📄 rfc1549.txt
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Simpson [Page 6]
RFC 1549 HDLC Framing Decvember 1993 3309 [2] or CCITT X.25 [6]. The end of the Information and Padding fields is found by locating the closing Flag Sequence and removing the Frame Check Sequence field.3.2. Modification of the Basic Frame The Link Control Protocol can negotiate modifications to the basic HDLC frame structure. However, modified frames will always be clearly distinguishable from standard frames. Address-and-Control-Field-Compression When using the default HDLC framing, the Address and Control fields contain the hexadecimal values 0xff and 0x03 respectively. On transmission, compressed Address and Control fields are formed by simply omitting them. On reception, the Address and Control fields are decompressed by examining the first two octets. If they contain the values 0xff and 0x03, they are assumed to be the Address and Control fields. If not, it is assumed that the fields were compressed and were not transmitted. By definition, the first octet of a two octet Protocol field will never be 0xff (since it is not even). The Protocol field value 0x00ff is not allowed (reserved) to avoid ambiguity when Protocol-Field-Compression is enabled and the first Information field octet is 0x03. When other Address or Control field values are in use, Address- and-Control-Field-Compression MUST NOT be negotiated.4. Asynchronous HDLC This section summarizes the use of HDLC with 8-bit asynchronous links. Flag Sequence The Flag Sequence indicates the beginning or end of a frame. The octet stream is examined on an octet-by-octet basis for the value 01111110 (hexadecimal 0x7e).Simpson [Page 7]
RFC 1549 HDLC Framing Decvember 1993 Transparency An octet stuffing procedure is used. The Control Escape octet is defined as binary 01111101 (hexadecimal 0x7d) where the bit positions are numbered 87654321 (not 76543210, BEWARE). Each end of the link maintains two Async-Control-Character-Maps. The receiving ACCM is 32 bits, but the sending ACCM may be up to 256 bits. This results in four distinct ACCMs, two in each direction of the link. The default receiving ACCM is 0xffffffff. The default sending ACCM is 0xffffffff, plus the Control Escape and Flag Sequence characters themselves, plus whatever other outgoing characters are known to be intercepted. After FCS computation, the transmitter examines the entire frame between the two Flag Sequences. Each Flag Sequence, Control Escape octet, and octet with value less than hexadecimal 0x20 which is flagged in the sending Async-Control-Character-Map, is replaced by a two octet sequence consisting of the Control Escape octet and the original octet with bit 6 complemented (exclusive- or'd with hexadecimal 0x20). Prior to FCS computation, the receiver examines the entire frame between the two Flag Sequences. Each octet with value less than hexadecimal 0x20 is checked. If it is flagged in the receiving Async-Control-Character-Map, it is simply removed (it may have been inserted by intervening data communications equipment). For each Control Escape octet, that octet is also removed, but bit 6 of the following octet is complemented, unless it is the Flag Sequence. Note: The inclusion of all octets less than hexadecimal 0x20 allows all ASCII control characters [8] excluding DEL (Delete) to be transparently communicated through all known data communications equipment. The transmitter may also send octets with value in the range 0x40 through 0xff (except 0x5e) in Control Escape format. Since these octet values are not negotiable, this does not solve the problem of receivers which cannot handle all non-control characters. Also, since the technique does not affect the 8th bit, this does not solve problems for communications links that can send only 7- bit characters. A few examples may make this more clear. Packet data is transmitted on the link as follows:Simpson [Page 8]
RFC 1549 HDLC Framing Decvember 1993 0x7e is encoded as 0x7d, 0x5e. 0x7d is encoded as 0x7d, 0x5d. 0x01 is encoded as 0x7d, 0x21. Some modems with software flow control may intercept outgoing DC1 and DC3 ignoring the 8th (parity) bit. This data would be transmitted on the link as follows: 0x11 is encoded as 0x7d, 0x31. 0x13 is encoded as 0x7d, 0x33. 0x91 is encoded as 0x7d, 0xb1. 0x93 is encoded as 0x7d, 0xb3. Aborting a Transmission On asynchronous links, frames may be aborted by transmitting a "0" stop bit where a "1" bit is expected (framing error) or by transmitting a Control Escape octet followed immediately by a closing Flag Sequence. Time Fill For asynchronous links, inter-octet and inter-frame time fill MUST be accomplished by transmitting continuous "1" bits (mark-hold state). Inter-frame time fill can be viewed as extended inter-octet time fill. Doing so can save one octet for every frame, decreasing delay and increasing bandwidth. This is possible since a Flag Sequence may serve as both a frame close and a frame begin. After having received any frame, an idle receiver will always be in a frame begin state. Robust transmitters should avoid using this trick over-zealously, since the price for decreased delay is decreased reliability. Noisy links may cause the receiver to receive garbage characters and interpret them as part of an incoming frame. If the transmitter does not send a new opening Flag Sequence before sending the next frame, then that frame will be appended to the noise characters causing an invalid frame (with high reliability). It is suggested that implementations will achieve the best results by always sending an opening Flag Sequence if the new frame is not back-to-back with the last. Transmitters SHOULD send an open Flag Sequence whenever "appreciable time" has elapsed after the prior closing Flag Sequence. The maximum value for "appreciable time" is likely to be no greater than the typing rate of a slow typist, say 1 second. Encoding All octets are transmitted with one start bit, eight bits of data,Simpson [Page 9]
RFC 1549 HDLC Framing Decvember 1993 and one stop bit. There is no provision for seven bit asynchronous links.5. Bit-synchronous HDLC This section summarizes the use of HDLC with bit-synchronous links. Flag Sequence The Flag Sequence indicates the beginning or end of a frame, and is used for frame synchronization. The bit stream is examined on a bit-by-bit basis for the binary sequence 01111110 (hexadecimal 0x7e). The "shared zero mode" Flag Sequence "011111101111110" SHOULD NOT be used. When not avoidable, such an implementation MUST ensure that the first Flag Sequence detected (the end of the frame) is promptly communicated to the link layer. Use of the shared zero mode hinders interoperability with synchronous-to-asynchronous converters. Transparency The transmitter examines the entire frame between the two Flag Sequences. A "0" bit is inserted after all sequences of five contiguous "1" bits (including the last 5 bits of the FCS) to ensure that a Flag Sequence is not simulated. When receiving, any "0" bit that directly follows five contiguous "1" bits is discarded. Since the Control Escape octet-stuffing method is not used, the default receiving and sending Async-Control-Character-Maps are 0. There may be some use of synchronous-to-asynchronous converters (some built into modems) in point-to-point links resulting in a synchronous PPP implementation on one end of a link and an asynchronous implementation on the other. It is the responsibility of the converter to do all mapping conversions during operation. To enable this functionality, bit-synchronous PPP implementations MUST always respond to the Async-Control-Character-Map Configuration Option with an LCP Configure-Ack. However, acceptance of the Configuration Option does not imply that the bit-synchronous implementation will do any octet mapping. Instead, all such octet mapping will be performed by the asynchronous-to-synchronous converter.Simpson [Page 10]
RFC 1549 HDLC Framing Decvember 1993 Aborting a Transmission A sequence of more than six "1" bits indicates an invalid frame, which is ignored, and not counted as a FCS error. Inter-frame Time Fill For bit-synchronous links, the Flag Sequence SHOULD be transmitted during inter-frame time fill. There is no provision for inter- octet time fill. Mark idle (continuous ones) SHOULD NOT be used for inter-frame ill. However, certain types of circuit-switched links require the use of mark idle, particularly those that calculate accounting based on periods of bit activity. When mark idle is used on a bit-synchronous link, the implementation MUST ensure at least 15 consecutive "1" bits between Flags during the idle period, and that the Flag Sequence is always generated at the beginning of a frame after an idle period. Encoding The definition of various encodings and scrambling is the responsibility of the DTE/DCE equipment in use, and is outside the scope of this specification. While PPP will operate without regard to the underlying representation of the bit stream, lack of standards for transmission will hinder interoperability as surely as lack of data link standards. At speeds of 56 Kbps through 2.0 Mbps, NRZ is currently most widely available, and on that basis is recommended as a default. When configuration of the encoding is allowed, NRZI is recommended as an alternative, because of its relative immunity to signal inversion configuration errors, and instances when it MAY allow connection without an expensive DSU/CSU. Unfortunately, NRZI encoding obviates the (1 + x) factor of the 16-bit FCS, so that one error in 2**15 goes undetected (instead of one in 2**16), and triple errors are not detected. Therefore, when NRZI is in use, it is recommended that the 32-bit FCS be negotiated, which does not include the (1 + x) factor. At higher speeds of up to 45 Mbps, some implementors have chosen the ANSI High Speed Synchronous Interface [HSSI]. While this experience is currently limited, implementors are encouraged to cooperate in choosing transmission encoding.Simpson [Page 11]
RFC 1549 HDLC Framing Decvember 19936. Octet-synchronous HDLC This section summarizes the use of HDLC with octet-synchronous links, such as SONET and optionally ISDN B or H channels. Although the bit rate is synchronous, there is no bit-stuffing. Instead, the octet-stuffing feature of 8-bit asynchronous HDLC is used. Flag Sequence The Flag Sequence indicates the beginning or end of a frame. The octet stream is examined on an octet-by-octet basis for the value 01111110 (hexadecimal 0x7e). Transparency An octet stuffing procedure is used. The Control Escape octet is defined as binary 01111101 (hexadecimal 0x7d). The octet stuffing procedure is described in "Asynchronous HDLC" above. The sending and receiving implementations need escape only the Flag Sequence and Control Escape octets. Considerations concerning the use of converters are described in "Bit-synchronous HDLC" above. Aborting a Transmission Frames may be aborted by transmitting a Control Escape octet followed immediately by a closing Flag Sequence. The preceding frame is ignored, and not counted as a FCS error. Inter-frame Time Fill The Flag Sequence MUST be transmitted during inter-frame time fill. There is no provision for inter-octet time fill. Encoding The definition of various encodings and scrambling is the responsibility of the DTE/DCE equipment in use, and is outside the scope of this specification.Simpson [Page 12]⌨️ 快捷键说明
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