169 lines
5.8 KiB
ReStructuredText
169 lines
5.8 KiB
ReStructuredText
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===================================
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refcount_t API compared to atomic_t
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===================================
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.. contents:: :local:
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Introduction
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============
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The goal of refcount_t API is to provide a minimal API for implementing
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an object's reference counters. While a generic architecture-independent
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implementation from lib/refcount.c uses atomic operations underneath,
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there are a number of differences between some of the ``refcount_*()`` and
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``atomic_*()`` functions with regards to the memory ordering guarantees.
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This document outlines the differences and provides respective examples
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in order to help maintainers validate their code against the change in
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these memory ordering guarantees.
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The terms used through this document try to follow the formal LKMM defined in
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tools/memory-model/Documentation/explanation.txt.
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memory-barriers.txt and atomic_t.txt provide more background to the
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memory ordering in general and for atomic operations specifically.
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Relevant types of memory ordering
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=================================
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.. note:: The following section only covers some of the memory
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ordering types that are relevant for the atomics and reference
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counters and used through this document. For a much broader picture
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please consult memory-barriers.txt document.
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In the absence of any memory ordering guarantees (i.e. fully unordered)
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atomics & refcounters only provide atomicity and
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program order (po) relation (on the same CPU). It guarantees that
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each ``atomic_*()`` and ``refcount_*()`` operation is atomic and instructions
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are executed in program order on a single CPU.
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This is implemented using :c:func:`READ_ONCE`/:c:func:`WRITE_ONCE` and
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compare-and-swap primitives.
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A strong (full) memory ordering guarantees that all prior loads and
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stores (all po-earlier instructions) on the same CPU are completed
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before any po-later instruction is executed on the same CPU.
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It also guarantees that all po-earlier stores on the same CPU
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and all propagated stores from other CPUs must propagate to all
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other CPUs before any po-later instruction is executed on the original
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CPU (A-cumulative property). This is implemented using :c:func:`smp_mb`.
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A RELEASE memory ordering guarantees that all prior loads and
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stores (all po-earlier instructions) on the same CPU are completed
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before the operation. It also guarantees that all po-earlier
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stores on the same CPU and all propagated stores from other CPUs
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must propagate to all other CPUs before the release operation
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(A-cumulative property). This is implemented using
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:c:func:`smp_store_release`.
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An ACQUIRE memory ordering guarantees that all post loads and
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stores (all po-later instructions) on the same CPU are
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completed after the acquire operation. It also guarantees that all
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po-later stores on the same CPU must propagate to all other CPUs
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after the acquire operation executes. This is implemented using
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:c:func:`smp_acquire__after_ctrl_dep`.
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A control dependency (on success) for refcounters guarantees that
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if a reference for an object was successfully obtained (reference
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counter increment or addition happened, function returned true),
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then further stores are ordered against this operation.
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Control dependency on stores are not implemented using any explicit
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barriers, but rely on CPU not to speculate on stores. This is only
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a single CPU relation and provides no guarantees for other CPUs.
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Comparison of functions
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=======================
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case 1) - non-"Read/Modify/Write" (RMW) ops
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-------------------------------------------
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Function changes:
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* :c:func:`atomic_set` --> :c:func:`refcount_set`
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* :c:func:`atomic_read` --> :c:func:`refcount_read`
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Memory ordering guarantee changes:
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* none (both fully unordered)
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case 2) - increment-based ops that return no value
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--------------------------------------------------
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Function changes:
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* :c:func:`atomic_inc` --> :c:func:`refcount_inc`
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* :c:func:`atomic_add` --> :c:func:`refcount_add`
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Memory ordering guarantee changes:
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* none (both fully unordered)
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case 3) - decrement-based RMW ops that return no value
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------------------------------------------------------
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Function changes:
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* :c:func:`atomic_dec` --> :c:func:`refcount_dec`
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Memory ordering guarantee changes:
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* fully unordered --> RELEASE ordering
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case 4) - increment-based RMW ops that return a value
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-----------------------------------------------------
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Function changes:
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* :c:func:`atomic_inc_not_zero` --> :c:func:`refcount_inc_not_zero`
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* no atomic counterpart --> :c:func:`refcount_add_not_zero`
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Memory ordering guarantees changes:
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* fully ordered --> control dependency on success for stores
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.. note:: We really assume here that necessary ordering is provided as a
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result of obtaining pointer to the object!
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case 5) - generic dec/sub decrement-based RMW ops that return a value
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---------------------------------------------------------------------
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Function changes:
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* :c:func:`atomic_dec_and_test` --> :c:func:`refcount_dec_and_test`
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* :c:func:`atomic_sub_and_test` --> :c:func:`refcount_sub_and_test`
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Memory ordering guarantees changes:
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* fully ordered --> RELEASE ordering + ACQUIRE ordering on success
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case 6) other decrement-based RMW ops that return a value
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---------------------------------------------------------
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Function changes:
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* no atomic counterpart --> :c:func:`refcount_dec_if_one`
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* ``atomic_add_unless(&var, -1, 1)`` --> ``refcount_dec_not_one(&var)``
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Memory ordering guarantees changes:
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* fully ordered --> RELEASE ordering + control dependency
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.. note:: :c:func:`atomic_add_unless` only provides full order on success.
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case 7) - lock-based RMW
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------------------------
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Function changes:
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* :c:func:`atomic_dec_and_lock` --> :c:func:`refcount_dec_and_lock`
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* :c:func:`atomic_dec_and_mutex_lock` --> :c:func:`refcount_dec_and_mutex_lock`
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Memory ordering guarantees changes:
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* fully ordered --> RELEASE ordering + control dependency + hold
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:c:func:`spin_lock` on success
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