Example 1: PID Filter—Table-based Unicast Session Configuration
Consider the below table-based unicast session on a input port number 1 with vei-ip 198.51.100.1
logical-edge-device led1 id 1
protocol table-based
virtual-edge-input-ip 198.51.100.1 input-port-number 1
vcg vcg1
active
table-based
vcg vcg1
rf-channel 2
session unicast input-port 1 start-udp-port 49152 processing-type passthru
The corresponding filter rule is shown below:
filter pid vcg vcg1
rf-channel 2
vei-ip 198.51.100.1 udp-port 49152
pid 120
pid 20-30
Example 2: PID Filter—Table-based ASM Multicast Session Configuration
Consider a table-based ASM multicast session replicated on rf-channel 30-40.
table-based
vcg vcg1
rf-channel 2
session asml group 198.51.100.2 processing-type passthru
You can specify PID rule for the session on each rf-channel a group of rf-channels as shown below:
filter pid vcg vcg1
rf-channel 2
asm-multicast 198.51.100.2
pid 1000
pid 1002-1020
Example 4: Program Filter—Table-based Unicast Session Configuration
Consider the below table-based unicast session on a input port number 1 with vei-ip 198.51.100.1
logical-edge-device led1 id 1
protocol table-based
virtual-edge-input-ip 198.51.100.1 input-port-number 1
vcg vcg1
active
table-based
vcg vcg1
rf-channel 2
session unicast input-port 1 start-udp-port 49152 processing-type passthru
The corresponding filter rule is shown below:
filter program vcg vcg1
rf-channel 2
vei-ip 198.51.100.1 udp-port 49152
program 10
program 20
program 30-40
Example 5: Program Filter—Table-based ASM Multicast Session Configuration
Consider a table-based ASM multicast session replicated on rf-channel 30-40.
table-based
vcg vcg1
rf-channel 2
session asml group 198.51.100.2 processing-type passthru
You can specify PID rule for the session on each rf-channel a group of rf-channels as shown below:
filter program vcg vcg1
rf-channel 2
asm-multicast 198.51.100.2
program 10-20
Example 6: Program Filter—Table-based SSM Multicast Session Configuration
Consider a SSM multicast stream as shown below:
table-based
vcg vcg1
rf-channel 2
session ssml group 198.51.100.3 source 198.51.100.6 processing-type passthru
One of the remap rules is applied depending on the source and group match as shown below:
filter program vcg vcg1
rf-channel 2
ssm-multicast 198.51.100.200 198.51.100.254
program 10-20
ssm-multicast 198.51.100.201 198.51.100.254
program 10-20
ssm-multicast 198.51.100.203 198.51.100.254
program 10-20
Example 7: PID Remap—Table-based Unicast Session Configuration
Consider the below table-based unicast session on a input port number 1 with vei-ip 198.51.100.1
table-based
vcg vcg1
rf-channel 20
session unicast input-port 1 start-udp-port 49152 processing-type passthru
The corresponding remap assuming 32 input unreferenced PIDs is shown below:
remap pid vcg vcg1
rf-channel 20
vei-ip 198.51.100.1 udp-port 49152
pid 100 200
pid 101 201
pid 102-130 202-230
pid 131 240
Example 8: PID Remap—Table-based ASM Multicast Session Configuration
Consider a table-based ASM multicast session replicated on rf-channel 30-40.
table-based
vcg vcg1
rf-channel 2
session asm_multi group 198.51.100.2 processing-type data
You can specify PID rule for the session on each rf-channel a group of rf-channels as shown below:
remap pid vcg vcg1
rf-channel 30
asm-multicast 198.51.100.2
pid 1000 8189
rf-channel 31-40
asm-multicast 198.51.100.2
pid 1000 8189
Example 9: PID Remap—Table-based SSM Multicast Session Configuration
Consider a SSM multicast stream as shown below:
table-based
vcg vcg1
rf-channel 30-40
session ssm_multi group 198.51.100.3 source 198.51.100.6 processing-type data
One of the remap rules is applied depending on the source and group match as shown below:
remap pid vcg vcg1
rf-channel 30-35
ssm-multicast 198.51.100.200 198.51.100.254
pid 1000 8190
ssm-multicast 198.51.100.201 198.51.100.254
pid 2000 8190
ssm-multicast 198.51.100.203 198.51.100.254
pid 1860 8190