2019-12-03 22:31:14 +03:00
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.. SPDX-License-Identifier: GPL-2.0
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=======================================
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The padata parallel execution mechanism
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=======================================
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2020-06-04 01:59:59 +03:00
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:Date: May 2020
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2019-12-03 22:31:14 +03:00
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Padata is a mechanism by which the kernel can farm jobs out to be done in
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2020-06-04 01:59:59 +03:00
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parallel on multiple CPUs while optionally retaining their ordering.
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2019-12-03 22:31:14 +03:00
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2020-06-04 01:59:59 +03:00
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It was originally developed for IPsec, which needs to perform encryption and
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decryption on large numbers of packets without reordering those packets. This
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is currently the sole consumer of padata's serialized job support.
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Padata also supports multithreaded jobs, splitting up the job evenly while load
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balancing and coordinating between threads.
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Running Serialized Jobs
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=======================
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2019-12-03 22:31:14 +03:00
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Initializing
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------------
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2020-06-04 01:59:59 +03:00
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The first step in using padata to run serialized jobs is to set up a
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padata_instance structure for overall control of how jobs are to be run::
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#include <linux/padata.h>
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2020-07-14 23:13:55 +03:00
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struct padata_instance *padata_alloc(const char *name);
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2019-12-03 22:31:14 +03:00
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'name' simply identifies the instance.
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2020-07-14 23:13:52 +03:00
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Then, complete padata initialization by allocating a padata_shell::
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struct padata_shell *padata_alloc_shell(struct padata_instance *pinst);
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A padata_shell is used to submit a job to padata and allows a series of such
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jobs to be serialized independently. A padata_instance may have one or more
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padata_shells associated with it, each allowing a separate series of jobs.
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Modifying cpumasks
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------------------
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The CPUs used to run jobs can be changed in two ways, programatically with
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padata_set_cpumask() or via sysfs. The former is defined::
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int padata_set_cpumask(struct padata_instance *pinst, int cpumask_type,
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cpumask_var_t cpumask);
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Here cpumask_type is one of PADATA_CPU_PARALLEL or PADATA_CPU_SERIAL, where a
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parallel cpumask describes which processors will be used to execute jobs
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submitted to this instance in parallel and a serial cpumask defines which
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processors are allowed to be used as the serialization callback processor.
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cpumask specifies the new cpumask to use.
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There may be sysfs files for an instance's cpumasks. For example, pcrypt's
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live in /sys/kernel/pcrypt/<instance-name>. Within an instance's directory
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there are two files, parallel_cpumask and serial_cpumask, and either cpumask
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may be changed by echoing a bitmask into the file, for example::
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echo f > /sys/kernel/pcrypt/pencrypt/parallel_cpumask
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Reading one of these files shows the user-supplied cpumask, which may be
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different from the 'usable' cpumask.
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Padata maintains two pairs of cpumasks internally, the user-supplied cpumasks
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and the 'usable' cpumasks. (Each pair consists of a parallel and a serial
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cpumask.) The user-supplied cpumasks default to all possible CPUs on instance
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allocation and may be changed as above. The usable cpumasks are always a
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subset of the user-supplied cpumasks and contain only the online CPUs in the
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user-supplied masks; these are the cpumasks padata actually uses. So it is
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legal to supply a cpumask to padata that contains offline CPUs. Once an
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offline CPU in the user-supplied cpumask comes online, padata is going to use
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it.
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Changing the CPU masks are expensive operations, so it should not be done with
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great frequency.
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Running A Job
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-------------
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Actually submitting work to the padata instance requires the creation of a
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padata_priv structure, which represents one job::
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struct padata_priv {
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/* Other stuff here... */
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void (*parallel)(struct padata_priv *padata);
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void (*serial)(struct padata_priv *padata);
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};
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This structure will almost certainly be embedded within some larger
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structure specific to the work to be done. Most of its fields are private to
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padata, but the structure should be zeroed at initialisation time, and the
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parallel() and serial() functions should be provided. Those functions will
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be called in the process of getting the work done as we will see
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momentarily.
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The submission of the job is done with::
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int padata_do_parallel(struct padata_shell *ps,
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struct padata_priv *padata, int *cb_cpu);
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The ps and padata structures must be set up as described above; cb_cpu
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points to the preferred CPU to be used for the final callback when the job is
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done; it must be in the current instance's CPU mask (if not the cb_cpu pointer
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is updated to point to the CPU actually chosen). The return value from
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padata_do_parallel() is zero on success, indicating that the job is in
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progress. -EBUSY means that somebody, somewhere else is messing with the
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instance's CPU mask, while -EINVAL is a complaint about cb_cpu not being in the
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serial cpumask, no online CPUs in the parallel or serial cpumasks, or a stopped
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instance.
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Each job submitted to padata_do_parallel() will, in turn, be passed to
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exactly one call to the above-mentioned parallel() function, on one CPU, so
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true parallelism is achieved by submitting multiple jobs. parallel() runs with
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software interrupts disabled and thus cannot sleep. The parallel()
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function gets the padata_priv structure pointer as its lone parameter;
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information about the actual work to be done is probably obtained by using
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container_of() to find the enclosing structure.
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Note that parallel() has no return value; the padata subsystem assumes that
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parallel() will take responsibility for the job from this point. The job
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need not be completed during this call, but, if parallel() leaves work
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outstanding, it should be prepared to be called again with a new job before
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the previous one completes.
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Serializing Jobs
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----------------
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When a job does complete, parallel() (or whatever function actually finishes
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the work) should inform padata of the fact with a call to::
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void padata_do_serial(struct padata_priv *padata);
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At some point in the future, padata_do_serial() will trigger a call to the
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serial() function in the padata_priv structure. That call will happen on
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the CPU requested in the initial call to padata_do_parallel(); it, too, is
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run with local software interrupts disabled.
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Note that this call may be deferred for a while since the padata code takes
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pains to ensure that jobs are completed in the order in which they were
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submitted.
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Destroying
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----------
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2020-07-14 23:13:52 +03:00
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Cleaning up a padata instance predictably involves calling the two free
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functions that correspond to the allocation in reverse::
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void padata_free_shell(struct padata_shell *ps);
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void padata_free(struct padata_instance *pinst);
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It is the user's responsibility to ensure all outstanding jobs are complete
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before any of the above are called.
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2020-06-04 01:59:59 +03:00
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Running Multithreaded Jobs
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==========================
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A multithreaded job has a main thread and zero or more helper threads, with the
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main thread participating in the job and then waiting until all helpers have
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finished. padata splits the job into units called chunks, where a chunk is a
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piece of the job that one thread completes in one call to the thread function.
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A user has to do three things to run a multithreaded job. First, describe the
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job by defining a padata_mt_job structure, which is explained in the Interface
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section. This includes a pointer to the thread function, which padata will
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call each time it assigns a job chunk to a thread. Then, define the thread
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function, which accepts three arguments, ``start``, ``end``, and ``arg``, where
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the first two delimit the range that the thread operates on and the last is a
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pointer to the job's shared state, if any. Prepare the shared state, which is
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typically allocated on the main thread's stack. Last, call
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padata_do_multithreaded(), which will return once the job is finished.
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2019-12-03 22:31:14 +03:00
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Interface
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=========
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.. kernel-doc:: include/linux/padata.h
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.. kernel-doc:: kernel/padata.c
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