One document matched: draft-wei-tsvwg-tunnel-congestion-feedback-01.txt
Differences from draft-wei-tsvwg-tunnel-congestion-feedback-00.txt
Internet Engineering Task Force X. Wei
INTERNET-DRAFT L.Zhu
Intended Status: Informational Huawei Technologies
Expires: August 15, 2014 L.Deng
China Mobile
February 11, 2014
Tunnel Congestion Feedback
draft-wei-tsvwg-tunnel-congestion-feedback-01
Abstract
This document describes a mechanism to calculate congestion of a
tunnel segment based on RFC 6040 recommendations, and a feedback
protocol by which to send the measured congestion of the tunnel from
egress to ingress router. A basic model for measuring tunnel
congestion and congestion information feeding back is described, and
a protocol for congestion information feeding back is outlined.
Status of this Memo
This Internet-Draft is submitted to IETF in full conformance with the
provisions of BCP 78 and BCP 79.
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Copyright and License Notice
Copyright (c) 2014 IETF Trust and the persons identified as the
document authors. All rights reserved.
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This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Conventions and Terminology . . . . . . . . . . . . . . . . . . 3
2.1 Conventions . . . . . . . . . . . . . . . . . . . . . . . . 3
2.2 Terminology . . . . . . . . . . . . . . . . . . . . . . . . 3
3. Problem Statement . . . . . . . . . . . . . . . . . . . . . . . 4
3.1 3GPP network scenario . . . . . . . . . . . . . . . . . . . 5
3.2 Network Function Virtualization Scenario . . . . . . . . . . 6
4. Congestion Model . . . . . . . . . . . . . . . . . . . . . . . 8
4.1 Congestion Calculation . . . . . . . . . . . . . . . . . . . 8
4.2 Congestion Feedback . . . . . . . . . . . . . . . . . . . . 9
5. Congestion Feedback Protocol . . . . . . . . . . . . . . . . . 11
5.1 Properties of Candidate Protocol . . . . . . . . . . . . . . 11
5.2 IPFIX Extensions for Congestion Feedback . . . . . . . . . . 11
5.3 Other Protocols . . . . . . . . . . . . . . . . . . . . . . 15
6. Security Considerations . . . . . . . . . . . . . . . . . . . . 16
7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . . 16
8. References . . . . . . . . . . . . . . . . . . . . . . . . . . 16
8.1 Normative References . . . . . . . . . . . . . . . . . . . 16
8.2 Informative References . . . . . . . . . . . . . . . . . . 17
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 17
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1. Introduction
This document describes a mechanism for feedback of congestion
observed in IP-in-IP tunnels (also referred to as IP tunnels). Common
tunnel deployments such as mobile backhaul networks, VPNs and other
IP-in-IP tunnels can be congested as a result of sustained high load.
Network providers use a number of methods to deal with high load
conditions including proper network dimensioning, policies for
preferential flow treatment and selective offloading among others.
The mechanism proposed in this document is expected to complement
them and provide congestion information that to allow making better,
policies and decisions.
The model and general solution proposed in chapter 4 consist of
identifying congestion marks set in the tunnel segment, and feeding
back the congestion information from the egress to the ingress of the
tunnel. Measuring congestion of a tunnel segment is based on counting
outer packet CE marks for packets that have ECT marks in the inner
packet. This proposal depends on statistical marking of congestion
and uses the method described in RFC 6040 [RFC6040], Appendix C.
Chapter 5 describes the protocol mechanisms to feed back the
calculated congestion information from egress to ingress. The desired
properties of the congestion information conveying protocol are
outlined, and IPFIX [RFC5101] as a candidate protocol for these
extensions is explored further.
2. Conventions and Terminology
2.1 Conventions
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119 [RFC2119]
2.2 Terminology
Tunnel: A channel over which encapsulated packets traverse
across a network.
Encapsulation: The process of adding control information as it passes
through the layered model.
Encapsulator: The tunnel endpoint function that adds an outer IP
header to tunnel a packet, the encapsulator is
considered as the "ingress" of the tunnel.
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Decapsulator: The tunnel endpoint function that removes an outer IP
header from a tunneled packet, the decapsulator is
considered as the "egress" of the tunnel.
Outer header: The header added to encapsulate a tunneled packet.
Inner header: The header encapsulated by the outer header.
E2E: End to End.
VPN: Virtual Private Network is a technology for using the
Internet or another intermediate network to connect
computers to isolated remote computer networks that
would otherwise be inaccessible.
GRE: Generic Routing Encapsulation.
IPFIX IP Flow Information Export. An IETF protocol to export
flow information from routers and other devices.
RED Random Early Detection
NFV Network Functions Virtualization is an alternative design
approach for building complex IT applications,
particularly in the telecommunications and service
provider industries, that virtualizes entire classes
of function into building blocks that may be
connected, or chained, together to create services.
VNF Virtualized Network Function may consist of one or more virtual
machines running different software and processes,
which form the building blocks for NFV.
SFC Service Function Chain is a group of connected VNF in a specific
sequence/map using NFV approach, in order to deliver a
specific service.
3. Problem Statement
Network traffic congestion plays an important role in network
performance, and the congestion level could impact subscriber's
experience significantly. Currently the solution of network
congestion problem mainly focuses on end-to-end method, i.e. ECN
[RFC3168], and the end hosts are in charge of reduce traffic rates in
case of network congested. But sometimes it's not always reliable to
dependent on end hosts to solve the congestion situation, because
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some end hosts may not support ECN, or even ECN is supported by end
hosts some traffics, e.g. UDP-based traffic, may not support ECN.
Though the congestion happens in operator's network, but because the
congestion information is transparent to operator, so it's hard for
operator to take action to control the network traffic in case of
network congested. To improve the performance of the network, it's
better for operator to take network congestion situation into network
traffic management.
Many kinds of tunnels are widely deployed in current networks, even
in some scenarios all traffics travel in the network through
designated tunnel(s).
Because the ingress and egress of tunnel are usually deployed by
operator, so it's easy for operator to have control on them, and it's
feasible for operator to collect network congestion information in
the tunnel. After obtaining congestion information, operator could
make policy for traffic management taking these information into
consideration.
ECN handling mechanisms in RFC 6040 specifies how ECN should be
handled for tunneling. In addition, RFC 6040, Appendix C provides
guidance on how to calculate congestion experienced in the tunnel
itself. However, there is no standardized mechanism by which the
congestion information inside the tunnel can be fed back from egress
to ingress router.
In the following sub-sections, some network tunnel scenarios are
discussed.
3.1 3GPP network scenario
Tunnels, including GRE [RFC2784], GTP [TS29.060], IP-in-IP [RFC2003]
or IPSec [RFC4301] etc, are widely deployed in 3GPP networks. And in
3GPP network tunnels are used to carry end user flows within the
backhaul network such as shown in Figure 1.
IP backhaul networks such as those of mobile networks are provisioned
and managed to provide the subscribed levels of end user service.
These networks are traffic engineered, and have defined mechanisms
for providing differentiated services and QoS per user or flow.
Policy to configure per user flow attributes in these networks have
traditionally been based on monitoring and static configuration.
Currently, these networks are increasingly used for applications that
demand high bandwidth. The nature of the flows and length of end user
sessions can lead to significant variability in aggregate bandwidth
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demands and latency. In such cases, it would be useful to have a more
dynamic feedback of congestion information. This aggregate congestion
feedback could be used to determine flow handling and admission
control.
\|/
|
|
+-|---+ +------+ +------+
+--+ | | Tunnel1 | | Tunnel2 | | Ext
|UE|-(RAN)-| eNB |===========| S-GW |=========| P-GW |--------
+--+ | | RAN | | Core | |Network
+-+---+ Backhaul +---+--+ Network +---+--+
Figure 1: Example - Mobile Network and Tunnels
3.2 Network Function Virtualization Scenario
Telecoms networks contain an increasing variety of proprietary
hardware appliances, leading to increasing difficulty in lauching new
network services, as well as the complexity of integrating and
deploying these appliances in a network.
Network Functions Virtualisation (NFV) aims to address these problems
by decoupling the software from dedicated hardware platforms to a
range of industry standard server hardware for various network
services, through IT virtualization technology that can be moved to,
or instantiated in, various locations in the network as required. In
this way, it is expected to provide significant benefits for network
operators (reduced expenditures for network construction and
maintenance) and their customers (shortened time-to-market for new
network services).
Further more, service functions are preferred to be deployed and
management in a data center manner, rather than being inserted on the
data-forwarding path between communicating peers as today. SFC WG is
currently working on a new framework to cope with this highly dynamic
routing problem for a network service, which requires that the
relevant data traffic be traversing a group of virtualized network
function nodes (VNFs), each of which could be applied at any layer
within the network protocol stack (network layer, transport layer,
application layer, etc.). [SFC]
As shown in Figure 2, in a SFC-enabled domain (e.g. with or across
network operator's deployed data centers), a PDP (Policy Decision
Point) is the central entity which is responsible for maintaining SFC
Policy Tables (rules for the boundary nodes on deciding which IP flow
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to traverse which service function path), and enforcing appropriate
policies in SF Nodes and SFC Boundary Nodes. Beginning at the Ingress
node, at each hop of a given service function path (as decided by a
matched SFC policy rule/map), if the next function node is not an
immediate (L3) neighbor, packet are encapsulated and forwarded to
correspondent downstream function node, as shown in Figure 3.
. . . . . . . . . . . . . . . . . . . . . . . . .
. SFC Policy Enforcement .
. +-------+ .
. | |-----------------+ .
. +-------| PDP | | .
. | | |-------+ | .
. | +-------+ | | .
. . . | . . . . . | . . . . . | . . . . | . . . .
. . . | . . . . . | . . . . . | . . . . | . . . .
. | | | | .
. v v v v .
. +---------+ +---------+ +-------+ +-------+ .
. |SFC_BN_1 | |SFC_BN_n | | SF_1 | | SF_m | .
. +---------+ +---------+ +-------+ +-------+ .
. SFC-enabled Domain .
. . . . . . . . . . . . . . . . . . . . . . . . .
Figure 2: SFC Policy Enforcement Scheme
Network Service
+----------+ +----------+ +----------+
| VNF#1 | tunnel#1 | VNF#2 | tunnels | VNF#n |
| Instance |-----------| Instance |- ... ... -| Instance |
+----------+ +----------+ +----------+
^
| Virtualization
+--------------------------------------------------------+
| Virtualization Platform |
+--------------------------------------------------------+
Figure 3: Example - Mobile Network service chaining and Tunnels
However, using VNFs running commodity platforms can introduce
additional points of failure beyond those inherent in a single
specialized server, and therefore poses additional challenges on
reliability. [VNFPOOL] proposes using pooling techniques in response,
which requires maintaining a backup mapping among running VNF
instances for a given service function, and choosing from them for a
specific data flow. It is clear that it would be helpful to make more
efficient use of network capacity in case of local congestion, if the
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choice is based on the ECN feedback as well as the running status
and/or physical resources accommodation of a candidate VNF instance.
4. Congestion Model
To support traffic management and congestion information feedback in
tunnel, there are mainly two issues that this document discusses:
calculation of congestion level information, and feeding back the
congestion information from egress to ingress router.
In this solution, we assume the tunnel ingress/egress is compliant
with RFC6040 and the tunnel interior routers are compliant with
RFC3168.
In addition, it should be noted that these tunnels may carry ECT or
Not-ECT traffic. A well defined mechanism for aggregate congestion
calculation should be able to work in the presence of all kinds of
traffic and would benefit from a common feedback mechanism and
protocol.
4.1 Congestion Calculation
Calculation of congestion in the tunnel is based on the method
described in RFC 6040, Appendix C.
The egress can calculate congestion using moving averages. The
proportion of packets not marked in the inner header that have a CE
marking in the outer header is considered to have experienced
congestion in the tunnel. Note that the packets are ECN capable and
not congestion-marked before tunnel. Since routers implementing RED
randomly select a percentage of packets to mark, this method can be
effectively used to expose congestion in the tunnel.
When the ingress is RFC6040 compliant, the packets collected by
egress can be divided into to 4 categories, shown in figure 2. The
tag before "|" stands for ECN field in outer header; and the tag
after "|" stands for ECN field in inner header.
"Not-ECN|Not-ECN" indicates traffic that does not support ECN, for
example UDP and Not-ECT marked TCP; "CE|CE" indicates ECN capable
packets that have CE-mark before entering the tunnel; "CE|ECT"
indicates ECN capable packets that are CE-marked in the tunnel;
"ECT|ECT" indicates ECN capable packets that have not experienced
congested in tunnel (or outside the tunnel).
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+--------------------------+
| Not-ECN|Not-ECN |
+--------------------------+
| CE|CE |
+--------------------------+
| CE|ECT |
+--------------------------+
| ECT|ECT |
+--------------------------+
Figure 2: ECN marking categories by outer/inner packet
Out of the total number of packets, if the quantity of CE|ECT packets
is A, the quantity of ECT|ECT packets is B, then the congestion level
(C) can be calculated as follows:
C=A/(A+B)
As an example, consider 100 packets to calculate the moving average
as shown in RFC 6040, Appendix C. Say that there are 12 packets that
have CE|ECT marks indicating that they have experienced congestion in
the tunnel. And, there are 58 packets that have ECT|ECT marks
indicating that there was no congestion in either the tunnel or
elsewhere. The egress can calculate congestions as:
C = 12/ (12 + 58)
= 12/70 (17% congestion)
4.2 Congestion Feedback
The figure below introduces an abstract view of the tunnel and
outlines a tunnel congestion feedback model.
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,-----------. IP-in-IP TUNNEL ,-----------.
| Ingress |========================================| Egress |
| | | |
| ,-----------Congestion-Feedback-Signals--------------. |
| | | | | |
| | | | | |
| | | | | |
| | | | | |
| | | | | |
| | | ,-----------. '\ | | |
| | |____________| |__________| \ | | |
|+----v----+| Outer Header(IP Layer) Data Flow \ |+----+----+|
||Collector|| | | \||Feedback ||
|+---------+| |(Congested)| /|+---------+|
|| Manager || | Router |Outer-CE-Signals--> Meter ||
|+---------+|____________| |________ / |+---------+|
| | | | |/ | |
| | `-----------' ' | |
| |========================================| |
`-----------' `-----------'
Figure 3: Basic Feedback Model
The basic model consists of the following components: Ingress,
Egress, Feedback, Meter, Collector and Manager.
At egress, a module named Meter is used to estimate the congestion
level of in the tunnel as described in the section above. A
congestion information feedback module, called Feedback, is used to
control the congestion information feedback.
The metering module (Meter) in the Egress node accounts the
congestion marks it receives. The Feedback module calculates the
amount of congestion and feeds back the congestion information to the
Ingress node. The Collector at the Ingress receives the congestion
information which is fed back from the Egress node. The Manager has
admission control and flow control functions which are out of the
scope of this document.
It should be assumed that the ingress and egress of the tunnel are
ECN-enabled and the intermediate routers in the tunnel path are also
ECN-enabled. Congestion feedback signals in the figure are fed back
using protocols described in section 5.
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5. Congestion Feedback Protocol
5.1 Properties of Candidate Protocol
To feedback congestion efficiently there are some properties that are
desirable in the feedback protocol.
1. Congestion friendliness. The feeding back traffics are coexistence
with other traffics, so when congestion happens in the network,
the feeding back traffic should be reduced, So that feedback
itself will not congest the network further when the network is
already getting congested. In other words, feedback frequency
should adjust to network's congestion level.
2. Extensibility. The authors consider that using an existing
protocol, or extensions to an existing protocol is preferable. The
ability of a protocol to support modular extensions to report
congestion level as feedback is a key attribute of the protocol
under consideration.
3. Compactness. In different situations, there may be different
congestion information to be conveyed, and in order to reduce
network load, the information to be conveyed should be selectable,
i.e. only the required information should be possible to convey.
5.2 IPFIX Extensions for Congestion Feedback
This section outlines IPFIX extensions for feedback of congestion.
The authors consider that IPFIX is a suitable protocol that is
reasonably easy to extend to carry tunnel congestion reporting.
Since IPFIX uses TCP transport, it has the foundation for congestion-
friendly behavior. When congestion occurs in the network, the
Exporter (Egress) can reduce the IPFIX traffic. Thus the feedback
itself will not congest the network further when the network is
already getting congested. When the Exporter detects network
congestion, it can also reduce IPFIX traffic frequency to avoid more
congestion in network while being able to sufficiently convey
congestion status.
Because the template mechanism in IPFIX is flexible, it allows the
export of only the required information. Sending only the required
information can also reduce network load.
The basic procedure for feedback using IPFIX is as follows:
(1)The exporter inform the collector how to interpret the IEs in
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IPFIX message using template. Collector just accepts template
passively; which IEs to send is configured by other means that not
included in IPFIX specification.
(2)The exporter meters the traffic and sends the congestion level to
collector.
Congestion feedback using IPFIX is shown in the figures below. There
are two variations to congestion feedback model using IPFIX. In the
first one shown in Figure 4(a), congestion information is sent
directly from egress to ingress and ingress makes decisions according
this information. In the second case shown in Figure 4(b), congestion
information is sent to a mediation controller instead of tunnel
ingress; the controller is in charge of making decisions according to
network congestion and control the behavior of ingress node, for
example, reducing traffic or forbidding new traffic flows. In this
model the congestion information from egress to controller is
conveyed by IPFIX, but how controller controls the behavior of
ingress is out of scope of this document.
IPFIX
|-----------------------------------------|
| |
| |
| V
+----------+ tunnel +-----------+
|Egress |========================== |Inress |
|(Exporter)| |(Collector)|
+----------+ +-----------+
(a) Direct Feedback.
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IPFIX +-----------+
--------->|Controller |#####################
| |(Collector)| #
| +-----------+ #
| #
+----------+ tunnel +-----V-+
|Egress | ===========================|Ingress|
|(Exporter)| +-------+
+----------+
(b) Mediated Feedback.
Figure 4: IPFIX Congestion Feedback Models
To support feeding back congestion information, some extensions to
the IPFIX protocol are necessary. A new IE conveying congestion level
is defined for this purpose.
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Definition of new IE indicating congestion level.
Description:
The congestion level calculated by exporter.
Abstract Data Type: unsigned8
Data Type Semantics: quantity
ElementId: TBD.
Status: current
The example below shows how IPFIX can be used for congestion
feedback.
[NOTE: the information conveyed here may be incomplete, and what
information should be conveyed needs to be determined.]
(1) Sending Template Set The exporter use Template Set to inform the
collector how to interpret the IEs in the following Data Set.
+------------------------+--------------------+
|Set ID=2 |Length=n |
+------------------------+--------------------+
|Template ID=257 |Field Count=m |
+------------------------+--------------------+
|exporterIPv4Address=130 |Field Length=4 |
+------------------------+--------------------+
|collectorIPv4Address=211|Field Length=4 |
+------------------------+--------------------+
|CongestionLevel=TBD1 |Field Length=2 |
+---------------------------------------------+
|Enterprise Number=TBD2 |
+---------------------------------------------+
(2) Sending Data Set The exporter meters the traffic and sends the
congestion information to collector by Data Set.
+------------------+-------------------+
|Set ID=257 |Length=n |
+--------------------------------------+
|192.0.2.12 |
+--------------------------------------+
|192.0.2.34 |
+--------------------------------------+
|15 |
+--------------------------------------+
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+--------+ +---------+
|Exporter| |Collector|
+--------+ +---------+
| |
| |
| (1)Sending Template Set |
|------------------------------------->|
| |
+--------+ |
|metering| |
+--------+ |
| (2)Sending Data Set |
|------------------------------------->|
| . |
| . |
| . |
| |
| |
Figure 5: IPFIX Congestion Flow
The Exporter can send congestion information periodically or when
triggered by the Collector. Before sending congestion information to
collector, the exporter sends a Template set to Collector. The
Template set specifies the structure and semantics of the subsequent
Data Set containing congestion-related information. The Collector
understands the Data Sets that follow according to Template Set that
was sent previously. The exporting Process transmits the Template Set
in advance of any Data Sets that use that Template ID, to help ensure
that the Collector has the Template Record before receiving the first
Data Record. Data Records that correspond to a Template Record may
appear in the same and/or subsequent IPFIX Message(s).
The Exporter meters the traffic passing through it and generates flow
records. At this point, the Exporter may cache the records and then
send congestion cumulative information to the collector. When
Exporter detects that the network is heavily congested, it can change
the feedback frequency to avoid adding more congestion to network.
When receiving congestion related information, the Collector will
make decisions to control the traffic entering the tunnel to reduce
tunnel congestion.
5.3 Other Protocols
A thorough evaluation of other protocols have not been performed at
this time.
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6. Security Considerations
This document describes the tunnel congestion calculation and
feedback. For feeding back congestion, security mechanisms of IPFIX
are expected to be sufficient. No additional security concerns are
expected.
7. IANA Considerations
IANA assignment of parameters for IPFIX extension may need to be
considered in this document.
8. References
8.1 Normative References
[RFC2003] Perkins, C., "IP Encapsulation within IP", RFC 2003,
October 1996.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2784] Farinacci, D., Li, T., Hanks, S., Meyer, D., and P.
Traina, "Generic Routing Encapsulation (GRE)", RFC 2784,
March 2000.
[RFC3168] Ramakrishnan, K., Floyd, S., and D. Black, "The Addition
of Explicit Congestion Notification (ECN) to IP",
RFC 3168, September 2001.
[RFC4301] Kent, S. and K. Seo, "Security Architecture for the
Internet Protocol", RFC 4301, December 2005.
[RFC5101] Claise, B., Ed., "Specification of the IP Flow Information
Export (IPFIX) Protocol for the Exchange of IP Traffic
Flow Information", RFC 5101, January 2008.
[RFC6040] Briscoe, B., "Tunnelling of Explicit Congestion
Notification", RFC 6040, November 2010.
[I-D.boucadair-sfc-framework] Boucadair, M. etc, "Service Function
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Chaining: Framework & Architecture", draft-boucadair-sfc-
framework-00(work in progress), October 2013.
[I-D.zong-vnfpool-problem-statement] Zong, N. etc, "Virtualized
Network Function (VNF) Pool Problem Statement", draft-
zong-vnfpool-problem-statement-02(work in progress),
January 2014.
8.2 Informative References
[TS29.060]3GPP TS 29.060: "General Packet Radio Service (GPRS); GPRS
Tunnelling Protocol (GTP) across the Gn and Gp interface".
Authors' Addresses
Xinpeng Wei
Beiqing Rd. Z-park No.156, Haidian District,
Beijing, 100095, P. R. China
E-mail: weixinpeng@huawei.com
Zhu Lei
Beiqing Rd. Z-park No.156, Haidian District,
Beijing, 100095, P. R. China
E-mail:lei.zhu@huawei.com
Lingli Deng
Beijing, 100095, P. R. China
E-mail: denglingli@gmail.com
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