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authorThomas Gleixner <tglx@linutronix.de>2020-03-21 12:25:57 +0100
committerPeter Zijlstra <peterz@infradead.org>2020-03-21 16:00:23 +0100
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parente21fee5368f46e211bc1f3cf118f2b122d644132 (diff)
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Documentation: Add lock ordering and nesting documentation
The kernel provides a variety of locking primitives. The nesting of these lock types and the implications of them on RT enabled kernels is nowhere documented. Add initial documentation. Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Signed-off-by: Peter Zijlstra (Intel) <peterz@infradead.org> Link: https://lkml.kernel.org/r/20200321113242.026561244@linutronix.de
Diffstat (limited to 'Documentation/locking')
-rw-r--r--Documentation/locking/index.rst1
-rw-r--r--Documentation/locking/locktypes.rst299
2 files changed, 300 insertions, 0 deletions
diff --git a/Documentation/locking/index.rst b/Documentation/locking/index.rst
index 626a463f7e42..5d6800a723dc 100644
--- a/Documentation/locking/index.rst
+++ b/Documentation/locking/index.rst
@@ -7,6 +7,7 @@ locking
.. toctree::
:maxdepth: 1
+ locktypes
lockdep-design
lockstat
locktorture
diff --git a/Documentation/locking/locktypes.rst b/Documentation/locking/locktypes.rst
new file mode 100644
index 000000000000..f0aa91142e94
--- /dev/null
+++ b/Documentation/locking/locktypes.rst
@@ -0,0 +1,299 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+.. _kernel_hacking_locktypes:
+
+==========================
+Lock types and their rules
+==========================
+
+Introduction
+============
+
+The kernel provides a variety of locking primitives which can be divided
+into two categories:
+
+ - Sleeping locks
+ - Spinning locks
+
+This document conceptually describes these lock types and provides rules
+for their nesting, including the rules for use under PREEMPT_RT.
+
+
+Lock categories
+===============
+
+Sleeping locks
+--------------
+
+Sleeping locks can only be acquired in preemptible task context.
+
+Although implementations allow try_lock() from other contexts, it is
+necessary to carefully evaluate the safety of unlock() as well as of
+try_lock(). Furthermore, it is also necessary to evaluate the debugging
+versions of these primitives. In short, don't acquire sleeping locks from
+other contexts unless there is no other option.
+
+Sleeping lock types:
+
+ - mutex
+ - rt_mutex
+ - semaphore
+ - rw_semaphore
+ - ww_mutex
+ - percpu_rw_semaphore
+
+On PREEMPT_RT kernels, these lock types are converted to sleeping locks:
+
+ - spinlock_t
+ - rwlock_t
+
+Spinning locks
+--------------
+
+ - raw_spinlock_t
+ - bit spinlocks
+
+On non-PREEMPT_RT kernels, these lock types are also spinning locks:
+
+ - spinlock_t
+ - rwlock_t
+
+Spinning locks implicitly disable preemption and the lock / unlock functions
+can have suffixes which apply further protections:
+
+ =================== ====================================================
+ _bh() Disable / enable bottom halves (soft interrupts)
+ _irq() Disable / enable interrupts
+ _irqsave/restore() Save and disable / restore interrupt disabled state
+ =================== ====================================================
+
+
+rtmutex
+=======
+
+RT-mutexes are mutexes with support for priority inheritance (PI).
+
+PI has limitations on non PREEMPT_RT enabled kernels due to preemption and
+interrupt disabled sections.
+
+PI clearly cannot preempt preemption-disabled or interrupt-disabled
+regions of code, even on PREEMPT_RT kernels. Instead, PREEMPT_RT kernels
+execute most such regions of code in preemptible task context, especially
+interrupt handlers and soft interrupts. This conversion allows spinlock_t
+and rwlock_t to be implemented via RT-mutexes.
+
+
+raw_spinlock_t and spinlock_t
+=============================
+
+raw_spinlock_t
+--------------
+
+raw_spinlock_t is a strict spinning lock implementation regardless of the
+kernel configuration including PREEMPT_RT enabled kernels.
+
+raw_spinlock_t is a strict spinning lock implementation in all kernels,
+including PREEMPT_RT kernels. Use raw_spinlock_t only in real critical
+core code, low level interrupt handling and places where disabling
+preemption or interrupts is required, for example, to safely access
+hardware state. raw_spinlock_t can sometimes also be used when the
+critical section is tiny, thus avoiding RT-mutex overhead.
+
+spinlock_t
+----------
+
+The semantics of spinlock_t change with the state of CONFIG_PREEMPT_RT.
+
+On a non PREEMPT_RT enabled kernel spinlock_t is mapped to raw_spinlock_t
+and has exactly the same semantics.
+
+spinlock_t and PREEMPT_RT
+-------------------------
+
+On a PREEMPT_RT enabled kernel spinlock_t is mapped to a separate
+implementation based on rt_mutex which changes the semantics:
+
+ - Preemption is not disabled
+
+ - The hard interrupt related suffixes for spin_lock / spin_unlock
+ operations (_irq, _irqsave / _irqrestore) do not affect the CPUs
+ interrupt disabled state
+
+ - The soft interrupt related suffix (_bh()) still disables softirq
+ handlers.
+
+ Non-PREEMPT_RT kernels disable preemption to get this effect.
+
+ PREEMPT_RT kernels use a per-CPU lock for serialization which keeps
+ preemption disabled. The lock disables softirq handlers and also
+ prevents reentrancy due to task preemption.
+
+PREEMPT_RT kernels preserve all other spinlock_t semantics:
+
+ - Tasks holding a spinlock_t do not migrate. Non-PREEMPT_RT kernels
+ avoid migration by disabling preemption. PREEMPT_RT kernels instead
+ disable migration, which ensures that pointers to per-CPU variables
+ remain valid even if the task is preempted.
+
+ - Task state is preserved across spinlock acquisition, ensuring that the
+ task-state rules apply to all kernel configurations. Non-PREEMPT_RT
+ kernels leave task state untouched. However, PREEMPT_RT must change
+ task state if the task blocks during acquisition. Therefore, it saves
+ the current task state before blocking and the corresponding lock wakeup
+ restores it.
+
+ Other types of wakeups would normally unconditionally set the task state
+ to RUNNING, but that does not work here because the task must remain
+ blocked until the lock becomes available. Therefore, when a non-lock
+ wakeup attempts to awaken a task blocked waiting for a spinlock, it
+ instead sets the saved state to RUNNING. Then, when the lock
+ acquisition completes, the lock wakeup sets the task state to the saved
+ state, in this case setting it to RUNNING.
+
+rwlock_t
+========
+
+rwlock_t is a multiple readers and single writer lock mechanism.
+
+Non-PREEMPT_RT kernels implement rwlock_t as a spinning lock and the
+suffix rules of spinlock_t apply accordingly. The implementation is fair,
+thus preventing writer starvation.
+
+rwlock_t and PREEMPT_RT
+-----------------------
+
+PREEMPT_RT kernels map rwlock_t to a separate rt_mutex-based
+implementation, thus changing semantics:
+
+ - All the spinlock_t changes also apply to rwlock_t.
+
+ - Because an rwlock_t writer cannot grant its priority to multiple
+ readers, a preempted low-priority reader will continue holding its lock,
+ thus starving even high-priority writers. In contrast, because readers
+ can grant their priority to a writer, a preempted low-priority writer
+ will have its priority boosted until it releases the lock, thus
+ preventing that writer from starving readers.
+
+
+PREEMPT_RT caveats
+==================
+
+spinlock_t and rwlock_t
+-----------------------
+
+These changes in spinlock_t and rwlock_t semantics on PREEMPT_RT kernels
+have a few implications. For example, on a non-PREEMPT_RT kernel the
+following code sequence works as expected::
+
+ local_irq_disable();
+ spin_lock(&lock);
+
+and is fully equivalent to::
+
+ spin_lock_irq(&lock);
+
+Same applies to rwlock_t and the _irqsave() suffix variants.
+
+On PREEMPT_RT kernel this code sequence breaks because RT-mutex requires a
+fully preemptible context. Instead, use spin_lock_irq() or
+spin_lock_irqsave() and their unlock counterparts. In cases where the
+interrupt disabling and locking must remain separate, PREEMPT_RT offers a
+local_lock mechanism. Acquiring the local_lock pins the task to a CPU,
+allowing things like per-CPU irq-disabled locks to be acquired. However,
+this approach should be used only where absolutely necessary.
+
+
+raw_spinlock_t
+--------------
+
+Acquiring a raw_spinlock_t disables preemption and possibly also
+interrupts, so the critical section must avoid acquiring a regular
+spinlock_t or rwlock_t, for example, the critical section must avoid
+allocating memory. Thus, on a non-PREEMPT_RT kernel the following code
+works perfectly::
+
+ raw_spin_lock(&lock);
+ p = kmalloc(sizeof(*p), GFP_ATOMIC);
+
+But this code fails on PREEMPT_RT kernels because the memory allocator is
+fully preemptible and therefore cannot be invoked from truly atomic
+contexts. However, it is perfectly fine to invoke the memory allocator
+while holding normal non-raw spinlocks because they do not disable
+preemption on PREEMPT_RT kernels::
+
+ spin_lock(&lock);
+ p = kmalloc(sizeof(*p), GFP_ATOMIC);
+
+
+bit spinlocks
+-------------
+
+Bit spinlocks are problematic for PREEMPT_RT as they cannot be easily
+substituted by an RT-mutex based implementation for obvious reasons.
+
+The semantics of bit spinlocks are preserved on PREEMPT_RT kernels and the
+caveats vs. raw_spinlock_t apply.
+
+Some bit spinlocks are substituted by regular spinlock_t for PREEMPT_RT but
+this requires conditional (#ifdef'ed) code changes at the usage site while
+the spinlock_t substitution is simply done by the compiler and the
+conditionals are restricted to header files and core implementation of the
+locking primitives and the usage sites do not require any changes.
+
+
+Lock type nesting rules
+=======================
+
+The most basic rules are:
+
+ - Lock types of the same lock category (sleeping, spinning) can nest
+ arbitrarily as long as they respect the general lock ordering rules to
+ prevent deadlocks.
+
+ - Sleeping lock types cannot nest inside spinning lock types.
+
+ - Spinning lock types can nest inside sleeping lock types.
+
+These rules apply in general independent of CONFIG_PREEMPT_RT.
+
+As PREEMPT_RT changes the lock category of spinlock_t and rwlock_t from
+spinning to sleeping this has obviously restrictions how they can nest with
+raw_spinlock_t.
+
+This results in the following nest ordering:
+
+ 1) Sleeping locks
+ 2) spinlock_t and rwlock_t
+ 3) raw_spinlock_t and bit spinlocks
+
+Lockdep is aware of these constraints to ensure that they are respected.
+
+
+Owner semantics
+===============
+
+Most lock types in the Linux kernel have strict owner semantics, i.e. the
+context (task) which acquires a lock has to release it.
+
+There are two exceptions:
+
+ - semaphores
+ - rwsems
+
+semaphores have no owner semantics for historical reason, and as such
+trylock and release operations can be called from any context. They are
+often used for both serialization and waiting purposes. That's generally
+discouraged and should be replaced by separate serialization and wait
+mechanisms, such as mutexes and completions.
+
+rwsems have grown interfaces which allow non owner release for special
+purposes. This usage is problematic on PREEMPT_RT because PREEMPT_RT
+substitutes all locking primitives except semaphores with RT-mutex based
+implementations to provide priority inheritance for all lock types except
+the truly spinning ones. Priority inheritance on ownerless locks is
+obviously impossible.
+
+For now the rwsem non-owner release excludes code which utilizes it from
+being used on PREEMPT_RT enabled kernels. In same cases this can be
+mitigated by disabling portions of the code, in other cases the complete
+functionality has to be disabled until a workable solution has been found.