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ISO/IEC 15909: A Simple Example of Protocol Specification and Verification. Jonathan Billington Computer Systems Engineering Centre School of Electrical and Information Engineering University of South Australia 16 September 2003. Goal. To illustrate the use of ISO/IEC 15909
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ISO/IEC 15909: A Simple Example of Protocol Specification and Verification Jonathan Billington Computer Systems Engineering Centre School of Electrical and Information Engineering University of South Australia 16 September 2003
Goal • To illustrate the use of ISO/IEC 15909 • Use a simple stop and wait protocol • Illustrate specification and verification • Use concrete syntax of Coloured Petri Nets • Use Design/CPN for graphical representation SC7/WG19 Geneva 2003
High-level Nets • Standard: ISO/IEC 15909 • Part 1: Concepts, Definitions and Graphical Notation (FDIS) • CPN semantics • Algebraic graphical form (signatures) • Part 2: Transfer Format (PNML) • XML based • First draft (Ekkart Kindler) • Part 3: Extensions (Future) • Modularity (eg hierarchical models) • Time SC7/WG19 Geneva 2003
High-level Net Semantics HLPN = (P,T,D;Type,Pre,Post,M0) • P is a finite set of Places • T is a finite set Transitions disjoint from P • D is a non-empty finite set of non-empty domains (sets) where each element of D is called a type • Type:PUT D is a function used to assign types to places and to determine transition modes • Pre,Post:TRANS μPLACE are the pre and post mappings • TRANS = {(t,m) | t Є T, m Є Type(t)} • PLACE = {(p,g) | p Є P, g Є Type(p)} • M0 ЄμPLACE is a multiset, the initial marking of the net • μPLACE is the set of multisets over the set, PLACE SC7/WG19 Geneva 2003
Stop and Wait Protocols (SWP) • Send a message and wait for ack before sending the next message (flow control) • Recover from loss by retransmissions (ARQ) • Receiver discarding messages with bit errors • Router discarding messages due to congestion • Sequence Number included to detect duplicates • Finite maximum sequence number: MaxSeqNo • Modulo arithmetic MaxSeqNo + 1 • Maximum Retransmission Counter: MaxRetrans • Medium • Initially order preserving channels (DLL Protocol) • However, part of TCP (window size of one) SC7/WG19 Geneva 2003
Motivation • TCP is the dominant transport protocol in the Internet • TCP uses ARQ with 32 bit sequence numbers • Original designers were concerned about duplicates • message is delayed in reordering medium • sequence numbers wrap • then duplicate can be accepted as a new message • Proposed • 3 way handshake (old connections) plus • large sequence numbers (same connection) • time to live in IP (but implemented as hop count) • Networks are getting faster – Gbit/s and beyond • How does the simplest ARQ (SWP) fail? SC7/WG19 Geneva 2003
Approach • Use graphical models that allow for visualisation • Coloured Petri net models of the SWP • Lossy FIFO channel • Lossy reordering channel • Properties • Boundedness of channels • Stop and Wait Service – alternating sends and receives • Duplicate acceptance • Message Loss • Hand proofs for boundedness (general) • Reachability analysis, automata reduction and language equivalence for the other 3 properties (limited parameter values) • Use Design/CPN (Aarhus) and FSM (ATT) SC7/WG19 Geneva 2003
Modelling Assumptions • Stop and Wait ARQ Protocol • Recovery from loss by retransmissions • Retransmission counter with limit: MaxRetrans • Transmission is aborted when limit reached – not modelled • Bounded sequence numbers: MaxSeqNo • Message represented by sequence number only – data independence assumption • Channels • Lossy/lossless unbounded FIFO • Lossy/lossless, re-ordering and unbounded • Lossy/lossless, re-ordering and bounded SC7/WG19 Geneva 2003
CPN Model 1 SWP over Lossy FIFO Channels • Sender: • Send message as sequence number (sn) • Retransmission on timeout to limit (MaxRetrans) • Receive acks and duplicate acks • Increment sn modulo MaxSeqNo + 1 • Receiver: • Receive messages (sn=rn) and discard duplicates • Send ack of next expected message (rn) • FIFO Channel: • Message loss (or not) SC7/WG19 Geneva 2003
SWP over Lossy FIFO: Results • Boundedness • arbitrary MaxSeqNo and MaxRetrans • bound on FIFO length of both mess_channel and ack_channel given by 2MaxRetrans + 1 • Alternating sends and receives (sn=rn) • No duplication • No loss (except for possibly the last message if the transmission is aborted, i.e. MaxRetrans limit is reached) SC7/WG19 Geneva 2003
CPN Model 2 SWP over Lossy Reordering Channels • Same as CPN Model 1 except for the message and ack channels • Each channel is represented by a place, where a token is a message (rather than a list of messages) • Loss of any message or ack at anytime • Can switch loss off readily by use of the guard false on the loss transitions SC7/WG19 Geneva 2003
SWP over Lossy non-FIFO: Results 1 • Theorem 1 For the SWP of CPN2 (lossy non-FIFO channels), with MaxRetrans and MaxSeqNo > 0, the message channel is unbounded. • Proof sketch: • find transition sequence (cycle) that on each repetition will increase the number of tokens in mess_channel by 1 • consider: send_mess, receive_mess (sn=rn), send_ack, timeout_retrans, receive_ack • from the initial marking, a new marking with send_mess enabled and duplicate in mess_channel is obtained • repeat transition sequence • every repetition of the sequence increases the number of tokens in mess_channel by one • sequence can be repeated indefinitely => unbounded. SC7/WG19 Geneva 2003
SWP over Lossy non-FIFO: Results 2 • Theorem 2 For the SWP of CPN2 with MaxRetrans and MaxSeqNo > 0, the ack channel is unbounded. • Proof: • consider transition sequence: send_mess, receive_mess(sn=rn), send_ack, timeout_retrans, receive_ack, receive_mess, send_ack • same arguments as for the proof of Theorem 1 SC7/WG19 Geneva 2003
SWP over Lossy non-FIFO: Results 3 • Theorem 3 The SWP of CPN2 with MaxRetrans and MaxSeqNo > 0, does not satisfy the Stop and Wait service. • Theorem 4 For the SWP of CPN2 with MaxRetrans and MaxSeqNo > 0, duplicates may be received as new messages. • Theorem 5 For the SWP of CPN2 with MaxRetrans and MaxSeqNo > 0, messages can be lost without being detected. SC7/WG19 Geneva 2003
Proof of Theorems 3-5 • Use language analysis to consider sequences of sends and receives: desired service is (send receive)* • send is send_mess; receive is receive_mess(sn=rn) • Restricted to bounded channels (capacity = 2), but if there are failures in this case, they will also occur for capacities > 2 (conjecture) • Set MaxRetrans = 1 = MaxSeqNo. Any incorrect behaviour also present when MaxRetrans, MaxSeqNo > 1 (conjecture) • Two cases: • No message loss • With message loss SC7/WG19 Geneva 2003
FSA for Lossless Channel • OG: 410 nodes and 848 arcs • Minimised FSA: 14 states and 21 transitions • Stop and Wait Service not satisfied as • Alternating sequences of sends and receives is violated (s=send, r=receive) • Duplicate acceptance cycles: • (srr)* : 5 s 8 r 11 r 13 s 6 r 4 r 5 • (srsrrr)* : 7 s 10 r 13 s 6 r 4 r 5 r 7 • Loss Cycles: • (sssr)* : 13 s 6 s 9 s 12 r 13 • Messages lost even though channel not lossy ! • Problems do not occur till SNs wrap SC7/WG19 Geneva 2003
FSA for Lossy Channel • OG: 624 nodes and 2484 arcs • Minimised FSA: 29 states and 47 transitions • All states are acceptance states • Stop and Wait Service not satisfied • Duplicate acceptance cycles • Loss Cycles • Problems do not occur till SNs wrap SC7/WG19 Geneva 2003
Relevance to TCP • TCP uses a sliding window mechanism with dynamic changes to window size and 32 bit SN • Reduces to a stop and wait protocol if window size is set to one • Conjecture that similar modes of loss and duplication will occur with TCP if • Sequence numbers wrap; and • Duplicates still exist in the Internet • Time-to-live field in IP packets (hop count!) • RFC 793 (TCP) suggests Max Seg Lifetime of 2 minutes • At 1 Gbit/s effective throughput, SN wrap in 34 secs, allowing duplicates to still be present, but need 4GB of data to send! • RFC 1323 recommends the use of 32 bit time-stamps to overcome this problem (PAWS) • 64 bit SN? - at 10 Gbit/s would take 470 years to wrap SC7/WG19 Geneva 2003
Relevance to TCP - II • Unbounded channels • Will potentially unbounded growth of messages lead to congestion? • Due to retransmissions, which will occur • Most duplicates will be deleted by the receiver • Remaining duplicates will be killed off after time to live limit is reached (if implemented) • Congestion control procedures already in place • Conclusion: No problem for TCP SC7/WG19 Geneva 2003
Conclusions • Shown that Stop and Wait Protocols do not work over reordering channels in the following ways: • The channels are unbounded (for any MaxRetrans, MaxSeqNo) • The SWP does not satisfy its service of (sr)* • Cyclic behaviour exists where: • Duplicates can be accepted as new messages • Messages can be lost (unknowingly) • Congestion • Lossy FIFO channels, congestion contained (2MaxRetrans + 1) • Reordering channels, other mechanisms required • The last 3 problems depend on SNs wrapping • For Gbit/s networks, duplicates and loss can be a problem => implement PAWS as per RFC 1323 SC7/WG19 Geneva 2003
Future Work • Extend work to TCP mechanisms, including PAWS • Incorporate mechanisms into CPN model for deleting old messages • Formally extend results for loss and duplication to arbitrary values of MaxRetrans, MaxSeqNo and channel capacity • Investigate duplication and loss even when (sr)* is not violated SC7/WG19 Geneva 2003