[linux-2.6-block.git] / Documentation / local_ops.txt

	     Semantics and Behavior of Local Atomic Operations

			    Mathieu Desnoyers


	This document explains the purpose of the local atomic operations, how
to implement them for any given architecture and shows how they can be used
properly. It also stresses on the precautions that must be taken when reading
those local variables across CPUs when the order of memory writes matters.

Note that local_t based operations are not recommended for general kernel use.
Please use the this_cpu operations instead unless there is really a special purpose.
Most uses of local_t in the kernel have been replaced by this_cpu operations.
this_cpu operations combine the relocation with the local_t like semantics in
a single instruction and yield more compact and faster executing code.


* Purpose of local atomic operations

Local atomic operations are meant to provide fast and highly reentrant per CPU
counters. They minimize the performance cost of standard atomic operations by
removing the LOCK prefix and memory barriers normally required to synchronize
across CPUs.

Having fast per CPU atomic counters is interesting in many cases : it does not
require disabling interrupts to protect from interrupt handlers and it permits
coherent counters in NMI handlers. It is especially useful for tracing purposes
and for various performance monitoring counters.

Local atomic operations only guarantee variable modification atomicity wrt the
CPU which owns the data. Therefore, care must taken to make sure that only one
CPU writes to the local_t data. This is done by using per cpu data and making
sure that we modify it from within a preemption safe context. It is however
permitted to read local_t data from any CPU : it will then appear to be written
out of order wrt other memory writes by the owner CPU.


* Implementation for a given architecture

It can be done by slightly modifying the standard atomic operations : only
their UP variant must be kept. It typically means removing LOCK prefix (on
i386 and x86_64) and any SMP synchronization barrier. If the architecture does
not have a different behavior between SMP and UP, including asm-generic/local.h
in your architecture's local.h is sufficient.

The local_t type is defined as an opaque signed long by embedding an
atomic_long_t inside a structure. This is made so a cast from this type to a
long fails. The definition looks like :

typedef struct { atomic_long_t a; } local_t;


* Rules to follow when using local atomic operations

- Variables touched by local ops must be per cpu variables.
- _Only_ the CPU owner of these variables must write to them.
- This CPU can use local ops from any context (process, irq, softirq, nmi, ...)
  to update its local_t variables.
- Preemption (or interrupts) must be disabled when using local ops in
  process context to   make sure the process won't be migrated to a
  different CPU between getting the per-cpu variable and doing the
  actual local op.
- When using local ops in interrupt context, no special care must be
  taken on a mainline kernel, since they will run on the local CPU with
  preemption already disabled. I suggest, however, to explicitly
  disable preemption anyway to make sure it will still work correctly on
  -rt kernels.
- Reading the local cpu variable will provide the current copy of the
  variable.
- Reads of these variables can be done from any CPU, because updates to
  "long", aligned, variables are always atomic. Since no memory
  synchronization is done by the writer CPU, an outdated copy of the
  variable can be read when reading some _other_ cpu's variables.


* How to use local atomic operations

#include <linux/percpu.h>
#include <asm/local.h>

static DEFINE_PER_CPU(local_t, counters) = LOCAL_INIT(0);


* Counting

Counting is done on all the bits of a signed long.

In preemptible context, use get_cpu_var() and put_cpu_var() around local atomic
operations : it makes sure that preemption is disabled around write access to
the per cpu variable. For instance :

	local_inc(&get_cpu_var(counters));
	put_cpu_var(counters);

If you are already in a preemption-safe context, you can use
this_cpu_ptr() instead.

	local_inc(this_cpu_ptr(&counters));


* Reading the counters

Those local counters can be read from foreign CPUs to sum the count. Note that
the data seen by local_read across CPUs must be considered to be out of order
relatively to other memory writes happening on the CPU that owns the data.

	long sum = 0;
	for_each_online_cpu(cpu)
		sum += local_read(&per_cpu(counters, cpu));

If you want to use a remote local_read to synchronize access to a resource
between CPUs, explicit smp_wmb() and smp_rmb() memory barriers must be used
respectively on the writer and the reader CPUs. It would be the case if you use
the local_t variable as a counter of bytes written in a buffer : there should
be a smp_wmb() between the buffer write and the counter increment and also a
smp_rmb() between the counter read and the buffer read.


Here is a sample module which implements a basic per cpu counter using local.h.

--- BEGIN ---
/* test-local.c
 *
 * Sample module for local.h usage.
 */


#include <asm/local.h>
#include <linux/module.h>
#include <linux/timer.h>

static DEFINE_PER_CPU(local_t, counters) = LOCAL_INIT(0);

static struct timer_list test_timer;

/* IPI called on each CPU. */
static void test_each(void *info)
{
	/* Increment the counter from a non preemptible context */
	printk("Increment on cpu %d\n", smp_processor_id());
	local_inc(this_cpu_ptr(&counters));

	/* This is what incrementing the variable would look like within a
	 * preemptible context (it disables preemption) :
	 *
	 * local_inc(&get_cpu_var(counters));
	 * put_cpu_var(counters);
	 */
}

static void do_test_timer(unsigned long data)
{
	int cpu;

	/* Increment the counters */
	on_each_cpu(test_each, NULL, 1);
	/* Read all the counters */
	printk("Counters read from CPU %d\n", smp_processor_id());
	for_each_online_cpu(cpu) {
		printk("Read : CPU %d, count %ld\n", cpu,
			local_read(&per_cpu(counters, cpu)));
	}
	del_timer(&test_timer);
	test_timer.expires = jiffies + 1000;
	add_timer(&test_timer);
}

static int __init test_init(void)
{
	/* initialize the timer that will increment the counter */
	init_timer(&test_timer);
	test_timer.function = do_test_timer;
	test_timer.expires = jiffies + 1;
	add_timer(&test_timer);

	return 0;
}

static void __exit test_exit(void)
{
	del_timer_sync(&test_timer);
}

module_init(test_init);
module_exit(test_exit);

MODULE_LICENSE("GPL");
MODULE_AUTHOR("Mathieu Desnoyers");
MODULE_DESCRIPTION("Local Atomic Ops");
--- END ---
Commit	Line	Data
f1f8810c MD	1	Semantics and Behavior of Local Atomic Operations
	2
	3	Mathieu Desnoyers
	4
	5
	6	This document explains the purpose of the local atomic operations, how
	7	to implement them for any given architecture and shows how they can be used
	8	properly. It also stresses on the precautions that must be taken when reading
	9	those local variables across CPUs when the order of memory writes matters.
	10
7d94a82e CL	11	Note that local_t based operations are not recommended for general kernel use.
	12	Please use the this_cpu operations instead unless there is really a special purpose.
	13	Most uses of local_t in the kernel have been replaced by this_cpu operations.
	14	this_cpu operations combine the relocation with the local_t like semantics in
	15	a single instruction and yield more compact and faster executing code.
f1f8810c MD	16
	17
	18	* Purpose of local atomic operations
	19
	20	Local atomic operations are meant to provide fast and highly reentrant per CPU
	21	counters. They minimize the performance cost of standard atomic operations by
	22	removing the LOCK prefix and memory barriers normally required to synchronize
	23	across CPUs.
	24
	25	Having fast per CPU atomic counters is interesting in many cases : it does not
	26	require disabling interrupts to protect from interrupt handlers and it permits
	27	coherent counters in NMI handlers. It is especially useful for tracing purposes
	28	and for various performance monitoring counters.
	29
	30	Local atomic operations only guarantee variable modification atomicity wrt the
	31	CPU which owns the data. Therefore, care must taken to make sure that only one
	32	CPU writes to the local_t data. This is done by using per cpu data and making
	33	sure that we modify it from within a preemption safe context. It is however
	34	permitted to read local_t data from any CPU : it will then appear to be written
0e1ccb96	35	out of order wrt other memory writes by the owner CPU.
f1f8810c MD	36
	37
	38	* Implementation for a given architecture
	39
	40	It can be done by slightly modifying the standard atomic operations : only
	41	their UP variant must be kept. It typically means removing LOCK prefix (on
19f59460	42	i386 and x86_64) and any SMP synchronization barrier. If the architecture does
f1f8810c	43	not have a different behavior between SMP and UP, including asm-generic/local.h
d9195881	44	in your architecture's local.h is sufficient.
f1f8810c MD	45
	46	The local_t type is defined as an opaque signed long by embedding an
	47	atomic_long_t inside a structure. This is made so a cast from this type to a
	48	long fails. The definition looks like :
	49
	50	typedef struct { atomic_long_t a; } local_t;
	51
	52
74beb9db MD	53	* Rules to follow when using local atomic operations
	54
	55	- Variables touched by local ops must be per cpu variables.
	56	- _Only_ the CPU owner of these variables must write to them.
	57	- This CPU can use local ops from any context (process, irq, softirq, nmi, ...)
	58	to update its local_t variables.
	59	- Preemption (or interrupts) must be disabled when using local ops in
	60	process context to make sure the process won't be migrated to a
	61	different CPU between getting the per-cpu variable and doing the
	62	actual local op.
	63	- When using local ops in interrupt context, no special care must be
	64	taken on a mainline kernel, since they will run on the local CPU with
	65	preemption already disabled. I suggest, however, to explicitly
	66	disable preemption anyway to make sure it will still work correctly on
	67	-rt kernels.
	68	- Reading the local cpu variable will provide the current copy of the
	69	variable.
	70	- Reads of these variables can be done from any CPU, because updates to
	71	"long", aligned, variables are always atomic. Since no memory
	72	synchronization is done by the writer CPU, an outdated copy of the
	73	variable can be read when reading some _other_ cpu's variables.
	74
	75
f1f8810c MD	76	* How to use local atomic operations
	77
	78	#include <linux/percpu.h>
	79	#include <asm/local.h>
	80
	81	static DEFINE_PER_CPU(local_t, counters) = LOCAL_INIT(0);
	82
	83
	84	* Counting
	85
	86	Counting is done on all the bits of a signed long.
	87
	88	In preemptible context, use get_cpu_var() and put_cpu_var() around local atomic
	89	operations : it makes sure that preemption is disabled around write access to
	90	the per cpu variable. For instance :
	91
	92	local_inc(&get_cpu_var(counters));
	93	put_cpu_var(counters);
	94
7d94a82e CL	95	If you are already in a preemption-safe context, you can use
7d94a82e CL	96	this_cpu_ptr() instead.
f1f8810c	97
7d94a82e	98	local_inc(this_cpu_ptr(&counters));
f1f8810c MD	99
	100
	101
	102	* Reading the counters
	103
	104	Those local counters can be read from foreign CPUs to sum the count. Note that
	105	the data seen by local_read across CPUs must be considered to be out of order
	106	relatively to other memory writes happening on the CPU that owns the data.
	107
	108	long sum = 0;
	109	for_each_online_cpu(cpu)
	110	sum += local_read(&per_cpu(counters, cpu));
	111
	112	If you want to use a remote local_read to synchronize access to a resource
	113	between CPUs, explicit smp_wmb() and smp_rmb() memory barriers must be used
	114	respectively on the writer and the reader CPUs. It would be the case if you use
	115	the local_t variable as a counter of bytes written in a buffer : there should
	116	be a smp_wmb() between the buffer write and the counter increment and also a
	117	smp_rmb() between the counter read and the buffer read.
	118
	119
	120	Here is a sample module which implements a basic per cpu counter using local.h.
	121
	122	--- BEGIN ---
	123	/* test-local.c
	124	*
	125	* Sample module for local.h usage.
	126	*/
	127
	128
	129	#include <asm/local.h>
	130	#include <linux/module.h>
	131	#include <linux/timer.h>
	132
	133	static DEFINE_PER_CPU(local_t, counters) = LOCAL_INIT(0);
	134
	135	static struct timer_list test_timer;
	136
	137	/* IPI called on each CPU. */
	138	static void test_each(void *info)
	139	{
	140	/* Increment the counter from a non preemptible context */
	141	printk("Increment on cpu %d\n", smp_processor_id());
7d94a82e	142	local_inc(this_cpu_ptr(&counters));
f1f8810c MD	143
	144	/* This is what incrementing the variable would look like within a
	145	* preemptible context (it disables preemption) :
	146	*
	147	* local_inc(&get_cpu_var(counters));
	148	* put_cpu_var(counters);
	149	*/
	150	}
	151
	152	static void do_test_timer(unsigned long data)
	153	{
	154	int cpu;
	155
	156	/* Increment the counters */
02d43b1d	157	on_each_cpu(test_each, NULL, 1);
f1f8810c MD	158	/* Read all the counters */
	159	printk("Counters read from CPU %d\n", smp_processor_id());
	160	for_each_online_cpu(cpu) {
	161	printk("Read : CPU %d, count %ld\n", cpu,
	162	local_read(&per_cpu(counters, cpu)));
	163	}
	164	del_timer(&test_timer);
	165	test_timer.expires = jiffies + 1000;
	166	add_timer(&test_timer);
	167	}
	168
	169	static int __init test_init(void)
	170	{
	171	/* initialize the timer that will increment the counter */
	172	init_timer(&test_timer);
	173	test_timer.function = do_test_timer;
	174	test_timer.expires = jiffies + 1;
	175	add_timer(&test_timer);
	176
	177	return 0;
	178	}
	179
	180	static void __exit test_exit(void)
	181	{
	182	del_timer_sync(&test_timer);
	183	}
	184
	185	module_init(test_init);
	186	module_exit(test_exit);
	187
	188	MODULE_LICENSE("GPL");
	189	MODULE_AUTHOR("Mathieu Desnoyers");
	190	MODULE_DESCRIPTION("Local Atomic Ops");
	191	--- END ---