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31 .. _multi_process_app:
33 Multi-process Sample Application
34 ================================
36 This chapter describes the example applications for multi-processing that are included in the DPDK.
41 Building the Sample Applications
42 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
44 The multi-process example applications are built in the same way as other sample applications,
45 and as documented in the *DPDK Getting Started Guide*.
46 To build all the example applications:
48 #. Set RTE_SDK and go to the example directory:
50 .. code-block:: console
52 export RTE_SDK=/path/to/rte_sdk
53 cd ${RTE_SDK}/examples/multi_process
55 #. Set the target (a default target will be used if not specified). For example:
57 .. code-block:: console
59 export RTE_TARGET=x86_64-native-linuxapp-gcc
61 See the *DPDK Getting Started Guide* for possible RTE_TARGET values.
63 #. Build the applications:
65 .. code-block:: console
71 If just a specific multi-process application needs to be built,
72 the final make command can be run just in that application's directory,
73 rather than at the top-level multi-process directory.
75 Basic Multi-process Example
76 ~~~~~~~~~~~~~~~~~~~~~~~~~~~
78 The examples/simple_mp folder in the DPDK release contains a basic example application to demonstrate how
79 two DPDK processes can work together using queues and memory pools to share information.
81 Running the Application
82 ^^^^^^^^^^^^^^^^^^^^^^^
84 To run the application, start one copy of the simple_mp binary in one terminal,
85 passing at least two cores in the coremask/corelist, as follows:
87 .. code-block:: console
89 ./build/simple_mp -l 0-1 -n 4 --proc-type=primary
91 For the first DPDK process run, the proc-type flag can be omitted or set to auto,
92 since all DPDK processes will default to being a primary instance,
93 meaning they have control over the hugepage shared memory regions.
94 The process should start successfully and display a command prompt as follows:
96 .. code-block:: console
98 $ ./build/simple_mp -l 0-1 -n 4 --proc-type=primary
99 EAL: coremask set to 3
100 EAL: Detected lcore 0 on socket 0
101 EAL: Detected lcore 1 on socket 0
102 EAL: Detected lcore 2 on socket 0
103 EAL: Detected lcore 3 on socket 0
106 EAL: Requesting 2 pages of size 1073741824
107 EAL: Requesting 768 pages of size 2097152
108 EAL: Ask a virtual area of 0x40000000 bytes
109 EAL: Virtual area found at 0x7ff200000000 (size = 0x40000000)
112 EAL: check igb_uio module
113 EAL: check module finished
114 EAL: Master core 0 is ready (tid=54e41820)
115 EAL: Core 1 is ready (tid=53b32700)
121 To run the secondary process to communicate with the primary process,
122 again run the same binary setting at least two cores in the coremask/corelist:
124 .. code-block:: console
126 ./build/simple_mp -l 2-3 -n 4 --proc-type=secondary
128 When running a secondary process such as that shown above, the proc-type parameter can again be specified as auto.
129 However, omitting the parameter altogether will cause the process to try and start as a primary rather than secondary process.
131 Once the process type is specified correctly,
132 the process starts up, displaying largely similar status messages to the primary instance as it initializes.
133 Once again, you will be presented with a command prompt.
135 Once both processes are running, messages can be sent between them using the send command.
136 At any stage, either process can be terminated using the quit command.
138 .. code-block:: console
140 EAL: Master core 10 is ready (tid=b5f89820) EAL: Master core 8 is ready (tid=864a3820)
141 EAL: Core 11 is ready (tid=84ffe700) EAL: Core 9 is ready (tid=85995700)
142 Starting core 11 Starting core 9
143 simple_mp > send hello_secondary simple_mp > core 9: Received 'hello_secondary'
144 simple_mp > core 11: Received 'hello_primary' simple_mp > send hello_primary
145 simple_mp > quit simple_mp > quit
149 If the primary instance is terminated, the secondary instance must also be shut-down and restarted after the primary.
150 This is necessary because the primary instance will clear and reset the shared memory regions on startup,
151 invalidating the secondary process's pointers.
152 The secondary process can be stopped and restarted without affecting the primary process.
154 How the Application Works
155 ^^^^^^^^^^^^^^^^^^^^^^^^^
157 The core of this example application is based on using two queues and a single memory pool in shared memory.
158 These three objects are created at startup by the primary process,
159 since the secondary process cannot create objects in memory as it cannot reserve memory zones,
160 and the secondary process then uses lookup functions to attach to these objects as it starts up.
164 if (rte_eal_process_type() == RTE_PROC_PRIMARY){
165 send_ring = rte_ring_create(_PRI_2_SEC, ring_size, SOCKET0, flags);
166 recv_ring = rte_ring_create(_SEC_2_PRI, ring_size, SOCKET0, flags);
167 message_pool = rte_mempool_create(_MSG_POOL, pool_size, string_size, pool_cache, priv_data_sz, NULL, NULL, NULL, NULL, SOCKET0, flags);
169 recv_ring = rte_ring_lookup(_PRI_2_SEC);
170 send_ring = rte_ring_lookup(_SEC_2_PRI);
171 message_pool = rte_mempool_lookup(_MSG_POOL);
174 Note, however, that the named ring structure used as send_ring in the primary process is the recv_ring in the secondary process.
176 Once the rings and memory pools are all available in both the primary and secondary processes,
177 the application simply dedicates two threads to sending and receiving messages respectively.
178 The receive thread simply dequeues any messages on the receive ring, prints them,
179 and frees the buffer space used by the messages back to the memory pool.
180 The send thread makes use of the command-prompt library to interactively request user input for messages to send.
181 Once a send command is issued by the user, a buffer is allocated from the memory pool, filled in with the message contents,
182 then enqueued on the appropriate rte_ring.
184 Symmetric Multi-process Example
185 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
187 The second example of DPDK multi-process support demonstrates how a set of processes can run in parallel,
188 with each process performing the same set of packet- processing operations.
189 (Since each process is identical in functionality to the others,
190 we refer to this as symmetric multi-processing, to differentiate it from asymmetric multi- processing -
191 such as a client-server mode of operation seen in the next example,
192 where different processes perform different tasks, yet co-operate to form a packet-processing system.)
193 The following diagram shows the data-flow through the application, using two processes.
195 .. _figure_sym_multi_proc_app:
197 .. figure:: img/sym_multi_proc_app.*
199 Example Data Flow in a Symmetric Multi-process Application
202 As the diagram shows, each process reads packets from each of the network ports in use.
203 RSS is used to distribute incoming packets on each port to different hardware RX queues.
204 Each process reads a different RX queue on each port and so does not contend with any other process for that queue access.
205 Similarly, each process writes outgoing packets to a different TX queue on each port.
207 Running the Application
208 ^^^^^^^^^^^^^^^^^^^^^^^
210 As with the simple_mp example, the first instance of the symmetric_mp process must be run as the primary instance,
211 though with a number of other application- specific parameters also provided after the EAL arguments.
212 These additional parameters are:
214 * -p <portmask>, where portmask is a hexadecimal bitmask of what ports on the system are to be used.
215 For example: -p 3 to use ports 0 and 1 only.
217 * --num-procs <N>, where N is the total number of symmetric_mp instances that will be run side-by-side to perform packet processing.
218 This parameter is used to configure the appropriate number of receive queues on each network port.
220 * --proc-id <n>, where n is a numeric value in the range 0 <= n < N (number of processes, specified above).
221 This identifies which symmetric_mp instance is being run, so that each process can read a unique receive queue on each network port.
223 The secondary symmetric_mp instances must also have these parameters specified,
224 and the first two must be the same as those passed to the primary instance, or errors result.
226 For example, to run a set of four symmetric_mp instances, running on lcores 1-4,
227 all performing level-2 forwarding of packets between ports 0 and 1,
228 the following commands can be used (assuming run as root):
230 .. code-block:: console
232 # ./build/symmetric_mp -l 1 -n 4 --proc-type=auto -- -p 3 --num-procs=4 --proc-id=0
233 # ./build/symmetric_mp -l 2 -n 4 --proc-type=auto -- -p 3 --num-procs=4 --proc-id=1
234 # ./build/symmetric_mp -l 3 -n 4 --proc-type=auto -- -p 3 --num-procs=4 --proc-id=2
235 # ./build/symmetric_mp -l 4 -n 4 --proc-type=auto -- -p 3 --num-procs=4 --proc-id=3
239 In the above example, the process type can be explicitly specified as primary or secondary, rather than auto.
240 When using auto, the first process run creates all the memory structures needed for all processes -
241 irrespective of whether it has a proc-id of 0, 1, 2 or 3.
245 For the symmetric multi-process example, since all processes work in the same manner,
246 once the hugepage shared memory and the network ports are initialized,
247 it is not necessary to restart all processes if the primary instance dies.
248 Instead, that process can be restarted as a secondary,
249 by explicitly setting the proc-type to secondary on the command line.
250 (All subsequent instances launched will also need this explicitly specified,
251 as auto-detection will detect no primary processes running and therefore attempt to re-initialize shared memory.)
253 How the Application Works
254 ^^^^^^^^^^^^^^^^^^^^^^^^^
256 The initialization calls in both the primary and secondary instances are the same for the most part,
257 calling the rte_eal_init(), 1 G and 10 G driver initialization and then rte_pci_probe() functions.
258 Thereafter, the initialization done depends on whether the process is configured as a primary or secondary instance.
260 In the primary instance, a memory pool is created for the packet mbufs and the network ports to be used are initialized -
261 the number of RX and TX queues per port being determined by the num-procs parameter passed on the command-line.
262 The structures for the initialized network ports are stored in shared memory and
263 therefore will be accessible by the secondary process as it initializes.
268 rte_exit(EXIT_FAILURE, "Application must use an even number of ports\n");
270 for(i = 0; i < num_ports; i++){
271 if(proc_type == RTE_PROC_PRIMARY)
272 if (smp_port_init(ports[i], mp, (uint16_t)num_procs) < 0)
273 rte_exit(EXIT_FAILURE, "Error initializing ports\n");
276 In the secondary instance, rather than initializing the network ports, the port information exported by the primary process is used,
277 giving the secondary process access to the hardware and software rings for each network port.
278 Similarly, the memory pool of mbufs is accessed by doing a lookup for it by name:
282 mp = (proc_type == RTE_PROC_SECONDARY) ? rte_mempool_lookup(_SMP_MBUF_POOL) : rte_mempool_create(_SMP_MBUF_POOL, NB_MBUFS, MBUF_SIZE, ... )
284 Once this initialization is complete, the main loop of each process, both primary and secondary,
285 is exactly the same - each process reads from each port using the queue corresponding to its proc-id parameter,
286 and writes to the corresponding transmit queue on the output port.
288 Client-Server Multi-process Example
289 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
291 The third example multi-process application included with the DPDK shows how one can
292 use a client-server type multi-process design to do packet processing.
293 In this example, a single server process performs the packet reception from the ports being used and
294 distributes these packets using round-robin ordering among a set of client processes,
295 which perform the actual packet processing.
296 In this case, the client applications just perform level-2 forwarding of packets by sending each packet out on a different network port.
298 The following diagram shows the data-flow through the application, using two client processes.
300 .. _figure_client_svr_sym_multi_proc_app:
302 .. figure:: img/client_svr_sym_multi_proc_app.*
304 Example Data Flow in a Client-Server Symmetric Multi-process Application
307 Running the Application
308 ^^^^^^^^^^^^^^^^^^^^^^^
310 The server process must be run initially as the primary process to set up all memory structures for use by the clients.
311 In addition to the EAL parameters, the application- specific parameters are:
313 * -p <portmask >, where portmask is a hexadecimal bitmask of what ports on the system are to be used.
314 For example: -p 3 to use ports 0 and 1 only.
316 * -n <num-clients>, where the num-clients parameter is the number of client processes that will process the packets received
317 by the server application.
321 In the server process, a single thread, the master thread, that is, the lowest numbered lcore in the coremask/corelist, performs all packet I/O.
322 If a coremask/corelist is specified with more than a single lcore bit set in it,
323 an additional lcore will be used for a thread to periodically print packet count statistics.
325 Since the server application stores configuration data in shared memory, including the network ports to be used,
326 the only application parameter needed by a client process is its client instance ID.
327 Therefore, to run a server application on lcore 1 (with lcore 2 printing statistics) along with two client processes running on lcores 3 and 4,
328 the following commands could be used:
330 .. code-block:: console
332 # ./mp_server/build/mp_server -l 1-2 -n 4 -- -p 3 -n 2
333 # ./mp_client/build/mp_client -l 3 -n 4 --proc-type=auto -- -n 0
334 # ./mp_client/build/mp_client -l 4 -n 4 --proc-type=auto -- -n 1
338 If the server application dies and needs to be restarted, all client applications also need to be restarted,
339 as there is no support in the server application for it to run as a secondary process.
340 Any client processes that need restarting can be restarted without affecting the server process.
342 How the Application Works
343 ^^^^^^^^^^^^^^^^^^^^^^^^^
345 The server process performs the network port and data structure initialization much as the symmetric multi-process application does when run as primary.
346 One additional enhancement in this sample application is that the server process stores its port configuration data in a memory zone in hugepage shared memory.
347 This eliminates the need for the client processes to have the portmask parameter passed into them on the command line,
348 as is done for the symmetric multi-process application, and therefore eliminates mismatched parameters as a potential source of errors.
350 In the same way that the server process is designed to be run as a primary process instance only,
351 the client processes are designed to be run as secondary instances only.
352 They have no code to attempt to create shared memory objects.
353 Instead, handles to all needed rings and memory pools are obtained via calls to rte_ring_lookup() and rte_mempool_lookup().
354 The network ports for use by the processes are obtained by loading the network port drivers and probing the PCI bus,
355 which will, as in the symmetric multi-process example,
356 automatically get access to the network ports using the settings already configured by the primary/server process.
358 Once all applications are initialized, the server operates by reading packets from each network port in turn and
359 distributing those packets to the client queues (software rings, one for each client process) in round-robin order.
360 On the client side, the packets are read from the rings in as big of bursts as possible, then routed out to a different network port.
361 The routing used is very simple. All packets received on the first NIC port are transmitted back out on the second port and vice versa.
362 Similarly, packets are routed between the 3rd and 4th network ports and so on.
363 The sending of packets is done by writing the packets directly to the network ports; they are not transferred back via the server process.
365 In both the server and the client processes, outgoing packets are buffered before being sent,
366 so as to allow the sending of multiple packets in a single burst to improve efficiency.
367 For example, the client process will buffer packets to send,
368 until either the buffer is full or until we receive no further packets from the server.
370 Master-slave Multi-process Example
371 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
373 The fourth example of DPDK multi-process support demonstrates a master-slave model that
374 provide the capability of application recovery if a slave process crashes or meets unexpected conditions.
375 In addition, it also demonstrates the floating process,
376 which can run among different cores in contrast to the traditional way of binding a process/thread to a specific CPU core,
377 using the local cache mechanism of mempool structures.
379 This application performs the same functionality as the L2 Forwarding sample application,
380 therefore this chapter does not cover that part but describes functionality that is introduced in this multi-process example only.
381 Please refer to :doc:`l2_forward_real_virtual` for more information.
383 Unlike previous examples where all processes are started from the command line with input arguments, in this example,
384 only one process is spawned from the command line and that process creates other processes.
385 The following section describes this in more detail.
387 Master-slave Process Models
388 ^^^^^^^^^^^^^^^^^^^^^^^^^^^
390 The process spawned from the command line is called the *master process* in this document.
391 A process created by the master is called a *slave process*.
392 The application has only one master process, but could have multiple slave processes.
394 Once the master process begins to run, it tries to initialize all the resources such as
395 memory, CPU cores, driver, ports, and so on, as the other examples do.
396 Thereafter, it creates slave processes, as shown in the following figure.
398 .. _figure_master_slave_proc:
400 .. figure:: img/master_slave_proc.*
402 Master-slave Process Workflow
405 The master process calls the rte_eal_mp_remote_launch() EAL function to launch an application function for each pinned thread through the pipe.
406 Then, it waits to check if any slave processes have exited.
407 If so, the process tries to re-initialize the resources that belong to that slave and launch them in the pinned thread entry again.
408 The following section describes the recovery procedures in more detail.
410 For each pinned thread in EAL, after reading any data from the pipe, it tries to call the function that the application specified.
411 In this master specified function, a fork() call creates a slave process that performs the L2 forwarding task.
412 Then, the function waits until the slave exits, is killed or crashes. Thereafter, it notifies the master of this event and returns.
413 Finally, the EAL pinned thread waits until the new function is launched.
415 After discussing the master-slave model, it is necessary to mention another issue, global and static variables.
417 For multiple-thread cases, all global and static variables have only one copy and they can be accessed by any thread if applicable.
418 So, they can be used to sync or share data among threads.
420 In the previous examples, each process has separate global and static variables in memory and are independent of each other.
421 If it is necessary to share the knowledge, some communication mechanism should be deployed, such as, memzone, ring, shared memory, and so on.
422 The global or static variables are not a valid approach to share data among processes.
423 For variables in this example, on the one hand, the slave process inherits all the knowledge of these variables after being created by the master.
424 On the other hand, other processes cannot know if one or more processes modifies them after slave creation since that
425 is the nature of a multiple process address space.
426 But this does not mean that these variables cannot be used to share or sync data; it depends on the use case.
427 The following are the possible use cases:
429 #. The master process starts and initializes a variable and it will never be changed after slave processes created. This case is OK.
431 #. After the slave processes are created, the master or slave cores need to change a variable, but other processes do not need to know the change.
432 This case is also OK.
434 #. After the slave processes are created, the master or a slave needs to change a variable.
435 In the meantime, one or more other process needs to be aware of the change.
436 In this case, global and static variables cannot be used to share knowledge. Another communication mechanism is needed.
437 A simple approach without lock protection can be a heap buffer allocated by rte_malloc or mem zone.
439 Slave Process Recovery Mechanism
440 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
442 Before talking about the recovery mechanism, it is necessary to know what is needed before a new slave instance can run if a previous one exited.
444 When a slave process exits, the system returns all the resources allocated for this process automatically.
445 However, this does not include the resources that were allocated by the DPDK. All the hardware resources are shared among the processes,
446 which include memzone, mempool, ring, a heap buffer allocated by the rte_malloc library, and so on.
447 If the new instance runs and the allocated resource is not returned, either resource allocation failed or the hardware resource is lost forever.
449 When a slave process runs, it may have dependencies on other processes.
450 They could have execution sequence orders; they could share the ring to communicate; they could share the same port for reception and forwarding;
451 they could use lock structures to do exclusive access in some critical path.
452 What happens to the dependent process(es) if the peer leaves?
453 The consequence are varied since the dependency cases are complex.
454 It depends on what the processed had shared.
455 However, it is necessary to notify the peer(s) if one slave exited.
456 Then, the peer(s) will be aware of that and wait until the new instance begins to run.
458 Therefore, to provide the capability to resume the new slave instance if the previous one exited, it is necessary to provide several mechanisms:
460 #. Keep a resource list for each slave process.
461 Before a slave process run, the master should prepare a resource list.
462 After it exits, the master could either delete the allocated resources and create new ones,
463 or re-initialize those for use by the new instance.
465 #. Set up a notification mechanism for slave process exit cases. After the specific slave leaves,
466 the master should be notified and then help to create a new instance.
467 This mechanism is provided in Section `Master-slave Process Models`_.
469 #. Use a synchronization mechanism among dependent processes.
470 The master should have the capability to stop or kill slave processes that have a dependency on the one that has exited.
471 Then, after the new instance of exited slave process begins to run, the dependency ones could resume or run from the start.
472 The example sends a STOP command to slave processes dependent on the exited one, then they will exit.
473 Thereafter, the master creates new instances for the exited slave processes.
475 The following diagram describes slave process recovery.
477 .. _figure_slave_proc_recov:
479 .. figure:: img/slave_proc_recov.*
481 Slave Process Recovery Process Flow
484 Floating Process Support
485 ^^^^^^^^^^^^^^^^^^^^^^^^
487 When the DPDK application runs, there is always a -c option passed in to indicate the cores that are enabled.
488 Then, the DPDK creates a thread for each enabled core.
489 By doing so, it creates a 1:1 mapping between the enabled core and each thread.
490 The enabled core always has an ID, therefore, each thread has a unique core ID in the DPDK execution environment.
491 With the ID, each thread can easily access the structures or resources exclusively belonging to it without using function parameter passing.
492 It can easily use the rte_lcore_id() function to get the value in every function that is called.
494 For threads/processes not created in that way, either pinned to a core or not, they will not own a unique ID and the
495 rte_lcore_id() function will not work in the correct way.
496 However, sometimes these threads/processes still need the unique ID mechanism to do easy access on structures or resources.
497 For example, the DPDK mempool library provides a local cache mechanism
498 (refer to :ref:`mempool_local_cache`)
499 for fast element allocation and freeing.
500 If using a non-unique ID or a fake one,
501 a race condition occurs if two or more threads/ processes with the same core ID try to use the local cache.
503 Therefore, unused core IDs from the passing of parameters with the -c option are used to organize the core ID allocation array.
504 Once the floating process is spawned, it tries to allocate a unique core ID from the array and release it on exit.
506 A natural way to spawn a floating process is to use the fork() function and allocate a unique core ID from the unused core ID array.
507 However, it is necessary to write new code to provide a notification mechanism for slave exit
508 and make sure the process recovery mechanism can work with it.
510 To avoid producing redundant code, the Master-Slave process model is still used to spawn floating processes,
511 then cancel the affinity to specific cores.
512 Besides that, clear the core ID assigned to the DPDK spawning a thread that has a 1:1 mapping with the core mask.
513 Thereafter, get a new core ID from the unused core ID allocation array.
518 This example has a command line similar to the L2 Forwarding sample application with a few differences.
520 To run the application, start one copy of the l2fwd_fork binary in one terminal.
521 Unlike the L2 Forwarding example,
522 this example requires at least three cores since the master process will wait and be accountable for slave process recovery.
523 The command is as follows:
525 .. code-block:: console
527 #./build/l2fwd_fork -l 2-4 -n 4 -- -p 3 -f
529 This example provides another -f option to specify the use of floating process.
530 If not specified, the example will use a pinned process to perform the L2 forwarding task.
532 To verify the recovery mechanism, proceed as follows: First, check the PID of the slave processes:
534 .. code-block:: console
536 #ps -fe | grep l2fwd_fork
537 root 5136 4843 29 11:11 pts/1 00:00:05 ./build/l2fwd_fork
538 root 5145 5136 98 11:11 pts/1 00:00:11 ./build/l2fwd_fork
539 root 5146 5136 98 11:11 pts/1 00:00:11 ./build/l2fwd_fork
541 Then, kill one of the slaves:
543 .. code-block:: console
547 After 1 or 2 seconds, check whether the slave has resumed:
549 .. code-block:: console
551 #ps -fe | grep l2fwd_fork
552 root 5136 4843 3 11:11 pts/1 00:00:06 ./build/l2fwd_fork
553 root 5247 5136 99 11:14 pts/1 00:00:01 ./build/l2fwd_fork
554 root 5248 5136 99 11:14 pts/1 00:00:01 ./build/l2fwd_fork
556 It can also monitor the traffic generator statics to see whether slave processes have resumed.
561 As described in previous sections,
562 not all global and static variables need to change to be accessible in multiple processes;
563 it depends on how they are used.
565 the statics info on packets dropped/forwarded/received count needs to be updated by the slave process,
566 and the master needs to see the update and print them out.
567 So, it needs to allocate a heap buffer using rte_zmalloc.
568 In addition, if the -f option is specified,
569 an array is needed to store the allocated core ID for the floating process so that the master can return it
570 after a slave has exited accidentally.
575 l2fwd_malloc_shared_struct(void)
577 port_statistics = rte_zmalloc("port_stat", sizeof(struct l2fwd_port_statistics) * RTE_MAX_ETHPORTS, 0);
579 if (port_statistics == NULL)
582 /* allocate mapping_id array */
587 mapping_id = rte_malloc("mapping_id", sizeof(unsigned) * RTE_MAX_LCORE, 0);
588 if (mapping_id == NULL)
591 for (i = 0 ;i < RTE_MAX_LCORE; i++)
592 mapping_id[i] = INVALID_MAPPING_ID;
598 For each slave process, packets are received from one port and forwarded to another port that another slave is operating on.
599 If the other slave exits accidentally, the port it is operating on may not work normally,
600 so the first slave cannot forward packets to that port.
601 There is a dependency on the port in this case. So, the master should recognize the dependency.
602 The following is the code to detect this dependency:
606 for (portid = 0; portid < nb_ports; portid++) {
607 /* skip ports that are not enabled */
609 if ((l2fwd_enabled_port_mask & (1 << portid)) == 0)
612 /* Find pair ports' lcores */
614 find_lcore = find_pair_lcore = 0;
615 pair_port = l2fwd_dst_ports[portid];
617 for (i = 0; i < RTE_MAX_LCORE; i++) {
618 if (!rte_lcore_is_enabled(i))
621 for (j = 0; j < lcore_queue_conf[i].n_rx_port;j++) {
622 if (lcore_queue_conf[i].rx_port_list[j] == portid) {
628 if (lcore_queue_conf[i].rx_port_list[j] == pair_port) {
635 if (find_lcore && find_pair_lcore)
639 if (!find_lcore || !find_pair_lcore)
640 rte_exit(EXIT_FAILURE, "Not find port=%d pair\\n", portid);
642 printf("lcore %u and %u paired\\n", lcore, pair_lcore);
644 lcore_resource[lcore].pair_id = pair_lcore;
645 lcore_resource[pair_lcore].pair_id = lcore;
648 Before launching the slave process,
649 it is necessary to set up the communication channel between the master and slave so that
650 the master can notify the slave if its peer process with the dependency exited.
651 In addition, the master needs to register a callback function in the case where a specific slave exited.
655 for (i = 0; i < RTE_MAX_LCORE; i++) {
656 if (lcore_resource[i].enabled) {
657 /* Create ring for master and slave communication */
659 ret = create_ms_ring(i);
661 rte_exit(EXIT_FAILURE, "Create ring for lcore=%u failed",i);
663 if (flib_register_slave_exit_notify(i,slave_exit_cb) != 0)
664 rte_exit(EXIT_FAILURE, "Register master_trace_slave_exit failed");
668 After launching the slave process, the master waits and prints out the port statics periodically.
669 If an event indicating that a slave process exited is detected,
670 it sends the STOP command to the peer and waits until it has also exited.
671 Then, it tries to clean up the execution environment and prepare new resources.
672 Finally, the new slave instance is launched.
678 cur_tsc = rte_rdtsc();
679 diff_tsc = cur_tsc - prev_tsc;
681 /* if timer is enabled */
683 if (timer_period > 0) {
684 /* advance the timer */
685 timer_tsc += diff_tsc;
687 /* if timer has reached its timeout */
688 if (unlikely(timer_tsc >= (uint64_t) timer_period)) {
691 /* reset the timer */
698 /* Check any slave need restart or recreate */
700 rte_spinlock_lock(&res_lock);
702 for (i = 0; i < RTE_MAX_LCORE; i++) {
703 struct lcore_resource_struct *res = &lcore_resource[i];
704 struct lcore_resource_struct *pair = &lcore_resource[res->pair_id];
706 /* If find slave exited, try to reset pair */
708 if (res->enabled && res->flags && pair->enabled) {
710 master_sendcmd_with_ack(pair->lcore_id, CMD_STOP);
711 rte_spinlock_unlock(&res_lock);
713 rte_spinlock_lock(&res_lock);
718 if (reset_pair(res->lcore_id, pair->lcore_id) != 0)
719 rte_exit(EXIT_FAILURE, "failed to reset slave");
725 rte_spinlock_unlock(&res_lock);
728 When the slave process is spawned and starts to run, it checks whether the floating process option is applied.
729 If so, it clears the affinity to a specific core and also sets the unique core ID to 0.
730 Then, it tries to allocate a new core ID.
731 Since the core ID has changed, the resource allocated by the master cannot work,
732 so it remaps the resource to the new core ID slot.
737 l2fwd_launch_one_lcore( attribute ((unused)) void *dummy)
739 unsigned lcore_id = rte_lcore_id();
744 /* Change it to floating process, also change it's lcore_id */
746 clear_cpu_affinity();
748 RTE_PER_LCORE(_lcore_id) = 0;
752 if (flib_assign_lcore_id() < 0 ) {
753 printf("flib_assign_lcore_id failed\n");
757 flcore_id = rte_lcore_id();
759 /* Set mapping id, so master can return it after slave exited */
761 mapping_id[lcore_id] = flcore_id;
762 printf("Org lcore_id = %u, cur lcore_id = %u\n",lcore_id, flcore_id);
763 remapping_slave_resource(lcore_id, flcore_id);
768 /* return lcore_id before return */
770 flib_free_lcore_id(rte_lcore_id());
771 mapping_id[lcore_id] = INVALID_MAPPING_ID;