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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-27 10:05:51 +0000
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+===================================================
+A Tour Through TREE_RCU's Data Structures [LWN.net]
+===================================================
+
+December 18, 2016
+
+This article was contributed by Paul E. McKenney
+
+Introduction
+============
+
+This document describes RCU's major data structures and their relationship
+to each other.
+
+Data-Structure Relationships
+============================
+
+RCU is for all intents and purposes a large state machine, and its
+data structures maintain the state in such a way as to allow RCU readers
+to execute extremely quickly, while also processing the RCU grace periods
+requested by updaters in an efficient and extremely scalable fashion.
+The efficiency and scalability of RCU updaters is provided primarily
+by a combining tree, as shown below:
+
+.. kernel-figure:: BigTreeClassicRCU.svg
+
+This diagram shows an enclosing ``rcu_state`` structure containing a tree
+of ``rcu_node`` structures. Each leaf node of the ``rcu_node`` tree has up
+to 16 ``rcu_data`` structures associated with it, so that there are
+``NR_CPUS`` number of ``rcu_data`` structures, one for each possible CPU.
+This structure is adjusted at boot time, if needed, to handle the common
+case where ``nr_cpu_ids`` is much less than ``NR_CPUs``.
+For example, a number of Linux distributions set ``NR_CPUs=4096``,
+which results in a three-level ``rcu_node`` tree.
+If the actual hardware has only 16 CPUs, RCU will adjust itself
+at boot time, resulting in an ``rcu_node`` tree with only a single node.
+
+The purpose of this combining tree is to allow per-CPU events
+such as quiescent states, dyntick-idle transitions,
+and CPU hotplug operations to be processed efficiently
+and scalably.
+Quiescent states are recorded by the per-CPU ``rcu_data`` structures,
+and other events are recorded by the leaf-level ``rcu_node``
+structures.
+All of these events are combined at each level of the tree until finally
+grace periods are completed at the tree's root ``rcu_node``
+structure.
+A grace period can be completed at the root once every CPU
+(or, in the case of ``CONFIG_PREEMPT_RCU``, task)
+has passed through a quiescent state.
+Once a grace period has completed, record of that fact is propagated
+back down the tree.
+
+As can be seen from the diagram, on a 64-bit system
+a two-level tree with 64 leaves can accommodate 1,024 CPUs, with a fanout
+of 64 at the root and a fanout of 16 at the leaves.
+
++-----------------------------------------------------------------------+
+| **Quick Quiz**: |
++-----------------------------------------------------------------------+
+| Why isn't the fanout at the leaves also 64? |
++-----------------------------------------------------------------------+
+| **Answer**: |
++-----------------------------------------------------------------------+
+| Because there are more types of events that affect the leaf-level |
+| ``rcu_node`` structures than further up the tree. Therefore, if the |
+| leaf ``rcu_node`` structures have fanout of 64, the contention on |
+| these structures' ``->structures`` becomes excessive. Experimentation |
+| on a wide variety of systems has shown that a fanout of 16 works well |
+| for the leaves of the ``rcu_node`` tree. |
+| |
+| Of course, further experience with systems having hundreds or |
+| thousands of CPUs may demonstrate that the fanout for the non-leaf |
+| ``rcu_node`` structures must also be reduced. Such reduction can be |
+| easily carried out when and if it proves necessary. In the meantime, |
+| if you are using such a system and running into contention problems |
+| on the non-leaf ``rcu_node`` structures, you may use the |
+| ``CONFIG_RCU_FANOUT`` kernel configuration parameter to reduce the |
+| non-leaf fanout as needed. |
+| |
+| Kernels built for systems with strong NUMA characteristics might |
+| also need to adjust ``CONFIG_RCU_FANOUT`` so that the domains of |
+| the ``rcu_node`` structures align with hardware boundaries. |
+| However, there has thus far been no need for this. |
++-----------------------------------------------------------------------+
+
+If your system has more than 1,024 CPUs (or more than 512 CPUs on a
+32-bit system), then RCU will automatically add more levels to the tree.
+For example, if you are crazy enough to build a 64-bit system with
+65,536 CPUs, RCU would configure the ``rcu_node`` tree as follows:
+
+.. kernel-figure:: HugeTreeClassicRCU.svg
+
+RCU currently permits up to a four-level tree, which on a 64-bit system
+accommodates up to 4,194,304 CPUs, though only a mere 524,288 CPUs for
+32-bit systems. On the other hand, you can set both
+``CONFIG_RCU_FANOUT`` and ``CONFIG_RCU_FANOUT_LEAF`` to be as small as
+2, which would result in a 16-CPU test using a 4-level tree. This can be
+useful for testing large-system capabilities on small test machines.
+
+This multi-level combining tree allows us to get most of the performance
+and scalability benefits of partitioning, even though RCU grace-period
+detection is inherently a global operation. The trick here is that only
+the last CPU to report a quiescent state into a given ``rcu_node``
+structure need advance to the ``rcu_node`` structure at the next level
+up the tree. This means that at the leaf-level ``rcu_node`` structure,
+only one access out of sixteen will progress up the tree. For the
+internal ``rcu_node`` structures, the situation is even more extreme:
+Only one access out of sixty-four will progress up the tree. Because the
+vast majority of the CPUs do not progress up the tree, the lock
+contention remains roughly constant up the tree. No matter how many CPUs
+there are in the system, at most 64 quiescent-state reports per grace
+period will progress all the way to the root ``rcu_node`` structure,
+thus ensuring that the lock contention on that root ``rcu_node``
+structure remains acceptably low.
+
+In effect, the combining tree acts like a big shock absorber, keeping
+lock contention under control at all tree levels regardless of the level
+of loading on the system.
+
+RCU updaters wait for normal grace periods by registering RCU callbacks,
+either directly via ``call_rcu()`` or indirectly via
+``synchronize_rcu()`` and friends. RCU callbacks are represented by
+``rcu_head`` structures, which are queued on ``rcu_data`` structures
+while they are waiting for a grace period to elapse, as shown in the
+following figure:
+
+.. kernel-figure:: BigTreePreemptRCUBHdyntickCB.svg
+
+This figure shows how ``TREE_RCU``'s and ``PREEMPT_RCU``'s major data
+structures are related. Lesser data structures will be introduced with
+the algorithms that make use of them.
+
+Note that each of the data structures in the above figure has its own
+synchronization:
+
+#. Each ``rcu_state`` structures has a lock and a mutex, and some fields
+ are protected by the corresponding root ``rcu_node`` structure's lock.
+#. Each ``rcu_node`` structure has a spinlock.
+#. The fields in ``rcu_data`` are private to the corresponding CPU,
+ although a few can be read and written by other CPUs.
+
+It is important to note that different data structures can have very
+different ideas about the state of RCU at any given time. For but one
+example, awareness of the start or end of a given RCU grace period
+propagates slowly through the data structures. This slow propagation is
+absolutely necessary for RCU to have good read-side performance. If this
+balkanized implementation seems foreign to you, one useful trick is to
+consider each instance of these data structures to be a different
+person, each having the usual slightly different view of reality.
+
+The general role of each of these data structures is as follows:
+
+#. ``rcu_state``: This structure forms the interconnection between the
+ ``rcu_node`` and ``rcu_data`` structures, tracks grace periods,
+ serves as short-term repository for callbacks orphaned by CPU-hotplug
+ events, maintains ``rcu_barrier()`` state, tracks expedited
+ grace-period state, and maintains state used to force quiescent
+ states when grace periods extend too long,
+#. ``rcu_node``: This structure forms the combining tree that propagates
+ quiescent-state information from the leaves to the root, and also
+ propagates grace-period information from the root to the leaves. It
+ provides local copies of the grace-period state in order to allow
+ this information to be accessed in a synchronized manner without
+ suffering the scalability limitations that would otherwise be imposed
+ by global locking. In ``CONFIG_PREEMPT_RCU`` kernels, it manages the
+ lists of tasks that have blocked while in their current RCU read-side
+ critical section. In ``CONFIG_PREEMPT_RCU`` with
+ ``CONFIG_RCU_BOOST``, it manages the per-\ ``rcu_node``
+ priority-boosting kernel threads (kthreads) and state. Finally, it
+ records CPU-hotplug state in order to determine which CPUs should be
+ ignored during a given grace period.
+#. ``rcu_data``: This per-CPU structure is the focus of quiescent-state
+ detection and RCU callback queuing. It also tracks its relationship
+ to the corresponding leaf ``rcu_node`` structure to allow
+ more-efficient propagation of quiescent states up the ``rcu_node``
+ combining tree. Like the ``rcu_node`` structure, it provides a local
+ copy of the grace-period information to allow for-free synchronized
+ access to this information from the corresponding CPU. Finally, this
+ structure records past dyntick-idle state for the corresponding CPU
+ and also tracks statistics.
+#. ``rcu_head``: This structure represents RCU callbacks, and is the
+ only structure allocated and managed by RCU users. The ``rcu_head``
+ structure is normally embedded within the RCU-protected data
+ structure.
+
+If all you wanted from this article was a general notion of how RCU's
+data structures are related, you are done. Otherwise, each of the
+following sections give more details on the ``rcu_state``, ``rcu_node``
+and ``rcu_data`` data structures.
+
+The ``rcu_state`` Structure
+~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The ``rcu_state`` structure is the base structure that represents the
+state of RCU in the system. This structure forms the interconnection
+between the ``rcu_node`` and ``rcu_data`` structures, tracks grace
+periods, contains the lock used to synchronize with CPU-hotplug events,
+and maintains state used to force quiescent states when grace periods
+extend too long,
+
+A few of the ``rcu_state`` structure's fields are discussed, singly and
+in groups, in the following sections. The more specialized fields are
+covered in the discussion of their use.
+
+Relationship to rcu_node and rcu_data Structures
+''''''''''''''''''''''''''''''''''''''''''''''''
+
+This portion of the ``rcu_state`` structure is declared as follows:
+
+::
+
+ 1 struct rcu_node node[NUM_RCU_NODES];
+ 2 struct rcu_node *level[NUM_RCU_LVLS + 1];
+ 3 struct rcu_data __percpu *rda;
+
++-----------------------------------------------------------------------+
+| **Quick Quiz**: |
++-----------------------------------------------------------------------+
+| Wait a minute! You said that the ``rcu_node`` structures formed a |
+| tree, but they are declared as a flat array! What gives? |
++-----------------------------------------------------------------------+
+| **Answer**: |
++-----------------------------------------------------------------------+
+| The tree is laid out in the array. The first node In the array is the |
+| head, the next set of nodes in the array are children of the head |
+| node, and so on until the last set of nodes in the array are the |
+| leaves. |
+| See the following diagrams to see how this works. |
++-----------------------------------------------------------------------+
+
+The ``rcu_node`` tree is embedded into the ``->node[]`` array as shown
+in the following figure:
+
+.. kernel-figure:: TreeMapping.svg
+
+One interesting consequence of this mapping is that a breadth-first
+traversal of the tree is implemented as a simple linear scan of the
+array, which is in fact what the ``rcu_for_each_node_breadth_first()``
+macro does. This macro is used at the beginning and ends of grace
+periods.
+
+Each entry of the ``->level`` array references the first ``rcu_node``
+structure on the corresponding level of the tree, for example, as shown
+below:
+
+.. kernel-figure:: TreeMappingLevel.svg
+
+The zero\ :sup:`th` element of the array references the root
+``rcu_node`` structure, the first element references the first child of
+the root ``rcu_node``, and finally the second element references the
+first leaf ``rcu_node`` structure.
+
+For whatever it is worth, if you draw the tree to be tree-shaped rather
+than array-shaped, it is easy to draw a planar representation:
+
+.. kernel-figure:: TreeLevel.svg
+
+Finally, the ``->rda`` field references a per-CPU pointer to the
+corresponding CPU's ``rcu_data`` structure.
+
+All of these fields are constant once initialization is complete, and
+therefore need no protection.
+
+Grace-Period Tracking
+'''''''''''''''''''''
+
+This portion of the ``rcu_state`` structure is declared as follows:
+
+::
+
+ 1 unsigned long gp_seq;
+
+RCU grace periods are numbered, and the ``->gp_seq`` field contains the
+current grace-period sequence number. The bottom two bits are the state
+of the current grace period, which can be zero for not yet started or
+one for in progress. In other words, if the bottom two bits of
+``->gp_seq`` are zero, then RCU is idle. Any other value in the bottom
+two bits indicates that something is broken. This field is protected by
+the root ``rcu_node`` structure's ``->lock`` field.
+
+There are ``->gp_seq`` fields in the ``rcu_node`` and ``rcu_data``
+structures as well. The fields in the ``rcu_state`` structure represent
+the most current value, and those of the other structures are compared
+in order to detect the beginnings and ends of grace periods in a
+distributed fashion. The values flow from ``rcu_state`` to ``rcu_node``
+(down the tree from the root to the leaves) to ``rcu_data``.
+
+Miscellaneous
+'''''''''''''
+
+This portion of the ``rcu_state`` structure is declared as follows:
+
+::
+
+ 1 unsigned long gp_max;
+ 2 char abbr;
+ 3 char *name;
+
+The ``->gp_max`` field tracks the duration of the longest grace period
+in jiffies. It is protected by the root ``rcu_node``'s ``->lock``.
+
+The ``->name`` and ``->abbr`` fields distinguish between preemptible RCU
+(“rcu_preempt” and “p”) and non-preemptible RCU (“rcu_sched” and “s”).
+These fields are used for diagnostic and tracing purposes.
+
+The ``rcu_node`` Structure
+~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The ``rcu_node`` structures form the combining tree that propagates
+quiescent-state information from the leaves to the root and also that
+propagates grace-period information from the root down to the leaves.
+They provides local copies of the grace-period state in order to allow
+this information to be accessed in a synchronized manner without
+suffering the scalability limitations that would otherwise be imposed by
+global locking. In ``CONFIG_PREEMPT_RCU`` kernels, they manage the lists
+of tasks that have blocked while in their current RCU read-side critical
+section. In ``CONFIG_PREEMPT_RCU`` with ``CONFIG_RCU_BOOST``, they
+manage the per-\ ``rcu_node`` priority-boosting kernel threads
+(kthreads) and state. Finally, they record CPU-hotplug state in order to
+determine which CPUs should be ignored during a given grace period.
+
+The ``rcu_node`` structure's fields are discussed, singly and in groups,
+in the following sections.
+
+Connection to Combining Tree
+''''''''''''''''''''''''''''
+
+This portion of the ``rcu_node`` structure is declared as follows:
+
+::
+
+ 1 struct rcu_node *parent;
+ 2 u8 level;
+ 3 u8 grpnum;
+ 4 unsigned long grpmask;
+ 5 int grplo;
+ 6 int grphi;
+
+The ``->parent`` pointer references the ``rcu_node`` one level up in the
+tree, and is ``NULL`` for the root ``rcu_node``. The RCU implementation
+makes heavy use of this field to push quiescent states up the tree. The
+``->level`` field gives the level in the tree, with the root being at
+level zero, its children at level one, and so on. The ``->grpnum`` field
+gives this node's position within the children of its parent, so this
+number can range between 0 and 31 on 32-bit systems and between 0 and 63
+on 64-bit systems. The ``->level`` and ``->grpnum`` fields are used only
+during initialization and for tracing. The ``->grpmask`` field is the
+bitmask counterpart of ``->grpnum``, and therefore always has exactly
+one bit set. This mask is used to clear the bit corresponding to this
+``rcu_node`` structure in its parent's bitmasks, which are described
+later. Finally, the ``->grplo`` and ``->grphi`` fields contain the
+lowest and highest numbered CPU served by this ``rcu_node`` structure,
+respectively.
+
+All of these fields are constant, and thus do not require any
+synchronization.
+
+Synchronization
+'''''''''''''''
+
+This field of the ``rcu_node`` structure is declared as follows:
+
+::
+
+ 1 raw_spinlock_t lock;
+
+This field is used to protect the remaining fields in this structure,
+unless otherwise stated. That said, all of the fields in this structure
+can be accessed without locking for tracing purposes. Yes, this can
+result in confusing traces, but better some tracing confusion than to be
+heisenbugged out of existence.
+
+.. _grace-period-tracking-1:
+
+Grace-Period Tracking
+'''''''''''''''''''''
+
+This portion of the ``rcu_node`` structure is declared as follows:
+
+::
+
+ 1 unsigned long gp_seq;
+ 2 unsigned long gp_seq_needed;
+
+The ``rcu_node`` structures' ``->gp_seq`` fields are the counterparts of
+the field of the same name in the ``rcu_state`` structure. They each may
+lag up to one step behind their ``rcu_state`` counterpart. If the bottom
+two bits of a given ``rcu_node`` structure's ``->gp_seq`` field is zero,
+then this ``rcu_node`` structure believes that RCU is idle.
+
+The ``>gp_seq`` field of each ``rcu_node`` structure is updated at the
+beginning and the end of each grace period.
+
+The ``->gp_seq_needed`` fields record the furthest-in-the-future grace
+period request seen by the corresponding ``rcu_node`` structure. The
+request is considered fulfilled when the value of the ``->gp_seq`` field
+equals or exceeds that of the ``->gp_seq_needed`` field.
+
++-----------------------------------------------------------------------+
+| **Quick Quiz**: |
++-----------------------------------------------------------------------+
+| Suppose that this ``rcu_node`` structure doesn't see a request for a |
+| very long time. Won't wrapping of the ``->gp_seq`` field cause |
+| problems? |
++-----------------------------------------------------------------------+
+| **Answer**: |
++-----------------------------------------------------------------------+
+| No, because if the ``->gp_seq_needed`` field lags behind the |
+| ``->gp_seq`` field, the ``->gp_seq_needed`` field will be updated at |
+| the end of the grace period. Modulo-arithmetic comparisons therefore |
+| will always get the correct answer, even with wrapping. |
++-----------------------------------------------------------------------+
+
+Quiescent-State Tracking
+''''''''''''''''''''''''
+
+These fields manage the propagation of quiescent states up the combining
+tree.
+
+This portion of the ``rcu_node`` structure has fields as follows:
+
+::
+
+ 1 unsigned long qsmask;
+ 2 unsigned long expmask;
+ 3 unsigned long qsmaskinit;
+ 4 unsigned long expmaskinit;
+
+The ``->qsmask`` field tracks which of this ``rcu_node`` structure's
+children still need to report quiescent states for the current normal
+grace period. Such children will have a value of 1 in their
+corresponding bit. Note that the leaf ``rcu_node`` structures should be
+thought of as having ``rcu_data`` structures as their children.
+Similarly, the ``->expmask`` field tracks which of this ``rcu_node``
+structure's children still need to report quiescent states for the
+current expedited grace period. An expedited grace period has the same
+conceptual properties as a normal grace period, but the expedited
+implementation accepts extreme CPU overhead to obtain much lower
+grace-period latency, for example, consuming a few tens of microseconds
+worth of CPU time to reduce grace-period duration from milliseconds to
+tens of microseconds. The ``->qsmaskinit`` field tracks which of this
+``rcu_node`` structure's children cover for at least one online CPU.
+This mask is used to initialize ``->qsmask``, and ``->expmaskinit`` is
+used to initialize ``->expmask`` and the beginning of the normal and
+expedited grace periods, respectively.
+
++-----------------------------------------------------------------------+
+| **Quick Quiz**: |
++-----------------------------------------------------------------------+
+| Why are these bitmasks protected by locking? Come on, haven't you |
+| heard of atomic instructions??? |
++-----------------------------------------------------------------------+
+| **Answer**: |
++-----------------------------------------------------------------------+
+| Lockless grace-period computation! Such a tantalizing possibility! |
+| But consider the following sequence of events: |
+| |
+| #. CPU 0 has been in dyntick-idle mode for quite some time. When it |
+| wakes up, it notices that the current RCU grace period needs it to |
+| report in, so it sets a flag where the scheduling clock interrupt |
+| will find it. |
+| #. Meanwhile, CPU 1 is running ``force_quiescent_state()``, and |
+| notices that CPU 0 has been in dyntick idle mode, which qualifies |
+| as an extended quiescent state. |
+| #. CPU 0's scheduling clock interrupt fires in the middle of an RCU |
+| read-side critical section, and notices that the RCU core needs |
+| something, so commences RCU softirq processing. |
+| #. CPU 0's softirq handler executes and is just about ready to report |
+| its quiescent state up the ``rcu_node`` tree. |
+| #. But CPU 1 beats it to the punch, completing the current grace |
+| period and starting a new one. |
+| #. CPU 0 now reports its quiescent state for the wrong grace period. |
+| That grace period might now end before the RCU read-side critical |
+| section. If that happens, disaster will ensue. |
+| |
+| So the locking is absolutely required in order to coordinate clearing |
+| of the bits with updating of the grace-period sequence number in |
+| ``->gp_seq``. |
++-----------------------------------------------------------------------+
+
+Blocked-Task Management
+'''''''''''''''''''''''
+
+``PREEMPT_RCU`` allows tasks to be preempted in the midst of their RCU
+read-side critical sections, and these tasks must be tracked explicitly.
+The details of exactly why and how they are tracked will be covered in a
+separate article on RCU read-side processing. For now, it is enough to
+know that the ``rcu_node`` structure tracks them.
+
+::
+
+ 1 struct list_head blkd_tasks;
+ 2 struct list_head *gp_tasks;
+ 3 struct list_head *exp_tasks;
+ 4 bool wait_blkd_tasks;
+
+The ``->blkd_tasks`` field is a list header for the list of blocked and
+preempted tasks. As tasks undergo context switches within RCU read-side
+critical sections, their ``task_struct`` structures are enqueued (via
+the ``task_struct``'s ``->rcu_node_entry`` field) onto the head of the
+``->blkd_tasks`` list for the leaf ``rcu_node`` structure corresponding
+to the CPU on which the outgoing context switch executed. As these tasks
+later exit their RCU read-side critical sections, they remove themselves
+from the list. This list is therefore in reverse time order, so that if
+one of the tasks is blocking the current grace period, all subsequent
+tasks must also be blocking that same grace period. Therefore, a single
+pointer into this list suffices to track all tasks blocking a given
+grace period. That pointer is stored in ``->gp_tasks`` for normal grace
+periods and in ``->exp_tasks`` for expedited grace periods. These last
+two fields are ``NULL`` if either there is no grace period in flight or
+if there are no blocked tasks preventing that grace period from
+completing. If either of these two pointers is referencing a task that
+removes itself from the ``->blkd_tasks`` list, then that task must
+advance the pointer to the next task on the list, or set the pointer to
+``NULL`` if there are no subsequent tasks on the list.
+
+For example, suppose that tasks T1, T2, and T3 are all hard-affinitied
+to the largest-numbered CPU in the system. Then if task T1 blocked in an
+RCU read-side critical section, then an expedited grace period started,
+then task T2 blocked in an RCU read-side critical section, then a normal
+grace period started, and finally task 3 blocked in an RCU read-side
+critical section, then the state of the last leaf ``rcu_node``
+structure's blocked-task list would be as shown below:
+
+.. kernel-figure:: blkd_task.svg
+
+Task T1 is blocking both grace periods, task T2 is blocking only the
+normal grace period, and task T3 is blocking neither grace period. Note
+that these tasks will not remove themselves from this list immediately
+upon resuming execution. They will instead remain on the list until they
+execute the outermost ``rcu_read_unlock()`` that ends their RCU
+read-side critical section.
+
+The ``->wait_blkd_tasks`` field indicates whether or not the current
+grace period is waiting on a blocked task.
+
+Sizing the ``rcu_node`` Array
+'''''''''''''''''''''''''''''
+
+The ``rcu_node`` array is sized via a series of C-preprocessor
+expressions as follows:
+
+::
+
+ 1 #ifdef CONFIG_RCU_FANOUT
+ 2 #define RCU_FANOUT CONFIG_RCU_FANOUT
+ 3 #else
+ 4 # ifdef CONFIG_64BIT
+ 5 # define RCU_FANOUT 64
+ 6 # else
+ 7 # define RCU_FANOUT 32
+ 8 # endif
+ 9 #endif
+ 10
+ 11 #ifdef CONFIG_RCU_FANOUT_LEAF
+ 12 #define RCU_FANOUT_LEAF CONFIG_RCU_FANOUT_LEAF
+ 13 #else
+ 14 # ifdef CONFIG_64BIT
+ 15 # define RCU_FANOUT_LEAF 64
+ 16 # else
+ 17 # define RCU_FANOUT_LEAF 32
+ 18 # endif
+ 19 #endif
+ 20
+ 21 #define RCU_FANOUT_1 (RCU_FANOUT_LEAF)
+ 22 #define RCU_FANOUT_2 (RCU_FANOUT_1 * RCU_FANOUT)
+ 23 #define RCU_FANOUT_3 (RCU_FANOUT_2 * RCU_FANOUT)
+ 24 #define RCU_FANOUT_4 (RCU_FANOUT_3 * RCU_FANOUT)
+ 25
+ 26 #if NR_CPUS <= RCU_FANOUT_1
+ 27 # define RCU_NUM_LVLS 1
+ 28 # define NUM_RCU_LVL_0 1
+ 29 # define NUM_RCU_NODES NUM_RCU_LVL_0
+ 30 # define NUM_RCU_LVL_INIT { NUM_RCU_LVL_0 }
+ 31 # define RCU_NODE_NAME_INIT { "rcu_node_0" }
+ 32 # define RCU_FQS_NAME_INIT { "rcu_node_fqs_0" }
+ 33 # define RCU_EXP_NAME_INIT { "rcu_node_exp_0" }
+ 34 #elif NR_CPUS <= RCU_FANOUT_2
+ 35 # define RCU_NUM_LVLS 2
+ 36 # define NUM_RCU_LVL_0 1
+ 37 # define NUM_RCU_LVL_1 DIV_ROUND_UP(NR_CPUS, RCU_FANOUT_1)
+ 38 # define NUM_RCU_NODES (NUM_RCU_LVL_0 + NUM_RCU_LVL_1)
+ 39 # define NUM_RCU_LVL_INIT { NUM_RCU_LVL_0, NUM_RCU_LVL_1 }
+ 40 # define RCU_NODE_NAME_INIT { "rcu_node_0", "rcu_node_1" }
+ 41 # define RCU_FQS_NAME_INIT { "rcu_node_fqs_0", "rcu_node_fqs_1" }
+ 42 # define RCU_EXP_NAME_INIT { "rcu_node_exp_0", "rcu_node_exp_1" }
+ 43 #elif NR_CPUS <= RCU_FANOUT_3
+ 44 # define RCU_NUM_LVLS 3
+ 45 # define NUM_RCU_LVL_0 1
+ 46 # define NUM_RCU_LVL_1 DIV_ROUND_UP(NR_CPUS, RCU_FANOUT_2)
+ 47 # define NUM_RCU_LVL_2 DIV_ROUND_UP(NR_CPUS, RCU_FANOUT_1)
+ 48 # define NUM_RCU_NODES (NUM_RCU_LVL_0 + NUM_RCU_LVL_1 + NUM_RCU_LVL_2)
+ 49 # define NUM_RCU_LVL_INIT { NUM_RCU_LVL_0, NUM_RCU_LVL_1, NUM_RCU_LVL_2 }
+ 50 # define RCU_NODE_NAME_INIT { "rcu_node_0", "rcu_node_1", "rcu_node_2" }
+ 51 # define RCU_FQS_NAME_INIT { "rcu_node_fqs_0", "rcu_node_fqs_1", "rcu_node_fqs_2" }
+ 52 # define RCU_EXP_NAME_INIT { "rcu_node_exp_0", "rcu_node_exp_1", "rcu_node_exp_2" }
+ 53 #elif NR_CPUS <= RCU_FANOUT_4
+ 54 # define RCU_NUM_LVLS 4
+ 55 # define NUM_RCU_LVL_0 1
+ 56 # define NUM_RCU_LVL_1 DIV_ROUND_UP(NR_CPUS, RCU_FANOUT_3)
+ 57 # define NUM_RCU_LVL_2 DIV_ROUND_UP(NR_CPUS, RCU_FANOUT_2)
+ 58 # define NUM_RCU_LVL_3 DIV_ROUND_UP(NR_CPUS, RCU_FANOUT_1)
+ 59 # define NUM_RCU_NODES (NUM_RCU_LVL_0 + NUM_RCU_LVL_1 + NUM_RCU_LVL_2 + NUM_RCU_LVL_3)
+ 60 # define NUM_RCU_LVL_INIT { NUM_RCU_LVL_0, NUM_RCU_LVL_1, NUM_RCU_LVL_2, NUM_RCU_LVL_3 }
+ 61 # define RCU_NODE_NAME_INIT { "rcu_node_0", "rcu_node_1", "rcu_node_2", "rcu_node_3" }
+ 62 # define RCU_FQS_NAME_INIT { "rcu_node_fqs_0", "rcu_node_fqs_1", "rcu_node_fqs_2", "rcu_node_fqs_3" }
+ 63 # define RCU_EXP_NAME_INIT { "rcu_node_exp_0", "rcu_node_exp_1", "rcu_node_exp_2", "rcu_node_exp_3" }
+ 64 #else
+ 65 # error "CONFIG_RCU_FANOUT insufficient for NR_CPUS"
+ 66 #endif
+
+The maximum number of levels in the ``rcu_node`` structure is currently
+limited to four, as specified by lines 21-24 and the structure of the
+subsequent “if” statement. For 32-bit systems, this allows
+16*32*32*32=524,288 CPUs, which should be sufficient for the next few
+years at least. For 64-bit systems, 16*64*64*64=4,194,304 CPUs is
+allowed, which should see us through the next decade or so. This
+four-level tree also allows kernels built with ``CONFIG_RCU_FANOUT=8``
+to support up to 4096 CPUs, which might be useful in very large systems
+having eight CPUs per socket (but please note that no one has yet shown
+any measurable performance degradation due to misaligned socket and
+``rcu_node`` boundaries). In addition, building kernels with a full four
+levels of ``rcu_node`` tree permits better testing of RCU's
+combining-tree code.
+
+The ``RCU_FANOUT`` symbol controls how many children are permitted at
+each non-leaf level of the ``rcu_node`` tree. If the
+``CONFIG_RCU_FANOUT`` Kconfig option is not specified, it is set based
+on the word size of the system, which is also the Kconfig default.
+
+The ``RCU_FANOUT_LEAF`` symbol controls how many CPUs are handled by
+each leaf ``rcu_node`` structure. Experience has shown that allowing a
+given leaf ``rcu_node`` structure to handle 64 CPUs, as permitted by the
+number of bits in the ``->qsmask`` field on a 64-bit system, results in
+excessive contention for the leaf ``rcu_node`` structures' ``->lock``
+fields. The number of CPUs per leaf ``rcu_node`` structure is therefore
+limited to 16 given the default value of ``CONFIG_RCU_FANOUT_LEAF``. If
+``CONFIG_RCU_FANOUT_LEAF`` is unspecified, the value selected is based
+on the word size of the system, just as for ``CONFIG_RCU_FANOUT``.
+Lines 11-19 perform this computation.
+
+Lines 21-24 compute the maximum number of CPUs supported by a
+single-level (which contains a single ``rcu_node`` structure),
+two-level, three-level, and four-level ``rcu_node`` tree, respectively,
+given the fanout specified by ``RCU_FANOUT`` and ``RCU_FANOUT_LEAF``.
+These numbers of CPUs are retained in the ``RCU_FANOUT_1``,
+``RCU_FANOUT_2``, ``RCU_FANOUT_3``, and ``RCU_FANOUT_4`` C-preprocessor
+variables, respectively.
+
+These variables are used to control the C-preprocessor ``#if`` statement
+spanning lines 26-66 that computes the number of ``rcu_node`` structures
+required for each level of the tree, as well as the number of levels
+required. The number of levels is placed in the ``NUM_RCU_LVLS``
+C-preprocessor variable by lines 27, 35, 44, and 54. The number of
+``rcu_node`` structures for the topmost level of the tree is always
+exactly one, and this value is unconditionally placed into
+``NUM_RCU_LVL_0`` by lines 28, 36, 45, and 55. The rest of the levels
+(if any) of the ``rcu_node`` tree are computed by dividing the maximum
+number of CPUs by the fanout supported by the number of levels from the
+current level down, rounding up. This computation is performed by
+lines 37, 46-47, and 56-58. Lines 31-33, 40-42, 50-52, and 62-63 create
+initializers for lockdep lock-class names. Finally, lines 64-66 produce
+an error if the maximum number of CPUs is too large for the specified
+fanout.
+
+The ``rcu_segcblist`` Structure
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The ``rcu_segcblist`` structure maintains a segmented list of callbacks
+as follows:
+
+::
+
+ 1 #define RCU_DONE_TAIL 0
+ 2 #define RCU_WAIT_TAIL 1
+ 3 #define RCU_NEXT_READY_TAIL 2
+ 4 #define RCU_NEXT_TAIL 3
+ 5 #define RCU_CBLIST_NSEGS 4
+ 6
+ 7 struct rcu_segcblist {
+ 8 struct rcu_head *head;
+ 9 struct rcu_head **tails[RCU_CBLIST_NSEGS];
+ 10 unsigned long gp_seq[RCU_CBLIST_NSEGS];
+ 11 long len;
+ 12 long len_lazy;
+ 13 };
+
+The segments are as follows:
+
+#. ``RCU_DONE_TAIL``: Callbacks whose grace periods have elapsed. These
+ callbacks are ready to be invoked.
+#. ``RCU_WAIT_TAIL``: Callbacks that are waiting for the current grace
+ period. Note that different CPUs can have different ideas about which
+ grace period is current, hence the ``->gp_seq`` field.
+#. ``RCU_NEXT_READY_TAIL``: Callbacks waiting for the next grace period
+ to start.
+#. ``RCU_NEXT_TAIL``: Callbacks that have not yet been associated with a
+ grace period.
+
+The ``->head`` pointer references the first callback or is ``NULL`` if
+the list contains no callbacks (which is *not* the same as being empty).
+Each element of the ``->tails[]`` array references the ``->next``
+pointer of the last callback in the corresponding segment of the list,
+or the list's ``->head`` pointer if that segment and all previous
+segments are empty. If the corresponding segment is empty but some
+previous segment is not empty, then the array element is identical to
+its predecessor. Older callbacks are closer to the head of the list, and
+new callbacks are added at the tail. This relationship between the
+``->head`` pointer, the ``->tails[]`` array, and the callbacks is shown
+in this diagram:
+
+.. kernel-figure:: nxtlist.svg
+
+In this figure, the ``->head`` pointer references the first RCU callback
+in the list. The ``->tails[RCU_DONE_TAIL]`` array element references the
+``->head`` pointer itself, indicating that none of the callbacks is
+ready to invoke. The ``->tails[RCU_WAIT_TAIL]`` array element references
+callback CB 2's ``->next`` pointer, which indicates that CB 1 and CB 2
+are both waiting on the current grace period, give or take possible
+disagreements about exactly which grace period is the current one. The
+``->tails[RCU_NEXT_READY_TAIL]`` array element references the same RCU
+callback that ``->tails[RCU_WAIT_TAIL]`` does, which indicates that
+there are no callbacks waiting on the next RCU grace period. The
+``->tails[RCU_NEXT_TAIL]`` array element references CB 4's ``->next``
+pointer, indicating that all the remaining RCU callbacks have not yet
+been assigned to an RCU grace period. Note that the
+``->tails[RCU_NEXT_TAIL]`` array element always references the last RCU
+callback's ``->next`` pointer unless the callback list is empty, in
+which case it references the ``->head`` pointer.
+
+There is one additional important special case for the
+``->tails[RCU_NEXT_TAIL]`` array element: It can be ``NULL`` when this
+list is *disabled*. Lists are disabled when the corresponding CPU is
+offline or when the corresponding CPU's callbacks are offloaded to a
+kthread, both of which are described elsewhere.
+
+CPUs advance their callbacks from the ``RCU_NEXT_TAIL`` to the
+``RCU_NEXT_READY_TAIL`` to the ``RCU_WAIT_TAIL`` to the
+``RCU_DONE_TAIL`` list segments as grace periods advance.
+
+The ``->gp_seq[]`` array records grace-period numbers corresponding to
+the list segments. This is what allows different CPUs to have different
+ideas as to which is the current grace period while still avoiding
+premature invocation of their callbacks. In particular, this allows CPUs
+that go idle for extended periods to determine which of their callbacks
+are ready to be invoked after reawakening.
+
+The ``->len`` counter contains the number of callbacks in ``->head``,
+and the ``->len_lazy`` contains the number of those callbacks that are
+known to only free memory, and whose invocation can therefore be safely
+deferred.
+
+.. important::
+
+ It is the ``->len`` field that determines whether or
+ not there are callbacks associated with this ``rcu_segcblist``
+ structure, *not* the ``->head`` pointer. The reason for this is that all
+ the ready-to-invoke callbacks (that is, those in the ``RCU_DONE_TAIL``
+ segment) are extracted all at once at callback-invocation time
+ (``rcu_do_batch``), due to which ``->head`` may be set to NULL if there
+ are no not-done callbacks remaining in the ``rcu_segcblist``. If
+ callback invocation must be postponed, for example, because a
+ high-priority process just woke up on this CPU, then the remaining
+ callbacks are placed back on the ``RCU_DONE_TAIL`` segment and
+ ``->head`` once again points to the start of the segment. In short, the
+ head field can briefly be ``NULL`` even though the CPU has callbacks
+ present the entire time. Therefore, it is not appropriate to test the
+ ``->head`` pointer for ``NULL``.
+
+In contrast, the ``->len`` and ``->len_lazy`` counts are adjusted only
+after the corresponding callbacks have been invoked. This means that the
+``->len`` count is zero only if the ``rcu_segcblist`` structure really
+is devoid of callbacks. Of course, off-CPU sampling of the ``->len``
+count requires careful use of appropriate synchronization, for example,
+memory barriers. This synchronization can be a bit subtle, particularly
+in the case of ``rcu_barrier()``.
+
+The ``rcu_data`` Structure
+~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The ``rcu_data`` maintains the per-CPU state for the RCU subsystem. The
+fields in this structure may be accessed only from the corresponding CPU
+(and from tracing) unless otherwise stated. This structure is the focus
+of quiescent-state detection and RCU callback queuing. It also tracks
+its relationship to the corresponding leaf ``rcu_node`` structure to
+allow more-efficient propagation of quiescent states up the ``rcu_node``
+combining tree. Like the ``rcu_node`` structure, it provides a local
+copy of the grace-period information to allow for-free synchronized
+access to this information from the corresponding CPU. Finally, this
+structure records past dyntick-idle state for the corresponding CPU and
+also tracks statistics.
+
+The ``rcu_data`` structure's fields are discussed, singly and in groups,
+in the following sections.
+
+Connection to Other Data Structures
+'''''''''''''''''''''''''''''''''''
+
+This portion of the ``rcu_data`` structure is declared as follows:
+
+::
+
+ 1 int cpu;
+ 2 struct rcu_node *mynode;
+ 3 unsigned long grpmask;
+ 4 bool beenonline;
+
+The ``->cpu`` field contains the number of the corresponding CPU and the
+``->mynode`` field references the corresponding ``rcu_node`` structure.
+The ``->mynode`` is used to propagate quiescent states up the combining
+tree. These two fields are constant and therefore do not require
+synchronization.
+
+The ``->grpmask`` field indicates the bit in the ``->mynode->qsmask``
+corresponding to this ``rcu_data`` structure, and is also used when
+propagating quiescent states. The ``->beenonline`` flag is set whenever
+the corresponding CPU comes online, which means that the debugfs tracing
+need not dump out any ``rcu_data`` structure for which this flag is not
+set.
+
+Quiescent-State and Grace-Period Tracking
+'''''''''''''''''''''''''''''''''''''''''
+
+This portion of the ``rcu_data`` structure is declared as follows:
+
+::
+
+ 1 unsigned long gp_seq;
+ 2 unsigned long gp_seq_needed;
+ 3 bool cpu_no_qs;
+ 4 bool core_needs_qs;
+ 5 bool gpwrap;
+
+The ``->gp_seq`` field is the counterpart of the field of the same name
+in the ``rcu_state`` and ``rcu_node`` structures. The
+``->gp_seq_needed`` field is the counterpart of the field of the same
+name in the rcu_node structure. They may each lag up to one behind their
+``rcu_node`` counterparts, but in ``CONFIG_NO_HZ_IDLE`` and
+``CONFIG_NO_HZ_FULL`` kernels can lag arbitrarily far behind for CPUs in
+dyntick-idle mode (but these counters will catch up upon exit from
+dyntick-idle mode). If the lower two bits of a given ``rcu_data``
+structure's ``->gp_seq`` are zero, then this ``rcu_data`` structure
+believes that RCU is idle.
+
++-----------------------------------------------------------------------+
+| **Quick Quiz**: |
++-----------------------------------------------------------------------+
+| All this replication of the grace period numbers can only cause |
+| massive confusion. Why not just keep a global sequence number and be |
+| done with it??? |
++-----------------------------------------------------------------------+
+| **Answer**: |
++-----------------------------------------------------------------------+
+| Because if there was only a single global sequence numbers, there |
+| would need to be a single global lock to allow safely accessing and |
+| updating it. And if we are not going to have a single global lock, we |
+| need to carefully manage the numbers on a per-node basis. Recall from |
+| the answer to a previous Quick Quiz that the consequences of applying |
+| a previously sampled quiescent state to the wrong grace period are |
+| quite severe. |
++-----------------------------------------------------------------------+
+
+The ``->cpu_no_qs`` flag indicates that the CPU has not yet passed
+through a quiescent state, while the ``->core_needs_qs`` flag indicates
+that the RCU core needs a quiescent state from the corresponding CPU.
+The ``->gpwrap`` field indicates that the corresponding CPU has remained
+idle for so long that the ``gp_seq`` counter is in danger of overflow,
+which will cause the CPU to disregard the values of its counters on its
+next exit from idle.
+
+RCU Callback Handling
+'''''''''''''''''''''
+
+In the absence of CPU-hotplug events, RCU callbacks are invoked by the
+same CPU that registered them. This is strictly a cache-locality
+optimization: callbacks can and do get invoked on CPUs other than the
+one that registered them. After all, if the CPU that registered a given
+callback has gone offline before the callback can be invoked, there
+really is no other choice.
+
+This portion of the ``rcu_data`` structure is declared as follows:
+
+::
+
+ 1 struct rcu_segcblist cblist;
+ 2 long qlen_last_fqs_check;
+ 3 unsigned long n_cbs_invoked;
+ 4 unsigned long n_nocbs_invoked;
+ 5 unsigned long n_cbs_orphaned;
+ 6 unsigned long n_cbs_adopted;
+ 7 unsigned long n_force_qs_snap;
+ 8 long blimit;
+
+The ``->cblist`` structure is the segmented callback list described
+earlier. The CPU advances the callbacks in its ``rcu_data`` structure
+whenever it notices that another RCU grace period has completed. The CPU
+detects the completion of an RCU grace period by noticing that the value
+of its ``rcu_data`` structure's ``->gp_seq`` field differs from that of
+its leaf ``rcu_node`` structure. Recall that each ``rcu_node``
+structure's ``->gp_seq`` field is updated at the beginnings and ends of
+each grace period.
+
+The ``->qlen_last_fqs_check`` and ``->n_force_qs_snap`` coordinate the
+forcing of quiescent states from ``call_rcu()`` and friends when
+callback lists grow excessively long.
+
+The ``->n_cbs_invoked``, ``->n_cbs_orphaned``, and ``->n_cbs_adopted``
+fields count the number of callbacks invoked, sent to other CPUs when
+this CPU goes offline, and received from other CPUs when those other
+CPUs go offline. The ``->n_nocbs_invoked`` is used when the CPU's
+callbacks are offloaded to a kthread.
+
+Finally, the ``->blimit`` counter is the maximum number of RCU callbacks
+that may be invoked at a given time.
+
+Dyntick-Idle Handling
+'''''''''''''''''''''
+
+This portion of the ``rcu_data`` structure is declared as follows:
+
+::
+
+ 1 int dynticks_snap;
+ 2 unsigned long dynticks_fqs;
+
+The ``->dynticks_snap`` field is used to take a snapshot of the
+corresponding CPU's dyntick-idle state when forcing quiescent states,
+and is therefore accessed from other CPUs. Finally, the
+``->dynticks_fqs`` field is used to count the number of times this CPU
+is determined to be in dyntick-idle state, and is used for tracing and
+debugging purposes.
+
+This portion of the rcu_data structure is declared as follows:
+
+::
+
+ 1 long dynticks_nesting;
+ 2 long dynticks_nmi_nesting;
+ 3 atomic_t dynticks;
+ 4 bool rcu_need_heavy_qs;
+ 5 bool rcu_urgent_qs;
+
+These fields in the rcu_data structure maintain the per-CPU dyntick-idle
+state for the corresponding CPU. The fields may be accessed only from
+the corresponding CPU (and from tracing) unless otherwise stated.
+
+The ``->dynticks_nesting`` field counts the nesting depth of process
+execution, so that in normal circumstances this counter has value zero
+or one. NMIs, irqs, and tracers are counted by the
+``->dynticks_nmi_nesting`` field. Because NMIs cannot be masked, changes
+to this variable have to be undertaken carefully using an algorithm
+provided by Andy Lutomirski. The initial transition from idle adds one,
+and nested transitions add two, so that a nesting level of five is
+represented by a ``->dynticks_nmi_nesting`` value of nine. This counter
+can therefore be thought of as counting the number of reasons why this
+CPU cannot be permitted to enter dyntick-idle mode, aside from
+process-level transitions.
+
+However, it turns out that when running in non-idle kernel context, the
+Linux kernel is fully capable of entering interrupt handlers that never
+exit and perhaps also vice versa. Therefore, whenever the
+``->dynticks_nesting`` field is incremented up from zero, the
+``->dynticks_nmi_nesting`` field is set to a large positive number, and
+whenever the ``->dynticks_nesting`` field is decremented down to zero,
+the ``->dynticks_nmi_nesting`` field is set to zero. Assuming that
+the number of misnested interrupts is not sufficient to overflow the
+counter, this approach corrects the ``->dynticks_nmi_nesting`` field
+every time the corresponding CPU enters the idle loop from process
+context.
+
+The ``->dynticks`` field counts the corresponding CPU's transitions to
+and from either dyntick-idle or user mode, so that this counter has an
+even value when the CPU is in dyntick-idle mode or user mode and an odd
+value otherwise. The transitions to/from user mode need to be counted
+for user mode adaptive-ticks support (see timers/NO_HZ.txt).
+
+The ``->rcu_need_heavy_qs`` field is used to record the fact that the
+RCU core code would really like to see a quiescent state from the
+corresponding CPU, so much so that it is willing to call for
+heavy-weight dyntick-counter operations. This flag is checked by RCU's
+context-switch and ``cond_resched()`` code, which provide a momentary
+idle sojourn in response.
+
+Finally, the ``->rcu_urgent_qs`` field is used to record the fact that
+the RCU core code would really like to see a quiescent state from the
+corresponding CPU, with the various other fields indicating just how
+badly RCU wants this quiescent state. This flag is checked by RCU's
+context-switch path (``rcu_note_context_switch``) and the cond_resched
+code.
+
++-----------------------------------------------------------------------+
+| **Quick Quiz**: |
++-----------------------------------------------------------------------+
+| Why not simply combine the ``->dynticks_nesting`` and |
+| ``->dynticks_nmi_nesting`` counters into a single counter that just |
+| counts the number of reasons that the corresponding CPU is non-idle? |
++-----------------------------------------------------------------------+
+| **Answer**: |
++-----------------------------------------------------------------------+
+| Because this would fail in the presence of interrupts whose handlers |
+| never return and of handlers that manage to return from a made-up |
+| interrupt. |
++-----------------------------------------------------------------------+
+
+Additional fields are present for some special-purpose builds, and are
+discussed separately.
+
+The ``rcu_head`` Structure
+~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Each ``rcu_head`` structure represents an RCU callback. These structures
+are normally embedded within RCU-protected data structures whose
+algorithms use asynchronous grace periods. In contrast, when using
+algorithms that block waiting for RCU grace periods, RCU users need not
+provide ``rcu_head`` structures.
+
+The ``rcu_head`` structure has fields as follows:
+
+::
+
+ 1 struct rcu_head *next;
+ 2 void (*func)(struct rcu_head *head);
+
+The ``->next`` field is used to link the ``rcu_head`` structures
+together in the lists within the ``rcu_data`` structures. The ``->func``
+field is a pointer to the function to be called when the callback is
+ready to be invoked, and this function is passed a pointer to the
+``rcu_head`` structure. However, ``kfree_rcu()`` uses the ``->func``
+field to record the offset of the ``rcu_head`` structure within the
+enclosing RCU-protected data structure.
+
+Both of these fields are used internally by RCU. From the viewpoint of
+RCU users, this structure is an opaque “cookie”.
+
++-----------------------------------------------------------------------+
+| **Quick Quiz**: |
++-----------------------------------------------------------------------+
+| Given that the callback function ``->func`` is passed a pointer to |
+| the ``rcu_head`` structure, how is that function supposed to find the |
+| beginning of the enclosing RCU-protected data structure? |
++-----------------------------------------------------------------------+
+| **Answer**: |
++-----------------------------------------------------------------------+
+| In actual practice, there is a separate callback function per type of |
+| RCU-protected data structure. The callback function can therefore use |
+| the ``container_of()`` macro in the Linux kernel (or other |
+| pointer-manipulation facilities in other software environments) to |
+| find the beginning of the enclosing structure. |
++-----------------------------------------------------------------------+
+
+RCU-Specific Fields in the ``task_struct`` Structure
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The ``CONFIG_PREEMPT_RCU`` implementation uses some additional fields in
+the ``task_struct`` structure:
+
+::
+
+ 1 #ifdef CONFIG_PREEMPT_RCU
+ 2 int rcu_read_lock_nesting;
+ 3 union rcu_special rcu_read_unlock_special;
+ 4 struct list_head rcu_node_entry;
+ 5 struct rcu_node *rcu_blocked_node;
+ 6 #endif /* #ifdef CONFIG_PREEMPT_RCU */
+ 7 #ifdef CONFIG_TASKS_RCU
+ 8 unsigned long rcu_tasks_nvcsw;
+ 9 bool rcu_tasks_holdout;
+ 10 struct list_head rcu_tasks_holdout_list;
+ 11 int rcu_tasks_idle_cpu;
+ 12 #endif /* #ifdef CONFIG_TASKS_RCU */
+
+The ``->rcu_read_lock_nesting`` field records the nesting level for RCU
+read-side critical sections, and the ``->rcu_read_unlock_special`` field
+is a bitmask that records special conditions that require
+``rcu_read_unlock()`` to do additional work. The ``->rcu_node_entry``
+field is used to form lists of tasks that have blocked within
+preemptible-RCU read-side critical sections and the
+``->rcu_blocked_node`` field references the ``rcu_node`` structure whose
+list this task is a member of, or ``NULL`` if it is not blocked within a
+preemptible-RCU read-side critical section.
+
+The ``->rcu_tasks_nvcsw`` field tracks the number of voluntary context
+switches that this task had undergone at the beginning of the current
+tasks-RCU grace period, ``->rcu_tasks_holdout`` is set if the current
+tasks-RCU grace period is waiting on this task,
+``->rcu_tasks_holdout_list`` is a list element enqueuing this task on
+the holdout list, and ``->rcu_tasks_idle_cpu`` tracks which CPU this
+idle task is running, but only if the task is currently running, that
+is, if the CPU is currently idle.
+
+Accessor Functions
+~~~~~~~~~~~~~~~~~~
+
+The following listing shows the ``rcu_get_root()``,
+``rcu_for_each_node_breadth_first`` and ``rcu_for_each_leaf_node()``
+function and macros:
+
+::
+
+ 1 static struct rcu_node *rcu_get_root(struct rcu_state *rsp)
+ 2 {
+ 3 return &rsp->node[0];
+ 4 }
+ 5
+ 6 #define rcu_for_each_node_breadth_first(rsp, rnp) \
+ 7 for ((rnp) = &(rsp)->node[0]; \
+ 8 (rnp) < &(rsp)->node[NUM_RCU_NODES]; (rnp)++)
+ 9
+ 10 #define rcu_for_each_leaf_node(rsp, rnp) \
+ 11 for ((rnp) = (rsp)->level[NUM_RCU_LVLS - 1]; \
+ 12 (rnp) < &(rsp)->node[NUM_RCU_NODES]; (rnp)++)
+
+The ``rcu_get_root()`` simply returns a pointer to the first element of
+the specified ``rcu_state`` structure's ``->node[]`` array, which is the
+root ``rcu_node`` structure.
+
+As noted earlier, the ``rcu_for_each_node_breadth_first()`` macro takes
+advantage of the layout of the ``rcu_node`` structures in the
+``rcu_state`` structure's ``->node[]`` array, performing a breadth-first
+traversal by simply traversing the array in order. Similarly, the
+``rcu_for_each_leaf_node()`` macro traverses only the last part of the
+array, thus traversing only the leaf ``rcu_node`` structures.
+
++-----------------------------------------------------------------------+
+| **Quick Quiz**: |
++-----------------------------------------------------------------------+
+| What does ``rcu_for_each_leaf_node()`` do if the ``rcu_node`` tree |
+| contains only a single node? |
++-----------------------------------------------------------------------+
+| **Answer**: |
++-----------------------------------------------------------------------+
+| In the single-node case, ``rcu_for_each_leaf_node()`` traverses the |
+| single node. |
++-----------------------------------------------------------------------+
+
+Summary
+~~~~~~~
+
+So the state of RCU is represented by an ``rcu_state`` structure, which
+contains a combining tree of ``rcu_node`` and ``rcu_data`` structures.
+Finally, in ``CONFIG_NO_HZ_IDLE`` kernels, each CPU's dyntick-idle state
+is tracked by dynticks-related fields in the ``rcu_data`` structure. If
+you made it this far, you are well prepared to read the code
+walkthroughs in the other articles in this series.
+
+Acknowledgments
+~~~~~~~~~~~~~~~
+
+I owe thanks to Cyrill Gorcunov, Mathieu Desnoyers, Dhaval Giani, Paul
+Turner, Abhishek Srivastava, Matt Kowalczyk, and Serge Hallyn for
+helping me get this document into a more human-readable state.
+
+Legal Statement
+~~~~~~~~~~~~~~~
+
+This work represents the view of the author and does not necessarily
+represent the view of IBM.
+
+Linux is a registered trademark of Linus Torvalds.
+
+Other company, product, and service names may be trademarks or service
+marks of others.