📄 rfc166.txt
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Network Working Group Bob AndersonRequest for Comments: 166 RandNIC 6780 Vint Cerf UCLA Eric Harslem John Haefner Rand Jim Madden U. of Illinois Bob Metcalfe MIT Arie Shoshani SDC Jim White UCSB David Wood Mitre 25 May 1971 DATA RECONFIGURATION SERVICE -- AN IMPLEMENTATION SPECIFICATION CONTENTS I. INTRODUCTION ................................... 2 Purpose of this RFC ............................ 2 Motivation ..................................... 2 II. OVERVIEW OF THE DATA RECONFIGURATION SERVICE ... 3 Elements of the Data Reconfiguration SERVICE ... 3 Conceptual Network Connections ................. 3 Conception Protocols and Message Formats ....... 4 Example Connection Configurations .............. 7 III. THE FORM MACHINE ............................... 8 Input/Output Streams and Forms ................. 8 Form Machine BNF Syntax ........................ 8 Alternate Specification of Form Machine Syntax . 9 Forms .......................................... 10 Rules .......................................... 10 Terms .......................................... 11 Term Format 1 ................................ 11 Term Format 2 ................................ 11 Term Format 3 ................................ 14 Term Format 4 ................................ 14Anderson, et al. [Page 1]
RFC 166 Data Reconfiguration Service May 1971 The Application of a Term .................... 14 Restrictions and Interpretations of Term Functions .................................. 15 Term and Rule Sequencing ..................... 16 IV. EXAMPLES ....................................... 17 Remarks ........................................ 17 Field Insertion ................................ 17 Deletion ....................................... 17 Variable Length Records ........................ 18 String Length Computation ...................... 18 Transposition .................................. 18 Character Packing and Unpacking ................ 18 I. INTRODUCTIONPURPOSE OF THIS RFC The Purpose of this RFC is to specify the Data Reconfiguration Service (DRS.) The DRS experiment involves a software mechanism to reformat Network data streams. The mechanism can be adapted to numerous Network application programs. We hope that the result of the experiment will lead to a future standard service that embodies the principles described in this RFC.MOTIVATION Application programs require specific data I/O formats yet the formats are different from program to program. We take the position that the Network should adapt to the individual program requirements rather than changing each program to comply with a standard. This position doesn't preclude the use of standards that describe the formats of regular message contents; it is merely an interpretation of a standard as being a desirable mode of operation but not a necessary one. In addition to differing program requirements, a format mismatch problem occurs where users wish to employ many different kinds of consoles to attach to a single service program. It is desirable to have the Network adapt to individual console configurations rather than requiring unique software packages for each console transformation.Anderson, et al. [Page 2]
RFC 166 Data Reconfiguration Service May 1971 One approach to providing adaptation is for those sites with substantial computing power to offer a data reconfiguration service; this document is a specification of such a service. The envisioned modus operandi of the service is that an applications programmer defines _forms_ that describe data reconfigurations. The service stores the forms by name. At a later time, a user (perhaps a non-programmer) employs the service to accomplish a particular transformation of a Network data stream, simply by calling the form by name. We have attempted to provide a notation tailored to some specifically needed instances of data reformatting while keeping the notation and its underlying implementation within some utility range that is bounded on the lower end by a notation expressive enough to make the experimental service useful, and that is bounded on the upper end by a notation short of a general purpose programming language. II. OVERVIEW OF THE DATA RECONFIGURATION SERVICEELEMENTS OF THE DATA RECONFIGURATION SERVICE An implementation of the Data Reconfiguration Service (DRS) includes modules for connection protocols, a handler of some requests that can be made of the service, a compiler and/or interpreter (called the Form Machine) to act on those requests, and a file storage module for saving and retrieving definitions of data reconfigurations (forms). This section describes connection protocols and requests. The next section covers the Form Machine language in some detail. File storage is not described in this document because it is transparent to the use of the service an its implementation is different at each DRS host.CONCEPTUAL NETWORK CONNECTIONS There are three conceptual Network connections to the DRS, see Fig. 1. 1) The control connection (CC) is between an originating user and the DRS. Forms specifying data reconfigurations are defined over this connection. The user indicates (once) forms to be applied to data passing over the two connections described below. 2) The user connection (UC) is between a user process and the DRS.Anderson, et al. [Page 3]
RFC 166 Data Reconfiguration Service May 1971 3) The server connection (SC) is between the DRS and the serving process. Since the goal is to adapt the Network to user and server processes, a minimum of requirements are imposed on the UC and SC. +------------+ +------+ +---------+ | ORIGINATING| CC | DRS | SC | SERVER | | USER |--------------| |----------| PROCESS | +------------+ ^ +------+ ^ +---------+ | / | | UC/ <-----\ | | / \ | | +-----------+ \| TELNET ---------+ | USER | +-- Simplex or Duplex Protocol | PROCESS | Connections Connection +-----------+ Figure 1. DRS Network ConnectionsCONNECTION PROTOCOLS AND MESSAGE FORMATS Over a control connection the dialog is directly between an originating user and the DRS. Here the user is defining forms or assigning predefined forms to connections for reformatting. The user connects to the DRS via the standard initial connection protocol (ICP). Rather than going through a logger, the user calls on a particular socket on which the DRS alway listens. (Experimental socket numbers will be published later.) DRS switches the user to another socket pair. Messages sent over a control connection are of the types and formats specified for TELNET. (The data type code should specify ASCII -- the default.) Thus, a user at a terminal should be able to connect to a DRS via his local TELNET, for example, as shown in Fig. 2. +---------+ CC +---------+ +---------| TELNET |-------| DRS | | +---------+ +---------+ +-----------------------+ | USER | | (TERMINAL OR PROGRAM) | +-----------------------+ Figure 2. A TELNET Connection to DRSAnderson, et al. [Page 4]
RFC 166 Data Reconfiguration Service May 1971 When a user connects to DRS he supplies a six-character user ID (UID) as a qualifier to guarantee the uniqueness of his form names. He will initially have the following commands: 1. DEFFORM (form) 2. ENDFORM (form) These two commands define a form, the text of which is chronologically entered between them. The form is stored in the DRS local file system. 3. PURGE (form) The named form, as qualified by the current UID, is purged from the DRS file system. 4. LISTNAMES (UID) The unqualified names of all forms assigned to UID are returned. 5. LISTFORM (form) The source text of a named form is returned. 6. DUPLEXCONNECT (user site, user receive socket, user method, server site, server receive socket, server method, user- to-server form name, server-to-user form name) A duplex connection is made between two processes using the receive sockets and the sockets one greater. Method is defined below. The forms define the transformations on these connections. 7. SIMPLEXCONNECT (user site, user socket, user method, server site, server socket, server method, form) A simplex connection is made between the two sockets as specified by method. 8. ABORT (site, receive socket) The reconfiguration of data is terminated by closing both the UC and SC specified in part in the command. Either one, both, or neither of the two parties specified in 6 or 7 may be at the same host as the party issuing the request. Sites and sockets specify user and server for the connection. Method indicatesAnderson, et al. [Page 5]
RFC 166 Data Reconfiguration Service May 1971 the way in which the connection is established. The following rules apply to these commands: 1) Commands may be abbreviated to the minimum number of characters to identify them uniquely. 2) All commands should be at the start of a line. 3) Parameters are enclosed in parentheses and separated by commas. 4) Imbedded blanks are ignored. 5) The parameters are: form name 1-6 characters UID 1-6 characters Site 1-2 characters specifying the hexadecimal host number Socket 1-8 characters specifying the hexadecimal socket number Method A single character 6) Method has the following values: C The site/socket is already connected to the DRS as a dummy control connection (should not be the real control connection). I Connect via the standard ICP (does not apply to SIMPLEXCONNECT). D Connect directly via STR, RTS. The DRS will make at least the following minimal responses to the user: 1) A positive or negative acknowledgement after each line (CR/LF) 2) If a form fails or terminates TERMINATE, ASCII Host # as hex, ASCII Socket # as hex, ASCII Return Code as decimal thus identifying at least one end of the connection.Anderson, et al. [Page 6]
RFC 166 Data Reconfiguration Service May 1971EXAMPLE CONNECTION CONFIGURATIONS There are basically two modes of DRS operation: 1) the user wishes to establish a DRS UC/SC connection(s) between the programs and 2) the user wants to establish the same connection(s) where he (his terminal) is at the end of the UC or the SC. The latter case is appropriate when the user wishes to interact from his terminal with the serving process (e.g., a logger). In the first case (Fig. 1, where the originating user is either a terminal or a program) the user issues the appropriate CONNECT command. The UC/SC can be simplex or duplex. The second case has two possible configurations, shown in Figs. 3 and 4. +-------+ +--------+ CC +-----+ +----+ | |----| |---------| | SC | | | USER | | TELNET | UC | DRS |--------| SP | | |----| |---------| | | | +-------+ +--------+ +-----+ +----+ Figure 3. Use of Dummy Control Connection +---------+ +------+ /| USER | CC +-----+ | |---/ | SIDE |--------| | SC +----+ | USER | +---------+ UC | DRS |--------| SP | | |---\ | SERVING |--------| | +----+ +------+ \| SIDE | +-----+ +---------+⌨️ 快捷键说明
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