Особенности архитектуры и траблшутинга маршрутизаторов серии ASR1000

Особенности архитектуры
и траблшутинга
маршрутизаторов серии
ASR1000
Дмитрий Леонтьев
Инженер российского центра технической поддержки Cisco TAC
28.01.2015

2© 2013-2014 Cisco and/or its affiliates. All rights reserved.
Cisco Support Community – Expert Series Webcast
Сегодня на семинаре эксперт Cisco Дмитрий Леонтьев
расскажет об особенностях архитектуры и траблшутинга
маршрутизаторов Cisco ASR1000 при его работе.
Инженер российского
центра технической
поддержки Cisco TAC

Технические Эксперты
Тема: Особенности архитектуры и траблшутинга
маршрутизаторов серии ASR1000
Дата проведения вебинара: 28 января 2015 года
Олег Типисов
Инженер центра
технической поддержки
Cisco TAC в России
Сергей Василенко
Инженер центра
технической поддержки
Cisco TAC в России

Спасибо, что посетили наш вебинар сегодня
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Наши эксперты ответят на них.

Вопрос №1
Какой у вас опыт в использовании ASR1000?
a) Только начинаю осваивать ASR1k и IOS-XE
b) Хорошие знания IOS-XE, но знакомство с ASR1k только
начинается
c) Хорошие знания IOS-XE и уверенно пользуюсь системой
d) Давно использую ASR1K и являюсь специалистом

Cisco Support Community – Expert
Series Webcast
Инженер российского центра технической поддержки Cisco
Январь, 2015
Особенности архитектуры и
траблшутинга маршрутизаторов
серии ASR1000

 Архитектура маршрутизаторов ASR1000
 Архитектура ASR1001, ASR1001-X и ASR1002-X
 Прохождение пакета через маршрутизатор
 Архитектура операционной системы IOS-XE
 Примеры распространенных проблем на ASR1000 и способы их
устранения
Программа вебинара

Cisco 7200, 10+ years in networks

Goodbye, Cisco 7200
http://www.cisco.com/c/en/us/products/collateral/routers/7200-series-
routers/end_of_life_c51-681414.html
Milestone Definition Date
End-of-Life Announcement Date The date the document that announces the end-of-
sale and end-of-life of a product is distributed to the
general public.
September 30, 2011
End-of-Sale Date The last date to order the product through Cisco
point-of-sale mechanisms. The product is no longer
for sale after this date.
September 29, 2012
End-of-Sale Product
Part Number
Product Description Replacement Product Part
Number
Replacement Product
Description
Additional Information
CISCO7201 Cisco 7201 Chassis, 1GB
Memory, Dual P/S, 256MB
Flash
ASR1001 Cisco ASR1001 System,
Crypto, 4 built-in GE, Dual P/S
-
CISCO7201 Cisco 7201 Chassis, 1GB
Memory, Dual P/S, 256MB
Flash
ASR1002 Cisco ASR1002 Chassis, 4
built-in GE, Dual P/S, 4GB
DRAM
-
CISCO7201-5PK 5-Pack Bundle of CISCO7201
MRBU Router
See Product Migration Options
section for details.
ASR 1000 -
CISCO7204VXR Cisco 7204VXR, 4-slot
chassis, 1 AC Supply w/IP
Software
ASR1001 Cisco ASR1001 System,
Crypto, 4 built-in GE, Dual P/S
-
CISCO7204VXR Cisco 7204VXR, 4-slot
chassis, 1 AC Supply w/IP
Software
ASR1002 Cisco ASR1002 Chassis, 4
built-in GE, Dual P/S, 4 GB
DRAM
-

Cisco 7200 and ASR 1000 Comparison
Характеристика Cisco 7200 ASR 1000
Throughput Up to 1.8 Gbps,
Up to 2Mpps
2.5-100 Gbps,
до 32Mpps
IP CEF Software Hardware
Operation system IOS IOS-XE

Cisco 7200 Architecture
Power
Supply
CPU
ROM
RAM
Flash
Bus
Interface
Interface Interface
System Bus
NVRAM
Network
Controller
Network
Controller
Interface
Network
Controller
System Bus

Running all code in processes can be slow.
• Have to wait for the scheduler to allow the process to run.
• In IOS a process can not interrupt another process while
it’s running. The process has to wait until the other process
completes
• Processes have to be programmed to be well behaved
• CPU’s provide a mechanism to do processing on critical
things nearly immediately - Interrupts
Most interrupts are hardware initiated
Most CPU’s provide at least 1 software interrupt
Interrupting the CPU

ASR 1000 – Product Positioning
3845
7200
< 3G
>300G
List Price Price includes Chassis, engine
18G
7304-NSE
ASR1004 w/
ASR1000-ESP20
ASR1002 w/
ASR1000-ESP5
ASR1006 w/ dual
ASR1000-ESP10
ASR1000-RP1
5G
10G
20G
7600,
GSR,CRS
ASR 1000 Series
5-200Gbps
(Depends on ESP/SIP not Chassis Type)
ASR1002 w/
ASR1000-ESP10

ASR 1000 Series Building Blocks
Route
Processor
(standby)
RP
Interconn.
Embedded Services
Processor
(active)
FECP
Interconn.
QFP
subsys-
tem
Crypto
assist
Embedded Services
Processor
(standby)
FECP
Interconn.
QFP
subsystemCrypto
assist
SPASPA
IOCP
SPA
Agg.
…
Interconn.
SPASPA
IOCP
SPA
Agg.
…
Interconn.
SPASPA
IOCP
SPA
Agg.
…
Interconn.
Passive Midplane
Route
Processor
(active)
RP
Interconn.
Hypertransport, 10Gbps
ESI, (Enhanced Serdes) 11.5Gbps
SIPs ESI, (Enhanced Serdes) 11.5Gbps
• RP (Route Processor)
Handles control plane traffic
Manages system
• ESP
Handles forwarding plane traffic
• SPA Interface Processor
Shared Port Adapters provide
interface connectivity
• Centralized Forwarding
Architecture
All traffic flows through the active ESP,
standby is synchronized with all flow
state with a dedicated ESI link
• Distributed Control Architecture
All major system components have a
powerful control processor dedicated for
control and management planes

ASR1000 Control Plane Links
• Ethernet out-of-band Channel (EOBC)
Run between ALL components
Indication if cards are installed and ready
Watchdog timers
State information exchange for L2 or L3
Protocols
• Inter-Integrated Circuit (I2C)
Monitor health of hardware components
Control resets
Communicate acive/standby, Real time
presence and ready indicators
Control the other RP (reset, power-
down,interrupt, report Power-supply status,
signal ESP active/standby)
EEPROM access
• SPA control links
Run between IOCP and SPAs
Detect SPA OIR
Reset SPAs (via I2C)
Power-control SPAs (via I2C)
Read EEPROMs
SPASPA
IOCP
SPA
Agg.
…
Interconn.
SPASPA
IOCP
SPA
Agg.
…
Interconn.
SPASPA
IOCP
SPA
Agg.
…
Interconn.
Route
Processor
(Standby)
Route
Processor
(active)
Forwarding
Processor
(Standby)
FECP
Interconn.
QFP
subsys-
tem
Crypto
assist
Forwarding
Processor
(active)
FECP
Interconn.
QFP
subsys-
tem
Crypto
assist
Midplane
RP RP
GE, 1Gbps
I2C
SPA Control
SPA Bus
SPASPA
IOCP
SPA
Agg.
…
Interconn.
SPASPA
IOCP
SPA
Agg.
…
Interconn.
SPASPA
IOCP
SPA
Agg.
…
Interconn.

FP = Forwarding Processor now known as the Embedded Services
Processor (ESP)
CPP = Cisco Packet Processor now known as the QuantumFlow
Processor (QFP)
PPEs = Packet Processor Elements
CC = CarrierCard now known as the SPA Interface Processor (SIP)
RP = Route Processor
FRU = Field Replaceable Unit
IOSd = IOS daemon, IOS process running on RP
ASR1000 - Naming

Cisco ASR1000 Series
ASR1001 ASR 1002 - F ASR 1002 ASR 1004 ASR 1006 ASR 1013
Chassis
Scalable to 5 Gbps
Four built-in GE ports
Software redundancy
Scalable to 2.5 Gbps
Software redundancy
Scalable to 10 Gbps
Software
redundancy
Scalable to 40 Gbps
Software
redundancy
Scalable to 100 Gbps
Hardware
redundancy
Scalable to 200Gbps
Hardware
redundancy
Embedded
Services
Processors
Integrated Software
Upgradeable
ASR1001-ESP2.5/5
(single)
Integrated ESP
(2.5-Gbps)
(single)
ASR1000-ESP5
(single)
ASR1000-ESP10
(single)
ASR1000-ESP10
(single)
ASR1000-ESP20
(single)
ASR1000-ESP40
(single)
ASR1000-ESP10
(redundant-optional)
ASR1000-ESP20
ASR1000-ESP40
ASR1000-ESP100
ASR1000-ESP40
ASR1000-ESP100
ASR1000-ESP200
Route Processor
Integrated
ASR1001-RP
(single)
Integrated
ASR1000-RP1
(single)
Integrated
ASR1000-RP1
(single)
ASR1000-RP1
(single)
ASR1000-RP2
(single)
ASR1000-RP1
ASR1000-RP2
ASR1000-RP2
SPA Interface
Processor
Integrated SIP10 Integrated SIP10 Integrated SIP10
ASR1000-SIP10
ASR1000-SIP40
ASR1000-SIP10
ASR1000-SIP40
ASR1000-SIP10
ASR1000-SIP40
SPA Slots 1 (single-height) 1 (single-height) 3 8 12 24

Cisco ASR1000 Series
ASR1001 ASR 1001 - X ASR 1002 ASR 1002 - X
Chassis
Scalable to 5 Gbps
Software redundancy
Scalable to 20 Gbps
Six built-in GE ports +
Two built-in 10GE ports
Software redundancy
Scalable to 10 Gbps
Software redundancy
Scalable to 40 Gbps+
Software redundancy
Embedded
Services
Processors
Integrated Software
Upgradeable
ASR1001-ESP2.5/5
(single)
Integrated Software
Upgradeable
ASR1001-X (2.5/5/10/20)
(single)
ASR1000-ESP5
(single)
ASR1000-ESP10
(single)
Integrated Software
Upgradeable
ASR1002-X (5/10/20/36)
(single)
Route Processor
Integrated
ASR1001
(single)
Integrated
ASR1001-X
(single)
Integrated
ASR1000-RP1
(single)
Integrated
ASR1002-X
(single)
SPA Interface
Processor
Integrated SIP10 Integrated ASR1001-X Integrated SIP10 Integrated ASR1002-X
SPA Slots 1 (single-height) 1 (single-height) 3 3

Chassis Options: ASR1006
RP1
in slots
“r0”&“r1”
ESP10
SIP10
SPAs
Rack Mounts and Cable Mgt not shown

Numbering Convention
USB 0 USB 1
PWR 1
PWR 0
SIP 2
F0
SIP 0
F1
SIP 1
R1
R0

------------------ show platform ------------------
Chassis type: ASR1006
Slot Type State Insert time (ago)
--------- ------------------- --------------------- -----------------
0 ASR1000-SIP10 ok 1d01h
0/0 SPA-2X1GE-V2 ok 1d01h
1 ASR1000-SIP10 ok 1d01h
1/0 SPA-8X1GE-V2 ok 1d01h
R0 ASR1000-RP2 ok, active 1d01h
R1 ASR1000-RP2 ok, standby 1d01h
F0 ASR1000-ESP20 ok, active 1d01h
F1 ASR1000-ESP20 ok, standby 1d01h
P0 ASR1013/06-PWR-AC ok 1d01h
P1 ASR1013/06-PWR-AC ok 1d01h
Slot CPLD Version Firmware Version
--------- ------------------- ---------------------------------------
0 14011701 15.4(2r)S
1 14011701 15.4(2r)S
R0 13092401 15.2(1r)S
R1 13092401 15.2(1r)S
F0 12071700 15.3(1r)S
F1 12071700 15.3(1r)S
Hardware configuration checking

RP Functions Summary
• CPU
Runs IOS
Control plane processing
Chassis management (via EOBC GE Switch, Inter-Integrate Circuit Mux…)
Activation / de-activation of other building blocks
Alarm handling
Logging
HA switchover
Image management
Processes legacy protocols (punt path)
• Console / Aux / Management Ethernet
Provide management access interfaces
Aux does not provide a normal CLI
• Interconnect
Provides interconnection for data path (via ESI)
• GE Switch
Provides interconnection to other building blocks (IPC over EOBC)
• I2CMux
Control plane interconnection to other building blocks (e.g. used for resets)

RP1 and RP2 Comparison
ASR1000 RP1 ASR1000 RP2
CPU 1.5GHz Dual-Core 2.67GHz
Memory 2GB default (2x1GB)
4GB maximum (2x2GB)
RP1 with 4GB built in
ASR1002 and
ASR1002-F
8GB default (4x2GB)
16GB maximum
(4x4GB)
Built-in eUSB bootflash 1GB (8GB on ASR-1002
and ASR1002-F)
2GB
NVRAM 32MB 32MB
Hard disk drive size 40GB 80GB
Chassis Support ASR 1002 (built-in),
ASR 1004 and ASR
1006
ASR 1004 and ASR
1006 and ASR1013
Cisco IOS XE Operating
System
32 bit 64 bit

ESP Functions
• Integrates QuantumFlow Processor Architecture
Data plane forwarding / Data plane services / QFP Client
MAC classification
L2/L3 forwarding
QoS
ACL
VPN
Netflow etc. etc. etc. etc. etc. etc.
• FECP
Manages ESP (Crypto, QFP, …)
Communicates with RP using IPC over EOBC
Statistics reporting to RP
OBFL
• Crypto
Processes security functions for data plane packets
• Data Interconnect to SIPs, RPs and other ESP if present
Enhanced SerDes Interconnect (ESI)
Supports 2 Data priorities + Control
• SPI Mux – System Packet Interface’s give 10Gbps BW
provides connectivity between QFP, Crypto and the Interconnect
Same standard interface used to connect to SPAs

Embedded Services Processors (ESP)
• Centralized, programmable forwarding engine
(i.e. QFP subsystem (PPE) and crypto engine)
providing full-packet processing
• Packet buffering and queuing/scheduling
(BQS)
For output traffic to carrier cards/SPA’s
For special features such as input shaping,
reassembly, replication, punt to RP, etc.
• Interconnect providing data path links (ESI)
to/from other cards over midplane
Transports traffic into and out of the Cisco
QuantumFlow Processor (QFP)
Input scheduler for allocating QFP BW among
ESI’s
• FECP CPU managing QFP, crypto device,
midplane links, etc
ESP10

Cisco QuantumFlow Processor (QFP)
Multi-Core (40) Packet
Processor
Traffic Manager
+ +
QuantumFlow
Processor
Software

ESP Generations
ESP-2.5G ESP-5G ESP-10G ESP-20G ESP-40G ESP-100G ESP-200G
System
Bandwidth
2.5Gbps 5Gbps 10Gbps 20Gbps 40Gbps 100Gbps 200Gbps
# of
Processors
(PPEs)
10 20 40 40 40 124 248
Clock Rate 900 Mhz 900 Mhz 900 Mhz 1.2 GHz 1.2 GHz 1.5 GHz 1.5 GHz
Crypto Engine
BW (1400
bytes)
1Gbps 1.8Gbps 4.4Gbps 8.5Gbps 11Gbps 29Gbps 78Gbps
QFP Resource
Memory
256MB 256MB 512MB 1GB 1GB 4GB 8GB
Packet Buffer 64MB 64MB 128MB 256MB 256MB 1GB 2GB
Control CPU 800 MHz 800 MHz 800 MHz 1.2 GHz
Dual core
1.86 GHz
Dual core
1.73 GHz
Dual core
1.73 GHz
Control
Memory
1GB 1GB 2GB 4GB 8GB 16GB 32GB
TCAM 10Mb 10Mb 10Mb 40Mb 40Mb 80Mb 2x80Mb
Chassis
Support
ASR 1002-F
(Integrated)
ASR 1002
ASR 1002,
1004, 1006
ASR 1004,
1006
ASR
1004,
1006,
1013
ASR1006,
1013
ASR1013

SIP10 and SIP40 Comparison
ASR1000-SIP10 ASR1000-SIP40
Bandwidth 10G 40G
Ingress Buffering 128MB 128MB
Egress Buffering 8MB 8MB
Bandwidth per ESI Link 11Gbps 23Gbps
ESI Links used 1 1 or 2

SIP10 Functions
• SPA Aggregation
Provides connectivity for data plane to SPAs
Ingress classification and buffering
Egress buffering
Reporting of egress queue status to ESP
• IOCP
Runs separate SPA driver for each SPA
Initialization, configuration, statistics, link handling events
Manages Carrier Card components
Handles OIR
Communicates with RP via IPC/EOBC
OBFL
• Interconnect
Provides Interconnection for the data path
• Network timing circuitry
Responsible for timing
Generate local clock

g
Interconn.
Ingress
classifier
Ingress
Scheduler
Egress
Buffer
Status
ESI, 10/40Gbps
SPA-SPI, 11.2Gbps
Other
4 SPAs
…
Ingress Buffers
(per port)
…
Egress Buffers
(per port)
ESPs
SPA Agg.
SPA
aggregation
ASIC
Data
32
1. SPA receives packet data from its network
interfaces and transfers the packet to the SIP
2. SPA Aggregation ASIC classifies the
packet into H/L priority
3. SIP writes packet data to external 128B memory
(at 40Gbps from 4 full-rate SPAs)
4. Ingress buffer memory is carved into 64 queues.
The queues are arranged by SPA-SPI channel
and optionally H/L. Channels on “channelized”
SPAs share the same queue.
5. SPA ASIC selects among ingress queues for
next pkt to send to ESP over ESI. It prepares
the packet for internal transmission
6. The interconnect transmits packet data of
selected packet over ESI to active ESP at up to
40 Gbps
7. Active ESP can backpressure SIP via ESI ctl
message to slow pkt transfer over ESI if
overloaded (provides separate backpressure
for Hi vs. Low priority pkt data)
Data Packet Flow: From SPA Through SIP

Data Packet Flow: Through ESP40
1. Packet arrives on QFP
2. Packet assigned to a PPE thread.
3. The PPE thread processes the packet in a
feature chain similar to 12.2S IOS (very
basic view of a v4 use case):
Input Features applied
NetFlow, MQC/NBAR Classify, FW, RPF,
Mark/Police, NAT, WCCP etc.
Forwarding Decision is made
Ipv4 FIB, Load Balance, MPLS, MPLSoGRE,
Multicast etc.
Output Features applied
NetFlow, FW, NAT, Crypto, MQC/NBAR
Classify, Police/Mark etc.
Finished
4. Packet released from on-chip memory
to Traffic Manager (Queued)
5. The Traffic Manager schedules which
traffic to send to which SIP interface (or
RP or Crypto Chip) based on priority and
what is configured in MQC
6. SIP can independently backpressure ESP
via ESI control message to pace the
packet transfer if overloaded
Interconnect
Pkt Buffer
DRAM
(128MB)
Part Len/
BW SRAM
Resource
DRAM
(512MB)
SIP-10
TCAM4
(10Mbit)
Processor pool
PPE0PPE0PPE0PPE1
PPE0PPE0PPE0PPE6
PPE0PPE0PPE0PPE2
PPE0PPE0PPE0PPE5
PPE0PPE0PPE0PPE3
… PPE0PPE0PPE0PPE40
PPE0PPE0PPE0PPE4
Buffer, queue, schedule
(BQS)
Quantum Flow
Processor
Buffer, queue, schedule
(BQS)
Buffer, queue, schedule (BQS)
Dispatcher/
Pkt Buffer
Data
ESI, 10/40Gbps
SPA-SPI, 11.2Gbps
Other
ASR System BW
(Depends on ESP)

g
Interconn.
Ingress
classifier
Ingress
Scheduler
Egress
Buffer
Status
ESI, 10/40Gbps
SPA-SPI, 11.2Gbps
Other
4 SPAs
…
Ingress Buffers
(per port)
…
Egress Buffers
(per port)
ESPs
SPA Agg.
SPA
Aggregation
ASIC
Data Packet Flow: Through SIP to SPA
1. Interconnect receives packet data over ESI from
the active ESP at up to 40 Gbps
2. SPA Aggregation ASIC receives the packet and
writes it to external egress buffer memory
3. Egress buffer memory is carved into 64 queues.
The queues are arranged by
egress SPA-SPI channel and optionally H/L.
Channels on “channelized” SPAs share
the same queue.
4. SPA Aggregation ASIC selects and transfers
packet data from eligible queues to SPA-SPI
channel (Hi queue are selected before Low)
5. SPA can backpressure transfer of packet data
burst independently for each SPA-SPI channel
using SPI FIFO status
6. SPA transmits packet data on network interface
Data

ASR 1002 & 1002-X, 1001, 1001-X Differences
ASR1002
• Each of the 3 main building blocks has its own control CPU
Route Processor (RP1)
Embedded services Processor (ESP5/ESP10)
SPA interface Processor (SIP10)
• Comes with 4GB DRAM (default and maximum)
• 32bit Architecture
ASR1002-X, ASR1001, ASR1001-X
• All 3 main building blocks are controlled by one CPU
RP, SIP, ESP
Default system bandwidth of 5 Gbps upgradable to 10, 20, 36 Gbps via software licenses
• Comes with 4GB DRAM (default); upgradeable to 8GB and 16GB DRAM. 16GB DRAM is
maximum. (ASR1002-X, ASR1001)
• Comes with 8GB DRAM (default); upgradeable to 16GB DRAM. 16GB DRAM is maximum.
(ASR1001-Х)
• 64bit Architecture

ASR1000 Software Architecture – IOS XE
• IOS XE = IOS + IOS XE Middleware +
Platform Software
• Operational Consistency - same look
and feel as IOS Router
• IOS runs as its own Linux process for
control plane (Routing, SNMP, CLI etc).
Capable of 64bit operation
• Linux kernel with multiple processes
running in protected memory for
Fault containment
Re-startability
ISSU of individual SW packages
• ASR 1000 HA Innovations
Zero-packet-loss RP Failover
<50ms ESP Failover
“Software Redundancy” SPA Interface Processor Embedded Services
Processor
Route Processor
Control Messaging
Kernel Kernel
Kernel
QFP
Client/Driver
Chassis
Manager
Interface
Manager
Forwarding
Manager
SPA
Driver
SPA
Driver
SPA
Driver
SPA
Driver
IOS
(Standby)
Forwarding
Manager
Chassis
Manager
IOS
(Active)
IOS XE Platform Adaptation Layer (PAL)
Interface
Manager
Chassis
Manager

Cisco.com->Support->Download

Support Model Cisco IOS XE Software Release
ASR 1000
Standard-Support 2.1, 2.2, 2.3, 2.5, 2.6, 3.2S, 3.3S, 3.5S, 3.6S, 3.8S,
3.9S
Extended-Support 2.4, 3.1S, 3.4S, 3.7S
Cisco IOS XE Software Release 3.7S End-of-Life Timeline
Cisco IOS XE Software Release Support

Support Model Cisco IOS XE Software Release
ASR 1000
Standard-Support 3.11S, 3.12S, 3.14S, 3.15S, etc.
Extended-Support 3.10S, 3.13S, 3.16S, etc.
Cisco IOS XE Software Release 3.10S is the first Extended-Support release
under the new support timeline. Every subsequent third release (for example,
Cisco IOS XE Software Releases 3.13S, 3.16S, etc.) will also be Extended-
Support releases.
Cisco IOS XE Software Release Support

Cisco IOS XE Software Standard-Support Schedule
Cisco IOS XE Software Standard-Support releases will be supported for 18
months with three rebuilds. The timing of the rebuilds will be as follows: 3 months,
3 months, and 6 months. Following the third rebuild will be a 6-month phase of
PSIRT. During the PSIRT phase, if it is deemed that a fourth rebuild is required,
then a scheduled rebuild will occur at the end of the Cisco Product Security
Incident Response Team (PSIRT) period (6 months from the third rebuild).

Cisco IOS XE Software Extended-Support Schedule
Cisco IOS XE Software Extended-Support releases will be supported for 48
months with eight rebuilds. The timing of the rebuilds will be as follows: 3
months, 3 months, 4 months, 4 months, 4 months, 6 months, 6 months, and 6
months. Following the eighth rebuild will be a 12-month phase of PSIRT. During
the PSIRT phase, if it is deemed that additional rebuilds are required, then a
scheduled rebuilds will occur 6 months into the PSIRT phase, or another at the
end of the PSIRT phase. If it is deemed that these additional rebuilds are not
required, then there will not be additional rebuilds.

Recommended ROMmon Release for Each FRU
------------------ show platform ------------------
......
Slot CPLD Version Firmware Version
--------- ------------------- ---------------------------------------
0 14011701 15.4(2r)S
1 14011701 15.4(2r)S
R0 13092401 15.2(1r)S
R1 13092401 15.2(1r)S
F0 12071700 15.3(1r)S
F1 12071700 15.3(1r)S
http://www.cisco.com/c/en/us/td/docs/routers/asr1000/release/notes/asr1k_rn_rel_notes/asr1k_rn_sys_req.html#pgfId-3201398

Вопрос №2
a) Как BRAS/ISG
b) Настроен NAT/PAT
c) Настроен IPSec/DMVPN
d) Как маршрутизатор для подключения к провайдеру (BGP)
e) Выжимаю из него все что умеет
Как Вы используете ASR1000?

ASR 1000 Memory Allocation
RP and Physical Memory Memory Allocated to IOSd
(w/o IOSd redundancy enabled)
Memory Allocated to Kernel
and other processes
RP1 (4GB) 1.7GB 2.3GB
RP2 (8GB) 4.2GB 3.8GB
RP2 (16GB) 10GB 6GB
ASR 1001 – 4GB 1.4GB 2.6GB
ASR 1001 – 8GB 4GB 4GB
ASR 1001 – 16GB 7GB 9GB
• Memory allocation is fixed by design, not configurable.
• If turn on IOSd redundancy, memory allocated to each IOSd is further reduced by
more than half comparing to memory allocation without IOSd redundancy enabled
• ASR 1001 memory is shared among RP, ESP, SIP

ASR 1000 System Resources To Monitor

show process memory output (IOS)
ASR1002
Processor Pool Total: 1695268496 Used: 362330804 Free: 1332937692
lsmpi_io Pool Total: 6295088 Used: 6294116 Free: 972
ASR1002-X
Processor Pool Total: 3905088960 Used: 2876800024 Free: 1028288936
lsmpi_io Pool Total: 6295128 Used: 6294296 Free: 832

show version output (IOS)
ASR1002
cisco ASR1002 (2RU) processor with 1655643K/6147K bytes of memory.
6 Gigabit Ethernet interfaces
32768K bytes of non-volatile configuration memory.
4194304K bytes of physical memory.
7798783K bytes of eUSB flash at bootflash:.
ASR1002-X
cisco ASR1002-X (2RU-X) processor with 3813739K/6147K bytes of memory.

show platform software status control-processor brief
ASR1002
Load Average
Slot Status 1-Min 5-Min 15-Min
RP0 Healthy 0.22 0.11 0.07
ESP0 Healthy 0.01 0.00 0.00
SIP0 Healthy 0.00 0.00 0.00
Memory (kB)
Slot Status Total Used (Pct) Free (Pct) Committed (Pct)
RP0 Healthy 3874476 1834856 (47%) 2039620 (53%) 2478476 (64%)
ESP0 Healthy 2009400 804956 (40%) 1204444 (60%) 586828 (29%)
SIP0 Healthy 471804 350112 (74%) 121692 (26%) 300896 (64%)
CPU Utilization
Slot CPU User System Nice Idle IRQ SIRQ IOwait
RP0 0 8.28 2.89 0.00 88.62 0.09 0.09 0.00
ESP0 0 2.40 18.70 0.00 78.80 0.00 0.10 0.00
SIP0 0 3.60 1.40 0.00 94.90 0.00 0.10 0.00

show platform software status control-processor brief
ASR1002-X
Load Average
Slot Status 1-Min 5-Min 15-Min
RP0 Healthy 0.08 0.07 0.07
Memory (kB)
Slot Status Total Used (Pct) Free (Pct) Committed (Pct)
RP0 Critical 8092408 8011928 (99%) 80480 ( 1%) 8284496 (102%)
CPU Utilization
Slot CPU User System Nice Idle IRQ SIRQ IOwait
RP0 0 8.00 2.40 0.00 89.58 0.00 0.00 0.00
1 0.40 0.60 0.00 98.99 0.00 0.00 0.00
2 0.10 0.20 0.00 99.70 0.00 0.00 0.00
3 0.00 0.00 0.00 100.00 0.00 0.00 0.00

show bgp vpnv4 unicast all summary
BGP router identifier 10.10.10.10, local AS number 00000
BGP table version is 122579269, main routing table version 122579269
511585 network entries using 130965760 bytes of memory
1007045 path entries using 112789040 bytes of memory
544817/77417 BGP path/bestpath attribute entries using 135114616 bytes of memory
5 BGP rrinfo entries using 200 bytes of memory
142975 BGP AS-PATH entries using 6954234 bytes of memory
15542 BGP community entries using 1359838 bytes of memory
82 BGP extended community entries using 2660 bytes of memory
578 BGP route-map cache entries using 36992 bytes of memory
0 BGP filter-list cache entries using 0 bytes of memory
BGP using 387223340 total bytes of memory
BGP activity 5254146/4742553 prefixes, 81675934/80668874 paths, scan interval 60 secs

Cisco ASR 1002-X Integrated Route Processor Product
Specifications
Item Details
Chassis support Cisco ASR 1002-X chassis
Software compatibility Cisco IOS XE Software Release 3.7.0S and later versions
Performance With 4-GB memory:
● Up to 500,000 IPv4 or 500,000 IPv6 routes
With 8-GB or more memory:
● Up to 1,000,000 IPv4 or 1,000,000 IPv6 routes – 8GB
Memory
● Up to 3,500,000 IPv4 or 3,000,000 IPv6 routes – 16GB
Memory
● BGP RR Scalability up to 7,000,000 IPv4 or 6,000,000
IPv6 routes – 8GB Memory
● BGP RR Scalability up to 13,000,000 IPv4 or 11,000,000
IPv6 routes – 16GB Memory
http://www.cisco.com/c/en/us/products/collateral/routers/asr-1000-series-aggregation-
services-routers/data_sheet_c78-441072.html

Software redundancy
#show running-config
...
redundancy
mode sso
#show version
...
cisco ASR1004 (RP2) processor with 1575783K/6147K bytes of memory.
8 FastEthernet interfaces
4 Packet over SONET interfaces
78085207K bytes of SATA hard disk at harddisk:.

Alarm LED Is Illuminated
If the CRIT, MAJ, or MIN alarm LED is illuminated, determine the cause of the alarm by doing one of the
following:
• Review the alarm message. The logging alarm command must be enabled for the system to send alarm
messages to the console. The following is an example of an alarm message that was generated when a
SPA was removed without a graceful deactivation of the SPA:
*Aug 22 13:27:33.774: %ASR1000_OIR-6-REMSPA: SPA removed from subslot 1/1, interfaces
disabled
*Aug 22 13:27:33.775: %SPA_OIR-6-OFFLINECARD: SPA (SPA-4XT-SERIAL) offline in subslot 1/1
• Enter the show facility-alarm status command. The following example shows a critical alarm that is
generated when a SPA is removed fr om the system:
Router# show facility-alarm status
System Totals Critical: 1 Major: 0 Minor: 0
Source Severity Description [Index]
------ -------- -------------------
subslot 1/1 CRITICAL Active Card Removed OIR Alarm [0]
A critical alarm "Active Card Removed OIR Alarm" is generated even if a SPA is removed after performing
graceful deactivation.

Critical Error LED indicator
#show facility-alarm status
System Totals Critical: 1 Major: 0 Minor: 0
Source Severity Description [Index]
------ -------- -------------------
GigabitEthernet0/0/0 CRITICAL Physical Port Link Down [1]
xcvr container 0/0/1 INFO Transceiver Missing [0]
xcvr container 0/0/2 INFO Transceiver Missing [0]
show run show interfaces
…
interface GigabitEthernet0/0/0
ip address 10.10.10.1 255.255.255.0
negotiation auto
!
interface GigabitEthernet0/0/1
no ip address
shutdown
negotiation auto
!
…
GigabitEthernet0/0/0 is down, line protocol is down
…
GigabitEthernet0/0/1 is administratively down, line
protocol is down
…

Critical Error LED indicator
Solution
Now that you know what is causing the alarm in this case you basically have two choices. You can
place the interface that is causing the status into admin down until you turn up the interface and
place it into testing or production. (ie in config-interface perform shutdown) This is preffered. You
could also just ignore the error, although it not suggested unless you're going to be turning up the
interface in the next couple minutes. If you have another critical issue you won't know the
difference, via the LED indicators in any case.
Finally, clearing the alarms with clear facility-alarm most likely won't work unless the state of the
interface(s) has changed either to admin down or up/up because the alarm will just be thrown again
in a couple of seconds. When the interface(s) are in a preferred state this alarm (LED indicator)
should clear automatically.

Automatic Router Shutdown
When the router detects a condition that could result in physical damage to system components, the router
can shut down without operator intervention. When the router shuts down automatically, the system
controller disables DC power to all internal components. All DC power remains disabled until you toggle the
power switch.
The default for automatic router shutdown is off. To allow automatic router shutdown, the facility-alarm
critical exceed-action shutdown command must be enabled. If the facility-alarm critical exceed-action
shutdown command is enabled, the router performs an automatic shutdown under the following
conditions:
Internal Temperature of Router or Power Supply Exceeds Temperature Threshold
Voltage of AC or DC Power Supplies Is Out of Tolerance
Power Supply Is Removed
Two power supplies must be installed in the chassis at all times to ensure sufficient cooling. The system
fans are inside the power supply units and must spin for cooling. Because all the system fans can be
powered by one power supply, the second power supply unit does not have to be powered on, but it must
be installed.
If a power supply is removed, the system can run with only one power supply for a maximum of five
minutes. The router waits five minutes before shutting down. This five-minute window allows time to
replace a failed power supply.
Two power supplies are not required but recommeneded for Cisco ASR 1001Router. An automatic 5
minute shutdown will not occur if power supply is removed for Cisco ASR 1001 Router.

Embedded Packet Capture
Embedded Packet Capture (EPC) is an onboard packet capture facility that allows
network administrators to capture packets flowing to, through, and from the device
and to analyze them locally or save and export them for offline analysis by using a
tool such as Wireshark. This feature simplifies network operations by allowing
devices to become active participants in the management and operation of the
network. This feature facilitates troubleshooting by gathering information about the
packet format.
#monitor capture cisco interface GigabitEthernet0/0/0 both
#monitor capture cisco buffer circular size 100
#monitor capture cisco match any
#monitor capture cisco start
#monitor capture cisco stop
#monitor capture cisco export tftp://10.10.10.10/cisco.pcap
http://www.cisco.com/c/en/us/td/docs/ios-xml/ios/epc/configuration/xe-3s/asr1000/epc-xe-3s-
asr1000-book/nm-packet-capture-xe.html

Embedded Event Manager
Embedded Event Manager (EEM) is a distributed and customized approach to
event detection and recovery offered directly in a Cisco IOS XE device. EEM offers
the ability to monitor events and take informational, corrective, or any desired EEM
action when the monitored events occur or when a threshold is reached. An EEM
policy is an entity that defines an event and the actions to be taken when that
event occurs.
event manager applet if_stats
event timer cron cron-entry "0,10,20,30 12 28 01 *"
action 1.02 cli command "enable"
action 1.03 cli command "show clock | append bootflash:if_stats.log"
action 1.04 cli command "show process cpu sorted | append bootflash:if_stats.log"
action 1.05 cli command "show interfaces | append bootflash:if_stats.log"
http://www.cisco.com/c/en/us/td/docs/ios-xml/ios/eem/configuration/xe-3s/asr1000/eem-xe-3s-
asr1000-book/eem-overview.html

Вопрос №3
С какими проблемами вы сталкивались при
работе с ASR1000
a) Некорректная работа BRAS/ISG
b) Некорректная работа NAT/PAT
c) Некорректная работа IPSec/DMVPN
d) Нехватка памяти
e) Крэш маршрутизатора
f) Проблем в работе не замечено

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Вы можете получить видеозапись данного семинара и текст
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Вебинар на русском языке
Тема: Outbound Option Dialer в UCCX/UCCE -
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