/* * arch/s390/appldata/appldata_os.c * * Data gathering module for Linux-VM Monitor Stream, Stage 1. * Collects misc. OS related data (CPU utilization, running processes). * * Copyright (C) 2003,2006 IBM Corporation, IBM Deutschland Entwicklung GmbH. * * Author: Gerald Schaefer */ #include #include #include #include #include #include #include #include #include #include "appldata.h" #define MY_PRINT_NAME "appldata_os" /* for debug messages, etc. */ #define LOAD_INT(x) ((x) >> FSHIFT) #define LOAD_FRAC(x) LOAD_INT(((x) & (FIXED_1-1)) * 100) /* * OS data * * This is accessed as binary data by z/VM. If changes to it can't be avoided, * the structure version (product ID, see appldata_base.c) needs to be changed * as well and all documentation and z/VM applications using it must be * updated. * * The record layout is documented in the Linux for zSeries Device Drivers * book: * http://oss.software.ibm.com/developerworks/opensource/linux390/index.shtml */ struct appldata_os_per_cpu { u32 per_cpu_user; /* timer ticks spent in user mode */ u32 per_cpu_nice; /* ... spent with modified priority */ u32 per_cpu_system; /* ... spent in kernel mode */ u32 per_cpu_idle; /* ... spent in idle mode */ /* New in 2.6 */ u32 per_cpu_irq; /* ... spent in interrupts */ u32 per_cpu_softirq; /* ... spent in softirqs */ u32 per_cpu_iowait; /* ... spent while waiting for I/O */ /* New in modification level 01 */ u32 per_cpu_steal; /* ... stolen by hypervisor */ u32 cpu_id; /* number of this CPU */ } __attribute__((packed)); struct appldata_os_data { u64 timestamp; u32 sync_count_1; /* after VM collected the record data, */ u32 sync_count_2; /* sync_count_1 and sync_count_2 should be the same. If not, the record has been updated on the Linux side while VM was collecting the (possibly corrupt) data */ u32 nr_cpus; /* number of (virtual) CPUs */ u32 per_cpu_size; /* size of the per-cpu data struct */ u32 cpu_offset; /* offset of the first per-cpu data struct */ u32 nr_running; /* number of runnable threads */ u32 nr_threads; /* number of threads */ u32 avenrun[3]; /* average nr. of running processes during */ /* the last 1, 5 and 15 minutes */ /* New in 2.6 */ u32 nr_iowait; /* number of blocked threads (waiting for I/O) */ /* per cpu data */ struct appldata_os_per_cpu os_cpu[0]; } __attribute__((packed)); static struct appldata_os_data *appldata_os_data; static struct appldata_ops ops = { .ctl_nr = CTL_APPLDATA_OS, .name = "os", .record_nr = APPLDATA_RECORD_OS_ID, .owner = THIS_MODULE, .mod_lvl = {0xF0, 0xF1}, /* EBCDIC "01" */ }; static inline void appldata_print_debug(struct appldata_os_data *os_data) { int a0, a1, a2, i; P_DEBUG("--- OS - RECORD ---\n"); P_DEBUG("nr_threads = %u\n", os_data->nr_threads); P_DEBUG("nr_running = %u\n", os_data->nr_running); P_DEBUG("nr_iowait = %u\n", os_data->nr_iowait); P_DEBUG("avenrun(int) = %8x / %8x / %8x\n", os_data->avenrun[0], os_data->avenrun[1], os_data->avenrun[2]); a0 = os_data->avenrun[0]; a1 = os_data->avenrun[1]; a2 = os_data->avenrun[2]; P_DEBUG("avenrun(float) = %d.%02d / %d.%02d / %d.%02d\n", LOAD_INT(a0), LOAD_FRAC(a0), LOAD_INT(a1), LOAD_FRAC(a1), LOAD_INT(a2), LOAD_FRAC(a2)); P_DEBUG("nr_cpus = %u\n", os_data->nr_cpus); for (i = 0; i < os_data->nr_cpus; i++) { P_DEBUG("cpu%u : user = %u, nice = %u, system = %u, " "idle = %u, irq = %u, softirq = %u, iowait = %u, " "steal = %u\n", os_data->os_cpu[i].cpu_id, os_data->os_cpu[i].per_cpu_user, os_data->os_cpu[i].per_cpu_nice, os_data->os_cpu[i].per_cpu_system, os_data->os_cpu[i].per_cpu_idle, os_data->os_cpu[i].per_cpu_irq, os_data->os_cpu[i].per_cpu_softirq, os_data->os_cpu[i].per_cpu_iowait, os_data->os_cpu[i].per_cpu_steal); } P_DEBUG("sync_count_1 = %u\n", os_data->sync_count_1); P_DEBUG("sync_count_2 = %u\n", os_data->sync_count_2); P_DEBUG("timestamp = %lX\n", os_data->timestamp); } /* * appldata_get_os_data() * * gather OS data */ static void appldata_get_os_data(void *data) { int i, j, rc; struct appldata_os_data *os_data; unsigned int new_size; os_data = data; os_data->sync_count_1++; os_data->nr_threads = nr_threads; os_data->nr_running = nr_running(); os_data->nr_iowait = nr_iowait(); os_data->avenrun[0] = avenrun[0] + (FIXED_1/200); os_data->avenrun[1] = avenrun[1] + (FIXED_1/200); os_data->avenrun[2] = avenrun[2] + (FIXED_1/200); j = 0; for_each_online_cpu(i) { os_data->os_cpu[j].per_cpu_user = cputime_to_jiffies(kstat_cpu(i).cpustat.user); os_data->os_cpu[j].per_cpu_nice = cputime_to_jiffies(kstat_cpu(i).cpustat.nice); os_data->os_cpu[j].per_cpu_system = cputime_to_jiffies(kstat_cpu(i).cpustat.system); os_data->os_cpu[j].per_cpu_idle = cputime_to_jiffies(kstat_cpu(i).cpustat.idle); os_data->os_cpu[j].per_cpu_irq = cputime_to_jiffies(kstat_cpu(i).cpustat.irq); os_data->os_cpu[j].per_cpu_softirq = cputime_to_jiffies(kstat_cpu(i).cpustat.softirq); os_data->os_cpu[j].per_cpu_iowait = cputime_to_jiffies(kstat_cpu(i).cpustat.iowait); os_data->os_cpu[j].per_cpu_steal = cputime_to_jiffies(kstat_cpu(i).cpustat.steal); os_data->os_cpu[j].cpu_id = i; j++; } os_data->nr_cpus = j; new_size = sizeof(struct appldata_os_data) + (os_data->nr_cpus * sizeof(struct appldata_os_per_cpu)); if (ops.size != new_size) { if (ops.active) { rc = appldata_diag(APPLDATA_RECORD_OS_ID, APPLDATA_START_INTERVAL_REC, (unsigned long) ops.data, new_size, ops.mod_lvl); if (rc != 0) { P_ERROR("os: START NEW DIAG 0xDC failed, " "return code: %d, new size = %i\n", rc, new_size); P_INFO("os: stopping old record now\n"); } else P_INFO("os: new record size = %i\n", new_size); rc = appldata_diag(APPLDATA_RECORD_OS_ID, APPLDATA_STOP_REC, (unsigned long) ops.data, ops.size, ops.mod_lvl); if (rc != 0) P_ERROR("os: STOP OLD DIAG 0xDC failed, " "return code: %d, old size = %i\n", rc, ops.size); else P_INFO("os: old record size = %i stopped\n", ops.size); } ops.size = new_size; } os_data->timestamp = get_clock(); os_data->sync_count_2++; #ifdef APPLDATA_DEBUG appldata_print_debug(os_data); #endif } /* * appldata_os_init() * * init data, register ops */ static int __init appldata_os_init(void) { int rc, max_size; max_size = sizeof(struct appldata_os_data) + (NR_CPUS * sizeof(struct appldata_os_per_cpu)); if (max_size > APPLDATA_MAX_REC_SIZE) { P_ERROR("Max. size of OS record = %i, bigger than maximum " "record size (%i)\n", max_size, APPLDATA_MAX_REC_SIZE); rc = -ENOMEM; goto out; } P_DEBUG("max. sizeof(os) = %i, sizeof(os_cpu) = %lu\n", max_size, sizeof(struct appldata_os_per_cpu)); appldata_os_data = kzalloc(max_size, GFP_DMA); if (appldata_os_data == NULL) { P_ERROR("No memory for %s!\n", ops.name); rc = -ENOMEM; goto out; } appldata_os_data->per_cpu_size = sizeof(struct appldata_os_per_cpu); appldata_os_data->cpu_offset = offsetof(struct appldata_os_data, os_cpu); P_DEBUG("cpu offset = %u\n", appldata_os_data->cpu_offset); ops.data = appldata_os_data; ops.callback = &appldata_get_os_data; rc = appldata_register_ops(&ops); if (rc != 0) { P_ERROR("Error registering ops, rc = %i\n", rc); kfree(appldata_os_data); } else { P_DEBUG("%s-ops registered!\n", ops.name); } out: return rc; } /* * appldata_os_exit() * * unregister ops */ static void __exit appldata_os_exit(void) { appldata_unregister_ops(&ops); kfree(appldata_os_data); P_DEBUG("%s-ops unregistered!\n", ops.name); } module_init(appldata_os_init); module_exit(appldata_os_exit); MODULE_LICENSE("GPL"); MODULE_AUTHOR("Gerald Schaefer"); MODULE_DESCRIPTION("Linux-VM Monitor Stream, OS statistics");