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flow.c
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flow.c
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#include "fio.h"
#include "fio_sem.h"
#include "smalloc.h"
#include "flist.h"
struct fio_flow {
unsigned int refs;
unsigned int id;
struct flist_head list;
unsigned long flow_counter;
unsigned int total_weight;
};
static struct flist_head *flow_list;
static struct fio_sem *flow_lock;
int flow_threshold_exceeded(struct thread_data *td)
{
struct fio_flow *flow = td->flow;
double flow_counter_ratio, flow_weight_ratio;
if (!flow)
return 0;
flow_counter_ratio = (double)td->flow_counter /
atomic_load_relaxed(&flow->flow_counter);
flow_weight_ratio = (double)td->o.flow /
atomic_load_relaxed(&flow->total_weight);
/*
* each thread/process executing a fio job will stall based on the
* expected user ratio for a given flow_id group. the idea is to keep
* 2 counters, flow and job-specific counter to test if the
* ratio between them is proportional to other jobs in the same flow_id
*/
if (flow_counter_ratio > flow_weight_ratio) {
if (td->o.flow_sleep) {
io_u_quiesce(td);
usleep(td->o.flow_sleep);
} else if (td->o.zone_mode == ZONE_MODE_ZBD) {
io_u_quiesce(td);
}
return 1;
}
/*
* increment flow(shared counter, therefore atomically)
* and job-specific counter
*/
atomic_add(&flow->flow_counter, 1);
++td->flow_counter;
return 0;
}
static struct fio_flow *flow_get(unsigned int id)
{
struct fio_flow *flow = NULL;
struct flist_head *n;
if (!flow_lock)
return NULL;
fio_sem_down(flow_lock);
flist_for_each(n, flow_list) {
flow = flist_entry(n, struct fio_flow, list);
if (flow->id == id)
break;
flow = NULL;
}
if (!flow) {
flow = smalloc(sizeof(*flow));
if (!flow) {
fio_sem_up(flow_lock);
return NULL;
}
flow->refs = 0;
INIT_FLIST_HEAD(&flow->list);
flow->id = id;
flow->flow_counter = 1;
flow->total_weight = 0;
flist_add_tail(&flow->list, flow_list);
}
flow->refs++;
fio_sem_up(flow_lock);
return flow;
}
static void flow_put(struct fio_flow *flow, unsigned long flow_counter,
unsigned int weight)
{
if (!flow_lock)
return;
fio_sem_down(flow_lock);
atomic_sub(&flow->flow_counter, flow_counter);
atomic_sub(&flow->total_weight, weight);
if (!--flow->refs) {
assert(flow->flow_counter == 1);
flist_del(&flow->list);
sfree(flow);
}
fio_sem_up(flow_lock);
}
void flow_init_job(struct thread_data *td)
{
if (td->o.flow) {
td->flow = flow_get(td->o.flow_id);
td->flow_counter = 0;
atomic_add(&td->flow->total_weight, td->o.flow);
}
}
void flow_exit_job(struct thread_data *td)
{
if (td->flow) {
flow_put(td->flow, td->flow_counter, td->o.flow);
td->flow = NULL;
}
}
void flow_init(void)
{
flow_list = smalloc(sizeof(*flow_list));
if (!flow_list) {
log_err("fio: smalloc pool exhausted\n");
return;
}
flow_lock = fio_sem_init(FIO_SEM_UNLOCKED);
if (!flow_lock) {
log_err("fio: failed to allocate flow lock\n");
sfree(flow_list);
return;
}
INIT_FLIST_HEAD(flow_list);
}
void flow_exit(void)
{
if (flow_lock)
fio_sem_remove(flow_lock);
if (flow_list)
sfree(flow_list);
}