INTERNET DRAFT Mallikarjun Chadalapaka draft-ietf-ips-iscsi-impl-guide-01.txt Hewlett-Packard Co. Editor Expires March 2006 iSCSI Implementer's Guide Status of this Memo By submitting this Internet-Draft, each author represents that any applicable patent or other IPR claims of which he or she is aware have been or will be disclosed, and any of which he or she becomes aware will be disclosed, in accordance with Section 6 of BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet-Drafts. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than a "work in progress." The list of current Internet-Drafts can be accessed at http://www.ietf.org/1id-abstracts.html The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. Abstract iSCSI is a SCSI transport protocol and maps the SCSI family of application protocols onto TCP/IP. RFC 3720 defines the iSCSI protocol. This document compiles the clarifications to the original protocol definition in RFC 3720 to serve as a companion document for the iSCSI implementers. This document updates RFC 3720 and the text in this document supersedes the text in RFC 3720 when the two differ. Chadalapaka Expires February, 2006 [Page 1] Internet-Draft iSCSI Guide 19 September 2005 Table of Contents 1 Definitions and acronyms ...............................3 1.1 Definitions ............................................3 1.2 Acronyms ...............................................3 2 Introduction ...........................................5 3 iSCSI semantics for SCSI tasks .........................6 3.1 Residual handling ......................................6 3.1.1 Overview..............................................6 3.1.2 SCSI REPORT LUNS and Residual Overflow................7 3.2 R2T Ordering ...........................................8 4 Task Management ........................................9 4.1 Requests Affecting Multiple Tasks ......................9 4.1.1 Scope of affected tasks...............................9 4.1.2 Updated semantics.....................................9 4.1.3 Rationale behind the new semantics...................11 5 Discovery semantics ...................................13 5.1 Error Recovery for Discovery Sessions .................13 5.2 Reinstatement Semantics of Discovery Sessions .........13 5.2.1 Unnamed Discovery Sessions...........................14 5.2.2 Named Discovery Sessions.............................14 5.3 TPGT Values ...........................................15 6 iSCSI Error Handling and Recovery .....................16 6.1 ITT ...................................................16 6.2 Format Errors .........................................16 6.3 Digest Errors .........................................16 7 Security Considerations ...............................18 8 IANA Considerations ...................................19 9 References and Bibliography ...........................20 9.1 Normative References ..................................20 9.2 Informative References ................................20 10 Editor's Address ......................................21 11 Acknowledgements ......................................22 12 Full Copyright Statement ..............................23 13 Intellectual Property Statement .......................24 Chadalapaka Expires March, 2006 [Page 2] Internet-Draft iSCSI Guide 19 September 2005 1 Definitions and acronyms 1.1 Definitions I/O Buffer ¡ A buffer that is used in a SCSI Read or Write operation so SCSI data may be sent from or received into that buffer. For a read or write data transfer to take place for a task, an I/O Buffer is required on the initiator and at least one required on the target. SCSI-Presented Data Transfer Length (SPDTL): SPDTL is the aggregate data length of the data that SCSI layer logically "presents" to iSCSI layer for a Data-in or Data-out transfer in the context of a SCSI task. For a bidirectional task, there are two SPDTL values ¡ one for Data-in and one for Data-out. Note that the notion of "presenting" includes immediate data per the data transfer model in [SAM2], and excludes overlapping data transfers, if any, requested by the SCSI layer. Third-party: A term used in this document to denote nexus objects (I_T or I_T_L) and iSCSI sessions which reap the side-effects of actions took place in the context of a separate iSCSI session, while being third parties to the action that caused the side-effects. One example of a Third-party session is an iSCSI session hosting an I_T_L nexus to an LU that is reset with an LU Reset TMF via a separate I_T nexus. 1.2 Acronyms Acronym Definition ------------------------------------------------------------- EDTL Expected Data Transfer Length IANA Internet Assigned Numbers Authority IETF Internet Engineering Task Force I/O Input - Output IP Internet Protocol iSCSI Internet SCSI iSER iSCSI Extensions for RDMA Chadalapaka Expires March, 2006 [Page 3] Internet-Draft iSCSI Guide 19 September 2005 ITT Initiator Task Tag LO Leading Only LU Logical Unit LUN Logical Unit Number PDU Protocol Data Unit RDMA Remote Direct Memory Access R2T Ready To Transfer R2TSN Ready To Transfer Sequence Number RFC Request For Comments SAM SCSI Architecture Model SCSI Small Computer Systems Interface SN Sequence Number SNACK Selective Negative Acknowledgment - also Sequence Number Acknowledgement for data TCP Transmission Control Protocol TMF Task Management Function TTT Target Transfer Tag UA Unit Attention Chadalapaka Expires March, 2006 [Page 4] Internet-Draft iSCSI Guide 19 September 2005 2 Introduction Several iSCSI implementations had been built after [RFC3720] was published and the iSCSI community is now richer by the resulting implementation expertise. The goal of this document is to leverage this expertise both to offer clarifications to the [RFC3720] semantics and to address defects in [RFC3720] as appropriate. This document intends to offer critical guidance to implementers with regard to non-obvious iSCSI implementation aspects so as to improve interoperability and accelerate iSCSI adoption. This document, however, does not purport to be an all-encompassing iSCSI how-to guide for implementers, nor a complete revision of [RFC3720]. This document instead is intended as a companion document to [RFC3720] for the iSCSI implementers. iSCSI implementers are required to reference [RFC3722] and [RFC3723] in addition to [RFC3720] for mandatory requirements. In addition, [RFC3721] also contains useful information for iSCSI implementers. The text in this document, however, updates and supersedes the text in all the noted RFCs whenever there is such a question. Chadalapaka Expires March, 2006 [Page 5] Internet-Draft iSCSI Guide 19 September 2005 3 iSCSI semantics for SCSI tasks 3.1 Residual handling Section 10.4.1 of [RFC3720] defines the notion of "residuals" and specifies how the residual information should be encoded into the SCSI Response PDU in Counts and Flags fields. Section 3.1.1 clarifies the intent of [RFC3720] and explains the general principles. Section 3.1.2 describes the residual handling in the REPORT LUNS scenario. 3.1.1 Overview SCSI-Presented Data Transfer Length (SPDTL) is the term this document uses (see section 1.1 for definition) to represent the aggregate data length that the target SCSI layer attempts to transfer using the local iSCSI layer for a task. Expected Data Transfer Length (EDTL) is the iSCSI term that represents the length of data that iSCSI layer expects to transfer for a task. EDTL is specified in the SCSI Command PDU. When SPDTL = EDTL for a task, the target iSCSI layer completes the task with no residuals. Whenever SPDTL differs from EDTL for a task, that task is said to have a residual. If SPDTL > EDTL for a task, iSCSI Overflow MUST be signaled in the SCSI Response PDU as specified in [RFC3720]. Residual Count MUST be set to the numerical value of (SPDTL ¡ EDTL). If SPDTL < EDTL for a task, iSCSI Underflow MUST be signaled in the SCSI Response PDU as specified in [RFC3720]. Residual Count MUST be set to the numerical value of (EDTL ¡ SPDTL). Note that the Overflow and Underflow scenarios are independent of Data-in and Data-out. Either scenario is logically possible in either direction of data transfer. Chadalapaka Expires March, 2006 [Page 6] Internet-Draft iSCSI Guide 19 September 2005 3.1.2 SCSI REPORT LUNS and Residual Overflow The specification of the SCSI REPORT LUNS command requires that the SCSI target limit the amount of data transferred to a maximum size (ALLOCATION LENGTH) provided by the initiator in the REPORT LUNS CDB. If the Expected Data Transfer Length (EDTL) in the iSCSI header of the SCSI Command PDU for a REPORT LUNS command is set to at least as large as that ALLOCATION LENGTH, the SCSI layer truncation prevents an iSCSI Residual Overflow from occurring. A SCSI initiator can detect that such truncation has occurred via other information at the SCSI layer. The rest of the section elaborates this required behavior. iSCSI uses the (O) bit (bit 5) in the Flags field of the SCSI Response and the last SCSI Data-In PDUs to indicate that that an iSCSI target was unable to transfer all of the SCSI data for a command to the initiator because the amount of data to be transferred exceeded the EDTL in the corresponding SCSI Command PDU (see Section 10.4.1 of [RFC3720]). The SCSI REPORT LUNS command requests a target SCSI layer to return a logical unit inventory (LUN list) to the initiator SCSI layer (see section 6.21 of SPC-3 [SPC3]). The size of this LUN list may not be known to the initiator SCSI layer when it issues the REPORT LUNS command; to avoid transfer of more LUN list data than the initiator is prepared for, the REPORT LUNS CDB contains an ALLOCATION LENGTH field to specify the maximum amount of data to be transferred to the initiator for this command. If the initiator SCSI layer has under-estimated the number of logical units at the target, it is possible that the complete logical unit inventory does not fit in the specified ALLOCATION LENGTH. In this situation, section 4.3.3.6 in [SPC3] requires that the target SCSI layer "shall terminate transfers to the Data-In Buffer" when the number of bytes specified by the ALLOCATION LENGTH field have been transferred. Therefore, in response to a REPORT LUNS command, the SCSI layer at the target presents at most ALLOCATION LENGTH bytes of data (logical unit inventory) to iSCSI for transfer to the initiator. For a REPORT LUNS command, if the iSCSI EDTL is at least as large as the ALLOCATION LENGTH, the SCSI truncation ensures that the EDTL will accommodate all of the data to be transferred. If all of the logical unit inventory data presented to the iSCSI layer ¡ i.e. the data remaining after any SCSI truncation - is Chadalapaka Expires March, 2006 [Page 7] Internet-Draft iSCSI Guide 19 September 2005 transferred to the initiator by the iSCSI layer, an iSCSI Residual Overflow has not occurred and the iSCSI (O) bit MUST NOT be set in the SCSI Response or final SCSI Data-Out PDU. This is not a new requirement but is already required by the combination of [RFC 3720] with the specification of the REPORT LUNS command in [SPC3]. If the iSCSI EDTL is larger than the ALLOCATION LENGTH however in this scenario, note that the iSCSI Underflow MUST be signaled in the SCSI Response PDU. An iSCSI Underflow MUST also be signaled when the iSCSI EDTL is equal to ALLOCATION LENGTH but the logical unit inventory data presented to the iSCSI layer is smaller than ALLOCATION LENGTH. The LUN LIST LENGTH field in the logical unit inventory (first field in the inventory) is not affected by truncation of the inventory to fit in ALLOCATION LENGTH; this enables a SCSI initiator to determine that the received inventory is incomplete by noticing that the LUN LIST LENGTH in the inventory is larger than the ALLOCATION LENGTH that was sent in the REPORT LUNS CDB. A common initiator behavior in this situation is to re-issue the REPORT LUNS command with a larger ALLOCATION LENGTH. 3.2 R2T Ordering Section 10.8 in [RFC3720] says the following: The target may send several R2T PDUs. It, therefore, can have a number of pending data transfers. The number of outstanding R2T PDUs are limited by the value of the negotiated key MaxOutstandingR2T. Within a connection, outstanding R2Ts MUST be fulfilled by the initiator in the order in which they were received. The quoted [RFC3720] text was unclear on the scope of applicability ¡ either per task, or across all tasks on a connection ¡ and may be interpreted as either. This section is intended to clarify that the scope of applicability of the quoted text is a task. No R2T ordering relationship ¡ either in generation at the target or in fulfilling at the initiator ¡ across tasks is implied. I.e., outstanding R2Ts within a task MUST be fulfilled by the initiator in the order in which they were received on a connection. Chadalapaka Expires March, 2006 [Page 8] Internet-Draft iSCSI Guide 19 September 2005 4 Task Management 4.1 Requests Affecting Multiple Tasks This section updates the original text in section 10.6.2 of [RFC3720]. The clarified semantics are a superset of the semantics of the original text in it the new text covers all TMFs that can impact multiple tasks. 4.1.1 Scope of affected tasks ABORT TASK SET: All outstanding tasks for the I_T_L nexus identified by the LUN field in the ABORT TASK SET TMF Request PDU. CLEAR TASK SET: All outstanding tasks in the task set for the LU identified by the LUN field in the CLEAR TASK SET TMF Request PDU. See [SPC3] for the definition of a "task set". LOGICAL UNIT RESET: All outstanding tasks from all initiators for the LU identified by the LUN field in the LOGICAL UNIT RESET Request PDU. TARGET WARM RESET/TARGET COLD RESET: All outstanding tasks from all initiators across all LUs that the TMF-issuing session has access to on the SCSI target device hosting the iSCSI session. Usage example: an "ABORT TASK SET TMF Request PDU" in the preceding text is an iSCSI TMF Request PDU with the "Function" field set to "ABORT TASK SET" as defined in [RFC3720]. Similar usage is employed for other scope descriptions. 4.1.2 Updated semantics The execution of ABORT TASK SET, CLEAR TASK SET, LOGICAL UNIT RESET, TARGET WARM RESET, and TARGET COLD RESET TMF Requests consists of the following sequence of actions in the specified order on each of the entities. The initiator: a) Issues ABORT TASK SET/CLEAR TASK SET/LOGICAL UNIT RESET/TARGET WARM RESET/TARGET COLD RESET request. b) Continues to respond to each TTT received for the affected tasks. Chadalapaka Expires March, 2006 [Page 9] Internet-Draft iSCSI Guide 19 September 2005 c) Receives any responses that the target may provide for some tasks among the affected tasks (may process them as usual because they are guaranteed to have chronologically originated before the TMF response). d) Receives the task management response concluding all the tasks in the set of affected tasks. The Target MUST do the following: a) Receives the ABORT TASK SET/CLEAR TASK SET/LOGICAL UNIT RESET/TARGET WARM RESET/TARGET COLD RESET request. b) Waits for all currently valid target transfer tags of the affected tasks to be responded. c) Based on the CmdSN ordering, waits (concurrent with the wait in step (b)) for all commands of the affected tasks to be received. In the case of target-scoped requests (i.e. TARGET WARM RESET and TARGET COLD RESET), all the commands that are not received, as at the end of step (b), in the command stream however can be considered to have been received with no command waiting period - i.e. the entire CmdSN space upto the CmdSN of the task management function can be "plugged" (refer section 6.9 on how aborting a specific task can implicitly plug the CmdSN of the task being aborted) at the end of step (b). d) Propagates the TMF request to and receives the response from the target SCSI layer. e) Takes note of last-sent StatSN on each of the connections in the iSCSI session(s) (one or more) sharing the affected tasks, and waits for acknowledgement of each StatSN (may solicit for acknowledgement by way of a NOP-In). If any new task responses are meanwhile received from the SCSI layer while waiting for StatSN acknowledgement(s), those response PDUs ¡ the first SCSI Response PDU of which is presumably carrying the UA notification on all Third-party sessions - MUST be held and queued at the iSCSI layer. If some tasks originate from non-iSCSI I_T_L nexuses then the means by which the target insures that all affected tasks have returned their status to the initiator are defined by the specific non-iSCSI transport protocol(s). f) Sends the task set management response to the issuing initiator. All task response PDUs held back at the iSCSI layer in step e are simultaneously eligible for being Chadalapaka Expires March, 2006 [Page 10] Internet-Draft iSCSI Guide 19 September 2005 placed on the wire at this point. 4.1.3 Rationale behind the new semantics There are fundamentally three basic objectives behind the semantics specified in section 4.1.2. 1. Maintaining an ordered command flow I_T nexus abstraction to the target SCSI layer even with multi-connection sessions. o Target iSCSI processing of a TMF request must maintain the single flow illusion - steps c & d of the target behavior correspond to this objective. 2. Maintaining a single ordered response flow I_T nexus abstraction to the initiator SCSI layer even with multi- connection sessions when one response (i.e. TMF response) could imply the status of other unfinished tasks from the initiator's perspective. o Target must ensure that the initiator does not see "old" task responses (that were placed on the wire chronologically earlier than the TMF response) after seeing the TMF response - step e of the target behavior corresponds to this objective. o Whenever the result of a TMF action is visible across multiple I_T_L nexuses, [SAM2] requires the SCSI device server to trigger a UA on each of the other I_T_L nexuses. Once an initiator is notified of such an UA, the application client on the receiving initiator is required to clear its task state (clause 5.5 in [SAM2]) for the affected tasks. It would thus be inappropriate to deliver a SCSI Response for a task after the task state is cleared on the initiator, i.e. after the UA is notified. The UA notification contained in the first SCSI Response PDU on each affected Third-party I_T_L nexus after the TMF action thus MUST NOT pass the affected task responses on any of the iSCSI sessions accessing the LU ¡ steps e & f of the target behavior correspond to this objective. 3. Draining all active TTTs corresponding to affected tasks before the TMF is acted on. Chadalapaka Expires March, 2006 [Page 11] Internet-Draft iSCSI Guide 19 September 2005 o Targets are better off if the TTTs are deterministically retired before the affected tasks are terminated because that eliminates the possibility of large-sized Data-out PDUs with stale TTTs arriving after the tasks are terminated. Step b of the target behavior corresponds to this objective. The only other notable thing in step c of the target behavior is the "plugging" part - it is an optimization that says if all tasks on the I_T nexus will be aborted anyway (as with a target reset), there is no need to wait, the target can simply plug all missing CmdSN slots and move on with TMF processing. The first objective (maintaining a single ordered command flow) is still met with this optimization because target SCSI layer only sees ordered commands. Chadalapaka Expires March, 2006 [Page 12] Internet-Draft iSCSI Guide 19 September 2005 5 Discovery semantics 5.1 Error Recovery for Discovery Sessions The negotiation of the key ErrorRecoveryLevel is not required for Discovery sessions ¡ i.e. for sessions that negotiated "SessionType=Discovery" ¡ because the default value of 0 is necessary and sufficient for Discovery sessions. It is however possible that some legacy iSCSI implementations might attempt to negotiate the ErrorRecoveryLevel key on Discovery sessions. When such a negotiation attempt is made by the remote side, a compliant iSCSI implementation MUST propose a value of 0 (zero) in response. The operational ErrorRecoveryLevel for Discovery sessions thus MUST be 0. This naturally follows from the functionality constraints [RFC3720] imposes on Discovery sessions. 5.2 Reinstatement Semantics of Discovery Sessions Discovery sessions are intended to be relatively short-lived. Initiators are not expected to establish multiple Discovery sessions to the same iSCSI Network Portal (see [RFC3720]). An initiator may use the same iSCSI Initiator Name and ISID when establishing different unique sessions with different targets and/or different portal groups. This behavior is discussed in Section 9.1.1 of [RFC3720] and is, in fact, encouraged as conservative reuse of ISIDs. ISID RULE in [RFC3720] states that there must not be more than one session with a matching 4-tuple: . While the spirit of the ISID RULE applies to Discovery sessions the same as it does for Normal sessions, note that some Discovery sessions differ from the Normal sessions in two important aspects: Because [RFC3720] allows a Discovery session to be established without specifying a TargetName key in the Login Request PDU (let us call such a session an "Unnamed" Discovery session), there is no Target Node context to enforce the ISID RULE. Portal Groups are defined only in the context of a Target Node. When the TargetName key is NULL-valued (i.e. not specified), the TargetPortalGroupTag thus cannot be ascertained to enforce the ISID RULE. Chadalapaka Expires March, 2006 [Page 13] Internet-Draft iSCSI Guide 19 September 2005 The following sections describe the two scenarios ¡ Named Discovery sessions and Unnamed Discovery sessions ¡ separately. 5.2.1 Unnamed Discovery Sessions For Unnamed Discovery sessions, neither the TargetName nor the TargetPortalGroupTag is available to the targets in order to enforce the ISID RULE. So the following rule applies. UNNAMED ISID RULE: Targets MUST enforce the uniqueness of the following 4-tuple for Unnamed Discovery sessions: . The following semantics are implied by this uniqueness requirement. Targets SHOULD allow concurrent establishment of one Discovery session with each of its Network Portals by the same initiator port with a given iSCSI Node Name and an ISID. Each of the concurrent Discovery sessions, if established by the same initiator port to other Network Portals, MUST be treated as independent sessions ¡ i.e. one session MUST NOT reinstate the other. A new Unnamed Discovery session that has a matching to an existing discovery session MUST reinstate the existing Unnamed Discovery session. Note thus that only an Unnamed Discovery session may reinstate an Unnamed Discovery session. 5.2.2 Named Discovery Sessions For a Named Discovery session, the TargetName key is specified by the initiator and thus the target can unambiguously ascertain the TargetPortalGroupTag as well. Since all the four elements of the 4-tuple are known, the ISID RULE MUST be enforced by targets with no changes from [RFC3720] semantics. A new session with a matching thus will reinstate an existing session. Note in this case that any new iSCSI session (Discovery or Normal) with the matching 4-tuple may reinstate an existing Named Discovery iSCSI session. Chadalapaka Expires March, 2006 [Page 14] Internet-Draft iSCSI Guide 19 September 2005 5.3 TPGT Values SAM-2 and SAM-3 specifications incorrectly note in their informative text that TPGT value should be non-zero, although [RFC3720} allows the value of zero for TPGT. This section is to clarify that zero value is expressly allowed as a legal value for TPGT. A future revision of SAM will be corrected to address this discrepancy. Chadalapaka Expires March, 2006 [Page 15] Internet-Draft iSCSI Guide 19 September 2005 6 iSCSI Error Handling and Recovery 6.1 ITT Section 10.19 in [RFC3720] mentions this in passing but noted here again for making it obvious since the semantics apply to the initiators in general. An ITT value of 0xffffffff is reserved and MUST NOT be assigned for a task by the initiator. The only instance it may be seen on the wire is in a target- initiated NOP-In PDU (and in the initiator response to that PDU if necessary). 6.2 Format Errors Section 6.6 of [RFC3720] discusses format error handling. This section elaborates on the "inconsistent" PDU field contents noted in [RFC3720]. All initiator-detected PDU construction errors MUST be considered as format errors. Some examples of such errors are: - NOP-In with a valid TTT but an invalid LUN - NOP-In with a valid ITT (i.e. a NOP-In response) and also a valid TTT - SCSI Response PDU with Status=CHECK CONDITION, but DataSegmentLength = 0 6.3 Digest Errors Section 6.7 of [RFC3720] discusses digest error handling. It states that "No further action is necessary for initiators if the discarded PDU is an unsolicited PDU (e.g., Async, Reject)" on detecting a payload digest error. This is incorrect. An Asynchronous Message PDU or a Reject PDU carries the next StatSN value on an iSCSI connection, advancing the StatSN. When an initiator discards one of these PDUs due to a payload digest error, the entire PDU including the header MUST be discarded. Consequently, the initiator MUST treat the exception like a loss of any other solicited response PDU ¡ i.e. it MUST use one of the following options noted in [RFC3720]: Chadalapaka Expires March, 2006 [Page 16] Internet-Draft iSCSI Guide 19 September 2005 a) Request PDU retransmission with a status SNACK. b) Logout the connection for recovery and continue the tasks on a different connection instance. c) Logout to close the connection (abort all the commands associated with the connection). Chadalapaka Expires March, 2006 [Page 17] Internet-Draft iSCSI Guide 19 September 2005 7 Security Considerations This document does not introduce any new security considerations other than those already noted in [RFC3720]. Consequently, all the iSCSI-related security text in [RFC3723] is also directly applicable to this document. Chadalapaka Expires March, 2006 [Page 18] Internet-Draft iSCSI Guide 19 September 2005 8 IANA Considerations This draft does not have any specific IANA considerations other than those already noted in [RFC3720]. Chadalapaka Expires March, 2006 [Page 19] Internet-Draft iSCSI Guide 19 September 2005 9 References and Bibliography 9.1 Normative References [RFC3720] Satran, J., Meth, K., Sapuntzakis, C., Chadalapaka, M., and E. Zeidner, "Internet Small Computer Systems Interface (iSCSI)", RFC 3720, April 2004. [RFC3722] Bakke, M., "String Profile for Internet Small Computer Systems Interface (iSCSI) Names", RFC 3722, April 2004. [RFC3723] Aboba, B., Tseng, J., Walker, J., Rangan, V., and F. Travostino, "Securing Block Storage Protocols over IP", RFC 3723, April 2004. [SPC3] T10/1416-D, SCSI Primary Commands-3. 9.2 Informative References [RFC3721] Bakke, M., Hafner, J., Hufferd, J., Voruganti, K., and M. Krueger, "Internet Small Computer Systems Interface (iSCSI) Naming and Discovery", RFC 3721, April 2004. [iSER] Ko, M., Chadalapaka, M., Elzur, U., Shah, H., Thaler, P., J. Hufferd, "iSCSI Extensions for RDMA", IETF Internet Draft draft-ietf-ips-iser-04.txt (work in progress), June 2005. [RFC2119] Bradner, S. "Key Words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [SAM2] ANSI X3.366-2003, SCSI Architecture Model-2 (SAM-2). Chadalapaka Expires March, 2006 [Page 20] Internet-Draft iSCSI Guide 19 September 2005 10 Editor's Address Mallikarjun Chadalapaka Hewlett-Packard Company 8000 Foothills Blvd. Roseville, CA 95747-5668, USA Phone: +1-916-785-5621 E-mail: cbm@rose.hp.com Chadalapaka Expires March, 2006 [Page 21] Internet-Draft iSCSI Guide 19 September 2005 11 Acknowledgements The IP Storage (ips) Working Group in the Transport Area of IETF has been responsible for defining the iSCSI protocol (apart from a host of other relevant IP Storage protocols). The editor acknowledges the contributions of the entire working group. The following individuals directly contributed to identifying [RFC3720] issues and/or suggesting resolutions to the issues clarified in this document: David Black (REPORT LUNS/overflow semantics), Gwendal Grignou (TMF scope), Mike Ko (digest error handling for Asynchronous Message), Dmitry Fomichev (reserved ITT), Bill Studenmund (residual handling, discovery semantics), Ken Sandars (discovery semantics), Bob Russell (discovery semantics), Julian Satran (discovery semantics), Rob Elliott (T10 liaison, R2T ordering), Joseph Pittman(TMF scope). This document benefited from all these contributions. Chadalapaka Expires March, 2006 [Page 22] Internet-Draft iSCSI Guide 19 September 2005 12 Full Copyright Statement Copyright (C) The Internet Society (2005). This document is subject to the rights, licenses and restrictions contained in BCP 78, and except as set forth therein, the authors retain all their rights. This document and the information contained herein are provided on an "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Chadalapaka Expires March, 2006 [Page 23] Internet-Draft iSCSI Guide 19 September 2005 13 Intellectual Property Statement The IETF takes no position regarding the validity or scope of any Intellectual Property Rights or other rights that might be claimed to pertain to the implementation or use of the technology described in this document or the extent to which any license under such rights might or might not be available; nor does it represent that it has made any independent effort to identify any such rights. Information on the procedures with respect to rights in RFC documents can be found in BCP 78 and BCP 79. Copies of IPR disclosures made to the IETF Secretariat and any assurances of licenses to be made available, or the result of an attempt made to obtain a general license or permission for the use of such proprietary rights by implementers or users of this specification can be obtained from the IETF on-line IPR repository at http://www.ietf.org/ipr. The IETF invites any interested party to bring to its attention any copyrights, patents or patent applications, or other proprietary rights that may cover technology that may be required to implement this standard. Please address the information to the IETF at ietf-ipr@ietf.org. Chadalapaka Expires March, 2006 [Page 24]