const linux = @import("linux.zig"); const errno = @import("errno.zig"); const assert = @import("index.zig").assert; pub error SigInterrupt; pub error Unexpected; pub error Io; pub error TimedOut; pub error ConnectionReset; pub error ConnectionRefused; pub error NoMem; pub error NotSocket; pub error BadFd; struct Connection { socket_fd: i32, pub fn send(c: Connection, buf: []const u8) -> %isize { const send_ret = linux.sendto(c.socket_fd, buf.ptr, buf.len, 0, null, 0); const send_err = linux.get_errno(send_ret); switch (send_err) { 0 => return send_ret, errno.EINVAL => unreachable{}, errno.EFAULT => unreachable{}, errno.ECONNRESET => return error.ConnectionReset, errno.EINTR => return error.SigInterrupt, // TODO there are more possible errors else => return error.Unexpected, } } pub fn recv(c: Connection, buf: []u8) -> %[]u8 { const recv_ret = linux.recvfrom(c.socket_fd, buf.ptr, buf.len, 0, null, null); const recv_err = linux.get_errno(recv_ret); switch (recv_err) { 0 => return buf[0...recv_ret], errno.EINVAL => unreachable{}, errno.EFAULT => unreachable{}, errno.ENOTSOCK => return error.NotSocket, errno.EINTR => return error.SigInterrupt, errno.ENOMEM => return error.NoMem, errno.ECONNREFUSED => return error.ConnectionRefused, errno.EBADF => return error.BadFd, // TODO more error values else => return error.Unexpected, } } pub fn close(c: Connection) -> %void { switch (linux.get_errno(linux.close(c.socket_fd))) { 0 => return, errno.EBADF => unreachable{}, errno.EINTR => return error.SigInterrupt, errno.EIO => return error.Io, else => return error.Unexpected, } } } struct Address { family: u16, scope_id: u32, addr: [16]u8, sort_key: i32, } pub fn lookup(hostname: []const u8, out_addrs: []Address) -> %[]Address { if (hostname.len == 0) { /* if (family != AF_INET6) buf[cnt++] = (struct address){ .family = AF_INET, .addr = { 127,0,0,1 } }; if (family != AF_INET) buf[cnt++] = (struct address){ .family = AF_INET6, .addr = { [15] = 1 } }; */ unreachable{} // TODO } switch (parse_ip_literal(hostname)) { Ok => |addr| { out_addrs[0] = addr; return out_addrs[0...1]; }, else => {}, }; unreachable{} // TODO } pub fn connect_addr(addr: &Address, port: u16) -> %Connection { const socket_ret = linux.socket(addr.family, linux.SOCK_STREAM, linux.PROTO_tcp); const socket_err = linux.get_errno(socket_ret); if (socket_err > 0) { // TODO figure out possible errors from socket() return error.Unexpected; } const socket_fd = i32(socket_ret); const connect_ret = if (addr.family == linux.AF_INET) { var os_addr: linux.sockaddr_in = undefined; os_addr.family = addr.family; os_addr.port = host_to_be(u16)(port); @memcpy((&u8)(&os_addr.addr), &addr.addr[0], 4); @memset(&os_addr.zero, 0, @sizeof(@typeof(os_addr.zero))); linux.connect(socket_fd, (&linux.sockaddr)(&os_addr), @sizeof(linux.sockaddr_in)) } else if (addr.family == linux.AF_INET6) { var os_addr: linux.sockaddr_in6 = undefined; os_addr.family = addr.family; os_addr.port = host_to_be(u16)(port); os_addr.flowinfo = 0; os_addr.scope_id = addr.scope_id; @memcpy(&os_addr.addr[0], &addr.addr[0], 16); linux.connect(socket_fd, (&linux.sockaddr)(&os_addr), @sizeof(linux.sockaddr_in6)) } else { unreachable{} }; const connect_err = linux.get_errno(connect_ret); if (connect_err > 0) { switch (connect_err) { errno.ETIMEDOUT => return error.TimedOut, else => { // TODO figure out possible errors from connect() return error.Unexpected; }, } } return Connection { .socket_fd = socket_fd, }; } pub fn connect(hostname: []const u8, port: u16) -> %Connection { var addrs_buf: [1]Address = undefined; const addrs_slice = %return lookup(hostname, addrs_buf); const main_addr = &addrs_slice[0]; return connect_addr(main_addr, port); } pub error InvalidIpLiteral; pub fn parse_ip_literal(buf: []const u8) -> %Address { switch (parse_ip4(buf)) { Ok => |ip4| { var result: Address = undefined; @memcpy(&result.addr[0], (&u8)(&ip4), @sizeof(u32)); result.family = linux.AF_INET; result.scope_id = 0; return result; }, else => {}, } switch (parse_ip6(buf)) { Ok => |addr| { return addr; }, else => {}, } return error.InvalidIpLiteral; } fn hex_digit(c: u8) -> u8 { // TODO use switch with range if ('0' <= c && c <= '9') { c - '0' } else if ('A' <= c && c <= 'Z') { c - 'A' + 10 } else if ('a' <= c && c <= 'z') { c - 'a' + 10 } else { @max_value(u8) } } error InvalidChar; error Overflow; error JunkAtEnd; error Incomplete; #static_eval_enable(false) fn parse_ip6(buf: []const u8) -> %Address { var result: Address = undefined; result.family = linux.AF_INET6; result.scope_id = 0; const ip_slice = result.addr[0...]; var x: u16 = 0; var saw_any_digits = false; var index: u8 = 0; var scope_id = false; for (buf) |c| { if (scope_id) { if (c >= '0' && c <= '9') { const digit = c - '0'; if (@mul_with_overflow(u32, result.scope_id, 10, &result.scope_id)) { return error.Overflow; } if (@add_with_overflow(u32, result.scope_id, digit, &result.scope_id)) { return error.Overflow; } } else { return error.InvalidChar; } } else if (c == ':') { if (!saw_any_digits) { return error.InvalidChar; } if (index == 14) { return error.JunkAtEnd; } ip_slice[index] = @truncate(u8, x >> 8); index += 1; ip_slice[index] = @truncate(u8, x); index += 1; x = 0; saw_any_digits = false; } else if (c == '%') { if (!saw_any_digits) { return error.InvalidChar; } if (index == 14) { ip_slice[index] = @truncate(u8, x >> 8); index += 1; ip_slice[index] = @truncate(u8, x); index += 1; } scope_id = true; saw_any_digits = false; } else { const digit = hex_digit(c); if (digit == @max_value(u8)) { return error.InvalidChar; } if (@mul_with_overflow(u16, x, 16, &x)) { return error.Overflow; } if (@add_with_overflow(u16, x, digit, &x)) { return error.Overflow; } saw_any_digits = true; } } if (!saw_any_digits) { return error.Incomplete; } /* if (p) { if (isdigit(*++p)) scopeid = strtoull(p, &z, 10); else z = p-1; if (*z) { if (!IN6_IS_ADDR_LINKLOCAL(&a6) && !IN6_IS_ADDR_MC_LINKLOCAL(&a6)) return EAI_NONAME; scopeid = if_nametoindex(p); if (!scopeid) return EAI_NONAME; } if (scopeid > UINT_MAX) return EAI_NONAME; } */ if (scope_id) { return result; } if (index == 14) { ip_slice[14] = @truncate(u8, x >> 8); ip_slice[15] = @truncate(u8, x); return result; } return error.Incomplete; } fn parse_ip4(buf: []const u8) -> %u32 { var result: u32 = undefined; const out_ptr = ([]u8)((&result)[0...1]); var x: u8 = 0; var index: u8 = 0; var saw_any_digits = false; for (buf) |c| { if (c == '.') { if (!saw_any_digits) { return error.InvalidChar; } if (index == 3) { return error.JunkAtEnd; } out_ptr[index] = x; index += 1; x = 0; saw_any_digits = false; } else if (c >= '0' && c <= '9') { saw_any_digits = true; const digit = c - '0'; if (@mul_with_overflow(u8, x, 10, &x)) { return error.Overflow; } if (@add_with_overflow(u8, x, digit, &x)) { return error.Overflow; } } else { return error.InvalidChar; } } if (index == 3 && saw_any_digits) { out_ptr[index] = x; return result; } return error.Incomplete; } #attribute("test") fn test_parse_ip4() { assert(%%parse_ip4("127.0.0.1") == be_to_host(u32)(0x7f000001)); switch (parse_ip4("256.0.0.1")) { Overflow => {}, else => unreachable {}, } switch (parse_ip4("x.0.0.1")) { InvalidChar => {}, else => unreachable {}, } switch (parse_ip4("127.0.0.1.1")) { JunkAtEnd => {}, else => unreachable {}, } switch (parse_ip4("127.0.0.")) { Incomplete => {}, else => unreachable {}, } switch (parse_ip4("100..0.1")) { InvalidChar => {}, else => unreachable {}, } } #attribute("test") fn test_parse_ip6() { { const addr = %%parse_ip6("FF01:0:0:0:0:0:0:FB"); assert(addr.addr[0] == 0xff); assert(addr.addr[1] == 0x01); assert(addr.addr[2] == 0x00); } } #attribute("test") fn test_lookup_simple_ip() { { var addrs_buf: [5]Address = undefined; const addrs = %%lookup("192.168.1.1", addrs_buf); assert(addrs.len == 1); const addr = addrs[0]; assert(addr.family == linux.AF_INET); assert(addr.addr[0] == 192); assert(addr.addr[1] == 168); assert(addr.addr[2] == 1); assert(addr.addr[3] == 1); } } const be_to_host = host_to_be; fn host_to_be(T: type)(x: T) -> T { if (@compile_var("is_big_endian")) x else endian_swap(T)(x) } fn endian_swap(T: type)(x: T) -> T { const x_slice = ([]u8)((&const x)[0...1]); var result: T = undefined; const result_slice = ([]u8)((&result)[0...1]); for (result_slice) |*b, i| { *b = x_slice[@sizeof(T) - i - 1]; } return result; }