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This document defines FLUTE, a protocol for the unidirectional delivery of files over the Internet, which is particularly suited to multicast networks. The specification builds on Asynchronous Layered Coding, the base protocol designed for massively scalable multicast distribution. This document obsoletes RFC3926.
This Internet-Draft is submitted to IETF in full conformance with the provisions of BCP 78 and BCP 79.
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1.
Introduction
1.1.
Applicability Statement
1.1.1.
The Target Application Space
1.1.2.
The Target Scale
1.1.3.
Intended Environments
1.1.4.
Weaknesses
2.
Conventions used in this Document
3.
File delivery
3.1.
File delivery session
3.2.
File Delivery Table
3.3.
Dynamics of FDT Instances within file delivery session
3.4.
Structure of FDT Instance packets
3.4.1.
Format of FDT Instance Header
3.4.2.
Syntax of FDT Instance
3.4.3.
Content Encoding of FDT Instance
3.5.
Multiplexing of files within a file delivery session
4.
Channels, congestion control and timing
5.
Delivering FEC Object Transmission Information
6.
Describing file delivery sessions
7.
Security Considerations
7.1.
Problem Statement
7.2.
Attacks against the data flow
7.2.1.
Access to confidential files
7.2.2.
File corruption
7.3.
Attacks against the session control parameters and associated Building Blocks
7.3.1.
Attacks against the Session Description
7.3.2.
Attacks against the FDT Instances
7.3.3.
Attacks against the ALC/LCT parameters
7.3.4.
Attacks against the associated Building Blocks
7.4.
Other Security Considerations
7.5.
Minimum Security Recommendations
8.
IANA Considerations
8.1.
Registration Request for XML Schema of FDT Instance
8.2.
Media-Type Registration Request for application/fdt+xml
8.3.
Content Encoding Algorithm Registration Request
8.3.1.
Explicit IANA Assignment Guidelines
9.
Acknowledgements
10.
Contributors
11.
Change Log
11.1.
RFC3926 to draft-ietf-rmt-flute-revised-09
12.
References
12.1.
Normative references
12.2.
Informative references
Appendix A.
Receiver operation (informative)
Appendix B.
Example of FDT Instance (informative)
§
Authors' Addresses
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This document defines FLUTE version 1, a protocol for unidirectional delivery of files over the Internet. The specification builds on Asynchronous Layered Coding (ALC), version 1 [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.), the base protocol designed for massively scalable multicast distribution. ALC defines transport of arbitrary binary objects. For file delivery applications mere transport of objects is not enough, however. The end systems need to know what the objects actually represent. This document specifies a technique called FLUTE - a mechanism for signaling and mapping the properties of files to concepts of ALC in a way that allows receivers to assign those parameters for received objects. Consequently, throughout this document the term 'file' relates to an 'object' as discussed in ALC. Although this specification frequently makes use of multicast addressing as an example, the techniques are similarly applicable for use with unicast addressing.
This document defines a specific transport application of ALC, adding the following specifications:
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- Definition of a file delivery session built on top of ALC, including transport details and timing constraints.
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- In-band signalling of the transport parameters of the ALC session.
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- In-band signalling of the properties of delivered files.
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- Details associated with the multiplexing of multiple files within a session.
This specification is structured as follows. Section 3 begins by defining the concept of the file delivery session. Following that it introduces the File Delivery Table that forms the core part of this specification. Further, it discusses multiplexing issues of transmission objects within a file delivery session. Section 4 describes the use of congestion control and channels with FLUTE. Section 5 defines how the Forward Error Correction (FEC) Object Transmission Information is to be delivered within a file delivery session. Section 6 defines the required parameters for describing file delivery sessions in a general case. Section 7 outlines security considerations regarding file delivery with FLUTE. Last, there are two informative appendices. The first appendix describes an envisioned receiver operation for the receiver of the file delivery session. The second appendix gives an example of File Delivery Table.
This specification contains part of the definitions necessary to fully specify a Reliable Multicast Transport protocol in accordance with RFC2357.
This document obsoletes RFC3926 which contained a previous version of this specification and was published in the "Experimental" category. This Proposed Standard specification is thus based on RFC3926 updated according to accumulated experience and growing protocol maturity since the publication of RFC3926. Said experience applies both to this specification itself and to congestion control strategies related to the use of this specification.
The differences between RFC3926 and this document listed in Section 11 (Change Log).
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FLUTE is applicable to the delivery of large and small files to many hosts, using delivery sessions of several seconds or more. For instance, FLUTE could be used for the delivery of large software updates to many hosts simultaneously. It could also be used for continuous, but segmented, data such as time-lined text for subtitling - potentially leveraging its layering inheritance from ALC and LCT to scale the richness of the session to the congestion status of the network. It is also suitable for the basic transport of metadata, for example SDP [19] (Handley, M., Jacobson, V., and C. Perkins, “Session Description Protocol,” July 2006.) files which enable user applications to access multimedia sessions.
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Massive scalability is a primary design goal for FLUTE. IP multicast is inherently massively scalable, but the best effort service that it provides does not provide session management functionality, congestion control or reliability. FLUTE provides all of this using ALC and IP multicast without sacrificing any of the inherent scalability of IP multicast.
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All of the environmental requirements and considerations that apply to the ALC building block [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.) and to any additional building blocks that FLUTE uses also apply to FLUTE.
FLUTE can be used with both multicast and unicast delivery, but it's primary application is for unidirectional multicast file delivery. FLUTE requires connectivity between a sender and receivers but does not require connectivity from receivers to a sender. FLUTE inherently works with all types of networks, including LANs, WANs, Intranets, the Internet, asymmetric networks, wireless networks, and satellite networks.
FLUTE is compatible with both IPv4 or IPv6 as no part of the packet is IP version specific. FLUTE works with both multicast models: Any-Source Multicast (ASM) [20] (Deering, S., “Host Extensions for IP Multicasting,” August 1989.) and the Source-Specific Multicast (SSM) [21] (Holbrook, H., “A Channel Model for Multicast, Ph.D. Dissertation, Stanford University, Department of Computer Science, Stanford, California,” August 2001.).
FLUTE is applicable for both Internet use, with a suitable congestion control building block, and provisioned/controlled systems, such as delivery over wireless broadcast radio systems.
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Some networks are not amenable to some congestion control protocols that could be used with FLUTE. In particular, for a satellite or wireless network, there may be no mechanism for receivers to effectively reduce their reception rate since there may be a fixed transmission rate allocated to the session.
FLUTE can also be used for point-to-point (unicast) communications. At a minimum, implementations of ALC MUST support the WEBRC [16] (Luby, M. and V. Goyal, “Wave and Equation Based Rate Control (WEBRC) Building Block,” April 2004.) multiple rate congestion control scheme [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.). However, since WEBRC has been designed for massively scalable multicast flows, it is not clear how appropriate it is to the particular case of unicast flows. Using a separate point-to-point congestion control scheme is another alternative. How to do do that is outside the scope of the present document.
FLUTE provides reliability using the FEC building block. This will reduce the error rate as seen by applications. However, FLUTE does not provide a method for senders to verify the reception success of receivers, and the specification of such a method is outside the scope of this document.
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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 RFC 2119 [1] (Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” March 1997.).
The terms "object" and "transmission object" are consistent with the definitions in ALC [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.) and LCT [3] (Luby, M., Watson, M., and L. Vicisano, “Layered Coding Transport (LCT) Building Block,” October 2009.). The terms "file" and "source object" are pseudonyms for "object".
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Asynchronous Layered Coding [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.) is a protocol designed for delivery of arbitrary binary objects. It is especially suitable for massively scalable, unidirectional, multicast distribution. ALC provides the basic transport for FLUTE, and thus FLUTE inherits the requirements of ALC.
This specification is designed for the delivery of files. The core of this specification is to define how the properties of the files are carried in-band together with the delivered files.
As an example, let us consider a 5200 byte file referred to by "http://www.example.com/docs/file.txt". Using the example, the following properties describe the properties that need to be conveyed by the file delivery protocol.
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- Identifier of the file, expressed as a URI. This identifier may be globally unique. The identifier may also provide a location for the file. In the above example: "http://www.example.com/docs/file.txt".
- *
- File name (usually, this can be concluded from the URI). In the above example: "file.txt".
- *
- File type, expressed as MIME media type (usually, this can also be concluded from the extension of the file name). In the above example: "text/plain". If an explicit value for the MIME type is provided separately from the file extension and does not match the MIME type of the file extension then the explicitly provided value MUST be used as the MIME type.
- *
- File size, expressed in bytes. In the above example: "5200". If the file is content encoded then this is the file size before content encoding.
- *
- Content encoding of the file, within transport. In the above example, the file could be encoded using ZLIB [13] (Deutsch, P. and J-L. Gailly, “ZLIB Compressed Data Format Specification version 3.3,” May 1996.). In this case the size of the transmission object carrying the file would probably differ from the file size. The transmission object size is delivered to receivers as part of the FLUTE protocol.
- *
- Security properties of the file such as digital signatures, message digests, etc. For example, one could use S/MIME [24] (Ramsdell, B., “Secure/Multipurpose Internet Mail Extensions (S/MIME) Version 3.1 Message Specification,” July 2004.) as the content encoding type for files with this authentication wrapper, and one could use XML-DSIG [25] (Eastlake, D., Reagle, J., and D. Solo, “(Extensible Markup Language) XML-Signature Syntax and Processing,” March 2002.) to digitally sign an FDT Instance. XML-DSIG can also be used to provide tamper prevention e.g. on the Content-Location field.
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ALC is a protocol instantiation of Layered Coding Transport building block (LCT) [3] (Luby, M., Watson, M., and L. Vicisano, “Layered Coding Transport (LCT) Building Block,” October 2009.). Thus ALC inherits the session concept of LCT. In this document we will use the concept ALC/LCT session to collectively denote the interchangeable terms ALC session and LCT session.
An ALC/LCT session consists of a set of logically grouped ALC/LCT channels associated with a single sender sending packets with ALC/LCT headers for one or more objects. An ALC/LCT channel is defined by the combination of a sender and an address associated with the channel by the sender. A receiver joins a channel to start receiving the data packets sent to the channel by the sender, and a receiver leaves a channel to stop receiving data packets from the channel.
One of the fields carried in the ALC/LCT header is the Transport Session Identifier (TSI). The TSI is scoped by the source IP address, and the (source IP address, TSI) pair uniquely identifies a session, i.e., the receiver uses this pair carried in each packet to uniquely identify from which session the packet was received. In case multiple objects are carried within a session, the Transmission Object Identifier (TOI) field within the ALC/LCT header identifies from which object the data in the packet was generated. Note that each object is associated with a unique TOI within the scope of a session.
If the sender is not assigned a permanent IP address accessible to receivers, but instead, packets that can be received by receivers containing a temporary IP address for packets sent by the sender, then the TSI is scoped by this temporary IP address of the sender for the duration of the session. As an example, the sender may be behind a Network Address Translation (NAT) device that temporarily assigns an IP address for the sender that is accessible to receivers, and in this case the TSI is scoped by the temporary IP address assigned by the NAT that will appear in packets received by the receiver. As another example, the sender may send its original packets using IPv6, but some portions of the network may not be IPv6 capable and thus there may be an IPv6 to IPv4 translator that changes the IP address of the packets to a different IPv4 address. In this case, receivers in the IPv4 portion of the network will receive packets containing the IPv4 address, and thus the TSI for them is scoped by the IPv4 address. How the IP address of the sender to be used to scope the session by receivers is delivered to receivers, whether it is a permanent IP address or a temporary IP address, is outside the scope of this document.
When FLUTE is used for file delivery over ALC the following rules apply:
- *
- The ALC/LCT session is called file delivery session.
- *
- The ALC/LCT concept of 'object' denotes either a 'file' or a 'File Delivery Table Instance' (section 3.2)
- *
- The TOI field MUST be included in ALC packets sent within a FLUTE session, with the exception that ALC packets sent in a FLUTE session with the Close Session (A) flag set to 1 (signaling the end of the session) and that contain no payload (carrying no information for any file or FDT) SHALL NOT carry the TOI. See Section 5.1 of RFC 3451 [3] (Luby, M., Watson, M., and L. Vicisano, “Layered Coding Transport (LCT) Building Block,” October 2009.) for the LCT definition of the Close Session flag, and see Section 4.2 of RFC 3450 [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.) for an example of its use within an ALC packet.
- *
- The TOI value '0' is reserved for delivery of File Delivery Table Instances. Each non expired File Delivery Table Instance is uniquely identified by an FDT Instance ID.
- *
- Each file in a file delivery session MUST be associated with a TOI (>0) in the scope of that session.
- *
- Information carried in the headers and the payload of a packet is scoped by the source IP address and the TSI. Information particular to the object carried in the headers and the payload of a packet is further scoped by the TOI for file objects, and is further scoped by both the TOI and the FDT Instance ID for FDT Instance objects.
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The File Delivery Table (FDT) provides a means to describe various attributes associated with files that are to be delivered within the file delivery session. The following lists are examples of such attributes, and are not intended to be mutually exclusive nor exhaustive.
Attributes related to the delivery of file:
- -
- TOI value that represents the file
- -
- FEC Object Transmission Information (including the FEC Encoding ID and, if relevant, the FEC Instance ID)
- -
- Size of the transmission object carrying the file
- -
- Aggregate rate of sending packets to all channels
Attributes related to the file itself:
- -
- Name, Identification and Location of file (specified by the URI)
- -
- MIME media type of file
- -
- Size of file
- -
- Encoding of file
- -
- Message digest of file
Some of these attributes MUST be included in the file description entry for a file, others are optional, as defined in section 3.4.2.
Logically, the FDT is a set of file description entries for files to be delivered in the session. Each file description entry MUST include the TOI for the file that it describes and the URI identifying the file. The TOI is included in each ALC/LCT data packet during the delivery of the file, and thus the TOI carried in the file description entry is how the receiver determines which ALC/LCT data packets contain information about which file. Each file description entry may also contain one or more descriptors that map the above-mentioned attributes to the file.
Each file delivery session MUST have an FDT that is local to the given session. The FDT MUST provide a file description entry mapped to a TOI for each file appearing within the session. An object that is delivered within the ALC session, but not described in the FDT, is not considered a 'file' belonging to the file delivery session. Handling of these unmapped TOIs (TOIs that are not resolved by the FDT) is out of scope of this specification.
Within the file delivery session the FDT is delivered as FDT Instances. An FDT Instance contains one or more file description entries of the FDT. Any FDT Instance can be equal to, a subset of, a superset of, or complement any other FDT Instance. A certain FDT Instance may be repeated several times during a session, even after subsequent FDT Instances (with higher FDT Instance ID numbers) have been transmitted. Each FDT Instance contains at least a single file description entry and at most the exhaustive set of file description entries of the files being delivered in the file delivery session.
A receiver of the file delivery session keeps an FDT database for received file description entries. The receiver maintains the database, for example, upon reception of FDT Instances. Thus, at any given time the contents of the FDT database represent the receiver's current view of the FDT of the file delivery session. Since each receiver behaves independently of other receivers, it SHOULD NOT be assumed that the contents of the FDT database are the same for all the receivers of a given file delivery session.
Since FDT database is an abstract concept, the structure and the maintaining of the FDT database are left to individual implementations and are thus out of scope of this specification.
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The following rules define the dynamics of the FDT Instances within a file delivery session:
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- For every file delivered within a file delivery session there MUST be a file description entry included in at least one FDT Instance sent within the session. A file description entry contains at a minimum the mapping between the TOI and the URI.
- *
- An FDT Instance MAY appear in any part of the file delivery session and packets for an FDT Instance MAY be interleaved with packets for other files or other FDT Instances within a session.
- *
- The TOI value of '0' MUST be reserved for delivery of FDT Instances. The use of other TOI values for FDT Instances is outside the scope of this specification.
- *
- FDT Instance is identified by the use of a new fixed length LCT Header Extension EXT_FDT (defined later in this section). Each non expired FDT Instance is uniquely identified within the file delivery session by its FDT Instance ID. Any ALC/LCT packet carrying FDT Instance (indicated by TOI = 0) MUST include EXT_FDT.
- *
- It is RECOMMENDED that an FDT Instance that contains the file description entry for a file is sent prior to the sending of the described file within a file delivery session.
- *
- Within a file delivery session, any TOI > 0 MAY be described more than once. An example: previous FDT Instance 0 describes TOI of value '3'. Now, subsequent FDT Instances can either keep TOI '3' unmodified on the table, not include it, or complement the description. However, subsequent FDT Instances MUST NOT change the parameters already described for a specific TOI.
- *
- An FDT Instance is valid until its expiration time. The expiration time is expressed within the FDT Instance payload as a 32 bit data field. The value of the data field represents the 32 most significant bits of a 64 bit Network Time Protocol (NTP) [6] (Mills, D., “Network Time Protocol (Version 3), Specification, Implementation and Analysis,” March 1992.) time value. These 32 bits provide an unsigned integer representing the time in seconds relative to 0 hours 1 January 1900 in case of the prime epoch (era 0) [22] (Kasch, W., Mills, D., and J. Burbank, “Network Time Protocol Version 4 Protocol And Algorithms Specification,” October 2009.). The handling of time wraparound (to happen in 2036) requires to consider the associated epoch. In any case, both a sender and a receiver can easily determine to which (136 year) epoch the FDT Instance expiration time value pertains to.
- *
- The receiver SHOULD NOT use a received FDT Instance to interpret packets received beyond the expiration time of the FDT Instance.
- *
- A sender MUST use an expiry time in the future upon creation of an FDT Instance relative to its Sender Current Time (SCT).
- *
- Any FEC Encoding ID MAY be used for the sending of FDT Instances. The default is to use FEC Encoding ID 0 [5] (Watson, M., “Basic Forward Error Correction (FEC) Schemes,” March 2009.) for the sending of FDT Instances. (Note that since FEC Encoding ID 0 is the default for FLUTE, this implies that Source Block Number and Encoding Symbol ID lengths both default to 16 bits each.)
Generally, a receiver needs to receive an FDT Instance describing a file before it is able to recover the file itself. In this sense FDT Instances are of higher priority than files. Additionally, a FLUTE sender SHOULD assume receivers will not receive all packets pertaining to FDT Instances, i.e., it is RECOMMENDED that FDT Instances be managed in such a way that a receiver will be able to recover at least one FDT Instance describing a file delivered within the file delivery session with as much or greater reliability as the receiver is able to receive enough packets containing encoding symbols to recover the file.
The way FDT Instances are transmitted has a large impact on satisfying the recommendation above. When there is a single file transmitted in the session, one way to satisfy the recommendation above is to repeatedly transmit on a regular enough basis FDT Instances describing the file while the file is being transmitted. As another example, if an FDT Instance is longer than one packet payload in length, it is RECOMMENDED that an FEC code that provides protection against loss be used for delivering this FDT Instance. When there are multiple files in a session concurrently being transmitted to receivers, the way the FDT Instances are structured and transmitted also has a large impact. As an example, a way to satisfy the recommendation above is to transmit an FDT Instance that describes all files currently being transmitted, and to transmit this FDT Instance reliably, using the same techniques as explained for the case when there is a single file transmitted in a session. If instead the concurrently transmitted files are described in separate FDT Instances, another way to satisfy this recommendation is to transmit all the relevant FDT Instances reliably, using the same techniques as explained for the case when there is a single file transmitted in a session.
In any case, how often the description of a file is sent in an FDT Instance, how often an FDT Instance is sent, and how much FEC protection is provided for an FDT Instance (if longer than one packet payload) are dependent on the particular application and are outside the scope of this document.
Sometimes the various attributes associated with files that are to be delivered within the file delivery session are sent out-of-band (rather than in-band, within one or several FDT Instances). The details of how this is done are out of the scope of this document. However, it is still RECOMMENDED that any out-of-band transmission be managed in such a way that a receiver will be able to recover the attributes associated with a file with as much or greater reliability as the receiver is able to receive enough packets containing encoding symbols to recover the file.
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FDT Instances are carried in ALC packets with TOI = 0 and with an additional REQUIRED LCT Header extension called the FDT Instance Header. The FDT Instance Header (EXT_FDT) contains the FDT Instance ID that uniquely identifies FDT Instances within a file delivery session. The FDT Instance Header is placed in the same way as any other LCT extension header. There MAY be other LCT extension headers in use.
The LCT extension headers are followed by the FEC Payload ID, and finally the Encoding Symbols for the FDT Instance which contains one or more file description entries. A FDT Instance MAY span several ALC packets - the number of ALC packets is a function of the file attributes associated with the FDT Instance. The FDT Instance Header is carried in each ALC packet carrying the FDT Instance. The FDT Instance Header is identical for all ALC/LCT packets for a particular FDT Instance.
The overall format of ALC/LCT packets carrying an FDT Instance is depicted in the Figure 1 below. All integer fields are carried in "big-endian" or "network order" format, that is, most significant byte (octet) first. As defined in [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.), all ALC/LCT packets are sent using UDP.
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | UDP header | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Default LCT header (with TOI = 0) | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | LCT header extensions (EXT_FDT, EXT_FTI, etc.) | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | FEC Payload ID | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ FLUTE Payload: Encoding Symbol(s) ~ (for FDT Instance in a FDT packet) ~ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 1: Overall FDT Packet |
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FDT Instance Header (EXT_FDT) is a new fixed length, ALC PI specific LCT header extension [3] (Luby, M., Watson, M., and L. Vicisano, “Layered Coding Transport (LCT) Building Block,” October 2009.). The Header Extension Type (HET) for the extension is 192. Its format is defined below:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | HET = 192 | V | FDT Instance ID | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 2 |
Version of FLUTE (V), 4 bits:
This document specifies FLUTE version 1. Hence in any ALC packet that carries FDT Instance and that belongs to the file delivery session as specified in this specification MUST set this field to '1'.
FDT Instance ID, 20 bits:
For each file delivery session the numbering of FDT Instances starts from '0' and is incremented by one for each subsequent FDT Instance. After reaching the maximum value (2^20-1), the numbering starts from the smallest FDT Instance value assigned to an expired FDT Instance. When wraparound from a greater FDT Instance ID value to a smaller FDT Instance ID value occurs, the smaller FDT Instance ID value is considered logically higher than the greater FDT Instance ID value. A new FDT Instance reusing a previous FDT Instance ID number, due to wraparound, does not implicitly expire the previous FDT Instance with the same ID. Sender behavior when all the FDT Instance IDs are used by non expired FEC Instances is outside the scope of this specification and left to individual implementations of FLUTE. Receiver behavior when receiving an FDT Instance that reuses an FDT Instance ID value that is currently used by a non expired FDT Instance is outside the scope of this specification and left to individual implementations of FLUTE. However a receiver MUST be ready to handle FDT Instance ID wraparound and situations where missing FDT Instance IDs result in increments larger than one.
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The FDT Instance contains file description entries that provide the mapping functionality described in 3.2 above.
The FDT Instance is an XML structure that has a single root element "FDT-Instance". The "FDT-Instance" element MUST contain "Expires" attribute, which tells the expiry time of the FDT Instance. In addition, the "FDT-Instance" element MAY contain the "Complete" attribute (boolean), which, when TRUE, signals that this "FDT Instance" includes the set of "File" entries that exhausts both the set of files delivered so far and also the set of files to be delivered in the session. This implies that no new data will be provided in future FDT Instances within this session (i.e., that either FDT Instances with higher ID numbers will not be used or if they are used, will only provide identical file parameters to those already given in this and previous FDT Instances). The "Complete" attribute is therefore used to provide a complete list of files in an entire FLUTE session (a "complete FDT").
The "FDT-Instance" element MAY contain attributes that give common parameters for all files of an FDT Instance. These attributes MAY also be provided for individual files in the "File" element. Where the same attribute appears in both the "FDT-Instance" and the "File" elements, the value of the attribute provided in the "File" element takes precedence.
For each file to be declared in the given FDT Instance there is a single file description entry in the FDT Instance. Each entry is represented by element "File" which is a child element of the FDT Instance structure.
The attributes of "File" element in the XML structure represent the attributes given to the file that is delivered in the file delivery session. The value of the XML attribute name corresponds to MIME field name and the XML attribute value corresponds to the value of the MIME field body. Each "File" element MUST contain at least two attributes "TOI" and "Content-Location". "TOI" MUST be assigned a valid TOI value as described in section 3.3 above. "Content-Location" MUST be assigned a valid URI as defined in [7] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.). The semantics for any two "File" elements declaring the same "Content-Location" but differing "TOI" is that the element appearing in the FDT Instance with the greater FDT Instance ID is considered to declare newer instance (e.g. version) of the same "File".
In addition to mandatory attributes, the "FDT-Instance" element and the "File" element MAY contain other attributes of which the following are specifically pointed out.
- *
- Where the MIME type is described, the attribute "Content-Type" MUST be used for the purpose as defined in [7] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.).
- *
- Where the length is described, the attribute "Content-Length" MUST be used for the purpose as defined in [7] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.). The transfer length is defined to be the length of the object transported in bytes. It is often important to convey the transfer length to receivers, because the source block structure needs to be known for the FEC decoder to be applied to recover source blocks of the file, and the transfer length is often needed to properly determine the source block structure of the file. There generally will be a difference between the length of the original file and the transfer length if content encoding is applied to the file before transport, and thus the "Content-Encoding" attribute is used. If the file is not content encoded before transport (and thus the "Content-Encoding" attribute is not used) then the transfer length is the length of the original file, and in this case the "Content-Length" is also the transfer length. However, if the file is content encoded before transport (and thus the "Content-Encoding" attribute is used), e.g., if compression is applied before transport to reduce the number of bytes that need to be transferred, then the transfer length is generally different than the length of the original file, and in this case the attribute "Transfer-Length" MAY be used to carry the transfer length.
- *
- Where the content encoding scheme is described, the attribute "Content-Encoding" MUST be used for the purpose as defined in [7] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.).
- *
- Where the MD5 message digest is described, the attribute "Content-MD5" MUST be used for the purpose as defined in [7] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.).
- *
- The FEC Object Transmission Information attributes as described in section 5.2.
The following specifies the XML Schema [8] (Thompson, H., Beech, D., Maloney, M., and N. Mendelsohn, “XML Schema Part 1: Structures,” May 2001.)[9] (Biron, P. and A. Malhotra, “XML Schema Part 2: Datatypes,” May 2001.) for FDT Instance:
BEGIN <?xml version="1.0" encoding="UTF-8"?> <xs:schema xmlns="urn:ietf:params:xml:ns:fdt" xmlns:xs="http://www.w3.org/2001/XMLSchema" targetNamespace="urn:ietf:params:xml:ns:fdt" elementFormDefault="qualified"> <xs:element name="FDT-Instance" type="FDT-InstanceType"/> <xs:complexType name="FDT-InstanceType"> <xs:sequence> <xs:element name="File" type="FileType" maxOccurs="unbounded"/> <xs:any namespace="##other" processContents="skip" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="Expires" type="xs:string" use="required"/> <xs:attribute name="Complete" type="xs:boolean" use="optional"/> <xs:attribute name="Content-Type" type="xs:string" use="optional"/> <xs:attribute name="Content-Encoding" type="xs:string" use="optional"/> <xs:attribute name="FEC-OTI-FEC-Encoding-ID" type="xs:unsignedByte" use="optional"/> <xs:attribute name="FEC-OTI-FEC-Instance-ID" type="xs:unsignedLong" use="optional"/> <xs:attribute name="FEC-OTI-Maximum-Source-Block-Length" type="xs:unsignedLong" use="optional"/> <xs:attribute name="FEC-OTI-Encoding-Symbol-Length" type="xs:unsignedLong" use="optional"/> <xs:attribute name="FEC-OTI-Max-Number-of-Encoding-Symbols" type="xs:unsignedLong" use="optional"/> <xs:attribute name="FEC-OTI-Scheme-Specific-Info" type="xs:base64Binary" use="optional"/> <xs:anyAttribute processContents="skip"/> </xs:complexType> <xs:complexType name="FileType"> <xs:sequence> <xs:any namespace="##other" processContents="skip" minOccurs="0" maxOccurs="unbounded"/> </xs:sequence> <xs:attribute name="Content-Location" type="xs:anyURI" use="required"/> <xs:attribute name="TOI" type="xs:positiveInteger" use="required"/> <xs:attribute name="Content-Length" type="xs:unsignedLong" use="optional"/> <xs:attribute name="Transfer-Length" type="xs:unsignedLong" use="optional"/> <xs:attribute name="Content-Type" type="xs:string" use="optional"/> <xs:attribute name="Content-Encoding" type="xs:string" use="optional"/> <xs:attribute name="Content-MD5" type="xs:base64Binary" use="optional"/> <xs:attribute name="FEC-OTI-FEC-Encoding-ID" type="xs:unsignedByte" use="optional"/> <xs:attribute name="FEC-OTI-FEC-Instance-ID" type="xs:unsignedLong" use="optional"/> <xs:attribute name="FEC-OTI-Maximum-Source-Block-Length" type="xs:unsignedLong" use="optional"/> <xs:attribute name="FEC-OTI-Encoding-Symbol-Length" type="xs:unsignedLong" use="optional"/> <xs:attribute name="FEC-OTI-Max-Number-of-Encoding-Symbols" type="xs:unsignedLong" use="optional"/> <xs:attribute name="FEC-OTI-Scheme-Specific-Info" type="xs:base64Binary" use="optional"/> <xs:anyAttribute processContents="skip"/> </xs:complexType> </xs:schema> END
Figure 3 |
Any valid FDT Instance must use the above XML Schema. This way FDT provides extensibility to support private attributes within the file description entries. Those could be, for example, the attributes related to the delivery of the file (timing, packet transmission rate, etc.).
In case the basic FDT XML Schema is extended in terms of new descriptors (attributes or elements), for descriptors applying to a single file, those MUST be placed within the element "File". For descriptors applying to all files described by the current FDT Instance, those MUST be placed within the element "FDT-Instance". It is RECOMMENDED that the new attributes applied in the FDT are in the format of MIME fields and are either defined in the HTTP/1.1 specification [7] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.) or another well-known specification.
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The FDT Instance itself MAY be content encoded, for example compressed. This specification defines FDT Instance Content Encoding Header (EXT_CENC). EXT_CENC is a new fixed length, ALC PI specific LCT header extension [3] (Luby, M., Watson, M., and L. Vicisano, “Layered Coding Transport (LCT) Building Block,” October 2009.). The Header Extension Type (HET) for the extension is 193. If the FDT Instance is content encoded, the EXT_CENC MUST be used to signal the content encoding type. In that case, EXT_CENC header extension MUST be used in all ALC packets carrying the same FDT Instance ID. Consequently, when EXT_CENC header is used, it MUST be used together with a proper FDT Instance Header (EXT_FDT). Within a file delivery session, FDT Instances that are not content encoded and FDT Instances that are content encoded MAY both appear. If content encoding is not used for a given FDT Instance, the EXT_CENC MUST NOT be used in any packet carrying the FDT Instance. The format of EXT_CENC is defined below:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | HET = 193 | CENC | Reserved | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 4 |
Content Encoding Algorithm (CENC), 8 bits:
This field signals the content encoding algorithm used in the FDT Instance payload. This subsection reserves the Content Encoding Algorithm values 0, 1, 2 and 3 for null, ZLIB [13] (Deutsch, P. and J-L. Gailly, “ZLIB Compressed Data Format Specification version 3.3,” May 1996.), DEFLATE [14] (Deutsch, P., “DEFLATE Compressed Data Format Specification version 1.3,” May 1996.) and GZIP [15] (Deutsch, P., “GZIP file format specification version 4.3,” May 1996.) respectively.
Reserved, 16 bits:
This field MUST be set to all '0'. This field SHOULD be ignored on reception.
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The delivered files are carried as transmission objects (identified with TOIs) in the file delivery session. All these objects, including the FDT Instances, MAY be multiplexed in any order and in parallel with each other within a session, i.e., packets for one file MAY be interleaved with packets for other files or other FDT Instances within a session.
Multiple FDT Instances MAY be delivered in a single session using TOI = 0. In this case, it is RECOMMENDED that the sending of a previous FDT Instance SHOULD end before the sending of the next FDT Instance starts. However, due to unexpected network conditions, packets for the FDT Instances MAY be interleaved. A receiver can determine which FDT Instance a packet contains information about since the FDT Instances are uniquely identified by their FDT Instance ID carried in the EXT_FDT headers.
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ALC/LCT has a concept of channels and congestion control. There are four scenarios FLUTE is envisioned to be applied.
- (a)
- Use a single channel and a single-rate congestion control protocol.
- (b)
- Use multiple channels and a multiple-rate congestion control protocol. In this case the FDT Instances MAY be delivered on more than one channel.
- (c)
- Use a single channel without congestion control supplied by ALC, but only when in a controlled network environment where flow/congestion control is being provided by other means.
- (d)
- Use multiple channels without congestion control supplied by ALC, but only when in a controlled network environment where flow/congestion control is being provided by other means. In this case the FDT Instances MAY be delivered on more than one channel.
When using just one channel for a file delivery session, as in (a) and (c), the notion of 'prior' and 'after' are intuitively defined for the delivery of objects with respect to their delivery times.
However, if multiple channels are used, as in (b) and (d), it is not straightforward to state that an object was delivered 'prior' to the other. An object may begin to be delivered on one or more of those channels before the delivery of a second object begins. However, the use of multiple channels/layers may complete the delivery of the second object before the first. This is not a problem when objects are delivered sequentially using a single channel. Thus, if the application of FLUTE has a mandatory or critical requirement that the first transmission object must complete 'prior' to the second one, it is RECOMMENDED that only a single channel is used for the file delivery session.
Furthermore, if multiple channels are used then a receiver joined to the session at a low reception rate will only be joined to the lower layers of the session. Thus, since the reception of FDT Instances is of higher priority than the reception of files (because the reception of files depends on the reception of an FDT Instance describing it), the following is RECOMMENDED:
- 1.
- The layers to which packets for FDT Instances are sent SHOULD NOT be biased towards those layers to which lower rate receivers are not joined. For example, it is okay to put all the packets for an FDT Instance into the lowest layer (if this layer carries enough packets to deliver the FDT to higher rate receivers in a reasonable amount of time), but it is not okay to put all the packets for an FDT Instance into the higher layers that only high rate receivers will receive.
- 2.
- If FDT Instances are generally longer than one Encoding Symbol in length and some packets for FDT Instances are sent to layers that lower rate receivers do not receive, an FEC Encoding other than FEC Encoding ID 0 [5] (Watson, M., “Basic Forward Error Correction (FEC) Schemes,” March 2009.) SHOULD be used to deliver FDT Instances. This is because in this case, even when there is no packet loss in the network, a lower rate receiver will not receive all packets sent for an FDT Instance.
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FLUTE inherits the use of FEC building block [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.) from ALC. When using FLUTE for file delivery over ALC the FEC Object Transmission Information MUST be delivered in-band within the file delivery session. There are two methods to achieve this: the use of ALC specific LCT extension header EXT_FTI [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.) and the use of FDT. The latter method is specified in this section.
The receiver of file delivery session MUST support delivery of FEC Object Transmission Information using the EXT_FTI for the FDT Instances carried using TOI value 0. For the TOI values other than 0 the receiver MUST support both methods: the use of EXT_FTI and the use of FDT.
The FEC Object Transmission Information that needs to be delivered to receivers MUST be exactly the same whether it is delivered using EXT_FTI or using FDT (or both). The FEC Object Transmission Information that MUST be delivered to receivers is defined by the FEC Scheme. This section describes the delivery using FDT.
The FEC Object Transmission Information regarding a given TOI may be available from several sources. In this case, it is RECOMMENDED that the receiver of the file delivery session prioritizes the sources in the following way (in the order of decreasing priority).
- 1.
- FEC Object Transmission Information that is available in EXT_FTI.
- 2.
- FEC Object Transmission Information that is available in the FDT.
The FDT delivers FEC Object Transmission Information for each file using an appropriate attribute within the "FDT-Instance" or the "File" element of the FDT structure.
- *
- "Transfer-Length" carries the Transfer-Length Object Transmission Information element defined in [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.).
- *
- "FEC-OTI-FEC-Encoding-ID" carries the "FEC Encoding ID" Object Transmission Information element defined in [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.), as carried in the Codepoint field of the ALC/LCT header.
- *
- "FEC-OTI-FEC-Instance-ID" carries the "FEC Instance ID" Object Transmission Information element defined in [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.) for Under-specified FEC Schemes.
- *
- "FEC-OTI-Maximum-Source-Block-Length" carries the "Maximum Source Block Length" Object Transmission Information element defined in [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.), if required by the FEC Scheme.
- *
- "FEC-OTI-Encoding-Symbol-Length" carries the "Encoding Symbol Length" Object Transmission Information element defined in [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.), if required by the FEC Scheme.
- *
- "FEC-OTI-Max-Number-of-Encoding-Symbols" carries the "Maximum Number of Encoding Symbols" Object Transmission Information element defined in [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.), if required by the FEC Scheme.
- *
- "FEC-OTI-Scheme-specific-information" carries the "encoded scheme-specific FEC Object Transmission Information" as defined in [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.), if required by the FEC Scheme.
In FLUTE, the FEC Encoding ID (8 bits) for a given TOI MUST be carried in the Codepoint field of the ALC/LCT header. When the FEC Object Transmission Information for this TOI is delivered through the FDT, then the associated "FEC-OTI-FEC-Encoding-ID" attribute and the Codepoint field of all packets for this TOI MUST be the same.
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To start receiving a file delivery session, the receiver needs to know transport parameters associated with the session. Interpreting these parameters and starting the reception therefore represents the entry point from which thereafter the receiver operation falls into the scope of this specification. According to [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.), the transport parameters of an ALC/LCT session that the receiver needs to know are:
- *
- The source IP address;
- *
- The number of channels in the session;
- *
- The destination IP address and port number for each channel in the session;
- *
- The Transport Session Identifier (TSI) of the session;
- *
- An indication that the session is a FLUTE session. The need to demultiplex objects upon reception is implicit in any use of FLUTE, and this fulfills the ALC requirement of an indication of whether or not a session carries packets for more than one object (all FLUTE sessions carry packets for more than one object).
Optionally, the following parameters MAY be associated with the session (Note, the list is not exhaustive):
- *
- The start time and end time of the session;
- *
- FEC Encoding ID and FEC Instance ID when the default FEC Encoding ID 0 is not used for the delivery of FDT;
- *
- Content Encoding format if optional content encoding of FDT Instance is used, e.g., compression;
- *
- Some information that tells receiver, in the first place, that the session contains files that are of interest;
- *
- Definition and configuration of congestion control mechanism for the session ;
- *
- Security parameters relevant for the session.
It is envisioned that these parameters would be described according to some session description syntax (such as SDP [19] (Handley, M., Jacobson, V., and C. Perkins, “Session Description Protocol,” July 2006.) or XML based) and held in a file which would be acquired by the receiver before the FLUTE session begins by means of some transport protocol (such as Session Announcement Protocol [18] (Handley, M., Perkins, C., and E. Whelan, “Session Announcement Protocol,” October 2000.), email, HTTP [7] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.), SIP [28] (Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston, A., Peterson, J., Sparks, R., Handley, M., and E. Schooler, “SIP: session initiation protocol,” June 2002.), manual pre-configuration, etc.) However, the way in which the receiver discovers the above-mentioned parameters is out of scope of this document, as it is for LCT and ALC. In particular, this specification does not mandate or exclude any mechanism.
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A content delivery system is potentially subject to attacks. Attacks may target:
- *
- the network (to compromise the routing infrastructure, e.g., by creating congestion),
- *
- the Content Delivery Protocol (CDP) (e.g., to compromise the normal behaviour of FLUTE), or
- *
- the content itself (e.g., to corrupt the files being transmitted).
These attacks can be launched either:
- *
- against the data flow itself (e.g., by sending forged packets),
- *
- against the session control parameters (e.g., by corrupting the session description, the FDT Instances, or the ALC/LCT control parameters) that are sent either in-band or out-of-band, or
- *
- against some associated building blocks (e.g., the congestion control component).
In the following sections we provide more details on these possible attacks and sketch some possible counter-measures. We finally provide recommendations in Section 7.5 (Minimum Security Recommendations).
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Let us consider attacks against the data flow first. At least, the following types of attacks exist:
- *
- attacks that are meant to give access to a confidential file (e.g., in case of a non-free content) and
- *
- attacks that try to corrupt the file being transmitted (e.g., to inject malicious code within a file, or to prevent a receiver from using a file, which is a kind of Denial of Service, DoS).
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Access control to the file being transmitted is typically provided by means of encryption. This encryption can be done over the whole file (e.g., by the content provider, before submitting the file to FLUTE), or be done on a packet per packet basis (e.g., when IPsec/ESP is used [17] (Kent, S., “Encapsulating Security Payload (ESP),” December 2005.), see Section 7.5 (Minimum Security Recommendations)). If confidentiality is a concern, it is RECOMMENDED that one of these solutions be used.
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Protection against corruptions (e.g., if an attacker sends forged packets) is achieved by means of a content integrity verification/sender authentication scheme. This service can be provided at the file level, but in that case a receiver has no way to identify which symbol(s) is(are) corrupted if the file is detected as corrupted. This service can also be provided at the packet level. In this case, after removing all corrupted packets, the file may be in some cases recovered. Several techniques can provide this source authentication/content integrity service:
- *
- at the file level, the file MAY be digitally signed, for instance by using RSASSA-PKCS1-v1_5 [30] (Jonsson, J. and B. Kaliski, “Public-Key Cryptography Standards (PKCS) #1: RSA Cryptography Specifications Version 2.1,” February 2003.). This signature enables a receiver to check the file integrity, once this latter has been fully decoded. Even if digital signatures are computationally expensive, this calculation occurs only once per file, which is usually acceptable;
- *
- at the packet level, each packet can be digitally signed [34] (Roca, V., “Simple Authentication Schemes for the ALC and NORM Protocols,” October 2009.). A major limitation is the high computational and transmission overheads that this solution requires. To avoid this problem, the signature may span a set of symbols (instead of a single one) in order to amortize the signature calculation, but if a single symbol is missing, the integrity of the whole set cannot be checked;
- *
- at the packet level, a Group Message Authentication Code (MAC) [31] (Krawczyk, H., Bellare, M., and R. Canetti, “HMAC: Keyed-Hashing for Message Authentication,” February 1997.)[34] (Roca, V., “Simple Authentication Schemes for the ALC and NORM Protocols,” October 2009.) scheme can be used, for instance by using HMAC-SHA-256 with a secret key shared by all the group members, senders and receivers. This technique creates a cryptographically secured digest of a packet that is sent along with the packet. The Group MAC scheme does not create prohibitive processing load nor transmission overhead, but it has a major limitation: it only provides a group authentication/integrity service since all group members share the same secret group key, which means that each member can send a forged packet. It is therefore restricted to situations where group members are fully trusted (or in association with another technique as a pre-check);
- *
- at the packet level, TESLA [32] (Perrig, A., Canetti, R., Tygar, J D., and B. Briscoe, “Timed Efficient Stream Loss-Tolerant Authentication (TESLA): Multicast Source Authentication Transform Introduction,” June 2005.)[33] (Roca, V., Francillon, A., and S. Faurite, “Use of TESLA in the ALC and NORM Protocols,” October 2009.) is an attractive solution that is robust to losses, provides a true authentication/integrity service, and does not create any prohibitive processing load or transmission overhead. Yet checking a packet requires a small delay (a second or more) after its reception;
- *
- at the packet level, IPsec/ESP [17] (Kent, S., “Encapsulating Security Payload (ESP),” December 2005.) can be used to check the integrity and authenticate the sender of all the packets being exchanged in a session (see Section 7.5 (Minimum Security Recommendations)).
Techniques relying on public key cryptography (digital signatures and TESLA during the bootstrap process, when used) require that public keys be securely associated to the entities. This can be achieved by a Public Key Infrastructure (PKI), or by a PGP Web of Trust, or by pre-distributing the public keys of each group member.
Techniques relying on symmetric key cryptography (Group MAC) require that a secret key be shared by all group members. This can be achieved by means of a group key management protocol, or simply by pre-distributing the secret key (but this manual solution has many limitations).
It is up to the developer and deployer, who know the security requirements and features of the target application area, to define which solution is the most appropriate. Nonetheless, in case there is any concern of the threat of file corruption, it is RECOMMENDED that at least one of these techniques be used.
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Let us now consider attacks against the session control parameters and the associated building blocks. The attacker has at least the following opportunities to launch an attack:
- *
- the attack can target the session description,
- *
- the attack can target the FDT Instances,
- *
- the attack can target the ALC/LCT parameters, carried within the LCT header or
- *
- the attack can target the FLUTE associated building blocks, for instance the multiple rate congestion control protocol.
The consequences of these attacks are potentially serious, since they might compromise the behavior of content delivery system itself.
TOC |
A FLUTE receiver may potentially obtain an incorrect Session Description for the session. The consequence of this is that legitimate receivers with the wrong Session Description are unable to correctly receive the session content, or that receivers inadvertently try to receive at a much higher rate than they are capable of, thereby possibly disrupting other traffic in the network.
To avoid these problems, it is RECOMMENDED that measures be taken to prevent receivers from accepting incorrect Session Descriptions. One such measure is source authentication to ensure that receivers only accept legitimate Session Descriptions from authorized senders. How these measures are achieved is outside the scope of this document since this session description is usually carried out-of-band.
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Corrupting the FDT Instances is one way to create a Denial of Service attack. For example, the attacker changes the MD5 sum associated to a file. This possibly leads a receiver to reject the files received, no matter whether the files have been correctly received or not.
Corrupting the FDT Instances is also a way to make the reception process more costly than it should be. This can be achieved by changing the FEC Object Transmission Information when the FEC Object Transmission Information is included in the FDT Instance. For example, an attacker may corrupt the FDT Instance in such a way that Reed-Solomon over GF(2^^16) be used instead of GF(2^^8) with FEC Encoding ID 2. This may significantly increase the processing load while compromising FEC decoding.
It is therefore RECOMMENDED that measures be taken to guarantee the integrity and to check the sender's identity of the FDT Instances. To that purpose, one of the counter-measures mentioned above (Section 7.2.2 (File corruption)) SHOULD be used. These measures will either be applied on a packet level, or globally over the whole FDT Instance object. Additionally, XML digital signatures [25] (Eastlake, D., Reagle, J., and D. Solo, “(Extensible Markup Language) XML-Signature Syntax and Processing,” March 2002.) are a way to protect the FDT Instance by digitally signing it. When there is no packet level integrity verification scheme, it is RECOMMENDED to rely on XML digital signatures of the FDT Instances.
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By corrupting the ALC/LCT header (or header extensions) one can execute attacks on underlying ALC/LCT implementation. For example, sending forged ALC packets with the Close Session flag (A) set to one can lead the receiver to prematurely close the session. Similarly, sending forged ALC packets with the Close Object flag (B) set to one can lead the receiver to prematurely give up the reception of an object.
It is therefore RECOMMENDED that measures be taken to guarantee the integrity and to check the sender's identity of the ALC packets received. To that purpose, one of the counter-measures mentioned above (Section 7.2.2 (File corruption)) SHOULD be used.
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Let us first focus on the congestion control building block, that may be used in the ALC session. A receiver with an incorrect or corrupted implementation of the multiple rate congestion control building block may affect the health of the network in the path between the sender and the receiver. That may also affect the reception rates of other receivers who joined the session.
When congestion control building block is applied with FLUTE, it is therefore RECOMMENDED that receivers be required to identify themselves as legitimate before they receive the Session Description needed to join the session. How receivers identify themselves as legitimate is outside the scope of this document. If authenticating a receiver does not prevent this latter to launch an attack, it will enable the network operator to identify him and to take counter-measures.
When congestion control building block is applied with FLUTE, it is also RECOMMENDED that a packet level authentication scheme be used, as explained in Section 7.2.2 (File corruption). Some of them, like TESLA, only provide a delayed authentication service, whereas congestion control requires a rapid reaction. It is therefore RECOMMENDED [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.) that a receiver using TESLA quickly reduces its subscription level when the receiver believes that a congestion did occur, even if the packet has not yet been authenticated. Therefore TESLA will not prevent DoS attacks where an attacker makes the receiver believe that a congestion occurred. This is an issue for the receiver, but this will not compromise the network. Other authentication methods that do not feature this delayed authentication could be preferred, or a group MAC scheme could be used in parallel to TESLA to prevent attacks launched from outside of the group.
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Lastly, we note that the security considerations that apply to, and are described in, ALC [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.), LCT [3] (Luby, M., Watson, M., and L. Vicisano, “Layered Coding Transport (LCT) Building Block,” October 2009.) and FEC [4] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.) also apply to FLUTE as FLUTE builds on those specifications. In addition, any security considerations that apply to any congestion control building block used in conjunction with FLUTE also apply to FLUTE.
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We now introduce a mandatory to implement but not necessarily to use security configuration, in the sense of [23] (Schiller, J., “Strong Security Requirements for Internet Engineering Task Force Standard Protocols,” August 2002.). Since FLUTE relies on ALC/LCT, it inherits the "baseline secure ALC operation" of [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.). More precisely, security is achieved by means of IPsec/ESP in transport mode. [17] (Kent, S., “Encapsulating Security Payload (ESP),” December 2005.) explains that ESP can be used to potentially provide confidentiality, data origin authentication, content integrity, anti-replay and (limited) traffic flow confidentiality. [2] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” November 2009.) specifies that the data origin authentication, content integrity and anti-replay services SHALL be used, and that the confidentiality service is RECOMMENDED. If a short lived session MAY rely on manual keying, it is also RECOMMENDED that an automated key management scheme be used, especially in case of long lived sessions.
Therefore, the RECOMMENDED solution for FLUTE provides per-packet security, with data origin authentication, integrity verification and anti-replay. This is sufficient to prevent most of the in-band attacks listed above. If confidentiality is required, a per-packet encryption SHOULD also be used.
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This specification contains three separate items for IANA Considerations:
- 1.
- Registration Request for XML Schema of FDT Instance.
- 2.
- Media-Type Registration Request for application/fdt+xml.
- 3.
- Content Encoding Algorithm Registration Request.
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Document [29] (Mealling, M., “The IETF XML Registry,” January 2004.) defines an IANA maintained registry of XML documents used within IETF protocols. The following is the registration request for the FDT XML schema.
Registrant Contact: Toni Paila (toni.paila (at) nokia.com)
XML: The XML Schema specified in Section 3.4.2 (Syntax of FDT Instance)
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This section provides the registration request, as per [26] (Freed, N. and J. Klensin, “Media Type Specifications and Registration Procedures,” December 2005.), [27] (Freed, N. and J. Klensin, “Multipurpose Internet Mail Extensions (MIME) Part Four: Registration Procedures,” December 2005.) and [10] (Murata, M., St.Laurent, S., and D. Kohn, “XML Media Types,” January 2001.), to be submitted to IANA following IESG approval.
Type name: application
Subtype name: fdt+xml
Required parameters: none
Optional parameters: none
Encoding considerations: The fdt+xml type consists of UTF-8 ASCII characters [11] (Yergeau, F., “UTF-8, a transformation format of ISO 10646,” November 2003.) and must be well-formed XML.
Additional content and transfer encodings may be used with fdt+xml files, with the appropriate encoding for any specific file being entirely dependant upon the deployed application.
Restrictions on usage: Only for usage with FDT Instances which are valid according to the XML schema of section 3.4.2.
Security considerations: fdt+xml data is passive, and does not generally represent a unique or new security threat. However, there is some risk in sharing any kind of data, in that unintentional information may be exposed, and that risk applies to fdt+xml data as well.
Interoperability considerations: None
Published specification: The present document including section 3.4.2. The specified FDT Instance functions as an actual media format of use to the general Internet community and thus media type registration under the Standards Tree is appropriate to maximize interoperability.
Applications which use this media type: Not restricted to any particular application
Additional information:
Magic number(s): none File extension(s): An FDT Instance may use the extension ".fdt" but this is not required. Macintosh File Type Code(s): none
Person and email address to contact for further information: Toni Paila (toni.paila (at) nokia.com)
Intended usage: Common
Author/Change controller: IETF
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Values of Content Encoding Algorithms are subject to IANA registration. The value of Content Encoding Algorithm is a numeric non-negative index. In this document, the range of values for Content Encoding Algorithms is 0 to 255. This specification already assigns the values 0, 1, 2 and 3 as described in section 3.4.3.
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This document defines a name-space called "Content Encoding Algorithms".
IANA has established and manages the new registry for the "Content Encoding Algorithm" name-space. The values that can be assigned within this name-space are numeric indexes in the range [0, 255], boundaries included. Assignment requests are granted on a "Specification Required" basis as defined in RFC 2434 [12] (Narten, T. and H. Alvestrand, “Guidelines for Writing an IANA Considerations Section in RFCs,” May 2008.). Note that the values 0, 1, 2 and 3 of this registry are already assigned by this document as described in section 3.4.3.
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The following persons have contributed to this specification: Brian Adamson, Mark Handley, Esa Jalonen, Roger Kermode, Juha-Pekka Luoma, Topi Pohjolainen, Lorenzo Vicisano, and Mark Watson. The authors would like to thank all the contributors for their valuable work in reviewing and providing feedback regarding this specification.
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Jani Peltotalo
Tampere University of Technology
P.O. Box 553 (Korkeakoulunkatu 1)
Tampere FIN-33101
Finland
Email: jani.peltotalo (at) tut.fi
Sami Peltotalo
Tampere University of Technology
P.O. Box 553 (Korkeakoulunkatu 1)
Tampere FIN-33101
Finland
Email: sami.peltotalo (at) tut.fi
Magnus Westerlund
Ericsson Research
Ericsson AB
SE-164 80 Stockholm
Sweden
EMail: magnus.westerlund (at) ericsson.com
Thorsten Lohmar
Ericsson Research (EDD)
Ericsson Allee 1
52134 Herzogenrath, Germany
EMail: thorsten.lohmar (at) ericsson.com
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Added clarification for the use of FLUTE for unicast communications in Section 1.1.4 (Weaknesses).
Clarified how to reliably deliver the FDT in Section 3.3 (Dynamics of FDT Instances within file delivery session) and the possibility of using an out-of-band delivery of FDT information.
Clarified how to address FDT Instance expiry time wraparound with the notion of "epoch" of NTPv4 in Section 3.3 (Dynamics of FDT Instances within file delivery session).
Clarified what should be considered as erroneous situations in Section 3.4.1 (Format of FDT Instance Header) (definition of FDT Instance ID). In particular a receiver MUST be ready to handle FDT Instance ID wraparounds and missing FDT Instances.
Updated the security section to define IPsec/ESP as a mandatory to implement security solution in Section 7.5 (Minimum Security Recommendations).
Removed the 'Statement of Intent' from the Section 1 (Introduction). The statement of intent was meant to clarify the "Experimental" status of RFC3926. It does not apply to this draft that is intended for "Standard Track" submission.
Added clarification on XML-DSIG in the end of Section 3 (File delivery).
Revised the use of word "complete" in the Section 3.2 (File Delivery Table).
Clarified Figure 1 (Overall FDT Packet) WRT "Encoding Symbol(s) for FDT Instance".
Clarified the FDT Instance ID wrap-around in the end of Section 3.4.1 (Format of FDT Instance Header).
Clarification for "Complete FDT" in the Section 3.4.2 (Syntax of FDT Instance).
Added semantics for the case two TOIs refer to same Content-Location. Now it is in line how 3GPP and DVB interpret the case.
In the Section 3.4.2 (Syntax of FDT Instance) XML Schema of FDT instance is modified to various advices. For example, extension by element was missing but is now supported. Also namespace definition is changed to URN format.
Clarified FDT-schema extensibility in the end of Section 3.4.2 (Syntax of FDT Instance).
The CENC value allocation is added in the end of Section 3.4.3 (Content Encoding of FDT Instance).
Section 5 (Delivering FEC Object Transmission Information) is modified so that EXT_FTI and the FEC issues are replaced by a reference to LCT specification. We count on revised LCT specification to specify the EXT_FTI.
Added a clarifying paragraph on the use of Codepoint in the very end of Section 5 (Delivering FEC Object Transmission Information).
Reworked Section 8 (IANA Considerations) - IANA Considerations. Now it contains three IANA registration requests:
- *
- Registration Request for XML Schema of FDT Instance (urn:ietf:params:xml:schema:fdt)
- *
- Media-Type Registration Request for application/fdt+xml
- *
- Content Encoding Algorithm Registration Request (ietf:rmt:cenc)
Added Section 10 (Contributors) - Contributors.
Revised list of both Normative as well as Informative references.
Added a clarification that receiver should ignore reserved bits of Header Extension type 193 upon reception.
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TOC |
[1] | Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” RFC 2119, BCP 14, March 1997. |
[2] | Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” draft-ietf-rmt-pi-alc-revised-10 (work in progress), November 2009 (TXT). |
[3] | Luby, M., Watson, M., and L. Vicisano, “Layered Coding Transport (LCT) Building Block,” RFC 5651, October 2009. |
[4] | Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” RFC 5052, August 2007. |
[5] | Watson, M., “Basic Forward Error Correction (FEC) Schemes,” RFC 5445, March 2009. |
[6] | Mills, D., “Network Time Protocol (Version 3), Specification, Implementation and Analysis,” RFC 1305, March 1992. |
[7] | Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” RFC 2616, June 1999. |
[8] | Thompson, H., Beech, D., Maloney, M., and N. Mendelsohn, “XML Schema Part 1: Structures,” W3C Recommendation, May 2001. |
[9] | Biron, P. and A. Malhotra, “XML Schema Part 2: Datatypes,” W3C Recommendation, May 2001. |
[10] | Murata, M., St.Laurent, S., and D. Kohn, “XML Media Types,” RFC 3023, January 2001. |
[11] | Yergeau, F., “UTF-8, a transformation format of ISO 10646,” RFC 3629, November 2003. |
[12] | Narten, T. and H. Alvestrand, “Guidelines for Writing an IANA Considerations Section in RFCs,” RFC 5226, May 2008. |
[13] | Deutsch, P. and J-L. Gailly, “ZLIB Compressed Data Format Specification version 3.3,” RFC 1950, May 1996. |
[14] | Deutsch, P., “DEFLATE Compressed Data Format Specification version 1.3,” RFC 1951, May 1996. |
[15] | Deutsch, P., “GZIP file format specification version 4.3,” RFC 1952, May 1996. |
[16] | Luby, M. and V. Goyal, “Wave and Equation Based Rate Control (WEBRC) Building Block,” RFC 3738, April 2004. |
[17] | Kent, S., “Encapsulating Security Payload (ESP),” RFC 4303, December 2005. |
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[18] | Handley, M., Perkins, C., and E. Whelan, “Session Announcement Protocol,” RFC 2974, October 2000. |
[19] | Handley, M., Jacobson, V., and C. Perkins, “Session Description Protocol,” RFC 4566, July 2006. |
[20] | Deering, S., “Host Extensions for IP Multicasting,” RFC 1112, STD 5, August 1989. |
[21] | Holbrook, H., “A Channel Model for Multicast, Ph.D. Dissertation, Stanford University, Department of Computer Science, Stanford, California,” August 2001. |
[22] | Kasch, W., Mills, D., and J. Burbank, “Network Time Protocol Version 4 Protocol And Algorithms Specification,” draft-ietf-ntp-ntpv4-proto-13 (work in progress) (work in progress), October 2009. |
[23] | Schiller, J., “Strong Security Requirements for Internet Engineering Task Force Standard Protocols,” BCP 61, RFC 3365, August 2002. |
[24] | Ramsdell, B., “Secure/Multipurpose Internet Mail Extensions (S/MIME) Version 3.1 Message Specification,” RFC 3851, July 2004. |
[25] | Eastlake, D., Reagle, J., and D. Solo, “(Extensible Markup Language) XML-Signature Syntax and Processing,” RFC 3275, March 2002. |
[26] | Freed, N. and J. Klensin, “Media Type Specifications and Registration Procedures,” RFC 4288, December 2005. |
[27] | Freed, N. and J. Klensin, “Multipurpose Internet Mail Extensions (MIME) Part Four: Registration Procedures,” RFC 4289, December 2005. |
[28] | Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston, A., Peterson, J., Sparks, R., Handley, M., and E. Schooler, “SIP: session initiation protocol,” RFC 3261, June 2002. |
[29] | Mealling, M., “The IETF XML Registry,” RFC 3688, January 2004. |
[30] | Jonsson, J. and B. Kaliski, “Public-Key Cryptography Standards (PKCS) #1: RSA Cryptography Specifications Version 2.1,” RFC 3447, February 2003. |
[31] | Krawczyk, H., Bellare, M., and R. Canetti, “HMAC: Keyed-Hashing for Message Authentication,” RFC 2104, February 1997. |
[32] | Perrig, A., Canetti, R., Tygar, J D., and B. Briscoe, “Timed Efficient Stream Loss-Tolerant Authentication (TESLA): Multicast Source Authentication Transform Introduction,” RFC 4082, June 2005. |
[33] | Roca, V., Francillon, A., and S. Faurite, “Use of TESLA in the ALC and NORM Protocols,” draft-ietf-msec-tesla-for-alc-norm-10.txt (work in progress), October 2009. |
[34] | Roca, V., “Simple Authentication Schemes for the ALC and NORM Protocols,” draft-ietf-rmt-simple-auth-for-alc-norm-02.txt (work in progress), October 2009. |
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This section gives an example how the receiver of the file delivery session may operate. Instead of a detailed state-by-state specification the following should be interpreted as a rough sequence of an envisioned file delivery receiver.
- 1.
- The receiver obtains the description of the file delivery session identified by the pair: (source IP address, Transport Session Identifier). The receiver also obtains the destination IP addresses and respective ports associated with the file delivery session.
- 2.
- The receiver joins the channels in order to receive packets associated with the file delivery session. The receiver may schedule this join operation utilizing the timing information contained in a possible description of the file delivery session.
- 3.
- The receiver receives ALC/LCT packets associated with the file delivery session. The receiver checks that the packets match the declared Transport Session Identifier. If not, packets are silently discarded.
- 4.
- While receiving, the receiver demultiplexes packets based on their TOI and stores the relevant packet information in an appropriate area for recovery of the corresponding file. Multiple files can be reconstructed concurrently.
- 5.
- Receiver recovers an object. An object can be recovered when an appropriate set of packets containing Encoding Symbols for the transmission object have been received. An appropriate set of packets is dependent on the properties of the FEC Encoding ID and FEC Instance ID, and on other information contained in the FEC Object Transmission Information.
- 6.
- If the recovered object was an FDT Instance with FDT Instance ID 'N', the receiver parses the payload of the instance 'N' of FDT and updates its FDT database accordingly. The receiver identifies FDT Instances within a file delivery session by the EXT_FDT header extension. Any object that is delivered using EXT_FDT header extension is an FDT Instance, uniquely identified by the FDT Instance ID. Note that TOI '0' is exclusively reserved for FDT delivery.
- 7.
- If the object recovered is not an FDT Instance but a file, the receiver looks up its FDT database to get the properties described in the database, and assigns file with the given properties. The receiver also checks that received content length matches with the description in the database. Optionally, if MD5 checksum has been used, the receiver checks that calculated MD5 matches with the description in the FDT database.
- 8.
- The actions the receiver takes with imperfectly received files (missing data, mismatching digestive, etc.) is outside the scope of this specification. When a file is recovered before the associated file description entry is available, a possible behavior is to wait until an FDT Instance is received that includes the missing properties.
- 9.
- If the file delivery session end time has not been reached go back to 3. Otherwise end.
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<?xml version="1.0" encoding="UTF-8"?> <FDT-Instance xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="urn:ietf:params:xml:ns:fdt ietf-flute-fdt.xsd" Expires="2890842807"> <File Content-Location="http://www.example.com/menu/tracklist.html" TOI="1" Content-Type="text/html"/> <File Content-Location="http://www.example.com/tracks/track1.mp3" TOI="2" Content-Length="6100" Content-Type="audio/mp3" Content-Encoding="gzip" Content-MD5="+VP5IrWploFkZWc11iLDdA==" Some-Private-Extension-Tag="abc123"/> </FDT-Instance>
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Toni Paila | |
Nokia | |
Itamerenkatu 11-13 | |
Helsinki 00180 | |
Finland | |
Email: | toni.paila@nokia.com |
Rod Walsh | |
Nokia | |
Visiokatu 1 | |
Tampere FIN-33720 | |
Finland | |
Email: | rod.walsh@nokia.com |
Michael Luby | |
Qualcomm, Inc. | |
3165 Kifer Rd. | |
Santa Clara, CA 95051 | |
US | |
Email: | luby@qualcomm.com |
Vincent Roca | |
INRIA | |
655, av. de l'Europe | |
Inovallee; Montbonnot | |
ST ISMIER cedex 38334 | |
France | |
Email: | vincent.roca@inria.fr |
Rami Lehtonen | |
TeliaSonera | |
Hatanpaan valtatie 18 | |
Tampere FIN-33100 | |
Finland | |
Email: | rami.lehtonen@teliasonera.com |