Packet Trace

First Published: August 03, 2016

The Packet-Trace feature provides a detailed understanding of how data packets are processed by the Cisco IOS XE platform, and thus helps customers to diagnose issues and troubleshoot them more efficiently. This module provides information about how to use the Packet-Trace feature.

Information About Packet Trace

The Packet-Trace feature provides three levels of inspection for packets: accounting, summary, and path data. Each level provides a detailed view of packet processing at the cost of some packet processing capability. However, Packet Trace limits inspection to packets that match the debug platform condition statements, and is a viable option even under heavy-traffic situations in customer environments.

The following table explains the three levels of inspection provided by packet trace.

Table 1. Packet-Trace Level

Packet-Trace Level

Description

Accounting

Packet-Trace accounting provides a count of packets that enter and leave the network processor. Packet-Trace accounting is a lightweight performance activity, and runs continuously until it is disabled.

Summary

At the summary level of packet trace, data is collected for a finite number of packets. Packet-Trace summary tracks the input and output interfaces, the final packet state, and punt, drop, or inject packets, if any. Collecting summary data adds to additional performance compared to normal packet processing, and can help to isolate a troublesome interface.

Path data

The packet-trace path data level provides the greatest level of detail in packet trace. Data is collected for a finite number of packets. Packet-Trace path data captures data, including a conditional debugging ID that is useful to correlate with feature debugs, a timestamp, and also feature-specific path-trace data.

Path data also has two optional capabilities: packet copy and Feature Invocation Array (FIA) trace. The packet-copy option enables you to copy input and output packets at various layers of the packet (layer 2, layer 3 or layer 4). The FIA- trace option tracks every feature entry invoked during packet processing and helps you to know what is happening during packet processing.

Note

 
Collecting path data consumes more packet-processing resources, and the optional capabilities incrementally affect packet performance. Therefore, path-data level should be used in limited capacity or in situations where packet performance change is acceptable.

Usage Guidelines for Configuring Packet Trace

Consider the following best practices while configuring the Packet-Trace feature:

  • Use of ingress conditions when using the Packet-Trace feature is recommended for a more comprehensive view of packets.
  • Packet-trace configuration requires data-plane memory. On systems where data-plane memory is constrained, carefully consider how you will select the packet-trace values. A close approximation of the amount of memory consumed by packet trace is provided by the following equation:

memory required = (statistics overhead) + number of packets * (summary size + data size + packet copy size).

When the Packet-Trace feature is enabled, a small, fixed amount of memory is allocated for statistics. Similarly, when per-packet data is captured, a small, fixed amount of memory is required for each packet for summary data. However, as shown by the equation, you can significantly influence the amount of memory consumed by the number of packets you select to trace, and whether you collect path data and copies of packets.

Configuring Packet Trace

Perform the following steps to configure the Packet-Trace feature.


Note


The amount of memory consumed by the Packet-Trace feature is affected by the packet-trace configuration. You should carefully select the size of per-packet path data and copy buffers and the number of packets to be traced in order to avoid interrupting normal services. You can check the current data-plane DRAM memory consumption by using the show platform hardware qfp active infrastructure exmem statistics command.

SUMMARY STEPS

  1. enable
  2. debug platform packet-trace packet pkt-num [fia-trace | summary-only] [circular] [data-size data-size ]
  3. debug platform packet-trace {punt |inject|copy|drop|packet|statistics}
  4. debug platform condition [ipv4 | ipv6] [interface interface ][access-list access-list -name | ipv4-address / subnet-mask | ipv6-address / subnet-mask ] [ingress | egress |both]
  5. debug platform condition start
  6. debug platform condition stop
  7. show platform packet-trace {configuration | statistics | summary | packet {all | pkt-num }}
  8. clear platform condition all
  9. exit

DETAILED STEPS

  Command or Action Purpose

Step 1

enable

Example:


Router> enable

Enables the privileged EXEC mode. Enter your password if prompted.

Step 2

debug platform packet-trace packet pkt-num [fia-trace | summary-only] [circular] [data-size data-size ]

Example:


Router# debug platform packet-trace packets 2048 summary-only

Collects summary data for a specified number of packets. Captures feature path data by default, and optionally performs FIA trace.

pkt-num —Specifies the maximum number of packets maintained at a given time.

fia-trace —Provides detailed level of data capture, including summary data, feature-specific data. Also displays each feature entry visited during packet processing.

summary-only —Enables the capture of summary data with minimal details.

circular —Saves the data of the most recently traced packets.

data-size —Specifies the size of data buffers for storing feature and FIA trace data for each packet in bytes. When very heavy packet processing is performed on packets, users can increase the size of the data buffers if necessary. The default value is 2048.

Step 3

debug platform packet-trace {punt |inject|copy|drop|packet|statistics}

Example:


Router# debug platform packet-trace punt

Enables tracing of punted packets from data to control plane.

Step 4

debug platform condition [ipv4 | ipv6] [interface interface ][access-list access-list -name | ipv4-address / subnet-mask | ipv6-address / subnet-mask ] [ingress | egress |both]

Example:


Router# debug platform condition interface g0/0/0 ingress 

Specifies the matching criteria for tracing packets. Provides the ability to filter by protocol, IP address and subnet mask, access control list (ACL), interface, and direction.

Step 5

debug platform condition start

Example:


Router# debug platform condition start

Enables the specified matching criteria and starts packet tracing.

Step 6

debug platform condition stop

Example:


Router# debug platform condition start

Deactivates the condition and stops packet tracing.

Step 7

show platform packet-trace {configuration | statistics | summary | packet {all | pkt-num }}

Example:


Router# show platform packet-trace 14

Displays packet-trace data according to the specified option. See {start cross reference} Table 21-1 {end cross reference} for detailed information about the show command options.

Step 8

clear platform condition all

Example:


Router(config)# clear platform condition all

Removes the configurations provided by the debug platform condition and debug platform packet-trace commands.

Step 9

exit

Example:


Router# exit

Exits the privileged EXEC mode.

Configuring Packet Tracer with UDF Offset

Perform the following steps to configure the Packet-Trace UDF with offset:

SUMMARY STEPS

  1. enable
  2. configure terminal
  3. udf udf name header {inner | outer} {13|14} offset offset-in-bytes length length-in-bytes
  4. udf udf name {header | packet-start} offset-base offset length
  5. ip access-list extended {acl-name |acl-num}
  6. ip access-list extended { deny | permit } udf udf-name value mask
  7. debug platform condition [ipv4 | ipv6] [ interface interface ] [access-list access-list -name | ipv4-address / subnet-mask | ipv6-address / subnet-mask ] [ ingress | egress |both ]
  8. debug platform condition start
  9. debug platform packet-trace packet pkt-num [ fia-trace | summary-only] [ circular ] [ data-size data-size ]
  10. debug platform packet-trace {punt | inject|copy | drop |packet | statistics}
  11. debug platform condition stop
  12. exit

DETAILED STEPS

  Command or Action Purpose

Step 1

enable

Example:


Device> enable

Enables privileged EXEC mode.

  • Enter your password if prompted.

Step 2

configure terminal

Example:


Device# configure terminal

Enters global configuration mode.

Step 3

udf udf name header {inner | outer} {13|14} offset offset-in-bytes length length-in-bytes

Example:


Router(config)# udf TEST_UDF_NAME_1 header  inner l3 64 1 

Router(config)# udf TEST_UDF_NAME_2 header  inner l4 77 2

Router(config)# udf TEST_UDF_NAME_3 header outer l3 65 1
Router(config)# udf TEST_UDF_NAME_4 header outer l4 67 1 

Configures individual UDF definitions. You can specify the name of the UDF, the networking header from which offset, and the length of data to be extracted.

The inner or outer keywords indicate the start of the offset from the unencapsulated Layer 3 or Layer 4 headers, or if there is an encapsulated packet, they indicate the start of offset from the inner L3/L4.

The length keyword specifies, in bytes, the length from the offset. The range is from 1 to 2.

.

Step 4

udf udf name {header | packet-start} offset-base offset length

Example:


Router(config)# udf TEST_UDF_NAME_5 packet-start 120 1 
  • header—Specifies the offset base configuration.

  • packet-start—Specifies the offset base from packet-start. packet-start” can vary depending on if packet-trace is for an inbound packet or outbound packet. If the packet-trace is for an inbound packet then the packet-start will be layer2. For outbound, he packet-start will be layer3.

  • offset—Specifies the number of bytes offset from the offset base. To match the first byte from the offset base (Layer 3/Layer 4 header), configure the offset as 0.

  • length—Specifies the number of bytes from the offset. Only 1 or 2 bytes are supported. To match additional bytes, you must define multiple UDFs.

Step 5

ip access-list extended {acl-name |acl-num}

Example:


Router(config)# ip access-list extended acl2

Enables extended ACL configuration mode. The CLI enters the extended ACL configuration mode in which all subsequent commands apply to the current extended access list. Extended ACLs control traffic by the comparison of the source and destination addresses of the IP packets to the addresses configured in the ACL.

Step 6

ip access-list extended { deny | permit } udf udf-name value mask

Example:


Router(config-acl)# permit ip any any udf TEST_UDF_NAME_5 0xD3 0xFF

Configures the ACL to match on UDFs along with the current access control entries (ACEs) . The bytes defined in ACL is 0xD3. Masks are used with IP addresses in IP ACLs to specify what should be permitted and denied.

Step 7

debug platform condition [ipv4 | ipv6] [ interface interface ] [access-list access-list -name | ipv4-address / subnet-mask | ipv6-address / subnet-mask ] [ ingress | egress |both ]

Example:


Router# debug platform condition interface gi0/0/0 ipv4 access-list acl2 both 

Specifies the matching criteria for tracing packets. Provides the ability to filter by protocol, IP address and subnet mask, access control list (ACL), interface, and direction.

Step 8

debug platform condition start

Example:


Router# debug platform condition start

Enables the specified matching criteria and starts packet tracing.

Step 9

debug platform packet-trace packet pkt-num [ fia-trace | summary-only] [ circular ] [ data-size data-size ]

Example:


Router# debug platform packet-trace packet 1024 fia-trace data-size 2048

Collects summary data for a specified number of packets. Captures feature path data by default, and optionally performs FIA trace.

pkt-num —Specifies the maximum number of packets maintained at a given time.

fia-trace —Provides detailed level of data capture, including summary data, feature-specific data. Also displays each feature entry visited during packet processing.

summary-only —Enables the capture of summary data with minimal details.

circular —Saves the data of the most recently traced packets.

data-size —Specifies the size of data buffers for storing feature and FIA trace data for each packet in bytes. When very heavy packet processing is performed on packets, users can increase the size of the data buffers if necessary. The default value is 2048.

Step 10

debug platform packet-trace {punt | inject|copy | drop |packet | statistics}

Example:


Router# debug platform packet-trace punt

Enables tracing of punted packets from data to control plane.

Step 11

debug platform condition stop

Example:


Router# debug platform condition start

Deactivates the condition and stops packet tracing.

Step 12

exit

Example:


Router# exit

Exits the privileged EXEC mode.

Displaying Packet-Trace Information

Use these show commands to display packet-trace information.

Table 2. show Commands

Command

Description

show platform packet-trace configuration

Displays packet trace configuration, including any defaults.

show platform packet-trace statistics

Displays accounting data for all the traced packets.

show platform packet-trace summary

Displays summary data for the number of packets specified.

show platform packet-trace {all | pkt-num } [decode]

Displays the path data for all the packets or the packet specified. The decode option attempts to decode the binary packet into a more human- readable form.

Removing Packet-Trace Data

Use these commands to clear packet-trace data.

Table 3. clear Commands

Command

Description

clear platform packet-trace statistics

Clears the collected packet-trace data and statistics.

clear platform packet-trace configuration

Clears the packet-trace configuration and the statistics.

Configuration Examples for Packet Trace

This section provides the following configuration examples:

Example: Configuring Packet Trace

This example describes how to configure packet trace and display the results. In this example, incoming packets to Gigabit Ethernet interface 0/0/1 are traced, and FIA-trace data is captured for the first 128 packets. Also, the input packets are copied. The show platform packet-trace packet 0 command displays the summary data and each feature entry visited during packet processing for packet 0.


Router> 
enable
Router# debug platform packet-trace packet 128 fia-trace
Router# debug platform packet-trace punt 
Router# debug platform condition interface g0/0/1 ingress
Router# debug platform condition start
Router#! ping to UUT
Router# debug platform condition stop
Router# show platform packet-trace packet 0
Packet: 0           CBUG ID: 9
Summary
  Input     : GigabitEthernet0/0/1
  Output    : GigabitEthernet0/0/0
  State     : FWD
  Timestamp 
    Start   : 1819281992118 ns (05/17/2014 06:42:01.207240 UTC)
    Stop    : 1819282095121 ns (05/17/2014 06:42:01.207343 UTC)
Path Trace
  Feature: IPV4
    Source      : 198.51.100.2
    Destination : 198.51.100.2
    Protocol    : 1 (ICMP)
  Feature: FIA_TRACE
    Entry     : 0x8059dbe8 - DEBUG_COND_INPUT_PKT
    Timestamp : 3685243309297
  Feature: FIA_TRACE
    Entry     : 0x82011a00 - IPV4_INPUT_DST_LOOKUP_CONSUME
    Timestamp : 3685243311450
  Feature: FIA_TRACE
    Entry     : 0x82000170 - IPV4_INPUT_FOR_US_MARTIAN
    Timestamp : 3685243312427
  Feature: FIA_TRACE
    Entry     : 0x82004b68 - IPV4_OUTPUT_LOOKUP_PROCESS
    Timestamp : 3685243313230
  Feature: FIA_TRACE
    Entry     : 0x8034f210 - IPV4_INPUT_IPOPTIONS_PROCESS
    Timestamp : 3685243315033
  Feature: FIA_TRACE
    Entry     : 0x82013200 - IPV4_OUTPUT_GOTO_OUTPUT_FEATURE
    Timestamp : 3685243315787
  Feature: FIA_TRACE
    Entry     : 0x80321450 - IPV4_VFR_REFRAG
    Timestamp : 3685243316980
  Feature: FIA_TRACE
    Entry     : 0x82014700 - IPV6_INPUT_L2_REWRITE
    Timestamp : 3685243317713
  Feature: FIA_TRACE
    Entry     : 0x82000080 - IPV4_OUTPUT_FRAG
    Timestamp : 3685243319223
  Feature: FIA_TRACE
    Entry     : 0x8200e500 - IPV4_OUTPUT_DROP_POLICY
    Timestamp : 3685243319950
  Feature: FIA_TRACE
    Entry     : 0x8059aff4 - PACTRAC_OUTPUT_STATS
    Timestamp : 3685243323603
  Feature: FIA_TRACE
    Entry     : 0x82016100 - MARMOT_SPA_D_TRANSMIT_PKT
    Timestamp : 3685243326183

Router# clear platform condition all
Router# exit

Linux Forwarding Transport Service (LFTS) is a transport mechanism to forward packets punted from the CPP into applications other than IOSd. This example displays the LFTS-based intercepted packet destined for binos application.

Router# show platform packet-trace packet 10
Packet: 10     CBUG ID: 52
Summary
  Input  : GigabitEthernet0/0/0
  Output : internal0/0/rp:1
  State  : PUNT 55 (For-us control)
  Timestamp
    Start : 597718358383 ns (06/06/2016 09:00:13.643341 UTC)
    Stop : 597718409650 ns (06/06/2016 09:00:13.643392 UTC)
Path Trace
  Feature: IPV4
    Input  : GigabitEthernet0/0/0
    Output : <unknown>
    Source : 10.64.68.2
    Destination : 224.0.0.102
    Protocol : 17 (UDP)
      SrcPort : 1985
      DstPort : 1985
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : <unknown>
    Entry  : 0x8a0177bc - DEBUG_COND_INPUT_PKT
    Lapsed time : 426 ns
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : <unknown>
    Entry  : 0x8a017788 - IPV4_INPUT_DST_LOOKUP_CONSUME
    Lapsed time : 386 ns
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : <unknown>  
    Entry  : 0x8a01778c - IPV4_INPUT_FOR_US_MARTIAN
    Lapsed time : 13653 ns
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : internal0/0/rp:1
    Entry  : 0x8a017730 - IPV4_INPUT_LOOKUP_PROCESS_EXT
    Lapsed time : 2360 ns
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : internal0/0/rp:1
    Entry  : 0x8a017be0 - IPV4_INPUT_IPOPTIONS_PROCESS_EXT
    Lapsed time : 66 ns
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : internal0/0/rp:1
    Entry  : 0x8a017bfc - IPV4_INPUT_GOTO_OUTPUT_FEATURE_EXT
    Lapsed time : 680 ns
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : internal0/0/rp:1
    Entry  : 0x8a017d60 - IPV4_INTERNAL_ARL_SANITY_EXT
    Lapsed time : 320 ns
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : internal0/0/rp:1
    Entry  : 0x8a017a40 - IPV4_VFR_REFRAG_EXT
    Lapsed time : 106 ns
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : internal0/0/rp:1
    Entry  : 0x8a017d2c - IPV4_OUTPUT_DROP_POLICY_EXT
    Lapsed time : 1173 ns  
  Feature: FIA_TRACE
    Input  : GigabitEthernet0/0/0
    Output : internal0/0/rp:1
    Entry  : 0x8a017940 - INTERNAL_TRANSMIT_PKT_EXT
    Lapsed time : 20173 ns
  LFTS Path Flow: Packet: 10    CBUG ID: 52
    Feature: LFTS
    Pkt Direction: IN
    Punt Cause  : 55
         subCause : 0

Example: Using Packet Trace

This example provides a scenario in which packet trace is used to troubleshoot packet drops for a NAT configuration on a Cisco ASR 1006 Router. This example shows how you can effectively utilize the level of detail provided by the Packet-Trace feature to gather information about an issue, isolate the issue, and then find a solution.

In this scenario, you can detect that there are issues, but are not sure where to start troubleshooting. You should, therefore, consider accessing the Packet-Trace summary for a number of incoming packets.


Router# debug platform condition ingress
Router# debug platform packet-trace packet 2048 summary-only
Router# debug platform condition start
Router# debug platform condition stop
Router# show platform packet-trace summary
Pkt   Input             Output            State  Reason
0     Gi0/0/0           Gi0/0/0           DROP   402 (NoStatsUpdate)
1     internal0/0/rp:0  internal0/0/rp:0  PUNT   21  (RP<->QFP keepalive)
2     internal0/0/recycle:0  Gi0/0/0      FWD

The output shows that packets are dropped due to NAT configuration on Gigabit Ethernet interface 0/0/0, which enables you to understand that an issue is occurring on a specific interface. Using this information, you can limit which packets to trace, reduce the number of packets for data capture, and increase the level of inspection.


Router# debug platform packet-trace packet 256
Router# debug platform packet-trace punt
Router# debug platform condition interface Gi0/0/0
Router# debug platform condition start
Router# debug platform condition stop
Router# show platform packet-trace summary 
Router# show platform packet-trace 15
Packet: 15          CBUG ID: 238
Summary
  Input     : GigabitEthernet0/0/0
  Output    : internal0/0/rp:1
  State     : PUNT 55  (For-us control)
  Timestamp
    Start   : 1166288346725 ns (06/06/2016 09:09:42.202734 UTC)
    Stop    : 1166288383210 ns (06/06/2016 09:09:42.202770 UTC)
Path Trace
  Feature: IPV4
    Input       : GigabitEthernet0/0/0
    Output      : <unknown>
    Source      : 10.64.68.3
    Destination : 224.0.0.102
    Protocol    : 17 (UDP)
      SrcPort   : 1985
      DstPort   : 1985
IOSd Path Flow: Packet: 15    CBUG ID: 238
  Feature: INFRA
    Pkt Direction: IN
    Packet Rcvd From CPP
  Feature: IP
    Pkt Direction: IN
    Source      : 10.64.68.122
    Destination : 10.64.68.255
  Feature: IP
    Pkt Direction: IN
    Packet Enqueued in IP layer
    Source      : 10.64.68.122
    Destination : 10.64.68.255
    Interface   : GigabitEthernet0/0/0
  Feature: UDP
    Pkt Direction: IN
    src         : 10.64.68.122(1053)
    dst         : 10.64.68.255(1947)
    length      : 48

Router#show platform packet-trace packet 10 
Packet: 10          CBUG ID: 10
Summary
  Input     : GigabitEthernet0/0/0
  Output    : internal0/0/rp:0
  State     : PUNT 55  (For-us control)
  Timestamp
    Start   : 274777907351 ns (01/10/2020 10:56:47.918494 UTC)
    Stop    : 274777922664 ns (01/10/2020 10:56:47.918509 UTC)
Path Trace
  Feature: IPV4(Input)
    Input       : GigabitEthernet0/0/0
    Output      : <unknown>
    Source      : 10.78.106.2
    Destination : 224.0.0.102
    Protocol    : 17 (UDP)
      SrcPort   : 1985
      DstPort   : 1985
 
IOSd Path Flow: Packet: 10    CBUG ID: 10
  Feature: INFRA
    Pkt Direction: IN
Packet Rcvd From DATAPLANE
 Feature: IP
    Pkt Direction: IN
    Packet Enqueued in IP layer
    Source      : 10.78.106.2
    Destination : 224.0.0.102
    Interface   : GigabitEthernet0/0/0

  Feature: UDP
    Pkt Direction: IN DROP
    Pkt : DROPPED
    UDP: Discarding silently 
    src        : 881 10.78.106.2(1985)
    dst         : 224.0.0.102(1985)
    length      : 60

Router#show platform packet-trace packet  12
Packet: 12          CBUG ID: 767
Summary
  Input     : GigabitEthernet3
  Output    : internal0/0/rp:0
  State     : PUNT 11  (For-us data)
  Timestamp
    Start   : 16120990774814 ns (01/20/2020 12:38:02.816435 UTC)
    Stop    : 16120990801840 ns (01/20/2020 12:38:02.816462 UTC)
Path Trace
  Feature: IPV4(Input)
    Input       : GigabitEthernet3
    Output      : <unknown>
    Source      : 12.1.1.1
    Destination : 12.1.1.2
    Protocol    : 6 (TCP)
      SrcPort   : 46593
      DstPort   : 23
IOSd Path Flow: Packet: 12    CBUG ID: 767
  Feature: INFRA
    Pkt Direction: IN
    Packet Rcvd From DATAPLANE

  Feature: IP
    Pkt Direction: IN
    Packet Enqueued in IP layer
    Source      : 12.1.1.1
    Destination : 12.1.1.2
    Interface   : GigabitEthernet3

  Feature: IP
    Pkt Direction: IN
    FORWARDEDTo transport layer
    Source        : 12.1.1.1
    Destination   : 12.1.1.2
    Interface     : GigabitEthernet3

  Feature: TCP
    Pkt Direction: IN
    tcp0: I NoTCB 12.1.1.1:46593 12.1.1.2:23 seq 1925377975 OPTS 4 SYN  WIN 4128
Router# show platform packet-trace summary                                  
Pkt   Input                     Output                    State  Reason         
0     INJ.2                     Gi1                       FWD                   
1     Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
2     INJ.2                     Gi1                       FWD                   
3     Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
4     INJ.2                     Gi1                       FWD                   
5     INJ.2                     Gi1                       FWD                   
6     Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
7     Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
8     Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
9     Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
10    INJ.2                     Gi1                       FWD                   
11    INJ.2                     Gi1                       FWD                   
12    INJ.2                     Gi1                       FWD                   
13    Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
14    Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
15    Gi1                       internal0/0/rp:0          PUNT   11  (For-us data)
16    INJ.2                     Gi1                       FWD                   

The following example displays the packet trace data statistics.

Router#show platform packet-trace statistics
Packets Summary
  Matched  3
  Traced   3
Packets Received
  Ingress  0
  Inject   0
Packets Processed
  Forward  0
  Punt     3
    Count       Code  Cause
    3           56    RP injected for-us control
  Drop     0
  Consume  0
 
          PKT_DIR_IN 
             Dropped       Consumed       Forwarded
INFRA            0             0             0
TCP              0             0             0
UDP              0             0             0
IP               0             0             0
IPV6             0             0             0
ARP              0             0             0
 
         PKT_DIR_OUT 
             Dropped       Consumed       Forwarded
INFRA            0             0             0
TCP              0             0             0
UDP              0             0             0
IP               0             0             0
IPV6             0             0             0
ARP              0             0             0

The following example displays packets that are injected and punted to the forwarding processor from the control plane.

Router#debug platform condition ipv4 10.118.74.53/32 both
 Router#Router#debug platform condition start
Router#debug platform packet-trace packet 200
Packet count rounded up from 200 to 256

Router#show platform packet-tracer packet 0
show plat pack pa 0
Packet: 0           CBUG ID: 674
Summary
  Input     : GigabitEthernet1
  Output    : internal0/0/rp:0
  State     : PUNT 11  (For-us data)
  Timestamp
    Start   : 17756544435656 ns (06/29/2020 18:19:17.326313 UTC)
    Stop    : 17756544469451 ns (06/29/2020 18:19:17.326346 UTC)
Path Trace
  Feature: IPV4(Input)
    Input       : GigabitEthernet1
    Output      : <unknown>
    Source      : 10.118.74.53
    Destination : 198.51.100.38
    Protocol    : 17 (UDP)
      SrcPort   : 2640
      DstPort   : 500

IOSd Path Flow: Packet: 0    CBUG ID: 674
  Feature: INFRA
  Pkt Direction: IN
    Packet Rcvd From DATAPLANE

  Feature: IP
  Pkt Direction: IN
    Packet Enqueued in IP layer
    Source      : 10.118.74.53
    Destination : 198.51.100.38
    Interface   : GigabitEthernet1

  Feature: IP
  Pkt Direction: IN
  FORWARDED To transport layer
    Source        : 10.118.74.53
    Destination   : 198.51.100.38
    Interface     : GigabitEthernet1

  Feature: UDP
  Pkt Direction: IN
  DROPPED
	UDP: Checksum error: dropping
	Source      : 10.118.74.53(2640)
	Destination : 198.51.100.38(500)

Router#show platform packet-tracer packet 2
Packet: 2           CBUG ID: 2

IOSd Path Flow:
  Feature: TCP
  Pkt Direction: OUTtcp0: O SYNRCVD 198.51.100.38:22 198.51.100.55:52774 seq 3052140910 OPTS 4 ACK 2346709419 SYN  WIN 4128

  Feature: TCP
  Pkt Direction: OUT
  FORWARDED
	TCP: Connection is in SYNRCVD state
	ACK         : 2346709419
	SEQ         : 3052140910
	Source      : 198.51.100.38(22)
	Destination : 198.51.100.55(52774)


  Feature: IP
  Pkt Direction: OUTRoute out the generated packet.srcaddr: 198.51.100.38, dstaddr: 198.51.100.55

  Feature: IP
  Pkt Direction: OUTInject and forward successful srcaddr: 198.51.100.38, dstaddr: 198.51.100.55

  Feature: TCP
  Pkt Direction: OUTtcp0: O SYNRCVD 198.51.100.38:22 198.51.100.55:52774 seq 3052140910 OPTS 4 ACK 2346709419 SYN  WIN 4128
Summary
  Input     : INJ.2
  Output    : GigabitEthernet1
  State     : FWD
  Timestamp
    Start   : 490928006866 ns (06/29/2020 13:31:30.807879 UTC)
    Stop    : 490928038567 ns (06/29/2020 13:31:30.807911 UTC)
Path Trace
  Feature: IPV4(Input)
    Input       : internal0/0/rp:0
    Output      : <unknown>
    Source      : 172.18.124.38
    Destination : 172.18.124.55
    Protocol    : 6 (TCP)
      SrcPort   : 22
      DstPort   : 52774
  Feature: IPSec
    Result    : IPSEC_RESULT_DENY
    Action    : SEND_CLEAR
    SA Handle : 0
    Peer Addr : 55.124.18.172
    Local Addr: 38.124.18.172
 

Router#

Additional References

Standards

Standard

Title

None

MIBs

MIB

MIBs Link

None

To locate and download MIBs for selected platforms, Cisco IOS releases, and feature sets, use Cisco MIB Locator found at this URL:

{start hypertext}http://www.cisco.com/go/mibs{end hypertext}

RFCs

RFC

Title

None

Technical Assistance

Description

Link

The Cisco Support and Documentation website provides online resources to download documentation, software, and tools. Use these resources to install and configure the software and to troubleshoot and resolve technical issues with Cisco products and technologies. Access to most tools on the Cisco Support and Documentation website requires a Cisco.com user ID and password.

{start hypertext}http://www.cisco.com/cisco/web/support/index.html{end hypertext}

Feature Information for Packet Trace

{start cross reference}Table 21-4{end cross reference} lists the features in this module and provides links to specific configuration information.

Use Cisco Feature Navigator to find information about platform support and software image support. Cisco Feature Navigator enables you to determine which software images support a specific software release, feature set, or platform. To access Cisco Feature Navigator, go to{start hypertext} http://www.cisco.com/go/cfn{end hypertext}. An account on Cisco.com is not required.


Note


{start cross reference}Table 21-4{end cross reference} lists only the software releases that support a given feature in a given software release train. Unless noted otherwise, subsequent releases of that software release train also support that feature.
Table 4. Feature Information for Packet Trace

Feature Name

Releases

Feature Information

Packet Trace

Cisco IOS XE 3.10S

The Packet Trace feature provides information about how data packets are processed by the Cisco IOS XE software.

In Cisco IOS XE Release 3.10S, this feature was introduced on the Cisco ASR 1000 Series Aggregation Services Routers.

The following commands were introduced or modified:

  • debug platform packet-trace packet pkt-num [fia-trace | summary-only ] [data-size data-size ] [circular ]
  • debug platform packet-trace copy packet {input | output | both } [size num-bytes ] [L2 | L3 | L4 ]
  • show platform packet-trace {configuration | statistics | summary | packet {all | pkt-num }}

Cisco IOS XE 3.11S

In Cisco IOS XE Release 3.11S, this feature was enhanced to include the following features:

  • Matched versus traced statistics.
  • Trace stop timestamp in addition to trace start timestamp.

The following commands were introduced or modified:

  • debug platform packet-trace drop [code drop-num ]
  • show platform packet-trace packet {all | pkt-num } [decode ]

Cisco IOS XE Denali 16.3.1

In Cisco IOS XE Denali 16.3.1, this feature was enhanced to include Layer3 packet tracing along with IOSd.

The following commands were introduced or modified: debug platform packet-trace punt .

Cisco IOS XE Amsterdam 17.3.1

The output of the show platform packet-trace command now includes additional trace information for packets either originated from IOSd or destined to IOSd or other BinOS processes.