Network Working Group L.D. Deng
Internet-Draft J.P. Peng
Intended status: Informational China Mobile
Expires: January 03, 2014 Y.Z. Zhang
CoolPad
July 02, 2013

Efficient Chunk Availability Compression for PPSP
draft-deng-ppsp-bfbitmap-00.txt

Abstract

This document proposes to employ bloom filter algorithms in compressing chunk availability information in exchange between peers and the tracker through the PPSP-TP protocol and PPSPP protocol.

Status of This Memo

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Table of Contents

1. Introduction

As it is pointed out by [I-D.ietf-ppsp-problem-statement], current practices often use a "bitmap" message in order to exchange chunk availability. The message is of kilobytes in size and exchanged frequently, e.g., an interval of several seconds or less.

To begin with, in a mobile environment with scarce bandwidth, the message size may need to be shortened or it may require more efficient methods for expressing and distributing chunk availability information, which is different from wire-line P2P streaming.

Even in a wire-line P2P streaming application, frequent exchange of large volume of bitmap information, is among the key factors that set a limit to the system's efficiency and scalability [P2P-limit].

Therefore, the following requirements for PPSP protocols in terms of chunk availability exchange are stated in [I-D.ietf-ppsp-problem-statement] :

To this end, we propose to employ bloom filter algorithms in compressing chunk availability information in exchange between peers and the tracker through the PPSP-TP protocol and PPSPP protocol, in view of its widely demonstrated high compacted data structure and low complexity and cost in storage, transportation and computation.

2. Background on Bloom Filter

Bloom Filter (or BF for short) was first introduced in 1970s [BF-bloom], which makes use of multiple hashing functions to build a mapping from a set to a compact binary array, for the purpose of highly efficient member queries with a tolerably low error rate of wrongly reported hits. Despite their extraordinary efficiency in terms of storage reduction and query acceleration, bloom filters suffer from the fact that there is possibility that a non-member of the set be taken as a member after the query. However, research [BF-analysis] shows that the odds that a BF makes an erroneous query response can be suppressed to near zero, by tactful selection and configuration of various system parameters, including the hash functions used, the number of hash functions to be used, and the length of the bit array.

						

------------------------------------------------
BF(set S, integer m, hash set H)          
1 filter=allocate m bits initialized to 0;
2 for each xi in S do                     
3 for each hash functions hi in H do      
4 filter[hi(xi)]=1;                       
5 return filter;                          
-------------------------------------------------
MT(element elm, BF filter, integar m, hash set H)
1 for each hash functions hi in H do             
2 if (filter[hi(elm)]!=1)                       
3 return false;                                 
4 return true;                                              
-------------------------------------------------
						
						

Figure 1: Basic algorithms for BF-bitmap

More specifically, as shown in Figure 1, the BF(S,m) algorithm takes a n-membered sub-set S={x1,x2,...,xn} from a universal set U, as input and outputs a m-bit binary array B as a compacted representation of S. In order to do that, it makes use of k independent random hash functions, each of which maps a member to a bit in B (i.e hj: U-> [1,m], j=1...k) by marking all the k bits mapped from each member of S. The BF algorithm is highly efficient in the following aspects:

For instance, given a 2GB movie file, the original bitmap for a sharing peer would be 1024-bit, if using 2MB-sized chunks. By simply using 4 random hash functions and a 128-bit BF-bitmap, the possibility of erroneous hits by MT algorithm would be lower than 3%.

As for a simple illustration, the 4 hash functions may be established through the MD5 message-digest algorithm [RFC1321], a widely used cryptographic hash function that produces a 128-bit (16-byte) hash value from an arbitrary binary input. MD5 has been utilized in a wide variety of security applications, and is also commonly used to check data integrity.

Specifically, the processing of 4 hash functions is as follows: use the MD5 algorithm to turn a given chunk_ID into a 128-bit binary array, further separate the 128 bits into 4 arrays (32-bit each), and finally divide each of them using 128 to yield four integers in the range of [1,m].

3. BF-based Chunk Availability Exchange

3.1. A non-BF PPSP session

We borrow the general message flow (shown in Figure 2) from [I-D.ietf-ppsp-base-tracker-protocol] to exemplify the usage of BF-bitmap in PPSP protocols.

						
   +--------+      +--------+     +--------+    +--------+  +-------+
   | Player |      | Peer 1 |     | Portal |    | Tracker|  | Peer 2|
   +--------+      +--------+     +--------+    +--------+  +-------+
       |                |               |              |           |
       |--Page request----------------->|              |           |
       |<--------------Page with links--|              |           |
       |--Select stream (MPD Request)-->|              |           |
       |<--------------------OK+MPD(x)--|              |           |
       |--Start/Resume->|--CONNECT(join x)------------>|           |
       |<-----------OK--|<----------------OK+Peerlist--|           |
       |                |                              |           |
       |--Get(Chunk)--->|<---------- (Peer protocol) ------------->|
       |<--------Chunk--|<---------------------------------Chunks--|
       :                :               :              :           :
       |                |--STAT_REPORT---------------->|           |
       |                |<-------------------------Ok--|           |
       :                :               :              :           :
       |--Get(Chunk)--->|<---------- (Peer protocol) ------------->|
       |<--------Chunk--|<---------------------------------Chunks--|
       :                :               :              :           :
                    	
						

Figure 2: A typical PPSP session for watching a streaming content.

When a peer wants to receive streaming of a selected content (Leech mode):

  1. Peer connects to a connection tracker and joins a swarm.
  2. Peer acquires a list of other peers in the swarm from the connection tracker.
  3. Peer exchanges its content availability with the peers on the obtained peer list (via peer protocol).
  4. Peer identifies the peers with desired content.
  5. Peer requests content from the identified peers (peer protocol).

When a peer wants to share streaming contents (Seeder mode) with other peers:

  1. Peer connects to the connection tracker.
  2. Peer sends information to the connection tracker about the swarms it belongs to (joined swarms).

3.2. A PPSP Session with BF-bitmaps

This document proposes to employ bloom filter algorithms in compressing chunk availability information in exchange between peers and the tracker through the PPSP-TP protocols and PPSPP protocol. The key modifications to the current protocols are summarized as follows: (as shown in Figure 3)

						
   +--------+      +--------+     +--------+    +--------+  +-------+
   | Player |      | Peer 1 |     | Portal |    | Tracker|  | Peer 2|
   +--------+      +--------+     +--------+    +--------+  +-------+
       |                |               |              |           |
  (a1) |--Page request----------------->|              |           |
       |<----Page with links(+BF conf)--|              |           |
       |--Select stream (MPD Request)-->|              |           |
       |<----------OK+MPD(x)(+BF conf)--|              |           |
  (a2) |--Start/Resume->|--CONNECT(join x)------------>|           |
       |<-----------OK--|<------OK(+BF conf)+Peerlist--|           |
       |                |                              |           |
  (c1) |                |<------------ HAVE(BF(S2))----------------|
  (c2) |-Get(Chunk s1)->|               |              |           |
  (c3) |                |------------- REQUEST(BF(s1))------------>|
       |<--------Chunk--|<---------------------------------Chunks--|
       :                :               :              :           :
  (a3) |                |-STAT_REPORT(BF(ContentMap))->|           |
       |                |<-------------------------Ok--|           |
       :                :               :              :           :
       |--Get(Chunk)--->|<---------- (Peer protocol) ------------->|
       |<--------Chunk--|<---------------------------------Chunks--|
       :                :               :              :           :
                    	
						

Figure 3: A typical PPSP session with BF-bitmaps.

  1. Integration to the base TP protocol:
    • (a1-a2)Configuration Setup: m, The length of the output bit array and H, the hash functions in use, are system level parameters that should be configured globally and stored at the tracker and published to a joining peer through the TP protocols.
    • (a3)Peers use the BF(S,m,H) algorithm for compressing the subset of locally stored and integrity verified chunks (set S) in terms of a given swarm-ID, whenever reporting or updating its chunk availability information with the tracker. The length of each BF-bitmap is constant (O(m)).
    • In response to a JOIN request from a peer, the tracker may accompany the returned peer list with each recommended peer's BF-formed chunk availability bitmap, as the initial guidance for the requestor to start looking for neighbors in the same swarm. The additional cost for bearing the chunk-level availability information is constant (O(m)).

  2. Integration to the extended TP protocol:
    • Peers use the BF(S,m,H) algorithm for indicating its query intention in the FIND request for a specific chunk sub set S' of the given swarm to the tracker or the other peer. The additional cost for bearing the chunk set is constant (O(m)).
    • In response to a FIND request with specific chunk set S' in need from a peer, the tracker performs the subset containment check on the query set parameter BF(S' against each registered peer's chunk availability BF(S) by three simple binary operations to decided whether or not include the peer into the peer list in return: check if "F(S) equals (BF(S) bitwise OR (BF(S) bitwise XOR BF(S'))" holds. The computation cost for each subset check is constant (O(m)).

  3. Integration to the peer protocol:
    • Peers use the BF(S,m,H) algorithm for compressing the subset of locally stored and integrity verified chunks (set S) in terms of a given swarm-ID, whenever reporting or updating its chunk availability information with another peer. The length of each BF-bitmap is constant (O(m)).
    • For a downloading peer to decide which neighbor to request for a given chunk_ID s, it uses the member query algorithm MT(s,bf,m,H) on each neighbor's BF-bitmap bf. The computation cost for this member check is constant (O(m)).

4. Open Issues

4.1. Algorithm Configuration Setup

As stated earlier, the BF scheme is based on a mutual arrangement between the information requestor and the responder of the basic settings for the hash algorithms (both the number of them and the specific ones) in use and the coded bitmap's binary length. In other words, there SHOULD be a way of configuration setup mechanism in a local system.

To serve as the input for further discussion, we provide two initial proposals here:

  • Option1: Centralized Server for Uniform Configuration: The most simple and straightforward way would be to set up a logically centralized configuration server to do the trick. For instance, the RELOAD base protocol introduces such a configuration server to synchronize the hash function for the P2P DHT before a peer/client joins in the overlay [I-D.ietf-p2psip-base]. The most simple and straightforward way would be to set up a logically centralized configuration server to do the trick. For instance, the RELOAD base protocol introduces such a configuration server to synchronize the hash function for the P2P DHT before a peer/client joins in the overlay [I-D.ietf-p2psip-base]. There are two potential ways to integrate into the base TP protocol's enrollment and bootstrap process: The Publishing and Searching Portal could serve as a configuration server and return the BF configuration information to the peer through player, either
    • via the page returned in response to a web page request, or
    • via the MPD(Media Presentation Description) file in response to a MPD request.

  • Option2: Configuration Exchange as Joining in a SWARM: In view of the interworking usage of PPSP as a generally accepted suite of protocols to bridging different P2P systems, who may differ in specific choice of hash functions and other parameters, there SHOULD be a way of parameter negotiation mechanism across different systems. Negotiation may also introduce flexibility in a single system. E.g. large files or mobile peers may prefer more compact way of exchanging this information. Therefore, the tracker could include a swarm-specific BF configuration parameters into the OK response to the JOIN request from a new-coming peer (as labeled by (a2) in Figure 3).

5. Security Considerations

TBA

6. IANA Considerations

None.

7. References

7.1. Normative References

[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2234] Crocker, D. and P. Overell, "Augmented BNF for Syntax Specifications: ABNF", RFC 2234, November 1997.

7.2. Informative References

[I-D.ietf-ppsp-problem-statement] Zhang, Y. and N. Zong, "Problem Statement and Requirements of Peer-to-Peer Streaming Protocol (PPSP)", draft-ietf-ppsp-problem-statement-12 (work in progress), January 2013.
[P2P-limit] Feng, C., Li, B. and B. Li, "Understanding the performance gap between pull-based mesh streaming protocols and fundamental limits", in Proc. of IEEE INFOCOM , 2009.
[I-D.ietf-ppsp-base-tracker-protocol] Cruz, R., Nunes, M., Gu, Y., Xia, J. and J. Taveira, "PPSP Tracker Protocol-Base Protocol (PPSP-TP/1.0)", draft-ietf-ppsp-base-tracker-protocol-00 (work in progress), February 2013.
[I-D.ietf-huang-extended-tracker-protocol] Huang, R., Zong, N., Cruz, R., Nunes, and J. Taveira, "PPSP Tracker Protocol-Extended Protocol", draft-ietf-huang-extended-tracker-protocol-02 (work in progress), February 2013.
[BF-bloom] Bloom, B.H., "Space/time trade-offs in hash coding with allowable errors.", Communications of ACM Vol. 13, No. 7, pp. 422-426, 1970.
[BF-analysis] Broder, A. and M. Mitzenmacher, "Network applications of Bloom Filters: a survey", Internet Mathematics Vol. 1, No. 4, pp. 485–509, 2004.
[RFC1321] Rivest, and Newport, "RFC 1321: The MD5 message-digest algorithm", draft-ietf-p2psip-base-26 (work in progress), April 1992.
[I-D.ietf-p2psip-base] Jennings, C., Lowekamp, B., Rescorla, E., Baset, S. and H. Schulzrinne, "REsource LOcation And Discovery (RELOAD) Base Protocol", February 2013.

Authors' Addresses

Lingli Deng China Mobile EMail: denglingli@chinamobile.com
Jin Peng China Mobile EMail: pengjin@chinamobile.com
Yunfei Zhang CoolPad EMail: hishigh@gmail.com