL.ERR | posix.POLL.NVAL | posix.POLL.HUP; const events_len = try posix.poll(&self.poll_fds, if (nanoseconds) |ns| std.math.cast(i32, ns / std.time.ns_per_ms) orelse std.math.maxInt(i32) else -1); if (events_len == 0) { for (self.poll_fds) |poll_fd| { if (poll_fd.fd != -1) return true; } else return false; } var keep_polling = false; for (&self.poll_fds, &self.readers) |*poll_fd, *r| { // Try reading whatever is available before checking the error // conditions. // It's still possible to read after a POLL.HUP is received, // always check if there's some data waiting to be read first. if (poll_fd.revents & posix.POLL.IN != 0) { const buf = try writableSliceGreedyAlloc(r, gpa, bump_amt); const amt = posix.read(poll_fd.fd, buf) catch |err| switch (err) { error.BrokenPipe => 0, // Handle the same as EOF. else => |e| return e, }; advanceBufferEnd(r, amt); if (amt == 0) { // Remove the fd when the EOF condition is met. poll_fd.fd = -1; } else { keep_polling = true; } } else if (poll_fd.revents & err_mask != 0) { // Exclude the fds that signaled an error. poll_fd.fd = -1; } else if (poll_fd.fd != -1) { keep_polling = true; } } return keep_polling; } /// Returns a slice into the unused capacity of `buffer` with at least /// `min_len` bytes, extending `buffer` by resizing it with `gpa` as necessary. /// /// After calling this function, typically the caller will follow up with a /// call to `advanceBufferEnd` to report the actual number of bytes buffered. fn writableSliceGreedyAlloc(r: *Reader, allocator: Allocator, min_len: usize) Allocator.Error![]u8 { { const unused = r.buffer[r.end..]; if (unused.len >= min_len) return unused; } if (r.seek > 0) { const data = r.buffer[r.seek..r.end]; @memmove(r.buffer[0..data.len], data); r.seek = 0; r.end = data.len; } { var list: std.ArrayListUnmanaged(u8) = .{ .items = r.buffer[0..r.end], .capacity = r.buffer.len, }; defer r.buffer = list.allocatedSlice(); try list.ensureUnusedCapacity(allocator, min_len); } const unused = r.buffer[r.end..]; assert(unused.len >= min_len); return unused; } /// After writing directly into the unused capacity of `buffer`, this function /// updates `end` so that users of `Reader` can receive the data. fn advanceBufferEnd(r: *Reader, n: usize) void { assert(n <= r.buffer.len - r.end); r.end += n; } /// The `ReadFile` docuementation states that `lpNumberOfBytesRead` does not have a meaningful /// result when using overlapped I/O, but also that it cannot be `null` on Windows 7. For /// compatibility, we point it to this dummy variables, which we never otherwise access. /// See: https://learn.microsoft.com/en-us/windows/win32/api/fileapi/nf-fileapi-readfile var win_dummy_bytes_read: u32 = undefined; /// Read as much data as possible from `handle` with `overlapped`, and write it to the FIFO. Before /// returning, queue a read into `small_buf` so that `WaitForMultipleObjects` returns when more data /// is available. `handle` must have no pending asynchronous operation. fn windowsAsyncReadToFifoAndQueueSmallRead( gpa: Allocator, handle: windows.HANDLE, overlapped: *windows.OVERLAPPED, r: *Reader, small_buf: *[128]u8, bump_amt: usize, ) !enum { empty, populated, closed_populated, closed } { var read_any_data = false; while (true) { const fifo_read_pending = while (true) { const buf = try writableSliceGreedyAlloc(r, gpa, bump_amt); const buf_len = math.cast(u32, buf.len) orelse math.maxInt(u32); if (0 == windows.kernel32.ReadFile( handle, buf.ptr, buf_len, &win_dummy_bytes_read, overlapped, )) switch (windows.GetLastError()) { .IO_PENDING => break true, .BROKEN_PIPE => return if (read_any_data) .closed_populated else .closed, else => |err| return windows.unexpectedError(err), }; const num_bytes_read = switch (try windowsGetReadResult(handle, overlapped, false)) { .success => |n| n, .closed => return if (read_any_data) .closed_populated else .closed, .aborted => unreachable, }; read_any_data = true; advanceBufferEnd(r, num_bytes_read); if (num_bytes_read == buf_len) { // We filled the buffer, so there's probably more data available. continue; } else { // We didn't fill the buffer, so assume we're out of data. // There is no pending read. break false; } }; if (fifo_read_pending) cancel_read: { // Cancel the pending read into the FIFO. _ = windows.kernel32.CancelIo(handle); // We have to wait for the handle to be signalled, i.e. for the cancellation to complete. switch (windows.kernel32.WaitForSingleObject(handle, windows.INFINITE)) { windows.WAIT_OBJECT_0 => {}, windows.WAIT_FAILED => return windows.unexpectedError(windows.GetLastError()), else => unreachable, } // If it completed before we canceled, make sure to tell the FIFO! const num_bytes_read = switch (try windowsGetReadResult(handle, overlapped, true)) { .success => |n| n, .closed => return if (read_any_data) .closed_populated else .closed, .aborted => break :cancel_read, }; read_any_data = true; advanceBufferEnd(r, num_bytes_read); } // Try to queue the 1-byte read. if (0 == windows.kernel32.ReadFile( handle, small_buf, small_buf.len, &win_dummy_bytes_read, overlapped, )) switch (windows.GetLastError()) { .IO_PENDING => { // 1-byte read pending as intended return if (read_any_data) .populated else .empty; }, .BROKEN_PIPE => return if (read_any_data) .closed_populated else .closed, else => |err| return windows.unexpectedError(err), }; // We got data back this time. Write it to the FIFO and run the main loop again. const num_bytes_read = switch (try windowsGetReadResult(handle, overlapped, false)) { .success => |n| n, .closed => return if (read_any_data) .closed_populated else .closed, .aborted => unreachable, }; const buf = small_buf[0..num_bytes_read]; const dest = try writableSliceGreedyAlloc(r, gpa, buf.len); @memcpy(dest[0..buf.len], buf); advanceBufferEnd(r, buf.len); read_any_data = true; } } /// Simple wrapper around `GetOverlappedResult` to determine the result of a `ReadFile` operation. /// If `!allow_aborted`, then `aborted` is never returned (`OPERATION_ABORTED` is considered unexpected). /// /// The `ReadFile` documentation states that the number of bytes read by an overlapped `ReadFile` must be determined using `GetOverlappedResult`, even if the /// operation immediately returns data: /// "Use NULL for [lpNumberOfBytesRead] if this is an asynchronous operation to avoid potentially /// erroneous results." /// "If `hFile` was opened with `FILE_FLAG_OVERLAPPED`, the following conditions are in effect: [...] /// The lpNumberOfBytesRead parameter should be set to NULL. Use the GetOverlappedResult function to /// get the actual number of bytes read." /// See: https://learn.microsoft.com/en-us/windows/win32/api/fileapi/nf-fileapi-readfile fn windowsGetReadResult( handle: windows.HANDLE, overlapped: *windows.OVERLAPPED, allow_aborted: bool, ) !union(enum) { success: u32, closed, aborted, } { var num_bytes_read: u32 = undefined; if (0 == windows.kernel32.GetOverlappedResult( handle, overlapped, &num_bytes_read, 0, )) switch (windows.GetLastError()) { .BROKEN_PIPE => return .closed, .OPERATION_ABORTED => |err| if (allow_aborted) { return .aborted; } else { return windows.unexpectedError(err); }, else => |err| return windows.unexpectedError(err), }; return .{ .success = num_bytes_read }; } }; } /// Given an enum, returns a struct with fields of that enum, each field /// representing an I/O stream for polling. pub fn PollFiles(comptime StreamEnum: type) type { const enum_fields = @typeInfo(StreamEnum).@"enum".fields; var struct_fields: [enum_fields.len]std.builtin.Type.StructField = undefined; for (&struct_fields, enum_fields) |*struct_field, enum_field| { struct_field.* = .{ .name = enum_field.name, .type = std.fs.File, .default_value_ptr = null, .is_comptime = false, .alignment = @alignOf(std.fs.File), }; } return @Type(.{ .@"struct" = .{ .layout = .auto, .fields = &struct_fields, .decls = &.{}, .is_tuple = false, } }); } test { _ = Reader; _ = Writer; _ = tty; _ = @import("Io/test.zig"); }