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authorDeepak S <deepak.s@linux.intel.com>2017-09-04 02:52:15 -0700
committerDeepak S <deepak.s@linux.intel.com>2017-09-05 20:53:02 -0700
commitdc8e018823c18c7ef0afdd84336064c417b05287 (patch)
tree4f630d103dcfac099ab78e1bdfa0a371ca550f1b /docs
parent4a31f76b5f3e1caad12b7cc3bfe97ee1f0dacfc7 (diff)
Updating SampleVNF Highlevel design
Change-Id: I16edf82eec02c671c1c72d07348d1badf58fc42d Signed-off-by: Deepak S <deepak.s@linux.intel.com>
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diff --git a/docs/testing/developer/design/04-SampleVNF_Desgin.rest b/docs/testing/developer/design/04-SampleVNF_Desgin.rest
deleted file mode 100644
index 6c39da73..00000000
--- a/docs/testing/developer/design/04-SampleVNF_Desgin.rest
+++ /dev/null
@@ -1,123 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) OPNFV, Intel Corporation and others.
-
-.. OPNFV SAMPLEVNF Documentation design file.
-
-===================================
-SampleVNF Highlevel Desing
-===================================
-
-vFW - Design
-=============
-
-Requirements
------------------
-Following are the design requierments of the vFW.
-
-- The firewall will examine packets and verify that they are appropriate for the
- current state of the connection. Inappropriate packets will be discarded, and
- counter(s) incremented.
-- Support both IPv4 and IPv6 traffic type for TCP/UDP/ICMP.
-- All packet inspection features like firewall, synproxy, connection tracker
- in this component may be turned off or on through CLI commands
-- The Static filtering is done thorugh ACL using DPDK libraries. The rules
- can be added/modified through CLI commands.
-- Multiple instance of the vFW Pipeline running on multipe cores should be
- supported for scaling the performance scaling.
-- Should follow the DPDK IP pipeline framework
-- Sould use the DPDK libraries and functionalities for better performance
-- The memory should be allocated in Hugepages using DPDK RTE calls for better
- performance.
-
-
-High Level Design
-=================
-
-The Firewall performs basic filtering for malformed packets and dynamic packet
-filtering incoming packets using the connection tracker library.
-The connection data will be stored using a DPDK hash table. There will be one
-entry in the hash table for each connection. The hash key will be based on
-source address/port,destination address/port, and protocol of a packet. The
-hash key will be processed to allow a single entry to be used, regardless of
-which direction the packet is flowing (thus changing source and destination).
-The ACL is implemented as libray stattically linked to vFW, which is used for
-used for rule based packet filtering.
-
-TCP connections and UDP pseudo connections will be tracked separately even if
-theaddresses and ports are identical. Including the protocol in the hash key
-will ensure this.
-
-The Input FIFO contains all the incoming packets for vFW filtering. The vFW
-Filter has no dependency on which component has written to the Input FIFO.
-Packets will be dequeued from the FIFO in bulk for processing by the vFW.
-Packets will be enqueued to the output FIFO.
-
-The software or hardware loadbalancing can be used for traffic distribution
-across multiple worker threads. The hardware loadbalancing require ethernet
-flow director support from hardware (eg. Fortville x710 NIC card).
-The Input and Output FIFOs will be implemented using DPDK Ring Buffers.
-
-Components of vFW
-=================
-
-In vFW, each component is constructed using packet framework pipelines.
-It includes Rx and Tx Driver, Master pipeline, load balancer pipeline and
-vfw worker pipeline components. A Pipeline framework is a collection of input
-ports, table(s),output ports and actions (functions).
-
----------------------------
-Receive and Transmit Driver
----------------------------
-Packets will be received in bulk and provided to LoadBalancer(LB) thread.
-Transimit takes packets from worker threads in a dedicated ring and sent to
-hardware queue.
-
----------------
-Master Pipeline
----------------
-The Master component is part of all the IP Pipeline applications. This component
-does not process any packets and should configure with Core 0, to allow
-other cores for processing of the traffic. This component is responsible for
-1. Initializing each component of the Pipeline application in different threads
-2. Providing CLI shell for the user control/debug
-3. Propagating the commands from user to the corresponding components
-
-----------------
-ARPICMP Pipeline
-----------------
-This pipeline processes the APRICMP packets.
-
---------------
-TXRX Pipelines
---------------
-The TXTX and RXRX pipelines are pass through pipelines to forward both ingress
-and egress traffic to Loadbalancer. This is required when the Software
-Loadbalancer is used.
-
-----------------------
-Load Balancer Pipeline
-----------------------
-The vFW support both hardware and software balancing for load balancing of
-traffic across multiple VNF threads. The Hardware load balancing require support
-from hardware like Flow Director for steering of packets to application through
-hardware queues.
-
-The Software Load balancer is also supported if hardware load balancing can't be
-used for any reason. The TXRX along with LOADB pipeline provides support for
-software load balancing by distributing the flows to Multiple vFW worker
-threads.
-Loadbalancer (HW or SW) distributes traffic based on the 5 tuple (src addr, src
-port, dest addr, dest port and protocol) applying an XOR logic distributing to
-active worker threads, thereby maintaining an affinity of flows to worker
-threads.
-
-------------
-vFW Pipeline
-------------
-The vFW performs the basic packet filtering and will drop the invalid and
-malformed packets.The Dynamic packet filtering done using the connection tracker
-library. The packets are processed in bulk and Hash table is used to maintain
-the connection details.
-Every TCP/UDP packets are passed through connection tracker library for valid
-connection. The ACL library integrated to firewall provide rule based filtering.
diff --git a/docs/testing/developer/design/04-SampleVNF_Design.rst b/docs/testing/developer/design/04-SampleVNF_Design.rst
new file mode 100644
index 00000000..cdef7448
--- /dev/null
+++ b/docs/testing/developer/design/04-SampleVNF_Design.rst
@@ -0,0 +1,630 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International License.
+.. http://creativecommons.org/licenses/by/4.0
+.. (c) OPNFV, Intel Corporation and others.
+
+.. OPNFV SAMPLEVNF Documentation design file.
+
+===================================
+SampleVNF Highlevel Design
+===================================
+
+Introduction
+--------------
+This project provides a placeholder for various sample VNF (Virtual Network Function)
+development which includes example reference architecture and optimization methods
+related to VNF/Network service for high performance VNFs. This project provides benefits
+to other OPNFV projects like Functest, Models, yardstick etc to perform real life
+use-case based testing and NFVi characterization for the same.
+The sample VNFs are Open Source approximations* of Telco grade VNF’s using optimized
+VNF + NFVi Infrastructure libraries, with Performance Characterization of Sample† Traffic Flows.
+ • * Not a commercial product. Encourage the community to contribute and close the feature gaps.
+ • † No Vendor/Proprietary Workloads
+
+About DPDK
+^^^^^^^^^^^
+The DPDK IP Pipeline Framework provides set of libraries to build a pipeline
+application. In this document, CG-NAT application will be explained with its
+own building blocks.
+
+This document assumes the reader possess the knowledge of DPDK concepts and IP
+Pipeline Framework. For more details, read DPDK Getting Started Guide, DPDK
+Programmers Guide, DPDK Sample Applications Guide.
+
+Scope
+--------
+These application provides a standalone DPDK based high performance different
+Virtual Network Function implementation.
+
+
+
+Common Code - L2L3 stack
+-------------------------
+
+Introduction
+^^^^^^^^^^^^^^^
+L2L3 stack comprises of a set of libraries which are commonly used by all
+other VNF's. The different components of this stack is shown in the picture
+below.
+
+.. image:: l2l3-components.png
+
+It comprises of following components.
+
+ (i) Interface Manager
+ (ii) RTM Lock Library
+ (iii) ARP/ND & L2 adjacency Library
+ (iv) L3 stack components
+
+
+Interface Manager
+^^^^^^^^^^^^^^^^^
+Interface manager is a set of API's which acts as a wrapper for the physical
+interfaces initialization & population. This set of api's assists in configuring
+an ethernet device, setting up TX & RX queues & starting of the devices. It
+provides various types of interfaces like L2 interface, IPv4/IPv6 interface.
+It helps in Configuration (set/get) operations and status updates like (UP/DOWN)
+from admin or operations. It provides Callback functions registration for other
+components who wants to listen to interface status. It Maintains table of all
+the interfaces present. It provides API for getting interface statistics.
+
+It Provides wrapper APIs on top of DPDKs LAG(link Aggregation) APIs, This
+includes creating/deleting BOND interfaces, knowing the properties like Bond mode,
+xmit policy, link up delay, link monitor frequency.
+
+
+RTM Lock Library
+^^^^^^^^^^^^^^^^^
+It provides basic lock & unlock functions which should be used for synchronization
+purposes.
+
+ARP/ND & L2 adjacency Library
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+
+The ARP/ND state machine is given in the following diagram.
+
+.. image:: state-machine.png
+
+This library provides api's for handling ARP/ICMPv4 & ND/ICMPV6 packets
+handling. It provides api's for creating/deleting & populating an entry.
+It handles ARP request/response messages, Handles ICMP v4 echo request &
+echo response messages. It handles ND solicitation/advertisement messages
+for IPV6 packets. It Provide API for L2 Adjacency creation/deletion and
+retrieval based on nexthop & port_id. It handles Gratuitous ARP.
+
+::
+
+ Basic commands for ARP/ND table
+ p 1 arpls 0 (for ARP)
+ p 1 arpls 1 (for ND)
+ p 1 arpadd 0 <ip> <mac address> (for adding arp entry)
+ p 1 arpdel 0 <ip> (for deleting an arp entry)
+ p 1 arpreq 0 <ip> (for sending an arp request)
+
+
+L3 stack Library
+^^^^^^^^^^^^^^^^^
+
+This library provides API for taking decision of whether pkt belongs to local
+system or to forwarding.It Provides API for IPv4/IPv6 local packet out send
+function. It Provides API for packet forwarding - LPM lookup function.
+
+
+vFW - Design
+=============
+
+Requirements
+-------------
+
+Following are the design requierments of the vFW.
+
+- The firewall will examine packets and verify that they are appropriate for the
+ current state of the connection. Inappropriate packets will be discarded, and
+ counter(s) incremented.
+- Support both IPv4 and IPv6 traffic type for TCP/UDP/ICMP.
+- All packet inspection features like firewall, synproxy, connection tracker
+ in this component may be turned off or on through CLI commands
+- The Static filtering is done thorugh ACL using DPDK libraries. The rules
+ can be added/modified through CLI commands.
+- Multiple instance of the vFW Pipeline running on multipe cores should be
+ supported for scaling the performance scaling.
+- Should follow the DPDK IP pipeline framework
+- Should use the DPDK libraries and functionalities for better performance
+- The memory should be allocated in Hugepages using DPDK RTE calls for better
+ performance.
+
+High Level Design
+-------------------
+
+The Firewall performs basic filtering for malformed packets and dynamic packet
+filtering incoming packets using the connection tracker library.
+The connection data will be stored using a DPDK hash table. There will be one
+entry in the hash table for each connection. The hash key will be based on
+source address/port,destination address/port, and protocol of a packet. The
+hash key will be processed to allow a single entry to be used, regardless of
+which direction the packet is flowing (thus changing source and destination).
+The ACL is implemented as libray stattically linked to vFW, which is used for
+used for rule based packet filtering.
+
+TCP connections and UDP pseudo connections will be tracked separately even if
+theaddresses and ports are identical. Including the protocol in the hash key
+will ensure this.
+
+The Input FIFO contains all the incoming packets for vFW filtering. The vFW
+Filter has no dependency on which component has written to the Input FIFO.
+Packets will be dequeued from the FIFO in bulk for processing by the vFW.
+Packets will be enqueued to the output FIFO.
+
+The software or hardware loadbalancing can be used for traffic distribution
+across multiple worker threads. The hardware loadbalancing require ethernet
+flow director support from hardware (eg. Fortville x710 NIC card).
+The Input and Output FIFOs will be implemented using DPDK Ring Buffers.
+
+Components of vFW
+-----------------
+
+In vFW, each component is constructed using packet framework pipelines.
+It includes Rx and Tx Driver, Master pipeline, load balancer pipeline and
+vfw worker pipeline components. A Pipeline framework is a collection of input
+ports, table(s),output ports and actions (functions).
+
+Receive and Transmit Driver
+^^^^^^^^^^^^^^^^^^^^^^^^^^^
+Packets will be received in bulk and provided to LoadBalancer(LB) thread.
+Transimit takes packets from worker threads in a dedicated ring and sent to
+hardware queue.
+
+Master Pipeline
+^^^^^^^^^^^^^^^
+The Master component is part of all the IP Pipeline applications. This component
+does not process any packets and should configure with Core 0, to allow
+other cores for processing of the traffic. This component is responsible for
+1. Initializing each component of the Pipeline application in different threads
+2. Providing CLI shell for the user control/debug
+3. Propagating the commands from user to the corresponding components
+
+ARPICMP Pipeline
+^^^^^^^^^^^^^^^^
+This pipeline processes the APRICMP packets.
+
+TXRX Pipelines
+^^^^^^^^^^^^^^
+The TXTX and RXRX pipelines are pass through pipelines to forward both ingress
+and egress traffic to Loadbalancer. This is required when the Software
+Loadbalancer is used.
+
+Load Balancer Pipeline
+^^^^^^^^^^^^^^^^^^^^^^
+The vFW support both hardware and software balancing for load balancing of
+traffic across multiple VNF threads. The Hardware load balancing require support
+from hardware like Flow Director for steering of packets to application through
+hardware queues.
+
+The Software Load balancer is also supported if hardware load balancing can't be
+used for any reason. The TXRX along with LOADB pipeline provides support for
+software load balancing by distributing the flows to Multiple vFW worker
+threads.
+Loadbalancer (HW or SW) distributes traffic based on the 5 tuple (src addr, src
+port, dest addr, dest port and protocol) applying an XOR logic distributing to
+active worker threads, thereby maintaining an affinity of flows to worker
+threads.
+
+vFW Pipeline
+^^^^^^^^^^^^
+The vFW performs the basic packet filtering and will drop the invalid and
+malformed packets.The Dynamic packet filtering done using the connection tracker
+library. The packets are processed in bulk and Hash table is used to maintain
+the connection details.
+Every TCP/UDP packets are passed through connection tracker library for valid
+connection. The ACL library integrated to firewall provide rule based filtering.
+
+
+vCGNAPT - Design
+=================
+
+Introduction
+^^^^^^^^^^^^^^
+This application implements vCGNAPT. The idea of vCGNAPT is to extend the life of
+the service providers IPv4 network infrastructure and mitigate IPv4 address
+exhaustion by using address and port translation in large scale. It processes the
+traffic in both the directions.
+
+It also supports the connectivity between the IPv6 access network to IPv4 data network
+using the IPv6 to IPv4 address translation and vice versa.
+
+Scope
+^^^^^^
+This application provides a standalone DPDK based high performance vCGNAPT
+Virtual Network Function implementation.
+
+Features
+^^^^^^^^^
+The vCGNAPT VNF currently supports the following functionality:
+ • Static NAT
+ • Dynamic NAT
+ • Static NAPT
+ • Dynamic NAPT
+ • ARP (request, response, gratuitous)
+ • ICMP (terminal echo, echo response, passthrough)
+ • UDP, TCP and ICMP protocol passthrough
+ • Multithread support
+ • Multiple physical port support
+ • Limiting max ports per client
+ • Limiting max clients per public IP address
+ • Live Session tracking to NAT flow
+ • NAT64
+
+
+High Level Design
+^^^^^^^^^^^^^^^^^^^
+The Upstream path defines the traffic from Private to Public and the downstream
+path defines the traffic from Public to Private. The vCGNAPT has same set of
+components to process Upstream and Downstream traffic.
+
+In vCGNAPT application, each component is constructed as IP Pipeline framework.
+It includes Master pipeline component, load balancer pipeline component and vCGNAPT
+pipeline component.
+
+A Pipeline framework is collection of input ports, table(s), output ports and
+actions (functions). In vCGNAPT pipeline, main sub components are the Inport function
+handler, Table and Table function handler. vCGNAPT rules will be configured in the
+table which translates egress and ingress traffic according to physical port
+information from which side packet is arrived. The actions can be forwarding to the
+output port (either egress or ingress) or to drop the packet.
+
+vCGNAPT Background
+^^^^^^^^^^^^^^^^^^^
+The idea of vCGNAPT is to extend the life of the service providers IPv4 network infrastructure
+and mitigate IPv4 address exhaustion by using address and port translation in large scale.
+It processes the traffic in both the directions. ::
++------------------+
+| +-----+
+| Private consumer | CPE ----
+| IPv4 traffic +-----+ |
++------------------+ |
+ | +-------------------+ +------------------+
+ | | +------------+ -
+ |-> - Private IPv4 - vCGNAPT - Public -
+ |-> - access network - NAT44 - IPv4 traffic -
+ | | +------------+ -
+ | +-------------------+ +------------------+
++------------------+ |
+| +-----+ |
+| Private consumer - CPE ----
+| IPv4 traffic +-----+
++------------------+
+ Figure: vCGNAPT deployment in Service provider network
+
+
+Components of vCGNAPT
+---------------------
+In vCGNAPT, each component is constructed as a packet framework. It includes Master pipeline
+component, driver, load balancer pipeline component and vCGNAPT worker pipeline component. A
+pipeline framework is a collection of input ports, table(s), output ports and actions
+(functions).
+
+Receive and transmit driver
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+Packets will be received in bulk and provided to load balancer thread. The transmit takes
+packets from worker thread in a dedicated ring and sent to the hardware queue.
+
+Master pipeline
+^^^^^^^^^^^^^^^^
+This component does not process any packets and should configure with Core 0,
+to save cores for other components which processes traffic. The component
+is responsible for:
+ 1. Initializing each component of the Pipeline application in different threads
+ 2. Providing CLI shell for the user
+ 3. Propagating the commands from user to the corresponding components.
+ 4. ARP and ICMP are handled here.
+
+Load Balancer pipeline
+^^^^^^^^^^^^^^^^^^^^^^^
+Load balancer is part of the Multi-Threaded CGMAPT release which distributes
+the flows to Multiple ACL worker threads.
+
+Distributes traffic based on the 2 or 5 tuple (source address, source port,
+destination address, destination port and protocol) applying an XOR logic
+distributing the load to active worker threads, thereby maintaining an
+affinity of flows to worker threads.
+
+Tuple can be modified/configured using configuration file
+
+vCGNAPT - Static
+------------------
+The vCGNAPT component performs translation of private IP & port to public IP &
+port at egress side and public IP & port to private IP & port at Ingress side
+based on the NAT rules added to the pipeline Hash table. The NAT rules are
+added to the Hash table via user commands. The packets that have a matching
+egress key or ingress key in the NAT table will be processed to change IP &
+port and will be forwarded to the output port. The packets that do not have a
+match will be taken a default action. The default action may result in drop of
+the packets.
+
+vCGNAPT- Dynamic
+-----------------
+The vCGNAPT component performs translation of private IP & port to public IP & port
+at egress side and public IP & port to private IP & port at Ingress side based on the
+NAT rules added to the pipeline Hash table. Dynamic nature of vCGNAPT refers to the
+addition of NAT entries in the Hash table dynamically when new packet arrives. The NAT
+rules will be added to the Hash table automatically when there is no matching entry in
+the table and the packet is circulated through software queue. The packets that have a
+matching egress key or ingress key in the NAT table will be processed to change IP &
+port and will be forwarded to the output port defined in the entry.
+
+Dynamic vCGNAPT acts as static one too, we can do NAT entries statically. Static NAT
+entries port range must not conflict to dynamic NAT port range.
+
+vCGNAPT Static Topology:
+--------------------------
+IXIA(Port 0)-->(Port 0)VNF(Port 1)-->(Port 1) IXIA
+operation:
+ Egress --> The packets sent out from ixia(port 0) will be CGNAPTed to ixia(port 1).
+ Igress --> The packets sent out from ixia(port 1) will be CGNAPTed to ixia(port 0).
+
+vCGNAPT Dynamic Topology (UDP_REPLAY):
+--------------------------------------
+IXIA(Port 0)-->(Port 0)VNF(Port 1)-->(Port 0)UDP_REPLAY
+operation:
+ Egress --> The packets sent out from ixia will be CGNAPTed to L3FWD/L4REPLAY.
+ Ingress --> The L4REPLAY upon reception of packets (Private to Public Network),
+ will immediately replay back the traffic to IXIA interface. (Pub -->Priv).
+
+How to run L4Replay:
+--------------------
+ 1. After the installation of ISB on L4Replay server
+ go to /opt/isb_bin
+ 2. ./UDP_Replay -c core_mask -n no_of_channels(let it be as 2) -- -p PORT_MASK --config="(port,queue,lcore)"
+ eg: ./UDP_Replay -c 0xf -n 4 -- -p 0x3 --config="(0,0,1)"
+
+
+vACL - Design
+=================
+
+Introduction
+--------------
+This application implements Access Control List (ACL). ACL is typically used for rule
+based policy enforcement. It restricts access to a destination IP address/port based
+on various header fields, such as source IP address/port, destination IP address/port
+and protocol. It is built on top of DPDK and uses the packet framework infrastructure.
+
+Scope
+------
+This application provides a standalone DPDK based high performance ACL Virtual Network
+Function implementation.
+
+High Level Design
+------------------
+The ACL Filter performs bulk filtering of incoming packets based on rules in current ruleset,
+discarding any packets not permitted by the rules. The mechanisms needed for building the
+rule database and performing lookups are provided by the DPDK API.
+http://dpdk.org/doc/api/rte__acl_8h.html
+
+The Input FIFO contains all the incoming packets for ACL filtering. Packets will be dequeued
+from the FIFO in bulk for processing by the ACL. Packets will be enqueued to the output FIFO.
+The Input and Output FIFOs will be implemented using DPDK Ring Buffers.
+
+The DPDK ACL example: http://dpdk.org/doc/guides/sample_app_ug/l3_forward_access_ctrl.html
+#figure-ipv4-acl-rule contains a suitable syntax and parser for ACL rules.
+
+Components of ACL
+------------------
+In ACL, each component is constructed as a packet framework. It includes Master pipeline
+component, driver, load balancer pipeline component and ACL worker pipeline component. A
+pipeline framework is a collection of input ports, table(s), output ports and actions
+(functions).
+
+Receive and transmit driver
+---------------------------
+Packets will be received in bulk and provided to load balancer thread. The transmit takes
+packets from worker thread in a dedicated ring and it is sent to the hardware queue.
+
+Master
+-------
+This component does not process any packets and should configure with Core 0,
+to save cores for other components which processes traffic. The component
+is responsible for:
+ 1. Initializing each component of the Pipeline application in different threads
+ 2. Providing CLI shell for the user
+ 3. Propagating the commands from user to the corresponding components.
+ 4. ARP and ICMP are handled here.
+
+Load Balancer
+--------------
+Load balancer is part of the Multi-Threaded ACL release which distributes
+the flows to Multiple ACL worker threads.
+
+Distributes traffic based on the 5 tuple (source address, source port, destination
+address, destination port and protocol) applying an XOR logic distributing the
+load to active worker threads, thereby maintaining an affinity of flows to
+worker threads.
+
+ACL
+---
+Visit the following link for DPDK ACL library implementation.
+http://dpdk.org/doc/api/rte__acl_8h.html
+http://dpdk.org/doc/guides/prog_guide/packet_classif_access_ctrl.html
+
+Provides shadow copy for runtime rule configuration support
+
+Implements policy based packet forwarding
+
+vPE - Design
+=============
+
+Introduction
+---------------
+An Edge Router typically sits between two networks such as the provider core
+network and the provider access network. In the below diagram, Customer Edge
+(CE) Router sits in the provider access network and MPLS cloud network
+represents the provide core network.
+The edge router processes the traffic in both the directions. The functionality
+of the Edge Router varies while processing each direction of traffic. The
+packets to the core network will be filtered, classified and metered with QoS
+parameters. The packets to the access network will be shaped according to the
+subscription policy.
+The idea of Edge Router application is to provide the benchmark for the
+functionality of Provider Edge routers in each direction.
+
+The DPDK IP Pipeline Framework provides set of libraries to build a pipeline
+application. The Provider Edge Router functionality delivered as a virtual
+network function (VNF) is integrated with DPDK, optimized for Intel hardware
+architecture.
+This document assumes the reader possess the knowledge of DPDK concepts and
+IP Pipeline Framework. For more details, read DPDK Getting Started Guide, DPDK
+Programmers Guide, DPDK Sample Applications Guide.
+
+Scope
+------
+This application provides a standalone DPDK based high performance Provide
+Edge Router Network Function implementation.
+
+High Level Design
+-------------------
+The Edge Router application processes the traffic between Customer and the core
+network.
+The Upstream path defines the traffic from Customer to Core and the downstream
+path defines the traffic from Core to Customer. The Edge Router has different
+set of components to process Upstream and Downstream traffic.
+
+In Edge Router application, each component is constructed as building blocks in
+IP Pipeline framework. As in Pipeline framework, each component has its own
+input ports, table and output ports. The rules of the component will be
+configured in the table which decides the path of the traffic and any action to
+be performed on the traffic. The actions can be forwarding to the output port,
+forwarding to the next table or drop. For more details, please refer Section 24
+of DPDK Programmers Guide (3).
+
+The Core-to-Customer traffic is mentioned as downstream. For downstream
+processing, Edge Router has the following functionalities in Downstream
+
+ ---> Packet Rx --> Routing --> Traffic Manager --> Packet Tx -->
+
+ Routing
+ To identify the route based on the destination IP.
+ To provide QinQ label based on the destination IP.
+ Encapsulation
+ Updates the MAC address based on the route entry.
+ Appends the QinQ label based on the route entry.
+ Traffic Manager
+ To perform QoS traffic management (5-level hierarchical scheduling) based on
+ the predefined set of Service Level Agreements (SLAs)
+ SVLAN, CVLAN, DSCP fields are used to determine transmission priority.
+ Traffic Manager Profile which contains the SLA parameters are provided as
+ part of the application.
+
+The Customer-to-Core traffic is mentioned as upstream. For upstream processing,
+Edge Router has the following functionalities in Upstream.
+
+ ---> Packet Rx --> ACL filters --> Flow control --> Metering Policing &
+ Marking --> Routing --> Queueing & Packet Tx -->
+
+ Firewall
+ To filter the unwanted packets based on the defined ACL rules.
+ Source IP, Destination IP, Protocol, Source Port and Destination Port are
+ used to derive the ACL rules.
+ Flow Classification
+ To classify the packet based on the QinQ label
+ To assign a specific flow id based on the classification.
+ Metering
+ Two stages of QoS traffic metering and policing is applied.
+ 1st stage is performed per flow ID using trTCM algorithm
+ 2nd stage is performed per flow ID traffic class using trTCM algorithm
+ Packets will be either dropped or marked Green, Yellow, Red based on the
+ metering rules.
+ Routing
+ To identify the route based on the destination IP
+ To provide MPLS label to the packets based on destination IP.
+ Encapsulation
+ Updates the MAC address based on the route entry.
+ Appends the MPLS label based on the route entry.
+ Update the packet color in MPLS EXP field in each MPLS header.
+
+Components of vPE
+-------------------
+The vPE has downstream and upstream pipelines controlled by Master component.
+Edge router processes two different types of traffic through pipelines
+I. Downstream (Core-to-Customer)
+ 1. Receives TCP traffic from core
+ 2. Routes the packet based on the routing rules
+ 3. Performs traffic scheduling based on the traffic profile
+ a. Qos scheduling is performed using token bucket algorithm
+ SVLAN, CVLAN, DSCP fields are used to determine transmission priority.
+ 4. Appends QinQ label in each outgoing packet.
+II. Upstream (Customer-to-Core)
+ 1. Receives QinQ labelled TCP packets from Customer
+ 2. Removes the QinQ label
+ 3. Classifies the flow using QinQ label and apply Qos metering
+ a. 1st stage Qos metering is performed with flow ID using trTCM algorithm
+ b. 2nd stage Qos metering is performed with flow ID and traffic class using
+ trTCM algorithm
+ c. traffic class maps to DSCP field in the packet.
+ 4. Routes the packet based on the routing rules
+ 5. Appends two MPLS labels in each outgoing packet.
+
+Master Component
+-----------------
+The Master component is part of all the IP Pipeline applications. This
+component does not process any packets and should configure with Core0,
+to save cores for other components which processes traffic. The component
+is responsible for
+ 1. Initializing each component of the Pipeline application in different threads
+ 2. Providing CLI shell for the user
+ 3. Propagating the commands from user to the corresponding components.
+
+Upstream and Downstream Pipelines
+----------------------------------
+The downstream will have Firewall, Pass-through, Metering and Routing pipelines.
+The upstream will have Pass-through and Routing pipelines.
+
+To run the VNF, execute the following:
+isb_root/VNFs/vPE$ ./build/ip_pipeline -p 0x3 \
+ -f config/auto_combo_1_instances_1_queues_2_ports_v2.cfg \
+ -s config/auto_combo_1_instances_1_queues_2_ports_v2.txt
+
+Prox - Packet pROcessing eXecution engine
+==========================================
+
+Overview:
+----------
+Packet pROcessing eXecution Engine (PROX) which is a DPDK application.
+PROX can do operations on packets in a highly configurable manner.
+The PROX application is also displaying performance statistics that can
+be used for performance investigations.
+Intel® DPPD - PROX is an application built on top of DPDK which allows creating
+software architectures, such as the one depicted below, through small and readable
+configuration files.
+
+.. image:: images/prox-qo-img01.png
+
+The figure shows that each core is executing a set of tasks. Currently,
+a task can be any one of the following:
+1. Classify
+2. Drop
+3. Basic Forwarding (no touch)
+4. L2 Forwarding (change MAC)
+5. GRE encap/decap
+6. Load balance based on packet fields
+7. Symmetric load balancing
+8. QinQ encap/decap IPv4/IPv6
+9. ARP
+10. QoS
+11. Routing
+12. Unmpls
+13. Policing
+14. ACL ...
+
+One of the example configurations that is distributed with the source code is a
+Proof of Concept (PoC) implementation of a Broadband Network Gateway (BNG) with Quality of Service (QoS).
+The software architecture for this PoC is presented below.
+
+.. image:: images/prox-qo-img02.png
+
+The display shows per task statistics through an ncurses interface.
+Statistics include: estimated idleness; per second statistics for packets received,
+transmitted or dropped; per core cache occupancy; cycles per packet.
+These statistics can help pinpoint bottlenecks in the system.
+This information can then be used to optimize the configuration.
+Other features include debugging support, scripting,
+Open vSwitch support... A screenshot of the display is provided below.
+
+.. image:: images/prox-screen-01.png
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