void convert_thread_options_to_cpu(struct thread_options *o, struct thread_options_pack *top) { int i, j; string_to_cpu(&o->description, top->description); string_to_cpu(&o->name, top->name); string_to_cpu(&o->directory, top->directory); string_to_cpu(&o->filename, top->filename); string_to_cpu(&o->filename_format, top->filename_format); string_to_cpu(&o->opendir, top->opendir); string_to_cpu(&o->ioengine, top->ioengine); string_to_cpu(&o->mmapfile, top->mmapfile); string_to_cpu(&o->read_iolog_file, top->read_iolog_file); string_to_cpu(&o->write_iolog_file, top->write_iolog_file); string_to_cpu(&o->bw_log_file, top->bw_log_file); string_to_cpu(&o->lat_log_file, top->lat_log_file); string_to_cpu(&o->iops_log_file, top->iops_log_file); string_to_cpu(&o->replay_redirect, top->replay_redirect); string_to_cpu(&o->exec_prerun, top->exec_prerun); string_to_cpu(&o->exec_postrun, top->exec_postrun); string_to_cpu(&o->ioscheduler, top->ioscheduler); string_to_cpu(&o->profile, top->profile); string_to_cpu(&o->cgroup, top->cgroup); o->td_ddir = le32_to_cpu(top->td_ddir); o->rw_seq = le32_to_cpu(top->rw_seq); o->kb_base = le32_to_cpu(top->kb_base); o->unit_base = le32_to_cpu(top->kb_base); o->ddir_seq_nr = le32_to_cpu(top->ddir_seq_nr); o->ddir_seq_add = le64_to_cpu(top->ddir_seq_add); o->iodepth = le32_to_cpu(top->iodepth); o->iodepth_low = le32_to_cpu(top->iodepth_low); o->iodepth_batch = le32_to_cpu(top->iodepth_batch); o->iodepth_batch_complete = le32_to_cpu(top->iodepth_batch_complete); o->size = le64_to_cpu(top->size); o->size_percent = le32_to_cpu(top->size_percent); o->fill_device = le32_to_cpu(top->fill_device); o->file_size_low = le64_to_cpu(top->file_size_low); o->file_size_high = le64_to_cpu(top->file_size_high); o->start_offset = le64_to_cpu(top->start_offset); for (i = 0; i < DDIR_RWDIR_CNT; i++) { o->bs[i] = le32_to_cpu(top->bs[i]); o->ba[i] = le32_to_cpu(top->ba[i]); o->min_bs[i] = le32_to_cpu(top->min_bs[i]); o->max_bs[i] = le32_to_cpu(top->max_bs[i]); o->bssplit_nr[i] = le32_to_cpu(top->bssplit_nr[i]); if (o->bssplit_nr[i]) { o->bssplit[i] = malloc(o->bssplit_nr[i] * sizeof(struct bssplit)); for (j = 0; j < o->bssplit_nr[i]; j++) { o->bssplit[i][j].bs = le32_to_cpu(top->bssplit[i][j].bs); o->bssplit[i][j].perc = le32_to_cpu(top->bssplit[i][j].perc); } } o->rwmix[i] = le32_to_cpu(top->rwmix[i]); o->rate[i] = le32_to_cpu(top->rate[i]); o->ratemin[i] = le32_to_cpu(top->ratemin[i]); o->rate_iops[i] = le32_to_cpu(top->rate_iops[i]); o->rate_iops_min[i] = le32_to_cpu(top->rate_iops_min[i]); o->perc_rand[i] = le32_to_cpu(top->perc_rand[i]); } o->ratecycle = le32_to_cpu(top->ratecycle); o->nr_files = le32_to_cpu(top->nr_files); o->open_files = le32_to_cpu(top->open_files); o->file_lock_mode = le32_to_cpu(top->file_lock_mode); o->odirect = le32_to_cpu(top->odirect); o->oatomic = le32_to_cpu(top->oatomic); o->invalidate_cache = le32_to_cpu(top->invalidate_cache); o->create_serialize = le32_to_cpu(top->create_serialize); o->create_fsync = le32_to_cpu(top->create_fsync); o->create_on_open = le32_to_cpu(top->create_on_open); o->create_only = le32_to_cpu(top->create_only); o->end_fsync = le32_to_cpu(top->end_fsync); o->pre_read = le32_to_cpu(top->pre_read); o->sync_io = le32_to_cpu(top->sync_io); o->verify = le32_to_cpu(top->verify); o->do_verify = le32_to_cpu(top->do_verify); o->verifysort = le32_to_cpu(top->verifysort); o->verifysort_nr = le32_to_cpu(top->verifysort_nr); o->experimental_verify = le32_to_cpu(top->experimental_verify); o->verify_interval = le32_to_cpu(top->verify_interval); o->verify_offset = le32_to_cpu(top->verify_offset); memcpy(o->verify_pattern, top->verify_pattern, MAX_PATTERN_SIZE); o->verify_pattern_bytes = le32_to_cpu(top->verify_pattern_bytes); o->verify_fatal = le32_to_cpu(top->verify_fatal); o->verify_dump = le32_to_cpu(top->verify_dump); o->verify_async = le32_to_cpu(top->verify_async); o->verify_batch = le32_to_cpu(top->verify_batch); o->use_thread = le32_to_cpu(top->use_thread); o->unlink = le32_to_cpu(top->unlink); o->do_disk_util = le32_to_cpu(top->do_disk_util); o->override_sync = le32_to_cpu(top->override_sync); o->rand_repeatable = le32_to_cpu(top->rand_repeatable); o->rand_seed = le32_to_cpu(top->rand_seed); o->use_os_rand = le32_to_cpu(top->use_os_rand); o->log_avg_msec = le32_to_cpu(top->log_avg_msec); o->norandommap = le32_to_cpu(top->norandommap); o->softrandommap = le32_to_cpu(top->softrandommap); o->bs_unaligned = le32_to_cpu(top->bs_unaligned); o->fsync_on_close = le32_to_cpu(top->fsync_on_close); o->bs_is_seq_rand = le32_to_cpu(top->bs_is_seq_rand); o->random_distribution = le32_to_cpu(top->random_distribution); o->zipf_theta.u.f = fio_uint64_to_double(le64_to_cpu(top->zipf_theta.u.i)); o->pareto_h.u.f = fio_uint64_to_double(le64_to_cpu(top->pareto_h.u.i)); o->random_generator = le32_to_cpu(top->random_generator); o->hugepage_size = le32_to_cpu(top->hugepage_size); o->rw_min_bs = le32_to_cpu(top->rw_min_bs); o->thinktime = le32_to_cpu(top->thinktime); o->thinktime_spin = le32_to_cpu(top->thinktime_spin); o->thinktime_blocks = le32_to_cpu(top->thinktime_blocks); o->fsync_blocks = le32_to_cpu(top->fsync_blocks); o->fdatasync_blocks = le32_to_cpu(top->fdatasync_blocks); o->barrier_blocks = le32_to_cpu(top->barrier_blocks); o->verify_backlog = le64_to_cpu(top->verify_backlog); o->start_delay = le64_to_cpu(top->start_delay); o->timeout = le64_to_cpu(top->timeout); o->ramp_time = le64_to_cpu(top->ramp_time); o->zone_range = le64_to_cpu(top->zone_range); o->zone_size = le64_to_cpu(top->zone_size); o->zone_skip = le64_to_cpu(top->zone_skip); o->lockmem = le64_to_cpu(top->lockmem); o->offset_increment = le64_to_cpu(top->offset_increment); o->number_ios = le64_to_cpu(top->number_ios); o->overwrite = le32_to_cpu(top->overwrite); o->bw_avg_time = le32_to_cpu(top->bw_avg_time); o->iops_avg_time = le32_to_cpu(top->iops_avg_time); o->loops = le32_to_cpu(top->loops); o->mem_type = le32_to_cpu(top->mem_type); o->mem_align = le32_to_cpu(top->mem_align); o->max_latency = le32_to_cpu(top->max_latency); o->stonewall = le32_to_cpu(top->stonewall); o->new_group = le32_to_cpu(top->new_group); o->numjobs = le32_to_cpu(top->numjobs); o->cpumask_set = le32_to_cpu(top->cpumask_set); o->verify_cpumask_set = le32_to_cpu(top->verify_cpumask_set); o->iolog = le32_to_cpu(top->iolog); o->rwmixcycle = le32_to_cpu(top->rwmixcycle); o->nice = le32_to_cpu(top->nice); o->ioprio = le32_to_cpu(top->ioprio); o->ioprio_class = le32_to_cpu(top->ioprio_class); o->file_service_type = le32_to_cpu(top->file_service_type); o->group_reporting = le32_to_cpu(top->group_reporting); o->fadvise_hint = le32_to_cpu(top->fadvise_hint); o->fallocate_mode = le32_to_cpu(top->fallocate_mode); o->zero_buffers = le32_to_cpu(top->zero_buffers); o->refill_buffers = le32_to_cpu(top->refill_buffers); o->scramble_buffers = le32_to_cpu(top->scramble_buffers); o->time_based = le32_to_cpu(top->time_based); o->disable_lat = le32_to_cpu(top->disable_lat); o->disable_clat = le32_to_cpu(top->disable_clat); o->disable_slat = le32_to_cpu(top->disable_slat); o->disable_bw = le32_to_cpu(top->disable_bw); o->unified_rw_rep = le32_to_cpu(top->unified_rw_rep); o->gtod_reduce = le32_to_cpu(top->gtod_reduce); o->gtod_cpu = le32_to_cpu(top->gtod_cpu); o->gtod_offload = le32_to_cpu(top->gtod_offload); o->clocksource = le32_to_cpu(top->clocksource); o->no_stall = le32_to_cpu(top->no_stall); o->trim_percentage = le32_to_cpu(top->trim_percentage); o->trim_batch = le32_to_cpu(top->trim_batch); o->trim_zero = le32_to_cpu(top->trim_zero); o->clat_percentiles = le32_to_cpu(top->clat_percentiles); o->percentile_precision = le32_to_cpu(top->percentile_precision); o->continue_on_error = le32_to_cpu(top->continue_on_error); o->cgroup_weight = le32_to_cpu(top->cgroup_weight); o->cgroup_nodelete = le32_to_cpu(top->cgroup_nodelete); o->uid = le32_to_cpu(top->uid); o->gid = le32_to_cpu(top->gid); o->flow_id = __le32_to_cpu(top->flow_id); o->flow = __le32_to_cpu(top->flow); o->flow_watermark = __le32_to_cpu(top->flow_watermark); o->flow_sleep = le32_to_cpu(top->flow_sleep); o->sync_file_range = le32_to_cpu(top->sync_file_range); o->latency_target = le64_to_cpu(top->latency_target); o->latency_window = le64_to_cpu(top->latency_window); o->latency_percentile.u.f = fio_uint64_to_double(le64_to_cpu(top->latency_percentile.u.i)); o->compress_percentage = le32_to_cpu(top->compress_percentage); o->compress_chunk = le32_to_cpu(top->compress_chunk); o->trim_backlog = le64_to_cpu(top->trim_backlog); for (i = 0; i < FIO_IO_U_LIST_MAX_LEN; i++) o->percentile_list[i].u.f = fio_uint64_to_double(le64_to_cpu(top->percentile_list[i].u.i)); #if 0 uint8_t cpumask[FIO_TOP_STR_MAX]; uint8_t verify_cpumask[FIO_TOP_STR_MAX]; #endif }
/* * We' call this early before loadmmu(). If we do the other way around * the firmware will crash and burn. */ void __init sgi_sysinit(void) { pcomponent *p, *toplev, *cpup = 0; int cputype = -1; long cnt; char c; /* The root component tells us what machine architecture we * have here. */ p = ArcGetChild(PROM_NULL_COMPONENT); /* Now scan for cpu(s). */ toplev = p = ArcGetChild(p); while(p) { int ncpus = 0; if(p->type == Cpu) { if(++ncpus > 1) { prom_printf("\nYeee, SGI MP not ready yet\n"); prom_printf("press a key to reboot\n"); ArcRead(0, &c, 1, &cnt); ArcEnterInteractiveMode(); } printk("CPU: %s ", p->iname); cpup = p; cputype = string_to_cpu(cpup->iname); } p = ArcGetPeer(p); } if (cputype == -1) { prom_printf("\nYeee, could not find cpu ARCS component\n"); prom_printf("press a key to reboot\n"); ArcRead(0, &c, 1, &cnt); ArcEnterInteractiveMode(); } p = ArcGetChild(cpup); while(p) { switch(p->class) { case processor: switch(p->type) { case Fpu: printk("FPU<%s> ", p->iname); break; default: break; }; break; case cache: switch(p->type) { case picache: printk("ICACHE "); break; case pdcache: printk("DCACHE "); break; case sccache: printk("SCACHE "); break; default: break; }; break; default: break; }; p = ArcGetPeer(p); } printk("\n"); }