Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
wuqiang | 3275 | 100.00% | 2 | 100.00% |
Total | 3275 | 2 |
// SPDX-License-Identifier: GPL-2.0 /* * Test module for lockless object pool * * Copyright: wuqiang.matt@bytedance.com */ #include <linux/errno.h> #include <linux/module.h> #include <linux/moduleparam.h> #include <linux/completion.h> #include <linux/kthread.h> #include <linux/slab.h> #include <linux/vmalloc.h> #include <linux/delay.h> #include <linux/hrtimer.h> #include <linux/objpool.h> #define OT_NR_MAX_BULK (16) /* memory usage */ struct ot_mem_stat { atomic_long_t alloc; atomic_long_t free; }; /* object allocation results */ struct ot_obj_stat { unsigned long nhits; unsigned long nmiss; }; /* control & results per testcase */ struct ot_data { struct rw_semaphore start; struct completion wait; struct completion rcu; atomic_t nthreads ____cacheline_aligned_in_smp; atomic_t stop ____cacheline_aligned_in_smp; struct ot_mem_stat kmalloc; struct ot_mem_stat vmalloc; struct ot_obj_stat objects; u64 duration; }; /* testcase */ struct ot_test { int async; /* synchronous or asynchronous */ int mode; /* only mode 0 supported */ int objsz; /* object size */ int duration; /* ms */ int delay; /* ms */ int bulk_normal; int bulk_irq; unsigned long hrtimer; /* ms */ const char *name; struct ot_data data; }; /* per-cpu worker */ struct ot_item { struct objpool_head *pool; /* pool head */ struct ot_test *test; /* test parameters */ void (*worker)(struct ot_item *item, int irq); /* hrtimer control */ ktime_t hrtcycle; struct hrtimer hrtimer; int bulk[2]; /* for thread and irq */ int delay; u32 niters; /* summary per thread */ struct ot_obj_stat stat[2]; /* thread and irq */ u64 duration; }; /* * memory leakage checking */ static void *ot_kzalloc(struct ot_test *test, long size) { void *ptr = kzalloc(size, GFP_KERNEL); if (ptr) atomic_long_add(size, &test->data.kmalloc.alloc); return ptr; } static void ot_kfree(struct ot_test *test, void *ptr, long size) { if (!ptr) return; atomic_long_add(size, &test->data.kmalloc.free); kfree(ptr); } static void ot_mem_report(struct ot_test *test) { long alloc, free; pr_info("memory allocation summary for %s\n", test->name); alloc = atomic_long_read(&test->data.kmalloc.alloc); free = atomic_long_read(&test->data.kmalloc.free); pr_info(" kmalloc: %lu - %lu = %lu\n", alloc, free, alloc - free); alloc = atomic_long_read(&test->data.vmalloc.alloc); free = atomic_long_read(&test->data.vmalloc.free); pr_info(" vmalloc: %lu - %lu = %lu\n", alloc, free, alloc - free); } /* user object instance */ struct ot_node { void *owner; unsigned long data; unsigned long refs; unsigned long payload[32]; }; /* user objpool manager */ struct ot_context { struct objpool_head pool; /* objpool head */ struct ot_test *test; /* test parameters */ void *ptr; /* user pool buffer */ unsigned long size; /* buffer size */ struct rcu_head rcu; }; static DEFINE_PER_CPU(struct ot_item, ot_pcup_items); static int ot_init_data(struct ot_data *data) { memset(data, 0, sizeof(*data)); init_rwsem(&data->start); init_completion(&data->wait); init_completion(&data->rcu); atomic_set(&data->nthreads, 1); return 0; } static int ot_init_node(void *nod, void *context) { struct ot_context *sop = context; struct ot_node *on = nod; on->owner = &sop->pool; return 0; } static enum hrtimer_restart ot_hrtimer_handler(struct hrtimer *hrt) { struct ot_item *item = container_of(hrt, struct ot_item, hrtimer); struct ot_test *test = item->test; if (atomic_read_acquire(&test->data.stop)) return HRTIMER_NORESTART; /* do bulk-testings for objects pop/push */ item->worker(item, 1); hrtimer_forward(hrt, hrt->base->get_time(), item->hrtcycle); return HRTIMER_RESTART; } static void ot_start_hrtimer(struct ot_item *item) { if (!item->test->hrtimer) return; hrtimer_start(&item->hrtimer, item->hrtcycle, HRTIMER_MODE_REL); } static void ot_stop_hrtimer(struct ot_item *item) { if (!item->test->hrtimer) return; hrtimer_cancel(&item->hrtimer); } static int ot_init_hrtimer(struct ot_item *item, unsigned long hrtimer) { struct hrtimer *hrt = &item->hrtimer; if (!hrtimer) return -ENOENT; item->hrtcycle = ktime_set(0, hrtimer * 1000000UL); hrtimer_init(hrt, CLOCK_MONOTONIC, HRTIMER_MODE_REL); hrt->function = ot_hrtimer_handler; return 0; } static int ot_init_cpu_item(struct ot_item *item, struct ot_test *test, struct objpool_head *pool, void (*worker)(struct ot_item *, int)) { memset(item, 0, sizeof(*item)); item->pool = pool; item->test = test; item->worker = worker; item->bulk[0] = test->bulk_normal; item->bulk[1] = test->bulk_irq; item->delay = test->delay; /* initialize hrtimer */ ot_init_hrtimer(item, item->test->hrtimer); return 0; } static int ot_thread_worker(void *arg) { struct ot_item *item = arg; struct ot_test *test = item->test; ktime_t start; atomic_inc(&test->data.nthreads); down_read(&test->data.start); up_read(&test->data.start); start = ktime_get(); ot_start_hrtimer(item); do { if (atomic_read_acquire(&test->data.stop)) break; /* do bulk-testings for objects pop/push */ item->worker(item, 0); } while (!kthread_should_stop()); ot_stop_hrtimer(item); item->duration = (u64) ktime_us_delta(ktime_get(), start); if (atomic_dec_and_test(&test->data.nthreads)) complete(&test->data.wait); return 0; } static void ot_perf_report(struct ot_test *test, u64 duration) { struct ot_obj_stat total, normal = {0}, irq = {0}; int cpu, nthreads = 0; pr_info("\n"); pr_info("Testing summary for %s\n", test->name); for_each_possible_cpu(cpu) { struct ot_item *item = per_cpu_ptr(&ot_pcup_items, cpu); if (!item->duration) continue; normal.nhits += item->stat[0].nhits; normal.nmiss += item->stat[0].nmiss; irq.nhits += item->stat[1].nhits; irq.nmiss += item->stat[1].nmiss; pr_info("CPU: %d duration: %lluus\n", cpu, item->duration); pr_info("\tthread:\t%16lu hits \t%16lu miss\n", item->stat[0].nhits, item->stat[0].nmiss); pr_info("\tirq: \t%16lu hits \t%16lu miss\n", item->stat[1].nhits, item->stat[1].nmiss); pr_info("\ttotal: \t%16lu hits \t%16lu miss\n", item->stat[0].nhits + item->stat[1].nhits, item->stat[0].nmiss + item->stat[1].nmiss); nthreads++; } total.nhits = normal.nhits + irq.nhits; total.nmiss = normal.nmiss + irq.nmiss; pr_info("ALL: \tnthreads: %d duration: %lluus\n", nthreads, duration); pr_info("SUM: \t%16lu hits \t%16lu miss\n", total.nhits, total.nmiss); test->data.objects = total; test->data.duration = duration; } /* * synchronous test cases for objpool manipulation */ /* objpool manipulation for synchronous mode (percpu objpool) */ static struct ot_context *ot_init_sync_m0(struct ot_test *test) { struct ot_context *sop = NULL; int max = num_possible_cpus() << 3; gfp_t gfp = GFP_KERNEL; sop = (struct ot_context *)ot_kzalloc(test, sizeof(*sop)); if (!sop) return NULL; sop->test = test; if (test->objsz < 512) gfp = GFP_ATOMIC; if (objpool_init(&sop->pool, max, test->objsz, gfp, sop, ot_init_node, NULL)) { ot_kfree(test, sop, sizeof(*sop)); return NULL; } WARN_ON(max != sop->pool.nr_objs); return sop; } static void ot_fini_sync(struct ot_context *sop) { objpool_fini(&sop->pool); ot_kfree(sop->test, sop, sizeof(*sop)); } static struct { struct ot_context * (*init)(struct ot_test *oc); void (*fini)(struct ot_context *sop); } g_ot_sync_ops[] = { {.init = ot_init_sync_m0, .fini = ot_fini_sync}, }; /* * synchronous test cases: performance mode */ static void ot_bulk_sync(struct ot_item *item, int irq) { struct ot_node *nods[OT_NR_MAX_BULK]; int i; for (i = 0; i < item->bulk[irq]; i++) nods[i] = objpool_pop(item->pool); if (!irq && (item->delay || !(++(item->niters) & 0x7FFF))) msleep(item->delay); while (i-- > 0) { struct ot_node *on = nods[i]; if (on) { on->refs++; objpool_push(on, item->pool); item->stat[irq].nhits++; } else { item->stat[irq].nmiss++; } } } static int ot_start_sync(struct ot_test *test) { struct ot_context *sop; ktime_t start; u64 duration; unsigned long timeout; int cpu; /* initialize objpool for syncrhonous testcase */ sop = g_ot_sync_ops[test->mode].init(test); if (!sop) return -ENOMEM; /* grab rwsem to block testing threads */ down_write(&test->data.start); for_each_possible_cpu(cpu) { struct ot_item *item = per_cpu_ptr(&ot_pcup_items, cpu); struct task_struct *work; ot_init_cpu_item(item, test, &sop->pool, ot_bulk_sync); /* skip offline cpus */ if (!cpu_online(cpu)) continue; work = kthread_create_on_node(ot_thread_worker, item, cpu_to_node(cpu), "ot_worker_%d", cpu); if (IS_ERR(work)) { pr_err("failed to create thread for cpu %d\n", cpu); } else { kthread_bind(work, cpu); wake_up_process(work); } } /* wait a while to make sure all threads waiting at start line */ msleep(20); /* in case no threads were created: memory insufficient ? */ if (atomic_dec_and_test(&test->data.nthreads)) complete(&test->data.wait); // sched_set_fifo_low(current); /* start objpool testing threads */ start = ktime_get(); up_write(&test->data.start); /* yeild cpu to worker threads for duration ms */ timeout = msecs_to_jiffies(test->duration); schedule_timeout_interruptible(timeout); /* tell workers threads to quit */ atomic_set_release(&test->data.stop, 1); /* wait all workers threads finish and quit */ wait_for_completion(&test->data.wait); duration = (u64) ktime_us_delta(ktime_get(), start); /* cleanup objpool */ g_ot_sync_ops[test->mode].fini(sop); /* report testing summary and performance results */ ot_perf_report(test, duration); /* report memory allocation summary */ ot_mem_report(test); return 0; } /* * asynchronous test cases: pool lifecycle controlled by refcount */ static void ot_fini_async_rcu(struct rcu_head *rcu) { struct ot_context *sop = container_of(rcu, struct ot_context, rcu); struct ot_test *test = sop->test; /* here all cpus are aware of the stop event: test->data.stop = 1 */ WARN_ON(!atomic_read_acquire(&test->data.stop)); objpool_fini(&sop->pool); complete(&test->data.rcu); } static void ot_fini_async(struct ot_context *sop) { /* make sure the stop event is acknowledged by all cores */ call_rcu(&sop->rcu, ot_fini_async_rcu); } static int ot_objpool_release(struct objpool_head *head, void *context) { struct ot_context *sop = context; WARN_ON(!head || !sop || head != &sop->pool); /* do context cleaning if needed */ if (sop) ot_kfree(sop->test, sop, sizeof(*sop)); return 0; } static struct ot_context *ot_init_async_m0(struct ot_test *test) { struct ot_context *sop = NULL; int max = num_possible_cpus() << 3; gfp_t gfp = GFP_KERNEL; sop = (struct ot_context *)ot_kzalloc(test, sizeof(*sop)); if (!sop) return NULL; sop->test = test; if (test->objsz < 512) gfp = GFP_ATOMIC; if (objpool_init(&sop->pool, max, test->objsz, gfp, sop, ot_init_node, ot_objpool_release)) { ot_kfree(test, sop, sizeof(*sop)); return NULL; } WARN_ON(max != sop->pool.nr_objs); return sop; } static struct { struct ot_context * (*init)(struct ot_test *oc); void (*fini)(struct ot_context *sop); } g_ot_async_ops[] = { {.init = ot_init_async_m0, .fini = ot_fini_async}, }; static void ot_nod_recycle(struct ot_node *on, struct objpool_head *pool, int release) { struct ot_context *sop; on->refs++; if (!release) { /* push object back to opjpool for reuse */ objpool_push(on, pool); return; } sop = container_of(pool, struct ot_context, pool); WARN_ON(sop != pool->context); /* unref objpool with nod removed forever */ objpool_drop(on, pool); } static void ot_bulk_async(struct ot_item *item, int irq) { struct ot_test *test = item->test; struct ot_node *nods[OT_NR_MAX_BULK]; int i, stop; for (i = 0; i < item->bulk[irq]; i++) nods[i] = objpool_pop(item->pool); if (!irq) { if (item->delay || !(++(item->niters) & 0x7FFF)) msleep(item->delay); get_cpu(); } stop = atomic_read_acquire(&test->data.stop); /* drop all objects and deref objpool */ while (i-- > 0) { struct ot_node *on = nods[i]; if (on) { on->refs++; ot_nod_recycle(on, item->pool, stop); item->stat[irq].nhits++; } else { item->stat[irq].nmiss++; } } if (!irq) put_cpu(); } static int ot_start_async(struct ot_test *test) { struct ot_context *sop; ktime_t start; u64 duration; unsigned long timeout; int cpu; /* initialize objpool for syncrhonous testcase */ sop = g_ot_async_ops[test->mode].init(test); if (!sop) return -ENOMEM; /* grab rwsem to block testing threads */ down_write(&test->data.start); for_each_possible_cpu(cpu) { struct ot_item *item = per_cpu_ptr(&ot_pcup_items, cpu); struct task_struct *work; ot_init_cpu_item(item, test, &sop->pool, ot_bulk_async); /* skip offline cpus */ if (!cpu_online(cpu)) continue; work = kthread_create_on_node(ot_thread_worker, item, cpu_to_node(cpu), "ot_worker_%d", cpu); if (IS_ERR(work)) { pr_err("failed to create thread for cpu %d\n", cpu); } else { kthread_bind(work, cpu); wake_up_process(work); } } /* wait a while to make sure all threads waiting at start line */ msleep(20); /* in case no threads were created: memory insufficient ? */ if (atomic_dec_and_test(&test->data.nthreads)) complete(&test->data.wait); /* start objpool testing threads */ start = ktime_get(); up_write(&test->data.start); /* yeild cpu to worker threads for duration ms */ timeout = msecs_to_jiffies(test->duration); schedule_timeout_interruptible(timeout); /* tell workers threads to quit */ atomic_set_release(&test->data.stop, 1); /* do async-finalization */ g_ot_async_ops[test->mode].fini(sop); /* wait all workers threads finish and quit */ wait_for_completion(&test->data.wait); duration = (u64) ktime_us_delta(ktime_get(), start); /* assure rcu callback is triggered */ wait_for_completion(&test->data.rcu); /* * now we are sure that objpool is finalized either * by rcu callback or by worker threads */ /* report testing summary and performance results */ ot_perf_report(test, duration); /* report memory allocation summary */ ot_mem_report(test); return 0; } /* * predefined testing cases: * synchronous case / overrun case / async case * * async: synchronous or asynchronous testing * mode: only mode 0 supported * objsz: object size * duration: int, total test time in ms * delay: int, delay (in ms) between each iteration * bulk_normal: int, repeat times for thread worker * bulk_irq: int, repeat times for irq consumer * hrtimer: unsigned long, hrtimer intervnal in ms * name: char *, tag for current test ot_item */ #define NODE_COMPACT sizeof(struct ot_node) #define NODE_VMALLOC (512) static struct ot_test g_testcases[] = { /* sync & normal */ {0, 0, NODE_COMPACT, 1000, 0, 1, 0, 0, "sync: percpu objpool"}, {0, 0, NODE_VMALLOC, 1000, 0, 1, 0, 0, "sync: percpu objpool from vmalloc"}, /* sync & hrtimer */ {0, 0, NODE_COMPACT, 1000, 0, 1, 1, 4, "sync & hrtimer: percpu objpool"}, {0, 0, NODE_VMALLOC, 1000, 0, 1, 1, 4, "sync & hrtimer: percpu objpool from vmalloc"}, /* sync & overrun */ {0, 0, NODE_COMPACT, 1000, 0, 16, 0, 0, "sync overrun: percpu objpool"}, {0, 0, NODE_VMALLOC, 1000, 0, 16, 0, 0, "sync overrun: percpu objpool from vmalloc"}, /* async mode */ {1, 0, NODE_COMPACT, 1000, 100, 1, 0, 0, "async: percpu objpool"}, {1, 0, NODE_VMALLOC, 1000, 100, 1, 0, 0, "async: percpu objpool from vmalloc"}, /* async + hrtimer mode */ {1, 0, NODE_COMPACT, 1000, 0, 4, 4, 4, "async & hrtimer: percpu objpool"}, {1, 0, NODE_VMALLOC, 1000, 0, 4, 4, 4, "async & hrtimer: percpu objpool from vmalloc"}, }; static int __init ot_mod_init(void) { int i; /* perform testings */ for (i = 0; i < ARRAY_SIZE(g_testcases); i++) { ot_init_data(&g_testcases[i].data); if (g_testcases[i].async) ot_start_async(&g_testcases[i]); else ot_start_sync(&g_testcases[i]); } /* show tests summary */ pr_info("\n"); pr_info("Summary of testcases:\n"); for (i = 0; i < ARRAY_SIZE(g_testcases); i++) { pr_info(" duration: %lluus \thits: %10lu \tmiss: %10lu \t%s\n", g_testcases[i].data.duration, g_testcases[i].data.objects.nhits, g_testcases[i].data.objects.nmiss, g_testcases[i].name); } return -EAGAIN; } static void __exit ot_mod_exit(void) { } module_init(ot_mod_init); module_exit(ot_mod_exit); MODULE_LICENSE("GPL");
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