[linux-2.6-block.git] / kernel / sched / loadavg.c

/*
 * kernel/sched/loadavg.c
 *
 * This file contains the magic bits required to compute the global loadavg
 * figure. Its a silly number but people think its important. We go through
 * great pains to make it work on big machines and tickless kernels.
 */

#include <linux/export.h>

#include "sched.h"

/*
 * Global load-average calculations
 *
 * We take a distributed and async approach to calculating the global load-avg
 * in order to minimize overhead.
 *
 * The global load average is an exponentially decaying average of nr_running +
 * nr_uninterruptible.
 *
 * Once every LOAD_FREQ:
 *
 *   nr_active = 0;
 *   for_each_possible_cpu(cpu)
 *	nr_active += cpu_of(cpu)->nr_running + cpu_of(cpu)->nr_uninterruptible;
 *
 *   avenrun[n] = avenrun[0] * exp_n + nr_active * (1 - exp_n)
 *
 * Due to a number of reasons the above turns in the mess below:
 *
 *  - for_each_possible_cpu() is prohibitively expensive on machines with
 *    serious number of cpus, therefore we need to take a distributed approach
 *    to calculating nr_active.
 *
 *        \Sum_i x_i(t) = \Sum_i x_i(t) - x_i(t_0) | x_i(t_0) := 0
 *                      = \Sum_i { \Sum_j=1 x_i(t_j) - x_i(t_j-1) }
 *
 *    So assuming nr_active := 0 when we start out -- true per definition, we
 *    can simply take per-cpu deltas and fold those into a global accumulate
 *    to obtain the same result. See calc_load_fold_active().
 *
 *    Furthermore, in order to avoid synchronizing all per-cpu delta folding
 *    across the machine, we assume 10 ticks is sufficient time for every
 *    cpu to have completed this task.
 *
 *    This places an upper-bound on the IRQ-off latency of the machine. Then
 *    again, being late doesn't loose the delta, just wrecks the sample.
 *
 *  - cpu_rq()->nr_uninterruptible isn't accurately tracked per-cpu because
 *    this would add another cross-cpu cacheline miss and atomic operation
 *    to the wakeup path. Instead we increment on whatever cpu the task ran
 *    when it went into uninterruptible state and decrement on whatever cpu
 *    did the wakeup. This means that only the sum of nr_uninterruptible over
 *    all cpus yields the correct result.
 *
 *  This covers the NO_HZ=n code, for extra head-aches, see the comment below.
 */

/* Variables and functions for calc_load */
atomic_long_t calc_load_tasks;
unsigned long calc_load_update;
unsigned long avenrun[3];
EXPORT_SYMBOL(avenrun); /* should be removed */

/**
 * get_avenrun - get the load average array
 * @loads:	pointer to dest load array
 * @offset:	offset to add
 * @shift:	shift count to shift the result left
 *
 * These values are estimates at best, so no need for locking.
 */
void get_avenrun(unsigned long *loads, unsigned long offset, int shift)
{
	loads[0] = (avenrun[0] + offset) << shift;
	loads[1] = (avenrun[1] + offset) << shift;
	loads[2] = (avenrun[2] + offset) << shift;
}

long calc_load_fold_active(struct rq *this_rq)
{
	long nr_active, delta = 0;

	nr_active = this_rq->nr_running;
	nr_active += (long)this_rq->nr_uninterruptible;

	if (nr_active != this_rq->calc_load_active) {
		delta = nr_active - this_rq->calc_load_active;
		this_rq->calc_load_active = nr_active;
	}

	return delta;
}

/*
 * a1 = a0 * e + a * (1 - e)
 */
static unsigned long
calc_load(unsigned long load, unsigned long exp, unsigned long active)
{
	load *= exp;
	load += active * (FIXED_1 - exp);
	load += 1UL << (FSHIFT - 1);
	return load >> FSHIFT;
}

#ifdef CONFIG_NO_HZ_COMMON
/*
 * Handle NO_HZ for the global load-average.
 *
 * Since the above described distributed algorithm to compute the global
 * load-average relies on per-cpu sampling from the tick, it is affected by
 * NO_HZ.
 *
 * The basic idea is to fold the nr_active delta into a global idle-delta upon
 * entering NO_HZ state such that we can include this as an 'extra' cpu delta
 * when we read the global state.
 *
 * Obviously reality has to ruin such a delightfully simple scheme:
 *
 *  - When we go NO_HZ idle during the window, we can negate our sample
 *    contribution, causing under-accounting.
 *
 *    We avoid this by keeping two idle-delta counters and flipping them
 *    when the window starts, thus separating old and new NO_HZ load.
 *
 *    The only trick is the slight shift in index flip for read vs write.
 *
 *        0s            5s            10s           15s
 *          +10           +10           +10           +10
 *        |-|-----------|-|-----------|-|-----------|-|
 *    r:0 0 1           1 0           0 1           1 0
 *    w:0 1 1           0 0           1 1           0 0
 *
 *    This ensures we'll fold the old idle contribution in this window while
 *    accumlating the new one.
 *
 *  - When we wake up from NO_HZ idle during the window, we push up our
 *    contribution, since we effectively move our sample point to a known
 *    busy state.
 *
 *    This is solved by pushing the window forward, and thus skipping the
 *    sample, for this cpu (effectively using the idle-delta for this cpu which
 *    was in effect at the time the window opened). This also solves the issue
 *    of having to deal with a cpu having been in NOHZ idle for multiple
 *    LOAD_FREQ intervals.
 *
 * When making the ILB scale, we should try to pull this in as well.
 */
static atomic_long_t calc_load_idle[2];
static int calc_load_idx;

static inline int calc_load_write_idx(void)
{
	int idx = calc_load_idx;

	/*
	 * See calc_global_nohz(), if we observe the new index, we also
	 * need to observe the new update time.
	 */
	smp_rmb();

	/*
	 * If the folding window started, make sure we start writing in the
	 * next idle-delta.
	 */
	if (!time_before(jiffies, calc_load_update))
		idx++;

	return idx & 1;
}

static inline int calc_load_read_idx(void)
{
	return calc_load_idx & 1;
}

void calc_load_enter_idle(void)
{
	struct rq *this_rq = this_rq();
	long delta;

	/*
	 * We're going into NOHZ mode, if there's any pending delta, fold it
	 * into the pending idle delta.
	 */
	delta = calc_load_fold_active(this_rq);
	if (delta) {
		int idx = calc_load_write_idx();

		atomic_long_add(delta, &calc_load_idle[idx]);
	}
}

void calc_load_exit_idle(void)
{
	struct rq *this_rq = this_rq();

	/*
	 * If we're still before the sample window, we're done.
	 */
	if (time_before(jiffies, this_rq->calc_load_update))
		return;

	/*
	 * We woke inside or after the sample window, this means we're already
	 * accounted through the nohz accounting, so skip the entire deal and
	 * sync up for the next window.
	 */
	this_rq->calc_load_update = calc_load_update;
	if (time_before(jiffies, this_rq->calc_load_update + 10))
		this_rq->calc_load_update += LOAD_FREQ;
}

static long calc_load_fold_idle(void)
{
	int idx = calc_load_read_idx();
	long delta = 0;

	if (atomic_long_read(&calc_load_idle[idx]))
		delta = atomic_long_xchg(&calc_load_idle[idx], 0);

	return delta;
}

/**
 * fixed_power_int - compute: x^n, in O(log n) time
 *
 * @x:         base of the power
 * @frac_bits: fractional bits of @x
 * @n:         power to raise @x to.
 *
 * By exploiting the relation between the definition of the natural power
 * function: x^n := x*x*...*x (x multiplied by itself for n times), and
 * the binary encoding of numbers used by computers: n := \Sum n_i * 2^i,
 * (where: n_i \elem {0, 1}, the binary vector representing n),
 * we find: x^n := x^(\Sum n_i * 2^i) := \Prod x^(n_i * 2^i), which is
 * of course trivially computable in O(log_2 n), the length of our binary
 * vector.
 */
static unsigned long
fixed_power_int(unsigned long x, unsigned int frac_bits, unsigned int n)
{
	unsigned long result = 1UL << frac_bits;

	if (n) {
		for (;;) {
			if (n & 1) {
				result *= x;
				result += 1UL << (frac_bits - 1);
				result >>= frac_bits;
			}
			n >>= 1;
			if (!n)
				break;
			x *= x;
			x += 1UL << (frac_bits - 1);
			x >>= frac_bits;
		}
	}

	return result;
}

/*
 * a1 = a0 * e + a * (1 - e)
 *
 * a2 = a1 * e + a * (1 - e)
 *    = (a0 * e + a * (1 - e)) * e + a * (1 - e)
 *    = a0 * e^2 + a * (1 - e) * (1 + e)
 *
 * a3 = a2 * e + a * (1 - e)
 *    = (a0 * e^2 + a * (1 - e) * (1 + e)) * e + a * (1 - e)
 *    = a0 * e^3 + a * (1 - e) * (1 + e + e^2)
 *
 *  ...
 *
 * an = a0 * e^n + a * (1 - e) * (1 + e + ... + e^n-1) [1]
 *    = a0 * e^n + a * (1 - e) * (1 - e^n)/(1 - e)
 *    = a0 * e^n + a * (1 - e^n)
 *
 * [1] application of the geometric series:
 *
 *              n         1 - x^(n+1)
 *     S_n := \Sum x^i = -------------
 *             i=0          1 - x
 */
static unsigned long
calc_load_n(unsigned long load, unsigned long exp,
	    unsigned long active, unsigned int n)
{
	return calc_load(load, fixed_power_int(exp, FSHIFT, n), active);
}

/*
 * NO_HZ can leave us missing all per-cpu ticks calling
 * calc_load_account_active(), but since an idle CPU folds its delta into
 * calc_load_tasks_idle per calc_load_account_idle(), all we need to do is fold
 * in the pending idle delta if our idle period crossed a load cycle boundary.
 *
 * Once we've updated the global active value, we need to apply the exponential
 * weights adjusted to the number of cycles missed.
 */
static void calc_global_nohz(void)
{
	long delta, active, n;

	if (!time_before(jiffies, calc_load_update + 10)) {
		/*
		 * Catch-up, fold however many we are behind still
		 */
		delta = jiffies - calc_load_update - 10;
		n = 1 + (delta / LOAD_FREQ);

		active = atomic_long_read(&calc_load_tasks);
		active = active > 0 ? active * FIXED_1 : 0;

		avenrun[0] = calc_load_n(avenrun[0], EXP_1, active, n);
		avenrun[1] = calc_load_n(avenrun[1], EXP_5, active, n);
		avenrun[2] = calc_load_n(avenrun[2], EXP_15, active, n);

		calc_load_update += n * LOAD_FREQ;
	}

	/*
	 * Flip the idle index...
	 *
	 * Make sure we first write the new time then flip the index, so that
	 * calc_load_write_idx() will see the new time when it reads the new
	 * index, this avoids a double flip messing things up.
	 */
	smp_wmb();
	calc_load_idx++;
}
#else /* !CONFIG_NO_HZ_COMMON */

static inline long calc_load_fold_idle(void) { return 0; }
static inline void calc_global_nohz(void) { }

#endif /* CONFIG_NO_HZ_COMMON */

/*
 * calc_load - update the avenrun load estimates 10 ticks after the
 * CPUs have updated calc_load_tasks.
 *
 * Called from the global timer code.
 */
void calc_global_load(unsigned long ticks)
{
	long active, delta;

	if (time_before(jiffies, calc_load_update + 10))
		return;

	/*
	 * Fold the 'old' idle-delta to include all NO_HZ cpus.
	 */
	delta = calc_load_fold_idle();
	if (delta)
		atomic_long_add(delta, &calc_load_tasks);

	active = atomic_long_read(&calc_load_tasks);
	active = active > 0 ? active * FIXED_1 : 0;

	avenrun[0] = calc_load(avenrun[0], EXP_1, active);
	avenrun[1] = calc_load(avenrun[1], EXP_5, active);
	avenrun[2] = calc_load(avenrun[2], EXP_15, active);

	calc_load_update += LOAD_FREQ;

	/*
	 * In case we idled for multiple LOAD_FREQ intervals, catch up in bulk.
	 */
	calc_global_nohz();
}

/*
 * Called from scheduler_tick() to periodically update this CPU's
 * active count.
 */
void calc_global_load_tick(struct rq *this_rq)
{
	long delta;

	if (time_before(jiffies, this_rq->calc_load_update))
		return;

	delta  = calc_load_fold_active(this_rq);
	if (delta)
		atomic_long_add(delta, &calc_load_tasks);

	this_rq->calc_load_update += LOAD_FREQ;
}
Commit	Line	Data
45ceebf7	1	/*
3289bdb4	2	* kernel/sched/loadavg.c
45ceebf7	3	*
3289bdb4 PZ	4	* This file contains the magic bits required to compute the global loadavg
	5	* figure. Its a silly number but people think its important. We go through
	6	* great pains to make it work on big machines and tickless kernels.
45ceebf7 PG	7	*/
	8
	9	#include <linux/export.h>
	10
	11	#include "sched.h"
	12
45ceebf7 PG	13	/*
	14	* Global load-average calculations
	15	*
	16	* We take a distributed and async approach to calculating the global load-avg
	17	* in order to minimize overhead.
	18	*
	19	* The global load average is an exponentially decaying average of nr_running +
	20	* nr_uninterruptible.
	21	*
	22	* Once every LOAD_FREQ:
	23	*
	24	* nr_active = 0;
	25	* for_each_possible_cpu(cpu)
	26	* nr_active += cpu_of(cpu)->nr_running + cpu_of(cpu)->nr_uninterruptible;
	27	*
	28	* avenrun[n] = avenrun[0] * exp_n + nr_active * (1 - exp_n)
	29	*
	30	* Due to a number of reasons the above turns in the mess below:
	31	*
	32	* - for_each_possible_cpu() is prohibitively expensive on machines with
	33	* serious number of cpus, therefore we need to take a distributed approach
	34	* to calculating nr_active.
	35	*
	36	* \Sum_i x_i(t) = \Sum_i x_i(t) - x_i(t_0) \| x_i(t_0) := 0
	37	* = \Sum_i { \Sum_j=1 x_i(t_j) - x_i(t_j-1) }
	38	*
	39	* So assuming nr_active := 0 when we start out -- true per definition, we
	40	* can simply take per-cpu deltas and fold those into a global accumulate
	41	* to obtain the same result. See calc_load_fold_active().
	42	*
	43	* Furthermore, in order to avoid synchronizing all per-cpu delta folding
	44	* across the machine, we assume 10 ticks is sufficient time for every
	45	* cpu to have completed this task.
	46	*
	47	* This places an upper-bound on the IRQ-off latency of the machine. Then
	48	* again, being late doesn't loose the delta, just wrecks the sample.
	49	*
	50	* - cpu_rq()->nr_uninterruptible isn't accurately tracked per-cpu because
	51	* this would add another cross-cpu cacheline miss and atomic operation
	52	* to the wakeup path. Instead we increment on whatever cpu the task ran
	53	* when it went into uninterruptible state and decrement on whatever cpu
	54	* did the wakeup. This means that only the sum of nr_uninterruptible over
	55	* all cpus yields the correct result.
	56	*
	57	* This covers the NO_HZ=n code, for extra head-aches, see the comment below.
	58	*/
	59
	60	/* Variables and functions for calc_load */
	61	atomic_long_t calc_load_tasks;
	62	unsigned long calc_load_update;
	63	unsigned long avenrun[3];
	64	EXPORT_SYMBOL(avenrun); /* should be removed */
	65
	66	/**
	67	* get_avenrun - get the load average array
	68	* @loads: pointer to dest load array
	69	* @offset: offset to add
	70	* @shift: shift count to shift the result left
	71	*
	72	* These values are estimates at best, so no need for locking.
	73	*/
	74	void get_avenrun(unsigned long *loads, unsigned long offset, int shift)
	75	{
	76	loads[0] = (avenrun[0] + offset) << shift;
77	loads[1] = (avenrun[1] + offset) << shift;
78	loads[2] = (avenrun[2] + offset) << shift;
79	}
80
81	long calc_load_fold_active(struct rq *this_rq)
82	{
83	long nr_active, delta = 0;
84
85	nr_active = this_rq->nr_running;
3289bdb4	86	nr_active += (long)this_rq->nr_uninterruptible;
45ceebf7 PG	87
	88	if (nr_active != this_rq->calc_load_active) {
	89	delta = nr_active - this_rq->calc_load_active;
	90	this_rq->calc_load_active = nr_active;
	91	}
	92
	93	return delta;
	94	}
	95
	96	/*
	97	* a1 = a0 * e + a * (1 - e)
	98	*/
	99	static unsigned long
	100	calc_load(unsigned long load, unsigned long exp, unsigned long active)
	101	{
	102	load *= exp;
	103	load += active * (FIXED_1 - exp);
	104	load += 1UL << (FSHIFT - 1);
	105	return load >> FSHIFT;
	106	}
	107
	108	#ifdef CONFIG_NO_HZ_COMMON
	109	/*
	110	* Handle NO_HZ for the global load-average.
	111	*
	112	* Since the above described distributed algorithm to compute the global
	113	* load-average relies on per-cpu sampling from the tick, it is affected by
	114	* NO_HZ.
	115	*
	116	* The basic idea is to fold the nr_active delta into a global idle-delta upon
	117	* entering NO_HZ state such that we can include this as an 'extra' cpu delta
	118	* when we read the global state.
	119	*
	120	* Obviously reality has to ruin such a delightfully simple scheme:
	121	*
	122	* - When we go NO_HZ idle during the window, we can negate our sample
	123	* contribution, causing under-accounting.
	124	*
	125	* We avoid this by keeping two idle-delta counters and flipping them
	126	* when the window starts, thus separating old and new NO_HZ load.
	127	*
	128	* The only trick is the slight shift in index flip for read vs write.
	129	*
	130	* 0s 5s 10s 15s
	131	* +10 +10 +10 +10
	132	* \|-\|-----------\|-\|-----------\|-\|-----------\|-\|
	133	* r:0 0 1 1 0 0 1 1 0
	134	* w:0 1 1 0 0 1 1 0 0
	135	*
	136	* This ensures we'll fold the old idle contribution in this window while
	137	* accumlating the new one.
	138	*
	139	* - When we wake up from NO_HZ idle during the window, we push up our
	140	* contribution, since we effectively move our sample point to a known
	141	* busy state.
	142	*
	143	* This is solved by pushing the window forward, and thus skipping the
	144	* sample, for this cpu (effectively using the idle-delta for this cpu which
	145	* was in effect at the time the window opened). This also solves the issue
	146	* of having to deal with a cpu having been in NOHZ idle for multiple
	147	* LOAD_FREQ intervals.
	148	*
	149	* When making the ILB scale, we should try to pull this in as well.
	150	*/
151	static atomic_long_t calc_load_idle[2];
152	static int calc_load_idx;
153
154	static inline int calc_load_write_idx(void)
155	{
156	int idx = calc_load_idx;
157
158	/*
159	* See calc_global_nohz(), if we observe the new index, we also
160	* need to observe the new update time.
161	*/
162	smp_rmb();
163
164	/*
165	* If the folding window started, make sure we start writing in the
166	* next idle-delta.
167	*/
168	if (!time_before(jiffies, calc_load_update))
169	idx++;
170
171	return idx & 1;
172	}
173
174	static inline int calc_load_read_idx(void)
175	{
176	return calc_load_idx & 1;
177	}
178
179	void calc_load_enter_idle(void)
180	{
181	struct rq *this_rq = this_rq();
182	long delta;
183
184	/*
185	* We're going into NOHZ mode, if there's any pending delta, fold it
186	* into the pending idle delta.
187	*/
188	delta = calc_load_fold_active(this_rq);
189	if (delta) {
190	int idx = calc_load_write_idx();
3289bdb4	191
45ceebf7 PG	192	atomic_long_add(delta, &calc_load_idle[idx]);
	193	}
	194	}
	195
	196	void calc_load_exit_idle(void)
	197	{
	198	struct rq *this_rq = this_rq();
	199
	200	/*
	201	* If we're still before the sample window, we're done.
	202	*/
	203	if (time_before(jiffies, this_rq->calc_load_update))
	204	return;
	205
	206	/*
	207	* We woke inside or after the sample window, this means we're already
	208	* accounted through the nohz accounting, so skip the entire deal and
	209	* sync up for the next window.
	210	*/
	211	this_rq->calc_load_update = calc_load_update;
	212	if (time_before(jiffies, this_rq->calc_load_update + 10))
	213	this_rq->calc_load_update += LOAD_FREQ;
	214	}
	215
	216	static long calc_load_fold_idle(void)
	217	{
	218	int idx = calc_load_read_idx();
	219	long delta = 0;
	220
	221	if (atomic_long_read(&calc_load_idle[idx]))
	222	delta = atomic_long_xchg(&calc_load_idle[idx], 0);
	223
	224	return delta;
	225	}
	226
	227	/**
	228	* fixed_power_int - compute: x^n, in O(log n) time
	229	*
	230	* @x: base of the power
	231	* @frac_bits: fractional bits of @x
	232	* @n: power to raise @x to.
	233	*
	234	* By exploiting the relation between the definition of the natural power
	235	* function: x^n := xx...*x (x multiplied by itself for n times), and
	236	* the binary encoding of numbers used by computers: n := \Sum n_i * 2^i,
	237	* (where: n_i \elem {0, 1}, the binary vector representing n),
	238	* we find: x^n := x^(\Sum n_i * 2^i) := \Prod x^(n_i * 2^i), which is
	239	* of course trivially computable in O(log_2 n), the length of our binary
	240	* vector.
	241	*/
	242	static unsigned long
	243	fixed_power_int(unsigned long x, unsigned int frac_bits, unsigned int n)
	244	{
	245	unsigned long result = 1UL << frac_bits;
	246
3289bdb4 PZ	247	if (n) {
	248	for (;;) {
	249	if (n & 1) {
	250	result *= x;
	251	result += 1UL << (frac_bits - 1);
	252	result >>= frac_bits;
	253	}
	254	n >>= 1;
	255	if (!n)
	256	break;
	257	x *= x;
	258	x += 1UL << (frac_bits - 1);
	259	x >>= frac_bits;
45ceebf7	260	}
45ceebf7 PG	261	}
	262
	263	return result;
	264	}
	265
	266	/*
	267	* a1 = a0 * e + a * (1 - e)
	268	*
	269	* a2 = a1 * e + a * (1 - e)
	270	* = (a0 * e + a * (1 - e)) * e + a * (1 - e)
	271	* = a0 * e^2 + a * (1 - e) * (1 + e)
	272	*
	273	* a3 = a2 * e + a * (1 - e)
	274	* = (a0 * e^2 + a * (1 - e) * (1 + e)) * e + a * (1 - e)
	275	* = a0 * e^3 + a * (1 - e) * (1 + e + e^2)
	276	*
	277	* ...
	278	*
	279	* an = a0 * e^n + a * (1 - e) * (1 + e + ... + e^n-1) [1]
	280	* = a0 * e^n + a * (1 - e) * (1 - e^n)/(1 - e)
	281	* = a0 * e^n + a * (1 - e^n)
	282	*
	283	* [1] application of the geometric series:
	284	*
	285	* n 1 - x^(n+1)
	286	* S_n := \Sum x^i = -------------
	287	* i=0 1 - x
	288	*/
	289	static unsigned long
	290	calc_load_n(unsigned long load, unsigned long exp,
	291	unsigned long active, unsigned int n)
	292	{
45ceebf7 PG	293	return calc_load(load, fixed_power_int(exp, FSHIFT, n), active);
	294	}
	295
	296	/*
	297	* NO_HZ can leave us missing all per-cpu ticks calling
	298	* calc_load_account_active(), but since an idle CPU folds its delta into
	299	* calc_load_tasks_idle per calc_load_account_idle(), all we need to do is fold
	300	* in the pending idle delta if our idle period crossed a load cycle boundary.
	301	*
	302	* Once we've updated the global active value, we need to apply the exponential
	303	* weights adjusted to the number of cycles missed.
	304	*/
	305	static void calc_global_nohz(void)
	306	{
	307	long delta, active, n;
	308
	309	if (!time_before(jiffies, calc_load_update + 10)) {
	310	/*
	311	* Catch-up, fold however many we are behind still
	312	*/
	313	delta = jiffies - calc_load_update - 10;
	314	n = 1 + (delta / LOAD_FREQ);
	315
	316	active = atomic_long_read(&calc_load_tasks);
	317	active = active > 0 ? active * FIXED_1 : 0;
	318
	319	avenrun[0] = calc_load_n(avenrun[0], EXP_1, active, n);
	320	avenrun[1] = calc_load_n(avenrun[1], EXP_5, active, n);
	321	avenrun[2] = calc_load_n(avenrun[2], EXP_15, active, n);
	322
	323	calc_load_update += n * LOAD_FREQ;
	324	}
	325
	326	/*
	327	* Flip the idle index...
	328	*
	329	* Make sure we first write the new time then flip the index, so that
	330	* calc_load_write_idx() will see the new time when it reads the new
	331	* index, this avoids a double flip messing things up.
	332	*/
	333	smp_wmb();
	334	calc_load_idx++;
	335	}
	336	#else /* !CONFIG_NO_HZ_COMMON */
	337
	338	static inline long calc_load_fold_idle(void) { return 0; }
	339	static inline void calc_global_nohz(void) { }
	340
	341	#endif /* CONFIG_NO_HZ_COMMON */
	342
	343	/*
	344	* calc_load - update the avenrun load estimates 10 ticks after the
	345	* CPUs have updated calc_load_tasks.
3289bdb4 PZ	346	*
3289bdb4 PZ	347	* Called from the global timer code.
45ceebf7 PG	348	*/
	349	void calc_global_load(unsigned long ticks)
	350	{
	351	long active, delta;
	352
	353	if (time_before(jiffies, calc_load_update + 10))
	354	return;
	355
	356	/*
	357	* Fold the 'old' idle-delta to include all NO_HZ cpus.
	358	*/
	359	delta = calc_load_fold_idle();
	360	if (delta)
	361	atomic_long_add(delta, &calc_load_tasks);
	362
	363	active = atomic_long_read(&calc_load_tasks);
	364	active = active > 0 ? active * FIXED_1 : 0;
	365
	366	avenrun[0] = calc_load(avenrun[0], EXP_1, active);
	367	avenrun[1] = calc_load(avenrun[1], EXP_5, active);
	368	avenrun[2] = calc_load(avenrun[2], EXP_15, active);
	369
	370	calc_load_update += LOAD_FREQ;
	371
	372	/*
	373	* In case we idled for multiple LOAD_FREQ intervals, catch up in bulk.
	374	*/
	375	calc_global_nohz();
	376	}
	377
	378	/*
3289bdb4	379	* Called from scheduler_tick() to periodically update this CPU's
45ceebf7 PG	380	* active count.
45ceebf7 PG	381	*/
3289bdb4	382	void calc_global_load_tick(struct rq *this_rq)
45ceebf7 PG	383	{
	384	long delta;
	385
	386	if (time_before(jiffies, this_rq->calc_load_update))
	387	return;
	388
	389	delta = calc_load_fold_active(this_rq);
	390	if (delta)
	391	atomic_long_add(delta, &calc_load_tasks);
	392
	393	this_rq->calc_load_update += LOAD_FREQ;
	394	}