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601601 1094_06F9_c4 1094_06F9_c1 Cisco Systems, Inc. Inc. 1094_06F9_c4 © 1999, © 1999, Cisco Systems,
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Cisco Router Architecture Session 601
601 1094_06F9_c4
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Agenda
• Router Fundamentals • Layered Switching • Router Architectures/Switching Paths • Optimized Network Design • Troubleshooting 601 1094_06F9_c4
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Router Fundamentals
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What Is a Router? • Routers perform two main functions
List of Reachable Networks
OSPF, EIGRP,BGP Static Routes, Etc…
• Control path routines • Data path control (switching) Packet Frame
Packet
Layer 3 Switch
Packet Frame Frame
Packet
Layer 2 Encapsulation TTL-1 Layer 3 Checksum 601 1094_06F9_c4
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Routers (Operationally) • Maintain/manipulate routing information Listen for updates/update neighbors
• Classify packets for manipulation/queuing/permit-deny, etc. Compare packets to classification lists and perform control
• Perform Layer 3 switching Create outbound Layer 2 encapsulation Layer 3 checksum TTL/hop count update
• Management/billing (statistics) Interface statistics—Netflow export Telnet, SNMP, ping, trace route, HTTP 601 1094_06F9_c4
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Router Functionality
System Level Tasks
Control Plane
• • • • • •
Run routing protocols Maintain routing tables Check for CLI commands Increment accounting counters ICMP Queue packets, etc…
CPU
Data Plane Packet Switching
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Layer 1: Retime, Regenerate Signal Layer 2: Rewrite Header and CRC Layer 3: Decrement TTL and CRC Rewrite
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Routers (Layer 3 Packet Functionally) • (Attempt to) switch packets Layer 3 switching based on routing information
• (Attempt to) transmit packets Access outbound media
• Manipulate packets Change contents of packet (CAR/NAT/compression/encryption)
• Consume packets Routing protocol updates etc…/services advertisements(SAP)/ICMP/SNMP
• Generate packets Routing protocol packets/SAPs/ICMP/SNMP Tunnels—GRE, IPSec, DLSw etc… 601 1094_06F9_c4
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Generic Router Architectures
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Shared Memory
CPU Memory
CPU
Routing Table
Shared Memory
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Interface
Interface
Interface
Interface
Shared Bus
Electrical Limitations Limit of Shared Bus Switches <= 20 Gbps Thus 10 Gbps/No. Line Cards = Max Line Rate
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SM Data Path (Conventional)
CPU Memory
CPU
Routing Table
Shared Memory
Interface
Interface
Interface
Interface
Shared Bus
One Packet/Switching Cycle 601 1094_06F9_c4
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SM Data Path (Distributed Processors) CPU Memory CPU
Routing Table CPU
Interface CPU
Interface CPU
Interface CPU
Shared Memory 601 1094_06F9_c4
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Interface
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Cross Bar Data Path CPU Memory CPU
Routing Table CPU
Interface
i/p
CPU
Interface o/p
CPU
Interface CPU
Interface
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Cross Bar Data Path CPU Memory CPU
Routing Table CPU
Interface
Bit Slicing Allows Multiple Switching Fabrics
CPU
Interface CPU
Interface CPU
Interface
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Cisco Router Components
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General Router Hardware
Flash
CPU
NVRAM ROM
Bus Interface
RAM
System Bus
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Interface
Interface
Interface
Network Controller
Network Controller
Network Controller
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Software Components • ROM monitor
• Device microcode
Startup diagnostic code Contains exception handling
Part of Cisco IOS that deals with network controllers Microcode deals with modular interface processors
• RxBoot Host mode Operating System Used for downloading full Cisco IOS®
• Cisco IOS Internetwork operating system Contains process scheduler, memory manager, parser Also contains protocolspecific code for packet handling 601 1094_06F9_c4
• Configuration register 16 Bits, specifies router startup parameters
• Configuration file Startup-config: Contains configuration info Running-config: Currently active configuration
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Memory Usage
Boot Flash
PCMCIA Flash
RxBoot
Cisco IOS File
NVRAM
Cisco IOS Exec
Main
Running config
Routing Table
System Buffers
Data Structures
Layer 2/3 Cache
Interface Buffers
Startup-Config Config Reg. ROM ROM Monitor
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CPU
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RAM
I/O
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Cisco Router Buffers and Queues
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Router Interface Buffers • Interface FIFO A very small amount of buffer memory (for large MTUs not even one packet in size) used to store bits as they arrives from the wire and are dealt with by the interface driver These buffers are NOT configurable
• Interface Rx and Tx RING On some platforms these buffers are used by the interface driver for reception and transmission of packets Each interface has a FIFO Rx/Tx Ring Inbound (Rx) they are used to store a packet until an Interface buffer is available. Outbound (Tx) until the interface can transmit to the wire They can exist on the interface card or in shared memory These buffers are NOT normally configurable 601 1094_06F9_c4
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Router Internal Buffers • Buffer Headers These data structures containing information about related buffer (e.g. location pointers, size, etc.). They are mostly located in main processor memory for all buffers. In some cases headers or particle headers may be stored in shared I/O memory for speed The purpose of buffer headers is to keep track of buffers and enqueue them for various processes
• Shared or main memory system buffers These buffers are used when packets are bound for the processor for either consumption or process switching System buffers are sized as small (104), middle (600), big (1,524), very big (4,520), large (5,024), and huge (18,024) The total number of buffers depends on available DRAM System buffers can grow or Trim on demand and can be configured These buffers are public. All interfaces can use them 601 1094_06F9_c4
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Router Internal Buffers • Shared memory interface buffers These buffers are used to store packets between the interface driver and the switching path (not process switching) software (e.g optimum switching) These buffers are allocated at startup or after OIR. The number of buffers depends on the speed and MTU of the interfaces available These buffers are Interface specific These buffers are NOT configurable
• Shared memory interface particle buffers Used as Packet buffers on some platforms and VIP cards Particle Buffers are located in Shared I/O Memory Their size is 512 bytes (or 128 byte multicast/broadcast) The incoming packets are “scattered” into 512 byte particles and then “gathered” into a contiguous packets for transmission” These buffers are NOT configurable 601 1094_06F9_c4
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Contiguous Buffers • Contiguous buffers Contiguous buffers (older platforms as well as RSP/RSM) store packets in buffers sized with respect to the interface media MTU and speed The amount of buffers is based on grouping the MTUs of the interfaces e.g. Ethernet = 1500b MTU, Token Ring/FDDI = 4500b MTU Let’s assume we have 6 Ethernet and 2 FDDI = 2 buffer pools. (all the Ethernet I/f share the 1500b pool and all the FDDI share the 4500b pool) Based on the aggregate bandwidth we get: Ethernet = (60/60+200) = 23% and FDDI = (200/60+200) = 77% We then apportion the available buffers (let’s say it’s a 7K SP) (.23*504K)/1500 = 79 buffers and (.77*504K)/4500 = 88 Buffers Therefore, 601 1094_06F9_c4
79/6 = 12 buffers/Ethernet interface and 88/2 = 44 buffers/FDDI interface 23
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Contiguous Buffers • Contiguous buffers Packet buffers (contiguous) can be wasteful in terms of memory (Frames are rarely all full size), but more importantly are not as efficient as particles when it comes to packet replication In contiguous buffers the packets is treated as a whole, therefore to create a replication of the packet with a different output header requires a completely new packet to be created 1500
Ethernet Interface Buffer Pool 601 1094_06F9_c4
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4500
FDDI Interface Buffer Pool 24
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Particles vs. Contiguous Buffers • On some newer platforms (36xx, 72xx, 71xx, VIP2) packet memory is allocated in “particles”. Particles are either 1024b (36xx), 512b or 128b chunks of memory • Packets are divided into particle size blocks and stored in free particles • Particles have an associated Particle Buffer header which stores information as to which particles constitute an entire frame and or an?
I/P Buffer Header
Particle Headers Packet Memory Divided Into Particles O/P Buffer Header
Particle Headers 601 1094_06F9_c4
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Particles vs. Contiguous Buffers • We have the ability to “clone” particle buffer headers • This allows us to “replicate” a packets particles a number of times without actually replicating the packet itself for every outbound interface. This significantly improved multicast performance I/P Buffer Header New Header New Header Particle Headers Cloned Particle Headers
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Particle Headers Packet Memory Divided into Particles O/P Buffer Header O/P Buffer Header 26
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Types of Queues • System interface queues Input hold queues Used to queue packets in system buffers for process switching These queues are based in Main Processor Memory The size of Input Hold queue is configurable per interface basis Use “Show Interface” to look at Input Queue statistics Output hold queues These queues are used for packets in System buffers after they have been process switched and are waiting to be transmitted by the interface driver These queues exist in main processor memory The size of input hold queue is configurable per interface basis Use “Show Interface” to look at output queue statistics 601 1094_06F9_c4
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Types of Queues • Interface Queues Receive Queues The queues are used for incoming packets that wait in interface buffers for Fast Switching code Receive queue usually has a size limit (called RQL) which is calculated based upon various factors By default the RQL = Total buffers in a pool/no. interfaces in that pool (If for any reason this results in less than 16KB of buffers RQL= 16384/MTU) Transmit Queues These queues are used for outgoing packets that wait in interface buffers for transmission by outgoing interface driver code 601 1094_06F9_c4
Transmit queue usually has a size limit (called TQL) which is calculated based upon various factors © 1999, Cisco Systems, Inc.
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Router Operating System Details
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Cisco IOS Image and File Storage • BOOT ROM EPROM used for startup diagnostic code and ROM monitor (read only) and to load Cisco IOS
• NVRAM Used to store startup configuration (rewritable). Configuration register settings
• PCMCIA FLASH Portable storage of Cisco IOS image, configuration files etc… (rewritable)
• FLASH Onboard storage of full Cisco IOS (rewritable). In some cases Cisco IOS execution 601 1094_06F9_c4
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Operational Storage • DRAM Used to store loaded Cisco IOS, running configuration, route tables, switching caches, processor and switched packets
• SRAM Used on platforms to deal with high-speed switching and high-speed interfaces
• FIFO First-In, First-Out memory used for interface buffering (not queued—circular buffer or RING) 601 1094_06F9_c4
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Elements of Execution • ROM MONITOR (System Bootstrap, or Bootstrap code) Hardware configuration and system diagnostics performed at system startup
• RxBOOT (Boot Helper image, Helper Cisco IOS, or Bootstrap Image) A Subset of the Cisco IOS, used when a valid Cisco IOS image is not present allowing a user to download a full Cisco IOS image from the network
• Cisco IOS Cisco IOS normally resides in Flash or PCMCIA Flash card and is loaded into processor memory (DRAM) for execution In some platforms it may also run from Flash memory to save DRAM
• ROUTER CONFIG The Startup configuration is stored in NVRAM and a copy is loaded in DRAM at startup 601 1094_06F9_c4
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Configuration Register Function • Force the system into the bootstrap program • Select a boot source and default boot filename • Recognition of break signal from console • Control broadcast addresses • Set the console terminal baud rate • Load operating software from ROM • Enable booting from a Trivial File Transfer Protocol (TFTP) server 601 1094_06F9_c4
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Router Startup ROM Monitor Diagnostic Check, Console Setup, Memory Sizing, Config Register Check Loads Rxboot, or Stays in ROMMON [rommon>]
RxBoot Builds Basic Data Structures, Interface Setup, Host Mode Functionality, Startup-Config Check loads Cisco IOS, or Stays in RxBoot [router(boot)>]
Cisco IOS Interface Setup, Router Functionality, Allocate Buffers, Loads Startup-Config Boot Process Complete [router>] 601 1094_06F9_c4
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How Routers Receive and Transmit Packets
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Receiving Packet Shared Memory
Buffer Headers Process Scheduler
66
44
CPU
Packet Packet on on Interface Interface
22
Interface Interface Driver Driver Code Code
33
Frame Frame Check Check
22 33
Fail
x
55
11
Discard Frame Update Frame errors, e.g. “Runt, Giant, CRC”
OK 11
44
55
66
601 1094_06F9_c4
No
Yes
R
Interface FIFO Buffer
Assign Assign aa Free Free Buffer Buffer Header Header
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Discard Frame Increment “Overrun” If CPU Too Slow
Increment “Ignore” Free Free Buffer Buffer No Increment “No Header Header Available Available Buffer” *Drop Packet* Yes Return to Scheduled Processes Move Move Packet Packet to to
Shared Shared Memory Memory
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Receiving a Packet (Process Switching) Classify Classify Packet Packet
System Memory IP Process Input Hold Queue
Yes
Fast Cache
Can Can the the Packet Packet Be Be Fast Fast Switched Switched
88
Assign Assign System System Buffer Buffer Return Return Packet Packet Buffer Buffer to to Free Free List List
99
Enqueue Enqueue Packet Packet for for Process Process Switching Switching
If “Input Hold Queue” Full, *Drop Packet* Increment “Input Queue Drop”
Rx Rx Interrupt Interrupt Complete Complete Return Return CPU CPU to to Scheduled Scheduled Tasks Tasks
How Is This Box Related?
77
99
88
88
No
CPU
System System Buffers Buffers
Go to FastSwitching
77
Interface Rx Interrupt FIFO Buffer 601 1094_06F9_c4
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Transmitting a Packet (Process Switching) System Memory Output Hold Queue
Forwarding Forwarding Decision Decision
11 11
10 10 12 12
Write Write New New Header Header Over Over Old Old Header Header
11 11
Packet Packet Is Is Enqueued Enqueued in in for for Output Output I/f I/f in in Output Output Hold Hold Queue Queue
How Is this Box Related?
12 12
Packet Packet Is Is Transmitted Transmitted
If Output Hold Queue Is Full, Packet Is Dropped With an “Output Queue Drop”
CPU
System System Buffers Buffers
Interface FIFO Buffer
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Transmitting a Packet (Fast Switching)
88
77
Can Can the the Packet Packet be be Fast Fast Switched Switched
o/p
CPU
10 10 Packet Buffers
11 11
Interface FIFO Buffer
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Yes
77
TQL i/p 99
Classify Classify Packet Packet
Fast Cache
Packet Memory
If No Output Buffer Available Drop Packet With “Output Buffer Failure” Note: If “Transmit Buffer Backing-Store” Is Enabled the Packet Will Be Moved to System Buffers and Dequeued as with Process Switching An Output Buffer Swap Is Incremented
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Go to FastSwitching
88
Obtain Output Header From Fast Cache
99
Rewrite Header and Move Buffer Header or Move Packet to Output Interface Buffer
10 10
Enqueue Packet for Interface Transmit Queue
11 11 Transmit Packet 39
Packet Switching “Processes” and “Functions”
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Processes and Functions • Process switching is a collection of functions based on a particular protocol that is being switched • The Scheduler gives processor time to each “Process” which may call a number of “Functions” before the “Process” is complete • Each “Process” is run to completion unless a higherpriority “Process” is invoked. The original “Process” is suspended until such time as the higher-priority “Process” is completed at which time the original “Process” will continue to be run
IP Input
Compression Compression Encryption Encryption
Process 601 1094_06F9_c4
I/P I/P ACLs ACLs
CAR CAR
Completed
Functions 41
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Processes and Functions • For Fast and ½ Fast Switching there is no concept of a “Input Process” • The Fast Switching code, invoked after an Rx Interrupt, calls various functions, independently as defined by the configuration file for an interface or protocol • Some features are run in Rx Interrupt mode, but the packets are moved to system buffers depending on the requirements of the feature (e.g. NAT) MLPPP
NAT
IPSec
Function Calls Rx Interrupt 601 1094_06F9_c4
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Processes and Functions • Dequeuing is the function used when a packet has been process switched and needs to be passed to the output interface, or when an interface has “fancy” queuing enabled and again packets are stored in system buffers until they are dequeued (based on queuing mechanism) System System Buffers Buffers
Output Output Hold Hold Q Q
Shared System Memory (DRAM)
Output I/f
Packet Packet Buffers Buffers “Fancy” “Fancy” Queued Queued Packets Packets
Shared Packet Memory (SRAM) 601 1094_06F9_c4
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Processes and Functions • In the case of “fancy” queuing being applied to an interface, the Output Hold Queue represents either the (4) Priority, (>16) Custom or (>256) Weighted Fair queues • In Process switching this is a FIFO queue by default Process Switching Priority Queuing Custom Queuing
L
N
M H
0
1
2
3
Output Hold Q
FIFO
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Process Switching Dequeue Dequeue Packet Packet from from Input Input Hold Hold Queue Queue
IP Process Input Hold Queue Input Processing
Compressed Compressed
System Memory
No
Encrypted Encrypted No
Input Input ACL ACL
CPU
Permit
Yes
Yes
Deny
Decompress Packet
Decrypt Packet
*Drop Packet*
Conform/Not Conform CAR Action
CAR CAR Is Is TTL>0 TTL>0
No
*Drop Packet*
Yes
TTL=TTL-1 TTL=TTL-1 NAT NAT Transform Transform
Yes
Out->In NAT
Attempt Attempt to to Forward Forward Packet Packet
= Packet Compared To Access List in Configuration 601 1094_06F9_c4
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Process Switching IP Process Output Hold Queue Output Processing
Broadcast Broadcast No
System Memory
Policy Policy Route Route No
NAT NAT Transform Transform
CPU
Yes
Yes
Yes
Broadcast Packet
Policy Route
In->Out
No
Route Table
Look Look Up Up Route Route Output Output ACL ACL
Deny
*Drop Packet*
Permit
Encryption Encryption Compression Compression
Yes Yes
Encrypt Packet Compress Packet
= Packet Compared To Access List in Configuration 601 1094_06F9_c4
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How Routers Make Switching Decisions
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Routing Tables • Forwarding information populated by IGPs and EGPs RIP, OSPF, Statics, EIGRP etc… c3620#sh ip route Codes: C - connected, S - static, I - IGRP, R - RIP, M - mobile, B - BGP D - EIGRP, EX - EIGRP external, O - OSPF, IA - OSPF inter area N1 - OSPF NSSA external type 1, N2 - OSPF NSSA external type 2 E1 - OSPF external type 1, E2 - OSPF external type 2, E - EGP i - IS-IS, L1 - IS-IS level-1, L2 - IS-IS level-2, * - candidate default U - per-user static route, o - ODR Gateway of last resort is 0.0.0.0 to network 0.0.0.0 1.0.0.0/24 is subnetted, 2 subnets 1.1.1.0 is directly connected, Ethernet0/0 1.1.2.0 is directly connected, Loopback1 10.0.0.0/24 is subnetted, 1 subnets C 10.64.217.0 is directly connected, Ethernet0/1 S* 0.0.0.0/0 is directly connected, Ethernet0/1 C C
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Adjacency Information • Discovered in various ways including ARP protocol c3620#sh arp Protocol Address Internet 1.1.1.1 Internet 1.1.1.5 Internet 32.97.105.46 Internet 1.1.1.6 Internet 171.68.225.9 Internet 209.17.176.120 Internet 204.71.200.74 Internet 128.32.18.166 Internet 152.163.241.223 Internet 38.15.254.206 Internet 206.79.171.51
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Age (min) 118 153 4 145 142 91 156 161 144 153
Hardware Addr 0010.7b1f.4a61 00a0.c903.6077 0000.0caa.2350 00a0.c903.6064 0000.0caa.2350 0000.0caa.2350 0000.0caa.2350 0000.0caa.2350 0000.0caa.2350 0000.0caa.2350 0000.0caa.2350
Type ARPA ARPA ARPA ARPA ARPA ARPA ARPA ARPA ARPA ARPA ARPA
Interface Ethernet0/0 Ethernet0/0 Ethernet0/1 Ethernet0/0 Ethernet0/1 Ethernet0/1 Ethernet0/1 Ethernet0/1 Ethernet0/1 Ethernet0/1 Ethernet0/1
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A Cached Table of Forwarding and Adjacency Information • Initialized after a packet has been successfully Process Switched and *Can* be cached… c3620#sh ip ca verb IP routing cache 3 entries, 516 bytes 232 adds, 229 invalidates, 0 refcounts Minimum invalidation interval 2 seconds, maximum interval 5 seconds, quiet interval 3 seconds, threshold 0 requests Invalidation rate 0 in last second, 0 in last 3 seconds Prefix/Length 1.1.1.5/32-24 1.1.1.151/32-24 171.69.0.0/16-0
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Age Interface Next Hop 21:07:47 Ethernet0/0 1.1.1.5 14 00A0C903607700107B1F4A610800 00:06:22 Ethernet0/0 1.1.1.151 14 000039542C0800107B1F4A610800 01:16:08 Ethernet0/1 171.69.10.34 14 00000CAA235000107B1F4A620800
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Finding an Entry in a Table • We could look sequentially through each entry until we find the one we are looking for • This could end up being very time consuming and (unless the tables were sorted inversely with time) probably end up with the most useful entries (i.e. the most recent ones) at the end • Also it is possible that a more specific and more optimized entry maybe missed if we take the first one we find sequentially Prefix/Length 1.1.1.5/32 1.1.1.151/32 171.68.0.0/16 171.68.1.0/24 199.2.54.0/24 601 1094_06F9_c4
Age Interface Next Hop 20:50:18 Ethernet0/0 1.1.1.5 00:08:20 Ethernet0/0 1.1.1.151 00:43:59 Ethernet0/1 171.70.10.70 This would come first 00:08:39 Ethernet0/2 171.68.11.34 This is more specific 00:03:54 Ethernet0/1 199.2.54.193
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How Binary Trees Help Us Speed up Performance Linear List Look-Up Find X=4 X=n X=n X=n X=n
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1 2 3 4 5 6 7 8 9
ü
This Is OK for Small Tables of Information Where the Maximum Look up Time Is the Number on Entries in the List
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How Binary Trees Help Us Speed up Performance Binary List Look-Up Find X=4 Find Midpoint of the List
Find Midpoint of the List
1 3 4 6 8 9 11
An Entry in a Table W/2 Billion Entries Will Take 32 Iterations
1 3 4
ü
4
If X= -> L, Found, If X< -> L, look in first half of the list, else look in the second half
If X= -> L, Found, If X< -> L, look in first half of the list, else look in the second half 601 1094_06F9_c4
Or… 53
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How Binary Trees Help Us Speed-Up Performance Binary List Look-Up Find X=4 LHS
RHS This Is a Node (In This Case the Root Node)
6
Compare X to Root Node If X = RN Done If X < RN Search in LHS If X > RN Search in RHS
3 1
9 4
8
11
Look-Up Time = (Max = Logn, Where N=no. Nodes) 601 1094_06F9_c4
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Cisco Router Internals (Low-Mid Range)
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Low-End Systems
Main DRAM Cisco IOS (Not 1600/2500) Running Config Data Structures
Shared DRAM Switch Cache Routing Tables Buffer Headers
SRAM 7200 (Npe150/200)
Tx and Rx Rings
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Contiguous System Buffers (Small, Large, Huge, Etc.) Public, Dynamic, Configurable Contiguous Interface Buffers Private, Static, Configurable Particle Based in 7200 (512 B) 3600 (1524 B), Nonconfigurable
Particle-based Interface Buffer. (3 Hi BW PA Only), Nonconfigurable
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Tx and Rx Descriptor Rings Private, Circular Linked Lists
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28
Cisco 1000/2500 Family
601 1094_06F9_c4
57
© 1999, Cisco Systems, Inc.
Cisco 100x Series
I/O Buses Serial CSU/DSU BRI S/T, U
601 1094_06F9_c4
Boot ROM M 68360 SCC
Ethernet
© 1999, Cisco Systems, Inc.
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CPU Bus
CPU Console
NVRAM PCMCIA DRAM
58
29
Cisco 160x Series
WIC
Boot ROM
WIC Slot
Console
I/O Buses Serial CSU/DSU BRI S/T, U
601 1094_06F9_c4
M 68360 SCC
CPU Bus
NVRAM
CPU
PCMCIA DRAM SIMM On Board DRAM
Ethernet
59
© 1999, Cisco Systems, Inc.
Cisco 25xx Series
Async 2509-2512 Hub Ports 2505, 2507 2516
Dual UART M 68030
Sys Ctrl ASIC
CPU Bus
Mgmt Card 2517-2519 Daughter and Hub Cards
WIC Slots 2524, 2525 System Bus
WIC
Boot ROM NVRAM PCMCIA Flash
Ether/TR WAN Intf
601 1094_06F9_c4
On Board DRAM
© 1999, Cisco Systems, Inc.
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DRAM SIMM
60
30
Cisco 3600 Family
601 1094_06F9_c4
61
© 1999, Cisco Systems, Inc.
PCI Bridge
PCMCIA
Dual UART
R 4700 CPU Bus Sys Ctrl GT 64010
Boot ROM I/O Bus
Network Modules
PCI Bridge PCI Bus 0
Network Modules
PCI Bus 1 PCI Bus 2
Cisco 36x0 Series
NVRAM Flash DRAM
601 1094_06F9_c4
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31
Cisco 4000 Family
601 1094_06F9_c4
63
© 1999, Cisco Systems, Inc.
DBus
NIMs
Dual UART M 68030
Sys Ctrl Logic Shared DRAM
601 1094_06F9_c4
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CPU Bus
Control Bus
Cisco 4000 and 4000M
Boot ROM NVRAM Flash / EPROM Main DRAM
64
32
Cisco 4500 and 4700
Power Supply
601 1094_06F9_c4
Control Bus
R 4600 R 4700
Dual UART
CPU Bus Other Logic Shared DRAM
Sys Ctrl ASICs
I/O Bus
DBus
NIMs
Layer 2 Cache 4700 Only
Boot ROM NVRAM Flash
Main DRAM
Boot Flash
65
© 1999, Cisco Systems, Inc.
Low-Mid Router Comparison CPU Bus
4000
M68030
CISC
40 MHz
32 bit
NIM
-
4000M
M68030
CISC
40 MHz
32 bit
NIM
-
4500
R4600
RISC
100 MHz
64 bit
NIM
-
4500M
R4600
RISC
100 MHz
64 bit
NIM
-
4700
R4700
RISC
133 MHz
64 bit
NIM
512 KB
4700M
R4700
RISC
133 MHz
64 bit
NIM
512 KB
3620
R4700
RISC
80 MHz
64 bit
NM,WIC,VIC
-
3640
R4700
RISC
100 MHz
64 bit
NM,WIC,VIC
-
25xx
M68360
CISC
20 MHz
32 bit
Built in
-
17xx
?????
??????
BI,WIC,VIC
-
M68360
????? CISC
?????
160x
33 MHz
32 bit
BI,WIC,VIC
-
100x
M68360
CISC
25 MHz
32 bit
Built in
-
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INTERFACES
4xxx
TYPE
36XX
PROCESSOR
601 1094_06F9_c4
CLOCK
Layer 2 CACHE
CPU
66
33
High-End Systems Main DRAM Switch Cisco IOS (Not 1600/2500) Cache Running Routing Configuration Tables Data Buffer Structures Headers Contiguous System Buffers Public, Dynamic, Configurable
DRAM
IProc
Microcode Local Buff Tx and Rx Rings 601 1094_06F9_c4
Micro Processor Network Controllers
SRAM
CPU RP SP/SSP
RSP SRAM
Contiguous Interface Buffers Shared, Static, Nonconfigurable
VIP
Particle Based 256 B Local Buffs Tx and Rx Rings
Micro Processor
DRAM
VIP Cisco IOS
Distributed Cache
PA Network Controllers
PA Network Controllers
© 1999, Cisco Systems, Inc.
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Cisco 7200/7500 Family
601 1094_06F9_c4
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34
PCI Bridge
PA 3
PCI Bridge
PA 1
PCI Bridge
PCI Bus 2
PA 5
PCI Bus 1
Cisco 720x Series PCI Bridge
PA 6
PCI Bridge
PA 4
PCI Bridge
PA 2
I/O Controller Fast Ether
PCMCIA
SRAM ! NPE-100
PCI Bus 0 CPU Bus
Sys Ctrl GT 64010
Dual UART
Boot ROM
I/O Bus NVRAM 601 1094_06F9_c4
Boot Flash
CPU NPE
PCI PCI Bridge Bridge
Midplane
DRAM
EEPROM
R 4700 R 5000 Layer 2 Cache NPE-200 69
© 1999, Cisco Systems, Inc.
SP/SSP EEPROM
Bit Slice Proc.
Multi Bus Intf Logic
Local Bus SRAM
CxBus Intf DMA Logic
Diag Bus Intf Logic
Multi Bus
Cisco 70x0—RP and SP/SSP I/O Devices
RP I/O Ctrl
M 68040
CPU Bus Multi Bus Intf Logic
Diag Bus Intf Logic
DRAM
Diag Bus Cx Bus Fan Tray
601 1094_06F9_c4
Intf Proc.
Intf Proc.
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Cx Bus Arbiter
70
35
Cisco 70x0—RSP7000 Dual UART
EEPROM
Boot ROM
Envm Logic
NVRAM
DRAM I/O Bus
CI Board
PCMCIA
Diag Bus Intf Logic
Register FPGA Diag Bus FPGA
Boot Flash
RSP7K
Sys Ctrl ASICs
R 4600 CPU Bus SRAM
MemD Ctrl ASICs
QA ASIC
Diag Bus Cx Bus Fan Tray
601 1094_06F9_c4
IP/VIP
IP / VIP
Cx Bus Arbiter
71
© 1999, Cisco Systems, Inc.
Cisco 75xx Series Dual UART
NVRAM
I/O Bus
Boot ROM
RSP
PCMCIA
Register FPGA Diag Bus FPGA
Boot Flash
Sys Ctrl ASICs
DRAM Layer 2 Cache
R 4600 R 4700 R 5000
CPU Bus MemD Ctrl ASICs
SRAM QA ASIC
Diag Bus Cy Bus 1
Cy Bus 0 IP/VIP
601 1094_06F9_c4
IP/VIP
Cy Bus Arbiter
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IP/VIP
IP/VIP
72
36
VIP PCI Bridge 2
PCI Bus 0
DRAM
PCI Bridge 1
Boot ROM SRAM PMA ASICs
DRAM Ctrl ASICs
I/O Ctrl ASIC
Layer 2 Cache
CYA ASICs
EEPROM
CBus
601 1094_06F9_c4
R 4600 R 4700 R 5000
CPU Bus Packet Bus
PA
PCI Bus 1
PA
PCI Bus 2
Cisco 75xx Series—VIP
Diag Bus
73
© 1999, Cisco Systems, Inc.
High End Router Comparison TYPE
RSP1
R4600
RISC
100 MHz
64 bit
IP,VIP1,VIP2
RSP2
R4600/R4700
RISC
100 MHz
64 bit
IP,VIP1,VIP2
-
RSP4
R5000
RISC
200 MHz
64 bit
IP,VIP1,VIP2
512 KB
VIP2-15
R4700
RISC
100 MHz
64 bit
PA
512 KB
VIP2-40
R4700
RISC
100 MHz
64 bit
PA
512 KB
VIP2-50
R4700
RISC
200 MHz
64 bit
PA
512 KB
NPE100
R4700
RISC
150 MHz
64 bit
PA,IO -FE
512 KB
NPE150
R4700
RISC
150 MHz
64 bit
PA,IO -FE
512 KB
NPE200
R5000
RISC
200 MHz
64 bit
PA,IO -FE
512 KB
RP
M68040
RISC
40 MHz
32 bit
IP, VIP1
-
RP
M68040
RISC
40 MHz
32 bit
IP, VIP1
-
RSP7K
R4600
RISC
100 MHz
64 bit
IP, VIP1,VIP2
-
601 1094_06F9_c4
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INTERFACES
-
7500
CPU Bus
7200
CLOCK
Layer 2 CACHE
PROCESSOR
7000
CPU
74
37
GSR Family
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75
© 1999, Cisco Systems, Inc.
GSR Switch Fabric Switch Fabric Cards CPU
I/f
CPU
I/f
CPU
I/f
CPU
I/f
CPU
I/f
CPU
I/f
CPU
I/f
CPU
I/f
CPU
I/f
CPU
I/f
CPU
CPU
RP
RP
Clock and Scheduler Cards 601 1094_06F9_c4
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38
Each Card can Switch 15Gbps
GSR Throughput
Transceivers
CPU
I/f
CPU
RP 1.25Gbps per Trace 601 1094_06F9_c4
77
© 1999, Cisco Systems, Inc.
GSR RP
Layer 2 Cache
DRAM
SRAM
Tiger Asic
CSAR
R5000 CPU
FIA
SLI
Tranciever
FIA
SLI
Tranciever
R5000 CPU Executes Cisco IOS Software —200mhz RISC Processor
I/O BUS
Layer 2 CACH—512KB Write through Data and Instruction Cache
Ethernet
NVRAM
DRAM Memory for Main Storage Supporing up to 256MB
PCMCIA Console Flash SIMM
TIGER ASIC Connects RP to DRAM, CSAR I/O Bus
Boot ROM
CSAR Segments and Reassembles Packets SAR SRAM Provides a Cache for the CSAR FABRIC INTERFACE ASICS Manage Cisco Cells to and from the Fabric SLI ASICS Encode Packets for Transmission on the Fabric 8B/10B Encoding Similar to Gigabit Ethernet or FDDI
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39
GSR Switch Processor Configurations
Mode
CSC
SFC
Bandwidth Clock Redundancy
Fabric Redundancy
Entry Level
1
0
622Mbps
none
none
Redundant Entry
2
0
622Mbps
1:1
1:1
High BW
1
3
2.4Gbps
none
none
High BW
2
2
2.4Gbps
1:1
none
Redundant High BW 2
3
2.4Gbps
1:1
1:N
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© 1999, Cisco Systems, Inc.
GSR Interface Card
Tx
512Kb 512Kb Burst Burst Buffer Buffer
Rx
Processor
512Kb 512Kb Burst Burst Buffer Buffer
SQE 16-64MB 16-64MB Buffer Buffer Memory Memory
16-64MB 16-64MB Buffer Buffer Memory Memory
CPU
I/f
Fabric Interface
601 1094_06F9_c4
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80
40
Head of Line Blocking (HOL)
Blocked (grrrrr!!)
601 1094_06F9_c4
81
© 1999, Cisco Systems, Inc.
Output Queue CPU
C Interface
C
A
C
B
Delayed/ Dropped
B Interface
Congested
C
Interface
Shared Memory 601 1094_06F9_c4
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41
“Lane Control” B
A
D
C
B A
C
B A
D
D A
B
C
C
D 601 1094_06F9_c4
83
© 1999, Cisco Systems, Inc.
All Destinations Have a Lane B
A
D
C
B A
C
B A
D
D A
B
C
C
No interface (Outbound) Can affect another Interface
D 601 1094_06F9_c4
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42
Virtual Input Queuing CPU FIFO
C
FIFO
B
C
Interface
C
A
Delayed/ Dropped
B Interface
Congested
C
Interface
Shared Memory 601 1094_06F9_c4
85
© 1999, Cisco Systems, Inc.
Virtual Input Queue CPU FIFO
C
C
C
Queue Scheduler
FIFO Interface
B
A
B
Interface
Congested
C
Interface
Shared Memory 601 1094_06F9_c4
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86
43
Please Complete Your Evaluation Form Session 601
601 1094_06F9_c4 1094_06F9_c1
© 1999, Cisco Systems, Inc.
87
601 1094_06F9_c1
© 1999, Cisco Systems, Inc.
88
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