From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc7145.txt | 5099 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 5099 insertions(+) create mode 100644 doc/rfc/rfc7145.txt (limited to 'doc/rfc/rfc7145.txt') diff --git a/doc/rfc/rfc7145.txt b/doc/rfc/rfc7145.txt new file mode 100644 index 0000000..aa30c33 --- /dev/null +++ b/doc/rfc/rfc7145.txt @@ -0,0 +1,5099 @@ + + + + + + +Internet Engineering Task Force (IETF) M. Ko +Request for Comments: 7145 +Obsoletes: 5046 A. Nezhinsky +Category: Standards Track Mellanox +ISSN: 2070-1721 April 2014 + + + Internet Small Computer System Interface (iSCSI) Extensions + for the Remote Direct Memory Access (RDMA) Specification + +Abstract + + Internet Small Computer System Interface (iSCSI) Extensions for + Remote Direct Memory Access (RDMA) provides the RDMA data transfer + capability to iSCSI by layering iSCSI on top of an RDMA-Capable + Protocol. An RDMA-Capable Protocol provides RDMA Read and Write + services, which enable data to be transferred directly into SCSI I/O + Buffers without intermediate data copies. This document describes + the extensions to the iSCSI protocol to support RDMA services as + provided by an RDMA-Capable Protocol. + + This document obsoletes RFC 5046. + +Status of This Memo + + This is an Internet Standards Track document. + + This document is a product of the Internet Engineering Task Force + (IETF). It represents the consensus of the IETF community. It has + received public review and has been approved for publication by the + Internet Engineering Steering Group (IESG). Further information on + Internet Standards is available in Section 2 of RFC 5741. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + http://www.rfc-editor.org/info/rfc7145. + + + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 1] + +RFC 7145 iSER Specification April 2014 + + +Copyright Notice + + Copyright (c) 2014 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents + (http://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + to this document. Code Components extracted from this document must + include Simplified BSD License text as described in Section 4.e of + the Trust Legal Provisions and are provided without warranty as + described in the Simplified BSD License. + +Table of Contents + + 1. Introduction ....................................................5 + 1.1. Motivation .................................................5 + 1.2. iSCSI/iSER Layering ........................................6 + 1.3. Architectural Goals ........................................7 + 1.4. Protocol Overview ..........................................7 + 1.5. RDMA Services and iSER .....................................9 + 1.5.1. STag ................................................9 + 1.5.2. Send ...............................................10 + 1.5.3. RDMA Write .........................................11 + 1.5.4. RDMA Read ..........................................11 + 1.6. SCSI Read Overview ........................................11 + 1.7. SCSI Write Overview .......................................12 + 2. Definitions and Acronyms .......................................12 + 2.1. Definitions ...............................................12 + 2.2. Acronyms ..................................................18 + 2.3. Conventions ...............................................20 + 3. Upper-Layer Interface Requirements .............................20 + 3.1. Operational Primitives offered by iSER ....................21 + 3.1.1. Send_Control .......................................21 + 3.1.2. Put_Data ...........................................21 + 3.1.3. Get_Data ...........................................22 + 3.1.4. Allocate_Connection_Resources ......................22 + 3.1.5. Deallocate_Connection_Resources ....................23 + 3.1.6. Enable_Datamover ...................................23 + 3.1.7. Connection_Terminate ...............................23 + 3.1.8. Notice_Key_Values ..................................24 + 3.1.9. Deallocate_Task_Resources ..........................24 + 3.2. Operational Primitives Used by iSER .......................24 + 3.2.1. Control_Notify .....................................25 + 3.2.2. Data_Completion_Notify .............................25 + 3.2.3. Data_ACK_Notify ....................................25 + + + +Ko & Nezhinsky Standards Track [Page 2] + +RFC 7145 iSER Specification April 2014 + + + 3.2.4. Connection_Terminate_Notify ........................26 + 3.3. iSCSI Protocol Usage Requirements .........................26 + 4. Lower-Layer Interface Requirements .............................27 + 4.1. Interactions with the RCaP Layer ..........................27 + 4.2. Interactions with the Transport Layer .....................28 + 5. Connection Setup and Termination ...............................28 + 5.1. iSCSI/iSER Connection Setup ...............................28 + 5.1.1. Initiator Behavior .................................30 + 5.1.2. Target Behavior ....................................31 + 5.1.3. iSER Hello Exchange ................................33 + 5.2. iSCSI/iSER Connection Termination .........................36 + 5.2.1. Normal Connection Termination at the Initiator .....36 + 5.2.2. Normal Connection Termination at the Target ........36 + 5.2.3. Termination without Logout Request/Response PDUs ...37 + 6. Login/Text Operational Keys ....................................38 + 6.1. HeaderDigest and DataDigest ...............................38 + 6.2. MaxRecvDataSegmentLength ..................................38 + 6.3. RDMAExtensions ............................................39 + 6.4. TargetRecvDataSegmentLength ...............................40 + 6.5. InitiatorRecvDataSegmentLength ............................41 + 6.6. OFMarker and IFMarker .....................................41 + 6.7. MaxOutstandingUnexpectedPDUs ..............................41 + 6.8. MaxAHSLength ..............................................42 + 6.9. TaggedBufferForSolicitedDataOnly ..........................43 + 6.10. iSERHelloRequired ........................................43 + 7. iSCSI PDU Considerations .......................................44 + 7.1. iSCSI Data-Type PDU .......................................44 + 7.2. iSCSI Control-Type PDU ....................................45 + 7.3. iSCSI PDUs ................................................45 + 7.3.1. SCSI Command .......................................45 + 7.3.2. SCSI Response ......................................47 + 7.3.3. Task Management Function Request/Response ..........49 + 7.3.4. SCSI Data-out ......................................50 + 7.3.5. SCSI Data-in .......................................51 + 7.3.6. Ready To Transfer (R2T) ............................53 + 7.3.7. Asynchronous Message ...............................55 + 7.3.8. Text Request and Text Response .....................55 + 7.3.9. Login Request and Login Response ...................55 + 7.3.10. Logout Request and Logout Response ................56 + 7.3.11. SNACK Request .....................................56 + 7.3.12. Reject ............................................56 + 7.3.13. NOP-Out and NOP-In ................................57 + 8. Flow Control and STag Management ...............................57 + 8.1. Flow Control for RDMA Send Messages .......................57 + 8.1.1. Flow Control for Control-Type PDUs from the + Initiator ..........................................58 + 8.1.2. Flow Control for Control-Type PDUs from the + Target .............................................60 + + + +Ko & Nezhinsky Standards Track [Page 3] + +RFC 7145 iSER Specification April 2014 + + + 8.2. Flow Control for RDMA Read Resources ......................61 + 8.3. STag Management ...........................................62 + 8.3.1. Allocation of STags ................................62 + 8.3.2. Invalidation of STags ..............................62 + 9. iSER Control and Data Transfer .................................64 + 9.1. iSER Header Format ........................................64 + 9.2. iSER Header Format for iSCSI Control-Type PDU .............65 + 9.3. iSER Header Format for iSER Hello Message .................67 + 9.4. iSER Header Format for iSER HelloReply Message ............68 + 9.5. SCSI Data Transfer Operations .............................69 + 9.5.1. SCSI Write Operation ...............................69 + 9.5.2. SCSI Read Operation ................................70 + 9.5.3. Bidirectional Operation ............................70 + 10. iSER Error Handling and Recovery ..............................71 + 10.1. Error Handling ...........................................71 + 10.1.1. Errors in the Transport Layer .....................71 + 10.1.2. Errors in the RCaP Layer ..........................72 + 10.1.3. Errors in the iSER Layer ..........................73 + 10.1.4. Errors in the iSCSI Layer .........................75 + 10.2. Error Recovery ...........................................76 + 10.2.1. PDU Recovery ......................................77 + 10.2.2. Connection Recovery ...............................77 + 11. Security Considerations .......................................78 + 12. IANA Considerations ...........................................79 + 13. References ....................................................79 + 13.1. Normative References .....................................79 + 13.2. Informative References ...................................80 + Appendix A. Summary of Changes from RFC 5046 ......................81 + Appendix B. Message Format for iSER ...............................83 + B.1. iWARP Message Format for iSER Hello Message ..................83 + B.2. iWARP Message Format for iSER HelloReply Message .............84 + B.3. iSER Header Format for SCSI Read Command PDU .................85 + B.4. iSER Header Format for SCSI Write Command PDU ................86 + B.5. iSER Header Format for SCSI Response PDU .....................87 + Appendix C. Architectural discussion of iSER over InfiniBand ......88 + C.1. Host Side of iSCSI and iSER Connections in InfiniBand ........88 + C.2. Storage Side of iSCSI and iSER Mixed Network Environment .....89 + C.3. Discovery Processes for an InfiniBand Host ...................89 + C.4. IBTA Connection Specifications ...............................90 + Appendix D. Acknowledgments .......................................90 + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 4] + +RFC 7145 iSER Specification April 2014 + + +Table of Figures + + Figure 1. Example of iSCSI/iSER Layering in Full Feature Phase .....6 + Figure 2. iSER Header Format ......................................64 + Figure 3. iSER Header Format for iSCSI Control-Type PDU ...........65 + Figure 4. iSER Header Format for iSER Hello Message ...............67 + Figure 5. iSER Header Format for iSER HelloReply Message ..........68 + Figure 6. SendSE Message Containing an iSER Hello Message .........83 + Figure 7. SendSE Message Containing an iSER HelloReply Message ....84 + Figure 8. iSER Header Format for SCSI Read Command PDU ............85 + Figure 9. iSER Header Format for SCSI Write Command PDU ...........86 + Figure 10. iSER Header Format for SCSI Response PDU ...............87 + Figure 11. iSCSI and iSER on IB ...................................88 + Figure 12. Storage Controller with TCP, iWARP, and IB Connections .89 + +1. Introduction + +1.1. Motivation + + The iSCSI protocol ([iSCSI]) is a mapping of the SCSI Architecture + Model (see [SAM5] and [iSCSI-SAM]) over the TCP protocol. SCSI + commands are carried by iSCSI requests, and SCSI responses and status + are carried by iSCSI responses. Other iSCSI protocol exchanges and + SCSI Data are also transported in iSCSI PDUs. + + Out-of-order TCP segments in the Traditional iSCSI model have to be + stored and reassembled before the iSCSI protocol layer within an end + node can place the data in the iSCSI buffers. This reassembly is + required because not every TCP segment is likely to contain an iSCSI + header to enable its placement and TCP itself does not have a built- + in mechanism for signaling ULP (Upper Level Protocol) message + boundaries to aid placement of out-of-order segments. This TCP + reassembly at high network speeds is quite counterproductive for the + following reasons: wasted memory bandwidth in data copying, need for + reassembly memory, wasted CPU cycles in data copying, and the general + store-and-forward latency from an application perspective. + + The generic term RDMA-Capable Protocol (RCaP) is used to refer to + protocol stacks that provide the Remote Direct Memory Access (RDMA) + functionality, such as iWARP and InfiniBand. + + With the availability of RDMA-Capable Controllers within a host + system, it is appropriate for iSCSI to be able to exploit the direct + data placement function of the RDMA-Capable Controller like other + applications. + + + + + + +Ko & Nezhinsky Standards Track [Page 5] + +RFC 7145 iSER Specification April 2014 + + + iSCSI Extensions for RDMA (iSER) is designed precisely to take + advantage of generic RDMA technologies -- iSER's goal is to permit + iSCSI to employ direct data placement and RDMA capabilities using a + generic RDMA-Capable Controller. In summary, the iSCSI/iSER protocol + stack is designed to enable scaling to high speeds by relying on a + generic data placement process and RDMA technologies and products + that enable direct data placement of both in-order and out-of-order + data. + + This document describes iSER as a protocol extension to iSCSI, both + for convenience of description and also because it is true in a very + strict protocol sense. However, it is to be noted that iSER is in + reality extending the connectivity of the iSCSI protocol defined in + [iSCSI], and the name "iSER" reflects this reality. + + When the iSCSI protocol as defined in [iSCSI] (i.e., without the iSER + enhancements) is intended in the rest of the document, the term + "Traditional iSCSI" is used to make the intention clear. + + This document obsoletes RFC 5046. See Appendix A for the list of + changes from RFC 5046. + +1.2. iSCSI/iSER Layering + + iSCSI Extensions for RDMA (iSER) is layered between the iSCSI layer + and the RCaP layer. + + +--------------------------------------------------------+ + | SCSI | + +--------------------------------------------------------+ + | iSCSI | + DI -> +--------------------------------------------------------+ + | iSER | + +-------+--------------------------+---------------------+ + | RDMAP | | | + +-------+ InfiniBand | | + | DDP | Reliable | Other | + +-------+ Connected | RDMA | + | MPA | Transport | Capable | + +-------+ Service | Protocol | + | TCP | | | + +-------+--------------------------+---------------------+ + | IP | InfiniBand Network Layer | Other Network Layer | + +-------+--------------------------+---------------------+ + + Figure 1: Example of iSCSI/iSER Layering in Full Feature Phase + + + + + +Ko & Nezhinsky Standards Track [Page 6] + +RFC 7145 iSER Specification April 2014 + + + Figure 1 shows an example of the relationship between SCSI, iSCSI, + iSER, and the different RCaP layers. For TCP, the RCaP is iWARP. + For InfiniBand, the RCaP is the Reliable Connected Transport Service. + Note that the iSCSI layer as described here supports the RDMA + Extensions as used in iSER. + +1.3. Architectural Goals + + This section summarizes the architectural goals that guided the + design of iSER. + + 1. Provide an RDMA data transfer model for iSCSI that enables direct + in-order or out-of-order data placement of SCSI data into pre- + allocated SCSI buffers while maintaining in-order data delivery. + + 2. Do not require any major changes to the SCSI Architecture Model + [SAM5] and SCSI command set standards. + + 3. Utilize the existing iSCSI infrastructure (sometimes referred to + as "iSCSI ecosystem") including but not limited to MIB, + bootstrapping, negotiation, naming and discovery, and security. + + 4. Enable a session to operate in the Traditional iSCSI data + transfer mode if iSER is not supported by either the initiator or + the target. (Do not require iSCSI Full Feature Phase + interoperability between an end node operating in Traditional + iSCSI mode and an end node operating in iSER-assisted mode.) + + 5. Allow initiator and target implementations to utilize generic + RDMA-Capable Controllers such as RNICs or to implement iSCSI and + iSER in software. (Do not require iSCSI- or iSER-specific + assists in the RCaP implementation or RDMA-Capable Controller.) + + 6. Implement a lightweight Datamover protocol for iSCSI with minimal + state maintenance. + +1.4. Protocol Overview + + Consistent with the architectural goals stated in Section 1.3, the + iSER protocol does not require changes in the iSCSI ecosystem or any + related SCSI specifications. The iSER protocol defines the mapping + of iSCSI PDUs to RCaP Messages in such a way that it is entirely + feasible to realize iSCSI/iSER implementations that are based on + generic RDMA-Capable Controllers. The iSER protocol layer requires + minimal state maintenance to assist a connection during the iSCSI + Full Feature Phase, besides being oblivious to the notion of an iSCSI + session. The crucial protocol aspects of iSER may be summarized as + follows: + + + +Ko & Nezhinsky Standards Track [Page 7] + +RFC 7145 iSER Specification April 2014 + + + 1. iSER-assisted mode is negotiated during the iSCSI login in the + leading connection for each session, and an entire iSCSI session + can only operate in one mode (i.e., a connection in a session + cannot operate in iSER-assisted mode if a different connection of + the same session is already in Full Feature Phase in the + Traditional iSCSI mode). + + 2. Once in iSER-assisted mode, all iSCSI interactions on that + connection use RCaP Messages. + + 3. A Send Message is used for carrying an iSCSI control-type PDU + preceded by an iSER header. See Section 7.2 for more details on + iSCSI control-type PDUs. + + 4. RDMA Write, RDMA Read Request, and RDMA Read Response Messages + are used for carrying control and all data information associated + with the iSCSI data-type PDUs (i.e., SCSI Data-In PDUs and R2T + PDUs). iSER does not use SCSI Data-Out PDUs for solicited data, + and SCSI Data-Out PDUs for unsolicited data are not treated as + iSCSI data-type PDUs by iSER because RDMA is not used. See + Section 7.1 for more details on iSCSI data-type PDUs. + + 5. The target drives all data transfer (with the exception of iSCSI + unsolicited data) for SCSI writes and SCSI reads, by issuing RDMA + Read Requests and RDMA Writes, respectively. + + 6. RCaP is responsible for ensuring data integrity. (For example, + iWARP includes a CRC-enhanced framing layer called MPA on top of + TCP; and for InfiniBand, the CRCs are included in the Reliable + Connection mode). For this reason, iSCSI header and data digests + are negotiated to "None" for iSCSI/iSER sessions. + + 7. The iSCSI error recovery hierarchy defined in [iSCSI] is fully + supported by iSER. (However, see Section 7.3.11 on the handling + of SNACK Request PDUs.) + + 8. iSER requires no changes to iSCSI security and text mode + negotiation mechanisms. + + Note that Traditional iSCSI implementations may have to be adapted to + employ iSER. It is expected that the adaptation when required is + likely to be centered around the upper-layer interface requirements + of iSER (Section 3). + + + + + + + + +Ko & Nezhinsky Standards Track [Page 8] + +RFC 7145 iSER Specification April 2014 + + +1.5. RDMA Services and iSER + + iSER is designed to work with software and/or hardware protocol + stacks providing the protocol services defined in RCaP documents such + as [RDMAP], [IB], etc. The following subsections describe the key + protocol elements of RCaP services on which iSER relies. + +1.5.1. STag + + An STag is the identifier of an I/O Buffer unique to an RDMA-Capable + Controller that the iSER layer Advertises to the remote iSCSI/iSER + node in order to complete a SCSI I/O. + + In iSER, Advertisement is the act of informing the target by the + initiator that an I/O Buffer is available at the initiator for RDMA + Read or RDMA Write access by the target. The initiator Advertises + the I/O Buffer by including the STag and the Base Offset in the + header of an iSER Message containing the SCSI Command PDU to the + target. The buffer length is as specified in the SCSI Command PDU. + + The iSER layer at the initiator Advertises the STag and the Base + Offset for the I/O Buffer of each SCSI I/O to the iSER layer at the + target in the iSER header of a Send Message containing the SCSI + Command PDU, unless the I/O can be completely satisfied by + unsolicited data alone. The SendSE Message should be used if + supported by the RCaP layer (e.g., iWARP). + + The iSER layer at the target provides the STag for the I/O Buffer + that is the Data Sink of an RDMA Read Operation (Section 1.5.4) to + the RCaP layer on the initiator node -- i.e., this is completely + transparent to the iSER layer at the initiator. + + The iSER layer at the initiator SHOULD invalidate the Advertised STag + upon a normal completion of the associated task. The Send with + Invalidate Message, if supported by the RCaP layer (e.g., iWARP), can + be used for automatic invalidation when it is used to carry the SCSI + Response PDU. There are two exceptions to this automatic + invalidation -- bidirectional commands and abnormal completion of a + command. The iSER layer at the initiator SHOULD explicitly + invalidate the STag in these two cases. That iSER layer MUST check + that STag invalidation has occurred whenever receipt of a Send with + Invalidate message is the expected means of causing an STag to be + invalidated, and it MUST perform the STag invalidation if the STag + has not already been invalidated (e.g., because a Send Message was + used instead of Send with Invalidate). + + + + + + +Ko & Nezhinsky Standards Track [Page 9] + +RFC 7145 iSER Specification April 2014 + + + If the Advertised STag is not invalidated as recommended in the + foregoing paragraph (e.g., in order to cache the STag for future + reuse), the I/O Buffer remains exposed to the network for access by + the RCaP. Such an I/O Buffer is capable of being read or written by + the RCaP outside the scope of the iSCSI operation for which it was + originally established; this fact has both robustness and security + considerations. The robustness considerations are that the system + containing the iSER initiator may react poorly to an unexpected + modification of its memory. For the security considerations, see + Section 11. + +1.5.2. Send + + Send is the RDMA Operation that is not addressed to an Advertised + buffer and uses Untagged buffers as the message is received. + + The iSER layer at the initiator uses the Send Operation to transmit + any iSCSI control-type PDU to the target. As an example, the + initiator uses Send Operations to transfer iSER Messages containing + SCSI Command PDUs to the iSER layer at the target. + + An iSER layer at the target uses the Send Operation to transmit any + iSCSI control-type PDU to the initiator. As an example, the target + uses Send Operations to transfer iSER Messages containing SCSI + Response PDUs to the iSER layer at the initiator. + + For interoperability, iSER implementations SHOULD accept and + correctly process SendSE and SendInvSE messages. However, SendSE and + SendInvSE messages are to be regarded as optimizations or + enhancements to the basic Send Message, and their support may vary by + RCaP protocol and specific implementation. In general, these + messages SHOULD NOT be used, unless the RCaP requires support for + them in all implementations. If these messages are used, the + implementation SHOULD be capable of reverting to use of Send in order + to work with a receiver that does not support these messages. + Attempted use of these messages with a peer that does not support + them may result in a fatal error that closes the RCaP connection. + For example, these messages SHOULD NOT be used with the InfiniBand + RCaP because InfiniBand does not require support for them in all + cases. New iSER implementations SHOULD use Send (and not SendSE or + SendInvSE) unless there are compelling reasons for doing otherwise. + Similarly, iSER implementations SHOULD NOT rely on events triggered + by SendSE and SendInvSE, as these messages may not be used. + + + + + + + + +Ko & Nezhinsky Standards Track [Page 10] + +RFC 7145 iSER Specification April 2014 + + +1.5.3. RDMA Write + + RDMA Write is the RDMA Operation that is used to place data into an + Advertised buffer at the Data Sink. The Data Source addresses the + Message using an STag and a Tagged Offset that are valid on the Data + Sink. + + The iSER layer at the target uses the RDMA Write Operation to + transfer the contents of a local I/O Buffer to an Advertised I/O + Buffer at the initiator. The iSER layer at the target uses the RDMA + Write to transfer the whole data or part of the data required to + complete a SCSI Read command. + + The iSER layer at the initiator does not employ RDMA Writes. + +1.5.4. RDMA Read + + RDMA Read is the RDMA Operation that is used to retrieve data from an + Advertised buffer at the Data Source. The sender of the RDMA Read + Request addresses the Message using an STag and a Tagged Offset that + are valid on the Data Source in addition to providing a valid local + STag and Tagged Offset that identify the Data Sink. + + The iSER layer at the target uses the RDMA Read Operation to transfer + the contents of an Advertised I/O Buffer at the initiator to a local + I/O Buffer at the target. The iSER layer at the target uses the RDMA + Read to fetch whole or part of the data required to complete a SCSI + Write Command. + + The iSER layer at the initiator does not employ RDMA Reads. + +1.6. SCSI Read Overview + + The iSER layer at the initiator receives the SCSI Command PDU from + the iSCSI layer. The iSER layer at the initiator generates an STag + for the I/O Buffer of the SCSI Read and Advertises the buffer by + including the STag and the Base Offset as part of the iSER header for + the PDU. The iSER Message is transferred to the target using a Send + Message. The SendSE Message should be used if supported by the RCaP + layer (e.g., iWARP). + + The iSER layer at the target uses one or more RDMA Writes to transfer + the data required to complete the SCSI Read. + + The iSER layer at the target uses a Send Message to transfer the SCSI + Response PDU back to the iSER layer at the initiator. The iSER layer + at the initiator invalidates the STag and notifies the iSCSI layer of + + + + +Ko & Nezhinsky Standards Track [Page 11] + +RFC 7145 iSER Specification April 2014 + + + the availability of the SCSI Response PDU. The Send with Invalidate + Message, if supported by the RCaP layer (e.g., iWARP), can be used + for automatic invalidation of the STag. + +1.7. SCSI Write Overview + + The iSER layer at the initiator receives the SCSI Command PDU from + the iSCSI layer. If solicited data transfer is involved, the iSER + layer at the initiator generates an STag for the I/O Buffer of the + SCSI Write and Advertises the buffer by including the STag and the + Base Offset as part of the iSER header for the PDU. The iSER Message + is transferred to the target using a Send Message. The SendSE + Message should be used if supported by the RCaP layer (e.g., iWARP). + + The iSER layer at the initiator may optionally send one or more non- + immediate unsolicited data PDUs to the target using Send Messages. + + If solicited data transfer is involved, the iSER layer at the target + uses one or more RDMA Reads to transfer the data required to complete + the SCSI Write. + + The iSER layer at the target uses a Send Message to transfer the SCSI + Response PDU back to the iSER layer at the initiator. The iSER layer + at the initiator invalidates the STag and notifies the iSCSI layer of + the availability of the SCSI Response PDU. The Send with Invalidate + Message, if supported by the RCaP layer (e.g., iWARP), can be used + for automatic invalidation of the STag. + +2. Definitions and Acronyms + +2.1. Definitions + + Advertisement (Advertised, Advertise, Advertisements, Advertises) -- + The act of informing a remote iSER (iSCSI Extensions for RDMA) + layer that a local node's buffer is available to it. A node makes + a buffer available for incoming RDMA Read Request Message or + incoming RDMA Write Message access by informing the remote iSER + layer of the Tagged Buffer identifiers (STag, Base Offset, and + buffer length). Note that this Advertisement of Tagged Buffer + information is the responsibility of the iSER layer on either end + and is not defined by the RDMA-Capable Protocol. A typical method + would be for the iSER layer to embed the Tagged Buffer's STag, + Base Offset, and buffer length in a message destined for the + remote iSER layer. + + Base Offset - A value when added to the Buffer Offset forms the + Tagged Offset. + + + + +Ko & Nezhinsky Standards Track [Page 12] + +RFC 7145 iSER Specification April 2014 + + + Completion (Completed, Complete, Completes) - Completion is defined + as the process by which the RDMA-Capable Protocol layer informs + the iSER layer that a particular RDMA Operation has performed all + functions specified for the RDMA Operation. + + Connection - A connection is a logical bidirectional communication + channel between the initiator and the target, e.g., a TCP + connection. Communication between the initiator and the target + occurs over one or more connections. The connections carry + control messages, SCSI commands, parameters, and data within iSCSI + Protocol Data Units (iSCSI PDUs). + + Connection Handle - An information element that identifies the + particular iSCSI connection and is unique for a given iSCSI layer + and the underlying iSER layer. Every invocation of an Operational + Primitive is qualified with the Connection Handle. + + Data Sink - The peer receiving a data payload. Note that the Data + Sink can be required to both send and receive RCaP (RDMA-Capable + Protocol) Messages to transfer a data payload. + + Data Source - The peer sending a data payload. Note that the Data + Source can be required to both send and receive RCaP Messages to + transfer a data payload. + + Datamover Interface (DI) - The interface between the iSCSI layer and + the Datamover Layer as described in [DA]. + + Datamover Layer - A layer that is directly below the iSCSI layer and + above the underlying transport layers. This layer exposes and + uses a set of transport-independent Operational Primitives for the + communication between the iSCSI layer and itself. The Datamover + layer, operating in conjunction with the transport layers, moves + the control and data information on the iSCSI connection. In this + specification, the iSER layer is the Datamover layer. + + Datamover Protocol - A Datamover protocol is the wire protocol that + is defined to realize the Datamover-layer functionality. In this + specification, the iSER protocol is the Datamover protocol. + + Inbound RDMA Read Queue Depth (IRD) - The maximum number of incoming + outstanding RDMA Read Requests that the RDMA-Capable Controller + can handle on a particular RCaP Stream at the Data Source. For + some RDMA-Capable Protocol layers, the term "IRD" may be known by + a different name. For example, for InfiniBand, the equivalent to + IRD is the Responder Resources. + + + + + +Ko & Nezhinsky Standards Track [Page 13] + +RFC 7145 iSER Specification April 2014 + + + 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. + + iSCSI - The iSCSI protocol as defined in [iSCSI] is a mapping of the + SCSI Architecture Model of SAM-5 over TCP. + + iSCSI control-type PDU - Any iSCSI PDU that is not an iSCSI data- + type PDU and also not a SCSI Data-Out PDU carrying solicited data + is defined as an iSCSI control-type PDU. Specifically, it is to + be noted that SCSI Data-Out PDUs for unsolicited data are defined + as iSCSI control-type PDUs. + + iSCSI data-type PDU - An iSCSI data-type PDU is defined as an iSCSI + PDU that causes data transfer via RDMA operations at the iSER + layer, transparent to the remote iSCSI layer, to take place + between the peer iSCSI nodes on a Full Feature Phase iSCSI + connection. An iSCSI data-type PDU, when requested for + transmission by the sender iSCSI layer, results in the associated + data transfer without the participation of the remote iSCSI layer, + i.e., the PDU itself is not delivered as-is to the remote iSCSI + layer. The following iSCSI PDUs constitute the set of iSCSI data- + type PDUs -- SCSI Data-In PDU and R2T PDU. + + iSCSI Layer - A layer in the protocol stack implementation within an + end node that implements the iSCSI protocol and interfaces with + the iSER layer via the Datamover Interface. + + iSCSI PDU (iSCSI Protocol Data Unit) - The iSCSI layer at the + initiator and the iSCSI layer at the target divide their + communications into messages. The term "iSCSI Protocol Data Unit" + (iSCSI PDU) is used for these messages. + + iSCSI/iSER Connection - An iSER-assisted iSCSI connection. An iSCSI + connection that is not iSER assisted always maps onto a TCP + connection at the transport level. But an iSER-assisted iSCSI + connection may not have an underlying TCP connection. For some + RCaP implementations (e.g., iWARP), an iSER-assisted iSCSI + connection has an underlying TCP connection. For other RCaP + implementations (e.g., InfiniBand), there is no underlying TCP + connection. (In the specific example of InfiniBand [IB], an iSER- + assisted iSCSI connection is directly mapped onto the InfiniBand + Reliable Connection-based (RC) channel.) + + iSCSI/iSER Session - An iSER-assisted iSCSI session. All connections + of an iSCSI/iSER session are iSCSI/iSER connections. + + iSER - iSCSI Extensions for RDMA, the protocol defined in this + document. + + + +Ko & Nezhinsky Standards Track [Page 14] + +RFC 7145 iSER Specification April 2014 + + + iSER-assisted - A term generally used to describe the operation of + iSCSI when the iSER functionality is also enabled below the iSCSI + layer for the specific iSCSI/iSER connection in question. + + iSER-IRD - This variable represents the maximum number of incoming + outstanding RDMA Read Requests that the iSER layer at the + initiator grants on a particular RCaP Stream. + + iSER-ORD - This variable represents the maximum number of outstanding + RDMA Read Requests that the iSER layer can initiate on a + particular RCaP Stream. This variable is maintained only by the + iSER layer at the target. + + iSER Layer - The layer that implements the iSCSI Extensions for RDMA + (iSER) protocol. + + iWARP - A suite of wire protocols comprising of [RDMAP], [DDP], and + [MPA] when layered above [TCP]. [RDMAP] and [DDP] may be layered + above SCTP or other transport protocols. + + Local Mapping - A task state record maintained by the iSER layer that + associates the Initiator Task Tag to the Local STag(s). The + specifics of the record structure are implementation dependent. + + Local Peer - The implementation of the RDMA-Capable Protocol on the + local end of the connection. Used to refer to the local entity + when describing protocol exchanges or other interactions between + two nodes. + + Node - A computing device attached to one or more links of a network. + A node in this context does not refer to a specific application or + protocol instantiation running on the computer. A node may + consist of one or more RDMA-Capable Controllers installed in a + host computer. + + Operational Primitive - An Operational Primitive is an abstract + functional interface procedure that requests another layer to + perform a specific action on the requestor's behalf or notifies + the other layer of some event. The Datamover Interface between an + iSCSI layer and a Datamover layer within an iSCSI end node uses a + set of Operational Primitives to define the functional interface + between the two layers. Note that not every invocation of an + Operational Primitive may elicit a response from the requested + layer. A full discussion of the Operational Primitive types and + request-response semantics available to iSCSI and iSER can be + found in [DA]. + + + + + +Ko & Nezhinsky Standards Track [Page 15] + +RFC 7145 iSER Specification April 2014 + + + Outbound RDMA Read Queue Depth (ORD) - The maximum number of + outstanding RDMA Read Requests that the RDMA-Capable Controller + can initiate on a particular RCaP Stream at the Data Sink. For + some RDMA-Capable Protocol layer, the term "ORD" may be known by a + different name. For example, for InfiniBand, the equivalent to + ORD is the Initiator Depth. + + Phase Collapse - Refers to the optimization in iSCSI where the SCSI + status is transferred along with the final SCSI Data-In PDU from a + target. See Section 4.2 in [iSCSI]. + + RCaP Message - One or more packets of the network layer that + constitute a single RDMA operation or a part of an RDMA Read + Operation of the RDMA-Capable Protocol. For iWARP, an RCaP + Message is known as an RDMAP Message. + + RCaP Stream - A single bidirectional association between the peer + RDMA-Capable Protocol layers on two nodes over a single transport- + level stream. For iWARP, an RCaP Stream is known as an RDMAP + Stream, and the association is created following a successful + Login Phase during which iSER support is negotiated. + + RDMA-Capable Protocol (RCaP) - The protocol or protocol suite that + provides a reliable RDMA transport functionality, e.g., iWARP, + InfiniBand, etc. + + RDMA-Capable Controller - A network I/O adapter or embedded + controller with RDMA functionality. For example, for iWARP, this + could be an RNIC, and for InfiniBand, this could be a HCA (Host + Channel Adapter) or TCA (Target Channel Adapter). + + RDMA-enabled Network Interface Controller (RNIC) - A network I/O + adapter or embedded controller with iWARP functionality. + + RDMA Operation - A sequence of RCaP Messages, including control + messages, to transfer data from a Data Source to a Data Sink. The + following RDMA Operations are defined -- RDMA Write Operation, + RDMA Read Operation, and Send Operation. + + RDMA Protocol (RDMAP) - A wire protocol that supports RDMA Operations + to transfer ULP data between a Local Peer and the Remote Peer as + described in [RDMAP]. + + RDMA Read Operation - An RDMA Operation used by the Data Sink to + transfer the contents of a Data Source buffer from the Remote Peer + to a Data Sink buffer at the Local Peer. An RDMA Read operation + consists of a single RDMA Read Request Message and a single RDMA + Read Response Message. + + + +Ko & Nezhinsky Standards Track [Page 16] + +RFC 7145 iSER Specification April 2014 + + + RDMA Read Request - An RCaP Message used by the Data Sink to request + the Data Source to transfer the contents of a buffer. The RDMA + Read Request Message describes both the Data Source and the Data + Sink buffers. + + RDMA Read Response - An RCaP Message used by the Data Source to + transfer the contents of a buffer to the Data Sink, in response to + an RDMA Read Request. The RDMA Read Response Message only + describes the Data Sink buffer. + + RDMA Write Operation - An RDMA Operation used by the Data Source to + transfer the contents of a Data Source buffer from the Local Peer + to a Data Sink buffer at the Remote Peer. The RDMA Write Message + only describes the Data Sink buffer. + + Remote Direct Memory Access (RDMA) - A method of accessing memory on + a remote system in which the local system specifies the remote + location of the data to be transferred. Employing an RDMA- + Capable Controller in the remote system allows the access to take + place without interrupting the processing of the CPU(s) on the + system. + + Remote Mapping - A task state record maintained by the iSER layer + that associates the Initiator Task Tag to the Advertised STag(s) + and the Base Offset(s). The specifics of the record structure are + implementation dependent. + + Remote Peer - The implementation of the RDMA-Capable Protocol on the + opposite end of the connection. Used to refer to the remote + entity when describing protocol exchanges or other interactions + between two nodes. + + SCSI Layer - This layer builds/receives SCSI CDBs (Command Descriptor + Blocks) and sends/receives them with the remaining command execute + [SAM5] parameters to/from the iSCSI layer. + + Send - An RDMA Operation that transfers the content of a buffer from + the Local Peer to an untagged buffer at the Remote Peer. + + SendInvSE Message - A Send with Solicited Event and Invalidate + Message. + + SendSE Message - A Send with Solicited Event Message. + + Sequence Number (SN) - DataSN for a SCSI Data-In PDU and R2TSN for an + R2T PDU. The semantics for both types of sequence numbers are as + defined in [iSCSI]. + + + + +Ko & Nezhinsky Standards Track [Page 17] + +RFC 7145 iSER Specification April 2014 + + + Session, iSCSI Session - The group of connections that link an + initiator SCSI port with a target SCSI port form an iSCSI session + (equivalent to a SCSI Initiator-Target (I-T) nexus). Connections + can be added to and removed from a session even while the I-T + nexus is intact. Across all connections within a session, an + initiator sees one and the same target. + + Steering Tag (STag) - An identifier of a Tagged Buffer on a node + (Local or Remote) as defined in [RDMAP] and [DDP]. For other + RDMA-Capable Protocols, the Steering Tag may be known by different + names but will be referred to herein as STags. For example, for + InfiniBand, a Remote STag is known as an R-Key, and a Local STag + is known as an L-Key, and both will be considered STags. + + Tagged Buffer - A buffer that is explicitly Advertised to the iSER + layer at the remote node through the exchange of an STag, Base + Offset, and length. + + Tagged Offset - The offset within a Tagged Buffer. + + Traditional iSCSI - Refers to the iSCSI protocol as defined in + [iSCSI] (i.e., without the iSER enhancements). + + Untagged Buffer - A buffer that is not explicitly Advertised to the + iSER layer at the remode node. + +2.2. Acronyms + + Acronym Definition + + -------------------------------------------------------------- + + AHS Additional Header Segment + + BHS Basic Header Segment + + CO Connection Only + + CRC Cyclic Redundancy Check + + DDP Direct Data Placement Protocol + + DI Datamover Interface + + HCA Host Channel Adapter + + IANA Internet Assigned Numbers Authority + + + + +Ko & Nezhinsky Standards Track [Page 18] + +RFC 7145 iSER Specification April 2014 + + + IB InfiniBand + + IETF Internet Engineering Task Force + + I/O Input - Output + + IO Initialize Only + + IP Internet Protocol + + IPoIB IP over InfiniBand + + IPsec Internet Protocol Security + + iSER iSCSI Extensions for RDMA + + ITT Initiator Task Tag + + LO Leading Only + + MPA Marker PDU Aligned Framing for TCP + + NOP No Operation + + NSG Next Stage (during the iSCSI Login Phase) + + PDU Protocol Data Unit + + R2T Ready To Transfer + + R2TSN Ready To Transfer Sequence Number + + RCaP RDMA-Capable Protocol + + RDMA Remote Direct Memory Access + + RDMAP Remote Direct Memory Access Protocol + + RFC Request For Comments + + RNIC RDMA-enabled Network Interface Controller + + SAM5 SCSI Architecture Model - 5 + + SCSI Small Computer System Interface + + + + + + +Ko & Nezhinsky Standards Track [Page 19] + +RFC 7145 iSER Specification April 2014 + + + SNACK Selective Negative Acknowledgment - also + + Sequence Number Acknowledgement for data + + STag Steering Tag + + SW Session Wide + + TCA Target Channel Adapter + + TCP Transmission Control Protocol + + TMF Task Management Function + + TTT Target Transfer Tag + + ULP Upper Level Protocol + +2.3. Conventions + + The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", + "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this + document are to be interpreted as described in [RFC2119]. + +3. Upper-Layer Interface Requirements + + This section discusses the upper-layer interface requirements in the + form of an abstract model of the required interactions between the + iSCSI layer and the iSER layer. The abstract model used here is + derived from the architectural model described in [DA]. [DA] also + provides a functional overview of the interactions between the iSCSI + layer and the Datamover layer as intended by the Datamover + Architecture. + + The interface requirements are specified by Operational Primitives. + An Operational Primitive is an abstract functional interface + procedure between the iSCSI layer and the iSER layer that requests + one layer to perform a specific action on behalf of the other layer + or notifies the other layer of some event. Whenever an Operational + Primitive in invoked, the Connection_Handle qualifier is used to + identify a particular iSCSI connection. For some Operational + Primitives, a Data_Descriptor is used to identify the iSCSI/SCSI data + buffer associated with the requested or completed operation. + + The abstract model and the Operational Primitives defined in this + section facilitate the description of the iSER protocol. In the rest + of the iSER specification, the compliance statements related to the + use of these Operational Primitives are only for the purpose of the + + + +Ko & Nezhinsky Standards Track [Page 20] + +RFC 7145 iSER Specification April 2014 + + + required interactions between the iSCSI layer and the iSER layer. + Note that the compliance statements related to the Operational + Primitives in the rest of this specification only mandate functional + equivalence on implementations, but do not put any requirements on + the implementation specifics of the interface between the iSCSI layer + and the iSER layer. + + Each Operational Primitive is invoked with a set of qualifiers which + specify the information context for performing the specific action + being requested of the Operational Primitive. While the qualifiers + are required, the method of realizing the qualifiers (e.g., by + passing synchronously with invocation, or by retrieving from task + context, or by retrieving from shared memory, etc.) is implementation + dependent. + +3.1. Operational Primitives offered by iSER + + The iSER protocol layer MUST support the following Operational + Primitives to be used by the iSCSI protocol layer. + +3.1.1. Send_Control + + Input qualifiers: Connection_Handle, BHS and AHS (if any) of the + iSCSI PDU, PDU-specific qualifiers + + Return results: Not specified + + This is used by the iSCSI layers at the initiator and the target to + request the outbound transfer of an iSCSI control-type PDU (see + Section 7.2). Qualifiers that only apply for a particular control- + type PDU are known as PDU-specific qualifiers, e.g., + ImmediateDataSize for a SCSI Write command. For details on PDU- + specific qualifiers, see Section 7.3. The iSCSI layer can only + invoke the Send_Control Operational Primitive when the connection is + in iSER-assisted mode. + +3.1.2. Put_Data + + Input qualifiers: Connection_Handle, content of a SCSI Data-In + PDU header, Data_Descriptor, Notify_Enable + + Return results: Not specified + + This is used by the iSCSI layer at the target to request the outbound + transfer of data for a SCSI Data-In PDU from the buffer identified by + the Data_Descriptor qualifier. The iSCSI layer can only invoke the + Put_Data Operational Primitive when the connection is in iSER- + assisted mode. + + + +Ko & Nezhinsky Standards Track [Page 21] + +RFC 7145 iSER Specification April 2014 + + + The Notify_Enable qualifier is used to indicate to the iSER layer + whether or not it should generate an eventual local completion + notification to the iSCSI layer. See Section 3.2.2 on + Data_Completion_Notify for details. + +3.1.3. Get_Data + + Input qualifiers: Connection_Handle, content of an R2T PDU, + Data_Descriptor, Notify_Enable + + Return results: Not specified + + This is used by the iSCSI layer at the target to request the inbound + transfer of solicited data requested by an R2T PDU into the buffer + identified by the Data_Descriptor qualifier. The iSCSI layer can + only invoke the Get_Data Operational Primitive when the connection is + in iSER-assisted mode. + + The Notify_Enable qualifier is used to indicate to the iSER layer + whether or not it should generate the eventual local completion + notification to the iSCSI layer. See Section 3.2.2 on + Data_Completion_Notify for details. + +3.1.4. Allocate_Connection_Resources + + Input qualifiers: Connection_Handle, Resource_Descriptor + (optional) + + Return results: Status + + This is used by the iSCSI layers at the initiator and the target to + request the allocation of all connection resources necessary to + support RCaP for an operational iSCSI/iSER connection. The iSCSI + layer may optionally specify the implementation-specific resource + requirements for the iSCSI connection using the Resource_Descriptor + qualifier. + + A return result of Status=success means the invocation succeeded, and + a return result of Status=failure means that the invocation failed. + If the invocation is for a Connection_Handle for which an earlier + invocation succeeded, the request will be ignored by the iSER layer + and the result of Status=success will be returned. Only one + Allocate_Connection_Resources Operational Primitive invocation can be + outstanding for a given Connection_Handle at any time. + + + + + + + +Ko & Nezhinsky Standards Track [Page 22] + +RFC 7145 iSER Specification April 2014 + + +3.1.5. Deallocate_Connection_Resources + + Input qualifiers: Connection_Handle + + Return results: Not specified + + This is used by the iSCSI layers at the initiator and the target to + request the deallocation of all connection resources that were + allocated earlier as a result of a successful invocation of the + Allocate_Connection_Resources Operational Primitive. + +3.1.6. Enable_Datamover + + Input qualifiers: Connection_Handle, + Transport_Connection_Descriptor, Final Login_Response_PDU + (optional) + + Return results: Not specified + + This is used by the iSCSI layers at the initiator and the target to + request that iSER-assisted mode be used for the connection. The + Transport_Connection_Descriptor qualifier is used to identify the + specific connection associated with the Connection_Handle. The iSCSI + layer can only invoke the Enable_Datamover Operational Primitive when + there was a corresponding prior resource allocation. + + The Final_Login_Response_PDU input qualifier is applicable only for a + target and contains the final Login Response PDU that concludes the + iSCSI Login Phase. + +3.1.7. Connection_Terminate + + Input qualifiers: Connection_Handle + + Return results: Not specified + + This is used by the iSCSI layers at the initiator and the target to + request that a specified iSCSI/iSER connection be terminated and all + associated connection and task resources be freed. When this + Operational Primitive invocation returns to the iSCSI layer, the + iSCSI layer may assume full ownership of all iSCSI-level resources, + e.g., I/O Buffers, associated with the connection. + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 23] + +RFC 7145 iSER Specification April 2014 + + +3.1.8. Notice_Key_Values + + Input qualifiers: Connection_Handle, number of keys, list of Key- + Value pairs + + Return results: Not specified + + This is used by the iSCSI layers at the initiator and the target to + request the iSER layer to take note of the specified Key-Value pairs + that were negotiated by the iSCSI peers for the connection. + +3.1.9. Deallocate_Task_Resources + + Input qualifiers: Connection_Handle, ITT + + Return results: Not specified + + This is used by the iSCSI layers at the initiator and the target to + request the deallocation of all RCaP-specific resources allocated by + the iSER layer for the task identified by the ITT qualifier. The + iSER layer may require a certain number of RCaP-specific resources + associated with the ITT for each new iSCSI task. In the normal + course of execution, these task-level resources in the iSER layer are + assumed to be transparently allocated on each task initiation and + deallocated on the conclusion of each task as appropriate. In + exception scenarios where the task does not conclude with a SCSI + Response PDU, the iSER layer needs to be notified of the individual + task terminations to aid its task-level resource management. This + Operational Primitive is used for this purpose and is not needed when + a SCSI Response PDU normally concludes a task. Note that RCaP- + specific task resources are deallocated by the iSER layer when a SCSI + Response PDU normally concludes a task, even if the SCSI status was + not success. + +3.2. Operational Primitives Used by iSER + + The iSER layer MUST use the following Operational Primitives offered + by the iSCSI protocol layer when the connection is in iSER-assisted + mode. + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 24] + +RFC 7145 iSER Specification April 2014 + + +3.2.1. Control_Notify + + Input qualifiers: Connection_Handle, an iSCSI control-type PDU + + Return results: Not specified + + This is used by the iSER layers at the initiator and the target to + notify the iSCSI layer of the availability of an inbound iSCSI + control-type PDU. A PDU is described as "available" to the iSCSI + layer when the iSER layer notifies the iSCSI layer of the reception + of that inbound PDU, along with an implementation-specific indication + as to where the received PDU is. + +3.2.2. Data_Completion_Notify + + Input qualifiers: Connection_Handle, ITT, SN + + Return results: Not specified + + This is used by the iSER layer to notify the iSCSI layer of the + completion of the outbound data transfer that was requested by the + iSCSI layer only if the invocation of the Put_Data Operational + Primitive (see Section 3.1.2) was qualified with Notify_Enable set. + SN refers to the DataSN associated with the SCSI Data-In PDU. + + This is used by the iSER layer to notify the iSCSI layer of the + completion of the inbound data transfer that was requested by the + iSCSI layer only if the invocation of the Get_Data Operational + Primitive (see Section 3.1.3) was qualified with Notify_Enable set. + SN refers to the R2TSN associated with the R2T PDU. + +3.2.3. Data_ACK_Notify + + Input qualifier: Connection_Handle, ITT, DataSN + + Return results: Not specified + + This is used by the iSER layer at the target to notify the iSCSI + layer of the arrival of the data acknowledgement (as defined in + [iSCSI]) requested earlier by the iSCSI layer for the outbound data + transfer via an invocation of the Put_Data Operational Primitive + where the A-bit in the SCSI Data-In PDU is set to one. See Section + 7.3.5. DataSN refers to the expected DataSN of the next SCSI Data-In + PDU that immediately follows the SCSI Data-In PDU with the A-bit set + to which this notification corresponds, with semantics as defined in + [iSCSI]. + + + + + +Ko & Nezhinsky Standards Track [Page 25] + +RFC 7145 iSER Specification April 2014 + + +3.2.4. Connection_Terminate_Notify + + Input qualifiers: Connection_Handle + + Return results: Not specified + + This is used by the iSER layers at the initiator and the target to + notify the iSCSI layer of the unsolicited termination or failure of + an iSCSI/iSER connection. The iSER layer MUST deallocate the + connection and task resources associated with the terminated + connection before the invocation of this Operational Primitive. Note + that the Connection_Terminate_Notify Operational Primitive is not + invoked when the termination of the connection was earlier requested + by the local iSCSI layer. + +3.3. iSCSI Protocol Usage Requirements + + To operate in iSER-assisted mode, the iSCSI layers at both the + initiator and the target MUST negotiate the RDMAExtensions key (see + Section 6.3) to "Yes" on the leading connection. If the + RDMAExtensions key is not negotiated to "Yes", then iSER-assisted + mode MUST NOT be used. If the RDMAExtensons key is negotiated to + "Yes", but the invocation of the Allocate_Connection_Resources + Operational Primitive to the iSER layer fails, the iSCSI layer MUST + fail the iSCSI Login process or terminate the connection as + appropriate. See Section 10.1.3.1 for details. + + If the RDMAExtensions key is negotiated to "Yes", the iSCSI layer + MUST satisfy the following protocol usage requirements from the iSER + protocol: + + 1. The iSCSI layer at the initiator MUST set ExpDataSN to zero in + Task Management Function Requests for Task Allegiance + Reassignment for read/bidirectional commands, so as to cause the + target to send all unacknowledged read data. + + 2. The iSCSI layer at the target MUST always return the SCSI status + in a separate SCSI Response PDU for read commands, i.e., there + MUST NOT be a "phase collapse" in concluding a SCSI Read Command. + + 3. The iSCSI layers at both the initiator and the target MUST + support the keys as defined in Section 6 on Login/Text + Operational Keys. If used as specified, these keys MUST NOT be + answered with NotUnderstood, and the semantics as defined MUST be + followed for each iSER-assisted connection. + + 4. The iSCSI layer at the initiator MUST NOT issue SNACKs for PDUs. + + + + +Ko & Nezhinsky Standards Track [Page 26] + +RFC 7145 iSER Specification April 2014 + + +4. Lower-Layer Interface Requirements + +4.1. Interactions with the RCaP Layer + + The iSER protocol layer is layered on top of an RCaP layer (see + Figure 1) and the following are the key features that are assumed to + be supported by any RCaP layer: + + * The RCaP layer supports all basic RDMA operations, including the + RDMA Write Operation, RDMA Read Operation, and Send Operation. + + * The RCaP layer provides reliable, in-order message delivery and + direct data placement. + + * When the iSER layer initiates an RDMA Read Operation following an + RDMA Write Operation on one RCaP Stream, the RDMA Read Response + Message processing on the remote node will be started only after + the preceding RDMA Write Message payload is placed in the memory + of the remote node. + + * The RCaP layer encapsulates a single iSER Message into a single + RCaP Message on the Data Source side. The RCaP layer decapsulates + the iSER Message before delivering it to the iSER layer on the + Data Sink side. + + * For an RCaP layer that supports the Send with Invalidate Message + (e.g., iWARP), when the iSER layer provides the STag to be + remotely invalidated to the RCaP layer for a Send with Invalidate + Message, the RCaP layer uses this STag as the STag to be + invalidated in the Send with Invalidate Message. + + * The RCaP layer uses the STag and Tagged Offset provided by the + iSER layer for the RDMA Write and RDMA Read Request Messages. + + * When the RCaP layer delivers the content of an RDMA Send Message + to the iSER layer, the RCaP layer provides the length of the RDMA + Send Message. This ensures that the iSER layer does not have to + carry a length field in the iSER header. + + * When the RCaP layer delivers the Send Message to the iSER layer, + it notifies the iSER layer with the mechanism provided on that + interface. + + * For an RCaP layer that supports the Send with Invalidate Message + (e.g., iWARP), when the RCaP layer delivers a Send with Invalidate + Message to the iSER layer, it passes the value of the STag that + was invalidated. + + + + +Ko & Nezhinsky Standards Track [Page 27] + +RFC 7145 iSER Specification April 2014 + + + * The RCaP layer propagates all status and error indications to the + iSER layer. + + * For a transport layer that operates in byte stream mode such as + TCP, the RCaP implementation supports the enabling of the RDMA + mode after connection establishment and the exchange of Login + parameters in byte stream mode. For a transport layer that + provides message delivery capability such as [IB], the RCaP + implementation supports the direct use of the messaging capability + by the iSCSI layer for the Login Phase after connection + establishment and before enabling iSER-assisted mode. (In the + specific example of InfiniBand [IB], the iSCSI layer uses IB + messages to transfer iSCSI PDUs for the Login Phase after + connection establishment and before enabling iSER-assisted mode.) + + * Whenever the iSER layer terminates the RCaP Stream, the RCaP layer + terminates the associated connection. + +4.2. Interactions with the Transport Layer + + After the iSER connection is established, the RCaP layer and the + underlying transport layer are responsible for maintaining the + connection and reporting to the iSER layer any connection failures. + +5. Connection Setup and Termination + +5.1. iSCSI/iSER Connection Setup + + During connection setup, the iSCSI layer at the initiator is + responsible for establishing a connection with the target. After the + connection is established, the iSCSI layers at the initiator and the + target enter the Login Phase using the same rules as outlined in + [iSCSI]. The connection transitions into the iSCSI Full Feature + Phase in iSER-assisted mode following a successful login negotiation + between the initiator and the target in which iSER-assisted mode is + negotiated and the connection resources necessary to support RCaP + have been allocated at both the initiator and the target. The same + connection MUST be used for both the iSCSI Login Phase and the + subsequent iSER-assisted Full Feature Phase. + + For a transport layer that operates in byte stream mode such as TCP, + the RCaP implementation supports the enabling of the RDMA mode after + connection establishment and the exchange of Login parameters in byte + stream mode. For a transport layer that provides message delivery + capability such as [IB], the RCaP implementation supports the use of + the messaging capability by the iSCSI layer directly for the Login + Phase after connection establishment before enabling iSER-assisted + mode. + + + +Ko & Nezhinsky Standards Track [Page 28] + +RFC 7145 iSER Specification April 2014 + + + iSER-assisted mode MUST NOT be enabled unless it is negotiated on the + leading connection during the LoginOperationalNegotiation stage of + the iSCSI Login Phase. iSER-assisted mode is negotiated using the + RDMAExtensions= key. Both the initiator and the + target MUST exchange the RDMAExtensions key with the value set to + "Yes" to enable iSER-assisted mode. If both the initiator and the + target fail to negotiate the RDMAExtensions key set to "Yes", then + the connection MUST continue with the login semantics as defined in + [iSCSI]. If the RDMAExtensions key is not negotiated to Yes, then + for some RCaP implementation (such as [IB]), the existing connection + may need to be torn down and a new connection may need to be + established in TCP-capable mode. (For InfiniBand, this will require + a connection like [IPoIB].) + + iSER-assisted mode is defined for a Normal session only, and the + RDMAExtensions key MUST NOT be negotiated for a Discovery session. + Discovery sessions are always conducted using the transport layer as + described in [iSCSI]. + + An iSER-enabled node is not required to initiate the RDMAExtensions + key exchange if its preference is for the Traditional iSCSI mode. + The RDMAExtensions key, if offered, MUST be sent in the first + available Login Response or Login Request PDU in the + LoginOperationalNegotiation stage. This is due to the fact that the + value of some Login parameters might depend on whether or not iSER- + assisted mode is enabled. + + iSER-assisted mode is a session-wide attribute. If both the + initiator and the target negotiated RDMAExtensions="Yes" on the + leading connection of a session, then all subsequent connections of + the same session MUST enable iSER-assisted mode without having to + exchange RDMAExtensions keys during the iSCSI Login Phase. + Conversely, if both the initiator and the target failed to negotiate + RDMAExtensions to "Yes" on the leading connection of a session, then + the RDMAExtensions key MUST NOT be negotiated further on any + additional subsequent connection of the session. + + When the RDMAExtensions key is negotiated to "Yes", the HeaderDigest + and the DataDigest keys MUST be negotiated to "None" on all + iSCSI/iSER connections participating in that iSCSI session. This is + because, for an iSCSI/iSER connection, RCaP is responsible for + providing error detection that is at least as good as a 32-bit CRC + for all iSER Messages. Furthermore, all SCSI Read data are sent + using RDMA Write Messages instead of the SCSI Data-In PDUs, and all + solicited SCSI Write data are sent using RDMA Read Response Messages + instead of the SCSI Data-Out PDUs. HeaderDigest and DataDigest that + apply to iSCSI PDUs would not be appropriate for RDMA Read and RDMA + Write operations used with iSER. + + + +Ko & Nezhinsky Standards Track [Page 29] + +RFC 7145 iSER Specification April 2014 + + +5.1.1. Initiator Behavior + + If the outcome of the iSCSI negotiation is to enable iSER-assisted + mode, then on the initiator side, prior to sending the Login Request + with the T (Transit) bit set to one and the NSG (Next Stage) field + set to FullFeaturePhase, the iSCSI layer SHOULD request the iSER + layer to allocate the connection resources necessary to support RCaP + by invoking the Allocate_Connection_Resources Operational Primitive. + The connection resources required are defined by the implementation + and are outside the scope of this specification. The iSCSI layer may + invoke the Notice_Key_Values Operational Primitive before invoking + the Allocate_Connection_Resources Operational Primitive to request + the iSER layer to take note of the negotiated values of the iSCSI + keys for the connection. The specific keys to be passed in as input + qualifiers are implementation dependent. These may include, but are + not limited to, MaxOutstandingR2T and ErrorRecoveryLevel. + + Among the connection resources allocated at the initiator is the + Inbound RDMA Read Queue Depth (IRD). As described in Section 9.5.1, + R2Ts are transformed by the target into RDMA Read operations. IRD + limits the maximum number of simultaneously incoming outstanding RDMA + Read Requests per an RCaP Stream from the target to the initiator. + The required value of IRD is outside the scope of the iSER + specification. The iSER layer at the initiator MUST set IRD to 1 or + higher if R2Ts are to be used in the connection. However, the iSER + layer at the initiator MAY set IRD to zero based on implementation + configuration; setting IRD to zero indicates that no R2Ts will be + used on that connection. Initially, the iSER-IRD value at the + initiator SHOULD be set to the IRD value at the initiator and MUST + NOT be more than the IRD value. + + On the other hand, the Outbound RDMA Read Queue Depth (ORD) MAY be + set to zero since the iSER layer at the initiator does not issue RDMA + Read Requests to the target. + + Failure to allocate the requested connection resources locally + results in a login failure, and its handling is described in Section + 10.1.3.1. + + The iSER layer MUST return a success status to the iSCSI layer in + response to the Allocate_Connection_Resources Operational Primitive. + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 30] + +RFC 7145 iSER Specification April 2014 + + + After the target returns the Login Response with the T bit set to one + and the NSG field set to FullFeaturePhase, and a Status-Class of 0x00 + (Success), the iSCSI layer MUST invoke the Enable_Datamover + Operational Primitive with the following qualifiers. (See Section + 10.1.4.6 for the case when the Status-Class is not Success.) + + a. Connection_Handle that identifies the iSCSI connection. + + b. Transport_Connection_Descriptor that identifies the specific + transport connection associated with the Connection_Handle. + + The iSER layer MUST send the iSER Hello Message as the first iSER + Message only if iSERHelloRequired is negotiated to "Yes". See + Section 5.1.3 on iSER Hello Exchange. + + If the iSCSI layer on the initiator side allocates the connection + resources to support RCaP only after it receives the final Login + Response PDU from the target, then it may not be able to handle the + number of unexpected iSCSI control-type PDUs (as declared by the + MaxOutstandingUnexpectedPDUs key from the initiator) that can be sent + by the target before the buffer resources are allocated at the + initiator side. In this case, the iSERHelloRequired key SHOULD be + negotiated to "Yes" so that the initiator can allocate the connection + resources before sending the iSER Hello Message. See Section 5.1.3 + for more details. + +5.1.2. Target Behavior + + If the outcome of the iSCSI negotiation is to enable iSER-assisted + mode, then on the target side, prior to sending the Login Response + with the T (Transit) bit set to one and the NSG (Next Stage) field + set to FullFeaturePhase, the iSCSI layer MUST request the iSER layer + to allocate the resources necessary to support RCaP by invoking the + Allocate_Connection_Resources Operational Primitive. The connection + resources required are defined by implementation and are outside the + scope of this specification. Optionally, the iSCSI layer may invoke + the Notice_Key_Values Operational Primitive before invoking the + Allocate_Connection_Resources Operational Primitive to request the + iSER layer to take note of the negotiated values of the iSCSI keys + for the connection. The specific keys to be passed in as input + qualifiers are implementation dependent. These may include, but not + limited to, MaxOutstandingR2T and ErrorRecoveryLevel. + + Premature allocation of RCaP connection resources can expose an iSER + target to a resource exhaustion attack on those resources via + multiple iSER connections that progress only to the point at which + the implementation allocates the RCaP connection resources. The + countermeasure for this attack is initiator authentication; the iSCSI + + + +Ko & Nezhinsky Standards Track [Page 31] + +RFC 7145 iSER Specification April 2014 + + + layer MUST NOT request the iSER layer to allocate the connection + resources necessary to support RCaP until the iSCSI layer is + sufficiently far along in the iSCSI Login Phase that it is reasonably + certain that the peer side is not an attacker. In particular, if the + Login Phase includes a SecurityNegotiation stage, the iSCSI layer + MUST defer the connection resource allocation (i.e., invoking the + Allocate_Connection_Resources Operational Primitive) to the + LoginOperationalNegotiation stage ([iSCSI]) so that the resource + allocation occurs after the authentication phase is completed. + + Among the connection resources allocated at the target is the + Outbound RDMA Read Queue Depth (ORD). As described in Section 9.5.1, + R2Ts are transformed by the target into RDMA Read operations. The + ORD limits the maximum number of simultaneously outstanding RDMA Read + Requests per RCaP Stream from the target to the initiator. + Initially, the iSER-ORD value at the target SHOULD be set to the ORD + value at the target. + + On the other hand, the IRD at the target MAY be set to zero since the + iSER layer at the target does not expect RDMA Read Requests to be + issued by the initiator. + + Failure to allocate the requested connection resources locally + results in a login failure, and its handling is described in Section + 10.1.3.1. + + If the iSER layer at the target is successful in allocating the + connection resources necessary to support RCaP, the following events + MUST occur in the specified sequence: + + 1. The iSER layer MUST return a success status to the iSCSI layer in + response to the Allocate_Connection_Resources Operational + Primitive. + + 2. The iSCSI layer MUST invoke the Enable_Datamover Operational + Primitive with the following qualifiers: + + a. Connection_Handle that identifies the iSCSI connection. + + b. Transport_Connection_Descriptor that identifies the specific + transport connection associated with the Connection_Handle. + + c. The final transport-layer (e.g., TCP) message containing the + Login Response with the T bit set to one and the NSG field set + to FullFeaturePhase. + + + + + + +Ko & Nezhinsky Standards Track [Page 32] + +RFC 7145 iSER Specification April 2014 + + + 3. The iSER layer MUST send the final Login Response PDU in the + native transport mode to conclude the iSCSI Login Phase. If the + underlying transport is TCP, then the iSER layer MUST send the + final Login Response PDU in byte stream mode. + + 4. After receiving the iSER Hello Message from the initiator, the + iSER layer MUST respond with the iSER HelloReply Message to be + sent as the first iSER Message if iSERHelloRequired is negotiated + to "Yes". If the iSER layer receives an iSER Hello Message when + iSERHelloRequired is negotiated to "No", then this MUST be treated + as an iSER protocol error. See Section 5.1.3 on iSER Hello + Exchange for more details. + + Note: In the above sequence, the operations as described in items 3 + and 4 MUST be performed atomically for iWARP connections. Failure to + do this may result in race conditions. + +5.1.3. iSER Hello Exchange + + If iSERHelloRequired is negotiated to "Yes", the first iSER Message + sent by the iSER layer at the initiator to the target MUST be the + iSER Hello Message. The iSER Hello Message is used by the iSER layer + at the initiator to declare iSER parameters to the target. See + Section 9.3 on iSER Header Format for iSER Hello Message. + Conversely, if iSERHelloRequired is negotiated to "No", then the iSER + layer at the initiator MUST NOT send an iSER Hello Message. + + In response to the iSER Hello Message, the iSER layer at the target + MUST return the iSER HelloReply Message as the first iSER Message + sent by the target if iSERHelloRequired is negotiated to "Yes". The + iSER HelloReply Message is used by the iSER layer at the target to + declare iSER parameters to the initiator. See Section 9.4 on iSER + Header Format for iSER HelloReply Message. If the iSER layer + receives an iSER Hello Message when iSERHelloRequired is negotiated + to "No", then this MUST be treated as an iSER protocol error. See + Section 10.1.3.4 on iSER Protocol Errors on for more details. + + In the iSER Hello Message, the iSER layer at the initiator declares + the iSER-IRD value to the target. + + Upon receiving the iSER Hello Message, the iSER layer at the target + MUST set the iSER-ORD value to the minimum of the iSER-ORD value at + the target and the iSER-IRD value declared by the initiator. In + order to free up the unused resources, the iSER layer at the target + MAY adjust (lower) its ORD value to match the iSER-ORD value if the + iSER-ORD value is smaller than the ORD value at the target. + + + + + +Ko & Nezhinsky Standards Track [Page 33] + +RFC 7145 iSER Specification April 2014 + + + In the iSER HelloReply Message, the iSER layer at the target declares + the iSER-ORD value to the initiator. + + Upon receiving the iSER HelloReply Message, the iSER layer at the + initiator MAY adjust (lower) its IRD value to match the iSER-ORD + value in order to free up the unused resources, if the iSER-ORD value + declared by the target is smaller than the iSER-IRD value declared by + the initiator. + + It is an iSER-level negotiation failure if the iSER parameters + declared in the iSER Hello Message by the initiator are unacceptable + to the target. This includes the following: + + * The initiator-declared iSER-IRD value is greater than 0, and the + target-declared iSER-ORD value is 0. + + * The initiator-supported and the target-supported iSER protocol + versions do not overlap. + + See Section 10.1.3.2 on the handling of the error situation. + + An initiator that conforms to [RFC5046] allocates connection + resources before sending the Login Request with the T (Transit) bit + set to one and the NSG (Next Stage) field set to FullFeaturePhase. + (For brevity, this is referred to as "early" connection allocation.) + The current iSER specification relaxes this requirement to allow an + initiator to allocate connection resources after it receives the + final Login Response PDU from the target. (For brevity, this is + referred to as "late" connection allocation.) An initiator that + employs "late" connection allocation may encounter problems (e.g., + RCaP connection closure) with a target that sends unexpected iSCSI + PDUs immediately upon transitioning to Full Feature Phase, as allowed + by the negotiated value of the MaxOutstandingUnexpectedPDUs key. The + only way to prevent this situation in full generality is to use iSER + Hello Messages, as they enable the initiator to allocate its + connection resources before sending its iSER Hello Message. The + iSERHelloRequired key is used by the initiator to determine if it is + dealing with a target that supports the iSER Hello exchanges. + Fortunately, known iSER target implementations do not take full + advantage of the number of allowed unexpected PDUs immediately upon + transitioning into Full Feature Phase, thus enabling an initiator + workaround that involves a smaller quantity of connection resources + prior to Full Feature Phase, as explained further below. + + In the following summary, where "late" connection allocation is + practiced, an initiator that follows [RFC5046] is referred to as an + "old" initiator; otherwise, it is referred to as a "new" initiator. + Similarly, a target that does not support the iSERHelloRequired key + + + +Ko & Nezhinsky Standards Track [Page 34] + +RFC 7145 iSER Specification April 2014 + + + (and responds with "NotUnderstood" when negotiating the + iSERHelloRequired key) is referred to as an "old" target; otherwise, + it is referred to as a "new" target. Note that an "old" target can + still support the iSER Hello exchanges, but this fact is not known by + the initiator. A "new" target can also respond with "No" when + negotiating the iSERHelloRequired key. In this case, its behavior + with respect to "late" connection allocation is similar to an "old" + target. + + A "new" initiator will work fine with a "new" target. + + For an "old" initiator and an "old" target, the failure by the + initiator to handle the number of unexpected iSCSI control-type PDUs + that are sent by the target before the buffer resources are allocated + at the initiator can result in the failure of the iSER session caused + by closure of the underlying RCaP connection. For the "old" target, + there is a known implementation that sends one unexpected iSCSI + control-type PDU after sending the final Login Response and then + waits awhile before sending the next one. This tends to alleviate + somewhat the buffer allocation problem at the initiator. + + For a "new" initiator and an "old" target, the failure by the + initiator to handle the number of unexpected iSCSI control-type PDUs + that are sent by the target before the buffer resources are allocated + at the initiator can result in the failure of the iSER session caused + by closure of the underlying RCaP connection. A "new" initiator MAY + choose to terminate the connection; otherwise, it SHOULD do one of + the following: + + 1. Allocate the connection resources before sending the final Login + Request PDU. + + 2. Allocate one or more buffers for receiving unexpected control-type + PDUs from the target before sending the final Login Request PDU. + This reduces the possibility of the unexpected control-type PDUs + causing the RCaP connection to close before the connection + resources have been allocated. + + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 35] + +RFC 7145 iSER Specification April 2014 + + + For an "old" initiator and a "new" target, if the iSERHelloRequired + key is not negotiated, a "new" target MUST still respond with the + iSER HelloReply Message when it receives the iSER Hello Message. If + the iSERHelloRequired key is negotiated to "No" or "NotUnderstood", a + "new" target MAY choose to terminate the connection; otherwise, it + SHOULD delay sending any unexpected control-type PDUs until one of + the following events has occurred: + + 1. A PDU is received from the initiator after it sends the final + Login Response PDU. + + 2. A system-configurable timeout period (say, one second) has + expired. + +5.2. iSCSI/iSER Connection Termination + +5.2.1. Normal Connection Termination at the Initiator + + The iSCSI layer at the initiator terminates an iSCSI/iSER connection + normally by invoking the Send_Control Operational Primitive qualified + with the Logout Request PDU. The iSER layer at the initiator MUST + use a Send Message to send the Logout Request PDU to the target. The + SendSE Message should be used if supported by the RCaP layer (e.g., + iWARP). After the iSER layer at the initiator receives the Send + Message containing the Logout Response PDU from the target, it MUST + notify the iSCSI layer by invoking the Control_Notify Operational + Primitive qualified with the Logout Response PDU. + + After the iSCSI logout process is complete, the iSCSI layer at the + target is responsible for closing the iSCSI/iSER connection as + described in Section 5.2.2. After the RCaP layer at the initiator + reports that the connection has been closed, the iSER layer at the + initiator MUST deallocate all connection and task resources (if any) + associated with the connection, and invalidate the Local Mappings (if + any) before notifying the iSCSI layer by invoking the + Connection_Terminate_Notify Operational Primitive. + +5.2.2. Normal Connection Termination at the Target + + Upon receiving the Send Message containing the Logout Request PDU, + the iSER layer at the target MUST notify the iSCSI layer at the + target by invoking the Control_Notify Operational Primitive qualified + with the Logout Request PDU. The iSCSI layer completes the logout + process by invoking the Send_Control Operational Primitive qualified + with the Logout Response PDU. The iSER layer at the target MUST use + a Send Message to send the Logout Response PDU to the initiator. The + SendSE Message should be used if supported by the RCaP layer (e.g., + iWARP). After the iSCSI logout process is complete, the iSCSI layer + + + +Ko & Nezhinsky Standards Track [Page 36] + +RFC 7145 iSER Specification April 2014 + + + at the target MUST request the iSER layer at the target to terminate + the RCaP Stream by invoking the Connection_Terminate Operational + Primitive. + + As part of the termination process, the RCaP layer MUST close the + connection. When the RCaP layer notifies the iSER layer after the + RCaP Stream and the associated connection are terminated, the iSER + layer MUST deallocate all connection and task resources (if any) + associated with the connection, and invalidate the Local and Remote + Mappings (if any). + +5.2.3. Termination without Logout Request/Response PDUs + +5.2.3.1. Connection Termination Initiated by the iSCSI layer + + The Connection_Terminate Operational Primitive MAY be invoked by the + iSCSI layer to request the iSER layer to terminate the RCaP Stream + without having previously exchanged the Logout Request and Logout + Response PDUs between the two iSCSI/iSER nodes. As part of the + termination process, the RCaP layer will close the connection. When + the RCaP layer notifies the iSER layer after the RCaP Stream and the + associated connection are terminated, the iSER layer MUST perform the + following actions. + + If the Connection_Terminate Operational Primitive is invoked by the + iSCSI layer at the target, then the iSER layer at the target MUST + deallocate all connection and task resources (if any) associated with + the connection, and invalidate the Local and Remote Mappings (if + any). + + If the Connection_Terminate Operational Primitive is invoked by the + iSCSI layer at the initiator, then the iSER layer at the initiator + MUST deallocate all connection and task resources (if any) associated + with the connection, and invalidate the Local Mappings (if any). + +5.2.3.2. Connection Termination Notification to the iSCSI layer + + If the iSCSI/iSER connection is terminated without the invocation of + Connection_Terminate from the iSCSI layer, the iSER layer MUST notify + the iSCSI layer that the iSCSI/iSER connection has been terminated by + invoking the Connection_Terminate_Notify Operational Primitive. + + Prior to invoking Connection_Terminate_Notify, the iSER layer at the + target MUST deallocate all connection and task resources (if any) + associated with the connection, and invalidate the Local and Remote + Mappings (if any). + + + + + +Ko & Nezhinsky Standards Track [Page 37] + +RFC 7145 iSER Specification April 2014 + + + Prior to invoking Connection_Terminate_Notify, the iSER layer at the + initiator MUST deallocate all connection and task resources (if any) + associated with the connection, and invalidate the Local Mappings (if + any). + + If the remote iSCSI/iSER node initiated the closing of the connection + (e.g., by sending a TCP FIN or TCP RST), the iSER layer MUST notify + the iSCSI layer after the RCaP layer reports that the connection is + closed by invoking the Connection_Terminate_Notify Operational + Primitive. + + Another example of a connection termination without a preceding + logout is when the iSCSI layer at the initiator does an implicit + logout (connection reinstatement). + +6. Login/Text Operational Keys + + Certain iSCSI login/text operational keys have restricted usage in + iSER, and additional keys are used to support the iSER protocol + functionality. All other keys defined in [iSCSI] and not discussed + in this section may be used on iSCSI/iSER connections with the same + semantics. + +6.1. HeaderDigest and DataDigest + + Irrelevant when: RDMAExtensions=Yes + + Negotiations resulting in RDMAExtensions=Yes for a session imply + HeaderDigest=None and DataDigest=None for all connections in that + session and override the settings, whether default or configured. + +6.2. MaxRecvDataSegmentLength + + For an iSCSI connection belonging to a session in which + RDMAExtensions=Yes was negotiated on the leading connection of the + session, MaxRecvDataSegmentLength need not be declared in the Login + Phase, and MUST be ignored if it is declared. Instead, + InitiatorRecvDataSegmentLength (as described in Section 6.5) and + TargetRecvDataSegmentLength (as described in Section 6.4) keys are + negotiated. The values of the local and remote + MaxRecvDataSegmentLength are derived from the + InitiatorRecvDataSegmentLength and TargetRecvDataSegmentLength keys. + + In the Full Feature Phase, the initiator MUST consider the value of + its local MaxRecvDataSegmentLength (that it would have declared to + the target) as having the value of InitiatorRecvDataSegmentLength, + and the value of the remote MaxRecvDataSegmentLength (that would have + been declared by the target) as having the value of + + + +Ko & Nezhinsky Standards Track [Page 38] + +RFC 7145 iSER Specification April 2014 + + + TargetRecvDataSegmentLength. Similarly, the target MUST consider the + value of its local MaxRecvDataSegmentLength (that it would have + declared to the initiator) as having the value of + TargetRecvDataSegmentLength, and the value of the remote + MaxRecvDataSegmentLength (that would have been declared by the + initiator) as having the value of InitiatorRecvDataSegmentLength. + + Note that RFC 3720 requires that when a target receives a NOP-Out + request with a valid Initiator Task Tag, it responds with a NOP-In + with the same Initiator Task Tag that was provided in the NOP-Out + request. Furthermore, it returns the first MaxRecvDataSegmentLength + bytes of the initiator-provided Ping Data. Since there is no + MaxRecvDataSegmentLength common to the initiator and the target in + iSER, the length of the data sent with the NOP-Out request MUST NOT + exceed InitiatorMaxRecvDataSegmentLength. + + The MaxRecvDataSegmentLength key is applicable only for iSCSI + control-type PDUs. + +6.3. RDMAExtensions + + Use: LO (leading only) + + Senders: Initiator and Target + + Scope: SW (session-wide) + + RDMAExtensions= + + Irrelevant when: SessionType=Discovery + + Default is No + + Result function is AND + + This key is used by the initiator and the target to negotiate the + support for iSER-assisted mode. To enable the use of iSER-assisted + mode, both the initiator and the target MUST exchange + RDMAExtensions=Yes. iSER-assisted mode MUST NOT be used if either + the initiator or the target offers RDMAExtensions=No. + + An iSER-enabled node is not required to initiate the RDMAExtensions + key exchange if it prefers to operate in the Traditional iSCSI mode. + However, if the RDMAExtensions key is to be negotiated, an initiator + MUST offer the key in the first Login Request PDU in the + LoginOperationalNegotiation stage of the leading connection, and a + target MUST offer the key in the first Login Response PDU with which + it is allowed to do so (i.e., the first Login Response PDU issued + + + +Ko & Nezhinsky Standards Track [Page 39] + +RFC 7145 iSER Specification April 2014 + + + after the first Login Request PDU with the C bit set to zero) in the + LoginOperationalNegotiation stage of the leading connection. In + response to the offered key=value pair of RDMAExtensions=yes, an + initiator MUST respond in the next Login Request PDU with which it is + allowed to do so, and a target MUST respond in the next Login + Response PDU with which it is allowed to do so. + + Negotiating the RDMAExtensions key first enables a node to negotiate + the optimal value for other keys. Certain iSCSI keys such as + MaxBurstLength, MaxOutstandingR2T, ErrorRecoveryLevel, InitialR2T, + ImmediateData, etc., may be negotiated differently depending on + whether the connection is in Traditional iSCSI mode or iSER-assisted + mode. + +6.4. TargetRecvDataSegmentLength + + Use: IO (Initialize only) + + Senders: Initiator and Target + + Scope: CO (connection-only) + + Irrelevant when: RDMAExtensions=No + + TargetRecvDataSegmentLength= + + Default is 8192 bytes + + Result function is minimum + + This key is relevant only for the iSCSI connection of an iSCSI + session if RDMAExtensions=Yes was negotiated on the leading + connection of the session. It is used by the initiator and the + target to negotiate the maximum size of the data segment that an + initiator may send to the target in an iSCSI control-type PDU in the + Full Feature Phase. For SCSI Command PDUs and SCSI Data-Out PDUs + containing non-immediate unsolicited data to be sent by the + initiator, the initiator MUST send all non-Final PDUs with a data + segment size of exactly TargetRecvDataSegmentLength whenever the PDUs + constitute a data sequence whose size is larger than + TargetRecvDataSegmentLength. + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 40] + +RFC 7145 iSER Specification April 2014 + + +6.5. InitiatorRecvDataSegmentLength + + Use: IO (Initialize only) + + Senders: Initiator and Target + + Scope: CO (connection-only) + + Irrelevant when: RDMAExtensions=No + + InitiatorRecvDataSegmentLength= + + Default is 8192 bytes + + Result function is minimum + + This key is relevant only for the iSCSI connection of an iSCSI + session if RDMAExtensions=Yes was negotiated on the leading + connection of the session. It is used by the initiator and the + target to negotiate the maximum size of the data segment that a + target may send to the initiator in an iSCSI control-type PDU in the + Full Feature Phase. + +6.6. OFMarker and IFMarker + + Irrelevant when: RDMAExtensions=Yes + + Negotiations resulting in RDMAExtensions=Yes for a session imply + OFMarker=No and IFMarker=No for all connections in that session and + override the settings, whether default or configured. + +6.7. MaxOutstandingUnexpectedPDUs + + Use: LO (leading only), Declarative + + Senders: Initiator and Target + + Scope: SW (session-wide) + + Irrelevant when: RDMAExtensions=No + + MaxOutstandingUnexpectedPDUs= + + + Default is 0 + + + + + + +Ko & Nezhinsky Standards Track [Page 41] + +RFC 7145 iSER Specification April 2014 + + + This key is used by the initiator and the target to declare the + maximum number of outstanding "unexpected" iSCSI control-type PDUs + that it can receive in the Full Feature Phase. It is intended to + allow the receiving side to determine the amount of buffer resources + needed beyond the normal flow control mechanism available in iSCSI. + An initiator or target should select a value such that it would not + impose an unnecessary constraint on the iSCSI layer under normal + circumstances. The value of 0 is defined to indicate that the + declarer has no limit on the maximum number of outstanding + "unexpected" iSCSI control-type PDUs that it can receive. See + Sections 8.1.1 and 8.1.2 for the usage of this key. Note that iSER + Hello and HelloReply Messages are not iSCSI control-type PDUs and are + not affected by this key. + + For interoperability with implementations based on [RFC5046], this + key SHOULD be negotiated because the default value of 0 in [RFC5046] + is problematic for most implementations as it does not impose a bound + on resources consumable by unexpected PDUs. + +6.8. MaxAHSLength + + Use: LO (leading only), Declarative + + Senders: Initiator and Target + + Scope: SW (session-wide) + + Irrelevant when: RDMAExtensions=No + + MaxAHSLength= + + Default is 256 + + This key is used by the initiator and target to declare the maximum + size of AHS in an iSCSI control-type PDU that it can receive in the + Full Feature Phase. It is intended to allow the receiving side to + determine the amount of resources needed for receive buffering. An + initiator or target should select a value such that it would not + impose an unnecessary constraint on the iSCSI layer under normal + circumstances. The value of 0 is defined to indicate that the + declarer has no limit on the maximum size of AHS in iSCSI control- + type PDUs that it can receive. + + For interoperability with implementations based on [RFC5046], an + initiator or target MAY terminate the connection if it anticipates + MaxAHSLength to be greater than 256 and the key is not understood by + its peer. + + + + +Ko & Nezhinsky Standards Track [Page 42] + +RFC 7145 iSER Specification April 2014 + + +6.9. TaggedBufferForSolicitedDataOnly + + Use: LO (leading only), Declarative + + Senders: Initiator + + Scope: SW (session-wide) + + RDMAExtensions= + + Irrelevant when: RDMAExtensions=No + + Default is No + + This key is used by the initiator to declare to the target the usage + of the Write Base Offset in the iSER header of an iSCSI control-type + PDU. When set to No, the Base Offset is associated with an I/O + buffer that contains all the write data, including both unsolicited + and solicited data. When set to Yes, the Base Offset is associated + with an I/O buffer that only contains solicited data. + +6.10. iSERHelloRequired + + Use: LO (leading only), Declarative + + Senders: Initiator + + Scope: SW (session-wide) + + RDMAExtensions= + + Irrelevant when: RDMAExtensions=No + + Default is No + + This key is relevant only for the iSCSI connection of an iSCSI + session if RDMAExtensions=Yes was negotiated on the leading + connection of the session. It is used by the initiator to declare to + the target whether the iSER Hello Exchange is required. When set to + Yes, the iSER layers MUST perform the iSER Hello Exchange as + described in Section 5.1.3. When set to No, the iSER layers MUST NOT + perform the iSER Hello Exchange. + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 43] + +RFC 7145 iSER Specification April 2014 + + +7. iSCSI PDU Considerations + + When a connection is in the iSER-assisted mode, two types of message + transfers are allowed between the iSCSI layer (at the initiator) and + the iSCSI layer (at the target). These are known as the iSCSI data- + type PDUs and the iSCSI control-type PDUs, and these terms are + described in the following sections. + +7.1. iSCSI Data-Type PDU + + An iSCSI data-type PDU is defined as an iSCSI PDU that causes data + transfer, transparent to the remote iSCSI layer, to take place + between the peer iSCSI nodes in the Full Feature Phase of an + iSCSI/iSER connection. An iSCSI data-type PDU, when requested for + transmission by the iSCSI layer in the sending node, results in the + data's transfer without the participation of the iSCSI layers at the + sending and the receiving nodes. This is due to the fact that the + PDU itself is not delivered as-is to the iSCSI layer in the receiving + node. Instead, the data transfer operations are transformed into the + appropriate RDMA operations, which are handled by the RDMA-Capable + Controller. The set of iSCSI data-type PDUs consists of SCSI Data-In + PDUs and R2T PDUs. + + If the invocation of the Operational Primitive by the iSCSI layer to + request the iSER layer to process an iSCSI data-type PDU is qualified + with Notify_Enable set, then upon completing the RDMA operation, the + iSER layer at the target MUST notify the iSCSI layer at the target by + invoking the Data_Completion_Notify Operational Primitive qualified + with the ITT and SN. There is no data completion notification at the + initiator since the RDMA operations are completely handled by the + RDMA-Capable Controller at the initiator and the iSER layer at the + initiator is not involved with the data transfer associated with + iSCSI data-type PDUs. + + If the invocation of the Operational Primitive by the iSCSI layer to + request the iSER layer to process an iSCSI data-type PDU is qualified + with Notify_Enable cleared, then upon completing the RDMA operation, + the iSER layer at the target MUST NOT notify the iSCSI layer at the + target and MUST NOT invoke the Data_Completion_Notify Operational + Primitive. + + If an operation associated with an iSCSI data-type PDU fails for any + reason, the contents of the Data Sink buffers associated with the + operation are considered indeterminate. + + + + + + + +Ko & Nezhinsky Standards Track [Page 44] + +RFC 7145 iSER Specification April 2014 + + +7.2. iSCSI Control-Type PDU + + Any iSCSI PDU that is not an iSCSI data-type PDU and also not a SCSI + Data-Out PDU carrying solicited data is defined as an iSCSI control- + type PDU. The iSCSI layer invokes the Send_Control Operational + Primitive to request the iSER layer to process an iSCSI control-type + PDU. iSCSI control-type PDUs are transferred using Send Messages of + RCaP. Specifically, it is to be noted that SCSI Data-Out PDUs + carrying unsolicited data are defined as iSCSI control-type PDUs. + See Section 7.3.4 on the treatment of SCSI Data-Out PDUs. + + When the iSER layer receives an iSCSI control-type PDU, it MUST + notify the iSCSI layer by invoking the Control_Notify Operational + Primitive qualified with the iSCSI control-type PDU. + +7.3. iSCSI PDUs + + This section describes the handling of each of the iSCSI PDU types by + the iSER layer. The iSCSI layer requests the iSER layer to process + the iSCSI PDU by invoking the appropriate Operational Primitive. A + Connection_Handle MUST qualify each of these invocations. In + addition, the BHS and the optional AHS of the iSCSI PDU as defined in + [iSCSI] MUST qualify each of the invocations. The qualifying + Connection_Handle, the BHS, and the AHS are not explicitly listed in + the subsequent sections. + +7.3.1. SCSI Command + + Type: control-type PDU + + PDU-specific qualifiers (for SCSI Write or bidirectional command): + ImmediateDataSize, UnsolicitedDataSize, DataDescriptorOut + + PDU-specific qualifiers (for SCSI Read or bidirectional command): + DataDescriptorIn + + The iSER layer at the initiator MUST send the SCSI command in a Send + Message to the target. The SendSE Message should be used if + supported by the RCaP layer (e.g., iWARP). + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 45] + +RFC 7145 iSER Specification April 2014 + + + For a SCSI Write or bidirectional command, the iSCSI layer at the + initiator MUST invoke the Send_Control Operational Primitive as + follows: + + * If there is immediate data to be transferred for the SCSI write or + bidirectional command, the qualifier ImmediateDataSize MUST be + used to define the number of bytes of immediate unsolicited data + to be sent with the write or bidirectional command, and the + qualifier DataDescriptorOut MUST be used to define the initiator's + I/O Buffer containing the SCSI Write data. + + * If there is unsolicited data to be transferred for the SCSI Write + or bidirectional command, the qualifier UnsolicitedDataSize MUST + be used to define the number of bytes of immediate and non- + immediate unsolicited data for the command. The iSCSI layer will + issue one or more SCSI Data-Out PDUs for the non-immediate + unsolicited data. See Section 7.3.4 on SCSI Data-Out. + + * If there is solicited data to be transferred for the SCSI Write or + bidirectional command, as indicated when the Expected Data + Transfer Length in the SCSI Command PDU exceeds the value of + UnsolicitedDataSize, the iSER layer at the initiator MUST do the + following: + + a. It MUST allocate a Write STag for the I/O Buffer defined by the + qualifier DataDescriptorOut. DataDescriptorOut describes the + I/O buffer starting with the immediate unsolicited data (if + any), followed by the non-immediate unsolicited data (if any) + and solicited data. When TaggedBufferForSolicitedDataOnly is + negotiated to No, the Base Offset is associated with this I/O + Buffer. When TaggedBufferForSolicitedDataOnly is negotiated to + Yes, the Base Offset is associated with an I/O Buffer that + contains only solicited data. + + b. It MUST establish a Local Mapping that associates the Initiator + Task Tag (ITT) to the Write STag. + + c. It MUST Advertise the Write STag and the Base Offset to the + target by sending them in the iSER header of the iSER Message + (the payload of the Send Message of RCaP) containing the SCSI + Write or bidirectional command PDU. The SendSE Message should + be used if supported by the RCaP layer (e.g., iWARP). See + Section 9.2 on iSER Header Format for iSCSI Control-Type PDU. + + + + + + + + +Ko & Nezhinsky Standards Track [Page 46] + +RFC 7145 iSER Specification April 2014 + + + For a SCSI Read or bidirectional command, the iSCSI layer at the + initiator MUST invoke the Send_Control Operational Primitive + qualified with DataDescriptorIn, which defines the initiator's I/O + Buffer for receiving the SCSI Read data. The iSER layer at the + initiator MUST do the following: + + a. It MUST allocate a Read STag for the I/O Buffer and note the + Base Offset for this I/O Buffer. + + b. It MUST establish a Local Mapping that associates the Initiator + Task Tag (ITT) to the Read STag. + + c. It MUST Advertise the Read STag and the Base Offset to the + target by sending them in the iSER header of the iSER Message + (the payload of the Send Message of RCaP) containing the SCSI + Read or bidirectional command PDU. The SendSE Message should + be used if supported by the RCaP layer (e.g., iWARP). See + Section 9.2 on iSER Header Format for iSCSI Control-Type PDU. + + If the amount of unsolicited data to be transferred in a SCSI Command + exceeds TargetRecvDataSegmentLength, then the iSCSI layer at the + initiator MUST segment the data into multiple iSCSI control-type + PDUs, with the data segment length in all generated PDUs (except the + last one) having exactly the size TargetRecvDataSegmentLength. The + data segment length of the last iSCSI control-type PDU carrying the + unsolicited data can be up to TargetRecvDataSegmentLength. + + When the iSER layer at the target receives the SCSI Command, it MUST + establish a Remote Mapping that associates the ITT to the Base + Offset(s) and the Advertised STag(s) in the iSER header. The Write + STag is used by the iSER layer at the target in handling the data + transfer associated with the R2T PDU(s) as described in Section + 7.3.6. The Read STag is used in handling the SCSI Data-In PDU(s) + from the iSCSI layer at the target as described in Section 7.3.5. + +7.3.2. SCSI Response + + Type: control-type PDU + + PDU-specific qualifiers: DataDescriptorStatus + + The iSCSI layer at the target MUST invoke the Send_Control + Operational Primitive qualified with DataDescriptorStatus, which + defines the buffer containing the sense and response information. + The iSCSI layer at the target MUST always return the SCSI status for + a SCSI command in a separate SCSI Response PDU. "Phase collapse" for + + + + + +Ko & Nezhinsky Standards Track [Page 47] + +RFC 7145 iSER Specification April 2014 + + + transferring SCSI status in a SCSI Data-In PDU MUST NOT be used. The + iSER layer at the target sends the SCSI Response PDU according to the + following rules: + + * If no STags were Advertised by the initiator in the iSER Message + containing the SCSI command PDU, then the iSER layer at the target + MUST send a Send Message containing the SCSI Response PDU. The + SendSE Message should be used if supported by the RCaP layer + (e.g., iWARP). + + * If the initiator Advertised a Read STag in the iSER Message + containing the SCSI Command PDU, then the iSER layer at the target + MUST send a Send Message containing the SCSI Response PDU. The + header of the Send Message MUST carry the Read STag to be + invalidated at the initiator. The Send with Invalidate Message, + if supported by the RCaP layer (e.g., iWARP), can be used for the + automatic invalidation of the STag. + + * If the initiator Advertised only the Write STag in the iSER + Message containing the SCSI command PDU, then the iSER layer at + the target MUST send a Send Message containing the SCSI Response + PDU. The header of the Send Message MUST carry the Write STag to + be invalidated at the initiator. The Send with Invalidate + Message, if supported by the RCaP layer (e.g., iWARP), can be used + for the automatic invalidation of the STag. + + When the iSCSI layer at the target invokes the Send_Control + Operational Primitive to send the SCSI Response PDU, the iSER layer + at the target MUST invalidate the Remote Mapping before transferring + the SCSI Response PDU to the initiator. + + Upon receiving a Send Message containing the SCSI Response PDU from + the target, the iSER layer at the initiator MUST invalidate the + STag(s) specified in the header. (If a Send with Invalidate Message + is supported by the RCaP layer (e.g., iWARP) and is used to carry the + SCSI Response PDU, the RCaP layer at the initiator will invalidate + the STag. The iSER layer at the initiator MUST ensure that the + correct STag is invalidated. If both the Read and the Write STags + were Advertised earlier by the initiator, then the iSER layer at the + initiator MUST explicitly invalidate the Write STag upon receiving + the Send with Invalidate Message because the header of the Send with + Invalidate Message can only carry one STag (in this case, the Read + STag) to be invalidated.) + + The iSER layer at the initiator MUST ensure the invalidation of the + STag(s) used in a command before notifying the iSCSI layer at the + initiator by invoking the Control_Notify Operational Primitive + qualified with the SCSI Response. This precludes the possibility of + + + +Ko & Nezhinsky Standards Track [Page 48] + +RFC 7145 iSER Specification April 2014 + + + using the STag(s) after the completion of the command; such use would + cause data corruption. + + When the iSER layer at the initiator receives a Send Message + containing the SCSI Response PDU, it SHOULD invalidate the Local + Mapping. The iSER layer MUST ensure that all local STag(s) + associated with the ITT are invalidated before notifying the iSCSI + layer of the SCSI Response PDU by invoking the Control_Notify + Operational Primitive qualified with the SCSI Response PDU. + +7.3.3. Task Management Function Request/Response + + Type: control-type PDU + + PDU-specific qualifiers (for TMF Request): DataDescriptorOut, + DataDescriptorIn + + The iSER layer MUST use a Send Message to send the Task Management + Function Request/Response PDU. The SendSE Message should be used if + supported by the RCaP layer (e.g., iWARP). + + For the Task Management Function Request with the TASK REASSIGN + function, the iSER layer at the initiator MUST do the following: + + * It MUST use the ITT as specified in the Referenced Task Tag from + the Task Management Function Request PDU to locate the existing + STags (if any) in the Local Mappings. + + * It MUST invalidate the existing STags (if any) and the Local + Mappings. + + * It MUST allocate a Read STag for the I/O Buffer and note the Base + Offset associated with the I/O Buffer as defined by the qualifier + DataDescriptorIn if the Send_Control Operational Primitive + invocation is qualified with DataDescriptorIn. + + * It MUST allocate a Write STag for the I/O Buffer and note the Base + Offset associated with the I/O Buffer as defined by the qualifier + DataDescriptorOut if the Send_Control Operational Primitive + invocation is qualified with DataDescriptorOut. + + * If STags are allocated, it MUST establish new Local Mapping(s) + that associate the ITT to the allocated STag(s). + + * It MUST Advertise the STags and the Base Offsets, if allocated, to + the target in the iSER header of the Send Message carrying the + iSCSI PDU, as described in Section 9.2. The SendSE Message should + be used if supported by the RCaP layer (e.g., iWARP). + + + +Ko & Nezhinsky Standards Track [Page 49] + +RFC 7145 iSER Specification April 2014 + + + For the Task Management Function Request with the TASK REASSIGN + function for a SCSI Read or bidirectional command, the iSCSI layer at + the initiator MUST set ExpDataSN to zero since the data transfer and + acknowledgements happen transparently to the iSCSI layer at the + initiator. This provides the flexibility to the iSCSI layer at the + target to request transmission of only the unacknowledged data as + specified in [iSCSI]. + + When the iSER layer at the target receives the Task Management + Function Request with the TASK REASSIGN function, it MUST do the + following: + + * It MUST use the ITT as specified in the Referenced Task Tag from + the Task Management Function Request PDU to locate the Local and + Remote Mappings (if any). + + * It MUST invalidate the local STags (if any) associated with the + ITT. + + * It MUST replace the Base Offset(s) and the Advertised STag(s) in + the Remote Mapping with the Base Offset(s) and the Advertised + STag(s) in the iSER header. The Write STag is used in the + handling of the R2T PDU(s) from the iSCSI layer at the target as + described in Section 7.3.6. The Read STag is used in the handling + of the SCSI Data-In PDU(s) from the iSCSI layer at the target as + described in Section 7.3.5. + +7.3.4. SCSI Data-Out + + Type: control-type PDU + + PDU-specific qualifiers: DataDescriptorOut + + The iSCSI layer at the initiator MUST invoke the Send_Control + Operational Primitive qualified with DataDescriptorOut, which defines + the initiator's I/O Buffer containing unsolicited SCSI Write data. + + If the amount of unsolicited data to be transferred as SCSI Data-Out + exceeds TargetRecvDataSegmentLength, then the iSCSI layer at the + initiator MUST segment the data into multiple iSCSI control-type + PDUs, where the DataSegmentLength has the value of + TargetRecvDataSegmentLength in all generated PDUs except the last + one. The DataSegmentLength of the last iSCSI control-type PDU + carrying the unsolicited data can be up to + TargetRecvDataSegmentLength. The iSCSI layer at the target MUST + perform the reassembly function for the unsolicited data. + + + + + +Ko & Nezhinsky Standards Track [Page 50] + +RFC 7145 iSER Specification April 2014 + + + For unsolicited data, the iSER layer at the initiator MUST use a Send + Message to send the SCSI Data-Out PDU. If the F bit is set to 1, the + SendSE Message should be used if supported by the RCaP layer (e.g., + iWARP). + + Note that for solicited data, the SCSI Data-Out PDUs are not used + since R2T PDUs are not delivered to the iSCSI layer at the initiator; + instead, R2T PDUs are transformed by the iSER layer at the target + into RDMA Read operations. (See Section 7.3.6.) + +7.3.5. SCSI Data-In + + Type: data-type PDU + + PDU-specific qualifiers: DataDescriptorIn + + When the iSCSI layer at the target is ready to return the SCSI Read + data to the initiator, it MUST invoke the Put_Data Operational + Primitive qualified with DataDescriptorIn, which defines the SCSI + Data-In buffer. See Section 7.1 on the general requirement on the + handling of iSCSI data-type PDUs. SCSI Data-In PDU(s) are used in + SCSI Read data transfer as described in Section 9.5.2. + + The iSER layer at the target MUST do the following for each + invocation of the Put_Data Operational Primitive: + + 1. It MUST use the ITT in the SCSI Data-In PDU to locate the remote + Read STag and the Base Offset in the Remote Mapping. The Remote + Mapping was established earlier by the iSER layer at the target + when the SCSI Read Command was received from the initiator. + + 2. It MUST generate and send an RDMA Write Message containing the + read data to the initiator. + + a. It MUST use the remote Read STag as the Data Sink STag of the + RDMA Write Message. + + b. It MUST add the Buffer Offset from the SCSI Data-In PDU to the + Base Offset from the Remote Mapping as the Data Sink Tagged + Offset of the RDMA Write Message. + + c. It MUST use DataSegmentLength from the SCSI Data-In PDU to + determine the amount of data to be sent in the RDMA Write + Message. + + 3. It MUST associate the DataSN and ITT from the SCSI Data-In PDU + with the RDMA Write operation. If the Put_Data Operational + Primitive invocation was qualified with Notify_Enable set, then + + + +Ko & Nezhinsky Standards Track [Page 51] + +RFC 7145 iSER Specification April 2014 + + + when the iSER layer at the target receives a completion from the + RCaP layer for the RDMA Write Message, the iSER layer at the + target MUST notify the iSCSI layer by invoking the + Data_Completion_Notify Operational Primitive qualified with the + DataSN and ITT. Conversely, if the Put_Data Operational Primitive + invocation was qualified with Notify_Enable cleared, then the iSER + layer at the target MUST NOT notify the iSCSI layer on completion + and MUST NOT invoke the Data_Completion_Notify Operational + Primitive. + + When the A-bit is set to one in the SCSI Data-In PDU, the iSER layer + at the target MUST notify the iSCSI layer at the target when the data + transfer is complete at the initiator. To perform this additional + function, the iSER layer at the target can take advantage of the + operational ErrorRecoveryLevel if previously disclosed by the iSCSI + layer via an earlier invocation of the Notice_Key_Values Operational + Primitive. There are two approaches that can be taken: + + 1. If the iSER layer at the target knows that the operational + ErrorRecoveryLevel is 2, or if the iSER layer at the target does + not know the operational ErrorRecoveryLevel, then the iSER layer + at the target MUST issue a zero-length RDMA Read Request Message + following the RDMA Write Message. When the iSER layer at the + target receives a completion for the RDMA Read Request Message + from the RCaP layer, implying that the RDMA-Capable Controller at + the initiator has completed processing the RDMA Write Message due + to the completion ordering semantics of RCaP, the iSER layer at + the target MUST notify the iSCSI layer at the target by invoking + the Data_ACK_Notify Operational Primitive qualified with ITT and + DataSN (see Section 3.2.3). + + 2. If the iSER layer at the target knows that the operational + ErrorRecoveryLevel is 1, then the iSER layer at the target MUST do + one of the following: + + a. It MUST notify the iSCSI layer at the target by invoking the + Data_ACK_Notify Operational Primitive qualified with ITT and + DataSN (see Section 3.2.3) when it receives the local + completion from the RCaP layer for the RDMA Write Message. + This is allowed since digest errors do not occur in iSER (see + Section 10.1.4.2) and a CRC error will cause the connection to + be terminated and the task to be terminated anyway. The local + RDMA Write completion from the RCaP layer guarantees that the + RCaP layer will not access the I/O Buffer again to transfer the + data associated with that RDMA Write operation. + + + + + + +Ko & Nezhinsky Standards Track [Page 52] + +RFC 7145 iSER Specification April 2014 + + + b. Alternatively, it MUST use the same procedure for handling the + data transfer completion at the initiator as for + ErrorRecoveryLevel 2. + + It should be noted that the iSCSI layer at the target cannot set the + A-bit to 1 if the ErrorRecoveryLevel=0. + + SCSI status MUST always be returned in a separate SCSI Response PDU. + The S bit in the SCSI Data-In PDU MUST always be set to zero. There + MUST NOT be a "phase collapse" in the SCSI Data-In PDU. + + Since the RDMA Write Message only transfers the data portion of the + SCSI Data-In PDU but not the control information in the header, such + as ExpCmdSN, if timely updates of such information are crucial, the + iSCSI layer at the initiator MAY issue NOP-Out PDUs to request the + iSCSI layer at the target to respond with the information using + NOP-In PDUs. + +7.3.6. Ready To Transfer (R2T) + + Type: data-type PDU + + PDU-specific qualifiers: DataDescriptorOut + + In order to send an R2T PDU, the iSCSI layer at the target MUST + invoke the Get_Data Operational Primitive qualified with + DataDescriptorOut, which defines the I/O Buffer for receiving the + SCSI Write data from the initiator. See Section 7.1 on the general + requirements on the handling of iSCSI data-type PDUs. + + The iSER layer at the target MUST do the following for each + invocation of the Get_Data Operational Primitive: + + 1. It MUST ensure a valid local STag for the I/O Buffer and a valid + Local Mapping. This may involve allocating a valid local STag and + establishing a Local Mapping. + + 2. It MUST use the ITT in the R2T to locate the remote Write STag and + the Base Offset in the Remote Mapping. The Remote Mapping was + established earlier by the iSER layer at the target when the iSER + Message containing the Advertised Write STag, the Base Offset, and + the SCSI Command PDU for a SCSI Write or bidirectional command was + received from the initiator. + + 3. If the iSER-ORD value at the target is set to zero, the iSER layer + at the target MUST terminate the connection and free up the + resources associated with the connection (as described in Section + 5.2.3) if it received the R2T PDU from the iSCSI layer at the + + + +Ko & Nezhinsky Standards Track [Page 53] + +RFC 7145 iSER Specification April 2014 + + + target. Upon termination of the connection, the iSER layer at the + target MUST notify the iSCSI layer at the target by invoking the + Connection_Terminate_Notify Operational Primitive. + + 4. If the iSER-ORD value at the target is set to greater than 0, the + iSER layer at the target MUST transform the R2T PDU into an RDMA + Read Request Message. While transforming the R2T PDU, the iSER + layer at the target MUST ensure that the number of outstanding + RDMA Read Request Messages does not exceed the iSER-ORD value. To + transform the R2T PDU, the iSER layer at the target: + + a. MUST derive the local STag and local Tagged Offset from the + DataDescriptorOut that qualified the Get_Data invocation. + + b. MUST use the local STag as the Data Sink STag of the RDMA Read + Request Message. + + c. MUST use the local Tagged Offset as the Data Sink Tagged Offset + of the RDMA Read Request Message. + + d. MUST use the Desired Data Transfer Length from the R2T PDU as + the RDMA Read Message Size of the RDMA Read Request Message. + + e. MUST use the remote Write STag as the Data Source STag of the + RDMA Read Request Message. + + f. MUST add the Buffer Offset from the R2T PDU to the Base Offset + from the Remote Mapping as the Data Source Tagged Offset of the + RDMA Read Request Message. + + 5. It MUST associate the R2TSN and ITT from the R2T PDU with the RDMA + Read operation. If the Get_Data Operational Primitive invocation + was qualified with Notify_Enable set, then when the iSER layer at + the target receives a completion from the RCaP layer for the RDMA + Read operation, the iSER layer at the target MUST notify the iSCSI + layer by invoking the Data_Completion_Notify Operational Primitive + qualified with the R2TSN and ITT. Conversely, if the Get_Data + Operational Primitive invocation was qualified with Notify_Enable + cleared, then the iSER layer at the target MUST NOT notify the + iSCSI layer on completion and MUST NOT invoke the + Data_Completion_Notify Operational Primitive. + + When the RCaP layer at the initiator receives a valid RDMA Read + Request Message, it will return an RDMA Read Response Message + containing the solicited write data to the target. When the RCaP + layer at the target receives the RDMA Read Response Message from the + initiator, it will place the solicited data in the I/O Buffer + referenced by the Data Sink STag in the RDMA Read Response Message. + + + +Ko & Nezhinsky Standards Track [Page 54] + +RFC 7145 iSER Specification April 2014 + + + Since the RDMA Read Request Message from the target does not transfer + the control information in the R2T PDU such as ExpCmdSN, if timely + updates of such information are crucial, the iSCSI layer at the + initiator MAY issue NOP-Out PDUs to request the iSCSI layer at the + target to respond with the information using NOP-In PDUs. + + Similarly, since the RDMA Read Response Message from the initiator + only transfers the data but not the control information normally + found in the SCSI Data-Out PDU, such as ExpStatSN, if timely updates + of such information are crucial, the iSCSI layer at the target MAY + issue NOP-In PDUs to request the iSCSI layer at the initiator to + respond with the information using NOP-Out PDUs. + +7.3.7. Asynchronous Message + + Type: control-type PDU + + PDU-specific qualifiers: DataDescriptorSense + + The iSCSI layer MUST invoke the Send_Control Operational Primitive + qualified with DataDescriptorSense, which defines the buffer + containing the sense and iSCSI event information. The iSER layer + MUST use a Send Message to send the Asynchronous Message PDU. The + SendSE Message should be used if supported by the RCaP layer (e.g., + iWARP). + +7.3.8. Text Request and Text Response + + Type: control-type PDU + + PDU-specific qualifiers: DataDescriptorTextOut (for Text + Request), DataDescriptorIn (for Text Response) + + The iSCSI layer MUST invoke the Send_Control Operational Primitive + qualified with DataDescriptorTextOut (or DataDescriptorIn), which + defines the Text Request (or Text Response) buffer. The iSER layer + MUST use Send Messages to send the Text Request (or Text Response + PDUs). The SendSE Message should be used if supported by the RCaP + layer (e.g., iWARP). + +7.3.9. Login Request and Login Response + + During the login negotiation, the iSCSI layer interacts with the + transport layer directly, and the iSER layer is not involved. See + Section 5.1 on iSCSI/iSER Connection Setup. If the underlying + transport is TCP, the Login Request PDUs and the Login Response PDUs + are exchanged when the connection between the initiator and the + target is still in the byte stream mode. + + + +Ko & Nezhinsky Standards Track [Page 55] + +RFC 7145 iSER Specification April 2014 + + + The iSCSI layer MUST NOT send a Login Request (or a Login Response) + PDU during the Full Feature Phase. A Login Request (or a Login + Response) PDU, if used, MUST be treated as an iSCSI protocol error. + The iSER layer MAY reject such a PDU from the iSCSI layer with an + appropriate error code. If a Login Request PDU is received by the + iSCSI layer at the target, it MUST respond with a Reject PDU with a + reason code of "protocol error". + +7.3.10. Logout Request and Logout Response + + Type: control-type PDU + + PDU-specific qualifiers: None + + The iSER layer MUST use a Send Message to send the Logout Request or + Logout Response PDU. The SendSE Message should be used if supported + by the RCaP layer (e.g., iWARP). Sections 5.2.1 and 5.2.2 describe + the handling of the Logout Request and the Logout Response at the + initiator and the target and the interactions between the initiator + and the target to terminate a connection. + +7.3.11. SNACK Request + + Since HeaderDigest and DataDigest must be negotiated to "None", there + are no digest errors when the connection is in iSER-assisted mode. + Also, since RCaP delivers all messages in the order they were sent, + there are no sequence errors when the connection is in iSER-assisted + mode. Therefore, the iSCSI layer MUST NOT send SNACK Request PDUs. + A SNACK Request PDU, if used, MUST be treated as an iSCSI protocol + error. The iSER layer MAY reject such a PDU from the iSCSI layer + with an appropriate error code. If a SNACK Request PDU is received + by the iSCSI layer at the target, it MUST respond with a Reject PDU + with a reason code of "protocol error". + +7.3.12. Reject + + Type: control-type PDU + + PDU-specific qualifiers: DataDescriptorReject + + The iSCSI layer MUST invoke the Send_Control Operational Primitive + qualified with DataDescriptorReject, which defines the Reject buffer. + The iSER layer MUST use a Send Message to send the Reject PDU. The + SendSE Message should be used if supported by the RCaP layer (e.g., + iWARP). + + + + + + +Ko & Nezhinsky Standards Track [Page 56] + +RFC 7145 iSER Specification April 2014 + + +7.3.13. NOP-Out and NOP-In + + Type: control-type PDU + + PDU-specific qualifiers: DataDescriptorNOPOut (for NOP-Out), + DataDescriptorNOPIn (for NOP-In) + + The iSCSI layer MUST invoke the Send_Control Operational Primitive + qualified with DataDescriptorNOPOut (or DataDescriptorNOPIn), which + defines the Ping (or Return Ping) data buffer. The iSER layer MUST + use Send Messages to send the NOP-Out (or NOP-In) PDU. The SendSE + Message should be used if supported by the RCaP layer (e.g., iWARP). + +8. Flow Control and STag Management + +8.1. Flow Control for RDMA Send Messages + + Send Messages in RCaP are used by the iSER layer to transfer iSCSI + control-type PDUs. Each Send Message in RCaP consumes an Untagged + Buffer at the Data Sink. However, neither the RCaP layer nor the + iSER layer provides an explicit flow control mechanism for the Send + Messages. Therefore, the iSER layer SHOULD provision enough Untagged + buffers for handling incoming Send Messages to prevent buffer + exhaustion at the RCaP layer. If buffer exhaustion occurs, it may + result in the termination of the connection. + + An implementation may choose to satisfy the buffer requirement by + using a common buffer pool shared across multiple connections, with + usage limits on a per-connection basis and usage limits on the buffer + pool itself. In such an implementation, exceeding the buffer usage + limit for a connection or the buffer pool itself may trigger + interventions from the iSER layer to replenish the buffer pool and/or + to isolate the connection causing the problem. + + iSER also provides the MaxOutstandingUnexpectedPDUs key to be used by + the initiator and the target to declare the maximum number of + outstanding "unexpected" control-type PDUs that it can receive. It + is intended to allow the receiving side to determine the amount of + buffer resources needed beyond the normal flow control mechanism + available in iSCSI. + + The buffer resources required at both the initiator and the target as + a result of control-type PDUs sent by the initiator are described in + Section 8.1.1. The buffer resources required at both the initiator + and target as a result of control-type PDUs sent by the target are + described in Section 8.1.2. + + + + + +Ko & Nezhinsky Standards Track [Page 57] + +RFC 7145 iSER Specification April 2014 + + +8.1.1. Flow Control for Control-Type PDUs from the Initiator + + The control-type PDUs that can be sent by an initiator to a target + can be grouped into the following categories: + + 1. Regulated: Control-type PDUs in this category are regulated by + the iSCSI CmdSN window mechanism, and the immediate flag is not + set. + + 2. Unregulated but Expected: Control-type PDUs in this category are + not regulated by the iSCSI CmdSN window mechanism but are expected + by the target. + + 3. Unregulated and Unexpected: Control-type PDUs in this category + are not regulated by the iSCSI CmdSN window mechanism and are + "unexpected" by the target. + +8.1.1.1. Control-Type PDUs from the Initiator in the Regulated Category + + Control-type PDUs that can be sent by the initiator in this category + are regulated by the iSCSI CmdSN window mechanism, and the immediate + flag is not set. + + The queuing capacity required of the iSCSI layer at the target is + described in Section 4.2.2.1 of [iSCSI]. For each of the control- + type PDUs that can be sent by the initiator in this category, the + initiator MUST provision for the buffer resources required for the + corresponding control-type PDU sent as a response from the target. + The following is a list of the PDUs that can be sent by the initiator + and the PDUs that are sent by the target in response: + + a. When an initiator sends a SCSI Command PDU, it expects a SCSI + Response PDU from the target. + + b. When the initiator sends a Task Management Function Request + PDU, it expects a Task Management Function Response PDU from + the target. + + c. When the initiator sends a Text Request PDU, it expects a Text + Response PDU from the target. + + d. When the initiator sends a Logout Request PDU, it expects a + Logout Response PDU from the target. + + e. When the initiator sends a NOP-Out PDU as a ping request with + ITT != 0xffffffff and TTT = 0xffffffff, it expects a NOP-In PDU + from the target with the same ITT and TTT as in the ping + request. + + + +Ko & Nezhinsky Standards Track [Page 58] + +RFC 7145 iSER Specification April 2014 + + + The response from the target for any of the PDUs enumerated here may + alternatively be in the form of a Reject PDU sent before the task is + active, as described in Section 7.3 of [iSCSI]. + +8.1.1.2. Control-Type PDUs from the Initiator in the Unregulated but + Expected Category + + For the control-type PDUs in the Unregulated but Expected category, + the amount of buffering resources required at the target can be + predetermined. The following is a list of the PDUs in this category: + + a. SCSI Data-Out PDUs are used by the initiator to send + unsolicited data. The amount of buffer resources required by + the target can be determined using FirstBurstLength. Note that + SCSI Data-Out PDUs are not used for solicited data since the + R2T PDU, which is used for solicitation, is transformed into + RDMA Read operations by the iSER layer at the target. See + Section 7.3.4. + + b. A NOP-Out PDU with TTT != 0xffffffff is sent as a ping response + by the initiator to the NOP-In PDU sent as a ping request by + the target. + +8.1.1.3. Control-Type PDUs from the Initiator in the Unregulated and + Unexpected Category + + PDUs in the Unregulated and Unexpected category are PDUs with the + immediate flag set. The number of PDUs that are in this category and + can be sent by an initiator is controlled by the value of + MaxOutstandingUnexpectedPDUs declared by the target. (See Section + 6.7.) After a PDU in this category is sent by the initiator, it is + outstanding until it is retired. At any time, the number of + outstanding unexpected PDUs MUST NOT exceed the value of + MaxOutstandingUnexpectedPDUs declared by the target. + + The target uses the value of MaxOutstandingUnexpectedPDUs that it + declared to determine the amount of buffer resources required for + control-type PDUs in this category that can be sent by an initiator. + For the initiator, for each of the control-type PDUs that can be sent + in this category, the initiator MUST provision for the buffer + resources if required for the corresponding control-type PDU that can + be sent as a response from the target. + + An outstanding PDU in this category is retired as follows. If the + CmdSN of the PDU sent by the initiator in this category is x, the PDU + is outstanding until the initiator sends a non-immediate control-type + + + + + +Ko & Nezhinsky Standards Track [Page 59] + +RFC 7145 iSER Specification April 2014 + + + PDU on the same connection with CmdSN = y (where y is at least x) and + the target responds with a control-type PDU on any connection where + ExpCmdSN is at least y+1. + + When the number of outstanding unexpected control-type PDUs equals + MaxOutstandingUnexpectedPDUs, the iSCSI layer at the initiator MUST + NOT generate any unexpected PDUs, which otherwise it would have + generated, even if the unexpected PDU is intended for immediate + delivery. + +8.1.2. Flow Control for Control-Type PDUs from the Target + + Control-type PDUs that can be sent by a target and are expected by + the initiator are listed in the Regulated category. (See Section + 8.1.1.1.) + + For the control-type PDUs that can be sent by a target and are + unexpected by the initiator, the number is controlled by + MaxOutstandingUnexpectedPDUs declared by the initiator. (See Section + 6.7.) After a PDU in this category is sent by a target, it is + outstanding until it is retired. At any time, the number of + outstanding unexpected PDUs MUST NOT exceed the value of + MaxOutstandingUnexpectedPDUs declared by the initiator. The + initiator uses the value of MaxOutstandingUnexpectedPDUs that it + declared to determine the amount of buffer resources required for + control-type PDUs in this category that can be sent by a target. The + following is a list of the PDUs in this category and the conditions + for retiring the outstanding PDU: + + a. For an Asynchronous Message PDU with StatSN = x, the PDU is + outstanding until the initiator sends a control-type PDU with + ExpStatSN set to at least x+1. + + b. For a Reject PDU with StatSN = x, which is sent after a task is + active, the PDU is outstanding until the initiator sends a + control-type PDU with ExpStatSN set to at least x+1. + + c. For a NOP-In PDU with ITT = 0xffffffff and StatSN = x, the PDU + is outstanding until the initiator responds with a control-type + PDU on the same connection where ExpStatSN is at least x+1. + But if the NOP-In PDU is sent as a ping request with + TTT != 0xffffffff, the PDU can also be retired when the + initiator sends a NOP-Out PDU with the same ITT and TTT as in + the ping request. Note that when a target sends a NOP-In PDU + as a ping request, it must provision a buffer for the NOP-Out + PDU sent as a ping response from the initiator. + + + + + +Ko & Nezhinsky Standards Track [Page 60] + +RFC 7145 iSER Specification April 2014 + + + When the number of outstanding unexpected control-type PDUs equals + MaxOutstandingUnexpectedPDUs, the iSCSI layer at the target MUST NOT + generate any unexpected PDUs, which otherwise it would have + generated, even if its intent is to indicate an iSCSI error condition + (e.g., Asynchronous Message, Reject). Task timeouts, as in the + initiator's waiting for a command completion or other connection and + session-level exceptions, will ensure that correct operational + behavior will result in these cases despite not generating the PDU. + This rule overrides any other requirements elsewhere that require + that a Reject PDU MUST be sent. + + (Implementation note: SCSI task timeout and recovery can be a + lengthy process and hence SHOULD be avoided by proper provisioning of + resources.) + + (Implementation note: To ensure that the initiator has a means to + inform the target that outstanding PDUs have been retired, the target + should reserve the last unexpected control-type PDU allowable by the + value of MaxOutstandingUnexpectedPDUs declared by the initiator for + sending a NOP-In ping request with TTT != 0xffffffff to allow the + initiator to return the NOP-Out ping response with the current + ExpStatSN.) + +8.2. Flow Control for RDMA Read Resources + + If iSERHelloRequired is negotiated to "Yes", then the total number of + RDMA Read operations that can be active simultaneously on an + iSCSI/iSER connection depends on the amount of resources allocated as + declared in the iSER Hello exchange described in Section 5.1.3. + Exceeding the number of RDMA Read operations allowed on a connection + will result in the connection being terminated by the RCaP layer. + The iSER layer at the target maintains the iSER-ORD to keep track of + the maximum number of RDMA Read Requests that can be issued by the + iSER layer on a particular RCaP Stream. + + During connection setup (see Section 5.1), iSER-IRD is known at the + initiator and iSER-ORD is known at the target after the iSER layers + at the initiator and the target have respectively allocated the + connection resources necessary to support RCaP, as directed by the + Allocate_Connection_Resources Operational Primitive from the iSCSI + layer before the end of the iSCSI Login Phase. In the Full Feature + Phase, if iSERHelloRequired is negotiated to "Yes", then the first + message sent by the initiator is the iSER Hello Message (see Section + 9.3), which contains the value of iSER-IRD. In response to the iSER + Hello Message, the target sends the iSER HelloReply Message (see + Section 9.4), which contains the value of iSER-ORD. The iSER layer + at both the initiator and the target MAY adjust (lower) the resources + associated with iSER-IRD and iSER-ORD, respectively, to match the + + + +Ko & Nezhinsky Standards Track [Page 61] + +RFC 7145 iSER Specification April 2014 + + + iSER-ORD value declared in the HelloReply Message. The iSER layer at + the target MUST control the flow of the RDMA Read Request Messages so + that it does not exceed the iSER-ORD value at the target. + + If iSERHelloRequired is negotiated to "No", then the maximum number + of RDMA Read operations that can be active is negotiated via other + means outside the scope of this document. For example, in + InfiniBand, iSER connection setup uses InfiniBand Connection Manager + (CM) Management Datagrams (MADs), with additional iSER information + exchanged in the private data. + +8.3. STag Management + + An STag is an identifier of a Tagged Buffer used in an RDMA + operation. If the STags are exposed on the wire by being Advertised + in the iSER header or declared in the header of an RCaP Message, then + the allocation and the subsequent invalidation of the STags are as + specified in this document. + +8.3.1. Allocation of STags + + When the iSCSI layer at the initiator invokes the Send_Control + Operational Primitive to request the iSER layer at the initiator to + process a SCSI Command, zero, one, or two STags may be allocated by + the iSER layer. See Section 7.3.1 for details. The number of STags + allocated depends on whether the command is unidirectional or + bidirectional and whether or not solicited write data transfer is + involved. + + When the iSCSI layer at the initiator invokes the Send_Control + Operational Primitive to request the iSER layer at the initiator to + process a Task Management Function Request with the TASK REASSIGN + function, besides allocating zero, one, or two STags, the iSER layer + MUST invalidate the existing STags (if any) associated with the ITT. + See Section 7.3.3 for details. + + The iSER layer at the target allocates a local Data Sink STag when + the iSCSI layer at the target invokes the Get_Data Operational + Primitive to request the iSER layer to process an R2T PDU. See + Section 7.3.6 for details. + +8.3.2. Invalidation of STags + + The invalidation of the STags at the initiator at the completion of a + unidirectional or bidirectional command when the associated SCSI + Response PDU is sent by the target is described in Section 7.3.2. + + + + + +Ko & Nezhinsky Standards Track [Page 62] + +RFC 7145 iSER Specification April 2014 + + + When a unidirectional or bidirectional command concludes without the + associated SCSI Response PDU being sent by the target, the iSCSI + layer at the initiator MUST request the iSER layer at the initiator + to invalidate the STags by invoking the Deallocate_Task_Resources + Operational Primitive qualified with ITT. In response, the iSER + layer at the initiator MUST locate the STags (if any) in the Local + Mapping. The iSER layer at the initiator MUST invalidate the STags + (if any) and the Local Mapping. + + For an RDMA Read operation used to realize a SCSI Write data + transfer, the iSER layer at the target SHOULD invalidate the Data + Sink STag at the conclusion of the RDMA Read operation referencing + the Data Sink STag (to permit the immediate reuse of buffer + resources). + + For an RDMA Write operation used to realize a SCSI Read data + transfer, the Data Source STag at the target is not declared to the + initiator and is not exposed on the wire. Invalidation of the STag + is thus not specified. + + When a unidirectional or bidirectional command concludes without the + associated SCSI Response PDU being sent by the target, the iSCSI + layer at the target MUST request the iSER layer at the target to + invalidate the STags by invoking the Deallocate_Task_Resources + Operational Primitive qualified with ITT. In response, the iSER + layer at the target MUST locate the local STags (if any) in the Local + Mapping. The iSER layer at the target MUST invalidate the local + STags (if any) and the Local Mapping. + + + + + + + + + + + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 63] + +RFC 7145 iSER Specification April 2014 + + +9. iSER Control and Data Transfer + + For iSCSI data-type PDUs (see Section 7.1), the iSER layer uses RDMA + Read and RDMA Write operations to transfer the solicited data. For + iSCSI control-type PDUs (see Section 7.2), the iSER layer uses Send + Messages of RCaP. + +9.1. iSER Header Format + + An iSER header MUST be present in every Send Message of RCaP. The + iSER header is located in the first 28 bytes of the message payload + of the Send Message of RCaP, as shown in Figure 2. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Opcode| Opcode Specific Fields | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Opcode Specific Fields (32 bits) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Opcode Specific Fields (64 bits) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Opcode Specific Fields (32 bits) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Opcode Specific Fields (64 bits) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 2: iSER Header Format + + Opcode - Operation Code: 4 bits + + The Opcode field identifies the type of iSER Messages: + + 0001b = iSCSI control-type PDU + + 0010b = iSER Hello Message + + 0011b = iSER HelloReply Message + + All other Opcodes are unassigned. + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 64] + +RFC 7145 iSER Specification April 2014 + + +9.2. iSER Header Format for iSCSI Control-Type PDU + + The iSER layer uses Send Messages of RCaP to transfer iSCSI control- + type PDUs (see Section 7.2). The message payload of each of the Send + Messages of RCaP used for transferring an iSER Message contains an + iSER Header followed by an iSCSI control-type PDU. + + The iSER header in a Send Message of RCaP carrying an iSCSI control- + type PDU MUST have the format as described in Figure 3. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | |W|R| | + | 0001b |S|S| Reserved | + | |V|V| | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Write STag | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Write Base Offset | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Read STag | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Read Base Offset | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 3: iSER Header Format for iSCSI Control-Type PDU + + WSV - Write STag Valid flag: 1 bit + + This flag indicates the validity of the Write STag field and the + Write Base Offset field of the iSER Header. If set to one, the + Write STag field and the Write Base Offset field in this iSER + Header are valid. If set to zero, the Write STag field and the + Write Base Offset field in this iSER Header MUST be ignored at the + receiver. The Write STag Valid flag is set to one when there is + solicited data to be transferred for a SCSI Write or bidirectional + command, or when there are non-immediate unsolicited and solicited + data to be transferred for the referenced task specified in a Task + Management Function Request with the TASK REASSIGN function. + + RSV - Read STag Valid flag: 1 bit + + This flag indicates the validity of the Read STag field and the + Read Base Offset field of the iSER Header. If set to one, the + Read STag field and the Read Base Offset field in this iSER Header + + + +Ko & Nezhinsky Standards Track [Page 65] + +RFC 7145 iSER Specification April 2014 + + + are valid. If set to zero, the Read STag field and the Read Base + Offset field in this iSER Header MUST be ignored at the receiver. + The Read STag Valid flag is set to one for a SCSI Read or + bidirectional command, or a Task Management Function Request with + the TASK REASSIGN function. + + Write STag - Write Steering Tag: 32 bits + + This field contains the Write STag when the Write STag Valid flag + is set to one. For a SCSI Write or bidirectional command, the + Write STag is used to Advertise the initiator's I/O Buffer + containing the solicited data. For a Task Management Function + Request with the TASK REASSIGN function, the Write STag is used to + Advertise the initiator's I/O Buffer containing the non-immediate + unsolicited data and solicited data. This Write STag is used as + the Data Source STag in the resultant RDMA Read operation(s). + When the Write STag Valid flag is set to zero, this field MUST be + set to zero and ignored on receive. + + Write Base Offset: 64 bits + + This field contains the Base Offset associated with the I/O Buffer + for the SCSI Write command when the Write STag Valid flag is set + to one. When the Write STag Valid flag is set to zero, this field + MUST be set to zero and ignored on receive. + + Read STag - Read Steering Tag: 32 bits + + This field contains the Read STag when the Read STag Valid flag is + set to one. The Read STag is used to Advertise the initiator's + Read I/O Buffer of a SCSI Read or bidirectional command, or a Task + Management Function Request with the TASK REASSIGN function. This + Read STag is used as the Data Sink STag in the resultant RDMA + Write operation(s). When the Read STag Valid flag is zero, this + field MUST be set to zero and ignored on receive. + + Read Base Offset: 64 bits + + This field contains the Base Offset associated with the I/O Buffer + for the SCSI Read command when the Read STag Valid flag is set to + one. When the Read STag Valid flag is set to zero, this field + MUST be set to zero and ignored on receive. + + Reserved: + + Reserved fields MUST be set to zero on transmit and MUST be + ignored on receive. + + + + +Ko & Nezhinsky Standards Track [Page 66] + +RFC 7145 iSER Specification April 2014 + + +9.3. iSER Header Format for iSER Hello Message + + An iSER Hello Message MUST only contain the iSER header, which MUST + have the format as described in Figure 4. If iSERHelloRequired is + negotiated to "Yes", then iSER Hello Message is the first iSER + Message sent on the RCaP Stream from the iSER layer at the initiator + to the iSER layer at the target. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | | | | | + | 0010b | Rsvd | MaxVer| MinVer| iSER-IRD | + | | | | | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 4: iSER Header Format for iSER Hello Message + + MaxVer - Maximum Version: 4 bits + + This field specifies the maximum version of the iSER protocol + supported. It MUST be set to 10 to indicate the version of the + specification described in this document. + + MinVer - Minimum Version: 4 bits + + This field specifies the minimum version of the iSER protocol + supported. It MUST be set to 10 to indicate the version of the + specification described in this document. + + iSER-IRD: 16 bits + + This field contains the value of the iSER-IRD at the initiator. + + Reserved (Rsvd): + + Reserved fields MUST be set to zero on transmit and MUST be + ignored on receive. + + + +Ko & Nezhinsky Standards Track [Page 67] + +RFC 7145 iSER Specification April 2014 + + +9.4. iSER Header Format for iSER HelloReply Message + + An iSER HelloReply Message MUST only contain the iSER header, which + MUST have the format as described in Figure 5. If iSERHelloRequired + is negotiated to "Yes", then the iSER HelloReply Message is the first + iSER Message sent on the RCaP Stream from the iSER layer at the + target to the iSER layer at the initiator. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | |R| | | | + | 0011b |Rsvd |E| MaxVer| CurVer| iSER-ORD | + | | |J| | | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 5: iSER Header Format for iSER HelloReply Message + + REJ - Reject flag: 1 bit + + This flag indicates whether the target is rejecting this + connection. If set to one, the target is rejecting the + connection. + + MaxVer - Maximum Version: 4 bits + + This field specifies the maximum version of the iSER protocol + supported. It MUST be set to 10 to indicate the version of the + specification described in this document. + + CurVer - Current Version: 4 bits + + This field specifies the current version of the iSER protocol + supported. It MUST be set to 10 to indicate the version of the + specification described in this document. + + + + + + +Ko & Nezhinsky Standards Track [Page 68] + +RFC 7145 iSER Specification April 2014 + + + iSER-ORD: 16 bits + + This field contains the value of the iSER-ORD at the target. + + Reserved (Rsvd): + + Reserved fields MUST be set to zero on transmit and MUST be + ignored on receive. + +9.5. SCSI Data Transfer Operations + + The iSER layer at the initiator and the iSER layer at the target + handle each SCSI Write, SCSI Read, and bidirectional operation as + described below. + +9.5.1. SCSI Write Operation + + The iSCSI layer at the initiator MUST invoke the Send_Control + Operational Primitive to request the iSER layer at the initiator to + send the SCSI Write Command. The iSER layer at the initiator MUST + request the RCaP layer to transmit a Send Message with the message + payload consisting of the iSER header followed by the SCSI Command + PDU and immediate data (if any). The SendSE Message should be used + if supported by the RCaP layer (e.g., iWARP). If there is solicited + data, the iSER layer MUST Advertise the Write STag and the Base + Offset in the iSER header of the Send Message, as described in + Section 9.2. Upon receiving the Send Message, the iSER layer at the + target MUST notify the iSCSI layer at the target by invoking the + Control_Notify Operational Primitive qualified with the SCSI Command + PDU. See Section 7.3.1 for details on the handling of the SCSI Write + Command. + + For the non-immediate unsolicited data, the iSCSI layer at the + initiator MUST invoke a Send_Control Operational Primitive qualified + with the SCSI Data-Out PDU. Upon receiving each Send Message + containing the non-immediate unsolicited data, the iSER layer at the + target MUST notify the iSCSI layer at the target by invoking the + Control_Notify Operational Primitive qualified with the SCSI Data-Out + PDU. See Section 7.3.4 for details on the handling of the SCSI Data- + Out PDU. + + For the solicited data, when the iSCSI layer at the target has an I/O + Buffer available, it MUST invoke the Get_Data Operational Primitive + qualified with the R2T PDU. See Section 7.3.6 for details on the + handling of the R2T PDU. + + + + + + +Ko & Nezhinsky Standards Track [Page 69] + +RFC 7145 iSER Specification April 2014 + + + When the data transfer associated with this SCSI Write operation is + complete, the iSCSI layer at the target MUST invoke the Send_Control + Operational Primitive when it is ready to send the SCSI Response PDU. + Upon receiving a Send Message containing the SCSI Response PDU, the + iSER layer at the initiator MUST notify the iSCSI layer at the + initiator by invoking the Control_Notify Operational Primitive + qualified with the SCSI Response PDU. See Section 7.3.2 for details + on the handling of the SCSI Response PDU. + +9.5.2. SCSI Read Operation + + The iSCSI layer at the initiator MUST invoke the Send_Control + Operational Primitive to request the iSER layer at the initiator to + send the SCSI Read Command. The iSER layer at the initiator MUST + request the RCaP layer to transmit a Send Message with the message + payload consisting of the iSER header followed by the SCSI Command + PDU. The SendSE Message should be used if supported by the RCaP + layer (e.g., iWARP). The iSER layer at the initiator MUST Advertise + the Read STag and the Base Offset in the iSER header of the Send + Message, as described in Section 9.2. Upon receiving the Send + Message, the iSER layer at the target MUST notify the iSCSI layer at + the target by invoking the Control_Notify Operational Primitive + qualified with the SCSI Command PDU. See Section 7.3.1 for details + on the handling of the SCSI Read Command. + + When the requested SCSI data is available in the I/O Buffer, the + iSCSI layer at the target MUST invoke the Put_Data Operational + Primitive qualified with the SCSI Data-In PDU. See Section 7.3.5 for + details on the handling of the SCSI Data-In PDU. + + When the data transfer associated with this SCSI Read operation is + complete, the iSCSI layer at the target MUST invoke the Send_Control + Operational Primitive when it is ready to send the SCSI Response PDU. + The SendInvSE Message should be used if supported by the RCaP layer + (e.g., iWARP). Upon receiving the Send Message containing the SCSI + Response PDU, the iSER layer at the initiator MUST notify the iSCSI + layer at the initiator by invoking the Control_Notify Operational + Primitive qualified with the SCSI Response PDU. See Section 7.3.2 + for details on the handling of the SCSI Response PDU. + +9.5.3. Bidirectional Operation + + The initiator and the target handle the SCSI Write and the SCSI Read + portions of this bidirectional operation the same as described in + Sections 9.5.1 and 9.5.2, respectively. + + + + + + +Ko & Nezhinsky Standards Track [Page 70] + +RFC 7145 iSER Specification April 2014 + + +10. iSER Error Handling and Recovery + + RCaP provides the iSER layer with reliable in-order delivery. + Therefore, the error management needs of an iSER-assisted connection + are somewhat different than those of a Traditional iSCSI connection. + +10.1. Error Handling + + iSER error handling is described in the following sections, + classified loosely based on the sources of errors: + + 1. Those originating at the transport layer (e.g., TCP). + + 2. Those originating at the RCaP layer. + + 3. Those originating at the iSER layer. + + 4. Those originating at the iSCSI layer. + +10.1.1. Errors in the Transport Layer + + If the transport layer is TCP, then TCP packets with detected errors + are silently dropped by the TCP layer and result in retransmission at + the TCP layer. This has no impact on the iSER layer. However, + connection loss (e.g., link failure) and unexpected termination + (e.g., TCP graceful or abnormal close without the iSCSI Logout + exchanges) at the transport layer will cause the iSCSI/iSER + connection to be terminated as well. + +10.1.1.1. Failure in the Transport Layer Before RCaP Mode is Enabled + + If the connection is lost or terminated before the iSCSI layer + invokes the Allocate_Connection_Resources Operational Primitive, the + login process is terminated and no further action is required. + + If the connection is lost or terminated after the iSCSI layer has + invoked the Allocate_Connection_Resources Operational Primitive, then + the iSCSI layer MUST request the iSER layer to deallocate all + connection resources by invoking the Deallocate_Connection_Resources + Operational Primitive. + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 71] + +RFC 7145 iSER Specification April 2014 + + +10.1.1.2. Failure in the Transport Layer After RCaP Mode is Enabled + + If the connection is lost or terminated after the iSCSI layer has + invoked the Enable_Datamover Operational Primitive, the iSER layer + MUST notify the iSCSI layer of the connection loss by invoking the + Connection_Terminate_Notify Operational Primitive. Prior to invoking + the Connection_Terminate_Notify Operational Primitive, the iSER layer + MUST perform the actions described in Section 5.2.3.2. + +10.1.2. Errors in the RCaP Layer + + The RCaP layer does not have error recovery operations built in. If + errors are detected at the RCaP layer, the RCaP layer will terminate + the RCaP Stream and the associated connection. + +10.1.2.1. Errors Detected in the Local RCaP Layer + + If an error is encountered at the local RCaP layer, the RCaP layer + MAY send a Send Message to the Remote Peer to report the error if + possible. (For iWARP, see [RDMAP] for the list of errors where a + Terminate Message is sent.) The RCaP layer is responsible for + terminating the connection. After the RCaP layer notifies the iSER + layer that the connection is terminated, the iSER layer MUST notify + the iSCSI layer by invoking the Connection_Terminate_Notify + Operational Primitive. Prior to invoking the + Connection_Terminate_Notify Operational Primitive, the iSER layer + MUST perform the actions described in Section 5.2.3.2. + +10.1.2.2. Errors Detected in the RCaP Layer at the Remote Peer + + If an error is encountered at the RCaP layer at the Remote Peer, the + RCaP layer at the Remote Peer may send a Send Message to report the + error if possible. If it is unable to send a Send Message, the + connection is terminated. This is treated the same as a failure in + the transport layer after RDMA is enabled, as described in Section + 10.1.1.2. + + If an error is encountered at the RCaP layer at the Remote Peer and + it is able to send a Send Message, the RCaP layer at the Remote Peer + is responsible for terminating the connection. After the local RCaP + layer notifies the iSER layer that the connection is terminated, the + iSER layer MUST notify the iSCSI layer by invoking the + Connection_Terminate_Notify Operational Primitive. Prior to invoking + the Connection_Terminate_Notify Operational Primitive, the iSER layer + MUST perform the actions described in Section 5.2.3.2. + + + + + + +Ko & Nezhinsky Standards Track [Page 72] + +RFC 7145 iSER Specification April 2014 + + +10.1.3. Errors in the iSER Layer + + The error handling due to errors at the iSER layer is described in + the following sections. + +10.1.3.1. Insufficient Connection Resources to Support RCaP at + Connection Setup + + After the iSCSI layer at the initiator invokes the + Allocate_Connection_Resources Operational Primitive during the iSCSI + login negotiation phase, if the iSER layer at the initiator fails to + allocate the connection resources necessary to support RCaP, it MUST + return a status of failure to the iSCSI layer at the initiator. The + iSCSI layer at the initiator MUST terminate the connection as + described in Section 5.2.3.1. + + After the iSCSI layer at the target invokes the + Allocate_Connection_Resources Operational Primitive during the iSCSI + login negotiation phase, if the iSER layer at the target fails to + allocate the connection resources necessary to support RCaP, it MUST + return a status of failure to the iSCSI layer at the target. The + iSCSI layer at the target MUST send a Login Response with a Status- + Class of 0x03 (Target Error), and a Status-Code of 0x02 (Out of + Resources). The iSCSI layers at the initiator and the target MUST + terminate the connection as described in Section 5.2.3.1. + +10.1.3.2. iSER Negotiation Failures + + If iSERHelloRequired is negotiated to "Yes" and the RCaP or iSER + related parameters declared by the initiator in the iSER Hello + Message are unacceptable to the iSER layer at the target, the iSER + layer at the target MUST set the Reject (REJ) flag, as described in + Section 9.4, in the iSER HelloReply Message. The following are the + cases when the iSER layer MUST set the REJ flag to 1 in the + HelloReply Message: + + * The initiator-declared iSER-IRD value is greater than 0, and the + target-declared iSER-ORD value is 0. + + * The initiator-supported and the target-supported iSER protocol + versions do not overlap. + + After requesting the RCaP layer to send the iSER HelloReply Message, + the handling of the error situation is the same as that for iSER + format errors as described in Section 10.1.3.3. + + + + + + +Ko & Nezhinsky Standards Track [Page 73] + +RFC 7145 iSER Specification April 2014 + + +10.1.3.3. iSER Format Errors + + The following types of errors in an iSER header are considered format + errors: + + * Illegal contents of any iSER header field + + * Inconsistent field contents in an iSER header + + * Length error for an iSER Hello or HelloReply Message (see Sections + 9.3 and 9.4) + + When a format error is detected, the following events MUST occur in + the specified sequence: + + 1. The iSER layer MUST request the RCaP layer to terminate the RCaP + Stream. The RCaP layer MUST terminate the associated connection. + + 2. The iSER layer MUST notify the iSCSI layer of the connection + termination by invoking the Connection_Terminate_Notify + Operational Primitive. Prior to invoking the + Connection_Terminate_Notify Operational Primitive, the iSER layer + MUST perform the actions described in Section 5.2.3.2. + +10.1.3.4. iSER Protocol Errors + + If iSERHelloRequired is negotiated to "Yes", then the first iSER + Message sent by the iSER layer at the initiator MUST be the iSER + Hello Message (see Section 9.3). In this case the first iSER Message + sent by the iSER layer at the target MUST be the iSER HelloReply + Message (see Section 9.4). Failure to send the iSER Hello or + HelloReply Message, as indicated by the wrong Opcode in the iSER + header, is a protocol error. Conversely, if the iSER Hello Message + is sent by the iSER layer at the initiator when iSERHelloRequired is + negotiated to "No", the iSER layer at the target MAY treat this as a + protocol error or respond with an iSER HelloReply Message. The + handling of iSER protocol errors is the same as that for iSER format + errors as described in Section 10.1.3.3. + + If the sending side of an iSER-enabled connection acts in a manner + not permitted by the negotiated or declared login/text operational + key values as described in Section 6, this is a protocol error and + the receiving side MAY handle this the same as for iSER format errors + as described in Section 10.1.3.3. + + + + + + + +Ko & Nezhinsky Standards Track [Page 74] + +RFC 7145 iSER Specification April 2014 + + +10.1.4. Errors in the iSCSI Layer + + The error handling due to errors at the iSCSI layer is described in + the following sections. For error recovery, see Section 10.2. + +10.1.4.1. iSCSI Format Errors + + When an iSCSI format error is detected, the iSCSI layer MUST request + the iSER layer to terminate the RCaP Stream by invoking the + Connection_Terminate Operational Primitive. For more details on + connection termination, see Section 5.2.3.1. + +10.1.4.2. iSCSI Digest Errors + + In the iSER-assisted mode, the iSCSI layer will not see any digest + error because both the HeaderDigest and the DataDigest keys are + negotiated to "None". + +10.1.4.3. iSCSI Sequence Errors + + For Traditional iSCSI, sequence errors are caused by dropped PDUs due + to header or data digest errors. Since digests are not used in iSER- + assisted mode and the RCaP layer will deliver all messages in the + order they were sent, sequence errors will not occur in iSER-assisted + mode. + +10.1.4.4. iSCSI Protocol Error + + When the iSCSI layer handles certain protocol errors by dropping the + connection, the error handling is the same as that for iSCSI format + errors as described in Section 10.1.4.1. + + When the iSCSI layer uses the iSCSI Reject PDU and response codes to + handle certain other protocol errors, no special handling at the iSER + layer is required. + +10.1.4.5. SCSI Timeouts and Session Errors + + This is handled at the iSCSI layer, and no special handling at the + iSER layer is required. + +10.1.4.6. iSCSI Negotiation Failures + + For negotiation failures that happen during the Login Phase at the + initiator after the iSCSI layer has invoked the + Allocate_Connection_Resources Operational Primitive and before the + Enable_Datamover Operational Primitive has been invoked, the iSCSI + layer MUST request the iSER layer to deallocate all connection + + + +Ko & Nezhinsky Standards Track [Page 75] + +RFC 7145 iSER Specification April 2014 + + + resources by invoking the Deallocate_Connection_Resources Operational + Primitive. The iSCSI layer at the initiator MUST terminate the + connection. + + For negotiation failures during the Login Phase at the target, the + iSCSI layer can use a Login Response with a Status-Class other than 0 + (success) to terminate the Login Phase. If the iSCSI layer has + invoked the Allocate_Connection_Resources Operational Primitive and + has not yet invoked the Enable_Datamover Operational Primitive, the + iSCSI layer at the target MUST request the iSER layer at the target + to deallocate all connection resources by invoking the + Deallocate_Connection_Resources Operational Primitive. The iSCSI + layer at both the initiator and the target MUST terminate the + connection. + + During the iSCSI Login Phase, if the iSCSI layer at the initiator + receives a Login Response from the target with a Status-Class other + than 0 (Success) after the iSCSI layer at the initiator has invoked + the Allocate_Connection_Resources Operational Primitive, the iSCSI + layer MUST request the iSER layer to deallocate all connection + resources by invoking the Deallocate_Connection_Resources Operational + Primitive. The iSCSI layer MUST terminate the connection in this + case. + + For negotiation failures during the Full Feature Phase, the error + handling is left to the iSCSI layer and no special handling at the + iSER layer is required. + +10.2. Error Recovery + + Error recovery requirements of iSCSI/iSER are the same as that of + Traditional iSCSI. All three ErrorRecoveryLevels as defined in + [iSCSI] are supported in iSCSI/iSER. + + * For ErrorRecoveryLevel 0, session recovery is handled by iSCSI and + no special handling by the iSER layer is required. + + * For ErrorRecoveryLevel 1, see Section 10.2.1 on PDU Recovery. + + * For ErrorRecoveryLevel 2, see Section 10.2.2 on Connection + Recovery. + + The iSCSI layer may invoke the Notice_Key_Values Operational + Primitive during connection setup to request the iSER layer to take + note of the value of the operational ErrorRecoveryLevel, as described + in Sections 5.1.1 and 5.1.2. + + + + + +Ko & Nezhinsky Standards Track [Page 76] + +RFC 7145 iSER Specification April 2014 + + +10.2.1. PDU Recovery + + As described in Sections 10.1.4.2 and 10.1.4.3, digest and sequence + errors will not occur in the iSER-assisted mode. If the RCaP layer + detects an error, it will close the iSCSI/iSER connection, as + described in Section 10.1.2. Therefore, PDU recovery is not useful + in the iSER-assisted mode. + + The iSCSI layer at the initiator SHOULD disable iSCSI timeout-driven + PDU retransmissions. + +10.2.2. Connection Recovery + + The iSCSI layer at the initiator MAY reassign connection allegiance + for non-immediate commands that are still in progress and are + associated with the failed connection by using a Task Management + Function Request with the TASK REASSIGN function. See Section 7.3.3 + for more details. + + When the iSCSI layer at the initiator does a task reassignment for a + SCSI Write command, it MUST qualify the Send_Control Operational + Primitive invocation with DataDescriptorOut, which defines the I/O + Buffer for both the non-immediate unsolicited data and the solicited + data. This allows the iSCSI layer at the target to use recovery R2Ts + to request data originally sent as unsolicited and solicited from the + initiator. + + When the iSCSI layer at the target accepts a reassignment request for + a SCSI Read command, it MUST request the iSER layer to process SCSI + Data-In for all unacknowledged data by invoking the Put_Data + Operational Primitive. See Section 7.3.5 on the handling of SCSI + Data-In. + + When the iSCSI layer at the target accepts a reassignment request for + a SCSI Write command, it MUST request the iSER layer to process a + recovery R2T for any non-immediate unsolicited data and any solicited + data sequences that have not been received by invoking the Get_Data + Operational Primitive. See Section 7.3.6 on the handling of Ready To + Transfer (R2T). + + The iSCSI layer at the target MUST NOT issue recovery R2Ts on an + iSCSI/iSER connection for a task for which the connection allegiance + was never reassigned. The iSER layer at the target MAY reject such a + recovery R2T received via the Get_Data Operational Primitive + invocation from the iSCSI layer at the target, with an appropriate + error code. + + + + + +Ko & Nezhinsky Standards Track [Page 77] + +RFC 7145 iSER Specification April 2014 + + + The iSER layer at the target will process the requests invoked by the + Put_Data and Get_Data Operational Primitives for a reassigned task in + the same way as for the original commands. + +11. Security Considerations + + When iSER is layered on top of an RCaP layer and provides the RDMA + extensions to the iSCSI protocol, the security considerations of iSER + are the same as that of the underlying RCaP layer. For iWARP, this + is described in [RDMAP] and [RDDPSEC], plus the updates to both of + those RFCs that are contained in [IPSEC-IPS]. + + Since iSER-assisted iSCSI protocol is still functionally iSCSI from a + security considerations perspective, all of the iSCSI security + requirements as described in [iSCSI] apply. If iSER is layered on + top of a non-IP-based RCaP layer, all the security protocol + mechanisms applicable to that RCaP layer are also applicable to an + iSCSI/iSER connection. If iSER is layered on top of a non-IP + protocol, the IPsec mechanism as specified in [iSCSI] MUST be + implemented at any point where the iSER protocol enters the IP + network (e.g., via gateways), and the non-IP protocol SHOULD + implement (optional to use) a packet-by-packet security protocol + equal in strength to the IPsec mechanism specified by [iSCSI]. + + In order to protect target RCaP connection resources from possible + resource exhaustion attacks, allocation of such resources for a new + connection MUST be delayed until it is reasonably certain that the + new connection is not part of a resource exhaustion attack (e.g., + until after the SecurityNegotiation stage of Login); see Section + 5.1.2. + + A valid STag exposes I/O Buffer resources to the network for access + via the RCaP. The security measures for the RCAP and iSER described + in the above paragraphs can be used to protect data in an I/O buffer + from undesired disclosure or modification, and these measures are of + heightened importance for implementations that retain (e.g., cache) + STags for use in multiple tasks (e.g., iSCSI I/O operations) because + the resources are exposed to the network for a longer period of time. + + A complementary means of controlling I/O Buffer resource exposure is + invalidation of the STag after completion of the associated task, as + specified in Section 1.5.1. The use of Send with Invalidate messages + (which cause remote STag invalidation) is OPTIONAL, therefore the + iSER layer MUST NOT rely on use of a Send with Invalidate by its + Remote Peer to cause local STag invalidation. If an STag is expected + to be invalid after completion of a task, the iSER layer MUST check + the STag and invalidate it if it is still valid. + + + + +Ko & Nezhinsky Standards Track [Page 78] + +RFC 7145 iSER Specification April 2014 + + +12. IANA Considerations + + IANA has added the following entries to the "iSCSI Login/Text Keys" + registry: + + MaxAHSLength, RFC 7145 + + TaggedBufferForSolicitedDataOnly, RFC 7145 + + iSERHelloRequired, RFC 7145 + + IANA has updated the following entries in the "iSCSI Login/Text Keys" + registry to reference this RFC. + + InitiatorRecvDataSegmentLength + + MaxOutstandingUnexpectedPDUs + + RDMAExtensions + + TargetRecvDataSegmentLength + + IANA has also changed the reference to RFC 5046 for the "iSCSI + Login/Text Keys" registry to refer to this RFC. + + IANA has updated the registrations of the iSER Opcodes 1-3 in the + "iSER Opcodes" registry to reference this RFC. IANA has also changed + the reference to RFC 5046 for the "iSER Opcodes" registry to refer to + this RFC. + +13. References + +13.1. Normative References + + [RFC5046] Ko, M., Chadalapaka, M., Hufferd, J., Elzur, U., Shah, + H., and P. Thaler, "Internet Small Computer System + Interface (iSCSI) Extensions for Remote Direct Memory + Access (RDMA)", RFC 5046, October 2007. + + [iSCSI] Chadalapaka, M., Satran, J., Meth, K., and D. Black, + "Internet Small Computer System Interface (iSCSI) + Protocol (Consolidated)", RFC 7143, April 2014. + + [RDMAP] Recio, R., Metzler, B., Culley, P., Hilland, J., and D. + Garcia, "A Remote Direct Memory Access Protocol + Specification", RFC 5040, October 2007. + + + + + +Ko & Nezhinsky Standards Track [Page 79] + +RFC 7145 iSER Specification April 2014 + + + [DDP] Shah, H., Pinkerton, J., Recio, R., and P. Culley, + "Direct Data Placement over Reliable Transports", RFC + 5041, October 2007. + + [MPA] Culley, P., Elzur, U., Recio, R., Bailey, S., and J. + Carrier, "Marker PDU Aligned Framing for TCP + Specification", RFC 5044, October 2007. + + [RDDPSEC] Pinkerton, J. and E. Deleganes, "Direct Data Placement + Protocol (DDP) / Remote Direct Memory Access Protocol + (RDMAP) Security", RFC 5042, October 2007. + + [TCP] Postel, J., "Transmission Control Protocol", STD 7, RFC + 793, September 1981. + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, March 1997. + + [IPSEC-IPS] Black, D. and P. Koning, "Securing Block Storage + Protocols over IP: RFC 3723 Requirements Update for IPsec + v3", RFC 7146, April 2014. + +13.2. Informative References + + [SAM5] INCITS Technical Committee T10, "SCSI Architecture Model + - 5 (SAM-5)", T10/BSR INCITS 515 rev 04, Committee Draft. + + [iSCSI-SAM] Knight, F. and M. Chadalapaka, "Internet Small Computer + System Interface (iSCSI) SCSI Features Update", RFC 7144, + April 2014. + + [DA] Chadalapaka, M., Hufferd, J., Satran, J., and H. Shah, + "DA: Datamover Architecture for the Internet Small + Computer System Interface (iSCSI)", RFC 5047, October + 2007. + + [IB] InfiniBand Architecture Specification Volume 1 Release + 1.2, October 2004 + + [IPoIB] Chu, J. and V. Kashyap, "Transmission of IP over + InfiniBand (IPoIB)", RFC 4391, April 2006. + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 80] + +RFC 7145 iSER Specification April 2014 + + +Appendix A. Summary of Changes from RFC 5046 + + All changes are backward compatible with RFC 5046 except for item #8, + which reflects all known implementations of iSER, each of which has + implemented this change, despite its absence in RFC 5046. As a + result, a hypothetical implementation based on RFC 5046 will not + interoperate with an implementation based on this version of the + specification. + + 1. Removed the requirement that a connection be opened in "normal" + TCP mode and transitioned to zero-copy mode. This allows the + specification to conform to existing implementations for both + InfiniBand and iWARP. Changes were made in Sections 1, 3.1.6, + 4.2, 5.1, 5.1.1, 5.1.2, 5.1.3, 10.1.3.4, and 11. + + 2. Added a clause in Section 6.2 to clarify that + MaxRecvDataSegmentLength must be ignored if it is declared in the + Login Phase. + + 3. Added a clause in Section 6.2 to clarify that the initiator must + not send more than InitiatorMaxRecvDataSegmentLength worth of + data when a NOP-Out request is sent with a valid Initiator Task + Tag. Since InitiatorMaxRecvDataSegmentLength can be smaller than + TargetMaxRecvDataSegmentLength, returning the original data in + the NOP-Out request in this situation can overflow the receive + buffer unless the length of the data sent with the NOP-Out + request is less than InitiatorMaxRecvDataSegmentLength. + + 4. Added a SHOULD negotiate recommendation for + MaxOutstandingUnexpectedPDUs in Section 6.7. + + 5. Added MaxAHSLength key in Section 6.8 to set a limit on the AHS + Length. This is useful when posting receive buffers in knowing + what the maximum possible message length is in a PDU that + contains AHS. + + 6. Added TaggedBufferForSolicitedDataOnly key in Section 6.9 to + indicate how the memory region will be used. An initiator can + treat the memory regions intended for unsolicited and solicited + data differently and can use different registration modes. In + contrast, RFC 5046 treats the memory occupied by the data as a + contiguous (or virtually contiguous, by means of scatter-gather + mechanisms) and homogenous region. Adding a new key will allow + different memory models to be accommodated. Changes were also + made in Section 7.3.1. + + + + + + +Ko & Nezhinsky Standards Track [Page 81] + +RFC 7145 iSER Specification April 2014 + + + 7. Added iSERHelloRequired key in Section 6.10 to allow an initiator + to allocate connection resources after the login process by + requiring the use of the iSER Hello messages before sending iSCSI + PDUs. The default is "No" since iSER Hello messages have not + been implemented and are not in use. Changes were made in + Sections 5.1.1, 5.1.2, 5.1.3, 8.2, 9.3, 9.4, 10.1.3.2, and + 10.1.3.4. + + 8. Added two 64-bit fields in iSER header in Section 9.2 for the + Read Base Offset and the Write Base Offset to accommodate a non- + zero Base Offset. This allows one implementation such as the + Open Fabrics Enterprise Distribution (OFED) stack to be used in + both the InfiniBand and the iWARP environment. + + Changes were made in the definitions of Base Offset, + Advertisement, and Tagged Buffer. Changes were also made in + Sections 1.5.1, 1.6, 1.7, 7.3.1, 7.3.3, 7.3.5, 7.3.6, 9.1, 9.3, + 9.4, 9.5.1, and 9.5.2. This change is not backward compatible + with RFC 5046, but it was part of all known implementations of + iSER at the time this document was developed. + + 9. Remove iWARP-specific behavior. Changes were made in the + definitions of RDMA Operation and Send Message Type. + + Clarifications were added in Section 1.5.2 on the use of SendSE + and SendInvSE. These clarifications reflect a removal of the + requirements in RFC 5046 for the use of these messages, as + implementations have not followed RFC 5046 in this area. Changes + affecting Send with Invalidate were made in Sections 1.5.1, 1.6, + 1.7, 4.1, and 7.3.2. Changes affecting Terminate were made in + Sections 10.1.2.1 and 10.1.2.2. Changes were made in Appendix B + to remove iWARP headers. + + 10. Removed denial-of-service descriptions for the initiator in + Section 5.1.1 since they are applicable for the target only. + + 11. Clarified in Section 1.5.1 that STag invalidation is the + initiator's responsibility for security reasons, and the + initiator cannot rely on the target using an Invalidate version + of Send. Added text in Section 11 on Stag invalidation. + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 82] + +RFC 7145 iSER Specification April 2014 + + +Appendix B. Message Format for iSER + + This section is for information only and is NOT part of the standard. + +B.1. iWARP Message Format for iSER Hello Message + + The following figure depicts an iSER Hello Message encapsulated in an + iWARP SendSE Message. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | MPA Header | DDP Control | RDMA Control | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | (Send) Queue Number | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | (Send) Message Sequence Number | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | (Send) Message Offset | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | 0010b | Zeros | 0001b | 0001b | iSER-IRD | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | All Zeros | + + | MPA CRC | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 6: SendSE Message Containing an iSER Hello Message + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 83] + +RFC 7145 iSER Specification April 2014 + + +B.2. iWARP Message Format for iSER HelloReply Message + + The following figure depicts an iSER HelloReply Message encapsulated + in an iWARP SendSE Message. The Reject (REJ) flag is set to zero. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | MPA Header | DDP Control | RDMA Control | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | (Send) Queue Number | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | (Send) Message Sequence Number | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | (Send) Message Offset | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | 0011b |Zeros|0| 0001b | 0001b | iSER-ORD | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | MPA CRC | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 7: SendSE Message Containing an iSER HelloReply Message + + + + + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 84] + +RFC 7145 iSER Specification April 2014 + + +B.3. iSER Header Format for SCSI Read Command PDU + + The following figure depicts a SCSI Read Command PDU embedded in an + iSER Message. For this particular example, in the iSER header, the + Write STag Valid flag is set to zero, the Read STag Valid flag is set + to one, the Write STag field is set to all zeros, the Write Base + Offset field is set to all zeros, the Read STag field contains a + valid Read STag, and the Read Base Offset field contains a valid Base + Offset for the Read Tagged Buffer. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | 0001b |0|1| All zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Read STag | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Read Base Offset | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | SCSI Read Command PDU | + // // + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 8: iSER Header Format for SCSI Read Command PDU + + + + + + + + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 85] + +RFC 7145 iSER Specification April 2014 + + +B.4. iSER Header Format for SCSI Write Command PDU + + The following figure depicts a SCSI Write Command PDU embedded in an + iSER Message. For this particular example, in the iSER header, the + Write STag Valid flag is set to one, the Read STag Valid flag is set + to zero, the Write STag field contains a valid Write STag, the Write + Base Offset field contains a valid Base Offset for the Write Tagged + Buffer, the Read STag field is set to all zeros since it is not used, + and the Read Base Offset field is set to all zeros. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | 0001b |1|0| All zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Write STag | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | Write Base Offset | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | SCSI Write Command PDU | + // // + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 9: iSER Header Format for SCSI Write Command PDU + + + + + + + + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 86] + +RFC 7145 iSER Specification April 2014 + + +B.5. iSER Header Format for SCSI Response PDU + + The following figure depicts a SCSI Response PDU embedded in an iSER + Message: + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | 0001b |0|0| All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | All Zeros | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | SCSI Response PDU | + // // + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 10: iSER Header Format for SCSI Response PDU + + + + + + + + + + + + + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 87] + +RFC 7145 iSER Specification April 2014 + + +Appendix C. Architectural Discussion of iSER over InfiniBand + + This section explains how an InfiniBand network (with Gateways) would + be structured. It is informational only and is intended to provide + insight on how iSER is used in an InfiniBand environment. + +C.1. Host Side of iSCSI and iSER Connections in InfiniBand + + Figure 11 defines the topologies in which iSCSI and iSER will be able + to operate on an InfiniBand Network. + + +---------+ +---------+ +---------+ +---------+ +--- -----+ + | Host | | Host | | Host | | Host | | Host | + | | | | | | | | | | + +---+-+---+ +---+-+---+ +---+-+---+ +---+-+---+ +---+-+---+ + |HCA| |HCA| |HCA| |HCA| |HCA| |HCA| |HCA| |HCA| |HCA| |HCA| + +-v-+ +-v-+ +-v-+ +-v-+ +-v-+ +-v-+ +-v-+ +-v-+ +-v-+ +-v-+ + |----+------|-----+-----|-----+-----|-----+-----|-----+---> To IB + IB| IB | IB | IB | IB | SubNet2 SWTCH + +-v-----------v-----------v-----------v-----------v---------+ + | InfiniBand Switch for Subnet1 | + +---+-----+--------+-----+--------+-----+------------v------+ + | TCA | | TCA | | TCA | | + +-----+ +-----+ +-----+ | IB + / IB \ / IB \ / \ +--+--v--+--+ + | iSER | | iSER | | IPoIB | | | TCA | | + | Gateway | | Gateway | | Gateway | | +-----+ | + | to | | to | | to | | Storage | + | iSCSI | | iSER | | IP | | Controller| + | TCP | | iWARP | |Ethernet | +-----+-----+ + +---v-----| +---v-----| +----v----+ + | EN | EN | EN + +--------------+---------------+----> to IP based storage + Ethernet links that carry iSCSI or iWARP + + Figure 11: iSCSI and iSER on IB + + In Figure 11, the Host systems are connected via the InfiniBand Host + Channel Adapters (HCAs) to the InfiniBand links. With the use of IB + switch(es), the InfiniBand links connect the HCA to InfiniBand Target + Channel Adapters (TCAs) located in gateways or Storage Controllers. + An iSER-capable IB-IP Gateway converts the iSER Messages encapsulated + in IB protocols to either standard iSCSI, or iSER Messages for iWARP. + An [IPoIB] Gateway converts the InfiniBand [IPoIB] protocol to IP + protocol, and in the iSCSI case, permits iSCSI to be operated on an + IB Network between the Hosts and the [IPoIB] Gateway. + + + + + +Ko & Nezhinsky Standards Track [Page 88] + +RFC 7145 iSER Specification April 2014 + + +C.2. Storage Side of iSCSI and iSER Mixed Network Environment + + Figure 12 shows a storage controller that has three different portal + groups: one supporting only iSCSI (TPG-4), one supporting iSER/iWARP + or iSCSI (TPG-2), and one supporting iSER/IB (TPG-1). Here, "TPG" + stands for "Target Portal Group". + + | | | + | | | + +--+--v--+----------+--v--+----------+--v--+--+ + | | IB | |iWARP| | EN | | + | | | | TCP | | NIC | | + | |(TCA)| | RNIC| | | | + | +-----| +-----+ +-----+ | + | TPG-1 TPG-2 TPG-4 | + | 9.1.3.3 9.1.2.4 9.1.2.6 | + | | + | Storage Controller | + | | + +---------------------------------------------+ + + Figure 12: Storage Controller with TCP, iWARP, and IB Connections + + The normal iSCSI portal group advertising processes (via the Service + Location Protocol (SLP), Internet Storage Name Service (iSNS), or + SendTargets) are available to a Storage Controller. + +C.3. Discovery Processes for an InfiniBand Host + + An InfiniBand Host system can gather portal group IP addresses from + SLP, iSNS, or the SendTargets discovery processes by using TCP/IP via + [IPoIB]. After obtaining one or more remote portal IP addresses, the + Initiator uses the standard IP mechanisms to resolve the IP address + to a local outgoing interface and the destination hardware address + (Ethernet MAC or InfiniBand Global Identifier (GID) of the target or + a gateway leading to the target). If the resolved interface is an + [IPoIB] network interface, then the target portal can be reached + through an InfiniBand fabric. In this case, the Initiator can + establish an iSCSI/TCP or iSCSI/iSER session with the Target over + that InfiniBand interface, using the hardware address (InfiniBand + GID) obtained through the standard Address Resolution Protocol (ARP) + processes. + + If more than one IP address is obtained through the discovery + process, the Initiator should select a Target IP address that is on + the same IP subnet as the Initiator, if one exists. This will avoid + a potential overhead of going through a gateway when a direct path + exists. + + + +Ko & Nezhinsky Standards Track [Page 89] + +RFC 7145 iSER Specification April 2014 + + + In addition, a user can configure manual static IP route entries if a + particular path to the target is preferred. + +C.4. IBTA Connection Specifications + + It is outside the scope of this document, but it is expected that the + InfiniBand Trade Association (IBTA) has or will define: + + * The iSER ServiceID + + * A means for permitting a Host to establish a connection with a + peer InfiniBand end-node, and that peer indicating when that end- + node supports iSER, so the Host would be able to fall back to + iSCSI/TCP over [IPoIB]. + + * A means for permitting the Host to establish connections with IB + iSER connections on storage controllers or IB iSER-connected + Gateways in preference to IPoIB-connected Gateways/Bridges or + connections to Target Storage Controllers that also accept iSCSI + via [IPoIB]. + + * A means for combining the IB ServiceID for iSER and the IP port + number such that the IB Host can use normal IB connection + processes, yet ensure that the iSER target peer can actually + connect to the required IP port number. + +Appendix D. Acknowledgments + + The authors acknowledge the following individuals for identifying + implementation issues and/or suggesting resolutions to the issues + clarified in this document: Robert Russell, Arne Redlich, David + Black, Mallikarjun Chadalapaka, Tom Talpey, Felix Marti, Robert + Sharp, Caitlin Bestler, Hemal Shah, Spencer Dawkins, Pete Resnick, + Ted Lemon, Pete McCann, and Steve Kent. Credit also goes to the + authors of the original iSER Specification [RFC5046], including + Michael Ko, Mallikarjun Chadalapaka, John Hufferd, Uri Elzur, Hemal + Shah, and Patricia Thaler. This document benefited from all of their + contributions. + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 90] + +RFC 7145 iSER Specification April 2014 + + +Authors' Addresses + + Michael Ko + + EMail: mkosjc@gmail.com + + + Alexander Nezhinsky + Mellanox Technologies + 13 Zarchin St. + Raanana 43662 + Israel + + Phone: +972-74-712-9000 + EMail: alexandern@mellanox.com, nezhinsky@gmail.com + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Ko & Nezhinsky Standards Track [Page 91] + -- cgit v1.2.3