module websocket import encoding.utf8 const ( header_len_offset = 2 buffer_size = 256 extended_payload16_end_byte = 4 extended_payload64_end_byte = 10 ) struct Fragment { data []byte opcode OPCode } struct Frame { mut: header_len int = 2 frame_size int = 2 fin bool rsv1 bool rsv2 bool rsv3 bool opcode OPCode has_mask bool payload_len int masking_key [4]byte } const ( invalid_close_codes = [999, 1004, 1005, 1006, 1014, 1015, 1016, 1100, 2000, 2999, 5000, 65536] ) // validate_client, validate client frame rules from RFC6455 pub fn (mut ws Client) validate_frame(frame &Frame) ? { if frame.rsv1 || frame.rsv2 || frame.rsv3 { ws.close(1002, 'rsv cannot be other than 0, not negotiated') return error('rsv cannot be other than 0, not negotiated') } if (int(frame.opcode) >= 3 && int(frame.opcode) <= 7) || (int(frame.opcode) >= 11 && int(frame.opcode) <= 15) { ws.close(1002, 'use of reserved opcode')? return error('use of reserved opcode') } if frame.has_mask && !ws.is_server { // Server should never send masked frames // to client, close connection ws.close(1002, 'client got masked frame')? return error('client sent masked frame') } if is_control_frame(frame.opcode) { if !frame.fin { ws.close(1002, 'control message must not be fragmented')? return error('unexpected control frame with no fin') } if frame.payload_len > 125 { ws.close(1002, 'control frames must not exceed 125 bytes')? return error('unexpected control frame payload length') } } if frame.fin == false && ws.fragments.len == 0 && frame.opcode == .continuation { err_msg := 'unexecpected continuation, there are no frames to continue, $frame' ws.close(1002, err_msg)? return error(err_msg) } } [inline] fn is_control_frame(opcode OPCode) bool { return opcode !in [.text_frame, .binary_frame, .continuation] } [inline] fn is_data_frame(opcode OPCode) bool { return opcode in [.text_frame, .binary_frame] } // read_payload, reads the payload from socket fn (mut ws Client) read_payload(frame &Frame) ?[]byte { if frame.payload_len == 0 { return []byte{} } // TODO: make a dynamic reusable memory pool here mut buffer := []byte{cap: frame.payload_len} mut read_buf := [1]byte{} mut bytes_read := 0 for bytes_read < frame.payload_len { len := ws.socket_read_ptr(byteptr(&read_buf), 1)? if len != 1 { return error('expected read all message, got zero') } bytes_read += len buffer << read_buf[0] } if bytes_read != frame.payload_len { return error('failed to read payload') } if frame.has_mask { for i in 0 .. frame.payload_len { buffer[i] ^= frame.masking_key[i % 4] & 0xff } } return buffer } // validate_utf_8, validates payload for valid utf encoding // todo: support fail fast utf errors for strict autobahn conformance fn (mut ws Client) validate_utf_8(opcode OPCode, payload []byte) ? { if opcode in [.text_frame, .close] && !utf8.validate(payload.data, payload.len) { ws.logger.error('malformed utf8 payload, payload len: ($payload.len)') ws.send_error_event('Recieved malformed utf8.') ws.close(1007, 'malformed utf8 payload') return error('malformed utf8 payload') } } // read_next_message reads 1 to n frames to compose a message pub fn (mut ws Client) read_next_message() ?Message { for { frame := ws.parse_frame_header()? // This debug message leaks so remove if needed // ws.debug_log('read_next_message: frame\n$frame') ws.validate_frame(&frame)? frame_payload := ws.read_payload(&frame)? if is_control_frame(frame.opcode) { // Control frames can interject other frames // and need to be returned immediately msg := Message{ opcode: OPCode(frame.opcode) payload: frame_payload.clone() } unsafe { frame_payload.free() } return msg } // If the message is fragmented we just put it on fragments // a fragment is allowed to have zero size payload if !frame.fin { ws.fragments << &Fragment{ data: frame_payload.clone() opcode: frame.opcode } unsafe { frame_payload.free() } continue } if ws.fragments.len == 0 { ws.validate_utf_8(frame.opcode, frame_payload) or { ws.logger.error('UTF8 validation error: $err, len of payload($frame_payload.len)') ws.send_error_event('UTF8 validation error: $err, len of payload($frame_payload.len)') return error(err) } msg := Message{ opcode: OPCode(frame.opcode) payload: frame_payload.clone() } unsafe { frame_payload.free() } return msg } defer { ws.fragments = [] } if is_data_frame(frame.opcode) { ws.close(0, '')? return error('Unexpected frame opcode') } payload := ws.payload_from_fragments(frame_payload)? opcode := ws.opcode_from_fragments() ws.validate_utf_8(opcode, payload)? msg := Message{ opcode: opcode payload: payload.clone() } unsafe { frame_payload.free() payload.free() } return msg } } // payload_from_fragments, returs the whole paylaod from fragmented message fn (ws Client) payload_from_fragments(fin_payload []byte) ?[]byte { mut total_size := 0 for f in ws.fragments { if f.data.len > 0 { total_size += f.data.len } } total_size += fin_payload.len if total_size == 0 { return []byte{} } mut total_buffer := []byte{cap: total_size} for f in ws.fragments { if f.data.len > 0 { total_buffer << f.data } } total_buffer << fin_payload return total_buffer } // opcode_from_fragments, returns the opcode for message from the first fragment sent fn (ws Client) opcode_from_fragments() OPCode { return OPCode(ws.fragments[0].opcode) } // parse_frame_header parses next message by decoding the incoming frames pub fn (mut ws Client) parse_frame_header() ?Frame { // TODO: make a dynamic reusable memory pool here // mut buffer := []byte{cap: buffer_size} mut buffer := [256]byte{} mut bytes_read := 0 mut frame := Frame{} mut rbuff := [1]byte{} mut mask_end_byte := 0 for ws.state == .open { // Todo: different error scenarios to make sure we close correctly on error // reader.read_into(mut rbuff) ? read_bytes := ws.socket_read_ptr(byteptr(rbuff), 1)? if read_bytes == 0 { // This is probably a timeout or close continue } buffer[bytes_read] = rbuff[0] bytes_read++ // parses the first two header bytes to get basic frame information if bytes_read == u64(header_len_offset) { frame.fin = (buffer[0] & 0x80) == 0x80 frame.rsv1 = (buffer[0] & 0x40) == 0x40 frame.rsv2 = (buffer[0] & 0x20) == 0x20 frame.rsv3 = (buffer[0] & 0x10) == 0x10 frame.opcode = OPCode(int(buffer[0] & 0x7F)) frame.has_mask = (buffer[1] & 0x80) == 0x80 frame.payload_len = buffer[1] & 0x7F // if has mask set the byte postition where mask ends if frame.has_mask { mask_end_byte = if frame.payload_len < 126 { header_len_offset + 4 } else if frame.payload_len == 126 { header_len_offset + 6 } else if frame.payload_len == 127 { header_len_offset + 12 } else { 0 } // Impossible } frame.payload_len = frame.payload_len frame.frame_size = frame.header_len + frame.payload_len if !frame.has_mask && frame.payload_len < 126 { break } } if frame.payload_len == 126 && bytes_read == u64(extended_payload16_end_byte) { frame.header_len += 2 frame.payload_len = 0 frame.payload_len |= buffer[2] << 8 frame.payload_len |= buffer[3] << 0 frame.frame_size = frame.header_len + frame.payload_len if !frame.has_mask { break } } if frame.payload_len == 127 && bytes_read == u64(extended_payload64_end_byte) { frame.header_len += 8 // TODO Not sure... frame.payload_len = 0 frame.payload_len |= buffer[2] << 56 frame.payload_len |= buffer[3] << 48 frame.payload_len |= buffer[4] << 40 frame.payload_len |= buffer[5] << 32 frame.payload_len |= buffer[6] << 24 frame.payload_len |= buffer[7] << 16 frame.payload_len |= buffer[8] << 8 frame.payload_len |= buffer[9] << 0 if !frame.has_mask { break } } // We have a mask and we read the whole mask data if frame.has_mask && bytes_read == mask_end_byte { frame.masking_key[0] = buffer[mask_end_byte - 4] frame.masking_key[1] = buffer[mask_end_byte - 3] frame.masking_key[2] = buffer[mask_end_byte - 2] frame.masking_key[3] = buffer[mask_end_byte - 1] break } } return frame } // unmask_sequence unmask any given sequence fn (f Frame) unmask_sequence(mut buffer []byte) { for i in 0 .. buffer.len { buffer[i] ^= f.masking_key[i % 4] & 0xff } }