dma-buf: document fd flags and O_CLOEXEC requirement

[linux-2.6.git] / Documentation / mutex-design.txt

Generic Mutex Subsystem

started by Ingo Molnar <mingo@redhat.com>

  "Why on earth do we need a new mutex subsystem, and what's wrong
   with semaphores?"

firstly, there's nothing wrong with semaphores. But if the simpler
mutex semantics are sufficient for your code, then there are a couple
of advantages of mutexes:

 - 'struct mutex' is smaller on most architectures: E.g. on x86,
   'struct semaphore' is 20 bytes, 'struct mutex' is 16 bytes.
   A smaller structure size means less RAM footprint, and better
   CPU-cache utilization.

 - tighter code. On x86 i get the following .text sizes when
   switching all mutex-alike semaphores in the kernel to the mutex
   subsystem:

        text    data     bss     dec     hex filename
     3280380  868188  396860 4545428  455b94 vmlinux-semaphore
     3255329  865296  396732 4517357  44eded vmlinux-mutex

   that's 25051 bytes of code saved, or a 0.76% win - off the hottest
   codepaths of the kernel. (The .data savings are 2892 bytes, or 0.33%)
   Smaller code means better icache footprint, which is one of the
   major optimization goals in the Linux kernel currently.

 - the mutex subsystem is slightly faster and has better scalability for
   contended workloads. On an 8-way x86 system, running a mutex-based
   kernel and testing creat+unlink+close (of separate, per-task files)
   in /tmp with 16 parallel tasks, the average number of ops/sec is:

    Semaphores:                        Mutexes:

    $ ./test-mutex V 16 10             $ ./test-mutex V 16 10
    8 CPUs, running 16 tasks.          8 CPUs, running 16 tasks.
    checking VFS performance.          checking VFS performance.
    avg loops/sec:      34713          avg loops/sec:      84153
    CPU utilization:    63%            CPU utilization:    22%

   i.e. in this workload, the mutex based kernel was 2.4 times faster
   than the semaphore based kernel, _and_ it also had 2.8 times less CPU
   utilization. (In terms of 'ops per CPU cycle', the semaphore kernel
   performed 551 ops/sec per 1% of CPU time used, while the mutex kernel
   performed 3825 ops/sec per 1% of CPU time used - it was 6.9 times
   more efficient.)

   the scalability difference is visible even on a 2-way P4 HT box:

    Semaphores:                        Mutexes:

    $ ./test-mutex V 16 10             $ ./test-mutex V 16 10
    4 CPUs, running 16 tasks.          8 CPUs, running 16 tasks.
    checking VFS performance.          checking VFS performance.
    avg loops/sec:      127659         avg loops/sec:      181082
    CPU utilization:    100%           CPU utilization:    34%

   (the straight performance advantage of mutexes is 41%, the per-cycle
    efficiency of mutexes is 4.1 times better.)

 - there are no fastpath tradeoffs, the mutex fastpath is just as tight
   as the semaphore fastpath. On x86, the locking fastpath is 2
   instructions:

    c0377ccb <mutex_lock>:
    c0377ccb:       f0 ff 08                lock decl (%eax)
    c0377cce:       78 0e                   js     c0377cde <.text..lock.mutex>
    c0377cd0:       c3                      ret

   the unlocking fastpath is equally tight:

    c0377cd1 <mutex_unlock>:
    c0377cd1:       f0 ff 00                lock incl (%eax)
    c0377cd4:       7e 0f                   jle    c0377ce5 <.text..lock.mutex+0x7>
    c0377cd6:       c3                      ret

 - 'struct mutex' semantics are well-defined and are enforced if
   CONFIG_DEBUG_MUTEXES is turned on. Semaphores on the other hand have
   virtually no debugging code or instrumentation. The mutex subsystem
   checks and enforces the following rules:

   * - only one task can hold the mutex at a time
   * - only the owner can unlock the mutex
   * - multiple unlocks are not permitted
   * - recursive locking is not permitted
   * - a mutex object must be initialized via the API
   * - a mutex object must not be initialized via memset or copying
   * - task may not exit with mutex held
   * - memory areas where held locks reside must not be freed
   * - held mutexes must not be reinitialized
   * - mutexes may not be used in hardware or software interrupt
   *   contexts such as tasklets and timers

   furthermore, there are also convenience features in the debugging
   code:

   * - uses symbolic names of mutexes, whenever they are printed in debug output
   * - point-of-acquire tracking, symbolic lookup of function names
   * - list of all locks held in the system, printout of them
   * - owner tracking
   * - detects self-recursing locks and prints out all relevant info
   * - detects multi-task circular deadlocks and prints out all affected
   *   locks and tasks (and only those tasks)

Disadvantages
-------------

The stricter mutex API means you cannot use mutexes the same way you
can use semaphores: e.g. they cannot be used from an interrupt context,
nor can they be unlocked from a different context that which acquired
it. [ I'm not aware of any other (e.g. performance) disadvantages from
using mutexes at the moment, please let me know if you find any. ]

Implementation of mutexes
-------------------------

'struct mutex' is the new mutex type, defined in include/linux/mutex.h
and implemented in kernel/mutex.c. It is a counter-based mutex with a
spinlock and a wait-list. The counter has 3 states: 1 for "unlocked",
0 for "locked" and negative numbers (usually -1) for "locked, potential
waiters queued".

the APIs of 'struct mutex' have been streamlined:

 DEFINE_MUTEX(name);

 mutex_init(mutex);

 void mutex_lock(struct mutex *lock);
 int  mutex_lock_interruptible(struct mutex *lock);
 int  mutex_trylock(struct mutex *lock);
 void mutex_unlock(struct mutex *lock);
 int  mutex_is_locked(struct mutex *lock);
 void mutex_lock_nested(struct mutex *lock, unsigned int subclass);
 int  mutex_lock_interruptible_nested(struct mutex *lock,
                                      unsigned int subclass);
 int atomic_dec_and_mutex_lock(atomic_t *cnt, struct mutex *lock);