1.. BSD LICENSE 2 Copyright(c) 2010-2014 Intel Corporation. All rights reserved. 3 All rights reserved. 4 5 Redistribution and use in source and binary forms, with or without 6 modification, are permitted provided that the following conditions 7 are met: 8 9 * Redistributions of source code must retain the above copyright 10 notice, this list of conditions and the following disclaimer. 11 * Redistributions in binary form must reproduce the above copyright 12 notice, this list of conditions and the following disclaimer in 13 the documentation and/or other materials provided with the 14 distribution. 15 * Neither the name of Intel Corporation nor the names of its 16 contributors may be used to endorse or promote products derived 17 from this software without specific prior written permission. 18 19 THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 20 "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 21 LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 22 A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 23 OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 24 SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 25 LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 26 DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 27 THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 28 (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 29 OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 30 31Test Pipeline Application 32========================= 33 34The Test Pipeline application illustrates the use of the DPDK Packet Framework tool suite. 35Its purpose is to demonstrate the performance of single-table DPDK pipelines. 36 37Overview 38-------- 39 40The application uses three CPU cores: 41 42* Core A ("RX core") receives traffic from the NIC ports and feeds core B with traffic through SW queues. 43 44* Core B ("Pipeline core") implements a single-table DPDK pipeline 45 whose type is selectable through specific command line parameter. 46 Core B receives traffic from core A through software queues, 47 processes it according to the actions configured in the table entries that 48 are hit by the input packets and feeds it to core C through another set of software queues. 49 50* Core C ("TX core") receives traffic from core B through software queues and sends it to the NIC ports for transmission. 51 52.. _figure_test_pipeline_app: 53 54.. figure:: img/test_pipeline_app.* 55 56 Test Pipeline Application 57 58 59Compiling the Application 60------------------------- 61 62#. Go to the app/test directory: 63 64 .. code-block:: console 65 66 export RTE_SDK=/path/to/rte_sdk 67 cd ${RTE_SDK}/app/test/test-pipeline 68 69#. Set the target (a default target is used if not specified): 70 71 .. code-block:: console 72 73 export RTE_TARGET=x86_64-native-linuxapp-gcc 74 75#. Build the application: 76 77 .. code-block:: console 78 79 make 80 81Running the Application 82----------------------- 83 84Application Command Line 85~~~~~~~~~~~~~~~~~~~~~~~~ 86 87The application execution command line is: 88 89.. code-block:: console 90 91 ./test-pipeline [EAL options] -- -p PORTMASK --TABLE_TYPE 92 93The -c or -l EAL CPU coremask/corelist option has to contain exactly 3 CPU cores. 94The first CPU core in the core mask is assigned for core A, the second for core B and the third for core C. 95 96The PORTMASK parameter must contain 2 or 4 ports. 97 98Table Types and Behavior 99~~~~~~~~~~~~~~~~~~~~~~~~ 100 101:numref:`table_test_pipeline_1` describes the table types used and how they are populated. 102 103The hash tables are pre-populated with 16 million keys. 104For hash tables, the following parameters can be selected: 105 106* **Configurable key size implementation or fixed (specialized) key size implementation (e.g. hash-8-ext or hash-spec-8-ext).** 107 The key size specialized implementations are expected to provide better performance for 8-byte and 16-byte key sizes, 108 while the key-size-non-specialized implementation is expected to provide better performance for larger key sizes; 109 110* **Key size (e.g. hash-spec-8-ext or hash-spec-16-ext).** 111 The available options are 8, 16 and 32 bytes; 112 113* **Table type (e.g. hash-spec-16-ext or hash-spec-16-lru).** 114 The available options are ext (extendable bucket) or lru (least recently used). 115 116.. _table_test_pipeline_1: 117 118.. table:: Table Types 119 120 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 121 | **#** | **TABLE_TYPE** | **Description of Core B Table** | **Pre-added Table Entries** | 122 | | | | | 123 +=======+========================+==========================================================+=======================================================+ 124 | 1 | none | Core B is not implementing a DPDK pipeline. | N/A | 125 | | | Core B is implementing a pass-through from its input set | | 126 | | | of software queues to its output set of software queues. | | 127 | | | | | 128 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 129 | 2 | stub | Stub table. Core B is implementing the same pass-through | N/A | 130 | | | functionality as described for the "none" option by | | 131 | | | using the DPDK Packet Framework by using one | | 132 | | | stub table for each input NIC port. | | 133 | | | | | 134 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 135 | 3 | hash-[spec]-8-lru | LRU hash table with 8-byte key size and 16 million | 16 million entries are successfully added to the | 136 | | | entries. | hash table with the following key format: | 137 | | | | | 138 | | | | [4-byte index, 4 bytes of 0] | 139 | | | | | 140 | | | | The action configured for all table entries is | 141 | | | | "Sendto output port", with the output port index | 142 | | | | uniformly distributed for the range of output ports. | 143 | | | | | 144 | | | | The default table rule (used in the case of a lookup | 145 | | | | miss) is to drop the packet. | 146 | | | | | 147 | | | | At run time, core A is creating the following lookup | 148 | | | | key and storing it into the packet meta data for | 149 | | | | core B to use for table lookup: | 150 | | | | | 151 | | | | [destination IPv4 address, 4 bytes of 0] | 152 | | | | | 153 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 154 | 4 | hash-[spec]-8-ext | Extendable bucket hash table with 8-byte key size | Same as hash-[spec]-8-lru table entries, above. | 155 | | | and 16 million entries. | | 156 | | | | | 157 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 158 | 5 | hash-[spec]-16-lru | LRU hash table with 16-byte key size and 16 million | 16 million entries are successfully added to the hash | 159 | | | entries. | table with the following key format: | 160 | | | | | 161 | | | | [4-byte index, 12 bytes of 0] | 162 | | | | | 163 | | | | The action configured for all table entries is | 164 | | | | "Send to output port", with the output port index | 165 | | | | uniformly distributed for the range of output ports. | 166 | | | | | 167 | | | | The default table rule (used in the case of a lookup | 168 | | | | miss) is to drop the packet. | 169 | | | | | 170 | | | | At run time, core A is creating the following lookup | 171 | | | | key and storing it into the packet meta data for core | 172 | | | | B to use for table lookup: | 173 | | | | | 174 | | | | [destination IPv4 address, 12 bytes of 0] | 175 | | | | | 176 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 177 | 6 | hash-[spec]-16-ext | Extendable bucket hash table with 16-byte key size | Same as hash-[spec]-16-lru table entries, above. | 178 | | | and 16 million entries. | | 179 | | | | | 180 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 181 | 7 | hash-[spec]-32-lru | LRU hash table with 32-byte key size and 16 million | 16 million entries are successfully added to the hash | 182 | | | entries. | table with the following key format: | 183 | | | | | 184 | | | | [4-byte index, 28 bytes of 0]. | 185 | | | | | 186 | | | | The action configured for all table entries is | 187 | | | | "Send to output port", with the output port index | 188 | | | | uniformly distributed for the range of output ports. | 189 | | | | | 190 | | | | The default table rule (used in the case of a lookup | 191 | | | | miss) is to drop the packet. | 192 | | | | | 193 | | | | At run time, core A is creating the following lookup | 194 | | | | key and storing it into the packet meta data for | 195 | | | | Lpmcore B to use for table lookup: | 196 | | | | | 197 | | | | [destination IPv4 address, 28 bytes of 0] | 198 | | | | | 199 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 200 | 8 | hash-[spec]-32-ext | Extendable bucket hash table with 32-byte key size | Same as hash-[spec]-32-lru table entries, above. | 201 | | | and 16 million entries. | | 202 | | | | | 203 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 204 | 9 | lpm | Longest Prefix Match (LPM) IPv4 table. | In the case of two ports, two routes | 205 | | | | are added to the table: | 206 | | | | | 207 | | | | [0.0.0.0/9 => send to output port 0] | 208 | | | | | 209 | | | | [0.128.0.0/9 => send to output port 1] | 210 | | | | | 211 | | | | In case of four ports, four entries are added to the | 212 | | | | table: | 213 | | | | | 214 | | | | [0.0.0.0/10 => send to output port 0] | 215 | | | | | 216 | | | | [0.64.0.0/10 => send to output port 1] | 217 | | | | | 218 | | | | [0.128.0.0/10 => send to output port 2] | 219 | | | | | 220 | | | | [0.192.0.0/10 => send to output port 3] | 221 | | | | | 222 | | | | The default table rule (used in the case of a lookup | 223 | | | | miss) is to drop the packet. | 224 | | | | | 225 | | | | At run time, core A is storing the IPv4 destination | 226 | | | | within the packet meta data to be later used by core | 227 | | | | B as the lookup key. | 228 | | | | | 229 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 230 | 10 | acl | Access Control List (ACL) table | In the case of two ports, two ACL rules are added to | 231 | | | | the table: | 232 | | | | | 233 | | | | [priority = 0 (highest), | 234 | | | | | 235 | | | | IPv4 source = ANY, | 236 | | | | | 237 | | | | IPv4 destination = 0.0.0.0/9, | 238 | | | | | 239 | | | | L4 protocol = ANY, | 240 | | | | | 241 | | | | TCP source port = ANY, | 242 | | | | | 243 | | | | TCP destination port = ANY | 244 | | | | | 245 | | | | => send to output port 0] | 246 | | | | | 247 | | | | | 248 | | | | [priority = 0 (highest), | 249 | | | | | 250 | | | | IPv4 source = ANY, | 251 | | | | | 252 | | | | IPv4 destination = 0.128.0.0/9, | 253 | | | | | 254 | | | | L4 protocol = ANY, | 255 | | | | | 256 | | | | TCP source port = ANY, | 257 | | | | | 258 | | | | TCP destination port = ANY | 259 | | | | | 260 | | | | => send to output port 0]. | 261 | | | | | 262 | | | | | 263 | | | | The default table rule (used in the case of a lookup | 264 | | | | miss) is to drop the packet. | 265 | | | | | 266 +-------+------------------------+----------------------------------------------------------+-------------------------------------------------------+ 267 268Input Traffic 269~~~~~~~~~~~~~ 270 271Regardless of the table type used for the core B pipeline, 272the same input traffic can be used to hit all table entries with uniform distribution, 273which results in uniform distribution of packets sent out on the set of output NIC ports. 274The profile for input traffic is TCP/IPv4 packets with: 275 276* destination IP address as A.B.C.D with A fixed to 0 and B, C,D random 277 278* source IP address fixed to 0.0.0.0 279 280* destination TCP port fixed to 0 281 282* source TCP port fixed to 0 283