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1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255 1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282 1283 1284 1285 1286 1287 1288 1289 1290 1291 1292 1293 1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 | // SPDX-License-Identifier: GPL-2.0+ /* * Linux on zSeries Channel Measurement Facility support * * Copyright IBM Corp. 2000, 2006 * * Authors: Arnd Bergmann <arndb@de.ibm.com> * Cornelia Huck <cornelia.huck@de.ibm.com> * * original idea from Natarajan Krishnaswami <nkrishna@us.ibm.com> */ #define KMSG_COMPONENT "cio" #define pr_fmt(fmt) KMSG_COMPONENT ": " fmt #include <linux/memblock.h> #include <linux/device.h> #include <linux/init.h> #include <linux/list.h> #include <linux/export.h> #include <linux/moduleparam.h> #include <linux/slab.h> #include <linux/timex.h> /* get_tod_clock() */ #include <asm/ccwdev.h> #include <asm/cio.h> #include <asm/cmb.h> #include <asm/div64.h> #include "cio.h" #include "css.h" #include "device.h" #include "ioasm.h" #include "chsc.h" /* * parameter to enable cmf during boot, possible uses are: * "s390cmf" -- enable cmf and allocate 2 MB of ram so measuring can be * used on any subchannel * "s390cmf=<num>" -- enable cmf and allocate enough memory to measure * <num> subchannel, where <num> is an integer * between 1 and 65535, default is 1024 */ #define ARGSTRING "s390cmf" /* indices for READCMB */ enum cmb_index { avg_utilization = -1, /* basic and exended format: */ cmb_ssch_rsch_count = 0, cmb_sample_count, cmb_device_connect_time, cmb_function_pending_time, cmb_device_disconnect_time, cmb_control_unit_queuing_time, cmb_device_active_only_time, /* extended format only: */ cmb_device_busy_time, cmb_initial_command_response_time, }; /** * enum cmb_format - types of supported measurement block formats * * @CMF_BASIC: traditional channel measurement blocks supported * by all machines that we run on * @CMF_EXTENDED: improved format that was introduced with the z990 * machine * @CMF_AUTODETECT: default: use extended format when running on a machine * supporting extended format, otherwise fall back to * basic format */ enum cmb_format { CMF_BASIC, CMF_EXTENDED, CMF_AUTODETECT = -1, }; /* * format - actual format for all measurement blocks * * The format module parameter can be set to a value of 0 (zero) * or 1, indicating basic or extended format as described for * enum cmb_format. */ static int format = CMF_AUTODETECT; module_param(format, bint, 0444); /** * struct cmb_operations - functions to use depending on cmb_format * * Most of these functions operate on a struct ccw_device. There is only * one instance of struct cmb_operations because the format of the measurement * data is guaranteed to be the same for every ccw_device. * * @alloc: allocate memory for a channel measurement block, * either with the help of a special pool or with kmalloc * @free: free memory allocated with @alloc * @set: enable or disable measurement * @read: read a measurement entry at an index * @readall: read a measurement block in a common format * @reset: clear the data in the associated measurement block and * reset its time stamp */ struct cmb_operations { int (*alloc) (struct ccw_device *); void (*free) (struct ccw_device *); int (*set) (struct ccw_device *, u32); u64 (*read) (struct ccw_device *, int); int (*readall)(struct ccw_device *, struct cmbdata *); void (*reset) (struct ccw_device *); /* private: */ struct attribute_group *attr_group; }; static struct cmb_operations *cmbops; struct cmb_data { void *hw_block; /* Pointer to block updated by hardware */ void *last_block; /* Last changed block copied from hardware block */ int size; /* Size of hw_block and last_block */ unsigned long long last_update; /* when last_block was updated */ }; /* * Our user interface is designed in terms of nanoseconds, * while the hardware measures total times in its own * unit. */ static inline u64 time_to_nsec(u32 value) { return ((u64)value) * 128000ull; } /* * Users are usually interested in average times, * not accumulated time. * This also helps us with atomicity problems * when reading sinlge values. */ static inline u64 time_to_avg_nsec(u32 value, u32 count) { u64 ret; /* no samples yet, avoid division by 0 */ if (count == 0) return 0; /* value comes in units of 128 µsec */ ret = time_to_nsec(value); do_div(ret, count); return ret; } #define CMF_OFF 0 #define CMF_ON 2 /* * Activate or deactivate the channel monitor. When area is NULL, * the monitor is deactivated. The channel monitor needs to * be active in order to measure subchannels, which also need * to be enabled. */ static inline void cmf_activate(void *area, unsigned int onoff) { /* activate channel measurement */ asm volatile( " lgr 1,%[r1]\n" " lgr 2,%[mbo]\n" " schm\n" : : [r1] "d" ((unsigned long)onoff), [mbo] "d" (area) : "1", "2"); } static int set_schib(struct ccw_device *cdev, u32 mme, int mbfc, unsigned long address) { struct subchannel *sch = to_subchannel(cdev->dev.parent); int ret; sch->config.mme = mme; sch->config.mbfc = mbfc; /* address can be either a block address or a block index */ if (mbfc) sch->config.mba = address; else sch->config.mbi = address; ret = cio_commit_config(sch); if (!mme && ret == -ENODEV) { /* * The task was to disable measurement block updates but * the subchannel is already gone. Report success. */ ret = 0; } return ret; } struct set_schib_struct { u32 mme; int mbfc; unsigned long address; wait_queue_head_t wait; int ret; }; #define CMF_PENDING 1 #define SET_SCHIB_TIMEOUT (10 * HZ) static int set_schib_wait(struct ccw_device *cdev, u32 mme, int mbfc, unsigned long address) { struct set_schib_struct set_data; int ret = -ENODEV; spin_lock_irq(cdev->ccwlock); if (!cdev->private->cmb) goto out; ret = set_schib(cdev, mme, mbfc, address); if (ret != -EBUSY) goto out; /* if the device is not online, don't even try again */ if (cdev->private->state != DEV_STATE_ONLINE) goto out; init_waitqueue_head(&set_data.wait); set_data.mme = mme; set_data.mbfc = mbfc; set_data.address = address; set_data.ret = CMF_PENDING; cdev->private->state = DEV_STATE_CMFCHANGE; cdev->private->cmb_wait = &set_data; spin_unlock_irq(cdev->ccwlock); ret = wait_event_interruptible_timeout(set_data.wait, set_data.ret != CMF_PENDING, SET_SCHIB_TIMEOUT); spin_lock_irq(cdev->ccwlock); if (ret <= 0) { if (set_data.ret == CMF_PENDING) { set_data.ret = (ret == 0) ? -ETIME : ret; if (cdev->private->state == DEV_STATE_CMFCHANGE) cdev->private->state = DEV_STATE_ONLINE; } } cdev->private->cmb_wait = NULL; ret = set_data.ret; out: spin_unlock_irq(cdev->ccwlock); return ret; } void retry_set_schib(struct ccw_device *cdev) { struct set_schib_struct *set_data = cdev->private->cmb_wait; if (!set_data) return; set_data->ret = set_schib(cdev, set_data->mme, set_data->mbfc, set_data->address); wake_up(&set_data->wait); } static int cmf_copy_block(struct ccw_device *cdev) { struct subchannel *sch = to_subchannel(cdev->dev.parent); struct cmb_data *cmb_data; void *hw_block; if (cio_update_schib(sch)) return -ENODEV; if (scsw_fctl(&sch->schib.scsw) & SCSW_FCTL_START_FUNC) { /* Don't copy if a start function is in progress. */ if ((!(scsw_actl(&sch->schib.scsw) & SCSW_ACTL_SUSPENDED)) && (scsw_actl(&sch->schib.scsw) & (SCSW_ACTL_DEVACT | SCSW_ACTL_SCHACT)) && (!(scsw_stctl(&sch->schib.scsw) & SCSW_STCTL_SEC_STATUS))) return -EBUSY; } cmb_data = cdev->private->cmb; hw_block = cmb_data->hw_block; memcpy(cmb_data->last_block, hw_block, cmb_data->size); cmb_data->last_update = get_tod_clock(); return 0; } struct copy_block_struct { wait_queue_head_t wait; int ret; }; static int cmf_cmb_copy_wait(struct ccw_device *cdev) { struct copy_block_struct copy_block; int ret = -ENODEV; spin_lock_irq(cdev->ccwlock); if (!cdev->private->cmb) goto out; ret = cmf_copy_block(cdev); if (ret != -EBUSY) goto out; if (cdev->private->state != DEV_STATE_ONLINE) goto out; init_waitqueue_head(©_block.wait); copy_block.ret = CMF_PENDING; cdev->private->state = DEV_STATE_CMFUPDATE; cdev->private->cmb_wait = ©_block; spin_unlock_irq(cdev->ccwlock); ret = wait_event_interruptible(copy_block.wait, copy_block.ret != CMF_PENDING); spin_lock_irq(cdev->ccwlock); if (ret) { if (copy_block.ret == CMF_PENDING) { copy_block.ret = -ERESTARTSYS; if (cdev->private->state == DEV_STATE_CMFUPDATE) cdev->private->state = DEV_STATE_ONLINE; } } cdev->private->cmb_wait = NULL; ret = copy_block.ret; out: spin_unlock_irq(cdev->ccwlock); return ret; } void cmf_retry_copy_block(struct ccw_device *cdev) { struct copy_block_struct *copy_block = cdev->private->cmb_wait; if (!copy_block) return; copy_block->ret = cmf_copy_block(cdev); wake_up(©_block->wait); } static void cmf_generic_reset(struct ccw_device *cdev) { struct cmb_data *cmb_data; spin_lock_irq(cdev->ccwlock); cmb_data = cdev->private->cmb; if (cmb_data) { memset(cmb_data->last_block, 0, cmb_data->size); /* * Need to reset hw block as well to make the hardware start * from 0 again. */ memset(cmb_data->hw_block, 0, cmb_data->size); cmb_data->last_update = 0; } cdev->private->cmb_start_time = get_tod_clock(); spin_unlock_irq(cdev->ccwlock); } /** * struct cmb_area - container for global cmb data * * @mem: pointer to CMBs (only in basic measurement mode) * @list: contains a linked list of all subchannels * @num_channels: number of channels to be measured * @lock: protect concurrent access to @mem and @list */ struct cmb_area { struct cmb *mem; struct list_head list; int num_channels; spinlock_t lock; }; static struct cmb_area cmb_area = { .lock = __SPIN_LOCK_UNLOCKED(cmb_area.lock), .list = LIST_HEAD_INIT(cmb_area.list), .num_channels = 1024, }; /* ****** old style CMB handling ********/ /* * Basic channel measurement blocks are allocated in one contiguous * block of memory, which can not be moved as long as any channel * is active. Therefore, a maximum number of subchannels needs to * be defined somewhere. This is a module parameter, defaulting to * a reasonable value of 1024, or 32 kb of memory. * Current kernels don't allow kmalloc with more than 128kb, so the * maximum is 4096. */ module_param_named(maxchannels, cmb_area.num_channels, uint, 0444); /** * struct cmb - basic channel measurement block * @ssch_rsch_count: number of ssch and rsch * @sample_count: number of samples * @device_connect_time: time of device connect * @function_pending_time: time of function pending * @device_disconnect_time: time of device disconnect * @control_unit_queuing_time: time of control unit queuing * @device_active_only_time: time of device active only * @reserved: unused in basic measurement mode * * The measurement block as used by the hardware. The fields are described * further in z/Architecture Principles of Operation, chapter 17. * * The cmb area made up from these blocks must be a contiguous array and may * not be reallocated or freed. * Only one cmb area can be present in the system. */ struct cmb { u16 ssch_rsch_count; u16 sample_count; u32 device_connect_time; u32 function_pending_time; u32 device_disconnect_time; u32 control_unit_queuing_time; u32 device_active_only_time; u32 reserved[2]; }; /* * Insert a single device into the cmb_area list. * Called with cmb_area.lock held from alloc_cmb. */ static int alloc_cmb_single(struct ccw_device *cdev, struct cmb_data *cmb_data) { struct cmb *cmb; struct ccw_device_private *node; int ret; spin_lock_irq(cdev->ccwlock); if (!list_empty(&cdev->private->cmb_list)) { ret = -EBUSY; goto out; } /* * Find first unused cmb in cmb_area.mem. * This is a little tricky: cmb_area.list * remains sorted by ->cmb->hw_data pointers. */ cmb = cmb_area.mem; list_for_each_entry(node, &cmb_area.list, cmb_list) { struct cmb_data *data; data = node->cmb; if ((struct cmb*)data->hw_block > cmb) break; cmb++; } if (cmb - cmb_area.mem >= cmb_area.num_channels) { ret = -ENOMEM; goto out; } /* insert new cmb */ list_add_tail(&cdev->private->cmb_list, &node->cmb_list); cmb_data->hw_block = cmb; cdev->private->cmb = cmb_data; ret = 0; out: spin_unlock_irq(cdev->ccwlock); return ret; } static int alloc_cmb(struct ccw_device *cdev) { int ret; struct cmb *mem; ssize_t size; struct cmb_data *cmb_data; /* Allocate private cmb_data. */ cmb_data = kzalloc(sizeof(struct cmb_data), GFP_KERNEL); if (!cmb_data) return -ENOMEM; cmb_data->last_block = kzalloc(sizeof(struct cmb), GFP_KERNEL); if (!cmb_data->last_block) { kfree(cmb_data); return -ENOMEM; } cmb_data->size = sizeof(struct cmb); spin_lock(&cmb_area.lock); if (!cmb_area.mem) { /* there is no user yet, so we need a new area */ size = sizeof(struct cmb) * cmb_area.num_channels; WARN_ON(!list_empty(&cmb_area.list)); spin_unlock(&cmb_area.lock); mem = (void*)__get_free_pages(GFP_KERNEL | GFP_DMA, get_order(size)); spin_lock(&cmb_area.lock); if (cmb_area.mem) { /* ok, another thread was faster */ free_pages((unsigned long)mem, get_order(size)); } else if (!mem) { /* no luck */ ret = -ENOMEM; goto out; } else { /* everything ok */ memset(mem, 0, size); cmb_area.mem = mem; cmf_activate(cmb_area.mem, CMF_ON); } } /* do the actual allocation */ ret = alloc_cmb_single(cdev, cmb_data); out: spin_unlock(&cmb_area.lock); if (ret) { kfree(cmb_data->last_block); kfree(cmb_data); } return ret; } static void free_cmb(struct ccw_device *cdev) { struct ccw_device_private *priv; struct cmb_data *cmb_data; spin_lock(&cmb_area.lock); spin_lock_irq(cdev->ccwlock); priv = cdev->private; cmb_data = priv->cmb; priv->cmb = NULL; if (cmb_data) kfree(cmb_data->last_block); kfree(cmb_data); list_del_init(&priv->cmb_list); if (list_empty(&cmb_area.list)) { ssize_t size; size = sizeof(struct cmb) * cmb_area.num_channels; cmf_activate(NULL, CMF_OFF); free_pages((unsigned long)cmb_area.mem, get_order(size)); cmb_area.mem = NULL; } spin_unlock_irq(cdev->ccwlock); spin_unlock(&cmb_area.lock); } static int set_cmb(struct ccw_device *cdev, u32 mme) { u16 offset; struct cmb_data *cmb_data; unsigned long flags; spin_lock_irqsave(cdev->ccwlock, flags); if (!cdev->private->cmb) { spin_unlock_irqrestore(cdev->ccwlock, flags); return -EINVAL; } cmb_data = cdev->private->cmb; offset = mme ? (struct cmb *)cmb_data->hw_block - cmb_area.mem : 0; spin_unlock_irqrestore(cdev->ccwlock, flags); return set_schib_wait(cdev, mme, 0, offset); } /* calculate utilization in 0.1 percent units */ static u64 __cmb_utilization(u64 device_connect_time, u64 function_pending_time, u64 device_disconnect_time, u64 start_time) { u64 utilization, elapsed_time; utilization = time_to_nsec(device_connect_time + function_pending_time + device_disconnect_time); elapsed_time = get_tod_clock() - start_time; elapsed_time = tod_to_ns(elapsed_time); elapsed_time /= 1000; return elapsed_time ? (utilization / elapsed_time) : 0; } static u64 read_cmb(struct ccw_device *cdev, int index) { struct cmb_data *cmb_data; unsigned long flags; struct cmb *cmb; u64 ret = 0; u32 val; spin_lock_irqsave(cdev->ccwlock, flags); cmb_data = cdev->private->cmb; if (!cmb_data) goto out; cmb = cmb_data->hw_block; switch (index) { case avg_utilization: ret = __cmb_utilization(cmb->device_connect_time, cmb->function_pending_time, cmb->device_disconnect_time, cdev->private->cmb_start_time); goto out; case cmb_ssch_rsch_count: ret = cmb->ssch_rsch_count; goto out; case cmb_sample_count: ret = cmb->sample_count; goto out; case cmb_device_connect_time: val = cmb->device_connect_time; break; case cmb_function_pending_time: val = cmb->function_pending_time; break; case cmb_device_disconnect_time: val = cmb->device_disconnect_time; break; case cmb_control_unit_queuing_time: val = cmb->control_unit_queuing_time; break; case cmb_device_active_only_time: val = cmb->device_active_only_time; break; default: goto out; } ret = time_to_avg_nsec(val, cmb->sample_count); out: spin_unlock_irqrestore(cdev->ccwlock, flags); return ret; } static int readall_cmb(struct ccw_device *cdev, struct cmbdata *data) { struct cmb *cmb; struct cmb_data *cmb_data; u64 time; unsigned long flags; int ret; ret = cmf_cmb_copy_wait(cdev); if (ret < 0) return ret; spin_lock_irqsave(cdev->ccwlock, flags); cmb_data = cdev->private->cmb; if (!cmb_data) { ret = -ENODEV; goto out; } if (cmb_data->last_update == 0) { ret = -EAGAIN; goto out; } cmb = cmb_data->last_block; time = cmb_data->last_update - cdev->private->cmb_start_time; memset(data, 0, sizeof(struct cmbdata)); /* we only know values before device_busy_time */ data->size = offsetof(struct cmbdata, device_busy_time); data->elapsed_time = tod_to_ns(time); /* copy data to new structure */ data->ssch_rsch_count = cmb->ssch_rsch_count; data->sample_count = cmb->sample_count; /* time fields are converted to nanoseconds while copying */ data->device_connect_time = time_to_nsec(cmb->device_connect_time); data->function_pending_time = time_to_nsec(cmb->function_pending_time); data->device_disconnect_time = time_to_nsec(cmb->device_disconnect_time); data->control_unit_queuing_time = time_to_nsec(cmb->control_unit_queuing_time); data->device_active_only_time = time_to_nsec(cmb->device_active_only_time); ret = 0; out: spin_unlock_irqrestore(cdev->ccwlock, flags); return ret; } static void reset_cmb(struct ccw_device *cdev) { cmf_generic_reset(cdev); } static int cmf_enabled(struct ccw_device *cdev) { int enabled; spin_lock_irq(cdev->ccwlock); enabled = !!cdev->private->cmb; spin_unlock_irq(cdev->ccwlock); return enabled; } static struct attribute_group cmf_attr_group; static struct cmb_operations cmbops_basic = { .alloc = alloc_cmb, .free = free_cmb, .set = set_cmb, .read = read_cmb, .readall = readall_cmb, .reset = reset_cmb, .attr_group = &cmf_attr_group, }; /* ******** extended cmb handling ********/ /** * struct cmbe - extended channel measurement block * @ssch_rsch_count: number of ssch and rsch * @sample_count: number of samples * @device_connect_time: time of device connect * @function_pending_time: time of function pending * @device_disconnect_time: time of device disconnect * @control_unit_queuing_time: time of control unit queuing * @device_active_only_time: time of device active only * @device_busy_time: time of device busy * @initial_command_response_time: initial command response time * @reserved: unused * * The measurement block as used by the hardware. May be in any 64 bit physical * location. * The fields are described further in z/Architecture Principles of Operation, * third edition, chapter 17. */ struct cmbe { u32 ssch_rsch_count; u32 sample_count; u32 device_connect_time; u32 function_pending_time; u32 device_disconnect_time; u32 control_unit_queuing_time; u32 device_active_only_time; u32 device_busy_time; u32 initial_command_response_time; u32 reserved[7]; } __packed __aligned(64); static struct kmem_cache *cmbe_cache; static int alloc_cmbe(struct ccw_device *cdev) { struct cmb_data *cmb_data; struct cmbe *cmbe; int ret = -ENOMEM; cmbe = kmem_cache_zalloc(cmbe_cache, GFP_KERNEL); if (!cmbe) return ret; cmb_data = kzalloc(sizeof(*cmb_data), GFP_KERNEL); if (!cmb_data) goto out_free; cmb_data->last_block = kzalloc(sizeof(struct cmbe), GFP_KERNEL); if (!cmb_data->last_block) goto out_free; cmb_data->size = sizeof(*cmbe); cmb_data->hw_block = cmbe; spin_lock(&cmb_area.lock); spin_lock_irq(cdev->ccwlock); if (cdev->private->cmb) goto out_unlock; cdev->private->cmb = cmb_data; /* activate global measurement if this is the first channel */ if (list_empty(&cmb_area.list)) cmf_activate(NULL, CMF_ON); list_add_tail(&cdev->private->cmb_list, &cmb_area.list); spin_unlock_irq(cdev->ccwlock); spin_unlock(&cmb_area.lock); return 0; out_unlock: spin_unlock_irq(cdev->ccwlock); spin_unlock(&cmb_area.lock); ret = -EBUSY; out_free: if (cmb_data) kfree(cmb_data->last_block); kfree(cmb_data); kmem_cache_free(cmbe_cache, cmbe); return ret; } static void free_cmbe(struct ccw_device *cdev) { struct cmb_data *cmb_data; spin_lock(&cmb_area.lock); spin_lock_irq(cdev->ccwlock); cmb_data = cdev->private->cmb; cdev->private->cmb = NULL; if (cmb_data) { kfree(cmb_data->last_block); kmem_cache_free(cmbe_cache, cmb_data->hw_block); } kfree(cmb_data); /* deactivate global measurement if this is the last channel */ list_del_init(&cdev->private->cmb_list); if (list_empty(&cmb_area.list)) cmf_activate(NULL, CMF_OFF); spin_unlock_irq(cdev->ccwlock); spin_unlock(&cmb_area.lock); } static int set_cmbe(struct ccw_device *cdev, u32 mme) { unsigned long mba; struct cmb_data *cmb_data; unsigned long flags; spin_lock_irqsave(cdev->ccwlock, flags); if (!cdev->private->cmb) { spin_unlock_irqrestore(cdev->ccwlock, flags); return -EINVAL; } cmb_data = cdev->private->cmb; mba = mme ? (unsigned long) cmb_data->hw_block : 0; spin_unlock_irqrestore(cdev->ccwlock, flags); return set_schib_wait(cdev, mme, 1, mba); } static u64 read_cmbe(struct ccw_device *cdev, int index) { struct cmb_data *cmb_data; unsigned long flags; struct cmbe *cmb; u64 ret = 0; u32 val; spin_lock_irqsave(cdev->ccwlock, flags); cmb_data = cdev->private->cmb; if (!cmb_data) goto out; cmb = cmb_data->hw_block; switch (index) { case avg_utilization: ret = __cmb_utilization(cmb->device_connect_time, cmb->function_pending_time, cmb->device_disconnect_time, cdev->private->cmb_start_time); goto out; case cmb_ssch_rsch_count: ret = cmb->ssch_rsch_count; goto out; case cmb_sample_count: ret = cmb->sample_count; goto out; case cmb_device_connect_time: val = cmb->device_connect_time; break; case cmb_function_pending_time: val = cmb->function_pending_time; break; case cmb_device_disconnect_time: val = cmb->device_disconnect_time; break; case cmb_control_unit_queuing_time: val = cmb->control_unit_queuing_time; break; case cmb_device_active_only_time: val = cmb->device_active_only_time; break; case cmb_device_busy_time: val = cmb->device_busy_time; break; case cmb_initial_command_response_time: val = cmb->initial_command_response_time; break; default: goto out; } ret = time_to_avg_nsec(val, cmb->sample_count); out: spin_unlock_irqrestore(cdev->ccwlock, flags); return ret; } static int readall_cmbe(struct ccw_device *cdev, struct cmbdata *data) { struct cmbe *cmb; struct cmb_data *cmb_data; u64 time; unsigned long flags; int ret; ret = cmf_cmb_copy_wait(cdev); if (ret < 0) return ret; spin_lock_irqsave(cdev->ccwlock, flags); cmb_data = cdev->private->cmb; if (!cmb_data) { ret = -ENODEV; goto out; } if (cmb_data->last_update == 0) { ret = -EAGAIN; goto out; } time = cmb_data->last_update - cdev->private->cmb_start_time; memset (data, 0, sizeof(struct cmbdata)); /* we only know values before device_busy_time */ data->size = offsetof(struct cmbdata, device_busy_time); data->elapsed_time = tod_to_ns(time); cmb = cmb_data->last_block; /* copy data to new structure */ data->ssch_rsch_count = cmb->ssch_rsch_count; data->sample_count = cmb->sample_count; /* time fields are converted to nanoseconds while copying */ data->device_connect_time = time_to_nsec(cmb->device_connect_time); data->function_pending_time = time_to_nsec(cmb->function_pending_time); data->device_disconnect_time = time_to_nsec(cmb->device_disconnect_time); data->control_unit_queuing_time = time_to_nsec(cmb->control_unit_queuing_time); data->device_active_only_time = time_to_nsec(cmb->device_active_only_time); data->device_busy_time = time_to_nsec(cmb->device_busy_time); data->initial_command_response_time = time_to_nsec(cmb->initial_command_response_time); ret = 0; out: spin_unlock_irqrestore(cdev->ccwlock, flags); return ret; } static void reset_cmbe(struct ccw_device *cdev) { cmf_generic_reset(cdev); } static struct attribute_group cmf_attr_group_ext; static struct cmb_operations cmbops_extended = { .alloc = alloc_cmbe, .free = free_cmbe, .set = set_cmbe, .read = read_cmbe, .readall = readall_cmbe, .reset = reset_cmbe, .attr_group = &cmf_attr_group_ext, }; static ssize_t cmb_show_attr(struct device *dev, char *buf, enum cmb_index idx) { return sprintf(buf, "%lld\n", (unsigned long long) cmf_read(to_ccwdev(dev), idx)); } static ssize_t cmb_show_avg_sample_interval(struct device *dev, struct device_attribute *attr, char *buf) { struct ccw_device *cdev = to_ccwdev(dev); unsigned long count; long interval; count = cmf_read(cdev, cmb_sample_count); spin_lock_irq(cdev->ccwlock); if (count) { interval = get_tod_clock() - cdev->private->cmb_start_time; interval = tod_to_ns(interval); interval /= count; } else interval = -1; spin_unlock_irq(cdev->ccwlock); return sprintf(buf, "%ld\n", interval); } static ssize_t cmb_show_avg_utilization(struct device *dev, struct device_attribute *attr, char *buf) { unsigned long u = cmf_read(to_ccwdev(dev), avg_utilization); return sprintf(buf, "%02lu.%01lu%%\n", u / 10, u % 10); } #define cmf_attr(name) \ static ssize_t show_##name(struct device *dev, \ struct device_attribute *attr, char *buf) \ { return cmb_show_attr((dev), buf, cmb_##name); } \ static DEVICE_ATTR(name, 0444, show_##name, NULL); #define cmf_attr_avg(name) \ static ssize_t show_avg_##name(struct device *dev, \ struct device_attribute *attr, char *buf) \ { return cmb_show_attr((dev), buf, cmb_##name); } \ static DEVICE_ATTR(avg_##name, 0444, show_avg_##name, NULL); cmf_attr(ssch_rsch_count); cmf_attr(sample_count); cmf_attr_avg(device_connect_time); cmf_attr_avg(function_pending_time); cmf_attr_avg(device_disconnect_time); cmf_attr_avg(control_unit_queuing_time); cmf_attr_avg(device_active_only_time); cmf_attr_avg(device_busy_time); cmf_attr_avg(initial_command_response_time); static DEVICE_ATTR(avg_sample_interval, 0444, cmb_show_avg_sample_interval, NULL); static DEVICE_ATTR(avg_utilization, 0444, cmb_show_avg_utilization, NULL); static struct attribute *cmf_attributes[] = { &dev_attr_avg_sample_interval.attr, &dev_attr_avg_utilization.attr, &dev_attr_ssch_rsch_count.attr, &dev_attr_sample_count.attr, &dev_attr_avg_device_connect_time.attr, &dev_attr_avg_function_pending_time.attr, &dev_attr_avg_device_disconnect_time.attr, &dev_attr_avg_control_unit_queuing_time.attr, &dev_attr_avg_device_active_only_time.attr, NULL, }; static struct attribute_group cmf_attr_group = { .name = "cmf", .attrs = cmf_attributes, }; static struct attribute *cmf_attributes_ext[] = { &dev_attr_avg_sample_interval.attr, &dev_attr_avg_utilization.attr, &dev_attr_ssch_rsch_count.attr, &dev_attr_sample_count.attr, &dev_attr_avg_device_connect_time.attr, &dev_attr_avg_function_pending_time.attr, &dev_attr_avg_device_disconnect_time.attr, &dev_attr_avg_control_unit_queuing_time.attr, &dev_attr_avg_device_active_only_time.attr, &dev_attr_avg_device_busy_time.attr, &dev_attr_avg_initial_command_response_time.attr, NULL, }; static struct attribute_group cmf_attr_group_ext = { .name = "cmf", .attrs = cmf_attributes_ext, }; static ssize_t cmb_enable_show(struct device *dev, struct device_attribute *attr, char *buf) { struct ccw_device *cdev = to_ccwdev(dev); return sprintf(buf, "%d\n", cmf_enabled(cdev)); } static ssize_t cmb_enable_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t c) { struct ccw_device *cdev = to_ccwdev(dev); unsigned long val; int ret; ret = kstrtoul(buf, 16, &val); if (ret) return ret; switch (val) { case 0: ret = disable_cmf(cdev); break; case 1: ret = enable_cmf(cdev); break; default: ret = -EINVAL; } return ret ? ret : c; } DEVICE_ATTR_RW(cmb_enable); /** * enable_cmf() - switch on the channel measurement for a specific device * @cdev: The ccw device to be enabled * * Enable channel measurements for @cdev. If this is called on a device * for which channel measurement is already enabled a reset of the * measurement data is triggered. * Returns: %0 for success or a negative error value. * Context: * non-atomic */ int enable_cmf(struct ccw_device *cdev) { int ret = 0; device_lock(&cdev->dev); if (cmf_enabled(cdev)) { cmbops->reset(cdev); goto out_unlock; } get_device(&cdev->dev); ret = cmbops->alloc(cdev); if (ret) goto out; cmbops->reset(cdev); ret = sysfs_create_group(&cdev->dev.kobj, cmbops->attr_group); if (ret) { cmbops->free(cdev); goto out; } ret = cmbops->set(cdev, 2); if (ret) { sysfs_remove_group(&cdev->dev.kobj, cmbops->attr_group); cmbops->free(cdev); } out: if (ret) put_device(&cdev->dev); out_unlock: device_unlock(&cdev->dev); return ret; } /** * __disable_cmf() - switch off the channel measurement for a specific device * @cdev: The ccw device to be disabled * * Returns: %0 for success or a negative error value. * * Context: * non-atomic, device_lock() held. */ int __disable_cmf(struct ccw_device *cdev) { int ret; ret = cmbops->set(cdev, 0); if (ret) return ret; sysfs_remove_group(&cdev->dev.kobj, cmbops->attr_group); cmbops->free(cdev); put_device(&cdev->dev); return ret; } /** * disable_cmf() - switch off the channel measurement for a specific device * @cdev: The ccw device to be disabled * * Returns: %0 for success or a negative error value. * * Context: * non-atomic */ int disable_cmf(struct ccw_device *cdev) { int ret; device_lock(&cdev->dev); ret = __disable_cmf(cdev); device_unlock(&cdev->dev); return ret; } /** * cmf_read() - read one value from the current channel measurement block * @cdev: the channel to be read * @index: the index of the value to be read * * Returns: The value read or %0 if the value cannot be read. * * Context: * any */ u64 cmf_read(struct ccw_device *cdev, int index) { return cmbops->read(cdev, index); } /** * cmf_readall() - read the current channel measurement block * @cdev: the channel to be read * @data: a pointer to a data block that will be filled * * Returns: %0 on success, a negative error value otherwise. * * Context: * any */ int cmf_readall(struct ccw_device *cdev, struct cmbdata *data) { return cmbops->readall(cdev, data); } /* Reenable cmf when a disconnected device becomes available again. */ int cmf_reenable(struct ccw_device *cdev) { cmbops->reset(cdev); return cmbops->set(cdev, 2); } /** * cmf_reactivate() - reactivate measurement block updates * * Use this during resume from hibernate. */ void cmf_reactivate(void) { spin_lock(&cmb_area.lock); if (!list_empty(&cmb_area.list)) cmf_activate(cmb_area.mem, CMF_ON); spin_unlock(&cmb_area.lock); } static int __init init_cmbe(void) { cmbe_cache = kmem_cache_create("cmbe_cache", sizeof(struct cmbe), __alignof__(struct cmbe), 0, NULL); return cmbe_cache ? 0 : -ENOMEM; } static int __init init_cmf(void) { char *format_string; char *detect_string; int ret; /* * If the user did not give a parameter, see if we are running on a * machine supporting extended measurement blocks, otherwise fall back * to basic mode. */ if (format == CMF_AUTODETECT) { if (!css_general_characteristics.ext_mb) { format = CMF_BASIC; } else { format = CMF_EXTENDED; } detect_string = "autodetected"; } else { detect_string = "parameter"; } switch (format) { case CMF_BASIC: format_string = "basic"; cmbops = &cmbops_basic; break; case CMF_EXTENDED: format_string = "extended"; cmbops = &cmbops_extended; ret = init_cmbe(); if (ret) return ret; break; default: return -EINVAL; } pr_info("Channel measurement facility initialized using format " "%s (mode %s)\n", format_string, detect_string); return 0; } device_initcall(init_cmf); EXPORT_SYMBOL_GPL(enable_cmf); EXPORT_SYMBOL_GPL(disable_cmf); EXPORT_SYMBOL_GPL(cmf_read); EXPORT_SYMBOL_GPL(cmf_readall); |