The Test Pipeline application illustrates the use of the DPDK Packet Framework tool suite. Its purpose is to demonstrate the performance of single-table DPDK pipelines.
The application uses three CPU cores:
Figure 21.Test Pipeline Application
Go to the app/test directory:
export RTE_SDK=/path/to/rte_sdk
cd ${RTE_SDK}/app/test/test-pipeline
Set the target (a default target is used if not specified):
export RTE_TARGET=x86_64-native-linuxapp-gcc
Build the application:
make
The application execution command line is:
./test-pipeline [EAL options] -- -p PORTMASK --TABLE_TYPE
The -c EAL CPU core mask option has to contain exactly 3 CPU cores. The first CPU core in the core mask is assigned for core A, the second for core B and the third for core C.
The PORTMASK parameter must contain 2 or 4 ports.
Table 3 describes the table types used and how they are populated.
The hash tables are pre-populated with 16 million keys. For hash tables, the following parameters can be selected:
Table 3. Table Types
# | TABLE_TYPE | Description of Core B Table | Pre-added Table Entries |
---|---|---|---|
1 | none | Core B is not implementing a DPDK pipeline. Core B is implementing a pass-through from its input set of software queues to its output set of software queues. | N/A |
2 | stub | Stub table. Core B is implementing the same pass-through functionality as described for the “none” option by using the DPDK Packet Framework by using one stub table for each input NIC port. | N/A |
3 | hash-[spec]-8-lru | LRU hash table with 8-byte key size and 16 million entries. | 16 million entries are successfully added to the hash table with the following key format: [4-byte index, 4 bytes of 0] The action configured for all table entries is “Sendto output port”, with the output port index uniformly distributed for the range of output ports. The default table rule (used in the case of a lookup miss) is to drop the packet. At run time, core A is creating the following lookup key and storing it into the packet meta data for core B to use for table lookup: [destination IPv4 address, 4 bytes of 0] |
4 | hash-[spec]-8-ext | Extendible bucket hash table with 8-byte key size and 16 million entries. | |
5 | hash-[spec]-16-lru | LRU hash table with 16-byte key size and 16 million entries. | 16 million entries are successfully added to the hash table with the following key format: [4-byte index, 12 bytes of 0] The action configured for all table entries is “Send to output port”, with the output port index uniformly distributed for the range of output ports. The default table rule (used in the case of a lookup miss) is to drop the packet. At run time, core A is creating the following lookup key and storing it into the packet meta data for core B to use for table lookup: [destination IPv4 address, 12 bytes of 0] |
6 | hash-[spec]-ash-16-ext | Extendible bucket hash table with 16-byte key size and 16 million entries. | |
7 | hash-[spec]-32-lru | LRU hash table with 32-byte key size and 16 million entries. |
[4-byte index, 28 bytes of 0]. The action configured for all table entries is “Send to output port”, with the output port index uniformly distributed for the range of output ports. The default table rule (used in the case of a lookup miss) is to drop the packet. At run time, core A is creating the following lookup key and storing it into the packet meta data for Lpmcore B to use for table lookup: [destination IPv4 address, 28 bytes of 0] |
8 | hash-[spec]-32-ext | Extendible bucket hash table with 32-byte key size and 16 million entries. | |
9 | lpm | Longest Prefix Match (LPM) IPv4 table. | In the case of two ports, two routes are added to the table: [0.0.0.0/9 => send to output port 0] [0.128.0.0/9 => send to output port 1] In case of four ports, four entries are added to the table: [0.0.0.0/10 => send to output port 0] [0.64.0.0/10 => send to output port 1] [0.128.0.0/10 => send to output port 2] [0.192.0.0/10 => send to output port 3] The default table rule (used in the case of a lookup miss) is to drop the packet. At run time, core A is storing the IPv4 destination within the packet meta data to be later used by core B as the lookup key. |
10 | acl | Access Control List (ACL) table | In the case of two ports, two ACL rules are added to the table: [priority = 0 (highest), IPv4 source = ANY, IPv4 destination = 0.0.0.0/9, L4 protocol = ANY, TCP source port = ANY, TCP destination port = ANY => send to output port 0] [priority = 0 (highest), IPv4 source = ANY, IPv4 destination = 0.128.0.0/9, L4 protocol = ANY, TCP source port = ANY, TCP destination port = ANY => send to output port 0]. The default table rule (used in the case of a lookup miss) is to drop the packet. |
Regardless of the table type used for the core B pipeline, the same input traffic can be used to hit all table entries with uniform distribution, which results in uniform distribution of packets sent out on the set of output NIC ports. The profile for input traffic is TCP/IPv4 packets with: